NonMCBackground/src/SelectionEMU.cc

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

#include "HZZBDTElectronSelection.h"
#include "IsolationSelection.h"
#include "PassHLT.h"
#include "SelectionEMU.h"

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


// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
EventData apply_EMU_selection(ControlFlags &ctrl,           // input control 
                              mithep::TEventInfo *info,     // input event info
                              TClonesArray *electronArr,    // input electrons
                              SelectionStatus (*ElectronPreSelector)( ControlFlags &, const mithep::TElectron*),
                              SelectionStatus (*ElectronIDSelector)( ControlFlags &, const mithep::TElectron*),
                              SelectionStatus (*ElectronIsoSelector)( ControlFlags &, const mithep::TElectron*),
                              TClonesArray *muonArr,         // input muons
                              SelectionStatus (*MuonPreSelector)( ControlFlags &, const mithep::TMuon*),
                              SelectionStatus (*MuonIDSelector)( ControlFlags &, const mithep::TMuon*),
                              SelectionStatus (*MuonIsoSelector)( ControlFlags &, const mithep::TMuon*) )
// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
{       

  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;
    }
  }
  
  
  //********************************************************
  // Trigger
  //********************************************************
//   if( !ctrl.mc ) { 
//     if( !(passHLTSingleMuon(info->triggerBits) )  ) { 
//       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;
  if( muonArr->GetEntries() != 1 && electronArr->GetEntries() != 1 ) { 
    ret.status.setStatus(0);
    return ret;
  }

  //    
  if( ctrl.debug ) cout << "\tnMuons: " << muonArr->GetEntries() << endl;
  //----------------------------------------------------
  for(Int_t i=0; i<muonArr->GetEntries(); i++) 
    {
      const mithep::TMuon *mu = (mithep::TMuon*)((*muonArr)[i]);      
      
      SelectionStatus musel;
      if(ctrl.debug) cout << "musel.status  before anything: " << musel.getStatus() << endl;
      musel |= (*MuonPreSelector)(ctrl,mu);
      if(ctrl.debug) cout << "musel.status  after presel: " << musel.getStatus() << endl;
      musel |= (*MuonIDSelector)(ctrl,mu);
      if(ctrl.debug) cout << "musel.status  after ID: " << musel.getStatus() << endl;
      musel |= (*MuonIsoSelector)(ctrl,mu);
      if(ctrl.debug) cout << "musel.status  after iso: " << musel.getStatus() << endl;

      if( ctrl.debug ) { 
        cout << "muon:: pt: " << mu->pt 
             << "\teta: " << mu->eta 
             << "\tisorel: " <<  mu->pfIso03/mu->pt
             << "\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->q;
        tmplep.isoTrk  = mu->trkIso03;
        tmplep.isoEcal = mu->emIso03;
        tmplep.isoHcal = mu->hadIso03;
        tmplep.isoPF03 = mu->pfIso03;
        tmplep.isoPF04 = mu->pfIso04;
        tmplep.ip3dSig = mu->ip3dSig;
        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::TElectron *ele = (mithep::TElectron*)((*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 ( abs(lepvec[k].type == 13) && lepvec[k].vec->Vect().DrEtaPhi(tmplep) < 0.15 ) {
            if( ctrl.debug ) cout << "-----> isMuonOverlap! " << endl;
            isMuonOverlap = kTRUE; 
            break;
          }
        }
        
        SelectionStatus elesel;
        elesel |= (*ElectronPreSelector)(ctrl,ele);
        elesel |= (*ElectronIDSelector)(ctrl,ele);
        elesel |= (*ElectronIsoSelector)(ctrl,ele);
        if( elesel.getStatus() & SelectionStatus::PRESELECTION ) 
          elesel.setStatus(SelectionStatus::LOOSESELECTION);

        if( ctrl.debug ){ 
          cout << "\tscEt: " << ele->scEt 
               << "\tscEta: " << ele->scEta
               << "\tncluster: " << ele->ncluster
               << "\tisorel: " <<  ele->pfIso04/ele->pt
               << "\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->q;
            tmplep.isoTrk  = ele->trkIso03;
            tmplep.isoEcal = ele->emIso03;
            tmplep.isoHcal = ele->hadIso03;
            tmplep.isoPF03 = ele->pfIso03;
            tmplep.isoPF04 = ele->pfIso04;
            tmplep.ip3dSig = ele->ip3dSig;
            tmplep.is4l    = false;
            tmplep.isEB    = ele->isEB;
            tmplep.scID    = ele->scID;
            tmplep.isTight = elesel.tight();
            tmplep.isLoose = elesel.pass();
            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;
    }
    
    
    //******************************************************************************
    // Selection
    //******************************************************************************
    float bestMass=-1; int best_mu_index=-1, best_ele_index=-1;
    for(int i = 0; i<lepvec.size(); i++) {      // get a tight muon
      if( abs(lepvec[i].type) != 13 ) continue; 
      if( !(lepvec[i].isTight) ) continue; 
      //      if( lepvec[i].vec->Pt() < 35 ) continue; 
      if( ctrl.debug ) cout << "got a muon, index: " << i << endl;

      for(int j = 0; j<lepvec.size(); j++) {     // get a loose electron
        if( j == i ) continue; 
        if( abs(lepvec[j].type) != 11 ) continue; 
        if( !(lepvec[j].isLoose) ) continue; 
        if (lepvec[i].charge == lepvec[j].charge) continue;          
        //      if (lepvec[i].charge != lepvec[j].charge) continue;          
        if( ctrl.debug ) cout << "got a electron, index: " << j << endl;

        float tmpMass = ( *(lepvec[i].vec) + *(lepvec[j].vec) ).M();
        if( ctrl.debug ) cout << "tmp vs best :: " << tmpMass << "," << bestMass << endl;
        if( tmpMass > bestMass ) { 
          bestMass = tmpMass;
          best_mu_index=i;
          best_ele_index=j;
        }

      }
    }

    if( bestMass > 0 ) { 
      if( ctrl.debug ) cout << "EMU candidate, mass : " << bestMass << endl;
      if( lepvec[best_ele_index].isTight ) 
        ret.status.setStatus(SelectionStatus::TIGHTSELECTION);
      else
        ret.status.setStatus(SelectionStatus::LOOSESELECTION);
      ret.Z1leptons.push_back(lepvec[best_mu_index]);
      ret.Z1leptons.push_back(lepvec[best_ele_index]);
      ret.Z2leptons.push_back(lepvec[best_mu_index]);
      ret.Z2leptons.push_back(lepvec[best_ele_index]);
      return ret;
    }

    ret.status.setStatus(0);
    return ret;

}


Revision:	1.2
Committed:	Tue Feb 14 21:29:18 2012 UTC (13 years, 3 months ago) by khahn
Content type:	text/plain
Branch:	MAIN
Changes since 1.1:	+10 -11 lines
Log Message:	various fixes
#	Content
1	#include "SelectionStatus.h"
2	#include "EventData.h"
3	#include "SimpleLepton.h"
4	#include "EfficiencyWeightsInterface.h"
5
6	#include "HZZBDTElectronSelection.h"
7	#include "IsolationSelection.h"
8	#include "PassHLT.h"
9	#include "SelectionEMU.h"
10
11	#include "ExternData.h"
12	#include "SelectionDefs.h"
13
14
15
16	// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
17	// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
18	EventData apply_EMU_selection(ControlFlags &ctrl, // input control
19	mithep::TEventInfo *info, // input event info
20	TClonesArray *electronArr, // input electrons
21	SelectionStatus (ElectronPreSelector)( ControlFlags &, const mithep::TElectron),
22	SelectionStatus (ElectronIDSelector)( ControlFlags &, const mithep::TElectron),
23	SelectionStatus (ElectronIsoSelector)( ControlFlags &, const mithep::TElectron),
24	TClonesArray *muonArr, // input muons
25	SelectionStatus (MuonPreSelector)( ControlFlags &, const mithep::TMuon),
26	SelectionStatus (MuonIDSelector)( ControlFlags &, const mithep::TMuon),
27	SelectionStatus (MuonIsoSelector)( ControlFlags &, const mithep::TMuon) )
28	// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
29	// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
30	{
31
32	EventData ret;
33	unsigned evtfail = 0x0;
34	TRandom3 r;
35
36	if( ctrl.debug ) {
37	cout << "Run: " << info->runNum
38	<< "\tEvt: " << info->evtNum
39	<< "\tLumi: " << info->lumiSec
40	<< endl;
41	}
42
43	if( !ctrl.mc ) {
44	// not accounting for overlap atm
45	RunLumiRangeMap::RunLumiPairType rl(info->runNum, info->lumiSec);
46	if( !(rlrm.HasRunLumi(rl)) ) {
47	if( ctrl.debug ) cout << "\tfails JSON" << endl;
48	ret.status.setStatus(0);
49	return ret;
50	}
51	}
52
53
54	//********************************************************
55	// Trigger
56	//********************************************************
57	// if( !ctrl.mc ) {
58	// if( !(passHLTSingleMuon(info->triggerBits) ) ) {
59	// if( ctrl.debug ) cout << "\tfails trigger" << endl;
60	// evtfail \|= (1<<EVTFAIL_TRIGGER);
61	// ret.status.setStatus(0);
62	// return ret;
63	// }
64	// }
65	if( ctrl.debug ) {
66	cout << "presel nlep: " << muonArr->GetEntries() + electronArr->GetEntries()
67	<< "\tnmuon: " << muonArr->GetEntries()
68	<< "\tnelectron: " << electronArr->GetEntries()
69	<< endl;
70	}
71
72	//********************************************************
73	// Lepton Selection
74	//********************************************************
75	vector<SimpleLepton> lepvec;
76	if( muonArr->GetEntries() != 1 && electronArr->GetEntries() != 1 ) {
77	ret.status.setStatus(0);
78	return ret;
79	}
80
81	//
82	if( ctrl.debug ) cout << "\tnMuons: " << muonArr->GetEntries() << endl;
83	//----------------------------------------------------
84	for(Int_t i=0; i<muonArr->GetEntries(); i++)
85	{
86	const mithep::TMuon mu = (mithep::TMuon)((*muonArr)[i]);
87
88	SelectionStatus musel;
89	if(ctrl.debug) cout << "musel.status before anything: " << musel.getStatus() << endl;
90	musel \|= (*MuonPreSelector)(ctrl,mu);
91	if(ctrl.debug) cout << "musel.status after presel: " << musel.getStatus() << endl;
92	musel \|= (*MuonIDSelector)(ctrl,mu);
93	if(ctrl.debug) cout << "musel.status after ID: " << musel.getStatus() << endl;
94	musel \|= (*MuonIsoSelector)(ctrl,mu);
95	if(ctrl.debug) cout << "musel.status after iso: " << musel.getStatus() << endl;
96
97	if( ctrl.debug ) {
98	cout << "muon:: pt: " << mu->pt
99	<< "\teta: " << mu->eta
100	<< "\tisorel: " << mu->pfIso03/mu->pt
101	<< "\tstatus: " << hex << musel.getStatus() << dec
102	<< endl;
103	}
104
105	if ( musel.pass() ) {
106
107	SimpleLepton tmplep;
108	float pt = mu->pt;
109	tmplep.vecorig->SetPtEtaPhiM(pt,
110	mu->eta,
111	mu->phi,
112	MUON_MASS);
113
114	if( ctrl.do_escale_up ) {
115	pt=scale_smear_muon_Up(pt, 1, r);
116	}
117	if( ctrl.do_escale_down ) {
118	pt=scale_smear_muon_Down(pt, 1, r);
119	}
120
121	tmplep.vec->SetPtEtaPhiM(pt,
122	mu->eta,
123	mu->phi,
124	MUON_MASS);
125
126	tmplep.type = 13;
127	tmplep.index = i;
128	tmplep.charge = mu->q;
129	tmplep.isoTrk = mu->trkIso03;
130	tmplep.isoEcal = mu->emIso03;
131	tmplep.isoHcal = mu->hadIso03;
132	tmplep.isoPF03 = mu->pfIso03;
133	tmplep.isoPF04 = mu->pfIso04;
134	tmplep.ip3dSig = mu->ip3dSig;
135	tmplep.is4l = false;
136	tmplep.isEB = (fabs(mu->eta) < 1.479 ? 1 : 0 );
137	tmplep.isTight = musel.tight();
138	tmplep.isLoose = musel.loose();
139	lepvec.push_back(tmplep);
140	if( ctrl.debug ) { cout << "muon passes ... " << endl;}
141	}
142	// }
143	}
144
145
146
147	//
148	if( ctrl.debug ) { cout << "\tnElectron: " << electronArr->GetEntries() << endl; }
149	// --------------------------------------------------------------------------------
150	for(Int_t i=0; i<electronArr->GetEntries(); i++)
151	{
152	const mithep::TElectron ele = (mithep::TElectron)((*electronArr)[i]);
153
154	Bool_t isMuonOverlap = kFALSE;
155	for (int k=0; k<lepvec.size(); ++k) {
156	TVector3 tmplep;
157	tmplep.SetPtEtaPhi(ele->pt, ele->eta, ele->phi);
158	if ( abs(lepvec[k].type == 13) && lepvec[k].vec->Vect().DrEtaPhi(tmplep) < 0.15 ) {
159	if( ctrl.debug ) cout << "-----> isMuonOverlap! " << endl;
160	isMuonOverlap = kTRUE;
161	break;
162	}
163	}
164
165	SelectionStatus elesel;
166	elesel \|= (*ElectronPreSelector)(ctrl,ele);
167	elesel \|= (*ElectronIDSelector)(ctrl,ele);
168	elesel \|= (*ElectronIsoSelector)(ctrl,ele);
169	if( elesel.getStatus() & SelectionStatus::PRESELECTION )
170	elesel.setStatus(SelectionStatus::LOOSESELECTION);
171
172	if( ctrl.debug ){
173	cout << "\tscEt: " << ele->scEt
174	<< "\tscEta: " << ele->scEta
175	<< "\tncluster: " << ele->ncluster
176	<< "\tisorel: " << ele->pfIso04/ele->pt
177	<< "\tstatus: " << hex << elesel.getStatus() << dec
178	<< endl;
179	}
180
181	if ( elesel.pass() && !isMuonOverlap )
182	{
183	SimpleLepton tmplep;
184
185	float pt = ele->pt;
186	tmplep.vecorig->SetPtEtaPhiM( pt,
187	ele->eta,
188	ele->phi,
189	ELECTRON_MASS );
190
191	if( ctrl.do_escale ) {
192	pt=scale_smear_electron(pt, ele->isEB, r);
193	}
194	if( ctrl.do_escale_up ) {
195	pt=scale_smear_electron_Up(pt, ele->isEB, r);
196	}
197	if( ctrl.do_escale_down ) {
198	pt=scale_smear_electron_Down(pt, ele->isEB, r);
199	}
200
201
202	tmplep.vec->SetPtEtaPhiM( pt,
203	ele->eta,
204	ele->phi,
205	ELECTRON_MASS );
206
207	tmplep.type = 11;
208	tmplep.index = i;
209	tmplep.charge = ele->q;
210	tmplep.isoTrk = ele->trkIso03;
211	tmplep.isoEcal = ele->emIso03;
212	tmplep.isoHcal = ele->hadIso03;
213	tmplep.isoPF03 = ele->pfIso03;
214	tmplep.isoPF04 = ele->pfIso04;
215	tmplep.ip3dSig = ele->ip3dSig;
216	tmplep.is4l = false;
217	tmplep.isEB = ele->isEB;
218	tmplep.scID = ele->scID;
219	tmplep.isTight = elesel.tight();
220	tmplep.isLoose = elesel.pass();
221	lepvec.push_back(tmplep);
222	if( ctrl.debug ) { cout << "\telectron passes ... " << endl; }
223	}
224	}
225
226
227	//********************************************************
228	// Dump Stuff
229	//********************************************************
230	sort( lepvec.begin(), lepvec.end(), SimpleLepton::lep_pt_sort );
231	int nmu=0, nele=0;
232	for( int i=0; i<lepvec.size(); i++ ) {
233	if(ctrl.debug) cout << "lepvec :: index: " << i
234	<< "\tpt: " << lepvec[i].vec->Pt()
235	<< "\ttype: " << lepvec[i].type
236	<< endl;
237	if( abs(lepvec[i].type) == 11 ) nele++;
238	else nmu++;
239	}
240	if( ctrl.debug ) {
241	cout << "postsel nlep: " << lepvec.size()
242	<< "\tnmuon: " << nmu
243	<< "\tnelectron: " << nele
244	<< endl;
245	}
246
247
248	//******************************************************************************
249	// Selection
250	//******************************************************************************
251	float bestMass=-1; int best_mu_index=-1, best_ele_index=-1;
252	for(int i = 0; i<lepvec.size(); i++) { // get a tight muon
253	if( abs(lepvec[i].type) != 13 ) continue;
254	if( !(lepvec[i].isTight) ) continue;
255	// if( lepvec[i].vec->Pt() < 35 ) continue;
256	if( ctrl.debug ) cout << "got a muon, index: " << i << endl;
257
258	for(int j = 0; j<lepvec.size(); j++) { // get a loose electron
259	if( j == i ) continue;
260	if( abs(lepvec[j].type) != 11 ) continue;
261	if( !(lepvec[j].isLoose) ) continue;
262	if (lepvec[i].charge == lepvec[j].charge) continue;
263	// if (lepvec[i].charge != lepvec[j].charge) continue;
264	if( ctrl.debug ) cout << "got a electron, index: " << j << endl;
265
266	float tmpMass = ( (lepvec[i].vec) + (lepvec[j].vec) ).M();
267	if( ctrl.debug ) cout << "tmp vs best :: " << tmpMass << "," << bestMass << endl;
268	if( tmpMass > bestMass ) {
269	bestMass = tmpMass;
270	best_mu_index=i;
271	best_ele_index=j;
272	}
273
274	}
275	}
276
277	if( bestMass > 0 ) {
278	if( ctrl.debug ) cout << "EMU candidate, mass : " << bestMass << endl;
279	if( lepvec[best_ele_index].isTight )
280	ret.status.setStatus(SelectionStatus::TIGHTSELECTION);
281	else
282	ret.status.setStatus(SelectionStatus::LOOSESELECTION);
283	ret.Z1leptons.push_back(lepvec[best_mu_index]);
284	ret.Z1leptons.push_back(lepvec[best_ele_index]);
285	ret.Z2leptons.push_back(lepvec[best_mu_index]);
286	ret.Z2leptons.push_back(lepvec[best_ele_index]);
287	return ret;
288	}
289
290	ret.status.setStatus(0);
291	return ret;
292
293	}
294
295