Selection/src/Selection.cc

#include "SelectionStatus.h" 
#include "EventData.h" 
#include "SimpleLepton.h" 
#include "EfficiencyWeightsInterface.h"

#include "ElectronSelection.h"
#include "MuonSelection.h"
#include "IsolationSelection.h"
//#include "PassHLT.h"
#include "Selection.h"

#include "ExternData.h"
#include "SelectionDefs.h"


// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
EventData apply_HZZ4L_selection(ControlFlags &ctrl,           // input control 
                                const mithep::EventHeader *info,     // input event info
                                const mithep::Vertex & vtx,
                                const mithep::Array<mithep::PFCandidate>  *pfCandidates,
                                const mithep::Array<mithep::PileupEnergyDensity>  *puEnergyDensity,
                                const mithep::Array<mithep::Electron> *electronArr,    // input electrons
                                SelectionStatus (*ElectronPreSelector)( ControlFlags &, 
                                                                        const mithep::Electron*,
                                                                        const mithep::Vertex &),
                                SelectionStatus (*ElectronIDSelector)( ControlFlags &, 
                                                                       const mithep::Electron*,
                                                                       const mithep::Vertex &), 
                                SelectionStatus (*ElectronIsoSelector)( ControlFlags &, 
                                                                        const mithep::Electron*, 
                                                                        const mithep::Vertex &, 
                                                                        const mithep::Array<mithep::PFCandidate> *, 
                                                                        const mithep::Array<mithep::PileupEnergyDensity> *, 
                                                                        mithep::ElectronTools::EElectronEffectiveAreaTarget,
                                                                        vector<const mithep::Muon*>,
                                                                        vector<const mithep::Electron*> ),
                                const mithep::Array<mithep::Muon> *muonArr,    // input muons
                                SelectionStatus (*MuonPreSelector)( ControlFlags &, 
                                                                    const mithep::Muon*,
                                                                    const mithep::Vertex &,
                                                                    const mithep::Array<mithep::PFCandidate> *),
                                SelectionStatus (*MuonIDSelector)( ControlFlags &, 
                                                                   const mithep::Muon*, 
                                                                   const mithep::Vertex &),
                                SelectionStatus (*MuonIsoSelector)( ControlFlags &, 
                                                                    const mithep::Muon*, 
                                                                    const mithep::Vertex &, 
                                                                    const mithep::Array<mithep::PFCandidate> *,
                                                                    const mithep::Array<mithep::PileupEnergyDensity> *, 
                                                                    mithep::MuonTools::EMuonEffectiveAreaTarget,
                                                                    vector<const mithep::Muon*>,
                                                                    vector<const mithep::Electron*> ) 
                                )
  // +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
{       

  EventData ret;
  unsigned evtfail = 0x0;
  TRandom3 r;
  
  if( ctrl.debug ) {
    cout << "Run: " << info->RunNum() 
         << "\tEvt: " << info->EvtNum()
         << "\tLumi: " << info->LumiSec()
         << endl;
  }

  if( !ctrl.mc ) {
    // not accounting for overlap atm
    RunLumiRangeMap::RunLumiPairType rl(info->RunNum(), info->LumiSec());      
    if( !(rlrm.HasRunLumi(rl)) )  {
      if( ctrl.debug ) cout << "\tfails JSON" << endl;
      ret.status.setStatus(0);
      return ret;
    }
  }

  mithep::MuonTools::EMuonEffectiveAreaTarget         eraMu  = mithep::MuonTools::kMuEAData2011;
  mithep::ElectronTools::EElectronEffectiveAreaTarget eraEle = mithep::ElectronTools::kEleEAData2011;
  if( ctrl.mc ) { 
    eraMu  = mithep::MuonTools::kMuEAFall11MC;
    eraEle = mithep::ElectronTools::kEleEAFall11MC;
  }
  
  
  //********************************************************
  // Trigger
  //********************************************************
  //
  // still have to port this part to bambu
  //
  /* 
  if( !ctrl.mc ) { 
    //if( !(passHLT(info->triggerBits, info->runNum, channel) )  ) { 
    if( !(passHLT(info->triggerBits, info->runNum, 999) )  ) { 
      if( ctrl.debug ) cout << "\tfails trigger" << endl;
      evtfail |= (1<<EVTFAIL_TRIGGER);
      ret.status.setStatus(0);
      return ret;
    }   
  } 
  if( ctrl.debug ) { 
    cout << "presel nlep: " << muonArr->GetEntries() + electronArr->GetEntries()
         << "\tnmuon: "    << muonArr->GetEntries()
         << "\tnelectron: " << electronArr->GetEntries()
         << endl;
  }
  */

  //********************************************************
  // Lepton Selection
  //********************************************************
  vector<SimpleLepton> lepvec;

  // do something hacky for vetos for now 
  vector<const mithep::Muon*> muonsToVeto;
  vector<const mithep::Electron*> electronsToVeto;
  for(Int_t i=0; i<muonArr->GetEntries(); i++) 
    {
      const mithep::Muon *mu = (mithep::Muon*)((*muonArr)[i]);      
      SelectionStatus musel;
      musel |= (*MuonPreSelector)(ctrl,mu,vtx,pfCandidates);
      if( !(musel.getStatus() & SelectionStatus::PRESELECTION) ) continue;
      musel |= (*MuonIDSelector)(ctrl,mu,vtx );
      if( musel.getStatus() == SelectionStatus::TIGHTIDANDPRE ) 
        muonsToVeto.push_back( mu );
    }
  for(Int_t i=0; i<electronArr->GetEntries(); i++) 
    {
      const mithep::Electron *ele = (mithep::Electron*)((*electronArr)[i]);      
      SelectionStatus esel;
      esel |= (*ElectronPreSelector)(ctrl,ele,vtx);
      if( !(esel.getStatus() & SelectionStatus::PRESELECTION) ) continue;
      esel |= (*ElectronIDSelector)(ctrl,ele,vtx );
      if( esel.getStatus() == SelectionStatus::TIGHTIDANDPRE ) 
        electronsToVeto.push_back( ele );
    }

  //    
  if( ctrl.debug ) cout << "\tnMuons: " << muonArr->GetEntries() << endl;
  //----------------------------------------------------
  for(Int_t i=0; i<muonArr->GetEntries(); i++) 
    {
      const mithep::Muon *mu = (mithep::Muon*)((*muonArr)[i]);      
      
      SelectionStatus musel;
      if(ctrl.debug) cout << "musel.status  before anything: " << musel.getStatus() << endl;
      musel |= (*MuonPreSelector)(ctrl,mu,vtx,pfCandidates);
      if(ctrl.debug) cout << "musel.status  after presel: " << musel.getStatus() << endl;
      if( !(musel.getStatus() & SelectionStatus::PRESELECTION) ) continue;
      musel |= (*MuonIDSelector)(ctrl,mu,vtx );
      if(ctrl.debug) cout << "musel.status  after ID: " << musel.getStatus() << endl;
      musel |= (*MuonIsoSelector)(ctrl,mu,vtx,pfCandidates,puEnergyDensity,eraMu,muonsToVeto,electronsToVeto);
      if(ctrl.debug) cout << "musel.status  after iso: " << musel.getStatus() << endl;

      if( ctrl.debug ) { 
        cout << "muon:: pt: " << mu->Pt() 
             << "\teta: " << mu->Eta() 
             << "\tstatus: " << hex << musel.getStatus() << dec
             << endl;
      }
      
      if ( musel.pass() ) {

        SimpleLepton tmplep;
        float pt = mu->Pt();
        tmplep.vecorig->SetPtEtaPhiM(pt, 
                                     mu->Eta(), 
                                     mu->Phi(),
                                     MUON_MASS);
        
        if( ctrl.do_escale_up ) { 
          pt=scale_smear_muon_Up(pt, 1,  r);
        }
        if( ctrl.do_escale_down ) { 
          pt=scale_smear_muon_Down(pt, 1,  r);
        }
        
        tmplep.vec->SetPtEtaPhiM(pt, 
                                 mu->Eta(), 
                                 mu->Phi(),
                                 MUON_MASS);
        
        tmplep.type    = 13;
        tmplep.index   = i;
        tmplep.charge  = mu->Charge();
        tmplep.isoTrk  = mu->IsoR03SumPt();
        tmplep.isoEcal = mu->IsoR03EmEt();
        tmplep.isoHcal = mu->IsoR03HadEt();
        tmplep.isoPF03 = computePFMuonIso(mu,vtx,pfCandidates,0.3);
        tmplep.isoPF04 = computePFMuonIso(mu,vtx,pfCandidates,0.4);
        tmplep.ip3dSig = mu->Ip3dPVSignificance();
        tmplep.is4l    = false;
        tmplep.isEB    = (fabs(mu->Eta()) < 1.479 ? 1 : 0 ); 
        tmplep.isTight = musel.tight();
        tmplep.isLoose = musel.loose();
        lepvec.push_back(tmplep);
        if( ctrl.debug ) { cout << "muon passes ... " << endl;}
      }
      //  }
    }    
  
  
    //
    if( ctrl.debug ) { cout << "\tnElectron: " << electronArr->GetEntries() << endl; }
    // --------------------------------------------------------------------------------
    for(Int_t i=0; i<electronArr->GetEntries(); i++) 
      {
        const mithep::Electron *ele = (mithep::Electron*)((*electronArr)[i]);
        
        Bool_t isMuonOverlap = kFALSE;
        for (int k=0; k<lepvec.size(); ++k) {
          TVector3 tmplep;
          tmplep.SetPtEtaPhi(ele->Pt(), ele->Eta(), ele->Phi());
          if ( lepvec[k].isLoose && lepvec[k].type == 13 && lepvec[k].vec->Vect().DrEtaPhi(tmplep) < 0.1 ) {
            if( ctrl.debug ) cout << "-----> isMuonOverlap! " << endl;
            isMuonOverlap = kTRUE; 
            break;
          }
        }
        
        SelectionStatus elesel;
        if( ctrl.debug ) cout << "--> status before anything: " << hex << elesel.getStatus() << dec << endl;
        elesel |= (*ElectronPreSelector)(ctrl,ele,vtx);
        if( ctrl.debug ) cout << "--> status after presel: " << hex << elesel.getStatus() << dec << endl;
        elesel |= (*ElectronIDSelector)(ctrl,ele,vtx);
        if( ctrl.debug ) cout << "--> status after ID: " << hex << elesel.getStatus() << dec << endl;
        elesel |= (*ElectronIsoSelector)(ctrl,ele,vtx,pfCandidates,puEnergyDensity,eraEle,muonsToVeto,electronsToVeto);
        if( ctrl.debug ) cout << "--> status after iso: " << hex << elesel.getStatus() << dec << endl;
        
        if( ctrl.debug ){ 
          cout << "\tscEt: " << ele->SCluster()->Et()
               << "\tscEta: " << ele->SCluster()->Eta()
               << "\tstatus: " << hex << elesel.getStatus() << dec
               << endl;
        }

        if ( elesel.pass() && !isMuonOverlap ) 
          {
            SimpleLepton tmplep;
            
            float pt = ele->Pt();
            tmplep.vecorig->SetPtEtaPhiM( pt,
                                          ele->Eta(),
                                          ele->Phi(),
                                          ELECTRON_MASS );
            
            if( ctrl.do_escale ) { 
              pt=scale_smear_electron(pt, ele->IsEB(), r);
            }
            if( ctrl.do_escale_up ) { 
              pt=scale_smear_electron_Up(pt, ele->IsEB(),  r);
            }
            if( ctrl.do_escale_down ) { 
              pt=scale_smear_electron_Down(pt, ele->IsEB(),  r);
            }

            
            tmplep.vec->SetPtEtaPhiM( pt,
                                      ele->Eta(),
                                      ele->Phi(),
                                      ELECTRON_MASS );
            
            tmplep.type    = 11;
            tmplep.index   = i;
            tmplep.charge  = ele->Charge();
            tmplep.isoTrk  = ele->TrackIsolationDr03();
            tmplep.isoEcal = ele->EcalRecHitIsoDr03();
            tmplep.isoHcal = ele->HcalTowerSumEtDr03();
            tmplep.isoPF03 = computePFEleIso(ele,vtx,pfCandidates,0.3);
            tmplep.isoPF04 = computePFEleIso(ele,vtx,pfCandidates,0.4);
            tmplep.ip3dSig = ele->Ip3dPVSignificance();
            tmplep.is4l    = false;
            tmplep.isEB    = ele->IsEB();
            tmplep.scID    = ele->SCluster()->GetUniqueID();
            tmplep.isTight = elesel.tight();
            tmplep.isLoose = elesel.loose();
            lepvec.push_back(tmplep);
            if( ctrl.debug ) { cout << "\telectron passes ... " << endl; }
          }
      }
    
    
    //********************************************************
    // Dump Stuff
    //********************************************************
    sort( lepvec.begin(), lepvec.end(), SimpleLepton::lep_pt_sort );
    int nmu=0, nele=0;
    for( int i=0; i<lepvec.size(); i++ ) {
      if(ctrl.debug) cout << "lepvec :: index: " << i 
                          << "\tpt: " << lepvec[i].vec->Pt()
                          << "\ttype: " << lepvec[i].type 
                          << endl;
      if( abs(lepvec[i].type) == 11 ) nele++;
      else nmu++;
    }
    if( ctrl.debug ) { 
      cout << "postsel nlep: " << lepvec.size()
           << "\tnmuon: " << nmu
           << "\tnelectron: " << nele
           << endl;
    }
    
    
    //******************************************************************************
    // Z1 Selection
    //******************************************************************************
    int Z1LeptonPlusIndex = -1;
    int Z1LeptonMinusIndex = -1;
    double BestZ1Mass = -999;
    if( ctrl.debug ) { cout << "looking for a Z1 ..." << endl; }
    for(int i = 0; i < lepvec.size(); ++i) {
      if( !(lepvec[i].isLoose) ) continue; 
      for(int j = i+1; j < lepvec.size(); ++j) {
        if( !(lepvec[j].isLoose) ) continue; 
        if( ctrl.debug ) { cout << "\tconsidering leptons " << i << " & " << j << endl; }
        if (!(lepvec[i].vec->Pt() > 20.0 || lepvec[j].vec->Pt() > 20.0)) continue; 
        if( ctrl.debug ) { cout << "\tat least one is > 20 GeV" << endl; }
        if (!(lepvec[i].vec->Pt() > 10.0 && lepvec[j].vec->Pt() > 10.0)) continue; 
        if( ctrl.debug ) { cout << "\tthe other  is > 10 GeV" << endl; }
        if (lepvec[i].charge == lepvec[j].charge) continue;          
        if( ctrl.debug ) { cout << "\tthey're opposite charge" << endl; }
        if (fabs(lepvec[i].type) != fabs(lepvec[j].type)) continue;  
        if( ctrl.debug ) { cout << "\tthey're same flavor" << endl; }
        
        //Make Z1 hypothesis
        TLorentzVector *leptonPlus, *leptonMinus;
        if ( lepvec[i].charge > 0 ) {
          leptonPlus  = lepvec[i].vec;
          leptonMinus = lepvec[j].vec;
        } else {
          leptonPlus  = lepvec[j].vec;
          leptonMinus = lepvec[i].vec;
        }
        
        float tmpZ1Mass = (*leptonPlus + *leptonMinus).M();
        if( ctrl.debug ) cout << "Z1 selection, tmpZ1Mass: " << tmpZ1Mass << endl;
        if( tmpZ1Mass > 60 ) {
          if (fabs(tmpZ1Mass - Z_MASS) < fabs(BestZ1Mass - Z_MASS)) {
            BestZ1Mass = tmpZ1Mass;
            if( ctrl.debug ) cout << "Z1 selection, new BestZ1Mass: " << BestZ1Mass 
                                  << "\tdM: " << fabs(BestZ1Mass - Z_MASS)
                                  << endl;
            if (lepvec[i].charge > 0) {
              Z1LeptonPlusIndex = i;
              Z1LeptonMinusIndex = j;
            } else {
              Z1LeptonPlusIndex = j;
              Z1LeptonMinusIndex = i;
            }
          }
        }
      }
    }
    // stop if no Z1 candidate is found
    if( BestZ1Mass < 0 ) { 
      evtfail |= (1<<EVTFAIL_Z1);
      //ret.status = evtfail;
      ret.status.setStatus(0);
      return ret;
    }
    if( ctrl.debug ) cout << "\tgot a Z1 ... run: " << info->RunNum() << "\tevt: " << info->EvtNum()  << endl;
    if( ctrl.debug ) cout << "\tZ1 plusindex: " << Z1LeptonPlusIndex << "\tminusindex: " << Z1LeptonMinusIndex << endl;
    TLorentzVector Z1LeptonPlus  = *(lepvec[Z1LeptonPlusIndex].vec);
    TLorentzVector Z1LeptonMinus = *(lepvec[Z1LeptonMinusIndex].vec);
    TLorentzVector Z1Candidate   =  Z1LeptonPlus + Z1LeptonMinus;
    
    
    //******************************************************************************
    // Z1 + l
    //******************************************************************************
    if( lepvec.size() < 3 ) { 
      evtfail |= (1<<EVTFAIL_Z1_PLUSL);
      //ret.status = evtfail;
      ret.status.setStatus(0);
      return ret;
    }
    
    //******************************************************************************
    // 4l/Z2 Selection
    //******************************************************************************
    Int_t Z2LeptonPlusIndex = -1;
    Int_t Z2LeptonMinusIndex = -1;
    Double_t BestZ2Mass = -1;
    if( ctrl.debug ) cout << "looking for a Z2 ... out of " << lepvec.size() << " leptons" <<endl;
    for(int i = 0; i < lepvec.size(); ++i) {
      
      if( ctrl.debug)  cout << "i: " << i 
                            << "\tpt: " << lepvec[i].vec->Pt() 
                            << "\ttype: " << lepvec[i].type 
                            << endl;
      
      if( ctrl.eleSeleScheme == "mediumloose" && 
          !(lepvec[i].isTight) ) { 
        if( ctrl.debug)  cout << "it's not tight, skipping ... " << endl;
        continue;
      }
      
      for(int j = i+1; j < lepvec.size(); ++j) {
        if( ctrl.debug)  cout << "\t\tj: " << j 
                              << "\tpt: " << lepvec[j].vec->Pt() 
                              << "\ttype: " << lepvec[j].type 
                              << endl;
        
        if( ctrl.eleSeleScheme == "mediumloose" && 
            !(lepvec[j].isTight) ) { 
          if( ctrl.debug)  cout << "it's not tight, skipping ... " << endl;
          continue;
        }
        
        
        if (i == Z1LeptonPlusIndex || i == Z1LeptonMinusIndex) { 
          if( ctrl.debug)  cout << "\ti matches a Z1 index, skipping ..." << endl;
          continue; //skip Z1 leptons
        }
        if (j == Z1LeptonPlusIndex || j == Z1LeptonMinusIndex) { 
          if( ctrl.debug)  cout << "\tj matches a Z1 index, skipping ..." << endl;
          continue; //skip Z1 leptons
        }
        if (lepvec[i].charge == lepvec[j].charge) { 
          if( ctrl.debug)  cout << "\ti and j are same sign, skipping ..." << endl;
          continue;         //require opp sign
        }
        if (fabs(lepvec[i].type) != fabs(lepvec[j].type)) { 
          if( ctrl.debug) cout << "\ti and j are not same flavor, skipping ..." << endl;
          continue; //require same flavor
        }
        
        
        //Make Z2 hypothesis
        TLorentzVector *leptonPlus, *leptonMinus;
        
        if (lepvec[i].charge > 0 ) {
          leptonPlus  = lepvec[i].vec;
          leptonMinus = lepvec[j].vec;
        } else {
          leptonPlus  = lepvec[j].vec;
          leptonMinus = lepvec[i].vec;
        }
        
        TLorentzVector dilepton = *leptonPlus + *leptonMinus;
        TLorentzVector fourLepton = Z1Candidate + dilepton;
        
        if( ctrl.debug ) cout << "dilepton.M() : " << dilepton.M() << endl;
        if( ctrl.debug ) cout << "fourLepton.M() : " << fourLepton.M() << endl;
        
        if (!(dilepton.M() > 12.0)) continue;
        if (!(fourLepton.M() > 100.0)) continue;
        
        //for 4e and 4mu, require at least 1 of the other opp sign lepton pairs have mass > 12
        if (fabs(lepvec[i].type) == fabs(lepvec[Z1LeptonPlusIndex].type)) {
          TLorentzVector pair1 = Z1LeptonPlus + *leptonMinus;
          TLorentzVector pair2 = Z1LeptonMinus + *leptonPlus;
          if( ctrl.debug ) cout << "pair1: " << pair1.M() << "\tpair2: "<< pair2.M() << endl;
          if (!(pair1.M() > 12 || pair2.M() > 12)) continue;
        }
      
      
        //Disambiguiation is done by choosing the pair with the largest ptMax and largest ptMin
        if (Z2LeptonPlusIndex < 0) {
          if (lepvec[i].charge > 0) {
            Z2LeptonPlusIndex = i;
            Z2LeptonMinusIndex = j;
          } else {
            Z2LeptonPlusIndex = j;
            Z2LeptonMinusIndex = i;
          }
        } else {
          Double_t BestPairPtMax = lepvec[Z2LeptonPlusIndex].vec->Pt();               
          Double_t BestPairPtMin = lepvec[Z2LeptonMinusIndex].vec->Pt(); 
          if (lepvec[Z2LeptonMinusIndex].vec->Pt() > BestPairPtMax) {
            BestPairPtMax = lepvec[Z2LeptonMinusIndex].vec->Pt();
            BestPairPtMin = lepvec[Z2LeptonPlusIndex].vec->Pt();
          }
        
          Double_t CurrentPairPtMax = lepvec[i].vec->Pt();               
          Double_t CurrentPairPtMin = lepvec[j].vec->Pt(); 
          if (lepvec[j].vec->Pt() > CurrentPairPtMax) {
            CurrentPairPtMax = lepvec[j].vec->Pt();
            CurrentPairPtMin = lepvec[i].vec->Pt();
          }
        
          if (CurrentPairPtMax > BestPairPtMax) {
            if (lepvec[i].charge > 0) {
              Z2LeptonPlusIndex = i;
              Z2LeptonMinusIndex = j;
            } else {
              Z2LeptonPlusIndex = j;
              Z2LeptonMinusIndex = i;
            }
          } else if (CurrentPairPtMax  == BestPairPtMax) {
            if (CurrentPairPtMin > BestPairPtMin) {
              if (lepvec[i].charge > 0) {
                Z2LeptonPlusIndex = i;
                Z2LeptonMinusIndex = j;
              } else {
                Z2LeptonPlusIndex = j;
                Z2LeptonMinusIndex = i;
              }                  
            }
          }
        }            
      }
    }
  
    // stop if no Z2 candidate is found
    if (Z2LeptonPlusIndex == -1) { 
      evtfail |= ( 1<<EVTFAIL_4L );
      //      ret.status = evtfail;
      ret.status.setStatus(0);
      return ret;
    }
    if( ctrl.debug ) cout << "\tgot a Z2 ..." << endl;
    if( ctrl.debug ) cout << "\tZ2 plusindex: " << Z2LeptonPlusIndex
                          << "\tminusindex: " << Z2LeptonMinusIndex << endl;
    TLorentzVector  Z2LeptonPlus  = *(lepvec[Z2LeptonPlusIndex].vec);
    TLorentzVector  Z2LeptonMinus = *(lepvec[Z2LeptonMinusIndex].vec);
    TLorentzVector  Z2Candidate   = Z2LeptonPlus+Z2LeptonMinus;
    TLorentzVector  ZZSystem      = Z1Candidate + Z2Candidate;
    lepvec[Z1LeptonPlusIndex].is4l = true;
    lepvec[Z1LeptonMinusIndex].is4l = true;
    lepvec[Z2LeptonPlusIndex].is4l = true;
    lepvec[Z2LeptonMinusIndex].is4l = true;
  

    //***************************************************************
    // remaining kinematic cuts 
    //***************************************************************
    double Z2massCut=0;
    if      ( ctrl.kinematics == "loose" ) Z2massCut = 12;
    else if ( ctrl.kinematics == "tight" ) Z2massCut = 20;
    else { cout <<  "error! kinematic tightness not defined!" << endl; assert(0); }
  
    if ( Z1Candidate.M() > 120        || 
         Z2Candidate.M() < Z2massCut  ||
         Z2Candidate.M() > 120        || 
         !(lepvec[Z1LeptonPlusIndex].vec->Pt() > 20.0 || lepvec[Z1LeptonMinusIndex].vec->Pt() > 20.0) ||
         !(lepvec[Z1LeptonPlusIndex].vec->Pt() > 10.0 && lepvec[Z1LeptonMinusIndex].vec->Pt() > 10.0)
         ) {
      evtfail |= (1<<EVTFAIL_KINEMATICS );
      //      ret.status = evtfail;
      ret.status.setStatus(0);
      return ret;
    }
  
    unsigned channel;
    if( lepvec[Z1LeptonMinusIndex].type == 11 && lepvec[Z2LeptonMinusIndex].type == 11 ) channel=0; 
    if( lepvec[Z1LeptonMinusIndex].type == 13 && lepvec[Z2LeptonMinusIndex].type == 13 ) channel=1; 
    if( (lepvec[Z1LeptonMinusIndex].type == 11 && lepvec[Z2LeptonMinusIndex].type == 13) || 
        (lepvec[Z1LeptonMinusIndex].type == 13 && lepvec[Z2LeptonMinusIndex].type == 11)) channel=2; 
  
  
    if( ctrl.debug ) cout  << "run: " << info->RunNum()   
                           << "\tevt: " << info->EvtNum()
                           << "\tZ1channel: " << lepvec[Z1LeptonMinusIndex].type
                           << "\tZ2channel: " << lepvec[Z2LeptonMinusIndex].type
                           << "\tmZ1: " << Z1Candidate.M()
                           << "\tmZ2: " << Z2Candidate.M()
                           << "\tm4l: " << ZZSystem.M()
                           << "\tevtfail: " << hex << evtfail << dec 
      //                           << "\ttrigbits: " << hex << info->triggerBits << dec
      //              << "\ttree: " << inputFiles[q][f] 
                           << endl;
  

    //***************************************************************
    // finish
    //***************************************************************

    if( !evtfail ) { 
      ret.status.setStatus(SelectionStatus::EVTPASS);
      ret.Z1leptons.push_back(lepvec[Z1LeptonMinusIndex]);
      ret.Z1leptons.push_back(lepvec[Z1LeptonPlusIndex]);
      ret.Z2leptons.push_back(lepvec[Z2LeptonMinusIndex]);
      ret.Z2leptons.push_back(lepvec[Z2LeptonPlusIndex]);
    }

    return ret;
}


Revision:	1.20
Committed:	Thu Apr 26 06:56:30 2012 UTC (13 years ago) by khahn
Content type:	text/plain
Branch:	MAIN
Changes since 1.19:	+130 -68 lines
Log Message:	first pass port to bambu
#	Content
1	#include "SelectionStatus.h"
2	#include "EventData.h"
3	#include "SimpleLepton.h"
4	#include "EfficiencyWeightsInterface.h"
5
6	#include "ElectronSelection.h"
7	#include "MuonSelection.h"
8	#include "IsolationSelection.h"
9	//#include "PassHLT.h"
10	#include "Selection.h"
11
12	#include "ExternData.h"
13	#include "SelectionDefs.h"
14
15
16	// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
17	// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
18	// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
19	EventData apply_HZZ4L_selection(ControlFlags &ctrl, // input control
20	const mithep::EventHeader *info, // input event info
21	const mithep::Vertex & vtx,
22	const mithep::Array<mithep::PFCandidate> *pfCandidates,
23	const mithep::Array<mithep::PileupEnergyDensity> *puEnergyDensity,
24	const mithep::Array<mithep::Electron> *electronArr, // input electrons
25	SelectionStatus (*ElectronPreSelector)( ControlFlags &,
26	const mithep::Electron*,
27	const mithep::Vertex &),
28	SelectionStatus (*ElectronIDSelector)( ControlFlags &,
29	const mithep::Electron*,
30	const mithep::Vertex &),
31	SelectionStatus (*ElectronIsoSelector)( ControlFlags &,
32	const mithep::Electron*,
33	const mithep::Vertex &,
34	const mithep::Array<mithep::PFCandidate> *,
35	const mithep::Array<mithep::PileupEnergyDensity> *,
36	mithep::ElectronTools::EElectronEffectiveAreaTarget,
37	vector<const mithep::Muon*>,
38	vector<const mithep::Electron*> ),
39	const mithep::Array<mithep::Muon> *muonArr, // input muons
40	SelectionStatus (*MuonPreSelector)( ControlFlags &,
41	const mithep::Muon*,
42	const mithep::Vertex &,
43	const mithep::Array<mithep::PFCandidate> *),
44	SelectionStatus (*MuonIDSelector)( ControlFlags &,
45	const mithep::Muon*,
46	const mithep::Vertex &),
47	SelectionStatus (*MuonIsoSelector)( ControlFlags &,
48	const mithep::Muon*,
49	const mithep::Vertex &,
50	const mithep::Array<mithep::PFCandidate> *,
51	const mithep::Array<mithep::PileupEnergyDensity> *,
52	mithep::MuonTools::EMuonEffectiveAreaTarget,
53	vector<const mithep::Muon*>,
54	vector<const mithep::Electron*> )
55	)
56	// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
57	{
58
59	EventData ret;
60	unsigned evtfail = 0x0;
61	TRandom3 r;
62
63	if( ctrl.debug ) {
64	cout << "Run: " << info->RunNum()
65	<< "\tEvt: " << info->EvtNum()
66	<< "\tLumi: " << info->LumiSec()
67	<< endl;
68	}
69
70	if( !ctrl.mc ) {
71	// not accounting for overlap atm
72	RunLumiRangeMap::RunLumiPairType rl(info->RunNum(), info->LumiSec());
73	if( !(rlrm.HasRunLumi(rl)) ) {
74	if( ctrl.debug ) cout << "\tfails JSON" << endl;
75	ret.status.setStatus(0);
76	return ret;
77	}
78	}
79
80	mithep::MuonTools::EMuonEffectiveAreaTarget eraMu = mithep::MuonTools::kMuEAData2011;
81	mithep::ElectronTools::EElectronEffectiveAreaTarget eraEle = mithep::ElectronTools::kEleEAData2011;
82	if( ctrl.mc ) {
83	eraMu = mithep::MuonTools::kMuEAFall11MC;
84	eraEle = mithep::ElectronTools::kEleEAFall11MC;
85	}
86
87
88	//********************************************************
89	// Trigger
90	//********************************************************
91	//
92	// still have to port this part to bambu
93	//
94	/*
95	if( !ctrl.mc ) {
96	//if( !(passHLT(info->triggerBits, info->runNum, channel) ) ) {
97	if( !(passHLT(info->triggerBits, info->runNum, 999) ) ) {
98	if( ctrl.debug ) cout << "\tfails trigger" << endl;
99	evtfail \|= (1<<EVTFAIL_TRIGGER);
100	ret.status.setStatus(0);
101	return ret;
102	}
103	}
104	if( ctrl.debug ) {
105	cout << "presel nlep: " << muonArr->GetEntries() + electronArr->GetEntries()
106	<< "\tnmuon: " << muonArr->GetEntries()
107	<< "\tnelectron: " << electronArr->GetEntries()
108	<< endl;
109	}
110	*/
111
112	//********************************************************
113	// Lepton Selection
114	//********************************************************
115	vector<SimpleLepton> lepvec;
116
117	// do something hacky for vetos for now
118	vector<const mithep::Muon*> muonsToVeto;
119	vector<const mithep::Electron*> electronsToVeto;
120	for(Int_t i=0; i<muonArr->GetEntries(); i++)
121	{
122	const mithep::Muon mu = (mithep::Muon)((*muonArr)[i]);
123	SelectionStatus musel;
124	musel \|= (*MuonPreSelector)(ctrl,mu,vtx,pfCandidates);
125	if( !(musel.getStatus() & SelectionStatus::PRESELECTION) ) continue;
126	musel \|= (*MuonIDSelector)(ctrl,mu,vtx );
127	if( musel.getStatus() == SelectionStatus::TIGHTIDANDPRE )
128	muonsToVeto.push_back( mu );
129	}
130	for(Int_t i=0; i<electronArr->GetEntries(); i++)
131	{
132	const mithep::Electron ele = (mithep::Electron)((*electronArr)[i]);
133	SelectionStatus esel;
134	esel \|= (*ElectronPreSelector)(ctrl,ele,vtx);
135	if( !(esel.getStatus() & SelectionStatus::PRESELECTION) ) continue;
136	esel \|= (*ElectronIDSelector)(ctrl,ele,vtx );
137	if( esel.getStatus() == SelectionStatus::TIGHTIDANDPRE )
138	electronsToVeto.push_back( ele );
139	}
140
141	//
142	if( ctrl.debug ) cout << "\tnMuons: " << muonArr->GetEntries() << endl;
143	//----------------------------------------------------
144	for(Int_t i=0; i<muonArr->GetEntries(); i++)
145	{
146	const mithep::Muon mu = (mithep::Muon)((*muonArr)[i]);
147
148	SelectionStatus musel;
149	if(ctrl.debug) cout << "musel.status before anything: " << musel.getStatus() << endl;
150	musel \|= (*MuonPreSelector)(ctrl,mu,vtx,pfCandidates);
151	if(ctrl.debug) cout << "musel.status after presel: " << musel.getStatus() << endl;
152	if( !(musel.getStatus() & SelectionStatus::PRESELECTION) ) continue;
153	musel \|= (*MuonIDSelector)(ctrl,mu,vtx );
154	if(ctrl.debug) cout << "musel.status after ID: " << musel.getStatus() << endl;
155	musel \|= (*MuonIsoSelector)(ctrl,mu,vtx,pfCandidates,puEnergyDensity,eraMu,muonsToVeto,electronsToVeto);
156	if(ctrl.debug) cout << "musel.status after iso: " << musel.getStatus() << endl;
157
158	if( ctrl.debug ) {
159	cout << "muon:: pt: " << mu->Pt()
160	<< "\teta: " << mu->Eta()
161	<< "\tstatus: " << hex << musel.getStatus() << dec
162	<< endl;
163	}
164
165	if ( musel.pass() ) {
166
167	SimpleLepton tmplep;
168	float pt = mu->Pt();
169	tmplep.vecorig->SetPtEtaPhiM(pt,
170	mu->Eta(),
171	mu->Phi(),
172	MUON_MASS);
173
174	if( ctrl.do_escale_up ) {
175	pt=scale_smear_muon_Up(pt, 1, r);
176	}
177	if( ctrl.do_escale_down ) {
178	pt=scale_smear_muon_Down(pt, 1, r);
179	}
180
181	tmplep.vec->SetPtEtaPhiM(pt,
182	mu->Eta(),
183	mu->Phi(),
184	MUON_MASS);
185
186	tmplep.type = 13;
187	tmplep.index = i;
188	tmplep.charge = mu->Charge();
189	tmplep.isoTrk = mu->IsoR03SumPt();
190	tmplep.isoEcal = mu->IsoR03EmEt();
191	tmplep.isoHcal = mu->IsoR03HadEt();
192	tmplep.isoPF03 = computePFMuonIso(mu,vtx,pfCandidates,0.3);
193	tmplep.isoPF04 = computePFMuonIso(mu,vtx,pfCandidates,0.4);
194	tmplep.ip3dSig = mu->Ip3dPVSignificance();
195	tmplep.is4l = false;
196	tmplep.isEB = (fabs(mu->Eta()) < 1.479 ? 1 : 0 );
197	tmplep.isTight = musel.tight();
198	tmplep.isLoose = musel.loose();
199	lepvec.push_back(tmplep);
200	if( ctrl.debug ) { cout << "muon passes ... " << endl;}
201	}
202	// }
203	}
204
205
206
207	//
208	if( ctrl.debug ) { cout << "\tnElectron: " << electronArr->GetEntries() << endl; }
209	// --------------------------------------------------------------------------------
210	for(Int_t i=0; i<electronArr->GetEntries(); i++)
211	{
212	const mithep::Electron ele = (mithep::Electron)((*electronArr)[i]);
213
214	Bool_t isMuonOverlap = kFALSE;
215	for (int k=0; k<lepvec.size(); ++k) {
216	TVector3 tmplep;
217	tmplep.SetPtEtaPhi(ele->Pt(), ele->Eta(), ele->Phi());
218	if ( lepvec[k].isLoose && lepvec[k].type == 13 && lepvec[k].vec->Vect().DrEtaPhi(tmplep) < 0.1 ) {
219	if( ctrl.debug ) cout << "-----> isMuonOverlap! " << endl;
220	isMuonOverlap = kTRUE;
221	break;
222	}
223	}
224
225	SelectionStatus elesel;
226	if( ctrl.debug ) cout << "--> status before anything: " << hex << elesel.getStatus() << dec << endl;
227	elesel \|= (*ElectronPreSelector)(ctrl,ele,vtx);
228	if( ctrl.debug ) cout << "--> status after presel: " << hex << elesel.getStatus() << dec << endl;
229	elesel \|= (*ElectronIDSelector)(ctrl,ele,vtx);
230	if( ctrl.debug ) cout << "--> status after ID: " << hex << elesel.getStatus() << dec << endl;
231	elesel \|= (*ElectronIsoSelector)(ctrl,ele,vtx,pfCandidates,puEnergyDensity,eraEle,muonsToVeto,electronsToVeto);
232	if( ctrl.debug ) cout << "--> status after iso: " << hex << elesel.getStatus() << dec << endl;
233
234	if( ctrl.debug ){
235	cout << "\tscEt: " << ele->SCluster()->Et()
236	<< "\tscEta: " << ele->SCluster()->Eta()
237	<< "\tstatus: " << hex << elesel.getStatus() << dec
238	<< endl;
239	}
240
241	if ( elesel.pass() && !isMuonOverlap )
242	{
243	SimpleLepton tmplep;
244
245	float pt = ele->Pt();
246	tmplep.vecorig->SetPtEtaPhiM( pt,
247	ele->Eta(),
248	ele->Phi(),
249	ELECTRON_MASS );
250
251	if( ctrl.do_escale ) {
252	pt=scale_smear_electron(pt, ele->IsEB(), r);
253	}
254	if( ctrl.do_escale_up ) {
255	pt=scale_smear_electron_Up(pt, ele->IsEB(), r);
256	}
257	if( ctrl.do_escale_down ) {
258	pt=scale_smear_electron_Down(pt, ele->IsEB(), r);
259	}
260
261
262	tmplep.vec->SetPtEtaPhiM( pt,
263	ele->Eta(),
264	ele->Phi(),
265	ELECTRON_MASS );
266
267	tmplep.type = 11;
268	tmplep.index = i;
269	tmplep.charge = ele->Charge();
270	tmplep.isoTrk = ele->TrackIsolationDr03();
271	tmplep.isoEcal = ele->EcalRecHitIsoDr03();
272	tmplep.isoHcal = ele->HcalTowerSumEtDr03();
273	tmplep.isoPF03 = computePFEleIso(ele,vtx,pfCandidates,0.3);
274	tmplep.isoPF04 = computePFEleIso(ele,vtx,pfCandidates,0.4);
275	tmplep.ip3dSig = ele->Ip3dPVSignificance();
276	tmplep.is4l = false;
277	tmplep.isEB = ele->IsEB();
278	tmplep.scID = ele->SCluster()->GetUniqueID();
279	tmplep.isTight = elesel.tight();
280	tmplep.isLoose = elesel.loose();
281	lepvec.push_back(tmplep);
282	if( ctrl.debug ) { cout << "\telectron passes ... " << endl; }
283	}
284	}
285
286
287	//********************************************************
288	// Dump Stuff
289	//********************************************************
290	sort( lepvec.begin(), lepvec.end(), SimpleLepton::lep_pt_sort );
291	int nmu=0, nele=0;
292	for( int i=0; i<lepvec.size(); i++ ) {
293	if(ctrl.debug) cout << "lepvec :: index: " << i
294	<< "\tpt: " << lepvec[i].vec->Pt()
295	<< "\ttype: " << lepvec[i].type
296	<< endl;
297	if( abs(lepvec[i].type) == 11 ) nele++;
298	else nmu++;
299	}
300	if( ctrl.debug ) {
301	cout << "postsel nlep: " << lepvec.size()
302	<< "\tnmuon: " << nmu
303	<< "\tnelectron: " << nele
304	<< endl;
305	}
306
307
308	//******************************************************************************
309	// Z1 Selection
310	//******************************************************************************
311	int Z1LeptonPlusIndex = -1;
312	int Z1LeptonMinusIndex = -1;
313	double BestZ1Mass = -999;
314	if( ctrl.debug ) { cout << "looking for a Z1 ..." << endl; }
315	for(int i = 0; i < lepvec.size(); ++i) {
316	if( !(lepvec[i].isLoose) ) continue;
317	for(int j = i+1; j < lepvec.size(); ++j) {
318	if( !(lepvec[j].isLoose) ) continue;
319	if( ctrl.debug ) { cout << "\tconsidering leptons " << i << " & " << j << endl; }
320	if (!(lepvec[i].vec->Pt() > 20.0 \|\| lepvec[j].vec->Pt() > 20.0)) continue;
321	if( ctrl.debug ) { cout << "\tat least one is > 20 GeV" << endl; }
322	if (!(lepvec[i].vec->Pt() > 10.0 && lepvec[j].vec->Pt() > 10.0)) continue;
323	if( ctrl.debug ) { cout << "\tthe other is > 10 GeV" << endl; }
324	if (lepvec[i].charge == lepvec[j].charge) continue;
325	if( ctrl.debug ) { cout << "\tthey're opposite charge" << endl; }
326	if (fabs(lepvec[i].type) != fabs(lepvec[j].type)) continue;
327	if( ctrl.debug ) { cout << "\tthey're same flavor" << endl; }
328
329	//Make Z1 hypothesis
330	TLorentzVector leptonPlus, leptonMinus;
331	if ( lepvec[i].charge > 0 ) {
332	leptonPlus = lepvec[i].vec;
333	leptonMinus = lepvec[j].vec;
334	} else {
335	leptonPlus = lepvec[j].vec;
336	leptonMinus = lepvec[i].vec;
337	}
338
339	float tmpZ1Mass = (leptonPlus + leptonMinus).M();
340	if( ctrl.debug ) cout << "Z1 selection, tmpZ1Mass: " << tmpZ1Mass << endl;
341	if( tmpZ1Mass > 60 ) {
342	if (fabs(tmpZ1Mass - Z_MASS) < fabs(BestZ1Mass - Z_MASS)) {
343	BestZ1Mass = tmpZ1Mass;
344	if( ctrl.debug ) cout << "Z1 selection, new BestZ1Mass: " << BestZ1Mass
345	<< "\tdM: " << fabs(BestZ1Mass - Z_MASS)
346	<< endl;
347	if (lepvec[i].charge > 0) {
348	Z1LeptonPlusIndex = i;
349	Z1LeptonMinusIndex = j;
350	} else {
351	Z1LeptonPlusIndex = j;
352	Z1LeptonMinusIndex = i;
353	}
354	}
355	}
356	}
357	}
358	// stop if no Z1 candidate is found
359	if( BestZ1Mass < 0 ) {
360	evtfail \|= (1<<EVTFAIL_Z1);
361	//ret.status = evtfail;
362	ret.status.setStatus(0);
363	return ret;
364	}
365	if( ctrl.debug ) cout << "\tgot a Z1 ... run: " << info->RunNum() << "\tevt: " << info->EvtNum() << endl;
366	if( ctrl.debug ) cout << "\tZ1 plusindex: " << Z1LeptonPlusIndex << "\tminusindex: " << Z1LeptonMinusIndex << endl;
367	TLorentzVector Z1LeptonPlus = *(lepvec[Z1LeptonPlusIndex].vec);
368	TLorentzVector Z1LeptonMinus = *(lepvec[Z1LeptonMinusIndex].vec);
369	TLorentzVector Z1Candidate = Z1LeptonPlus + Z1LeptonMinus;
370
371
372	//******************************************************************************
373	// Z1 + l
374	//******************************************************************************
375	if( lepvec.size() < 3 ) {
376	evtfail \|= (1<<EVTFAIL_Z1_PLUSL);
377	//ret.status = evtfail;
378	ret.status.setStatus(0);
379	return ret;
380	}
381
382	//******************************************************************************
383	// 4l/Z2 Selection
384	//******************************************************************************
385	Int_t Z2LeptonPlusIndex = -1;
386	Int_t Z2LeptonMinusIndex = -1;
387	Double_t BestZ2Mass = -1;
388	if( ctrl.debug ) cout << "looking for a Z2 ... out of " << lepvec.size() << " leptons" <<endl;
389	for(int i = 0; i < lepvec.size(); ++i) {
390
391	if( ctrl.debug) cout << "i: " << i
392	<< "\tpt: " << lepvec[i].vec->Pt()
393	<< "\ttype: " << lepvec[i].type
394	<< endl;
395
396	if( ctrl.eleSeleScheme == "mediumloose" &&
397	!(lepvec[i].isTight) ) {
398	if( ctrl.debug) cout << "it's not tight, skipping ... " << endl;
399	continue;
400	}
401
402	for(int j = i+1; j < lepvec.size(); ++j) {
403	if( ctrl.debug) cout << "\t\tj: " << j
404	<< "\tpt: " << lepvec[j].vec->Pt()
405	<< "\ttype: " << lepvec[j].type
406	<< endl;
407
408	if( ctrl.eleSeleScheme == "mediumloose" &&
409	!(lepvec[j].isTight) ) {
410	if( ctrl.debug) cout << "it's not tight, skipping ... " << endl;
411	continue;
412	}
413
414
415	if (i == Z1LeptonPlusIndex \|\| i == Z1LeptonMinusIndex) {
416	if( ctrl.debug) cout << "\ti matches a Z1 index, skipping ..." << endl;
417	continue; //skip Z1 leptons
418	}
419	if (j == Z1LeptonPlusIndex \|\| j == Z1LeptonMinusIndex) {
420	if( ctrl.debug) cout << "\tj matches a Z1 index, skipping ..." << endl;
421	continue; //skip Z1 leptons
422	}
423	if (lepvec[i].charge == lepvec[j].charge) {
424	if( ctrl.debug) cout << "\ti and j are same sign, skipping ..." << endl;
425	continue; //require opp sign
426	}
427	if (fabs(lepvec[i].type) != fabs(lepvec[j].type)) {
428	if( ctrl.debug) cout << "\ti and j are not same flavor, skipping ..." << endl;
429	continue; //require same flavor
430	}
431
432
433	//Make Z2 hypothesis
434	TLorentzVector leptonPlus, leptonMinus;
435
436	if (lepvec[i].charge > 0 ) {
437	leptonPlus = lepvec[i].vec;
438	leptonMinus = lepvec[j].vec;
439	} else {
440	leptonPlus = lepvec[j].vec;
441	leptonMinus = lepvec[i].vec;
442	}
443
444	TLorentzVector dilepton = leptonPlus + leptonMinus;
445	TLorentzVector fourLepton = Z1Candidate + dilepton;
446
447	if( ctrl.debug ) cout << "dilepton.M() : " << dilepton.M() << endl;
448	if( ctrl.debug ) cout << "fourLepton.M() : " << fourLepton.M() << endl;
449
450	if (!(dilepton.M() > 12.0)) continue;
451	if (!(fourLepton.M() > 100.0)) continue;
452
453	//for 4e and 4mu, require at least 1 of the other opp sign lepton pairs have mass > 12
454	if (fabs(lepvec[i].type) == fabs(lepvec[Z1LeptonPlusIndex].type)) {
455	TLorentzVector pair1 = Z1LeptonPlus + *leptonMinus;
456	TLorentzVector pair2 = Z1LeptonMinus + *leptonPlus;
457	if( ctrl.debug ) cout << "pair1: " << pair1.M() << "\tpair2: "<< pair2.M() << endl;
458	if (!(pair1.M() > 12 \|\| pair2.M() > 12)) continue;
459	}
460
461
462	//Disambiguiation is done by choosing the pair with the largest ptMax and largest ptMin
463	if (Z2LeptonPlusIndex < 0) {
464	if (lepvec[i].charge > 0) {
465	Z2LeptonPlusIndex = i;
466	Z2LeptonMinusIndex = j;
467	} else {
468	Z2LeptonPlusIndex = j;
469	Z2LeptonMinusIndex = i;
470	}
471	} else {
472	Double_t BestPairPtMax = lepvec[Z2LeptonPlusIndex].vec->Pt();
473	Double_t BestPairPtMin = lepvec[Z2LeptonMinusIndex].vec->Pt();
474	if (lepvec[Z2LeptonMinusIndex].vec->Pt() > BestPairPtMax) {
475	BestPairPtMax = lepvec[Z2LeptonMinusIndex].vec->Pt();
476	BestPairPtMin = lepvec[Z2LeptonPlusIndex].vec->Pt();
477	}
478
479	Double_t CurrentPairPtMax = lepvec[i].vec->Pt();
480	Double_t CurrentPairPtMin = lepvec[j].vec->Pt();
481	if (lepvec[j].vec->Pt() > CurrentPairPtMax) {
482	CurrentPairPtMax = lepvec[j].vec->Pt();
483	CurrentPairPtMin = lepvec[i].vec->Pt();
484	}
485
486	if (CurrentPairPtMax > BestPairPtMax) {
487	if (lepvec[i].charge > 0) {
488	Z2LeptonPlusIndex = i;
489	Z2LeptonMinusIndex = j;
490	} else {
491	Z2LeptonPlusIndex = j;
492	Z2LeptonMinusIndex = i;
493	}
494	} else if (CurrentPairPtMax == BestPairPtMax) {
495	if (CurrentPairPtMin > BestPairPtMin) {
496	if (lepvec[i].charge > 0) {
497	Z2LeptonPlusIndex = i;
498	Z2LeptonMinusIndex = j;
499	} else {
500	Z2LeptonPlusIndex = j;
501	Z2LeptonMinusIndex = i;
502	}
503	}
504	}
505	}
506	}
507	}
508
509	// stop if no Z2 candidate is found
510	if (Z2LeptonPlusIndex == -1) {
511	evtfail \|= ( 1<<EVTFAIL_4L );
512	// ret.status = evtfail;
513	ret.status.setStatus(0);
514	return ret;
515	}
516	if( ctrl.debug ) cout << "\tgot a Z2 ..." << endl;
517	if( ctrl.debug ) cout << "\tZ2 plusindex: " << Z2LeptonPlusIndex
518	<< "\tminusindex: " << Z2LeptonMinusIndex << endl;
519	TLorentzVector Z2LeptonPlus = *(lepvec[Z2LeptonPlusIndex].vec);
520	TLorentzVector Z2LeptonMinus = *(lepvec[Z2LeptonMinusIndex].vec);
521	TLorentzVector Z2Candidate = Z2LeptonPlus+Z2LeptonMinus;
522	TLorentzVector ZZSystem = Z1Candidate + Z2Candidate;
523	lepvec[Z1LeptonPlusIndex].is4l = true;
524	lepvec[Z1LeptonMinusIndex].is4l = true;
525	lepvec[Z2LeptonPlusIndex].is4l = true;
526	lepvec[Z2LeptonMinusIndex].is4l = true;
527
528
529
530
531	//***************************************************************
532	// remaining kinematic cuts
533	//***************************************************************
534	double Z2massCut=0;
535	if ( ctrl.kinematics == "loose" ) Z2massCut = 12;
536	else if ( ctrl.kinematics == "tight" ) Z2massCut = 20;
537	else { cout << "error! kinematic tightness not defined!" << endl; assert(0); }
538
539	if ( Z1Candidate.M() > 120 \|\|
540	Z2Candidate.M() < Z2massCut \|\|
541	Z2Candidate.M() > 120 \|\|
542	!(lepvec[Z1LeptonPlusIndex].vec->Pt() > 20.0 \|\| lepvec[Z1LeptonMinusIndex].vec->Pt() > 20.0) \|\|
543	!(lepvec[Z1LeptonPlusIndex].vec->Pt() > 10.0 && lepvec[Z1LeptonMinusIndex].vec->Pt() > 10.0)
544	) {
545	evtfail \|= (1<<EVTFAIL_KINEMATICS );
546	// ret.status = evtfail;
547	ret.status.setStatus(0);
548	return ret;
549	}
550
551	unsigned channel;
552	if( lepvec[Z1LeptonMinusIndex].type == 11 && lepvec[Z2LeptonMinusIndex].type == 11 ) channel=0;
553	if( lepvec[Z1LeptonMinusIndex].type == 13 && lepvec[Z2LeptonMinusIndex].type == 13 ) channel=1;
554	if( (lepvec[Z1LeptonMinusIndex].type == 11 && lepvec[Z2LeptonMinusIndex].type == 13) \|\|
555	(lepvec[Z1LeptonMinusIndex].type == 13 && lepvec[Z2LeptonMinusIndex].type == 11)) channel=2;
556
557
558
559
560	if( ctrl.debug ) cout << "run: " << info->RunNum()
561	<< "\tevt: " << info->EvtNum()
562	<< "\tZ1channel: " << lepvec[Z1LeptonMinusIndex].type
563	<< "\tZ2channel: " << lepvec[Z2LeptonMinusIndex].type
564	<< "\tmZ1: " << Z1Candidate.M()
565	<< "\tmZ2: " << Z2Candidate.M()
566	<< "\tm4l: " << ZZSystem.M()
567	<< "\tevtfail: " << hex << evtfail << dec
568	// << "\ttrigbits: " << hex << info->triggerBits << dec
569	// << "\ttree: " << inputFiles[q][f]
570	<< endl;
571
572
573
574	//***************************************************************
575	// finish
576	//***************************************************************
577
578	if( !evtfail ) {
579	ret.status.setStatus(SelectionStatus::EVTPASS);
580	ret.Z1leptons.push_back(lepvec[Z1LeptonMinusIndex]);
581	ret.Z1leptons.push_back(lepvec[Z1LeptonPlusIndex]);
582	ret.Z2leptons.push_back(lepvec[Z2LeptonMinusIndex]);
583	ret.Z2leptons.push_back(lepvec[Z2LeptonPlusIndex]);
584	}
585
586	return ret;
587	}
588
589