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PileupJetIdAlgo Class Reference

#include <PileupJetIdAlgo.h>

Classes

class  AlgoGBRForestsAndConstants
 

Public Types

typedef std::map< std::string, std::pair< float *, float > > variables_list_t
 
enum  version_t { USER = -1, PHILv0 = 0 }
 

Public Member Functions

int computeCutIDflag (float betaStarClassic, float dR2Mean, float nvtx, float jetPt, float jetEta)
 
int computeIDflag (float mva, float jetPt, float jetEta)
 
int computeIDflag (float mva, int ptId, int etaId)
 
PileupJetIdentifier computeIdVariables (const reco::Jet *jet, float jec, const reco::Vertex *, const reco::VertexCollection &, double rho, edm::ValueMap< float > &constituentWeights, bool applyConstituentWeight)
 
PileupJetIdentifier computeMva ()
 
std::string dumpVariables () const
 
std::pair< int, int > getJetIdKey (float jetPt, float jetEta)
 
float getMVAval (const std::vector< std::string > &, const std::unique_ptr< const GBRForest > &)
 
const variables_list_tgetVariables () const
 const PileupJetIdentifier::variables_list_t & getVariables() const { return variables_; }; More...
 
const std::string method () const
 
 PileupJetIdAlgo (AlgoGBRForestsAndConstants const *cache)
 
void set (const PileupJetIdentifier &)
 
 ~PileupJetIdAlgo ()
 

Protected Member Functions

void initVariables ()
 
void resetVariables ()
 
void runMva ()
 

Protected Attributes

AlgoGBRForestsAndConstants const * cache_
 
PileupJetIdentifier internalId_
 
variables_list_t variables_
 

Detailed Description

Definition at line 22 of file PileupJetIdAlgo.h.

Member Typedef Documentation

◆ variables_list_t

typedef std::map<std::string, std::pair<float*, float> > PileupJetIdAlgo::variables_list_t

Definition at line 46 of file PileupJetIdAlgo.h.

Member Enumeration Documentation

◆ version_t

Enumerator
USER 
PHILv0 

Definition at line 24 of file PileupJetIdAlgo.h.

Constructor & Destructor Documentation

◆ PileupJetIdAlgo()

PileupJetIdAlgo::PileupJetIdAlgo ( AlgoGBRForestsAndConstants const *  cache)

Definition at line 133 of file PileupJetIdAlgo.cc.

References initVariables().

133 : cache_(cache) { initVariables(); }
AlgoGBRForestsAndConstants const * cache_
def cache(function)
Definition: utilities.py:3

◆ ~PileupJetIdAlgo()

PileupJetIdAlgo::~PileupJetIdAlgo ( )

Definition at line 136 of file PileupJetIdAlgo.cc.

136 {}

Member Function Documentation

◆ computeCutIDflag()

int PileupJetIdAlgo::computeCutIDflag ( float  betaStarClassic,
float  dR2Mean,
float  nvtx,
float  jetPt,
float  jetEta 
)

Definition at line 219 of file PileupJetIdAlgo.cc.

References getJetIdKey(), reco::btau::jetEta, reco::btau::jetPt, PileupJetIdentifier::kLoose, PileupJetIdentifier::kMedium, PileupJetIdentifier::kTight, and dqm-mbProfile::log.

Referenced by runMva().

219  {
220  std::pair<int, int> jetIdKey = getJetIdKey(jetPt, jetEta);
221  float betaStarModified = betaStarClassic / log(nvtx - 0.64);
222  int idFlag(0);
223  if (betaStarModified < cache_->betaStarCut()[PileupJetIdentifier::kTight][jetIdKey.first][jetIdKey.second] &&
224  dR2Mean < cache_->rmsCut()[PileupJetIdentifier::kTight][jetIdKey.first][jetIdKey.second])
225  idFlag += 1 << PileupJetIdentifier::kTight;
226 
227  if (betaStarModified < cache_->betaStarCut()[PileupJetIdentifier::kMedium][jetIdKey.first][jetIdKey.second] &&
228  dR2Mean < cache_->rmsCut()[PileupJetIdentifier::kMedium][jetIdKey.first][jetIdKey.second])
229  idFlag += 1 << PileupJetIdentifier::kMedium;
230 
231  if (betaStarModified < cache_->betaStarCut()[PileupJetIdentifier::kLoose][jetIdKey.first][jetIdKey.second] &&
232  dR2Mean < cache_->rmsCut()[PileupJetIdentifier::kLoose][jetIdKey.first][jetIdKey.second])
233  idFlag += 1 << PileupJetIdentifier::kLoose;
234  return idFlag;
235 }
std::pair< int, int > getJetIdKey(float jetPt, float jetEta)

◆ computeIDflag() [1/2]

int PileupJetIdAlgo::computeIDflag ( float  mva,
float  jetPt,
float  jetEta 
)

Definition at line 237 of file PileupJetIdAlgo.cc.

References getJetIdKey(), reco::btau::jetEta, reco::btau::jetPt, and beam_dqm_sourceclient-live_cfg::mva.

Referenced by runMva().

237  {
238  std::pair<int, int> jetIdKey = getJetIdKey(jetPt, jetEta);
239  return computeIDflag(mva, jetIdKey.first, jetIdKey.second);
240 }
std::pair< int, int > getJetIdKey(float jetPt, float jetEta)
int computeIDflag(float mva, float jetPt, float jetEta)

◆ computeIDflag() [2/2]

int PileupJetIdAlgo::computeIDflag ( float  mva,
int  ptId,
int  etaId 
)

◆ computeIdVariables()

PileupJetIdentifier PileupJetIdAlgo::computeIdVariables ( const reco::Jet jet,
float  jec,
const reco::Vertex vtx,
const reco::VertexCollection allvtx,
double  rho,
edm::ValueMap< float > &  constituentWeights,
bool  applyConstituentWeight 
)

Definition at line 261 of file PileupJetIdAlgo.cc.

References funct::abs(), cms::cuda::assert(), assign(), reco::Muon::bestTrack(), reco::Candidate::bestTrack(), cache_, reco::Candidate::charge(), reco::PFJet::chargedEmEnergy(), pat::Jet::chargedEmEnergy(), reco::PFJet::chargedHadronEnergy(), pat::Jet::chargedHadronEnergy(), reco::PFJet::chargedMultiplicity(), pat::Jet::chargedMultiplicity(), PileupJetIdentifier::chFrac01_, PileupJetIdentifier::chFrac02_, PileupJetIdentifier::chFrac03_, PileupJetIdentifier::chFrac04_, PileupJetIdentifier::chFrac05_, PileupJetIdentifier::chFrac06_, PileupJetIdentifier::chFrac07_, PileupJetIdentifier::chgEMfrac_, PileupJetIdentifier::chgHadrfrac_, pat::Jet::correctedJet(), PileupJetIdentifier::d0_, reco::deltaPhi(), reco::deltaR(), PileupJetIdentifier::dRLead2nd_, PileupJetIdentifier::dRLeadCent_, PileupJetIdentifier::dRMeanCh_, PileupJetIdentifier::dRMeanEm_, PileupJetIdentifier::dRMeanNeut_, HLT_2024v14_cff::dRmin, reco::TrackBase::dxy(), pat::PackedCandidate::dxy(), l1ctLayer1_cff::dZ, reco::TrackBase::dz(), pat::PackedCandidate::dz(), PileupJetIdentifier::emFrac01_, PileupJetIdentifier::emFrac02_, PileupJetIdentifier::emFrac03_, PileupJetIdentifier::emFrac04_, PileupJetIdentifier::emFrac05_, PileupJetIdentifier::emFrac06_, PileupJetIdentifier::emFrac07_, reco::Candidate::eta(), PileupJetIdentifier::etaW_, PileupJetIdentifier::fourthChFrac_, PileupJetIdentifier::fourthEmFrac_, PileupJetIdentifier::fourthFrac_, PileupJetIdentifier::fourthNeutFrac_, DivergingColor::frac, pat::PackedCandidate::fromPV(), edm::Ptr< T >::get(), edm::Ref< C, T, F >::get(), reco::PFCandidate::gsfTrackRef(), mps_fire::i, internalId_, edm::Ref< C, T, F >::isNonnull(), ALPAKA_ACCELERATOR_NAMESPACE::vertexFinder::iv, jetMETDQMOfflineSource_cff::jec, metsig::jet, PileupJetIdentifier::jetM_, PileupJetIdentifier::jetPhi_, reco::btau::jetPt, PileupJetIdentifier::jetW_, dqmdumpme::k, large_val, PileupJetIdentifier::leadChEta_, PileupJetIdentifier::leadChFrac_, PileupJetIdentifier::leadChPhi_, PileupJetIdentifier::leadChPt_, PileupJetIdentifier::leadEmEta_, PileupJetIdentifier::leadEmFrac_, PileupJetIdentifier::leadEmPhi_, PileupJetIdentifier::leadEmPt_, PileupJetIdentifier::leadEta_, PileupJetIdentifier::leadFrac_, PileupJetIdentifier::leadNeutEta_, PileupJetIdentifier::leadNeutFrac_, PileupJetIdentifier::leadNeutPhi_, PileupJetIdentifier::leadNeutPt_, PileupJetIdentifier::leadPhi_, PileupJetIdentifier::leadPt_, pfDeepBoostedJetPreprocessParams_cfi::lower_bound, SiStripPI::min, reco::PFCandidate::muonRef(), PileupJetIdentifier::neuEMfrac_, PileupJetIdentifier::neuHadrfrac_, PileupJetIdentifier::neutFrac01_, PileupJetIdentifier::neutFrac02_, PileupJetIdentifier::neutFrac03_, PileupJetIdentifier::neutFrac04_, PileupJetIdentifier::neutFrac05_, PileupJetIdentifier::neutFrac06_, PileupJetIdentifier::neutFrac07_, reco::PFJet::neutralEmEnergy(), pat::Jet::neutralEmEnergy(), reco::PFJet::neutralHadronEnergy(), pat::Jet::neutralHadronEnergy(), reco::PFJet::neutralMultiplicity(), pat::Jet::neutralMultiplicity(), reco::Candidate::pdgId(), reco::Candidate::phi(), PileupJetIdentifier::phiW_, reco::Candidate::pt(), reco::LeafCandidate::pt(), PileupJetIdentifier::pt2A_, PileupJetIdentifier::ptDCh_, PileupJetIdentifier::ptDNe_, PileupJetIdentifier::ptMean_, PileupJetIdentifier::ptRMS_, pat::PackedCandidate::PVUsedInFit, alignCSCRings::r, resetVariables(), rho, runMva(), PileupJetIdAlgo::AlgoGBRForestsAndConstants::runMvas(), PileupJetIdentifier::secondChFrac_, PileupJetIdentifier::secondEmFrac_, PileupJetIdentifier::secondEta_, PileupJetIdentifier::secondFrac_, PileupJetIdentifier::secondNeutFrac_, PileupJetIdentifier::secondPhi_, PileupJetIdentifier::secondPt_, setPtEtaPhi(), jetUpdater_cfi::sort, mathSSE::sqrt(), PileupJetIdentifier::sumChPt_, PileupJetIdentifier::sumNePt_, TtFullHadEvtBuilder_cfi::sumPt, PileupJetIdentifier::sumPt_, edm::swap(), PileupJetIdentifier::thirdChFrac_, PileupJetIdentifier::thirdEmFrac_, PileupJetIdentifier::thirdFrac_, PileupJetIdentifier::thirdNeutFrac_, reco::PFCandidate::trackRef(), L1BJetProducer_cff::vtx, and mps_merge::weight.

Referenced by PileupJetIdProducer::produce().

267  {
268  // initialize all variables to 0
269  resetVariables();
270 
271  // loop over constituents, accumulate sums and find leading candidates
272  const pat::Jet* patjet = dynamic_cast<const pat::Jet*>(jet);
273  const reco::PFJet* pfjet = dynamic_cast<const reco::PFJet*>(jet);
274  assert(patjet != nullptr || pfjet != nullptr);
275  if (patjet != nullptr && jec == 0.) { // if this is a pat jet and no jec has been passed take the jec from the object
276  jec = patjet->pt() / patjet->correctedJet(0).pt();
277  }
278  if (jec <= 0.) {
279  jec = 1.;
280  }
281 
282  const reco::Candidate *lLead = nullptr, *lSecond = nullptr, *lLeadNeut = nullptr, *lLeadEm = nullptr,
283  *lLeadCh = nullptr, *lTrail = nullptr;
284 
285  std::vector<float> frac, fracCh, fracEm, fracNeut;
286  float cones[] = {0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7};
287  size_t ncones = sizeof(cones) / sizeof(float);
288  float* coneFracs[] = {&internalId_.frac01_,
289  &internalId_.frac02_,
290  &internalId_.frac03_,
291  &internalId_.frac04_,
292  &internalId_.frac05_,
293  &internalId_.frac06_,
294  &internalId_.frac07_};
295  float* coneEmFracs[] = {&internalId_.emFrac01_,
302  float* coneNeutFracs[] = {&internalId_.neutFrac01_,
309  float* coneChFracs[] = {&internalId_.chFrac01_,
316  TMatrixDSym covMatrix(2);
317  covMatrix = 0.;
318  float jetPt = jet->pt() / jec; // use uncorrected pt for shape variables
319  float sumPt = 0., sumPt2 = 0., sumTkPt = 0., sumPtCh = 0, sumPtNe = 0;
320  float multNeut = 0.0;
321  float sumW2(0.0);
322  float sum_deta(0.0), sum_dphi(0.0);
323  float ave_deta(0.0), ave_dphi(0.0);
324  setPtEtaPhi(
325  *jet, internalId_.jetPt_, internalId_.jetEta_, internalId_.jetPhi_); // use corrected pt for jet kinematics
326  internalId_.jetM_ = jet->mass();
327  internalId_.nvtx_ = allvtx.size();
328  internalId_.rho_ = rho;
329 
330  float dRmin(1000);
331  float LeadcandWeight = 1.0;
332  float SecondcandWeight = 1.0;
333  float LeadNeutcandWeight = 1.0;
334  float LeadEmcandWeight = 1.0;
335  float LeadChcandWeight = 1.0;
336  float TrailcandWeight = 1.0;
337 
338  for (unsigned i = 0; i < jet->numberOfSourceCandidatePtrs(); ++i) {
339  reco::CandidatePtr pfJetConstituent = jet->sourceCandidatePtr(i);
340  const reco::Candidate* icand = pfJetConstituent.get();
341  const pat::PackedCandidate* lPack = dynamic_cast<const pat::PackedCandidate*>(icand);
342  const reco::PFCandidate* lPF = dynamic_cast<const reco::PFCandidate*>(icand);
343  bool isPacked = true;
344  if (lPack == nullptr) {
345  isPacked = false;
346  }
347 
348  float candWeight = 1.0;
349  if (applyConstituentWeight) { // PUPPI Jet weight should be pulled up from valuemap, not packed candidate
350  candWeight = constituentWeights[jet->sourceCandidatePtr(i)];
351  }
352  float candPt = (icand->pt()) * candWeight;
353  float candPtFrac = candPt / jetPt;
354  float candDr = reco::deltaR(*icand, *jet);
355  float candDeta = icand->eta() - jet->eta();
356  float candDphi = reco::deltaPhi(*icand, *jet);
357  float candPtDr = candPt * candDr;
358  size_t icone = std::lower_bound(&cones[0], &cones[ncones], candDr) - &cones[0];
359 
360  if (candDr < dRmin)
361  dRmin = candDr;
362 
363  // // all particles; PUPPI weights multiplied to leading and subleading constituent if it is for PUPPI
364  if (lLead == nullptr || candPt > (lLead->pt()) * LeadcandWeight) {
365  lSecond = lLead;
366  SecondcandWeight = LeadcandWeight;
367  lLead = icand;
368  if (applyConstituentWeight) {
369  LeadcandWeight = constituentWeights[jet->sourceCandidatePtr(i)];
370  }
371  } else if ((lSecond == nullptr || candPt > (lSecond->pt()) * SecondcandWeight) &&
372  (candPt < (lLead->pt()) * LeadcandWeight)) {
373  lSecond = icand;
374  if (applyConstituentWeight) {
375  SecondcandWeight = constituentWeights[jet->sourceCandidatePtr(i)];
376  }
377  }
378 
379  // // average shapes
380  internalId_.dRMean_ += candPtDr;
381  internalId_.dR2Mean_ += candPtDr * candPtDr;
382  covMatrix(0, 0) += candPt * candPt * candDeta * candDeta;
383  covMatrix(0, 1) += candPt * candPt * candDeta * candDphi;
384  covMatrix(1, 1) += candPt * candPt * candDphi * candDphi;
385  internalId_.ptD_ += candPt * candPt;
386  sumPt += candPt;
387  sumPt2 += candPt * candPt;
388 
389  // single most energetic candiates and jet shape profiles
390  frac.push_back(candPtFrac);
391 
392  if (icone < ncones) {
393  *coneFracs[icone] += candPt;
394  }
395 
396  // neutrals Neutral hadrons
397  if (abs(icand->pdgId()) == 130) {
398  if (lLeadNeut == nullptr || candPt > (lLeadNeut->pt()) * LeadNeutcandWeight) {
399  lLeadNeut = icand;
400  if (applyConstituentWeight) {
401  LeadNeutcandWeight = constituentWeights[jet->sourceCandidatePtr(i)];
402  }
403  }
404 
405  internalId_.dRMeanNeut_ += candPtDr;
406  fracNeut.push_back(candPtFrac);
407  if (icone < ncones) {
408  *coneNeutFracs[icone] += candPt;
409  }
410  internalId_.ptDNe_ += candPt * candPt;
411  sumPtNe += candPt;
412  multNeut += candWeight;
413  }
414 
415  // EM candidated photon
416  if (icand->pdgId() == 22) {
417  if (lLeadEm == nullptr || candPt > (lLeadEm->pt()) * LeadEmcandWeight) {
418  lLeadEm = icand;
419  if (applyConstituentWeight) {
420  LeadEmcandWeight = constituentWeights[jet->sourceCandidatePtr(i)];
421  }
422  }
423  internalId_.dRMeanEm_ += candPtDr;
424  fracEm.push_back(candPtFrac);
425  if (icone < ncones) {
426  *coneEmFracs[icone] += candPt;
427  }
428  internalId_.ptDNe_ += candPt * candPt;
429  sumPtNe += candPt;
430  multNeut += candWeight;
431  }
432  // hadrons and EM in HF
433  if ((abs(icand->pdgId()) == 1) || (abs(icand->pdgId()) == 2))
434  multNeut += candWeight;
435 
436  // Charged particles
437  if (icand->charge() != 0) {
438  if (lLeadCh == nullptr || candPt > (lLeadCh->pt()) * LeadChcandWeight) {
439  lLeadCh = icand;
440  if (applyConstituentWeight) {
441  LeadChcandWeight = constituentWeights[jet->sourceCandidatePtr(i)];
442  }
443  const reco::Track* pfTrk = icand->bestTrack();
444  if (lPF && std::abs(icand->pdgId()) == 13 && pfTrk == nullptr) {
445  reco::MuonRef lmuRef = lPF->muonRef();
446  if (lmuRef.isNonnull()) {
447  const reco::Muon& lmu = *lmuRef.get();
448  pfTrk = lmu.bestTrack();
449  edm::LogWarning("BadMuon")
450  << "Found a PFCandidate muon without a trackRef: falling back to Muon::bestTrack ";
451  }
452  }
453  if (pfTrk == nullptr) { //protection against empty pointers for the miniAOD case
454  //To handle the electron case
455  if (isPacked) {
456  internalId_.d0_ = std::abs(lPack->dxy(vtx->position()));
457  internalId_.dZ_ = std::abs(lPack->dz(vtx->position()));
458  } else if (lPF != nullptr) {
459  pfTrk = (lPF->trackRef().get() == nullptr) ? lPF->gsfTrackRef().get() : lPF->trackRef().get();
460  internalId_.d0_ = std::abs(pfTrk->dxy(vtx->position()));
461  internalId_.dZ_ = std::abs(pfTrk->dz(vtx->position()));
462  }
463  } else {
464  internalId_.d0_ = std::abs(pfTrk->dxy(vtx->position()));
465  internalId_.dZ_ = std::abs(pfTrk->dz(vtx->position()));
466  }
467  }
468  internalId_.dRMeanCh_ += candPtDr;
469  internalId_.ptDCh_ += candPt * candPt;
470  fracCh.push_back(candPtFrac);
471  if (icone < ncones) {
472  *coneChFracs[icone] += candPt;
473  }
474  sumPtCh += candPt;
475  }
476  // // beta and betastar
477  if (icand->charge() != 0) {
478  if (!isPacked) {
479  if (lPF->trackRef().isNonnull()) {
480  float tkpt = candPt;
481  sumTkPt += tkpt;
482  // 'classic' beta definition based on track-vertex association
483  bool inVtx0 = vtx->trackWeight(lPF->trackRef()) > 0;
484 
485  bool inAnyOther = false;
486  // alternative beta definition based on track-vertex distance of closest approach
487  double dZ0 = std::abs(lPF->trackRef()->dz(vtx->position()));
488  double dZ = dZ0;
489  for (reco::VertexCollection::const_iterator vi = allvtx.begin(); vi != allvtx.end(); ++vi) {
490  const reco::Vertex& iv = *vi;
491  if (iv.isFake() || iv.ndof() < 4) {
492  continue;
493  }
494  // the primary vertex may have been copied by the user: check identity by position
495  bool isVtx0 = (iv.position() - vtx->position()).r() < 0.02;
496  // 'classic' beta definition: check if the track is associated with
497  // any vertex other than the primary one
498  if (!isVtx0 && !inAnyOther) {
499  inAnyOther = vtx->trackWeight(lPF->trackRef()) <= 0;
500  }
501  // alternative beta: find closest vertex to the track
502  dZ = std::min(dZ, std::abs(lPF->trackRef()->dz(iv.position())));
503  }
504  // classic beta/betaStar
505  if (inVtx0 && !inAnyOther) {
506  internalId_.betaClassic_ += tkpt;
507  } else if (!inVtx0 && inAnyOther) {
508  internalId_.betaStarClassic_ += tkpt;
509  }
510  // alternative beta/betaStar
511  if (dZ0 < 0.2) {
512  internalId_.beta_ += tkpt;
513  } else if (dZ < 0.2) {
514  internalId_.betaStar_ += tkpt;
515  }
516  }
517  } else {
518  float tkpt = candPt;
519  sumTkPt += tkpt;
520  bool inVtx0 = false;
521  bool inVtxOther = false;
522  double dZ0 = 9999.;
523  double dZ_tmp = 9999.;
524  for (unsigned vtx_i = 0; vtx_i < allvtx.size(); vtx_i++) {
525  const auto& iv = allvtx[vtx_i];
526 
527  if (iv.isFake())
528  continue;
529 
530  // Match to vertex in case of copy as above
531  bool isVtx0 = (iv.position() - vtx->position()).r() < 0.02;
532 
533  if (isVtx0) {
534  if (lPack->fromPV(vtx_i) == pat::PackedCandidate::PVUsedInFit)
535  inVtx0 = true;
536  if (lPack->fromPV(vtx_i) == 0)
537  inVtxOther = true;
538  dZ0 = lPack->dz(iv.position());
539  }
540 
541  if (fabs(lPack->dz(iv.position())) < fabs(dZ_tmp)) {
542  dZ_tmp = lPack->dz(iv.position());
543  }
544  }
545  if (inVtx0) {
546  internalId_.betaClassic_ += tkpt;
547  } else if (inVtxOther) {
548  internalId_.betaStarClassic_ += tkpt;
549  }
550  if (fabs(dZ0) < 0.2) {
551  internalId_.beta_ += tkpt;
552  } else if (fabs(dZ_tmp) < 0.2) {
553  internalId_.betaStar_ += tkpt;
554  }
555  }
556  }
557 
558  // trailing candidate
559  if (lTrail == nullptr || candPt < (lTrail->pt()) * TrailcandWeight) {
560  lTrail = icand;
561  if (applyConstituentWeight) {
562  TrailcandWeight = constituentWeights[jet->sourceCandidatePtr(i)];
563  }
564  }
565 
566  // average for pull variable
567 
568  float weight2 = candPt * candPt;
569  sumW2 += weight2;
570  float deta = icand->eta() - jet->eta();
571  float dphi = reco::deltaPhi(*icand, *jet);
572  sum_deta += deta * weight2;
573  sum_dphi += dphi * weight2;
574  }
575  if (sumW2 > 0) {
576  ave_deta = sum_deta / sumW2;
577  ave_dphi = sum_dphi / sumW2;
578  }
579 
580  // // Finalize all variables
581  // Most of Below values are not used for puID variable generation at the moment, except lLeadCh Pt for JetRchg, so I assign that zero if there is no charged constituent.
582 
583  assert(!(lLead == nullptr));
584  internalId_.leadPt_ = lLead->pt() * LeadcandWeight;
585  internalId_.leadEta_ = lLead->eta();
586  internalId_.leadPhi_ = lLead->phi();
587 
588  if (lSecond != nullptr) {
589  internalId_.secondPt_ = lSecond->pt() * SecondcandWeight;
590  internalId_.secondEta_ = lSecond->eta();
591  internalId_.secondPhi_ = lSecond->phi();
592  } else {
593  internalId_.secondPt_ = 0.0;
596  }
597 
598  if (lLeadNeut != nullptr) {
599  internalId_.leadNeutPt_ = lLeadNeut->pt() * LeadNeutcandWeight;
600  internalId_.leadNeutEta_ = lLeadNeut->eta();
601  internalId_.leadNeutPhi_ = lLeadNeut->phi();
602  } else {
603  internalId_.leadNeutPt_ = 0.0;
606  }
607 
608  if (lLeadEm != nullptr) {
609  internalId_.leadEmPt_ = lLeadEm->pt() * LeadEmcandWeight;
610  internalId_.leadEmEta_ = lLeadEm->eta();
611  internalId_.leadEmPhi_ = lLeadEm->phi();
612  } else {
613  internalId_.leadEmPt_ = 0.0;
616  }
617 
618  if (lLeadCh != nullptr) {
619  internalId_.leadChPt_ = lLeadCh->pt() * LeadChcandWeight;
620  internalId_.leadChEta_ = lLeadCh->eta();
621  internalId_.leadChPhi_ = lLeadCh->phi();
622  } else {
623  internalId_.leadChPt_ = 0.0;
626  }
627 
628  if (patjet != nullptr) { // to enable running on MiniAOD slimmedJets
629  internalId_.nCharged_ = patjet->chargedMultiplicity();
630  internalId_.nNeutrals_ = patjet->neutralMultiplicity();
631  internalId_.chgEMfrac_ = patjet->chargedEmEnergy() / jet->energy();
632  internalId_.neuEMfrac_ = patjet->neutralEmEnergy() / jet->energy();
633  internalId_.chgHadrfrac_ = patjet->chargedHadronEnergy() / jet->energy();
634  internalId_.neuHadrfrac_ = patjet->neutralHadronEnergy() / jet->energy();
635  if (applyConstituentWeight)
636  internalId_.nNeutrals_ = multNeut;
637  } else {
638  internalId_.nCharged_ = pfjet->chargedMultiplicity();
639  internalId_.nNeutrals_ = pfjet->neutralMultiplicity();
640  internalId_.chgEMfrac_ = pfjet->chargedEmEnergy() / jet->energy();
641  internalId_.neuEMfrac_ = pfjet->neutralEmEnergy() / jet->energy();
642  internalId_.chgHadrfrac_ = pfjet->chargedHadronEnergy() / jet->energy();
643  internalId_.neuHadrfrac_ = pfjet->neutralHadronEnergy() / jet->energy();
644  if (applyConstituentWeight)
645  internalId_.nNeutrals_ = multNeut;
646  }
647  internalId_.nParticles_ = jet->nConstituents();
648 
650  float ddetaR_sum(0.0), ddphiR_sum(0.0), pull_tmp(0.0);
651  for (unsigned k = 0; k < jet->numberOfSourceCandidatePtrs(); k++) {
652  reco::CandidatePtr temp_pfJetConstituent = jet->sourceCandidatePtr(k);
653  // reco::CandidatePtr temp_weightpfJetConstituent = jet->sourceCandidatePtr(k);
654  const reco::Candidate* part = temp_pfJetConstituent.get();
655 
656  float candWeight = 1.0;
657 
658  if (applyConstituentWeight)
659  candWeight = constituentWeights[jet->sourceCandidatePtr(k)];
660 
661  float weight = candWeight * (part->pt()) * candWeight * (part->pt());
662  float deta = part->eta() - jet->eta();
663  float dphi = reco::deltaPhi(*part, *jet);
664  float ddeta, ddphi, ddR;
665  ddeta = deta - ave_deta;
666  ddphi = dphi - ave_dphi;
667  ddR = sqrt(ddeta * ddeta + ddphi * ddphi);
668  ddetaR_sum += ddR * ddeta * weight;
669  ddphiR_sum += ddR * ddphi * weight;
670  }
671  if (sumW2 > 0) {
672  float ddetaR_ave = ddetaR_sum / sumW2;
673  float ddphiR_ave = ddphiR_sum / sumW2;
674  pull_tmp = sqrt(ddetaR_ave * ddetaR_ave + ddphiR_ave * ddphiR_ave);
675  }
676  internalId_.pull_ = pull_tmp;
678 
679  std::sort(frac.begin(), frac.end(), std::greater<float>());
680  std::sort(fracCh.begin(), fracCh.end(), std::greater<float>());
681  std::sort(fracEm.begin(), fracEm.end(), std::greater<float>());
682  std::sort(fracNeut.begin(), fracNeut.end(), std::greater<float>());
684  assign(
686  assign(
688  assign(fracNeut,
693 
694  covMatrix(0, 0) /= sumPt2;
695  covMatrix(0, 1) /= sumPt2;
696  covMatrix(1, 1) /= sumPt2;
697  covMatrix(1, 0) = covMatrix(0, 1);
698  internalId_.etaW_ = sqrt(covMatrix(0, 0));
699  internalId_.phiW_ = sqrt(covMatrix(1, 1));
701  TVectorD eigVals(2);
702  eigVals = TMatrixDSymEigen(covMatrix).GetEigenValues();
703  internalId_.majW_ = sqrt(std::abs(eigVals(0)));
704  internalId_.minW_ = sqrt(std::abs(eigVals(1)));
705  if (internalId_.majW_ < internalId_.minW_) {
706  std::swap(internalId_.majW_, internalId_.minW_);
707  }
708 
710  if (lSecond != nullptr) {
711  internalId_.dRLead2nd_ = reco::deltaR(*jet, *lSecond);
712  }
713  internalId_.dRMean_ /= jetPt;
717  internalId_.dR2Mean_ /= sumPt2;
718 
719  for (size_t ic = 0; ic < ncones; ++ic) {
720  *coneFracs[ic] /= jetPt;
721  *coneEmFracs[ic] /= jetPt;
722  *coneNeutFracs[ic] /= jetPt;
723  *coneChFracs[ic] /= jetPt;
724  }
725  //http://jets.physics.harvard.edu/qvg/
726  double ptMean = sumPt / internalId_.nParticles_;
727  double ptRMS = 0;
728  for (unsigned int i0 = 0; i0 < frac.size(); i0++) {
729  ptRMS += (frac[i0] - ptMean) * (frac[i0] - ptMean);
730  }
731  ptRMS /= internalId_.nParticles_;
732  ptRMS = sqrt(ptRMS);
733 
734  internalId_.ptMean_ = ptMean;
735  internalId_.ptRMS_ = ptRMS / jetPt;
736  internalId_.pt2A_ = sqrt(internalId_.ptD_ / internalId_.nParticles_) / jetPt;
737  internalId_.ptD_ = sqrt(internalId_.ptD_) / sumPt;
741  internalId_.sumChPt_ = sumPtCh;
742  internalId_.sumNePt_ = sumPtNe;
743 
744  internalId_.jetR_ = (lLead->pt()) * LeadcandWeight / sumPt;
745  if (lLeadCh != nullptr) {
746  internalId_.jetRchg_ = (lLeadCh->pt()) * LeadChcandWeight / sumPt;
747  } else {
748  internalId_.jetRchg_ = 0;
749  }
750 
751  internalId_.dRMatch_ = dRmin;
752 
753  if (sumTkPt != 0.) {
754  internalId_.beta_ /= sumTkPt;
755  internalId_.betaStar_ /= sumTkPt;
756  internalId_.betaClassic_ /= sumTkPt;
757  internalId_.betaStarClassic_ /= sumTkPt;
758  } else {
759  assert(internalId_.beta_ == 0. && internalId_.betaStar_ == 0. && internalId_.betaClassic_ == 0. &&
760  internalId_.betaStarClassic_ == 0.);
761  }
762 
763  if (cache_->runMvas()) {
764  runMva();
765  }
766 
768 }
const float large_val
constexpr double deltaPhi(double phi1, double phi2)
Definition: deltaPhi.h:26
reco::GsfTrackRef gsfTrackRef() const
Definition: PFCandidate.cc:469
AlgoGBRForestsAndConstants const * cache_
float neutralHadronEnergy() const
neutralHadronEnergy
Definition: PFJet.h:99
double pt() const final
transverse momentum
int chargedMultiplicity() const
chargedMultiplicity
Definition: PFJet.h:152
int chargedMultiplicity() const
chargedMultiplicity
Definition: Jet.h:740
float chargedEmEnergy() const
chargedEmEnergy
Definition: PFJet.h:139
float neutralEmEnergy() const
neutralEmEnergy
Definition: PFJet.h:147
virtual double pt() const =0
transverse momentum
bool isNonnull() const
Checks for non-null.
Definition: Ref.h:238
Definition: weight.py:1
const PVAssoc fromPV(size_t ipv=0) const
int neutralMultiplicity() const
neutralMultiplicity
Definition: Jet.h:464
const Track * bestTrack() const override
Definition: Muon.h:58
int neutralMultiplicity() const
neutralMultiplicity
Definition: PFJet.h:154
assert(be >=bs)
Jets made from PFObjects.
Definition: PFJet.h:20
void swap(Association< C > &lhs, Association< C > &rhs)
Definition: Association.h:112
float chargedHadronEnergy() const
chargedHadronEnergy
Definition: Jet.h:694
double dz() const
dz parameter (= dsz/cos(lambda)). This is the track z0 w.r.t (0,0,0) only if the refPoint is close to...
Definition: TrackBase.h:622
PileupJetIdentifier internalId_
T sqrt(T t)
Definition: SSEVec.h:19
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
void assign(const std::vector< float > &vec, float &a, float &b, float &c, float &d)
virtual int charge() const =0
electric charge
Jet correctedJet(const std::string &level, const std::string &flavor="none", const std::string &set="") const
float chargedEmEnergy() const
chargedEmEnergy
Definition: Jet.h:712
reco::MuonRef muonRef() const
Definition: PFCandidate.cc:450
T const * get() const
Returns C++ pointer to the item.
Definition: Ptr.h:139
constexpr auto deltaR(const T1 &t1, const T2 &t2) -> decltype(t1.eta())
Definition: deltaR.h:30
virtual int pdgId() const =0
PDG identifier.
float neutralHadronEnergy() const
neutralHadronEnergy
Definition: Jet.h:704
void setPtEtaPhi(const reco::Candidate &p, float &pt, float &eta, float &phi)
part
Definition: HCALResponse.h:20
Analysis-level calorimeter jet class.
Definition: Jet.h:77
float neutralEmEnergy() const
neutralEmEnergy
Definition: Jet.h:722
Particle reconstructed by the particle flow algorithm.
Definition: PFCandidate.h:41
float chargedHadronEnergy() const
chargedHadronEnergy
Definition: PFJet.h:95
virtual const Track * bestTrack() const
Definition: Candidate.h:268
T const * get() const
Returns C++ pointer to the item.
Definition: Ref.h:232
reco::TrackRef trackRef() const
Definition: PFCandidate.cc:437
virtual float dxy() const
dxy with respect to the PV ref
virtual float dz(size_t ipv=0) const
dz with respect to the PV[ipv]
Log< level::Warning, false > LogWarning
virtual double phi() const =0
momentum azimuthal angle
virtual double eta() const =0
momentum pseudorapidity
double dxy() const
dxy parameter. (This is the transverse impact parameter w.r.t. to (0,0,0) ONLY if refPoint is close t...
Definition: TrackBase.h:608

◆ computeMva()

PileupJetIdentifier PileupJetIdAlgo::computeMva ( )

Definition at line 255 of file PileupJetIdAlgo.cc.

References internalId_, and runMva().

Referenced by PileupJetIdProducer::produce().

255  {
256  runMva();
258 }
PileupJetIdentifier internalId_

◆ dumpVariables()

std::string PileupJetIdAlgo::dumpVariables ( ) const

Definition at line 771 of file PileupJetIdAlgo.cc.

References ALPAKA_ACCELERATOR_NAMESPACE::vertexFinder::it, MillePedeFileConverter_cfg::out, and variables_.

771  {
772  std::stringstream out;
773  for (variables_list_t::const_iterator it = variables_.begin(); it != variables_.end(); ++it) {
774  out << std::setw(15) << it->first << std::setw(3) << "=" << std::setw(5) << *it->second.first << " ("
775  << std::setw(5) << it->second.second << ")" << std::endl;
776  }
777  return out.str();
778 }
variables_list_t variables_

◆ getJetIdKey()

std::pair< int, int > PileupJetIdAlgo::getJetIdKey ( float  jetPt,
float  jetEta 
)

Definition at line 197 of file PileupJetIdAlgo.cc.

References funct::abs(), reco::btau::jetEta, and reco::btau::jetPt.

Referenced by computeCutIDflag(), and computeIDflag().

197  {
198  int ptId = 0;
199  if (jetPt >= 10 && jetPt < 20)
200  ptId = 1;
201  if (jetPt >= 20 && jetPt < 30)
202  ptId = 2;
203  if (jetPt >= 30 && jetPt < 40)
204  ptId = 3;
205  if (jetPt >= 40)
206  ptId = 4;
207 
208  int etaId = 0;
209  if (std::abs(jetEta) >= 2.5 && std::abs(jetEta) < 2.75)
210  etaId = 1;
211  if (std::abs(jetEta) >= 2.75 && std::abs(jetEta) < 3.0)
212  etaId = 2;
213  if (std::abs(jetEta) >= 3.0 && std::abs(jetEta) < 5.0)
214  etaId = 3;
215 
216  return std::pair<int, int>(ptId, etaId);
217 }
Abs< T >::type abs(const T &t)
Definition: Abs.h:22

◆ getMVAval()

float PileupJetIdAlgo::getMVAval ( const std::vector< std::string > &  varList,
const std::unique_ptr< const GBRForest > &  reader 
)

Definition at line 158 of file PileupJetIdAlgo.cc.

References ALPAKA_ACCELERATOR_NAMESPACE::vertexFinder::it, DQM::reader, trigObjTnPSource_cfi::var, and variables_.

Referenced by runMva().

159  {
160  std::vector<float> vars;
161  for (std::vector<std::string>::const_iterator it = varList.begin(); it != varList.end(); ++it) {
162  std::pair<float*, float> var = variables_.at(*it);
163  vars.push_back(*var.first);
164  }
165  return reader->GetClassifier(vars.data());
166 }
vars
Definition: DeepTauIdBase.h:60
reader
Definition: DQM.py:105
variables_list_t variables_

◆ getVariables()

const variables_list_t& PileupJetIdAlgo::getVariables ( ) const
inline

const PileupJetIdentifier::variables_list_t & getVariables() const { return variables_; };

Definition at line 54 of file PileupJetIdAlgo.h.

References variables_.

54 { return variables_; };
variables_list_t variables_

◆ initVariables()

void PileupJetIdAlgo::initVariables ( )
protected

Definition at line 794 of file PileupJetIdAlgo.cc.

References HLT_2024v14_cff::beta, simBeamSpotPI::betaStar, d0, METSignificanceParams_cfi::dRMatch, l1ctLayer1_cff::dZ, PileupJetIdentifier::idFlag_, INIT_VARIABLE, internalId_, reco::btau::jetEta, reco::btau::jetPhi, reco::btau::jetPt, LHEJetFilter_cfi::jetR, large_val, beam_dqm_sourceclient-live_cfg::mva, HLT_2024v14_cff::nCharged, jetsAK4_CHS_cff::ptD, rho, and TtFullHadEvtBuilder_cfi::sumPt.

Referenced by PileupJetIdAlgo().

794  {
795  internalId_.idFlag_ = 0;
796  INIT_VARIABLE(mva, "", -100.);
797  //INIT_VARIABLE(jetPt , "jspt_1", 0.);
798  //INIT_VARIABLE(jetEta , "jseta_1", large_val);
799  INIT_VARIABLE(jetPt, "", 0.);
801  INIT_VARIABLE(jetPhi, "jsphi_1", large_val);
802  INIT_VARIABLE(jetM, "jm_1", 0.);
803 
804  INIT_VARIABLE(nCharged, "", 0.);
805  INIT_VARIABLE(nNeutrals, "", 0.);
806 
807  INIT_VARIABLE(chgEMfrac, "", 0.);
808  INIT_VARIABLE(neuEMfrac, "", 0.);
809  INIT_VARIABLE(chgHadrfrac, "", 0.);
810  INIT_VARIABLE(neuHadrfrac, "", 0.);
811 
812  INIT_VARIABLE(d0, "jd0_1", -1000.);
813  INIT_VARIABLE(dZ, "jdZ_1", -1000.);
814  //INIT_VARIABLE(nParticles , "npart_1" , 0.);
815  INIT_VARIABLE(nParticles, "", 0.);
816 
817  INIT_VARIABLE(leadPt, "lpt_1", 0.);
818  INIT_VARIABLE(leadEta, "leta_1", large_val);
819  INIT_VARIABLE(leadPhi, "lphi_1", large_val);
820  INIT_VARIABLE(secondPt, "spt_1", 0.);
821  INIT_VARIABLE(secondEta, "seta_1", large_val);
822  INIT_VARIABLE(secondPhi, "sphi_1", large_val);
823  INIT_VARIABLE(leadNeutPt, "lnept_1", 0.);
824  INIT_VARIABLE(leadNeutEta, "lneeta_1", large_val);
825  INIT_VARIABLE(leadNeutPhi, "lnephi_1", large_val);
826  INIT_VARIABLE(leadEmPt, "lempt_1", 0.);
827  INIT_VARIABLE(leadEmEta, "lemeta_1", large_val);
828  INIT_VARIABLE(leadEmPhi, "lemphi_1", large_val);
829  INIT_VARIABLE(leadChPt, "lchpt_1", 0.);
830  INIT_VARIABLE(leadChEta, "lcheta_1", large_val);
831  INIT_VARIABLE(leadChPhi, "lchphi_1", large_val);
832  INIT_VARIABLE(leadFrac, "lLfr_1", 0.);
833 
834  INIT_VARIABLE(dRLeadCent, "drlc_1", 0.);
835  INIT_VARIABLE(dRLead2nd, "drls_1", 0.);
836  INIT_VARIABLE(dRMean, "drm_1", 0.);
837  INIT_VARIABLE(dRMean, "", 0.);
838  INIT_VARIABLE(pull, "", 0.);
839  INIT_VARIABLE(dRMeanNeut, "drmne_1", 0.);
840  INIT_VARIABLE(dRMeanEm, "drem_1", 0.);
841  INIT_VARIABLE(dRMeanCh, "drch_1", 0.);
842  INIT_VARIABLE(dR2Mean, "", 0.);
843 
844  INIT_VARIABLE(ptD, "", 0.);
845  INIT_VARIABLE(ptMean, "", 0.);
846  INIT_VARIABLE(ptRMS, "", 0.);
847  INIT_VARIABLE(pt2A, "", 0.);
848  INIT_VARIABLE(ptDCh, "", 0.);
849  INIT_VARIABLE(ptDNe, "", 0.);
850  INIT_VARIABLE(sumPt, "", 0.);
851  INIT_VARIABLE(sumChPt, "", 0.);
852  INIT_VARIABLE(sumNePt, "", 0.);
853 
854  INIT_VARIABLE(secondFrac, "", 0.);
855  INIT_VARIABLE(thirdFrac, "", 0.);
856  INIT_VARIABLE(fourthFrac, "", 0.);
857 
858  INIT_VARIABLE(leadChFrac, "", 0.);
859  INIT_VARIABLE(secondChFrac, "", 0.);
860  INIT_VARIABLE(thirdChFrac, "", 0.);
861  INIT_VARIABLE(fourthChFrac, "", 0.);
862 
863  INIT_VARIABLE(leadNeutFrac, "", 0.);
864  INIT_VARIABLE(secondNeutFrac, "", 0.);
865  INIT_VARIABLE(thirdNeutFrac, "", 0.);
866  INIT_VARIABLE(fourthNeutFrac, "", 0.);
867 
868  INIT_VARIABLE(leadEmFrac, "", 0.);
869  INIT_VARIABLE(secondEmFrac, "", 0.);
870  INIT_VARIABLE(thirdEmFrac, "", 0.);
871  INIT_VARIABLE(fourthEmFrac, "", 0.);
872 
873  INIT_VARIABLE(jetW, "", 1.);
874  INIT_VARIABLE(etaW, "", 1.);
875  INIT_VARIABLE(phiW, "", 1.);
876 
877  INIT_VARIABLE(majW, "", 1.);
878  INIT_VARIABLE(minW, "", 1.);
879 
880  INIT_VARIABLE(frac01, "", 0.);
881  INIT_VARIABLE(frac02, "", 0.);
882  INIT_VARIABLE(frac03, "", 0.);
883  INIT_VARIABLE(frac04, "", 0.);
884  INIT_VARIABLE(frac05, "", 0.);
885  INIT_VARIABLE(frac06, "", 0.);
886  INIT_VARIABLE(frac07, "", 0.);
887 
888  INIT_VARIABLE(chFrac01, "", 0.);
889  INIT_VARIABLE(chFrac02, "", 0.);
890  INIT_VARIABLE(chFrac03, "", 0.);
891  INIT_VARIABLE(chFrac04, "", 0.);
892  INIT_VARIABLE(chFrac05, "", 0.);
893  INIT_VARIABLE(chFrac06, "", 0.);
894  INIT_VARIABLE(chFrac07, "", 0.);
895 
896  INIT_VARIABLE(neutFrac01, "", 0.);
897  INIT_VARIABLE(neutFrac02, "", 0.);
898  INIT_VARIABLE(neutFrac03, "", 0.);
899  INIT_VARIABLE(neutFrac04, "", 0.);
900  INIT_VARIABLE(neutFrac05, "", 0.);
901  INIT_VARIABLE(neutFrac06, "", 0.);
902  INIT_VARIABLE(neutFrac07, "", 0.);
903 
904  INIT_VARIABLE(emFrac01, "", 0.);
905  INIT_VARIABLE(emFrac02, "", 0.);
906  INIT_VARIABLE(emFrac03, "", 0.);
907  INIT_VARIABLE(emFrac04, "", 0.);
908  INIT_VARIABLE(emFrac05, "", 0.);
909  INIT_VARIABLE(emFrac06, "", 0.);
910  INIT_VARIABLE(emFrac07, "", 0.);
911 
912  INIT_VARIABLE(beta, "", 0.);
913  INIT_VARIABLE(betaStar, "", 0.);
914  INIT_VARIABLE(betaClassic, "", 0.);
915  INIT_VARIABLE(betaStarClassic, "", 0.);
916 
917  INIT_VARIABLE(nvtx, "", 0.);
918  INIT_VARIABLE(rho, "", 0.);
919  INIT_VARIABLE(nTrueInt, "", 0.);
920 
921  INIT_VARIABLE(jetR, "", 0.);
922  INIT_VARIABLE(jetRchg, "", 0.);
923  INIT_VARIABLE(dRMatch, "", 0.);
924 }
const float large_val
#define INIT_VARIABLE(NAME, TMVANAME, VAL)
PileupJetIdentifier internalId_
static constexpr float d0

◆ method()

const std::string PileupJetIdAlgo::method ( ) const
inline

Definition at line 42 of file PileupJetIdAlgo.h.

References cache_, and PileupJetIdAlgo::AlgoGBRForestsAndConstants::tmvaMethod().

42 { return cache_->tmvaMethod(); }
AlgoGBRForestsAndConstants const * cache_
std::string const & tmvaMethod() const

◆ resetVariables()

void PileupJetIdAlgo::resetVariables ( )
protected

Definition at line 781 of file PileupJetIdAlgo.cc.

References PileupJetIdentifier::idFlag_, internalId_, ALPAKA_ACCELERATOR_NAMESPACE::vertexFinder::it, and variables_.

Referenced by computeIdVariables().

781  {
782  internalId_.idFlag_ = 0;
783  for (variables_list_t::iterator it = variables_.begin(); it != variables_.end(); ++it) {
784  *it->second.first = it->second.second;
785  }
786 }
PileupJetIdentifier internalId_
variables_list_t variables_

◆ runMva()

void PileupJetIdAlgo::runMva ( )
protected

Definition at line 168 of file PileupJetIdAlgo.cc.

References funct::abs(), cache_, computeCutIDflag(), computeIDflag(), PileupJetIdAlgo::AlgoGBRForestsAndConstants::cutBased(), PileupJetIdAlgo::AlgoGBRForestsAndConstants::etaBinnedWeights(), PileupJetIdAlgo::AlgoGBRForestsAndConstants::etaReader(), getMVAval(), PileupJetIdentifier::idFlag_, internalId_, PileupJetIdAlgo::AlgoGBRForestsAndConstants::jEtaMax(), PileupJetIdAlgo::AlgoGBRForestsAndConstants::jEtaMin(), PileupJetIdentifier::mva_, PileupJetIdAlgo::AlgoGBRForestsAndConstants::nEtaBins(), PileupJetIdAlgo::AlgoGBRForestsAndConstants::reader(), PileupJetIdAlgo::AlgoGBRForestsAndConstants::tmvaEtaVariables(), PileupJetIdAlgo::AlgoGBRForestsAndConstants::tmvaVariables(), and findQualityFiles::v.

Referenced by computeIdVariables(), and computeMva().

168  {
169  if (cache_->cutBased()) {
171  internalId_.betaStarClassic_, internalId_.dR2Mean_, internalId_.nvtx_, internalId_.jetPt_, internalId_.jetEta_);
172  } else {
173  if (std::abs(internalId_.jetEta_) >= 5.0) {
174  internalId_.mva_ = -2.;
175  } else {
176  if (cache_->etaBinnedWeights()) {
177  if (std::abs(internalId_.jetEta_) > cache_->jEtaMax().at(cache_->nEtaBins() - 1)) {
178  internalId_.mva_ = -2.;
179  } else {
180  for (int v = 0; v < cache_->nEtaBins(); v++) {
181  if (std::abs(internalId_.jetEta_) >= cache_->jEtaMin().at(v) &&
182  std::abs(internalId_.jetEta_) < cache_->jEtaMax().at(v)) {
184  break;
185  }
186  }
187  }
188  } else {
190  }
191  }
193  }
194 }
std::vector< double > const & jEtaMin() const
AlgoGBRForestsAndConstants const * cache_
int computeCutIDflag(float betaStarClassic, float dR2Mean, float nvtx, float jetPt, float jetEta)
std::vector< std::vector< std::string > > const & tmvaEtaVariables() const
PileupJetIdentifier internalId_
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
std::vector< std::string > const & tmvaVariables() const
int computeIDflag(float mva, float jetPt, float jetEta)
std::vector< std::unique_ptr< const GBRForest > > const & etaReader() const
std::unique_ptr< const GBRForest > const & reader() const
std::vector< double > const & jEtaMax() const
float getMVAval(const std::vector< std::string > &, const std::unique_ptr< const GBRForest > &)

◆ set()

void PileupJetIdAlgo::set ( const PileupJetIdentifier id)

Definition at line 154 of file PileupJetIdAlgo.cc.

References l1ctLayer2EG_cff::id, and internalId_.

Referenced by PileupJetIdProducer::produce().

154 { internalId_ = id; }
PileupJetIdentifier internalId_

Member Data Documentation

◆ cache_

AlgoGBRForestsAndConstants const* PileupJetIdAlgo::cache_
protected

Definition at line 111 of file PileupJetIdAlgo.h.

Referenced by computeIDflag(), computeIdVariables(), method(), and runMva().

◆ internalId_

PileupJetIdentifier PileupJetIdAlgo::internalId_
protected

◆ variables_

variables_list_t PileupJetIdAlgo::variables_
protected

Definition at line 110 of file PileupJetIdAlgo.h.

Referenced by dumpVariables(), getMVAval(), getVariables(), and resetVariables().