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Comparing UserCode/MitHzz4l/LeptonSelection/src/IsolationSelection.cc (file contents):
Revision 1.2 by khahn, Fri Feb 17 14:49:00 2012 UTC vs.
Revision 1.23 by khahn, Wed May 23 14:50:06 2012 UTC

#	Line 3 | Line 3
3		#include "IsolationSelection.h"
4		#include "IsolationSelectionDefs.h"
5
6	<	bool pairwiseIsoSelection( ControlFlags &ctrl, vector<SimpleLepton> &lepvec, float rho ) {
6	>	#include "MathUtils.h"
7	>	#include "MuonTools.h"
8	>	#include "MuonIDMVA.h"
9	>	#include "ElectronTools.h"
10	>	#include "ElectronIDMVA.h"
11	>
12	>	using namespace mithep;
13	>
14	>	mithep::MuonIDMVA     * muIsoMVA;
15	>	mithep::MuonTools       muT;
16	>	mithep::ElectronIDMVA * eleIsoMVA;
17	>	mithep::ElectronTools   eleT;
18	>
19	>	// global hack to sync
20	>	double gChargedIso;
21	>	double gGammaIso;
22	>	double gNeutralIso;
23	>
24	>	extern vector<bool> PFnoPUflag;
25	>
26	>	//--------------------------------------------------------------------------------------------------
27	>	Float_t computePFMuonIso(const mithep::Muon *muon,
28	>	const mithep::Vertex * vtx,
29	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
30	>	const Double_t dRMax)
31	>	//--------------------------------------------------------------------------------------------------
32	>	{
33	>	const Double_t dRMin    = 0;
34	>	const Double_t neuPtMin = 1.0;
35	>	const Double_t dzMax    = 0.1;
36	>
37	>	Double_t zLepton = (muon->BestTrk()) ? muon->BestTrk()->DzCorrected(*vtx) : 0.0;
38	>
39	>	Float_t iso=0;
40	>	for(UInt_t ipf=0; ipf<fPFCandidates->GetEntries(); ipf++) {
41	>	const PFCandidate *pfcand = fPFCandidates->At(ipf);
42	>
43	>	if(!pfcand->HasTrk() && (pfcand->Pt()<=neuPtMin)) continue;  // pT cut on neutral particles
44	>
45	>	// exclude THE muon
46	>	if(pfcand->TrackerTrk() && muon->TrackerTrk() && (pfcand->TrackerTrk()==muon->TrackerTrk())) continue;
47	>
48	>	// dz cut
49	>	Double_t dz = (pfcand->BestTrk()) ? fabs(pfcand->BestTrk()->DzCorrected(*vtx) - zLepton) : 0;
50	>	if(dz >= dzMax) continue;
51	>
52	>	// check iso cone
53	>	Double_t dr = MathUtils::DeltaR(muon->Mom(), pfcand->Mom());
54	>	if(dr<dRMax && dr>=dRMin)
55	>	iso += pfcand->Pt();
56	>	}
57	>
58	>	return iso;
59	>	}
60	>
61	>	//--------------------------------------------------------------------------------------------------
62	>	Float_t computePFEleIso(const mithep::Electron *electron,
63	>	const mithep::Vertex * fVertex,
64	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
65	>	const Double_t dRMax)
66	>	//--------------------------------------------------------------------------------------------------
67	>	{
68	>	const Double_t dRMin    = 0;
69	>	const Double_t neuPtMin = 1.0;
70	>	const Double_t dzMax    = 0.1;
71	>
72	>	Double_t zLepton = (electron->BestTrk()) ? electron->BestTrk()->DzCorrected(*fVertex) : 0.0;
73	>
74	>	Float_t iso=0;
75	>	for(UInt_t ipf=0; ipf<fPFCandidates->GetEntries(); ipf++) {
76	>	const PFCandidate *pfcand = (PFCandidate*)(fPFCandidates->At(ipf));
77	>
78	>	if(!pfcand->HasTrk() && (pfcand->Pt()<=neuPtMin)) continue;  // pT cut on neutral particles
79	>
80	>	// dz cut
81	>	Double_t dz = (pfcand->BestTrk()) ? fabs(pfcand->BestTrk()->DzCorrected(*fVertex) - zLepton) : 0;
82	>	if(dz >= dzMax) continue;
83	>
84	>	// remove THE electron
85	>	if(pfcand->TrackerTrk() && electron->TrackerTrk() && (pfcand->TrackerTrk()==electron->TrackerTrk())) continue;
86	>	if(pfcand->GsfTrk()     && electron->GsfTrk()     && (pfcand->GsfTrk()==electron->GsfTrk()))         continue;
87	>
88	>	// check iso cone
89	>	Double_t dr = MathUtils::DeltaR(electron->Mom(), pfcand->Mom());
90	>	if(dr<dRMax && dr>=dRMin) {
91	>	// eta-strip veto for photons
92	>	if((pfcand->PFType() == PFCandidate::eGamma) && fabs(electron->Eta() - pfcand->Eta()) < 0.025) continue;
93	>
94	>	// Inner cone (one tower = dR < 0.07) veto for non-photon neutrals
95	>	if(!pfcand->HasTrk() && (pfcand->PFType() == PFCandidate::eNeutralHadron) &&
96	>	(MathUtils::DeltaR(electron->Mom(), pfcand->Mom()) < 0.07)) continue;
97	>
98	>	iso += pfcand->Pt();
99	>	}
100	>	}
101	>
102	>	return iso;
103	>	};
104	>
105	>	//--------------------------------------------------------------------------------------------------
106	>	bool pairwiseIsoSelection( ControlFlags &ctrl,
107	>	vector<SimpleLepton> &lepvec,
108	>	float rho )
109	>	//--------------------------------------------------------------------------------------------------
110	>	{
111
112		bool passiso=true;
113
#	Line 60 | Line 164 | bool pairwiseIsoSelection( ControlFlags
164
165		float isoEcal_corr_j = lepvec[j].isoEcal - (effArea_ecal_j*rho);
166		float isoHcal_corr_j = lepvec[j].isoHcal - (effArea_hcal_j*rho);
167	<	float RIso_i = (lepvec[i].isoTrk+isoEcal_corr_i+isoHcal_corr_i)/lepvec[i].vec->Pt();
168	<	float RIso_j = (lepvec[j].isoTrk+isoEcal_corr_j+isoHcal_corr_j)/lepvec[j].vec->Pt();
167	>	float RIso_i = (lepvec[i].isoTrk+isoEcal_corr_i+isoHcal_corr_i)/lepvec[i].vec.Pt();
168	>	float RIso_j = (lepvec[j].isoTrk+isoEcal_corr_j+isoHcal_corr_j)/lepvec[j].vec.Pt();
169		float comboIso = RIso_i + RIso_j;
170
171		if( comboIso > 0.35 ) {
#	Line 75 | Line 179 | bool pairwiseIsoSelection( ControlFlags
179		return passiso;
180		}
181
182	<
183	<	SelectionStatus passMuonIsoSelection( ControlFlags &ctrl, const mithep::TMuon * mu ) {
184	<
185	<	float reliso = mu->pfIso03/mu->pt;
186	<	bool isEB = (fabs(mu->eta) < 1.479 ? 1 : 0 );
182	>	//--------------------------------------------------------------------------------------------------
183	>	SelectionStatus muonIsoSelection(ControlFlags &ctrl,
184	>	const mithep::Muon * mu,
185	>	const mithep::Vertex * vtx,
186	>	const mithep::Array<mithep::PFCandidate> * fPFCandidateCol   )
187	>	//--------------------------------------------------------------------------------------------------
188	>	{
189	>	float reliso = computePFMuonIso(mu,vtx,fPFCandidateCol,0.3)/mu->Pt();
190	>	bool isEB = (fabs(mu->Eta()) < 1.479 ? 1 : 0 );
191		bool failiso = false;
192	<	if( isEB && mu->pt > 20 && reliso > PFISO_MU_LOOSE_EB_HIGHPT ) {
192	>	if( isEB && mu->Pt() > 20 && reliso > PFISO_MU_LOOSE_EB_HIGHPT ) {
193		failiso = true;
194		}
195	<	if( isEB && mu->pt < 20 && reliso > PFISO_MU_LOOSE_EB_LOWPT ) {
195	>	if( isEB && mu->Pt() < 20 && reliso > PFISO_MU_LOOSE_EB_LOWPT ) {
196		failiso = true;
197		}
198	<	if( !(isEB) && mu->pt > 20 && reliso > PFISO_MU_LOOSE_EE_HIGHPT ) {
198	>	if( !(isEB) && mu->Pt() > 20 && reliso > PFISO_MU_LOOSE_EE_HIGHPT ) {
199		failiso = true;
200		}
201	<	if( !(isEB) && mu->pt < 20 && reliso > PFISO_MU_LOOSE_EE_LOWPT ) {
201	>	if( !(isEB) && mu->Pt() < 20 && reliso > PFISO_MU_LOOSE_EE_LOWPT ) {
202		failiso = true;
203		}
204
#	Line 101 | Line 209 | SelectionStatus passMuonIsoSelection( Co
209
210		};
211
212	<
213	<	SelectionStatus failEleIso(ControlFlags &ctrl, const mithep::TElectron * ele) {
212	>	//--------------------------------------------------------------------------------------------------
213	>	SelectionStatus electronIsoSelection(ControlFlags &ctrl,
214	>	const mithep::Electron * ele,
215	>	const mithep::Vertex *fVertex,
216	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates)
217	>	//--------------------------------------------------------------------------------------------------
218	>	{
219
220		bool failiso=false;
221
222	<	float reliso = ele->pfIso04/ele->pt;
223	<	bool isEB = (fabs(ele->eta) < 1.479 ? 1 : 0 );
224	<	if( isEB && ele->pt > 20 && reliso > PFISO_ELE_LOOSE_EB_HIGHPT ) {
222	>	float reliso = computePFEleIso(ele,fVertex,fPFCandidates,0.4)/ele->Pt();
223	>
224	>	if( ele->IsEB() && ele->Pt() > 20 && reliso > PFISO_ELE_LOOSE_EB_HIGHPT ) {
225		failiso = true;
226		}
227	<	if( isEB && ele->pt < 20 && reliso > PFISO_ELE_LOOSE_EB_LOWPT ) {
227	>	if( ele->IsEB() && ele->Pt() < 20 && reliso > PFISO_ELE_LOOSE_EB_LOWPT ) {
228		failiso = true;
229		}
230	<	if(ctrl.debug) cout << "before iso check ..." << endl;
118	<	if( !(isEB) && ele->pt > 20 && reliso > PFISO_ELE_LOOSE_EE_HIGHPT ) {
119	<	if(ctrl.debug) cout << "\tit fails ..." << endl;
230	>	if( !(ele->IsEB()) && ele->Pt() > 20 && reliso > PFISO_ELE_LOOSE_EE_HIGHPT ) {
231		failiso = true;
232		}
233	<	if( !(isEB) && ele->pt < 20 && reliso > PFISO_ELE_LOOSE_EE_LOWPT ) {
233	>	if( !(ele->IsEB()) && ele->Pt() < 20 && reliso > PFISO_ELE_LOOSE_EE_LOWPT ) {
234		failiso = true;
235		}
236
237		SelectionStatus status;
238		if( !failiso ) {
239	<	status.setStatus(SelectionStatus::LOOSEISO);
240	<	status.setStatus(SelectionStatus::TIGHTISO);
239	>	status.orStatus(SelectionStatus::LOOSEISO);
240	>	status.orStatus(SelectionStatus::TIGHTISO);
241	>	}
242	>	if(ctrl.debug) cout << "returning status : " << hex << status.getStatus() << dec << endl;
243	>	return status;
244	>
245	>	}
246	>
247	>
248	>	bool noIso(ControlFlags &, vector<SimpleLepton> &, float rho) {
249	>
250	>	return true;
251	>	}
252	>
253	>
254	>	//--------------------------------------------------------------------------------------------------
255	>	SelectionStatus muonIsoMVASelection(ControlFlags &ctrl,
256	>	const mithep::Muon * mu,
257	>	const mithep::Vertex * vtx,
258	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
259	>	const mithep::Array<mithep::PileupEnergyDensity> * fPUEnergyDensity,
260	>	mithep::MuonTools::EMuonEffectiveAreaTarget EffectiveAreaVersion,
261	>	vector<const mithep::Muon*> muonsToVeto,
262	>	vector<const mithep::Electron*> electronsToVeto)
263	>	//--------------------------------------------------------------------------------------------------
264	>	{
265	>
266	>	if( ctrl.debug ) {
267	>	cout << "muonIsoMVASelection :: muons to veto " << endl;
268	>	for( int i=0; i<muonsToVeto.size(); i++ ) {
269	>	const mithep::Muon * vmu = muonsToVeto[i];
270	>	cout << "\tpt: " << vmu->Pt()
271	>	<< "\teta: " << vmu->Eta()
272	>	<< "\tphi: " << vmu->Phi()
273	>	<< endl;
274	>	}
275	>	cout << "muonIsoMVASelection :: electrson to veto " << endl;
276	>	for( int i=0; i<electronsToVeto.size(); i++ ) {
277	>	const mithep::Electron * vel = electronsToVeto[i];
278	>	cout << "\tpt: " << vel->Pt()
279	>	<< "\teta: " << vel->Eta()
280	>	<< "\tphi: " << vel->Phi()
281	>	<< endl;
282	>	}
283	>	}
284	>	bool failiso=false;
285	>
286	>	//
287	>	// tmp iso rings
288	>	//
289	>	Double_t tmpChargedIso_DR0p0To0p1  = 0;
290	>	Double_t tmpChargedIso_DR0p1To0p2  = 0;
291	>	Double_t tmpChargedIso_DR0p2To0p3  = 0;
292	>	Double_t tmpChargedIso_DR0p3To0p4  = 0;
293	>	Double_t tmpChargedIso_DR0p4To0p5  = 0;
294	>	Double_t tmpChargedIso_DR0p5To0p7  = 0;
295	>
296	>	Double_t tmpGammaIso_DR0p0To0p1  = 0;
297	>	Double_t tmpGammaIso_DR0p1To0p2  = 0;
298	>	Double_t tmpGammaIso_DR0p2To0p3  = 0;
299	>	Double_t tmpGammaIso_DR0p3To0p4  = 0;
300	>	Double_t tmpGammaIso_DR0p4To0p5  = 0;
301	>	Double_t tmpGammaIso_DR0p5To0p7  = 0;
302	>
303	>	Double_t tmpNeutralHadronIso_DR0p0To0p1  = 0;
304	>	Double_t tmpNeutralHadronIso_DR0p1To0p2  = 0;
305	>	Double_t tmpNeutralHadronIso_DR0p2To0p3  = 0;
306	>	Double_t tmpNeutralHadronIso_DR0p3To0p4  = 0;
307	>	Double_t tmpNeutralHadronIso_DR0p4To0p5  = 0;
308	>	Double_t tmpNeutralHadronIso_DR0p5To0p7  = 0;
309	>
310	>
311	>
312	>	//
313	>	// final rings for the MVA
314	>	//
315	>	Double_t fChargedIso_DR0p0To0p1;
316	>	Double_t fChargedIso_DR0p1To0p2;
317	>	Double_t fChargedIso_DR0p2To0p3;
318	>	Double_t fChargedIso_DR0p3To0p4;
319	>	Double_t fChargedIso_DR0p4To0p5;
320	>	Double_t fChargedIso_DR0p5To0p7;
321	>
322	>	Double_t fGammaIso_DR0p0To0p1;
323	>	Double_t fGammaIso_DR0p1To0p2;
324	>	Double_t fGammaIso_DR0p2To0p3;
325	>	Double_t fGammaIso_DR0p3To0p4;
326	>	Double_t fGammaIso_DR0p4To0p5;
327	>	Double_t fGammaIso_DR0p5To0p7;
328	>
329	>	Double_t fNeutralHadronIso_DR0p0To0p1;
330	>	Double_t fNeutralHadronIso_DR0p1To0p2;
331	>	Double_t fNeutralHadronIso_DR0p2To0p3;
332	>	Double_t fNeutralHadronIso_DR0p3To0p4;
333	>	Double_t fNeutralHadronIso_DR0p4To0p5;
334	>	Double_t fNeutralHadronIso_DR0p5To0p7;
335	>
336	>
337	>	//
338	>	//Loop over PF Candidates
339	>	//
340	>	for(int k=0; k<fPFCandidates->GetEntries(); ++k) {
341	>
342	>	if( !(PFnoPUflag[k]) ) continue; // my PF no PU hack
343	>
344	>	const mithep::PFCandidate *pf = (mithep::PFCandidate*)((*fPFCandidates)[k]);
345	>
346	>	Double_t deta = (mu->Eta() - pf->Eta());
347	>	Double_t dphi = mithep::MathUtils::DeltaPhi(Double_t(mu->Phi()),Double_t(pf->Phi()));
348	>	Double_t dr = mithep::MathUtils::DeltaR(mu->Phi(),mu->Eta(), pf->Phi(), pf->Eta());
349	>	if (dr > 1.0) continue;
350	>
351	>	if (pf->HasTrackerTrk() && (pf->TrackerTrk() == mu->TrackerTrk()) ) continue;
352	>
353	>	//
354	>	// Lepton Footprint Removal
355	>	//
356	>	Bool_t IsLeptonFootprint = kFALSE;
357	>	if (dr < 1.0) {
358	>
359	>	//
360	>	// Check for electrons
361	>	//
362	>	for (Int_t q=0; q < electronsToVeto.size(); ++q) {
363	>	const mithep::Electron *tmpele = electronsToVeto[q];
364	>	// 4l electron
365	>	if( pf->HasTrackerTrk() ) {
366	>	if( pf->TrackerTrk() == tmpele->TrackerTrk() )
367	>	IsLeptonFootprint = kTRUE;
368	>	}
369	>	if( pf->HasGsfTrk() ) {
370	>	if( pf->GsfTrk() == tmpele->GsfTrk() )
371	>	IsLeptonFootprint = kTRUE;
372	>	}
373	>	// PF charged
374	>	if (pf->Charge() != 0 && fabs(tmpele->SCluster()->Eta()) >= 1.479
375	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.015)
376	>	IsLeptonFootprint = kTRUE;
377	>	// PF gamma
378	>	if (abs(pf->PFType()) == PFCandidate::eGamma && fabs(tmpele->SCluster()->Eta()) >= 1.479
379	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.08)
380	>	IsLeptonFootprint = kTRUE;
381	>	} // loop over electrons
382	>
383	>	/* KH - commented for sync
384	>	//
385	>	// Check for muons
386	>	//
387	>	for (Int_t q=0; q < muonsToVeto.size(); ++q) {
388	>	const mithep::Muon *tmpmu = muonsToVeto[q];
389	>	// 4l muon
390	>	if( pf->HasTrackerTrk() ) {
391	>	if( pf->TrackerTrk() == tmpmu->TrackerTrk() )
392	>	IsLeptonFootprint = kTRUE;
393	>	}
394	>	// PF charged
395	>	if (pf->Charge() != 0 && mithep::MathUtils::DeltaR(tmpmu->Phi(),tmpmu->Eta(), pf->Phi(), pf->Eta()) < 0.01)
396	>	IsLeptonFootprint = kTRUE;
397	>	} // loop over muons
398	>	*/
399	>
400	>	if (IsLeptonFootprint)
401	>	continue;
402	>
403	>	//
404	>	// Charged Iso Rings
405	>	//
406	>	if (pf->Charge() != 0 && (pf->HasTrackerTrk()||pf->HasGsfTrk()) ) {
407	>
408	>	if( dr < 0.01 ) continue; // only for muon iso mva?
409	>	if (abs(pf->PFType()) == PFCandidate::eElectron || abs(pf->PFType()) == PFCandidate::eMuon) continue;
410	>
411	>	//       if( pf->HasTrackerTrk() ) {
412	>	//      if (abs(pf->TrackerTrk()->DzCorrected(vtx)) > 0.2) continue;
413	>	//      if( ctrl.debug ) cout << "charged:: " << pf->PFType() << " " << pf->Pt() << " "
414	>	//                            << abs(pf->TrackerTrk()->DzCorrected(vtx)) << " "
415	>	//                            << dr << endl;
416	>	//       }
417	>	//       if( pf->HasGsfTrk() ) {
418	>	//      if (abs(pf->GsfTrk()->DzCorrected(vtx)) > 0.2) continue;
419	>	//      if( ctrl.debug ) cout << "charged:: " << pf->PFType() << " " << pf->Pt() << " "
420	>	//                            << abs(pf->GsfTrk()->DzCorrected(vtx)) << " "
421	>	//                            << dr << endl;
422	>	//       }
423	>
424	>	// Footprint Veto
425	>	if (dr < 0.1) tmpChargedIso_DR0p0To0p1 += pf->Pt();
426	>	if (dr >= 0.1 && dr < 0.2) tmpChargedIso_DR0p1To0p2 += pf->Pt();
427	>	if (dr >= 0.2 && dr < 0.3) tmpChargedIso_DR0p2To0p3 += pf->Pt();
428	>	if (dr >= 0.3 && dr < 0.4) tmpChargedIso_DR0p3To0p4 += pf->Pt();
429	>	if (dr >= 0.4 && dr < 0.5) tmpChargedIso_DR0p4To0p5 += pf->Pt();
430	>	if (dr >= 0.5 && dr < 0.7) tmpChargedIso_DR0p5To0p7 += pf->Pt();
431	>	}
432	>
433	>	//
434	>	// Gamma Iso Rings
435	>	//
436	>	else if (abs(pf->PFType()) == PFCandidate::eGamma) {
437	>	if (dr < 0.1) tmpGammaIso_DR0p0To0p1 += pf->Pt();
438	>	if (dr >= 0.1 && dr < 0.2) tmpGammaIso_DR0p1To0p2 += pf->Pt();
439	>	if (dr >= 0.2 && dr < 0.3) tmpGammaIso_DR0p2To0p3 += pf->Pt();
440	>	if (dr >= 0.3 && dr < 0.4) tmpGammaIso_DR0p3To0p4 += pf->Pt();
441	>	if (dr >= 0.4 && dr < 0.5) tmpGammaIso_DR0p4To0p5 += pf->Pt();
442	>	if (dr >= 0.5 && dr < 0.7) tmpGammaIso_DR0p5To0p7 += pf->Pt();
443	>	}
444	>
445	>	//
446	>	// Other Neutral Iso Rings
447	>	//
448	>	else {
449	>	if (dr < 0.1) tmpNeutralHadronIso_DR0p0To0p1 += pf->Pt();
450	>	if (dr >= 0.1 && dr < 0.2) tmpNeutralHadronIso_DR0p1To0p2 += pf->Pt();
451	>	if (dr >= 0.2 && dr < 0.3) tmpNeutralHadronIso_DR0p2To0p3 += pf->Pt();
452	>	if (dr >= 0.3 && dr < 0.4) tmpNeutralHadronIso_DR0p3To0p4 += pf->Pt();
453	>	if (dr >= 0.4 && dr < 0.5) tmpNeutralHadronIso_DR0p4To0p5 += pf->Pt();
454	>	if (dr >= 0.5 && dr < 0.7) tmpNeutralHadronIso_DR0p5To0p7 += pf->Pt();
455	>	}
456	>
457	>	}
458	>
459	>	}
460	>
461	>	fChargedIso_DR0p0To0p1   = fmin((tmpChargedIso_DR0p0To0p1)/mu->Pt(), 2.5);
462	>	fChargedIso_DR0p1To0p2   = fmin((tmpChargedIso_DR0p1To0p2)/mu->Pt(), 2.5);
463	>	fChargedIso_DR0p2To0p3   = fmin((tmpChargedIso_DR0p2To0p3)/mu->Pt(), 2.5);
464	>	fChargedIso_DR0p3To0p4   = fmin((tmpChargedIso_DR0p3To0p4)/mu->Pt(), 2.5);
465	>	fChargedIso_DR0p4To0p5   = fmin((tmpChargedIso_DR0p4To0p5)/mu->Pt(), 2.5);
466	>
467	>
468	>	double rho = 0;
469	>	if (!(isnan(fPUEnergyDensity->At(0)->Rho()) || isinf(fPUEnergyDensity->At(0)->Rho())))
470	>	rho = fPUEnergyDensity->At(0)->Rho();
471	>	//   if (!(isnan(fPUEnergyDensity->At(0)->RhoLowEta()) || isinf(fPUEnergyDensity->At(0)->RhoLowEta())))
472	>	//     rho = fPUEnergyDensity->At(0)->RhoLowEta();
473	>
474	>	// WARNING!!!!
475	>	// hardcode for sync ...
476	>	EffectiveAreaVersion = muT.kMuEAData2011;
477	>	// WARNING!!!!
478	>
479	>
480	>	fGammaIso_DR0p0To0p1 = fmax(fmin((tmpGammaIso_DR0p0To0p1
481	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaIsoDR0p0To0p1,mu->Eta(),EffectiveAreaVersion))/mu->Pt()
482	>	,2.5)
483	>	,0.0);
484	>	fGammaIso_DR0p1To0p2 = fmax(fmin((tmpGammaIso_DR0p1To0p2
485	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaIsoDR0p1To0p2,mu->Eta(),EffectiveAreaVersion))/mu->Pt()
486	>	,2.5)
487	>	,0.0);
488	>	fGammaIso_DR0p2To0p3 = fmax(fmin((tmpGammaIso_DR0p2To0p3
489	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaIsoDR0p2To0p3,mu->Eta(),EffectiveAreaVersion))/mu->Pt()
490	>	,2.5)
491	>	,0.0);
492	>	fGammaIso_DR0p3To0p4 = fmax(fmin((tmpGammaIso_DR0p3To0p4
493	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaIsoDR0p3To0p4,mu->Eta(),EffectiveAreaVersion))/mu->Pt()
494	>	,2.5)
495	>	,0.0);
496	>	fGammaIso_DR0p4To0p5 = fmax(fmin((tmpGammaIso_DR0p4To0p5
497	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaIsoDR0p4To0p5,mu->Eta(),EffectiveAreaVersion))/mu->Pt()
498	>	,2.5)
499	>	,0.0);
500	>
501	>
502	>
503	>	fNeutralHadronIso_DR0p0To0p1 = fmax(fmin((tmpNeutralHadronIso_DR0p0To0p1
504	>	-rho*muT.MuonEffectiveArea(muT.kMuNeutralHadronIsoDR0p0To0p1,
505	>	mu->Eta(),EffectiveAreaVersion))/mu->Pt()
506	>	, 2.5)
507	>	, 0.0);
508	>	fNeutralHadronIso_DR0p1To0p2 = fmax(fmin((tmpNeutralHadronIso_DR0p1To0p2
509	>	-rho*muT.MuonEffectiveArea(muT.kMuNeutralHadronIsoDR0p1To0p2,
510	>	mu->Eta(),EffectiveAreaVersion))/mu->Pt()
511	>	, 2.5)
512	>	, 0.0);
513	>	fNeutralHadronIso_DR0p2To0p3 = fmax(fmin((tmpNeutralHadronIso_DR0p2To0p3
514	>	-rho*muT.MuonEffectiveArea(muT.kMuNeutralHadronIsoDR0p2To0p3,
515	>	mu->Eta(),EffectiveAreaVersion))/mu->Pt()
516	>	, 2.5)
517	>	, 0.0);
518	>	fNeutralHadronIso_DR0p3To0p4 = fmax(fmin((tmpNeutralHadronIso_DR0p3To0p4
519	>	-rho*muT.MuonEffectiveArea(muT.kMuNeutralHadronIsoDR0p3To0p4,
520	>	mu->Eta(), EffectiveAreaVersion))/mu->Pt()
521	>	, 2.5)
522	>	, 0.0);
523	>	fNeutralHadronIso_DR0p4To0p5 = fmax(fmin((tmpNeutralHadronIso_DR0p4To0p5
524	>	-rho*muT.MuonEffectiveArea(muT.kMuNeutralHadronIsoDR0p4To0p5,
525	>	mu->Eta(), EffectiveAreaVersion))/mu->Pt()
526	>	, 2.5)
527	>	, 0.0);
528	>
529	>
530	>	double mvaval = muIsoMVA->MVAValue_IsoRings( mu->Pt(),
531	>	mu->Eta(),
532	>	mu->IsGlobalMuon(),
533	>	mu->IsTrackerMuon(),
534	>	fChargedIso_DR0p0To0p1,
535	>	fChargedIso_DR0p1To0p2,
536	>	fChargedIso_DR0p2To0p3,
537	>	fChargedIso_DR0p3To0p4,
538	>	fChargedIso_DR0p4To0p5,
539	>	fGammaIso_DR0p0To0p1,
540	>	fGammaIso_DR0p1To0p2,
541	>	fGammaIso_DR0p2To0p3,
542	>	fGammaIso_DR0p3To0p4,
543	>	fGammaIso_DR0p4To0p5,
544	>	fNeutralHadronIso_DR0p0To0p1,
545	>	fNeutralHadronIso_DR0p1To0p2,
546	>	fNeutralHadronIso_DR0p2To0p3,
547	>	fNeutralHadronIso_DR0p3To0p4,
548	>	fNeutralHadronIso_DR0p4To0p5,
549	>	ctrl.debug);
550	>
551	>	SelectionStatus status;
552	>	bool pass;
553	>
554	>	pass = false;
555	>	if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
556	>	&& fabs(mu->Eta()) <= 1.5 && mu->Pt() <= 10 && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_OPT_BIN0)   pass = true;
557	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
558	>	&& fabs(mu->Eta()) <= 1.5 && mu->Pt() > 10 && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_OPT_BIN1)  pass = true;
559	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
560	>	&& fabs(mu->Eta()) > 1.5 && mu->Pt() <= 10 && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_OPT_BIN2)  pass = true;
561	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
562	>	&& fabs(mu->Eta()) > 1.5 && mu->Pt() > 10 && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_OPT_BIN3)  pass = true;
563	>	else if( !(mu->IsGlobalMuon()) && mu->IsTrackerMuon() && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_OPT_BIN4)  pass = true;
564	>	else if( mu->IsGlobalMuon() && !(mu->IsTrackerMuon()) && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_OPT_BIN5)  pass = true;
565	>	if( pass ) status.orStatus(SelectionStatus::LOOSEISO);
566	>
567	>	/*
568	>	pass = false;
569	>	if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
570	>	&& fabs(mu->Eta()) <= 1.5 && mu->Pt() <= 10 && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN0)   pass = true;
571	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
572	>	&& fabs(mu->Eta()) <= 1.5 && mu->Pt() > 10 && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN1)  pass = true;
573	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
574	>	&& fabs(mu->Eta()) > 1.5 && mu->Pt() <= 10 && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN2)  pass = true;
575	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
576	>	&& fabs(mu->Eta()) > 1.5 && mu->Pt() > 10 && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN3)  pass = true;
577	>	else if( !(mu->IsGlobalMuon()) && mu->IsTrackerMuon() && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN4)  pass = true;
578	>	else if( mu->IsGlobalMuon() && !(mu->IsTrackerMuon()) && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN5)  pass = true;
579	>	if( pass ) status.orStatus(SelectionStatus::TIGHTISO);
580	>	*/
581	>
582	>	//  pass &= (fChargedIso_DR0p0To0p1 + fChargedIso_DR0p1To0p2 + fChargedIso_DR0p2To0p3 < 0.7);
583	>
584	>	status.isoMVA = mvaval;
585	>
586	>	if(ctrl.debug)  {
587	>	cout << "returning status : " << hex << status.getStatus() << dec << endl;
588	>	cout << "MVAVAL : " << status.isoMVA << endl;
589	>	}
590	>	return status;
591	>
592	>	}
593	>
594	>
595	>	//--------------------------------------------------------------------------------------------------
596	>	SelectionStatus muonIsoMVASelection(ControlFlags &ctrl,
597	>	const mithep::Muon * mu,
598	>	const mithep::Vertex * vtx,
599	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
600	>	float rho,
601	>	//const mithep::Array<mithep::PileupEnergyDensity> * fPUEnergyDensity,
602	>	mithep::MuonTools::EMuonEffectiveAreaTarget EffectiveAreaVersion,
603	>	vector<const mithep::Muon*> muonsToVeto,
604	>	vector<const mithep::Electron*> electronsToVeto)
605	>	//--------------------------------------------------------------------------------------------------
606	>	// hacked version
607	>	{
608	>
609	>	if( ctrl.debug ) {
610	>	cout << "muonIsoMVASelection :: muons to veto " << endl;
611	>	for( int i=0; i<muonsToVeto.size(); i++ ) {
612	>	const mithep::Muon * vmu = muonsToVeto[i];
613	>	cout << "\tpt: " << vmu->Pt()
614	>	<< "\teta: " << vmu->Eta()
615	>	<< "\tphi: " << vmu->Phi()
616	>	<< endl;
617	>	}
618	>	cout << "muonIsoMVASelection :: electrson to veto " << endl;
619	>	for( int i=0; i<electronsToVeto.size(); i++ ) {
620	>	const mithep::Electron * vel = electronsToVeto[i];
621	>	cout << "\tpt: " << vel->Pt()
622	>	<< "\teta: " << vel->Eta()
623	>	<< "\tphi: " << vel->Phi()
624	>	<< endl;
625	>	}
626	>	}
627	>	bool failiso=false;
628	>
629	>	//
630	>	// tmp iso rings
631	>	//
632	>	Double_t tmpChargedIso_DR0p0To0p1  = 0;
633	>	Double_t tmpChargedIso_DR0p1To0p2  = 0;
634	>	Double_t tmpChargedIso_DR0p2To0p3  = 0;
635	>	Double_t tmpChargedIso_DR0p3To0p4  = 0;
636	>	Double_t tmpChargedIso_DR0p4To0p5  = 0;
637	>	Double_t tmpChargedIso_DR0p5To0p7  = 0;
638	>
639	>	Double_t tmpGammaIso_DR0p0To0p1  = 0;
640	>	Double_t tmpGammaIso_DR0p1To0p2  = 0;
641	>	Double_t tmpGammaIso_DR0p2To0p3  = 0;
642	>	Double_t tmpGammaIso_DR0p3To0p4  = 0;
643	>	Double_t tmpGammaIso_DR0p4To0p5  = 0;
644	>	Double_t tmpGammaIso_DR0p5To0p7  = 0;
645	>
646	>	Double_t tmpNeutralHadronIso_DR0p0To0p1  = 0;
647	>	Double_t tmpNeutralHadronIso_DR0p1To0p2  = 0;
648	>	Double_t tmpNeutralHadronIso_DR0p2To0p3  = 0;
649	>	Double_t tmpNeutralHadronIso_DR0p3To0p4  = 0;
650	>	Double_t tmpNeutralHadronIso_DR0p4To0p5  = 0;
651	>	Double_t tmpNeutralHadronIso_DR0p5To0p7  = 0;
652	>
653	>
654	>
655	>	//
656	>	// final rings for the MVA
657	>	//
658	>	Double_t fChargedIso_DR0p0To0p1;
659	>	Double_t fChargedIso_DR0p1To0p2;
660	>	Double_t fChargedIso_DR0p2To0p3;
661	>	Double_t fChargedIso_DR0p3To0p4;
662	>	Double_t fChargedIso_DR0p4To0p5;
663	>	Double_t fChargedIso_DR0p5To0p7;
664	>
665	>	Double_t fGammaIso_DR0p0To0p1;
666	>	Double_t fGammaIso_DR0p1To0p2;
667	>	Double_t fGammaIso_DR0p2To0p3;
668	>	Double_t fGammaIso_DR0p3To0p4;
669	>	Double_t fGammaIso_DR0p4To0p5;
670	>	Double_t fGammaIso_DR0p5To0p7;
671	>
672	>	Double_t fNeutralHadronIso_DR0p0To0p1;
673	>	Double_t fNeutralHadronIso_DR0p1To0p2;
674	>	Double_t fNeutralHadronIso_DR0p2To0p3;
675	>	Double_t fNeutralHadronIso_DR0p3To0p4;
676	>	Double_t fNeutralHadronIso_DR0p4To0p5;
677	>	Double_t fNeutralHadronIso_DR0p5To0p7;
678	>
679	>
680	>	//
681	>	//Loop over PF Candidates
682	>	//
683	>	for(int k=0; k<fPFCandidates->GetEntries(); ++k) {
684	>
685	>	if( !(PFnoPUflag[k]) ) continue; // my PF no PU hack
686	>
687	>	const mithep::PFCandidate *pf = (mithep::PFCandidate*)((*fPFCandidates)[k]);
688	>
689	>	Double_t deta = (mu->Eta() - pf->Eta());
690	>	Double_t dphi = mithep::MathUtils::DeltaPhi(Double_t(mu->Phi()),Double_t(pf->Phi()));
691	>	Double_t dr = mithep::MathUtils::DeltaR(mu->Phi(),mu->Eta(), pf->Phi(), pf->Eta());
692	>	if (dr > 1.0) continue;
693	>
694	>	if (pf->HasTrackerTrk() && (pf->TrackerTrk() == mu->TrackerTrk()) ) continue;
695	>
696	>	//
697	>	// Lepton Footprint Removal
698	>	//
699	>	Bool_t IsLeptonFootprint = kFALSE;
700	>	if (dr < 1.0) {
701	>
702	>	//
703	>	// Check for electrons
704	>	//
705	>	for (Int_t q=0; q < electronsToVeto.size(); ++q) {
706	>	const mithep::Electron *tmpele = electronsToVeto[q];
707	>	// 4l electron
708	>	if( pf->HasTrackerTrk() ) {
709	>	if( pf->TrackerTrk() == tmpele->TrackerTrk() )
710	>	IsLeptonFootprint = kTRUE;
711	>	}
712	>	if( pf->HasGsfTrk() ) {
713	>	if( pf->GsfTrk() == tmpele->GsfTrk() )
714	>	IsLeptonFootprint = kTRUE;
715	>	}
716	>	// PF charged
717	>	if (pf->Charge() != 0 && fabs(tmpele->SCluster()->Eta()) >= 1.479
718	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.015)
719	>	IsLeptonFootprint = kTRUE;
720	>	// PF gamma
721	>	if (abs(pf->PFType()) == PFCandidate::eGamma && fabs(tmpele->SCluster()->Eta()) >= 1.479
722	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.08)
723	>	IsLeptonFootprint = kTRUE;
724	>	} // loop over electrons
725	>
726	>	/* KH - commented for sync
727	>	//
728	>	// Check for muons
729	>	//
730	>	for (Int_t q=0; q < muonsToVeto.size(); ++q) {
731	>	const mithep::Muon *tmpmu = muonsToVeto[q];
732	>	// 4l muon
733	>	if( pf->HasTrackerTrk() ) {
734	>	if( pf->TrackerTrk() == tmpmu->TrackerTrk() )
735	>	IsLeptonFootprint = kTRUE;
736	>	}
737	>	// PF charged
738	>	if (pf->Charge() != 0 && mithep::MathUtils::DeltaR(tmpmu->Phi(),tmpmu->Eta(), pf->Phi(), pf->Eta()) < 0.01)
739	>	IsLeptonFootprint = kTRUE;
740	>	} // loop over muons
741	>	*/
742	>
743	>	if (IsLeptonFootprint)
744	>	continue;
745	>
746	>	//
747	>	// Charged Iso Rings
748	>	//
749	>	if (pf->Charge() != 0 && (pf->HasTrackerTrk()||pf->HasGsfTrk()) ) {
750	>
751	>	if( dr < 0.01 ) continue; // only for muon iso mva?
752	>	if (abs(pf->PFType()) == PFCandidate::eElectron || abs(pf->PFType()) == PFCandidate::eMuon) continue;
753	>
754	>	//       if( pf->HasTrackerTrk() ) {
755	>	//      if (abs(pf->TrackerTrk()->DzCorrected(vtx)) > 0.2) continue;
756	>	//      if( ctrl.debug ) cout << "charged:: " << pf->PFType() << " " << pf->Pt() << " "
757	>	//                            << abs(pf->TrackerTrk()->DzCorrected(vtx)) << " "
758	>	//                            << dr << endl;
759	>	//       }
760	>	//       if( pf->HasGsfTrk() ) {
761	>	//      if (abs(pf->GsfTrk()->DzCorrected(vtx)) > 0.2) continue;
762	>	//      if( ctrl.debug ) cout << "charged:: " << pf->PFType() << " " << pf->Pt() << " "
763	>	//                            << abs(pf->GsfTrk()->DzCorrected(vtx)) << " "
764	>	//                            << dr << endl;
765	>	//       }
766	>
767	>	// Footprint Veto
768	>	if (dr < 0.1) tmpChargedIso_DR0p0To0p1 += pf->Pt();
769	>	if (dr >= 0.1 && dr < 0.2) tmpChargedIso_DR0p1To0p2 += pf->Pt();
770	>	if (dr >= 0.2 && dr < 0.3) tmpChargedIso_DR0p2To0p3 += pf->Pt();
771	>	if (dr >= 0.3 && dr < 0.4) tmpChargedIso_DR0p3To0p4 += pf->Pt();
772	>	if (dr >= 0.4 && dr < 0.5) tmpChargedIso_DR0p4To0p5 += pf->Pt();
773	>	if (dr >= 0.5 && dr < 0.7) tmpChargedIso_DR0p5To0p7 += pf->Pt();
774	>	}
775	>
776	>	//
777	>	// Gamma Iso Rings
778	>	//
779	>	else if (abs(pf->PFType()) == PFCandidate::eGamma) {
780	>	if (dr < 0.1) tmpGammaIso_DR0p0To0p1 += pf->Pt();
781	>	if (dr >= 0.1 && dr < 0.2) tmpGammaIso_DR0p1To0p2 += pf->Pt();
782	>	if (dr >= 0.2 && dr < 0.3) tmpGammaIso_DR0p2To0p3 += pf->Pt();
783	>	if (dr >= 0.3 && dr < 0.4) tmpGammaIso_DR0p3To0p4 += pf->Pt();
784	>	if (dr >= 0.4 && dr < 0.5) tmpGammaIso_DR0p4To0p5 += pf->Pt();
785	>	if (dr >= 0.5 && dr < 0.7) tmpGammaIso_DR0p5To0p7 += pf->Pt();
786	>	}
787	>
788	>	//
789	>	// Other Neutral Iso Rings
790	>	//
791	>	else {
792	>	if (dr < 0.1) tmpNeutralHadronIso_DR0p0To0p1 += pf->Pt();
793	>	if (dr >= 0.1 && dr < 0.2) tmpNeutralHadronIso_DR0p1To0p2 += pf->Pt();
794	>	if (dr >= 0.2 && dr < 0.3) tmpNeutralHadronIso_DR0p2To0p3 += pf->Pt();
795	>	if (dr >= 0.3 && dr < 0.4) tmpNeutralHadronIso_DR0p3To0p4 += pf->Pt();
796	>	if (dr >= 0.4 && dr < 0.5) tmpNeutralHadronIso_DR0p4To0p5 += pf->Pt();
797	>	if (dr >= 0.5 && dr < 0.7) tmpNeutralHadronIso_DR0p5To0p7 += pf->Pt();
798	>	}
799	>
800	>	}
801	>
802	>	}
803	>
804	>	fChargedIso_DR0p0To0p1   = fmin((tmpChargedIso_DR0p0To0p1)/mu->Pt(), 2.5);
805	>	fChargedIso_DR0p1To0p2   = fmin((tmpChargedIso_DR0p1To0p2)/mu->Pt(), 2.5);
806	>	fChargedIso_DR0p2To0p3   = fmin((tmpChargedIso_DR0p2To0p3)/mu->Pt(), 2.5);
807	>	fChargedIso_DR0p3To0p4   = fmin((tmpChargedIso_DR0p3To0p4)/mu->Pt(), 2.5);
808	>	fChargedIso_DR0p4To0p5   = fmin((tmpChargedIso_DR0p4To0p5)/mu->Pt(), 2.5);
809	>
810	>
811	>	//   double rho = 0;
812	>	//   if (!(isnan(fPUEnergyDensity->At(0)->Rho()) || isinf(fPUEnergyDensity->At(0)->Rho())))
813	>	//     rho = fPUEnergyDensity->At(0)->Rho();
814	>	//   if (!(isnan(fPUEnergyDensity->At(0)->RhoLowEta()) || isinf(fPUEnergyDensity->At(0)->RhoLowEta())))
815	>	//     rho = fPUEnergyDensity->At(0)->RhoLowEta();
816	>
817	>	// WARNING!!!!
818	>	// hardcode for sync ...
819	>	EffectiveAreaVersion = muT.kMuEAData2011;
820	>	// WARNING!!!!
821	>
822	>
823	>	fGammaIso_DR0p0To0p1 = fmax(fmin((tmpGammaIso_DR0p0To0p1
824	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaIsoDR0p0To0p1,mu->Eta(),EffectiveAreaVersion))/mu->Pt()
825	>	,2.5)
826	>	,0.0);
827	>	fGammaIso_DR0p1To0p2 = fmax(fmin((tmpGammaIso_DR0p1To0p2
828	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaIsoDR0p1To0p2,mu->Eta(),EffectiveAreaVersion))/mu->Pt()
829	>	,2.5)
830	>	,0.0);
831	>	fGammaIso_DR0p2To0p3 = fmax(fmin((tmpGammaIso_DR0p2To0p3
832	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaIsoDR0p2To0p3,mu->Eta(),EffectiveAreaVersion))/mu->Pt()
833	>	,2.5)
834	>	,0.0);
835	>	fGammaIso_DR0p3To0p4 = fmax(fmin((tmpGammaIso_DR0p3To0p4
836	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaIsoDR0p3To0p4,mu->Eta(),EffectiveAreaVersion))/mu->Pt()
837	>	,2.5)
838	>	,0.0);
839	>	fGammaIso_DR0p4To0p5 = fmax(fmin((tmpGammaIso_DR0p4To0p5
840	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaIsoDR0p4To0p5,mu->Eta(),EffectiveAreaVersion))/mu->Pt()
841	>	,2.5)
842	>	,0.0);
843	>
844	>
845	>
846	>	fNeutralHadronIso_DR0p0To0p1 = fmax(fmin((tmpNeutralHadronIso_DR0p0To0p1
847	>	-rho*muT.MuonEffectiveArea(muT.kMuNeutralHadronIsoDR0p0To0p1,
848	>	mu->Eta(),EffectiveAreaVersion))/mu->Pt()
849	>	, 2.5)
850	>	, 0.0);
851	>	fNeutralHadronIso_DR0p1To0p2 = fmax(fmin((tmpNeutralHadronIso_DR0p1To0p2
852	>	-rho*muT.MuonEffectiveArea(muT.kMuNeutralHadronIsoDR0p1To0p2,
853	>	mu->Eta(),EffectiveAreaVersion))/mu->Pt()
854	>	, 2.5)
855	>	, 0.0);
856	>	fNeutralHadronIso_DR0p2To0p3 = fmax(fmin((tmpNeutralHadronIso_DR0p2To0p3
857	>	-rho*muT.MuonEffectiveArea(muT.kMuNeutralHadronIsoDR0p2To0p3,
858	>	mu->Eta(),EffectiveAreaVersion))/mu->Pt()
859	>	, 2.5)
860	>	, 0.0);
861	>	fNeutralHadronIso_DR0p3To0p4 = fmax(fmin((tmpNeutralHadronIso_DR0p3To0p4
862	>	-rho*muT.MuonEffectiveArea(muT.kMuNeutralHadronIsoDR0p3To0p4,
863	>	mu->Eta(), EffectiveAreaVersion))/mu->Pt()
864	>	, 2.5)
865	>	, 0.0);
866	>	fNeutralHadronIso_DR0p4To0p5 = fmax(fmin((tmpNeutralHadronIso_DR0p4To0p5
867	>	-rho*muT.MuonEffectiveArea(muT.kMuNeutralHadronIsoDR0p4To0p5,
868	>	mu->Eta(), EffectiveAreaVersion))/mu->Pt()
869	>	, 2.5)
870	>	, 0.0);
871	>
872	>
873	>	double mvaval = muIsoMVA->MVAValue_IsoRings( mu->Pt(),
874	>	mu->Eta(),
875	>	mu->IsGlobalMuon(),
876	>	mu->IsTrackerMuon(),
877	>	fChargedIso_DR0p0To0p1,
878	>	fChargedIso_DR0p1To0p2,
879	>	fChargedIso_DR0p2To0p3,
880	>	fChargedIso_DR0p3To0p4,
881	>	fChargedIso_DR0p4To0p5,
882	>	fGammaIso_DR0p0To0p1,
883	>	fGammaIso_DR0p1To0p2,
884	>	fGammaIso_DR0p2To0p3,
885	>	fGammaIso_DR0p3To0p4,
886	>	fGammaIso_DR0p4To0p5,
887	>	fNeutralHadronIso_DR0p0To0p1,
888	>	fNeutralHadronIso_DR0p1To0p2,
889	>	fNeutralHadronIso_DR0p2To0p3,
890	>	fNeutralHadronIso_DR0p3To0p4,
891	>	fNeutralHadronIso_DR0p4To0p5,
892	>	ctrl.debug);
893	>
894	>	SelectionStatus status;
895	>	bool pass;
896	>
897	>	pass = false;
898	>	if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
899	>	&& fabs(mu->Eta()) <= 1.5 && mu->Pt() <= 10 && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_BIN0)   pass = true;
900	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
901	>	&& fabs(mu->Eta()) <= 1.5 && mu->Pt() > 10 && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_BIN1)  pass = true;
902	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
903	>	&& fabs(mu->Eta()) > 1.5 && mu->Pt() <= 10 && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_BIN2)  pass = true;
904	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
905	>	&& fabs(mu->Eta()) > 1.5 && mu->Pt() > 10 && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_BIN3)  pass = true;
906	>	else if( !(mu->IsGlobalMuon()) && mu->IsTrackerMuon() && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_BIN4)  pass = true;
907	>	else if( mu->IsGlobalMuon() && !(mu->IsTrackerMuon()) && mvaval >= MUON_ISOMVA_LOOSE_FORPFID_CUT_BIN5)  pass = true;
908	>	if( pass ) status.orStatus(SelectionStatus::LOOSEISO);
909	>
910	>	/*
911	>	pass = false;
912	>	if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
913	>	&& fabs(mu->Eta()) <= 1.5 && mu->Pt() <= 10 && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN0)   pass = true;
914	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
915	>	&& fabs(mu->Eta()) <= 1.5 && mu->Pt() > 10 && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN1)  pass = true;
916	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
917	>	&& fabs(mu->Eta()) > 1.5 && mu->Pt() <= 10 && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN2)  pass = true;
918	>	else if( mu->IsGlobalMuon() && mu->IsTrackerMuon()
919	>	&& fabs(mu->Eta()) > 1.5 && mu->Pt() > 10 && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN3)  pass = true;
920	>	else if( !(mu->IsGlobalMuon()) && mu->IsTrackerMuon() && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN4)  pass = true;
921	>	else if( mu->IsGlobalMuon() && !(mu->IsTrackerMuon()) && mvaval >= MUON_ISOMVA_TIGHT_FORPFID_CUT_BIN5)  pass = true;
922	>	if( pass ) status.orStatus(SelectionStatus::TIGHTISO);
923	>	*/
924	>
925	>	//  pass &= (fChargedIso_DR0p0To0p1 + fChargedIso_DR0p1To0p2 + fChargedIso_DR0p2To0p3 < 0.7);
926	>
927	>	status.isoMVA = mvaval;
928	>
929	>	if(ctrl.debug)  {
930	>	cout << "returning status : " << hex << status.getStatus() << dec << endl;
931	>	cout << "MVAVAL : " << status.isoMVA << endl;
932	>	}
933	>	return status;
934	>
935	>	}
936	>
937	>
938	>	//--------------------------------------------------------------------------------------------------
939	>	void initMuonIsoMVA() {
940	>	//--------------------------------------------------------------------------------------------------
941	>	muIsoMVA = new mithep::MuonIDMVA();
942	>	vector<string> weightFiles;
943	>	weightFiles.push_back("./data/MuonIsoMVAWeights/MuonIsoMVA_BDTG_V0_barrel_lowpt.weights.xml");
944	>	weightFiles.push_back("./data/MuonIsoMVAWeights/MuonIsoMVA_BDTG_V0_barrel_highpt.weights.xml");
945	>	weightFiles.push_back("./data/MuonIsoMVAWeights/MuonIsoMVA_BDTG_V0_endcap_lowpt.weights.xml");
946	>	weightFiles.push_back("./data/MuonIsoMVAWeights/MuonIsoMVA_BDTG_V0_endcap_highpt.weights.xml");
947	>	weightFiles.push_back("./data/MuonIsoMVAWeights/MuonIsoMVA_BDTG_V0_tracker.weights.xml");
948	>	weightFiles.push_back("./data/MuonIsoMVAWeights/MuonIsoMVA_BDTG_V0_global.weights.xml");
949	>	muIsoMVA->Initialize( "MuonIsoMVA",
950	>	mithep::MuonIDMVA::kIsoRingsV0,
951	>	kTRUE, weightFiles);
952	>	}
953	>
954	>
955	>
956	>
957	>	//--------------------------------------------------------------------------------------------------
958	>	double  muonPFIso04(ControlFlags &ctrl,
959	>	const mithep::Muon * mu,
960	>	const mithep::Vertex * vtx,
961	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
962	>	const mithep::Array<mithep::PileupEnergyDensity> * fPUEnergyDensity,
963	>	mithep::MuonTools::EMuonEffectiveAreaTarget EffectiveAreaVersion,
964	>	vector<const mithep::Muon*> muonsToVeto,
965	>	vector<const mithep::Electron*> electronsToVeto)
966	>	//--------------------------------------------------------------------------------------------------
967	>	{
968	>
969	>	extern double gChargedIso;
970	>	extern double  gGammaIso;
971	>	extern double  gNeutralIso;
972	>
973	>	if( ctrl.debug ) {
974	>	cout << "muonIsoMVASelection :: muons to veto " << endl;
975	>	for( int i=0; i<muonsToVeto.size(); i++ ) {
976	>	const mithep::Muon * vmu = muonsToVeto[i];
977	>	cout << "\tpt: " << vmu->Pt()
978	>	<< "\teta: " << vmu->Eta()
979	>	<< "\tphi: " << vmu->Phi()
980	>	<< endl;
981	>	}
982	>	cout << "muonIsoMVASelection :: electrson to veto " << endl;
983	>	for( int i=0; i<electronsToVeto.size(); i++ ) {
984	>	const mithep::Electron * vel = electronsToVeto[i];
985	>	cout << "\tpt: " << vel->Pt()
986	>	<< "\teta: " << vel->Eta()
987	>	<< "\tphi: " << vel->Phi()
988	>	<< endl;
989	>	}
990	>	}
991	>
992	>	//
993	>	// final iso
994	>	//
995	>	Double_t fChargedIso  = 0.0;
996	>	Double_t fGammaIso  = 0.0;
997	>	Double_t fNeutralHadronIso  = 0.0;
998	>
999	>	//
1000	>	//Loop over PF Candidates
1001	>	//
1002	>	for(int k=0; k<fPFCandidates->GetEntries(); ++k) {
1003	>
1004	>	if( !(PFnoPUflag[k]) ) continue; // my PF no PU hack
1005	>	const mithep::PFCandidate *pf = (mithep::PFCandidate*)((*fPFCandidates)[k]);
1006	>
1007	>	Double_t deta = (mu->Eta() - pf->Eta());
1008	>	Double_t dphi = mithep::MathUtils::DeltaPhi(Double_t(mu->Phi()),Double_t(pf->Phi()));
1009	>	Double_t dr = mithep::MathUtils::DeltaR(mu->Phi(),mu->Eta(), pf->Phi(), pf->Eta());
1010	>	if (dr > 0.4) continue;
1011	>
1012	>	if (pf->HasTrackerTrk() && (pf->TrackerTrk() == mu->TrackerTrk()) ) continue;
1013	>
1014	>	//
1015	>	// Lepton Footprint Removal
1016	>	//
1017	>	Bool_t IsLeptonFootprint = kFALSE;
1018	>	if (dr < 1.0) {
1019	>
1020	>	//
1021	>	// Check for electrons
1022	>	//
1023	>	for (Int_t q=0; q < electronsToVeto.size(); ++q) {
1024	>	const mithep::Electron *tmpele = electronsToVeto[q];
1025	>	// 4l electron
1026	>	if( pf->HasTrackerTrk() ) {
1027	>	if( pf->TrackerTrk() == tmpele->TrackerTrk() )
1028	>	IsLeptonFootprint = kTRUE;
1029	>	}
1030	>	if( pf->HasGsfTrk() ) {
1031	>	if( pf->GsfTrk() == tmpele->GsfTrk() )
1032	>	IsLeptonFootprint = kTRUE;
1033	>	}
1034	>	// PF charged
1035	>	if (pf->Charge() != 0 && fabs(tmpele->SCluster()->Eta()) > 1.479
1036	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.015) {
1037	>	if( ctrl.debug) cout << "\tcharged trk, dR ("
1038	>	<< mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta())
1039	>	<< " matches 4L ele ..." << endl;
1040	>	IsLeptonFootprint = kTRUE;
1041	>	}
1042	>	// PF gamma
1043	>	if (abs(pf->PFType()) == PFCandidate::eGamma && fabs(tmpele->SCluster()->Eta()) > 1.479
1044	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.08)
1045	>	IsLeptonFootprint = kTRUE;
1046	>	} // loop over electrons
1047	>
1048	>	/* KH - comment for sync
1049	>	//
1050	>	// Check for muons
1051	>	//
1052	>	for (Int_t q=0; q < muonsToVeto.size(); ++q) {
1053	>	const mithep::Muon *tmpmu = muonsToVeto[q];
1054	>	// 4l muon
1055	>	if( pf->HasTrackerTrk() ) {
1056	>	if( pf->TrackerTrk() == tmpmu->TrackerTrk() )
1057	>	IsLeptonFootprint = kTRUE;
1058	>	}
1059	>	// PF charged
1060	>	if (pf->Charge() != 0 && mithep::MathUtils::DeltaR(tmpmu->Phi(),tmpmu->Eta(), pf->Phi(), pf->Eta()) < 0.01)
1061	>	IsLeptonFootprint = kTRUE;
1062	>	} // loop over muons
1063	>	*/
1064	>
1065	>	if (IsLeptonFootprint)
1066	>	continue;
1067	>
1068	>	//
1069	>	// Charged Iso
1070	>	//
1071	>	if (pf->Charge() != 0 && (pf->HasTrackerTrk()||pf->HasGsfTrk()) ) {
1072	>
1073	>	//if( dr < 0.01 ) continue; // only for muon iso mva?
1074	>	if (abs(pf->PFType()) == PFCandidate::eElectron || abs(pf->PFType()) == PFCandidate::eMuon) continue;
1075	>
1076	>
1077	>	//       if( pf->HasTrackerTrk() ) {
1078	>	//      if (abs(pf->TrackerTrk()->DzCorrected(vtx)) > 0.2) continue;
1079	>	//      if( ctrl.debug ) cout << "charged:: " << pf->PFType() << " " << pf->Pt() << " "
1080	>	//                            << abs(pf->TrackerTrk()->DzCorrected(vtx)) << " "
1081	>	//                            << dr << endl;
1082	>	//       }
1083	>	//       if( pf->HasGsfTrk() ) {
1084	>	//      if (abs(pf->GsfTrk()->DzCorrected(vtx)) > 0.2) continue;
1085	>	//      if( ctrl.debug ) cout << "charged:: " << pf->PFType() << " " << pf->Pt() << " "
1086	>	//                            << abs(pf->GsfTrk()->DzCorrected(vtx)) << " "
1087	>	//                            << dr << endl;
1088	>	//       }
1089	>
1090	>
1091	>	fChargedIso += pf->Pt();
1092	>	}
1093	>
1094	>	//
1095	>	// Gamma Iso
1096	>	//
1097	>	else if (abs(pf->PFType()) == PFCandidate::eGamma) {
1098	>	// KH, add to sync
1099	>	if( pf->Pt() > 0.5 )
1100	>	fGammaIso += pf->Pt();
1101	>	}
1102	>
1103	>	//
1104	>	// Other Neutrals
1105	>	//
1106	>	else {
1107	>	// KH, add to sync
1108	>	if( pf->Pt() > 0.5 )
1109	>	fNeutralHadronIso += pf->Pt();
1110	>	}
1111	>
1112	>	}
1113	>
1114	>	}
1115	>
1116	>	double rho=0;
1117	>	if (!(isnan(fPUEnergyDensity->At(0)->Rho()) || isinf(fPUEnergyDensity->At(0)->Rho())))
1118	>	rho = fPUEnergyDensity->At(0)->Rho();
1119	>
1120	>	// WARNING!!!!
1121	>	// hardcode for sync ...
1122	>	EffectiveAreaVersion = muT.kMuEAData2011;
1123	>	// WARNING!!!!
1124	>
1125	>
1126	>
1127	>	double pfIso = fChargedIso + fmax(0.0,(fGammaIso + fNeutralHadronIso
1128	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaAndNeutralHadronIso04,
1129	>	mu->Eta(),EffectiveAreaVersion)));
1130	>	gChargedIso = fChargedIso;
1131	>	gGammaIso   = fGammaIso;
1132	>	gNeutralIso = fNeutralHadronIso;
1133	>
1134	>	return pfIso;
1135	>	}
1136	>
1137	>
1138	>
1139	>
1140	>	//--------------------------------------------------------------------------------------------------
1141	>	// hacked version
1142	>	double  muonPFIso04(ControlFlags &ctrl,
1143	>	const mithep::Muon * mu,
1144	>	const mithep::Vertex * vtx,
1145	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
1146	>	float rho,
1147	>	mithep::MuonTools::EMuonEffectiveAreaTarget EffectiveAreaVersion,
1148	>	vector<const mithep::Muon*> muonsToVeto,
1149	>	vector<const mithep::Electron*> electronsToVeto)
1150	>	//--------------------------------------------------------------------------------------------------
1151	>	{
1152	>
1153	>	extern double gChargedIso;
1154	>	extern double  gGammaIso;
1155	>	extern double  gNeutralIso;
1156	>
1157	>	if( ctrl.debug ) {
1158	>	cout << "muonIsoMVASelection :: muons to veto " << endl;
1159	>	for( int i=0; i<muonsToVeto.size(); i++ ) {
1160	>	const mithep::Muon * vmu = muonsToVeto[i];
1161	>	cout << "\tpt: " << vmu->Pt()
1162	>	<< "\teta: " << vmu->Eta()
1163	>	<< "\tphi: " << vmu->Phi()
1164	>	<< endl;
1165	>	}
1166	>	cout << "muonIsoMVASelection :: electrson to veto " << endl;
1167	>	for( int i=0; i<electronsToVeto.size(); i++ ) {
1168	>	const mithep::Electron * vel = electronsToVeto[i];
1169	>	cout << "\tpt: " << vel->Pt()
1170	>	<< "\teta: " << vel->Eta()
1171	>	<< "\tphi: " << vel->Phi()
1172	>	<< endl;
1173	>	}
1174	>	}
1175	>
1176	>	//
1177	>	// final iso
1178	>	//
1179	>	Double_t fChargedIso  = 0.0;
1180	>	Double_t fGammaIso  = 0.0;
1181	>	Double_t fNeutralHadronIso  = 0.0;
1182	>
1183	>	//
1184	>	//Loop over PF Candidates
1185	>	//
1186	>	for(int k=0; k<fPFCandidates->GetEntries(); ++k) {
1187	>
1188	>	if( !(PFnoPUflag[k]) ) continue; // my PF no PU hack
1189	>	const mithep::PFCandidate *pf = (mithep::PFCandidate*)((*fPFCandidates)[k]);
1190	>
1191	>	Double_t deta = (mu->Eta() - pf->Eta());
1192	>	Double_t dphi = mithep::MathUtils::DeltaPhi(Double_t(mu->Phi()),Double_t(pf->Phi()));
1193	>	Double_t dr = mithep::MathUtils::DeltaR(mu->Phi(),mu->Eta(), pf->Phi(), pf->Eta());
1194	>	if (dr > 0.4) continue;
1195	>
1196	>	if (pf->HasTrackerTrk() && (pf->TrackerTrk() == mu->TrackerTrk()) ) continue;
1197	>
1198	>	//
1199	>	// Lepton Footprint Removal
1200	>	//
1201	>	Bool_t IsLeptonFootprint = kFALSE;
1202	>	if (dr < 1.0) {
1203	>
1204	>	//
1205	>	// Check for electrons
1206	>	//
1207	>	for (Int_t q=0; q < electronsToVeto.size(); ++q) {
1208	>	const mithep::Electron *tmpele = electronsToVeto[q];
1209	>	// 4l electron
1210	>	if( pf->HasTrackerTrk() ) {
1211	>	if( pf->TrackerTrk() == tmpele->TrackerTrk() )
1212	>	IsLeptonFootprint = kTRUE;
1213	>	}
1214	>	if( pf->HasGsfTrk() ) {
1215	>	if( pf->GsfTrk() == tmpele->GsfTrk() )
1216	>	IsLeptonFootprint = kTRUE;
1217	>	}
1218	>	// PF charged
1219	>	if (pf->Charge() != 0 && fabs(tmpele->SCluster()->Eta()) > 1.479
1220	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.015)
1221	>	IsLeptonFootprint = kTRUE;
1222	>	// PF gamma
1223	>	if (abs(pf->PFType()) == PFCandidate::eGamma && fabs(tmpele->SCluster()->Eta()) > 1.479
1224	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.08)
1225	>	IsLeptonFootprint = kTRUE;
1226	>	} // loop over electrons
1227	>
1228	>	/* KH - comment for sync
1229	>	//
1230	>	// Check for muons
1231	>	//
1232	>	for (Int_t q=0; q < muonsToVeto.size(); ++q) {
1233	>	const mithep::Muon *tmpmu = muonsToVeto[q];
1234	>	// 4l muon
1235	>	if( pf->HasTrackerTrk() ) {
1236	>	if( pf->TrackerTrk() == tmpmu->TrackerTrk() )
1237	>	IsLeptonFootprint = kTRUE;
1238	>	}
1239	>	// PF charged
1240	>	if (pf->Charge() != 0 && mithep::MathUtils::DeltaR(tmpmu->Phi(),tmpmu->Eta(), pf->Phi(), pf->Eta()) < 0.01)
1241	>	IsLeptonFootprint = kTRUE;
1242	>	} // loop over muons
1243	>	*/
1244	>
1245	>	if (IsLeptonFootprint)
1246	>	continue;
1247	>
1248	>	//
1249	>	// Charged Iso
1250	>	//
1251	>	if (pf->Charge() != 0 && (pf->HasTrackerTrk()||pf->HasGsfTrk()) ) {
1252	>
1253	>	//if( dr < 0.01 ) continue; // only for muon iso mva?
1254	>	if (abs(pf->PFType()) == PFCandidate::eElectron || abs(pf->PFType()) == PFCandidate::eMuon) continue;
1255	>
1256	>
1257	>	//       if( pf->HasTrackerTrk() ) {
1258	>	//      if (abs(pf->TrackerTrk()->DzCorrected(vtx)) > 0.2) continue;
1259	>	//      if( ctrl.debug ) cout << "charged:: " << pf->PFType() << " " << pf->Pt() << " "
1260	>	//                            << abs(pf->TrackerTrk()->DzCorrected(vtx)) << " "
1261	>	//                            << dr << endl;
1262	>	//       }
1263	>	//       if( pf->HasGsfTrk() ) {
1264	>	//      if (abs(pf->GsfTrk()->DzCorrected(vtx)) > 0.2) continue;
1265	>	//      if( ctrl.debug ) cout << "charged:: " << pf->PFType() << " " << pf->Pt() << " "
1266	>	//                            << abs(pf->GsfTrk()->DzCorrected(vtx)) << " "
1267	>	//                            << dr << endl;
1268	>	//       }
1269	>
1270	>
1271	>	fChargedIso += pf->Pt();
1272	>	}
1273	>
1274	>	//
1275	>	// Gamma Iso
1276	>	//
1277	>	else if (abs(pf->PFType()) == PFCandidate::eGamma) {
1278	>	// KH, add to sync
1279	>	if( pf->Pt() > 0.5 )
1280	>	fGammaIso += pf->Pt();
1281	>	}
1282	>
1283	>	//
1284	>	// Other Neutrals
1285	>	//
1286	>	else {
1287	>	// KH, add to sync
1288	>	if( pf->Pt() > 0.5 )
1289	>	fNeutralHadronIso += pf->Pt();
1290	>	}
1291	>
1292	>	}
1293	>
1294	>	}
1295	>
1296	>	//   double rho = 0;
1297	>	//   if (!(isnan(fPUEnergyDensity->At(0)->Rho()) || isinf(fPUEnergyDensity->At(0)->Rho())))
1298	>	//     rho = fPUEnergyDensity->At(0)->Rho();
1299	>
1300	>	// WARNING!!!!
1301	>	// hardcode for sync ...
1302	>	EffectiveAreaVersion = muT.kMuEAData2011;
1303	>	// WARNING!!!!
1304	>
1305	>
1306	>	double pfIso = fChargedIso + fmax(0.0,(fGammaIso + fNeutralHadronIso
1307	>	-rho*muT.MuonEffectiveArea(muT.kMuGammaAndNeutralHadronIso04,
1308	>	mu->Eta(),EffectiveAreaVersion)));
1309	>	gChargedIso = fChargedIso;
1310	>	gGammaIso   = fGammaIso;
1311	>	gNeutralIso = fNeutralHadronIso;
1312	>
1313	>	return pfIso;
1314	>	}
1315	>
1316	>
1317	>	//--------------------------------------------------------------------------------------------------
1318	>	SelectionStatus muonReferenceIsoSelection(ControlFlags &ctrl,
1319	>	const mithep::Muon * mu,
1320	>	const mithep::Vertex * vtx,
1321	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
1322	>	const mithep::Array<mithep::PileupEnergyDensity> * fPUEnergyDensity,
1323	>	mithep::MuonTools::EMuonEffectiveAreaTarget EffectiveAreaVersion,
1324	>	vector<const mithep::Muon*> muonsToVeto,
1325	>	vector<const mithep::Electron*> electronsToVeto)
1326	>	//--------------------------------------------------------------------------------------------------
1327	>	{
1328	>
1329	>	SelectionStatus status;
1330	>
1331	>	double pfIso = muonPFIso04( ctrl, mu, vtx, fPFCandidates, fPUEnergyDensity,
1332	>	EffectiveAreaVersion, muonsToVeto ,electronsToVeto );
1333	>	//  cout << "--------------> setting muon isoPF04 to" << pfIso << endl;
1334	>	status.isoPF04 = pfIso;
1335	>	status.chisoPF04 = gChargedIso;
1336	>	status.gaisoPF04 = gGammaIso;
1337	>	status.neisoPF04 = gNeutralIso;
1338	>
1339	>	bool pass = false;
1340	>	if( (pfIso/mu->Pt()) < MUON_REFERENCE_PFISO_CUT ) pass = true;
1341	>
1342	>	if( pass ) {
1343	>	status.orStatus(SelectionStatus::LOOSEISO);
1344	>	status.orStatus(SelectionStatus::TIGHTISO);
1345	>	}
1346	>	if(ctrl.debug) cout << "returning status : " << hex << status.getStatus() << dec << endl;
1347	>	return status;
1348	>
1349	>	}
1350	>
1351	>
1352	>	//--------------------------------------------------------------------------------------------------
1353	>	// hacked version
1354	>	SelectionStatus muonReferenceIsoSelection(ControlFlags &ctrl,
1355	>	const mithep::Muon * mu,
1356	>	const mithep::Vertex * vtx,
1357	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
1358	>	float rho,
1359	>	mithep::MuonTools::EMuonEffectiveAreaTarget EffectiveAreaVersion,
1360	>	vector<const mithep::Muon*> muonsToVeto,
1361	>	vector<const mithep::Electron*> electronsToVeto)
1362	>	//--------------------------------------------------------------------------------------------------
1363	>	{
1364	>
1365	>	SelectionStatus status;
1366	>
1367	>	double pfIso = muonPFIso04( ctrl, mu, vtx, fPFCandidates, rho,
1368	>	EffectiveAreaVersion, muonsToVeto ,electronsToVeto );
1369	>
1370	>	status.isoPF04 = pfIso;
1371	>	status.chisoPF04 = gChargedIso;
1372	>	status.gaisoPF04 = gGammaIso;
1373	>	status.neisoPF04 = gNeutralIso;
1374	>
1375	>	bool pass = false;
1376	>	if( (pfIso/mu->Pt()) < MUON_REFERENCE_PFISO_CUT ) pass = true;
1377	>
1378	>	if( pass ) {
1379	>	status.orStatus(SelectionStatus::LOOSEISO);
1380	>	status.orStatus(SelectionStatus::TIGHTISO);
1381	>	}
1382	>	if(ctrl.debug) cout << "returning status : " << hex << status.getStatus() << dec << endl;
1383	>	return status;
1384	>
1385	>	}
1386	>
1387	>
1388	>
1389	>
1390	>	//--------------------------------------------------------------------------------------------------
1391	>	SelectionStatus electronIsoMVASelection(ControlFlags &ctrl,
1392	>	const mithep::Electron * ele,
1393	>	const mithep::Vertex * vtx,
1394	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
1395	>	const mithep::Array<mithep::PileupEnergyDensity> * fPUEnergyDensity,
1396	>	mithep::ElectronTools::EElectronEffectiveAreaTarget EffectiveAreaVersion,
1397	>	vector<const mithep::Muon*> muonsToVeto,
1398	>	vector<const mithep::Electron*> electronsToVeto)
1399	>	//--------------------------------------------------------------------------------------------------
1400	>	{
1401	>
1402	>	if( ctrl.debug ) {
1403	>	cout << "electronIsoMVASelection :: muons to veto " << endl;
1404	>	for( int i=0; i<muonsToVeto.size(); i++ ) {
1405	>	const mithep::Muon * vmu = muonsToVeto[i];
1406	>	cout << "\tpt: " << vmu->Pt()
1407	>	<< "\teta: " << vmu->Eta()
1408	>	<< "\tphi: " << vmu->Phi()
1409	>	<< endl;
1410	>	}
1411	>	cout << "electronIsoMVASelection :: electrson to veto " << endl;
1412	>	for( int i=0; i<electronsToVeto.size(); i++ ) {
1413	>	const mithep::Electron * vel = electronsToVeto[i];
1414	>	cout << "\tpt: " << vel->Pt()
1415	>	<< "\teta: " << vel->Eta()
1416	>	<< "\tphi: " << vel->Phi()
1417	>	<< "\ttrk: " << vel->TrackerTrk()
1418	>	<< endl;
1419	>	}
1420	>	}
1421	>
1422	>	bool failiso=false;
1423	>
1424	>	//
1425	>	// tmp iso rings
1426	>	//
1427	>	Double_t tmpChargedIso_DR0p0To0p1  = 0;
1428	>	Double_t tmpChargedIso_DR0p1To0p2  = 0;
1429	>	Double_t tmpChargedIso_DR0p2To0p3  = 0;
1430	>	Double_t tmpChargedIso_DR0p3To0p4  = 0;
1431	>	Double_t tmpChargedIso_DR0p4To0p5  = 0;
1432	>
1433	>	Double_t tmpGammaIso_DR0p0To0p1  = 0;
1434	>	Double_t tmpGammaIso_DR0p1To0p2  = 0;
1435	>	Double_t tmpGammaIso_DR0p2To0p3  = 0;
1436	>	Double_t tmpGammaIso_DR0p3To0p4  = 0;
1437	>	Double_t tmpGammaIso_DR0p4To0p5  = 0;
1438	>
1439	>
1440	>	Double_t tmpNeutralHadronIso_DR0p0To0p1  = 0;
1441	>	Double_t tmpNeutralHadronIso_DR0p1To0p2  = 0;
1442	>	Double_t tmpNeutralHadronIso_DR0p2To0p3  = 0;
1443	>	Double_t tmpNeutralHadronIso_DR0p3To0p4  = 0;
1444	>	Double_t tmpNeutralHadronIso_DR0p4To0p5  = 0;
1445	>
1446	>
1447	>
1448	>	//
1449	>	// final rings for the MVA
1450	>	//
1451	>	Double_t fChargedIso_DR0p0To0p1;
1452	>	Double_t fChargedIso_DR0p1To0p2;
1453	>	Double_t fChargedIso_DR0p2To0p3;
1454	>	Double_t fChargedIso_DR0p3To0p4;
1455	>	Double_t fChargedIso_DR0p4To0p5;
1456	>
1457	>	Double_t fGammaIso_DR0p0To0p1;
1458	>	Double_t fGammaIso_DR0p1To0p2;
1459	>	Double_t fGammaIso_DR0p2To0p3;
1460	>	Double_t fGammaIso_DR0p3To0p4;
1461	>	Double_t fGammaIso_DR0p4To0p5;
1462	>
1463	>	Double_t fNeutralHadronIso_DR0p0To0p1;
1464	>	Double_t fNeutralHadronIso_DR0p1To0p2;
1465	>	Double_t fNeutralHadronIso_DR0p2To0p3;
1466	>	Double_t fNeutralHadronIso_DR0p3To0p4;
1467	>	Double_t fNeutralHadronIso_DR0p4To0p5;
1468	>
1469	>
1470	>	//
1471	>	//Loop over PF Candidates
1472	>	//
1473	>	for(int k=0; k<fPFCandidates->GetEntries(); ++k) {
1474	>
1475	>	if( !(PFnoPUflag[k]) ) continue; // my PF no PU hack
1476	>
1477	>	const mithep::PFCandidate *pf = (mithep::PFCandidate*)((*fPFCandidates)[k]);
1478	>	Double_t deta = (ele->Eta() - pf->Eta());
1479	>	Double_t dphi = mithep::MathUtils::DeltaPhi(Double_t(ele->Phi()),Double_t(pf->Phi()));
1480	>	Double_t dr = mithep::MathUtils::DeltaR(ele->Phi(),ele->Eta(), pf->Phi(), pf->Eta());
1481	>	if (dr > 1.0) continue;
1482	>
1483	>	if(ctrl.debug) {
1484	>	cout << "pf :: type: " << pf->PFType() << "\tpt: " << pf->Pt();
1485	>	if( pf->HasTrackerTrk() ) cout << "\tdZ: " << pf->TrackerTrk()->DzCorrected(*vtx);
1486	>	cout << endl;
1487	>	}
1488	>
1489	>
1490	>	if ( (pf->HasTrackerTrk() && (pf->TrackerTrk() == ele->TrackerTrk())) ||
1491	>	(pf->HasGsfTrk() && (pf->GsfTrk() == ele->GsfTrk()))) continue;
1492	>
1493	>
1494	>	//
1495	>	// Lepton Footprint Removal
1496	>	//
1497	>	Bool_t IsLeptonFootprint = kFALSE;
1498	>	if (dr < 1.0) {
1499	>
1500	>
1501	>	//
1502	>	// Check for electrons
1503	>	//
1504	>
1505	>	for (Int_t q=0; q < electronsToVeto.size(); ++q) {
1506	>	const mithep::Electron *tmpele = electronsToVeto[q];
1507	>	double tmpdr = mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta());
1508	>
1509	>	// 4l electron
1510	>	if( pf->HasTrackerTrk()  ) {
1511	>	if( pf->TrackerTrk() == tmpele->TrackerTrk() ) {
1512	>	if( ctrl.debug) cout << "\tcharged tktrk, matches 4L ele ..." << endl;
1513	>	IsLeptonFootprint = kTRUE;
1514	>	}
1515	>	}
1516	>	if( pf->HasGsfTrk()  ) {
1517	>	if( pf->GsfTrk() == tmpele->GsfTrk() ) {
1518	>	if( ctrl.debug) cout << "\tcharged gsftrk, matches 4L ele ..." << endl;
1519	>	IsLeptonFootprint = kTRUE;
1520	>	}
1521	>	}
1522	>	// PF charged
1523	>	if (pf->Charge() != 0 && fabs(tmpele->SCluster()->Eta()) >= 1.479 && tmpdr < 0.015) {
1524	>	if( ctrl.debug) cout << "\tcharged trk, dR matches 4L ele ..." << endl;
1525	>	IsLeptonFootprint = kTRUE;
1526	>	}
1527	>	// PF gamma
1528	>	if (abs(pf->PFType()) == PFCandidate::eGamma && fabs(tmpele->SCluster()->Eta()) >= 1.479
1529	>	&& tmpdr < 0.08) {
1530	>	if( ctrl.debug) cout << "\tPF gamma, matches 4L ele ..." << endl;
1531	>	IsLeptonFootprint = kTRUE;
1532	>	}
1533	>	} // loop over electrons
1534	>
1535	>
1536	>	/* KH - comment for sync
1537	>	//
1538	>	// Check for muons
1539	>	//
1540	>	for (Int_t q=0; q < muonsToVeto.size(); ++q) {
1541	>	const mithep::Muon *tmpmu = muonsToVeto[q];
1542	>	// 4l muon
1543	>	if( pf->HasTrackerTrk() ) {
1544	>	if (pf->TrackerTrk() == tmpmu->TrackerTrk() ){
1545	>	if( ctrl.debug) cout << "\tmatches 4L mu ..." << endl;
1546	>	IsLeptonFootprint = kTRUE;
1547	>	}
1548	>	}
1549	>	// PF charged
1550	>	if (pf->Charge() != 0 && mithep::MathUtils::DeltaR(tmpmu->Phi(),tmpmu->Eta(), pf->Phi(), pf->Eta()) < 0.01) {
1551	>	if( ctrl.debug) cout << "\tcharged trk, dR matches 4L mu ..." << endl;
1552	>	IsLeptonFootprint = kTRUE;
1553	>	}
1554	>	} // loop over muons
1555	>	*/
1556	>
1557	>	if (IsLeptonFootprint)
1558	>	continue;
1559	>
1560	>	//
1561	>	// Charged Iso Rings
1562	>	//
1563	>	if (pf->Charge() != 0 && (pf->HasTrackerTrk()||pf->HasGsfTrk()) ) {
1564	>
1565	>	//       if( pf->HasGsfTrk() ) {
1566	>	//       if (abs(pf->GsfTrk()->DzCorrected(vtx)) > 0.2) continue;
1567	>	//       } else if( pf->HasTrackerTrk() ){
1568	>	//      if (abs(pf->TrackerTrk()->DzCorrected(vtx)) > 0.2) continue;
1569	>	//       }
1570	>
1571	>	// Veto any PFmuon, or PFEle
1572	>	if (abs(pf->PFType()) == PFCandidate::eElectron || abs(pf->PFType()) == PFCandidate::eMuon) continue;
1573	>
1574	>	// Footprint Veto
1575	>	if (fabs(ele->SCluster()->Eta()) > 1.479 && dr < 0.015) continue;
1576	>
1577	>	if( ctrl.debug) cout << "charged:: pt: " << pf->Pt()
1578	>	<< "\ttype: " << pf->PFType()
1579	>	<< "\ttrk: " << pf->TrackerTrk() << endl;
1580	>
1581	>	if (dr < 0.1) tmpChargedIso_DR0p0To0p1 += pf->Pt();
1582	>	if (dr >= 0.1 && dr < 0.2) tmpChargedIso_DR0p1To0p2 += pf->Pt();
1583	>	if (dr >= 0.2 && dr < 0.3) tmpChargedIso_DR0p2To0p3 += pf->Pt();
1584	>	if (dr >= 0.3 && dr < 0.4) tmpChargedIso_DR0p3To0p4 += pf->Pt();
1585	>	if (dr >= 0.4 && dr < 0.5) tmpChargedIso_DR0p4To0p5 += pf->Pt();
1586	>
1587	>	}
1588	>
1589	>	//
1590	>	// Gamma Iso Rings
1591	>	//
1592	>	else if (abs(pf->PFType()) == PFCandidate::eGamma) {
1593	>
1594	>	if (fabs(ele->SCluster()->Eta()) > 1.479 && dr < 0.08) continue;
1595	>
1596	>	if( ctrl.debug) cout << "gamma:: " << pf->Pt() << " "
1597	>	<< dr << endl;
1598	>
1599	>	if (dr < 0.1) tmpGammaIso_DR0p0To0p1 += pf->Pt();
1600	>	if (dr >= 0.1 && dr < 0.2) tmpGammaIso_DR0p1To0p2 += pf->Pt();
1601	>	if (dr >= 0.2 && dr < 0.3) tmpGammaIso_DR0p2To0p3 += pf->Pt();
1602	>	if (dr >= 0.3 && dr < 0.4) tmpGammaIso_DR0p3To0p4 += pf->Pt();
1603	>	if (dr >= 0.4 && dr < 0.5) tmpGammaIso_DR0p4To0p5 += pf->Pt();
1604	>	}
1605	>
1606	>	//
1607	>	// Other Neutral Iso Rings
1608	>	//
1609	>	else {
1610	>	if( ctrl.debug) cout << "neutral:: " << pf->Pt() << " "
1611	>	<< dr << endl;
1612	>	if (dr < 0.1) tmpNeutralHadronIso_DR0p0To0p1 += pf->Pt();
1613	>	if (dr >= 0.1 && dr < 0.2) tmpNeutralHadronIso_DR0p1To0p2 += pf->Pt();
1614	>	if (dr >= 0.2 && dr < 0.3) tmpNeutralHadronIso_DR0p2To0p3 += pf->Pt();
1615	>	if (dr >= 0.3 && dr < 0.4) tmpNeutralHadronIso_DR0p3To0p4 += pf->Pt();
1616	>	if (dr >= 0.4 && dr < 0.5) tmpNeutralHadronIso_DR0p4To0p5 += pf->Pt();
1617	>	}
1618	>
1619	>	}
1620	>
1621	>	}
1622	>
1623	>	fChargedIso_DR0p0To0p1   = fmin((tmpChargedIso_DR0p0To0p1)/ele->Pt(), 2.5);
1624	>	fChargedIso_DR0p1To0p2   = fmin((tmpChargedIso_DR0p1To0p2)/ele->Pt(), 2.5);
1625	>	fChargedIso_DR0p2To0p3   = fmin((tmpChargedIso_DR0p2To0p3)/ele->Pt(), 2.5);
1626	>	fChargedIso_DR0p3To0p4   = fmin((tmpChargedIso_DR0p3To0p4)/ele->Pt(), 2.5);
1627	>	fChargedIso_DR0p4To0p5   = fmin((tmpChargedIso_DR0p4To0p5)/ele->Pt(), 2.5);
1628	>
1629	>	if(ctrl.debug) {
1630	>	cout << "fChargedIso_DR0p0To0p1 : " << fChargedIso_DR0p0To0p1  << endl;
1631	>	cout << "fChargedIso_DR0p1To0p2 : " << fChargedIso_DR0p1To0p2  << endl;
1632	>	cout << "fChargedIso_DR0p2To0p3 : " << fChargedIso_DR0p2To0p3  << endl;
1633	>	cout << "fChargedIso_DR0p3To0p4 : " << fChargedIso_DR0p3To0p4  << endl;
1634	>	cout << "fChargedIso_DR0p4To0p5 : " << fChargedIso_DR0p4To0p5  << endl;
1635	>	}
1636	>
1637	>
1638	>	double rho = 0;
1639	>	if (!(isnan(fPUEnergyDensity->At(0)->Rho()) || isinf(fPUEnergyDensity->At(0)->Rho())))
1640	>	rho = fPUEnergyDensity->At(0)->Rho();
1641	>	//   if (!(isnan(fPUEnergyDensity->At(0)->RhoLowEta()) || isinf(fPUEnergyDensity->At(0)->RhoLowEta())))
1642	>	//     rho = fPUEnergyDensity->At(0)->RhoLowEta();
1643	>
1644	>	// WARNING!!!!
1645	>	// hardcode for sync ...
1646	>	EffectiveAreaVersion = eleT.kEleEAData2011;
1647	>	// WARNING!!!!
1648	>
1649	>	if( ctrl.debug) {
1650	>	cout << "RHO: " << rho << endl;
1651	>	cout << "eta: " << ele->SCluster()->Eta() << endl;
1652	>	cout << "target: " << EffectiveAreaVersion << endl;
1653	>	cout << "effA 0-1: " << eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p0To0p1,
1654	>	ele->SCluster()->Eta(),
1655	>	EffectiveAreaVersion)
1656	>	<< endl;
1657	>	cout << "effA 1-2: " << eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p1To0p2,
1658	>	ele->SCluster()->Eta(),
1659	>	EffectiveAreaVersion)
1660	>	<< endl;
1661	>	cout << "effA 2-3: " << eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p2To0p3,
1662	>	ele->SCluster()->Eta(),
1663	>	EffectiveAreaVersion)
1664	>	<< endl;
1665	>	cout << "effA 3-4: " << eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p3To0p4,
1666	>	ele->SCluster()->Eta(),
1667	>	EffectiveAreaVersion)
1668	>	<< endl;
1669	>	}
1670	>
1671	>	fGammaIso_DR0p0To0p1 = fmax(fmin((tmpGammaIso_DR0p0To0p1
1672	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaIsoDR0p0To0p1,
1673	>	ele->SCluster()->Eta(),
1674	>	EffectiveAreaVersion))/ele->Pt()
1675	>	,2.5)
1676	>	,0.0);
1677	>	fGammaIso_DR0p1To0p2 = fmax(fmin((tmpGammaIso_DR0p1To0p2
1678	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaIsoDR0p1To0p2,
1679	>	ele->SCluster()->Eta(),
1680	>	EffectiveAreaVersion))/ele->Pt()
1681	>	,2.5)
1682	>	,0.0);
1683	>	fGammaIso_DR0p2To0p3 = fmax(fmin((tmpGammaIso_DR0p2To0p3
1684	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaIsoDR0p2To0p3,
1685	>	ele->SCluster()->Eta()
1686	>	,EffectiveAreaVersion))/ele->Pt()
1687	>	,2.5)
1688	>	,0.0);
1689	>	fGammaIso_DR0p3To0p4 = fmax(fmin((tmpGammaIso_DR0p3To0p4
1690	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaIsoDR0p3To0p4,
1691	>	ele->SCluster()->Eta(),
1692	>	EffectiveAreaVersion))/ele->Pt()
1693	>	,2.5)
1694	>	,0.0);
1695	>	fGammaIso_DR0p4To0p5 = fmax(fmin((tmpGammaIso_DR0p4To0p5
1696	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaIsoDR0p4To0p5,
1697	>	ele->SCluster()->Eta(),
1698	>	EffectiveAreaVersion))/ele->Pt()
1699	>	,2.5)
1700	>	,0.0);
1701	>
1702	>
1703	>	if( ctrl.debug) {
1704	>	cout << "fGammaIso_DR0p0To0p1: " << fGammaIso_DR0p0To0p1 << endl;
1705	>	cout << "fGammaIso_DR0p1To0p2: " << fGammaIso_DR0p1To0p2 << endl;
1706	>	cout << "fGammaIso_DR0p2To0p3: " << fGammaIso_DR0p2To0p3 << endl;
1707	>	cout << "fGammaIso_DR0p3To0p4: " << fGammaIso_DR0p3To0p4 << endl;
1708	>	cout << "fGammaIso_DR0p4To0p5: " << fGammaIso_DR0p4To0p5 << endl;
1709	>	}
1710	>
1711	>	fNeutralHadronIso_DR0p0To0p1 = fmax(fmin((tmpNeutralHadronIso_DR0p0To0p1
1712	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p0To0p1,
1713	>	ele->SCluster()->Eta(),EffectiveAreaVersion))/ele->Pt()
1714	>	, 2.5)
1715	>	, 0.0);
1716	>	fNeutralHadronIso_DR0p1To0p2 = fmax(fmin((tmpNeutralHadronIso_DR0p1To0p2
1717	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p1To0p2,
1718	>	ele->SCluster()->Eta(),EffectiveAreaVersion))/ele->Pt()
1719	>	, 2.5)
1720	>	, 0.0);
1721	>	fNeutralHadronIso_DR0p2To0p3 = fmax(fmin((tmpNeutralHadronIso_DR0p2To0p3
1722	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p2To0p3,
1723	>	ele->SCluster()->Eta(),EffectiveAreaVersion))/ele->Pt()
1724	>	, 2.5)
1725	>	, 0.0);
1726	>	fNeutralHadronIso_DR0p3To0p4 = fmax(fmin((tmpNeutralHadronIso_DR0p3To0p4
1727	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p3To0p4,
1728	>	ele->SCluster()->Eta(), EffectiveAreaVersion))/ele->Pt()
1729	>	, 2.5)
1730	>	, 0.0);
1731	>	fNeutralHadronIso_DR0p4To0p5 = fmax(fmin((tmpNeutralHadronIso_DR0p4To0p5
1732	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p4To0p5,
1733	>	ele->SCluster()->Eta(), EffectiveAreaVersion))/ele->Pt()
1734	>	, 2.5)
1735	>	, 0.0);
1736	>
1737	>	if( ctrl.debug) {
1738	>	cout << "fNeutralHadronIso_DR0p0To0p1: " << fNeutralHadronIso_DR0p0To0p1 << endl;
1739	>	cout << "fNeutralHadronIso_DR0p1To0p2: " << fNeutralHadronIso_DR0p1To0p2 << endl;
1740	>	cout << "fNeutralHadronIso_DR0p2To0p3: " << fNeutralHadronIso_DR0p2To0p3 << endl;
1741	>	cout << "fNeutralHadronIso_DR0p3To0p4: " << fNeutralHadronIso_DR0p3To0p4 << endl;
1742	>	cout << "fNeutralHadronIso_DR0p4To0p5: " << fNeutralHadronIso_DR0p4To0p5 << endl;
1743	>	}
1744	>
1745	>	double mvaval = eleIsoMVA->MVAValue_IsoRings( ele->Pt(),
1746	>	ele->SCluster()->Eta(),
1747	>	fChargedIso_DR0p0To0p1,
1748	>	fChargedIso_DR0p1To0p2,
1749	>	fChargedIso_DR0p2To0p3,
1750	>	fChargedIso_DR0p3To0p4,
1751	>	fChargedIso_DR0p4To0p5,
1752	>	fGammaIso_DR0p0To0p1,
1753	>	fGammaIso_DR0p1To0p2,
1754	>	fGammaIso_DR0p2To0p3,
1755	>	fGammaIso_DR0p3To0p4,
1756	>	fGammaIso_DR0p4To0p5,
1757	>	fNeutralHadronIso_DR0p0To0p1,
1758	>	fNeutralHadronIso_DR0p1To0p2,
1759	>	fNeutralHadronIso_DR0p2To0p3,
1760	>	fNeutralHadronIso_DR0p3To0p4,
1761	>	fNeutralHadronIso_DR0p4To0p5,
1762	>	ctrl.debug);
1763	>
1764	>	SelectionStatus status;
1765	>	status.isoMVA = mvaval;
1766	>	bool pass = false;
1767	>
1768	>	Int_t subdet = 0;
1769	>	if (fabs(ele->SCluster()->Eta()) < 0.8) subdet = 0;
1770	>	else if (fabs(ele->SCluster()->Eta()) < 1.479) subdet = 1;
1771	>	else subdet = 2;
1772	>
1773	>	Int_t ptBin = 0;
1774	>	if (ele->Pt() >= 10.0) ptBin = 1;
1775	>
1776	>	Int_t MVABin = -1;
1777	>	if (subdet == 0 && ptBin == 0) MVABin = 0;
1778	>	if (subdet == 1 && ptBin == 0) MVABin = 1;
1779	>	if (subdet == 2 && ptBin == 0) MVABin = 2;
1780	>	if (subdet == 0 && ptBin == 1) MVABin = 3;
1781	>	if (subdet == 1 && ptBin == 1) MVABin = 4;
1782	>	if (subdet == 2 && ptBin == 1) MVABin = 5;
1783	>
1784	>	pass = false;
1785	>	if( MVABin == 0 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_OPT_BIN0 ) pass = true;
1786	>	if( MVABin == 1 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_OPT_BIN1 ) pass = true;
1787	>	if( MVABin == 2 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_OPT_BIN2 ) pass = true;
1788	>	if( MVABin == 3 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_OPT_BIN3 ) pass = true;
1789	>	if( MVABin == 4 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_OPT_BIN4 ) pass = true;
1790	>	if( MVABin == 5 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_OPT_BIN5 ) pass = true;
1791	>	//  pass &= (fChargedIso_DR0p0To0p1 + fChargedIso_DR0p1To0p2 + fChargedIso_DR0p2To0p3 < 0.7);
1792	>	if( pass ) status.orStatus(SelectionStatus::LOOSEISO);
1793	>
1794	>	//   pass = false;
1795	>	//   if( MVABin == 0 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN0 ) pass = true;
1796	>	//   if( MVABin == 1 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN1 ) pass = true;
1797	>	//   if( MVABin == 2 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN2 ) pass = true;
1798	>	//   if( MVABin == 3 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN3 ) pass = true;
1799	>	//   if( MVABin == 4 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN4 ) pass = true;
1800	>	//   if( MVABin == 5 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN5 ) pass = true;
1801	>	//   if( pass ) status.orStatus(SelectionStatus::TIGHTISO);
1802	>
1803	>	if(ctrl.debug) cout << "returning status : " << hex << status.getStatus() << dec << endl;
1804	>	return status;
1805	>
1806	>	}
1807	>
1808	>
1809	>	//--------------------------------------------------------------------------------------------------
1810	>	SelectionStatus electronIsoMVASelection(ControlFlags &ctrl,
1811	>	const mithep::Electron * ele,
1812	>	const mithep::Vertex * vtx,
1813	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
1814	>	float rho,
1815	>	//const mithep::Array<mithep::PileupEnergyDensity> * fPUEnergyDensity,
1816	>	mithep::ElectronTools::EElectronEffectiveAreaTarget EffectiveAreaVersion,
1817	>	vector<const mithep::Muon*> muonsToVeto,
1818	>	vector<const mithep::Electron*> electronsToVeto)
1819	>	//--------------------------------------------------------------------------------------------------
1820	>	// hacked version
1821	>	{
1822	>	if( ctrl.debug ) {
1823	>	cout << "================> hacked ele Iso MVA <======================" << endl;
1824	>	}
1825	>
1826	>	if( ctrl.debug ) {
1827	>	cout << "electronIsoMVASelection :: muons to veto " << endl;
1828	>	for( int i=0; i<muonsToVeto.size(); i++ ) {
1829	>	const mithep::Muon * vmu = muonsToVeto[i];
1830	>	cout << "\tpt: " << vmu->Pt()
1831	>	<< "\teta: " << vmu->Eta()
1832	>	<< "\tphi: " << vmu->Phi()
1833	>	<< endl;
1834	>	}
1835	>	cout << "electronIsoMVASelection :: electrson to veto " << endl;
1836	>	for( int i=0; i<electronsToVeto.size(); i++ ) {
1837	>	const mithep::Electron * vel = electronsToVeto[i];
1838	>	cout << "\tpt: " << vel->Pt()
1839	>	<< "\teta: " << vel->Eta()
1840	>	<< "\tphi: " << vel->Phi()
1841	>	<< "\ttrk: " << vel->TrackerTrk()
1842	>	<< endl;
1843	>	}
1844	>	}
1845	>
1846	>	bool failiso=false;
1847	>
1848	>	//
1849	>	// tmp iso rings
1850	>	//
1851	>	Double_t tmpChargedIso_DR0p0To0p1  = 0;
1852	>	Double_t tmpChargedIso_DR0p1To0p2  = 0;
1853	>	Double_t tmpChargedIso_DR0p2To0p3  = 0;
1854	>	Double_t tmpChargedIso_DR0p3To0p4  = 0;
1855	>	Double_t tmpChargedIso_DR0p4To0p5  = 0;
1856	>
1857	>	Double_t tmpGammaIso_DR0p0To0p1  = 0;
1858	>	Double_t tmpGammaIso_DR0p1To0p2  = 0;
1859	>	Double_t tmpGammaIso_DR0p2To0p3  = 0;
1860	>	Double_t tmpGammaIso_DR0p3To0p4  = 0;
1861	>	Double_t tmpGammaIso_DR0p4To0p5  = 0;
1862	>
1863	>
1864	>	Double_t tmpNeutralHadronIso_DR0p0To0p1  = 0;
1865	>	Double_t tmpNeutralHadronIso_DR0p1To0p2  = 0;
1866	>	Double_t tmpNeutralHadronIso_DR0p2To0p3  = 0;
1867	>	Double_t tmpNeutralHadronIso_DR0p3To0p4  = 0;
1868	>	Double_t tmpNeutralHadronIso_DR0p4To0p5  = 0;
1869	>
1870	>
1871	>
1872	>	//
1873	>	// final rings for the MVA
1874	>	//
1875	>	Double_t fChargedIso_DR0p0To0p1;
1876	>	Double_t fChargedIso_DR0p1To0p2;
1877	>	Double_t fChargedIso_DR0p2To0p3;
1878	>	Double_t fChargedIso_DR0p3To0p4;
1879	>	Double_t fChargedIso_DR0p4To0p5;
1880	>
1881	>	Double_t fGammaIso_DR0p0To0p1;
1882	>	Double_t fGammaIso_DR0p1To0p2;
1883	>	Double_t fGammaIso_DR0p2To0p3;
1884	>	Double_t fGammaIso_DR0p3To0p4;
1885	>	Double_t fGammaIso_DR0p4To0p5;
1886	>
1887	>	Double_t fNeutralHadronIso_DR0p0To0p1;
1888	>	Double_t fNeutralHadronIso_DR0p1To0p2;
1889	>	Double_t fNeutralHadronIso_DR0p2To0p3;
1890	>	Double_t fNeutralHadronIso_DR0p3To0p4;
1891	>	Double_t fNeutralHadronIso_DR0p4To0p5;
1892	>
1893	>
1894	>	//
1895	>	//Loop over PF Candidates
1896	>	//
1897	>	for(int k=0; k<fPFCandidates->GetEntries(); ++k) {
1898	>
1899	>	if( !(PFnoPUflag[k]) ) continue; // my PF no PU hack
1900	>
1901	>	const mithep::PFCandidate *pf = (mithep::PFCandidate*)((*fPFCandidates)[k]);
1902	>	Double_t deta = (ele->Eta() - pf->Eta());
1903	>	Double_t dphi = mithep::MathUtils::DeltaPhi(Double_t(ele->Phi()),Double_t(pf->Phi()));
1904	>	Double_t dr = mithep::MathUtils::DeltaR(ele->Phi(),ele->Eta(), pf->Phi(), pf->Eta());
1905	>	if (dr > 1.0) continue;
1906	>
1907	>	if(ctrl.debug) {
1908	>	cout << "pf :: type: " << pf->PFType() << "\tpt: " << pf->Pt();
1909	>	if( pf->HasTrackerTrk() ) cout << "\tdZ: " << pf->TrackerTrk()->DzCorrected(*vtx);
1910	>	cout << endl;
1911	>	}
1912	>
1913	>
1914	>	if ( (pf->HasTrackerTrk() && (pf->TrackerTrk() == ele->TrackerTrk())) ||
1915	>	(pf->HasGsfTrk() && (pf->GsfTrk() == ele->GsfTrk()))) continue;
1916	>
1917	>
1918	>	//
1919	>	// Lepton Footprint Removal
1920	>	//
1921	>	Bool_t IsLeptonFootprint = kFALSE;
1922	>	if (dr < 1.0) {
1923	>
1924	>
1925	>	//
1926	>	// Check for electrons
1927	>	//
1928	>
1929	>	for (Int_t q=0; q < electronsToVeto.size(); ++q) {
1930	>	const mithep::Electron *tmpele = electronsToVeto[q];
1931	>	double tmpdr = mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta());
1932	>
1933	>	// 4l electron
1934	>	if( pf->HasTrackerTrk()  ) {
1935	>	if( pf->TrackerTrk() == tmpele->TrackerTrk() ) {
1936	>	if( ctrl.debug) cout << "\tcharged tktrk, matches 4L ele ..." << endl;
1937	>	IsLeptonFootprint = kTRUE;
1938	>	}
1939	>	}
1940	>	if( pf->HasGsfTrk()  ) {
1941	>	if( pf->GsfTrk() == tmpele->GsfTrk() ) {
1942	>	if( ctrl.debug) cout << "\tcharged gsftrk, matches 4L ele ..." << endl;
1943	>	IsLeptonFootprint = kTRUE;
1944	>	}
1945	>	}
1946	>	// PF charged
1947	>	if (pf->Charge() != 0 && fabs(tmpele->SCluster()->Eta()) >= 1.479 && tmpdr < 0.015) {
1948	>	if( ctrl.debug) cout << "\tcharged trk, dR matches 4L ele ..." << endl;
1949	>	IsLeptonFootprint = kTRUE;
1950	>	}
1951	>	// PF gamma
1952	>	if (abs(pf->PFType()) == PFCandidate::eGamma && fabs(tmpele->SCluster()->Eta()) >= 1.479
1953	>	&& tmpdr < 0.08) {
1954	>	if( ctrl.debug) cout << "\tPF gamma, matches 4L ele ..." << endl;
1955	>	IsLeptonFootprint = kTRUE;
1956	>	}
1957	>	} // loop over electrons
1958	>
1959	>
1960	>	/* KH - comment for sync
1961	>	//
1962	>	// Check for muons
1963	>	//
1964	>	for (Int_t q=0; q < muonsToVeto.size(); ++q) {
1965	>	const mithep::Muon *tmpmu = muonsToVeto[q];
1966	>	// 4l muon
1967	>	if( pf->HasTrackerTrk() ) {
1968	>	if (pf->TrackerTrk() == tmpmu->TrackerTrk() ){
1969	>	if( ctrl.debug) cout << "\tmatches 4L mu ..." << endl;
1970	>	IsLeptonFootprint = kTRUE;
1971	>	}
1972	>	}
1973	>	// PF charged
1974	>	if (pf->Charge() != 0 && mithep::MathUtils::DeltaR(tmpmu->Phi(),tmpmu->Eta(), pf->Phi(), pf->Eta()) < 0.01) {
1975	>	if( ctrl.debug) cout << "\tcharged trk, dR matches 4L mu ..." << endl;
1976	>	IsLeptonFootprint = kTRUE;
1977	>	}
1978	>	} // loop over muons
1979	>	*/
1980	>
1981	>	if (IsLeptonFootprint)
1982	>	continue;
1983	>
1984	>	//
1985	>	// Charged Iso Rings
1986	>	//
1987	>	if (pf->Charge() != 0 && (pf->HasTrackerTrk()||pf->HasGsfTrk()) ) {
1988	>
1989	>	//       if( pf->HasGsfTrk() ) {
1990	>	//       if (abs(pf->GsfTrk()->DzCorrected(vtx)) > 0.2) continue;
1991	>	//       } else if( pf->HasTrackerTrk() ){
1992	>	//      if (abs(pf->TrackerTrk()->DzCorrected(vtx)) > 0.2) continue;
1993	>	//       }
1994	>
1995	>	// Veto any PFmuon, or PFEle
1996	>	if (abs(pf->PFType()) == PFCandidate::eElectron || abs(pf->PFType()) == PFCandidate::eMuon) continue;
1997	>
1998	>	// Footprint Veto
1999	>	if (fabs(ele->SCluster()->Eta()) > 1.479 && dr < 0.015) continue;
2000	>
2001	>	if( ctrl.debug) cout << "charged:: pt: " << pf->Pt()
2002	>	<< "\ttype: " << pf->PFType()
2003	>	<< "\ttrk: " << pf->TrackerTrk() << endl;
2004	>
2005	>	if (dr < 0.1) tmpChargedIso_DR0p0To0p1 += pf->Pt();
2006	>	if (dr >= 0.1 && dr < 0.2) tmpChargedIso_DR0p1To0p2 += pf->Pt();
2007	>	if (dr >= 0.2 && dr < 0.3) tmpChargedIso_DR0p2To0p3 += pf->Pt();
2008	>	if (dr >= 0.3 && dr < 0.4) tmpChargedIso_DR0p3To0p4 += pf->Pt();
2009	>	if (dr >= 0.4 && dr < 0.5) tmpChargedIso_DR0p4To0p5 += pf->Pt();
2010	>
2011	>	}
2012	>
2013	>	//
2014	>	// Gamma Iso Rings
2015	>	//
2016	>	else if (abs(pf->PFType()) == PFCandidate::eGamma) {
2017	>
2018	>	if (fabs(ele->SCluster()->Eta()) > 1.479 && dr < 0.08) continue;
2019	>
2020	>	if( ctrl.debug) cout << "gamma:: " << pf->Pt() << " "
2021	>	<< dr << endl;
2022	>
2023	>	if (dr < 0.1) tmpGammaIso_DR0p0To0p1 += pf->Pt();
2024	>	if (dr >= 0.1 && dr < 0.2) tmpGammaIso_DR0p1To0p2 += pf->Pt();
2025	>	if (dr >= 0.2 && dr < 0.3) tmpGammaIso_DR0p2To0p3 += pf->Pt();
2026	>	if (dr >= 0.3 && dr < 0.4) tmpGammaIso_DR0p3To0p4 += pf->Pt();
2027	>	if (dr >= 0.4 && dr < 0.5) tmpGammaIso_DR0p4To0p5 += pf->Pt();
2028	>	}
2029	>
2030	>	//
2031	>	// Other Neutral Iso Rings
2032	>	//
2033	>	else {
2034	>	if( ctrl.debug) cout << "neutral:: " << pf->Pt() << " "
2035	>	<< dr << endl;
2036	>	if (dr < 0.1) tmpNeutralHadronIso_DR0p0To0p1 += pf->Pt();
2037	>	if (dr >= 0.1 && dr < 0.2) tmpNeutralHadronIso_DR0p1To0p2 += pf->Pt();
2038	>	if (dr >= 0.2 && dr < 0.3) tmpNeutralHadronIso_DR0p2To0p3 += pf->Pt();
2039	>	if (dr >= 0.3 && dr < 0.4) tmpNeutralHadronIso_DR0p3To0p4 += pf->Pt();
2040	>	if (dr >= 0.4 && dr < 0.5) tmpNeutralHadronIso_DR0p4To0p5 += pf->Pt();
2041	>	}
2042	>
2043	>	}
2044	>
2045	>	}
2046	>
2047	>	fChargedIso_DR0p0To0p1   = fmin((tmpChargedIso_DR0p0To0p1)/ele->Pt(), 2.5);
2048	>	fChargedIso_DR0p1To0p2   = fmin((tmpChargedIso_DR0p1To0p2)/ele->Pt(), 2.5);
2049	>	fChargedIso_DR0p2To0p3   = fmin((tmpChargedIso_DR0p2To0p3)/ele->Pt(), 2.5);
2050	>	fChargedIso_DR0p3To0p4   = fmin((tmpChargedIso_DR0p3To0p4)/ele->Pt(), 2.5);
2051	>	fChargedIso_DR0p4To0p5   = fmin((tmpChargedIso_DR0p4To0p5)/ele->Pt(), 2.5);
2052	>
2053	>	if(ctrl.debug) {
2054	>	cout << "fChargedIso_DR0p0To0p1 : " << fChargedIso_DR0p0To0p1  << endl;
2055	>	cout << "fChargedIso_DR0p1To0p2 : " << fChargedIso_DR0p1To0p2  << endl;
2056	>	cout << "fChargedIso_DR0p2To0p3 : " << fChargedIso_DR0p2To0p3  << endl;
2057	>	cout << "fChargedIso_DR0p3To0p4 : " << fChargedIso_DR0p3To0p4  << endl;
2058	>	cout << "fChargedIso_DR0p4To0p5 : " << fChargedIso_DR0p4To0p5  << endl;
2059	>	}
2060	>
2061	>
2062	>	//  rho=0;
2063	>	//  double rho = 0;
2064	>	//   if (!(isnan(fPUEnergyDensity->At(0)->Rho()) || isinf(fPUEnergyDensity->At(0)->Rho())))
2065	>	//     rho = fPUEnergyDensity->At(0)->Rho();
2066	>	//   if (!(isnan(fPUEnergyDensity->At(0)->RhoLowEta()) || isinf(fPUEnergyDensity->At(0)->RhoLowEta())))
2067	>	//     rho = fPUEnergyDensity->At(0)->RhoLowEta();
2068	>
2069	>	// WARNING!!!!
2070	>	// hardcode for sync ...
2071	>	EffectiveAreaVersion = eleT.kEleEAData2011;
2072	>	// WARNING!!!!
2073	>
2074	>	if( ctrl.debug) {
2075	>	cout << "RHO: " << rho << endl;
2076	>	cout << "eta: " << ele->SCluster()->Eta() << endl;
2077	>	cout << "target: " << EffectiveAreaVersion << endl;
2078	>	cout << "effA 0-1: " << eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p0To0p1,
2079	>	ele->SCluster()->Eta(),
2080	>	EffectiveAreaVersion)
2081	>	<< endl;
2082	>	cout << "effA 1-2: " << eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p1To0p2,
2083	>	ele->SCluster()->Eta(),
2084	>	EffectiveAreaVersion)
2085	>	<< endl;
2086	>	cout << "effA 2-3: " << eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p2To0p3,
2087	>	ele->SCluster()->Eta(),
2088	>	EffectiveAreaVersion)
2089	>	<< endl;
2090	>	cout << "effA 3-4: " << eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p3To0p4,
2091	>	ele->SCluster()->Eta(),
2092	>	EffectiveAreaVersion)
2093	>	<< endl;
2094	>	}
2095	>
2096	>	fGammaIso_DR0p0To0p1 = fmax(fmin((tmpGammaIso_DR0p0To0p1
2097	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaIsoDR0p0To0p1,
2098	>	ele->SCluster()->Eta(),
2099	>	EffectiveAreaVersion))/ele->Pt()
2100	>	,2.5)
2101	>	,0.0);
2102	>	fGammaIso_DR0p1To0p2 = fmax(fmin((tmpGammaIso_DR0p1To0p2
2103	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaIsoDR0p1To0p2,
2104	>	ele->SCluster()->Eta(),
2105	>	EffectiveAreaVersion))/ele->Pt()
2106	>	,2.5)
2107	>	,0.0);
2108	>	fGammaIso_DR0p2To0p3 = fmax(fmin((tmpGammaIso_DR0p2To0p3
2109	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaIsoDR0p2To0p3,
2110	>	ele->SCluster()->Eta()
2111	>	,EffectiveAreaVersion))/ele->Pt()
2112	>	,2.5)
2113	>	,0.0);
2114	>	fGammaIso_DR0p3To0p4 = fmax(fmin((tmpGammaIso_DR0p3To0p4
2115	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaIsoDR0p3To0p4,
2116	>	ele->SCluster()->Eta(),
2117	>	EffectiveAreaVersion))/ele->Pt()
2118	>	,2.5)
2119	>	,0.0);
2120	>	fGammaIso_DR0p4To0p5 = fmax(fmin((tmpGammaIso_DR0p4To0p5
2121	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaIsoDR0p4To0p5,
2122	>	ele->SCluster()->Eta(),
2123	>	EffectiveAreaVersion))/ele->Pt()
2124	>	,2.5)
2125	>	,0.0);
2126	>
2127	>
2128	>	if( ctrl.debug) {
2129	>	cout << "fGammaIso_DR0p0To0p1: " << fGammaIso_DR0p0To0p1 << endl;
2130	>	cout << "fGammaIso_DR0p1To0p2: " << fGammaIso_DR0p1To0p2 << endl;
2131	>	cout << "fGammaIso_DR0p2To0p3: " << fGammaIso_DR0p2To0p3 << endl;
2132	>	cout << "fGammaIso_DR0p3To0p4: " << fGammaIso_DR0p3To0p4 << endl;
2133	>	cout << "fGammaIso_DR0p4To0p5: " << fGammaIso_DR0p4To0p5 << endl;
2134	>	}
2135	>
2136	>	fNeutralHadronIso_DR0p0To0p1 = fmax(fmin((tmpNeutralHadronIso_DR0p0To0p1
2137	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p0To0p1,
2138	>	ele->SCluster()->Eta(),EffectiveAreaVersion))/ele->Pt()
2139	>	, 2.5)
2140	>	, 0.0);
2141	>	fNeutralHadronIso_DR0p1To0p2 = fmax(fmin((tmpNeutralHadronIso_DR0p1To0p2
2142	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p1To0p2,
2143	>	ele->SCluster()->Eta(),EffectiveAreaVersion))/ele->Pt()
2144	>	, 2.5)
2145	>	, 0.0);
2146	>	fNeutralHadronIso_DR0p2To0p3 = fmax(fmin((tmpNeutralHadronIso_DR0p2To0p3
2147	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p2To0p3,
2148	>	ele->SCluster()->Eta(),EffectiveAreaVersion))/ele->Pt()
2149	>	, 2.5)
2150	>	, 0.0);
2151	>	fNeutralHadronIso_DR0p3To0p4 = fmax(fmin((tmpNeutralHadronIso_DR0p3To0p4
2152	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p3To0p4,
2153	>	ele->SCluster()->Eta(), EffectiveAreaVersion))/ele->Pt()
2154	>	, 2.5)
2155	>	, 0.0);
2156	>	fNeutralHadronIso_DR0p4To0p5 = fmax(fmin((tmpNeutralHadronIso_DR0p4To0p5
2157	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleNeutralHadronIsoDR0p4To0p5,
2158	>	ele->SCluster()->Eta(), EffectiveAreaVersion))/ele->Pt()
2159	>	, 2.5)
2160	>	, 0.0);
2161	>
2162	>	if( ctrl.debug) {
2163	>	cout << "fNeutralHadronIso_DR0p0To0p1: " << fNeutralHadronIso_DR0p0To0p1 << endl;
2164	>	cout << "fNeutralHadronIso_DR0p1To0p2: " << fNeutralHadronIso_DR0p1To0p2 << endl;
2165	>	cout << "fNeutralHadronIso_DR0p2To0p3: " << fNeutralHadronIso_DR0p2To0p3 << endl;
2166	>	cout << "fNeutralHadronIso_DR0p3To0p4: " << fNeutralHadronIso_DR0p3To0p4 << endl;
2167	>	cout << "fNeutralHadronIso_DR0p4To0p5: " << fNeutralHadronIso_DR0p4To0p5 << endl;
2168	>	}
2169	>
2170	>	double mvaval = eleIsoMVA->MVAValue_IsoRings( ele->Pt(),
2171	>	ele->SCluster()->Eta(),
2172	>	fChargedIso_DR0p0To0p1,
2173	>	fChargedIso_DR0p1To0p2,
2174	>	fChargedIso_DR0p2To0p3,
2175	>	fChargedIso_DR0p3To0p4,
2176	>	fChargedIso_DR0p4To0p5,
2177	>	fGammaIso_DR0p0To0p1,
2178	>	fGammaIso_DR0p1To0p2,
2179	>	fGammaIso_DR0p2To0p3,
2180	>	fGammaIso_DR0p3To0p4,
2181	>	fGammaIso_DR0p4To0p5,
2182	>	fNeutralHadronIso_DR0p0To0p1,
2183	>	fNeutralHadronIso_DR0p1To0p2,
2184	>	fNeutralHadronIso_DR0p2To0p3,
2185	>	fNeutralHadronIso_DR0p3To0p4,
2186	>	fNeutralHadronIso_DR0p4To0p5,
2187	>	ctrl.debug);
2188	>
2189	>	SelectionStatus status;
2190	>	status.isoMVA = mvaval;
2191	>	bool pass = false;
2192	>
2193	>	Int_t subdet = 0;
2194	>	if (fabs(ele->SCluster()->Eta()) < 0.8) subdet = 0;
2195	>	else if (fabs(ele->SCluster()->Eta()) < 1.479) subdet = 1;
2196	>	else subdet = 2;
2197	>
2198	>	Int_t ptBin = 0;
2199	>	if (ele->Pt() >= 10.0) ptBin = 1;
2200	>
2201	>	Int_t MVABin = -1;
2202	>	if (subdet == 0 && ptBin == 0) MVABin = 0;
2203	>	if (subdet == 1 && ptBin == 0) MVABin = 1;
2204	>	if (subdet == 2 && ptBin == 0) MVABin = 2;
2205	>	if (subdet == 0 && ptBin == 1) MVABin = 3;
2206	>	if (subdet == 1 && ptBin == 1) MVABin = 4;
2207	>	if (subdet == 2 && ptBin == 1) MVABin = 5;
2208	>
2209	>	pass = false;
2210	>	if( MVABin == 0 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_BIN0 ) pass = true;
2211	>	if( MVABin == 1 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_BIN1 ) pass = true;
2212	>	if( MVABin == 2 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_BIN2 ) pass = true;
2213	>	if( MVABin == 3 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_BIN3 ) pass = true;
2214	>	if( MVABin == 4 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_BIN4 ) pass = true;
2215	>	if( MVABin == 5 && mvaval > ELECTRON_LOOSE_ISOMVA_CUT_BIN5 ) pass = true;
2216	>	if( pass ) status.orStatus(SelectionStatus::LOOSEISO);
2217	>
2218	>	//   pass = false;
2219	>	//   if( MVABin == 0 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN0 ) pass = true;
2220	>	//   if( MVABin == 1 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN1 ) pass = true;
2221	>	//   if( MVABin == 2 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN2 ) pass = true;
2222	>	//   if( MVABin == 3 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN3 ) pass = true;
2223	>	//   if( MVABin == 4 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN4 ) pass = true;
2224	>	//   if( MVABin == 5 && mvaval > ELECTRON_TIGHT_ISOMVA_CUT_BIN5 ) pass = true;
2225	>	//   if( pass ) status.orStatus(SelectionStatus::TIGHTISO);
2226	>
2227	>	if(ctrl.debug) cout << "returning status : " << hex << status.getStatus() << dec << endl;
2228	>	return status;
2229	>
2230	>	}
2231	>
2232	>
2233	>	//--------------------------------------------------------------------------------------------------
2234	>	void initElectronIsoMVA() {
2235	>	//--------------------------------------------------------------------------------------------------
2236	>	eleIsoMVA = new mithep::ElectronIDMVA();
2237	>	vector<string> weightFiles;
2238	>	weightFiles.push_back("../MitPhysics/data/ElectronMVAWeights/ElectronIso_BDTG_V0_BarrelPt5To10.weights.xml");
2239	>	weightFiles.push_back("../MitPhysics/data/ElectronMVAWeights/ElectronIso_BDTG_V0_EndcapPt5To10.weights.xml");
2240	>	weightFiles.push_back("../MitPhysics/data/ElectronMVAWeights/ElectronIso_BDTG_V0_BarrelPt10ToInf.weights.xml");
2241	>	weightFiles.push_back("../MitPhysics/data/ElectronMVAWeights/ElectronIso_BDTG_V0_EndcapPt10ToInf.weights.xml");
2242	>	eleIsoMVA->Initialize( "ElectronIsoMVA",
2243	>	mithep::ElectronIDMVA::kIsoRingsV0,
2244	>	kTRUE, weightFiles);
2245	>	}
2246	>
2247	>
2248	>
2249	>
2250	>	//--------------------------------------------------------------------------------------------------
2251	>	// hacked version
2252	>	float electronPFIso04(ControlFlags &ctrl,
2253	>	const mithep::Electron * ele,
2254	>	const mithep::Vertex * vtx,
2255	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
2256	>	const mithep::Array<mithep::PileupEnergyDensity> * fPUEnergyDensity,
2257	>	mithep::ElectronTools::EElectronEffectiveAreaTarget EffectiveAreaVersion,
2258	>	vector<const mithep::Muon*> muonsToVeto,
2259	>	vector<const mithep::Electron*> electronsToVeto)
2260	>	//--------------------------------------------------------------------------------------------------
2261	>	{
2262	>	/*
2263	>	if( ctrl.debug ) {
2264	>	cout << "electronIsoMVASelection :: muons to veto " << endl;
2265	>	for( int i=0; i<muonsToVeto.size(); i++ ) {
2266	>	const mithep::Muon * vmu = muonsToVeto[i];
2267	>	cout << "\tpt: " << vmu->Pt()
2268	>	<< "\teta: " << vmu->Eta()
2269	>	<< "\tphi: " << vmu->Phi()
2270	>	<< endl;
2271	>	}
2272	>	cout << "electronIsoMVASelection :: electrons to veto " << endl;
2273	>	for( int i=0; i<electronsToVeto.size(); i++ ) {
2274	>	const mithep::Electron * vel = electronsToVeto[i];
2275	>	cout << "\tpt: " << vel->Pt()
2276	>	<< "\teta: " << vel->Eta()
2277	>	<< "\tphi: " << vel->Phi()
2278	>	<< "\ttrk: " << vel->TrackerTrk()
2279	>	<< endl;
2280	>	}
2281	>	}
2282	>	*/
2283	>
2284	>	//
2285	>	// final iso
2286	>	//
2287	>	Double_t fChargedIso = 0.0;
2288	>	Double_t fGammaIso = 0.0;
2289	>	Double_t fNeutralHadronIso = 0.0;
2290	>
2291	>
2292	>	//
2293	>	//Loop over PF Candidates
2294	>	//
2295	>	for(int k=0; k<fPFCandidates->GetEntries(); ++k) {
2296	>
2297	>
2298	>	const mithep::PFCandidate *pf = (mithep::PFCandidate*)((*fPFCandidates)[k]);
2299	>	Double_t deta = (ele->Eta() - pf->Eta());
2300	>	Double_t dphi = mithep::MathUtils::DeltaPhi(Double_t(ele->Phi()),Double_t(pf->Phi()));
2301	>	Double_t dr = mithep::MathUtils::DeltaR(ele->Phi(),ele->Eta(), pf->Phi(), pf->Eta());
2302	>
2303	>	if (dr > 0.4) continue;
2304	>	if( !(PFnoPUflag[k]) ) continue; // my PF no PU hack
2305	>
2306	>	if(ctrl.debug) {
2307	>	cout << "pf :: type: " << pf->PFType() << "\tpt: " << pf->Pt() << "\tdR: " << dr;
2308	>	if( pf->HasTrackerTrk() ) cout << "\tdZ: " << pf->TrackerTrk()->DzCorrected(*vtx)
2309	>	<< "\ttrk: " << pf->HasTrackerTrk()
2310	>	<< "\tgsf: " << pf->HasGsfTrk();
2311	>
2312	>	cout << endl;
2313	>	}
2314	>
2315	>
2316	>	//
2317	>	// sync : I don't think theyre doing this ...
2318	>	//
2319	>	//     if ( (pf->HasTrackerTrk() && (pf->TrackerTrk() == ele->TrackerTrk())) ||
2320	>	//   (pf->HasGsfTrk() && (pf->GsfTrk() == ele->GsfTrk()))) {
2321	>	//       if( ctrl.debug ) cout << "\tskipping, matches to the electron ..."  << endl;
2322	>	//       continue;
2323	>	//     }
2324	>
2325	>
2326	>	//
2327	>	// Lepton Footprint Removal
2328	>	//
2329	>	Bool_t IsLeptonFootprint = kFALSE;
2330	>	if (dr < 1.0) {
2331	>
2332	>	//
2333	>	// Check for electrons
2334	>	//
2335	>	for (Int_t q=0; q < electronsToVeto.size(); ++q) {
2336	>	const mithep::Electron *tmpele = electronsToVeto[q];
2337	>	/*
2338	>	// 4l electron
2339	>	if( pf->HasTrackerTrk()  ) {
2340	>	if( pf->TrackerTrk() == tmpele->TrackerTrk() ) {
2341	>	if( ctrl.debug) cout << "\tcharged tktrk, matches 4L ele ..." << endl;
2342	>	IsLeptonFootprint = kTRUE;
2343	>	}
2344	>	}
2345	>	if( pf->HasGsfTrk()  ) {
2346	>	if( pf->GsfTrk() == tmpele->GsfTrk() ) {
2347	>	if( ctrl.debug) cout << "\tcharged gsftrk, matches 4L ele ..." << endl;
2348	>	IsLeptonFootprint = kTRUE;
2349	>	}
2350	>	}
2351	>	*/
2352	>	// PF charged
2353	>	if (pf->Charge() != 0 && fabs(tmpele->SCluster()->Eta()) > 1.479
2354	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.015) {
2355	>	if( ctrl.debug) cout << "\tcharged trk, dR matches 4L ele ..." << endl;
2356	>	IsLeptonFootprint = kTRUE;
2357	>	}
2358	>	// PF gamma
2359	>	if (abs(pf->PFType()) == PFCandidate::eGamma && fabs(tmpele->SCluster()->Eta()) > 1.479
2360	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.08) {
2361	>	if( ctrl.debug) cout << "\tPF gamma, matches 4L ele ..." << endl;
2362	>	IsLeptonFootprint = kTRUE;
2363	>	}
2364	>	} // loop over electrons
2365	>
2366	>	/* KH - comment for sync
2367	>	//
2368	>	// Check for muons
2369	>	//
2370	>	for (Int_t q=0; q < muonsToVeto.size(); ++q) {
2371	>	const mithep::Muon *tmpmu = muonsToVeto[q];
2372	>	// 4l muon
2373	>	if( pf->HasTrackerTrk() ) {
2374	>	if (pf->TrackerTrk() == tmpmu->TrackerTrk() ){
2375	>	if( ctrl.debug) cout << "\tmatches 4L mu ..." << endl;
2376	>	IsLeptonFootprint = kTRUE;
2377	>	}
2378	>	}
2379	>	// PF charged
2380	>	if (pf->Charge() != 0 && mithep::MathUtils::DeltaR(tmpmu->Phi(),tmpmu->Eta(), pf->Phi(), pf->Eta()) < 0.01) {
2381	>	if( ctrl.debug) cout << "\tcharged trk, dR matches 4L mu ..." << endl;
2382	>	IsLeptonFootprint = kTRUE;
2383	>	}
2384	>	} // loop over muons
2385	>	*/
2386	>
2387	>	if (IsLeptonFootprint)
2388	>	continue;
2389	>
2390	>	//
2391	>	// Charged Iso
2392	>	//
2393	>	if (pf->Charge() != 0 && (pf->HasTrackerTrk()||pf->HasGsfTrk()) ) {
2394	>
2395	>	//       if( pf->HasTrackerTrk() )
2396	>	//      if (abs(pf->TrackerTrk()->DzCorrected(vtx)) > 0.2) continue;
2397	>	//       if( pf->HasGsfTrk() )
2398	>	//      if (abs(pf->GsfTrk()->DzCorrected(vtx)) > 0.2) continue;
2399	>
2400	>	// Veto any PFmuon, or PFEle
2401	>	if (abs(pf->PFType()) == PFCandidate::eElectron || abs(pf->PFType()) == PFCandidate::eMuon) {
2402	>	cout << "\t skipping, pf is and ele or mu .." <<endl;
2403	>	continue;
2404	>	}
2405	>
2406	>	// Footprint Veto
2407	>	if (fabs(ele->SCluster()->Eta()) > 1.479 && dr < 0.015) continue;
2408	>
2409	>	if( ctrl.debug) cout << "charged:: pt: " << pf->Pt()
2410	>	<< "\ttype: " << pf->PFType()
2411	>	<< "\ttrk: " << pf->TrackerTrk() << endl;
2412	>
2413	>	fChargedIso += pf->Pt();
2414	>	}
2415	>
2416	>	//
2417	>	// Gamma Iso
2418	>	//
2419	>	else if (abs(pf->PFType()) == PFCandidate::eGamma) {
2420	>
2421	>	if (fabs(ele->SCluster()->Eta()) > 1.479) {
2422	>	if (mithep::MathUtils::DeltaR(ele->Phi(),ele->Eta(), pf->Phi(), pf->Eta()) < 0.08) continue;
2423	>	}
2424	>	if( ctrl.debug) cout << "gamma:: " << pf->Pt() << " "
2425	>	<< dr << endl;
2426	>	// KH, add to sync
2427	>	//      if( pf->Pt() > 0.5 )
2428	>	fGammaIso += pf->Pt();
2429	>	}
2430	>
2431	>	//
2432	>	// Neutral Iso
2433	>	//
2434	>	else {
2435	>	if( ctrl.debug) cout << "neutral:: " << pf->Pt() << " "
2436	>	<< dr << endl;
2437	>	// KH, add to sync
2438	>	//      if( pf->Pt() > 0.5 )
2439	>	fNeutralHadronIso += pf->Pt();
2440	>	}
2441	>
2442	>	}
2443	>
2444	>	}
2445	>
2446	>
2447	>	double rho=0;
2448	>	if (!(isnan(fPUEnergyDensity->At(0)->Rho()) || isinf(fPUEnergyDensity->At(0)->Rho())))
2449	>	rho = fPUEnergyDensity->At(0)->Rho();
2450	>
2451	>	// WARNING!!!!
2452	>	// hardcode for sync ...
2453	>	EffectiveAreaVersion = eleT.kEleEAData2011;
2454	>	// WARNING!!!!
2455	>
2456	>
2457	>	double pfIso = fChargedIso + fmax(0.0,(fGammaIso + fNeutralHadronIso
2458	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaAndNeutralHadronIso04,
2459	>	ele->Eta(),EffectiveAreaVersion)));
2460	>
2461	>
2462	>	gChargedIso = fChargedIso;
2463	>	gGammaIso = fGammaIso;
2464	>	gNeutralIso = fNeutralHadronIso;
2465	>	return pfIso;
2466	>	}
2467	>
2468	>
2469	>
2470	>	//--------------------------------------------------------------------------------------------------
2471	>	// hacked version
2472	>	float electronPFIso04(ControlFlags &ctrl,
2473	>	const mithep::Electron * ele,
2474	>	const mithep::Vertex * vtx,
2475	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
2476	>	float rho,
2477	>	mithep::ElectronTools::EElectronEffectiveAreaTarget EffectiveAreaVersion,
2478	>	vector<const mithep::Muon*> muonsToVeto,
2479	>	vector<const mithep::Electron*> electronsToVeto)
2480	>	//--------------------------------------------------------------------------------------------------
2481	>	{
2482	>
2483	>	if( ctrl.debug ) {
2484	>	cout << "electronIsoMVASelection :: muons to veto " << endl;
2485	>	for( int i=0; i<muonsToVeto.size(); i++ ) {
2486	>	const mithep::Muon * vmu = muonsToVeto[i];
2487	>	cout << "\tpt: " << vmu->Pt()
2488	>	<< "\teta: " << vmu->Eta()
2489	>	<< "\tphi: " << vmu->Phi()
2490	>	<< endl;
2491	>	}
2492	>	cout << "electronIsoMVASelection :: electrons to veto " << endl;
2493	>	for( int i=0; i<electronsToVeto.size(); i++ ) {
2494	>	const mithep::Electron * vel = electronsToVeto[i];
2495	>	cout << "\tpt: " << vel->Pt()
2496	>	<< "\teta: " << vel->Eta()
2497	>	<< "\tphi: " << vel->Phi()
2498	>	<< "\ttrk: " << vel->TrackerTrk()
2499	>	<< endl;
2500	>	}
2501	>	}
2502	>
2503	>
2504	>	//
2505	>	// final iso
2506	>	//
2507	>	Double_t fChargedIso = 0.0;
2508	>	Double_t fGammaIso = 0.0;
2509	>	Double_t fNeutralHadronIso = 0.0;
2510	>
2511	>
2512	>	//
2513	>	//Loop over PF Candidates
2514	>	//
2515	>	for(int k=0; k<fPFCandidates->GetEntries(); ++k) {
2516	>
2517	>
2518	>	const mithep::PFCandidate *pf = (mithep::PFCandidate*)((*fPFCandidates)[k]);
2519	>	Double_t deta = (ele->Eta() - pf->Eta());
2520	>	Double_t dphi = mithep::MathUtils::DeltaPhi(Double_t(ele->Phi()),Double_t(pf->Phi()));
2521	>	Double_t dr = mithep::MathUtils::DeltaR(ele->Phi(),ele->Eta(), pf->Phi(), pf->Eta());
2522	>
2523	>	if (dr > 0.4) continue;
2524	>	if( !(PFnoPUflag[k]) ) continue; // my PF no PU hack
2525	>
2526	>	if(ctrl.debug) {
2527	>	cout << "pf :: type: " << pf->PFType() << "\tpt: " << pf->Pt() << "\tdR: " << dr;
2528	>	if( pf->HasTrackerTrk() ) cout << "\tdZ: " << pf->TrackerTrk()->DzCorrected(*vtx)
2529	>	<< "\ttrk: " << pf->HasTrackerTrk()
2530	>	<< "\tgsf: " << pf->HasGsfTrk();
2531	>
2532	>	cout << endl;
2533	>	}
2534	>
2535	>
2536	>	//
2537	>	// sync : I don't think theyre doing this ...
2538	>	//
2539	>	//     if ( (pf->HasTrackerTrk() && (pf->TrackerTrk() == ele->TrackerTrk())) ||
2540	>	//   (pf->HasGsfTrk() && (pf->GsfTrk() == ele->GsfTrk()))) {
2541	>	//       if( ctrl.debug ) cout << "\tskipping, matches to the electron ..."  << endl;
2542	>	//       continue;
2543	>	//     }
2544	>
2545	>
2546	>	//
2547	>	// Lepton Footprint Removal
2548	>	//
2549	>	Bool_t IsLeptonFootprint = kFALSE;
2550	>	if (dr < 1.0) {
2551	>
2552	>	//
2553	>	// Check for electrons
2554	>	//
2555	>	for (Int_t q=0; q < electronsToVeto.size(); ++q) {
2556	>	const mithep::Electron *tmpele = electronsToVeto[q];
2557	>	/*
2558	>	// 4l electron
2559	>	if( pf->HasTrackerTrk()  ) {
2560	>	if( pf->TrackerTrk() == tmpele->TrackerTrk() ) {
2561	>	if( ctrl.debug) cout << "\tcharged tktrk, matches 4L ele ..." << endl;
2562	>	IsLeptonFootprint = kTRUE;
2563	>	}
2564	>	}
2565	>	if( pf->HasGsfTrk()  ) {
2566	>	if( pf->GsfTrk() == tmpele->GsfTrk() ) {
2567	>	if( ctrl.debug) cout << "\tcharged gsftrk, matches 4L ele ..." << endl;
2568	>	IsLeptonFootprint = kTRUE;
2569	>	}
2570	>	}
2571	>	*/
2572	>	// PF charged
2573	>	if (pf->Charge() != 0 && fabs(tmpele->SCluster()->Eta()) > 1.479
2574	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.015) {
2575	>	if( ctrl.debug) cout << "\tcharged trk, dR matches 4L ele ..." << endl;
2576	>	IsLeptonFootprint = kTRUE;
2577	>	}
2578	>	// PF gamma
2579	>	if (abs(pf->PFType()) == PFCandidate::eGamma && fabs(tmpele->SCluster()->Eta()) > 1.479
2580	>	&& mithep::MathUtils::DeltaR(tmpele->Phi(),tmpele->Eta(), pf->Phi(), pf->Eta()) < 0.08) {
2581	>	if( ctrl.debug) cout << "\tPF gamma, matches 4L ele ..." << endl;
2582	>	IsLeptonFootprint = kTRUE;
2583	>	}
2584	>	} // loop over electrons
2585	>
2586	>	/* KH - comment for sync
2587	>	//
2588	>	// Check for muons
2589	>	//
2590	>	for (Int_t q=0; q < muonsToVeto.size(); ++q) {
2591	>	const mithep::Muon *tmpmu = muonsToVeto[q];
2592	>	// 4l muon
2593	>	if( pf->HasTrackerTrk() ) {
2594	>	if (pf->TrackerTrk() == tmpmu->TrackerTrk() ){
2595	>	if( ctrl.debug) cout << "\tmatches 4L mu ..." << endl;
2596	>	IsLeptonFootprint = kTRUE;
2597	>	}
2598	>	}
2599	>	// PF charged
2600	>	if (pf->Charge() != 0 && mithep::MathUtils::DeltaR(tmpmu->Phi(),tmpmu->Eta(), pf->Phi(), pf->Eta()) < 0.01) {
2601	>	if( ctrl.debug) cout << "\tcharged trk, dR matches 4L mu ..." << endl;
2602	>	IsLeptonFootprint = kTRUE;
2603	>	}
2604	>	} // loop over muons
2605	>	*/
2606	>
2607	>	if (IsLeptonFootprint)
2608	>	continue;
2609	>
2610	>	//
2611	>	// Charged Iso
2612	>	//
2613	>	if (pf->Charge() != 0 && (pf->HasTrackerTrk()||pf->HasGsfTrk()) ) {
2614	>
2615	>	//       if( pf->HasTrackerTrk() )
2616	>	//      if (abs(pf->TrackerTrk()->DzCorrected(vtx)) > 0.2) continue;
2617	>	//       if( pf->HasGsfTrk() )
2618	>	//      if (abs(pf->GsfTrk()->DzCorrected(vtx)) > 0.2) continue;
2619	>
2620	>	// Veto any PFmuon, or PFEle
2621	>	if (abs(pf->PFType()) == PFCandidate::eElectron || abs(pf->PFType()) == PFCandidate::eMuon) {
2622	>	cout << "\t skipping, pf is and ele or mu .." <<endl;
2623	>	continue;
2624	>	}
2625	>
2626	>	// Footprint Veto
2627	>	if (fabs(ele->SCluster()->Eta()) > 1.479 && dr < 0.015) continue;
2628	>
2629	>	if( ctrl.debug) cout << "charged:: pt: " << pf->Pt()
2630	>	<< "\ttype: " << pf->PFType()
2631	>	<< "\ttrk: " << pf->TrackerTrk() << endl;
2632	>
2633	>	fChargedIso += pf->Pt();
2634	>	}
2635	>
2636	>	//
2637	>	// Gamma Iso
2638	>	//
2639	>	else if (abs(pf->PFType()) == PFCandidate::eGamma) {
2640	>
2641	>	if (fabs(ele->SCluster()->Eta()) > 1.479) {
2642	>	if (mithep::MathUtils::DeltaR(ele->Phi(),ele->Eta(), pf->Phi(), pf->Eta()) < 0.08) continue;
2643	>	}
2644	>	if( ctrl.debug) cout << "gamma:: " << pf->Pt() << " "
2645	>	<< dr << endl;
2646	>	// KH, add to sync
2647	>	//      if( pf->Pt() > 0.5 )
2648	>	fGammaIso += pf->Pt();
2649	>	}
2650	>
2651	>	//
2652	>	// Neutral Iso
2653	>	//
2654	>	else {
2655	>	if( ctrl.debug) cout << "neutral:: " << pf->Pt() << " "
2656	>	<< dr << endl;
2657	>	// KH, add to sync
2658	>	//      if( pf->Pt() > 0.5 )
2659	>	fNeutralHadronIso += pf->Pt();
2660	>	}
2661	>
2662	>	}
2663	>
2664	>	}
2665	>
2666	>	//   double rho = 0;
2667	>	//   if (!(isnan(fPUEnergyDensity->At(0)->Rho()) || isinf(fPUEnergyDensity->At(0)->Rho())))
2668	>	//     rho = fPUEnergyDensity->At(0)->Rho();
2669	>
2670	>	// WARNING!!!!
2671	>	// hardcode for sync ...
2672	>	EffectiveAreaVersion = eleT.kEleEAData2011;
2673	>	// WARNING!!!!
2674	>
2675	>
2676	>	double pfIso = fChargedIso + fmax(0.0,(fGammaIso + fNeutralHadronIso
2677	>	-rho*eleT.ElectronEffectiveArea(eleT.kEleGammaAndNeutralHadronIso04,
2678	>	ele->Eta(),EffectiveAreaVersion)));
2679	>
2680	>
2681	>	gChargedIso = fChargedIso;
2682	>	gGammaIso = fGammaIso;
2683	>	gNeutralIso = fNeutralHadronIso;
2684	>	return pfIso;
2685	>	}
2686	>
2687	>
2688	>	//--------------------------------------------------------------------------------------------------
2689	>	SelectionStatus electronReferenceIsoSelection(ControlFlags &ctrl,
2690	>	const mithep::Electron * ele,
2691	>	const mithep::Vertex * vtx,
2692	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
2693	>	const mithep::Array<mithep::PileupEnergyDensity> * fPUEnergyDensity,
2694	>	mithep::ElectronTools::EElectronEffectiveAreaTarget EffectiveAreaVersion,
2695	>	vector<const mithep::Muon*> muonsToVeto,
2696	>	vector<const mithep::Electron*> electronsToVeto)
2697	>	//--------------------------------------------------------------------------------------------------
2698	>	{
2699	>
2700	>	SelectionStatus status;
2701	>
2702	>	double pfIso = electronPFIso04( ctrl, ele, vtx, fPFCandidates, fPUEnergyDensity,
2703	>	EffectiveAreaVersion, muonsToVeto ,electronsToVeto );
2704	>	//  cout << "--------------> setting electron isoPF04 to " << pfIso << endl;
2705	>	status.isoPF04 = pfIso;
2706	>	status.chisoPF04 = gChargedIso;
2707	>	status.gaisoPF04 = gGammaIso;
2708	>	status.neisoPF04 = gNeutralIso;
2709	>
2710	>	bool pass = false;
2711	>	if( (pfIso/ele->Pt()) < ELECTRON_REFERENCE_PFISO_CUT ) pass = true;
2712	>
2713	>	if( pass ) {
2714	>	status.orStatus(SelectionStatus::LOOSEISO);
2715	>	status.orStatus(SelectionStatus::TIGHTISO);
2716	>	}
2717	>	if(ctrl.debug) cout << "returning status : " << hex << status.getStatus() << dec << endl;
2718	>	return status;
2719	>
2720	>	}
2721	>
2722	>
2723	>	//--------------------------------------------------------------------------------------------------
2724	>	// hacked version
2725	>	SelectionStatus electronReferenceIsoSelection(ControlFlags &ctrl,
2726	>	const mithep::Electron * ele,
2727	>	const mithep::Vertex * vtx,
2728	>	const mithep::Array<mithep::PFCandidate> * fPFCandidates,
2729	>	float rho,
2730	>	mithep::ElectronTools::EElectronEffectiveAreaTarget EffectiveAreaVersion,
2731	>	vector<const mithep::Muon*> muonsToVeto,
2732	>	vector<const mithep::Electron*> electronsToVeto)
2733	>	//--------------------------------------------------------------------------------------------------
2734	>	{
2735	>
2736	>	SelectionStatus status;
2737	>
2738	>	double pfIso = electronPFIso04( ctrl, ele, vtx, fPFCandidates, rho,
2739	>	EffectiveAreaVersion, muonsToVeto ,electronsToVeto );
2740	>	status.isoPF04 = pfIso;
2741	>	status.chisoPF04 = gChargedIso;
2742	>	status.gaisoPF04 = gGammaIso;
2743	>	status.neisoPF04 = gNeutralIso;
2744	>	bool pass = false;
2745	>	if( (pfIso/ele->Pt()) < ELECTRON_REFERENCE_PFISO_CUT ) pass = true;
2746	>
2747	>	if( pass ) {
2748	>	status.orStatus(SelectionStatus::LOOSEISO);
2749	>	status.orStatus(SelectionStatus::TIGHTISO);
2750		}
2751		if(ctrl.debug) cout << "returning status : " << hex << status.getStatus() << dec << endl;
2752		return status;

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