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/TrackerGeometryBuilder/interface/TrackerGeometry.h"
 #include "Geometry/CommonDetUnit/interface/GeomDet.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 "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>(pset.getParameter<edm::InputTag>("simTracks"));
     g4_simVtx_Token_ = consumes<edm::SimVertexContainer>(pset.getParameter<edm::InputTag>("simTracks"));

     tpSelForEff_Token_ = consumes<TrackingParticleRefVector> (
         edm::InputTag("tpSelecForEfficiency"));
     tpSelForFake_Token_ = consumes<TrackingParticleRefVector> (
         edm::InputTag("tpSelecForFakeRate"));
     //hepMC_Token_ = consumes<edm::HepMCProduct>(edm::InputTag("generatorSmeared"));
     //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_ = nullptr;
   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 const& 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");
   TrackingParticleRefVector dummy;
   edm::Handle<TrackingParticleRefVector> TPHandleForEff;
   edm::Handle<TrackingParticleRefVector> TPHandleForFakeRate;
   if (useTP) {
     e.getByToken(tpSelForEff_Token_, TPHandleForEff);
     e.getByToken(tpSelForFake_Token_, TPHandleForFakeRate);
   }

   const TrackingParticleRefVector &tpForEfficiency= useTP? *(TPHandleForEff.product()) : dummy;
   const TrackingParticleRefVector &tpForFakeRate= useTP? *(TPHandleForFakeRate.product()):dummy;

   const std::vector<SimTrack> &theSimTracks= *SimTk;
   const std::vector<SimVertex> &theSimVertices= *SimVtx;

   //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);
   //const 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(const TrackingParticleRef tp: tpForEfficiency) {
     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?
     const 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()==reco::TrackBase::outInEcalSeededConv || tfrb1->algo()==reco::TrackBase::inOutEcalSeededConv) || !(tfrb2->algo()==reco::TrackBase::outInEcalSeededConv || tfrb2->algo()==reco::TrackBase::inOutEcalSeededConv)  )  ) 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.empty()&&!trackV2.empty()))
           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()==reco::TrackBase::outInEcalSeededConv || tk1->algo()==reco::TrackBase::inOutEcalSeededConv) || !(tk2->algo()==reco::TrackBase::outInEcalSeededConv || tk2->algo()==reco::TrackBase::inOutEcalSeededConv)  )  ) 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().numberOfLostHits(reco::HitPattern::MISSING_INNER_HITS)
        - tktrail->hitPattern().numberOfLostHits(reco::HitPattern::MISSING_INNER_HITS);
     int leadExpectedHitsInner = tklead->hitPattern().numberOfLostHits(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(const TrackingParticleRef tp: tpForFakeRate) {
     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 const& p1 =  theTrackAssociator->associateRecoToSim(tc1,theConvTP_);
       reco::RecoToSimCollection const& p2 =  theTrackAssociator->associateRecoToSim(tc2,theConvTP_);

       auto itP1 = p1.find(tk1);
       auto itP2 = p2.find(tk2);
       bool good = (itP1 != p1.end()) and (not itP1->val.empty()) and (itP2 != p2.end()) and (not itP2->val.empty());
       if(not good) {
         itP1 = p1.find(tk2);
         itP2 = p2.find(tk1);
         good = (itP1 != p1.end()) and (not itP1->val.empty()) and (itP2 != p2.end()) and (not itP2->val.empty());
       }

       if(good) {
     std::vector<std::pair<TrackingParticleRef, double> >const& tp1 = itP1->val;
     std::vector<std::pair<TrackingParticleRef, double> >const& tp2 = itP2->val;
         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;
             }
           }
         }
       }

     }// end loop on sim photons


     if (false) {
         theConvTP_.clear();
         theConvTP_ = tpForFakeRate;
         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(TrackingParticleRef tp: tpForFakeRate) {
           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.empty() && !p2incl.empty()) && (!p1.empty() || !p2.empty()) ) { // associated = true;
             try{
               std::vector<std::pair<TrackingParticleRef, double> > tp1 = p1incl[tk1];
               std::vector<std::pair<TrackingParticleRef, double> > tp2 = p2incl[tk2];
               if (!(!tp1.empty()&&!tp2.empty())){
                   tp1 = p1[tk2];
                   tp2 = p2[tk1];
               }
               if (!tp1.empty()&&!tp2.empty()) {
                 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

reco::Conversion
Definition: Conversion.h:24

edm::RefToBase::get
value_type const * get() const
Definition: RefToBase.h:234

edm::ParameterSet::getParameter
T getParameter(std::string const &) const

EcalClusterTools.h

dummy
Definition: DummySelector.h:38

edm::ParameterSet::getUntrackedParameter
T getUntrackedParameter(std::string const &, T const &) const

TransientTrackBuilder.h

TrackerDigiGeometryRecord.h

photonValidator_cfi.dPhiTracksBin
dPhiTracksBin
Definition: photonValidator_cfi.py:70

photonValidator_cfi.dPhiTracksMin
dPhiTracksMin
Definition: photonValidator_cfi.py:71

MessageLogger.h

btagDijet_cfi.etMin
etMin
Definition: btagDijet_cfi.py:5

mps_fire.i
i
Definition: mps_fire.py:269

edm::Service
Definition: Service.h:30

conversionPostprocessing_cfi.rBin
rBin
Definition: conversionPostprocessing_cfi.py:27

tkConvValidator_cfi.maxPhoZForEffic
maxPhoZForEffic
Definition: tkConvValidator_cfi.py:61

photonValidationSequence_cff.eoverpMax
eoverpMax
Definition: photonValidationSequence_cff.py:17

reco::Conversion::highPurity
Definition: Conversion.h:38

SimTrack.h

tkConvValidator_cfi.maxPhoEtaForEffic
maxPhoEtaForEffic
Definition: tkConvValidator_cfi.py:60

PropagatorWithMaterial.h

photonValidator_cfi.rMaxForXray
rMaxForXray
Definition: photonValidator_cfi.py:119

GeomDet.h

mps_fire.result
result
Definition: mps_fire.py:226

anyDirection
Definition: PropagationDirection.h:4

edm::AssociationMap::end
const_iterator end() const
last iterator over the map (read only)
Definition: AssociationMap.h:160

DQMStore::IBooker::bookProfile
MonitorElement * bookProfile(Args &&...args)
Definition: DQMStore.h:160

CSCSegmentAlgorithmDF_cfi.chi2Max
chi2Max
Definition: CSCSegmentAlgorithmDF_cfi.py:11

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:519

edm::Ref< TrackingParticleCollection >

photonValidator_cfi.resMax
resMax
Definition: photonValidator_cfi.py:92

AlCaHLTBitMon_QueryRunRegistry.string
string
Definition: AlCaHLTBitMon_QueryRunRegistry.py:255

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:113

TkConvValidator::recalculateMomentumAtFittedVertex
math::XYZVector recalculateMomentumAtFittedVertex(const MagneticField &mf, const TrackerGeometry &trackerGeom, const edm::RefToBase< reco::Track > &tk, const reco::Vertex &vtx)
Definition: TkConvValidator.cc:1804

reco::Vertex::isValid
bool isValid() const
Tells whether the vertex is valid.
Definition: Vertex.h:68

photonValidator_cfi.zMaxForXray
zMaxForXray
Definition: photonValidator_cfi.py:123

edm::AssociationMap::empty
bool empty() const
return true if empty
Definition: AssociationMap.h:149

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:162

Photon.h

TrackAssociatorRecord.h

tkConvValidator_cfi.maxPhoRForEffic
maxPhoRForEffic
Definition: tkConvValidator_cfi.py:62

PV3DBase::y
T y() const
Definition: PV3DBase.h:63

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

muonDTDigis_cfi.pset
pset
Definition: muonDTDigis_cfi.py:27

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:19

reco::VertexCollection
std::vector< Vertex > VertexCollection
collection of Vertex objects
Definition: VertexFwd.h:9

SimpleDiskBounds.h

std
Definition: JetResolutionObject.h:76

TrackFwd.h

TkConvValidator::endJob
void endJob() override
Definition: TkConvValidator.cc:1788

reco::Conversion::arbitratedEcalSeeded
Definition: Conversion.h:35

reco::TrackBase::outInEcalSeededConv
Definition: TrackBase.h:113

TrackingParticle.h

photonValidator_cfi.resMin
resMin
Definition: photonValidator_cfi.py:91

CaloTopologyRecord.h

edm::Ref::key
key_type key() const
Accessor for product key.
Definition: Ref.h:265

MillePedeFileConverter_cfg.e
e
Definition: MillePedeFileConverter_cfg.py:37

TrajectoryStateOnSurface
Definition: TrajectoryStateOnSurface.h:17

reco::Photon
Definition: Photon.h:22

reco::Photon::superCluster
reco::SuperClusterRef superCluster() const  override
Ref to SuperCluster.

reco::Vertex::refittedTracks
const std::vector< Track > & refittedTracks() const
Returns the container of refitted tracks.
Definition: Vertex.h:164

correctedPhotons_cfi.photonCollection
photonCollection
Definition: correctedPhotons_cfi.py:12

ALCARECOTkAlBeamHalo_cff.etaMin
etaMin
GeV.
Definition: ALCARECOTkAlBeamHalo_cff.py:32

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:109

CaloGeometryRecord
Definition: CaloGeometryRecord.h:31

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

reco::ConversionCollection
std::vector< Conversion > ConversionCollection
collectin of Conversion objects
Definition: ConversionFwd.h:9

Cylinder
Definition: Cylinder.h:19

photonValidator_cfi.rBinForXray
rBinForXray
Definition: photonValidator_cfi.py:117

TrackerHitAssociator.h

TwoTrackMinimumDistance.h

TFileService.h

ReferenceCountingPointer< Cylinder >

conversionPostprocessing_cfi.zMin
zMin
Definition: conversionPostprocessing_cfi.py:32

MagneticField.h

reco::TrackBase::algo
TrackAlgorithm algo() const
Definition: TrackBase.h:497

Disk
Definition: BoundDisk.h:19

TkConvValidator::bookHistograms
void bookHistograms(DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
Definition: TkConvValidator.cc:161

SimpleCylinderBounds.h

photonValidator_cfi.eoverpBin
eoverpBin
Definition: photonValidator_cfi.py:106

edm::LogError
Definition: MessageLogger.h:166

TkConvValidator::endRun
void endRun(edm::Run const &r, edm::EventSetup const &es) override
Definition: TkConvValidator.cc:793

photonValidator_cfi.zMinForXray
zMinForXray
Definition: photonValidator_cfi.py:122

ETA
#define ETA
Definition: GenericBenchmark.cc:32

AlignmentTrackSelector_cfi.phiMin
phiMin
Definition: AlignmentTrackSelector_cfi.py:18

CaloClusterFwd.h

ConversionHitChecker
Definition: ConversionHitChecker.h:31

reco::Vertex
Definition: Vertex.h:34

reco::Conversion::arbitratedMerged
Definition: Conversion.h:36

CaloGeometryRecord.h

TrackingRecHit.h

photonValidator_cfi.rMinForXray
rMinForXray
Definition: photonValidator_cfi.py:118

TkConvValidator::etaTransformation
float etaTransformation(float a, float b)
Definition: TkConvValidator.cc:1854

Utilities.operator
operator
Definition: Utilities.py:23

TkConvValidator.h

TkConvValidator::phiNormalization
float phiNormalization(float &a)
Definition: TkConvValidator.cc:1838

CaloCluster.h

tkConvValidator_cfi.maxPhoEtaForPurity
maxPhoEtaForPurity
Definition: tkConvValidator_cfi.py:64

TkRotation< float >

DQMStore::IBooker::bookProfile2D
MonitorElement * bookProfile2D(Args &&...args)
Definition: DQMStore.h:166

HcalObjRepresent::Fill
void Fill(HcalDetId &id, double val, std::vector< TH2F > &depth)
Definition: HcalObjRepresent.h:611

photonValidator_cfi.zBinForXray
zBinForXray
Definition: photonValidator_cfi.py:120

conversionPostprocessing_cfi.zMax
zMax
Definition: conversionPostprocessing_cfi.py:33

mathSSE::sqrt
T sqrt(T t)
Definition: SSEVec.h:18

edm::Exception
Definition: EDMException.h:73

edm::ESHandle< TransientTrackBuilder >

conversionPostprocessing_cfi.etaBin
etaBin
Definition: conversionPostprocessing_cfi.py:18

reco::TrackBase::pt
double pt() const
track transverse momentum
Definition: TrackBase.h:621

PV3DBase::z
T z() const
Definition: PV3DBase.h:64

photonValidator_cfi.dCotTracksMax
dCotTracksMax
Definition: photonValidator_cfi.py:100

TkConvValidator::~TkConvValidator
~TkConvValidator() override
Definition: TkConvValidator.cc:156

GenJetCollection.h

l1t::tracks
Definition: MicroGMTCancelOutUnit.h:12

TkConvValidator::TkConvValidator
TkConvValidator(const edm::ParameterSet &)
Definition: TkConvValidator.cc:102

DQMStore::IBooker::book1D
MonitorElement * book1D(Args &&...args)
Definition: DQMStore.h:118

photonValidator_cfi.dCotTracksMin
dCotTracksMin
Definition: photonValidator_cfi.py:99

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

postProcessorL1Gen_cff.outputFileName
outputFileName
Definition: postProcessorL1Gen_cff.py:26

reco::Vertex::chi2
double chi2() const
chi-squares
Definition: Vertex.h:98

TWOPI
#define TWOPI
Definition: DQMSourcePi0.cc:37

conversionPostprocessing_cfi.zBin
zBin
Definition: conversionPostprocessing_cfi.py:31

edm::AssociationMap< edm::OneToManyWithQualityGeneric< TrackingParticleCollection, edm::View< reco::Track >, double > >

edm::RefToBaseVector< reco::Track >

Service.h

SimVertex.h

f
double f[11][100]
Definition: MuScleFitUtils.cc:78

ChiSquaredProbability
float ChiSquaredProbability(double chiSquared, double nrDOF)
Definition: ChiSquaredProbability.cc:13

edm::EventSetup
Definition: EventSetup.h:48

conversionPostprocessing_cfi.rMax
rMax
Definition: conversionPostprocessing_cfi.py:29

math::XYZVectorF
ROOT::Math::DisplacementVector3D< ROOT::Math::Cartesian3D< float > > XYZVectorF
spatial vector with cartesian internal representation
Definition: Vector3D.h:17

ALCARECOTkAlJpsiMuMu_cff.charge
charge
Definition: ALCARECOTkAlJpsiMuMu_cff.py:47

ChiSquaredProbability.h

edm::HandleBase::isValid
bool isValid() const
Definition: HandleBase.h:74

SiStripPI::max
Definition: SiStripPayloadInspectorHelper.h:26

ALCARECOTkAlBeamHalo_cff.etaMax
etaMax
Definition: ALCARECOTkAlBeamHalo_cff.py:33

p2
double p2[4]
Definition: TauolaWrapper.h:90

PI
#define PI
Definition: QcdUeDQM.h:36

HepMCProduct.h

findQualityFiles.run
run
Definition: findQualityFiles.py:408

dbe_
DQMStore * dbe_
Definition: PFJetBenchmarkAnalyzer.cc:79

reco::Vertex::ndof
double ndof() const
Definition: Vertex.h:105

TrackCandidateCollection.h

BasicClusterFwd.h

edm::LogInfo
Definition: MessageLogger.h:216

PFRecoTauDiscriminationAgainstElectronDeadECAL_cfi.dR
dR
Definition: PFRecoTauDiscriminationAgainstElectronDeadECAL_cfi.py:19

alignCSCRings.r
r
Definition: alignCSCRings.py:92

reco::deltaPhi
double deltaPhi(double phi1, double phi2)
Definition: deltaPhi.h:22

Exception.h

reco::Vertex::x
double x() const
x coordinate
Definition: Vertex.h:111

photonValidator_cfi.dCotTracksBin
dCotTracksBin
Definition: photonValidator_cfi.py:98

tkConvValidator_cfi.maxPhoRForPurity
maxPhoRForPurity
Definition: tkConvValidator_cfi.py:66

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:279

TrackExtra.h

edm::Handle::product
T const * product() const
Definition: Handle.h:81

DQMStore::IBooker::book2D
MonitorElement * book2D(Args &&...args)
Definition: DQMStore.h:136

reco::TrackBase::hitPattern
const HitPattern & hitPattern() const
Access the hit pattern, indicating in which Tracker layers the track has hits.
Definition: TrackBase.h:446

reco::TrackToTrackingParticleAssociator::associateRecoToSim
reco::RecoToSimCollection associateRecoToSim(const edm::Handle< edm::View< reco::Track > > &tCH, const edm::Handle< TrackingParticleCollection > &tPCH) const
compare reco to sim the handle of reco::Track and TrackingParticle collections
Definition: TrackToTrackingParticleAssociator.h:65

common_cff.pdgId
pdgId
Definition: common_cff.py:54

q1
double q1[4]
Definition: TauolaWrapper.h:87

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:59

mixOne_simraw_on_sim_cfi.tracker
tracker
Definition: mixOne_simraw_on_sim_cfi.py:265

parallelization.uint
def uint(string)
Definition: parallelization.py:49

photonValidationSequence_cff.eoverpMin
eoverpMin
Definition: photonValidationSequence_cff.py:16

edm::RefVector< TrackingParticleCollection >

photonValidator_cfi.zBin2ForXray
zBin2ForXray
Definition: photonValidator_cfi.py:121

conversionPostprocessing_cfi.etBin
etBin
Definition: conversionPostprocessing_cfi.py:14

reco::Track
Definition: Track.h:28

Propagator::propagate
TrajectoryStateOnSurface propagate(STA const &state, SUR const &surface) const
Definition: Propagator.h:53

etaBarrelEndcap
static const float etaBarrelEndcap
Definition: ECALPositionCalculator.cc:12

photonValidator_cfi.resBin
resBin
Definition: photonValidator_cfi.py:90

reco::HitPattern::numberOfLostHits
int numberOfLostHits(HitCategory category) const
Definition: HitPattern.h:902

Z_Endcap
static const float Z_Endcap
Definition: ECALPositionCalculator.cc:11

cmsBatch.log
log
Definition: cmsBatch.py:341

reco::return
return(e1-e2)*(e1-e2)+dp *dp

particleFlowSuperClusterECAL_cfi.vertexCollection
vertexCollection
Definition: particleFlowSuperClusterECAL_cfi.py:41

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

edm
HLT enums.
Definition: AlignableModifier.h:17

p1
double p1[4]
Definition: TauolaWrapper.h:89

edm::InputTag
Definition: InputTag.h:15

TrajectoryStateOnSurface::globalMomentum
GlobalVector globalMomentum() const
Definition: TrajectoryStateOnSurface.h:86

Cylinder::computeRadius
static float computeRadius(Bounds const &bounds)
Definition: Cylinder.h:30

conversionPostprocessing_cfi.etaBin2
etaBin2
Definition: conversionPostprocessing_cfi.py:19

allConversions_cfi.d0
d0
Definition: allConversions_cfi.py:30

deltaPhi.h

PhotonMCTruth.h

tkConvValidator_cfi.minPhoPtForEffic
minPhoPtForEffic
Definition: tkConvValidator_cfi.py:59

TrackerGeometry.h

edm::RefVectorIterator
Definition: EDProductfwd.h:26

edm::RefToBaseVector::push_back
void push_back(const RefToBase< T > &)
Definition: RefToBaseVector.h:264

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:62

PropagatorWithMaterial
Definition: PropagatorWithMaterial.h:25

reco::BeamSpot::y0
double y0() const
y coordinate
Definition: BeamSpot.h:66

R_ECAL
static const float R_ECAL
Definition: ECALPositionCalculator.cc:10

photonValidator_cfi.dPhiTracksMax
dPhiTracksMax
Definition: photonValidator_cfi.py:72

conversionPostprocessing_cfi.rMin
rMin
Definition: conversionPostprocessing_cfi.py:28

SimpleDiskBounds
Definition: SimpleDiskBounds.h:13

edm::ParameterSet
Definition: ParameterSet.h:36

TkConvValidator::analyze
void analyze(const edm::Event &, const edm::EventSetup &) override
Definition: TkConvValidator.cc:801

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

photonValidationSequence_cff.useTP
useTP
Definition: photonValidationSequence_cff.py:14

badGlobalMuonTaggersAOD_cff.vtx
vtx
Definition: badGlobalMuonTaggersAOD_cff.py:5

ElectronMCTruth.h

reco::TrackToTrackingParticleAssociator::associateSimToReco
reco::SimToRecoCollection associateSimToReco(const edm::Handle< edm::View< reco::Track > > &tCH, const edm::Handle< TrackingParticleCollection > &tPCH) const
compare reco to sim the handle of reco::Track and TrackingParticle collections
Definition: TrackToTrackingParticleAssociator.h:71

TrackingParticleFwd.h

tkConvValidator_cfi.maxPhoZForPurity
maxPhoZForPurity
Definition: tkConvValidator_cfi.py:65

edm::Event
Definition: Event.h:69

Track.h

TrackerDigiGeometryRecord
Definition: TrackerDigiGeometryRecord.h:15

AlignmentTrackSelector_cfi.phiMax
phiMax
Definition: AlignmentTrackSelector_cfi.py:17

PhotonMCTruthFinder.h

DQMStore::IBooker
Definition: DQMStore.h:93

PV3DBase::x
T x() const
Definition: PV3DBase.h:62

conversionPostprocessing_cfi.phiBin
phiBin
Definition: conversionPostprocessing_cfi.py:23

reco::HitPattern::MISSING_INNER_HITS
Definition: HitPattern.h:163

BasicCluster.h

conversionPostprocessing_cfi.etMax
etMax
Definition: conversionPostprocessing_cfi.py:16

edm::ESHandle::product
T const * product() const
Definition: ESHandle.h:86

DetId.h

tkConvValidator_cfi.minPhoPtForPurity
minPhoPtForPurity
Definition: tkConvValidator_cfi.py:63

reco::BeamSpot
Definition: BeamSpot.h:22

muonBadTrackFilter_cfi.chi2Min
chi2Min
Definition: muonBadTrackFilter_cfi.py:8

BoundCylinder.h

TrackerGeometry
Definition: TrackerGeometry.h:14

reco::TrackBase::inOutEcalSeededConv
Definition: TrackBase.h:113

makeMuonMisalignmentScenario.rot
rot
Definition: makeMuonMisalignmentScenario.py:320

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

event
Definition: event.py:1

edm::Run
Definition: Run.h:43

nanoDQM_cfi.Photon
Photon
Definition: nanoDQM_cfi.py:328

Handle.h

trajectoryStateTransform::innerStateOnSurface
TrajectoryStateOnSurface innerStateOnSurface(const reco::Track &tk, const TrackingGeometry &geom, const MagneticField *field, bool withErr=true)
Definition: TrajectoryStateTransform.cc:110

SimVertexContainer.h

reco::BeamSpot::x0
double x0() const
x coordinate
Definition: BeamSpot.h:64

TkConvValidator::dqmBeginRun
void dqmBeginRun(edm::Run const &r, edm::EventSetup const &theEventSetup) override
Definition: TkConvValidator.cc:783

SuperCluster.h