ElectronAnalyzer.cc

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#include "DQMOffline/EGamma/plugins/ElectronAnalyzer.h"

#include "DQMServices/Core/interface/DQMStore.h"

#include "DataFormats/GsfTrackReco/interface/GsfTrack.h"
#include "DataFormats/EgammaCandidates/interface/GsfElectron.h"
#include "DataFormats/EgammaReco/interface/BasicClusterFwd.h"
#include "DataFormats/Common/interface/Handle.h"
#include "DataFormats/BeamSpot/interface/BeamSpot.h"
#include "DataFormats/Common/interface/TriggerResults.h"

#include "FWCore/Common/interface/TriggerNames.h"
#include "FWCore/ParameterSet/interface/ParameterSet.h"
#include "FWCore/Framework/interface/Event.h"
#include "FWCore/Framework/interface/MakerMacros.h"
#include "FWCore/MessageLogger/interface/MessageLogger.h"
#include "FWCore/ServiceRegistry/interface/Service.h"

#include "CLHEP/Units/GlobalPhysicalConstants.h"
#include "TMath.h"

#include <iostream>

using namespace reco;

ElectronAnalyzer::ElectronAnalyzer(const edm::ParameterSet& conf) : ElectronDqmAnalyzerBase(conf) {
  // general, collections
  Selection_ = conf.getParameter<int>("Selection");
  electronCollection_ = consumes<GsfElectronCollection>(conf.getParameter<edm::InputTag>("ElectronCollection"));
  matchingObjectCollection_ =
      consumes<SuperClusterCollection>(conf.getParameter<edm::InputTag>("MatchingObjectCollection"));
  trackCollection_ = consumes<TrackCollection>(conf.getParameter<edm::InputTag>("TrackCollection"));
  vertexCollection_ = consumes<VertexCollection>(conf.getParameter<edm::InputTag>("VertexCollection"));
  gsftrackCollection_ = consumes<GsfTrackCollection>(conf.getParameter<edm::InputTag>("GsfTrackCollection"));
  beamSpotTag_ = consumes<BeamSpot>(conf.getParameter<edm::InputTag>("BeamSpot"));
  readAOD_ = conf.getParameter<bool>("ReadAOD");

  // matching
  matchingCondition_ = conf.getParameter<std::string>("MatchingCondition");
  assert(matchingCondition_ == "Cone");
  maxPtMatchingObject_ = conf.getParameter<double>("MaxPtMatchingObject");
  maxAbsEtaMatchingObject_ = conf.getParameter<double>("MaxAbsEtaMatchingObject");
  deltaR_ = conf.getParameter<double>("DeltaR");

  // electron selection
  minEt_ = conf.getParameter<double>("MinEt");
  minPt_ = conf.getParameter<double>("MinPt");
  maxAbsEta_ = conf.getParameter<double>("MaxAbsEta");
  isEB_ = conf.getParameter<bool>("SelectEb");
  isEE_ = conf.getParameter<bool>("SelectEe");
  isNotEBEEGap_ = conf.getParameter<bool>("SelectNotEbEeGap");
  isEcalDriven_ = conf.getParameter<bool>("SelectEcalDriven");
  isTrackerDriven_ = conf.getParameter<bool>("SelectTrackerDriven");
  eOverPMinBarrel_ = conf.getParameter<double>("MinEopBarrel");
  eOverPMaxBarrel_ = conf.getParameter<double>("MaxEopBarrel");
  eOverPMinEndcaps_ = conf.getParameter<double>("MinEopEndcaps");
  eOverPMaxEndcaps_ = conf.getParameter<double>("MaxEopEndcaps");
  dEtaMinBarrel_ = conf.getParameter<double>("MinDetaBarrel");
  dEtaMaxBarrel_ = conf.getParameter<double>("MaxDetaBarrel");
  dEtaMinEndcaps_ = conf.getParameter<double>("MinDetaEndcaps");
  dEtaMaxEndcaps_ = conf.getParameter<double>("MaxDetaEndcaps");
  dPhiMinBarrel_ = conf.getParameter<double>("MinDphiBarrel");
  dPhiMaxBarrel_ = conf.getParameter<double>("MaxDphiBarrel");
  dPhiMinEndcaps_ = conf.getParameter<double>("MinDphiEndcaps");
  dPhiMaxEndcaps_ = conf.getParameter<double>("MaxDphiEndcaps");
  sigIetaIetaMinBarrel_ = conf.getParameter<double>("MinSigIetaIetaBarrel");
  sigIetaIetaMaxBarrel_ = conf.getParameter<double>("MaxSigIetaIetaBarrel");
  sigIetaIetaMinEndcaps_ = conf.getParameter<double>("MinSigIetaIetaEndcaps");
  sigIetaIetaMaxEndcaps_ = conf.getParameter<double>("MaxSigIetaIetaEndcaps");
  hadronicOverEmMaxBarrel_ = conf.getParameter<double>("MaxHoeBarrel");
  hadronicOverEmMaxEndcaps_ = conf.getParameter<double>("MaxHoeEndcaps");
  mvaMin_ = conf.getParameter<double>("MinMva");
  tipMaxBarrel_ = conf.getParameter<double>("MaxTipBarrel");
  tipMaxEndcaps_ = conf.getParameter<double>("MaxTipEndcaps");
  tkIso03Max_ = conf.getParameter<double>("MaxTkIso03");
  hcalIso03Depth1MaxBarrel_ = conf.getParameter<double>("MaxHcalIso03Depth1Barrel");
  hcalIso03Depth1MaxEndcaps_ = conf.getParameter<double>("MaxHcalIso03Depth1Endcaps");
  hcalIso03Depth2MaxEndcaps_ = conf.getParameter<double>("MaxHcalIso03Depth2Endcaps");
  ecalIso03MaxBarrel_ = conf.getParameter<double>("MaxEcalIso03Barrel");
  ecalIso03MaxEndcaps_ = conf.getParameter<double>("MaxEcalIso03Endcaps");

  // for trigger
  triggerResults_ = conf.getParameter<edm::InputTag>("TriggerResults");

  // histos limits and binning
  //  edm::ParameterSet histosSet = conf.getParameter<edm::ParameterSet>("histosCfg") ;

  nbineta = conf.getParameter<int>("NbinEta");
  nbineta2D = conf.getParameter<int>("NbinEta2D");
  etamin = conf.getParameter<double>("EtaMin");
  etamax = conf.getParameter<double>("EtaMax");
  //
  nbinphi = conf.getParameter<int>("NbinPhi");
  nbinphi2D = conf.getParameter<int>("NbinPhi2D");
  phimin = conf.getParameter<double>("PhiMin");
  phimax = conf.getParameter<double>("PhiMax");
  //
  nbinpt = conf.getParameter<int>("NbinPt");
  nbinpteff = conf.getParameter<int>("NbinPtEff");
  nbinpt2D = conf.getParameter<int>("NbinPt2D");
  ptmax = conf.getParameter<double>("PtMax");
  //
  nbinp = conf.getParameter<int>("NbinP");
  nbinp2D = conf.getParameter<int>("NbinP2D");
  pmax = conf.getParameter<double>("PMax");
  //
  nbineop = conf.getParameter<int>("NbinEop");
  nbineop2D = conf.getParameter<int>("NbinEop2D");
  eopmax = conf.getParameter<double>("EopMax");
  eopmaxsht = conf.getParameter<double>("EopMaxSht");
  //
  nbindeta = conf.getParameter<int>("NbinDeta");
  detamin = conf.getParameter<double>("DetaMin");
  detamax = conf.getParameter<double>("DetaMax");
  //
  nbindphi = conf.getParameter<int>("NbinDphi");
  dphimin = conf.getParameter<double>("DphiMin");
  dphimax = conf.getParameter<double>("DphiMax");
  //
  nbindetamatch = conf.getParameter<int>("NbinDetaMatch");
  nbindetamatch2D = conf.getParameter<int>("NbinDetaMatch2D");
  detamatchmin = conf.getParameter<double>("DetaMatchMin");
  detamatchmax = conf.getParameter<double>("DetaMatchMax");
  //
  nbindphimatch = conf.getParameter<int>("NbinDphiMatch");
  nbindphimatch2D = conf.getParameter<int>("NbinDphiMatch2D");
  dphimatchmin = conf.getParameter<double>("DphiMatchMin");
  dphimatchmax = conf.getParameter<double>("DphiMatchMax");
  //
  nbinfhits = conf.getParameter<int>("NbinFhits");
  fhitsmax = conf.getParameter<double>("FhitsMax");
  //
  nbinlhits = conf.getParameter<int>("NbinLhits");
  lhitsmax = conf.getParameter<double>("LhitsMax");
  //
  nbinxyz = conf.getParameter<int>("NbinXyz");
  nbinxyz2D = conf.getParameter<int>("NbinXyz2D");
  //
  nbinpoptrue = conf.getParameter<int>("NbinPopTrue");
  poptruemin = conf.getParameter<double>("PopTrueMin");
  poptruemax = conf.getParameter<double>("PopTrueMax");
  //
  nbinmee = conf.getParameter<int>("NbinMee");
  meemin = conf.getParameter<double>("MeeMin");
  meemax = conf.getParameter<double>("MeeMax");
  //
  nbinhoe = conf.getParameter<int>("NbinHoe");
  hoemin = conf.getParameter<double>("HoeMin");
  hoemax = conf.getParameter<double>("HoeMax");

  //  set_EfficiencyFlag=histosSet.getParameter<bool>("EfficiencyFlag");
  //  set_StatOverflowFlag=histosSet.getParameter<bool>("StatOverflowFlag");
}

ElectronAnalyzer::~ElectronAnalyzer() {}

void ElectronAnalyzer::bookHistograms(DQMStore::IBooker& iBooker, edm::Run const&, edm::EventSetup const&) {
  iBooker.setCurrentFolder(outputInternalPath_);

  nEvents_ = 0;

  // basic quantities
  h1_vertexPt_barrel = bookH1(
      iBooker, "vertexPt_barrel", "ele transverse momentum in barrel", nbinpt, 0., ptmax, "p_{T vertex} (GeV/c)");
  h1_vertexPt_endcaps = bookH1(
      iBooker, "vertexPt_endcaps", "ele transverse momentum in endcaps", nbinpt, 0., ptmax, "p_{T vertex} (GeV/c)");
  h1_vertexEta = bookH1(iBooker, "vertexEta", "ele momentum #eta", nbineta, etamin, etamax, "#eta");
  h2_vertexEtaVsPhi = bookH2(iBooker,
                             "vertexEtaVsPhi",
                             "ele momentum #eta vs #phi",
                             nbineta2D,
                             etamin,
                             etamax,
                             nbinphi2D,
                             phimin,
                             phimax,
                             "#eta",
                             "#phi (rad)");
  h2_vertexXvsY = bookH2(
      iBooker, "vertexXvsY", "ele vertex x vs y", nbinxyz2D, -0.1, 0.1, nbinxyz2D, -0.1, 0.1, "x (cm)", "y (cm)");
  h1_vertexZ = bookH1(iBooker, "vertexZ", "ele vertex z", nbinxyz, -25, 25, "z (cm)");

  // super-clusters
  h1_sclEt = bookH1(iBooker, "sclEt", "ele supercluster transverse energy", nbinpt, 0., ptmax, "E_{T} (GeV)");

  // electron track
  h1_chi2 = bookH1(iBooker, "chi2", "ele track #chi^{2}", 100, 0., 15., "#Chi^{2}");
  py_chi2VsEta = bookP1(
      iBooker, "chi2VsEta", "ele track #chi^{2} vs #eta", nbineta2D, etamin, etamax, 0., 15., "#eta", "<#chi^{2}>");
  py_chi2VsPhi = bookP1(iBooker,
                        "chi2VsPhi",
                        "ele track #chi^{2} vs #phi",
                        nbinphi2D,
                        phimin,
                        phimax,
                        0.,
                        15.,
                        "#phi (rad)",
                        "<#chi^{2}>");
  h1_foundHits = bookH1(iBooker, "foundHits", "ele track # found hits", nbinfhits, 0., fhitsmax, "N_{hits}");
  py_foundHitsVsEta = bookP1(iBooker,
                             "foundHitsVsEta",
                             "ele track # found hits vs #eta",
                             nbineta2D,
                             etamin,
                             etamax,
                             0.,
                             fhitsmax,
                             "#eta",
                             "<# hits>");
  py_foundHitsVsPhi = bookP1(iBooker,
                             "foundHitsVsPhi",
                             "ele track # found hits vs #phi",
                             nbinphi2D,
                             phimin,
                             phimax,
                             0.,
                             fhitsmax,
                             "#phi (rad)",
                             "<# hits>");
  h1_lostHits = bookH1(iBooker, "lostHits", "ele track # lost hits", 5, 0., 5., "N_{lost hits}");
  py_lostHitsVsEta = bookP1(iBooker,
                            "lostHitsVsEta",
                            "ele track # lost hits vs #eta",
                            nbineta2D,
                            etamin,
                            etamax,
                            0.,
                            lhitsmax,
                            "#eta",
                            "<# hits>");
  py_lostHitsVsPhi = bookP1(iBooker,
                            "lostHitsVsPhi",
                            "ele track # lost hits vs #eta",
                            nbinphi2D,
                            phimin,
                            phimax,
                            0.,
                            lhitsmax,
                            "#phi (rad)",
                            "<# hits>");

  // electron matching and ID
  h1_Eop_barrel = bookH1(iBooker, "Eop_barrel", "ele E/P_{vertex} in barrel", nbineop, 0., eopmax, "E/P_{vertex}");
  h1_Eop_endcaps = bookH1(iBooker, "Eop_endcaps", "ele E/P_{vertex} in endcaps", nbineop, 0., eopmax, "E/P_{vertex}");
  py_EopVsPhi = bookP1(iBooker,
                       "EopVsPhi",
                       "ele E/P_{vertex} vs #phi",
                       nbinphi2D,
                       phimin,
                       phimax,
                       0.,
                       eopmax,
                       "#phi (rad)",
                       "<E/P_{vertex}>");
  h1_EeleOPout_barrel =
      bookH1(iBooker, "EeleOPout_barrel", "ele E_{ele}/P_{out} in barrel", nbineop, 0., eopmax, "E_{ele}/P_{out}");
  h1_EeleOPout_endcaps =
      bookH1(iBooker, "EeleOPout_endcaps", "ele E_{ele}/P_{out} in endcaps", nbineop, 0., eopmax, "E_{ele}/P_{out}");
  h1_dEtaSc_propVtx_barrel = bookH1(iBooker,
                                    "dEtaSc_propVtx_barrel",
                                    "ele #eta_{sc} - #eta_{tr}, prop from vertex, in barrel",
                                    nbindetamatch,
                                    detamatchmin,
                                    detamatchmax,
                                    "#eta_{sc} - #eta_{tr}");
  h1_dEtaSc_propVtx_endcapsPos = bookH1(iBooker,
                                        "dEtaSc_propVtx_endcapsPos",
                                        "ele #eta_{sc} - #eta_{tr}, prop from vertex, in positive endcap",
                                        nbindetamatch,
                                        detamatchmin,
                                        detamatchmax,
                                        "#eta_{sc} - #eta_{tr}");
  h1_dEtaSc_propVtx_endcapsNeg = bookH1(iBooker,
                                        "dEtaSc_propVtx_endcapsNeg",
                                        "ele #eta_{sc} - #eta_{tr}, prop from vertex, in negative endcap",
                                        nbindetamatch,
                                        detamatchmin,
                                        detamatchmax,
                                        "#eta_{sc} - #eta_{tr}");
  py_dEtaSc_propVtxVsPhi = bookP1(iBooker,
                                  "dEtaSc_propVtxVsPhi",
                                  "ele #eta_{sc} - #eta_{tr}, prop from vertex vs #phi",
                                  nbinphi2D,
                                  phimin,
                                  phimax,
                                  detamatchmin,
                                  detamatchmax,
                                  "#phi (rad)",
                                  "<#eta_{sc} - #eta_{tr}>");
  h1_dEtaEleCl_propOut_barrel = bookH1(iBooker,
                                       "dEtaEleCl_propOut_barrel",
                                       "ele #eta_{EleCl} - #eta_{tr}, prop from outermost, in barrel",
                                       nbindetamatch,
                                       detamatchmin,
                                       detamatchmax,
                                       "#eta_{elecl} - #eta_{tr}");
  h1_dEtaEleCl_propOut_endcapsPos = bookH1(iBooker,
                                           "dEtaEleCl_propOut_endcapsPos",
                                           "ele #eta_{EleCl} - #eta_{tr}, prop from outermost, in positive endcap",
                                           nbindetamatch,
                                           detamatchmin,
                                           detamatchmax,
                                           "#eta_{elecl} - #eta_{tr}");
  h1_dEtaEleCl_propOut_endcapsNeg = bookH1(iBooker,
                                           "dEtaEleCl_propOut_endcapsNeg",
                                           "ele #eta_{EleCl} - #eta_{tr}, prop from outermost, in negative endcap",
                                           nbindetamatch,
                                           detamatchmin,
                                           detamatchmax,
                                           "#eta_{elecl} - #eta_{tr}");
  h1_dPhiSc_propVtx_barrel = bookH1(iBooker,
                                    "dPhiSc_propVtx_barrel",
                                    "ele #phi_{sc} - #phi_{tr}, prop from vertex, in barrel",
                                    nbindphimatch,
                                    dphimatchmin,
                                    dphimatchmax,
                                    "#phi_{sc} - #phi_{tr} (rad)");
  h1_dPhiSc_propVtx_endcapsPos = bookH1(iBooker,
                                        "dPhiSc_propVtx_endcapsPos",
                                        "ele #phi_{sc} - #phi_{tr}, prop from vertex, in positive endcap",
                                        nbindphimatch,
                                        dphimatchmin,
                                        dphimatchmax,
                                        "#phi_{sc} - #phi_{tr} (rad)");
  h1_dPhiSc_propVtx_endcapsNeg = bookH1(iBooker,
                                        "dPhiSc_propVtx_endcapsNeg",
                                        "ele #phi_{sc} - #phi_{tr}, prop from vertex, in negative endcap",
                                        nbindphimatch,
                                        dphimatchmin,
                                        dphimatchmax,
                                        "#phi_{sc} - #phi_{tr} (rad)");
  py_dPhiSc_propVtxVsPhi = bookP1(iBooker,
                                  "dPhiSc_propVtxVsPhi",
                                  "ele #phi_{sc} - #phi_{tr}, prop from vertex vs #phi",
                                  nbinphi2D,
                                  phimin,
                                  phimax,
                                  dphimatchmin,
                                  dphimatchmax,
                                  "#phi (rad)",
                                  "<#phi_{sc} - #phi_{tr}> (rad)");
  h1_dPhiEleCl_propOut_barrel = bookH1(iBooker,
                                       "dPhiEleCl_propOut_barrel",
                                       "ele #phi_{EleCl} - #phi_{tr}, prop from outermost, in barrel",
                                       nbindphimatch,
                                       dphimatchmin,
                                       dphimatchmax,
                                       "#phi_{elecl} - #phi_{tr} (rad)");
  h1_dPhiEleCl_propOut_endcapsPos = bookH1(iBooker,
                                           "dPhiEleCl_propOut_endcapsPos",
                                           "ele #phi_{EleCl} - #phi_{tr}, prop from outermost, in positive endcap",
                                           nbindphimatch,
                                           dphimatchmin,
                                           dphimatchmax,
                                           "#phi_{elecl} - #phi_{tr} (rad)");
  h1_dPhiEleCl_propOut_endcapsNeg = bookH1(iBooker,
                                           "dPhiEleCl_propOut_endcapsNeg",
                                           "ele #phi_{EleCl} - #phi_{tr}, prop from outermost, in negative endcap",
                                           nbindphimatch,
                                           dphimatchmin,
                                           dphimatchmax,
                                           "#phi_{elecl} - #phi_{tr} (rad)");
  h1_Hoe_barrel = bookH1(iBooker,
                         "Hoe_barrel",
                         "ele hadronic energy / em energy, in barrel",
                         nbinhoe,
                         hoemin,
                         hoemax,
                         "H/E",
                         "Events",
                         "ELE_LOGY E1 P");
  h1_Hoe_endcaps = bookH1(iBooker,
                          "Hoe_endcaps",
                          "ele hadronic energy / em energy, in endcaps",
                          nbinhoe,
                          hoemin,
                          hoemax,
                          "H/E",
                          "Events",
                          "ELE_LOGY E1 P");
  py_HoeVsPhi = bookP1(iBooker,
                       "HoeVsPhi",
                       "ele hadronic energy / em energy vs #phi",
                       nbinphi2D,
                       phimin,
                       phimax,
                       hoemin,
                       hoemax,
                       "#phi (rad)",
                       "<H/E>",
                       "E1 P");
  h1_sclSigEtaEta_barrel =
      bookH1(iBooker, "sclSigEtaEta_barrel", "ele sigma eta eta in barrel", 100, 0., 0.05, "sietaieta");
  h1_sclSigEtaEta_endcaps =
      bookH1(iBooker, "sclSigEtaEta_endcaps", "ele sigma eta eta in endcaps", 100, 0., 0.05, "sietaieta");
  h1_sigIEtaIEta5x5_barrel =
      bookH1(iBooker, "sigIEtaIEta5x5_barrel", "ele sigma ieta ieta 5x5 in barrel", 100, 0., 0.05, "sietaieta5x5");
  h1_sigIEtaIEta5x5_endcaps =
      bookH1(iBooker, "sigIEtaIEta5x5_endcaps", "ele sigma ieta ieta 5x5 in endcaps", 100, 0., 0.05, "sietaieta5x5");

  // fbrem
  h1_fbrem = bookH1(iBooker, "fbrem", "ele brem fraction", 100, 0., 1., "P_{in} - P_{out} / P_{in}");
  py_fbremVsEta = bookP1(iBooker,
                         "fbremVsEta",
                         "ele brem fraction vs #eta",
                         nbineta2D,
                         etamin,
                         etamax,
                         0.,
                         1.,
                         "#eta",
                         "<P_{in} - P_{out} / P_{in}>");
  py_fbremVsPhi = bookP1(iBooker,
                         "fbremVsPhi",
                         "ele brem fraction vs #phi",
                         nbinphi2D,
                         phimin,
                         phimax,
                         0.,
                         1.,
                         "#phi (rad)",
                         "<P_{in} - P_{out} / P_{in}>");
  h1_classes = bookH1(iBooker, "classes", "ele electron classes", 10, 0.0, 10.);

  // pflow
  h1_mva = bookH1(iBooker, "mva", "ele identification mva", 100, -1., 1., "mva");
  h1_provenance = bookH1(iBooker, "provenance", "ele provenance", 5, -2., 3., "provenance");

  // isolation
  h1_tkSumPt_dr03 = bookH1(
      iBooker, "tkSumPt_dr03", "tk isolation sum, dR=0.3", 100, 0.0, 20., "TkIsoSum (GeV/c)", "Events", "ELE_LOGY E1 P");
  h1_ecalRecHitSumEt_dr03 = bookH1(iBooker,
                                   "ecalRecHitSumEt_dr03",
                                   "ecal isolation sum, dR=0.3",
                                   100,
                                   0.0,
                                   20.,
                                   "EcalIsoSum (GeV)",
                                   "Events",
                                   "ELE_LOGY E1 P");
  h1_hcalTowerSumEt_dr03 = bookH1(iBooker,
                                  "hcalTowerSumEt_dr03",
                                  "hcal isolation sum, dR=0.3",
                                  100,
                                  0.0,
                                  20.,
                                  "HcalIsoSum (GeV)",
                                  "Events",
                                  "ELE_LOGY E1 P");

  // pf isolation
  h1_PFch_dr03 = bookH1(iBooker,
                        "PFch_dr03",
                        "Charged PF candidate sum, dR=0.3",
                        100,
                        0.0,
                        20.,
                        "PF charged (GeV/c)",
                        "Events",
                        "ELE_LOGY E1 P");
  h1_PFem_dr03 = bookH1(iBooker,
                        "PFem_dr03",
                        "Neutral EM PF candidate sum, dR=0.3",
                        100,
                        0.0,
                        20.,
                        "PF neutral EM (GeV)",
                        "Events",
                        "ELE_LOGY E1 P");
  h1_PFnh_dr03 = bookH1(iBooker,
                        "PFnh_dr03",
                        "Neutral Had PF candidate sum, dR=0.3",
                        100,
                        0.0,
                        20.,
                        "PF neutral Had (GeV)",
                        "Events",
                        "ELE_LOGY E1 P");

  // di-electron mass
  setBookIndex(200);
  h1_mee = bookH1(iBooker, "mee", "ele pairs invariant mass", nbinmee, meemin, meemax, "m_{ee} (GeV/c^{2})");
  h1_mee_os = bookH1(iBooker,
                     "mee_os",
                     "ele pairs invariant mass, opposite sign",
                     nbinmee,
                     meemin,
                     meemax,
                     "m_{e^{+}e^{-}} (GeV/c^{2})");
  h1_mee_os_bb = bookH1(iBooker,
                        "mee_os_bb",
                        "ele pairs invariant mass, opposite sign, barrel-barrel",
                        nbinmee,
                        meemin,
                        meemax,
                        "m_{e^{+}e^{-}} (GeV/c^{2})");
  h1_mee_os_ee = bookH1(iBooker,
                        "mee_os_ee",
                        "ele pairs invariant mass, opposite sign, endcap-endcap",
                        nbinmee,
                        meemin,
                        meemax,
                        "m_{e^{+}e^{-}} (GeV/c^{2})");
  h1_mee_os_eb = bookH1(iBooker,
                        "mee_os_eb",
                        "ele pairs invariant mass, opposite sign, barrel-endcap",
                        nbinmee,
                        meemin,
                        meemax,
                        "m_{e^{+}e^{-}} (GeV/c^{2})");

  //===========================
  // histos for matching and matched matched objects
  //===========================

  // matching object
  std::string matchingObjectType;
  Labels l;
  labelsForToken(matchingObjectCollection_, l);
  if (std::string::npos != std::string(l.module).find("SuperCluster", 0)) {
    matchingObjectType = "SC";
  }
  if (matchingObjectType.empty()) {
    edm::LogError("ElectronMcFakeValidator::beginJob") << "Unknown matching object type !";
  } else {
    edm::LogInfo("ElectronMcFakeValidator::beginJob") << "Matching object type: " << matchingObjectType;
  }

  // matching object distributions
  h1_matchingObject_Eta = bookH1withSumw2(
      iBooker, "matchingObject_Eta", matchingObjectType + " #eta", nbineta, etamin, etamax, "#eta_{SC}");

  h1_matchingObject_Pt = bookH1withSumw2(
      iBooker, "matchingObject_Pt", matchingObjectType + " pt", nbinpteff, 5., ptmax, "pt_{SC} (GeV/c)");
  h1_matchingObject_Phi = bookH1withSumw2(
      iBooker, "matchingObject_Phi", matchingObjectType + " #phi", nbinphi, phimin, phimax, "#phi (rad)");

  h1_matchedObject_Eta = bookH1withSumw2(
      iBooker, "matchedObject_Eta", "Efficiency vs matching SC #eta", nbineta, etamin, etamax, "#eta_{SC}");
  h1_matchedObject_Pt = bookH1withSumw2(
      iBooker, "matchedObject_Pt", "Efficiency vs matching SC E_{T}", nbinpteff, 5., ptmax, "pt_{SC} (GeV/c)");
  h1_matchedObject_Phi = bookH1withSumw2(
      iBooker, "matchedObject_Phi", "Efficiency vs matching SC #phi", nbinphi, phimin, phimax, "#phi (rad)");
  
}

void ElectronAnalyzer::analyze(const edm::Event& iEvent, const edm::EventSetup& iSetup) {
  nEvents_++;

  edm::Handle<GsfElectronCollection> gsfElectrons;
  iEvent.getByToken(electronCollection_, gsfElectrons);
  edm::Handle<reco::SuperClusterCollection> recoClusters;
  iEvent.getByToken(matchingObjectCollection_, recoClusters);
  edm::Handle<reco::TrackCollection> tracks;
  iEvent.getByToken(trackCollection_, tracks);
  edm::Handle<reco::GsfTrackCollection> gsfTracks;
  iEvent.getByToken(gsftrackCollection_, gsfTracks);
  edm::Handle<reco::VertexCollection> vertices;
  iEvent.getByToken(vertexCollection_, vertices);
  edm::Handle<reco::BeamSpot> recoBeamSpotHandle;
  iEvent.getByToken(beamSpotTag_, recoBeamSpotHandle);
  const BeamSpot bs = *recoBeamSpotHandle;

  edm::EventNumber_t ievt = iEvent.id().event();
  edm::RunNumber_t irun = iEvent.id().run();
  edm::LuminosityBlockNumber_t ils = iEvent.luminosityBlock();

  edm::LogInfo("ElectronAnalyzer::analyze") << "Treating " << gsfElectrons.product()->size() << " electrons"
                                            << " from event " << ievt << " in run " << irun << " and lumiblock " << ils;
  //h1_num_->Fill((*gsfElectrons).size()) ;

  // selected rec electrons
  reco::GsfElectronCollection::const_iterator gsfIter;
  for (gsfIter = gsfElectrons->begin(); gsfIter != gsfElectrons->end(); gsfIter++) {
    // vertex TIP
    double vertexTIP = (gsfIter->vertex().x() - bs.position().x()) * (gsfIter->vertex().x() - bs.position().x()) +
                       (gsfIter->vertex().y() - bs.position().y()) * (gsfIter->vertex().y() - bs.position().y());
    vertexTIP = sqrt(vertexTIP);

    // select electrons
    if (!selected(gsfIter, vertexTIP))
      continue;

    // invariant mass of 2 selected electrons
    reco::GsfElectronCollection::const_iterator gsfIter2;
    for (gsfIter2 = gsfIter + 1; gsfIter2 != gsfElectrons->end(); gsfIter2++) {
      if (!selected(gsfIter2, vertexTIP))
        continue;
      float invMass = computeInvMass(*gsfIter, *gsfIter2);
      h1_mee->Fill(invMass);
      if (((gsfIter->charge()) * (gsfIter2->charge())) < 0.) {
        h1_mee_os->Fill(invMass);
        if (gsfIter->isEB() && gsfIter2->isEB())
          h1_mee_os_bb->Fill(invMass);
        else if (gsfIter->isEE() && gsfIter2->isEE())
          h1_mee_os_ee->Fill(invMass);
        else
          h1_mee_os_eb->Fill(invMass);
      }
    }

    // basic quantities
    if (gsfIter->isEB())
      h1_vertexPt_barrel->Fill(gsfIter->pt());
    if (gsfIter->isEE())
      h1_vertexPt_endcaps->Fill(gsfIter->pt());
    h1_vertexEta->Fill(gsfIter->eta());
    h2_vertexEtaVsPhi->Fill(gsfIter->eta(), gsfIter->phi());
    h2_vertexXvsY->Fill(gsfIter->vertex().x(), gsfIter->vertex().y());
    h1_vertexZ->Fill(gsfIter->vertex().z());

    // supercluster related distributions
    reco::SuperClusterRef sclRef = gsfIter->superCluster();
    // ALREADY DONE IN GSF ELECTRON CORE
    double R = TMath::Sqrt(sclRef->x() * sclRef->x() + sclRef->y() * sclRef->y() + sclRef->z() * sclRef->z());
    double Rt = TMath::Sqrt(sclRef->x() * sclRef->x() + sclRef->y() * sclRef->y());
    h1_sclEt->Fill(sclRef->energy() * (Rt / R));

    // track related distributions
    if (!readAOD_) {  // track extra does not exist in AOD
      h1_foundHits->Fill(gsfIter->gsfTrack()->numberOfValidHits());
      py_foundHitsVsEta->Fill(gsfIter->eta(), gsfIter->gsfTrack()->numberOfValidHits());
      py_foundHitsVsPhi->Fill(gsfIter->phi(), gsfIter->gsfTrack()->numberOfValidHits());
      h1_lostHits->Fill(gsfIter->gsfTrack()->numberOfLostHits());
      py_lostHitsVsEta->Fill(gsfIter->eta(), gsfIter->gsfTrack()->numberOfLostHits());
      py_lostHitsVsPhi->Fill(gsfIter->phi(), gsfIter->gsfTrack()->numberOfLostHits());
      h1_chi2->Fill(gsfIter->gsfTrack()->normalizedChi2());
      py_chi2VsEta->Fill(gsfIter->eta(), gsfIter->gsfTrack()->normalizedChi2());
      py_chi2VsPhi->Fill(gsfIter->phi(), gsfIter->gsfTrack()->normalizedChi2());
    }

    // match distributions
    if (gsfIter->isEB()) {
      h1_Eop_barrel->Fill(gsfIter->eSuperClusterOverP());
      h1_EeleOPout_barrel->Fill(gsfIter->eEleClusterOverPout());
      h1_dEtaSc_propVtx_barrel->Fill(gsfIter->deltaEtaSuperClusterTrackAtVtx());
      h1_dEtaEleCl_propOut_barrel->Fill(gsfIter->deltaEtaEleClusterTrackAtCalo());
      h1_dPhiSc_propVtx_barrel->Fill(gsfIter->deltaPhiSuperClusterTrackAtVtx());
      h1_dPhiEleCl_propOut_barrel->Fill(gsfIter->deltaPhiEleClusterTrackAtCalo());
      h1_Hoe_barrel->Fill(gsfIter->hadronicOverEm());
      h1_sclSigEtaEta_barrel->Fill(gsfIter->scSigmaEtaEta());
      h1_sigIEtaIEta5x5_barrel->Fill(gsfIter->full5x5_sigmaIetaIeta());
    }
    if (gsfIter->isEE()) {
      h1_Eop_endcaps->Fill(gsfIter->eSuperClusterOverP());
      h1_EeleOPout_endcaps->Fill(gsfIter->eEleClusterOverPout());
      if (gsfIter->eta() > 0) {
        h1_dEtaSc_propVtx_endcapsPos->Fill(gsfIter->deltaEtaSuperClusterTrackAtVtx());
        h1_dEtaEleCl_propOut_endcapsPos->Fill(gsfIter->deltaEtaEleClusterTrackAtCalo());
        h1_dPhiSc_propVtx_endcapsPos->Fill(gsfIter->deltaPhiSuperClusterTrackAtVtx());
        h1_dPhiEleCl_propOut_endcapsPos->Fill(gsfIter->deltaPhiEleClusterTrackAtCalo());
      } else {
        h1_dEtaSc_propVtx_endcapsNeg->Fill(gsfIter->deltaEtaSuperClusterTrackAtVtx());
        h1_dEtaEleCl_propOut_endcapsNeg->Fill(gsfIter->deltaEtaEleClusterTrackAtCalo());
        h1_dPhiSc_propVtx_endcapsNeg->Fill(gsfIter->deltaPhiSuperClusterTrackAtVtx());
        h1_dPhiEleCl_propOut_endcapsNeg->Fill(gsfIter->deltaPhiEleClusterTrackAtCalo());
      }
      h1_Hoe_endcaps->Fill(gsfIter->hadronicOverEm());
      h1_sclSigEtaEta_endcaps->Fill(gsfIter->scSigmaEtaEta());
      h1_sigIEtaIEta5x5_endcaps->Fill(gsfIter->full5x5_sigmaIetaIeta());
    }
    py_EopVsPhi->Fill(gsfIter->phi(), gsfIter->eSuperClusterOverP());
    py_dEtaSc_propVtxVsPhi->Fill(gsfIter->phi(), gsfIter->deltaEtaSuperClusterTrackAtVtx());
    py_dPhiSc_propVtxVsPhi->Fill(gsfIter->phi(), gsfIter->deltaPhiSuperClusterTrackAtVtx());
    py_HoeVsPhi->Fill(gsfIter->phi(), gsfIter->hadronicOverEm());

    // fbrem, classes
    h1_fbrem->Fill(gsfIter->fbrem());
    py_fbremVsEta->Fill(gsfIter->eta(), gsfIter->fbrem());
    py_fbremVsPhi->Fill(gsfIter->phi(), gsfIter->fbrem());
    int eleClass = gsfIter->classification();
    if (gsfIter->isEE())
      eleClass += 5;
    h1_classes->Fill(eleClass);

    // pflow
    h1_mva->Fill(gsfIter->mva_e_pi());
    if (gsfIter->ecalDrivenSeed())
      h1_provenance->Fill(1.);
    if (gsfIter->trackerDrivenSeed())
      h1_provenance->Fill(-1.);
    if (gsfIter->trackerDrivenSeed() || gsfIter->ecalDrivenSeed())
      h1_provenance->Fill(0.);
    if (gsfIter->trackerDrivenSeed() && !gsfIter->ecalDrivenSeed())
      h1_provenance->Fill(-2.);
    if (!gsfIter->trackerDrivenSeed() && gsfIter->ecalDrivenSeed())
      h1_provenance->Fill(2.);

    // isolation
    h1_tkSumPt_dr03->Fill(gsfIter->dr03TkSumPt());
    h1_ecalRecHitSumEt_dr03->Fill(gsfIter->dr03EcalRecHitSumEt());
    h1_hcalTowerSumEt_dr03->Fill(gsfIter->dr03HcalTowerSumEt());

    // PF isolation
    GsfElectron::PflowIsolationVariables pfIso = gsfIter->pfIsolationVariables();
    h1_PFch_dr03->Fill(pfIso.sumChargedHadronPt);
    h1_PFem_dr03->Fill(pfIso.sumPhotonEt);
    h1_PFnh_dr03->Fill(pfIso.sumNeutralHadronEt);
  }

  // association matching object-reco electrons
  reco::SuperClusterCollection::const_iterator moIter;
  for (moIter = recoClusters->begin(); moIter != recoClusters->end(); moIter++) {
    //    // number of matching objects

    if (moIter->energy() / cosh(moIter->eta()) > maxPtMatchingObject_ ||
        std::abs(moIter->eta()) > maxAbsEtaMatchingObject_) {
      continue;
    }

    //    // suppress the endcaps
    h1_matchingObject_Eta->Fill(moIter->eta());
    h1_matchingObject_Pt->Fill(moIter->energy() / cosh(moIter->eta()));
    h1_matchingObject_Phi->Fill(moIter->phi());

    bool okGsfFound = false;
    double gsfOkRatio = 999999999.;
    reco::GsfElectron bestGsfElectron;
    reco::GsfElectronCollection::const_iterator gsfIter;
    for (gsfIter = gsfElectrons->begin(); gsfIter != gsfElectrons->end(); gsfIter++) {
      double vertexTIP = (gsfIter->vertex().x() - bs.position().x()) * (gsfIter->vertex().x() - bs.position().x()) +
                         (gsfIter->vertex().y() - bs.position().y()) * (gsfIter->vertex().y() - bs.position().y());
      vertexTIP = sqrt(vertexTIP);

      // select electrons
      if (!selected(gsfIter, vertexTIP))
        continue;

      // matching with a cone in eta phi
      if (matchingCondition_ == "Cone") {
        double dphi = gsfIter->phi() - moIter->phi();
        if (std::abs(dphi) > CLHEP::pi) {
          dphi = dphi < 0 ? (CLHEP::twopi) + dphi : dphi - CLHEP::twopi;
        }
        double deltaR = sqrt(pow((moIter->eta() - gsfIter->eta()), 2) + pow(dphi, 2));
        if (deltaR < deltaR_) {
          double tmpGsfRatio = gsfIter->p() / moIter->energy();
          if (std::abs(tmpGsfRatio - 1) < std::abs(gsfOkRatio - 1)) {
            gsfOkRatio = tmpGsfRatio;
            bestGsfElectron = *gsfIter;
            okGsfFound = true;
          }
        }
      }
    }  // loop over rec ele to look for the best one
    if (okGsfFound) {
      // generated distributions for matched electrons
      h1_matchedObject_Eta->Fill(moIter->eta());
      h1_matchedObject_Pt->Fill(moIter->energy() / cosh(moIter->eta()));
      h1_matchedObject_Phi->Fill(moIter->phi());

      //classes
    }

  }  // loop overmatching object
}

float ElectronAnalyzer::computeInvMass(const reco::GsfElectron& e1, const reco::GsfElectron& e2) {
  math::XYZTLorentzVector p12 = e1.p4() + e2.p4();
  float mee2 = p12.Dot(p12);
  float invMass = mee2 > 0. ? sqrt(mee2) : 0;
  return invMass;
}

bool ElectronAnalyzer::selected(const reco::GsfElectronCollection::const_iterator& gsfIter, double vertexTIP) {
  if ((Selection_ > 0) && generalCut(gsfIter))
    return false;
  if ((Selection_ >= 1) && etCut(gsfIter))
    return false;
  if ((Selection_ >= 2) && isolationCut(gsfIter, vertexTIP))
    return false;
  if ((Selection_ >= 3) && idCut(gsfIter))
    return false;
  return true;
}

bool ElectronAnalyzer::generalCut(const reco::GsfElectronCollection::const_iterator& gsfIter) {
  if (std::abs(gsfIter->eta()) > maxAbsEta_)
    return true;
  if (gsfIter->pt() < minPt_)
    return true;

  if (gsfIter->isEB() && isEE_)
    return true;
  if (gsfIter->isEE() && isEB_)
    return true;
  if (gsfIter->isEBEEGap() && isNotEBEEGap_)
    return true;

  if (gsfIter->ecalDrivenSeed() && isTrackerDriven_)
    return true;
  if (gsfIter->trackerDrivenSeed() && isEcalDriven_)
    return true;

  return false;
}

bool ElectronAnalyzer::etCut(const reco::GsfElectronCollection::const_iterator& gsfIter) {
  if (gsfIter->superCluster()->energy() / cosh(gsfIter->superCluster()->eta()) < minEt_)
    return true;

  return false;
}

bool ElectronAnalyzer::isolationCut(const reco::GsfElectronCollection::const_iterator& gsfIter, double vertexTIP) {
  if (gsfIter->isEB() && vertexTIP > tipMaxBarrel_)
    return true;
  if (gsfIter->isEE() && vertexTIP > tipMaxEndcaps_)
    return true;

  if (gsfIter->dr03TkSumPt() > tkIso03Max_)
    return true;
  if (gsfIter->isEB() && gsfIter->dr03HcalTowerSumEt(1) > hcalIso03Depth1MaxBarrel_)
    return true;
  if (gsfIter->isEE() && gsfIter->dr03HcalTowerSumEt(1) > hcalIso03Depth1MaxEndcaps_)
    return true;
  if (gsfIter->isEE() && gsfIter->dr03HcalTowerSumEt(2) > hcalIso03Depth2MaxEndcaps_)
    return true;
  if (gsfIter->isEB() && gsfIter->dr03EcalRecHitSumEt() > ecalIso03MaxBarrel_)
    return true;
  if (gsfIter->isEE() && gsfIter->dr03EcalRecHitSumEt() > ecalIso03MaxEndcaps_)
    return true;

  return false;
}

bool ElectronAnalyzer::idCut(const reco::GsfElectronCollection::const_iterator& gsfIter) {
  if (gsfIter->isEB() && gsfIter->eSuperClusterOverP() < eOverPMinBarrel_)
    return true;
  if (gsfIter->isEB() && gsfIter->eSuperClusterOverP() > eOverPMaxBarrel_)
    return true;
  if (gsfIter->isEE() && gsfIter->eSuperClusterOverP() < eOverPMinEndcaps_)
    return true;
  if (gsfIter->isEE() && gsfIter->eSuperClusterOverP() > eOverPMaxEndcaps_)
    return true;
  if (gsfIter->isEB() && std::abs(gsfIter->deltaEtaSuperClusterTrackAtVtx()) < dEtaMinBarrel_)
    return true;
  if (gsfIter->isEB() && std::abs(gsfIter->deltaEtaSuperClusterTrackAtVtx()) > dEtaMaxBarrel_)
    return true;
  if (gsfIter->isEE() && std::abs(gsfIter->deltaEtaSuperClusterTrackAtVtx()) < dEtaMinEndcaps_)
    return true;
  if (gsfIter->isEE() && std::abs(gsfIter->deltaEtaSuperClusterTrackAtVtx()) > dEtaMaxEndcaps_)
    return true;
  if (gsfIter->isEB() && std::abs(gsfIter->deltaPhiSuperClusterTrackAtVtx()) < dPhiMinBarrel_)
    return true;
  if (gsfIter->isEB() && std::abs(gsfIter->deltaPhiSuperClusterTrackAtVtx()) > dPhiMaxBarrel_)
    return true;
  if (gsfIter->isEE() && std::abs(gsfIter->deltaPhiSuperClusterTrackAtVtx()) < dPhiMinEndcaps_)
    return true;
  if (gsfIter->isEE() && std::abs(gsfIter->deltaPhiSuperClusterTrackAtVtx()) > dPhiMaxEndcaps_)
    return true;
  if (gsfIter->isEB() && gsfIter->scSigmaIEtaIEta() < sigIetaIetaMinBarrel_)
    return true;
  if (gsfIter->isEB() && gsfIter->scSigmaIEtaIEta() > sigIetaIetaMaxBarrel_)
    return true;
  if (gsfIter->isEE() && gsfIter->scSigmaIEtaIEta() < sigIetaIetaMinEndcaps_)
    return true;
  if (gsfIter->isEE() && gsfIter->scSigmaIEtaIEta() > sigIetaIetaMaxEndcaps_)
    return true;
  if (gsfIter->isEB() && gsfIter->hadronicOverEm() > hadronicOverEmMaxBarrel_)
    return true;
  if (gsfIter->isEE() && gsfIter->hadronicOverEm() > hadronicOverEmMaxEndcaps_)
    return true;

  return false;
}