PhotonValidator Class Reference

#include <PhotonValidator.h>

Inheritance diagram for PhotonValidator:

Classes
class	sortPhotons

Public Member Functions
void	analyze (const edm::Event &, const edm::EventSetup &) override
void	bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
void	dqmBeginRun (edm::Run const &r, edm::EventSetup const &theEventSetup) override
void	dqmEndRun (edm::Run const &r, edm::EventSetup const &es) override
	PhotonValidator (const edm::ParameterSet &)
	~PhotonValidator () override
Public Member Functions inherited from DQMOneEDAnalyzer<>
void	accumulate (edm::Event const &event, edm::EventSetup const &setup) override
void	beginRun (edm::Run const &run, edm::EventSetup const &setup) final
	DQMOneEDAnalyzer ()
void	endRun (edm::Run const &, edm::EventSetup const &) final
void	endRunProduce (edm::Run &run, edm::EventSetup const &setup) final
virtual bool	getCanSaveByLumi ()
Public Member Functions inherited from edm::one::EDProducer< edm::EndRunProducer, edm::one::WatchRuns, edm::Accumulator, Args...>
	EDProducer ()=default
	EDProducer (const EDProducer &)=delete
SerialTaskQueue *	globalLuminosityBlocksQueue () final
SerialTaskQueue *	globalRunsQueue () final
bool	hasAbilityToProduceInBeginLumis () const final
bool	hasAbilityToProduceInBeginProcessBlocks () const final
bool	hasAbilityToProduceInBeginRuns () const final
bool	hasAbilityToProduceInEndLumis () const final
bool	hasAbilityToProduceInEndProcessBlocks () const final
bool	hasAbilityToProduceInEndRuns () const final
const EDProducer &	operator= (const EDProducer &)=delete
bool	wantsGlobalLuminosityBlocks () const final
bool	wantsGlobalRuns () const final
bool	wantsInputProcessBlocks () const final
bool	wantsProcessBlocks () const final
Public Member Functions inherited from edm::one::EDProducerBase
	EDProducerBase ()
ModuleDescription const &	moduleDescription () const
bool	wantsStreamLuminosityBlocks () const
bool	wantsStreamRuns () const
	~EDProducerBase () override
Public Member Functions inherited from edm::ProducerBase
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)
std::vector < edm::ProductResolverIndex > const &	indiciesForPutProducts (BranchType iBranchType) const
	ProducerBase ()
std::vector < edm::ProductResolverIndex > const &	putTokenIndexToProductResolverIndex () const
void	registerProducts (ProducerBase *, ProductRegistry *, ModuleDescription const &)
std::function< void(BranchDescription const &)>	registrationCallback () const
	used by the fwk to register list of products More...
void	resolvePutIndicies (BranchType iBranchType, ModuleToResolverIndicies const &iIndicies, std::string const &moduleLabel)
	~ProducerBase () noexcept(false) override
Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfo >	consumesInfo () const
void	convertCurrentProcessAlias (std::string const &processName)
	Convert "@currentProcess" in InputTag process names to the actual current process name. More...
	EDConsumerBase ()
	EDConsumerBase (EDConsumerBase const &)=delete
	EDConsumerBase (EDConsumerBase &&)=default
ESProxyIndex const *	esGetTokenIndices (edm::Transition iTrans) const
std::vector< ESProxyIndex > const &	esGetTokenIndicesVector (edm::Transition iTrans) const
std::vector< ESRecordIndex > const &	esGetTokenRecordIndicesVector (edm::Transition iTrans) const
ProductResolverIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const
void	itemsMayGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
void	itemsToGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
std::vector < ProductResolverIndexAndSkipBit > const &	itemsToGetFrom (BranchType iType) const
void	labelsForToken (EDGetToken iToken, Labels &oLabels) const
void	modulesWhoseProductsAreConsumed (std::array< std::vector< ModuleDescription const * > *, NumBranchTypes > &modulesAll, std::vector< ModuleProcessName > &modulesInPreviousProcesses, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const
EDConsumerBase const &	operator= (EDConsumerBase const &)=delete
EDConsumerBase &	operator= (EDConsumerBase &&)=default
bool	registeredToConsume (ProductResolverIndex, bool, BranchType) const
bool	registeredToConsumeMany (TypeID const &, BranchType) const
void	selectInputProcessBlocks (ProductRegistry const &productRegistry, ProcessBlockHelperBase const &processBlockHelperBase)
ProductResolverIndexAndSkipBit	uncheckedIndexFrom (EDGetToken) const
void	updateLookup (BranchType iBranchType, ProductResolverIndexHelper const &, bool iPrefetchMayGet)
void	updateLookup (eventsetup::ESRecordsToProxyIndices const &)
virtual	~EDConsumerBase () noexcept(false)

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_
const edm::ESGetToken < CaloGeometry, CaloGeometryRecord >	caloGeometryToken_
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_
edm::EDGetTokenT < reco::GenParticleCollection >	genpartToken_
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_chHadIso_miniAOD_ [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_ecalRecHitSumEtConeDR04_miniAOD_ [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_full5x5_r9_miniAOD_ [3][3]
MonitorElement *	h_full5x5_sigmaIetaIeta_miniAOD_ [3][3]
MonitorElement *	h_gamgamMass_ [3][3]
MonitorElement *	h_gamgamMassRegr1_ [3][3]
MonitorElement *	h_gamgamMassRegr2_ [3][3]
MonitorElement *	h_hcalTowerBcSumEtConeDR04_ [3][3]
MonitorElement *	h_hcalTowerBcSumEtConeDR04_miniAOD_ [3][3]
MonitorElement *	h_hcalTowerSumEtConeDR04_ [3][3]
MonitorElement *	h_hcalTowerSumEtConeDR04_miniAOD_ [3][3]
MonitorElement *	h_hcalTowerSumEtConeDR04Bkg_ [3]
MonitorElement *	h_hOverE_ [3][3]
MonitorElement *	h_hOverE_miniAOD_ [3][3]
MonitorElement *	h_hOverEBkg_ [3]
MonitorElement *	h_invMass_ [2][3]
MonitorElement *	h_IOinnermostHitR_
MonitorElement *	h_isoTrkSolidConeDR04_ [3][3]
MonitorElement *	h_isoTrkSolidConeDR04_miniAOD_ [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_newhOverE_miniAOD_ [3][3]
MonitorElement *	h_nHadIso_ [3]
MonitorElement *	h_nHadIso_miniAOD_ [3]
MonitorElement *	h_nPho_
MonitorElement *	h_nRecoVtx_
MonitorElement *	h_nSimConv_ [2]
MonitorElement *	h_nSimPho_ [2]
MonitorElement *	h_nTrkSolidConeDR04_ [3][3]
MonitorElement *	h_nTrkSolidConeDR04_miniAOD_ [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_phoE_miniAOD_ [2][3]
MonitorElement *	h_phoERes_ [3][3]
MonitorElement *	h_phoERes_miniAOD_ [3][3]
MonitorElement *	h_phoEResRegr1_ [3][3]
MonitorElement *	h_phoEResRegr2_ [3][3]
MonitorElement *	h_phoEt_ [2][3]
MonitorElement *	h_phoEt_miniAOD_ [2][3]
MonitorElement *	h_phoEta_ [2]
MonitorElement *	h_phoIso_ [3]
MonitorElement *	h_phoIso_miniAOD_ [3]
MonitorElement *	h_phoPhi_ [2]
MonitorElement *	h_phoPixSeedSize_ [2]
MonitorElement *	h_phoSigmaEoE_ [3][3]
MonitorElement *	h_phoSigmaEoE_miniAOD_ [3][3]
MonitorElement *	h_PoverETracks_ [2][3]
MonitorElement *	h_PoverETracksBkg_ [3]
MonitorElement *	h_psE_
MonitorElement *	h_r1_ [3][3]
MonitorElement *	h_r1_miniAOD_ [3][3]
MonitorElement *	h_r1Bkg_ [3]
MonitorElement *	h_r2_ [3][3]
MonitorElement *	h_r2_miniAOD_ [3][3]
MonitorElement *	h_r2Bkg_ [3]
MonitorElement *	h_r9_ [3][3]
MonitorElement *	h_r9_miniAOD_ [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_scEta_miniAOD_ [2]
	Histos for comparison with miniAOD content. More...
MonitorElement *	h_scEtaPhi_ [2]
MonitorElement *	h_scEtaWidth_ [2]
MonitorElement *	h_scPhi_ [2]
MonitorElement *	h_scPhi_miniAOD_ [2]
MonitorElement *	h_scPhiWidth_ [2]
MonitorElement *	h_sigmaIetaIeta_ [3][3]
MonitorElement *	h_sigmaIetaIeta_miniAOD_ [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_
const edm::ESGetToken < MagneticField, IdealMagneticFieldRecord >	magneticFieldToken_
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_
const edm::ESGetToken < TransientTrackBuilder, TransientTrackRecord >	transientTrackBuilderToken_
double	trkIsolExtRadius_
double	trkIsolInnRadius_
double	trkPtLow_
double	trkPtSumCut_
std::string	valueMapPhoPFCandIso_
int	verbosity_

Additional Inherited Members
Public Types inherited from DQMOneEDAnalyzer<>
typedef dqm::reco::DQMStore	DQMStore
typedef dqm::reco::MonitorElement	MonitorElement
Public Types inherited from edm::one::EDProducerBase
typedef EDProducerBase	ModuleType
Public Types inherited from edm::ProducerBase
using	ModuleToResolverIndicies = std::unordered_multimap< std::string, std::tuple< edm::TypeID const *, const char *, edm::ProductResolverIndex >>
typedef ProductRegistryHelper::TypeLabelList	TypeLabelList
Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels
Static Public Member Functions inherited from edm::one::EDProducerBase
static const std::string &	baseType ()
static void	fillDescriptions (ConfigurationDescriptions &descriptions)
static void	prevalidate (ConfigurationDescriptions &descriptions)
Protected Member Functions inherited from edm::ProducerBase
ProducesCollector	producesCollector ()
Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)
template<BranchType B = InEvent>
EDConsumerBaseAdaptor< B >	consumes (edm::InputTag tag) noexcept
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 ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto	esConsumes ()
template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag const &tag)
template<Transition Tr = Transition::Event>
constexpr auto	esConsumes () noexcept
template<Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag tag) noexcept
template<Transition Tr = Transition::Event>
ESGetTokenGeneric	esConsumes (eventsetup::EventSetupRecordKey const &iRecord, eventsetup::DataKey const &iKey)
	Used with EventSetupRecord::doGet. More...
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)
void	resetItemsToGetFrom (BranchType iType)
Protected Attributes inherited from DQMOneEDAnalyzer<>
edm::EDPutTokenT< DQMToken >	runToken_

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 83 of file PhotonValidator.cc.

References barrelEcalHits_, bcEtLow_, caloGeometryToken_, conversionIOTrackPr_Token_, conversionIOTrackProducer_, conversionOITrackPr_Token_, conversionOITrackProducer_, convTrackMinPtCut_, dCotCutOn_, dCotCutValue_, dCotHardCutValue_, ecalEtSumCut_, ecalIsolRadius_, endcapEcalHits_, edm::EDConsumerBase::esConsumes(), famos_simTk_Token_, famos_simVtx_Token_, fastSim_, fName_, g4_simTk_Token_, g4_simVtx_Token_, genjets_Token_, genpartToken_, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), hcalEtSumCut_, hcalHitEtLow_, hcalIsolExtRadius_, hcalIsolInnRadius_, hepMC_Token_, HLT_FULL_cff::InputTag, isRunCentrally_, likelihoodCut_, lip_, minPhoEtCut_, nEntry_, nEvt_, nInvalidPCA_, nRecConv_, nRecConvAss_, nRecConvAssWithEcal_, numOfTracksInCone_, offline_pvToken_, parameters_, particleBasedIso_token, pfCandidates_, photonCollection_, photonCollectionProducer_, photonCollectionToken_, TrackValidation_cff::pset, AlCaHLTBitMon_QueryRunRegistry::string, token_tp_, transientTrackBuilderToken_, trkIsolExtRadius_, trkIsolInnRadius_, trkPtLow_, trkPtSumCut_, valueMapPhoPFCandIso_, and verbosity_.

    : magneticFieldToken_{esConsumes<edm::Transition::BeginRun>()},
      caloGeometryToken_{esConsumes()},
      transientTrackBuilderToken_{esConsumes(edm::ESInputTag("", "TransientTrackBuilder"))} {
  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("fastSimProducer"));
  famos_simVtx_Token_ = consumes<edm::SimVertexContainer>(edm::InputTag("fastSimProducer"));
  hepMC_Token_ = consumes<edm::HepMCProduct>(edm::InputTag("generatorSmeared"));
  genjets_Token_ = consumes<reco::GenJetCollection>(edm::InputTag("ak4GenJets"));

  genpartToken_ = consumes<reco::GenParticleCollection>(edm::InputTag("genParticles"));

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

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

PhotonValidator::~PhotonValidator ( )

override

Definition at line 157 of file PhotonValidator.cc.

{}

Member Function Documentation

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

overridevirtual

uncleaned

Reimplemented from DQMOneEDAnalyzer<>.

Definition at line 3169 of file PhotonValidator.cc.

References funct::abs(), barrelEcalHits_, SplitLinear::begin, edm::RefVector< C, T, F >::begin(), edm::SortedCollection< T, SORT >::begin(), caloGeometryToken_, RecoTauCleanerPlugins::charge, HLT_FULL_cff::chi2, ChiSquaredProbability(), edm::RefVector< C, T, F >::clear(), conversionIOTrackPr_Token_, conversionOITrackPr_Token_, conversions_cfi::conversions, reco::Photon::conversions(), convTrackMinPtCut_, d0, dCotCutOn_, dCotCutValue_, dCotHardCutValue_, CommonMethods::delta(), spr::deltaEta, srCondWrite_cfg::deltaPhi, HLT_FULL_cff::deltaR, reco::PFCandidate::e, reco::Photon::ecalRecHitSumEtConeDR04(), relativeConstraints::empty, edm::RefVector< C, T, F >::end(), edm::SortedCollection< T, SORT >::end(), edm::AssociationMap< Tag >::end(), endcapEcalHits_, reco::LeafCandidate::energy(), reco::LeafCandidate::et(), reco::LeafCandidate::eta(), etaTransformation(), famos_simTk_Token_, famos_simVtx_Token_, fastSim_, dqm::impl::MonitorElement::Fill(), HcalObjRepresent::Fill(), edm::AssociationMap< Tag >::find(), fName_, g4_simTk_Token_, g4_simVtx_Token_, reco::PFCandidate::gamma, genjets_Token_, GenParticle::GenParticle, genParticleCandidates2GenParticles_cfi::genParticles, genpartToken_, edm::RefToBase< T >::get(), edm::Event::getByLabel(), edm::Event::getByToken(), edm::EventSetup::getHandle(), edm::ParameterSet::getParameter(), good, reco::PFCandidate::h, reco::PFCandidate::h0, h2_Chi2VsEta_, h2_Chi2VsR_, h2_convVtxdRVsEta_, h2_convVtxdRVsR_, h2_convVtxRrecVsTrue_, h2_DCotTracksVsEta_, h2_DCotTracksVsR_, h2_DPhiTracksAtEcalVsEta_, h2_DPhiTracksAtEcalVsR_, h2_DPhiTracksAtVtxVsEta_, h2_DPhiTracksAtVtxVsR_, h2_dzPVVsR_, h2_ecalRecHitSumEtConeDR04VsEt_, h2_ecalRecHitSumEtConeDR04VsEta_, h2_ecalRecHitSumEtConeDR04VsEtaBkg_, h2_ecalRecHitSumEtConeDR04VsEtBkg_, h2_EoverEtrueVsEoverP_, h2_EoverEtrueVsEta_, h2_EoverEtrueVsR_, h2_EoverPVsEta_, h2_EoverPVsR_, h2_eResVsEt_, h2_eResVsEta_, h2_eResVsR9_, h2_etaVsRreco_, h2_etaVsRsim_, h2_hcalTowerSumEtConeDR04VsEt_, h2_hcalTowerSumEtConeDR04VsEta_, h2_hcalTowerSumEtConeDR04VsEtaBkg_, h2_hcalTowerSumEtConeDR04VsEtBkg_, h2_hOverEVsEt_, h2_hOverEVsEta_, h2_hOverEVsEtaBkg_, h2_hOverEVsEtBkg_, h2_isoTrkSolidConeDR04VsEt_, h2_isoTrkSolidConeDR04VsEta_, h2_isoTrkSolidConeDR04VsEtaBkg_, h2_isoTrkSolidConeDR04VsEtBkg_, h2_nTrkSolidConeDR04VsEt_, h2_nTrkSolidConeDR04VsEta_, h2_nTrkSolidConeDR04VsEtaBkg_, h2_nTrkSolidConeDR04VsEtBkg_, h2_PoverPtrueVsEoverP_, h2_PoverPtrueVsEta_, h2_PtRecVsPtSim_, h2_PtRecVsPtSimMixProv_, h2_r1VsEt_, h2_r1VsEta_, h2_r1VsEtaBkg_, h2_r1VsEtBkg_, h2_r2VsEt_, h2_r2VsEta_, h2_r2VsEtaBkg_, h2_r2VsEtBkg_, h2_r9VsEt_, h2_r9VsEtaBkg_, h2_r9VsEtBkg_, h2_sceResVsR9_, h2_sigmaIetaIetaVsEt_, h2_sigmaIetaIetaVsEta_, h2_sigmaIetaIetaVsEtaBkg_, h2_sigmaIetaIetaVsEtBkg_, h2_TkPtPull_, h_AllSimConv_, h_chHadIso_, h_chHadIso_miniAOD_, h_convAlgo_, h_convERes_, h_convEta_, h_convEtaBkg_, h_convPhi_, h_convPhiBkg_, h_convPtRes_, h_convSLVtxRvsZ_, h_convVtxdEta_, h_convVtxdPhi_, h_convVtxdR_, h_convVtxdR_barrel_, h_convVtxdR_endcap_, h_convVtxdX_, h_convVtxdX_barrel_, h_convVtxdX_endcap_, h_convVtxdY_, h_convVtxdY_barrel_, h_convVtxdY_endcap_, h_convVtxdZ_, h_convVtxdZ_barrel_, h_convVtxdZ_endcap_, h_convVtxRvsZ_, h_convVtxRvsZ_zoom_, h_convVtxRvsZBkg_, h_convVtxYvsX_, h_convVtxYvsX_zoom_, h_convVtxYvsXBkg_, h_DCotTracks_, h_DCotTracksBkg_, h_DEtaTracksAtEcal_, h_DPhiTracksAtEcal_, h_DPhiTracksAtVtx_, h_DPhiTracksAtVtxBkg_, h_dRPhoPFcand_ChHad_Cleaned_, h_dRPhoPFcand_ChHad_unCleaned_, h_dRPhoPFcand_NeuHad_Cleaned_, h_dRPhoPFcand_NeuHad_unCleaned_, h_dRPhoPFcand_Pho_Cleaned_, h_dRPhoPFcand_Pho_unCleaned_, h_dzPVFromTracks_, h_ecalRecHitSumEtConeDR04_, h_ecalRecHitSumEtConeDR04_miniAOD_, h_ecalRecHitSumEtConeDR04Bkg_, h_EoverP_SL_, h_EoverPTracks_, h_EoverPTracksBkg_, h_etOutsideMustache_, h_EtR9Less093_, h_full5x5_r9_miniAOD_, h_full5x5_sigmaIetaIeta_miniAOD_, h_gamgamMass_, h_gamgamMassRegr1_, h_gamgamMassRegr2_, h_hcalTowerBcSumEtConeDR04_, h_hcalTowerBcSumEtConeDR04_miniAOD_, h_hcalTowerSumEtConeDR04_, h_hcalTowerSumEtConeDR04_miniAOD_, h_hcalTowerSumEtConeDR04Bkg_, h_hOverE_, h_hOverE_miniAOD_, h_hOverEBkg_, h_invMass_, h_IOinnermostHitR_, h_isoTrkSolidConeDR04_, h_isoTrkSolidConeDR04_miniAOD_, h_isoTrkSolidConeDR04Bkg_, h_MatchedSimJet_, h_MatchedSimJetBadCh_, h_MatchedSimPho_, h_MatchedSimPhoBadCh_, h_mvaOut_, h_mvaOutBkg_, h_nCluOutsideMustache_, h_nConv_, h_newhOverE_, h_newhOverE_miniAOD_, h_nHadIso_, h_nHadIso_miniAOD_, h_nPho_, h_nRecoVtx_, h_nSimConv_, h_nSimPho_, h_nTrkSolidConeDR04_, h_nTrkSolidConeDR04_miniAOD_, h_nTrkSolidConeDR04Bkg_, h_OIinnermostHitR_, h_pfMva_, h_phoBkgDEta_, h_phoBkgDPhi_, h_phoBkgE_, h_phoBkgEt_, h_phoBkgEta_, h_phoBkgPhi_, h_phoDEta_, h_phoDPhi_, h_phoE_, h_phoE_miniAOD_, h_phoERes_, h_phoERes_miniAOD_, h_phoEResRegr1_, h_phoEResRegr2_, h_phoEt_, h_phoEt_miniAOD_, h_phoEta_, h_phoIso_, h_phoIso_miniAOD_, h_phoPhi_, h_phoPixSeedSize_, h_phoSigmaEoE_, h_phoSigmaEoE_miniAOD_, h_PoverETracks_, h_PoverETracksBkg_, h_psE_, h_r1_, h_r1_miniAOD_, h_r1Bkg_, h_r2_, h_r2_miniAOD_, h_r2Bkg_, h_r9_, h_r9_miniAOD_, h_r9Bkg_, h_r9VsNofTracks_, h_RecoConvTwoMTracks_, h_RecoConvTwoTracks_, h_scBkgE_, h_scBkgEt_, h_scBkgEta_, h_scBkgPhi_, h_scE_, h_scEt_, h_scEta_, h_scEta_miniAOD_, h_scEtaWidth_, h_scPhi_, h_scPhi_miniAOD_, h_scPhiWidth_, h_sigmaIetaIeta_, h_sigmaIetaIeta_miniAOD_, h_sigmaIetaIetaBkg_, h_SimConvEtaPix_, h_SimConvOneMTracks_, h_SimConvTwoMTracks_, h_SimConvTwoMTracksAndVtxPGT0005_, h_SimConvTwoMTracksAndVtxPGT0_, h_SimConvTwoTracks_, h_simConvVtxRvsZ_, h_simConvVtxYvsX_, h_SimJet_, h_SimPho_, h_SimPhoMotherEt_, h_SimPhoMotherEta_, h_simTkEta_, h_simTkPt_, h_SumPtOverPhoPt_ChHad_Cleaned_, h_SumPtOverPhoPt_ChHad_unCleaned_, h_SumPtOverPhoPt_NeuHad_Cleaned_, h_SumPtOverPhoPt_NeuHad_unCleaned_, h_SumPtOverPhoPt_Pho_Cleaned_, h_SumPtOverPhoPt_Pho_unCleaned_, h_tkChi2_, h_tkChi2Large_, h_tkChi2SL_, h_TkD0_, h_TkPtPull_, h_trkAlgo_, h_trkProv_, h_VisSimConv_, h_vtxChi2_, h_vtxChi2Prob_, h_zPVFromTracks_, reco::Photon::hadronicOverEm(), hBCEnergyOverTrackPout_, reco::Photon::hcalTowerSumEtConeDR04(), hepMC_Token_, mps_fire::i, edm::EventBase::id(), edm::Ref< C, T, F >::isNonnull(), isRunCentrally_, edm::HandleBase::isValid(), edm::Ref< C, T, F >::key(), cmsLHEtoEOSManager::l, edm::EDConsumerBase::labelsForToken(), likelihoodCut_, mcConvEta_, mcConvPhi_, mcConvR_, mcConvX_, mcConvY_, mcConvZ_, mcEta_, mcJetEta_, mcJetPhi_, mcPhi_, minPhoEtCut_, edm::ProductLabels::module, reco::TrackBase::momentum(), ndof, nEvt_, nHits, nHitsVsEta_, nHitsVsR_, HLT_FULL_cff::normalizedChi2, nRecConv_, nRecConvAss_, nRecConvAssWithEcal_, nSimConv_, nSimPho_, BeamSpotPI::nTracks, reco::Photon::nTrkSolidConeDR04(), HLT_FULL_cff::numberOfValidHits, offline_pvToken_, fireworks::p1, fireworks::p2, p_Chi2VsEta_, p_Chi2VsR_, p_convVtxdRVsEta_, p_convVtxdRVsR_, p_convVtxdXVsX_, p_convVtxdYVsY_, p_convVtxdZVsZ_, p_DCotTracksVsEta_, p_DCotTracksVsR_, p_DPhiTracksAtEcalVsEta_, p_DPhiTracksAtEcalVsR_, p_DPhiTracksAtVtxVsEta_, p_DPhiTracksAtVtxVsR_, p_dzPVVsEta_, p_dzPVVsR_, p_ecalRecHitSumEtConeDR04VsEt_, p_ecalRecHitSumEtConeDR04VsEta_, p_ecalRecHitSumEtConeDR04VsEtaBkg_, p_ecalRecHitSumEtConeDR04VsEtBkg_, p_EoverEtrueVsEta_, p_EoverEtrueVsR_, p_EoverPVsEta_, p_EoverPVsR_, p_eResVsEt_, p_eResVsEta_, p_eResVsNVtx_, p_eResVsR9_, p_eResVsR_, p_hcalTowerBcSumEtConeDR04VsEt_, p_hcalTowerBcSumEtConeDR04VsEta_, p_hcalTowerSumEtConeDR04VsEt_, p_hcalTowerSumEtConeDR04VsEta_, p_hcalTowerSumEtConeDR04VsEtaBkg_, p_hcalTowerSumEtConeDR04VsEtBkg_, p_hOverEVsEt_, p_hOverEVsEta_, p_hOverEVsEtaBkg_, p_hOverEVsEtBkg_, p_isoTrkSolidConeDR04VsEtaBkg_, p_isoTrkSolidConeDR04VsEtBkg_, p_newhOverEVsEt_, p_newhOverEVsEta_, p_nHitsVsEta_, p_nHitsVsEtaSL_, p_nHitsVsR_, p_nHitsVsRSL_, p_nTrkSolidConeDR04VsEtaBkg_, p_nTrkSolidConeDR04VsEtBkg_, p_PoverPtrueVsEta_, p_r1VsEtaBkg_, p_r1VsEtBkg_, p_r2VsEtaBkg_, p_r2VsEtBkg_, p_r9VsEta_, p_sceResVsR9_, p_sigmaEoEVsEt_, p_sigmaEoEVsEta_, p_sigmaEoEVsNVtx_, p_sigmaIetaIetaVsEtaBkg_, p_sigmaIetaIetaVsEtBkg_, parameters_, parents, particleBasedIso_token, pfCandidates_, reco::LeafCandidate::phi(), phiNormalization(), configurableAnalysis::Photon, photonCollectionToken_, pi, funct::pow(), edm::Handle< T >::product(), edm::RefToBaseVector< T >::push_back(), edm::RefVector< C, T, F >::push_back(), submitPVResolutionJobs::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(), createPayload::skip, mathSSE::sqrt(), reco::Photon::superCluster(), theCaloGeom_, theConvTP_, thePhotonMCTruthFinder_, token_tp_, cmsswSequenceInfo::tp, trackingTruthProducer_cfi::trackingParticles, tracks, transientTrackBuilderToken_, reco::Photon::trkSumPtSolidConeDR04(), and z.

                                                                          {
  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:
  theCaloGeom_ = esup.getHandle(caloGeometryToken_);

  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)
  auto theTTB = esup.getHandle(transientTrackBuilderToken_);

  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();

  Handle<reco::GenParticleCollection> genParticles;
  e.getByToken(genpartToken_, genParticles);

  // 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().empty() && !myPhotons[1]->conversions().empty()) {
          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().empty() && myPhotons[1]->conversions().empty() &&
                   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().empty() && myPhotons[0]->conversions().empty() &&
                   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().empty() && !myPhotons[1]->conversions().empty()) {
          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().empty() && myPhotons[1]->conversions().empty() &&
                   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().empty() && myPhotons[0]->conversions().empty() &&
                   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().empty() && !myPhotons[1]->conversions().empty()) {
          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().empty() && myPhotons[1]->conversions().empty() &&
                   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().empty() && myPhotons[0]->conversions().empty() &&
                   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 = nullptr;
      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 == nullptr || (mother != nullptr && mother->pdg_id() == 22) ||
          (mother != nullptr && mother->pdg_id() == 25) || (mother != nullptr && 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 photonEt = matchingPho->pt();
      float photonERegr1 = matchingPho->getCorrectedEnergy(reco::Photon::regression1);
      float photonERegr2 = matchingPho->getCorrectedEnergy(reco::Photon::regression2);
      float r9 = matchingPho->r9();
      //     float full5x5_r9 = matchingPho->full5x5_r9();
      float r1 = matchingPho->r1x5();
      float r2 = matchingPho->r2x5();
      float sigmaIetaIeta = matchingPho->sigmaIetaIeta();
      //float full5x5_sieie =  matchingPho->full5x5_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.empty())
              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().empty())
              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().empty())
                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().empty()) {
                    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().empty())
                      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().empty())
                      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().empty() && 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();
                // unused   float bcPhi1 = aConv->bcMatchingWithTracks()[0]->phi();
                // unused   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);
                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().empty() && 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().empty() && 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().empty() && 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.empty())
                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 const& p1 = trackAssociator->associateRecoToSim(tc1, theConvTP_);
          reco::RecoToSimCollection const& p2 = trackAssociator->associateRecoToSim(tc2, theConvTP_);
          std::vector<std::pair<RefToBase<reco::Track>, double> > trackV1, trackV2;

          auto itP1 = p1.find(tk1);
          auto itP2 = p2.find(tk2);
          bool good = (itP1 != p1.end()) and (not itP1->val.empty()) and (itP2 != p2.end()) and (not itP2->val.empty());
          if (not good) {
            itP1 = p1.find(tk2);
            itP2 = p2.find(tk1);
            good = (itP1 != p1.end()) and (not itP1->val.empty()) and (itP2 != p2.end()) and (not itP2->val.empty());
          }
          if (good) {
            std::vector<std::pair<TrackingParticleRef, double> > const& tp1 = itP1->val;
            std::vector<std::pair<TrackingParticleRef, double> > const& tp2 = itP2->val;

            TrackingParticleRef tpr1 = tp1.front().first;
            TrackingParticleRef tpr2 = tp2.front().first;

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

        }  // 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().empty()) {
            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().empty()) {
          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().empty() && 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

  for (reco::GenParticleCollection::const_iterator mcIter = genParticles->begin(); mcIter != genParticles->end();
       mcIter++) {
    if (!(mcIter->pdgId() == 22))
      continue;
    if (mcIter->mother() != nullptr and !(mcIter->mother()->pdgId() == 25))
      continue;
    if (fabs(mcIter->eta()) > 2.5)
      continue;

    float mcPhi = mcIter->phi();
    float mcEta = mcIter->eta();
    //mcEta = etaTransformation(mcEta, (*mcPho).primaryVertex().z() );
    float mcEnergy = mcIter->energy();

    double dR = 9999999.;
    float minDr = 10000.;
    int iMatch = -1;
    bool matched = false;

    for (unsigned int ipho = 0; ipho < photonHandle->size(); ipho++) {
      reco::PhotonRef pho(reco::PhotonRef(photonHandle, ipho));

      double dphi = pho->phi() - mcPhi;
      if (std::fabs(dphi) > CLHEP::pi) {
        dphi = dphi < 0 ? (CLHEP::twopi) + dphi : dphi - CLHEP::twopi;
      }
      double deta = pho->superCluster()->position().eta() - mcEta;

      dR = sqrt(pow((deta), 2) + pow(dphi, 2));
      if (dR < 0.1 && dR < minDr) {
        minDr = dR;
        iMatch = ipho;
      }
    }

    if (iMatch > -1)
      matched = true;
    if (!matched)
      continue;

    reco::PhotonRef matchingPho(reco::PhotonRef(photonHandle, iMatch));

    bool phoIsInBarrel = false;
    bool phoIsInEndcap = false;

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

    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 full5x5_r9 = matchingPho->full5x5_r9();
    float r1 = matchingPho->r1x5();
    float r2 = matchingPho->r2x5();
    float sigmaIetaIeta = matchingPho->sigmaIetaIeta();
    float full5x5_sieie = matchingPho->full5x5_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();

    if ((photonEt > 14 && newhOverE < 0.15) || (photonEt > 10 && photonEt < 14 && chargedHadIso < 10)) {
      h_scEta_miniAOD_[0]->Fill(matchingPho->superCluster()->eta());
      h_scPhi_miniAOD_[0]->Fill(matchingPho->superCluster()->phi());

      h_phoE_miniAOD_[0][0]->Fill(photonE);
      h_phoEt_miniAOD_[0][0]->Fill(photonEt);

      h_phoERes_miniAOD_[0][0]->Fill(photonE / mcEnergy);
      h_phoSigmaEoE_miniAOD_[0][0]->Fill(sigmaEoE);

      h_r9_miniAOD_[0][0]->Fill(r9);
      h_full5x5_r9_miniAOD_[0][0]->Fill(full5x5_r9);
      h_r1_miniAOD_[0][0]->Fill(r1);
      h_r2_miniAOD_[0][0]->Fill(r2);

      h_sigmaIetaIeta_miniAOD_[0][0]->Fill(sigmaIetaIeta);
      h_full5x5_sigmaIetaIeta_miniAOD_[0][0]->Fill(full5x5_sieie);
      h_hOverE_miniAOD_[0][0]->Fill(hOverE);
      h_newhOverE_miniAOD_[0][0]->Fill(newhOverE);

      h_ecalRecHitSumEtConeDR04_miniAOD_[0][0]->Fill(ecalIso);
      h_hcalTowerSumEtConeDR04_miniAOD_[0][0]->Fill(hcalIso);
      h_hcalTowerBcSumEtConeDR04_miniAOD_[0][0]->Fill(newhcalIso);
      h_isoTrkSolidConeDR04_miniAOD_[0][0]->Fill(trkIso);
      h_nTrkSolidConeDR04_miniAOD_[0][0]->Fill(nIsoTrk);

      //
      h_chHadIso_miniAOD_[0]->Fill(chargedHadIso);
      h_nHadIso_miniAOD_[0]->Fill(neutralHadIso);
      h_phoIso_miniAOD_[0]->Fill(photonIso);

      //
      if (phoIsInBarrel) {
        h_phoE_miniAOD_[0][1]->Fill(photonE);
        h_phoEt_miniAOD_[0][1]->Fill(photonEt);

        h_phoERes_miniAOD_[0][1]->Fill(photonE / mcEnergy);
        h_phoSigmaEoE_miniAOD_[0][1]->Fill(sigmaEoE);

        h_r9_miniAOD_[0][1]->Fill(r9);
        h_full5x5_r9_miniAOD_[0][1]->Fill(full5x5_r9);
        h_r1_miniAOD_[0][1]->Fill(r1);
        h_r2_miniAOD_[0][1]->Fill(r2);
        h_sigmaIetaIeta_miniAOD_[0][1]->Fill(sigmaIetaIeta);
        h_full5x5_sigmaIetaIeta_miniAOD_[0][1]->Fill(full5x5_sieie);
        h_hOverE_miniAOD_[0][1]->Fill(hOverE);
        h_newhOverE_miniAOD_[0][1]->Fill(newhOverE);
        h_ecalRecHitSumEtConeDR04_miniAOD_[0][1]->Fill(ecalIso);
        h_hcalTowerSumEtConeDR04_miniAOD_[0][1]->Fill(hcalIso);
        h_hcalTowerBcSumEtConeDR04_miniAOD_[0][1]->Fill(newhcalIso);
        h_isoTrkSolidConeDR04_miniAOD_[0][1]->Fill(trkIso);
        h_nTrkSolidConeDR04_miniAOD_[0][1]->Fill(nIsoTrk);
        h_chHadIso_miniAOD_[1]->Fill(chargedHadIso);
        h_nHadIso_miniAOD_[1]->Fill(neutralHadIso);
        h_phoIso_miniAOD_[1]->Fill(photonIso);
      }
      if (phoIsInEndcap) {
        h_phoE_miniAOD_[0][2]->Fill(photonE);
        h_phoEt_miniAOD_[0][2]->Fill(photonEt);

        h_phoERes_miniAOD_[0][2]->Fill(photonE / mcEnergy);
        h_phoSigmaEoE_miniAOD_[0][2]->Fill(sigmaEoE);
        h_r9_miniAOD_[0][2]->Fill(r9);
        h_full5x5_r9_miniAOD_[0][2]->Fill(full5x5_r9);
        h_r1_miniAOD_[0][2]->Fill(r1);
        h_r2_miniAOD_[0][2]->Fill(r2);
        h_sigmaIetaIeta_miniAOD_[0][2]->Fill(sigmaIetaIeta);
        h_full5x5_sigmaIetaIeta_miniAOD_[0][2]->Fill(full5x5_sieie);
        h_hOverE_miniAOD_[0][2]->Fill(hOverE);
        h_newhOverE_miniAOD_[0][2]->Fill(newhOverE);
        h_ecalRecHitSumEtConeDR04_miniAOD_[0][2]->Fill(ecalIso);
        h_hcalTowerSumEtConeDR04_miniAOD_[0][2]->Fill(hcalIso);
        h_hcalTowerBcSumEtConeDR04_miniAOD_[0][2]->Fill(newhcalIso);
        h_isoTrkSolidConeDR04_miniAOD_[0][2]->Fill(trkIso);
        h_nTrkSolidConeDR04_miniAOD_[0][2]->Fill(nIsoTrk);
        h_chHadIso_miniAOD_[2]->Fill(chargedHadIso);
        h_nHadIso_miniAOD_[2]->Fill(neutralHadIso);
        h_phoIso_miniAOD_[2]->Fill(photonIso);
      }
    }  // end histos for comparing with miniAOD

  }  // end loop over gen photons

  h_nPho_->Fill(float(nPho));
}

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

overridevirtual

Histograms for efficiencies

Denominators

Numerators

zooms

test track provenance

Implements DQMOneEDAnalyzer<>.

Definition at line 159 of file PhotonValidator.cc.

References reco::TrackBase::algoSize, dqm::implementation::IBooker::book1D(), dqm::implementation::IBooker::book2D(), dqm::implementation::IBooker::bookProfile(), gpuVertexFinder::chi2Max, etaBin(), Puppi_cff::etaMax, Puppi_cff::etaMin, HLT_FULL_cff::etMin, fName_, edm::ParameterSet::getParameter(), h2_Chi2VsEta_, h2_Chi2VsR_, h2_convVtxdRVsEta_, h2_convVtxdRVsR_, h2_convVtxRrecVsTrue_, h2_DCotTracksVsEta_, h2_DCotTracksVsR_, h2_DPhiTracksAtEcalVsEta_, h2_DPhiTracksAtEcalVsR_, h2_DPhiTracksAtVtxVsEta_, h2_DPhiTracksAtVtxVsR_, h2_dzPVVsR_, h2_ecalRecHitSumEtConeDR04VsEt_, h2_ecalRecHitSumEtConeDR04VsEta_, h2_ecalRecHitSumEtConeDR04VsEtaBkg_, h2_ecalRecHitSumEtConeDR04VsEtBkg_, h2_EoverEtrueVsEoverP_, h2_EoverEtrueVsEta_, h2_EoverEtrueVsR_, h2_EoverPVsEta_, h2_EoverPVsR_, h2_eResVsEt_, h2_eResVsEta_, h2_eResVsR9_, h2_etaVsRreco_, h2_etaVsRsim_, h2_hcalTowerSumEtConeDR04VsEt_, h2_hcalTowerSumEtConeDR04VsEta_, h2_hcalTowerSumEtConeDR04VsEtaBkg_, h2_hcalTowerSumEtConeDR04VsEtBkg_, h2_hOverEVsEt_, h2_hOverEVsEta_, h2_hOverEVsEtaBkg_, h2_hOverEVsEtBkg_, h2_isoTrkSolidConeDR04VsEt_, h2_isoTrkSolidConeDR04VsEta_, h2_isoTrkSolidConeDR04VsEtaBkg_, h2_isoTrkSolidConeDR04VsEtBkg_, h2_nTrkSolidConeDR04VsEt_, h2_nTrkSolidConeDR04VsEta_, h2_nTrkSolidConeDR04VsEtaBkg_, h2_nTrkSolidConeDR04VsEtBkg_, h2_PoverPtrueVsEoverP_, h2_PoverPtrueVsEta_, h2_PtRecVsPtSim_, h2_PtRecVsPtSimMixProv_, h2_r1VsEt_, h2_r1VsEta_, h2_r1VsEtaBkg_, h2_r1VsEtBkg_, h2_r2VsEt_, h2_r2VsEta_, h2_r2VsEtaBkg_, h2_r2VsEtBkg_, h2_r9VsEt_, h2_r9VsEtaBkg_, h2_r9VsEtBkg_, h2_sceResVsR9_, h2_sigmaIetaIetaVsEt_, h2_sigmaIetaIetaVsEta_, h2_sigmaIetaIetaVsEtaBkg_, h2_sigmaIetaIetaVsEtBkg_, h2_TkPtPull_, h_AllSimConv_, h_chHadIso_, h_chHadIso_miniAOD_, h_convAlgo_, h_convERes_, h_convEta_, h_convEtaBkg_, h_convPhi_, h_convPhiBkg_, h_convPtRes_, h_convQuality_, h_convSLVtxRvsZ_, h_convVtxdEta_, h_convVtxdPhi_, h_convVtxdR_, h_convVtxdR_barrel_, h_convVtxdR_endcap_, h_convVtxdX_, h_convVtxdX_barrel_, h_convVtxdX_endcap_, h_convVtxdY_, h_convVtxdY_barrel_, h_convVtxdY_endcap_, h_convVtxdZ_, h_convVtxdZ_barrel_, h_convVtxdZ_endcap_, h_convVtxRvsZ_, h_convVtxRvsZ_zoom_, h_convVtxRvsZBkg_, h_convVtxYvsX_, h_convVtxYvsX_zoom_, h_convVtxYvsXBkg_, h_DCotTracks_, h_DCotTracksBkg_, h_DEtaTracksAtEcal_, h_distMinAppTracks_, h_DPhiTracksAtEcal_, h_DPhiTracksAtVtx_, h_DPhiTracksAtVtxBkg_, h_dRPhoPFcand_ChHad_Cleaned_, h_dRPhoPFcand_ChHad_unCleaned_, h_dRPhoPFcand_NeuHad_Cleaned_, h_dRPhoPFcand_NeuHad_unCleaned_, h_dRPhoPFcand_Pho_Cleaned_, h_dRPhoPFcand_Pho_unCleaned_, h_dzPVFromTracks_, h_ecalRecHitSumEtConeDR04_, h_ecalRecHitSumEtConeDR04_miniAOD_, h_ecalRecHitSumEtConeDR04Bkg_, h_EoverP_SL_, h_EoverPTracks_, h_EoverPTracksBkg_, h_etOutsideMustache_, h_EtR9Less093_, h_full5x5_r9_miniAOD_, h_full5x5_sigmaIetaIeta_miniAOD_, h_gamgamMass_, h_gamgamMassRegr1_, h_gamgamMassRegr2_, h_hcalTowerBcSumEtConeDR04_, h_hcalTowerBcSumEtConeDR04_miniAOD_, h_hcalTowerSumEtConeDR04_, h_hcalTowerSumEtConeDR04_miniAOD_, h_hcalTowerSumEtConeDR04Bkg_, h_hOverE_, h_hOverE_miniAOD_, h_hOverEBkg_, h_invMass_, h_IOinnermostHitR_, h_isoTrkSolidConeDR04_, h_isoTrkSolidConeDR04_miniAOD_, h_isoTrkSolidConeDR04Bkg_, h_MatchedSimJet_, h_MatchedSimJetBadCh_, h_MatchedSimPho_, h_MatchedSimPhoBadCh_, h_mvaOut_, h_mvaOutBkg_, h_nCluOutsideMustache_, h_nConv_, h_newhOverE_, h_newhOverE_miniAOD_, h_nHadIso_, h_nHadIso_miniAOD_, h_nPho_, h_nRecoVtx_, h_nSimConv_, h_nSimPho_, h_nTrkSolidConeDR04_, h_nTrkSolidConeDR04_miniAOD_, h_nTrkSolidConeDR04Bkg_, h_OIinnermostHitR_, h_pfMva_, h_phoBkgDEta_, h_phoBkgDPhi_, h_phoBkgE_, h_phoBkgEt_, h_phoBkgEta_, h_phoBkgPhi_, h_phoDEta_, h_phoDPhi_, h_phoE_, h_phoE_miniAOD_, h_phoERes_, h_phoERes_miniAOD_, h_phoEResRegr1_, h_phoEResRegr2_, h_phoEt_, h_phoEt_miniAOD_, h_phoEta_, h_phoIso_, h_phoIso_miniAOD_, h_phoPhi_, h_phoPixSeedSize_, h_phoSigmaEoE_, h_phoSigmaEoE_miniAOD_, h_PoverETracks_, h_PoverETracksBkg_, h_psE_, h_r1_, h_r1_miniAOD_, h_r1Bkg_, h_r2_, h_r2_miniAOD_, h_r2Bkg_, h_r9_, h_r9_miniAOD_, h_r9Bkg_, h_r9VsNofTracks_, h_RecoConvTwoMTracks_, h_RecoConvTwoTracks_, h_scBkgE_, h_scBkgEt_, h_scBkgEta_, h_scBkgPhi_, h_scE_, h_scEt_, h_scEta_, h_scEta_miniAOD_, h_scEtaWidth_, h_scPhi_, h_scPhi_miniAOD_, h_scPhiWidth_, h_sigmaIetaIeta_, h_sigmaIetaIeta_miniAOD_, h_sigmaIetaIetaBkg_, h_SimConvEtaPix_, h_SimConvOneMTracks_, h_SimConvOneTracks_, h_SimConvTwoMTracks_, h_SimConvTwoMTracksAndVtxPGT0005_, h_SimConvTwoMTracksAndVtxPGT0_, h_SimConvTwoTracks_, h_simConvVtxRvsZ_, h_simConvVtxYvsX_, h_SimJet_, h_SimPho_, h_SimPhoMotherEt_, h_SimPhoMotherEta_, h_simTkEta_, h_simTkPt_, h_SumPtOverPhoPt_ChHad_Cleaned_, h_SumPtOverPhoPt_ChHad_unCleaned_, h_SumPtOverPhoPt_NeuHad_Cleaned_, h_SumPtOverPhoPt_NeuHad_unCleaned_, h_SumPtOverPhoPt_Pho_Cleaned_, h_SumPtOverPhoPt_Pho_unCleaned_, h_tkChi2_, h_tkChi2Large_, h_tkChi2SL_, h_TkD0_, h_TkPtPull_, h_trkAlgo_, h_trkProv_, h_VisSimConv_, h_vtxChi2_, h_vtxChi2Prob_, h_zPVFromTracks_, hBCEnergyOverTrackPout_, isRunCentrally_, nHitsVsEta_, nHitsVsR_, p_Chi2VsEta_, p_Chi2VsR_, p_convVtxdRVsEta_, p_convVtxdRVsR_, p_convVtxdXVsX_, p_convVtxdYVsY_, p_convVtxdZVsZ_, p_DCotTracksVsEta_, p_DCotTracksVsR_, p_DPhiTracksAtEcalVsEta_, p_DPhiTracksAtEcalVsR_, p_DPhiTracksAtVtxVsEta_, p_DPhiTracksAtVtxVsR_, p_dzPVVsEta_, p_dzPVVsR_, p_ecalRecHitSumEtConeDR04VsEt_, p_ecalRecHitSumEtConeDR04VsEta_, p_ecalRecHitSumEtConeDR04VsEtaBkg_, p_ecalRecHitSumEtConeDR04VsEtBkg_, p_EoverEtrueVsEta_, p_EoverEtrueVsR_, p_EoverPVsEta_, p_EoverPVsR_, p_eResVsEt_, p_eResVsEta_, p_eResVsNVtx_, p_eResVsR9_, p_eResVsR_, p_hcalTowerBcSumEtConeDR04VsEt_, p_hcalTowerBcSumEtConeDR04VsEta_, p_hcalTowerSumEtConeDR04VsEt_, p_hcalTowerSumEtConeDR04VsEta_, p_hcalTowerSumEtConeDR04VsEtaBkg_, p_hcalTowerSumEtConeDR04VsEtBkg_, p_hOverEVsEt_, p_hOverEVsEta_, p_hOverEVsEtaBkg_, p_hOverEVsEtBkg_, p_isoTrkSolidConeDR04VsEtaBkg_, p_isoTrkSolidConeDR04VsEtBkg_, p_newhOverEVsEt_, p_newhOverEVsEta_, p_nHitsVsEta_, p_nHitsVsEtaSL_, p_nHitsVsR_, p_nHitsVsRSL_, p_nTrkSolidConeDR04VsEtaBkg_, p_nTrkSolidConeDR04VsEtBkg_, p_PoverPtrueVsEta_, p_r1VsEtaBkg_, p_r1VsEtBkg_, p_r2VsEtaBkg_, p_r2VsEtBkg_, p_r9VsEta_, p_sceResVsR9_, p_sigmaEoEVsEt_, p_sigmaEoEVsEta_, p_sigmaEoEVsNVtx_, p_sigmaIetaIetaVsEtaBkg_, p_sigmaIetaIetaVsEtBkg_, p_TkPtPull_, parameters_, L1TMuonDQMOffline_cfi::phiMax, L1TMuonDQMOffline_cfi::phiMin, dqm::implementation::NavigatorBase::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", 200, -0.5, 199.5);

  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",
                                                200,
                                                -0.5,
                                                199.5,
                                                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 ",
                          200,
                          -0.5,
                          199.5,
                          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",
                                                200,
                                                -0.5,
                                                199.5,
                                                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",
                                                200,
                                                -0.5,
                                                199.5,
                                                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 ",
                          200,
                          -0.5,
                          199.5,
                          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",
                                                200,
                                                -0.5,
                                                199.5,
                                                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}",
                                            200,
                                            -0.5,
                                            199.5,
                                            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} ",
                          200,
                          -0.5,
                          199.5,
                          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} ",
                          200,
                          -0.5,
                          199.5,
                          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} ",
                                            200,
                                            -0.5,
                                            199.5,
                                            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} ",
                          2080,
                          -0.5,
                          199.5,
                          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} ",
                                            200,
                                            -0.5,
                                            199.5,
                                            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);

  //}


  h_scEta_miniAOD_[0] = iBooker.book1D("scEta_miniAOD", " SC Eta ", etaBin, etaMin, etaMax);
  h_scPhi_miniAOD_[0] = iBooker.book1D("scPhi_miniAOD", " SC Phi ", phiBin, phiMin, phiMax);
  histname = "phoE";
  h_phoE_miniAOD_[0][0] = iBooker.book1D(histname + "All_miniAOD", " Photon Energy: All ecal ", eBin, eMin, eMax);
  h_phoE_miniAOD_[0][1] = iBooker.book1D(histname + "Barrel_miniAOD", " Photon Energy: barrel ", eBin, eMin, eMax);
  h_phoE_miniAOD_[0][2] = iBooker.book1D(histname + "Endcap_miniAOD", " Photon Energy: Endcap ", eBin, eMin, eMax);

  histname = "phoEt";
  h_phoEt_miniAOD_[0][0] =
      iBooker.book1D(histname + "All_miniAOD", " Photon Transverse Energy: All ecal ", etBin, etMin, etMax);
  h_phoEt_miniAOD_[0][1] =
      iBooker.book1D(histname + "Barrel_miniAOD", " Photon Transverse Energy: Barrel ", etBin, etMin, etMax);
  h_phoEt_miniAOD_[0][2] =
      iBooker.book1D(histname + "Endcap_miniAOD", " Photon Transverse Energy: Endcap ", etBin, etMin, etMax);

  histname = "eRes";
  h_phoERes_miniAOD_[0][0] = iBooker.book1D(
      histname + "All_miniAOD", " Photon E/E_{true}: All ecal;  E/E_{true} (GeV)", resBin, resMin, resMax);
  h_phoERes_miniAOD_[0][1] = iBooker.book1D(
      histname + "Barrel_miniAOD", "Photon E/E_{true}: Barrel; E/E_{true} (GeV)", resBin, resMin, resMax);
  h_phoERes_miniAOD_[0][2] = iBooker.book1D(
      histname + "Endcap_miniAOD", " Photon E/E_{true}: Endcap; E/E_{true} (GeV)", resBin, resMin, resMax);

  histname = "sigmaEoE";
  h_phoSigmaEoE_miniAOD_[0][0] =
      iBooker.book1D(histname + "All_miniAOD", "#sigma_{E}/E: All ecal; #sigma_{E}/E", 100, 0., 0.08);
  h_phoSigmaEoE_miniAOD_[0][1] =
      iBooker.book1D(histname + "Barrel_miniAOD", "#sigma_{E}/E: Barrel; #sigma_{E}/E", 100, 0., 0.08);
  h_phoSigmaEoE_miniAOD_[0][2] =
      iBooker.book1D(histname + "Endcap_miniAOD", "#sigma_{E}/E: Endcap, #sigma_{E}/E", 100, 0., 0.08);

  histname = "r9";
  h_r9_miniAOD_[0][0] = iBooker.book1D(histname + "All_miniAOD", " r9: All Ecal", r9Bin, r9Min, r9Max);
  h_r9_miniAOD_[0][1] = iBooker.book1D(histname + "Barrel_miniAOD", " r9: Barrel ", r9Bin, r9Min, r9Max);
  h_r9_miniAOD_[0][2] = iBooker.book1D(histname + "Endcap_miniAOD", " r9: Endcap ", r9Bin, r9Min, r9Max);
  histname = "full5x5_r9";
  h_full5x5_r9_miniAOD_[0][0] = iBooker.book1D(histname + "All_miniAOD", " r9: All Ecal", r9Bin, r9Min, r9Max);
  h_full5x5_r9_miniAOD_[0][1] = iBooker.book1D(histname + "Barrel_miniAOD", " r9: Barrel ", r9Bin, r9Min, r9Max);
  h_full5x5_r9_miniAOD_[0][2] = iBooker.book1D(histname + "Endcap_miniAOD", " r9: Endcap ", r9Bin, r9Min, r9Max);
  histname = "r1";
  h_r1_miniAOD_[0][0] = iBooker.book1D(histname + "All_miniAOD", " e1x5/e5x5: All Ecal", r9Bin, r9Min, r9Max);
  h_r1_miniAOD_[0][1] = iBooker.book1D(histname + "Barrel_miniAOD", " e1x5/e5x5: Barrel ", r9Bin, r9Min, r9Max);
  h_r1_miniAOD_[0][2] = iBooker.book1D(histname + "Endcap_miniAOD", " e1x5/e5x5: Endcap ", r9Bin, r9Min, r9Max);
  histname = "r2";
  h_r2_miniAOD_[0][0] = iBooker.book1D(histname + "All_miniAOD", " e2x5/e5x5: All Ecal", r9Bin, r9Min, r9Max);
  h_r2_miniAOD_[0][1] = iBooker.book1D(histname + "Barrel_miniAOD", " e2x5/e5x5: Barrel ", r9Bin, r9Min, r9Max);
  h_r2_miniAOD_[0][2] = iBooker.book1D(histname + "Endcap_miniAOD", " e2x5/e5x5: Endcap ", r9Bin, r9Min, r9Max);
  histname = "hOverE";
  h_hOverE_miniAOD_[0][0] = iBooker.book1D(histname + "All_miniAOD", "H/E: All Ecal", 100, 0., 0.2);
  h_hOverE_miniAOD_[0][1] = iBooker.book1D(histname + "Barrel_miniAOD", "H/E: Barrel ", 100, 0., 0.2);
  h_hOverE_miniAOD_[0][2] = iBooker.book1D(histname + "Endcap_miniAOD", "H/E: Endcap ", 100, 0., 0.2);
  //
  histname = "newhOverE";
  h_newhOverE_miniAOD_[0][0] = iBooker.book1D(histname + "All_miniAOD", "new H/E: All Ecal", 100, 0., 0.2);
  h_newhOverE_miniAOD_[0][1] = iBooker.book1D(histname + "Barrel_miniAOD", "new H/E: Barrel ", 100, 0., 0.2);
  h_newhOverE_miniAOD_[0][2] = iBooker.book1D(histname + "Endcap_miniAOD", "new H/E: Endcap ", 100, 0., 0.2);
  //
  histname = "sigmaIetaIeta";
  h_sigmaIetaIeta_miniAOD_[0][0] = iBooker.book1D(histname + "All_miniAOD", "sigmaIetaIeta: All Ecal", 100, 0., 0.1);
  h_sigmaIetaIeta_miniAOD_[0][1] = iBooker.book1D(histname + "Barrel_miniAOD", "sigmaIetaIeta: Barrel ", 100, 0., 0.05);
  h_sigmaIetaIeta_miniAOD_[0][2] = iBooker.book1D(histname + "Endcap_miniAOD", "sigmaIetaIeta: Endcap ", 100, 0., 0.1);
  histname = "full5x5_sigmaIetaIeta";
  h_full5x5_sigmaIetaIeta_miniAOD_[0][0] =
      iBooker.book1D(histname + "All_miniAOD", "Full5x5 sigmaIetaIeta: All Ecal", 100, 0., 0.1);
  h_full5x5_sigmaIetaIeta_miniAOD_[0][1] =
      iBooker.book1D(histname + "Barrel_miniAOD", "Full5x5 sigmaIetaIeta: Barrel ", 100, 0., 0.05);
  h_full5x5_sigmaIetaIeta_miniAOD_[0][2] =
      iBooker.book1D(histname + "Endcap_miniAOD", "Full5x5 sigmaIetaIeta: Endcap ", 100, 0., 0.1);
  //
  histname = "ecalRecHitSumEtConeDR04";
  h_ecalRecHitSumEtConeDR04_miniAOD_[0][0] =
      iBooker.book1D(histname + "All_miniAOD", "ecalRecHitSumEtDR04: All Ecal", etBin, etMin, 20.);
  h_ecalRecHitSumEtConeDR04_miniAOD_[0][1] =
      iBooker.book1D(histname + "Barrel_miniAOD", "ecalRecHitSumEtDR04: Barrel ", etBin, etMin, 20.);
  h_ecalRecHitSumEtConeDR04_miniAOD_[0][2] =
      iBooker.book1D(histname + "Endcap_miniAOD", "ecalRecHitSumEtDR04: Endcap ", etBin, etMin, 20.);
  histname = "hcalTowerSumEtConeDR04";
  h_hcalTowerSumEtConeDR04_miniAOD_[0][0] =
      iBooker.book1D(histname + "All_miniAOD", "hcalTowerSumEtConeDR04: All Ecal", etBin, etMin, 20.);
  h_hcalTowerSumEtConeDR04_miniAOD_[0][1] =
      iBooker.book1D(histname + "Barrel_miniAOD", "hcalTowerSumEtConeDR04: Barrel ", etBin, etMin, 20.);
  h_hcalTowerSumEtConeDR04_miniAOD_[0][2] =
      iBooker.book1D(histname + "Endcap_miniAOD", "hcalTowerSumEtConeDR04: Endcap ", etBin, etMin, 20.);
  //
  histname = "hcalTowerBcSumEtConeDR04";
  h_hcalTowerBcSumEtConeDR04_miniAOD_[0][0] =
      iBooker.book1D(histname + "All_miniAOD", "hcalTowerBcSumEtConeDR04: All Ecal", etBin, etMin, 20.);
  h_hcalTowerBcSumEtConeDR04_miniAOD_[0][1] =
      iBooker.book1D(histname + "Barrel_miniAOD", "hcalTowerBcSumEtConeDR04: Barrel ", etBin, etMin, 20.);
  h_hcalTowerBcSumEtConeDR04_miniAOD_[0][2] =
      iBooker.book1D(histname + "Endcap_miniAOD", "hcalTowerBcSumEtConeDR04: Endcap ", etBin, etMin, 20.);
  histname = "isoTrkSolidConeDR04";
  h_isoTrkSolidConeDR04_miniAOD_[0][0] =
      iBooker.book1D(histname + "All_miniAOD", "isoTrkSolidConeDR04: All Ecal", etBin, etMin, etMax * 0.1);
  h_isoTrkSolidConeDR04_miniAOD_[0][1] =
      iBooker.book1D(histname + "Barrel_miniAOD", "isoTrkSolidConeDR04: Barrel ", etBin, etMin, etMax * 0.1);
  h_isoTrkSolidConeDR04_miniAOD_[0][2] =
      iBooker.book1D(histname + "Endcap_miniAOD", "isoTrkSolidConeDR04: Endcap ", etBin, etMin, etMax * 0.1);
  histname = "nTrkSolidConeDR04";
  h_nTrkSolidConeDR04_miniAOD_[0][0] =
      iBooker.book1D(histname + "All_miniAOD", "nTrkSolidConeDR04: All Ecal", 20, 0., 20);
  h_nTrkSolidConeDR04_miniAOD_[0][1] =
      iBooker.book1D(histname + "Barrel_miniAOD", "nTrkSolidConeDR04: Barrel ", 20, 0., 20);
  h_nTrkSolidConeDR04_miniAOD_[0][2] =
      iBooker.book1D(histname + "Endcap_miniAOD", "nTrkSolidConeDR04: Endcap ", 20, 0., 20);

  //  Infos from Particle Flow - isolation and ID
  histname = "chargedHadIso";
  h_chHadIso_miniAOD_[0] = iBooker.book1D(histname + "All_miniAOD", "PF chargedHadIso:  All Ecal", etBin, etMin, 20.);
  h_chHadIso_miniAOD_[1] = iBooker.book1D(histname + "Barrel_miniAOD", "PF chargedHadIso:  Barrel", etBin, etMin, 20.);
  h_chHadIso_miniAOD_[2] = iBooker.book1D(histname + "Endcap_miniAOD", "PF chargedHadIso:  Endcap", etBin, etMin, 20.);
  histname = "neutralHadIso";
  h_nHadIso_miniAOD_[0] = iBooker.book1D(histname + "All_miniAOD", "PF neutralHadIso:  All Ecal", etBin, etMin, 20.);
  h_nHadIso_miniAOD_[1] = iBooker.book1D(histname + "Barrel_miniAOD", "PF neutralHadIso:  Barrel", etBin, etMin, 20.);
  h_nHadIso_miniAOD_[2] = iBooker.book1D(histname + "Endcap_miniAOD", "PF neutralHadIso:  Endcap", etBin, etMin, 20.);
  histname = "photonIso";
  h_phoIso_miniAOD_[0] = iBooker.book1D(histname + "All_miniAOD", "PF photonIso:  All Ecal", etBin, etMin, 20.);
  h_phoIso_miniAOD_[1] = iBooker.book1D(histname + "Barrel_miniAOD", "PF photonIso:  Barrel", etBin, etMin, 20.);
  h_phoIso_miniAOD_[2] = iBooker.book1D(histname + "Endcap_miniAOD", "PF photonIso:  Endcap", etBin, etMin, 20.);

  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 DQMOneEDAnalyzer<>.

Definition at line 3158 of file PhotonValidator.cc.

References edm::EventSetup::getHandle(), magneticFieldToken_, theMF_, and thePhotonMCTruthFinder_.

                                                                                     {
  //get magnetic field
  edm::LogInfo("ConvertedPhotonProducer") << " get magnetic field"
                                          << "\n";
  theMF_ = theEventSetup.getHandle(magneticFieldToken_);

  thePhotonMCTruthFinder_ = std::make_unique<PhotonMCTruthFinder>();
}

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

overridevirtual

Reimplemented from DQMOneEDAnalyzer<>.

Definition at line 3167 of file PhotonValidator.cc.

References thePhotonMCTruthFinder_.

{ thePhotonMCTruthFinder_.reset(); }

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

private

Definition at line 5478 of file PhotonValidator.cc.

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

Referenced by analyze().

                                                                         {
  //---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 5463 of file PhotonValidator.cc.

References phi, PI, and TWOPI.

Referenced by analyze().

                                                  {
  //---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 108 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

edm::InputTag PhotonValidator::bcBarrelCollection_

private

Definition at line 104 of file PhotonValidator.h.

edm::InputTag PhotonValidator::bcEndcapCollection_

private

Definition at line 105 of file PhotonValidator.h.

double PhotonValidator::bcEtLow_

private

Definition at line 142 of file PhotonValidator.h.

Referenced by PhotonValidator().

const edm::ESGetToken<CaloGeometry, CaloGeometryRecord> PhotonValidator::caloGeometryToken_

private

Definition at line 126 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

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

private

Definition at line 116 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

edm::InputTag PhotonValidator::conversionIOTrackProducer_

private

Definition at line 113 of file PhotonValidator.h.

Referenced by PhotonValidator().

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

private

Definition at line 115 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

edm::InputTag PhotonValidator::conversionOITrackProducer_

private

Definition at line 112 of file PhotonValidator.h.

Referenced by PhotonValidator().

double PhotonValidator::convTrackMinPtCut_

private

Definition at line 135 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

bool PhotonValidator::dCotCutOn_

private

Definition at line 150 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

double PhotonValidator::dCotCutValue_

private

Definition at line 151 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

double PhotonValidator::dCotHardCutValue_

private

Definition at line 152 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

double PhotonValidator::ecalEtSumCut_

private

Definition at line 148 of file PhotonValidator.h.

Referenced by PhotonValidator().

double PhotonValidator::ecalIsolRadius_

private

Definition at line 141 of file PhotonValidator.h.

Referenced by PhotonValidator().

edm::EDGetTokenT<EcalRecHitCollection> PhotonValidator::endcapEcalHits_

private

Definition at line 109 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

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

private

Definition at line 120 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

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

private

Definition at line 121 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

bool PhotonValidator::fastSim_

private

Definition at line 131 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

std::string PhotonValidator::fName_

private

Definition at line 78 of file PhotonValidator.h.

Referenced by analyze(), bookHistograms(), and PhotonValidator().

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

private

Definition at line 118 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

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

private

Definition at line 119 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

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

private

Definition at line 123 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

edm::EDGetTokenT<reco::GenParticleCollection> PhotonValidator::genpartToken_

private

Definition at line 106 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

MonitorElement* PhotonValidator::h2_Chi2VsEta_[3]

private

Definition at line 499 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_Chi2VsR_[3]

private

Definition at line 501 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_convVtxdRVsEta_

private

Definition at line 472 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_convVtxdRVsR_

private

Definition at line 470 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_convVtxRrecVsTrue_

private

Definition at line 478 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_DCotTracksVsEta_

private

Definition at line 431 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_DCotTracksVsR_

private

Definition at line 433 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_DPhiTracksAtEcalVsEta_

private

Definition at line 441 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_DPhiTracksAtEcalVsR_

private

Definition at line 439 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_DPhiTracksAtVtxVsEta_

private

Definition at line 425 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_DPhiTracksAtVtxVsR_

private

Definition at line 427 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_dzPVVsR_

private

Definition at line 485 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_ecalRecHitSumEtConeDR04VsEt_[3]

private

Definition at line 276 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_ecalRecHitSumEtConeDR04VsEta_[3]

private

Definition at line 274 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_ecalRecHitSumEtConeDR04VsEtaBkg_

private

Definition at line 564 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_ecalRecHitSumEtConeDR04VsEtBkg_[3]

private

Definition at line 566 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_EoverEtrueVsEoverP_[3]

private

Definition at line 408 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_EoverEtrueVsEta_[3]

private

Definition at line 416 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_EoverEtrueVsR_[3]

private

Definition at line 418 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_EoverPVsEta_[3]

private

Definition at line 411 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_EoverPVsR_[3]

private

Definition at line 413 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 314 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_eResVsEta_[3]

private

Definition at line 311 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_eResVsR9_[3]

private

Definition at line 321 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_etaVsRreco_[3]

private

Definition at line 406 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_etaVsRsim_[3]

private

Definition at line 405 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_hcalTowerSumEtConeDR04VsEt_[3]

private

Definition at line 282 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_hcalTowerSumEtConeDR04VsEta_[3]

private

Definition at line 280 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_hcalTowerSumEtConeDR04VsEtaBkg_

private

Definition at line 570 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_hcalTowerSumEtConeDR04VsEtBkg_[3]

private

Definition at line 572 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_hOverEVsEt_[3]

private

Definition at line 265 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_hOverEVsEta_[3]

private

Definition at line 263 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_hOverEVsEtaBkg_

private

Definition at line 558 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_hOverEVsEtBkg_

private

Definition at line 559 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_isoTrkSolidConeDR04VsEt_[3]

private

Definition at line 292 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_isoTrkSolidConeDR04VsEta_[3]

private

Definition at line 290 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_isoTrkSolidConeDR04VsEtaBkg_

private

Definition at line 576 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_isoTrkSolidConeDR04VsEtBkg_[3]

private

Definition at line 578 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_nTrkSolidConeDR04VsEt_[3]

private

Definition at line 298 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_nTrkSolidConeDR04VsEta_[3]

private

Definition at line 296 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_nTrkSolidConeDR04VsEtaBkg_

private

Definition at line 582 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_nTrkSolidConeDR04VsEtBkg_[3]

private

Definition at line 584 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_PoverPtrueVsEoverP_[3]

private

Definition at line 409 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_PoverPtrueVsEta_[3]

private

Definition at line 421 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_PtRecVsPtSim_[3]

private

Definition at line 509 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_PtRecVsPtSimMixProv_

private

Definition at line 510 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_r1VsEt_[3]

private

Definition at line 247 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_r1VsEta_[3]

private

Definition at line 245 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_r1VsEtaBkg_

private

Definition at line 542 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_r1VsEtBkg_

private

Definition at line 543 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_r2VsEt_[3]

private

Definition at line 253 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_r2VsEta_[3]

private

Definition at line 251 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_r2VsEtaBkg_

private

Definition at line 547 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_r2VsEtBkg_

private

Definition at line 548 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_r9VsEt_[3]

private

Definition at line 241 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_r9VsEtaBkg_

private

Definition at line 539 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_r9VsEtBkg_

private

Definition at line 540 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_sceResVsR9_[3]

private

Definition at line 323 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_sigmaIetaIetaVsEt_[3]

private

Definition at line 259 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_sigmaIetaIetaVsEta_[3]

private

Definition at line 257 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_sigmaIetaIetaVsEtaBkg_

private

Definition at line 553 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_sigmaIetaIetaVsEtBkg_[3]

private

Definition at line 555 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h2_TkPtPull_[3]

private

Definition at line 507 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_AllSimConv_[5]

private

Definition at line 194 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_chHadIso_[3]

private

Definition at line 338 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_chHadIso_miniAOD_[3]

private

Definition at line 384 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convAlgo_

private

Definition at line 221 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 392 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convEta_[3]

private

Definition at line 390 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convEtaBkg_

private

Definition at line 587 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convPhi_[2]

private

Definition at line 391 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convPhiBkg_

private

Definition at line 588 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 395 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convQuality_

private

Definition at line 222 of file PhotonValidator.h.

Referenced by bookHistograms().

MonitorElement* PhotonValidator::h_convSLVtxRvsZ_[3]

private

Definition at line 450 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdEta_

private

Definition at line 467 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdPhi_

private

Definition at line 468 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdR_

private

Definition at line 455 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdR_barrel_

private

Definition at line 460 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdR_endcap_

private

Definition at line 465 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdX_

private

Definition at line 452 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdX_barrel_

private

Definition at line 457 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdX_endcap_

private

Definition at line 462 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdY_

private

Definition at line 453 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdY_barrel_

private

Definition at line 458 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdY_endcap_

private

Definition at line 463 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdZ_

private

Definition at line 454 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdZ_barrel_

private

Definition at line 459 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxdZ_endcap_

private

Definition at line 464 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxRvsZ_[3]

private

Definition at line 446 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxRvsZ_zoom_[2]

private

Definition at line 448 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxRvsZBkg_[2]

private

Definition at line 597 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxYvsX_

private

Definition at line 447 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxYvsX_zoom_[2]

private

Definition at line 449 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_convVtxYvsXBkg_

private

Definition at line 596 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 430 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_DCotTracksBkg_[3]

private

Definition at line 595 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 444 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 436 of file PhotonValidator.h.

Referenced by bookHistograms().

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

private

Definition at line 438 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 424 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_DPhiTracksAtVtxBkg_[3]

private

Definition at line 594 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_dRPhoPFcand_ChHad_Cleaned_[3]

private

Definition at line 346 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_dRPhoPFcand_ChHad_unCleaned_[3]

private

Definition at line 349 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_dRPhoPFcand_NeuHad_Cleaned_[3]

private

Definition at line 347 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_dRPhoPFcand_NeuHad_unCleaned_[3]

private

Definition at line 350 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_dRPhoPFcand_Pho_Cleaned_[3]

private

Definition at line 348 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_dRPhoPFcand_Pho_unCleaned_[3]

private

Definition at line 351 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_dzPVFromTracks_[5]

private

Definition at line 484 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 273 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_ecalRecHitSumEtConeDR04_miniAOD_[3][3]

private

Definition at line 371 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_ecalRecHitSumEtConeDR04Bkg_[3]

private

Definition at line 563 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_EoverP_SL_[3]

private

Definition at line 402 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 399 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_EoverPTracksBkg_[3]

private

Definition at line 592 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_etOutsideMustache_[3]

private

Definition at line 343 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 238 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_full5x5_r9_miniAOD_[3][3]

private

Definition at line 364 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_full5x5_sigmaIetaIeta_miniAOD_[3][3]

private

Definition at line 366 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 302 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 303 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 304 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 285 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_hcalTowerBcSumEtConeDR04_miniAOD_[3][3]

private

Definition at line 373 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 279 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_hcalTowerSumEtConeDR04_miniAOD_[3][3]

private

Definition at line 372 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_hcalTowerSumEtConeDR04Bkg_[3]

private

Definition at line 569 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 262 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_hOverE_miniAOD_[3][3]

private

Definition at line 369 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_hOverEBkg_[3]

private

Definition at line 537 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 397 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_IOinnermostHitR_

private

Definition at line 218 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 289 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_isoTrkSolidConeDR04_miniAOD_[3][3]

private

Definition at line 374 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_isoTrkSolidConeDR04Bkg_[3]

private

Definition at line 575 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_MatchedSimJet_[3]

private

Definition at line 516 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_MatchedSimJetBadCh_[3]

private

Definition at line 517 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_MatchedSimPho_[3]

private

Numerator for efficiencies.

Definition at line 198 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_MatchedSimPhoBadCh_[3]

private

Definition at line 199 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_mvaOut_[3]

private

Definition at line 404 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_mvaOutBkg_[3]

private

Definition at line 589 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_nCluOutsideMustache_[3]

private

Definition at line 342 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

info per conversion

Definition at line 389 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 268 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_newhOverE_miniAOD_[3][3]

private

Definition at line 370 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_nHadIso_[3]

private

Definition at line 339 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_nHadIso_miniAOD_[3]

private

Definition at line 385 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_nPho_

private

Definition at line 520 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_nRecoVtx_

private

Definition at line 175 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_nSimConv_[2]

private

Definition at line 183 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_nSimPho_[2]

private

Definition at line 177 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 295 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_nTrkSolidConeDR04_miniAOD_[3][3]

private

Definition at line 375 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_nTrkSolidConeDR04Bkg_[3]

private

Definition at line 581 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_OIinnermostHitR_

private

Definition at line 217 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_pfMva_[3]

private

Definition at line 344 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoBkgDEta_

private

Definition at line 526 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoBkgDPhi_

private

Definition at line 527 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoBkgE_[3]

private

Definition at line 528 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoBkgEt_[3]

private

Definition at line 529 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoBkgEta_

private

Definition at line 524 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoBkgPhi_

private

Definition at line 525 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoDEta_[2]

private

Definition at line 224 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoDPhi_[2]

private

Definition at line 225 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 306 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 377 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 308 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoERes_miniAOD_[3][3]

private

Definition at line 379 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 330 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 331 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 307 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 378 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoEta_[2]

private

Definition at line 326 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoIso_[3]

private

Definition at line 340 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoIso_miniAOD_[3]

private

Definition at line 386 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoPhi_[2]

private

Definition at line 327 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoPixSeedSize_[2]

private

Definition at line 334 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 309 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_phoSigmaEoE_miniAOD_[3][3]

private

Definition at line 380 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 400 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_PoverETracksBkg_[3]

private

Definition at line 593 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_psE_

private

Definition at line 236 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 244 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_r1_miniAOD_[3][3]

private

Definition at line 367 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_r1Bkg_[3]

private

Definition at line 535 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 250 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_r2_miniAOD_[3][3]

private

Definition at line 368 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_r2Bkg_[3]

private

Definition at line 536 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 239 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_r9_miniAOD_[3][3]

private

Definition at line 363 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_r9Bkg_[3]

private

Definition at line 534 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 398 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_RecoConvTwoMTracks_[5]

private

Definition at line 211 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_RecoConvTwoTracks_[5]

private

Definition at line 209 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_scBkgE_[3]

private

Definition at line 531 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_scBkgEt_[3]

private

Definition at line 532 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_scBkgEta_

private

Definition at line 522 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_scBkgPhi_

private

Definition at line 523 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 233 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 234 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_scEta_[2]

private

Definition at line 227 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_scEta_miniAOD_[2]

private

Histos for comparison with miniAOD content.

Definition at line 360 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_scEtaPhi_[2]

private

Definition at line 231 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_scEtaWidth_[2]

private

Definition at line 228 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_scPhi_[2]

private

Definition at line 229 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_scPhi_miniAOD_[2]

private

Definition at line 361 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_scPhiWidth_[2]

private

Definition at line 230 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 256 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_sigmaIetaIeta_miniAOD_[3][3]

private

Definition at line 365 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_sigmaIetaIetaBkg_[3]

private

Definition at line 552 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SimConvEtaPix_[2]

private

Definition at line 184 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SimConvMTotal_[5]

private

Definition at line 204 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimConvOneMTracks_[5]

private

Definition at line 201 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SimConvOneTracks_[5]

private

Definition at line 200 of file PhotonValidator.h.

Referenced by bookHistograms().

MonitorElement* PhotonValidator::h_SimConvTwoMTracks_[5]

private

Definition at line 203 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SimConvTwoMTracksAndVtxPGT0005_[5]

private

Definition at line 206 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SimConvTwoMTracksAndVtxPGT01_[5]

private

Definition at line 207 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimConvTwoMTracksAndVtxPGT0_[5]

private

Definition at line 205 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SimConvTwoTracks_[5]

private

Definition at line 202 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_simConvVtxRvsZ_[4]

private

Definition at line 189 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_simConvVtxYvsX_

private

Definition at line 190 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SimJet_[3]

private

Definition at line 515 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SimPho_[3]

private

Denominator for efficiencies.

Definition at line 193 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SimPhoEtaSmallR9_

private

Definition at line 181 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_SimPhoMotherEt_[2]

private

Definition at line 179 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SimPhoMotherEta_[2]

private

Definition at line 180 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SimPhoMotherType_[2]

private

Definition at line 178 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_simTkEta_

private

Definition at line 187 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_simTkPt_

private

Definition at line 186 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_ChHad_Cleaned_[3]

private

Definition at line 352 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_ChHad_unCleaned_[3]

private

Definition at line 355 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_NeuHad_Cleaned_[3]

private

Definition at line 353 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_NeuHad_unCleaned_[3]

private

Definition at line 356 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_Pho_Cleaned_[3]

private

Definition at line 354 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_SumPtOverPhoPt_Pho_unCleaned_[3]

private

Definition at line 357 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_tkChi2_[2]

private

Definition at line 496 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_tkChi2Bkg_

private

Definition at line 591 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_tkChi2Large_[2]

private

Definition at line 498 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_tkChi2SL_[2]

private

Definition at line 497 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_TkD0_[3]

private

Definition at line 504 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_TkPtPull_[3]

private

Definition at line 506 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_trkAlgo_

private

Definition at line 220 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_trkProv_[2]

private

Definition at line 219 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_VisSimConv_[6]

private

Definition at line 195 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_VisSimConvLarge_

private

Definition at line 196 of file PhotonValidator.h.

MonitorElement* PhotonValidator::h_vtxChi2_[3]

private

Definition at line 480 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_vtxChi2Prob_[3]

private

Definition at line 481 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::h_zPVFromTracks_[5]

private

Definition at line 483 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::hBCEnergyOverTrackPout_[3]

private

Definition at line 512 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

double PhotonValidator::hcalEtSumCut_

private

Definition at line 149 of file PhotonValidator.h.

Referenced by PhotonValidator().

double PhotonValidator::hcalHitEtLow_

private

Definition at line 145 of file PhotonValidator.h.

Referenced by PhotonValidator().

double PhotonValidator::hcalIsolExtRadius_

private

Definition at line 143 of file PhotonValidator.h.

Referenced by PhotonValidator().

double PhotonValidator::hcalIsolInnRadius_

private

Definition at line 144 of file PhotonValidator.h.

Referenced by PhotonValidator().

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

private

Definition at line 122 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

bool PhotonValidator::isRunCentrally_

private

Definition at line 132 of file PhotonValidator.h.

Referenced by analyze(), bookHistograms(), and PhotonValidator().

double PhotonValidator::likelihoodCut_

private

Definition at line 136 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

double PhotonValidator::lip_

private

Definition at line 140 of file PhotonValidator.h.

Referenced by PhotonValidator().

const edm::ESGetToken<MagneticField, IdealMagneticFieldRecord> PhotonValidator::magneticFieldToken_

private

Definition at line 125 of file PhotonValidator.h.

Referenced by dqmBeginRun().

double PhotonValidator::mcConvEta_

private

Definition at line 162 of file PhotonValidator.h.

Referenced by analyze().

double PhotonValidator::mcConvPhi_

private

Definition at line 161 of file PhotonValidator.h.

Referenced by analyze().

double PhotonValidator::mcConvR_

private

Definition at line 157 of file PhotonValidator.h.

Referenced by analyze().

double PhotonValidator::mcConvX_

private

Definition at line 160 of file PhotonValidator.h.

Referenced by analyze().

double PhotonValidator::mcConvY_

private

Definition at line 159 of file PhotonValidator.h.

Referenced by analyze().

double PhotonValidator::mcConvZ_

private

Definition at line 158 of file PhotonValidator.h.

Referenced by analyze().

double PhotonValidator::mcEta_

private

Definition at line 156 of file PhotonValidator.h.

Referenced by analyze().

double PhotonValidator::mcJetEta_

private

Definition at line 163 of file PhotonValidator.h.

Referenced by analyze().

double PhotonValidator::mcJetPhi_

private

Definition at line 164 of file PhotonValidator.h.

Referenced by analyze().

double PhotonValidator::mcPhi_

private

global variable for the MC photon

Definition at line 155 of file PhotonValidator.h.

Referenced by analyze().

double PhotonValidator::minPhoEtCut_

private

Definition at line 134 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

int PhotonValidator::nEntry_

private

Definition at line 83 of file PhotonValidator.h.

Referenced by PhotonValidator().

int PhotonValidator::nEvt_

private

Definition at line 82 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

MonitorElement* PhotonValidator::nHitsVsEta_[2]

private

Definition at line 492 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::nHitsVsEtaBkg_

private

Definition at line 590 of file PhotonValidator.h.

MonitorElement* PhotonValidator::nHitsVsR_[2]

private

Definition at line 495 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

int PhotonValidator::nInvalidPCA_

private

Definition at line 91 of file PhotonValidator.h.

Referenced by PhotonValidator().

int PhotonValidator::nMatched_

private

Definition at line 86 of file PhotonValidator.h.

int PhotonValidator::nRecConv_

private

Definition at line 87 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

int PhotonValidator::nRecConvAss_

private

Definition at line 88 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

int PhotonValidator::nRecConvAssWithEcal_

private

Definition at line 89 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

int PhotonValidator::nSimConv_[2]

private

Definition at line 85 of file PhotonValidator.h.

Referenced by analyze().

int PhotonValidator::nSimPho_[2]

private

Definition at line 84 of file PhotonValidator.h.

Referenced by analyze().

int PhotonValidator::numOfTracksInCone_

private

Definition at line 146 of file PhotonValidator.h.

Referenced by PhotonValidator().

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

private

Definition at line 103 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

MonitorElement* PhotonValidator::p_Chi2VsEta_[3]

private

Definition at line 500 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_Chi2VsR_[3]

private

Definition at line 502 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_convVtxdRVsEta_

private

Definition at line 473 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_convVtxdRVsR_

private

Definition at line 471 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_convVtxdXVsX_

private

Definition at line 474 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_convVtxdYVsY_

private

Definition at line 475 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_convVtxdZVsZ_

private

Definition at line 476 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_DCotTracksVsEta_

private

Definition at line 432 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_DCotTracksVsR_

private

Definition at line 434 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_DPhiTracksAtEcalVsEta_

private

Definition at line 442 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_DPhiTracksAtEcalVsR_

private

Definition at line 440 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_DPhiTracksAtVtxVsEta_

private

Definition at line 426 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_DPhiTracksAtVtxVsR_

private

Definition at line 428 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_dzPVVsEta_

private

Definition at line 487 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_dzPVVsR_

private

Definition at line 486 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_ecalRecHitSumEtConeDR04VsEt_[3]

private

Definition at line 277 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_ecalRecHitSumEtConeDR04VsEta_[3]

private

Definition at line 275 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_ecalRecHitSumEtConeDR04VsEtaBkg_

private

Definition at line 565 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_ecalRecHitSumEtConeDR04VsEtBkg_[3]

private

Definition at line 567 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_EoverEtrueVsEta_[3]

private

Definition at line 417 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_EoverEtrueVsR_[3]

private

Definition at line 419 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_EoverPVsEta_[3]

private

Definition at line 412 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_EoverPVsR_[3]

private

Definition at line 414 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 315 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_eResVsEta_[3]

private

Definition at line 312 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 316 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_eResVsR9_[3]

private

Definition at line 322 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_eResVsR_

private

Definition at line 393 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_hcalTowerBcSumEtConeDR04VsEt_[3]

private

Definition at line 287 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_hcalTowerBcSumEtConeDR04VsEta_[3]

private

Definition at line 286 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_hcalTowerSumEtConeDR04VsEt_[3]

private

Definition at line 283 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_hcalTowerSumEtConeDR04VsEta_[3]

private

Definition at line 281 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_hcalTowerSumEtConeDR04VsEtaBkg_

private

Definition at line 571 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_hcalTowerSumEtConeDR04VsEtBkg_[3]

private

Definition at line 573 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_hOverEVsEt_[3]

private

Definition at line 266 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_hOverEVsEta_[3]

private

Definition at line 264 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_hOverEVsEtaBkg_

private

Definition at line 560 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_hOverEVsEtBkg_

private

Definition at line 561 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_isoTrkSolidConeDR04VsEt_[3]

private

Definition at line 293 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_isoTrkSolidConeDR04VsEta_[3]

private

Definition at line 291 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_isoTrkSolidConeDR04VsEtaBkg_

private

Definition at line 577 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_isoTrkSolidConeDR04VsEtBkg_[3]

private

Definition at line 579 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_newhOverEVsEt_[3]

private

Definition at line 270 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_newhOverEVsEta_[3]

private

Definition at line 269 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_nHitsVsEta_[2]

private

Definition at line 490 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_nHitsVsEtaSL_[2]

private

Definition at line 491 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_nHitsVsR_[2]

private

Definition at line 493 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_nHitsVsRSL_[2]

private

Definition at line 494 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_nTrkSolidConeDR04VsEt_[3]

private

Definition at line 299 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_nTrkSolidConeDR04VsEta_[3]

private

Definition at line 297 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_nTrkSolidConeDR04VsEtaBkg_

private

Definition at line 583 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_nTrkSolidConeDR04VsEtBkg_[3]

private

Definition at line 585 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_PoverPtrueVsEta_[3]

private

Definition at line 422 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_r1VsEt_[3]

private

Definition at line 248 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r1VsEta_[3]

private

Definition at line 246 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r1VsEtaBkg_

private

Definition at line 544 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_r1VsEtBkg_

private

Definition at line 545 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_r2VsEt_[3]

private

Definition at line 254 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r2VsEta_[3]

private

Definition at line 252 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r2VsEtaBkg_

private

Definition at line 549 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_r2VsEtBkg_

private

Definition at line 550 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_r9VsEt_[3]

private

Definition at line 242 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_r9VsEta_[3]

private

Definition at line 240 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_sceResVsR9_[3]

private

Definition at line 324 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 318 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_sigmaEoEVsEta_[3]

private

Definition at line 313 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

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

private

Definition at line 319 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_sigmaIetaIetaVsEt_[3]

private

Definition at line 260 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_sigmaIetaIetaVsEta_[3]

private

Definition at line 258 of file PhotonValidator.h.

MonitorElement* PhotonValidator::p_sigmaIetaIetaVsEtaBkg_

private

Definition at line 554 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_sigmaIetaIetaVsEtBkg_[3]

private

Definition at line 556 of file PhotonValidator.h.

Referenced by analyze(), and bookHistograms().

MonitorElement* PhotonValidator::p_TkPtPull_[3]

private

Definition at line 508 of file PhotonValidator.h.

Referenced by bookHistograms().

edm::ParameterSet PhotonValidator::parameters_

private

Definition at line 93 of file PhotonValidator.h.

Referenced by analyze(), bookHistograms(), Mixins._TypedParameterizable::clone(), Types.PSet::clone(), Types.EDAlias::clone(), Mixins._TypedParameterizable::copy(), and PhotonValidator().

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

private

Definition at line 102 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

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

private

Definition at line 100 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

std::string PhotonValidator::photonCollection_

private

Definition at line 98 of file PhotonValidator.h.

Referenced by PhotonValidator().

std::string PhotonValidator::photonCollectionProducer_

private

Definition at line 97 of file PhotonValidator.h.

Referenced by PhotonValidator().

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

private

Definition at line 99 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

double PhotonValidator::recMaxPt_

private

Definition at line 174 of file PhotonValidator.h.

double PhotonValidator::recMinPt_

private

Global variables for reco Photon.

Definition at line 173 of file PhotonValidator.h.

double PhotonValidator::simMaxPt_

private

Definition at line 170 of file PhotonValidator.h.

double PhotonValidator::simMinPt_

private

Definition at line 169 of file PhotonValidator.h.

TH1F* PhotonValidator::th1f_SimConvMTotal_[5]

private

Definition at line 214 of file PhotonValidator.h.

edm::ESHandle<CaloGeometry> PhotonValidator::theCaloGeom_

private

Definition at line 94 of file PhotonValidator.h.

Referenced by analyze().

edm::ESHandle<CaloTopology> PhotonValidator::theCaloTopo_

private

Definition at line 95 of file PhotonValidator.h.

edm::RefVector<TrackingParticleCollection> PhotonValidator::theConvTP_

private

Definition at line 166 of file PhotonValidator.h.

Referenced by analyze().

edm::ESHandle<MagneticField> PhotonValidator::theMF_

private

Definition at line 79 of file PhotonValidator.h.

Referenced by dqmBeginRun().

std::unique_ptr<PhotonMCTruthFinder> PhotonValidator::thePhotonMCTruthFinder_

private

Definition at line 129 of file PhotonValidator.h.

Referenced by analyze(), dqmBeginRun(), and dqmEndRun().

edm::EDGetTokenT<TrackingParticleCollection> PhotonValidator::token_tp_

private

Definition at line 110 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

const edm::ESGetToken<TransientTrackBuilder, TransientTrackRecord> PhotonValidator::transientTrackBuilderToken_

private

Definition at line 127 of file PhotonValidator.h.

Referenced by analyze(), and PhotonValidator().

double PhotonValidator::trkIsolExtRadius_

private

Definition at line 137 of file PhotonValidator.h.

Referenced by PhotonValidator().

double PhotonValidator::trkIsolInnRadius_

private

Definition at line 138 of file PhotonValidator.h.

Referenced by PhotonValidator().

double PhotonValidator::trkPtLow_

private

Definition at line 139 of file PhotonValidator.h.

Referenced by PhotonValidator().

double PhotonValidator::trkPtSumCut_

private

Definition at line 147 of file PhotonValidator.h.

Referenced by PhotonValidator().

std::string PhotonValidator::valueMapPhoPFCandIso_

private

Definition at line 101 of file PhotonValidator.h.

Referenced by PhotonValidator().

int PhotonValidator::verbosity_

private

Definition at line 81 of file PhotonValidator.h.

Referenced by PhotonValidator().

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