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SingleTopTChannelLeptonDQM_miniAOD.cc
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10 #include <iostream>
15 using namespace std;
17 
18 // maximal number of leading jets
19 // to be used for top mass estimate
20 static const unsigned int MAXJETS = 4;
21 // nominal mass of the W boson to
22 // be used for the top mass estimate
23 static const double WMASS = 80.4;
24 
25 MonitorEnsemble::MonitorEnsemble(const char* label,
26  const edm::ParameterSet& cfg,
27  const edm::VParameterSet& vcfg,
29  : label_(label),
30  pvSelect_(nullptr),
31  jetIDSelect_(nullptr),
32  includeBTag_(false),
33  lowerEdge_(-1.),
34  upperEdge_(-1.),
35  logged_(0) {
36  // sources have to be given; this PSet is not optional
37  edm::ParameterSet sources = cfg.getParameter<edm::ParameterSet>("sources");
38  muons_ = iC.consumes<edm::View<pat::Muon>>(
39  sources.getParameter<edm::InputTag>("muons"));
40  elecs_gsf_ = iC.consumes<edm::View<pat::Electron>>(
41  sources.getParameter<edm::InputTag>("elecs_gsf"));
42 
43  jets_ = iC.consumes<edm::View<pat::Jet>>(
44  sources.getParameter<edm::InputTag>("jets"));
45  for (edm::InputTag const& tag :
46  sources.getParameter<std::vector<edm::InputTag>>("mets"))
47  mets_.push_back(iC.consumes<edm::View<pat::MET>>(tag));
48  pvs_ = iC.consumes<edm::View<reco::Vertex>>(
49  sources.getParameter<edm::InputTag>("pvs"));
50  // electronExtras are optional; they may be omitted or
51  // empty
52  if (cfg.existsAs<edm::ParameterSet>("elecExtras")) {
53  edm::ParameterSet elecExtras =
54  cfg.getParameter<edm::ParameterSet>("elecExtras");
55  // select is optional; in case it's not found no
56  // selection will be applied
57  if (elecExtras.existsAs<std::string>("select")) {
58  elecSelect_ = vcfg[1].getParameter<std::string>("select");
59  }
60  // isolation is optional; in case it's not found no
61  // isolation will be applied
62  if (elecExtras.existsAs<std::string>("isolation")) {
63  elecIso_ = elecExtras.getParameter<std::string>("isolation");
64  }
65 
66 
67  // electronId is optional; in case it's not found the
68  // InputTag will remain empty
69  if (elecExtras.existsAs<edm::ParameterSet>("electronId")) {
70  edm::ParameterSet elecId =
71  elecExtras.getParameter<edm::ParameterSet>("electronId");
72  electronId_ = iC.consumes<edm::ValueMap<float>>(
73  elecId.getParameter<edm::InputTag>("src"));
74  eidCutValue_ = elecId.getParameter<double>("cutValue");
75  }
76  }
77  // pvExtras are opetional; they may be omitted or empty
78  if (cfg.existsAs<edm::ParameterSet>("pvExtras")) {
79  edm::ParameterSet pvExtras =
80  cfg.getParameter<edm::ParameterSet>("pvExtras");
81  // select is optional; in case it's not found no
82  // selection will be applied
83  if (pvExtras.existsAs<std::string>("select")) {
85  pvExtras.getParameter<std::string>("select")));
86  }
87  }
88  // muonExtras are optional; they may be omitted or empty
89  if (cfg.existsAs<edm::ParameterSet>(
90  "muonExtras")) {
91  edm::ParameterSet muonExtras =
92  cfg.getParameter<edm::ParameterSet>("muonExtras");
93 
94  // select is optional; in case it's not found no
95  // selection will be applied
96  if (muonExtras.existsAs<std::string>("select")) {
97  muonSelect_ = vcfg[1].getParameter<std::string>("select");
98  }
99  // isolation is optional; in case it's not found no
100  // isolation will be applied
101  if (muonExtras.existsAs<std::string>("isolation")) {
102  muonIso_ = muonExtras.getParameter<std::string>("isolation");
103  }
104  }
105 
106 
107  // jetExtras are optional; they may be omitted or
108  // empty
109  if (cfg.existsAs<edm::ParameterSet>("jetExtras")) {
110  edm::ParameterSet jetExtras =
111  cfg.getParameter<edm::ParameterSet>("jetExtras");
112  // jetCorrector is optional; in case it's not found
113  // the InputTag will remain empty
114  if (jetExtras.existsAs<std::string>("jetCorrector")) {
115  jetCorrector_ = jetExtras.getParameter<std::string>("jetCorrector");
116  }
117  // read jetID information if it exists
118  if (jetExtras.existsAs<edm::ParameterSet>("jetID")) {
119  edm::ParameterSet jetID =
120  jetExtras.getParameter<edm::ParameterSet>("jetID");
121  jetIDLabel_ = iC.consumes<reco::JetIDValueMap>(
122  jetID.getParameter<edm::InputTag>("label"));
124  jetID.getParameter<std::string>("select")));
125  }
126  // select is optional; in case it's not found no
127  // selection will be applied (only implemented for
128  // CaloJets at the moment)
129  if (jetExtras.existsAs<std::string>("select")) {
130 
131  jetSelect_ = jetExtras.getParameter<std::string>("select");
132  jetSelect_ = vcfg[2].getParameter<std::string>("select");
133  }
134 
135  }
136 
137  // triggerExtras are optional; they may be omitted or empty
138  if (cfg.existsAs<edm::ParameterSet>("triggerExtras")) {
139  edm::ParameterSet triggerExtras =
140  cfg.getParameter<edm::ParameterSet>("triggerExtras");
141  triggerTable_ = iC.consumes<edm::TriggerResults>(
142  triggerExtras.getParameter<edm::InputTag>("src"));
143  triggerPaths_ =
144  triggerExtras.getParameter<std::vector<std::string>>("paths");
145  }
146 
147  // massExtras is optional; in case it's not found no mass
148  // window cuts are applied for the same flavor monitor
149  // histograms
150  if (cfg.existsAs<edm::ParameterSet>("massExtras")) {
151  edm::ParameterSet massExtras =
152  cfg.getParameter<edm::ParameterSet>("massExtras");
153  lowerEdge_ = massExtras.getParameter<double>("lowerEdge");
154  upperEdge_ = massExtras.getParameter<double>("upperEdge");
155  }
156 
157  // setup the verbosity level for booking histograms;
158  // per default the verbosity level will be set to
159  // STANDARD. This will also be the chosen level in
160  // the case when the monitoring PSet is not found
162  if (cfg.existsAs<edm::ParameterSet>("monitoring")) {
164  cfg.getParameter<edm::ParameterSet>("monitoring");
165  if (monitoring.getParameter<std::string>("verbosity") == "DEBUG")
166  verbosity_ = DEBUG;
167  if (monitoring.getParameter<std::string>("verbosity") == "VERBOSE")
168  verbosity_ = VERBOSE;
169  if (monitoring.getParameter<std::string>("verbosity") == "STANDARD")
170  verbosity_ = STANDARD;
171  }
172  // and don't forget to do the histogram booking
173  directory_ = cfg.getParameter<std::string>("directory");
174 
175 
178 
181 
182 }
183 
185  // set up the current directory path
186  std::string current(directory_);
187  current += label_;
188  ibooker.setCurrentFolder(current);
189 
190  // determine number of bins for trigger monitoring
191  unsigned int nPaths = triggerPaths_.size();
192 
193  // --- [STANDARD] --- //
194  // number of selected primary vertices
195  hists_["pvMult_"] = ibooker.book1D("PvMult", "N_{pvs}", 100, 0., 100.);
196  // pt of the leading muon
197  hists_["muonPt_"] = ibooker.book1D("MuonPt", "pt(#mu)", 50, 0., 250.);
198  // muon multiplicity before std isolation
199  hists_["muonMult_"] = ibooker.book1D("MuonMult", "N_{20}(#mu)", 10, 0., 10.);
200  // muon multiplicity after std isolation
201  hists_["muonMultIso_"] = ibooker.book1D("MuonMultIso", "N_{Iso}(#mu)", 10, 0., 10.);
202  // pt of the leading electron
203  hists_["elecPt_"] = ibooker.book1D("ElecPt", "pt(e)", 50, 0., 250.);
204  // electron multiplicity before std isolation
205  hists_["elecMult_"] = ibooker.book1D("ElecMult", "N_{30}(e)", 10, 0., 10.);
206  // electron multiplicity after std isolation
207  hists_["elecMultIso_"] = ibooker.book1D("ElecMultIso", "N_{Iso}(e)", 10, 0., 10.);
208  // multiplicity of jets with pt>20 (corrected to L2+L3)
209  hists_["jetMult_"] = ibooker.book1D("JetMult", "N_{30}(jet)", 10, 0., 10.);
210  // trigger efficiency estimates for single lepton triggers
211  hists_["triggerEff_"] = ibooker.book1D("TriggerEff",
212  "Eff(trigger)", nPaths, 0., nPaths);
213  // monitored trigger occupancy for single lepton triggers
214  hists_["triggerMon_"] = ibooker.book1D("TriggerMon",
215  "Mon(trigger)", nPaths, 0., nPaths);
216 
217  hists_["slimmedMETs_"] = ibooker.book1D("slimmedMETs", "MET_{slimmed}", 50, 0., 200.);
218 
219  // MET (calo)
220  hists_["slimmedMETsNoHF_"] = ibooker.book1D("slimmedMETsNoHF", "MET_{slimmedNoHF}", 50, 0., 200.);
221  // MET (pflow)
222  hists_["slimmedMETsPuppi_"] = ibooker.book1D("slimmedMETsPuppi", "MET_{slimmedPuppi}", 50, 0., 200.);
223  // W mass estimate
224  hists_["massW_"] = ibooker.book1D("MassW", "M(W)", 60, 0., 300.);
225  // Top mass estimate
226  hists_["massTop_"] = ibooker.book1D("MassTop", "M(Top)", 50, 0., 500.);
227  // W mass transverse estimate mu
228  hists_["MTWm_"] = ibooker.book1D("MTWm", "M_{T}^{W}(#mu)", 60, 0., 300.);
229  // Top mass transverse estimate mu
230  hists_["mMTT_"] = ibooker.book1D("mMTT", "M_{T}^{t}(#mu)", 50, 0., 500.);
231 
232  // W mass transverse estimate e
233  hists_["MTWe_"] = ibooker.book1D("MTWe", "M_{T}^{W}(e)", 60, 0., 300.);
234  // Top mass transverse estimate e
235  hists_["eMTT_"] = ibooker.book1D("eMTT", "M_{T}^{t}(e)", 50, 0., 500.);
236 
237  // set bin labels for trigger monitoring
239 
240  if (verbosity_ == STANDARD) return;
241 
242  // --- [VERBOSE] --- //
243 
244  // eta of the leading muon
245  hists_["muonEta_"] = ibooker.book1D("MuonEta", "#eta(#mu)", 30, -3., 3.);
246  // std isolation variable of the leading muon
247  hists_["muonPFRelIso_"] = ibooker.book1D("MuonPFRelIso",
248  "PFIso_{Rel}(#mu)", 50, 0., 1.);
249  hists_["muonRelIso_"] = ibooker.book1D("MuonRelIso", "Iso_{Rel}(#mu)", 50, 0., 1.);
250 
251  // eta of the leading electron
252  hists_["elecEta_"] = ibooker.book1D("ElecEta", "#eta(e)", 30, -3., 3.);
253  // std isolation variable of the leading electron
254  hists_["elecRelIso_"] = ibooker.book1D("ElecRelIso", "Iso_{Rel}(e)", 50, 0., 1.);
255  hists_["elecPFRelIso_"] = ibooker.book1D("ElecPFRelIso",
256  "PFIso_{Rel}(e)", 50, 0., 1.);
257 
258  // multiplicity of btagged jets (for track counting high efficiency) with
259  // pt(L2L3)>30
260  hists_["jetMultBEff_"] = ibooker.book1D("JetMultBEff",
261  "N_{30}(b/eff)", 10, 0., 10.);
262  // btag discriminator for track counting high efficiency for jets with
263  // pt(L2L3)>30
264  hists_["jetBDiscEff_"] = ibooker.book1D("JetBDiscEff",
265  "Disc_{b/eff}(jet)", 100, 0., 10.);
266 
267  // eta of the 1. leading jet
268  hists_["jet1Eta_"] = ibooker.book1D("Jet1Eta", "#eta (jet1)", 50, -5., 5.);
269  // eta of the 2. leading jet
270  hists_["jet2Eta_"] = ibooker.book1D("Jet2Eta", "#eta (jet2)", 50, -5., 5.);
271 
272  // pt of the 1. leading jet (corrected to L2+L3)
273  hists_["jet1Pt_"] = ibooker.book1D("Jet1Pt", "pt_{L2L3}(jet1)", 60, 0., 300.);
274  // pt of the 2. leading jet (corrected to L2+L3)
275  hists_["jet2Pt_"] = ibooker.book1D("Jet2Pt", "pt_{L2L3}(jet2)", 60, 0., 300.);
276 
277  // eta and pt of the b-tagged jet (filled only when nJets==2)
278  hists_["TaggedJetEta_"] = ibooker.book1D("TaggedJetEta",
279  "#eta (Tagged jet)", 50, -5., 5.);
280  hists_["TaggedJetPt_"] = ibooker.book1D("TaggedJetPt",
281  "pt_{L2L3}(Tagged jet)", 60, 0., 300.);
282 
283  // eta and pt of the jet not passing b-tag (filled only when nJets==2)
284  hists_["UnTaggedJetEta_"] = ibooker.book1D("UnTaggedJetEta",
285  "#eta (UnTagged jet)", 50, -5., 5.);
286  hists_["UnTaggedJetPt_"] = ibooker.book1D("UnTaggedJetPt",
287  "pt_{L2L3}(UnTagged jet)", 60, 0., 300.);
288 
289  // eta and pt of the most forward jet in the event with nJets==2
290  hists_["FwdJetEta_"] = ibooker.book1D("FwdJetEta", "#eta (Fwd jet)", 50, -5., 5.);
291  hists_["FwdJetPt_"] = ibooker.book1D("FwdJetPt",
292  "pt_{L2L3}(Fwd jet)", 60, 0., 300.);
293 
294  // 2D histogram (pt,eta) of the b-tagged jet (filled only when nJets==2)
295  hists_["TaggedJetPtEta_"] = ibooker.book2D("TaggedJetPt_Eta",
296  "(pt vs #eta)_{L2L3}(Tagged jet)", 60, 0., 300., 50, -5., 5.);
297 
298  // 2D histogram (pt,eta) of the not-b tagged jet (filled only when nJets==2)
299  hists_["UnTaggedJetPtEta_"] = ibooker.book2D("UnTaggedJetPt_Eta",
300  "(pt vs #eta)_{L2L3}(UnTagged jet)", 60, 0., 300., 50, -5., 5.);
301 
302 
303 
304  // dz for muons (to suppress cosmis)
305  hists_["muonDelZ_"] = ibooker.book1D("MuonDelZ", "d_{z}(#mu)", 50, -25., 25.);
306  // dxy for muons (to suppress cosmics)
307  hists_["muonDelXY_"] = ibooker.book2D("MuonDelXY",
308  "d_{xy}(#mu)", 50, -0.1, 0.1, 50, -0.1, 0.1);
309 
310  // set axes titles for dxy for muons
311  hists_["muonDelXY_"]->setAxisTitle("x [cm]", 1);
312  hists_["muonDelXY_"]->setAxisTitle("y [cm]", 2);
313 
314  if (verbosity_ == VERBOSE) return;
315 
316  // --- [DEBUG] --- //
317 
318  // relative muon isolation from charged hadrons for the leading muon
319  hists_["muonChHadIso_"] = ibooker.book1D("MuonChHadIso",
320  "Iso_{ChHad}(#mu)", 100, 0., 1.);
321  // relative muon isolation from neutral hadrons for the leading muon
322  hists_["muonNeuHadIso_"] = ibooker.book1D("MuonNeuHadIso",
323  "Iso_{NeuHad}(#mu)", 100, 0., 1.);
324  // relative muon isolation from photons for the leading muon
325  hists_["muonPhIso_"] = ibooker.book1D("MuonPhIso", "Iso_{Ph}(#mu)", 100, 0., 1.);
326 
327  // relative electron isolation from charged hadrons for the leading electron
328  hists_["elecChHadIso_"] = ibooker.book1D("ElecChHadIso",
329  "Iso_{ChHad}(e)", 100, 0., 1.);
330  // relative electron isolation from neutral hadrons for the leading electron
331  hists_["elecNeuHadIso_"] = ibooker.book1D("ElecNeuHadIso",
332  "Iso_{NeuHad}(e)", 100, 0., 1.);
333  // relative electron isolation from photons for the leading electron
334  hists_["elecPhIso_"] = ibooker.book1D("ElecPhIso", "Iso_{Ph}(e)", 100, 0., 1.);
335 
336  // multiplicity of btagged jets (for track counting high purity) with
337  // pt(L2L3)>30
338  hists_["jetMultBPur_"] = ibooker.book1D("JetMultBPur",
339  "N_{30}(b/pur)", 10, 0., 10.);
340  // btag discriminator for track counting high purity
341  hists_["jetBDiscPur_"] = ibooker.book1D("JetBDiscPur",
342  "Disc_{b/pur}(Jet)", 200, -10., 10.);
343  // btag discriminator for track counting high purity for 1. leading jet
344  hists_["jet1BDiscPur_"] = ibooker.book1D("Jet1BDiscPur",
345  "Disc_{b/pur}(Jet1)", 200, -10., 10.);
346  // btag discriminator for track counting high purity for 2. leading jet
347  hists_["jet2BDiscPur_"] = ibooker.book1D("Jet2BDiscPur",
348  "Disc_{b/pur}(Jet2)", 200, -10., 10.);
349 
350  // multiplicity of btagged jets (for simple secondary vertex) with pt(L2L3)>30
351  hists_["jetMultBVtx_"] = ibooker.book1D("JetMultBVtx",
352  "N_{30}(b/vtx)", 10, 0., 10.);
353  // btag discriminator for simple secondary vertex
354  hists_["jetBDiscVtx_"] = ibooker.book1D("JetBDiscVtx",
355  "Disc_{b/vtx}(Jet)", 35, -1., 6.);
356 
357  // multiplicity of btagged jets (for combined secondary vertex) with
358  // pt(L2L3)>30
359  hists_["jetMultBCombVtx_"] = ibooker.book1D("JetMultBCombVtx",
360  "N_{30}(b/CSV)", 10, 0., 10.);
361  // btag discriminator for combined secondary vertex
362  hists_["jetBDiscCombVtx_"] = ibooker.book1D("JetBDiscCombVtx",
363  "Disc_{b/CSV}(Jet)", 60, -1., 2.);
364  // btag discriminator for combined secondary vertex for 1. leading jet
365  hists_["jet1BDiscCombVtx_"] = ibooker.book1D("Jet1BDiscCombVtx",
366  "Disc_{b/CSV}(Jet1)", 60, -1., 2.);
367  // btag discriminator for combined secondary vertex for 2. leading jet
368  hists_["jet2BDiscCombVtx_"] = ibooker.book1D("Jet2BDiscCombVtx",
369  "Disc_{b/CSV}(Jet2)", 60, -1., 2.);
370 
371  // pt of the 1. leading jet (uncorrected)
372  hists_["jet1PtRaw_"] = ibooker.book1D("Jet1PtRaw", "pt_{Raw}(jet1)", 60, 0., 300.);
373  // pt of the 2. leading jet (uncorrected)
374  hists_["jet2PtRaw_"] = ibooker.book1D("Jet2PtRaw", "pt_{Raw}(jet2)", 60, 0., 300.);
375 
376  // selected events
377  hists_["eventLogger_"] = ibooker.book2D("EventLogger",
378  "Logged Events", 9, 0., 9., 10, 0., 10.);
379 
380  // set axes titles for selected events
381  hists_["eventLogger_"]->getTH1()->SetOption("TEXT");
382  hists_["eventLogger_"]->setBinLabel(1, "Run", 1);
383  hists_["eventLogger_"]->setBinLabel(2, "Block", 1);
384  hists_["eventLogger_"]->setBinLabel(3, "Event", 1);
385  hists_["eventLogger_"]->setBinLabel(4, "pt_{L2L3}(jet1)", 1);
386  hists_["eventLogger_"]->setBinLabel(5, "pt_{L2L3}(jet2)", 1);
387  hists_["eventLogger_"]->setBinLabel(6, "pt_{L2L3}(jet3)", 1);
388  hists_["eventLogger_"]->setBinLabel(7, "pt_{L2L3}(jet4)", 1);
389  hists_["eventLogger_"]->setBinLabel(8, "M_{W}", 1);
390  hists_["eventLogger_"]->setBinLabel(9, "M_{Top}", 1);
391  hists_["eventLogger_"]->setAxisTitle("logged evts", 2);
392  return;
393 }
394 
396  const edm::EventSetup& setup) {
397  // fetch trigger event if configured such
400  if (!event.getByToken(triggerTable_, triggerTable)) return;
401  }
402  /*
403  ------------------------------------------------------------
404 
405  Primary Vertex Monitoring
406 
407  ------------------------------------------------------------
408  */
409 
410  // fill monitoring plots for primary vertices
412  if (!event.getByToken(pvs_, pvs)) return;
413  unsigned int pvMult = 0;
414  for (edm::View<reco::Vertex>::const_iterator pv = pvs->begin();
415  pv != pvs->end(); ++pv) {
416  if (!pvSelect_ || (*pvSelect_)(*pv)) pvMult++;
417  }
418  fill("pvMult_", pvMult);
419 
420  /*
421  ------------------------------------------------------------
422 
423  Electron Monitoring
424 
425  ------------------------------------------------------------
426  */
427 
428  // fill monitoring plots for electrons
430 
431 
432 
433 
434 
435 
436  if (!event.getByToken(elecs_gsf_, elecs_gsf)) return;
437 
438  // loop electron collection
439  unsigned int eMult = 0, eMultIso = 0;
440  std::vector<const pat::Electron*> isoElecs;
442 
443  unsigned int idx_gsf = 0;
444  for ( edm::View<pat::Electron>::const_iterator elec = elecs_gsf->begin(); elec != elecs_gsf->end(); ++elec) {
445 
446  if (true){
447  if ((*elecSelect)(*elec)) {
448  double isolationRel =
449  (elec->dr03TkSumPt() + elec->dr03EcalRecHitSumEt() +
450  elec->dr03HcalTowerSumEt()) /
451  elec->pt();
452 
453  double isolationChHad =
454  elec->pt() /
455  (elec->pt() + elec->pfIsolationVariables().sumChargedHadronPt);
456  double isolationNeuHad =
457  elec->pt() /
458  (elec->pt() + elec->pfIsolationVariables().sumNeutralHadronEt);
459  double isolationPhoton =
460  elec->pt() /
461  (elec->pt() + elec->pfIsolationVariables().sumPhotonEt);
462  double el_ChHadIso = elec->pfIsolationVariables().sumChargedHadronPt;
463  double el_NeHadIso = elec->pfIsolationVariables().sumNeutralHadronEt;
464  double el_PhIso = elec->pfIsolationVariables().sumPhotonEt;
465  double PFisolationRel =
466  (el_ChHadIso +
467  max(0., el_NeHadIso + el_PhIso -
468  0.5 * elec->pfIsolationVariables().sumPUPt)) /
469  elec->pt();
470 
471  if (eMult == 0) {
472  fill("elecPt_", elec->pt());
473  fill("elecEta_", elec->eta());
474  fill("elecRelIso_", isolationRel);
475  fill("elecPFRelIso_", PFisolationRel);
476  fill("elecChHadIso_", isolationChHad);
477  fill("elecNeuHadIso_", isolationNeuHad);
478  fill("elecPhIso_", isolationPhoton);
479  }
480 
481  ++eMult;
482  if ((*elecIso)(*elec)) {
483  if (eMultIso == 0) e = *elec;
484  isoElecs.push_back(&(*elec));
485  ++eMultIso;
486  }
487  }
488  }
489  idx_gsf++;
490  }
491 
492  fill("elecMult_", eMult);
493  fill("elecMultIso_", eMultIso);
494 
495  /*
496  ------------------------------------------------------------
497 
498  Muon Monitoring
499 
500  ------------------------------------------------------------
501  */
502 
503  // fill monitoring plots for muons
504  unsigned int mMult = 0, mMultIso = 0;
505 
507 
508  pat::Muon mu;
509 
510  if (!event.getByToken(muons_, muons)) return;
511  for (edm::View<pat::Muon>::const_iterator muon = muons->begin(); muon != muons->end();
512  ++muon) {
513 
514  // restrict to globalMuons
515  if (muon->isGlobalMuon()) {
516  fill("muonDelZ_", muon->globalTrack()->vz());
517  fill("muonDelXY_", muon->globalTrack()->vx(), muon->globalTrack()->vy());
518 
519  // apply selection
520  if ((*muonSelect)(*muon)) {
521 
522  double isolationRel =
523  (muon->isolationR03().sumPt + muon->isolationR03().emEt +
524  muon->isolationR03().hadEt) /
525  muon->pt();
526  double isolationChHad =
527  muon->pt() /
528  (muon->pt() + muon->pfIsolationR04().sumChargedHadronPt);
529  double isolationNeuHad =
530  muon->pt() /
531  (muon->pt() + muon->pfIsolationR04().sumNeutralHadronEt);
532  double isolationPhoton =
533  muon->pt() / (muon->pt() + muon->pfIsolationR04().sumPhotonEt);
534  double PFisolationRel = (muon->pfIsolationR04().sumChargedHadronPt +
535  muon->pfIsolationR04().sumNeutralHadronEt +
536  muon->pfIsolationR04().sumPhotonEt) /
537  muon->pt();
538 
539  if (mMult == 0) {
540  // restrict to leading muon
541  fill("muonPt_", muon->pt());
542  fill("muonEta_", muon->eta());
543  fill("muonRelIso_", isolationRel);
544  fill("muonChHadIso_", isolationChHad);
545  fill("muonNeuHadIso_", isolationNeuHad);
546  fill("muonPhIso_", isolationPhoton);
547  fill("muonPFRelIso_", PFisolationRel);
548  }
549  ++mMult;
550 
551  if ((*muonIso)(*muon)) {
552  if (mMultIso == 0) mu = *muon;
553  ++mMultIso;
554  }
555  }
556  }
557  }
558  fill("muonMult_", mMult);
559  fill("muonMultIso_", mMultIso);
560 
561  /*
562  ------------------------------------------------------------
563 
564  Jet Monitoring
565 
566  ------------------------------------------------------------
567  */
568 
569  // loop jet collection
570  std::vector<pat::Jet> correctedJets;
571  unsigned int mult = 0, multBEff = 0, multBPur = 0, multNoBPur = 0,
572  multBVtx = 0, multBCombVtx = 0;
573 
575  if (!event.getByToken(jets_, jets)) return;
576 
577  vector<double> bJetDiscVal;
578  vector<double> NobJetDiscVal;
579  pat::Jet TaggedJetCand;
580  pat::Jet UnTaggedJetCand;
581  pat::Jet FwdJetCand;
582  for (edm::View<pat::Jet>::const_iterator jet = jets->begin();
583  jet != jets->end(); ++jet) {
584 
585  pat::Jet sel = *jet;
586 
587  if ( jetSelectJet==nullptr)
589 
590  if (!((*jetSelectJet)(sel))) continue;
591 
592  // prepare jet to fill monitor histograms
593  pat::Jet monitorJet = *jet;
594  correctedJets.push_back(monitorJet);
595 
596  ++mult; // determine jet multiplicity
597 
598 
599  fill("jetBDiscEff_", monitorJet.bDiscriminator("pfCombinedInclusiveSecondaryVertexV2BJetTags")); //hard coded discriminator and value right now.
600  if (monitorJet.bDiscriminator("pfCombinedInclusiveSecondaryVertexV2BJetTags") > 0.89) ++multBEff;
601 
602 
603 
604  if (monitorJet.bDiscriminator("pfCombinedInclusiveSecondaryVertexV2BJetTags") > 0.89) {
605  if (multBPur == 0) {
606  TaggedJetCand = monitorJet;
607  bJetDiscVal.push_back(monitorJet.bDiscriminator("pfCombinedInclusiveSecondaryVertexV2BJetTags"));
608 
609  } else if (multBPur == 1) {
610  bJetDiscVal.push_back(monitorJet.bDiscriminator("pfCombinedInclusiveSecondaryVertexV2BJetTags"));
611  if (bJetDiscVal[1] > bJetDiscVal[0]) TaggedJetCand = monitorJet;
612  }
613  ++multBPur;
614  } else {
615  if (multNoBPur == 0) {
616  UnTaggedJetCand = monitorJet;
617  NobJetDiscVal.push_back(monitorJet.bDiscriminator("pfCombinedInclusiveSecondaryVertexV2BJetTags"));
618 
619  } else if (multNoBPur == 1) {
620  NobJetDiscVal.push_back(monitorJet.bDiscriminator("pfCombinedInclusiveSecondaryVertexV2BJetTags"));
621  if (NobJetDiscVal[1] < NobJetDiscVal[0]) UnTaggedJetCand = monitorJet;
622  }
623 
624  ++multNoBPur;
625  }
626 
627 
628  if (monitorJet.bDiscriminator("pfCombinedInclusiveSecondaryVertexV2BJetTags") > 0.89) ++multBEff;
629  if (mult == 1) {
630  fill("jet1BDiscPur_", monitorJet.bDiscriminator("pfCombinedInclusiveSecondaryVertexV2BJetTags"));
631  } else if (mult == 2) {
632  fill("jet2BDiscPur_", monitorJet.bDiscriminator("pfCombinedInclusiveSecondaryVertexV2BJetTags"));
633  }
634 
635  fill("jetBDiscPur_", monitorJet.bDiscriminator("pfCombinedInclusiveSecondaryVertexV2BJetTags"));
636 
637 
638  // fill pt (raw or L2L3) for the leading jets
639  if (mult == 1) {
640  fill("jet1Pt_", monitorJet.pt());
641  fill("jet1Eta_", monitorJet.eta());
642  fill("jet1PtRaw_", jet->pt());
643  FwdJetCand = monitorJet;
644  }
645 
646  if (mult == 2) {
647  fill("jet2Pt_", monitorJet.pt());
648  fill("jet2Eta_", monitorJet.eta());
649  fill("jet2PtRaw_", jet->pt());
650 
651  if (abs(monitorJet.eta()) > abs(FwdJetCand.eta())) {
652  FwdJetCand = monitorJet;
653  }
654 
655  fill("FwdJetPt_", FwdJetCand.pt());
656  fill("FwdJetEta_", FwdJetCand.eta());
657  }
658  }
659 
660  if (multNoBPur == 1 && multBPur == 1) {
661 
662  fill("TaggedJetPtEta_", TaggedJetCand.pt(), TaggedJetCand.eta());
663  fill("UnTaggedJetPtEta_", UnTaggedJetCand.pt(), UnTaggedJetCand.eta());
664 
665  fill("TaggedJetPt_", TaggedJetCand.pt());
666  fill("TaggedJetEta_", TaggedJetCand.eta());
667  fill("UnTaggedJetPt_", UnTaggedJetCand.pt());
668  fill("UnTaggedJetEta_", UnTaggedJetCand.eta());
669  }
670 
671  fill("jetMult_", mult);
672  fill("jetMultBEff_", multBEff);
673  fill("jetMultBPur_", multBPur);
674  fill("jetMultBVtx_", multBVtx);
675  fill("jetMultBCombVtx_", multBCombVtx);
676 
677  /*
678  ------------------------------------------------------------
679 
680  MET Monitoring
681 
682  ------------------------------------------------------------
683  */
684 
685  // fill monitoring histograms for met
686  pat::MET mET;
687 
688  for (std::vector<edm::EDGetTokenT<edm::View<pat::MET>>>::const_iterator
689  met_ = mets_.begin();
690  met_ != mets_.end(); ++met_) {
692  if (!event.getByToken(*met_, met)) continue;
693  mET = *(met->begin());
694  if (met->begin() != met->end()) {
695  unsigned int idx = met_ - mets_.begin();
696  if (idx == 0) fill("slimmedMETs_", met->begin()->et());
697  if (idx == 1) fill("slimmedMETsNoHF_", met->begin()->et());
698  if (idx == 2) fill("slimmedMETsPuppi_", met->begin()->et());
699 
700  }
701  }
702 
703  /*
704  ------------------------------------------------------------
705 
706  Event Monitoring
707 
708  ------------------------------------------------------------
709  */
710 
711  // fill W boson and top mass estimates
712  Calculate_miniAOD eventKinematics(MAXJETS, WMASS);
713  double wMass = eventKinematics.massWBoson(correctedJets);
714  double topMass = eventKinematics.massTopQuark(correctedJets);
715  if (wMass >= 0 && topMass >= 0) {
716  fill("massW_", wMass);
717  fill("massTop_", topMass);
718  }
719  // fill plots for trigger monitoring
720  if ((lowerEdge_ == -1. && upperEdge_ == -1.) ||
721  (lowerEdge_ < wMass && wMass < upperEdge_)) {
723  fill(event, *triggerTable, "trigger", triggerPaths_);
724  if (logged_ <= hists_.find("eventLogger_")->second->getNbinsY()) {
725  // log runnumber, lumi block, event number & some
726  // more pysics infomation for interesting events
727  fill("eventLogger_", 0.5, logged_ + 0.5, event.eventAuxiliary().run());
728  fill("eventLogger_", 1.5, logged_ + 0.5,
729  event.eventAuxiliary().luminosityBlock());
730  fill("eventLogger_", 2.5, logged_ + 0.5, event.eventAuxiliary().event());
731  if (!correctedJets.empty())
732  fill("eventLogger_", 3.5, logged_ + 0.5, correctedJets[0].pt());
733  if (correctedJets.size() > 1)
734  fill("eventLogger_", 4.5, logged_ + 0.5, correctedJets[1].pt());
735  if (correctedJets.size() > 2)
736  fill("eventLogger_", 5.5, logged_ + 0.5, correctedJets[2].pt());
737  if (correctedJets.size() > 3)
738  fill("eventLogger_", 6.5, logged_ + 0.5, correctedJets[3].pt());
739  fill("eventLogger_", 7.5, logged_ + 0.5, wMass);
740  fill("eventLogger_", 8.5, logged_ + 0.5, topMass);
741  ++logged_;
742  }
743  }
744  if (multBPur != 0 && mMultIso == 1) {
745 
746  double mtW = eventKinematics.tmassWBoson(&mu, mET, TaggedJetCand);
747  fill("MTWm_", mtW);
748  double MTT = eventKinematics.tmassTopQuark(&mu, mET, TaggedJetCand);
749  fill("mMTT_", MTT);
750  }
751 
752  if (multBPur != 0 && eMultIso == 1) {
753  double mtW = eventKinematics.tmassWBoson(&e, mET, TaggedJetCand);
754  fill("MTWe_", mtW);
755  double MTT = eventKinematics.tmassTopQuark(&e, mET, TaggedJetCand);
756  fill("eMTT_", MTT);
757  }
758 }
759 }
760 
762  const edm::ParameterSet& cfg)
763  : vertexSelect_(nullptr),
764  beamspot_(""),
765  beamspotSelect_(nullptr),
766  muonStep_(nullptr),
767  electronStep_(nullptr),
768  pvStep_(nullptr),
769  metStep_(nullptr) {
770  jetSteps_.clear();
771 
772 
773  // configure preselection
774  edm::ParameterSet presel =
775  cfg.getParameter<edm::ParameterSet>("preselection");
776  if (presel.existsAs<edm::ParameterSet>("trigger")) {
778  presel.getParameter<edm::ParameterSet>("trigger");
779  triggerTable__ = consumes<edm::TriggerResults>(
780  trigger.getParameter<edm::InputTag>("src"));
781  triggerPaths_ = trigger.getParameter<std::vector<std::string>>("select");
782  }
783  if (presel.existsAs<edm::ParameterSet>("vertex")) {
784  edm::ParameterSet vertex = presel.getParameter<edm::ParameterSet>("vertex");
785  vertex_ = vertex.getParameter<edm::InputTag>("src");
786  vertex__ =
787  consumes<reco::Vertex>(vertex.getParameter<edm::InputTag>("src"));
789  vertex.getParameter<std::string>("select")));
790  }
791  if (presel.existsAs<edm::ParameterSet>("beamspot")) {
793  presel.getParameter<edm::ParameterSet>("beamspot");
794  beamspot_ = beamspot.getParameter<edm::InputTag>("src");
795  beamspot__ =
796  consumes<reco::BeamSpot>(beamspot.getParameter<edm::InputTag>("src"));
798  beamspot.getParameter<std::string>("select")));
799  }
800  // conifgure the selection
801  std::vector<edm::ParameterSet> sel =
802  cfg.getParameter<std::vector<edm::ParameterSet>>("selection");
803 
804  for (unsigned int i = 0; i < sel.size(); ++i) {
805  selectionOrder_.push_back(sel.at(i).getParameter<std::string>("label"));
806  selection_[selectionStep(selectionOrder_.back())] = std::make_pair(
807  sel.at(i),
808  std::unique_ptr<SingleTopTChannelLepton_miniAOD::MonitorEnsemble>(
810  selectionStep(selectionOrder_.back()).c_str(),
811  cfg.getParameter<edm::ParameterSet>("setup"),
812  cfg.getParameter<std::vector<edm::ParameterSet>>("selection"),
813  consumesCollector())));
814  }
815  for (std::vector<std::string>::const_iterator selIt = selectionOrder_.begin();
816  selIt != selectionOrder_.end(); ++selIt) {
817  std::string key = selectionStep(*selIt), type = objectType(*selIt);
818  if (selection_.find(key) != selection_.end()) {
819  using std::unique_ptr;
820 
821  if (type == "muons") {
823  consumesCollector()));
824  }
825  if (type == "elecs") {
828  }
829 
830  if (type == "pvs") {
832  consumesCollector()));
833  }
834  if (type == "jets") {
835  jetSteps_.push_back(std::unique_ptr<SelectionStep<pat::Jet>>(
837  consumesCollector())));
838  }
839  if (type == "met") {
841  consumesCollector()));
842  }
843  }
844  }
845 }
847  edm::Run const &, edm::EventSetup const & ){
848 
849  for (auto selIt = selection_.begin(); selIt != selection_.end(); ++selIt) {
850  selIt->second.second->book(ibooker);
851  }
852 }
854  const edm::EventSetup& setup) {
857  if (!event.getByToken(triggerTable__, triggerTable)) return;
858  if (!accept(event, *triggerTable, triggerPaths_)) return;
859  }
860  if (!beamspot__.isUninitialized()) {
862  if (!event.getByToken(beamspot__, beamspot)) return;
863  if (!(*beamspotSelect_)(*beamspot)) return;
864  }
865 
866  if (!vertex__.isUninitialized()) {
868  if (!event.getByToken(vertex__, vertex)) return;
870  if (!(*vertexSelect_)(*pv)) return;
871  }
872 
873  // apply selection steps
874  unsigned int passed = 0;
875  unsigned int nJetSteps = -1;
876 
877  for (std::vector<std::string>::const_iterator selIt = selectionOrder_.begin();
878  selIt != selectionOrder_.end(); ++selIt) {
879  std::string key = selectionStep(*selIt), type = objectType(*selIt);
880  if (selection_.find(key) != selection_.end()) {
881  if (type == "empty") {
882  selection_[key].second->fill(event, setup);
883  }
884  if (type == "presel") {
885  selection_[key].second->fill(event, setup);
886  }
887  if (type == "elecs" && electronStep_ != nullptr) {
888  if (electronStep_->select(event)) {
889  ++passed;
890  selection_[key].second->fill(event, setup);
891  } else
892  break;
893  }
894  if (type == "muons" && muonStep_ != nullptr) {
895  if (muonStep_->select(event)) {
896  ++passed;
897  selection_[key].second->fill(event, setup);
898  } else
899  break;
900  }
901  if (type == "jets") {
902  nJetSteps++;
903  if (jetSteps_[nJetSteps]) {
904  if (jetSteps_[nJetSteps]->select(event, setup)) {
905  ++passed;
906  selection_[key].second->fill(event, setup);
907  } else
908  break;
909  }
910  }
911  if (type == "met" && metStep_ != nullptr) {
912  if (metStep_->select(event)) {
913  ++passed;
914  selection_[key].second->fill(event, setup);
915  } else
916  break;
917  }
918  }
919  }
920 }
type
Definition: HCALResponse.h:21
Analysis-level MET class.
Definition: MET.h:43
std::unique_ptr< SelectionStep< pat::Electron > > electronStep_
T getParameter(std::string const &) const
edm::EDGetTokenT< edm::ValueMap< float > > electronId_
electronId label
EventAuxiliary const & eventAuxiliary() const override
Definition: Event.h:92
edm::EDGetTokenT< edm::View< pat::Electron > > elecs_gsf_
edm::EDGetTokenT< edm::TriggerResults > triggerTable_
trigger table
double eta() const final
momentum pseudorapidity
bool existsAs(std::string const &parameterName, bool trackiness=true) const
checks if a parameter exists as a given type
Definition: ParameterSet.h:186
bool getByToken(EDGetToken token, Handle< PROD > &result) const
Definition: Event.h:519
std::vector< ParameterSet > VParameterSet
Definition: ParameterSet.h:33
std::unique_ptr< StringCutObjectSelector< reco::JetID > > jetIDSelect_
extra jetID selection on calo jets
void triggerBinLabels(std::string channel, const std::vector< std::string > labels)
set configurable labels for trigger monitoring histograms
RunNumber_t run() const
def setup(process, global_tag, zero_tesla=False)
Definition: GeneralSetup.py:1
double pt() const final
transverse momentum
std::unique_ptr< StringCutObjectSelector< pat::Muon, true > > muonIso
std::map< std::string, std::pair< edm::ParameterSet, std::unique_ptr< SingleTopTChannelLepton_miniAOD::MonitorEnsemble > > > selection_
float bDiscriminator(const std::string &theLabel) const
-— methods for accessing b-tagging info -—
#define nullptr
bool accept(const edm::Event &event, const edm::TriggerResults &triggerTable, const std::string &triggerPath)
Definition: TopDQMHelpers.h:30
LuminosityBlockNumber_t luminosityBlock() const
edm::EDGetTokenT< edm::View< pat::Jet > > jets_
input sources for monitoring
std::unique_ptr< StringCutObjectSelector< pat::Electron, true > > elecSelect
void fill(const edm::Event &event, const edm::EventSetup &setup)
fill monitor histograms with electronId and jetCorrections
void analyze(const edm::Event &event, const edm::EventSetup &setup) override
do this during the event loop
std::string selectionStep(const std::string &label)
ConsumesCollector consumesCollector()
Use a ConsumesCollector to gather consumes information from helper functions.
vector< PseudoJet > jets
std::unique_ptr< SelectionStep< pat::MET > > metStep_
std::unique_ptr< StringCutObjectSelector< reco::Vertex > > pvSelect_
MonitorElement * book1D(Args &&...args)
Definition: DQMStore.h:118
def pv(vc)
Definition: MetAnalyzer.py:6
std::string objectType(const std::string &label)
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
std::unique_ptr< SelectionStep< pat::Muon > > muonStep_
const int mu
Definition: Constants.h:22
std::string muonIso_
extra isolation criterion on muon
std::vector< std::unique_ptr< SelectionStep< pat::Jet > > > jetSteps_
edm::EDGetTokenT< reco::JetIDValueMap > jetIDLabel_
jetID as an extra selection type
std::vector< std::string > triggerPaths_
trigger paths
std::unique_ptr< StringCutObjectSelector< pat::Muon, true > > muonSelect
void book(DQMStore::IBooker &ibooker)
book histograms in subdirectory directory
void setCurrentFolder(const std::string &fullpath)
Definition: DQMStore.cc:279
MonitorElement * book2D(Args &&...args)
Definition: DQMStore.h:136
met
===> hadronic RAZOR
Analysis-level electron class.
Definition: Electron.h:52
Analysis-level calorimeter jet class.
Definition: Jet.h:80
void bookHistograms(DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
Templated helper class to allow a selection on a certain object collection.
boost::indirect_iterator< typename seq_t::const_iterator > const_iterator
Definition: View.h:86
std::unique_ptr< StringCutObjectSelector< pat::Jet > > jetSelectJet
std::unique_ptr< StringCutObjectSelector< reco::Vertex > > vertexSelect_
string cut selector
std::unique_ptr< StringCutObjectSelector< pat::Electron, true > > elecIso
std::unique_ptr< StringCutObjectSelector< reco::BeamSpot > > beamspotSelect_
string cut selector
bool isUninitialized() const
Definition: EDGetToken.h:73
std::vector< edm::EDGetTokenT< edm::View< pat::MET > > > mets_
considers a vector of METs
SingleTopTChannelLeptonDQM_miniAOD(const edm::ParameterSet &cfg)
default constructor
edm::EDGetTokenT< edm::TriggerResults > triggerTable__
trigger table
std::unique_ptr< SelectionStep< reco::Vertex > > pvStep_
Analysis-level muon class.
Definition: Muon.h:50
EventNumber_t event() const
std::string elecIso_
extra isolation criterion on electron
Definition: event.py:1
Definition: Run.h:43