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PFAlgo.cc
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6 
7 #include "TDecompChol.h"
8 
9 #include <numeric>
10 #include <fstream>
11 
12 using namespace std;
13 using namespace reco;
14 
15 PFAlgo::PFAlgo(double nSigmaECAL,
16  double nSigmaHCAL,
17  double nSigmaHFEM,
18  double nSigmaHFHAD,
19  std::vector<double> resolHF_square,
21  PFEnergyCalibrationHF& thepfEnergyCalibrationHF,
22  const edm::ParameterSet& pset)
23  : pfCandidates_(new PFCandidateCollection),
24  nSigmaECAL_(nSigmaECAL),
25  nSigmaHCAL_(nSigmaHCAL),
26  nSigmaHFEM_(nSigmaHFEM),
27  nSigmaHFHAD_(nSigmaHFHAD),
28  resolHF_square_(resolHF_square),
29  calibration_(calibration),
30  thepfEnergyCalibrationHF_(thepfEnergyCalibrationHF),
31  connector_() {
32  const edm::ParameterSet pfMuonAlgoParams = pset.getParameter<edm::ParameterSet>("PFMuonAlgoParameters");
33  bool postMuonCleaning = pset.getParameter<bool>("postMuonCleaning");
34  pfmu_ = std::make_unique<PFMuonAlgo>(pfMuonAlgoParams, postMuonCleaning);
35 
36  // HF resolution parameters
37  assert(resolHF_square_.size() == 3); // make sure that stochastic, constant, noise (i.e. three) terms are specified.
38 
39  // Muon parameters
40  muonHCAL_ = pset.getParameter<std::vector<double>>("muon_HCAL");
41  muonECAL_ = pset.getParameter<std::vector<double>>("muon_ECAL");
42  muonHO_ = pset.getParameter<std::vector<double>>("muon_HO");
43  assert(muonHCAL_.size() == 2 && muonECAL_.size() == 2 && muonHO_.size() == 2);
44  nSigmaTRACK_ = pset.getParameter<double>("nsigma_TRACK");
45  ptError_ = pset.getParameter<double>("pt_Error");
46  factors45_ = pset.getParameter<std::vector<double>>("factors_45");
47  assert(factors45_.size() == 2);
48 
49  // Bad Hcal Track Parameters
50  goodTrackDeadHcal_ptErrRel_ = pset.getParameter<double>("goodTrackDeadHcal_ptErrRel");
51  goodTrackDeadHcal_chi2n_ = pset.getParameter<double>("goodTrackDeadHcal_chi2n");
52  goodTrackDeadHcal_layers_ = pset.getParameter<uint32_t>("goodTrackDeadHcal_layers");
53  goodTrackDeadHcal_validFr_ = pset.getParameter<double>("goodTrackDeadHcal_validFr");
54  goodTrackDeadHcal_dxy_ = pset.getParameter<double>("goodTrackDeadHcal_dxy");
55 
56  goodPixelTrackDeadHcal_minEta_ = pset.getParameter<double>("goodPixelTrackDeadHcal_minEta");
57  goodPixelTrackDeadHcal_maxPt_ = pset.getParameter<double>("goodPixelTrackDeadHcal_maxPt");
58  goodPixelTrackDeadHcal_ptErrRel_ = pset.getParameter<double>("goodPixelTrackDeadHcal_ptErrRel");
59  goodPixelTrackDeadHcal_chi2n_ = pset.getParameter<double>("goodPixelTrackDeadHcal_chi2n");
60  goodPixelTrackDeadHcal_maxLost3Hit_ = pset.getParameter<int32_t>("goodPixelTrackDeadHcal_maxLost3Hit");
61  goodPixelTrackDeadHcal_maxLost4Hit_ = pset.getParameter<int32_t>("goodPixelTrackDeadHcal_maxLost4Hit");
62  goodPixelTrackDeadHcal_dxy_ = pset.getParameter<double>("goodPixelTrackDeadHcal_dxy");
63  goodPixelTrackDeadHcal_dz_ = pset.getParameter<double>("goodPixelTrackDeadHcal_dz");
64 }
65 
67 
68 void PFAlgo::setEGammaParameters(bool use_EGammaFilters, bool useProtectionsForJetMET) {
69  useEGammaFilters_ = use_EGammaFilters;
70 
71  if (!useEGammaFilters_)
72  return;
73 
75 }
77  const edm::ValueMap<reco::GsfElectronRef>& valueMapGedElectrons,
78  const edm::ValueMap<reco::PhotonRef>& valueMapGedPhotons) {
79  if (useEGammaFilters_) {
81  valueMapGedElectrons_ = &valueMapGedElectrons;
82  valueMapGedPhotons_ = &valueMapGedPhotons;
83  }
84 }
85 
88  minHFCleaningPt_ = pfHFCleaningParams.getParameter<double>("minHFCleaningPt");
89  minSignificance_ = pfHFCleaningParams.getParameter<double>("minSignificance");
90  maxSignificance_ = pfHFCleaningParams.getParameter<double>("maxSignificance");
91  minSignificanceReduction_ = pfHFCleaningParams.getParameter<double>("minSignificanceReduction");
92  maxDeltaPhiPt_ = pfHFCleaningParams.getParameter<double>("maxDeltaPhiPt");
93  minDeltaMet_ = pfHFCleaningParams.getParameter<double>("minDeltaMet");
94 }
95 
99  bool usePFConversions,
100  bool usePFDecays,
101  double dptRel_DispVtx) {
108 }
109 
112 
113  //Set the vertices for muon cleaning
114  pfmu_->setInputsForCleaning(primaryVertices);
115 
116  //Now find the primary vertex!
117  bool primaryVertexFound = false;
118  nVtx_ = primaryVertices.size();
119  for (auto const& vertex : primaryVertices) {
120  if (vertex.isValid() && (!vertex.isFake())) {
122  primaryVertexFound = true;
123  break;
124  }
125  }
126  //Use vertices if the user wants to but only if it exists a good vertex
127  useVertices_ = useVertex && primaryVertexFound;
128 }
129 
130 void PFAlgo::reconstructParticles(const reco::PFBlockHandle& blockHandle, PFEGammaFilters const* pfegamma) {
131  auto const& blocks = *blockHandle;
132 
133  // reset output collection
134  pfCandidates_->clear();
135 
136  LogTrace("PFAlgo|reconstructParticles")
137  << "start of function PFAlgo::reconstructParticles, blocks.size()=" << blocks.size();
138 
139  // sort elements in three lists:
140  std::list<reco::PFBlockRef> hcalBlockRefs;
141  std::list<reco::PFBlockRef> ecalBlockRefs;
142  std::list<reco::PFBlockRef> hoBlockRefs;
143  std::list<reco::PFBlockRef> otherBlockRefs;
144 
145  for (unsigned i = 0; i < blocks.size(); ++i) {
146  reco::PFBlockRef blockref = reco::PFBlockRef(blockHandle, i);
147 
148  const reco::PFBlock& block = *blockref;
150 
151  bool singleEcalOrHcal = false;
152  if (elements.size() == 1) {
154  ecalBlockRefs.push_back(blockref);
155  singleEcalOrHcal = true;
156  }
158  hcalBlockRefs.push_back(blockref);
159  singleEcalOrHcal = true;
160  }
161  if (elements[0].type() == reco::PFBlockElement::HO) {
162  // Single HO elements are likely to be noise. Not considered for now.
163  hoBlockRefs.push_back(blockref);
164  singleEcalOrHcal = true;
165  }
166  }
167 
168  if (!singleEcalOrHcal) {
169  otherBlockRefs.push_back(blockref);
170  }
171  } //loop blocks
172 
173  LogTrace("PFAlgo|reconstructParticles")
174  << "# Ecal blocks: " << ecalBlockRefs.size() << ", # Hcal blocks: " << hcalBlockRefs.size()
175  << ", # HO blocks: " << hoBlockRefs.size() << ", # Other blocks: " << otherBlockRefs.size();
176 
177  // loop on blocks that are not single ecal,
178  // and not single hcal.
179 
180  unsigned nblcks = 0;
181  for (auto const& other : otherBlockRefs) {
182  LogTrace("PFAlgo|reconstructParticles") << "processBlock, Block number " << nblcks++;
183  processBlock(other, hcalBlockRefs, ecalBlockRefs, pfegamma);
184  }
185 
186  std::list<reco::PFBlockRef> empty;
187 
188  unsigned hblcks = 0;
189  // process remaining single hcal blocks
190  for (auto const& hcal : hcalBlockRefs) {
191  LogTrace("PFAlgo|reconstructParticles") << "processBlock, HCAL block number " << hblcks++;
192  processBlock(hcal, empty, empty, pfegamma);
193  }
194 
195  unsigned eblcks = 0;
196  // process remaining single ecal blocks
197  for (auto const& ecal : ecalBlockRefs) {
198  LogTrace("PFAlgo|reconstructParticles") << "processBlock, ECAL block number " << eblcks++;
199  processBlock(ecal, empty, empty, pfegamma);
200  }
201 
202  // Post HF Cleaning
203  pfCleanedCandidates_.clear();
204  // Check if the post HF Cleaning was requested - if not, do nothing
205  if (postHFCleaning_) {
206  postCleaning();
207  }
208 
209  //Muon post cleaning
210  pfmu_->postClean(pfCandidates_.get());
211 
212  //Add Missing muons
213  if (muonHandle_.isValid())
214  pfmu_->addMissingMuons(muonHandle_, pfCandidates_.get());
215 
216  LogTrace("PFAlgo|reconstructParticles")
217  << "end of function PFAlgo::reconstructParticles, pfCandidates_->size()=" << pfCandidates_->size();
218 }
219 
221  std::vector<bool>& active,
222  PFEGammaFilters const* pfegamma) {
223  // const edm::ValueMap<reco::GsfElectronRef> & myGedElectronValMap(*valueMapGedElectrons_);
224 
225  unsigned int negmcandidates = pfEgammaCandidates_->size();
226  LogTrace("PFAlgo|egammaFilters") << "start of function PFAlgo::egammaFilters(), negmcandidates=" << negmcandidates;
227 
228  for (unsigned int ieg = 0; ieg < negmcandidates; ++ieg) {
229  // const reco::PFCandidate & egmcand((*pfEgammaCandidates_)[ieg]);
231 
232  const PFCandidate::ElementsInBlocks& theElements = (*pfEgmRef).elementsInBlocks();
233  PFCandidate::ElementsInBlocks::const_iterator iegfirst = theElements.begin();
234  bool sameBlock = false;
235  bool isGoodElectron = false;
236  bool isGoodPhoton = false;
237  bool isPrimaryElectron = false;
238  if (iegfirst->first == blockref)
239  sameBlock = true;
240  if (sameBlock) {
241  LogTrace("PFAlgo|egammaFilters") << " I am in looping on EGamma Candidates: pt " << (*pfEgmRef).pt()
242  << " eta,phi " << (*pfEgmRef).eta() << ", " << (*pfEgmRef).phi() << " charge "
243  << (*pfEgmRef).charge();
244 
245  if ((*pfEgmRef).gsfTrackRef().isNonnull()) {
246  reco::GsfElectronRef gedEleRef = (*valueMapGedElectrons_)[pfEgmRef];
247  if (gedEleRef.isNonnull()) {
248  isGoodElectron = pfegamma->passElectronSelection(*gedEleRef, *pfEgmRef, nVtx_);
249  isPrimaryElectron = pfegamma->isElectron(*gedEleRef);
250  if (isGoodElectron)
251  LogTrace("PFAlgo|egammaFilters")
252  << "** Good Electron, pt " << gedEleRef->pt() << " eta, phi " << gedEleRef->eta() << ", "
253  << gedEleRef->phi() << " charge " << gedEleRef->charge() << " isPrimary " << isPrimaryElectron
254  << " isoDr03 "
255  << (gedEleRef->dr03TkSumPt() + gedEleRef->dr03EcalRecHitSumEt() + gedEleRef->dr03HcalTowerSumEt())
256  << " mva_isolated " << gedEleRef->mva_Isolated() << " mva_e_pi " << gedEleRef->mva_e_pi();
257  }
258  }
259  if ((*pfEgmRef).superClusterRef().isNonnull()) {
260  reco::PhotonRef gedPhoRef = (*valueMapGedPhotons_)[pfEgmRef];
261  if (gedPhoRef.isNonnull()) {
262  isGoodPhoton = pfegamma->passPhotonSelection(*gedPhoRef);
263  if (isGoodPhoton)
264  LogTrace("PFAlgo|egammaFilters") << "** Good Photon, pt " << gedPhoRef->pt() << " eta, phi "
265  << gedPhoRef->eta() << ", " << gedPhoRef->phi() << endl;
266  }
267  }
268  } // end sameBlock
269 
270  if (isGoodElectron && isGoodPhoton) {
271  if (isPrimaryElectron)
272  isGoodPhoton = false;
273  else
274  isGoodElectron = false;
275  }
276 
277  // isElectron
278  if (isGoodElectron) {
279  reco::GsfElectronRef gedEleRef = (*valueMapGedElectrons_)[pfEgmRef];
280  reco::PFCandidate myPFElectron = *pfEgmRef;
281  // run protections
282  bool lockTracks = false;
283  bool isSafe = true;
285  lockTracks = true;
286  isSafe = pfegamma->isElectronSafeForJetMET(*gedEleRef, myPFElectron, primaryVertex_, lockTracks);
287  }
288 
289  if (isSafe) {
291  myPFElectron.setParticleType(particleType);
292  myPFElectron.setCharge(gedEleRef->charge());
293  myPFElectron.setP4(gedEleRef->p4());
294  myPFElectron.set_mva_e_pi(gedEleRef->mva_e_pi());
295  myPFElectron.set_mva_Isolated(gedEleRef->mva_Isolated());
296 
297  myPFElectron.set_dnn_e_sigIsolated(gedEleRef->dnn_signal_Isolated());
298  myPFElectron.set_dnn_e_sigNonIsolated(gedEleRef->dnn_signal_nonIsolated());
299  myPFElectron.set_dnn_e_bkgNonIsolated(gedEleRef->dnn_bkg_nonIsolated());
300  myPFElectron.set_dnn_e_bkgTau(gedEleRef->dnn_bkg_Tau());
301  myPFElectron.set_dnn_e_bkgPhoton(gedEleRef->dnn_bkg_Photon());
302 
303  LogTrace("PFAlgo|egammaFilters") << " PFAlgo: found an electron with NEW EGamma code ";
304  LogTrace("PFAlgo|egammaFilters") << " myPFElectron: pt " << myPFElectron.pt() << " eta,phi "
305  << myPFElectron.eta() << ", " << myPFElectron.phi() << " mva "
306  << myPFElectron.mva_e_pi() << " charge " << myPFElectron.charge();
307 
308  LogTrace("PFAlgo|egammaFilters") << " THE BLOCK " << *blockref;
309  for (auto const& eb : theElements) {
310  active[eb.second] = false;
311  LogTrace("PFAlgo|egammaFilters") << " Elements used " << eb.second;
312  }
313 
314  // The electron is considered safe for JetMET and the additional tracks pointing to it are locked
315  if (lockTracks) {
316  const PFCandidate::ElementsInBlocks& extraTracks = myPFElectron.egammaExtraRef()->extraNonConvTracks();
317  for (auto const& trk : extraTracks) {
318  LogTrace("PFAlgo|egammaFilters") << " Extra locked track " << trk.second;
319  active[trk.second] = false;
320  }
321  }
322 
323  LogTrace("PFAlgo|egammaFilters") << "Creating PF electron: pt=" << myPFElectron.pt()
324  << " eta=" << myPFElectron.eta() << " phi=" << myPFElectron.phi();
325  pfCandidates_->push_back(myPFElectron);
326 
327  } else {
328  LogTrace("PFAlgo|egammaFilters") << "PFAlgo: Electron DISCARDED, NOT SAFE FOR JETMET ";
329  }
330  } //isGoodElectron
331 
332  if (isGoodPhoton) {
333  reco::PhotonRef gedPhoRef = (*valueMapGedPhotons_)[pfEgmRef];
334  reco::PFCandidate myPFPhoton = *pfEgmRef;
335  bool isSafe = true;
337  isSafe = pfegamma->isPhotonSafeForJetMET(*gedPhoRef, myPFPhoton);
338  }
339 
340  if (isSafe) {
342  myPFPhoton.setParticleType(particleType);
343  myPFPhoton.setCharge(0);
344  myPFPhoton.set_mva_nothing_gamma(1.);
346  myPFPhoton.setVertex(v);
347  myPFPhoton.setP4(gedPhoRef->p4());
348  // DNN pfid
349  myPFPhoton.set_dnn_gamma(gedPhoRef->pfDNN());
350  LogTrace("PFAlgo|egammaFilters") << " PFAlgo: found a photon with NEW EGamma code ";
351  LogTrace("PFAlgo|egammaFilters") << " myPFPhoton: pt " << myPFPhoton.pt() << " eta,phi " << myPFPhoton.eta()
352  << ", " << myPFPhoton.phi() << " charge " << myPFPhoton.charge();
353 
354  // Lock all the elements
355  LogTrace("PFAlgo|egammaFilters") << " THE BLOCK " << *blockref;
356  for (auto const& eb : theElements) {
357  active[eb.second] = false;
358  LogTrace("PFAlgo|egammaFilters") << " Elements used " << eb.second;
359  }
360  LogTrace("PFAlgo|egammaFilters") << "Creating PF photon: pt=" << myPFPhoton.pt() << " eta=" << myPFPhoton.eta()
361  << " phi=" << myPFPhoton.phi();
362  pfCandidates_->push_back(myPFPhoton);
363 
364  } // end isSafe
365  } // end isGoodPhoton
366  } // end loop on EGM candidates
367  LogTrace("PFAlgo|egammaFilters") << "end of function PFAlgo::egammaFilters";
368 }
369 
371  LogTrace("PFAlgo|conversionAlgo") << "start of function PFAlgo::conversionAlgo(), elements.size()="
372  << elements.size();
373  for (unsigned iEle = 0; iEle < elements.size(); iEle++) {
374  PFBlockElement::Type type = elements[iEle].type();
375  if (type == PFBlockElement::TRACK) {
376  LogTrace("PFAlgo|conversionAlgo") << "elements[" << iEle << "].type() == TRACK, active[" << iEle
377  << "]=" << active[iEle];
378  if (elements[iEle].trackRef()->algo() == reco::TrackBase::conversionStep) {
379  active[iEle] = false;
380  }
381  if (elements[iEle].trackRef()->quality(reco::TrackBase::highPurity)) {
382  LogTrace("PFAlgo|conversionAlgo") << "Track is high purity";
383  continue;
384  }
385  const auto* trackRef = dynamic_cast<const reco::PFBlockElementTrack*>((&elements[iEle]));
386  if (!(trackRef->trackType(reco::PFBlockElement::T_FROM_GAMMACONV))) {
387  LogTrace("PFAlgo|conversionAlgo") << "!trackType(T_FROM_GAMMACONV)";
388  continue;
389  }
390  if (!elements[iEle].convRefs().empty()) {
391  active[iEle] = false;
392  }
393  LogTrace("PFAlgo|conversionAlgo") << "active[iEle=" << iEle << "]=" << active[iEle];
394  }
395  }
396  LogTrace("PFAlgo|conversionAlgo") << "end of function PFAlgo::conversionAlgo";
397 }
398 
400  reco::PFBlock::LinkData& linkData,
402  const reco::PFBlockRef& blockref,
403  std::vector<bool>& active,
404  bool goodTrackDeadHcal,
405  bool hasDeadHcal,
406  unsigned int iTrack,
407  std::multimap<double, unsigned>& ecalElems,
408  reco::TrackRef& trackRef) {
409  LogTrace("PFAlgo|recoTracksNotHCAL") << "start of function PFAlgo::recoTracksNotHCAL(), now dealing with tracks "
410  "linked to no HCAL clusters. Was HCal active? "
411  << (!hasDeadHcal);
412  // vector<unsigned> elementIndices;
413  // elementIndices.push_back(iTrack);
414 
415  // The track momentum
416  double trackMomentum = elements[iTrack].trackRef()->p();
417  LogTrace("PFAlgo|recoTracksNotHCAL") << elements[iTrack];
418 
419  // Is it a "tight" muon ? In that case assume no
420  //Track momentum corresponds to the calorimeter
421  //energy for now
422  bool thisIsAMuon = PFMuonAlgo::isMuon(elements[iTrack]);
423  if (thisIsAMuon)
424  trackMomentum = 0.;
425 
426  // If it is not a muon check if Is it a fake track ?
427  //Michalis: I wonder if we should convert this to dpt/pt?
428  if (!thisIsAMuon && elements[iTrack].trackRef()->ptError() > ptError_) {
429  double deficit = trackMomentum;
430  double resol = neutralHadronEnergyResolution(trackMomentum, elements[iTrack].trackRef()->eta());
431  resol *= trackMomentum;
432 
433  if (!ecalElems.empty()) {
434  unsigned thisEcal = ecalElems.begin()->second;
435  reco::PFClusterRef clusterRef = elements[thisEcal].clusterRef();
436  bool useCluster = true;
437  if (hasDeadHcal) {
438  std::multimap<double, unsigned> sortedTracks;
439  block.associatedElements(
440  thisEcal, linkData, sortedTracks, reco::PFBlockElement::TRACK, reco::PFBlock::LINKTEST_ALL);
441  useCluster = (sortedTracks.begin()->second == iTrack);
442  }
443  if (useCluster) {
444  deficit -= clusterRef->energy();
445  resol = neutralHadronEnergyResolution(trackMomentum, clusterRef->positionREP().Eta());
446  resol *= trackMomentum;
447  }
448  }
449 
450  bool isPrimary = isFromSecInt(elements[iTrack], "primary");
451 
452  if (deficit > nSigmaTRACK_ * resol && !isPrimary && !goodTrackDeadHcal) {
453  active[iTrack] = false;
454  LogTrace("PFAlgo|recoTracksNotHCAL")
455  << elements[iTrack] << std::endl
456  << " deficit " << deficit << " > " << nSigmaTRACK_ << " x " << resol << " track pt " << trackRef->pt()
457  << " +- " << trackRef->ptError() << " layers valid " << trackRef->hitPattern().trackerLayersWithMeasurement()
458  << ", lost " << trackRef->hitPattern().trackerLayersWithoutMeasurement(HitPattern::TRACK_HITS)
459  << ", lost outer " << trackRef->hitPattern().trackerLayersWithoutMeasurement(HitPattern::MISSING_OUTER_HITS)
460  << ", lost inner " << trackRef->hitPattern().trackerLayersWithoutMeasurement(HitPattern::MISSING_INNER_HITS)
461  << "(valid fraction " << trackRef->validFraction() << ")"
462  << " chi2/ndf " << trackRef->normalizedChi2() << " |dxy| "
463  << std::abs(trackRef->dxy(primaryVertex_.position())) << " +- " << trackRef->dxyError() << " |dz| "
464  << std::abs(trackRef->dz(primaryVertex_.position())) << " +- " << trackRef->dzError()
465  << "is probably a fake (1) --> lock the track";
466  return true;
467  }
468  } // !thisIsaMuon
469 
470  // Create a track candidate
471  // unsigned tmpi = reconstructTrack( elements[iTrack] );
472  //active[iTrack] = false;
473  std::vector<unsigned> tmpi;
474  std::vector<unsigned> kTrack;
475 
476  // Some cleaning : secondary tracks without calo's and large momentum must be fake
477  double dpt = trackRef->ptError();
478 
479  if (rejectTracks_Step45_ && ecalElems.empty() && trackMomentum > 30. && dpt > 0.5 &&
480  (PFTrackAlgoTools::step45(trackRef->algo()) && !goodTrackDeadHcal)) {
481  double dptRel = dpt / trackRef->pt() * 100;
482  bool isPrimaryOrSecondary = isFromSecInt(elements[iTrack], "all");
483 
484  if (isPrimaryOrSecondary && dptRel < dptRel_DispVtx_) {
485  return true;
486  };
487  unsigned nHits = elements[iTrack].trackRef()->hitPattern().trackerLayersWithMeasurement();
488  unsigned int NLostHit = trackRef->hitPattern().trackerLayersWithoutMeasurement(HitPattern::TRACK_HITS);
489 
490  LogTrace("PFAlgo|recoTracksNotHCAL") << "A track (algo = " << trackRef->algo() << ") with momentum "
491  << trackMomentum << " / " << elements[iTrack].trackRef()->pt() << " +/- "
492  << dpt << " / " << elements[iTrack].trackRef()->eta()
493  << " without any link to ECAL/HCAL and with " << nHits << " (" << NLostHit
494  << ") hits (lost hits) has been cleaned";
495 
496  active[iTrack] = false;
497  return true;
498  } //rejectTracks_Step45_ && ...
499 
500  tmpi.push_back(reconstructTrack(elements[iTrack]));
501 
502  kTrack.push_back(iTrack);
503  active[iTrack] = false;
504 
505  // No ECAL cluster either ... continue...
506  if (ecalElems.empty()) {
507  (*pfCandidates_)[tmpi[0]].setEcalEnergy(0., 0.);
508  (*pfCandidates_)[tmpi[0]].setHcalEnergy(0., 0.);
509  (*pfCandidates_)[tmpi[0]].setHoEnergy(0., 0.);
510  (*pfCandidates_)[tmpi[0]].setPs1Energy(0);
511  (*pfCandidates_)[tmpi[0]].setPs2Energy(0);
512  (*pfCandidates_)[tmpi[0]].addElementInBlock(blockref, kTrack[0]);
513  return true;
514  }
515 
516  // Look for closest ECAL cluster
517  const unsigned int thisEcal = ecalElems.begin()->second;
518  reco::PFClusterRef clusterRef = elements[thisEcal].clusterRef();
519  LogTrace("PFAlgo|recoTracksNotHCAL") << " is associated to " << elements[thisEcal];
520 
521  // Set ECAL energy for muons
522  if (thisIsAMuon) {
523  (*pfCandidates_)[tmpi[0]].setEcalEnergy(clusterRef->energy(), std::min(clusterRef->energy(), muonECAL_[0]));
524  (*pfCandidates_)[tmpi[0]].setHcalEnergy(0., 0.);
525  (*pfCandidates_)[tmpi[0]].setHoEnergy(0., 0.);
526  (*pfCandidates_)[tmpi[0]].setPs1Energy(0);
527  (*pfCandidates_)[tmpi[0]].setPs2Energy(0);
528  (*pfCandidates_)[tmpi[0]].addElementInBlock(blockref, kTrack[0]);
529  }
530 
531  double slopeEcal = 1.;
532  bool connectedToEcal = false;
533  unsigned iEcal = 99999;
534  double calibEcal = 0.;
535  double calibHcal = 0.;
536  double totalEcal = thisIsAMuon ? -muonECAL_[0] : 0.;
537 
538  // Consider charged particles closest to the same ECAL cluster
539  std::multimap<double, unsigned> sortedTracks;
540  block.associatedElements(thisEcal, linkData, sortedTracks, reco::PFBlockElement::TRACK, reco::PFBlock::LINKTEST_ALL);
541  LogTrace("PFAlgo|recoTracksNotHCAL") << "the closest ECAL cluster, id " << thisEcal << ", has " << sortedTracks.size()
542  << " associated tracks, now processing them. ";
543 
544  if (hasDeadHcal && !sortedTracks.empty()) {
545  // GP: only allow the ecal cluster closest to this track to be considered
546  LogTrace("PFAlgo|recoTracksNotHCAL") << " the closest track to ECAL " << thisEcal << " is "
547  << sortedTracks.begin()->second << " (distance " << sortedTracks.begin()->first
548  << ")";
549  if (sortedTracks.begin()->second != iTrack) {
550  LogTrace("PFAlgo|recoTracksNotHCAL")
551  << " the closest track to ECAL " << thisEcal << " is " << sortedTracks.begin()->second
552  << " which is not the one being processed. Will skip ECAL linking for this track";
553  (*pfCandidates_)[tmpi[0]].setEcalEnergy(0., 0.);
554  (*pfCandidates_)[tmpi[0]].setHcalEnergy(0., 0.);
555  (*pfCandidates_)[tmpi[0]].setHoEnergy(0., 0.);
556  (*pfCandidates_)[tmpi[0]].setPs1Energy(0);
557  (*pfCandidates_)[tmpi[0]].setPs2Energy(0);
558  (*pfCandidates_)[tmpi[0]].addElementInBlock(blockref, kTrack[0]);
559  return true;
560  } else {
561  LogTrace("PFAlgo|recoTracksNotHCAL")
562  << " the closest track to ECAL " << thisEcal << " is " << sortedTracks.begin()->second
563  << " which is the one being processed. Will skip ECAL linking for all other track";
564  sortedTracks.clear();
565  }
566  }
567 
568  for (auto const& trk : sortedTracks) {
569  unsigned jTrack = trk.second;
570 
571  // Don't consider already used tracks
572  if (!active[jTrack])
573  continue;
574 
575  // The loop is on the other tracks !
576  if (jTrack == iTrack)
577  continue;
578 
579  // Check if the ECAL cluster closest to this track is
580  // indeed the current ECAL cluster. Only tracks not
581  // linked to an HCAL cluster are considered here
582  // (GP: this is because if there's a jTrack linked
583  // to the same Ecal cluster and that also has an Hcal link
584  // we would have also linked iTrack to that Hcal above)
585  std::multimap<double, unsigned> sortedECAL;
586  block.associatedElements(jTrack, linkData, sortedECAL, reco::PFBlockElement::ECAL, reco::PFBlock::LINKTEST_ALL);
587  if (sortedECAL.begin()->second != thisEcal)
588  continue;
589 
590  // Check if this track is a muon
591  bool thatIsAMuon = PFMuonAlgo::isMuon(elements[jTrack]);
592  LogTrace("PFAlgo|recoTracksNotHCAL") << " found track " << jTrack << (thatIsAMuon ? " (muon) " : " (non-muon)")
593  << ", with distance = " << sortedECAL.begin()->first;
594 
595  // Check if this track is not a fake
596  bool rejectFake = false;
597  reco::TrackRef trackRef = elements[jTrack].trackRef();
598  if (!thatIsAMuon && trackRef->ptError() > ptError_) {
599  // GP: FIXME this selection should be adapted depending on hasDeadHcal
600  // but we don't know if jTrack is linked to a dead Hcal or not
601  double deficit = trackMomentum + trackRef->p() - clusterRef->energy();
602  double resol =
603  nSigmaTRACK_ * neutralHadronEnergyResolution(trackMomentum + trackRef->p(), clusterRef->positionREP().Eta());
604  resol *= (trackMomentum + trackRef->p());
605  if (deficit > nSigmaTRACK_ * resol && !goodTrackDeadHcal) {
606  rejectFake = true;
607  kTrack.push_back(jTrack);
608  active[jTrack] = false;
609  LogTrace("PFAlgo|recoTracksNotHCAL")
610  << elements[jTrack] << std::endl
611  << "is probably a fake (2) --> lock the track"
612  << "(trackMomentum = " << trackMomentum << ", clusterEnergy = " << clusterRef->energy()
613  << ", deficit = " << deficit << " > " << nSigmaTRACK_ << " x " << resol
614  << " assuming neutralHadronEnergyResolution "
615  << neutralHadronEnergyResolution(trackMomentum + trackRef->p(), clusterRef->positionREP().Eta()) << ") ";
616  }
617  }
618  if (rejectFake)
619  continue;
620 
621  // Otherwise, add this track momentum to the total track momentum
622  /* */
623  // reco::TrackRef trackRef = elements[jTrack].trackRef();
624  if (!thatIsAMuon) {
625  LogTrace("PFAlgo|recoTracksNotHCAL") << "Track momentum increased from " << trackMomentum << " GeV ";
626  trackMomentum += trackRef->p();
627  LogTrace("PFAlgo|recoTracksNotHCAL") << "to " << trackMomentum << " GeV.";
628  LogTrace("PFAlgo|recoTracksNotHCAL") << "with " << elements[jTrack];
629  } else {
630  totalEcal -= muonECAL_[0];
631  totalEcal = std::max(totalEcal, 0.);
632  }
633 
634  // And create a charged particle candidate !
635 
636  tmpi.push_back(reconstructTrack(elements[jTrack]));
637 
638  kTrack.push_back(jTrack);
639  active[jTrack] = false;
640 
641  if (thatIsAMuon) {
642  (*pfCandidates_)[tmpi.back()].setEcalEnergy(clusterRef->energy(), std::min(clusterRef->energy(), muonECAL_[0]));
643  (*pfCandidates_)[tmpi.back()].setHcalEnergy(0., 0.);
644  (*pfCandidates_)[tmpi.back()].setHoEnergy(0., 0.);
645  (*pfCandidates_)[tmpi.back()].setPs1Energy(0);
646  (*pfCandidates_)[tmpi.back()].setPs2Energy(0);
647  (*pfCandidates_)[tmpi.back()].addElementInBlock(blockref, kTrack.back());
648  }
649  }
650 
651  LogTrace("PFAlgo|recoTracksNotHCAL") << "Loop over all associated ECAL clusters";
652  // Loop over all ECAL linked clusters ordered by increasing distance.
653  for (auto const& ecal : ecalElems) {
654  const unsigned index = ecal.second;
655  const PFBlockElement::Type type = elements[index].type();
657  LogTrace("PFAlgo|recoTracksNotHCAL") << elements[index];
658 
659  // Just skip clusters already taken
660  if (!active[index]) {
661  LogTrace("PFAlgo|recoTracksNotHCAL") << "is not active - ignore ";
662  continue;
663  }
664 
665  // Just skip this cluster if it's closer to another track
666  block.associatedElements(index, linkData, sortedTracks, reco::PFBlockElement::TRACK, reco::PFBlock::LINKTEST_ALL);
667 
668  const bool skip = std::none_of(
669  kTrack.begin(), kTrack.end(), [&](unsigned iTrack) { return sortedTracks.begin()->second == iTrack; });
670 
671  if (skip) {
672  LogTrace("PFAlgo|recoTracksNotHCAL") << "is closer to another track - ignore ";
673  continue;
674  }
675 
676  // The corresponding PFCluster and energy
677  const reco::PFClusterRef clusterRef = elements[index].clusterRef();
678  assert(!clusterRef.isNull());
679 
680  LogTrace("PFAlgo|recoTracksNotHCAL") << "Ecal cluster with raw energy = " << clusterRef->energy()
681  << " linked with distance = " << ecal.first;
682 
683  // Check the presence of preshower clusters in the vicinity
684  // Preshower cluster closer to another ECAL cluster are ignored.
685  //JOSH: This should use the association map already produced by the cluster corrector for consistency,
686  //but should be ok for now
687  vector<double> ps1Ene{0.};
688  associatePSClusters(index, reco::PFBlockElement::PS1, block, elements, linkData, active, ps1Ene);
689  vector<double> ps2Ene{0.};
690  associatePSClusters(index, reco::PFBlockElement::PS2, block, elements, linkData, active, ps2Ene);
691 
692  // KH: use raw ECAL energy for PF hadron calibration. use calibrated ECAL energy when adding PF photons
693  const double ecalEnergy = clusterRef->energy();
694  const double ecalEnergyCalibrated = clusterRef->correctedEnergy(); // calibrated based on the egamma hypothesis
695  LogTrace("PFAlgo|recoTracksNotHCAL") << "Corrected ECAL(+PS) energy = " << ecalEnergy;
696 
697  // Since the electrons were found beforehand, this track must be a hadron. Calibrate
698  // the energy under the hadron hypothesis.
699  totalEcal += ecalEnergy;
700  const double previousCalibEcal = calibEcal;
701  const double previousSlopeEcal = slopeEcal;
702  calibEcal = std::max(totalEcal, 0.);
703  calibHcal = 0.;
705  trackMomentum, calibEcal, calibHcal, clusterRef->positionREP().Eta(), clusterRef->positionREP().Phi());
706  if (totalEcal > 0.)
707  slopeEcal = calibEcal / totalEcal;
708 
709  LogTrace("PFAlgo|recoTracksNotHCAL") << "The total calibrated energy so far amounts to = " << calibEcal
710  << " (slope = " << slopeEcal << ")";
711 
712  // Stop the loop when adding more ECAL clusters ruins the compatibility
713  if (connectedToEcal && calibEcal - trackMomentum >= 0.) {
714  // if ( connectedToEcal && calibEcal - trackMomentum >=
715  // nSigmaECAL_*neutralHadronEnergyResolution(trackMomentum,clusterRef->positionREP().Eta()) ) {
716  calibEcal = previousCalibEcal;
717  slopeEcal = previousSlopeEcal;
718  totalEcal = calibEcal / slopeEcal;
719 
720  // Turn this last cluster in a photon
721  // (The PS clusters are already locked in "associatePSClusters")
722  active[index] = false;
723 
724  // Find the associated tracks
725  std::multimap<double, unsigned> assTracks;
726  block.associatedElements(index, linkData, assTracks, reco::PFBlockElement::TRACK, reco::PFBlock::LINKTEST_ALL);
727 
728  auto& ecalCand = (*pfCandidates_)[reconstructCluster(
729  *clusterRef, ecalEnergyCalibrated)]; // KH: use the PF ECAL cluster calibrated energy
730  ecalCand.setEcalEnergy(clusterRef->energy(), ecalEnergyCalibrated);
731  ecalCand.setHcalEnergy(0., 0.);
732  ecalCand.setHoEnergy(0., 0.);
733  ecalCand.setPs1Energy(ps1Ene[0]);
734  ecalCand.setPs2Energy(ps2Ene[0]);
735  ecalCand.addElementInBlock(blockref, index);
736  // Check that there is at least one track
737  if (!assTracks.empty()) {
738  ecalCand.addElementInBlock(blockref, assTracks.begin()->second);
739 
740  // Assign the position of the track at the ECAL entrance
741  const ::math::XYZPointF& chargedPosition =
742  dynamic_cast<const reco::PFBlockElementTrack*>(&elements[assTracks.begin()->second])
743  ->positionAtECALEntrance();
744  ecalCand.setPositionAtECALEntrance(chargedPosition);
745  }
746  break;
747  }
748 
749  // Lock used clusters.
750  connectedToEcal = true;
751  iEcal = index;
752  active[index] = false;
753  for (unsigned ic : tmpi)
754  (*pfCandidates_)[ic].addElementInBlock(blockref, iEcal);
755 
756  } // Loop ecal elements
757 
758  bool bNeutralProduced = false;
759 
760  // Create a photon if the ecal energy is too large
761  if (connectedToEcal) {
762  reco::PFClusterRef pivotalRef = elements[iEcal].clusterRef();
763 
764  double neutralEnergy = calibEcal - trackMomentum;
765 
766  /*
767  // Check if there are other tracks linked to that ECAL
768  for(IE ie = sortedTracks.begin(); ie != sortedTracks.end() && neutralEnergy > 0; ++ie ) {
769  unsigned jTrack = ie->second;
770 
771  // The loop is on the other tracks !
772  if ( jTrack == iTrack ) continue;
773 
774  // Check if the ECAL closest to this track is the current ECAL
775  // Otherwise ignore this track in the neutral energy determination
776  std::multimap<double, unsigned> sortedECAL;
777  block.associatedElements( jTrack, linkData,
778  sortedECAL,
779  reco::PFBlockElement::ECAL,
780  reco::PFBlock::LINKTEST_ALL );
781  if ( sortedECAL.begin()->second != iEcal ) continue;
782 
783  // Check if this track is also linked to an HCAL
784  // (in which case it goes to the next loop and is ignored here)
785  std::multimap<double, unsigned> sortedHCAL;
786  block.associatedElements( jTrack, linkData,
787  sortedHCAL,
788  reco::PFBlockElement::HCAL,
789  reco::PFBlock::LINKTEST_ALL );
790  if ( sortedHCAL.size() ) continue;
791 
792  // Otherwise, subtract this track momentum from the ECAL energy
793  reco::TrackRef trackRef = elements[jTrack].trackRef();
794  neutralEnergy -= trackRef->p();
795 
796  } // End other tracks
797  */
798 
799  // Add a photon if the energy excess is large enough
800  double resol = neutralHadronEnergyResolution(trackMomentum, pivotalRef->positionREP().Eta());
801  resol *= trackMomentum;
802  if (neutralEnergy > std::max(0.5, nSigmaECAL_ * resol)) {
803  neutralEnergy /= slopeEcal;
804  unsigned tmpj = reconstructCluster(*pivotalRef, neutralEnergy);
805  (*pfCandidates_)[tmpj].setEcalEnergy(pivotalRef->energy(), neutralEnergy);
806  (*pfCandidates_)[tmpj].setHcalEnergy(0., 0.);
807  (*pfCandidates_)[tmpj].setHoEnergy(0., 0.);
808  (*pfCandidates_)[tmpj].setPs1Energy(0.);
809  (*pfCandidates_)[tmpj].setPs2Energy(0.);
810  (*pfCandidates_)[tmpj].addElementInBlock(blockref, iEcal);
811  bNeutralProduced = true;
812  for (unsigned ic = 0; ic < kTrack.size(); ++ic)
813  (*pfCandidates_)[tmpj].addElementInBlock(blockref, kTrack[ic]);
814  } // End neutral energy
815 
816  // Set elements in blocks and ECAL energies to all tracks
817  for (unsigned ic = 0; ic < tmpi.size(); ++ic) {
818  // Skip muons
819  if ((*pfCandidates_)[tmpi[ic]].particleId() == reco::PFCandidate::mu)
820  continue;
821 
822  double fraction = trackMomentum > 0 ? (*pfCandidates_)[tmpi[ic]].trackRef()->p() / trackMomentum : 0;
823  double ecalCal = bNeutralProduced ? (calibEcal - neutralEnergy * slopeEcal) * fraction : calibEcal * fraction;
824  double ecalRaw = totalEcal * fraction;
825 
826  LogTrace("PFAlgo|recoTracksNotHCAL")
827  << "The fraction after photon supression is " << fraction << " calibrated ecal = " << ecalCal;
828 
829  (*pfCandidates_)[tmpi[ic]].setEcalEnergy(ecalRaw, ecalCal);
830  (*pfCandidates_)[tmpi[ic]].setHcalEnergy(0., 0.);
831  (*pfCandidates_)[tmpi[ic]].setHoEnergy(0., 0.);
832  (*pfCandidates_)[tmpi[ic]].setPs1Energy(0);
833  (*pfCandidates_)[tmpi[ic]].setPs2Energy(0);
834  (*pfCandidates_)[tmpi[ic]].addElementInBlock(blockref, kTrack[ic]);
835  }
836 
837  } // End connected ECAL
838 
839  // Fill the element_in_block for tracks that are eventually linked to no ECAL clusters at all.
840  for (unsigned ic = 0; ic < tmpi.size(); ++ic) {
841  const PFCandidate& pfc = (*pfCandidates_)[tmpi[ic]];
842  const PFCandidate::ElementsInBlocks& eleInBlocks = pfc.elementsInBlocks();
843  if (eleInBlocks.empty()) {
844  LogTrace("PFAlgo|recoTracksNotHCAL") << "Single track / Fill element in block! ";
845  (*pfCandidates_)[tmpi[ic]].addElementInBlock(blockref, kTrack[ic]);
846  }
847  }
848  LogTrace("PFAlgo|recoTracksNotHCAL") << "end of function PFAlgo::recoTracksNotHCAL";
849  return false;
850 }
851 
852 //Check if the track is a primary track of a secondary interaction
853 //If that is the case reconstruct a charged hadron only using that
854 //track
857  bool isActive,
858  int iElement) {
859  bool ret = isActive;
860  if (isActive && isFromSecInt(elements[iElement], "primary")) {
861  bool isPrimaryTrack =
862  elements[iElement].displacedVertexRef(PFBlockElement::T_TO_DISP)->displacedVertexRef()->isTherePrimaryTracks();
863  if (isPrimaryTrack) {
864  LogTrace("PFAlgo|elementLoop") << "Primary Track reconstructed alone";
865 
866  unsigned tmpi = reconstructTrack(elements[iElement]);
867  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iElement);
868  ret = false;
869  }
870  }
871 
872  return ret;
873 }
874 
875 bool PFAlgo::checkHasDeadHcal(const std::multimap<double, unsigned>& hcalElems, const std::vector<bool>& deadArea) {
876  // there's 3 possible options possible here, in principle:
877  // 1) flag everything that may be associated to a dead hcal marker
878  // 2) flag everything whose closest hcal link is a dead hcal marker
879  // 3) flag only things that are linked only to dead hcal marker
880  // in our first test we go for (2)
881  //--- option (1) --
882  //bool hasDeadHcal = false;
883  //for (auto it = hcalElems.begin(), ed = hcalElems.end(); it != ed; /*NOTE NO ++it HERE */ ) {
884  // if (deadArea[it->second]) { hasDeadHcal = true; it = hcalElems.erase(it); } // std::multimap::erase returns iterator to next
885  // else ++it;
886  //}
887  //--- option (2) --
888  bool hasDeadHcal = false;
889  if (!hcalElems.empty() && deadArea[hcalElems.begin()->second]) {
890  hasDeadHcal = true;
891  }
892  //--- option (3) --
893  //bool hasDeadHcal = true;
894  //for (auto it = hcalElems.begin(), ed = hcalElems.end(); it != ed; /*NOTE NO ++it HERE */ ) {
895  // if (deadArea[it->second]) { it = hcalElems.erase(it); } // std::multimap::erase returns iterator to next
896  // else { hasDeadHcal = false; }
897  //}
898  return hasDeadHcal;
899 }
900 
901 // for tracks with bad Hcal, check the track quality
902 bool PFAlgo::checkGoodTrackDeadHcal(const reco::TrackRef& trackRef, bool hasDeadHcal) {
903  bool goodTrackDeadHcal = false;
904  if (hasDeadHcal) {
905  goodTrackDeadHcal = (trackRef->ptError() < goodTrackDeadHcal_ptErrRel_ * trackRef->pt() &&
906  trackRef->normalizedChi2() < goodTrackDeadHcal_chi2n_ &&
907  trackRef->hitPattern().trackerLayersWithMeasurement() >= goodTrackDeadHcal_layers_ &&
908  trackRef->validFraction() > goodTrackDeadHcal_validFr_ &&
910  // now we add an extra block for tracks at high |eta|
911  if (!goodTrackDeadHcal && std::abs(trackRef->eta()) > goodPixelTrackDeadHcal_minEta_ && // high eta
912  trackRef->hitPattern().pixelLayersWithMeasurement() >= 3 && // pixel track
913  trackRef->hitPattern().trackerLayersWithoutMeasurement(HitPattern::TRACK_HITS) == 0 &&
914  trackRef->hitPattern().trackerLayersWithoutMeasurement(HitPattern::MISSING_INNER_HITS) == 0 &&
915  trackRef->hitPattern().trackerLayersWithoutMeasurement(HitPattern::MISSING_OUTER_HITS) <=
916  (trackRef->hitPattern().pixelLayersWithMeasurement() > 3 ? goodPixelTrackDeadHcal_maxLost4Hit_
918  trackRef->normalizedChi2() < goodPixelTrackDeadHcal_chi2n_ && // tighter cut
921  trackRef->ptError() < goodPixelTrackDeadHcal_ptErrRel_ * trackRef->pt() && // sanity
922  trackRef->pt() < goodPixelTrackDeadHcal_maxPt_) { // sanity
923  goodTrackDeadHcal = true;
924  // FIXME: may decide to do something to the track pT
925  }
926  //if (!goodTrackDeadHcal && trackRef->hitPattern().trackerLayersWithMeasurement() == 4 && trackRef->validFraction() == 1
927  LogTrace("PFAlgo|elementLoop")
928  << " track pt " << trackRef->pt() << " +- " << trackRef->ptError() << " layers valid "
929  << trackRef->hitPattern().trackerLayersWithMeasurement() << ", lost "
930  << trackRef->hitPattern().trackerLayersWithoutMeasurement(HitPattern::TRACK_HITS) << ", lost outer "
931  << trackRef->hitPattern().trackerLayersWithoutMeasurement(HitPattern::MISSING_OUTER_HITS) << ", lost inner "
932  << trackRef->hitPattern().trackerLayersWithoutMeasurement(HitPattern::MISSING_INNER_HITS) << "(valid fraction "
933  << trackRef->validFraction() << ")"
934  << " chi2/ndf " << trackRef->normalizedChi2() << " |dxy| " << std::abs(trackRef->dxy(primaryVertex_.position()))
935  << " +- " << trackRef->dxyError() << " |dz| " << std::abs(trackRef->dz(primaryVertex_.position())) << " +- "
936  << trackRef->dzError() << (goodTrackDeadHcal ? " passes " : " fails ") << "quality cuts";
937  }
938  return goodTrackDeadHcal;
939 }
940 
942  std::multimap<double, unsigned>& ecalElems,
943  std::multimap<double, unsigned>& hcalElems,
944  const std::vector<bool>& active,
945  reco::PFBlock::LinkData& linkData,
946  unsigned int iTrack) {
947  unsigned ntt = 1;
948  unsigned index = ecalElems.begin()->second;
949  std::multimap<double, unsigned> sortedTracks;
950  block.associatedElements(index, linkData, sortedTracks, reco::PFBlockElement::TRACK, reco::PFBlock::LINKTEST_ALL);
951  LogTrace("PFAlgo|elementLoop") << "The closest ECAL cluster is linked to " << sortedTracks.size()
952  << " tracks, with distance = " << ecalElems.begin()->first;
953 
954  LogTrace("PFAlgo|elementLoop") << "Looping over sortedTracks";
955  // Loop over all tracks
956  for (auto const& trk : sortedTracks) {
957  unsigned jTrack = trk.second;
958  LogTrace("PFAlgo|elementLoop") << "jTrack=" << jTrack;
959  // Track must be active
960  if (!active[jTrack])
961  continue;
962  LogTrace("PFAlgo|elementLoop") << "active[jTrack]=" << active[jTrack];
963 
964  // The loop is on the other tracks !
965  if (jTrack == iTrack)
966  continue;
967  LogTrace("PFAlgo|elementLoop") << "skipping jTrack=" << jTrack << " for same iTrack";
968 
969  // Check if the ECAL closest to this track is the current ECAL
970  // Otherwise ignore this track in the neutral energy determination
971  std::multimap<double, unsigned> sortedECAL;
972  block.associatedElements(jTrack, linkData, sortedECAL, reco::PFBlockElement::ECAL, reco::PFBlock::LINKTEST_ALL);
973  if (sortedECAL.begin()->second != index)
974  continue;
975  LogTrace("PFAlgo|elementLoop") << " track " << jTrack << " with closest ECAL identical ";
976 
977  // Check if this track is also linked to an HCAL
978  std::multimap<double, unsigned> sortedHCAL;
979  block.associatedElements(jTrack, linkData, sortedHCAL, reco::PFBlockElement::HCAL, reco::PFBlock::LINKTEST_ALL);
980  if (sortedHCAL.empty())
981  continue;
982  LogTrace("PFAlgo|elementLoop") << " and with an HCAL cluster " << sortedHCAL.begin()->second;
983  ntt++;
984 
985  // In that case establish a link with the first track
986  block.setLink(iTrack, sortedHCAL.begin()->second, sortedECAL.begin()->first, linkData, PFBlock::LINKTEST_RECHIT);
987 
988  } // End other tracks
989 
990  // Redefine HCAL elements
991  block.associatedElements(iTrack, linkData, hcalElems, reco::PFBlockElement::HCAL, reco::PFBlock::LINKTEST_ALL);
992 
993  if (!hcalElems.empty())
994  LogTrace("PFAlgo|elementLoop") << "Track linked back to HCAL due to ECAL sharing with other tracks";
995 }
996 
998  reco::PFBlock::LinkData& linkData,
1000  std::vector<bool>& active,
1001  const reco::PFBlockRef& blockref,
1002  ElementIndices& inds,
1003  std::vector<bool>& deadArea) {
1004  LogTrace("PFAlgo|elementLoop") << "start of function PFAlgo::elementLoop, elements.size()" << elements.size();
1005 
1006  for (unsigned iEle = 0; iEle < elements.size(); iEle++) {
1007  PFBlockElement::Type type = elements[iEle].type();
1008 
1009  LogTrace("PFAlgo|elementLoop") << "elements[iEle=" << iEle << "]=" << elements[iEle];
1010  //only process TRACK elements, but fill the ElementIndices vector with indices for all elements.
1011  //Mark the active & deadArea for bad HCAL
1012  auto ret_decideType = decideType(elements, type, active, inds, deadArea, iEle);
1013  if (ret_decideType == 1) {
1014  LogTrace("PFAlgo|elementLoop") << "ret_decideType==1, continuing";
1015  continue;
1016  }
1017  LogTrace("PFAlgo|elementLoop") << "ret_decideType=" << ret_decideType << " type=" << type;
1018 
1019  active[iEle] = checkAndReconstructSecondaryInteraction(blockref, elements, active[iEle], iEle);
1020 
1021  if (!active[iEle]) {
1022  LogTrace("PFAlgo|elementLoop") << "Already used by electrons, muons, conversions";
1023  continue;
1024  }
1025 
1026  reco::TrackRef trackRef = elements[iEle].trackRef();
1027  assert(!trackRef.isNull());
1028 
1029  LogTrace("PFAlgo|elementLoop") << "PFAlgo:processBlock"
1030  << " trackIs.size()=" << inds.trackIs.size()
1031  << " ecalIs.size()=" << inds.ecalIs.size() << " hcalIs.size()=" << inds.hcalIs.size()
1032  << " hoIs.size()=" << inds.hoIs.size() << " hfEmIs.size()=" << inds.hfEmIs.size()
1033  << " hfHadIs.size()=" << inds.hfHadIs.size();
1034 
1035  // look for associated elements of all types
1036  //COLINFEB16
1037  // all types of links are considered.
1038  // the elements are sorted by increasing distance
1039  std::multimap<double, unsigned> ecalElems;
1040  block.associatedElements(iEle, linkData, ecalElems, reco::PFBlockElement::ECAL, reco::PFBlock::LINKTEST_ALL);
1041 
1042  std::multimap<double, unsigned> hcalElems;
1043  block.associatedElements(iEle, linkData, hcalElems, reco::PFBlockElement::HCAL, reco::PFBlock::LINKTEST_ALL);
1044 
1045  std::multimap<double, unsigned> hfEmElems;
1046  std::multimap<double, unsigned> hfHadElems;
1047  block.associatedElements(iEle, linkData, hfEmElems, reco::PFBlockElement::HFEM, reco::PFBlock::LINKTEST_ALL);
1048  block.associatedElements(iEle, linkData, hfHadElems, reco::PFBlockElement::HFHAD, reco::PFBlock::LINKTEST_ALL);
1049 
1050  LogTrace("PFAlgo|elementLoop") << "\tTrack " << iEle << " is linked to " << ecalElems.size() << " ecal and "
1051  << hcalElems.size() << " hcal and " << hfEmElems.size() << " hfEm and "
1052  << hfHadElems.size() << " hfHad elements";
1053 
1054 #ifdef EDM_ML_DEBUG
1055  for (const auto& pair : ecalElems) {
1056  LogTrace("PFAlgo|elementLoop") << "ecal: dist " << pair.first << "\t elem " << pair.second;
1057  }
1058  for (const auto& pair : hcalElems) {
1059  LogTrace("PFAlgo|elementLoop") << "hcal: dist " << pair.first << "\t elem " << pair.second
1060  << (deadArea[pair.second] ? " DEAD AREA MARKER" : "");
1061  }
1062 #endif
1063 
1064  const bool hasDeadHcal = checkHasDeadHcal(hcalElems, deadArea);
1065  if (hasDeadHcal) {
1066  hcalElems.clear();
1067  }
1068  const bool goodTrackDeadHcal = checkGoodTrackDeadHcal(trackRef, hasDeadHcal);
1069 
1070  // When a track has no HCAL cluster linked, but another track is linked to the same
1071  // ECAL cluster and an HCAL cluster, link the track to the HCAL cluster for
1072  // later analysis
1073  if (hcalElems.empty() && !ecalElems.empty() && !hasDeadHcal) {
1074  relinkTrackToHcal(block, ecalElems, hcalElems, active, linkData, iEle);
1075  }
1076 
1077  //MICHELE
1078  //TEMPORARY SOLUTION FOR ELECTRON REJECTION IN PFTAU
1079  //COLINFEB16
1080  // in case particle flow electrons are not reconstructed,
1081  // the mva_e_pi of the charged hadron will be set to 1
1082  // if a GSF element is associated to the current TRACK element
1083  // This information will be used in the electron rejection for tau ID.
1084  std::multimap<double, unsigned> gsfElems;
1085  block.associatedElements(iEle, linkData, gsfElems, reco::PFBlockElement::GSF);
1086 
1087  if (hcalElems.empty()) {
1088  LogTrace("PFAlgo|elementLoop") << "no hcal element connected to track " << iEle;
1089  }
1090 
1091  // will now loop on associated elements ...
1092  bool hcalFound = false;
1093  bool hfhadFound = false;
1094 
1095  LogTrace("PFAlgo|elementLoop") << "now looping on elements associated to the track: ecalElems";
1096 
1097  // ... first on associated ECAL elements
1098  // Check if there is still a free ECAL for this track
1099  for (auto const& ecal : ecalElems) {
1100  unsigned index = ecal.second;
1101  // Sanity checks and optional printout
1103 #ifdef EDM_ML_DEBUG
1104  double dist = ecal.first;
1105  LogTrace("PFAlgo|elementLoop") << "\telement " << elements[index] << " linked with distance = " << dist;
1106  if (!active[index])
1107  LogTrace("PFAlgo|elementLoop") << "This ECAL is already used - skip it";
1108 #endif
1110 
1111  // This ECAL is not free (taken by an electron?) - just skip it
1112  if (!active[index])
1113  continue;
1114 
1115  // Flag ECAL clusters for which the corresponding track is not linked to an HCAL cluster
1116 
1117  //reco::PFClusterRef clusterRef = elements[index].clusterRef();
1118  //assert( !clusterRef.isNull() );
1119  if (!hcalElems.empty())
1120  LogTrace("PFAlgo|elementLoop") << "\t\tat least one hcal element connected to the track."
1121  << " Sparing Ecal cluster for the hcal loop";
1122 
1123  } //loop print ecal elements
1124 
1125  // tracks which are not linked to an HCAL (or HFHAD)
1126  // are reconstructed now.
1127 
1128  if (hcalElems.empty() && hfHadElems.empty()) {
1129  auto ret_continue = recoTracksNotHCAL(
1130  block, linkData, elements, blockref, active, goodTrackDeadHcal, hasDeadHcal, iEle, ecalElems, trackRef);
1131  if (ret_continue) {
1132  continue;
1133  }
1134  } // end if( hcalElems.empty() && hfHadElems.empty() )
1135 
1136  // In case several HCAL elements are linked to this track,
1137  // unlinking all of them except the closest.
1138  for (auto const& hcal : hcalElems) {
1139  unsigned index = hcal.second;
1140 
1142 
1143 #ifdef EDM_ML_DEBUG
1144  double dist = block.dist(iEle, index, linkData, reco::PFBlock::LINKTEST_ALL);
1145  LogTrace("PFAlgo|elementLoop") << "\telement " << elements[index] << " linked with distance " << dist;
1146 #endif
1148 
1149  // all hcal clusters except the closest
1150  // will be unlinked from the track
1151  if (!hcalFound) { // closest hcal
1152  LogTrace("PFAlgo|elementLoop") << "\t\tclosest hcal cluster, doing nothing";
1153 
1154  hcalFound = true;
1155 
1156  // active[index] = false;
1157  // hcalUsed.push_back( index );
1158  } else { // other associated hcal
1159  // unlink from the track
1160  LogTrace("PFAlgo|elementLoop") << "\t\tsecondary hcal cluster. unlinking";
1161  block.setLink(iEle, index, -1., linkData, PFBlock::LINKTEST_RECHIT);
1162  }
1163  } //loop hcal elements
1164 
1165  // ---Same for HFHAD---
1166  // In case several HFHAD elements are linked to this track,
1167  // unlinking all of them except the closest.
1168  for (auto const& hfhad : hfHadElems) {
1169  unsigned index = hfhad.second;
1170 
1172 
1173 #ifdef EDM_ML_DEBUG
1174  double dist = block.dist(iEle, index, linkData, reco::PFBlock::LINKTEST_ALL);
1175  LogTrace("PFAlgo|elementLoop") << "\telement " << elements[index] << " linked with distance " << dist;
1176 #endif
1177  assert(type == PFBlockElement::HFHAD);
1178 
1179  // all hfhad clusters except the closest
1180  // will be unlinked from the track
1181  if (!hfhadFound) { // closest hfhad
1182  LogTrace("PFAlgo|elementLoop") << "\t\tclosest hfhad cluster, doing nothing";
1183 
1184  hfhadFound = true;
1185 
1186  } else { // other associated hfhad
1187  // unlink from the track
1188  LogTrace("PFAlgo|elementLoop") << "\t\tsecondary hfhad cluster. unlinking";
1189  block.setLink(iEle, index, -1., linkData, PFBlock::LINKTEST_RECHIT);
1190  }
1191  } //loop hfhad elements
1192 
1193  LogTrace("PFAlgo|elementLoop") << "end of loop over iEle";
1194  } // end of outer loop on elements iEle of any type
1195  LogTrace("PFAlgo|elementLoop") << "end of function PFAlgo::elementLoop";
1196 }
1197 
1198 //Arranges the PFBlock elements according to type into the ElementIndices output vector.
1199 //Also checks for dead HCAL area and updates the active and deadArea vectors.
1200 //Returns 0 for elements of TRACK type, 1 otherwise
1203  std::vector<bool>& active,
1204  ElementIndices& inds,
1205  std::vector<bool>& deadArea,
1206  unsigned int iEle) {
1207  switch (type) {
1208  case PFBlockElement::TRACK:
1209  if (active[iEle]) {
1210  inds.trackIs.push_back(iEle);
1211  LogTrace("PFAlgo|decideType") << "TRACK, stored index, continue";
1212  }
1213  break;
1214  case PFBlockElement::ECAL:
1215  if (active[iEle]) {
1216  inds.ecalIs.push_back(iEle);
1217  LogTrace("PFAlgo|decideType") << "ECAL, stored index, continue";
1218  }
1219  return 1; //continue
1220  case PFBlockElement::HCAL:
1221  if (active[iEle]) {
1222  if (elements[iEle].clusterRef()->flags() & reco::CaloCluster::badHcalMarker) {
1223  LogTrace("PFAlgo|decideType") << "HCAL DEAD AREA: remember and skip.";
1224  active[iEle] = false;
1225  deadArea[iEle] = true;
1226  return 1; //continue
1227  }
1228  inds.hcalIs.push_back(iEle);
1229  LogTrace("PFAlgo|decideType") << "HCAL, stored index, continue";
1230  }
1231  return 1; //continue
1232  case PFBlockElement::HO:
1233  if (useHO_) {
1234  if (active[iEle]) {
1235  inds.hoIs.push_back(iEle);
1236  LogTrace("PFAlgo|decideType") << "HO, stored index, continue";
1237  }
1238  }
1239  return 1; //continue
1240  case PFBlockElement::HFEM:
1241  if (active[iEle]) {
1242  inds.hfEmIs.push_back(iEle);
1243  LogTrace("PFAlgo|decideType") << "HFEM, stored index, continue";
1244  }
1245  return 1; //continue
1246  case PFBlockElement::HFHAD:
1247  if (active[iEle]) {
1248  inds.hfHadIs.push_back(iEle);
1249  LogTrace("PFAlgo|decideType") << "HFHAD, stored index, continue";
1250  }
1251  return 1; //continue
1252  default:
1253  return 1; //continue
1254  }
1255  LogTrace("PFAlgo|decideType") << "Did not match type to anything, return 0";
1256  return 0;
1257 }
1258 
1260  reco::PFBlock::LinkData& linkData,
1262  std::vector<bool>& active,
1263  const reco::PFBlockRef& blockref,
1264  ElementIndices& inds) {
1265  LogTrace("PFAlgo|createCandidatesHF") << "starting function PFAlgo::createCandidatesHF";
1266 
1267  bool trackInBlock = !inds.trackIs.empty();
1268  // inds.trackIs can be empty, even if there are tracks in this block,
1269  // but what we want to check is if this block has any track including inactive ones
1270  if (!trackInBlock)
1271  for (unsigned iEle = 0; iEle < elements.size(); iEle++) {
1272  PFBlockElement::Type type = elements[iEle].type();
1273  if (type == PFBlockElement::TRACK) {
1274  trackInBlock = true;
1275  break;
1276  }
1277  }
1278  // there is at least one HF element in this block.
1279  // in case of no track, all elements must be HF
1280  if (!trackInBlock)
1281  assert(inds.hfEmIs.size() + inds.hfHadIs.size() == elements.size());
1282 
1283  //
1284  // Dealing with a block with at least one track
1285  // Occasionally, there are only inactive tracks and multiple HF clusters. Consider such blocks too.
1286  //
1287  if (trackInBlock) { // count any tracks (not only active tracks)
1288  // sorted tracks associated with a HfHad cluster
1289  std::multimap<double, unsigned> sortedTracks;
1290  std::multimap<double, unsigned> sortedTracksActive; // only active ones
1291  // HfEms associated with tracks linked to a HfHad cluster
1292  std::multimap<unsigned, std::pair<double, unsigned>> associatedHfEms;
1293  // Temporary map for HfEm satellite clusters
1294  std::multimap<double, std::pair<unsigned, double>> hfemSatellites;
1295 
1296  //
1297  // Loop over active HfHad clusters
1298  //
1299  for (unsigned iHfHad : inds.hfHadIs) {
1300  PFBlockElement::Type type = elements[iHfHad].type();
1301  assert(type == PFBlockElement::HFHAD);
1302 
1303  PFClusterRef hclusterRef = elements[iHfHad].clusterRef();
1304  assert(!hclusterRef.isNull());
1305 
1306  sortedTracks.clear();
1307  sortedTracksActive.clear();
1308  associatedHfEms.clear();
1309  hfemSatellites.clear();
1310 
1311  // Look for associated tracks
1312  block.associatedElements(
1313  iHfHad, linkData, sortedTracks, reco::PFBlockElement::TRACK, reco::PFBlock::LINKTEST_ALL);
1314 
1315  LogTrace("PFAlgo|createCandidatesHF") << "elements[" << iHfHad << "]=" << elements[iHfHad];
1316 
1317  if (sortedTracks.empty()) {
1318  LogTrace("PFAlgo|createCandidatesHCF") << "\tno associated tracks, keep for later";
1319  continue;
1320  }
1321 
1322  // Lock the HFHAD cluster
1323  active[iHfHad] = false;
1324 
1325  LogTrace("PFAlgo|createCandidatesHF") << sortedTracks.size() << " associated tracks:";
1326 
1327  double totalChargedMomentum = 0.;
1328  double sumpError2 = 0.;
1329 
1330  //
1331  // Loop over all tracks associated to this HFHAD cluster
1332  //
1333  for (auto const& trk : sortedTracks) {
1334  unsigned iTrack = trk.second;
1335 
1336  // Check the track has not already been used
1337  if (!active[iTrack])
1338  continue;
1339  // Sanity check 1
1340  PFBlockElement::Type type = elements[iTrack].type();
1342  // Sanity check 2
1343  reco::TrackRef trackRef = elements[iTrack].trackRef();
1344  assert(!trackRef.isNull());
1345 
1346  // Introduce tracking errors
1347  double trackMomentum = trackRef->p();
1348  totalChargedMomentum += trackMomentum;
1349 
1350  // Also keep the total track momentum error for comparison with the calo energy
1351  double dp = trackRef->qoverpError() * trackMomentum * trackMomentum;
1352  sumpError2 += dp * dp;
1353 
1354  // Store active tracks for 2nd loop to create charged hadrons
1355  sortedTracksActive.emplace(trk);
1356 
1357  // look for HFEM elements associated to iTrack (associated to iHfHad)
1358  std::multimap<double, unsigned> sortedHfEms;
1359  block.associatedElements(
1360  iTrack, linkData, sortedHfEms, reco::PFBlockElement::HFEM, reco::PFBlock::LINKTEST_ALL);
1361 
1362  LogTrace("PFAlgo|createCandidatesHF") << "number of HfEm elements linked to this track: " << sortedHfEms.size();
1363 
1364  bool connectedToHfEm = false; // Will become true if there is at least one HFEM cluster connected
1365 
1366  //
1367  // Loop over all HFEM clusters connected to iTrack
1368  //
1369  for (auto const& hfem : sortedHfEms) {
1370  unsigned iHfEm = hfem.second;
1371  double dist = hfem.first;
1372 
1373  // Ignore HFEM cluters already used
1374  if (!active[iHfEm]) {
1375  LogTrace("PFAlgo|createCandidatesHF") << "cluster locked";
1376  continue;
1377  }
1378 
1379  // Sanity checks
1380  PFBlockElement::Type type = elements[iHfEm].type();
1381  assert(type == PFBlockElement::HFEM);
1382  PFClusterRef eclusterRef = elements[iHfEm].clusterRef();
1383  assert(!eclusterRef.isNull());
1384 
1385  // Check if this HFEM is not closer to another track - ignore it in that case
1386  std::multimap<double, unsigned> sortedTracksHfEm;
1387  block.associatedElements(
1388  iHfEm, linkData, sortedTracksHfEm, reco::PFBlockElement::TRACK, reco::PFBlock::LINKTEST_ALL);
1389  unsigned jTrack = sortedTracksHfEm.begin()->second;
1390  if (jTrack != iTrack)
1391  continue;
1392 
1393  double distHfEm = block.dist(jTrack, iHfEm, linkData, reco::PFBlock::LINKTEST_ALL);
1394  double hfemEnergy = eclusterRef->energy();
1395 
1396  if (!connectedToHfEm) { // This is the closest HFEM cluster - will add its energy later
1397 
1398  LogTrace("PFAlgo|createCandidatesHF") << "closest: " << elements[iHfEm];
1399  connectedToHfEm = true;
1400  std::pair<unsigned, double> satellite(iHfEm, hfemEnergy);
1401  hfemSatellites.emplace(-1., satellite);
1402 
1403  } else { // Keep satellite clusters for later
1404 
1405  // KH: same as above.
1406  std::pair<unsigned, double> satellite(iHfEm, hfemEnergy);
1407  hfemSatellites.emplace(dist, satellite);
1408  }
1409 
1410  std::pair<double, unsigned> associatedHfEm(distHfEm, iHfEm);
1411  associatedHfEms.emplace(iTrack, associatedHfEm);
1412 
1413  } // End loop hfem associated to iTrack
1414  } // sortedTracks
1415 
1416  // HfHad energy
1417  double uncalibratedenergyHfHad = hclusterRef->energy();
1418  double energyHfHad = uncalibratedenergyHfHad;
1420  energyHfHad = thepfEnergyCalibrationHF_.energyHad( // HAD only calibration
1421  uncalibratedenergyHfHad,
1422  hclusterRef->positionREP().Eta(),
1423  hclusterRef->positionREP().Phi());
1424  }
1425  double calibFactorHfHad = (uncalibratedenergyHfHad > 0.) ? energyHfHad / uncalibratedenergyHfHad : 1.;
1426 
1427  // HfEm energy
1428  double energyHfEmTmp = 0.;
1429  double uncalibratedenergyHfEmTmp = 0.;
1430  double energyHfEm = 0.;
1431  double uncalibratedenergyHfEm = 0.;
1432 
1433  // estimated HF resolution and track p error
1434  double caloResolution = hfEnergyResolution(totalChargedMomentum);
1435  caloResolution *= totalChargedMomentum;
1436  double totalError = sqrt(caloResolution * caloResolution + sumpError2);
1437  double nsigmaHFEM = nSigmaHFEM(totalChargedMomentum);
1438  double nsigmaHFHAD = nSigmaHFHAD(totalChargedMomentum);
1439 
1440  // Handle case that no active track gets associated to HfHad cluster
1441  if (sortedTracksActive.empty()) {
1442  // look for HFEM elements associated to iHfHad
1443  std::multimap<double, unsigned> sortedHfEms;
1444  std::multimap<double, unsigned> sortedHfEmsActive;
1445  block.associatedElements(
1446  iHfHad, linkData, sortedHfEms, reco::PFBlockElement::HFEM, reco::PFBlock::LINKTEST_ALL);
1447  //
1448  // If iHfHad is connected to HFEM cluster, Loop over all of them
1449  //
1450  if (!sortedHfEms.empty()) {
1451  for (auto const& hfem : sortedHfEms) {
1452  unsigned iHfEm = hfem.second;
1453  // Ignore HFEM cluters already used
1454  if (!active[iHfEm])
1455  continue;
1456  sortedHfEmsActive.emplace(hfem);
1457  PFClusterRef eclusterRef = elements[iHfEm].clusterRef();
1458  assert(!eclusterRef.isNull());
1459  double hfemEnergy = eclusterRef->energy();
1460  uncalibratedenergyHfEm += hfemEnergy;
1461  energyHfEm = uncalibratedenergyHfEm;
1464  uncalibratedenergyHfEm, 0.0, eclusterRef->positionREP().Eta(), eclusterRef->positionREP().Phi());
1465  energyHfHad = thepfEnergyCalibrationHF_.energyEmHad(
1466  0.0, uncalibratedenergyHfHad, hclusterRef->positionREP().Eta(), hclusterRef->positionREP().Phi());
1467  } // calib true
1468  } // loop over sortedHfEm
1469  } // if !sortedHfEms.empty()
1470  //
1471  // Create HF candidates
1472  unsigned tmpi = reconstructCluster(*hclusterRef, energyHfEm + energyHfHad);
1473  (*pfCandidates_)[tmpi].setHcalEnergy(uncalibratedenergyHfHad, energyHfHad);
1474  (*pfCandidates_)[tmpi].setEcalEnergy(uncalibratedenergyHfEm, energyHfEm);
1475  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iHfHad);
1476  for (auto const& hfem : sortedHfEmsActive) {
1477  unsigned iHfEm = hfem.second;
1478  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iHfEm);
1479  active[iHfEm] = false;
1480  }
1481 
1482  } // if sortedTracksActive.empty() ends
1483  //
1484  // Active tracks are associated.
1485  // Create HFHAD candidates from excess energy w.r.t. tracks
1486  else if ((energyHfHad - totalChargedMomentum) > nsigmaHFHAD * totalError) { // HfHad is excessive
1487  assert(energyHfEm == 0.);
1488  // HfHad candidate from excess
1489  double energyHfHadExcess = max(energyHfHad - totalChargedMomentum, 0.);
1490  double uncalibratedenergyHfHadExcess = energyHfHadExcess / calibFactorHfHad;
1491  unsigned tmpi = reconstructCluster(*hclusterRef, energyHfHadExcess);
1492  (*pfCandidates_)[tmpi].setHcalEnergy(uncalibratedenergyHfHadExcess, energyHfHadExcess);
1493  (*pfCandidates_)[tmpi].setEcalEnergy(0., 0.);
1494  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iHfHad);
1495  energyHfHad = max(energyHfHad - energyHfHadExcess, 0.);
1496  uncalibratedenergyHfHad = max(uncalibratedenergyHfHad - uncalibratedenergyHfHadExcess, 0.);
1497  }
1498  //
1499  // If there is a room for HFEM satellites to get associated,
1500  // loop over all HFEM satellites, starting for the closest to the various tracks
1501  // and adding other satellites until saturation of the total track momentum
1502  //
1503  else {
1504  for (auto const& hfemSatellite : hfemSatellites) {
1505  //
1506  uncalibratedenergyHfEmTmp += std::get<1>(hfemSatellite.second); // KH: raw HFEM energy
1507  energyHfEmTmp = uncalibratedenergyHfEmTmp;
1508  double energyHfHadTmp = uncalibratedenergyHfHad; // now to test hfhad calibration with EM+HAD cases
1509  unsigned iHfEm = std::get<0>(hfemSatellite.second);
1510  PFClusterRef eclusterRef = elements[iHfEm].clusterRef();
1511  assert(!eclusterRef.isNull());
1513  energyHfEmTmp = thepfEnergyCalibrationHF_.energyEmHad(
1514  uncalibratedenergyHfEmTmp, 0.0, eclusterRef->positionREP().Eta(), eclusterRef->positionREP().Phi());
1515  energyHfHadTmp = thepfEnergyCalibrationHF_.energyEmHad(
1516  0.0, uncalibratedenergyHfHad, hclusterRef->positionREP().Eta(), hclusterRef->positionREP().Phi());
1517  }
1518 
1519  double caloEnergyTmp = energyHfEmTmp + energyHfHadTmp;
1520  double calibFactorHfEm = (uncalibratedenergyHfEmTmp > 0.) ? energyHfEmTmp / uncalibratedenergyHfEmTmp : 1.;
1521 
1522  // Continue looping until all closest clusters are exhausted and as long as
1523  // the calorimetric energy does not saturate the total momentum.
1524  if (hfemSatellite.first < 0. || caloEnergyTmp < totalChargedMomentum) {
1525  LogTrace("PFAlgo|createCandidatesHF")
1526  << "\t\t\tactive, adding " << std::get<1>(hfemSatellite.second) << " to HFEM energy, and locking";
1527  active[std::get<0>(hfemSatellite.second)] = false;
1528  // HfEm is excessive (possible for the first hfemSatellite)
1529  if (hfemSatellite.first < 0. && (caloEnergyTmp - totalChargedMomentum) > nsigmaHFEM * totalError) {
1530  // HfEm candidate from excess
1531  double energyHfEmExcess = max(caloEnergyTmp - totalChargedMomentum, 0.);
1532  double uncalibratedenergyHfEmExcess = energyHfEmExcess / calibFactorHfEm;
1533  unsigned tmpi = reconstructCluster(*eclusterRef, energyHfEmExcess);
1534  (*pfCandidates_)[tmpi].setEcalEnergy(uncalibratedenergyHfEmExcess, energyHfEmExcess);
1535  (*pfCandidates_)[tmpi].setHcalEnergy(0, 0.);
1536  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iHfEm);
1537  energyHfEmTmp = max(energyHfEmTmp - energyHfEmExcess, 0.);
1538  uncalibratedenergyHfEmTmp = max(uncalibratedenergyHfEmTmp - uncalibratedenergyHfEmExcess, 0.);
1539  }
1540  energyHfEm = energyHfEmTmp;
1541  uncalibratedenergyHfEm = uncalibratedenergyHfEmTmp;
1542  energyHfHad = energyHfHadTmp;
1543  continue;
1544  }
1545  break;
1546  } // loop over hfemsattelites ends
1547  } // if HFHAD is excessive or not
1548 
1549  //
1550  // Loop over all tracks associated to this HFHAD cluster *again* in order to produce charged hadrons
1551  //
1552  for (auto const& trk : sortedTracksActive) {
1553  unsigned iTrack = trk.second;
1554 
1555  // Sanity check
1556  reco::TrackRef trackRef = elements[iTrack].trackRef();
1557  assert(!trackRef.isNull());
1558 
1559  //
1560  // Reconstructing charged hadrons
1561  //
1562  unsigned tmpi = reconstructTrack(elements[iTrack]);
1563  active[iTrack] = false;
1564  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iHfHad);
1565  auto myHfEms = associatedHfEms.equal_range(iTrack);
1566  for (auto ii = myHfEms.first; ii != myHfEms.second; ++ii) {
1567  unsigned iHfEm = ii->second.second;
1568  if (active[iHfEm])
1569  continue;
1570  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iHfEm);
1571  }
1572  double frac = 0.;
1573  if (totalChargedMomentum)
1574  frac = trackRef->p() / totalChargedMomentum;
1575  (*pfCandidates_)[tmpi].setEcalEnergy(uncalibratedenergyHfEm * frac, energyHfEm * frac);
1576  (*pfCandidates_)[tmpi].setHcalEnergy(uncalibratedenergyHfHad * frac, energyHfHad * frac);
1577 
1578  } // sortedTracks loop ends
1579 
1580  } // iHfHad element loop ends
1581 
1582  //
1583  // Loop over remaining active HfEm clusters
1584  //
1585  for (unsigned iHfEm = 0; iHfEm < elements.size(); iHfEm++) {
1586  PFBlockElement::Type type = elements[iHfEm].type();
1587  if (type == PFBlockElement::HFEM && active[iHfEm]) {
1588  reco::PFClusterRef eclusterRef = elements[iHfEm].clusterRef();
1589  double energyHF = 0.;
1590  double uncalibratedenergyHF = 0.;
1591  unsigned tmpi = 0;
1592  // do EM-only calibration here
1593  energyHF = eclusterRef->energy();
1594  uncalibratedenergyHF = energyHF;
1597  uncalibratedenergyHF, eclusterRef->positionREP().Eta(), eclusterRef->positionREP().Phi());
1598  }
1599  tmpi = reconstructCluster(*eclusterRef, energyHF);
1600  (*pfCandidates_)[tmpi].setEcalEnergy(uncalibratedenergyHF, energyHF);
1601  (*pfCandidates_)[tmpi].setHcalEnergy(0., 0.);
1602  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iHfEm);
1603  active[iHfEm] = false;
1604  LogTrace("PFAlgo|createCandidatesHF") << "HF EM alone from blocks with tracks! " << energyHF;
1605  }
1606  } // remaining active HfEm cluster loop ends
1607 
1608  } // if-statement for blocks including tracks ends here
1609  //
1610  // -----------------------------------------------
1611  // From here, traditional PF HF candidate creation
1612  // -----------------------------------------------
1613  //
1614  else if (elements.size() == 1) {
1615  //Auguste: HAD-only calibration here
1616  reco::PFClusterRef clusterRef = elements[0].clusterRef();
1617  double energyHF = 0.;
1618  double uncalibratedenergyHF = 0.;
1619  unsigned tmpi = 0;
1620  switch (clusterRef->layer()) {
1621  case PFLayer::HF_EM:
1622  // do EM-only calibration here
1623  energyHF = clusterRef->energy();
1624  uncalibratedenergyHF = energyHF;
1627  uncalibratedenergyHF, clusterRef->positionREP().Eta(), clusterRef->positionREP().Phi());
1628  }
1629  tmpi = reconstructCluster(*clusterRef, energyHF);
1630  (*pfCandidates_)[tmpi].setEcalEnergy(uncalibratedenergyHF, energyHF);
1631  (*pfCandidates_)[tmpi].setHcalEnergy(0., 0.);
1632  (*pfCandidates_)[tmpi].setHoEnergy(0., 0.);
1633  (*pfCandidates_)[tmpi].setPs1Energy(0.);
1634  (*pfCandidates_)[tmpi].setPs2Energy(0.);
1635  (*pfCandidates_)[tmpi].addElementInBlock(blockref, inds.hfEmIs[0]);
1636  LogTrace("PFAlgo|createCandidatesHF") << "HF EM alone ! " << energyHF;
1637  break;
1638  case PFLayer::HF_HAD:
1639  // do HAD-only calibration here
1640  energyHF = clusterRef->energy();
1641  uncalibratedenergyHF = energyHF;
1644  uncalibratedenergyHF, clusterRef->positionREP().Eta(), clusterRef->positionREP().Phi());
1645  }
1646  tmpi = reconstructCluster(*clusterRef, energyHF);
1647  (*pfCandidates_)[tmpi].setHcalEnergy(uncalibratedenergyHF, energyHF);
1648  (*pfCandidates_)[tmpi].setEcalEnergy(0., 0.);
1649  (*pfCandidates_)[tmpi].setHoEnergy(0., 0.);
1650  (*pfCandidates_)[tmpi].setPs1Energy(0.);
1651  (*pfCandidates_)[tmpi].setPs2Energy(0.);
1652  (*pfCandidates_)[tmpi].addElementInBlock(blockref, inds.hfHadIs[0]);
1653  LogTrace("PFAlgo|createCandidatesHF") << "HF Had alone ! " << energyHF;
1654  break;
1655  default:
1656  assert(0);
1657  }
1658  } else if (elements.size() == 2) {
1659  //Auguste: EM + HAD calibration here
1660  reco::PFClusterRef c0 = elements[0].clusterRef();
1661  reco::PFClusterRef c1 = elements[1].clusterRef();
1662  // 2 HF elements. Must be in each layer.
1663  reco::PFClusterRef cem = (c0->layer() == PFLayer::HF_EM ? c0 : c1);
1664  reco::PFClusterRef chad = (c1->layer() == PFLayer::HF_HAD ? c1 : c0);
1665 
1666  if (cem->layer() != PFLayer::HF_EM || chad->layer() != PFLayer::HF_HAD) {
1667  edm::LogError("PFAlgo::createCandidatesHF") << "Error: 2 elements, but not 1 HFEM and 1 HFHAD";
1668  edm::LogError("PFAlgo::createCandidatesHF") << block;
1669  assert(0);
1670  // assert( c1->layer()== PFLayer::HF_EM &&
1671  // c0->layer()== PFLayer::HF_HAD );
1672  }
1673  // do EM+HAD calibration here
1674  double energyHfEm = cem->energy();
1675  double energyHfHad = chad->energy();
1676  double uncalibratedenergyHfEm = energyHfEm;
1677  double uncalibratedenergyHfHad = energyHfHad;
1680  uncalibratedenergyHfEm, 0.0, c0->positionREP().Eta(), c0->positionREP().Phi());
1681  energyHfHad = thepfEnergyCalibrationHF_.energyEmHad(
1682  0.0, uncalibratedenergyHfHad, c1->positionREP().Eta(), c1->positionREP().Phi());
1683  }
1684  auto& cand = (*pfCandidates_)[reconstructCluster(*chad, energyHfEm + energyHfHad)];
1685  cand.setEcalEnergy(uncalibratedenergyHfEm, energyHfEm);
1686  cand.setHcalEnergy(uncalibratedenergyHfHad, energyHfHad);
1687  cand.setHoEnergy(0., 0.);
1688  cand.setPs1Energy(0.);
1689  cand.setPs2Energy(0.);
1690  cand.addElementInBlock(blockref, inds.hfEmIs[0]);
1691  cand.addElementInBlock(blockref, inds.hfHadIs[0]);
1692  LogTrace("PFAlgo|createCandidatesHF") << "HF EM+HAD found ! " << energyHfEm << " " << energyHfHad;
1693  } else {
1694  // Unusual blocks including HF elements, but do not fit any of the above categories
1695  edm::LogWarning("PFAlgo::createCandidatesHF")
1696  << "Warning: HF, but n elem different from 1 or 2 or >=3 or !trackIs.empty()";
1697  edm::LogWarning("PFAlgo::createCandidatesHF") << block;
1698  }
1699  LogTrace("PFAlgo|createCandidateHF") << "end of function PFAlgo::createCandidateHF";
1700 }
1701 
1703  reco::PFBlock::LinkData& linkData,
1705  std::vector<bool>& active,
1706  const reco::PFBlockRef& blockref,
1707  ElementIndices& inds,
1708  std::vector<bool>& deadArea) {
1709  LogTrace("PFAlgo|createCandidatesHCAL")
1710  << "start of function PFAlgo::createCandidatesHCAL, inds.hcalIs.size()=" << inds.hcalIs.size();
1711 
1712  // --------------- loop hcal ------------------
1713 
1714  for (unsigned iHcal : inds.hcalIs) {
1715  PFBlockElement::Type type = elements[iHcal].type();
1716 
1718 
1719  LogTrace("PFAlgo|createCandidatesHCAL") << "elements[" << iHcal << "]=" << elements[iHcal];
1720 
1721  // associated tracks
1722  std::multimap<double, unsigned> sortedTracks;
1723  block.associatedElements(iHcal, linkData, sortedTracks, reco::PFBlockElement::TRACK, reco::PFBlock::LINKTEST_ALL);
1724 
1725  std::multimap<unsigned, std::pair<double, unsigned>> associatedEcals;
1726 
1727  std::map<unsigned, std::pair<double, double>> associatedPSs;
1728 
1729  std::multimap<double, std::pair<unsigned, bool>> associatedTracks;
1730 
1731  // A temporary maps for ECAL satellite clusters
1732  std::multimap<double, std::tuple<unsigned, ::math::XYZVector, double>>
1733  ecalSatellites; // last element (double) : correction under the egamma hypothesis
1734  std::tuple<unsigned, ::math::XYZVector, double> fakeSatellite(iHcal, ::math::XYZVector(0., 0., 0.), 1.);
1735  ecalSatellites.emplace(-1., fakeSatellite);
1736 
1737  std::multimap<unsigned, std::pair<double, unsigned>> associatedHOs;
1738 
1739  PFClusterRef hclusterref = elements[iHcal].clusterRef();
1740  assert(!hclusterref.isNull());
1741 
1742  //if there is no track attached to that HCAL, then do not
1743  //reconstruct an HCAL alone, check if it can be recovered
1744  //first
1745 
1746  // if no associated tracks, create a neutral hadron
1747  //if(sortedTracks.empty() ) {
1748 
1749  if (sortedTracks.empty()) {
1750  LogTrace("PFAlgo|createCandidatesHCAL") << "\tno associated tracks, keep for later";
1751  continue;
1752  }
1753 
1754  // Lock the HCAL cluster
1755  active[iHcal] = false;
1756 
1757  // in the following, tracks are associated to this hcal cluster.
1758  // will look for an excess of energy in the calorimeters w/r to
1759  // the charged energy, and turn this excess into a neutral hadron or
1760  // a photon.
1761 
1762  LogTrace("PFAlgo|createCandidatesHCAL") << sortedTracks.size() << " associated tracks:";
1763 
1764  double totalChargedMomentum = 0;
1765  double sumpError2 = 0.;
1766  double totalHO = 0.;
1767  double totalEcal = 0.;
1768  double totalEcalEGMCalib = 0.;
1769  double totalHcal = hclusterref->energy();
1770  vector<double> hcalP;
1771  vector<double> hcalDP;
1772  vector<unsigned> tkIs;
1773  double maxDPovP = -9999.;
1774 
1775  //Keep track of how much energy is assigned to calorimeter-vs-track energy/momentum excess
1776  vector<unsigned> chargedHadronsIndices;
1777  vector<unsigned> chargedHadronsInBlock;
1778  double mergedNeutralHadronEnergy = 0;
1779  double mergedPhotonEnergy = 0;
1780  double muonHCALEnergy = 0.;
1781  double muonECALEnergy = 0.;
1782  double muonHCALError = 0.;
1783  double muonECALError = 0.;
1784  unsigned nMuons = 0;
1785 
1786  ::math::XYZVector photonAtECAL(0., 0., 0.);
1787  std::vector<std::tuple<unsigned, ::math::XYZVector, double>>
1788  ecalClusters; // last element (double) : correction under the egamma hypothesis
1789  double sumEcalClusters = 0;
1790  ::math::XYZVector hadronDirection(
1791  hclusterref->position().X(), hclusterref->position().Y(), hclusterref->position().Z());
1792  hadronDirection = hadronDirection.Unit();
1793  ::math::XYZVector hadronAtECAL = totalHcal * hadronDirection;
1794 
1795  // Loop over all tracks associated to this HCAL cluster
1796  for (auto const& trk : sortedTracks) {
1797  unsigned iTrack = trk.second;
1798 
1799  // Check the track has not already been used (e.g., in electrons, conversions...)
1800  if (!active[iTrack])
1801  continue;
1802  // Sanity check 1
1803  PFBlockElement::Type type = elements[iTrack].type();
1805  // Sanity check 2
1806  reco::TrackRef trackRef = elements[iTrack].trackRef();
1807  assert(!trackRef.isNull());
1808 
1809  // The direction at ECAL entrance
1810  const ::math::XYZPointF& chargedPosition =
1811  dynamic_cast<const reco::PFBlockElementTrack*>(&elements[iTrack])->positionAtECALEntrance();
1812  ::math::XYZVector chargedDirection(chargedPosition.X(), chargedPosition.Y(), chargedPosition.Z());
1813  chargedDirection = chargedDirection.Unit();
1814 
1815  // look for ECAL elements associated to iTrack (associated to iHcal)
1816  std::multimap<double, unsigned> sortedEcals;
1817  block.associatedElements(iTrack, linkData, sortedEcals, reco::PFBlockElement::ECAL, reco::PFBlock::LINKTEST_ALL);
1818 
1819  LogTrace("PFAlgo|createCandidatesHCAL") << "number of Ecal elements linked to this track: " << sortedEcals.size();
1820 
1821  // look for HO elements associated to iTrack (associated to iHcal)
1822  std::multimap<double, unsigned> sortedHOs;
1823  if (useHO_) {
1824  block.associatedElements(iTrack, linkData, sortedHOs, reco::PFBlockElement::HO, reco::PFBlock::LINKTEST_ALL);
1825  }
1826  LogTrace("PFAlgo|createCandidatesHCAL")
1827  << "PFAlgo : number of HO elements linked to this track: " << sortedHOs.size();
1828 
1829  // Create a PF Candidate right away if the track is a tight muon
1830  reco::MuonRef muonRef = elements[iTrack].muonRef();
1831 
1832  bool thisIsAMuon = PFMuonAlgo::isMuon(elements[iTrack]);
1833  bool thisIsAnIsolatedMuon = PFMuonAlgo::isIsolatedMuon(elements[iTrack]);
1834  bool thisIsALooseMuon = false;
1835 
1836  if (!thisIsAMuon) {
1837  thisIsALooseMuon = PFMuonAlgo::isLooseMuon(elements[iTrack]);
1838  }
1839 
1840  if (thisIsAMuon) {
1841  LogTrace("PFAlgo|createCandidatesHCAL") << "This track is identified as a muon - remove it from the stack";
1842  LogTrace("PFAlgo|createCandidatesHCAL") << elements[iTrack];
1843 
1844  // Create a muon.
1845 
1846  unsigned tmpi = reconstructTrack(elements[iTrack]);
1847 
1848  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iTrack);
1849  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iHcal);
1850  double muonHcal = std::min(muonHCAL_[0] + muonHCAL_[1], totalHcal);
1851 
1852  // if muon is isolated and muon momentum exceeds the calo energy, absorb the calo energy
1853  // rationale : there has been a EM showering by the muon in the calorimeter - or the coil -
1854  // and we don't want to double count the energy
1855  bool letMuonEatCaloEnergy = false;
1856 
1857  if (thisIsAnIsolatedMuon) {
1858  // The factor 1.3 is the e/pi factor in HCAL...
1859  double totalCaloEnergy = totalHcal / 1.30;
1860  unsigned iEcal = 0;
1861  if (!sortedEcals.empty()) {
1862  iEcal = sortedEcals.begin()->second;
1863  PFClusterRef eclusterref = elements[iEcal].clusterRef();
1864  totalCaloEnergy += eclusterref->energy();
1865  }
1866 
1867  if (useHO_) {
1868  // The factor 1.3 is assumed to be the e/pi factor in HO, too.
1869  unsigned iHO = 0;
1870  if (!sortedHOs.empty()) {
1871  iHO = sortedHOs.begin()->second;
1872  PFClusterRef eclusterref = elements[iHO].clusterRef();
1873  totalCaloEnergy += eclusterref->energy() / 1.30;
1874  }
1875  }
1876 
1877  if ((pfCandidates_->back()).p() > totalCaloEnergy)
1878  letMuonEatCaloEnergy = true;
1879  }
1880 
1881  if (letMuonEatCaloEnergy)
1882  muonHcal = totalHcal;
1883  double muonEcal = 0.;
1884  unsigned iEcal = 0;
1885  if (!sortedEcals.empty()) {
1886  iEcal = sortedEcals.begin()->second;
1887  PFClusterRef eclusterref = elements[iEcal].clusterRef();
1888  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iEcal);
1889  muonEcal = std::min(muonECAL_[0] + muonECAL_[1], eclusterref->energy());
1890  if (letMuonEatCaloEnergy)
1891  muonEcal = eclusterref->energy();
1892  // If the muon expected energy accounts for the whole ecal cluster energy, lock the ecal cluster
1893  if (eclusterref->energy() - muonEcal < 0.2)
1894  active[iEcal] = false;
1895  (*pfCandidates_)[tmpi].setEcalEnergy(eclusterref->energy(), muonEcal);
1896  }
1897  unsigned iHO = 0;
1898  double muonHO = 0.;
1899  if (useHO_) {
1900  if (!sortedHOs.empty()) {
1901  iHO = sortedHOs.begin()->second;
1902  PFClusterRef hoclusterref = elements[iHO].clusterRef();
1903  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iHO);
1904  muonHO = std::min(muonHO_[0] + muonHO_[1], hoclusterref->energy());
1905  if (letMuonEatCaloEnergy)
1906  muonHO = hoclusterref->energy();
1907  // If the muon expected energy accounts for the whole HO cluster energy, lock the HO cluster
1908  if (hoclusterref->energy() - muonHO < 0.2)
1909  active[iHO] = false;
1910  (*pfCandidates_)[tmpi].setHcalEnergy(totalHcal, muonHcal);
1911  (*pfCandidates_)[tmpi].setHoEnergy(hoclusterref->energy(), muonHO);
1912  }
1913  } else {
1914  (*pfCandidates_)[tmpi].setHcalEnergy(totalHcal, muonHcal);
1915  }
1916  setHcalDepthInfo((*pfCandidates_)[tmpi], *hclusterref);
1917 
1918  if (letMuonEatCaloEnergy) {
1919  muonHCALEnergy += totalHcal;
1920  if (useHO_)
1921  muonHCALEnergy += muonHO;
1922  muonHCALError += 0.;
1923  muonECALEnergy += muonEcal;
1924  muonECALError += 0.;
1925  photonAtECAL -= muonEcal * chargedDirection;
1926  hadronAtECAL -= totalHcal * chargedDirection;
1927  if (!sortedEcals.empty())
1928  active[iEcal] = false;
1929  active[iHcal] = false;
1930  if (useHO_ && !sortedHOs.empty())
1931  active[iHO] = false;
1932  } else {
1933  // Estimate of the energy deposit & resolution in the calorimeters
1934  muonHCALEnergy += muonHCAL_[0];
1935  muonHCALError += muonHCAL_[1] * muonHCAL_[1];
1936  if (muonHO > 0.) {
1937  muonHCALEnergy += muonHO_[0];
1938  muonHCALError += muonHO_[1] * muonHO_[1];
1939  }
1940  muonECALEnergy += muonECAL_[0];
1941  muonECALError += muonECAL_[1] * muonECAL_[1];
1942  // ... as well as the equivalent "momentum" at ECAL entrance
1943  photonAtECAL -= muonECAL_[0] * chargedDirection;
1944  hadronAtECAL -= muonHCAL_[0] * chargedDirection;
1945  }
1946 
1947  // Remove it from the stack
1948  active[iTrack] = false;
1949  // Go to next track
1950  continue;
1951  }
1952 
1953  //
1954 
1955  LogTrace("PFAlgo|createCandidatesHCAL") << "elements[iTrack=" << iTrack << "]=" << elements[iTrack];
1956 
1957  // introduce tracking errors
1958  double trackMomentum = trackRef->p();
1959  totalChargedMomentum += trackMomentum;
1960 
1961  // If the track is not a tight muon, but still resembles a muon
1962  // keep it for later for blocks with too large a charged energy
1963  if (thisIsALooseMuon && !thisIsAMuon)
1964  nMuons += 1;
1965 
1966  // ... and keep anyway the pt error for possible fake rejection
1967  // ... blow up errors of 5th and 4th iteration, to reject those
1968  // ... tracks first (in case it's needed)
1969  double dpt = trackRef->ptError();
1970  double blowError = PFTrackAlgoTools::errorScale(trackRef->algo(), factors45_);
1971  // except if it is from an interaction
1972  bool isPrimaryOrSecondary = isFromSecInt(elements[iTrack], "all");
1973 
1974  if (isPrimaryOrSecondary)
1975  blowError = 1.;
1976 
1977  std::pair<unsigned, bool> tkmuon(iTrack, thisIsALooseMuon);
1978  associatedTracks.emplace(-dpt * blowError, tkmuon);
1979 
1980  // Also keep the total track momentum error for comparison with the calo energy
1981  double dp = trackRef->qoverpError() * trackMomentum * trackMomentum;
1982  sumpError2 += dp * dp;
1983 
1984  bool connectedToEcal = false; // Will become true if there is at least one ECAL cluster connected
1985  if (!sortedEcals.empty()) { // start case: at least one ecal element associated to iTrack
1986 
1987  // Loop over all connected ECAL clusters
1988  for (auto const& ecal : sortedEcals) {
1989  unsigned iEcal = ecal.second;
1990  double dist = ecal.first;
1991 
1992  // Ignore ECAL cluters already used
1993  if (!active[iEcal]) {
1994  LogTrace("PFAlgo|createCandidatesHCAL") << "cluster locked";
1995  continue;
1996  }
1997 
1998  // Sanity checks
1999  PFBlockElement::Type type = elements[iEcal].type();
2001  PFClusterRef eclusterref = elements[iEcal].clusterRef();
2002  assert(!eclusterref.isNull());
2003 
2004  // Check if this ECAL is not closer to another track - ignore it in that case
2005  std::multimap<double, unsigned> sortedTracksEcal;
2006  block.associatedElements(
2007  iEcal, linkData, sortedTracksEcal, reco::PFBlockElement::TRACK, reco::PFBlock::LINKTEST_ALL);
2008  unsigned jTrack = sortedTracksEcal.begin()->second;
2009  if (jTrack != iTrack)
2010  continue;
2011 
2012  double distEcal = block.dist(jTrack, iEcal, linkData, reco::PFBlock::LINKTEST_ALL);
2013 
2014  float ecalEnergyCalibrated = eclusterref->correctedEnergy(); // calibrated based on the egamma hypothesis
2015  float ecalEnergy = eclusterref->energy();
2016  ::math::XYZVector photonDirection(
2017  eclusterref->position().X(), eclusterref->position().Y(), eclusterref->position().Z());
2018  photonDirection = photonDirection.Unit();
2019 
2020  if (!connectedToEcal) { // This is the closest ECAL cluster - will add its energy later
2021 
2022  LogTrace("PFAlgo|createCandidatesHCAL") << "closest: " << elements[iEcal];
2023 
2024  connectedToEcal = true;
2025  // PJ 1st-April-09 : To be done somewhere !!! (Had to comment it, but it is needed)
2026  // currentChargedHadron.addElementInBlock( blockref, iEcal );
2027 
2028  // KH: we don't know if this satellite is due to egamma or hadron shower. use raw energy for PF hadron calibration._ store also calibration constant.
2029  double ecalCalibFactor = (ecalEnergy > 1E-9) ? ecalEnergyCalibrated / ecalEnergy : 1.;
2030  std::tuple<unsigned, ::math::XYZVector, double> satellite(
2031  iEcal, ecalEnergy * photonDirection, ecalCalibFactor);
2032  ecalSatellites.emplace(-1., satellite);
2033 
2034  } else { // Keep satellite clusters for later
2035 
2036  // KH: same as above.
2037  double ecalCalibFactor = (ecalEnergy > 1E-9) ? ecalEnergyCalibrated / ecalEnergy : 1.;
2038  std::tuple<unsigned, ::math::XYZVector, double> satellite(
2039  iEcal, ecalEnergy * photonDirection, ecalCalibFactor);
2040  ecalSatellites.emplace(dist, satellite);
2041  }
2042 
2043  std::pair<double, unsigned> associatedEcal(distEcal, iEcal);
2044  associatedEcals.emplace(iTrack, associatedEcal);
2045 
2046  } // End loop ecal associated to iTrack
2047  } // end case: at least one ecal element associated to iTrack
2048 
2049  if (useHO_ && !sortedHOs.empty()) { // start case: at least one ho element associated to iTrack
2050 
2051  // Loop over all connected HO clusters
2052  for (auto const& ho : sortedHOs) {
2053  unsigned iHO = ho.second;
2054  double distHO = ho.first;
2055 
2056  // Ignore HO cluters already used
2057  if (!active[iHO]) {
2058  LogTrace("PFAlgo|createCandidatesHCAL") << "cluster locked";
2059  continue;
2060  }
2061 
2062  // Sanity checks
2063  PFBlockElement::Type type = elements[iHO].type();
2065  PFClusterRef hoclusterref = elements[iHO].clusterRef();
2066  assert(!hoclusterref.isNull());
2067 
2068  // Check if this HO is not closer to another track - ignore it in that case
2069  std::multimap<double, unsigned> sortedTracksHO;
2070  block.associatedElements(
2071  iHO, linkData, sortedTracksHO, reco::PFBlockElement::TRACK, reco::PFBlock::LINKTEST_ALL);
2072  unsigned jTrack = sortedTracksHO.begin()->second;
2073  if (jTrack != iTrack)
2074  continue;
2075 
2076  // double chi2HO = block.chi2(jTrack,iHO,linkData,
2077  // reco::PFBlock::LINKTEST_ALL);
2078  //double distHO = block.dist(jTrack,iHO,linkData,
2079  // reco::PFBlock::LINKTEST_ALL);
2080 
2081  // Increment the total energy by the energy of this HO cluster
2082  totalHO += hoclusterref->energy();
2083  active[iHO] = false;
2084  // Keep track for later reference in the PFCandidate.
2085  std::pair<double, unsigned> associatedHO(distHO, iHO);
2086  associatedHOs.emplace(iTrack, associatedHO);
2087 
2088  } // End loop ho associated to iTrack
2089  } // end case: at least one ho element associated to iTrack
2090 
2091  } // end loop on tracks associated to hcal element iHcal
2092 
2093  // Include totalHO in totalHCAL for the time being (it will be calibrated as HCAL energy)
2094  totalHcal += totalHO;
2095 
2096  // test compatibility between calo and tracker. //////////////
2097 
2098  double caloEnergy = 0.;
2099  double slopeEcal = 1.0;
2100  double calibEcal = 0.;
2101  double calibHcal = 0.;
2102  hadronDirection = hadronAtECAL.Unit();
2103 
2104  // Determine the expected calo resolution from the total charged momentum
2105  double caloResolution = neutralHadronEnergyResolution(totalChargedMomentum, hclusterref->positionREP().Eta());
2106  caloResolution *= totalChargedMomentum;
2107  // Account for muons
2108  caloResolution = std::sqrt(caloResolution * caloResolution + muonHCALError + muonECALError);
2109  totalEcal -= std::min(totalEcal, muonECALEnergy);
2110  totalEcalEGMCalib -= std::min(totalEcalEGMCalib, muonECALEnergy);
2111  totalHcal -= std::min(totalHcal, muonHCALEnergy);
2112  if (totalEcal < 1E-9)
2113  photonAtECAL = ::math::XYZVector(0., 0., 0.);
2114  if (totalHcal < 1E-9)
2115  hadronAtECAL = ::math::XYZVector(0., 0., 0.);
2116 
2117  // Loop over all ECAL satellites, starting for the closest to the various tracks
2118  // and adding other satellites until saturation of the total track momentum
2119  // Note : for code simplicity, the first element of the loop is the HCAL cluster
2120  // with 0 energy in the ECAL
2121  for (auto const& ecalSatellite : ecalSatellites) {
2122  // Add the energy of this ECAL cluster
2123  double previousCalibEcal = calibEcal;
2124  double previousCalibHcal = calibHcal;
2125  double previousCaloEnergy = caloEnergy;
2126  double previousSlopeEcal = slopeEcal;
2127  ::math::XYZVector previousHadronAtECAL = hadronAtECAL;
2128  //
2129  totalEcal +=
2130  sqrt(std::get<1>(ecalSatellite.second).Mag2()); // KH: raw ECAL energy for input to PF hadron calibration
2131  totalEcalEGMCalib += sqrt(std::get<1>(ecalSatellite.second).Mag2()) *
2132  std::get<2>(ecalSatellite.second); // KH: calibrated ECAL energy under the egamma hypothesis
2133  photonAtECAL += std::get<1>(ecalSatellite.second) *
2134  std::get<2>(ecalSatellite.second); // KH: calibrated ECAL energy under the egamma hypothesis
2135  calibEcal = std::max(0., totalEcal); // KH: preparing for hadron calibration
2136  calibHcal = std::max(0., totalHcal);
2137  hadronAtECAL = calibHcal * hadronDirection;
2138  // Calibrate ECAL and HCAL energy under the hadron hypothesis.
2139  calibration_.energyEmHad(totalChargedMomentum,
2140  calibEcal,
2141  calibHcal,
2142  hclusterref->positionREP().Eta(),
2143  hclusterref->positionREP().Phi());
2144  caloEnergy = calibEcal + calibHcal;
2145  if (totalEcal > 0.)
2146  slopeEcal = calibEcal / totalEcal;
2147 
2148  hadronAtECAL = calibHcal * hadronDirection;
2149 
2150  // Continue looping until all closest clusters are exhausted and as long as
2151  // the calorimetric energy does not saturate the total momentum.
2152  if (ecalSatellite.first < 0. || caloEnergy - totalChargedMomentum <= 0.) {
2153  LogTrace("PFAlgo|createCandidatesHCAL")
2154  << "\t\t\tactive, adding " << std::get<1>(ecalSatellite.second) << " to ECAL energy, and locking";
2155  active[std::get<0>(ecalSatellite.second)] = false;
2156  double clusterEnergy =
2157  sqrt(std::get<1>(ecalSatellite.second).Mag2()) *
2158  std::get<2>(ecalSatellite.second); // KH: ECAL energy calibrated under the egamma hypothesis
2159  if (clusterEnergy > 50) { // KH: used to split energetic ecal clusters (E>50 GeV)
2160  ecalClusters.push_back(ecalSatellite.second);
2161  sumEcalClusters += clusterEnergy;
2162  }
2163  continue;
2164  }
2165 
2166  // Otherwise, do not consider the last cluster examined and exit.
2167  // active[is->second.first] = true;
2168  totalEcal -= sqrt(std::get<1>(ecalSatellite.second).Mag2());
2169  totalEcalEGMCalib -= sqrt(std::get<1>(ecalSatellite.second).Mag2()) * std::get<2>(ecalSatellite.second);
2170  photonAtECAL -= std::get<1>(ecalSatellite.second) * std::get<2>(ecalSatellite.second);
2171  calibEcal = previousCalibEcal;
2172  calibHcal = previousCalibHcal;
2173  hadronAtECAL = previousHadronAtECAL;
2174  slopeEcal = previousSlopeEcal;
2175  caloEnergy = previousCaloEnergy;
2176 
2177  break;
2178  }
2179 
2180  // Sanity check !
2181  assert(caloEnergy >= 0);
2182 
2183  // And now check for hadronic energy excess...
2184 
2185  //colin: resolution should be measured on the ecal+hcal case.
2186  // however, the result will be close.
2187  // double caloResolution = neutralHadronEnergyResolution( caloEnergy );
2188  // caloResolution *= caloEnergy;
2189  // PJ The resolution is on the expected charged calo energy !
2190  //double caloResolution = neutralHadronEnergyResolution( totalChargedMomentum, hclusterref->positionREP().Eta());
2191  //caloResolution *= totalChargedMomentum;
2192  // that of the charged particles linked to the cluster!
2193 
2195  if (totalChargedMomentum - caloEnergy > nSigmaTRACK_ * caloResolution) {
2196  // First consider loose muons
2197  if (nMuons > 0) {
2198  for (auto const& trk : associatedTracks) {
2199  // Only muons
2200  if (!trk.second.second)
2201  continue;
2202 
2203  const unsigned int iTrack = trk.second.first;
2204  // Only active tracks
2205  if (!active[iTrack])
2206  continue;
2207 
2208  const double trackMomentum = elements[trk.second.first].trackRef()->p();
2209 
2210  // look for ECAL elements associated to iTrack (associated to iHcal)
2211  std::multimap<double, unsigned> sortedEcals;
2212  block.associatedElements(
2213  iTrack, linkData, sortedEcals, reco::PFBlockElement::ECAL, reco::PFBlock::LINKTEST_ALL);
2214  std::multimap<double, unsigned> sortedHOs;
2215  block.associatedElements(iTrack, linkData, sortedHOs, reco::PFBlockElement::HO, reco::PFBlock::LINKTEST_ALL);
2216 
2217  //Here allow for loose muons!
2218  auto& muon = (*pfCandidates_)[reconstructTrack(elements[iTrack], true)];
2219 
2220  muon.addElementInBlock(blockref, iTrack);
2221  muon.addElementInBlock(blockref, iHcal);
2222  const double muonHcal = std::min(muonHCAL_[0] + muonHCAL_[1], totalHcal - totalHO);
2223  double muonHO = 0.;
2224  muon.setHcalEnergy(totalHcal, muonHcal);
2225  if (!sortedEcals.empty()) {
2226  const unsigned int iEcal = sortedEcals.begin()->second;
2227  PFClusterRef eclusterref = elements[iEcal].clusterRef();
2228  muon.addElementInBlock(blockref, iEcal);
2229  const double muonEcal = std::min(muonECAL_[0] + muonECAL_[1], eclusterref->energy());
2230  muon.setEcalEnergy(eclusterref->energy(), muonEcal);
2231  }
2232  if (useHO_ && !sortedHOs.empty()) {
2233  const unsigned int iHO = sortedHOs.begin()->second;
2234  PFClusterRef hoclusterref = elements[iHO].clusterRef();
2235  muon.addElementInBlock(blockref, iHO);
2236  muonHO = std::min(muonHO_[0] + muonHO_[1], hoclusterref->energy());
2237  muon.setHcalEnergy(max(totalHcal - totalHO, 0.0), muonHcal);
2238  muon.setHoEnergy(hoclusterref->energy(), muonHO);
2239  }
2240  setHcalDepthInfo(muon, *hclusterref);
2241  // Remove it from the block
2242  const ::math::XYZPointF& chargedPosition =
2243  dynamic_cast<const reco::PFBlockElementTrack*>(&elements[trk.second.first])->positionAtECALEntrance();
2244  ::math::XYZVector chargedDirection(chargedPosition.X(), chargedPosition.Y(), chargedPosition.Z());
2245  chargedDirection = chargedDirection.Unit();
2246  totalChargedMomentum -= trackMomentum;
2247  // Update the calo energies
2248  if (totalEcal > 0.)
2249  calibEcal -= std::min(calibEcal, muonECAL_[0] * calibEcal / totalEcal);
2250  if (totalHcal > 0.)
2251  calibHcal -= std::min(calibHcal, muonHCAL_[0] * calibHcal / totalHcal);
2252  totalEcal -= std::min(totalEcal, muonECAL_[0]);
2253  totalHcal -= std::min(totalHcal, muonHCAL_[0]);
2254  if (totalEcal > muonECAL_[0])
2255  photonAtECAL -= muonECAL_[0] * chargedDirection;
2256  if (totalHcal > muonHCAL_[0])
2257  hadronAtECAL -= muonHCAL_[0] * calibHcal / totalHcal * chargedDirection;
2258  caloEnergy = calibEcal + calibHcal;
2259  muonHCALEnergy += muonHCAL_[0];
2260  muonHCALError += muonHCAL_[1] * muonHCAL_[1];
2261  if (muonHO > 0.) {
2262  muonHCALEnergy += muonHO_[0];
2263  muonHCALError += muonHO_[1] * muonHO_[1];
2264  if (totalHcal > 0.) {
2265  calibHcal -= std::min(calibHcal, muonHO_[0] * calibHcal / totalHcal);
2266  totalHcal -= std::min(totalHcal, muonHO_[0]);
2267  }
2268  }
2269  muonECALEnergy += muonECAL_[0];
2270  muonECALError += muonECAL_[1] * muonECAL_[1];
2271  active[iTrack] = false;
2272  // Stop the loop whenever enough muons are removed
2273  //Commented out: Keep looking for muons since they often come in pairs -Matt
2274  //if ( totalChargedMomentum < caloEnergy ) break;
2275  }
2276  // New calo resolution.
2277  caloResolution = neutralHadronEnergyResolution(totalChargedMomentum, hclusterref->positionREP().Eta());
2278  caloResolution *= totalChargedMomentum;
2279  caloResolution = std::sqrt(caloResolution * caloResolution + muonHCALError + muonECALError);
2280  }
2281  }
2282 
2283 #ifdef EDM_ML_DEBUG
2284  LogTrace("PFAlgo|createCandidatesHCAL") << "\tBefore Cleaning ";
2285  LogTrace("PFAlgo|createCandidatesHCAL") << "\tCompare Calo Energy to total charged momentum ";
2286  LogTrace("PFAlgo|createCandidatesHCAL") << "\t\tsum p = " << totalChargedMomentum << " +- " << sqrt(sumpError2);
2287  LogTrace("PFAlgo|createCandidatesHCAL") << "\t\tsum ecal = " << totalEcal;
2288  LogTrace("PFAlgo|createCandidatesHCAL") << "\t\tsum hcal = " << totalHcal;
2289  LogTrace("PFAlgo|createCandidatesHCAL") << "\t\t => Calo Energy = " << caloEnergy << " +- " << caloResolution;
2290  LogTrace("PFAlgo|createCandidatesHCAL")
2291  << "\t\t => Calo Energy- total charged momentum = " << caloEnergy - totalChargedMomentum << " +- "
2292  << sqrt(sumpError2 + caloResolution * caloResolution);
2293 #endif
2294 
2295  // Second consider bad tracks (if still needed after muon removal)
2296  unsigned corrTrack = 10000000;
2297  double corrFact = 1.;
2298 
2299  if (rejectTracks_Bad_ && totalChargedMomentum - caloEnergy > nSigmaTRACK_ * caloResolution) {
2300  for (auto const& trk : associatedTracks) {
2301  const unsigned iTrack = trk.second.first;
2302  // Only active tracks
2303  if (!active[iTrack])
2304  continue;
2305  const reco::TrackRef& trackref = elements[trk.second.first].trackRef();
2306 
2307  const double dptRel = fabs(trk.first) / trackref->pt() * 100;
2308  const bool isSecondary = isFromSecInt(elements[iTrack], "secondary");
2309  const bool isPrimary = isFromSecInt(elements[iTrack], "primary");
2310 
2311  if (isSecondary && dptRel < dptRel_DispVtx_)
2312  continue;
2313  // Consider only bad tracks
2314  if (fabs(trk.first) < ptError_)
2315  break;
2316  // What would become the block charged momentum if this track were removed
2317  const double wouldBeTotalChargedMomentum = totalChargedMomentum - trackref->p();
2318  // Reject worst tracks, as long as the total charged momentum
2319  // is larger than the calo energy
2320 
2321  if (wouldBeTotalChargedMomentum > caloEnergy) {
2322  if (isSecondary) {
2323  LogTrace("PFAlgo|createCandidatesHCAL")
2324  << "In bad track rejection step dptRel = " << dptRel << " dptRel_DispVtx_ = " << dptRel_DispVtx_;
2325  LogTrace("PFAlgo|createCandidatesHCAL")
2326  << "The calo energy would be still smaller even without this track but it is attached to a NI";
2327  }
2328 
2329  if (isPrimary || (isSecondary && dptRel < dptRel_DispVtx_))
2330  continue;
2331  active[iTrack] = false;
2332  totalChargedMomentum = wouldBeTotalChargedMomentum;
2333  LogTrace("PFAlgo|createCandidatesHCAL")
2334  << "\tElement " << elements[iTrack] << " rejected (dpt = " << -trk.first
2335  << " GeV/c, algo = " << trackref->algo() << ")";
2336  // Just rescale the nth worst track momentum to equalize the calo energy
2337  } else {
2338  if (isPrimary)
2339  break;
2340  corrTrack = iTrack;
2341  corrFact = (caloEnergy - wouldBeTotalChargedMomentum) / elements[trk.second.first].trackRef()->p();
2342  if (trackref->p() * corrFact < 0.05) {
2343  corrFact = 0.;
2344  active[iTrack] = false;
2345  }
2346  totalChargedMomentum -= trackref->p() * (1. - corrFact);
2347  LogTrace("PFAlgo|createCandidatesHCAL")
2348  << "\tElement " << elements[iTrack] << " (dpt = " << -trk.first << " GeV/c, algo = " << trackref->algo()
2349  << ") rescaled by " << corrFact << " Now the total charged momentum is " << totalChargedMomentum;
2350  break;
2351  }
2352  }
2353  }
2354 
2355  // New determination of the calo and track resolution avec track deletion/rescaling.
2356  caloResolution = neutralHadronEnergyResolution(totalChargedMomentum, hclusterref->positionREP().Eta());
2357  caloResolution *= totalChargedMomentum;
2358  caloResolution = std::sqrt(caloResolution * caloResolution + muonHCALError + muonECALError);
2359 
2360  // Check if the charged momentum is still very inconsistent with the calo measurement.
2361  // In this case, just drop all tracks from 4th and 5th iteration linked to this block
2362 
2363  if (rejectTracks_Step45_ && sortedTracks.size() > 1 &&
2364  totalChargedMomentum - caloEnergy > nSigmaTRACK_ * caloResolution) {
2365  for (auto const& trk : associatedTracks) {
2366  unsigned iTrack = trk.second.first;
2367  reco::TrackRef trackref = elements[iTrack].trackRef();
2368  if (!active[iTrack])
2369  continue;
2370 
2371  double dptRel = fabs(trk.first) / trackref->pt() * 100;
2372  bool isPrimaryOrSecondary = isFromSecInt(elements[iTrack], "all");
2373 
2374  if (isPrimaryOrSecondary && dptRel < dptRel_DispVtx_)
2375  continue;
2376 
2377  if (PFTrackAlgoTools::step5(trackref->algo())) {
2378  active[iTrack] = false;
2379  totalChargedMomentum -= trackref->p();
2380 
2381  LogTrace("PFAlgo|createCandidatesHCAL")
2382  << "\tElement " << elements[iTrack] << " rejected (dpt = " << -trk.first
2383  << " GeV/c, algo = " << trackref->algo() << ")";
2384  }
2385  }
2386  }
2387 
2388  // New determination of the calo and track resolution avec track deletion/rescaling.
2389  caloResolution = neutralHadronEnergyResolution(totalChargedMomentum, hclusterref->positionREP().Eta());
2390  caloResolution *= totalChargedMomentum;
2391  caloResolution = std::sqrt(caloResolution * caloResolution + muonHCALError + muonECALError);
2392 
2393  // Make PF candidates with the remaining tracks in the block
2394  sumpError2 = 0.;
2395  for (auto const& trk : associatedTracks) {
2396  unsigned iTrack = trk.second.first;
2397  if (!active[iTrack])
2398  continue;
2399  reco::TrackRef trackRef = elements[iTrack].trackRef();
2400  double trackMomentum = trackRef->p();
2401  double dp = trackRef->qoverpError() * trackMomentum * trackMomentum;
2402  unsigned tmpi = reconstructTrack(elements[iTrack]);
2403 
2404  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iTrack);
2405  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iHcal);
2406  setHcalDepthInfo((*pfCandidates_)[tmpi], *hclusterref);
2407  auto myEcals = associatedEcals.equal_range(iTrack);
2408  for (auto ii = myEcals.first; ii != myEcals.second; ++ii) {
2409  unsigned iEcal = ii->second.second;
2410  if (active[iEcal])
2411  continue;
2412  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iEcal);
2413  }
2414 
2415  if (useHO_) {
2416  auto myHOs = associatedHOs.equal_range(iTrack);
2417  for (auto ii = myHOs.first; ii != myHOs.second; ++ii) {
2418  unsigned iHO = ii->second.second;
2419  if (active[iHO])
2420  continue;
2421  (*pfCandidates_)[tmpi].addElementInBlock(blockref, iHO);
2422  }
2423  }
2424 
2425  if (iTrack == corrTrack) {
2426  if (corrFact < 0.)
2427  corrFact = 0.; // protect against negative scaling
2428  (*pfCandidates_)[tmpi].rescaleMomentum(corrFact);
2429  trackMomentum *= corrFact;
2430  }
2431  chargedHadronsIndices.push_back(tmpi);
2432  chargedHadronsInBlock.push_back(iTrack);
2433  active[iTrack] = false;
2434  hcalP.push_back(trackMomentum);
2435  hcalDP.push_back(dp);
2436  if (dp / trackMomentum > maxDPovP)
2437  maxDPovP = dp / trackMomentum;
2438  sumpError2 += dp * dp;
2439  }
2440 
2441  // The total uncertainty of the difference Calo-Track
2442  double totalError = sqrt(sumpError2 + caloResolution * caloResolution);
2443 
2444 #ifdef EDM_ML_DEBUG
2445  LogTrace("PFAlgo|createCandidatesHCAL")
2446  << "\tCompare Calo Energy to total charged momentum " << endl
2447  << "\t\tsum p = " << totalChargedMomentum << " +- " << sqrt(sumpError2) << endl
2448  << "\t\tsum ecal = " << totalEcal << endl
2449  << "\t\tsum hcal = " << totalHcal << endl
2450  << "\t\t => Calo Energy = " << caloEnergy << " +- " << caloResolution << endl
2451  << "\t\t => Calo Energy- total charged momentum = " << caloEnergy - totalChargedMomentum << " +- "
2452  << totalError;
2453 #endif
2454 
2455  /* */
2456 
2458  double nsigma = nSigmaHCAL(totalChargedMomentum, hclusterref->positionREP().Eta());
2459  //double nsigma = nSigmaHCAL(caloEnergy,hclusterref->positionREP().Eta());
2460  if (abs(totalChargedMomentum - caloEnergy) < nsigma * totalError) {
2461  // deposited caloEnergy compatible with total charged momentum
2462  // if tracking errors are large take weighted average
2463 
2464 #ifdef EDM_ML_DEBUG
2465  LogTrace("PFAlgo|createCandidatesHCAL")
2466  << "\t\tcase 1: COMPATIBLE "
2467  << "|Calo Energy- total charged momentum| = " << abs(caloEnergy - totalChargedMomentum) << " < " << nsigma
2468  << " x " << totalError;
2469  if (maxDPovP < 0.1)
2470  LogTrace("PFAlgo|createCandidatesHCAL") << "\t\t\tmax DP/P = " << maxDPovP << " less than 0.1: do nothing ";
2471  else
2472  LogTrace("PFAlgo|createCandidatesHCAL")
2473  << "\t\t\tmax DP/P = " << maxDPovP << " > 0.1: take weighted averages ";
2474 #endif
2475 
2476  // if max DP/P < 10% do nothing
2477  if (maxDPovP > 0.1) {
2478  // for each track associated to hcal
2479  // int nrows = tkIs.size();
2480  int nrows = chargedHadronsIndices.size();
2481  TMatrixTSym<double> a(nrows);
2482  TVectorD b(nrows);
2483  TVectorD check(nrows);
2484  double sigma2E = caloResolution * caloResolution;
2485  for (int i = 0; i < nrows; i++) {
2486  double sigma2i = hcalDP[i] * hcalDP[i];
2487  LogTrace("PFAlgo|createCandidatesHCAL")
2488  << "\t\t\ttrack associated to hcal " << i << " P = " << hcalP[i] << " +- " << hcalDP[i];
2489  a(i, i) = 1. / sigma2i + 1. / sigma2E;
2490  b(i) = hcalP[i] / sigma2i + caloEnergy / sigma2E;
2491  for (int j = 0; j < nrows; j++) {
2492  if (i == j)
2493  continue;
2494  a(i, j) = 1. / sigma2E;
2495  } // end loop on j
2496  } // end loop on i
2497 
2498  // solve ax = b
2499  TDecompChol decomp(a);
2500  bool ok = false;
2501  TVectorD x = decomp.Solve(b, ok);
2502  // for each track create a PFCandidate track
2503  // with a momentum rescaled to weighted average
2504  if (ok) {
2505  for (int i = 0; i < nrows; i++) {
2506  // unsigned iTrack = trackInfos[i].index;
2507  unsigned ich = chargedHadronsIndices[i];
2508  double rescaleFactor = x(i) / hcalP[i];
2509  if (rescaleFactor < 0.)
2510  rescaleFactor = 0.; // protect against negative scaling
2511  (*pfCandidates_)[ich].rescaleMomentum(rescaleFactor);
2512 
2513  LogTrace("PFAlgo|createCandidatesHCAL")
2514  << "\t\t\told p " << hcalP[i] << " new p " << x(i) << " rescale " << rescaleFactor;
2515  }
2516  } else {
2517  edm::LogError("PFAlgo::createCandidatesHCAL") << "TDecompChol.Solve returned ok=false";
2518  assert(0);
2519  }
2520  }
2521  }
2522 
2524  else if (caloEnergy > totalChargedMomentum) {
2525  //case 2: caloEnergy > totalChargedMomentum + nsigma*totalError
2526  //there is an excess of energy in the calos
2527  //create a neutral hadron or a photon
2528 
2529  double eNeutralHadron = caloEnergy - totalChargedMomentum;
2530  double ePhoton = (caloEnergy - totalChargedMomentum) /
2531  slopeEcal; // KH: this slopeEcal is computed based on ECAL energy under the hadron hypothesis,
2532  // thought we are creating photons.
2533  // This is a fuzzy case, but it should be better than corrected twice under both egamma and hadron hypotheses.
2534 
2535 #ifdef EDM_ML_DEBUG
2536  if (!sortedTracks.empty()) {
2537  LogTrace("PFAlgo|createCandidatesHCAL") << "\t\tcase 2: NEUTRAL DETECTION " << caloEnergy << " > " << nsigma
2538  << "x" << totalError << " + " << totalChargedMomentum;
2539  LogTrace("PFAlgo|createCandidatesHCAL") << "\t\tneutral activity detected: " << endl
2540  << "\t\t\t photon = " << ePhoton << endl
2541  << "\t\t\tor neutral hadron = " << eNeutralHadron;
2542 
2543  LogTrace("PFAlgo|createCandidatesHCAL") << "\t\tphoton or hadron ?";
2544  }
2545 
2546  if (sortedTracks.empty())
2547  LogTrace("PFAlgo|createCandidatesHCAL") << "\t\tno track -> hadron ";
2548  else
2549  LogTrace("PFAlgo|createCandidatesHCAL")
2550  << "\t\t" << sortedTracks.size() << " tracks -> check if the excess is photonic or hadronic";
2551 #endif
2552 
2553  double ratioMax = 0.;
2554  reco::PFClusterRef maxEcalRef;
2555  unsigned maxiEcal = 9999;
2556 
2557  // for each track associated to hcal: iterator IE ie :
2558 
2559  LogTrace("PFAlgo|createCandidatesHCAL") << "loop over sortedTracks.size()=" << sortedTracks.size();
2560  for (auto const& trk : sortedTracks) {
2561  unsigned iTrack = trk.second;
2562 
2563  PFBlockElement::Type type = elements[iTrack].type();
2565 
2566  reco::TrackRef trackRef = elements[iTrack].trackRef();
2567  assert(!trackRef.isNull());
2568 
2569  auto iae = associatedEcals.find(iTrack);
2570 
2571  if (iae == associatedEcals.end())
2572  continue;
2573 
2574  // double distECAL = iae->second.first;
2575  unsigned iEcal = iae->second.second;
2576 
2577  PFBlockElement::Type typeEcal = elements[iEcal].type();
2578  assert(typeEcal == reco::PFBlockElement::ECAL);
2579 
2580  reco::PFClusterRef clusterRef = elements[iEcal].clusterRef();
2581  assert(!clusterRef.isNull());
2582 
2583  double pTrack = trackRef->p();
2584  double eECAL = clusterRef->energy();
2585  double eECALOverpTrack = eECAL / pTrack;
2586 
2587  if (eECALOverpTrack > ratioMax) {
2588  ratioMax = eECALOverpTrack;
2589  maxEcalRef = clusterRef;
2590  maxiEcal = iEcal;
2591  }
2592 
2593  } // end loop on tracks associated to hcal: iterator IE ie
2594 
2595  std::vector<reco::PFClusterRef> pivotalClusterRef;
2596  std::vector<unsigned> iPivotal;
2597  std::vector<double> particleEnergy, ecalEnergy, hcalEnergy, rawecalEnergy, rawhcalEnergy;
2598  std::vector<::math::XYZVector> particleDirection;
2599 
2600  // If the excess is smaller than the ecal energy, assign the whole
2601  // excess to photons
2602  if (ePhoton < totalEcal || eNeutralHadron - calibEcal < 1E-10) {
2603  if (!maxEcalRef.isNull()) {
2604  // So the merged photon energy is,
2605  mergedPhotonEnergy = ePhoton;
2606  }
2607  } else {
2608  // Otherwise assign the whole ECAL energy to the photons
2609  if (!maxEcalRef.isNull()) {
2610  // So the merged photon energy is,
2611  mergedPhotonEnergy = totalEcalEGMCalib; // KH: use calibrated ECAL energy under the egamma hypothesis
2612  }
2613  // ... and assign the remaining excess to neutral hadrons using the direction of ecal clusters
2614  mergedNeutralHadronEnergy = eNeutralHadron - calibEcal;
2615  }
2616 
2617  if (mergedPhotonEnergy > 0) {
2618  // Split merged photon into photons for each energetic ecal cluster (necessary for jet substructure reconstruction)
2619  // make only one merged photon if less than 2 ecal clusters
2620  // KH: this part still needs review, after using non-corrected ECAL energy for PF hadron calibrations
2621  if (ecalClusters.size() <= 1) {
2622  ecalClusters.clear();
2623  ecalClusters.emplace_back(
2624  maxiEcal,
2625  photonAtECAL,
2626  1.); // KH: calibration factor of 1, which should be ok as long as sumEcalClusters is consistent with photonAtECAL in this case
2627  sumEcalClusters = sqrt(photonAtECAL.Mag2());
2628  }
2629  for (auto const& pae : ecalClusters) {
2630  const double clusterEnergyCalibrated =
2631  sqrt(std::get<1>(pae).Mag2()) *
2632  std::get<2>(
2633  pae); // KH: calibrated under the egamma hypothesis. Note: sumEcalClusters is normally calibrated under egamma hypothesis
2634  particleEnergy.push_back(mergedPhotonEnergy * clusterEnergyCalibrated / sumEcalClusters);
2635  particleDirection.push_back(std::get<1>(pae));
2636  ecalEnergy.push_back(mergedPhotonEnergy * clusterEnergyCalibrated / sumEcalClusters);
2637  hcalEnergy.push_back(0.);
2638  rawecalEnergy.push_back(totalEcal);
2639  rawhcalEnergy.push_back(0.);
2640  pivotalClusterRef.push_back(elements[std::get<0>(pae)].clusterRef());
2641  iPivotal.push_back(std::get<0>(pae));
2642  }
2643  } // mergedPhotonEnergy > 0
2644 
2645  if (mergedNeutralHadronEnergy > 1.0) {
2646  // Split merged neutral hadrons according to directions of energetic ecal clusters (necessary for jet substructure reconstruction)
2647  // make only one merged neutral hadron if less than 2 ecal clusters
2648  if (ecalClusters.size() <= 1) {
2649  ecalClusters.clear();
2650  ecalClusters.emplace_back(
2651  iHcal,
2652  hadronAtECAL,
2653  1.); // KH: calibration factor of 1, which should be ok as long as sumEcalClusters is consistent with photonAtECAL
2654  sumEcalClusters = sqrt(hadronAtECAL.Mag2());
2655  }
2656  for (auto const& pae : ecalClusters) {
2657  const double clusterEnergyCalibrated =
2658  sqrt(std::get<1>(pae).Mag2()) *
2659  std::get<2>(
2660  pae); // KH: calibrated under the egamma hypothesis. Note: sumEcalClusters is normally calibrated under egamma hypothesis
2661  particleEnergy.push_back(mergedNeutralHadronEnergy * clusterEnergyCalibrated / sumEcalClusters);
2662  particleDirection.push_back(std::get<1>(pae));
2663  ecalEnergy.push_back(0.);
2664  hcalEnergy.push_back(mergedNeutralHadronEnergy * clusterEnergyCalibrated / sumEcalClusters);
2665  rawecalEnergy.push_back(0.);
2666  rawhcalEnergy.push_back(totalHcal);
2667  pivotalClusterRef.push_back(hclusterref);
2668  iPivotal.push_back(iHcal);
2669  }
2670  } //mergedNeutralHadronEnergy > 1.0
2671 
2672  // reconstructing a merged neutral
2673  // the type of PFCandidate is known from the
2674  // reference to the pivotal cluster.
2675 
2676  for (unsigned iPivot = 0; iPivot < iPivotal.size(); ++iPivot) {
2677  if (particleEnergy[iPivot] < 0.)
2678  edm::LogWarning("PFAlgo|createCandidatesHCAL")
2679  << "ALARM = Negative energy for iPivot=" << iPivot << ", " << particleEnergy[iPivot];
2680 
2681  const bool useDirection = true;
2682  auto& neutral = (*pfCandidates_)[reconstructCluster(*pivotalClusterRef[iPivot],
2683  particleEnergy[iPivot],
2684  useDirection,
2685  particleDirection[iPivot].X(),
2686  particleDirection[iPivot].Y(),
2687  particleDirection[iPivot].Z())];
2688 
2689  neutral.setEcalEnergy(rawecalEnergy[iPivot], ecalEnergy[iPivot]);
2690  if (!useHO_) {
2691  neutral.setHcalEnergy(rawhcalEnergy[iPivot], hcalEnergy[iPivot]);
2692  neutral.setHoEnergy(0., 0.);
2693  } else { // useHO_
2694  if (rawhcalEnergy[iPivot] == 0.) { // photons should be here
2695  neutral.setHcalEnergy(0., 0.);
2696  neutral.setHoEnergy(0., 0.);
2697  } else {
2698  neutral.setHcalEnergy(max(rawhcalEnergy[iPivot] - totalHO, 0.0),
2699  hcalEnergy[iPivot] * max(1. - totalHO / rawhcalEnergy[iPivot], 0.));
2700  neutral.setHoEnergy(totalHO, totalHO * hcalEnergy[iPivot] / rawhcalEnergy[iPivot]);
2701  }
2702  }
2703  neutral.setPs1Energy(0.);
2704  neutral.setPs2Energy(0.);
2705  neutral.set_mva_nothing_gamma(-1.);
2706  // neutral.addElement(&elements[iPivotal]);
2707  // neutral.addElementInBlock(blockref, iPivotal[iPivot]);
2708  neutral.addElementInBlock(blockref, iHcal);
2709  for (unsigned iTrack : chargedHadronsInBlock) {
2710  neutral.addElementInBlock(blockref, iTrack);
2711  // Assign the position of the track at the ECAL entrance
2712  const ::math::XYZPointF& chargedPosition =
2713  dynamic_cast<const reco::PFBlockElementTrack*>(&elements[iTrack])->positionAtECALEntrance();
2714  neutral.setPositionAtECALEntrance(chargedPosition);
2715 
2716  auto myEcals = associatedEcals.equal_range(iTrack);
2717  for (auto ii = myEcals.first; ii != myEcals.second; ++ii) {
2718  unsigned iEcal = ii->second.second;
2719  if (active[iEcal])
2720  continue;
2721  neutral.addElementInBlock(blockref, iEcal);
2722  }
2723  }
2724  }
2725 
2726  } // excess of energy
2727 
2728  // will now share the hcal energy between the various charged hadron
2729  // candidates, taking into account the potential neutral hadrons
2730 
2731  //JB: The question is: we've resolved the merged photons cleanly, but how should
2732  //the remaining hadrons be assigned the remaining ecal energy?
2733  //*Temporary solution*: follow HCAL example with fractions...
2734 
2735  // remove the energy of the potential neutral hadron
2736  double totalHcalEnergyCalibrated = std::max(calibHcal - mergedNeutralHadronEnergy, 0.);
2737  // similarly for the merged photons
2738  double totalEcalEnergyCalibrated = std::max(calibEcal - mergedPhotonEnergy, 0.);
2739  // share between the charged hadrons
2740 
2741  //COLIN can compute this before
2742  // not exactly equal to sum p, this is sum E
2743  double chargedHadronsTotalEnergy = 0;
2744  for (unsigned index : chargedHadronsIndices) {
2745  reco::PFCandidate& chargedHadron = (*pfCandidates_)[index];
2746  chargedHadronsTotalEnergy += chargedHadron.energy();
2747  }
2748 
2749  for (unsigned index : chargedHadronsIndices) {
2750  reco::PFCandidate& chargedHadron = (*pfCandidates_)[index];
2751  float fraction = chargedHadron.energy() / chargedHadronsTotalEnergy;
2752 
2753  if (!useHO_) {
2754  chargedHadron.setHcalEnergy(fraction * totalHcal, fraction * totalHcalEnergyCalibrated);
2755  chargedHadron.setHoEnergy(0., 0.);
2756  } else {
2757  chargedHadron.setHcalEnergy(fraction * max(totalHcal - totalHO, 0.0),
2758  fraction * totalHcalEnergyCalibrated * (1. - totalHO / totalHcal));
2759  chargedHadron.setHoEnergy(fraction * totalHO, fraction * totalHO * totalHcalEnergyCalibrated / totalHcal);
2760  }
2761  //JB: fixing up (previously omitted) setting of ECAL energy gouzevit
2762  chargedHadron.setEcalEnergy(fraction * totalEcal, fraction * totalEcalEnergyCalibrated);
2763  }
2764 
2765  // Finally treat unused ecal satellites as photons.
2766  for (auto const& ecalSatellite : ecalSatellites) {
2767  // Ignore satellites already taken
2768  unsigned iEcal = std::get<0>(ecalSatellite.second);
2769  if (!active[iEcal])
2770  continue;
2771 
2772  // Sanity checks again (well not useful, this time!)
2773  PFBlockElement::Type type = elements[iEcal].type();
2775  PFClusterRef eclusterref = elements[iEcal].clusterRef();
2776  assert(!eclusterref.isNull());
2777 
2778  // Lock the cluster
2779  active[iEcal] = false;
2780 
2781  // Find the associated tracks
2782  std::multimap<double, unsigned> assTracks;
2783  block.associatedElements(iEcal, linkData, assTracks, reco::PFBlockElement::TRACK, reco::PFBlock::LINKTEST_ALL);
2784 
2785  // Create a photon
2786  double ecalClusterEnergyCalibrated =
2787  sqrt(std::get<1>(ecalSatellite.second).Mag2()) *
2788  std::get<2>(
2789  ecalSatellite.second); // KH: calibrated under the egamma hypothesis (rawEcalClusterEnergy * calibration)
2790  auto& cand = (*pfCandidates_)[reconstructCluster(*eclusterref, ecalClusterEnergyCalibrated)];
2791  cand.setEcalEnergy(eclusterref->energy(), ecalClusterEnergyCalibrated);
2792  cand.setHcalEnergy(0., 0.);
2793  cand.setHoEnergy(0., 0.);
2794  cand.setPs1Energy(associatedPSs[iEcal].first);
2795  cand.setPs2Energy(associatedPSs[iEcal].second);
2796  cand.addElementInBlock(blockref, iEcal);
2797  cand.addElementInBlock(blockref, sortedTracks.begin()->second);
2798 
2799  if (fabs(eclusterref->energy() - sqrt(std::get<1>(ecalSatellite.second).Mag2())) > 1e-3 ||
2800  fabs(eclusterref->correctedEnergy() - ecalClusterEnergyCalibrated) > 1e-3)
2801  edm::LogWarning("PFAlgo:processBlock")
2802  << "ecalCluster vs ecalSatellites look inconsistent (eCluster E, calibE, ecalSatellite E, calib E): "
2803  << eclusterref->energy() << " " << eclusterref->correctedEnergy() << " "
2804  << sqrt(std::get<1>(ecalSatellite.second).Mag2()) << " " << ecalClusterEnergyCalibrated;
2805 
2806  } // ecalSatellites
2807 
2808  } // hcalIs
2809  // end loop on hcal element iHcal= hcalIs[i]
2810  LogTrace("PFAlgo|createCandidatesHCAL") << "end of function PFAlgo::createCandidatesHCAL";
2811 }
2812 
2814  reco::PFBlock::LinkData& linkData,
2816  std::vector<bool>& active,
2817  const reco::PFBlockRef& blockref,
2818  ElementIndices& inds,
2819  std::vector<bool>& deadArea) {
2820  // Processing the remaining HCAL clusters
2821  LogTrace("PFAlgo|createCandidatesHCALUnlinked")
2822  << "start of function PFAlgo::createCandidatesHCALUnlinked, hcalIs.size()=" << inds.hcalIs.size();
2823 
2824  // --------------- loop remaining hcal ------------------
2825 
2826  for (unsigned iHcal : inds.hcalIs) {
2827  // Keep ECAL and HO elements for reference in the PFCandidate
2828  std::vector<unsigned> ecalRefs;
2829  std::vector<unsigned> hoRefs;
2830 
2831  LogTrace("PFAlgo|createCandidatesHCALUnlinked") << elements[iHcal] << " ";
2832 
2833  if (!active[iHcal]) {
2834  LogTrace("PFAlgo|createCandidatesHCALUnlinked") << "not active " << iHcal;
2835  continue;
2836  }
2837 
2838  // Find the ECAL elements linked to it
2839  std::multimap<double, unsigned> ecalElems;
2840  block.associatedElements(iHcal, linkData, ecalElems, reco::PFBlockElement::ECAL, reco::PFBlock::LINKTEST_ALL);
2841 
2842  // Loop on these ECAL elements
2843  float totalEcal = 0.;
2844  float ecalMax = 0.;
2845  reco::PFClusterRef eClusterRef;
2846  for (auto const& ecal : ecalElems) {
2847  unsigned iEcal = ecal.second;
2848  double dist = ecal.first;
2849  PFBlockElement::Type type = elements[iEcal].type();
2851 
2852  // Check if already used
2853  if (!active[iEcal])
2854  continue;
2855 
2856  // Check the distance (one HCALPlusECAL tower, roughly)
2857  // if ( dist > 0.15 ) continue;
2858 
2859  //COLINFEB16
2860  // what could be done is to
2861  // - link by rechit.
2862  // - take in the neutral hadron all the ECAL clusters
2863  // which are within the same CaloTower, according to the distance,
2864  // except the ones which are closer to another HCAL cluster.
2865  // - all the other ECAL linked to this HCAL are photons.
2866  //
2867  // about the closest HCAL cluster.
2868  // it could maybe be easier to loop on the ECAL clusters first
2869  // to cut the links to all HCAL clusters except the closest, as is
2870  // done in the first track loop. But maybe not!
2871  // or add an helper function to the PFAlgo class to ask
2872  // if a given element is the closest of a given type to another one?
2873 
2874  // Check if not closer from another free HCAL
2875  std::multimap<double, unsigned> hcalElems;
2876  block.associatedElements(iEcal, linkData, hcalElems, reco::PFBlockElement::HCAL, reco::PFBlock::LINKTEST_ALL);
2877 
2878  const bool isClosest = std::none_of(hcalElems.begin(), hcalElems.end(), [&](auto const& hcal) {
2879  return active[hcal.second] && hcal.first < dist;
2880  });
2881 
2882  if (!isClosest)
2883  continue;
2884 
2885 #ifdef EDM_ML_DEBUG
2886  LogTrace("PFAlgo|createCandidatesHCALUnlinked")
2887  << "\telement " << elements[iEcal] << " linked with dist " << dist;
2888  LogTrace("PFAlgo|createCandidatesHCALUnlinked") << "Added to HCAL cluster to form a neutral hadron";
2889 #endif
2890 
2891  reco::PFClusterRef eclusterRef = elements[iEcal].clusterRef();
2892  assert(!eclusterRef.isNull());
2893 
2894  // KH: use raw ECAL energy for PF hadron calibration_.
2895  double ecalEnergy = eclusterRef->energy(); // ecalEnergy = eclusterRef->correctedEnergy();
2896 
2897  totalEcal += ecalEnergy;
2898  if (ecalEnergy > ecalMax) {
2899  ecalMax = ecalEnergy;
2900  eClusterRef = eclusterRef;
2901  }
2902 
2903  ecalRefs.push_back(iEcal);
2904  active[iEcal] = false;
2905 
2906  } // End loop ECAL
2907 
2908  // Now find the HO clusters linked to the HCAL cluster
2909  double totalHO = 0.;
2910  double hoMax = 0.;
2911  //unsigned jHO = 0;
2912  if (useHO_) {
2913  std::multimap<double, unsigned> hoElems;
2914  block.associatedElements(iHcal, linkData, hoElems, reco::PFBlockElement::HO, reco::PFBlock::LINKTEST_ALL);
2915 
2916  // Loop on these HO elements
2917  // double totalHO = 0.;
2918  // double hoMax = 0.;
2919  // unsigned jHO = 0;
2920  reco::PFClusterRef hoClusterRef;
2921  for (auto const& ho : hoElems) {
2922  unsigned iHO = ho.second;
2923  double dist = ho.first;
2924  PFBlockElement::Type type = elements[iHO].type();
2926 
2927  // Check if already used
2928  if (!active[iHO])
2929  continue;
2930 
2931  // Check the distance (one HCALPlusHO tower, roughly)
2932  // if ( dist > 0.15 ) continue;
2933 
2934  // Check if not closer from another free HCAL
2935  std::multimap<double, unsigned> hcalElems;
2936  block.associatedElements(iHO, linkData, hcalElems, reco::PFBlockElement::HCAL, reco::PFBlock::LINKTEST_ALL);
2937 
2938  const bool isClosest = std::none_of(hcalElems.begin(), hcalElems.end(), [&](auto const& hcal) {
2939  return active[hcal.second] && hcal.first < dist;
2940  });
2941 
2942  if (!isClosest)
2943  continue;
2944 
2945 #ifdef EDM_ML_DEBUG
2946  if (useHO_) {
2947  LogTrace("PFAlgo|createCandidatesHCALUnlinked")
2948  << "\telement " << elements[iHO] << " linked with dist " << dist;
2949  LogTrace("PFAlgo|createCandidatesHCALUnlinked") << "Added to HCAL cluster to form a neutral hadron";
2950  }
2951 #endif
2952 
2953  reco::PFClusterRef hoclusterRef = elements[iHO].clusterRef();
2954  assert(!hoclusterRef.isNull());
2955 
2956  double hoEnergy =
2957  hoclusterRef->energy(); // calibration_.energyEm(*hoclusterRef,ps1Ene,ps2Ene,crackCorrection);
2958 
2959  totalHO += hoEnergy;
2960  if (hoEnergy > hoMax) {
2961  hoMax = hoEnergy;
2962  hoClusterRef = hoclusterRef;
2963  //jHO = iHO;
2964  }
2965 
2966  hoRefs.push_back(iHO);
2967  active[iHO] = false;
2968 
2969  } // End loop HO
2970  }
2971 
2972  PFClusterRef hclusterRef = elements[iHcal].clusterRef();
2973  assert(!hclusterRef.isNull());
2974 
2975  // HCAL energy
2976  double totalHcal = hclusterRef->energy();
2977  // Include the HO energy
2978  if (useHO_)
2979  totalHcal += totalHO;
2980 
2981  // Calibration
2982  double calibEcal = totalEcal > 0. ? totalEcal : 0.;
2983  double calibHcal = std::max(0., totalHcal);
2984  if (hclusterRef->layer() == PFLayer::HF_HAD || hclusterRef->layer() == PFLayer::HF_EM) {
2985  calibEcal = totalEcal;
2986  } else {
2988  -1., calibEcal, calibHcal, hclusterRef->positionREP().Eta(), hclusterRef->positionREP().Phi());
2989  }
2990 
2991  auto& cand = (*pfCandidates_)[reconstructCluster(*hclusterRef, calibEcal + calibHcal)];
2992 
2993  cand.setEcalEnergy(totalEcal, calibEcal);
2994  if (!useHO_) {
2995  cand.setHcalEnergy(totalHcal, calibHcal);
2996  cand.setHoEnergy(0., 0.);
2997  } else {
2998  cand.setHcalEnergy(max(totalHcal - totalHO, 0.0), calibHcal * (1. - totalHO / totalHcal));
2999  cand.setHoEnergy(totalHO, totalHO * calibHcal / totalHcal);
3000  }
3001  cand.setPs1Energy(0.);
3002  cand.setPs2Energy(0.);
3003  cand.addElementInBlock(blockref, iHcal);
3004  for (auto const& ec : ecalRefs)
3005  cand.addElementInBlock(blockref, ec);
3006  for (auto const& ho : hoRefs)
3007  cand.addElementInBlock(blockref, ho);
3008 
3009  } //loop hcal elements
3010 }
3011 
3013  reco::PFBlock::LinkData& linkData,
3015  std::vector<bool>& active,
3016  const reco::PFBlockRef& blockref,
3017  ElementIndices& inds,
3018  std::vector<bool>& deadArea) {
3019  LogTrace("PFAlgo|createCandidatesECAL")
3020  << "start of function PFAlgo::createCandidatesECAL(), ecalIs.size()=" << inds.ecalIs.size();
3021 
3022  // --------------- loop ecal ------------------
3023 
3024  // for each ecal element iEcal = ecalIs[i] in turn:
3025 
3026  for (unsigned i = 0; i < inds.ecalIs.size(); i++) {
3027  unsigned iEcal = inds.ecalIs[i];
3028 
3029  LogTrace("PFAlgo|createCandidatesECAL") << "elements[" << iEcal << "]=" << elements[iEcal];
3030 
3031  if (!active[iEcal]) {
3032  LogTrace("PFAlgo|createCandidatesECAL") << "iEcal=" << iEcal << " not active";
3033  continue;
3034  }
3035 
3036  PFBlockElement::Type type = elements[iEcal].type();
3038 
3039  PFClusterRef clusterref = elements[iEcal].clusterRef();
3040  assert(!clusterref.isNull());
3041 
3042  active[iEcal] = false;
3043 
3044  float ecalEnergy = clusterref->correctedEnergy();
3045  // float ecalEnergy = calibration_.energyEm( clusterref->energy() );
3046  double particleEnergy = ecalEnergy;
3047 
3048  auto& cand = (*pfCandidates_)[reconstructCluster(*clusterref, particleEnergy)];
3049 
3050  cand.setEcalEnergy(clusterref->energy(), ecalEnergy);
3051  cand.setHcalEnergy(0., 0.);
3052  cand.setHoEnergy(0., 0.);
3053  cand.setPs1Energy(0.);
3054  cand.setPs2Energy(0.);
3055  cand.addElementInBlock(blockref, iEcal);
3056 
3057  } // end loop on ecal elements iEcal = ecalIs[i]
3058  LogTrace("PFAlgo|createCandidatesECAL") << "end of function PFALgo::createCandidatesECAL";
3059 }
3060 
3062  std::list<reco::PFBlockRef>& hcalBlockRefs,
3063  std::list<reco::PFBlockRef>& ecalBlockRefs,
3064  PFEGammaFilters const* pfegamma) {
3065  assert(!blockref.isNull());
3066  const reco::PFBlock& block = *blockref;
3067 
3068  LogTrace("PFAlgo|processBlock") << "start of function PFAlgo::processBlock, block=" << block;
3069 
3071  LogTrace("PFAlgo|processBlock") << "elements.size()=" << elements.size();
3072  // make a copy of the link data, which will be edited.
3073  PFBlock::LinkData linkData = block.linkData();
3074 
3075  // keep track of the elements which are still active.
3076  vector<bool> active(elements.size(), true);
3077 
3078  // //PFElectrons:
3079  // usePFElectrons_ external configurable parameter to set the usage of pf electron
3080  std::vector<reco::PFCandidate> tempElectronCandidates;
3081  tempElectronCandidates.clear();
3082 
3083  // New EGamma Reconstruction 10/10/2013
3084  if (useEGammaFilters_) {
3085  egammaFilters(blockref, active, pfegamma);
3086  } // end if use EGammaFilters
3087 
3088  //Lock extra conversion tracks not used by Photon Algo
3089  if (usePFConversions_) {
3090  conversionAlgo(elements, active);
3091  }
3092 
3093  // In the following elementLoop() function, the primary goal is to deal with tracks that are:
3094  // - not associated to an HCAL cluster
3095  // - not identified as an electron.
3096  // Those tracks should be predominantly relatively low energy charged
3097  // hadrons which are not detected in the ECAL.
3098 
3099  // The secondary goal is to prepare for the next loops
3100  // - The ecal and hcal elements are sorted in separate vectors in `ElementIndices inds`
3101  // which will be used as a base for the corresponding loops.
3102  // - For tracks which are connected to more than one HCAL cluster,
3103  // the links between the track and the cluster are cut for all clusters
3104  // but the closest one.
3105  // - HF only blocks ( HFEM, HFHAD, HFEM+HFAD) are identified
3106 
3107  // obsolete comments?
3108  // loop1:
3109  // - sort ecal and hcal elements in separate vectors
3110  // - for tracks:
3111  // - lock closest ecal cluster
3112  // - cut link to farthest hcal cluster, if more than 1.
3113 
3114  vector<bool> deadArea(elements.size(), false);
3115 
3116  // vectors to store element indices to ho, hcal and ecal elements, will be filled by elementLoop()
3117  ElementIndices inds;
3118 
3119  elementLoop(block, linkData, elements, active, blockref, inds, deadArea);
3120 
3121  // Reconstruct pfCandidate from HF (either EM-only, Had-only or both)
3122  // For phase2, process also pfblocks containing HF clusters and linked tracks
3123  if (!(inds.hfEmIs.empty() && inds.hfHadIs.empty())) {
3124  createCandidatesHF(block, linkData, elements, active, blockref, inds);
3125  if (inds.hcalIs.empty() && inds.ecalIs.empty())
3126  return;
3127  LogDebug("PFAlgo::processBlock")
3128  << "Block contains HF clusters, and also contains ECAL or HCAL clusters. Continue.\n"
3129  << block;
3130  }
3131 
3132  createCandidatesHCAL(block, linkData, elements, active, blockref, inds, deadArea);
3133  // COLINFEB16: now dealing with the HCAL elements that are not linked to any track
3134  createCandidatesHCALUnlinked(block, linkData, elements, active, blockref, inds, deadArea);
3135  createCandidatesECAL(block, linkData, elements, active, blockref, inds, deadArea);
3136 
3137  LogTrace("PFAlgo|processBlock") << "end of function PFAlgo::processBlock";
3138 } // end processBlock
3139 
3141 unsigned PFAlgo::reconstructTrack(const reco::PFBlockElement& elt, bool allowLoose) {
3142  const auto* eltTrack = dynamic_cast<const reco::PFBlockElementTrack*>(&elt);
3143 
3144  const reco::TrackRef& trackRef = eltTrack->trackRef();
3145  const reco::Track& track = *trackRef;
3146  const reco::MuonRef& muonRef = eltTrack->muonRef();
3147  int charge = track.charge() > 0 ? 1 : -1;
3148 
3149  // Assume this particle is a charged Hadron
3150  double px = track.px();
3151  double py = track.py();
3152  double pz = track.pz();
3153  double energy = sqrt(track.p() * track.p() + 0.13957 * 0.13957);
3154 
3155  LogTrace("PFAlgo|reconstructTrack") << "Reconstructing PF candidate from track of pT = " << track.pt()
3156  << " eta = " << track.eta() << " phi = " << track.phi() << " px = " << px
3157  << " py = " << py << " pz = " << pz << " energy = " << energy;
3158 
3159  // Create a PF Candidate
3160  ::math::XYZTLorentzVector momentum(px, py, pz, energy);
3162 
3163  // Add it to the stack
3164  LogTrace("PFAlgo|reconstructTrack") << "Creating PFCandidate charge=" << charge << ", type=" << particleType
3165  << ", pt=" << momentum.pt() << ", eta=" << momentum.eta()
3166  << ", phi=" << momentum.phi();
3167  pfCandidates_->push_back(PFCandidate(charge, momentum, particleType));
3168  //Set vertex and stuff like this
3169  pfCandidates_->back().setVertex(trackRef->vertex());
3170  pfCandidates_->back().setTrackRef(trackRef);
3171  pfCandidates_->back().setPositionAtECALEntrance(eltTrack->positionAtECALEntrance());
3172  if (muonRef.isNonnull())
3173  pfCandidates_->back().setMuonRef(muonRef);
3174 
3175  //Set time
3176  if (elt.isTimeValid())
3177  pfCandidates_->back().setTime(elt.time(), elt.timeError());
3178 
3179  //OK Now try to reconstruct the particle as a muon
3180  bool isMuon = pfmu_->reconstructMuon(pfCandidates_->back(), muonRef, allowLoose);
3181  bool isFromDisp = isFromSecInt(elt, "secondary");
3182 
3183  if ((!isMuon) && isFromDisp) {
3184  double dpt = trackRef->ptError();
3185  double dptRel = dpt / trackRef->pt() * 100;
3186  //If the track is ill measured it is better to not refit it, since the track information probably would not be used.
3187  //In the PFAlgo we use the trackref information. If the track error is too big the refitted information might be very different
3188  // from the not refitted one.
3189  if (dptRel < dptRel_DispVtx_) {
3190  LogTrace("PFAlgo|reconstructTrack")
3191  << "Not refitted px = " << px << " py = " << py << " pz = " << pz << " energy = " << energy;
3192  //reco::TrackRef trackRef = eltTrack->trackRef();
3194  eltTrack->displacedVertexRef(reco::PFBlockElement::T_FROM_DISP)->displacedVertexRef();
3195  reco::Track trackRefit = vRef->refittedTrack(trackRef);
3196  //change the momentum with the refitted track
3197  ::math::XYZTLorentzVector momentum(
3198  trackRefit.px(), trackRefit.py(), trackRefit.pz(), sqrt(trackRefit.p() * trackRefit.p() + 0.13957 * 0.13957));
3199  LogTrace("PFAlgo|reconstructTrack")
3200  << "Refitted px = " << px << " py = " << py << " pz = " << pz << " energy = " << energy;
3201  }
3202  pfCandidates_->back().setFlag(reco::PFCandidate::T_FROM_DISP, true);
3203  pfCandidates_->back().setDisplacedVertexRef(
3204  eltTrack->displacedVertexRef(reco::PFBlockElement::T_FROM_DISP)->displacedVertexRef(),
3206  }
3207 
3208  // do not label as primary a track which would be recognised as a muon. A muon cannot produce NI. It is with high probability a fake
3209  if (isFromSecInt(elt, "primary") && !isMuon) {
3210  pfCandidates_->back().setFlag(reco::PFCandidate::T_TO_DISP, true);
3211  pfCandidates_->back().setDisplacedVertexRef(
3212  eltTrack->displacedVertexRef(reco::PFBlockElement::T_TO_DISP)->displacedVertexRef(),
3214  }
3215 
3216  // returns index to the newly created PFCandidate
3217  return pfCandidates_->size() - 1;
3218 }
3219 
3221  double particleEnergy,
3222  bool useDirection,
3223  double particleX,
3224  double particleY,
3225  double particleZ) {
3226  LogTrace("PFAlgo|reconstructCluster") << "start of function PFAlgo::reconstructCluster, cluster=" << cluster
3227  << "particleEnergy=" << particleEnergy << "useDirection=" << useDirection
3228  << "particleX=" << particleX << "particleY=" << particleY
3229  << "particleZ=" << particleZ;
3230 
3232 
3233  // need to convert the ::math::XYZPoint data member of the PFCluster class=
3234  // to a displacement vector:
3235 
3236  // Transform particleX,Y,Z to a position at ECAL/HCAL entrance
3237  double factor = 1.;
3238  if (useDirection) {
3239  switch (cluster.layer()) {
3240  case PFLayer::ECAL_BARREL:
3241  case PFLayer::HCAL_BARREL1:
3242  factor = std::sqrt(cluster.position().Perp2() / (particleX * particleX + particleY * particleY));
3243  break;
3244  case PFLayer::ECAL_ENDCAP:
3245  case PFLayer::HCAL_ENDCAP:
3246  case PFLayer::HF_HAD:
3247  case PFLayer::HF_EM:
3248  factor = cluster.position().Z() / particleZ;
3249  break;
3250  default:
3251  assert(0);
3252  }
3253  }
3254  //MIKE First of all let's check if we have vertex.
3255  ::math::XYZPoint vertexPos;
3256  if (useVertices_)
3258  else
3259  vertexPos = ::math::XYZPoint(0.0, 0.0, 0.0);
3260 
3261  ::math::XYZVector clusterPos(cluster.position().X() - vertexPos.X(),
3262  cluster.position().Y() - vertexPos.Y(),
3263  cluster.position().Z() - vertexPos.Z());
3264  ::math::XYZVector particleDirection(
3265  particleX * factor - vertexPos.X(), particleY * factor - vertexPos.Y(), particleZ * factor - vertexPos.Z());
3266 
3267  //::math::XYZVector clusterPos( cluster.position().X(), cluster.position().Y(),cluster.position().Z() );
3268  //::math::XYZVector particleDirection ( particleX, particleY, particleZ );
3269 
3270  clusterPos = useDirection ? particleDirection.Unit() : clusterPos.Unit();
3271  clusterPos *= particleEnergy;
3272 
3273  // clusterPos is now a vector along the cluster direction,
3274  // with a magnitude equal to the cluster energy.
3275 
3276  double mass = 0;
3277  ROOT::Math::LorentzVector<ROOT::Math::PxPyPzM4D<double>> momentum(
3278  clusterPos.X(), clusterPos.Y(), clusterPos.Z(), mass);
3279  // mathcore is a piece of #$%
3281  // implicit constructor not allowed
3282  tmp = momentum;
3283 
3284  // Charge
3285  int charge = 0;
3286 
3287  // Type
3288  switch (cluster.layer()) {
3289  case PFLayer::ECAL_BARREL:
3290  case PFLayer::ECAL_ENDCAP:
3292  break;
3293  case PFLayer::HCAL_BARREL1:
3294  case PFLayer::HCAL_ENDCAP:
3295  particleType = PFCandidate::h0;
3296  break;
3297  case PFLayer::HF_HAD:
3298  particleType = PFCandidate::h_HF;
3299  break;
3300  case PFLayer::HF_EM:
3301  particleType = PFCandidate::egamma_HF;
3302  break;
3303  default:
3304  assert(0);
3305  }
3306 
3307  // The pf candidate
3308  LogTrace("PFAlgo|reconstructCluster") << "Creating PFCandidate charge=" << charge << ", type=" << particleType
3309  << ", pt=" << tmp.pt() << ", eta=" << tmp.eta() << ", phi=" << tmp.phi();
3311 
3312  // The position at ECAL entrance (well: watch out, it is not true
3313  // for HCAL clusters... to be fixed)
3314  pfCandidates_->back().setPositionAtECALEntrance(
3315  ::math::XYZPointF(cluster.position().X(), cluster.position().Y(), cluster.position().Z()));
3316 
3317  //Set the cnadidate Vertex
3318  pfCandidates_->back().setVertex(vertexPos);
3319 
3320  // depth info
3321  setHcalDepthInfo(pfCandidates_->back(), cluster);
3322 
3323  //*TODO* cluster time is not reliable at the moment, so only use track timing
3324 
3325  LogTrace("PFAlgo|reconstructCluster") << "** candidate: " << pfCandidates_->back();
3326 
3327  // returns index to the newly created PFCandidate
3328  return pfCandidates_->size() - 1;
3329 }
3330 
3332  std::array<double, 7> energyPerDepth;
3333  std::fill(energyPerDepth.begin(), energyPerDepth.end(), 0.0);
3334  for (auto& hitRefAndFrac : cluster.recHitFractions()) {
3335  const auto& hit = *hitRefAndFrac.recHitRef();
3336  if (DetId(hit.detId()).det() == DetId::Hcal) {
3337  if (hit.depth() == 0) {
3338  edm::LogWarning("setHcalDepthInfo") << "Depth zero found";
3339  continue;
3340  }
3341  if (hit.depth() < 1 || hit.depth() > 7) {
3342  throw cms::Exception("CorruptData") << "Bogus depth " << hit.depth() << " at detid " << hit.detId() << "\n";
3343  }
3344  energyPerDepth[hit.depth() - 1] += hitRefAndFrac.fraction() * hit.energy();
3345  }
3346  }
3347  double sum = std::accumulate(energyPerDepth.begin(), energyPerDepth.end(), 0.);
3348  std::array<float, 7> depthFractions;
3349  if (sum > 0) {
3350  for (unsigned int i = 0; i < depthFractions.size(); ++i) {
3351  depthFractions[i] = energyPerDepth[i] / sum;
3352  }
3353  } else {
3354  std::fill(depthFractions.begin(), depthFractions.end(), 0.f);
3355  }
3356  cand.setHcalDepthEnergyFractions(depthFractions);
3357 }
3358 
3359 //GMA need the followign two for HO also
3360 
3361 double PFAlgo::neutralHadronEnergyResolution(double clusterEnergyHCAL, double eta) const {
3362  // Add a protection
3363  clusterEnergyHCAL = std::max(clusterEnergyHCAL, 1.);
3364 
3365  double resol = fabs(eta) < 1.48 ? sqrt(1.02 * 1.02 / clusterEnergyHCAL + 0.065 * 0.065)
3366  : sqrt(1.20 * 1.20 / clusterEnergyHCAL + 0.028 * 0.028);
3367 
3368  return resol;
3369 }
3370 
3371 double PFAlgo::nSigmaHCAL(double clusterEnergyHCAL, double eta) const {
3372  double nS = fabs(eta) < 1.48 ? nSigmaHCAL_ * (1. + exp(-clusterEnergyHCAL / nSigmaEConstHCAL))
3373  : nSigmaHCAL_ * (1. + exp(-clusterEnergyHCAL / nSigmaEConstHCAL));
3374 
3375  return nS;
3376 }
3377 
3378 double PFAlgo::hfEnergyResolution(double clusterEnergyHF) const {
3379  // Add a protection
3380  clusterEnergyHF = std::max(clusterEnergyHF, 1.);
3381 
3382  double resol =
3383  sqrt(resolHF_square_[0] / clusterEnergyHF + resolHF_square_[1] + resolHF_square_[2] / pow(clusterEnergyHF, 2));
3384  // 0: stochastic term, 1: constant term, 2: noise term
3385  // Note: resolHF_square_[0,1,2] should be already squared
3386 
3387  return resol;
3388 }
3389 
3390 double PFAlgo::nSigmaHFEM(double clusterEnergyHF) const {
3391  double nS = nSigmaHFEM_ * (1. + exp(-clusterEnergyHF / nSigmaEConstHFEM));
3392  return nS;
3393 }
3394 
3395 double PFAlgo::nSigmaHFHAD(double clusterEnergyHF) const {
3396  double nS = nSigmaHFHAD_ * (1. + exp(-clusterEnergyHF / nSigmaEConstHFHAD));
3397  return nS;
3398 }
3399 
3400 ostream& operator<<(ostream& out, const PFAlgo& algo) {
3401  if (!out)
3402  return out;
3403 
3404  out << "====== Particle Flow Algorithm ======= ";
3405  out << endl;
3406  out << "nSigmaECAL_ " << algo.nSigmaECAL_ << endl;
3407  out << "nSigmaHCAL_ " << algo.nSigmaHCAL_ << endl;
3408  out << "nSigmaHFEM_ " << algo.nSigmaHFEM_ << endl;
3409  out << "nSigmaHFHAD_ " << algo.nSigmaHFHAD_ << endl;
3410  out << endl;
3411  out << algo.calibration_ << endl;
3412  out << endl;
3413  out << "reconstructed particles: " << endl;
3414 
3415  if (!algo.pfCandidates_.get()) {
3416  out << "candidates already transfered" << endl;
3417  return out;
3418  }
3419  for (auto const& c : *algo.pfCandidates_)
3420  out << c << endl;
3421 
3422  return out;
3423 }
3424 
3425 void PFAlgo::associatePSClusters(unsigned iEcal,
3426  reco::PFBlockElement::Type psElementType,
3427  const reco::PFBlock& block,
3429  const reco::PFBlock::LinkData& linkData,
3430  std::vector<bool>& active,
3431  std::vector<double>& psEne) {
3432  // Find all PS clusters with type psElement associated to ECAL cluster iEcal,
3433  // within all PFBlockElement "elements" of a given PFBlock "block"
3434  // psElement can be reco::PFBlockElement::PS1 or reco::PFBlockElement::PS2
3435  // Returns a vector of PS cluster energies, and updates the "active" vector.
3436 
3437  // Find all PS clusters linked to the iEcal cluster
3438  std::multimap<double, unsigned> sortedPS;
3439  block.associatedElements(iEcal, linkData, sortedPS, psElementType, reco::PFBlock::LINKTEST_ALL);
3440 
3441  // Loop over these PS clusters
3442  for (auto const& ps : sortedPS) {
3443  // CLuster index and distance to iEcal
3444  unsigned iPS = ps.second;
3445  // double distPS = ps.first;
3446 
3447  // Ignore clusters already in use
3448  if (!active[iPS])
3449  continue;
3450 
3451  // Check that this cluster is not closer to another ECAL cluster
3452  std::multimap<double, unsigned> sortedECAL;
3453  block.associatedElements(iPS, linkData, sortedECAL, reco::PFBlockElement::ECAL, reco::PFBlock::LINKTEST_ALL);
3454  unsigned jEcal = sortedECAL.begin()->second;
3455  if (jEcal != iEcal)
3456  continue;
3457 
3458  // Update PS energy
3459  PFBlockElement::Type pstype = elements[iPS].type();
3460  assert(pstype == psElementType);
3461  PFClusterRef psclusterref = elements[iPS].clusterRef();
3462  assert(!psclusterref.isNull());
3463  psEne[0] += psclusterref->energy();
3464  active[iPS] = false;
3465  }
3466 }
3467 
3468 bool PFAlgo::isFromSecInt(const reco::PFBlockElement& eTrack, string order) const {
3471  // reco::PFBlockElement::TrackType T_FROM_GAMMACONV = reco::PFBlockElement::T_FROM_GAMMACONV;
3473 
3474  bool bPrimary = (order.find("primary") != string::npos);
3475  bool bSecondary = (order.find("secondary") != string::npos);
3476  bool bAll = (order.find("all") != string::npos);
3477 
3478  bool isToDisp = usePFNuclearInteractions_ && eTrack.trackType(T_TO_DISP);
3479  bool isFromDisp = usePFNuclearInteractions_ && eTrack.trackType(T_FROM_DISP);
3480 
3481  if (bPrimary && isToDisp)
3482  return true;
3483  if (bSecondary && isFromDisp)
3484  return true;
3485  if (bAll && (isToDisp || isFromDisp))
3486  return true;
3487 
3488  // bool isFromConv = usePFConversions_ && eTrack.trackType(T_FROM_GAMMACONV);
3489 
3490  // if ((bAll || bSecondary)&& isFromConv) return true;
3491 
3492  bool isFromDecay = (bAll || bSecondary) && usePFDecays_ && eTrack.trackType(T_FROM_V0);
3493 
3494  return isFromDecay;
3495 }
3496 
3498  //Compute met and met significance (met/sqrt(SumEt))
3499  double metX = 0.;
3500  double metY = 0.;
3501  double sumet = 0;
3502  std::vector<unsigned int> pfCandidatesToBeRemoved;
3503  for (auto const& pfc : *pfCandidates_) {
3504  metX += pfc.px();
3505  metY += pfc.py();
3506  sumet += pfc.pt();
3507  }
3508  double met2 = metX * metX + metY * metY;
3509  // Select events with large MET significance.
3510  double significance = std::sqrt(met2 / sumet);
3511  double significanceCor = significance;
3513  double metXCor = metX;
3514  double metYCor = metY;
3515  double sumetCor = sumet;
3516  double met2Cor = met2;
3517  double deltaPhi = 3.14159;
3518  double deltaPhiPt = 100.;
3519  bool next = true;
3520  unsigned iCor = 1E9;
3521 
3522  // Find the HF candidate with the largest effect on the MET
3523  while (next) {
3524  double metReduc = -1.;
3525  // Loop on the candidates
3526  for (unsigned i = 0; i < pfCandidates_->size(); ++i) {
3527  const PFCandidate& pfc = (*pfCandidates_)[i];
3528 
3529  // Check that the pfCandidate is in the HF
3531  continue;
3532 
3533  // Check if has meaningful pt
3534  if (pfc.pt() < minHFCleaningPt_)
3535  continue;
3536 
3537  // Check that it is not already scheculed to be cleaned
3538  const bool skip = std::any_of(
3539  pfCandidatesToBeRemoved.begin(), pfCandidatesToBeRemoved.end(), [&](unsigned int j) { return i == j; });
3540  if (skip)
3541  continue;
3542 
3543  // Check that the pt and the MET are aligned
3544  deltaPhi = std::acos((metX * pfc.px() + metY * pfc.py()) / (pfc.pt() * std::sqrt(met2)));
3545  deltaPhiPt = deltaPhi * pfc.pt();
3546  if (deltaPhiPt > maxDeltaPhiPt_)
3547  continue;
3548 
3549  // Now remove the candidate from the MET
3550  double metXInt = metX - pfc.px();
3551  double metYInt = metY - pfc.py();
3552  double sumetInt = sumet - pfc.pt();
3553  double met2Int = metXInt * metXInt + metYInt * metYInt;
3554  if (met2Int < met2Cor) {
3555  metXCor = metXInt;
3556  metYCor = metYInt;
3557  metReduc = (met2 - met2Int) / met2Int;
3558  met2Cor = met2Int;
3559  sumetCor = sumetInt;
3560  significanceCor = std::sqrt(met2Cor / sumetCor);
3561  iCor = i;
3562  }
3563  }
3564  //
3565  // If the MET must be significanly reduced, schedule the candidate to be cleaned
3566  if (metReduc > minDeltaMet_) {
3567  pfCandidatesToBeRemoved.push_back(iCor);
3568  metX = metXCor;
3569  metY = metYCor;
3570  sumet = sumetCor;
3571  met2 = met2Cor;
3572  } else {
3573  // Otherwise just stop the loop
3574  next = false;
3575  }
3576  }
3577  //
3578  // The significance must be significantly reduced to indeed clean the candidates
3579  if (significance - significanceCor > minSignificanceReduction_ && significanceCor < maxSignificance_) {
3580  edm::LogInfo("PFAlgo|postCleaning") << "Significance reduction = " << significance << " -> " << significanceCor
3581  << " = " << significanceCor - significance;
3582  for (unsigned int toRemove : pfCandidatesToBeRemoved) {
3583  edm::LogInfo("PFAlgo|postCleaning") << "Removed : " << (*pfCandidates_)[toRemove];
3584  pfCleanedCandidates_.push_back((*pfCandidates_)[toRemove]);
3585  (*pfCandidates_)[toRemove].rescaleMomentum(1E-6);
3586  //reco::PFCandidate::ParticleType unknown = reco::PFCandidate::X;
3587  //(*pfCandidates_)[toRemove].setParticleType(unknown);
3588  }
3589  }
3590  } //significance
3591 } //postCleaning
3592 
3594  // No hits to recover, leave.
3595  if (cleanedHits.empty())
3596  return;
3597 
3598  //Compute met and met significance (met/sqrt(SumEt))
3599  double metX = 0.;
3600  double metY = 0.;
3601  double sumet = 0;
3602  std::vector<unsigned int> hitsToBeAdded;
3603  for (auto const& pfc : *pfCandidates_) {
3604  metX += pfc.px();
3605  metY += pfc.py();
3606  sumet += pfc.pt();
3607  }
3608  double met2 = metX * metX + metY * metY;
3609  double met2_Original = met2;
3610  // Select events with large MET significance.
3611  // double significance = std::sqrt(met2/sumet);
3612  // double significanceCor = significance;
3613  double metXCor = metX;
3614  double metYCor = metY;
3615  double sumetCor = sumet;
3616  double met2Cor = met2;
3617  bool next = true;
3618  unsigned iCor = 1E9;
3619 
3620  // Find the cleaned hit with the largest effect on the MET
3621  while (next) {
3622  double metReduc = -1.;
3623  // Loop on the candidates
3624  for (unsigned i = 0; i < cleanedHits.size(); ++i) {
3625  const PFRecHit& hit = cleanedHits[i];
3626  double length = std::sqrt(hit.position().mag2());
3627  double px = hit.energy() * hit.position().x() / length;
3628  double py = hit.energy() * hit.position().y() / length;
3629  double pt = std::sqrt(px * px + py * py);
3630 
3631  // Check that it is not already scheculed to be cleaned
3632  bool skip = false;
3633  for (unsigned int hitIdx : hitsToBeAdded) {
3634  if (i == hitIdx)
3635  skip = true;
3636  if (skip)
3637  break;
3638  }
3639  if (skip)
3640  continue;
3641 
3642  // Now add the candidate to the MET
3643  double metXInt = metX + px;
3644  double metYInt = metY + py;
3645  double sumetInt = sumet + pt;
3646  double met2Int = metXInt * metXInt + metYInt * metYInt;
3647 
3648  // And check if it could contribute to a MET reduction
3649  if (met2Int < met2Cor) {
3650  metXCor = metXInt;
3651  metYCor = metYInt;
3652  metReduc = (met2 - met2Int) / met2Int;
3653  met2Cor = met2Int;
3654  sumetCor = sumetInt;
3655  // significanceCor = std::sqrt(met2Cor/sumetCor);
3656  iCor = i;
3657  }
3658  }
3659  //
3660  // If the MET must be significanly reduced, schedule the candidate to be added
3661  //
3662  if (metReduc > minDeltaMet_) {
3663  hitsToBeAdded.push_back(iCor);
3664  metX = metXCor;
3665  metY = metYCor;
3666  sumet = sumetCor;
3667  met2 = met2Cor;
3668  } else {
3669  // Otherwise just stop the loop
3670  next = false;
3671  }
3672  }
3673  //
3674  // At least 10 GeV MET reduction
3675  if (std::sqrt(met2_Original) - std::sqrt(met2) > 5.) {
3676  LogTrace("PFAlgo|checkCleaning") << hitsToBeAdded.size() << " hits were re-added ";
3677  LogTrace("PFAlgo|checkCleaning") << "MET reduction = " << std::sqrt(met2_Original) << " -> " << std::sqrt(met2Cor)
3678  << " = " << std::sqrt(met2Cor) - std::sqrt(met2_Original);
3679  LogTrace("PFAlgo|checkCleaning") << "Added after cleaning check : ";
3680  for (unsigned int hitIdx : hitsToBeAdded) {
3681  const PFRecHit& hit = cleanedHits[hitIdx];
3682  PFCluster cluster(hit.layer(), hit.energy(), hit.position().x(), hit.position().y(), hit.position().z());
3683  reconstructCluster(cluster, hit.energy());
3684  LogTrace("PFAlgo|checkCleaning") << pfCandidates_->back() << ". time = " << hit.time();
3685  }
3686  }
3687 } //PFAlgo::checkCleaning
const math::XYZPoint & position() const
cluster centroid position
Definition: CaloCluster.h:154
void set_dnn_e_sigIsolated(float mva)
Definition: PFCandidate.h:349
bool checkHasDeadHcal(const std::multimap< double, unsigned > &hcalElems, const std::vector< bool > &deadArea)
Definition: PFAlgo.cc:875
edm::Ref< PFBlockCollection > PFBlockRef
persistent reference to PFCluster objects
Definition: PFBlockFwd.h:19
Abstract base class for a PFBlock element (track, cluster...)
static bool isIsolatedMuon(const reco::PFBlockElement &elt)
Definition: PFMuonAlgo.cc:94
double ptError_
Definition: PFAlgo.h:297
bool usePFConversions_
Definition: PFAlgo.h:280
float goodTrackDeadHcal_dxy_
Definition: PFAlgo.h:305
std::vector< double > muonHCAL_
Variables for muons and fakes.
Definition: PFAlgo.h:293
T getParameter(std::string const &) const
Definition: ParameterSet.h:303
ParticleType
particle types
Definition: PFCandidate.h:44
double maxDeltaPhiPt_
Definition: PFAlgo.h:323
RefToBase< value_type > refAt(size_type i) const
double maxSignificance_
Definition: PFAlgo.h:321
double pt() const final
transverse momentum
std::vector< unsigned > hoIs
Definition: PFAlgo.h:43
bool checkGoodTrackDeadHcal(const reco::TrackRef &trackRef, bool hasDeadHcal)
Definition: PFAlgo.cc:902
const double nSigmaHFEM_
number of sigma to judge energy excess in HF
Definition: PFAlgo.h:251
double z() const
z coordinate
Definition: Vertex.h:133
void set_mva_nothing_gamma(float mva)
set mva for gamma detection
Definition: PFCandidate.h:332
double minHFCleaningPt_
Definition: PFAlgo.h:319
bool isMuon(const Candidate &part)
Definition: pdgIdUtils.h:9
Particle flow cluster, see clustering algorithm in PFClusterAlgo.
Definition: PFCluster.h:42
bool isPrimary(const SimTrack &simTrk, const PSimHit *simHit)
static bool isMuon(const reco::PFBlockElement &elt)
Definition: PFMuonAlgo.cc:48
double minDeltaMet_
Definition: PFAlgo.h:324
const double nSigmaHCAL_
number of sigma to judge energy excess in HCAL
Definition: PFAlgo.h:248
double minSignificance_
Definition: PFAlgo.h:320
double errorScale(const reco::TrackBase::TrackAlgorithm &, const std::vector< double > &)
std::unique_ptr< reco::PFCandidateCollection > pfCandidates_
Definition: PFAlgo.h:226
unsigned reconstructCluster(const reco::PFCluster &cluster, double particleEnergy, bool useDirection=false, double particleX=0., double particleY=0., double particleZ=0.)
Definition: PFAlgo.cc:3220
ret
prodAgent to be discontinued
const Point & position() const
position
Definition: Vertex.h:127
void elementLoop(const reco::PFBlock &block, reco::PFBlock::LinkData &linkData, const edm::OwnVector< reco::PFBlockElement > &elements, std::vector< bool > &active, const reco::PFBlockRef &blockref, ElementIndices &inds, std::vector< bool > &deadArea)
Definition: PFAlgo.cc:997
double px() const
x coordinate of momentum vector
Definition: TrackBase.h:641
bool useProtectionsForJetMET_
Definition: PFAlgo.h:266
const std::vector< double > resolHF_square_
Definition: PFAlgo.h:255
float timeError() const
double p() const
momentum vector magnitude
Definition: TrackBase.h:632
float goodPixelTrackDeadHcal_minEta_
Definition: PFAlgo.h:307
void set_dnn_gamma(float mva)
Definition: PFCandidate.h:369
void set_dnn_e_bkgNonIsolated(float mva)
Definition: PFCandidate.h:357
#define X(str)
Definition: MuonsGrabber.cc:38
double py() const
y coordinate of momentum vector
Definition: TrackBase.h:644
bool isNonnull() const
Checks for non-null.
Definition: Ref.h:238
const std::vector< reco::PFRecHitFraction > & recHitFractions() const
vector of rechit fractions
Definition: PFCluster.h:65
std::vector< Vertex > VertexCollection
collection of Vertex objects
Definition: VertexFwd.h:9
std::map< unsigned int, Link > LinkData
Definition: PFBlock.h:39
std::vector< PFRecHit > PFRecHitCollection
collection of PFRecHit objects
Definition: PFRecHitFwd.h:9
const edm::ValueMap< reco::PhotonRef > * valueMapGedPhotons_
Definition: PFAlgo.h:269
void checkCleaning(const reco::PFRecHitCollection &cleanedHF)
Check HF Cleaning.
Definition: PFAlgo.cc:3593
const double nSigmaEConstHCAL
Definition: PFAlgo.h:334
reco::PFCandidateCollection pfCleanedCandidates_
Definition: PFAlgo.h:228
ROOT::Math::PositionVector3D< ROOT::Math::Cartesian3D< float > > XYZPointF
point in space with cartesian internal representation
Definition: Point3D.h:10
void setDisplacedVerticesParameters(bool rejectTracks_Bad, bool rejectTracks_Step45, bool usePFNuclearInteractions, bool usePFConversions, bool usePFDecays, double dptRel_DispVtx)
Definition: PFAlgo.cc:96
void egammaFilters(const reco::PFBlockRef &blockref, std::vector< bool > &active, PFEGammaFilters const *pfegamma)
Definition: PFAlgo.cc:220
PFLayer::Layer layer() const
cluster layer, see PFLayer.h in this directory
Definition: PFCluster.cc:56
Log< level::Error, false > LogError
bool isFromSecInt(const reco::PFBlockElement &eTrack, std::string order) const
Definition: PFAlgo.cc:3468
assert(be >=bs)
float goodPixelTrackDeadHcal_dxy_
Definition: PFAlgo.h:313
double energyEmHad(double uncalibratedEnergyECAL, double uncalibratedEnergyHCAL, double eta, double phi)
bool isElectron(const reco::GsfElectron &) const
int nVtx_
Definition: PFAlgo.h:286
bool rejectTracks_Step45_
Definition: PFAlgo.h:277
double minSignificanceReduction_
Definition: PFAlgo.h:322
#define LogTrace(id)
std::vector< double > factors45_
Definition: PFAlgo.h:298
void setVertex(const Point &vertex) override
set vertex
double hfEnergyResolution(double clusterEnergy) const
Definition: PFAlgo.cc:3378
bool useHO_
Definition: PFAlgo.h:260
void setPFVertexParameters(bool useVertex, reco::VertexCollection const &primaryVertices)
Definition: PFAlgo.cc:110
size_type size() const
std::vector< ElementInBlock > ElementsInBlocks
Definition: PFCandidate.h:404
U second(std::pair< T, U > const &p)
reco::PFCandidateEGammaExtraRef egammaExtraRef() const
return a reference to the EGamma extra
Definition: PFCandidate.cc:581
std::vector< unsigned > hfHadIs
Definition: PFAlgo.h:50
void setCharge(Charge q) final
set electric charge
XYZTLorentzVectorD XYZTLorentzVector
Lorentz vector with cylindrical internal representation using pseudorapidity.
Definition: LorentzVector.h:29
void setPostHFCleaningParameters(bool postHFCleaning, const edm::ParameterSet &pfHFCleaningParams)
Definition: PFAlgo.cc:86
const bool & getcalibHF_use() const
string quality
void set_mva_e_pi(float mvaNI)
Definition: PFCandidate.h:315
std::vector< unsigned > hcalIs
Definition: PFAlgo.h:42
bool usePFNuclearInteractions_
Definition: PFAlgo.h:279
const double nSigmaEConstHFEM
Definition: PFAlgo.h:335
double px() const final
x coordinate of momentum vector
const ElementsInBlocks & elementsInBlocks() const
Definition: PFCandidate.cc:663
bool postHFCleaning_
Definition: PFAlgo.h:317
void setEGammaCollections(const edm::View< reco::PFCandidate > &pfEgammaCandidates, const edm::ValueMap< reco::GsfElectronRef > &valueMapGedElectrons, const edm::ValueMap< reco::PhotonRef > &valueMapGedPhotons)
Definition: PFAlgo.cc:76
Particle flow rechit (rechit + geometry and topology information). See clustering algorithm in PFClus...
Definition: PFRecHit.h:31
void set_mva_Isolated(float mvaI)
Definition: PFCandidate.h:311
const edm::View< reco::PFCandidate > * pfEgammaCandidates_
Definition: PFAlgo.h:267
void createCandidatesECAL(const reco::PFBlock &block, reco::PFBlock::LinkData &linkData, const edm::OwnVector< reco::PFBlockElement > &elements, std::vector< bool > &active, const reco::PFBlockRef &blockref, ElementIndices &inds, std::vector< bool > &deadArea)
Definition: PFAlgo.cc:3012
double energyEm(double uncalibratedEnergyECAL, double eta, double phi)
void associatePSClusters(unsigned iEcal, reco::PFBlockElement::Type psElementType, const reco::PFBlock &block, const edm::OwnVector< reco::PFBlockElement > &elements, const reco::PFBlock::LinkData &linkData, std::vector< bool > &active, std::vector< double > &psEne)
Associate PS clusters to a given ECAL cluster, and return their energy.
Definition: PFAlgo.cc:3425
void setParticleType(ParticleType type)
set Particle Type
Definition: PFCandidate.cc:278
T sqrt(T t)
Definition: SSEVec.h:19
bool recoTracksNotHCAL(const reco::PFBlock &block, reco::PFBlock::LinkData &linkData, const edm::OwnVector< reco::PFBlockElement > &elements, const reco::PFBlockRef &blockref, std::vector< bool > &active, bool goodTrackDeadHcal, bool hasDeadHcal, unsigned int iTrack, std::multimap< double, unsigned > &ecalElems, reco::TrackRef &trackRef)
Definition: PFAlgo.cc:399
double nSigmaHFEM(double clusterEnergy) const
Definition: PFAlgo.cc:3390
bool step45(const reco::TrackBase::TrackAlgorithm &)
float goodTrackDeadHcal_validFr_
Definition: PFAlgo.h:304
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
reco::Vertex primaryVertex_
Definition: PFAlgo.h:328
edm::Handle< reco::MuonCollection > muonHandle_
Definition: PFAlgo.h:331
bool passElectronSelection(const reco::GsfElectron &, const reco::PFCandidate &, const int &) const
std::vector< double > muonECAL_
Definition: PFAlgo.h:294
void setPositionAtECALEntrance(float x, float y, float z)
set position at ECAL entrance
PFEnergyCalibration & calibration_
Definition: PFAlgo.h:257
bool isTimeValid() const
do we have a valid time information
const double nSigmaEConstHFHAD
Definition: PFAlgo.h:336
double x() const
x coordinate
Definition: Vertex.h:129
void energyEmHad(double t, double &e, double &h, double eta, double phi) const
double py() const final
y coordinate of momentum vector
bool isNull() const
Checks for null.
Definition: Ref.h:235
void processBlock(const reco::PFBlockRef &blockref, std::list< reco::PFBlockRef > &hcalBlockRefs, std::list< reco::PFBlockRef > &ecalBlockRefs, PFEGammaFilters const *pfegamma)
Definition: PFAlgo.cc:3061
int goodPixelTrackDeadHcal_maxLost3Hit_
Definition: PFAlgo.h:311
double y() const
y coordinate
Definition: Vertex.h:131
void createCandidatesHCAL(const reco::PFBlock &block, reco::PFBlock::LinkData &linkData, const edm::OwnVector< reco::PFBlockElement > &elements, std::vector< bool > &active, const reco::PFBlockRef &blockref, ElementIndices &inds, std::vector< bool > &deadArea)
Definition: PFAlgo.cc:1702
void set_dnn_e_sigNonIsolated(float mva)
Definition: PFCandidate.h:353
ii
Definition: cuy.py:589
virtual bool trackType(TrackType trType) const
void set_dnn_e_bkgPhoton(float mva)
Definition: PFCandidate.h:365
PFAlgo(double nSigmaECAL, double nSigmaHCAL, double nSigmaHFEM, double nSigmaHFHAD, std::vector< double > resolHF_square, PFEnergyCalibration &calibration, PFEnergyCalibrationHF &thepfEnergyCalibrationHF, const edm::ParameterSet &pset)
constructor
Definition: PFAlgo.cc:15
void reconstructParticles(const reco::PFBlockHandle &blockHandle, PFEGammaFilters const *pfegamma)
reconstruct particles
Definition: PFAlgo.cc:130
Log< level::Info, false > LogInfo
Definition: DetId.h:17
float goodPixelTrackDeadHcal_maxPt_
Definition: PFAlgo.h:308
std::vector< reco::PFCandidate > PFCandidateCollection
collection of PFCandidates
double nSigmaHFHAD(double clusterEnergy) const
Definition: PFAlgo.cc:3395
int decideType(const edm::OwnVector< reco::PFBlockElement > &elements, const reco::PFBlockElement::Type type, std::vector< bool > &active, ElementIndices &inds, std::vector< bool > &deadArea, unsigned int iEle)
Definition: PFAlgo.cc:1201
bool isElectronSafeForJetMET(const reco::GsfElectron &, const reco::PFCandidate &, const reco::Vertex &, bool &lockTracks) const
unsigned reconstructTrack(const reco::PFBlockElement &elt, bool allowLoose=false)
Definition: PFAlgo.cc:3141
int goodTrackDeadHcal_layers_
Definition: PFAlgo.h:303
bool passPhotonSelection(const reco::Photon &) const
std::vector< unsigned > hfEmIs
Definition: PFAlgo.h:49
std::vector< double > muonHO_
Definition: PFAlgo.h:295
bool useVertices_
Definition: PFAlgo.h:329
double energyHad(double uncalibratedEnergyHCAL, double eta, double phi)
bool isPhotonSafeForJetMET(const reco::Photon &, const reco::PFCandidate &) const
float goodPixelTrackDeadHcal_ptErrRel_
Definition: PFAlgo.h:309
XYZVectorD XYZVector
spatial vector with cartesian internal representation
Definition: Vector3D.h:31
double dptRel_DispVtx_
Definition: PFAlgo.h:285
static bool isLooseMuon(const reco::PFBlockElement &elt)
Definition: PFMuonAlgo.cc:57
XYZPointD XYZPoint
point in space with cartesian internal representation
Definition: Point3D.h:12
std::vector< unsigned > ecalIs
Definition: PFAlgo.h:44
double pz() const
z coordinate of momentum vector
Definition: TrackBase.h:647
double neutralHadronEnergyResolution(double clusterEnergy, double clusterEta) const
todo: use PFClusterTools for this
Definition: PFAlgo.cc:3361
double b
Definition: hdecay.h:118
void set_dnn_e_bkgTau(float mva)
Definition: PFCandidate.h:361
void relinkTrackToHcal(const reco::PFBlock &block, std::multimap< double, unsigned > &ecalElems, std::multimap< double, unsigned > &hcalElems, const std::vector< bool > &active, reco::PFBlock::LinkData &linkData, unsigned int iTrack)
Definition: PFAlgo.cc:941
bool isValid() const
Definition: HandleBase.h:70
significance
Definition: met_cff.py:15
const double nSigmaECAL_
number of sigma to judge energy excess in ECAL
Definition: PFAlgo.h:245
math::XYZVector XYZPoint
PFEnergyCalibrationHF & thepfEnergyCalibrationHF_
Definition: PFAlgo.h:258
void setHcalDepthInfo(reco::PFCandidate &cand, const reco::PFCluster &cluster) const
Definition: PFAlgo.cc:3331
Particle reconstructed by the particle flow algorithm.
Definition: PFCandidate.h:41
fixed size matrix
double a
Definition: hdecay.h:119
double nSigmaHCAL(double clusterEnergy, double clusterEta) const
Definition: PFAlgo.cc:3371
void conversionAlgo(const edm::OwnVector< reco::PFBlockElement > &elements, std::vector< bool > &active)
Definition: PFAlgo.cc:370
void createCandidatesHF(const reco::PFBlock &block, reco::PFBlock::LinkData &linkData, const edm::OwnVector< reco::PFBlockElement > &elements, std::vector< bool > &active, const reco::PFBlockRef &blockref, ElementIndices &inds)
Definition: PFAlgo.cc:1259
bool rejectTracks_Bad_
Definition: PFAlgo.h:276
PFMuonAlgo * getPFMuonAlgo()
Definition: PFAlgo.cc:66
bool useEGammaFilters_
Variables for NEW EGAMMA selection.
Definition: PFAlgo.h:265
void createCandidatesHCALUnlinked(const reco::PFBlock &block, reco::PFBlock::LinkData &linkData, const edm::OwnVector< reco::PFBlockElement > &elements, std::vector< bool > &active, const reco::PFBlockRef &blockref, ElementIndices &inds, std::vector< bool > &deadArea)
Definition: PFAlgo.cc:2813
ostream & operator<<(ostream &out, const PFAlgo &algo)
Definition: PFAlgo.cc:3400
float goodTrackDeadHcal_ptErrRel_
Variables for track cleaning in bad HCal areas.
Definition: PFAlgo.h:301
bool step5(const reco::TrackBase::TrackAlgorithm &)
int goodPixelTrackDeadHcal_maxLost4Hit_
Definition: PFAlgo.h:312
const double nSigmaHFHAD_
Definition: PFAlgo.h:252
float goodPixelTrackDeadHcal_chi2n_
Definition: PFAlgo.h:310
Log< level::Warning, false > LogWarning
double nSigmaTRACK_
Definition: PFAlgo.h:296
TupleMultiplicity< TrackerTraits > const *__restrict__ uint32_t nHits
math::XYZVector XYZVector
Definition: RawParticle.h:26
void postCleaning()
Definition: PFAlgo.cc:3497
std::vector< unsigned > trackIs
Definition: PFAlgo.h:45
tmp
align.sh
Definition: createJobs.py:716
Definition: PFAlgo.h:53
bool usePFDecays_
Definition: PFAlgo.h:281
double phi() const final
momentum azimuthal angle
std::unique_ptr< PFMuonAlgo > pfmu_
Definition: PFAlgo.h:262
void setP4(const LorentzVector &p4) final
set 4-momentum
float goodTrackDeadHcal_chi2n_
Definition: PFAlgo.h:302
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:29
float goodPixelTrackDeadHcal_dz_
Definition: PFAlgo.h:314
bool checkAndReconstructSecondaryInteraction(const reco::PFBlockRef &blockref, const edm::OwnVector< reco::PFBlockElement > &elements, bool isActive, int iElement)
Definition: PFAlgo.cc:855
void setEGammaParameters(bool use_EGammaFilters, bool useProtectionsForJetMET)
Definition: PFAlgo.cc:68
float mva_e_pi() const
mva for electron-pion discrimination
Definition: PFCandidate.h:317
int charge() const final
electric charge
const edm::ValueMap< reco::GsfElectronRef > * valueMapGedElectrons_
Definition: PFAlgo.h:268
#define LogDebug(id)
Block of elements.
Definition: PFBlock.h:26
virtual ParticleType particleId() const
Definition: PFCandidate.h:392
double eta() const final
momentum pseudorapidity