bool L2RecoMatchTest::processEvent(cafe::Event &event) { // The vector of "Matches" and iterators of it are used with the _old_ interface std::vector<Match< TMBL2Base, TMBLorentzVector> > test; std::vector<Match< TMBL2Base, TMBLorentzVector> >::iterator match_it; //The new interface uses a multimap and iterators thereof. std::multimap<Collection<TMBL2Base>::iterator, Collection<TMBLorentzVector>::iterator> L2Reco; std::multimap<Collection<TMBL2Base>::iterator, Collection<TMBLorentzVector>::iterator>::iterator L2Reco_it; Collection<TMBL2Base>::iterator l2_it; Collection<TMBLorentzVector>::iterator reco_it; //Uncomment the following section to print a list of all triggers of the event /* Collection<TMBTrigger> triggers = event.getTriggers(); Collection<TMBTrigger>::iterator trigger_it=triggers.begin(); for(; trigger_it!=triggers.end(); trigger_it++) { std::cout << (*trigger_it).getTrgName() << std::endl; }; */ //Example to access the matchings, old interface! if(event.get(_matchname, test)) { match_it=test.begin(); std::cout << "Found " << test.size() << " match(es) in the event." << std::endl; for(; match_it!=test.end(); match_it++) { std::cout << "dr = " << (*match_it).getdR() << std::endl; std::cout << "Et = " << (*match_it).getObj1It()->Et() << std::endl; }; } //Example code to access the matchings, new interface! if(event.get(_matchname+"MAP", L2Reco)) { std::cout << "Matches in the event: " << L2Reco.size() << std::endl; L2Reco_it = L2Reco.begin(); int i=0; for(; L2Reco_it!=L2Reco.end(); L2Reco_it++) { l2_it = (*L2Reco_it).first; reco_it = (*L2Reco_it).second; float dphi = kinem::delta_phi((*l2_it).Phi(), (*reco_it).Phi()); float deta = (*l2_it).Eta() - (*reco_it).Eta(); float dR = sqrt(dphi * dphi + deta * deta); std::cout << "Distance of match: " << dR << std::endl; std::cout << "Et of L2 object: " << (*l2_it).Et() << "; and pT of reco object: " << (*reco_it).Pt() << std::endl; }; }; std::cout << "--------------------------------------------------------------------------" << std::endl; return true; };
bool RemoveObjects::processEvent(cafe::Event& event) { using namespace cafe; using namespace std; vector<TObjArray*> vars; for(vector<string>::const_iterator it = _list.begin(); it != _list.end(); ++it) { TObjArray *ptr = 0; if(event.get(*it, ptr) && ptr != 0) { vars.push_back(ptr); } else { err() << "RemoveObjects[" << name() << "]: No such list:" << *it << endl; } } if(TClonesArray *objects = const_cast<TClonesArray*>(event.getClonesArray(_branch))) { unsigned int initial = objects->GetLast() + 1; unsigned int count = 0; // need non-const object since we modify it... TIter iter(objects); while(TObject *obj = iter.Next()) { bool remove = true; for(vector<TObjArray*>::const_iterator it = vars.begin(); it != vars.end(); ++it) { if((*it)->FindObject(obj) != 0) { remove = false; break; } } if(remove) { count++; objects->Remove(obj); } } objects->Compress(); } else { err() << "RemoveObjects[" << name() << "]: No such branch: " << _branch << endl; } return true; }
// process bool FakeAnalysis::processEvent(cafe::Event& event) { vector<CAFEMObj*> emobjs; CAFMet met_corr; int triglist_flag = -1; vector<const TMBL1CalTower*> l1cal_vec; vector<const TMBL1Cal2bEM*> l1cal2b_vec; vector<const TMBL2GblEM*> l2cal_vec; vector<const TMBL3Ele*> l3cal_vec; float event_vertex; int solpol = -999; double instlumi = 0.; if(event.get("Good EMObjs", emobjs) && event.get("EMCorr Met", met_corr) && event.get("L1CalTowers", l1cal_vec) && event.get("L1Cal2bTowers", l1cal2b_vec) && event.get("L2GblEMs", l2cal_vec) && event.get("L3Eles", l3cal_vec) && event.get("triglist flag", triglist_flag) && event.get("InstLumi", instlumi) && event.get("solenoid polarity", solpol) && event.get("Primary vertexZ", event_vertex)) { if(instlumi > _InstLumi_lowcut && instlumi < _InstLumi_highcut){ double met = met_corr.met(); // require exactly one electron and this electron must pass trigger requirement bool pass_trigger = false; if(emobjs.size() == 1) pass_trigger = emobjs[0]->PassTrigCMB(triglist_flag, 0.4, l1cal_vec, l1cal2b_vec, l2cal_vec, l3cal_vec); // only look at the electron that passes trigger requirement if(pass_trigger) { // get primary vertex double v_z = event_vertex; char bins_Vtx[10]; int bin_Vtx_number; bin_Vtx_number=int((v_z+60.)/20.); sprintf(bins_Vtx, "%d", bin_Vtx_number); // identify Zee candidates // ************* code from WAnalysis ********************* // ************* for estimating zee bkgd ***************** // require no high pT isolated track back-to-back with the electron bool EM_Track_backtoback = false; // change solpol from 0/1 to -1/1 int polarity = 2*solpol -1; // get all isolated tracks vector<CAFTrack *> isolatedTrks; if(event.get("Good Tracks", isolatedTrks)) { for(int itrk=0; itrk<isolatedTrks.size(); itrk++) { double em_trk_phidiff = kinem::delta_phi(emobjs[0]->Phi(), isolatedTrks[itrk]->Phi()); if(em_trk_phidiff > 2.5 && // back to back with the EM cluster fabs(isolatedTrks[itrk]->TrackDetEta(polarity, false /*_MCStudy*/))>1.1 && // track in ICR fabs(isolatedTrks[itrk]->TrackDetEta(polarity, false /*_MCStudy*/))<1.5 && fabs(isolatedTrks[itrk]->z()-v_z)<1. && // vertex close to each other (isolatedTrks[itrk]->charge())*(emobjs[0]->charge())<0.) { // opposite charge TLorentzVector vect_trk(isolatedTrks[itrk]->Px(),isolatedTrks[itrk]->Py(),isolatedTrks[itrk]->Pz(),isolatedTrks[itrk]->E()); TLorentzVector vect_emobj(emobjs[0]->Px(),emobjs[0]->Py(),emobjs[0]->Pz(),emobjs[0]->E()); TLorentzVector vect_Z=vect_trk+vect_emobj; // invariant mass if(vect_Z.M()>70. && vect_Z.M()<110.) EM_Track_backtoback = true; } } } // end of identify Zee candidates if(EM_Track_backtoback==false) { //get jets from the event cafe::Collection<TMBJet> jets = event.getJCCB(_jccb_vars); for(Collection<TMBJet>::iterator iter = jets.begin(); iter!= jets.end(); ++iter) { if(GoodJet(*iter)) { float dphi_jet_em = kinem::delta_phi(emobjs[0]->Phi(), (*iter).Phi()); //get rid of the jet if they are close to each other //since EM cluster may also be reconstructed as a jet if(fabs(dphi_jet_em) > _DPhi_Jet_EM_Cut) { // determine whether electron in CC or EC region int cal_region = -1; if(emobjs[0]->IsCC(_DetEtaCC)) cal_region = 0; if(emobjs[0]->IsEC(_DetEtaEC1, _DetEtaEC2)) cal_region = 1; char region[10]; sprintf(region, "%d", cal_region); float elec_deteta = emobjs[0]->CalDetectorEta(); float elec_eta = emobjs[0]->Eta(); float elec_pT = emobjs[0]->Pt(); _histos.Fill1D("Fake_Electron_DetEta", elec_deteta); _histos.Fill1D("Fake_Electron_Eta", elec_eta); _histos.Fill1D("Fake_Electron_Pt", elec_pT); _histos.Fill1D("Fake_Met", met); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_")+region, elec_pT); _histos.Fill1D(string("Fake_Met_")+region, met); if(met< 15. && cal_region==0){ _histos.Fill1D(string("Fake_Electron_DetEta_CCVtxBin_")+bins_Vtx, emobjs[0]->CalDetectorEta()); } // spatial+E/P if(emobjs[0]->has_track_match()) { _histos.Fill1D("Fake_Electron_DetEta_Match", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Match", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Match", elec_pT); _histos.Fill1D("Fake_Met_Match", met); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Match_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Match_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Match_")+region, elec_pT); _histos.Fill1D(string("Fake_Met_Match_")+region, met); } // spatial only if(emobjs[0]->has_good_spatial_track_match()) { _histos.Fill1D("Fake_Electron_DetEta_Spatial_Match", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Spatial_Match", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Spatial_Match", elec_pT); _histos.Fill1D("Fake_Met_Spatial_Match", met); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Spatial_Match_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Spatial_Match_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Spatial_Match_")+region, elec_pT); _histos.Fill1D(string("Fake_Met_Spatial_Match_")+region, met); if(met< 15. && cal_region==0){ _histos.Fill1D(string("Fake_Electron_DetEta_CCVtxBin_Spatial_Match_")+bins_Vtx, emobjs[0]->CalDetectorEta()); } } // spatial only+SMT,CFT if(emobjs[0]->has_spatial_track_match(-0.5)) { // check chi2 vs met _histos.Fill2D("Fake_Electron_Chi2_V_Met_Spatial_Match", met, emobjs[0]->track_match_spatialchi2prob()); _histos.Fill2D(string("Fake_Electron_Chi2_V_Met_Spatial_Match_")+region, met, emobjs[0]->track_match_spatialchi2prob()); _histos.Fill1D("Fake_Electron_Chi2", emobjs[0]->track_match_spatialchi2prob()); _histos.Fill1D(string("Fake_Electron_Chi2_")+region, emobjs[0]->track_match_spatialchi2prob()); double ElecPt = emobjs[0]->Pt(); double TrkPt = emobjs[0]->getPtrSpatialChp()->Pt(); double EOverP = 0.; if(TrkPt>0.) EOverP = ElecPt/TrkPt; if(emobjs[0]->getPtrSpatialChp()->nsmt()>=1 && emobjs[0]->getPtrSpatialChp()->ncft()>=4) { // check chi2 vs met _histos.Fill2D("Fake_Electron_Chi2_V_Met_Spatial_Match_Tight", met, emobjs[0]->track_match_spatialchi2prob()); _histos.Fill2D(string("Fake_Electron_Chi2_V_Met_Spatial_Match_Tight_")+region, met, emobjs[0]->track_match_spatialchi2prob()); _histos.Fill1D("Fake_Electron_Chi2_Tight", emobjs[0]->track_match_spatialchi2prob()); _histos.Fill1D(string("Fake_Electron_Chi2_Tight_")+region, emobjs[0]->track_match_spatialchi2prob()); _histos.Fill1D("Fake_Electron_DetEta_Spatial_Match_Tight", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Spatial_Match_Tight", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Spatial_Match_Tight", elec_pT); _histos.Fill1D("Fake_Met_Spatial_Match_Tight", met); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Spatial_Match_Tight_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Spatial_Match_Tight_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Spatial_Match_Tight_")+region, elec_pT); _histos.Fill1D(string("Fake_Met_Spatial_Match_Tight_")+region, met); } } //####################################################### // same histograms for met<_MetCut_FakeRate //####################################################### if( met < _MetCut_FakeRate ) { _histos.Fill1D("Fake_Electron_DetEta_MetCut", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_MetCut", elec_eta); _histos.Fill1D("Fake_Electron_Pt_MetCut", elec_pT); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_MetCut_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_MetCut_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_MetCut_")+region, elec_pT); // spatial+E/P if(emobjs[0]->has_track_match()) { _histos.Fill1D("Fake_Electron_DetEta_Match_MetCut", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Match_MetCut", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Match_MetCut", elec_pT); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Match_MetCut_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Match_MetCut_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Match_MetCut_")+region, elec_pT); } // good spatial only if(emobjs[0]->has_good_spatial_track_match()) { _histos.Fill1D("Fake_Electron_DetEta_Spatial_Match_MetCut", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Spatial_Match_MetCut", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Spatial_Match_MetCut", elec_pT); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Spatial_Match_MetCut_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Spatial_Match_MetCut_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Spatial_Match_MetCut_")+region, elec_pT); } // spatial only+SMT,CFT+E/p if(emobjs[0]->has_spatial_track_match(-0.5)) { double ElecPt = emobjs[0]->Pt(); double TrkPt = emobjs[0]->getPtrSpatialChp()->Pt(); double EOverP = 0.; if(TrkPt>0.) EOverP = ElecPt/TrkPt; if(emobjs[0]->getPtrSpatialChp()->nsmt()>=1 && emobjs[0]->getPtrSpatialChp()->ncft()>=4) { _histos.Fill1D("Fake_Electron_DetEta_Spatial_Match_Tight_MetCut", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Spatial_Match_Tight_MetCut", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Spatial_Match_Tight_MetCut", elec_pT); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Spatial_Match_Tight_MetCut_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Spatial_Match_Tight_MetCut_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Spatial_Match_Tight_MetCut_")+region, elec_pT); } } } // missing Et cut } // EM and Jet are back-to-back } } // loop over jets }//if(EM_Track_backtoback==false) i.e. this is not zee event }// exactly one good EM object and pass trigger }//lumi cut } return true; }
bool TopMuonPairSelector::processEvent(cafe::Event &event) { //get pointer to statistics collector StatPointer stat ; event.get("StatPointer", stat) ; Collection<TMBEMCluster> em_from(event.getCollection<TMBEMCluster>(_electronBranch.c_str())); Collection<TMBMuon> mu_from(event.getCollection<TMBMuon>(_muonBranch.c_str())); Collection<TMBMuon> all_muons( event.getMuons() ); if (em_from.size() == 0 && mu_from.size() == 0 && debug ) { out() << "PAIR SELECTOR WARNING! Electron/Muon branch " << _electronBranch << "/" << _muonBranch << " is empty or is not existing! " << endl ; return true ; } if (em_from.size() >=2 && debug) { out() << "PAIR SELECTOR ERROR! 2 electrons found in branch \"" << _electronBranch << "\". Considering only leading electron outside of a jet!" << endl ; // return false ; } l_mom.SetPxPyPzE( 0 , 0 , 0 , 0 ); lepton_charge = 0; jet_array = event.getCollection<TMBJet>(_jet_branch.c_str()); if( em_from.size() == 0 ) { for( int i = 0 ; i < mu_from.size() ; i++ ) { bool is_in_jet = false; if( dR_cut > 0 ) { for( int j = 0 ; j < jet_array.size() ; j++ ) { if( do_dr_mujet_lead_muon && mu_from[i].DeltaR( jet_array[j] ) < dR_cut ) is_in_jet = true; } } if( use_only_leading_lepton && i > 0 ) is_in_jet = true; if( mu_from[i].Pt() > l_mom.Pt() && mu_from[i].charge() != 0 && !is_in_jet ) { l_mom = mu_from[i]; l_track = const_cast<TMBTrack*>(mu_from[i].GetChargedTrack()); lepton_charge = mu_from[i].charge(); } } } else { for( int i = 0 ; i < em_from.size() ; i++ ) { if( em_from[i].Pt() > l_mom.Pt() && em_from[i].charge() != 0 ) { bool common_track = false; for( int j = 0 ; j < all_muons.size() ; j++ ) { if( remove_common_track && ( all_muons[j].GetChargedTrack() && all_muons[j].isLoose() == 1 ) && ( em_from[i].getPtrChp()->DeltaR( *all_muons[j].GetChargedTrack() ) < 1e-4 ) ) common_track = true; } if( use_only_leading_lepton && i > 0 ) common_track = true; if( !common_track ) { l_mom = em_from[i]; l_track = const_cast<TMBTrack*>(em_from[i].getPtrChp()); lepton_charge = em_from[i].charge(); } } } } if (_selectSameSign) { stat.EventSelected("Same charge selection") ; } else { stat.EventSelected("Opposite charge selection") ; } SelectUserObjects<TMBMuon>::processEvent(event); return true; }
// process bool FakeAnalysis_with_ej_tree::processEvent(cafe::Event& event) { cout <<"in Fakeanalysis code"<<endl; const TMBCellContainer *cells = event.get<TMBCellContainer>("CaloCells"); vector<CAFEMObj*> emobjs; CAFMet met_corr; CAFMet met_corricd; CAFMet rawmet; int triglist_flag = -1; vector<const TMBL1CalTower*> l1cal_vec; vector<const TMBL1Cal2bEM*> l1cal2b_vec; vector<const TMBL2GblEM*> l2cal_vec; vector<const TMBL3Ele*> l3cal_vec; float event_vertex; float v_x,v_y,v_z; int solpol = -999; double instlumi = 0.; cout<<"Good EMObjs, emobjs " <<event.get("Good EMObjs", emobjs) << endl; cout<<"EMCorr Met, met_cor " <<event.get("EMCorr Met", met_corr) << endl; cout<<"Raw Met, rawmet) << " <<event.get("Raw Met", rawmet) << endl; cout<<"EMCorr MetICD, met_ " <<event.get("EMCorr MetICD", met_corricd) << endl; cout<<"L1CalTowers, l1cal_ " <<event.get("L1CalTowers", l1cal_vec) << endl; cout<<"L1Cal2bTowers, l1ca " <<event.get("L1Cal2bTowers", l1cal2b_vec) << endl; cout<<"L2GblEMs, l2cal_vec " <<event.get("L2GblEMs", l2cal_vec) << endl; cout<<"L3Eles, l3cal_vec) " <<event.get("L3Eles", l3cal_vec) << endl; cout<<"triglist flag, trig " <<event.get("triglist flag", triglist_flag) << endl; cout<<"InstLumi, instlumi) " <<event.get("InstLumi", instlumi) << endl; cout<<"solenoid polarity, " <<event.get("solenoid polarity", solpol) << endl; cout<<"Best primary vertexZ " <<event.get("Best primary vertexZ", v_z) << endl; cout<<"Best primary vertexX " <<event.get("Best primary vertexX", v_x) << endl; cout<<"Best primary vertexY " <<event.get("Best primary vertexY", v_y) << endl; cout<<" just before event.get loop"<<endl; if(event.get("Good EMObjs", emobjs) && event.get("EMCorr Met", met_corr) && event.get("Raw Met", rawmet) && //event.get("EMCorr MetICD", met_corricd) && event.get("L1CalTowers", l1cal_vec) && event.get("L1Cal2bTowers", l1cal2b_vec) && event.get("L2GblEMs", l2cal_vec) && event.get("L3Eles", l3cal_vec) && event.get("triglist flag", triglist_flag) && event.get("InstLumi", instlumi) && event.get("solenoid polarity", solpol) && event.get("Best primary vertexZ", v_z) && event.get("Best primary vertexX", v_x) && event.get("Best primary vertexY", v_y) ) { cout<<" just before inst lumi"<<endl; if(instlumi > _InstLumi_lowcut && instlumi < _InstLumi_highcut){ double met = met_corr.met(); double set = met_corr.scalarEt(); double meticd = met_corricd.met(); double seticd = met_corricd.scalarEt(); // require exactly one electron and this electron must pass trigger requirement bool pass_trigger = false; if(emobjs.size() == 1) pass_trigger = emobjs[0]->PassTrigCMB(triglist_flag, 0.4, l1cal_vec, l1cal2b_vec, l2cal_vec, l3cal_vec); // only look at the electron that passes trigger requirement if(pass_trigger) { // get primary vertex //double v_z = event_vertex; char bins_Vtx[10]; int bin_Vtx_number; bin_Vtx_number=int((v_z+60.)/20.); sprintf(bins_Vtx, "%d", bin_Vtx_number); // identify Zee candidates // ************* code from WAnalysis ********************* // ************* for estimating zee bkgd ***************** // require no high pT isolated track back-to-back with the electron bool EM_Track_backtoback = false; // change solpol from 0/1 to -1/1 int polarity = 2*solpol -1; // get all isolated tracks vector<CAFTrack *> isolatedTrks; if(event.get("Good Tracks", isolatedTrks)) { for(int itrk=0; itrk<isolatedTrks.size(); itrk++) { double em_trk_phidiff = kinem::delta_phi(emobjs[0]->Phi(), isolatedTrks[itrk]->Phi()); if(em_trk_phidiff > 2.5 && // back to back with the EM cluster fabs(isolatedTrks[itrk]->TrackDetEta(polarity, false /*_MCStudy*/))>1.1 && // track in ICR fabs(isolatedTrks[itrk]->TrackDetEta(polarity, false /*_MCStudy*/))<1.5 && fabs(isolatedTrks[itrk]->z()-v_z)<1. && // vertex close to each other (isolatedTrks[itrk]->charge())*(emobjs[0]->charge())<0.) { // opposite charge TLorentzVector vect_trk(isolatedTrks[itrk]->Px(),isolatedTrks[itrk]->Py(),isolatedTrks[itrk]->Pz(),isolatedTrks[itrk]->E()); TLorentzVector vect_emobj(emobjs[0]->Px(),emobjs[0]->Py(),emobjs[0]->Pz(),emobjs[0]->E()); TLorentzVector vect_Z=vect_trk+vect_emobj; // invariant mass if(vect_Z.M()>70. && vect_Z.M()<110.) EM_Track_backtoback = true; } } } // end of identify Zee candidates if(EM_Track_backtoback==false) { // construct W candidate // primary vertex float vtx[3]={v_x, v_y, v_z}; CAFWCand wcand; CAFEMObj *emobj = 0; double wScalarET = 0.; if (emobjs.size()>=1) { emobj = emobjs[0]; if(_dorawCellsRecoil) { if (_useConsistentMET) { wcand = CAFWCand(emobj, &rawmet, vtx, true); } else { wcand = CAFWCand(emobj, &met_corr, vtx); } } else { wcand = CAFWCand(emobj, &met_corr); } if (_useConsistentMET) { TVector2 consistMET=wcand.GetConsistentMET(); double dummySET=met_corr.scalarEt(); wScalarET = dummySET; met_corr.SetMet(consistMET.X(),consistMET.Y(),consistMET.Mod(),dummySET); } } // ejt tree code //entry = -555; run = -555; evt = -555; lumi = -555; vtxz = -555; evtmet = -555; evtset = -555; evtmeticd = -555; evtseticd = -555; wcandut = -555; wcandmt = -555; e_n = -555; e_pt = -555; e_e = -555; e_eta = -555; e_deta = -555; e_phi = -555; e_charge = -555; e_spmtch = -555; e_goodspmtch = -555; e_id = -555; j_n = -555; j_pt = -555; j_e = -555; j_eta = -555; j_deta = -555; j_phi = -555; j_trks = -555; j_n90 = -555; j_emf = -555; j_chf = -555; j_hcr = -555; ej_deltaphi = -555; ej_m = -555; ej_angle = -555; bool found_JET=false; entry++; run=event.getGlobal()->runno(); evt=event.getGlobal()->evtno(); lumi=instlumi*36.0; vtxz=v_z; evtmet = met; evtset = set; evtmeticd = meticd; evtseticd = seticd; wcandut = wcand.MagRecoil(); wcandmt = wcand.Mt(); if(emobjs[0]->has_spatial_track_match(-0.5)) e_spmtch=1; if(emobjs[0]->has_good_spatial_track_match()) e_goodspmtch=1; e_id=emobjs[0]->id(); e_pt=emobjs[0]->Pt(); e_e=emobjs[0]->E(); e_eta=emobjs[0]->Eta(); e_deta=emobjs[0]->CalDetectorEta(); e_phi=emobjs[0]->Phi(); e_charge=emobjs[0]->charge(); e_n=emobjs.size(); //loop over jets cafe::Collection<TMBJet> jets_ejttree = event.getJCCB(); j_n = 0; if(jets_ejttree.size() > 0) { for(Collection<TMBJet>::iterator iter = jets_ejttree.begin(); iter != jets_ejttree.end(); ++iter) { j_n++; ej_deltaphi=kinem::delta_phi(e_phi, (*iter).Phi()); j_n90 = (*iter).n90(); j_pt = (*iter).Pt(); j_emf = (*iter).emf(); j_chf = (*iter).chf(); j_hcr = (*iter).hotcellratio(); j_trks = (*iter).Ntr(); j_eta = (*iter).Eta(); j_phi = (*iter).Phi(); j_deta = 0.1*((*iter).deta()); j_e = (*iter).E(); TLorentzVector vect_jet((*iter).Px(), (*iter).Py(),(*iter).Pz(),(*iter).E()); TLorentzVector vect_emobj(emobjs[0]->Px(),emobjs[0]->Py(),emobjs[0]->Pz(),emobjs[0]->E()); TLorentzVector vect_Z=vect_jet+vect_emobj; ej_m=vect_Z.M(); TVector3 em_vect3 = emobjs[0]->vect3(); TVector3 jet_vect3( (*iter).Px(), (*iter).Py(), (*iter).Pz() ); ej_angle = em_vect3.Angle(jet_vect3); found_JET = true; ej->Fill(); }// for(Collection<TMBJet> }//if(jets_ejttree.size() > 0) // end of ejt tree code //get jets from the event cafe::Collection<TMBJet> jets = event.getJCCB(_jccb_vars); for(Collection<TMBJet>::iterator iter = jets.begin(); iter!= jets.end(); ++iter) { if(GoodJet(*iter)) { float dphi_jet_em = kinem::delta_phi(emobjs[0]->Phi(), (*iter).Phi()); //get rid of the jet if they are close to each other //since EM cluster may also be reconstructed as a jet if(fabs(dphi_jet_em) > _DPhi_Jet_EM_Cut) { // determine whether electron in CC or EC region int cal_region = -1; if(emobjs[0]->IsCC(_DetEtaCC)) cal_region = 0; if(emobjs[0]->IsEC(_DetEtaEC1, _DetEtaEC2)) cal_region = 1; char region[10]; sprintf(region, "%d", cal_region); float elec_deteta = emobjs[0]->CalDetectorEta(); float elec_eta = emobjs[0]->Eta(); float elec_pT = emobjs[0]->Pt(); cout<<"Fake_Electron_DetEta "<<elec_deteta<<endl; _histos.Fill1D("Fake_Electron_DetEta", elec_deteta); _histos.Fill1D("Fake_Electron_Eta", elec_eta); _histos.Fill1D("Fake_Electron_Pt", elec_pT); _histos.Fill1D("Fake_Met", met); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_")+region, elec_pT); _histos.Fill1D(string("Fake_Met_")+region, met); if(met< 15. && cal_region==0){ _histos.Fill1D(string("Fake_Electron_DetEta_CCVtxBin_")+bins_Vtx, emobjs[0]->CalDetectorEta()); } // spatial+E/P if(emobjs[0]->has_track_match()) { _histos.Fill1D("Fake_Electron_DetEta_Match", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Match", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Match", elec_pT); _histos.Fill1D("Fake_Met_Match", met); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Match_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Match_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Match_")+region, elec_pT); _histos.Fill1D(string("Fake_Met_Match_")+region, met); } // spatial only if(emobjs[0]->has_good_spatial_track_match()) { _histos.Fill1D("Fake_Electron_DetEta_Spatial_Match", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Spatial_Match", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Spatial_Match", elec_pT); _histos.Fill1D("Fake_Met_Spatial_Match", met); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Spatial_Match_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Spatial_Match_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Spatial_Match_")+region, elec_pT); _histos.Fill1D(string("Fake_Met_Spatial_Match_")+region, met); if(met< 15. && cal_region==0){ _histos.Fill1D(string("Fake_Electron_DetEta_CCVtxBin_Spatial_Match_")+bins_Vtx, emobjs[0]->CalDetectorEta()); } } // spatial only+SMT,CFT if(emobjs[0]->has_spatial_track_match(-0.5)) { // check chi2 vs met _histos.Fill2D("Fake_Electron_Chi2_V_Met_Spatial_Match", met, emobjs[0]->track_match_spatialchi2prob()); _histos.Fill2D(string("Fake_Electron_Chi2_V_Met_Spatial_Match_")+region, met, emobjs[0]->track_match_spatialchi2prob()); _histos.Fill1D("Fake_Electron_Chi2", emobjs[0]->track_match_spatialchi2prob()); _histos.Fill1D(string("Fake_Electron_Chi2_")+region, emobjs[0]->track_match_spatialchi2prob()); double ElecPt = emobjs[0]->Pt(); double TrkPt = emobjs[0]->getPtrSpatialChp()->Pt(); double EOverP = 0.; if(TrkPt>0.) EOverP = ElecPt/TrkPt; if(emobjs[0]->getPtrSpatialChp()->nsmt()>=1 && emobjs[0]->getPtrSpatialChp()->ncft()>=4) { // check chi2 vs met _histos.Fill2D("Fake_Electron_Chi2_V_Met_Spatial_Match_Tight", met, emobjs[0]->track_match_spatialchi2prob()); _histos.Fill2D(string("Fake_Electron_Chi2_V_Met_Spatial_Match_Tight_")+region, met, emobjs[0]->track_match_spatialchi2prob()); _histos.Fill1D("Fake_Electron_Chi2_Tight", emobjs[0]->track_match_spatialchi2prob()); _histos.Fill1D(string("Fake_Electron_Chi2_Tight_")+region, emobjs[0]->track_match_spatialchi2prob()); _histos.Fill1D("Fake_Electron_DetEta_Spatial_Match_Tight", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Spatial_Match_Tight", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Spatial_Match_Tight", elec_pT); _histos.Fill1D("Fake_Met_Spatial_Match_Tight", met); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Spatial_Match_Tight_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Spatial_Match_Tight_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Spatial_Match_Tight_")+region, elec_pT); _histos.Fill1D(string("Fake_Met_Spatial_Match_Tight_")+region, met); } } //####################################################### // same histograms for met<_MetCut_FakeRate //####################################################### if( met < _MetCut_FakeRate ) { _histos.Fill1D("Fake_Electron_DetEta_MetCut", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_MetCut", elec_eta); _histos.Fill1D("Fake_Electron_Pt_MetCut", elec_pT); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_MetCut_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_MetCut_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_MetCut_")+region, elec_pT); // spatial+E/P if(emobjs[0]->has_track_match()) { _histos.Fill1D("Fake_Electron_DetEta_Match_MetCut", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Match_MetCut", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Match_MetCut", elec_pT); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Match_MetCut_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Match_MetCut_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Match_MetCut_")+region, elec_pT); } // good spatial only if(emobjs[0]->has_good_spatial_track_match()) { _histos.Fill1D("Fake_Electron_DetEta_Spatial_Match_MetCut", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Spatial_Match_MetCut", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Spatial_Match_MetCut", elec_pT); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Spatial_Match_MetCut_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Spatial_Match_MetCut_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Spatial_Match_MetCut_")+region, elec_pT); } // spatial only+SMT,CFT+E/p if(emobjs[0]->has_spatial_track_match(-0.5)) { double ElecPt = emobjs[0]->Pt(); double TrkPt = emobjs[0]->getPtrSpatialChp()->Pt(); double EOverP = 0.; if(TrkPt>0.) EOverP = ElecPt/TrkPt; if(emobjs[0]->getPtrSpatialChp()->nsmt()>=1 && emobjs[0]->getPtrSpatialChp()->ncft()>=4) { _histos.Fill1D("Fake_Electron_DetEta_Spatial_Match_Tight_MetCut", elec_deteta); _histos.Fill1D("Fake_Electron_Eta_Spatial_Match_Tight_MetCut", elec_eta); _histos.Fill1D("Fake_Electron_Pt_Spatial_Match_Tight_MetCut", elec_pT); // fill distributions for CC or EC region _histos.Fill1D(string("Fake_Electron_DetEta_Spatial_Match_Tight_MetCut_")+region, elec_deteta); _histos.Fill1D(string("Fake_Electron_Eta_Spatial_Match_Tight_MetCut_")+region, elec_eta); _histos.Fill1D(string("Fake_Electron_Pt_Spatial_Match_Tight_MetCut_")+region, elec_pT); } } } // missing Et cut } // EM and Jet are back-to-back } } // loop over jets }//if(EM_Track_backtoback==false) i.e. this is not zee event }// exactly one good EM object and pass trigger }//lumi cut }// if event.get loop cout<<" end of process event" <<endl; return true; }