d7/dbf/TkConvValidator_8cc_source.html

 #include <iostream>

 //

 #include "FWCore/ServiceRegistry/interface/Service.h"

 #include "CommonTools/UtilAlgos/interface/TFileService.h"

 //

 #include "Validation/RecoEgamma/plugins/TkConvValidator.h"


 //

 #include "FWCore/Framework/interface/MakerMacros.h"

 #include "FWCore/MessageLogger/interface/MessageLogger.h"

 #include "FWCore/Utilities/interface/Exception.h"

 //

 #include "SimDataFormats/GeneratorProducts/interface/HepMCProduct.h"

 #include "SimDataFormats/Track/interface/SimTrack.h"

 #include "SimDataFormats/Track/interface/SimTrackContainer.h"

 #include "SimDataFormats/Vertex/interface/SimVertex.h"

 #include "SimDataFormats/Vertex/interface/SimVertexContainer.h"

 //

 #include "SimDataFormats/TrackingAnalysis/interface/TrackingParticleFwd.h"

 #include "SimDataFormats/TrackingAnalysis/interface/TrackingParticle.h"

 #include "SimDataFormats/TrackingAnalysis/interface/TrackingVertexContainer.h"

 //

 #include "SimTracker/TrackerHitAssociation/interface/TrackerHitAssociator.h"

 #include "SimTracker/Records/interface/TrackAssociatorRecord.h"

 #include "Geometry/Records/interface/TrackerDigiGeometryRecord.h"

 #include "Geometry/CommonDetUnit/interface/GeomDet.h"

 #include "Geometry/TrackerGeometryBuilder/interface/TrackerGeometry.h"

 #include "Geometry/CommonDetUnit/interface/GeomDetUnit.h"

 //

 #include "TrackingTools/TrajectoryState/interface/FreeTrajectoryState.h"

 #include "TrackingTools/PatternTools/interface/TwoTrackMinimumDistance.h"

 #include "TrackingTools/TransientTrack/interface/TrackTransientTrack.h"

 //

 #include "TrackingTools/TransientTrack/interface/TransientTrackBuilder.h"

 #include "TrackingTools/Records/interface/TransientTrackRecord.h"

 #include "CLHEP/Units/GlobalPhysicalConstants.h"

 #include "CommonTools/Statistics/interface/ChiSquaredProbability.h"

 //

 #include "MagneticField/Engine/interface/MagneticField.h"

 #include "Geometry/TrackerGeometryBuilder/interface/TrackerGeometry.h"

 #include "Geometry/Records/interface/TrackerDigiGeometryRecord.h"

 #include "MagneticField/Records/interface/IdealMagneticFieldRecord.h"

 #include "TrackingTools/Records/interface/TrackingComponentsRecord.h"

 #include "TrackingTools/TrajectoryState/interface/TrajectoryStateOnSurface.h"

 #include "TrackingTools/TrajectoryState/interface/TrajectoryStateTransform.h"

 #include "Geometry/CommonDetUnit/interface/GeomDet.h"

 #include "TrackingTools/MaterialEffects/interface/PropagatorWithMaterial.h"


 //

 #include "DataFormats/Common/interface/Handle.h"

 #include "DataFormats/TrackReco/interface/Track.h"

 #include "DataFormats/TrackReco/interface/TrackExtra.h"

 #include "DataFormats/TrackReco/interface/TrackFwd.h"

 #include "DataFormats/EgammaCandidates/interface/Conversion.h"

 #include "DataFormats/EgammaCandidates/interface/Photon.h"

 #include "DataFormats/EgammaReco/interface/SuperCluster.h"

 #include "DataFormats/TrackCandidate/interface/TrackCandidateCollection.h"

 #include "DataFormats/TrackingRecHit/interface/TrackingRecHit.h"

 #include "DataFormats/EgammaReco/interface/BasicCluster.h"

 #include "DataFormats/EgammaReco/interface/BasicCluster.h"

 #include "DataFormats/EgammaReco/interface/BasicClusterFwd.h"

 #include "DataFormats/CaloRecHit/interface/CaloCluster.h"

 #include "DataFormats/CaloRecHit/interface/CaloClusterFwd.h"

 #include "DataFormats/DetId/interface/DetId.h"

 #include "DataFormats/JetReco/interface/GenJetCollection.h"

 #include "DataFormats/HepMCCandidate/interface/GenParticle.h"

 #include "DataFormats/GeometrySurface/interface/BoundCylinder.h"

 #include "DataFormats/GeometrySurface/interface/BoundDisk.h"

 #include "DataFormats/GeometrySurface/interface/SimpleCylinderBounds.h"

 #include "DataFormats/GeometrySurface/interface/SimpleDiskBounds.h"

 #include "DataFormats/Math/interface/deltaPhi.h"


 //

 #include "RecoEgamma/EgammaMCTools/interface/PhotonMCTruthFinder.h"

 #include "RecoEgamma/EgammaMCTools/interface/PhotonMCTruth.h"

 #include "RecoEgamma/EgammaMCTools/interface/ElectronMCTruth.h"

 #include "RecoEcal/EgammaCoreTools/interface/EcalClusterTools.h"

 #include "Geometry/Records/interface/CaloGeometryRecord.h"

 #include "Geometry/CaloTopology/interface/CaloTopology.h"

 #include "Geometry/CaloEventSetup/interface/CaloTopologyRecord.h"


 #include "RecoEgamma/EgammaPhotonAlgos/interface/ConversionHitChecker.h"


 //

 //

 #include "TFile.h"

 #include "TH1.h"

 #include "TH2.h"

 #include "TTree.h"

 #include "TVector3.h"

 #include "TProfile.h"

 //

 using namespace std;


 TkConvValidator::TkConvValidator( const edm::ParameterSet& pset )

   {


     fName_     = pset.getUntrackedParameter<std::string>("Name");

     verbosity_ = pset.getUntrackedParameter<int>("Verbosity");

     parameters_ = pset;


     photonCollectionProducer_ = pset.getParameter<std::string>("phoProducer");

     photonCollection_ = pset.getParameter<std::string>("photonCollection");

     photonCollectionPr_Token_ = consumes<reco::PhotonCollection> (

         edm::InputTag(photonCollectionProducer_,

                       photonCollection_));


     conversionCollectionProducer_ = pset.getParameter<std::string>("convProducer");

     conversionCollection_ = pset.getParameter<std::string>("conversionCollection");

     conversionCollectionPr_Token_ = consumes<reco::ConversionCollection> (

         edm::InputTag(conversionCollectionProducer_,

                       conversionCollection_));


     // conversionTrackProducer_ = pset.getParameter<std::string>("trackProducer");

     dqmpath_ = pset.getParameter<std::string>("dqmpath");

     minPhoEtCut_ = pset.getParameter<double>("minPhoEtCut");

     generalTracksOnly_ = pset.getParameter<bool>("generalTracksOnly");

     arbitratedMerged_ = pset.getParameter<bool>("arbitratedMerged");

     arbitratedEcalSeeded_ = pset.getParameter<bool>("arbitratedEcalSeeded");

     ecalalgotracks_ = pset.getParameter<bool>("ecalalgotracks");

     highPurity_ = pset.getParameter<bool>("highPurity");

     minProb_ = pset.getParameter<double>("minProb");

     maxHitsBeforeVtx_ = pset.getParameter<uint>("maxHitsBeforeVtx");

     minLxy_           = pset.getParameter<double>("minLxy");

     isRunCentrally_=   pset.getParameter<bool>("isRunCentrally");


     offline_pvToken_ = consumes<reco::VertexCollection>(

         pset.getUntrackedParameter<edm::InputTag> ("offlinePV",

                                                    edm::InputTag("offlinePrimaryVertices")));

     beamspotToken_ = consumes<reco::BeamSpot>(

         pset.getUntrackedParameter<edm::InputTag> ("beamspot",

                                                    edm::InputTag("offlineBeamSpot")));

     g4_simTk_Token_  = consumes<edm::SimTrackContainer>(edm::InputTag("g4SimHits"));

     g4_simVtx_Token_ = consumes<edm::SimVertexContainer>(edm::InputTag("g4SimHits"));


     tpSelForEff_Token_ = consumes<TrackingParticleCollection> (

         edm::InputTag("tpSelecForEfficiency"));

     tpSelForFake_Token_ = consumes<TrackingParticleCollection> (

         edm::InputTag("tpSelecForFakeRate"));

     hepMC_Token_ = consumes<edm::HepMCProduct>(edm::InputTag("generator"));

     genjets_Token_ = consumes<reco::GenJetCollection>(

         edm::InputTag("ak4GenJets"));


     trackAssociator_Token_ = consumes<reco::TrackToTrackingParticleAssociator>(edm::InputTag("trackAssociatorByHitsForConversionValidation"));

   }


 TkConvValidator::~TkConvValidator() {}


 void  TkConvValidator::bookHistograms( DQMStore::IBooker & iBooker, edm::Run const & run, edm::EventSetup const & es) {


   nEvt_=0;

   nEntry_=0;

   nRecConv_=0;

   nRecConvAss_=0;

   nRecConvAssWithEcal_=0;


   nInvalidPCA_=0;


   dbe_ = 0;

   dbe_ = edm::Service<DQMStore>().operator->();


   double etMin = parameters_.getParameter<double>("etMin");

   double etMax = parameters_.getParameter<double>("etMax");

   int etBin = parameters_.getParameter<int>("etBin");


   double resMin = parameters_.getParameter<double>("resMin");

   double resMax = parameters_.getParameter<double>("resMax");

   int resBin = parameters_.getParameter<int>("resBin");


   double etaMin = parameters_.getParameter<double>("etaMin");

   double etaMax = parameters_.getParameter<double>("etaMax");

   int etaBin = parameters_.getParameter<int>("etaBin");

   int etaBin2 = parameters_.getParameter<int>("etaBin2");


   double phiMin = parameters_.getParameter<double>("phiMin");

   double phiMax = parameters_.getParameter<double>("phiMax");

   int    phiBin = parameters_.getParameter<int>("phiBin");


   double rMin = parameters_.getParameter<double>("rMin");

   double rMax = parameters_.getParameter<double>("rMax");

   int    rBin = parameters_.getParameter<int>("rBin");


   double zMin = parameters_.getParameter<double>("zMin");

   double zMax = parameters_.getParameter<double>("zMax");

   int    zBin = parameters_.getParameter<int>("zBin");


   double dPhiTracksMin = parameters_.getParameter<double>("dPhiTracksMin");

   double dPhiTracksMax = parameters_.getParameter<double>("dPhiTracksMax");

   int dPhiTracksBin = parameters_.getParameter<int>("dPhiTracksBin");


   double eoverpMin = parameters_.getParameter<double>("eoverpMin");

   double eoverpMax = parameters_.getParameter<double>("eoverpMax");

   int    eoverpBin = parameters_.getParameter<int>("eoverpBin");


   //  double dEtaTracksMin = parameters_.getParameter<double>("dEtaTracksMin");  // unused

   //  double dEtaTracksMax = parameters_.getParameter<double>("dEtaTracksMax"); // unused

   //  int    dEtaTracksBin = parameters_.getParameter<int>("dEtaTracksBin");  // unused


   double dCotTracksMin = parameters_.getParameter<double>("dCotTracksMin");

   double dCotTracksMax = parameters_.getParameter<double>("dCotTracksMax");

   int    dCotTracksBin = parameters_.getParameter<int>("dCotTracksBin");


   double chi2Min = parameters_.getParameter<double>("chi2Min");

   double chi2Max = parameters_.getParameter<double>("chi2Max");


   double rMinForXray = parameters_.getParameter<double>("rMinForXray");

   double rMaxForXray = parameters_.getParameter<double>("rMaxForXray");

   int    rBinForXray = parameters_.getParameter<int>("rBinForXray");

   double zMinForXray = parameters_.getParameter<double>("zMinForXray");

   double zMaxForXray = parameters_.getParameter<double>("zMaxForXray");

   int    zBinForXray = parameters_.getParameter<int>("zBinForXray");

   int    zBin2ForXray = parameters_.getParameter<int>("zBin2ForXray");


   minPhoPtForEffic = parameters_.getParameter<double>("minPhoPtForEffic");

   maxPhoEtaForEffic = parameters_.getParameter<double>("maxPhoEtaForEffic");

   maxPhoZForEffic = parameters_.getParameter<double>("maxPhoZForEffic");

   maxPhoRForEffic = parameters_.getParameter<double>("maxPhoRForEffic");

   minPhoPtForPurity = parameters_.getParameter<double>("minPhoPtForPurity");

   maxPhoEtaForPurity = parameters_.getParameter<double>("maxPhoEtaForPurity");

   maxPhoZForPurity = parameters_.getParameter<double>("maxPhoZForPurity");

   maxPhoRForPurity = parameters_.getParameter<double>("maxPhoRForPurity");


   if (dbe_) {


     // SC from reco photons


     //TString simfolder = TString(

     std::string simpath = dqmpath_ + "SimulationInfo";

     iBooker.setCurrentFolder(simpath);

     //

     // simulation information about conversions

     std::string histname = "nOfSimConversions";

     h_nSimConv_[0] = iBooker.book1D(histname,"# of Sim conversions per event ",20,-0.5,19.5);

     histname = "h_AllSimConvEta";

     h_AllSimConv_[0] =  iBooker.book1D(histname," All conversions: simulated #eta",etaBin2,etaMin,etaMax);

     histname = "h_AllSimConvPhi";

     h_AllSimConv_[1] =  iBooker.book1D(histname," All conversions: simulated #phi",phiBin,phiMin,phiMax);

     histname = "h_AllSimConvR";

     h_AllSimConv_[2] =  iBooker.book1D(histname," All conversions: simulated R",rBin,rMin,rMax);

     histname = "h_AllSimConvZ";

     h_AllSimConv_[3] =  iBooker.book1D(histname," All conversions: simulated Z",zBin,zMin,zMax);

     histname = "h_AllSimConvEt";

     h_AllSimConv_[4] =  iBooker.book1D(histname," All conversions: simulated Et",etBin,etMin,etMax);

     //

     histname = "nOfVisSimConversions";

     h_nSimConv_[1] = iBooker.book1D(histname,"# of Sim conversions per event ",20,-0.5,19.5);

     histname = "h_VisSimConvEta";

     h_VisSimConv_[0] =  iBooker.book1D(histname," All vis conversions: simulated #eta",etaBin2,etaMin, etaMax);

     histname = "h_VisSimConvPhi";

     h_VisSimConv_[1] =  iBooker.book1D(histname," All vis conversions: simulated #phi",phiBin,phiMin, phiMax);

     histname = "h_VisSimConvR";

     h_VisSimConv_[2] =  iBooker.book1D(histname," All vis conversions: simulated R",rBin,rMin,rMax);

     histname = "h_VisSimConvZ";

     h_VisSimConv_[3] =  iBooker.book1D(histname," All vis conversions: simulated Z",zBin,zMin, zMax);

     histname = "h_VisSimConvEt";

     h_VisSimConv_[4] =  iBooker.book1D(histname," All vis conversions: simulated Et",etBin,etMin, etMax);


     //

     histname = "h_SimConvTwoMTracksEta";

     h_SimConvTwoMTracks_[0] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks: simulated #eta",etaBin2,etaMin, etaMax);

     histname = "h_SimConvTwoMTracksPhi";

     h_SimConvTwoMTracks_[1] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks: simulated #phi",phiBin,phiMin, phiMax);

     histname = "h_SimConvTwoMTracksR";

     h_SimConvTwoMTracks_[2] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks: simulated R",rBin,rMin, rMax);

     histname = "h_SimConvTwoMTracksZ";

     h_SimConvTwoMTracks_[3] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks: simulated Z",zBin,zMin, zMax);

     histname = "h_SimConvTwoMTracksEt";

     h_SimConvTwoMTracks_[4] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks: simulated Et",etBin,etMin, etMax);

     //

     histname = "h_SimConvTwoTracksEta";

     h_SimConvTwoTracks_[0] =  iBooker.book1D(histname," All vis conversions with 2 reco  tracks: simulated #eta",etaBin2,etaMin, etaMax);

     histname = "h_SimConvTwoTracksPhi";

     h_SimConvTwoTracks_[1] =  iBooker.book1D(histname," All vis conversions with 2 reco tracks: simulated #phi",phiBin,phiMin, phiMax);

     histname = "h_SimConvTwoTracksR";

     h_SimConvTwoTracks_[2] =  iBooker.book1D(histname," All vis conversions with 2 reco tracks: simulated R",rBin,rMin, rMax);

     histname = "h_SimConvTwoTracksZ";

     h_SimConvTwoTracks_[3] =  iBooker.book1D(histname," All vis conversions with 2 reco tracks: simulated Z",zBin,zMin, zMax);

     histname = "h_SimConvTwoTracksEt";

     h_SimConvTwoTracks_[4] =  iBooker.book1D(histname," All vis conversions with 2 reco tracks: simulated Et",etBin,etMin, etMax);

     //

     histname = "h_SimConvTwoMTracksEtaAndVtxPGT0";

     h_SimConvTwoMTracksAndVtxPGT0_[0] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks + vertex: simulated #eta",etaBin2,etaMin, etaMax);

     histname = "h_SimConvTwoMTracksPhiAndVtxPGT0";

     h_SimConvTwoMTracksAndVtxPGT0_[1] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks + vertex: simulated #phi",phiBin,phiMin, phiMax);

     histname = "h_SimConvTwoMTracksRAndVtxPGT0";

     h_SimConvTwoMTracksAndVtxPGT0_[2] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks + vertex: simulated R",rBin,rMin, rMax);

     histname = "h_SimConvTwoMTracksZAndVtxPGT0";

     h_SimConvTwoMTracksAndVtxPGT0_[3] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks + vertex: simulated Z",zBin,zMin, zMax);

     histname = "h_SimConvTwoMTracksEtAndVtxPGT0";

     h_SimConvTwoMTracksAndVtxPGT0_[4] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks + vertex: simulated Et",etBin,etMin, etMax);


     //

     histname = "h_SimConvTwoMTracksEtaAndVtxPGT0005";

     h_SimConvTwoMTracksAndVtxPGT0005_[0] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks + vertex: simulated #eta",etaBin2,etaMin, etaMax);

     histname = "h_SimConvTwoMTracksPhiAndVtxPGT0005";

     h_SimConvTwoMTracksAndVtxPGT0005_[1] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks + vertex: simulated #phi",phiBin,phiMin, phiMax);

     histname = "h_SimConvTwoMTracksRAndVtxPGT0005";

     h_SimConvTwoMTracksAndVtxPGT0005_[2] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks + vertex: simulated R",rBin,rMin, rMax);

     histname = "h_SimConvTwoMTracksZAndVtxPGT0005";

     h_SimConvTwoMTracksAndVtxPGT0005_[3] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks + vertex: simulated Z",zBin,zMin, zMax);

     histname = "h_SimConvTwoMTracksEtAndVtxPGT0005";

     h_SimConvTwoMTracksAndVtxPGT0005_[4] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks + vertex: simulated Et",etBin,etMin, etMax);


     histname = "h_SimRecConvTwoMTracksEta";

     h_SimRecConvTwoMTracks_[0] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks: simulated #eta",etaBin2,etaMin, etaMax);

     histname = "h_SimRecConvTwoMTracksPhi";

     h_SimRecConvTwoMTracks_[1] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks: simulated #phi",phiBin,phiMin, phiMax);

     histname = "h_SimRecConvTwoMTracksR";

     h_SimRecConvTwoMTracks_[2] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks: simulated R",rBin,rMin, rMax);

     histname = "h_SimRecConvTwoMTracksZ";

     h_SimRecConvTwoMTracks_[3] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks: simulated Z",zBin,zMin, zMax);

     histname = "h_SimRecConvTwoMTracksEt";

     h_SimRecConvTwoMTracks_[4] =  iBooker.book1D(histname," All vis conversions with 2 reco-matching tracks: simulated Et",etBin,etMin, etMax);

     //


     h_SimConvEtaPix_[0] = iBooker.book1D("simConvEtaPix"," sim converted Photon Eta: Pix ",etaBin,etaMin, etaMax) ;

     h_simTkPt_ = iBooker.book1D("simTkPt","Sim conversion tracks pt ",etBin*3,0.,etMax);

     h_simTkEta_ = iBooker.book1D("simTkEta","Sim conversion tracks eta ",etaBin,etaMin,etaMax);


     h_simConvVtxRvsZ_[0] =   iBooker.book2D("simConvVtxRvsZAll"," Photon Sim conversion vtx position",zBinForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);

     h_simConvVtxRvsZ_[1] =   iBooker.book2D("simConvVtxRvsZBarrel"," Photon Sim conversion vtx position",zBinForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);

     h_simConvVtxRvsZ_[2] =   iBooker.book2D("simConvVtxRvsZEndcap"," Photon Sim conversion vtx position",zBin2ForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);

     h_simConvVtxRvsZ_[3] =   iBooker.book2D("simConvVtxRvsZBarrel2"," Photon Sim conversion vtx position when reco R<4cm",zBinForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);

     h_simConvVtxYvsX_ =   iBooker.book2D("simConvVtxYvsXTrkBarrel"," Photon Sim conversion vtx position, (x,y) eta<1 ",100, -80., 80., 100, -80., 80.);


     std::string convpath = dqmpath_ + "ConversionInfo";

     iBooker.setCurrentFolder(convpath);


     histname="nConv";

     h_nConv_[0][0] = iBooker.book1D(histname+"All","Number Of Conversions per isolated candidates per events: All Ecal  ",10,-0.5, 9.5);

     h_nConv_[0][1] = iBooker.book1D(histname+"Barrel","Number Of Conversions per isolated candidates per events: Ecal Barrel  ",10,-0.5, 9.5);

     h_nConv_[0][2] = iBooker.book1D(histname+"Endcap","Number Of Conversions per isolated candidates per events: Ecal Endcap ",10,-0.5, 9.5);

     h_nConv_[1][0] = iBooker.book1D(histname+"All_Ass","Number Of associated Conversions per isolated candidates per events: All Ecal  ",10,-0.5, 9.5);


     h_convEta_[0][0] = iBooker.book1D("convEta"," converted Photon  Eta ",etaBin,etaMin, etaMax) ;

     h_convEtaMatchSC_[0][0] = iBooker.book1D("convEtaMatchSC"," converted Photon  Eta when SC is matched ",etaBin,etaMin, etaMax) ;

     h_convEta2_[0][0] = iBooker.book1D("convEta2"," converted Photon  Eta ",etaBin2,etaMin, etaMax) ;

     h_convPhi_[0][0] = iBooker.book1D("convPhi"," converted Photon  Phi ",phiBin,phiMin,phiMax) ;

     h_convR_[0][0]  =  iBooker.book1D("convR"," converted photon R",rBin,rMin, rMax);

     h_convZ_[0][0] =  iBooker.book1D("convZ"," converted photon Z",zBin,zMin, zMax);

     h_convPt_[0][0] = iBooker.book1D("convPt","  conversions Transverse Energy: all eta ", etBin,etMin, etMax);


     h_convEta_[1][0] = iBooker.book1D("convEtaAss2"," Matched converted Photon  Eta ",etaBin2,etaMin, etaMax) ;

     h_convEta_[1][1] = iBooker.book1D("convEtaAss"," Matched converted Photon  Eta ",etaBin,etaMin, etaMax) ;

     h_convEtaMatchSC_[1][0] = iBooker.book1D("convEtaMatchSCAss"," converted Photon  Eta when SC is matched ",etaBin,etaMin, etaMax) ;

     h_convPhi_[1][0] = iBooker.book1D("convPhiAss"," Matched converted Photon  Phi ",phiBin,phiMin,phiMax) ;

     h_convR_[1][0]  =  iBooker.book1D("convRAss"," Matched converted photon R",rBin,rMin, rMax);

     h_convZ_[1][0] =  iBooker.book1D("convZAss"," Matched converted photon Z",zBin,zMin, zMax);

     h_convPt_[1][0] = iBooker.book1D("convPtAss","Matched conversions Transverse Energy: all eta ", etBin,etMin, etMax);


     h_convEta_[2][0] = iBooker.book1D("convEtaFake2"," Fake converted Photon  Eta ",etaBin2,etaMin, etaMax) ;

     h_convEta_[2][1] = iBooker.book1D("convEtaFake"," Fake converted Photon  Eta ",etaBin,etaMin, etaMax) ;

     h_convEtaMatchSC_[2][0] = iBooker.book1D("convEtaMatchSCFake"," converted Photon  Eta when SC is matched ",etaBin,etaMin, etaMax) ;

     h_convPhi_[2][0] = iBooker.book1D("convPhiFake"," Fake converted Photon  Phi ",phiBin,phiMin,phiMax) ;

     h_convR_[2][0]  =  iBooker.book1D("convRFake"," Fake converted photon R",rBin,rMin, rMax);

     h_convZ_[2][0] =  iBooker.book1D("convZFake"," Fake converted photon Z",zBin,zMin, zMax);

     h_convPt_[2][0] = iBooker.book1D("convPtFake","Fake conversions Transverse Energy: all eta ", etBin,etMin, etMax);


     h_convRplot_  =  iBooker.book1D("convRplot"," converted photon R",600, 0.,120.);

     h_convZplot_  =  iBooker.book1D("convZplot"," converted photon Z",320,-160.,160.);


     histname = "convSCdPhi";

     h_convSCdPhi_[0][0] =   iBooker.book1D(histname+"All","dPhi between SC and conversion",100, -0.1,0.1);

     h_convSCdPhi_[0][1] =   iBooker.book1D(histname+"Barrel"," dPhi between SC and conversion: Barrel",100, -0.1,0.1);

     h_convSCdPhi_[0][2] =   iBooker.book1D(histname+"Endcap"," dPhi between SC and conversion: Endcap",100, -0.1,0.1);

     h_convSCdPhi_[1][0] =   iBooker.book1D(histname+"All_Ass","dPhi between SC and conversion",100, -0.1,0.1);

     h_convSCdPhi_[1][1] =   iBooker.book1D(histname+"Barrel_Ass"," dPhi between SC and conversion: Barrel",100, -0.1,0.1);

     h_convSCdPhi_[1][2] =   iBooker.book1D(histname+"Endcap_Ass"," dPhi between SC and conversion: Endcap",100, -0.1,0.1);

     h_convSCdPhi_[2][0] =   iBooker.book1D(histname+"All_Fakes","dPhi between SC and conversion",100, -0.1,0.1);

     h_convSCdPhi_[2][1] =   iBooker.book1D(histname+"Barrel_Fakes"," dPhi between SC and conversion: Barrel",100, -0.1,0.1);

     h_convSCdPhi_[2][2] =   iBooker.book1D(histname+"Endcap_Fakes"," dPhi between SC and conversion: Endcap",100, -0.1,0.1);

     histname = "convSCdEta";

     h_convSCdEta_[0][0] =   iBooker.book1D(histname+"All"," dEta between SC and conversion",100, -0.1,0.1);

     h_convSCdEta_[0][1] =   iBooker.book1D(histname+"Barrel"," dEta between SC and conversion: Barrel",100, -0.1,0.1);

     h_convSCdEta_[0][2] =   iBooker.book1D(histname+"Endcap"," dEta between SC and conversion: Endcap",100, -0.1,0.1);

     h_convSCdEta_[1][0] =   iBooker.book1D(histname+"All_Ass"," dEta between SC and conversion",100, -0.1,0.1);

     h_convSCdEta_[1][1] =   iBooker.book1D(histname+"Barrel_Ass"," dEta between SC and conversion: Barrel",100, -0.1,0.1);

     h_convSCdEta_[1][2] =   iBooker.book1D(histname+"Endcap_Ass"," dEta between SC and conversion: Endcap",100, -0.1,0.1);

     h_convSCdEta_[2][0] =   iBooker.book1D(histname+"All_Fakes"," dEta between SC and conversion",100, -0.1,0.1);

     h_convSCdEta_[2][1] =   iBooker.book1D(histname+"Barrel_Fakes"," dEta between SC and conversion: Barrel",100, -0.1,0.1);

     h_convSCdEta_[2][2] =   iBooker.book1D(histname+"Endcap_Fakes"," dEta between SC and conversion: Endcap",100, -0.1,0.1);


     histname = "convPtRes";

     h_convPtRes_[0] = iBooker.book1D(histname+"All"," Conversion Pt rec/true : All ecal ", resBin,resMin, resMax);

     h_convPtRes_[1] = iBooker.book1D(histname+"Barrel"," Conversion Pt rec/true : Barrel ",resBin,resMin, resMax);

     h_convPtRes_[2] = iBooker.book1D(histname+"Endcap"," Conversion Pt rec/true : Endcap ",resBin,resMin, resMax);


     histname="hInvMass";

     h_invMass_[0][0]= iBooker.book1D(histname+"All_AllTracks"," Photons:Tracks from conversion: Pair invariant mass: all Ecal ",100, 0., 1.5);

     h_invMass_[0][1]= iBooker.book1D(histname+"Barrel_AllTracks"," Photons:Tracks from conversion: Pair invariant mass: Barrel Ecal ",100, 0., 1.5);

     h_invMass_[0][2]= iBooker.book1D(histname+"Endcap_AllTracks"," Photons:Tracks from conversion: Pair invariant mass: Endcap Ecal ",100, 0., 1.5);

     //

     h_invMass_[1][0]= iBooker.book1D(histname+"All_AssTracks"," Photons:Tracks from conversion: Pair invariant mass: all Ecal ",100, 0., 1.5);

     h_invMass_[1][1]= iBooker.book1D(histname+"Barrel_AssTracks"," Photons:Tracks from conversion: Pair invariant mass: Barrel Ecal ",100, 0., 1.5);

     h_invMass_[1][2]= iBooker.book1D(histname+"Endcap_AssTracks"," Photons:Tracks from conversion: Pair invariant mass: Endcap Ecal ",100, 0., 1.5);

     //

     h_invMass_[2][0]= iBooker.book1D(histname+"All_FakeTracks"," Photons:Tracks from conversion: Pair invariant mass: all Ecal ",100, 0., 1.5);

     h_invMass_[2][1]= iBooker.book1D(histname+"Barrel_FakeTracks"," Photons:Tracks from conversion: Pair invariant mass: Barrel Ecal ",100, 0., 1.5);

     h_invMass_[2][2]= iBooker.book1D(histname+"Endcap_FaleTracks"," Photons:Tracks from conversion: Pair invariant mass: Endcap Ecal ",100, 0., 1.5);


     histname="hDPhiTracksAtVtx";

     h_DPhiTracksAtVtx_[0][0] =iBooker.book1D(histname+"All", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: all Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);

     h_DPhiTracksAtVtx_[0][1] =iBooker.book1D(histname+"Barrel", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: Barrel Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);

     h_DPhiTracksAtVtx_[0][2] =iBooker.book1D(histname+"Endcap", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: Endcap Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);

     h_DPhiTracksAtVtx_[1][0] =iBooker.book1D(histname+"All_Ass", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: all Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);

     h_DPhiTracksAtVtx_[1][1] =iBooker.book1D(histname+"Barrel_Ass", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: Barrel Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);

     h_DPhiTracksAtVtx_[1][2] =iBooker.book1D(histname+"Endcap_Ass", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: Endcap Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);

     h_DPhiTracksAtVtx_[2][0] =iBooker.book1D(histname+"All_Fakes", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: all Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);

     h_DPhiTracksAtVtx_[2][1] =iBooker.book1D(histname+"Barrel_Fakes", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: Barrel Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);

     h_DPhiTracksAtVtx_[2][2] =iBooker.book1D(histname+"Endcap_Fakes", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: Endcap Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);


     histname="hDPhiTracksAtVtxVsEta";

     h2_DPhiTracksAtVtxVsEta_ = iBooker.book2D(histname+"All","  Photons:Tracks from conversions: #delta#phi Tracks at vertex vs #eta",etaBin2,etaMin, etaMax,100, -0.5, 0.5);

     histname="pDPhiTracksAtVtxVsEta";

     p_DPhiTracksAtVtxVsEta_ = iBooker.bookProfile(histname+"All"," Photons:Tracks from conversions: #delta#phi Tracks at vertex vs #eta ",etaBin2,etaMin, etaMax, 100, -0.5, 0.5,"");


     histname="hDPhiTracksAtVtxVsR";

     h2_DPhiTracksAtVtxVsR_ = iBooker.book2D(histname+"All","  Photons:Tracks from conversions: #delta#phi Tracks at vertex vs R",rBin,rMin, rMax,100, -0.5, 0.5);

     histname="pDPhiTracksAtVtxVsR";

     p_DPhiTracksAtVtxVsR_ = iBooker.bookProfile(histname+"All"," Photons:Tracks from conversions: #delta#phi Tracks at vertex vs R ",rBin,rMin, rMax,100, -0.5, 0.5,"");


     histname="hDCotTracks";

     h_DCotTracks_[0][0]= iBooker.book1D(histname+"All"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: all Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);

     h_DCotTracks_[0][1]= iBooker.book1D(histname+"Barrel"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: Barrel Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);

     h_DCotTracks_[0][2]= iBooker.book1D(histname+"Endcap"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: Endcap Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);

     h_DCotTracks_[1][0]= iBooker.book1D(histname+"All_Ass"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: all Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);

     h_DCotTracks_[1][1]= iBooker.book1D(histname+"Barrel_Ass"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: Barrel Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);

     h_DCotTracks_[1][2]= iBooker.book1D(histname+"Endcap_Ass"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: Endcap Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);

     h_DCotTracks_[2][0]= iBooker.book1D(histname+"All_Fakes"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: all Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);

     h_DCotTracks_[2][1]= iBooker.book1D(histname+"Barrel_Fakes"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: Barrel Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);

     h_DCotTracks_[2][2]= iBooker.book1D(histname+"Endcap_Fakes"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: Endcap Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);


     histname="hDCotTracksVsEta";

     h2_DCotTracksVsEta_ = iBooker.book2D(histname+"All","  Photons:Tracks from conversions:  #delta cotg(#Theta) Tracks vs #eta",etaBin2,etaMin, etaMax,100, -0.2, 0.2);

     histname="pDCotTracksVsEta";

     p_DCotTracksVsEta_ = iBooker.bookProfile(histname+"All"," Photons:Tracks from conversions:  #delta cotg(#Theta) Tracks vs #eta ",etaBin2,etaMin, etaMax, 100, -0.2, 0.2,"");


     histname="hDCotTracksVsR";

     h2_DCotTracksVsR_ = iBooker.book2D(histname+"All","  Photons:Tracks from conversions:  #delta cotg(#Theta)  Tracks at vertex vs R",rBin,rMin, rMax,100, -0.2, 0.2);

     histname="pDCotTracksVsR";

     p_DCotTracksVsR_ = iBooker.bookProfile(histname+"All"," Photons:Tracks from conversions:  #delta cotg(#Theta) Tracks at vertex vs R ",rBin,rMin, rMax,100, -0.2, 0.2,"");


     histname="hDistMinAppTracks";

     h_distMinAppTracks_[0][0]= iBooker.book1D(histname+"All"," Photons:Tracks from conversions Min Approach Dist Tracks: all Ecal ",120, -0.5, 1.0);

     h_distMinAppTracks_[0][1]= iBooker.book1D(histname+"Barrel"," Photons:Tracks from conversions Min Approach Dist Tracks: Barrel Ecal ",120, -0.5, 1.0);

     h_distMinAppTracks_[0][2]= iBooker.book1D(histname+"Endcap"," Photons:Tracks from conversions Min Approach Dist Tracks: Endcap Ecal ",120, -0.5, 1.0);

     h_distMinAppTracks_[1][0]= iBooker.book1D(histname+"All_Ass"," Photons:Tracks from conversions Min Approach Dist Tracks: all Ecal ",120, -0.5, 1.0);

     h_distMinAppTracks_[1][1]= iBooker.book1D(histname+"Barrel_Ass"," Photons:Tracks from conversions Min Approach Dist Tracks: Barrel Ecal ",120, -0.5, 1.0);

     h_distMinAppTracks_[1][2]= iBooker.book1D(histname+"Endcap_Ass"," Photons:Tracks from conversions Min Approach Dist Tracks: Endcap Ecal ",120, -0.5, 1.0);

     h_distMinAppTracks_[2][0]= iBooker.book1D(histname+"All_Fakes"," Photons:Tracks from conversions Min Approach Dist Tracks: all Ecal ",120, -0.5, 1.0);

     h_distMinAppTracks_[2][1]= iBooker.book1D(histname+"Barrel_Fakes"," Photons:Tracks from conversions Min Approach Dist Tracks: Barrel Ecal ",120, -0.5, 1.0);

     h_distMinAppTracks_[2][2]= iBooker.book1D(histname+"Endcap_Fakes"," Photons:Tracks from conversions Min Approach Dist Tracks: Endcap Ecal ",120, -0.5, 1.0);


     h_convVtxRvsZ_[0] =   iBooker.book2D("convVtxRvsZAll"," Photon Reco conversion vtx position",zBinForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);

     h_convVtxRvsZ_[1] =   iBooker.book2D("convVtxRvsZBarrel"," Photon Reco conversion vtx position",zBinForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);

     h_convVtxRvsZ_[2] =   iBooker.book2D("convVtxRvsZEndcap"," Photon Reco conversion vtx position",zBin2ForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);

     h_convVtxYvsX_ =   iBooker.book2D("convVtxYvsXTrkBarrel"," Photon Reco conversion vtx position, (x,y) eta<1 ", 1000, -60., 60., 1000, -60., 60.);

     h_convVtxRvsZ_zoom_[0] =  iBooker.book2D("convVtxRvsZBarrelZoom1"," Photon Reco conversion vtx position",zBinForXray, zMinForXray, zMaxForXray, rBinForXray, -10., 40.);

     h_convVtxRvsZ_zoom_[1] =  iBooker.book2D("convVtxRvsZBarrelZoom2"," Photon Reco conversion vtx position",zBinForXray, zMinForXray, zMaxForXray, rBinForXray, -10., 20.);

     h_convVtxYvsX_zoom_[0] =   iBooker.book2D("convVtxYvsXTrkBarrelZoom1"," Photon Reco conversion vtx position, (x,y) eta<1 ",100, -40., 40., 100, -40., 40.);

     h_convVtxYvsX_zoom_[1] =   iBooker.book2D("convVtxYvsXTrkBarrelZoom2"," Photon Reco conversion vtx position, (x,y) eta<1 ",100, -20., 20., 100, -20., 20.);


     h_convVtxdR_ =   iBooker.book1D("convVtxdR"," Photon Reco conversion vtx dR",100, -10.,10.);

     h_convVtxdX_ =   iBooker.book1D("convVtxdX"," Photon Reco conversion vtx dX",100, -10.,10.);

     h_convVtxdY_ =   iBooker.book1D("convVtxdY"," Photon Reco conversion vtx dY",100, -10.,10.);

     h_convVtxdZ_ =   iBooker.book1D("convVtxdZ"," Photon Reco conversion vtx dZ",100, -20.,20.);


     h_convVtxdPhi_ =   iBooker.book1D("convVtxdPhi"," Photon Reco conversion vtx dPhi",100, -0.01,0.01);

     h_convVtxdEta_ =   iBooker.book1D("convVtxdEta"," Photon Reco conversion vtx dEta",100, -0.5,0.5);


     h_convVtxdR_barrel_ =   iBooker.book1D("convVtxdR_barrel"," Photon Reco conversion vtx dR, |eta|<=1.2",100, -10.,10.);

     h_convVtxdX_barrel_ =   iBooker.book1D("convVtxdX_barrel"," Photon Reco conversion vtx dX, |eta|<=1.2",100, -10.,10.);

     h_convVtxdY_barrel_ =   iBooker.book1D("convVtxdY_barrel"," Photon Reco conversion vtx dY, |eta|<=1.2 ",100, -10.,10.);

     h_convVtxdZ_barrel_ =   iBooker.book1D("convVtxdZ_barrel"," Photon Reco conversion vtx dZ, |eta|<=1.2,",100, -20.,20.);


     h_convVtxdR_endcap_ =   iBooker.book1D("convVtxdR_endcap"," Photon Reco conversion vtx dR,  |eta|>1.2 ",100, -10.,10.);

     h_convVtxdX_endcap_ =   iBooker.book1D("convVtxdX_endcap"," Photon Reco conversion vtx dX,  |eta|>1.2",100, -10.,10.);

     h_convVtxdY_endcap_ =   iBooker.book1D("convVtxdY_endcap"," Photon Reco conversion vtx dY,  |eta|>1.2",100, -10.,10.);

     h_convVtxdZ_endcap_ =   iBooker.book1D("convVtxdZ_endcap"," Photon Reco conversion vtx dZ,  |eta|>1.2",100, -20.,20.);


     h2_convVtxdRVsR_ =  iBooker.book2D("h2ConvVtxdRVsR"," Conversion vtx dR vsR" ,rBin,rMin, rMax,100, -20.,20.);

     h2_convVtxdRVsEta_ =  iBooker.book2D("h2ConvVtxdRVsEta","Conversion vtx dR vs Eta" ,etaBin2,etaMin, etaMax,100, -20.,20.);


     p_convVtxdRVsR_ =  iBooker.bookProfile("pConvVtxdRVsR"," Conversion vtx dR vsR" ,rBin,rMin, rMax ,100, -20.,20., "");

     p_convVtxdRVsEta_ =  iBooker.bookProfile("pConvVtxdRVsEta","Conversion vtx dR vs Eta" ,etaBin2,etaMin, etaMax, 100, -20.,20., "");

     p_convVtxdXVsX_ =  iBooker.bookProfile("pConvVtxdXVsX","Conversion vtx dX vs X" ,120,-60, 60 ,100, -20.,20., "");

     p_convVtxdYVsY_ =  iBooker.bookProfile("pConvVtxdYVsY","Conversion vtx dY vs Y" ,120,-60, 60 ,100, -20.,20., "");

     p_convVtxdZVsZ_ =  iBooker.bookProfile("pConvVtxdZVsZ","Conversion vtx dZ vs Z" ,zBin,zMin,zMax ,100, -20.,20., "");


     p_convVtxdZVsR_ =  iBooker.bookProfile("pConvVtxdZVsR","Conversion vtx dZ vs R" ,rBin,rMin,rMax ,100, -20.,20., "");

     p2_convVtxdRVsRZ_ =  iBooker.bookProfile2D("p2ConvVtxdRVsRZ","Conversion vtx dR vs RZ" ,zBin,zMin, zMax,rBin,rMin,rMax,100, 0.,20.,"s");

     p2_convVtxdZVsRZ_ =  iBooker.bookProfile2D("p2ConvVtxdZVsRZ","Conversion vtx dZ vs RZ" ,zBin,zMin, zMax,rBin,rMin,rMax,100, 0.,20.,"s");


     histname="EoverPtracks";

     h_EoverPTracks_[0][0] = iBooker.book1D(histname+"All"," photons conversion E/p: all Ecal ",       eoverpBin, eoverpMin, eoverpMax );

     h_EoverPTracks_[0][1] = iBooker.book1D(histname+"Barrel"," photons conversion E/p: Barrel Ecal",  eoverpBin, eoverpMin,  eoverpMax);

     h_EoverPTracks_[0][2] = iBooker.book1D(histname+"Endcap"," photons conversion E/p: Endcap Ecal ", eoverpBin, eoverpMin,  eoverpMax);

     h_EoverPTracks_[1][0] = iBooker.book1D(histname+"All_Ass"," photons conversion E/p: all Ecal ",   eoverpBin, eoverpMin,  eoverpMax);

     h_EoverPTracks_[1][1] = iBooker.book1D(histname+"Barrel_Ass"," photons conversion E/p: Barrel Ecal", eoverpBin, eoverpMin,  eoverpMax);

     h_EoverPTracks_[1][2] = iBooker.book1D(histname+"Endcap_Ass"," photons conversion E/p: Endcap Ecal ", eoverpBin, eoverpMin,  eoverpMax);

     h_EoverPTracks_[2][0] = iBooker.book1D(histname+"All_Fakes"," photons conversion E/p: all Ecal ",     eoverpBin, eoverpMin,  eoverpMax);

     h_EoverPTracks_[2][1] = iBooker.book1D(histname+"Barrel_Fakes"," photons conversion E/p: Barrel Ecal", eoverpBin, eoverpMin,  eoverpMax);

     h_EoverPTracks_[2][2] = iBooker.book1D(histname+"Endcap_Fakes"," photons conversion E/p: Endcap Ecal ", eoverpBin, eoverpMin,  eoverpMax);


     h2_convVtxRrecVsTrue_ =  iBooker.book2D("h2ConvVtxRrecVsTrue","Photon Reco conversion vtx R rec vs true" ,rBin,rMin, rMax,rBin,rMin, rMax);


     histname="vtxChi2Prob";

     h_vtxChi2Prob_[0][0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 100, 0., 1.);

     h_vtxChi2Prob_[0][1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 100, 0., 1.);

     h_vtxChi2Prob_[0][2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 100, 0., 1.);

     h_vtxChi2Prob_[1][0] = iBooker.book1D(histname+"All_Ass","vertex #chi^{2} all", 100, 0., 1.);

     h_vtxChi2Prob_[1][1] = iBooker.book1D(histname+"Barrel_Ass","vertex #chi^{2} barrel", 100, 0., 1.);

     h_vtxChi2Prob_[1][2] = iBooker.book1D(histname+"Endcap_Ass","vertex #chi^{2} endcap", 100, 0., 1.);

     h_vtxChi2Prob_[2][0] = iBooker.book1D(histname+"All_Fakes","vertex #chi^{2} all", 100, 0., 1.);

     h_vtxChi2Prob_[2][1] = iBooker.book1D(histname+"Barrel_Fakes","vertex #chi^{2} barrel", 100, 0., 1.);

     h_vtxChi2Prob_[2][2] = iBooker.book1D(histname+"Endcap_Fakes","vertex #chi^{2} endcap", 100, 0., 1.);


     h_zPVFromTracks_[1] =  iBooker.book1D("zPVFromTracks"," Photons: PV z from conversion tracks",100, -25., 25.);

     h_dzPVFromTracks_[1] =  iBooker.book1D("dzPVFromTracks"," Photons: PV Z_rec - Z_true from conversion tracks",100, -5., 5.);

     h2_dzPVVsR_ =  iBooker.book2D("h2dzPVVsR","Photon Reco conversions: dz(PV) vs R" ,rBin,rMin, rMax,100, -3.,3.);

     p_dzPVVsR_ =  iBooker.bookProfile("pdzPVVsR","Photon Reco conversions: dz(PV) vs R" ,rBin,rMin, rMax, 100, -3.,3.,"");


     histname="lxybs";

     h_lxybs_[0][0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 200, -100., 100.);

     h_lxybs_[0][1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 200, -100., 100.);

     h_lxybs_[0][2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 200, -100., 100.);

     h_lxybs_[1][0] = iBooker.book1D(histname+"All_Ass","vertex #chi^{2} all", 200, -100., 100.);

     h_lxybs_[1][1] = iBooker.book1D(histname+"Barrel_Ass","vertex #chi^{2} barrel", 200, -100., 100.);

     h_lxybs_[1][2] = iBooker.book1D(histname+"Endcap_Ass","vertex #chi^{2} endcap", 200, -100., 100.);

     h_lxybs_[2][0] = iBooker.book1D(histname+"All_Fakes","vertex #chi^{2} all", 200, -100., 100.);

     h_lxybs_[2][1] = iBooker.book1D(histname+"Barrel_Fakes","vertex #chi^{2} barrel", 200, -100., 100.);

     h_lxybs_[2][2] = iBooker.book1D(histname+"Endcap_Fakes","vertex #chi^{2} endcap", 200, -100., 100.);


     histname="maxNHitsBeforeVtx";

     h_maxNHitsBeforeVtx_[0][0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_maxNHitsBeforeVtx_[0][1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_maxNHitsBeforeVtx_[0][2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_maxNHitsBeforeVtx_[1][0] = iBooker.book1D(histname+"All_Ass","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_maxNHitsBeforeVtx_[1][1] = iBooker.book1D(histname+"Barrel_Ass","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_maxNHitsBeforeVtx_[1][2] = iBooker.book1D(histname+"Endcap_Ass","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_maxNHitsBeforeVtx_[2][0] = iBooker.book1D(histname+"All_Fakes","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_maxNHitsBeforeVtx_[2][1] = iBooker.book1D(histname+"Barrel_Fakes","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_maxNHitsBeforeVtx_[2][2] = iBooker.book1D(histname+"Endcap_Fakes","vertex #chi^{2} endcap", 16, -0.5, 15.5);


     histname="leadNHitsBeforeVtx";

     h_leadNHitsBeforeVtx_[0][0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_leadNHitsBeforeVtx_[0][1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_leadNHitsBeforeVtx_[0][2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_leadNHitsBeforeVtx_[1][0] = iBooker.book1D(histname+"All_Ass","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_leadNHitsBeforeVtx_[1][1] = iBooker.book1D(histname+"Barrel_Ass","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_leadNHitsBeforeVtx_[1][2] = iBooker.book1D(histname+"Endcap_Ass","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_leadNHitsBeforeVtx_[2][0] = iBooker.book1D(histname+"All_Fakes","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_leadNHitsBeforeVtx_[2][1] = iBooker.book1D(histname+"Barrel_Fakes","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_leadNHitsBeforeVtx_[2][2] = iBooker.book1D(histname+"Endcap_Fakes","vertex #chi^{2} endcap", 16, -0.5, 15.5);


     histname="trailNHitsBeforeVtx";

     h_trailNHitsBeforeVtx_[0][0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_trailNHitsBeforeVtx_[0][1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_trailNHitsBeforeVtx_[0][2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_trailNHitsBeforeVtx_[1][0] = iBooker.book1D(histname+"All_Ass","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_trailNHitsBeforeVtx_[1][1] = iBooker.book1D(histname+"Barrel_Ass","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_trailNHitsBeforeVtx_[1][2] = iBooker.book1D(histname+"Endcap_Ass","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_trailNHitsBeforeVtx_[2][0] = iBooker.book1D(histname+"All_Fakes","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_trailNHitsBeforeVtx_[2][1] = iBooker.book1D(histname+"Barrel_Fakes","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_trailNHitsBeforeVtx_[2][2] = iBooker.book1D(histname+"Endcap_Fakes","vertex #chi^{2} endcap", 16, -0.5, 15.5);


     histname="sumNHitsBeforeVtx";

     h_sumNHitsBeforeVtx_[0][0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_sumNHitsBeforeVtx_[0][1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_sumNHitsBeforeVtx_[0][2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_sumNHitsBeforeVtx_[1][0] = iBooker.book1D(histname+"All_Ass","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_sumNHitsBeforeVtx_[1][1] = iBooker.book1D(histname+"Barrel_Ass","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_sumNHitsBeforeVtx_[1][2] = iBooker.book1D(histname+"Endcap_Ass","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_sumNHitsBeforeVtx_[2][0] = iBooker.book1D(histname+"All_Fakes","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_sumNHitsBeforeVtx_[2][1] = iBooker.book1D(histname+"Barrel_Fakes","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_sumNHitsBeforeVtx_[2][2] = iBooker.book1D(histname+"Endcap_Fakes","vertex #chi^{2} endcap", 16, -0.5, 15.5);


     histname="maxDlClosestHitToVtx";

     h_maxDlClosestHitToVtx_[0][0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 100, -10., 10.);

     h_maxDlClosestHitToVtx_[0][1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 100, -10., 10.);

     h_maxDlClosestHitToVtx_[0][2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 100, -10., 10.);

     h_maxDlClosestHitToVtx_[1][0] = iBooker.book1D(histname+"All_Ass","vertex #chi^{2} all", 100, -10., 10.);

     h_maxDlClosestHitToVtx_[1][1] = iBooker.book1D(histname+"Barrel_Ass","vertex #chi^{2} barrel", 100, -10., 10.);

     h_maxDlClosestHitToVtx_[1][2] = iBooker.book1D(histname+"Endcap_Ass","vertex #chi^{2} endcap", 100, -10., 10.);

     h_maxDlClosestHitToVtx_[2][0] = iBooker.book1D(histname+"All_Fakes","vertex #chi^{2} all", 100, -10., 10.);

     h_maxDlClosestHitToVtx_[2][1] = iBooker.book1D(histname+"Barrel_Fakes","vertex #chi^{2} barrel", 100, -10., 10.);

     h_maxDlClosestHitToVtx_[2][2] = iBooker.book1D(histname+"Endcap_Fakes","vertex #chi^{2} endcap", 100, -10., 10.);


     histname="maxDlClosestHitToVtxSig";

     h_maxDlClosestHitToVtxSig_[0][0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 100, -8., 8.);

     h_maxDlClosestHitToVtxSig_[0][1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 100, -8., 8.);

     h_maxDlClosestHitToVtxSig_[0][2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 100, -8., 8.);

     h_maxDlClosestHitToVtxSig_[1][0] = iBooker.book1D(histname+"All_Ass","vertex #chi^{2} all", 100, -8., 8.);

     h_maxDlClosestHitToVtxSig_[1][1] = iBooker.book1D(histname+"Barrel_Ass","vertex #chi^{2} barrel", 100, -8., 8.);

     h_maxDlClosestHitToVtxSig_[1][2] = iBooker.book1D(histname+"Endcap_Ass","vertex #chi^{2} endcap", 100, -8., 8.);

     h_maxDlClosestHitToVtxSig_[2][0] = iBooker.book1D(histname+"All_Fakes","vertex #chi^{2} all", 100, -8., 8.);

     h_maxDlClosestHitToVtxSig_[2][1] = iBooker.book1D(histname+"Barrel_Fakes","vertex #chi^{2} barrel", 100, -8., 8.);

     h_maxDlClosestHitToVtxSig_[2][2] = iBooker.book1D(histname+"Endcap_Fakes","vertex #chi^{2} endcap", 100, -8., 8.);


     histname="deltaExpectedHitsInner";

     h_deltaExpectedHitsInner_[0][0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 31, -15.5, 15.5);

     h_deltaExpectedHitsInner_[0][1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 31, -15.5, 15.5);

     h_deltaExpectedHitsInner_[0][2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 31, -15.5, 15.5);

     h_deltaExpectedHitsInner_[1][0] = iBooker.book1D(histname+"All_Ass","vertex #chi^{2} all", 31, -15.5, 15.5);

     h_deltaExpectedHitsInner_[1][1] = iBooker.book1D(histname+"Barrel_Ass","vertex #chi^{2} barrel", 31, -15.5, 15.5);

     h_deltaExpectedHitsInner_[1][2] = iBooker.book1D(histname+"Endcap_Ass","vertex #chi^{2} endcap", 31, -15.5, 15.5);

     h_deltaExpectedHitsInner_[2][0] = iBooker.book1D(histname+"All_Fakes","vertex #chi^{2} all", 31, -15.5, 15.5);

     h_deltaExpectedHitsInner_[2][1] = iBooker.book1D(histname+"Barrel_Fakes","vertex #chi^{2} barrel", 31, -15.5, 15.5);

     h_deltaExpectedHitsInner_[2][2] = iBooker.book1D(histname+"Endcap_Fakes","vertex #chi^{2} endcap", 31, -15.5, 15.5);


     histname="leadExpectedHitsInner";

     h_leadExpectedHitsInner_[0][0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_leadExpectedHitsInner_[0][1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_leadExpectedHitsInner_[0][2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_leadExpectedHitsInner_[1][0] = iBooker.book1D(histname+"All_Ass","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_leadExpectedHitsInner_[1][1] = iBooker.book1D(histname+"Barrel_Ass","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_leadExpectedHitsInner_[1][2] = iBooker.book1D(histname+"Endcap_Ass","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_leadExpectedHitsInner_[2][0] = iBooker.book1D(histname+"All_Fakes","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_leadExpectedHitsInner_[2][1] = iBooker.book1D(histname+"Barrel_Fakes","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_leadExpectedHitsInner_[2][2] = iBooker.book1D(histname+"Endcap_Fakes","vertex #chi^{2} endcap", 16, -0.5, 15.5);


     histname="nSharedHits";

     h_nSharedHits_[0][0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_nSharedHits_[0][1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_nSharedHits_[0][2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_nSharedHits_[1][0] = iBooker.book1D(histname+"All_Ass","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_nSharedHits_[1][1] = iBooker.book1D(histname+"Barrel_Ass","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_nSharedHits_[1][2] = iBooker.book1D(histname+"Endcap_Ass","vertex #chi^{2} endcap", 16, -0.5, 15.5);

     h_nSharedHits_[2][0] = iBooker.book1D(histname+"All_Fakes","vertex #chi^{2} all", 16, -0.5, 15.5);

     h_nSharedHits_[2][1] = iBooker.book1D(histname+"Barrel_Fakes","vertex #chi^{2} barrel", 16, -0.5, 15.5);

     h_nSharedHits_[2][2] = iBooker.book1D(histname+"Endcap_Fakes","vertex #chi^{2} endcap", 16, -0.5, 15.5);


     histname="nHits";

     nHits_[0] =  iBooker.book2D(histname+"AllTracks","Photons:Tracks from conversions: # of hits all tracks",etaBin,etaMin, etaMax,30,0., 30.);

     nHits_[1] =  iBooker.book2D(histname+"AllTracks_Ass","Photons:Tracks from conversions: # of hits  all tracks ass",etaBin,etaMin, etaMax,30,0., 30.);

     nHits_[2] =  iBooker.book2D(histname+"AllTracks_Fakes","Photons:Tracks from conversions: # of hits all tracks fakes",etaBin,etaMin, etaMax,30,0., 30.);


     histname="nHitsVsEta";

     nHitsVsEta_[0] =  iBooker.book2D(histname+"AllTracks","Photons:Tracks from conversions: # of hits vs #eta all tracks",etaBin,etaMin, etaMax,30,0., 30.);

     nHitsVsEta_[1] =  iBooker.book2D(histname+"AllTracks_Ass","Photons:Tracks from conversions: # of hits vs #eta all tracks",etaBin,etaMin, etaMax,30,0., 30.);

     nHitsVsEta_[2] =  iBooker.book2D(histname+"AllTracks_Fakes","Photons:Tracks from conversions: # of hits vs #eta all tracks",etaBin,etaMin, etaMax,30,0., 30.);

     histname="h_nHitsVsEta";

     p_nHitsVsEta_[0] =  iBooker.bookProfile(histname+"AllTracks","Photons:Tracks from conversions: # of hits vs #eta all tracks",etaBin,etaMin, etaMax, 30,-0.5, 29.5,"");

     p_nHitsVsEta_[1] =  iBooker.bookProfile(histname+"AllTracks_Ass","Photons:Tracks from conversions: # of hits vs #eta all tracks",etaBin,etaMin, etaMax, 30,-0.5, 29.5,"");

     p_nHitsVsEta_[2] =  iBooker.bookProfile(histname+"AllTracks_Fakes","Photons:Tracks from conversions: # of hits vs #eta all tracks",etaBin,etaMin, etaMax, 30,-0.5, 29.5,"");


     histname="nHitsVsR";

     nHitsVsR_[0] =  iBooker.book2D(histname+"AllTracks","Photons:Tracks from conversions: # of hits vs radius all tracks" ,rBin,rMin, rMax,30,0., 30.);

     nHitsVsR_[1] =  iBooker.book2D(histname+"AllTracks_Ass","Photons:Tracks from conversions: # of hits vs radius all tracks" ,rBin,rMin, rMax,30,0., 30.);

     nHitsVsR_[2] =  iBooker.book2D(histname+"AllTracks_Fakes","Photons:Tracks from conversions: # of hits vs radius all tracks" ,rBin,rMin, rMax,30,0., 30.);


     histname="h_nHitsVsR";

     p_nHitsVsR_[0] =  iBooker.bookProfile(histname+"AllTracks","Photons:Tracks from conversions: # of hits vs radius all tracks",rBin,rMin, rMax, 30,-0.5, 29.5,"");

     p_nHitsVsR_[1] =  iBooker.bookProfile(histname+"AllTracks_Ass","Photons:Tracks from conversions: # of hits vs radius all tracks",rBin,rMin, rMax, 30,-0.5, 29.5,"");

     p_nHitsVsR_[2] =  iBooker.bookProfile(histname+"AllTracks_Fakes","Photons:Tracks from conversions: # of hits vs radius all tracks",rBin,rMin, rMax, 30,-0.5, 29.5,"");


     histname="tkChi2";

     h_tkChi2_[0] = iBooker.book1D(histname+"AllTracks","Photons:Tracks from conversions: #chi^{2} of all tracks", 100, chi2Min, chi2Max);

     h_tkChi2_[1] = iBooker.book1D(histname+"AllTracks_Ass","Photons:Tracks from conversions: #chi^{2} of all tracks", 100, chi2Min, chi2Max);

     h_tkChi2_[2] = iBooker.book1D(histname+"AllTracks_Fakes","Photons:Tracks from conversions: #chi^{2} of all tracks", 100, chi2Min, chi2Max);


     histname="tkChi2Large";

     h_tkChi2Large_[0] = iBooker.book1D(histname+"AllTracks","Photons:Tracks from conversions: #chi^{2} of all tracks", 1000, 0., 5000.0);

     h_tkChi2Large_[1] = iBooker.book1D(histname+"AllTracks_Ass","Photons:Tracks from conversions: #chi^{2} of all tracks", 1000, 0., 5000.0);

     h_tkChi2Large_[2] = iBooker.book1D(histname+"AllTracks_Fakes","Photons:Tracks from conversions: #chi^{2} of all tracks", 1000, 0., 5000.0);


     histname="h2Chi2VsEta";

     h2_Chi2VsEta_[0]=iBooker.book2D(histname+"All"," Reco Track  #chi^{2} vs #eta: All ",etaBin2,etaMin, etaMax,100, chi2Min, chi2Max);

     h2_Chi2VsEta_[1]=iBooker.book2D(histname+"All_Ass"," Reco Track  #chi^{2} vs #eta: All ",etaBin2,etaMin, etaMax,100, chi2Min, chi2Max);

     h2_Chi2VsEta_[2]=iBooker.book2D(histname+"All_Fakes"," Reco Track  #chi^{2} vs #eta: All ",etaBin2,etaMin, etaMax,100, chi2Min, chi2Max);

     histname="pChi2VsEta";

     p_Chi2VsEta_[0]=iBooker.bookProfile(histname+"All"," Reco Track #chi^{2} vs #eta : All ",etaBin2,etaMin, etaMax, 100, chi2Min, chi2Max,"");

     p_Chi2VsEta_[1]=iBooker.bookProfile(histname+"All_Ass"," Reco Track #chi^{2} vs #eta : All ",etaBin2,etaMin, etaMax, 100, chi2Min, chi2Max,"");

     p_Chi2VsEta_[2]=iBooker.bookProfile(histname+"All_Fakes"," Reco Track #chi^{2} vs #eta : All ",etaBin2,etaMin, etaMax, 100, chi2Min, chi2Max,"");


     histname="h2Chi2VsR";

     h2_Chi2VsR_[0]=iBooker.book2D(histname+"All"," Reco Track  #chi^{2} vs R: All ",rBin,rMin, rMax,100,chi2Min, chi2Max);

     h2_Chi2VsR_[1]=iBooker.book2D(histname+"All_Ass"," Reco Track  #chi^{2} vs R: All ",rBin,rMin, rMax,100,chi2Min, chi2Max);

     h2_Chi2VsR_[2]=iBooker.book2D(histname+"All_Fakes"," Reco Track  #chi^{2} vs R: All ",rBin,rMin, rMax,100,chi2Min, chi2Max);

     histname="pChi2VsR";

     p_Chi2VsR_[0]=iBooker.bookProfile(histname+"All"," Reco Track #chi^{2} vas R : All ",rBin,rMin,rMax, 100,chi2Min, chi2Max,"");

     p_Chi2VsR_[1]=iBooker.bookProfile(histname+"All_Ass"," Reco Track #chi^{2} vas R : All ",rBin,rMin,rMax, 100,chi2Min, chi2Max,"");

     p_Chi2VsR_[2]=iBooker.bookProfile(histname+"All_Fakes"," Reco Track #chi^{2} vas R : All ",rBin,rMin,rMax, 100,chi2Min, chi2Max,"");


     histname="hTkD0";

     h_TkD0_[0]=iBooker.book1D(histname+"All"," Reco Track D0*q: All ",200,-0.1,60);

     h_TkD0_[1]=iBooker.book1D(histname+"All_Ass"," Reco Track D0*q: Barrel ",200,-0.1,60);

     h_TkD0_[2]=iBooker.book1D(histname+"All_Fakes"," Reco Track D0*q: Endcap ",200,-0.1,60);


     histname="hTkPtPull";

     h_TkPtPull_[0]=iBooker.book1D(histname+"All"," Reco Track Pt pull: All ",100, -20., 10.);

     histname="hTkPtPull";

     h_TkPtPull_[1]=iBooker.book1D(histname+"Barrel"," Reco Track Pt pull: Barrel ",100, -20., 10.);

     histname="hTkPtPull";

     h_TkPtPull_[2]=iBooker.book1D(histname+"Endcap"," Reco Track Pt pull: Endcap ",100, -20., 10.);


     histname="h2TkPtPullEta";

     h2_TkPtPull_[0]=iBooker.book2D(histname+"All"," Reco Track Pt pull: All ",etaBin2,etaMin, etaMax,100, -20., 10.);

     histname="pTkPtPullEta";

     p_TkPtPull_[0]=iBooker.bookProfile(histname+"All"," Reco Track Pt pull: All ",etaBin2,etaMin, etaMax, 100, -20., 10., " ");


     histname="PtRecVsPtSim";

     h2_PtRecVsPtSim_[0]=iBooker.book2D(histname+"All", "Pt Rec vs Pt sim: All ", etBin,etMin,etMax,etBin,etMin, etMax);

     h2_PtRecVsPtSim_[1]=iBooker.book2D(histname+"Barrel", "Pt Rec vs Pt sim: Barrel ", etBin,etMin,etMax,etBin,etMin, etMax);

     h2_PtRecVsPtSim_[2]=iBooker.book2D(histname+"Endcap", "Pt Rec vs Pt sim: Endcap ", etBin,etMin,etMax,etBin,etMin, etMax);


     histname="photonPtRecVsPtSim";

     h2_photonPtRecVsPtSim_=iBooker.book2D(histname+"All", "Pt Rec vs Pt sim: All ", etBin,etMin,etMax,etBin,etMin, etMax);


     histname="nHitsBeforeVtx";

     h_nHitsBeforeVtx_[0]=iBooker.book1D(histname+"All", "Pt Rec vs Pt sim: All ", 16, -0.5, 15.5);

     h_nHitsBeforeVtx_[1]=iBooker.book1D(histname+"Barrel", "Pt Rec vs Pt sim: Barrel ", 16, -0.5, 15.5);

     h_nHitsBeforeVtx_[2]=iBooker.book1D(histname+"Endcap", "Pt Rec vs Pt sim: Endcap ", 16, -0.5, 15.5);


     histname="dlClosestHitToVtx";

     h_dlClosestHitToVtx_[0]=iBooker.book1D(histname+"All", "Pt Rec vs Pt sim: All ", 100, -10., 10.);

     h_dlClosestHitToVtx_[1]=iBooker.book1D(histname+"Barrel", "Pt Rec vs Pt sim: Barrel ", 100, -10., 10.);

     h_dlClosestHitToVtx_[2]=iBooker.book1D(histname+"Endcap", "Pt Rec vs Pt sim: Endcap ", 100, -10., 10.);


     histname="dlClosestHitToVtxSig";

     h_dlClosestHitToVtxSig_[0]=iBooker.book1D(histname+"All", "Pt Rec vs Pt sim: All ", 100, -8., 8.);

     h_dlClosestHitToVtxSig_[1]=iBooker.book1D(histname+"Barrel", "Pt Rec vs Pt sim: Barrel ", 100, -8., 8.);

     h_dlClosestHitToVtxSig_[2]=iBooker.book1D(histname+"Endcap", "Pt Rec vs Pt sim: Endcap ", 100, -8., 8.);


     h_match_= iBooker.book1D("h_match"," ", 3, -0.5,2.5);


    } // if DQM


 }


  void  TkConvValidator::dqmBeginRun (edm::Run const & r, edm::EventSetup const & theEventSetup) {


    //get magnetic field

   edm::LogInfo("ConvertedPhotonProducer") << " get magnetic field" << "\n";

   theEventSetup.get<IdealMagneticFieldRecord>().get(theMF_);


   thePhotonMCTruthFinder_ = new PhotonMCTruthFinder();


 }


 void  TkConvValidator::endRun (edm::Run& r, edm::EventSetup const & theEventSetup) {


   delete thePhotonMCTruthFinder_;


 }


 void TkConvValidator::analyze( const edm::Event& e, const edm::EventSetup& esup ) {

   thePhotonMCTruthFinder_->clear();

   using namespace edm;

   //  const float etaPhiDistance=0.01;

   // Fiducial region

   // const float TRK_BARL =0.9;

   const float BARL = 1.4442; // DAQ TDR p.290

   //  const float END_LO = 1.566; // unused

   const float END_HI = 2.5;

   // Electron mass

   //  const Float_t mElec= 0.000511; // unused


   Handle<reco::TrackToTrackingParticleAssociator> theTrackAssociator;

   e.getByToken(trackAssociator_Token_,theTrackAssociator);


   nEvt_++;

   LogInfo("TkConvValidator") << "TkConvValidator Analyzing event number: " << e.id() << " Global Counter " << nEvt_ <<"\n";

   //  std::cout << "TkConvValidator Analyzing event number: "  << e.id() << " Global Counter " << nEvt_ <<"\n";


   // get the geometry from the event setup:

   esup.get<CaloGeometryRecord>().get(theCaloGeom_);


   // Transform Track into TransientTrack (needed by the Vertex fitter)

   edm::ESHandle<TransientTrackBuilder> theTTB;

   esup.get<TransientTrackRecord>().get("TransientTrackBuilder",theTTB);


   Handle<reco::ConversionCollection> convHandle;

   e.getByToken(conversionCollectionPr_Token_, convHandle);

   const reco::ConversionCollection convCollection = *(convHandle.product());

   if (!convHandle.isValid()) {

     edm::LogError("ConversionsProducer") << "Error! Can't get the  collection "<< std::endl;

     return;

   }


   Handle<reco::PhotonCollection> photonHandle;

   e.getByToken(photonCollectionPr_Token_, photonHandle);

   const reco::PhotonCollection photonCollection = *(photonHandle.product());

   if (!photonHandle.isValid()) {

     edm::LogError("PhotonProducer") << "Error! Can't get the Photon collection "<< std::endl;

     return;

   }


   // offline  Primary vertex

   edm::Handle<reco::VertexCollection> vertexHandle;

   reco::VertexCollection vertexCollection;

   e.getByToken(offline_pvToken_, vertexHandle);

   if (!vertexHandle.isValid()) {

       edm::LogError("TrackerOnlyConversionProducer") << "Error! Can't get the product primary Vertex Collection "<< "\n";

   } else {

       vertexCollection = *(vertexHandle.product());

   }

   reco::Vertex the_pvtx;

   bool valid_pvtx = false;

   if (!vertexCollection.empty()){

       the_pvtx = *(vertexCollection.begin());

       //asking for one good vertex

       if (the_pvtx.isValid() && fabs(the_pvtx.position().z())<=15 && the_pvtx.position().Rho()<=2){

           valid_pvtx = true;

       }

   }


   edm::Handle<reco::BeamSpot> bsHandle;

   e.getByToken(beamspotToken_, bsHandle);

   if (!bsHandle.isValid()) {

       edm::LogError("TrackerOnlyConversionProducer")

           << "Error! Can't get the product primary Vertex Collection "<< "\n";

       return;

   }

   const reco::BeamSpot &thebs = *bsHandle.product();


  //get tracker geometry for hits positions

   edm::ESHandle<TrackerGeometry> tracker;

   esup.get<TrackerDigiGeometryRecord>().get(tracker);

   const TrackerGeometry* trackerGeom = tracker.product();


   //get simtrack info

   std::vector<SimTrack> theSimTracks;

   std::vector<SimVertex> theSimVertices;


   edm::Handle<SimTrackContainer> SimTk;

   edm::Handle<SimVertexContainer> SimVtx;

   e.getByToken(g4_simTk_Token_, SimTk);

   e.getByToken(g4_simVtx_Token_, SimVtx);


   bool useTP = parameters_.getParameter<bool>("useTP");

   TrackingParticleCollection tpForEfficiency;

   TrackingParticleCollection tpForFakeRate;

   edm::Handle<TrackingParticleCollection> TPHandleForEff;

   edm::Handle<TrackingParticleCollection> TPHandleForFakeRate;

   if (useTP) {

     e.getByToken(tpSelForEff_Token_, TPHandleForEff);

     tpForEfficiency = *(TPHandleForEff.product());

     e.getByToken(tpSelForFake_Token_, TPHandleForFakeRate);

     tpForFakeRate = *(TPHandleForFakeRate.product());

   }


   theSimTracks.insert(theSimTracks.end(),SimTk->begin(),SimTk->end());

   theSimVertices.insert(theSimVertices.end(),SimVtx->begin(),SimVtx->end());

   std::vector<PhotonMCTruth> mcPhotons=thePhotonMCTruthFinder_->find (theSimTracks,  theSimVertices);


   edm::Handle<edm::HepMCProduct> hepMC;

   e.getByToken(hepMC_Token_, hepMC);

   //  const HepMC::GenEvent *myGenEvent = hepMC->GetEvent(); // unused


   // get generated jets

   edm::Handle<reco::GenJetCollection> GenJetsHandle;

   e.getByToken(genjets_Token_, GenJetsHandle);

   reco::GenJetCollection genJetCollection = *(GenJetsHandle.product());


   ConversionHitChecker hitChecker;


   // ################  SIM to RECO ######################### //

   std::map<const reco::Track*,TrackingParticleRef> myAss;

   std::map<const reco::Track*,TrackingParticleRef>::const_iterator itAss;


   for ( std::vector<PhotonMCTruth>::const_iterator mcPho=mcPhotons.begin(); mcPho !=mcPhotons.end(); mcPho++) {


     mcConvPt_= (*mcPho).fourMomentum().et();

     float mcPhi= (*mcPho).fourMomentum().phi();

     mcPhi_= phiNormalization(mcPhi);

     mcEta_= (*mcPho).fourMomentum().pseudoRapidity();

     mcEta_ = etaTransformation(mcEta_, (*mcPho).primaryVertex().z() );

     mcConvR_= (*mcPho).vertex().perp();

     mcConvX_= (*mcPho).vertex().x();

     mcConvY_= (*mcPho).vertex().y();

     mcConvZ_= (*mcPho).vertex().z();

     mcConvEta_= (*mcPho).vertex().eta();

     mcConvPhi_= (*mcPho).vertex().phi();


     if ( fabs(mcEta_) > END_HI ) continue;


     if (mcConvPt_<minPhoPtForEffic) continue;

     if (fabs(mcEta_)>maxPhoEtaForEffic) continue;

     if (fabs(mcConvZ_)>maxPhoZForEffic) continue;

     if (mcConvR_>maxPhoRForEffic) continue;


     bool goodSimConversion=false;

     bool visibleConversion=false;

     bool visibleConversionsWithTwoSimTracks=false;

     if (  (*mcPho).isAConversion() == 1 ) {

       nSimConv_[0]++;

       h_AllSimConv_[0]->Fill( mcEta_ ) ;

       h_AllSimConv_[1]->Fill( mcPhi_ );

       h_AllSimConv_[2]->Fill( mcConvR_ );

       h_AllSimConv_[3]->Fill( mcConvZ_ );

       h_AllSimConv_[4]->Fill(  (*mcPho).fourMomentum().et());


       if ( mcConvR_ <15) h_SimConvEtaPix_[0]->Fill( mcEta_ ) ;


       if ( ( fabs(mcEta_) <= BARL && mcConvR_ <85 )  ||

        ( fabs(mcEta_) > BARL && fabs(mcEta_) <=END_HI && fabs( (*mcPho).vertex().z() ) < 210 )  ) visibleConversion=true;


       theConvTP_.clear();

       //      std::cout << " TkConvValidator TrackingParticles   TrackingParticleCollection size "<<  trackingParticles.size() <<  "\n";

       //duplicated TP collections for two associations

       for(size_t i = 0; i < tpForEfficiency.size(); ++i){

     TrackingParticleRef tp (TPHandleForEff,i);

     if ( fabs( tp->vx() - (*mcPho).vertex().x() ) < 0.0001   &&

          fabs( tp->vy() - (*mcPho).vertex().y() ) < 0.0001   &&

          fabs( tp->vz() - (*mcPho).vertex().z() ) < 0.0001) {

       theConvTP_.push_back( tp );

     }

       }

       //std::cout << " TkConvValidator  theConvTP_ size " <<   theConvTP_.size() << std::endl;


       if ( theConvTP_.size() == 2 )   visibleConversionsWithTwoSimTracks=true;

       goodSimConversion=false;


       if (   visibleConversion && visibleConversionsWithTwoSimTracks )  goodSimConversion=true;

       if ( goodSimConversion ) {

     nSimConv_[1]++;

     h_VisSimConv_[0]->Fill( mcEta_ ) ;

     h_VisSimConv_[1]->Fill( mcPhi_ );

     h_VisSimConv_[2]->Fill( mcConvR_ );

     h_VisSimConv_[3]->Fill( mcConvZ_ );

     h_VisSimConv_[4]->Fill(  (*mcPho).fourMomentum().et());


       }


       for ( edm::RefVector<TrackingParticleCollection>::iterator iTrk=theConvTP_.begin(); iTrk!=theConvTP_.end(); ++iTrk) {

     h_simTkPt_ -> Fill ( (*iTrk)->pt() );

     h_simTkEta_ -> Fill ( (*iTrk)->eta() );

       }


     }


     if ( ! (visibleConversion &&  visibleConversionsWithTwoSimTracks ) ) continue;


       h_simConvVtxRvsZ_[0] ->Fill ( fabs (mcConvZ_), mcConvR_  ) ;

       if ( fabs(mcEta_) <=1.) {

     h_simConvVtxRvsZ_[1] ->Fill ( fabs (mcConvZ_), mcConvR_  ) ;

     h_simConvVtxYvsX_ ->Fill ( mcConvX_, mcConvY_  ) ;

       }

       else

     h_simConvVtxRvsZ_[2] ->Fill ( fabs (mcConvZ_), mcConvR_  ) ;


       //std::cout << " TkConvValidator  theConvTP_ size " <<   theConvTP_.size() << std::endl;

       for ( edm::RefVector<TrackingParticleCollection>::iterator iTP= theConvTP_.begin(); iTP!=theConvTP_.end(); iTP++)

     {

       //  std::cout << " SIM to RECO TP vertex " << (*iTP)->vx() << " " <<  (*iTP)->vy() << " " << (*iTP)->vz() << " pt " << (*iTP)->pt() << std::endl;

     }


      bool recomatch = false;

      float chi2Prob = 0.;

      // cout << " size of conversions " << convHandle->size() << endl;

      for (reco::ConversionCollection::const_iterator conv = convHandle->begin();conv!=convHandle->end();++conv) {


     const reco::Conversion aConv = (*conv);

         if ( arbitratedMerged_ && !aConv.quality(reco::Conversion::arbitratedMerged)  ) continue;

     if ( generalTracksOnly_ && !aConv.quality(reco::Conversion::generalTracksOnly) ) continue;

         if ( arbitratedEcalSeeded_ && !aConv.quality(reco::Conversion::arbitratedEcalSeeded)  ) continue;


         if ( highPurity_ && !aConv.quality(reco::Conversion::highPurity) ) continue;


     //problematic?

     std::vector<edm::RefToBase<reco::Track> > tracks = aConv.tracks();


     const reco::Vertex& vtx = aConv.conversionVertex();

     //requires two tracks and a valid vertex

     if (tracks.size() !=2 || !(vtx.isValid())) continue;


         if (ChiSquaredProbability( aConv.conversionVertex().chi2(),  aConv.conversionVertex().ndof() ) <= minProb_) continue;

         if (aConv.nHitsBeforeVtx().size()>1 && max(aConv.nHitsBeforeVtx().at(0),aConv.nHitsBeforeVtx().at(1)) > maxHitsBeforeVtx_ ) continue;


         //compute transverse decay length with respect to beamspot

         math::XYZVectorF  themom = aConv.refittedPairMomentum();

         double dbsx = aConv.conversionVertex().x() - thebs.x0();

         double dbsy = aConv.conversionVertex().y() - thebs.y0();

         double lxy = (themom.x()*dbsx + themom.y()*dbsy)/themom.rho();


         if (lxy<minLxy_) continue;


     //  bool  phoIsInBarrel=false; // unused

     //  bool  phoIsInEndcap=false; // unused

     RefToBase<reco::Track> tfrb1 = aConv.tracks().front();

     RefToBase<reco::Track> tfrb2 = aConv.tracks().back();


         if ( ecalalgotracks_ && ( !(tfrb1->algo()==15 || tfrb1->algo()==16) || !(tfrb2->algo()==15 || tfrb2->algo()==16)  )  ) continue;


     //reco::TrackRef tk1 = aConv.tracks().front();

     //reco::TrackRef tk2 = aConv.tracks().back();

     //std::cout << "SIM to RECO  conversion track pt " << tk1->pt() << " " << tk2->pt() << endl;

     //

     //Use two RefToBaseVector and do two association actions to avoid that if two tracks from different collection

     RefToBaseVector<reco::Track> tc1, tc2;

     tc1.push_back(tfrb1);

     tc2.push_back(tfrb2);

     bool isAssociated = false;

     reco::SimToRecoCollection q1 = theTrackAssociator->associateSimToReco(tc1,theConvTP_);

     reco::SimToRecoCollection q2 = theTrackAssociator->associateSimToReco(tc2,theConvTP_);

     //try {

       std::vector<std::pair<RefToBase<reco::Track>, double> > trackV1, trackV2;


       int tp_1 = 0, tp_2 = 1;//the index of associated tp in theConvTP_ for two tracks

       if (q1.find(theConvTP_[0])!=q1.end()){

           trackV1 = (std::vector<std::pair<RefToBase<reco::Track>, double> >) q1[theConvTP_[0]];

       } else if (q1.find(theConvTP_[1])!=q1.end()){

           trackV1 = (std::vector<std::pair<RefToBase<reco::Track>, double> >) q1[theConvTP_[1]];

           tp_1 = 1;

       }

       if (q2.find(theConvTP_[1])!=q2.end()){

           trackV2 = (std::vector<std::pair<RefToBase<reco::Track>, double> >) q2[theConvTP_[1]];

       } else if (q2.find(theConvTP_[0])!=q2.end()){

           trackV2 = (std::vector<std::pair<RefToBase<reco::Track>, double> >) q2[theConvTP_[0]];

           tp_2 = 0;

       }

       if (!(trackV1.size()&&trackV2.size()))

           continue;

       if (tp_1 == tp_2) continue;


       edm::RefToBase<reco::Track> tr1 = trackV1.front().first;

       edm::RefToBase<reco::Track> tr2 = trackV2.front().first;

       //std::cout << "associated tp1 " <<theConvTP_[0]->pt() << " to track with  pT=" << tr1->pt() << " " << (tr1.get())->pt() << endl;

       //std::cout << "associated tp2 " <<theConvTP_[1]->pt() << " to track with  pT=" << tr2->pt() << " " << (tr2.get())->pt() << endl;

       myAss.insert( std::make_pair (tr1.get(),theConvTP_[tp_1] ) );

       myAss.insert( std::make_pair (tr2.get(),theConvTP_[tp_2]) );


     //} catch (Exception event) {

       //cout << "continue: " << event.what()  << endl;

     //  continue;

     //}


     isAssociated = true;

         recomatch = true;

         chi2Prob = ChiSquaredProbability( aConv.conversionVertex().chi2(),  aConv.conversionVertex().ndof() );


         if (isAssociated) {

           h_SimRecConvTwoMTracks_[0]->Fill( mcEta_ ) ;

           h_SimRecConvTwoMTracks_[1]->Fill( mcPhi_ );

           h_SimRecConvTwoMTracks_[2]->Fill( mcConvR_ );

           h_SimRecConvTwoMTracks_[3]->Fill( mcConvZ_ );

           h_SimRecConvTwoMTracks_[4]->Fill(  (*mcPho).fourMomentum().et());

         }


        // break;

       } // loop over reco conversions

       if (recomatch) {

         h_SimConvTwoMTracks_[0]->Fill( mcEta_ ) ;

         h_SimConvTwoMTracks_[1]->Fill( mcPhi_ );

         h_SimConvTwoMTracks_[2]->Fill( mcConvR_ );

         h_SimConvTwoMTracks_[3]->Fill( mcConvZ_ );

         h_SimConvTwoMTracks_[4]->Fill(  (*mcPho).fourMomentum().et());


         if (   chi2Prob > 0) {

           h_SimConvTwoMTracksAndVtxPGT0_[0]->Fill( mcEta_ ) ;

           h_SimConvTwoMTracksAndVtxPGT0_[1]->Fill( mcPhi_ );

           h_SimConvTwoMTracksAndVtxPGT0_[2]->Fill( mcConvR_ );

           h_SimConvTwoMTracksAndVtxPGT0_[3]->Fill( mcConvZ_ );

           h_SimConvTwoMTracksAndVtxPGT0_[4]->Fill(  (*mcPho).fourMomentum().et());

         }

         if (   chi2Prob > 0.0005) {

           h_SimConvTwoMTracksAndVtxPGT0005_[0]->Fill( mcEta_ ) ;

           h_SimConvTwoMTracksAndVtxPGT0005_[1]->Fill( mcPhi_ );

           h_SimConvTwoMTracksAndVtxPGT0005_[2]->Fill( mcConvR_ );

           h_SimConvTwoMTracksAndVtxPGT0005_[3]->Fill( mcConvZ_ );

           h_SimConvTwoMTracksAndVtxPGT0005_[4]->Fill(  (*mcPho).fourMomentum().et());


         }

       }


   } //End loop over simulated conversions


   // ########################### RECO to SIM ############################## //


   for (reco::ConversionCollection::const_iterator conv = convHandle->begin();conv!=convHandle->end();++conv) {

     const reco::Conversion aConv = (*conv);

     if ( arbitratedMerged_ && !aConv.quality(reco::Conversion::arbitratedMerged)  ) continue;

     if ( generalTracksOnly_ && !aConv.quality(reco::Conversion::generalTracksOnly) ) continue;

     if ( arbitratedEcalSeeded_ && !aConv.quality(reco::Conversion::arbitratedEcalSeeded)  ) continue;


     if ( highPurity_ && !aConv.quality(reco::Conversion::highPurity) ) continue;


     //problematic?

     std::vector<edm::RefToBase<reco::Track> > tracks = aConv.tracks();


     const reco::Vertex& vtx = aConv.conversionVertex();

     //requires two tracks and a valid vertex

     if (tracks.size() !=2 || !(vtx.isValid())) continue;

     //if (tracks.size() !=2) continue;


     if (ChiSquaredProbability( aConv.conversionVertex().chi2(),  aConv.conversionVertex().ndof() ) <= minProb_) continue;

     if (aConv.nHitsBeforeVtx().size()>1 && max(aConv.nHitsBeforeVtx().at(0),aConv.nHitsBeforeVtx().at(1)) > maxHitsBeforeVtx_ ) continue;


     //compute transverse decay length with respect to beamspot

     math::XYZVectorF  themom = aConv.refittedPairMomentum();

     double dbsx = aConv.conversionVertex().x() - thebs.x0();

     double dbsy = aConv.conversionVertex().y() - thebs.y0();

     double lxy = (themom.x()*dbsx + themom.y()*dbsy)/themom.rho();


     if (lxy<minLxy_) continue;


     bool  phoIsInBarrel=false;

     bool  phoIsInEndcap=false;

     RefToBase<reco::Track> tk1 = aConv.tracks().front();

     RefToBase<reco::Track> tk2 = aConv.tracks().back();

     RefToBaseVector<reco::Track> tc1, tc2;

     tc1.push_back(tk1);

     tc2.push_back(tk2);


    if ( ecalalgotracks_ && ( !(tk1->algo()==15 || tk1->algo()==16) || !(tk2->algo()==15 || tk2->algo()==16)  )  ) continue;


     //std::cout << " RECO to SIM conversion track pt " << tk1->pt() << " " << tk2->pt() << endl;

     const reco::Track refTk1 = aConv.conversionVertex().refittedTracks().front();

     const reco::Track refTk2 = aConv.conversionVertex().refittedTracks().back();


     //TODO replace it with phi at vertex

     float  dPhiTracksAtVtx =  aConv.dPhiTracksAtVtx();

     // override with the phi calculated at the vertex

     math::XYZVector p1AtVtx= recalculateMomentumAtFittedVertex (  (*theMF_), *trackerGeom, tk1,  aConv.conversionVertex() );

     math::XYZVector p2AtVtx= recalculateMomentumAtFittedVertex (  (*theMF_), *trackerGeom, tk2,  aConv.conversionVertex() );

     if (  sqrt(p1AtVtx.perp2())  >  sqrt(p2AtVtx.perp2())  )

       dPhiTracksAtVtx = p1AtVtx.phi() - p2AtVtx.phi();

     else

       dPhiTracksAtVtx = p2AtVtx.phi() - p1AtVtx.phi();


     math::XYZVectorF refittedMom =  aConv.refittedPairMomentum();


     if (fabs(refittedMom.eta())< 1.479 ) {

       phoIsInBarrel=true;

     } else {

       phoIsInEndcap=true;

     }


     nRecConv_++;


     // check matching with reco photon

     double Mindeltaeta = 999999;

     double Mindeltaphi = 999999;

     bool matchConvSC=false;

     reco::PhotonCollection::const_iterator  iMatchingSC;

     for( reco::PhotonCollection::const_iterator  iPho = photonCollection.begin(); iPho != photonCollection.end(); iPho++) {

       reco::Photon aPho = reco::Photon(*iPho);

       const double deltaphi= reco::deltaPhi( aConv.refittedPairMomentum().phi(), aPho.superCluster()->position().phi());

       double ConvEta = etaTransformation(aConv.refittedPairMomentum().eta(),aConv.zOfPrimaryVertexFromTracks());

       double deltaeta = abs( aPho.superCluster()->position().eta() -ConvEta);

       if (abs(deltaeta)<abs(Mindeltaeta) && abs(deltaphi)<abs(Mindeltaphi)) {

     Mindeltaphi=abs(deltaphi);

     Mindeltaeta=abs(deltaeta);

     iMatchingSC = iPho ;

       }

     }

     if (abs(Mindeltaeta)<0.1 && abs(Mindeltaphi)<0.1) {

       matchConvSC=true;

     }


     int match =0;

     float invM=aConv.pairInvariantMass();

     float chi2Prob = ChiSquaredProbability( aConv.conversionVertex().chi2(),  aConv.conversionVertex().ndof() );

     uint maxNHitsBeforeVtx = aConv.nHitsBeforeVtx().size()>1 ? max(aConv.nHitsBeforeVtx().at(0),aConv.nHitsBeforeVtx().at(1)) : 0;

     uint sumNHitsBeforeVtx = aConv.nHitsBeforeVtx().size()>1 ? aConv.nHitsBeforeVtx().at(0) + aConv.nHitsBeforeVtx().at(1) : 0;

     float maxDlClosestHitToVtx = aConv.dlClosestHitToVtx().size()>1 ? max(aConv.dlClosestHitToVtx().at(0).value(),aConv.dlClosestHitToVtx().at(1).value()) : 0;

     float maxDlClosestHitToVtxSig = aConv.dlClosestHitToVtx().size()>1 ? max(aConv.dlClosestHitToVtx().at(0).value()/aConv.dlClosestHitToVtx().at(0).error(),aConv.dlClosestHitToVtx().at(1).value()/aConv.dlClosestHitToVtx().at(1).error()) : 0;


     int ilead = 0, itrail = 1;

     if (tk2->pt() > tk1->pt()) {

       ilead = 1;

       itrail = 0;

     }

     RefToBase<reco::Track> tklead = aConv.tracks().at(ilead);

     RefToBase<reco::Track> tktrail = aConv.tracks().at(itrail);


     int deltaExpectedHitsInner = tklead->hitPattern().numberOfHits(reco::HitPattern::MISSING_INNER_HITS)

        - tktrail->hitPattern().numberOfHits(reco::HitPattern::MISSING_INNER_HITS);

     int leadExpectedHitsInner = tklead->hitPattern().numberOfHits(reco::HitPattern::MISSING_INNER_HITS);

     uint leadNHitsBeforeVtx = aConv.nHitsBeforeVtx().size()>1 ? aConv.nHitsBeforeVtx().at(ilead) : 0;

     uint trailNHitsBeforeVtx = aConv.nHitsBeforeVtx().size()>1 ? aConv.nHitsBeforeVtx().at(itrail) : 0;


     h_convEta_[match][0]->Fill( refittedMom.eta() );

     h_convEta2_[match][0]->Fill( refittedMom.eta() );


     h_convPhi_[match][0]->Fill( refittedMom.phi() );

     h_convR_[match][0]->Fill( sqrt(aConv.conversionVertex().position().perp2()) );

     h_convRplot_->Fill( sqrt(aConv.conversionVertex().position().perp2()) );

     h_convZ_[match][0]->Fill( aConv.conversionVertex().position().z() );

     h_convZplot_->Fill( aConv.conversionVertex().position().z() );

     h_convPt_[match][0]->Fill(  sqrt(refittedMom.perp2()) );

     h_invMass_[match][0] ->Fill( invM);

     h_vtxChi2Prob_[match][0] ->Fill (chi2Prob);

     h_lxybs_[match][0] ->Fill (lxy);

     h_maxNHitsBeforeVtx_[match][0] ->Fill (maxNHitsBeforeVtx);

     h_leadNHitsBeforeVtx_[match][0] ->Fill (leadNHitsBeforeVtx);

     h_trailNHitsBeforeVtx_[match][0] ->Fill (trailNHitsBeforeVtx);

     h_sumNHitsBeforeVtx_[match][0] ->Fill (sumNHitsBeforeVtx);

     h_deltaExpectedHitsInner_[match][0] ->Fill (deltaExpectedHitsInner);

     h_leadExpectedHitsInner_[match][0] ->Fill (leadExpectedHitsInner);

     h_maxDlClosestHitToVtx_[match][0] ->Fill (maxDlClosestHitToVtx);

     h_maxDlClosestHitToVtxSig_[match][0] ->Fill (maxDlClosestHitToVtxSig);

     h_nSharedHits_[match][0] ->Fill (aConv.nSharedHits());


     if (  matchConvSC ) {

       h_convEtaMatchSC_[match][0]->Fill( refittedMom.eta() );

       h_EoverPTracks_[match][0] ->Fill (iMatchingSC->superCluster()->energy()/sqrt(refittedMom.mag2()));

       h_convSCdPhi_[match][0]->Fill( iMatchingSC->superCluster()->position().phi() - refittedMom.phi() );

       double ConvEta = etaTransformation(aConv.refittedPairMomentum().eta(),aConv.zOfPrimaryVertexFromTracks());

       h_convSCdEta_[match][0]->Fill( iMatchingSC->superCluster()->position().eta() - ConvEta );

     }


     h_distMinAppTracks_[match][0] ->Fill (aConv.distOfMinimumApproach());

     h_DPhiTracksAtVtx_[match][0]->Fill( dPhiTracksAtVtx);

     h2_DPhiTracksAtVtxVsEta_->Fill( mcEta_, dPhiTracksAtVtx);

     h2_DPhiTracksAtVtxVsR_->Fill( mcConvR_, dPhiTracksAtVtx);

     p_DPhiTracksAtVtxVsEta_->Fill( mcEta_, dPhiTracksAtVtx);

     p_DPhiTracksAtVtxVsR_->Fill( mcConvR_, dPhiTracksAtVtx);


     h_DCotTracks_[match][0] ->Fill ( aConv.pairCotThetaSeparation() );

     h2_DCotTracksVsEta_->Fill( mcEta_, aConv.pairCotThetaSeparation() );

     h2_DCotTracksVsR_->Fill( mcConvR_, aConv.pairCotThetaSeparation() );

     p_DCotTracksVsEta_->Fill( mcEta_, aConv.pairCotThetaSeparation() );

     p_DCotTracksVsR_->Fill( mcConvR_, aConv.pairCotThetaSeparation() );


     if ( phoIsInBarrel ) {

       h_invMass_[match][1] ->Fill(invM);

       h_vtxChi2Prob_[match][1] ->Fill (chi2Prob);

       h_distMinAppTracks_[match][1] ->Fill (aConv.distOfMinimumApproach());

       h_DPhiTracksAtVtx_[match][1]->Fill( dPhiTracksAtVtx);

       h_DCotTracks_[match][1] ->Fill ( aConv.pairCotThetaSeparation() );

       h_lxybs_[match][1] ->Fill (lxy);

       h_maxNHitsBeforeVtx_[match][1] ->Fill (maxNHitsBeforeVtx);

       h_leadNHitsBeforeVtx_[match][1] ->Fill (leadNHitsBeforeVtx);

       h_trailNHitsBeforeVtx_[match][1] ->Fill (trailNHitsBeforeVtx);

       h_sumNHitsBeforeVtx_[match][1] ->Fill (sumNHitsBeforeVtx);

       h_deltaExpectedHitsInner_[match][1] ->Fill (deltaExpectedHitsInner);

       h_leadExpectedHitsInner_[match][1] ->Fill (leadExpectedHitsInner);

       h_maxDlClosestHitToVtx_[match][1] ->Fill (maxDlClosestHitToVtx);

       h_maxDlClosestHitToVtxSig_[match][1] ->Fill (maxDlClosestHitToVtxSig);

       h_nSharedHits_[match][1] ->Fill (aConv.nSharedHits());


       /*

       if ( aConv.caloCluster().size() ) {

     h_convSCdPhi_[match][1]->Fill(  aConv.caloCluster()[0]->phi() - refittedMom.phi() );

     double ConvEta = etaTransformation(aConv.refittedPairMomentum().eta(),aConv.zOfPrimaryVertexFromTracks());

     h_convSCdEta_[match][1]->Fill( aConv.caloCluster()[0]->eta() - ConvEta );

       }

       */


       if (  matchConvSC ) {

     h_EoverPTracks_[match][1] -> Fill(iMatchingSC->superCluster()->energy()/sqrt(refittedMom.mag2()));

     h_convSCdPhi_[match][1]->Fill( iMatchingSC->superCluster()->position().phi() - refittedMom.phi() );

     double ConvEta = etaTransformation(aConv.refittedPairMomentum().eta(),aConv.zOfPrimaryVertexFromTracks());

     h_convSCdEta_[match][1]->Fill( iMatchingSC->superCluster()->position().eta() - ConvEta );

       }

     }


     if ( phoIsInEndcap ) {

       h_invMass_[match][2] ->Fill(invM);

       h_vtxChi2Prob_[match][2] ->Fill (chi2Prob);

       h_distMinAppTracks_[match][2] ->Fill (aConv.distOfMinimumApproach());

       h_DPhiTracksAtVtx_[match][2]->Fill( dPhiTracksAtVtx);

       h_DCotTracks_[match][2] ->Fill ( aConv.pairCotThetaSeparation() );

       h_lxybs_[match][2] ->Fill (lxy);

       h_maxNHitsBeforeVtx_[match][2] ->Fill (maxNHitsBeforeVtx);

       h_leadNHitsBeforeVtx_[match][2] ->Fill (leadNHitsBeforeVtx);

       h_trailNHitsBeforeVtx_[match][2] ->Fill (trailNHitsBeforeVtx);

       h_sumNHitsBeforeVtx_[match][2] ->Fill (sumNHitsBeforeVtx);

       h_deltaExpectedHitsInner_[match][2] ->Fill (deltaExpectedHitsInner);

       h_leadExpectedHitsInner_[match][2] ->Fill (leadExpectedHitsInner);

       h_maxDlClosestHitToVtx_[match][2] ->Fill (maxDlClosestHitToVtx);

       h_maxDlClosestHitToVtxSig_[match][2] ->Fill (maxDlClosestHitToVtxSig);

       h_nSharedHits_[match][2] ->Fill (aConv.nSharedHits());

       if (  matchConvSC ) {

     h_EoverPTracks_[match][2] ->Fill (iMatchingSC->superCluster()->energy()/sqrt(refittedMom.mag2()));

     h_convSCdPhi_[match][2]->Fill( iMatchingSC->superCluster()->position().phi() - refittedMom.phi() );

     double ConvEta = etaTransformation(aConv.refittedPairMomentum().eta(),aConv.zOfPrimaryVertexFromTracks());

     h_convSCdEta_[match][2]->Fill( iMatchingSC->superCluster()->position().eta() - ConvEta );


       }

     }


     h_convVtxRvsZ_[0] ->Fill ( fabs (aConv.conversionVertex().position().z() ),  sqrt(aConv.conversionVertex().position().perp2())  ) ;

     h_convVtxYvsX_ ->Fill (  aConv.conversionVertex().position().x(), aConv.conversionVertex().position().y() );

     h_convVtxYvsX_zoom_[0] ->Fill (  aConv.conversionVertex().position().x(), aConv.conversionVertex().position().y() );

     h_convVtxYvsX_zoom_[1] ->Fill (  aConv.conversionVertex().position().x(), aConv.conversionVertex().position().y() );


     // quantities per track: all conversions

     for (unsigned int i=0; i<tracks.size(); i++) {

       double d0;

       if (valid_pvtx){

     d0 = - tracks[i]->dxy(the_pvtx.position());

       } else {

     d0 = tracks[i]->d0();

       }

       h_TkD0_[match]->Fill ( d0* tracks[i]->charge() );

       h_nHitsBeforeVtx_[match]->Fill ( aConv.nHitsBeforeVtx().size()>1 ? aConv.nHitsBeforeVtx().at(i) : 0 );

       h_dlClosestHitToVtx_[match]->Fill ( aConv.dlClosestHitToVtx().size()>1 ? aConv.dlClosestHitToVtx().at(i).value() : 0 );

       h_dlClosestHitToVtxSig_[match]->Fill ( aConv.dlClosestHitToVtx().size()>1 ? aConv.dlClosestHitToVtx().at(i).value()/aConv.dlClosestHitToVtx().at(i).error() : 0 );


       nHitsVsEta_[match] ->Fill (mcEta_,   float(tracks[i]->numberOfValidHits()) );

       nHitsVsR_[match] ->Fill (mcConvR_,   float(tracks[i]->numberOfValidHits()) );

       p_nHitsVsEta_[match] ->Fill (mcEta_,   float(tracks[i]->numberOfValidHits()) -0.0001);

       p_nHitsVsR_[match] ->Fill (mcConvR_,   float(tracks[i]->numberOfValidHits()) -0.0001);

       h_tkChi2_[match] ->Fill (tracks[i]->normalizedChi2() );

       h_tkChi2Large_[match] ->Fill (tracks[i]->normalizedChi2() );

       h2_Chi2VsEta_[match] ->Fill(  mcEta_, tracks[i]->normalizedChi2() );

       h2_Chi2VsR_[match] ->Fill(  mcConvR_, tracks[i]->normalizedChi2() );

       p_Chi2VsEta_[match] ->Fill(  mcEta_, tracks[i]->normalizedChi2() );

       p_Chi2VsR_[match] ->Fill(  mcConvR_, tracks[i]->normalizedChi2() );


     }


     bool associated = false;

     float mcConvPt_= -99999999;

     //    float mcPhi= 0; // unused

     float simPV_Z=0;

     for ( std::vector<PhotonMCTruth>::const_iterator mcPho=mcPhotons.begin(); mcPho !=mcPhotons.end(); mcPho++) {

       mcConvPt_= (*mcPho).fourMomentum().et();

       float mcPhi= (*mcPho).fourMomentum().phi();

       simPV_Z = (*mcPho).primaryVertex().z();

       mcPhi_= phiNormalization(mcPhi);

       mcEta_= (*mcPho).fourMomentum().pseudoRapidity();

       mcEta_ = etaTransformation(mcEta_, (*mcPho).primaryVertex().z() );

       mcConvR_= (*mcPho).vertex().perp();

       mcConvX_= (*mcPho).vertex().x();

       mcConvY_= (*mcPho).vertex().y();

       mcConvZ_= (*mcPho).vertex().z();

       mcConvEta_= (*mcPho).vertex().eta();

       mcConvPhi_= (*mcPho).vertex().phi();

       if ( fabs(mcEta_) > END_HI ) continue;

       if (mcConvPt_<minPhoPtForPurity) continue;

       if (fabs(mcEta_)>maxPhoEtaForPurity) continue;

       if (fabs(mcConvZ_)>maxPhoZForPurity) continue;

       if (mcConvR_>maxPhoRForEffic) continue;


       if (  (*mcPho).isAConversion() != 1 ) continue;

       if (!( ( fabs(mcEta_) <= BARL && mcConvR_ <85 )  ||

          ( fabs(mcEta_) > BARL && fabs(mcEta_) <=END_HI && fabs( (*mcPho).vertex().z() ) < 210 )  ) )

     continue;


       theConvTP_.clear();

       for(size_t i = 0; i < tpForFakeRate.size(); ++i){

     TrackingParticleRef tp (TPHandleForFakeRate,i);

     if ( fabs( tp->vx() - (*mcPho).vertex().x() ) < 0.0001   &&

          fabs( tp->vy() - (*mcPho).vertex().y() ) < 0.0001   &&

          fabs( tp->vz() - (*mcPho).vertex().z() ) < 0.0001) {

       theConvTP_.push_back( tp );


     }

       }


       if ( theConvTP_.size() < 2 )   continue;


       //associated = false;

       reco::RecoToSimCollection p1 =  theTrackAssociator->associateRecoToSim(tc1,theConvTP_);

       reco::RecoToSimCollection p2 =  theTrackAssociator->associateRecoToSim(tc2,theConvTP_);

       try{

     std::vector<std::pair<TrackingParticleRef, double> > tp1 = p1[tk1];

     std::vector<std::pair<TrackingParticleRef, double> > tp2 = p2[tk2];

     if (!(tp1.size()&&tp2.size())){

         tp1 = p1[tk2];

         tp2 = p2[tk1];

     }

     if (tp1.size()&&tp2.size()) {

       TrackingParticleRef tpr1 = tp1.front().first;

       TrackingParticleRef tpr2 = tp2.front().first;

       if (abs(tpr1->pdgId())==11&&abs(tpr2->pdgId())==11&& tpr1->pdgId()*tpr2->pdgId()<0) {

         if ( (tpr1->parentVertex()->sourceTracks_end()-tpr1->parentVertex()->sourceTracks_begin()==1) &&

          (tpr2->parentVertex()->sourceTracks_end()-tpr2->parentVertex()->sourceTracks_begin()==1)) {

           if (tpr1->parentVertex().key()==tpr2->parentVertex().key() && ((*tpr1->parentVertex()->sourceTracks_begin())->pdgId()==22)) {

         mcConvR_ = sqrt(tpr1->parentVertex()->position().Perp2());

         mcConvZ_ = tpr1->parentVertex()->position().z();

         mcConvX_ = tpr1->parentVertex()->position().x();

         mcConvY_ = tpr1->parentVertex()->position().y();

         mcConvEta_ = tpr1->parentVertex()->position().eta();

         mcConvPhi_ = tpr1->parentVertex()->position().phi();

         mcConvPt_ = sqrt((*tpr1->parentVertex()->sourceTracks_begin())->momentum().Perp2());

         //std::cout << " Reco to Sim mcconvpt " << mcConvPt_ << std::endl;

         //cout << "associated track1 to " << tpr1->pdgId() << " with p=" << tpr1->p4() << " with pT=" << tpr1->pt() << endl;

         //cout << "associated track2 to " << tpr2->pdgId() << " with p=" << tpr2->p4() << " with pT=" << tpr2->pt() << endl;

         associated = true;

                 break;

           }

         }

       }

     }

       } catch (Exception event) {

     //cout << "do not continue: " << event.what()  << endl;

     //continue;

       }


     }// end loop on sim photons


     if (0) {

         theConvTP_.clear();

         for(size_t i = 0; i < tpForFakeRate.size(); ++i){

           TrackingParticleRef tp (TPHandleForFakeRate,i);

             theConvTP_.push_back( tp );

         }

         reco::RecoToSimCollection p1incl =  theTrackAssociator->associateRecoToSim(tc1,theConvTP_);

         reco::RecoToSimCollection p2incl =  theTrackAssociator->associateRecoToSim(tc2,theConvTP_);


       for ( std::vector<PhotonMCTruth>::const_iterator mcPho=mcPhotons.begin(); mcPho !=mcPhotons.end(); mcPho++) {

         mcConvPt_= (*mcPho).fourMomentum().et();

         float mcPhi= (*mcPho).fourMomentum().phi();

         simPV_Z = (*mcPho).primaryVertex().z();

         mcPhi_= phiNormalization(mcPhi);

         mcEta_= (*mcPho).fourMomentum().pseudoRapidity();

         mcEta_ = etaTransformation(mcEta_, (*mcPho).primaryVertex().z() );

         mcConvR_= (*mcPho).vertex().perp();

         mcConvX_= (*mcPho).vertex().x();

         mcConvY_= (*mcPho).vertex().y();

         mcConvZ_= (*mcPho).vertex().z();

         mcConvEta_= (*mcPho).vertex().eta();

         mcConvPhi_= (*mcPho).vertex().phi();

         if ( fabs(mcEta_) > END_HI ) continue;

         if (mcConvPt_<minPhoPtForPurity) continue;

         if (fabs(mcEta_)>maxPhoEtaForPurity) continue;

         if (fabs(mcConvZ_)>maxPhoZForPurity) continue;

         if (mcConvR_>maxPhoRForEffic) continue;


         if (  (*mcPho).isAConversion() != 1 ) continue;

         if (!( ( fabs(mcEta_) <= BARL && mcConvR_ <85 )  ||

               ( fabs(mcEta_) > BARL && fabs(mcEta_) <=END_HI && fabs( (*mcPho).vertex().z() ) < 210 )  ) )

           continue;


         theConvTP_.clear();

         for(size_t i = 0; i < tpForFakeRate.size(); ++i){

           TrackingParticleRef tp (TPHandleForFakeRate,i);

           if ( fabs( tp->vx() - (*mcPho).vertex().x() ) < 0.0001   &&

               fabs( tp->vy() - (*mcPho).vertex().y() ) < 0.0001   &&

               fabs( tp->vz() - (*mcPho).vertex().z() ) < 0.0001) {

             theConvTP_.push_back( tp );


           }

         }


         if ( theConvTP_.size() < 2 )   continue;


         //associated = false;

         reco::RecoToSimCollection p1 =  theTrackAssociator->associateRecoToSim(tc1,theConvTP_);

         reco::RecoToSimCollection p2 =  theTrackAssociator->associateRecoToSim(tc2,theConvTP_);


           if ( (p1incl.size() && p2incl.size()) && (p1.size() || p2.size()) ) { // associated = true;

             try{

               std::vector<std::pair<TrackingParticleRef, double> > tp1 = p1incl[tk1];

               std::vector<std::pair<TrackingParticleRef, double> > tp2 = p2incl[tk2];

               if (!(tp1.size()&&tp2.size())){

                   tp1 = p1[tk2];

                   tp2 = p2[tk1];

               }

               if (tp1.size()&&tp2.size()) {

                 TrackingParticleRef tpr1 = tp1.front().first;

                 TrackingParticleRef tpr2 = tp2.front().first;

                 if (abs(tpr1->pdgId())==11&&abs(tpr2->pdgId())==11 && tpr1->pdgId()*tpr2->pdgId()<0) {

                   if ( ((tpr1->parentVertex()->sourceTracks_end()-tpr1->parentVertex()->sourceTracks_begin()>=1) && (*tpr1->parentVertex()->sourceTracks_begin())->pdgId()==22) &&

                       ((tpr2->parentVertex()->sourceTracks_end()-tpr2->parentVertex()->sourceTracks_begin()>=1) && (*tpr2->parentVertex()->sourceTracks_begin())->pdgId()==22) ) {


                    // if ( fabs(tpr1->vx() - tpr2->vx()) < 0.1 && fabs(tpr1->vy() - tpr2->vy()) < 0.1 && fabs(tpr1->vz() - tpr2->vz()) < 0.1) {

                     //if (((*tpr1->parentVertex()->sourceTracks_begin())->pdgId()==22) || ((*tpr2->parentVertex()->sourceTracks_begin())->pdgId()==22)) {

 //                       mcConvR_ = sqrt(tpr1->parentVertex()->position().Perp2());

 //                       mcConvZ_ = tpr1->parentVertex()->position().z();

 //                       mcConvX_ = tpr1->parentVertex()->position().x();

 //                       mcConvY_ = tpr1->parentVertex()->position().y();

 //                       mcConvEta_ = tpr1->parentVertex()->position().eta();

 //                       mcConvPhi_ = tpr1->parentVertex()->position().phi();

 //                       mcConvPt_ = sqrt((*tpr1->parentVertex()->sourceTracks_begin())->momentum().Perp2());

                       //std::cout << " Reco to Sim mcconvpt " << mcConvPt_ << std::endl;

                       //cout << "associated track1 to " << tpr1->pdgId() << " with p=" << tpr1->p4() << " with pT=" << tpr1->pt() << endl;

                       //cout << "associated track2 to " << tpr2->pdgId() << " with p=" << tpr2->p4() << " with pT=" << tpr2->pt() << endl;

                       associated = true;

                       break;

                     //}

                     //}

                   }

                 }

               }

             } catch (Exception event) {

               //cout << "do not continue: " << event.what()  << endl;

               //continue;

             }


           }


         }

       }


       if ( associated ) match=1;

       else

     match=2;


       h_match_->Fill(float(match));

       if ( match == 1) nRecConvAss_++;

       h_convEta_[match][0]->Fill( refittedMom.eta() );

       h_convEta_[match][1]->Fill( refittedMom.eta() );

       if (matchConvSC) h_convEtaMatchSC_[match][0]->Fill( refittedMom.eta() );

       h_convPhi_[match][0]->Fill( refittedMom.phi() );

       h_convR_[match][0]->Fill( sqrt(aConv.conversionVertex().position().perp2()) );

       h_convZ_[match][0]->Fill( aConv.conversionVertex().position().z() );

       h_convPt_[match][0]->Fill(  sqrt(refittedMom.perp2()) );

       h_invMass_[match][0] ->Fill( invM);

       h_vtxChi2Prob_[match][0] ->Fill (chi2Prob);

       h_DPhiTracksAtVtx_[match][0]->Fill( dPhiTracksAtVtx);

       h_DCotTracks_[match][0] ->Fill ( aConv.pairCotThetaSeparation() );

       h_distMinAppTracks_[match][0] ->Fill (aConv.distOfMinimumApproach());

       h_lxybs_[match][0] ->Fill (lxy);

       h_maxNHitsBeforeVtx_[match][0] ->Fill (maxNHitsBeforeVtx);

       h_leadNHitsBeforeVtx_[match][0] ->Fill (leadNHitsBeforeVtx);

       h_trailNHitsBeforeVtx_[match][0] ->Fill (trailNHitsBeforeVtx);

       h_sumNHitsBeforeVtx_[match][0] ->Fill (sumNHitsBeforeVtx);

       h_deltaExpectedHitsInner_[match][0] ->Fill (deltaExpectedHitsInner);

       h_leadExpectedHitsInner_[match][0] ->Fill (leadExpectedHitsInner);

       h_maxDlClosestHitToVtx_[match][0] ->Fill (maxDlClosestHitToVtx);

       h_maxDlClosestHitToVtxSig_[match][0] ->Fill (maxDlClosestHitToVtxSig);

       h_nSharedHits_[match][0] ->Fill (aConv.nSharedHits());

       if (  matchConvSC ) {

     //h_EoverPTracks_[match][0] ->Fill (aConv.EoverPrefittedTracks());

     h_EoverPTracks_[match][0] ->Fill (iMatchingSC->superCluster()->energy()/sqrt(refittedMom.mag2()));

     h_convSCdPhi_[match][0]->Fill( iMatchingSC->superCluster()->position().phi() - refittedMom.phi() );

     double ConvEta = etaTransformation(aConv.refittedPairMomentum().eta(),aConv.zOfPrimaryVertexFromTracks());

     h_convSCdEta_[match][0]->Fill( iMatchingSC->superCluster()->position().eta() - ConvEta );


       }

       if ( match==1) {

     h2_photonPtRecVsPtSim_->Fill ( mcConvPt_, sqrt(refittedMom.perp2()) );

     h_convPtRes_[0]->Fill (  sqrt(refittedMom.perp2())/mcConvPt_);

       }


     if ( phoIsInBarrel ) {

       h_invMass_[match][1] ->Fill(invM);

       h_vtxChi2Prob_[match][1] ->Fill (chi2Prob);

       h_DPhiTracksAtVtx_[match][1]->Fill( dPhiTracksAtVtx);

       h_DCotTracks_[match][1] ->Fill ( aConv.pairCotThetaSeparation() );

       h_distMinAppTracks_[match][1] ->Fill (aConv.distOfMinimumApproach());

       h_lxybs_[match][1] ->Fill (lxy);

       h_maxNHitsBeforeVtx_[match][1] ->Fill (maxNHitsBeforeVtx);

       h_leadNHitsBeforeVtx_[match][1] ->Fill (leadNHitsBeforeVtx);

       h_trailNHitsBeforeVtx_[match][1] ->Fill (trailNHitsBeforeVtx);

       h_sumNHitsBeforeVtx_[match][1] ->Fill (sumNHitsBeforeVtx);

       h_deltaExpectedHitsInner_[match][1] ->Fill (deltaExpectedHitsInner);

       h_leadExpectedHitsInner_[match][1] ->Fill (leadExpectedHitsInner);

       h_maxDlClosestHitToVtx_[match][1] ->Fill (maxDlClosestHitToVtx);

       h_maxDlClosestHitToVtxSig_[match][1] ->Fill (maxDlClosestHitToVtxSig);

       h_nSharedHits_[match][1] ->Fill (aConv.nSharedHits());

       if (  matchConvSC ) {

     //  h_EoverPTracks_[match][1] ->Fill (aConv.EoverPrefittedTracks());

     h_EoverPTracks_[match][1] ->Fill (iMatchingSC->superCluster()->energy()/sqrt(refittedMom.mag2()));

     h_convSCdPhi_[match][1]->Fill( iMatchingSC->superCluster()->position().phi() - refittedMom.phi() );

     double ConvEta = etaTransformation(aConv.refittedPairMomentum().eta(),aConv.zOfPrimaryVertexFromTracks());

     h_convSCdEta_[match][1]->Fill( iMatchingSC->superCluster()->position().eta() - ConvEta );


       }

       if ( match==1) h_convPtRes_[1]->Fill (  sqrt(refittedMom.perp2())/mcConvPt_);

     }


     if ( phoIsInEndcap ) {

       h_invMass_[match][2] ->Fill(invM);

       h_vtxChi2Prob_[match][2] ->Fill (chi2Prob);

       h_DPhiTracksAtVtx_[match][2]->Fill( dPhiTracksAtVtx);

       h_DCotTracks_[match][2] ->Fill ( aConv.pairCotThetaSeparation() );

       h_distMinAppTracks_[match][2] ->Fill (aConv.distOfMinimumApproach());

       h_lxybs_[match][2] ->Fill (lxy);

       h_maxNHitsBeforeVtx_[match][2] ->Fill (maxNHitsBeforeVtx);

       h_leadNHitsBeforeVtx_[match][2] ->Fill (leadNHitsBeforeVtx);

       h_trailNHitsBeforeVtx_[match][2] ->Fill (trailNHitsBeforeVtx);

       h_sumNHitsBeforeVtx_[match][2] ->Fill (sumNHitsBeforeVtx);

       h_deltaExpectedHitsInner_[match][2] ->Fill (deltaExpectedHitsInner);

       h_leadExpectedHitsInner_[match][2] ->Fill (leadExpectedHitsInner);

       h_maxDlClosestHitToVtx_[match][2] ->Fill (maxDlClosestHitToVtx);

       h_maxDlClosestHitToVtxSig_[match][2] ->Fill (maxDlClosestHitToVtxSig);

       h_nSharedHits_[match][2] ->Fill (aConv.nSharedHits());

       if (  matchConvSC ) {

     //  h_EoverPTracks_[match][2] ->Fill (aConv.EoverPrefittedTracks());

     h_EoverPTracks_[match][2] ->Fill (iMatchingSC->superCluster()->energy()/sqrt(refittedMom.mag2()));

     h_convSCdPhi_[match][2]->Fill( iMatchingSC->superCluster()->position().phi() - refittedMom.phi() );

     double ConvEta = etaTransformation(aConv.refittedPairMomentum().eta(),aConv.zOfPrimaryVertexFromTracks());

     h_convSCdEta_[match][2]->Fill( iMatchingSC->superCluster()->position().eta() - ConvEta );

       }

       if ( match==1) h_convPtRes_[2]->Fill (  sqrt(refittedMom.perp2())/mcConvPt_);

     }


     if ( match == 1 ) {

       h_convVtxdX_ ->Fill ( aConv.conversionVertex().position().x() - mcConvX_);

       h_convVtxdY_ ->Fill ( aConv.conversionVertex().position().y() - mcConvY_);

       h_convVtxdZ_ ->Fill ( aConv.conversionVertex().position().z() - mcConvZ_);

       h_convVtxdR_ ->Fill ( sqrt(aConv.conversionVertex().position().perp2()) - mcConvR_);

       h_convVtxdPhi_ ->Fill ( aConv.conversionVertex().position().phi() - mcConvPhi_);

       h_convVtxdEta_ ->Fill ( aConv.conversionVertex().position().eta() - mcConvEta_);

       h2_convVtxdRVsR_ ->Fill (mcConvR_, sqrt(aConv.conversionVertex().position().perp2()) - mcConvR_ );

       h2_convVtxdRVsEta_ ->Fill (mcEta_, sqrt(aConv.conversionVertex().position().perp2()) - mcConvR_ );

       p_convVtxdRVsR_ ->Fill (mcConvR_, sqrt(aConv.conversionVertex().position().perp2()) - mcConvR_ );

       p_convVtxdRVsEta_ ->Fill (mcEta_, sqrt(aConv.conversionVertex().position().perp2()) - mcConvR_ );

       p_convVtxdXVsX_ ->Fill (mcConvX_, aConv.conversionVertex().position().x() - mcConvX_ );

       p_convVtxdYVsY_ ->Fill (mcConvY_, aConv.conversionVertex().position().y() - mcConvY_ );

       p_convVtxdZVsZ_ ->Fill (mcConvZ_, aConv.conversionVertex().position().z() - mcConvZ_ );

       p_convVtxdZVsR_ ->Fill (mcConvR_, aConv.conversionVertex().position().z() - mcConvZ_ );


       float dR=sqrt(aConv.conversionVertex().position().perp2()) - mcConvR_;

       float dZ=aConv.conversionVertex().position().z() - mcConvZ_;

       p2_convVtxdRVsRZ_ ->Fill (mcConvZ_,mcConvR_, dR );

       p2_convVtxdZVsRZ_ ->Fill (mcConvZ_,mcConvR_, dZ );


       h2_convVtxRrecVsTrue_ -> Fill (mcConvR_, sqrt(aConv.conversionVertex().position().perp2()) );


       h_zPVFromTracks_[match]->Fill ( aConv.zOfPrimaryVertexFromTracks() );

       h_dzPVFromTracks_[match]->Fill ( aConv.zOfPrimaryVertexFromTracks() - simPV_Z );

       h2_dzPVVsR_ ->Fill(mcConvR_, aConv.zOfPrimaryVertexFromTracks() - simPV_Z );

       p_dzPVVsR_ ->Fill(mcConvR_, aConv.zOfPrimaryVertexFromTracks() - simPV_Z );


       if ( phoIsInBarrel ) {

     h_convVtxdX_barrel_ ->Fill ( aConv.conversionVertex().position().x() - mcConvX_);

     h_convVtxdY_barrel_ ->Fill ( aConv.conversionVertex().position().y() - mcConvY_);

     h_convVtxdZ_barrel_ ->Fill ( aConv.conversionVertex().position().z() - mcConvZ_);

     h_convVtxdR_barrel_ ->Fill ( sqrt(aConv.conversionVertex().position().perp2()) - mcConvR_);


       }

       if ( phoIsInEndcap ) {

     h_convVtxdX_endcap_ ->Fill ( aConv.conversionVertex().position().x() - mcConvX_);

     h_convVtxdY_endcap_ ->Fill ( aConv.conversionVertex().position().y() - mcConvY_);

     h_convVtxdZ_endcap_ ->Fill ( aConv.conversionVertex().position().z() - mcConvZ_);

     h_convVtxdR_endcap_ ->Fill ( sqrt(aConv.conversionVertex().position().perp2()) - mcConvR_);


       }


     }


     for (unsigned int i=0; i<tracks.size(); i++) {

       //std::cout << " Loop over tracks  pt " << tracks[i]->pt() << std::endl;

       RefToBase<reco::Track> tfrb(aConv.tracks()[i] );

       itAss= myAss.find( tfrb.get() );


       nHitsVsEta_[match] ->Fill (mcEta_,   float(tracks[i]->numberOfValidHits()) );

       nHitsVsR_[match] ->Fill (mcConvR_,   float(tracks[i]->numberOfValidHits()) );

       p_nHitsVsEta_[match] ->Fill (mcEta_,   float(tracks[i]->numberOfValidHits()) -0.0001);

       p_nHitsVsR_[match] ->Fill (mcConvR_,   float(tracks[i]->numberOfValidHits()) -0.0001);

       h_tkChi2_[match] ->Fill (tracks[i]->normalizedChi2() );

       h_tkChi2Large_[match] ->Fill (tracks[i]->normalizedChi2() );

       h2_Chi2VsEta_[match] ->Fill(  mcEta_, tracks[i]->normalizedChi2() );

       h2_Chi2VsR_[match] ->Fill(  mcConvR_, tracks[i]->normalizedChi2() );

       p_Chi2VsEta_[match] ->Fill(  mcEta_, tracks[i]->normalizedChi2() );

       p_Chi2VsR_[match] ->Fill(  mcConvR_, tracks[i]->normalizedChi2() );

       double d0;

       if (valid_pvtx){

     d0 = - tracks[i]->dxy(the_pvtx.position());

       } else {

     d0 = tracks[i]->d0();

       }

       h_TkD0_[match]->Fill (d0* tracks[i]->charge() );

       h_nHitsBeforeVtx_[match]->Fill ( aConv.nHitsBeforeVtx().size()>1 ? aConv.nHitsBeforeVtx().at(i) : 0 );

       h_dlClosestHitToVtx_[match]->Fill ( aConv.dlClosestHitToVtx().size()>1 ? aConv.dlClosestHitToVtx().at(i).value() : 0 );

       h_dlClosestHitToVtxSig_[match]->Fill ( aConv.dlClosestHitToVtx().size()>1 ? aConv.dlClosestHitToVtx().at(i).value()/aConv.dlClosestHitToVtx().at(i).error() : 0 );


       if ( itAss == myAss.end()  ) continue;

       reco::Track refTrack= aConv.conversionVertex().refittedTracks()[i];


       float simPt = sqrt( ((*itAss).second)->momentum().perp2() );

       float recPt = refTrack.pt();

       float ptres= recPt - simPt ;

       //float pterror = aConv.tracks()[i]->ptError();

       float pterror = aConv.conversionVertex().refittedTracks()[i].ptError();

       h2_PtRecVsPtSim_[0]->Fill ( simPt, recPt);

       h_TkPtPull_[0] ->Fill(ptres/pterror);

       h2_TkPtPull_[0] ->Fill(mcEta_, ptres/pterror);


       if ( phoIsInBarrel ) {

     h_TkPtPull_[1] ->Fill(ptres/pterror);

     h2_PtRecVsPtSim_[1]->Fill ( simPt, recPt);

       }

       if ( phoIsInEndcap ) {

     h_TkPtPull_[2] ->Fill(ptres/pterror);

     h2_PtRecVsPtSim_[2]->Fill ( simPt, recPt);

       }

     } // end loop over track


   } // loop over reco conversions


   h_nConv_[0][0]->Fill (float(nRecConv_));

   h_nConv_[1][0]->Fill (float(nRecConvAss_));


 }


 void TkConvValidator::endJob() {


   std::string outputFileName = parameters_.getParameter<std::string>("OutputFileName");

   if ( ! isRunCentrally_ ) {

     dbe_->save(outputFileName);

   }


   edm::LogInfo("TkConvValidator") << "Analyzed " << nEvt_  << "\n";

   // std::cout  << "::endJob Analyzed " << nEvt_ << " events " << " with total " << nPho_ << " Photons " << "\n";

   //  std::cout  << "TkConvValidator::endJob Analyzed " << nEvt_ << " events " << "\n";


   return ;

 }


 math::XYZVector TkConvValidator::recalculateMomentumAtFittedVertex ( const MagneticField& mf, const TrackerGeometry& trackerGeom, const  edm::RefToBase<reco::Track>&   tk, const reco::Vertex& vtx) {


   math::XYZVector result;

   Surface::RotationType rot;

   auto scp = new SimpleCylinderBounds(  sqrt(vtx.position().perp2())-0.001f,

                     sqrt(vtx.position().perp2())+0.001f,

                     -fabs(vtx.position().z()),

                      fabs(vtx.position().z())

                                      );

   ReferenceCountingPointer<Cylinder>  theBarrel_(new Cylinder(Cylinder::computeRadius(*scp), Surface::PositionType(0,0,0), rot,scp));


   ReferenceCountingPointer<Disk>      theDisk_(new Disk( Surface::PositionType( 0, 0, vtx.position().z()), rot,

                                    new SimpleDiskBounds( 0,  sqrt(vtx.position().perp2()), -0.001, 0.001) )

                                               );


   const TrajectoryStateOnSurface myTSOS = trajectoryStateTransform::innerStateOnSurface(*tk, trackerGeom, &mf);

   PropagatorWithMaterial propag( anyDirection, 0.000511, &mf );

   TrajectoryStateOnSurface  stateAtVtx;

   stateAtVtx = propag.propagate(myTSOS, *theBarrel_);

   if (!stateAtVtx.isValid() ) {

     stateAtVtx = propag.propagate(myTSOS, *theDisk_);

   }

   if (stateAtVtx.isValid()){

     return  math::XYZVector ( double(stateAtVtx.globalMomentum().x()), double(stateAtVtx.globalMomentum().y()), double(stateAtVtx.globalMomentum().z()));

   } else {

     return  math::XYZVector(0.,0.,0.);

   }


 }


 float TkConvValidator::phiNormalization(float & phi)

 {

   //---Definitions

   const float PI    = 3.1415927;

   const float TWOPI = 2.0*PI;


   if(phi >  PI) {phi = phi - TWOPI;}

   if(phi < -PI) {phi = phi + TWOPI;}


   //  cout << " Float_t PHInormalization out " << PHI << endl;

   return phi;


 }


 float TkConvValidator::etaTransformation(  float EtaParticle , float Zvertex)  {


   //---Definitions

   const float PI    = 3.1415927;


   //---Definitions for ECAL

   const float R_ECAL           = 136.5;

   const float Z_Endcap         = 328.0;

   const float etaBarrelEndcap  = 1.479;


   //---ETA correction


   float Theta = 0.0  ;

   float ZEcal = R_ECAL*sinh(EtaParticle)+Zvertex;


   if(ZEcal != 0.0) Theta = atan(R_ECAL/ZEcal);

   if(Theta<0.0) Theta = Theta+PI ;

   float ETA = - log(tan(0.5*Theta));


   if( fabs(ETA) > etaBarrelEndcap )

     {

       float Zend = Z_Endcap ;

       if(EtaParticle<0.0 )  Zend = -Zend ;

       float Zlen = Zend - Zvertex ;

       float RR = Zlen/sinh(EtaParticle);

       Theta = atan(RR/Zend);

       if(Theta<0.0) Theta = Theta+PI ;

       ETA = - log(tan(0.5*Theta));

     }

   //---Return the result

   return ETA;

   //---end

 }


TrackingComponentsRecord.h

reco::Conversion::conversionVertex
const reco::Vertex & conversionVertex() const
returns the reco conversion vertex
Definition: Conversion.h:97

lxy
double lxy(const math::XYZPoint &myBeamSpot, const Conversion &conv)
Definition: RecoConversionMaker.cc:16

reco::Conversion
Definition: Conversion.h:24

edm::RefToBase::get
value_type const * get() const
Definition: RefToBase.h:212

edm::ParameterSet::getParameter
T getParameter(std::string const &) const

EcalClusterTools.h

edm::ParameterSet::getUntrackedParameter
T getUntrackedParameter(std::string const &, T const &) const

TransientTrackBuilder.h

Propagator::propagate
virtual FreeTrajectoryState propagate(const FreeTrajectoryState &ftsStart, const GlobalPoint &pDest) const final
Definition: Propagator.h:119

i
int i
Definition: DBlmapReader.cc:9

TrackerDigiGeometryRecord.h

TkConvValidator::endRun
virtual void endRun(edm::Run &r, edm::EventSetup const &es)
Definition: TkConvValidator.cc:795

MessageLogger.h

edm::Service
Definition: Service.h:30

reco::Conversion::highPurity
Definition: Conversion.h:38

SimTrack.h

PropagatorWithMaterial.h

reco::Photon::superCluster
reco::SuperClusterRef superCluster() const
Ref to SuperCluster.

GeomDet.h

anyDirection
Definition: PropagationDirection.h:4

TrackingParticleCollection
std::vector< TrackingParticle > TrackingParticleCollection
Definition: HiEvtPlaneFlatProducer.cc:111

PI
#define PI
Definition: HcalBeamMonitor.cc:14

edm::AssociationMap::end
const_iterator end() const
last iterator over the map (read only)
Definition: AssociationMap.h:89

DQMStore::IBooker::bookProfile
MonitorElement * bookProfile(Args &&...args)
Definition: DQMStore.h:157

conv
static HepMC::IO_HEPEVT conv
Definition: BeamHaloProducer.cc:50

reco::Conversion::generalTracksOnly
Definition: Conversion.h:34

edm::Event::getByToken
bool getByToken(EDGetToken token, Handle< PROD > &result) const
Definition: Event.h:449

cppFunctionSkipper.operator
string operator
Definition: cppFunctionSkipper.py:10

edm::Ref< TrackingParticleCollection >

configurableAnalysis::Photon
char Photon[]
Definition: modules.cc:14

reco::Conversion::quality
bool quality(ConversionQuality q) const
Definition: Conversion.h:181

GenParticle.h

ConversionHitChecker.h

reco::Vertex::y
double y() const
y coordinate
Definition: Vertex.h:110

TkConvValidator::recalculateMomentumAtFittedVertex
math::XYZVector recalculateMomentumAtFittedVertex(const MagneticField &mf, const TrackerGeometry &trackerGeom, const edm::RefToBase< reco::Track > &tk, const reco::Vertex &vtx)
Definition: TkConvValidator.cc:1812

reco::Vertex::isValid
bool isValid() const
Tells whether the vertex is valid.
Definition: Vertex.h:60

reco::GenJetCollection
std::vector< GenJet > GenJetCollection
collection of GenJet objects
Definition: GenJetCollection.h:14

reco::Conversion::dlClosestHitToVtx
const std::vector< Measurement1DFloat > & dlClosestHitToVtx() const
Vector of signed decay length with uncertainty from nearest hit on track to the conversion vtx positi...
Definition: Conversion.h:163

MakerMacros.h

edm::Handle< reco::TrackToTrackingParticleAssociator >

edm::AssociationMap::find
const_iterator find(const key_type &k) const
find element with specified reference key
Definition: AssociationMap.h:91

Photon.h

TrackAssociatorRecord.h

PV3DBase::y
T y() const
Definition: PV3DBase.h:63

TkConvValidator::analyze
virtual void analyze(const edm::Event &, const edm::EventSetup &)
Definition: TkConvValidator.cc:803

IdealMagneticFieldRecord
Definition: IdealMagneticFieldRecord.h:11

reco::Conversion::zOfPrimaryVertexFromTracks
double zOfPrimaryVertexFromTracks(const math::XYZPoint &myBeamSpot=math::XYZPoint()) const
Definition: Conversion.h:145

TrackingVertexContainer.h

TrajectoryStateTransform.h

reco::Conversion::distOfMinimumApproach
double distOfMinimumApproach() const
Definition: Conversion.h:125

BoundDisk.h

Conversion.h

reco::Conversion::pairCotThetaSeparation
double pairCotThetaSeparation() const
Delta cot(Theta) where Theta is the angle in the (y,z) plane between the two tracks. Original tracks are used.
Definition: Conversion.cc:209

MagneticField
Definition: MagneticField.h:17

reco::VertexCollection
std::vector< Vertex > VertexCollection
collection of Vertex objects
Definition: VertexFwd.h:9

SimpleDiskBounds.h

TrackFwd.h

reco::Conversion::arbitratedEcalSeeded
Definition: Conversion.h:35

TrackingParticle.h

CaloTopologyRecord.h

edm::Ref::key
key_type key() const
Accessor for product key.
Definition: Ref.h:266

Handle.h

TrajectoryStateOnSurface
Definition: TrajectoryStateOnSurface.h:17

reco::Photon
Definition: Photon.h:22

reco::Vertex::refittedTracks
const std::vector< Track > & refittedTracks() const
Returns the container of refitted tracks.
Definition: Vertex.h:149

TrackTransientTrack.h

reco::Conversion::pairInvariantMass
double pairInvariantMass() const
if nTracks=2 returns the pair invariant mass. Original tracks are used here
Definition: Conversion.cc:190

reco::Vertex::position
const Point & position() const
position
Definition: Vertex.h:106

GoodVertex_cfg.vertexCollection
tuple vertexCollection
Definition: GoodVertex_cfg.py:61

HLT_25ns14e33_v1_cff.InputTag
tuple InputTag
Definition: HLT_25ns14e33_v1_cff.py:45333

CaloGeometryRecord
Definition: CaloGeometryRecord.h:26

edm::RefToBase< reco::Track >

reco::Conversion::refittedPairMomentum
math::XYZVectorF refittedPairMomentum() const
Conversion tracks momentum from the tracks refitted with vertex constraint.
Definition: Conversion.cc:248

q2
double q2[4]
Definition: TauolaWrapper.h:88

HLT_25ns14e33_v1_cff.etaMin
tuple etaMin
Definition: HLT_25ns14e33_v1_cff.py:26057

reco::ConversionCollection
std::vector< Conversion > ConversionCollection
collectin of Conversion objects
Definition: ConversionFwd.h:9

AlCaHLTBitMon_QueryRunRegistry.string
string string
Definition: AlCaHLTBitMon_QueryRunRegistry.py:255

Cylinder
Definition: Cylinder.h:19

TrackerHitAssociator.h

mathSSE::return
return((rh^lh)&mask)

TwoTrackMinimumDistance.h

TFileService.h

TkConvValidator::~TkConvValidator
virtual ~TkConvValidator()
Definition: TkConvValidator.cc:158

ReferenceCountingPointer< Cylinder >

MagneticField.h

reco::TrackBase::algo
TrackAlgorithm algo() const
Definition: TrackBase.h:450

Disk
Definition: BoundDisk.h:19

TkConvValidator::bookHistograms
void bookHistograms(DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
Definition: TkConvValidator.cc:163

dumpDBToFile_GT_ttrig_cfg.outputFileName
tuple outputFileName
Definition: dumpDBToFile_GT_ttrig_cfg.py:31

SimpleCylinderBounds.h

edm::LogError
Definition: MessageLogger.h:164

ETA
#define ETA
Definition: GenericBenchmark.cc:32

CaloClusterFwd.h

ConversionHitChecker
Definition: ConversionHitChecker.h:31

reco::Vertex
Definition: Vertex.h:34

reco::Conversion::arbitratedMerged
Definition: Conversion.h:36

CaloGeometryRecord.h

TrackingRecHit.h

TkConvValidator::etaTransformation
float etaTransformation(float a, float b)
Definition: TkConvValidator.cc:1862

TkConvValidator.h

TkConvValidator::phiNormalization
float phiNormalization(float &a)
Definition: TkConvValidator.cc:1846

CaloCluster.h

TkRotation< float >

DQMStore::IBooker::bookProfile2D
MonitorElement * bookProfile2D(Args &&...args)
Definition: DQMStore.h:163

HcalObjRepresent::Fill
void Fill(HcalDetId &id, double val, std::vector< TH2F > &depth)
Definition: HcalObjRepresent.h:611

mathSSE::sqrt
T sqrt(T t)
Definition: SSEVec.h:48

edm::Exception
Definition: EDMException.h:71

edm::ESHandle< TransientTrackBuilder >

reco::TrackBase::pt
double pt() const
track transverse momentum
Definition: TrackBase.h:574

PV3DBase::z
T z() const
Definition: PV3DBase.h:64

query.result
tuple result
Definition: query.py:137

GenJetCollection.h

TkConvValidator::TkConvValidator
TkConvValidator(const edm::ParameterSet &)
Definition: TkConvValidator.cc:104

DQMStore::IBooker::book1D
MonitorElement * book1D(Args &&...args)
Definition: DQMStore.h:115

funct::tan
Tan< T >::type tan(const T &t)
Definition: Tan.h:22

funct::abs
Abs< T >::type abs(const T &t)
Definition: Abs.h:22

reco::Vertex::chi2
double chi2() const
chi-squares
Definition: Vertex.h:95

TWOPI
#define TWOPI
EgammaCoreTools.
Definition: DQMSourcePi0.cc:40

edm::AssociationMap< edm::OneToManyWithQualityGeneric< TrackingParticleCollection, edm::View< reco::Track >, double > >

edm::RefToBaseVector
Definition: EDProductfwd.h:25

Service.h

SimVertex.h

f
double f[11][100]
Definition: MuScleFitUtils.cc:78

ChiSquaredProbability
float ChiSquaredProbability(double chiSquared, double nrDOF)
Definition: ChiSquaredProbability.cc:13

patCandidatesForDimuonsSequences_cff.tracker
tuple tracker
Definition: patCandidatesForDimuonsSequences_cff.py:69

edm::EventSetup
Definition: EventSetup.h:44

PFRecoTauDiscriminationAgainstElectronDeadECAL_cfi.dR
tuple dR
Definition: PFRecoTauDiscriminationAgainstElectronDeadECAL_cfi.py:19

math::XYZVectorF
ROOT::Math::DisplacementVector3D< ROOT::Math::Cartesian3D< float > > XYZVectorF
spatial vector with cartesian internal representation
Definition: Vector3D.h:17

event
How EventSelector::AcceptEvent() decides whether to accept an event for output otherwise it is excluding the probing of A single or multiple positive and the trigger will pass if any such matching triggers are PASS or EXCEPTION[A criterion thatmatches no triggers at all is detected and causes a throw.] A single negative with an expectation of appropriate bit checking in the decision and the trigger will pass if any such matching triggers are FAIL or EXCEPTION A wildcarded negative criterion that matches more than one trigger in the trigger but the state exists so we define the behavior If all triggers are the negative crieriion will lead to accepting the event(this again matches the behavior of"!*"before the partial wildcard feature was incorporated).The per-event"cost"of each negative criterion with multiple relevant triggers is about the same as!*was in the past

ChiSquaredProbability.h

p2
double p2[4]
Definition: TauolaWrapper.h:90

HepMCProduct.h

DTTTrigCorrFirst.run
run
Definition: DTTTrigCorrFirst.py:63

TkConvValidator::dqmBeginRun
virtual void dqmBeginRun(edm::Run const &r, edm::EventSetup const &theEventSetup)
Definition: TkConvValidator.cc:785

dbe_
DQMStore * dbe_
Definition: PFJetBenchmarkAnalyzer.cc:79

reco::Vertex::ndof
double ndof() const
Definition: Vertex.h:102

TrackCandidateCollection.h

BasicClusterFwd.h

GeomDetUnit.h

edm::LogInfo
Definition: MessageLogger.h:214

reco::deltaPhi
double deltaPhi(double phi1, double phi2)
Definition: deltaPhi.h:12

Exception.h

reco::Vertex::x
double x() const
x coordinate
Definition: Vertex.h:108

reco::Conversion::nSharedHits
uint8_t nSharedHits() const
number of shared hits btw the two track
Definition: Conversion.h:165

DQMStore::IBooker::setCurrentFolder
void setCurrentFolder(const std::string &fullpath)
Definition: DQMStore.cc:274

TrackExtra.h

edm::AssociationMap::size
size_type size() const
map size
Definition: AssociationMap.h:76

DQMStore::IBooker::book2D
MonitorElement * book2D(Args &&...args)
Definition: DQMStore.h:133

reco::TrackBase::hitPattern
const HitPattern & hitPattern() const
Access the hit pattern, indicating in which Tracker layers the track has hits.
Definition: TrackBase.h:411

q1
double q1[4]
Definition: TauolaWrapper.h:87

testEve_cfg.tracks
tuple tracks
Definition: testEve_cfg.py:39

math::XYZVector
XYZVectorD XYZVector
spatial vector with cartesian internal representation
Definition: Vector3D.h:30

reco::PhotonCollection
std::vector< Photon > PhotonCollection
collectin of Photon objects
Definition: PhotonFwd.h:9

edm::EventSetup::get
const T & get() const
Definition: EventSetup.h:55

TkConvValidator::endJob
virtual void endJob()
Definition: TkConvValidator.cc:1796

reco::Track
Definition: Track.h:28

etaBarrelEndcap
static const float etaBarrelEndcap
Definition: ECALPositionCalculator.cc:12

Z_Endcap
static const float Z_Endcap
Definition: ECALPositionCalculator.cc:11

alignCSCRings.e
list e
Definition: alignCSCRings.py:90

bookConverter.max
max
Definition: bookConverter.py:166

Point3DBase< float, GlobalTag >

SimpleCylinderBounds
Definition: SimpleCylinderBounds.h:20

TransientTrackRecord
Definition: TransientTrackRecord.h:12

edm::EventBase::id
edm::EventID id() const
Definition: EventBase.h:60

PhotonMCTruthFinder
Definition: PhotonMCTruthFinder.h:22

TransientTrackRecord.h

SimTrackContainer.h

p1
double p1[4]
Definition: TauolaWrapper.h:89

edm::InputTag
Definition: InputTag.h:17

TrajectoryStateOnSurface::globalMomentum
GlobalVector globalMomentum() const
Definition: TrajectoryStateOnSurface.h:92

Cylinder::computeRadius
static float computeRadius(Bounds const &bounds)
Definition: Cylinder.h:30

deltaPhi.h

PhotonMCTruth.h

TrackerGeometry.h

edm::RefVectorIterator
Definition: EDProductfwd.h:27

edm::RefToBaseVector::push_back
void push_back(const RefToBase< T > &)
Definition: RefToBaseVector.h:258

reco::Conversion::nHitsBeforeVtx
const std::vector< uint8_t > & nHitsBeforeVtx() const
Vector of the number of hits before the vertex along each track trajector.
Definition: Conversion.h:161

TrajectoryStateOnSurface.h

TrajectoryStateOnSurface::isValid
bool isValid() const
Definition: TrajectoryStateOnSurface.h:68

PropagatorWithMaterial
Definition: PropagatorWithMaterial.h:25

HLT_25ns14e33_v1_cff.etMin
tuple etMin
Definition: HLT_25ns14e33_v1_cff.py:2739

R_ECAL
static const float R_ECAL
Definition: ECALPositionCalculator.cc:10

alignCSCRings.r
list r
Definition: alignCSCRings.py:92

SimpleDiskBounds
Definition: SimpleDiskBounds.h:13

edm::ParameterSet
Definition: ParameterSet.h:35

recPt
double recPt
Definition: PFJetBenchmarkAnalyzer.cc:77

match
std::pair< typename Association::data_type::first_type, double > match(Reference key, Association association, bool bestMatchByMaxValue)
Generic matching function.
Definition: Utils.h:10

ElectronMCTruth.h

benchmark_cfg.pdgId
tuple pdgId
Definition: benchmark_cfg.py:18

TrackingParticleFwd.h

edm::Event
Definition: Event.h:59

Track.h

HLT_25ns14e33_v1_cff.etaMax
tuple etaMax
Definition: HLT_25ns14e33_v1_cff.py:26058

TrackerDigiGeometryRecord
Definition: TrackerDigiGeometryRecord.h:32

reco::TrackBase::dxy
double dxy() const
dxy parameter. (This is the transverse impact parameter w.r.t. to (0,0,0) ONLY if refPoint is close t...
Definition: TrackBase.h:544

PhotonMCTruthFinder.h

DQMStore::IBooker
Definition: DQMStore.h:90

PV3DBase::x
T x() const
Definition: PV3DBase.h:62

reco::HitPattern::MISSING_INNER_HITS
Definition: HitPattern.h:153

BasicCluster.h

DetId.h

reco::BeamSpot
Definition: BeamSpot.h:22

BoundCylinder.h

TrackerGeometry
Definition: TrackerGeometry.h:29

FreeTrajectoryState.h

IdealMagneticFieldRecord.h

reco::Conversion::dPhiTracksAtVtx
double dPhiTracksAtVtx() const
Definition: Conversion.cc:313

CaloTopology.h

reco::Conversion::tracks
std::vector< edm::RefToBase< reco::Track > > const & tracks() const
vector of track to base references
Definition: Conversion.cc:176

edm::Run
Definition: Run.h:41

reco::HitPattern::numberOfHits
int numberOfHits(HitCategory category) const
Definition: HitPattern.h:718

makeMuonMisalignmentScenario.rot
list rot
Definition: makeMuonMisalignmentScenario.py:320

trajectoryStateTransform::innerStateOnSurface
TrajectoryStateOnSurface innerStateOnSurface(const reco::Track &tk, const TrackingGeometry &geom, const MagneticField *field, bool withErr=true)
Definition: TrajectoryStateTransform.cc:110

SimVertexContainer.h

cmsBatch.log
tuple log
Definition: cmsBatch.py:347

phi
Definition: DDAxes.h:10

SuperCluster.h