PhotonValidator Class Reference

#include <PhotonValidator.h>

Inheritance diagram for PhotonValidator:

Classes
class	sortPhotons

Public Member Functions
virtual void	analyze (const edm::Event &, const edm::EventSetup &) override
void	bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
virtual void	dqmBeginRun (edm::Run const &r, edm::EventSetup const &theEventSetup) override
virtual void	endRun (edm::Run const &r, edm::EventSetup const &es) override
	PhotonValidator (const edm::ParameterSet &)
virtual	~PhotonValidator ()
Public Member Functions inherited from DQMEDAnalyzer
virtual void	beginRun (edm::Run const &, edm::EventSetup const &) final
virtual void	beginStream (edm::StreamID id) final
	DQMEDAnalyzer (void)
virtual void	endLuminosityBlockSummary (edm::LuminosityBlock const &, edm::EventSetup const &, dqmDetails::NoCache *) const final
virtual void	endRunSummary (edm::Run const &, edm::EventSetup const &, dqmDetails::NoCache *) const final
uint32_t	streamId () const
Public Member Functions inherited from edm::stream::EDAnalyzer< edm::RunSummaryCache< dqmDetails::NoCache >, edm::LuminosityBlockSummaryCache< dqmDetails::NoCache > >
	EDAnalyzer ()=default
Public Member Functions inherited from edm::stream::EDAnalyzerBase
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)
	EDAnalyzerBase ()
ModuleDescription const &	moduleDescription () const
virtual	~EDAnalyzerBase ()
Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfo >	consumesInfo () const
	EDConsumerBase ()
ProductHolderIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const
void	itemsMayGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const
void	itemsToGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const
std::vector < ProductHolderIndexAndSkipBit > const &	itemsToGetFromEvent () const
void	labelsForToken (EDGetToken iToken, Labels &oLabels) const
void	modulesDependentUpon (const std::string &iProcessName, std::vector< const char * > &oModuleLabels) const
void	modulesWhoseProductsAreConsumed (std::vector< ModuleDescription const * > &modules, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const
bool	registeredToConsume (ProductHolderIndex, bool, BranchType) const
bool	registeredToConsumeMany (TypeID const &, BranchType) const
void	updateLookup (BranchType iBranchType, ProductHolderIndexHelper const &)
virtual	~EDConsumerBase ()

Private Member Functions
float	etaTransformation (float a, float b)
float	phiNormalization (float &a)

Private Attributes
edm::EDGetTokenT < EcalRecHitCollection >	barrelEcalHits_
edm::InputTag	bcBarrelCollection_
edm::InputTag	bcEndcapCollection_
double	bcEtLow_
edm::EDGetTokenT< edm::View < reco::Track > >	conversionIOTrackPr_Token_
edm::InputTag	conversionIOTrackProducer_
edm::EDGetTokenT< edm::View < reco::Track > >	conversionOITrackPr_Token_
edm::InputTag	conversionOITrackProducer_
double	convTrackMinPtCut_
bool	dCotCutOn_
double	dCotCutValue_
double	dCotHardCutValue_
double	ecalEtSumCut_
double	ecalIsolRadius_
edm::EDGetTokenT < EcalRecHitCollection >	endcapEcalHits_
edm::EDGetTokenT < edm::SimTrackContainer >	famos_simTk_Token_
edm::EDGetTokenT < edm::SimVertexContainer >	famos_simVtx_Token_
bool	fastSim_
std::string	fName_
edm::EDGetTokenT < edm::SimTrackContainer >	g4_simTk_Token_
edm::EDGetTokenT < edm::SimVertexContainer >	g4_simVtx_Token_
edm::EDGetTokenT < reco::GenJetCollection >	genjets_Token_
MonitorElement *	h2_Chi2VsEta_ [3]
MonitorElement *	h2_Chi2VsR_ [3]
MonitorElement *	h2_convVtxdRVsEta_
MonitorElement *	h2_convVtxdRVsR_
MonitorElement *	h2_convVtxRrecVsTrue_
MonitorElement *	h2_DCotTracksVsEta_
MonitorElement *	h2_DCotTracksVsR_
MonitorElement *	h2_DPhiTracksAtEcalVsEta_
MonitorElement *	h2_DPhiTracksAtEcalVsR_
MonitorElement *	h2_DPhiTracksAtVtxVsEta_
MonitorElement *	h2_DPhiTracksAtVtxVsR_
MonitorElement *	h2_dzPVVsR_
MonitorElement *	h2_ecalRecHitSumEtConeDR04VsEt_ [3]
MonitorElement *	h2_ecalRecHitSumEtConeDR04VsEta_ [3]
MonitorElement *	h2_ecalRecHitSumEtConeDR04VsEtaBkg_
MonitorElement *	h2_ecalRecHitSumEtConeDR04VsEtBkg_ [3]
MonitorElement *	h2_EoverEtrueVsEoverP_ [3]
MonitorElement *	h2_EoverEtrueVsEta_ [3]
MonitorElement *	h2_EoverEtrueVsR_ [3]
MonitorElement *	h2_EoverPVsEta_ [3]
MonitorElement *	h2_EoverPVsR_ [3]
MonitorElement *	h2_eResVsEt_ [3][3]
MonitorElement *	h2_eResVsEta_ [3]
MonitorElement *	h2_eResVsR9_ [3]
MonitorElement *	h2_etaVsRreco_ [3]
MonitorElement *	h2_etaVsRsim_ [3]
MonitorElement *	h2_hcalTowerSumEtConeDR04VsEt_ [3]
MonitorElement *	h2_hcalTowerSumEtConeDR04VsEta_ [3]
MonitorElement *	h2_hcalTowerSumEtConeDR04VsEtaBkg_
MonitorElement *	h2_hcalTowerSumEtConeDR04VsEtBkg_ [3]
MonitorElement *	h2_hOverEVsEt_ [3]
MonitorElement *	h2_hOverEVsEta_ [3]
MonitorElement *	h2_hOverEVsEtaBkg_
MonitorElement *	h2_hOverEVsEtBkg_
MonitorElement *	h2_isoTrkSolidConeDR04VsEt_ [3]
MonitorElement *	h2_isoTrkSolidConeDR04VsEta_ [3]
MonitorElement *	h2_isoTrkSolidConeDR04VsEtaBkg_
MonitorElement *	h2_isoTrkSolidConeDR04VsEtBkg_ [3]
MonitorElement *	h2_nTrkSolidConeDR04VsEt_ [3]
MonitorElement *	h2_nTrkSolidConeDR04VsEta_ [3]
MonitorElement *	h2_nTrkSolidConeDR04VsEtaBkg_
MonitorElement *	h2_nTrkSolidConeDR04VsEtBkg_ [3]
MonitorElement *	h2_PoverPtrueVsEoverP_ [3]
MonitorElement *	h2_PoverPtrueVsEta_ [3]
MonitorElement *	h2_PtRecVsPtSim_ [3]
MonitorElement *	h2_PtRecVsPtSimMixProv_
MonitorElement *	h2_r1VsEt_ [3]
MonitorElement *	h2_r1VsEta_ [3]
MonitorElement *	h2_r1VsEtaBkg_
MonitorElement *	h2_r1VsEtBkg_
MonitorElement *	h2_r2VsEt_ [3]
MonitorElement *	h2_r2VsEta_ [3]
MonitorElement *	h2_r2VsEtaBkg_
MonitorElement *	h2_r2VsEtBkg_
MonitorElement *	h2_r9VsEt_ [3]
MonitorElement *	h2_r9VsEtaBkg_
MonitorElement *	h2_r9VsEtBkg_
MonitorElement *	h2_sceResVsR9_ [3]
MonitorElement *	h2_sigmaIetaIetaVsEt_ [3]
MonitorElement *	h2_sigmaIetaIetaVsEta_ [3]
MonitorElement *	h2_sigmaIetaIetaVsEtaBkg_
MonitorElement *	h2_sigmaIetaIetaVsEtBkg_ [3]
MonitorElement *	h2_TkPtPull_ [3]
MonitorElement *	h_AllSimConv_ [5]
MonitorElement *	h_chHadIso_ [3]
MonitorElement *	h_convAlgo_
MonitorElement *	h_convERes_ [2][3]
MonitorElement *	h_convEta_ [3]
MonitorElement *	h_convEtaBkg_
MonitorElement *	h_convPhi_ [2]
MonitorElement *	h_convPhiBkg_
MonitorElement *	h_convPtRes_ [2][3]
MonitorElement *	h_convQuality_
MonitorElement *	h_convSLVtxRvsZ_ [3]
MonitorElement *	h_convVtxdEta_
MonitorElement *	h_convVtxdPhi_
MonitorElement *	h_convVtxdR_
MonitorElement *	h_convVtxdR_barrel_
MonitorElement *	h_convVtxdR_endcap_
MonitorElement *	h_convVtxdX_
MonitorElement *	h_convVtxdX_barrel_
MonitorElement *	h_convVtxdX_endcap_
MonitorElement *	h_convVtxdY_
MonitorElement *	h_convVtxdY_barrel_
MonitorElement *	h_convVtxdY_endcap_
MonitorElement *	h_convVtxdZ_
MonitorElement *	h_convVtxdZ_barrel_
MonitorElement *	h_convVtxdZ_endcap_
MonitorElement *	h_convVtxRvsZ_ [3]
MonitorElement *	h_convVtxRvsZ_zoom_ [2]
MonitorElement *	h_convVtxRvsZBkg_ [2]
MonitorElement *	h_convVtxYvsX_
MonitorElement *	h_convVtxYvsX_zoom_ [2]
MonitorElement *	h_convVtxYvsXBkg_
MonitorElement *	h_DCotTracks_ [2][3]
MonitorElement *	h_DCotTracksBkg_ [3]
MonitorElement *	h_DEtaTracksAtEcal_ [2][3]
MonitorElement *	h_distMinAppTracks_ [2][3]
MonitorElement *	h_DPhiTracksAtEcal_ [2][3]
MonitorElement *	h_DPhiTracksAtVtx_ [2][3]
MonitorElement *	h_DPhiTracksAtVtxBkg_ [3]
MonitorElement *	h_dRPhoPFcand_ChHad_Cleaned_ [3]
MonitorElement *	h_dRPhoPFcand_ChHad_unCleaned_ [3]
MonitorElement *	h_dRPhoPFcand_NeuHad_Cleaned_ [3]
MonitorElement *	h_dRPhoPFcand_NeuHad_unCleaned_ [3]
MonitorElement *	h_dRPhoPFcand_Pho_Cleaned_ [3]
MonitorElement *	h_dRPhoPFcand_Pho_unCleaned_ [3]
MonitorElement *	h_dzPVFromTracks_ [5]
MonitorElement *	h_ecalRecHitSumEtConeDR04_ [3][3]
MonitorElement *	h_ecalRecHitSumEtConeDR04Bkg_ [3]
MonitorElement *	h_EoverP_SL_ [3]
MonitorElement *	h_EoverPTracks_ [2][3]
MonitorElement *	h_EoverPTracksBkg_ [3]
MonitorElement *	h_etOutsideMustache_ [3]
MonitorElement *	h_EtR9Less093_ [3][3]
MonitorElement *	h_gamgamMass_ [3][3]
MonitorElement *	h_gamgamMassRegr1_ [3][3]
MonitorElement *	h_gamgamMassRegr2_ [3][3]
MonitorElement *	h_hcalTowerBcSumEtConeDR04_ [3][3]
MonitorElement *	h_hcalTowerSumEtConeDR04_ [3][3]
MonitorElement *	h_hcalTowerSumEtConeDR04Bkg_ [3]
MonitorElement *	h_hOverE_ [3][3]
MonitorElement *	h_hOverEBkg_ [3]
MonitorElement *	h_invMass_ [2][3]
MonitorElement *	h_IOinnermostHitR_
MonitorElement *	h_isoTrkSolidConeDR04_ [3][3]
MonitorElement *	h_isoTrkSolidConeDR04Bkg_ [3]
MonitorElement *	h_MatchedSimJet_ [3]
MonitorElement *	h_MatchedSimJetBadCh_ [3]
MonitorElement *	h_MatchedSimPho_ [3]
	Numerator for efficiencies. More...
MonitorElement *	h_MatchedSimPhoBadCh_ [3]
MonitorElement *	h_mvaOut_ [3]
MonitorElement *	h_mvaOutBkg_ [3]
MonitorElement *	h_nCluOutsideMustache_ [3]
MonitorElement *	h_nConv_ [2][3]
	info per conversion More...
MonitorElement *	h_newhOverE_ [3][3]
MonitorElement *	h_nHadIso_ [3]
MonitorElement *	h_nPho_
MonitorElement *	h_nRecoVtx_
MonitorElement *	h_nSimConv_ [2]
MonitorElement *	h_nSimPho_ [2]
MonitorElement *	h_nTrkSolidConeDR04_ [3][3]
MonitorElement *	h_nTrkSolidConeDR04Bkg_ [3]
MonitorElement *	h_OIinnermostHitR_
MonitorElement *	h_pfMva_ [3]
MonitorElement *	h_phoBkgDEta_
MonitorElement *	h_phoBkgDPhi_
MonitorElement *	h_phoBkgE_ [3]
MonitorElement *	h_phoBkgEt_ [3]
MonitorElement *	h_phoBkgEta_
MonitorElement *	h_phoBkgPhi_
MonitorElement *	h_phoDEta_ [2]
MonitorElement *	h_phoDPhi_ [2]
MonitorElement *	h_phoE_ [2][3]
MonitorElement *	h_phoERes_ [3][3]
MonitorElement *	h_phoEResRegr1_ [3][3]
MonitorElement *	h_phoEResRegr2_ [3][3]
MonitorElement *	h_phoEt_ [2][3]
MonitorElement *	h_phoEta_ [2]
MonitorElement *	h_phoIso_ [3]
MonitorElement *	h_phoPhi_ [2]
MonitorElement *	h_phoPixSeedSize_ [2]
MonitorElement *	h_phoSigmaEoE_ [3][3]
MonitorElement *	h_PoverETracks_ [2][3]
MonitorElement *	h_PoverETracksBkg_ [3]
MonitorElement *	h_psE_
MonitorElement *	h_r1_ [3][3]
MonitorElement *	h_r1Bkg_ [3]
MonitorElement *	h_r2_ [3][3]
MonitorElement *	h_r2Bkg_ [3]
MonitorElement *	h_r9_ [3][3]
MonitorElement *	h_r9Bkg_ [3]
MonitorElement *	h_r9VsNofTracks_ [2][3]
MonitorElement *	h_RecoConvTwoMTracks_ [5]
MonitorElement *	h_RecoConvTwoTracks_ [5]
MonitorElement *	h_scBkgE_ [3]
MonitorElement *	h_scBkgEt_ [3]
MonitorElement *	h_scBkgEta_
MonitorElement *	h_scBkgPhi_
MonitorElement *	h_scE_ [2][3]
MonitorElement *	h_scEt_ [2][3]
MonitorElement *	h_scEta_ [2]
MonitorElement *	h_scEtaPhi_ [2]
MonitorElement *	h_scEtaWidth_ [2]
MonitorElement *	h_scPhi_ [2]
MonitorElement *	h_scPhiWidth_ [2]
MonitorElement *	h_sigmaIetaIeta_ [3][3]
MonitorElement *	h_sigmaIetaIetaBkg_ [3]
MonitorElement *	h_SimConvEtaPix_ [2]
MonitorElement *	h_SimConvMTotal_ [5]
MonitorElement *	h_SimConvOneMTracks_ [5]
MonitorElement *	h_SimConvOneTracks_ [5]
MonitorElement *	h_SimConvTwoMTracks_ [5]
MonitorElement *	h_SimConvTwoMTracksAndVtxPGT0005_ [5]
MonitorElement *	h_SimConvTwoMTracksAndVtxPGT01_ [5]
MonitorElement *	h_SimConvTwoMTracksAndVtxPGT0_ [5]
MonitorElement *	h_SimConvTwoTracks_ [5]
MonitorElement *	h_simConvVtxRvsZ_ [4]
MonitorElement *	h_simConvVtxYvsX_
MonitorElement *	h_SimJet_ [3]
MonitorElement *	h_SimPho_ [3]
	Denominator for efficiencies. More...
MonitorElement *	h_SimPhoEtaSmallR9_
MonitorElement *	h_SimPhoMotherEt_ [2]
MonitorElement *	h_SimPhoMotherEta_ [2]
MonitorElement *	h_SimPhoMotherType_ [2]
MonitorElement *	h_simTkEta_
MonitorElement *	h_simTkPt_
MonitorElement *	h_SumPtOverPhoPt_ChHad_Cleaned_ [3]
MonitorElement *	h_SumPtOverPhoPt_ChHad_unCleaned_ [3]
MonitorElement *	h_SumPtOverPhoPt_NeuHad_Cleaned_ [3]
MonitorElement *	h_SumPtOverPhoPt_NeuHad_unCleaned_ [3]
MonitorElement *	h_SumPtOverPhoPt_Pho_Cleaned_ [3]
MonitorElement *	h_SumPtOverPhoPt_Pho_unCleaned_ [3]
MonitorElement *	h_tkChi2_ [2]
MonitorElement *	h_tkChi2Bkg_
MonitorElement *	h_tkChi2Large_ [2]
MonitorElement *	h_tkChi2SL_ [2]
MonitorElement *	h_TkD0_ [3]
MonitorElement *	h_TkPtPull_ [3]
MonitorElement *	h_trkAlgo_
MonitorElement *	h_trkProv_ [2]
MonitorElement *	h_VisSimConv_ [6]
MonitorElement *	h_VisSimConvLarge_
MonitorElement *	h_vtxChi2_ [3]
MonitorElement *	h_vtxChi2Prob_ [3]
MonitorElement *	h_zPVFromTracks_ [5]
MonitorElement *	hBCEnergyOverTrackPout_ [3]
double	hcalEtSumCut_
double	hcalHitEtLow_
double	hcalIsolExtRadius_
double	hcalIsolInnRadius_
edm::EDGetTokenT < edm::HepMCProduct >	hepMC_Token_
bool	isRunCentrally_
double	likelihoodCut_
double	lip_
double	mcConvEta_
double	mcConvPhi_
double	mcConvR_
double	mcConvX_
double	mcConvY_
double	mcConvZ_
double	mcEta_
double	mcJetEta_
double	mcJetPhi_
double	mcPhi_
	global variable for the MC photon More...
double	minPhoEtCut_
int	nEntry_
int	nEvt_
MonitorElement *	nHitsVsEta_ [2]
MonitorElement *	nHitsVsEtaBkg_
MonitorElement *	nHitsVsR_ [2]
int	nInvalidPCA_
int	nMatched_
int	nRecConv_
int	nRecConvAss_
int	nRecConvAssWithEcal_
int	nSimConv_ [2]
int	nSimPho_ [2]
int	numOfTracksInCone_
edm::EDGetTokenT < reco::VertexCollection >	offline_pvToken_
MonitorElement *	p_Chi2VsEta_ [3]
MonitorElement *	p_Chi2VsR_ [3]
MonitorElement *	p_convVtxdRVsEta_
MonitorElement *	p_convVtxdRVsR_
MonitorElement *	p_convVtxdXVsX_
MonitorElement *	p_convVtxdYVsY_
MonitorElement *	p_convVtxdZVsZ_
MonitorElement *	p_DCotTracksVsEta_
MonitorElement *	p_DCotTracksVsR_
MonitorElement *	p_DPhiTracksAtEcalVsEta_
MonitorElement *	p_DPhiTracksAtEcalVsR_
MonitorElement *	p_DPhiTracksAtVtxVsEta_
MonitorElement *	p_DPhiTracksAtVtxVsR_
MonitorElement *	p_dzPVVsEta_
MonitorElement *	p_dzPVVsR_
MonitorElement *	p_ecalRecHitSumEtConeDR04VsEt_ [3]
MonitorElement *	p_ecalRecHitSumEtConeDR04VsEta_ [3]
MonitorElement *	p_ecalRecHitSumEtConeDR04VsEtaBkg_
MonitorElement *	p_ecalRecHitSumEtConeDR04VsEtBkg_ [3]
MonitorElement *	p_EoverEtrueVsEta_ [3]
MonitorElement *	p_EoverEtrueVsR_ [3]
MonitorElement *	p_EoverPVsEta_ [3]
MonitorElement *	p_EoverPVsR_ [3]
MonitorElement *	p_eResVsEt_ [3][3]
MonitorElement *	p_eResVsEta_ [3]
MonitorElement *	p_eResVsNVtx_ [3][3]
MonitorElement *	p_eResVsR9_ [3]
MonitorElement *	p_eResVsR_
MonitorElement *	p_hcalTowerBcSumEtConeDR04VsEt_ [3]
MonitorElement *	p_hcalTowerBcSumEtConeDR04VsEta_ [3]
MonitorElement *	p_hcalTowerSumEtConeDR04VsEt_ [3]
MonitorElement *	p_hcalTowerSumEtConeDR04VsEta_ [3]
MonitorElement *	p_hcalTowerSumEtConeDR04VsEtaBkg_
MonitorElement *	p_hcalTowerSumEtConeDR04VsEtBkg_ [3]
MonitorElement *	p_hOverEVsEt_ [3]
MonitorElement *	p_hOverEVsEta_ [3]
MonitorElement *	p_hOverEVsEtaBkg_
MonitorElement *	p_hOverEVsEtBkg_
MonitorElement *	p_isoTrkSolidConeDR04VsEt_ [3]
MonitorElement *	p_isoTrkSolidConeDR04VsEta_ [3]
MonitorElement *	p_isoTrkSolidConeDR04VsEtaBkg_
MonitorElement *	p_isoTrkSolidConeDR04VsEtBkg_ [3]
MonitorElement *	p_newhOverEVsEt_ [3]
MonitorElement *	p_newhOverEVsEta_ [3]
MonitorElement *	p_nHitsVsEta_ [2]
MonitorElement *	p_nHitsVsEtaSL_ [2]
MonitorElement *	p_nHitsVsR_ [2]
MonitorElement *	p_nHitsVsRSL_ [2]
MonitorElement *	p_nTrkSolidConeDR04VsEt_ [3]
MonitorElement *	p_nTrkSolidConeDR04VsEta_ [3]
MonitorElement *	p_nTrkSolidConeDR04VsEtaBkg_
MonitorElement *	p_nTrkSolidConeDR04VsEtBkg_ [3]
MonitorElement *	p_PoverPtrueVsEta_ [3]
MonitorElement *	p_r1VsEt_ [3]
MonitorElement *	p_r1VsEta_ [3]
MonitorElement *	p_r1VsEtaBkg_
MonitorElement *	p_r1VsEtBkg_
MonitorElement *	p_r2VsEt_ [3]
MonitorElement *	p_r2VsEta_ [3]
MonitorElement *	p_r2VsEtaBkg_
MonitorElement *	p_r2VsEtBkg_
MonitorElement *	p_r9VsEt_ [3]
MonitorElement *	p_r9VsEta_ [3]
MonitorElement *	p_sceResVsR9_ [3]
MonitorElement *	p_sigmaEoEVsEt_ [3][3]
MonitorElement *	p_sigmaEoEVsEta_ [3]
MonitorElement *	p_sigmaEoEVsNVtx_ [3][3]
MonitorElement *	p_sigmaIetaIetaVsEt_ [3]
MonitorElement *	p_sigmaIetaIetaVsEta_ [3]
MonitorElement *	p_sigmaIetaIetaVsEtaBkg_
MonitorElement *	p_sigmaIetaIetaVsEtBkg_ [3]
MonitorElement *	p_TkPtPull_ [3]
edm::ParameterSet	parameters_
edm::EDGetTokenT < edm::ValueMap< std::vector < reco::PFCandidateRef > > >	particleBasedIso_token
edm::EDGetTokenT < reco::PFCandidateCollection >	pfCandidates_
std::string	photonCollection_
std::string	photonCollectionProducer_
edm::EDGetTokenT < reco::PhotonCollection >	photonCollectionToken_
double	recMaxPt_
double	recMinPt_
	Global variables for reco Photon. More...
double	simMaxPt_
double	simMinPt_
TH1F *	th1f_SimConvMTotal_ [5]
edm::ESHandle< CaloGeometry >	theCaloGeom_
edm::ESHandle< CaloTopology >	theCaloTopo_
edm::RefVector < TrackingParticleCollection >	theConvTP_
edm::ESHandle< MagneticField >	theMF_
std::unique_ptr < PhotonMCTruthFinder >	thePhotonMCTruthFinder_
edm::EDGetTokenT < TrackingParticleCollection >	token_tp_
double	trkIsolExtRadius_
double	trkIsolInnRadius_
double	trkPtLow_
double	trkPtSumCut_
std::string	valueMapPhoPFCandIso_
int	verbosity_

Additional Inherited Members
Public Types inherited from edm::stream::EDAnalyzer< edm::RunSummaryCache< dqmDetails::NoCache >, edm::LuminosityBlockSummaryCache< dqmDetails::NoCache > >
typedef CacheContexts< T...>	CacheTypes
typedef CacheTypes::GlobalCache	GlobalCache
typedef AbilityChecker< T...>	HasAbility
typedef CacheTypes::LuminosityBlockCache	LuminosityBlockCache
typedef LuminosityBlockContextT < LuminosityBlockCache, RunCache, GlobalCache >	LuminosityBlockContext
typedef CacheTypes::LuminosityBlockSummaryCache	LuminosityBlockSummaryCache
typedef CacheTypes::RunCache	RunCache
typedef RunContextT< RunCache, GlobalCache >	RunContext
typedef CacheTypes::RunSummaryCache	RunSummaryCache
Public Types inherited from edm::stream::EDAnalyzerBase
typedef EDAnalyzerAdaptorBase	ModuleType
Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels
Static Public Member Functions inherited from DQMEDAnalyzer
static std::shared_ptr < dqmDetails::NoCache >	globalBeginLuminosityBlockSummary (edm::LuminosityBlock const &, edm::EventSetup const &, LuminosityBlockContext const *)
static std::shared_ptr < dqmDetails::NoCache >	globalBeginRunSummary (edm::Run const &, edm::EventSetup const &, RunContext const *)
static void	globalEndLuminosityBlockSummary (edm::LuminosityBlock const &, edm::EventSetup const &, LuminosityBlockContext const *, dqmDetails::NoCache *)
static void	globalEndRunSummary (edm::Run const &, edm::EventSetup const &, RunContext const *, dqmDetails::NoCache *)
Static Public Member Functions inherited from edm::stream::EDAnalyzerBase
static const std::string &	baseType ()
static void	fillDescriptions (ConfigurationDescriptions &descriptions)
static void	prevalidate (ConfigurationDescriptions &descriptions)
Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)
EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	consumes (TypeToGet const &id, edm::InputTag const &tag)
ConsumesCollector	consumesCollector ()
	Use a ConsumesCollector to gather consumes information from helper functions. More...
template<typename ProductType , BranchType B = InEvent>
void	consumesMany ()
void	consumesMany (const TypeToGet &id)
template<BranchType B>
void	consumesMany (const TypeToGet &id)
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

Detailed Description

$Id: PhotonValidator

Author

Nancy Marinelli, U. of Notre Dame, US

Definition at line 60 of file PhotonValidator.h.

Constructor & Destructor Documentation

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

explicit

Definition at line 86 of file PhotonValidator.cc.

References edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), HLT_25ns14e33_v1_cff::InputTag, and AlCaHLTBitMon_QueryRunRegistry::string.

{
  fName_     = pset.getParameter<std::string>("analyzerName");
  verbosity_ = pset.getUntrackedParameter<int>("Verbosity");
  parameters_ = pset;
  fastSim_ =   pset.getParameter<bool>("fastSim");
  isRunCentrally_=   pset.getParameter<bool>("isRunCentrally");

  photonCollectionProducer_ = pset.getParameter<std::string>("phoProducer");
  photonCollection_ = pset.getParameter<std::string>("photonCollection");
  photonCollectionToken_ = consumes<reco::PhotonCollection>(
      edm::InputTag(photonCollectionProducer_,
                    photonCollection_));

  token_tp_   = consumes<TrackingParticleCollection>(
      pset.getParameter<edm::InputTag>("label_tp"));

  barrelEcalHits_   = consumes<EcalRecHitCollection>(
      pset.getParameter<edm::InputTag>("barrelEcalHits"));
  endcapEcalHits_   = consumes<EcalRecHitCollection>(
      pset.getParameter<edm::InputTag>("endcapEcalHits"));

  conversionOITrackProducer_ = pset.getParameter<std::string>("conversionOITrackProducer");
  conversionIOTrackProducer_ = pset.getParameter<std::string>("conversionIOTrackProducer");
  conversionOITrackPr_Token_ = consumes<edm::View<reco::Track> >(
      edm::InputTag(conversionOITrackProducer_));
  conversionIOTrackPr_Token_ = consumes<edm::View<reco::Track> >(
      edm::InputTag(conversionIOTrackProducer_));

  pfCandidates_  = consumes<reco::PFCandidateCollection>(pset.getParameter<edm::InputTag>("pfCandidates"));
  valueMapPhoPFCandIso_ = pset.getParameter<std::string>("valueMapPhoToParticleBasedIso");
  particleBasedIso_token = consumes<edm::ValueMap<std::vector<reco::PFCandidateRef> > >(pset.getUntrackedParameter<edm::InputTag>("particleBasedIso",edm::InputTag("particleBasedIsolation",valueMapPhoPFCandIso_)));

  minPhoEtCut_ = pset.getParameter<double>("minPhoEtCut");
  convTrackMinPtCut_ = pset.getParameter<double>("convTrackMinPtCut");
  likelihoodCut_ = pset.getParameter<double>("likelihoodCut");

  trkIsolExtRadius_ = pset.getParameter<double>("trkIsolExtR");
  trkIsolInnRadius_ = pset.getParameter<double>("trkIsolInnR");
  trkPtLow_     = pset.getParameter<double>("minTrackPtCut");
  lip_       = pset.getParameter<double>("lipCut");
  ecalIsolRadius_ = pset.getParameter<double>("ecalIsolR");
  bcEtLow_     = pset.getParameter<double>("minBcEtCut");
  hcalIsolExtRadius_ = pset.getParameter<double>("hcalIsolExtR");
  hcalIsolInnRadius_ = pset.getParameter<double>("hcalIsolInnR");
  hcalHitEtLow_     = pset.getParameter<double>("minHcalHitEtCut");

  numOfTracksInCone_ = pset.getParameter<int>("maxNumOfTracksInCone");
  trkPtSumCut_  = pset.getParameter<double>("trkPtSumCut");
  ecalEtSumCut_ = pset.getParameter<double>("ecalEtSumCut");
  hcalEtSumCut_ = pset.getParameter<double>("hcalEtSumCut");
  dCotCutOn_ = pset.getParameter<bool>("dCotCutOn");
  dCotCutValue_ = pset.getParameter<double>("dCotCutValue");
  dCotHardCutValue_ = pset.getParameter<double>("dCotHardCutValue");

  offline_pvToken_ = consumes<reco::VertexCollection>(
      pset.getUntrackedParameter<edm::InputTag>("offlinePV",
                                           edm::InputTag("offlinePrimaryVertices")));
  g4_simTk_Token_  = consumes<edm::SimTrackContainer>(edm::InputTag("g4SimHits"));
  g4_simVtx_Token_ = consumes<edm::SimVertexContainer>(edm::InputTag("g4SimHits"));
  famos_simTk_Token_  = consumes<edm::SimTrackContainer>(
      edm::InputTag("famosSimHits"));
  famos_simVtx_Token_ = consumes<edm::SimVertexContainer>(
      edm::InputTag("famosSimHits"));
  hepMC_Token_ = consumes<edm::HepMCProduct>(edm::InputTag("generator"));
  genjets_Token_ = consumes<reco::GenJetCollection>(
      edm::InputTag("ak4GenJets"));

  consumes<reco::TrackToTrackingParticleAssociator>(edm::InputTag("trackAssociatorByHitsForPhotonValidation"));


  nEvt_=0;
  nEntry_=0;
  nRecConv_=0;
  nRecConvAss_=0;
  nRecConvAssWithEcal_=0;
  nInvalidPCA_=0;


}

PhotonValidator::~PhotonValidator ( )

virtual

Definition at line 171 of file PhotonValidator.cc.

{}

Member Function Documentation

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

overridevirtual

uncleaned

Implements edm::stream::EDAnalyzerBase.

Definition at line 1632 of file PhotonValidator.cc.

References funct::abs(), ecalcalib_dqm_sourceclient-live_cfg::algo, begin, edm::SortedCollection< T, SORT >::begin(), RecoTauCleanerPlugins::charge, ChiSquaredProbability(), conversions_cfi::conversions, reco::Photon::conversions(), delta, HLTFastRecoForTau_cff::deltaEta, SiPixelRawToDigiRegional_cfi::deltaPhi, deltaR(), dPhi(), PFRecoTauDiscriminationAgainstElectronDeadECAL_cfi::dR, reco::PFCandidate::e, reco::Photon::ecalRecHitSumEtConeDR04(), edm::SortedCollection< T, SORT >::end(), edm::AssociationMap< Tag >::end(), reco::LeafCandidate::energy(), reco::LeafCandidate::et(), reco::LeafCandidate::eta(), event(), HcalObjRepresent::Fill(), edm::AssociationMap< Tag >::find(), reco::PFCandidate::gamma, GenParticle::GenParticle, edm::EventSetup::get(), edm::RefToBase< T >::get(), edm::Event::getByLabel(), edm::Event::getByToken(), reco::PFCandidate::h, reco::PFCandidate::h0, reco::Photon::hadronicOverEm(), reco::Photon::hcalTowerSumEtConeDR04(), i, edm::EventBase::id(), cmsHarvester::index, edm::Ref< C, T, F >::isNonnull(), edm::HandleBase::isValid(), edm::Ref< C, T, F >::key(), prof2calltree::l, edm::ProductLabels::module, reco::TrackBase::momentum(), ndof, reco::Photon::nTrkSolidConeDR04(), p1, p2, parents, benchmark_cfg::pdgId, reco::LeafCandidate::phi(), configurableAnalysis::Photon, pi, funct::pow(), edm::Handle< T >::product(), edm::RefToBaseVector< T >::push_back(), lumiQueryAPI::q, diffTwoXMLs::r1, reco::Photon::r1x5(), diffTwoXMLs::r2, reco::Photon::r2x5(), reco::Photon::r9(), reco::Photon::regression1, reco::Photon::regression2, hitfit::scalar(), reco::Photon::sigmaIetaIeta(), funct::sin(), edm::RefVector< C, T, F >::size(), findQualityFiles::size, runGlobalFakeInputProducer::skip, python.multivaluedict::sort(), mathSSE::sqrt(), reco::Photon::superCluster(), trackingParticlesFastSim_cfi::trackingParticles, testEve_cfg::tracks, and reco::Photon::trkSumPtSolidConeDR04().

                                                                            {

  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;

  edm::Handle<reco::TrackToTrackingParticleAssociator> theHitsAssociator;
  e.getByLabel("trackAssociatorByHitsForPhotonValidation",theHitsAssociator);
  reco::TrackToTrackingParticleAssociator const* trackAssociator = theHitsAssociator.product();



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


  // get the geometry from the event setup:
  esup.get<CaloGeometryRecord>().get(theCaloGeom_);

  edm::Handle<reco::VertexCollection> vtxH;
  e.getByToken(offline_pvToken_, vtxH);
  h_nRecoVtx_ ->Fill (float(vtxH->size()));
 

  // Transform Track into TransientTrack (needed by the Vertex fitter)
  edm::ESHandle<TransientTrackBuilder> theTTB;
  esup.get<TransientTrackRecord>().get("TransientTrackBuilder",theTTB);


  Handle<reco::PhotonCollection> photonHandle;
  e.getByToken(photonCollectionToken_, photonHandle);
  const reco::PhotonCollection photonCollection = *(photonHandle.product());
  if (!photonHandle.isValid()) {
    edm::LogError("PhotonProducer")
        << "Error! Can't get the Photon collection "
        << std::endl;
    return;
  }

  // Get the  PF refined cluster  collection
  Handle<reco::PFCandidateCollection> pfCandidateHandle;
  e.getByToken(pfCandidates_,pfCandidateHandle);
  if (!pfCandidateHandle.isValid()) {
    edm::LogError("PhotonValidator") << "Error! Can't get the product pfCandidates "<< std::endl ;
  }

  edm::Handle<edm::ValueMap<std::vector<reco::PFCandidateRef> > > phoToParticleBasedIsoMapHandle;
  edm::ValueMap<std::vector<reco::PFCandidateRef> > phoToParticleBasedIsoMap;
  if ( fName_ == "pfPhotonValidator") {
    e.getByToken(particleBasedIso_token,phoToParticleBasedIsoMapHandle);
    if ( ! phoToParticleBasedIsoMapHandle.isValid()) {
      edm::LogInfo("PhotonValidator") << "Error! Can't get the product: valueMap photons to particle based iso " << std::endl;
      
    }
    phoToParticleBasedIsoMap = *(phoToParticleBasedIsoMapHandle.product());
  }

  Handle< edm::View<reco::Track> > outInTrkHandle;
  Handle< edm::View<reco::Track> > inOutTrkHandle;
  if ( !fastSim_) {
    e.getByToken(conversionOITrackPr_Token_, outInTrkHandle);
    e.getByToken(conversionIOTrackPr_Token_, inOutTrkHandle);

    // Loop over Out In Tracks
    int iTrk=0;
    int nHits=0;
    for( View<reco::Track>::const_iterator    iTk = outInTrkHandle->begin(); iTk !=  outInTrkHandle->end(); iTk++) {
      h_OIinnermostHitR_ ->Fill ( sqrt( iTk->innerPosition().Perp2() ) );
      for (  trackingRecHit_iterator itHits=iTk->extra()->recHitsBegin();  itHits!=iTk->extra()->recHitsEnd(); ++itHits ) {
        if ( (*itHits)->isValid() ) {
            nHits++;
        }

        
      }

      iTrk++;


    }

    // Loop over In Out Tracks Barrel
    iTrk=0;
    for( View<reco::Track>::const_iterator    iTk =  inOutTrkHandle->begin(); iTk !=  inOutTrkHandle->end(); iTk++) {
      h_IOinnermostHitR_ ->Fill ( sqrt( iTk->innerPosition().Perp2() ) );
      nHits=0;
      for (  trackingRecHit_iterator itHits=iTk->extra()->recHitsBegin();  itHits!=iTk->extra()->recHitsEnd(); ++itHits ) {
        if ( (*itHits)->isValid() ) {
          nHits++;
        }
      }
      iTrk++;
    }

  }  // if !fastSim


  //get simtrack info
  std::vector<SimTrack> theSimTracks;
  std::vector<SimVertex> theSimVertices;
  edm::Handle<SimTrackContainer> SimTk;
  edm::Handle<SimVertexContainer> SimVtx;

  if ( ! fastSim_) {
    e.getByToken(g4_simTk_Token_, SimTk);
    e.getByToken(g4_simVtx_Token_, SimVtx);
  } else {
    e.getByToken(famos_simTk_Token_, SimTk);
    e.getByToken(famos_simVtx_Token_, 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();


  // get generated jets
  Handle<reco::GenJetCollection> GenJetsHandle ;
  e.getByToken(genjets_Token_, GenJetsHandle);
  reco::GenJetCollection genJetCollection = *(GenJetsHandle.product());



  // Get electron tracking truth
  bool useTP= parameters_.getParameter<bool>("useTP");
  TrackingParticleCollection trackingParticles;
  edm::Handle<TrackingParticleCollection> ElectronTPHandle;
  if ( useTP) {
    if ( ! fastSim_) {
      e.getByToken(token_tp_, ElectronTPHandle);
      trackingParticles = *(ElectronTPHandle.product());
    }
  }

  std::vector<reco::PhotonCollection::const_iterator> StoRMatchedConvertedPhotons;
  reco::SimToRecoCollection OISimToReco;
  reco::SimToRecoCollection IOSimToReco;
  // Reco to Sim
  reco::RecoToSimCollection OIRecoToSim;
  reco::RecoToSimCollection IORecoToSim;

  if ( useTP) {
    if ( ! fastSim_) {
      // Sim to Reco
      OISimToReco = trackAssociator->associateSimToReco(outInTrkHandle, ElectronTPHandle);
      IOSimToReco = trackAssociator->associateSimToReco(inOutTrkHandle, ElectronTPHandle);
      // Reco to Sim
      OIRecoToSim = trackAssociator->associateRecoToSim(outInTrkHandle, ElectronTPHandle);
      IORecoToSim = trackAssociator->associateRecoToSim(inOutTrkHandle, ElectronTPHandle);
    }
  }
  //
  vector<reco::SimToRecoCollection*> StoRCollPtrs;
  StoRCollPtrs.push_back(&OISimToReco);
  StoRCollPtrs.push_back(&IOSimToReco);
  vector<reco::RecoToSimCollection*> RtoSCollPtrs;
  RtoSCollPtrs.push_back(&OIRecoToSim);
  RtoSCollPtrs.push_back(&IORecoToSim);
  //
  for (int i=0; i<2; i++)
    nSimPho_[i]=0;
  for (int i=0; i<2; i++)
    nSimConv_[i]=0;


  std::vector<reco::PhotonRef> myPhotons;

  for(unsigned int iPho=0; iPho < photonHandle->size(); iPho++) {
    reco::PhotonRef phoRef(reco::PhotonRef(photonHandle, iPho));
  //  for( reco::PhotonCollection::const_iterator  iPho = photonCollection.begin(); iPho != photonCollection.end(); iPho++) {
    if ( fabs(phoRef->eta()) > 2.5 ) continue;
    myPhotons.push_back(phoRef);
  }

  std::sort(myPhotons.begin(), myPhotons.end(), sortPhotons());
  // if ( ! isRunCentrally_ ) {
  if ( myPhotons.size() >=2 ) {
    if ( myPhotons[0]->et() > 40 && myPhotons[1]->et() > 25 ) {

      math::XYZTLorentzVector p12 = myPhotons[0]->p4()+myPhotons[1]->p4();
      math::XYZTLorentzVector p12_regr1 = myPhotons[0]->p4(reco::Photon::regression1)+myPhotons[1]->p4(reco::Photon::regression1);
      math::XYZTLorentzVector p12_regr2 = myPhotons[0]->p4(reco::Photon::regression2)+myPhotons[1]->p4(reco::Photon::regression2);
      float gamgamMass2 = p12.Dot(p12);
      float gamgamMass2_regr1 = p12_regr1.Dot(p12_regr1);
      float gamgamMass2_regr2 = p12_regr2.Dot(p12_regr2);

      if (  gamgamMass2 > 0 ) {
        // total
        h_gamgamMass_[0][0] -> Fill(sqrt( gamgamMass2 ));
        if (  myPhotons[0]->isEB() &&    myPhotons[1]->isEB() )
          h_gamgamMass_[0][1] -> Fill(sqrt( gamgamMass2 ));
        if ( (  myPhotons[0]->isEE() &&      myPhotons[1]->isEE() )  ||
             (  myPhotons[0]->isEE() &&      myPhotons[1]->isEB() ) ||
             (  myPhotons[0]->isEB() &&      myPhotons[1]->isEE() ) )
          h_gamgamMass_[0][2] -> Fill(sqrt( gamgamMass2 ));
        // Golden photons
        if (  myPhotons[0]->r9() > 0.94 &&  myPhotons[1]->r9() > 0.94 ) {
          h_gamgamMass_[1][0] -> Fill(sqrt( gamgamMass2 ));
          if (  myPhotons[0]->isEB() &&      myPhotons[1]->isEB() )
            h_gamgamMass_[1][1] -> Fill(sqrt( gamgamMass2 ));
          if ( (  myPhotons[0]->isEE() &&    myPhotons[1]->isEE() )  ||
               (  myPhotons[0]->isEE() &&    myPhotons[1]->isEB() ) ||
               (  myPhotons[0]->isEB() &&    myPhotons[1]->isEE() ) )
            h_gamgamMass_[1][2] -> Fill(sqrt( gamgamMass2 ));
        }
        // both photons converted
        if ( myPhotons[0]->conversions().size() > 0 && myPhotons[1]->conversions().size() >0 ) {
          if ( myPhotons[0]->conversions()[0]->nTracks() ==2 &&  myPhotons[1]->conversions()[0]->nTracks() ==2  ) {
            float chi2Prob1 = ChiSquaredProbability( myPhotons[0]->conversions()[0]->conversionVertex().chi2(),  myPhotons[0]->conversions()[0]->conversionVertex().ndof() );
            float chi2Prob2 = ChiSquaredProbability( myPhotons[1]->conversions()[0]->conversionVertex().chi2(),  myPhotons[1]->conversions()[0]->conversionVertex().ndof() );
            if ( chi2Prob1 > 0.0005 &&  chi2Prob2 > 0.0005 ) {
              h_gamgamMass_[2][0] -> Fill(sqrt( gamgamMass2 ));
              if (  myPhotons[0]->isEB() &&      myPhotons[1]->isEB() ) {
                h_gamgamMass_[2][1] -> Fill(sqrt( gamgamMass2 ));
              }
              if ( (  myPhotons[0]->isEE() &&    myPhotons[1]->isEE() )  ||
                   (  myPhotons[0]->isEE() &&    myPhotons[1]->isEB() ) ||
                   (  myPhotons[0]->isEB() &&    myPhotons[1]->isEE() ) )
                h_gamgamMass_[2][2] -> Fill(sqrt( gamgamMass2 )); {
              }
            }
          }
        } else if ( myPhotons[0]->conversions().size() > 0 && myPhotons[1]->conversions().size() ==0 && myPhotons[1]->r9() > 0.93  )  {     // one photon converted
          if ( myPhotons[0]->conversions()[0]->nTracks() ==2 ) {
            float chi2Prob1 = ChiSquaredProbability( myPhotons[0]->conversions()[0]->conversionVertex().chi2(),  myPhotons[0]->conversions()[0]->conversionVertex().ndof() );
            if ( chi2Prob1 > 0.0005 ) {
              h_gamgamMass_[2][0] -> Fill(sqrt( gamgamMass2 ));
              if (  myPhotons[0]->isEB() &&  myPhotons[1]->isEB() ) {
                h_gamgamMass_[2][1] -> Fill(sqrt( gamgamMass2 ));
              }
              if (  myPhotons[0]->isEE() ||  myPhotons[1]->isEE() ) {
                h_gamgamMass_[2][2] -> Fill(sqrt( gamgamMass2 ));
              }
            }
          }
        } else if ( myPhotons[1]->conversions().size() > 0 && myPhotons[0]->conversions().size() ==0 &&  myPhotons[0]->r9() > 0.93 )  {     // one photon converted
          if ( myPhotons[1]->conversions()[0]->nTracks() ==2 ) {
            float chi2Prob1 = ChiSquaredProbability( myPhotons[1]->conversions()[0]->conversionVertex().chi2(),  myPhotons[1]->conversions()[0]->conversionVertex().ndof() );
            if ( chi2Prob1 > 0.0005 ) {
              h_gamgamMass_[2][0] -> Fill(sqrt( gamgamMass2 ));
              if (  myPhotons[0]->isEB() && myPhotons[1]->isEB() ) {
                h_gamgamMass_[2][1] -> Fill(sqrt( gamgamMass2 ));
              }
              if (  myPhotons[0]->isEE() ||  myPhotons[1]->isEE() ) {
                h_gamgamMass_[2][2] -> Fill(sqrt( gamgamMass2 ));
              }
            }
          }
        }
      } // gamgamMass2 > 0

      if (  gamgamMass2_regr1 > 0 ) {
        // total
        h_gamgamMassRegr1_[0][0] -> Fill(sqrt( gamgamMass2_regr1 ));
        if (  myPhotons[0]->isEB() &&    myPhotons[1]->isEB() )
          h_gamgamMassRegr1_[0][1] -> Fill(sqrt( gamgamMass2_regr1 ));
        if ( (  myPhotons[0]->isEE() &&      myPhotons[1]->isEE() )  ||
             (  myPhotons[0]->isEE() &&      myPhotons[1]->isEB() ) ||
             (  myPhotons[0]->isEB() &&      myPhotons[1]->isEE() ) )
          h_gamgamMassRegr1_[0][2] -> Fill(sqrt( gamgamMass2_regr1 ));
        // Golden photons
        if (  myPhotons[0]->r9() > 0.94 &&  myPhotons[1]->r9() > 0.94 ) {
          h_gamgamMassRegr1_[1][0] -> Fill(sqrt( gamgamMass2_regr1 ));
          if (  myPhotons[0]->isEB() &&      myPhotons[1]->isEB() )
            h_gamgamMassRegr1_[1][1] -> Fill(sqrt( gamgamMass2_regr1 ));
          if ( (  myPhotons[0]->isEE() &&    myPhotons[1]->isEE() )  ||
               (  myPhotons[0]->isEE() &&    myPhotons[1]->isEB() ) ||
               (  myPhotons[0]->isEB() &&    myPhotons[1]->isEE() ) )
            h_gamgamMassRegr1_[1][2] -> Fill(sqrt( gamgamMass2_regr1 ));
        }


        // both photons converted
        if ( myPhotons[0]->conversions().size() > 0 && myPhotons[1]->conversions().size() >0 ) {
          if ( myPhotons[0]->conversions()[0]->nTracks() ==2 &&  myPhotons[1]->conversions()[0]->nTracks() ==2  ) {
            float chi2Prob1 = ChiSquaredProbability( myPhotons[0]->conversions()[0]->conversionVertex().chi2(),  myPhotons[0]->conversions()[0]->conversionVertex().ndof() );
            float chi2Prob2 = ChiSquaredProbability( myPhotons[1]->conversions()[0]->conversionVertex().chi2(),  myPhotons[1]->conversions()[0]->conversionVertex().ndof() );
            if ( chi2Prob1 > 0.0005 &&  chi2Prob2 > 0.0005 ) {
              h_gamgamMassRegr1_[2][0] -> Fill(sqrt( gamgamMass2_regr1 ));
              if (  myPhotons[0]->isEB() &&      myPhotons[1]->isEB() ) {
                h_gamgamMassRegr1_[2][1] -> Fill(sqrt( gamgamMass2_regr1 ));
              }
              if ( (  myPhotons[0]->isEE() &&    myPhotons[1]->isEE() )  ||
                   (  myPhotons[0]->isEE() &&    myPhotons[1]->isEB() ) ||
                   (  myPhotons[0]->isEB() &&    myPhotons[1]->isEE() ) )
                h_gamgamMassRegr1_[2][2] -> Fill(sqrt( gamgamMass2_regr1 )); {
              }
            }
          }
        } else if ( myPhotons[0]->conversions().size() > 0 && myPhotons[1]->conversions().size() ==0 && myPhotons[1]->r9() > 0.93  )  {     // one photon converted
          if ( myPhotons[0]->conversions()[0]->nTracks() ==2 ) {
            float chi2Prob1 = ChiSquaredProbability( myPhotons[0]->conversions()[0]->conversionVertex().chi2(),  myPhotons[0]->conversions()[0]->conversionVertex().ndof() );
            if ( chi2Prob1 > 0.0005 ) {
              h_gamgamMassRegr1_[2][0] -> Fill(sqrt( gamgamMass2_regr1 ));
              if (  myPhotons[0]->isEB() &&  myPhotons[1]->isEB() ) {
                h_gamgamMassRegr1_[2][1] -> Fill(sqrt( gamgamMass2_regr1 ));
              }
              if (  myPhotons[0]->isEE() ||  myPhotons[1]->isEE() ) {
                h_gamgamMassRegr1_[2][2] -> Fill(sqrt( gamgamMass2_regr1 ));
              }
            }
          }
        } else if ( myPhotons[1]->conversions().size() > 0 && myPhotons[0]->conversions().size() ==0 &&  myPhotons[0]->r9() > 0.93 )  {     // one photon converted
          if ( myPhotons[1]->conversions()[0]->nTracks() ==2 ) {
            float chi2Prob1 = ChiSquaredProbability( myPhotons[1]->conversions()[0]->conversionVertex().chi2(),  myPhotons[1]->conversions()[0]->conversionVertex().ndof() );
            if ( chi2Prob1 > 0.0005 ) {
              h_gamgamMassRegr1_[2][0] -> Fill(sqrt( gamgamMass2_regr1 ));
              if (  myPhotons[0]->isEB() && myPhotons[1]->isEB() ) {
                h_gamgamMassRegr1_[2][1] -> Fill(sqrt( gamgamMass2_regr1 ));
              }
              if (  myPhotons[0]->isEE() ||  myPhotons[1]->isEE() ) {
                h_gamgamMassRegr1_[2][2] -> Fill(sqrt( gamgamMass2_regr1 ));
              }
            }
          }
        }
      } // gamgamMass2_regr1 > 0


      if (  gamgamMass2_regr2 > 0 ) {
        // total
        h_gamgamMassRegr2_[0][0] -> Fill(sqrt( gamgamMass2_regr2 ));
        if (  myPhotons[0]->isEB() &&    myPhotons[1]->isEB() )
          h_gamgamMassRegr2_[0][1] -> Fill(sqrt( gamgamMass2_regr2 ));
        if ( (  myPhotons[0]->isEE() &&      myPhotons[1]->isEE() )  ||
             (  myPhotons[0]->isEE() &&      myPhotons[1]->isEB() ) ||
             (  myPhotons[0]->isEB() &&      myPhotons[1]->isEE() ) )
          h_gamgamMassRegr2_[0][2] -> Fill(sqrt( gamgamMass2_regr2 ));
        // Golden photons
        if (  myPhotons[0]->r9() > 0.94 &&  myPhotons[1]->r9() > 0.94 ) {
          h_gamgamMassRegr2_[1][0] -> Fill(sqrt( gamgamMass2_regr2 ));
          if (  myPhotons[0]->isEB() &&      myPhotons[1]->isEB() )
            h_gamgamMassRegr2_[1][1] -> Fill(sqrt( gamgamMass2_regr2 ));
          if ( (  myPhotons[0]->isEE() &&    myPhotons[1]->isEE() )  ||
               (  myPhotons[0]->isEE() &&    myPhotons[1]->isEB() ) ||
               (  myPhotons[0]->isEB() &&    myPhotons[1]->isEE() ) )
            h_gamgamMassRegr2_[1][2] -> Fill(sqrt( gamgamMass2_regr2 ));
        }


        // both photons converted
        if ( myPhotons[0]->conversions().size() > 0 && myPhotons[1]->conversions().size() >0 ) {
          if ( myPhotons[0]->conversions()[0]->nTracks() ==2 &&  myPhotons[1]->conversions()[0]->nTracks() ==2  ) {
            float chi2Prob1 = ChiSquaredProbability( myPhotons[0]->conversions()[0]->conversionVertex().chi2(),  myPhotons[0]->conversions()[0]->conversionVertex().ndof() );
            float chi2Prob2 = ChiSquaredProbability( myPhotons[1]->conversions()[0]->conversionVertex().chi2(),  myPhotons[1]->conversions()[0]->conversionVertex().ndof() );
            if ( chi2Prob1 > 0.0005 &&  chi2Prob2 > 0.0005 ) {
              h_gamgamMassRegr2_[2][0] -> Fill(sqrt( gamgamMass2_regr2 ));
              if (  myPhotons[0]->isEB() &&      myPhotons[1]->isEB() ) {
                h_gamgamMassRegr2_[2][1] -> Fill(sqrt( gamgamMass2_regr2 ));
              }
              if ( (  myPhotons[0]->isEE() &&    myPhotons[1]->isEE() )  ||
                   (  myPhotons[0]->isEE() &&    myPhotons[1]->isEB() ) ||
                   (  myPhotons[0]->isEB() &&    myPhotons[1]->isEE() ) )
                h_gamgamMassRegr2_[2][2] -> Fill(sqrt( gamgamMass2_regr2 )); {
              }
            }
          }
        } else if ( myPhotons[0]->conversions().size() > 0 && myPhotons[1]->conversions().size() ==0 && myPhotons[1]->r9() > 0.93  )  {     // one photon converted
          if ( myPhotons[0]->conversions()[0]->nTracks() ==2 ) {
            float chi2Prob1 = ChiSquaredProbability( myPhotons[0]->conversions()[0]->conversionVertex().chi2(),  myPhotons[0]->conversions()[0]->conversionVertex().ndof() );
            if ( chi2Prob1 > 0.0005 ) {
              h_gamgamMassRegr2_[2][0] -> Fill(sqrt( gamgamMass2_regr2 ));
              if (  myPhotons[0]->isEB() &&  myPhotons[1]->isEB() ) {
                h_gamgamMassRegr2_[2][1] -> Fill(sqrt( gamgamMass2_regr2 ));
              }
              if (  myPhotons[0]->isEE() ||  myPhotons[1]->isEE() ) {
                h_gamgamMassRegr2_[2][2] -> Fill(sqrt( gamgamMass2_regr2 ));
              }
            }
          }
        } else if ( myPhotons[1]->conversions().size() > 0 && myPhotons[0]->conversions().size() ==0 &&  myPhotons[0]->r9() > 0.93 )  {     // one photon converted
          if ( myPhotons[1]->conversions()[0]->nTracks() ==2 ) {
            float chi2Prob1 = ChiSquaredProbability( myPhotons[1]->conversions()[0]->conversionVertex().chi2(),  myPhotons[1]->conversions()[0]->conversionVertex().ndof() );
            if ( chi2Prob1 > 0.0005 ) {
              h_gamgamMassRegr2_[2][0] -> Fill(sqrt( gamgamMass2_regr2 ));
              if (  myPhotons[0]->isEB() && myPhotons[1]->isEB() ) {
                h_gamgamMassRegr2_[2][1] -> Fill(sqrt( gamgamMass2_regr2 ));
              }
              if (  myPhotons[0]->isEE() ||  myPhotons[1]->isEE() ) {
                h_gamgamMassRegr2_[2][2] -> Fill(sqrt( gamgamMass2_regr2 ));
              }
            }
          }
        }
      } // gamgamMass2_regr2 > 0












    }
  }
  // }


  for ( std::vector<PhotonMCTruth>::const_iterator mcPho=mcPhotons.begin(); mcPho !=mcPhotons.end(); mcPho++) {
    if ( (*mcPho).fourMomentum().et() < minPhoEtCut_ ) continue;

    for ( HepMC::GenEvent::particle_const_iterator mcIter=myGenEvent->particles_begin(); mcIter != myGenEvent->particles_end(); mcIter++ ) {
      if ( (*mcIter)->pdg_id() != 22 ) continue;
      bool isTheSame= false;
      HepMC::GenParticle* mother = 0;
      if ( (*mcIter)->production_vertex() )  {
    if ( (*mcIter)->production_vertex()->particles_begin(HepMC::parents) !=
         (*mcIter)->production_vertex()->particles_end(HepMC::parents))
      mother = *((*mcIter)->production_vertex()->particles_begin(HepMC::parents));
      }




      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 (  mother ==0
            ||  (mother != 0  && mother->pdg_id() == 22)
        ||  (mother != 0  && mother->pdg_id() == 25)
        ||  (mother != 0  && mother->pdg_id() == 35) )
      {
        double dPt =  fabs((*mcIter)->momentum().perp() - (*mcPho).fourMomentum().et());
        float phiMother=(*mcIter)->momentum().phi();
        double dPhi = phiNormalization(phiMother) - mcPhi_ ;
        double dEta = fabs( (*mcIter)->momentum().eta() - (*mcPho).fourMomentum().pseudoRapidity() );

        if ( dEta <=0.0001 && dPhi <=0.0001 && dPt <=0.0001)
          isTheSame = true;

      }
      if ( ! isTheSame ) continue;

      nSimPho_[0]++;
      if ( ! isRunCentrally_ ) {
    h_SimPhoMotherEt_[0]->Fill(  (*mcPho).motherMomentum().et()  );
    h_SimPhoMotherEta_[0]->Fill(  (*mcPho).motherMomentum().pseudoRapidity());
      }

      h_SimPho_[0]->Fill ( mcEta_);
      h_SimPho_[1]->Fill ( mcPhi_);
      h_SimPho_[2]->Fill ( (*mcPho).fourMomentum().et()   );





      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 ( ! isRunCentrally_ ) {
      if ( mcConvR_ <51) 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();
    for(size_t i = 0; i < trackingParticles.size(); ++i){
      TrackingParticleRef tp (ElectronTPHandle,i);
      if ( fabs( tp->vx() - (*mcPho).vertex().x() ) < 0.001   &&
           fabs( tp->vy() - (*mcPho).vertex().y() ) < 0.001   &&
           fabs( tp->vz() - (*mcPho).vertex().z() ) < 0.001) {

        theConvTP_.push_back( tp );
      }
    }
    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());


      if ( useTP ) {
        if ( ! isRunCentrally_ ) {
          for ( edm::RefVector<TrackingParticleCollection>::iterator iTrk=theConvTP_.begin(); iTrk!=theConvTP_.end(); ++iTrk) {
        h_simTkPt_ -> Fill ( (*iTrk)->pt() );
        h_simTkEta_ -> Fill ( (*iTrk)->eta() );
          }
        }

      }
    }
      }  



      float minDelta=10000.;
      std::vector<reco::PhotonRef> thePhotons;
      int index=0;
      int iMatch=-1;
      bool matched=false;

      for(unsigned int iPho=0; iPho < photonHandle->size(); iPho++) {
    reco::PhotonRef aPho(reco::PhotonRef(photonHandle, iPho));
    thePhotons.push_back(aPho);
    float phiPho=aPho->phi();
    float etaPho=aPho->eta();
    float deltaPhi = phiPho-mcPhi_;
    float deltaEta = etaPho-mcEta_;
    if ( deltaPhi > pi )  deltaPhi -= twopi;
    if ( deltaPhi < -pi) deltaPhi += twopi;
    deltaPhi=pow(deltaPhi,2);
    deltaEta=pow(deltaEta,2);
    float delta = sqrt( deltaPhi+deltaEta);
    if ( delta<0.1 && delta < minDelta ) {
      minDelta=delta;
      iMatch=index;

    }
    index++;
      }  // end loop over reco photons
      if ( iMatch>-1 ) matched=true;

      if ( matched ) {
    nSimPho_[1]++;
    if ( ! isRunCentrally_ ) {
      h_SimPhoMotherEt_[1]->Fill(  (*mcPho).motherMomentum().et()  );
      h_SimPhoMotherEta_[1]->Fill(  (*mcPho).motherMomentum().pseudoRapidity());
    }
    h_MatchedSimPho_[0]->Fill( mcEta_ ) ;
    h_MatchedSimPho_[1]->Fill( mcPhi_ );
    h_MatchedSimPho_[2]->Fill(  (*mcPho).fourMomentum().et());

      }




      if ( ! matched) continue;

      bool  phoIsInBarrel=false;
      bool  phoIsInEndcap=false;
      bool  phoIsInEndcapP=false;
      bool  phoIsInEndcapM=false;

      reco::PhotonRef matchingPho = thePhotons[iMatch];

      if ( fabs(matchingPho->superCluster()->position().eta() ) < 1.479 ) {
    phoIsInBarrel=true;
      } else {
    phoIsInEndcap=true;
        if ( matchingPho->superCluster()->position().eta() > 0) phoIsInEndcapP=true;
    if ( matchingPho->superCluster()->position().eta() < 0) phoIsInEndcapM=true;

      }

      edm::Handle<EcalRecHitCollection>   ecalRecHitHandle;
      if ( phoIsInBarrel ) {
    // Get handle to rec hits ecal barrel
    e.getByToken(barrelEcalHits_, ecalRecHitHandle);
    if (!ecalRecHitHandle.isValid()) {
      Labels l;
          labelsForToken(barrelEcalHits_, l);
          edm::LogError("PhotonProducer")
              << "Error! Can't get the product "
              << l.module;
      return;
    }

      } else if ( phoIsInEndcap ) {

    // Get handle to rec hits ecal encap
    e.getByToken(endcapEcalHits_, ecalRecHitHandle);
    if (!ecalRecHitHandle.isValid()) {
      Labels l;
          labelsForToken(barrelEcalHits_, l);
      edm::LogError("PhotonProducer")
              << "Error! Can't get the product "
              << l.module;
      return;
    }

      }

      int type=0;
      const EcalRecHitCollection ecalRecHitCollection = *(ecalRecHitHandle.product());
      float photonE = matchingPho->energy();
      float sigmaEoE =  matchingPho->getCorrectedEnergyError(matchingPho->getCandidateP4type())/matchingPho->energy();
      float photonEt= matchingPho->energy()/cosh( matchingPho->eta()) ;
      float photonERegr1 = matchingPho->getCorrectedEnergy(reco::Photon::regression1);
      float photonERegr2 = matchingPho->getCorrectedEnergy(reco::Photon::regression2);
      float r9 = matchingPho->r9();
      float r1 = matchingPho->r1x5();
      float r2 = matchingPho->r2x5();
      float sigmaIetaIeta =  matchingPho->sigmaIetaIeta();
      float hOverE = matchingPho->hadronicOverEm();
      float newhOverE = matchingPho->hadTowOverEm();
      float ecalIso = matchingPho->ecalRecHitSumEtConeDR04();
      float hcalIso = matchingPho->hcalTowerSumEtConeDR04();
      float newhcalIso = matchingPho->hcalTowerSumEtBcConeDR04();
      float trkIso =  matchingPho->trkSumPtSolidConeDR04();
      float nIsoTrk   =  matchingPho->nTrkSolidConeDR04();
      // PF related quantities
      float chargedHadIso =  matchingPho->chargedHadronIso();
      float neutralHadIso =  matchingPho->neutralHadronIso();
      float photonIso     =  matchingPho->photonIso();
      float etOutsideMustache = matchingPho->etOutsideMustache();
      int   nClusterOutsideMustache = matchingPho->nClusterOutsideMustache();
      float pfMVA = matchingPho->pfMVA();

      std::vector< std::pair<DetId, float> >::const_iterator rhIt;
      bool atLeastOneDeadChannel=false;
      for(reco::CaloCluster_iterator bcIt = matchingPho->superCluster()->clustersBegin();bcIt != matchingPho->superCluster()->clustersEnd(); ++bcIt) {
    for(rhIt = (*bcIt)->hitsAndFractions().begin();rhIt != (*bcIt)->hitsAndFractions().end(); ++rhIt) {

      for(EcalRecHitCollection::const_iterator it =  ecalRecHitCollection.begin(); it !=  ecalRecHitCollection.end(); ++it) {
        if  (rhIt->first ==  (*it).id() ) {
          if (  (*it).recoFlag() == 9 ) {
                atLeastOneDeadChannel=true;
        break;
          }
        }
      }
    }
      }

      if (   atLeastOneDeadChannel ) {
    h_MatchedSimPhoBadCh_[0]->Fill( mcEta_ ) ;
    h_MatchedSimPhoBadCh_[1]->Fill( mcPhi_ );
    h_MatchedSimPhoBadCh_[2]->Fill(  (*mcPho).fourMomentum().et());

      }

      if ( phoIsInBarrel ) 
    h_phoPixSeedSize_[0] -> Fill( matchingPho->electronPixelSeeds().size());
      else 
    h_phoPixSeedSize_[1] -> Fill( matchingPho->electronPixelSeeds().size());

      h_scEta_[type]->Fill( matchingPho->superCluster()->eta() );
      h_scPhi_[type]->Fill( matchingPho->superCluster()->phi() );
      if ( ! isRunCentrally_ ) {
    h_scEtaWidth_[type]->Fill( matchingPho->superCluster()->etaWidth() );
    h_scPhiWidth_[type]->Fill( matchingPho->superCluster()->phiWidth() );
      }
      h_scE_[type][0]->Fill( matchingPho->superCluster()->energy() );
      h_scEt_[type][0]->Fill( matchingPho->superCluster()->energy()/cosh( matchingPho->superCluster()->eta()) );
      if ( phoIsInEndcap ) h_psE_->Fill( matchingPho->superCluster()->preshowerEnergy() ) ;
      //
      h_r9_[type][0]->Fill( r9 );
      //
      h_r1_[type][0]->Fill( r1 );
      //
      h_r2_[type][0]->Fill( r2 );
      //
      h_sigmaIetaIeta_[type][0]->Fill( sigmaIetaIeta );
      //
      h_hOverE_[type][0]->Fill( hOverE );
      p_r9VsEta_[0] -> Fill (mcEta_, r9);

      if ( ! isRunCentrally_ ) {
    h2_r9VsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), r9);
    h2_r1VsEta_[0] -> Fill (mcEta_, r1);
    h2_r1VsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), r1);
    h2_r2VsEta_[0] -> Fill (mcEta_, r2);
    h2_r2VsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), r2);
    h2_sigmaIetaIetaVsEta_[0] -> Fill (mcEta_, sigmaIetaIeta );
    h2_sigmaIetaIetaVsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), sigmaIetaIeta);
    h2_hOverEVsEta_[0] -> Fill (mcEta_, hOverE );
    h2_hOverEVsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), hOverE);
      }
      p_hOverEVsEta_[0] -> Fill (mcEta_, hOverE );
      p_hOverEVsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), hOverE);
      //
      h_newhOverE_[type][0]->Fill( newhOverE );
      p_newhOverEVsEta_[0] -> Fill (mcEta_, newhOverE );
      p_newhOverEVsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), newhOverE);



      //
      h_ecalRecHitSumEtConeDR04_[type][0]->Fill( ecalIso );
      if ( ! isRunCentrally_ ) {
    h2_ecalRecHitSumEtConeDR04VsEta_[0] -> Fill (mcEta_, ecalIso );
    h2_ecalRecHitSumEtConeDR04VsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), ecalIso);
    h2_hcalTowerSumEtConeDR04VsEta_[0] -> Fill (mcEta_, hcalIso );
    h2_hcalTowerSumEtConeDR04VsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), hcalIso);

      }
      p_ecalRecHitSumEtConeDR04VsEta_[0] -> Fill (mcEta_, ecalIso );
      if ( ! isRunCentrally_ ) p_ecalRecHitSumEtConeDR04VsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), ecalIso);
      //
      h_hcalTowerSumEtConeDR04_[type][0]->Fill( hcalIso );
      p_hcalTowerSumEtConeDR04VsEta_[0] -> Fill (mcEta_, hcalIso );
      if ( ! isRunCentrally_ ) p_hcalTowerSumEtConeDR04VsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), hcalIso);
      //
      if ( ! isRunCentrally_ ) h_hcalTowerBcSumEtConeDR04_[type][0]->Fill( newhcalIso );
      p_hcalTowerBcSumEtConeDR04VsEta_[0] -> Fill (mcEta_, newhcalIso );
      if ( ! isRunCentrally_ ) p_hcalTowerBcSumEtConeDR04VsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), newhcalIso);
      //
      h_isoTrkSolidConeDR04_[type][0]->Fill( trkIso );
      h_nTrkSolidConeDR04_[type][0]->Fill( nIsoTrk );

      if ( ! isRunCentrally_ ) {
    h2_isoTrkSolidConeDR04VsEta_[0] -> Fill (mcEta_, trkIso );
    h2_isoTrkSolidConeDR04VsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), trkIso);
    h2_nTrkSolidConeDR04VsEta_[0] -> Fill (mcEta_, nIsoTrk );
    h2_nTrkSolidConeDR04VsEt_[0] -> Fill ((*mcPho).fourMomentum().et(), nIsoTrk);
      }

      

      h_chHadIso_[0]-> Fill (chargedHadIso);
      h_nHadIso_[0]-> Fill (neutralHadIso);
      h_phoIso_[0]-> Fill (photonIso);
      h_nCluOutsideMustache_[0]->Fill(float(nClusterOutsideMustache));
      h_etOutsideMustache_[0]->Fill(etOutsideMustache);
      h_pfMva_[0]->Fill(pfMVA);
      //
      h_phoEta_[type]->Fill( matchingPho->eta() );
      h_phoPhi_[type]->Fill( matchingPho->phi() );
      h_phoDEta_[0]->Fill (  matchingPho->eta() - (*mcPho).fourMomentum().eta() );
      h_phoDPhi_[0]->Fill (  matchingPho->phi() - mcPhi_ );
      h_phoE_[type][0]->Fill( photonE );
      h_phoEt_[type][0]->Fill( photonEt);
      h_nConv_[0][0]->Fill(float( matchingPho->conversions().size()));
      h_nConv_[1][0]->Fill(float( matchingPho->conversionsOneLeg().size()));

      //
      h_phoERes_[0][0]->Fill( photonE / (*mcPho).fourMomentum().e() );
      h_phoSigmaEoE_[0][0] -> Fill (sigmaEoE);
      h_phoEResRegr1_[0][0]->Fill( photonERegr1 / (*mcPho).fourMomentum().e() );
      h_phoEResRegr2_[0][0]->Fill( photonERegr2 / (*mcPho).fourMomentum().e() );

      p_eResVsEta_[0]->Fill (mcEta_, photonE/(*mcPho).fourMomentum().e()  ) ;
      p_sigmaEoEVsEta_[0] ->Fill(mcEta_,sigmaEoE);
      p_eResVsEt_[0][0]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;

      

      if ( ! isRunCentrally_ ) h2_eResVsEta_[0]->Fill (mcEta_, photonE/(*mcPho).fourMomentum().e()  ) ;
      if ( ! isRunCentrally_ ) h2_eResVsEt_[0][0]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
      if ( ! isRunCentrally_ ) h2_eResVsR9_[0]->Fill (r9, photonE/(*mcPho).fourMomentum().e()  ) ;
      if ( ! isRunCentrally_ ) h2_sceResVsR9_[0]->Fill (r9,  matchingPho->superCluster()->energy()/(*mcPho).fourMomentum().e()  ) ;
      if ( ! isRunCentrally_ ) p_eResVsR9_[0]->Fill (r9, photonE/(*mcPho).fourMomentum().e()  ) ;
      if ( ! isRunCentrally_ ) p_sceResVsR9_[0]->Fill (r9,  matchingPho->superCluster()->energy()/(*mcPho).fourMomentum().e()  ) ;
      //
      if (  (*mcPho).isAConversion() == 0 ) {
    if ( ! isRunCentrally_ ) {
      h2_eResVsEta_[1]->Fill (mcEta_, photonE/ (*mcPho).fourMomentum().e()  ) ;
      h2_r9VsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), r9);
      //
      h2_r1VsEta_[1] -> Fill (mcEta_, r1);
      h2_r1VsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), r1);
      //
      h2_r2VsEta_[1] -> Fill (mcEta_, r2);
      h2_r2VsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), r2);
      //
      h2_sigmaIetaIetaVsEta_[1] -> Fill (mcEta_, sigmaIetaIeta );
      h2_sigmaIetaIetaVsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), sigmaIetaIeta);
      //
      h2_hOverEVsEta_[1] -> Fill (mcEta_, hOverE );
      h2_hOverEVsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), hOverE);
    }

    if ( ! isRunCentrally_ ) {
      h2_ecalRecHitSumEtConeDR04VsEta_[1] -> Fill (mcEta_, ecalIso );
      h2_hcalTowerSumEtConeDR04VsEta_[1] -> Fill (mcEta_, hcalIso );
      h2_isoTrkSolidConeDR04VsEta_[1] -> Fill (mcEta_, trkIso );
      h2_isoTrkSolidConeDR04VsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), trkIso);
      h2_nTrkSolidConeDR04VsEta_[1] -> Fill (mcEta_, nIsoTrk );
      h2_nTrkSolidConeDR04VsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), nIsoTrk);

    }
    p_ecalRecHitSumEtConeDR04VsEta_[1] -> Fill (mcEta_, ecalIso );
    if ( ! isRunCentrally_ ) p_hcalTowerSumEtConeDR04VsEta_[1] -> Fill (mcEta_, hcalIso );
      }

      

      if ( photonE/(*mcPho).fourMomentum().e()  < 0.3 &&   photonE/(*mcPho).fourMomentum().e() > 0.1 ) {

      }


      if ( (r9>0.94 && phoIsInBarrel) ||   (r9>0.95 && phoIsInEndcap)  )  {
    h_phoERes_[1][0]->Fill( photonE / (*mcPho).fourMomentum().e() );
    h_phoSigmaEoE_[1][0] -> Fill (sigmaEoE);
    h_phoEResRegr1_[1][0]->Fill( photonERegr1 / (*mcPho).fourMomentum().e() );
    h_phoEResRegr2_[1][0]->Fill( photonERegr2 / (*mcPho).fourMomentum().e() );
    if ( ! isRunCentrally_ ) h2_eResVsEt_[0][1]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
    p_eResVsEt_[0][1]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
    p_eResVsEta_[1]->Fill (mcEta_,photonE/ (*mcPho).fourMomentum().e()  ) ;
    p_r9VsEta_[1] -> Fill (mcEta_, r9);
    p_sigmaEoEVsEta_[1] ->Fill(mcEta_,sigmaEoE);


      } else if ( ( r9 <= 0.94&& phoIsInBarrel) ||  ( r9 <= 0.95&& phoIsInEndcap)  ) {
    h_phoERes_[2][0]->Fill(photonE / (*mcPho).fourMomentum().e() );
    h_phoSigmaEoE_[2][0] -> Fill (sigmaEoE);
    h_phoEResRegr1_[2][0]->Fill( photonERegr1 / (*mcPho).fourMomentum().e() );
    h_phoEResRegr2_[2][0]->Fill( photonERegr2 / (*mcPho).fourMomentum().e() );
    p_eResVsEt_[0][2]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
    p_eResVsEta_[2]->Fill (mcEta_,photonE/ (*mcPho).fourMomentum().e()  ) ;
    p_r9VsEta_[2] -> Fill (mcEta_, r9);
    p_sigmaEoEVsEta_[2] ->Fill(mcEta_, sigmaEoE);

    if ( ! isRunCentrally_ ) {
      h2_eResVsEt_[0][2]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
      h_EtR9Less093_[0][0] ->Fill ( photonEt );
    }

      }

      if ( phoIsInBarrel ) {
    h_scE_[type][1]->Fill( matchingPho->superCluster()->energy() );
    h_scEt_[type][1]->Fill( matchingPho->superCluster()->energy()/cosh( matchingPho->superCluster()->eta()) );
    h_r9_[type][1]->Fill( r9 );
    h_r1_[type][1]->Fill( r1 );
    h_r2_[type][1]->Fill( r2 );
    h_sigmaIetaIeta_[type][1]->Fill( sigmaIetaIeta );
    h_hOverE_[type][1]->Fill( hOverE );
    h_newhOverE_[type][1]->Fill( newhOverE );
    h_ecalRecHitSumEtConeDR04_[type][1]->Fill( ecalIso );
    p_ecalRecHitSumEtConeDR04VsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), ecalIso);
    h_hcalTowerSumEtConeDR04_[type][1]->Fill( hcalIso );
    p_hcalTowerSumEtConeDR04VsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), hcalIso);
    h_hcalTowerBcSumEtConeDR04_[type][1]->Fill( newhcalIso );
    p_hcalTowerBcSumEtConeDR04VsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), newhcalIso);
    h_isoTrkSolidConeDR04_[type][1]->Fill( trkIso );
    h_nTrkSolidConeDR04_[type][1]->Fill( nIsoTrk );
    h_chHadIso_[1]-> Fill (chargedHadIso);
    h_nHadIso_[1]-> Fill (neutralHadIso);
    h_phoIso_[1]-> Fill (photonIso);
    h_nCluOutsideMustache_[1]->Fill(float(nClusterOutsideMustache));
    h_etOutsideMustache_[1]->Fill(etOutsideMustache);
    h_pfMva_[1]->Fill(pfMVA);
    h_phoE_[type][1]->Fill( photonE );
    h_phoEt_[type][1]->Fill( photonEt );
    h_nConv_[type][1]->Fill(float( matchingPho->conversions().size()));
    h_nConv_[1][1]->Fill(float( matchingPho->conversionsOneLeg().size()));
    h_phoERes_[0][1]->Fill( photonE / (*mcPho).fourMomentum().e() );
    h_phoSigmaEoE_[0][1] -> Fill (sigmaEoE);
    h_phoEResRegr1_[0][1]->Fill( photonERegr1 / (*mcPho).fourMomentum().e() );
    h_phoEResRegr2_[0][1]->Fill( photonERegr2 / (*mcPho).fourMomentum().e() );
    p_eResVsR9_[1]->Fill (r9, photonE/(*mcPho).fourMomentum().e()  ) ;
    p_sceResVsR9_[1]->Fill (r9,  matchingPho->superCluster()->energy()/(*mcPho).fourMomentum().e()  ) ;
    if ( ! isRunCentrally_ ) {
      h2_eResVsR9_[1]->Fill (r9, photonE/(*mcPho).fourMomentum().e()  ) ;
      h2_sceResVsR9_[1]->Fill (r9,  matchingPho->superCluster()->energy()/(*mcPho).fourMomentum().e()  ) ;
      h2_ecalRecHitSumEtConeDR04VsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), ecalIso);
      h2_hcalTowerSumEtConeDR04VsEt_[1] -> Fill ((*mcPho).fourMomentum().et(), hcalIso);
      h2_eResVsEt_[1][0]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
    }
    p_eResVsEt_[1][0]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
    p_eResVsNVtx_[1][0]->Fill ( float(vtxH->size()), photonE/(*mcPho).fourMomentum().e()  ) ;
    p_sigmaEoEVsEt_[1][0] ->Fill ((*mcPho).fourMomentum().et(),sigmaEoE);
    p_sigmaEoEVsNVtx_[1][0]->Fill ( float(vtxH->size()), sigmaEoE);

    if ( r9 > 0.94 ) {
      h_phoERes_[1][1]->Fill(  photonE  / (*mcPho).fourMomentum().e() );
      h_phoSigmaEoE_[1][1] -> Fill (sigmaEoE);
      h_phoEResRegr1_[1][1]->Fill( photonERegr1 / (*mcPho).fourMomentum().e() );
      h_phoEResRegr2_[1][1]->Fill( photonERegr2 / (*mcPho).fourMomentum().e() );
      if ( ! isRunCentrally_ ) h2_eResVsEt_[1][1]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
      p_eResVsEt_[1][1]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
      p_eResVsNVtx_[1][1]->Fill ( float(vtxH->size()), photonE/(*mcPho).fourMomentum().e()  ) ;
      p_sigmaEoEVsEt_[1][1] ->Fill ((*mcPho).fourMomentum().et(),sigmaEoE);
      p_sigmaEoEVsNVtx_[1][1]->Fill ( float(vtxH->size()), sigmaEoE);
    }
    if ( r9 <= 0.94 )  {
      h_phoERes_[2][1]->Fill( photonE / (*mcPho).fourMomentum().e() );
      h_phoSigmaEoE_[2][1] -> Fill (sigmaEoE);
      h_phoEResRegr1_[2][1]->Fill( photonERegr1 / (*mcPho).fourMomentum().e() );
      h_phoEResRegr2_[2][1]->Fill( photonERegr2 / (*mcPho).fourMomentum().e() );
      p_eResVsEt_[1][2]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
      p_eResVsNVtx_[1][2]->Fill ( float(vtxH->size()), photonE/(*mcPho).fourMomentum().e()  ) ;
      p_sigmaEoEVsEt_[1][2] ->Fill ((*mcPho).fourMomentum().et(),sigmaEoE);
      p_sigmaEoEVsNVtx_[1][2]->Fill ( float(vtxH->size()), sigmaEoE);
      if ( ! isRunCentrally_ ) {
        h2_eResVsEt_[1][2]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
        h_EtR9Less093_[0][1] ->Fill ( photonEt );
      }
    }
      }
      if ( phoIsInEndcap ) {
    h_scE_[type][2]->Fill( matchingPho->superCluster()->energy() );
    h_scEt_[type][2]->Fill( matchingPho->superCluster()->energy()/cosh( matchingPho->superCluster()->eta()) );
    h_r9_[type][2]->Fill( r9 );
    h_r1_[type][2]->Fill( r1 );
    h_r2_[type][2]->Fill( r2 );
    h_sigmaIetaIeta_[type][2]->Fill( sigmaIetaIeta );
    h_hOverE_[type][2]->Fill( hOverE );
    h_newhOverE_[type][2]->Fill( newhOverE );
    h_ecalRecHitSumEtConeDR04_[type][2]->Fill( ecalIso );
    p_ecalRecHitSumEtConeDR04VsEt_[2] -> Fill ((*mcPho).fourMomentum().et(), ecalIso);
    h_hcalTowerSumEtConeDR04_[type][2]->Fill( hcalIso );
        p_hcalTowerSumEtConeDR04VsEt_[2] -> Fill ((*mcPho).fourMomentum().et(), hcalIso);
    h_hcalTowerBcSumEtConeDR04_[type][2]->Fill( newhcalIso );
        p_hcalTowerBcSumEtConeDR04VsEt_[2] -> Fill ((*mcPho).fourMomentum().et(), newhcalIso);
    h_isoTrkSolidConeDR04_[type][2]->Fill( trkIso );
    h_nTrkSolidConeDR04_[type][2]->Fill( nIsoTrk );
    h_chHadIso_[2]-> Fill (chargedHadIso);
    h_nHadIso_[2]-> Fill (neutralHadIso);
    h_phoIso_[2]-> Fill (photonIso);
    h_nCluOutsideMustache_[2]->Fill(float(nClusterOutsideMustache));
    h_etOutsideMustache_[2]->Fill(etOutsideMustache);
    h_pfMva_[2]->Fill(pfMVA);
    h_phoE_[type][2]->Fill( photonE );
    h_phoEt_[type][2]->Fill( photonEt );
    h_nConv_[type][2]->Fill(float( matchingPho->conversions().size()));
    h_nConv_[1][2]->Fill(float( matchingPho->conversionsOneLeg().size()));
    h_phoERes_[0][2]->Fill( photonE / (*mcPho).fourMomentum().e() );
    h_phoSigmaEoE_[0][2] -> Fill (sigmaEoE);
    h_phoEResRegr1_[0][2]->Fill( photonERegr1 / (*mcPho).fourMomentum().e() );
    h_phoEResRegr2_[0][2]->Fill( photonERegr2 / (*mcPho).fourMomentum().e() );
        p_eResVsR9_[2]->Fill (r9, photonE/(*mcPho).fourMomentum().e()  ) ;
    p_sceResVsR9_[2]->Fill (r9,  matchingPho->superCluster()->energy()/(*mcPho).fourMomentum().e()  ) ;
    if ( ! isRunCentrally_ ) {
      h2_eResVsR9_[2]->Fill (r9, photonE/(*mcPho).fourMomentum().e()  ) ;
      h2_sceResVsR9_[2]->Fill (r9,  matchingPho->superCluster()->energy()/(*mcPho).fourMomentum().e()  ) ;
      h2_ecalRecHitSumEtConeDR04VsEt_[2] -> Fill ((*mcPho).fourMomentum().et(), ecalIso);
      h2_hcalTowerSumEtConeDR04VsEt_[2] -> Fill ((*mcPho).fourMomentum().et(), hcalIso);
      h2_eResVsEt_[2][0]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
    }

    p_eResVsEt_[2][0]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
    p_eResVsNVtx_[2][0]->Fill ( float(vtxH->size()), photonE/(*mcPho).fourMomentum().e()  ) ;
    p_sigmaEoEVsEt_[2][0] ->Fill ((*mcPho).fourMomentum().et(),sigmaEoE);
    p_sigmaEoEVsNVtx_[2][0]->Fill ( float(vtxH->size()), sigmaEoE);

    if ( r9 > 0.95 ) {

      h_phoERes_[1][2]->Fill( photonE / (*mcPho).fourMomentum().e() );
      h_phoSigmaEoE_[1][2] -> Fill (sigmaEoE);
      h_phoEResRegr1_[1][2]->Fill( photonERegr1 / (*mcPho).fourMomentum().e() );
      h_phoEResRegr2_[1][2]->Fill( photonERegr2 / (*mcPho).fourMomentum().e() );
      if ( ! isRunCentrally_ ) h2_eResVsEt_[2][1]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
      p_eResVsEt_[2][1]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
      p_eResVsNVtx_[2][1]->Fill ( float(vtxH->size()), photonE/(*mcPho).fourMomentum().e()  ) ;
      p_sigmaEoEVsEt_[2][1] ->Fill ((*mcPho).fourMomentum().et(),sigmaEoE);
      p_sigmaEoEVsNVtx_[2][1]->Fill ( float(vtxH->size()), sigmaEoE);
    }
    if ( r9 <= 0.95 ) {
      h_phoERes_[2][2]->Fill( photonE / (*mcPho).fourMomentum().e() );
      h_phoSigmaEoE_[2][2] -> Fill (sigmaEoE);
      h_phoEResRegr1_[2][2]->Fill( photonERegr1 / (*mcPho).fourMomentum().e() );
      h_phoEResRegr2_[2][2]->Fill( photonERegr2 / (*mcPho).fourMomentum().e() );
      p_eResVsEt_[2][2]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
      p_eResVsNVtx_[2][2]->Fill ( float(vtxH->size()), photonE/(*mcPho).fourMomentum().e()  ) ;
      p_sigmaEoEVsEt_[2][2] ->Fill ((*mcPho).fourMomentum().et(),sigmaEoE);
      p_sigmaEoEVsNVtx_[2][2]->Fill ( float(vtxH->size()), sigmaEoE);

      if ( ! isRunCentrally_ ) {
        h2_eResVsEt_[2][2]->Fill ((*mcPho).fourMomentum().et(), photonE/(*mcPho).fourMomentum().e()  ) ;
        h_EtR9Less093_[0][2] ->Fill ( photonEt );
      }
    }
      }

      if ( fName_ == "pfPhotonValidator") {
    
    float SumPtIsoValCh = 0.;   
    float SumPtIsoValNh = 0.;
    float SumPtIsoValPh = 0.;
    
    float SumPtIsoValCleanCh = 0.;  
    float SumPtIsoValCleanNh = 0.;
    float SumPtIsoValCleanPh = 0.;

    for(unsigned int lCand=0; lCand < pfCandidateHandle->size(); lCand++) {
      reco::PFCandidateRef pfCandRef(reco::PFCandidateRef(pfCandidateHandle,lCand));
      float dR= deltaR(matchingPho->eta(),  matchingPho->phi(),pfCandRef->eta(),  pfCandRef->phi()); 
      if ( dR<0.4) {
        reco::PFCandidate::ParticleType type = pfCandRef->particleId();
        if ( type == reco::PFCandidate::e ) continue; 
        if ( type == reco::PFCandidate::gamma && pfCandRef->mva_nothing_gamma() > 0.) continue;
        
        if( type == reco::PFCandidate::h ) {
          SumPtIsoValCh += pfCandRef->pt();
          h_dRPhoPFcand_ChHad_unCleaned_[0]->Fill(dR);
          if( phoIsInBarrel)
        h_dRPhoPFcand_ChHad_unCleaned_[1]->Fill(dR);
          else 
        h_dRPhoPFcand_ChHad_unCleaned_[2]->Fill(dR);
        }
        if( type == reco::PFCandidate::h0 ) {
          SumPtIsoValNh += pfCandRef->pt();
          h_dRPhoPFcand_NeuHad_unCleaned_[0]->Fill(dR);
          if( phoIsInBarrel)
        h_dRPhoPFcand_NeuHad_unCleaned_[1]->Fill(dR);
          else 
        h_dRPhoPFcand_NeuHad_unCleaned_[2]->Fill(dR);
        }
        if( type == reco::PFCandidate::gamma ) {
          SumPtIsoValPh += pfCandRef->pt();
          h_dRPhoPFcand_Pho_unCleaned_[0]->Fill(dR);
          if( phoIsInBarrel)
        h_dRPhoPFcand_Pho_unCleaned_[1]->Fill(dR);
          else 
        h_dRPhoPFcand_Pho_unCleaned_[2]->Fill(dR);
        }
            bool skip=false;
        for( std::vector<reco::PFCandidateRef>::const_iterator i = phoToParticleBasedIsoMap[matchingPho].begin(); i != phoToParticleBasedIsoMap[matchingPho].end(); ++i ) {
          if ( (*i) == pfCandRef ) {
        skip=true;
          }
        } // loop over the PFCandidates flagged as overlapping with the photon

            if ( skip ) continue;
        if( type == reco::PFCandidate::h ) {
          SumPtIsoValCleanCh += pfCandRef->pt();
          h_dRPhoPFcand_ChHad_Cleaned_[0]->Fill(dR);
          if( phoIsInBarrel)
        h_dRPhoPFcand_ChHad_Cleaned_[1]->Fill(dR);
          else 
        h_dRPhoPFcand_ChHad_Cleaned_[2]->Fill(dR);
        }
        if( type == reco::PFCandidate::h0 ) {
          SumPtIsoValCleanNh += pfCandRef->pt();
          h_dRPhoPFcand_NeuHad_Cleaned_[0]->Fill(dR);
          if( phoIsInBarrel)
        h_dRPhoPFcand_NeuHad_Cleaned_[1]->Fill(dR);
          else 
        h_dRPhoPFcand_NeuHad_Cleaned_[2]->Fill(dR);
        }
        if( type == reco::PFCandidate::gamma ) {
          SumPtIsoValCleanPh += pfCandRef->pt();
          h_dRPhoPFcand_Pho_Cleaned_[0]->Fill(dR);
          if( phoIsInBarrel)
        h_dRPhoPFcand_Pho_Cleaned_[1]->Fill(dR);
          else 
        h_dRPhoPFcand_Pho_Cleaned_[2]->Fill(dR);
        }
        
        
        
        
      }  // dr=0.4          
    }  // loop over all PF Candidates

    h_SumPtOverPhoPt_ChHad_Cleaned_[0]->Fill(SumPtIsoValCleanCh/matchingPho->pt());
    h_SumPtOverPhoPt_NeuHad_Cleaned_[0]->Fill(SumPtIsoValCleanNh/matchingPho->pt());
    h_SumPtOverPhoPt_Pho_Cleaned_[0]->Fill(SumPtIsoValCleanPh/matchingPho->pt());
    h_SumPtOverPhoPt_ChHad_unCleaned_[0]->Fill(SumPtIsoValCh/matchingPho->pt());
    h_SumPtOverPhoPt_NeuHad_unCleaned_[0]->Fill(SumPtIsoValNh/matchingPho->pt());
    h_SumPtOverPhoPt_Pho_unCleaned_[0]->Fill(SumPtIsoValPh/matchingPho->pt());
    if( phoIsInBarrel) {
      h_SumPtOverPhoPt_ChHad_Cleaned_[1]->Fill(SumPtIsoValCleanCh/matchingPho->pt());
      h_SumPtOverPhoPt_NeuHad_Cleaned_[1]->Fill(SumPtIsoValCleanNh/matchingPho->pt());
      h_SumPtOverPhoPt_Pho_Cleaned_[1]->Fill(SumPtIsoValCleanPh/matchingPho->pt());
      h_SumPtOverPhoPt_ChHad_unCleaned_[1]->Fill(SumPtIsoValCh/matchingPho->pt());
      h_SumPtOverPhoPt_NeuHad_unCleaned_[1]->Fill(SumPtIsoValNh/matchingPho->pt());
      h_SumPtOverPhoPt_Pho_unCleaned_[1]->Fill(SumPtIsoValPh/matchingPho->pt());
    } else {
      h_SumPtOverPhoPt_ChHad_Cleaned_[2]->Fill(SumPtIsoValCleanCh/matchingPho->pt());
      h_SumPtOverPhoPt_NeuHad_Cleaned_[2]->Fill(SumPtIsoValCleanNh/matchingPho->pt());
      h_SumPtOverPhoPt_Pho_Cleaned_[2]->Fill(SumPtIsoValCleanPh/matchingPho->pt());
      h_SumPtOverPhoPt_ChHad_unCleaned_[2]->Fill(SumPtIsoValCh/matchingPho->pt());
      h_SumPtOverPhoPt_NeuHad_unCleaned_[2]->Fill(SumPtIsoValNh/matchingPho->pt());
      h_SumPtOverPhoPt_Pho_unCleaned_[2]->Fill(SumPtIsoValPh/matchingPho->pt());
    }
    
      } // only for pfPhotonValidator 


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

      if ( ! isRunCentrally_ ) {
    h_r9_[1][0]->Fill( r9 );
    if ( phoIsInBarrel ) h_r9_[1][1]->Fill( r9 );
    if ( phoIsInEndcap ) h_r9_[1][2]->Fill( r9 );

    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_  ) ;
      }


      if ( ! fastSim_) {
    reco::ConversionRefVector conversions = matchingPho->conversions();
        bool atLeastOneRecoTwoTrackConversion=false;
    for (unsigned int iConv=0; iConv<conversions.size(); iConv++) {
      reco::ConversionRef aConv=conversions[iConv];
      double like = aConv->MVAout();
      if ( like < likelihoodCut_ ) continue;

      if ( ! isRunCentrally_ ) h2_EoverEtrueVsEta_[1]->Fill (mcEta_,matchingPho->superCluster()->energy()/ (*mcPho).fourMomentum().e()  ) ;
      p_EoverEtrueVsEta_[1]->Fill (mcEta_,matchingPho->superCluster()->energy()/ (*mcPho).fourMomentum().e()  ) ;


      //std::vector<reco::TrackRef> tracks = aConv->tracks();
      const std::vector<edm::RefToBase<reco::Track> > tracks = aConv->tracks();
      if (tracks.size() < 2 ) continue;
          atLeastOneRecoTwoTrackConversion=true;

      h_mvaOut_[0]-> Fill(like);

      if ( tracks.size()==2 ) {
        if ( sqrt( aConv->tracksPin()[0].Perp2()) < convTrackMinPtCut_ || sqrt( aConv->tracksPin()[1].Perp2()) < convTrackMinPtCut_) continue;
      } 


      if ( dCotCutOn_ ) {
        if (  (fabs(mcEta_) > 1.1 && fabs (mcEta_)  < 1.4  )  &&
          fabs( aConv->pairCotThetaSeparation() ) > dCotHardCutValue_ ) continue;
        if ( fabs( aConv->pairCotThetaSeparation() ) > dCotCutValue_ ) continue;
      }

      nRecConv_++;

      std::map<const reco::Track*,TrackingParticleRef> myAss;
      std::map<const reco::Track*,TrackingParticleRef>::const_iterator itAss;
      std::map<reco::TrackRef,TrackingParticleRef>::const_iterator itAssMin;
      std::map<reco::TrackRef,TrackingParticleRef>::const_iterator itAssMax;
      //

      int nAssT2=0;
      for (unsigned int i=0; i<tracks.size(); i++) {
        //      reco::TrackRef track = tracks[i].castTo<reco::TrackRef>();

        type =0;
        if ( ! isRunCentrally_ ) nHitsVsEta_[type] ->Fill (mcEta_,   float(tracks[i]->numberOfValidHits())-0.0001 );
        if ( ! isRunCentrally_ ) nHitsVsR_[type] ->Fill (mcConvR_,   float(tracks[i]->numberOfValidHits())-0.0001 );
        p_nHitsVsEta_[type] ->Fill (mcEta_,   float(tracks[i]->numberOfValidHits()-0.0001) );
        p_nHitsVsR_[type] ->Fill (mcConvR_,   float(tracks[i]->numberOfValidHits()-0.0001) );
        h_tkChi2_[type] ->Fill (tracks[i]->normalizedChi2() );

        RefToBase<reco::Track> tfrb = tracks[i];
        RefToBaseVector<reco::Track> tc;
            tc.push_back(tfrb);
        // reco::RecoToSimCollection q = trackAssociator->associateRecoToSim(tc,theConvTP_);
        reco::SimToRecoCollection q = trackAssociator->associateSimToReco(tc,theConvTP_);
        std::vector<std::pair<RefToBase<reco::Track>, double> >  trackV;
        int tpI = 0;

        if (q.find(theConvTP_[0])!=q.end()){
          trackV = (std::vector<std::pair<RefToBase<reco::Track>, double> >) q[theConvTP_[0]];
        } else if (q.find(theConvTP_[1])!=q.end()){
          trackV = (std::vector<std::pair<RefToBase<reco::Track>, double> >) q[theConvTP_[1]];
          tpI = 1;
        }

            if ( !trackV.size() ) continue;
        edm::RefToBase<reco::Track> tr = trackV.front().first;
        myAss.insert( std::make_pair (tr.get(),theConvTP_[tpI] ) );
        nAssT2++;

      }


      type=0;

      //      float totP = sqrt(aConv->pairMomentum().Mag2());
      float refP =-99999.;
      float refPt =-99999.;
          if ( aConv->conversionVertex().isValid() ) {
            refP=sqrt(aConv->refittedPairMomentum().Mag2());
            refPt=sqrt(aConv->refittedPairMomentum().perp2());
      }
          float invM = aConv->pairInvariantMass();

      h_invMass_[type][0] ->Fill( invM);
      if ( phoIsInBarrel ) h_invMass_[type][1] ->Fill(invM);
      if ( phoIsInEndcap ) h_invMass_[type][2] ->Fill(invM);

      if ( tracks.size() ==2 ) {
        
        h_SimConvTwoTracks_[0]->Fill( mcEta_ ) ;
        h_SimConvTwoTracks_[1]->Fill( mcPhi_ );
        h_SimConvTwoTracks_[2]->Fill( mcConvR_ );
        h_SimConvTwoTracks_[3]->Fill( mcConvZ_ );
        h_SimConvTwoTracks_[4]->Fill(  (*mcPho).fourMomentum().et());

        if (aConv->caloCluster().size() !=0) h_convEta_[1]->Fill( aConv->caloCluster()[0]->eta() );

        float trkProvenance=3;
        if ( tracks[0]->algoName() == "outInEcalSeededConv"  &&  tracks[1]->algoName() == "outInEcalSeededConv" ) trkProvenance=0;
        if ( tracks[0]->algoName() == "inOutEcalSeededConv"  &&  tracks[1]->algoName() == "inOutEcalSeededConv" ) trkProvenance=1;
        if ( ( tracks[0]->algoName() == "outInEcalSeededConv"  &&  tracks[1]->algoName() == "inOutEcalSeededConv") ||
         ( tracks[1]->algoName() == "outInEcalSeededConv"  &&  tracks[0]->algoName() == "inOutEcalSeededConv") ) trkProvenance=2;
        if ( trkProvenance==3 ) {
        }
        h_trkProv_[0]->Fill( trkProvenance );
            h_trkAlgo_->Fill (  tracks[0]->algo() );
            h_trkAlgo_->Fill (  tracks[1]->algo() );
            h_convAlgo_->Fill ( aConv->algo() );

        if ( nAssT2 ==2 ) {



          if ( ! isRunCentrally_ ) {
        h_r9_[2][0]->Fill( r9 );
        if ( phoIsInBarrel ) h_r9_[2][1]->Fill( r9 );
        if ( phoIsInEndcap ) h_r9_[2][2]->Fill( r9 );
          }

          if (aConv->caloCluster().size() !=0)  h_convEta_[2]->Fill( aConv->caloCluster()[0]->eta() );
          nRecConvAss_++;


          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 ( aConv->conversionVertex().isValid() ) {
        float chi2Prob = ChiSquaredProbability( aConv->conversionVertex().chi2(),  aConv->conversionVertex().ndof() );
        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());


        }

        if (  chi2Prob > 0.0005 ) {
          if (aConv->caloCluster().size() !=0) {
            h_convEta_[0]->Fill( aConv->caloCluster()[0]->eta() );
            h_convPhi_[0]->Fill( aConv->caloCluster()[0]->phi() );
            h_convERes_[0][0]->Fill( aConv->caloCluster()[0]->energy() / (*mcPho).fourMomentum().e() );
          }
          if ( ! isRunCentrally_ ) {
            h_r9VsNofTracks_[0][0]->Fill( r9, aConv->nTracks() ) ;
            h_EtR9Less093_[1][0] ->Fill ( photonEt );
            if ( phoIsInBarrel ) h_EtR9Less093_[1][1] ->Fill ( photonEt );
            if ( phoIsInEndcap ) h_EtR9Less093_[1][2] ->Fill ( photonEt );
          }
          if ( phoIsInBarrel )  {
            if (aConv->caloCluster().size() !=0) h_convERes_[0][1]->Fill(aConv->caloCluster()[0]->energy() / (*mcPho).fourMomentum().e() );
            if ( ! isRunCentrally_ ) h_r9VsNofTracks_[0][1]->Fill( r9, aConv->nTracks() ) ;
            h_mvaOut_[1]-> Fill(like);
          }
          if ( phoIsInEndcap ) {
            if (aConv->caloCluster().size() !=0)  h_convERes_[0][2]->Fill(aConv->caloCluster()[0]->energy() / (*mcPho).fourMomentum().e() );
            if ( ! isRunCentrally_ ) h_r9VsNofTracks_[0][2]->Fill( r9, aConv->nTracks() ) ;
            h_mvaOut_[2]-> Fill(like);
          }

        }




          }


          type =1;

          h_trkProv_[1]->Fill( trkProvenance );
          h_invMass_[type][0] ->Fill( invM);

          float eoverp= -99999.;

          if ( aConv->conversionVertex().isValid() ) {
        eoverp = photonE/sqrt(aConv->refittedPairMomentum().Mag2());
          //eoverp= aConv->EoverPrefittedTracks();
        h_convPtRes_[type][0]->Fill( refPt / (*mcPho).fourMomentum().et() );
        h_EoverPTracks_[type][0] ->Fill( eoverp ) ;
        h_PoverETracks_[type][0] ->Fill( 1./eoverp ) ;
        if ( ! isRunCentrally_ ) h2_EoverEtrueVsEoverP_[0] ->Fill( eoverp,matchingPho->superCluster()->energy()/ (*mcPho).fourMomentum().e()  ) ;
        if ( ! isRunCentrally_ ) h2_PoverPtrueVsEoverP_[0] ->Fill( eoverp, refP/ (*mcPho).fourMomentum().e()  ) ;
        if ( ! isRunCentrally_ ) h2_EoverPVsEta_[0]->Fill (mcEta_, eoverp);
        if ( ! isRunCentrally_ ) h2_EoverPVsR_[0]->Fill (mcConvR_, eoverp);
        p_EoverPVsEta_[0]->Fill (mcEta_, eoverp);
        p_EoverPVsR_[0]->Fill (mcConvR_, eoverp);
        p_eResVsR_ ->Fill ( mcConvR_, photonE / (*mcPho).fourMomentum().e() );
                if ( ! isRunCentrally_ ) h2_PoverPtrueVsEta_[0]->Fill (mcEta_,refP/ (*mcPho).fourMomentum().e()  ) ;
        p_PoverPtrueVsEta_[0]->Fill (mcEta_,refP/ (*mcPho).fourMomentum().e()  ) ;


          }

          if ( ! isRunCentrally_ )  h2_EoverEtrueVsEta_[0]->Fill (mcEta_,matchingPho->superCluster()->energy()/ (*mcPho).fourMomentum().e()  ) ;
          if ( ! isRunCentrally_ )  h2_EoverEtrueVsR_[0]->Fill (mcConvR_,matchingPho->superCluster()->energy()/ (*mcPho).fourMomentum().e()  ) ;
          p_EoverEtrueVsEta_[0]->Fill (mcEta_,matchingPho->superCluster()->energy()/ (*mcPho).fourMomentum().e()  ) ;
          p_EoverEtrueVsR_[0]->Fill (mcConvR_,matchingPho->superCluster()->energy()/ (*mcPho).fourMomentum().e()  ) ;


          if ( ! isRunCentrally_ ) h2_etaVsRsim_[0]->Fill (mcEta_,mcConvR_);

          //  here original tracks and their inner momentum is considered
          float  dPhiTracksAtVtx =  aConv->dPhiTracksAtVtx();
          h_DPhiTracksAtVtx_[type][0]->Fill( dPhiTracksAtVtx);
          if ( ! isRunCentrally_ ) h2_DPhiTracksAtVtxVsEta_->Fill( mcEta_, dPhiTracksAtVtx);
          if ( ! isRunCentrally_ ) h2_DPhiTracksAtVtxVsR_->Fill( mcConvR_, dPhiTracksAtVtx);
          p_DPhiTracksAtVtxVsEta_->Fill( mcEta_, dPhiTracksAtVtx);
          p_DPhiTracksAtVtxVsR_->Fill( mcConvR_, dPhiTracksAtVtx);

          h_DCotTracks_[type][0] ->Fill ( aConv->pairCotThetaSeparation() );
          if ( ! isRunCentrally_ ) h2_DCotTracksVsEta_->Fill( mcEta_, aConv->pairCotThetaSeparation() );
          if ( ! isRunCentrally_ ) h2_DCotTracksVsR_->Fill( mcConvR_, aConv->pairCotThetaSeparation() );
          p_DCotTracksVsEta_->Fill( mcEta_, aConv->pairCotThetaSeparation() );
          p_DCotTracksVsR_->Fill( mcConvR_, aConv->pairCotThetaSeparation() );

          if ( phoIsInBarrel ) {
        h_invMass_[type][1] ->Fill(invM);
        if ( aConv->conversionVertex().isValid() ) {
          h_convPtRes_[type][1]->Fill( refPt / (*mcPho).fourMomentum().et() );
          h_EoverPTracks_[type][1] ->Fill( eoverp ) ;
          if (  mcConvR_ < 15 )                 h_EoverPTracks_[0][0] ->Fill( eoverp ) ;
          if (  mcConvR_ > 15 && mcConvR_< 58 ) h_EoverPTracks_[0][1] ->Fill( eoverp ) ;
          if (  mcConvR_ > 58 )                 h_EoverPTracks_[0][2] ->Fill( eoverp ) ;
          h_PoverETracks_[type][1] ->Fill( 1./eoverp ) ;
          if ( ! isRunCentrally_ ) h2_EoverEtrueVsEoverP_[1] ->Fill( eoverp,matchingPho->superCluster()->energy()/ (*mcPho).fourMomentum().e()  ) ;
          if ( ! isRunCentrally_ ) h2_PoverPtrueVsEoverP_[1] ->Fill( eoverp, refP/ (*mcPho).fourMomentum().e()  ) ;
        }
        h_DPhiTracksAtVtx_[type][1]->Fill( dPhiTracksAtVtx);
        h_DCotTracks_[type][1] ->Fill ( aConv->pairCotThetaSeparation() );


          }

          if ( phoIsInEndcap ) {
        h_invMass_[type][2] ->Fill(invM);
        if ( aConv->conversionVertex().isValid() ) {
          h_convPtRes_[type][2]->Fill( refPt / (*mcPho).fourMomentum().et() );
          h_EoverPTracks_[type][2] ->Fill( eoverp ) ;
          h_PoverETracks_[type][2] ->Fill( 1./eoverp ) ;
          if ( ! isRunCentrally_ ) h2_EoverEtrueVsEoverP_[2] ->Fill( eoverp,matchingPho->superCluster()->energy()/ (*mcPho).fourMomentum().e()  ) ;
          if ( ! isRunCentrally_ ) h2_PoverPtrueVsEoverP_[2] ->Fill( eoverp, refP/ (*mcPho).fourMomentum().e()  ) ;
        }
        h_DPhiTracksAtVtx_[type][2]->Fill( dPhiTracksAtVtx);
        h_DCotTracks_[type][2] ->Fill ( aConv->pairCotThetaSeparation() );

          }

          if ( aConv->conversionVertex().isValid() ) {

        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_);

        if ( fabs( mcConvEta_ ) <= 1.2 ) {
          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_);
        } else {
          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_);
        }

        h_convVtxdPhi_ ->Fill ( aConv->conversionVertex().position().phi() - mcConvPhi_);
        h_convVtxdEta_ ->Fill ( aConv->conversionVertex().position().eta() - mcConvEta_);
        if ( ! isRunCentrally_ ) h2_convVtxdRVsR_ ->Fill (mcConvR_, sqrt(aConv->conversionVertex().position().perp2()) - mcConvR_ );
        if ( ! isRunCentrally_ ) 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_ );
        float signX= aConv->refittedPairMomentum().x()/fabs(aConv->refittedPairMomentum().x());
        float signY= aConv->refittedPairMomentum().y()/fabs(aConv->refittedPairMomentum().y());
        float signZ= aConv->refittedPairMomentum().z()/fabs(aConv->refittedPairMomentum().z());
        p_convVtxdXVsX_ ->Fill (mcConvX_, (aConv->conversionVertex().position().x() - mcConvX_)*signX );
        p_convVtxdYVsY_ ->Fill (mcConvY_, (aConv->conversionVertex().position().y() - mcConvY_)*signY );
        p_convVtxdZVsZ_ ->Fill (mcConvZ_, (aConv->conversionVertex().position().z() - mcConvZ_)*signZ );


        if ( ! isRunCentrally_ ) h2_convVtxRrecVsTrue_ -> Fill (mcConvR_, sqrt(aConv->conversionVertex().position().perp2()) );



        //float zPV = aConv->zOfPrimaryVertexFromTracks();
        float thetaConv=aConv->refittedPairMomentum().Theta();
                float thetaSC=matchingPho->superCluster()->position().theta();
                float rSC=sqrt(matchingPho->superCluster()->position().x()*matchingPho->superCluster()->position().x() +
                   matchingPho->superCluster()->position().y()*matchingPho->superCluster()->position().y() );
                float zSC=matchingPho->superCluster()->position().z();
                float zPV = sqrt(rSC*rSC+zSC*zSC)*sin( thetaConv - thetaSC)/sin(thetaConv);

        h_zPVFromTracks_[0]->Fill (  zPV );
        h_dzPVFromTracks_[0]->Fill ( zPV- (*mcPho).primaryVertex().z() );

        if ( phoIsInBarrel ) {
          h_zPVFromTracks_[1]->Fill ( zPV );
          h_dzPVFromTracks_[1]->Fill ( zPV - (*mcPho).primaryVertex().z() );
        } else if ( phoIsInEndcap) {
          h_zPVFromTracks_[2]->Fill ( zPV );
          h_dzPVFromTracks_[2]->Fill ( zPV - (*mcPho).primaryVertex().z() );
        } else if ( phoIsInEndcapP) {
          h_zPVFromTracks_[3]->Fill ( zPV );
          h_dzPVFromTracks_[3]->Fill ( zPV - (*mcPho).primaryVertex().z() );
        }  else if ( phoIsInEndcapM) {
          h_zPVFromTracks_[4]->Fill ( zPV );
          h_dzPVFromTracks_[4]->Fill ( zPV - (*mcPho).primaryVertex().z() );
        }

        p_dzPVVsR_ ->Fill(mcConvR_, zPV - (*mcPho).primaryVertex().z() );
        p_dzPVVsEta_ ->Fill(mcConvEta_, zPV - (*mcPho).primaryVertex().z() );
        if ( ! isRunCentrally_ ) h2_dzPVVsR_ ->Fill(mcConvR_, zPV - (*mcPho).primaryVertex().z() );
          }

          float  dPhiTracksAtEcal=-99;
          float  dEtaTracksAtEcal=-99;
        if (aConv->bcMatchingWithTracks().size() > 0 && aConv->bcMatchingWithTracks()[0].isNonnull() && aConv->bcMatchingWithTracks()[1].isNonnull() ) {
          nRecConvAssWithEcal_++;
          float recoPhi1 = aConv->ecalImpactPosition()[0].phi();
          float recoPhi2 = aConv->ecalImpactPosition()[1].phi();
          float recoEta1 = aConv->ecalImpactPosition()[0].eta();
          float recoEta2 = aConv->ecalImpactPosition()[1].eta();
          float bcPhi1 = aConv->bcMatchingWithTracks()[0]->phi();
          float bcPhi2 = aConv->bcMatchingWithTracks()[1]->phi();
          // unused float bcEta1 = aConv->bcMatchingWithTracks()[0]->eta();
          // unused   float bcEta2 = aConv->bcMatchingWithTracks()[1]->eta();
          recoPhi1 = phiNormalization(recoPhi1);
          recoPhi2 = phiNormalization(recoPhi2);
          bcPhi1 = phiNormalization(bcPhi1);
          bcPhi2 = phiNormalization(bcPhi2);
          dPhiTracksAtEcal = recoPhi1 -recoPhi2;
          dPhiTracksAtEcal = phiNormalization( dPhiTracksAtEcal );
          dEtaTracksAtEcal = recoEta1 -recoEta2;

          h_DPhiTracksAtEcal_[type][0]->Fill( fabs(dPhiTracksAtEcal));
          if ( ! isRunCentrally_ ) h2_DPhiTracksAtEcalVsR_ ->Fill (mcConvR_, fabs(dPhiTracksAtEcal));
          if ( ! isRunCentrally_ ) h2_DPhiTracksAtEcalVsEta_ ->Fill (mcEta_, fabs(dPhiTracksAtEcal));
          p_DPhiTracksAtEcalVsR_ ->Fill (mcConvR_, fabs(dPhiTracksAtEcal));
          p_DPhiTracksAtEcalVsEta_ ->Fill (mcEta_, fabs(dPhiTracksAtEcal));

          h_DEtaTracksAtEcal_[type][0]->Fill( dEtaTracksAtEcal);

          if ( phoIsInBarrel ) {
            h_DPhiTracksAtEcal_[type][1]->Fill( fabs(dPhiTracksAtEcal));
            h_DEtaTracksAtEcal_[type][1]->Fill( dEtaTracksAtEcal);
          }
          if ( phoIsInEndcap ) {
            h_DPhiTracksAtEcal_[type][2]->Fill( fabs(dPhiTracksAtEcal));
            h_DEtaTracksAtEcal_[type][2]->Fill( dEtaTracksAtEcal);
          }
        }
          for (unsigned int i=0; i<tracks.size(); i++) {
        RefToBase<reco::Track> tfrb(tracks[i] );
        itAss= myAss.find( tfrb.get() );
        if ( itAss == myAss.end()  ) continue;

        float trkProvenance=3;
        if ( tracks[0]->algoName() == "outInEcalSeededConv"  &&  tracks[1]->algoName() == "outInEcalSeededConv" ) trkProvenance=0;
        if ( tracks[0]->algoName() == "inOutEcalSeededConv"  &&  tracks[1]->algoName() == "inOutEcalSeededConv" ) trkProvenance=1;
        if ( ( tracks[0]->algoName() == "outInEcalSeededConv"  &&  tracks[1]->algoName() == "inOutEcalSeededConv") ||
             ( tracks[1]->algoName() == "outInEcalSeededConv"  &&  tracks[0]->algoName() == "inOutEcalSeededConv") ) trkProvenance=2;

        if ( ! isRunCentrally_ ) nHitsVsEta_[type] ->Fill (mcEta_,   float(tracks[i]->numberOfValidHits()) );
                if ( ! isRunCentrally_ ) nHitsVsR_[type] ->Fill (mcConvR_,   float(tracks[i]->numberOfValidHits()) );
        p_nHitsVsEta_[type] ->Fill (mcEta_,   float(tracks[i]->numberOfValidHits()) -0.0001);
        p_nHitsVsR_[type] ->Fill (mcConvR_,   float(tracks[i]->numberOfValidHits()) -0.0001);
        h_tkChi2_[type] ->Fill (tracks[i]->normalizedChi2() );
        h_tkChi2Large_[type] ->Fill (tracks[i]->normalizedChi2() );
        if ( ! isRunCentrally_ ) h2_Chi2VsEta_[0] ->Fill(  mcEta_, tracks[i]->normalizedChi2() );
                if ( ! isRunCentrally_ ) h2_Chi2VsR_[0] ->Fill(  mcConvR_, tracks[i]->normalizedChi2() );
        p_Chi2VsEta_[0] ->Fill(  mcEta_, tracks[i]->normalizedChi2() );
        p_Chi2VsR_[0] ->Fill(  mcConvR_, tracks[i]->normalizedChi2() );


        float simPt = sqrt( ((*itAss).second)->momentum().perp2() );
        //      float recPt =   sqrt( aConv->tracks()[i]->innerMomentum().Perp2() ) ;
        float refPt=-9999.;
        float px=0, py=0;

        if ( aConv->conversionVertex().isValid() ) {
          reco::Track refTrack= aConv->conversionVertex().refittedTracks()[i];
          px= refTrack.momentum().x() ;
          py= refTrack.momentum().y() ;
          refPt=sqrt (px*px + py*py );

          float ptres= refPt - simPt ;
          // float pterror = aConv->tracks()[i]->ptError();
          float pterror =  aConv->conversionVertex().refittedTracks()[i].ptError();
          if ( ! isRunCentrally_ ) {
            h2_PtRecVsPtSim_[0]->Fill ( simPt, refPt);
            if ( trkProvenance ==3 ) h2_PtRecVsPtSimMixProv_->Fill ( simPt, refPt);
          }

          h_TkPtPull_[0] ->Fill(ptres/pterror);
                  if ( ! isRunCentrally_ ) h2_TkPtPull_[0] ->Fill(mcEta_, ptres/pterror);

          h_TkD0_[0]->Fill ( tracks[i]->d0()* tracks[i]->charge() );


          // if ( fName_ != "pfPhotonValidator" &&  fName_ != "oldpfPhotonValidator" )
          if ( aConv->bcMatchingWithTracks().size() > 0 && aConv->bcMatchingWithTracks()[i].isNonnull() ) hBCEnergyOverTrackPout_[0]->Fill  ( aConv->bcMatchingWithTracks()[i]->energy()/sqrt(aConv->tracks()[i]->outerMomentum().Mag2())  );

          if ( phoIsInBarrel ) {
            h_TkD0_[1]->Fill ( tracks[i]->d0()* tracks[i]->charge() );
            h_TkPtPull_[1] ->Fill(ptres/pterror);
            if ( ! isRunCentrally_ ) h2_PtRecVsPtSim_[1]->Fill ( simPt, refPt);
            //if ( fName_ != "pfPhotonValidator"  &&  fName_ != "oldpfPhotonValidator")
            if ( aConv->bcMatchingWithTracks().size() > 0 && aConv->bcMatchingWithTracks()[i].isNonnull() ) hBCEnergyOverTrackPout_[1]->Fill  ( aConv->bcMatchingWithTracks()[i]->energy()/sqrt(aConv->tracks()[i]->outerMomentum().Mag2())  );

          }
          if ( phoIsInEndcap ) {
            h_TkD0_[2]->Fill ( tracks[i]->d0()* tracks[i]->charge() );
            h_TkPtPull_[2] ->Fill(ptres/pterror);
            if ( ! isRunCentrally_ ) h2_PtRecVsPtSim_[2]->Fill ( simPt, refPt);
            //          if ( fName_ != "pfPhotonValidator" &&  fName_ != "oldpfPhotonValidator")
            if ( aConv->bcMatchingWithTracks().size() > 0 && aConv->bcMatchingWithTracks()[i].isNonnull() ) hBCEnergyOverTrackPout_[2]->Fill  ( aConv->bcMatchingWithTracks()[i]->energy()/sqrt(aConv->tracks()[i]->outerMomentum().Mag2())  );
          }

        }

          } // end loop over track
        } // end analysis of two associated tracks
      } // end analysis of two  tracks

    } // loop over conversions

        
    reco::ConversionRefVector conversionsOneLeg = matchingPho->conversionsOneLeg();
    if ( !atLeastOneRecoTwoTrackConversion  ) {
      for (unsigned int iConv=0; iConv<conversionsOneLeg.size(); iConv++) {
        reco::ConversionRef aConv=conversionsOneLeg[iConv];
        const std::vector<edm::RefToBase<reco::Track> > tracks = aConv->tracks();

            h_trkAlgo_->Fill (  tracks[0]->algo() );
            h_convAlgo_->Fill ( aConv->algo() );
        
        int nAssT=0;
        std::map<const reco::Track*,TrackingParticleRef> myAss;
        for (unsigned int i=0; i<tracks.size(); i++) {
        
       
          p_nHitsVsEtaSL_[0] ->Fill (mcEta_,   float(tracks[0]->numberOfValidHits()-0.0001) );
          p_nHitsVsRSL_[0] ->Fill (mcConvR_,   float(tracks[0]->numberOfValidHits()-0.0001) );
          h_tkChi2SL_[0] ->Fill (tracks[0]->normalizedChi2() );


          float eoverp = photonE/tracks[0]->p();
          h_EoverP_SL_[0]->Fill ( eoverp );
          if ( phoIsInBarrel ) {
        h_EoverP_SL_[1]->Fill ( eoverp );
          } else {
        h_EoverP_SL_[2]->Fill ( eoverp );
          }
          h_convSLVtxRvsZ_[0] ->Fill ( tracks[0]->innerPosition().z(), sqrt( tracks[0]->innerPosition().Perp2() ) );          
          if ( fabs(mcEta_) <=1.) {
        h_convSLVtxRvsZ_[1] ->Fill ( tracks[0]->innerPosition().z(), sqrt( tracks[0]->innerPosition().Perp2() ) );        
          } else {
        h_convSLVtxRvsZ_[2] ->Fill ( tracks[0]->innerPosition().z(), sqrt( tracks[0]->innerPosition().Perp2() ) );        
         } 

          RefToBase<reco::Track> tfrb = tracks[i];
          RefToBaseVector<reco::Track> tc;
          tc.push_back(tfrb);
          reco::SimToRecoCollection q = trackAssociator->associateSimToReco(tc,theConvTP_);
          std::vector<std::pair<RefToBase<reco::Track>, double> >  trackV;
          int tpI = 0;
          
          if (q.find(theConvTP_[0])!=q.end()){
        trackV = (std::vector<std::pair<RefToBase<reco::Track>, double> >) q[theConvTP_[0]];
          } else if (q.find(theConvTP_[1])!=q.end()){
        trackV = (std::vector<std::pair<RefToBase<reco::Track>, double> >) q[theConvTP_[1]];
        tpI = 1;
          }
          
          if ( !trackV.size() ) continue;
          edm::RefToBase<reco::Track> tr = trackV.front().first;
          myAss.insert( std::make_pair (tr.get(),theConvTP_[tpI] ) );
          nAssT++;
          
        }
        
            if ( nAssT > 0 ) {
          h_SimConvOneMTracks_[0]->Fill( mcEta_ ) ;
          h_SimConvOneMTracks_[1]->Fill( mcPhi_ );
          h_SimConvOneMTracks_[2]->Fill( mcConvR_ );
          h_SimConvOneMTracks_[3]->Fill( mcConvZ_ );
          h_SimConvOneMTracks_[4]->Fill(  (*mcPho).fourMomentum().et());
        
        }
      } // End loop over single leg conversions
      
    } 

      }  // if !fastSim
    }  // End loop over generated particles
  } // End loop over simulated Photons


  if ( ! isRunCentrally_ ) {
    h_nSimPho_[0]->Fill(float(nSimPho_[0]));
    h_nSimPho_[1]->Fill(float(nSimPho_[1]));
    h_nSimConv_[0]->Fill(float(nSimConv_[0]));
    h_nSimConv_[1]->Fill(float(nSimConv_[1]));
  }

  if ( !fastSim_) {
    for( reco::PhotonCollection::const_iterator  iPho = photonCollection.begin(); iPho != photonCollection.end(); iPho++) {
      reco::Photon aPho = reco::Photon(*iPho);
      //    float et= aPho.superCluster()->energy()/cosh( aPho.superCluster()->eta()) ;
      reco::ConversionRefVector conversions = aPho.conversions();
      for (unsigned int iConv=0; iConv<conversions.size(); iConv++) {
    reco::ConversionRef aConv=conversions[iConv];
    double like = aConv->MVAout();
    if ( like < likelihoodCut_ ) continue;
    //std::vector<reco::TrackRef> tracks = aConv->tracks();
    const std::vector<edm::RefToBase<reco::Track> > tracks = aConv->tracks();
    if (tracks.size() < 2 ) continue;

    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);

    bool  phoIsInBarrel=false;
    bool  phoIsInEndcap=false;
    if ( fabs(aPho.superCluster()->position().eta())  < 1.479 ) {
      phoIsInBarrel=true;
    } else {
      phoIsInEndcap=true;
    }

    if ( dCotCutOn_ ) {
      if ( ( fabs(mcEta_) > 1.1 && fabs (mcEta_)  < 1.4  )  &&
           fabs( aConv->pairCotThetaSeparation() ) > dCotHardCutValue_ )  continue;
      if ( fabs( aConv->pairCotThetaSeparation() ) > dCotCutValue_ ) continue;
    }


    h_RecoConvTwoTracks_[0]->Fill( aPho.eta() ) ;
    h_RecoConvTwoTracks_[1]->Fill( aPho.phi() );
    if (  aConv->conversionVertex().isValid() ) h_RecoConvTwoTracks_[2]->Fill(  aConv->conversionVertex().position().perp2() );
    h_RecoConvTwoTracks_[3]->Fill( aConv->conversionVertex().position().z() );
    h_RecoConvTwoTracks_[4]->Fill( aPho.et() ) ;



    int  nAssT2=0;
    for ( std::vector<PhotonMCTruth>::const_iterator mcPho=mcPhotons.begin(); mcPho !=mcPhotons.end(); mcPho++) {
      // mcConvPt_= (*mcPho).fourMomentum().et();
      float mcPhi= (*mcPho).fourMomentum().phi();
      //simPV_Z = (*mcPho).primaryVertex().z();
      mcPhi_= phiNormalization(mcPhi);
      mcEta_= (*mcPho).fourMomentum().pseudoRapidity();
      mcEta_ = etaTransformation(mcEta_, (*mcPho).primaryVertex().z() );
      //mcConvR_= (*mcPho).vertex().perp();
      //mcConvX_= (*mcPho).vertex().x();
      //mcConvY_= (*mcPho).vertex().y();
      //mcConvZ_= (*mcPho).vertex().z();
      //mcConvEta_= (*mcPho).vertex().eta();
      //mcConvPhi_= (*mcPho).vertex().phi();
      if ( fabs(mcEta_) > END_HI ) continue;
      //        if (mcConvPt_<minPhoPtForPurity) continue;
      //if (fabs(mcEta_)>maxPhoEtaForPurity) continue;
      //if (fabs(mcConvZ_)>maxPhoZForPurity) continue;
      //if (mcConvR_>maxPhoRForEffic) continue;

      if (  (*mcPho).isAConversion() != 1 ) continue;
      if (!( ( fabs(mcEta_) <= BARL && mcConvR_ <85 )  ||
         ( fabs(mcEta_) > BARL && fabs(mcEta_) <=END_HI && fabs( (*mcPho).vertex().z() ) < 210 )  ) )
        continue;

      theConvTP_.clear();
      for(size_t i = 0; i <  trackingParticles.size(); ++i){
        TrackingParticleRef tp (ElectronTPHandle,i);
        if ( fabs( tp->vx() - (*mcPho).vertex().x() ) < 0.0001   &&
         fabs( tp->vy() - (*mcPho).vertex().y() ) < 0.0001   &&
         fabs( tp->vz() - (*mcPho).vertex().z() ) < 0.0001) {
          theConvTP_.push_back( tp );
        }
      }


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

      reco::RecoToSimCollection p1 =  trackAssociator->associateRecoToSim(tc1,theConvTP_);
      reco::RecoToSimCollection p2 =  trackAssociator->associateRecoToSim(tc2,theConvTP_);
      std::vector<std::pair<RefToBase<reco::Track>, double> > trackV1, trackV2;
          try {
            std::vector<std::pair<TrackingParticleRef, double> > tp1 = p1[tk1];
            std::vector<std::pair<TrackingParticleRef, double> > tp2 = p2[tk2];

            if (tp1.size()&&tp2.size()) {
              TrackingParticleRef tpr1 = tp1.front().first;
              TrackingParticleRef tpr2 = tp2.front().first;

              if (abs(tpr1->pdgId())==11&&abs(tpr2->pdgId())==11) {
                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)) {
                    nAssT2 = 2;
                    break;
                  }
                }
              }
            }

      } catch (Exception event) {
      }

    } // end loop over simulated photons


        if ( nAssT2 == 2) {


          h_RecoConvTwoMTracks_[0]->Fill( aPho.eta() ) ;
          h_RecoConvTwoMTracks_[1]->Fill( aPho.phi() );
          if (  aConv->conversionVertex().isValid() ) h_RecoConvTwoMTracks_[2]->Fill(  aConv->conversionVertex().position().perp2() );
          h_RecoConvTwoMTracks_[3]->Fill( aConv->conversionVertex().position().z() );
          h_RecoConvTwoMTracks_[4]->Fill( aPho.et() ) ;

        }


    if ( aConv->conversionVertex().isValid() ) {

      float chi2Prob = ChiSquaredProbability( aConv->conversionVertex().chi2(),  aConv->conversionVertex().ndof() );
      double convR= sqrt(aConv->conversionVertex().position().perp2());
      double scalar = aConv->conversionVertex().position().x()*aConv->pairMomentum().x() +
              aConv->conversionVertex().position().y()*aConv->pairMomentum().y();


      if ( scalar < 0 ) convR= -sqrt(aConv->conversionVertex().position().perp2());
      h_convVtxRvsZ_[0] ->Fill ( fabs (aConv->conversionVertex().position().z() ),  sqrt(aConv->conversionVertex().position().perp2())  ) ;

      if (aConv->caloCluster().size() !=0) {
        if ( ! isRunCentrally_ ) h2_etaVsRreco_[0]->Fill (aConv->caloCluster()[0]->eta(),sqrt(aConv->conversionVertex().position().perp2()) );
        if ( fabs(aConv->caloCluster()[0]->eta() ) <= 1.) {

          h_convVtxYvsX_ ->Fill ( aConv->conversionVertex().position().y() , aConv->conversionVertex().position().x()  ) ;
          h_convVtxRvsZ_[1] ->Fill ( fabs (aConv->conversionVertex().position().z() ),  convR  ) ;

          if ( ! isRunCentrally_ ) {
        h_convVtxYvsX_zoom_[0] ->Fill ( aConv->conversionVertex().position().y() , aConv->conversionVertex().position().x()  ) ;
        h_convVtxYvsX_zoom_[1] ->Fill ( aConv->conversionVertex().position().y() , aConv->conversionVertex().position().x()  ) ;
        h_convVtxRvsZ_zoom_[0] ->Fill ( fabs (aConv->conversionVertex().position().z() ),  convR  ) ;
        h_convVtxRvsZ_zoom_[1] ->Fill ( fabs (aConv->conversionVertex().position().z() ),  convR ) ;
          }

        }
        if ( fabs(aConv->caloCluster()[0]->eta() ) > 1.)      h_convVtxRvsZ_[2] ->Fill ( fabs (aConv->conversionVertex().position().z() ),  convR  ) ;
      }


      h_vtxChi2Prob_[0]->Fill( chi2Prob );
      h_vtxChi2_[0]->Fill(  aConv->conversionVertex().normalizedChi2() );
      if ( phoIsInBarrel ) {
        h_vtxChi2Prob_[1]->Fill( chi2Prob );
        h_vtxChi2_[1]->Fill( aConv->conversionVertex().normalizedChi2() );
      }
      if ( phoIsInEndcap ) {
        h_vtxChi2Prob_[2]->Fill(  chi2Prob );
        h_vtxChi2_[2]->Fill( aConv->conversionVertex().normalizedChi2() );
      }


    } // end conversion vertex valid
      } // end loop over reco conversions
    } // end loop on all reco photons
  } // if !fastSim



  float nPho=0;
  for (reco::GenJetCollection::const_iterator genJetIter = genJetCollection.begin();
       genJetIter != genJetCollection.end();     ++genJetIter) {

    if ( genJetIter->pt() < minPhoEtCut_ ) continue;
    if ( fabs(genJetIter->eta())  > 2.5 ) continue;

    float mcJetPhi= genJetIter->phi();
    mcJetPhi_= phiNormalization(mcJetPhi);
    mcJetEta_= genJetIter->eta();
    float mcJetPt = genJetIter->pt() ;

    h_SimJet_[0]->Fill ( mcJetEta_);
    h_SimJet_[1]->Fill ( mcJetPhi_);
    h_SimJet_[2]->Fill ( mcJetPt );

    std::vector<reco::Photon> thePhotons;
    bool matched=false;

    reco::Photon matchingPho;
    for( reco::PhotonCollection::const_iterator  iPho = photonCollection.begin(); iPho != photonCollection.end(); iPho++) {
      reco::Photon aPho = reco::Photon(*iPho);
      float phiPho=aPho.phi();
      float etaPho=aPho.eta();
      float deltaPhi = phiPho-mcJetPhi_;
      float deltaEta = etaPho-mcJetEta_;
      if ( deltaPhi > pi )  deltaPhi -= twopi;
      if ( deltaPhi < -pi) deltaPhi += twopi;
      deltaPhi=pow(deltaPhi,2);
      deltaEta=pow(deltaEta,2);
      float delta = sqrt( deltaPhi+deltaEta);
      if ( delta<0.3 ) {
        matchingPho = * iPho;
        matched = true;
      }
    }  // end loop over reco photons

    if (!  matched ) continue;
    nPho++;

    h_MatchedSimJet_[0]->Fill( mcJetEta_ ) ;
    h_MatchedSimJet_[1]->Fill( mcJetPhi_ );
    h_MatchedSimJet_[2]->Fill( mcJetPt );


    bool  phoIsInBarrel=false;
    bool  phoIsInEndcap=false;
    if ( fabs(matchingPho.superCluster()->position().eta() ) < 1.479 ) {
      phoIsInBarrel=true;
    } else {
      phoIsInEndcap=true;
    }
    edm::Handle<EcalRecHitCollection>   ecalRecHitHandle;
    if ( phoIsInBarrel ) {
      // Get handle to rec hits ecal barrel
      e.getByToken(barrelEcalHits_, ecalRecHitHandle);
      if (!ecalRecHitHandle.isValid()) {
        Labels l;
        labelsForToken(barrelEcalHits_, l);
    edm::LogError("PhotonProducer")
            << "Error! Can't get the product "
            << l.module;
    return;
      }

    } else if ( phoIsInEndcap ) {

      // Get handle to rec hits ecal encap
      e.getByToken(endcapEcalHits_, ecalRecHitHandle);
      if (!ecalRecHitHandle.isValid()) {
        Labels l;
        labelsForToken(barrelEcalHits_, l);
    edm::LogError("PhotonProducer")
            << "Error! Can't get the product "
            << l.module;
    return;
      }

    }

    const EcalRecHitCollection ecalRecHitCollection = *(ecalRecHitHandle.product());
    float photonE = matchingPho.energy();
    float photonEt= matchingPho.et();
    float r9 = matchingPho.r9();
    float r1 = matchingPho.r1x5();
    float r2 = matchingPho.r2x5();
    float sigmaIetaIeta =  matchingPho.sigmaIetaIeta();
    float hOverE = matchingPho.hadronicOverEm();
    float ecalIso = matchingPho.ecalRecHitSumEtConeDR04();
    float hcalIso = matchingPho.hcalTowerSumEtConeDR04();
    float trkIso =  matchingPho.trkSumPtSolidConeDR04();
    float nIsoTrk   =  matchingPho.nTrkSolidConeDR04();
    std::vector< std::pair<DetId, float> >::const_iterator rhIt;

    bool atLeastOneDeadChannel=false;
    for(reco::CaloCluster_iterator bcIt = matchingPho.superCluster()->clustersBegin();bcIt != matchingPho.superCluster()->clustersEnd(); ++bcIt) {
      for(rhIt = (*bcIt)->hitsAndFractions().begin();rhIt != (*bcIt)->hitsAndFractions().end(); ++rhIt) {

        for(EcalRecHitCollection::const_iterator it =  ecalRecHitCollection.begin(); it !=  ecalRecHitCollection.end(); ++it) {
          if  (rhIt->first ==  (*it).id() ) {
            if (  (*it).recoFlag() == 9 ) {
              atLeastOneDeadChannel=true;
              break;
            }
          }
        }
      }
    }

    if (   atLeastOneDeadChannel ) {
      h_MatchedSimJetBadCh_[0]->Fill( mcJetEta_ ) ;
      h_MatchedSimJetBadCh_[1]->Fill( mcJetPhi_ );
      h_MatchedSimJetBadCh_[2]->Fill( mcJetPt );

    }

    h_scBkgEta_->Fill( matchingPho.superCluster()->eta() );
    h_scBkgPhi_->Fill( matchingPho.superCluster()->phi() );
    h_scBkgE_[0]->Fill( matchingPho.superCluster()->energy() );
    h_scBkgEt_[0]->Fill( matchingPho.superCluster()->energy()/cosh( matchingPho.superCluster()->eta()) );
    //
    h_phoBkgEta_->Fill( matchingPho.eta() );
    h_phoBkgPhi_->Fill( matchingPho.phi() );
    h_phoBkgE_[0]->Fill( photonE );
    h_phoBkgEt_[0]->Fill( photonEt);
    h_phoBkgDEta_->Fill (  matchingPho.eta() - mcJetEta_ );
    h_phoBkgDPhi_->Fill (  matchingPho.phi() - mcJetPhi_ );

    h_r9Bkg_[0]->Fill( r9 );
    h_r1Bkg_[0]->Fill( r1 );
    h_r2Bkg_[0]->Fill( r2 );
    h_sigmaIetaIetaBkg_[0]->Fill( sigmaIetaIeta );
    h_hOverEBkg_[0]->Fill( hOverE );
    h_ecalRecHitSumEtConeDR04Bkg_[0]->Fill( ecalIso );
    h_hcalTowerSumEtConeDR04Bkg_[0]->Fill( hcalIso );
    h_isoTrkSolidConeDR04Bkg_[0]->Fill( trkIso );
    h_nTrkSolidConeDR04Bkg_[0]->Fill( nIsoTrk );

    if ( ! isRunCentrally_ ) {

      h2_r9VsEtaBkg_ -> Fill (mcJetEta_, r9);
      h2_r9VsEtBkg_ -> Fill (mcJetPt, r9);
      h2_r1VsEtaBkg_ -> Fill (mcJetEta_, r1);
      h2_r1VsEtBkg_ -> Fill (mcJetPt, r1);
      h2_r2VsEtaBkg_ -> Fill (mcJetEta_, r2);
      h2_r2VsEtBkg_ -> Fill (mcJetPt, r2);
      h2_sigmaIetaIetaVsEtaBkg_ -> Fill (mcJetEta_, sigmaIetaIeta );
      h2_sigmaIetaIetaVsEtBkg_[0] -> Fill (mcJetPt, sigmaIetaIeta);
      h2_hOverEVsEtaBkg_ -> Fill (mcJetEta_, hOverE );
      h2_hOverEVsEtBkg_ -> Fill (mcJetPt, hOverE);

      p_r1VsEtaBkg_ -> Fill (mcJetEta_, r1);
      p_r1VsEtBkg_ -> Fill (mcJetPt, r1);
      p_r2VsEtaBkg_ -> Fill (mcJetEta_, r2);
      p_r2VsEtBkg_ -> Fill (mcJetPt, r2);
      p_sigmaIetaIetaVsEtaBkg_ -> Fill (mcJetEta_, sigmaIetaIeta );
      p_sigmaIetaIetaVsEtBkg_[0] -> Fill (mcJetPt, sigmaIetaIeta);
      p_hOverEVsEtaBkg_ -> Fill (mcJetEta_, hOverE );
      p_hOverEVsEtBkg_ -> Fill (mcJetPt, hOverE);

    }


    if ( ! isRunCentrally_ ) {
      h2_ecalRecHitSumEtConeDR04VsEtaBkg_ -> Fill (mcJetEta_, ecalIso );
      h2_ecalRecHitSumEtConeDR04VsEtBkg_[0] -> Fill ( mcJetPt, ecalIso);
      h2_hcalTowerSumEtConeDR04VsEtaBkg_ -> Fill (mcJetEta_, hcalIso );
      h2_hcalTowerSumEtConeDR04VsEtBkg_[0] -> Fill ( mcJetPt, hcalIso);
      p_ecalRecHitSumEtConeDR04VsEtaBkg_ -> Fill (mcJetEta_, ecalIso );
      p_ecalRecHitSumEtConeDR04VsEtBkg_[0] -> Fill ( mcJetPt, ecalIso);
      p_hcalTowerSumEtConeDR04VsEtaBkg_ -> Fill (mcJetEta_, hcalIso );
      p_hcalTowerSumEtConeDR04VsEtBkg_[0] -> Fill ( mcJetPt, hcalIso);
      p_isoTrkSolidConeDR04VsEtaBkg_ -> Fill (mcJetEta_, trkIso );
      p_isoTrkSolidConeDR04VsEtBkg_[0] -> Fill (mcJetPt, trkIso);
      p_nTrkSolidConeDR04VsEtaBkg_ -> Fill (mcJetEta_, nIsoTrk );
      p_nTrkSolidConeDR04VsEtBkg_[0] -> Fill (mcJetPt, nIsoTrk);
      h2_isoTrkSolidConeDR04VsEtaBkg_ -> Fill (mcJetEta_, trkIso );
      h2_isoTrkSolidConeDR04VsEtBkg_[0] -> Fill (mcJetPt, trkIso);
      h2_nTrkSolidConeDR04VsEtaBkg_ -> Fill (mcJetEta_, nIsoTrk );
      h2_nTrkSolidConeDR04VsEtBkg_[0] -> Fill (mcJetPt, nIsoTrk);

    }


    if ( phoIsInBarrel ) {

      h_r9Bkg_[1]->Fill( r9 );
      h_r1Bkg_[1]->Fill( r1 );
      h_r2Bkg_[1]->Fill( r2 );


      h_sigmaIetaIetaBkg_[1]->Fill( sigmaIetaIeta );
      h_hOverEBkg_[1]->Fill( hOverE );
      h_ecalRecHitSumEtConeDR04Bkg_[1]->Fill( ecalIso );
      h_hcalTowerSumEtConeDR04Bkg_[1]->Fill( hcalIso );
      h_isoTrkSolidConeDR04Bkg_[1]->Fill( trkIso );
      h_nTrkSolidConeDR04Bkg_[1]->Fill( nIsoTrk );

      if ( ! isRunCentrally_ ) {
        h2_sigmaIetaIetaVsEtBkg_[1] -> Fill (mcJetPt, sigmaIetaIeta);
        h2_isoTrkSolidConeDR04VsEtBkg_[1] -> Fill (mcJetPt, trkIso);
        h2_nTrkSolidConeDR04VsEtBkg_[1] -> Fill (mcJetPt, nIsoTrk);
        h2_ecalRecHitSumEtConeDR04VsEtBkg_[1] -> Fill ( mcJetPt, ecalIso);
        h2_hcalTowerSumEtConeDR04VsEtBkg_[1] -> Fill ( mcJetPt, hcalIso);
        p_sigmaIetaIetaVsEtBkg_[1] -> Fill (mcJetPt, sigmaIetaIeta);
        p_ecalRecHitSumEtConeDR04VsEtBkg_[1] -> Fill ( mcJetPt, ecalIso);
        p_hcalTowerSumEtConeDR04VsEtBkg_[1] -> Fill ( mcJetPt, hcalIso);
        p_isoTrkSolidConeDR04VsEtBkg_[1] -> Fill (mcJetPt, trkIso);
        p_nTrkSolidConeDR04VsEtBkg_[1] -> Fill (mcJetPt, nIsoTrk);
      }
    } else if ( phoIsInEndcap )  {

      h_r9Bkg_[2]->Fill( r9 );
      h_r1Bkg_[2]->Fill( r1 );
      h_r2Bkg_[2]->Fill( r2 );

      h_sigmaIetaIetaBkg_[2]->Fill( sigmaIetaIeta );
      h_hOverEBkg_[2]->Fill( hOverE );
      h_ecalRecHitSumEtConeDR04Bkg_[2]->Fill( ecalIso );
      h_hcalTowerSumEtConeDR04Bkg_[2]->Fill( hcalIso );
      h_isoTrkSolidConeDR04Bkg_[2]->Fill( trkIso );
      h_nTrkSolidConeDR04Bkg_[2]->Fill( nIsoTrk );

      if ( ! isRunCentrally_ ) {
        h2_sigmaIetaIetaVsEtBkg_[2] -> Fill (mcJetPt, sigmaIetaIeta);
        h2_isoTrkSolidConeDR04VsEtBkg_[2] -> Fill (mcJetPt, trkIso);
        h2_nTrkSolidConeDR04VsEtBkg_[2] -> Fill (mcJetPt, nIsoTrk);
        h2_ecalRecHitSumEtConeDR04VsEtBkg_[2] -> Fill ( mcJetPt, ecalIso);
        h2_hcalTowerSumEtConeDR04VsEtBkg_[2] -> Fill ( mcJetPt, hcalIso);
        p_sigmaIetaIetaVsEtBkg_[2] -> Fill (mcJetPt, sigmaIetaIeta);
        p_ecalRecHitSumEtConeDR04VsEtBkg_[2] -> Fill ( mcJetPt, ecalIso);
        p_hcalTowerSumEtConeDR04VsEtBkg_[2] -> Fill ( mcJetPt, hcalIso);
        p_isoTrkSolidConeDR04VsEtBkg_[2] -> Fill (mcJetPt, trkIso);
        p_nTrkSolidConeDR04VsEtBkg_[2] -> Fill (mcJetPt, nIsoTrk);
      }
    }

    if ( !fastSim_) {
      reco::ConversionRefVector conversions = matchingPho.conversions();
      for (unsigned int iConv=0; iConv<conversions.size(); iConv++) {
        reco::ConversionRef aConv=conversions[iConv];
        //std::vector<reco::TrackRef> tracks = aConv->tracks();
        const std::vector<edm::RefToBase<reco::Track> > tracks = aConv->tracks();
        double like = aConv->MVAout();
        if ( like < likelihoodCut_ ) continue;
        if ( tracks.size() < 2 ) continue;
        if (aConv->caloCluster().size() !=0) {
          h_convEtaBkg_->Fill( aConv->caloCluster()[0]->eta() );
          h_convPhiBkg_->Fill( aConv->caloCluster()[0]->phi() );
        }
        h_mvaOutBkg_[0]-> Fill(like);
        float eoverp= aConv->EoverP();
        h_EoverPTracksBkg_[0] ->Fill( eoverp ) ;
        h_PoverETracksBkg_[0] ->Fill( 1./eoverp ) ;
        h_DCotTracksBkg_[0] ->Fill ( aConv->pairCotThetaSeparation() );
        float  dPhiTracksAtVtx =  aConv->dPhiTracksAtVtx();
        h_DPhiTracksAtVtxBkg_[0]->Fill( dPhiTracksAtVtx);

        if ( phoIsInBarrel ) {
          h_mvaOutBkg_[1]-> Fill(like);
          h_EoverPTracksBkg_[1] ->Fill( eoverp ) ;
          h_PoverETracksBkg_[1] ->Fill( 1./eoverp ) ;
          h_DCotTracksBkg_[1] ->Fill ( aConv->pairCotThetaSeparation() );
          h_DPhiTracksAtVtxBkg_[1]->Fill( dPhiTracksAtVtx);
        }     else if ( phoIsInEndcap )  {
          h_mvaOutBkg_[2]-> Fill(like);
          h_EoverPTracksBkg_[2] ->Fill( eoverp ) ;
          h_PoverETracksBkg_[2] ->Fill( 1./eoverp ) ;
          h_DCotTracksBkg_[2] ->Fill ( aConv->pairCotThetaSeparation() );
          h_DPhiTracksAtVtxBkg_[2]->Fill( dPhiTracksAtVtx);
        }

        if ( aConv->conversionVertex().isValid() ) {

          double convR= sqrt(aConv->conversionVertex().position().perp2());
          double scalar = aConv->conversionVertex().position().x()*aConv->pairMomentum().x() +
          aConv->conversionVertex().position().y()*aConv->pairMomentum().y();
          if ( scalar < 0 ) convR= -sqrt(aConv->conversionVertex().position().perp2());

          if ( ! isRunCentrally_ ) {
            h_convVtxRvsZBkg_[0] ->Fill ( fabs (aConv->conversionVertex().position().z() ),  sqrt(aConv->conversionVertex().position().perp2())  ) ;
            if ( aConv->caloCluster().size() !=0 && fabs(aConv->caloCluster()[0]->eta() )  <= 1. ) {
              h_convVtxYvsXBkg_ ->Fill ( aConv->conversionVertex().position().y() , aConv->conversionVertex().position().x()  ) ;
              h_convVtxRvsZBkg_[1] ->Fill ( fabs (aConv->conversionVertex().position().z() ),  convR  ) ;
            }
          }


        } // end vertex valid


      } // end loop over conversions
    } // if !fastSim
  } // end loop over sim jets

  h_nPho_->Fill(float(nPho));

}

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

overridevirtual

Histograms for efficiencies

Denominators

Numerators

zooms

test track provenance

Implements DQMEDAnalyzer.

Definition at line 175 of file PhotonValidator.cc.

References reco::TrackBase::algoSize, DQMStore::IBooker::book1D(), DQMStore::IBooker::book2D(), DQMStore::IBooker::bookProfile(), HLT_25ns14e33_v1_cff::etaMax, HLT_25ns14e33_v1_cff::etaMin, HLT_25ns14e33_v1_cff::etMin, DQMStore::IBooker::setCurrentFolder(), and AlCaHLTBitMon_QueryRunRegistry::string.

                                                                                                              {

  

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

  double eMin = parameters_.getParameter<double>("eMin");
  double eMax = parameters_.getParameter<double>("eMax");
  int eBin = parameters_.getParameter<int>("eBin");

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

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

  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 dEtaMin = parameters_.getParameter<double>("dEtaMin");
  double dEtaMax = parameters_.getParameter<double>("dEtaMax");
  int dEtaBin = parameters_.getParameter<int>("dEtaBin");

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

  double dPhiMin = parameters_.getParameter<double>("dPhiMin");
  double dPhiMax = parameters_.getParameter<double>("dPhiMax");
  int    dPhiBin = parameters_.getParameter<int>("dPhiBin");

  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 r9Min = parameters_.getParameter<double>("r9Min");
  double r9Max = parameters_.getParameter<double>("r9Max");
  int r9Bin = parameters_.getParameter<int>("r9Bin");

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

  double dEtaTracksMin = parameters_.getParameter<double>("dEtaTracksMin");
  double dEtaTracksMax = parameters_.getParameter<double>("dEtaTracksMax");
  int    dEtaTracksBin = parameters_.getParameter<int>("dEtaTracksBin");

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


  double povereMin = parameters_.getParameter<double>("povereMin");
  double povereMax = parameters_.getParameter<double>("povereMax");
  int povereBin = parameters_.getParameter<int>("povereBin");

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

  double chi2Min = parameters_.getParameter<double>("chi2Min");
  double chi2Max = parameters_.getParameter<double>("chi2Max");

  int    ggMassBin = parameters_.getParameter<int>("ggMassBin");
  double ggMassMin = parameters_.getParameter<double>("ggMassMin");
  double ggMassMax = parameters_.getParameter<double>("ggMassMax");


  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");


 
  // SC from reco photons
  
  
  iBooker.setCurrentFolder("EgammaV/"+fName_+"/SimulationInfo");

  // simulation information about all MC photons found
  std::string histname = "nOfSimPhotons";
  if ( ! isRunCentrally_ ) {
    h_nSimPho_[0] = iBooker.book1D(histname,"# of Sim photons per event ",20,-0.5,19.5);
    histname = "SimPhoMotherEt";
    h_SimPhoMotherEt_[0] = iBooker.book1D(histname,"Sim photon Mother tranverse energy spectrum",etBin,etMin,etMax);
    h_SimPhoMotherEta_[0] = iBooker.book1D("SimPhoMotherEta"," Sim Photon Mother Eta ",etaBin,etaMin, etaMax) ;
    histname = "SimPhoMotherEtMatched";
    h_SimPhoMotherEt_[1] = iBooker.book1D(histname,"Sim photon  matched by a reco Photon: Mother tranverse energy spectrum",etBin,etMin,etMax);
    h_SimPhoMotherEta_[1] = iBooker.book1D("SimPhoMotherEtaMatched"," Sim Photon matched by a reco Photon:  Mother Eta ",etaBin,etaMin, etaMax) ;
  }

  histname = "h_SimPhoEta";
  h_SimPho_[0] =  iBooker.book1D(histname," All photons simulated #eta",etaBin,etaMin, etaMax);
  histname = "h_SimPhoPhi";
  h_SimPho_[1] =  iBooker.book1D(histname," All photons simulated #phi",phiBin,phiMin, phiMax);
  histname = "h_SimPhoEt";
  h_SimPho_[2] =  iBooker.book1D(histname," All photons simulated Et",etBin,etMin, etMax);
  // Numerators
  histname = "nOfSimPhotonsMatched";
  h_nSimPho_[1] = iBooker.book1D(histname,"# of Sim photons matched by a reco Photon per event ",20,-0.5,19.5);
  histname = "h_MatchedSimPhoEta";
  h_MatchedSimPho_[0] =  iBooker.book1D(histname," Matching photons simulated #eta",etaBin,etaMin, etaMax);
  histname = "h_MatchedSimPhoPhi";
  h_MatchedSimPho_[1] =  iBooker.book1D(histname," Matching photons simulated #phi",phiBin,phiMin, phiMax);
  histname = "h_MatchedSimPhoEt";
  h_MatchedSimPho_[2] =  iBooker.book1D(histname," Matching photons simulated Et",etBin,etMin, etMax);
  //
  histname = "h_MatchedSimPhoBadChEta";
  h_MatchedSimPhoBadCh_[0] =  iBooker.book1D(histname," Matching photons simulated #eta",etaBin,etaMin, etaMax);
  histname = "h_MatchedSimPhoBadChPhi";
  h_MatchedSimPhoBadCh_[1] =  iBooker.book1D(histname," Matching photons simulated #phi",phiBin,phiMin, phiMax);
  histname = "h_MatchedSimPhoBadChEt";
  h_MatchedSimPhoBadCh_[2] =  iBooker.book1D(histname," Matching photons simulated Et",etBin,etMin, etMax);
  

  histname = "nOfSimConversions";
  if ( ! isRunCentrally_ ) {
    h_nSimConv_[0] = iBooker.book1D(histname,"# of Sim conversions per event ",20,-0.5,19.5);
    histname = "nOfVisSimConversions";
    h_nSimConv_[1] = 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 = "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_SimConvOneTracksEta";
  h_SimConvOneTracks_[0] =  iBooker.book1D(histname," All vis conversions with 1 reco  tracks: simulated #eta",etaBin2,etaMin, etaMax);
  histname = "h_SimConvOneTracksPhi";
  h_SimConvOneTracks_[1] =  iBooker.book1D(histname," All vis conversions with 1 reco  tracks: simulated #phi",phiBin,phiMin, phiMax);
  histname = "h_SimConvOneTracksR";
  h_SimConvOneTracks_[2] =  iBooker.book1D(histname," All vis conversions with 1 reco  tracks: simulated R",rBin,rMin, rMax);
  histname = "h_SimConvOneTracksZ";
  h_SimConvOneTracks_[3] =  iBooker.book1D(histname," All vis conversions with 1 reco  tracks: simulated Z",zBin,zMin, zMax);
  histname = "h_SimConvOneTracksEt";
  h_SimConvOneTracks_[4] =  iBooker.book1D(histname," All vis conversions with 1 reco  tracks: 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_SimConvOneMTracksEta";
  h_SimConvOneMTracks_[0] =  iBooker.book1D(histname," All vis conversions with 1 reco-matching tracks: simulated #eta",etaBin2,etaMin, etaMax);
  histname = "h_SimConvOneMTracksPhi";
  h_SimConvOneMTracks_[1] =  iBooker.book1D(histname," All vis conversions with 1 reco-matching tracks: simulated #phi",phiBin,phiMin, phiMax);
  histname = "h_SimConvOneMTracksR";
  h_SimConvOneMTracks_[2] =  iBooker.book1D(histname," All vis conversions with 1 reco-matching tracks: simulated R",rBin,rMin, rMax);
  histname = "h_SimConvOneMTracksZ";
  h_SimConvOneMTracks_[3] =  iBooker.book1D(histname," All vis conversions with 1 reco-matching tracks: simulated Z",zBin,zMin, zMax);
  histname = "h_SimConvOneMTracksEt";
  h_SimConvOneMTracks_[4] =  iBooker.book1D(histname," All vis conversions with 1 reco-matching 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);



  if ( ! isRunCentrally_ ) {
    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_simConvVtxYvsX_ =   iBooker.book2D("simConvVtxYvsXTrkBarrel"," Photon Sim conversion vtx position, (x,y) eta<1 ",100, -80., 80., 100, -80., 80.);
  }
  
  histname = "h_SimJetEta";
  h_SimJet_[0] =  iBooker.book1D(histname," Jet bkg simulated #eta",etaBin,etaMin, etaMax);
  histname = "h_SimJetPhi";
  h_SimJet_[1] =  iBooker.book1D(histname," Jet bkg simulated #phi",phiBin,phiMin, phiMax);
  histname = "h_SimJetEt";
  h_SimJet_[2] =  iBooker.book1D(histname," Jet bkg simulated Et",etBin,etMin, etMax);
  //
  histname = "h_MatchedSimJetEta";
  h_MatchedSimJet_[0] =  iBooker.book1D(histname," Matching jet simulated #eta",etaBin,etaMin, etaMax);
  histname = "h_MatchedSimJetPhi";
  h_MatchedSimJet_[1] =  iBooker.book1D(histname," Matching jet simulated #phi",phiBin,phiMin, phiMax);
  histname = "h_MatchedSimJetEt";
  h_MatchedSimJet_[2] =  iBooker.book1D(histname," Matching jet simulated Et",etBin,etMin, etMax);
  //
  histname = "h_MatchedSimJetBadChEta";
  h_MatchedSimJetBadCh_[0] =  iBooker.book1D(histname," Matching jet simulated #eta",etaBin,etaMin, etaMax);
  histname = "h_MatchedSimJetBadChPhi";
  h_MatchedSimJetBadCh_[1] =  iBooker.book1D(histname," Matching jet simulated #phi",phiBin,phiMin, phiMax);
  histname = "h_MatchedSimJetBadChEt";
  h_MatchedSimJetBadCh_[2] =  iBooker.book1D(histname," Matching jet simulated Et",etBin,etMin, etMax);
  
  
  iBooker.setCurrentFolder("EgammaV/"+fName_+"/Background");
  
  histname = "nOfPhotons";
  h_nPho_ = iBooker.book1D(histname,"# of Reco photons per event ",20,-0.5,19.5);
  
  h_scBkgEta_ = iBooker.book1D("scBkgEta"," SC Bkg Eta ",etaBin,etaMin, etaMax) ;
  h_scBkgPhi_ = iBooker.book1D("scBkgPhi"," SC Bkg  Phi ",phiBin,phiMin,phiMax) ;
  //
  h_phoBkgEta_ = iBooker.book1D("phoBkgEta"," Photon Bkg Eta ",etaBin,etaMin, etaMax) ;
  h_phoBkgPhi_ = iBooker.book1D("phoBkgPhi"," Photon Bkg Phi ",phiBin,phiMin,phiMax) ;
  //
  h_phoBkgDEta_ = iBooker.book1D("phoBkgDEta"," Photon Eta(rec)-Eta(true) ",dEtaBin,dEtaMin, dEtaMax) ;
  h_phoBkgDPhi_ = iBooker.book1D("phoBkgDPhi"," Photon  Phi(rec)-Phi(true) ",dPhiBin,dPhiMin,dPhiMax) ;
  //
  histname = "phoBkgE";
  h_phoBkgE_[0]=iBooker.book1D(histname+"All"," Photon Bkg Energy: All ecal ", eBin,eMin, eMax);
  h_phoBkgE_[1]=iBooker.book1D(histname+"Barrel"," Photon Bkg Energy: barrel ",eBin,eMin, eMax);
  h_phoBkgE_[2]=iBooker.book1D(histname+"Endcap"," Photon Bkg Energy: Endcap ",eBin,eMin, eMax);
  //
  histname = "phoBkgEt";
  h_phoBkgEt_[0] = iBooker.book1D(histname+"All"," Photon Bkg Transverse Energy: All ecal ", etBin,etMin, etMax);
  h_phoBkgEt_[1] = iBooker.book1D(histname+"Barrel"," Photon Bkg Transverse Energy: Barrel ",etBin,etMin, etMax);
  h_phoBkgEt_[2] = iBooker.book1D(histname+"Endcap"," Photon BkgTransverse Energy: Endcap ",etBin,etMin, etMax);
  
  //
  histname = "scBkgE";
  h_scBkgE_[0] = iBooker.book1D(histname+"All","    SC bkg Energy: All Ecal  ",eBin,eMin, eMax);
  h_scBkgE_[1] = iBooker.book1D(histname+"Barrel"," SC bkg Energy: Barrel ",eBin,eMin, eMax);
  h_scBkgE_[2] = iBooker.book1D(histname+"Endcap"," SC bkg Energy: Endcap ",eBin,eMin, eMax);
  histname = "scBkgEt";
  h_scBkgEt_[0] = iBooker.book1D(histname+"All","    SC bkg Et: All Ecal  ",eBin,eMin, eMax);
  h_scBkgEt_[1] = iBooker.book1D(histname+"Barrel"," SC bkg Et: Barrel ",eBin,eMin, eMax);
  h_scBkgEt_[2] = iBooker.book1D(histname+"Endcap"," SC bkg Et: Endcap ",eBin,eMin, eMax);
  //
  histname = "r9Bkg";
  h_r9Bkg_[0] = iBooker.book1D(histname+"All",   " r9 bkg: All Ecal",r9Bin,r9Min, r9Max) ;
  h_r9Bkg_[1] = iBooker.book1D(histname+"Barrel"," r9 bkg: Barrel ",r9Bin,r9Min, r9Max) ;
  h_r9Bkg_[2] = iBooker.book1D(histname+"Endcap"," r9 bkg: Endcap ",r9Bin,r9Min, r9Max) ;
  //
  histname="R9VsEtaBkg";
  if ( ! isRunCentrally_ ) h2_r9VsEtaBkg_ = iBooker.book2D(histname+"All"," Bkg r9 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  //
  histname="R9VsEtBkg";
  if ( ! isRunCentrally_ ) h2_r9VsEtBkg_ = iBooker.book2D(histname+"All"," Bkg photons r9 vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,1.1);
  //
  histname = "r1Bkg";
  h_r1Bkg_[0] = iBooker.book1D(histname+"All",   " Bkg photon e1x5/e5x5: All Ecal",r9Bin,r9Min, r9Max) ;
  h_r1Bkg_[1] = iBooker.book1D(histname+"Barrel"," Bkg photon e1x5/e5x5: Barrel ",r9Bin,r9Min, r9Max) ;
  h_r1Bkg_[2] = iBooker.book1D(histname+"Endcap"," Bkg photon e1x5/e5x5: Endcap ",r9Bin,r9Min, r9Max) ;
  //
  histname="R1VsEtaBkg";
  if ( ! isRunCentrally_ ) h2_r1VsEtaBkg_ = iBooker.book2D(histname+"All"," Bkg photons e1x5/e5x5 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  histname="pR1VsEtaBkg";
  if ( ! isRunCentrally_ ) p_r1VsEtaBkg_ = iBooker.bookProfile(histname+"All"," Bkg photons e1x5/e5x5 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  //
  histname="R1VsEtBkg";
  if ( ! isRunCentrally_ ) h2_r1VsEtBkg_ = iBooker.book2D(histname+"All"," Bkg photons e1x5/e5x5 vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,1.1);
  histname="pR1VsEtBkg";
  if ( ! isRunCentrally_ ) p_r1VsEtBkg_ = iBooker.bookProfile(histname+"All"," Bkg photons e2x5/e5x5 vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,1.1);
  //
  histname = "r2Bkg";
  h_r2Bkg_[0] = iBooker.book1D(histname+"All",   " Bkg photon e2x5/e5x5: All Ecal",r9Bin,r9Min, r9Max) ;
  h_r2Bkg_[1] = iBooker.book1D(histname+"Barrel"," Bkg photon e2x5/e5x5: Barrel ",r9Bin,r9Min, r9Max) ;
  h_r2Bkg_[2] = iBooker.book1D(histname+"Endcap"," Bkg photon e2x5/e5x5: Endcap ",r9Bin,r9Min, r9Max) ;
  //
  histname="R2VsEtaBkg";
  if ( ! isRunCentrally_ ) h2_r2VsEtaBkg_ = iBooker.book2D(histname+"All"," Bkg photons e2x5/e5x5 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  histname="pR2VsEtaBkg";
  if ( ! isRunCentrally_ ) p_r2VsEtaBkg_ = iBooker.bookProfile(histname+"All"," Bkg photons e2x5/e5x5 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  //
  histname="R2VsEtBkg";
  if ( ! isRunCentrally_ ) h2_r2VsEtBkg_ = iBooker.book2D(histname+"All"," Bkg photons e2x5/e5x5 vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,1.1);
  histname="pR2VsEtBkg";
  if ( ! isRunCentrally_ ) p_r2VsEtBkg_ = iBooker.bookProfile(histname+"All"," Bkg photons e2x5/e5x5 vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,1.1);
  
  
  histname = "sigmaIetaIetaBkg";
  h_sigmaIetaIetaBkg_[0] = iBooker.book1D(histname+"All",   "Bkg sigmaIetaIeta: All Ecal",100,0., 0.1) ;
  h_sigmaIetaIetaBkg_[1] = iBooker.book1D(histname+"Barrel","Bkg sigmaIetaIeta: Barrel ", 100,0., 0.05) ;
  h_sigmaIetaIetaBkg_[2] = iBooker.book1D(histname+"Endcap","Bkg sigmaIetaIeta: Endcap ", 100,0., 0.1) ;
  //
  histname="sigmaIetaIetaVsEtaBkg";
  if ( ! isRunCentrally_ ) h2_sigmaIetaIetaVsEtaBkg_ = iBooker.book2D(histname+"All"," Bkg photons sigmaIetaIeta vs #eta: all Ecal ",  etaBin2,etaMin, etaMax,100, 0.,0.1);
  histname="pSigmaIetaIetaVsEtaBkg";
  if ( ! isRunCentrally_ ) p_sigmaIetaIetaVsEtaBkg_ = iBooker.bookProfile(histname+"All"," Bkg photons sigmaIetaIeta vs #eta: all Ecal ",  etaBin2,etaMin, etaMax,100, 0.,0.1);
  //
  histname="sigmaIetaIetaVsEtBkg";
  if ( ! isRunCentrally_ ) h2_sigmaIetaIetaVsEtBkg_[0] = iBooker.book2D(histname+"All"," Bkg photons sigmaIetaIeta vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  if ( ! isRunCentrally_ ) h2_sigmaIetaIetaVsEtBkg_[1] = iBooker.book2D(histname+"Barrel"," Bkg photons sigmaIetaIeta vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  if ( ! isRunCentrally_ ) h2_sigmaIetaIetaVsEtBkg_[2] = iBooker.book2D(histname+"Endcap"," Bkg photons sigmaIetaIeta vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  //
  histname="pSigmaIetaIetaVsEtBkg";
  if ( ! isRunCentrally_ ) p_sigmaIetaIetaVsEtBkg_[0] = iBooker.bookProfile(histname+"All"," Bkg photons sigmaIetaIeta vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  if ( ! isRunCentrally_ ) p_sigmaIetaIetaVsEtBkg_[1] = iBooker.bookProfile(histname+"Barrel"," Bkg photons sigmaIetaIeta vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  if ( ! isRunCentrally_ ) p_sigmaIetaIetaVsEtBkg_[2] = iBooker.bookProfile(histname+"Endcap"," Bkg photons sigmaIetaIeta vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  //
  histname = "hOverEBkg";
  h_hOverEBkg_[0] = iBooker.book1D(histname+"All",   "H/E bkg: All Ecal",100,0., 1.) ;
  h_hOverEBkg_[1] = iBooker.book1D(histname+"Barrel","H/E bkg: Barrel ", 100,0., 1.) ;
  h_hOverEBkg_[2] = iBooker.book1D(histname+"Endcap","H/E bkg: Endcap ", 100,0., 1.) ;
  //
  histname="pHOverEVsEtaBkg";
  if ( ! isRunCentrally_ ) p_hOverEVsEtaBkg_ = iBooker.bookProfile(histname+"All"," Bkg H/E vs #eta: all Ecal ",  etaBin2,etaMin, etaMax,100, 0.,0.1);
  histname="pHOverEVsEtBkg";
  if ( ! isRunCentrally_ ) p_hOverEVsEtBkg_ = iBooker.bookProfile(histname+"All"," Bkg photons H/E vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  if ( ! isRunCentrally_ ) {
    histname="hOverEVsEtaBkg";
    h2_hOverEVsEtaBkg_ = iBooker.book2D(histname+"All"," Bkg H/E vs #eta: all Ecal ",  etaBin2,etaMin, etaMax,100, 0.,0.1);
    //
    histname="hOverEVsEtBkg";
    h2_hOverEVsEtBkg_ = iBooker.book2D(histname+"All"," Bkg photons H/E vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  }
  //
  histname = "ecalRecHitSumEtConeDR04Bkg";
  h_ecalRecHitSumEtConeDR04Bkg_[0] = iBooker.book1D(histname+"All",   "bkg ecalRecHitSumEtDR04: All Ecal",etBin,etMin,50.);
  h_ecalRecHitSumEtConeDR04Bkg_[1] = iBooker.book1D(histname+"Barrel","bkg ecalRecHitSumEtDR04: Barrel ", etBin,etMin,50.);
  h_ecalRecHitSumEtConeDR04Bkg_[2] = iBooker.book1D(histname+"Endcap","bkg ecalRecHitSumEtDR04: Endcap ", etBin,etMin,50.);
  //
  if ( ! isRunCentrally_ ) {
    histname="ecalRecHitSumEtConeDR04VsEtaBkg";
    h2_ecalRecHitSumEtConeDR04VsEtaBkg_ = iBooker.book2D(histname+"All"," bkg ecalRecHitSumEtDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*etScale);
    histname="ecalRecHitSumEtConeDR04VsEtBkg";
    h2_ecalRecHitSumEtConeDR04VsEtBkg_[0] = iBooker.book2D(histname+"All"," Bkg ecalRecHitSumEtDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*etScale);
    h2_ecalRecHitSumEtConeDR04VsEtBkg_[1] = iBooker.book2D(histname+"Barrel"," Bkg ecalRecHitSumEtDR04 vs Et: Barrel ",etBin,etMin, etMax, etBin,etMin,etMax*etScale);
    h2_ecalRecHitSumEtConeDR04VsEtBkg_[2] = iBooker.book2D(histname+"Endcap"," Bkg ecalRecHitSumEtDR04 vs Et: Endcap ",etBin,etMin, etMax, etBin,etMin,etMax*etScale);
    histname="hcalTowerSumEtConeDR04VsEtaBkg";
    h2_hcalTowerSumEtConeDR04VsEtaBkg_ = iBooker.book2D(histname+"All"," bkg hcalTowerSumEtDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*etScale);
    histname="hcalTowerSumEtConeDR04VsEtBkg";
    h2_hcalTowerSumEtConeDR04VsEtBkg_[0] = iBooker.book2D(histname+"All"," Bkg hcalTowerSumEtDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*etScale);
    h2_hcalTowerSumEtConeDR04VsEtBkg_[1] = iBooker.book2D(histname+"Barrel"," Bkg hcalTowerSumEtDR04 vs Et: Barrel ",etBin,etMin, etMax, etBin,etMin,etMax*etScale);
    h2_hcalTowerSumEtConeDR04VsEtBkg_[2] = iBooker.book2D(histname+"Endcap"," Bkg hcalTowerSumEtDR04 vs Et: Endcap ",etBin,etMin, etMax, etBin,etMin,etMax*etScale);
  }
  
  histname="pEcalRecHitSumEtConeDR04VsEtaBkg";
  if ( ! isRunCentrally_ ) p_ecalRecHitSumEtConeDR04VsEtaBkg_ = iBooker.bookProfile(histname+"All","bkg photons ecalRecHitSumEtDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*etScale, "");
  //
  histname="pEcalRecHitSumEtConeDR04VsEtBkg";
  if ( ! isRunCentrally_ ) p_ecalRecHitSumEtConeDR04VsEtBkg_[0] = iBooker.bookProfile(histname+"All","Bkg ecalRecHitSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  if ( ! isRunCentrally_ ) p_ecalRecHitSumEtConeDR04VsEtBkg_[1] = iBooker.bookProfile(histname+"Barrel","Bkg ecalRecHitSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  if ( ! isRunCentrally_ ) p_ecalRecHitSumEtConeDR04VsEtBkg_[2] = iBooker.bookProfile(histname+"Endcap","Bkg ecalRecHitSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  //
  histname = "hcalTowerSumEtConeDR04Bkg";
  h_hcalTowerSumEtConeDR04Bkg_[0] = iBooker.book1D(histname+"All",   "bkg hcalTowerSumEtDR04: All Ecal",etBin,etMin,20.);
  h_hcalTowerSumEtConeDR04Bkg_[1] = iBooker.book1D(histname+"Barrel","bkg hcalTowerSumEtDR04: Barrel ", etBin,etMin,20.);
  h_hcalTowerSumEtConeDR04Bkg_[2] = iBooker.book1D(histname+"Endcap","bkg hcalTowerSumEtDR04: Endcap ", etBin,etMin,20.);
  //
  histname="pHcalTowerSumEtConeDR04VsEtaBkg";
  if ( ! isRunCentrally_ ) p_hcalTowerSumEtConeDR04VsEtaBkg_ = iBooker.bookProfile(histname+"All","bkg photons hcalTowerSumEtDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*etScale, "");
  //
  histname="pHcalTowerSumEtConeDR04VsEtBkg";
  if ( ! isRunCentrally_ ) p_hcalTowerSumEtConeDR04VsEtBkg_[0] = iBooker.bookProfile(histname+"All","Bkg hcalTowerSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  if ( ! isRunCentrally_ ) p_hcalTowerSumEtConeDR04VsEtBkg_[1] = iBooker.bookProfile(histname+"Barrel","Bkg hcalTowerSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  if ( ! isRunCentrally_ ) p_hcalTowerSumEtConeDR04VsEtBkg_[2] = iBooker.bookProfile(histname+"Endcap","Bkg hcalTowerSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  //
  histname = "isoTrkSolidConeDR04Bkg";
  h_isoTrkSolidConeDR04Bkg_[0] = iBooker.book1D(histname+"All",   "isoTrkSolidConeDR04 Bkg: All Ecal",etBin,etMin,etMax*0.1);
  h_isoTrkSolidConeDR04Bkg_[1] = iBooker.book1D(histname+"Barrel","isoTrkSolidConeDR04 Bkg: Barrel ", etBin,etMin,etMax*0.1);
  h_isoTrkSolidConeDR04Bkg_[2] = iBooker.book1D(histname+"Endcap","isoTrkSolidConeDR04 Bkg: Endcap ", etBin,etMin,etMax*0.1);
  //
  histname="isoTrkSolidConeDR04VsEtaBkg";
  if ( ! isRunCentrally_ ) h2_isoTrkSolidConeDR04VsEtaBkg_ = iBooker.book2D(histname+"All"," Bkg photons isoTrkSolidConeDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*0.1);
  histname="pIsoTrkSolidConeDR04VsEtaBkg";
  if ( ! isRunCentrally_ ) p_isoTrkSolidConeDR04VsEtaBkg_ = iBooker.bookProfile(histname+"All"," Bkg photons isoTrkSolidConeDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*0.1);
  //
  histname="isoTrkSolidConeDR04VsEtBkg";
  if ( ! isRunCentrally_ ) h2_isoTrkSolidConeDR04VsEtBkg_[0] = iBooker.book2D(histname+"All"," Bkg photons isoTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*0.1);
  if ( ! isRunCentrally_ ) h2_isoTrkSolidConeDR04VsEtBkg_[1] = iBooker.book2D(histname+"Barrel"," Bkg photons isoTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*0.1);
  if ( ! isRunCentrally_ ) h2_isoTrkSolidConeDR04VsEtBkg_[2] = iBooker.book2D(histname+"Endcap"," Bkg photons isoTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*0.1);
  histname="pIsoTrkSolidConeDR04VsEtBkg";
  if ( ! isRunCentrally_ ) p_isoTrkSolidConeDR04VsEtBkg_[0] = iBooker.bookProfile(histname+"All"," Bkg photons isoTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*0.1);
  if ( ! isRunCentrally_ ) p_isoTrkSolidConeDR04VsEtBkg_[1] = iBooker.bookProfile(histname+"Barrel"," Bkg photons isoTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*0.1);
  if ( ! isRunCentrally_ ) p_isoTrkSolidConeDR04VsEtBkg_[2] = iBooker.bookProfile(histname+"Endcap"," Bkg photons isoTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*0.1);
  //
  histname = "nTrkSolidConeDR04Bkg";
  h_nTrkSolidConeDR04Bkg_[0] = iBooker.book1D(histname+"All",   "Bkg nTrkSolidConeDR04: All Ecal",20,0., 20) ;
  h_nTrkSolidConeDR04Bkg_[1] = iBooker.book1D(histname+"Barrel","Bkg nTrkSolidConeDR04: Barrel ", 20,0., 20) ;
  h_nTrkSolidConeDR04Bkg_[2] = iBooker.book1D(histname+"Endcap","Bkg nTrkSolidConeDR04: Endcap ", 20,0., 20) ;
  //
  histname="nTrkSolidConeDR04VsEtaBkg";
  if ( ! isRunCentrally_ ) h2_nTrkSolidConeDR04VsEtaBkg_ = iBooker.book2D(histname+"All"," Bkg photons nTrkSolidConeDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, 20,0., 20) ;
  histname="p_nTrkSolidConeDR04VsEtaBkg";
  if ( ! isRunCentrally_ ) p_nTrkSolidConeDR04VsEtaBkg_ = iBooker.bookProfile(histname+"All"," Bkg photons nTrkSolidConeDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, 20,0., 20) ;
  //
  histname="nTrkSolidConeDR04VsEtBkg";
  if ( ! isRunCentrally_ ) h2_nTrkSolidConeDR04VsEtBkg_[0] = iBooker.book2D(histname+"All","Bkg photons nTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, 20,0., 20) ;
  if ( ! isRunCentrally_ ) h2_nTrkSolidConeDR04VsEtBkg_[1] = iBooker.book2D(histname+"Barrel","Bkg photons nTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, 20,0., 20) ;
  if ( ! isRunCentrally_ ) h2_nTrkSolidConeDR04VsEtBkg_[2] = iBooker.book2D(histname+"Endcap","Bkg photons nTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, 20,0., 20) ;
  //
  histname="pnTrkSolidConeDR04VsEtBkg";
  if ( ! isRunCentrally_ ) p_nTrkSolidConeDR04VsEtBkg_[0] = iBooker.bookProfile(histname+"All","Bkg photons nTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, 20,0., 20) ;
  if ( ! isRunCentrally_ ) p_nTrkSolidConeDR04VsEtBkg_[1] = iBooker.bookProfile(histname+"Barrel","Bkg photons nTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, 20,0., 20) ;
  if ( ! isRunCentrally_ ) p_nTrkSolidConeDR04VsEtBkg_[2] = iBooker.bookProfile(histname+"Endcap","Bkg photons nTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, 20,0., 20) ;
  //
  h_convEtaBkg_ = iBooker.book1D("convEtaBkg"," converted Photon Bkg Eta 2 tracks",etaBin,etaMin, etaMax) ;
  h_convPhiBkg_ = iBooker.book1D("convPhiBkg"," converted Photon Bkg Phi ",phiBin,phiMin,phiMax) ;
  //
  histname="mvaOutBkg";
  h_mvaOutBkg_[0] = iBooker.book1D(histname+"All"," mvaOut  conversions bkg : All Ecal",100, 0., 1.);
  h_mvaOutBkg_[1] = iBooker.book1D(histname+"Barrel"," mvaOut conversions bkg: Barrel Ecal",100, 0., 1.);
  h_mvaOutBkg_[2] = iBooker.book1D(histname+"Endcap"," mvaOut  conversions bkg: Endcap Ecal",100, 0., 1.);
  
  histname="PoverEtracksBkg";
  h_PoverETracksBkg_[0] = iBooker.book1D(histname+"All"," bkg photons conversion p/E: all Ecal ",povereBin, povereMin, povereMax);
  h_PoverETracksBkg_[1] = iBooker.book1D(histname+"Barrel","bkg photons conversion p/E: Barrel Ecal",povereBin, povereMin, povereMax);
  h_PoverETracksBkg_[2] = iBooker.book1D(histname+"Endcap"," bkg photons conversion p/E: Endcap Ecal ",povereBin, povereMin, povereMax);
  
  histname="EoverPtracksBkg";
  h_EoverPTracksBkg_[0] = iBooker.book1D(histname+"All"," bkg photons conversion E/p: all Ecal ",eoverpBin, eoverpMin, eoverpMax);
  h_EoverPTracksBkg_[1] = iBooker.book1D(histname+"Barrel","bkg photons conversion E/p: Barrel Ecal",eoverpBin, eoverpMin, eoverpMax);
  h_EoverPTracksBkg_[2] = iBooker.book1D(histname+"Endcap"," bkg photons conversion E/p: Endcap Ecal ",eoverpBin, eoverpMin, eoverpMax);
  
  histname="hDCotTracksBkg";
  h_DCotTracksBkg_[0]= iBooker.book1D(histname+"All"," bkg Photons:Tracks from conversions #delta cotg(#Theta) Tracks: all Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);
  h_DCotTracksBkg_[1]= iBooker.book1D(histname+"Barrel"," bkg Photons:Tracks from conversions #delta cotg(#Theta) Tracks: Barrel Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);
  h_DCotTracksBkg_[2]= iBooker.book1D(histname+"Endcap"," bkg Photons:Tracks from conversions #delta cotg(#Theta) Tracks: Endcap Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);
  
  histname="hDPhiTracksAtVtxBkg";
  h_DPhiTracksAtVtxBkg_[0] =iBooker.book1D(histname+"All", " Bkg Photons:Tracks from conversions: #delta#phi Tracks at vertex: all Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);
  h_DPhiTracksAtVtxBkg_[1] =iBooker.book1D(histname+"Barrel", " Bkg Photons:Tracks from conversions: #delta#phi Tracks at vertex: Barrel Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);
  h_DPhiTracksAtVtxBkg_[2] =iBooker.book1D(histname+"Endcap", " Bkg Photons:Tracks from conversions: #delta#phi Tracks at vertex: Endcap Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);
  
  if ( ! isRunCentrally_ ) {
    h_convVtxRvsZBkg_[0] =   iBooker.book2D("convVtxRvsZAllBkg"," Bkg Photon Reco conversion vtx position",zBinForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);
    h_convVtxRvsZBkg_[1] =   iBooker.book2D("convVtxRvsZBarrelBkg"," Bkg Photon Reco conversion vtx position",zBinForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);
    h_convVtxYvsXBkg_ =   iBooker.book2D("convVtxYvsXTrkBarrelBkg"," Bkg Photon Reco conversion vtx position, (x,y) eta<1 ",100, -80., 80., 100, -80., 80.);
  }

  //
  iBooker.setCurrentFolder("EgammaV/"+fName_+"/Photons");
  
  histname="nOfflineVtx";
  h_nRecoVtx_ = iBooker.book1D(histname,"# of Offline Vertices",80, -0.5, 79.5);
  
  h_phoEta_[0] = iBooker.book1D("phoEta"," Photon Eta ",etaBin,etaMin, etaMax) ;
  h_phoPhi_[0] = iBooker.book1D("phoPhi"," Photon  Phi ",phiBin,phiMin,phiMax) ;
  
  h_phoDEta_[0] = iBooker.book1D("phoDEta"," Photon Eta(rec)-Eta(true) ",dEtaBin,dEtaMin, dEtaMax) ;
  h_phoDPhi_[0] = iBooker.book1D("phoDPhi"," Photon  Phi(rec)-Phi(true) ",dPhiBin,dPhiMin,dPhiMax) ;
  
  h_scEta_[0] =   iBooker.book1D("scEta"," SC Eta ",etaBin,etaMin, etaMax);
  h_scPhi_[0] =   iBooker.book1D("scPhi"," SC Phi ",phiBin,phiMin,phiMax);
  
  if ( ! isRunCentrally_ ) {
    h_scEtaWidth_[0] =   iBooker.book1D("scEtaWidth"," SC Eta Width ",100,0., 0.1);
    h_scPhiWidth_[0] =   iBooker.book1D("scPhiWidth"," SC Phi Width ",100,0., 1.);
  }
  
  histname = "scE";
  h_scE_[0][0] = iBooker.book1D(histname+"All"," SC Energy: All Ecal  ",eBin,eMin, eMax);
  h_scE_[0][1] = iBooker.book1D(histname+"Barrel"," SC Energy: Barrel ",eBin,eMin, eMax);
  h_scE_[0][2] = iBooker.book1D(histname+"Endcap"," SC Energy: Endcap ",eBin,eMin, eMax);
  
  histname = "psE";
  h_psE_ = iBooker.book1D(histname+"Endcap"," ES Energy  ",eBin,eMin, 50.);
  
  
  histname = "scEt";
  h_scEt_[0][0] = iBooker.book1D(histname+"All"," SC Et: All Ecal ",etBin,etMin, etMax) ;
  h_scEt_[0][1] = iBooker.book1D(histname+"Barrel"," SC Et: Barrel",etBin,etMin, etMax) ;
  h_scEt_[0][2] = iBooker.book1D(histname+"Endcap"," SC Et: Endcap",etBin,etMin, etMax) ;
  
  histname = "r9";
  h_r9_[0][0] = iBooker.book1D(histname+"All",   " r9: All Ecal",r9Bin,r9Min, r9Max) ;
  h_r9_[0][1] = iBooker.book1D(histname+"Barrel"," r9: Barrel ",r9Bin,r9Min, r9Max) ;
  h_r9_[0][2] = iBooker.book1D(histname+"Endcap"," r9: Endcap ",r9Bin,r9Min, r9Max) ;
  //
  
  if ( ! isRunCentrally_ ) {
    histname = "r9ConvFromMC";
    h_r9_[1][0] = iBooker.book1D(histname+"All",   " r9: All Ecal",r9Bin,r9Min, r9Max) ;
    h_r9_[1][1] = iBooker.book1D(histname+"Barrel"," r9: Barrel ",r9Bin,r9Min, r9Max) ;
    h_r9_[1][2] = iBooker.book1D(histname+"Endcap"," r9: Endcap ",r9Bin,r9Min, r9Max) ;
    //
    histname = "r9ConvFromReco";
    h_r9_[2][0] = iBooker.book1D(histname+"All",   " r9: All Ecal",r9Bin,r9Min, r9Max) ;
    h_r9_[2][1] = iBooker.book1D(histname+"Barrel"," r9: Barrel ",r9Bin,r9Min, r9Max) ;
    h_r9_[2][2] = iBooker.book1D(histname+"Endcap"," r9: Endcap ",r9Bin,r9Min, r9Max) ;
    histname = "EtR9Less093";
    h_EtR9Less093_[0][0] = iBooker.book1D(histname+"All",   " r9 < 0.94 or 0.95 : All Ecal",etBin,etMin, etMax);
    h_EtR9Less093_[0][1] = iBooker.book1D(histname+"Barrel"," r9 < 0.94 : Barrel ",etBin,etMin, etMax);
    h_EtR9Less093_[0][2] = iBooker.book1D(histname+"Endcap"," r9 < 0.95 : Endcap ",etBin,etMin, etMax);
    histname = "EtR9Less093Conv";
    h_EtR9Less093_[1][0] = iBooker.book1D(histname+"All",   " r9 < 0.94, 0.95 and good conv : All Ecal",etBin,etMin, etMax);
    h_EtR9Less093_[1][1] = iBooker.book1D(histname+"Barrel"," r9 < 0.94 and good conv : Barrel ",etBin,etMin, etMax);
    h_EtR9Less093_[1][2] = iBooker.book1D(histname+"Endcap"," r9 < 0.95 and good conv : Endcap ",etBin,etMin, etMax);
  }
  
  histname="pR9VsEta";
  p_r9VsEta_[0] = iBooker.bookProfile(histname+"All"," All photons r9 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  p_r9VsEta_[1] = iBooker.bookProfile(histname+"Unconv"," Unconv photons r9 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  p_r9VsEta_[2] = iBooker.bookProfile(histname+"Conv"," Conv photons r9 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  //
  histname="R9VsEt";
  if ( ! isRunCentrally_ ) h2_r9VsEt_[0] = iBooker.book2D(histname+"All"," All photons r9 vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,1.1);
  if ( ! isRunCentrally_ ) h2_r9VsEt_[1] = iBooker.book2D(histname+"Unconv"," All photons r9 vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,1.1);
  //
  histname = "r1";
  h_r1_[0][0] = iBooker.book1D(histname+"All",   " e1x5/e5x5: All Ecal",r9Bin,r9Min, r9Max) ;
  h_r1_[0][1] = iBooker.book1D(histname+"Barrel"," e1x5/e5x5: Barrel ",r9Bin,r9Min, r9Max) ;
  h_r1_[0][2] = iBooker.book1D(histname+"Endcap"," e1x5/e5x5: Endcap ",r9Bin,r9Min, r9Max) ;
  //
  histname="R1VsEta";
  if ( ! isRunCentrally_ ) h2_r1VsEta_[0] = iBooker.book2D(histname+"All"," All photons e1x5/e5x5 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  if ( ! isRunCentrally_ ) h2_r1VsEta_[1] = iBooker.book2D(histname+"Unconv"," All photons e1x5/e5x5 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  //
  histname="R1VsEt";
  if ( ! isRunCentrally_ ) h2_r1VsEt_[0] = iBooker.book2D(histname+"All"," All photons e1x5/e5x5 vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,1.1);
  if ( ! isRunCentrally_ ) h2_r1VsEt_[1] = iBooker.book2D(histname+"Unconv"," All photons e1x5/e5x5 vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,1.1);
  //
  histname = "r2";
  h_r2_[0][0] = iBooker.book1D(histname+"All",   " e2x5/e5x5: All Ecal",r9Bin,r9Min, r9Max) ;
  h_r2_[0][1] = iBooker.book1D(histname+"Barrel"," e2x5/e5x5: Barrel ",r9Bin,r9Min, r9Max) ;
  h_r2_[0][2] = iBooker.book1D(histname+"Endcap"," e2x5/e5x5: Endcap ",r9Bin,r9Min, r9Max) ;
  //
  histname="R2VsEta";
  if ( ! isRunCentrally_ ) h2_r2VsEta_[0] = iBooker.book2D(histname+"All"," All photons e2x5/e5x5 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  if ( ! isRunCentrally_ ) h2_r2VsEta_[1] = iBooker.book2D(histname+"Unconv"," All photons e2x5/e5x5 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,1.1);
  //
  histname="R2VsEt";
  if ( ! isRunCentrally_ ) h2_r2VsEt_[0] = iBooker.book2D(histname+"All"," All photons e2x5/e5x5 vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,1.1);
  if ( ! isRunCentrally_ ) h2_r2VsEt_[1] = iBooker.book2D(histname+"Unconv"," All photons e2x5/e5x5 vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,1.1);
  //
  histname = "sigmaIetaIeta";
  h_sigmaIetaIeta_[0][0] = iBooker.book1D(histname+"All",   "sigmaIetaIeta: All Ecal",100,0., 0.1) ;
  h_sigmaIetaIeta_[0][1] = iBooker.book1D(histname+"Barrel","sigmaIetaIeta: Barrel ", 100,0., 0.05) ;
  h_sigmaIetaIeta_[0][2] = iBooker.book1D(histname+"Endcap","sigmaIetaIeta: Endcap ", 100,0., 0.1) ;
  //
  histname="sigmaIetaIetaVsEta";
  if ( ! isRunCentrally_ ) h2_sigmaIetaIetaVsEta_[0] = iBooker.book2D(histname+"All"," All photons sigmaIetaIeta vs #eta: all Ecal ",  etaBin2,etaMin, etaMax,100, 0.,0.1);
  if ( ! isRunCentrally_ ) h2_sigmaIetaIetaVsEta_[1] = iBooker.book2D(histname+"Unconv"," All photons sigmaIetaIeta vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,0.1);
  //
  histname="sigmaIetaIetaVsEt";
  if ( ! isRunCentrally_ ) h2_sigmaIetaIetaVsEt_[0] = iBooker.book2D(histname+"All"," All photons sigmaIetaIeta vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  if ( ! isRunCentrally_ ) h2_sigmaIetaIetaVsEt_[1] = iBooker.book2D(histname+"Unconv"," All photons sigmaIetaIeta vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  //
  histname = "hOverE";
  h_hOverE_[0][0] = iBooker.book1D(histname+"All",   "H/E: All Ecal",100,0., 0.1) ;
  h_hOverE_[0][1] = iBooker.book1D(histname+"Barrel","H/E: Barrel ", 100,0., 0.1) ;
  h_hOverE_[0][2] = iBooker.book1D(histname+"Endcap","H/E: Endcap ", 100,0., 0.1) ;
  //
  histname = "newhOverE";
  h_newhOverE_[0][0] = iBooker.book1D(histname+"All",   "new H/E: All Ecal",100,0., 0.1) ;
  h_newhOverE_[0][1] = iBooker.book1D(histname+"Barrel","new H/E: Barrel ", 100,0., 0.1) ;
  h_newhOverE_[0][2] = iBooker.book1D(histname+"Endcap","new H/E: Endcap ", 100,0., 0.1) ;
  
  //
  if ( ! isRunCentrally_ ) {
    histname="hOverEVsEta";
    h2_hOverEVsEta_[0] = iBooker.book2D(histname+"All"," All photons H/E vs #eta: all Ecal ",  etaBin2,etaMin, etaMax,100, 0.,0.1);
    h2_hOverEVsEta_[1] = iBooker.book2D(histname+"Unconv"," All photons H/E vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,0.1);
    //
    histname="hOverEVsEt";
    h2_hOverEVsEt_[0] = iBooker.book2D(histname+"All"," All photons H/E vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
    h2_hOverEVsEt_[1] = iBooker.book2D(histname+"Unconv"," All photons H/E vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
    //
  }
  histname="pHoverEVsEta";
  p_hOverEVsEta_[0] = iBooker.bookProfile(histname+"All"," All photons H/E vs #eta: all Ecal ",  etaBin2,etaMin, etaMax,100, 0.,0.1);
  p_hOverEVsEta_[1] = iBooker.bookProfile(histname+"Unconv"," All photons H/E vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,0.1);
  //
  histname="pHoverEVsEt";
  p_hOverEVsEt_[0] = iBooker.bookProfile(histname+"All"," All photons H/E vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  p_hOverEVsEt_[1] = iBooker.bookProfile(histname+"Unconv"," All photons H/E vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  //
  histname="pnewHoverEVsEta";
  p_newhOverEVsEta_[0] = iBooker.bookProfile(histname+"All"," All photons new H/E vs #eta: all Ecal ",  etaBin2,etaMin, etaMax,100, 0.,0.1);
  p_newhOverEVsEta_[1] = iBooker.bookProfile(histname+"Unconv"," All photons new H/E vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0.,0.1);
  //
  histname="pnewHoverEVsEt";
  p_newhOverEVsEt_[0] = iBooker.bookProfile(histname+"All"," All photons new H/E vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  p_newhOverEVsEt_[1] = iBooker.bookProfile(histname+"Unconv"," All photons new H/E vs Et: all Ecal ",etBin,etMin, etMax,100, 0.,0.1);
  //
  histname = "ecalRecHitSumEtConeDR04";
  h_ecalRecHitSumEtConeDR04_[0][0] = iBooker.book1D(histname+"All",   "ecalRecHitSumEtDR04: All Ecal",etBin,etMin,20.);
  h_ecalRecHitSumEtConeDR04_[0][1] = iBooker.book1D(histname+"Barrel","ecalRecHitSumEtDR04: Barrel ", etBin,etMin,20.);
  h_ecalRecHitSumEtConeDR04_[0][2] = iBooker.book1D(histname+"Endcap","ecalRecHitSumEtDR04: Endcap ", etBin,etMin,20.);
  //
  
  if ( ! isRunCentrally_ ) {
    histname="ecalRecHitSumEtConeDR04VsEta";
    h2_ecalRecHitSumEtConeDR04VsEta_[0] = iBooker.book2D(histname+"All"," All photons ecalRecHitSumEtDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*etScale);
    h2_ecalRecHitSumEtConeDR04VsEta_[1] = iBooker.book2D(histname+"Unconv"," All photons ecalRecHitSumEtDR04 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,etBin,etMin,etMax*etScale);
  }
  histname="pEcalRecHitSumEtConeDR04VsEta";
  p_ecalRecHitSumEtConeDR04VsEta_[0] = iBooker.bookProfile(histname+"All","All photons ecalRecHitSumEtDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*etScale, "");
  p_ecalRecHitSumEtConeDR04VsEta_[1] = iBooker.bookProfile(histname+"Unconv","All photons ecalRecHitSumEtDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*etScale, "");
  //
  if ( ! isRunCentrally_ ) {
    histname="ecalRecHitSumEtConeDR04VsEt";
    h2_ecalRecHitSumEtConeDR04VsEt_[0] = iBooker.book2D(histname+"All"," All photons ecalRecHitSumEtDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*etScale);
    h2_ecalRecHitSumEtConeDR04VsEt_[1] = iBooker.book2D(histname+"Barrel"," All photons ecalRecHitSumEtDR04 vs Et: Barrel ",etBin,etMin, etMax, etBin,etMin,etMax*etScale);
    h2_ecalRecHitSumEtConeDR04VsEt_[2] = iBooker.book2D(histname+"Endcap"," All photons ecalRecHitSumEtDR04 vs Et: Endcap ",etBin,etMin, etMax, etBin,etMin,etMax*etScale);
  }
  histname="pEcalRecHitSumEtConeDR04VsEt";
  if ( ! isRunCentrally_ ) p_ecalRecHitSumEtConeDR04VsEt_[0] = iBooker.bookProfile(histname+"All","All photons ecalRecHitSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  p_ecalRecHitSumEtConeDR04VsEt_[1] = iBooker.bookProfile(histname+"Barrel","All photons ecalRecHitSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  p_ecalRecHitSumEtConeDR04VsEt_[2] = iBooker.bookProfile(histname+"Endcap","All photons ecalRecHitSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  //
  histname = "hcalTowerSumEtConeDR04";
  h_hcalTowerSumEtConeDR04_[0][0] = iBooker.book1D(histname+"All",   "hcalTowerSumEtConeDR04: All Ecal",etBin,etMin,20.);
  h_hcalTowerSumEtConeDR04_[0][1] = iBooker.book1D(histname+"Barrel","hcalTowerSumEtConeDR04: Barrel ", etBin,etMin,20.);
  h_hcalTowerSumEtConeDR04_[0][2] = iBooker.book1D(histname+"Endcap","hcalTowerSumEtConeDR04: Endcap ", etBin,etMin,20.);
  //
  histname = "hcalTowerBcSumEtConeDR04";
  if ( ! isRunCentrally_ ) h_hcalTowerBcSumEtConeDR04_[0][0] = iBooker.book1D(histname+"All",   "hcalTowerBcSumEtConeDR04: All Ecal",etBin,etMin,20.);
  h_hcalTowerBcSumEtConeDR04_[0][1] = iBooker.book1D(histname+"Barrel","hcalTowerBcSumEtConeDR04: Barrel ", etBin,etMin,20.);
  h_hcalTowerBcSumEtConeDR04_[0][2] = iBooker.book1D(histname+"Endcap","hcalTowerBcSumEtConeDR04: Endcap ", etBin,etMin,20.);
  
  //
  if ( ! isRunCentrally_ ) {
    histname="hcalTowerSumEtConeDR04VsEta";
    h2_hcalTowerSumEtConeDR04VsEta_[0] = iBooker.book2D(histname+"All"," All photons hcalTowerSumEtConeDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*0.1);
    h2_hcalTowerSumEtConeDR04VsEta_[1] = iBooker.book2D(histname+"Unconv"," All photons hcalTowerSumEtConeDR04 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,etBin,etMin,etMax*0.1);
  }
  histname="pHcalTowerSumEtConeDR04VsEta";
  p_hcalTowerSumEtConeDR04VsEta_[0] = iBooker.bookProfile(histname+"All","All photons hcalTowerSumEtDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*0.1, "");
  p_hcalTowerSumEtConeDR04VsEta_[1] = iBooker.bookProfile(histname+"Unconv","All photons hcalTowerSumEtDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*0.1, "");
  histname="pHcalTowerBcSumEtConeDR04VsEta";
  p_hcalTowerBcSumEtConeDR04VsEta_[0] = iBooker.bookProfile(histname+"All","All photons hcalTowerBcSumEtDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*0.1, "");
  p_hcalTowerBcSumEtConeDR04VsEta_[1] = iBooker.bookProfile(histname+"Unconv","All photons hcalTowerBcSumEtDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*0.1, "");
  //
  if ( ! isRunCentrally_ ) {
    histname="hcalTowerSumEtConeDR04VsEt";
    h2_hcalTowerSumEtConeDR04VsEt_[0] = iBooker.book2D(histname+"All"," All photons hcalTowerSumEtConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*0.1);
    h2_hcalTowerSumEtConeDR04VsEt_[1] = iBooker.book2D(histname+"Barrel"," All photons hcalTowerSumEtConeDR04 vs Et: Barrel ",etBin,etMin, etMax,etBin,etMin,etMax*0.1);
    h2_hcalTowerSumEtConeDR04VsEt_[2] = iBooker.book2D(histname+"Endcap"," All photons hcalTowerSumEtConeDR04 vs Et: Endcap ",etBin,etMin, etMax,etBin,etMin,etMax*0.1);
  }
  histname="pHcalTowerSumEtConeDR04VsEt";
  if ( ! isRunCentrally_ ) p_hcalTowerSumEtConeDR04VsEt_[0] = iBooker.bookProfile(histname+"All","All photons hcalTowerSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  p_hcalTowerSumEtConeDR04VsEt_[1] = iBooker.bookProfile(histname+"Barrel","All photons hcalTowerSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  p_hcalTowerSumEtConeDR04VsEt_[2] = iBooker.bookProfile(histname+"Endcap","All photons hcalTowerSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  //
  histname="pHcalTowerBcSumEtConeDR04VsEt";
  if ( ! isRunCentrally_ ) p_hcalTowerBcSumEtConeDR04VsEt_[0] = iBooker.bookProfile(histname+"All","All photons hcalTowerBcSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  p_hcalTowerBcSumEtConeDR04VsEt_[1] = iBooker.bookProfile(histname+"Barrel","All photons hcalTowerBcSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  p_hcalTowerBcSumEtConeDR04VsEt_[2] = iBooker.bookProfile(histname+"Endcap","All photons hcalTowerBcSumEtDR04 vs Et: all Ecal ",  etBin,etMin, etMax, etBin,etMin,etMax*etScale, "");
  
  //
  histname = "isoTrkSolidConeDR04";
  h_isoTrkSolidConeDR04_[0][0] = iBooker.book1D(histname+"All",   "isoTrkSolidConeDR04: All Ecal",etBin,etMin,etMax*0.1);
  h_isoTrkSolidConeDR04_[0][1] = iBooker.book1D(histname+"Barrel","isoTrkSolidConeDR04: Barrel ", etBin,etMin,etMax*0.1);
  h_isoTrkSolidConeDR04_[0][2] = iBooker.book1D(histname+"Endcap","isoTrkSolidConeDR04: Endcap ", etBin,etMin,etMax*0.1);
  //
  
  histname="isoTrkSolidConeDR04VsEta";
  if ( ! isRunCentrally_ ) h2_isoTrkSolidConeDR04VsEta_[0] = iBooker.book2D(histname+"All"," All photons isoTrkSolidConeDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, etBin,etMin,etMax*0.1);
  if ( ! isRunCentrally_ ) h2_isoTrkSolidConeDR04VsEta_[1] = iBooker.book2D(histname+"Unconv"," All photons isoTrkSolidConeDR04 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,etBin,etMin,etMax*0.1);
  
  //
  histname="isoTrkSolidConeDR04VsEt";
  if ( ! isRunCentrally_ ) h2_isoTrkSolidConeDR04VsEt_[0] = iBooker.book2D(histname+"All"," All photons isoTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*0.1);
  if ( ! isRunCentrally_ ) h2_isoTrkSolidConeDR04VsEt_[1] = iBooker.book2D(histname+"Unconv"," All photons isoTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, etBin,etMin,etMax*0.1);
  //
  histname = "nTrkSolidConeDR04";
  h_nTrkSolidConeDR04_[0][0] = iBooker.book1D(histname+"All",   "nTrkSolidConeDR04: All Ecal",20,0., 20) ;
  h_nTrkSolidConeDR04_[0][1] = iBooker.book1D(histname+"Barrel","nTrkSolidConeDR04: Barrel ", 20,0., 20) ;
  h_nTrkSolidConeDR04_[0][2] = iBooker.book1D(histname+"Endcap","nTrkSolidConeDR04: Endcap ", 20,0., 20) ;
  //
  histname="nTrkSolidConeDR04VsEta";
  if ( ! isRunCentrally_ ) h2_nTrkSolidConeDR04VsEta_[0] = iBooker.book2D(histname+"All"," All photons nTrkSolidConeDR04 vs #eta: all Ecal ",  etaBin2,etaMin, etaMax, 20,0., 20) ;
  if ( ! isRunCentrally_ ) h2_nTrkSolidConeDR04VsEta_[1] = iBooker.book2D(histname+"Unconv"," All photons nTrkSolidConeDR04 vs #eta: all Ecal ",etaBin2,etaMin, etaMax,20,0., 20) ;
  //
  histname="nTrkSolidConeDR04VsEt";
  if ( ! isRunCentrally_ ) h2_nTrkSolidConeDR04VsEt_[0] = iBooker.book2D(histname+"All"," All photons nTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax, 20,0., 20) ;
  if ( ! isRunCentrally_ ) h2_nTrkSolidConeDR04VsEt_[1] = iBooker.book2D(histname+"Unconv"," All photons nTrkSolidConeDR04 vs Et: all Ecal ",etBin,etMin, etMax,20,0., 20) ;
  //
  histname = "phoE";
  h_phoE_[0][0]=iBooker.book1D(histname+"All"," Photon Energy: All ecal ", eBin,eMin, eMax);
  h_phoE_[0][1]=iBooker.book1D(histname+"Barrel"," Photon Energy: barrel ",eBin,eMin, eMax);
  h_phoE_[0][2]=iBooker.book1D(histname+"Endcap"," Photon Energy: Endcap ",eBin,eMin, eMax);
  
  histname = "phoEt";
  h_phoEt_[0][0] = iBooker.book1D(histname+"All"," Photon Transverse Energy: All ecal ", etBin,etMin, etMax);
  h_phoEt_[0][1] = iBooker.book1D(histname+"Barrel"," Photon Transverse Energy: Barrel ",etBin,etMin, etMax);
  h_phoEt_[0][2] = iBooker.book1D(histname+"Endcap"," Photon Transverse Energy: Endcap ",etBin,etMin, etMax);
  
  
  histname = "eRes";
  h_phoERes_[0][0] = iBooker.book1D(histname+"All"," Photon E/E_{true}: All ecal;  E/E_{true} (GeV)", resBin,resMin, resMax);
  h_phoERes_[0][1] = iBooker.book1D(histname+"Barrel","Photon E/E_{true}: Barrel; E/E_{true} (GeV)",resBin,resMin, resMax);
  h_phoERes_[0][2] = iBooker.book1D(histname+"Endcap"," Photon E/E_{true}: Endcap; E/E_{true} (GeV)",resBin,resMin, resMax);
  
  h_phoERes_[1][0] = iBooker.book1D(histname+"unconvAll"," Photon E/E_{true} if r9>0.94, 0.95: All ecal; E/E_{true} (GeV)", resBin,resMin, resMax);
  h_phoERes_[1][1] = iBooker.book1D(histname+"unconvBarrel"," Photon E/E_{true} if r9>0.94: Barrel; E/E_{true} (GeV)",resBin,resMin, resMax);
  h_phoERes_[1][2] = iBooker.book1D(histname+"unconvEndcap"," Photon E/E_{true} if r9>0.95: Endcap; E/E_{true} (GeV)",resBin,resMin, resMax);
  
  h_phoERes_[2][0] = iBooker.book1D(histname+"convAll"," Photon E/E_{true} if r9<0.0.94, 0.95: All ecal; E/E_{true} (GeV)", resBin,resMin, resMax);
  h_phoERes_[2][1] = iBooker.book1D(histname+"convBarrel"," Photon E/E_{true} if r9<0.94: Barrel; E/E_{true} (GeV)",resBin,resMin, resMax);
  h_phoERes_[2][2] = iBooker.book1D(histname+"convEndcap"," Photon E/E_{true} if r9<0.95: Endcap; E/E_{true} (GeV)",resBin,resMin, resMax);
  
  
  histname = "sigmaEoE";
  h_phoSigmaEoE_[0][0] = iBooker.book1D(histname+"All","#sigma_{E}/E: All ecal; #sigma_{E}/E", 100,0., 0.08);
  h_phoSigmaEoE_[0][1] = iBooker.book1D(histname+"Barrel","#sigma_{E}/E: Barrel; #sigma_{E}/E",100,0., 0.08);
  h_phoSigmaEoE_[0][2] = iBooker.book1D(histname+"Endcap","#sigma_{E}/E: Endcap, #sigma_{E}/E",100,0., 0.08);
  
  h_phoSigmaEoE_[1][0] = iBooker.book1D(histname+"unconvAll","#sigma_{E}/E if r9>0.94, 0.95: All ecal; #sigma_{E}/E", 100,0., 0.08);
  h_phoSigmaEoE_[1][1] = iBooker.book1D(histname+"unconvBarrel","#sigma_{E}/E if r9>0.94: Barrel; #sigma_{E}/E",100,0., 0.08);
  h_phoSigmaEoE_[1][2] = iBooker.book1D(histname+"unconvEndcap","#sigma_{E}/E r9>0.95: Endcap; #sigma_{E}/E",100,0., 0.08);
  
  h_phoSigmaEoE_[2][0] = iBooker.book1D(histname+"convAll","#sigma_{E}/E if r9<0.0.94, 0.95: All ecal, #sigma_{E}/E", 100,0., 0.08);
  h_phoSigmaEoE_[2][1] = iBooker.book1D(histname+"convBarrel","#sigma_{E}/E if r9<0.94: Barrel, #sigma_{E}/E",100,0., 0.08);
  h_phoSigmaEoE_[2][2] = iBooker.book1D(histname+"convEndcap","#sigma_{E}/E if r9<0.95: Endcap, #sigma_{E}/E",100,0., 0.08);
  
    


  histname="eResVsEta";
  if ( ! isRunCentrally_ ) h2_eResVsEta_[0] = iBooker.book2D(histname+"All"," All photons E/Etrue vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0., 2.5);
  if ( ! isRunCentrally_ ) h2_eResVsEta_[1] = iBooker.book2D(histname+"Unconv"," Unconv photons E/Etrue vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0., 2.5);
  
  histname="pEResVsEta";
  p_eResVsEta_[0] = iBooker.bookProfile(histname+"All","All photons  E/Etrue vs #eta: all Ecal ",etaBin2,etaMin,etaMax,resBin,resMin, resMax,"");
  p_eResVsEta_[1] = iBooker.bookProfile(histname+"Unconv","Unconv photons  E/Etrue vs #eta: all Ecal",etaBin2,etaMin,etaMax,resBin,resMin, resMax,"");
  p_eResVsEta_[2] = iBooker.bookProfile(histname+"Conv","Conv photons  E/Etrue vs #eta: all Ecal",etaBin2,etaMin,etaMax,resBin,resMin, resMax,"");
  
  histname="pSigmaEoEVsEta";
  p_sigmaEoEVsEta_[0] = iBooker.bookProfile(histname+"All","All photons: #sigma_{E}/E vs #eta: all Ecal; #eta; #sigma_{E}/E",etaBin2,etaMin,etaMax,100,0., 0.08,"");
  p_sigmaEoEVsEta_[1] = iBooker.bookProfile(histname+"Unconv","Unconv photons #sigma_{E}/E vs #eta: all Ecal; #eta; #sigma_{E}/E ",etaBin2,etaMin,etaMax,100,0., 0.08, "");
  p_sigmaEoEVsEta_[2] = iBooker.bookProfile(histname+"Conv","Conv photons  #sigma_{E}/E vs #eta: all Ecal;  #eta; #sigma_{E}/E",etaBin2,etaMin,etaMax, 100,0., 0.08, "");

    

  histname="pSigmaEoEVsEt";
  p_sigmaEoEVsEt_[1][0] = iBooker.bookProfile(histname+"Barrel","All photons #sigma_{E}/E vs E_{T}: Barrel;  E_{T} (GeV); #sigma_{E}/E ",etBin,etMin,etMax, 100,0., 0.08, "");
  p_sigmaEoEVsEt_[1][1] = iBooker.bookProfile(histname+"unconvBarrel","Unconv photons #sigma_{E}/E vs E_{T}: Barrel;  E_{T} (GeV); #sigma_{E}/E ",etBin,etMin,etMax, 100,0., 0.08, "");
  p_sigmaEoEVsEt_[1][2] = iBooker.bookProfile(histname+"convBarrel","Conv photons  #sigma_{E}/E vs E_{T}: Barrel;  E_{T} (GeV); #sigma_{E}/E",etBin,etMin,etMax, 100,0., 0.08, "");
  p_sigmaEoEVsEt_[2][0] = iBooker.bookProfile(histname+"Endcap","All photons #sigma_{E}/E vs E_{T}: Endcap;  E_{T} (GeV); #sigma_{E}/E ",etBin,etMin,etMax, 100,0., 0.08, "");
  p_sigmaEoEVsEt_[2][1] = iBooker.bookProfile(histname+"unconvEndcap","Unconv photons #sigma_{E}/E vs E_{T}: Endcap;  E_{T} (GeV); #sigma_{E}/E ",etBin,etMin,etMax, 100,0., 0.08, "");
  p_sigmaEoEVsEt_[2][2] = iBooker.bookProfile(histname+"convEndcap","Conv photons  #sigma_{E}/E vs E_{T}: Endcap;  E_{T} (GeV); #sigma_{E}/E",etBin,etMin,etMax, 100,0., 0.08, "");
  
  

  histname="pSigmaEoEVsNVtx";
  p_sigmaEoEVsNVtx_[1][0] = iBooker.bookProfile(histname+"Barrel","All photons: #sigma_{E}/E vs N_{vtx}: Barrel; N_{vtx}; #sigma_{E}/E",80, -0.5, 79.5, 100,0., 0.08, "");
  p_sigmaEoEVsNVtx_[1][1] = iBooker.bookProfile(histname+"unconvBarrel","Unconv photons #sigma_{E}/E vs N_{vtx}: Barrel; N_{vtx}; #sigma_{E}/E ",80, -0.5, 79.5, 100,0., 0.08, "");
  p_sigmaEoEVsNVtx_[1][2] = iBooker.bookProfile(histname+"convBarrel","Conv photons  #sigma_{E}/E vs N_{vtx}: Barrel;  N_{vtx}; #sigma_{E}/E",80, -0.5, 79.5, 100,0., 0.08, "");
  p_sigmaEoEVsNVtx_[2][0] = iBooker.bookProfile(histname+"Endcap","All photons: #sigma_{E}/E vs N_{vtx}: Endcap; N_{vtx}; #sigma_{E}/E",80, -0.5, 79.5, 100,0., 0.08, "");
  p_sigmaEoEVsNVtx_[2][1] = iBooker.bookProfile(histname+"unconvEndcap","Unconv photons #sigma_{E}/E vs N_{vtx}: Endcap; N_{vtx}; #sigma_{E}/E ",80, -0.5, 79.5, 100,0., 0.08, "");
  p_sigmaEoEVsNVtx_[2][2] = iBooker.bookProfile(histname+"convEndcap","Conv photons  #sigma_{E}/E vs N_{vtx}: Endcap;  N_{vtx}; #sigma_{E}/E",80, -0.5, 79.5, 100,0., 0.08, "");
   

  if ( ! isRunCentrally_ ) {
    histname="eResVsEt";
    h2_eResVsEt_[0][0] = iBooker.book2D(histname+"All"," All photons E/Etrue vs true Et: all Ecal ",etBin,etMin, etMax,100, 0.9, 1.1);
    h2_eResVsEt_[0][1] = iBooker.book2D(histname+"unconv"," All photons E/Etrue vs true Et: all Ecal ",etBin,etMin, etMax,100, 0.9, 1.1);
    h2_eResVsEt_[0][2] = iBooker.book2D(histname+"conv"," All photons E/Etrue vs true Et: all Ecal ",etBin,etMin, etMax,100, 0.9, 1.1);
    h2_eResVsEt_[1][0] = iBooker.book2D(histname+"Barrel"," All photons E/Etrue vs true Et: Barrel ",etBin,etMin, etMax,100, 0.9, 1.1);
    h2_eResVsEt_[1][1] = iBooker.book2D(histname+"unconvBarrel"," All photons E/Etrue vs true Et: Barrel ",etBin,etMin, etMax,100, 0.9, 1.1);
    h2_eResVsEt_[1][2] = iBooker.book2D(histname+"convBarrel"," All photons E/Etrue vs true Et: Barrel ",etBin,etMin, etMax,100, 0.9, 1.1);
    h2_eResVsEt_[2][0] = iBooker.book2D(histname+"Endcap"," All photons E/Etrue vs true Et: Endcap ",etBin,etMin, etMax,100, 0.9, 1.1);
    h2_eResVsEt_[2][1] = iBooker.book2D(histname+"unconvEndcap"," All photons E/Etrue vs true Et: Endcap ",etBin,etMin, etMax,100, 0.9, 1.1);
    h2_eResVsEt_[2][2] = iBooker.book2D(histname+"convEndcap"," All photons E/Etrue vs true Et: Endcap ",etBin,etMin, etMax,100, 0.9, 1.1);
  }
  
  histname="pEResVsEt";
  p_eResVsEt_[0][0] = iBooker.bookProfile(histname+"All","All photons  E/Etrue vs Et: all Ecal ",etBin,etMin,etMax,resBin,resMin, resMax,"");
  p_eResVsEt_[0][1] = iBooker.bookProfile(histname+"unconv","All photons  E/Etrue vs Et: all Ecal ",etBin,etMin,etMax,resBin,resMin, resMax,"");
  p_eResVsEt_[0][2] = iBooker.bookProfile(histname+"conv","All photons  E/Etrue vs Et: all Ecal ",etBin,etMin,etMax,resBin,resMin, resMax,"");
  p_eResVsEt_[1][0] = iBooker.bookProfile(histname+"Barrel","All photons  E/Etrue vs Et: Barrel ",etBin,etMin,etMax,resBin,resMin, resMax,"");
  p_eResVsEt_[1][1] = iBooker.bookProfile(histname+"unconvBarrel","All photons  E/Etrue vs Et: Barrel ",etBin,etMin,etMax,resBin,resMin, resMax,"");
  p_eResVsEt_[1][2] = iBooker.bookProfile(histname+"convBarrel","All photons  E/Etrue vs Et: Barrel ",etBin,etMin,etMax,resBin,resMin, resMax,"");
  p_eResVsEt_[2][0] = iBooker.bookProfile(histname+"Endcap","All photons  E/Etrue vs Et: Endcap ",etBin,etMin,etMax,resBin,resMin, resMax,"");
  p_eResVsEt_[2][1] = iBooker.bookProfile(histname+"unconvEndcap","All photons  E/Etrue vs Et: Endcap ",etBin,etMin,etMax,resBin,resMin, resMax,"");
  p_eResVsEt_[2][2] = iBooker.bookProfile(histname+"convEndcap","All photons  E/Etrue vs Et: Endcap ",etBin,etMin,etMax,resBin,resMin, resMax,"");
  
  
  histname="pEResVsNVtx";
  p_eResVsNVtx_[1][0] = iBooker.bookProfile(histname+"Barrel","All photons  E/E_{true}  vs N_{vtx}: Barrel;  N_{vtx}; E}/E_{true}",80, -0.5, 79.5,resBin,resMin, resMax,"");
  p_eResVsNVtx_[1][1] = iBooker.bookProfile(histname+"unconvBarrel","Unconverted photons E/E_{true}  vs N_{vtx}: Barrel;  N_{vtx}; E}/E_{true} ",80, -0.5, 79.5,resBin,resMin, resMax,"");
  p_eResVsNVtx_[1][2] = iBooker.bookProfile(histname+"convBarrel"," Converted photons  E/E_{true}  vs N_{vtx}: Barrel;  N_{vtx}; E}/E_{true} ",80, -0.5, 79.5,resBin,resMin, resMax,"");
  p_eResVsNVtx_[2][0] = iBooker.bookProfile(histname+"Endcap","All photons  E/E_{true}  vs N_{vtx}: Endcap;  N_{vtx}; E}/E_{true} ",80, -0.5, 79.5,resBin,resMin, resMax,"");
  p_eResVsNVtx_[2][1] = iBooker.bookProfile(histname+"unconvEndcap","Uncoverted photons  E/E_{true}  vs N_{vtx}: Endcap;  N_{vtx}; E}/E_{true} ",80, -0.5, 79.5,resBin,resMin, resMax,"");
  p_eResVsNVtx_[2][2] = iBooker.bookProfile(histname+"convEndcap","Converted photons E/E_{true}  vs N_{vtx}: Endcap;  N_{vtx}; E}/E_{true} ",80, -0.5, 79.5,resBin,resMin, resMax,"");



  histname="eResVsR9";
  if ( ! isRunCentrally_ ) h2_eResVsR9_[0] = iBooker.book2D(histname+"All"," All photons E/Etrue vs R9: all Ecal ",r9Bin*2,r9Min, r9Max,100, 0., 2.5);
  if ( ! isRunCentrally_ ) h2_eResVsR9_[1] = iBooker.book2D(histname+"Barrel"," All photons E/Etrue vs R9: Barrel ",  r9Bin*2,r9Min, r9Max,100, 0.,2.5);
  if ( ! isRunCentrally_ ) h2_eResVsR9_[2] = iBooker.book2D(histname+"Endcap"," All photons E/Etrue vs R9: Endcap ",  r9Bin*2,r9Min, r9Max,100, 0., 2.5);
  histname="pEResVsR9";
  if ( ! isRunCentrally_ ) p_eResVsR9_[0] = iBooker.bookProfile(histname+"All"," All photons  E/Etrue vs R9: all Ecal ",r9Bin*2,r9Min, r9Max,resBin,resMin, resMax,"");
  p_eResVsR9_[1] = iBooker.bookProfile(histname+"Barrel"," All photons  E/Etrue vs R9: Barrel ",  r9Bin*2,r9Min, r9Max,resBin,resMin, resMax,"");
  p_eResVsR9_[2] = iBooker.bookProfile(histname+"Endcap"," All photons  E/Etrue vs R9: Endcap ",  r9Bin*2,r9Min, r9Max,resBin,resMin, resMax,"");
  histname="sceResVsR9";
  if ( ! isRunCentrally_ ) h2_sceResVsR9_[0] = iBooker.book2D(histname+"All"," All photons scE/Etrue vs R9: all Ecal ",r9Bin*2,r9Min, r9Max,100, 0., 2.5);
  if ( ! isRunCentrally_ ) h2_sceResVsR9_[1] = iBooker.book2D(histname+"Barrel"," All photons scE/Etrue vs R9: Barrel ",  r9Bin*2,r9Min, r9Max,100, 0.,2.5);
  if ( ! isRunCentrally_ ) h2_sceResVsR9_[2] = iBooker.book2D(histname+"Endcap"," All photons scE/Etrue vs R9: Endcap ",  r9Bin*2,r9Min, r9Max,100, 0., 2.5);
  histname="scpEResVsR9";
  if ( ! isRunCentrally_ ) p_sceResVsR9_[0] = iBooker.bookProfile(histname+"All"," All photons  scE/Etrue vs R9: all Ecal ",r9Bin*2,r9Min, r9Max,resBin,resMin, resMax,"");
  p_sceResVsR9_[1] = iBooker.bookProfile(histname+"Barrel"," All photons  scE/Etrue vs R9: Barrel ",  r9Bin*2,r9Min, r9Max,resBin,resMin, resMax,"");
  p_sceResVsR9_[2] = iBooker.bookProfile(histname+"Endcap"," All photons  scE/Etrue vs R9: Endcap ",  r9Bin*2,r9Min, r9Max,resBin,resMin, resMax,"");

  // Photon E resolution when using energy values from regressions
  histname = "eResRegr1";
  h_phoEResRegr1_[0][0] = iBooker.book1D(histname+"All"," Photon rec/true Energy from Regression1 : All ecal ", resBin,resMin, resMax);
  h_phoEResRegr1_[0][1] = iBooker.book1D(histname+"Barrel"," Photon rec/true Energy from Regression1: Barrel ",resBin,resMin, resMax);
  h_phoEResRegr1_[0][2] = iBooker.book1D(histname+"Endcap"," Photon rec/true Energy from Regression1: Endcap ",resBin,resMin, resMax);
  
  h_phoEResRegr1_[1][0] = iBooker.book1D(histname+"unconvAll"," Photon rec/true Energy from Regression1 if r9>0.94, 0.95: All ecal ", resBin,resMin, resMax);
  h_phoEResRegr1_[1][1] = iBooker.book1D(histname+"unconvBarrel"," Photon rec/true Energy from Regression1 if r9>0.94: Barrel ",resBin,resMin, resMax);
  h_phoEResRegr1_[1][2] = iBooker.book1D(histname+"unconvEndcap"," Photon rec/true Energy from Regression1 if r9>0.95: Endcap ",resBin,resMin, resMax);
  
  h_phoEResRegr1_[2][0] = iBooker.book1D(histname+"convAll"," Photon rec/true Energy  from Regression1if r9<0.0.94, 0.95: All ecal ", resBin,resMin, resMax);
  h_phoEResRegr1_[2][1] = iBooker.book1D(histname+"convBarrel"," Photon rec/true Energy from Regression1 if r9<0.94: Barrel ",resBin,resMin, resMax);
  h_phoEResRegr1_[2][2] = iBooker.book1D(histname+"convEndcap"," Photon rec/true Energy from Regression1 if r9<0.95: Endcap ",resBin,resMin, resMax);
  
  histname = "eResRegr2";
  h_phoEResRegr2_[0][0] = iBooker.book1D(histname+"All"," Photon rec/true Energy from Regression2 : All ecal ", resBin,resMin, resMax);
  h_phoEResRegr2_[0][1] = iBooker.book1D(histname+"Barrel"," Photon rec/true Energy from Regression2: Barrel ",resBin,resMin, resMax);
  h_phoEResRegr2_[0][2] = iBooker.book1D(histname+"Endcap"," Photon rec/true Energy from Regression2: Endcap ",resBin,resMin, resMax);
  
  h_phoEResRegr2_[1][0] = iBooker.book1D(histname+"unconvAll"," Photon rec/true Energy from Regression2 if r9>0.94, 0.95: All ecal ", resBin,resMin, resMax);
  h_phoEResRegr2_[1][1] = iBooker.book1D(histname+"unconvBarrel"," Photon rec/true Energy from Regression2 if r9>0.94: Barrel ",resBin,resMin, resMax);
  h_phoEResRegr2_[1][2] = iBooker.book1D(histname+"unconvEndcap"," Photon rec/true Energy from Regression2 if r9>0.95: Endcap ",resBin,resMin, resMax);
  
  h_phoEResRegr2_[2][0] = iBooker.book1D(histname+"convAll"," Photon rec/true Energy  from Regression2 if r9<0.0.94, 0.95: All ecal ", resBin,resMin, resMax);
  h_phoEResRegr2_[2][1] = iBooker.book1D(histname+"convBarrel"," Photon rec/true Energy from Regression2 if r9<0.94: Barrel ",resBin,resMin, resMax);
  h_phoEResRegr2_[2][2] = iBooker.book1D(histname+"convEndcap"," Photon rec/true Energy from Regression2 if r9<0.95: Endcap ",resBin,resMin, resMax);
  //
  histname = "phoPixSeedSize";
  h_phoPixSeedSize_[0]= iBooker.book1D(histname+"Barrel","Pixel seeds size ", 100, 0., 100.);
  h_phoPixSeedSize_[1]= iBooker.book1D(histname+"Endcap","Pixel seeds size ", 100, 0., 100.);
  
  //  Infos from Particle Flow - isolation and ID
  histname = "chargedHadIso";
  h_chHadIso_[0]=  iBooker.book1D(histname+"All",   "PF chargedHadIso:  All Ecal",etBin,etMin,20.);
  h_chHadIso_[1]=  iBooker.book1D(histname+"Barrel",   "PF chargedHadIso:  Barrel",etBin,etMin,20.);
  h_chHadIso_[2]=  iBooker.book1D(histname+"Endcap",   "PF chargedHadIso:  Endcap",etBin,etMin,20.);
  histname = "neutralHadIso";
  h_nHadIso_[0]=  iBooker.book1D(histname+"All",   "PF neutralHadIso:  All Ecal",etBin,etMin,20.);
  h_nHadIso_[1]=  iBooker.book1D(histname+"Barrel",   "PF neutralHadIso:  Barrel",etBin,etMin,20.);
  h_nHadIso_[2]=  iBooker.book1D(histname+"Endcap",   "PF neutralHadIso:  Endcap",etBin,etMin,20.);
  histname = "photonIso";
  h_phoIso_[0]=  iBooker.book1D(histname+"All",   "PF photonIso:  All Ecal",etBin,etMin,20.);
  h_phoIso_[1]=  iBooker.book1D(histname+"Barrel",   "PF photonIso:  Barrel",etBin,etMin,20.);
  h_phoIso_[2]=  iBooker.book1D(histname+"Endcap",   "PF photonIso:  Endcap",etBin,etMin,20.);
  histname = "nCluOutMustache";
  h_nCluOutsideMustache_[0]= iBooker.book1D(histname+"All",   "PF number of clusters outside Mustache:  All Ecal",50,0.,50.);
  h_nCluOutsideMustache_[1]= iBooker.book1D(histname+"Barrel",   "PF number of clusters outside Mustache:  Barrel",50,0.,50.);
  h_nCluOutsideMustache_[2]= iBooker.book1D(histname+"Endcap",   "PF number of clusters outside Mustache:  Endcap",50,0.,50.);
  histname = "etOutMustache";
  h_etOutsideMustache_[0]= iBooker.book1D(histname+"All",   "PF et outside Mustache:  All Ecal",etBin,etMin,20.);
  h_etOutsideMustache_[1]= iBooker.book1D(histname+"Barrel",   "PF et outside Mustache:  Barrel",etBin,etMin,20.);
  h_etOutsideMustache_[2]= iBooker.book1D(histname+"Endcap",   "PF et outside Mustache:  Endcap",etBin,etMin,20.);
  histname = "pfMVA";
  h_pfMva_[0]= iBooker.book1D(histname+"All",   "PF MVA output:  All Ecal",50,-1.,2.);
  h_pfMva_[1]= iBooker.book1D(histname+"Barrel",   "PF MVA output:  Barrel",50,-1.,2.);
  h_pfMva_[2]= iBooker.book1D(histname+"Endcap",   "PF MVA output:  Endcap",50,-1,2.);
  histname = "SumPtOverPhoPt_ChHad_Cleaned";
  h_SumPtOverPhoPt_ChHad_Cleaned_[0]=  iBooker.book1D(histname+"All","Pf Cand SumPt/P_{T}_{#gamma}: Charged Hadrons:  All Ecal",etBin,etMin,2.);
  h_SumPtOverPhoPt_ChHad_Cleaned_[1]=  iBooker.book1D(histname+"Barrel","PF Cand SumPt/P_{T}_{#gamma}: Charged Hadrons:  Barrel",etBin,etMin,2.);
  h_SumPtOverPhoPt_ChHad_Cleaned_[2]=  iBooker.book1D(histname+"Endcap","PF Cand SumPt/P_{T}_{#gamma}: Charged Hadrons:  Endcap",etBin,etMin,2.);
  histname = "SumPtOverPhoPt_NeuHad_Cleaned";
  h_SumPtOverPhoPt_NeuHad_Cleaned_[0]=  iBooker.book1D(histname+"All","Pf Cand  SumPt/P_{T}_{#gamma}: Neutral Hadrons:  All Ecal",etBin,etMin,2.);
  h_SumPtOverPhoPt_NeuHad_Cleaned_[1]=  iBooker.book1D(histname+"Barrel","PF Cand  SumPt/P_{T}_{#gamma}: Neutral Hadrons:  Barrel",etBin,etMin,2.);
  h_SumPtOverPhoPt_NeuHad_Cleaned_[2]=  iBooker.book1D(histname+"Endcap","PF Cand  SumPt/P_{T}_{#gamma}: Neutral Hadrons:  Endcap",etBin,etMin,2.);
  histname = "SumPtOverPhoPt_Pho_Cleaned";
  h_SumPtOverPhoPt_Pho_Cleaned_[0]=  iBooker.book1D(histname+"All","Pf Cand SumPt/P_{T}_{#gamma}: Photons:  All Ecal",etBin,etMin,2.);
  h_SumPtOverPhoPt_Pho_Cleaned_[1]=  iBooker.book1D(histname+"Barrel","PF Cand SumPt/P_{T}_{#gamma}: Photons:  Barrel",etBin,etMin,2.);
  h_SumPtOverPhoPt_Pho_Cleaned_[2]=  iBooker.book1D(histname+"Endcap","PF Cand SumPt/P_{T}_{#gamma}: Photons:  Endcap",etBin,etMin,2.);
  
  histname = "dRPhoPFcand_ChHad_Cleaned";
  h_dRPhoPFcand_ChHad_Cleaned_[0]=  iBooker.book1D(histname+"All","dR(pho,cand) Charged Hadrons : All Ecal",etBin,etMin,0.7);
  h_dRPhoPFcand_ChHad_Cleaned_[1]=  iBooker.book1D(histname+"Barrel","dR(pho,cand) Charged Hadrons :  Barrel",etBin,etMin,0.7);
  h_dRPhoPFcand_ChHad_Cleaned_[2]=  iBooker.book1D(histname+"Endcap","dR(pho,cand) Charged Hadrons :  Endcap",etBin,etMin,0.7);
  histname = "dRPhoPFcand_NeuHad_Cleaned";
  h_dRPhoPFcand_NeuHad_Cleaned_[0]=  iBooker.book1D(histname+"All","dR(pho,cand) Neutral Hadrons : All Ecal",etBin,etMin,0.7);
  h_dRPhoPFcand_NeuHad_Cleaned_[1]=  iBooker.book1D(histname+"Barrel","dR(pho,cand) Neutral Hadrons :  Barrel",etBin,etMin,0.7);
  h_dRPhoPFcand_NeuHad_Cleaned_[2]=  iBooker.book1D(histname+"Endcap","dR(pho,cand) Neutral Hadrons :  Endcap",etBin,etMin,0.7);
  histname = "dRPhoPFcand_Pho_Cleaned";
  h_dRPhoPFcand_Pho_Cleaned_[0]=  iBooker.book1D(histname+"All","dR(pho,cand) Photons : All Ecal",etBin,etMin,0.7);
  h_dRPhoPFcand_Pho_Cleaned_[1]=  iBooker.book1D(histname+"Barrel","dR(pho,cand) Photons :  Barrel",etBin,etMin,0.7);
  h_dRPhoPFcand_Pho_Cleaned_[2]=  iBooker.book1D(histname+"Endcap","dR(pho,cand) Photons :  Endcap",etBin,etMin,0.7);
 
  //
  histname = "SumPtOverPhoPt_ChHad_unCleaned";
  h_SumPtOverPhoPt_ChHad_unCleaned_[0]=  iBooker.book1D(histname+"All","Pf Cand Sum Pt Over photon pt Charged Hadrons :  All Ecal",etBin,etMin,2.);
  h_SumPtOverPhoPt_ChHad_unCleaned_[1]=  iBooker.book1D(histname+"Barrel","PF Cand Sum Pt Over photon pt Charged Hadrons:  Barrel",etBin,etMin,2.);
  h_SumPtOverPhoPt_ChHad_unCleaned_[2]=  iBooker.book1D(histname+"Endcap","PF Cand Sum Pt Over photon pt Charged Hadrons:  Endcap",etBin,etMin,2.);
  histname = "SumPtOverPhoPt_NeuHad_unCleaned";
  h_SumPtOverPhoPt_NeuHad_unCleaned_[0]=  iBooker.book1D(histname+"All","Pf Cand Sum Pt Over photon pt Neutral Hadrons :  All Ecal",etBin,etMin,2.);
  h_SumPtOverPhoPt_NeuHad_unCleaned_[1]=  iBooker.book1D(histname+"Barrel","PF Cand Sum Pt Over photon pt Neutral Hadrons:  Barrel",etBin,etMin,2.);
  h_SumPtOverPhoPt_NeuHad_unCleaned_[2]=  iBooker.book1D(histname+"Endcap","PF Cand Sum Pt Over photon pt Neutral Hadrons:  Endcap",etBin,etMin,2.);
  histname = "SumPtOverPhoPt_Pho_unCleaned";
  h_SumPtOverPhoPt_Pho_unCleaned_[0]=  iBooker.book1D(histname+"All","Pf Cand Sum Pt Over photon pt Photons:  All Ecal",etBin,etMin,2.);
  h_SumPtOverPhoPt_Pho_unCleaned_[1]=  iBooker.book1D(histname+"Barrel","PF Cand Sum Pt Over photon pt Photons:  Barrel",etBin,etMin,2.);
  h_SumPtOverPhoPt_Pho_unCleaned_[2]=  iBooker.book1D(histname+"Endcap","PF Cand Sum Pt Over photon pt Photons:  Endcap",etBin,etMin,2.);
  histname = "dRPhoPFcand_ChHad_unCleaned";
  h_dRPhoPFcand_ChHad_unCleaned_[0]=  iBooker.book1D(histname+"All","dR(pho,cand) Charged Hadrons :  All Ecal",etBin,etMin,0.7);
  h_dRPhoPFcand_ChHad_unCleaned_[1]=  iBooker.book1D(histname+"Barrel","dR(pho,cand) Charged Hadrons :  Barrel",etBin,etMin,0.7);
  h_dRPhoPFcand_ChHad_unCleaned_[2]=  iBooker.book1D(histname+"Endcap","dR(pho,cand) Charged Hadrons :  Endcap",etBin,etMin,0.7);
  histname = "dRPhoPFcand_NeuHad_unCleaned";
  h_dRPhoPFcand_NeuHad_unCleaned_[0]=  iBooker.book1D(histname+"All","dR(pho,cand) Neutral Hadrons :  All Ecal",etBin,etMin,0.7);
  h_dRPhoPFcand_NeuHad_unCleaned_[1]=  iBooker.book1D(histname+"Barrel","dR(pho,cand) Neutral Hadrons :  Barrel",etBin,etMin,0.7);
  h_dRPhoPFcand_NeuHad_unCleaned_[2]=  iBooker.book1D(histname+"Endcap","dR(pho,cand) Neutral Hadrons :  Endcap",etBin,etMin,0.7);
  histname = "dRPhoPFcand_Pho_unCleaned";
  h_dRPhoPFcand_Pho_unCleaned_[0]=  iBooker.book1D(histname+"All","dR(pho,cand) Photons:  All Ecal",etBin,etMin,0.7);
  h_dRPhoPFcand_Pho_unCleaned_[1]=  iBooker.book1D(histname+"Barrel","dR(pho,cand) Photons:  Barrel",etBin,etMin,0.7);
  h_dRPhoPFcand_Pho_unCleaned_[2]=  iBooker.book1D(histname+"Endcap","dR(pho,cand) Photons:  Endcap",etBin,etMin,0.7);


  
  //    if ( ! isRunCentrally_ ) {
  // Photon pair invariant mass
  histname = "gamgamMass";
  h_gamgamMass_[0][0] = iBooker.book1D(histname+"All","2 photons invariant mass: All ecal ", ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMass_[0][1] = iBooker.book1D(histname+"Barrel","2 photons invariant mass:  Barrel ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMass_[0][2] = iBooker.book1D(histname+"Endcap","2 photons invariant mass:  Endcap ",ggMassBin, ggMassMin, ggMassMax);
  //
  histname = "gamgamMassNoConv";
  h_gamgamMass_[1][0] = iBooker.book1D(histname+"All","2 photons with no conversion invariant mass: All ecal ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMass_[1][1] = iBooker.book1D(histname+"Barrel","2 photons with no conversion  invariant mass:  Barrel ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMass_[1][2] = iBooker.book1D(histname+"Endcap","2 photons with no conversion  invariant mass:  Endcap ",ggMassBin, ggMassMin, ggMassMax);
  //
  histname = "gamgamMassConv";
  h_gamgamMass_[2][0] = iBooker.book1D(histname+"All","2 photons with conversion invariant mass: All ecal ", ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMass_[2][1] = iBooker.book1D(histname+"Barrel","2 photons with  conversion  invariant mass:  Barrel ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMass_[2][2] = iBooker.book1D(histname+"Endcap","2 photons with  conversion  invariant mass:  Endcap ",ggMassBin, ggMassMin, ggMassMax);
  // with energy regression1
  histname = "gamgamMassRegr1";
  h_gamgamMassRegr1_[0][0] = iBooker.book1D(histname+"All","2 photons invariant mass Regr1 : All ecal ", ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr1_[0][1] = iBooker.book1D(histname+"Barrel","2 photons invariant mass Regr1 :  Barrel ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr1_[0][2] = iBooker.book1D(histname+"Endcap","2 photons invariant mass Regr1 :  Endcap ",ggMassBin, ggMassMin, ggMassMax);
  //
  histname = "gamgamMassRegr1NoConv";
  h_gamgamMassRegr1_[1][0] = iBooker.book1D(histname+"All","2 photons with no conversion invariant mass Regr1: All ecal ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr1_[1][1] = iBooker.book1D(histname+"Barrel","2 photons with no conversion  invariant mass Regr1:  Barrel ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr1_[1][2] = iBooker.book1D(histname+"Endcap","2 photons with no conversion  invariant mass Regr1:  Endcap ",ggMassBin, ggMassMin, ggMassMax);
  //
  histname = "gamgamMassRegr1Conv";
  h_gamgamMassRegr1_[2][0] = iBooker.book1D(histname+"All","2 photons with conversion invariant mass Regr1: All ecal ", ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr1_[2][1] = iBooker.book1D(histname+"Barrel","2 photons with  conversion  invariant mass Regr1:  Barrel ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr1_[2][2] = iBooker.book1D(histname+"Endcap","2 photons with  conversion  invariant mass Regr1:  Endcap ",ggMassBin, ggMassMin, ggMassMax);
  // with energy regression2
  histname = "gamgamMassRegr2";
  h_gamgamMassRegr2_[0][0] = iBooker.book1D(histname+"All","2 photons invariant mass Regr2 : All ecal ", ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr2_[0][1] = iBooker.book1D(histname+"Barrel","2 photons invariant mass Regr2 :  Barrel ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr2_[0][2] = iBooker.book1D(histname+"Endcap","2 photons invariant mass Regr2 :  Endcap ",ggMassBin, ggMassMin, ggMassMax);
  //
  histname = "gamgamMassRegr2NoConv";
  h_gamgamMassRegr2_[1][0] = iBooker.book1D(histname+"All","2 photons with no conversion invariant mass Regr2: All ecal ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr2_[1][1] = iBooker.book1D(histname+"Barrel","2 photons with no conversion  invariant mass Regr2:  Barrel ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr2_[1][2] = iBooker.book1D(histname+"Endcap","2 photons with no conversion  invariant mass Regr2:  Endcap ",ggMassBin, ggMassMin, ggMassMax);
  //
  histname = "gamgamMassRegr2Conv";
  h_gamgamMassRegr2_[2][0] = iBooker.book1D(histname+"All","2 photons with conversion invariant mass Regr2: All ecal ", ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr2_[2][1] = iBooker.book1D(histname+"Barrel","2 photons with  conversion  invariant mass Regr2:  Barrel ",ggMassBin, ggMassMin, ggMassMax);
  h_gamgamMassRegr2_[2][2] = iBooker.book1D(histname+"Endcap","2 photons with  conversion  invariant mass Regr2:  Endcap ",ggMassBin, ggMassMin, ggMassMax);
  
  
    //}
  
  iBooker.setCurrentFolder("EgammaV/"+fName_+"/ConversionInfo");
  
  
  histname="nConv";
  h_nConv_[0][0] = iBooker.book1D(histname+"All","Number Of two-tracks Conversions per isolated candidates per events: All Ecal  ",10,-0.5, 9.5);
  h_nConv_[0][1] = iBooker.book1D(histname+"Barrel","Number Of two-tracks Conversions per isolated candidates per events: Ecal Barrel  ",10,-0.5, 9.5);
  h_nConv_[0][2] = iBooker.book1D(histname+"Endcap","Number Of two-tracks Conversions per isolated candidates per events: Ecal Endcap ",10,-0.5, 9.5);
  h_nConv_[1][0] = iBooker.book1D(histname+"OneLegAll","Number Of single leg Conversions per isolated candidates per events: All Ecal  ",10,-0.5, 9.5);
  h_nConv_[1][1] = iBooker.book1D(histname+"OneLegBarrel","Number Of single leg Conversions per isolated candidates per events: Ecal Barrel  ",10,-0.5, 9.5);
  h_nConv_[1][2] = iBooker.book1D(histname+"OneLegEndcap","Number Of single leg Conversions per isolated candidates per events: Ecal Endcap ",10,-0.5, 9.5);
  
  
  h_convEta_[0] = iBooker.book1D("convEta1"," converted Photon Eta >1 track",etaBin,etaMin, etaMax) ;
  h_convEta_[1] = iBooker.book1D("convEta2"," converted Photon Eta =2 tracks ",etaBin,etaMin, etaMax) ;
  h_convEta_[2] = iBooker.book1D("convEta2ass"," converted Photon Eta =2 tracks, both ass ",etaBin,etaMin, etaMax) ;
  h_convPhi_[0] = iBooker.book1D("convPhi"," converted Photon  Phi ",phiBin,phiMin,phiMax) ;
  

  histname = "convERes";
  h_convERes_[0][0] = iBooker.book1D(histname+"All"," Conversion rec/true Energy: All ecal ", resBin,resMin, resMax);
  h_convERes_[0][1] = iBooker.book1D(histname+"Barrel"," Conversion rec/true Energy: Barrel ",resBin,resMin, resMax);
  h_convERes_[0][2] = iBooker.book1D(histname+"Endcap"," Conversion rec/true Energy: Endcap ",resBin,resMin, resMax);
  
  histname="p_EResVsR";
  p_eResVsR_ = iBooker.bookProfile(histname+"All"," photons conversion E/Etrue vs R: all Ecal ",rBin,rMin,rMax, 100, 0.,1.5,"");
  
  
  histname = "convPtRes";
  h_convPtRes_[1][0] = iBooker.book1D(histname+"All"," Conversion Pt rec/true  from tracks : All ecal ", resBin,0.,1.5);
  h_convPtRes_[1][1] = iBooker.book1D(histname+"Barrel"," Conversion Pt rec/true  from tracks: Barrel ",resBin,0., 1.5);
  h_convPtRes_[1][2] = iBooker.book1D(histname+"Endcap"," Conversion Pt rec/true  from tracks: Endcap ",resBin,0., 1.5);
  
  
  if ( ! isRunCentrally_ ) {
    histname="r9VsTracks";
    h_r9VsNofTracks_[0][0] = iBooker.book2D(histname+"All"," photons r9 vs nTracks from conversions: All Ecal",r9Bin,r9Min, r9Max, 3, -0.5, 2.5) ;
    h_r9VsNofTracks_[0][1] = iBooker.book2D(histname+"Barrel"," photons r9 vs nTracks from conversions: Barrel Ecal",r9Bin,r9Min, r9Max, 3, -0.5, 2.5) ;
    h_r9VsNofTracks_[0][2] = iBooker.book2D(histname+"Endcap"," photons r9 vs nTracks from conversions: Endcap Ecal",r9Bin,r9Min, r9Max, 3, -0.5, 2.5) ;
  }
  
  histname="mvaOut";
  h_mvaOut_[0] = iBooker.book1D(histname+"All"," mvaOut for all conversions : All Ecal",100, 0., 1.);
  h_mvaOut_[1] = iBooker.book1D(histname+"Barrel"," mvaOut for all conversions : Barrel Ecal",100, 0., 1.);
  h_mvaOut_[2] = iBooker.book1D(histname+"Endcap"," mvaOut for all conversions : Endcap Ecal",100, 0., 1.);
  
  

  histname="EoverPtracks";
  h_EoverPTracks_[0][0] = iBooker.book1D(histname+"BarrelPix"," photons conversion E/p: barrel pix",eoverpBin, eoverpMin,eoverpMax);
  h_EoverPTracks_[0][1] = iBooker.book1D(histname+"BarrelTib"," photons conversion E/p: barrel tib",eoverpBin, eoverpMin,eoverpMax);
  h_EoverPTracks_[0][2] = iBooker.book1D(histname+"BarrelTob"," photons conversion E/p: barrel tob ",eoverpBin, eoverpMin,eoverpMax);
  
  h_EoverPTracks_[1][0] = iBooker.book1D(histname+"All"," photons conversion E/p: all Ecal ",100, 0., 5.);
  h_EoverPTracks_[1][1] = iBooker.book1D(histname+"Barrel"," photons conversion E/p: Barrel Ecal",100, 0., 5.);
  h_EoverPTracks_[1][2] = iBooker.book1D(histname+"Endcap"," photons conversion E/p: Endcap Ecal ",100, 0., 5.);
  histname="EoverP_SL";
  h_EoverP_SL_[0] = iBooker.book1D(histname+"All"," photons single leg conversion E/p: all Ecal ",100, 0., 5.);
  h_EoverP_SL_[1] = iBooker.book1D(histname+"Barrel"," photons single leg conversion E/p: Barrel Ecal",100, 0., 5.);
  h_EoverP_SL_[2] = iBooker.book1D(histname+"Endcap"," photons single leg conversion E/p: Endcap Ecal ",100, 0., 5.);
  
  
  histname="PoverEtracks";
  h_PoverETracks_[1][0] = iBooker.book1D(histname+"All"," photons conversion p/E: all Ecal ",povereBin, povereMin, povereMax);
  h_PoverETracks_[1][1] = iBooker.book1D(histname+"Barrel"," photons conversion p/E: Barrel Ecal",povereBin, povereMin, povereMax);
  h_PoverETracks_[1][2] = iBooker.book1D(histname+"Endcap"," photons conversion p/E: Endcap Ecal ",povereBin, povereMin, povereMax);
  
  histname="pEoverEtrueVsEta";
  p_EoverEtrueVsEta_[0] = iBooker.bookProfile(histname+"All"," photons conversion with 2 (associated) reco tracks E/Etrue vs #eta: all Ecal ",etaBin2,etaMin, etaMax, 100,0.,2.5,"");
  
  histname="pEoverEtrueVsR";
  p_EoverEtrueVsR_[0] = iBooker.bookProfile(histname+"All"," photons conversion E/Etrue vs R: all Ecal ",rBin,rMin,rMax, 100, 0., 2.5, "");
  
  histname="pEoverEtrueVsEta";
  p_EoverEtrueVsEta_[1] = iBooker.bookProfile(histname+"All2"," photons conversion  2 reco tracks  E/Etrue vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0., 2.5,"");
  
  histname="pPoverPtrueVsEta";
  p_PoverPtrueVsEta_[0] = iBooker.bookProfile(histname+"All"," photons conversion P/Ptrue vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0., 5.,"");
  
  histname="pEoverPVsEta";
  p_EoverPVsEta_[0] = iBooker.bookProfile(histname+"All"," photons conversion E/P vs #eta: all Ecal ",etaBin2,etaMin, etaMax, 100, 0., 5.,"");
  
  
  if ( ! isRunCentrally_ ) {
    histname="EoverEtrueVsEoverP";
    h2_EoverEtrueVsEoverP_[0] = iBooker.book2D(histname+"All"," photons conversion E/Etrue vs E/P: all Ecal ",100, 0., 5., 100, 0.5, 1.5);
    h2_EoverEtrueVsEoverP_[1] = iBooker.book2D(histname+"Barrel"," photons conversion  E/Etrue vs E/: Barrel Ecal",100, 0., 5.,100, 0.5, 1.5);
    h2_EoverEtrueVsEoverP_[2] = iBooker.book2D(histname+"Endcap"," photons conversion  E/Etrue vs E/: Endcap Ecal ",100, 0., 5., 100, 0.5, 1.5);
    histname="PoverPtrueVsEoverP";
    h2_PoverPtrueVsEoverP_[0] = iBooker.book2D(histname+"All"," photons conversion P/Ptrue vs E/P: all Ecal ",100, 0., 5., 100, 0., 2.5);
    h2_PoverPtrueVsEoverP_[1] = iBooker.book2D(histname+"Barrel"," photons conversion  P/Ptrue vs E/: Barrel Ecal",100, 0., 5.,100, 0., 2.5);
    h2_PoverPtrueVsEoverP_[2] = iBooker.book2D(histname+"Endcap"," photons conversion  P/Ptrue vs E/: Endcap Ecal ",100, 0., 5., 100, 0., 2.5);
    
    histname="EoverEtrueVsEta";
    h2_EoverEtrueVsEta_[0] = iBooker.book2D(histname+"All"," photons conversion with 2 (associated) reco tracks  E/Etrue vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0., 2.5);
    
    
    histname="EoverEtrueVsEta";
    h2_EoverEtrueVsEta_[1] = iBooker.book2D(histname+"All2"," photons conversion  2 reco tracks  E/Etrue vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0., 2.5);
    
    histname="EoverEtrueVsR";
    h2_EoverEtrueVsR_[0] = iBooker.book2D(histname+"All"," photons conversion E/Etrue vs R: all Ecal ",rBin,rMin, rMax,100, 0., 2.5);
    
    histname="PoverPtrueVsEta";
    h2_PoverPtrueVsEta_[0] = iBooker.book2D(histname+"All"," photons conversion P/Ptrue vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0., 5.);
    
    histname="EoverPVsEta";
    h2_EoverPVsEta_[0] = iBooker.book2D(histname+"All"," photons conversion E/P vs #eta: all Ecal ",etaBin2,etaMin, etaMax,100, 0., 5.);
    
    histname="EoverPVsR";
    h2_EoverPVsR_[0] = iBooker.book2D(histname+"All"," photons conversion E/P vs R: all Ecal ",rBin,rMin, rMax,100, 0., 5.);
    
    histname="etaVsRsim";
    h2_etaVsRsim_[0] = iBooker.book2D(histname+"All"," eta(sim) vs R (sim) for associated conversions: all Ecal ",etaBin, etaMin, etaMax,rBin,rMin, rMax);
    histname="etaVsRreco";
    h2_etaVsRreco_[0] = iBooker.book2D(histname+"All"," eta(reco) vs R (reco) for associated conversions: all Ecal ",etaBin, etaMin, etaMax,rBin,rMin, rMax);
    
  }
  
  histname="pEoverPVsR";
  p_EoverPVsR_[0] = iBooker.bookProfile(histname+"All"," photons conversion E/P vs R: all Ecal ",rBin,rMin,rMax, 100, 0., 5.,"");
  

  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);
  histname="hInvMass";
  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);
  
  
  histname="hDPhiTracksAtVtx";
  h_DPhiTracksAtVtx_[1][0] =iBooker.book1D(histname+"All", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: all Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);
  h_DPhiTracksAtVtx_[1][1] =iBooker.book1D(histname+"Barrel", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: Barrel Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);
  h_DPhiTracksAtVtx_[1][2] =iBooker.book1D(histname+"Endcap", " Photons:Tracks from conversions: #delta#phi Tracks at vertex: Endcap Ecal",dPhiTracksBin,dPhiTracksMin,dPhiTracksMax);
  
  
  if ( ! isRunCentrally_ ) {
    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="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="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="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="h2_DPhiTracksAtEcalVsR";
    if ( fName_ != "pfPhotonValidator" &&  fName_ != "oldpfPhotonValidator" ) h2_DPhiTracksAtEcalVsR_= iBooker.book2D(histname+"All"," Photons:Tracks from conversions:  #delta#phi at Ecal vs R : all Ecal ",rBin,rMin, rMax, dPhiTracksBin,0.,dPhiTracksMax);
    
    histname="h2_DPhiTracksAtEcalVsEta";
    if ( fName_ != "pfPhotonValidator" &&  fName_ != "oldpfPhotonValidator" ) h2_DPhiTracksAtEcalVsEta_= iBooker.book2D(histname+"All"," Photons:Tracks from conversions:  #delta#phi at Ecal vs #eta : all Ecal ",etaBin2,etaMin, etaMax, dPhiTracksBin,0.,dPhiTracksMax);
    
    
  }
  
  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="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_[1][0]= iBooker.book1D(histname+"All"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: all Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);
  h_DCotTracks_[1][1]= iBooker.book1D(histname+"Barrel"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: Barrel Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);
  h_DCotTracks_[1][2]= iBooker.book1D(histname+"Endcap"," Photons:Tracks from conversions #delta cotg(#Theta) Tracks: Endcap Ecal ",dCotTracksBin,dCotTracksMin,dCotTracksMax);

  
  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="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_[1][0]= iBooker.book1D(histname+"All"," Photons:Tracks from conversions Min Approach Dist Tracks: all Ecal ",dEtaTracksBin,-0.1,0.6);
  h_distMinAppTracks_[1][1]= iBooker.book1D(histname+"Barrel"," Photons:Tracks from conversions Min Approach Dist Tracks: Barrel Ecal ",dEtaTracksBin,-0.1,0.6);
  h_distMinAppTracks_[1][2]= iBooker.book1D(histname+"Endcap"," Photons:Tracks from conversions Min Approach Dist Tracks: Endcap Ecal ",dEtaTracksBin,-0.1,0.6);
  
    // if ( fName_ != "pfPhotonValidator" &&  fName_ != "oldpfPhotonValidator" ) {
  histname="hDPhiTracksAtEcal";
  h_DPhiTracksAtEcal_[1][0]= iBooker.book1D(histname+"All"," Photons:Tracks from conversions:  #delta#phi at Ecal : all Ecal ",dPhiTracksBin,0.,dPhiTracksMax);
  h_DPhiTracksAtEcal_[1][1]= iBooker.book1D(histname+"Barrel"," Photons:Tracks from conversions:  #delta#phi at Ecal : Barrel Ecal ",dPhiTracksBin,0.,dPhiTracksMax);
  h_DPhiTracksAtEcal_[1][2]= iBooker.book1D(histname+"Endcap"," Photons:Tracks from conversions:  #delta#phi at Ecal : Endcap Ecal ",dPhiTracksBin,0.,dPhiTracksMax);
  
  histname="pDPhiTracksAtEcalVsR";
  p_DPhiTracksAtEcalVsR_ = iBooker.bookProfile(histname+"All"," Photons:Tracks from conversions:  #delta#phi at Ecal  vs R ",rBin,rMin, rMax, dPhiTracksBin,0.,dPhiTracksMax,"");
  
  histname="pDPhiTracksAtEcalVsEta";
  p_DPhiTracksAtEcalVsEta_ = iBooker.bookProfile(histname+"All"," Photons:Tracks from conversions:  #delta#phi at Ecal  vs #eta ",etaBin2,etaMin, etaMax,dPhiTracksBin,0.,dPhiTracksMax,"");
  
  
  histname="hDEtaTracksAtEcal";
  h_DEtaTracksAtEcal_[1][0]= iBooker.book1D(histname+"All"," Photons:Tracks from conversions:  #delta#eta at Ecal : all Ecal ",dEtaTracksBin,dEtaTracksMin,dEtaTracksMax);
  h_DEtaTracksAtEcal_[1][1]= iBooker.book1D(histname+"Barrel"," Photons:Tracks from conversions:  #delta#eta at Ecal : Barrel Ecal ",dEtaTracksBin,dEtaTracksMin,dEtaTracksMax);
  h_DEtaTracksAtEcal_[1][2]= iBooker.book1D(histname+"Endcap"," Photons:Tracks from conversions:  #delta#eta at Ecal : Endcap Ecal ",dEtaTracksBin,dEtaTracksMin,dEtaTracksMax);
  
      //  }


  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 ",100, -80., 80., 100, -80., 80.);
  //
  h_convSLVtxRvsZ_[0] =   iBooker.book2D("convSLVtxRvsZAll"," Photon Reco single leg conversion innermost hit  position",zBinForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);
  h_convSLVtxRvsZ_[1] =   iBooker.book2D("convSLVtxRvsZBarrel"," Photon Reco single leg conversion innermost hit position",zBinForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);
  h_convSLVtxRvsZ_[2] =   iBooker.book2D("convSLVtxRvsZEndcap"," Photon Reco single leg conversion innermost hit position",zBin2ForXray, zMinForXray, zMaxForXray, rBinForXray, rMinForXray, rMaxForXray);
  
  if ( ! isRunCentrally_ ) {
    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_convVtxdX_ =   iBooker.book1D("convVtxdX"," Photon Reco conversion vtx dX",100, -20.,20.);
  h_convVtxdY_ =   iBooker.book1D("convVtxdY"," Photon Reco conversion vtx dY",100, -20.,20.);
  h_convVtxdZ_ =   iBooker.book1D("convVtxdZ"," Photon Reco conversion vtx dZ",100, -20.,20.);
  h_convVtxdR_ =   iBooker.book1D("convVtxdR"," Photon Reco conversion vtx dR",100, -20.,20.);
  
  h_convVtxdX_barrel_ =   iBooker.book1D("convVtxdX_barrel"," Photon Reco conversion vtx dX, |eta|<=1.2",100, -20.,20.);
  h_convVtxdY_barrel_ =   iBooker.book1D("convVtxdY_barrel"," Photon Reco conversion vtx dY, |eta|<=1.2 ",100, -20.,20.);
  h_convVtxdZ_barrel_ =   iBooker.book1D("convVtxdZ_barrel"," Photon Reco conversion vtx dZ, |eta|<=1.2,",100, -20.,20.);
  h_convVtxdR_barrel_ =   iBooker.book1D("convVtxdR_barrel"," Photon Reco conversion vtx dR, |eta|<=1.2",100, -20.,20.);
  h_convVtxdX_endcap_ =   iBooker.book1D("convVtxdX_endcap"," Photon Reco conversion vtx dX,  |eta|>1.2",100, -20.,20.);
  h_convVtxdY_endcap_ =   iBooker.book1D("convVtxdY_endcap"," Photon Reco conversion vtx dY,  |eta|>1.2",100, -20.,20.);
  h_convVtxdZ_endcap_ =   iBooker.book1D("convVtxdZ_endcap"," 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, -20.,20.);
  
  
  h_convVtxdPhi_ =   iBooker.book1D("convVtxdPhi"," Photon Reco conversion vtx dPhi",100, -0.005,0.005);
  h_convVtxdEta_ =   iBooker.book1D("convVtxdEta"," Photon Reco conversion vtx dEta",100, -0.5,0.5);
  
  if ( ! isRunCentrally_ ) {
    h2_convVtxdRVsR_ =  iBooker.book2D("h2ConvVtxdRVsR","Photon Reco conversion vtx dR vsR" ,rBin,rMin, rMax,100, -20.,20.);
    h2_convVtxdRVsEta_ =  iBooker.book2D("h2ConvVtxdRVsEta","Photon Reco conversion vtx dR vs Eta" ,etaBin2,etaMin, etaMax,100, -20.,20.);
  }
  
  p_convVtxdRVsR_ =  iBooker.bookProfile("pConvVtxdRVsR","Photon Reco conversion vtx dR vsR" ,rBin,rMin, rMax ,100, -20.,20., "");
  p_convVtxdRVsEta_ =  iBooker.bookProfile("pConvVtxdRVsEta","Photon Reco 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., "");


  if ( ! isRunCentrally_ ) {
    h2_convVtxRrecVsTrue_ =  iBooker.book2D("h2ConvVtxRrecVsTrue","Photon Reco conversion vtx R rec vs true" ,rBin,rMin, rMax,rBin,rMin, rMax);
  }
  
  histname="vtxChi2";
  h_vtxChi2_[0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 100, chi2Min, chi2Max);
  h_vtxChi2_[1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 100, chi2Min, chi2Max);
  h_vtxChi2_[2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 100, chi2Min, chi2Max);
  histname="vtxChi2Prob";
  h_vtxChi2Prob_[0] = iBooker.book1D(histname+"All","vertex #chi^{2} all", 100, 0., 1.);
  h_vtxChi2Prob_[1] = iBooker.book1D(histname+"Barrel","vertex #chi^{2} barrel", 100, 0., 1.);
  h_vtxChi2Prob_[2] = iBooker.book1D(histname+"Endcap","vertex #chi^{2} endcap", 100, 0., 1.);
  
  histname="zPVFromTracks";
  h_zPVFromTracks_[0] =  iBooker.book1D(histname+"All"," Photons: PV z from conversion tracks",   100, -30., 30.);
  h_zPVFromTracks_[1] =  iBooker.book1D(histname+"Barrel"," Photons: PV z from conversion tracks",100, -30., 30.);
  h_zPVFromTracks_[2] =  iBooker.book1D(histname+"Endcap"," Photons: PV z from conversion tracks",100, -30., 30.);
  h_zPVFromTracks_[3] =  iBooker.book1D(histname+"EndcapP"," Photons: PV z from conversion tracks",100, -30., 30.);
  h_zPVFromTracks_[4] =  iBooker.book1D(histname+"EndcapM"," Photons: PV z from conversion tracks",100, -30., 30.);
  histname="dzPVFromTracks";
  h_dzPVFromTracks_[0] =  iBooker.book1D(histname+"All"," Photons: PV Z_rec - Z_true from conversion tracks",   100, -10., 10.);
  h_dzPVFromTracks_[1] =  iBooker.book1D(histname+"Barrel"," Photons: PV Z_rec - Z_true from conversion tracks",100, -10., 10.);
  h_dzPVFromTracks_[2] =  iBooker.book1D(histname+"Endcap"," Photons: PV Z_rec - Z_true from conversion tracks",100, -10., 10.);
  h_dzPVFromTracks_[3] =  iBooker.book1D(histname+"EndcapP"," Photons: PV Z_rec - Z_true from conversion tracks",100, -10., 10.);
  h_dzPVFromTracks_[4] =  iBooker.book1D(histname+"EndcapM"," Photons: PV Z_rec - Z_true from conversion tracks",100, -10., 10.);
  p_dzPVVsR_ =  iBooker.bookProfile("pdzPVVsR","Photon Reco conversions: dz(PV) vs R" ,rBin,rMin, rMax, 100, -3.,3.,"");
  p_dzPVVsEta_ =  iBooker.bookProfile("pdzPVVsEta","Photon Reco conversions: dz(PV) vs Eta" ,etaBin,etaMin, etaMax, 100, -3.,3.,"");
  
  if ( ! isRunCentrally_ ) {
    h2_dzPVVsR_ =  iBooker.book2D("h2dzPVVsR","Photon Reco conversions: dz(PV) vs R" ,rBin,rMin, rMax,100, -3.,3.);
  }
  
  if ( ! isRunCentrally_ ) {
    histname="nHitsVsEta";
    nHitsVsEta_[0] =  iBooker.book2D(histname+"AllTracks","Photons:Tracks from conversions: # of hits vs #eta all tracks",etaBin,etaMin, etaMax,25,0., 25.);
    
    histname="nHitsVsEta";
    nHitsVsEta_[1] =  iBooker.book2D(histname+"AssTracks","Photons:Tracks from conversions: # of hits vs #eta associated tracks",etaBin,etaMin, etaMax,25,0., 25.);
    
    histname="nHitsVsR";
    nHitsVsR_[0] =  iBooker.book2D(histname+"AllTracks","Photons:Tracks from conversions: # of hits vs radius all tracks" ,rBin,rMin, rMax,25,0.,25);
    
    histname="nHitsVsR";
    nHitsVsR_[1] =  iBooker.book2D(histname+"AssTracks","Photons:Tracks from conversions: # of hits vs radius associated tracks" ,rBin,rMin, rMax,25,0.,25);
    
    histname="h2Chi2VsEta";
    h2_Chi2VsEta_[0]=iBooker.book2D(histname+"All"," 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);
  }
  
  histname="h_nHitsVsEta";
  p_nHitsVsEta_[0] =  iBooker.bookProfile(histname+"AllTracks","Photons:Tracks from conversions: # of hits vs #eta all tracks",etaBin,etaMin, etaMax, 25,-0.5, 24.5,"");
  
  histname="h_nHitsVsEta";
  p_nHitsVsEta_[1] =  iBooker.bookProfile(histname+"AssTracks","Photons:Tracks from conversions: # of hits vs #eta associated tracks",etaBin,etaMin, etaMax, 25,-0.5, 24.5,"");
  
  histname="p_nHitsVsEtaSL";
  p_nHitsVsEtaSL_[0] =  iBooker.bookProfile(histname+"AllTracks","Photons:Tracks from single leg conversions: # of hits vs #eta all tracks",etaBin,etaMin, etaMax, 25,-0.5, 24.5,"");
  
  
  histname="h_nHitsVsR";
  p_nHitsVsR_[0] =  iBooker.bookProfile(histname+"AllTracks","Photons:Tracks from conversions: # of hits vs radius all tracks",rBin,rMin, rMax, 25,-0.5, 24.5,"");
  histname="p_nHitsVsRSL";
  p_nHitsVsRSL_[0] =  iBooker.bookProfile(histname+"AllTracks","Photons:Tracks from single leg conversions: # of hits vs radius all tracks",rBin,rMin, rMax, 25,-0.5, 24.5,"");
  
  histname="tkChi2";
  h_tkChi2_[0] = iBooker.book1D(histname+"AllTracks","Photons:Tracks from conversions: #chi^{2} of all tracks", 100, chi2Min, chi2Max);
  histname="tkChi2SL";
  h_tkChi2SL_[0] = iBooker.book1D(histname+"AllTracks","Photons:Tracks from single leg conversions: #chi^{2} of associated  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);
  
  
  histname="h_nHitsVsR";
  p_nHitsVsR_[1] =  iBooker.bookProfile(histname+"AssTracks","Photons:Tracks from conversions: # of hits vs radius associated tracks",rBin,rMin, rMax, 25,-0.5, 24.5,"");
  
  histname="tkChi2";
  h_tkChi2_[1] = iBooker.book1D(histname+"AssTracks","Photons:Tracks from conversions: #chi^{2} of associated  tracks", 100, chi2Min, chi2Max);
  histname="tkChi2Large";
  h_tkChi2Large_[1] = iBooker.book1D(histname+"AssTracks","Photons:Tracks from conversions: #chi^{2} of associated  tracks", 1000, 0., 5000.0);
  
  histname="pChi2VsEta";
  p_Chi2VsEta_[0]=iBooker.bookProfile(histname+"All"," Reco Track #chi^{2} vs #eta : All ",etaBin2,etaMin, etaMax, 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,"");
  
  
  histname="hTkD0";
  h_TkD0_[0]=iBooker.book1D(histname+"All"," Reco Track D0*q: All ",100,-0.1,0.6);
  h_TkD0_[1]=iBooker.book1D(histname+"Barrel"," Reco Track D0*q: Barrel ",100,-0.1,0.6);
  h_TkD0_[2]=iBooker.book1D(histname+"Endcap"," Reco Track D0*q: Endcap ",100,-0.1,0.6);
  
  
  histname="hTkPtPull";
  h_TkPtPull_[0]=iBooker.book1D(histname+"All"," Reco Track Pt pull: All ",100, -10., 10.);
  histname="hTkPtPull";
  h_TkPtPull_[1]=iBooker.book1D(histname+"Barrel"," Reco Track Pt pull: Barrel ",100, -10., 10.);
  histname="hTkPtPull";
  h_TkPtPull_[2]=iBooker.book1D(histname+"Endcap"," Reco Track Pt pull: Endcap ",100, -10., 10.);
  
  histname="pTkPtPullEta";
  p_TkPtPull_[0]=iBooker.bookProfile(histname+"All"," Reco Track Pt pull: All ",etaBin2,etaMin, etaMax, 100, -10., 10., " ");
  
  if ( ! isRunCentrally_ ) {
    histname="h2TkPtPullEta";
    h2_TkPtPull_[0]=iBooker.book2D(histname+"All"," Reco Track Pt pull: All ",etaBin2,etaMin, etaMax,100, -10., 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="PtRecVsPtSimMixProv";
    h2_PtRecVsPtSimMixProv_ =iBooker.book2D(histname+"All", "Pt Rec vs Pt sim All for mix with general tracks ", etBin,etMin,etMax,etBin,etMin, etMax);
  }
  
  // if ( fName_ != "pfPhotonValidator" &&  fName_ != "oldpfPhotonValidator" ) {
  histname="eBcOverTkPout";
  hBCEnergyOverTrackPout_[0] = iBooker.book1D(histname+"All","Matrching BC E/P_out: all Ecal ",100, 0., 5.);
  hBCEnergyOverTrackPout_[1] = iBooker.book1D(histname+"Barrel","Matrching BC E/P_out: Barrel ",100, 0., 5.);
  hBCEnergyOverTrackPout_[2] = iBooker.book1D(histname+"Endcap","Matrching BC E/P_out: Endcap ",100, 0., 5.);
  // }
  
  h_OIinnermostHitR_ = iBooker.book1D("OIinnermostHitR"," R innermost hit for OI tracks ",50, 0., 25);
  h_IOinnermostHitR_ = iBooker.book1D("IOinnermostHitR"," R innermost hit for IO tracks ",50, 0., 25);
  
  h_trkProv_[0] = iBooker.book1D("allTrkProv"," Track pair provenance ",4, 0., 4.);
  h_trkProv_[1] = iBooker.book1D("assTrkProv"," Track pair provenance ",4, 0., 4.);
  //
  h_trkAlgo_ = iBooker.book1D("allTrackAlgo"," Track Algo ", reco::TrackBase::algoSize, -0.5, reco::TrackBase::algoSize-0.5);
  h_convAlgo_ = iBooker.book1D("allConvAlgo"," Conv Algo ",5, -0.5, 4.5);
  h_convQuality_ = iBooker.book1D("allConvQuality","Conv quality ",11,-0.5,11.);
  
  
  // histos for fake rate
  histname = "h_RecoConvTwoTracksEta";
  h_RecoConvTwoTracks_[0] =  iBooker.book1D(histname," All reco conversions with 2 reco  tracks: simulated #eta",etaBin2,etaMin, etaMax);
  histname = "h_RecoConvTwoTracksPhi";
  h_RecoConvTwoTracks_[1] =  iBooker.book1D(histname," All reco conversions with 2 reco tracks: simulated #phi",phiBin,phiMin, phiMax);
  histname = "h_RecoConvTwoTracksR";
  h_RecoConvTwoTracks_[2] =  iBooker.book1D(histname," All reco conversions with 2 reco tracks: simulated R",rBin,rMin, rMax);
  histname = "h_RecoConvTwoTracksZ";
  h_RecoConvTwoTracks_[3] =  iBooker.book1D(histname," All reco conversions with 2 reco tracks: simulated Z",zBin,zMin, zMax);
  histname = "h_RecoConvTwoTracksEt";
  h_RecoConvTwoTracks_[4] =  iBooker.book1D(histname," All reco conversions with 2 reco tracks: simulated Et",etBin,etMin, etMax);
  //
  histname = "h_RecoConvTwoMTracksEta";
  h_RecoConvTwoMTracks_[0] =  iBooker.book1D(histname," All reco conversions with 2 reco-ass tracks: simulated #eta",etaBin2,etaMin, etaMax);
  histname = "h_RecoConvTwoMTracksPhi";
  h_RecoConvTwoMTracks_[1] =  iBooker.book1D(histname," All reco conversions with 2 reco-ass tracks: simulated #phi",phiBin,phiMin, phiMax);
  histname = "h_RecoConvTwoMTracksR";
  h_RecoConvTwoMTracks_[2] =  iBooker.book1D(histname," All reco conversions with 2 reco-ass tracks: simulated R",rBin,rMin, rMax);
  histname = "h_RecoConvTwoMTracksZ";
  h_RecoConvTwoMTracks_[3] =  iBooker.book1D(histname," All reco conversions with 2 reco-ass tracks: simulated Z",zBin,zMin, zMax);
  histname = "h_RecoConvTwoMTracksEt";
  h_RecoConvTwoMTracks_[4] =  iBooker.book1D(histname," All reco conversions with 2 reco-ass tracks: simulated Et",etBin,etMin, etMax);

}

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

overridevirtual

Reimplemented from DQMEDAnalyzer.

Definition at line 1613 of file PhotonValidator.cc.

References edm::EventSetup::get().

                                                                                         {


  //get magnetic field
  edm::LogInfo("ConvertedPhotonProducer") << " get magnetic field" << "\n";
  theEventSetup.get<IdealMagneticFieldRecord>().get(theMF_);


  thePhotonMCTruthFinder_.reset(new PhotonMCTruthFinder() );

}

void PhotonValidator::endRun ( edm::Run const &  r, edm::EventSetup const &  es  )

overridevirtual

Reimplemented from edm::stream::EDAnalyzerBase.

Definition at line 1625 of file PhotonValidator.cc.

                                                                                   {

  thePhotonMCTruthFinder_.reset();
}

float PhotonValidator::etaTransformation ( float  a, float  b  )

private

Definition at line 3775 of file PhotonValidator.cc.

References ETA, etaBarrelEndcap, create_public_lumi_plots::log, PI, R_ECAL, funct::tan(), and Z_Endcap.

                                                                             {

  //---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
}

float PhotonValidator::phiNormalization ( float &  a )

private

Definition at line 3760 of file PhotonValidator.cc.

References PI, and TWOPI.

{
  //---Definitions
  const float PI    = 3.1415927;
  const float TWOPI = 2.0*PI;


  if(phi >  PI) {phi = phi - TWOPI;}
  if(phi < -PI) {phi = phi + TWOPI;}

  return phi;

}

Member Data Documentation

edm::EDGetTokenT<EcalRecHitCollection> PhotonValidator::barrelEcalHits_

private

Definition at line 114 of file PhotonValidator.h.

edm::InputTag PhotonValidator::bcBarrelCollection_

private

Definition at line 110 of file PhotonValidator.h.

edm::InputTag PhotonValidator::bcEndcapCollection_

private

Definition at line 111 of file PhotonValidator.h.

double PhotonValidator::bcEtLow_

private

Definition at line 147 of file PhotonValidator.h.

edm::EDGetTokenT<edm::View<reco::Track> > PhotonValidator::conversionIOTrackPr_Token_

private

Definition at line 124 of file PhotonValidator.h.

edm::InputTag PhotonValidator::conversionIOTrackProducer_

private

Definition at line 121 of file PhotonValidator.h.

edm::EDGetTokenT<edm::View<reco::Track> > PhotonValidator::conversionOITrackPr_Token_

private

Definition at line 123 of file PhotonValidator.h.

edm::InputTag PhotonValidator::conversionOITrackProducer_

private

Definition at line 120 of file PhotonValidator.h.

double PhotonValidator::convTrackMinPtCut_

private

Definition at line 140 of file PhotonValidator.h.

bool PhotonValidator::dCotCutOn_

private

Definition at line 155 of file PhotonValidator.h.

double PhotonValidator::dCotCutValue_

private

Definition at line 156 of file PhotonValidator.h.

double PhotonValidator::dCotHardCutValue_

private

Definition at line 157 of file PhotonValidator.h.

double PhotonValidator::ecalEtSumCut_

private

Definition at line 153 of file PhotonValidator.h.

double PhotonValidator::ecalIsolRadius_

private

Definition at line 146 of file PhotonValidator.h.

edm::EDGetTokenT<EcalRecHitCollection> PhotonValidator::endcapEcalHits_

private

Definition at line 115 of file PhotonValidator.h.

edm::EDGetTokenT<edm::SimTrackContainer> PhotonValidator::famos_simTk_Token_

private

Definition at line 128 of file PhotonValidator.h.

edm::EDGetTokenT<edm::SimVertexContainer> PhotonValidator::famos_simVtx_Token_

private

Definition at line 129 of file PhotonValidator.h.

bool PhotonValidator::fastSim_

private

Definition at line 135 of file PhotonValidator.h.

std::string PhotonValidator::fName_

private

Definition at line 83 of file PhotonValidator.h.

edm::EDGetTokenT<edm::SimTrackContainer> PhotonValidator::g4_simTk_Token_

private

Definition at line 126 of file PhotonValidator.h.

edm::EDGetTokenT<edm::SimVertexContainer> PhotonValidator::g4_simVtx_Token_

private

Definition at line 127 of file PhotonValidator.h.

edm::EDGetTokenT<reco::GenJetCollection> PhotonValidator::genjets_Token_

private

Definition at line 131 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_Chi2VsEta_[3]

private

Definition at line 497 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_Chi2VsR_[3]

private

Definition at line 499 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_convVtxdRVsEta_

private

Definition at line 467 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_convVtxdRVsR_

private

Definition at line 465 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_convVtxRrecVsTrue_

private

Definition at line 473 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_DCotTracksVsEta_

private

Definition at line 420 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_DCotTracksVsR_

private

Definition at line 422 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_DPhiTracksAtEcalVsEta_

private

Definition at line 432 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_DPhiTracksAtEcalVsR_

private

Definition at line 430 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_DPhiTracksAtVtxVsEta_

private

Definition at line 414 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_DPhiTracksAtVtxVsR_

private

Definition at line 416 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_dzPVVsR_

private

Definition at line 482 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_ecalRecHitSumEtConeDR04VsEt_[3]

private

Definition at line 291 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_ecalRecHitSumEtConeDR04VsEta_[3]

private

Definition at line 289 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_ecalRecHitSumEtConeDR04VsEtaBkg_

private

Definition at line 565 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_ecalRecHitSumEtConeDR04VsEtBkg_[3]

private

Definition at line 567 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_EoverEtrueVsEoverP_[3]

private

Definition at line 396 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_EoverEtrueVsEta_[3]

private

Definition at line 404 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_EoverEtrueVsR_[3]

private

Definition at line 406 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_EoverPVsEta_[3]

private

Definition at line 399 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_EoverPVsR_[3]

private

Definition at line 401 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_eResVsEt_[3][3]

private

Definition at line 330 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_eResVsEta_[3]

private

Definition at line 327 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_eResVsR9_[3]

private

Definition at line 337 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_etaVsRreco_[3]

private

Definition at line 394 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_etaVsRsim_[3]

private

Definition at line 393 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_hcalTowerSumEtConeDR04VsEt_[3]

private

Definition at line 297 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_hcalTowerSumEtConeDR04VsEta_[3]

private

Definition at line 295 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_hcalTowerSumEtConeDR04VsEtaBkg_

private

Definition at line 572 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_hcalTowerSumEtConeDR04VsEtBkg_[3]

private

Definition at line 574 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_hOverEVsEt_[3]

private

Definition at line 276 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_hOverEVsEta_[3]

private

Definition at line 274 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_hOverEVsEtaBkg_

private

Definition at line 558 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_hOverEVsEtBkg_

private

Definition at line 559 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_isoTrkSolidConeDR04VsEt_[3]

private

Definition at line 307 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_isoTrkSolidConeDR04VsEta_[3]

private

Definition at line 305 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_isoTrkSolidConeDR04VsEtaBkg_

private

Definition at line 578 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_isoTrkSolidConeDR04VsEtBkg_[3]

private

Definition at line 580 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_nTrkSolidConeDR04VsEt_[3]

private

Definition at line 313 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_nTrkSolidConeDR04VsEta_[3]

private

Definition at line 311 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_nTrkSolidConeDR04VsEtaBkg_

private

Definition at line 584 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_nTrkSolidConeDR04VsEtBkg_[3]

private

Definition at line 586 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_PoverPtrueVsEoverP_[3]

private

Definition at line 397 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_PoverPtrueVsEta_[3]

private

Definition at line 410 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_PtRecVsPtSim_[3]

private

Definition at line 507 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_PtRecVsPtSimMixProv_

private

Definition at line 508 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_r1VsEt_[3]

private

Definition at line 258 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_r1VsEta_[3]

private

Definition at line 256 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_r1VsEtaBkg_

private

Definition at line 541 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_r1VsEtBkg_

private

Definition at line 542 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_r2VsEt_[3]

private

Definition at line 264 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_r2VsEta_[3]

private

Definition at line 262 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_r2VsEtaBkg_

private

Definition at line 546 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_r2VsEtBkg_

private

Definition at line 547 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_r9VsEt_[3]

private

Definition at line 252 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_r9VsEtaBkg_

private

Definition at line 538 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_r9VsEtBkg_

private

Definition at line 539 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_sceResVsR9_[3]

private

Definition at line 339 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_sigmaIetaIetaVsEt_[3]

private

Definition at line 270 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_sigmaIetaIetaVsEta_[3]

private

Definition at line 268 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_sigmaIetaIetaVsEtaBkg_

private

Definition at line 552 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_sigmaIetaIetaVsEtBkg_[3]

private

Definition at line 554 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h2_TkPtPull_[3]

private

Definition at line 505 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_AllSimConv_[5]

private

Definition at line 201 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_chHadIso_[3]

private

Definition at line 354 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convAlgo_

private

Definition at line 228 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convERes_[2][3]

private

Definition at line 380 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convEta_[3]

private

Definition at line 378 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convEtaBkg_

private

Definition at line 589 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convPhi_[2]

private

Definition at line 379 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convPhiBkg_

private

Definition at line 590 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convPtRes_[2][3]

private

Definition at line 383 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convQuality_

private

Definition at line 229 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convSLVtxRvsZ_[3]

private

Definition at line 444 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdEta_

private

Definition at line 461 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdPhi_

private

Definition at line 462 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdR_

private

Definition at line 449 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdR_barrel_

private

Definition at line 454 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdR_endcap_

private

Definition at line 459 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdX_

private

Definition at line 446 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdX_barrel_

private

Definition at line 451 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdX_endcap_

private

Definition at line 456 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdY_

private

Definition at line 447 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdY_barrel_

private

Definition at line 452 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdY_endcap_

private

Definition at line 457 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdZ_

private

Definition at line 448 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdZ_barrel_

private

Definition at line 453 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxdZ_endcap_

private

Definition at line 458 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxRvsZ_[3]

private

Definition at line 440 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxRvsZ_zoom_[2]

private

Definition at line 442 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxRvsZBkg_[2]

private

Definition at line 599 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxYvsX_

private

Definition at line 441 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxYvsX_zoom_[2]

private

Definition at line 443 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_convVtxYvsXBkg_

private

Definition at line 598 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_DCotTracks_[2][3]

private

Definition at line 419 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_DCotTracksBkg_[3]

private

Definition at line 597 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_DEtaTracksAtEcal_[2][3]

private

Definition at line 436 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_distMinAppTracks_[2][3]

private

Definition at line 425 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_DPhiTracksAtEcal_[2][3]

private

Definition at line 429 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_DPhiTracksAtVtx_[2][3]

private

Definition at line 413 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_DPhiTracksAtVtxBkg_[3]

private

Definition at line 596 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_dRPhoPFcand_ChHad_Cleaned_[3]

private

Definition at line 362 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_dRPhoPFcand_ChHad_unCleaned_[3]

private

Definition at line 365 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_dRPhoPFcand_NeuHad_Cleaned_[3]

private

Definition at line 363 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_dRPhoPFcand_NeuHad_unCleaned_[3]

private

Definition at line 366 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_dRPhoPFcand_Pho_Cleaned_[3]

private

Definition at line 364 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_dRPhoPFcand_Pho_unCleaned_[3]

private

Definition at line 367 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_dzPVFromTracks_[5]

private

Definition at line 481 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_ecalRecHitSumEtConeDR04_[3][3]

private

Definition at line 288 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_ecalRecHitSumEtConeDR04Bkg_[3]

private

Definition at line 564 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_EoverP_SL_[3]

private

Definition at line 390 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_EoverPTracks_[2][3]

private

Definition at line 387 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_EoverPTracksBkg_[3]

private

Definition at line 594 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_etOutsideMustache_[3]

private

Definition at line 359 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_EtR9Less093_[3][3]

private

Definition at line 249 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_gamgamMass_[3][3]

private

Definition at line 317 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_gamgamMassRegr1_[3][3]

private

Definition at line 318 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_gamgamMassRegr2_[3][3]

private

Definition at line 319 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_hcalTowerBcSumEtConeDR04_[3][3]

private

Definition at line 300 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_hcalTowerSumEtConeDR04_[3][3]

private

Definition at line 294 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_hcalTowerSumEtConeDR04Bkg_[3]

private

Definition at line 571 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_hOverE_[3][3]

private

Definition at line 273 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_hOverEBkg_[3]

private

Definition at line 536 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_invMass_[2][3]

private

Definition at line 385 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_IOinnermostHitR_

private

Definition at line 225 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_isoTrkSolidConeDR04_[3][3]

private

Definition at line 304 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_isoTrkSolidConeDR04Bkg_[3]

private

Definition at line 577 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_MatchedSimJet_[3]

private

Definition at line 514 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_MatchedSimJetBadCh_[3]

private

Definition at line 515 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_MatchedSimPho_[3]

private

Numerator for efficiencies.

Definition at line 205 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_MatchedSimPhoBadCh_[3]

private

Definition at line 206 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_mvaOut_[3]

private

Definition at line 392 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_mvaOutBkg_[3]

private

Definition at line 591 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_nCluOutsideMustache_[3]

private

Definition at line 358 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_nConv_[2][3]

private

info per conversion

Definition at line 377 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_newhOverE_[3][3]

private

Definition at line 279 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_nHadIso_[3]

private

Definition at line 355 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_nPho_

private

Definition at line 518 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_nRecoVtx_

private

Definition at line 181 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_nSimConv_[2]

private

Definition at line 189 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_nSimPho_[2]

private

Definition at line 183 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_nTrkSolidConeDR04_[3][3]

private

Definition at line 310 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_nTrkSolidConeDR04Bkg_[3]

private

Definition at line 583 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_OIinnermostHitR_

private

Definition at line 224 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_pfMva_[3]

private

Definition at line 360 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoBkgDEta_

private

Definition at line 524 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoBkgDPhi_

private

Definition at line 525 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoBkgE_[3]

private

Definition at line 526 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoBkgEt_[3]

private

Definition at line 527 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoBkgEta_

private

Definition at line 522 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoBkgPhi_

private

Definition at line 523 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoDEta_[2]

private

Definition at line 232 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoDPhi_[2]

private

Definition at line 233 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoE_[2][3]

private

Definition at line 321 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoERes_[3][3]

private

Definition at line 323 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoEResRegr1_[3][3]

private

Definition at line 346 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoEResRegr2_[3][3]

private

Definition at line 347 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoEt_[2][3]

private

Definition at line 322 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoEta_[2]

private

Definition at line 342 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoIso_[3]

private

Definition at line 356 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoPhi_[2]

private

Definition at line 343 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoPixSeedSize_[2]

private

Definition at line 350 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_phoSigmaEoE_[3][3]

private

Definition at line 324 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_PoverETracks_[2][3]

private

Definition at line 388 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_PoverETracksBkg_[3]

private

Definition at line 595 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_psE_

private

Definition at line 247 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_r1_[3][3]

private

Definition at line 255 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_r1Bkg_[3]

private

Definition at line 534 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_r2_[3][3]

private

Definition at line 261 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_r2Bkg_[3]

private

Definition at line 535 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_r9_[3][3]

private

Definition at line 250 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_r9Bkg_[3]

private

Definition at line 533 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_r9VsNofTracks_[2][3]

private

Definition at line 386 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_RecoConvTwoMTracks_[5]

private

Definition at line 218 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_RecoConvTwoTracks_[5]

private

Definition at line 216 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scBkgE_[3]

private

Definition at line 530 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scBkgEt_[3]

private

Definition at line 531 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scBkgEta_

private

Definition at line 520 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scBkgPhi_

private

Definition at line 521 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scE_[2][3]

private

Definition at line 244 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scEt_[2][3]

private

Definition at line 245 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scEta_[2]

private

Definition at line 237 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scEtaPhi_[2]

private

Definition at line 241 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scEtaWidth_[2]

private

Definition at line 238 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scPhi_[2]

private

Definition at line 239 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scPhiWidth_[2]

private

Definition at line 240 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_sigmaIetaIeta_[3][3]

private

Definition at line 267 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_sigmaIetaIetaBkg_[3]

private

Definition at line 551 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimConvEtaPix_[2]

private

Definition at line 190 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimConvMTotal_[5]

private

Definition at line 211 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimConvOneMTracks_[5]

private

Definition at line 208 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimConvOneTracks_[5]

private

Definition at line 207 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimConvTwoMTracks_[5]

private

Definition at line 210 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimConvTwoMTracksAndVtxPGT0005_[5]

private

Definition at line 213 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimConvTwoMTracksAndVtxPGT01_[5]

private

Definition at line 214 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimConvTwoMTracksAndVtxPGT0_[5]

private

Definition at line 212 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimConvTwoTracks_[5]

private

Definition at line 209 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_simConvVtxRvsZ_[4]

private

Definition at line 195 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_simConvVtxYvsX_

private

Definition at line 196 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimJet_[3]

private

Definition at line 513 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimPho_[3]

private

Denominator for efficiencies.

Definition at line 200 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimPhoEtaSmallR9_

private

Definition at line 187 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimPhoMotherEt_[2]

private

Definition at line 185 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimPhoMotherEta_[2]

private

Definition at line 186 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimPhoMotherType_[2]

private

Definition at line 184 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_simTkEta_

private

Definition at line 193 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_simTkPt_

private

Definition at line 192 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_ChHad_Cleaned_[3]

private

Definition at line 368 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_ChHad_unCleaned_[3]

private

Definition at line 371 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_NeuHad_Cleaned_[3]

private

Definition at line 369 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_NeuHad_unCleaned_[3]

private

Definition at line 372 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_Pho_Cleaned_[3]

private

Definition at line 370 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_Pho_unCleaned_[3]

private

Definition at line 373 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_tkChi2_[2]

private

Definition at line 494 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_tkChi2Bkg_

private

Definition at line 593 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_tkChi2Large_[2]

private

Definition at line 496 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_tkChi2SL_[2]

private

Definition at line 495 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_TkD0_[3]

private

Definition at line 502 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_TkPtPull_[3]

private

Definition at line 504 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_trkAlgo_

private

Definition at line 227 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_trkProv_[2]

private

Definition at line 226 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_VisSimConv_[6]

private

Definition at line 202 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_VisSimConvLarge_

private

Definition at line 203 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_vtxChi2_[3]

private

Definition at line 475 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_vtxChi2Prob_[3]

private

Definition at line 476 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_zPVFromTracks_[5]

private

Definition at line 480 of file PhotonValidator.h.

MonitorElement* PhotonValidator::hBCEnergyOverTrackPout_[3]

private

Definition at line 510 of file PhotonValidator.h.

double PhotonValidator::hcalEtSumCut_

private

Definition at line 154 of file PhotonValidator.h.

double PhotonValidator::hcalHitEtLow_

private

Definition at line 150 of file PhotonValidator.h.

double PhotonValidator::hcalIsolExtRadius_

private

Definition at line 148 of file PhotonValidator.h.

double PhotonValidator::hcalIsolInnRadius_

private

Definition at line 149 of file PhotonValidator.h.

edm::EDGetTokenT<edm::HepMCProduct> PhotonValidator::hepMC_Token_

private

Definition at line 130 of file PhotonValidator.h.

bool PhotonValidator::isRunCentrally_

private

Definition at line 136 of file PhotonValidator.h.

double PhotonValidator::likelihoodCut_

private

Definition at line 141 of file PhotonValidator.h.

double PhotonValidator::lip_

private

Definition at line 145 of file PhotonValidator.h.

double PhotonValidator::mcConvEta_

private

Definition at line 168 of file PhotonValidator.h.

double PhotonValidator::mcConvPhi_

private

Definition at line 167 of file PhotonValidator.h.

double PhotonValidator::mcConvR_

private

Definition at line 163 of file PhotonValidator.h.

double PhotonValidator::mcConvX_

private

Definition at line 166 of file PhotonValidator.h.

double PhotonValidator::mcConvY_

private

Definition at line 165 of file PhotonValidator.h.

double PhotonValidator::mcConvZ_

private

Definition at line 164 of file PhotonValidator.h.

double PhotonValidator::mcEta_

private

Definition at line 162 of file PhotonValidator.h.

double PhotonValidator::mcJetEta_

private

Definition at line 169 of file PhotonValidator.h.

double PhotonValidator::mcJetPhi_

private

Definition at line 170 of file PhotonValidator.h.

double PhotonValidator::mcPhi_

private

global variable for the MC photon

Definition at line 161 of file PhotonValidator.h.

double PhotonValidator::minPhoEtCut_

private

Definition at line 139 of file PhotonValidator.h.

int PhotonValidator::nEntry_

private

Definition at line 88 of file PhotonValidator.h.

int PhotonValidator::nEvt_

private

Definition at line 87 of file PhotonValidator.h.

MonitorElement* PhotonValidator::nHitsVsEta_[2]

private

Definition at line 490 of file PhotonValidator.h.

MonitorElement* PhotonValidator::nHitsVsEtaBkg_

private

Definition at line 592 of file PhotonValidator.h.

MonitorElement* PhotonValidator::nHitsVsR_[2]

private

Definition at line 493 of file PhotonValidator.h.

int PhotonValidator::nInvalidPCA_

private

Definition at line 96 of file PhotonValidator.h.

int PhotonValidator::nMatched_

private

Definition at line 91 of file PhotonValidator.h.

int PhotonValidator::nRecConv_

private

Definition at line 92 of file PhotonValidator.h.

int PhotonValidator::nRecConvAss_

private

Definition at line 93 of file PhotonValidator.h.

int PhotonValidator::nRecConvAssWithEcal_

private

Definition at line 94 of file PhotonValidator.h.

int PhotonValidator::nSimConv_[2]

private

Definition at line 90 of file PhotonValidator.h.

int PhotonValidator::nSimPho_[2]

private

Definition at line 89 of file PhotonValidator.h.

int PhotonValidator::numOfTracksInCone_

private

Definition at line 151 of file PhotonValidator.h.

edm::EDGetTokenT<reco::VertexCollection> PhotonValidator::offline_pvToken_

private

Definition at line 109 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_Chi2VsEta_[3]

private

Definition at line 498 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_Chi2VsR_[3]

private

Definition at line 500 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_convVtxdRVsEta_

private

Definition at line 468 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_convVtxdRVsR_

private

Definition at line 466 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_convVtxdXVsX_

private

Definition at line 469 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_convVtxdYVsY_

private

Definition at line 470 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_convVtxdZVsZ_

private

Definition at line 471 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_DCotTracksVsEta_

private

Definition at line 421 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_DCotTracksVsR_

private

Definition at line 423 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_DPhiTracksAtEcalVsEta_

private

Definition at line 433 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_DPhiTracksAtEcalVsR_

private

Definition at line 431 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_DPhiTracksAtVtxVsEta_

private

Definition at line 415 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_DPhiTracksAtVtxVsR_

private

Definition at line 417 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_dzPVVsEta_

private

Definition at line 484 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_dzPVVsR_

private

Definition at line 483 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_ecalRecHitSumEtConeDR04VsEt_[3]

private

Definition at line 292 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_ecalRecHitSumEtConeDR04VsEta_[3]

private

Definition at line 290 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_ecalRecHitSumEtConeDR04VsEtaBkg_

private

Definition at line 566 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_ecalRecHitSumEtConeDR04VsEtBkg_[3]

private

Definition at line 568 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_EoverEtrueVsEta_[3]

private

Definition at line 405 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_EoverEtrueVsR_[3]

private

Definition at line 407 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_EoverPVsEta_[3]

private

Definition at line 400 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_EoverPVsR_[3]

private

Definition at line 402 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_eResVsEt_[3][3]

private

Definition at line 331 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_eResVsEta_[3]

private

Definition at line 328 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_eResVsNVtx_[3][3]

private

Definition at line 332 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_eResVsR9_[3]

private

Definition at line 338 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_eResVsR_

private

Definition at line 381 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_hcalTowerBcSumEtConeDR04VsEt_[3]

private

Definition at line 302 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_hcalTowerBcSumEtConeDR04VsEta_[3]

private

Definition at line 301 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_hcalTowerSumEtConeDR04VsEt_[3]

private

Definition at line 298 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_hcalTowerSumEtConeDR04VsEta_[3]

private

Definition at line 296 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_hcalTowerSumEtConeDR04VsEtaBkg_

private

Definition at line 573 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_hcalTowerSumEtConeDR04VsEtBkg_[3]

private

Definition at line 575 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_hOverEVsEt_[3]

private

Definition at line 277 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_hOverEVsEta_[3]

private

Definition at line 275 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_hOverEVsEtaBkg_

private

Definition at line 560 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_hOverEVsEtBkg_

private

Definition at line 561 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_isoTrkSolidConeDR04VsEt_[3]

private

Definition at line 308 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_isoTrkSolidConeDR04VsEta_[3]

private

Definition at line 306 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_isoTrkSolidConeDR04VsEtaBkg_

private

Definition at line 579 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_isoTrkSolidConeDR04VsEtBkg_[3]

private

Definition at line 581 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_newhOverEVsEt_[3]

private

Definition at line 281 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_newhOverEVsEta_[3]

private

Definition at line 280 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_nHitsVsEta_[2]

private

Definition at line 488 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_nHitsVsEtaSL_[2]

private

Definition at line 489 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_nHitsVsR_[2]

private

Definition at line 491 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_nHitsVsRSL_[2]

private

Definition at line 492 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_nTrkSolidConeDR04VsEt_[3]

private

Definition at line 314 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_nTrkSolidConeDR04VsEta_[3]

private

Definition at line 312 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_nTrkSolidConeDR04VsEtaBkg_

private

Definition at line 585 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_nTrkSolidConeDR04VsEtBkg_[3]

private

Definition at line 587 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_PoverPtrueVsEta_[3]

private

Definition at line 411 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r1VsEt_[3]

private

Definition at line 259 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r1VsEta_[3]

private

Definition at line 257 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r1VsEtaBkg_

private

Definition at line 543 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r1VsEtBkg_

private

Definition at line 544 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r2VsEt_[3]

private

Definition at line 265 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r2VsEta_[3]

private

Definition at line 263 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r2VsEtaBkg_

private

Definition at line 548 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r2VsEtBkg_

private

Definition at line 549 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r9VsEt_[3]

private

Definition at line 253 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r9VsEta_[3]

private

Definition at line 251 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_sceResVsR9_[3]

private

Definition at line 340 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_sigmaEoEVsEt_[3][3]

private

Definition at line 334 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_sigmaEoEVsEta_[3]

private

Definition at line 329 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_sigmaEoEVsNVtx_[3][3]

private

Definition at line 335 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_sigmaIetaIetaVsEt_[3]

private

Definition at line 271 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_sigmaIetaIetaVsEta_[3]

private

Definition at line 269 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_sigmaIetaIetaVsEtaBkg_

private

Definition at line 553 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_sigmaIetaIetaVsEtBkg_[3]

private

Definition at line 555 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_TkPtPull_[3]

private

Definition at line 506 of file PhotonValidator.h.

edm::ParameterSet PhotonValidator::parameters_

private

Definition at line 98 of file PhotonValidator.h.

Referenced by Mixins._TypedParameterizable::clone(), Types.PSet::clone(), and Mixins._TypedParameterizable::copy().

edm::EDGetTokenT<edm::ValueMap<std::vector<reco::PFCandidateRef> > > PhotonValidator::particleBasedIso_token

private

Definition at line 108 of file PhotonValidator.h.

edm::EDGetTokenT<reco::PFCandidateCollection> PhotonValidator::pfCandidates_

private

Definition at line 106 of file PhotonValidator.h.

std::string PhotonValidator::photonCollection_

private

Definition at line 104 of file PhotonValidator.h.

std::string PhotonValidator::photonCollectionProducer_

private

Definition at line 103 of file PhotonValidator.h.

edm::EDGetTokenT<reco::PhotonCollection> PhotonValidator::photonCollectionToken_

private

Definition at line 105 of file PhotonValidator.h.

double PhotonValidator::recMaxPt_

private

Definition at line 180 of file PhotonValidator.h.

double PhotonValidator::recMinPt_

private

Global variables for reco Photon.

Definition at line 179 of file PhotonValidator.h.

double PhotonValidator::simMaxPt_

private

Definition at line 176 of file PhotonValidator.h.

double PhotonValidator::simMinPt_

private

Definition at line 175 of file PhotonValidator.h.

TH1F* PhotonValidator::th1f_SimConvMTotal_[5]

private

Definition at line 221 of file PhotonValidator.h.

edm::ESHandle<CaloGeometry> PhotonValidator::theCaloGeom_

private

Definition at line 99 of file PhotonValidator.h.

edm::ESHandle<CaloTopology> PhotonValidator::theCaloTopo_

private

Definition at line 100 of file PhotonValidator.h.

edm::RefVector<TrackingParticleCollection> PhotonValidator::theConvTP_

private

Definition at line 172 of file PhotonValidator.h.

edm::ESHandle<MagneticField> PhotonValidator::theMF_

private

Definition at line 84 of file PhotonValidator.h.

std::unique_ptr<PhotonMCTruthFinder> PhotonValidator::thePhotonMCTruthFinder_

private

Definition at line 133 of file PhotonValidator.h.

edm::EDGetTokenT<TrackingParticleCollection> PhotonValidator::token_tp_

private

Definition at line 116 of file PhotonValidator.h.

double PhotonValidator::trkIsolExtRadius_

private

Definition at line 142 of file PhotonValidator.h.

double PhotonValidator::trkIsolInnRadius_

private

Definition at line 143 of file PhotonValidator.h.

double PhotonValidator::trkPtLow_

private

Definition at line 144 of file PhotonValidator.h.

double PhotonValidator::trkPtSumCut_

private

Definition at line 152 of file PhotonValidator.h.

std::string PhotonValidator::valueMapPhoPFCandIso_

private

Definition at line 107 of file PhotonValidator.h.

int PhotonValidator::verbosity_

private

Definition at line 86 of file PhotonValidator.h.