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PFElectronAlgo Class Reference

#include <PFElectronAlgo.h>

Public Member Functions

const std::vector
< reco::PFCandidate > & 
getAllElectronCandidates ()
 
const std::vector
< reco::PFCandidate > & 
getElectronCandidates ()
 
const std::vector
< reco::PFCandidateElectronExtra > & 
getElectronExtra ()
 
bool isElectronValidCandidate (const reco::PFBlockRef &blockRef, std::vector< bool > &active, const reco::Vertex &primaryVertex)
 
 PFElectronAlgo (const double mvaEleCut, std::string mvaWeightFileEleID, const boost::shared_ptr< PFSCEnergyCalibration > &thePFSCEnergyCalibration, const boost::shared_ptr< PFEnergyCalibration > &thePFEnergyCalibration, bool applyCrackCorrections, bool usePFSCEleCalib, bool useEGElectrons, bool useEGammaSupercluster, double sumEtEcalIsoForEgammaSC_barrel, double sumEtEcalIsoForEgammaSC_endcap, double coneEcalIsoForEgammaSC, double sumPtTrackIsoForEgammaSC_barrel, double sumPtTrackIsoForEgammaSC_endcap, unsigned int nTrackIsoForEgammaSC, double coneTrackIsoForEgammaSC)
 
void setEGElectronCollection (const reco::GsfElectronCollection &egelectrons)
 
 ~PFElectronAlgo ()
 

Private Types

typedef std::map< unsigned int,
std::vector< unsigned int > > 
AssMap
 

Private Member Functions

unsigned int FindClosestElement (const unsigned int iele, std::multimap< double, unsigned int > &Elems, float &chi2cut, std::vector< bool > &active, const reco::PFBlockRef &blockRef)
 
bool isPrimaryTrack (const reco::PFBlockElementTrack &KfEl, const reco::PFBlockElementGsfTrack &GsfEl)
 
void RunPFElectron (const reco::PFBlockRef &blockRef, std::vector< bool > &active, const reco::Vertex &primaryVertex)
 
void SetActive (const reco::PFBlockRef &blockRef, AssMap &associatedToGsf_, AssMap &associatedToBrems_, AssMap &associatedToEcal_, std::vector< bool > &active)
 
void SetCandidates (const reco::PFBlockRef &blockRef, AssMap &associatedToGsf_, AssMap &associatedToBrems_, AssMap &associatedToEcal_)
 
void SetIDOutputs (const reco::PFBlockRef &blockRef, AssMap &associatedToGsf_, AssMap &associatedToBrems_, AssMap &associatedToEcal_, const reco::Vertex &primaryVertex)
 
bool SetLinks (const reco::PFBlockRef &blockRef, AssMap &associatedToGsf_, AssMap &associatedToBrems_, AssMap &associatedToEcal_, std::vector< bool > &active, const reco::Vertex &primaryVertex)
 
unsigned int whichTrackAlgo (const reco::TrackRef &trackRef)
 

Private Attributes

std::vector< reco::PFCandidateallElCandidate_
 
bool applyCrackCorrections_
 
std::vector< double > BDToutput_
 
float chi2_gsf
 
float chi2_kf
 
double coneEcalIsoForEgammaSC_
 
double coneTrackIsoForEgammaSC_
 
std::vector< std::pair
< unsigned int, unsigned int > > 
convGsfTrack_
 
float DEtaGsfEcalClust
 
float dPtOverPt_gsf
 
float DPtOverPt_gsf
 
float DPtOverPt_kf
 
float earlyBrem
 
float EGsfPoutMode
 
std::vector< reco::PFCandidateelCandidate_
 
std::map< unsigned int,
std::vector< reco::PFCandidate > > 
electronConstituents_
 
std::vector
< reco::PFCandidateElectronExtra
electronExtra_
 
float Eta_gsf
 
float EtotBremPinPoutMode
 
float EtotPinMode
 
std::vector< std::pair
< unsigned int, unsigned int > > 
fifthStepKfTrack_
 
float firstBrem
 
std::vector< bool > GsfTrackSingleEcal_
 
float HOverHE
 
float HOverPin
 
bool isvalid_
 
float lateBrem
 
float lnPt_gsf
 
std::vector< bool > lockExtraKf_
 
double mvaEleCut_
 
const char * mvaWeightFile_
 
float nhit_gsf
 
float nhit_kf
 
unsigned int nTrackIsoForEgammaSC_
 
float SigmaEtaEta
 
double sumEtEcalIsoForEgammaSC_barrel_
 
double sumEtEcalIsoForEgammaSC_endcap_
 
double sumPtTrackIsoForEgammaSC_barrel_
 
double sumPtTrackIsoForEgammaSC_endcap_
 
const std::vector
< reco::GsfElectron > * 
theGsfElectrons_
 
boost::shared_ptr
< PFEnergyCalibration
thePFEnergyCalibration_
 
boost::shared_ptr
< PFSCEnergyCalibration
thePFSCEnergyCalibration_
 
TMVA::Reader * tmvaReader_
 
bool useEGammaSupercluster_
 
bool useEGElectrons_
 
bool usePFSCEleCalib_
 

Detailed Description

Definition at line 26 of file PFElectronAlgo.h.

Member Typedef Documentation

typedef std::map< unsigned int, std::vector<unsigned int> > PFElectronAlgo::AssMap
private

Definition at line 71 of file PFElectronAlgo.h.

Constructor & Destructor Documentation

PFElectronAlgo::PFElectronAlgo ( const double  mvaEleCut,
std::string  mvaWeightFileEleID,
const boost::shared_ptr< PFSCEnergyCalibration > &  thePFSCEnergyCalibration,
const boost::shared_ptr< PFEnergyCalibration > &  thePFEnergyCalibration,
bool  applyCrackCorrections,
bool  usePFSCEleCalib,
bool  useEGElectrons,
bool  useEGammaSupercluster,
double  sumEtEcalIsoForEgammaSC_barrel,
double  sumEtEcalIsoForEgammaSC_endcap,
double  coneEcalIsoForEgammaSC,
double  sumPtTrackIsoForEgammaSC_barrel,
double  sumPtTrackIsoForEgammaSC_endcap,
unsigned int  nTrackIsoForEgammaSC,
double  coneTrackIsoForEgammaSC 
)

Definition at line 32 of file PFElectronAlgo.cc.

References chi2_gsf, chi2_kf, DEtaGsfEcalClust, DPtOverPt_gsf, dPtOverPt_gsf, EGsfPoutMode, Eta_gsf, EtotBremPinPoutMode, EtotPinMode, firstBrem, HOverHE, lateBrem, lnPt_gsf, nhit_kf, SigmaEtaEta, and tmvaReader_.

46  :
47  mvaEleCut_(mvaEleCut),
48  thePFSCEnergyCalibration_(thePFSCEnergyCalibration),
49  thePFEnergyCalibration_(thePFEnergyCalibration),
50  applyCrackCorrections_(applyCrackCorrections),
51  usePFSCEleCalib_(usePFSCEleCalib),
52  useEGElectrons_(useEGElectrons),
53  useEGammaSupercluster_(useEGammaSupercluster),
54  sumEtEcalIsoForEgammaSC_barrel_(sumEtEcalIsoForEgammaSC_barrel),
55  sumEtEcalIsoForEgammaSC_endcap_(sumEtEcalIsoForEgammaSC_endcap),
56  coneEcalIsoForEgammaSC_(coneEcalIsoForEgammaSC),
57  sumPtTrackIsoForEgammaSC_barrel_(sumPtTrackIsoForEgammaSC_barrel),
58  sumPtTrackIsoForEgammaSC_endcap_(sumPtTrackIsoForEgammaSC_endcap),
59  nTrackIsoForEgammaSC_(nTrackIsoForEgammaSC),
60  coneTrackIsoForEgammaSC_(coneTrackIsoForEgammaSC)
61 {
62  // Set the tmva reader
63  tmvaReader_ = new TMVA::Reader("!Color:Silent");
64  tmvaReader_->AddVariable("lnPt_gsf",&lnPt_gsf);
65  tmvaReader_->AddVariable("Eta_gsf",&Eta_gsf);
66  tmvaReader_->AddVariable("dPtOverPt_gsf",&dPtOverPt_gsf);
67  tmvaReader_->AddVariable("DPtOverPt_gsf",&DPtOverPt_gsf);
68  //tmvaReader_->AddVariable("nhit_gsf",&nhit_gsf);
69  tmvaReader_->AddVariable("chi2_gsf",&chi2_gsf);
70  //tmvaReader_->AddVariable("DPtOverPt_kf",&DPtOverPt_kf);
71  tmvaReader_->AddVariable("nhit_kf",&nhit_kf);
72  tmvaReader_->AddVariable("chi2_kf",&chi2_kf);
73  tmvaReader_->AddVariable("EtotPinMode",&EtotPinMode);
74  tmvaReader_->AddVariable("EGsfPoutMode",&EGsfPoutMode);
75  tmvaReader_->AddVariable("EtotBremPinPoutMode",&EtotBremPinPoutMode);
76  tmvaReader_->AddVariable("DEtaGsfEcalClust",&DEtaGsfEcalClust);
77  tmvaReader_->AddVariable("SigmaEtaEta",&SigmaEtaEta);
78  tmvaReader_->AddVariable("HOverHE",&HOverHE);
79 // tmvaReader_->AddVariable("HOverPin",&HOverPin);
80  tmvaReader_->AddVariable("lateBrem",&lateBrem);
81  tmvaReader_->AddVariable("firstBrem",&firstBrem);
82  tmvaReader_->BookMVA("BDT",mvaWeightFileEleID.c_str());
83 }
float EtotBremPinPoutMode
double coneEcalIsoForEgammaSC_
TMVA::Reader * tmvaReader_
double sumEtEcalIsoForEgammaSC_barrel_
double sumEtEcalIsoForEgammaSC_endcap_
double sumPtTrackIsoForEgammaSC_endcap_
boost::shared_ptr< PFSCEnergyCalibration > thePFSCEnergyCalibration_
double coneTrackIsoForEgammaSC_
double sumPtTrackIsoForEgammaSC_barrel_
unsigned int nTrackIsoForEgammaSC_
boost::shared_ptr< PFEnergyCalibration > thePFEnergyCalibration_
bool applyCrackCorrections_
bool useEGammaSupercluster_
PFElectronAlgo::~PFElectronAlgo ( )
inline

Definition at line 47 of file PFElectronAlgo.h.

References tmvaReader_.

47 {delete tmvaReader_;};
TMVA::Reader * tmvaReader_

Member Function Documentation

unsigned int PFElectronAlgo::FindClosestElement ( const unsigned int  iele,
std::multimap< double, unsigned int > &  Elems,
float &  chi2cut,
std::vector< bool > &  active,
const reco::PFBlockRef blockRef 
)
private
const std::vector<reco::PFCandidate>& PFElectronAlgo::getAllElectronCandidates ( )
inline

Definition at line 62 of file PFElectronAlgo.h.

References allElCandidate_.

Referenced by PFAlgo::processBlock().

62 {return allElCandidate_;};
std::vector< reco::PFCandidate > allElCandidate_
const std::vector<reco::PFCandidate>& PFElectronAlgo::getElectronCandidates ( )
inline

Definition at line 59 of file PFElectronAlgo.h.

References elCandidate_.

Referenced by PFAlgo::processBlock().

59 {return elCandidate_;};
std::vector< reco::PFCandidate > elCandidate_
const std::vector< reco::PFCandidateElectronExtra>& PFElectronAlgo::getElectronExtra ( )
inline

Definition at line 65 of file PFElectronAlgo.h.

References electronExtra_.

Referenced by PFAlgo::processBlock().

65 {return electronExtra_;};
std::vector< reco::PFCandidateElectronExtra > electronExtra_
bool PFElectronAlgo::isElectronValidCandidate ( const reco::PFBlockRef blockRef,
std::vector< bool > &  active,
const reco::Vertex primaryVertex 
)
inline

Definition at line 50 of file PFElectronAlgo.h.

References isvalid_, and RunPFElectron().

Referenced by PFAlgo::processBlock().

53  {
54  isvalid_=false;
55  RunPFElectron(blockRef,active, primaryVertex);
56  return isvalid_;};
void RunPFElectron(const reco::PFBlockRef &blockRef, std::vector< bool > &active, const reco::Vertex &primaryVertex)
bool PFElectronAlgo::isPrimaryTrack ( const reco::PFBlockElementTrack KfEl,
const reco::PFBlockElementGsfTrack GsfEl 
)
private

Definition at line 2695 of file PFElectronAlgo.cc.

References reco::PFBlockElementGsfTrack::GsftrackRefPF(), edm::Ref< C, T, F >::isNonnull(), and reco::PFBlockElementTrack::trackRefPF().

Referenced by SetCandidates(), SetIDOutputs(), and SetLinks().

2696  {
2697  bool isPrimary = false;
2698 
2699  GsfPFRecTrackRef gsfPfRef = GsfEl.GsftrackRefPF();
2700 
2701  if(gsfPfRef.isNonnull()) {
2702  PFRecTrackRef kfPfRef = KfEl.trackRefPF();
2703  PFRecTrackRef kfPfRef_fromGsf = (*gsfPfRef).kfPFRecTrackRef();
2704  if(kfPfRef.isNonnull() && kfPfRef_fromGsf.isNonnull()) {
2705  reco::TrackRef kfref= (*kfPfRef).trackRef();
2706  reco::TrackRef kfref_fromGsf = (*kfPfRef_fromGsf).trackRef();
2707  if(kfref.isNonnull() && kfref_fromGsf.isNonnull()) {
2708  if(kfref == kfref_fromGsf)
2709  isPrimary = true;
2710  }
2711  }
2712  }
2713 
2714  return isPrimary;
2715 }
bool isNonnull() const
Checks for non-null.
Definition: Ref.h:250
const GsfPFRecTrackRef & GsftrackRefPF() const
const PFRecTrackRef & trackRefPF() const
void PFElectronAlgo::RunPFElectron ( const reco::PFBlockRef blockRef,
std::vector< bool > &  active,
const reco::Vertex primaryVertex 
)
private

Definition at line 84 of file PFElectronAlgo.cc.

References allElCandidate_, BDToutput_, convGsfTrack_, elCandidate_, electronConstituents_, electronExtra_, fifthStepKfTrack_, isvalid_, lockExtraKf_, SetActive(), SetCandidates(), SetIDOutputs(), and SetLinks().

Referenced by isElectronValidCandidate().

86  {
87 
88  // the maps are initialized
89  AssMap associatedToGsf;
90  AssMap associatedToBrems;
91  AssMap associatedToEcal;
92 
93  // should be cleaned as often as often as possible
94  elCandidate_.clear();
95  electronExtra_.clear();
96  allElCandidate_.clear();
97  electronConstituents_.clear();
98  fifthStepKfTrack_.clear();
99  convGsfTrack_.clear();
100  // SetLinks finds all the elements (kf,ecal,ps,hcal,brems)
101  // associated to each gsf track
102  bool blockHasGSF = SetLinks(blockRef,associatedToGsf,
103  associatedToBrems,associatedToEcal,
104  active, primaryVertex);
105 
106  // check if there is at least a gsf track in the block.
107  if (blockHasGSF) {
108 
109  BDToutput_.clear();
110 
111  lockExtraKf_.clear();
112  // For each GSF track is initialized a BDT value = -1
113  BDToutput_.assign(associatedToGsf.size(),-1.);
114  lockExtraKf_.assign(associatedToGsf.size(),true);
115 
116  // The FinalID is run and BDToutput values is assigned
117  SetIDOutputs(blockRef,associatedToGsf,associatedToBrems,associatedToEcal,primaryVertex);
118 
119  // For each GSF track that pass the BDT configurable cut a pf candidate electron is created.
120  // This function finds also the best estimation of the initial electron 4-momentum.
121 
122  SetCandidates(blockRef,associatedToGsf,associatedToBrems,associatedToEcal);
123  if (elCandidate_.size() > 0 ){
124  isvalid_ = true;
125  // when a pfelectron candidate is created all the elements associated to the
126  // electron are locked.
127  SetActive(blockRef,associatedToGsf,associatedToBrems,associatedToEcal,active);
128  }
129  } // endif blockHasGSF
130 }
std::vector< std::pair< unsigned int, unsigned int > > fifthStepKfTrack_
bool SetLinks(const reco::PFBlockRef &blockRef, AssMap &associatedToGsf_, AssMap &associatedToBrems_, AssMap &associatedToEcal_, std::vector< bool > &active, const reco::Vertex &primaryVertex)
std::map< unsigned int, std::vector< unsigned int > > AssMap
void SetCandidates(const reco::PFBlockRef &blockRef, AssMap &associatedToGsf_, AssMap &associatedToBrems_, AssMap &associatedToEcal_)
std::vector< std::pair< unsigned int, unsigned int > > convGsfTrack_
std::vector< reco::PFCandidateElectronExtra > electronExtra_
void SetActive(const reco::PFBlockRef &blockRef, AssMap &associatedToGsf_, AssMap &associatedToBrems_, AssMap &associatedToEcal_, std::vector< bool > &active)
std::vector< bool > lockExtraKf_
std::vector< double > BDToutput_
void SetIDOutputs(const reco::PFBlockRef &blockRef, AssMap &associatedToGsf_, AssMap &associatedToBrems_, AssMap &associatedToEcal_, const reco::Vertex &primaryVertex)
std::map< unsigned int, std::vector< reco::PFCandidate > > electronConstituents_
std::vector< reco::PFCandidate > elCandidate_
std::vector< reco::PFCandidate > allElCandidate_
void PFElectronAlgo::SetActive ( const reco::PFBlockRef blockRef,
AssMap associatedToGsf_,
AssMap associatedToBrems_,
AssMap associatedToEcal_,
std::vector< bool > &  active 
)
private

Definition at line 2543 of file PFElectronAlgo.cc.

References reco::PFBlock::associatedElements(), BDToutput_, createPayload::block, reco::PFBlockElement::BREM, convGsfTrack_, reco::PFBlockElement::ECAL, reco::PFBlock::elements(), asciidump::elements, fifthStepKfTrack_, first, reco::PFBlockElementGsfTrack::GsftrackRef(), reco::PFBlock::linkData(), reco::PFBlock::LINKTEST_ALL, lockExtraKf_, python.multivaluedict::map(), mvaEleCut_, reco::PFBlockElement::PS1, reco::PFBlockElement::PS2, edm::second(), theGsfElectrons_, reco::PFBlockElement::TRACK, and useEGElectrons_.

Referenced by RunPFElectron().

2547  {
2548  const reco::PFBlock& block = *blockRef;
2549  PFBlock::LinkData linkData = block.linkData();
2550 
2552 
2553  unsigned int cgsf=0;
2554  for (map<unsigned int,vector<unsigned int> >::iterator igsf = associatedToGsf_.begin();
2555  igsf != associatedToGsf_.end(); igsf++,cgsf++) {
2556 
2557  unsigned int gsf_index = igsf->first;
2558  const reco::PFBlockElementGsfTrack * GsfEl =
2559  dynamic_cast<const reco::PFBlockElementGsfTrack*>((&elements[gsf_index]));
2560  reco::GsfTrackRef RefGSF = GsfEl->GsftrackRef();
2561 
2562  // lock only the elements that pass the BDT cut
2563  bool bypassmva=false;
2564  if(useEGElectrons_) {
2565  GsfElectronEqual myEqual(RefGSF);
2566  std::vector<reco::GsfElectron>::const_iterator itcheck=find_if(theGsfElectrons_->begin(),theGsfElectrons_->end(),myEqual);
2567  if(itcheck!=theGsfElectrons_->end()) {
2568  if(BDToutput_[cgsf] >= -1.)
2569  bypassmva=true;
2570  }
2571  }
2572 
2573  if(BDToutput_[cgsf] < mvaEleCut_ && bypassmva == false) continue;
2574 
2575 
2576  active[gsf_index] = false; // lock the gsf
2577  vector<unsigned int> assogsf_index = igsf->second;
2578  for (unsigned int ielegsf=0;ielegsf<assogsf_index.size();ielegsf++) {
2579  PFBlockElement::Type assoele_type = elements[(assogsf_index[ielegsf])].type();
2580  // lock the elements associated to the gsf: ECAL, Brems
2581  active[(assogsf_index[ielegsf])] = false;
2582  if (assoele_type == reco::PFBlockElement::ECAL) {
2583  unsigned int keyecalgsf = assogsf_index[ielegsf];
2584 
2585  // added protection against fifth step
2586  if(fifthStepKfTrack_.size() > 0) {
2587  for(unsigned int itr = 0; itr < fifthStepKfTrack_.size(); itr++) {
2588  if(fifthStepKfTrack_[itr].first == keyecalgsf) {
2589  active[(fifthStepKfTrack_[itr].second)] = false;
2590  }
2591  }
2592  }
2593 
2594  // added locking for conv gsf tracks and kf tracks
2595  if(convGsfTrack_.size() > 0) {
2596  for(unsigned int iconv = 0; iconv < convGsfTrack_.size(); iconv++) {
2597  if(convGsfTrack_[iconv].first == keyecalgsf) {
2598  // lock the GSF track
2599  active[(convGsfTrack_[iconv].second)] = false;
2600  // lock also the KF track associated
2601  std::multimap<double, unsigned> convKf;
2602  block.associatedElements( convGsfTrack_[iconv].second,
2603  linkData,
2604  convKf,
2607  if(convKf.size() > 0) {
2608  active[convKf.begin()->second] = false;
2609  }
2610  }
2611  }
2612  }
2613 
2614 
2615  vector<unsigned int> assoecalgsf_index = associatedToEcal_.find(keyecalgsf)->second;
2616  for(unsigned int ips =0; ips<assoecalgsf_index.size();ips++) {
2617  // lock the elements associated to ECAL: PS1,PS2, for the moment not HCAL
2618  if (elements[(assoecalgsf_index[ips])].type() == reco::PFBlockElement::PS1)
2619  active[(assoecalgsf_index[ips])] = false;
2620  if (elements[(assoecalgsf_index[ips])].type() == reco::PFBlockElement::PS2)
2621  active[(assoecalgsf_index[ips])] = false;
2622  if (elements[(assoecalgsf_index[ips])].type() == reco::PFBlockElement::TRACK) {
2623  if(lockExtraKf_[cgsf] == true) {
2624  active[(assoecalgsf_index[ips])] = false;
2625  }
2626  }
2627  }
2628  } // End if ECAL
2629  if (assoele_type == reco::PFBlockElement::BREM) {
2630  unsigned int brem_index = assogsf_index[ielegsf];
2631  vector<unsigned int> assobrem_index = associatedToBrems_.find(brem_index)->second;
2632  for (unsigned int ibrem = 0; ibrem < assobrem_index.size(); ibrem++){
2633  if (elements[(assobrem_index[ibrem])].type() == reco::PFBlockElement::ECAL) {
2634  unsigned int keyecalbrem = assobrem_index[ibrem];
2635  // lock the ecal cluster associated to the brem
2636  active[(assobrem_index[ibrem])] = false;
2637 
2638  // add protection against fifth step
2639  if(fifthStepKfTrack_.size() > 0) {
2640  for(unsigned int itr = 0; itr < fifthStepKfTrack_.size(); itr++) {
2641  if(fifthStepKfTrack_[itr].first == keyecalbrem) {
2642  active[(fifthStepKfTrack_[itr].second)] = false;
2643  }
2644  }
2645  }
2646 
2647  vector<unsigned int> assoelebrem_index = associatedToEcal_.find(keyecalbrem)->second;
2648  // lock the elements associated to ECAL: PS1,PS2, for the moment not HCAL
2649  for (unsigned int ielebrem=0; ielebrem<assoelebrem_index.size();ielebrem++) {
2650  if (elements[(assoelebrem_index[ielebrem])].type() == reco::PFBlockElement::PS1)
2651  active[(assoelebrem_index[ielebrem])] = false;
2652  if (elements[(assoelebrem_index[ielebrem])].type() == reco::PFBlockElement::PS2)
2653  active[(assoelebrem_index[ielebrem])] = false;
2654  }
2655  }
2656  }
2657  } // End if BREM
2658  } // End loop on elements from gsf track
2659  } // End loop on gsf track
2660  return;
2661 }
std::vector< std::pair< unsigned int, unsigned int > > fifthStepKfTrack_
type
Definition: HCALResponse.h:21
const reco::GsfTrackRef & GsftrackRef() const
std::vector< std::pair< unsigned int, unsigned int > > convGsfTrack_
std::map< unsigned int, Link > LinkData
Definition: PFBlock.h:46
list elements
Definition: asciidump.py:414
const std::vector< reco::GsfElectron > * theGsfElectrons_
const edm::OwnVector< reco::PFBlockElement > & elements() const
Definition: PFBlock.h:107
const LinkData & linkData() const
Definition: PFBlock.h:112
U second(std::pair< T, U > const &p)
std::vector< bool > lockExtraKf_
std::vector< double > BDToutput_
bool first
Definition: L1TdeRCT.cc:75
void associatedElements(unsigned i, const LinkData &linkData, std::multimap< double, unsigned > &sortedAssociates, reco::PFBlockElement::Type type=PFBlockElement::NONE, LinkTest test=LINKTEST_RECHIT) const
Definition: PFBlock.cc:75
Block of elements.
Definition: PFBlock.h:30
void PFElectronAlgo::SetCandidates ( const reco::PFBlockRef blockRef,
AssMap associatedToGsf_,
AssMap associatedToBrems_,
AssMap associatedToEcal_ 
)
private

Definition at line 1907 of file PFElectronAlgo.cc.

References reco::CompositeCandidate::addDaughter(), reco::PFCandidate::addElementInBlock(), allElCandidate_, applyCrackCorrections_, reco::PFBlock::associatedElements(), BDToutput_, createPayload::block, reco::PFBlockElement::BREM, GetRecoTauVFromDQM_MC_cff::cl, reco::PFBlockElementCluster::clusterRef(), gather_cfg::cout, reco::PFCandidate::e, reco::PFBlockElement::ECAL, HWWFunctions::EE, elCandidate_, electronConstituents_, electronExtra_, reco::PFBlock::elements(), asciidump::elements, reco::PFCandidate::gamma, edm::Ref< C, T, F >::get(), PFEnergyResolution::getEnergyResolutionEm(), reco::PFBlockElementGsfTrack::GsftrackRef(), reco::PFBlockElement::HCAL, patCandidatesForDimuonsSequences_cff::hcal, edm::Ref< C, T, F >::isAvailable(), edm::Ref< C, T, F >::isNonnull(), isPrimaryTrack(), reco::PFBlock::linkData(), reco::PFBlock::LINKTEST_ALL, M_PI, python.multivaluedict::map(), mvaEleCut_, nhit_gsf, nhit_kf, objects.autophobj::particleType, PFClusterWidthAlgo::pflowEtaWidth(), PFClusterWidthAlgo::pflowPhiWidth(), reco::PFBlockElementBrem::positionAtECALEntrance(), reco::PFBlockElementGsfTrack::positionAtECALEntrance(), reco::PFBlockElement::PS1, reco::PFBlockElement::PS2, pileupReCalc_HLTpaths::scale, reco::PFCandidate::set_mva_e_pi(), reco::PFCandidate::setEcalEnergy(), reco::PFCandidate::setGsfTrackRef(), reco::PFCandidate::setHcalEnergy(), reco::PFCandidate::setPositionAtECALEntrance(), reco::PFCandidate::setPs1Energy(), reco::PFCandidate::setPs2Energy(), reco::PFCandidate::setSuperClusterRef(), reco::PFCandidate::setTrackRef(), reco::PFCandidate::setVertexSource(), funct::sin(), mathSSE::sqrt(), theGsfElectrons_, thePFEnergyCalibration_, thePFSCEnergyCalibration_, reco::PFBlockElement::TRACK, reco::PFBlockElementTrack::trackRef(), useEGElectrons_, and usePFSCEleCalib_.

Referenced by RunPFElectron().

1910  {
1911 
1912  const reco::PFBlock& block = *blockRef;
1913  PFBlock::LinkData linkData = block.linkData();
1915  PFEnergyResolution pfresol_;
1916  //PFEnergyCalibration pfcalib_;
1917 
1918  bool DebugIDCandidates = false;
1919 // vector<reco::PFCluster> pfClust_vec(0);
1920 // pfClust_vec.clear();
1921 
1922  unsigned int cgsf=0;
1923  for (map<unsigned int,vector<unsigned int> >::iterator igsf = associatedToGsf_.begin();
1924  igsf != associatedToGsf_.end(); igsf++,cgsf++) {
1925  unsigned int gsf_index = igsf->first;
1926 
1927 
1928 
1929  // They should be reset for each gsf track
1930  int eecal=0;
1931  int hcal=0;
1932  int charge =0;
1933  // bool goodphi=true;
1934  math::XYZTLorentzVector momentum_kf,momentum_gsf,momentum,momentum_mean;
1935  float dpt=0; float dpt_gsf=0;
1936  float Eene=0; float dene=0; float Hene=0.;
1937  float RawEene = 0.;
1938  double posX=0.;
1939  double posY=0.;
1940  double posZ=0.;
1941  std::vector<float> bremEnergyVec;
1942 
1943  std::vector<const PFCluster*> pfSC_Clust_vec;
1944 
1945  float de_gs = 0., de_me = 0., de_kf = 0.;
1946  float m_el=0.00051;
1947  int nhit_kf=0; int nhit_gsf=0;
1948  bool has_gsf=false;
1949  bool has_kf=false;
1950  math::XYZTLorentzVector newmomentum;
1951  float ps1TotEne = 0;
1952  float ps2TotEne = 0;
1953  vector<unsigned int> elementsToAdd(0);
1954  reco::TrackRef RefKF;
1955 
1956 
1957 
1958  elementsToAdd.push_back(gsf_index);
1959  const reco::PFBlockElementGsfTrack * GsfEl =
1960  dynamic_cast<const reco::PFBlockElementGsfTrack*>((&elements[gsf_index]));
1961  const math::XYZPointF& posGsfEcalEntrance = GsfEl->positionAtECALEntrance();
1962  reco::GsfTrackRef RefGSF = GsfEl->GsftrackRef();
1963  if (RefGSF.isNonnull()) {
1964 
1965  has_gsf=true;
1966 
1967  charge= RefGSF->chargeMode();
1968  nhit_gsf= RefGSF->hitPattern().trackerLayersWithMeasurement();
1969 
1970  momentum_gsf.SetPx(RefGSF->pxMode());
1971  momentum_gsf.SetPy(RefGSF->pyMode());
1972  momentum_gsf.SetPz(RefGSF->pzMode());
1973  float ENE=sqrt(RefGSF->pMode()*
1974  RefGSF->pMode()+m_el*m_el);
1975 
1976  if( DebugIDCandidates )
1977  cout << "SetCandidates:: GsfTrackRef: Ene " << ENE
1978  << " charge " << charge << " nhits " << nhit_gsf <<endl;
1979 
1980  momentum_gsf.SetE(ENE);
1981  dpt_gsf=RefGSF->ptModeError()*
1982  (RefGSF->pMode()/RefGSF->ptMode());
1983 
1984  momentum_mean.SetPx(RefGSF->px());
1985  momentum_mean.SetPy(RefGSF->py());
1986  momentum_mean.SetPz(RefGSF->pz());
1987  float ENEm=sqrt(RefGSF->p()*
1988  RefGSF->p()+m_el*m_el);
1989  momentum_mean.SetE(ENEm);
1990  // dpt_mean=RefGSF->ptError()*
1991  // (RefGSF->p()/RefGSF->pt());
1992  }
1993  else {
1994  if( DebugIDCandidates )
1995  cout << "SetCandidates:: !!!! NULL GSF Track Ref " << endl;
1996  }
1997 
1998  // vector<unsigned int> assogsf_index = associatedToGsf_[igsf].second;
1999  vector<unsigned int> assogsf_index = igsf->second;
2000  unsigned int ecalGsf_index = 100000;
2001  bool FirstEcalGsf = true;
2002  for (unsigned int ielegsf=0;ielegsf<assogsf_index.size();ielegsf++) {
2003  PFBlockElement::Type assoele_type = elements[(assogsf_index[ielegsf])].type();
2004  if (assoele_type == reco::PFBlockElement::TRACK) {
2005  elementsToAdd.push_back((assogsf_index[ielegsf])); // Daniele
2006  const reco::PFBlockElementTrack * KfTk =
2007  dynamic_cast<const reco::PFBlockElementTrack*>((&elements[(assogsf_index[ielegsf])]));
2008  // 19 Mar 2010 do not consider here track from gamam conv
2009  bool isPrim = isPrimaryTrack(*KfTk,*GsfEl);
2010  if(!isPrim) continue;
2011 
2012  RefKF = KfTk->trackRef();
2013  if (RefKF.isNonnull()) {
2014  has_kf = true;
2015  // dpt_kf=(RefKF->ptError()*RefKF->ptError());
2016  nhit_kf=RefKF->hitPattern().trackerLayersWithMeasurement();
2017  momentum_kf.SetPx(RefKF->px());
2018  momentum_kf.SetPy(RefKF->py());
2019  momentum_kf.SetPz(RefKF->pz());
2020  float ENE=sqrt(RefKF->p()*RefKF->p()+m_el*m_el);
2021  if( DebugIDCandidates )
2022  cout << "SetCandidates:: KFTrackRef: Ene " << ENE << " nhits " << nhit_kf << endl;
2023 
2024  momentum_kf.SetE(ENE);
2025  }
2026  else {
2027  if( DebugIDCandidates )
2028  cout << "SetCandidates:: !!!! NULL KF Track Ref " << endl;
2029  }
2030  }
2031 
2032  if (assoele_type == reco::PFBlockElement::ECAL) {
2033  unsigned int keyecalgsf = assogsf_index[ielegsf];
2034  vector<unsigned int> assoecalgsf_index = associatedToEcal_.find(keyecalgsf)->second;
2035  vector<double> ps1Ene(0);
2036  vector<double> ps2Ene(0);
2037  // Important is the PS clusters are not saved before the ecal one, these
2038  // energy are not correctly assigned
2039  // For the moment I get only the closest PS clusters: this has to be changed
2040  for(unsigned int ips =0; ips<assoecalgsf_index.size();ips++) {
2041  PFBlockElement::Type typeassoecal = elements[(assoecalgsf_index[ips])].type();
2042  if (typeassoecal == reco::PFBlockElement::PS1) {
2043  PFClusterRef psref = elements[(assoecalgsf_index[ips])].clusterRef();
2044  ps1Ene.push_back(psref->energy());
2045  elementsToAdd.push_back((assoecalgsf_index[ips]));
2046  }
2047  if (typeassoecal == reco::PFBlockElement::PS2) {
2048  PFClusterRef psref = elements[(assoecalgsf_index[ips])].clusterRef();
2049  ps2Ene.push_back(psref->energy());
2050  elementsToAdd.push_back((assoecalgsf_index[ips]));
2051  }
2052  if (typeassoecal == reco::PFBlockElement::HCAL) {
2053  const reco::PFBlockElementCluster * clust =
2054  dynamic_cast<const reco::PFBlockElementCluster*>((&elements[(assoecalgsf_index[ips])]));
2055  elementsToAdd.push_back((assoecalgsf_index[ips]));
2056  Hene+=clust->clusterRef()->energy();
2057  hcal++;
2058  }
2059  }
2060  elementsToAdd.push_back((assogsf_index[ielegsf]));
2061 
2062 
2063  const reco::PFBlockElementCluster * clust =
2064  dynamic_cast<const reco::PFBlockElementCluster*>((&elements[(assogsf_index[ielegsf])]));
2065 
2066  eecal++;
2067 
2068  const reco::PFCluster& cl(*clust->clusterRef());
2069  //pfClust_vec.push_back((*clust->clusterRef()));
2070 
2071  // The electron RAW energy is the energy of the corrected GSF cluster
2072  double ps1,ps2;
2073  ps1=ps2=0.;
2074  // float EE=pfcalib_.energyEm(cl,ps1Ene,ps2Ene);
2075  float EE = thePFEnergyCalibration_->energyEm(cl,ps1Ene,ps2Ene,ps1,ps2,applyCrackCorrections_);
2076  // float RawEE = cl.energy();
2077 
2078  float ceta=cl.position().eta();
2079  float cphi=cl.position().phi();
2080 
2081  /*
2082  float mphi=-2.97025;
2083  if (ceta<0) mphi+=0.00638;
2084 
2085  for (int ip=1; ip<19; ip++){
2086  float df= cphi - (mphi+(ip*6.283185/18));
2087  if (fabs(df)<0.01) goodphi=false;
2088  }
2089  */
2090 
2091  float dE=pfresol_.getEnergyResolutionEm(EE,cl.position().eta());
2092  if( DebugIDCandidates )
2093  cout << "SetCandidates:: EcalCluster: EneNoCalib " << clust->clusterRef()->energy()
2094  << " eta,phi " << ceta << "," << cphi << " Calib " << EE << " dE " << dE <<endl;
2095 
2096  bool elecCluster=false;
2097  if (FirstEcalGsf) {
2098  FirstEcalGsf = false;
2099  elecCluster=true;
2100  ecalGsf_index = assogsf_index[ielegsf];
2101  // std::cout << " PFElectronAlgo / Seed " << EE << std::endl;
2102  RawEene += EE;
2103  }
2104 
2105  // create a photon/electron candidate
2106  math::XYZTLorentzVector clusterMomentum;
2107  math::XYZPoint direction=cl.position()/cl.position().R();
2108  clusterMomentum.SetPxPyPzE(EE*direction.x(),
2109  EE*direction.y(),
2110  EE*direction.z(),
2111  EE);
2112  reco::PFCandidate cluster_Candidate((elecCluster)?charge:0,
2113  clusterMomentum,
2115 
2116  cluster_Candidate.setPs1Energy(ps1);
2117  cluster_Candidate.setPs2Energy(ps2);
2118  // The Raw Ecal energy will be the energy of the basic cluster.
2119  // It will be the corrected energy without the preshower
2120  cluster_Candidate.setEcalEnergy(EE-ps1-ps2,EE);
2121  // std::cout << " PFElectronAlgo, adding Brem (1) " << EE << std::endl;
2122  cluster_Candidate.setPositionAtECALEntrance(math::XYZPointF(cl.position()));
2123  cluster_Candidate.addElementInBlock(blockRef,assogsf_index[ielegsf]);
2124  // store the photon candidate
2125  std::map<unsigned int,std::vector<reco::PFCandidate> >::iterator itcheck=
2126  electronConstituents_.find(cgsf);
2127  if(itcheck==electronConstituents_.end())
2128  {
2129  // beurk
2130  std::vector<reco::PFCandidate> tmpVec;
2131  tmpVec.push_back(cluster_Candidate);
2132  electronConstituents_.insert(std::pair<unsigned int, std::vector<reco::PFCandidate> >
2133  (cgsf,tmpVec));
2134  }
2135  else
2136  {
2137  itcheck->second.push_back(cluster_Candidate);
2138  }
2139 
2140  Eene+=EE;
2141  posX += EE * cl.position().X();
2142  posY += EE * cl.position().Y();
2143  posZ += EE * cl.position().Z();
2144  ps1TotEne+=ps1;
2145  ps2TotEne+=ps2;
2146  dene+=dE*dE;
2147 
2148  //MM Add cluster to the vector pfSC_Clust_vec needed for brem corrections
2149  pfSC_Clust_vec.push_back( &cl );
2150 
2151  }
2152 
2153 
2154 
2155  // Important: Add energy from the brems
2156  if (assoele_type == reco::PFBlockElement::BREM) {
2157  unsigned int brem_index = assogsf_index[ielegsf];
2158  vector<unsigned int> assobrem_index = associatedToBrems_.find(brem_index)->second;
2159  elementsToAdd.push_back(brem_index);
2160  for (unsigned int ibrem = 0; ibrem < assobrem_index.size(); ibrem++){
2161  if (elements[(assobrem_index[ibrem])].type() == reco::PFBlockElement::ECAL) {
2162  // brem emission is from the considered gsf track
2163  if( assobrem_index[ibrem] != ecalGsf_index) {
2164  unsigned int keyecalbrem = assobrem_index[ibrem];
2165  const vector<unsigned int>& assoelebrem_index = associatedToEcal_.find(keyecalbrem)->second;
2166  vector<double> ps1EneFromBrem(0);
2167  vector<double> ps2EneFromBrem(0);
2168  for (unsigned int ielebrem=0; ielebrem<assoelebrem_index.size();ielebrem++) {
2169  if (elements[(assoelebrem_index[ielebrem])].type() == reco::PFBlockElement::PS1) {
2170  PFClusterRef psref = elements[(assoelebrem_index[ielebrem])].clusterRef();
2171  ps1EneFromBrem.push_back(psref->energy());
2172  elementsToAdd.push_back(assoelebrem_index[ielebrem]);
2173  }
2174  if (elements[(assoelebrem_index[ielebrem])].type() == reco::PFBlockElement::PS2) {
2175  PFClusterRef psref = elements[(assoelebrem_index[ielebrem])].clusterRef();
2176  ps2EneFromBrem.push_back(psref->energy());
2177  elementsToAdd.push_back(assoelebrem_index[ielebrem]);
2178  }
2179  }
2180  elementsToAdd.push_back(assobrem_index[ibrem]);
2181  reco::PFClusterRef clusterRef = elements[(assobrem_index[ibrem])].clusterRef();
2182  //pfClust_vec.push_back(*clusterRef);
2183  // to get a calibrated PS energy
2184  double ps1=0;
2185  double ps2=0;
2186  float EE = thePFEnergyCalibration_->energyEm(*clusterRef,ps1EneFromBrem,ps2EneFromBrem,ps1,ps2,applyCrackCorrections_);
2187  bremEnergyVec.push_back(EE);
2188  // float RawEE = clusterRef->energy();
2189  float ceta = clusterRef->position().eta();
2190  // float cphi = clusterRef->position().phi();
2191  float dE=pfresol_.getEnergyResolutionEm(EE,ceta);
2192  if( DebugIDCandidates )
2193  cout << "SetCandidates:: BremCluster: Ene " << EE << " dE " << dE <<endl;
2194 
2195  Eene+=EE;
2196  posX += EE * clusterRef->position().X();
2197  posY += EE * clusterRef->position().Y();
2198  posZ += EE * clusterRef->position().Z();
2199  ps1TotEne+=ps1;
2200  ps2TotEne+=ps2;
2201  // Removed 4 March 2009. Florian. The Raw energy is the (corrected) one of the GSF cluster only
2202  // RawEene += RawEE;
2203  dene+=dE*dE;
2204 
2205  //MM Add cluster to the vector pfSC_Clust_vec needed for brem corrections
2206  pfSC_Clust_vec.push_back( clusterRef.get() );
2207 
2208  // create a PFCandidate out of it. Watch out, it is for the e/gamma and tau only
2209  // not to be used by the PFAlgo
2210  math::XYZTLorentzVector photonMomentum;
2211  math::XYZPoint direction=clusterRef->position()/clusterRef->position().R();
2212 
2213  photonMomentum.SetPxPyPzE(EE*direction.x(),
2214  EE*direction.y(),
2215  EE*direction.z(),
2216  EE);
2217  reco::PFCandidate photon_Candidate(0,photonMomentum, reco::PFCandidate::gamma);
2218 
2219  photon_Candidate.setPs1Energy(ps1);
2220  photon_Candidate.setPs2Energy(ps2);
2221  // yes, EE, we want the raw ecal energy of the daugther to have the same definition
2222  // as the GSF cluster
2223  photon_Candidate.setEcalEnergy(EE-ps1-ps2,EE);
2224  // std::cout << " PFElectronAlgo, adding Brem " << EE << std::endl;
2225  photon_Candidate.setPositionAtECALEntrance(math::XYZPointF(clusterRef->position()));
2226  photon_Candidate.addElementInBlock(blockRef,assobrem_index[ibrem]);
2227 
2228  // store the photon candidate
2229  std::map<unsigned int,std::vector<reco::PFCandidate> >::iterator itcheck=
2230  electronConstituents_.find(cgsf);
2231  if(itcheck==electronConstituents_.end())
2232  {
2233  // beurk
2234  std::vector<reco::PFCandidate> tmpVec;
2235  tmpVec.push_back(photon_Candidate);
2236  electronConstituents_.insert(std::pair<unsigned int, std::vector<reco::PFCandidate> >
2237  (cgsf,tmpVec));
2238  }
2239  else
2240  {
2241  itcheck->second.push_back(photon_Candidate);
2242  }
2243  }
2244  }
2245  }
2246  }
2247  } // End Loop On element associated to the GSF tracks
2248  if (has_gsf) {
2249 
2250  // SuperCluster energy corrections
2251  double unCorrEene = Eene;
2252  double absEta = fabs(momentum_gsf.Eta());
2253  double emTheta = momentum_gsf.Theta();
2254  PFClusterWidthAlgo pfSCwidth(pfSC_Clust_vec);
2255  double brLinear = pfSCwidth.pflowPhiWidth()/pfSCwidth.pflowEtaWidth();
2256  pfSC_Clust_vec.clear();
2257 
2258  if( DebugIDCandidates )
2259  cout << "PFEelectronAlgo:: absEta " << absEta << " theta " << emTheta
2260  << " EneRaw " << Eene << " Err " << dene;
2261 
2262  // The calibrations are provided till ET = 200 GeV //No longer a such cut MM
2263  // Protection on at least 1 GeV energy...avoid possible divergencies at very low energy.
2264  if(usePFSCEleCalib_ && unCorrEene > 0.) {
2265  if( absEta < 1.5) {
2266  double Etene = Eene*sin(emTheta);
2267  double emBR_e = thePFSCEnergyCalibration_->SCCorrFBremBarrel(Eene, Etene, brLinear);
2268  double emBR_et = emBR_e*sin(emTheta);
2269  double emCorrFull_et = thePFSCEnergyCalibration_->SCCorrEtEtaBarrel(emBR_et, absEta);
2270  Eene = emCorrFull_et/sin(emTheta);
2271  }
2272  else {
2273  // double Etene = Eene*sin(emTheta); //not needed anymore for endcaps MM
2274  double emBR_e = thePFSCEnergyCalibration_->SCCorrFBremEndcap(Eene, absEta, brLinear);
2275  double emBR_et = emBR_e*sin(emTheta);
2276  double emCorrFull_et = thePFSCEnergyCalibration_->SCCorrEtEtaEndcap(emBR_et, absEta);
2277  Eene = emCorrFull_et/sin(emTheta);
2278  }
2279  dene = sqrt(dene)*(Eene/unCorrEene);
2280  dene = dene*dene;
2281  }
2282 
2283  if( DebugIDCandidates )
2284  cout << " EneCorrected " << Eene << " Err " << dene << endl;
2285 
2286  // charge determination with the majority method
2287  // if the kf track exists: 2 among 3 of supercluster barycenter position
2288  // gsf track and kf track
2289  if(has_kf && unCorrEene > 0.) {
2290  posX /=unCorrEene;
2291  posY /=unCorrEene;
2292  posZ /=unCorrEene;
2293  math::XYZPoint sc_pflow(posX,posY,posZ);
2294 
2295  std::multimap<double, unsigned int> bremElems;
2296  block.associatedElements( gsf_index,linkData,
2297  bremElems,
2300 
2301  double phiTrack = RefGSF->phiMode();
2302  if(bremElems.size()>0) {
2303  unsigned int brem_index = bremElems.begin()->second;
2304  const reco::PFBlockElementBrem * BremEl =
2305  dynamic_cast<const reco::PFBlockElementBrem*>((&elements[brem_index]));
2306  phiTrack = BremEl->positionAtECALEntrance().phi();
2307  }
2308 
2309  double dphi_normalsc = sc_pflow.Phi() - phiTrack;
2310  if ( dphi_normalsc < -M_PI )
2311  dphi_normalsc = dphi_normalsc + 2.*M_PI;
2312  else if ( dphi_normalsc > M_PI )
2313  dphi_normalsc = dphi_normalsc - 2.*M_PI;
2314 
2315  int chargeGsf = RefGSF->chargeMode();
2316  int chargeKf = RefKF->charge();
2317 
2318  int chargeSC = 0;
2319  if(dphi_normalsc < 0.)
2320  chargeSC = 1;
2321  else
2322  chargeSC = -1;
2323 
2324  if(chargeKf == chargeGsf)
2325  charge = chargeGsf;
2326  else if(chargeGsf == chargeSC)
2327  charge = chargeGsf;
2328  else
2329  charge = chargeKf;
2330 
2331  if( DebugIDCandidates )
2332  cout << "PFElectronAlgo:: charge determination "
2333  << " charge GSF " << chargeGsf
2334  << " charge KF " << chargeKf
2335  << " charge SC " << chargeSC
2336  << " Final Charge " << charge << endl;
2337 
2338  }
2339 
2340  // Think about this...
2341  if ((nhit_gsf<8) && (has_kf)){
2342 
2343  // Use Hene if some condition....
2344 
2345  momentum=momentum_kf;
2346  float Fe=Eene;
2347  float scale= Fe/momentum.E();
2348 
2349  // Daniele Changed
2350  if (Eene < 0.0001) {
2351  Fe = momentum.E();
2352  scale = 1.;
2353  }
2354 
2355 
2356  newmomentum.SetPxPyPzE(scale*momentum.Px(),
2357  scale*momentum.Py(),
2358  scale*momentum.Pz(),Fe);
2359  if( DebugIDCandidates )
2360  cout << "SetCandidates:: (nhit_gsf<8) && (has_kf):: pt " << newmomentum.pt() << " Ene " << Fe <<endl;
2361 
2362 
2363  }
2364  if ((nhit_gsf>7) || (has_kf==false)){
2365  if(Eene > 0.0001) {
2366  de_gs=1-momentum_gsf.E()/Eene;
2367  de_me=1-momentum_mean.E()/Eene;
2368  de_kf=1-momentum_kf.E()/Eene;
2369  }
2370 
2371  momentum=momentum_gsf;
2372  dpt=1/(dpt_gsf*dpt_gsf);
2373 
2374  if(dene > 0.)
2375  dene= 1./dene;
2376 
2377  float Fe = 0.;
2378  if(Eene > 0.0001) {
2379  Fe =((dene*Eene) +(dpt*momentum.E()))/(dene+dpt);
2380  }
2381  else {
2382  Fe=momentum.E();
2383  }
2384 
2385  if ((de_gs>0.05)&&(de_kf>0.05)){
2386  Fe=Eene;
2387  }
2388  if ((de_gs<-0.1)&&(de_me<-0.1) &&(de_kf<0.) &&
2389  (momentum.E()/dpt_gsf) > 5. && momentum_gsf.pt() < 30.){
2390  Fe=momentum.E();
2391  }
2392  float scale= Fe/momentum.E();
2393 
2394  newmomentum.SetPxPyPzE(scale*momentum.Px(),
2395  scale*momentum.Py(),
2396  scale*momentum.Pz(),Fe);
2397  if( DebugIDCandidates )
2398  cout << "SetCandidates::(nhit_gsf>7) || (has_kf==false) " << newmomentum.pt() << " Ene " << Fe <<endl;
2399 
2400 
2401  }
2402  if (newmomentum.pt()>0.5){
2403 
2404  // the pf candidate are created: we need to set something more?
2405  // IMPORTANT -> We need the gsftrackRef, not only the TrackRef??
2406 
2407  if( DebugIDCandidates )
2408  cout << "SetCandidates:: I am before doing candidate " <<endl;
2409 
2410  //vector with the cluster energies (for the extra)
2411  std::vector<float> clusterEnergyVec;
2412  clusterEnergyVec.push_back(RawEene);
2413  clusterEnergyVec.insert(clusterEnergyVec.end(),bremEnergyVec.begin(),bremEnergyVec.end());
2414 
2415  // add the information in the extra
2416  std::vector<reco::PFCandidateElectronExtra>::iterator itextra;
2417  PFElectronExtraEqual myExtraEqual(RefGSF);
2418  itextra=find_if(electronExtra_.begin(),electronExtra_.end(),myExtraEqual);
2419  if(itextra!=electronExtra_.end()) {
2420  itextra->setClusterEnergies(clusterEnergyVec);
2421  }
2422  else {
2423  if(RawEene>0.)
2424  std::cout << " There is a big problem with the electron extra, PFElectronAlgo should crash soon " << RawEene << std::endl;
2425  }
2426 
2429  reco::PFCandidate temp_Candidate;
2430  temp_Candidate = PFCandidate(charge,newmomentum,particleType);
2431  temp_Candidate.set_mva_e_pi(BDToutput_[cgsf]);
2432  temp_Candidate.setEcalEnergy(RawEene,Eene);
2433  // Note the Hcal energy is set but the element is never locked
2434  temp_Candidate.setHcalEnergy(Hene,Hene);
2435  temp_Candidate.setPs1Energy(ps1TotEne);
2436  temp_Candidate.setPs2Energy(ps2TotEne);
2437  temp_Candidate.setTrackRef(RefKF);
2438  // This reference could be NULL it is needed a protection?
2439  temp_Candidate.setGsfTrackRef(RefGSF);
2440  temp_Candidate.setPositionAtECALEntrance(posGsfEcalEntrance);
2441  // Add Vertex
2442  temp_Candidate.setVertexSource(PFCandidate::kGSFVertex);
2443 
2444  // save the superclusterRef when available
2445  if(RefGSF->extra().isAvailable() && RefGSF->extra()->seedRef().isAvailable()) {
2446  reco::ElectronSeedRef seedRef= RefGSF->extra()->seedRef().castTo<reco::ElectronSeedRef>();
2447  if(seedRef.isAvailable() && seedRef->isEcalDriven()) {
2448  reco::SuperClusterRef scRef = seedRef->caloCluster().castTo<reco::SuperClusterRef>();
2449  if(scRef.isNonnull())
2450  temp_Candidate.setSuperClusterRef(scRef);
2451  }
2452  }
2453 
2454  if( DebugIDCandidates )
2455  cout << "SetCandidates:: I am after doing candidate " <<endl;
2456 
2457  for (unsigned int elad=0; elad<elementsToAdd.size();elad++){
2458  temp_Candidate.addElementInBlock(blockRef,elementsToAdd[elad]);
2459  }
2460 
2461  // now add the photons to this candidate
2462  std::map<unsigned int, std::vector<reco::PFCandidate> >::const_iterator itcluster=
2463  electronConstituents_.find(cgsf);
2464  if(itcluster!=electronConstituents_.end())
2465  {
2466  const std::vector<reco::PFCandidate> & theClusters=itcluster->second;
2467  unsigned nclus=theClusters.size();
2468  // std::cout << " PFElectronAlgo " << nclus << " daugthers to add" << std::endl;
2469  for(unsigned iclus=0;iclus<nclus;++iclus)
2470  {
2471  temp_Candidate.addDaughter(theClusters[iclus]);
2472  }
2473  }
2474 
2475  // By-pass the mva is the electron has been pre-selected
2476  bool bypassmva=false;
2477  if(useEGElectrons_) {
2478  GsfElectronEqual myEqual(RefGSF);
2479  std::vector<reco::GsfElectron>::const_iterator itcheck=find_if(theGsfElectrons_->begin(),theGsfElectrons_->end(),myEqual);
2480  if(itcheck!=theGsfElectrons_->end()) {
2481  if(BDToutput_[cgsf] >= -1.) {
2482  // bypass the mva only if the reconstruction went fine
2483  bypassmva=true;
2484 
2485  if( DebugIDCandidates ) {
2486  if(BDToutput_[cgsf] < -0.1) {
2487  float esceg = itcheck->caloEnergy();
2488  cout << " Attention By pass the mva " << BDToutput_[cgsf]
2489  << " SuperClusterEnergy " << esceg
2490  << " PF Energy " << Eene << endl;
2491 
2492  cout << " hoe " << itcheck->hcalOverEcal()
2493  << " tkiso04 " << itcheck->dr04TkSumPt()
2494  << " ecaliso04 " << itcheck->dr04EcalRecHitSumEt()
2495  << " hcaliso04 " << itcheck->dr04HcalTowerSumEt()
2496  << " tkiso03 " << itcheck->dr03TkSumPt()
2497  << " ecaliso03 " << itcheck->dr03EcalRecHitSumEt()
2498  << " hcaliso03 " << itcheck->dr03HcalTowerSumEt() << endl;
2499  }
2500  } // end DebugIDCandidates
2501  }
2502  }
2503  }
2504 
2505  bool mvaSelected = (BDToutput_[cgsf] >= mvaEleCut_);
2506  if( mvaSelected || bypassmva ) {
2507  elCandidate_.push_back(temp_Candidate);
2508  if(itextra!=electronExtra_.end())
2509  itextra->setStatus(PFCandidateElectronExtra::Selected,true);
2510  }
2511  else {
2512  if(itextra!=electronExtra_.end())
2513  itextra->setStatus(PFCandidateElectronExtra::Rejected,true);
2514  }
2515  allElCandidate_.push_back(temp_Candidate);
2516 
2517  // save the status information
2518  if(itextra!=electronExtra_.end()) {
2519  itextra->setStatus(PFCandidateElectronExtra::ECALDrivenPreselected,bypassmva);
2520  itextra->setStatus(PFCandidateElectronExtra::MVASelected,mvaSelected);
2521  }
2522 
2523 
2524  }
2525  else {
2526  BDToutput_[cgsf] = -1.; // if the momentum is < 0.5 ID = false, but not sure
2527  // it could be misleading.
2528  if( DebugIDCandidates )
2529  cout << "SetCandidates:: No Candidate Produced because of Pt cut: 0.5 " <<endl;
2530  }
2531  }
2532  else {
2533  BDToutput_[cgsf] = -1.; // if gsf ref does not exist
2534  if( DebugIDCandidates )
2535  cout << "SetCandidates:: No Candidate Produced because of No GSF Track Ref " <<endl;
2536  }
2537  } // End Loop On GSF tracks
2538  return;
2539 }
bool isAvailable() const
Definition: Ref.h:614
type
Definition: HCALResponse.h:21
void setPs2Energy(float e2)
set corrected PS2 energy
Definition: PFCandidate.h:275
const math::XYZPointF & positionAtECALEntrance() const
const reco::TrackRef & trackRef() const
const reco::GsfTrackRef & GsftrackRef() const
void setPs1Energy(float e1)
set corrected PS1 energy
Definition: PFCandidate.h:269
ParticleType
particle types
Definition: PFCandidate.h:44
bool isNonnull() const
Checks for non-null.
Definition: Ref.h:250
Particle flow cluster, see clustering algorithm in PFClusterAlgo.
Definition: PFCluster.h:47
void setPositionAtECALEntrance(const math::XYZPointF &pos)
set position at ECAL entrance
Definition: PFCandidate.h:344
const math::XYZPointF & positionAtECALEntrance() const
std::vector< reco::PFCandidateElectronExtra > electronExtra_
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
std::map< unsigned int, Link > LinkData
Definition: PFBlock.h:46
list elements
Definition: asciidump.py:414
const std::vector< reco::GsfElectron > * theGsfElectrons_
bool isPrimaryTrack(const reco::PFBlockElementTrack &KfEl, const reco::PFBlockElementGsfTrack &GsfEl)
const PFClusterRef & clusterRef() const
const edm::OwnVector< reco::PFBlockElement > & elements() const
Definition: PFBlock.h:107
const LinkData & linkData() const
Definition: PFBlock.h:112
ROOT::Math::PositionVector3D< ROOT::Math::Cartesian3D< float > > XYZPointF
point in space with cartesian internal representation
Definition: Point3D.h:10
XYZTLorentzVectorD XYZTLorentzVector
Lorentz vector with cylindrical internal representation using pseudorapidity.
Definition: LorentzVector.h:29
void set_mva_e_pi(float mvaNI)
Definition: PFCandidate.h:307
void setVertexSource(PFVertexType vt)
Definition: PFCandidate.h:402
double getEnergyResolutionEm(double CorrectedEnergy, double eta) const
tuple particleType
Definition: autophobj.py:28
void addElementInBlock(const reco::PFBlockRef &blockref, unsigned elementIndex)
add an element to the current PFCandidate
Definition: PFCandidate.cc:211
T sqrt(T t)
Definition: SSEVec.h:48
std::vector< double > BDToutput_
T const * get() const
Returns C++ pointer to the item.
Definition: Ref.h:242
#define M_PI
void addDaughter(const Candidate &, const std::string &s="")
add a clone of the passed candidate as daughter
std::map< unsigned int, std::vector< reco::PFCandidate > > electronConstituents_
void setEcalEnergy(float eeRaw, float eeCorr)
set corrected Ecal energy
Definition: PFCandidate.h:213
void setGsfTrackRef(const reco::GsfTrackRef &ref)
set gsftrack reference
Definition: PFCandidate.cc:454
void associatedElements(unsigned i, const LinkData &linkData, std::multimap< double, unsigned > &sortedAssociates, reco::PFBlockElement::Type type=PFBlockElement::NONE, LinkTest test=LINKTEST_RECHIT) const
Definition: PFBlock.cc:75
XYZPointD XYZPoint
point in space with cartesian internal representation
Definition: Point3D.h:12
boost::shared_ptr< PFSCEnergyCalibration > thePFSCEnergyCalibration_
Particle reconstructed by the particle flow algorithm.
Definition: PFCandidate.h:39
void setSuperClusterRef(const reco::SuperClusterRef &scRef)
Definition: PFCandidate.cc:620
tuple cout
Definition: gather_cfg.py:121
void setTrackRef(const reco::TrackRef &ref)
set track reference
Definition: PFCandidate.cc:416
void setHcalEnergy(float ehRaw, float ehCorr)
set corrected Hcal energy
Definition: PFCandidate.h:223
boost::shared_ptr< PFEnergyCalibration > thePFEnergyCalibration_
std::vector< reco::PFCandidate > elCandidate_
bool applyCrackCorrections_
Block of elements.
Definition: PFBlock.h:30
std::vector< reco::PFCandidate > allElCandidate_
void PFElectronAlgo::setEGElectronCollection ( const reco::GsfElectronCollection egelectrons)

Definition at line 2662 of file PFElectronAlgo.cc.

References theGsfElectrons_.

Referenced by PFAlgo::setEGElectronCollection().

2662  {
2663  theGsfElectrons_ = & egelectrons;
2664 }
const std::vector< reco::GsfElectron > * theGsfElectrons_
void PFElectronAlgo::SetIDOutputs ( const reco::PFBlockRef blockRef,
AssMap associatedToGsf_,
AssMap associatedToBrems_,
AssMap associatedToEcal_,
const reco::Vertex primaryVertex 
)
private

Definition at line 1420 of file PFElectronAlgo.cc.

References applyCrackCorrections_, reco::PFBlock::associatedElements(), BDToutput_, createPayload::block, reco::PFBlockElement::BREM, chi2_gsf, chi2_kf, reco::PFBlockElementCluster::clusterRef(), gather_cfg::cout, DEtaGsfEcalClust, DPtOverPt_gsf, dPtOverPt_gsf, DPtOverPt_kf, earlyBrem, reco::PFBlockElement::ECAL, EGsfPoutMode, electronExtra_, reco::PFBlock::elements(), asciidump::elements, Eta_gsf, EtotBremPinPoutMode, EtotPinMode, firstBrem, reco::PFBlockElementGsfTrack::GsftrackRef(), reco::PFBlockElement::HCAL, HOverHE, HOverPin, reco::PFBlockElementBrem::indTrajPoint(), edm::Ref< C, T, F >::isNonnull(), isPrimaryTrack(), lateBrem, reco::PFBlock::linkData(), reco::PFBlock::LINKTEST_ALL, lnPt_gsf, lockExtraKf_, create_public_lumi_plots::log, M_PI, python.multivaluedict::map(), mvaEleCut_, nhit_gsf, nhit_kf, PFClusterWidthAlgo::pflowSigmaEtaEta(), reco::PFBlockElementGsfTrack::positionAtECALEntrance(), reco::PFBlockElementGsfTrack::Pout(), reco::PFBlockElement::PS1, reco::PFBlockElement::PS2, reco::PFCandidateElectronExtra::setDeltaEta(), reco::PFCandidateElectronExtra::setEarlyBrem(), reco::PFCandidateElectronExtra::setGsfTrackPout(), reco::PFCandidateElectronExtra::setHadEnergy(), reco::PFCandidateElectronExtra::setKfTrackRef(), reco::PFCandidateElectronExtra::setLateBrem(), reco::PFCandidateElectronExtra::setMVA(), reco::PFCandidateElectronExtra::setSigmaEtaEta(), SigmaEtaEta, funct::sin(), mathSSE::sqrt(), thePFEnergyCalibration_, tmvaReader_, reco::PFBlockElement::TRACK, reco::PFBlockElementTrack::trackRef(), reco::Vertex::tracks_begin(), reco::Vertex::tracks_end(), and whichTrackAlgo().

Referenced by RunPFElectron().

1424  {
1425  //PFEnergyCalibration pfcalib_;
1426  const reco::PFBlock& block = *blockRef;
1427  PFBlock::LinkData linkData = block.linkData();
1429  bool DebugIDOutputs = false;
1430  if(DebugIDOutputs) cout << " ######## Enter in SetIDOutputs #########" << endl;
1431 
1432  unsigned int cgsf=0;
1433  for (map<unsigned int,vector<unsigned int> >::iterator igsf = associatedToGsf_.begin();
1434  igsf != associatedToGsf_.end(); igsf++,cgsf++) {
1435 
1436  float Ene_ecalgsf = 0.;
1437  float Ene_hcalgsf = 0.;
1438  double sigmaEtaEta = 0.;
1439  float deta_gsfecal = 0.;
1440  float Ene_ecalbrem = 0.;
1441  float Ene_extraecalgsf = 0.;
1442  bool LateBrem = false;
1443  // bool EarlyBrem = false;
1444  int FirstBrem = 1000;
1445  unsigned int ecalGsf_index = 100000;
1446  unsigned int kf_index = 100000;
1447  // unsigned int nhits_gsf = 0;
1448  int NumBrem = 0;
1449  reco::TrackRef RefKF;
1450  double posX=0.;
1451  double posY=0.;
1452  double posZ=0.;
1453 
1454  unsigned int gsf_index = igsf->first;
1455  const reco::PFBlockElementGsfTrack * GsfEl =
1456  dynamic_cast<const reco::PFBlockElementGsfTrack*>((&elements[gsf_index]));
1457  reco::GsfTrackRef RefGSF = GsfEl->GsftrackRef();
1458  float Ein_gsf = 0.;
1459  if (RefGSF.isNonnull()) {
1460  float m_el=0.00051;
1461  Ein_gsf =sqrt(RefGSF->pMode()*
1462  RefGSF->pMode()+m_el*m_el);
1463  // nhits_gsf = RefGSF->hitPattern().trackerLayersWithMeasurement();
1464  }
1465  float Eout_gsf = GsfEl->Pout().t();
1466  float Etaout_gsf = GsfEl->positionAtECALEntrance().eta();
1467 
1468 
1469  if (DebugIDOutputs)
1470  cout << " setIdOutput! GSF Track: Ein " << Ein_gsf
1471  << " eta,phi " << Etaout_gsf
1472  <<", " << GsfEl->positionAtECALEntrance().phi() << endl;
1473 
1474 
1475  vector<unsigned int> assogsf_index = igsf->second;
1476  bool FirstEcalGsf = true;
1477  for (unsigned int ielegsf=0;ielegsf<assogsf_index.size();ielegsf++) {
1478  PFBlockElement::Type assoele_type = elements[(assogsf_index[ielegsf])].type();
1479 
1480 
1481  // The RefKf is needed to build pure tracking observables
1482  if(assoele_type == reco::PFBlockElement::TRACK) {
1483  const reco::PFBlockElementTrack * KfTk =
1484  dynamic_cast<const reco::PFBlockElementTrack*>((&elements[(assogsf_index[ielegsf])]));
1485  // 19 Mar 2010 do not consider here track from gamma conv
1486 
1487  bool isPrim = isPrimaryTrack(*KfTk,*GsfEl);
1488  if(!isPrim) continue;
1489  RefKF = KfTk->trackRef();
1490  kf_index = assogsf_index[ielegsf];
1491  }
1492 
1493 
1494  if (assoele_type == reco::PFBlockElement::ECAL) {
1495  unsigned int keyecalgsf = assogsf_index[ielegsf];
1496  vector<unsigned int> assoecalgsf_index = associatedToEcal_.find(keyecalgsf)->second;
1497 
1498  vector<double> ps1Ene(0);
1499  vector<double> ps2Ene(0);
1500  for(unsigned int ips =0; ips<assoecalgsf_index.size();ips++) {
1501  PFBlockElement::Type typeassoecal = elements[(assoecalgsf_index[ips])].type();
1502  if (typeassoecal == reco::PFBlockElement::PS1) {
1503  PFClusterRef psref = elements[(assoecalgsf_index[ips])].clusterRef();
1504  ps1Ene.push_back(psref->energy());
1505  }
1506  if (typeassoecal == reco::PFBlockElement::PS2) {
1507  PFClusterRef psref = elements[(assoecalgsf_index[ips])].clusterRef();
1508  ps2Ene.push_back(psref->energy());
1509  }
1510  if (typeassoecal == reco::PFBlockElement::HCAL) {
1511  const reco::PFBlockElementCluster * clust =
1512  dynamic_cast<const reco::PFBlockElementCluster*>((&elements[(assoecalgsf_index[ips])]));
1513  Ene_hcalgsf+=clust->clusterRef()->energy();
1514  }
1515  }
1516  if (FirstEcalGsf) {
1517  FirstEcalGsf = false;
1518  ecalGsf_index = assogsf_index[ielegsf];
1519  reco::PFClusterRef clusterRef = elements[(assogsf_index[ielegsf])].clusterRef();
1520  double ps1,ps2;
1521  ps1=ps2=0.;
1522  // Ene_ecalgsf = pfcalib_.energyEm(*clusterRef,ps1Ene,ps2Ene);
1523  Ene_ecalgsf = thePFEnergyCalibration_->energyEm(*clusterRef,ps1Ene,ps2Ene,ps1,ps2,applyCrackCorrections_);
1524  // std::cout << "Test " << Ene_ecalgsf << " PS1 / PS2 " << ps1 << " " << ps2 << std::endl;
1525  posX += Ene_ecalgsf * clusterRef->position().X();
1526  posY += Ene_ecalgsf * clusterRef->position().Y();
1527  posZ += Ene_ecalgsf * clusterRef->position().Z();
1528 
1529  if (DebugIDOutputs)
1530  cout << " setIdOutput! GSF ECAL Cluster E " << Ene_ecalgsf
1531  << " eta,phi " << clusterRef->position().eta()
1532  <<", " << clusterRef->position().phi() << endl;
1533 
1534  deta_gsfecal = clusterRef->position().eta() - Etaout_gsf;
1535 
1536  vector< const reco::PFCluster * > pfClust_vec(0);
1537  pfClust_vec.clear();
1538  pfClust_vec.push_back(&(*clusterRef));
1539 
1540  PFClusterWidthAlgo pfwidth(pfClust_vec);
1541  sigmaEtaEta = pfwidth.pflowSigmaEtaEta();
1542 
1543 
1544  }
1545  else {
1546  reco::PFClusterRef clusterRef = elements[(assogsf_index[ielegsf])].clusterRef();
1547  float TempClus_energy = thePFEnergyCalibration_->energyEm(*clusterRef,ps1Ene,ps2Ene,applyCrackCorrections_);
1548  Ene_extraecalgsf += TempClus_energy;
1549  posX += TempClus_energy * clusterRef->position().X();
1550  posY += TempClus_energy * clusterRef->position().Y();
1551  posZ += TempClus_energy * clusterRef->position().Z();
1552 
1553  if (DebugIDOutputs)
1554  cout << " setIdOutput! Extra ECAL Cluster E "
1555  << TempClus_energy << " Tot " << Ene_extraecalgsf << endl;
1556  }
1557  } // end type Ecal
1558 
1559 
1560  if (assoele_type == reco::PFBlockElement::BREM) {
1561  unsigned int brem_index = assogsf_index[ielegsf];
1562  const reco::PFBlockElementBrem * BremEl =
1563  dynamic_cast<const reco::PFBlockElementBrem*>((&elements[brem_index]));
1564  int TrajPos = (BremEl->indTrajPoint())-2;
1565  //if (TrajPos <= 3) EarlyBrem = true;
1566  if (TrajPos < FirstBrem) FirstBrem = TrajPos;
1567 
1568  vector<unsigned int> assobrem_index = associatedToBrems_.find(brem_index)->second;
1569  for (unsigned int ibrem = 0; ibrem < assobrem_index.size(); ibrem++){
1570  if (elements[(assobrem_index[ibrem])].type() == reco::PFBlockElement::ECAL) {
1571  unsigned int keyecalbrem = assobrem_index[ibrem];
1572  vector<unsigned int> assoelebrem_index = associatedToEcal_.find(keyecalbrem)->second;
1573  vector<double> ps1EneFromBrem(0);
1574  vector<double> ps2EneFromBrem(0);
1575  for (unsigned int ielebrem=0; ielebrem<assoelebrem_index.size();ielebrem++) {
1576  if (elements[(assoelebrem_index[ielebrem])].type() == reco::PFBlockElement::PS1) {
1577  PFClusterRef psref = elements[(assoelebrem_index[ielebrem])].clusterRef();
1578  ps1EneFromBrem.push_back(psref->energy());
1579  }
1580  if (elements[(assoelebrem_index[ielebrem])].type() == reco::PFBlockElement::PS2) {
1581  PFClusterRef psref = elements[(assoelebrem_index[ielebrem])].clusterRef();
1582  ps2EneFromBrem.push_back(psref->energy());
1583  }
1584  }
1585  // check if it is a compatible cluster also with the gsf track
1586  if( assobrem_index[ibrem] != ecalGsf_index) {
1587  reco::PFClusterRef clusterRef =
1588  elements[(assobrem_index[ibrem])].clusterRef();
1589  float BremClus_energy = thePFEnergyCalibration_->energyEm(*clusterRef,ps1EneFromBrem,ps2EneFromBrem,applyCrackCorrections_);
1590  Ene_ecalbrem += BremClus_energy;
1591  posX += BremClus_energy * clusterRef->position().X();
1592  posY += BremClus_energy * clusterRef->position().Y();
1593  posZ += BremClus_energy * clusterRef->position().Z();
1594 
1595  NumBrem++;
1596  if (DebugIDOutputs) cout << " setIdOutput::BREM Cluster "
1597  << BremClus_energy << " eta,phi "
1598  << clusterRef->position().eta() <<", "
1599  << clusterRef->position().phi() << endl;
1600  }
1601  else {
1602  LateBrem = true;
1603  }
1604  }
1605  }
1606  }
1607  }
1608  if (Ene_ecalgsf > 0.) {
1609  // here build the new BDT observables
1610 
1611  // ***** Normalization observables ****
1612  if(RefGSF.isNonnull()) {
1613  PFCandidateElectronExtra myExtra(RefGSF) ;
1614  myExtra.setGsfTrackPout(GsfEl->Pout());
1615  myExtra.setKfTrackRef(RefKF);
1616  float Pt_gsf = RefGSF->ptMode();
1617  lnPt_gsf = log(Pt_gsf);
1618  Eta_gsf = RefGSF->etaMode();
1619 
1620  // **** Pure tracking observables.
1621  if(RefGSF->ptModeError() > 0.)
1622  dPtOverPt_gsf = RefGSF->ptModeError()/Pt_gsf;
1623 
1624  nhit_gsf= RefGSF->hitPattern().trackerLayersWithMeasurement();
1625  chi2_gsf = RefGSF->normalizedChi2();
1626  // change GsfEl->Pout().pt() as soon the PoutMode is on the GsfTrack DataFormat
1627  DPtOverPt_gsf = (RefGSF->ptMode() - GsfEl->Pout().pt())/RefGSF->ptMode();
1628 
1629 
1630  nhit_kf = 0;
1631  chi2_kf = -0.01;
1632  DPtOverPt_kf = -0.01;
1633  if (RefKF.isNonnull()) {
1634  nhit_kf= RefKF->hitPattern().trackerLayersWithMeasurement();
1635  chi2_kf = RefKF->normalizedChi2();
1636  // Not used, strange behaviour to be checked. And Kf->OuterPt is
1637  // in track extra.
1638  //DPtOverPt_kf =
1639  // (RefKF->pt() - RefKF->outerPt())/RefKF->pt();
1640 
1641  }
1642 
1643  // **** Tracker-Ecal-Hcal observables
1644  EtotPinMode = (Ene_ecalgsf + Ene_ecalbrem + Ene_extraecalgsf) / Ein_gsf;
1645  EGsfPoutMode = Ene_ecalgsf/Eout_gsf;
1646  EtotBremPinPoutMode = Ene_ecalbrem /(Ein_gsf - Eout_gsf);
1647  DEtaGsfEcalClust = fabs(deta_gsfecal);
1648  myExtra.setSigmaEtaEta(sigmaEtaEta);
1649  myExtra.setDeltaEta(DEtaGsfEcalClust);
1650  SigmaEtaEta = log(sigmaEtaEta);
1651 
1652  lateBrem = -1;
1653  firstBrem = -1;
1654  earlyBrem = -1;
1655  if(NumBrem > 0) {
1656  if (LateBrem) lateBrem = 1;
1657  else lateBrem = 0;
1658  firstBrem = FirstBrem;
1659  if(FirstBrem < 4) earlyBrem = 1;
1660  else earlyBrem = 0;
1661  }
1662 
1663  HOverHE = Ene_hcalgsf/(Ene_hcalgsf + Ene_ecalgsf);
1664  HOverPin = Ene_hcalgsf / Ein_gsf;
1665  myExtra.setHadEnergy(Ene_hcalgsf);
1666  myExtra.setEarlyBrem(earlyBrem);
1667  myExtra.setLateBrem(lateBrem);
1668  // std::cout<< " Inserting in extra " << electronExtra_.size() << std::endl;
1669 
1670  // Put cuts and access the BDT output
1671  if(DPtOverPt_gsf < -0.2) DPtOverPt_gsf = -0.2;
1672  if(DPtOverPt_gsf > 1.) DPtOverPt_gsf = 1.;
1673 
1674  if(dPtOverPt_gsf > 0.3) dPtOverPt_gsf = 0.3;
1675 
1676  if(chi2_gsf > 10.) chi2_gsf = 10.;
1677 
1678  if(DPtOverPt_kf < -0.2) DPtOverPt_kf = -0.2;
1679  if(DPtOverPt_kf > 1.) DPtOverPt_kf = 1.;
1680 
1681  if(chi2_kf > 10.) chi2_kf = 10.;
1682 
1683  if(EtotPinMode < 0.) EtotPinMode = 0.;
1684  if(EtotPinMode > 5.) EtotPinMode = 5.;
1685 
1686  if(EGsfPoutMode < 0.) EGsfPoutMode = 0.;
1687  if(EGsfPoutMode > 5.) EGsfPoutMode = 5.;
1688 
1689  if(EtotBremPinPoutMode < 0.) EtotBremPinPoutMode = 0.01;
1691 
1692  if(DEtaGsfEcalClust > 0.1) DEtaGsfEcalClust = 0.1;
1693 
1694  if(SigmaEtaEta < -14) SigmaEtaEta = -14;
1695 
1696  if(HOverPin < 0.) HOverPin = 0.;
1697  if(HOverPin > 5.) HOverPin = 5.;
1698  double mvaValue = tmvaReader_->EvaluateMVA("BDT");
1699 
1700  // add output observables
1701  BDToutput_[cgsf] = mvaValue;
1702  myExtra.setMVA(mvaValue);
1703  electronExtra_.push_back(myExtra);
1704 
1705 
1706  // IMPORTANT Additional conditions
1707  if(mvaValue > mvaEleCut_) {
1708  // Check if the ecal cluster is isolated.
1709  //
1710  // If there is at least one extra track and H/H+E > 0.05 or SumP(ExtraKf)/EGsf or
1711  // #Tracks > 3 I leave this job to PFAlgo, otherwise I lock those extra tracks.
1712  // Note:
1713  // The tracks coming from the 4 step of the iterative tracking are not considered,
1714  // because they can come from secondary converted brems.
1715  // They are locked to avoid double counting.
1716  // The lock is done in SetActivate function.
1717  // All this can improved but it is already a good step.
1718 
1719 
1720  // Find if the cluster is isolated.
1721  unsigned int iextratrack = 0;
1722  unsigned int itrackHcalLinked = 0;
1723  float SumExtraKfP = 0.;
1724 
1725 
1726  double Etotal = Ene_ecalgsf + Ene_ecalbrem + Ene_extraecalgsf;
1727  posX /=Etotal;
1728  posY /=Etotal;
1729  posZ /=Etotal;
1730  math::XYZPoint sc_pflow(posX,posY,posZ);
1731  double ETtotal = Etotal*sin(sc_pflow.Theta());
1732  double phiTrack = RefGSF->phiMode();
1733  double dphi_normalsc = sc_pflow.Phi() - phiTrack;
1734  if ( dphi_normalsc < -M_PI )
1735  dphi_normalsc = dphi_normalsc + 2.*M_PI;
1736  else if ( dphi_normalsc > M_PI )
1737  dphi_normalsc = dphi_normalsc - 2.*M_PI;
1738  dphi_normalsc = fabs(dphi_normalsc);
1739 
1740 
1741  if(ecalGsf_index < 100000) {
1742  vector<unsigned int> assoecalgsf_index = associatedToEcal_.find(ecalGsf_index)->second;
1743  for(unsigned int itrk =0; itrk<assoecalgsf_index.size();itrk++) {
1744  PFBlockElement::Type typeassoecal = elements[(assoecalgsf_index[itrk])].type();
1745  if(typeassoecal == reco::PFBlockElement::TRACK) {
1746  const reco::PFBlockElementTrack * kfTk =
1747  dynamic_cast<const reco::PFBlockElementTrack*>((&elements[(assoecalgsf_index[itrk])]));
1748  // 19 Mar 2010 do not consider here tracks from gamma conv
1749  // This should be not needed because the seleted extra tracks from GammaConv
1750  // will be locked and can not be associated to the ecal elements
1751  //if(kfTk->trackType(reco::PFBlockElement::T_FROM_GAMMACONV)) continue;
1752 
1753 
1754  reco::TrackRef trackref = kfTk->trackRef();
1755  unsigned int Algo = whichTrackAlgo(trackref);
1756  // iter0, iter1, iter2, iter3 = Algo < 3
1757  // algo 4,5,6,7
1758  int nexhits = trackref->hitPattern().numberOfLostHits(HitPattern::MISSING_INNER_HITS);
1759 
1760  bool trackIsFromPrimaryVertex = false;
1761  for (Vertex::trackRef_iterator trackIt = primaryVertex.tracks_begin(); trackIt != primaryVertex.tracks_end(); ++trackIt) {
1762  if ( (*trackIt).castTo<TrackRef>() == trackref ) {
1763  trackIsFromPrimaryVertex = true;
1764  break;
1765  }
1766  }
1767 
1768  // probably we could now remove the algo request??
1769  if(Algo < 3 && nexhits == 0 && trackIsFromPrimaryVertex) {
1770  //if(Algo < 3)
1771  if(DebugIDOutputs)
1772  cout << " The ecalGsf cluster is not isolated: >0 KF extra with algo < 3" << endl;
1773 
1774  float p_trk = trackref->p();
1775 
1776  // expected number of inner hits
1777 
1778  if(DebugIDOutputs)
1779  cout << " p_trk " << p_trk
1780  << " nexhits " << nexhits << endl;
1781 
1782  SumExtraKfP += p_trk;
1783  iextratrack++;
1784  // Check if these extra tracks are HCAL linked
1785  std::multimap<double, unsigned int> hcalKfElems;
1786  block.associatedElements( assoecalgsf_index[itrk],linkData,
1787  hcalKfElems,
1790  if(hcalKfElems.size() > 0) {
1791  itrackHcalLinked++;
1792  }
1793  }
1794  }
1795  }
1796  }
1797  if( iextratrack > 0) {
1798  //if(iextratrack > 3 || HOverHE > 0.05 || (SumExtraKfP/Ene_ecalgsf) > 1.
1799  if(iextratrack > 3 || Ene_hcalgsf > 10 || (SumExtraKfP/Ene_ecalgsf) > 1.
1800  || (ETtotal > 50. && iextratrack > 1 && (Ene_hcalgsf/Ene_ecalgsf) > 0.1) ) {
1801  if(DebugIDOutputs)
1802  cout << " *****This electron candidate is discarded: Non isolated # tracks "
1803  << iextratrack << " HOverHE " << HOverHE
1804  << " SumExtraKfP/Ene_ecalgsf " << SumExtraKfP/Ene_ecalgsf
1805  << " SumExtraKfP " << SumExtraKfP
1806  << " Ene_ecalgsf " << Ene_ecalgsf
1807  << " ETtotal " << ETtotal
1808  << " Ene_hcalgsf/Ene_ecalgsf " << Ene_hcalgsf/Ene_ecalgsf
1809  << endl;
1810 
1811  BDToutput_[cgsf] = mvaValue-2.;
1812  lockExtraKf_[cgsf] = false;
1813  }
1814  // if the Ecluster ~ Ptrack and the extra tracks are HCAL linked
1815  // the electron is retained and the kf tracks are not locked
1816  if( (fabs(1.-EtotPinMode) < 0.2 && (fabs(Eta_gsf) < 1.0 || fabs(Eta_gsf) > 2.0)) ||
1817  ((EtotPinMode < 1.1 && EtotPinMode > 0.6) && (fabs(Eta_gsf) >= 1.0 && fabs(Eta_gsf) <= 2.0))) {
1818  if( fabs(1.-EGsfPoutMode) < 0.5 &&
1819  (itrackHcalLinked == iextratrack) &&
1820  kf_index < 100000 ) {
1821 
1822  BDToutput_[cgsf] = mvaValue;
1823  lockExtraKf_[cgsf] = false;
1824  if(DebugIDOutputs)
1825  cout << " *****This electron is reactivated # tracks "
1826  << iextratrack << " #tracks hcal linked " << itrackHcalLinked
1827  << " SumExtraKfP/Ene_ecalgsf " << SumExtraKfP/Ene_ecalgsf
1828  << " EtotPinMode " << EtotPinMode << " EGsfPoutMode " << EGsfPoutMode
1829  << " eta gsf " << fabs(Eta_gsf) << " kf index " << kf_index <<endl;
1830  }
1831  }
1832  }
1833  // This is a pion:
1834  if (HOverPin > 1. && HOverHE > 0.1 && EtotPinMode < 0.5) {
1835  if(DebugIDOutputs)
1836  cout << " *****This electron candidate is discarded HCAL ENERGY "
1837  << " HOverPin " << HOverPin << " HOverHE " << HOverHE << " EtotPinMode" << EtotPinMode << endl;
1838  BDToutput_[cgsf] = mvaValue-4.;
1839  lockExtraKf_[cgsf] = false;
1840  }
1841 
1842  // Reject Crazy E/p values... to be understood in the future how to train a
1843  // BDT in order to avoid to select this bad electron candidates.
1844 
1845  if( EtotPinMode < 0.2 && EGsfPoutMode < 0.2 ) {
1846  if(DebugIDOutputs)
1847  cout << " *****This electron candidate is discarded Low ETOTPIN "
1848  << " EtotPinMode " << EtotPinMode << " EGsfPoutMode " << EGsfPoutMode << endl;
1849  BDToutput_[cgsf] = mvaValue-6.;
1850  }
1851 
1852  // For not-preselected Gsf Tracks ET > 50 GeV, apply dphi preselection
1853  if(ETtotal > 50. && dphi_normalsc > 0.1 ) {
1854  if(DebugIDOutputs)
1855  cout << " *****This electron candidate is discarded Large ANGLE "
1856  << " ETtotal " << ETtotal << " EGsfPoutMode " << dphi_normalsc << endl;
1857  BDToutput_[cgsf] = mvaValue-6.;
1858  }
1859  }
1860 
1861 
1862  if (DebugIDOutputs) {
1863  cout << " **** BDT observables ****" << endl;
1864  cout << " < Normalization > " << endl;
1865  cout << " Pt_gsf " << Pt_gsf << " Pin " << Ein_gsf << " Pout " << Eout_gsf
1866  << " Eta_gsf " << Eta_gsf << endl;
1867  cout << " < PureTracking > " << endl;
1868  cout << " dPtOverPt_gsf " << dPtOverPt_gsf
1869  << " DPtOverPt_gsf " << DPtOverPt_gsf
1870  << " chi2_gsf " << chi2_gsf
1871  << " nhit_gsf " << nhit_gsf
1872  << " DPtOverPt_kf " << DPtOverPt_kf
1873  << " chi2_kf " << chi2_kf
1874  << " nhit_kf " << nhit_kf << endl;
1875  cout << " < track-ecal-hcal-ps " << endl;
1876  cout << " EtotPinMode " << EtotPinMode
1877  << " EGsfPoutMode " << EGsfPoutMode
1878  << " EtotBremPinPoutMode " << EtotBremPinPoutMode
1879  << " DEtaGsfEcalClust " << DEtaGsfEcalClust
1880  << " SigmaEtaEta " << SigmaEtaEta
1881  << " HOverHE " << HOverHE << " Hcal energy " << Ene_hcalgsf
1882  << " HOverPin " << HOverPin
1883  << " lateBrem " << lateBrem
1884  << " firstBrem " << firstBrem << endl;
1885  cout << " !!!!!!!!!!!!!!!! the BDT output !!!!!!!!!!!!!!!!!: direct " << mvaValue
1886  << " corrected " << BDToutput_[cgsf] << endl;
1887 
1888  }
1889  }
1890  else {
1891  if (DebugIDOutputs)
1892  cout << " Gsf Ref isNULL " << endl;
1893  BDToutput_[cgsf] = -2.;
1894  }
1895  } else {
1896  if (DebugIDOutputs)
1897  cout << " No clusters associated to the gsf " << endl;
1898  BDToutput_[cgsf] = -2.;
1899  }
1900  DebugIDOutputs = false;
1901  } // End Loop on Map1
1902  return;
1903 }
type
Definition: HCALResponse.h:21
const math::XYZTLorentzVector & Pout() const
const reco::TrackRef & trackRef() const
const reco::GsfTrackRef & GsftrackRef() const
bool isNonnull() const
Checks for non-null.
Definition: Ref.h:250
trackRef_iterator tracks_end() const
last iterator over tracks
Definition: Vertex.cc:44
float EtotBremPinPoutMode
const math::XYZPointF & positionAtECALEntrance() const
std::vector< reco::PFCandidateElectronExtra > electronExtra_
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
std::map< unsigned int, Link > LinkData
Definition: PFBlock.h:46
list elements
Definition: asciidump.py:414
bool isPrimaryTrack(const reco::PFBlockElementTrack &KfEl, const reco::PFBlockElementGsfTrack &GsfEl)
const PFClusterRef & clusterRef() const
const edm::OwnVector< reco::PFBlockElement > & elements() const
Definition: PFBlock.h:107
const LinkData & linkData() const
Definition: PFBlock.h:112
unsigned int indTrajPoint() const
TMVA::Reader * tmvaReader_
T sqrt(T t)
Definition: SSEVec.h:48
std::vector< bool > lockExtraKf_
std::vector< double > BDToutput_
#define M_PI
unsigned int whichTrackAlgo(const reco::TrackRef &trackRef)
void associatedElements(unsigned i, const LinkData &linkData, std::multimap< double, unsigned > &sortedAssociates, reco::PFBlockElement::Type type=PFBlockElement::NONE, LinkTest test=LINKTEST_RECHIT) const
Definition: PFBlock.cc:75
XYZPointD XYZPoint
point in space with cartesian internal representation
Definition: Point3D.h:12
std::vector< TrackBaseRef >::const_iterator trackRef_iterator
The iteratator for the vector&lt;TrackRef&gt;
Definition: Vertex.h:37
tuple cout
Definition: gather_cfg.py:121
trackRef_iterator tracks_begin() const
first iterator over tracks
Definition: Vertex.cc:39
Definition: fakeMenu.h:6
boost::shared_ptr< PFEnergyCalibration > thePFEnergyCalibration_
bool applyCrackCorrections_
Block of elements.
Definition: PFBlock.h:30
bool PFElectronAlgo::SetLinks ( const reco::PFBlockRef blockRef,
AssMap associatedToGsf_,
AssMap associatedToBrems_,
AssMap associatedToEcal_,
std::vector< bool > &  active,
const reco::Vertex primaryVertex 
)
private

Definition at line 131 of file PFElectronAlgo.cc.

References applyCrackCorrections_, reco::PFBlock::associatedElements(), createPayload::block, reco::PFBlockElement::BREM, reco::PFBlockElementCluster::clusterRef(), coneEcalIsoForEgammaSC_, convGsfTrack_, gather_cfg::cout, reco::PFBlock::dist(), ECAL, reco::PFBlockElement::ECAL, reco::PFBlock::elements(), asciidump::elements, fifthStepKfTrack_, reco::PFBlockElement::GSF, reco::PFBlockElementGsfTrack::GsftrackRef(), reco::PFBlockElement::HCAL, i, cuy::ii, cmsHarvester::index, reco::PFBlockElementBrem::indTrajPoint(), PFMuonAlgo::isMuon(), edm::Ref< C, T, F >::isNonnull(), isPrimaryTrack(), reco::PFBlock::linkData(), reco::PFBlock::LINKTEST_ALL, M_PI, python.multivaluedict::map(), nTrackIsoForEgammaSC_, reco::PFBlockElementBrem::positionAtECALEntrance(), reco::PFBlockElementGsfTrack::positionAtECALEntrance(), reco::PFBlockElementGsfTrack::Pout(), reco::PFBlockElement::PS1, reco::PFBlockElement::PS2, run_regression::ret, funct::sin(), edm::OwnVector< T, P >::size(), mathSSE::sqrt(), sumEtEcalIsoForEgammaSC_barrel_, sumEtEcalIsoForEgammaSC_endcap_, sumPtTrackIsoForEgammaSC_barrel_, sumPtTrackIsoForEgammaSC_endcap_, reco::PFBlockElement::T_FROM_GAMMACONV, thePFEnergyCalibration_, reco::PFBlockElement::TRACK, reco::PFBlockElementTrack::trackRef(), reco::Vertex::tracks_begin(), reco::Vertex::tracks_end(), reco::PFBlockElementGsfTrack::trackType(), useEGammaSupercluster_, and whichTrackAlgo().

Referenced by RunPFElectron().

136  {
137  unsigned int CutIndex = 100000;
138  double CutGSFECAL = 10000. ;
139  // no other cut are not used anymore. We use the default of PFBlockAlgo
140  //PFEnergyCalibration pfcalib_;
141  bool DebugSetLinksSummary = false;
142  bool DebugSetLinksDetailed = false;
143 
144  const reco::PFBlock& block = *blockRef;
146  PFBlock::LinkData linkData = block.linkData();
147 
148  bool IsThereAGSFTrack = false;
149  bool IsThereAGoodGSFTrack = false;
150 
151  vector<unsigned int> trackIs(0);
152  vector<unsigned int> gsfIs(0);
153  vector<unsigned int> ecalIs(0);
154 
155  std::vector<bool> localactive(elements.size(),true);
156 
157 
158  // Save the elements in shorter vectors like in PFAlgo.
159  std::multimap<double, unsigned int> kfElems;
160  for(unsigned int iEle=0; iEle<elements.size(); iEle++) {
161  localactive[iEle] = active[iEle];
162  bool thisIsAMuon = false;
163  PFBlockElement::Type type = elements[iEle].type();
164  switch( type ) {
165  case PFBlockElement::TRACK:
166  // Check if the track is already identified as a muon
167  thisIsAMuon = PFMuonAlgo::isMuon(elements[iEle]);
168  // Otherwise store index
169  if ( !thisIsAMuon && active[iEle] ) {
170  trackIs.push_back( iEle );
171  if (DebugSetLinksDetailed)
172  cout<<"TRACK, stored index, continue "<< iEle << endl;
173  }
174  continue;
175  case PFBlockElement::GSF:
176  // Check if the track has a KF partner identified as a muon
177  block.associatedElements( iEle,linkData,
178  kfElems,
181  thisIsAMuon = kfElems.size() ?
182  PFMuonAlgo::isMuon(elements[kfElems.begin()->second]) : false;
183  // Otherwise store index
184  if ( !thisIsAMuon && active[iEle] ) {
185  IsThereAGSFTrack = true;
186  gsfIs.push_back( iEle );
187  if (DebugSetLinksDetailed)
188  cout<<"GSF, stored index, continue "<< iEle << endl;
189  }
190  continue;
191  case PFBlockElement::ECAL:
192  if ( active[iEle] ) {
193  ecalIs.push_back( iEle );
194  if (DebugSetLinksDetailed)
195  cout<<"ECAL, stored index, continue "<< iEle << endl;
196  }
197  continue;
198  default:
199  continue;
200  }
201  }
202  // ******************* Start Link *****************************
203  // Do something only if a gsf track is found in the block
204  if(IsThereAGSFTrack) {
205 
206 
207  // LocalLock the Elements associated to a Kf tracks and not to a Gsf
208  // The clusters associated both to a kf track and to a brem tangend
209  // are then assigned only to the kf track
210  // Could be improved doing this after.
211 
212  // 19 Mar 2010 adding the KF track from Gamma Conv.
213  // They are linked to the GSF tracks they are not considered
214  // anymore in the following ecal cluster locking
215  if (DebugSetLinksDetailed) {
216  cout<<"#########################################################"<<endl;
217  cout<<"##### Process Block: #####"<<endl;
218  cout<<"#########################################################"<<endl;
219  cout<<block<<endl;
220  }
221 
222 
223  for(unsigned int iEle=0; iEle<trackIs.size(); iEle++) {
224  std::multimap<double, unsigned int> gsfElems;
225  block.associatedElements( trackIs[iEle], linkData,
226  gsfElems ,
229  if(gsfElems.size() == 0){
230  // This means that the considered kf is *not* associated
231  // to any gsf track
232  std::multimap<double, unsigned int> ecalKfElems;
233  block.associatedElements( trackIs[iEle],linkData,
234  ecalKfElems,
237  if(ecalKfElems.size() > 0) {
238  unsigned int ecalKf_index = ecalKfElems.begin()->second;
239  if(localactive[ecalKf_index]==true) {
240  // Check if this clusters is however well linked to a primary gsf track
241  // if this the case the cluster is not locked.
242 
243  bool isGsfLinked = false;
244  for(unsigned int iGsf=0; iGsf<gsfIs.size(); iGsf++) {
245  // if the ecal cluster is associated contemporary to a KF track
246  // and to a GSF track from conv, it is assigned to the KF track
247  // In this way we can loose some cluster but it is safer for double counting.
248  const reco::PFBlockElementGsfTrack * GsfEl =
249  dynamic_cast<const reco::PFBlockElementGsfTrack*>((&elements[gsfIs[iGsf]]));
251 
252  std::multimap<double, unsigned int> ecalGsfElems;
253  block.associatedElements( gsfIs[iGsf],linkData,
254  ecalGsfElems,
257  if(ecalGsfElems.size() > 0) {
258  if (ecalGsfElems.begin()->second == ecalKf_index) {
259  isGsfLinked = true;
260  }
261  }
262  }
263  if(isGsfLinked == false) {
264  // add protection against energy loss because
265  // of the tracking fifth step
266  const reco::PFBlockElementTrack * kfEle =
267  dynamic_cast<const reco::PFBlockElementTrack*>((&elements[(trackIs[iEle])]));
268  reco::TrackRef refKf = kfEle->trackRef();
269 
270  int nexhits = refKf->hitPattern().numberOfLostHits(HitPattern::MISSING_INNER_HITS);
271 
272  unsigned int Algo = 0;
273  if (refKf.isNonnull())
274  Algo = refKf->algo();
275 
276  bool trackIsFromPrimaryVertex = false;
277  for (Vertex::trackRef_iterator trackIt = primaryVertex.tracks_begin(); trackIt != primaryVertex.tracks_end(); ++trackIt) {
278  if ( (*trackIt).castTo<TrackRef>() == refKf ) {
279  trackIsFromPrimaryVertex = true;
280  break;
281  }
282  }
283 
284  if(Algo < 9 && nexhits == 0 && trackIsFromPrimaryVertex) {
285  localactive[ecalKf_index] = false;
286  } else {
287  fifthStepKfTrack_.push_back(make_pair(ecalKf_index,trackIs[iEle]));
288  }
289  }
290  }
291  }
292  } // gsfElems.size()
293  } // loop on kf tracks
294 
295 
296  // start loop on gsf tracks
297  for(unsigned int iEle=0; iEle<gsfIs.size(); iEle++) {
298 
299  if (!localactive[(gsfIs[iEle])]) continue;
300 
301  localactive[gsfIs[iEle]] = false;
302  bool ClosestEcalWithKf = false;
303 
304  if (DebugSetLinksDetailed) cout << " Gsf Index " << gsfIs[iEle] << endl;
305 
306  const reco::PFBlockElementGsfTrack * GsfEl =
307  dynamic_cast<const reco::PFBlockElementGsfTrack*>((&elements[(gsfIs[iEle])]));
308 
309  // if GsfTrack fron converted bremsstralung continue
311  IsThereAGoodGSFTrack = true;
312  float eta_gsf = GsfEl->positionAtECALEntrance().eta();
313  float etaOut_gsf = GsfEl->Pout().eta();
314  float diffOutEcalEta = fabs(eta_gsf-etaOut_gsf);
315  reco::GsfTrackRef RefGSF = GsfEl->GsftrackRef();
316  float Pin_gsf = 0.01;
317  if (RefGSF.isNonnull() )
318  Pin_gsf = RefGSF->pMode();
319 
320 
321  // Find Associated Kf Track elements and Ecal to KF elements
322  unsigned int KfGsf_index = CutIndex;
323  unsigned int KfGsf_secondIndex = CutIndex;
324  std::multimap<double, unsigned int> kfElems;
325  block.associatedElements( gsfIs[iEle],linkData,
326  kfElems,
329  std::multimap<double, unsigned int> ecalKfElems;
330  if (kfElems.size() > 0) {
331  // 19 Mar 2010 now a loop is needed because > 1 KF track could
332  // be associated to the same GSF track
333 
334  for(std::multimap<double, unsigned int>::iterator itkf = kfElems.begin();
335  itkf != kfElems.end(); ++itkf) {
336  const reco::PFBlockElementTrack * TrkEl =
337  dynamic_cast<const reco::PFBlockElementTrack*>((&elements[itkf->second]));
338 
339  bool isPrim = isPrimaryTrack(*TrkEl,*GsfEl);
340  if(!isPrim)
341  continue;
342 
343  if(localactive[itkf->second] == true) {
344 
345  KfGsf_index = itkf->second;
346  localactive[KfGsf_index] = false;
347  // Find clusters associated to kftrack using linkbyrechit
348  block.associatedElements( KfGsf_index, linkData,
349  ecalKfElems ,
352  }
353  else {
354  KfGsf_secondIndex = itkf->second;
355  }
356  }
357  }
358 
359  // Find the closest Ecal clusters associated to this Gsf
360  std::multimap<double, unsigned int> ecalGsfElems;
361  block.associatedElements( gsfIs[iEle],linkData,
362  ecalGsfElems,
365  double ecalGsf_dist = CutGSFECAL;
366  unsigned int ClosestEcalGsf_index = CutIndex;
367  if (ecalGsfElems.size() > 0) {
368  if(localactive[(ecalGsfElems.begin()->second)] == true) {
369  // check energy compatibility for outer eta != ecal entrance, looping tracks
370  bool compatibleEPout = true;
371  if(diffOutEcalEta > 0.3) {
372  reco::PFClusterRef clusterRef = elements[(ecalGsfElems.begin()->second)].clusterRef();
373  float EoPout = (clusterRef->energy())/(GsfEl->Pout().t());
374  if(EoPout > 5)
375  compatibleEPout = false;
376  }
377  if(compatibleEPout) {
378  ClosestEcalGsf_index = ecalGsfElems.begin()->second;
379  ecalGsf_dist = block.dist(gsfIs[iEle],ClosestEcalGsf_index,
380  linkData,reco::PFBlock::LINKTEST_ALL);
381 
382  // Check that this cluster is not closer to another primary Gsf track
383 
384  std::multimap<double, unsigned int> ecalOtherGsfElems;
385  block.associatedElements( ClosestEcalGsf_index,linkData,
386  ecalOtherGsfElems,
389 
390  if(ecalOtherGsfElems.size()>0) {
391  // get if it is closed to a conv brem gsf tracks
392  const reco::PFBlockElementGsfTrack * gsfCheck =
393  dynamic_cast<const reco::PFBlockElementGsfTrack*>((&elements[ecalOtherGsfElems.begin()->second]));
394 
395  if(ecalOtherGsfElems.begin()->second != gsfIs[iEle]&&
396  gsfCheck->trackType(reco::PFBlockElement::T_FROM_GAMMACONV) == false) {
397  ecalGsf_dist = CutGSFECAL;
398  ClosestEcalGsf_index = CutIndex;
399  }
400  }
401  }
402  // do not lock at the moment we need this for the late brem
403  }
404  }
405  // if any cluster is found with the gsf-ecal link, try with kf-ecal
406  else if(ecalKfElems.size() > 0) {
407  if(localactive[(ecalKfElems.begin()->second)] == true) {
408  ClosestEcalGsf_index = ecalKfElems.begin()->second;
409  ecalGsf_dist = block.dist(gsfIs[iEle],ClosestEcalGsf_index,
410  linkData,reco::PFBlock::LINKTEST_ALL);
411  ClosestEcalWithKf = true;
412 
413  // Check if this cluster is not closer to another Gsf track
414  std::multimap<double, unsigned int> ecalOtherGsfElems;
415  block.associatedElements( ClosestEcalGsf_index,linkData,
416  ecalOtherGsfElems,
419  if(ecalOtherGsfElems.size() > 0) {
420  const reco::PFBlockElementGsfTrack * gsfCheck =
421  dynamic_cast<const reco::PFBlockElementGsfTrack*>((&elements[ecalOtherGsfElems.begin()->second]));
422 
423  if(ecalOtherGsfElems.begin()->second != gsfIs[iEle] &&
425  ecalGsf_dist = CutGSFECAL;
426  ClosestEcalGsf_index = CutIndex;
427  ClosestEcalWithKf = false;
428  }
429  }
430  }
431  }
432 
433  if (DebugSetLinksDetailed)
434  cout << " Closest Ecal to the Gsf/Kf: index " << ClosestEcalGsf_index
435  << " dist " << ecalGsf_dist << endl;
436 
437 
438 
439  // Find the brems associated to this Gsf
440  std::multimap<double, unsigned int> bremElems;
441  block.associatedElements( gsfIs[iEle],linkData,
442  bremElems,
445 
446 
447  multimap<unsigned int,unsigned int> cleanedEcalBremElems;
448  vector<unsigned int> keyBremIndex(0);
449  unsigned int latestBrem_trajP = 0;
450  unsigned int latestBrem_index = CutIndex;
451  for(std::multimap<double, unsigned int>::iterator ieb = bremElems.begin();
452  ieb != bremElems.end(); ++ieb ) {
453  unsigned int brem_index = ieb->second;
454  if(localactive[brem_index] == false) continue;
455 
456 
457  // Find the ecal clusters associated to the brems
458  std::multimap<double, unsigned int> ecalBremsElems;
459 
460  block.associatedElements( brem_index, linkData,
461  ecalBremsElems,
464 
465  for (std::multimap<double, unsigned int>::iterator ie = ecalBremsElems.begin();
466  ie != ecalBremsElems.end();ie++) {
467  unsigned int ecalBrem_index = ie->second;
468  if(localactive[ecalBrem_index] == false) continue;
469 
470  //to be changed, using the distance
471  float ecalBrem_dist = block.dist(brem_index,ecalBrem_index,
472  linkData,reco::PFBlock::LINKTEST_ALL);
473 
474 
475  if (ecalBrem_index == ClosestEcalGsf_index && (ecalBrem_dist + 0.0012) > ecalGsf_dist) continue;
476 
477  // Find the closest brem
478  std::multimap<double, unsigned int> sortedBremElems;
479  block.associatedElements( ecalBrem_index,linkData,
480  sortedBremElems,
483  // check that this brem is that one coming from the same *primary* gsf
484  bool isGoodBrem = false;
485  unsigned int sortedBrem_index = CutIndex;
486  for (std::multimap<double, unsigned int>::iterator ibs = sortedBremElems.begin();
487  ibs != sortedBremElems.end();ibs++) {
488  unsigned int temp_sortedBrem_index = ibs->second;
489  std::multimap<double, unsigned int> sortedGsfElems;
490  block.associatedElements( temp_sortedBrem_index,linkData,
491  sortedGsfElems,
494  bool enteredInPrimaryGsf = false;
495  for (std::multimap<double, unsigned int>::iterator igs = sortedGsfElems.begin();
496  igs != sortedGsfElems.end();igs++) {
497  const reco::PFBlockElementGsfTrack * gsfCheck =
498  dynamic_cast<const reco::PFBlockElementGsfTrack*>((&elements[igs->second]));
499 
500  if(gsfCheck->trackType(reco::PFBlockElement::T_FROM_GAMMACONV) == false) {
501  if(igs->second == gsfIs[iEle]) {
502  isGoodBrem = true;
503  sortedBrem_index = temp_sortedBrem_index;
504  }
505  enteredInPrimaryGsf = true;
506  break;
507  }
508  }
509  if(enteredInPrimaryGsf)
510  break;
511  }
512 
513  if(isGoodBrem) {
514 
515  // Check that this cluster is not closer to another Gsf Track
516  // The check is not performed on KF track because the ecal clusters are aready locked.
517  std::multimap<double, unsigned int> ecalOtherGsfElems;
518  block.associatedElements( ecalBrem_index,linkData,
519  ecalOtherGsfElems,
522  if (ecalOtherGsfElems.size() > 0) {
523  const reco::PFBlockElementGsfTrack * gsfCheck =
524  dynamic_cast<const reco::PFBlockElementGsfTrack*>((&elements[ecalOtherGsfElems.begin()->second]));
525  if(ecalOtherGsfElems.begin()->second != gsfIs[iEle] &&
527  continue;
528  }
529  }
530 
531  const reco::PFBlockElementBrem * BremEl =
532  dynamic_cast<const reco::PFBlockElementBrem*>((&elements[sortedBrem_index]));
533 
534  reco::PFClusterRef clusterRef =
535  elements[ecalBrem_index].clusterRef();
536 
537 
538  float sortedBremEcal_deta = fabs(clusterRef->position().eta() - BremEl->positionAtECALEntrance().eta());
539  // Triangular cut on plan chi2:deta -> OLD
540  //if((0.0075*sortedBremEcal_chi2 + 100.*sortedBremEcal_deta -1.5) < 0.) {
541  if(sortedBremEcal_deta < 0.015) {
542 
543  cleanedEcalBremElems.insert(pair<unsigned int,unsigned int>(sortedBrem_index,ecalBrem_index));
544 
545  unsigned int BremTrajP = BremEl->indTrajPoint();
546  if (BremTrajP > latestBrem_trajP) {
547  latestBrem_trajP = BremTrajP;
548  latestBrem_index = sortedBrem_index;
549  }
550  if (DebugSetLinksDetailed)
551  cout << " brem Index " << sortedBrem_index
552  << " associated cluster " << ecalBrem_index << " BremTrajP " << BremTrajP <<endl;
553 
554  // > 1 ecal clusters could be associated to the same brem twice: allowed N-1 link.
555  // But the brem need to be stored once.
556  // locallock the brem and the ecal clusters
557  localactive[ecalBrem_index] = false; // the cluster
558  bool alreadyfound = false;
559  for(unsigned int ii=0;ii<keyBremIndex.size();ii++) {
560  if (sortedBrem_index == keyBremIndex[ii]) alreadyfound = true;
561  }
562  if (alreadyfound == false) {
563  keyBremIndex.push_back(sortedBrem_index);
564  localactive[sortedBrem_index] = false; // the brem
565  }
566  }
567  }
568  }
569  }
570 
571 
572  // Find Possible Extra Cluster associated to the gsf/kf
573  vector<unsigned int> GsfElemIndex(0);
574  vector<unsigned int> EcalIndex(0);
575 
576  // locallock the ecal cluster associated to the gsf
577  if (ClosestEcalGsf_index < CutIndex) {
578  GsfElemIndex.push_back(ClosestEcalGsf_index);
579  localactive[ClosestEcalGsf_index] = false;
580  for (std::multimap<double, unsigned int>::iterator ii = ecalGsfElems.begin();
581  ii != ecalGsfElems.end();ii++) {
582  if(localactive[ii->second]) {
583  // Check that this cluster is not closer to another Gsf Track
584  std::multimap<double, unsigned int> ecalOtherGsfElems;
585  block.associatedElements( ii->second,linkData,
586  ecalOtherGsfElems,
589  if(ecalOtherGsfElems.size()) {
590  if(ecalOtherGsfElems.begin()->second != gsfIs[iEle]) continue;
591  }
592 
593  // get the cluster only if the deta (ecal-gsf) < 0.05
594  reco::PFClusterRef clusterRef = elements[(ii->second)].clusterRef();
595  float etacl = clusterRef->eta();
596  if( fabs(eta_gsf-etacl) < 0.05) {
597  GsfElemIndex.push_back(ii->second);
598  localactive[ii->second] = false;
599  if (DebugSetLinksDetailed)
600  cout << " ExtraCluster From Gsf " << ii->second << endl;
601  }
602  }
603  }
604  }
605 
606  //Add the possibility to link other ecal clusters from kf.
607 
608 // for (std::multimap<double, unsigned int>::iterator ii = ecalKfElems.begin();
609 // ii != ecalKfElems.end();ii++) {
610 // if(localactive[ii->second]) {
611 // // Check that this cluster is not closer to another Gsf Track
612 // std::multimap<double, unsigned int> ecalOtherGsfElems;
613 // block.associatedElements( ii->second,linkData,
614 // ecalOtherGsfElems,
615 // reco::PFBlockElement::GSF,
616 // reco::PFBlock::LINKTEST_CHI2);
617 // if(ecalOtherGsfElems.size()) {
618 // if(ecalOtherGsfElems.begin()->second != gsfIs[iEle]) continue;
619 // }
620 // GsfElemIndex.push_back(ii->second);
621 // reco::PFClusterRef clusterRef = elements[(ii->second)].clusterRef();
622 // float etacl = clusterRef->eta();
623 // if( fabs(eta_gsf-etacl) < 0.05) {
624 // localactive[ii->second] = false;
625 // if (DebugSetLinksDetailed)
626 // cout << " ExtraCluster From KF " << ii->second << endl;
627 // }
628 // }
629 // }
630 
631  //****************** Fill Maps *************************
632 
633  // The GsfMap
634 
635  // if any clusters have been associated to the gsf track
636  // use the Ecal clusters associated to the latest brem and associate it to the gsf
637  if(GsfElemIndex.size() == 0){
638  if(latestBrem_index < CutIndex) {
639  unsigned int ckey = cleanedEcalBremElems.count(latestBrem_index);
640  if(ckey == 1) {
641  unsigned int temp_cal =
642  cleanedEcalBremElems.find(latestBrem_index)->second;
643  GsfElemIndex.push_back(temp_cal);
644  if (DebugSetLinksDetailed)
645  cout << "******************** Gsf Cluster From Brem " << temp_cal
646  << " Latest Brem index " << latestBrem_index
647  << " ************************* " << endl;
648  }
649  else{
650  pair<multimap<unsigned int,unsigned int>::iterator,multimap<unsigned int,unsigned int>::iterator> ret;
651  ret = cleanedEcalBremElems.equal_range(latestBrem_index);
652  multimap<unsigned int,unsigned int>::iterator it;
653  for(it=ret.first; it!=ret.second; ++it) {
654  GsfElemIndex.push_back((*it).second);
655  if (DebugSetLinksDetailed)
656  cout << "******************** Gsf Cluster From Brem " << (*it).second
657  << " Latest Brem index " << latestBrem_index
658  << " ************************* " << endl;
659  }
660  }
661  // erase the brem.
662  unsigned int elToErase = 0;
663  for(unsigned int i = 0; i<keyBremIndex.size();i++) {
664  if(latestBrem_index == keyBremIndex[i]) {
665  elToErase = i;
666  }
667  }
668  keyBremIndex.erase(keyBremIndex.begin()+elToErase);
669  }
670  }
671 
672  // Get Extra Clusters from converted brem gsf tracks. The locallock method
673  // tells me if the ecal cluster has been already assigned to the primary
674  // gsf track or to a brem
675 
676  for(unsigned int iConv=0; iConv<gsfIs.size(); iConv++) {
677  if(iConv != iEle) {
678 
679  const reco::PFBlockElementGsfTrack * gsfConv =
680  dynamic_cast<const reco::PFBlockElementGsfTrack*>((&elements[(gsfIs[iConv])]));
681 
682  // look at only to secondary gsf tracks
684  if (DebugSetLinksDetailed)
685  cout << " PFElectronAlgo:: I'm running on convGsfBrem " << endl;
686  // check if they are linked to the primary
687  float conv_dist = block.dist(gsfIs[iConv],gsfIs[iEle],
688  linkData,reco::PFBlock::LINKTEST_ALL);
689  if(conv_dist > 0.) {
690  // find the closest ecal cluster associated to conversions
691 
692  std::multimap<double, unsigned int> ecalConvElems;
693  block.associatedElements( gsfIs[iConv],linkData,
694  ecalConvElems,
697  if(ecalConvElems.size() > 0) {
698  // the ecal cluster is still active?
699  if(localactive[(ecalConvElems.begin()->second)] == true) {
700  if (DebugSetLinksDetailed)
701  cout << " PFElectronAlgo:: convGsfBrem has a ECAL cluster linked and free" << endl;
702  // Check that this cluster is not closer to another primary Gsf track
703  std::multimap<double, unsigned int> ecalOtherGsfPrimElems;
704  block.associatedElements( ecalConvElems.begin()->second,linkData,
705  ecalOtherGsfPrimElems,
708  if(ecalOtherGsfPrimElems.size()>0) {
709  unsigned int gsfprimcheck_index = ecalOtherGsfPrimElems.begin()->second;
710  const reco::PFBlockElementGsfTrack * gsfCheck =
711  dynamic_cast<const reco::PFBlockElementGsfTrack*>((&elements[gsfprimcheck_index]));
712  if(gsfCheck->trackType(reco::PFBlockElement::T_FROM_GAMMACONV) == false) continue;
713 
714  reco::PFClusterRef clusterRef = elements[ecalConvElems.begin()->second].clusterRef();
715  if (DebugSetLinksDetailed)
716  cout << " PFElectronAlgo: !!!!!!! convGsfBrem ECAL cluster has been stored !!!!!!! "
717  << " Energy " << clusterRef->energy() << " eta,phi " << clusterRef->position().eta()
718  <<", " << clusterRef->position().phi() << endl;
719 
720  GsfElemIndex.push_back(ecalConvElems.begin()->second);
721  convGsfTrack_.push_back(make_pair(ecalConvElems.begin()->second,gsfIs[iConv]));
722  localactive[ecalConvElems.begin()->second] = false;
723 
724  }
725  }
726  }
727  }
728  }
729  }
730  }
731 
732 
733 
734  EcalIndex.insert(EcalIndex.end(),GsfElemIndex.begin(),GsfElemIndex.end());
735 
736 
737 
738  // The BremMap
739  for(unsigned int i =0;i<keyBremIndex.size();i++) {
740  unsigned int ikey = keyBremIndex[i];
741  unsigned int ckey = cleanedEcalBremElems.count(ikey);
742  vector<unsigned int> BremElemIndex(0);
743  if(ckey == 1) {
744  unsigned int temp_cal =
745  cleanedEcalBremElems.find(ikey)->second;
746  BremElemIndex.push_back(temp_cal);
747  }
748  else{
749  pair<multimap<unsigned int,unsigned int>::iterator,multimap<unsigned int,unsigned int>::iterator> ret;
750  ret = cleanedEcalBremElems.equal_range(ikey);
751  multimap<unsigned int,unsigned int>::iterator it;
752  for(it=ret.first; it!=ret.second; ++it) {
753  BremElemIndex.push_back((*it).second);
754  }
755  }
756  EcalIndex.insert(EcalIndex.end(),BremElemIndex.begin(),BremElemIndex.end());
757  associatedToBrems_.insert(pair<unsigned int,vector<unsigned int> >(ikey,BremElemIndex));
758  }
759 
760 
761  // 19 Mar 2010: add KF and ECAL elements from converted brem photons
762  vector<unsigned int> convBremKFTrack;
763  convBremKFTrack.clear();
764  if (kfElems.size() > 0) {
765  for(std::multimap<double, unsigned int>::iterator itkf = kfElems.begin();
766  itkf != kfElems.end(); ++itkf) {
767  const reco::PFBlockElementTrack * TrkEl =
768  dynamic_cast<const reco::PFBlockElementTrack*>((&elements[itkf->second]));
769  bool isPrim = isPrimaryTrack(*TrkEl,*GsfEl);
770 
771  if(!isPrim) {
772 
773  // search for linked ECAL clusters
774  std::multimap<double, unsigned int> ecalConvElems;
775  block.associatedElements( itkf->second,linkData,
776  ecalConvElems,
779  if(ecalConvElems.size() > 0) {
780  // Further Cleaning: DANIELE This could be improved!
781  TrackRef trkRef = TrkEl->trackRef();
782  // iter0, iter1, iter2, iter3 = Algo < 3
783  unsigned int Algo = whichTrackAlgo(trkRef);
784 
785  float secpin = trkRef->p();
786 
787  const reco::PFBlockElementCluster * clust =
788  dynamic_cast<const reco::PFBlockElementCluster*>((&elements[(ecalConvElems.begin()->second)]));
789  float eneclust =clust->clusterRef()->energy();
790 
791  //1) ******* Reject secondary KF tracks linked to also an HCAL cluster with H/(E+H) > 0.1
792  // This is applied also to KF linked to locked ECAL cluster
793  // NOTE: trusting the H/(E+H) and not the conv brem selection increse the number
794  // of charged hadrons around the electron. DANIELE? re-think about this.
795  std::multimap<double, unsigned int> hcalConvElems;
796  block.associatedElements( itkf->second,linkData,
797  hcalConvElems,
800 
801  bool isHoHE = false;
802  bool isHoE = false;
803  bool isPoHE = false;
804 
805  float enehcalclust = -1;
806  if(hcalConvElems.size() > 0) {
807  const reco::PFBlockElementCluster * clusthcal =
808  dynamic_cast<const reco::PFBlockElementCluster*>((&elements[(hcalConvElems.begin()->second)]));
809  enehcalclust =clusthcal->clusterRef()->energy();
810  // NOTE: DANIELE? Are you sure you want to use the Algo type here?
811  if( (enehcalclust / (enehcalclust+eneclust) ) > 0.1 && Algo < 3) {
812  isHoHE = true;
813  if(enehcalclust > eneclust)
814  isHoE = true;
815  if(secpin > (enehcalclust+eneclust) )
816  isPoHE = true;
817  }
818  }
819 
820 
821  if(localactive[(ecalConvElems.begin()->second)] == false) {
822 
823  if(isHoE || isPoHE) {
824  if (DebugSetLinksDetailed)
825  cout << "PFElectronAlgo:: LOCKED ECAL REJECTED TRACK FOR H/E or P/(H+E) "
826  << " H/H+E " << enehcalclust/(enehcalclust+eneclust)
827  << " H/E " << enehcalclust/eneclust
828  << " P/(H+E) " << secpin/(enehcalclust+eneclust)
829  << " HCAL ENE " << enehcalclust
830  << " ECAL ENE " << eneclust
831  << " secPIN " << secpin
832  << " Algo Track " << Algo << endl;
833  continue;
834  }
835 
836  // check if this track has been alread assigned to an ECAL cluster
837  for(unsigned int iecal =0; iecal < EcalIndex.size(); iecal++) {
838  // in case this track is already assigned to a locked ECAL cluster
839  // the secondary kf track is also saved for further lock
840  if(EcalIndex[iecal] == ecalConvElems.begin()->second) {
841  if (DebugSetLinksDetailed)
842  cout << " PFElectronAlgo:: Conv Brem Recovery locked cluster and I will lock also the KF track " << endl;
843  convBremKFTrack.push_back(itkf->second);
844  }
845  }
846  }
847  else{
848  // ECAL cluster free
849 
850  //
851  if(isHoHE){
852  if (DebugSetLinksDetailed)
853  cout << "PFElectronAlgo:: FREE ECAL REJECTED TRACK FOR H/H+E "
854  << " H/H+E " << (enehcalclust / (enehcalclust+eneclust) )
855  << " H/E " << enehcalclust/eneclust
856  << " P/(H+E) " << secpin/(enehcalclust+eneclust)
857  << " HCAL ENE " << enehcalclust
858  << " ECAL ENE " << eneclust
859  << " secPIN " << secpin
860  << " Algo Track " << Algo << endl;
861  continue;
862  }
863 
864  // check that this cluster is not cluser to another KF track (primary)
865  std::multimap<double, unsigned int> ecalOtherKFPrimElems;
866  block.associatedElements( ecalConvElems.begin()->second,linkData,
867  ecalOtherKFPrimElems,
870  if(ecalOtherKFPrimElems.size() > 0) {
871 
872  // check that this ECAL clusters is the best associated to at least one of the KF tracks
873  // linked to the considered GSF track
874  bool isFromGSF = false;
875  for(std::multimap<double, unsigned int>::iterator itclos = kfElems.begin();
876  itclos != kfElems.end(); ++itclos) {
877  if(ecalOtherKFPrimElems.begin()->second == itclos->second) {
878  isFromGSF = true;
879  break;
880  }
881  }
882  if(isFromGSF){
883 
884  // Further Cleaning: DANIELE This could be improved!
885 
886 
887  float Epin = eneclust/secpin;
888 
889  // compute the pfsupercluster energy till now
890  float totenergy = 0.;
891  for(unsigned int ikeyecal = 0;
892  ikeyecal<EcalIndex.size(); ikeyecal++){
893  // EcalIndex can have the same cluster save twice (because of the late brem cluster).
894  bool foundcluster = false;
895  if(ikeyecal > 0) {
896  for(unsigned int i2 = 0; i2<ikeyecal-1; i2++) {
897  if(EcalIndex[ikeyecal] == EcalIndex[i2])
898  foundcluster = true;
899  }
900  }
901  if(foundcluster) continue;
902  const reco::PFBlockElementCluster * clusasso =
903  dynamic_cast<const reco::PFBlockElementCluster*>((&elements[(EcalIndex[ikeyecal])]));
904  totenergy += clusasso->clusterRef()->energy();
905  }
906 
907  // Further Cleaning: DANIELE This could be improved!
908  //2) ***** Do not consider secondary tracks if the GSF and brems have failed in finding ECAL clusters
909  if(totenergy == 0.) {
910  if (DebugSetLinksDetailed)
911  cout << "PFElectronAlgo:: REJECTED_NULLTOT totenergy " << totenergy << endl;
912  continue;
913  }
914 
915  //3) ****** Reject secondary KF tracks that have an high E/secPin and that make worse the Etot/pin
916  if(Epin > 3) {
917  double res_before = fabs((totenergy-Pin_gsf)/Pin_gsf);
918  double res_after = fabs(((totenergy+eneclust)-Pin_gsf)/Pin_gsf);
919 
920  if(res_before < res_after) {
921  if (DebugSetLinksDetailed)
922  cout << "PFElectronAlgo::REJECTED_RES totenergy " << totenergy << " Pin_gsf " << Pin_gsf << " cluster to secondary " << eneclust
923  << " Res before " << res_before << " res_after " << res_after << endl;
924  continue;
925  }
926  }
927 
928  if (DebugSetLinksDetailed)
929  cout << "PFElectronAlgo:: conv brem found asso to ECAL linked to a secondary KF " << endl;
930  convBremKFTrack.push_back(itkf->second);
931  GsfElemIndex.push_back(ecalConvElems.begin()->second);
932  EcalIndex.push_back(ecalConvElems.begin()->second);
933  localactive[(ecalConvElems.begin()->second)] = false;
934  localactive[(itkf->second)] = false;
935  }
936  }
937  }
938  }
939  }
940  }
941  }
942 
943  // 4May import EG supercluster
944  if(EcalIndex.size() > 0 && useEGammaSupercluster_) {
945  double sumEtEcalInTheCone = 0.;
946 
947  // Position of the first cluster
948  const reco::PFBlockElementCluster * clust =
949  dynamic_cast<const reco::PFBlockElementCluster*>((&elements[EcalIndex[0]]));
950  double PhiFC = clust->clusterRef()->position().Phi();
951  double EtaFC = clust->clusterRef()->position().Eta();
952 
953  // Compute ECAL isolation ->
954  for(unsigned int iEcal=0; iEcal<ecalIs.size(); iEcal++) {
955  bool foundcluster = false;
956  for(unsigned int ikeyecal = 0;
957  ikeyecal<EcalIndex.size(); ikeyecal++){
958  if(ecalIs[iEcal] == EcalIndex[ikeyecal])
959  foundcluster = true;
960  }
961 
962  // -> only for clusters not already in the PFSCCluster
963  if(foundcluster == false) {
964  const reco::PFBlockElementCluster * clustExt =
965  dynamic_cast<const reco::PFBlockElementCluster*>((&elements[ecalIs[iEcal]]));
966  double eta_clust = clustExt->clusterRef()->position().Eta();
967  double phi_clust = clustExt->clusterRef()->position().Phi();
968  double theta_clust = clustExt->clusterRef()->position().Theta();
969  double deta_clust = eta_clust - EtaFC;
970  double dphi_clust = phi_clust - PhiFC;
971  if ( dphi_clust < -M_PI )
972  dphi_clust = dphi_clust + 2.*M_PI;
973  else if ( dphi_clust > M_PI )
974  dphi_clust = dphi_clust - 2.*M_PI;
975  double DR = sqrt(deta_clust*deta_clust+
976  dphi_clust*dphi_clust);
977 
978  //Jurassic veto in deta
979  if(fabs(deta_clust) > 0.05 && DR < coneEcalIsoForEgammaSC_) {
980  vector<double> ps1Ene(0);
981  vector<double> ps2Ene(0);
982  double ps1,ps2;
983  ps1=ps2=0.;
984  double EE_calib = thePFEnergyCalibration_->energyEm(*(clustExt->clusterRef()),ps1Ene,ps2Ene,ps1,ps2,applyCrackCorrections_);
985  double ET_calib = EE_calib*sin(theta_clust);
986  sumEtEcalInTheCone += ET_calib;
987  }
988  }
989  } //EndLoop Additional ECAL clusters in the block
990 
991  // Compute track isolation: number of tracks && sumPt
992  unsigned int sumNTracksInTheCone = 0;
993  double sumPtTracksInTheCone = 0.;
994  for(unsigned int iTrack=0; iTrack<trackIs.size(); iTrack++) {
995  // the track from the electron are already locked at this stage
996  if(localactive[(trackIs[iTrack])]==true) {
997  const reco::PFBlockElementTrack * kfEle =
998  dynamic_cast<const reco::PFBlockElementTrack*>((&elements[(trackIs[iTrack])]));
999  reco::TrackRef trkref = kfEle->trackRef();
1000  if (trkref.isNonnull()) {
1001  double deta_trk = trkref->eta() - RefGSF->etaMode();
1002  double dphi_trk = trkref->phi() - RefGSF->phiMode();
1003  if ( dphi_trk < -M_PI )
1004  dphi_trk = dphi_trk + 2.*M_PI;
1005  else if ( dphi_trk > M_PI )
1006  dphi_trk = dphi_trk - 2.*M_PI;
1007  double DR = sqrt(deta_trk*deta_trk+
1008  dphi_trk*dphi_trk);
1009 
1010  int NValPixelHit = trkref->hitPattern().numberOfValidPixelHits();
1011 
1012  if(DR < coneTrackIsoForEgammaSC_ && NValPixelHit >=3) {
1013  sumNTracksInTheCone++;
1014  sumPtTracksInTheCone+=trkref->pt();
1015  }
1016  }
1017  }
1018  }
1019 
1020 
1021  bool isBarrelIsolated = false;
1022  if( fabs(EtaFC < 1.478) &&
1023  (sumEtEcalInTheCone < sumEtEcalIsoForEgammaSC_barrel_ &&
1024  (sumNTracksInTheCone < nTrackIsoForEgammaSC_ || sumPtTracksInTheCone < sumPtTrackIsoForEgammaSC_barrel_)))
1025  isBarrelIsolated = true;
1026 
1027 
1028  bool isEndcapIsolated = false;
1029  if( fabs(EtaFC >= 1.478) &&
1030  (sumEtEcalInTheCone < sumEtEcalIsoForEgammaSC_endcap_ &&
1031  (sumNTracksInTheCone < nTrackIsoForEgammaSC_ || sumPtTracksInTheCone < sumPtTrackIsoForEgammaSC_endcap_)))
1032  isEndcapIsolated = true;
1033 
1034 
1035  // only print out
1036  if(DebugSetLinksDetailed) {
1037  if(fabs(EtaFC < 1.478) && isBarrelIsolated == false) {
1038  cout << "**** PFElectronAlgo:: SUPERCLUSTER FOUND BUT FAILS ISOLATION:BARREL *** "
1039  << " sumEtEcalInTheCone " <<sumEtEcalInTheCone
1040  << " sumNTracksInTheCone " << sumNTracksInTheCone
1041  << " sumPtTracksInTheCone " << sumPtTracksInTheCone << endl;
1042  }
1043  if(fabs(EtaFC >= 1.478) && isEndcapIsolated == false) {
1044  cout << "**** PFElectronAlgo:: SUPERCLUSTER FOUND BUT FAILS ISOLATION:ENDCAP *** "
1045  << " sumEtEcalInTheCone " <<sumEtEcalInTheCone
1046  << " sumNTracksInTheCone " << sumNTracksInTheCone
1047  << " sumPtTracksInTheCone " << sumPtTracksInTheCone << endl;
1048  }
1049  }
1050 
1051 
1052 
1053 
1054  if(isBarrelIsolated || isEndcapIsolated ) {
1055 
1056 
1057  // Compute TotEnergy
1058  double totenergy = 0.;
1059  for(unsigned int ikeyecal = 0;
1060  ikeyecal<EcalIndex.size(); ikeyecal++){
1061  // EcalIndex can have the same cluster save twice (because of the late brem cluster).
1062  bool foundcluster = false;
1063  if(ikeyecal > 0) {
1064  for(unsigned int i2 = 0; i2<ikeyecal-1; i2++) {
1065  if(EcalIndex[ikeyecal] == EcalIndex[i2])
1066  foundcluster = true;;
1067  }
1068  }
1069  if(foundcluster) continue;
1070  const reco::PFBlockElementCluster * clusasso =
1071  dynamic_cast<const reco::PFBlockElementCluster*>((&elements[(EcalIndex[ikeyecal])]));
1072  totenergy += clusasso->clusterRef()->energy();
1073  }
1074  // End copute TotEnergy
1075 
1076 
1077  // Find extra cluster from e/g importing
1078  for(unsigned int ikeyecal = 0;
1079  ikeyecal<EcalIndex.size(); ikeyecal++){
1080  // EcalIndex can have the same cluster save twice (because of the late brem cluster).
1081  bool foundcluster = false;
1082  if(ikeyecal > 0) {
1083  for(unsigned int i2 = 0; i2<ikeyecal-1; i2++) {
1084  if(EcalIndex[ikeyecal] == EcalIndex[i2])
1085  foundcluster = true;
1086  }
1087  }
1088  if(foundcluster) continue;
1089 
1090 
1091  std::multimap<double, unsigned int> ecalFromSuperClusterElems;
1092  block.associatedElements( EcalIndex[ikeyecal],linkData,
1093  ecalFromSuperClusterElems,
1096  if(ecalFromSuperClusterElems.size() > 0) {
1097  for(std::multimap<double, unsigned int>::iterator itsc = ecalFromSuperClusterElems.begin();
1098  itsc != ecalFromSuperClusterElems.end(); ++itsc) {
1099  if(localactive[itsc->second] == false) {
1100  continue;
1101  }
1102 
1103  std::multimap<double, unsigned int> ecalOtherKFPrimElems;
1104  block.associatedElements( itsc->second,linkData,
1105  ecalOtherKFPrimElems,
1106  reco::PFBlockElement::TRACK,
1108  if(ecalOtherKFPrimElems.size() > 0) {
1109  if(localactive[ecalOtherKFPrimElems.begin()->second] == true) {
1110  if (DebugSetLinksDetailed)
1111  cout << "**** PFElectronAlgo:: SUPERCLUSTER FOUND BUT FAILS KF VETO *** " << endl;
1112  continue;
1113  }
1114  }
1115  bool isInTheEtaRange = false;
1116  const reco::PFBlockElementCluster * clustToAdd =
1117  dynamic_cast<const reco::PFBlockElementCluster*>((&elements[itsc->second]));
1118  double deta_clustToAdd = clustToAdd->clusterRef()->position().Eta() - EtaFC;
1119  double ene_clustToAdd = clustToAdd->clusterRef()->energy();
1120 
1121  if(fabs(deta_clustToAdd) < 0.05)
1122  isInTheEtaRange = true;
1123 
1124  // check for both KF and GSF
1125  bool isBetterEpin = false;
1126  if(isInTheEtaRange == false ) {
1127  if (DebugSetLinksDetailed)
1128  cout << "**** PFElectronAlgo:: SUPERCLUSTER FOUND BUT FAILS GAMMA DETA RANGE *** "
1129  << fabs(deta_clustToAdd) << endl;
1130 
1131  if(KfGsf_index < CutIndex) {
1132  //GSF
1133  double res_before_gsf = fabs((totenergy-Pin_gsf)/Pin_gsf);
1134  double res_after_gsf = fabs(((totenergy+ene_clustToAdd)-Pin_gsf)/Pin_gsf);
1135 
1136  //KF
1137  const reco::PFBlockElementTrack * trackEl =
1138  dynamic_cast<const reco::PFBlockElementTrack*>((&elements[KfGsf_index]));
1139  double Pin_kf = trackEl->trackRef()->p();
1140  double res_before_kf = fabs((totenergy-Pin_kf)/Pin_kf);
1141  double res_after_kf = fabs(((totenergy+ene_clustToAdd)-Pin_kf)/Pin_kf);
1142 
1143  // The new cluster improve both the E/pin?
1144  if(res_after_gsf < res_before_gsf && res_after_kf < res_before_kf ) {
1145  isBetterEpin = true;
1146  }
1147  else {
1148  if (DebugSetLinksDetailed)
1149  cout << "**** PFElectronAlgo:: SUPERCLUSTER FOUND AND FAILS ALSO RES_EPIN"
1150  << " tot energy " << totenergy
1151  << " Pin_gsf " << Pin_gsf
1152  << " Pin_kf " << Pin_kf
1153  << " cluster from SC to ADD " << ene_clustToAdd
1154  << " Res before GSF " << res_before_gsf << " res_after_gsf " << res_after_gsf
1155  << " Res before KF " << res_before_kf << " res_after_kf " << res_after_kf << endl;
1156  }
1157  }
1158  }
1159 
1160  if(isInTheEtaRange || isBetterEpin) {
1161  if (DebugSetLinksDetailed)
1162  cout << "!!!! PFElectronAlgo:: ECAL from SUPERCLUSTER FOUND !!!!! " << endl;
1163  GsfElemIndex.push_back(itsc->second);
1164  EcalIndex.push_back(itsc->second);
1165  localactive[(itsc->second)] = false;
1166  }
1167  }
1168  }
1169  }
1170  } // END ISOLATION IF
1171  }
1172 
1173 
1174  if(KfGsf_index < CutIndex)
1175  GsfElemIndex.push_back(KfGsf_index);
1176  else if(KfGsf_secondIndex < CutIndex)
1177  GsfElemIndex.push_back(KfGsf_secondIndex);
1178 
1179  // insert the secondary KF tracks
1180  GsfElemIndex.insert(GsfElemIndex.end(),convBremKFTrack.begin(),convBremKFTrack.end());
1181  GsfElemIndex.insert(GsfElemIndex.end(),keyBremIndex.begin(),keyBremIndex.end());
1182  associatedToGsf_.insert(pair<unsigned int, vector<unsigned int> >(gsfIs[iEle],GsfElemIndex));
1183 
1184  // The EcalMap
1185  for(unsigned int ikeyecal = 0;
1186  ikeyecal<EcalIndex.size(); ikeyecal++){
1187 
1188 
1189  vector<unsigned int> EcalElemsIndex(0);
1190 
1191  std::multimap<double, unsigned int> PS1Elems;
1192  block.associatedElements( EcalIndex[ikeyecal],linkData,
1193  PS1Elems,
1196  for( std::multimap<double, unsigned int>::iterator it = PS1Elems.begin();
1197  it != PS1Elems.end();it++) {
1198  unsigned int index = it->second;
1199  if(localactive[index] == true) {
1200 
1201  // Check that this cluster is not closer to another ECAL cluster
1202  std::multimap<double, unsigned> sortedECAL;
1203  block.associatedElements( index, linkData,
1204  sortedECAL,
1207  unsigned jEcal = sortedECAL.begin()->second;
1208  if ( jEcal != EcalIndex[ikeyecal]) continue;
1209 
1210 
1211  EcalElemsIndex.push_back(index);
1212  localactive[index] = false;
1213  }
1214  }
1215 
1216  std::multimap<double, unsigned int> PS2Elems;
1217  block.associatedElements( EcalIndex[ikeyecal],linkData,
1218  PS2Elems,
1221  for( std::multimap<double, unsigned int>::iterator it = PS2Elems.begin();
1222  it != PS2Elems.end();it++) {
1223  unsigned int index = it->second;
1224  if(localactive[index] == true) {
1225  // Check that this cluster is not closer to another ECAL cluster
1226  std::multimap<double, unsigned> sortedECAL;
1227  block.associatedElements( index, linkData,
1228  sortedECAL,
1231  unsigned jEcal = sortedECAL.begin()->second;
1232  if ( jEcal != EcalIndex[ikeyecal]) continue;
1233 
1234  EcalElemsIndex.push_back(index);
1235  localactive[index] = false;
1236  }
1237  }
1238  if(ikeyecal == 0) {
1239  // The first cluster is that one coming from the Gsf.
1240  // Only for this one is found the HCAL cluster using the Track-HCAL link
1241  // and not the Ecal-Hcal not well tested yet.
1242  std::multimap<double, unsigned int> hcalGsfElems;
1243  block.associatedElements( gsfIs[iEle],linkData,
1244  hcalGsfElems,
1247  for( std::multimap<double, unsigned int>::iterator it = hcalGsfElems.begin();
1248  it != hcalGsfElems.end();it++) {
1249  unsigned int index = it->second;
1250  // if(localactive[index] == true) {
1251 
1252  // Check that this cluster is not closer to another GSF
1253  // remove in high energetic jets this is dangerous.
1254 // std::multimap<double, unsigned> sortedGsf;
1255 // block.associatedElements( index, linkData,
1256 // sortedGsf,
1257 // reco::PFBlockElement::GSF,
1258 // reco::PFBlock::LINKTEST_ALL );
1259 // unsigned jGsf = sortedGsf.begin()->second;
1260 // if ( jGsf != gsfIs[iEle]) continue;
1261 
1262  EcalElemsIndex.push_back(index);
1263  localactive[index] = false;
1264 
1265  // }
1266  }
1267  // if the closest ecal cluster has been link with the KF, check KF - HCAL link
1268  if(hcalGsfElems.size() == 0 && ClosestEcalWithKf == true) {
1269  std::multimap<double, unsigned int> hcalKfElems;
1270  block.associatedElements( KfGsf_index,linkData,
1271  hcalKfElems,
1274  for( std::multimap<double, unsigned int>::iterator it = hcalKfElems.begin();
1275  it != hcalKfElems.end();it++) {
1276  unsigned int index = it->second;
1277  if(localactive[index] == true) {
1278 
1279  // Check that this cluster is not closer to another KF
1280  std::multimap<double, unsigned> sortedKf;
1281  block.associatedElements( index, linkData,
1282  sortedKf,
1283  reco::PFBlockElement::TRACK,
1285  unsigned jKf = sortedKf.begin()->second;
1286  if ( jKf != KfGsf_index) continue;
1287  EcalElemsIndex.push_back(index);
1288  localactive[index] = false;
1289  }
1290  }
1291  }
1292  // Find Other Primary Tracks Associated to the same Gsf Clusters
1293  std::multimap<double, unsigned int> kfEtraElems;
1294  block.associatedElements( EcalIndex[ikeyecal],linkData,
1295  kfEtraElems,
1296  reco::PFBlockElement::TRACK,
1298  if(kfEtraElems.size() > 0) {
1299  for( std::multimap<double, unsigned int>::iterator it = kfEtraElems.begin();
1300  it != kfEtraElems.end();it++) {
1301  unsigned int index = it->second;
1302 
1303  // 19 Mar 2010 do not consider here tracks from gamma conv
1304  // const reco::PFBlockElementTrack * kfTk =
1305  // dynamic_cast<const reco::PFBlockElementTrack*>((&elements[index]));
1306  // DANIELE ? It is not need because of the local locking
1307  // if(kfTk->isLinkedToDisplacedVertex()) continue;
1308 
1309  bool thisIsAMuon = false;
1310  thisIsAMuon = PFMuonAlgo::isMuon(elements[index]);
1311  if (DebugSetLinksDetailed && thisIsAMuon)
1312  cout << " This is a Muon: index " << index << endl;
1313  if(localactive[index] == true && !thisIsAMuon) {
1314  if(index != KfGsf_index) {
1315  // Check that this track is not closer to another ECAL cluster
1316  // Not Sure here I need this step
1317  std::multimap<double, unsigned> sortedECAL;
1318  block.associatedElements( index, linkData,
1319  sortedECAL,
1322  unsigned jEcal = sortedECAL.begin()->second;
1323  if ( jEcal != EcalIndex[ikeyecal]) continue;
1324  EcalElemsIndex.push_back(index);
1325  localactive[index] = false;
1326  }
1327  }
1328  }
1329  }
1330 
1331  }
1332  associatedToEcal_.insert(pair<unsigned int,vector<unsigned int> >(EcalIndex[ikeyecal],EcalElemsIndex));
1333  }
1334  }// end type GSF
1335  } // endis there a gsf track
1336 
1337  // ******************* End Link *****************************
1338 
1339  //
1340  // Below is only for debugging printout
1341  if (DebugSetLinksSummary) {
1342  if(IsThereAGoodGSFTrack) {
1343  if (DebugSetLinksSummary) cout << " -- The Link Summary --" << endl;
1344  for(map<unsigned int,vector<unsigned int> >::iterator it = associatedToGsf_.begin();
1345  it != associatedToGsf_.end(); it++) {
1346 
1347  if (DebugSetLinksSummary) cout << " AssoGsf " << it->first << endl;
1348  vector<unsigned int> eleasso = it->second;
1349  for(unsigned int i=0;i<eleasso.size();i++) {
1350  PFBlockElement::Type type = elements[eleasso[i]].type();
1351  if(type == reco::PFBlockElement::BREM) {
1352  if (DebugSetLinksSummary)
1353  cout << " AssoGsfElements BREM " << eleasso[i] << endl;
1354  }
1355  else if(type == reco::PFBlockElement::ECAL) {
1356  if (DebugSetLinksSummary)
1357  cout << " AssoGsfElements ECAL " << eleasso[i] << endl;
1358  }
1359  else if(type == reco::PFBlockElement::TRACK) {
1360  if (DebugSetLinksSummary)
1361  cout << " AssoGsfElements KF " << eleasso[i] << endl;
1362  }
1363  else {
1364  if (DebugSetLinksSummary)
1365  cout << " AssoGsfElements ????? " << eleasso[i] << endl;
1366  }
1367  }
1368  }
1369 
1370  for(map<unsigned int,vector<unsigned int> >::iterator it = associatedToBrems_.begin();
1371  it != associatedToBrems_.end(); it++) {
1372  if (DebugSetLinksSummary) cout << " AssoBrem " << it->first << endl;
1373  vector<unsigned int> eleasso = it->second;
1374  for(unsigned int i=0;i<eleasso.size();i++) {
1375  PFBlockElement::Type type = elements[eleasso[i]].type();
1376  if(type == reco::PFBlockElement::ECAL) {
1377  if (DebugSetLinksSummary)
1378  cout << " AssoBremElements ECAL " << eleasso[i] << endl;
1379  }
1380  else {
1381  if (DebugSetLinksSummary)
1382  cout << " AssoBremElements ????? " << eleasso[i] << endl;
1383  }
1384  }
1385  }
1386 
1387  for(map<unsigned int,vector<unsigned int> >::iterator it = associatedToEcal_.begin();
1388  it != associatedToEcal_.end(); it++) {
1389  if (DebugSetLinksSummary) cout << " AssoECAL " << it->first << endl;
1390  vector<unsigned int> eleasso = it->second;
1391  for(unsigned int i=0;i<eleasso.size();i++) {
1392  PFBlockElement::Type type = elements[eleasso[i]].type();
1393  if(type == reco::PFBlockElement::PS1) {
1394  if (DebugSetLinksSummary)
1395  cout << " AssoECALElements PS1 " << eleasso[i] << endl;
1396  }
1397  else if(type == reco::PFBlockElement::PS2) {
1398  if (DebugSetLinksSummary)
1399  cout << " AssoECALElements PS2 " << eleasso[i] << endl;
1400  }
1401  else if(type == reco::PFBlockElement::HCAL) {
1402  if (DebugSetLinksSummary)
1403  cout << " AssoECALElements HCAL " << eleasso[i] << endl;
1404  }
1405  else {
1406  if (DebugSetLinksSummary)
1407  cout << " AssoHCALElements ????? " << eleasso[i] << endl;
1408  }
1409  }
1410  }
1411  if (DebugSetLinksSummary)
1412  cout << "-- End Summary --" << endl;
1413  }
1414 
1415  }
1416  // EndPrintOut
1417  return IsThereAGoodGSFTrack;
1418 }
std::vector< std::pair< unsigned int, unsigned int > > fifthStepKfTrack_
type
Definition: HCALResponse.h:21
const math::XYZTLorentzVector & Pout() const
const math::XYZPointF & positionAtECALEntrance() const
int i
Definition: DBlmapReader.cc:9
const reco::TrackRef & trackRef() const
const reco::GsfTrackRef & GsftrackRef() const
bool isNonnull() const
Checks for non-null.
Definition: Ref.h:250
trackRef_iterator tracks_end() const
last iterator over tracks
Definition: Vertex.cc:44
static bool isMuon(const reco::PFBlockElement &elt)
Definition: PFMuonAlgo.cc:153
std::vector< std::pair< unsigned int, unsigned int > > convGsfTrack_
const math::XYZPointF & positionAtECALEntrance() const
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
std::map< unsigned int, Link > LinkData
Definition: PFBlock.h:46
size_type size() const
Definition: OwnVector.h:254
list elements
Definition: asciidump.py:414
bool isPrimaryTrack(const reco::PFBlockElementTrack &KfEl, const reco::PFBlockElementGsfTrack &GsfEl)
const PFClusterRef & clusterRef() const
const edm::OwnVector< reco::PFBlockElement > & elements() const
Definition: PFBlock.h:107
const LinkData & linkData() const
Definition: PFBlock.h:112
unsigned int indTrajPoint() const
int ii
Definition: cuy.py:588
double coneEcalIsoForEgammaSC_
T sqrt(T t)
Definition: SSEVec.h:48
double sumEtEcalIsoForEgammaSC_barrel_
double sumEtEcalIsoForEgammaSC_endcap_
virtual bool trackType(TrackType trType) const
#define M_PI
double sumPtTrackIsoForEgammaSC_endcap_
unsigned int whichTrackAlgo(const reco::TrackRef &trackRef)
void associatedElements(unsigned i, const LinkData &linkData, std::multimap< double, unsigned > &sortedAssociates, reco::PFBlockElement::Type type=PFBlockElement::NONE, LinkTest test=LINKTEST_RECHIT) const
Definition: PFBlock.cc:75
std::vector< TrackBaseRef >::const_iterator trackRef_iterator
The iteratator for the vector&lt;TrackRef&gt;
Definition: Vertex.h:37
double sumPtTrackIsoForEgammaSC_barrel_
tuple cout
Definition: gather_cfg.py:121
double dist(unsigned ie1, unsigned ie2, const LinkData &linkData, LinkTest test) const
Definition: PFBlock.h:94
trackRef_iterator tracks_begin() const
first iterator over tracks
Definition: Vertex.cc:39
unsigned int nTrackIsoForEgammaSC_
Definition: fakeMenu.h:6
boost::shared_ptr< PFEnergyCalibration > thePFEnergyCalibration_
bool applyCrackCorrections_
bool useEGammaSupercluster_
Block of elements.
Definition: PFBlock.h:30
unsigned int PFElectronAlgo::whichTrackAlgo ( const reco::TrackRef trackRef)
private

Definition at line 2665 of file PFElectronAlgo.cc.

References IterativeDetachedTripletStep_cff::detachedTripletStep, InitialStep_cff::initialStep, IterativeMixedTripletStep_cff::mixedTripletStep, and PixelLessStep_cff::pixelLessStep.

Referenced by SetIDOutputs(), and SetLinks().

2665  {
2666  unsigned int Algo = 0;
2667  switch (trackRef->algo()) {
2668  case TrackBase::ctf:
2670  case TrackBase::lowPtTripletStep:
2671  case TrackBase::pixelPairStep:
2672  case TrackBase::jetCoreRegionalStep:
2673  case TrackBase::muonSeededStepInOut:
2674  case TrackBase::muonSeededStepOutIn:
2675  Algo = 0;
2676  break;
2678  Algo = 1;
2679  break;
2681  Algo = 2;
2682  break;
2684  Algo = 3;
2685  break;
2686  case TrackBase::tobTecStep:
2687  Algo = 4;
2688  break;
2689  default:
2690  Algo = 5;
2691  break;
2692  }
2693  return Algo;
2694 }
Definition: fakeMenu.h:6

Member Data Documentation

std::vector<reco::PFCandidate> PFElectronAlgo::allElCandidate_
private

Definition at line 113 of file PFElectronAlgo.h.

Referenced by getAllElectronCandidates(), RunPFElectron(), and SetCandidates().

bool PFElectronAlgo::applyCrackCorrections_
private

Definition at line 127 of file PFElectronAlgo.h.

Referenced by SetCandidates(), SetIDOutputs(), and SetLinks().

std::vector<double> PFElectronAlgo::BDToutput_
private

Definition at line 115 of file PFElectronAlgo.h.

Referenced by RunPFElectron(), SetActive(), SetCandidates(), and SetIDOutputs().

float PFElectronAlgo::chi2_gsf
private

Definition at line 146 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

float PFElectronAlgo::chi2_kf
private

Definition at line 146 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

double PFElectronAlgo::coneEcalIsoForEgammaSC_
private

Definition at line 133 of file PFElectronAlgo.h.

Referenced by SetLinks().

double PFElectronAlgo::coneTrackIsoForEgammaSC_
private

Definition at line 137 of file PFElectronAlgo.h.

std::vector< std::pair <unsigned int, unsigned int> > PFElectronAlgo::convGsfTrack_
private

Definition at line 120 of file PFElectronAlgo.h.

Referenced by RunPFElectron(), SetActive(), and SetLinks().

float PFElectronAlgo::DEtaGsfEcalClust
private

Definition at line 153 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

float PFElectronAlgo::dPtOverPt_gsf
private

Definition at line 146 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

float PFElectronAlgo::DPtOverPt_gsf
private

Definition at line 146 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

float PFElectronAlgo::DPtOverPt_kf
private

Definition at line 146 of file PFElectronAlgo.h.

Referenced by SetIDOutputs().

float PFElectronAlgo::earlyBrem
private

Definition at line 156 of file PFElectronAlgo.h.

Referenced by SetIDOutputs().

float PFElectronAlgo::EGsfPoutMode
private

Definition at line 152 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

std::vector<reco::PFCandidate> PFElectronAlgo::elCandidate_
private

Definition at line 112 of file PFElectronAlgo.h.

Referenced by getElectronCandidates(), RunPFElectron(), and SetCandidates().

std::map<unsigned int,std::vector<reco::PFCandidate> > PFElectronAlgo::electronConstituents_
private

Definition at line 114 of file PFElectronAlgo.h.

Referenced by RunPFElectron(), and SetCandidates().

std::vector<reco::PFCandidateElectronExtra > PFElectronAlgo::electronExtra_
private

Definition at line 116 of file PFElectronAlgo.h.

Referenced by getElectronExtra(), RunPFElectron(), SetCandidates(), and SetIDOutputs().

float PFElectronAlgo::Eta_gsf
private

Definition at line 143 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

float PFElectronAlgo::EtotBremPinPoutMode
private

Definition at line 152 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

float PFElectronAlgo::EtotPinMode
private

Definition at line 152 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

std::vector< std::pair <unsigned int, unsigned int> > PFElectronAlgo::fifthStepKfTrack_
private

Definition at line 119 of file PFElectronAlgo.h.

Referenced by RunPFElectron(), SetActive(), and SetLinks().

float PFElectronAlgo::firstBrem
private

Definition at line 156 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

std::vector<bool> PFElectronAlgo::GsfTrackSingleEcal_
private

Definition at line 118 of file PFElectronAlgo.h.

float PFElectronAlgo::HOverHE
private

Definition at line 157 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

float PFElectronAlgo::HOverPin
private

Definition at line 157 of file PFElectronAlgo.h.

Referenced by SetIDOutputs().

bool PFElectronAlgo::isvalid_
private

Definition at line 159 of file PFElectronAlgo.h.

Referenced by isElectronValidCandidate(), and RunPFElectron().

float PFElectronAlgo::lateBrem
private

Definition at line 156 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

float PFElectronAlgo::lnPt_gsf
private

Definition at line 143 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

std::vector<bool> PFElectronAlgo::lockExtraKf_
private

Definition at line 117 of file PFElectronAlgo.h.

Referenced by RunPFElectron(), SetActive(), and SetIDOutputs().

double PFElectronAlgo::mvaEleCut_
private

Definition at line 124 of file PFElectronAlgo.h.

Referenced by SetActive(), SetCandidates(), and SetIDOutputs().

const char* PFElectronAlgo::mvaWeightFile_
private

Definition at line 139 of file PFElectronAlgo.h.

float PFElectronAlgo::nhit_gsf
private

Definition at line 149 of file PFElectronAlgo.h.

Referenced by SetCandidates(), and SetIDOutputs().

float PFElectronAlgo::nhit_kf
private

Definition at line 149 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), SetCandidates(), and SetIDOutputs().

unsigned int PFElectronAlgo::nTrackIsoForEgammaSC_
private

Definition at line 136 of file PFElectronAlgo.h.

Referenced by SetLinks().

float PFElectronAlgo::SigmaEtaEta
private

Definition at line 154 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), and SetIDOutputs().

double PFElectronAlgo::sumEtEcalIsoForEgammaSC_barrel_
private

Definition at line 131 of file PFElectronAlgo.h.

Referenced by SetLinks().

double PFElectronAlgo::sumEtEcalIsoForEgammaSC_endcap_
private

Definition at line 132 of file PFElectronAlgo.h.

Referenced by SetLinks().

double PFElectronAlgo::sumPtTrackIsoForEgammaSC_barrel_
private

Definition at line 134 of file PFElectronAlgo.h.

Referenced by SetLinks().

double PFElectronAlgo::sumPtTrackIsoForEgammaSC_endcap_
private

Definition at line 135 of file PFElectronAlgo.h.

Referenced by SetLinks().

const std::vector<reco::GsfElectron>* PFElectronAlgo::theGsfElectrons_
private

Definition at line 161 of file PFElectronAlgo.h.

Referenced by SetActive(), SetCandidates(), and setEGElectronCollection().

boost::shared_ptr<PFEnergyCalibration> PFElectronAlgo::thePFEnergyCalibration_
private

Definition at line 126 of file PFElectronAlgo.h.

Referenced by SetCandidates(), SetIDOutputs(), and SetLinks().

boost::shared_ptr<PFSCEnergyCalibration> PFElectronAlgo::thePFSCEnergyCalibration_
private

Definition at line 125 of file PFElectronAlgo.h.

Referenced by SetCandidates().

TMVA::Reader* PFElectronAlgo::tmvaReader_
private

Definition at line 123 of file PFElectronAlgo.h.

Referenced by PFElectronAlgo(), SetIDOutputs(), and ~PFElectronAlgo().

bool PFElectronAlgo::useEGammaSupercluster_
private

Definition at line 130 of file PFElectronAlgo.h.

Referenced by SetLinks().

bool PFElectronAlgo::useEGElectrons_
private

Definition at line 129 of file PFElectronAlgo.h.

Referenced by SetActive(), and SetCandidates().

bool PFElectronAlgo::usePFSCEleCalib_
private

Definition at line 128 of file PFElectronAlgo.h.

Referenced by SetCandidates().