#include <JetTester.h>

Inheritance diagram for JetTester:

Public Member Functions
virtual void	analyze (const edm::Event &, const edm::EventSetup &)

virtual void	bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override

	JetTester (const edm::ParameterSet &)

	~JetTester ()

Public Member Functions inherited from DQMEDAnalyzer
virtual void	beginRun (edm::Run const &, edm::EventSetup const &) final

virtual void	beginStream (edm::StreamID id) final

virtual void	dqmBeginRun (edm::Run const &, edm::EventSetup const &)

	DQMEDAnalyzer (void)

virtual void	endLuminosityBlockSummary (edm::LuminosityBlock const &, edm::EventSetup const &, dqmDetails::NoCache *) const final

virtual void	endRunSummary (edm::Run const &, edm::EventSetup const &, dqmDetails::NoCache *) const final

uint32_t	streamId () const

Public Member Functions inherited from edm::stream::EDAnalyzer< edm::RunSummaryCache< dqmDetails::NoCache >, edm::LuminosityBlockSummaryCache< dqmDetails::NoCache > >
	EDAnalyzer ()=default

Public Member Functions inherited from edm::stream::EDAnalyzerBase
	EDAnalyzerBase ()

ModuleDescription const &	moduleDescription () const

virtual	~EDAnalyzerBase ()

Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfo >	consumesInfo () const

	EDConsumerBase ()

ProductHolderIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const

void	itemsMayGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const

void	itemsToGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const

std::vector < ProductHolderIndexAndSkipBit > const &	itemsToGetFromEvent () const

void	labelsForToken (EDGetToken iToken, Labels &oLabels) const

void	modulesDependentUpon (const std::string &iProcessName, std::vector< const char * > &oModuleLabels) const

void	modulesWhoseProductsAreConsumed (std::vector< ModuleDescription const * > &modules, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const

bool	registeredToConsume (ProductHolderIndex, bool, BranchType) const

bool	registeredToConsumeMany (TypeID const &, BranchType) const

void	updateLookup (BranchType iBranchType, ProductHolderIndexHelper const &)

virtual	~EDConsumerBase ()

Private Member Functions
void	fillMatchHists (const double GenEta, const double GenPhi, const double GenPt, const double RecoEta, const double RecoPhi, const double RecoPt)

Private Attributes
edm::EDGetTokenT < reco::CaloJetCollection >	caloJetsToken_

MonitorElement *	chargedEmEnergy

MonitorElement *	chargedEmEnergyFraction

MonitorElement *	chargedHadronEnergy

MonitorElement *	chargedHadronEnergyFraction

MonitorElement *	chargedHadronMultiplicity

MonitorElement *	chargedMuEnergy

MonitorElement *	chargedMuEnergyFraction

MonitorElement *	chargedMultiplicity

MonitorElement *	electronEnergy

MonitorElement *	electronEnergyFraction

MonitorElement *	electronMultiplicity

MonitorElement *	emEnergyFraction

MonitorElement *	emEnergyInEB

MonitorElement *	emEnergyInEE

MonitorElement *	emEnergyInHF

MonitorElement *	energyFractionHadronic

edm::EDGetTokenT < GenEventInfoProduct >	evtToken_

edm::EDGetTokenT < reco::GenJetCollection >	genJetsToken_

MonitorElement *	hadEnergyInHB

MonitorElement *	hadEnergyInHE

MonitorElement *	hadEnergyInHF

MonitorElement *	hadEnergyInHO

MonitorElement *	HFEMEnergy

MonitorElement *	HFEMEnergyFraction

MonitorElement *	HFEMMultiplicity

MonitorElement *	HFHadronEnergy

MonitorElement *	HFHadronEnergyFraction

MonitorElement *	HFHadronMultiplicity

MonitorElement *	HOEnergy

MonitorElement *	HOEnergyFraction

bool	isCaloJet

bool	isMiniAODJet

bool	isPFJet

edm::EDGetTokenT < reco::JetCorrector >	jetCorrectorToken_

std::string	JetType

MonitorElement *	maxEInEmTowers

MonitorElement *	maxEInHadTowers

MonitorElement *	mConstituents

MonitorElement *	mCorrJetEta

MonitorElement *	mCorrJetEta_Pt40

MonitorElement *	mCorrJetPhi

MonitorElement *	mCorrJetPhi_Pt40

MonitorElement *	mCorrJetPt

MonitorElement *	mDeltaEta

MonitorElement *	mDeltaPhi

MonitorElement *	mDeltaPt

MonitorElement *	mEnergy

MonitorElement *	mEta

MonitorElement *	mEtaFirst

MonitorElement *	mGenEta

MonitorElement *	mGenEtaFirst

MonitorElement *	mGenPhi

MonitorElement *	mGenPhiFirst

MonitorElement *	mGenPt

edm::InputTag	mInputCollection

edm::InputTag	mInputGenCollection

MonitorElement *	mJetArea

edm::InputTag	mJetCorrector

MonitorElement *	mMass

double	mMatchGenPtThreshold

MonitorElement *	mMjj

MonitorElement *	mNJets1

MonitorElement *	mNJets2

MonitorElement *	mNJets_40

MonitorElement *	mNJetsEta_B_20_40

MonitorElement *	mNJetsEta_B_40

MonitorElement *	mNJetsEta_E_20_40

MonitorElement *	mNJetsEta_E_40

MonitorElement *	mNvtx

MonitorElement *	mP

MonitorElement *	mPhi

MonitorElement *	mPhiFirst

MonitorElement *	mPt

MonitorElement *	mPtCorrOverGen_GenEta_1500_3500

MonitorElement *	mPtCorrOverGen_GenEta_200_600

MonitorElement *	mPtCorrOverGen_GenEta_20_40

MonitorElement *	mPtCorrOverGen_GenEta_40_200

MonitorElement *	mPtCorrOverGen_GenEta_600_1500

MonitorElement *	mPtCorrOverGen_GenPt_B

MonitorElement *	mPtCorrOverGen_GenPt_E

MonitorElement *	mPtCorrOverGen_GenPt_F

MonitorElement *	mPtCorrOverReco_Eta_1500_3500

MonitorElement *	mPtCorrOverReco_Eta_200_600

MonitorElement *	mPtCorrOverReco_Eta_20_40

MonitorElement *	mPtCorrOverReco_Eta_40_200

MonitorElement *	mPtCorrOverReco_Eta_600_1500

MonitorElement *	mPtCorrOverReco_Pt_B

MonitorElement *	mPtCorrOverReco_Pt_E

MonitorElement *	mPtCorrOverReco_Pt_F

MonitorElement *	mPtFirst

MonitorElement *	mPtHat

MonitorElement *	mPtRecoOverGen_B_1500_3500

MonitorElement *	mPtRecoOverGen_B_200_600

MonitorElement *	mPtRecoOverGen_B_20_40

MonitorElement *	mPtRecoOverGen_B_40_200

MonitorElement *	mPtRecoOverGen_B_600_1500

MonitorElement *	mPtRecoOverGen_E_1500_3500

MonitorElement *	mPtRecoOverGen_E_200_600

MonitorElement *	mPtRecoOverGen_E_20_40

MonitorElement *	mPtRecoOverGen_E_40_200

MonitorElement *	mPtRecoOverGen_E_600_1500

MonitorElement *	mPtRecoOverGen_F_1500_3500

MonitorElement *	mPtRecoOverGen_F_200_600

MonitorElement *	mPtRecoOverGen_F_20_40

MonitorElement *	mPtRecoOverGen_F_40_200

MonitorElement *	mPtRecoOverGen_F_600_1500

MonitorElement *	mPtRecoOverGen_GenEta_1500_3500

MonitorElement *	mPtRecoOverGen_GenEta_200_600

MonitorElement *	mPtRecoOverGen_GenEta_20_40

MonitorElement *	mPtRecoOverGen_GenEta_40_200

MonitorElement *	mPtRecoOverGen_GenEta_600_1500

MonitorElement *	mPtRecoOverGen_GenPhi_B

MonitorElement *	mPtRecoOverGen_GenPhi_E

MonitorElement *	mPtRecoOverGen_GenPhi_F

MonitorElement *	mPtRecoOverGen_GenPt_B

MonitorElement *	mPtRecoOverGen_GenPt_E

MonitorElement *	mPtRecoOverGen_GenPt_F

double	mRecoJetPtThreshold

double	mRThreshold

MonitorElement *	muonEnergy

MonitorElement *	muonEnergyFraction

MonitorElement *	muonMultiplicity

MonitorElement *	n60

MonitorElement *	n90

MonitorElement *	neutralEmEnergy

MonitorElement *	neutralEmEnergyFraction

MonitorElement *	neutralHadronEnergy

MonitorElement *	neutralHadronEnergyFraction

MonitorElement *	neutralHadronMultiplicity

MonitorElement *	neutralMultiplicity

edm::EDGetTokenT < pat::JetCollection >	patJetsToken_

edm::EDGetTokenT < reco::PFJetCollection >	pfJetsToken_

MonitorElement *	photonEnergy

MonitorElement *	photonEnergyFraction

MonitorElement *	photonMultiplicity

edm::EDGetTokenT< std::vector < reco::Vertex > >	pvToken_

MonitorElement *	towersArea

Additional Inherited Members
Public Types inherited from edm::stream::EDAnalyzer< edm::RunSummaryCache< dqmDetails::NoCache >, edm::LuminosityBlockSummaryCache< dqmDetails::NoCache > >
typedef CacheContexts< T...>	CacheTypes

typedef CacheTypes::GlobalCache	GlobalCache

typedef AbilityChecker< T...>	HasAbility

typedef CacheTypes::LuminosityBlockCache	LuminosityBlockCache

typedef LuminosityBlockContextT < LuminosityBlockCache, RunCache, GlobalCache >	LuminosityBlockContext

typedef CacheTypes::LuminosityBlockSummaryCache	LuminosityBlockSummaryCache

typedef CacheTypes::RunCache	RunCache

typedef RunContextT< RunCache, GlobalCache >	RunContext

typedef CacheTypes::RunSummaryCache	RunSummaryCache

Public Types inherited from edm::stream::EDAnalyzerBase
typedef EDAnalyzerAdaptorBase	ModuleType

Static Public Member Functions inherited from DQMEDAnalyzer
static std::shared_ptr < dqmDetails::NoCache >	globalBeginLuminosityBlockSummary (edm::LuminosityBlock const &, edm::EventSetup const &, LuminosityBlockContext const *)

static std::shared_ptr < dqmDetails::NoCache >	globalBeginRunSummary (edm::Run const &, edm::EventSetup const &, RunContext const *)

static void	globalEndLuminosityBlockSummary (edm::LuminosityBlock const &, edm::EventSetup const &, LuminosityBlockContext const , dqmDetails::NoCache )

static void	globalEndRunSummary (edm::Run const &, edm::EventSetup const &, RunContext const , dqmDetails::NoCache )

Static Public Member Functions inherited from edm::stream::EDAnalyzerBase
static const std::string &	baseType ()

static void	fillDescriptions (ConfigurationDescriptions &descriptions)

static void	prevalidate (ConfigurationDescriptions &descriptions)

Protected Member Functions inherited from edm::stream::EDAnalyzerBase
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)

Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)

EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)

template<BranchType B>
EDGetToken	consumes (TypeToGet const &id, edm::InputTag const &tag)

ConsumesCollector	consumesCollector ()
	Use a ConsumesCollector to gather consumes information from helper functions. More...

template<typename ProductType , BranchType B = InEvent>
void	consumesMany ()

void	consumesMany (const TypeToGet &id)

template<BranchType B>
void	consumesMany (const TypeToGet &id)

template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)

EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

Detailed Description

Definition at line 43 of file JetTester.h.

Constructor & Destructor Documentation

JetTester::JetTester ( const edm::ParameterSet & iConfig )

returns the maximum energy deposited in ECAL towers

returns the maximum energy deposited in HCAL towers

returns the jet hadronic energy fraction

returns the jet electromagnetic energy fraction

returns the jet hadronic energy in HB

returns the jet hadronic energy in HO

returns the jet hadronic energy in HE

returns the jet hadronic energy in HF

returns the jet electromagnetic energy in EB

returns the jet electromagnetic energy in EE

returns the jet electromagnetic energy extracted from HF

returns area of contributing towers

returns the number of constituents carrying a 90% of the total Jet energy*/

returns the number of constituents carrying a 60% of the total Jet energy*/

chargedMultiplicity

muonMultiplicity

chargedMultiplicity

chargedEmEnergy

neutralEmEnergy

chargedHadronEnergy

neutralHadronEnergy

chargedHadronEnergyFraction (relative to uncorrected jet energy)

neutralHadronEnergyFraction (relative to uncorrected jet energy)

chargedEmEnergyFraction (relative to uncorrected jet energy)

neutralEmEnergyFraction (relative to uncorrected jet energy)

photonEnergy

photonEnergyFraction (relative to corrected jet energy)

electronEnergy

electronEnergyFraction (relative to corrected jet energy)

muonEnergy

muonEnergyFraction (relative to corrected jet energy)

HFHadronEnergy

HFHadronEnergyFraction (relative to corrected jet energy)

HFEMEnergy

HFEMEnergyFraction (relative to corrected jet energy)

chargedHadronMultiplicity

neutralHadronMultiplicity

photonMultiplicity

electronMultiplicity

HFHadronMultiplicity

HFEMMultiplicity

chargedMuEnergy

chargedMuEnergyFraction

neutralMultiplicity

HOEnergy

HOEnergyFraction (relative to corrected jet energy)

Definition at line 12 of file JetTester.cc.

References caloJetsToken_, chargedEmEnergy, chargedEmEnergyFraction, chargedHadronEnergy, chargedHadronEnergyFraction, chargedHadronMultiplicity, chargedMuEnergy, chargedMuEnergyFraction, chargedMultiplicity, electronEnergy, electronEnergyFraction, electronMultiplicity, emEnergyFraction, emEnergyInEB, emEnergyInEE, emEnergyInHF, energyFractionHadronic, evtToken_, genJetsToken_, edm::ParameterSet::getParameter(), hadEnergyInHB, hadEnergyInHE, hadEnergyInHF, hadEnergyInHO, HFEMEnergy, HFEMEnergyFraction, HFEMMultiplicity, HFHadronEnergy, HFHadronEnergyFraction, HFHadronMultiplicity, HOEnergy, HOEnergyFraction, HLT_25ns14e33_v1_cff::InputTag, isCaloJet, isMiniAODJet, isPFJet, jetCorrectorToken_, JetType, edm::InputTag::label(), maxEInEmTowers, maxEInHadTowers, mConstituents, mCorrJetEta, mCorrJetEta_Pt40, mCorrJetPhi, mCorrJetPhi_Pt40, mCorrJetPt, mDeltaEta, mDeltaPhi, mDeltaPt, mEnergy, mEta, mEtaFirst, mGenEta, mGenEtaFirst, mGenPhi, mGenPhiFirst, mGenPt, mInputCollection, mInputGenCollection, mJetArea, mJetCorrector, mMass, mMjj, mNJets1, mNJets2, mNJetsEta_B_20_40, mNJetsEta_B_40, mNJetsEta_E_20_40, mNJetsEta_E_40, mNvtx, mP, mPhi, mPhiFirst, mPt, mPtCorrOverGen_GenEta_1500_3500, mPtCorrOverGen_GenEta_200_600, mPtCorrOverGen_GenEta_20_40, mPtCorrOverGen_GenEta_40_200, mPtCorrOverGen_GenEta_600_1500, mPtCorrOverGen_GenPt_B, mPtCorrOverGen_GenPt_E, mPtCorrOverGen_GenPt_F, mPtCorrOverReco_Eta_1500_3500, mPtCorrOverReco_Eta_200_600, mPtCorrOverReco_Eta_20_40, mPtCorrOverReco_Eta_40_200, mPtCorrOverReco_Eta_600_1500, mPtCorrOverReco_Pt_B, mPtCorrOverReco_Pt_E, mPtCorrOverReco_Pt_F, mPtFirst, mPtHat, mPtRecoOverGen_B_1500_3500, mPtRecoOverGen_B_200_600, mPtRecoOverGen_B_20_40, mPtRecoOverGen_B_40_200, mPtRecoOverGen_B_600_1500, mPtRecoOverGen_E_1500_3500, mPtRecoOverGen_E_200_600, mPtRecoOverGen_E_20_40, mPtRecoOverGen_E_40_200, mPtRecoOverGen_E_600_1500, mPtRecoOverGen_F_1500_3500, mPtRecoOverGen_F_200_600, mPtRecoOverGen_F_20_40, mPtRecoOverGen_F_40_200, mPtRecoOverGen_F_600_1500, mPtRecoOverGen_GenEta_1500_3500, mPtRecoOverGen_GenEta_200_600, mPtRecoOverGen_GenEta_20_40, mPtRecoOverGen_GenEta_40_200, mPtRecoOverGen_GenEta_600_1500, mPtRecoOverGen_GenPhi_B, mPtRecoOverGen_GenPhi_E, mPtRecoOverGen_GenPhi_F, mPtRecoOverGen_GenPt_B, mPtRecoOverGen_GenPt_E, mPtRecoOverGen_GenPt_F, muonEnergy, muonEnergyFraction, muonMultiplicity, n60, n90, neutralEmEnergy, neutralEmEnergyFraction, neutralHadronEnergy, neutralHadronEnergyFraction, neutralHadronMultiplicity, neutralMultiplicity, patJetsToken_, pfJetsToken_, photonEnergy, photonEnergyFraction, photonMultiplicity, pvToken_, AlCaHLTBitMon_QueryRunRegistry::string, and towersArea.

                                                    :
   mInputCollection               (iConfig.getParameter<edm::InputTag>       ("src")),
 //  rhoTag                         (iConfig.getParameter<edm::InputTag>       ("srcRho")), 
   JetType                        (iConfig.getUntrackedParameter<std::string>("JetType")),
   mRecoJetPtThreshold            (iConfig.getParameter<double>              ("recoJetPtThreshold")),
   mMatchGenPtThreshold           (iConfig.getParameter<double>              ("matchGenPtThreshold")),
   mRThreshold                    (iConfig.getParameter<double>              ("RThreshold"))
 {
   std::string inputCollectionLabel(mInputCollection.label());
 
   isCaloJet = (std::string("calo")==JetType);
   isPFJet   = (std::string("pf")  ==JetType);
   isMiniAODJet = (std::string("miniaod")  ==JetType);
   if(!isMiniAODJet){
     mJetCorrector                  =iConfig.getParameter<edm::InputTag>("JetCorrections"); 
   } 
 
   //consumes
   pvToken_ = consumes<std::vector<reco::Vertex> >(iConfig.getParameter<edm::InputTag>("primVertex"));
   if (isCaloJet) caloJetsToken_  = consumes<reco::CaloJetCollection>(mInputCollection);
   if (isPFJet)   pfJetsToken_    = consumes<reco::PFJetCollection>(mInputCollection);
   if(isMiniAODJet)patJetsToken_ = consumes<pat::JetCollection>(mInputCollection);
   mInputGenCollection            =iConfig.getParameter<edm::InputTag>("srcGen");
   genJetsToken_ = consumes<reco::GenJetCollection>(edm::InputTag(mInputGenCollection));
   evtToken_ = consumes<GenEventInfoProduct>(edm::InputTag("generator"));
   if(!isMiniAODJet && !mJetCorrector.label().empty()){
     jetCorrectorToken_ = consumes<reco::JetCorrector>(mJetCorrector);
   }
   
   // Events variables
   mNvtx           = 0;
 
   // Jet parameters
   mEta          = 0;
   mPhi          = 0;
   mEnergy       = 0;
   mP            = 0;
   mPt           = 0;
   mMass         = 0;
   mConstituents = 0;
   mJetArea      = 0;
 //  mRho          = 0;
 
   // Corrected jets
   mCorrJetPt  = 0;
   mCorrJetEta = 0;
   mCorrJetPhi = 0;
   mCorrJetEta_Pt40 = 0;
   mCorrJetPhi_Pt40 = 0;
 
   // Corrected jets profiles
   mPtCorrOverReco_Pt_B                = 0;
   mPtCorrOverReco_Pt_E                = 0;
   mPtCorrOverReco_Pt_F                = 0;
   mPtCorrOverReco_Eta_20_40          = 0;
   mPtCorrOverReco_Eta_40_200          = 0;
   mPtCorrOverReco_Eta_200_600         = 0;
   mPtCorrOverReco_Eta_600_1500        = 0;
   mPtCorrOverReco_Eta_1500_3500       = 0;
   mPtCorrOverGen_GenPt_B          = 0;
   mPtCorrOverGen_GenPt_E          = 0;
   mPtCorrOverGen_GenPt_F          = 0;
   mPtCorrOverGen_GenEta_20_40    = 0;
   mPtCorrOverGen_GenEta_40_200    = 0;
   mPtCorrOverGen_GenEta_200_600   = 0;
   mPtCorrOverGen_GenEta_600_1500  = 0;
   mPtCorrOverGen_GenEta_1500_3500 = 0;
 
   // Generation
   mGenEta      = 0;
   mGenPhi      = 0;
   mGenPt       = 0;
   mGenEtaFirst = 0;
   mGenPhiFirst = 0;
   mPtHat       = 0;
   mDeltaEta    = 0;
   mDeltaPhi    = 0;
   mDeltaPt     = 0;
 
   mPtRecoOverGen_B_20_40    = 0;
   mPtRecoOverGen_E_20_40    = 0;
   mPtRecoOverGen_F_20_40    = 0;
   mPtRecoOverGen_B_40_200    = 0;
   mPtRecoOverGen_E_40_200    = 0;
   mPtRecoOverGen_F_40_200    = 0;
   mPtRecoOverGen_B_200_600   = 0;
   mPtRecoOverGen_E_200_600   = 0;
   mPtRecoOverGen_F_200_600   = 0;
   mPtRecoOverGen_B_600_1500  = 0;
   mPtRecoOverGen_E_600_1500  = 0;
   mPtRecoOverGen_F_600_1500  = 0;
   mPtRecoOverGen_B_1500_3500 = 0;
   mPtRecoOverGen_E_1500_3500 = 0;
   mPtRecoOverGen_F_1500_3500 = 0;
 
   // Generation profiles
   mPtRecoOverGen_GenPt_B          = 0;
   mPtRecoOverGen_GenPt_E          = 0;
   mPtRecoOverGen_GenPt_F          = 0;
   mPtRecoOverGen_GenPhi_B         = 0;
   mPtRecoOverGen_GenPhi_E         = 0;
   mPtRecoOverGen_GenPhi_F         = 0;
   mPtRecoOverGen_GenEta_20_40    = 0;
   mPtRecoOverGen_GenEta_40_200    = 0;
   mPtRecoOverGen_GenEta_200_600   = 0;
   mPtRecoOverGen_GenEta_600_1500  = 0;
   mPtRecoOverGen_GenEta_1500_3500 = 0;
 
   // Some jet algebra
   mEtaFirst   = 0;
   mPhiFirst   = 0;
   mPtFirst    = 0;
   mMjj        = 0;
   mNJetsEta_B_20_40 = 0;
   mNJetsEta_E_20_40 = 0;
   mNJetsEta_B_40 = 0;
   mNJetsEta_E_40 = 0;
   mNJets1     = 0;
   mNJets2     = 0;
 
 //  // PFJet specific
 //  mHadEnergyInHF       = 0;
 //  mEmEnergyInHF        = 0;
 //  mChargedEmEnergy     = 0;
 //  mChargedHadronEnergy = 0;
 //  mNeutralEmEnergy     = 0;
 //  mNeutralHadronEnergy = 0;
 
   // ---- Calo Jet specific information ----
   maxEInEmTowers = 0;
   maxEInHadTowers = 0;
   energyFractionHadronic = 0;
   emEnergyFraction = 0;
   hadEnergyInHB = 0;
   hadEnergyInHO = 0;
   hadEnergyInHE = 0;
   hadEnergyInHF = 0;
   emEnergyInEB = 0;
   emEnergyInEE = 0;
   emEnergyInHF = 0;
   towersArea = 0;
   n90 = 0;
   n60 = 0;
 
   // ---- JPT Jet specific information ----
 //  elecMultiplicity = 0;
 
   // ---- JPT or PF Jet specific information ----
   muonMultiplicity = 0;
   chargedMultiplicity = 0;
   chargedEmEnergy = 0;
   neutralEmEnergy = 0;
   chargedHadronEnergy = 0;
   neutralHadronEnergy = 0;
   chargedHadronEnergyFraction = 0;
   neutralHadronEnergyFraction = 0;
   chargedEmEnergyFraction = 0;
   neutralEmEnergyFraction = 0;
 
   // ---- PF Jet specific information ----
   photonEnergy = 0;
   photonEnergyFraction = 0;
   electronEnergy = 0;
   electronEnergyFraction = 0;
   muonEnergy = 0;
   muonEnergyFraction = 0;
   HFHadronEnergy = 0;
   HFHadronEnergyFraction = 0;
   HFEMEnergy = 0;
   HFEMEnergyFraction = 0;
   chargedHadronMultiplicity = 0;
   neutralHadronMultiplicity = 0;
   photonMultiplicity = 0;
   electronMultiplicity = 0;
   HFHadronMultiplicity = 0;
   HFEMMultiplicity = 0;
   chargedMuEnergy = 0;
   chargedMuEnergyFraction = 0;
   neutralMultiplicity = 0;
 
   HOEnergy = 0;
   HOEnergyFraction = 0;
 }

JetTester::~JetTester ( )

Definition at line 416 of file JetTester.cc.

416 {}

Member Function Documentation

void JetTester::analyze	(	const edm::Event &	mEvent,
		const edm::EventSetup &	mSetup
	)

virtual

Implements edm::stream::EDAnalyzerBase.

Definition at line 422 of file JetTester.cc.

References caloJetsToken_, chargedEmEnergy, chargedEmEnergyFraction, chargedHadronEnergy, chargedHadronEnergyFraction, chargedHadronMultiplicity, chargedMuEnergy, chargedMuEnergyFraction, chargedMultiplicity, deltaR(), electronEnergy, electronEnergyFraction, electronMultiplicity, emEnergyFraction, emEnergyInEB, emEnergyInEE, emEnergyInHF, relval_parameters_module::energy, energyFractionHadronic, reco::LeafCandidate::eta(), eta(), evtToken_, MonitorElement::Fill(), HcalObjRepresent::Fill(), fillMatchHists(), genJetsToken_, edm::Event::getByToken(), hadEnergyInHB, hadEnergyInHE, hadEnergyInHF, hadEnergyInHO, HFEMEnergy, HFEMEnergyFraction, HFEMMultiplicity, HFHadronEnergy, HFHadronEnergyFraction, HFHadronMultiplicity, HOEnergy, HOEnergyFraction, i, isCaloJet, isMiniAODJet, isPFJet, edm::EventBase::isRealData(), edm::HandleBase::isValid(), jetCorrectorToken_, edm::InputTag::label(), maxEInEmTowers, maxEInHadTowers, mConstituents, mCorrJetEta, mCorrJetEta_Pt40, mCorrJetPhi, mCorrJetPhi_Pt40, mCorrJetPt, mEnergy, mEta, mEtaFirst, mGenEta, mGenEtaFirst, mGenPhi, mGenPhiFirst, mGenPt, mInputGenCollection, mJetArea, mJetCorrector, mMass, mMatchGenPtThreshold, mMjj, mNJets1, mNJets2, mNJets_40, mNJetsEta_B_20_40, mNJetsEta_B_40, mNJetsEta_E_20_40, mNJetsEta_E_40, mNvtx, mP, mPhi, mPhiFirst, mPt, mPtCorrOverGen_GenEta_1500_3500, mPtCorrOverGen_GenEta_200_600, mPtCorrOverGen_GenEta_20_40, mPtCorrOverGen_GenEta_40_200, mPtCorrOverGen_GenEta_600_1500, mPtCorrOverGen_GenPt_B, mPtCorrOverGen_GenPt_E, mPtCorrOverGen_GenPt_F, mPtCorrOverReco_Eta_1500_3500, mPtCorrOverReco_Eta_200_600, mPtCorrOverReco_Eta_20_40, mPtCorrOverReco_Eta_40_200, mPtCorrOverReco_Eta_600_1500, mPtCorrOverReco_Pt_B, mPtCorrOverReco_Pt_E, mPtCorrOverReco_Pt_F, mPtFirst, mPtHat, mRecoJetPtThreshold, mRThreshold, muonEnergy, muonEnergyFraction, muonMultiplicity, n60, n90, neutralEmEnergy, neutralEmEnergyFraction, neutralHadronEnergy, neutralHadronEnergyFraction, neutralHadronMultiplicity, neutralMultiplicity, AlCaHLTBitMon_ParallelJobs::p, jetProducer_cfi::patJets, patJetsToken_, pfJets_cff::pfJets, pfJetsToken_, phi, reco::LeafCandidate::phi(), photonEnergy, photonEnergyFraction, photonMultiplicity, position, EnergyCorrector::pt, reco::LeafCandidate::pt(), pvToken_, RecoJets_cff::recoJets, rho, pileupReCalc_HLTpaths::scale, reco::Jet::scaleEnergy(), towersArea, and detailsBasic3DVector::z.

 {
   // Get the primary vertices
   //----------------------------------------------------------------------------
   edm::Handle<vector<reco::Vertex> > pvHandle;
   mEvent.getByToken(pvToken_, pvHandle);
 
   int nGoodVertices = 0;
 
   if (pvHandle.isValid())
     {
       for (unsigned i=0; i<pvHandle->size(); i++)
     {
       if ((*pvHandle)[i].ndof() > 4 &&
           (fabs((*pvHandle)[i].z()) <= 24) &&
           (fabs((*pvHandle)[i].position().rho()) <= 2))
         nGoodVertices++;
     }
     }
 
   mNvtx->Fill(nGoodVertices);
 
 //  // Get the jet rho
 //  //----------------------------------------------------------------------------
 //  edm::Handle<double> pRho;
 //  mEvent.getByToken(rhoTag, pRho);
 //
 //  if (pRho.isValid())
 //    {
 //      double jetRho = *pRho;
 //
 //      if (mRho) mRho->Fill(jetRho);
 //    }
 
 
   // Get the Jet collection
   //----------------------------------------------------------------------------
   math::XYZTLorentzVector p4tmp[2];
 
   std::vector<Jet> recoJets;
   recoJets.clear();
 
   edm::Handle<CaloJetCollection> caloJets;
   edm::Handle<PFJetCollection>   pfJets;
 //  edm::Handle<JPTJetCollection>  jptJets;
   edm::Handle<pat::JetCollection> patJets;
 
   if (isCaloJet) mEvent.getByToken(caloJetsToken_, caloJets);
   if (isPFJet)   mEvent.getByToken(pfJetsToken_, pfJets);
 //  if (isJPTJet)  mEvent.getByToken(jptJetsToken_, jptJets);
   if (isMiniAODJet)   mEvent.getByToken(patJetsToken_, patJets);
 
   if (isCaloJet && !caloJets.isValid()) return;
   if (isPFJet   && !pfJets.isValid())   return;
 //  if (isJPTJet  && !jptJets.isValid())  return;
  if (isMiniAODJet   && !patJets.isValid())   return;
 
 
   if (isCaloJet)
     {
       for (unsigned ijet=0; ijet<caloJets->size(); ijet++)
     recoJets.push_back((*caloJets)[ijet]);
     }
 
 /*  if (isJPTJet)
     {
       for (unsigned ijet=0; ijet<jptJets->size(); ijet++)
     recoJets.push_back((*jptJets)[ijet]);
     }*/
 
   if (isPFJet) {
     for (unsigned ijet=0; ijet<pfJets->size(); ijet++)
       recoJets.push_back((*pfJets)[ijet]);
   }
   if (isMiniAODJet) {
     for (unsigned ijet=0; ijet<patJets->size(); ijet++)
       recoJets.push_back((*patJets)[ijet]);
   }
 
   int nJet      = 0;
   int nJet_E_20_40 = 0;
   int nJet_B_20_40 = 0;
   int nJet_E_40 = 0;
   int nJet_B_40 = 0;
   int nJet_40 = 0;
 
   int index_first_jet=-1;
   double pt_first=-1;
 
  int index_second_jet=-1;
  double pt_second=-1;
 
   for (unsigned ijet=0; ijet<recoJets.size(); ijet++) {
     bool pass_lowjet=false;
     bool pass_mediumjet = false;
     if(!isMiniAODJet){
       if (  (recoJets[ijet].pt() > 20.) &&  (recoJets[ijet].pt() < mRecoJetPtThreshold)) {
     pass_lowjet=true;
       }
     }
     if(isMiniAODJet){
       if((recoJets[ijet].pt()*(*patJets)[ijet].jecFactor("Uncorrected"))>20. && ((recoJets[ijet].pt()*(*patJets)[ijet].jecFactor("Uncorrected")) < mRecoJetPtThreshold)){
     pass_lowjet=true;
       }
     }
     if (pass_lowjet) {
       if (fabs(recoJets[ijet].eta()) > 1.5)
         nJet_E_20_40++;
       else
         nJet_B_20_40++;   
     }
     if(!isMiniAODJet){
       if (recoJets[ijet].pt() > mRecoJetPtThreshold) {
     pass_mediumjet = true;
       }
     }
     if(isMiniAODJet){
       if((recoJets[ijet].pt()*(*patJets)[ijet].jecFactor("Uncorrected")) > mRecoJetPtThreshold){
     pass_mediumjet=true;
       }
     }
     if (pass_mediumjet) {
       if(isMiniAODJet){
     if( (recoJets[ijet].pt()*(*patJets)[ijet].jecFactor("Uncorrected"))>pt_first){
       pt_second=pt_first;
       pt_first=recoJets[ijet].pt()*(*patJets)[ijet].jecFactor("Uncorrected");
       index_second_jet=index_first_jet;
       index_first_jet=ijet;
     }else if( (recoJets[ijet].pt()*(*patJets)[ijet].jecFactor("Uncorrected"))>pt_second){
       index_second_jet=ijet;
       pt_second=recoJets[ijet].pt()*(*patJets)[ijet].jecFactor("Uncorrected");
     }
       }
       //counting forward and barrel jets
       if (fabs(recoJets[ijet].eta()) > 1.5)
         nJet_E_40++;
       else
         nJet_B_40++;      
       nJet_40++;
 
       if (mEta) mEta->Fill(recoJets[ijet].eta());
 
       if (mJetArea)      mJetArea     ->Fill(recoJets[ijet].jetArea());
       if (mPhi)          mPhi         ->Fill(recoJets[ijet].phi());
       if(!isMiniAODJet){
     if (mEnergy)       mEnergy      ->Fill(recoJets[ijet].energy());
     if (mP)            mP           ->Fill(recoJets[ijet].p());
     if (mPt)           mPt          ->Fill(recoJets[ijet].pt());
     if (mMass)         mMass        ->Fill(recoJets[ijet].mass());
       }else{
     if (mEnergy)       mEnergy      ->Fill(recoJets[ijet].energy()*(*patJets)[ijet].jecFactor("Uncorrected"));
     if (mP)            mP           ->Fill(recoJets[ijet].p()*(*patJets)[ijet].jecFactor("Uncorrected"));
     if (mPt)           mPt          ->Fill(recoJets[ijet].pt()*(*patJets)[ijet].jecFactor("Uncorrected"));
     if (mMass)         mMass        ->Fill(recoJets[ijet].mass()*(*patJets)[ijet].jecFactor("Uncorrected"));
       }
       if (mConstituents) mConstituents->Fill(recoJets[ijet].nConstituents());
       if(!isMiniAODJet){
     if (ijet == 0) {
       if (mEtaFirst) mEtaFirst->Fill(recoJets[ijet].eta());
       if (mPhiFirst) mPhiFirst->Fill(recoJets[ijet].phi());
       if (mPtFirst)  mPtFirst ->Fill(recoJets[ijet].pt());
     }
 
     if (ijet == 0) {nJet++; p4tmp[0] = recoJets[ijet].p4();}
     if (ijet == 1) {nJet++; p4tmp[1] = recoJets[ijet].p4();}
       }
   //    if (isPFJet || isCaloJet) {
   //      if (mHadEnergyInHF)       mHadEnergyInHF      ->Fill((*pfJets)[ijet].HFHadronEnergy());
   //      if (mEmEnergyInHF)        mEmEnergyInHF       ->Fill((*pfJets)[ijet].HFEMEnergy());
   //      if (mChargedEmEnergy)     mChargedEmEnergy    ->Fill((*pfJets)[ijet].chargedEmEnergy());
   //      if (mChargedHadronEnergy) mChargedHadronEnergy->Fill((*pfJets)[ijet].chargedHadronEnergy());
   //      if (mNeutralEmEnergy)     mNeutralEmEnergy    ->Fill((*pfJets)[ijet].neutralEmEnergy());
   //      if (mNeutralHadronEnergy) mNeutralHadronEnergy->Fill((*pfJets)[ijet].neutralHadronEnergy());
   //    }
 
 
       // ---- Calo Jet specific information ----
       if (isCaloJet) {
         maxEInEmTowers              ->Fill((*caloJets)[ijet].maxEInEmTowers());
         maxEInHadTowers             ->Fill((*caloJets)[ijet].maxEInHadTowers());
         energyFractionHadronic      ->Fill((*caloJets)[ijet].energyFractionHadronic());
         emEnergyFraction            ->Fill((*caloJets)[ijet].emEnergyFraction());
         hadEnergyInHB               ->Fill((*caloJets)[ijet].hadEnergyInHB());
         hadEnergyInHO               ->Fill((*caloJets)[ijet].hadEnergyInHO());
         hadEnergyInHE               ->Fill((*caloJets)[ijet].hadEnergyInHE());
         hadEnergyInHF               ->Fill((*caloJets)[ijet].hadEnergyInHF());
         emEnergyInEB                ->Fill((*caloJets)[ijet].emEnergyInEB());
         emEnergyInEE                ->Fill((*caloJets)[ijet].emEnergyInEE());
         emEnergyInHF                ->Fill((*caloJets)[ijet].emEnergyInHF());
         towersArea                  ->Fill((*caloJets)[ijet].towersArea());
         n90                         ->Fill((*caloJets)[ijet].n90());
         n60                         ->Fill((*caloJets)[ijet].n60());
       }
       // ---- PF Jet specific information ----
       if (isPFJet) {
         muonMultiplicity ->Fill((*pfJets)[ijet].muonMultiplicity());
         chargedMultiplicity ->Fill((*pfJets)[ijet].chargedMultiplicity());
         chargedEmEnergy ->Fill((*pfJets)[ijet].chargedEmEnergy());
         neutralEmEnergy ->Fill((*pfJets)[ijet].neutralEmEnergy());
         chargedHadronEnergy ->Fill((*pfJets)[ijet].chargedHadronEnergy());
         neutralHadronEnergy ->Fill((*pfJets)[ijet].neutralHadronEnergy());
         chargedHadronEnergyFraction ->Fill((*pfJets)[ijet].chargedHadronEnergyFraction());
         neutralHadronEnergyFraction ->Fill((*pfJets)[ijet].neutralHadronEnergyFraction());
         chargedEmEnergyFraction ->Fill((*pfJets)[ijet].chargedEmEnergyFraction());
         neutralEmEnergyFraction ->Fill((*pfJets)[ijet].neutralEmEnergyFraction());
         photonEnergy ->Fill((*pfJets)[ijet].photonEnergy());
         photonEnergyFraction ->Fill((*pfJets)[ijet].photonEnergyFraction());
         electronEnergy ->Fill((*pfJets)[ijet].electronEnergy());
         electronEnergyFraction ->Fill((*pfJets)[ijet].electronEnergyFraction());
         muonEnergy ->Fill((*pfJets)[ijet].muonEnergy());
         muonEnergyFraction ->Fill((*pfJets)[ijet].muonEnergyFraction());
         HFHadronEnergy ->Fill((*pfJets)[ijet].HFHadronEnergy());
         HFHadronEnergyFraction ->Fill((*pfJets)[ijet].HFHadronEnergyFraction());
         HFEMEnergy ->Fill((*pfJets)[ijet].HFEMEnergy());
         HFEMEnergyFraction ->Fill((*pfJets)[ijet].HFEMEnergyFraction());
         chargedHadronMultiplicity ->Fill((*pfJets)[ijet].chargedHadronMultiplicity());
         neutralHadronMultiplicity ->Fill((*pfJets)[ijet].neutralHadronMultiplicity());
         photonMultiplicity ->Fill((*pfJets)[ijet].photonMultiplicity());
         electronMultiplicity ->Fill((*pfJets)[ijet].electronMultiplicity());
         HFHadronMultiplicity ->Fill((*pfJets)[ijet].HFHadronMultiplicity());
         HFEMMultiplicity ->Fill((*pfJets)[ijet].HFEMMultiplicity());
         chargedMuEnergy ->Fill((*pfJets)[ijet].chargedMuEnergy());
         chargedMuEnergyFraction ->Fill((*pfJets)[ijet].chargedMuEnergyFraction());
         neutralMultiplicity ->Fill((*pfJets)[ijet].neutralMultiplicity()); 
         HOEnergy ->Fill((*pfJets)[ijet].hoEnergy());
         HOEnergyFraction ->Fill((*pfJets)[ijet].hoEnergyFraction());
      }
    if (isMiniAODJet && (*patJets)[ijet].isPFJet()) {
         muonMultiplicity ->Fill((*patJets)[ijet].muonMultiplicity());
         chargedMultiplicity ->Fill((*patJets)[ijet].chargedMultiplicity());
         chargedEmEnergy ->Fill((*patJets)[ijet].chargedEmEnergy());
         neutralEmEnergy ->Fill((*patJets)[ijet].neutralEmEnergy());
         chargedHadronEnergy ->Fill((*patJets)[ijet].chargedHadronEnergy());
         neutralHadronEnergy ->Fill((*patJets)[ijet].neutralHadronEnergy());
         chargedHadronEnergyFraction ->Fill((*patJets)[ijet].chargedHadronEnergyFraction());
         neutralHadronEnergyFraction ->Fill((*patJets)[ijet].neutralHadronEnergyFraction());
         chargedEmEnergyFraction ->Fill((*patJets)[ijet].chargedEmEnergyFraction());
         neutralEmEnergyFraction ->Fill((*patJets)[ijet].neutralEmEnergyFraction());
         photonEnergy ->Fill((*patJets)[ijet].photonEnergy());
         photonEnergyFraction ->Fill((*patJets)[ijet].photonEnergyFraction());
         electronEnergy ->Fill((*patJets)[ijet].electronEnergy());
         electronEnergyFraction ->Fill((*patJets)[ijet].electronEnergyFraction());
         muonEnergy ->Fill((*patJets)[ijet].muonEnergy());
         muonEnergyFraction ->Fill((*patJets)[ijet].muonEnergyFraction());
         HFHadronEnergy ->Fill((*patJets)[ijet].HFHadronEnergy());
         HFHadronEnergyFraction ->Fill((*patJets)[ijet].HFHadronEnergyFraction());
         HFEMEnergy ->Fill((*patJets)[ijet].HFEMEnergy());
         HFEMEnergyFraction ->Fill((*patJets)[ijet].HFEMEnergyFraction());
         chargedHadronMultiplicity ->Fill((*patJets)[ijet].chargedHadronMultiplicity());
         neutralHadronMultiplicity ->Fill((*patJets)[ijet].neutralHadronMultiplicity());
         photonMultiplicity ->Fill((*patJets)[ijet].photonMultiplicity());
         electronMultiplicity ->Fill((*patJets)[ijet].electronMultiplicity());
         HFHadronMultiplicity ->Fill((*patJets)[ijet].HFHadronMultiplicity());
         HFEMMultiplicity ->Fill((*patJets)[ijet].HFEMMultiplicity());
         chargedMuEnergy ->Fill((*patJets)[ijet].chargedMuEnergy());
         chargedMuEnergyFraction ->Fill((*patJets)[ijet].chargedMuEnergyFraction());
         neutralMultiplicity ->Fill((*patJets)[ijet].neutralMultiplicity()); 
         HOEnergy ->Fill((*patJets)[ijet].hoEnergy());
         HOEnergyFraction ->Fill((*patJets)[ijet].hoEnergyFraction());
       }
     }//fill quantities for medium jets
   }
 
   if (mNJetsEta_B_20_40) mNJetsEta_B_20_40->Fill(nJet_B_20_40);
   if (mNJetsEta_E_20_40) mNJetsEta_E_20_40->Fill(nJet_E_20_40);
   if (mNJetsEta_B_40) mNJetsEta_B_40->Fill(nJet_B_40);
   if (mNJetsEta_E_40) mNJetsEta_E_40->Fill(nJet_E_40);
   if (mNJets_40) mNJets_40->Fill(nJet_40); 
   if(!isMiniAODJet){
     if (nJet >= 2)
       {
     if (mMjj) mMjj->Fill((p4tmp[0]+p4tmp[1]).mass());
       }
   }else{
     if(index_first_jet>-1){
       if (mEtaFirst) mEtaFirst->Fill(recoJets[index_first_jet].eta());
       if (mPhiFirst) mPhiFirst->Fill(recoJets[index_first_jet].phi());
       if (mPtFirst)  mPtFirst ->Fill(recoJets[index_first_jet].pt()*(*patJets)[index_first_jet].jecFactor("Uncorrected"));
       nJet++; p4tmp[0] = recoJets[index_first_jet].p4()*(*patJets)[index_first_jet].jecFactor("Uncorrected");
     }
     if(index_second_jet>-1){
       nJet++; p4tmp[1] = recoJets[index_second_jet].p4()*(*patJets)[index_second_jet].jecFactor("Uncorrected");
     }
     if (nJet >= 2)
       {
     if (mMjj) mMjj->Fill((p4tmp[0]+p4tmp[1]).mass());
       }
   }
 
   // Count jets above pt cut
   //----------------------------------------------------------------------------
   for (int istep=0; istep<100; ++istep)
     {
       int njets1 = 0;
       int njets2 = 0;
 
       float ptStep1 = (istep * ( 200. / 100.));
       float ptStep2 = (istep * (4000. / 100.));
 
       for (unsigned ijet=0; ijet<recoJets.size(); ijet++) {
     if(!isMiniAODJet){
       if (recoJets[ijet].pt() > ptStep1) njets1++;
       if (recoJets[ijet].pt() > ptStep2) njets2++;
     }else{
       if ((recoJets[ijet].pt()*(*patJets)[ijet].jecFactor("Uncorrected")) > ptStep1) njets1++;
       if ((recoJets[ijet].pt()*(*patJets)[ijet].jecFactor("Uncorrected")) > ptStep2) njets2++;
     }
     mNJets1->Fill(ptStep1, njets1);
     mNJets2->Fill(ptStep2, njets2);
       }
     }
 
 
   // Corrected jets
   //----------------------------------------------------------------------------
   double scale = -999;
   edm::Handle<reco::JetCorrector> jetCorr;
   bool pass_correction_flag =false;
   if(!isMiniAODJet && !mJetCorrector.label().empty()){
     mEvent.getByToken(jetCorrectorToken_, jetCorr);
     if (jetCorr.isValid()){
       pass_correction_flag=true;
     }
   }
   if(isMiniAODJet){
     pass_correction_flag =true;
   }
   for (unsigned ijet=0; ijet<recoJets.size(); ijet++) {
     Jet correctedJet = recoJets[ijet];
     if(pass_correction_flag){
       if (isCaloJet) scale = jetCorr->correction((*caloJets)[ijet]); 
       if (isPFJet)   scale = jetCorr->correction((*pfJets)[ijet]); 
       //if (isJPTJet)  scale = jetCorr->correction((*jptJets)[ijet]);
       if(!isMiniAODJet){
     correctedJet.scaleEnergy(scale); 
       }
       
       if (correctedJet.pt() < 20) continue;
       
       mCorrJetEta->Fill(correctedJet.eta());
       mCorrJetPhi->Fill(correctedJet.phi());
       mCorrJetPt ->Fill(correctedJet.pt());
       if (correctedJet.pt() >= 40) {
     mCorrJetEta_Pt40->Fill(correctedJet.eta()); 
     mCorrJetPhi_Pt40->Fill(correctedJet.phi());
       }
       
       double ijetEta = recoJets[ijet].eta();
       double ijetPt  = recoJets[ijet].pt();
       if(isMiniAODJet){
     ijetPt=recoJets[ijet].pt()*(*patJets)[ijet].jecFactor("Uncorrected");
       }
       double ratio   = correctedJet.pt() / ijetPt;
       if(isMiniAODJet){
     ratio =1./(*patJets)[ijet].jecFactor("Uncorrected");
       }
       
       if      (fabs(ijetEta) < 1.5) mPtCorrOverReco_Pt_B->Fill(log10(ijetPt), ratio);
       else if (fabs(ijetEta) < 3.0) mPtCorrOverReco_Pt_E->Fill(log10(ijetPt), ratio);
       else if (fabs(ijetEta) < 6.0) mPtCorrOverReco_Pt_F->Fill(log10(ijetPt), ratio);
       
       if      (ijetPt <  40) mPtCorrOverReco_Eta_20_40   ->Fill(ijetEta, ratio);
       else if (ijetPt <  200) mPtCorrOverReco_Eta_40_200  ->Fill(ijetEta, ratio);
       else if (ijetPt <  600) mPtCorrOverReco_Eta_200_600  ->Fill(ijetEta, ratio);
       else if (ijetPt < 1500) mPtCorrOverReco_Eta_600_1500 ->Fill(ijetEta, ratio);
       else if (ijetPt < 3500) mPtCorrOverReco_Eta_1500_3500->Fill(ijetEta, ratio);
     }
   }
 
   //----------------------------------------------------------------------------
   //
   // Generation
   //
   //----------------------------------------------------------------------------
   if (!mEvent.isRealData())
     {
       // Get ptHat
       //------------------------------------------------------------------------
       edm::Handle<GenEventInfoProduct> myGenEvt;
       mEvent.getByToken(evtToken_, myGenEvt);
 
       if (myGenEvt.isValid()) {
         if(myGenEvt->hasBinningValues()){
       double ptHat = myGenEvt->binningValues()[0];
       if (mPtHat) mPtHat->Fill(ptHat);
         }
       }
       // Gen jets
       //------------------------------------------------------------------------
       edm::Handle<GenJetCollection> genJets;
       mEvent.getByToken(genJetsToken_, genJets);
 
       if (!genJets.isValid()) return;
       
       for (GenJetCollection::const_iterator gjet=genJets->begin();  gjet!=genJets->end(); gjet++)   {
     //for MiniAOD we have here intrinsic thresholds, introduce also threshold for RECO
     if(gjet->pt() > mMatchGenPtThreshold){
       if (mGenEta) mGenEta->Fill(gjet->eta());
       if (mGenPhi) mGenPhi->Fill(gjet->phi());
       if (mGenPt)  mGenPt ->Fill(gjet->pt());
       if (gjet == genJets->begin()) {
         if (mGenEtaFirst) mGenEtaFirst->Fill(gjet->eta());
         if (mGenPhiFirst) mGenPhiFirst->Fill(gjet->phi());
       }
     }
       }
 
       if (!(mInputGenCollection.label().empty())) {
       for (GenJetCollection::const_iterator gjet=genJets->begin(); gjet!=genJets->end(); gjet++) {
         if (fabs(gjet->eta()) > 6.) continue;  // Out of the detector 
         if (gjet->pt() < mMatchGenPtThreshold) continue;
         if (recoJets.size() <= 0) continue;
         // pt response
         //------------------------------------------------------------
     int iMatch    =   -1;
     double CorrdeltaRBest = 999;
     double CorrJetPtBest  =   0;
     for (unsigned ijet=0; ijet<recoJets.size(); ++ijet) {
       Jet correctedJet = recoJets[ijet];
       if(pass_correction_flag && !isMiniAODJet){
         if (isCaloJet) scale = jetCorr->correction((*caloJets)[ijet]); 
         if (isPFJet)   scale = jetCorr->correction((*pfJets)[ijet]); 
         correctedJet.scaleEnergy(scale);
       }
       double CorrJetPt = correctedJet.pt();
       if (CorrJetPt > 10) {
         double CorrdR = deltaR(gjet->eta(), gjet->phi(), correctedJet.eta(), correctedJet.phi());
         if (CorrdR < CorrdeltaRBest) {
           CorrdeltaRBest = CorrdR;
           CorrJetPtBest  = CorrJetPt;
           iMatch = ijet;
         }
       }
     }
     if (iMatch<0) continue;
     if(!isMiniAODJet){
         fillMatchHists(gjet->eta(),  gjet->phi(),  gjet->pt(), recoJets[iMatch].eta(), recoJets[iMatch].phi(),  recoJets[iMatch].pt());
       }else{
       fillMatchHists(gjet->eta(),  gjet->phi(),  gjet->pt(), (*patJets)[iMatch].eta(), (*patJets)[iMatch].phi(),(*patJets)[iMatch].pt()*(*patJets)[iMatch].jecFactor("Uncorrected"));
     }
         if (pass_correction_flag) {//fill only for corrected jets
       if (CorrdeltaRBest < mRThreshold) {
             double response = CorrJetPtBest / gjet->pt();
             
             if      (fabs(gjet->eta()) < 1.5) mPtCorrOverGen_GenPt_B->Fill(log10(gjet->pt()), response);
             else if (fabs(gjet->eta()) < 3.0) mPtCorrOverGen_GenPt_E->Fill(log10(gjet->pt()), response);   
             else if (fabs(gjet->eta()) < 6.0) mPtCorrOverGen_GenPt_F->Fill(log10(gjet->pt()), response);
             
             if (gjet->pt() > 20) {
               if      (gjet->pt() <  40) mPtCorrOverGen_GenEta_20_40   ->Fill(gjet->eta(), response);
               else if (gjet->pt() <  200) mPtCorrOverGen_GenEta_40_200   ->Fill(gjet->eta(), response);
               else if (gjet->pt() <  600) mPtCorrOverGen_GenEta_200_600  ->Fill(gjet->eta(), response);
               else if (gjet->pt() < 1500) mPtCorrOverGen_GenEta_600_1500 ->Fill(gjet->eta(), response);
               else if (gjet->pt() < 3500) mPtCorrOverGen_GenEta_1500_3500->Fill(gjet->eta(), response);
             }
           }
         }
       }
     }
     }
 }

void JetTester::bookHistograms	(	DQMStore::IBooker &	ibooker,
		edm::Run const &	iRun,
		edm::EventSetup const &
	)

overridevirtual

Implements DQMEDAnalyzer.

Definition at line 242 of file JetTester.cc.

                                                           { 
 
   ibooker.setCurrentFolder("JetMET/JetValidation/"+mInputCollection.label());  
 
     double log10PtMin  = 0.50;
     double log10PtMax  = 3.75;
     int    log10PtBins = 26; 
 
     double etaRange[91] = {-6.0, -5.8, -5.6, -5.4, -5.2, -5.0, -4.8, -4.6, -4.4, -4.2,
              -4.0, -3.8, -3.6, -3.4, -3.2, -3.0, -2.9, -2.8, -2.7, -2.6,
              -2.5, -2.4, -2.3, -2.2, -2.1, -2.0, -1.9, -1.8, -1.7, -1.6,
              -1.5, -1.4, -1.3, -1.2, -1.1, -1.0, -0.9, -0.8, -0.7, -0.6,
              -0.5, -0.4, -0.3, -0.2, -0.1,
              0.0, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9,
              1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9,
              2.0, 2.1, 2.2, 2.3, 2.4, 2.5, 2.6, 2.7, 2.8, 2.9,
              3.0, 3.2, 3.4, 3.6, 3.8, 4.0, 4.2, 4.4, 4.6, 4.8,
              5.0, 5.2, 5.4, 5.6, 5.8, 6.0};
 
     // Event variables
     mNvtx           = ibooker.book1D("Nvtx",           "number of vertices", 60, 0, 60);
 
     // Jet parameters
     mEta          = ibooker.book1D("Eta",          "Eta",          120,   -6,    6); 
     mPhi          = ibooker.book1D("Phi",          "Phi",           70, -3.5,  3.5); 
     mPt           = ibooker.book1D("Pt",           "Pt",           100,    0,  1000); 
     mP            = ibooker.book1D("P",            "P",            100,    0,  1000); 
     mEnergy       = ibooker.book1D("Energy",       "Energy",       100,    0,  1000); 
     mMass         = ibooker.book1D("Mass",         "Mass",         100,    0,  200); 
     mConstituents = ibooker.book1D("Constituents", "Constituents", 100,    0,  100); 
     mJetArea      = ibooker.book1D("JetArea",      "JetArea",       100,   0, 4);
 
     // Corrected jets
     if (isMiniAODJet || !mJetCorrector.label().empty()) {//if correction label is filled, but fill also for MiniAOD though
       mCorrJetPt  = ibooker.book1D("CorrJetPt",  "CorrJetPt",  150,    0, 1500);
       mCorrJetEta = ibooker.book1D("CorrJetEta", "CorrJetEta Pt>20", 60,   -6,   6);
       mCorrJetPhi = ibooker.book1D("CorrJetPhi", "CorrJetPhi Pt>20",  70, -3.5, 3.5);
       mCorrJetEta_Pt40 = ibooker.book1D("CorrJetEta_Pt40", "CorrJetEta Pt>40", 60,   -6,   6);
       mCorrJetPhi_Pt40 = ibooker.book1D("CorrJetPhi_Pt40", "CorrJetPhi Pt>40",  70, -3.5, 3.5);
 
       // Corrected jets profiles
       mPtCorrOverReco_Pt_B = ibooker.bookProfile("PtCorrOverReco_Pt_B", "0<|eta|<1.5", log10PtBins, log10PtMin, log10PtMax, 0, 5, " ");
       mPtCorrOverReco_Pt_E = ibooker.bookProfile("PtCorrOverReco_Pt_E", "1.5<|eta|<3", log10PtBins, log10PtMin, log10PtMax, 0, 5, " ");
       mPtCorrOverReco_Pt_F = ibooker.bookProfile("PtCorrOverReco_Pt_F", "3<|eta|<6",   log10PtBins, log10PtMin, log10PtMax, 0, 5, " ");
 
       mPtCorrOverReco_Eta_20_40    = ibooker.bookProfile("PtCorrOverReco_Eta_20_40",    "20<genPt<40",    90, etaRange, 0, 5, " ");
       mPtCorrOverReco_Eta_40_200    = ibooker.bookProfile("PtCorrOverReco_Eta_40_200",    "40<genPt<200",    90, etaRange, 0, 5, " ");
       mPtCorrOverReco_Eta_200_600   = ibooker.bookProfile("PtCorrOverReco_Eta_200_600",   "200<genPt<600",   90, etaRange, 0, 5, " ");
       mPtCorrOverReco_Eta_600_1500  = ibooker.bookProfile("PtCorrOverReco_Eta_600_1500",  "600<genPt<1500",  90, etaRange, 0, 5, " ");
       mPtCorrOverReco_Eta_1500_3500 = ibooker.bookProfile("PtCorrOverReco_Eta_1500_3500", "1500<genPt<3500", 90, etaRange, 0, 5, " ");
 
       mPtCorrOverGen_GenPt_B = ibooker.bookProfile("PtCorrOverGen_GenPt_B", "0<|eta|<1.5", log10PtBins, log10PtMin, log10PtMax, 0.8, 1.2, " ");
       mPtCorrOverGen_GenPt_E = ibooker.bookProfile("PtCorrOverGen_GenPt_E", "1.5<|eta|<3", log10PtBins, log10PtMin, log10PtMax, 0.8, 1.2, " ");
       mPtCorrOverGen_GenPt_F = ibooker.bookProfile("PtCorrOverGen_GenPt_F", "3<|eta|<6",   log10PtBins, log10PtMin, log10PtMax, 0.8, 1.2, " ");
 
       mPtCorrOverGen_GenEta_20_40    = ibooker.bookProfile("PtCorrOverGen_GenEta_20_40",      "20<genPt<40;#eta",    90, etaRange, 0.8, 1.2, " ");
       mPtCorrOverGen_GenEta_40_200    = ibooker.bookProfile("PtCorrOverGen_GenEta_40_200",    "40<genPt<200;#eta",    90, etaRange, 0.8, 1.2, " ");
       mPtCorrOverGen_GenEta_200_600   = ibooker.bookProfile("PtCorrOverGen_GenEta_200_600",   "200<genPt<600;#eta",   90, etaRange, 0.8, 1.2, " ");
       mPtCorrOverGen_GenEta_600_1500  = ibooker.bookProfile("PtCorrOverGen_GenEta_600_1500",  "600<genPt<1500;#eta",  90, etaRange, 0.8, 1.2, " ");
       mPtCorrOverGen_GenEta_1500_3500 = ibooker.bookProfile("PtCorrOverGen_GenEta_1500_3500", "1500<genPt<3500;#eta", 90, etaRange, 0.8, 1.2, " ");
     }
 
     mGenEta      = ibooker.book1D("GenEta",      "GenEta",      120,   -6,    6);
     mGenPhi      = ibooker.book1D("GenPhi",      "GenPhi",       70, -3.5,  3.5);
     mGenPt       = ibooker.book1D("GenPt",       "GenPt",       100,    0,  1000);
     mGenEtaFirst = ibooker.book1D("GenEtaFirst", "GenEtaFirst", 120,   -6,    6);
     mGenPhiFirst = ibooker.book1D("GenPhiFirst", "GenPhiFirst",  70, -3.5,  3.5);
     mPtHat       = ibooker.book1D("PtHat",       "PtHat",       100,    0, 1000); 
     mDeltaEta    = ibooker.book1D("DeltaEta",    "DeltaEta",    100, -0.5,  0.5);
     mDeltaPhi    = ibooker.book1D("DeltaPhi",    "DeltaPhi",    100, -0.5,  0.5);
     mDeltaPt     = ibooker.book1D("DeltaPt",     "DeltaPt",     100, -1.0,  1.0);
     
     mPtRecoOverGen_B_20_40    = ibooker.book1D("PtRecoOverGen_B_20_40",    "20<genpt<40",    90, 0, 2);
     mPtRecoOverGen_E_20_40    = ibooker.book1D("PtRecoOverGen_E_20_40",    "20<genpt<40",    90, 0, 2);
     mPtRecoOverGen_F_20_40    = ibooker.book1D("PtRecoOverGen_F_20_40",    "20<genpt<40",    90, 0, 2);
     mPtRecoOverGen_B_40_200    = ibooker.book1D("PtRecoOverGen_B_40_200",    "40<genpt<200",    90, 0, 2);
     mPtRecoOverGen_E_40_200    = ibooker.book1D("PtRecoOverGen_E_40_200",    "40<genpt<200",    90, 0, 2);
     mPtRecoOverGen_F_40_200    = ibooker.book1D("PtRecoOverGen_F_40_200",    "40<genpt<200",    90, 0, 2);
     mPtRecoOverGen_B_200_600   = ibooker.book1D("PtRecoOverGen_B_200_600",   "200<genpt<600",   90, 0, 2);
     mPtRecoOverGen_E_200_600   = ibooker.book1D("PtRecoOverGen_E_200_600",   "200<genpt<600",   90, 0, 2);
     mPtRecoOverGen_F_200_600   = ibooker.book1D("PtRecoOverGen_F_200_600",   "200<genpt<600",   90, 0, 2);
     mPtRecoOverGen_B_600_1500  = ibooker.book1D("PtRecoOverGen_B_600_1500",  "600<genpt<1500",  90, 0, 2);
     mPtRecoOverGen_E_600_1500  = ibooker.book1D("PtRecoOverGen_E_600_1500",  "600<genpt<1500",  90, 0, 2);
     mPtRecoOverGen_F_600_1500  = ibooker.book1D("PtRecoOverGen_F_600_1500",  "600<genpt<1500",  90, 0, 2);
     mPtRecoOverGen_B_1500_3500 = ibooker.book1D("PtRecoOverGen_B_1500_3500", "1500<genpt<3500", 90, 0, 2);
     mPtRecoOverGen_E_1500_3500 = ibooker.book1D("PtRecoOverGen_E_1500_3500", "1500<genpt<3500", 90, 0, 2);
     mPtRecoOverGen_F_1500_3500 = ibooker.book1D("PtRecoOverGen_F_1500_3500", "1500<genpt<3500", 90, 0, 2);
 
     // Generation profiles
     mPtRecoOverGen_GenPt_B          = ibooker.bookProfile("PtRecoOverGen_GenPt_B",          "0<|eta|<1.5",     log10PtBins, log10PtMin, log10PtMax, 0, 2, " ");
     mPtRecoOverGen_GenPt_E          = ibooker.bookProfile("PtRecoOverGen_GenPt_E",          "1.5<|eta|<3",     log10PtBins, log10PtMin, log10PtMax, 0, 2, " ");
     mPtRecoOverGen_GenPt_F          = ibooker.bookProfile("PtRecoOverGen_GenPt_F",          "3<|eta|<6",       log10PtBins, log10PtMin, log10PtMax, 0, 2, " ");
     mPtRecoOverGen_GenPhi_B         = ibooker.bookProfile("PtRecoOverGen_GenPhi_B",         "0<|eta|<1.5",     70, -3.5, 3.5, 0, 2, " ");
     mPtRecoOverGen_GenPhi_E         = ibooker.bookProfile("PtRecoOverGen_GenPhi_E",         "1.5<|eta|<3",     70, -3.5, 3.5, 0, 2, " ");
     mPtRecoOverGen_GenPhi_F         = ibooker.bookProfile("PtRecoOverGen_GenPhi_F",         "3<|eta|<6",       70, -3.5, 3.5, 0, 2, " ");
     mPtRecoOverGen_GenEta_20_40    = ibooker.bookProfile("PtRecoOverGen_GenEta_20_40",    "20<genpt<40",    90, etaRange, 0, 2, " ");
     mPtRecoOverGen_GenEta_40_200    = ibooker.bookProfile("PtRecoOverGen_GenEta_40_200",    "40<genpt<200",    90, etaRange, 0, 2, " ");
     mPtRecoOverGen_GenEta_200_600   = ibooker.bookProfile("PtRecoOverGen_GenEta_200_600",   "200<genpt<600",   90, etaRange, 0, 2, " ");
     mPtRecoOverGen_GenEta_600_1500  = ibooker.bookProfile("PtRecoOverGen_GenEta_600_1500",  "600<genpt<1500",  90, etaRange, 0, 2, " ");
     mPtRecoOverGen_GenEta_1500_3500 = ibooker.bookProfile("PtRecoOverGen_GenEta_1500_3500", "1500<genpt<3500", 90, etaRange, 0, 2, " ");
     
     // Some jet algebra
     //------------------------------------------------------------------------
     mEtaFirst   = ibooker.book1D("EtaFirst",   "EtaFirst",   120,   -6,    6); 
     mPhiFirst   = ibooker.book1D("PhiFirst",   "PhiFirst",    70, -3.5,  3.5);      
     mPtFirst    = ibooker.book1D("PtFirst",    "PtFirst",    50,    0,  1000); 
     mMjj        = ibooker.book1D("Mjj",        "Mjj",        100,    0, 2000); 
     mNJetsEta_B_20_40 = ibooker.book1D("NJetsEta_B_20_40", "NJetsEta_B 20<Pt<40",  15,    0,   15);
     mNJetsEta_E_20_40 = ibooker.book1D("NJetsEta_E_20_40", "NJetsEta_E 20<Pt<40",  15,    0,   15);
     mNJetsEta_B_40 = ibooker.book1D("NJetsEta_B", "NJetsEta_B 40<Pt",  15,    0,   15);
     mNJetsEta_E_40 = ibooker.book1D("NJetsEta_E", "NJetsEta_E 40<Pt",  15,    0,   15);
     mNJets_40 = ibooker.book1D("NJets", "NJets 40>Pt",  15,    0,   15);
     mNJets1 = ibooker.bookProfile("NJets1", "Number of jets above Pt threshold", 100, 0,  200, 100, 0, 50, "s");
     mNJets2 = ibooker.bookProfile("NJets2", "Number of jets above Pt threshold", 100, 0, 4000, 100, 0, 50, "s");
 
 
     if (isCaloJet) {
       maxEInEmTowers              = ibooker.book1D("maxEInEmTowers", "maxEInEmTowers", 50,0,500);
       maxEInHadTowers             = ibooker.book1D("maxEInHadTowers", "maxEInHadTowers", 50,0,500);
       energyFractionHadronic      = ibooker.book1D("energyFractionHadronic", "energyFractionHadronic", 50,0,1);
       emEnergyFraction            = ibooker.book1D("emEnergyFraction", "emEnergyFraction", 50,0,1);
       hadEnergyInHB               = ibooker.book1D("hadEnergyInHB", "hadEnergyInHB", 50,0,500);
       hadEnergyInHO               = ibooker.book1D("hadEnergyInHO", "hadEnergyInHO", 50,0,500);
       hadEnergyInHE               = ibooker.book1D("hadEnergyInHE", "hadEnergyInHE", 50,0,500);
       hadEnergyInHF               = ibooker.book1D("hadEnergyInHF", "hadEnergyInHF", 50,0,500);
       emEnergyInEB                = ibooker.book1D("emEnergyInEB", "emEnergyInEB", 50,0,500);
       emEnergyInEE                = ibooker.book1D("emEnergyInEE", "emEnergyInEE", 50,0,500);
       emEnergyInHF                = ibooker.book1D("emEnergyInHF", "emEnergyInHF", 50,0,500);
       towersArea                  = ibooker.book1D("towersArea", "towersArea", 50,0,1);
       n90                         = ibooker.book1D("n90", "n90", 30,0,30);
       n60                         = ibooker.book1D("n60", "n60", 30,0,30);
     }
 
     if (isPFJet || isMiniAODJet) {
       muonMultiplicity = ibooker.book1D("muonMultiplicity", "muonMultiplicity", 10,0,10);
       chargedMultiplicity = ibooker.book1D("chargedMultiplicity", "chargedMultiplicity", 100,0,100);
       chargedEmEnergy = ibooker.book1D("chargedEmEnergy", "chargedEmEnergy", 100,0,500);
       neutralEmEnergy = ibooker.book1D("neutralEmEnergy", "neutralEmEnergy", 100,0,500);
       chargedHadronEnergy = ibooker.book1D("chargedHadronEnergy", "chargedHadronEnergy", 100,0,500);
       neutralHadronEnergy = ibooker.book1D("neutralHadronEnergy", "neutralHadronEnergy", 100,0,500);
       chargedHadronEnergyFraction = ibooker.book1D("chargedHadronEnergyFraction", "chargedHadronEnergyFraction", 50,0,1);
       neutralHadronEnergyFraction = ibooker.book1D("neutralHadronEnergyFraction", "neutralHadronEnergyFraction", 50,0,1);
       chargedEmEnergyFraction = ibooker.book1D("chargedEmEnergyFraction", "chargedEmEnergyFraction", 50,0,1);
       neutralEmEnergyFraction = ibooker.book1D("neutralEmEnergyFraction", "neutralEmEnergyFraction", 50,0,1);
       photonEnergy = ibooker.book1D("photonEnergy", "photonEnergy", 50,0,500);
       photonEnergyFraction = ibooker.book1D("photonEnergyFraction", "photonEnergyFraction", 50,0,1);
       electronEnergy = ibooker.book1D("electronEnergy", "electronEnergy", 50,0,500);
       electronEnergyFraction = ibooker.book1D("electronEnergyFraction", "electronEnergyFraction", 50,0,1);
       muonEnergy = ibooker.book1D("muonEnergy", "muonEnergy", 50,0,500);
       muonEnergyFraction = ibooker.book1D("muonEnergyFraction", "muonEnergyFraction", 50,0,1);
       HFHadronEnergy = ibooker.book1D("HFHadronEnergy", "HFHadronEnergy", 50,0,500);
       HFHadronEnergyFraction = ibooker.book1D("HFHadronEnergyFraction", "HFHadronEnergyFraction", 50,0,1);
       HFEMEnergy = ibooker.book1D("HFEMEnergy", "HFEMEnergy", 50,0,500);
       HFEMEnergyFraction = ibooker.book1D("HFEMEnergyFraction", "HFEMEnergyFraction", 50,0,1);
       chargedHadronMultiplicity = ibooker.book1D("chargedHadronMultiplicity", "chargedHadronMultiplicity", 50,0,50);
       neutralHadronMultiplicity = ibooker.book1D("neutralHadronMultiplicity", "neutralHadronMultiplicity", 50,0,50);
       photonMultiplicity = ibooker.book1D("photonMultiplicity", "photonMultiplicity", 10,0,10);
       electronMultiplicity = ibooker.book1D("electronMultiplicity", "electronMultiplicity", 10,0,10);
       HFHadronMultiplicity = ibooker.book1D("HFHadronMultiplicity", "HFHadronMultiplicity", 50,0,50);
       HFEMMultiplicity = ibooker.book1D("HFEMMultiplicity", "HFEMMultiplicity", 50,0,50);
       chargedMuEnergy = ibooker.book1D("chargedMuEnergy", "chargedMuEnergy", 50,0,500);
       chargedMuEnergyFraction = ibooker.book1D("chargedMuEnergyFraction", "chargedMuEnergyFraction", 50,0,1);
       neutralMultiplicity = ibooker.book1D("neutralMultiplicity", "neutralMultiplicity", 50,0,50);
       HOEnergy = ibooker.book1D("HOEnergy", "HOEnergy", 50,0,500);
       HOEnergyFraction = ibooker.book1D("HOEnergyFraction", "HOEnergyFraction", 50,0,1);
     }
 }

void JetTester::fillMatchHists	(	const double	GenEta,
		const double	GenPhi,
		const double	GenPt,
		const double	RecoEta,
		const double	RecoPhi,
		const double	RecoPt
	)

private

Definition at line 888 of file JetTester.cc.

References MonitorElement::Fill(), mDeltaEta, mDeltaPhi, mDeltaPt, mMatchGenPtThreshold, mPtRecoOverGen_B_1500_3500, mPtRecoOverGen_B_200_600, mPtRecoOverGen_B_20_40, mPtRecoOverGen_B_40_200, mPtRecoOverGen_B_600_1500, mPtRecoOverGen_E_1500_3500, mPtRecoOverGen_E_200_600, mPtRecoOverGen_E_20_40, mPtRecoOverGen_E_40_200, mPtRecoOverGen_E_600_1500, mPtRecoOverGen_F_1500_3500, mPtRecoOverGen_F_200_600, mPtRecoOverGen_F_20_40, mPtRecoOverGen_F_40_200, mPtRecoOverGen_F_600_1500, mPtRecoOverGen_GenEta_1500_3500, mPtRecoOverGen_GenEta_200_600, mPtRecoOverGen_GenEta_20_40, mPtRecoOverGen_GenEta_40_200, mPtRecoOverGen_GenEta_600_1500, mPtRecoOverGen_GenPhi_B, mPtRecoOverGen_GenPhi_E, mPtRecoOverGen_GenPhi_F, mPtRecoOverGen_GenPt_B, mPtRecoOverGen_GenPt_E, and mPtRecoOverGen_GenPt_F.

Referenced by analyze().

 {
   if (GenPt > mMatchGenPtThreshold) {
     mDeltaEta->Fill(GenEta - RecoEta);
     mDeltaPhi->Fill(GenPhi - RecoPhi);
     mDeltaPt ->Fill((GenPt - RecoPt) / GenPt);
   }
 
   if (fabs(GenEta) < 1.5)
     {
       mPtRecoOverGen_GenPt_B ->Fill(log10(GenPt),  RecoPt / GenPt);
       mPtRecoOverGen_GenPhi_B->Fill(GenPhi, RecoPt / GenPt);
     
       if (GenPt > 20 && GenPt < 40) mPtRecoOverGen_B_20_40   ->Fill(RecoPt / GenPt);
       else if (GenPt <  200)         mPtRecoOverGen_B_40_200  ->Fill(RecoPt / GenPt);
       else if (GenPt <  600)         mPtRecoOverGen_B_200_600  ->Fill(RecoPt / GenPt);
       else if (GenPt < 1500)         mPtRecoOverGen_B_600_1500 ->Fill(RecoPt / GenPt);
       else if (GenPt < 3500)         mPtRecoOverGen_B_1500_3500->Fill(RecoPt / GenPt);
     }
   else if (fabs(GenEta) < 3.0)
     {
       mPtRecoOverGen_GenPt_E ->Fill(log10(GenPt),  RecoPt / GenPt);
       mPtRecoOverGen_GenPhi_E->Fill(GenPhi, RecoPt / GenPt);
     
       if (GenPt > 20 && GenPt < 40) mPtRecoOverGen_E_20_40   ->Fill(RecoPt / GenPt);
       else if (GenPt <  200)         mPtRecoOverGen_E_40_200  ->Fill(RecoPt / GenPt);
       else if (GenPt <  600)         mPtRecoOverGen_E_200_600  ->Fill(RecoPt / GenPt);
       else if (GenPt < 1500)         mPtRecoOverGen_E_600_1500 ->Fill(RecoPt / GenPt);
       else if (GenPt < 3500)         mPtRecoOverGen_E_1500_3500->Fill(RecoPt / GenPt);
     }
   else if (fabs(GenEta) < 6.0)
     {
       mPtRecoOverGen_GenPt_F ->Fill (log10(GenPt),  RecoPt / GenPt);
       mPtRecoOverGen_GenPhi_F->Fill (GenPhi, RecoPt / GenPt);
     
       if (GenPt > 20 && GenPt < 40) mPtRecoOverGen_F_20_40   ->Fill(RecoPt / GenPt);
       else if (GenPt <  200)         mPtRecoOverGen_F_40_200  ->Fill(RecoPt / GenPt);
       else if (GenPt <  600)         mPtRecoOverGen_F_200_600  ->Fill(RecoPt / GenPt);
       else if (GenPt < 1500)         mPtRecoOverGen_F_600_1500 ->Fill(RecoPt / GenPt);
       else if (GenPt < 3500)         mPtRecoOverGen_F_1500_3500->Fill(RecoPt / GenPt);
     }
 
   if (GenPt > 20 && GenPt < 40) mPtRecoOverGen_GenEta_20_40   ->Fill(GenEta, RecoPt / GenPt);
   else if (GenPt <  200)         mPtRecoOverGen_GenEta_40_200  ->Fill(GenEta, RecoPt / GenPt);
   else if (GenPt <  600)         mPtRecoOverGen_GenEta_200_600  ->Fill(GenEta, RecoPt / GenPt);
   else if (GenPt < 1500)         mPtRecoOverGen_GenEta_600_1500 ->Fill(GenEta, RecoPt / GenPt);
   else if (GenPt < 3500)         mPtRecoOverGen_GenEta_1500_3500->Fill(GenEta, RecoPt / GenPt);
 }