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Comparing UserCode/MitPhysics/Mods/src/MuonIDMod.cc (file contents):
Revision 1.4 by ceballos, Tue Nov 11 21:22:54 2008 UTC vs.
Revision 1.84 by ceballos, Fri Jun 15 11:58:54 2012 UTC

#	Line 1 | Line 1
1		// $Id$
2
3		#include "MitPhysics/Mods/interface/MuonIDMod.h"
4	–	#include "MitAna/DataTree/interface/Names.h"
5	–	#include "MitAna/DataCont/interface/ObjArray.h"
6	–	#include "MitPhysics/Utils/interface/IsolationTools.h"
4		#include "MitCommon/MathTools/interface/MathUtils.h"
5	<	#include "MitPhysics/Utils/interface/MuonTools.h"
5	>	#include "MitAna/DataTree/interface/MuonFwd.h"
6	>	#include "MitAna/DataTree/interface/ElectronFwd.h"
7	>	#include "MitAna/DataTree/interface/VertexCol.h"
8	>	#include "MitPhysics/Init/interface/ModNames.h"
9
10		using namespace mithep;
11
#	Line 14 | Line 14 | ClassImp(mithep::MuonIDMod)
14		//--------------------------------------------------------------------------------------------------
15		MuonIDMod::MuonIDMod(const char *name, const char *title) :
16		BaseMod(name,title),
17	<	fPrintDebug(false),
18	<	fMuonName(Names::gkMuonBrn),
19	<	fCleanMuonsName(Names::gkCleanMuonsName),
20	<	fMuonIDType("Tight"),
21	<	fMuonIsoType("TrackCalo"),
22	<	fMuons(0),
17	>	fPrintMVADebugInfo(kFALSE),
18	>	fMuonBranchName(Names::gkMuonBrn),
19	>	fCleanMuonsName(ModNames::gkCleanMuonsName),
20	>	fNonIsolatedMuonsName("random"),
21	>	fNonIsolatedElectronsName("random"),
22	>	fVertexName(ModNames::gkGoodVertexesName),
23	>	fBeamSpotName(Names::gkBeamSpotBrn),
24	>	fTrackName(Names::gkTrackBrn),
25	>	fPFCandidatesName(Names::gkPFCandidatesBrn),
26	>	fMuonIDType("WWMuIdV3"),
27	>	fMuonIsoType("PFIso"),
28	>	fMuonClassType("Global"),
29		fTrackIsolationCut(3.0),
30		fCaloIsolationCut(3.0),
31	<	fCombIsolationCut(-1.0),
32	<	fTMOneStationLooseCut(false),
33	<	fTMOneStationTightCut (false),
28	<	fTM2DCompatibilityLooseCut(false),
29	<	fTM2DCompatibilityTightCut(false),
31	>	fCombIsolationCut(0.15),
32	>	fCombRelativeIsolationCut(0.15),
33	>	fPFIsolationCut(-999.0),
34		fMuonPtMin(10),
35	<	fNEventsProcessed(0)
35	>	fApplyD0Cut(kTRUE),
36	>	fApplyDZCut(kTRUE),
37	>	fD0Cut(0.020),
38	>	fDZCut(0.10),
39	>	fWhichVertex(-1),
40	>	fEtaCut(2.4),
41	>	fMuIDType(kIdUndef),
42	>	fMuIsoType(kIsoUndef),
43	>	fMuClassType(kClassUndef),
44	>	fMuons(0),
45	>	fVertices(0),
46	>	fBeamSpot(0),
47	>	fTracks(0),
48	>	fPFCandidates(0),
49	>	fPFNoPileUpCands(0),
50	>	fIntRadius(0.0),
51	>	fNonIsolatedMuons(0),
52	>	fNonIsolatedElectrons(0),
53	>	fPileupEnergyDensityName(Names::gkPileupEnergyDensityBrn),
54	>	fPileupEnergyDensity(0),
55	>	fMuonTools(0),
56	>	fMuonIDMVA(0),
57	>	fTheRhoType(RhoUtilities::DEFAULT)
58		{
59		// Constructor.
60		}
61
62		//--------------------------------------------------------------------------------------------------
37	–	void MuonIDMod::Begin()
38	–	{
39	–	// Run startup code on the client machine. For this module, we dont do
40	–	// anything here.
41	–	}
42	–
43	–	//--------------------------------------------------------------------------------------------------
63		void MuonIDMod::Process()
64		{
65		// Process entries of the tree.
66
67	<	fNEventsProcessed++;
68	<
69	<	if (fNEventsProcessed % 1000000 == 0 || fPrintDebug) {
70	<	time_t systime;
71	<	systime = time(NULL);
72	<
73	<	cerr << endl << "MuonIDMod : Process Event " << fNEventsProcessed << "  Time: " << ctime(&systime) << endl;
74	<	}
75	<
76	<	MuonTools myMuonTools;
77	<
78	<	//Get Muons
79	<	LoadBranch(fMuonName);
80	<	ObjArray<Muon> *CleanMuons = new ObjArray<Muon>;
81	<	for (UInt_t i=0; i<fMuons->GetEntries(); ++i) {
82	<	Muon *mu = fMuons->At(i);
83	<
84	<	Double_t MuonClass = -1;
85	<	if (mu->GlobalTrk())
86	<	MuonClass = 0;
87	<	else if (mu->StandaloneTrk())
88	<	MuonClass = 1;
89	<	else if (mu->TrackerTrk())
90	<	MuonClass = 2;
91	<
92	<	bool allCuts = false;
93	<
94	<	// We always want global muons
95	<	if(MuonClass == 0) allCuts = true;
96	<
97	<	// Isolation requirements
98	<	if(fCombIsolationCut < 0.0){
99	<	if(mu->IsoR03SumPt() >= fTrackIsolationCut) allCuts = false;
100	<	if(mu->IsoR03EmEt() +
101	<	mu->IsoR03HadEt() >= fCaloIsolationCut) allCuts = false;
102	<	}
103	<	else {
104	<	if(1.0 * mu->IsoR03SumPt() +
105	<	1.0 * mu->IsoR03EmEt() +
106	<	1.0 * mu->IsoR03HadEt() >= fCombIsolationCut) allCuts = false;
67	>	if(fMuIsoType != kPFIsoNoL) {
68	>	LoadEventObject(fMuonBranchName, fMuons);
69	>	}
70	>	else {
71	>	fMuons = GetObjThisEvt<MuonOArr>(fMuonBranchName);
72	>	}
73	>	LoadEventObject(fBeamSpotName, fBeamSpot);
74	>	LoadEventObject(fTrackName, fTracks);
75	>	LoadEventObject(fPFCandidatesName, fPFCandidates);
76	>	if(fMuIsoType == kTrackCaloSliding ||
77	>	fMuIsoType == kCombinedRelativeConeAreaCorrected ||
78	>	fMuIsoType == kPFIsoEffectiveAreaCorrected ||
79	>	fMuIsoType == kMVAIso_BDTG_IDIso ||
80	>	fMuIsoType == kIsoRingsV0_BDTG_Iso ||
81	>	fMuIsoType == kIsoDeltaR
82	>	) {
83	>	LoadEventObject(fPileupEnergyDensityName, fPileupEnergyDensity);
84	>	}
85	>	if(fMuIsoType == kPFRadialIso || fMuIsoType == kIsoDeltaR){
86	>	// Name is hardcoded, can be changed if someone feels to do it
87	>	fPFNoPileUpCands = GetObjThisEvt<PFCandidateCol>("PFNoPileUp");
88	>	}
89	>
90	>	MuonOArr *CleanMuons = new MuonOArr;
91	>	CleanMuons->SetName(fCleanMuonsName);
92	>
93	>	fVertices = GetObjThisEvt<VertexOArr>(fVertexName);
94	>
95	>	for (UInt_t i=0; i<fMuons->GetEntries() && fVertices->GetEntries() > 0 ; ++i) {
96	>	const Muon *mu = fMuons->At(i);
97	>
98	>	Bool_t pass = kFALSE;
99	>	Double_t pt = 0;  // make sure pt is taken from the correct track!
100	>	Double_t eta = 0; // make sure eta is taken from the correct track!
101	>	switch (fMuClassType) {
102	>	case kAll:
103	>	pass = kTRUE;
104	>	if (mu->HasTrk()) {
105	>	pt  = mu->Pt();
106	>	eta = TMath::Abs(mu->Eta());
107	>	}
108	>	break;
109	>	case kGlobal:
110	>	pass = mu->HasGlobalTrk() && mu->IsTrackerMuon();
111	>	if (pass && mu->TrackerTrk()) {
112	>	pt  = mu->TrackerTrk()->Pt();
113	>	eta = TMath::Abs(mu->TrackerTrk()->Eta());
114	>	}
115	>	else {
116	>	pt  = mu->Pt();
117	>	eta = TMath::Abs(mu->Eta());
118	>	}
119	>	break;
120	>	case kGlobalTracker:
121	>	pass = (mu->HasGlobalTrk() && mu->GlobalTrk()->Chi2()/mu->GlobalTrk()->Ndof() < 10 &&
122	>	(mu->NSegments() > 1 || mu->NMatches() > 1) && mu->NValidHits() > 0) ||
123	>	(mu->IsTrackerMuon() &&
124	>	mu->Quality().Quality(MuonQuality::TMLastStationTight));
125	>	if (pass) {
126	>	pt  = mu->TrackerTrk()->Pt();
127	>	eta = TMath::Abs(mu->TrackerTrk()->Eta());
128	>	}
129	>	else {
130	>	pt  = mu->Pt();
131	>	eta = TMath::Abs(mu->Eta());
132	>	}
133	>	break;
134	>	case kSta:
135	>	pass = mu->HasStandaloneTrk();
136	>	if (pass) {
137	>	pt  = mu->StandaloneTrk()->Pt();
138	>	eta = TMath::Abs(mu->StandaloneTrk()->Eta());
139	>	}
140	>	break;
141	>	case kTrackerMuon:
142	>	pass = mu->HasTrackerTrk() && mu->IsTrackerMuon() &&
143	>	mu->Quality().Quality(MuonQuality::TrackerMuonArbitrated);
144	>	if (pass) {
145	>	pt  = mu->TrackerTrk()->Pt();
146	>	eta = TMath::Abs(mu->TrackerTrk()->Eta());
147	>	}
148	>	break;
149	>	case kCaloMuon:
150	>	pass = mu->HasTrackerTrk() && mu->IsCaloMuon();
151	>	if (pass) {
152	>	pt  = mu->TrackerTrk()->Pt();
153	>	eta = TMath::Abs(mu->TrackerTrk()->Eta());
154	>	}
155	>	break;
156	>	case kTrackerBased:
157	>	pass = mu->HasTrackerTrk();
158	>	if (pass) {
159	>	pt  = mu->TrackerTrk()->Pt();
160	>	eta = TMath::Abs(mu->TrackerTrk()->Eta());
161	>	}
162	>	break;
163	>	case kGlobalOnly:
164	>	pass = mu->HasGlobalTrk();
165	>	if (pass && mu->TrackerTrk()) {
166	>	pt  = mu->TrackerTrk()->Pt();
167	>	eta = TMath::Abs(mu->TrackerTrk()->Eta());
168	>	}
169	>	else {
170	>	pt  = mu->Pt();
171	>	eta = TMath::Abs(mu->Eta());
172	>	}
173	>	break;
174	>	default:
175	>	break;
176	>	}
177	>
178	>	if (!pass)
179	>	continue;
180	>
181	>	if (pt <= fMuonPtMin)
182	>	continue;
183	>
184	>	if (eta >= fEtaCut)
185	>	continue;
186	>
187	>	Double_t RChi2 = 0.0;
188	>	if     (mu->HasGlobalTrk()) {
189	>	RChi2 = mu->GlobalTrk()->Chi2()/mu->GlobalTrk()->Ndof();
190	>	}
191	>	else if(mu->BestTrk() != 0){
192	>	RChi2 = mu->BestTrk()->Chi2()/mu->BestTrk()->Ndof();
193	>	}
194	>	Bool_t idpass = kFALSE;
195	>	switch (fMuIDType) {
196	>	case kWMuId:
197	>	idpass = mu->BestTrk() != 0 &&
198	>	mu->BestTrk()->NHits() > 10 &&
199	>	RChi2 < 10.0 &&
200	>	(mu->NSegments() > 1 || mu->NMatches() > 1) &&
201	>	mu->BestTrk()->NPixelHits() > 0 &&
202	>	mu->Quality().Quality(MuonQuality::GlobalMuonPromptTight);
203	>	break;
204	>	case kZMuId:
205	>	idpass = mu->BestTrk() != 0 &&
206	>	mu->BestTrk()->NHits() > 10 &&
207	>	(mu->NSegments() > 1 || mu->NMatches() > 1) &&
208	>	mu->BestTrk()->NPixelHits() > 0 &&
209	>	mu->Quality().Quality(MuonQuality::GlobalMuonPromptTight);
210	>	break;
211	>	case kLoose:
212	>	idpass = mu->BestTrk() != 0 &&
213	>	mu->Quality().Quality(MuonQuality::TMOneStationLoose) &&
214	>	mu->Quality().Quality(MuonQuality::TM2DCompatibilityLoose) &&
215	>	mu->BestTrk()->NHits() > 10 &&
216	>	RChi2 < 10.0 &&
217	>	mu->Quality().Quality(MuonQuality::GlobalMuonPromptTight);
218	>	break;
219	>	case kTight:
220	>	idpass = mu->BestTrk() != 0 &&
221	>	mu->NTrkLayersHit() > 5 &&
222	>	mu->IsPFMuon() == kTRUE &&
223	>	mu->BestTrk()->NPixelHits() > 0 &&
224	>	RChi2 < 10.0;
225	>	break;
226	>	// 2012 WW analysis for 42x (there is no PFMuon link)
227	>	case kWWMuIdV1:
228	>	idpass = mu->BestTrk() != 0 &&
229	>	mu->NTrkLayersHit() > 5 &&
230	>	mu->BestTrk()->NPixelHits() > 0 &&
231	>	mu->BestTrk()->PtErr()/mu->BestTrk()->Pt() < 0.1 &&
232	>	mu->TrkKink() < 20.0;
233	>	break;
234	>	// 2010 WW analysis
235	>	case kWWMuIdV2:
236	>	idpass = mu->BestTrk() != 0 &&
237	>	mu->BestTrk()->NHits() > 10 &&
238	>	mu->BestTrk()->NPixelHits() > 0 &&
239	>	mu->BestTrk()->PtErr()/mu->BestTrk()->Pt() < 0.1;
240	>	break;
241	>	// 2011 WW analysis
242	>	case kWWMuIdV3:
243	>	idpass = mu->BestTrk() != 0 &&
244	>	mu->BestTrk()->NHits() > 10 &&
245	>	mu->BestTrk()->NPixelHits() > 0 &&
246	>	mu->BestTrk()->PtErr()/mu->BestTrk()->Pt() < 0.1 &&
247	>	mu->TrkKink() < 20.0;
248	>	break;
249	>	// 2012 WW analysis
250	>	case kWWMuIdV4:
251	>	idpass = mu->BestTrk() != 0 &&
252	>	mu->NTrkLayersHit() > 5 &&
253	>	mu->IsPFMuon() == kTRUE &&
254	>	mu->BestTrk()->NPixelHits() > 0 &&
255	>	mu->BestTrk()->PtErr()/mu->BestTrk()->Pt() < 0.1 &&
256	>	mu->TrkKink() < 20.0;
257	>	break;
258	>	case kMVAID_BDTG_IDIso:
259	>	{
260	>	Bool_t passDenominatorM2 = (mu->BestTrk() != 0 &&
261	>	mu->BestTrk()->NHits() > 10 &&
262	>	mu->BestTrk()->NPixelHits() > 0 &&
263	>	mu->BestTrk()->PtErr()/mu->BestTrk()->Pt() < 0.1 &&
264	>	MuonTools::PassD0Cut(mu, fVertices, 0.20, 0) &&
265	>	MuonTools::PassDZCut(mu, fVertices, 0.10, 0) &&
266	>	mu->TrkKink() < 20.0
267	>	);
268	>	idpass =  passDenominatorM2;
269	>	//only evaluate MVA if muon passes M2 denominator to save time
270	>	if (idpass) idpass = PassMuonMVA_BDTG_IdIso(mu, fVertices->At(0), fPileupEnergyDensity);
271	>	}
272	>	break;
273	>	case kNoId:
274	>	idpass = kTRUE;
275	>	break;
276	>	default:
277	>	break;
278	>	}
279	>
280	>	if (!idpass)
281	>	continue;
282	>
283	>	Double_t Rho = 0.;
284	>	if(fPileupEnergyDensity){
285	>	const PileupEnergyDensity *rho =  fPileupEnergyDensity->At(0);
286	>
287	>	switch (fTheRhoType) {
288	>	case RhoUtilities::MIT_RHO_VORONOI_LOW_ETA:
289	>	Rho = rho->RhoLowEta();
290	>	break;
291	>	case RhoUtilities::MIT_RHO_VORONOI_HIGH_ETA:
292	>	Rho = rho->Rho();
293	>	break;
294	>	case RhoUtilities::MIT_RHO_RANDOM_LOW_ETA:
295	>	Rho = rho->RhoRandomLowEta();
296	>	break;
297	>	case RhoUtilities::MIT_RHO_RANDOM_HIGH_ETA:
298	>	Rho = rho->RhoRandom();
299	>	break;
300	>	case RhoUtilities::CMS_RHO_RHOKT6PFJETS:
301	>	Rho = rho->RhoKt6PFJets();
302	>	break;
303	>	default:
304	>	Rho = rho->Rho();
305	>	}
306	>
307	>	if ((TMath::IsNaN(fPileupEnergyDensity->At(0)->Rho()) || std::isinf(fPileupEnergyDensity->At(0)->Rho()))) Rho = 0.;
308	>	}
309	>
310	>	Bool_t isocut = kFALSE;
311	>	switch (fMuIsoType) {
312	>	case kTrackCalo:
313	>	isocut = (mu->IsoR03SumPt() < fTrackIsolationCut) &&
314	>	(mu->IsoR03EmEt() + mu->IsoR03HadEt() < fCaloIsolationCut);
315	>	break;
316	>	case kTrackCaloCombined:
317	>	isocut = (1.0 * mu->IsoR03SumPt() +
318	>	1.0 * mu->IsoR03EmEt()  +
319	>	1.0 * mu->IsoR03HadEt() < fCombIsolationCut);
320	>	break;
321	>	case kTrackCaloSliding:
322	>	{
323	>	Double_t totalIso =  mu->IsoR03SumPt() + mu->IsoR03EmEt() + mu->IsoR03HadEt() - Rho * TMath::Pi() * 0.3 * 0.3 ;
324	>	// trick to change the signal region cut
325	>	double theIsoCut = fCombIsolationCut;
326	>	if(theIsoCut < 0.20){
327	>	if(mu->Pt() >  20.0) theIsoCut = 0.15;
328	>	else                 theIsoCut = 0.10;
329	>	}
330	>	if (totalIso < (mu->Pt()*theIsoCut)) isocut = kTRUE;
331	>	}
332	>	break;
333	>	case kTrackCaloSlidingNoCorrection:
334	>	{
335	>	Double_t totalIso =  1.0 * mu->IsoR03SumPt() +
336	>	1.0 * mu->IsoR03EmEt()  +
337	>	1.0 * mu->IsoR03HadEt();
338	>	// trick to change the signal region cut
339	>	double theIsoCut = fCombIsolationCut;
340	>	if(theIsoCut < 0.20){
341	>	if(mu->Pt() >  20.0) theIsoCut = 0.15;
342	>	else                 theIsoCut = 0.10;
343	>	}
344	>	if (totalIso < (mu->Pt()*theIsoCut)) isocut = kTRUE;
345	>	}
346	>	break;
347	>	case kCombinedRelativeConeAreaCorrected:
348	>	{
349	>	//const PileupEnergyDensity *rho =  fPileupEnergyDensity->At(0); // Fabian: made Rho customable
350	>	Double_t totalIso =  mu->IsoR03SumPt() + mu->IsoR03EmEt() + mu->IsoR03HadEt() - Rho * TMath::Pi() * 0.3 * 0.3 ;
351	>	double theIsoCut = fCombRelativeIsolationCut;
352	>	if (totalIso < (mu->Pt()*theIsoCut)) isocut = kTRUE;
353	>	}
354	>	break;
355	>	case kCombinedRelativeEffectiveAreaCorrected:
356	>	{
357	>	Double_t tmpRho = Rho;   // Fabian: made the Rho type customable.
358	>	//if (!(TMath::IsNaN(fPileupEnergyDensity->At(0)->Rho()) || std::isinf(fPileupEnergyDensity->At(0)->Rho())))
359	>	//tmpRho = fPileupEnergyDensity->At(0)->Rho();
360	>
361	>	isocut = ( mu->IsoR03SumPt() + mu->IsoR03EmEt() + mu->IsoR03HadEt()
362	>	-  tmpRho*MuonTools::MuonEffectiveArea(MuonTools::kMuEMIso03, mu->Eta())
363	>	-  tmpRho*MuonTools::MuonEffectiveArea(MuonTools::kMuHadIso03, mu->Eta())
364	>	) < (mu->Pt()* 0.40);
365	>	}
366	>	break;
367	>	case kPFIso:
368	>	{
369	>	Double_t pfIsoCutValue = 9999;
370	>	if(fPFIsolationCut > 0){
371	>	pfIsoCutValue = fPFIsolationCut;
372	>	} else {
373	>	if (mu->AbsEta() < 1.479) {
374	>	if (mu->Pt() > 20) {
375	>	pfIsoCutValue = 0.13;
376	>	} else {
377	>	pfIsoCutValue = 0.06;
378	>	}
379	>	} else {
380	>	if (mu->Pt() > 20) {
381	>	pfIsoCutValue = 0.09;
382	>	} else {
383	>	pfIsoCutValue = 0.05;
384	>	}
385	>	}
386	>	}
387	>	Double_t totalIso =  IsolationTools::PFMuonIsolation(mu, fPFCandidates, fVertices->At(0), 0.1, 1.0, 0.3, 0.0, fIntRadius);
388	>	if (totalIso < (mu->Pt()*pfIsoCutValue) )
389	>	isocut = kTRUE;
390	>	}
391	>	break;
392	>	case kPFRadialIso:
393	>	{
394	>	Double_t pfIsoCutValue = 9999;
395	>	if(fPFIsolationCut > 0){
396	>	pfIsoCutValue = fPFIsolationCut;
397	>	} else {
398	>	if (mu->Pt() > 20) {
399	>	pfIsoCutValue = 0.10;
400	>	} else {
401	>	pfIsoCutValue = 0.05;
402	>	}
403	>	}
404	>	Double_t totalIso =  IsolationTools::PFRadialMuonIsolation(mu, fPFNoPileUpCands, 1.0, 0.3);
405	>	if (totalIso < (mu->Pt()*pfIsoCutValue) )
406	>	isocut = kTRUE;
407	>	}
408	>	break;
409	>	case kPFIsoEffectiveAreaCorrected:
410	>	{
411	>	Double_t pfIsoCutValue = 9999;
412	>	if(fPFIsolationCut > 0){
413	>	pfIsoCutValue = fPFIsolationCut;
414	>	} else {
415	>	pfIsoCutValue = fPFIsolationCut; //leave it like this for now
416	>	}
417	>	Double_t EffectiveAreaCorrectedPFIso =  IsolationTools::PFMuonIsolation(mu, fPFCandidates, fVertices->At(0), 0.1, 1.0, 0.3, 0.0, fIntRadius)
418	>	- Rho * MuonTools::MuonEffectiveArea(MuonTools::kMuNeutralIso03, mu->Eta());
419	>	//- fPileupEnergyDensity->At(0)->Rho() * MuonTools::MuonEffectiveArea(MuonTools::kMuNeutralIso03, mu->Eta());  // Fabian: made Rho-type customable
420	>	isocut = EffectiveAreaCorrectedPFIso < (mu->Pt() * pfIsoCutValue);
421	>	break;
422	>	}
423	>
424
425	+	case kPFIsoNoL:
426	+	{
427	+	fNonIsolatedMuons     = GetObjThisEvt<MuonCol>(fNonIsolatedMuonsName);
428	+	fNonIsolatedElectrons = GetObjThisEvt<ElectronCol>(fNonIsolatedElectronsName);
429	+
430	+	Double_t pfIsoCutValue = 9999;
431	+	if(fPFIsolationCut > 0){
432	+	pfIsoCutValue = fPFIsolationCut;
433	+	} else {
434	+	if (mu->AbsEta() < 1.479) {
435	+	if (mu->Pt() > 20) {
436	+	pfIsoCutValue = 0.13;
437	+	} else {
438	+	pfIsoCutValue = 0.06;
439	+	}
440	+	} else {
441	+	if (mu->Pt() > 20) {
442	+	pfIsoCutValue = 0.09;
443	+	} else {
444	+	pfIsoCutValue = 0.05;
445	+	}
446	+	}
447	+	}
448	+	Double_t totalIso =  IsolationTools::PFMuonIsolation(mu, fPFCandidates, fNonIsolatedMuons, fNonIsolatedElectrons, fVertices->At(0), 0.1, 1.0, 0.3, 0.0, fIntRadius);
449	+	if (totalIso < (mu->Pt()*pfIsoCutValue) )
450	+	isocut = kTRUE;
451	+	}
452	+	break;
453	+	case kMVAIso_BDTG_IDIso:
454	+	{
455	+
456	+	Double_t totalIso =  IsolationTools::PFMuonIsolation(mu, fPFCandidates, fVertices->At(0), 0.1, 1.0, 0.3, 0.0, fIntRadius);
457	+	isocut = (totalIso < (mu->Pt()*0.4));
458	+
459	+	}
460	+	break;
461	+	case kIsoRingsV0_BDTG_Iso:
462	+	{
463	+
464	+	isocut = PassMuonIsoRingsV0_BDTG_Iso(mu, fVertices->At(0), fPileupEnergyDensity);
465	+
466	+	}
467	+	break;
468	+	case kIsoDeltaR:
469	+	{
470	+
471	+	isocut = PassMuonIsoDeltaR(mu, fVertices->At(0), fPileupEnergyDensity);
472	+
473	+	}
474	+	break;
475	+	case kNoIso:
476	+	isocut = kTRUE;
477	+	break;
478	+	case kCustomIso:
479	+	default:
480	+	break;
481	+	}
482	+
483	+	if (isocut == kFALSE)
484	+	continue;
485	+
486	+	// apply d0 cut
487	+	if (fApplyD0Cut) {
488	+	Bool_t passD0cut = kTRUE;
489	+	if(fD0Cut < 0.05) { // trick to change the signal region cut
490	+	if      (mu->Pt() >  20.0) fD0Cut = 0.02;
491	+	else if (mu->Pt() <= 20.0) fD0Cut = 0.01;
492	+	}
493	+	if(fWhichVertex >= -1) passD0cut = MuonTools::PassD0Cut(mu, fVertices, fD0Cut, fWhichVertex);
494	+	else                   passD0cut = MuonTools::PassD0Cut(mu, fBeamSpot, fD0Cut);
495	+	if (!passD0cut)
496	+	continue;
497		}
498
499	<	// Muon chambers and calo compatibility requirements
500	<	if(fTMOneStationLooseCut == true &&
501	<	myMuonTools.isGood(mu, MuonTools::TMOneStationLoose) == false)
502	<	allCuts = false;
503	<
96	<	if(fTMOneStationTightCut == true &&
97	<	myMuonTools.isGood(mu, MuonTools::TMOneStationTight) == false)
98	<	allCuts = false;
99	<
100	<	if(fTM2DCompatibilityLooseCut == true &&
101	<	myMuonTools.isGood(mu, MuonTools::TM2DCompatibilityLoose) == false)
102	<	allCuts = false;
103	<
104	<	if(fTM2DCompatibilityTightCut == true &&
105	<	myMuonTools.isGood(mu, MuonTools::TM2DCompatibilityTight) == false)
106	<	allCuts = false;
107	<
108	<	// Min Pt requirement
109	<	if(mu->Pt() <= fMuonPtMin) allCuts = false;
110	<
111	<	if(allCuts) {
112	<	CleanMuons->Add(mu);
499	>	// apply dz cut
500	>	if (fApplyDZCut) {
501	>	Bool_t passDZcut = MuonTools::PassDZCut(mu, fVertices, fDZCut, fWhichVertex);
502	>	if (!passDZcut)
503	>	continue;
504		}
505	+
506	+	// add good muon
507	+	CleanMuons->Add(mu);
508		}
509
510	<	//Final Summary Debug Output
511	<	if ( fPrintDebug ) {
118	<	cerr << "Event Dump: " << fNEventsProcessed << endl;
119	<	cerr << "Muons" << endl;
120	<	for (UInt_t i = 0; i < CleanMuons->GetEntries(); i++) {
121	<	cerr << i << " " << CleanMuons->At(i)->Pt() << " " << CleanMuons->At(i)->Eta()
122	<	<< " " << CleanMuons->At(i)->Phi() << endl;
123	<	}
124	<	}
125	<
126	<	//Save Objects for Other Modules to use
127	<	AddObjThisEvt(CleanMuons, fCleanMuonsName.Data());
128	<	}
510	>	// sort according to pt
511	>	CleanMuons->Sort();
512
513	+	// add objects for other modules to use
514	+	AddObjThisEvt(CleanMuons);
515	+	}
516
517		//--------------------------------------------------------------------------------------------------
518		void MuonIDMod::SlaveBegin()
519		{
520		// Run startup code on the computer (slave) doing the actual analysis. Here,
521	<	// we typically initialize histograms and other analysis objects and request
522	<	// branches. For this module, we request a branch of the MitTree.
521	>	// we just request the muon collection branch.
522	>
523	>	// In this case we cannot have a branch
524	>	if (fMuonIsoType.CompareTo("PFIsoNoL") != 0) {
525	>	ReqEventObject(fMuonBranchName, fMuons, kTRUE);
526	>	}
527	>	ReqEventObject(fBeamSpotName, fBeamSpot, kTRUE);
528	>	ReqEventObject(fTrackName, fTracks, kTRUE);
529	>	ReqEventObject(fPFCandidatesName, fPFCandidates, kTRUE);
530	>	if (fMuonIsoType.CompareTo("TrackCaloSliding") == 0
531	>	|| fMuonIsoType.CompareTo("CombinedRelativeConeAreaCorrected") == 0
532	>	|| fMuonIsoType.CompareTo("CombinedRelativeEffectiveAreaCorrected") == 0
533	>	|| fMuonIsoType.CompareTo("PFIsoEffectiveAreaCorrected") == 0
534	>	|| fMuonIsoType.CompareTo("MVA_BDTG_IDIso") == 0
535	>	|| fMuonIsoType.CompareTo("IsoRingsV0_BDTG_Iso") == 0
536	>	|| fMuonIsoType.CompareTo("IsoDeltaR") == 0
537	>	) {
538	>	ReqEventObject(fPileupEnergyDensityName, fPileupEnergyDensity, kTRUE);
539	>	}
540	>
541	>
542	>	if (fMuonIDType.CompareTo("WMuId") == 0)
543	>	fMuIDType = kWMuId;
544	>	else if (fMuonIDType.CompareTo("ZMuId") == 0)
545	>	fMuIDType = kZMuId;
546	>	else if (fMuonIDType.CompareTo("Tight") == 0)
547	>	fMuIDType = kTight;
548	>	else if (fMuonIDType.CompareTo("Loose") == 0)
549	>	fMuIDType = kLoose;
550	>	else if (fMuonIDType.CompareTo("WWMuIdV1") == 0)
551	>	fMuIDType = kWWMuIdV1;
552	>	else if (fMuonIDType.CompareTo("WWMuIdV2") == 0)
553	>	fMuIDType = kWWMuIdV2;
554	>	else if (fMuonIDType.CompareTo("WWMuIdV3") == 0)
555	>	fMuIDType = kWWMuIdV3;
556	>	else if (fMuonIDType.CompareTo("WWMuIdV4") == 0)
557	>	fMuIDType = kWWMuIdV4;
558	>	else if (fMuonIDType.CompareTo("NoId") == 0)
559	>	fMuIDType = kNoId;
560	>	else if (fMuonIDType.CompareTo("Custom") == 0) {
561	>	fMuIDType = kCustomId;
562	>	SendError(kWarning, "SlaveBegin",
563	>	"Custom muon identification is not yet implemented.");
564	>	} else if (fMuonIDType.CompareTo("MVA_BDTG_IDIso") == 0) {
565	>	fMuIDType = kMVAID_BDTG_IDIso;
566	>	} else {
567	>	SendError(kAbortAnalysis, "SlaveBegin",
568	>	"The specified muon identification %s is not defined.",
569	>	fMuonIDType.Data());
570	>	return;
571	>	}
572	>
573	>	if (fMuonIsoType.CompareTo("TrackCalo") == 0)
574	>	fMuIsoType = kTrackCalo;
575	>	else if (fMuonIsoType.CompareTo("TrackCaloCombined") == 0)
576	>	fMuIsoType = kTrackCaloCombined;
577	>	else if (fMuonIsoType.CompareTo("TrackCaloSliding") == 0)
578	>	fMuIsoType = kTrackCaloSliding;
579	>	else if (fMuonIsoType.CompareTo("TrackCaloSlidingNoCorrection") == 0)
580	>	fMuIsoType = kTrackCaloSlidingNoCorrection;
581	>	else if (fMuonIsoType.CompareTo("CombinedRelativeConeAreaCorrected") == 0)
582	>	fMuIsoType = kCombinedRelativeConeAreaCorrected;
583	>	else if (fMuonIsoType.CompareTo("CombinedRelativeEffectiveAreaCorrected") == 0)
584	>	fMuIsoType = kCombinedRelativeEffectiveAreaCorrected;
585	>	else if (fMuonIsoType.CompareTo("PFIso") == 0)
586	>	fMuIsoType = kPFIso;
587	>	else if (fMuonIsoType.CompareTo("PFRadialIso") == 0)
588	>	fMuIsoType = kPFRadialIso;
589	>	else if (fMuonIsoType.CompareTo("PFIsoEffectiveAreaCorrected") == 0)
590	>	fMuIsoType = kPFIsoEffectiveAreaCorrected;
591	>	else if (fMuonIsoType.CompareTo("PFIsoNoL") == 0)
592	>	fMuIsoType = kPFIsoNoL;
593	>	else if (fMuonIsoType.CompareTo("NoIso") == 0)
594	>	fMuIsoType = kNoIso;
595	>	else if (fMuonIsoType.CompareTo("Custom") == 0) {
596	>	fMuIsoType = kCustomIso;
597	>	SendError(kWarning, "SlaveBegin",
598	>	"Custom muon isolation is not yet implemented.");
599	>	} else if (fMuonIsoType.CompareTo("MVA_BDTG_IDIso") == 0) {
600	>	fMuIsoType = kMVAIso_BDTG_IDIso;
601	>	} else if (fMuonIsoType.CompareTo("IsoRingsV0_BDTG_Iso") == 0) {
602	>	fMuIsoType = kIsoRingsV0_BDTG_Iso;
603	>	} else if (fMuonIsoType.CompareTo("IsoDeltaR") == 0) {
604	>	fMuIsoType = kIsoDeltaR;
605	>	} else {
606	>	SendError(kAbortAnalysis, "SlaveBegin",
607	>	"The specified muon isolation %s is not defined.",
608	>	fMuonIsoType.Data());
609	>	return;
610	>	}
611	>
612	>	if (fMuonClassType.CompareTo("All") == 0)
613	>	fMuClassType = kAll;
614	>	else if (fMuonClassType.CompareTo("Global") == 0)
615	>	fMuClassType = kGlobal;
616	>	else if (fMuonClassType.CompareTo("GlobalTracker") == 0)
617	>	fMuClassType = kGlobalTracker;
618	>	else if (fMuonClassType.CompareTo("Standalone") == 0)
619	>	fMuClassType = kSta;
620	>	else if (fMuonClassType.CompareTo("TrackerMuon") == 0)
621	>	fMuClassType = kTrackerMuon;
622	>	else if (fMuonClassType.CompareTo("CaloMuon") == 0)
623	>	fMuClassType = kCaloMuon;
624	>	else if (fMuonClassType.CompareTo("TrackerBased") == 0)
625	>	fMuClassType = kTrackerBased;
626	>	else if (fMuonClassType.CompareTo("GlobalOnly") == 0)
627	>	fMuClassType = kGlobalOnly;
628	>	else {
629	>	SendError(kAbortAnalysis, "SlaveBegin",
630	>	"The specified muon class %s is not defined.",
631	>	fMuonClassType.Data());
632	>	return;
633	>	}
634	>
635	>
636	>	//If we use MVA ID, need to load MVA weights
637	>	if     (fMuIsoType == kMVAIso_BDTG_IDIso || fMuIDType == kMVAID_BDTG_IDIso) {
638	>	fMuonTools = new MuonTools();
639	>	fMuonIDMVA = new MuonIDMVA();
640	>	fMuonIDMVA->Initialize("BDTG method",
641	>	string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/BarrelPtBin0_IDIsoCombined_BDTG.weights.xml"))),
642	>	string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/EndcapPtBin0_IDIsoCombined_BDTG.weights.xml"))),
643	>	string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/BarrelPtBin1_IDIsoCombined_BDTG.weights.xml"))),
644	>	string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/EndcapPtBin1_IDIsoCombined_BDTG.weights.xml"))),
645	>	string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/BarrelPtBin2_IDIsoCombined_BDTG.weights.xml"))),
646	>	string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/EndcapPtBin2_IDIsoCombined_BDTG.weights.xml"))),
647	>	MuonIDMVA::kIDIsoCombinedDetIso,
648	>	fTheRhoType);
649	>	}
650	>	else if(fMuIsoType == kIsoRingsV0_BDTG_Iso) {
651	>	std::vector<std::string> muonidiso_weightfiles;
652	>	muonidiso_weightfiles.push_back(string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/MuonIsoMVA_BDTG_V0_barrel_lowpt.weights.xml"))));
653	>	muonidiso_weightfiles.push_back(string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/MuonIsoMVA_BDTG_V0_barrel_highpt.weights.xml"))));
654	>	muonidiso_weightfiles.push_back(string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/MuonIsoMVA_BDTG_V0_endcap_lowpt.weights.xml"))));
655	>	muonidiso_weightfiles.push_back(string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/MuonIsoMVA_BDTG_V0_endcap_highpt.weights.xml"))));
656	>	muonidiso_weightfiles.push_back(string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/MuonIsoMVA_BDTG_V0_tracker.weights.xml"))));
657	>	muonidiso_weightfiles.push_back(string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/MuonIsoMVA_BDTG_V0_global.weights.xml"))));
658	>	fMuonTools = new MuonTools();
659	>	fMuonIDMVA = new MuonIDMVA();
660	>	fMuonIDMVA->Initialize("MuonIso_BDTG_IsoRings",
661	>	MuonIDMVA::kIsoRingsV0,
662	>	kTRUE,
663	>	muonidiso_weightfiles,
664	>	fTheRhoType);
665	>	}
666	>	else if(fMuIsoType == kIsoDeltaR) {
667	>	std::vector<std::string> muonidiso_weightfiles;
668	>	muonidiso_weightfiles.push_back(string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/MuonIsoMVA_santi-V1_LB_BDT.weights.xml"))));
669	>	muonidiso_weightfiles.push_back(string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/MuonIsoMVA_santi-V1_LE_BDT.weights.xml"))));
670	>	muonidiso_weightfiles.push_back(string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/MuonIsoMVA_santi-V1_HB_BDT.weights.xml"))));
671	>	muonidiso_weightfiles.push_back(string((getenv("CMSSW_BASE")+string("/src/MitPhysics/data/MuonMVAWeights/MuonIsoMVA_santi-V1_HE_BDT.weights.xml"))));
672	>	fMuonTools = new MuonTools();
673	>	fMuonIDMVA = new MuonIDMVA();
674	>	fMuonIDMVA->Initialize("muonHZZ2012IsoDRMVA",
675	>	MuonIDMVA::kIsoDeltaR,
676	>	kTRUE,
677	>	muonidiso_weightfiles,
678	>	fTheRhoType);
679	>	}
680
138	–	ReqBranch(fMuonName,              fMuons);
681		}
682
683	+
684		//--------------------------------------------------------------------------------------------------
685	<	void MuonIDMod::SlaveTerminate()
685	>	Bool_t MuonIDMod::PassMuonMVA_BDTG_IdIso(const Muon *mu, const Vertex *vertex,
686	>	const PileupEnergyDensityCol *PileupEnergyDensity) const
687		{
144	–	// Run finishing code on the computer (slave) that did the analysis. For this
145	–	// module, we dont do anything here.
688
689	+	const Track *muTrk=0;
690	+	if(mu->HasTrackerTrk())         { muTrk = mu->TrackerTrk();    }
691	+	else if(mu->HasStandaloneTrk()) { muTrk = mu->StandaloneTrk(); }
692	+
693	+	Double_t MVAValue = fMuonIDMVA->MVAValue(mu,vertex,fMuonTools,fPFCandidates,PileupEnergyDensity);
694	+
695	+	Int_t subdet = 0;
696	+	if (fabs(muTrk->Eta()) < 1.479) subdet = 0;
697	+	else subdet = 1;
698	+	Int_t ptBin = 0;
699	+	if (muTrk->Pt() > 14.5) ptBin = 1;
700	+	if (muTrk->Pt() > 20.0) ptBin = 2;
701	+
702	+	Int_t MVABin = -1;
703	+	if      (subdet == 0 && ptBin == 0) MVABin = 0;
704	+	else if (subdet == 1 && ptBin == 0) MVABin = 1;
705	+	else if (subdet == 0 && ptBin == 1) MVABin = 2;
706	+	else if (subdet == 1 && ptBin == 1) MVABin = 3;
707	+	else if (subdet == 0 && ptBin == 2) MVABin = 4;
708	+	else if (subdet == 1 && ptBin == 2) MVABin = 5;
709	+
710	+	Double_t MVACut = -999;
711	+	if      (MVABin == 0) MVACut = -0.5618;
712	+	else if (MVABin == 1) MVACut = -0.3002;
713	+	else if (MVABin == 2) MVACut = -0.4642;
714	+	else if (MVABin == 3) MVACut = -0.2478;
715	+	else if (MVABin == 4) MVACut =  0.1706;
716	+	else if (MVABin == 5) MVACut =  0.8146;
717	+
718	+	if (MVAValue > MVACut) return kTRUE;
719	+	return kFALSE;
720	+	}
721	+
722	+	//--------------------------------------------------------------------------------------------------
723	+	Bool_t MuonIDMod::PassMuonIsoRingsV0_BDTG_Iso(const Muon *mu, const Vertex *vertex,
724	+	const PileupEnergyDensityCol *PileupEnergyDensity) const
725	+	{
726	+
727	+	Bool_t isDebug = kFALSE;
728	+	const Track *muTrk=0;
729	+	if(mu->HasTrackerTrk())         { muTrk = mu->TrackerTrk();    }
730	+	else if(mu->HasStandaloneTrk()) { muTrk = mu->StandaloneTrk(); }
731	+
732	+	ElectronOArr *tempElectrons = new  ElectronOArr;
733	+	MuonOArr     *tempMuons     = new  MuonOArr;
734	+	Double_t MVAValue = fMuonIDMVA->MVAValue(mu,vertex,fMuonTools,fPFCandidates,
735	+	PileupEnergyDensity,MuonTools::kMuEAFall11MC,tempElectrons,tempMuons,isDebug);
736	+	delete tempElectrons;
737	+	delete tempMuons;
738	+
739	+	Int_t MVABin = fMuonIDMVA->GetMVABin(muTrk->Eta(), muTrk->Pt(), mu->IsGlobalMuon(), mu->IsTrackerMuon());
740	+
741	+	Double_t MVACut = -1.0;
742	+	Double_t eta = mu->AbsEta();
743	+	if     (mu->Pt() <  20 && eta <  1.479) MVACut = 0.86;
744	+	else if(mu->Pt() <  20 && eta >= 1.479) MVACut = 0.82;
745	+	else if(mu->Pt() >= 20 && eta <  1.479) MVACut = 0.82;
746	+	else if(mu->Pt() >= 20 && eta >= 1.479) MVACut = 0.86;
747	+
748	+	if(fPFIsolationCut > -1.0) MVACut = fPFIsolationCut;
749	+
750	+	if(isDebug == kTRUE){
751	+	printf("PassMuonIsoRingsV0_BDTG_IsoDebug: %d, pt, eta = %f, %f, rho = %f(%f) : RingsMVA = %f, bin: %d\n",
752	+	GetEventHeader()->EvtNum(),mu->Pt(), mu->Eta(),
753	+	fPileupEnergyDensity->At(0)->Rho(),fPileupEnergyDensity->At(0)->RhoKt6PFJets(),MVAValue,MVABin);
754	+	}
755	+
756	+	if (MVAValue > MVACut) return kTRUE;
757	+	return kFALSE;
758	+	}
759	+
760	+	//--------------------------------------------------------------------------------------------------
761	+	Bool_t MuonIDMod::PassMuonIsoDeltaR(const Muon *mu, const Vertex *vertex,
762	+	const PileupEnergyDensityCol *PileupEnergyDensity) const
763	+	{
764	+
765	+	const Track *muTrk=0;
766	+	if(mu->HasTrackerTrk())         { muTrk = mu->TrackerTrk();    }
767	+	else if(mu->HasStandaloneTrk()) { muTrk = mu->StandaloneTrk(); }
768	+
769	+	ElectronOArr *tempElectrons = new  ElectronOArr;
770	+	MuonOArr     *tempMuons     = new  MuonOArr;
771	+	Double_t MVAValue = fMuonIDMVA->MVAValue(mu,vertex,fMuonTools,fPFNoPileUpCands,
772	+	PileupEnergyDensity,MuonTools::kMuEAFall11MC,tempElectrons,tempMuons,kFALSE);
773	+	delete tempElectrons;
774	+	delete tempMuons;
775	+
776	+	Int_t MVABin = fMuonIDMVA->GetMVABin(muTrk->Eta(), muTrk->Pt(), mu->IsGlobalMuon(), mu->IsTrackerMuon());
777	+
778	+	Double_t MVACut = -999;
779	+	if      (MVABin == 0) MVACut =  0.000;
780	+	else if (MVABin == 1) MVACut =  0.000;
781	+	else if (MVABin == 2) MVACut =  0.000;
782	+	else if (MVABin == 3) MVACut =  0.000;
783	+
784	+	if (MVAValue > MVACut) return kTRUE;
785	+	return kFALSE;
786		}
787
788		//--------------------------------------------------------------------------------------------------
789		void MuonIDMod::Terminate()
790		{
791	<	// Run finishing code on the client computer. For this module, we dont do
792	<	// anything here.
791	>	// Run finishing code on the computer (slave) that did the analysis
792	>	delete fMuonIDMVA;
793	>
794	>	delete fMuonTools;
795		}

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