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ReadLowPtSUSY_Tree_ComparisonDataMC.cc
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ReadLowPtSUSY_Tree_ComparisonDataMC.cc
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#include "ReadLowPtSUSY_Tree_ComparisonDataMC.h"
int ReadLowPtSUSY_Tree_ComparisonDataMC(std::string infile, std::string outfile, std::string type, std::string channel){
std::string inputfilename=(infile+".root").c_str();
TChain *tree=new TChain("LowPtSUSY_Tree");
tree->Add(inputfilename.c_str());
std::cout<<"Opened input file "<<inputfilename<<std::endl;
Int_t run;
Int_t lumi;
Int_t event;
Bool_t fired_HLTPho;
Bool_t fired_HLTPhoId;
Bool_t fired_HLTPhoIdMet;
vector<float> *ph_pt;
vector<float> *ph_phi;
vector<float> *ph_eta;
vector<float> *ph_energy;
Int_t nPhotons;
vector<float> *el_pt;
vector<float> *el_phi;
vector<float> *el_eta;
vector<float> *el_energy;
vector<int> *el_charge;
vector<bool> *el_isTight;
Int_t nElectrons;
vector<float> *mu_pt;
vector<float> *mu_phi;
vector<float> *mu_eta;
vector<float> *mu_energy;
vector<int> *mu_charge;
vector<bool> *mu_isTight;
Int_t nMuons;
vector<float> *jet_pt;
vector<float> *jet_phi;
vector<float> *jet_eta;
vector<float> *jet_energy;
vector<int> *jet_mva_loose;
vector<int> *jet_mva_tight;
vector<int> *jet_mva_medium;
vector<int> *jet_cut_loose;
vector<int> *jet_cut_tight;
vector<int> *jet_cut_medium;
Int_t nJets;
Float_t MET;
Float_t MET_Phi;
Float_t MET_Px;
Float_t MET_Py;
Int_t nVertices;
vector<float> *el_iso;
vector<float> *mu_iso;
vector<float> *ph_chIso;
vector<float> *ph_nuIso;
vector<float> *ph_phIso;
vector<bool> *ph_isTight;
vector<bool> *ph_phIsoTight;
vector<bool> *ph_phIsoMedium;
vector<bool> *ph_phIsoLoose;
bool Wt;
bool Ztt;
bool Zee;
bool Zmumu;
bool Znunu;
bool isPhoton;
Float_t nPUVertices;
Float_t nPUVerticesTrue;
Float_t PUWeightData;
Float_t PUWeightDataSys;
vector<int> *el_Matched;
vector<float> *el_MatchedPt;
vector<float> *el_MatchedEta;
vector<float> *el_MatchedPhi;
vector<float> *el_MatchedEnergy;
vector<int> *mu_Matched;
vector<float> *mu_MatchedPt;
vector<float> *mu_MatchedEta;
vector<float> *mu_MatchedPhi;
vector<float> *mu_MatchedEnergy;
float trigObj1Px;
float trigObj1Py;
float trigObj1Pz;
float trigObj1E;
float trigObj2Px;
float trigObj2Py;
float trigObj2Pz;
float trigObj2E;
// Set object pointer
ph_pt = 0;
ph_phi = 0;
ph_eta = 0;
ph_energy = 0;
el_pt = 0;
el_phi = 0;
el_eta = 0;
el_energy = 0;
el_charge = 0;
el_isTight = 0;
mu_pt = 0;
mu_phi = 0;
mu_eta = 0;
mu_energy = 0;
mu_charge = 0;
mu_isTight = 0;
jet_pt = 0;
jet_phi = 0;
jet_eta = 0;
jet_energy = 0;
jet_mva_loose = 0;
jet_mva_tight = 0;
jet_mva_medium = 0;
jet_cut_loose = 0;
jet_cut_tight = 0;
jet_cut_medium = 0;
el_iso = 0;
mu_iso = 0;
ph_chIso = 0;
ph_nuIso = 0;
ph_phIso = 0;
ph_isTight = 0;
ph_phIsoTight = 0;
ph_phIsoMedium = 0;
ph_phIsoLoose = 0;
if(type=="MC")
{
el_Matched = 0;
el_MatchedPt = 0;
el_MatchedEta = 0;
el_MatchedPhi = 0;
el_MatchedEnergy = 0;
mu_Matched = 0;
mu_MatchedPt = 0;
mu_MatchedEta = 0;
mu_MatchedPhi = 0;
mu_MatchedEnergy = 0;
}
tree->SetBranchAddress("run", &(run));
tree->SetBranchAddress("lumi", &(lumi));
tree->SetBranchAddress("event", &(event));
tree->SetBranchAddress("ph_pt", &(ph_pt));
tree->SetBranchAddress("ph_phi", &(ph_phi));
tree->SetBranchAddress("ph_eta", &(ph_eta));
tree->SetBranchAddress("ph_energy", &(ph_energy));
tree->SetBranchAddress("ph_chIso", &(ph_chIso));
tree->SetBranchAddress("ph_nuIso", &(ph_nuIso));
tree->SetBranchAddress("ph_phIso", &(ph_phIso));
tree->SetBranchAddress("ph_isTight", &(ph_isTight));
tree->SetBranchAddress("nPhotons", &(nPhotons));
tree->SetBranchAddress("el_pt", &(el_pt));
tree->SetBranchAddress("el_eta", &(el_eta));
tree->SetBranchAddress("el_phi", &(el_phi));
tree->SetBranchAddress("el_energy", &(el_energy));
tree->SetBranchAddress("el_charge", &(el_charge));
tree->SetBranchAddress("el_isTight", &(el_isTight));
tree->SetBranchAddress("el_iso", &(el_iso));
tree->SetBranchAddress("nElectrons", &(nElectrons));
tree->SetBranchAddress("mu_pt", &(mu_pt));
tree->SetBranchAddress("mu_eta", &(mu_eta));
tree->SetBranchAddress("mu_phi", &(mu_phi));
tree->SetBranchAddress("mu_energy", &(mu_energy));
tree->SetBranchAddress("mu_charge", &(mu_charge));
tree->SetBranchAddress("mu_isTight", &(mu_isTight));
tree->SetBranchAddress("mu_iso", &(mu_iso));
tree->SetBranchAddress("nMuons", &(nMuons));
tree->SetBranchAddress("jet_pt", &(jet_pt));
tree->SetBranchAddress("jet_phi", &(jet_phi));
tree->SetBranchAddress("jet_eta", &(jet_eta));
tree->SetBranchAddress("jet_energy", &(jet_energy));
tree->SetBranchAddress("jet_mva_loose", &(jet_mva_loose));
tree->SetBranchAddress("jet_mva_tight", &(jet_mva_tight));
tree->SetBranchAddress("jet_mva_medium", &(jet_mva_medium));
tree->SetBranchAddress("jet_cut_loose", &(jet_cut_loose));
tree->SetBranchAddress("jet_cut_tight", &(jet_cut_tight));
tree->SetBranchAddress("jet_cut_medium", &(jet_cut_medium));
tree->SetBranchAddress("nJets", &(nJets));
tree->SetBranchAddress("MET", &(MET));
tree->SetBranchAddress("MET_Phi", &(MET_Phi));
tree->SetBranchAddress("MET_Px", &(MET_Px));
tree->SetBranchAddress("MET_Py", &(MET_Py));
tree->SetBranchAddress("nVertices", &(nVertices));
tree->SetBranchAddress("nPUVertices", &(nPUVertices));
tree->SetBranchAddress("nPUVerticesTrue", &(nPUVerticesTrue));
tree->SetBranchAddress("PUWeightData", &(PUWeightData));
tree->SetBranchAddress("PUWeightDataSys", &(PUWeightDataSys));
tree->SetBranchAddress("ph_phIsoTight", &(ph_phIsoTight));
tree->SetBranchAddress("ph_phIsoMedium", &(ph_phIsoMedium));
tree->SetBranchAddress("ph_phIsoLoose", &(ph_phIsoLoose));
if(type=="Data"){
tree->SetBranchAddress("fired_HLTPho", &(fired_HLTPho));
tree->SetBranchAddress("fired_HLTPhoId", &(fired_HLTPhoId));
tree->SetBranchAddress("fired_HLTPhoIdMet", &(fired_HLTPhoIdMet));
tree->SetBranchAddress("trigObj1Px", &(trigObj1Px));
tree->SetBranchAddress("trigObj1Py", &(trigObj1Py));
tree->SetBranchAddress("trigObj1Pz", &(trigObj1Pz));
tree->SetBranchAddress("trigObj1E", &(trigObj1E));
tree->SetBranchAddress("trigObj2Px", &(trigObj2Px));
tree->SetBranchAddress("trigObj2Py", &(trigObj2Py));
tree->SetBranchAddress("trigObj2Pz", &(trigObj2Pz));
tree->SetBranchAddress("trigObj2E", &(trigObj2E));
}
if(type=="MC"){
tree->SetBranchAddress("el_Matched", &(el_Matched));
tree->SetBranchAddress("el_MatchedPt", &(el_MatchedPt));
tree->SetBranchAddress("el_MatchedEta", &(el_MatchedEta));
tree->SetBranchAddress("el_MatchedPhi", &(el_MatchedPhi));
tree->SetBranchAddress("el_MatchedEnergy", &(el_MatchedEnergy));
tree->SetBranchAddress("mu_Matched", &(mu_Matched));
tree->SetBranchAddress("mu_MatchedPt", &(mu_MatchedPt));
tree->SetBranchAddress("mu_MatchedEta", &(mu_MatchedEta));
tree->SetBranchAddress("mu_MatchedPhi", &(mu_MatchedPhi));
tree->SetBranchAddress("mu_MatchedEnergy", &(mu_MatchedEnergy));
tree->SetBranchAddress("Wt", &(Wt));
tree->SetBranchAddress("Ztt", &(Ztt));
tree->SetBranchAddress("Zee", &(Zee));
tree->SetBranchAddress("Zmumu", &(Zmumu));
tree->SetBranchAddress("Znunu", &(Znunu));
tree->SetBranchAddress("isPhoton", &(isPhoton));
}
//Booking histograms:
TH1F *h_mu_pt_leading=new TH1F("h_mu_pt_leading", "Leading muon pT; pT [GeV]; Events/GeV", 1000, 0, 1000); h_mu_pt_leading->Sumw2();
TH1F *h_mu_pt_trailing=new TH1F("h_mu_pt_trailing", "Trailing muon pT; pT [GeV]; Events/GeV", 1000, 0, 1000); h_mu_pt_trailing->Sumw2();
TH1F *h_el_pt_leading=new TH1F("h_el_pt_leading", "Leading electron pT; pT [GeV]; Events/GeV", 1000, 0, 1000); h_el_pt_leading->Sumw2();
TH1F *h_el_pt_trailing=new TH1F("h_el_pt_trailing", "Trailing electron pT; pT [GeV]; Events/GeV", 1000, 0, 1000); h_el_pt_trailing->Sumw2();
TH1F *h_mu_eta_leading=new TH1F("h_mu_eta_leading", "Leading muon #eta ; #eta ; Events", 600, -3.0, 3.0); h_mu_eta_leading->Sumw2();
TH1F *h_mu_eta_trailing=new TH1F("h_mu_eta_trailing", "Trailing muon #eta; #eta ; Events", 600, -3.0, 3.0); h_mu_eta_trailing->Sumw2();
TH1F *h_el_eta_leading=new TH1F("h_el_eta_leading", "Leading electron #eta; #eta ; Events", 600, -3.0, 3.0); h_el_eta_leading->Sumw2();
TH1F *h_el_eta_trailing=new TH1F("h_el_eta_trailing", "Trailing electron #eta; #eta ; Events", 600.0, -3.0, 3.0); h_el_eta_trailing->Sumw2();
TH1F *h_mu_phi_leading=new TH1F("h_mu_phi_leading", "Leading muon #phi ; #phi ; Events", 800, -4.0, 4.0); h_mu_phi_leading->Sumw2();
TH1F *h_mu_phi_trailing=new TH1F("h_mu_phi_trailing", "Trailing muon #phi; #phi ; Events", 800, -4.0, 4.0); h_mu_phi_trailing->Sumw2();
TH1F *h_el_phi_leading=new TH1F("h_el_phi_leading", "Leading electron #phi; #phi ; Events", 800, -4.0, 4.0); h_el_phi_leading->Sumw2();
TH1F *h_el_phi_trailing=new TH1F("h_el_phi_trailing", "Trailing electron #phi; #phi ; Events", 800.0, -4.0, 4.0); h_el_phi_trailing->Sumw2();
TH1F *h_mu_energy_leading=new TH1F("h_mu_energy_leading", "Leading muon Energy; Energy [GeV]; Events/GeV", 1000, 0, 1000); h_mu_energy_leading->Sumw2();
TH1F *h_mu_energy_trailing=new TH1F("h_mu_energy_trailing", "Trailing muon Energy; Energy [GeV]; Events/GeV", 1000, 0, 1000); h_mu_energy_trailing->Sumw2();
TH1F *h_el_energy_leading=new TH1F("h_el_energy_leading", "Leading electron Energy; Energy [GeV]; Events/GeV", 1000, 0, 1000); h_el_energy_leading->Sumw2();
TH1F *h_el_energy_trailing=new TH1F("h_el_energy_trailing", "Trailing electron Energy; Energy [GeV]; Events/GeV", 1000, 0, 1000); h_el_energy_trailing->Sumw2();
TH1F *h_photon_pt =new TH1F("h_photon_pt", "Photon pT; pT [GeV]; Events/GeV", 1000, 0, 1000); h_photon_pt->Sumw2();
TH1F *h_photon_eta =new TH1F("h_photon_eta", "Photon #eta; #eta ; Events", 600, -3.0, 3.0); h_photon_eta->Sumw2();
TH1F *h_photon_phi =new TH1F("h_photon_phi", "Photon #phi; #phi ; Events", 800, -4.0, 4.0); h_photon_phi->Sumw2();
TH1F *h_photon_energy =new TH1F("h_photon_energy", "Photon Energy; Energy [GeV]; Events", 1000, 0, 1000); h_photon_energy->Sumw2();
TH1F *h_InvariantMass_Mu=new TH1F("h_InvariantMass_Mu", "Di-muon invariant mass; m_{#mu#mu} [GeV]; Events/GeV", 9000, 0, 300); h_InvariantMass_Mu->Sumw2();
TH1F *h_InvariantMass_El=new TH1F("h_InvariantMass_El", "Di-electron invariant mass; m_{ee} [GeV]; Events/GeV", 9000, 0, 300); h_InvariantMass_El->Sumw2();
TH1F *h_InvariantMass_MuPh=new TH1F("h_InvariantMass_MuPh", "Di-muon and photon invariant mass; m_{#mu#mu#gamma} [GeV]; Events/GeV", 9000, 0, 300); h_InvariantMass_MuPh->Sumw2();
TH1F *h_InvariantMass_ElPh=new TH1F("h_InvariantMass_ElPh", "Di-electron and photon invariant mass; m_{ee#gamma} [GeV]; Events/GeV", 9000, 0, 300); h_InvariantMass_ElPh->Sumw2();
TH1F *h_InvariantMass_ElMu=new TH1F("h_InvariantMass_ElMu", "Electron-Muon invariant mass; m_{e#mu} [GeV]; Events/GeV", 9000, 0, 300); h_InvariantMass_ElMu->Sumw2();
TH1F *h_MET=new TH1F("h_MET", "Missing ET; MET [GeV]; Events/GeV", 600, 0, 600); h_MET->Sumw2();
TH1F *h_nVertices=new TH1F("h_nVertices", "Number of vertices; nvertices; Events", 30, -0.5, 29.5); h_nVertices->Sumw2();
TH1F *h_nPUVertices=new TH1F("h_nPUVertices", "Number of PU vertices; nvertices; Events", 30, -0.5, 29.5); h_nPUVertices->Sumw2();
TH1F *h_nPUVerticesTrue=new TH1F("h_nPUVerticesTrue", "Number of PU vertices; nvertices; Events", 30, -0.5, 29.5); h_nPUVerticesTrue->Sumw2();
TH1F *h_HT = new TH1F("h_HT", "HT (scalar sum of jet pT); H_T [GeV]; Events/GeV", 5000, 0, 5000.0);h_HT->Sumw2();
TH1F *h_cMt_Mu = new TH1F("h_cMt_Mu", "Cluster Transverse Mass; M_{T}(#mu,#gamma,MET) [GeV]; Events/GeV", 5000, 0, 500);h_cMt_Mu->Sumw2();
TH1F *h_Mt_Mu = new TH1F("h_Mt_Mu", "Transverse Mass; M_{T}(#mu, MET) [GeV]; Events/GeV", 3000, 0, 150);h_Mt_Mu->Sumw2();
TH1F *h_jet_pt_leading=new TH1F("h_jet_pt_leading", "Leading jet pT; pT [GeV]; Events/GeV", 10000, 0, 1000); h_jet_pt_leading->Sumw2();
TH1F *h_jet_pt_trailing=new TH1F("h_jet_pt_trailing", "Trailing jet pT; pT [GeV]; Events/GeV", 10000, 0, 1000); h_jet_pt_trailing->Sumw2();
TH1F *h_jet_pt_3rd=new TH1F("h_jet_pt_3rd", "3rd jet pT; pT [GeV]; Events/GeV", 10000, 0, 1000); h_jet_pt_3rd->Sumw2();
TH1F *h_jet_pt_4th=new TH1F("h_jet_pt_4th", "4th jet pT; pT [GeV]; Events/GeV", 10000, 0, 1000); h_jet_pt_4th->Sumw2();
TH1F *h_jet_pt_5th=new TH1F("h_jet_pt_5th", "5th jet pT; pT [GeV]; Events/GeV", 10000, 0, 1000); h_jet_pt_5th->Sumw2();
TH1F *h_jet_pt_6th=new TH1F("h_jet_pt_6th", "6th jet pT; pT [GeV]; Events/GeV", 10000, 0, 1000); h_jet_pt_6th->Sumw2();
TH1F *h_jet_eta_leading=new TH1F("h_jet_eta_leading", "Leading jet #eta; #eta; Events", 600, -3.0, 3.0); h_jet_eta_leading->Sumw2();
TH1F *h_jet_eta_trailing=new TH1F("h_jet_eta_trailing", "Trailing jet #eta; #eta; Events", 600, -3.0, 3.0); h_jet_eta_trailing->Sumw2();
TH1F *h_jet_eta_3rd=new TH1F("h_jet_eta_3rd", "3rd jet #eta; #eta; Events/GeV", 600, -3.0, 3.0); h_jet_eta_3rd->Sumw2();
TH1F *h_jet_eta_4th=new TH1F("h_jet_eta_4th", "4th jet #eta; #eta; Events/GeV", 600, -3.0, 3.0); h_jet_eta_4th->Sumw2();
TH1F *h_jet_eta_5th=new TH1F("h_jet_eta_5th", "5th jet #eta; #eta; Events/GeV", 600, -3.0, 3.0); h_jet_eta_5th->Sumw2();
TH1F *h_jet_eta_6th=new TH1F("h_jet_eta_6th", "6th jet #eta; #eta; Events/GeV", 600, -3.0, 3.0); h_jet_eta_6th->Sumw2();
TH1F *h_jet_phi_leading=new TH1F("h_jet_phi_leading", "Leading jet #phi; #phi; Events/GeV", 800, -4.0, 4.0); h_jet_phi_leading->Sumw2();
TH1F *h_jet_phi_trailing=new TH1F("h_jet_phi_trailing", "Trailing jet #phi; #phi; Events/GeV", 800, -4.0, 4.0); h_jet_phi_trailing->Sumw2();
TH1F *h_jet_phi_3rd=new TH1F("h_jet_phi_3rd", "3rd jet #phi; #phi; Events/GeV", 800, -4.0, 4.0); h_jet_phi_3rd->Sumw2();
TH1F *h_jet_phi_4th=new TH1F("h_jet_phi_4th", "4th jet #phi; #phi; Events/GeV", 800, -4.0, 4.0); h_jet_phi_4th->Sumw2();
TH1F *h_jet_phi_5th=new TH1F("h_jet_phi_5th", "5th jet #phi; #phi; Events/GeV", 800, -4.0, 4.0); h_jet_phi_5th->Sumw2();
TH1F *h_jet_phi_6th=new TH1F("h_jet_phi_6th", "6th jet #phi; #phi; Events/GeV", 800, -4.0, 4.0); h_jet_phi_6th->Sumw2();
TH1F *h_jet_energy_leading=new TH1F("h_jet_energy_leading", "Leading jet Energy; Energy [GeV]; Events/GeV", 10000, 0, 1000); h_jet_energy_leading->Sumw2();
TH1F *h_jet_energy_trailing=new TH1F("h_jet_energy_trailing", "Trailing jet Energy; Energy [GeV]; Events/GeV", 10000, 0, 1000); h_jet_energy_trailing->Sumw2();
TH1F *h_jet_energy_3rd=new TH1F("h_jet_energy_3rd", "3rd jet Energy; Energy [GeV]; Events/GeV", 10000, 0, 1000); h_jet_energy_3rd->Sumw2();
TH1F *h_jet_energy_4th=new TH1F("h_jet_energy_4th", "4th jet Energy; Energy [GeV]; Events/GeV", 10000, 0, 1000); h_jet_energy_4th->Sumw2();
TH1F *h_jet_energy_5th=new TH1F("h_jet_energy_5th", "5th jet Energy; Energy [GeV]; Events/GeV", 10000, 0, 1000); h_jet_energy_5th->Sumw2();
TH1F *h_jet_energy_6th=new TH1F("h_jet_energy_6th", "6th jet Energy; Energy [GeV]; Events/GeV", 10000, 0, 1000); h_jet_energy_6th->Sumw2();
TH1F *h_nJets = new TH1F("h_nJets", "Number of Jets; Number of Jets; Events", 20, -0.5, 19.5);h_nJets->Sumw2();
TH2F *h_Mmumu_MmumuGamma = new TH2F("h_Mmumu_MmumuGamma", "Scatter Plot of M_{#mu#mu} versus M_{#mu#mu#gamma}; M_{#mu#mu} [GeV]; M_{#mu#mu#gamma} [GeV]", 4000, 0, 2000, 4000, 0, 2000); h_Mmumu_MmumuGamma->Sumw2();
TH2F *h_Jet1Pt_PhPt = new TH2F("h_Jet1Pt_PhPt", "Scatter Plot of the leading Jet pT versus Photon pT; pT [GeV]; pT [GeV]", 2000, 0, 1000, 2000, 0, 1000); h_Jet1Pt_PhPt->Sumw2();
double Wt_events_mumu = 0;
double Wt_events_emu = 0;
double Ztt_events_mumu = 0;
double Ztt_events_emu = 0;
double MET_emu = 0;
double MET_mumu = 0;
double Ztt_events_LowHT_mumu = 0;
double Ztt_events_LowHT_emu = 0;
double LowHT_mumu = 0;
double LowHT_emu = 0;
double emu = 0;
double mumu = 0;
double Z_peakGammaEvents = 0;
TFile *triggerCurves=new TFile("Fit.root");
TF1* fit_curve1=(TF1*)triggerCurves->Get("fit_MET");
TF1* fit_curve2=(TF1*)triggerCurves->Get("fit_PHO");
int nEvents=tree->GetEntries();
std::cout << "nEvents= " << nEvents << std::endl;
for (int i=0; i<nEvents ; ++i)
{
tree->GetEvent(i);
if(type=="Data")
{
if(fired_HLTPhoIdMet!=1) continue;
}
/*if(type=="MC")
{
if(Znunu==false) continue;
}
*/
// filling the photon's properties into a vector of struct
std::vector<PhotonInfo> photons;
for (unsigned int j=0; j<ph_pt->size(); ++j)
{
PhotonInfo photon;
photon.pT=ph_pt->at(j);
photon.eta=ph_eta->at(j);
photon.phi=ph_phi->at(j);
photon.energy=ph_energy->at(j);
photon.isTight=ph_isTight->at(j);
photon.chIsolation=ph_chIso->at(j);
photon.nuIsolation=ph_nuIso->at(j);
photon.phIsolation=ph_phIso->at(j);
photon.phIsoTight=ph_phIsoTight->at(j);
photon.phIsoMedium=ph_phIsoMedium->at(j);
photon.phIsoLoose=ph_phIsoLoose->at(j);
photons.push_back(photon);
}
// Now sorting this vector of structs
std::sort (photons.begin(), photons.end(), sortPhotonsInDescendingpT);
TLorentzVector ph1_p4;
ph1_p4 = fillTLorentzVector(0.0, 0.0, 0.0, 0.0);
//here working with the leading photon.
if (photons.size() > 0) ph1_p4=fillTLorentzVector(photons.at(0).pT, photons.at(0).eta, photons.at(0).phi, photons.at(0).energy);
double eventWeight_Trigger = 0.0;
double eventWeight = 0.0;
if(type=="MC")
{
double triggerWeight1 = fit_curve1->Eval(MET);
double triggerWeight2 = 0.0;
if(ph1_p4.Pt()>30.0 and photons.at(0).isTight==1 and photons.at(0).phIsoTight==1) triggerWeight2 = fit_curve2->Eval(ph1_p4.Pt());
eventWeight_Trigger=triggerWeight1*triggerWeight2;
eventWeight=triggerWeight1*triggerWeight2*PUWeightData;
}
else if(type=="Data")
{
if(ph1_p4.Pt()>30.0 and photons.at(0).isTight==1 and photons.at(0).phIsoTight==1) eventWeight = 1.0;
}
TriggerInfo trigger1;
if(type=="Data")
{
trigger1.Px = trigObj1Px;
trigger1.Py = trigObj1Py;
trigger1.Pz = trigObj1Pz;
trigger1.E = trigObj1E;
}
// filling the electron's properties into a vector of struct
std::vector<LeptonInfo> electrons;
for (unsigned int j=0; j<el_pt->size(); ++j)
{
LeptonInfo electron;
electron.pT=el_pt->at(j);
electron.eta=el_eta->at(j);
electron.phi=el_phi->at(j);
electron.energy=el_energy->at(j);
electron.charge=el_charge->at(j);
electron.isTight=el_isTight->at(j);
electron.isolation=el_iso->at(j);
electrons.push_back(electron);
}
// Now sorting this vector of structs
std::sort (electrons.begin(), electrons.end(), sortLeptonsInDescendingpT);
TLorentzVector el1_p4;
TLorentzVector el2_p4;
el1_p4 = fillTLorentzVector(0.0, 0.0, 0.0, 0.0);
el2_p4 = fillTLorentzVector(0.0, 0.0, 0.0, 0.0);
double deltaR_el1 = -1.0;
if (electrons.size() > 0)
{
el1_p4=fillTLorentzVector(electrons.at(0).pT, electrons.at(0).eta, electrons.at(0).phi, electrons.at(0).energy);
if(type=="Data")
{
TLorentzVector trigger1_p4;
trigger1_p4.SetPxPyPzE(trigger1.Px, trigger1.Py, trigger1.Pz, trigger1.E);
if(el1_p4.Pt() > 0.0) deltaR_el1 = el1_p4.DeltaR(trigger1_p4);
}
}//only execute if an electron exists.
double deltaR_el2 = -1.0;
if (electrons.size() > 1)
{
el2_p4=fillTLorentzVector(electrons.at(1).pT, electrons.at(1).eta, electrons.at(1).phi, electrons.at(1).energy);
if(type=="Data")
{
TLorentzVector trigger1_p4;
trigger1_p4.SetPxPyPzE(trigger1.Px, trigger1.Py, trigger1.Pz, trigger1.E);
if(el2_p4.Pt() > 0.0) deltaR_el2 = el2_p4.DeltaR(trigger1_p4);
}
}//only execute if the second electron exists.
if(type=="MC") deltaR_el1 = 100.0;
if(type=="MC") deltaR_el2 = 100.0;
double leadingDeltaR, trailingDeltaR;
leadingDeltaR = -1.0;
trailingDeltaR = -1.0;
if(el1_p4.Pt()>0.0 and ph1_p4.Pt()>30.0 and photons.at(0).isTight==1 and photons.at(0).phIsoTight==1){
leadingDeltaR = el1_p4.DeltaR(ph1_p4);
}
if(el2_p4.Pt()>0.0 and ph1_p4.Pt()>30.0 and photons.at(0).isTight==1 and photons.at(0).phIsoTight==1){
trailingDeltaR = el2_p4.DeltaR(ph1_p4);
}
// filling the muon's properties into a vector of struct
std::vector<LeptonInfo> muons;
for (unsigned int j=0; j<mu_pt->size(); ++j)
{
LeptonInfo muon;
muon.pT=mu_pt->at(j);
muon.eta=mu_eta->at(j);
muon.phi=mu_phi->at(j);
muon.energy=mu_energy->at(j);
muon.charge=mu_charge->at(j);
muon.isTight=mu_isTight->at(j);
muon.isolation=mu_iso->at(j);
muons.push_back(muon);
}
// Now sorting this vector of structs
std::sort (muons.begin(), muons.end(), sortLeptonsInDescendingpT);
TLorentzVector mu1_p4;
TLorentzVector mu2_p4;
mu1_p4 = fillTLorentzVector(0.0, 0.0, 0.0, 0.0);
mu2_p4 = fillTLorentzVector(0.0, 0.0, 0.0, 0.0);
if (muons.size() > 0) mu1_p4=fillTLorentzVector(muons.at(0).pT, muons.at(0).eta, muons.at(0).phi, muons.at(0).energy);
if (muons.size() > 1) mu2_p4=fillTLorentzVector(muons.at(1).pT, muons.at(1).eta, muons.at(1).phi, muons.at(1).energy);
std::vector<JetInfo> jets;
for (unsigned int j=0; j<jet_pt->size(); ++j)
{
JetInfo jet;
jet.pT = jet_pt->at(j);
jet.eta = jet_eta->at(j);
jet.phi = jet_phi->at(j);
jet.energy = jet_energy->at(j);
jet.PU_mva_loose = jet_mva_loose->at(j);
jet.PU_mva_tight = jet_mva_tight->at(j);
jet.PU_mva_medium = jet_mva_medium->at(j);
jet.PU_cut_loose = jet_cut_loose->at(j);
jet.PU_cut_tight = jet_cut_tight->at(j);
jet.PU_cut_medium = jet_cut_medium->at(j);
jets.push_back(jet);
}
// Now sorting this vector of structs
std::sort (jets.begin(), jets.end(), sortJetsInDescendingpT);
double HT = 0.0; //jets are sorted. Don't care as far as HT is concerned.
vector<TLorentzVector> Jet_vector;
Jet_vector.clear();
for(unsigned int k=0; k<jets.size(); ++k)
{
TLorentzVector Jet;
if(fabs(jets.at(k).eta)<2.4 and jets.at(k).pT>25.0 and jets.at(k).PU_mva_loose==1)
{
Jet.SetPtEtaPhiE(jets.at(k).pT, jets.at(k).eta, jets.at(k).phi, jets.at(k).energy);
bool isGoodJet=true;
for(unsigned int j=0; j<electrons.size(); ++j)
{
TLorentzVector Electron;
if(electrons.at(j).isTight==1 and electrons.at(j).isolation < 0.10){
Electron.SetPtEtaPhiE(electrons.at(j).pT, electrons.at(j).eta, electrons.at(j).phi, electrons.at(j).energy);
double DRjet_el = Jet.DeltaR(Electron);
if(DRjet_el<0.5) isGoodJet=false;
}
}
for(unsigned int j=0; j<muons.size(); ++j)
{
TLorentzVector Muon;
if(muons.at(j).isTight==1 and muons.at(j).isolation < 0.12){
Muon.SetPtEtaPhiE(muons.at(j).pT, muons.at(j).eta, muons.at(j).phi, muons.at(j).energy);
double DRjet_mu = Jet.DeltaR(Muon);
if(DRjet_mu<0.5) isGoodJet=false;
}
}
for(unsigned int l=0; l<photons.size(); ++l)
{
TLorentzVector Photon;
if(photons.at(l).pT>30.0 and photons.at(l).isTight==1 and photons.at(l).phIsoTight==1){
Photon.SetPtEtaPhiE(photons.at(l).pT, photons.at(l).eta, photons.at(l).phi, photons.at(l).energy);
double DRjet_ph = Jet.DeltaR(Photon);
if(DRjet_ph<0.5) isGoodJet=false;
}
}
if(type=="Data")
{
TLorentzVector trigger1_p4;
trigger1_p4.SetPxPyPzE(trigger1.Px, trigger1.Py, trigger1.Pz, trigger1.E);
double DRjet_tr = Jet.DeltaR(trigger1_p4);
if(DRjet_tr<0.5) isGoodJet=false;
}
if(isGoodJet) Jet_vector.push_back(Jet);
}//close four vector if
}//close jet loop
// Now sorting this vector of structs
std::sort (Jet_vector.begin(), Jet_vector.end(), sortJetVectorsInDescendingpT);
for(unsigned int m=0; m<Jet_vector.size(); m++) HT += Jet_vector.at(m).Pt();
if(el1_p4.Pt()>0.0 and electrons.at(0).isTight==1 and electrons.at(0).isolation < 0.10 and leadingDeltaR > 0.4 and deltaR_el1 > 0.4){
if(type=="MC") eventWeight *= electronSF(el1_p4.Pt(), el1_p4.Eta());
h_el_phi_leading->Fill(el1_p4.Phi(), eventWeight);
h_el_eta_leading->Fill(el1_p4.Eta(), eventWeight);
h_el_pt_leading->Fill(el1_p4.Pt(), eventWeight);
h_el_energy_leading->Fill(el1_p4.E(), eventWeight);
if(el2_p4.Pt()>0.0 and electrons.at(1).isTight==1 and electrons.at(1).isolation < 0.10 and trailingDeltaR > 0.4 and deltaR_el2 > 0.4 and ((electrons.at(0).charge*electrons.at(1).charge)==-1)) {
if(type=="MC") eventWeight *= electronSF(el2_p4.Pt(), el2_p4.Eta());
h_el_phi_trailing->Fill(el2_p4.Phi(), eventWeight);
h_el_eta_trailing->Fill(el2_p4.Eta(), eventWeight);
h_el_pt_trailing->Fill(el2_p4.Pt(), eventWeight);
h_el_energy_trailing->Fill(el2_p4.E(), eventWeight);
h_InvariantMass_El->Fill((el1_p4+el2_p4).M(), eventWeight);
if(ph1_p4.Pt()>30.0 and photons.at(0).isTight==1 and photons.at(0).phIsoTight==1) h_InvariantMass_ElPh->Fill((el1_p4+el2_p4+ph1_p4).M(), eventWeight);
}//trailing electron "if"
}//closing ledinding electron "if" statement
double cMt2_Mu = -99.0;
double Mlg_Mu = -99.0;
double pTlg_Mu = -99.0;
double mt2_Mu = -99.0;
int mumu_event = 0;
if(mu1_p4.Pt()>0.0 and muons.at(0).isTight==1 and muons.at(0).isolation < 0.12 and eventWeight > 0.0){
if(type=="MC") eventWeight *= muonSF(mu1_p4.Pt(), mu1_p4.Eta());
h_mu_phi_leading->Fill(mu1_p4.Phi(), eventWeight);
h_mu_eta_leading->Fill(mu1_p4.Eta(), eventWeight);
h_mu_pt_leading->Fill(mu1_p4.Pt(), eventWeight);
h_mu_energy_leading->Fill(mu1_p4.E(), eventWeight);
double dphi = fabs(MET_Phi - mu1_p4.Phi());
if (dphi > TMath::Pi()) dphi = TMath::TwoPi() - dphi;
mt2_Mu = 2*mu1_p4.Pt()*MET*(1 - TMath::Cos(dphi));
h_Mt_Mu->Fill(TMath::Sqrt(mt2_Mu), eventWeight);
if(ph1_p4.Pt()>30.0 and photons.at(0).isTight==1 and photons.at(0).phIsoTight==1){
//Computing the clustered mass distribution:
TVector2 mu_transverse;
TVector2 met_transverse;
TVector2 ph_transverse;
mu_transverse.SetMagPhi(mu1_p4.Pt(), mu1_p4.Phi());
ph_transverse.SetMagPhi(ph1_p4.Pt(), ph1_p4.Phi());
met_transverse.SetMagPhi(MET, MET_Phi);
Mlg_Mu = (mu1_p4+ph1_p4).M();
pTlg_Mu = (ph_transverse + mu_transverse).Mod2();
double t1 = TMath::Sqrt(Mlg_Mu*Mlg_Mu + pTlg_Mu);
cMt2_Mu=((t1 + MET)*(t1 + MET) - (ph_transverse + mu_transverse + met_transverse).Mod2());
h_cMt_Mu->Fill(TMath::Sqrt(cMt2_Mu), eventWeight);
}
if(mu2_p4.Pt()>0.0 and muons.at(1).isTight==1 and muons.at(1).isolation < 0.12 and ((muons.at(0).charge*muons.at(1).charge)==-1)) {
if(type=="MC") eventWeight *= muonSF(mu2_p4.Pt(), mu2_p4.Eta());
mumu_event = 1;
mumu+=eventWeight;
h_mu_phi_trailing->Fill(mu2_p4.Phi(), eventWeight);
h_mu_eta_trailing->Fill(mu2_p4.Eta(), eventWeight);
h_mu_pt_trailing->Fill(mu2_p4.Pt(), eventWeight);
h_mu_energy_trailing->Fill(mu2_p4.E(), eventWeight);
h_InvariantMass_Mu->Fill((mu1_p4+mu2_p4).M(), eventWeight);
if(ph1_p4.Pt()>0.0 and photons.at(0).isTight==1 and photons.at(0).phIsoTight==1) h_InvariantMass_MuPh->Fill((mu1_p4+mu2_p4+ph1_p4).M(), eventWeight);
if(ph1_p4.Pt()>0.0 and photons.at(0).isTight==1 and photons.at(0).phIsoTight==1) {
h_Mmumu_MmumuGamma->Fill((mu1_p4+mu2_p4).M(), (mu1_p4+mu2_p4+ph1_p4).M(), eventWeight);
if(((mu1_p4+mu2_p4+ph1_p4).M()>76 and (mu1_p4+mu2_p4+ph1_p4).M()<106)) Z_peakGammaEvents+=eventWeight;
}
if(type=="MC" and Ztt==true) Ztt_events_mumu+=eventWeight;
if(type=="MC" and Wt==true) Wt_events_mumu+=eventWeight;
if(type=="Data" and ((mu1_p4+mu2_p4).M() > 10 and (mu1_p4+mu2_p4).M() < 60)) Ztt_events_mumu+=eventWeight;
if(MET > 25.0) MET_mumu+=eventWeight;
if(type=="MC" and Ztt==true and HT<300) Ztt_events_LowHT_mumu+=eventWeight;
if(type=="Data" and (((mu1_p4+mu2_p4).M() > 10 and (mu1_p4+mu2_p4).M() < 60) and HT<300)) Ztt_events_LowHT_mumu+=eventWeight;
if(HT<300) LowHT_mumu+=eventWeight;
}
}
int emu_event = 0;
if((mu1_p4.Pt()>0.0 and muons.at(0).isTight==1 and muons.at(0).isolation < 0.12) and (el1_p4.Pt()>0.0 and electrons.at(0).isTight==1 and electrons.at(0).isolation < 0.10 and leadingDeltaR > 0.4 and deltaR_el1 > 0.4) and eventWeight > 0.0 and mumu_event == 0 ) {
if(type=="MC") eventWeight *= electronSF(el1_p4.Pt(), el1_p4.Eta())*muonSF(mu1_p4.Pt(), mu1_p4.Eta());
emu_event = 1;
emu+=eventWeight;
h_InvariantMass_ElMu->Fill((mu1_p4+el1_p4).M(), eventWeight);
if(type=="MC" and Ztt==1) Ztt_events_emu+=eventWeight;
if(type=="MC" and Wt==true) Wt_events_emu+=eventWeight;
if(type=="Data" and ((mu1_p4+el1_p4).M() > 10 and (mu1_p4+el1_p4).M() < 60)) Ztt_events_emu+=eventWeight;
if(MET > 25.0) MET_emu+=eventWeight;
if(type=="MC" and Ztt==true and HT<300) Ztt_events_LowHT_emu+=eventWeight;
if(type=="Data" and (((mu1_p4+el1_p4).M() > 10 and (mu1_p4+el1_p4).M() < 60) and HT<300)) Ztt_events_LowHT_emu+=eventWeight;
if(HT<300) LowHT_emu+=eventWeight;
}//El-Mu invariant mass
if(channel=="MuMu" and mumu_event==1 and emu_event == 0){
if (ph1_p4.Pt()>30.0 and photons.at(0).isTight==1 and photons.at(0).phIsoTight==1 and eventWeight > 0.0){
h_photon_pt->Fill(ph1_p4.Pt(), eventWeight);
h_photon_eta->Fill(ph1_p4.Eta(), eventWeight);
h_photon_phi->Fill(ph1_p4.Phi(), eventWeight);
h_photon_energy->Fill(ph1_p4.E(), eventWeight);
if(Jet_vector.size()>0) h_Jet1Pt_PhPt->Fill(Jet_vector.at(0).Pt(), ph1_p4.Pt(), eventWeight);
}
if(eventWeight > 0.0) h_MET->Fill(MET, eventWeight);
if(eventWeight > 0.0) h_nVertices->Fill(nVertices, eventWeight);
if(eventWeight > 0.0) h_nPUVertices->Fill(nPUVertices, eventWeight);
if(eventWeight > 0.0) h_nPUVerticesTrue->Fill(nPUVerticesTrue, eventWeight);
if(Jet_vector.size()>0 and eventWeight > 0.0) h_jet_pt_leading->Fill(Jet_vector.at(0).Pt(), eventWeight);
if(Jet_vector.size()>1 and eventWeight > 0.0) h_jet_pt_trailing->Fill(Jet_vector.at(1).Pt(), eventWeight);
if(Jet_vector.size()>2 and eventWeight > 0.0) h_jet_pt_3rd->Fill(Jet_vector.at(2).Pt(), eventWeight);
if(Jet_vector.size()>3 and eventWeight > 0.0) h_jet_pt_4th->Fill(Jet_vector.at(3).Pt(), eventWeight);
if(Jet_vector.size()>4 and eventWeight > 0.0) h_jet_pt_5th->Fill(Jet_vector.at(4).Pt(), eventWeight);
if(Jet_vector.size()>5 and eventWeight > 0.0) h_jet_pt_6th->Fill(Jet_vector.at(5).Pt(), eventWeight);
if(Jet_vector.size()>0 and eventWeight > 0.0) h_jet_eta_leading->Fill(Jet_vector.at(0).Eta(), eventWeight);
if(Jet_vector.size()>1 and eventWeight > 0.0) h_jet_eta_trailing->Fill(Jet_vector.at(1).Eta(), eventWeight);
if(Jet_vector.size()>2 and eventWeight > 0.0) h_jet_eta_3rd->Fill(Jet_vector.at(2).Eta(), eventWeight);
if(Jet_vector.size()>3 and eventWeight > 0.0) h_jet_eta_4th->Fill(Jet_vector.at(3).Eta(), eventWeight);
if(Jet_vector.size()>4 and eventWeight > 0.0) h_jet_eta_5th->Fill(Jet_vector.at(4).Eta(), eventWeight);
if(Jet_vector.size()>5 and eventWeight > 0.0) h_jet_eta_6th->Fill(Jet_vector.at(5).Eta(), eventWeight);
if(Jet_vector.size()>0 and eventWeight > 0.0) h_jet_phi_leading->Fill(Jet_vector.at(0).Phi(), eventWeight);
if(Jet_vector.size()>1 and eventWeight > 0.0) h_jet_phi_trailing->Fill(Jet_vector.at(1).Phi(), eventWeight);
if(Jet_vector.size()>2 and eventWeight > 0.0) h_jet_phi_3rd->Fill(Jet_vector.at(2).Phi(), eventWeight);
if(Jet_vector.size()>3 and eventWeight > 0.0) h_jet_phi_4th->Fill(Jet_vector.at(3).Phi(), eventWeight);
if(Jet_vector.size()>4 and eventWeight > 0.0) h_jet_phi_5th->Fill(Jet_vector.at(4).Phi(), eventWeight);
if(Jet_vector.size()>5 and eventWeight > 0.0) h_jet_phi_6th->Fill(Jet_vector.at(5).Phi(), eventWeight);
if(Jet_vector.size()>0 and eventWeight > 0.0) h_jet_energy_leading->Fill(Jet_vector.at(0).E(), eventWeight);
if(Jet_vector.size()>1 and eventWeight > 0.0) h_jet_energy_trailing->Fill(Jet_vector.at(1).E(), eventWeight);
if(Jet_vector.size()>2 and eventWeight > 0.0) h_jet_energy_3rd->Fill(Jet_vector.at(2).E(), eventWeight);
if(Jet_vector.size()>3 and eventWeight > 0.0) h_jet_energy_4th->Fill(Jet_vector.at(3).E(), eventWeight);
if(Jet_vector.size()>4 and eventWeight > 0.0) h_jet_energy_5th->Fill(Jet_vector.at(4).E(), eventWeight);
if(Jet_vector.size()>5 and eventWeight > 0.0) h_jet_energy_6th->Fill(Jet_vector.at(5).E(), eventWeight);
if(eventWeight > 0.0) h_nJets->Fill(Jet_vector.size(), eventWeight);
if(eventWeight > 0.0) h_HT->Fill(HT, eventWeight);
}
if(channel=="ElMu" and emu_event==1 and mumu_event==0){
if (ph1_p4.Pt()>30.0 and photons.at(0).isTight==1 and photons.at(0).phIsoTight==1 and eventWeight > 0.0){
h_photon_pt->Fill(ph1_p4.Pt(), eventWeight);
h_photon_eta->Fill(ph1_p4.Eta(), eventWeight);
h_photon_phi->Fill(ph1_p4.Phi(), eventWeight);
h_photon_energy->Fill(ph1_p4.E(), eventWeight);
if(Jet_vector.size()>0) h_Jet1Pt_PhPt->Fill(Jet_vector.at(0).Pt(), ph1_p4.Pt(), eventWeight);
}
if(eventWeight > 0.0) h_MET->Fill(MET, eventWeight);
if(eventWeight > 0.0) h_nVertices->Fill(nVertices, eventWeight);
if(eventWeight > 0.0) h_nPUVertices->Fill(nPUVertices, eventWeight);
if(eventWeight > 0.0) h_nPUVerticesTrue->Fill(nPUVerticesTrue, eventWeight);
if(Jet_vector.size()>0 and eventWeight > 0.0) h_jet_pt_leading->Fill(Jet_vector.at(0).Pt(), eventWeight);
if(Jet_vector.size()>1 and eventWeight > 0.0) h_jet_pt_trailing->Fill(Jet_vector.at(1).Pt(), eventWeight);
if(Jet_vector.size()>2 and eventWeight > 0.0) h_jet_pt_3rd->Fill(Jet_vector.at(2).Pt(), eventWeight);
if(Jet_vector.size()>3 and eventWeight > 0.0) h_jet_pt_4th->Fill(Jet_vector.at(3).Pt(), eventWeight);
if(Jet_vector.size()>4 and eventWeight > 0.0) h_jet_pt_5th->Fill(Jet_vector.at(4).Pt(), eventWeight);
if(Jet_vector.size()>5 and eventWeight > 0.0) h_jet_pt_6th->Fill(Jet_vector.at(5).Pt(), eventWeight);
if(Jet_vector.size()>0 and eventWeight > 0.0) h_jet_eta_leading->Fill(Jet_vector.at(0).Eta(), eventWeight);
if(Jet_vector.size()>1 and eventWeight > 0.0) h_jet_eta_trailing->Fill(Jet_vector.at(1).Eta(), eventWeight);
if(Jet_vector.size()>2 and eventWeight > 0.0) h_jet_eta_3rd->Fill(Jet_vector.at(2).Eta(), eventWeight);
if(Jet_vector.size()>3 and eventWeight > 0.0) h_jet_eta_4th->Fill(Jet_vector.at(3).Eta(), eventWeight);
if(Jet_vector.size()>4 and eventWeight > 0.0) h_jet_eta_5th->Fill(Jet_vector.at(4).Eta(), eventWeight);
if(Jet_vector.size()>5 and eventWeight > 0.0) h_jet_eta_6th->Fill(Jet_vector.at(5).Eta(), eventWeight);
if(Jet_vector.size()>0 and eventWeight > 0.0) h_jet_phi_leading->Fill(Jet_vector.at(0).Phi(), eventWeight);
if(Jet_vector.size()>1 and eventWeight > 0.0) h_jet_phi_trailing->Fill(Jet_vector.at(1).Phi(), eventWeight);
if(Jet_vector.size()>2 and eventWeight > 0.0) h_jet_phi_3rd->Fill(Jet_vector.at(2).Phi(), eventWeight);
if(Jet_vector.size()>3 and eventWeight > 0.0) h_jet_phi_4th->Fill(Jet_vector.at(3).Phi(), eventWeight);
if(Jet_vector.size()>4 and eventWeight > 0.0) h_jet_phi_5th->Fill(Jet_vector.at(4).Phi(), eventWeight);
if(Jet_vector.size()>5 and eventWeight > 0.0) h_jet_phi_6th->Fill(Jet_vector.at(5).Phi(), eventWeight);
if(Jet_vector.size()>0 and eventWeight > 0.0) h_jet_energy_leading->Fill(Jet_vector.at(0).E(), eventWeight);
if(Jet_vector.size()>1 and eventWeight > 0.0) h_jet_energy_trailing->Fill(Jet_vector.at(1).E(), eventWeight);
if(Jet_vector.size()>2 and eventWeight > 0.0) h_jet_energy_3rd->Fill(Jet_vector.at(2).E(), eventWeight);
if(Jet_vector.size()>3 and eventWeight > 0.0) h_jet_energy_4th->Fill(Jet_vector.at(3).E(), eventWeight);
if(Jet_vector.size()>4 and eventWeight > 0.0) h_jet_energy_5th->Fill(Jet_vector.at(4).E(), eventWeight);
if(Jet_vector.size()>5 and eventWeight > 0.0) h_jet_energy_6th->Fill(Jet_vector.at(5).E(), eventWeight);
if(eventWeight > 0.0) h_nJets->Fill(Jet_vector.size(), eventWeight);
if(eventWeight > 0.0) h_HT->Fill(HT, eventWeight);
}
}//event loop closed
//Cut flow table
cout << "mumu = " << mumu << endl;
cout << "emu = " << emu << endl;
cout << "Ztt_events_mumu = " << Ztt_events_mumu << endl;
cout << "Ztt_events_emu = " << Ztt_events_emu << endl;
cout << "Wt_events_mumu = " << Wt_events_mumu << endl;
cout << "Wt_events_emu = " << Wt_events_emu << endl;
cout << "MET_emu = " << MET_emu << endl;
cout << "MET_mumu = " << MET_mumu << endl;
cout << "Ztt_events_LowHT_mumu = " << Ztt_events_LowHT_mumu << endl;
cout << "Ztt_events_LowHT_emu = " << Ztt_events_LowHT_emu << endl;
cout << "LowHT_mumu = " << LowHT_mumu << endl;
cout << "LowHT_emu = " << LowHT_emu << endl;
cout << "Z_peakGammaEvents = " << Z_peakGammaEvents << endl;
std::string histfilename=(outfile+".root").c_str();
TFile *tFile=new TFile(histfilename.c_str(), "RECREATE");
h_nJets->Write();
h_jet_pt_leading->Write();
h_jet_pt_trailing->Write();
h_jet_pt_3rd->Write();
h_jet_pt_4th->Write();
h_jet_pt_5th->Write();
h_jet_pt_6th->Write();
h_jet_eta_leading->Write();
h_jet_eta_trailing->Write();
h_jet_eta_3rd->Write();
h_jet_eta_4th->Write();
h_jet_eta_5th->Write();
h_jet_eta_6th->Write();
h_jet_phi_leading->Write();
h_jet_phi_trailing->Write();
h_jet_phi_3rd->Write();
h_jet_phi_4th->Write();
h_jet_phi_5th->Write();
h_jet_phi_6th->Write();
h_jet_energy_leading->Write();
h_jet_energy_trailing->Write();
h_jet_energy_3rd->Write();
h_jet_energy_4th->Write();
h_jet_energy_5th->Write();
h_jet_energy_6th->Write();
h_HT->Write();
h_nVertices->Write();
h_nPUVertices->Write();
h_nPUVerticesTrue->Write();
h_cMt_Mu->Write();
h_Mt_Mu->Write();
h_MET->Write();
h_mu_pt_leading->Write();
h_mu_pt_trailing->Write();
h_mu_eta_leading->Write();
h_mu_eta_trailing->Write();
h_mu_phi_leading->Write();
h_mu_phi_trailing->Write();
h_mu_energy_leading->Write();
h_mu_energy_trailing->Write();
h_el_pt_leading->Write();
h_el_pt_trailing->Write();
h_el_eta_leading->Write();
h_el_eta_trailing->Write();
h_el_phi_leading->Write();
h_el_phi_trailing->Write();
h_el_energy_leading->Write();
h_el_energy_trailing->Write();
h_photon_pt->Write();
h_photon_eta->Write();
h_photon_phi->Write();
h_photon_energy->Write();
h_InvariantMass_Mu->Write();
h_InvariantMass_El->Write();
h_InvariantMass_ElPh->Write();
h_InvariantMass_MuPh->Write();
h_InvariantMass_ElMu->Write();
h_Mmumu_MmumuGamma->Write();
h_Jet1Pt_PhPt->Write();
h_HT->Write();
tFile->Close();
std::cout<<"Wrote output file "<<histfilename<<std::endl;
return 0;
}