GenPurposeSkimmerData Class Reference

#include <GenPurposeSkimmerData.h>

Inheritance diagram for GenPurposeSkimmerData:

Public Member Functions
	GenPurposeSkimmerData (const edm::ParameterSet &)
	~GenPurposeSkimmerData ()
Public Member Functions inherited from edm::EDAnalyzer
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)
	EDAnalyzer ()
ModuleDescription const &	moduleDescription () const
std::string	workerType () const
virtual	~EDAnalyzer ()
Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfo >	consumesInfo () const
	EDConsumerBase ()
ProductHolderIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const
void	itemsMayGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const
void	itemsToGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const
std::vector < ProductHolderIndexAndSkipBit > const &	itemsToGetFromEvent () const
void	labelsForToken (EDGetToken iToken, Labels &oLabels) const
void	modulesDependentUpon (const std::string &iProcessName, std::vector< const char * > &oModuleLabels) const
void	modulesWhoseProductsAreConsumed (std::vector< ModuleDescription const * > &modules, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const
bool	registeredToConsume (ProductHolderIndex, bool, BranchType) const
bool	registeredToConsumeMany (TypeID const &, BranchType) const
void	updateLookup (BranchType iBranchType, ProductHolderIndexHelper const &)
virtual	~EDConsumerBase ()

Private Member Functions
virtual void	analyze (const edm::Event &, const edm::EventSetup &)
virtual void	beginJob ()
virtual void	endJob ()

Private Attributes
double	BarrelMaxEta
edm::EDGetTokenT < reco::SuperClusterCollection >	corHybridscToken_
double	ctf_track_eta [20]
double	ctf_track_phi [20]
double	ctf_track_pt [20]
double	ctf_track_tip [20]
double	ctf_track_tip_bs [20]
double	ctf_track_vx [20]
double	ctf_track_vy [20]
double	ctf_track_vz [20]
edm::EDGetTokenT < reco::TrackCollection >	ctfTracksToken_
int	elec_1_duplicate_removal
int	elec_number_in_event
edm::EDGetTokenT < pat::ElectronCollection >	ElectronCollectionToken_
double	EndcapMaxEta
double	EndcapMinEta
int	event_HLTPath [25]
double	event_mcMET
double	event_mcMET_phi
double	event_mcMET_sig
double	event_MET
double	event_MET_phi
double	event_MET_sig
double	event_pfMET
double	event_pfMET_phi
double	event_pfMET_sig
double	event_t1MET
double	event_t1MET_phi
double	event_t1MET_sig
double	event_tcMET
double	event_tcMET_phi
double	event_tcMET_sig
edm::EDGetTokenT < reco::GenMETCollection >	genMetCollectionToken_
double	GsfTrackMinInnerPt
TFile *	histofile
edm::InputTag	HLTCollectionE29_
edm::EDGetTokenT < trigger::TriggerEvent >	HLTCollectionE29Token_
edm::InputTag	HLTCollectionE31_
edm::EDGetTokenT < trigger::TriggerEvent >	HLTCollectionE31Token_
edm::InputTag	HLTFilterType_ [25]
edm::InputTag	HLTTriggerResultsE29_
edm::EDGetTokenT < edm::TriggerResults >	HLTTriggerResultsE29Token_
edm::InputTag	HLTTriggerResultsE31_
edm::EDGetTokenT < edm::TriggerResults >	HLTTriggerResultsE31Token_
edm::InputTag	MCCollection_
edm::EDGetTokenT < reco::GenParticleCollection >	MCCollectionToken_
double	MCMatch_Deta_
double	MCMatch_Dphi_
edm::EDGetTokenT < pat::METCollection >	mcMetCollectionToken_
edm::InputTag	MetCollectionTag_
edm::EDGetTokenT < reco::CaloMETCollection >	MetCollectionToken_
edm::EDGetTokenT < reco::SuperClusterCollection >	multi5x5scToken_
double	muon_eta [4]
double	muon_phi [4]
double	muon_pt [4]
double	muon_tip [4]
double	muon_tip_bs [4]
double	muon_vx [4]
double	muon_vy [4]
double	muon_vz [4]
int	numberOfHLTFilterObjects [25]
edm::EDGetTokenT< reco::BeamSpot >	offlineBeamSpotToken_
std::string	outputFile_
edm::EDGetTokenT < reco::PFMETCollection >	pfMetCollectionToken_
edm::EDGetTokenT < pat::MuonCollection >	pMuonsToken_
int	probe_charge_for_tree [4]
int	probe_classification_index_for_tree [4]
double	probe_ecal_iso_user [4]
double	probe_ecal_isolation_value [4]
double	probe_ele_dfi [4]
double	probe_ele_dhi [4]
double	probe_ele_e1x5 [4]
double	probe_ele_e2x5 [4]
double	probe_ele_e5x5 [4]
double	probe_ele_eop [4]
double	probe_ele_et_for_tree [4]
double	probe_ele_eta_for_tree [4]
double	probe_ele_hoe [4]
int	probe_ele_pass_et_cut [4]
int	probe_ele_pass_fiducial_cut [4]
double	probe_ele_phi_for_tree [4]
double	probe_ele_pin [4]
double	probe_ele_pout [4]
double	probe_ele_shh [4]
double	probe_ele_sihih [4]
double	probe_ele_tip [4]
double	probe_ele_Xvertex_for_tree [4]
double	probe_ele_Yvertex_for_tree [4]
double	probe_ele_Zvertex_for_tree [4]
double	probe_hcal_iso_user [4]
double	probe_hcal_isolation_value [4]
double	probe_hlt_matched_dr [4]
int	probe_index_for_tree [4]
double	probe_iso_user [4]
double	probe_isolation_value [4]
int	probe_mc_matched [4]
double	probe_mc_matched_denergy [4]
double	probe_mc_matched_deta [4]
double	probe_mc_matched_dphi [4]
int	probe_mc_matched_mother [4]
int	probe_pass_id_loose [4]
int	probe_pass_id_robust_loose [4]
int	probe_pass_id_robust_tight [4]
int	probe_pass_id_tight [4]
int	probe_pass_iso_cut [4]
int	probe_pass_recoEle_cut [4]
int	probe_pass_tip_cut [4]
int	probe_pass_trigger_cut [4][25]
double	probe_sc_et_for_tree [4]
double	probe_sc_eta_for_tree [4]
int	probe_sc_pass_et_cut [4]
int	probe_sc_pass_fiducial_cut [4]
double	probe_sc_phi_for_tree [4]
TTree *	probe_tree
double	ProbeHLTObjMaxDR
double	ProbeRecoEleSCMaxDE
double	ProbeSCMinEt
double	RecoEleSeedBCMaxDE
double	sc_hybrid_et [5]
double	sc_hybrid_eta [5]
double	sc_hybrid_phi [5]
double	sc_multi5x5_et [5]
double	sc_multi5x5_eta [5]
double	sc_multi5x5_phi [5]
edm::EDGetTokenT < pat::METCollection >	t1MetCollectionToken_
edm::EDGetTokenT < reco::METCollection >	tcMetCollectionToken_
int	tree_fills_

Additional Inherited Members
Public Types inherited from edm::EDAnalyzer
typedef EDAnalyzer	ModuleType
Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels
Static Public Member Functions inherited from edm::EDAnalyzer
static const std::string &	baseType ()
static void	fillDescriptions (ConfigurationDescriptions &descriptions)
static void	prevalidate (ConfigurationDescriptions &)
Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)
EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	consumes (TypeToGet const &id, edm::InputTag const &tag)
ConsumesCollector	consumesCollector ()
	Use a ConsumesCollector to gather consumes information from helper functions. More...
template<typename ProductType , BranchType B = InEvent>
void	consumesMany ()
void	consumesMany (const TypeToGet &id)
template<BranchType B>
void	consumesMany (const TypeToGet &id)
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

Detailed Description

Description:

Implementation:

This is a general purpose Skimmer ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ It reads datasets and keeps only the analysis-relevant information and stores it in a simple TTree. Code Inspired by the T&P code by Claire Timlin Note: a similar code to read PAT tuples is already available

History: 16.10.08: first version 24.10.08: added ECAL/HCAL isolation + sigma ieta ieta (S. Harper) 30.10.08: all isolations use isodeposits all parameters are untracked 18.03.09: modified to store just the 4 highest ET gsf electrons in the event 02.04.09: version for redigi including particle flow MET + gen level MET 04.04.09: version for redigi including tcMET, MET eta dropped 22.04.09: version for redigi including MET Type1 corrections 23.04.09: version completely changes to read from PAT....................... 07.09.09: version for 3_1_2 version 08.09.09: version for 3_1_2 that keeps all the trigger info and reduced number of the other collections

Further Information/Inquiries: Nikos Rompotis - Imperial College London Nikol.nosp@m.aos..nosp@m.Rompo.nosp@m.tis@.nosp@m.Cern..nosp@m.ch

Definition at line 70 of file GenPurposeSkimmerData.h.

Constructor & Destructor Documentation

GenPurposeSkimmerData::GenPurposeSkimmerData ( const edm::ParameterSet &  ps )

explicit

Definition at line 54 of file GenPurposeSkimmerData.cc.

References BarrelMaxEta, corHybridscToken_, ctfTracksToken_, ElectronCollectionToken_, EndcapMaxEta, EndcapMinEta, edm::ParameterSet::getUntrackedParameter(), HLTCollectionE29_, HLTCollectionE29Token_, HLTCollectionE31_, HLTCollectionE31Token_, HLTTriggerResultsE29_, HLTTriggerResultsE29Token_, HLTTriggerResultsE31_, HLTTriggerResultsE31Token_, HLT_25ns14e33_v1_cff::InputTag, mcMetCollectionToken_, MetCollectionTag_, MetCollectionToken_, multi5x5scToken_, offlineBeamSpotToken_, outputFile_, pfMetCollectionToken_, pMuonsToken_, ProbeHLTObjMaxDR, AlCaHLTBitMon_QueryRunRegistry::string, t1MetCollectionToken_, and tcMetCollectionToken_.

{
//
//   I N P U T      P A R A M E T E R S
//
  // output file name
  outputFile_ = ps.getUntrackedParameter<std::string>("outputfile");
  //
  // Electron Collection
  ElectronCollectionToken_=consumes<pat::ElectronCollection>(ps.getUntrackedParameter<edm::InputTag>("ElectronCollection"));
  //
  // MC:
  //MCCollection_ = ps.getUntrackedParameter<edm::InputTag>("MCCollection");
  //MCCollectionToken_ = consumes<reco::GenParticleCollection>(MCCollection_);
  //MCMatch_Deta_ = ps.getUntrackedParameter<double>("MCMatch_Deta",0.1);
  //MCMatch_Dphi_ = ps.getUntrackedParameter<double>("MCMatch_Dphi",0.35);
  //
  // MET Collections:
  MetCollectionTag_ = ps.getUntrackedParameter<edm::InputTag>("MetCollectionTag");
  MetCollectionToken_ = consumes<reco::CaloMETCollection>(MetCollectionTag_);
  mcMetCollectionToken_ = consumes<pat::METCollection>(ps.getUntrackedParameter<edm::InputTag>("mcMetCollectionTag"));
  t1MetCollectionToken_ = consumes<pat::METCollection>(ps.getUntrackedParameter<edm::InputTag>("t1MetCollectionTag"));
  pfMetCollectionToken_ = consumes<reco::PFMETCollection>(ps.getUntrackedParameter<edm::InputTag>("pfMetCollectionTag"));
  tcMetCollectionToken_ = consumes<reco::METCollection>(ps.getUntrackedParameter<edm::InputTag>("tcMetCollectionTag"));
  //  genMetCollectionToken_ = consumes<reco::GenMETCollection>(ps.getUntrackedParameter<edm::InputTag>("genMetCollectionTag"));
  //
  // HLT parameters:
  // allow info for 2 paths and 2 filters
  // ---------------------------------------------------------------------------
  HLTCollectionE29_= ps.getUntrackedParameter<edm::InputTag>("HLTCollectionE29");
  HLTCollectionE29Token_ = consumes<trigger::TriggerEvent>(HLTCollectionE29_);
  HLTCollectionE31_= ps.getUntrackedParameter<edm::InputTag>("HLTCollectionE31");
  HLTCollectionE31Token_ = consumes<trigger::TriggerEvent>(HLTCollectionE31_);
  HLTTriggerResultsE29_ = ps.getUntrackedParameter<edm::InputTag>("HLTTriggerResultsE29");
  HLTTriggerResultsE29Token_ = consumes<edm::TriggerResults>(HLTTriggerResultsE29_);
  HLTTriggerResultsE31_ = ps.getUntrackedParameter<edm::InputTag>("HLTTriggerResultsE31");
  HLTTriggerResultsE31Token_ = consumes<edm::TriggerResults>(HLTTriggerResultsE31_);
  //HLTPath_ = ps.getUntrackedParameter<std::string>("HLTPath","HLT_Ele15_LW_L1R");
  //HLTFilterType_ =ps.getUntrackedParameter<edm::InputTag>("HLTFilterType");
  //
  // matching HLT objects to electrons
  ProbeHLTObjMaxDR= ps.getUntrackedParameter<double>("ProbeHLTObjMaxDR",0.2);
  //
  // ----------------------------------------------------------------------------
  //
  // detector geometry
  //
  BarrelMaxEta = ps.getUntrackedParameter<double>("BarrelMaxEta");
  EndcapMinEta = ps.getUntrackedParameter<double>("EndcapMinEta");
  EndcapMaxEta = ps.getUntrackedParameter<double>("EndcapMaxEta");
  //
  ctfTracksToken_ = consumes<reco::TrackCollection>(ps.getUntrackedParameter<edm::InputTag>("ctfTracksTag"));
  corHybridscToken_  = consumes<reco::SuperClusterCollection>(ps.getUntrackedParameter<edm::InputTag>("corHybridsc"));
  multi5x5scToken_   = consumes<reco::SuperClusterCollection>(ps.getUntrackedParameter<edm::InputTag>("multi5x5sc"));
  offlineBeamSpotToken_ = consumes<reco::BeamSpot>(edm::InputTag("offlineBeamSpot"));
  pMuonsToken_ = consumes<pat::MuonCollection>(edm::InputTag("selectedLayer1Muons"));

}

GenPurposeSkimmerData::~GenPurposeSkimmerData

(

)

Definition at line 115 of file GenPurposeSkimmerData.cc.

{

   // do anything here that needs to be done at desctruction time
   // (e.g. close files, deallocate resources etc.)

}

Member Function Documentation

void GenPurposeSkimmerData::analyze ( const edm::Event &  evt, const edm::EventSetup &  es  )

privatevirtual

-*-*-*-*-*–*-*-*-*-*-*-*-*-*-*-*-*–*-*-*-*-*-*-*-*-*-*-*-*-*-*-*–*-*-*

Implements edm::EDAnalyzer.

Definition at line 130 of file GenPurposeSkimmerData.cc.

References BarrelMaxEta, corHybridscToken_, gather_cfg::cout, ctf_track_eta, ctf_track_phi, ctf_track_pt, ctf_track_tip, ctf_track_tip_bs, ctf_track_vx, ctf_track_vy, ctf_track_vz, ctfTracksToken_, reco::TrackBase::dxy(), elec_1_duplicate_removal, elec_number_in_event, ElectronCollectionToken_, HI_PhotonSkim_cff::electrons, EndcapMaxEta, EndcapMinEta, reco::CaloCluster::energy(), reco::CaloCluster::eta(), reco::TrackBase::eta(), event_mcMET, event_mcMET_phi, event_mcMET_sig, event_MET, event_MET_phi, event_MET_sig, event_pfMET, event_pfMET_phi, event_pfMET_sig, event_t1MET, event_t1MET_phi, event_t1MET_sig, event_tcMET, event_tcMET_phi, event_tcMET_sig, edm::Event::getByToken(), HLTCollectionE29Token_, i, cmsHarvester::index, edm::HandleBase::isValid(), mcMetCollectionToken_, HLT_25ns14e33_v3_cff::MET, MetCollectionTag_, MetCollectionToken_, multi5x5scToken_, metsig::muon, muon_eta, muon_phi, muon_pt, muon_tip, muon_tip_bs, muon_vx, muon_vy, muon_vz, offlineBeamSpotToken_, pfMET_cfi::pfMET, pfMetCollectionToken_, reco::CaloCluster::phi(), reco::TrackBase::phi(), pMuonsToken_, reco::BeamSpot::position(), probe_charge_for_tree, probe_classification_index_for_tree, probe_ecal_iso_user, probe_ecal_isolation_value, probe_ele_dfi, probe_ele_dhi, probe_ele_e1x5, probe_ele_e2x5, probe_ele_e5x5, probe_ele_eop, probe_ele_et_for_tree, probe_ele_eta_for_tree, probe_ele_hoe, probe_ele_phi_for_tree, probe_ele_pin, probe_ele_pout, probe_ele_shh, probe_ele_sihih, probe_ele_tip, probe_ele_Xvertex_for_tree, probe_ele_Yvertex_for_tree, probe_ele_Zvertex_for_tree, probe_hcal_iso_user, probe_hcal_isolation_value, probe_iso_user, probe_isolation_value, probe_sc_et_for_tree, probe_sc_eta_for_tree, probe_sc_pass_fiducial_cut, probe_sc_phi_for_tree, probe_tree, edm::Handle< T >::product(), reco::TrackBase::pt(), sc_hybrid_et, sc_hybrid_eta, sc_hybrid_phi, sc_multi5x5_et, sc_multi5x5_eta, sc_multi5x5_phi, t1MetCollectionToken_, tcMetCollectionToken_, pat::Muon::track(), tree_fills_, reco::TrackBase::vx(), reco::TrackBase::vy(), and reco::TrackBase::vz().

{
  // MC Collection ------------------------------------------------

  //  edm::Handle<reco::GenParticleCollection> pGenPart;
  //  evt.getByToken(MCCollectionToken_, pGenPart);
  //  if ( not  pGenPart.isValid() ) {
  //    std::cout <<"Error! Can't get "<<MCCollection_.label() << std::endl;
  //    return;
  //  }

  //  const reco::GenParticleCollection *McCand = pGenPart.product();

  // GsF Electron Collection ---------------------------------------
  edm::Handle<pat::ElectronCollection> pElectrons;

  try{
    evt.getByToken(ElectronCollectionToken_, pElectrons);
  }
  catch (cms::Exception)
    {
      edm::LogError("")<< "Error! Can't get ElectronCollection by label. ";
    }
  // ***********************************************************************
  // check which trigger has accepted the event ****************************
  // ***********************************************************************
  //
  // path allocation: first 10 paths belong to the low lum menu, the rest
  // in the high lum one
  //
  // Low Luminosity Menu (8e29)
  //
  /*
  edm::Handle<edm::TriggerResults> HLTResultsE29;
  evt.getByToken(HLTTriggerResultsE29Token_, HLTResultsE29);
  if (not HLTResultsE29.isValid()) {
    std::cout << "HLT Results with label: " << HLTTriggerResultsE29_
          << " not found" << std::endl;
    return;
  }
  //
  edm::Handle<trigger::TriggerEvent> pHLTe29;
  evt.getByToken(HLTCollectionE29Token_, pHLTe29);
  if (not pHLTe29.isValid()) {
    std::cout << "HLT Results with label: " << HLTCollectionE29_
          << " not found" << std::endl;
    return;
  }
  //
  int sum = 0;
  //
  for (int iT=0; iT<10; ++iT) {
    event_HLTPath[iT] = 0;
    numberOfHLTFilterObjects[iT] =0;
    //
    const edm::TriggerNames & triggerNames = evt.triggerNames(*HLTResultsE29);
    unsigned int trigger_size = HLTResultsE29->size();
    unsigned int trigger_position = triggerNames.triggerIndex(HLTPath_[iT]);
    if (trigger_position < trigger_size )
      event_HLTPath[iT] = (int) HLTResultsE29->accept(trigger_position);
    //
    numberOfHLTFilterObjects[iT] = 0;
    // check explicitly that the filter is there
    const int nF(pHLTe29->sizeFilters());
    const int filterInd = pHLTe29->filterIndex(HLTFilterType_[iT]);
    if (nF != filterInd) {
      const trigger::Vids& VIDS (pHLTe29->filterIds(filterInd));
      const trigger::Keys& KEYS(pHLTe29->filterKeys(filterInd));
      const int nI(VIDS.size());
      const int nK(KEYS.size());
      numberOfHLTFilterObjects[iT] = (nI>nK)? nI:nK;
    }
    //if (iT==2) // HLT_Ele15_LW_L1R only this trigger is required
      sum += numberOfHLTFilterObjects[iT];
  }
  //
  // High Luminosity Menu (1e31) DISABLED - only low lumi level
  //
  edm::Handle<edm::TriggerResults> HLTResultsE31;
  evt.getByToken(HLTTriggerResultsE31Token_, HLTResultsE31);
  if (not HLTResultsE31.isValid()) {
      std::cout << "HLT Results with label: " << HLTTriggerResultsE31_
            << " not found" << std::endl;
    return;
  }
  edm::Handle<trigger::TriggerEvent> pHLTe31;
  evt.getByToken(HLTCollectionE31Token_, pHLTe31);
  if (not pHLTe31.isValid()) {
    std::cout << "HLT Results with label: " << HLTCollectionE31_
          << " not found" << std::endl;
    return;
  }
  for (int iT=10; iT<25; ++iT) {
    event_HLTPath[iT] = 0;
    numberOfHLTFilterObjects[iT] =0;
    //
    const edm::TriggerNames & triggerNames = evt.triggerNames(*HLTResultsE31);
    unsigned int trigger_size = HLTResultsE31->size();
    unsigned int trigger_position = triggerNames.triggerIndex(HLTPath_[iT]);
    if (trigger_position < trigger_size )
      event_HLTPath[iT] = (int) HLTResultsE31->accept(trigger_position);
    //
    numberOfHLTFilterObjects[iT] = 0;
    // check explicitly that the filter is there
    const int nF(pHLTe31->sizeFilters());
    const int filterInd = pHLTe31->filterIndex(HLTFilterType_[iT]);
    if (nF != filterInd) {
      const trigger::Vids& VIDS (pHLTe31->filterIds(filterInd));
      const trigger::Keys& KEYS(pHLTe31->filterKeys(filterInd));
      const int nI(VIDS.size());
      const int nK(KEYS.size());
      numberOfHLTFilterObjects[iT] = (nI>nK)? nI:nK;
    }
    // not needed
    sum += numberOfHLTFilterObjects[iT];
  }
  if (sum == 0) {
    //std::cout << "No trigger found in this event..." << std::endl;
    return;
  }
  */
  //std::cout << "HLT objects: #" << sum << std::endl;
  // print out the triggers that exist in this event
    // comment this out if you want to see the names of the existing triggers
  edm::Handle<trigger::TriggerEvent> pHLTe29;
  evt.getByToken(HLTCollectionE29Token_, pHLTe29);
  if (not pHLTe29.isValid()){
    std::cout << "Error!!! HLT is missing!" << std::endl;
    return;
  } /*
  else {
    // check explicitly that the filter is there
    const int nF(pHLTe29->sizeFilters());
    for (int filterInd=0; filterInd< nF; ++filterInd) {
      const trigger::Vids& VIDS (pHLTe29->filterIds(filterInd));
      const trigger::Keys& KEYS(pHLTe29->filterKeys(filterInd));
      const int nI(VIDS.size());
      const int nK(KEYS.size());
      int   nObjects = (nI>nK)? nI:nK;
      const edm::InputTag filterTag = pHLTe29->filterTag(filterInd);
      std::cout << "Found filter with name " << filterTag
        << " and #objects: #" << nObjects << std::endl;
    }
  }
    */
  // *********************************************************************
  // MET Collections:
  //
  edm::Handle<reco::CaloMETCollection> caloMET;
  evt.getByToken(MetCollectionToken_, caloMET);
  //
  edm::Handle<pat::METCollection> t1MET;
  evt.getByToken(t1MetCollectionToken_, t1MET);
  //
  edm::Handle<pat::METCollection> mcMET;
  evt.getByToken(mcMetCollectionToken_, mcMET);
  //
  edm::Handle<reco::METCollection> tcMET;
  evt.getByToken(tcMetCollectionToken_, tcMET);
  //
  edm::Handle<reco::PFMETCollection> pfMET;
  evt.getByToken(pfMetCollectionToken_, pfMET);
  //
  //  edm::Handle<reco::GenMETCollection> genMET;
  //  evt.getByToken(genMetCollectionToken_, genMET);
  //
  // initialize the MET variables ........................................
  event_MET     = -99.;   event_MET_phi = -99.;    event_MET_sig = -99.;
  event_mcMET     = -99.;   event_mcMET_phi = -99.;    event_mcMET_sig = -99.;
  event_tcMET   = -99.;   event_tcMET_phi = -99.;  event_tcMET_sig = -99.;
  event_pfMET   = -99.;   event_pfMET_phi = -99.;  event_pfMET_sig = -99.;
  event_t1MET   = -99.;   event_t1MET_phi = -99.;  event_t1MET_sig = -99.;
  //
  //event_genMET  = -99.;   event_genMET_phi= -99.;  event_genMET_sig = -99.;
  //
  // get the values, if they are available
  if ( caloMET.isValid() ) {
    const reco::CaloMETRef MET(caloMET, 0);
    event_MET = MET->et();  event_MET_phi = MET->phi();
    event_MET_sig = MET->mEtSig();
  }
  else {
    std::cout << "caloMET not valid: input Tag: " << MetCollectionTag_
          << std::endl;
  }
  if ( tcMET.isValid() ) {
    const reco::METRef MET(tcMET, 0);
    event_tcMET = MET->et();  event_tcMET_phi = MET->phi();
    event_tcMET_sig = MET->mEtSig();
  }
  if ( pfMET.isValid() ) {
    const reco::PFMETRef MET(pfMET, 0);
    event_pfMET = MET->et();  event_pfMET_phi = MET->phi();
    event_pfMET_sig = MET->mEtSig();
  }
  if ( t1MET.isValid() ) {
    const pat::METRef MET(t1MET, 0);
    event_t1MET = MET->et();  event_t1MET_phi = MET->phi();
    event_t1MET_sig = MET->mEtSig();
  }
  if ( mcMET.isValid() ) {
    const pat::METRef MET(mcMET, 0);
    event_mcMET = MET->et();  event_mcMET_phi = MET->phi();
    event_mcMET_sig = MET->mEtSig();
  }

  //  if ( genMET.isValid() ) {
  //    const reco::GenMETRef MET(genMET, 0);
  //    event_genMET = MET->et();  event_genMET_phi = MET->phi();
  //    event_genMET_sig = MET->mEtSig();
  //  }

  //  std::cout << "t1MET: " << event_t1MET  << " twikiT1MET: "
  //        << event_twikiT1MET  << ", calo="<<event_MET  << std::endl;
  //
  // some supercluster collections ...........................................
  // correcyedHybridSuperClusters
  edm::Handle<reco::SuperClusterCollection> SC1;
  evt.getByToken(corHybridscToken_,SC1);
  const reco::SuperClusterCollection *sc1 = SC1.product();
  // multi5x5SuperClustersWithPreshower
  edm::Handle<reco::SuperClusterCollection> SC2;
  evt.getByToken(multi5x5scToken_,SC2);
  const reco::SuperClusterCollection *sc2 = SC2.product();
  //
  const int n1 =  sc1->size();
  const int n2 =  sc2->size();
  //std::cout << "SC found: hybrid: " << n1 << ", multi5x5: "
  //        << n2 << std::endl;
  // keep details of the 5 highest ET superclusters
  for (int i=0; i<5; ++i) {
    sc_hybrid_et[i] = -9999.;
    sc_hybrid_eta[i] = -9999.;
    sc_hybrid_phi[i] = -9999.;
    //
    sc_multi5x5_et[i] = -9999.;
    sc_multi5x5_eta[i] = -9999.;
    sc_multi5x5_phi[i] = -9999.;
    //
  }
  // sort the energies of the first sc
  std::vector<double> ETsc1;
  std::vector<reco::SuperCluster>::const_iterator sc;
  for (sc = sc1->begin(); sc !=  sc1->end(); ++sc) {
    reco::SuperCluster mySc = *sc;
    double scEt = mySc.energy()/(cosh(mySc.eta()));
    ETsc1.push_back(scEt);

  }
  int *sorted1 = new int[n1];
  double *et1 = new double[n1];
  for (int i=0; i<n1; ++i) {
    et1[i] = ETsc1[i];
  }
  // array sorted now has the indices of the highest ET electrons
  TMath::Sort(n1, et1, sorted1, true);
  // .........................................................................
  std::vector<double> ETsc2;
  for (sc = sc2->begin(); sc !=  sc2->end(); ++sc) {
    reco::SuperCluster mySc = *sc;
    double scEt = mySc.energy()/(cosh(mySc.eta()));
    ETsc2.push_back(scEt);

  }
  int *sorted2 = new int[n2];
  double *et2 = new double[n2];
  for (int i=0; i<n2; ++i) {
    et2[i] = ETsc2[i];
  }
  // array sorted now has the indices of the highest ET electrons
  TMath::Sort(n2, et2, sorted2, true);
  //
  //
  for( int probeSc = 0; probeSc < n1; ++probeSc)
    {
      //std::cout<<"sorted["<< probeIt<< "]=" << sorted[probeIt] << std::endl;
      // break if you have more than the appropriate number of electrons
      if (probeSc >= 5) break;
      //
      int sc_index = sorted1[probeSc];
      std::vector<reco::SuperCluster>::const_iterator
    Rprobe = sc1->begin() + sc_index;
      //
      reco::SuperCluster sc0 = *Rprobe;
      // now keep the relevant stuff:
      sc_hybrid_et[probeSc] =  sc0.energy()/(cosh(sc0.eta()));
      sc_hybrid_eta[probeSc] = sc0.eta();
      sc_hybrid_phi[probeSc] = sc0.phi();
    }
  // .........................................................................
  for( int probeSc = 0; probeSc < n2; ++probeSc)
    {
      //std::cout<<"sorted["<< probeIt<< "]=" << sorted[probeIt] << std::endl;
      // break if you have more than the appropriate number of electrons
      if (probeSc >= 5) break;
      //
      int sc_index = sorted2[probeSc];
      std::vector<reco::SuperCluster>::const_iterator
    Rprobe = sc2->begin() + sc_index;
      //
      reco::SuperCluster sc0 = *Rprobe;
      // now keep the relevant stuff:
      sc_multi5x5_et[probeSc] =  sc0.energy()/(cosh(sc0.eta()));
      sc_multi5x5_eta[probeSc] = sc0.eta();
      sc_multi5x5_phi[probeSc] = sc0.phi();
    }
  delete [] sorted1;  delete [] sorted2;
  delete [] et1;     delete [] et2;
  //  edm::InputTag ctfTracksTag("generalTracks", "", InputTagEnding_);
  edm::Handle<reco::TrackCollection> ctfTracks;
  evt.getByToken(ctfTracksToken_, ctfTracks);
  const reco::TrackCollection *ctf = ctfTracks.product();
  reco::TrackCollection::const_iterator tr;
  const int ntracks =  ctf->size();
  //
  // get the beam spot for the parameter of the track
  edm::Handle<reco::BeamSpot> pBeamSpot;
  evt.getByToken(offlineBeamSpotToken_, pBeamSpot);
  const reco::BeamSpot *bspot = pBeamSpot.product();
  const math::XYZPoint bspotPosition = bspot->position();
  //
  for (int i=0; i<20; ++i) {
    ctf_track_pt[i] = -9999.;
    ctf_track_eta[i] = -9999.;
    ctf_track_phi[i] = -9999.;
    ctf_track_vx[i] = -9999.; ctf_track_vy[i]=-9999.; ctf_track_vz[i] =-9999.;
    ctf_track_tip[i] = -9999.;    ctf_track_tip_bs[i] = -9999.;
  }
  //
  std::vector<double> ETtrack;
  for (tr = ctf->begin(); tr !=  ctf->end(); ++tr) {
    reco::Track mySc = *tr;
    double scEt = mySc.pt();
    ETtrack.push_back(scEt);
  }
  int *sortedTr = new int[ntracks];
  double *etTr = new double[ntracks];
  for (int i=0; i<ntracks; ++i) {
    etTr[i] = ETtrack[i];
  }
  // array sorted now has the indices of the highest ET electrons
  TMath::Sort(ntracks, etTr, sortedTr, true);
  //
  for( int probeSc = 0; probeSc < ntracks; ++probeSc)
    {
      //std::cout<<"sorted["<< probeIt<< "]=" << sorted[probeIt] << std::endl;
      // break if you have more than the appropriate number of electrons
      if (probeSc >= 20) break;
      //
      int sc_index = sortedTr[probeSc];
      std::vector<reco::Track>::const_iterator
    Rprobe = ctf->begin() + sc_index;
      //
      reco::Track sc0 = *Rprobe;
      // now keep the relevant stuff:
      ctf_track_pt[probeSc] =  sc0.pt();
      ctf_track_eta[probeSc] = sc0.eta();
      ctf_track_phi[probeSc] = sc0.phi();
      ctf_track_vx[probeSc] = sc0.vx();
      ctf_track_vy[probeSc] = sc0.vy();
      ctf_track_vz[probeSc] = sc0.vz();
      ctf_track_tip[probeSc] = -sc0.dxy();
      ctf_track_tip_bs[probeSc] = -sc0.dxy(bspotPosition);
    }
  delete [] sortedTr; delete [] etTr;
  //
  // keep 4 of the selectedLayer1Muons for reference
  edm::Handle<pat::MuonCollection> pMuons;
  evt.getByToken(pMuonsToken_, pMuons);
  const pat::MuonCollection *pmuon = pMuons.product();
  pat::MuonCollection::const_iterator muon;
  const int nmuons =  pMuons->size();
  //
  for (int i=0; i<4; ++i) {
    muon_pt[i] = -9999.;
    muon_eta[i] = -9999.;
    muon_phi[i] = -9999.;
    muon_vx[i] = -9999.; muon_vy[i] = -9999.; muon_vz[i] = -9999.;
    muon_tip[i] = -9999.;    muon_tip_bs[i] = -9999.;
  }
  //
  std::vector<double> ETmuons;
  for (muon = pmuon->begin(); muon !=  pmuon->end(); ++muon) {
    pat::Muon mySc = *muon;
    double scEt = mySc.track()->pt();
    ETmuons.push_back(scEt);
  }
  int *sortedMu = new int[nmuons];
  double *etMu = new double[nmuons];
  for (int i=0; i<nmuons; ++i) {
    etMu[i] = ETmuons[i];
  }
  // array sorted now has the indices of the highest ET electrons
  TMath::Sort(nmuons, etMu, sortedMu, true);
  //
  for( int probeSc = 0; probeSc < nmuons; ++probeSc)
    {
      //std::cout<<"sorted["<< probeIt<< "]=" << sorted[probeIt] << std::endl;
      // break if you have more than the appropriate number of electrons
      if (probeSc >= 4) break;
      //
      int sc_index = sortedMu[probeSc];
      std::vector<pat::Muon>::const_iterator
    Rprobe = pmuon->begin() + sc_index;
      //
      pat::Muon sc0 = *Rprobe;
      // now keep the relevant stuff:
      muon_pt[probeSc] =  sc0.track()->pt();
      muon_eta[probeSc] = sc0.track()->eta();
      muon_phi[probeSc] = sc0.track()->phi();
      muon_vx[probeSc] = sc0.track()->vx();
      muon_vy[probeSc] = sc0.track()->vy();
      muon_vz[probeSc] = sc0.track()->vz();
      muon_tip[probeSc] = -sc0.track()->dxy();
      muon_tip_bs[probeSc] = -sc0.track()->dxy(bspotPosition);
    }
  delete [] sortedMu; delete [] etMu;
  //
  if (n1+n2+ntracks == 0) {
    std::cout << "Return: no sc in this event" << std::endl;
    return;
  }
  // /////////////////////////////////////////////////////////////////////////
  // electron details
  const int MAX_PROBES = 4;
  for(int i =0; i < MAX_PROBES; i++){
    probe_ele_eta_for_tree[i] = -99.0;
    probe_ele_et_for_tree[i] = -99.0;
    probe_ele_phi_for_tree[i] = -99.0;
    probe_ele_Xvertex_for_tree[i] = -99.0;
    probe_ele_Yvertex_for_tree[i] = -99.0;
    probe_ele_Zvertex_for_tree[i] = -99.0;
    probe_ele_tip[i] = -999.;

    probe_sc_eta_for_tree[i] = -99.0;
    probe_sc_et_for_tree[i] = -99.0;
    probe_sc_phi_for_tree[i] = -99.0;

    probe_charge_for_tree[i] = -99;
    probe_sc_pass_fiducial_cut[i] = 0;
    probe_classification_index_for_tree[i]=-99;
    //
    // probe isolation values ............
    probe_isolation_value[i] = 999.0;
    probe_iso_user[i] = 999.0;
    probe_ecal_isolation_value[i] = 999;
    probe_ecal_iso_user[i] = 999;
    probe_hcal_isolation_value[i] = 999;
    probe_hcal_iso_user[i] = 999;

    probe_ele_hoe[i]  = 999.;
    probe_ele_shh[i]  = 999.;
    probe_ele_sihih[i] = 999.;
    probe_ele_dhi[i]  = 999.;
    probe_ele_dfi[i]  = 999.;
    probe_ele_eop[i]  = 999.;
    probe_ele_pin[i]  = 999.;
    probe_ele_pout[i] = 999.;
    probe_ele_e5x5[i] = 999.;
    probe_ele_e2x5[i] = 999.;
    probe_ele_e1x5[i] = 999.;

    //
    //
    //for (int j=0; j<25; ++j) {
    //  probe_pass_trigger_cut[i][j]=0;
    //}
    //probe_hlt_matched_dr[i]=0;
    //probe_mc_matched[i] = 0;
    //probe_mc_matched_deta[i] = 999.;
    //probe_mc_matched_dphi[i] = 999.;
    //probe_mc_matched_denergy[i] = 999.;
    //probe_mc_matched_mother[i] = 999;
    //
    //
  }
  const pat::ElectronCollection *electrons= pElectrons.product();


  elec_number_in_event = electrons->size();
  //std::cout << "In this event " << elec_number_in_event <<
  //  " electrons were found" << std::endl;
  //  if (elec_number_in_event == 0) return;

  std::vector<pat::ElectronRef> UniqueElectrons;
  // edm::LogInfo("") << "Starting loop over electrons.";
  int index =0;
  //***********************************************************************
  // NEW METHOD by D WARDROPE implemented 26.05.08 ************************
  //************* DUPLICATE ******  REMOVAL *******************************
  // 02.06.08: due to a bug in the hybrid algorithm that affects detid ****
  //           we change detid matching to superCluster ref matching ******
  for(pat::ElectronCollection::const_iterator
    elec = electrons->begin(); elec != electrons->end();++elec) {
    const pat::ElectronRef  electronRef(pElectrons, index);
    //Remove duplicate electrons which share a supercluster
    pat::ElectronCollection::const_iterator BestDuplicate = elec;
    int index2 = 0;
    for(pat::ElectronCollection::const_iterator
      elec2 = electrons->begin();
    elec2 != electrons->end(); ++elec2)
      {
    if(elec != elec2)
      {
        if( elec->superCluster() == elec2->superCluster())
          {
        if(fabs(BestDuplicate->eSuperClusterOverP()-1.)
           >= fabs(elec2->eSuperClusterOverP()-1.))
          {
            BestDuplicate = elec2;
          }
          }
      }
    ++index2;
      }
    if(BestDuplicate == elec) UniqueElectrons.push_back(electronRef);
    ++index;
  }
  //
  // debugging: store electrons after duplicate removal
  elec_1_duplicate_removal = UniqueElectrons.size();
  //std::cout << "In this event there are " << elec_1_duplicate_removal
  //        << " electrons" << std::endl;
  //
  //
  // duplicate removal is done now:
  //           the electron collection is in UniqueElectrons
  //
  // run over probes - now probe electrons and store
  //
  // the electron collection is now
  // vector<reco::PixelMatchGsfElectronRef>   UniqueElectrons
  std::vector<double> ETs;
  std::vector<pat::ElectronRef>::const_iterator  elec;
  for (elec = UniqueElectrons.begin(); elec !=  UniqueElectrons.end(); ++elec) {
    pat::ElectronRef probeEle;
    probeEle = *elec;
    double probeEt = probeEle->caloEnergy()/(cosh(probeEle->caloPosition().eta()));
    ETs.push_back(probeEt);

  }
  int *sorted = new int[elec_1_duplicate_removal];
  double *et = new double[elec_1_duplicate_removal];
  //std::cout << "Elecs: " << elec_1_duplicate_removal << std::endl;
  for (int i=0; i<elec_1_duplicate_removal; ++i) {
    et[i] = ETs[i];
    //std::cout << "et["<< i << "]=" << et[i] << std::endl;
  }
  // array sorted now has the indices of the highest ET electrons
  TMath::Sort(elec_1_duplicate_removal, et, sorted, true);
  //
  //
  for( int probeIt = 0; probeIt < elec_1_duplicate_removal; ++probeIt)
    {
      //std::cout<<"sorted["<< probeIt<< "]=" << sorted[probeIt] << std::endl;
      // break if you have more than the appropriate number of electrons
      if (probeIt >= MAX_PROBES) break;
      //
      int elec_index = sorted[probeIt];
      std::vector<pat::ElectronRef>::const_iterator
    Rprobe = UniqueElectrons.begin() + elec_index;
      //
      pat::ElectronRef probeEle;
      probeEle = *Rprobe;
      double probeEt = probeEle->caloEnergy()/(cosh(probeEle->caloPosition().eta()));
      probe_sc_eta_for_tree[probeIt] = probeEle->caloPosition().eta();
      probe_sc_phi_for_tree[probeIt] = probeEle->caloPosition().phi();
      probe_sc_et_for_tree[probeIt] = probeEt;
      // fiducial cut ...............................
      if(fabs(probeEle->caloPosition().eta()) < BarrelMaxEta ||
     (fabs(probeEle->caloPosition().eta()) > EndcapMinEta &&
      fabs(probeEle->caloPosition().eta()) < EndcapMaxEta)){
    probe_sc_pass_fiducial_cut[probeIt] = 1;
      }
      //
      probe_charge_for_tree[probeIt] = probeEle->charge();
      probe_ele_eta_for_tree[probeIt] = probeEle->eta();
      probe_ele_et_for_tree[probeIt] = probeEle->et();
      probe_ele_phi_for_tree[probeIt] =probeEle->phi();
      probe_ele_Xvertex_for_tree[probeIt] =probeEle->vx();
      probe_ele_Yvertex_for_tree[probeIt] =probeEle->vy();
      probe_ele_Zvertex_for_tree[probeIt] =probeEle->vz();
      probe_classification_index_for_tree[probeIt] =
    probeEle->classification();
      double ProbeTIP = probeEle->gsfTrack()->d0();
      probe_ele_tip[probeIt] = ProbeTIP;
      // isolation ..................................
      // these are the default values: trk 03, ecal, hcal 04
      // I know that there is a more direct way, but in this way it
      // is clearer what you get each time :P
      probe_isolation_value[probeIt] = probeEle->dr03IsolationVariables().tkSumPt;
      probe_ecal_isolation_value[probeIt] = probeEle->dr04IsolationVariables().ecalRecHitSumEt;
      probe_hcal_isolation_value[probeIt] =
    probeEle->dr04IsolationVariables().hcalDepth1TowerSumEt +
    probeEle->dr04IsolationVariables().hcalDepth2TowerSumEt;
      // one extra isos:
      probe_iso_user[probeIt] = probeEle->dr04IsolationVariables().tkSumPt;
      probe_ecal_iso_user[probeIt] = probeEle->dr03IsolationVariables().ecalRecHitSumEt;
      probe_hcal_iso_user[probeIt] =
    probeEle->dr03IsolationVariables().hcalDepth1TowerSumEt +
    probeEle->dr03IsolationVariables().hcalDepth2TowerSumEt;
      // ele id variables
      double hOverE = probeEle->hadronicOverEm();
      double deltaPhiIn = probeEle->deltaPhiSuperClusterTrackAtVtx();
      double deltaEtaIn = probeEle->deltaEtaSuperClusterTrackAtVtx();
      double eOverP = probeEle->eSuperClusterOverP();
      double pin  = probeEle->trackMomentumAtVtx().R();
      double pout = probeEle->trackMomentumOut().R();
      double sigmaee = probeEle->scSigmaEtaEta();
      double sigma_IetaIeta = probeEle->scSigmaIEtaIEta();
      // correct if in endcaps
      if( fabs (probeEle->caloPosition().eta()) > 1.479 )  {
    sigmaee = sigmaee - 0.02*(fabs(probeEle->caloPosition().eta()) -2.3);
      }
      //
      //double e5x5, e2x5Right, e2x5Left, e2x5Top, e2x5Bottom, e1x5;
      double e5x5, e2x5, e1x5;
      e5x5 = probeEle->scE5x5();
      e1x5 = probeEle->scE1x5();
      e2x5 = probeEle->scE2x5Max();
      //
      // electron ID variables
      probe_ele_hoe[probeIt] = hOverE;
      probe_ele_shh[probeIt] = sigmaee;
      probe_ele_sihih[probeIt] = sigma_IetaIeta;
      probe_ele_dfi[probeIt] = deltaPhiIn;
      probe_ele_dhi[probeIt] = deltaEtaIn;
      probe_ele_eop[probeIt] = eOverP;
      probe_ele_pin[probeIt] = pin;
      probe_ele_pout[probeIt] = pout;
      probe_ele_e5x5[probeIt] = e5x5;
      probe_ele_e2x5[probeIt] = e2x5;
      probe_ele_e1x5[probeIt] = e1x5;

      //
      // HLT filter ------------------------------------------------------
      //
      //
      // low luminosity filters
      /*************************************************************
      for (int filterNum=0; filterNum<10; ++filterNum) {
    int trigger_int_probe = 0;

    //double hlt_matched_dr   = -1.;
    const int nF(pHLTe29->sizeFilters());
    //
    // default (tag) trigger filter
    //
    // find how many relevant
    const int iF = pHLTe29->filterIndex(HLTFilterType_[filterNum]);
    // loop over these objects to see whether they match
    const trigger::TriggerObjectCollection& TOC(pHLTe29->getObjects());
    if (nF != iF) {
      // find how many objects there are
      const trigger::Keys& KEYS(pHLTe29->filterKeys(iF));
      const int nK(KEYS.size());
      for (int iTrig = 0;iTrig <nK; ++iTrig ) {
        const trigger::TriggerObject& TO(TOC[KEYS[iTrig]]);
        //std::cout << "--> filter: "<< HLTFilterType_[filterNum]  <<" TO id: " << TO.id() << std::endl;
        // this is better to be left out: HLT matching is with an HLT object
        // and we don't care what this object is
        //if (abs(TO.id())==11 ) { // demand it to be an electron
        double dr_ele_HLT =
          reco::deltaR(probeEle->eta(), probeEle->phi(), TO.eta(), TO.phi());
        if (fabs(dr_ele_HLT) < ProbeHLTObjMaxDR) {++trigger_int_probe;
        //hlt_matched_dr = dr_ele_HLT;
        }
        //}
      }
    }
    //
    if(trigger_int_probe>0) probe_pass_trigger_cut[probeIt][filterNum] = 1;
    //probe_hlt_matched_dr[probeIt] = hlt_matched_dr;
      }
      // high lumi filters
      for (int filterNum=10; filterNum<25; ++filterNum) {
        int trigger_int_probe = 0;

        //double hlt_matched_dr   = -1.;
        const int nF(pHLTe31->sizeFilters());
        //
        // default (tag) trigger filter
        //
        // find how many relevant
        const int iF = pHLTe31->filterIndex(HLTFilterType_[filterNum]);
        // loop over these objects to see whether they match
        const trigger::TriggerObjectCollection& TOC(pHLTe31->getObjects());
    if (nF != iF) {
      // find how many objects there are
      const trigger::Keys& KEYS(pHLTe31->filterKeys(iF));
      const int nK(KEYS.size());
      for (int iTrig = 0;iTrig <nK; ++iTrig ) {
        const trigger::TriggerObject& TO(TOC[KEYS[iTrig]]);
        //if (abs(TO.id())==11 ) { // demand it to be an electron
        double dr_ele_HLT =
          reco::deltaR(probeEle->eta(), probeEle->phi(), TO.eta(), TO.phi());
        if (fabs(dr_ele_HLT) < ProbeHLTObjMaxDR) {++trigger_int_probe;
        //hlt_matched_dr = dr_ele_HLT;
        }
      }
    }

    //
    if(trigger_int_probe>0) probe_pass_trigger_cut[probeIt][filterNum] = 1;
    //probe_hlt_matched_dr[probeIt] = hlt_matched_dr;
      }
      ******************************************/
      // ------------------------------------------------------------------
      //
      // MC Matching ......................................................
      // check whether these electrons are matched to a MC electron
      /*
      int mc_index = 0;
      int matched = 0; int mother_id = 999;
      double deta_matched = 999.;      double dphi_matched = 999.;
      double denergy_matched = 999.;
      for(reco::GenParticleCollection::const_iterator   McParticle =
        McCand->begin(); McParticle != McCand->end();  ++McParticle)
    {
      // check only for electrons
      if(abs(McParticle->pdgId())==11 && McParticle->status()==1) {
        mc_index++;
        // check whether it matches a gsf electron
        double deta = McParticle->eta() - probeEle->eta();
        double dphi = McParticle->phi() - probeEle->phi();
        if ( fabs(deta) < MCMatch_Deta_  && fabs(dphi) < MCMatch_Dphi_){
          ++matched;
          deta_matched = deta; dphi_matched = dphi;
          denergy_matched = McParticle->energy() - probeEle->caloEnergy();
          // find the mother of the MC electron
          const reco::Candidate *mum;
          bool mother_finder = true;
          if (abs(McParticle->mother()->pdgId()) != 11)
        mum = McParticle->mother();
          else if (abs(McParticle->mother()->mother()->pdgId())!= 11)
        mum = McParticle->mother()->mother();
          else {
        edm::LogInfo("info") << "Going too far to find the mum";
        mother_finder = false;
          }
          if (mother_finder) {
        mother_id = mum->pdgId();
          }
        }
      }
    }
      probe_mc_matched[probeIt] = matched;
      probe_mc_matched_deta[probeIt] = deta_matched;
      probe_mc_matched_dphi[probeIt] = dphi_matched;
      probe_mc_matched_denergy[probeIt] = denergy_matched;
      probe_mc_matched_mother[probeIt] = mother_id;
      */
    }

  probe_tree->Fill();
  ++ tree_fills_;
  delete []  sorted;
  delete []  et;
}

void GenPurposeSkimmerData::beginJob ( void  )

privatevirtual

Reimplemented from edm::EDAnalyzer.

Definition at line 897 of file GenPurposeSkimmerData.cc.

References ctf_track_eta, ctf_track_phi, ctf_track_pt, ctf_track_tip, ctf_track_tip_bs, ctf_track_vx, ctf_track_vy, ctf_track_vz, elec_1_duplicate_removal, event_mcMET, event_mcMET_phi, event_MET, event_MET_phi, event_pfMET, event_pfMET_phi, event_t1MET, event_t1MET_phi, event_tcMET, event_tcMET_phi, histofile, muon_eta, muon_phi, muon_pt, muon_tip, muon_tip_bs, muon_vx, muon_vy, muon_vz, outputFile_, probe_charge_for_tree, probe_ecal_iso_user, probe_ecal_isolation_value, probe_ele_dfi, probe_ele_dhi, probe_ele_eop, probe_ele_hoe, probe_ele_pin, probe_ele_pout, probe_ele_sihih, probe_ele_tip, probe_ele_Xvertex_for_tree, probe_ele_Yvertex_for_tree, probe_ele_Zvertex_for_tree, probe_hcal_iso_user, probe_hcal_isolation_value, probe_iso_user, probe_isolation_value, probe_sc_et_for_tree, probe_sc_eta_for_tree, probe_sc_phi_for_tree, probe_tree, sc_hybrid_et, sc_hybrid_eta, sc_hybrid_phi, sc_multi5x5_et, sc_multi5x5_eta, sc_multi5x5_phi, and tree_fills_.

{
  //std::cout << "In beginJob()" << std::endl;
  TString filename_histo = outputFile_;
  histofile = new TFile(filename_histo,"RECREATE");
  tree_fills_ = 0;

  probe_tree =  new TTree("probe_tree","Tree to store probe variables");

  //probe_tree->Branch("probe_ele_eta",probe_ele_eta_for_tree,"probe_ele_eta[4]/D");
  //probe_tree->Branch("probe_ele_phi",probe_ele_phi_for_tree,"probe_ele_phi[4]/D");
  //probe_tree->Branch("probe_ele_et",probe_ele_et_for_tree,"probe_ele_et[4]/D");
  probe_tree->Branch("probe_ele_tip",probe_ele_tip,"probe_ele_tip[4]/D");
  probe_tree->Branch("probe_ele_vertex_x",probe_ele_Xvertex_for_tree,
             "probe_ele_vertex_x[4]/D");
  probe_tree->Branch("probe_ele_vertex_y",probe_ele_Yvertex_for_tree,
             "probe_ele_vertex_y[4]/D");
  probe_tree->Branch("probe_ele_vertex_z",probe_ele_Zvertex_for_tree,
             "probe_ele_vertex_z[4]/D");
  probe_tree->Branch("probe_sc_eta",probe_sc_eta_for_tree,"probe_sc_eta[4]/D");
  probe_tree->Branch("probe_sc_phi",probe_sc_phi_for_tree,"probe_sc_phi[4]/D");
  probe_tree->Branch("probe_sc_et",probe_sc_et_for_tree,"probe_sc_et[4]/D");

  // trigger related variables
  //probe_tree->Branch("probe_trigger_cut",probe_pass_trigger_cut,"probe_trigger_cut[4][25]/I");
  //probe_tree->Branch("probe_hlt_matched_dr", probe_hlt_matched_dr,"probe_hlt_matched_dr[4]/D");
  // mc matching to electrons
  //  probe_tree->Branch("probe_mc_matched",probe_mc_matched,"probe_mc_matched[4]/I");
  //probe_tree->Branch("probe_mc_matched_deta",probe_mc_matched_deta,
  //         "probe_mc_matched_deta[4]/D");
  //probe_tree->Branch("probe_mc_matched_dphi",probe_mc_matched_dphi,
  //             "probe_mc_matched_dphi[4]/D");
  //probe_tree->Branch("probe_mc_matched_denergy",probe_mc_matched_denergy,
  //             "probe_mc_matched_denergy[4]/D");
  //probe_tree->Branch("probe_mc_matched_mother",probe_mc_matched_mother,
  //             "probe_mc_matched_mother[4]/I");
  //
  probe_tree->Branch("probe_charge",probe_charge_for_tree,"probe_charge[4]/I");
  //probe_tree->Branch("probe_sc_fiducial_cut",probe_sc_pass_fiducial_cut,
  //             "probe_sc_fiducial_cut[4]/I");



  //probe_tree->Branch("probe_classification",
  //        probe_classification_index_for_tree,"probe_classification[4]/I");
  //
  // Isolation related variables ........................................
  //
  probe_tree->Branch("probe_isolation_value",probe_isolation_value, "probe_isolation_value[4]/D");
  probe_tree->Branch("probe_ecal_isolation_value",probe_ecal_isolation_value, "probe_ecal_isolation_value[4]/D");
  probe_tree->Branch("probe_hcal_isolation_value",probe_hcal_isolation_value,"probe_hcal_isolation_value[4]/D");
  //
  probe_tree->Branch("probe_iso_user",     probe_iso_user,      "probe_iso_user[4]/D");
  probe_tree->Branch("probe_ecal_iso_user",probe_ecal_iso_user, "probe_ecal_iso_user[4]/D");
  probe_tree->Branch("probe_hcal_iso_user",probe_hcal_iso_user, "probe_hcal_iso_user[4]/D");

  //......................................................................
  // Electron ID Related variables .......................................
  probe_tree->Branch("probe_ele_hoe",probe_ele_hoe, "probe_ele_hoe[4]/D");
  //probe_tree->Branch("probe_ele_shh",probe_ele_shh, "probe_ele_shh[4]/D");
  probe_tree->Branch("probe_ele_sihih",probe_ele_sihih,"probe_ele_sihih[4]/D");
  probe_tree->Branch("probe_ele_dfi",probe_ele_dfi, "probe_ele_dfi[4]/D");
  probe_tree->Branch("probe_ele_dhi",probe_ele_dhi, "probe_ele_dhi[4]/D");
  probe_tree->Branch("probe_ele_eop",probe_ele_eop, "probe_ele_eop[4]/D");
  probe_tree->Branch("probe_ele_pin",probe_ele_pin, "probe_ele_pin[4]/D");
  probe_tree->Branch("probe_ele_pout",probe_ele_pout, "probe_ele_pout[4]/D");
  // probe_tree->Branch("probe_ele_e5x5",probe_ele_e5x5, "probe_ele_e5x5[4]/D");
  //probe_tree->Branch("probe_ele_e2x5",probe_ele_e2x5, "probe_ele_e2x5[4]/D");
  //probe_tree->Branch("probe_ele_e1x5",probe_ele_e1x5, "probe_ele_e1x5[4]/D");

  //.......................................................................
  //
  // each entry for each trigger path
  //probe_tree->Branch("event_HLTPath",event_HLTPath,"event_HLTPath[25]/I");
  //probe_tree->Branch("numberOfHLTFilterObjects", numberOfHLTFilterObjects,
  //             "numberOfHLTFilterObjects[25]/I");
  //
  // debugging info:
  //probe_tree->Branch("elec_number_in_event",&elec_number_in_event,"elec_number_in_event/I");
  probe_tree->Branch("elec_1_duplicate_removal",&elec_1_duplicate_removal,"elec_1_duplicate_removal/I");
  //

  // Missing ET in the event
  probe_tree->Branch("event_MET",&event_MET,"event_MET/D");
  probe_tree->Branch("event_MET_phi",&event_MET_phi,"event_MET_phi/D");
  //  probe_tree->Branch("event_MET_sig",&event_MET_sig,"event_MET_sig/D");
  probe_tree->Branch("event_mcMET",&event_mcMET,"event_mcMET/D");
  probe_tree->Branch("event_mcMET_phi",&event_mcMET_phi,"event_mcMET_phi/D");
  //
  probe_tree->Branch("event_tcMET",&event_tcMET,"event_tcMET/D");
  probe_tree->Branch("event_tcMET_phi",&event_tcMET_phi,"event_tcMET_phi/D");
  //  probe_tree->Branch("event_tcMET_sig",&event_tcMET_sig,"event_tcMET_sig/D");

  probe_tree->Branch("event_pfMET",&event_pfMET,"event_pfMET/D");
  probe_tree->Branch("event_pfMET_phi",&event_pfMET_phi,"event_pfMET_phi/D");
  //  probe_tree->Branch("event_pfMET_sig",&event_pfMET_sig,"event_pfMET_sig/D");

  //  probe_tree->Branch("event_genMET",&event_genMET,"event_genMET/D");
  //  probe_tree->Branch("event_genMET_phi",&event_genMET_phi, "event_genMET_phi/D");
  //  probe_tree->Branch("event_genMET_sig",&event_genMET_sig, "event_genMET_sig/D");
  //..... type 1 corrected MET
  probe_tree->Branch("event_t1MET", &event_t1MET, "event_t1MET/D");
  probe_tree->Branch("event_t1MET_phi", &event_t1MET_phi,"event_t1MET_phi/D");
  //probe_tree->Branch("event_t1MET_sig",&event_t1MET_sig,"event_t1MET_sig/D");

  //
  // some sc related variables
  probe_tree->Branch("sc_hybrid_et", sc_hybrid_et, "sc_hybrid_et[5]/D");
  probe_tree->Branch("sc_hybrid_eta", sc_hybrid_eta, "sc_hybrid_eta[5]/D");
  probe_tree->Branch("sc_hybrid_phi", sc_hybrid_phi, "sc_hybrid_phi[5]/D");
  //
  probe_tree->Branch("sc_multi5x5_et",sc_multi5x5_et, "sc_multi5x5_et[5]/D");
  probe_tree->Branch("sc_multi5x5_eta",sc_multi5x5_eta,"sc_multi5x5_eta[5]/D");
  probe_tree->Branch("sc_multi5x5_phi",sc_multi5x5_phi,"sc_multi5x5_phi[5]/D");
  // /////////////////////////////////////////////////////////////////////////
  // general tracks in the event: keep 20 tracks
  probe_tree->Branch("ctf_track_pt",  ctf_track_pt,  "ctf_track_pt[20]/D");
  probe_tree->Branch("ctf_track_eta", ctf_track_eta, "ctf_track_eta[20]/D");
  probe_tree->Branch("ctf_track_phi", ctf_track_phi, "ctf_track_phi[20]/D");
  probe_tree->Branch("ctf_track_vx", ctf_track_vx, "ctf_track_vx[20]/D");
  probe_tree->Branch("ctf_track_vy", ctf_track_vy, "ctf_track_vy[20]/D");
  probe_tree->Branch("ctf_track_vz", ctf_track_vz, "ctf_track_vz[20]/D");
  probe_tree->Branch("ctf_track_tip", ctf_track_tip, "ctf_track_tip[20]/D");
  probe_tree->Branch("ctf_track_tip_bs", ctf_track_tip_bs,
             "ctf_track_tip_bs[20]/D");
  //
  probe_tree->Branch("muon_pt",  muon_pt,  "muon_pt[4]/D");
  probe_tree->Branch("muon_eta", muon_eta, "muon_eta[4]/D");
  probe_tree->Branch("muon_phi", muon_phi, "muon_phi[4]/D");
  probe_tree->Branch("muon_vx", muon_vx, "muon_vx[4]/D");
  probe_tree->Branch("muon_vy", muon_vy, "muon_vy[4]/D");
  probe_tree->Branch("muon_vz", muon_vz, "muon_vz[4]/D");
  probe_tree->Branch("muon_tip", muon_tip, "muon_tip[4]/D");
  probe_tree->Branch("muon_tip_bs", muon_tip_bs, "muon_tip_bs[4]/D");

}

void GenPurposeSkimmerData::endJob ( void  )

privatevirtual

Reimplemented from edm::EDAnalyzer.

Definition at line 1036 of file GenPurposeSkimmerData.cc.

References gather_cfg::cout, histofile, and tree_fills_.

                              {
  //std::cout << "In endJob()" << std::endl;
  if (tree_fills_ == 0) {
    std::cout << "Empty tree: no output..." << std::endl;
    return;
  }
  //probe_tree->Print();
  histofile->Write();
  histofile->Close();

}

Member Data Documentation

double GenPurposeSkimmerData::BarrelMaxEta

private

Definition at line 188 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

edm::EDGetTokenT<reco::SuperClusterCollection> GenPurposeSkimmerData::corHybridscToken_

private

Definition at line 109 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

double GenPurposeSkimmerData::ctf_track_eta[20]

private

Definition at line 221 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::ctf_track_phi[20]

private

Definition at line 221 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::ctf_track_pt[20]

private

Definition at line 221 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::ctf_track_tip[20]

private

Definition at line 223 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::ctf_track_tip_bs[20]

private

Definition at line 223 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::ctf_track_vx[20]

private

Definition at line 222 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::ctf_track_vy[20]

private

Definition at line 222 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::ctf_track_vz[20]

private

Definition at line 222 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

edm::EDGetTokenT<reco::TrackCollection> GenPurposeSkimmerData::ctfTracksToken_

private

Definition at line 108 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

int GenPurposeSkimmerData::elec_1_duplicate_removal

private

Definition at line 200 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

int GenPurposeSkimmerData::elec_number_in_event

private

Definition at line 199 of file GenPurposeSkimmerData.h.

Referenced by analyze().

edm::EDGetTokenT<pat::ElectronCollection> GenPurposeSkimmerData::ElectronCollectionToken_

private

Definition at line 87 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

double GenPurposeSkimmerData::EndcapMaxEta

private

Definition at line 190 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

double GenPurposeSkimmerData::EndcapMinEta

private

Definition at line 189 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

int GenPurposeSkimmerData::event_HLTPath[25]

private

Definition at line 186 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::event_mcMET

private

Definition at line 214 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::event_mcMET_phi

private

Definition at line 214 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::event_mcMET_sig

private

Definition at line 214 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::event_MET

private

Definition at line 202 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::event_MET_phi

private

Definition at line 204 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::event_MET_sig

private

Definition at line 202 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::event_pfMET

private

Definition at line 206 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::event_pfMET_phi

private

Definition at line 208 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::event_pfMET_sig

private

Definition at line 206 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::event_t1MET

private

Definition at line 213 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::event_t1MET_phi

private

Definition at line 213 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::event_t1MET_sig

private

Definition at line 213 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::event_tcMET

private

Definition at line 205 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::event_tcMET_phi

private

Definition at line 205 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::event_tcMET_sig

private

Definition at line 205 of file GenPurposeSkimmerData.h.

Referenced by analyze().

edm::EDGetTokenT<reco::GenMETCollection> GenPurposeSkimmerData::genMetCollectionToken_

private

Definition at line 96 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::GsfTrackMinInnerPt

private

Definition at line 197 of file GenPurposeSkimmerData.h.

TFile* GenPurposeSkimmerData::histofile

private

Definition at line 115 of file GenPurposeSkimmerData.h.

Referenced by beginJob(), and endJob().

edm::InputTag GenPurposeSkimmerData::HLTCollectionE29_

private

Definition at line 98 of file GenPurposeSkimmerData.h.

Referenced by GenPurposeSkimmerData().

edm::EDGetTokenT<trigger::TriggerEvent> GenPurposeSkimmerData::HLTCollectionE29Token_

private

Definition at line 99 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

edm::InputTag GenPurposeSkimmerData::HLTCollectionE31_

private

Definition at line 100 of file GenPurposeSkimmerData.h.

Referenced by GenPurposeSkimmerData().

edm::EDGetTokenT<trigger::TriggerEvent> GenPurposeSkimmerData::HLTCollectionE31Token_

private

Definition at line 101 of file GenPurposeSkimmerData.h.

Referenced by GenPurposeSkimmerData().

edm::InputTag GenPurposeSkimmerData::HLTFilterType_[25]

private

Definition at line 106 of file GenPurposeSkimmerData.h.

edm::InputTag GenPurposeSkimmerData::HLTTriggerResultsE29_

private

Definition at line 102 of file GenPurposeSkimmerData.h.

Referenced by GenPurposeSkimmerData().

edm::EDGetTokenT<edm::TriggerResults> GenPurposeSkimmerData::HLTTriggerResultsE29Token_

private

Definition at line 103 of file GenPurposeSkimmerData.h.

Referenced by GenPurposeSkimmerData().

edm::InputTag GenPurposeSkimmerData::HLTTriggerResultsE31_

private

Definition at line 104 of file GenPurposeSkimmerData.h.

Referenced by GenPurposeSkimmerData().

edm::EDGetTokenT<edm::TriggerResults> GenPurposeSkimmerData::HLTTriggerResultsE31Token_

private

Definition at line 105 of file GenPurposeSkimmerData.h.

Referenced by GenPurposeSkimmerData().

edm::InputTag GenPurposeSkimmerData::MCCollection_

private

Definition at line 88 of file GenPurposeSkimmerData.h.

edm::EDGetTokenT<reco::GenParticleCollection> GenPurposeSkimmerData::MCCollectionToken_

private

Definition at line 89 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::MCMatch_Deta_

private

Definition at line 175 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::MCMatch_Dphi_

private

Definition at line 176 of file GenPurposeSkimmerData.h.

edm::EDGetTokenT<pat::METCollection> GenPurposeSkimmerData::mcMetCollectionToken_

private

Definition at line 92 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

edm::InputTag GenPurposeSkimmerData::MetCollectionTag_

private

Definition at line 90 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

edm::EDGetTokenT<reco::CaloMETCollection> GenPurposeSkimmerData::MetCollectionToken_

private

Definition at line 91 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

edm::EDGetTokenT<reco::SuperClusterCollection> GenPurposeSkimmerData::multi5x5scToken_

private

Definition at line 110 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

double GenPurposeSkimmerData::muon_eta[4]

private

Definition at line 225 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::muon_phi[4]

private

Definition at line 225 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::muon_pt[4]

private

Definition at line 225 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::muon_tip[4]

private

Definition at line 227 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::muon_tip_bs[4]

private

Definition at line 227 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::muon_vx[4]

private

Definition at line 226 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::muon_vy[4]

private

Definition at line 226 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::muon_vz[4]

private

Definition at line 226 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

int GenPurposeSkimmerData::numberOfHLTFilterObjects[25]

private

Definition at line 184 of file GenPurposeSkimmerData.h.

edm::EDGetTokenT<reco::BeamSpot> GenPurposeSkimmerData::offlineBeamSpotToken_

private

Definition at line 111 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

std::string GenPurposeSkimmerData::outputFile_

private

Definition at line 84 of file GenPurposeSkimmerData.h.

Referenced by beginJob(), and GenPurposeSkimmerData().

edm::EDGetTokenT<reco::PFMETCollection> GenPurposeSkimmerData::pfMetCollectionToken_

private

Definition at line 94 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

edm::EDGetTokenT<pat::MuonCollection> GenPurposeSkimmerData::pMuonsToken_

private

Definition at line 112 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

int GenPurposeSkimmerData::probe_charge_for_tree[4]

private

Definition at line 134 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

int GenPurposeSkimmerData::probe_classification_index_for_tree[4]

private

Definition at line 152 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::probe_ecal_iso_user[4]

private

Definition at line 147 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_ecal_isolation_value[4]

private

Definition at line 146 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_ele_dfi[4]

private

Definition at line 163 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_ele_dhi[4]

private

Definition at line 162 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_ele_e1x5[4]

private

Definition at line 169 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::probe_ele_e2x5[4]

private

Definition at line 168 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::probe_ele_e5x5[4]

private

Definition at line 167 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::probe_ele_eop[4]

private

Definition at line 164 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_ele_et_for_tree[4]

private

Definition at line 129 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::probe_ele_eta_for_tree[4]

private

Definition at line 127 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::probe_ele_hoe[4]

private

Definition at line 159 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

int GenPurposeSkimmerData::probe_ele_pass_et_cut[4]

private

Definition at line 139 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_ele_pass_fiducial_cut[4]

private

Definition at line 138 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::probe_ele_phi_for_tree[4]

private

Definition at line 128 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::probe_ele_pin[4]

private

Definition at line 165 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_ele_pout[4]

private

Definition at line 166 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_ele_shh[4]

private

Definition at line 160 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::probe_ele_sihih[4]

private

Definition at line 161 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_ele_tip[4]

private

Definition at line 133 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_ele_Xvertex_for_tree[4]

private

Definition at line 130 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_ele_Yvertex_for_tree[4]

private

Definition at line 131 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_ele_Zvertex_for_tree[4]

private

Definition at line 132 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_hcal_iso_user[4]

private

Definition at line 150 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_hcal_isolation_value[4]

private

Definition at line 149 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_hlt_matched_dr[4]

private

Definition at line 173 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_index_for_tree[4]

private

Definition at line 135 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::probe_iso_user[4]

private

Definition at line 144 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_isolation_value[4]

private

Definition at line 143 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

int GenPurposeSkimmerData::probe_mc_matched[4]

private

Definition at line 177 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::probe_mc_matched_denergy[4]

private

Definition at line 180 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::probe_mc_matched_deta[4]

private

Definition at line 178 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::probe_mc_matched_dphi[4]

private

Definition at line 179 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_mc_matched_mother[4]

private

Definition at line 181 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_pass_id_loose[4]

private

Definition at line 157 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_pass_id_robust_loose[4]

private

Definition at line 155 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_pass_id_robust_tight[4]

private

Definition at line 156 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_pass_id_tight[4]

private

Definition at line 158 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_pass_iso_cut[4]

private

Definition at line 141 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_pass_recoEle_cut[4]

private

Definition at line 140 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_pass_tip_cut[4]

private

Definition at line 153 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_pass_trigger_cut[4][25]

private

Definition at line 172 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::probe_sc_et_for_tree[4]

private

Definition at line 122 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::probe_sc_eta_for_tree[4]

private

Definition at line 120 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

int GenPurposeSkimmerData::probe_sc_pass_et_cut[4]

private

Definition at line 124 of file GenPurposeSkimmerData.h.

int GenPurposeSkimmerData::probe_sc_pass_fiducial_cut[4]

private

Definition at line 123 of file GenPurposeSkimmerData.h.

Referenced by analyze().

double GenPurposeSkimmerData::probe_sc_phi_for_tree[4]

private

Definition at line 121 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

TTree* GenPurposeSkimmerData::probe_tree

private

Definition at line 114 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::ProbeHLTObjMaxDR

private

Definition at line 195 of file GenPurposeSkimmerData.h.

Referenced by GenPurposeSkimmerData().

double GenPurposeSkimmerData::ProbeRecoEleSCMaxDE

private

Definition at line 193 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::ProbeSCMinEt

private

Definition at line 192 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::RecoEleSeedBCMaxDE

private

Definition at line 196 of file GenPurposeSkimmerData.h.

double GenPurposeSkimmerData::sc_hybrid_et[5]

private

Definition at line 218 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::sc_hybrid_eta[5]

private

Definition at line 218 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::sc_hybrid_phi[5]

private

Definition at line 218 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::sc_multi5x5_et[5]

private

Definition at line 219 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::sc_multi5x5_eta[5]

private

Definition at line 219 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

double GenPurposeSkimmerData::sc_multi5x5_phi[5]

private

Definition at line 219 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and beginJob().

edm::EDGetTokenT<pat::METCollection> GenPurposeSkimmerData::t1MetCollectionToken_

private

Definition at line 95 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

edm::EDGetTokenT<reco::METCollection> GenPurposeSkimmerData::tcMetCollectionToken_

private

Definition at line 93 of file GenPurposeSkimmerData.h.

Referenced by analyze(), and GenPurposeSkimmerData().

int GenPurposeSkimmerData::tree_fills_

private

Definition at line 85 of file GenPurposeSkimmerData.h.

Referenced by analyze(), beginJob(), and endJob().