Пример #1
0
void selectAntiWm(const TString conf="wm.conf", // input file
              const TString outputDir="."       // output directory
) {
  gBenchmark->Start("selectAntiWm");

  //--------------------------------------------------------------------------------------------------------------
  // Settings 
  //============================================================================================================== 

  const Double_t PT_CUT    = 25;
  const Double_t ETA_CUT   = 2.4;
  const Double_t MUON_MASS = 0.105658369;

  const Double_t VETO_PT   = 10;
  const Double_t VETO_ETA  = 2.4;

  const Int_t BOSON_ID  = 24;
  const Int_t LEPTON_ID = 13;

  // load trigger menu
  const baconhep::TTrigger triggerMenu("../../BaconAna/DataFormats/data/HLT_50nsGRun");

  // load pileup reweighting file
  TFile *f_rw = TFile::Open("../Tools/pileup_weights_2015B.root", "read");
  TH1D *h_rw = (TH1D*) f_rw->Get("npv_rw");

  //--------------------------------------------------------------------------------------------------------------
  // Main analysis code 
  //==============================================================================================================  

  vector<TString>  snamev;      // sample name (for output files)  
  vector<CSample*> samplev;     // data/MC samples

  //
  // parse .conf file
  //
  confParse(conf, snamev, samplev);
  const Bool_t hasData = (samplev[0]->fnamev.size()>0);

  // Create output directory
  gSystem->mkdir(outputDir,kTRUE);
  const TString ntupDir = outputDir + TString("/ntuples");
  gSystem->mkdir(ntupDir,kTRUE);
  
  //
  // Declare output ntuple variables
  //
  UInt_t  runNum, lumiSec, evtNum;
  UInt_t  npv, npu;
  UInt_t  id_1, id_2;
  Double_t x_1, x_2, xPDF_1, xPDF_2;
  Double_t scalePDF, weightPDF;
  TLorentzVector *genV=0, *genLep=0;
  Float_t genVPt, genVPhi, genVy, genVMass;
  Float_t genLepPt, genLepPhi;
  Float_t scale1fb, puWeight;
  Float_t met, metPhi, sumEt, mt, u1, u2;
  Float_t tkMet, tkMetPhi, tkSumEt, tkMt, tkU1, tkU2;
  Float_t mvaMet, mvaMetPhi, mvaSumEt, mvaMt, mvaU1, mvaU2;
  Int_t   q;
  TLorentzVector *lep=0;
  ///// muon specific /////
  Float_t trkIso, emIso, hadIso;
  Float_t pfChIso, pfGamIso, pfNeuIso, pfCombIso;
  Float_t d0, dz;
  Float_t muNchi2;
  UInt_t nPixHits, nTkLayers, nValidHits, nMatch, typeBits;
  
  // Data structures to store info from TTrees
  baconhep::TEventInfo *info  = new baconhep::TEventInfo();
  baconhep::TGenEventInfo *gen  = new baconhep::TGenEventInfo();
  TClonesArray *genPartArr = new TClonesArray("baconhep::TGenParticle");
  TClonesArray *muonArr    = new TClonesArray("baconhep::TMuon");
  TClonesArray *vertexArr  = new TClonesArray("baconhep::TVertex");
  
  TFile *infile=0;
  TTree *eventTree=0;
  
  //
  // loop over samples
  //  
  for(UInt_t isam=0; isam<samplev.size(); isam++) {
    
    // Assume data sample is first sample in .conf file
    // If sample is empty (i.e. contains no ntuple files), skip to next sample
    Bool_t isData=kFALSE;
    if(isam==0 && !hasData) continue;
    else if (isam==0) isData=kTRUE;
    
    // Assume signal sample is given name "wm"
    Bool_t isSignal = (snamev[isam].CompareTo("wm",TString::kIgnoreCase)==0);
    // flag to reject W->mnu events when selecting wrong-flavor background events
    Bool_t isWrongFlavor = (snamev[isam].CompareTo("wx",TString::kIgnoreCase)==0);  
    
    CSample* samp = samplev[isam];
  
    //
    // Set up output ntuple
    //
    TString outfilename = ntupDir + TString("/") + snamev[isam] + TString("_select.root");
    TFile *outFile = new TFile(outfilename,"RECREATE"); 
    TTree *outTree = new TTree("Events","Events");

    outTree->Branch("runNum",     &runNum,     "runNum/i");     // event run number
    outTree->Branch("lumiSec",    &lumiSec,    "lumiSec/i");    // event lumi section
    outTree->Branch("evtNum",     &evtNum,     "evtNum/i");     // event number
    outTree->Branch("npv",        &npv,        "npv/i");        // number of primary vertices
    outTree->Branch("npu",        &npu,        "npu/i");        // number of in-time PU events (MC)
    outTree->Branch("id_1",       &id_1,       "id_1/i");       // PDF info -- parton ID for parton 1
    outTree->Branch("id_2",       &id_2,       "id_2/i");       // PDF info -- parton ID for parton 2
    outTree->Branch("x_1",        &x_1,        "x_1/d");        // PDF info -- x for parton 1
    outTree->Branch("x_2",        &x_2,        "x_2/d");        // PDF info -- x for parton 2
    outTree->Branch("xPDF_1",     &xPDF_1,     "xPDF_1/d");     // PDF info -- x*F for parton 1
    outTree->Branch("xPDF_2",     &xPDF_2,     "xPDF_2/d");     // PDF info -- x*F for parton 2
    outTree->Branch("scalePDF",   &scalePDF,   "scalePDF/d");   // PDF info -- energy scale of parton interaction
    outTree->Branch("weightPDF",  &weightPDF,  "weightPDF/d");  // PDF info -- PDF weight
    outTree->Branch("genV",       "TLorentzVector", &genV);     // GEN boson 4-vector (signal MC)
    outTree->Branch("genLep",     "TLorentzVector", &genLep);   // GEN lepton 4-vector (signal MC)
    outTree->Branch("genVPt",     &genVPt,     "genVPt/F");     // GEN boson pT (signal MC)
    outTree->Branch("genVPhi",    &genVPhi,    "genVPhi/F");    // GEN boson phi (signal MC)
    outTree->Branch("genVy",      &genVy,      "genVy/F");      // GEN boson rapidity (signal MC)
    outTree->Branch("genVMass",   &genVMass,   "genVMass/F");   // GEN boson mass (signal MC)
    outTree->Branch("genLepPt",   &genLepPt,   "genLepPt/F");   // GEN lepton pT (signal MC)
    outTree->Branch("genLepPhi",  &genLepPhi,  "genLepPhi/F");  // GEN lepton phi (signal MC)
    outTree->Branch("scale1fb",   &scale1fb,   "scale1fb/F");   // event weight per 1/fb (MC)
    outTree->Branch("puWeight",   &puWeight,   "puWeight/F");    // scale factor for pileup reweighting (MC)
    outTree->Branch("met",        &met,        "met/F");        // MET
    outTree->Branch("metPhi",     &metPhi,     "metPhi/F");     // phi(MET)
    outTree->Branch("sumEt",      &sumEt,      "sumEt/F");      // Sum ET
    outTree->Branch("mt",         &mt,         "mt/F");         // transverse mass
    outTree->Branch("u1",         &u1,         "u1/F");         // parallel component of recoil
    outTree->Branch("u2",         &u2,         "u2/F");         // perpendicular component of recoil
    outTree->Branch("tkMet",      &tkMet,      "tkMet/F");      // MET (track MET)
    outTree->Branch("tkMetPhi",   &tkMetPhi,   "tkMetPhi/F");   // phi(MET) (track MET)
    outTree->Branch("tkSumEt",    &tkSumEt,    "tkSumEt/F");    // Sum ET (track MET)
    outTree->Branch("tkMt",       &tkMt,       "tkMt/F");       // transverse mass (track MET)
    outTree->Branch("tkU1",       &tkU1,       "tkU1/F");       // parallel component of recoil (track MET)
    outTree->Branch("tkU2",       &tkU2,       "tkU2/F");       // perpendicular component of recoil (track MET)
    outTree->Branch("mvaMet",     &mvaMet,     "mvaMet/F");     // MVA MET
    outTree->Branch("mvaMetPhi",  &mvaMetPhi,  "mvaMetPhi/F");  // phi(MVA MET)
    outTree->Branch("mvaSumEt",   &mvaSumEt,   "mvaSumEt/F");   // Sum ET (MVA MET)
    outTree->Branch("mvaMt",      &mvaMt,      "mvaMt/F");      // transverse mass (MVA MET)
    outTree->Branch("mvaU1",      &mvaU1,      "mvaU1/F");      // parallel component of recoil (mva MET)
    outTree->Branch("mvaU2",      &mvaU2,      "mvaU2/F");      // perpendicular component of recoil (mva MET)
    outTree->Branch("q",          &q,          "q/I");          // lepton charge
    outTree->Branch("lep",        "TLorentzVector", &lep);      // lepton 4-vector
    ///// muon specific /////
    outTree->Branch("trkIso",     &trkIso,     "trkIso/F");     // track isolation of lepton
    outTree->Branch("emIso",      &emIso,      "emIso/F");      // ECAL isolation of lepton
    outTree->Branch("hadIso",     &hadIso,     "hadIso/F");     // HCAL isolation of lepton
    outTree->Branch("pfChIso",    &pfChIso,    "pfChIso/F");    // PF charged hadron isolation of lepton
    outTree->Branch("pfGamIso",   &pfGamIso,   "pfGamIso/F");   // PF photon isolation of lepton
    outTree->Branch("pfNeuIso",   &pfNeuIso,   "pfNeuIso/F");   // PF neutral hadron isolation of lepton
    outTree->Branch("pfCombIso",  &pfCombIso,  "pfCombIso/F");  // PF combined isolation of lepton
    outTree->Branch("d0",         &d0,         "d0/F");         // transverse impact parameter of lepton
    outTree->Branch("dz",         &dz,         "dz/F");         // longitudinal impact parameter of lepton
    outTree->Branch("muNchi2",    &muNchi2,    "muNchi2/F");    // muon fit normalized chi^2 of lepton
    outTree->Branch("nPixHits",   &nPixHits,   "nPixHits/i");   // number of pixel hits of muon
    outTree->Branch("nTkLayers",  &nTkLayers,  "nTkLayers/i");  // number of tracker layers of muon
    outTree->Branch("nMatch",     &nMatch,     "nMatch/i");     // number of matched segments of muon	 
    outTree->Branch("nValidHits", &nValidHits, "nValidHits/i"); // number of valid muon hits of muon 
    outTree->Branch("typeBits",   &typeBits,   "typeBits/i");   // number of valid muon hits of muon 
    
    //
    // loop through files
    //
    const UInt_t nfiles = samp->fnamev.size();
    for(UInt_t ifile=0; ifile<nfiles; ifile++) {  

      // Read input file and get the TTrees
      cout << "Processing " << samp->fnamev[ifile] << " [xsec = " << samp->xsecv[ifile] << " pb] ... "; cout.flush();
      infile = TFile::Open(samp->fnamev[ifile]); 
      assert(infile);
      
      Bool_t hasJSON = kFALSE;
      baconhep::RunLumiRangeMap rlrm;
      if(samp->jsonv[ifile].CompareTo("NONE")!=0) { 
	hasJSON = kTRUE;
	rlrm.addJSONFile(samp->jsonv[ifile].Data()); 
      }

      eventTree = (TTree*)infile->Get("Events");
      assert(eventTree);
      eventTree->SetBranchAddress("Info", &info);    TBranch *infoBr = eventTree->GetBranch("Info");
      eventTree->SetBranchAddress("Muon", &muonArr); TBranch *muonBr = eventTree->GetBranch("Muon");
      eventTree->SetBranchAddress("PV",   &vertexArr); TBranch *vertexBr = eventTree->GetBranch("PV");
      Bool_t hasGen = eventTree->GetBranchStatus("GenEvtInfo");
      TBranch *genBr=0, *genPartBr=0;
      if(hasGen) {
        eventTree->SetBranchAddress("GenEvtInfo", &gen); genBr = eventTree->GetBranch("GenEvtInfo");
        eventTree->SetBranchAddress("GenParticle",&genPartArr); genPartBr = eventTree->GetBranch("GenParticle");
      }
    
      // Compute MC event weight per 1/fb
      const Double_t xsec = samp->xsecv[ifile];
      Double_t totalWeight=0;

      if (hasGen) {
	TH1D *hall = new TH1D("hall", "", 1,0,1);
	eventTree->Draw("0.5>>hall", "GenEvtInfo->weight");
	totalWeight=hall->Integral();
	delete hall;
	hall=0;
      }

      //
      // loop over events
      //
      Double_t nsel=0, nselvar=0;
      for(UInt_t ientry=0; ientry<eventTree->GetEntries(); ientry++) {
        infoBr->GetEntry(ientry);

	if(ientry%1000000==0) cout << "Processing event " << ientry << ". " << (double)ientry/(double)eventTree->GetEntries()*100 << " percent done with this file." << endl;

        Double_t weight=1;
        if(xsec>0 && totalWeight>0) weight = xsec/totalWeight;
	if(hasGen) {
          genPartArr->Clear();
          genBr->GetEntry(ientry);
          genPartBr->GetEntry(ientry);
	  weight*=gen->weight;
        }

        // veto w -> xv decays for signal and w -> mv for bacground samples (needed for inclusive WToLNu sample)
        if (isWrongFlavor && hasGen && fabs(toolbox::flavor(genPartArr, BOSON_ID))==LEPTON_ID) continue;
	else if (isSignal && hasGen && fabs(toolbox::flavor(genPartArr, BOSON_ID))!=LEPTON_ID) continue;
        
	// check for certified lumi (if applicable)
        baconhep::RunLumiRangeMap::RunLumiPairType rl(info->runNum, info->lumiSec);      
        if(hasJSON && !rlrm.hasRunLumi(rl)) continue;  

        // trigger requirement               
	if (!isMuonTrigger(triggerMenu, info->triggerBits)) continue;
      
        // good vertex requirement
        if(!(info->hasGoodPV)) continue;

        //
	// SELECTION PROCEDURE:
	//  (1) Look for 1 good muon matched to trigger
	//  (2) Reject event if another muon is present passing looser cuts
	//
	muonArr->Clear();
        muonBr->GetEntry(ientry);

	Int_t nLooseLep=0;
	const baconhep::TMuon *goodMuon=0;
	Bool_t passSel=kFALSE;

        for(Int_t i=0; i<muonArr->GetEntriesFast(); i++) {
          const baconhep::TMuon *mu = (baconhep::TMuon*)((*muonArr)[i]);

          if(fabs(mu->eta) > VETO_PT)  continue; // loose lepton |eta| cut
          if(mu->pt        < VETO_ETA) continue; // loose lepton pT cut
//          if(passMuonLooseID(mu)) nLooseLep++; // loose lepton selection
          if(nLooseLep>1) {  // extra lepton veto
            passSel=kFALSE;
            break;
          }
          
          if(fabs(mu->eta) > ETA_CUT)         continue; // lepton |eta| cut
          if(mu->pt < PT_CUT)                 continue; // lepton pT cut   
          if(!passAntiMuonID(mu))             continue; // lepton anti-selection
          if(!isMuonTriggerObj(triggerMenu, mu->hltMatchBits, kFALSE)) continue;
	  
	  passSel=kTRUE;
	  goodMuon = mu;
	}

	if(passSel) {	  
	  /******** We have a W candidate! HURRAY! ********/
	  nsel+=weight;
          nselvar+=weight*weight;
	  
	  TLorentzVector vLep; 
	  vLep.SetPtEtaPhiM(goodMuon->pt, goodMuon->eta, goodMuon->phi, MUON_MASS);

	  //
	  // Fill tree
	  //
	  runNum   = info->runNum;
	  lumiSec  = info->lumiSec;
	  evtNum   = info->evtNum;
	  
	  vertexArr->Clear();
	  vertexBr->GetEntry(ientry);

	  npv      = vertexArr->GetEntries();
	  npu	   = info->nPUmean;
	  genV      = new TLorentzVector(0,0,0,0);
          genLep    = new TLorentzVector(0,0,0,0);
	  genVPt    = -999;
          genVPhi   = -999;
          genVy     = -999;
          genVMass  = -999;
          u1        = -999;
          u2        = -999;
          tkU1      = -999;
          tkU2      = -999;
	  mvaU1     = -999;
          mvaU2     = -999;
          id_1      = -999;
          id_2      = -999;
          x_1       = -999;
          x_2       = -999;
          xPDF_1    = -999;
          xPDF_2    = -999;
          scalePDF  = -999;
          weightPDF = -999;

	  if(isSignal && hasGen) {
	    TLorentzVector *gvec=new TLorentzVector(0,0,0,0);
            TLorentzVector *glep1=new TLorentzVector(0,0,0,0);
            TLorentzVector *glep2=new TLorentzVector(0,0,0,0);
	    toolbox::fillGen(genPartArr, BOSON_ID, gvec, glep1, glep2,1);

            if (gvec && glep1) {
	      genV      = new TLorentzVector(0,0,0,0);
              genV->SetPtEtaPhiM(gvec->Pt(),gvec->Eta(),gvec->Phi(),gvec->M());
              genLep    = new TLorentzVector(0,0,0,0);
              genLep->SetPtEtaPhiM(glep1->Pt(),glep1->Eta(),glep1->Phi(),glep1->M());
              genVPt    = gvec->Pt();
              genVPhi   = gvec->Phi();
              genVy     = gvec->Rapidity();
              genVMass  = gvec->M();
              genLepPt  = glep1->Pt();
              genLepPhi = glep1->Phi();

	      TVector2 vWPt((genVPt)*cos(genVPhi),(genVPt)*sin(genVPhi));
	      TVector2 vLepPt(vLep.Px(),vLep.Py());
	      
	      TVector2 vMet((info->pfMETC)*cos(info->pfMETCphi), (info->pfMETC)*sin(info->pfMETCphi));
	      TVector2 vU = -1.0*(vMet+vLepPt);
	      u1 = ((vWPt.Px())*(vU.Px()) + (vWPt.Py())*(vU.Py()))/(genVPt);  // u1 = (pT . u)/|pT|
	      u2 = ((vWPt.Px())*(vU.Py()) - (vWPt.Py())*(vU.Px()))/(genVPt);  // u2 = (pT x u)/|pT|

	      TVector2 vTkMet((info->trkMET)*cos(info->trkMETphi), (info->trkMET)*sin(info->trkMETphi));
	      TVector2 vTkU = -1.0*(vTkMet+vLepPt);
	      tkU1 = ((vWPt.Px())*(vTkU.Px()) + (vWPt.Py())*(vTkU.Py()))/(genVPt);  // u1 = (pT . u)/|pT|
	      tkU2 = ((vWPt.Px())*(vTkU.Py()) - (vWPt.Py())*(vTkU.Px()))/(genVPt);  // u2 = (pT x u)/|pT|
	      
	      TVector2 vMvaMet((info->mvaMET)*cos(info->mvaMETphi), (info->mvaMET)*sin(info->mvaMETphi));
	      TVector2 vMvaU = -1.0*(vMvaMet+vLepPt);
	      mvaU1 = ((vWPt.Px())*(vMvaU.Px()) + (vWPt.Py())*(vMvaU.Py()))/(genVPt);  // u1 = (pT . u)/|pT|
	      mvaU2 = ((vWPt.Px())*(vMvaU.Py()) - (vWPt.Py())*(vMvaU.Px()))/(genVPt);  // u2 = (pT x u)/|pT|
          
            }
	    id_1      = gen->id_1;
            id_2      = gen->id_2;
            x_1       = gen->x_1;
            x_2       = gen->x_2;
            xPDF_1    = gen->xPDF_1;
            xPDF_2    = gen->xPDF_2;
            scalePDF  = gen->scalePDF;
            weightPDF = gen->weight;

	    delete gvec;
            delete glep1;
            delete glep2;
            gvec=0; glep1=0; glep2=0;
	  }
	  scale1fb = weight;
	  puWeight = h_rw->GetBinContent(info->nPUmean+1);
	  met	   = info->pfMETC;
	  metPhi   = info->pfMETCphi;
	  sumEt    = 0;
	  mt       = sqrt( 2.0 * (vLep.Pt()) * (info->pfMETC) * (1.0-cos(toolbox::deltaPhi(vLep.Phi(),info->pfMETCphi))) );
	  tkMet    = info->trkMET;
          tkMetPhi = info->trkMETphi;
          tkSumEt  = 0;
          tkMt     = sqrt( 2.0 * (vLep.Pt()) * (info->trkMET) * (1.0-cos(toolbox::deltaPhi(vLep.Phi(),info->trkMETphi))) );
	  mvaMet   = info->mvaMET;
          mvaMetPhi = info->mvaMETphi;
          mvaSumEt  = 0;
          mvaMt     = sqrt( 2.0 * (vLep.Pt()) * (info->mvaMET) * (1.0-cos(toolbox::deltaPhi(vLep.Phi(),info->mvaMETphi))) );
	  q        = goodMuon->q;
	  lep      = &vLep;
	  
	  ///// muon specific /////
	  trkIso     = goodMuon->trkIso;
          emIso      = goodMuon->ecalIso;
          hadIso     = goodMuon->hcalIso;
          pfChIso    = goodMuon->chHadIso;
          pfGamIso   = goodMuon->gammaIso;
          pfNeuIso   = goodMuon->neuHadIso;
          pfCombIso  = goodMuon->chHadIso + TMath::Max(goodMuon->neuHadIso + goodMuon->gammaIso -
						       0.5*(goodMuon->puIso),Double_t(0));
	  d0         = goodMuon->d0;
	  dz         = goodMuon->dz;
	  muNchi2    = goodMuon->muNchi2;
	  nPixHits   = goodMuon->nPixHits;
	  nTkLayers  = goodMuon->nTkLayers;
	  nMatch     = goodMuon->nMatchStn;
	  nValidHits = goodMuon->nValidHits;
	  typeBits   = goodMuon->typeBits;

	  outTree->Fill();
	  delete genV;
	  delete genLep;
	  genV=0, genLep=0, lep=0;
        }
      }
      delete infile;
      infile=0, eventTree=0;    

      cout << nsel  << " +/- " << sqrt(nselvar);
      if(isam!=0) cout << " per 1/fb";
      cout << endl;
    }
    outFile->Write();
    outFile->Close();
  }
  delete h_rw;
  delete f_rw;
  delete info;
  delete gen;
  delete genPartArr;
  delete muonArr;
  delete vertexArr;
      
  //--------------------------------------------------------------------------------------------------------------
  // Output
  //==============================================================================================================
   
  cout << "*" << endl;
  cout << "* SUMMARY" << endl;
  cout << "*--------------------------------------------------" << endl;
  cout << " W -> mu nu" << endl;
  cout << "  pT > " << PT_CUT << endl;
  cout << "  |eta| < " << ETA_CUT << endl;
  cout << endl;
  
  cout << endl;
  cout << "  <> Output saved in " << outputDir << "/" << endl;    
  cout << endl;  
      
  gBenchmark->Show("selectAntiWm"); 
}
Пример #2
0
void selectWe(const TString conf="we.conf", // input file
              const TString outputDir=".",  // output directory
              const Bool_t  doScaleCorr=0   // apply energy scale corrections?
             ) {
    gBenchmark->Start("selectWe");

    //--------------------------------------------------------------------------------------------------------------
    // Settings
    //==============================================================================================================

    const Double_t PT_CUT   = 25;
    const Double_t ETA_CUT  = 2.5;
    const Double_t ELE_MASS = 0.000511;

    const Double_t VETO_PT   = 10;
    const Double_t VETO_ETA  = 2.5;

    const Double_t ECAL_GAP_LOW  = 1.4442;
    const Double_t ECAL_GAP_HIGH = 1.566;

    const Double_t escaleNbins  = 2;
    const Double_t escaleEta[]  = { 1.4442, 2.5   };
    const Double_t escaleCorr[] = { 0.992,  1.009 };

    const Int_t BOSON_ID  = 24;
    const Int_t LEPTON_ID = 11;

    // load trigger menu
    const baconhep::TTrigger triggerMenu("../../BaconAna/DataFormats/data/HLT_50nsGRun");

    // load pileup reweighting file
    TFile *f_rw = TFile::Open("../Tools/pileup_rw_Golden.root", "read");
    TH1D *h_rw = (TH1D*) f_rw->Get("h_rw_golden");
    TH1D *h_rw_up = (TH1D*) f_rw->Get("h_rw_up_golden");
    TH1D *h_rw_down = (TH1D*) f_rw->Get("h_rw_down_golden");

    //--------------------------------------------------------------------------------------------------------------
    // Main analysis code
    //==============================================================================================================

    vector<TString>  snamev;      // sample name (for output files)
    vector<CSample*> samplev;     // data/MC samples

    //
    // parse .conf file
    //
    confParse(conf, snamev, samplev);
    const Bool_t hasData = (samplev[0]->fnamev.size()>0);

    // Create output directory
    gSystem->mkdir(outputDir,kTRUE);
    const TString ntupDir = outputDir + TString("/ntuples");
    gSystem->mkdir(ntupDir,kTRUE);

    //
    // Declare output ntuple variables
    //
    UInt_t  runNum, lumiSec, evtNum;
    UInt_t  npv, npu;
    UInt_t  id_1, id_2;
    Double_t x_1, x_2, xPDF_1, xPDF_2;
    Double_t scalePDF, weightPDF;
    TLorentzVector *genV=0, *genLep=0;
    Float_t genVPt, genVPhi, genVy, genVMass;
    Float_t genLepPt, genLepPhi;
    Float_t scale1fb, puWeight, puWeightUp, puWeightDown;
    Float_t met, metPhi, sumEt, mt, u1, u2;
    Float_t tkMet, tkMetPhi, tkSumEt, tkMt, tkU1, tkU2;
    Float_t mvaMet, mvaMetPhi, mvaSumEt, mvaMt, mvaU1, mvaU2;
    Float_t puppiMet, puppiMetPhi, puppiSumEt, puppiMt, puppiU1, puppiU2;
    Int_t   q;
    TLorentzVector *lep=0;
    Int_t lepID;
    ///// electron specific /////
    Float_t trkIso, emIso, hadIso;
    Float_t pfChIso, pfGamIso, pfNeuIso, pfCombIso;
    Float_t sigieie, hovere, eoverp, fbrem, ecalE;
    Float_t dphi, deta;
    Float_t d0, dz;
    UInt_t  isConv, nexphits, typeBits;
    TLorentzVector *sc=0;

    // Data structures to store info from TTrees
    baconhep::TEventInfo *info   = new baconhep::TEventInfo();
    baconhep::TGenEventInfo *gen = new baconhep::TGenEventInfo();
    TClonesArray *genPartArr     = new TClonesArray("baconhep::TGenParticle");
    TClonesArray *electronArr    = new TClonesArray("baconhep::TElectron");
    TClonesArray *scArr          = new TClonesArray("baconhep::TPhoton");
    TClonesArray *vertexArr      = new TClonesArray("baconhep::TVertex");

    TFile *infile=0;
    TTree *eventTree=0;

    //
    // loop over samples
    //
    for(UInt_t isam=0; isam<samplev.size(); isam++) {

        // Assume data sample is first sample in .conf file
        // If sample is empty (i.e. contains no ntuple files), skip to next sample
        Bool_t isData=kFALSE;
        if(isam==0 && !hasData) continue;
        else if (isam==0) isData=kTRUE;

        // Assume signal sample is given name "we" -- flag to store GEN W kinematics
        Bool_t isSignal = (snamev[isam].CompareTo("we",TString::kIgnoreCase)==0);
        // flag to reject W->enu events when selecting at wrong-flavor background events
        Bool_t isWrongFlavor = (snamev[isam].CompareTo("wx",TString::kIgnoreCase)==0);

        CSample* samp = samplev[isam];

        //
        // Set up output ntuple
        //
        TString outfilename = ntupDir + TString("/") + snamev[isam] + TString("_select.root");
        if(isam!=0 && !doScaleCorr) outfilename = ntupDir + TString("/") + snamev[isam] + TString("_select.raw.root");
        TFile *outFile = new TFile(outfilename,"RECREATE");
        TTree *outTree = new TTree("Events","Events");

        outTree->Branch("runNum",     &runNum,     "runNum/i");      // event run number
        outTree->Branch("lumiSec",    &lumiSec,    "lumiSec/i");     // event lumi section
        outTree->Branch("evtNum",     &evtNum,     "evtNum/i");      // event number
        outTree->Branch("npv",        &npv,        "npv/i");         // number of primary vertices
        outTree->Branch("npu",        &npu,        "npu/i");         // number of in-time PU events (MC)
        outTree->Branch("id_1",       &id_1,       "id_1/i");        // PDF info -- parton ID for parton 1
        outTree->Branch("id_2",       &id_2,       "id_2/i");        // PDF info -- parton ID for parton 2
        outTree->Branch("x_1",        &x_1,        "x_1/d");         // PDF info -- x for parton 1
        outTree->Branch("x_2",        &x_2,        "x_2/d");         // PDF info -- x for parton 2
        outTree->Branch("xPDF_1",     &xPDF_1,     "xPDF_1/d");      // PDF info -- x*F for parton 1
        outTree->Branch("xPDF_2",     &xPDF_2,     "xPDF_2/d");      // PDF info -- x*F for parton 2
        outTree->Branch("scalePDF",   &scalePDF,   "scalePDF/d");    // PDF info -- energy scale of parton interaction
        outTree->Branch("weightPDF",  &weightPDF,  "weightPDF/d");   // PDF info -- PDF weight
        outTree->Branch("genV",      "TLorentzVector", &genV);       // GEN boson 4-vector (signal MC)
        outTree->Branch("genLep",    "TLorentzVector", &genLep);     // GEN lepton 4-vector (signal MC)
        outTree->Branch("genVPt",     &genVPt,     "genVPt/F");      // GEN boson pT (signal MC)
        outTree->Branch("genVPhi",    &genVPhi,    "genVPhi/F");     // GEN boson phi (signal MC)
        outTree->Branch("genVy",      &genVy,      "genVy/F");       // GEN boson rapidity (signal MC)
        outTree->Branch("genVMass",   &genVMass,   "genVMass/F");    // GEN boson mass (signal MC)
        outTree->Branch("genLepPt",   &genLepPt,   "genLepPt/F");    // GEN lepton pT (signal MC)
        outTree->Branch("genLepPhi",  &genLepPhi,  "genLepPhi/F");   // GEN lepton phi (signal MC)
        outTree->Branch("scale1fb",   &scale1fb,   "scale1fb/F");    // event weight per 1/fb (MC)
        outTree->Branch("puWeight",   &puWeight,   "puWeight/F");    // scale factor for pileup reweighting (MC)
        outTree->Branch("puWeightUp",    &puWeightUp,   "puWeightUp/F");    // scale factor for pileup reweighting (MC)
        outTree->Branch("puWeightDown",    &puWeightDown,   "puWeightDown/F");    // scale factor for pileup reweighting (MC)
        outTree->Branch("met",        &met,        "met/F");         // MET
        outTree->Branch("metPhi",     &metPhi,     "metPhi/F");      // phi(MET)
        outTree->Branch("sumEt",      &sumEt,      "sumEt/F");       // Sum ET
        outTree->Branch("mt",         &mt,         "mt/F");          // transverse mass
        outTree->Branch("u1",         &u1,         "u1/F");          // parallel component of recoil
        outTree->Branch("u2",         &u2,         "u2/F");          // perpendicular component of recoil
        outTree->Branch("tkMet",      &tkMet,      "tkMet/F");       // MET (track MET)
        outTree->Branch("tkMetPhi",   &tkMetPhi,   "tkMetPhi/F");    // phi(MET) (track MET)
        outTree->Branch("tkSumEt",    &tkSumEt,    "tkSumEt/F");     // Sum ET (track MET)
        outTree->Branch("tkMt",       &tkMt,       "tkMt/F");        // transverse mass (track MET)
        outTree->Branch("tkU1",       &tkU1,       "tkU1/F");        // parallel component of recoil (track MET)
        outTree->Branch("tkU2",       &tkU2,       "tkU2/F");        // perpendicular component of recoil (track MET)
        outTree->Branch("mvaMet",     &mvaMet,     "mvaMet/F");      // MVA MET
        outTree->Branch("mvaMetPhi",  &mvaMetPhi,  "mvaMetPhi/F");   // phi(MVA MET)
        outTree->Branch("mvaSumEt",   &mvaSumEt,   "mvaSumEt/F");    // Sum ET (mva MET)
        outTree->Branch("mvaMt",      &mvaMt,      "mvaMt/F");       // transverse mass (mva MET)
        outTree->Branch("mvaU1",      &mvaU1,      "mvaU1/F");       // parallel component of recoil (mva MET)
        outTree->Branch("mvaU2",      &mvaU2,      "mvaU2/F");       // perpendicular component of recoil (mva MET)
        outTree->Branch("puppiMet",    &puppiMet,   "puppiMet/F");      // Puppi MET
        outTree->Branch("puppiMetPhi", &puppiMetPhi,"puppiMetPhi/F");   // phi(Puppi MET)
        outTree->Branch("puppiSumEt",  &puppiSumEt, "puppiSumEt/F");    // Sum ET (Puppi MET)
        outTree->Branch("puppiU1",     &puppiU1,    "puppiU1/F");       // parallel component of recoil (Puppi MET)
        outTree->Branch("puppiU2",     &puppiU2,    "puppiU2/F");       // perpendicular component of recoil (Puppi MET)
        outTree->Branch("q",          &q,          "q/I");           // lepton charge
        outTree->Branch("lep",       "TLorentzVector", &lep);        // lepton 4-vector
        outTree->Branch("lepID",      &lepID,      "lepID/I");       // lepton PDG ID
        ///// electron specific /////
        outTree->Branch("trkIso",     &trkIso,     "trkIso/F");      // track isolation of tag lepton
        outTree->Branch("emIso",      &emIso,      "emIso/F");       // ECAL isolation of tag lepton
        outTree->Branch("hadIso",     &hadIso,     "hadIso/F");      // HCAL isolation of tag lepton
        outTree->Branch("pfChIso",    &pfChIso,    "pfChIso/F");     // PF charged hadron isolation of lepton
        outTree->Branch("pfGamIso",   &pfGamIso,   "pfGamIso/F");    // PF photon isolation of lepton
        outTree->Branch("pfNeuIso",   &pfNeuIso,   "pfNeuIso/F");    // PF neutral hadron isolation of lepton
        outTree->Branch("pfCombIso",  &pfCombIso,  "pfCombIso/F");   // PF combined isolation of electron
        outTree->Branch("sigieie",    &sigieie,    "sigieie/F");     // sigma-ieta-ieta of electron
        outTree->Branch("hovere",     &hovere,     "hovere/F");      // H/E of electron
        outTree->Branch("eoverp",     &eoverp,     "eoverp/F");      // E/p of electron
        outTree->Branch("fbrem",      &fbrem,      "fbrem/F");       // brem fraction of electron
        outTree->Branch("dphi",       &dphi,       "dphi/F");        // GSF track - ECAL dphi of electron
        outTree->Branch("deta",       &deta,       "deta/F");        // GSF track - ECAL deta of electron
        outTree->Branch("ecalE",      &ecalE,      "ecalE/F");       // ECAL energy of electron
        outTree->Branch("d0",         &d0,         "d0/F");          // transverse impact parameter of electron
        outTree->Branch("dz",         &dz,         "dz/F");          // longitudinal impact parameter of electron
        outTree->Branch("isConv",     &isConv,     "isConv/i");      // conversion filter flag of electron
        outTree->Branch("nexphits",   &nexphits,   "nexphits/i");    // number of missing expected inner hits of electron
        outTree->Branch("typeBits",   &typeBits,   "typeBits/i");    // electron type of electron
        outTree->Branch("sc",        "TLorentzVector", &sc);         // supercluster 4-vector

        //
        // loop through files
        //
        const UInt_t nfiles = samp->fnamev.size();
        for(UInt_t ifile=0; ifile<nfiles; ifile++) {

            // Read input file and get the TTrees
            cout << "Processing " << samp->fnamev[ifile] << " [xsec = " << samp->xsecv[ifile] << " pb] ... ";
            cout.flush();
            infile = TFile::Open(samp->fnamev[ifile]);
            assert(infile);

            Bool_t hasJSON = kFALSE;
            baconhep::RunLumiRangeMap rlrm;
            if(samp->jsonv[ifile].CompareTo("NONE")!=0) {
                hasJSON = kTRUE;
                rlrm.addJSONFile(samp->jsonv[ifile].Data());
            }

            eventTree = (TTree*)infile->Get("Events");
            assert(eventTree);
            eventTree->SetBranchAddress("Info",     &info);
            TBranch *infoBr     = eventTree->GetBranch("Info");
            eventTree->SetBranchAddress("Electron", &electronArr);
            TBranch *electronBr = eventTree->GetBranch("Electron");
            eventTree->SetBranchAddress("PV",   &vertexArr);
            TBranch *vertexBr = eventTree->GetBranch("PV");

            Bool_t hasGen = eventTree->GetBranchStatus("GenEvtInfo");
            TBranch *genBr=0, *genPartBr=0;
            if(hasGen) {
                eventTree->SetBranchAddress("GenEvtInfo", &gen);
                genBr = eventTree->GetBranch("GenEvtInfo");
                eventTree->SetBranchAddress("GenParticle",&genPartArr);
                genPartBr = eventTree->GetBranch("GenParticle");
            }

            // Compute MC event weight per 1/fb
            const Double_t xsec = samp->xsecv[ifile];
            Double_t totalWeight=0;

            if (hasGen) {
                TH1D *hall = new TH1D("hall", "", 1,0,1);
                eventTree->Draw("0.5>>hall", "GenEvtInfo->weight");
                totalWeight=hall->Integral();
                delete hall;
                hall=0;
            }

            //
            // loop over events
            //
            Double_t nsel=0, nselvar=0;
            for(UInt_t ientry=0; ientry<eventTree->GetEntries(); ientry++) {
                infoBr->GetEntry(ientry);

                if(ientry%1000000==0) cout << "Processing event " << ientry << ". " << (double)ientry/(double)eventTree->GetEntries()*100 << " percent done with this file." << endl;

                Double_t weight=1;
                if(xsec>0 && totalWeight>0) weight = xsec/totalWeight;
                if(hasGen) {
                    genPartArr->Clear();
                    genBr->GetEntry(ientry);
                    genPartBr->GetEntry(ientry);
                    weight*=gen->weight;
                }

                // veto w -> xv decays for signal and w -> ev for bacground samples (needed for inclusive WToLNu sample)
                if (isWrongFlavor && hasGen && fabs(toolbox::flavor(genPartArr, BOSON_ID))==LEPTON_ID) continue;
                else if (isSignal && hasGen && fabs(toolbox::flavor(genPartArr, BOSON_ID))!=LEPTON_ID) continue;

                // check for certified lumi (if applicable)
                baconhep::RunLumiRangeMap::RunLumiPairType rl(info->runNum, info->lumiSec);
                if(hasJSON && !rlrm.hasRunLumi(rl)) continue;

                // trigger requirement
                if (!isEleTrigger(triggerMenu, info->triggerBits, isData)) continue;

                // good vertex requirement
                if(!(info->hasGoodPV)) continue;

                //
                // SELECTION PROCEDURE:
                //  (1) Look for 1 good electron matched to trigger
                //  (2) Reject event if another electron is present passing looser cuts
                //
                electronArr->Clear();
                electronBr->GetEntry(ientry);

                Int_t nLooseLep=0;
                const baconhep::TElectron *goodEle=0;
                Bool_t passSel=kFALSE;

                for(Int_t i=0; i<electronArr->GetEntriesFast(); i++) {
                    const baconhep::TElectron *ele = (baconhep::TElectron*)((*electronArr)[i]);

                    // check ECAL gap
                    if(fabs(ele->scEta)>=ECAL_GAP_LOW && fabs(ele->scEta)<=ECAL_GAP_HIGH) continue;

                    // apply scale and resolution corrections to MC
                    Double_t elescEt_corr = ele->scEt;
                    if(doScaleCorr && snamev[isam].CompareTo("data",TString::kIgnoreCase)!=0)
                        elescEt_corr = gRandom->Gaus(ele->scEt*getEleScaleCorr(ele->scEta,0),getEleResCorr(ele->scEta,0));

                    if(fabs(ele->scEta)   > VETO_ETA) continue;        // loose lepton |eta| cut
                    if(elescEt_corr       < VETO_PT)  continue;        // loose lepton pT cut
                    if(passEleLooseID(ele,info->rhoIso)) nLooseLep++;  // loose lepton selection
                    if(nLooseLep>1) {  // extra lepton veto
                        passSel=kFALSE;
                        break;
                    }

                    if(fabs(ele->scEta)   > ETA_CUT)     continue;  // lepton |eta| cut
                    if(elescEt_corr       < PT_CUT)      continue;  // lepton pT cut
                    if(!passEleID(ele,info->rhoIso))     continue;  // lepton selection
                    if(!isEleTriggerObj(triggerMenu, ele->hltMatchBits, kFALSE, isData)) continue;

                    passSel=kTRUE;
                    goodEle = ele;
                }

                if(passSel) {

                    //******* We have a W candidate! HURRAY! ********
                    nsel+=weight;
                    nselvar+=weight*weight;

                    // apply scale and resolution corrections to MC
                    Double_t goodElept_corr = goodEle->pt;
                    if(doScaleCorr && snamev[isam].CompareTo("data",TString::kIgnoreCase)!=0)
                        goodElept_corr = gRandom->Gaus(goodEle->pt*getEleScaleCorr(goodEle->scEta,0),getEleResCorr(goodEle->scEta,0));

                    TLorentzVector vLep(0,0,0,0);
                    TLorentzVector vSC(0,0,0,0);
                    // apply scale and resolution corrections to MC
                    if(doScaleCorr && snamev[isam].CompareTo("data",TString::kIgnoreCase)!=0) {
                        vLep.SetPtEtaPhiM(goodElept_corr, goodEle->eta, goodEle->phi, ELE_MASS);
                        vSC.SetPtEtaPhiM(gRandom->Gaus(goodEle->scEt*getEleScaleCorr(goodEle->scEta,0),getEleResCorr(goodEle->scEta,0)), goodEle->scEta, goodEle->scPhi, ELE_MASS);
                    } else {
                        vLep.SetPtEtaPhiM(goodEle->pt,goodEle->eta,goodEle->phi,ELE_MASS);
                        vSC.SetPtEtaPhiM(goodEle->scEt,goodEle->scEta,goodEle->scPhi,ELE_MASS);
                    }

                    //
                    // Fill tree
                    //
                    runNum    = info->runNum;
                    lumiSec   = info->lumiSec;
                    evtNum    = info->evtNum;

                    vertexArr->Clear();
                    vertexBr->GetEntry(ientry);

                    npv      = vertexArr->GetEntries();
                    npu	    = info->nPUmean;
                    genV      = new TLorentzVector(0,0,0,0);
                    genLep    = new TLorentzVector(0,0,0,0);
                    genVPt    = -999;
                    genVPhi   = -999;
                    genVy     = -999;
                    genVMass  = -999;
                    genLepPt  = -999;
                    genLepPhi = -999;
                    u1        = -999;
                    u2        = -999;
                    tkU1      = -999;
                    tkU2      = -999;
                    mvaU1     = -999;
                    mvaU2     = -999;
                    puppiU1     = -999;
                    puppiU2     = -999;
                    id_1      = -999;
                    id_2      = -999;
                    x_1       = -999;
                    x_2       = -999;
                    xPDF_1    = -999;
                    xPDF_2    = -999;
                    scalePDF  = -999;
                    weightPDF = -999;

                    if(isSignal && hasGen) {
                        TLorentzVector *gvec=new TLorentzVector(0,0,0,0);
                        TLorentzVector *glep1=new TLorentzVector(0,0,0,0);
                        TLorentzVector *glep2=new TLorentzVector(0,0,0,0);
                        toolbox::fillGen(genPartArr, BOSON_ID, gvec, glep1, glep2,1);

                        if (gvec && glep1) {
                            genV      = new TLorentzVector(0,0,0,0);
                            genV->SetPtEtaPhiM(gvec->Pt(),gvec->Eta(),gvec->Phi(),gvec->M());
                            genLep    = new TLorentzVector(0,0,0,0);
                            genLep->SetPtEtaPhiM(glep1->Pt(),glep1->Eta(),glep1->Phi(),glep1->M());
                            genVPt    = gvec->Pt();
                            genVPhi   = gvec->Phi();
                            genVy     = gvec->Rapidity();
                            genVMass  = gvec->M();
                            genLepPt  = glep1->Pt();
                            genLepPhi = glep1->Phi();

                            TVector2 vWPt((genVPt)*cos(genVPhi),(genVPt)*sin(genVPhi));
                            TVector2 vLepPt(vLep.Px(),vLep.Py());

                            TVector2 vMet((info->pfMETC)*cos(info->pfMETCphi), (info->pfMETC)*sin(info->pfMETCphi));
                            TVector2 vU = -1.0*(vMet+vLepPt);
                            u1 = ((vWPt.Px())*(vU.Px()) + (vWPt.Py())*(vU.Py()))/(genVPt);  // u1 = (pT . u)/|pT|
                            u2 = ((vWPt.Px())*(vU.Py()) - (vWPt.Py())*(vU.Px()))/(genVPt);  // u2 = (pT x u)/|pT|

                            TVector2 vTkMet((info->trkMET)*cos(info->trkMETphi), (info->trkMET)*sin(info->trkMETphi));
                            TVector2 vTkU = -1.0*(vTkMet+vLepPt);
                            tkU1 = ((vWPt.Px())*(vTkU.Px()) + (vWPt.Py())*(vTkU.Py()))/(genVPt);  // u1 = (pT . u)/|pT|
                            tkU2 = ((vWPt.Px())*(vTkU.Py()) - (vWPt.Py())*(vTkU.Px()))/(genVPt);  // u2 = (pT x u)/|pT|

                            TVector2 vMvaMet((info->mvaMET)*cos(info->mvaMETphi), (info->mvaMET)*sin(info->mvaMETphi));
                            TVector2 vMvaU = -1.0*(vMvaMet+vLepPt);
                            mvaU1 = ((vWPt.Px())*(vMvaU.Px()) + (vWPt.Py())*(vMvaU.Py()))/(genVPt);  // u1 = (pT . u)/|pT|
                            mvaU2 = ((vWPt.Px())*(vMvaU.Py()) - (vWPt.Py())*(vMvaU.Px()))/(genVPt);  // u2 = (pT x u)/|pT|

                            TVector2 vPuppiMet((info->puppET)*cos(info->puppETphi), (info->puppET)*sin(info->puppETphi));
                            TVector2 vPuppiU = -1.0*(vPuppiMet+vLepPt);
                            puppiU1 = ((vWPt.Px())*(vPuppiU.Px()) + (vWPt.Py())*(vPuppiU.Py()))/(genVPt);  // u1 = (pT . u)/|pT|
                            puppiU2 = ((vWPt.Px())*(vPuppiU.Py()) - (vWPt.Py())*(vPuppiU.Px()))/(genVPt);  // u2 = (pT x u)/|pT|

                        }
                        id_1      = gen->id_1;
                        id_2      = gen->id_2;
                        x_1       = gen->x_1;
                        x_2       = gen->x_2;
                        xPDF_1    = gen->xPDF_1;
                        xPDF_2    = gen->xPDF_2;
                        scalePDF  = gen->scalePDF;
                        weightPDF = gen->weight;

                        delete gvec;
                        delete glep1;
                        delete glep2;
                        gvec=0;
                        glep1=0;
                        glep2=0;
                    }
                    scale1fb = weight;
                    puWeight = h_rw->GetBinContent(h_rw->FindBin(npu));
                    puWeightUp = h_rw_up->GetBinContent(h_rw_up->FindBin(npu));
                    puWeightDown = h_rw_down->GetBinContent(h_rw_down->FindBin(npu));
                    met	   = info->pfMETC;
                    metPhi   = info->pfMETCphi;
                    sumEt    = 0;
                    mt       = sqrt( 2.0 * (vLep.Pt()) * (info->pfMETC) * (1.0-cos(toolbox::deltaPhi(vLep.Phi(),info->pfMETCphi))) );
                    tkMet	   = info->trkMET;
                    tkMetPhi = info->trkMETphi;
                    tkSumEt  = 0;
                    tkMt     = sqrt( 2.0 * (vLep.Pt()) * (info->trkMET) * (1.0-cos(toolbox::deltaPhi(vLep.Phi(),info->trkMETphi))) );
                    mvaMet   = info->mvaMET;
                    mvaMetPhi = info->mvaMETphi;
                    mvaSumEt  = 0;
                    mvaMt     = sqrt( 2.0 * (vLep.Pt()) * (info->mvaMET) * (1.0-cos(toolbox::deltaPhi(vLep.Phi(),info->mvaMETphi))) );
// 	  TVector2 vLepPt(vLep.Px(),vLep.Py());
// 	  TVector2 vPuppi((info->puppET)*cos(info->puppETphi), (info->puppET)*sin(info->puppETphi));
// 	  TVector2 vpp; vpp=vPuppi-vLepPt;
                    puppiMet   = info->puppET;
                    puppiMetPhi = info->puppETphi;
                    puppiSumEt  = 0;
                    puppiMt     = sqrt( 2.0 * (vLep.Pt()) * (info->puppET) * (1.0-cos(toolbox::deltaPhi(vLep.Phi(),info->puppETphi))) );
                    q        = goodEle->q;
                    lep      = &vLep;

                    ///// electron specific /////
                    sc       = &vSC;
                    trkIso    = goodEle->trkIso;
                    emIso     = goodEle->ecalIso;
                    hadIso    = goodEle->hcalIso;
                    pfChIso   = goodEle->chHadIso;
                    pfGamIso  = goodEle->gammaIso;
                    pfNeuIso  = goodEle->neuHadIso;
                    pfCombIso = goodEle->chHadIso + TMath::Max(goodEle->neuHadIso + goodEle->gammaIso -
                                (info->rhoIso)*getEffAreaEl(goodEle->scEta), 0.);
                    sigieie   = goodEle->sieie;
                    hovere    = goodEle->hovere;
                    eoverp    = goodEle->eoverp;
                    fbrem     = goodEle->fbrem;
                    dphi      = goodEle->dPhiIn;
                    deta      = goodEle->dEtaIn;
                    ecalE     = goodEle->ecalEnergy;
                    d0        = goodEle->d0;
                    dz        = goodEle->dz;
                    isConv    = goodEle->isConv;
                    nexphits  = goodEle->nMissingHits;
                    typeBits  = goodEle->typeBits;

                    outTree->Fill();
                    delete genV;
                    delete genLep;
                    genV=0, genLep=0, lep=0, sc=0;
                }
            }
            delete infile;
            infile=0, eventTree=0;

            cout << nsel  << " +/- " << sqrt(nselvar);
            if(isam!=0) cout << " per 1/pb";
            cout << endl;
        }
        outFile->Write();
        outFile->Close();
    }
    delete h_rw;
    delete h_rw_up;
    delete h_rw_down;
    delete f_rw;
    delete info;
    delete gen;
    delete genPartArr;
    delete electronArr;
    delete vertexArr;

    //--------------------------------------------------------------------------------------------------------------
    // Output
    //==============================================================================================================

    cout << "*" << endl;
    cout << "* SUMMARY" << endl;
    cout << "*--------------------------------------------------" << endl;
    cout << " W -> e nu" << endl;
    cout << "  pT > " << PT_CUT << endl;
    cout << "  |eta| < " << ETA_CUT << endl;
    if(doScaleCorr)
        cout << "  *** Scale corrections applied ***" << endl;
    cout << endl;

    cout << endl;
    cout << "  <> Output saved in " << outputDir << "/" << endl;
    cout << endl;

    gBenchmark->Show("selectWe");
}
Пример #3
0
void selectZee(const TString conf="zee.conf", // input file
               const TString outputDir=".",   // output directory
	       const Bool_t  doScaleCorr=0    // apply energy scale corrections?
) {
  gBenchmark->Start("selectZee");

  //--------------------------------------------------------------------------------------------------------------
  // Settings 
  //============================================================================================================== 

  const Double_t MASS_LOW  = 40;
  const Double_t MASS_HIGH = 200;
  const Double_t PT_CUT    = 22;
  const Double_t ETA_CUT   = 2.5;
  const Double_t ELE_MASS  = 0.000511;
  
  const Double_t ECAL_GAP_LOW  = 1.4442;
  const Double_t ECAL_GAP_HIGH = 1.566;

  const Double_t escaleNbins  = 2;
  const Double_t escaleEta[]  = { 1.4442, 2.5   };
  const Double_t escaleCorr[] = { 0.992,  1.009 };

  const Int_t BOSON_ID  = 23;
  const Int_t LEPTON_ID = 11;

  // load trigger menu
  const baconhep::TTrigger triggerMenu("../../BaconAna/DataFormats/data/HLT_50nsGRun");

  // load pileup reweighting file
  TFile *f_rw = TFile::Open("../Tools/pileup_rw_76X.root", "read");

  // for systematics we need 3
  TH1D *h_rw = (TH1D*) f_rw->Get("h_rw_golden");
  TH1D *h_rw_up = (TH1D*) f_rw->Get("h_rw_up_golden");
  TH1D *h_rw_down = (TH1D*) f_rw->Get("h_rw_down_golden");

  if (h_rw==NULL) cout<<"WARNIG h_rw == NULL"<<endl;
  if (h_rw_up==NULL) cout<<"WARNIG h_rw == NULL"<<endl;
  if (h_rw_down==NULL) cout<<"WARNIG h_rw == NULL"<<endl;

  //--------------------------------------------------------------------------------------------------------------
  // Main analysis code 
  //==============================================================================================================  

  enum { eEleEle2HLT=1, eEleEle1HLT1L1, eEleEle1HLT, eEleEleNoSel, eEleSC };  // event category enum
  
  vector<TString>  snamev;      // sample name (for output files)  
  vector<CSample*> samplev;     // data/MC samples

  //
  // parse .conf file
  //
  confParse(conf, snamev, samplev);
  const Bool_t hasData = (samplev[0]->fnamev.size()>0);

  // Create output directory
  gSystem->mkdir(outputDir,kTRUE);
  const TString ntupDir = outputDir + TString("/ntuples");
  gSystem->mkdir(ntupDir,kTRUE);
  
  //
  // Declare output ntuple variables
  //
  UInt_t  runNum, lumiSec, evtNum;
  UInt_t  matchGen;
  UInt_t  category;
  UInt_t  npv, npu;
  UInt_t  id_1, id_2;
  Double_t x_1, x_2, xPDF_1, xPDF_2;
  Double_t scalePDF, weightPDF;
  TLorentzVector *genV=0;
  Float_t genVPt, genVPhi, genVy, genVMass;
  Float_t genWeight, PUWeight;
  Float_t scale1fb,scale1fbUp,scale1fbDown;
  Float_t met, metPhi, sumEt, u1, u2;
  Float_t tkMet, tkMetPhi, tkSumEt, tkU1, tkU2;
  Float_t mvaMet, mvaMetPhi, mvaSumEt, mvaU1, mvaU2;
  Float_t puppiMet, puppiMetPhi, puppiSumEt, puppiU1, puppiU2;
  Int_t   q1, q2;
  TLorentzVector *dilep=0, *lep1=0, *lep2=0;
  ///// electron specific /////
  Float_t trkIso1, emIso1, hadIso1, trkIso2, emIso2, hadIso2;
  Float_t pfChIso1, pfGamIso1, pfNeuIso1, pfCombIso1, pfChIso2, pfGamIso2, pfNeuIso2, pfCombIso2;
  Float_t sigieie1, hovere1, eoverp1, fbrem1, ecalE1, sigieie2, hovere2, eoverp2, fbrem2, ecalE2;
  Float_t dphi1, deta1, dphi2, deta2;
  Float_t d01, dz1, d02, dz2;
  UInt_t  isConv1, nexphits1, typeBits1, isConv2, nexphits2, typeBits2; 
  TLorentzVector *sc1=0, *sc2=0;
  
  // Data structures to store info from TTrees
  baconhep::TEventInfo *info   = new baconhep::TEventInfo();
  baconhep::TGenEventInfo *gen = new baconhep::TGenEventInfo();
  TClonesArray *genPartArr     = new TClonesArray("baconhep::TGenParticle");
  TClonesArray *electronArr    = new TClonesArray("baconhep::TElectron");
  TClonesArray *scArr          = new TClonesArray("baconhep::TPhoton");
  TClonesArray *vertexArr      = new TClonesArray("baconhep::TVertex");

  TFile *infile=0;
  TTree *eventTree=0;
  
  //
  // loop over samples
  //  
  for(UInt_t isam=0; isam<samplev.size(); isam++) {
    
    // Assume data sample is first sample in .conf file
    // If sample is empty (i.e. contains no ntuple files), skip to next sample
    Bool_t isData=kFALSE;
    if(isam==0 && !hasData) continue;
    else if (isam==0) isData=kTRUE;
    
    // Assume signal sample is given name "zee" - flag to store GEN Z kinematics
    Bool_t isSignal = (snamev[isam].CompareTo("zee",TString::kIgnoreCase)==0);  
    // flag to reject Z->ee events when selecting at wrong-flavor background events
    Bool_t isWrongFlavor = (snamev[isam].CompareTo("zxx",TString::kIgnoreCase)==0);  
    
    CSample* samp = samplev[isam];
  
    //
    // Set up output ntuple
    //
    TString outfilename = ntupDir + TString("/") + snamev[isam] + TString("_select.root");
    if(isam!=0 && !doScaleCorr) outfilename = ntupDir + TString("/") + snamev[isam] + TString("_select.raw.root");
    TFile *outFile = new TFile(outfilename,"RECREATE"); 
    TTree *outTree = new TTree("Events","Events");
    outTree->Branch("runNum",     &runNum,     "runNum/i");      // event run number
    outTree->Branch("lumiSec",    &lumiSec,    "lumiSec/i");     // event lumi section
    outTree->Branch("evtNum",     &evtNum,     "evtNum/i");      // event number
    outTree->Branch("matchGen",   &matchGen,   "matchGen/i");    // event has both leptons matched to MC Z->ll
    outTree->Branch("category",   &category,   "category/i");    // dilepton category
    outTree->Branch("id_1",       &id_1,       "id_1/i");        // PDF info -- parton ID for parton 1
    outTree->Branch("id_2",       &id_2,       "id_2/i");        // PDF info -- parton ID for parton 2
    outTree->Branch("x_1",        &x_1,        "x_1/d");         // PDF info -- x for parton 1
    outTree->Branch("x_2",        &x_2,        "x_2/d");         // PDF info -- x for parton 2
    outTree->Branch("xPDF_1",     &xPDF_1,     "xPDF_1/d");      // PDF info -- x*F for parton 1
    outTree->Branch("xPDF_2",     &xPDF_2,     "xPDF_2/d");      // PDF info -- x*F for parton 2
    outTree->Branch("scalePDF",   &scalePDF,   "scalePDF/d");    // PDF info -- energy scale of parton interaction
    outTree->Branch("weightPDF",  &weightPDF,  "weightPDF/d");   // PDF info -- PDF weight
    outTree->Branch("npv",        &npv,        "npv/i");         // number of primary vertices
    outTree->Branch("npu",        &npu,        "npu/i");         // number of in-time PU events (MC)
    outTree->Branch("genV",      "TLorentzVector",  &genV);      // GEN boson 4-vector
    outTree->Branch("genVPt",     &genVPt,     "genVPt/F");      // GEN boson pT (signal MC)
    outTree->Branch("genVPhi",    &genVPhi,    "genVPhi/F");     // GEN boson phi (signal MC)
    outTree->Branch("genVy",      &genVy,      "genVy/F");       // GEN boson rapidity (signal MC)
    outTree->Branch("genVMass",   &genVMass,   "genVMass/F");    // GEN boson mass (signal MC)
    outTree->Branch("genWeight",   &genWeight,  "genWeight/F");
    outTree->Branch("PUWeight",    &PUWeight,   "PUWeight/F");
    outTree->Branch("scale1fb",   &scale1fb,   "scale1fb/F");    // event weight per 1/fb (MC)
    outTree->Branch("scale1fbUp",    &scale1fbUp,   "scale1fbUp/F");    // event weight per 1/fb (MC)
    outTree->Branch("scale1fbDown",    &scale1fbDown,   "scale1fbDown/F");    // event weight per 1/fb (MC)
    outTree->Branch("met",        &met,        "met/F");         // MET
    outTree->Branch("metPhi",     &metPhi,     "metPhi/F");      // phi(MET)
    outTree->Branch("sumEt",      &sumEt,      "sumEt/F");       // Sum ET
    outTree->Branch("u1",         &u1,         "u1/F");          // parallel component of recoil
    outTree->Branch("u2",         &u2,         "u2/F");          // perpendicular component of recoil
    outTree->Branch("tkMet",      &tkMet,      "tkMet/F");       // MET (track MET)
    outTree->Branch("tkMetPhi",   &tkMetPhi,   "tkMetPhi/F");    // phi(MET) (track MET)
    outTree->Branch("tkSumEt",    &tkSumEt,    "tkSumEt/F");     // Sum ET (track MET)
    outTree->Branch("tkU1",       &tkU1,       "tkU1/F");        // parallel component of recoil (track MET)
    outTree->Branch("tkU2",       &tkU2,       "tkU2/F");        // perpendicular component of recoil (track MET)
    outTree->Branch("mvaMet",     &mvaMet,     "mvaMet/F");      // MVA MET
    outTree->Branch("mvaMetPhi",  &mvaMetPhi,  "mvaMetPhi/F");   // phi(MVA MET)
    outTree->Branch("mvaSumEt",   &mvaSumEt,   "mvaSumEt/F");    // Sum ET (mva MET)
    outTree->Branch("mvaU1",      &mvaU1,      "mvaU1/F");       // parallel component of recoil (mva MET)
    outTree->Branch("mvaU2",      &mvaU2,      "mvaU2/F");       // perpendicular component of recoil (mva MET)
    outTree->Branch("puppiMet",    &puppiMet,   "puppiMet/F");      // Puppi MET
    outTree->Branch("puppiMetPhi", &puppiMetPhi,"puppiMetPhi/F");   // phi(Puppi MET)
    outTree->Branch("puppiSumEt",  &puppiSumEt, "puppiSumEt/F");    // Sum ET (Puppi MET)
    outTree->Branch("puppiU1",     &puppiU1,    "puppiU1/F");       // parallel component of recoil (Puppi MET)
    outTree->Branch("puppiU2",     &puppiU2,    "puppiU2/F");       // perpendicular component of recoil (Puppi MET)
    outTree->Branch("q1",         &q1,         "q1/I");          // charge of tag lepton
    outTree->Branch("q2",         &q2,         "q2/I");          // charge of probe lepton
    outTree->Branch("dilep",      "TLorentzVector",  &dilep);    // di-lepton 4-vector
    outTree->Branch("lep1",       "TLorentzVector",  &lep1);     // tag lepton 4-vector
    outTree->Branch("lep2",       "TLorentzVector",  &lep2);     // probe lepton 4-vector
    ///// electron specific /////
    outTree->Branch("trkIso1",    &trkIso1,    "trkIso1/F");     // track isolation of tag lepton
    outTree->Branch("trkIso2",    &trkIso2,    "trkIso2/F");     // track isolation of probe lepton
    outTree->Branch("emIso1",     &emIso1,     "emIso1/F");      // ECAL isolation of tag lepton
    outTree->Branch("emIso2",     &emIso2,     "emIso2/F");      // ECAL isolation of probe lepton
    outTree->Branch("hadIso1",    &hadIso1,    "hadIso1/F");     // HCAL isolation of tag lepton
    outTree->Branch("hadIso2",    &hadIso2,    "hadIso2/F");     // HCAL isolation of probe lepton
    outTree->Branch("pfChIso1",   &pfChIso1,   "pfChIso1/F");    // PF charged hadron isolation of tag lepton
    outTree->Branch("pfChIso2",   &pfChIso2,   "pfChIso2/F");    // PF charged hadron isolation of probe lepton
    outTree->Branch("pfGamIso1",  &pfGamIso1,  "pfGamIso1/F");   // PF photon isolation of tag lepton
    outTree->Branch("pfGamIso2",  &pfGamIso2,  "pfGamIso2/F");   // PF photon isolation of probe lepton
    outTree->Branch("pfNeuIso1",  &pfNeuIso1,  "pfNeuIso1/F");   // PF neutral hadron isolation of tag lepton
    outTree->Branch("pfNeuIso2",  &pfNeuIso2,  "pfNeuIso2/F");   // PF neutral hadron isolation of probe lepton
    outTree->Branch("pfCombIso1", &pfCombIso1, "pfCombIso1/F");  // PF combine isolation of tag lepton
    outTree->Branch("pfCombIso2", &pfCombIso2, "pfCombIso2/F");  // PF combined isolation of probe lepton    
    outTree->Branch("sigieie1",   &sigieie1,   "sigieie1/F");    // sigma-ieta-ieta of tag
    outTree->Branch("sigieie2",   &sigieie2,   "sigieie2/F");    // sigma-ieta-ieta of probe
    outTree->Branch("hovere1",    &hovere1,    "hovere1/F");     // H/E of tag
    outTree->Branch("hovere2",    &hovere2,    "hovere2/F");     // H/E of probe
    outTree->Branch("eoverp1",    &eoverp1,    "eoverp1/F");     // E/p of tag
    outTree->Branch("eoverp2",    &eoverp2,    "eoverp2/F");     // E/p of probe	 
    outTree->Branch("fbrem1",     &fbrem1,     "fbrem1/F");      // brem fraction of tag
    outTree->Branch("fbrem2",     &fbrem2,     "fbrem2/F");      // brem fraction of probe
    outTree->Branch("dphi1",      &dphi1,      "dphi1/F");       // GSF track - ECAL dphi of tag
    outTree->Branch("dphi2",      &dphi2,      "dphi2/F");       // GSF track - ECAL dphi of probe 	
    outTree->Branch("deta1",      &deta1,      "deta1/F");       // GSF track - ECAL deta of tag
    outTree->Branch("deta2",      &deta2,      "deta2/F");       // GSF track - ECAL deta of probe
    outTree->Branch("ecalE1",     &ecalE1,     "ecalE1/F");      // ECAL energy of tag
    outTree->Branch("ecalE2",     &ecalE2,     "ecalE2/F");      // ECAL energy of probe
    outTree->Branch("d01",        &d01,        "d01/F");	 // transverse impact parameter of tag
    outTree->Branch("d02",        &d02,        "d02/F");	 // transverse impact parameter of probe	  
    outTree->Branch("dz1",        &dz1,        "dz1/F");	 // longitudinal impact parameter of tag
    outTree->Branch("dz2",        &dz2,        "dz2/F");	 // longitudinal impact parameter of probe
    outTree->Branch("isConv1",    &isConv1,    "isConv1/i");     // conversion filter flag of tag lepton
    outTree->Branch("isConv2",    &isConv2,    "isConv2/i");     // conversion filter flag of probe lepton
    outTree->Branch("nexphits1",  &nexphits1,  "nexphits1/i");   // number of missing expected inner hits of tag lepton
    outTree->Branch("nexphits2",  &nexphits2,  "nexphits2/i");   // number of missing expected inner hits of probe lepton
    outTree->Branch("typeBits1",  &typeBits1,  "typeBits1/i");   // electron type of tag lepton
    outTree->Branch("typeBits2",  &typeBits2,  "typeBits2/i");   // electron type of probe lepton
    outTree->Branch("sc1",       "TLorentzVector",  &sc1);       // tag supercluster 4-vector
    outTree->Branch("sc2",       "TLorentzVector",  &sc2);       // probe supercluster 4-vector

    //
    // loop through files
    //
    const UInt_t nfiles = samp->fnamev.size();
    for(UInt_t ifile=0; ifile<nfiles; ifile++) {  

      // Read input file and get the TTrees
      cout << "Processing " << samp->fnamev[ifile] << " [xsec = " << samp->xsecv[ifile] << " pb] ... " << endl; cout.flush();
      infile = TFile::Open(samp->fnamev[ifile]); 
      assert(infile);

      Bool_t hasJSON = kFALSE;
      baconhep::RunLumiRangeMap rlrm;
      if(samp->jsonv[ifile].CompareTo("NONE")!=0) { 
	hasJSON = kTRUE;
	rlrm.addJSONFile(samp->jsonv[ifile].Data()); 
      }
  
      eventTree = (TTree*)infile->Get("Events");
      assert(eventTree);  
      eventTree->SetBranchAddress("Info",     &info);        TBranch *infoBr     = eventTree->GetBranch("Info");
      eventTree->SetBranchAddress("Electron", &electronArr); TBranch *electronBr = eventTree->GetBranch("Electron");
      eventTree->SetBranchAddress("Photon",   &scArr);       TBranch *scBr       = eventTree->GetBranch("Photon");
      eventTree->SetBranchAddress("PV",   &vertexArr);       TBranch *vertexBr = eventTree->GetBranch("PV");
      Bool_t hasGen = eventTree->GetBranchStatus("GenEvtInfo");
      TBranch *genBr=0, *genPartBr=0;
      if(hasGen) {
        eventTree->SetBranchAddress("GenEvtInfo", &gen); genBr = eventTree->GetBranch("GenEvtInfo");
	eventTree->SetBranchAddress("GenParticle",&genPartArr); genPartBr = eventTree->GetBranch("GenParticle");
      }

      // Compute MC event weight per 1/fb
      const Double_t xsec = samp->xsecv[ifile];
      Double_t totalWeight=0;
      Double_t totalWeightUp=0;
      Double_t totalWeightDown=0;
      Double_t puWeight=0;
      Double_t puWeightUp=0;
      Double_t puWeightDown=0;

      if (hasGen) {
	for(UInt_t ientry=0; ientry<eventTree->GetEntries(); ientry++) {
	  infoBr->GetEntry(ientry);
	  genBr->GetEntry(ientry);
	  puWeight = h_rw->GetBinContent(h_rw->FindBin(info->nPUmean));
	  puWeightUp = h_rw_up->GetBinContent(h_rw_up->FindBin(info->nPUmean));
	  puWeightDown = h_rw_down->GetBinContent(h_rw_down->FindBin(info->nPUmean));
	  totalWeight+=gen->weight*puWeight;
	  totalWeightUp+=gen->weight*puWeightUp;
	  totalWeightDown+=gen->weight*puWeightDown;
	}
      }
      else if (not isData){
	for(UInt_t ientry=0; ientry<eventTree->GetEntries(); ientry++) {
	  puWeight = h_rw->GetBinContent(h_rw->FindBin(info->nPUmean));
	  puWeightUp = h_rw_up->GetBinContent(h_rw_up->FindBin(info->nPUmean));
	  puWeightDown = h_rw_down->GetBinContent(h_rw_down->FindBin(info->nPUmean));
	  totalWeight+= 1.0*puWeight;
	  totalWeightUp+= 1.0*puWeightUp;
	  totalWeightDown+= 1.0*puWeightDown;
	}

      }
      
      //
      // loop over events
      //
      Double_t nsel=0, nselvar=0;
      for(UInt_t ientry=0; ientry<eventTree->GetEntries(); ientry++) {
        infoBr->GetEntry(ientry);

        if(ientry%1000000==0) cout << "Processing event " << ientry << ". " << (double)ientry/(double)eventTree->GetEntries()*100 << " percent done with this file." << endl;

        Double_t weight=1;
	Double_t weightUp=1;
	Double_t weightDown=1;
        if(xsec>0 && totalWeight>0) weight = xsec/totalWeight;
	if(xsec>0 && totalWeightUp>0) weightUp = xsec/totalWeightUp;
	if(xsec>0 && totalWeightDown>0) weightDown = xsec/totalWeightDown;
	if(hasGen) {
	  genPartArr->Clear();
	  genBr->GetEntry(ientry);
          genPartBr->GetEntry(ientry);
	  puWeight = h_rw->GetBinContent(h_rw->FindBin(info->nPUmean));
	  puWeightUp = h_rw_up->GetBinContent(h_rw_up->FindBin(info->nPUmean));
	  puWeightDown = h_rw_down->GetBinContent(h_rw_down->FindBin(info->nPUmean));
	  weight*=gen->weight*puWeight;
	  weightUp*=gen->weight*puWeightUp;
	  weightDown*=gen->weight*puWeightDown;
	}
	
	// veto z -> xx decays for signal and z -> ee for bacground samples (needed for inclusive DYToLL sample)
	if (isWrongFlavor && hasGen && fabs(toolbox::flavor(genPartArr, BOSON_ID))==LEPTON_ID) continue;
	else if (isSignal && hasGen && fabs(toolbox::flavor(genPartArr, BOSON_ID))!=LEPTON_ID) continue;

        // check for certified lumi (if applicable)
        baconhep::RunLumiRangeMap::RunLumiPairType rl(info->runNum, info->lumiSec);      
        if(hasJSON && !rlrm.hasRunLumi(rl)) continue;  

        // trigger requirement
	if (!isEleTrigger(triggerMenu, info->triggerBits, isData)) continue;

        // good vertex requirement
        if(!(info->hasGoodPV)) continue;

	electronArr->Clear();
        electronBr->GetEntry(ientry);
	scArr->Clear();
	scBr->GetEntry(ientry);

	TLorentzVector vTag(0,0,0,0);
	TLorentzVector vTagSC(0,0,0,0);
	Double_t tagPt=0;
	Double_t Pt1=0;
	Double_t Pt2=0;
	Int_t itag=-1;
	Int_t tagscID=-1;
		
	for(Int_t i1=0; i1<electronArr->GetEntriesFast(); i1++) {
          const baconhep::TElectron *tag = (baconhep::TElectron*)((*electronArr)[i1]);
	  
	  // check ECAL gap
	  if(fabs(tag->scEta)>=ECAL_GAP_LOW && fabs(tag->scEta)<=ECAL_GAP_HIGH) continue;
	  
          // apply scale and resolution corrections to MC
          Double_t tagscEt_corr = tag->scEt;
          if(doScaleCorr && snamev[isam].CompareTo("data",TString::kIgnoreCase)!=0)
            tagscEt_corr = gRandom->Gaus(tag->scEt*getEleScaleCorr(tag->scEta,0),getEleResCorr(tag->scEta,0));
	  
	  if(tagscEt_corr        < PT_CUT)     continue;  // lepton pT cut
	  if(fabs(tag->scEta)    > ETA_CUT)    continue;  // lepton |eta| cut
	  if(!passEleID(tag,info->rhoIso))     continue;  // lepton selection
	
	  double El_Pt=0;
	  if(doScaleCorr) {
	    El_Pt=gRandom->Gaus(tag->pt*getEleScaleCorr(tag->scEta,0),getEleResCorr(tag->scEta,0));
	  }
	  else
	    {
	      El_Pt=tag->pt;
	    }

	  if(El_Pt>Pt1)
	    {
	      Pt2=Pt1;
	      Pt1=El_Pt;
	    }
	  else if(El_Pt>Pt2&&El_Pt<Pt1)
	    {
	      Pt2=El_Pt;
	    }

	  if(!isEleTriggerObj(triggerMenu, tag->hltMatchBits, kFALSE, isData)) continue;
	  
	  if(El_Pt<tagPt) continue;
	  
	  tagPt=El_Pt;
	  itag=i1;
	  tagscID=tag->scID;

	  // apply scale and resolution corrections to MC
          if(doScaleCorr && snamev[isam].CompareTo("data",TString::kIgnoreCase)!=0) {
            vTag.SetPtEtaPhiM(El_Pt, tag->eta, tag->phi, ELE_MASS);
            vTagSC.SetPtEtaPhiM(tagscEt_corr, tag->scEta, tag->scPhi, ELE_MASS);
          } else {
  	    vTag.SetPtEtaPhiM(tag->pt, tag->eta, tag->phi, ELE_MASS);
	    vTagSC.SetPtEtaPhiM(tag->scEt, tag->scEta, tag->scPhi, ELE_MASS);
          }

	  trkIso1    = tag->trkIso;
	  emIso1     = tag->ecalIso;
	  hadIso1    = tag->hcalIso;
	  pfChIso1   = tag->chHadIso;
	  pfGamIso1  = tag->gammaIso;	    
	  pfNeuIso1  = tag->neuHadIso;
	  pfCombIso1 = tag->chHadIso + TMath::Max(tag->neuHadIso + tag->gammaIso - (info->rhoIso)*getEffAreaEl(tag->scEta), 0.);
	  sigieie1   = tag->sieie;
	  hovere1    = tag->hovere;
	  eoverp1    = tag->eoverp;
	  fbrem1     = tag->fbrem;
	  dphi1      = tag->dPhiIn;
	  deta1      = tag->dEtaIn;
	  ecalE1     = tag->ecalEnergy;
	  d01        = tag->d0;
	  dz1        = tag->dz;
	  isConv1    = tag->isConv;
	  nexphits1  = tag->nMissingHits;
	  typeBits1  = tag->typeBits;
	  q1         = tag->q;

	}

	if(tagPt<Pt2) continue;

	TLorentzVector vProbe(0,0,0,0); TLorentzVector vProbeSC(0,0,0,0);
	Double_t probePt=0;
	Int_t iprobe=-1;
	Int_t passID=false;
	UInt_t icat=0;
	
	const baconhep::TElectron *eleProbe=0;

	for(Int_t j=0; j<scArr->GetEntriesFast(); j++) {
	  const baconhep::TPhoton *scProbe = (baconhep::TPhoton*)((*scArr)[j]);
	  
	  if(scProbe->scID == tagscID) continue;

	  // check ECAL gap
	  if(fabs(scProbe->eta)>=ECAL_GAP_LOW && fabs(scProbe->eta)<=ECAL_GAP_HIGH) continue;
	  
	  // apply scale and resolution corrections to MC
	  Double_t scProbept_corr = scProbe->pt;
	  if(doScaleCorr && snamev[isam].CompareTo("data",TString::kIgnoreCase)!=0)
	    scProbept_corr = gRandom->Gaus(scProbe->pt*getEleScaleCorr(scProbe->eta,0),getEleResCorr(scProbe->eta,0));
	  
	  if(scProbept_corr        < PT_CUT)  continue;  // Supercluster ET cut ("pt" = corrected by PV position)
	  if(fabs(scProbe->eta)  > ETA_CUT) continue;  // Supercluster |eta| cuts

	  for(Int_t i2=0; i2<electronArr->GetEntriesFast(); i2++) {
	    if(itag==i2) continue;
	    const baconhep::TElectron *ele = (baconhep::TElectron*)((*electronArr)[i2]);
	    if(!(ele->typeBits & baconhep::EEleType::kEcalDriven)) continue;
	    if(scProbe->scID==ele->scID) { 
	      eleProbe = ele; 
	      iprobe   = i2;
	      break; 
	    }
	  }

	  double El_Pt=0;
	  if(doScaleCorr&&eleProbe) {
	    El_Pt=gRandom->Gaus(eleProbe->pt*getEleScaleCorr(scProbe->eta,0),getEleResCorr(scProbe->eta,0));
	  }
	  else if(!doScaleCorr&&eleProbe)
	    {
	      El_Pt=eleProbe->pt;
	    }
	  else
	    {
	      El_Pt=scProbept_corr;
	    }

	  if(passID&&eleProbe&&passEleID(eleProbe,info->rhoIso)&&El_Pt<probePt) continue;
	  if(passID&&eleProbe&&!passEleID(eleProbe,info->rhoIso)) continue;
	  if(passID&&!eleProbe) continue;
	  if(!passID&&eleProbe&&!passEleID(eleProbe,info->rhoIso)&&El_Pt<probePt) continue;
	  if(!passID&&!eleProbe&&El_Pt<probePt) continue;
	  if(!passID&&eleProbe&&passEleID(eleProbe,info->rhoIso)) passID=true;

	  probePt=El_Pt;

	  // apply scale and resolution corrections to MC
	  if(doScaleCorr && snamev[isam].CompareTo("data",TString::kIgnoreCase)!=0) {
	    vProbe.SetPtEtaPhiM((eleProbe) ? gRandom->Gaus(eleProbe->pt*getEleScaleCorr(scProbe->eta,0),getEleResCorr(scProbe->eta,0)) : scProbept_corr,
				(eleProbe) ? eleProbe->eta : scProbe->eta,
				(eleProbe) ? eleProbe->phi : scProbe->phi,
				ELE_MASS);
	    vProbeSC.SetPtEtaPhiM((eleProbe) ? gRandom->Gaus(eleProbe->scEt*getEleScaleCorr(scProbe->eta,0),getEleResCorr(scProbe->eta,0)) : gRandom->Gaus(scProbe->pt*getEleScaleCorr(scProbe->eta,0),getEleResCorr(scProbe->eta,0)),
				  scProbe->eta, scProbe->phi, ELE_MASS);
	  } else {
	    vProbe.SetPtEtaPhiM((eleProbe) ? eleProbe->pt : scProbe->pt,
				(eleProbe) ? eleProbe->eta : scProbe->eta,
				(eleProbe) ? eleProbe->phi : scProbe->phi,
				ELE_MASS);
	    vProbeSC.SetPtEtaPhiM((eleProbe) ? eleProbe->scEt : scProbe->pt,
				  scProbe->eta, scProbe->phi, ELE_MASS);
	  }

	  trkIso2    = (eleProbe) ? eleProbe->trkIso        : -1;
	  emIso2     = (eleProbe) ? eleProbe->ecalIso       : -1;
	  hadIso2    = (eleProbe) ? eleProbe->hcalIso       : -1;
	  pfChIso2   = (eleProbe) ? eleProbe->chHadIso      : -1;
	  pfGamIso2  = (eleProbe) ? eleProbe->gammaIso      : -1;
	  pfNeuIso2  = (eleProbe) ? eleProbe->neuHadIso     : -1;	    
	  pfCombIso2 = (eleProbe) ? 
	    eleProbe->chHadIso + TMath::Max(eleProbe->neuHadIso + eleProbe->gammaIso - 
					    (info->rhoIso)*getEffAreaEl(eleProbe->scEta), 0.) :  -1;
	  sigieie2   = (eleProbe) ? eleProbe->sieie         : scProbe->sieie;
	  hovere2    = (eleProbe) ? eleProbe->hovere        : scProbe->hovere;
	  eoverp2    = (eleProbe) ? eleProbe->eoverp        : -1;
	  fbrem2     = (eleProbe) ? eleProbe->fbrem         : -1;
	  dphi2      = (eleProbe) ? eleProbe->dPhiIn        : -999;
	  deta2      = (eleProbe) ? eleProbe->dEtaIn        : -999;
	  ecalE2     = (eleProbe) ? eleProbe->ecalEnergy    : -999;
	  d02        = (eleProbe) ? eleProbe->d0            : -999;
	  dz2        = (eleProbe) ? eleProbe->dz            : -999;
	  isConv2    = (eleProbe) ? eleProbe->isConv        : 0;
	  nexphits2  = (eleProbe) ? eleProbe->nMissingHits  : 0;
	  typeBits2  = (eleProbe) ? eleProbe->typeBits      : 0;
	  q2         = (eleProbe) ? eleProbe->q : -q1;

	  // determine event category
	  if(eleProbe) {
	    if(passEleID(eleProbe,info->rhoIso)) {
	      
	      if(isEleTriggerObj(triggerMenu, eleProbe->hltMatchBits, kFALSE, isData)) {
		icat=eEleEle2HLT;  
	      } 
	      else if(isEleTriggerObj(triggerMenu, eleProbe->hltMatchBits, kTRUE, isData)) {
		icat=eEleEle1HLT1L1; 
	      }
	      else { icat=eEleEle1HLT; }
	    }
	    else { icat=eEleEleNoSel; } 
	  } 
	  else { icat=eEleSC; }
	  
	}

	if(q1 == q2)         continue;  // opposite charge requirement

	// mass window
	TLorentzVector vDilep = vTag + vProbe;
	if((vDilep.M()<MASS_LOW) || (vDilep.M()>MASS_HIGH)) continue;

	if(icat==0) continue;

	//******** We have a Z candidate! HURRAY! ********
	nsel+=weight;
	nselvar+=weight*weight;

	// Perform matching of dileptons to GEN leptons from Z decay

	Int_t glepq1=-99;
	Int_t glepq2=-99;
	TLorentzVector *gvec=new TLorentzVector(0,0,0,0);
	TLorentzVector *glep1=new TLorentzVector(0,0,0,0);
	TLorentzVector *glep2=new TLorentzVector(0,0,0,0);
	TLorentzVector *gph=new TLorentzVector(0,0,0,0);
	Bool_t hasGenMatch = kFALSE;
	if(isSignal && hasGen) {
	  toolbox::fillGen(genPartArr, BOSON_ID, gvec, glep1, glep2,&glepq1,&glepq2,1);
	  
	  Bool_t match1 = ( ((glep1) && toolbox::deltaR(vTag.Eta(), vTag.Phi(), glep1->Eta(), glep1->Phi())<0.3) || 
			    ((glep2) && toolbox::deltaR(vTag.Eta(), vTag.Phi(), glep2->Eta(), glep2->Phi())<0.3) );
	  
	  Bool_t match2 = ( ((glep1) && toolbox::deltaR(vProbe.Eta(), vProbe.Phi(), glep1->Eta(), glep1->Phi())<0.3) || 
			    ((glep2) && toolbox::deltaR(vProbe.Eta(), vProbe.Phi(), glep2->Eta(), glep2->Phi())<0.3) );
	  
	  if(match1 && match2) {
	    hasGenMatch = kTRUE;
	    if (gvec!=0) {
	      genV=new TLorentzVector(0,0,0,0);
	      genV->SetPtEtaPhiM(gvec->Pt(), gvec->Eta(), gvec->Phi(), gvec->M());
	      genVPt   = gvec->Pt();
	      genVPhi  = gvec->Phi();
	      genVy    = gvec->Rapidity();
	      genVMass = gvec->M();
	    }
	    else {
	      TLorentzVector tvec=*glep1+*glep2;
	      genV=new TLorentzVector(0,0,0,0);
	      genV->SetPtEtaPhiM(tvec.Pt(), tvec.Eta(), tvec.Phi(), tvec.M());
	      genVPt   = tvec.Pt();
	      genVPhi  = tvec.Phi();
	      genVy    = tvec.Rapidity();
	      genVMass = tvec.M();
	    }
	    delete gvec;
	    delete glep1;
	    delete glep2;
	    glep1=0; glep2=0; gvec=0;
	  }
	  else {
	    genV     = new TLorentzVector(0,0,0,0);
	    genVPt   = -999;
	    genVPhi  = -999;
	    genVy    = -999;
	    genVMass = -999;
	  }
	}
	
	if (hasGen) {
	  id_1      = gen->id_1;
	  id_2      = gen->id_2;
	  x_1       = gen->x_1;
	  x_2       = gen->x_2;
	  xPDF_1    = gen->xPDF_1;
	  xPDF_2    = gen->xPDF_2;
	  scalePDF  = gen->scalePDF;
	  weightPDF = gen->weight;
	}
	else {
	  id_1      = -999;
	  id_2      = -999;
	  x_1       = -999;
	  x_2       = -999;
	  xPDF_1    = -999;
	  xPDF_2    = -999;
	  scalePDF  = -999;
	  weightPDF = -999;
	  }

	//
	// Fill tree
	//
	runNum   = info->runNum;
	lumiSec  = info->lumiSec;
	evtNum   = info->evtNum;

	if (hasGenMatch) matchGen=1;
	else matchGen=0;

	category = icat;

	vertexArr->Clear();
	vertexBr->GetEntry(ientry);

	npv      = vertexArr->GetEntries();
	npu      = info->nPUmean;
        genWeight= hasGen ? gen->weight: 1.;
        PUWeight = puWeight;
	scale1fb = weight;
	scale1fbUp = weightUp;
	scale1fbDown = weightDown;
	met      = info->pfMETC;
	metPhi   = info->pfMETCphi;
	sumEt    = 0;
	tkMet    = info->trkMET;
	tkMetPhi = info->trkMETphi;
	tkSumEt  = 0;
	mvaMet   = info->mvaMET;
	mvaMetPhi = info->mvaMETphi; 
	mvaSumEt = 0;
	TVector2 vZPt((vDilep.Pt())*cos(vDilep.Phi()),(vDilep.Pt())*sin(vDilep.Phi()));

	puppiMet = info->puppET;
        puppiMetPhi = info->puppETphi;
	puppiSumEt = 0;
	lep1     = &vTag;
	lep2     = &vProbe;
	dilep    = &vDilep;
	sc1        = &vTagSC;
	sc2        = &vProbeSC;

	TVector2 vMet((info->pfMETC)*cos(info->pfMETCphi), (info->pfMETC)*sin(info->pfMETCphi));
	TVector2 vU = -1.0*(vMet+vZPt);
	u1 = ((vDilep.Px())*(vU.Px()) + (vDilep.Py())*(vU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
	u2 = ((vDilep.Px())*(vU.Py()) - (vDilep.Py())*(vU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|
	
	TVector2 vTkMet((info->trkMET)*cos(info->trkMETphi), (info->trkMET)*sin(info->trkMETphi));        
	TVector2 vTkU = -1.0*(vTkMet+vZPt);
	tkU1 = ((vDilep.Px())*(vTkU.Px()) + (vDilep.Py())*(vTkU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
	tkU2 = ((vDilep.Px())*(vTkU.Py()) - (vDilep.Py())*(vTkU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|
	
	TVector2 vMvaMet((info->mvaMET)*cos(info->mvaMETphi), (info->mvaMET)*sin(info->mvaMETphi));
	TVector2 vMvaU = -1.0*(vMvaMet+vZPt);
	mvaU1 = ((vDilep.Px())*(vMvaU.Px()) + (vDilep.Py())*(vMvaU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
	mvaU2 = ((vDilep.Px())*(vMvaU.Py()) - (vDilep.Py())*(vMvaU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|
        
	TVector2 vPuppiMet((info->puppET)*cos(info->puppETphi), (info->puppET)*sin(info->puppETphi));
	TVector2 vPuppiU = -1.0*(vPuppiMet+vZPt);
	puppiU1 = ((vDilep.Px())*(vPuppiU.Px()) + (vDilep.Py())*(vPuppiU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
	puppiU2 = ((vDilep.Px())*(vPuppiU.Py()) - (vDilep.Py())*(vPuppiU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|

	outTree->Fill();
	delete genV;
	genV=0, dilep=0, lep1=0, lep2=0, sc1=0, sc2=0;
      }
      delete infile;
      infile=0, eventTree=0;    
      
      cout << nsel  << " +/- " << sqrt(nselvar);
      if(!isData) cout << " per 1/fb";
      cout << endl;
    }
    outFile->Write();
    outFile->Close(); 
  }
  delete h_rw;
  delete f_rw;
  delete info;
  delete gen;
  delete genPartArr;
  delete electronArr;
  delete scArr;
  delete vertexArr;
    
  //--------------------------------------------------------------------------------------------------------------
  // Output
  //==============================================================================================================
   
  cout << "*" << endl;
  cout << "* SUMMARY" << endl;
  cout << "*--------------------------------------------------" << endl;
  cout << " Z -> e e" << endl;
  cout << "  Mass window: [" << MASS_LOW << ", " << MASS_HIGH << "]" << endl;
  cout << "  pT > " << PT_CUT << endl;
  cout << "  |eta| < " << ETA_CUT << endl;
  cout << endl;
  
  cout << endl;
  cout << "  <> Output saved in " << outputDir << "/" << endl;    
  cout << endl;  
      
  gBenchmark->Show("selectZee"); 
}
Пример #4
0
void selectZmm(const TString conf="zmm.conf", // input file
               const TString outputDir=".",   // output directory
	       const Bool_t  doScaleCorr=0,    // apply energy scale corrections
	       const Bool_t  doPU=0
) {
  gBenchmark->Start("selectZmm");

  //--------------------------------------------------------------------------------------------------------------
  // Settings 
  //============================================================================================================== 

  const Double_t MASS_LOW  = 40;
  const Double_t MASS_HIGH = 200;
  const Double_t PT_CUT    = 22;
  const Double_t ETA_CUT   = 2.4;
  const Double_t MUON_MASS = 0.105658369;

  const Int_t BOSON_ID  = 23;
  const Int_t LEPTON_ID = 13;

  // load trigger menu                                                                                                  
  const baconhep::TTrigger triggerMenu("../../BaconAna/DataFormats/data/HLT_50nsGRun");

  // load pileup reweighting file                                                                                       
  TFile *f_rw = TFile::Open("../Tools/puWeights_76x.root", "read");

  TH1D *h_rw = (TH1D*) f_rw->Get("puWeights");
  TH1D *h_rw_up = (TH1D*) f_rw->Get("puWeightsUp");
  TH1D *h_rw_down = (TH1D*) f_rw->Get("puWeightsDown");


  if (h_rw==NULL) cout<<"WARNING h_rw == NULL"<<endl;
  if (h_rw_up==NULL) cout<<"WARNING h_rw == NULL"<<endl;
  if (h_rw_down==NULL) cout<<"WARNING h_rw == NULL"<<endl;

  //--------------------------------------------------------------------------------------------------------------
  // Main analysis code 
  //==============================================================================================================  

  enum { eMuMu2HLT=1, eMuMu1HLT1L1, eMuMu1HLT, eMuMuNoSel, eMuSta, eMuTrk };  // event category enum
  
  vector<TString>  snamev;      // sample name (for output files)  
  vector<CSample*> samplev;     // data/MC samples

  //
  // parse .conf file
  //
  confParse(conf, snamev, samplev);
  const Bool_t hasData = (samplev[0]->fnamev.size()>0);

  // Create output directory
  gSystem->mkdir(outputDir,kTRUE);
  const TString ntupDir = outputDir + TString("/ntuples");
  gSystem->mkdir(ntupDir,kTRUE);
  
  //
  // Declare output ntuple variables
  //
  UInt_t  runNum, lumiSec, evtNum;
  UInt_t  matchGen;
  UInt_t  category;
  UInt_t  npv, npu;
  UInt_t  id_1, id_2;
  Double_t x_1, x_2, xPDF_1, xPDF_2;
  Double_t scalePDF, weightPDF;
  TLorentzVector *genV=0;
  Float_t genVPt, genVPhi, genVy, genVMass;
  Float_t genWeight, PUWeight;
  Float_t scale1fb,scale1fbUp,scale1fbDown;
  Float_t met, metPhi, sumEt, u1, u2;
  Float_t tkMet, tkMetPhi, tkSumEt, tkU1, tkU2;
  Float_t mvaMet, mvaMetPhi, mvaSumEt, mvaU1, mvaU2;
  Float_t puppiMet, puppiMetPhi, puppiSumEt, puppiU1, puppiU2;
  Int_t   q1, q2;
  TLorentzVector *dilep=0, *lep1=0, *lep2=0;
  ///// muon specific /////
  Float_t trkIso1, emIso1, hadIso1, trkIso2, emIso2, hadIso2;
  Float_t pfChIso1, pfGamIso1, pfNeuIso1, pfCombIso1, pfChIso2, pfGamIso2, pfNeuIso2, pfCombIso2;
  Float_t d01, dz1, d02, dz2;
  Float_t muNchi21,  muNchi22;
  UInt_t nPixHits1, nTkLayers1, nPixHits2, nTkLayers2;
  UInt_t nValidHits1, nMatch1, nValidHits2, nMatch2;
  UInt_t typeBits1, typeBits2;
  TLorentzVector *sta1=0, *sta2=0;
  
  // Data structures to store info from TTrees
  baconhep::TEventInfo *info   = new baconhep::TEventInfo();
  baconhep::TGenEventInfo *gen = new baconhep::TGenEventInfo();
  TClonesArray *genPartArr = new TClonesArray("baconhep::TGenParticle");
  TClonesArray *muonArr    = new TClonesArray("baconhep::TMuon");
  TClonesArray *vertexArr  = new TClonesArray("baconhep::TVertex");
  
  TFile *infile=0;
  TTree *eventTree=0;

    
  //
  // loop over samples
  //  
  for(UInt_t isam=0; isam<samplev.size(); isam++) {
    // Assume data sample is first sample in .conf file
    // If sample is empty (i.e. contains no ntuple files), skip to next sample
    Bool_t isData=kFALSE;
    if(isam==0 && !hasData) continue;
    else if (isam==0) isData=kTRUE;
    
    // Assume signal sample is given name "zmm" - flag to store GEN Z kinematics
    Bool_t isSignal = (snamev[isam].CompareTo("zmm",TString::kIgnoreCase)==0);
    // flag to reject Z->mm events when selecting at wrong-flavor background events
    Bool_t isWrongFlavor = (snamev[isam].CompareTo("zxx",TString::kIgnoreCase)==0);
    
    CSample* samp = samplev[isam];
    
    //
    // Set up output ntuple
    //
    TString outfilename = ntupDir + TString("/") + snamev[isam] + TString("_select.root");
    if(isam!=0 && !doScaleCorr) outfilename = ntupDir + TString("/") + snamev[isam] + TString("_select.raw.root");
    
    TFile *outFile = new TFile(outfilename,"RECREATE"); 
    TTree *outTree = new TTree("Events","Events");
    outTree->Branch("runNum",      &runNum,     "runNum/i");      // event run number
    outTree->Branch("lumiSec",     &lumiSec,    "lumiSec/i");     // event lumi section
    outTree->Branch("evtNum",      &evtNum,     "evtNum/i");      // event number
    outTree->Branch("matchGen",    &matchGen,   "matchGen/i");    // event has both leptons matched to MC Z->ll
    outTree->Branch("category",    &category,   "category/i");    // dilepton category
    outTree->Branch("id_1",        &id_1,       "id_1/i");        // PDF info -- parton ID for parton 1
    outTree->Branch("id_2",        &id_2,       "id_2/i");        // PDF info -- parton ID for parton 2
    outTree->Branch("x_1",         &x_1,        "x_1/d");         // PDF info -- x for parton 1
    outTree->Branch("x_2",         &x_2,        "x_2/d");         // PDF info -- x for parton 2
    outTree->Branch("xPDF_1",      &xPDF_1,     "xPDF_1/d");      // PDF info -- x*F for parton 1
    outTree->Branch("xPDF_2",      &xPDF_2,     "xPDF_2/d");      // PDF info -- x*F for parton 2
    outTree->Branch("scalePDF",    &scalePDF,   "scalePDF/d");    // PDF info -- energy scale of parton interaction
    outTree->Branch("weightPDF",   &weightPDF,  "weightPDF/d");   // PDF info -- PDF weight
    outTree->Branch("npv",         &npv,        "npv/i");         // number of primary vertices
    outTree->Branch("npu",         &npu,        "npu/i");         // number of in-time PU events (MC)
    outTree->Branch("genV",        "TLorentzVector",  &genV);     // GEN boson 4-vector (signal MC)
    outTree->Branch("genVPt",      &genVPt,     "genVPt/F");      // GEN boson pT (signal MC)
    outTree->Branch("genVPhi",     &genVPhi,    "genVPhi/F");     // GEN boson phi (signal MC)
    outTree->Branch("genVy",       &genVy,      "genVy/F");       // GEN boson rapidity (signal MC)
    outTree->Branch("genVMass",    &genVMass,   "genVMass/F");    // GEN boson mass (signal MC)
    outTree->Branch("genWeight",   &genWeight,  "genWeight/F");
    outTree->Branch("PUWeight",    &PUWeight,   "PUWeight/F");
    outTree->Branch("scale1fb",    &scale1fb,   "scale1fb/F");    // event weight per 1/fb (MC)
    outTree->Branch("scale1fbUp",    &scale1fbUp,   "scale1fbUp/F");    // event weight per 1/fb (MC)
    outTree->Branch("scale1fbDown",    &scale1fbDown,   "scale1fbDown/F");    // event weight per 1/fb (MC)
    outTree->Branch("met",         &met,        "met/F");         // MET
    outTree->Branch("metPhi",      &metPhi,     "metPhi/F");      // phi(MET)
    outTree->Branch("sumEt",       &sumEt,      "sumEt/F");       // Sum ET
    outTree->Branch("u1",          &u1,         "u1/F");          // parallel component of recoil
    outTree->Branch("u2",          &u2,         "u2/F");          // perpendicular component of recoil
    outTree->Branch("tkMet",       &tkMet,      "tkMet/F");       // MET (track MET)
    outTree->Branch("tkMetPhi",    &tkMetPhi,   "tkMetPhi/F");    // phi(MET) (track MET)
    outTree->Branch("tkSumEt",     &tkSumEt,    "tkSumEt/F");     // Sum ET (track MET)
    outTree->Branch("tkU1",        &tkU1,       "tkU1/F");        // parallel component of recoil (track MET)
    outTree->Branch("tkU2",        &tkU2,       "tkU2/F");        // perpendicular component of recoil (track MET)
    outTree->Branch("mvaMet",      &mvaMet,     "mvaMet/F");      // MVA MET
    outTree->Branch("mvaMetPhi",   &mvaMetPhi,  "mvaMetPhi/F");   // phi(MVA MET)
    outTree->Branch("mvaSumEt",    &mvaSumEt,   "mvaSumEt/F");    // Sum ET (mva MET)
    outTree->Branch("mvaU1",       &mvaU1,      "mvaU1/F");       // parallel component of recoil (mva MET)
    outTree->Branch("mvaU2",       &mvaU2,      "mvaU2/F");       // perpendicular component of recoil (mva MET) 
    outTree->Branch("puppiMet",    &puppiMet,   "puppiMet/F");      // Puppi MET
    outTree->Branch("puppiMetPhi", &puppiMetPhi,"puppiMetPhi/F");   // phi(Puppi MET)
    outTree->Branch("puppiSumEt",  &puppiSumEt, "puppiSumEt/F");    // Sum ET (Puppi MET)
    outTree->Branch("puppiU1",     &puppiU1,    "puppiU1/F");       // parallel component of recoil (Puppi MET)
    outTree->Branch("puppiU2",     &puppiU2,    "puppiU2/F");       // perpendicular component of recoil (Puppi MET)
    outTree->Branch("q1",          &q1,         "q1/I");          // charge of tag lepton
    outTree->Branch("q2",          &q2,         "q2/I");          // charge of probe lepton
    outTree->Branch("dilep",       "TLorentzVector", &dilep);     // di-lepton 4-vector
    outTree->Branch("lep1",        "TLorentzVector", &lep1);      // tag lepton 4-vector
    outTree->Branch("lep2",        "TLorentzVector", &lep2);      // probe lepton 4-vector
    ///// muon specific /////
    outTree->Branch("trkIso1",     &trkIso1,     "trkIso1/F");       // track isolation of tag lepton
    outTree->Branch("trkIso2",     &trkIso2,     "trkIso2/F");       // track isolation of probe lepton
    outTree->Branch("emIso1",      &emIso1,      "emIso1/F");        // ECAL isolation of tag lepton
    outTree->Branch("emIso2",      &emIso2,      "emIso2/F");        // ECAL isolation of probe lepton
    outTree->Branch("hadIso1",     &hadIso1,     "hadIso1/F");       // HCAL isolation of tag lepton
    outTree->Branch("hadIso2",     &hadIso2,     "hadIso2/F");       // HCAL isolation of probe lepton
    outTree->Branch("pfChIso1",    &pfChIso1,    "pfChIso1/F");      // PF charged hadron isolation of tag lepton
    outTree->Branch("pfChIso2",    &pfChIso2,    "pfChIso2/F");      // PF charged hadron isolation of probe lepton
    outTree->Branch("pfGamIso1",   &pfGamIso1,   "pfGamIso1/F");     // PF photon isolation of tag lepton
    outTree->Branch("pfGamIso2",   &pfGamIso2,   "pfGamIso2/F");     // PF photon isolation of probe lepton
    outTree->Branch("pfNeuIso1",   &pfNeuIso1,   "pfNeuIso1/F");     // PF neutral hadron isolation of tag lepton
    outTree->Branch("pfNeuIso2",   &pfNeuIso2,   "pfNeuIso2/F");     // PF neutral hadron isolation of probe lepton
    outTree->Branch("pfCombIso1",  &pfCombIso1,  "pfCombIso1/F");    // PF combined isolation of tag lepton
    outTree->Branch("pfCombIso2",  &pfCombIso2,  "pfCombIso2/F");    // PF combined isolation of probe lepton    
    outTree->Branch("d01",         &d01,         "d01/F");           // transverse impact parameter of tag lepton
    outTree->Branch("d02",         &d02,         "d02/F");           // transverse impact parameter of probe lepton	 
    outTree->Branch("dz1",         &dz1,         "dz1/F");           // longitudinal impact parameter of tag lepton
    outTree->Branch("dz2",         &dz2,         "dz2/F");           // longitudinal impact parameter of probe lepton	 
    outTree->Branch("muNchi21",    &muNchi21,    "muNchi21/F");      // muon fit normalized chi^2 of tag lepton
    outTree->Branch("muNchi22",    &muNchi22,    "muNchi22/F");      // muon fit normalized chi^2 of probe lepton
    outTree->Branch("nPixHits1",   &nPixHits1,	 "nPixHits1/i");     // number of pixel hits of tag muon
    outTree->Branch("nPixHits2",   &nPixHits2,	 "nPixHits2/i");     // number of pixel hits of probe muon
    outTree->Branch("nTkLayers1",  &nTkLayers1,  "nTkLayers1/i");    // number of tracker layers of tag muon
    outTree->Branch("nTkLayers2",  &nTkLayers2,  "nTkLayers2/i");    // number of tracker layers of probe muon
    outTree->Branch("nMatch1",     &nMatch1,	 "nMatch1/i");       // number of matched segments of tag muon
    outTree->Branch("nMatch2",     &nMatch2,	 "nMatch2/i");       // number of matched segments of probe muon 
    outTree->Branch("nValidHits1", &nValidHits1, "nValidHits1/i");   // number of valid muon hits of tag muon
    outTree->Branch("nValidHits2", &nValidHits2, "nValidHits2/i");   // number of valid muon hits of probe muon
    outTree->Branch("typeBits1",   &typeBits1,   "typeBits1/i");     // muon type of tag muon
    outTree->Branch("typeBits2",   &typeBits2,   "typeBits2/i");     // muon type of probe muon
    outTree->Branch("sta1",        "TLorentzVector", &sta1);         // tag standalone muon 4-vector
    outTree->Branch("sta2",        "TLorentzVector", &sta2);         // probe standalone muon 4-vector
    
    //
    // loop through files
    //
    const UInt_t nfiles = samp->fnamev.size();
    for(UInt_t ifile=0; ifile<nfiles; ifile++) {  
      
      // Read input file and get the TTrees
      cout << "Processing " << samp->fnamev[ifile] << " [xsec = " << samp->xsecv[ifile] << " pb] ... "; cout.flush();
      infile = TFile::Open(samp->fnamev[ifile]); 
      assert(infile);
      if (samp->fnamev[ifile] == "/dev/null") 
	      {
	     	cout <<"-> Ignoring null input "<<endl; 
		continue;
	      }


      Bool_t hasJSON = kFALSE;
      baconhep::RunLumiRangeMap rlrm;
      if(samp->jsonv[ifile].CompareTo("NONE")!=0) { 
        hasJSON = kTRUE;
	rlrm.addJSONFile(samp->jsonv[ifile].Data()); 
      }
  
      eventTree = (TTree*)infile->Get("Events"); assert(eventTree);  
      eventTree->SetBranchAddress("Info", &info);      TBranch *infoBr = eventTree->GetBranch("Info");
      eventTree->SetBranchAddress("Muon", &muonArr);   TBranch *muonBr = eventTree->GetBranch("Muon");
      eventTree->SetBranchAddress("PV",   &vertexArr); TBranch *vertexBr = eventTree->GetBranch("PV");
      Bool_t hasGen = eventTree->GetBranchStatus("GenEvtInfo");
      TBranch *genBr=0, *genPartBr=0;
      if(hasGen) {
        eventTree->SetBranchAddress("GenEvtInfo", &gen); genBr = eventTree->GetBranch("GenEvtInfo");
	eventTree->SetBranchAddress("GenParticle",&genPartArr); genPartBr = eventTree->GetBranch("GenParticle");
      }

      // Compute MC event weight per 1/fb
      const Double_t xsec = samp->xsecv[ifile];
      Double_t totalWeight=0;
      Double_t totalWeightUp=0;
      Double_t totalWeightDown=0;
      Double_t puWeight=0;
      Double_t puWeightUp=0;
      Double_t puWeightDown=0;

      if (hasGen) {
	for(UInt_t ientry=0; ientry<eventTree->GetEntries(); ientry++) {
	  infoBr->GetEntry(ientry);
	  genBr->GetEntry(ientry);
	  puWeight = doPU ? h_rw->GetBinContent(h_rw->FindBin(info->nPUmean)) : 1.;
	  puWeightUp = doPU ? h_rw_up->GetBinContent(h_rw_up->FindBin(info->nPUmean)) : 1.;
	  puWeightDown = doPU ? h_rw_down->GetBinContent(h_rw_down->FindBin(info->nPUmean)) : 1.;
	  totalWeight+=gen->weight*puWeight;
	  totalWeightUp+=gen->weight*puWeightUp;
	  totalWeightDown+=gen->weight*puWeightDown;
	}
      }
      else if (not isData){
	for(UInt_t ientry=0; ientry<eventTree->GetEntries(); ientry++) {
	  puWeight = doPU ? h_rw->GetBinContent(h_rw->FindBin(info->nPUmean)) : 1.;
	  puWeightUp = doPU ? h_rw_up->GetBinContent(h_rw_up->FindBin(info->nPUmean)) : 1.;
	  puWeightDown = doPU ? h_rw_down->GetBinContent(h_rw_down->FindBin(info->nPUmean)) : 1.;
	  totalWeight+= 1.0*puWeight;
	  totalWeightUp+= 1.0*puWeightUp;
	  totalWeightDown+= 1.0*puWeightDown;
	}

      }
   
      //
      // loop over events
      //
      Double_t nsel=0, nselvar=0;
      for(UInt_t ientry=0; ientry<eventTree->GetEntries(); ientry++) {
        infoBr->GetEntry(ientry);

	if(ientry%1000000==0) cout << "Processing event " << ientry << ". " << (double)ientry/(double)eventTree->GetEntries()*100 << " percent done with this file." << endl;

	Double_t weight=1;
	Double_t weightUp=1;
	Double_t weightDown=1;
    if(xsec>0 && totalWeight>0) weight = xsec/totalWeight;
	if(xsec>0 && totalWeightUp>0) weightUp = xsec/totalWeightUp;
	if(xsec>0 && totalWeightDown>0) weightDown = xsec/totalWeightDown;
	if(hasGen) {
	  genPartArr->Clear();
	  genBr->GetEntry(ientry);
          genPartBr->GetEntry(ientry);
	  puWeight = doPU ? h_rw->GetBinContent(h_rw->FindBin(info->nPUmean)) : 1.;
	  puWeightUp = doPU ? h_rw_up->GetBinContent(h_rw_up->FindBin(info->nPUmean)) : 1.;
	  puWeightDown = doPU ? h_rw_down->GetBinContent(h_rw_down->FindBin(info->nPUmean)) : 1.;
	  weight*=gen->weight*puWeight;
	  weightUp*=gen->weight*puWeightUp;
	  weightDown*=gen->weight*puWeightDown;
	}

	// veto z -> xx decays for signal and z -> mm for bacground samples (needed for inclusive DYToLL sample)
        if (isWrongFlavor && hasGen && fabs(toolbox::flavor(genPartArr, BOSON_ID))==LEPTON_ID) continue;
        else if (isSignal && hasGen && fabs(toolbox::flavor(genPartArr, BOSON_ID))!=LEPTON_ID) continue;
     
        // check for certified lumi (if applicable)
        baconhep::RunLumiRangeMap::RunLumiPairType rl(info->runNum, info->lumiSec);      
        if(hasJSON && !rlrm.hasRunLumi(rl)) continue;

        // trigger requirement               
        if (!isMuonTrigger(triggerMenu, info->triggerBits)) continue;

        // good vertex requirement
        if(!(info->hasGoodPV)) continue;

	muonArr->Clear();
        muonBr->GetEntry(ientry);

	TLorentzVector vTag(0,0,0,0);
	TLorentzVector vTagSta(0,0,0,0);
	Double_t tagPt=0;
	Double_t Pt1=0;
	Double_t Pt2=0;
	Int_t itag=-1;
	
        for(Int_t i1=0; i1<muonArr->GetEntriesFast(); i1++) {
          const baconhep::TMuon *tag = (baconhep::TMuon*)((*muonArr)[i1]);

          // apply scale and resolution corrections to MC
          Double_t tagpt_corr = tag->pt;
          if(doScaleCorr && snamev[isam].CompareTo("data",TString::kIgnoreCase)!=0)
            tagpt_corr = gRandom->Gaus(tag->pt*getMuScaleCorr(tag->eta,0),getMuResCorr(tag->eta,0));
	
	  if(tagpt_corr     < PT_CUT)        continue;  // lepton pT cut
	  if(fabs(tag->eta) > ETA_CUT)       continue;  // lepton |eta| cut
	  if(!passMuonID(tag))               continue;  // lepton selection

	  double Mu_Pt=0;
	  if(doScaleCorr) {
	    Mu_Pt=gRandom->Gaus(tag->pt*getMuScaleCorr(tag->eta,0),getMuResCorr(tag->eta,0));
	  }
	  else
	    {
	      Mu_Pt=tag->pt;
	    }

	  if(Mu_Pt>Pt1)
	    {
	      Pt2=Pt1;
	      Pt1=Mu_Pt;
	    }
	  else if(Mu_Pt>Pt2&&Mu_Pt<Pt1)
	    {
	      Pt2=Mu_Pt;
	    }

          if(!isMuonTriggerObj(triggerMenu, tag->hltMatchBits, kFALSE)) continue;

	  if(Mu_Pt<tagPt) continue;

	  tagPt=Mu_Pt;
	  itag=i1;
        
          // apply scale and resolution corrections to MC
          if(doScaleCorr && snamev[isam].CompareTo("data",TString::kIgnoreCase)!=0) {
            vTag.SetPtEtaPhiM(tagpt_corr,tag->eta,tag->phi,MUON_MASS);
            vTagSta.SetPtEtaPhiM(gRandom->Gaus(tag->staPt*getMuScaleCorr(tag->eta,0),getMuResCorr(tag->eta,0)),tag->staEta,tag->staPhi,MUON_MASS);
          } else {
            vTag.SetPtEtaPhiM(tag->pt,tag->eta,tag->phi,MUON_MASS);
            vTagSta.SetPtEtaPhiM(tag->staPt,tag->staEta,tag->staPhi,MUON_MASS);
          }

	  trkIso1     = tag->trkIso;
	  emIso1      = tag->ecalIso;	    
	  hadIso1     = tag->hcalIso;
	  pfChIso1    = tag->chHadIso;
	  pfGamIso1   = tag->gammaIso;
	  pfNeuIso1   = tag->neuHadIso;
	  pfCombIso1  = tag->chHadIso + TMath::Max(tag->neuHadIso + tag->gammaIso - 
						   0.5*(tag->puIso),Double_t(0));
	  d01         = tag->d0;
	  dz1         = tag->dz;
	  muNchi21    = tag->muNchi2;
	  nPixHits1   = tag->nPixHits;
	  nTkLayers1  = tag->nTkLayers;
	  nMatch1     = tag->nMatchStn;
	  nValidHits1 = tag->nValidHits;
	  typeBits1   = tag->typeBits;
	  q1 = tag->q;
	}

	if(tagPt<Pt2) continue;

	TLorentzVector vProbe(0,0,0,0); TLorentzVector vProbeSta(0,0,0,0);
	Double_t probePt=0;
	Int_t passID=false;
	UInt_t icat=0;

	for(Int_t i2=0; i2<muonArr->GetEntriesFast(); i2++) {
	  if(itag==i2) continue;
	  const baconhep::TMuon *probe = (baconhep::TMuon*)((*muonArr)[i2]);
	  

	  // apply scale and resolution corrections to MC
	  Double_t probept_corr = probe->pt;
	  if(doScaleCorr && snamev[isam].CompareTo("data",TString::kIgnoreCase)!=0)
	    probept_corr = gRandom->Gaus(probe->pt*getMuScaleCorr(probe->eta,0),getMuResCorr(probe->eta,0));

	  if(probept_corr     < PT_CUT)  continue;  // lepton pT cut
	  if(fabs(probe->eta) > ETA_CUT) continue;  // lepton |eta| cut

	  double Mu_Pt=probept_corr;
  
	  if(passID&&passMuonID(probe)&&Mu_Pt<probePt) continue;
	  if(passID&&!passMuonID(probe)) continue;
	  if(!passID&&!passMuonID(probe)&&Mu_Pt<probePt) continue;

	  if(!passID&&passMuonID(probe)) passID=true;

	  probePt=Mu_Pt;

	  // apply scale and resolution corrections to MC
	  if(doScaleCorr && snamev[isam].CompareTo("data",TString::kIgnoreCase)!=0) {
	    vProbe.SetPtEtaPhiM(probept_corr,probe->eta,probe->phi,MUON_MASS);
	    if(probe->typeBits & baconhep::EMuType::kStandalone)
	      vProbeSta.SetPtEtaPhiM(gRandom->Gaus(probe->staPt*getMuScaleCorr(probe->eta,0),getMuResCorr(probe->eta,0)),probe->staEta,probe->staPhi,MUON_MASS);
	  } else {
	    vProbe.SetPtEtaPhiM(probe->pt,probe->eta,probe->phi,MUON_MASS);
	    if(probe->typeBits & baconhep::EMuType::kStandalone)
	      vProbeSta.SetPtEtaPhiM(probe->staPt,probe->staEta,probe->staPhi,MUON_MASS);
	  }

	  trkIso2     = probe->trkIso;
	  emIso2      = probe->ecalIso;
	  hadIso2     = probe->hcalIso;
	  pfChIso2    = probe->chHadIso;
	  pfGamIso2   = probe->gammaIso;
	  pfNeuIso2   = probe->neuHadIso;
	  pfCombIso2  = probe->chHadIso + TMath::Max(probe->neuHadIso + probe->gammaIso - 
						     0.5*(probe->puIso),Double_t(0));
	  d02         = probe->d0;
	  dz2         = probe->dz;
	  muNchi22    = probe->muNchi2;
	  nPixHits2   = probe->nPixHits;
	  nTkLayers2  = probe->nTkLayers;
	  nMatch2     = probe->nMatchStn;
	  nValidHits2 = probe->nValidHits;
	  typeBits2   = probe->typeBits;
	  q2 = probe->q;

	  // determine event category
	  if(passMuonID(probe)) {
	    if(isMuonTriggerObj(triggerMenu, probe->hltMatchBits, kFALSE)) {
	      icat=eMuMu2HLT;
	    }
	    else if(isMuonTriggerObj(triggerMenu, probe->hltMatchBits, kTRUE)) {
	      icat=eMuMu1HLT1L1;
	  }
	    else {
	      icat=eMuMu1HLT;
	    }
	  }
	  else if(probe->typeBits & baconhep::EMuType::kGlobal) { icat=eMuMuNoSel; }
	  else if(probe->typeBits & baconhep::EMuType::kStandalone) { icat=eMuSta; }
	  else if(probe->nTkLayers>=6 && probe->nPixHits>=1)        { icat=eMuTrk; }
	}
	
	if(q1 == q2)         continue;  // opposite charge requirement
	    
	// mass window
	TLorentzVector vDilep = vTag + vProbe;
	if((vDilep.M()<MASS_LOW) || (vDilep.M()>MASS_HIGH)) continue;
	
	if(icat==0) continue;
	
	/******** We have a Z candidate! HURRAY! ********/
	nsel+=weight;
	nselvar+=weight*weight;
	
	// Perform matching of dileptons to GEN leptons from Z decay

	Int_t glepq1=-99;
	Int_t glepq2=-99;
	TLorentzVector *gvec=new TLorentzVector(0,0,0,0);
	TLorentzVector *glep1=new TLorentzVector(0,0,0,0);
	TLorentzVector *glep2=new TLorentzVector(0,0,0,0);
	TLorentzVector *gph=new TLorentzVector(0,0,0,0);
	Bool_t hasGenMatch = kFALSE;
	if(isSignal && hasGen) {
	  toolbox::fillGen(genPartArr, BOSON_ID, gvec, glep1, glep2,&glepq1,&glepq2,1);
	  
	  Bool_t match1 = ( ((glep1) && toolbox::deltaR(vTag.Eta(), vTag.Phi(), glep1->Eta(), glep1->Phi())<0.5) ||
			    ((glep2) && toolbox::deltaR(vTag.Eta(), vTag.Phi(), glep2->Eta(), glep2->Phi())<0.5) );
	  
	  Bool_t match2 = ( ((glep1) && toolbox::deltaR(vProbe.Eta(), vProbe.Phi(), glep1->Eta(), glep1->Phi())<0.5) ||
			    ((glep2) && toolbox::deltaR(vProbe.Eta(), vProbe.Phi(), glep2->Eta(), glep2->Phi())<0.5) );

	  if(match1 && match2) {
	    hasGenMatch = kTRUE;
	    if (gvec!=0) {
	      genV=new TLorentzVector(0,0,0,0);
	      genV->SetPtEtaPhiM(gvec->Pt(), gvec->Eta(), gvec->Phi(), gvec->M());
	      genVPt   = gvec->Pt();
	      genVPhi  = gvec->Phi();
	      genVy    = gvec->Rapidity();
	      genVMass = gvec->M();
	    }
	    else {
	      TLorentzVector tvec=*glep1+*glep2;
	      genV=new TLorentzVector(0,0,0,0);
	      genV->SetPtEtaPhiM(tvec.Pt(), tvec.Eta(), tvec.Phi(), tvec.M());
	      genVPt   = tvec.Pt();
	      genVPhi  = tvec.Phi();
	      genVy    = tvec.Rapidity();
	      genVMass = tvec.M();
	    }
	    delete gvec;
	    delete glep1;
	    delete glep2;
	    glep1=0; glep2=0; gvec=0;
	  }
	  else {
	    genV     = new TLorentzVector(0,0,0,0); 
	    genVPt   = -999;
	    genVPhi  = -999;
	    genVy    = -999;
	    genVMass = -999;
	  }
	}
	
	if (hasGen) {
	  id_1      = gen->id_1;
	  id_2      = gen->id_2;
	  x_1       = gen->x_1;
	  x_2       = gen->x_2;
	  xPDF_1    = gen->xPDF_1;
	  xPDF_2    = gen->xPDF_2;
	  scalePDF  = gen->scalePDF;
	  weightPDF = gen->weight;
	}
	else {
	  id_1      = -999;
	  id_2      = -999;
	  x_1       = -999;
	  x_2       = -999;
	  xPDF_1    = -999;
	  xPDF_2    = -999;
	  scalePDF  = -999;
	  weightPDF = -999;
	}
	
	//
	// Fill tree
	//
	runNum   = info->runNum;
	lumiSec  = info->lumiSec;
	evtNum   = info->evtNum;
	
	if (hasGenMatch) matchGen=1;
	else matchGen=0;
	
	category = icat;
	
	vertexArr->Clear();
	vertexBr->GetEntry(ientry);
	
	npv      = vertexArr->GetEntries();
	npu      = info->nPUmean;
	genWeight= hasGen ? gen->weight: 1.;
	PUWeight = puWeight;
	scale1fb = weight;
	scale1fbUp = weightUp;
	scale1fbDown = weightDown;
	met      = info->pfMETC;
	metPhi   = info->pfMETCphi;
	sumEt    = 0;
	tkMet    = info->trkMET;
	tkMetPhi = info->trkMETphi;
	tkSumEt  = 0;
	mvaMet   = info->mvaMET;
	mvaMetPhi = info->mvaMETphi;
	mvaSumEt = 0;
	TVector2 vZPt((vDilep.Pt())*cos(vDilep.Phi()),(vDilep.Pt())*sin(vDilep.Phi()));

        puppiMet = info->puppET;
        puppiMetPhi = info->puppETphi;
	puppiSumEt = 0;
	lep1     = &vTag;
	lep2     = &vProbe;
	dilep    = &vDilep;
	sta1        = &vTagSta;
	sta2        = &vProbeSta;
	
	TVector2 vMet((info->pfMETC)*cos(info->pfMETCphi), (info->pfMETC)*sin(info->pfMETCphi));
	TVector2 vU = -1.0*(vMet+vZPt);
	u1 = ((vDilep.Px())*(vU.Px()) + (vDilep.Py())*(vU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
	u2 = ((vDilep.Px())*(vU.Py()) - (vDilep.Py())*(vU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|
	
	TVector2 vTkMet((info->trkMET)*cos(info->trkMETphi), (info->trkMET)*sin(info->trkMETphi));
	TVector2 vTkU = -1.0*(vTkMet+vZPt);
	tkU1 = ((vDilep.Px())*(vTkU.Px()) + (vDilep.Py())*(vTkU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
	tkU2 = ((vDilep.Px())*(vTkU.Py()) - (vDilep.Py())*(vTkU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|
	
	TVector2 vMvaMet((info->mvaMET)*cos(info->mvaMETphi), (info->mvaMET)*sin(info->mvaMETphi));
	TVector2 vMvaU = -1.0*(vMvaMet+vZPt);
	mvaU1 = ((vDilep.Px())*(vMvaU.Px()) + (vDilep.Py())*(vMvaU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
	mvaU2 = ((vDilep.Px())*(vMvaU.Py()) - (vDilep.Py())*(vMvaU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|
        
        TVector2 vPuppiMet((info->puppET)*cos(info->puppETphi), (info->puppET)*sin(info->puppETphi));
	TVector2 vPuppiU = -1.0*(vPuppiMet+vZPt);
	puppiU1 = ((vDilep.Px())*(vPuppiU.Px()) + (vDilep.Py())*(vPuppiU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
	puppiU2 = ((vDilep.Px())*(vPuppiU.Py()) - (vDilep.Py())*(vPuppiU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|
	
        outTree->Fill();
	delete genV;
	genV=0, dilep=0, lep1=0, lep2=0, sta1=0, sta2=0;
      }
      delete infile;
      infile=0, eventTree=0;    
      
      cout << nsel  << " +/- " << sqrt(nselvar);
      if(!isData) cout << " per 1/fb";
      cout << endl;
    }
    outFile->Write();
    outFile->Close(); 
  }
  delete h_rw;
  delete h_rw_up;
  delete h_rw_down;
  delete f_rw;
  delete info;
  delete gen;
  delete genPartArr;
  delete muonArr;
  delete vertexArr;
    
  //--------------------------------------------------------------------------------------------------------------
  // Output
  //==============================================================================================================
   
  cout << "*" << endl;
  cout << "* SUMMARY" << endl;
  cout << "*--------------------------------------------------" << endl;
  cout << " Z -> mu mu" << endl;
  cout << "  Mass window: [" << MASS_LOW << ", " << MASS_HIGH << "]" << endl;
  cout << "  pT > " << PT_CUT << endl;
  cout << "  |eta| < " << ETA_CUT << endl;
  cout << endl;
  
  cout << endl;
  cout << "  <> Output saved in " << outputDir << "/" << endl;    
  cout << endl;  
      
  gBenchmark->Show("selectZmm"); 
}
Пример #5
0
void selectZeeSC(const TString conf="zee_sc.conf", // input file
		 const TString outputDir=".",   // output directory
		 const Bool_t  doScaleCorr=0    // apply energy scale corrections?
) {
  gBenchmark->Start("selectZee");

  //--------------------------------------------------------------------------------------------------------------
  // Settings 
  //============================================================================================================== 

  const Double_t MASS_LOW  = 40;
  const Double_t MASS_HIGH = 200;
  const Double_t PT_CUT    = 25;
  const Double_t ETA_CUT   = 2.5;
  const Double_t ELE_MASS  = 0.000511;
  
  const Double_t ECAL_GAP_LOW  = 1.4442;
  const Double_t ECAL_GAP_HIGH = 1.566;
  
  const Double_t escaleNbins  = 6;
  const Double_t escaleEta[]  = { 0.4,     0.8,     1.2,     1.4442,  2,        2.5 };
  const Double_t escaleCorr[] = { 1.00284, 1.00479, 1.00734, 1.00851, 1.00001,  0.982898 };

  const Int_t BOSON_ID  = 23;
  const Int_t LEPTON_ID = 11;

  //--------------------------------------------------------------------------------------------------------------
  // Main analysis code 
  //==============================================================================================================  

  enum { ePass=0, eFail };  // event category enum
  
  vector<TString>  snamev;      // sample name (for output files)  
  vector<CSample*> samplev;     // data/MC samples

  //
  // parse .conf file
  //
  confParse(conf, snamev, samplev);
  const Bool_t hasData = (samplev[0]->fnamev.size()>0);

  // Create output directory
  gSystem->mkdir(outputDir,kTRUE);
  const TString ntupDir = outputDir + TString("/ntuples");
  gSystem->mkdir(ntupDir,kTRUE);
  
  //
  // Declare output ntuple variables
  //
  UInt_t  runNum, lumiSec, evtNum;
  UInt_t  matchGen;
  UInt_t  category;
  UInt_t  npv, npu;
  UInt_t  id_1, id_2;
  Double_t x_1, x_2, xPDF_1, xPDF_2;
  Double_t scalePDF, weightPDF;
  TLorentzVector *genV=0;
  Float_t genVPt, genVPhi, genVy, genVMass;
  Float_t scale1fb;
  Float_t met, metPhi, sumEt, u1, u2;
  Float_t tkMet, tkMetPhi, tkSumEt, tkU1, tkU2;
  Float_t mvaMet, mvaMetPhi, mvaSumEt, mvaU1, mvaU2;
  Float_t ppMet, ppMetPhi, ppSumEt, ppU1, ppU2;
  Int_t   q1, q2;
  TLorentzVector *dilep=0, *lep1=0, *lep2=0;
  ///// electron specific /////
  Float_t trkIso1, emIso1, hadIso1, trkIso2, emIso2, hadIso2;
  Float_t pfChIso1, pfGamIso1, pfNeuIso1, pfCombIso1, pfChIso2, pfGamIso2, pfNeuIso2, pfCombIso2;
  Float_t sigieie1, hovere1, eoverp1, fbrem1, ecalE1, sigieie2, hovere2, eoverp2, fbrem2, ecalE2;
  Float_t dphi1, deta1, dphi2, deta2;
  Float_t d01, dz1, d02, dz2;
  UInt_t  isConv1, nexphits1, typeBits1, isConv2, nexphits2, typeBits2; 
  TLorentzVector *sc1=0, *sc2=0;
  
  // Data structures to store info from TTrees
  baconhep::TEventInfo *info   = new baconhep::TEventInfo();
  baconhep::TGenEventInfo *gen = new baconhep::TGenEventInfo();
  TClonesArray *genPartArr     = new TClonesArray("baconhep::TGenParticle");
  TClonesArray *electronArr    = new TClonesArray("baconhep::TElectron");
  TClonesArray *muonArr        = new TClonesArray("baconhep::TMuon");
  TClonesArray *scArr          = new TClonesArray("baconhep::TPhoton");
  
  TFile *infile=0;
  TTree *eventTree=0;
  
  //
  // loop over samples
  //  
  for(UInt_t isam=0; isam<samplev.size(); isam++) {
    
    // Assume data sample is first sample in .conf file
    // If sample is empty (i.e. contains no ntuple files), skip to next sample
    if(isam==0 && !hasData) continue;
    
    // Assume signal sample is given name "zee" - flag to store GEN Z kinematics
    Bool_t isSignal = (snamev[isam].CompareTo("zee",TString::kIgnoreCase)==0);  

    // flag to reject Z->ee events when selecting at wrong-flavor background events
    Bool_t isWrongFlavor = (snamev[isam].CompareTo("zxx",TString::kIgnoreCase)==0);  

    CSample* samp = samplev[isam];
  
    //
    // Set up output ntuple
    //
    TString outfilename = ntupDir + TString("/") + snamev[isam] + TString("_select.root");
    if(isam==0 && !doScaleCorr) outfilename = ntupDir + TString("/") + snamev[isam] + TString("_select.raw.root");
    TFile *outFile = new TFile(outfilename,"RECREATE"); 
    TTree *outTree = new TTree("Events","Events");
    outTree->Branch("runNum",     &runNum,     "runNum/i");      // event run number
    outTree->Branch("lumiSec",    &lumiSec,    "lumiSec/i");     // event lumi section
    outTree->Branch("evtNum",     &evtNum,     "evtNum/i");      // event number
    outTree->Branch("matchGen",   &matchGen,   "matchGen/i");    // event has both leptons matched to MC Z->ll
    outTree->Branch("category",   &category,   "category/i");    // dilepton category
    outTree->Branch("id_1",       &id_1,       "id_1/i");        // PDF info -- parton ID for parton 1
    outTree->Branch("id_2",       &id_2,       "id_2/i");        // PDF info -- parton ID for parton 2
    outTree->Branch("x_1",        &x_1,        "x_1/d");         // PDF info -- x for parton 1
    outTree->Branch("x_2",        &x_2,        "x_2/d");         // PDF info -- x for parton 2
    outTree->Branch("xPDF_1",     &xPDF_1,     "xPDF_1/d");      // PDF info -- x*F for parton 1
    outTree->Branch("xPDF_2",     &xPDF_2,     "xPDF_2/d");      // PDF info -- x*F for parton 2
    outTree->Branch("scalePDF",   &scalePDF,   "scalePDF/d");    // PDF info -- energy scale of parton interaction
    outTree->Branch("weightPDF",  &weightPDF,  "weightPDF/d");   // PDF info -- PDF weight
    outTree->Branch("npv",        &npv,        "npv/i");         // number of primary vertices
    outTree->Branch("npu",        &npu,        "npu/i");         // number of in-time PU events (MC)
    outTree->Branch("genV",      "TLorentzVector",  &genV);      // GEN boson 4-vector
    outTree->Branch("genVPt",     &genVPt,     "genVPt/F");      // GEN boson pT (signal MC)
    outTree->Branch("genVPhi",    &genVPhi,    "genVPhi/F");     // GEN boson phi (signal MC)
    outTree->Branch("genVy",      &genVy,      "genVy/F");       // GEN boson rapidity (signal MC)
    outTree->Branch("genVMass",   &genVMass,   "genVMass/F");    // GEN boson mass (signal MC)
    outTree->Branch("scale1fb",   &scale1fb,   "scale1fb/F");    // event weight per 1/fb (MC)
    outTree->Branch("met",        &met,        "met/F");         // MET
    outTree->Branch("metPhi",     &metPhi,     "metPhi/F");      // phi(MET)
    outTree->Branch("sumEt",      &sumEt,      "sumEt/F");       // Sum ET
    outTree->Branch("u1",         &u1,         "u1/F");          // parallel component of recoil
    outTree->Branch("u2",         &u2,         "u2/F");          // perpendicular component of recoil
    outTree->Branch("tkMet",      &tkMet,      "tkMet/F");       // MET (track MET)
    outTree->Branch("tkMetPhi",   &tkMetPhi,   "tkMetPhi/F");    // phi(MET) (track MET)
    outTree->Branch("tkSumEt",    &tkSumEt,    "tkSumEt/F");     // Sum ET (track MET)
    outTree->Branch("tkU1",       &tkU1,       "tkU1/F");        // parallel component of recoil (track MET)
    outTree->Branch("tkU2",       &tkU2,       "tkU2/F");        // perpendicular component of recoil (track MET)
    outTree->Branch("mvaMet",     &mvaMet,     "mvaMet/F");      // MVA MET
    outTree->Branch("mvaMetPhi",  &mvaMetPhi,  "mvaMetPhi/F");   // phi(MVA MET)
    outTree->Branch("mvaSumEt",   &mvaSumEt,   "mvaSumEt/F");    // Sum ET (mva MET)
    outTree->Branch("mvaU1",      &mvaU1,      "mvaU1/F");       // parallel component of recoil (mva MET)
    outTree->Branch("mvaU2",      &mvaU2,      "mvaU2/F");       // perpendicular component of recoil (mva MET)
    outTree->Branch("ppMet",      &ppMet,      "ppMet/F");       // PUPPI MET
    outTree->Branch("ppMetPhi",   &ppMetPhi,   "ppMetPhi/F");    // phi(PUPPI MET)
    outTree->Branch("ppSumEt",    &ppSumEt,    "ppSumEt/F");     // Sum ET (PUPPI MET)
    outTree->Branch("ppU1",       &ppU1,       "ppU1/F");        // parallel component of recoil (PUPPI MET)
    outTree->Branch("ppU2",       &ppU2,       "ppU2/F");        // perpendicular component of recoil (PUPPI MET)
    outTree->Branch("q1",         &q1,         "q1/I");          // charge of tag lepton
    outTree->Branch("q2",         &q2,         "q2/I");          // charge of probe lepton
    outTree->Branch("dilep",      "TLorentzVector",  &dilep);    // di-lepton 4-vector
    outTree->Branch("lep1",       "TLorentzVector",  &lep1);     // tag lepton 4-vector
    outTree->Branch("lep2",       "TLorentzVector",  &lep2);     // probe lepton 4-vector
    ///// electron specific /////
    outTree->Branch("trkIso1",    &trkIso1,    "trkIso1/F");     // track isolation of tag lepton
    outTree->Branch("trkIso2",    &trkIso2,    "trkIso2/F");     // track isolation of probe lepton
    outTree->Branch("emIso1",     &emIso1,     "emIso1/F");      // ECAL isolation of tag lepton
    outTree->Branch("emIso2",     &emIso2,     "emIso2/F");      // ECAL isolation of probe lepton
    outTree->Branch("hadIso1",    &hadIso1,    "hadIso1/F");     // HCAL isolation of tag lepton
    outTree->Branch("hadIso2",    &hadIso2,    "hadIso2/F");     // HCAL isolation of probe lepton
    outTree->Branch("pfChIso1",   &pfChIso1,   "pfChIso1/F");    // PF charged hadron isolation of tag lepton
    outTree->Branch("pfChIso2",   &pfChIso2,   "pfChIso2/F");    // PF charged hadron isolation of probe lepton
    outTree->Branch("pfGamIso1",  &pfGamIso1,  "pfGamIso1/F");   // PF photon isolation of tag lepton
    outTree->Branch("pfGamIso2",  &pfGamIso2,  "pfGamIso2/F");   // PF photon isolation of probe lepton
    outTree->Branch("pfNeuIso1",  &pfNeuIso1,  "pfNeuIso1/F");   // PF neutral hadron isolation of tag lepton
    outTree->Branch("pfNeuIso2",  &pfNeuIso2,  "pfNeuIso2/F");   // PF neutral hadron isolation of probe lepton
    outTree->Branch("pfCombIso1", &pfCombIso1, "pfCombIso1/F");  // PF combine isolation of tag lepton
    outTree->Branch("pfCombIso2", &pfCombIso2, "pfCombIso2/F");  // PF combined isolation of probe lepton    
    outTree->Branch("sigieie1",   &sigieie1,   "sigieie1/F");    // sigma-ieta-ieta of tag
    outTree->Branch("sigieie2",   &sigieie2,   "sigieie2/F");    // sigma-ieta-ieta of probe
    outTree->Branch("hovere1",    &hovere1,    "hovere1/F");     // H/E of tag
    outTree->Branch("hovere2",    &hovere2,    "hovere2/F");     // H/E of probe
    outTree->Branch("eoverp1",    &eoverp1,    "eoverp1/F");     // E/p of tag
    outTree->Branch("eoverp2",    &eoverp2,    "eoverp2/F");     // E/p of probe	 
    outTree->Branch("fbrem1",     &fbrem1,     "fbrem1/F");      // brem fraction of tag
    outTree->Branch("fbrem2",     &fbrem2,     "fbrem2/F");      // brem fraction of probe
    outTree->Branch("dphi1",      &dphi1,      "dphi1/F");       // GSF track - ECAL dphi of tag
    outTree->Branch("dphi2",      &dphi2,      "dphi2/F");       // GSF track - ECAL dphi of probe 	
    outTree->Branch("deta1",      &deta1,      "deta1/F");       // GSF track - ECAL deta of tag
    outTree->Branch("deta2",      &deta2,      "deta2/F");       // GSF track - ECAL deta of probe
    outTree->Branch("ecalE1",     &ecalE1,     "ecalE1/F");      // ECAL energy of tag
    outTree->Branch("ecalE2",     &ecalE2,     "ecalE2/F");      // ECAL energy of probe
    outTree->Branch("d01",        &d01,        "d01/F");	 // transverse impact parameter of tag
    outTree->Branch("d02",        &d02,        "d02/F");	 // transverse impact parameter of probe	  
    outTree->Branch("dz1",        &dz1,        "dz1/F");	 // longitudinal impact parameter of tag
    outTree->Branch("dz2",        &dz2,        "dz2/F");	 // longitudinal impact parameter of probe
    outTree->Branch("isConv1",    &isConv1,    "isConv1/i");     // conversion filter flag of tag lepton
    outTree->Branch("isConv2",    &isConv2,    "isConv2/i");     // conversion filter flag of probe lepton
    outTree->Branch("nexphits1",  &nexphits1,  "nexphits1/i");   // number of missing expected inner hits of tag lepton
    outTree->Branch("nexphits2",  &nexphits2,  "nexphits2/i");   // number of missing expected inner hits of probe lepton
    outTree->Branch("typeBits1",  &typeBits1,  "typeBits1/i");   // electron type of tag lepton
    outTree->Branch("typeBits2",  &typeBits2,  "typeBits2/i");   // electron type of probe lepton
    outTree->Branch("sc1",       "TLorentzVector",  &sc1);       // tag supercluster 4-vector
    outTree->Branch("sc2",       "TLorentzVector",  &sc2);       // probe supercluster 4-vector

    //
    // loop through files
    //
    const UInt_t nfiles = samp->fnamev.size();
    for(UInt_t ifile=0; ifile<nfiles; ifile++) {  

      // Read input file and get the TTrees
      cout << "Processing " << samp->fnamev[ifile] << " [xsec = " << samp->xsecv[ifile] << " pb] ... " << endl; cout.flush();
      infile = TFile::Open(samp->fnamev[ifile]); 
      assert(infile);

      const baconhep::TTrigger triggerMenu("../../BaconAna/DataFormats/data/HLT_50nsGRun");
      UInt_t trigger, trigObjL1, trigObjHLT;
      if (isam==0) {
        trigger = triggerMenu.getTriggerBit("HLT_Ele23_WPLoose_Gsf_v*"); //data trigger
        trigObjL1  = 1; //data
        trigObjHLT = 2; //data
      }
      else {
        trigger = triggerMenu.getTriggerBit("HLT_Ele23_WP75_Gsf_v*");
        trigObjL1  = 4; //triggerMenu.getTriggerObjectBit("HLT_Ele22_WP75_Gsf_v*", "hltL1sL1SingleEG20");
        trigObjHLT = 5; //triggerMenu.getTriggerObjectBit("HLT_Ele23_WP75_Gsf_v*", "hltEle23WP75GsfTrackIsoFilter");
      }

      //Bool_t hasJSON = kFALSE;
      //baconhep::RunLumiRangeMap rlrm;
      //if(samp->jsonv[ifile].CompareTo("NONE")!=0) { 
      //hasJSON = kTRUE;
      //rlrm.AddJSONFile(samp->jsonv[ifile].Data()); 
      //}
  
      eventTree = (TTree*)infile->Get("Events");
      assert(eventTree);  
      eventTree->SetBranchAddress("Info",     &info);        TBranch *infoBr     = eventTree->GetBranch("Info");
      eventTree->SetBranchAddress("Electron", &electronArr); TBranch *electronBr = eventTree->GetBranch("Electron");
      eventTree->SetBranchAddress("Muon",     &muonArr);     TBranch *muonBr     = eventTree->GetBranch("Muon");
      eventTree->SetBranchAddress("Photon",   &scArr);       TBranch *scBr       = eventTree->GetBranch("Photon");
      Bool_t hasGen = eventTree->GetBranchStatus("GenEvtInfo");
      TBranch *genBr=0, *genPartBr=0;
      if(hasGen) {
        eventTree->SetBranchAddress("GenEvtInfo", &gen); genBr = eventTree->GetBranch("GenEvtInfo");
	eventTree->SetBranchAddress("GenParticle",&genPartArr); genPartBr = eventTree->GetBranch("GenParticle");
      }

      // Compute MC event weight per 1/fb
      const Double_t xsec = samp->xsecv[ifile];
      Double_t totalWeight=1;
      if (hasGen) {
	TH1D *hall = new TH1D("hall", "", 1,0,1);
	eventTree->Draw("0.5>>hall", "GenEvtInfo->weight");
	totalWeight=hall->Integral();
	delete hall;
	hall=0;
      }

      //
      // loop over events
      //
      Double_t nsel=0, nselvar=0;
      for(UInt_t ientry=0; ientry<eventTree->GetEntries()/10; ientry++) {
        infoBr->GetEntry(ientry);

        if(ientry%1000000==0) cout << "Processing event " << ientry << ". " << (double)ientry/(double)eventTree->GetEntries()*100 << " percent done with this file." << endl;

        Double_t weight=1;
        if(xsec>0 && totalWeight>0) weight = xsec/totalWeight;
	if(hasGen) {
	  genPartArr->Clear();
	  genBr->GetEntry(ientry);
	  genPartBr->GetEntry(ientry);
	  weight*=gen->weight;
	}

	// veto z -> xx decays for signal and z -> ee for bacground samples (needed for inclusive DYToLL sample)
	if (isWrongFlavor && hasGen && toolbox::flavor(genPartArr, BOSON_ID)==LEPTON_ID) continue;
	else if (isSignal && hasGen && toolbox::flavor(genPartArr, BOSON_ID)!=LEPTON_ID) continue;

        // check for certified lumi (if applicable)
        //baconhep::RunLumiRangeMap::RunLumiPairType rl(info->runNum, info->lumiSec);      
        //if(hasJSON && !rlrm.HasRunLumi(rl)) continue;  

        // trigger requirement               
        if(!(info->triggerBits[trigger])) continue;

        // good vertex requirement
        if(!(info->hasGoodPV)) continue;
	
        //
	// SELECTION PROCEDURE:
	//  (1) Find a good electron matched to trigger -> this will be the "tag"
	//  (2) Pair the tag with Supercluster probes which form a tag+probe mass inside 
	//      the Z window and divide candidates into exclusive categories as follows:
	//      (a) if probe SC is part of a good electron matched to trigger     -> EleEle2HLT category
	//      (b) if probe SC is part of a good electron not matched to trigger -> EleEle1HLT category
	//      (c) if probe SC is part of an electron failing selection cuts     -> EleEleNoSel category
	//      (d) if probe SC is not part of an ECAL driven electron            -> EleSC category
	//	

	TLorentzVector *gvec=new TLorentzVector(0,0,0,0);
	TLorentzVector *glep1=new TLorentzVector(0,0,0,0);
	TLorentzVector *glep2=new TLorentzVector(0,0,0,0);
	toolbox::fillGen(genPartArr, BOSON_ID, gvec, glep1, glep2,1);

	electronArr->Clear();
        electronBr->GetEntry(ientry);
	scArr->Clear();
	scBr->GetEntry(ientry);

	for(Int_t i1=0; i1<electronArr->GetEntriesFast(); i1++) {
          const baconhep::TElectron *tag = (baconhep::TElectron*)((*electronArr)[i1]);

	  // check ECAL gap
	  if(fabs(tag->scEta)>=ECAL_GAP_LOW && fabs(tag->scEta)<=ECAL_GAP_HIGH) continue;
	  
	  if (!(((glep1) && toolbox::deltaR(tag->eta, tag->phi, glep1->Eta(), glep1->Phi())<0.1) || 
		 ((glep2) && toolbox::deltaR(tag->eta, tag->phi, glep2->Eta(), glep2->Phi())<0.1))) continue;
	  
	  Double_t escale1=1;
	  if(doScaleCorr && isam==0) {
	    for(UInt_t ieta=0; ieta<escaleNbins; ieta++) {
	      if(fabs(tag->scEta)<escaleEta[ieta]) {
	        escale1 = escaleCorr[ieta];
		break;
	      }
	    }
	  }
	  if(escale1*(tag->scEt) < PT_CUT)     continue;  // lepton pT cut
	  if(fabs(tag->scEta)    > ETA_CUT)    continue;  // lepton |eta| cut
	  if(!passEleID(tag,info->rhoIso))     continue;  // lepton selection
	  if(!(tag->hltMatchBits[trigObjHLT])) continue;  // check trigger matching

	  TLorentzVector vTag;     vTag.SetPtEtaPhiM(tag->pt,   tag->eta,   tag->phi,   ELE_MASS);
	  TLorentzVector vTagSC; vTagSC.SetPtEtaPhiM(tag->scEt, tag->scEta, tag->scPhi, ELE_MASS);

	  muonArr->Clear();
	  muonBr->GetEntry(ientry); 
	  for(Int_t j=0; j<muonArr->GetEntriesFast(); j++) {
	    const baconhep::TMuon *tkProbe = (baconhep::TMuon*)((*muonArr)[j]);
	    if (tkProbe->typeBits & baconhep::EMuType::kGlobal) continue;
	    if (toolbox::deltaR(tkProbe->eta, tkProbe->phi, tag->eta, tag->phi)<0.1) continue;

	    if (!( ((glep1) && toolbox::deltaR(tkProbe->eta, tkProbe->phi, glep1->Eta(), glep1->Phi())<0.1) || 
		   ((glep2) && toolbox::deltaR(tkProbe->eta, tkProbe->phi, glep2->Eta(), glep2->Phi())<0.1) ) ) continue;

	    // check ECAL gap
	    if(fabs(tkProbe->eta)>=ECAL_GAP_LOW && fabs(tkProbe->eta)<=ECAL_GAP_HIGH) continue;
	    
	    if(tkProbe->pt < PT_CUT)  continue;  // Track pT cut 
	    if(fabs(tkProbe->eta)  > ETA_CUT) continue;  // track |eta| cuts
	  
	    const baconhep::TPhoton *scProbe=0;
	    Int_t iprobe=-1;
	    for(Int_t i2=0; i2<scArr->GetEntriesFast(); i2++) {
	      const baconhep::TPhoton *sc = (baconhep::TPhoton*)((*scArr)[i2]);
	      if (toolbox::deltaR(tkProbe->eta, tkProbe->phi, sc->eta, sc->phi)<0.1) {
		scProbe=sc;
		iprobe=i2;
		break;
	      }
	    }
	    
	    TLorentzVector vProbe(0,0,0,0);
	    vProbe.SetPtEtaPhiM(tkProbe->pt, tkProbe->eta, tkProbe->phi, ELE_MASS);
	    TLorentzVector vProbeSC(0,0,0,0);
	    vProbeSC.SetPtEtaPhiM((scProbe) ? scProbe->scEt  : tkProbe->pt,
				  tkProbe->eta, tkProbe->phi, ELE_MASS);
	    
	    // mass window
	    TLorentzVector vDilep = vTag + vProbe;
	    if((vDilep.M()<MASS_LOW) || (vDilep.M()>MASS_HIGH)) continue;
	    
	    // determine event category
	    UInt_t icat=0;
	    if(scProbe) icat=ePass;
	    else icat=eFail;

	    //******** We have a Z candidate! HURRAY! ********
	    nsel+=weight;
            nselvar+=weight*weight;

	    // Perform matching of dileptons to GEN leptons from Z decay
	    Bool_t hasGenMatch = kFALSE;
	    if(isSignal && hasGen) {

	      Bool_t match1 = ( ((glep1) && toolbox::deltaR(tag->eta, tag->phi, glep1->Eta(), glep1->Phi())<0.1) || 
				((glep2) && toolbox::deltaR(tag->eta, tag->phi, glep2->Eta(), glep2->Phi())<0.1) );

	      Bool_t match2 = ( ((glep1) && toolbox::deltaR(vProbe.Eta(), vProbe.Phi(), glep1->Eta(), glep1->Phi())<0.1) || 
				((glep2) && toolbox::deltaR(vProbe.Eta(), vProbe.Phi(), glep2->Eta(), glep2->Phi())<0.1) );
	      if(match1 && match2) {
		hasGenMatch = kTRUE;
		if (gvec!=0) {
		  genV=new TLorentzVector(0,0,0,0);
		  genV->SetPtEtaPhiM(gvec->Pt(), gvec->Eta(), gvec->Phi(), gvec->M());
		  genVPt   = gvec->Pt();
		  genVPhi  = gvec->Phi();
		  genVy    = gvec->Rapidity();
		  genVMass = gvec->M();
		}
		else {
		  TLorentzVector tvec=*lep1+*lep2;
		  genV=new TLorentzVector(0,0,0,0);
		  genV->SetPtEtaPhiM(tvec.Pt(), tvec.Eta(), tvec.Phi(), tvec.M());
		  genVPt   = tvec.Pt();
		  genVPhi  = tvec.Phi();
		  genVy    = tvec.Rapidity();
		  genVMass = tvec.M();
		}
		delete gvec;
		delete glep1;
		delete glep2;
		glep1=0; glep2=0; gvec=0;
	      }
	      else {
		genV     = new TLorentzVector(0,0,0,0);
		genVPt   = -999;
		genVPhi  = -999;
		genVy    = -999;
		genVMass = -999;
	      }
	    }

	    if (hasGen) {
	      id_1      = gen->id_1;
	      id_2      = gen->id_2;
	      x_1       = gen->x_1;
	      x_2       = gen->x_2;
	      xPDF_1    = gen->xPDF_1;
	      xPDF_2    = gen->xPDF_2;
	      scalePDF  = gen->scalePDF;
	      weightPDF = gen->weight;
	    }
	    else {
	      id_1      = -999;
	      id_2      = -999;
	      x_1       = -999;
	      x_2       = -999;
	      xPDF_1    = -999;
	      xPDF_2    = -999;
	      scalePDF  = -999;
	      weightPDF = -999;
	    }

	    //
	    // Fill tree
	    //
	    runNum   = info->runNum;
	    lumiSec  = info->lumiSec;
	    evtNum   = info->evtNum;

	    if (hasGenMatch) matchGen=1;
            else matchGen=0;

	    category = icat;
	    npv      = 0; 
	    npu      = info->nPU;
	    scale1fb = weight;
	    met      = info->pfMET;
	    metPhi   = info->pfMETphi;
	    sumEt    = 0;
	    tkMet    = info->trkMET;
	    tkMetPhi = info->trkMETphi;
	    tkSumEt  = 0;
	    mvaMet   = info->mvaMET;
            mvaMetPhi = info->mvaMETphi;
	    mvaSumEt = 0;
            ppMet    = 0;
            ppMetPhi = 0;
	    ppSumEt  = 0;
	    lep1     = &vTag;
	    lep2     = &vProbe;
	    dilep    = &vDilep;
	    q1       = tag->q;
	    q2       = (tkProbe) ? tkProbe->q : -(tag->q);

	    TVector2 vZPt((vDilep.Pt())*cos(vDilep.Phi()),(vDilep.Pt())*sin(vDilep.Phi()));        
            TVector2 vMet((info->pfMET)*cos(info->pfMETphi), (info->pfMET)*sin(info->pfMETphi));        
            TVector2 vU = -1.0*(vMet+vZPt);
            u1 = ((vDilep.Px())*(vU.Px()) + (vDilep.Py())*(vU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
            u2 = ((vDilep.Px())*(vU.Py()) - (vDilep.Py())*(vU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|

            TVector2 vTkMet((info->trkMET)*cos(info->trkMETphi), (info->trkMET)*sin(info->trkMETphi));        
            TVector2 vTkU = -1.0*(vTkMet+vZPt);
            tkU1 = ((vDilep.Px())*(vTkU.Px()) + (vDilep.Py())*(vTkU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
            tkU2 = ((vDilep.Px())*(vTkU.Py()) - (vDilep.Py())*(vTkU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|

	    TVector2 vMvaMet((info->mvaMET)*cos(info->mvaMETphi), (info->mvaMET)*sin(info->mvaMETphi));
            TVector2 vMvaU = -1.0*(vMvaMet+vZPt);
            mvaU1 = ((vDilep.Px())*(vMvaU.Px()) + (vDilep.Py())*(vMvaU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
            mvaU2 = ((vDilep.Px())*(vMvaU.Py()) - (vDilep.Py())*(vMvaU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|

	    //TVector2 vPpMet((info->ppMET)*cos(info->ppMETphi), (info->ppMET)*sin(info->ppMETphi));
            //TVector2 vPpU = -1.0*(vPpMet+vZPt);
            //ppU1 = ((vDilep.Px())*(vPpU.Px()) + (vDilep.Py())*(vPpU.Py()))/(vDilep.Pt());  // u1 = (pT . u)/|pT|
            //ppU2 = ((vDilep.Px())*(vPpU.Py()) - (vDilep.Py())*(vPpU.Px()))/(vDilep.Pt());  // u2 = (pT x u)/|pT|
	  
	    ///// electron specific ///// 
	    sc1        = &vTagSC;
	    trkIso1    = tag->trkIso;
	    emIso1     = tag->ecalIso;
	    hadIso1    = tag->hcalIso;
	    pfChIso1   = tag->chHadIso;
	    pfGamIso1  = tag->gammaIso;	    
	    pfNeuIso1  = tag->neuHadIso;
	    pfCombIso1 = tag->chHadIso + TMath::Max(tag->neuHadIso + tag->gammaIso - 
						    (info->rhoIso)*getEffAreaEl(tag->eta), 0.);
	    /*	    sigieie1   = tag->sieie;
	    hovere1    = tag->hovere;
	    eoverp1    = tag->eoverp;
	    fbrem1     = tag->fbrem;
	    dphi1      = tag->dPhiIn;
	    deta1      = tag->dEtaIn;
	    ecalE1     = 0;
	    d01        = tag->d0;
	    dz1        = tag->dz;
	    isConv1    = tag->isConv;
	    nexphits1  = tag->nMissingHits;
	    typeBits1  = tag->typeBits;*/

	    sc2        = &vProbeSC;
	    trkIso2    = (tkProbe) ? tkProbe->trkIso        : -1;
	    emIso2     = (tkProbe) ? tkProbe->ecalIso       : -1;
	    hadIso2    = (tkProbe) ? tkProbe->hcalIso       : -1;
	    pfChIso2   = (tkProbe) ? tkProbe->chHadIso      : -1;
	    pfGamIso2  = (tkProbe) ? tkProbe->gammaIso      : -1;
	    pfNeuIso2  = (tkProbe) ? tkProbe->neuHadIso     : -1;	    
	    pfCombIso2 = (tkProbe) ? 
	      tkProbe->chHadIso + TMath::Max(tkProbe->neuHadIso + tkProbe->gammaIso - 
					      (info->rhoIso)*getEffAreaEl(tkProbe->eta), 0.) :  -1;
	    /*	    sigieie2   = (tkProbe) ? tkProbe->sieie         : scProbe->sieie;
	    hovere2    = (tkProbe) ? tkProbe->hovere        : scProbe->hovere;
	    eoverp2    = (tkProbe) ? tkProbe->eoverp        : -1;
	    fbrem2     = (tkProbe) ? tkProbe->fbrem         : -1;
	    dphi2      = (tkProbe) ? tkProbe->dPhiIn        : -999;
	    deta2      = (tkProbe) ? tkProbe->dEtaIn        : -999;
	    ecalE2     = (tkProbe) ? 0    : -999;
	    d02        = (tkProbe) ? tkProbe->d0            : -999;
	    dz2        = (tkProbe) ? tkProbe->dz            : -999;
	    isConv2    = (tkProbe) ? tkProbe->isConv        : 0;
	    nexphits2  = (tkProbe) ? tkProbe->nMissingHits  : 0;
	    typeBits2  = (tkProbe) ? tkProbe->typeBits      : 0; */

	    outTree->Fill();
	    delete genV;
	    genV=0, dilep=0, lep1=0, lep2=0, sc1=0, sc2=0;
	  }
	}
      }
      delete infile;
      infile=0, eventTree=0;    

      cout << nsel  << " +/- " << sqrt(nselvar);
      if(isam!=0) cout << " per 1/fb";
      cout << endl;
    }
    outFile->Write();
    outFile->Close(); 
  }
  delete info;
  delete gen;
  delete genPartArr;
  delete electronArr;
  delete scArr;
    
  //--------------------------------------------------------------------------------------------------------------
  // Output
  //==============================================================================================================
   
  cout << "*" << endl;
  cout << "* SUMMARY" << endl;
  cout << "*--------------------------------------------------" << endl;
  cout << " Z -> e e" << endl;
  cout << "  Mass window: [" << MASS_LOW << ", " << MASS_HIGH << "]" << endl;
  cout << "  pT > " << PT_CUT << endl;
  cout << "  |eta| < " << ETA_CUT << endl;
  if(doScaleCorr)
    cout << "  *** Scale corrections applied ***" << endl;
  cout << endl;
  
  cout << endl;
  cout << "  <> Output saved in " << outputDir << "/" << endl;    
  cout << endl;  
      
  gBenchmark->Show("selectZee"); 
}