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HLTEgamma Class Reference

#include <HLTEgamma.h>

Classes

struct  OpenHLTElectron
 
struct  OpenHLTPhoton
 

Public Member Functions

void analyze (const edm::Handle< reco::GsfElectronCollection > &electrons, const edm::Handle< reco::PhotonCollection > &photons, const edm::Handle< reco::ElectronCollection > &electronIsoHandle, const edm::Handle< reco::ElectronCollection > &electronNonIsoHandle, const edm::Handle< reco::ElectronIsolationMap > &NonIsoTrackEleIsolMap, const edm::Handle< reco::ElectronIsolationMap > &TrackEleIsolMap, const edm::Handle< reco::ElectronSeedCollection > &L1IsoPixelSeedsMap, const edm::Handle< reco::ElectronSeedCollection > &L1NonIsoPixelSeedsMap, const edm::Handle< reco::RecoEcalCandidateCollection > &recoIsolecalcands, const edm::Handle< reco::RecoEcalCandidateCollection > &recoNonIsolecalcands, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &EcalIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &EcalNonIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalEleIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalEleNonIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalNonIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &TrackIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &TrackNonIsolMap, EcalClusterLazyTools &lazyTools, const edm::ESHandle< MagneticField > &theMagField, reco::BeamSpot::Point &BSPosition, std::vector< edm::Handle< edm::ValueMap< float > > > &eIDValueMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9IsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9NonIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9IsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9NonIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonHoverEHIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonHoverEHNonIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9IDIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9IDNonIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9IDIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9IDNonIsoMap, const edm::Handle< reco::SuperClusterCollection > &electronHFClusterHandle, const edm::Handle< reco::RecoEcalCandidateCollection > &electronHFElectronHandle, const edm::Handle< reco::HFEMClusterShapeAssociationCollection > &electronHFClusterAssociation, const edm::Handle< reco::RecoEcalCandidateCollection > &activityECAL, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &activityEcalIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &activityHcalIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &activityTrackIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &activityR9Map, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &activityR9IDMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &activityHoverEHMap, TTree *tree)
 
void clear (void)
 
 HLTEgamma ()
 
void setup (const edm::ParameterSet &pSet, TTree *tree)
 

Private Member Functions

void CalculateDetaDphi (const edm::ESHandle< MagneticField > &theMagField, reco::BeamSpot::Point &BSPosition, const reco::ElectronRef eleref, float &deltaeta, float &deltaphi, bool useTrackProjectionToEcal)
 
void MakeL1IsolatedElectrons (std::vector< OpenHLTElectron > &electrons, const edm::Handle< reco::ElectronCollection > &electronIsoHandle, const edm::Handle< reco::RecoEcalCandidateCollection > &recoIsolecalcands, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalEleIsolMap, const edm::Handle< reco::ElectronSeedCollection > &L1IsoPixelSeedsMap, const edm::Handle< reco::ElectronIsolationMap > &TrackEleIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9IsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonHoverEHIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &EcalIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9IDIsoMap, EcalClusterLazyTools &lazyTools, const edm::ESHandle< MagneticField > &theMagField, reco::BeamSpot::Point &BSPosition)
 
void MakeL1IsolatedPhotons (std::vector< OpenHLTPhoton > &photons, const edm::Handle< reco::RecoEcalCandidateCollection > &recoIsolecalcands, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &EcalIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &TrackIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9IsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonHoverEHIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9IDIsoMap, EcalClusterLazyTools &lazyTools)
 
void MakeL1NonIsolatedElectrons (std::vector< OpenHLTElectron > &electrons, const edm::Handle< reco::ElectronCollection > &electronNonIsoHandle, const edm::Handle< reco::RecoEcalCandidateCollection > &recoNonIsolecalcands, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalEleIsolMap, const edm::Handle< reco::ElectronSeedCollection > &L1NonIsoPixelSeedsMap, const edm::Handle< reco::ElectronIsolationMap > &TrackEleIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9NonIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonHoverEHIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &EcalIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9IDNonIsoMap, EcalClusterLazyTools &lazyTools, const edm::ESHandle< MagneticField > &theMagField, reco::BeamSpot::Point &BSPosition)
 
void MakeL1NonIsolatedPhotons (std::vector< OpenHLTPhoton > &photons, const edm::Handle< reco::RecoEcalCandidateCollection > &recoNonIsolecalcands, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &EcalNonIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalNonIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &TrackNonIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9NonIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonHoverEHNonIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9IDNonIsoMap, EcalClusterLazyTools &lazyTools)
 

Private Attributes

float * eld0corr
 
float * eldcot
 
float * eldeltaEtaIn
 
float * eldeltaPhiIn
 
float * eldist
 
float * ele
 
float * elecaliso
 
float * elECaloIsoR03
 
int * eleId
 
float * elet
 
float * eleta
 
float * elFbrem
 
float * elhcaliso
 
float * elHCaloIsoR03
 
float * elhOverE
 
float * elIP
 
bool * elIsEcalDriven
 
int * elmishits
 
int * elNLostHits
 
float * elphi
 
float * elpt
 
bool * elqGsfCtfScPixConsistent
 
float * elscEt
 
float * elsigmaietaieta
 
float * elTrkChi2NDF
 
float * eltrkiso
 
float * elTrkIsoR03
 
float * hecalactivClusShap
 
float * hecalactiveiso
 
float * hecalactivet
 
float * hecalactiveta
 
float * hecalactivhiso
 
float * hecalactivhovereh
 
int * hecalactivl1iso
 
float * hecalactivphi
 
float * hecalactivR9
 
float * hecalactivR9ID
 
float * hecalactivtiso
 
float * heleClusShap
 
float * heleDeta
 
float * heleDphi
 
float * heleE
 
float * heleeiso
 
float * heleet
 
float * heleeta
 
float * helehiso
 
float * helehovereh
 
int * helel1iso
 
int * heleNewSC
 
float * helep
 
float * helephi
 
int * helePixelSeeds
 
float * heleR9
 
float * heleR9ID
 
float * heletiso
 
float * helevtxz
 
float * hhfcluster2Dcut
 
float * hhfclustere1e9
 
float * hhfclustere9e25
 
float * hhfclustereCOREe9
 
float * hhfclustereSeL
 
float * hhfclustereta
 
float * hhfclusterphi
 
float * hhfeleeta
 
float * hhfelept
 
float * hphotClusShap
 
float * hphoteiso
 
float * hphotet
 
float * hphoteta
 
float * hphothiso
 
float * hphothovereh
 
int * hphotl1iso
 
float * hphotphi
 
float * hphotR9
 
float * hphotR9ID
 
float * hphottiso
 
int nele
 
int nhltecalactiv
 
int nhltele
 
int nhltgam
 
int nhlthfeclus
 
int nhlthfele
 
int nphoton
 
float * photonClusShap
 
float * photone
 
float * photonecaliso
 
float * photonet
 
float * photoneta
 
float * photonhcaliso
 
float * photonhovere
 
float * photonphi
 
float * photonpt
 
float * photonr9id
 
float * photontrkiso
 

Detailed Description

$Date: November 2006 $Revision:

Author
P. Bargassa - Rice U.

Definition at line 62 of file HLTEgamma.h.

Constructor & Destructor Documentation

HLTEgamma::HLTEgamma ( )

Definition at line 34 of file HLTEgamma.cc.

34  {
35 }

Member Function Documentation

void HLTEgamma::analyze ( const edm::Handle< reco::GsfElectronCollection > &  electrons,
const edm::Handle< reco::PhotonCollection > &  photons,
const edm::Handle< reco::ElectronCollection > &  electronIsoHandle,
const edm::Handle< reco::ElectronCollection > &  electronNonIsoHandle,
const edm::Handle< reco::ElectronIsolationMap > &  NonIsoTrackEleIsolMap,
const edm::Handle< reco::ElectronIsolationMap > &  TrackEleIsolMap,
const edm::Handle< reco::ElectronSeedCollection > &  L1IsoPixelSeedsMap,
const edm::Handle< reco::ElectronSeedCollection > &  L1NonIsoPixelSeedsMap,
const edm::Handle< reco::RecoEcalCandidateCollection > &  recoIsolecalcands,
const edm::Handle< reco::RecoEcalCandidateCollection > &  recoNonIsolecalcands,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  EcalIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  EcalNonIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  HcalEleIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  HcalEleNonIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  HcalIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  HcalNonIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  TrackIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  TrackNonIsolMap,
EcalClusterLazyTools lazyTools,
const edm::ESHandle< MagneticField > &  theMagField,
reco::BeamSpot::Point BSPosition,
std::vector< edm::Handle< edm::ValueMap< float > > > &  eIDValueMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonR9IsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonR9NonIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  electronR9IsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  electronR9NonIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonHoverEHIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonHoverEHNonIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonR9IDIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonR9IDNonIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  electronR9IDIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  electronR9IDNonIsoMap,
const edm::Handle< reco::SuperClusterCollection > &  electronHFClusterHandle,
const edm::Handle< reco::RecoEcalCandidateCollection > &  electronHFElectronHandle,
const edm::Handle< reco::HFEMClusterShapeAssociationCollection > &  electronHFClusterAssociation,
const edm::Handle< reco::RecoEcalCandidateCollection > &  activityECAL,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  activityEcalIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  activityHcalIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  activityTrackIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  activityR9Map,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  activityR9IDMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  activityHoverEHMap,
TTree *  tree 
)

Analyze the Data

Definition at line 319 of file HLTEgamma.cc.

References clear(), reco::HFEMClusterShape::eCOREe9(), eld0corr, eldcot, eldeltaEtaIn, eldeltaPhiIn, eldist, ele, elecaliso, elECaloIsoR03, elet, eleta, elFbrem, elhcaliso, elHCaloIsoR03, elhOverE, elIP, elIsEcalDriven, elmishits, elNLostHits, reco::HFEMClusterShape::eLong1x1(), reco::HFEMClusterShape::eLong3x3(), reco::HFEMClusterShape::eLong5x5(), elphi, elpt, elqGsfCtfScPixConsistent, elscEt, elsigmaietaieta, elTrkChi2NDF, eltrkiso, elTrkIsoR03, reco::HFEMClusterShape::eSeL(), reco::CaloCluster::eta(), create_public_lumi_plots::exp, hecalactivClusShap, hecalactiveiso, hecalactivet, hecalactiveta, hecalactivhiso, hecalactivhovereh, hecalactivl1iso, hecalactivphi, hecalactivR9, hecalactivR9ID, hecalactivtiso, heleClusShap, heleDeta, heleDphi, heleE, heleeiso, heleet, heleeta, helehiso, helehovereh, helel1iso, heleNewSC, helep, helephi, helePixelSeeds, heleR9, heleR9ID, heletiso, helevtxz, hhfcluster2Dcut, hhfclustere1e9, hhfclustere9e25, hhfclustereCOREe9, hhfclustereSeL, hhfclustereta, hhfclusterphi, hhfeleeta, hhfelept, hphotClusShap, hphoteiso, hphotet, hphoteta, hphothiso, hphothovereh, hphotl1iso, hphotphi, hphotR9, hphotR9ID, hphottiso, i, edm::HandleBase::isValid(), MakeL1IsolatedElectrons(), MakeL1IsolatedPhotons(), MakeL1NonIsolatedElectrons(), MakeL1NonIsolatedPhotons(), reco::HitPattern::MISSING_INNER_HITS, nele, nhltecalactiv, nhltele, nhltgam, nhlthfeclus, nhlthfele, nphoton, reco::CaloCluster::phi(), photonClusShap, photone, photonecaliso, photonet, photoneta, photonhcaliso, photonhovere, photonphi, photonpt, photonr9id, photontrkiso, funct::sin(), and reco::RecoEcalCandidate::superCluster().

Referenced by HLTAnalyzer::analyze().

362 {
363  // reset the tree variables
364  clear();
365 
366  if (electrons.isValid()) {
367  reco::GsfElectronCollection myelectrons( electrons->begin(), electrons->end() );
368  nele = myelectrons.size();
369  std::sort(myelectrons.begin(), myelectrons.end(), EtGreater());
370  int iel = 0;
371  for (reco::GsfElectronCollection::const_iterator i = myelectrons.begin(); i != myelectrons.end(); i++) {
372  elpt[iel] = i->pt();
373  elphi[iel] = i->phi();
374  eleta[iel] = i->eta();
375  elet[iel] = i->et();
376  ele[iel] = i->energy();
377 
378  if(i->gsfTrack().isNonnull()){
379  elNLostHits[iel] = i->gsfTrack()->hitPattern().numberOfLostHits(reco::HitPattern::MISSING_INNER_HITS);
380  elIP[iel] = i->gsfTrack()->dxy(BSPosition);
381  elTrkChi2NDF[iel] = i->gsfTrack()->normalizedChi2();
382  }
383  else {
384  elNLostHits[iel] = -99.;
385  elIP[iel] = -99.;
386  elTrkChi2NDF[iel] = -99.;
387  }
388 
389  elTrkIsoR03[iel] = i->dr03TkSumPt();
390  elECaloIsoR03[iel] = i->dr03EcalRecHitSumEt();
391  elHCaloIsoR03[iel] = i->dr03HcalTowerSumEt();
392  elIsEcalDriven[iel] = i->ecalDrivenSeed();
393  elFbrem[iel] = i->fbrem();
394  elscEt[iel] = i->superCluster()->energy()*sin((2*atan(exp(-i->superCluster()->eta()))));
395  elhOverE[iel] = i->hadronicOverEm();
396  elsigmaietaieta[iel] = i->sigmaIetaIeta();
397  eldeltaPhiIn[iel] = i->deltaPhiSuperClusterTrackAtVtx();
398  eldeltaEtaIn[iel] = i->deltaEtaSuperClusterTrackAtVtx();
399  elmishits[iel] = i->gsfTrack()->hitPattern().numberOfHits(reco::HitPattern::MISSING_INNER_HITS);
400  eltrkiso[iel] = i->dr03TkSumPt();
401  elecaliso[iel] = i->dr03EcalRecHitSumEt();
402  elhcaliso[iel] = i->dr03HcalTowerSumEt();
403  eld0corr[iel]= - (i->gsfTrack()->dxy(BSPosition));
404  elqGsfCtfScPixConsistent[iel]=i->isGsfCtfScPixChargeConsistent();;
405 
406  // conversion info will be available after 3_10_X
407  eldist[iel] = 0;// fabs(i->convDist());
408  eldcot[iel] = 0; //fabs(i->convDcot());
409 
410  iel++;
411  }
412  } else {
413  nele = 0;
414  }
415 
416  if (photons.isValid()) {
417  reco::PhotonCollection myphotons(* photons);
418  nphoton = myphotons.size();
419  std::sort(myphotons.begin(), myphotons.end(), EtGreater());
420  int ipho = 0;
421  for (reco::PhotonCollection::const_iterator i = myphotons.begin(); i!= myphotons.end(); i++) {
422  photonpt[ipho] = i->pt();
423  photonphi[ipho] = i->phi();
424  photoneta[ipho] = i->eta();
425  photonet[ipho] = i->et();
426  photone[ipho] = i->energy();
427  photontrkiso[ipho] = i->trkSumPtSolidConeDR04();
428  photonecaliso[ipho] = i->ecalRecHitSumEtConeDR04();
429  photonhcaliso[ipho] = i->hcalTowerSumEtConeDR04();
430  photonhovere[ipho] = i->hadronicOverEm();
431  photonClusShap[ipho] = i->sigmaIetaIeta();
432  photonr9id[ipho] = i->r9();
433  ipho++;
434  }
435  } else {
436  nphoton = 0;
437  }
438 
440 
442  std::vector<OpenHLTPhoton> theHLTPhotons;
444  theHLTPhotons,
445  recoIsolecalcands,
446  EcalIsolMap,
447  HcalIsolMap,
448  TrackIsolMap,
449  photonR9IsoMap,
450  photonHoverEHIsoMap,
451  photonR9IDIsoMap,
452  lazyTools);
454  theHLTPhotons,
455  recoNonIsolecalcands,
456  EcalNonIsolMap,
457  HcalNonIsolMap,
458  TrackNonIsolMap,
459  photonR9NonIsoMap,
460  photonHoverEHNonIsoMap,
461  photonR9IDNonIsoMap,
462  lazyTools);
463 
464  std::sort(theHLTPhotons.begin(), theHLTPhotons.end(), EtGreater());
465  nhltgam = theHLTPhotons.size();
466 
467  for (int u = 0; u < nhltgam; u++) {
468  hphotet[u] = theHLTPhotons[u].Et;
469  hphoteta[u] = theHLTPhotons[u].eta;
470  hphotphi[u] = theHLTPhotons[u].phi;
471  hphoteiso[u] = theHLTPhotons[u].ecalIsol;
472  hphothiso[u] = theHLTPhotons[u].hcalIsol;
473  hphottiso[u] = theHLTPhotons[u].trackIsol;
474  hphotl1iso[u] = theHLTPhotons[u].L1Isolated;
475  hphotClusShap[u] = theHLTPhotons[u].clusterShape;
476  hphothovereh[u] = theHLTPhotons[u].hovereh;
477  hphotR9[u] = theHLTPhotons[u].r9;
478  hphotR9ID[u] = theHLTPhotons[u].r9ID;
479  }
480  // Activity
481  std::vector<OpenHLTPhoton> theHLTActivityPhotons;
483  theHLTActivityPhotons,
484  activityECAL,
485  activityEcalIsoMap,
486  activityHcalIsoMap,
487  activityTrackIsoMap,
488  activityR9Map,
489  activityHoverEHMap,
490  activityR9IDMap,
491  lazyTools);
492 
493  std::sort(theHLTActivityPhotons.begin(), theHLTActivityPhotons.end(), EtGreater());
494  nhltecalactiv = theHLTActivityPhotons.size();
495 
496  for (int u = 0; u < nhltecalactiv; u++) {
497  hecalactivet[u] = theHLTActivityPhotons[u].Et;
498  hecalactiveta[u] = theHLTActivityPhotons[u].eta;
499  hecalactivphi[u] = theHLTActivityPhotons[u].phi;
500  hecalactiveiso[u] = theHLTActivityPhotons[u].ecalIsol;
501  hecalactivhiso[u] = theHLTActivityPhotons[u].hcalIsol;
502  hecalactivtiso[u] = theHLTActivityPhotons[u].trackIsol;
503  hecalactivl1iso[u] = theHLTActivityPhotons[u].L1Isolated;
504  hecalactivClusShap[u] = theHLTActivityPhotons[u].clusterShape;
505  hecalactivhovereh[u] = theHLTActivityPhotons[u].hovereh;
506  hecalactivR9[u] = theHLTActivityPhotons[u].r9;
507  hecalactivR9ID[u] = theHLTActivityPhotons[u].r9ID;
508  }
509 
511  std::vector<OpenHLTElectron> theHLTElectrons;
513  theHLTElectrons,
514  electronIsoHandle,
515  recoIsolecalcands,
516  HcalEleIsolMap,
517  L1IsoPixelSeedsMap,
518  TrackEleIsolMap,
519  electronR9IsoMap,
520  photonHoverEHIsoMap,
521  EcalIsolMap,
522  electronR9IDIsoMap,
523  lazyTools,
524  theMagField,
525  BSPosition);
527  theHLTElectrons,
528  electronNonIsoHandle,
529  recoNonIsolecalcands,
530  HcalEleNonIsolMap,
531  L1NonIsoPixelSeedsMap,
532  NonIsoTrackEleIsolMap,
533  electronR9NonIsoMap,
534  photonHoverEHNonIsoMap,
535  EcalNonIsolMap,
536  electronR9IDNonIsoMap,
537  lazyTools,
538  theMagField,
539  BSPosition);
540 
541  std::sort(theHLTElectrons.begin(), theHLTElectrons.end(), EtGreater());
542  nhltele = theHLTElectrons.size();
543 
544  for (int u = 0; u < nhltele; u++) {
545  heleet[u] = theHLTElectrons[u].Et;
546  heleeta[u] = theHLTElectrons[u].eta;
547  helephi[u] = theHLTElectrons[u].phi;
548  helevtxz[u] = theHLTElectrons[u].vtxZ;
549  heleE[u] = theHLTElectrons[u].E;
550  helep[u] = theHLTElectrons[u].p;
551  helehiso[u] = theHLTElectrons[u].hcalIsol;
552  helePixelSeeds[u] = theHLTElectrons[u].pixelSeeds;
553  heletiso[u] = theHLTElectrons[u].trackIsol;
554  heleeiso[u] = theHLTElectrons[u].ecalIsol;
555  helel1iso[u] = theHLTElectrons[u].L1Isolated;
556  heleNewSC[u] = theHLTElectrons[u].newSC;
557  heleClusShap[u] = theHLTElectrons[u].clusterShape;
558  heleDeta[u] = theHLTElectrons[u].Deta;
559  heleDphi[u] = theHLTElectrons[u].Dphi;
560  heleR9[u] = theHLTElectrons[u].r9;
561  helehovereh[u] = theHLTElectrons[u].hovereh;
562  heleR9ID[u] = theHLTElectrons[u].r9ID;
563  }
564 
565  if(electronHFElectrons.isValid()) {
566  for (reco::RecoEcalCandidateCollection::const_iterator hfelecand = electronHFElectrons->begin(); hfelecand!=electronHFElectrons->end(); hfelecand++) {
567  hhfelept[nhlthfele] = hfelecand->pt();
568  hhfeleeta[nhlthfele] = hfelecand->eta();
569 
570  nhlthfele++;
571 
572  if(electronHFECALClusters.isValid()) {
573 
574  const reco::RecoEcalCandidate& HFcan = (*hfelecand);
575  reco::SuperClusterRef theClusRef=HFcan.superCluster();
576  const reco::SuperCluster& hfECALSuperCluster=*theClusRef;
577  const reco::HFEMClusterShapeRef clusShapeRef=(*electronHFClusterAssociation).find(theClusRef)->val;
578  const reco::HFEMClusterShape& clusShape=*clusShapeRef;
579 
580 
581  float hfCluster2Dcut =(clusShape.eCOREe9()-(clusShape.eSeL()*1.125));
582  float hfClustere9e25 = clusShape.eLong3x3()/clusShape.eLong5x5();
583  float hfClustere1e9 = clusShape.eLong1x1()/clusShape.eLong3x3();
584  float hfClustereCOREe9 = clusShape.eCOREe9();
585  float hfClustereSeL = clusShape.eSeL();
586 
587  hhfcluster2Dcut[nhlthfeclus] = hfCluster2Dcut;
588  hhfclustere9e25[nhlthfeclus] = hfClustere9e25;
589  hhfclustere1e9[nhlthfeclus] = hfClustere1e9;
590  hhfclustereCOREe9[nhlthfeclus] = hfClustereCOREe9;
591  hhfclustereSeL[nhlthfeclus] = hfClustereSeL;
592  hhfclustereta[nhlthfeclus] = hfECALSuperCluster.eta();
593  hhfclusterphi[nhlthfeclus] = hfECALSuperCluster.phi();
594 
595  } else {
596 
602  hhfclustereta[nhlthfeclus] = 0.0;
603  hhfclusterphi[nhlthfeclus] = 0.0;
604 
605  }
606 
607  nhlthfeclus++;
608  }
609  }
610 }
float * eldcot
Definition: HLTEgamma.h:188
float * elet
Definition: HLTEgamma.h:182
float * hphothovereh
Definition: HLTEgamma.h:193
int i
Definition: DBlmapReader.cc:9
int * helel1iso
Definition: HLTEgamma.h:200
float * hecalactivhovereh
Definition: HLTEgamma.h:192
float * hphotR9
Definition: HLTEgamma.h:199
float * helephi
Definition: HLTEgamma.h:194
float * photonhovere
Definition: HLTEgamma.h:190
int nhltele
Definition: HLTEgamma.h:204
float * helehovereh
Definition: HLTEgamma.h:194
int * hecalactivl1iso
Definition: HLTEgamma.h:200
float * elTrkIsoR03
Definition: HLTEgamma.h:182
float * eltrkiso
Definition: HLTEgamma.h:183
float * elTrkChi2NDF
Definition: HLTEgamma.h:182
void MakeL1NonIsolatedElectrons(std::vector< OpenHLTElectron > &electrons, const edm::Handle< reco::ElectronCollection > &electronNonIsoHandle, const edm::Handle< reco::RecoEcalCandidateCollection > &recoNonIsolecalcands, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalEleIsolMap, const edm::Handle< reco::ElectronSeedCollection > &L1NonIsoPixelSeedsMap, const edm::Handle< reco::ElectronIsolationMap > &TrackEleIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9NonIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonHoverEHIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &EcalIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9IDNonIsoMap, EcalClusterLazyTools &lazyTools, const edm::ESHandle< MagneticField > &theMagField, reco::BeamSpot::Point &BSPosition)
Definition: HLTEgamma.cc:935
double eLong5x5() const
float * elIP
Definition: HLTEgamma.h:182
float * heleDeta
Definition: HLTEgamma.h:198
double eLong1x1() const
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
int nhltecalactiv
Definition: HLTEgamma.h:204
float * photonphi
Definition: HLTEgamma.h:189
float * hhfclustereCOREe9
Definition: HLTEgamma.h:207
float * eldist
Definition: HLTEgamma.h:188
float * hphottiso
Definition: HLTEgamma.h:193
float * elphi
Definition: HLTEgamma.h:182
float * heleClusShap
Definition: HLTEgamma.h:198
virtual reco::SuperClusterRef superCluster() const
reference to a superCluster
float * photonecaliso
Definition: HLTEgamma.h:190
float * heleDphi
Definition: HLTEgamma.h:198
float * hphotet
Definition: HLTEgamma.h:193
float * photonr9id
Definition: HLTEgamma.h:190
std::vector< GsfElectron > GsfElectronCollection
collection of GsfElectron objects
float * hhfclustere1e9
Definition: HLTEgamma.h:207
double eta() const
pseudorapidity of cluster centroid
Definition: CaloCluster.h:163
float * photonet
Definition: HLTEgamma.h:189
float * elhOverE
Definition: HLTEgamma.h:184
float * hhfclusterphi
Definition: HLTEgamma.h:206
float * hhfcluster2Dcut
Definition: HLTEgamma.h:206
float * photonpt
Definition: HLTEgamma.h:189
float * hphoteiso
Definition: HLTEgamma.h:193
int * helePixelSeeds
Definition: HLTEgamma.h:200
float * ele
Definition: HLTEgamma.h:182
float * photonClusShap
Definition: HLTEgamma.h:190
float * elECaloIsoR03
Definition: HLTEgamma.h:182
float * heleeiso
Definition: HLTEgamma.h:194
float * elpt
Definition: HLTEgamma.h:182
float * elscEt
Definition: HLTEgamma.h:185
float * helehiso
Definition: HLTEgamma.h:194
float * photontrkiso
Definition: HLTEgamma.h:190
double eLong3x3() const
float * elHCaloIsoR03
Definition: HLTEgamma.h:182
float * heleet
Definition: HLTEgamma.h:194
float * eld0corr
Definition: HLTEgamma.h:185
float * hhfelept
Definition: HLTEgamma.h:206
float * heleeta
Definition: HLTEgamma.h:194
float * hecalactivR9ID
Definition: HLTEgamma.h:199
bool isValid() const
Definition: HandleBase.h:75
int nhlthfeclus
Definition: HLTEgamma.h:204
float * hphoteta
Definition: HLTEgamma.h:193
int * elmishits
Definition: HLTEgamma.h:187
int * heleNewSC
Definition: HLTEgamma.h:203
float * eleta
Definition: HLTEgamma.h:182
float * hhfclustereta
Definition: HLTEgamma.h:206
float * elsigmaietaieta
Definition: HLTEgamma.h:184
float * hhfeleeta
Definition: HLTEgamma.h:206
float * heleE
Definition: HLTEgamma.h:194
float * photone
Definition: HLTEgamma.h:189
float * eldeltaPhiIn
Definition: HLTEgamma.h:184
float * hecalactivtiso
Definition: HLTEgamma.h:192
int * hphotl1iso
Definition: HLTEgamma.h:200
std::vector< Photon > PhotonCollection
collectin of Photon objects
Definition: PhotonFwd.h:9
float * helep
Definition: HLTEgamma.h:194
void MakeL1IsolatedElectrons(std::vector< OpenHLTElectron > &electrons, const edm::Handle< reco::ElectronCollection > &electronIsoHandle, const edm::Handle< reco::RecoEcalCandidateCollection > &recoIsolecalcands, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalEleIsolMap, const edm::Handle< reco::ElectronSeedCollection > &L1IsoPixelSeedsMap, const edm::Handle< reco::ElectronIsolationMap > &TrackEleIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9IsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonHoverEHIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &EcalIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &electronR9IDIsoMap, EcalClusterLazyTools &lazyTools, const edm::ESHandle< MagneticField > &theMagField, reco::BeamSpot::Point &BSPosition)
Definition: HLTEgamma.cc:776
float * hphotR9ID
Definition: HLTEgamma.h:199
float * hecalactiveta
Definition: HLTEgamma.h:192
float * photonhcaliso
Definition: HLTEgamma.h:190
float * photoneta
Definition: HLTEgamma.h:189
int nhltgam
Definition: HLTEgamma.h:204
float * hecalactivClusShap
Definition: HLTEgamma.h:198
float * hphothiso
Definition: HLTEgamma.h:193
float * hecalactivhiso
Definition: HLTEgamma.h:192
int * elNLostHits
Definition: HLTEgamma.h:201
bool * elIsEcalDriven
Definition: HLTEgamma.h:202
float * hecalactivphi
Definition: HLTEgamma.h:192
float * hecalactivR9
Definition: HLTEgamma.h:199
float * elecaliso
Definition: HLTEgamma.h:183
int nphoton
Definition: HLTEgamma.h:204
float * hphotClusShap
Definition: HLTEgamma.h:198
float * hhfclustere9e25
Definition: HLTEgamma.h:206
double phi() const
azimuthal angle of cluster centroid
Definition: CaloCluster.h:166
bool * elqGsfCtfScPixConsistent
Definition: HLTEgamma.h:186
int nele
Definition: HLTEgamma.h:204
void MakeL1NonIsolatedPhotons(std::vector< OpenHLTPhoton > &photons, const edm::Handle< reco::RecoEcalCandidateCollection > &recoNonIsolecalcands, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &EcalNonIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalNonIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &TrackNonIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9NonIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonHoverEHNonIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9IDNonIsoMap, EcalClusterLazyTools &lazyTools)
Definition: HLTEgamma.cc:697
float * heletiso
Definition: HLTEgamma.h:194
float * hecalactivet
Definition: HLTEgamma.h:192
float * hhfclustereSeL
Definition: HLTEgamma.h:207
void MakeL1IsolatedPhotons(std::vector< OpenHLTPhoton > &photons, const edm::Handle< reco::RecoEcalCandidateCollection > &recoIsolecalcands, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &EcalIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &HcalIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &TrackIsolMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9IsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonHoverEHIsoMap, const edm::Handle< reco::RecoEcalCandidateIsolationMap > &photonR9IDIsoMap, EcalClusterLazyTools &lazyTools)
Definition: HLTEgamma.cc:612
float * hecalactiveiso
Definition: HLTEgamma.h:192
int nhlthfele
Definition: HLTEgamma.h:204
float * hphotphi
Definition: HLTEgamma.h:193
float * heleR9
Definition: HLTEgamma.h:199
float * elhcaliso
Definition: HLTEgamma.h:183
float * eldeltaEtaIn
Definition: HLTEgamma.h:184
float * elFbrem
Definition: HLTEgamma.h:182
float * helevtxz
Definition: HLTEgamma.h:194
void clear(void)
Definition: HLTEgamma.cc:244
float * heleR9ID
Definition: HLTEgamma.h:199
void HLTEgamma::CalculateDetaDphi ( const edm::ESHandle< MagneticField > &  theMagField,
reco::BeamSpot::Point BSPosition,
const reco::ElectronRef  eleref,
float &  deltaeta,
float &  deltaphi,
bool  useTrackProjectionToEcal 
)
private

Definition at line 1094 of file HLTEgamma.cc.

References ECALPositionCalculator::ecalPhi(), and edm::ESHandle< class >::product().

Referenced by MakeL1IsolatedElectrons(), and MakeL1NonIsolatedElectrons().

1099  {
1100 
1101  const reco::SuperClusterRef theClus = eleref->superCluster();
1102  math::XYZVector scv(theClus->x(), theClus->y(), theClus->z());
1103 
1104  const math::XYZVector trackMom = eleref->track()->momentum();
1105 
1106  math::XYZPoint SCcorrPosition(theClus->x()-BSPosition.x(), theClus->y()-BSPosition.y() , theClus->z()-eleref->track()->vz() );
1107  deltaeta = SCcorrPosition.eta()-eleref->track()->eta();
1108 
1109  if(useTrackProjectionToEcal){
1110  ECALPositionCalculator posCalc;
1111  const math::XYZPoint vertex(BSPosition.x(),BSPosition.y(),eleref->track()->vz());
1112 
1113  float phi1= posCalc.ecalPhi(theMagField.product(),trackMom,vertex,1);
1114  float phi2= posCalc.ecalPhi(theMagField.product(),trackMom,vertex,-1);
1115 
1116  float deltaphi1=fabs( phi1 - theClus->position().phi() );
1117  if(deltaphi1>6.283185308) deltaphi1 -= 6.283185308;
1118  if(deltaphi1>3.141592654) deltaphi1 = 6.283185308-deltaphi1;
1119 
1120  float deltaphi2=fabs( phi2 - theClus->position().phi() );
1121  if(deltaphi2>6.283185308) deltaphi2 -= 6.283185308;
1122  if(deltaphi2>3.141592654) deltaphi2 = 6.283185308-deltaphi2;
1123 
1124  deltaphi = deltaphi1;
1125  if(deltaphi2<deltaphi1){ deltaphi = deltaphi2;}
1126  }
1127  else {
1128  deltaphi=fabs(eleref->track()->outerPosition().phi()-theClus->phi());
1129  if(deltaphi>6.283185308) deltaphi -= 6.283185308;
1130  if(deltaphi>3.141592654) deltaphi = 6.283185308-deltaphi;
1131  }
1132 
1133  }
double ecalPhi(const MagneticField *magField, const math::XYZVector &momentum, const math::XYZPoint &vertex, const int charge)
XYZVectorD XYZVector
spatial vector with cartesian internal representation
Definition: Vector3D.h:30
XYZPointD XYZPoint
point in space with cartesian internal representation
Definition: Point3D.h:12
T const * product() const
Definition: ESHandle.h:86
void HLTEgamma::clear ( void  )

Definition at line 244 of file HLTEgamma.cc.

References ele, elECaloIsoR03, elet, eleta, elFbrem, elHCaloIsoR03, elIP, elIsEcalDriven, elNLostHits, elphi, elpt, elTrkChi2NDF, elTrkIsoR03, heleClusShap, heleDeta, heleDphi, heleE, heleeiso, heleet, heleeta, helehiso, helehovereh, helel1iso, heleNewSC, helep, helephi, helePixelSeeds, heletiso, helevtxz, hhfcluster2Dcut, hhfclustere1e9, hhfclustere9e25, hhfclustereCOREe9, hhfclustereSeL, hhfclustereta, hhfclusterphi, hhfeleeta, hhfelept, hphotClusShap, hphoteiso, hphotet, hphoteta, hphothiso, hphotl1iso, hphotphi, hphottiso, kMaxEl, kMaxhEle, kMaxhPhot, kMaxPhot, nele, nhltele, nhltgam, nhlthfeclus, nhlthfele, nphoton, photonClusShap, photone, photonecaliso, photonet, photoneta, photonhcaliso, photonhovere, photonphi, photonpt, photonr9id, and photontrkiso.

Referenced by analyze().

245 {
246  std::memset(elpt, '\0', kMaxEl * sizeof(float));
247  std::memset(elphi, '\0', kMaxEl * sizeof(float));
248  std::memset(eleta, '\0', kMaxEl * sizeof(float));
249  std::memset(elet, '\0', kMaxEl * sizeof(float));
250  std::memset(ele, '\0', kMaxEl * sizeof(float));
251  std::memset(ele, '\0', kMaxEl * sizeof(int));
252  std::memset(elIP, '\0', kMaxEl * sizeof(float));
253  std::memset(elNLostHits, '\0', kMaxEl * sizeof(int));
254  std::memset(elTrkChi2NDF, '\0', kMaxEl * sizeof(float));
255  std::memset(elTrkIsoR03, '\0', kMaxEl * sizeof(float));
256  std::memset(elECaloIsoR03, '\0', kMaxEl * sizeof(float));
257  std::memset(elHCaloIsoR03, '\0', kMaxEl * sizeof(float));
258  std::memset(elIsEcalDriven, '\0', kMaxEl * sizeof(bool));
259  std::memset(elFbrem, '\0', kMaxEl * sizeof(float));
260 
261  std::memset(photonpt, '\0', kMaxPhot * sizeof(float));
262  std::memset(photonphi, '\0', kMaxPhot * sizeof(float));
263  std::memset(photoneta, '\0', kMaxPhot * sizeof(float));
264  std::memset(photonet, '\0', kMaxPhot * sizeof(float));
265  std::memset(photone, '\0', kMaxPhot * sizeof(float));
266  std::memset(photontrkiso, '\0', kMaxPhot * sizeof(float));
267  std::memset(photonecaliso, '\0', kMaxPhot * sizeof(float));
268  std::memset(photonhcaliso, '\0', kMaxPhot * sizeof(float));
269  std::memset(photonhovere, '\0', kMaxPhot * sizeof(float));
270  std::memset(photonClusShap, '\0', kMaxPhot * sizeof(float));
271  std::memset(photonr9id, '\0', kMaxPhot * sizeof(float));
272 
273  std::memset(hphotet, '\0', kMaxhPhot * sizeof(float));
274  std::memset(hphoteta, '\0', kMaxhPhot * sizeof(float));
275  std::memset(hphotphi, '\0', kMaxhPhot * sizeof(float));
276  std::memset(helevtxz, '\0', kMaxhEle * sizeof(float));
277  std::memset(hphoteiso, '\0', kMaxhPhot * sizeof(float));
278  std::memset(hphothiso, '\0', kMaxhPhot * sizeof(float));
279  std::memset(hphottiso, '\0', kMaxhPhot * sizeof(float));
280  std::memset(hphotl1iso, '\0', kMaxhPhot * sizeof(int));
281  std::memset(hphotClusShap, '\0', kMaxhPhot * sizeof(float));
282 
283  std::memset(heleet, '\0', kMaxhEle * sizeof(float));
284  std::memset(heleeta, '\0', kMaxhEle * sizeof(float));
285  std::memset(helephi, '\0', kMaxhEle * sizeof(float));
286  std::memset(heleE, '\0', kMaxhEle * sizeof(float));
287  std::memset(helep, '\0', kMaxhEle * sizeof(float));
288  std::memset(helehiso, '\0', kMaxhEle * sizeof(float));
289  std::memset(heletiso, '\0', kMaxhEle * sizeof(float));
290  std::memset(heleeiso, '\0', kMaxhEle * sizeof(float));
291  std::memset(helehovereh, '\0', kMaxhEle * sizeof(float));
292  std::memset(helel1iso, '\0', kMaxhEle * sizeof(int));
293  std::memset(helePixelSeeds, '\0', kMaxhEle * sizeof(int));
294  std::memset(heleNewSC, '\0', kMaxhEle * sizeof(int));
295  std::memset(heleClusShap, '\0', kMaxhEle * sizeof(float));
296  std::memset(heleDeta, '\0', kMaxhEle * sizeof(float));
297  std::memset(heleDphi, '\0', kMaxhEle * sizeof(float));
298 
299  std::memset(hhfelept, '\0', kMaxhEle * sizeof(float));
300  std::memset(hhfeleeta, '\0', kMaxhEle * sizeof(float));
301 
302  std::memset(hhfclustere9e25, '\0', kMaxhEle * sizeof(float));
303  std::memset(hhfclustere1e9, '\0', kMaxhEle * sizeof(float));
304  std::memset(hhfclustereCOREe9, '\0', kMaxhEle * sizeof(float));
305  std::memset(hhfclustereSeL, '\0', kMaxhEle * sizeof(float));
306  std::memset(hhfcluster2Dcut, '\0', kMaxhEle * sizeof(float));
307  std::memset(hhfclustereta, '\0', kMaxhEle * sizeof(float));
308  std::memset(hhfclusterphi, '\0', kMaxhEle * sizeof(float));
309 
310  nele = 0;
311  nphoton = 0;
312  nhltgam = 0;
313  nhltele = 0;
314  nhlthfele = 0;
315  nhlthfeclus = 0;
316 }
float * elet
Definition: HLTEgamma.h:182
int * helel1iso
Definition: HLTEgamma.h:200
float * helephi
Definition: HLTEgamma.h:194
float * photonhovere
Definition: HLTEgamma.h:190
int nhltele
Definition: HLTEgamma.h:204
float * helehovereh
Definition: HLTEgamma.h:194
float * elTrkIsoR03
Definition: HLTEgamma.h:182
float * elTrkChi2NDF
Definition: HLTEgamma.h:182
float * elIP
Definition: HLTEgamma.h:182
float * heleDeta
Definition: HLTEgamma.h:198
float * photonphi
Definition: HLTEgamma.h:189
float * hhfclustereCOREe9
Definition: HLTEgamma.h:207
float * hphottiso
Definition: HLTEgamma.h:193
float * elphi
Definition: HLTEgamma.h:182
float * heleClusShap
Definition: HLTEgamma.h:198
float * photonecaliso
Definition: HLTEgamma.h:190
float * heleDphi
Definition: HLTEgamma.h:198
float * hphotet
Definition: HLTEgamma.h:193
float * photonr9id
Definition: HLTEgamma.h:190
float * hhfclustere1e9
Definition: HLTEgamma.h:207
float * photonet
Definition: HLTEgamma.h:189
static const size_t kMaxhPhot
Definition: HLTEgamma.cc:31
float * hhfclusterphi
Definition: HLTEgamma.h:206
float * hhfcluster2Dcut
Definition: HLTEgamma.h:206
float * photonpt
Definition: HLTEgamma.h:189
float * hphoteiso
Definition: HLTEgamma.h:193
int * helePixelSeeds
Definition: HLTEgamma.h:200
float * ele
Definition: HLTEgamma.h:182
float * photonClusShap
Definition: HLTEgamma.h:190
float * elECaloIsoR03
Definition: HLTEgamma.h:182
float * heleeiso
Definition: HLTEgamma.h:194
float * elpt
Definition: HLTEgamma.h:182
float * helehiso
Definition: HLTEgamma.h:194
float * photontrkiso
Definition: HLTEgamma.h:190
float * elHCaloIsoR03
Definition: HLTEgamma.h:182
float * heleet
Definition: HLTEgamma.h:194
float * hhfelept
Definition: HLTEgamma.h:206
float * heleeta
Definition: HLTEgamma.h:194
int nhlthfeclus
Definition: HLTEgamma.h:204
float * hphoteta
Definition: HLTEgamma.h:193
int * heleNewSC
Definition: HLTEgamma.h:203
static const size_t kMaxEl
Definition: HLTEgamma.cc:29
float * eleta
Definition: HLTEgamma.h:182
static const size_t kMaxhEle
Definition: HLTEgamma.cc:32
float * hhfclustereta
Definition: HLTEgamma.h:206
float * hhfeleeta
Definition: HLTEgamma.h:206
float * heleE
Definition: HLTEgamma.h:194
float * photone
Definition: HLTEgamma.h:189
int * hphotl1iso
Definition: HLTEgamma.h:200
float * helep
Definition: HLTEgamma.h:194
float * photonhcaliso
Definition: HLTEgamma.h:190
float * photoneta
Definition: HLTEgamma.h:189
int nhltgam
Definition: HLTEgamma.h:204
float * hphothiso
Definition: HLTEgamma.h:193
int * elNLostHits
Definition: HLTEgamma.h:201
bool * elIsEcalDriven
Definition: HLTEgamma.h:202
int nphoton
Definition: HLTEgamma.h:204
float * hphotClusShap
Definition: HLTEgamma.h:198
static const size_t kMaxPhot
Definition: HLTEgamma.cc:30
float * hhfclustere9e25
Definition: HLTEgamma.h:206
int nele
Definition: HLTEgamma.h:204
float * heletiso
Definition: HLTEgamma.h:194
float * hhfclustereSeL
Definition: HLTEgamma.h:207
int nhlthfele
Definition: HLTEgamma.h:204
float * hphotphi
Definition: HLTEgamma.h:193
float * elFbrem
Definition: HLTEgamma.h:182
float * helevtxz
Definition: HLTEgamma.h:194
void HLTEgamma::MakeL1IsolatedElectrons ( std::vector< OpenHLTElectron > &  electrons,
const edm::Handle< reco::ElectronCollection > &  electronIsoHandle,
const edm::Handle< reco::RecoEcalCandidateCollection > &  recoIsolecalcands,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  HcalEleIsolMap,
const edm::Handle< reco::ElectronSeedCollection > &  L1IsoPixelSeedsMap,
const edm::Handle< reco::ElectronIsolationMap > &  TrackEleIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  electronR9IsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonHoverEHIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  EcalIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  electronR9IDIsoMap,
EcalClusterLazyTools lazyTools,
const edm::ESHandle< MagneticField > &  theMagField,
reco::BeamSpot::Point BSPosition 
)
private

Definition at line 776 of file HLTEgamma.cc.

References CalculateDetaDphi(), edm::RefToBase< T >::castTo(), HLTEgamma::OpenHLTElectron::clusterShape, edm::AssociationMap< edm::OneToValue< std::vector< reco::RecoEcalCandidate >, float > >::const_iterator, edm::AssociationMap< edm::OneToValue< std::vector< reco::Electron >, float > >::const_iterator, HLTEgamma::OpenHLTElectron::Deta, HLT_25ns10e33_v2_cff::distance, HLTEgamma::OpenHLTElectron::Dphi, HLTEgamma::OpenHLTElectron::E, HLTEgamma::OpenHLTElectron::ecalIsol, ele, HLTEgamma::OpenHLTElectron::Et, HLTEgamma::OpenHLTElectron::eta, HLTEgamma::OpenHLTElectron::hcalIsol, HLTEgamma::OpenHLTElectron::hovereh, edm::HandleBase::isValid(), HLTEgamma::OpenHLTElectron::L1Isolated, HLTEgamma::OpenHLTElectron::newSC, HLTEgamma::OpenHLTElectron::p, HLTEgamma::OpenHLTElectron::phi, HLTEgamma::OpenHLTElectron::pixelSeeds, HLTEgamma::OpenHLTElectron::r9, HLTEgamma::OpenHLTElectron::r9ID, mathSSE::sqrt(), HLTEgamma::OpenHLTElectron::trackIsol, and HLTEgamma::OpenHLTElectron::vtxZ.

Referenced by analyze().

790  {
791  // if there are electrons, then the isolation maps and the SC should be in the event; if not it is an error
792  if (recoIsolecalcands.isValid()) {
793  for (reco::RecoEcalCandidateCollection::const_iterator recoecalcand = recoIsolecalcands->begin();
794  recoecalcand!= recoIsolecalcands->end(); recoecalcand++) {
795  // get the ref to the SC:
796  reco::RecoEcalCandidateRef ref = reco::RecoEcalCandidateRef(recoIsolecalcands, distance(recoIsolecalcands->begin(), recoecalcand));
797  reco::SuperClusterRef recrSC = ref->superCluster();
798  //reco::SuperClusterRef recrSC = recoecalcand->superCluster();
799 
800  OpenHLTElectron ele;
801  ele.hcalIsol = -999;
802  ele.trackIsol = -999;
803  ele.ecalIsol = -999;
804  ele.L1Isolated = true;
805  ele.p = -999;
806  ele.pixelSeeds = -999;
807  ele.newSC = true;
808  ele.clusterShape = -999;
809  ele.Dphi = 700;
810  ele.Deta = 700;
811  ele.hovereh = -999;
812  ele.Et = recoecalcand->et();
813  ele.eta = recoecalcand->eta();
814  ele.phi = recoecalcand->phi();
815  ele.E = recrSC->energy();
816  //Get the cluster shape
817  // std::vector<float> vCov = lazyTools.covariances( *(recrSC->seed()) );
818  std::vector<float> vCov = lazyTools.localCovariances( *(recrSC->seed()) );
819  double sigmaee = sqrt(vCov[0]);
820  // float EtaSC = fabs(recoecalcand->eta());
821  // if(EtaSC > 1.479 ) {//Endcap
822  // sigmaee = sigmaee - 0.02*(EtaSC - 2.3);
823  // }
824  ele.clusterShape = sigmaee;
825  ele.r9 = -999.;
826  ele.r9ID = -999.;
827 
828  // fill the ecal Isolation
829  if (EcalIsolMap.isValid()) {
830  reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*EcalIsolMap).find(ref);
831  if (mapi !=(*EcalIsolMap).end()) { ele.ecalIsol = mapi->val;}
832  }
833  // fill the hcal Isolation
834  if (HcalEleIsolMap.isValid()) {
835  //reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*HcalEleIsolMap).find( reco::RecoEcalCandidateRef(recoIsolecalcands, distance(recoIsolecalcands->begin(), recoecalcand)) );
836  reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*HcalEleIsolMap).find( ref );
837  if (mapi !=(*HcalEleIsolMap).end()) { ele.hcalIsol = mapi->val; }
838  }
839  // fill the R9
840  if (electronR9IsoMap.isValid()) {
841  reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*electronR9IsoMap).find( ref );
842  if (mapi !=(*electronR9IsoMap).end()) { ele.r9 = mapi->val; }
843  }
844  // fill the H for H/E
845  if (photonHoverEHIsoMap.isValid()) {
846  reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*photonHoverEHIsoMap).find(ref);
847  if (mapi !=(*photonHoverEHIsoMap).end()) { ele.hovereh = mapi->val;}
848  }
849  // fill the R9ID
850  if (electronR9IDIsoMap.isValid()) {
851  reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*electronR9IDIsoMap).find( ref );
852  if (mapi !=(*electronR9IDIsoMap).end()) { ele.r9ID = mapi->val; }
853  }
854 
855  // look if the SC has associated pixelSeeds
856  int nmatch = 0;
857 
858  if (L1IsoPixelSeedsMap.isValid()) {
859  for (reco::ElectronSeedCollection::const_iterator it = L1IsoPixelSeedsMap->begin();
860  it != L1IsoPixelSeedsMap->end(); it++) {
861  edm::RefToBase<reco::CaloCluster> caloCluster = it->caloCluster() ;
862  reco::SuperClusterRef scRef = caloCluster.castTo<reco::SuperClusterRef>() ;
863  if (&(*recrSC) == &(*scRef)) { nmatch++; }
864  }
865  }
866 
867  ele.pixelSeeds = nmatch;
868 
869  // look if the SC was promoted to an electron:
870  if (electronIsoHandle.isValid()) {
871  bool FirstElectron = true;
872  reco::ElectronRef electronref;
873  for (reco::ElectronCollection::const_iterator iElectron = electronIsoHandle->begin();
874  iElectron != electronIsoHandle->end(); iElectron++) {
875  // 1) find the SC from the electron
876  electronref = reco::ElectronRef(electronIsoHandle, iElectron - electronIsoHandle->begin());
877  const reco::SuperClusterRef theClus = electronref->superCluster(); // SC from the electron;
878  if (&(*recrSC) == &(*theClus)) { // ref is the RecoEcalCandidateRef corresponding to the electron
879  if (FirstElectron) { // the first electron is stored in ele, keeping the ele.newSC = true
880  FirstElectron = false;
881  ele.p = electronref->track()->momentum().R();
882  ele.vtxZ = electronref->track()->vertex().z();
883  float deta=-100, dphi=-100;
884  CalculateDetaDphi(theMagField,BSPosition , electronref , deta, dphi, false);
885  ele.Dphi=dphi; ele.Deta=deta;
886  // fill the track Isolation
887  if (TrackEleIsolMap.isValid()) {
888  reco::ElectronIsolationMap::const_iterator mapTr = (*TrackEleIsolMap).find(electronref);
889  if (mapTr != (*TrackEleIsolMap).end()) { ele.trackIsol = mapTr->val; }
890  }
891  }
892  else {
893  // FirstElectron is false, i.e. the SC of this electron is common to another electron.
894  // A new OpenHLTElectron is inserted in the theHLTElectrons vector setting newSC = false
895  OpenHLTElectron ele2;
896  ele2.hcalIsol = ele.hcalIsol;
897  ele2.trackIsol = -999;
898  ele2.Dphi = 700;
899  ele2.Deta = 700;
900  ele2.Et = ele.Et;
901  ele2.eta = ele.eta;
902  ele2.phi = ele.phi;
903  ele2.vtxZ = electronref->track()->vertex().z();
904  ele2.E = ele.E;
905  ele2.L1Isolated = ele.L1Isolated;
906  ele2.pixelSeeds = ele.pixelSeeds;
907  ele2.clusterShape = ele.clusterShape;
908  ele2.newSC = false;
909  ele2.p = electronref->track()->momentum().R();
910  ele2.r9 = ele.r9;
911  ele2.hovereh = ele.hovereh;
912  ele2.ecalIsol = ele.ecalIsol;
913  ele2.r9ID = ele.r9ID;
914  float deta=-100, dphi=-100;
915  CalculateDetaDphi(theMagField,BSPosition , electronref , deta, dphi, false);
916  ele2.Dphi=dphi; ele2.Deta=deta;
917  // fill the track Isolation
918  if (TrackEleIsolMap.isValid()) {
919  reco::ElectronIsolationMap::const_iterator mapTr = (*TrackEleIsolMap).find( electronref);
920  if (mapTr !=(*TrackEleIsolMap).end()) { ele2.trackIsol = mapTr->val;}
921  }
922  theHLTElectrons.push_back(ele2);
923  }
924  }
925  } // end of loop over electrons
926  } // end of if (electronIsoHandle) {
927 
928  //store the electron into the vector
929  theHLTElectrons.push_back(ele);
930  } // end of loop over ecalCandidates
931  } // end of if (recoIsolecalcands) {
932  }
edm::Ref< RecoEcalCandidateCollection > RecoEcalCandidateRef
reference to an object in a collection of RecoEcalCandidate objects
edm::Ref< ElectronCollection > ElectronRef
reference to an object in a collection of Electron objects
Definition: ElectronFwd.h:15
void CalculateDetaDphi(const edm::ESHandle< MagneticField > &theMagField, reco::BeamSpot::Point &BSPosition, const reco::ElectronRef eleref, float &deltaeta, float &deltaphi, bool useTrackProjectionToEcal)
Definition: HLTEgamma.cc:1094
float * ele
Definition: HLTEgamma.h:182
T sqrt(T t)
Definition: SSEVec.h:18
bool isValid() const
Definition: HandleBase.h:75
REF castTo() const
Definition: RefToBase.h:271
void HLTEgamma::MakeL1IsolatedPhotons ( std::vector< OpenHLTPhoton > &  photons,
const edm::Handle< reco::RecoEcalCandidateCollection > &  recoIsolecalcands,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  EcalIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  HcalIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  TrackIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonR9IsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonHoverEHIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonR9IDIsoMap,
EcalClusterLazyTools lazyTools 
)
private

Definition at line 612 of file HLTEgamma.cc.

References HLTEgamma::OpenHLTPhoton::clusterShape, edm::AssociationMap< edm::OneToValue< std::vector< reco::RecoEcalCandidate >, float > >::const_iterator, HLT_25ns10e33_v2_cff::distance, HLTEgamma::OpenHLTPhoton::ecalIsol, HLTEgamma::OpenHLTPhoton::Et, HLTEgamma::OpenHLTPhoton::eta, HLTEgamma::OpenHLTPhoton::hcalIsol, HLTEgamma::OpenHLTPhoton::hovereh, edm::HandleBase::isValid(), HLTEgamma::OpenHLTPhoton::L1Isolated, HLTEgamma::OpenHLTPhoton::phi, HLTEgamma::OpenHLTPhoton::r9, HLTEgamma::OpenHLTPhoton::r9ID, mathSSE::sqrt(), and HLTEgamma::OpenHLTPhoton::trackIsol.

Referenced by analyze().

622  {
623  // Iterator to the isolation-map
625 
626  if (recoIsolecalcands.isValid()) {
627  // loop over SuperCluster and fill the HLTPhotons
628 
629 
630  for (reco::RecoEcalCandidateCollection::const_iterator recoecalcand = recoIsolecalcands->begin();
631  recoecalcand!= recoIsolecalcands->end(); recoecalcand++) {
632 
633  OpenHLTPhoton pho;
634  pho.ecalIsol = -999;
635  pho.hcalIsol = -999;
636  pho.trackIsol = -999;
637  pho.clusterShape = -999;
638  pho.L1Isolated = true;
639  pho.Et = recoecalcand->et();
640  pho.eta = recoecalcand->eta();
641  pho.phi = recoecalcand->phi();
642  pho.r9 = -999.;
643  pho.hovereh = -999.;
644  pho.r9ID = -999.;
645 
646  //Get the cluster shape
647  // std::vector<float> vCov = lazyTools.covariances( *(recoecalcand->superCluster()->seed()) );
648  std::vector<float> vCov = lazyTools.localCovariances( *(recoecalcand->superCluster()->seed()) );
649  double sigmaee = sqrt(vCov[0]);
650  // float EtaSC = fabs(recoecalcand->eta());
651  // if(EtaSC > 1.479 ) {//Endcap
652  // sigmaee = sigmaee - 0.02*(EtaSC - 2.3);
653  // }
654  pho.clusterShape = sigmaee;
655 
656  // Method to get the reference to the candidate
657  reco::RecoEcalCandidateRef ref = reco::RecoEcalCandidateRef(recoIsolecalcands, distance(recoIsolecalcands->begin(), recoecalcand));
658 
659  // First/Second member of the Map: Ref-to-Candidate(mapi)/Isolation(->val)
660  // fill the ecal Isolation
661  if (EcalIsolMap.isValid()) {
662  mapi = (*EcalIsolMap).find(ref);
663  if (mapi !=(*EcalIsolMap).end()) { pho.ecalIsol = mapi->val;}
664  }
665  // fill the hcal Isolation
666  if (HcalIsolMap.isValid()) {
667  mapi = (*HcalIsolMap).find(ref);
668  if (mapi !=(*HcalIsolMap).end()) { pho.hcalIsol = mapi->val;}
669  }
670  // fill the track Isolation
671  if (TrackIsolMap.isValid()) {
672  mapi = (*TrackIsolMap).find(ref);
673  if (mapi !=(*TrackIsolMap).end()) { pho.trackIsol = mapi->val;}
674  }
675  // fill the R9
676  if (photonR9IsoMap.isValid()) {
677  mapi = (*photonR9IsoMap).find(ref);
678  if (mapi !=(*photonR9IsoMap).end()) { pho.r9 = mapi->val;}
679  }
680  // fill the H for H/E
681  if (photonHoverEHIsoMap.isValid()) {
682  mapi = (*photonHoverEHIsoMap).find(ref);
683  if (mapi !=(*photonHoverEHIsoMap).end()) { pho.hovereh = mapi->val;}
684  }
685  // fill the R9ID
686  if (photonR9IDIsoMap.isValid()) {
687  mapi = (*photonR9IDIsoMap).find(ref);
688  if (mapi !=(*photonR9IDIsoMap).end()) { pho.r9ID = mapi->val;}
689  }
690 
691  // store the photon into the vector
692  theHLTPhotons.push_back(pho);
693  }
694  }
695  }
edm::Ref< RecoEcalCandidateCollection > RecoEcalCandidateRef
reference to an object in a collection of RecoEcalCandidate objects
T sqrt(T t)
Definition: SSEVec.h:18
bool isValid() const
Definition: HandleBase.h:75
void HLTEgamma::MakeL1NonIsolatedElectrons ( std::vector< OpenHLTElectron > &  electrons,
const edm::Handle< reco::ElectronCollection > &  electronNonIsoHandle,
const edm::Handle< reco::RecoEcalCandidateCollection > &  recoNonIsolecalcands,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  HcalEleIsolMap,
const edm::Handle< reco::ElectronSeedCollection > &  L1NonIsoPixelSeedsMap,
const edm::Handle< reco::ElectronIsolationMap > &  TrackEleIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  electronR9NonIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonHoverEHIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  EcalIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  electronR9IDNonIsoMap,
EcalClusterLazyTools lazyTools,
const edm::ESHandle< MagneticField > &  theMagField,
reco::BeamSpot::Point BSPosition 
)
private

Definition at line 935 of file HLTEgamma.cc.

References CalculateDetaDphi(), edm::RefToBase< T >::castTo(), HLTEgamma::OpenHLTElectron::clusterShape, edm::AssociationMap< edm::OneToValue< std::vector< reco::RecoEcalCandidate >, float > >::const_iterator, edm::AssociationMap< edm::OneToValue< std::vector< reco::Electron >, float > >::const_iterator, HLTEgamma::OpenHLTElectron::Deta, HLT_25ns10e33_v2_cff::distance, HLTEgamma::OpenHLTElectron::Dphi, HLTEgamma::OpenHLTElectron::E, HLTEgamma::OpenHLTElectron::ecalIsol, ele, HLTEgamma::OpenHLTElectron::Et, HLTEgamma::OpenHLTElectron::eta, HLTEgamma::OpenHLTElectron::hcalIsol, HLTEgamma::OpenHLTElectron::hovereh, edm::HandleBase::isValid(), HLTEgamma::OpenHLTElectron::L1Isolated, HLTEgamma::OpenHLTElectron::newSC, HLTEgamma::OpenHLTElectron::p, HLTEgamma::OpenHLTElectron::phi, HLTEgamma::OpenHLTElectron::pixelSeeds, HLTEgamma::OpenHLTElectron::r9, HLTEgamma::OpenHLTElectron::r9ID, mathSSE::sqrt(), HLTEgamma::OpenHLTElectron::trackIsol, and HLTEgamma::OpenHLTElectron::vtxZ.

Referenced by analyze().

949  {
950  // if there are electrons, then the isolation maps and the SC should be in the event; if not it is an error
951  if (recoNonIsolecalcands.isValid()) {
952  for (reco::RecoEcalCandidateCollection::const_iterator recoecalcand = recoNonIsolecalcands->begin();
953  recoecalcand!= recoNonIsolecalcands->end(); recoecalcand++) {
954  //get the ref to the SC:
955  reco::RecoEcalCandidateRef ref = reco::RecoEcalCandidateRef(recoNonIsolecalcands, distance(recoNonIsolecalcands->begin(), recoecalcand));
956  reco::SuperClusterRef recrSC = ref->superCluster();
957  //reco::SuperClusterRef recrSC = recoecalcand->superCluster();
958 
959  OpenHLTElectron ele;
960  ele.hcalIsol = -999;
961  ele.trackIsol = -999;
962  ele.ecalIsol = -999;
963  ele.L1Isolated = false;
964  ele.p = -999;
965  ele.pixelSeeds = -999;
966  ele.newSC = true;
967  ele.clusterShape = -999;
968  ele.Dphi = 700;
969  ele.Deta = 700;
970  ele.r9 = -999.;
971  ele.r9ID = -999.;
972  ele.hovereh = -999;
973  ele.Et = recoecalcand->et();
974  ele.eta = recoecalcand->eta();
975  ele.phi = recoecalcand->phi();
976  ele.E = recrSC->energy();
977  //Get the cluster shape
978  // std::vector<float> vCov = lazyTools.covariances( *(recrSC->seed()) );
979  std::vector<float> vCov = lazyTools.localCovariances( *(recrSC->seed()) );
980  double sigmaee = sqrt(vCov[0]);
981  // float EtaSC = fabs(recoecalcand->eta());
982  // if(EtaSC > 1.479 ) {//Endcap
983  // sigmaee = sigmaee - 0.02*(EtaSC - 2.3);
984  // }
985  ele.clusterShape = sigmaee;
986 
987  // fill the ecal Isolation
988  if (EcalNonIsolMap.isValid()) {
989  reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*EcalNonIsolMap).find(ref);
990  if (mapi !=(*EcalNonIsolMap).end()) { ele.ecalIsol = mapi->val;}
991  }
992  // fill the hcal Isolation
993  if (HcalEleIsolMap.isValid()) {
994  // reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*HcalEleIsolMap).find( reco::RecoEcalCandidateRef(recoNonIsolecalcands, distance(recoNonIsolecalcands->begin(), recoecalcand)) );
995  reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*HcalEleIsolMap).find( ref );
996  if (mapi !=(*HcalEleIsolMap).end()) {ele.hcalIsol = mapi->val;}
997  }
998  // fill the R9
999  if (electronR9NonIsoMap.isValid()) {
1000  reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*electronR9NonIsoMap).find( ref );
1001  if (mapi !=(*electronR9NonIsoMap).end()) { ele.r9 = mapi->val; }
1002  }
1003  // fill the H for H/E
1004  if (photonHoverEHNonIsoMap.isValid()) {
1005  reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*photonHoverEHNonIsoMap).find(ref);
1006  if (mapi !=(*photonHoverEHNonIsoMap).end()) { ele.hovereh = mapi->val;}
1007  }
1008  // fill the R9ID
1009  if (electronR9IDNonIsoMap.isValid()) {
1010  reco::RecoEcalCandidateIsolationMap::const_iterator mapi = (*electronR9IDNonIsoMap).find( ref );
1011  if (mapi !=(*electronR9IDNonIsoMap).end()) { ele.r9ID = mapi->val; }
1012  }
1013 
1014  // look if the SC has associated pixelSeeds
1015  int nmatch = 0;
1016 
1017  if (L1NonIsoPixelSeedsMap.isValid()) {
1018  for (reco::ElectronSeedCollection::const_iterator it = L1NonIsoPixelSeedsMap->begin();
1019  it != L1NonIsoPixelSeedsMap->end(); it++) {
1020  edm::RefToBase<reco::CaloCluster> caloCluster = it->caloCluster() ;
1021  reco::SuperClusterRef scRef = caloCluster.castTo<reco::SuperClusterRef>() ;
1022  if (&(*recrSC) == &(*scRef)) { nmatch++;}
1023  }
1024  }
1025 
1026  ele.pixelSeeds = nmatch;
1027 
1028  // look if the SC was promoted to an electron:
1029  if (electronNonIsoHandle.isValid()) {
1030  bool FirstElectron = true;
1031  reco::ElectronRef electronref;
1032  for (reco::ElectronCollection::const_iterator iElectron = electronNonIsoHandle->begin();
1033  iElectron != electronNonIsoHandle->end();iElectron++) {
1034  // 1) find the SC from the electron
1035  electronref = reco::ElectronRef(electronNonIsoHandle, iElectron - electronNonIsoHandle->begin());
1036  const reco::SuperClusterRef theClus = electronref->superCluster(); //SC from the electron;
1037  if (&(*recrSC) == &(*theClus)) { // ref is the RecoEcalCandidateRef corresponding to the electron
1038  if (FirstElectron) { //the first electron is stored in ele, keeping the ele.newSC = true
1039  FirstElectron = false;
1040  ele.p = electronref->track()->momentum().R();
1041  ele.vtxZ = electronref->track()->dz();
1042  float deta=-100, dphi=-100;
1043  CalculateDetaDphi(theMagField,BSPosition , electronref , deta, dphi, false);
1044  ele.Dphi=dphi; ele.Deta=deta;
1045 
1046  // fill the track Isolation
1047  if (TrackEleIsolMap.isValid()) {
1048  reco::ElectronIsolationMap::const_iterator mapTr = (*TrackEleIsolMap).find( electronref);
1049  if (mapTr !=(*TrackEleIsolMap).end()) { ele.trackIsol = mapTr->val;}
1050  }
1051  } else {
1052  // FirstElectron is false, i.e. the SC of this electron is common to another electron.
1053  // A new OpenHLTElectron is inserted in the theHLTElectrons vector setting newSC = false
1054  OpenHLTElectron ele2;
1055  ele2.hcalIsol = ele.hcalIsol;
1056  ele2.trackIsol =-999;
1057  ele2.ecalIsol = ele.ecalIsol;
1058  ele2.Dphi = 700;
1059  ele2.Deta = 700;
1060  ele2.Et = ele.Et;
1061  ele2.eta = ele.eta;
1062  ele2.phi = ele.phi;
1063  ele2.vtxZ = electronref->track()->dz();
1064  ele2.E = ele.E;
1065  ele2.L1Isolated = ele.L1Isolated;
1066  ele2.pixelSeeds = ele.pixelSeeds;
1067  ele2.clusterShape = ele.clusterShape;
1068  ele2.newSC = false;
1069  ele2.p = electronref->track()->momentum().R();
1070  ele2.r9 = ele.r9;
1071  ele2.hovereh = ele.hovereh;
1072  ele2.r9ID = ele.r9ID;
1073  float deta=-100, dphi=-100;
1074  CalculateDetaDphi(theMagField,BSPosition , electronref , deta, dphi, false);
1075  ele2.Dphi=dphi; ele2.Deta=deta;
1076 
1077  // fill the track Isolation
1078  if (TrackEleIsolMap.isValid()) {
1079  reco::ElectronIsolationMap::const_iterator mapTr = (*TrackEleIsolMap).find( electronref);
1080  if (mapTr !=(*TrackEleIsolMap).end()) { ele2.trackIsol = mapTr->val;}
1081  }
1082  theHLTElectrons.push_back(ele2);
1083  }
1084  }
1085  } // end of loop over electrons
1086  } // end of if (electronNonIsoHandle) {
1087 
1088  // store the electron into the vector
1089  theHLTElectrons.push_back(ele);
1090  } // end of loop over ecalCandidates
1091  } // end of if (recoNonIsolecalcands) {
1092  }
edm::Ref< RecoEcalCandidateCollection > RecoEcalCandidateRef
reference to an object in a collection of RecoEcalCandidate objects
edm::Ref< ElectronCollection > ElectronRef
reference to an object in a collection of Electron objects
Definition: ElectronFwd.h:15
void CalculateDetaDphi(const edm::ESHandle< MagneticField > &theMagField, reco::BeamSpot::Point &BSPosition, const reco::ElectronRef eleref, float &deltaeta, float &deltaphi, bool useTrackProjectionToEcal)
Definition: HLTEgamma.cc:1094
float * ele
Definition: HLTEgamma.h:182
T sqrt(T t)
Definition: SSEVec.h:18
bool isValid() const
Definition: HandleBase.h:75
REF castTo() const
Definition: RefToBase.h:271
void HLTEgamma::MakeL1NonIsolatedPhotons ( std::vector< OpenHLTPhoton > &  photons,
const edm::Handle< reco::RecoEcalCandidateCollection > &  recoNonIsolecalcands,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  EcalNonIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  HcalNonIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  TrackNonIsolMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonR9NonIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonHoverEHNonIsoMap,
const edm::Handle< reco::RecoEcalCandidateIsolationMap > &  photonR9IDNonIsoMap,
EcalClusterLazyTools lazyTools 
)
private

Definition at line 697 of file HLTEgamma.cc.

References HLTEgamma::OpenHLTPhoton::clusterShape, edm::AssociationMap< edm::OneToValue< std::vector< reco::RecoEcalCandidate >, float > >::const_iterator, HLT_25ns10e33_v2_cff::distance, HLTEgamma::OpenHLTPhoton::ecalIsol, HLTEgamma::OpenHLTPhoton::Et, HLTEgamma::OpenHLTPhoton::eta, HLTEgamma::OpenHLTPhoton::hcalIsol, HLTEgamma::OpenHLTPhoton::hovereh, edm::HandleBase::isValid(), HLTEgamma::OpenHLTPhoton::L1Isolated, HLTEgamma::OpenHLTPhoton::phi, HLTEgamma::OpenHLTPhoton::r9, HLTEgamma::OpenHLTPhoton::r9ID, mathSSE::sqrt(), and HLTEgamma::OpenHLTPhoton::trackIsol.

Referenced by analyze().

707  {
709 
710  if (recoNonIsolecalcands.isValid()) {
711  for (reco::RecoEcalCandidateCollection::const_iterator recoecalcand = recoNonIsolecalcands->begin();
712  recoecalcand!= recoNonIsolecalcands->end(); recoecalcand++) {
713  // loop over SuperCluster and fill the HLTPhotons
714  OpenHLTPhoton pho;
715  pho.ecalIsol = -999;
716  pho.hcalIsol = -999;
717  pho.trackIsol = -999;
718  pho.clusterShape = -999;
719  pho.L1Isolated = false;
720  pho.Et = recoecalcand->et();
721  pho.eta = recoecalcand->eta();
722  pho.phi = recoecalcand->phi();
723  pho.r9 = -999;
724  pho.hovereh = -999.;
725  pho.r9ID = -999.;
726 
727  //Get the cluster shape
728  // std::vector<float> vCov = lazyTools.covariances( *(recoecalcand->superCluster()->seed()) );
729  std::vector<float> vCov = lazyTools.localCovariances( *(recoecalcand->superCluster()->seed()) );
730  double sigmaee = sqrt(vCov[0]);
731  // float EtaSC = fabs(recoecalcand->eta());
732  // if(EtaSC > 1.479 ) {//Endcap
733  // sigmaee = sigmaee - 0.02*(EtaSC - 2.3);
734  // }
735  pho.clusterShape = sigmaee;
736 
737  reco::RecoEcalCandidateRef ref = reco::RecoEcalCandidateRef(recoNonIsolecalcands, distance(recoNonIsolecalcands->begin(), recoecalcand));
738 
739  // fill the ecal Isolation
740  if (EcalNonIsolMap.isValid()) {
741  mapi = (*EcalNonIsolMap).find(ref);
742  if (mapi !=(*EcalNonIsolMap).end()) { pho.ecalIsol = mapi->val;}
743  }
744  // fill the hcal Isolation
745  if (HcalNonIsolMap.isValid()) {
746  mapi = (*HcalNonIsolMap).find(ref);
747  if (mapi !=(*HcalNonIsolMap).end()) { pho.hcalIsol = mapi->val;}
748  }
749  // fill the track Isolation
750  if (TrackNonIsolMap.isValid()) {
751  mapi = (*TrackNonIsolMap).find(ref);
752  if (mapi !=(*TrackNonIsolMap).end()) { pho.trackIsol = mapi->val;}
753  }
754  // fill the R9
755  if (photonR9NonIsoMap.isValid()) {
756  mapi = (*photonR9NonIsoMap).find(ref);
757  if (mapi !=(*photonR9NonIsoMap).end()) { pho.r9 = mapi->val;}
758  }
759  // fill the H for H/E
760  if (photonHoverEHNonIsoMap.isValid()) {
761  mapi = (*photonHoverEHNonIsoMap).find(ref);
762  if (mapi !=(*photonHoverEHNonIsoMap).end()) { pho.hovereh = mapi->val;}
763  }
764  // fill the R9ID
765  if (photonR9IDNonIsoMap.isValid()) {
766  mapi = (*photonR9IDNonIsoMap).find(ref);
767  if (mapi !=(*photonR9IDNonIsoMap).end()) { pho.r9ID = mapi->val;}
768  }
769 
770  // store the photon into the vector
771  theHLTPhotons.push_back(pho);
772  }
773  }
774  }
edm::Ref< RecoEcalCandidateCollection > RecoEcalCandidateRef
reference to an object in a collection of RecoEcalCandidate objects
T sqrt(T t)
Definition: SSEVec.h:18
bool isValid() const
Definition: HandleBase.h:75
void HLTEgamma::setup ( const edm::ParameterSet pSet,
TTree *  tree 
)

Definition at line 38 of file HLTEgamma.cc.

References eld0corr, eldcot, eldeltaEtaIn, eldeltaPhiIn, eldist, ele, elecaliso, elECaloIsoR03, eleId, elet, eleta, elFbrem, elhcaliso, elHCaloIsoR03, elhOverE, elIP, elIsEcalDriven, elmishits, elNLostHits, elphi, elpt, elqGsfCtfScPixConsistent, elscEt, elsigmaietaieta, elTrkChi2NDF, eltrkiso, elTrkIsoR03, hecalactivClusShap, hecalactiveiso, hecalactivet, hecalactiveta, hecalactivhiso, hecalactivhovereh, hecalactivl1iso, hecalactivphi, hecalactivR9, hecalactivR9ID, hecalactivtiso, heleClusShap, heleDeta, heleDphi, heleE, heleeiso, heleet, heleeta, helehiso, helehovereh, helel1iso, heleNewSC, helep, helephi, helePixelSeeds, heleR9, heleR9ID, heletiso, helevtxz, hhfcluster2Dcut, hhfclustere1e9, hhfclustere9e25, hhfclustereCOREe9, hhfclustereSeL, hhfclustereta, hhfclusterphi, hhfeleeta, hhfelept, hphotClusShap, hphoteiso, hphotet, hphoteta, hphothiso, hphothovereh, hphotl1iso, hphotphi, hphotR9, hphotR9ID, hphottiso, kMaxEl, kMaxhEle, kMaxhPhot, kMaxPhot, nele, nhltecalactiv, nhltele, nhltgam, nhlthfeclus, nhlthfele, nphoton, photonClusShap, photone, photonecaliso, photonet, photoneta, photonhcaliso, photonhovere, photonphi, photonpt, photonr9id, and photontrkiso.

Referenced by HLTAnalyzer::HLTAnalyzer().

39 {
40  elpt = new float[kMaxEl];
41  elphi = new float[kMaxEl];
42  eleta = new float[kMaxEl];
43  elet = new float[kMaxEl];
44  ele = new float[kMaxEl];
45  eleId = new int[kMaxEl];// RL + 2*RT + 4*L + 4*T
46  elIP = new float[kMaxEl];
47  elNLostHits = new int[kMaxEl];
48  elTrkChi2NDF = new float[kMaxEl];
49  elTrkIsoR03 = new float[kMaxEl];
50  elECaloIsoR03 = new float[kMaxEl];
51  elHCaloIsoR03 = new float[kMaxEl];
52  elIsEcalDriven = new bool[kMaxEl];
53  elFbrem = new float[kMaxEl];
54  elmishits = new int[kMaxEl];
55  eldist = new float[kMaxEl];
56  eldcot = new float[kMaxEl];
57  eltrkiso = new float[kMaxEl];
58  elecaliso = new float[kMaxEl];
59  elhcaliso = new float[kMaxEl];
60  elsigmaietaieta = new float[kMaxEl];
61  eldeltaPhiIn = new float[kMaxEl];
62  eldeltaEtaIn = new float[kMaxEl];
63  elhOverE = new float[kMaxEl];
64  elscEt = new float[kMaxEl];
65  eld0corr = new float[kMaxEl];
66  elqGsfCtfScPixConsistent = new bool[kMaxEl];
67 
68  photonpt = new float[kMaxPhot];
69  photonphi = new float[kMaxPhot];
70  photoneta = new float[kMaxPhot];
71  photonet = new float[kMaxPhot];
72  photone = new float[kMaxPhot];
73  photontrkiso = new float[kMaxPhot];
74  photonecaliso = new float[kMaxPhot];
75  photonhcaliso = new float[kMaxPhot];
76  photonhovere = new float[kMaxPhot];
77  photonClusShap = new float[kMaxPhot];
78  photonr9id = new float[kMaxPhot];
79 
80  hphotet = new float[kMaxhPhot];
81  hphoteta = new float[kMaxhPhot];
82  hphotphi = new float[kMaxhPhot];
83  hphoteiso = new float[kMaxhPhot];
84  hphothiso = new float[kMaxhPhot];
85  hphottiso = new float[kMaxhPhot];
86  hphotl1iso = new int[kMaxhPhot];
87  hphotClusShap = new float[kMaxhPhot];
88  hphotR9 = new float[kMaxhPhot];
89  hphothovereh = new float[kMaxhPhot];
90  hphotR9ID = new float[kMaxhPhot];
91 
92  hecalactivet = new float[kMaxhPhot];
93  hecalactiveta = new float[kMaxhPhot];
94  hecalactivphi = new float[kMaxhPhot];
95  hecalactiveiso = new float[kMaxhPhot];
96  hecalactivhiso = new float[kMaxhPhot];
97  hecalactivtiso = new float[kMaxhPhot];
98  hecalactivl1iso = new int[kMaxhPhot];
99  hecalactivClusShap = new float[kMaxhPhot];
100  hecalactivR9 = new float[kMaxhPhot];
101  hecalactivhovereh = new float[kMaxhPhot];
102  hecalactivR9ID = new float[kMaxhPhot];
103 
104  heleet = new float[kMaxhEle];
105  heleeta = new float[kMaxhEle];
106  helephi = new float[kMaxhEle];
107  helevtxz = new float[kMaxhEle];
108  heleE = new float[kMaxhEle];
109  helep = new float[kMaxhEle];
110  helehiso = new float[kMaxhEle];
111  heleeiso = new float[kMaxhEle];
112  heletiso = new float[kMaxhEle];
113  helel1iso = new int[kMaxhEle];
114  helePixelSeeds = new int[kMaxhEle];
115  heleNewSC = new int[kMaxhEle];
116  heleClusShap = new float[kMaxhEle];
117  heleDeta = new float[kMaxhEle];
118  heleDphi = new float[kMaxhEle];
119  heleR9 = new float[kMaxhEle];
120  helehovereh = new float[kMaxhEle];
121  heleR9ID = new float[kMaxhEle];
122 
123  hhfelept = new float[kMaxhEle];
124  hhfeleeta = new float[kMaxhEle];
125  hhfclustere9e25 = new float[kMaxhEle];
126  hhfclustere1e9 = new float[kMaxhEle];
127  hhfclustereCOREe9 = new float[kMaxhEle];
128  hhfclustereSeL = new float[kMaxhEle];
129  hhfcluster2Dcut = new float[kMaxhEle];
130  hhfclustereta = new float[kMaxhEle];
131  hhfclusterphi = new float[kMaxhEle];
132 
133 
134  nele = 0;
135  nphoton = 0;
136  nhltecalactiv = 0;
137  nhltgam = 0;
138  nhltele = 0;
139  nhlthfele = 0;
140  nhlthfeclus = 0;
141 
142  // Egamma-specific branches of the tree
143  HltTree->Branch("NrecoElec", & nele, "NrecoElec/I");
144  HltTree->Branch("recoElecPt", elpt, "recoElecPt[NrecoElec]/F");
145  HltTree->Branch("recoElecPhi", elphi, "recoElecPhi[NrecoElec]/F");
146  HltTree->Branch("recoElecEta", eleta, "recoElecEta[NrecoElec]/F");
147  HltTree->Branch("recoElecEt", elet, "recoElecEt[NrecoElec]/F");
148  HltTree->Branch("recoElecE", ele, "recoElecE[NrecoElec]/F");
149  HltTree->Branch("recoElecEleID", eleId, "recoElecEleID[NrecoElec]/I");
150  HltTree->Branch("recoElecIP", elIP, "recoElecIP[NrecoElec]/F");
151  HltTree->Branch("recoElecNLostHits", elNLostHits, "recoElecNLostHits[NrecoElec]/I");
152  HltTree->Branch("recoElecChi2NDF", elTrkChi2NDF, "recoElecChi2NDF[NrecoElec]/F");
153  HltTree->Branch("recoElecTrkIsoR03", elTrkIsoR03, "recoElecTrkIsoR03[NrecoElec]/F");
154  HltTree->Branch("recoElecECaloIsoR03", elECaloIsoR03, "recoElecECaloIsoR03[NrecoElec]/F");
155  HltTree->Branch("recoElecHCaloIsoR03", elHCaloIsoR03, "recoElecHCaloIsoR03[NrecoElec]/F");
156  HltTree->Branch("recoElecIsEcalDriven", elIsEcalDriven, "recoElecIsEcalDriven[NrecoElec]/O");
157  HltTree->Branch("recoElecFbrem", elFbrem, "recoElecFbrem[NrecoElec]/F");
158  HltTree->Branch("recoElecmishits", elmishits, "recoElecmishits[NrecoElec]/I");
159  HltTree->Branch("recoElecdist", eldist, "recoElecdist[NrecoElec]/F");
160  HltTree->Branch("recoElecdcot", eldcot, "recoElecdcot[NrecoElec]/F");
161  HltTree->Branch("recoElectrkiso", eltrkiso, "recoElectrkiso[NrecoElec]/F");
162  HltTree->Branch("recoElececaliso", elecaliso, "recoElececaliso[NrecoElec]/F");
163  HltTree->Branch("recoElechcaliso", elhcaliso, "recoElechcaliso[NrecoElec]/F");
164  HltTree->Branch("recoElecsigmaietaieta", elsigmaietaieta, "recoElecsigmaietaieta[NrecoElec]/F");
165  HltTree->Branch("recoElecdeltaPhiIn", eldeltaPhiIn, "recoElecdeltaPhiIn[NrecoElec]/F");
166  HltTree->Branch("recoElecdeltaEtaIn", eldeltaEtaIn, "recoElecdeltaEtaIn[NrecoElec]/F");
167  HltTree->Branch("recoElechOverE", elhOverE, "recoElechOverE[NrecoElec]/F");
168  HltTree->Branch("recoElecscEt", elscEt, "recoElecscEt[NrecoElec]/F");
169  HltTree->Branch("recoElecd0corr", eld0corr, "recoElecd0corr[NrecoElec]/F");
170  HltTree->Branch("recoElecqGsfCtfScPixConsistent", elqGsfCtfScPixConsistent, "recoElecqGsfCtfScPixConsistent[NrecoElec]/O");
171 
172  HltTree->Branch("NrecoPhot", &nphoton, "NrecoPhot/I");
173  HltTree->Branch("recoPhotPt", photonpt, "recoPhotPt[NrecoPhot]/F");
174  HltTree->Branch("recoPhotPhi", photonphi, "recoPhotPhi[NrecoPhot]/F");
175  HltTree->Branch("recoPhotEta", photoneta, "recoPhotEta[NrecoPhot]/F");
176  HltTree->Branch("recoPhotEt", photonet, "recoPhotEt[NrecoPhot]/F");
177  HltTree->Branch("recoPhotE", photone, "recoPhotE[NrecoPhot]/F");
178  HltTree->Branch("recoPhotTiso", photontrkiso, "recoPhotTiso[NrecoPhot]/F");
179  HltTree->Branch("recoPhotEiso", photonecaliso, "recoPhotEiso[NrecoPhot]/F");
180  HltTree->Branch("recoPhotHiso", photonhcaliso, "recoPhotHiso[NrecoPhot]/F");
181  HltTree->Branch("recoPhotHoverE", photonhovere, "recoPhotHoverE[NrecoPhot]/F");
182  HltTree->Branch("recoPhotClusShap", photonClusShap, "recoPhotClusShap[NrecoPhot]/F");
183  HltTree->Branch("recoPhotR9ID", photonr9id, "recoPhotR9ID[NrecoPhot]/F");
184 
185  HltTree->Branch("NohPhot", & nhltgam, "NohPhot/I");
186  HltTree->Branch("ohPhotEt", hphotet, "ohPhotEt[NohPhot]/F");
187  HltTree->Branch("ohPhotEta", hphoteta, "ohPhotEta[NohPhot]/F");
188  HltTree->Branch("ohPhotPhi", hphotphi, "ohPhotPhi[NohPhot]/F");
189  HltTree->Branch("ohPhotEiso", hphoteiso, "ohPhotEiso[NohPhot]/F");
190  HltTree->Branch("ohPhotHiso", hphothiso, "ohPhotHiso[NohPhot]/F");
191  HltTree->Branch("ohPhotTiso", hphottiso, "ohPhotTiso[NohPhot]/F");
192  HltTree->Branch("ohPhotL1iso", hphotl1iso, "ohPhotL1iso[NohPhot]/I");
193  HltTree->Branch("ohPhotClusShap", hphotClusShap, "ohPhotClusShap[NohPhot]/F");
194  HltTree->Branch("ohPhotR9", hphotR9, "ohPhotR9[NohPhot]/F");
195  HltTree->Branch("ohPhotHforHoverE", hphothovereh, "ohPhotHforHoverE[NohPhot]/F");
196  HltTree->Branch("ohPhotR9ID", hphotR9ID, "ohPhotR9ID[NohPhot]/F");
197 
198  HltTree->Branch("NohEcalActiv", & nhltecalactiv, "NohEcalActiv/I");
199  HltTree->Branch("ohEcalActivEt", hecalactivet, "ohEcalActivEt[NohEcalActiv]/F");
200  HltTree->Branch("ohEcalActivEta", hecalactiveta, "ohEcalActivEta[NohEcalActiv]/F");
201  HltTree->Branch("ohEcalActivPhi", hecalactivphi, "ohEcalActivPhi[NohEcalActiv]/F");
202  HltTree->Branch("ohEcalActivEiso", hecalactiveiso, "ohEcalActivEiso[NohEcalActiv]/F");
203  HltTree->Branch("ohEcalActivHiso", hecalactivhiso, "ohEcalActivHiso[NohEcalActiv]/F");
204  HltTree->Branch("ohEcalActivTiso", hecalactivtiso, "ohEcalActivTiso[NohEcalActiv]/F");
205  HltTree->Branch("ohEcalActivL1iso", hecalactivl1iso, "ohEcalActivL1iso[NohEcalActiv]/I");
206  HltTree->Branch("ohEcalActivClusShap", hecalactivClusShap, "ohEcalActivClusShap[NohEcalActiv]/F");
207  HltTree->Branch("ohEcalActivR9", hecalactivR9, "ohEcalActivR9[NohEcalActiv]/F");
208  HltTree->Branch("ohEcalActivHforHoverE", hecalactivhovereh, "ohEcalActivHforHoverE[NohEcalActiv]/F");
209  HltTree->Branch("ohEcalActivR9ID", hecalactivR9ID, "ohEcalActivR9ID[NohEcalActiv]/F");
210 
211  HltTree->Branch("NohEle", & nhltele, "NohEle/I");
212  HltTree->Branch("ohEleEt", heleet, "ohEleEt[NohEle]/F");
213  HltTree->Branch("ohEleEta", heleeta, "ohEleEta[NohEle]/F");
214  HltTree->Branch("ohElePhi", helephi, "ohElePhi[NohEle]/F");
215  HltTree->Branch("ohEleVtxZ", helevtxz, "ohEleVtxZ[NohEle]/F");
216  HltTree->Branch("ohEleE", heleE, "ohEleE[NohEle]/F");
217  HltTree->Branch("ohEleP", helep, "ohEleP[NohEle]/F");
218  HltTree->Branch("ohEleHiso", helehiso, "ohEleHiso[NohEle]/F");
219  HltTree->Branch("ohEleTiso", heletiso, "ohEleTiso[NohEle]/F");
220  HltTree->Branch("ohEleEiso", heleeiso, "ohEleEiso[NohEle]/F");
221  HltTree->Branch("ohEleL1iso", helel1iso, "ohEleLiso[NohEle]/I");
222  HltTree->Branch("ohElePixelSeeds", helePixelSeeds, "ohElePixelSeeds[NohEle]/I");
223  HltTree->Branch("ohEleNewSC", heleNewSC, "ohEleNewSC[NohEle]/I");
224  HltTree->Branch("ohEleClusShap", heleClusShap, "ohEleClusShap[NohEle]/F");
225  HltTree->Branch("ohEleDeta", heleDeta, "ohEleDeta[NohEle]/F");
226  HltTree->Branch("ohEleDphi", heleDphi, "ohEleDphi[NohEle]/F");
227  HltTree->Branch("ohEleR9", heleR9, "ohEleR9[NohEle]/F");
228  HltTree->Branch("ohEleHforHoverE", helehovereh, "ohEleHforHoverE[NohEle]/F");
229  HltTree->Branch("ohEleR9ID", heleR9ID, "ohEleR9ID[NohEle]/F");
230  HltTree->Branch("NohHFEle", &nhlthfele , "NohHFEle/I");
231  HltTree->Branch("ohHFElePt", hhfelept, "ohHFElePt[NohHFEle]/F");
232  HltTree->Branch("ohHFEleEta", hhfeleeta, "ohHFEleEta[NohHFEle]/F");
233  HltTree->Branch("NohHFECALClus", &nhlthfeclus, "NohHFECALClus/I");
234 
235  HltTree->Branch("ohHFEleClustere9e25", hhfclustere9e25, "ohHFEleClustere9e25[NohHFECALClus]/F");
236  HltTree->Branch("ohHFEleClustere1e9", hhfclustere1e9, "ohHFEleClustere1e9[NohHFECALClus]/F");
237  HltTree->Branch("ohHFEleClustereCOREe9", hhfclustereCOREe9, "ohHFEleClustereCOREe9[NohHFECALClus]/F");
238  HltTree->Branch("ohHFEleClustereSeL", hhfclustereSeL, "ohHFEleClustereSeL[NohHFECALClus]/F");
239  HltTree->Branch("ohHFEleCluster2Dcut", hhfcluster2Dcut, "ohHFEleCluster2Dcut[NohHFECALClus]/F");
240  HltTree->Branch("ohHFEleClusterEta", hhfclustereta, "ohHFEleClusterEta[NohHFECALClus]/F");
241  HltTree->Branch("ohHFEleClusterPhi", hhfclusterphi, "ohHFEleClusterPhi[NohHFECALClus]/F");
242 }
float * eldcot
Definition: HLTEgamma.h:188
float * elet
Definition: HLTEgamma.h:182
float * hphothovereh
Definition: HLTEgamma.h:193
int * helel1iso
Definition: HLTEgamma.h:200
float * hecalactivhovereh
Definition: HLTEgamma.h:192
float * hphotR9
Definition: HLTEgamma.h:199
float * helephi
Definition: HLTEgamma.h:194
float * photonhovere
Definition: HLTEgamma.h:190
int nhltele
Definition: HLTEgamma.h:204
float * helehovereh
Definition: HLTEgamma.h:194
int * hecalactivl1iso
Definition: HLTEgamma.h:200
float * elTrkIsoR03
Definition: HLTEgamma.h:182
float * eltrkiso
Definition: HLTEgamma.h:183
float * elTrkChi2NDF
Definition: HLTEgamma.h:182
float * elIP
Definition: HLTEgamma.h:182
float * heleDeta
Definition: HLTEgamma.h:198
int nhltecalactiv
Definition: HLTEgamma.h:204
float * photonphi
Definition: HLTEgamma.h:189
float * hhfclustereCOREe9
Definition: HLTEgamma.h:207
float * eldist
Definition: HLTEgamma.h:188
float * hphottiso
Definition: HLTEgamma.h:193
float * elphi
Definition: HLTEgamma.h:182
float * heleClusShap
Definition: HLTEgamma.h:198
float * photonecaliso
Definition: HLTEgamma.h:190
float * heleDphi
Definition: HLTEgamma.h:198
float * hphotet
Definition: HLTEgamma.h:193
float * photonr9id
Definition: HLTEgamma.h:190
float * hhfclustere1e9
Definition: HLTEgamma.h:207
float * photonet
Definition: HLTEgamma.h:189
static const size_t kMaxhPhot
Definition: HLTEgamma.cc:31
float * elhOverE
Definition: HLTEgamma.h:184
float * hhfclusterphi
Definition: HLTEgamma.h:206
float * hhfcluster2Dcut
Definition: HLTEgamma.h:206
float * photonpt
Definition: HLTEgamma.h:189
float * hphoteiso
Definition: HLTEgamma.h:193
int * helePixelSeeds
Definition: HLTEgamma.h:200
float * ele
Definition: HLTEgamma.h:182
float * photonClusShap
Definition: HLTEgamma.h:190
float * elECaloIsoR03
Definition: HLTEgamma.h:182
float * heleeiso
Definition: HLTEgamma.h:194
float * elpt
Definition: HLTEgamma.h:182
float * elscEt
Definition: HLTEgamma.h:185
float * helehiso
Definition: HLTEgamma.h:194
float * photontrkiso
Definition: HLTEgamma.h:190
float * elHCaloIsoR03
Definition: HLTEgamma.h:182
float * heleet
Definition: HLTEgamma.h:194
float * eld0corr
Definition: HLTEgamma.h:185
float * hhfelept
Definition: HLTEgamma.h:206
float * heleeta
Definition: HLTEgamma.h:194
float * hecalactivR9ID
Definition: HLTEgamma.h:199
int nhlthfeclus
Definition: HLTEgamma.h:204
float * hphoteta
Definition: HLTEgamma.h:193
int * elmishits
Definition: HLTEgamma.h:187
int * heleNewSC
Definition: HLTEgamma.h:203
static const size_t kMaxEl
Definition: HLTEgamma.cc:29
float * eleta
Definition: HLTEgamma.h:182
static const size_t kMaxhEle
Definition: HLTEgamma.cc:32
float * hhfclustereta
Definition: HLTEgamma.h:206
float * elsigmaietaieta
Definition: HLTEgamma.h:184
float * hhfeleeta
Definition: HLTEgamma.h:206
float * heleE
Definition: HLTEgamma.h:194
float * photone
Definition: HLTEgamma.h:189
float * eldeltaPhiIn
Definition: HLTEgamma.h:184
float * hecalactivtiso
Definition: HLTEgamma.h:192
int * hphotl1iso
Definition: HLTEgamma.h:200
float * helep
Definition: HLTEgamma.h:194
float * hphotR9ID
Definition: HLTEgamma.h:199
float * hecalactiveta
Definition: HLTEgamma.h:192
float * photonhcaliso
Definition: HLTEgamma.h:190
float * photoneta
Definition: HLTEgamma.h:189
int nhltgam
Definition: HLTEgamma.h:204
float * hecalactivClusShap
Definition: HLTEgamma.h:198
float * hphothiso
Definition: HLTEgamma.h:193
float * hecalactivhiso
Definition: HLTEgamma.h:192
int * elNLostHits
Definition: HLTEgamma.h:201
bool * elIsEcalDriven
Definition: HLTEgamma.h:202
float * hecalactivphi
Definition: HLTEgamma.h:192
float * hecalactivR9
Definition: HLTEgamma.h:199
int * eleId
Definition: HLTEgamma.h:201
float * elecaliso
Definition: HLTEgamma.h:183
int nphoton
Definition: HLTEgamma.h:204
float * hphotClusShap
Definition: HLTEgamma.h:198
static const size_t kMaxPhot
Definition: HLTEgamma.cc:30
float * hhfclustere9e25
Definition: HLTEgamma.h:206
bool * elqGsfCtfScPixConsistent
Definition: HLTEgamma.h:186
int nele
Definition: HLTEgamma.h:204
float * heletiso
Definition: HLTEgamma.h:194
float * hecalactivet
Definition: HLTEgamma.h:192
float * hhfclustereSeL
Definition: HLTEgamma.h:207
float * hecalactiveiso
Definition: HLTEgamma.h:192
int nhlthfele
Definition: HLTEgamma.h:204
float * hphotphi
Definition: HLTEgamma.h:193
float * heleR9
Definition: HLTEgamma.h:199
float * elhcaliso
Definition: HLTEgamma.h:183
float * eldeltaEtaIn
Definition: HLTEgamma.h:184
float * elFbrem
Definition: HLTEgamma.h:182
float * helevtxz
Definition: HLTEgamma.h:194
float * heleR9ID
Definition: HLTEgamma.h:199

Member Data Documentation

float * HLTEgamma::eld0corr
private

Definition at line 185 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::eldcot
private

Definition at line 188 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::eldeltaEtaIn
private

Definition at line 184 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::eldeltaPhiIn
private

Definition at line 184 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float* HLTEgamma::eldist
private

Definition at line 188 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::ele
private
float * HLTEgamma::elecaliso
private

Definition at line 183 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::elECaloIsoR03
private

Definition at line 182 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

int* HLTEgamma::eleId
private

Definition at line 201 of file HLTEgamma.h.

Referenced by setup().

float * HLTEgamma::elet
private

Definition at line 182 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::eleta
private

Definition at line 182 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::elFbrem
private

Definition at line 182 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::elhcaliso
private

Definition at line 183 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::elHCaloIsoR03
private

Definition at line 182 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::elhOverE
private

Definition at line 184 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::elIP
private

Definition at line 182 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

bool* HLTEgamma::elIsEcalDriven
private

Definition at line 202 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

int* HLTEgamma::elmishits
private

Definition at line 187 of file HLTEgamma.h.

Referenced by analyze(), and setup().

int * HLTEgamma::elNLostHits
private

Definition at line 201 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::elphi
private

Definition at line 182 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float* HLTEgamma::elpt
private

Definition at line 182 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

bool* HLTEgamma::elqGsfCtfScPixConsistent
private

Definition at line 186 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float* HLTEgamma::elscEt
private

Definition at line 185 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float* HLTEgamma::elsigmaietaieta
private

Definition at line 184 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::elTrkChi2NDF
private

Definition at line 182 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float* HLTEgamma::eltrkiso
private

Definition at line 183 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::elTrkIsoR03
private

Definition at line 182 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float* HLTEgamma::hecalactivClusShap
private

Definition at line 198 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::hecalactiveiso
private

Definition at line 192 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float* HLTEgamma::hecalactivet
private

Definition at line 192 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::hecalactiveta
private

Definition at line 192 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::hecalactivhiso
private

Definition at line 192 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::hecalactivhovereh
private

Definition at line 192 of file HLTEgamma.h.

Referenced by analyze(), and setup().

int* HLTEgamma::hecalactivl1iso
private

Definition at line 200 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::hecalactivphi
private

Definition at line 192 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float* HLTEgamma::hecalactivR9
private

Definition at line 199 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::hecalactivR9ID
private

Definition at line 199 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::hecalactivtiso
private

Definition at line 192 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::heleClusShap
private

Definition at line 198 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::heleDeta
private

Definition at line 198 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::heleDphi
private

Definition at line 198 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::heleE
private

Definition at line 194 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::heleeiso
private

Definition at line 194 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float* HLTEgamma::heleet
private

Definition at line 194 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::heleeta
private

Definition at line 194 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::helehiso
private

Definition at line 194 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::helehovereh
private

Definition at line 194 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

int * HLTEgamma::helel1iso
private

Definition at line 200 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

int* HLTEgamma::heleNewSC
private

Definition at line 203 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::helep
private

Definition at line 194 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::helephi
private

Definition at line 194 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

int * HLTEgamma::helePixelSeeds
private

Definition at line 200 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::heleR9
private

Definition at line 199 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::heleR9ID
private

Definition at line 199 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::heletiso
private

Definition at line 194 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::helevtxz
private

Definition at line 194 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hhfcluster2Dcut
private

Definition at line 206 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float* HLTEgamma::hhfclustere1e9
private

Definition at line 207 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hhfclustere9e25
private

Definition at line 206 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hhfclustereCOREe9
private

Definition at line 207 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hhfclustereSeL
private

Definition at line 207 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hhfclustereta
private

Definition at line 206 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hhfclusterphi
private

Definition at line 206 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hhfeleeta
private

Definition at line 206 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float* HLTEgamma::hhfelept
private

Definition at line 206 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hphotClusShap
private

Definition at line 198 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hphoteiso
private

Definition at line 193 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float* HLTEgamma::hphotet
private

Definition at line 193 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hphoteta
private

Definition at line 193 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hphothiso
private

Definition at line 193 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hphothovereh
private

Definition at line 193 of file HLTEgamma.h.

Referenced by analyze(), and setup().

int * HLTEgamma::hphotl1iso
private

Definition at line 200 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hphotphi
private

Definition at line 193 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::hphotR9
private

Definition at line 199 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::hphotR9ID
private

Definition at line 199 of file HLTEgamma.h.

Referenced by analyze(), and setup().

float * HLTEgamma::hphottiso
private

Definition at line 193 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

int HLTEgamma::nele
private

Definition at line 204 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

int HLTEgamma::nhltecalactiv
private

Definition at line 204 of file HLTEgamma.h.

Referenced by analyze(), and setup().

int HLTEgamma::nhltele
private

Definition at line 204 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

int HLTEgamma::nhltgam
private

Definition at line 204 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

int HLTEgamma::nhlthfeclus
private

Definition at line 204 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

int HLTEgamma::nhlthfele
private

Definition at line 204 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

int HLTEgamma::nphoton
private

Definition at line 204 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::photonClusShap
private

Definition at line 190 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::photone
private

Definition at line 189 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::photonecaliso
private

Definition at line 190 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::photonet
private

Definition at line 189 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::photoneta
private

Definition at line 189 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::photonhcaliso
private

Definition at line 190 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::photonhovere
private

Definition at line 190 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::photonphi
private

Definition at line 189 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float* HLTEgamma::photonpt
private

Definition at line 189 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float * HLTEgamma::photonr9id
private

Definition at line 190 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().

float* HLTEgamma::photontrkiso
private

Definition at line 190 of file HLTEgamma.h.

Referenced by analyze(), clear(), and setup().