#include <DataCertificationJetMET.h>

Inheritance diagram for DataCertificationJetMET:

Public Member Functions
	DataCertificationJetMET (const edm::ParameterSet &)

	~DataCertificationJetMET () override

Public Member Functions inherited from DQMEDHarvester
void	accumulate (edm::Event const &ev, edm::EventSetup const &es) final

void	beginJob () override

void	beginLuminosityBlock (edm::LuminosityBlock const &lumi, edm::EventSetup const &) final

void	beginRun (edm::Run const &run, edm::EventSetup const &) override

virtual void	dqmAnalyze (DQMStore::IBooker &, DQMStore::IGetter &, edm::Event const &, edm::EventSetup const &)

	DQMEDHarvester (edm::ParameterSet const &iConfig)

	DQMEDHarvester ()

virtual void	dqmEndLuminosityBlock (DQMStore::IBooker &, DQMStore::IGetter &, edm::LuminosityBlock const &, edm::EventSetup const &)

virtual void	dqmEndRun (DQMStore::IBooker &, DQMStore::IGetter &, edm::Run const &, edm::EventSetup const &)

void	endLuminosityBlock (edm::LuminosityBlock const &, edm::EventSetup const &) final

void	endLuminosityBlockProduce (edm::LuminosityBlock &lumi, edm::EventSetup const &es) final

void	endProcessBlockProduce (edm::ProcessBlock &) final

void	endRun (edm::Run const &, edm::EventSetup const &) override

void	endRunProduce (edm::Run &run, edm::EventSetup const &es) final

	~DQMEDHarvester () override=default

Public Member Functions inherited from edm::one::EDProducer< edm::EndLuminosityBlockProducer, edm::EndRunProducer, edm::EndProcessBlockProducer, edm::one::WatchLuminosityBlocks, edm::one::WatchRuns, edm::one::SharedResources, edm::Accumulator >
	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

std::vector< bool > const &	recordProvenanceList () 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)

TypeLabelList const &	typeLabelList () const
	used by the fwk to register the list of products of this module More...

	~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
void	dqmEndJob (DQMStore::IBooker &, DQMStore::IGetter &) override

Private Attributes
bool	caloJetKSTest

bool	caloJetMeanTest

bool	caloMETKSTest

bool	caloMETMeanTest

MonitorElement *	CertificationSummary

MonitorElement *	CertificationSummaryMap

edm::ParameterSet	conf_

int	etaBin_

double	etaMax_

double	etaMin_

std::string	folderName

bool	InMemory_

edm::InputTag	inputJetLabelMiniAOD_

edm::InputTag	inputJetLabelRECO_

edm::InputTag	inputMETLabelMiniAOD_

edm::InputTag	inputMETLabelRECO_

edm::InputTag	inputMETLabelRECOUncleaned_

bool	isData

bool	isHI

std::string	jetAlgo

bool	jetTests [5][2]

bool	jptJetKSTest

bool	jptJetMeanTest

MonitorElement *	mChargedHadronEtFraction_MiniAOD_over_Reco

MonitorElement *	mChargedHadronEtFraction_nVtx_profile_MiniAOD_over_Reco

MonitorElement *	mChargedMultiplicity_MiniAOD_over_Reco

MonitorElement *	mCHFrac_MiniAOD_over_Reco

MonitorElement *	mCHFracVSpT_Barrel_MiniAOD_over_Reco

MonitorElement *	mDPhi_MiniAOD_over_Reco

MonitorElement *	mEta_MiniAOD_over_Reco

MonitorElement *	mEta_uncor_MiniAOD_over_Reco

std::string	metFolder

bool	metTests [5][2]

MonitorElement *	mHFEFracVSpT_Forward_MiniAOD_over_Reco

MonitorElement *	mHFEMEtFraction_MiniAOD_over_Reco

MonitorElement *	mHFHadronEtFraction_MiniAOD_over_Reco

MonitorElement *	mHFHFracVSpT_Forward_MiniAOD_over_Reco

MonitorElement *	mJetEnergyCorr_MiniAOD_over_Reco

MonitorElement *	mJetEnergyCorrVSeta_MiniAOD_over_Reco

MonitorElement *	mLooseJIDPassFractionVSeta_MiniAOD_over_Reco

MonitorElement *	mMET_EffCSCTightHalo2015Filter

MonitorElement *	mMET_EffCSCTightHaloFilter

MonitorElement *	mMET_EffEcalDeadCellBoundaryFilter

MonitorElement *	mMET_EffEcalDeadCellTriggerFilter

MonitorElement *	mMET_EffeeBadScFilter

MonitorElement *	mMET_EffHBHEIsoNoiseFilter

MonitorElement *	mMET_EffHBHENoiseFilter

MonitorElement *	mMET_EffHcalStripHaloFilter

MonitorElement *	mMET_logx_MiniAOD_over_Reco

MonitorElement *	mMET_MiniAOD_over_Reco

MonitorElement *	mMET_nVtx_profile_MiniAOD_over_Reco

MonitorElement *	mMETPhi_MiniAOD_over_Reco

MonitorElement *	mMEy_MiniAOD_over_Reco

MonitorElement *	mMuonMultiplicity_MiniAOD_over_Reco

MonitorElement *	mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD_over_Reco

MonitorElement *	mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD_over_Reco

MonitorElement *	mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD_over_Reco

MonitorElement *	mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD_over_Reco

MonitorElement *	mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD_over_Reco

MonitorElement *	mNeutralFraction_MiniAOD_over_Reco

MonitorElement *	mNeutralHadronEtFraction_MiniAOD_over_Reco

MonitorElement *	mNeutralHadronEtFraction_nVtx_profile_MiniAOD_over_Reco

MonitorElement *	mNeutralMultiplicity_MiniAOD_over_Reco

MonitorElement *	mNHFrac_MiniAOD_over_Reco

MonitorElement *	mNHFracVSpT_EndCap_MiniAOD_over_Reco

MonitorElement *	mNjets_MiniAOD_over_Reco

MonitorElement *	mPhFrac_MiniAOD_over_Reco

MonitorElement *	mPhFracVSpT_Barrel_MiniAOD_over_Reco

MonitorElement *	mPhi_MiniAOD_over_Reco

MonitorElement *	mPhi_uncor_MiniAOD_over_Reco

MonitorElement *	mPhotonEtFraction_MiniAOD_over_Reco

MonitorElement *	mPhotonEtFraction_nVtx_profile_MiniAOD_over_Reco

MonitorElement *	mPt_Barrel_MiniAOD_over_Reco

MonitorElement *	mPt_EndCap_MiniAOD_over_Reco

MonitorElement *	mPt_Forward_MiniAOD_over_Reco

MonitorElement *	mPt_MiniAOD_over_Reco

MonitorElement *	mPt_uncor_MiniAOD_over_Reco

MonitorElement *	mSumET_logx_MiniAOD_over_Reco

MonitorElement *	mSumET_MiniAOD_over_Reco

MonitorElement *	mSumET_nVtx_profile_MiniAOD_over_Reco

int	nbinsPV_

double	nPVMax_

double	nPVMin_

bool	pfJetKSTest

bool	pfJetMeanTest

bool	pfMETKSTest

bool	pfMETMeanTest

int	ptBin_

double	ptMax_

double	ptMin_

MonitorElement *	reportSummary

MonitorElement *	reportSummaryMap

bool	tcMETKSTest

bool	tcMETMeanTest

int	verbose_

Additional Inherited Members
Public Types inherited from DQMEDHarvester
typedef dqm::harvesting::DQMStore	DQMStore

typedef dqm::harvesting::MonitorElement	MonitorElement

Public Types inherited from edm::one::EDProducerBase
typedef EDProducerBase	ModuleType

Public Types inherited from edm::ProducerBase
template<typename T >
using	BranchAliasSetterT = ProductRegistryHelper::BranchAliasSetterT< T >

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
template<Transition Tr = Transition::Event>
auto	produces (std::string instanceName) noexcept
	declare what type of product will make and with which optional label More...

template<Transition B>
BranchAliasSetter	produces (const TypeID &id, std::string instanceName=std::string(), bool recordProvenance=true)

template<BranchType B>
BranchAliasSetter	produces (const TypeID &id, std::string instanceName=std::string(), bool recordProvenance=true)

BranchAliasSetter	produces (const TypeID &id, std::string instanceName=std::string(), bool recordProvenance=true)

template<typename ProductType , Transition B>
BranchAliasSetterT< ProductType >	produces (std::string instanceName)

template<class ProductType >
BranchAliasSetterT< ProductType >	produces ()

template<typename ProductType , BranchType B>
BranchAliasSetterT< ProductType >	produces (std::string instanceName)

template<typename ProductType , BranchType B>
BranchAliasSetterT< ProductType >	produces ()

template<class ProductType >
BranchAliasSetterT< ProductType >	produces (std::string instanceName)

template<typename ProductType , Transition B>
BranchAliasSetterT< ProductType >	produces ()

template<Transition Tr = Transition::Event>
auto	produces () noexcept

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 ()

template<Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag tag)

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 DQMEDHarvester
DQMStore *	dqmstore_

edm::GetterOfProducts< DQMToken >	jobmegetter_

edm::EDPutTokenT< DQMToken >	jobToken_

edm::GetterOfProducts< DQMToken >	lumimegetter_

edm::EDPutTokenT< DQMToken >	lumiToken_

edm::GetterOfProducts< DQMToken >	runmegetter_

edm::EDPutTokenT< DQMToken >	runToken_

Detailed Description

Definition at line 25 of file DataCertificationJetMET.h.

Constructor & Destructor Documentation

◆ DataCertificationJetMET()

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

explicit

Definition at line 18 of file DataCertificationJetMET.cc.

References conf_, gather_cfg::cout, etaBin_, etaMax_, etaMin_, folderName, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), inputJetLabelMiniAOD_, inputJetLabelRECO_, inputMETLabelMiniAOD_, inputMETLabelRECO_, inputMETLabelRECOUncleaned_, isHI, jetAlgo, jetTests, metFolder, metTests, nbinsPV_, nPVMax_, nPVMin_, ptBin_, ptMax_, ptMin_, AlCaHLTBitMon_QueryRunRegistry::string, and verbose_.

                                                                                : conf_(iConfig) {
   // now do what ever initialization is needed
   inputMETLabelRECO_ = iConfig.getParameter<edm::InputTag>("METTypeRECO");
   inputMETLabelRECOUncleaned_ = iConfig.getParameter<edm::InputTag>("METTypeRECOUncleaned");
   inputMETLabelMiniAOD_ = iConfig.getParameter<edm::InputTag>("METTypeMiniAOD");
   inputJetLabelRECO_ = iConfig.getParameter<edm::InputTag>("JetTypeRECO");
   inputJetLabelMiniAOD_ = iConfig.getParameter<edm::InputTag>("JetTypeMiniAOD");
 
   nbinsPV_ = iConfig.getParameter<int>("pVBin");
   nPVMin_ = iConfig.getParameter<double>("pVMin");
   nPVMax_ = iConfig.getParameter<double>("pVMax");
 
   etaBin_ = iConfig.getParameter<int>("etaBin");
   etaMin_ = iConfig.getParameter<double>("etaMin");
   etaMax_ = iConfig.getParameter<double>("etaMax");
 
   ptBin_ = iConfig.getParameter<int>("ptBin");
   ptMin_ = iConfig.getParameter<double>("ptMin");
   ptMax_ = iConfig.getParameter<double>("ptMax");
 
   // -----------------------------------------
   // verbose_ 0: suppress printouts
   //          1: show printouts
   verbose_ = conf_.getUntrackedParameter<int>("Verbose", 0);
   metFolder = conf_.getUntrackedParameter<std::string>("metFolder");
   jetAlgo = conf_.getUntrackedParameter<std::string>("jetAlgo");
   folderName = conf_.getUntrackedParameter<std::string>("folderName");
 
   jetTests[0][0] = conf_.getUntrackedParameter<bool>("pfBarrelJetMeanTest", true);
   jetTests[0][1] = conf_.getUntrackedParameter<bool>("pfBarrelJetKSTest", false);
   jetTests[1][0] = conf_.getUntrackedParameter<bool>("pfEndcapJetMeanTest", true);
   jetTests[1][1] = conf_.getUntrackedParameter<bool>("pfEndcapJetKSTest", false);
   jetTests[2][0] = conf_.getUntrackedParameter<bool>("pfForwardJetMeanTest", true);
   jetTests[2][1] = conf_.getUntrackedParameter<bool>("pfForwardJetKSTest", false);
   jetTests[3][0] = conf_.getUntrackedParameter<bool>("caloJetMeanTest", true);
   jetTests[3][1] = conf_.getUntrackedParameter<bool>("caloJetKSTest", false);
   jetTests[4][0] = conf_.getUntrackedParameter<bool>("jptJetMeanTest", true);
   jetTests[4][1] = conf_.getUntrackedParameter<bool>("jptJetKSTest", false);
 
   metTests[0][0] = conf_.getUntrackedParameter<bool>("caloMETMeanTest", true);
   metTests[0][1] = conf_.getUntrackedParameter<bool>("caloMETKSTest", false);
   metTests[1][0] = conf_.getUntrackedParameter<bool>("pfMETMeanTest", true);
   metTests[1][1] = conf_.getUntrackedParameter<bool>("pfMETKSTest", false);
   metTests[2][0] = conf_.getUntrackedParameter<bool>("tcMETMeanTest", true);
   metTests[2][1] = conf_.getUntrackedParameter<bool>("tcMETKSTest", false);
 
   isHI = conf_.getUntrackedParameter<bool>("isHI", false);
 
   if (verbose_)
     std::cout << ">>> Constructor (DataCertificationJetMET) <<<" << std::endl;
 
   // -----------------------------------------
   //
 }

◆ ~DataCertificationJetMET()

DataCertificationJetMET::~DataCertificationJetMET ( )

override

Definition at line 73 of file DataCertificationJetMET.cc.

References gather_cfg::cout, and verbose_.

                                                   {
   // do anything here that needs to be done at desctruction time
   // (e.g. close files, deallocate resources etc.)
   if (verbose_)
     std::cout << ">>> Deconstructor (DataCertificationJetMET) <<<" << std::endl;
 }

Member Function Documentation

◆ dqmEndJob()

void DataCertificationJetMET::dqmEndJob	(	DQMStore::IBooker &	ibook_,
		DQMStore::IGetter &	iget_
	)

overrideprivatevirtual

Implements DQMEDHarvester.

Definition at line 81 of file DataCertificationJetMET.cc.

                                                                                        {
   //put RECO vs MiniAODDir first ->first MET
   std::vector<std::string> subDirVecMET;
   std::string RunDirMET = "JetMET/MET/";
   iget_.setCurrentFolder(RunDirMET);
   subDirVecMET = iget_.getSubdirs();
   bool found_METreco_dir = false;
   bool found_METminiaod_dir = false;
   //check if proper directories are inside the files
   for (int i = 0; i < int(subDirVecMET.size()); i++) {
     ibook_.setCurrentFolder(subDirVecMET[i]);
     if ((subDirVecMET[i] + "/Cleaned") == (RunDirMET + inputMETLabelRECO_.label() + "/Cleaned")) {
       found_METreco_dir = true;
     }
     if (((subDirVecMET[i] + "/Uncleaned") == (RunDirMET + inputMETLabelRECOUncleaned_.label() + "/Uncleaned")) ||
         ((subDirVecMET[i] + "/Uncleaned") == (RunDirMET + inputMETLabelMiniAOD_.label() + "/Uncleaned"))) {
       //check filters in uncleaned directory
       std::string rundirMET_reco = "";
       if ((subDirVecMET[i] + "/Uncleaned") == (RunDirMET + inputMETLabelRECOUncleaned_.label() + "/Uncleaned")) {
         rundirMET_reco = RunDirMET + inputMETLabelRECOUncleaned_.label() + "/Uncleaned";
       } else {
         rundirMET_reco = RunDirMET + inputMETLabelMiniAOD_.label() + "/Uncleaned";
       }
       MonitorElement* mMET_Reco = iget_.get(rundirMET_reco + "/" + "MET");
       MonitorElement* mMET_Reco_HBHENoiseFilter = iget_.get(rundirMET_reco + "/" + "MET_HBHENoiseFilter");
       MonitorElement* mMET_Reco_CSCTightHaloFilter = iget_.get(rundirMET_reco + "/" + "MET_CSCTightHaloFilter");
       MonitorElement* mMET_Reco_eeBadScFilter = iget_.get(rundirMET_reco + "/" + "MET_eeBadScFilter");
       MonitorElement* mMET_Reco_HBHEIsoNoiseFilter = iget_.get(rundirMET_reco + "/" + "MET_HBHEIsoNoiseFilter");
       MonitorElement* mMET_Reco_CSCTightHalo2015Filter = iget_.get(rundirMET_reco + "/" + "MET_CSCTightHalo2015Filter");
       MonitorElement* mMET_Reco_EcalDeadCellTriggerFilter =
           iget_.get(rundirMET_reco + "/" + "MET_EcalDeadCellTriggerFilter");
       MonitorElement* mMET_Reco_EcalDeadCellBoundaryFilter =
           iget_.get(rundirMET_reco + "/" + "MET_EcalDeadCellBoundaryFilter");
       MonitorElement* mMET_Reco_HcalStripHaloFilter = iget_.get(rundirMET_reco + "/" + "MET_HcalStripHaloFilter");
       ibook_.setCurrentFolder(rundirMET_reco);
       mMET_EffHBHENoiseFilter =
           ibook_.book1D("MET_EffHBHENoiseFilter", (TH1F*)mMET_Reco_HBHENoiseFilter->getRootObject());
       for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
         if (mMET_Reco->getBinContent(i) != 0) {
           mMET_EffHBHENoiseFilter->setBinContent(
               i, mMET_Reco_HBHENoiseFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
         } else {
           mMET_EffHBHENoiseFilter->setBinContent(i, 0);
         }
       }
       mMET_EffCSCTightHaloFilter =
           ibook_.book1D("MET_EffCSCTightHaloFilter", (TH1F*)mMET_Reco_CSCTightHaloFilter->getRootObject());
       for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
         if (mMET_Reco->getBinContent(i) != 0) {
           mMET_EffCSCTightHaloFilter->setBinContent(
               i, mMET_Reco_CSCTightHaloFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
         } else {
           mMET_EffCSCTightHaloFilter->setBinContent(i, 0);
         }
       }
       mMET_EffeeBadScFilter = ibook_.book1D("MET_EffeeBadScFilter", (TH1F*)mMET_Reco_eeBadScFilter->getRootObject());
       for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
         if (mMET_Reco->getBinContent(i) != 0) {
           mMET_EffeeBadScFilter->setBinContent(i,
                                                mMET_Reco_eeBadScFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
         } else {
           mMET_EffeeBadScFilter->setBinContent(i, 0);
         }
       }
       mMET_EffHBHEIsoNoiseFilter =
           ibook_.book1D("MET_EffHBHEIsoNoiseFilter", (TH1F*)mMET_Reco_HBHEIsoNoiseFilter->getRootObject());
       for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
         if (mMET_Reco->getBinContent(i) != 0) {
           mMET_EffHBHEIsoNoiseFilter->setBinContent(
               i, mMET_Reco_HBHEIsoNoiseFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
         } else {
           mMET_EffHBHEIsoNoiseFilter->setBinContent(i, 0);
         }
       }
       mMET_EffCSCTightHalo2015Filter =
           ibook_.book1D("MET_EffCSCTightHalo2015Filter", (TH1F*)mMET_Reco_CSCTightHalo2015Filter->getRootObject());
       for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
         if (mMET_Reco->getBinContent(i) != 0) {
           mMET_EffCSCTightHalo2015Filter->setBinContent(
               i, mMET_Reco_CSCTightHalo2015Filter->getBinContent(i) / mMET_Reco->getBinContent(i));
         } else {
           mMET_EffCSCTightHalo2015Filter->setBinContent(i, 0);
         }
       }
       mMET_EffEcalDeadCellTriggerFilter = ibook_.book1D("MET_EffEcalDeadCellTriggerFilter",
                                                         (TH1F*)mMET_Reco_EcalDeadCellTriggerFilter->getRootObject());
       for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
         if (mMET_Reco->getBinContent(i) != 0) {
           mMET_EffEcalDeadCellTriggerFilter->setBinContent(
               i, mMET_Reco_EcalDeadCellTriggerFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
         } else {
           mMET_EffEcalDeadCellTriggerFilter->setBinContent(i, 0);
         }
       }
       mMET_EffEcalDeadCellBoundaryFilter = ibook_.book1D("MET_EffEcalDeadCellBoundaryFilter",
                                                          (TH1F*)mMET_Reco_EcalDeadCellBoundaryFilter->getRootObject());
       for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
         if (mMET_Reco->getBinContent(i) != 0) {
           mMET_EffEcalDeadCellBoundaryFilter->setBinContent(
               i, mMET_Reco_EcalDeadCellBoundaryFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
         } else {
           mMET_EffEcalDeadCellBoundaryFilter->setBinContent(i, 0);
         }
       }
       mMET_EffHcalStripHaloFilter =
           ibook_.book1D("MET_EffHcalStripHaloFilter", (TH1F*)mMET_Reco_HcalStripHaloFilter->getRootObject());
       for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
         if (mMET_Reco->getBinContent(i) != 0) {
           mMET_EffHcalStripHaloFilter->setBinContent(
               i, mMET_Reco_HcalStripHaloFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
         } else {
           mMET_EffHcalStripHaloFilter->setBinContent(i, 0);
         }
       }
     }
     if ((subDirVecMET[i] + "/Cleaned") == (RunDirMET + inputMETLabelMiniAOD_.label() + "/Cleaned")) {
       found_METminiaod_dir = true;
     }
   }
   if (found_METreco_dir && found_METminiaod_dir) {
     std::string rundirMET_reco = RunDirMET + inputMETLabelRECO_.label() + "/Cleaned";
     std::string rundirMET_miniaod = RunDirMET + inputMETLabelMiniAOD_.label() + "/Cleaned";
     MonitorElement* mMET_Reco = iget_.get(rundirMET_reco + "/" + "MET");
     MonitorElement* mMEy_Reco = iget_.get(rundirMET_reco + "/" + "MEy");
     MonitorElement* mSumET_Reco = iget_.get(rundirMET_reco + "/" + "SumET");
     MonitorElement* mMETPhi_Reco = iget_.get(rundirMET_reco + "/" + "METPhi");
     MonitorElement* mMET_logx_Reco = iget_.get(rundirMET_reco + "/" + "MET_logx");
     MonitorElement* mSumET_logx_Reco = iget_.get(rundirMET_reco + "/" + "SumET_logx");
     MonitorElement* mChargedHadronEtFraction_Reco = iget_.get(rundirMET_reco + "/" + "PfChargedHadronEtFraction");
     MonitorElement* mNeutralHadronEtFraction_Reco = iget_.get(rundirMET_reco + "/" + "PfNeutralHadronEtFraction");
     MonitorElement* mPhotonEtFraction_Reco = iget_.get(rundirMET_reco + "/" + "PfPhotonEtFraction");
     MonitorElement* mHFHadronEtFraction_Reco = iget_.get(rundirMET_reco + "/" + "PfHFHadronEtFraction");
     MonitorElement* mHFEMEtFraction_Reco = iget_.get(rundirMET_reco + "/" + "PfHFEMEtFraction");
     MonitorElement* mMET_nVtx_profile_Reco = iget_.get(rundirMET_reco + "/" + "MET_profile");
     MonitorElement* mSumET_nVtx_profile_Reco = iget_.get(rundirMET_reco + "/" + "SumET_profile");
     MonitorElement* mChargedHadronEtFraction_nVtx_profile_Reco =
         iget_.get(rundirMET_reco + "/" + "PfChargedHadronEtFraction_profile");
     MonitorElement* mNeutralHadronEtFraction_nVtx_profile_Reco =
         iget_.get(rundirMET_reco + "/" + "PfNeutralHadronEtFraction_profile");
     MonitorElement* mPhotonEtFraction_nVtx_profile_Reco =
         iget_.get(rundirMET_reco + "/" + "PfPhotonEtFraction_profile");
 
     std::vector<MonitorElement*> me_MET_Reco;
     me_MET_Reco.push_back(mMET_Reco);
     me_MET_Reco.push_back(mMEy_Reco);
     me_MET_Reco.push_back(mSumET_Reco);
     me_MET_Reco.push_back(mMETPhi_Reco);
     me_MET_Reco.push_back(mMET_logx_Reco);
     me_MET_Reco.push_back(mSumET_logx_Reco);
     me_MET_Reco.push_back(mChargedHadronEtFraction_Reco);
     me_MET_Reco.push_back(mNeutralHadronEtFraction_Reco);
     me_MET_Reco.push_back(mPhotonEtFraction_Reco);
     me_MET_Reco.push_back(mHFHadronEtFraction_Reco);
     me_MET_Reco.push_back(mHFEMEtFraction_Reco);
     me_MET_Reco.push_back(mMET_nVtx_profile_Reco);
     me_MET_Reco.push_back(mSumET_nVtx_profile_Reco);
     me_MET_Reco.push_back(mChargedHadronEtFraction_nVtx_profile_Reco);
     me_MET_Reco.push_back(mNeutralHadronEtFraction_nVtx_profile_Reco);
     me_MET_Reco.push_back(mPhotonEtFraction_nVtx_profile_Reco);
 
     MonitorElement* mMET_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "MET");
     MonitorElement* mMEy_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "MEy");
     MonitorElement* mSumET_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "SumET");
     MonitorElement* mMETPhi_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "METPhi");
     MonitorElement* mMET_logx_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "MET_logx");
     MonitorElement* mSumET_logx_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "SumET_logx");
     MonitorElement* mChargedHadronEtFraction_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "PfChargedHadronEtFraction");
     MonitorElement* mNeutralHadronEtFraction_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "PfNeutralHadronEtFraction");
     MonitorElement* mPhotonEtFraction_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "PfPhotonEtFraction");
     MonitorElement* mHFHadronEtFraction_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "PfHFHadronEtFraction");
     MonitorElement* mHFEMEtFraction_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "PfHFEMEtFraction");
     MonitorElement* mMET_nVtx_profile_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "MET_profile");
     MonitorElement* mSumET_nVtx_profile_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "SumET_profile");
     MonitorElement* mChargedHadronEtFraction_nVtx_profile_MiniAOD =
         iget_.get(rundirMET_miniaod + "/" + "PfChargedHadronEtFraction_profile");
     MonitorElement* mNeutralHadronEtFraction_nVtx_profile_MiniAOD =
         iget_.get(rundirMET_miniaod + "/" + "PfNeutralHadronEtFraction_profile");
     MonitorElement* mPhotonEtFraction_nVtx_profile_MiniAOD =
         iget_.get(rundirMET_miniaod + "/" + "PfPhotonEtFraction_profile");
 
     std::vector<MonitorElement*> me_MET_MiniAOD;
     me_MET_MiniAOD.push_back(mMET_MiniAOD);
     me_MET_MiniAOD.push_back(mMEy_MiniAOD);
     me_MET_MiniAOD.push_back(mSumET_MiniAOD);
     me_MET_MiniAOD.push_back(mMETPhi_MiniAOD);
     me_MET_MiniAOD.push_back(mMET_logx_MiniAOD);
     me_MET_MiniAOD.push_back(mSumET_logx_MiniAOD);
     me_MET_MiniAOD.push_back(mChargedHadronEtFraction_MiniAOD);
     me_MET_MiniAOD.push_back(mNeutralHadronEtFraction_MiniAOD);
     me_MET_MiniAOD.push_back(mPhotonEtFraction_MiniAOD);
     me_MET_MiniAOD.push_back(mHFHadronEtFraction_MiniAOD);
     me_MET_MiniAOD.push_back(mHFEMEtFraction_MiniAOD);
     me_MET_MiniAOD.push_back(mMET_nVtx_profile_MiniAOD);
     me_MET_MiniAOD.push_back(mSumET_nVtx_profile_MiniAOD);
     me_MET_MiniAOD.push_back(mChargedHadronEtFraction_nVtx_profile_MiniAOD);
     me_MET_MiniAOD.push_back(mNeutralHadronEtFraction_nVtx_profile_MiniAOD);
     me_MET_MiniAOD.push_back(mPhotonEtFraction_nVtx_profile_MiniAOD);
 
     ibook_.setCurrentFolder(RunDirMET + "MiniAOD_over_RECO");
     mMET_MiniAOD_over_Reco = ibook_.book1D("MET_MiniAOD_over_RECO", (TH1F*)mMET_Reco->getRootObject());
     mMEy_MiniAOD_over_Reco = ibook_.book1D("MEy_MiniAOD_over_RECO", (TH1F*)mMEy_Reco->getRootObject());
     mSumET_MiniAOD_over_Reco = ibook_.book1D("SumET_MiniAOD_over_RECO", (TH1F*)mSumET_Reco->getRootObject());
     mMETPhi_MiniAOD_over_Reco = ibook_.book1D("METPhi_MiniAOD_over_RECO", (TH1F*)mMETPhi_Reco->getRootObject());
     mMET_logx_MiniAOD_over_Reco = ibook_.book1D("MET_logx_MiniAOD_over_RECO", (TH1F*)mMET_logx_Reco->getRootObject());
     mSumET_logx_MiniAOD_over_Reco =
         ibook_.book1D("SumET_logx_MiniAOD_over_RECO", (TH1F*)mSumET_logx_Reco->getRootObject());
     mChargedHadronEtFraction_MiniAOD_over_Reco = ibook_.book1D("PfChargedHadronEtFraction_MiniAOD_over_RECO",
                                                                (TH1F*)mChargedHadronEtFraction_Reco->getRootObject());
     mNeutralHadronEtFraction_MiniAOD_over_Reco = ibook_.book1D("PfNeutralHadronEtFraction_MiniAOD_over_RECO",
                                                                (TH1F*)mNeutralHadronEtFraction_Reco->getRootObject());
     mPhotonEtFraction_MiniAOD_over_Reco =
         ibook_.book1D("PfPhotonEtFraction_MiniAOD_over_RECO", (TH1F*)mPhotonEtFraction_Reco->getRootObject());
     mHFHadronEtFraction_MiniAOD_over_Reco =
         ibook_.book1D("PfHFHadronEtFraction_MiniAOD_over_RECO", (TH1F*)mHFHadronEtFraction_Reco->getRootObject());
     mHFEMEtFraction_MiniAOD_over_Reco =
         ibook_.book1D("PfHFEMEtFraction_MiniAOD_over_RECO", (TH1F*)mHFEMEtFraction_Reco->getRootObject());
     //use same parameters defining X-Axis of the profiles
     mMET_nVtx_profile_MiniAOD_over_Reco =
         ibook_.book1D("MET_profile_MiniAOD_over_RECO", "MET_vs_nVtx", nbinsPV_, nPVMin_, nPVMax_);
     mSumET_nVtx_profile_MiniAOD_over_Reco =
         ibook_.book1D("SumET_profile_MiniAOD_over_RECO", "SumET_vs_nVtx", nbinsPV_, nPVMin_, nPVMax_);
     mChargedHadronEtFraction_nVtx_profile_MiniAOD_over_Reco =
         ibook_.book1D("PfChargedHadronEtFraction_profile_MiniAOD_over_RECO",
                       "PfChargedHadronEtFraction_vs_nVtx",
                       nbinsPV_,
                       nPVMin_,
                       nPVMax_);
     mNeutralHadronEtFraction_nVtx_profile_MiniAOD_over_Reco =
         ibook_.book1D("PfNeutralHadronEtFraction_profile_MiniAOD_over_RECO",
                       "PfNeutralHadronEtFraction_vs_nVtx",
                       nbinsPV_,
                       nPVMin_,
                       nPVMax_);
     mPhotonEtFraction_nVtx_profile_MiniAOD_over_Reco = ibook_.book1D(
         "PfPhotonEtFraction_profile_MiniAOD_over_RECO", "PfPhotonEtFraction_vs_nVtx", nbinsPV_, nPVMin_, nPVMax_);
 
     std::vector<MonitorElement*> me_MET_MiniAOD_over_Reco;
     me_MET_MiniAOD_over_Reco.push_back(mMET_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mMEy_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mSumET_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mMETPhi_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mMET_logx_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mSumET_logx_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mChargedHadronEtFraction_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mNeutralHadronEtFraction_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mPhotonEtFraction_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mHFHadronEtFraction_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mHFEMEtFraction_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mMET_nVtx_profile_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mSumET_nVtx_profile_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mChargedHadronEtFraction_nVtx_profile_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mNeutralHadronEtFraction_nVtx_profile_MiniAOD_over_Reco);
     me_MET_MiniAOD_over_Reco.push_back(mPhotonEtFraction_nVtx_profile_MiniAOD_over_Reco);
 
     for (unsigned int j = 0; j < me_MET_MiniAOD_over_Reco.size(); j++) {
       MonitorElement* monMETReco = me_MET_Reco[j];
       if (monMETReco && monMETReco->getRootObject()) {
         MonitorElement* monMETMiniAOD = me_MET_MiniAOD[j];
         if (monMETMiniAOD && monMETMiniAOD->getRootObject()) {
           MonitorElement* monMETMiniAOD_over_RECO = me_MET_MiniAOD_over_Reco[j];
           if (monMETMiniAOD_over_RECO && monMETMiniAOD_over_RECO->getRootObject()) {
             for (int i = 0; i <= (monMETMiniAOD_over_RECO->getNbinsX() + 1); i++) {
               if (monMETReco->getBinContent(i) != 0) {
                 monMETMiniAOD_over_RECO->setBinContent(i,
                                                        monMETMiniAOD->getBinContent(i) / monMETReco->getBinContent(i));
               } else if (monMETMiniAOD->getBinContent(i) != 0) {
                 monMETMiniAOD_over_RECO->setBinContent(i, -0.5);
               }
             }
           }
         }
       }
     }
   }  //check for RECO and MiniAOD directories
 
   //put RECO vs MiniAODDir first ->second Jets
   std::vector<std::string> subDirVecJet;
   //go only for cleaned directory
   std::string RunDirJet = "JetMET/Jet/";
   iget_.setCurrentFolder(RunDirJet);
   subDirVecJet = iget_.getSubdirs();
   bool found_Jetreco_dir = false;
   bool found_Jetminiaod_dir = false;
   for (int i = 0; i < int(subDirVecJet.size()); i++) {
     ibook_.setCurrentFolder(subDirVecJet[i]);
     if (subDirVecJet[i] == (RunDirJet + "Cleaned" + inputJetLabelRECO_.label())) {
       found_Jetreco_dir = true;
     }
     if (subDirVecJet[i] == (RunDirJet + "Cleaned" + inputJetLabelMiniAOD_.label())) {
       found_Jetminiaod_dir = true;
     }
   }
   if (found_Jetreco_dir && found_Jetminiaod_dir) {
     std::string rundirJet_reco = RunDirJet + "Cleaned" + inputJetLabelRECO_.label();
     std::string rundirJet_miniaod = RunDirJet + "Cleaned" + inputJetLabelMiniAOD_.label();
 
     MonitorElement* mPt_Reco = iget_.get(rundirJet_reco + "/" + "Pt");
     MonitorElement* mEta_Reco = iget_.get(rundirJet_reco + "/" + "Eta");
     MonitorElement* mPhi_Reco = iget_.get(rundirJet_reco + "/" + "Phi");
     MonitorElement* mNjets_Reco = iget_.get(rundirJet_reco + "/" + "NJets");
     MonitorElement* mPt_uncor_Reco = iget_.get(rundirJet_reco + "/" + "Pt_uncor");
     MonitorElement* mEta_uncor_Reco = iget_.get(rundirJet_reco + "/" + "Eta_uncor");
     MonitorElement* mPhi_uncor_Reco = iget_.get(rundirJet_reco + "/" + "Phi_uncor");
     MonitorElement* mJetEnergyCorr_Reco = iget_.get(rundirJet_reco + "/" + "JetEnergyCorr");
     MonitorElement* mJetEnergyCorrVSeta_Reco = iget_.get(rundirJet_reco + "/" + "JetEnergyCorrVSEta");
     MonitorElement* mDPhi_Reco = iget_.get(rundirJet_reco + "/" + "DPhi");
     MonitorElement* mLooseJIDPassFractionVSeta_Reco = iget_.get(rundirJet_reco + "/" + "JetIDPassFractionVSeta");
     MonitorElement* mPt_Barrel_Reco = iget_.get(rundirJet_reco + "/" + "Pt_Barrel");
     MonitorElement* mPt_EndCap_Reco = iget_.get(rundirJet_reco + "/" + "Pt_EndCap");
     MonitorElement* mPt_Forward_Reco = iget_.get(rundirJet_reco + "/" + "Pt_Forward");
     MonitorElement* mMVAPUJIDDiscriminant_lowPt_Barrel_Reco =
         iget_.get(rundirJet_reco + "/" + "MVAPUJIDDiscriminant_lowPt_Barrel");
     MonitorElement* mMVAPUJIDDiscriminant_lowPt_EndCap_Reco =
         iget_.get(rundirJet_reco + "/" + "MVAPUJIDDiscriminant_lowPt_EndCap");
     MonitorElement* mMVAPUJIDDiscriminant_lowPt_Forward_Reco =
         iget_.get(rundirJet_reco + "/" + "MVAPUJIDDiscriminant_lowPt_Forward");
     MonitorElement* mMVAPUJIDDiscriminant_mediumPt_EndCap_Reco =
         iget_.get(rundirJet_reco + "/" + "MVAPUJIDDiscriminant_mediumPt_EndCap");
     MonitorElement* mMVAPUJIDDiscriminant_highPt_Barrel_Reco =
         iget_.get(rundirJet_reco + "/" + "MVAPUJIDDiscriminant_highPt_Barrel");
     MonitorElement* mCHFracVSpT_Barrel_Reco = iget_.get(rundirJet_reco + "/" + "CHFracVSpT_Barrel");
     MonitorElement* mNHFracVSpT_EndCap_Reco = iget_.get(rundirJet_reco + "/" + "NHFracVSpT_EndCap");
     MonitorElement* mPhFracVSpT_Barrel_Reco = iget_.get(rundirJet_reco + "/" + "PhFracVSpT_Barrel");
     MonitorElement* mHFHFracVSpT_Forward_Reco = iget_.get(rundirJet_reco + "/" + "HFHFracVSpT_Forward");
     MonitorElement* mHFEFracVSpT_Forward_Reco = iget_.get(rundirJet_reco + "/" + "HFEFracVSpT_Forward");
     MonitorElement* mCHFrac_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "CHFrac");
     MonitorElement* mNHFrac_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "NHFrac");
     MonitorElement* mPhFrac_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "PhFrac");
     MonitorElement* mChargedMultiplicity_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "ChargedMultiplicity");
     MonitorElement* mNeutralMultiplicity_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "NeutralMultiplicity");
     MonitorElement* mMuonMultiplicity_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "MuonMultiplicity");
     MonitorElement* mNeutralFraction_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "NeutralConstituentsFraction");
 
     std::vector<MonitorElement*> me_Jet_Reco;
     me_Jet_Reco.push_back(mPt_Reco);
     me_Jet_Reco.push_back(mEta_Reco);
     me_Jet_Reco.push_back(mPhi_Reco);
     me_Jet_Reco.push_back(mNjets_Reco);
     me_Jet_Reco.push_back(mPt_uncor_Reco);
     me_Jet_Reco.push_back(mEta_uncor_Reco);
     me_Jet_Reco.push_back(mPhi_uncor_Reco);
     me_Jet_Reco.push_back(mJetEnergyCorr_Reco);
     me_Jet_Reco.push_back(mJetEnergyCorrVSeta_Reco);
     me_Jet_Reco.push_back(mDPhi_Reco);
     me_Jet_Reco.push_back(mLooseJIDPassFractionVSeta_Reco);
     me_Jet_Reco.push_back(mPt_Barrel_Reco);
     me_Jet_Reco.push_back(mPt_EndCap_Reco);
     me_Jet_Reco.push_back(mPt_Forward_Reco);
     me_Jet_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_Barrel_Reco);
     me_Jet_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_EndCap_Reco);
     me_Jet_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_Forward_Reco);
     me_Jet_Reco.push_back(mMVAPUJIDDiscriminant_mediumPt_EndCap_Reco);
     me_Jet_Reco.push_back(mMVAPUJIDDiscriminant_highPt_Barrel_Reco);
     me_Jet_Reco.push_back(mCHFracVSpT_Barrel_Reco);
     me_Jet_Reco.push_back(mNHFracVSpT_EndCap_Reco);
     me_Jet_Reco.push_back(mPhFracVSpT_Barrel_Reco);
     me_Jet_Reco.push_back(mHFHFracVSpT_Forward_Reco);
     me_Jet_Reco.push_back(mHFEFracVSpT_Forward_Reco);
     me_Jet_Reco.push_back(mCHFrac_Reco);
     me_Jet_Reco.push_back(mNHFrac_Reco);
     me_Jet_Reco.push_back(mPhFrac_Reco);
     me_Jet_Reco.push_back(mChargedMultiplicity_Reco);
     me_Jet_Reco.push_back(mNeutralMultiplicity_Reco);
     me_Jet_Reco.push_back(mMuonMultiplicity_Reco);
     me_Jet_Reco.push_back(mNeutralFraction_Reco);
 
     MonitorElement* mPt_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Pt");
     MonitorElement* mEta_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Eta");
     MonitorElement* mPhi_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Phi");
     MonitorElement* mNjets_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "NJets");
     MonitorElement* mPt_uncor_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Pt_uncor");
     MonitorElement* mEta_uncor_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Eta_uncor");
     MonitorElement* mPhi_uncor_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Phi_uncor");
     MonitorElement* mJetEnergyCorr_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "JetEnergyCorr");
     MonitorElement* mJetEnergyCorrVSeta_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "JetEnergyCorrVSEta");
     MonitorElement* mDPhi_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "DPhi");
     MonitorElement* mLooseJIDPassFractionVSeta_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "JetIDPassFractionVSeta");
     MonitorElement* mPt_Barrel_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Pt_Barrel");
     MonitorElement* mPt_EndCap_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Pt_EndCap");
     MonitorElement* mPt_Forward_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Pt_Forward");
     MonitorElement* mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD =
         iget_.get(rundirJet_miniaod + "/" + "MVAPUJIDDiscriminant_lowPt_Barrel");
     MonitorElement* mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD =
         iget_.get(rundirJet_miniaod + "/" + "MVAPUJIDDiscriminant_lowPt_EndCap");
     MonitorElement* mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD =
         iget_.get(rundirJet_miniaod + "/" + "MVAPUJIDDiscriminant_lowPt_Forward");
     MonitorElement* mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD =
         iget_.get(rundirJet_miniaod + "/" + "MVAPUJIDDiscriminant_mediumPt_EndCap");
     MonitorElement* mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD =
         iget_.get(rundirJet_miniaod + "/" + "MVAPUJIDDiscriminant_highPt_Barrel");
     MonitorElement* mCHFracVSpT_Barrel_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "CHFracVSpT_Barrel");
     MonitorElement* mNHFracVSpT_EndCap_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "NHFracVSpT_EndCap");
     MonitorElement* mPhFracVSpT_Barrel_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "PhFracVSpT_Barrel");
     MonitorElement* mHFHFracVSpT_Forward_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "HFHFracVSpT_Forward");
     MonitorElement* mHFEFracVSpT_Forward_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "HFEFracVSpT_Forward");
     MonitorElement* mCHFrac_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "CHFrac");
     MonitorElement* mNHFrac_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "NHFrac");
     MonitorElement* mPhFrac_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "PhFrac");
     MonitorElement* mChargedMultiplicity_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "ChargedMultiplicity");
     MonitorElement* mNeutralMultiplicity_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "NeutralMultiplicity");
     MonitorElement* mMuonMultiplicity_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "MuonMultiplicity");
     MonitorElement* mNeutralFraction_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "NeutralConstituentsFraction");
 
     std::vector<MonitorElement*> me_Jet_MiniAOD;
     me_Jet_MiniAOD.push_back(mPt_MiniAOD);
     me_Jet_MiniAOD.push_back(mEta_MiniAOD);
     me_Jet_MiniAOD.push_back(mPhi_MiniAOD);
     me_Jet_MiniAOD.push_back(mNjets_MiniAOD);
     me_Jet_MiniAOD.push_back(mPt_uncor_MiniAOD);
     me_Jet_MiniAOD.push_back(mEta_uncor_MiniAOD);
     me_Jet_MiniAOD.push_back(mPhi_uncor_MiniAOD);
     me_Jet_MiniAOD.push_back(mJetEnergyCorr_MiniAOD);
     me_Jet_MiniAOD.push_back(mJetEnergyCorrVSeta_MiniAOD);
     me_Jet_MiniAOD.push_back(mDPhi_MiniAOD);
     me_Jet_MiniAOD.push_back(mLooseJIDPassFractionVSeta_MiniAOD);
     me_Jet_MiniAOD.push_back(mPt_Barrel_MiniAOD);
     me_Jet_MiniAOD.push_back(mPt_EndCap_MiniAOD);
     me_Jet_MiniAOD.push_back(mPt_Forward_MiniAOD);
     me_Jet_MiniAOD.push_back(mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD);
     me_Jet_MiniAOD.push_back(mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD);
     me_Jet_MiniAOD.push_back(mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD);
     me_Jet_MiniAOD.push_back(mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD);
     me_Jet_MiniAOD.push_back(mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD);
     me_Jet_MiniAOD.push_back(mCHFracVSpT_Barrel_MiniAOD);
     me_Jet_MiniAOD.push_back(mNHFracVSpT_EndCap_MiniAOD);
     me_Jet_MiniAOD.push_back(mPhFracVSpT_Barrel_MiniAOD);
     me_Jet_MiniAOD.push_back(mHFHFracVSpT_Forward_MiniAOD);
     me_Jet_MiniAOD.push_back(mHFEFracVSpT_Forward_MiniAOD);
     me_Jet_MiniAOD.push_back(mCHFrac_MiniAOD);
     me_Jet_MiniAOD.push_back(mNHFrac_MiniAOD);
     me_Jet_MiniAOD.push_back(mPhFrac_MiniAOD);
     me_Jet_MiniAOD.push_back(mChargedMultiplicity_MiniAOD);
     me_Jet_MiniAOD.push_back(mNeutralMultiplicity_MiniAOD);
     me_Jet_MiniAOD.push_back(mMuonMultiplicity_MiniAOD);
     me_Jet_MiniAOD.push_back(mNeutralFraction_MiniAOD);
 
     ibook_.setCurrentFolder(RunDirJet + "MiniAOD_over_RECO");
     mPt_MiniAOD_over_Reco = ibook_.book1D("Pt_MiniAOD_over_RECO", (TH1F*)mPt_Reco->getRootObject());
     mEta_MiniAOD_over_Reco = ibook_.book1D("Eta_MiniAOD_over_RECO", (TH1F*)mEta_Reco->getRootObject());
     mPhi_MiniAOD_over_Reco = ibook_.book1D("Phi_MiniAOD_over_RECO", (TH1F*)mPhi_Reco->getRootObject());
     mNjets_MiniAOD_over_Reco = ibook_.book1D("NJets_MiniAOD_over_RECO", (TH1F*)mNjets_Reco->getRootObject());
     mPt_uncor_MiniAOD_over_Reco = ibook_.book1D("Pt_uncor_MiniAOD_over_RECO", (TH1F*)mPt_uncor_Reco->getRootObject());
     mEta_uncor_MiniAOD_over_Reco =
         ibook_.book1D("Eta_uncor_MiniAOD_over_RECO", (TH1F*)mEta_uncor_Reco->getRootObject());
     mPhi_uncor_MiniAOD_over_Reco =
         ibook_.book1D("Phi_uncor_MiniAOD_over_RECO", (TH1F*)mPhi_uncor_Reco->getRootObject());
     mJetEnergyCorr_MiniAOD_over_Reco =
         ibook_.book1D("JetEnergyCorr_MiniAOD_over_RECO", (TH1F*)mJetEnergyCorr_Reco->getRootObject());
     mJetEnergyCorrVSeta_MiniAOD_over_Reco = ibook_.book1D(
         "JetEnergyCorrVSEta_MiniAOD_over_RECO", "jet energy correction factor VS eta", etaBin_, etaMin_, etaMax_);
     mDPhi_MiniAOD_over_Reco = ibook_.book1D("DPhi_MiniAOD_over_RECO", (TH1F*)mDPhi_Reco->getRootObject());
     mLooseJIDPassFractionVSeta_MiniAOD_over_Reco =
         ibook_.book1D("JetIDPassFractionVSeta_MiniAOD_over_RECO", "JetIDPassFractionVSeta", etaBin_, etaMin_, etaMax_);
     mPt_Barrel_MiniAOD_over_Reco =
         ibook_.book1D("Pt_Barrel_MiniAOD_over_RECO", (TH1F*)mPt_Barrel_Reco->getRootObject());
     mPt_EndCap_MiniAOD_over_Reco =
         ibook_.book1D("Pt_EndCap_MiniAOD_over_RECO", (TH1F*)mPt_EndCap_Reco->getRootObject());
     mPt_Forward_MiniAOD_over_Reco =
         ibook_.book1D("Pt_Forward_MiniAOD_over_RECO", (TH1F*)mPt_Forward_Reco->getRootObject());
     mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD_over_Reco =
         ibook_.book1D("MVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD_over_RECO",
                       (TH1F*)mMVAPUJIDDiscriminant_lowPt_Barrel_Reco->getRootObject());
     mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD_over_Reco =
         ibook_.book1D("MVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD_over_RECO",
                       (TH1F*)mMVAPUJIDDiscriminant_lowPt_EndCap_Reco->getRootObject());
     mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD_over_Reco =
         ibook_.book1D("MVAPUJIDDiscriminant_lowPt_Forward_MiniAOD_over_RECO",
                       (TH1F*)mMVAPUJIDDiscriminant_lowPt_Forward_Reco->getRootObject());
     mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD_over_Reco =
         ibook_.book1D("MVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD_over_RECO",
                       (TH1F*)mMVAPUJIDDiscriminant_mediumPt_EndCap_Reco->getRootObject());
     mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD_over_Reco =
         ibook_.book1D("MVAPUJIDDiscriminant_highPt_Barrel_MiniAOD_over_RECO",
                       (TH1F*)mMVAPUJIDDiscriminant_highPt_Barrel_Reco->getRootObject());
     mCHFracVSpT_Barrel_MiniAOD_over_Reco =
         ibook_.book1D("CHFracVSpT_Barrel_MiniAOD_over_RECO", "CHFracVSpT_Barrel", ptBin_, ptMin_, ptMax_);
     mNHFracVSpT_EndCap_MiniAOD_over_Reco =
         ibook_.book1D("NHFracVSpT_EndCap_MiniAOD_over_RECO", "NHFracVSpT_EndCap", ptBin_, ptMin_, ptMax_);
     mPhFracVSpT_Barrel_MiniAOD_over_Reco =
         ibook_.book1D("PhFracVSpT_Barrel_MiniAOD_over_RECO", "PhFracVSpT_Barrel", ptBin_, ptMin_, ptMax_);
     mHFHFracVSpT_Forward_MiniAOD_over_Reco =
         ibook_.book1D("HFHFracVSpT_Forward_MiniAOD_over_RECO", "HFHFracVSpT_Forward", ptBin_, ptMin_, ptMax_);
     mHFEFracVSpT_Forward_MiniAOD_over_Reco =
         ibook_.book1D("HFEFracVSpT_Forward_MiniAOD_over_RECO", "HFEFracVSpT_Forward", ptBin_, ptMin_, ptMax_);
     ibook_.setCurrentFolder(RunDirJet + "MiniAOD_over_RECO" + "/" + "DiJet");
     mCHFrac_MiniAOD_over_Reco = ibook_.book1D("CHFrac_MiniAOD_over_RECO", (TH1F*)mCHFrac_Reco->getRootObject());
     mNHFrac_MiniAOD_over_Reco = ibook_.book1D("NHFrac_MiniAOD_over_RECO", (TH1F*)mNHFrac_Reco->getRootObject());
     mPhFrac_MiniAOD_over_Reco = ibook_.book1D("PhFrac_MiniAOD_over_RECO", (TH1F*)mPhFrac_Reco->getRootObject());
     mChargedMultiplicity_MiniAOD_over_Reco =
         ibook_.book1D("ChargedMultiplicity_MiniAOD_over_RECO", (TH1F*)mChargedMultiplicity_Reco->getRootObject());
     mNeutralMultiplicity_MiniAOD_over_Reco =
         ibook_.book1D("NeutralMultiplicity_MiniAOD_over_RECO", (TH1F*)mNeutralMultiplicity_Reco->getRootObject());
     mMuonMultiplicity_MiniAOD_over_Reco =
         ibook_.book1D("MuonMultiplicity_MiniAOD_over_RECO", (TH1F*)mMuonMultiplicity_Reco->getRootObject());
     mNeutralFraction_MiniAOD_over_Reco =
         ibook_.book1D("NeutralConstituentsFraction_MiniAOD_over_RECO", (TH1F*)mNeutralFraction_Reco->getRootObject());
 
     std::vector<MonitorElement*> me_Jet_MiniAOD_over_Reco;
     me_Jet_MiniAOD_over_Reco.push_back(mPt_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mEta_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mPhi_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mNjets_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mPt_uncor_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mEta_uncor_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mPhi_uncor_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mJetEnergyCorr_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mJetEnergyCorrVSeta_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mDPhi_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mLooseJIDPassFractionVSeta_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mPt_Barrel_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mPt_EndCap_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mPt_Forward_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mCHFracVSpT_Barrel_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mNHFracVSpT_EndCap_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mPhFracVSpT_Barrel_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mHFHFracVSpT_Forward_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mHFEFracVSpT_Forward_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mCHFrac_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mNHFrac_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mPhFrac_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mChargedMultiplicity_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mNeutralMultiplicity_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mMuonMultiplicity_MiniAOD_over_Reco);
     me_Jet_MiniAOD_over_Reco.push_back(mNeutralFraction_MiniAOD_over_Reco);
 
     for (unsigned int j = 0; j < me_Jet_MiniAOD_over_Reco.size(); j++) {
       MonitorElement* monJetReco = me_Jet_Reco[j];
       if (monJetReco && monJetReco->getRootObject()) {
         MonitorElement* monJetMiniAOD = me_Jet_MiniAOD[j];
         if (monJetMiniAOD && monJetMiniAOD->getRootObject()) {
           MonitorElement* monJetMiniAOD_over_RECO = me_Jet_MiniAOD_over_Reco[j];
           if (monJetMiniAOD_over_RECO && monJetMiniAOD_over_RECO->getRootObject()) {
             for (int i = 0; i <= (monJetMiniAOD_over_RECO->getNbinsX() + 1); i++) {
               if (monJetReco->getBinContent(i) != 0) {
                 monJetMiniAOD_over_RECO->setBinContent(i,
                                                        monJetMiniAOD->getBinContent(i) / monJetReco->getBinContent(i));
               } else if (monJetMiniAOD->getBinContent(i) != 0) {
                 monJetMiniAOD_over_RECO->setBinContent(i, -0.5);
               }
             }
           }
         }
       }
     }
   }  //check for RECO and MiniAOD directories
 
   if (verbose_)
     std::cout << ">>> EndRun (DataCertificationJetMET) <<<" << std::endl;
 
   std::vector<std::string> subDirVec;
   std::string RunDir;
 
   if (verbose_)
     std::cout << "InMemory_           = " << InMemory_ << std::endl;
 
   ibook_.setCurrentFolder(folderName);
   reportSummary = ibook_.bookFloat("reportSummary");
   CertificationSummary = ibook_.bookFloat("CertificationSummary");
 
   reportSummaryMap = ibook_.book2D("reportSummaryMap", "reportSummaryMap", 3, 0, 3, 5, 0, 5);
   CertificationSummaryMap = ibook_.book2D("CertificationSummaryMap", "CertificationSummaryMap", 3, 0, 3, 5, 0, 5);
 
   reportSummary = iget_.get(folderName + "/" + "reportSummary");
   CertificationSummary = iget_.get(folderName + "/" + "CertificationSummary");
   reportSummaryMap = iget_.get(folderName + "/" + "reportSummaryMap");
   CertificationSummaryMap = iget_.get(folderName + "/" + "CertificationSummaryMap");
 
   if (reportSummaryMap && reportSummaryMap->getRootObject()) {
     reportSummaryMap->getTH2F()->SetStats(kFALSE);
     reportSummaryMap->setOption("colz");
     reportSummaryMap->setBinLabel(1, "CaloTower");
     reportSummaryMap->setBinLabel(2, "MET");
     reportSummaryMap->setBinLabel(3, "Jet");
   }
   if (CertificationSummaryMap && CertificationSummaryMap->getRootObject()) {
     CertificationSummaryMap->getTH2F()->SetStats(kFALSE);
     CertificationSummaryMap->setOption("colz");
     CertificationSummaryMap->setBinLabel(1, "CaloTower");
     CertificationSummaryMap->setBinLabel(2, "MET");
     CertificationSummaryMap->setBinLabel(3, "Jet");
   }
 
   reportSummary->Fill(1.);
   CertificationSummary->Fill(1.);
 
   if (RunDir == "Reference")
     RunDir = "";
   if (verbose_)
     std::cout << RunDir << std::endl;
   ibook_.setCurrentFolder("JetMET/EventInfo/CertificationSummaryContents/");
 
   std::string refHistoName;
   std::string newHistoName;
 
   //-----------------------------
   // Jet DQM Data Certification
   //-----------------------------
   //we have 4 types anymore: PF (barrel,endcap,forward) and calojets
   MonitorElement* meJetPt[4];
   MonitorElement* meJetEta[4];
   MonitorElement* meJetPhi[4];
   MonitorElement* meJetEMFrac[4];
   MonitorElement* meJetConstituents[4];
   RunDir = "";
   if (RunDir.empty())
     newHistoName = "JetMET/Jet/";
   else
     newHistoName = RunDir + "/JetMET/Runsummary/Jet/";
   std::string cleaningdir = "";
   cleaningdir = "Cleaned";
 
   // Read different histograms for PbPb and pp collisions
 
   if (isHI) {  // Histograms for heavy ions
 
     newHistoName = "JetMET/HIJetValidation/";
     cleaningdir = "";
 
     //Jet Phi histos
     meJetPhi[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Cs4PFJets/Phi");
     meJetPhi[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu3PFJets/Phi");
     meJetPhi[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4PFJets/Phi");
     meJetPhi[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4CaloJets/Phi");
 
     //Jet Eta histos
     meJetEta[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Cs4PFJets/Eta");
     meJetEta[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu3PFJets/Eta");
     meJetEta[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4PFJets/Eta");
     meJetEta[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4CaloJets/Eta");
 
     //Jet Pt histos
     meJetPt[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Cs4PFJets/Pt");
     meJetPt[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu3PFJets/Pt");
     meJetPt[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4PFJets/Pt");
     meJetPt[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4CaloJets/Pt");
 
     //Jet Constituents histos
     meJetConstituents[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Cs4PFJets/Constituents");
     meJetConstituents[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu3PFJets/Constituents");
     meJetConstituents[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4PFJets/Constituents");
     meJetConstituents[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4CaloJets/Constituents");
 
     //There are no jet EMFrac histograms for HI. Dummy paths will pass the tests by default
     meJetEMFrac[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "dummy/dummy");
     meJetEMFrac[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "dummy/dummy");
     meJetEMFrac[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "dummy/dummy");
     meJetEMFrac[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "dummy/dummy");
 
   } else {  // Histograms for protons
 
     //Jet Phi histos
     meJetPhi[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Phi_Barrel");
     meJetPhi[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Phi_EndCap");
     meJetPhi[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Phi_Forward");
     meJetPhi[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "CaloJets/Phi");
     //meJetPhi[4] = iget_.get(newHistoName+cleaningdir+"JetPlusTrackZSPCorJetAntiKt5/Phi");
 
     //Jet Eta histos
     meJetEta[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Eta");
     meJetEta[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Eta");
     meJetEta[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/EtaFirst");
     meJetEta[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "CaloJets/Eta");
     //meJetEta[4] = iget_.get(newHistoName+cleaningdir+"JetPlusTrackZSPCorJetAntiKt5/Eta");
 
     //Jet Pt histos
     meJetPt[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Pt_Barrel");
     meJetPt[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Pt_EndCap");
     meJetPt[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Pt_Forward");
     meJetPt[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "CaloJets/Pt_2");
 
     //Jet Constituents histos
     meJetConstituents[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Constituents_Barrel");
     meJetConstituents[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Constituents_EndCap");
     meJetConstituents[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Constituents_Forward");
     meJetConstituents[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "CaloJets/Constituents");
 
     //Jet EMFrac histos
     meJetEMFrac[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/EFrac_Barrel");
     meJetEMFrac[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/EFrac_EndCap");
     meJetEMFrac[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/EFrac_Forward");
     meJetEMFrac[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "CaloJets/EFrac");
   }
 
   //------------------------------------------------------------------------------
   //--- Extract quality test results and fill data certification results for Jets
   //--- Tests for Calo Barrel, EndCap and Forward, as well as PF and JPT jets
   //--- For Calo and PF jets:
   //--- Look at mean of Constituents, EM Frac and Pt
   //--- Look at Kolmogorov result for Eta, Phi, and Pt
   //--- For JPT jets:
   //--- Look at mean of Pt, AllPionsTrackNHits?, nTracks,
   //--- Look at Kolmogorov result for Eta, Phi, and Pt
   //------------------------------------------------------------------------------
 
   // Four types of jets {AK5 Barrel, AK5 EndCap, AK5 Forward, PF}, removed JPT which is 5th type of jets
   //----------------------------------------------------------------------------
   // Kolmogorov (KS) tests
   const QReport* QReport_JetEta[4] = {nullptr};
   const QReport* QReport_JetPhi[4] = {nullptr};
   // Mean and KS tests for Calo and PF jets
   const QReport* QReport_JetConstituents[4][2] = {{nullptr}};
   const QReport* QReport_JetEFrac[4][2] = {{nullptr}};
   const QReport* QReport_JetPt[4][2] = {{nullptr}};
 
   // Mean and KS tests for JPT jets
   //const QReport* QReport_JetNTracks[2] = {0, 0};
   float qr_Jet_Eta[4] = {-1};
   float qr_Jet_Phi[4] = {-1};
   float dc_Jet[4] = {-1};
 
   float qr_Jet_Constituents[4][2] = {{-1}};
   float qr_Jet_EFrac[4][2] = {{-1}};
   float qr_Jet_Pt[4][2] = {{-1}};
 
   // Loop
   //----------------------------------------------------------------------------
   for (int jtyp = 0; jtyp < 4; ++jtyp) {
     // Mean test results
 
     if (meJetConstituents[jtyp] && meJetConstituents[jtyp]->getRootObject()) {
       QReport_JetConstituents[jtyp][0] = meJetConstituents[jtyp]->getQReport("meanJetConstituentsTest");
       QReport_JetConstituents[jtyp][1] = meJetConstituents[jtyp]->getQReport("KolmogorovTest");
     }
     if (meJetEMFrac[jtyp] && meJetEMFrac[jtyp]->getRootObject()) {
       QReport_JetEFrac[jtyp][0] = meJetEMFrac[jtyp]->getQReport("meanEMFractionTest");
       QReport_JetEFrac[jtyp][1] = meJetEMFrac[jtyp]->getQReport("KolmogorovTest");
     }
     if (meJetPt[jtyp] && meJetPt[jtyp]->getRootObject()) {
       QReport_JetPt[jtyp][0] = meJetPt[jtyp]->getQReport("meanJetPtTest");
       QReport_JetPt[jtyp][1] = meJetPt[jtyp]->getQReport("KolmogorovTest");
     }
     if (meJetPhi[jtyp] && meJetPhi[jtyp]->getRootObject()) {
       QReport_JetPhi[jtyp] = meJetPhi[jtyp]->getQReport("KolmogorovTest");
     }
     if (meJetEta[jtyp] && meJetEta[jtyp]->getRootObject()) {
       QReport_JetEta[jtyp] = meJetEta[jtyp]->getQReport("KolmogorovTest");
     }
 
     //Jet Pt test
     if (QReport_JetPt[jtyp][0]) {
       //std::cout<<"jet type test pt "<<jtyp<<"/"<<QReport_JetPt[jtyp][0]->getStatus()<<std::endl;
       if (QReport_JetPt[jtyp][0]->getStatus() == 100 || QReport_JetPt[jtyp][0]->getStatus() == 200)
         qr_Jet_Pt[jtyp][0] = 1;
       else if (QReport_JetPt[jtyp][0]->getStatus() == 300)
         qr_Jet_Pt[jtyp][0] = 0;
       else
         qr_Jet_Pt[jtyp][0] = -1;
     } else {
       qr_Jet_Pt[jtyp][0] = -2;
       //std::cout<<"qreport is REALLY NULL type test pt "<<jtyp<<" 0 "<<std::endl;
     }
     if (QReport_JetPt[jtyp][1]) {
       if (QReport_JetPt[jtyp][1]->getStatus() == 100 || QReport_JetPt[jtyp][1]->getStatus() == 200)
         qr_Jet_Pt[jtyp][1] = 1;
       else if (QReport_JetPt[jtyp][1]->getStatus() == 300)
         qr_Jet_Pt[jtyp][1] = 0;
       else
         qr_Jet_Pt[jtyp][1] = -1;
     } else {
       qr_Jet_Pt[jtyp][1] = -2;
     }
 
     //Jet Phi test
     if (QReport_JetPhi[jtyp]) {
       if (QReport_JetPhi[jtyp]->getStatus() == 100 || QReport_JetPhi[jtyp]->getStatus() == 200)
         qr_Jet_Phi[jtyp] = 1;
       else if (QReport_JetPhi[jtyp]->getStatus() == 300)
         qr_Jet_Phi[jtyp] = 0;
       else
         qr_Jet_Phi[jtyp] = -1;
     } else {
       qr_Jet_Phi[jtyp] = -2;
     }
     //Jet Eta test
     if (QReport_JetEta[jtyp]) {
       if (QReport_JetEta[jtyp]->getStatus() == 100 || QReport_JetEta[jtyp]->getStatus() == 200)
         qr_Jet_Eta[jtyp] = 1;
       else if (QReport_JetEta[jtyp]->getStatus() == 300)
         qr_Jet_Eta[jtyp] = 0;
       else
         qr_Jet_Eta[jtyp] = -1;
     } else {
       qr_Jet_Eta[jtyp] = -2;
     }
     //Jet Constituents test
     if (QReport_JetConstituents[jtyp][0]) {
       if (QReport_JetConstituents[jtyp][0]->getStatus() == 100 || QReport_JetConstituents[jtyp][0]->getStatus() == 200)
         qr_Jet_Constituents[jtyp][0] = 1;
       else if (QReport_JetConstituents[jtyp][0]->getStatus() == 300)
         qr_Jet_Constituents[jtyp][0] = 0;
       else
         qr_Jet_Constituents[jtyp][0] = -1;
     } else {
       qr_Jet_Constituents[jtyp][0] = -2;
     }
 
     if (QReport_JetConstituents[jtyp][1]) {
       if (QReport_JetConstituents[jtyp][1]->getStatus() == 100 || QReport_JetConstituents[jtyp][1]->getStatus() == 200)
         qr_Jet_Constituents[jtyp][1] = 1;
       else if (QReport_JetConstituents[jtyp][1]->getStatus() == 300)
         qr_Jet_Constituents[jtyp][1] = 0;
       else
         qr_Jet_Constituents[jtyp][1] = -1;
     } else {
       qr_Jet_Constituents[jtyp][1] = -2;
     }
     //Jet EMFrac test
     if (QReport_JetEFrac[jtyp][0]) {
       if (QReport_JetEFrac[jtyp][0]->getStatus() == 100 || QReport_JetEFrac[jtyp][0]->getStatus() == 200)
         qr_Jet_EFrac[jtyp][0] = 1;
       else if (QReport_JetEFrac[jtyp][0]->getStatus() == 300)
         qr_Jet_EFrac[jtyp][0] = 0;
       else
         qr_Jet_EFrac[jtyp][0] = -1;
     } else {
       qr_Jet_EFrac[jtyp][0] = -2;
     }
 
     if (QReport_JetEFrac[jtyp][1]) {
       if (QReport_JetEFrac[jtyp][1]->getStatus() == 100 || QReport_JetEFrac[jtyp][1]->getStatus() == 200)
         qr_Jet_EFrac[jtyp][1] = 1;
       else if (QReport_JetEFrac[jtyp][1]->getStatus() == 300)
         qr_Jet_EFrac[jtyp][1] = 0;
       else
         qr_Jet_EFrac[jtyp][1] = -1;
     } else {
       qr_Jet_EFrac[jtyp][1] = -2;
     }
 
     if (verbose_) {
       printf("====================Jet Type %d QTest Report Summary========================\n", jtyp);
       printf("Eta:    Phi:   Pt 1:    2:    Const/Ntracks 1:    2:    EFrac/tracknhits 1:    2:\n");
 
       printf("%2.2f    %2.2f    %2.2f    %2.2f    %2.2f    %2.2f    %2.2f    %2.2f\n",
              qr_Jet_Eta[jtyp],
              qr_Jet_Phi[jtyp],
              qr_Jet_Pt[jtyp][0],
              qr_Jet_Pt[jtyp][1],
              qr_Jet_Constituents[jtyp][0],
              qr_Jet_Constituents[jtyp][1],
              qr_Jet_EFrac[jtyp][0],
              qr_Jet_EFrac[jtyp][1]);
     }
     //certification result for Jet
 
     //Only apply certain tests, as defined in the config
     for (int ttyp = 0; ttyp < 2; ++ttyp) {
       if (!jetTests[jtyp][ttyp]) {
         qr_Jet_Pt[jtyp][ttyp] = 1;
         if (ttyp == 1) {
           qr_Jet_Eta[jtyp] = 1;
           qr_Jet_Phi[jtyp] = 1;
         }
         qr_Jet_EFrac[jtyp][ttyp] = 1;
         qr_Jet_Constituents[jtyp][ttyp] = 1;
       }
     }
 
     if ((qr_Jet_EFrac[jtyp][0] == 0) || (qr_Jet_EFrac[jtyp][1] == 0) || (qr_Jet_Constituents[jtyp][1] == 0) ||
         (qr_Jet_Constituents[jtyp][0] == 0) || (qr_Jet_Eta[jtyp] == 0) || (qr_Jet_Phi[jtyp] == 0) ||
         (qr_Jet_Pt[jtyp][0] == 0) || (qr_Jet_Pt[jtyp][1] == 0))
       dc_Jet[jtyp] = 0;
     else if ((qr_Jet_EFrac[jtyp][0] == -1) && (qr_Jet_EFrac[jtyp][1] == -1) && (qr_Jet_Constituents[jtyp][1] == -1) &&
              (qr_Jet_Constituents[jtyp][0] == -1) && (qr_Jet_Eta[jtyp] == -1) && (qr_Jet_Phi[jtyp] == -1) &&
              (qr_Jet_Pt[jtyp][0] == -1) && (qr_Jet_Pt[jtyp][1] == -1))
       dc_Jet[jtyp] = -1;
     else if ((qr_Jet_EFrac[jtyp][0] == -2) && (qr_Jet_EFrac[jtyp][1] == -2) && (qr_Jet_Constituents[jtyp][1] == -2) &&
              (qr_Jet_Constituents[jtyp][0] == -2) && (qr_Jet_Eta[jtyp] == -2) && (qr_Jet_Phi[jtyp] == -2) &&
              (qr_Jet_Pt[jtyp][0] == -2) && (qr_Jet_Pt[jtyp][1] == -2))
       dc_Jet[jtyp] = -2;
     else
       dc_Jet[jtyp] = 1;
 
     if (verbose_)
       std::cout << "Certifying Jet algo: " << jtyp << " with value: " << dc_Jet[jtyp] << std::endl;
 
     CertificationSummaryMap->Fill(2, 4 - jtyp, dc_Jet[jtyp]);
     reportSummaryMap->Fill(2, 4 - jtyp, dc_Jet[jtyp]);
   }
 
   // There is nothing on the first row for HI, so mark the unfilled
   if (isHI) {
     CertificationSummaryMap->Fill(2, 0, -2);
     reportSummaryMap->Fill(2, 0, -2);
   }
 
   //-----------------------------
   // MET DQM Data Certification
   //-----------------------------
   //
   // Prepare test histograms
   //
   MonitorElement* meMExy[2][2];
   MonitorElement* meMEt[2];
   MonitorElement* meSumEt[2];
   MonitorElement* meMETPhi[2];
 
   RunDir = "";
   if (RunDir.empty())
     newHistoName = "JetMET/MET/";
   else
     newHistoName = RunDir + "/JetMET/Runsummary/MET/";
 
   metFolder = "Cleaned";
 
   //MEx/MEy monitor elements
   meMExy[0][0] = iget_.get(newHistoName + "met/" + metFolder + "/MEx");
   meMExy[0][1] = iget_.get(newHistoName + "met/" + metFolder + "/MEy");
   meMExy[1][0] = iget_.get(newHistoName + "pfMet/" + metFolder + "/MEx");
   meMExy[1][1] = iget_.get(newHistoName + "pfMet/" + metFolder + "/MEy");
 
   //MET Phi monitor elements
   meMETPhi[0] = iget_.get(newHistoName + "met/" + metFolder + "/METPhi");
   meMETPhi[1] = iget_.get(newHistoName + "pfMet/" + metFolder + "/METPhi");
   //MET monitor elements
   meMEt[0] = iget_.get(newHistoName + "met/" + metFolder + "/MET");
   meMEt[1] = iget_.get(newHistoName + "pfMet/" + metFolder + "/MET");
   //SumET monitor elements
   meSumEt[0] = iget_.get(newHistoName + "met/" + metFolder + "/SumET");
   meSumEt[1] = iget_.get(newHistoName + "pfMet/" + metFolder + "/SumET");
 
   //----------------------------------------------------------------------------
   //--- Extract quality test results and fill data certification results for MET
   //----------------------------------------------------------------------------
 
   // 2 types of MET {CaloMET, PfMET}  // It is 5 if CaloMETNoHF is included, 4 for MuonCorMET
   // removed 3rd type of TcMET
   // 2 types of tests Mean test/Kolmogorov test
   const QReport* QReport_MExy[2][2][2] = {{{nullptr}}};
   const QReport* QReport_MEt[2][2] = {{nullptr}};
   const QReport* QReport_SumEt[2][2] = {{nullptr}};
   //2 types of tests phiQTest and Kolmogorov test
   const QReport* QReport_METPhi[2][2] = {{nullptr}};
 
   float qr_MET_MExy[2][2][2] = {{{-999.}}};
   float qr_MET_MEt[2][2] = {{-999.}};
   float qr_MET_SumEt[2][2] = {{-999.}};
   float qr_MET_METPhi[2][2] = {{-999.}};
   float dc_MET[2] = {-999.};
 
   // J.Piedra, 27/02/212
   // removed MuCorrMET & TcMET --> loop up to 2 instead of 4, remove already from definition
   for (int mtyp = 0; mtyp < 2; ++mtyp) {
     //Mean test results
     if (meMExy[mtyp][0] && meMExy[mtyp][0]->getRootObject()) {
       QReport_MExy[mtyp][0][0] = meMExy[mtyp][0]->getQReport("meanMExyTest");
       QReport_MExy[mtyp][1][0] = meMExy[mtyp][0]->getQReport("KolmogorovTest");
     }
     if (meMExy[mtyp][1] && meMExy[mtyp][1]->getRootObject()) {
       QReport_MExy[mtyp][0][1] = meMExy[mtyp][1]->getQReport("meanMExyTest");
       QReport_MExy[mtyp][1][1] = meMExy[mtyp][1]->getQReport("KolmogorovTest");
     }
     if (meMEt[mtyp] && meMEt[mtyp]->getRootObject()) {
       QReport_MEt[mtyp][0] = meMEt[mtyp]->getQReport("meanMETTest");
       QReport_MEt[mtyp][1] = meMEt[mtyp]->getQReport("KolmogorovTest");
     }
 
     if (meSumEt[mtyp] && meSumEt[mtyp]->getRootObject()) {
       QReport_SumEt[mtyp][0] = meSumEt[mtyp]->getQReport("meanSumETTest");
       QReport_SumEt[mtyp][1] = meSumEt[mtyp]->getQReport("KolmogorovTest");
     }
 
     if (meMETPhi[mtyp] && meMETPhi[mtyp]->getRootObject()) {
       QReport_METPhi[mtyp][0] = meMETPhi[mtyp]->getQReport("phiQTest");
       QReport_METPhi[mtyp][1] = meMETPhi[mtyp]->getQReport("KolmogorovTest");
     }
     for (int testtyp = 0; testtyp < 2; ++testtyp) {
       //MEx test
       if (QReport_MExy[mtyp][testtyp][0]) {
         if (QReport_MExy[mtyp][testtyp][0]->getStatus() == 100 || QReport_MExy[mtyp][testtyp][0]->getStatus() == 200)
           qr_MET_MExy[mtyp][testtyp][0] = 1;
         else if (QReport_MExy[mtyp][testtyp][0]->getStatus() == 300)
           qr_MET_MExy[mtyp][testtyp][0] = 0;
         else
           qr_MET_MExy[mtyp][testtyp][0] = -1;
       } else
         qr_MET_MExy[mtyp][testtyp][0] = -2;
       //MEy test
       if (QReport_MExy[mtyp][testtyp][1]) {
         if (QReport_MExy[mtyp][testtyp][1]->getStatus() == 100 || QReport_MExy[mtyp][testtyp][1]->getStatus() == 200)
           qr_MET_MExy[mtyp][testtyp][1] = 1;
         else if (QReport_MExy[mtyp][testtyp][1]->getStatus() == 300)
           qr_MET_MExy[mtyp][testtyp][1] = 0;
         else
           qr_MET_MExy[mtyp][testtyp][1] = -1;
       } else
         qr_MET_MExy[mtyp][testtyp][1] = -2;
 
       //MEt test
       if (QReport_MEt[mtyp][testtyp]) {
         if (QReport_MEt[mtyp][testtyp]->getStatus() == 100 || QReport_MEt[mtyp][testtyp]->getStatus() == 200)
           qr_MET_MEt[mtyp][testtyp] = 1;
         else if (QReport_MEt[mtyp][testtyp]->getStatus() == 300)
           qr_MET_MEt[mtyp][testtyp] = 0;
         else
           qr_MET_MEt[mtyp][testtyp] = -1;
       } else {
         qr_MET_MEt[mtyp][testtyp] = -2;
       }
       //SumEt test
       if (QReport_SumEt[mtyp][testtyp]) {
         if (QReport_SumEt[mtyp][testtyp]->getStatus() == 100 || QReport_SumEt[mtyp][testtyp]->getStatus() == 200)
           qr_MET_SumEt[mtyp][testtyp] = 1;
         else if (QReport_SumEt[mtyp][testtyp]->getStatus() == 300)
           qr_MET_SumEt[mtyp][testtyp] = 0;
         else
           qr_MET_SumEt[mtyp][testtyp] = -1;
       } else {
         qr_MET_SumEt[mtyp][testtyp] = -2;
       }
       //METPhi test
       if (QReport_METPhi[mtyp][testtyp]) {
         if (QReport_METPhi[mtyp][testtyp]->getStatus() == 100 || QReport_METPhi[mtyp][testtyp]->getStatus() == 200)
           qr_MET_METPhi[mtyp][testtyp] = 1;
         else if (QReport_METPhi[mtyp][testtyp]->getStatus() == 300)
           qr_MET_METPhi[mtyp][testtyp] = 0;
         else
           qr_MET_METPhi[mtyp][testtyp] = -1;
       } else {
         qr_MET_METPhi[mtyp][testtyp] = -2;
       }
     }
 
     if (verbose_) {
       //certification result for MET
       printf("====================MET Type %d QTest Report Summary========================\n", mtyp);
       printf("MEx test    MEy test    MEt test:    SumEt test:    METPhi test:\n");
       for (int tt = 0; tt < 2; ++tt) {
         printf("%2.2f    %2.2f    %2.2f    %2.2f    %2.2f\n",
                qr_MET_MExy[mtyp][tt][0],
                qr_MET_MExy[mtyp][tt][1],
                qr_MET_MEt[mtyp][tt],
                qr_MET_SumEt[mtyp][tt],
                qr_MET_METPhi[mtyp][tt]);
       }
       printf("===========================================================================\n");
     }
 
     //Only apply certain tests, as defined in the config
     for (int ttyp = 0; ttyp < 2; ++ttyp) {
       if (!metTests[mtyp][ttyp]) {
         qr_MET_MExy[mtyp][ttyp][0] = 1;
         qr_MET_MExy[mtyp][ttyp][1] = 1;
         qr_MET_MEt[mtyp][ttyp] = 1;
         qr_MET_SumEt[mtyp][ttyp] = 1;
         qr_MET_METPhi[mtyp][ttyp] = 1;
       }
     }
 
     if ((qr_MET_MExy[mtyp][0][0] == 0) || (qr_MET_MExy[mtyp][0][1] == 0) || (qr_MET_MEt[mtyp][0] == 0) ||
         (qr_MET_SumEt[mtyp][0] == 0) || (qr_MET_METPhi[mtyp][0] == 0) || (qr_MET_MExy[mtyp][1][0] == 0) ||
         (qr_MET_MExy[mtyp][1][1] == 0) || (qr_MET_MEt[mtyp][1] == 0) || (qr_MET_SumEt[mtyp][1] == 0) ||
         (qr_MET_METPhi[mtyp][1] == 0))
       dc_MET[mtyp] = 0;
     else if ((qr_MET_MExy[mtyp][0][0] == -1) && (qr_MET_MExy[mtyp][0][1] == -1) && (qr_MET_MEt[mtyp][0] == -1) &&
              (qr_MET_SumEt[mtyp][0] == -1) && (qr_MET_METPhi[mtyp][0] == -1) && (qr_MET_MExy[mtyp][1][0] == -1) &&
              (qr_MET_MExy[mtyp][1][1] == -1) && (qr_MET_MEt[mtyp][1] == -1) && (qr_MET_SumEt[mtyp][1] == -1) &&
              (qr_MET_METPhi[mtyp][1] == -1))
       dc_MET[mtyp] = -1;
     else if ((qr_MET_MExy[mtyp][0][0] == -2) && (qr_MET_MExy[mtyp][0][1] == -2) && (qr_MET_MEt[mtyp][0] == -2) &&
              (qr_MET_SumEt[mtyp][0] == -2) && (qr_MET_METPhi[mtyp][0] == -2) && (qr_MET_MExy[mtyp][1][0] == -2) &&
              (qr_MET_MExy[mtyp][1][1] == -2) && (qr_MET_MEt[mtyp][1] == -2) && (qr_MET_SumEt[mtyp][1] == -2) &&
              (qr_MET_METPhi[mtyp][1] == -2))
       dc_MET[mtyp] = -2;
     else
       dc_MET[mtyp] = 1;
 
     if (verbose_)
       std::cout << "Certifying MET algo: " << mtyp << " with value: " << dc_MET[mtyp] << std::endl;
     CertificationSummaryMap->Fill(1, 4 - mtyp, dc_MET[mtyp]);
     reportSummaryMap->Fill(1, 4 - mtyp, dc_MET[mtyp]);
   }
 
   // There is nothing on the first three rows for HI, so mark them unfilled
   if (isHI) {
     for (int i = 0; i < 3; i++) {
       CertificationSummaryMap->Fill(1, i, -2);
       reportSummaryMap->Fill(1, i, -2);
     }
   }
 
   //----------------------------------------------------------------------------
   //--- Extract quality test results and fill data certification results for MET
   //----------------------------------------------------------------------------
   // Commenting out unused but initialized variables. [Suchandra Dutta]
   float dc_CT[3] = {-2.};
   dc_CT[0] = -2.;
   dc_CT[1] = -2.;
   dc_CT[2] = -2.;
 
   for (int cttyp = 0; cttyp < 3; ++cttyp) {
     if (verbose_)
       std::cout << "Certifying CaloTowers with value: " << dc_CT[cttyp] << std::endl;
     CertificationSummaryMap->Fill(0, 4 - cttyp, dc_CT[cttyp]);
     reportSummaryMap->Fill(0, 4 - cttyp, dc_CT[cttyp]);
   }
   ibook_.setCurrentFolder("");
 }

Member Data Documentation

◆ caloJetKSTest

bool DataCertificationJetMET::caloJetKSTest

private

Definition at line 68 of file DataCertificationJetMET.h.

◆ caloJetMeanTest

bool DataCertificationJetMET::caloJetMeanTest

private

Definition at line 67 of file DataCertificationJetMET.h.

◆ caloMETKSTest

bool DataCertificationJetMET::caloMETKSTest

private

Definition at line 74 of file DataCertificationJetMET.h.

◆ caloMETMeanTest

bool DataCertificationJetMET::caloMETMeanTest

private

Definition at line 73 of file DataCertificationJetMET.h.

◆ CertificationSummary

MonitorElement* DataCertificationJetMET::CertificationSummary

private

Definition at line 34 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ CertificationSummaryMap

MonitorElement* DataCertificationJetMET::CertificationSummaryMap

private

Definition at line 36 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ conf_

edm::ParameterSet DataCertificationJetMET::conf_

private

Definition at line 40 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET().

◆ etaBin_

int DataCertificationJetMET::etaBin_

private

Definition at line 57 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ etaMax_

double DataCertificationJetMET::etaMax_

private

Definition at line 59 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ etaMin_

double DataCertificationJetMET::etaMin_

private

Definition at line 58 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ folderName

std::string DataCertificationJetMET::folderName

private

Definition at line 65 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ InMemory_

bool DataCertificationJetMET::InMemory_

private

Definition at line 42 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ inputJetLabelMiniAOD_

edm::InputTag DataCertificationJetMET::inputJetLabelMiniAOD_

private

Definition at line 51 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ inputJetLabelRECO_

edm::InputTag DataCertificationJetMET::inputJetLabelRECO_

private

Definition at line 50 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ inputMETLabelMiniAOD_

edm::InputTag DataCertificationJetMET::inputMETLabelMiniAOD_

private

Definition at line 49 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ inputMETLabelRECO_

edm::InputTag DataCertificationJetMET::inputMETLabelRECO_

private

Definition at line 47 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ inputMETLabelRECOUncleaned_

edm::InputTag DataCertificationJetMET::inputMETLabelRECOUncleaned_

private

Definition at line 48 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ isData

bool DataCertificationJetMET::isData

private

Definition at line 43 of file DataCertificationJetMET.h.

◆ isHI

bool DataCertificationJetMET::isHI

private

Definition at line 83 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ jetAlgo

std::string DataCertificationJetMET::jetAlgo

private

Definition at line 45 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ jetTests

bool DataCertificationJetMET::jetTests[5][2]

private

Definition at line 80 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ jptJetKSTest

bool DataCertificationJetMET::jptJetKSTest

private

Definition at line 72 of file DataCertificationJetMET.h.

◆ jptJetMeanTest

bool DataCertificationJetMET::jptJetMeanTest

private

Definition at line 71 of file DataCertificationJetMET.h.

◆ mChargedHadronEtFraction_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mChargedHadronEtFraction_MiniAOD_over_Reco

private

Definition at line 102 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mChargedHadronEtFraction_nVtx_profile_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mChargedHadronEtFraction_nVtx_profile_MiniAOD_over_Reco

private

Definition at line 109 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mChargedMultiplicity_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mChargedMultiplicity_MiniAOD_over_Reco

private

Definition at line 141 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mCHFrac_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mCHFrac_MiniAOD_over_Reco

private

Definition at line 138 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mCHFracVSpT_Barrel_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mCHFracVSpT_Barrel_MiniAOD_over_Reco

private

Definition at line 133 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mDPhi_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mDPhi_MiniAOD_over_Reco

private

Definition at line 123 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mEta_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mEta_MiniAOD_over_Reco

private

Definition at line 115 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mEta_uncor_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mEta_uncor_MiniAOD_over_Reco

private

Definition at line 119 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ metFolder

std::string DataCertificationJetMET::metFolder

private

Definition at line 44 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ metTests

bool DataCertificationJetMET::metTests[5][2]

private

Definition at line 81 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ mHFEFracVSpT_Forward_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mHFEFracVSpT_Forward_MiniAOD_over_Reco

private

Definition at line 137 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mHFEMEtFraction_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mHFEMEtFraction_MiniAOD_over_Reco

private

Definition at line 106 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mHFHadronEtFraction_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mHFHadronEtFraction_MiniAOD_over_Reco

private

Definition at line 105 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mHFHFracVSpT_Forward_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mHFHFracVSpT_Forward_MiniAOD_over_Reco

private

Definition at line 136 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mJetEnergyCorr_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mJetEnergyCorr_MiniAOD_over_Reco

private

Definition at line 121 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mJetEnergyCorrVSeta_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mJetEnergyCorrVSeta_MiniAOD_over_Reco

private

Definition at line 122 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mLooseJIDPassFractionVSeta_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mLooseJIDPassFractionVSeta_MiniAOD_over_Reco

private

Definition at line 124 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMET_EffCSCTightHalo2015Filter

MonitorElement* DataCertificationJetMET::mMET_EffCSCTightHalo2015Filter

private

Definition at line 92 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMET_EffCSCTightHaloFilter

MonitorElement* DataCertificationJetMET::mMET_EffCSCTightHaloFilter

private

Definition at line 87 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMET_EffEcalDeadCellBoundaryFilter

MonitorElement* DataCertificationJetMET::mMET_EffEcalDeadCellBoundaryFilter

private

Definition at line 90 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMET_EffEcalDeadCellTriggerFilter

MonitorElement* DataCertificationJetMET::mMET_EffEcalDeadCellTriggerFilter

private

Definition at line 89 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMET_EffeeBadScFilter

MonitorElement* DataCertificationJetMET::mMET_EffeeBadScFilter

private

Definition at line 88 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMET_EffHBHEIsoNoiseFilter

MonitorElement* DataCertificationJetMET::mMET_EffHBHEIsoNoiseFilter

private

Definition at line 91 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMET_EffHBHENoiseFilter

MonitorElement* DataCertificationJetMET::mMET_EffHBHENoiseFilter

private

Definition at line 86 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMET_EffHcalStripHaloFilter

MonitorElement* DataCertificationJetMET::mMET_EffHcalStripHaloFilter

private

Definition at line 93 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMET_logx_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mMET_logx_MiniAOD_over_Reco

private

Definition at line 100 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMET_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mMET_MiniAOD_over_Reco

private

Definition at line 96 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMET_nVtx_profile_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mMET_nVtx_profile_MiniAOD_over_Reco

private

Definition at line 107 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMETPhi_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mMETPhi_MiniAOD_over_Reco

private

Definition at line 99 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMEy_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mMEy_MiniAOD_over_Reco

private

Definition at line 97 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMuonMultiplicity_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mMuonMultiplicity_MiniAOD_over_Reco

private

Definition at line 143 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD_over_Reco

private

Definition at line 132 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD_over_Reco

private

Definition at line 128 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD_over_Reco

private

Definition at line 129 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD_over_Reco

private

Definition at line 130 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD_over_Reco

private

Definition at line 131 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mNeutralFraction_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mNeutralFraction_MiniAOD_over_Reco

private

Definition at line 144 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mNeutralHadronEtFraction_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mNeutralHadronEtFraction_MiniAOD_over_Reco

private

Definition at line 103 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mNeutralHadronEtFraction_nVtx_profile_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mNeutralHadronEtFraction_nVtx_profile_MiniAOD_over_Reco

private

Definition at line 110 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mNeutralMultiplicity_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mNeutralMultiplicity_MiniAOD_over_Reco

private

Definition at line 142 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mNHFrac_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mNHFrac_MiniAOD_over_Reco

private

Definition at line 139 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mNHFracVSpT_EndCap_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mNHFracVSpT_EndCap_MiniAOD_over_Reco

private

Definition at line 134 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mNjets_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mNjets_MiniAOD_over_Reco

private

Definition at line 117 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mPhFrac_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mPhFrac_MiniAOD_over_Reco

private

Definition at line 140 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mPhFracVSpT_Barrel_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mPhFracVSpT_Barrel_MiniAOD_over_Reco

private

Definition at line 135 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mPhi_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mPhi_MiniAOD_over_Reco

private

Definition at line 116 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mPhi_uncor_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mPhi_uncor_MiniAOD_over_Reco

private

Definition at line 120 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mPhotonEtFraction_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mPhotonEtFraction_MiniAOD_over_Reco

private

Definition at line 104 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mPhotonEtFraction_nVtx_profile_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mPhotonEtFraction_nVtx_profile_MiniAOD_over_Reco

private

Definition at line 111 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mPt_Barrel_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mPt_Barrel_MiniAOD_over_Reco

private

Definition at line 125 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mPt_EndCap_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mPt_EndCap_MiniAOD_over_Reco

private

Definition at line 126 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mPt_Forward_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mPt_Forward_MiniAOD_over_Reco

private

Definition at line 127 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mPt_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mPt_MiniAOD_over_Reco

private

Definition at line 114 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mPt_uncor_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mPt_uncor_MiniAOD_over_Reco

private

Definition at line 118 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mSumET_logx_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mSumET_logx_MiniAOD_over_Reco

private

Definition at line 101 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mSumET_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mSumET_MiniAOD_over_Reco

private

Definition at line 98 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ mSumET_nVtx_profile_MiniAOD_over_Reco

MonitorElement* DataCertificationJetMET::mSumET_nVtx_profile_MiniAOD_over_Reco

private

Definition at line 108 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ nbinsPV_

int DataCertificationJetMET::nbinsPV_

private

Definition at line 53 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ nPVMax_

double DataCertificationJetMET::nPVMax_

private

Definition at line 55 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ nPVMin_

double DataCertificationJetMET::nPVMin_

private

Definition at line 54 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ pfJetKSTest

bool DataCertificationJetMET::pfJetKSTest

private

Definition at line 70 of file DataCertificationJetMET.h.

◆ pfJetMeanTest

bool DataCertificationJetMET::pfJetMeanTest

private

Definition at line 69 of file DataCertificationJetMET.h.

◆ pfMETKSTest

bool DataCertificationJetMET::pfMETKSTest

private

Definition at line 76 of file DataCertificationJetMET.h.

◆ pfMETMeanTest

bool DataCertificationJetMET::pfMETMeanTest

private

Definition at line 75 of file DataCertificationJetMET.h.

◆ ptBin_

int DataCertificationJetMET::ptBin_

private

Definition at line 61 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ ptMax_

double DataCertificationJetMET::ptMax_

private

Definition at line 63 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ ptMin_

double DataCertificationJetMET::ptMin_

private

Definition at line 62 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), and dqmEndJob().

◆ reportSummary

MonitorElement* DataCertificationJetMET::reportSummary

private

Definition at line 33 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ reportSummaryMap

MonitorElement* DataCertificationJetMET::reportSummaryMap

private

Definition at line 35 of file DataCertificationJetMET.h.

Referenced by dqmEndJob().

◆ tcMETKSTest

bool DataCertificationJetMET::tcMETKSTest

private

Definition at line 78 of file DataCertificationJetMET.h.

◆ tcMETMeanTest

bool DataCertificationJetMET::tcMETMeanTest

private

Definition at line 77 of file DataCertificationJetMET.h.

◆ verbose_

int DataCertificationJetMET::verbose_

private

Definition at line 41 of file DataCertificationJetMET.h.

Referenced by DataCertificationJetMET(), dqmEndJob(), and ~DataCertificationJetMET().

Public Member Functions

Private Member Functions

Private Attributes

Additional Inherited Members

Detailed Description

Constructor & Destructor Documentation

◆ DataCertificationJetMET()

◆ ~DataCertificationJetMET()

Member Function Documentation

◆ dqmEndJob()

Member Data Documentation

◆ caloJetKSTest

◆ caloJetMeanTest

◆ caloMETKSTest

◆ caloMETMeanTest

◆ CertificationSummary

◆ CertificationSummaryMap

◆ conf_

◆ etaBin_

◆ etaMax_

◆ etaMin_

◆ folderName

◆ InMemory_

◆ inputJetLabelMiniAOD_

◆ inputJetLabelRECO_

◆ inputMETLabelMiniAOD_

◆ inputMETLabelRECO_

◆ inputMETLabelRECOUncleaned_

◆ isData

◆ isHI

◆ jetAlgo

◆ jetTests

◆ jptJetKSTest

◆ jptJetMeanTest

◆ mChargedHadronEtFraction_MiniAOD_over_Reco

◆ mChargedHadronEtFraction_nVtx_profile_MiniAOD_over_Reco

◆ mChargedMultiplicity_MiniAOD_over_Reco

◆ mCHFrac_MiniAOD_over_Reco

◆ mCHFracVSpT_Barrel_MiniAOD_over_Reco

◆ mDPhi_MiniAOD_over_Reco

◆ mEta_MiniAOD_over_Reco

◆ mEta_uncor_MiniAOD_over_Reco

◆ metFolder

◆ metTests

◆ mHFEFracVSpT_Forward_MiniAOD_over_Reco

◆ mHFEMEtFraction_MiniAOD_over_Reco

◆ mHFHadronEtFraction_MiniAOD_over_Reco

◆ mHFHFracVSpT_Forward_MiniAOD_over_Reco

◆ mJetEnergyCorr_MiniAOD_over_Reco

◆ mJetEnergyCorrVSeta_MiniAOD_over_Reco

◆ mLooseJIDPassFractionVSeta_MiniAOD_over_Reco

◆ mMET_EffCSCTightHalo2015Filter

◆ mMET_EffCSCTightHaloFilter

◆ mMET_EffEcalDeadCellBoundaryFilter

◆ mMET_EffEcalDeadCellTriggerFilter

◆ mMET_EffeeBadScFilter

◆ mMET_EffHBHEIsoNoiseFilter

◆ mMET_EffHBHENoiseFilter

◆ mMET_EffHcalStripHaloFilter

◆ mMET_logx_MiniAOD_over_Reco

◆ mMET_MiniAOD_over_Reco

◆ mMET_nVtx_profile_MiniAOD_over_Reco

◆ mMETPhi_MiniAOD_over_Reco

◆ mMEy_MiniAOD_over_Reco

◆ mMuonMultiplicity_MiniAOD_over_Reco

◆ mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD_over_Reco

◆ mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD_over_Reco

◆ mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD_over_Reco

◆ mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD_over_Reco

◆ mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD_over_Reco

◆ mNeutralFraction_MiniAOD_over_Reco

◆ mNeutralHadronEtFraction_MiniAOD_over_Reco

◆ mNeutralHadronEtFraction_nVtx_profile_MiniAOD_over_Reco

◆ mNeutralMultiplicity_MiniAOD_over_Reco

◆ mNHFrac_MiniAOD_over_Reco

◆ mNHFracVSpT_EndCap_MiniAOD_over_Reco

◆ mNjets_MiniAOD_over_Reco

◆ mPhFrac_MiniAOD_over_Reco

◆ mPhFracVSpT_Barrel_MiniAOD_over_Reco

◆ mPhi_MiniAOD_over_Reco