#include <PFJetBenchmark.h>

Public Member Functions
void	gettrue (const reco::GenJet *truth, double &true_ChargedHadEnergy, double &true_NeutralHadEnergy, double &true_NeutralEmEnergy)

	PFJetBenchmark ()

void	printGenJet (const reco::GenJet *)

void	printPFJet (const reco::PFJet *)

void	process (const reco::PFJetCollection &, const reco::GenJetCollection &)

double	resChargedHadEnergyMax () const

double	resNeutralEmEnergyMax () const

double	resNeutralHadEnergyMax () const

double	resPtMax () const

void	setup (std::string Filename, bool debug, bool plotAgainstReco=false, bool onlyTwoJets=true, double deltaRMax=0.1, std::string benchmarkLabel_="ParticleFlow", double recPt=-1, double maxEta=-1, DQMStore *dbe_store=0)

void	write ()

virtual	~PFJetBenchmark ()

Protected Attributes
PFBenchmarkAlgo *	algo_

DQMStore *	dbe_

bool	debug_

double	deltaRMax_

unsigned int	entry_

double	maxEta_cut

bool	onlyTwoJets_

bool	plotAgainstReco_

double	recPt_cut

double	resChargedHadEnergyMax_

double	resNeutralEmEnergyMax_

double	resNeutralHadEnergyMax_

double	resPtMax_

Private Attributes
TFile *	file_

TH2F *	hBDEtavsPt

TH2F *	hBDPhivsPt

TH1F *	hBNCH

TH2F *	hBNCH0vsPt

TH2F *	hBNCH1vsPt

TH2F *	hBNCH2vsPt

TH2F *	hBNCH3vsPt

TH2F *	hBNCH4vsPt

TH2F *	hBNCH5vsPt

TH2F *	hBNCH6vsPt

TH2F *	hBNCH7vsPt

TH2F *	hBNCHvsPt

TH1F *	hBRCHE

TH2F *	hBRCHEvsPt

TH2F *	hBRHCALvsP

TH2F *	hBRHONLvsP

TH1F *	hBRNEE

TH2F *	hBRNEEvsPt

TH1F *	hBRneut

TH2F *	hBRNEUTvsP

TH2F *	hBRneutvsPt

TH1F *	hBRNHE

TH2F *	hBRNHEvsPt

TH2F *	hBRNONLvsP

TH1F *	hBRPt

TH1F *	hBRPt100_150

TH1F *	hBRPt1250_2000

TH1F *	hBRPt150_200

TH1F *	hBRPt2000_5000

TH1F *	hBRPt200_250

TH1F *	hBRPt20_40

TH1F *	hBRPt250_300

TH1F *	hBRPt300_400

TH1F *	hBRPt400_500

TH1F *	hBRPt40_60

TH1F *	hBRPt500_750

TH1F *	hBRPt60_80

TH1F *	hBRPt750_1250

TH1F *	hBRPt80_100

TH2F *	hBRPtvsPt

TH2F *	hDEtavsEta

TH2F *	hDPhivsEta

TH2F *	hEDEtavsPt

TH2F *	hEDPhivsPt

TH1F *	hENCH

TH2F *	hENCH0vsPt

TH2F *	hENCH1vsPt

TH2F *	hENCH2vsPt

TH2F *	hENCH3vsPt

TH2F *	hENCH4vsPt

TH2F *	hENCH5vsPt

TH2F *	hENCH6vsPt

TH2F *	hENCH7vsPt

TH2F *	hENCHvsPt

TH1F *	hERCHE

TH2F *	hERCHEvsPt

TH2F *	hERHCALvsP

TH2F *	hERHONLvsP

TH1F *	hERNEE

TH2F *	hERNEEvsPt

TH1F *	hERneut

TH2F *	hERNEUTvsP

TH2F *	hERneutvsPt

TH1F *	hERNHE

TH2F *	hERNHEvsPt

TH2F *	hERNONLvsP

TH1F *	hERPt

TH1F *	hERPt100_150

TH1F *	hERPt1250_2000

TH1F *	hERPt150_200

TH1F *	hERPt2000_5000

TH1F *	hERPt200_250

TH1F *	hERPt20_40

TH1F *	hERPt250_300

TH1F *	hERPt300_400

TH1F *	hERPt400_500

TH1F *	hERPt40_60

TH1F *	hERPt500_750

TH1F *	hERPt60_80

TH1F *	hERPt750_1250

TH1F *	hERPt80_100

TH2F *	hERPtvsPt

TH2F *	hFDEtavsPt

TH2F *	hFDPhivsPt

TH1F *	hFNCH

TH2F *	hFNCH0vsPt

TH2F *	hFNCH1vsPt

TH2F *	hFNCH2vsPt

TH2F *	hFNCH3vsPt

TH2F *	hFNCH4vsPt

TH2F *	hFNCH5vsPt

TH2F *	hFNCH6vsPt

TH2F *	hFNCH7vsPt

TH2F *	hFNCHvsPt

TH1F *	hFRCHE

TH2F *	hFRCHEvsPt

TH2F *	hFRHCALvsP

TH2F *	hFRHONLvsP

TH1F *	hFRNEE

TH2F *	hFRNEEvsPt

TH1F *	hFRneut

TH2F *	hFRNEUTvsP

TH2F *	hFRneutvsPt

TH1F *	hFRNHE

TH2F *	hFRNHEvsPt

TH2F *	hFRNONLvsP

TH1F *	hFRPt

TH1F *	hFRPt100_150

TH1F *	hFRPt1250_2000

TH1F *	hFRPt150_200

TH1F *	hFRPt2000_5000

TH1F *	hFRPt200_250

TH1F *	hFRPt20_40

TH1F *	hFRPt250_300

TH1F *	hFRPt300_400

TH1F *	hFRPt400_500

TH1F *	hFRPt40_60

TH1F *	hFRPt500_750

TH1F *	hFRPt60_80

TH1F *	hFRPt750_1250

TH1F *	hFRPt80_100

TH2F *	hFRPtvsPt

TH1F *	hjetsEta

TH1F *	hjetsPt

TH2F *	hNCH0vsEta

TH2F *	hNCH1vsEta

TH2F *	hNCH2vsEta

TH2F *	hNCH3vsEta

TH2F *	hNCH4vsEta

TH2F *	hNCH5vsEta

TH2F *	hNCH6vsEta

TH2F *	hNCH7vsEta

TH2F *	hNCHvsEta

TH1F *	hNjets

TH2F *	hRCHEvsEta

TH2F *	hRHCALvsEta

TH2F *	hRHONLvsEta

TH2F *	hRNeutvsEta

TH2F *	hRNEUTvsEta

TH2F *	hRNONLvsEta

TH2F *	hRPtvsEta

std::string	outputFile_

Detailed Description

Definition at line 30 of file PFJetBenchmark.h.

Constructor & Destructor Documentation

PFJetBenchmark::PFJetBenchmark ( )

Definition at line 42 of file PFJetBenchmark.cc.

42 : file_(nullptr), entry_(0) {}

PFJetBenchmark::entry_

unsigned int entry_

Definition: PFJetBenchmark.h:228

PFJetBenchmark::file_

TFile * file_

Definition: PFJetBenchmark.h:62

PFJetBenchmark::~PFJetBenchmark ( )

virtual

Definition at line 44 of file PFJetBenchmark.cc.

References file_.

                                 {
   if(file_) file_->Close();
 }

Member Function Documentation

void PFJetBenchmark::gettrue	(	const reco::GenJet *	truth,
		double &	true_ChargedHadEnergy,
		double &	true_NeutralHadEnergy,
		double &	true_NeutralEmEnergy
	)

Definition at line 644 of file PFJetBenchmark.cc.

References funct::abs(), MillePedeFileConverter_cfg::e, reco::LeafCandidate::energy(), reco::GenJet::getGenConstituents(), mps_fire::i, and reco::LeafCandidate::pdgId().

Referenced by process().

                                                                               {
   std::vector <const GenParticle*> mcparts = truth->getGenConstituents ();
   true_NeutralEmEnergy = 0.;
   true_ChargedHadEnergy = 0.;
   true_NeutralHadEnergy = 0.;
   // for each MC particle in turn  
   for (unsigned i = 0; i < mcparts.size (); i++) {
     const GenParticle* mcpart = mcparts[i];
     int PDG = std::abs( mcpart->pdgId());
     double e = mcpart->energy(); 
     switch(PDG){  // start PDG switch
     case 22: // photon
       true_NeutralEmEnergy += e;
       break;
     case 211: // pi
     case 321: // K
     case 2212: // p
     case 11: //electrons (until recognised)
       true_ChargedHadEnergy += e;
       break;
     case 310: // K_S0
     case 130: // K_L0
     case 3122: // Lambda0
     case 2112: // n0
       true_NeutralHadEnergy += e;
     default:
       break;
     }  // end PDG switch        
   }  // end loop on constituents.
 }

void PFJetBenchmark::printGenJet ( const reco::GenJet * truth )

Definition at line 697 of file PFJetBenchmark.cc.

References gather_cfg::cout, reco::LeafCandidate::eta(), reco::GenJet::getGenConstituents(), mps_fire::i, reco::LeafCandidate::p(), reco::LeafCandidate::pdgId(), reco::LeafCandidate::phi(), reco::LeafCandidate::pt(), reco::LeafCandidate::px(), reco::LeafCandidate::py(), and reco::LeafCandidate::pz().

Referenced by process().

                                                         {
   std::vector <const GenParticle*> mcparts = truth->getGenConstituents ();
   cout << "GenJet p/px/py/pz/pt: " << truth->p() << '/' << truth->px () 
        << '/' << truth->py() << '/' << truth->pz() << '/' << truth->pt() << endl
        << "    eta/phi: " << truth->eta () << '/' << truth->phi () << endl
        << "    # of constituents: " << mcparts.size() << endl;
   cout << "    constituents:" << endl;
   for (unsigned i = 0; i < mcparts.size (); i++) {
     const GenParticle* mcpart = mcparts[i];
     cout << "      #" << i << "  PDG code:" << mcpart->pdgId() 
      << ", p/pt/eta/phi: " << mcpart->p() << '/' << mcpart->pt() 
      << '/' << mcpart->eta() << '/' << mcpart->phi() << endl;   
   }    
 }

void PFJetBenchmark::printPFJet ( const reco::PFJet * pfj )

Definition at line 676 of file PFJetBenchmark.cc.

References reco::PFJet::chargedEmEnergy(), reco::PFJet::chargedHadronEnergy(), reco::PFJet::chargedMuEnergy(), reco::PFJet::chargedMultiplicity(), gather_cfg::cout, reco::LeafCandidate::eta(), alignBH_cfg::fixed, reco::PFJet::neutralEmEnergy(), reco::PFJet::neutralHadronEnergy(), reco::PFJet::neutralMultiplicity(), reco::LeafCandidate::p(), reco::LeafCandidate::phi(), reco::PFJet::print(), reco::LeafCandidate::pt(), reco::LeafCandidate::px(), reco::LeafCandidate::py(), and reco::LeafCandidate::pz().

Referenced by process().

                                                    {
   cout<<setiosflags(ios::right);
   cout<<setiosflags(ios::fixed);
   cout<<setprecision(3);
 
   cout << "PFJet  p/px/py/pz/pt: " << pfj->p() << "/" << pfj->px () 
        << "/" << pfj->py() << "/" << pfj->pz() << "/" << pfj->pt() << endl
        << "    eta/phi: " << pfj->eta () << "/" << pfj->phi () << endl          
        << "    PFJet specific:" << std::endl
        << "      charged/neutral hadrons energy: " << pfj->chargedHadronEnergy () << '/' << pfj->neutralHadronEnergy () << endl
        << "      charged/neutral em energy: " << pfj->chargedEmEnergy () << '/' << pfj->neutralEmEnergy () << endl
        << "      charged muon energy: " << pfj->chargedMuEnergy () << '/' << endl
        << "      charged/neutral multiplicity: " << pfj->chargedMultiplicity () << '/' << pfj->neutralMultiplicity () << endl;
   
   // And print the constituents
   std::cout << pfj->print() << std::endl;
 
   cout<<resetiosflags(ios::right|ios::fixed);
 }

void PFJetBenchmark::process	(	const reco::PFJetCollection &	pfJets,
		const reco::GenJetCollection &	genJets
	)

Definition at line 231 of file PFJetBenchmark.cc.

References funct::abs(), algo_, Barrel, reco::PFJet::chargedHadronEnergy(), reco::PFJet::chargedMultiplicity(), gather_cfg::cout, debug_, PFBenchmarkAlgo::deltaR(), boostedElectronIsolation_cff::deltaR, deltaRMax_, entry_, reco::LeafCandidate::eta(), reco::PFJet::getPFConstituents(), gettrue(), hBDEtavsPt, hBDPhivsPt, hBNCH, hBNCH0vsPt, hBNCH1vsPt, hBNCH2vsPt, hBNCH3vsPt, hBNCH4vsPt, hBNCH5vsPt, hBNCH6vsPt, hBNCH7vsPt, hBNCHvsPt, hBRCHE, hBRCHEvsPt, hBRHCALvsP, hBRHONLvsP, hBRNEE, hBRNEEvsPt, hBRneut, hBRNEUTvsP, hBRneutvsPt, hBRNHE, hBRNHEvsPt, hBRNONLvsP, hBRPt, hBRPt100_150, hBRPt1250_2000, hBRPt150_200, hBRPt2000_5000, hBRPt200_250, hBRPt20_40, hBRPt250_300, hBRPt300_400, hBRPt400_500, hBRPt40_60, hBRPt500_750, hBRPt60_80, hBRPt750_1250, hBRPt80_100, hBRPtvsPt, hDEtavsEta, hDPhivsEta, hEDEtavsPt, hEDPhivsPt, hENCH, hENCH0vsPt, hENCH1vsPt, hENCH2vsPt, hENCH3vsPt, hENCH4vsPt, hENCH5vsPt, hENCH6vsPt, hENCH7vsPt, hENCHvsPt, hERCHE, hERCHEvsPt, hERHCALvsP, hERHONLvsP, hERNEE, hERNEEvsPt, hERneut, hERNEUTvsP, hERneutvsPt, hERNHE, hERNHEvsPt, hERNONLvsP, hERPt, hERPt100_150, hERPt1250_2000, hERPt150_200, hERPt2000_5000, hERPt200_250, hERPt20_40, hERPt250_300, hERPt300_400, hERPt400_500, hERPt40_60, hERPt500_750, hERPt60_80, hERPt750_1250, hERPt80_100, hERPtvsPt, hFDEtavsPt, hFDPhivsPt, hFRCHE, hFRCHEvsPt, hFRHCALvsP, hFRHONLvsP, hFRNEE, hFRNEEvsPt, hFRneut, hFRNEUTvsP, hFRneutvsPt, hFRNHE, hFRNHEvsPt, hFRNONLvsP, hFRPt, hFRPt100_150, hFRPt1250_2000, hFRPt150_200, hFRPt2000_5000, hFRPt200_250, hFRPt20_40, hFRPt250_300, hFRPt300_400, hFRPt400_500, hFRPt40_60, hFRPt500_750, hFRPt60_80, hFRPt750_1250, hFRPt80_100, hFRPtvsPt, hjetsEta, hjetsPt, hNCH0vsEta, hNCH1vsEta, hNCH2vsEta, hNCH3vsEta, hNCH4vsEta, hNCH5vsEta, hNCH6vsEta, hNCH7vsEta, hNCHvsEta, hNjets, hRCHEvsEta, hRHCALvsEta, hRHONLvsEta, hRNeutvsEta, hRNEUTvsEta, hRNONLvsEta, hRPtvsEta, mps_fire::i, edm::Ref< C, T, F >::isNull(), PFBenchmarkAlgo::matchByDeltaR(), maxEta_cut, reco::PFJet::neutralEmEnergy(), reco::PFJet::neutralHadronEnergy(), onlyTwoJets_, reco::LeafCandidate::p(), reco::LeafCandidate::phi(), plotAgainstReco_, printGenJet(), printPFJet(), EnergyCorrector::pt, reco::LeafCandidate::pt(), recPt_cut, resChargedHadEnergyMax_, resNeutralEmEnergyMax_, resNeutralHadEnergyMax_, and resPtMax_.

Referenced by PFJetBenchmarkAnalyzer::analyze().

                                                                                                    {
   // loop over reco  pf  jets
   resPtMax_ = 0.;
   resChargedHadEnergyMax_ = 0.;
   resNeutralHadEnergyMax_ = 0.;
   resNeutralEmEnergyMax_ = 0.; 
   int NPFJets = 0;
     
   for(unsigned i=0; i<pfJets.size(); i++) {   
 
     // Count the number of jets with a larger energy
     unsigned highJets = 0;
     for(unsigned j=0; j<pfJets.size(); j++) { 
       if ( j != i && pfJets[j].pt() > pfJets[i].pt() ) highJets++;
     }
     if ( onlyTwoJets_ && highJets > 1 ) continue;
         
         
     const reco::PFJet& pfj = pfJets[i];
     double rec_pt = pfj.pt();
     double rec_eta = pfj.eta();
     double rec_phi = pfj.phi();
 
     // skip PFjets with pt < recPt_cut GeV
     if (rec_pt<recPt_cut and recPt_cut != -1.) continue;
     // skip PFjets with eta > maxEta_cut
     if (fabs(rec_eta)>maxEta_cut and maxEta_cut != -1.) continue;
 
     NPFJets++;
         
     // fill inclusive PFjet distribution pt > 20 GeV
     hNjets->Fill(NPFJets);
     hjetsPt->Fill(rec_pt);
     hjetsEta->Fill(rec_eta);
 
     // separate Barrel PFJets from Endcap PFJets
     bool Barrel = false;
     bool Endcap = false;
     bool Forward = false;
     if (std::abs(rec_eta) < 1.4 ) Barrel = true;
     if (std::abs (rec_eta) > 1.6 && std::abs (rec_eta) < 2.4 ) Endcap = true;
     if (std::abs (rec_eta) > 2.5 && std::abs (rec_eta) < 2.9 ) Forward = true;
     if (std::abs (rec_eta) > 3.1 && std::abs (rec_eta) < 4.7 ) Forward = true;
 
     // do only barrel for now
     //  if(!Barrel) continue;
 
     // look for the closets gen Jet : truth
     const GenJet *truth = algo_->matchByDeltaR(&pfj,&genJets);
     if(!truth) continue;   
     double deltaR = algo_->deltaR(&pfj, truth);
     // check deltaR is small enough
     if(deltaR < deltaRMax_ || (abs(rec_eta)>2.5 && deltaR < 0.2) || deltaRMax_ == -1.0 ) {//start case deltaR < deltaRMax
 
       // generate histograms comparing the reco and truth candidate (truth = closest in delta-R) 
       // get the quantities to place on the denominator and/or divide by
       double pt_denom;
       double true_E = truth->p();
       double true_pt = truth->pt();
       double true_eta = truth->eta();
       double true_phi = truth->phi();
 
       if (plotAgainstReco_) {pt_denom = rec_pt;}
       else {pt_denom = true_pt;}
       // get true specific quantities
       double true_ChargedHadEnergy;
       double true_NeutralHadEnergy;
       double true_NeutralEmEnergy;
       gettrue (truth, true_ChargedHadEnergy, true_NeutralHadEnergy, true_NeutralEmEnergy);
       double true_NeutralEnergy = true_NeutralHadEnergy + true_NeutralEmEnergy;
       double rec_ChargedHadEnergy = pfj.chargedHadronEnergy();
       double rec_NeutralHadEnergy = pfj.neutralHadronEnergy();
       double rec_NeutralEmEnergy = pfj.neutralEmEnergy();
       double rec_NeutralEnergy = rec_NeutralHadEnergy + rec_NeutralEmEnergy;
       double rec_ChargedMultiplicity = pfj.chargedMultiplicity();
       std::vector <PFCandidatePtr> constituents = pfj.getPFConstituents ();
       std::vector <unsigned int> chMult(9, static_cast<unsigned int>(0)); 
       for (unsigned ic = 0; ic < constituents.size (); ++ic) {
     if ( constituents[ic]->particleId() > 3 ) continue;
     reco::TrackRef trackRef = constituents[ic]->trackRef();
     if ( trackRef.isNull() ) {
       //std::cout << "Warning in entry " << entry_ 
       //        << " : a track with Id " << constituents[ic]->particleId() 
       //        << " has no track ref.." << std::endl;
       continue;
     }
     unsigned int iter = trackRef->algo()>6 ? 6: trackRef->algo();
     ++(chMult[iter]);
       }
 
       bool plot1 = false;
       bool plot2 = false;
       bool plot3 = false;
       bool plot4 = false;
       bool plot5 = false;
       bool plot6 = false;
       bool plot7 = false;
       double cut1 = 0.0001;
       double cut2 = 0.0001;
       double cut3 = 0.0001;
       double cut4 = 0.0001;
       double cut5 = 0.0001;
       double cut6 = 0.0001;
       double cut7 = 0.0001;
       double resPt =0.;
       double resChargedHadEnergy= 0.;
       double resNeutralHadEnergy= 0.;
       double resNeutralEmEnergy= 0.;
       double resNeutralEnergy= 0.;
 
       double resHCALEnergy = 0.;
       double resNEUTEnergy = 0.;
       if ( rec_NeutralHadEnergy > cut6 && rec_ChargedHadEnergy < cut1 ) { 
     double true_NEUTEnergy = true_NeutralHadEnergy + true_NeutralEmEnergy;
     double true_HCALEnergy = true_NEUTEnergy - rec_NeutralEmEnergy;
     double rec_NEUTEnergy = rec_NeutralHadEnergy+rec_NeutralEmEnergy; 
     double rec_HCALEnergy = rec_NeutralHadEnergy; 
     resHCALEnergy = (rec_HCALEnergy-true_HCALEnergy)/rec_HCALEnergy;
     resNEUTEnergy = (rec_NEUTEnergy-true_NEUTEnergy)/rec_NEUTEnergy;
     if ( rec_NeutralEmEnergy > cut7 ) {
       plot6 = true;
     } else {
       plot7 = true;
     }
       }
 
       // get relative delta quantities (protect against division by zero!)
       if (true_pt > 0.0001){
     resPt = (rec_pt -true_pt)/true_pt ; 
     plot1 = true;}
       if (true_ChargedHadEnergy > cut1){
     resChargedHadEnergy = (rec_ChargedHadEnergy- true_ChargedHadEnergy)/true_ChargedHadEnergy;
     plot2 = true;}
       if (true_NeutralHadEnergy > cut2){
     resNeutralHadEnergy = (rec_NeutralHadEnergy- true_NeutralHadEnergy)/true_NeutralHadEnergy;
     plot3 = true;}
       else 
     if (rec_NeutralHadEnergy > cut3){
       resNeutralHadEnergy = (rec_NeutralHadEnergy- true_NeutralHadEnergy)/rec_NeutralHadEnergy;
       plot3 = true;}
       if (true_NeutralEmEnergy > cut4){
     resNeutralEmEnergy = (rec_NeutralEmEnergy- true_NeutralEmEnergy)/true_NeutralEmEnergy;
     plot4 = true;}
       if (true_NeutralEnergy > cut5){
     resNeutralEnergy = (rec_NeutralEnergy- true_NeutralEnergy)/true_NeutralEnergy;
     plot5 = true;}
       
       //double deltaEta = algo_->deltaEta(&pfj, truth);
       //double deltaPhi = algo_->deltaPhi(&pfj, truth);
 
       // Print outliers for further debugging
       if ( ( resPt > 0.2 && true_pt > 100. ) || 
        ( resPt < -0.5 && true_pt > 100. ) ) {
     //if ( ( true_pt > 50. && 
     //     ( ( truth->eta()>3.0 && rec_eta-truth->eta() < -0.1 ) || 
     //       ( truth->eta()<-3.0 && rec_eta-truth->eta() > 0.1 ) ))) {
     std::cout << "Entry " << entry_ 
           << " resPt = " << resPt
           <<" resCharged  " << resChargedHadEnergy
           <<" resNeutralHad  " << resNeutralHadEnergy
           << " resNeutralEm  " << resNeutralEmEnergy
           << " pT (T/R) " << true_pt << "/" << rec_pt 
           << " Eta (T/R) " << truth->eta() << "/" << rec_eta 
           << " Phi (T/R) " << truth->phi() << "/" << rec_phi 
           << std::endl;
 
     // check overlapping PF jets
     const reco::PFJet* pfoj = nullptr; 
     double dRo = 1E9;
     for(unsigned j=0; j<pfJets.size(); j++) { 
       const reco::PFJet& pfo = pfJets[j];
       if ( j != i &&  algo_->deltaR(&pfj,&pfo) < dRo && pfo.pt() > 0.25*pfj.pt()) { 
         dRo = algo_->deltaR(&pfj,&pfo); 
         pfoj = &pfo;
       }
     }
     
     // Check overlapping Gen Jet 
     math::XYZTLorentzVector overlappinGenJet(0.,0.,0.,0.);
     const reco::GenJet* genoj = nullptr;
     double dRgo = 1E9;
     for(unsigned j=0; j<genJets.size(); j++) { 
       const reco::GenJet* gjo = &(genJets[j]);
       if ( gjo != truth && algo_->deltaR(truth,gjo) < dRgo && gjo->pt() > 0.25*truth->pt() ) { 
         dRgo = algo_->deltaR(truth,gjo);
         genoj = gjo;
       }
     }
     
     if ( dRo < 0.8 && dRgo < 0.8 && algo_->deltaR(genoj,pfoj) < 2.*deltaRMax_ ) 
       std::cout << "Excess probably due to overlapping jets (DR = " <<   algo_->deltaR(genoj,pfoj) << "),"
             << " at DeltaR(T/R) = " << dRgo << "/" << dRo  
             << " with pT(T/R) " << genoj->pt() << "/" << pfoj->pt()
             << " and Eta (T/R) " << genoj->eta() << "/" << pfoj->eta()
             << " and Phi (T/R) " << genoj->phi() << "/" << pfoj->phi()
             << std::endl;
       }
 
       if(std::abs(resPt) > std::abs(resPtMax_)) resPtMax_ = resPt;
       if(std::abs(resChargedHadEnergy) > std::abs(resChargedHadEnergyMax_) ) resChargedHadEnergyMax_ = resChargedHadEnergy;
       if(std::abs(resNeutralHadEnergy) > std::abs(resNeutralHadEnergyMax_) ) resNeutralHadEnergyMax_ = resNeutralHadEnergy;
       if(std::abs(resNeutralEmEnergy) > std::abs(resNeutralEmEnergyMax_) ) resNeutralEmEnergyMax_ = resNeutralEmEnergy;
       if (debug_) {
     cout << i <<"  =========PFJet Pt "<< rec_pt
          << " eta " << rec_eta
          << " phi " << rec_phi
          << " Charged Had Energy " << rec_ChargedHadEnergy
          << " Neutral Had Energy " << rec_NeutralHadEnergy
          << " Neutral elm Energy " << rec_NeutralEmEnergy << endl;
     cout << " matching Gen Jet Pt " << true_pt
          << " eta " << truth->eta()
          << " phi " << truth->phi()
          << " Charged Had Energy " << true_ChargedHadEnergy
          << " Neutral Had Energy " << true_NeutralHadEnergy
          << " Neutral elm Energy " << true_NeutralEmEnergy << endl;
     printPFJet(&pfj);
     //      cout<<pfj.print()<<endl;
     printGenJet(truth);
     //cout <<truth->print()<<endl;
                 
     cout << "==============deltaR " << deltaR << "  resPt " << resPt
          << " resChargedHadEnergy " << resChargedHadEnergy
          << " resNeutralHadEnergy " << resNeutralHadEnergy
          << " resNeutralEmEnergy " << resNeutralEmEnergy
          << endl;
       }
             
 
       if(plot1) {
     if ( rec_eta > 0. ) 
       hDEtavsEta->Fill(true_eta,rec_eta-true_eta);
     else
       hDEtavsEta->Fill(true_eta,-rec_eta+true_eta);
     hDPhivsEta->Fill(true_eta,rec_phi-true_phi);
 
     hRPtvsEta->Fill(true_eta, resPt);
     hNCHvsEta->Fill(true_eta, rec_ChargedMultiplicity);
     hNCH0vsEta->Fill(true_eta,chMult[0]);
     hNCH1vsEta->Fill(true_eta,chMult[1]);
     hNCH2vsEta->Fill(true_eta,chMult[2]);
     hNCH3vsEta->Fill(true_eta,chMult[3]);
     hNCH4vsEta->Fill(true_eta,chMult[4]);
     hNCH5vsEta->Fill(true_eta,chMult[5]);
     hNCH6vsEta->Fill(true_eta,chMult[6]);
     hNCH7vsEta->Fill(true_eta,chMult[7]);
       }
       if(plot2)hRCHEvsEta->Fill(true_eta, resChargedHadEnergy);
       if(plot5)hRNeutvsEta->Fill(true_eta, resNeutralEnergy);
       if(plot6) { 
     hRHCALvsEta->Fill(true_eta, resHCALEnergy);
     hRNEUTvsEta->Fill(true_eta, resNEUTEnergy);
       }
       if(plot7) {  
     hRHONLvsEta->Fill(true_eta, resHCALEnergy);
     hRNONLvsEta->Fill(true_eta, resNEUTEnergy);
       }
 
       // fill histograms for relative delta quantitites of matched jets
       // delta Pt or E quantities for Barrel
       if (Barrel){
     if(plot1) { 
       hBRPt->Fill (resPt);
       if ( pt_denom >  20. && pt_denom <  40. ) hBRPt20_40->Fill (resPt);
       if ( pt_denom >  40. && pt_denom <  60. ) hBRPt40_60->Fill (resPt);
       if ( pt_denom >  60. && pt_denom <  80. ) hBRPt60_80->Fill (resPt);
       if ( pt_denom >  80. && pt_denom < 100. ) hBRPt80_100->Fill (resPt);
       if ( pt_denom > 100. && pt_denom < 150. ) hBRPt100_150->Fill (resPt);
       if ( pt_denom > 150. && pt_denom < 200. ) hBRPt150_200->Fill (resPt);
       if ( pt_denom > 200. && pt_denom < 250. ) hBRPt200_250->Fill (resPt);
       if ( pt_denom > 250. && pt_denom < 300. ) hBRPt250_300->Fill (resPt);
       if ( pt_denom > 300. && pt_denom < 400. ) hBRPt300_400->Fill (resPt);
       if ( pt_denom > 400. && pt_denom < 500. ) hBRPt400_500->Fill (resPt);
       if ( pt_denom > 500. && pt_denom < 750. ) hBRPt500_750->Fill (resPt);
       if ( pt_denom > 750. && pt_denom < 1250. ) hBRPt750_1250->Fill (resPt);
       if ( pt_denom > 1250. && pt_denom < 2000. ) hBRPt1250_2000->Fill (resPt);
       if ( pt_denom > 2000. && pt_denom < 5000. ) hBRPt2000_5000->Fill (resPt);
       hBNCH->Fill(rec_ChargedMultiplicity);
       hBNCH0vsPt->Fill(pt_denom,chMult[0]);
       hBNCH1vsPt->Fill(pt_denom,chMult[1]);
       hBNCH2vsPt->Fill(pt_denom,chMult[2]);
       hBNCH3vsPt->Fill(pt_denom,chMult[3]);
       hBNCH4vsPt->Fill(pt_denom,chMult[4]);
       hBNCH5vsPt->Fill(pt_denom,chMult[5]);
       hBNCH6vsPt->Fill(pt_denom,chMult[6]);
       hBNCH7vsPt->Fill(pt_denom,chMult[7]);
       hBNCHvsPt->Fill(pt_denom,rec_ChargedMultiplicity);
       if ( rec_eta > 0. ) 
         hBDEtavsPt->Fill(pt_denom,rec_eta-true_eta);
       else
         hBDEtavsPt->Fill(pt_denom,-rec_eta+true_eta);
       hBDPhivsPt->Fill(pt_denom,rec_phi-true_phi);
     }
     if(plot2)hBRCHE->Fill(resChargedHadEnergy);
     if(plot3)hBRNHE->Fill(resNeutralHadEnergy);
     if(plot4)hBRNEE->Fill(resNeutralEmEnergy);
     if(plot5)hBRneut->Fill(resNeutralEnergy);
     if(plot1)hBRPtvsPt->Fill(pt_denom, resPt);
     if(plot2)hBRCHEvsPt->Fill(pt_denom, resChargedHadEnergy);
     if(plot3)hBRNHEvsPt->Fill(pt_denom, resNeutralHadEnergy);
     if(plot4)hBRNEEvsPt->Fill(pt_denom, resNeutralEmEnergy);
     if(plot5)hBRneutvsPt->Fill(pt_denom, resNeutralEnergy);
     if(plot6) { 
       hBRHCALvsP->Fill(true_E, resHCALEnergy);
       hBRNEUTvsP->Fill(true_E, resNEUTEnergy);
     }
     if(plot7) { 
       hBRHONLvsP->Fill(true_E, resHCALEnergy);
       hBRNONLvsP->Fill(true_E, resNEUTEnergy);
     }
 
       }
       // delta Pt or E quantities for Endcap
       if (Endcap){
     if(plot1) {
       hERPt->Fill (resPt);
       if ( pt_denom >  20. && pt_denom <  40. ) hERPt20_40->Fill (resPt);
       if ( pt_denom >  40. && pt_denom <  60. ) hERPt40_60->Fill (resPt);
       if ( pt_denom >  60. && pt_denom <  80. ) hERPt60_80->Fill (resPt);
       if ( pt_denom >  80. && pt_denom < 100. ) hERPt80_100->Fill (resPt);
       if ( pt_denom > 100. && pt_denom < 150. ) hERPt100_150->Fill (resPt);
       if ( pt_denom > 150. && pt_denom < 200. ) hERPt150_200->Fill (resPt);
       if ( pt_denom > 200. && pt_denom < 250. ) hERPt200_250->Fill (resPt);
       if ( pt_denom > 250. && pt_denom < 300. ) hERPt250_300->Fill (resPt);
       if ( pt_denom > 300. && pt_denom < 400. ) hERPt300_400->Fill (resPt);
       if ( pt_denom > 400. && pt_denom < 500. ) hERPt400_500->Fill (resPt);
       if ( pt_denom > 500. && pt_denom < 750. ) hERPt500_750->Fill (resPt);
       if ( pt_denom > 750. && pt_denom < 1250. ) hERPt750_1250->Fill (resPt);
       if ( pt_denom > 1250. && pt_denom < 2000. ) hERPt1250_2000->Fill (resPt);
       if ( pt_denom > 2000. && pt_denom < 5000. ) hERPt2000_5000->Fill (resPt);
       hENCH->Fill(rec_ChargedMultiplicity);
       hENCHvsPt->Fill(pt_denom,rec_ChargedMultiplicity);
       hENCH0vsPt->Fill(pt_denom,chMult[0]);
       hENCH1vsPt->Fill(pt_denom,chMult[1]);
       hENCH2vsPt->Fill(pt_denom,chMult[2]);
       hENCH3vsPt->Fill(pt_denom,chMult[3]);
       hENCH4vsPt->Fill(pt_denom,chMult[4]);
       hENCH5vsPt->Fill(pt_denom,chMult[5]);
       hENCH6vsPt->Fill(pt_denom,chMult[6]);
       hENCH7vsPt->Fill(pt_denom,chMult[7]);
       if ( rec_eta > 0. ) 
         hEDEtavsPt->Fill(pt_denom,rec_eta-true_eta);
       else
         hEDEtavsPt->Fill(pt_denom,-rec_eta+true_eta);
       hEDPhivsPt->Fill(pt_denom,rec_phi-true_phi);
     }
     if(plot2)hERCHE->Fill(resChargedHadEnergy);
     if(plot3)hERNHE->Fill(resNeutralHadEnergy);
     if(plot4)hERNEE->Fill(resNeutralEmEnergy);
     if(plot5)hERneut->Fill(resNeutralEnergy);
     if(plot1)hERPtvsPt->Fill(pt_denom, resPt);
     if(plot2)hERCHEvsPt->Fill(pt_denom, resChargedHadEnergy);
     if(plot3)hERNHEvsPt->Fill(pt_denom, resNeutralHadEnergy);
     if(plot4)hERNEEvsPt->Fill(pt_denom, resNeutralEmEnergy);
     if(plot5)hERneutvsPt->Fill(pt_denom, resNeutralEnergy);
     if(plot6) {
       hERHCALvsP->Fill(true_E, resHCALEnergy);
       hERNEUTvsP->Fill(true_E, resNEUTEnergy);
     }
     if(plot7) {
       hERHONLvsP->Fill(true_E, resHCALEnergy);
       hERNONLvsP->Fill(true_E, resNEUTEnergy);
     }
       }                     
       // delta Pt or E quantities for Forward
       if (Forward){
     if(plot1) {
       hFRPt->Fill (resPt);
       if ( pt_denom >  20. && pt_denom <  40. ) hFRPt20_40->Fill (resPt);
       if ( pt_denom >  40. && pt_denom <  60. ) hFRPt40_60->Fill (resPt);
       if ( pt_denom >  60. && pt_denom <  80. ) hFRPt60_80->Fill (resPt);
       if ( pt_denom >  80. && pt_denom < 100. ) hFRPt80_100->Fill (resPt);
       if ( pt_denom > 100. && pt_denom < 150. ) hFRPt100_150->Fill (resPt);
       if ( pt_denom > 150. && pt_denom < 200. ) hFRPt150_200->Fill (resPt);
       if ( pt_denom > 200. && pt_denom < 250. ) hFRPt200_250->Fill (resPt);
       if ( pt_denom > 250. && pt_denom < 300. ) hFRPt250_300->Fill (resPt);
       if ( pt_denom > 300. && pt_denom < 400. ) hFRPt300_400->Fill (resPt);
       if ( pt_denom > 400. && pt_denom < 500. ) hFRPt400_500->Fill (resPt);
       if ( pt_denom > 500. && pt_denom < 750. ) hFRPt500_750->Fill (resPt);
       if ( pt_denom > 750. && pt_denom < 1250. ) hFRPt750_1250->Fill (resPt);
       if ( pt_denom > 1250. && pt_denom < 2000. ) hFRPt1250_2000->Fill (resPt);
       if ( pt_denom > 2000. && pt_denom < 5000. ) hFRPt2000_5000->Fill (resPt);
       if ( rec_eta > 0. ) 
         hFDEtavsPt->Fill(pt_denom,rec_eta-true_eta);
       else
         hFDEtavsPt->Fill(pt_denom,-rec_eta+true_eta);
       hFDPhivsPt->Fill(pt_denom,rec_phi-true_phi);
     }
     if(plot2)hFRCHE->Fill(resChargedHadEnergy);
     if(plot3)hFRNHE->Fill(resNeutralHadEnergy);
     if(plot4)hFRNEE->Fill(resNeutralEmEnergy);
     if(plot5)hFRneut->Fill(resNeutralEnergy);
     if(plot1)hFRPtvsPt->Fill(pt_denom, resPt);
     if(plot2)hFRCHEvsPt->Fill(pt_denom, resChargedHadEnergy);
     if(plot3)hFRNHEvsPt->Fill(pt_denom, resNeutralHadEnergy);
     if(plot4)hFRNEEvsPt->Fill(pt_denom, resNeutralEmEnergy);
     if(plot5)hFRneutvsPt->Fill(pt_denom, resNeutralEnergy);
     if(plot6) {
       hFRHCALvsP->Fill(true_E, resHCALEnergy);
       hFRNEUTvsP->Fill(true_E, resNEUTEnergy);
     }
     if(plot7) {
       hFRHONLvsP->Fill(true_E, resHCALEnergy);
       hFRNONLvsP->Fill(true_E, resNEUTEnergy);
     }
       }                     
     } // end case deltaR < deltaRMax
         
   } // i loop on pf Jets    
 
   // Increment counter
   entry_++;
 }

double PFJetBenchmark::resChargedHadEnergyMax ( ) const

inline

Definition at line 54 of file PFJetBenchmark.h.

References resChargedHadEnergyMax_.

54 {return resChargedHadEnergyMax_;};

PFJetBenchmark::resChargedHadEnergyMax_

double resChargedHadEnergyMax_

Definition: PFJetBenchmark.h:223

double PFJetBenchmark::resNeutralEmEnergyMax ( ) const

inline

Definition at line 56 of file PFJetBenchmark.h.

References resNeutralEmEnergyMax_, and write().

56 {return resNeutralEmEnergyMax_;};

PFJetBenchmark::resNeutralEmEnergyMax_

double resNeutralEmEnergyMax_

Definition: PFJetBenchmark.h:225

double PFJetBenchmark::resNeutralHadEnergyMax ( ) const

inline

Definition at line 55 of file PFJetBenchmark.h.

References resNeutralHadEnergyMax_.

55 {return resNeutralHadEnergyMax_;};

PFJetBenchmark::resNeutralHadEnergyMax_

double resNeutralHadEnergyMax_

Definition: PFJetBenchmark.h:224

double PFJetBenchmark::resPtMax ( ) const

inline

Definition at line 53 of file PFJetBenchmark.h.

References resPtMax_.

53 {return resPtMax_;};

PFJetBenchmark::resPtMax_

double resPtMax_

Definition: PFJetBenchmark.h:222

void PFJetBenchmark::setup	(	std::string	Filename,
		bool	debug,
		bool	plotAgainstReco = `false`,
		bool	onlyTwoJets = `true`,
		double	deltaRMax = `0.1`,
		std::string	benchmarkLabel_ = `"ParticleFlow"`,
		double	recPt = `-1`,
		double	maxEta = `-1`,
		DQMStore *	dbe_store = `0`
	)

Definition at line 65 of file PFJetBenchmark.cc.

References BOOK1D, BOOK2D, gather_cfg::cout, dbe_, DBOOK1D, DBOOK2D, debug, debug_, deltaRMax, deltaRMax_, DSETAXES, ECAL, PVValHelper::eta, file_, maxEta, maxEta_cut, ECF_cff::Njets, onlyTwoJets, onlyTwoJets_, outputFile_, callgraph::path, phi, plotAgainstReco, plotAgainstReco_, PT, recPt, recPt_cut, and SETAXES.

Referenced by PFJetBenchmarkAnalyzer::PFJetBenchmarkAnalyzer().

                                      {
   debug_ = debug; 
   plotAgainstReco_ = plotAgainstReco;
   onlyTwoJets_ = onlyTwoJets;
   deltaRMax_ = deltaRMax;
   outputFile_=Filename;
   recPt_cut = recPt;
   maxEta_cut= maxEta;
   file_ = nullptr;
   dbe_ = dbe_store;
   // print parameters
   cout<< "PFJetBenchmark Setup parameters =============================================="<<endl;
   cout << "Filename to write histograms " << Filename<<endl;
   cout << "PFJetBenchmark debug " << debug_<< endl;
   cout << "plotAgainstReco " << plotAgainstReco_ << endl;
   cout << "onlyTwoJets " << onlyTwoJets_ << endl;
   cout << "deltaRMax " << deltaRMax << endl;
   cout << "benchmarkLabel " << benchmarkLabel_ << endl;
   cout << "recPt_cut " << recPt_cut << endl;
   cout << "maxEta_cut " << maxEta_cut << endl;
   
   // Book histogram
 
   // Establish DQM Store
   string path = "PFTask/Benchmarks/"+ benchmarkLabel_ + "/";
   if (plotAgainstReco) path += "Reco"; else path += "Gen";
   if (dbe_) {
     dbe_->setCurrentFolder(path);
   }
   else {
     file_ = new TFile(outputFile_.c_str(), "recreate");
 //    TTree * tr = new TTree("PFTast");
 //    tr->Branch("Benchmarks/ParticleFlow")
     cout << "Info: DQM is not available to provide data storage service. Using TFile to save histograms. "<<endl;
   }
   // Jets inclusive  distributions  (Pt > 20 or specified recPt GeV)
   char cutString[35];
   sprintf(cutString,"Jet multiplicity P_{T}>%4.1f GeV", recPt_cut);
   BOOK1D(Njets,cutString,50, 0, 50);
 
   BOOK1D(jetsPt,"Jets P_{T} Distribution",100, 0, 500);
 
   sprintf(cutString,"Jets #eta Distribution |#eta|<%4.1f", maxEta_cut);
   BOOK1D(jetsEta,cutString,100, -5, 5);
     
   BOOK2D(RPtvsEta,"#DeltaP_{T}/P_{T} vs #eta",200, -5., 5., 200,-1,1); 
   BOOK2D(RNeutvsEta,"R_{Neutral} vs #eta",200, -5., 5., 200,-1,1); 
   BOOK2D(RNEUTvsEta,"R_{HCAL+ECAL} vs #eta",200, -5., 5., 200,-1,1); 
   BOOK2D(RNONLvsEta,"R_{HCAL+ECAL - Hcal Only} vs #eta",200, -5., 5., 200,-1,1); 
   BOOK2D(RHCALvsEta,"R_{HCAL} vs #eta",200, -5., 5., 200,-1,1); 
   BOOK2D(RHONLvsEta,"R_{HCAL only} vs #eta",200, -5., 5., 200,-1,1); 
   BOOK2D(RCHEvsEta,"R_{Charged} vs #eta",200, -5., 5., 200,-1,1); 
   BOOK2D(NCHvsEta,"N_{Charged} vs #eta",200, -5., 5., 200,0.,200.);
   BOOK2D(NCH0vsEta,"N_{Charged} vs #eta, iter 0",200, -5., 5., 200,0.,200.);
   BOOK2D(NCH1vsEta,"N_{Charged} vs #eta, iter 1",200, -5., 5., 200,0.,200.);
   BOOK2D(NCH2vsEta,"N_{Charged} vs #eta, iter 2",200, -5., 5., 200,0.,200.);
   BOOK2D(NCH3vsEta,"N_{Charged} vs #eta, iter 3",200, -5., 5., 200,0.,200.);
   BOOK2D(NCH4vsEta,"N_{Charged} vs #eta, iter 4",200, -5., 5., 200,0.,200.);
   BOOK2D(NCH5vsEta,"N_{Charged} vs #eta, iter 5",200, -5., 5., 200,0.,200.);
   BOOK2D(NCH6vsEta,"N_{Charged} vs #eta, iter 6",200, -5., 5., 200,0.,200.);
   // delta Pt or E quantities for Barrel
   DBOOK1D(RPt,#DeltaP_{T}/P_{T},80,-1,1);
   DBOOK1D(RCHE,#DeltaE/E (charged had),80,-2,2);
   DBOOK1D(RNHE,#DeltaE/E (neutral had),80,-2,2);
   DBOOK1D(RNEE,#DeltaE/E (neutral em),80,-2,2);
   DBOOK1D(Rneut,#DeltaE/E (neutral),80,-2,2);
   DBOOK1D(NCH, #N_{charged},200,0.,200.);
   DBOOK2D(RPtvsPt,#DeltaP_{T}/P_{T} vs P_{T},250, 0, 500, 200,-1,1);       //used to be 50 bin for each in x-direction
   DBOOK2D(RCHEvsPt,#DeltaE/E (charged had) vs P_{T},250, 0, 500, 120,-1,2);
   DBOOK2D(RNHEvsPt,#DeltaE/E (neutral had) vs P_{T},250, 0, 500, 120,-1,2);
   DBOOK2D(RNEEvsPt,#DeltaE/E (neutral em) vs P_{T},250, 0, 500, 120,-1,2);
   DBOOK2D(RneutvsPt,#DeltaE/E (neutral) vs P_{T},250, 0, 500, 120,-1,2);
   DBOOK2D(NCHvsPt,N_{charged} vs P_{T},250,0,500,200,0.,200.);
   DBOOK2D(NCH0vsPt, N_{charged} vs P_{T} iter 0,250,0,500,200,0.,200.);
   DBOOK2D(NCH1vsPt, N_{charged} vs P_{T} iter 1,250,0,500,200,0.,200.);
   DBOOK2D(NCH2vsPt, N_{charged} vs P_{T} iter 2,250,0,500,200,0.,200.);
   DBOOK2D(NCH3vsPt, N_{charged} vs P_{T} iter 3,250,0,500,200,0.,200.);
   DBOOK2D(NCH4vsPt, N_{charged} vs P_{T} iter 4,250,0,500,200,0.,200.);
   DBOOK2D(NCH5vsPt, N_{charged} vs P_{T} iter 5,250,0,500,200,0.,200.);
   DBOOK2D(NCH6vsPt, N_{charged} vs P_{T} iter 6,250,0,500,200,0.,200.);
 
   
 
   DBOOK2D(RNEUTvsP,#DeltaE/E (ECAL+HCAL) vs P,250, 0, 1000, 150,-1.5,1.5);
   DBOOK2D(RNONLvsP,#DeltaE/E (ECAL+HCAL-only) vs P,250, 0, 1000, 150,-1.5,1.5);
   DBOOK2D(RHCALvsP,#DeltaE/E (HCAL) vs P,250, 0, 1000, 150,-1.5,1.5);
   DBOOK2D(RHONLvsP,#DeltaE/E (HCAL only) vs P,250, 0, 1000, 150,-1.5,1.5);
   DBOOK1D(RPt20_40,#DeltaP_{T}/P_{T},80,-1,1);
   DBOOK1D(RPt40_60,#DeltaP_{T}/P_{T},80,-1,1);
   DBOOK1D(RPt60_80,#DeltaP_{T}/P_{T},80,-1,1);
   DBOOK1D(RPt80_100,#DeltaP_{T}/P_{T},80,-1,1);
   DBOOK1D(RPt100_150,#DeltaP_{T}/P_{T},80,-1,1);
   DBOOK1D(RPt150_200,#DeltaP_{T}/P_{T},80,-1,1);
   DBOOK1D(RPt200_250,#DeltaP_{T}/P_{T},80,-1,1);
   DBOOK1D(RPt250_300,#DeltaP_{T}/P_{T},80,-1,1);
   DBOOK1D(RPt300_400,#DeltaP_{T}/P_{T},160,-1,1);
   DBOOK1D(RPt400_500,#DeltaP_{T}/P_{T},160,-1,1);
   DBOOK1D(RPt500_750,#DeltaP_{T}/P_{T},160,-1,1);
   DBOOK1D(RPt750_1250,#DeltaP_{T}/P_{T},160,-1,1);
   DBOOK1D(RPt1250_2000,#DeltaP_{T}/P_{T},160,-1,1);
   DBOOK1D(RPt2000_5000,#DeltaP_{T}/P_{T},160,-1,1);
 
   DBOOK2D(DEtavsPt,#Delta#eta vs P_{T},1000,0,2000,500,-0.5,0.5);
   DBOOK2D(DPhivsPt,#Delta#phi vs P_{T},1000,0,2000,500,-0.5,0.5);
   BOOK2D(DEtavsEta,"#Delta#eta vs P_{T}",1000,-5.,+5.,500,-0.5,0.5);
   BOOK2D(DPhivsEta,"#Delta#phi vs P_{T}",1000,-5.,+5.,500,-0.5,0.5);
     
  // Set Axis Titles
  
  // Jets inclusive  distributions  (Pt > 20 GeV)
   SETAXES(Njets,"","Multiplicity");
   SETAXES(jetsPt, PT, "Number of Events");
   SETAXES(jetsEta, "#eta", "Number of Events");
   SETAXES(RNeutvsEta, "#eta", "#DeltaE/E (Neutral)");
   SETAXES(RNEUTvsEta, "#eta", "#DeltaE/E (ECAL+HCAL)");
   SETAXES(RNONLvsEta, "#eta", "#DeltaE/E (ECAL+HCAL-only)");
   SETAXES(RHCALvsEta, "#eta", "#DeltaE/E (HCAL)");
   SETAXES(RHONLvsEta, "#eta", "#DeltaE/E (HCAL Only)");
   SETAXES(RCHEvsEta, "#eta", "#DeltaE/E (Charged)");
   SETAXES(RPtvsEta, "#eta", "#DeltaP_{T}/P_{T}");
   SETAXES(DEtavsEta, "#eta", "#Delta#eta");
   SETAXES(DPhivsEta,"#eta", "#Delta#phi");
   // delta Pt or E quantities for Barrel and Endcap
   DSETAXES(RPt, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt20_40, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt40_60, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt60_80, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt80_100, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt100_150, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt150_200, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt200_250, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt250_300, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt300_400, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt400_500, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt500_750, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt750_1250, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt1250_2000, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RPt2000_5000, "#DeltaP_{T}/P_{T}", "Events");
   DSETAXES(RCHE, "#DeltaE/E(charged had)", "Events");
   DSETAXES(RNHE, "#DeltaE/E(neutral had)", "Events");
   DSETAXES(RNEE, "#DeltaE/E(neutral em)", "Events");
   DSETAXES(Rneut, "#DeltaE/E(neutral)", "Events");
   DSETAXES(RPtvsPt, PT, "#DeltaP_{T}/P_{T}");
   DSETAXES(RCHEvsPt, PT, "#DeltaE/E(charged had)");
   DSETAXES(RNHEvsPt, PT, "#DeltaE/E(neutral had)");
   DSETAXES(RNEEvsPt, PT, "#DeltaE/E(neutral em)");
   DSETAXES(RneutvsPt, PT, "#DeltaE/E(neutral)");
   DSETAXES(RHCALvsP, P, "#DeltaE/E(HCAL)");
   DSETAXES(RHONLvsP, P, "#DeltaE/E(HCAL-only)");
   DSETAXES(RNEUTvsP, P, "#DeltaE/E(ECAL+HCAL)");
   DSETAXES(RNONLvsP, P, "#DeltaE/E(ECAL+HCAL-only)");
   DSETAXES(DEtavsPt, PT, "#Delta#eta");
   DSETAXES(DPhivsPt, PT, "#Delta#phi");
 
 }

void PFJetBenchmark::write ( )

Definition at line 48 of file PFJetBenchmark.cc.

References gather_cfg::cout, dbe_, file_, and outputFile_.

Referenced by PFJetBenchmarkAnalyzer::endJob(), and resNeutralEmEnergyMax().

                            {
    // Store the DAQ Histograms 
   if (!outputFile_.empty()) {
     if (dbe_)
           dbe_->save(outputFile_);
     // use bare Root if no DQM (FWLite applications)
     else if (file_) {
        file_->Write(outputFile_.c_str());
        cout << "Benchmark output written to file " << outputFile_.c_str() << endl;
        file_->Close();
        }
   }
   else 
     cout << "No output file specified ("<<outputFile_<<"). Results will not be saved!" << endl;
     
 } 

Member Data Documentation

PFBenchmarkAlgo* PFJetBenchmark::algo_

protected

Definition at line 217 of file PFJetBenchmark.h.

Referenced by process().

DQMStore* PFJetBenchmark::dbe_

protected

Definition at line 229 of file PFJetBenchmark.h.

Referenced by setup(), and write().

bool PFJetBenchmark::debug_

protected

Definition at line 218 of file PFJetBenchmark.h.

Referenced by process(), and setup().

double PFJetBenchmark::deltaRMax_

protected

Definition at line 221 of file PFJetBenchmark.h.

Referenced by process(), and setup().

unsigned int PFJetBenchmark::entry_

protected

Definition at line 228 of file PFJetBenchmark.h.

Referenced by process().

TFile* PFJetBenchmark::file_

private

Definition at line 62 of file PFJetBenchmark.h.

Referenced by setup(), write(), and ~PFJetBenchmark().

TH2F* PFJetBenchmark::hBDEtavsPt

private

Definition at line 117 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBDPhivsPt

private

Definition at line 118 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBNCH

private

Definition at line 120 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBNCH0vsPt

private

Definition at line 121 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBNCH1vsPt

private

Definition at line 122 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBNCH2vsPt

private

Definition at line 123 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBNCH3vsPt

private

Definition at line 124 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBNCH4vsPt

private

Definition at line 125 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBNCH5vsPt

private

Definition at line 126 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBNCH6vsPt

private

Definition at line 127 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBNCH7vsPt

private

Definition at line 128 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBNCHvsPt

private

Definition at line 119 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRCHE

private

Definition at line 104 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBRCHEvsPt

private

Definition at line 109 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBRHCALvsP

private

Definition at line 115 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBRHONLvsP

private

Definition at line 116 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRNEE

private

Definition at line 106 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBRNEEvsPt

private

Definition at line 111 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRneut

private

Definition at line 107 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBRNEUTvsP

private

Definition at line 113 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBRneutvsPt

private

Definition at line 112 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRNHE

private

Definition at line 105 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBRNHEvsPt

private

Definition at line 110 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBRNONLvsP

private

Definition at line 114 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt

private

Definition at line 89 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt100_150

private

Definition at line 94 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt1250_2000

private

Definition at line 102 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt150_200

private

Definition at line 95 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt2000_5000

private

Definition at line 103 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt200_250

private

Definition at line 96 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt20_40

private

Definition at line 90 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt250_300

private

Definition at line 97 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt300_400

private

Definition at line 98 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt400_500

private

Definition at line 99 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt40_60

private

Definition at line 91 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt500_750

private

Definition at line 100 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt60_80

private

Definition at line 92 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt750_1250

private

Definition at line 101 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hBRPt80_100

private

Definition at line 93 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hBRPtvsPt

private

Definition at line 108 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hDEtavsEta

private

Definition at line 70 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hDPhivsEta

private

Definition at line 71 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hEDEtavsPt

private

Definition at line 159 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hEDPhivsPt

private

Definition at line 160 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hENCH

private

Definition at line 162 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hENCH0vsPt

private

Definition at line 163 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hENCH1vsPt

private

Definition at line 164 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hENCH2vsPt

private

Definition at line 165 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hENCH3vsPt

private

Definition at line 166 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hENCH4vsPt

private

Definition at line 167 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hENCH5vsPt

private

Definition at line 168 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hENCH6vsPt

private

Definition at line 169 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hENCH7vsPt

private

Definition at line 170 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hENCHvsPt

private

Definition at line 161 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERCHE

private

Definition at line 146 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hERCHEvsPt

private

Definition at line 151 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hERHCALvsP

private

Definition at line 157 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hERHONLvsP

private

Definition at line 158 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERNEE

private

Definition at line 148 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hERNEEvsPt

private

Definition at line 153 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERneut

private

Definition at line 149 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hERNEUTvsP

private

Definition at line 155 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hERneutvsPt

private

Definition at line 154 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERNHE

private

Definition at line 147 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hERNHEvsPt

private

Definition at line 152 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hERNONLvsP

private

Definition at line 156 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt

private

Definition at line 131 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt100_150

private

Definition at line 136 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt1250_2000

private

Definition at line 144 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt150_200

private

Definition at line 137 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt2000_5000

private

Definition at line 145 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt200_250

private

Definition at line 138 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt20_40

private

Definition at line 132 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt250_300

private

Definition at line 139 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt300_400

private

Definition at line 140 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt400_500

private

Definition at line 141 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt40_60

private

Definition at line 133 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt500_750

private

Definition at line 142 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt60_80

private

Definition at line 134 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt750_1250

private

Definition at line 143 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hERPt80_100

private

Definition at line 135 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hERPtvsPt

private

Definition at line 150 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hFDEtavsPt

private

Definition at line 201 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hFDPhivsPt

private

Definition at line 202 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFNCH

private

Definition at line 204 of file PFJetBenchmark.h.

TH2F* PFJetBenchmark::hFNCH0vsPt

private

Definition at line 205 of file PFJetBenchmark.h.

TH2F* PFJetBenchmark::hFNCH1vsPt

private

Definition at line 206 of file PFJetBenchmark.h.

TH2F* PFJetBenchmark::hFNCH2vsPt

private

Definition at line 207 of file PFJetBenchmark.h.

TH2F* PFJetBenchmark::hFNCH3vsPt

private

Definition at line 208 of file PFJetBenchmark.h.

TH2F* PFJetBenchmark::hFNCH4vsPt

private

Definition at line 209 of file PFJetBenchmark.h.

TH2F* PFJetBenchmark::hFNCH5vsPt

private

Definition at line 210 of file PFJetBenchmark.h.

TH2F* PFJetBenchmark::hFNCH6vsPt

private

Definition at line 211 of file PFJetBenchmark.h.

TH2F* PFJetBenchmark::hFNCH7vsPt

private

Definition at line 212 of file PFJetBenchmark.h.

TH2F* PFJetBenchmark::hFNCHvsPt

private

Definition at line 203 of file PFJetBenchmark.h.

TH1F* PFJetBenchmark::hFRCHE

private

Definition at line 188 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hFRCHEvsPt

private

Definition at line 193 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hFRHCALvsP

private

Definition at line 199 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hFRHONLvsP

private

Definition at line 200 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRNEE

private

Definition at line 190 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hFRNEEvsPt

private

Definition at line 195 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRneut

private

Definition at line 191 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hFRNEUTvsP

private

Definition at line 197 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hFRneutvsPt

private

Definition at line 196 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRNHE

private

Definition at line 189 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hFRNHEvsPt

private

Definition at line 194 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hFRNONLvsP

private

Definition at line 198 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt

private

Definition at line 173 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt100_150

private

Definition at line 178 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt1250_2000

private

Definition at line 186 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt150_200

private

Definition at line 179 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt2000_5000

private

Definition at line 187 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt200_250

private

Definition at line 180 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt20_40

private

Definition at line 174 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt250_300

private

Definition at line 181 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt300_400

private

Definition at line 182 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt400_500

private

Definition at line 183 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt40_60

private

Definition at line 175 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt500_750

private

Definition at line 184 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt60_80

private

Definition at line 176 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt750_1250

private

Definition at line 185 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hFRPt80_100

private

Definition at line 177 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hFRPtvsPt

private

Definition at line 192 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hjetsEta

private

Definition at line 68 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hjetsPt

private

Definition at line 67 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hNCH0vsEta

private

Definition at line 79 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hNCH1vsEta

private

Definition at line 80 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hNCH2vsEta

private

Definition at line 81 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hNCH3vsEta

private

Definition at line 82 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hNCH4vsEta

private

Definition at line 83 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hNCH5vsEta

private

Definition at line 84 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hNCH6vsEta

private

Definition at line 85 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hNCH7vsEta

private

Definition at line 86 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hNCHvsEta

private

Definition at line 78 of file PFJetBenchmark.h.

Referenced by process().

TH1F* PFJetBenchmark::hNjets

private

Definition at line 66 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hRCHEvsEta

private

Definition at line 77 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hRHCALvsEta

private

Definition at line 75 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hRHONLvsEta

private

Definition at line 76 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hRNeutvsEta

private

Definition at line 72 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hRNEUTvsEta

private

Definition at line 73 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hRNONLvsEta

private

Definition at line 74 of file PFJetBenchmark.h.

Referenced by process().

TH2F* PFJetBenchmark::hRPtvsEta

private

Definition at line 69 of file PFJetBenchmark.h.

Referenced by process().

double PFJetBenchmark::maxEta_cut

protected

Definition at line 227 of file PFJetBenchmark.h.

Referenced by process(), and setup().

bool PFJetBenchmark::onlyTwoJets_

protected

Definition at line 220 of file PFJetBenchmark.h.

Referenced by process(), and setup().

std::string PFJetBenchmark::outputFile_

private

Definition at line 214 of file PFJetBenchmark.h.

Referenced by setup(), and write().

bool PFJetBenchmark::plotAgainstReco_

protected

Definition at line 219 of file PFJetBenchmark.h.

Referenced by process(), and setup().

double PFJetBenchmark::recPt_cut

protected

Definition at line 226 of file PFJetBenchmark.h.

Referenced by process(), and setup().

double PFJetBenchmark::resChargedHadEnergyMax_

protected

Definition at line 223 of file PFJetBenchmark.h.

Referenced by process(), and resChargedHadEnergyMax().

double PFJetBenchmark::resNeutralEmEnergyMax_

protected

Definition at line 225 of file PFJetBenchmark.h.

Referenced by process(), and resNeutralEmEnergyMax().

double PFJetBenchmark::resNeutralHadEnergyMax_

protected

Definition at line 224 of file PFJetBenchmark.h.

Referenced by process(), and resNeutralHadEnergyMax().

double PFJetBenchmark::resPtMax_

protected

Definition at line 222 of file PFJetBenchmark.h.

Referenced by process(), and resPtMax().

Public Member Functions

Protected Attributes

Private Attributes

Detailed Description

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation