kiesel/TreeWriter/treeWriter.cc

#include "treeWriter.h"

using namespace std;

TreeWriter::TreeWriter( std::string inputName, std::string outputName, int loggingVerbosity_ ) {
        // read the input file
        inputTree = new TChain("susyTree");
        if (loggingVerbosity_ > 0)
                std::cout << "Add files to chain" << std::endl;
        inputTree->Add( inputName.c_str() );
        Init( outputName, loggingVerbosity_ );
}

TreeWriter::TreeWriter( TChain* inputTree_, std::string outputName, int loggingVerbosity_ ) {
        inputTree = inputTree_;
        Init( outputName, loggingVerbosity_ );
}

void TreeWriter::Init( std::string outputName, int loggingVerbosity_ ) {

        if (loggingVerbosity_ > 0)
                std::cout << "Set Branch Address of susy::Event" << std::endl;
        event = new susy::Event;
        inputTree->SetBranchAddress("susyEvent", &event);

        // Here the number of proceeded events will be stored. For plotting, simply use L*sigma/eventNumber
        eventNumbers = new TH1F("eventNumbers", "Histogram containing number of generated events", 1, 0, 1);
        eventNumbers->GetXaxis()->SetBinLabel(1,"Number of generated events");

        // open the output file
        if (loggingVerbosity_>0)
                std::cout << "Open file " << outputName << " for writing." << std::endl;
        outFile = new TFile( outputName.c_str(), "recreate" );
        tree = new TTree("susyTree","Tree for single photon analysis");

        // set default parameter
        processNEvents = -1;
        reportEvery = 1000;
        loggingVerbosity = loggingVerbosity_;
        skim = true;
        pileupHisto = 0;
}

void TreeWriter::PileUpWeightFile( string pileupFileName ) {
        TFile *puFile = new TFile( pileupFileName.c_str() );
        pileupHisto = (TH1F*) puFile->Get("pileup");
}

TreeWriter::~TreeWriter() {
        if (pileupHisto != 0 )
                delete pileupHisto;
        inputTree->GetCurrentFile()->Close();
        delete inputTree;
        delete event;
        delete outFile;
        delete tree;
}

template<class Type>
std::vector<Type>* getVectorFromMap( map<TString, vector<Type> > myMap, TString search ){
        // if nothing is found, return a empty vector (which has to be deleted never the less)
        std::vector<Type>* vec;
        typename map<TString, vector<Type> >::iterator mapIt = myMap.find( search );
        if( mapIt == myMap.end() ) {
                cout << "ERROR: Collection \"" << search << "\" not found!" << endl;
                vec = new std::vector<Type>;
        } else
                vec = &mapIt->second;
        cout << vec->size() << endl;
        return vec;
}

// useful functions
float deltaR( const TLorentzVector& v1, const TLorentzVector& v2 ) {
        // deltaR  = sqrt ( deltaEta^2 + deltaPhi^2 )
        return sqrt(pow(v1.Eta() - v2.Eta(), 2) + pow(v1.Phi() - v2.Phi(), 2) );
}

float effectiveAreaElectron( float eta ) {
        // needed by calculating the isolation for electrons
        // see https://twiki.cern.ch/twiki/bin/view/CMS/EgammaEARhoCorrection
        // only for Delta R = 0.3 on 2012 Data
        eta = fabs( eta );
        float ea;
        if( eta < 1.0 ) ea = 0.13;
        else if( eta < 1.479 ) ea = 0.14;
        else if( eta < 2.0 ) ea = 0.07;
        else if( eta < 2.2 ) ea = 0.09;
        else if( eta < 2.3 ) ea = 0.11;
        else if( eta < 2.4 ) ea = 0.11;
        else ea = 0.14;
        return ea;
}

// correct iso, see https://twiki.cern.ch/twiki/bin/view/CMS/CutBasedPhotonID2012
float chargedHadronIso_corrected(const susy::Photon& gamma, float rho) {
        float eta = fabs(gamma.caloPosition.Eta());
        float ea;

        if(eta < 1.0) ea = 0.012;
        else if(eta < 1.479) ea = 0.010;
        else if(eta < 2.0) ea = 0.014;
        else if(eta < 2.2) ea = 0.012;
        else if(eta < 2.3) ea = 0.016;
        else if(eta < 2.4) ea = 0.020;
        else ea = 0.012;

        float iso = gamma.chargedHadronIso;
        iso = max(iso - rho*ea, (float)0.);

        return iso;
}

float neutralHadronIso_corrected(const susy::Photon& gamma, float rho) {
        float eta = fabs(gamma.caloPosition.Eta());
        float ea;

        if(eta < 1.0) ea = 0.030;
        else if(eta < 1.479) ea = 0.057;
        else if(eta < 2.0) ea = 0.039;
        else if(eta < 2.2) ea = 0.015;
        else if(eta < 2.3) ea = 0.024;
        else if(eta < 2.4) ea = 0.039;
        else ea = 0.072;

        float iso = gamma.neutralHadronIso;
        iso = max(iso - rho*ea, (float)0.);

        return iso;
}

float photonIso_corrected(const susy::Photon& gamma, float rho) {
        float eta = fabs(gamma.caloPosition.Eta());
        float ea;

        if(eta < 1.0) ea = 0.148;
        else if(eta < 1.479) ea = 0.130;
        else if(eta < 2.0) ea = 0.112;
        else if(eta < 2.2) ea = 0.216;
        else if(eta < 2.3) ea = 0.262;
        else if(eta < 2.4) ea = 0.260;
        else ea = 0.266;

        float iso = gamma.photonIso;
        iso = max(iso - rho*ea, (float)0.);

        return iso;
}

float d0correction( const susy::Electron& electron, const susy::Event& event ) {
        // copied from Brian Francis
        TVector3 beamspot = event.vertices[0].position;
        susy::Track track = event.tracks[electron.gsfTrackIndex];
        float d0 = track.d0() - beamspot.X()*sin(track.phi()) + beamspot.Y()*cos(track.phi());
        return d0;
}

float dZcorrection( const susy::Electron& electron, const susy::Event& event ) {
        // copied from Brian Francis
        TVector3 beamspot = event.vertices[0].position;
        susy::Track track = event.tracks[electron.gsfTrackIndex];

        if(track.momentum.Pt() == 0.) return 1.e6;
        float dz = (track.vertex.Z() - beamspot.Z()) - ((track.vertex.X() - beamspot.X())*track.momentum.Px() + (track.vertex.Y() - beamspot.Y())*track.momentum.Py()) / track.momentum.Pt() * (track.momentum.Pz() / track.momentum.Pt());
        return dz;
}

float getPtFromMatchedJet( const susy::Photon& myPhoton, const susy::PFJetCollection& jetColl, int loggingVerbosity = 0 ) {
        /**
         * \brief Takes jet p_T as photon p_T
         *
         * At first all jets with DeltaR < 0.3 (isolation cone) are searched.
         * If several jets are found, take the one with the minimal pt difference
         * compared to the photon. If no such jets are found, keep the photon_pt
         * TODO: remove photon matched jet from jet-selection?
         */
        std::vector<susy::PFJet> nearJets;
        nearJets.clear();

        for(std::vector<susy::PFJet>::const_iterator it = jetColl.begin();
                        it != jetColl.end(); ++it) {
                float scale = 1.;
                std::map<TString,Float_t>::const_iterator s_it = it->jecScaleFactors.find("L2L3");
                if (s_it == it->jecScaleFactors.end()) {
                        std::cout << "JEC is not available for this jet!!!" << std::endl;
                        continue;
                } else {
                        scale = s_it->second;
                }
                TLorentzVector corrP4 = scale * it->momentum;
                float deltaR_ = deltaR(myPhoton.momentum, corrP4 );
                if (deltaR_ > 0.3) continue;
                if( loggingVerbosity > 2 )
                        std::cout << " pT_jet / pT_gamma = " << it->momentum.Et() / myPhoton.momentum.Et() << std::endl;
                nearJets.push_back( *it );
        }// for jet

        if ( nearJets.size() == 0 ) {
                if( loggingVerbosity > 1 )
                        std::cout << "No jet with deltaR < .3 found, do not change photon_pt" << std::endl;
                return myPhoton.momentum.Et();
        }

        float pt = 0;
        float minPtDifferenz = 1E20; // should be very high
        for( std::vector<susy::PFJet>::iterator it = nearJets.begin(), jetEnd = nearJets.end();
                        it != jetEnd; ++it ) {
                float ptDiff = fabs(myPhoton.momentum.Et() - it->momentum.Et());
                if (  ptDiff < minPtDifferenz ) {
                        minPtDifferenz = ptDiff;
                        pt = it->momentum.Et();
                }
        }

        // testing
        if( nearJets.size() > 1 && loggingVerbosity > 0 )
                std::cout << "There are several jets matching to this photon. "
                                        << "Please check if jet-matching is correct." << std::endl;
        return pt;
}


void TreeWriter::Loop() {
        /**
         * \brief Loops over input chain and fills tree
         *
         * This is the major function of treeWriter, which initialize the output, loops
         * over all events and fill the tree. In the end, the tree is saved to the
         * output File
         */

        // here the event loop is implemented and the tree is filled
        if (inputTree == 0) return;

        // get number of events to be proceeded
        Long64_t nentries = inputTree->GetEntries();
        // store them in histo
        eventNumbers->Fill( "Number of generated events", nentries );
        if(processNEvents <= 0 || processNEvents > nentries) processNEvents = nentries;

        if( loggingVerbosity > 0 )
                std::cout << "Processing " << processNEvents << " ouf of "
                        << nentries << " events. " << std::endl;

        tree->Branch("photon", &photon);
        tree->Branch("jet", &jet);
        tree->Branch("electron", &electron);
        tree->Branch("muon", &muon);
        tree->Branch("met", &met, "met/F");
        tree->Branch("metPhi", &met_phi, "metPhi/F");
        tree->Branch("type1met", &type1met, "type1met/F");
        tree->Branch("type1metPhi", &type1met_phi, "type1metPhi/F");
        tree->Branch("ht", &ht, "ht/F");
        tree->Branch("nVertex", &nVertex, "nVertex/I");
        tree->Branch("pu_weight", &pu_weight, "pu_weight/F");


        for (unsigned long jentry=0; jentry < processNEvents; ++jentry) {
                if ( loggingVerbosity>1 || jentry%reportEvery==0 )
                        std::cout << jentry << " / " << processNEvents << std :: endl;
                inputTree->LoadTree( jentry );
                inputTree->GetEntry( jentry );

                photon.clear();
                jet.clear();
                electron.clear();
                muon.clear();
                ht = 0;

                // weights
                if (pileupHisto == 0) {
                        pu_weight = 1.;
                } else {
                        float trueNumInteractions = -1;
                        for( susy::PUSummaryInfoCollection::const_iterator iBX = event->pu.begin();
                                        iBX != event->pu.end() && trueNumInteractions < 0; ++iBX) {
                                if (iBX->BX == 0)
                                        trueNumInteractions = iBX->trueNumInteractions;
                        }
                        pu_weight = pileupHisto->GetBinContent( pileupHisto->FindBin( trueNumInteractions ) );
                }

                // get ak5 jets
                std::vector<susy::PFJet> jetVector = event->pfJets["ak5"];

                // photons
                std::vector<susy::Photon> photonVector = event->photons["photons"];

                for(std::vector<susy::Photon>::iterator it = photonVector.begin();
                                it != photonVector.end(); ++it ) {
                        if( !(it->isEB() || it->isEE()) && skim )
                                continue;
                        tree::Photon thisphoton;
                        thisphoton.pt = getPtFromMatchedJet( *it, jetVector, loggingVerbosity );

                        thisphoton.chargedIso = chargedHadronIso_corrected(*it, event->rho25);
                        thisphoton.neutralIso = neutralHadronIso_corrected(*it, event->rho25);
                        thisphoton.photonIso = photonIso_corrected(*it, event->rho25);

                        bool loose_photon_barrel = thisphoton.pt>20
                                && it->isEB()
                                && it->passelectronveto
                                && it->hadTowOverEm<0.05
                                && it->sigmaIetaIeta<0.012
                                && thisphoton.chargedIso<2.6
                                && thisphoton.neutralIso<3.5+0.04*thisphoton.pt
                                && thisphoton.photonIso<1.3+0.005*thisphoton.pt;
                        bool loose_photon_endcap = thisphoton.pt > 20
                                && it->isEE()
                                && it->passelectronveto
                                && it->hadTowOverEm<0.05
                                && it->sigmaIetaIeta<0.034
                                && thisphoton.chargedIso<2.3
                                && thisphoton.neutralIso<2.9+0.04*thisphoton.pt;
                        if(!(loose_photon_endcap || loose_photon_barrel || thisphoton.pt > 75 ) && skim )
                                continue;
                        thisphoton.eta = it->momentum.Eta();
                        thisphoton.phi = it->momentum.Phi();
                        thisphoton.r9 = it->r9;
                        thisphoton.sigmaIetaIeta = it->sigmaIetaIeta;
                        thisphoton.hadTowOverEm = it->hadTowOverEm;
                        thisphoton.pixelseed = it->nPixelSeeds;
                        thisphoton.conversionSafeVeto = it->passelectronveto;
                        photon.push_back( thisphoton );
                        if( loggingVerbosity > 2 )
                                std::cout << " p_T, gamma = " << thisphoton.pt << std::endl;
                }

                if( photon.size() == 0 && skim )
                        continue;
                std::sort( photon.begin(), photon.end(), tree::EtGreater);
                if( loggingVerbosity > 1 )
                        std::cout << "Found " << photon.size() << " photons" << std::endl;

                // jets


                for(std::vector<susy::PFJet>::iterator it = jetVector.begin();
                                it != jetVector.end(); ++it) {
                        tree::Jet thisjet;

                        // scale with JEC
                        float scale = 1.;
                        if(it->jecScaleFactors.count("L2L3") == 0)
                                std::cout << "ERROR: JEC is not available for this jet" << std::endl;
                        else
                                scale = it->jecScaleFactors.find("L2L3")->second;
                        TLorentzVector corrP4 = scale * it->momentum;

                        // Calculate HT.
                        // The definiton differs from the saved jet, since trigger is described better
                        if( std::abs( corrP4.Eta() ) < 3 && corrP4.Pt > 40 )
                                ht += thisjet.pt;

                        if(std::abs(corrP4.Eta()) > 2.6 && skim ) continue;
                        if(corrP4.Pt() < 30 && skim ) continue;
                        thisjet.pt = corrP4.Pt();
                        thisjet.eta = corrP4.Eta();
                        thisjet.phi = corrP4.Phi();
                        thisjet.bCSV = it->bTagDiscriminators[susy::kCSV];
                        // jet composition
                        thisjet.chargedHadronEnergy = it->chargedHadronEnergy;
                        thisjet.neutralHadronEnergy = it->neutralHadronEnergy;
                        thisjet.photonEnergy = it->photonEnergy;
                        thisjet.electronEnergy = it->electronEnergy;
                        thisjet.muonEnergy = it->muonEnergy;
                        thisjet.HFHadronEnergy = it->HFHadronEnergy;
                        thisjet.HFEMEnergy = it->HFEMEnergy;
                        thisjet.chargedEmEnergy = it->chargedEmEnergy;
                        thisjet.chargedMuEnergy = it->chargedMuEnergy;
                        thisjet.neutralEmEnergy = it->neutralEmEnergy;

                        if( loggingVerbosity > 2 )
                                std::cout << " p_T, jet = " << thisjet.pt << std::endl;

                        jet.push_back( thisjet );
                }// for jet
                if( jet.size() < 2 && skim )
                        continue;
                std::sort( jet.begin(), jet.end(), tree::EtGreater);
                if( loggingVerbosity > 1 )
                        std::cout << "Found " << jet.size() << " jets" << std::endl;


                // met
                std::map<TString, susy::MET>::iterator met_it = event->metMap.find("pfMet");
                susy::MET* metobj = &(met_it->second);
                met = metobj->met();
                met_phi = metobj->mEt.Phi();
                if( loggingVerbosity > 2 )
                        std::cout << " met = " << met << std::endl;

                std::map<TString, susy::MET>::iterator type1met_it = event->metMap.find("pfType1CorrectedMet");
                susy::MET* type1metobj = &(type1met_it->second);
                type1met = type1metobj->met();
                type1met_phi = type1metobj->mEt.Phi();
                if( loggingVerbosity > 2 )
                        std::cout << " type1met = " << type1met << std::endl;

                // electrons
                std::vector<susy::Electron> eVector = event->electrons["gsfElectrons"];
                for(std::vector<susy::Electron>::iterator it = eVector.begin(); it < eVector.end(); ++it) {
                        tree::Particle thiselectron;
                        if( loggingVerbosity > 2 )
                                cout << " electron pt = " << it->momentum.Pt() << endl;
                        // for cuts see https://twiki.cern.ch/twiki/bin/viewauth/CMS/EgammaCutBasedIdentification
                        // use veto electrons
                        if( it->momentum.Pt() < 20  || it->momentum.Pt() > 1e6 )
                                continue; // spike rejection
                        float iso = ( it->chargedHadronIso + max(it->neutralHadronIso+it->photonIso
                                                                                                                - effectiveAreaElectron(it->momentum.Eta())*event->rho25, (float)0. )
                                                ) / it->momentum.Pt();
                        float d0 = d0correction( *it, *event );
                        float dZ = std::abs( dZcorrection( *it, *event ) );
                        if ( it->isEB() ){
                                if ( fabs(it->deltaEtaSuperClusterTrackAtVtx) > 0.007
                                                || fabs(it->deltaPhiSuperClusterTrackAtVtx) > 0.8
                                                || it->sigmaIetaIeta > 0.01
                                                || it->hcalOverEcalBc > 0.15
                                                || d0 > 0.04
                                                || dZ > 0.2
                                                || iso > 0.15 )
                                        continue;
                                }
                        else if( it->isEE() ) {
                                if ( fabs(it->deltaEtaSuperClusterTrackAtVtx) > 0.01
                                                || fabs(it->deltaPhiSuperClusterTrackAtVtx) > 0.7
                                                || it->sigmaIetaIeta > 0.03
                                                || d0 > 0.04
                                                || dZ > 0.2
                                                || iso > 0.15 )
                                        continue;
                                }
                        else // not in barrel nor in endcap
                                continue;

                        thiselectron.pt = it->momentum.Pt();
                        if( loggingVerbosity > 2 )
                                std::cout << " p_T, electron = " << it->momentum.Et() << std::endl;
                        thiselectron.eta = it->momentum.Eta();
                        thiselectron.phi = it->momentum.Phi();
                        electron.push_back( thiselectron );
                }
                if( loggingVerbosity > 1 )
                        std::cout << "Found " << electron.size() << " electrons" << std::endl;

                // muons
                tree::Particle thismuon;
                std::vector<susy::Muon> mVector = event->muons["muons"];
                for( std::vector<susy::Muon>::iterator it = mVector.begin(); it != mVector.end(); ++it) {
                        if( !( it->isPFMuon() && ( it->isGlobalMuon() || it->isTrackerMuon() ) ) )
                                continue; // see https://twiki.cern.ch/twiki/bin/view/CMSPublic/SWGuideMuonId#Loose_Muon
                        thismuon.pt = it->momentum.Et();
                        if( thismuon.pt < 20 )
                                continue;
                        thismuon.eta = it->momentum.Eta();
                        thismuon.phi = it->momentum.Phi();
                        muon.push_back( thismuon );
                }
                if( loggingVerbosity > 1 )
                        std::cout << "Found " << muon.size() << " muons" << std::endl;

                // vertices
                nVertex = event->vertices.size();

                if( ht < 450 && skim)
                        continue;


                tree->Fill();
        } // for jentry


        outFile->cd();
        eventNumbers->Write();
        tree->Write();
        outFile->Write();
        outFile->Close();
}

Revision:	1.19
Committed:	Tue Apr 23 12:35:48 2013 UTC (12 years ago) by kiesel
Content type:	text/plain
Branch:	MAIN
Changes since 1.18:	+1 -1 lines
Log Message:	Float_t -> float
#	Content
1	#include "treeWriter.h"
2
3	using namespace std;
4
5	TreeWriter::TreeWriter( std::string inputName, std::string outputName, int loggingVerbosity_ ) {
6	// read the input file
7	inputTree = new TChain("susyTree");
8	if (loggingVerbosity_ > 0)
9	std::cout << "Add files to chain" << std::endl;
10	inputTree->Add( inputName.c_str() );
11	Init( outputName, loggingVerbosity_ );
12	}
13
14	TreeWriter::TreeWriter( TChain* inputTree_, std::string outputName, int loggingVerbosity_ ) {
15	inputTree = inputTree_;
16	Init( outputName, loggingVerbosity_ );
17	}
18
19	void TreeWriter::Init( std::string outputName, int loggingVerbosity_ ) {
20
21	if (loggingVerbosity_ > 0)
22	std::cout << "Set Branch Address of susy::Event" << std::endl;
23	event = new susy::Event;
24	inputTree->SetBranchAddress("susyEvent", &event);
25
26	// Here the number of proceeded events will be stored. For plotting, simply use L*sigma/eventNumber
27	eventNumbers = new TH1F("eventNumbers", "Histogram containing number of generated events", 1, 0, 1);
28	eventNumbers->GetXaxis()->SetBinLabel(1,"Number of generated events");
29
30	// open the output file
31	if (loggingVerbosity_>0)
32	std::cout << "Open file " << outputName << " for writing." << std::endl;
33	outFile = new TFile( outputName.c_str(), "recreate" );
34	tree = new TTree("susyTree","Tree for single photon analysis");
35
36	// set default parameter
37	processNEvents = -1;
38	reportEvery = 1000;
39	loggingVerbosity = loggingVerbosity_;
40	skim = true;
41	pileupHisto = 0;
42	}
43
44	void TreeWriter::PileUpWeightFile( string pileupFileName ) {
45	TFile *puFile = new TFile( pileupFileName.c_str() );
46	pileupHisto = (TH1F*) puFile->Get("pileup");
47	}
48
49	TreeWriter::~TreeWriter() {
50	if (pileupHisto != 0 )
51	delete pileupHisto;
52	inputTree->GetCurrentFile()->Close();
53	delete inputTree;
54	delete event;
55	delete outFile;
56	delete tree;
57	}
58
59	template<class Type>
60	std::vector<Type>* getVectorFromMap( map<TString, vector<Type> > myMap, TString search ){
61	// if nothing is found, return a empty vector (which has to be deleted never the less)
62	std::vector<Type>* vec;
63	typename map<TString, vector<Type> >::iterator mapIt = myMap.find( search );
64	if( mapIt == myMap.end() ) {
65	cout << "ERROR: Collection \"" << search << "\" not found!" << endl;
66	vec = new std::vector<Type>;
67	} else
68	vec = &mapIt->second;
69	cout << vec->size() << endl;
70	return vec;
71	}
72
73	// useful functions
74	float deltaR( const TLorentzVector& v1, const TLorentzVector& v2 ) {
75	// deltaR = sqrt ( deltaEta^2 + deltaPhi^2 )
76	return sqrt(pow(v1.Eta() - v2.Eta(), 2) + pow(v1.Phi() - v2.Phi(), 2) );
77	}
78
79	float effectiveAreaElectron( float eta ) {
80	// needed by calculating the isolation for electrons
81	// see https://twiki.cern.ch/twiki/bin/view/CMS/EgammaEARhoCorrection
82	// only for Delta R = 0.3 on 2012 Data
83	eta = fabs( eta );
84	float ea;
85	if( eta < 1.0 ) ea = 0.13;
86	else if( eta < 1.479 ) ea = 0.14;
87	else if( eta < 2.0 ) ea = 0.07;
88	else if( eta < 2.2 ) ea = 0.09;
89	else if( eta < 2.3 ) ea = 0.11;
90	else if( eta < 2.4 ) ea = 0.11;
91	else ea = 0.14;
92	return ea;
93	}
94
95	// correct iso, see https://twiki.cern.ch/twiki/bin/view/CMS/CutBasedPhotonID2012
96	float chargedHadronIso_corrected(const susy::Photon& gamma, float rho) {
97	float eta = fabs(gamma.caloPosition.Eta());
98	float ea;
99
100	if(eta < 1.0) ea = 0.012;
101	else if(eta < 1.479) ea = 0.010;
102	else if(eta < 2.0) ea = 0.014;
103	else if(eta < 2.2) ea = 0.012;
104	else if(eta < 2.3) ea = 0.016;
105	else if(eta < 2.4) ea = 0.020;
106	else ea = 0.012;
107
108	float iso = gamma.chargedHadronIso;
109	iso = max(iso - rho*ea, (float)0.);
110
111	return iso;
112	}
113
114	float neutralHadronIso_corrected(const susy::Photon& gamma, float rho) {
115	float eta = fabs(gamma.caloPosition.Eta());
116	float ea;
117
118	if(eta < 1.0) ea = 0.030;
119	else if(eta < 1.479) ea = 0.057;
120	else if(eta < 2.0) ea = 0.039;
121	else if(eta < 2.2) ea = 0.015;
122	else if(eta < 2.3) ea = 0.024;
123	else if(eta < 2.4) ea = 0.039;
124	else ea = 0.072;
125
126	float iso = gamma.neutralHadronIso;
127	iso = max(iso - rho*ea, (float)0.);
128
129	return iso;
130	}
131
132	float photonIso_corrected(const susy::Photon& gamma, float rho) {
133	float eta = fabs(gamma.caloPosition.Eta());
134	float ea;
135
136	if(eta < 1.0) ea = 0.148;
137	else if(eta < 1.479) ea = 0.130;
138	else if(eta < 2.0) ea = 0.112;
139	else if(eta < 2.2) ea = 0.216;
140	else if(eta < 2.3) ea = 0.262;
141	else if(eta < 2.4) ea = 0.260;
142	else ea = 0.266;
143
144	float iso = gamma.photonIso;
145	iso = max(iso - rho*ea, (float)0.);
146
147	return iso;
148	}
149
150	float d0correction( const susy::Electron& electron, const susy::Event& event ) {
151	// copied from Brian Francis
152	TVector3 beamspot = event.vertices[0].position;
153	susy::Track track = event.tracks[electron.gsfTrackIndex];
154	float d0 = track.d0() - beamspot.X()sin(track.phi()) + beamspot.Y()cos(track.phi());
155	return d0;
156	}
157
158	float dZcorrection( const susy::Electron& electron, const susy::Event& event ) {
159	// copied from Brian Francis
160	TVector3 beamspot = event.vertices[0].position;
161	susy::Track track = event.tracks[electron.gsfTrackIndex];
162
163	if(track.momentum.Pt() == 0.) return 1.e6;
164	float dz = (track.vertex.Z() - beamspot.Z()) - ((track.vertex.X() - beamspot.X())track.momentum.Px() + (track.vertex.Y() - beamspot.Y())track.momentum.Py()) / track.momentum.Pt() * (track.momentum.Pz() / track.momentum.Pt());
165	return dz;
166	}
167
168	float getPtFromMatchedJet( const susy::Photon& myPhoton, const susy::PFJetCollection& jetColl, int loggingVerbosity = 0 ) {
169	/**
170	* \brief Takes jet p_T as photon p_T
171	*
172	* At first all jets with DeltaR < 0.3 (isolation cone) are searched.
173	* If several jets are found, take the one with the minimal pt difference
174	* compared to the photon. If no such jets are found, keep the photon_pt
175	* TODO: remove photon matched jet from jet-selection?
176	*/
177	std::vector<susy::PFJet> nearJets;
178	nearJets.clear();
179
180	for(std::vector<susy::PFJet>::const_iterator it = jetColl.begin();
181	it != jetColl.end(); ++it) {
182	float scale = 1.;
183	std::map<TString,Float_t>::const_iterator s_it = it->jecScaleFactors.find("L2L3");
184	if (s_it == it->jecScaleFactors.end()) {
185	std::cout << "JEC is not available for this jet!!!" << std::endl;
186	continue;
187	} else {
188	scale = s_it->second;
189	}
190	TLorentzVector corrP4 = scale * it->momentum;
191	float deltaR_ = deltaR(myPhoton.momentum, corrP4 );
192	if (deltaR_ > 0.3) continue;
193	if( loggingVerbosity > 2 )
194	std::cout << " pT_jet / pT_gamma = " << it->momentum.Et() / myPhoton.momentum.Et() << std::endl;
195	nearJets.push_back( *it );
196	}// for jet
197
198	if ( nearJets.size() == 0 ) {
199	if( loggingVerbosity > 1 )
200	std::cout << "No jet with deltaR < .3 found, do not change photon_pt" << std::endl;
201	return myPhoton.momentum.Et();
202	}
203
204	float pt = 0;
205	float minPtDifferenz = 1E20; // should be very high
206	for( std::vector<susy::PFJet>::iterator it = nearJets.begin(), jetEnd = nearJets.end();
207	it != jetEnd; ++it ) {
208	float ptDiff = fabs(myPhoton.momentum.Et() - it->momentum.Et());
209	if ( ptDiff < minPtDifferenz ) {
210	minPtDifferenz = ptDiff;
211	pt = it->momentum.Et();
212	}
213	}
214
215	// testing
216	if( nearJets.size() > 1 && loggingVerbosity > 0 )
217	std::cout << "There are several jets matching to this photon. "
218	<< "Please check if jet-matching is correct." << std::endl;
219	return pt;
220	}
221
222
223	void TreeWriter::Loop() {
224	/**
225	* \brief Loops over input chain and fills tree
226	*
227	* This is the major function of treeWriter, which initialize the output, loops
228	* over all events and fill the tree. In the end, the tree is saved to the
229	* output File
230	*/
231
232	// here the event loop is implemented and the tree is filled
233	if (inputTree == 0) return;
234
235	// get number of events to be proceeded
236	Long64_t nentries = inputTree->GetEntries();
237	// store them in histo
238	eventNumbers->Fill( "Number of generated events", nentries );
239	if(processNEvents <= 0 \|\| processNEvents > nentries) processNEvents = nentries;
240
241	if( loggingVerbosity > 0 )
242	std::cout << "Processing " << processNEvents << " ouf of "
243	<< nentries << " events. " << std::endl;
244
245	tree->Branch("photon", &photon);
246	tree->Branch("jet", &jet);
247	tree->Branch("electron", &electron);
248	tree->Branch("muon", &muon);
249	tree->Branch("met", &met, "met/F");
250	tree->Branch("metPhi", &met_phi, "metPhi/F");
251	tree->Branch("type1met", &type1met, "type1met/F");
252	tree->Branch("type1metPhi", &type1met_phi, "type1metPhi/F");
253	tree->Branch("ht", &ht, "ht/F");
254	tree->Branch("nVertex", &nVertex, "nVertex/I");
255	tree->Branch("pu_weight", &pu_weight, "pu_weight/F");
256
257
258	for (unsigned long jentry=0; jentry < processNEvents; ++jentry) {
259	if ( loggingVerbosity>1 \|\| jentry%reportEvery==0 )
260	std::cout << jentry << " / " << processNEvents << std :: endl;
261	inputTree->LoadTree( jentry );
262	inputTree->GetEntry( jentry );
263
264	photon.clear();
265	jet.clear();
266	electron.clear();
267	muon.clear();
268	ht = 0;
269
270	// weights
271	if (pileupHisto == 0) {
272	pu_weight = 1.;
273	} else {
274	float trueNumInteractions = -1;
275	for( susy::PUSummaryInfoCollection::const_iterator iBX = event->pu.begin();
276	iBX != event->pu.end() && trueNumInteractions < 0; ++iBX) {
277	if (iBX->BX == 0)
278	trueNumInteractions = iBX->trueNumInteractions;
279	}
280	pu_weight = pileupHisto->GetBinContent( pileupHisto->FindBin( trueNumInteractions ) );
281	}
282
283	// get ak5 jets
284	std::vector<susy::PFJet> jetVector = event->pfJets["ak5"];
285
286	// photons
287	std::vector<susy::Photon> photonVector = event->photons["photons"];
288
289	for(std::vector<susy::Photon>::iterator it = photonVector.begin();
290	it != photonVector.end(); ++it ) {
291	if( !(it->isEB() \|\| it->isEE()) && skim )
292	continue;
293	tree::Photon thisphoton;
294	thisphoton.pt = getPtFromMatchedJet( *it, jetVector, loggingVerbosity );
295
296	thisphoton.chargedIso = chargedHadronIso_corrected(*it, event->rho25);
297	thisphoton.neutralIso = neutralHadronIso_corrected(*it, event->rho25);
298	thisphoton.photonIso = photonIso_corrected(*it, event->rho25);
299
300	bool loose_photon_barrel = thisphoton.pt>20
301	&& it->isEB()
302	&& it->passelectronveto
303	&& it->hadTowOverEm<0.05
304	&& it->sigmaIetaIeta<0.012
305	&& thisphoton.chargedIso<2.6
306	&& thisphoton.neutralIso<3.5+0.04*thisphoton.pt
307	&& thisphoton.photonIso<1.3+0.005*thisphoton.pt;
308	bool loose_photon_endcap = thisphoton.pt > 20
309	&& it->isEE()
310	&& it->passelectronveto
311	&& it->hadTowOverEm<0.05
312	&& it->sigmaIetaIeta<0.034
313	&& thisphoton.chargedIso<2.3
314	&& thisphoton.neutralIso<2.9+0.04*thisphoton.pt;
315	if(!(loose_photon_endcap \|\| loose_photon_barrel \|\| thisphoton.pt > 75 ) && skim )
316	continue;
317	thisphoton.eta = it->momentum.Eta();
318	thisphoton.phi = it->momentum.Phi();
319	thisphoton.r9 = it->r9;
320	thisphoton.sigmaIetaIeta = it->sigmaIetaIeta;
321	thisphoton.hadTowOverEm = it->hadTowOverEm;
322	thisphoton.pixelseed = it->nPixelSeeds;
323	thisphoton.conversionSafeVeto = it->passelectronveto;
324	photon.push_back( thisphoton );
325	if( loggingVerbosity > 2 )
326	std::cout << " p_T, gamma = " << thisphoton.pt << std::endl;
327	}
328
329	if( photon.size() == 0 && skim )
330	continue;
331	std::sort( photon.begin(), photon.end(), tree::EtGreater);
332	if( loggingVerbosity > 1 )
333	std::cout << "Found " << photon.size() << " photons" << std::endl;
334
335	// jets
336
337
338	for(std::vector<susy::PFJet>::iterator it = jetVector.begin();
339	it != jetVector.end(); ++it) {
340	tree::Jet thisjet;
341
342	// scale with JEC
343	float scale = 1.;
344	if(it->jecScaleFactors.count("L2L3") == 0)
345	std::cout << "ERROR: JEC is not available for this jet" << std::endl;
346	else
347	scale = it->jecScaleFactors.find("L2L3")->second;
348	TLorentzVector corrP4 = scale * it->momentum;
349
350	// Calculate HT.
351	// The definiton differs from the saved jet, since trigger is described better
352	if( std::abs( corrP4.Eta() ) < 3 && corrP4.Pt > 40 )
353	ht += thisjet.pt;
354
355	if(std::abs(corrP4.Eta()) > 2.6 && skim ) continue;
356	if(corrP4.Pt() < 30 && skim ) continue;
357	thisjet.pt = corrP4.Pt();
358	thisjet.eta = corrP4.Eta();
359	thisjet.phi = corrP4.Phi();
360	thisjet.bCSV = it->bTagDiscriminators[susy::kCSV];
361	// jet composition
362	thisjet.chargedHadronEnergy = it->chargedHadronEnergy;
363	thisjet.neutralHadronEnergy = it->neutralHadronEnergy;
364	thisjet.photonEnergy = it->photonEnergy;
365	thisjet.electronEnergy = it->electronEnergy;
366	thisjet.muonEnergy = it->muonEnergy;
367	thisjet.HFHadronEnergy = it->HFHadronEnergy;
368	thisjet.HFEMEnergy = it->HFEMEnergy;
369	thisjet.chargedEmEnergy = it->chargedEmEnergy;
370	thisjet.chargedMuEnergy = it->chargedMuEnergy;
371	thisjet.neutralEmEnergy = it->neutralEmEnergy;
372
373	if( loggingVerbosity > 2 )
374	std::cout << " p_T, jet = " << thisjet.pt << std::endl;
375
376	jet.push_back( thisjet );
377	}// for jet
378	if( jet.size() < 2 && skim )
379	continue;
380	std::sort( jet.begin(), jet.end(), tree::EtGreater);
381	if( loggingVerbosity > 1 )
382	std::cout << "Found " << jet.size() << " jets" << std::endl;
383
384
385	// met
386	std::map<TString, susy::MET>::iterator met_it = event->metMap.find("pfMet");
387	susy::MET* metobj = &(met_it->second);
388	met = metobj->met();
389	met_phi = metobj->mEt.Phi();
390	if( loggingVerbosity > 2 )
391	std::cout << " met = " << met << std::endl;
392
393	std::map<TString, susy::MET>::iterator type1met_it = event->metMap.find("pfType1CorrectedMet");
394	susy::MET* type1metobj = &(type1met_it->second);
395	type1met = type1metobj->met();
396	type1met_phi = type1metobj->mEt.Phi();
397	if( loggingVerbosity > 2 )
398	std::cout << " type1met = " << type1met << std::endl;
399
400	// electrons
401	std::vector<susy::Electron> eVector = event->electrons["gsfElectrons"];
402	for(std::vector<susy::Electron>::iterator it = eVector.begin(); it < eVector.end(); ++it) {
403	tree::Particle thiselectron;
404	if( loggingVerbosity > 2 )
405	cout << " electron pt = " << it->momentum.Pt() << endl;
406	// for cuts see https://twiki.cern.ch/twiki/bin/viewauth/CMS/EgammaCutBasedIdentification
407	// use veto electrons
408	if( it->momentum.Pt() < 20 \|\| it->momentum.Pt() > 1e6 )
409	continue; // spike rejection
410	float iso = ( it->chargedHadronIso + max(it->neutralHadronIso+it->photonIso
411	- effectiveAreaElectron(it->momentum.Eta())*event->rho25, (float)0. )
412	) / it->momentum.Pt();
413	float d0 = d0correction( it, event );
414	float dZ = std::abs( dZcorrection( it, event ) );
415	if ( it->isEB() ){
416	if ( fabs(it->deltaEtaSuperClusterTrackAtVtx) > 0.007
417	\|\| fabs(it->deltaPhiSuperClusterTrackAtVtx) > 0.8
418	\|\| it->sigmaIetaIeta > 0.01
419	\|\| it->hcalOverEcalBc > 0.15
420	\|\| d0 > 0.04
421	\|\| dZ > 0.2
422	\|\| iso > 0.15 )
423	continue;
424	}
425	else if( it->isEE() ) {
426	if ( fabs(it->deltaEtaSuperClusterTrackAtVtx) > 0.01
427	\|\| fabs(it->deltaPhiSuperClusterTrackAtVtx) > 0.7
428	\|\| it->sigmaIetaIeta > 0.03
429	\|\| d0 > 0.04
430	\|\| dZ > 0.2
431	\|\| iso > 0.15 )
432	continue;
433	}
434	else // not in barrel nor in endcap
435	continue;
436
437	thiselectron.pt = it->momentum.Pt();
438	if( loggingVerbosity > 2 )
439	std::cout << " p_T, electron = " << it->momentum.Et() << std::endl;
440	thiselectron.eta = it->momentum.Eta();
441	thiselectron.phi = it->momentum.Phi();
442	electron.push_back( thiselectron );
443	}
444	if( loggingVerbosity > 1 )
445	std::cout << "Found " << electron.size() << " electrons" << std::endl;
446
447	// muons
448	tree::Particle thismuon;
449	std::vector<susy::Muon> mVector = event->muons["muons"];
450	for( std::vector<susy::Muon>::iterator it = mVector.begin(); it != mVector.end(); ++it) {
451	if( !( it->isPFMuon() && ( it->isGlobalMuon() \|\| it->isTrackerMuon() ) ) )
452	continue; // see https://twiki.cern.ch/twiki/bin/view/CMSPublic/SWGuideMuonId#Loose_Muon
453	thismuon.pt = it->momentum.Et();
454	if( thismuon.pt < 20 )
455	continue;
456	thismuon.eta = it->momentum.Eta();
457	thismuon.phi = it->momentum.Phi();
458	muon.push_back( thismuon );
459	}
460	if( loggingVerbosity > 1 )
461	std::cout << "Found " << muon.size() << " muons" << std::endl;
462
463	// vertices
464	nVertex = event->vertices.size();
465
466	if( ht < 450 && skim)
467	continue;
468
469
470	tree->Fill();
471	} // for jentry
472
473
474	outFile->cd();
475	eventNumbers->Write();
476	tree->Write();
477	outFile->Write();
478	outFile->Close();
479	}
480