L1TdeRCT Class Reference

#include <L1TdeRCT.h>

Inheritance diagram for L1TdeRCT:

Public Member Functions
	L1TdeRCT (const edm::ParameterSet &ps)
	~L1TdeRCT () override
Public Member Functions inherited from DQMOneEDAnalyzer< edm::LuminosityBlockCache< l1tderct::Empty > >
void	accumulate (edm::Event const &event, edm::EventSetup const &setup) override
void	beginRun (edm::Run const &run, edm::EventSetup const &setup) final
	DQMOneEDAnalyzer ()
void	endRun (edm::Run const &, edm::EventSetup const &) final
void	endRunProduce (edm::Run &run, edm::EventSetup const &setup) final
virtual bool	getCanSaveByLumi ()
Public Member Functions inherited from edm::one::EDProducer< edm::EndRunProducer, edm::one::WatchRuns, edm::Accumulator, Args... >
	EDProducer ()=default
SerialTaskQueue *	globalLuminosityBlocksQueue () final
SerialTaskQueue *	globalRunsQueue () final
bool	hasAbilityToProduceInBeginLumis () const final
bool	hasAbilityToProduceInBeginRuns () const final
bool	hasAbilityToProduceInEndLumis () const final
bool	hasAbilityToProduceInEndRuns () const final
bool	wantsGlobalLuminosityBlocks () const final
bool	wantsGlobalRuns () 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 &&)=default
	EDConsumerBase (EDConsumerBase const &)=delete
ESProxyIndex const *	esGetTokenIndices (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::vector< ModuleDescription const * > &modules, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const
EDConsumerBase &	operator= (EDConsumerBase &&)=default
EDConsumerBase const &	operator= (EDConsumerBase const &)=delete
bool	registeredToConsume (ProductResolverIndex, bool, BranchType) const
bool	registeredToConsumeMany (TypeID const &, BranchType) const
ProductResolverIndexAndSkipBit	uncheckedIndexFrom (EDGetToken) const
void	updateLookup (BranchType iBranchType, ProductResolverIndexHelper const &, bool iPrefetchMayGet)
void	updateLookup (eventsetup::ESRecordsToProxyIndices const &)
virtual	~EDConsumerBase () noexcept(false)

Protected Member Functions
void	analyze (const edm::Event &e, const edm::EventSetup &c) override
void	bookHistograms (DQMStore::IBooker &ibooker, const edm::Run &, const edm::EventSetup &) override
void	DivideME1D (MonitorElement *numerator, MonitorElement *denominator, MonitorElement *result)
void	DivideME2D (MonitorElement *numerator, MonitorElement *denominator, MonitorElement *result)
std::shared_ptr< l1tderct::Empty >	globalBeginLuminosityBlock (const edm::LuminosityBlock &, const edm::EventSetup &) const override
void	globalEndLuminosityBlock (const edm::LuminosityBlock &, const edm::EventSetup &) final
void	readFEDVector (MonitorElement *, const edm::EventSetup &) const
Protected Member Functions inherited from DQMOneEDAnalyzer< edm::LuminosityBlockCache< l1tderct::Empty > >
virtual void	bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &)=0
virtual void	dqmBeginRun (edm::Run const &, edm::EventSetup const &)
virtual void	dqmEndRun (edm::Run const &, edm::EventSetup const &)
Protected Member Functions inherited from edm::ProducerBase
template<class ProductType >
BranchAliasSetterT< ProductType >	produces ()
	declare what type of product will make and with which optional label More...
template<typename ProductType , BranchType B>
BranchAliasSetterT< ProductType >	produces ()
template<typename ProductType , Transition B>
BranchAliasSetterT< ProductType >	produces ()
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)
template<Transition B>
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 (std::string instanceName)
template<typename ProductType , BranchType B>
BranchAliasSetterT< ProductType >	produces (std::string instanceName)
ProducesCollector	producesCollector ()
Protected Member Functions inherited from edm::EDConsumerBase
EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (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)
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)

Private Attributes
std::string	dataInputTagName_
int	doubleThreshold_
edm::EDGetTokenT< EcalTrigPrimDigiCollection >	ecalTPGData_
MonitorElement *	fedVectorMonitorLS_
MonitorElement *	fedVectorMonitorRUN_
int	filterTriggerType_
	filter TriggerType More...
edm::EDGetTokenT< L1CaloEmCollection >	gctSourceData_emData_
edm::EDGetTokenT< L1CaloRegionCollection >	gctSourceData_rgnData_
edm::EDGetTokenT< L1GlobalTriggerReadoutRecord >	gtDigisLabel_
std::string	gtEGAlgoName_
edm::EDGetTokenT< HcalTrigPrimDigiCollection >	hcalTPGData_
std::string	histFolder_
int	nev_
int	notrigCount
MonitorElement *	rctBitDataHfPlusTau2D_
MonitorElement *	rctBitDataMip2D_
MonitorElement *	rctBitDataOverFlow2D_
MonitorElement *	rctBitDataQuiet2D_
MonitorElement *	rctBitDataTauVeto2D_
MonitorElement *	rctBitEmulHfPlusTau2D_
MonitorElement *	rctBitEmulMip2D_
MonitorElement *	rctBitEmulOverFlow2D_
MonitorElement *	rctBitEmulQuiet2D_
MonitorElement *	rctBitEmulTauVeto2D_
MonitorElement *	rctBitHfPlusTauEff2D_
MonitorElement *	rctBitHfPlusTauIneff2D_
MonitorElement *	rctBitHfPlusTauOvereff2D_
MonitorElement *	rctBitMatchedHfPlusTau2D_
MonitorElement *	rctBitMatchedMip2D_
MonitorElement *	rctBitMatchedOverFlow2D_
MonitorElement *	rctBitMatchedQuiet2D_
MonitorElement *	rctBitMatchedTauVeto2D_
MonitorElement *	rctBitMipEff2D_
MonitorElement *	rctBitMipIneff2D_
MonitorElement *	rctBitMipOvereff2D_
MonitorElement *	rctBitOverFlowEff2D_
MonitorElement *	rctBitOverFlowIneff2D_
MonitorElement *	rctBitOverFlowOvereff2D_
MonitorElement *	rctBitTauVetoEff2D_
MonitorElement *	rctBitTauVetoIneff2D_
MonitorElement *	rctBitTauVetoOvereff2D_
MonitorElement *	rctBitUnmatchedDataHfPlusTau2D_
MonitorElement *	rctBitUnmatchedDataMip2D_
MonitorElement *	rctBitUnmatchedDataOverFlow2D_
MonitorElement *	rctBitUnmatchedDataQuiet2D_
MonitorElement *	rctBitUnmatchedDataTauVeto2D_
MonitorElement *	rctBitUnmatchedEmulHfPlusTau2D_
MonitorElement *	rctBitUnmatchedEmulMip2D_
MonitorElement *	rctBitUnmatchedEmulOverFlow2D_
MonitorElement *	rctBitUnmatchedEmulQuiet2D_
MonitorElement *	rctBitUnmatchedEmulTauVeto2D_
MonitorElement *	rctInputTPGEcalOcc_
MonitorElement *	rctInputTPGEcalOccNoCut_
MonitorElement *	rctInputTPGEcalRank_
MonitorElement *	rctInputTPGHcalOcc_
MonitorElement *	rctInputTPGHcalRank_
MonitorElement *	rctInputTPGHcalSample_
MonitorElement *	rctIsoEffChannel_ [396]
MonitorElement *	rctIsoEmBitDiff_
MonitorElement *	rctIsoEmBitOff_
MonitorElement *	rctIsoEmBitOn_
MonitorElement *	rctIsoEmDataOcc1D_
MonitorElement *	rctIsoEmDataOcc_
MonitorElement *	rctIsoEmEff1_
MonitorElement *	rctIsoEmEff1Occ1D_
MonitorElement *	rctIsoEmEff1Occ_
MonitorElement *	rctIsoEmEff1oneD_
MonitorElement *	rctIsoEmEff2_
MonitorElement *	rctIsoEmEff2Occ1D_
MonitorElement *	rctIsoEmEff2Occ_
MonitorElement *	rctIsoEmEff2oneD_
MonitorElement *	rctIsoEmEmulOcc1D_
MonitorElement *	rctIsoEmEmulOcc_
MonitorElement *	rctIsoEmIneff1D_
MonitorElement *	rctIsoEmIneff2_
MonitorElement *	rctIsoEmIneff2Occ1D_
MonitorElement *	rctIsoEmIneff2Occ_
MonitorElement *	rctIsoEmIneff2oneD_
MonitorElement *	rctIsoEmIneff_
MonitorElement *	rctIsoEmIneffOcc1D_
MonitorElement *	rctIsoEmIneffOcc_
MonitorElement *	rctIsoEmOvereff1D_
MonitorElement *	rctIsoEmOvereff_
MonitorElement *	rctIsoEmOvereffOcc1D_
MonitorElement *	rctIsoEmOvereffOcc_
MonitorElement *	rctIsoIneffChannel_ [396]
MonitorElement *	rctIsoOvereffChannel_ [396]
MonitorElement *	rctNisoEffChannel_ [396]
MonitorElement *	rctNIsoEmBitDiff_
MonitorElement *	rctNIsoEmBitOff_
MonitorElement *	rctNIsoEmBitOn_
MonitorElement *	rctNisoEmDataOcc1D_
MonitorElement *	rctNisoEmDataOcc_
MonitorElement *	rctNisoEmEff1_
MonitorElement *	rctNisoEmEff1Occ1D_
MonitorElement *	rctNisoEmEff1Occ_
MonitorElement *	rctNisoEmEff1oneD_
MonitorElement *	rctNisoEmEff2_
MonitorElement *	rctNisoEmEff2Occ1D_
MonitorElement *	rctNisoEmEff2Occ_
MonitorElement *	rctNisoEmEff2oneD_
MonitorElement *	rctNisoEmEmulOcc1D_
MonitorElement *	rctNisoEmEmulOcc_
MonitorElement *	rctNisoEmIneff1D_
MonitorElement *	rctNisoEmIneff2_
MonitorElement *	rctNisoEmIneff2Occ1D_
MonitorElement *	rctNisoEmIneff2Occ_
MonitorElement *	rctNisoEmIneff2oneD_
MonitorElement *	rctNisoEmIneff_
MonitorElement *	rctNisoEmIneffOcc1D_
MonitorElement *	rctNisoEmIneffOcc_
MonitorElement *	rctNisoEmOvereff1D_
MonitorElement *	rctNisoEmOvereff_
MonitorElement *	rctNisoEmOvereffOcc1D_
MonitorElement *	rctNisoEmOvereffOcc_
MonitorElement *	rctNisoIneffChannel_ [396]
MonitorElement *	rctNisoOvereffChannel_ [396]
MonitorElement *	rctRegBitDiff_
MonitorElement *	rctRegBitOff_
MonitorElement *	rctRegBitOn_
MonitorElement *	rctRegDataOcc1D_
MonitorElement *	rctRegDataOcc2D_
MonitorElement *	rctRegEff1D_
MonitorElement *	rctRegEff2D_
MonitorElement *	rctRegEffChannel_ [396]
MonitorElement *	rctRegEmulOcc1D_
MonitorElement *	rctRegEmulOcc2D_
MonitorElement *	rctRegIneff1D_
MonitorElement *	rctRegIneff2D_
MonitorElement *	rctRegIneffChannel_ [396]
MonitorElement *	rctRegMatchedOcc1D_
MonitorElement *	rctRegMatchedOcc2D_
MonitorElement *	rctRegOvereff1D_
MonitorElement *	rctRegOvereff2D_
MonitorElement *	rctRegOvereffChannel_ [396]
MonitorElement *	rctRegSpEff1D_
MonitorElement *	rctRegSpEff2D_
MonitorElement *	rctRegSpEffOcc1D_
MonitorElement *	rctRegSpEffOcc2D_
MonitorElement *	rctRegSpIneff1D_
MonitorElement *	rctRegSpIneff2D_
MonitorElement *	rctRegSpIneffOcc1D_
MonitorElement *	rctRegSpIneffOcc2D_
MonitorElement *	rctRegUnmatchedDataOcc1D_
MonitorElement *	rctRegUnmatchedDataOcc2D_
MonitorElement *	rctRegUnmatchedEmulOcc1D_
MonitorElement *	rctRegUnmatchedEmulOcc2D_
edm::EDGetTokenT< L1CaloEmCollection >	rctSourceData_emData_
edm::EDGetTokenT< L1CaloRegionCollection >	rctSourceData_rgnData_
edm::EDGetTokenT< L1CaloEmCollection >	rctSourceEmul_emEmul_
edm::EDGetTokenT< L1CaloRegionCollection >	rctSourceEmul_rgnEmul_
int	selectBX_
bool	singlechannelhistos_
int	trigCount
MonitorElement *	trigEff_ [396]
MonitorElement *	trigEffOcc_ [396]
MonitorElement *	trigEffThresh_
MonitorElement *	trigEffThreshOcc_
MonitorElement *	trigEffTriggOcc_ [396]
MonitorElement *	trigEffTriggThreshOcc_
MonitorElement *	triggerAlgoNumbers_
MonitorElement *	triggerType_
bool	verbose_

Static Private Attributes
static const int	crateFED [108]

Additional Inherited Members
Public Types inherited from DQMOneEDAnalyzer< edm::LuminosityBlockCache< l1tderct::Empty > >
typedef dqm::reco::DQMStore	DQMStore
typedef dqm::reco::MonitorElement	MonitorElement
Public Types inherited from edm::one::EDProducerBase
typedef EDProducerBase	ModuleType
Public Types inherited from edm::ProducerBase
using	ModuleToResolverIndicies = std::unordered_multimap< std::string, std::tuple< edm::TypeID const *, const char *, edm::ProductResolverIndex > >
typedef ProductRegistryHelper::TypeLabelList	TypeLabelList
Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels
Static Public Member Functions inherited from edm::one::EDProducerBase
static const std::string &	baseType ()
static void	fillDescriptions (ConfigurationDescriptions &descriptions)
static void	prevalidate (ConfigurationDescriptions &descriptions)
Protected Attributes inherited from DQMOneEDAnalyzer< edm::LuminosityBlockCache< l1tderct::Empty > >
edm::EDPutTokenT< DQMToken >	runToken_

Detailed Description

Definition at line 49 of file L1TdeRCT.h.

Constructor & Destructor Documentation

L1TdeRCT()

L1TdeRCT::L1TdeRCT

(

const edm::ParameterSet &

ps

)

Definition at line 80 of file L1TdeRCT.cc.

    : rctSourceEmul_rgnEmul_(consumes<L1CaloRegionCollection>(ps.getParameter<InputTag>("rctSourceEmul"))),
      rctSourceEmul_emEmul_(consumes<L1CaloEmCollection>(ps.getParameter<InputTag>("rctSourceEmul"))),
      rctSourceData_rgnData_(consumes<L1CaloRegionCollection>(ps.getParameter<InputTag>("rctSourceData"))),
      rctSourceData_emData_(consumes<L1CaloEmCollection>(ps.getParameter<InputTag>("rctSourceData"))),
      ecalTPGData_(consumes<EcalTrigPrimDigiCollection>(ps.getParameter<InputTag>("ecalTPGData"))),
      hcalTPGData_(consumes<HcalTrigPrimDigiCollection>(ps.getParameter<InputTag>("hcalTPGData"))),
      gtDigisLabel_(consumes<L1GlobalTriggerReadoutRecord>(ps.getParameter<InputTag>("gtDigisLabel"))),
      gtEGAlgoName_(ps.getParameter<std::string>("gtEGAlgoName")),
      doubleThreshold_(ps.getParameter<int>("doubleThreshold")),
      filterTriggerType_(ps.getParameter<int>("filterTriggerType")),
      selectBX_(ps.getUntrackedParameter<int>("selectBX", 2)),
      dataInputTagName_(ps.getParameter<InputTag>("rctSourceData").label()) {
  singlechannelhistos_ = ps.getUntrackedParameter<bool>("singlechannelhistos", false);
 
  if (singlechannelhistos_)
    if (verbose_)
      std::cout << "L1TdeRCT: single channels histos ON" << std::endl;
 
  // verbosity switch
  verbose_ = ps.getUntrackedParameter<bool>("verbose", false);
 
  if (verbose_)
    std::cout << "L1TdeRCT: constructor...." << std::endl;
 
  histFolder_ = ps.getUntrackedParameter<std::string>("HistFolder", "L1TEMU/L1TdeRCT");
}

References gather_cfg::cout, edm::ParameterSet::getUntrackedParameter(), histFolder_, singlechannelhistos_, AlCaHLTBitMon_QueryRunRegistry::string, and verbose_.

~L1TdeRCT()

L1TdeRCT::~L1TdeRCT ( )

override

Definition at line 108 of file L1TdeRCT.cc.

{}

Member Function Documentation

analyze()

void L1TdeRCT::analyze ( const edm::Event &  e, const edm::EventSetup &  c  )

overrideprotectedvirtual

Reimplemented from DQMOneEDAnalyzer< edm::LuminosityBlockCache< l1tderct::Empty > >.

Definition at line 110 of file L1TdeRCT.cc.

                                                          {
  nev_++;
  if (verbose_) {
    std::cout << "L1TdeRCT: analyze...." << std::endl;
  }
 
  // filter according trigger type
  //  enum ExperimentType {
  //        Undefined          =  0,
  //        PhysicsTrigger     =  1,
  //        CalibrationTrigger =  2,
  //        RandomTrigger      =  3,
  //        Reserved           =  4,
  //        TracedEvent        =  5,
  //        TestTrigger        =  6,
  //        ErrorTrigger       = 15
 
  // fill a histogram with the trigger type, for normalization fill also last bin
  // ErrorTrigger + 1
  double triggerType = static_cast<double>(e.experimentType()) + 0.001;
  double triggerTypeLast = static_cast<double>(edm::EventAuxiliary::ExperimentType::ErrorTrigger) + 0.001;
  triggerType_->Fill(triggerType);
  triggerType_->Fill(triggerTypeLast + 1);
 
  // filter only if trigger type is greater than 0, negative values disable filtering
  if (filterTriggerType_ >= 0) {
    // now filter, for real data only
    if (e.isRealData()) {
      if (!(e.experimentType() == filterTriggerType_)) {
        edm::LogInfo("L1TdeRCT") << "\n Event of TriggerType " << e.experimentType() << " rejected" << std::endl;
        return;
      }
    }
  }
 
  // for GT decision word
  edm::Handle<L1GlobalTriggerReadoutRecord> gtRecord;
 
  // get GT decision word
  e.getByToken(gtDigisLabel_, gtRecord);
  const DecisionWord dWord =
      gtRecord->decisionWord();  // this will get the decision word *before* masking disabled bits
  int effEGThresholdBitNumber = 999;
  if (gtEGAlgoName_ == "L1_SingleEG1") {
    effEGThresholdBitNumber = 46;
  }
  if (gtEGAlgoName_ == "L1_SingleEG5_0001") {
    effEGThresholdBitNumber = 47;
  }
  if (gtEGAlgoName_ == "L1_SingleEG8_0001") {
    effEGThresholdBitNumber = 48;
  }
  if (gtEGAlgoName_ == "L1_SingleEG10_0001") {
    effEGThresholdBitNumber = 49;
  }
  if (gtEGAlgoName_ == "L1_SingleEG12_0001") {
    effEGThresholdBitNumber = 50;
  }
  if (gtEGAlgoName_ == "L1_SingleEG15_0001") {
    effEGThresholdBitNumber = 51;
  }
  if (gtEGAlgoName_ == "L1_SingleEG20_0001") {
    effEGThresholdBitNumber = 52;
  }
 
  int algoBitNumber = 0;
  bool triggered = false;
  bool independent_triggered = false;
  DecisionWord::const_iterator algoItr;
  for (algoItr = dWord.begin(); algoItr != dWord.end(); algoItr++) {
    if (*algoItr) {
      triggerAlgoNumbers_->Fill(algoBitNumber);
      if (algoBitNumber == effEGThresholdBitNumber) {
        triggered = true;  // Fill triggered events (numerator) here!
      }
      if (algoBitNumber <= 45 || algoBitNumber >= 53) {
        independent_triggered = true;  // use the muon path only !
      }
    }
    algoBitNumber++;
  }
 
  if (triggered)
    trigCount++;
  else
    notrigCount++;
 
  // get TPGs
  edm::Handle<EcalTrigPrimDigiCollection> ecalTpData;
  edm::Handle<HcalTrigPrimDigiCollection> hcalTpData;
 
  // Get the RCT digis
  edm::Handle<L1CaloEmCollection> emData;
  edm::Handle<L1CaloRegionCollection> rgnData;
 
  // Get the RCT digis
  edm::Handle<L1CaloEmCollection> emEmul;
  edm::Handle<L1CaloRegionCollection> rgnEmul;
 
  bool doEcal = true;
  bool doHcal = true;
 
  // TPG, first try:
  e.getByToken(ecalTPGData_, ecalTpData);
  e.getByToken(hcalTPGData_, hcalTpData);
 
  if (!ecalTpData.isValid()) {
    edm::LogInfo("TPG DataNotFound") << "can't find EcalTrigPrimDigiCollection";
    if (verbose_)
      std::cout << "Can not find ecalTpData!" << std::endl;
 
    doEcal = false;
  }
 
  if (doEcal) {
    for (EcalTrigPrimDigiCollection::const_iterator iEcalTp = ecalTpData->begin(); iEcalTp != ecalTpData->end();
         iEcalTp++) {
      if (iEcalTp->compressedEt() > 0) {
        rctInputTPGEcalRank_->Fill(1. * (iEcalTp->compressedEt()));
 
        if (iEcalTp->id().ieta() > 0) {
          rctInputTPGEcalOccNoCut_->Fill(1. * (iEcalTp->id().ieta()) - 0.5, iEcalTp->id().iphi());
          if (iEcalTp->compressedEt() > 3)
            rctInputTPGEcalOcc_->Fill(1. * (iEcalTp->id().ieta()) - 0.5, iEcalTp->id().iphi());
        } else {
          rctInputTPGEcalOccNoCut_->Fill(1. * (iEcalTp->id().ieta()) + 0.5, iEcalTp->id().iphi());
          if (iEcalTp->compressedEt() > 3)
            rctInputTPGEcalOcc_->Fill(1. * (iEcalTp->id().ieta()) + 0.5, iEcalTp->id().iphi());
        }
 
        if (verbose_)
          std::cout << " ECAL data: Energy: " << iEcalTp->compressedEt() << " eta " << iEcalTp->id().ieta() << " phi "
                    << iEcalTp->id().iphi() << std::endl;
      }
    }
  }
 
  if (!hcalTpData.isValid()) {
    edm::LogInfo("TPG DataNotFound") << "can't find HcalTrigPrimDigiCollection";
    if (verbose_)
      std::cout << "Can not find hcalTpData!" << std::endl;
 
    doHcal = false;
  }
 
  if (doHcal) {
    for (HcalTrigPrimDigiCollection::const_iterator iHcalTp = hcalTpData->begin(); iHcalTp != hcalTpData->end();
         iHcalTp++) {
      int highSample = 0;
      int highEt = 0;
 
      for (int nSample = 0; nSample < 10; nSample++) {
        if (iHcalTp->sample(nSample).compressedEt() != 0) {
          if (verbose_)
            std::cout << "HCAL data: Et " << iHcalTp->sample(nSample).compressedEt() << "  fg "
                      << iHcalTp->sample(nSample).fineGrain() << "  ieta " << iHcalTp->id().ieta() << "  iphi "
                      << iHcalTp->id().iphi() << "  sample " << nSample << std::endl;
          if (iHcalTp->sample(nSample).compressedEt() > highEt) {
            highSample = nSample;
            highEt = iHcalTp->sample(nSample).compressedEt();
          }
        }
      }
 
      if (highEt != 0) {
        if (iHcalTp->id().ieta() > 0)
          rctInputTPGHcalOcc_->Fill(1. * (iHcalTp->id().ieta()) - 0.5, iHcalTp->id().iphi());
        else
          rctInputTPGHcalOcc_->Fill(1. * (iHcalTp->id().ieta()) + 0.5, iHcalTp->id().iphi());
        rctInputTPGHcalSample_->Fill(highSample, highEt);
        rctInputTPGHcalRank_->Fill(highEt);
      }
    }
  }
 
  e.getByToken(rctSourceData_rgnData_, rgnData);
  e.getByToken(rctSourceEmul_rgnEmul_, rgnEmul);
 
  if (!rgnData.isValid()) {
    edm::LogInfo("DataNotFound") << "can't find L1CaloRegionCollection";
    if (verbose_)
      std::cout << "Can not find rgnData!" << std::endl;
    return;
  }
 
  if (!rgnEmul.isValid()) {
    edm::LogInfo("DataNotFound") << "can't find L1CaloRegionCollection";
    if (verbose_)
      std::cout << "Can not find rgnEmul!" << std::endl;
    return;
  }
 
  e.getByToken(rctSourceData_emData_, emData);
  e.getByToken(rctSourceEmul_emEmul_, emEmul);
 
  if (!emData.isValid()) {
    edm::LogInfo("DataNotFound") << "can't find L1CaloEmCollection";
    if (verbose_)
      std::cout << "Can not find emData!" << std::endl;
    return;
  }
 
  if (!emEmul.isValid()) {
    edm::LogInfo("DataNotFound") << "can't find L1CaloEmCollection";
    if (verbose_)
      std::cout << "Can not find emEmul!" << std::endl;
    return;
  }
 
  // Isolated and non-isolated EM
 
  // StepI: Reset
 
  int nelectrIsoData = 0;
  int nelectrNisoData = 0;
  int nelectrIsoEmul = 0;
  int nelectrNisoEmul = 0;
 
  int electronDataRank[2][PhiEtaMax] = {{0}};
  int electronDataEta[2][PhiEtaMax] = {{0}};
  int electronDataPhi[2][PhiEtaMax] = {{0}};
  int electronEmulRank[2][PhiEtaMax] = {{0}};
  int electronEmulEta[2][PhiEtaMax] = {{0}};
  int electronEmulPhi[2][PhiEtaMax] = {{0}};
 
  // region/bit arrays
  int nRegionData = 0;
  int nRegionEmul = 0;
 
  int regionDataRank[PhiEtaMax] = {0};
  int regionDataEta[PhiEtaMax] = {0};
  int regionDataPhi[PhiEtaMax] = {0};
 
  bool regionDataOverFlow[PhiEtaMax] = {false};
  bool regionDataTauVeto[PhiEtaMax] = {false};
  bool regionDataMip[PhiEtaMax] = {false};
  bool regionDataQuiet[PhiEtaMax] = {false};
  bool regionDataHfPlusTau[PhiEtaMax] = {false};
 
  int regionEmulRank[PhiEtaMax] = {0};
  int regionEmulEta[PhiEtaMax] = {0};
  int regionEmulPhi[PhiEtaMax] = {0};
 
  bool regionEmulOverFlow[PhiEtaMax] = {false};
  bool regionEmulTauVeto[PhiEtaMax] = {false};
  bool regionEmulMip[PhiEtaMax] = {false};
  bool regionEmulQuiet[PhiEtaMax] = {false};
  bool regionEmulHfPlusTau[PhiEtaMax] = {false};
 
  // StepII: fill variables
 
  for (L1CaloEmCollection::const_iterator iem = emEmul->begin(); iem != emEmul->end(); iem++) {
    if (iem->rank() >= 1) {
      if (iem->isolated()) {
        rctIsoEmEmulOcc_->Fill(iem->regionId().ieta(), iem->regionId().iphi());
 
        // to  show bad channles in the 2D efficiency plots
        rctIsoEmIneffOcc_->Fill(iem->regionId().ieta(), iem->regionId().iphi(), 0.01);
        rctIsoEmEff1Occ_->Fill(iem->regionId().ieta(), iem->regionId().iphi(), 0.01);
 
        int channel;
 
        channel = PHIBINS * iem->regionId().ieta() + iem->regionId().iphi();
        rctIsoEmEmulOcc1D_->Fill(channel);
        electronEmulRank[0][nelectrIsoEmul] = iem->rank();
        electronEmulEta[0][nelectrIsoEmul] = iem->regionId().ieta();
        electronEmulPhi[0][nelectrIsoEmul] = iem->regionId().iphi();
        nelectrIsoEmul++;
      }
 
      else {
        rctNisoEmEmulOcc_->Fill(iem->regionId().ieta(), iem->regionId().iphi());
 
        // to  show bad channles in the 2D efficiency plots
        rctNisoEmIneffOcc_->Fill(iem->regionId().ieta(), iem->regionId().iphi(), 0.01);
        rctNisoEmEff1Occ_->Fill(iem->regionId().ieta(), iem->regionId().iphi(), 0.01);
 
        int channel;
        //
 
        channel = PHIBINS * iem->regionId().ieta() + iem->regionId().iphi();
        rctNisoEmEmulOcc1D_->Fill(channel);
        electronEmulRank[1][nelectrNisoEmul] = iem->rank();
        electronEmulEta[1][nelectrNisoEmul] = iem->regionId().ieta();
        electronEmulPhi[1][nelectrNisoEmul] = iem->regionId().iphi();
        nelectrNisoEmul++;
      }
    }
  }
 
  for (L1CaloEmCollection::const_iterator iem = emData->begin(); iem != emData->end(); iem++) {
    if (selectBX_ != -1 && selectBX_ != iem->bx())
      continue;
 
    if (iem->rank() >= 1) {
      if (iem->isolated()) {
        rctIsoEmDataOcc_->Fill(iem->regionId().ieta(), iem->regionId().iphi());
 
        // new stuff to avoid 0's in emulator 2D //
        // rctIsoEmEmulOcc_->Fill(iem->regionId().ieta(), iem->regionId().iphi(),0.01);
        rctIsoEmOvereffOcc_->Fill(iem->regionId().ieta(), iem->regionId().iphi(), 0.01);
 
        int channel;
 
        channel = PHIBINS * iem->regionId().ieta() + iem->regionId().iphi();
        rctIsoEmDataOcc1D_->Fill(channel);
 
        // new stuff to avoid 0's
        // rctIsoEmEmulOcc1D_->Fill(channel);
 
        electronDataRank[0][nelectrIsoData] = iem->rank();
        electronDataEta[0][nelectrIsoData] = iem->regionId().ieta();
        electronDataPhi[0][nelectrIsoData] = iem->regionId().iphi();
        nelectrIsoData++;
      }
 
      else {
        rctNisoEmDataOcc_->Fill(iem->regionId().ieta(), iem->regionId().iphi());
 
        // new stuff to avoid 0's in emulator 2D //
        // rctNisoEmEmulOcc_->Fill(iem->regionId().ieta(), iem->regionId().iphi(),0.01);
        rctNisoEmOvereffOcc_->Fill(iem->regionId().ieta(), iem->regionId().iphi(), 0.01);
 
        int channel;
 
        channel = PHIBINS * iem->regionId().ieta() + iem->regionId().iphi();
        rctNisoEmDataOcc1D_->Fill(channel);
 
        // new stuff to avoid 0's
        // rctNisoEmEmulOcc1D_->Fill(channel);
 
        electronDataRank[1][nelectrNisoData] = iem->rank();
        electronDataEta[1][nelectrNisoData] = iem->regionId().ieta();
        electronDataPhi[1][nelectrNisoData] = iem->regionId().iphi();
        nelectrNisoData++;
      }
    }
  }
 
  // fill region/bit arrays for emulator
  for (L1CaloRegionCollection::const_iterator ireg = rgnEmul->begin(); ireg != rgnEmul->end(); ireg++) {
    //     std::cout << "Emul: " << nRegionEmul << " " << ireg->gctEta() << " " << ireg->gctPhi() << std::endl;
    if (ireg->overFlow())
      rctBitEmulOverFlow2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    if (ireg->tauVeto())
      rctBitEmulTauVeto2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    if (ireg->mip())
      rctBitEmulMip2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    if (ireg->quiet())
      rctBitEmulQuiet2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    if (ireg->fineGrain())
      rctBitEmulHfPlusTau2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    if (ireg->et() > 0) {
      rctRegEmulOcc1D_->Fill(PHIBINS * ireg->gctEta() + ireg->gctPhi());
      rctRegEmulOcc2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    }
 
    // to show bad channels in 2D efficiency plots:
    if (ireg->overFlow()) {
      rctBitUnmatchedEmulOverFlow2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
      rctBitMatchedOverFlow2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    }
 
    if (ireg->tauVeto()) {
      rctBitUnmatchedEmulTauVeto2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
      rctBitMatchedTauVeto2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    }
 
    if (ireg->mip()) {
      rctBitUnmatchedEmulMip2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
      rctBitMatchedMip2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    }
 
    if (ireg->quiet()) {
      rctBitUnmatchedEmulQuiet2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
      rctBitMatchedQuiet2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    }
 
    if (ireg->fineGrain()) {
      rctBitUnmatchedEmulHfPlusTau2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
      rctBitMatchedHfPlusTau2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    }
 
    if (ireg->et() > 0) {
      rctRegUnmatchedEmulOcc2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
      rctRegMatchedOcc2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
      /*      rctRegDeltaEtOcc2D_->Fill       (ireg->gctEta(), ireg->gctPhi(), 0.01); */
    }
 
    nRegionEmul = PHIBINS * ireg->gctEta() + ireg->gctPhi();
 
    regionEmulRank[nRegionEmul] = ireg->et();
    regionEmulEta[nRegionEmul] = ireg->gctEta();
    regionEmulPhi[nRegionEmul] = ireg->gctPhi();
    regionEmulOverFlow[nRegionEmul] = ireg->overFlow();
    regionEmulTauVeto[nRegionEmul] = ireg->tauVeto();
    regionEmulMip[nRegionEmul] = ireg->mip();
    regionEmulQuiet[nRegionEmul] = ireg->quiet();
    regionEmulHfPlusTau[nRegionEmul] = ireg->fineGrain();
  }
  // fill region/bit arrays for hardware
  for (L1CaloRegionCollection::const_iterator ireg = rgnData->begin(); ireg != rgnData->end(); ireg++) {
    if (selectBX_ != -1 && selectBX_ != ireg->bx())
      continue;
 
    //     std::cout << "Data: " << nRegionData << " " << ireg->gctEta() << " " << ireg->gctPhi() << std::endl;
    if (ireg->overFlow())
      rctBitDataOverFlow2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    if (ireg->tauVeto())
      rctBitDataTauVeto2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    if (ireg->mip())
      rctBitDataMip2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    if (ireg->quiet())
      rctBitDataQuiet2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    if (ireg->fineGrain())
      rctBitDataHfPlusTau2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    if (ireg->et() > 0) {
      rctRegDataOcc1D_->Fill(PHIBINS * ireg->gctEta() + ireg->gctPhi());
      rctRegDataOcc2D_->Fill(ireg->gctEta(), ireg->gctPhi());
    }
    // to show bad channels in 2D inefficiency:
    // if(ireg->overFlow())  rctBitEmulOverFlow2D_ ->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    // if(ireg->tauVeto())   rctBitEmulTauVeto2D_  ->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    // if(ireg->mip())       rctBitEmulMip2D_      ->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    // if(ireg->quiet())     rctBitEmulQuiet2D_    ->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    // if(ireg->fineGrain()) rctBitEmulHfPlusTau2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    // if(ireg->et() > 0)    rctRegEmulOcc2D_      ->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    if (ireg->overFlow())
      rctBitUnmatchedDataOverFlow2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    if (ireg->tauVeto())
      rctBitUnmatchedDataTauVeto2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    if (ireg->mip())
      rctBitUnmatchedDataMip2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    if (ireg->quiet())
      rctBitUnmatchedDataQuiet2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    if (ireg->fineGrain())
      rctBitUnmatchedDataHfPlusTau2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
    if (ireg->et() > 0)
      rctRegUnmatchedDataOcc2D_->Fill(ireg->gctEta(), ireg->gctPhi(), 0.01);
 
    nRegionData = PHIBINS * ireg->gctEta() + ireg->gctPhi();
 
    regionDataRank[nRegionData] = ireg->et();
    regionDataEta[nRegionData] = ireg->gctEta();
    regionDataPhi[nRegionData] = ireg->gctPhi();
    regionDataOverFlow[nRegionData] = ireg->overFlow();
    regionDataTauVeto[nRegionData] = ireg->tauVeto();
    regionDataMip[nRegionData] = ireg->mip();
    regionDataQuiet[nRegionData] = ireg->quiet();
    regionDataHfPlusTau[nRegionData] = ireg->fineGrain();
  }
 
  if (verbose_) {
    std::cout << "I found Data! Iso: " << nelectrIsoData << " Niso: " << nelectrNisoData << std::endl;
    for (int i = 0; i < nelectrIsoData; i++)
      std::cout << " Iso Energy " << electronDataRank[0][i] << " eta " << electronDataEta[0][i] << " phi "
                << electronDataPhi[0][i] << std::endl;
    for (int i = 0; i < nelectrNisoData; i++)
      std::cout << " Niso Energy " << electronDataRank[1][i] << " eta " << electronDataEta[1][i] << " phi "
                << electronDataPhi[1][i] << std::endl;
 
    std::cout << "I found Emul! Iso: " << nelectrIsoEmul << " Niso: " << nelectrNisoEmul << std::endl;
    for (int i = 0; i < nelectrIsoEmul; i++)
      std::cout << " Iso Energy " << electronEmulRank[0][i] << " eta " << electronEmulEta[0][i] << " phi "
                << electronEmulPhi[0][i] << std::endl;
    for (int i = 0; i < nelectrNisoEmul; i++)
      std::cout << " Niso Energy " << electronEmulRank[1][i] << " eta " << electronEmulEta[1][i] << " phi "
                << electronEmulPhi[1][i] << std::endl;
 
    std::cout << "I found Data! Regions: " << PhiEtaMax << std::endl;
    for (int i = 0; i < (int)PhiEtaMax; i++)
      if (regionDataRank[i] != 0)
        std::cout << " Energy " << regionDataRank[i] << " eta " << regionDataEta[i] << " phi " << regionDataPhi[i]
                  << std::endl;
 
    std::cout << "I found Emul! Regions: " << PhiEtaMax << std::endl;
    for (int i = 0; i < (int)PhiEtaMax; i++)
      if (regionEmulRank[i] != 0)
        std::cout << " Energy " << regionEmulRank[i] << " eta " << regionEmulEta[i] << " phi " << regionEmulPhi[i]
                  << std::endl;
  }
 
  // StepIII: calculate and fill
 
  for (int k = 0; k < 2; k++) {
    int nelectrE, nelectrD;
 
    if (k == 0) {
      nelectrE = nelectrIsoEmul;
      nelectrD = nelectrIsoData;
    }
 
    else {
      nelectrE = nelectrNisoEmul;
      nelectrD = nelectrNisoData;
    }
 
    for (int i = 0; i < nelectrE; i++) {
      //bool triggered = l1SingleEG2; //false; //HACK until true trigger implimented
      double trigThresh = doubleThreshold_;  //ditto
      if (singlechannelhistos_) {
        int chnl = PHIBINS * electronEmulEta[k][i] + electronEmulPhi[k][i];
        if (k == 1 && independent_triggered) {  //non-iso
          //std::cout << "eta " << electronEmulEta[k][i] << " phi " << electronEmulPhi[k][i] << " with rank " <<  electronEmulRank[k][i] << std::endl;
          trigEffOcc_[chnl]->Fill(electronEmulRank[k][i]);
          //        }
          if (triggered)
            trigEffTriggOcc_[chnl]->Fill(electronEmulRank[k][i]);
        }
      }
      //find number of objects with rank above 2x trigger threshold
      //and number after requiring a trigger too
      if (electronEmulRank[k][i] >= trigThresh) {
        if (k == 1 && independent_triggered) {  //non-iso
          trigEffThreshOcc_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i]);
          trigEffTriggThreshOcc_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.01);
          //        }
          if (triggered)
            trigEffTriggThreshOcc_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.98001);
        }
      }
 
      Bool_t found = kFALSE;
 
      for (int j = 0; j < nelectrD; j++) {
        if (electronEmulEta[k][i] == electronDataEta[k][j] && electronEmulPhi[k][i] == electronDataPhi[k][j]) {
          if (k == 0) {
            rctIsoEmEff1Occ_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.98001);
            // Weight is for ROOT; when added to initial weight of 0.01, should just exceed 0.99
 
            int chnl;
 
            chnl = PHIBINS * electronEmulEta[k][i] + electronEmulPhi[k][i];
            rctIsoEmEff1Occ1D_->Fill(chnl);
            if (singlechannelhistos_) {
              int energy_difference;
 
              energy_difference = (electronEmulRank[k][i] - electronDataRank[k][j]);
              rctIsoEffChannel_[chnl]->Fill(energy_difference);
            }
 
            if (electronEmulRank[k][i] == electronDataRank[k][j]) {
              rctIsoEmEff2Occ1D_->Fill(chnl);
              rctIsoEmEff2Occ_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.98012);
              // Weight is for ROOT; should just exceed 0.99
              // NOTE: Weight is different for eff 2 because this isn't filled initially
              // for current definition of Eff2 and Ineff2 we need to add additional
              // factor 0.99 since we divide over eff1 which is 0.99001 e.g. we use 0.99001**2 !
              rctIsoEmIneff2Occ_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.0099);
            } else {
              rctIsoEmIneff2Occ1D_->Fill(chnl);
              rctIsoEmIneff2Occ_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.9801);
              //Check for the bit that is different and store it
              bitset<8> bitDifference(electronEmulRank[k][i] ^ electronDataRank[k][j]);
              for (size_t n = 0; n < bitDifference.size(); n++) {
                if (n < 4) {
                  rctIsoEmBitDiff_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i] + n * 0.25, bitDifference[n]);
                }
                if (n >= 4) {
                  rctIsoEmBitDiff_->Fill(
                      electronEmulEta[k][i] + 0.5, electronEmulPhi[k][i] + (n - 4) * 0.25, bitDifference[n]);
                }
              }
            }
          }
 
          else {
            rctNisoEmEff1Occ_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.98001);
            // Weight is for ROOT; when added to initial weight of 0.01, should just exceed 0.99
 
            int chnl;
 
            chnl = PHIBINS * electronEmulEta[k][i] + electronEmulPhi[k][i];
            rctNisoEmEff1Occ1D_->Fill(chnl);
            if (singlechannelhistos_) {
              int energy_difference;
 
              energy_difference = (electronEmulRank[k][i] - electronDataRank[k][j]);
              rctNisoEffChannel_[chnl]->Fill(energy_difference);
            }
 
            if (electronEmulRank[k][i] == electronDataRank[k][j]) {
              rctNisoEmEff2Occ1D_->Fill(chnl);
              rctNisoEmEff2Occ_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.98012);
              // Weight is for ROOT; should just exceed 0.99
              // NOTE: Weight is different for eff 2 because this isn't filled initially
              // see comments fo Iso
              rctNisoEmIneff2Occ_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.0099);
            } else {
              rctNisoEmIneff2Occ1D_->Fill(chnl);
              rctNisoEmIneff2Occ_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.9801);
              //Check for the bit that is different and store it
              bitset<8> bitDifference(electronEmulRank[k][i] ^ electronDataRank[k][j]);
              for (size_t n = 0; n < bitDifference.size(); n++) {
                if (n < 4) {
                  rctNIsoEmBitDiff_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i] + n * 0.25, bitDifference[n]);
                }
                if (n >= 4) {
                  rctNIsoEmBitDiff_->Fill(
                      electronEmulEta[k][i] + 0.5, electronEmulPhi[k][i] + (n - 4) * 0.25, bitDifference[n]);
                }
              }
            }
          }
 
          found = kTRUE;
        }
      }
 
      if (found == kFALSE) {
        if (k == 0) {
          rctIsoEmIneffOcc_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.98);
          // Weight is for ROOT; when added to initial weight of 0.01, should equal 0.99
 
          int chnl;
 
          //Store the bit map for the emulator
          bitset<8> bit(electronEmulRank[k][i]);
          for (size_t n = 0; n < bit.size(); n++) {
            if (n < 4) {
              rctIsoEmBitOff_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i] + n * 0.25, bit[n]);
            }
            if (n >= 4) {
              rctIsoEmBitOff_->Fill(electronEmulEta[k][i] + 0.5, electronEmulPhi[k][i] + (n - 4) * 0.25, bit[n]);
            }
          }
 
          chnl = PHIBINS * electronEmulEta[k][i] + electronEmulPhi[k][i];
          rctIsoEmIneffOcc1D_->Fill(chnl);
          if (singlechannelhistos_) {
            rctIsoIneffChannel_[chnl]->Fill(electronEmulRank[k][i]);
          }
        }
 
        else {
          rctNisoEmIneffOcc_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i], 0.98);
          // Weight is for ROOT; when added to initial weight of 0.01, should equal 0.99
 
          int chnl;
 
          chnl = PHIBINS * electronEmulEta[k][i] + electronEmulPhi[k][i];
          rctNisoEmIneffOcc1D_->Fill(chnl);
 
          //Store the bit map for the emulator
          bitset<8> bit(electronEmulRank[k][i]);
          for (size_t n = 0; n < bit.size(); n++) {
            if (n < 4) {
              rctNIsoEmBitOff_->Fill(electronEmulEta[k][i], electronEmulPhi[k][i] + n * 0.25, bit[n]);
            }
            if (n >= 4) {
              rctNIsoEmBitOff_->Fill(electronEmulEta[k][i] + 0.5, electronEmulPhi[k][i] + (n - 4) * 0.25, bit[n]);
            }
          }
 
          if (singlechannelhistos_) {
            rctNisoIneffChannel_[chnl]->Fill(electronEmulRank[k][i]);
          }
        }
      }
    }
 
    DivideME1D(rctIsoEmEff1Occ1D_, rctIsoEmEmulOcc1D_, rctIsoEmEff1oneD_);
    DivideME2D(rctIsoEmEff1Occ_, rctIsoEmEmulOcc_, rctIsoEmEff1_);
    //    DivideME1D(rctIsoEmEff2Occ1D_, rctIsoEmEmulOcc1D_, rctIsoEmEff2oneD_);
    //    DivideME2D(rctIsoEmEff2Occ_, rctIsoEmEmulOcc_, rctIsoEmEff2_) ;
    DivideME1D(rctIsoEmEff2Occ1D_, rctIsoEmEff1Occ1D_, rctIsoEmEff2oneD_);
    DivideME2D(rctIsoEmEff2Occ_, rctIsoEmEff1Occ_, rctIsoEmEff2_);
    //    DivideME1D(rctIsoEmIneff2Occ1D_, rctIsoEmEmulOcc1D_, rctIsoEmIneff2oneD_);
    //    DivideME2D(rctIsoEmIneff2Occ_, rctIsoEmEmulOcc_, rctIsoEmIneff2_) ;
    DivideME1D(rctIsoEmIneff2Occ1D_, rctIsoEmEff1Occ1D_, rctIsoEmIneff2oneD_);
    DivideME2D(rctIsoEmIneff2Occ_, rctIsoEmEff1Occ_, rctIsoEmIneff2_);
 
    DivideME1D(rctNisoEmEff1Occ1D_, rctNisoEmEmulOcc1D_, rctNisoEmEff1oneD_);
    DivideME2D(rctNisoEmEff1Occ_, rctNisoEmEmulOcc_, rctNisoEmEff1_);
    //    DivideME1D(rctNisoEmEff2Occ1D_, rctNisoEmEmulOcc1D_, rctNisoEmEff2oneD_);
    //    DivideME2D(rctNisoEmEff2Occ_, rctNisoEmEmulOcc_, rctNisoEmEff2_);
    DivideME1D(rctNisoEmEff2Occ1D_, rctNisoEmEff1Occ1D_, rctNisoEmEff2oneD_);
    DivideME2D(rctNisoEmEff2Occ_, rctNisoEmEff1Occ_, rctNisoEmEff2_);
    //    DivideME1D(rctNisoEmIneff2Occ1D_, rctNisoEmEmulOcc1D_, rctNisoEmIneff2oneD_);
    //    DivideME2D(rctNisoEmIneff2Occ_, rctNisoEmEmulOcc_, rctNisoEmIneff2_);
    DivideME1D(rctNisoEmIneff2Occ1D_, rctNisoEmEff1Occ1D_, rctNisoEmIneff2oneD_);
    DivideME2D(rctNisoEmIneff2Occ_, rctNisoEmEff1Occ_, rctNisoEmIneff2_);
 
    DivideME1D(rctIsoEmIneffOcc1D_, rctIsoEmEmulOcc1D_, rctIsoEmIneff1D_);
    DivideME2D(rctIsoEmIneffOcc_, rctIsoEmEmulOcc_, rctIsoEmIneff_);
    DivideME1D(rctNisoEmIneffOcc1D_, rctNisoEmEmulOcc1D_, rctNisoEmIneff1D_);
    DivideME2D(rctNisoEmIneffOcc_, rctNisoEmEmulOcc_, rctNisoEmIneff_);
 
    DivideME2D(trigEffTriggThreshOcc_, trigEffThreshOcc_, trigEffThresh_);
    if (singlechannelhistos_) {
      for (int i = 0; i < nelectrE; i++) {
        int chnl = PHIBINS * electronEmulEta[k][i] + electronEmulPhi[k][i];
        DivideME1D(trigEffTriggOcc_[chnl], trigEffOcc_[chnl], trigEff_[chnl]);
      }
    }
 
    for (int i = 0; i < nelectrD; i++) {
      Bool_t found = kFALSE;
 
      for (int j = 0; j < nelectrE; j++) {
        if (electronEmulEta[k][j] == electronDataEta[k][i] && electronEmulPhi[k][j] == electronDataPhi[k][i]) {
          found = kTRUE;
        }
      }
 
      if (found == kFALSE) {
        if (k == 0) {
          rctIsoEmOvereffOcc_->Fill(electronDataEta[k][i], electronDataPhi[k][i], 0.98);
          // Weight is for ROOT; when added to initial weight of 0.01, should equal 0.99
 
          int chnl;
 
          //Store the bit map for the emulator
          bitset<8> bit(electronDataRank[k][i]);
          for (size_t n = 0; n < bit.size(); n++) {
            if (n < 4) {
              rctIsoEmBitOn_->Fill(electronDataEta[k][i], electronDataPhi[k][i] + n * 0.25, bit[n]);
            }
            if (n >= 4) {
              rctIsoEmBitOn_->Fill(electronDataEta[k][i] + 0.5, electronDataPhi[k][i] + (n - 4) * 0.25, bit[n]);
            }
          }
 
          chnl = PHIBINS * electronDataEta[k][i] + electronDataPhi[k][i];
          rctIsoEmOvereffOcc1D_->Fill(chnl);
 
          if (singlechannelhistos_) {
            rctIsoOvereffChannel_[chnl]->Fill(electronDataRank[k][i]);
          }
        }
 
        else {
          rctNisoEmOvereffOcc_->Fill(electronDataEta[k][i], electronDataPhi[k][i], 0.98);
          // Weight is for ROOT; when added to initial weight of 0.01, should equal 0.99
 
          int chnl;
 
          //Store the bit map for the emulator
          bitset<8> bit(electronDataRank[k][i]);
          for (size_t n = 0; n < bit.size(); n++) {
            if (n < 4) {
              rctNIsoEmBitOn_->Fill(electronDataEta[k][i], electronDataPhi[k][i] + n * 0.25, bit[n]);
            }
            if (n >= 4) {
              rctNIsoEmBitOn_->Fill(electronDataEta[k][i] + 0.5, electronDataPhi[k][i] + (n - 4) * 0.25, bit[n]);
            }
          }
 
          chnl = PHIBINS * electronDataEta[k][i] + electronDataPhi[k][i];
          rctNisoEmOvereffOcc1D_->Fill(chnl);
 
          if (singlechannelhistos_) {
            rctNisoOvereffChannel_[chnl]->Fill(electronDataRank[k][i]);
          }
        }
      }
    }
  }
 
  // we try new definition of overefficiency:
  DivideME1D(rctIsoEmOvereffOcc1D_, rctIsoEmDataOcc1D_, rctIsoEmOvereff1D_);
  DivideME2D(rctIsoEmOvereffOcc_, rctIsoEmDataOcc_, rctIsoEmOvereff_);
  DivideME1D(rctNisoEmOvereffOcc1D_, rctNisoEmDataOcc1D_, rctNisoEmOvereff1D_);
  DivideME2D(rctNisoEmOvereffOcc_, rctNisoEmDataOcc_, rctNisoEmOvereff_);
 
  // calculate region/bit information
  for (unsigned int i = 0; i < (int)PhiEtaMax; i++) {
    Bool_t regFound = kFALSE;
    Bool_t overFlowFound = kFALSE;
    Bool_t tauVetoFound = kFALSE;
    Bool_t mipFound = kFALSE;
    Bool_t quietFound = kFALSE;
    Bool_t hfPlusTauFound = kFALSE;
 
    //       for(int j = 0; j < nRegionData; j++)
    //    {
    //         if(regionEmulEta[i] == regionDataEta[j] &&
    //            regionEmulPhi[i] == regionDataPhi[j])
    //         {
    if (regionDataRank[i] >= 1 && regionEmulRank[i] >= 1) {
      int chnl;
 
      chnl = PHIBINS * regionEmulEta[i] + regionEmulPhi[i];
      rctRegMatchedOcc1D_->Fill(chnl);
      rctRegMatchedOcc2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98001);
      // Weight is for ROOT; when added to initial weight of 0.01, should just exceed 0.99
 
      if (singlechannelhistos_)
        rctRegEffChannel_[chnl]->Fill(regionEmulRank[i] - regionDataRank[i]);
 
      // see comments for Iso Eff2
 
      if (regionEmulRank[i] == regionDataRank[i]) {
        rctRegSpEffOcc1D_->Fill(chnl);
        //             rctRegSpEffOcc2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.99001);
        rctRegSpEffOcc2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98012);
        rctRegSpIneffOcc2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.0099);
      } else {
        rctRegSpIneffOcc1D_->Fill(chnl);
        rctRegSpIneffOcc2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.9801);
 
        bitset<10> bitDifference(regionEmulRank[i] ^ regionDataRank[i]);
        for (size_t n = 0; n < bitDifference.size(); n++) {
          if (n < 5) {
            rctRegBitDiff_->Fill(regionEmulEta[i], regionEmulPhi[i] + n * 0.2, bitDifference[n]);
          }
          if (n >= 5) {
            rctRegBitDiff_->Fill(regionEmulEta[i] + 0.5, regionEmulPhi[i] + (n - 5) * 0.2, bitDifference[n]);
          }
        }
      }
      // Weight is for ROOT; should just exceed 0.99
      // NOTE: Weight is different for eff 2 because this isn't filled initially
 
      regFound = kTRUE;
    }
 
    if (regionEmulOverFlow[i] == true && regionDataOverFlow[i] == true) {
      rctBitMatchedOverFlow2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98001);
      overFlowFound = kTRUE;
    }
 
    if (regionEmulTauVeto[i] == true && regionDataTauVeto[i] == true) {
      rctBitMatchedTauVeto2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98001);
      tauVetoFound = kTRUE;
    }
 
    if (regionEmulMip[i] == true && regionDataMip[i] == true) {
      rctBitMatchedMip2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98001);
      mipFound = kTRUE;
    }
 
    if (regionEmulQuiet[i] == true && regionDataQuiet[i] == true) {
      rctBitMatchedQuiet2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98001);
      quietFound = kTRUE;
    }
 
    if (regionEmulHfPlusTau[i] == true && regionDataHfPlusTau[i] == true) {
      rctBitMatchedHfPlusTau2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98001);
      hfPlusTauFound = kTRUE;
    }
 
    //         }
    //       }
 
    if (regFound == kFALSE && regionEmulRank[i] >= 1) {
      int chnl;
 
      bitset<10> bit(regionEmulRank[i]);
      for (size_t n = 0; n < bit.size(); n++) {
        if (n < 5) {
          rctRegBitOff_->Fill(regionEmulEta[i], regionEmulPhi[i] + n * 0.2, bit[n]);
        }
        if (n >= 5) {
          rctRegBitOff_->Fill(regionEmulEta[i] + 0.5, regionEmulPhi[i] + (n - 5) * 0.2, bit[n]);
        }
      }
 
      chnl = PHIBINS * regionEmulEta[i] + regionEmulPhi[i];
      rctRegUnmatchedEmulOcc1D_->Fill(chnl);
      rctRegUnmatchedEmulOcc2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98);
      // Weight is for ROOT; when added to initial weight of 0.01, should equal 0.99
 
      if (singlechannelhistos_)
        rctRegIneffChannel_[chnl]->Fill(regionEmulRank[i]);
    }
 
    if (overFlowFound == kFALSE && regionEmulOverFlow[i] == true) {
      rctBitUnmatchedEmulOverFlow2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98);
    }
 
    if (tauVetoFound == kFALSE && regionEmulTauVeto[i] == true) {
      rctBitUnmatchedEmulTauVeto2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98);
    }
 
    if (mipFound == kFALSE && regionEmulMip[i] == true) {
      rctBitUnmatchedEmulMip2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98);
    }
 
    if (quietFound == kFALSE && regionEmulQuiet[i] == true) {
      rctBitUnmatchedEmulQuiet2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98);
    }
 
    if (hfPlusTauFound == kFALSE && regionEmulHfPlusTau[i] == true) {
      rctBitUnmatchedEmulHfPlusTau2D_->Fill(regionEmulEta[i], regionEmulPhi[i], 0.98);
    }
  }
 
  DivideME1D(rctRegMatchedOcc1D_, rctRegEmulOcc1D_, rctRegEff1D_);
  DivideME2D(rctRegMatchedOcc2D_, rctRegEmulOcc2D_, rctRegEff2D_);
  //      DivideME1D(rctRegSpEffOcc1D_, rctRegEmulOcc1D_, rctRegSpEff1D_);
  //      DivideME2D(rctRegSpEffOcc2D_, rctRegEmulOcc2D_, rctRegSpEff2D_);
  DivideME1D(rctRegSpEffOcc1D_, rctRegMatchedOcc1D_, rctRegSpEff1D_);
  DivideME2D(rctRegSpEffOcc2D_, rctRegMatchedOcc2D_, rctRegSpEff2D_);
  //      DivideME1D(rctRegSpIneffOcc1D_, rctRegEmulOcc1D_, rctRegSpIneff1D_);
  //      DivideME2D(rctRegSpIneffOcc2D_, rctRegEmulOcc2D_, rctRegSpIneff2D_);
  DivideME1D(rctRegSpIneffOcc1D_, rctRegMatchedOcc1D_, rctRegSpIneff1D_);
  DivideME2D(rctRegSpIneffOcc2D_, rctRegMatchedOcc2D_, rctRegSpIneff2D_);
  DivideME2D(rctBitMatchedOverFlow2D_, rctBitEmulOverFlow2D_, rctBitOverFlowEff2D_);
  DivideME2D(rctBitMatchedTauVeto2D_, rctBitEmulTauVeto2D_, rctBitTauVetoEff2D_);
  DivideME2D(rctBitMatchedMip2D_, rctBitEmulMip2D_, rctBitMipEff2D_);
  // QUIETBIT: To add quiet bit information, uncomment following line:
  // DivideME2D (rctBitMatchedQuiet2D_, rctBitEmulQuiet2D_, rctBitQuietEff2D_);
  DivideME2D(rctBitMatchedHfPlusTau2D_, rctBitEmulHfPlusTau2D_, rctBitHfPlusTauEff2D_);
 
  DivideME1D(rctRegUnmatchedEmulOcc1D_, rctRegEmulOcc1D_, rctRegIneff1D_);
  DivideME2D(rctRegUnmatchedEmulOcc2D_, rctRegEmulOcc2D_, rctRegIneff2D_);
  DivideME2D(rctBitUnmatchedEmulOverFlow2D_, rctBitEmulOverFlow2D_, rctBitOverFlowIneff2D_);
  DivideME2D(rctBitUnmatchedEmulTauVeto2D_, rctBitEmulTauVeto2D_, rctBitTauVetoIneff2D_);
  DivideME2D(rctBitUnmatchedEmulMip2D_, rctBitEmulMip2D_, rctBitMipIneff2D_);
  // QUIETBIT: To add quiet bit information, uncomment the following line:
  // DivideME2D (rctBitUnmatchedEmulQuiet2D_, rctBitEmulQuiet2D_, rctBitQuietIneff2D_);
  DivideME2D(rctBitUnmatchedEmulHfPlusTau2D_, rctBitEmulHfPlusTau2D_, rctBitHfPlusTauIneff2D_);
 
  // for(int i = 0; i < nRegionData; i++)
  for (int i = 0; i < (int)PhiEtaMax; i++) {
    Bool_t regFound = kFALSE;
    Bool_t overFlowFound = kFALSE;
    Bool_t tauVetoFound = kFALSE;
    Bool_t mipFound = kFALSE;
    Bool_t quietFound = kFALSE;
    Bool_t hfPlusTauFound = kFALSE;
 
    //       for(int j = 0; j < nRegionEmul; j++)
    //      {
    //         if(regionEmulEta[j] == regionDataEta[i] &&
    //            regionEmulPhi[j] == regionDataPhi[i])
    //         {
 
    if (regionEmulRank[i] >= 1 && regionDataRank[i] >= 1)
      regFound = kTRUE;
 
    if (regionDataOverFlow[i] == true && regionEmulOverFlow[i] == true)
      overFlowFound = kTRUE;
 
    if (regionDataTauVeto[i] == true && regionEmulTauVeto[i] == true)
      tauVetoFound = kTRUE;
 
    if (regionDataMip[i] == true && regionEmulMip[i] == true)
      mipFound = kTRUE;
 
    if (regionDataQuiet[i] == true && regionEmulQuiet[i] == true)
      quietFound = kTRUE;
 
    if (regionDataHfPlusTau[i] == true && regionEmulHfPlusTau[i] == true)
      hfPlusTauFound = kTRUE;
    //         }
    //       }
 
    if (regFound == kFALSE && regionDataRank[i] >= 1) {
      int chnl;
 
      bitset<10> bit(regionDataRank[i]);
      for (size_t n = 0; n < bit.size(); n++) {
        if (n < 5) {
          rctRegBitOn_->Fill(regionDataEta[i], regionDataPhi[i] + n * 0.2, bit[n]);
        }
        if (n >= 5) {
          rctRegBitOn_->Fill(regionDataEta[i] + 0.5, regionDataPhi[i] + (n - 5) * 0.2, bit[n]);
        }
      }
 
      chnl = PHIBINS * regionDataEta[i] + regionDataPhi[i];
      rctRegUnmatchedDataOcc1D_->Fill(chnl);
      rctRegUnmatchedDataOcc2D_->Fill(regionDataEta[i], regionDataPhi[i], 0.98);
      // Weight is for ROOT; when added to initial weight of 0.01, should equal 0.99
 
      // we try a new definition of overefficiency:
      // DivideME1D(rctRegUnmatchedDataOcc1D_, rctRegDataOcc1D_, rctRegOvereff1D_);
      // DivideME2D(rctRegUnmatchedDataOcc2D_, rctRegDataOcc2D_, rctRegOvereff2D_);
 
      if (singlechannelhistos_)
        rctRegOvereffChannel_[chnl]->Fill(regionDataRank[i]);
    }
 
    if (overFlowFound == kFALSE && regionDataOverFlow[i] == true) {
      rctBitUnmatchedDataOverFlow2D_->Fill(regionDataEta[i], regionDataPhi[i], 0.98);
    }
 
    if (tauVetoFound == kFALSE && regionDataTauVeto[i] == true) {
      rctBitUnmatchedDataTauVeto2D_->Fill(regionDataEta[i], regionDataPhi[i], 0.98);
    }
 
    if (mipFound == kFALSE && regionDataMip[i] == true) {
      rctBitUnmatchedDataMip2D_->Fill(regionDataEta[i], regionDataPhi[i], 0.98);
    }
 
    if (quietFound == kFALSE && regionDataQuiet[i] == true) {
      rctBitUnmatchedDataQuiet2D_->Fill(regionDataEta[i], regionDataPhi[i], 0.98);
    }
 
    if (hfPlusTauFound == kFALSE && regionDataHfPlusTau[i] == true) {
      rctBitUnmatchedDataHfPlusTau2D_->Fill(regionDataEta[i], regionDataPhi[i], 0.98);
    }
  }
 
  // we try a new definition of overefficiency:
  DivideME1D(rctRegUnmatchedDataOcc1D_, rctRegDataOcc1D_, rctRegOvereff1D_);
  DivideME2D(rctRegUnmatchedDataOcc2D_, rctRegDataOcc2D_, rctRegOvereff2D_);
  DivideME2D(rctBitUnmatchedDataOverFlow2D_, rctBitDataOverFlow2D_, rctBitOverFlowOvereff2D_);
  DivideME2D(rctBitUnmatchedDataTauVeto2D_, rctBitDataTauVeto2D_, rctBitTauVetoOvereff2D_);
  DivideME2D(rctBitUnmatchedDataMip2D_, rctBitDataMip2D_, rctBitMipOvereff2D_);
  // QUIETBIT: To add quiet bit information, uncomment following 2 lines:
  // DivideME2D (rctBitUnmatchedDataQuiet2D_, rctBitDataQuiet2D_,
  // rctBitQuietOvereff2D_);
  DivideME2D(rctBitUnmatchedDataHfPlusTau2D_, rctBitDataHfPlusTau2D_, rctBitHfPlusTauOvereff2D_);
}

References edm::SortedCollection< T, SORT >::begin(), gather_cfg::cout, L1GlobalTriggerReadoutRecord::decisionWord(), DivideME1D(), DivideME2D(), doubleThreshold_, MillePedeFileConverter_cfg::e, ecalTPGData_, edm::SortedCollection< T, SORT >::end(), dqm::impl::MonitorElement::Fill(), filterTriggerType_, newFWLiteAna::found, gtDigisLabel_, gtEGAlgoName_, hcalTPGData_, gedPhotons_cfi::highEt, mps_fire::i, createfilelist::int, edm::HandleBase::isValid(), dqmiolumiharvest::j, dqmdumpme::k, dqmiodumpmetadata::n, nev_, notrigCount, PHIBINS, rctBitDataHfPlusTau2D_, rctBitDataMip2D_, rctBitDataOverFlow2D_, rctBitDataQuiet2D_, rctBitDataTauVeto2D_, rctBitEmulHfPlusTau2D_, rctBitEmulMip2D_, rctBitEmulOverFlow2D_, rctBitEmulQuiet2D_, rctBitEmulTauVeto2D_, rctBitHfPlusTauEff2D_, rctBitHfPlusTauIneff2D_, rctBitHfPlusTauOvereff2D_, rctBitMatchedHfPlusTau2D_, rctBitMatchedMip2D_, rctBitMatchedOverFlow2D_, rctBitMatchedQuiet2D_, rctBitMatchedTauVeto2D_, rctBitMipEff2D_, rctBitMipIneff2D_, rctBitMipOvereff2D_, rctBitOverFlowEff2D_, rctBitOverFlowIneff2D_, rctBitOverFlowOvereff2D_, rctBitTauVetoEff2D_, rctBitTauVetoIneff2D_, rctBitTauVetoOvereff2D_, rctBitUnmatchedDataHfPlusTau2D_, rctBitUnmatchedDataMip2D_, rctBitUnmatchedDataOverFlow2D_, rctBitUnmatchedDataQuiet2D_, rctBitUnmatchedDataTauVeto2D_, rctBitUnmatchedEmulHfPlusTau2D_, rctBitUnmatchedEmulMip2D_, rctBitUnmatchedEmulOverFlow2D_, rctBitUnmatchedEmulQuiet2D_, rctBitUnmatchedEmulTauVeto2D_, rctInputTPGEcalOcc_, rctInputTPGEcalOccNoCut_, rctInputTPGEcalRank_, rctInputTPGHcalOcc_, rctInputTPGHcalRank_, rctInputTPGHcalSample_, rctIsoEffChannel_, rctIsoEmBitDiff_, rctIsoEmBitOff_, rctIsoEmBitOn_, rctIsoEmDataOcc1D_, rctIsoEmDataOcc_, rctIsoEmEff1_, rctIsoEmEff1Occ1D_, rctIsoEmEff1Occ_, rctIsoEmEff1oneD_, rctIsoEmEff2_, rctIsoEmEff2Occ1D_, rctIsoEmEff2Occ_, rctIsoEmEff2oneD_, rctIsoEmEmulOcc1D_, rctIsoEmEmulOcc_, rctIsoEmIneff1D_, rctIsoEmIneff2_, rctIsoEmIneff2Occ1D_, rctIsoEmIneff2Occ_, rctIsoEmIneff2oneD_, rctIsoEmIneff_, rctIsoEmIneffOcc1D_, rctIsoEmIneffOcc_, rctIsoEmOvereff1D_, rctIsoEmOvereff_, rctIsoEmOvereffOcc1D_, rctIsoEmOvereffOcc_, rctIsoIneffChannel_, rctIsoOvereffChannel_, rctNisoEffChannel_, rctNIsoEmBitDiff_, rctNIsoEmBitOff_, rctNIsoEmBitOn_, rctNisoEmDataOcc1D_, rctNisoEmDataOcc_, rctNisoEmEff1_, rctNisoEmEff1Occ1D_, rctNisoEmEff1Occ_, rctNisoEmEff1oneD_, rctNisoEmEff2_, rctNisoEmEff2Occ1D_, rctNisoEmEff2Occ_, rctNisoEmEff2oneD_, rctNisoEmEmulOcc1D_, rctNisoEmEmulOcc_, rctNisoEmIneff1D_, rctNisoEmIneff2_, rctNisoEmIneff2Occ1D_, rctNisoEmIneff2Occ_, rctNisoEmIneff2oneD_, rctNisoEmIneff_, rctNisoEmIneffOcc1D_, rctNisoEmIneffOcc_, rctNisoEmOvereff1D_, rctNisoEmOvereff_, rctNisoEmOvereffOcc1D_, rctNisoEmOvereffOcc_, rctNisoIneffChannel_, rctNisoOvereffChannel_, rctRegBitDiff_, rctRegBitOff_, rctRegBitOn_, rctRegDataOcc1D_, rctRegDataOcc2D_, rctRegEff1D_, rctRegEff2D_, rctRegEffChannel_, rctRegEmulOcc1D_, rctRegEmulOcc2D_, rctRegIneff1D_, rctRegIneff2D_, rctRegIneffChannel_, rctRegMatchedOcc1D_, rctRegMatchedOcc2D_, rctRegOvereff1D_, rctRegOvereff2D_, rctRegOvereffChannel_, rctRegSpEff1D_, rctRegSpEff2D_, rctRegSpEffOcc1D_, rctRegSpEffOcc2D_, rctRegSpIneff1D_, rctRegSpIneff2D_, rctRegSpIneffOcc1D_, rctRegSpIneffOcc2D_, rctRegUnmatchedDataOcc1D_, rctRegUnmatchedDataOcc2D_, rctRegUnmatchedEmulOcc1D_, rctRegUnmatchedEmulOcc2D_, rctSourceData_emData_, rctSourceData_rgnData_, rctSourceEmul_emEmul_, rctSourceEmul_rgnEmul_, selectBX_, singlechannelhistos_, trigCount, trigEff_, trigEffOcc_, trigEffThresh_, trigEffThreshOcc_, trigEffTriggOcc_, trigEffTriggThreshOcc_, triggerAlgoNumbers_, HLT_2018_cff::triggerType, triggerType_, and verbose_.

bookHistograms()

void L1TdeRCT::bookHistograms ( DQMStore::IBooker &  ibooker, const edm::Run &  run, const edm::EventSetup &  es  )

overrideprotected

Definition at line 1134 of file L1TdeRCT.cc.

                                                                                                  {
  // get hold of back-end interface
  nev_ = 0;
  //DQMStore *dbe = 0;
  //dbe = Service < DQMStore > ().operator->();
 
  //if (dbe) {
  //  dbe->setCurrentFolder(histFolder_);
  //  dbe->rmdir(histFolder_);
  //}
 
  //if (dbe) {
 
  ibooker.setCurrentFolder(histFolder_);
 
  triggerType_ = ibooker.book1D("TriggerType", "TriggerType", 17, -0.5, 16.5);
 
  triggerAlgoNumbers_ = ibooker.book1D("gtTriggerAlgoNumbers", "gtTriggerAlgoNumbers", 128, -0.5, 127.5);
 
  rctInputTPGEcalOcc_ = ibooker.book2D(
      "rctInputTPGEcalOcc", "rctInputTPGEcalOcc", TPGETABINS, TPGETAMIN, TPGETAMAX, TPGPHIBINS, TPGPHIMIN, TPGPHIMAX);
 
  rctInputTPGEcalOccNoCut_ = ibooker.book2D("rctInputTPGEcalOccNoCut",
                                            "rctInputTPGEcalOccNoCut",
                                            TPGETABINS,
                                            TPGETAMIN,
                                            TPGETAMAX,
                                            TPGPHIBINS,
                                            TPGPHIMIN,
                                            TPGPHIMAX);
 
  rctInputTPGEcalRank_ = ibooker.book1D("rctInputTPGEcalRank", "rctInputTPGEcalRank", TPGRANK, TPGRANKMIN, TPGRANKMAX);
 
  rctInputTPGHcalOcc_ = ibooker.book2D(
      "rctInputTPGHcalOcc", "rctInputTPGHcalOcc", TPGETABINS, TPGETAMIN, TPGETAMAX, TPGPHIBINS, TPGPHIMIN, TPGPHIMAX);
 
  rctInputTPGHcalSample_ = ibooker.book1D("rctInputTPGHcalSample", "rctInputTPGHcalSample", 10, -0.5, 9.5);
 
  rctInputTPGHcalRank_ = ibooker.book1D("rctInputTPGHcalRank", "rctInputTPGHcalRank", TPGRANK, TPGRANKMIN, TPGRANKMAX);
 
  ibooker.setCurrentFolder(histFolder_ + "/EffCurves/NisoEm/");
 
  trigEffThresh_ = ibooker.book2D("trigEffThresh",
                                  "Rank occupancy >= 2x trig thresh (source: " + dataInputTagName_ + ")",
                                  ETABINS,
                                  ETAMIN,
                                  ETAMAX,
                                  PHIBINS,
                                  PHIMIN,
                                  PHIMAX);
 
  ibooker.setCurrentFolder(histFolder_ + "/EffCurves/NisoEm/ServiceData");
 
  trigEffThreshOcc_ = ibooker.book2D("trigEffThreshOcc",
                                     "Rank occupancy >= 2x trig thresh (source: " + dataInputTagName_ + ")",
                                     ETABINS,
                                     ETAMIN,
                                     ETAMAX,
                                     PHIBINS,
                                     PHIMIN,
                                     PHIMAX);
  trigEffTriggThreshOcc_ =
      ibooker.book2D("trigEffTriggThreshOcc",
                     "Rank occupancy >= 2x trig thresh, triggered (source: " + dataInputTagName_ + ")",
                     ETABINS,
                     ETAMIN,
                     ETAMAX,
                     PHIBINS,
                     PHIMIN,
                     PHIMAX);
 
  ibooker.setCurrentFolder(histFolder_ + "/IsoEm");
 
  rctIsoEmEff1_ = ibooker.book2D("rctIsoEmEff1",
                                 "rctIsoEmEff1 (source: " + dataInputTagName_ + ")",
                                 ETABINS,
                                 ETAMIN,
                                 ETAMAX,
                                 PHIBINS,
                                 PHIMIN,
                                 PHIMAX);
 
  rctIsoEmEff1oneD_ = ibooker.book1D("rctIsoEmEff1oneD", "rctIsoEmEff1oneD", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctIsoEmEff2_ = ibooker.book2D("rctIsoEmEff2",
                                 "rctIsoEmEff2, energy matching required (source: " + dataInputTagName_ + ")",
                                 ETABINS,
                                 ETAMIN,
                                 ETAMAX,
                                 PHIBINS,
                                 PHIMIN,
                                 PHIMAX);
 
  rctIsoEmEff2oneD_ =
      ibooker.book1D("rctIsoEmEff2oneD", "rctIsoEmEff2oneD, energy matching required", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctIsoEmIneff2_ = ibooker.book2D("rctIsoEmIneff2",
                                   "rctIsoEmIneff2, energy matching required (source: " + dataInputTagName_ + ")",
                                   ETABINS,
                                   ETAMIN,
                                   ETAMAX,
                                   PHIBINS,
                                   PHIMIN,
                                   PHIMAX);
 
  rctIsoEmIneff2oneD_ =
      ibooker.book1D("rctIsoEmIneff2oneD", "rctIsoEmIneff2oneD, energy matching required", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctIsoEmIneff_ = ibooker.book2D("rctIsoEmIneff",
                                  "rctIsoEmIneff (source: " + dataInputTagName_ + ")",
                                  ETABINS,
                                  ETAMIN,
                                  ETAMAX,
                                  PHIBINS,
                                  PHIMIN,
                                  PHIMAX);
 
  rctIsoEmIneff1D_ = ibooker.book1D("rctIsoEmIneff1D", "rctIsoEmIneff1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctIsoEmOvereff_ = ibooker.book2D("rctIsoEmOvereff",
                                    "rctIsoEmOvereff (source: " + dataInputTagName_ + ")",
                                    ETABINS,
                                    ETAMIN,
                                    ETAMAX,
                                    PHIBINS,
                                    PHIMIN,
                                    PHIMAX);
 
  rctIsoEmOvereff1D_ = ibooker.book1D("rctIsoEmOvereff1D", "rctIsoEmOvereff1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  ibooker.setCurrentFolder(histFolder_ + "/IsoEm/ServiceData");
 
  rctIsoEmDataOcc_ = ibooker.book2D("rctIsoEmDataOcc",
                                    "rctIsoEmDataOcc (source: " + dataInputTagName_ + ")",
                                    ETABINS,
                                    ETAMIN,
                                    ETAMAX,
                                    PHIBINS,
                                    PHIMIN,
                                    PHIMAX);
 
  rctIsoEmDataOcc1D_ = ibooker.book1D("rctIsoEmDataOcc1D", "rctIsoEmDataOcc1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctIsoEmEmulOcc_ = ibooker.book2D("rctIsoEmEmulOcc",
                                    "rctIsoEmEmulOcc (source: " + dataInputTagName_ + ")",
                                    ETABINS,
                                    ETAMIN,
                                    ETAMAX,
                                    PHIBINS,
                                    PHIMIN,
                                    PHIMAX);
 
  rctIsoEmEmulOcc1D_ = ibooker.book1D("rctIsoEmEmulOcc1D", "rctIsoEmEmulOcc1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctIsoEmEff1Occ_ = ibooker.book2D("rctIsoEmEff1Occ",
                                    "rctIsoEmEff1Occ (source: " + dataInputTagName_ + ")",
                                    ETABINS,
                                    ETAMIN,
                                    ETAMAX,
                                    PHIBINS,
                                    PHIMIN,
                                    PHIMAX);
 
  rctIsoEmEff1Occ1D_ = ibooker.book1D("rctIsoEmEff1Occ1D", "rctIsoEmEff1Occ1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctIsoEmEff2Occ_ = ibooker.book2D("rctIsoEmEff2Occ",
                                    "rctIsoEmEff2Occ (source: " + dataInputTagName_ + ")",
                                    ETABINS,
                                    ETAMIN,
                                    ETAMAX,
                                    PHIBINS,
                                    PHIMIN,
                                    PHIMAX);
 
  rctIsoEmEff2Occ1D_ = ibooker.book1D("rctIsoEmEff2Occ1D", "rctIsoEmEff2Occ1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctIsoEmIneff2Occ_ = ibooker.book2D("rctIsoEmIneff2Occ",
                                      "rctIsoEmIneff2Occ (source: " + dataInputTagName_ + ")",
                                      ETABINS,
                                      ETAMIN,
                                      ETAMAX,
                                      PHIBINS,
                                      PHIMIN,
                                      PHIMAX);
 
  rctIsoEmIneff2Occ1D_ = ibooker.book1D("rctIsoEmIneff2Occ1D", "rctIsoEmIneff2Occ1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctIsoEmIneffOcc_ = ibooker.book2D("rctIsoEmIneffOcc",
                                     "rctIsoEmIneffOcc (source: " + dataInputTagName_ + ")",
                                     ETABINS,
                                     ETAMIN,
                                     ETAMAX,
                                     PHIBINS,
                                     PHIMIN,
                                     PHIMAX);
 
  rctIsoEmIneffOcc1D_ = ibooker.book1D("rctIsoEmIneffOcc1D", "rctIsoEmIneffOcc1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctIsoEmOvereffOcc_ = ibooker.book2D("rctIsoEmOvereffOcc",
                                       "rctIsoEmOvereffOcc (source: " + dataInputTagName_ + ")",
                                       ETABINS,
                                       ETAMIN,
                                       ETAMAX,
                                       PHIBINS,
                                       PHIMIN,
                                       PHIMAX);
 
  rctIsoEmOvereffOcc1D_ = ibooker.book1D("rctIsoEmOvereffOcc1D", "rctIsoEmOvereffOcc1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  ibooker.setCurrentFolder(histFolder_ + "/NisoEm");
  rctNisoEmEff1_ = ibooker.book2D("rctNisoEmEff1",
                                  "rctNisoEmEff1 (source: " + dataInputTagName_ + ")",
                                  ETABINS,
                                  ETAMIN,
                                  ETAMAX,
                                  PHIBINS,
                                  PHIMIN,
                                  PHIMAX);
 
  rctNisoEmEff1oneD_ = ibooker.book1D("rctNisoEmEff1oneD", "rctNisoEmEff1oneD", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctNisoEmEff2_ = ibooker.book2D("rctNisoEmEff2",
                                  "rctNisoEmEff2, energy matching required (source: " + dataInputTagName_ + ")",
                                  ETABINS,
                                  ETAMIN,
                                  ETAMAX,
                                  PHIBINS,
                                  PHIMIN,
                                  PHIMAX);
 
  rctNisoEmEff2oneD_ =
      ibooker.book1D("rctNisoEmEff2oneD", "rctNisoEmEff2oneD, energy matching required", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctNisoEmIneff2_ = ibooker.book2D("rctNisoEmIneff2",
                                    "rctNisoEmIneff2, energy matching required (source: " + dataInputTagName_ + ")",
                                    ETABINS,
                                    ETAMIN,
                                    ETAMAX,
                                    PHIBINS,
                                    PHIMIN,
                                    PHIMAX);
 
  rctNisoEmIneff2oneD_ = ibooker.book1D(
      "rctNisoEmIneff2oneD", "rctNisoEmIneff2oneD, energy matching required", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctNisoEmIneff_ = ibooker.book2D("rctNisoEmIneff",
                                   "rctNisoEmIneff (source: " + dataInputTagName_ + ")",
                                   ETABINS,
                                   ETAMIN,
                                   ETAMAX,
                                   PHIBINS,
                                   PHIMIN,
                                   PHIMAX);
 
  rctNisoEmIneff1D_ = ibooker.book1D("rctNisoEmIneff1D", "rctNisoEmIneff1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctNisoEmOvereff_ = ibooker.book2D("rctNisoEmOvereff",
                                     "rctNisoEmOvereff (source: " + dataInputTagName_ + ")",
                                     ETABINS,
                                     ETAMIN,
                                     ETAMAX,
                                     PHIBINS,
                                     PHIMIN,
                                     PHIMAX);
 
  rctNisoEmOvereff1D_ = ibooker.book1D("rctNisoEmOvereff1D", "rctNisoEmOvereff1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  ibooker.setCurrentFolder(histFolder_ + "/NisoEm/ServiceData");
 
  rctNisoEmDataOcc_ = ibooker.book2D("rctNisoEmDataOcc",
                                     "rctNisoEmDataOcc (source: " + dataInputTagName_ + ")",
                                     ETABINS,
                                     ETAMIN,
                                     ETAMAX,
                                     PHIBINS,
                                     PHIMIN,
                                     PHIMAX);
 
  rctNisoEmDataOcc1D_ = ibooker.book1D("rctNisoEmDataOcc1D", "rctNisoEmDataOcc1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctNisoEmEmulOcc_ = ibooker.book2D("rctNisoEmEmulOcc",
                                     "rctNisoEmEmulOcc (source: " + dataInputTagName_ + ")",
                                     ETABINS,
                                     ETAMIN,
                                     ETAMAX,
                                     PHIBINS,
                                     PHIMIN,
                                     PHIMAX);
 
  rctNisoEmEmulOcc1D_ = ibooker.book1D("rctNisoEmEmulOcc1D", "rctNisoEmEmulOcc1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctNisoEmEff1Occ_ = ibooker.book2D("rctNisoEmEff1Occ",
                                     "rctNisoEmEff1Occ (source: " + dataInputTagName_ + ")",
                                     ETABINS,
                                     ETAMIN,
                                     ETAMAX,
                                     PHIBINS,
                                     PHIMIN,
                                     PHIMAX);
 
  rctNisoEmEff1Occ1D_ = ibooker.book1D("rctNisoEmEff1Occ1D", "rctNisoEmEff1Occ1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctNisoEmEff2Occ_ = ibooker.book2D("rctNisoEmEff2Occ",
                                     "rctNisoEmEff2Occ (source: " + dataInputTagName_ + ")",
                                     ETABINS,
                                     ETAMIN,
                                     ETAMAX,
                                     PHIBINS,
                                     PHIMIN,
                                     PHIMAX);
 
  rctNisoEmEff2Occ1D_ = ibooker.book1D("rctNisoEmEff2Occ1D", "rctNisoEmEff2Occ1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctNisoEmIneff2Occ_ = ibooker.book2D("rctNisoEmIneff2Occ",
                                       "rctNisoEmIneff2Occ (source: " + dataInputTagName_ + ")",
                                       ETABINS,
                                       ETAMIN,
                                       ETAMAX,
                                       PHIBINS,
                                       PHIMIN,
                                       PHIMAX);
 
  rctNisoEmIneff2Occ1D_ = ibooker.book1D("rctNisoEmIneff2Occ1D", "rctNisoEmIneff2Occ1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctNisoEmIneffOcc_ = ibooker.book2D("rctNisoEmIneffOcc",
                                      "rctNisoEmIneffOcc (source: " + dataInputTagName_ + ")",
                                      ETABINS,
                                      ETAMIN,
                                      ETAMAX,
                                      PHIBINS,
                                      PHIMIN,
                                      PHIMAX);
 
  rctNisoEmIneffOcc1D_ = ibooker.book1D("rctNisoEmIneffOcc1D", "rctNisoEmIneffOcc1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctNisoEmOvereffOcc_ = ibooker.book2D("rctNisoEmOvereffOcc",
                                        "rctNisoEmOvereffOcc (source: " + dataInputTagName_ + ")",
                                        ETABINS,
                                        ETAMIN,
                                        ETAMAX,
                                        PHIBINS,
                                        PHIMIN,
                                        PHIMAX);
 
  rctNisoEmOvereffOcc1D_ = ibooker.book1D("rctNisoEmOvereffOcc1D", "rctNisoEmOvereffOcc1D", CHNLBINS, CHNLMIN, CHNLMAX);
 
  // region information
  ibooker.setCurrentFolder(histFolder_ + "/RegionData");
 
  rctRegEff1D_ = ibooker.book1D("rctRegEff1D", "1D region efficiency", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegIneff1D_ = ibooker.book1D("rctRegIneff1D", "1D region inefficiency", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegOvereff1D_ = ibooker.book1D("rctRegOvereff1D", "1D region overefficiency", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegSpEff1D_ =
      ibooker.book1D("rctRegSpEff1D", "1D region efficiency, energy matching required", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegSpIneff1D_ =
      ibooker.book1D("rctRegSpIneff1D", "1D region inefficiency, energy matching required", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegEff2D_ = ibooker.book2D("rctRegEff2D",
                                "2D region efficiency (source: " + dataInputTagName_ + ")",
                                ETABINS,
                                ETAMIN,
                                ETAMAX,
                                PHIBINS,
                                PHIMIN,
                                PHIMAX);
 
  rctRegIneff2D_ = ibooker.book2D("rctRegIneff2D",
                                  "2D region inefficiency (source: " + dataInputTagName_ + ")",
                                  ETABINS,
                                  ETAMIN,
                                  ETAMAX,
                                  PHIBINS,
                                  PHIMIN,
                                  PHIMAX);
 
  rctRegOvereff2D_ = ibooker.book2D("rctRegOvereff2D",
                                    "2D region overefficiency (source: " + dataInputTagName_ + ")",
                                    ETABINS,
                                    ETAMIN,
                                    ETAMAX,
                                    PHIBINS,
                                    PHIMIN,
                                    PHIMAX);
 
  rctRegSpEff2D_ = ibooker.book2D("rctRegSpEff2D",
                                  "2D region efficiency, energy matching required (source: " + dataInputTagName_ + ")",
                                  ETABINS,
                                  ETAMIN,
                                  ETAMAX,
                                  PHIBINS,
                                  PHIMIN,
                                  PHIMAX);
 
  rctRegSpIneff2D_ =
      ibooker.book2D("rctRegSpIneff2D",
                     "2D region inefficiency, energy matching required (source: " + dataInputTagName_ + ")",
                     ETABINS,
                     ETAMIN,
                     ETAMAX,
                     PHIBINS,
                     PHIMIN,
                     PHIMAX);
 
  ibooker.setCurrentFolder(histFolder_ + "/RegionData/ServiceData");
 
  rctRegDataOcc1D_ = ibooker.book1D("rctRegDataOcc1D", "1D region occupancy from data", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegEmulOcc1D_ = ibooker.book1D("rctRegEmulOcc1D", "1D region occupancy from emulator", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegMatchedOcc1D_ =
      ibooker.book1D("rctRegMatchedOcc1D", "1D region occupancy for matched hits", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegUnmatchedDataOcc1D_ = ibooker.book1D(
      "rctRegUnmatchedDataOcc1D", "1D region occupancy for unmatched hardware hits", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegUnmatchedEmulOcc1D_ = ibooker.book1D(
      "rctRegUnmatchedEmulOcc1D", "1D region occupancy for unmatched emulator hits", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegSpEffOcc1D_ = ibooker.book1D(
      "rctRegSpEffOcc1D", "1D region occupancy for \\Delta E_{T} efficiency", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegSpIneffOcc1D_ = ibooker.book1D(
      "rctRegSpIneffOcc1D", "1D region occupancy for \\Delta E_{T} efficiency ", CHNLBINS, CHNLMIN, CHNLMAX);
 
  rctRegDataOcc2D_ = ibooker.book2D("rctRegDataOcc2D",
                                    "2D region occupancy from hardware (source: " + dataInputTagName_ + ")",
                                    ETABINS,
                                    ETAMIN,
                                    ETAMAX,
                                    PHIBINS,
                                    PHIMIN,
                                    PHIMAX);
 
  rctRegEmulOcc2D_ = ibooker.book2D(
      "rctRegEmulOcc2D", "2D region occupancy from emulator", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctRegMatchedOcc2D_ = ibooker.book2D(
      "rctRegMatchedOcc2D", "2D region occupancy for matched hits", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctRegUnmatchedDataOcc2D_ = ibooker.book2D("rctRegUnmatchedDataOcc2D",
                                             "2D region occupancy for unmatched hardware hits",
                                             ETABINS,
                                             ETAMIN,
                                             ETAMAX,
                                             PHIBINS,
                                             PHIMIN,
                                             PHIMAX);
 
  rctRegUnmatchedEmulOcc2D_ = ibooker.book2D("rctRegUnmatchedEmulOcc2D",
                                             "2D region occupancy for unmatched emulator hits",
                                             ETABINS,
                                             ETAMIN,
                                             ETAMAX,
                                             PHIBINS,
                                             PHIMIN,
                                             PHIMAX);
 
  //    rctRegDeltaEt2D_ =
  //      dbe->book2D("rctRegDeltaEt2D", " \\Delta E_{T}  for each channel",
  //      CHNLBINS, CHNLMIN, CHNLMAX, 100, -50., 50.);
 
  rctRegSpEffOcc2D_ = ibooker.book2D("rctRegSpEffOcc2D",
                                     "2D region occupancy for \\Delta E_{T} efficiency",
                                     ETABINS,
                                     ETAMIN,
                                     ETAMAX,
                                     PHIBINS,
                                     PHIMIN,
                                     PHIMAX);
 
  rctRegSpIneffOcc2D_ = ibooker.book2D("rctRegSpIneffOcc2D",
                                       "2D region occupancy for \\Delta E_{T} inefficiency",
                                       ETABINS,
                                       ETAMIN,
                                       ETAMAX,
                                       PHIBINS,
                                       PHIMIN,
                                       PHIMAX);
 
  // bit information
  ibooker.setCurrentFolder(histFolder_ + "/BitData");
 
  rctBitOverFlowEff2D_ = ibooker.book2D("rctBitOverFlowEff2D",
                                        "2D overflow bit efficiency (source: " + dataInputTagName_ + ")",
                                        ETABINS,
                                        ETAMIN,
                                        ETAMAX,
                                        PHIBINS,
                                        PHIMIN,
                                        PHIMAX);
 
  rctBitOverFlowIneff2D_ = ibooker.book2D("rctBitOverFlowIneff2D",
                                          "2D overflow bit inefficiency (source: " + dataInputTagName_ + ")",
                                          ETABINS,
                                          ETAMIN,
                                          ETAMAX,
                                          PHIBINS,
                                          PHIMIN,
                                          PHIMAX);
 
  rctBitOverFlowOvereff2D_ = ibooker.book2D("rctBitOverFlowOvereff2D",
                                            "2D overflow bit overefficiency (source: " + dataInputTagName_ + ")",
                                            ETABINS,
                                            ETAMIN,
                                            ETAMAX,
                                            PHIBINS,
                                            PHIMIN,
                                            PHIMAX);
 
  rctBitTauVetoEff2D_ = ibooker.book2D("rctBitTauVetoEff2D",
                                       "2D tau veto bit efficiency (source: " + dataInputTagName_ + ")",
                                       ETABINS,
                                       ETAMIN,
                                       ETAMAX,
                                       PHIBINS,
                                       PHIMIN,
                                       PHIMAX);
 
  rctBitTauVetoIneff2D_ = ibooker.book2D("rctBitTauVetoIneff2D",
                                         "2D tau veto bit inefficiency (source: " + dataInputTagName_ + ")",
                                         ETABINS,
                                         ETAMIN,
                                         ETAMAX,
                                         PHIBINS,
                                         PHIMIN,
                                         PHIMAX);
 
  rctBitTauVetoOvereff2D_ = ibooker.book2D("rctBitTauVetoOvereff2D",
                                           "2D tau veto bit overefficiency (source: " + dataInputTagName_ + ")",
                                           ETABINS,
                                           ETAMIN,
                                           ETAMAX,
                                           PHIBINS,
                                           PHIMIN,
                                           PHIMAX);
 
  rctBitMipEff2D_ =
      ibooker.book2D("rctBitMipEff2D", "2D mip bit efficiency", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitMipIneff2D_ =
      ibooker.book2D("rctBitMipIneff2D", "2D mip bit inefficiency", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitMipOvereff2D_ = ibooker.book2D(
      "rctBitMipOvereff2D", "2D mip bit overefficiency", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  // QUIETBIT: To add quiet bit information, uncomment following 11 lines:
  // rctBitQuietEff2D_ =
  // dbe->book2D("rctBitQuietEff2D", "2D quiet bit efficiency",
  // ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  // rctBitQuietIneff2D_ =
  // dbe->book2D("rctBitQuietIneff2D", "2D quiet bit inefficiency",
  // ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  // rctBitQuietOvereff2D_ =
  // dbe->book2D("rctBitQuietOvereff2D", "2D quiet bit overefficiency",
  // ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitHfPlusTauEff2D_ = ibooker.book2D("rctBitHfPlusTauEff2D",
                                         "2D HfPlusTau bit efficiency (source: " + dataInputTagName_ + ")",
                                         ETABINS,
                                         ETAMIN,
                                         ETAMAX,
                                         PHIBINS,
                                         PHIMIN,
                                         PHIMAX);
 
  rctBitHfPlusTauIneff2D_ = ibooker.book2D("rctBitHfPlusTauIneff2D",
                                           "2D HfPlusTau bit inefficiency (source: " + dataInputTagName_ + ")",
                                           ETABINS,
                                           ETAMIN,
                                           ETAMAX,
                                           PHIBINS,
                                           PHIMIN,
                                           PHIMAX);
 
  rctBitHfPlusTauOvereff2D_ = ibooker.book2D("rctBitHfPlusTauOvereff2D",
                                             "2D HfPlusTau bit overefficiency (source: " + dataInputTagName_ + ")",
                                             ETABINS,
                                             ETAMIN,
                                             ETAMAX,
                                             PHIBINS,
                                             PHIMIN,
                                             PHIMAX);
 
  ibooker.setCurrentFolder(histFolder_ + "/BitData/ServiceData");
 
  rctBitEmulOverFlow2D_ = ibooker.book2D(
      "rctBitEmulOverFlow2D", "2D overflow bit from emulator", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitDataOverFlow2D_ = ibooker.book2D("rctBitDataOverFlow2D",
                                         "2D overflow bit from hardware (source: " + dataInputTagName_ + ")",
                                         ETABINS,
                                         ETAMIN,
                                         ETAMAX,
                                         PHIBINS,
                                         PHIMIN,
                                         PHIMAX);
 
  rctBitMatchedOverFlow2D_ = ibooker.book2D(
      "rctBitMatchedOverFlow2D", "2D overflow bit for matched hits", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitUnmatchedEmulOverFlow2D_ = ibooker.book2D("rctBitUnmatchedEmulOverFlow2D",
                                                  "2D overflow bit for unmatched emulator hits",
                                                  ETABINS,
                                                  ETAMIN,
                                                  ETAMAX,
                                                  PHIBINS,
                                                  PHIMIN,
                                                  PHIMAX);
 
  rctBitUnmatchedDataOverFlow2D_ = ibooker.book2D("rctBitUnmatchedDataOverFlow2D",
                                                  "2D overflow bit for unmatched hardware hits",
                                                  ETABINS,
                                                  ETAMIN,
                                                  ETAMAX,
                                                  PHIBINS,
                                                  PHIMIN,
                                                  PHIMAX);
 
  rctBitEmulTauVeto2D_ = ibooker.book2D(
      "rctBitEmulTauVeto2D", "2D tau veto bit from emulator", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitDataTauVeto2D_ = ibooker.book2D("rctBitDataTauVeto2D",
                                        "2D tau veto bit from hardware (source: " + dataInputTagName_ + ")",
                                        ETABINS,
                                        ETAMIN,
                                        ETAMAX,
                                        PHIBINS,
                                        PHIMIN,
                                        PHIMAX);
 
  rctBitMatchedTauVeto2D_ = ibooker.book2D(
      "rctBitMatchedTauVeto2D", "2D tau veto bit for matched hits", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitUnmatchedEmulTauVeto2D_ = ibooker.book2D("rctBitUnmatchedEmulTauVeto2D",
                                                 "2D tau veto bit for unmatched emulator hits",
                                                 ETABINS,
                                                 ETAMIN,
                                                 ETAMAX,
                                                 PHIBINS,
                                                 PHIMIN,
                                                 PHIMAX);
 
  rctBitUnmatchedDataTauVeto2D_ = ibooker.book2D("rctBitUnmatchedDataTauVeto2D",
                                                 "2D tau veto bit for unmatched hardware hits",
                                                 ETABINS,
                                                 ETAMIN,
                                                 ETAMAX,
                                                 PHIBINS,
                                                 PHIMIN,
                                                 PHIMAX);
 
  rctBitEmulMip2D_ =
      ibooker.book2D("rctBitEmulMip2D", "2D mip bit from emulator", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitDataMip2D_ =
      ibooker.book2D("rctBitDataMip2D", "2D mip bit from hardware", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitMatchedMip2D_ = ibooker.book2D(
      "rctBitMatchedMip2D", "2D mip bit for matched hits", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitUnmatchedEmulMip2D_ = ibooker.book2D("rctBitUnmatchedEmulMip2D",
                                             "2D mip bit for unmatched emulator hits",
                                             ETABINS,
                                             ETAMIN,
                                             ETAMAX,
                                             PHIBINS,
                                             PHIMIN,
                                             PHIMAX);
 
  rctBitUnmatchedDataMip2D_ = ibooker.book2D("rctBitUnmatchedDataMip2D",
                                             "2D mip bit for unmatched hardware hits",
                                             ETABINS,
                                             ETAMIN,
                                             ETAMAX,
                                             PHIBINS,
                                             PHIMIN,
                                             PHIMAX);
 
  rctBitEmulQuiet2D_ = ibooker.book2D(
      "rctBitEmulQuiet2D", "2D quiet bit from emulator", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitDataQuiet2D_ = ibooker.book2D(
      "rctBitDataQuiet2D", "2D quiet bit from hardware", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitMatchedQuiet2D_ = ibooker.book2D(
      "rctBitMatchedQuiet2D", "2D quiet bit for matched hits", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitUnmatchedEmulQuiet2D_ = ibooker.book2D("rctBitUnmatchedEmulQuiet2D",
                                               "2D quiet bit for unmatched emulator hits",
                                               ETABINS,
                                               ETAMIN,
                                               ETAMAX,
                                               PHIBINS,
                                               PHIMIN,
                                               PHIMAX);
 
  rctBitUnmatchedDataQuiet2D_ = ibooker.book2D("rctBitUnmatchedDataQuiet2D",
                                               "2D quiet bit for unmatched hardware hits",
                                               ETABINS,
                                               ETAMIN,
                                               ETAMAX,
                                               PHIBINS,
                                               PHIMIN,
                                               PHIMAX);
 
  rctBitEmulHfPlusTau2D_ = ibooker.book2D(
      "rctBitEmulHfPlusTau2D", "2D HfPlusTau bit from emulator", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitDataHfPlusTau2D_ = ibooker.book2D("rctBitDataHfPlusTau2D",
                                          "2D HfPlusTau bit from hardware (source: " + dataInputTagName_ + ")",
                                          ETABINS,
                                          ETAMIN,
                                          ETAMAX,
                                          PHIBINS,
                                          PHIMIN,
                                          PHIMAX);
 
  rctBitMatchedHfPlusTau2D_ = ibooker.book2D(
      "rctBitMatchedHfPlusTau2D", "2D HfPlusTau bit for matched hits", ETABINS, ETAMIN, ETAMAX, PHIBINS, PHIMIN, PHIMAX);
 
  rctBitUnmatchedEmulHfPlusTau2D_ = ibooker.book2D("rctBitUnmatchedEmulHfPlusTau2D",
                                                   "2D HfPlusTau bit for unmatched emulator hits",
                                                   ETABINS,
                                                   ETAMIN,
                                                   ETAMAX,
                                                   PHIBINS,
                                                   PHIMIN,
                                                   PHIMAX);
 
  rctBitUnmatchedDataHfPlusTau2D_ = ibooker.book2D("rctBitUnmatchedDataHfPlusTau2D",
                                                   "2D HfPlusTau bit for unmatched hardware hits",
                                                   ETABINS,
                                                   ETAMIN,
                                                   ETAMAX,
                                                   PHIBINS,
                                                   PHIMIN,
                                                   PHIMAX);
 
  ibooker.setCurrentFolder(histFolder_ + "/BitMon");
  rctRegBitOn_ = ibooker.book2D("rctRegBitOn",
                                "Monitoring for Bits Stuck On",
                                BITETABINS,
                                BITETAMIN,
                                BITETAMAX,
                                BITRPHIBINS,
                                BITRPHIMIN,
                                BITRPHIMAX);
 
  rctRegBitOff_ = ibooker.book2D("rctRegBitOff",
                                 "Monitoring for Bits Stuck Off",
                                 BITETABINS,
                                 BITETAMIN,
                                 BITETAMAX,
                                 BITRPHIBINS,
                                 BITRPHIMIN,
                                 BITRPHIMAX);
 
  rctRegBitDiff_ = ibooker.book2D("rctRegBitDiff",
                                  "Monitoring for Bits Difference",
                                  BITETABINS,
                                  BITETAMIN,
                                  BITETAMAX,
                                  BITRPHIBINS,
                                  BITRPHIMIN,
                                  BITRPHIMAX);
 
  rctIsoEmBitOn_ = ibooker.book2D("rctIsoEmBitOn",
                                  "Monitoring for Bits Stuck On",
                                  BITETABINS,
                                  BITETAMIN,
                                  BITETAMAX,
                                  BITPHIBINS,
                                  BITPHIMIN,
                                  BITPHIMAX);
 
  rctIsoEmBitOff_ = ibooker.book2D("rctIsoEmBitOff",
                                   "Monitoring for Bits Stuck Off",
                                   BITETABINS,
                                   BITETAMIN,
                                   BITETAMAX,
                                   BITPHIBINS,
                                   BITPHIMIN,
                                   BITPHIMAX);
 
  rctIsoEmBitDiff_ = ibooker.book2D("rctIsoEmBitDiff",
                                    "Monitoring for Bits Difference",
                                    BITETABINS,
                                    BITETAMIN,
                                    BITETAMAX,
                                    BITPHIBINS,
                                    BITPHIMIN,
                                    BITPHIMAX);
 
  rctNIsoEmBitOn_ = ibooker.book2D("rctNIsoEmBitOn",
                                   "Monitoring for Bits Stuck On",
                                   BITETABINS,
                                   BITETAMIN,
                                   BITETAMAX,
                                   BITPHIBINS,
                                   BITPHIMIN,
                                   BITPHIMAX);
 
  rctNIsoEmBitOff_ = ibooker.book2D("rctNIsoEmBitOff",
                                    "Monitoring for Bits Stuck Off",
                                    BITETABINS,
                                    BITETAMIN,
                                    BITETAMAX,
                                    BITPHIBINS,
                                    BITPHIMIN,
                                    BITPHIMAX);
 
  rctNIsoEmBitDiff_ = ibooker.book2D("rctNIsoEmBitDiff",
                                     "Monitoring for Bits Difference",
                                     BITETABINS,
                                     BITETAMIN,
                                     BITETAMAX,
                                     BITPHIBINS,
                                     BITPHIMIN,
                                     BITPHIMAX);
 
  ibooker.setCurrentFolder(histFolder_ + "/DBData");
  fedVectorMonitorRUN_ = ibooker.book2D("rctFedVectorMonitorRUN", "FED Vector Monitor Per Run", 108, 0, 108, 2, 0, 2);
  fedVectorMonitorLS_ = ibooker.book2D("rctFedVectorMonitorLS", "FED Vector Monitor Per LS", 108, 0, 108, 2, 0, 2);
 
  for (unsigned int i = 0; i < 108; ++i) {
    char fed[10];
    sprintf(fed, "%d", crateFED[i]);
    fedVectorMonitorRUN_->setBinLabel(i + 1, fed);
    fedVectorMonitorLS_->setBinLabel(i + 1, fed);
  }
  fedVectorMonitorRUN_->getTH2F()->GetYaxis()->SetBinLabel(1, "OUT");
  fedVectorMonitorRUN_->getTH2F()->GetYaxis()->SetBinLabel(2, "IN");
  fedVectorMonitorLS_->getTH2F()->GetYaxis()->SetBinLabel(1, "OUT");
  fedVectorMonitorLS_->getTH2F()->GetYaxis()->SetBinLabel(2, "IN");
 
  // for single channels
 
  if (singlechannelhistos_) {
    for (int m = 0; m < 12; m++) {
      if (m == 0)
        ibooker.setCurrentFolder(histFolder_ + "/IsoEm/ServiceData/Eff1SnglChnls");
      if (m == 1)
        ibooker.setCurrentFolder(histFolder_ + "/NisoEm/ServiceData/Eff1SnglChnls");
      if (m == 2)
        ibooker.setCurrentFolder(histFolder_ + "/RegionData/ServiceData/EffSnglChnls");
      if (m == 3)
        ibooker.setCurrentFolder(histFolder_ + "/IsoEm/ServiceData/IneffSnglChnls");
      if (m == 4)
        ibooker.setCurrentFolder(histFolder_ + "/NisoEm/ServiceData/IneffSnglChnls");
      if (m == 5)
        ibooker.setCurrentFolder(histFolder_ + "/RegionData/ServiceData/IneffSnglChnls");
      if (m == 6)
        ibooker.setCurrentFolder(histFolder_ + "/IsoEm/ServiceData/OvereffSnglChnls");
      if (m == 7)
        ibooker.setCurrentFolder(histFolder_ + "/NisoEm/ServiceData/OvereffSnglChnls");
      if (m == 8)
        ibooker.setCurrentFolder(histFolder_ + "/RegionData/ServiceData/OvereffSnglChnls");
      if (m == 9)
        ibooker.setCurrentFolder(histFolder_ + "/EffCurves/NisoEm/ServiceData/SingleChannels");
      if (m == 10)
        ibooker.setCurrentFolder(histFolder_ + "/EffCurves/NisoEm/ServiceData/SingleChannels");
      if (m == 11)
        ibooker.setCurrentFolder(histFolder_ + "/EffCurves/NisoEm/ServiceData/SingleChannels");
 
      for (int i = 0; i < ETAMAX; i++) {
        for (int j = 0; j < PHIMAX; j++) {
          char name[80], channel[80] = {""};
 
          if (m == 0)
            strcpy(name, "(Eemul-Edata)Chnl");
          if (m == 1)
            strcpy(name, "(Eemul-Edata)Chnl");
          if (m == 2)
            strcpy(name, "(Eemul-Edata)Chnl");
          if (m == 3)
            strcpy(name, "EemulChnl");
          if (m == 4)
            strcpy(name, "EemulChnl");
          if (m == 5)
            strcpy(name, "EemulChnl");
          if (m == 6)
            strcpy(name, "EdataChnl");
          if (m == 7)
            strcpy(name, "EdataChnl");
          if (m == 8)
            strcpy(name, "EdataChnl");
          if (m == 9)
            strcpy(name, "EemulChnlEff");
          if (m == 10)
            strcpy(name, "EemulChnlTrig");
          if (m == 11)
            strcpy(name, "EemulChnl");
 
          if (i < 10 && j < 10)
            sprintf(channel, "_0%d0%d", i, j);
          else if (i < 10)
            sprintf(channel, "_0%d%d", i, j);
          else if (j < 10)
            sprintf(channel, "_%d0%d", i, j);
          else
            sprintf(channel, "_%d%d", i, j);
          strcat(name, channel);
 
          int chnl = PHIBINS * i + j;
 
          if (m == 0)
            rctIsoEffChannel_[chnl] = ibooker.book1D(name, name, DEBINS, DEMIN, DEMAX);
          if (m == 1)
            rctNisoEffChannel_[chnl] = ibooker.book1D(name, name, DEBINS, DEMIN, DEMAX);
          if (m == 2)
            rctRegEffChannel_[chnl] = ibooker.book1D(name, name, DEBINS, DEMIN, DEMAX);
          if (m == 3)
            rctIsoIneffChannel_[chnl] = ibooker.book1D(name, name, DEBINS, DEMIN, DEMAX);
          if (m == 4)
            rctNisoIneffChannel_[chnl] = ibooker.book1D(name, name, DEBINS, DEMIN, DEMAX);
          if (m == 5)
            rctRegIneffChannel_[chnl] = ibooker.book1D(name, name, DEBINS, DEMIN, DEMAX);
          if (m == 6)
            rctIsoOvereffChannel_[chnl] = ibooker.book1D(name, name, DEBINS, DEMIN, DEMAX);
          if (m == 7)
            rctNisoOvereffChannel_[chnl] = ibooker.book1D(name, name, DEBINS, DEMIN, DEMAX);
          if (m == 8)
            rctRegOvereffChannel_[chnl] = ibooker.book1D(name, name, DEBINS, DEMIN, DEMAX);
          if (m == 9)
            trigEff_[chnl] = ibooker.book1D(name, name, ELBINS, ELMIN, ELMAX);
          if (m == 10)
            trigEffOcc_[chnl] = ibooker.book1D(name, name, ELBINS, ELMIN, ELMAX);
          if (m == 11)
            trigEffTriggOcc_[chnl] = ibooker.book1D(name, name, ELBINS, ELMIN, ELMAX);
        }
      }
    }
  }
 
  //end of single channels
 
  notrigCount = 0;
  trigCount = 0;
 
  readFEDVector(fedVectorMonitorRUN_, es);
}

References crateFED, dataInputTagName_, ETABINS, ETAMAX, ETAMIN, fedVectorMonitorLS_, fedVectorMonitorRUN_, dqm::impl::MonitorElement::getTH2F(), histFolder_, mps_fire::i, dqmiolumiharvest::j, visualization-live-secondInstance_cfg::m, Skims_PA_cff::name, nev_, notrigCount, PHIBINS, PHIMAX, PHIMIN, rctBitDataHfPlusTau2D_, rctBitDataMip2D_, rctBitDataOverFlow2D_, rctBitDataQuiet2D_, rctBitDataTauVeto2D_, rctBitEmulHfPlusTau2D_, rctBitEmulMip2D_, rctBitEmulOverFlow2D_, rctBitEmulQuiet2D_, rctBitEmulTauVeto2D_, rctBitHfPlusTauEff2D_, rctBitHfPlusTauIneff2D_, rctBitHfPlusTauOvereff2D_, rctBitMatchedHfPlusTau2D_, rctBitMatchedMip2D_, rctBitMatchedOverFlow2D_, rctBitMatchedQuiet2D_, rctBitMatchedTauVeto2D_, rctBitMipEff2D_, rctBitMipIneff2D_, rctBitMipOvereff2D_, rctBitOverFlowEff2D_, rctBitOverFlowIneff2D_, rctBitOverFlowOvereff2D_, rctBitTauVetoEff2D_, rctBitTauVetoIneff2D_, rctBitTauVetoOvereff2D_, rctBitUnmatchedDataHfPlusTau2D_, rctBitUnmatchedDataMip2D_, rctBitUnmatchedDataOverFlow2D_, rctBitUnmatchedDataQuiet2D_, rctBitUnmatchedDataTauVeto2D_, rctBitUnmatchedEmulHfPlusTau2D_, rctBitUnmatchedEmulMip2D_, rctBitUnmatchedEmulOverFlow2D_, rctBitUnmatchedEmulQuiet2D_, rctBitUnmatchedEmulTauVeto2D_, rctInputTPGEcalOcc_, rctInputTPGEcalOccNoCut_, rctInputTPGEcalRank_, rctInputTPGHcalOcc_, rctInputTPGHcalRank_, rctInputTPGHcalSample_, rctIsoEffChannel_, rctIsoEmBitDiff_, rctIsoEmBitOff_, rctIsoEmBitOn_, rctIsoEmDataOcc1D_, rctIsoEmDataOcc_, rctIsoEmEff1_, rctIsoEmEff1Occ1D_, rctIsoEmEff1Occ_, rctIsoEmEff1oneD_, rctIsoEmEff2_, rctIsoEmEff2Occ1D_, rctIsoEmEff2Occ_, rctIsoEmEff2oneD_, rctIsoEmEmulOcc1D_, rctIsoEmEmulOcc_, rctIsoEmIneff1D_, rctIsoEmIneff2_, rctIsoEmIneff2Occ1D_, rctIsoEmIneff2Occ_, rctIsoEmIneff2oneD_, rctIsoEmIneff_, rctIsoEmIneffOcc1D_, rctIsoEmIneffOcc_, rctIsoEmOvereff1D_, rctIsoEmOvereff_, rctIsoEmOvereffOcc1D_, rctIsoEmOvereffOcc_, rctIsoIneffChannel_, rctIsoOvereffChannel_, rctNisoEffChannel_, rctNIsoEmBitDiff_, rctNIsoEmBitOff_, rctNIsoEmBitOn_, rctNisoEmDataOcc1D_, rctNisoEmDataOcc_, rctNisoEmEff1_, rctNisoEmEff1Occ1D_, rctNisoEmEff1Occ_, rctNisoEmEff1oneD_, rctNisoEmEff2_, rctNisoEmEff2Occ1D_, rctNisoEmEff2Occ_, rctNisoEmEff2oneD_, rctNisoEmEmulOcc1D_, rctNisoEmEmulOcc_, rctNisoEmIneff1D_, rctNisoEmIneff2_, rctNisoEmIneff2Occ1D_, rctNisoEmIneff2Occ_, rctNisoEmIneff2oneD_, rctNisoEmIneff_, rctNisoEmIneffOcc1D_, rctNisoEmIneffOcc_, rctNisoEmOvereff1D_, rctNisoEmOvereff_, rctNisoEmOvereffOcc1D_, rctNisoEmOvereffOcc_, rctNisoIneffChannel_, rctNisoOvereffChannel_, rctRegBitDiff_, rctRegBitOff_, rctRegBitOn_, rctRegDataOcc1D_, rctRegDataOcc2D_, rctRegEff1D_, rctRegEff2D_, rctRegEffChannel_, rctRegEmulOcc1D_, rctRegEmulOcc2D_, rctRegIneff1D_, rctRegIneff2D_, rctRegIneffChannel_, rctRegMatchedOcc1D_, rctRegMatchedOcc2D_, rctRegOvereff1D_, rctRegOvereff2D_, rctRegOvereffChannel_, rctRegSpEff1D_, rctRegSpEff2D_, rctRegSpEffOcc1D_, rctRegSpEffOcc2D_, rctRegSpIneff1D_, rctRegSpIneff2D_, rctRegSpIneffOcc1D_, rctRegSpIneffOcc2D_, rctRegUnmatchedDataOcc1D_, rctRegUnmatchedDataOcc2D_, rctRegUnmatchedEmulOcc1D_, rctRegUnmatchedEmulOcc2D_, readFEDVector(), dqm::impl::MonitorElement::setBinLabel(), singlechannelhistos_, trigCount, trigEff_, trigEffOcc_, trigEffThresh_, trigEffThreshOcc_, trigEffTriggOcc_, trigEffTriggThreshOcc_, triggerAlgoNumbers_, and triggerType_.

DivideME1D()

void L1TdeRCT::DivideME1D ( MonitorElement *  numerator, MonitorElement *  denominator, MonitorElement *  result  )

protected

Definition at line 1126 of file L1TdeRCT.cc.

                                                                                                        {
  TH1F* num = numerator->getTH1F();
  TH1F* den = denominator->getTH1F();
  TH1F* res = result->getTH1F();
 
  res->Divide(num, den, 1, 1, "");
}

References HLTTauDQMOffline_cfi::denominator, EgammaValidation_cff::num, HLTTauDQMOffline_cfi::numerator, and mps_fire::result.

Referenced by analyze().

DivideME2D()

void L1TdeRCT::DivideME2D ( MonitorElement *  numerator, MonitorElement *  denominator, MonitorElement *  result  )

protected

Definition at line 1118 of file L1TdeRCT.cc.

                                                                                                        {
  TH2F* num = numerator->getTH2F();
  TH2F* den = denominator->getTH2F();
  TH2F* res = result->getTH2F();
 
  res->Divide(num, den, 1, 1, "");
}

References HLTTauDQMOffline_cfi::denominator, EgammaValidation_cff::num, HLTTauDQMOffline_cfi::numerator, and mps_fire::result.

Referenced by analyze().

globalBeginLuminosityBlock()

std::shared_ptr< l1tderct::Empty > L1TdeRCT::globalBeginLuminosityBlock ( const edm::LuminosityBlock &  ls, const edm::EventSetup &  es  ) const

overrideprotected

Definition at line 2082 of file L1TdeRCT.cc.

                                                                                                     {
  readFEDVector(fedVectorMonitorLS_, es);
  return std::shared_ptr<l1tderct::Empty>();
}

References fedVectorMonitorLS_, and readFEDVector().

globalEndLuminosityBlock()

void L1TdeRCT::globalEndLuminosityBlock ( const edm::LuminosityBlock &  , const edm::EventSetup &    )

inlinefinalprotected

Definition at line 65 of file L1TdeRCT.h.

{}

readFEDVector()

void L1TdeRCT::readFEDVector ( MonitorElement *  histogram, const edm::EventSetup &  es  ) const

protected

Definition at line 2088 of file L1TdeRCT.cc.

                                                                                     {
  // adding fed mask into channel mask
  edm::ESHandle<RunInfo> sum;
  es.get<RunInfoRcd>().get(sum);
  const RunInfo* summary = sum.product();
 
  std::vector<int> caloFeds;  // pare down the feds to the intresting ones
 
  const std::vector<int> Feds = summary->m_fed_in;
  for (std::vector<int>::const_iterator cf = Feds.begin(); cf != Feds.end(); ++cf) {
    int fedNum = *cf;
    if ((fedNum > 600 && fedNum < 724) || fedNum == 1118 || fedNum == 1120 || fedNum == 1122)
      caloFeds.push_back(fedNum);
  }
 
  for (unsigned int i = 0; i < 108; ++i) {
    std::vector<int>::iterator fv = std::find(caloFeds.begin(), caloFeds.end(), crateFED[i]);
    if (fv != caloFeds.end()) {
      histogram->setBinContent(i + 1, 2, 1);
      histogram->setBinContent(i + 1, 1, 0);
    } else {
      histogram->setBinContent(i + 1, 2, 0);
      histogram->setBinContent(i + 1, 1, 1);
    }
  }
}

References crateFED, spr::find(), edm::EventSetup::get(), get, mps_fire::i, edm::ESHandle< T >::product(), dqm::impl::MonitorElement::setBinContent(), and edmLumisInFiles::summary.

Referenced by bookHistograms(), and globalBeginLuminosityBlock().

Member Data Documentation

crateFED

const int L1TdeRCT::crateFED

staticprivate

Initial value:

= {
    613, 614, 603, 702, 718, 1118, 611, 612, 602, 700, 718, 1118, 627, 610, 601, 716, 722, 1122,
    625, 626, 609, 714, 722, 1122, 623, 624, 608, 712, 722, 1122, 621, 622, 607, 710, 720, 1120,
    619, 620, 606, 708, 720, 1120, 617, 618, 605, 706, 720, 1120, 615, 616, 604, 704, 718, 1118,
    631, 632, 648, 703, 719, 1118, 629, 630, 647, 701, 719, 1118, 645, 628, 646, 717, 723, 1122,
    643, 644, 654, 715, 723, 1122, 641, 642, 653, 713, 723, 1122, 639, 640, 652, 711, 721, 1120,
    637, 638, 651, 709, 721, 1120, 635, 636, 650, 707, 721, 1120, 633, 634, 649, 705, 719, 1118}

Definition at line 249 of file L1TdeRCT.h.

Referenced by bookHistograms(), and readFEDVector().

dataInputTagName_

std::string L1TdeRCT::dataInputTagName_

private

Definition at line 275 of file L1TdeRCT.h.

Referenced by bookHistograms().

doubleThreshold_

int L1TdeRCT::doubleThreshold_

private

Definition at line 269 of file L1TdeRCT.h.

Referenced by analyze().

ecalTPGData_

edm::EDGetTokenT<EcalTrigPrimDigiCollection> L1TdeRCT::ecalTPGData_

private

Definition at line 265 of file L1TdeRCT.h.

Referenced by analyze().

fedVectorMonitorLS_

MonitorElement* L1TdeRCT::fedVectorMonitorLS_

private

Definition at line 251 of file L1TdeRCT.h.

Referenced by bookHistograms(), and globalBeginLuminosityBlock().

fedVectorMonitorRUN_

MonitorElement* L1TdeRCT::fedVectorMonitorRUN_

private

Definition at line 250 of file L1TdeRCT.h.

Referenced by bookHistograms().

filterTriggerType_

int L1TdeRCT::filterTriggerType_

private

filter TriggerType

Definition at line 272 of file L1TdeRCT.h.

Referenced by analyze().

gctSourceData_emData_

edm::EDGetTokenT<L1CaloEmCollection> L1TdeRCT::gctSourceData_emData_

private

Definition at line 264 of file L1TdeRCT.h.

gctSourceData_rgnData_

edm::EDGetTokenT<L1CaloRegionCollection> L1TdeRCT::gctSourceData_rgnData_

private

Definition at line 263 of file L1TdeRCT.h.

gtDigisLabel_

edm::EDGetTokenT<L1GlobalTriggerReadoutRecord> L1TdeRCT::gtDigisLabel_

private

Definition at line 267 of file L1TdeRCT.h.

Referenced by analyze().

gtEGAlgoName_

std::string L1TdeRCT::gtEGAlgoName_

private

Definition at line 268 of file L1TdeRCT.h.

Referenced by analyze().

hcalTPGData_

edm::EDGetTokenT<HcalTrigPrimDigiCollection> L1TdeRCT::hcalTPGData_

private

Definition at line 266 of file L1TdeRCT.h.

Referenced by analyze().

histFolder_

std::string L1TdeRCT::histFolder_

private

Definition at line 255 of file L1TdeRCT.h.

Referenced by bookHistograms(), and L1TdeRCT().

nev_

int L1TdeRCT::nev_

private

Definition at line 254 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

notrigCount

int L1TdeRCT::notrigCount

private

Definition at line 277 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitDataHfPlusTau2D_

MonitorElement* L1TdeRCT::rctBitDataHfPlusTau2D_

private

Definition at line 148 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitDataMip2D_

MonitorElement* L1TdeRCT::rctBitDataMip2D_

private

Definition at line 131 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitDataOverFlow2D_

MonitorElement* L1TdeRCT::rctBitDataOverFlow2D_

private

Definition at line 115 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitDataQuiet2D_

MonitorElement* L1TdeRCT::rctBitDataQuiet2D_

private

Definition at line 139 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitDataTauVeto2D_

MonitorElement* L1TdeRCT::rctBitDataTauVeto2D_

private

Definition at line 123 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitEmulHfPlusTau2D_

MonitorElement* L1TdeRCT::rctBitEmulHfPlusTau2D_

private

Definition at line 147 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitEmulMip2D_

MonitorElement* L1TdeRCT::rctBitEmulMip2D_

private

Definition at line 130 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitEmulOverFlow2D_

MonitorElement* L1TdeRCT::rctBitEmulOverFlow2D_

private

Definition at line 114 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitEmulQuiet2D_

MonitorElement* L1TdeRCT::rctBitEmulQuiet2D_

private

Definition at line 138 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitEmulTauVeto2D_

MonitorElement* L1TdeRCT::rctBitEmulTauVeto2D_

private

Definition at line 122 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitHfPlusTauEff2D_

MonitorElement* L1TdeRCT::rctBitHfPlusTauEff2D_

private

Definition at line 152 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitHfPlusTauIneff2D_

MonitorElement* L1TdeRCT::rctBitHfPlusTauIneff2D_

private

Definition at line 153 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitHfPlusTauOvereff2D_

MonitorElement* L1TdeRCT::rctBitHfPlusTauOvereff2D_

private

Definition at line 154 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitMatchedHfPlusTau2D_

MonitorElement* L1TdeRCT::rctBitMatchedHfPlusTau2D_

private

Definition at line 149 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitMatchedMip2D_

MonitorElement* L1TdeRCT::rctBitMatchedMip2D_

private

Definition at line 132 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitMatchedOverFlow2D_

MonitorElement* L1TdeRCT::rctBitMatchedOverFlow2D_

private

Definition at line 116 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitMatchedQuiet2D_

MonitorElement* L1TdeRCT::rctBitMatchedQuiet2D_

private

Definition at line 140 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitMatchedTauVeto2D_

MonitorElement* L1TdeRCT::rctBitMatchedTauVeto2D_

private

Definition at line 124 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitMipEff2D_

MonitorElement* L1TdeRCT::rctBitMipEff2D_

private

Definition at line 135 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitMipIneff2D_

MonitorElement* L1TdeRCT::rctBitMipIneff2D_

private

Definition at line 136 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitMipOvereff2D_

MonitorElement* L1TdeRCT::rctBitMipOvereff2D_

private

Definition at line 137 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitOverFlowEff2D_

MonitorElement* L1TdeRCT::rctBitOverFlowEff2D_

private

Definition at line 119 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitOverFlowIneff2D_

MonitorElement* L1TdeRCT::rctBitOverFlowIneff2D_

private

Definition at line 120 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitOverFlowOvereff2D_

MonitorElement* L1TdeRCT::rctBitOverFlowOvereff2D_

private

Definition at line 121 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitTauVetoEff2D_

MonitorElement* L1TdeRCT::rctBitTauVetoEff2D_

private

Definition at line 127 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitTauVetoIneff2D_

MonitorElement* L1TdeRCT::rctBitTauVetoIneff2D_

private

Definition at line 128 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitTauVetoOvereff2D_

MonitorElement* L1TdeRCT::rctBitTauVetoOvereff2D_

private

Definition at line 129 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitUnmatchedDataHfPlusTau2D_

MonitorElement* L1TdeRCT::rctBitUnmatchedDataHfPlusTau2D_

private

Definition at line 151 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitUnmatchedDataMip2D_

MonitorElement* L1TdeRCT::rctBitUnmatchedDataMip2D_

private

Definition at line 134 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitUnmatchedDataOverFlow2D_

MonitorElement* L1TdeRCT::rctBitUnmatchedDataOverFlow2D_

private

Definition at line 118 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitUnmatchedDataQuiet2D_

MonitorElement* L1TdeRCT::rctBitUnmatchedDataQuiet2D_

private

Definition at line 142 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitUnmatchedDataTauVeto2D_

MonitorElement* L1TdeRCT::rctBitUnmatchedDataTauVeto2D_

private

Definition at line 126 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitUnmatchedEmulHfPlusTau2D_

MonitorElement* L1TdeRCT::rctBitUnmatchedEmulHfPlusTau2D_

private

Definition at line 150 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitUnmatchedEmulMip2D_

MonitorElement* L1TdeRCT::rctBitUnmatchedEmulMip2D_

private

Definition at line 133 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitUnmatchedEmulOverFlow2D_

MonitorElement* L1TdeRCT::rctBitUnmatchedEmulOverFlow2D_

private

Definition at line 117 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitUnmatchedEmulQuiet2D_

MonitorElement* L1TdeRCT::rctBitUnmatchedEmulQuiet2D_

private

Definition at line 141 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctBitUnmatchedEmulTauVeto2D_

MonitorElement* L1TdeRCT::rctBitUnmatchedEmulTauVeto2D_

private

Definition at line 125 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctInputTPGEcalOcc_

MonitorElement* L1TdeRCT::rctInputTPGEcalOcc_

private

Definition at line 158 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctInputTPGEcalOccNoCut_

MonitorElement* L1TdeRCT::rctInputTPGEcalOccNoCut_

private

Definition at line 159 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctInputTPGEcalRank_

MonitorElement* L1TdeRCT::rctInputTPGEcalRank_

private

Definition at line 160 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctInputTPGHcalOcc_

MonitorElement* L1TdeRCT::rctInputTPGHcalOcc_

private

Definition at line 161 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctInputTPGHcalRank_

MonitorElement* L1TdeRCT::rctInputTPGHcalRank_

private

Definition at line 162 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctInputTPGHcalSample_

MonitorElement* L1TdeRCT::rctInputTPGHcalSample_

private

Definition at line 163 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEffChannel_

MonitorElement* L1TdeRCT::rctIsoEffChannel_[396]

private

Definition at line 225 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmBitDiff_

MonitorElement* L1TdeRCT::rctIsoEmBitDiff_

private

Definition at line 193 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmBitOff_

MonitorElement* L1TdeRCT::rctIsoEmBitOff_

private

Definition at line 192 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmBitOn_

MonitorElement* L1TdeRCT::rctIsoEmBitOn_

private

Definition at line 191 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmDataOcc1D_

MonitorElement* L1TdeRCT::rctIsoEmDataOcc1D_

private

Definition at line 178 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmDataOcc_

MonitorElement* L1TdeRCT::rctIsoEmDataOcc_

private

Definition at line 165 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmEff1_

MonitorElement* L1TdeRCT::rctIsoEmEff1_

private

Definition at line 172 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmEff1Occ1D_

MonitorElement* L1TdeRCT::rctIsoEmEff1Occ1D_

private

Definition at line 180 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmEff1Occ_

MonitorElement* L1TdeRCT::rctIsoEmEff1Occ_

private

Definition at line 167 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmEff1oneD_

MonitorElement* L1TdeRCT::rctIsoEmEff1oneD_

private

Definition at line 185 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmEff2_

MonitorElement* L1TdeRCT::rctIsoEmEff2_

private

Definition at line 173 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmEff2Occ1D_

MonitorElement* L1TdeRCT::rctIsoEmEff2Occ1D_

private

Definition at line 181 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmEff2Occ_

MonitorElement* L1TdeRCT::rctIsoEmEff2Occ_

private

Definition at line 168 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmEff2oneD_

MonitorElement* L1TdeRCT::rctIsoEmEff2oneD_

private

Definition at line 186 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmEmulOcc1D_

MonitorElement* L1TdeRCT::rctIsoEmEmulOcc1D_

private

Definition at line 179 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmEmulOcc_

MonitorElement* L1TdeRCT::rctIsoEmEmulOcc_

private

Definition at line 166 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmIneff1D_

MonitorElement* L1TdeRCT::rctIsoEmIneff1D_

private

Definition at line 188 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmIneff2_

MonitorElement* L1TdeRCT::rctIsoEmIneff2_

private

Definition at line 174 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmIneff2Occ1D_

MonitorElement* L1TdeRCT::rctIsoEmIneff2Occ1D_

private

Definition at line 182 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmIneff2Occ_

MonitorElement* L1TdeRCT::rctIsoEmIneff2Occ_

private

Definition at line 169 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmIneff2oneD_

MonitorElement* L1TdeRCT::rctIsoEmIneff2oneD_

private

Definition at line 187 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmIneff_

MonitorElement* L1TdeRCT::rctIsoEmIneff_

private

Definition at line 175 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmIneffOcc1D_

MonitorElement* L1TdeRCT::rctIsoEmIneffOcc1D_

private

Definition at line 183 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmIneffOcc_

MonitorElement* L1TdeRCT::rctIsoEmIneffOcc_

private

Definition at line 170 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmOvereff1D_

MonitorElement* L1TdeRCT::rctIsoEmOvereff1D_

private

Definition at line 189 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmOvereff_

MonitorElement* L1TdeRCT::rctIsoEmOvereff_

private

Definition at line 176 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmOvereffOcc1D_

MonitorElement* L1TdeRCT::rctIsoEmOvereffOcc1D_

private

Definition at line 184 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoEmOvereffOcc_

MonitorElement* L1TdeRCT::rctIsoEmOvereffOcc_

private

Definition at line 171 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoIneffChannel_

MonitorElement* L1TdeRCT::rctIsoIneffChannel_[396]

private

Definition at line 226 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctIsoOvereffChannel_

MonitorElement* L1TdeRCT::rctIsoOvereffChannel_[396]

private

Definition at line 227 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEffChannel_

MonitorElement* L1TdeRCT::rctNisoEffChannel_[396]

private

Definition at line 229 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNIsoEmBitDiff_

MonitorElement* L1TdeRCT::rctNIsoEmBitDiff_

private

Definition at line 223 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNIsoEmBitOff_

MonitorElement* L1TdeRCT::rctNIsoEmBitOff_

private

Definition at line 222 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNIsoEmBitOn_

MonitorElement* L1TdeRCT::rctNIsoEmBitOn_

private

Definition at line 221 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmDataOcc1D_

MonitorElement* L1TdeRCT::rctNisoEmDataOcc1D_

private

Definition at line 208 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmDataOcc_

MonitorElement* L1TdeRCT::rctNisoEmDataOcc_

private

Definition at line 195 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmEff1_

MonitorElement* L1TdeRCT::rctNisoEmEff1_

private

Definition at line 202 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmEff1Occ1D_

MonitorElement* L1TdeRCT::rctNisoEmEff1Occ1D_

private

Definition at line 210 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmEff1Occ_

MonitorElement* L1TdeRCT::rctNisoEmEff1Occ_

private

Definition at line 197 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmEff1oneD_

MonitorElement* L1TdeRCT::rctNisoEmEff1oneD_

private

Definition at line 215 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmEff2_

MonitorElement* L1TdeRCT::rctNisoEmEff2_

private

Definition at line 203 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmEff2Occ1D_

MonitorElement* L1TdeRCT::rctNisoEmEff2Occ1D_

private

Definition at line 211 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmEff2Occ_

MonitorElement* L1TdeRCT::rctNisoEmEff2Occ_

private

Definition at line 198 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmEff2oneD_

MonitorElement* L1TdeRCT::rctNisoEmEff2oneD_

private

Definition at line 216 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmEmulOcc1D_

MonitorElement* L1TdeRCT::rctNisoEmEmulOcc1D_

private

Definition at line 209 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmEmulOcc_

MonitorElement* L1TdeRCT::rctNisoEmEmulOcc_

private

Definition at line 196 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmIneff1D_

MonitorElement* L1TdeRCT::rctNisoEmIneff1D_

private

Definition at line 218 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmIneff2_

MonitorElement* L1TdeRCT::rctNisoEmIneff2_

private

Definition at line 204 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmIneff2Occ1D_

MonitorElement* L1TdeRCT::rctNisoEmIneff2Occ1D_

private

Definition at line 212 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmIneff2Occ_

MonitorElement* L1TdeRCT::rctNisoEmIneff2Occ_

private

Definition at line 199 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmIneff2oneD_

MonitorElement* L1TdeRCT::rctNisoEmIneff2oneD_

private

Definition at line 217 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmIneff_

MonitorElement* L1TdeRCT::rctNisoEmIneff_

private

Definition at line 205 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmIneffOcc1D_

MonitorElement* L1TdeRCT::rctNisoEmIneffOcc1D_

private

Definition at line 213 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmIneffOcc_

MonitorElement* L1TdeRCT::rctNisoEmIneffOcc_

private

Definition at line 200 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmOvereff1D_

MonitorElement* L1TdeRCT::rctNisoEmOvereff1D_

private

Definition at line 219 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmOvereff_

MonitorElement* L1TdeRCT::rctNisoEmOvereff_

private

Definition at line 206 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmOvereffOcc1D_

MonitorElement* L1TdeRCT::rctNisoEmOvereffOcc1D_

private

Definition at line 214 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoEmOvereffOcc_

MonitorElement* L1TdeRCT::rctNisoEmOvereffOcc_

private

Definition at line 201 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoIneffChannel_

MonitorElement* L1TdeRCT::rctNisoIneffChannel_[396]

private

Definition at line 230 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctNisoOvereffChannel_

MonitorElement* L1TdeRCT::rctNisoOvereffChannel_[396]

private

Definition at line 231 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegBitDiff_

MonitorElement* L1TdeRCT::rctRegBitDiff_

private

Definition at line 109 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegBitOff_

MonitorElement* L1TdeRCT::rctRegBitOff_

private

Definition at line 108 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegBitOn_

MonitorElement* L1TdeRCT::rctRegBitOn_

private

Definition at line 107 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegDataOcc1D_

MonitorElement* L1TdeRCT::rctRegDataOcc1D_

private

Definition at line 78 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegDataOcc2D_

MonitorElement* L1TdeRCT::rctRegDataOcc2D_

private

Definition at line 92 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegEff1D_

MonitorElement* L1TdeRCT::rctRegEff1D_

private

Definition at line 86 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegEff2D_

MonitorElement* L1TdeRCT::rctRegEff2D_

private

Definition at line 101 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegEffChannel_

MonitorElement* L1TdeRCT::rctRegEffChannel_[396]

private

Definition at line 234 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegEmulOcc1D_

MonitorElement* L1TdeRCT::rctRegEmulOcc1D_

private

Definition at line 79 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegEmulOcc2D_

MonitorElement* L1TdeRCT::rctRegEmulOcc2D_

private

Definition at line 93 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegIneff1D_

MonitorElement* L1TdeRCT::rctRegIneff1D_

private

Definition at line 87 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegIneff2D_

MonitorElement* L1TdeRCT::rctRegIneff2D_

private

Definition at line 102 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegIneffChannel_

MonitorElement* L1TdeRCT::rctRegIneffChannel_[396]

private

Definition at line 235 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegMatchedOcc1D_

MonitorElement* L1TdeRCT::rctRegMatchedOcc1D_

private

Definition at line 80 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegMatchedOcc2D_

MonitorElement* L1TdeRCT::rctRegMatchedOcc2D_

private

Definition at line 94 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegOvereff1D_

MonitorElement* L1TdeRCT::rctRegOvereff1D_

private

Definition at line 88 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegOvereff2D_

MonitorElement* L1TdeRCT::rctRegOvereff2D_

private

Definition at line 103 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegOvereffChannel_

MonitorElement* L1TdeRCT::rctRegOvereffChannel_[396]

private

Definition at line 236 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegSpEff1D_

MonitorElement* L1TdeRCT::rctRegSpEff1D_

private

Definition at line 89 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegSpEff2D_

MonitorElement* L1TdeRCT::rctRegSpEff2D_

private

Definition at line 104 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegSpEffOcc1D_

MonitorElement* L1TdeRCT::rctRegSpEffOcc1D_

private

Definition at line 83 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegSpEffOcc2D_

MonitorElement* L1TdeRCT::rctRegSpEffOcc2D_

private

Definition at line 98 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegSpIneff1D_

MonitorElement* L1TdeRCT::rctRegSpIneff1D_

private

Definition at line 90 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegSpIneff2D_

MonitorElement* L1TdeRCT::rctRegSpIneff2D_

private

Definition at line 105 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegSpIneffOcc1D_

MonitorElement* L1TdeRCT::rctRegSpIneffOcc1D_

private

Definition at line 84 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegSpIneffOcc2D_

MonitorElement* L1TdeRCT::rctRegSpIneffOcc2D_

private

Definition at line 99 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegUnmatchedDataOcc1D_

MonitorElement* L1TdeRCT::rctRegUnmatchedDataOcc1D_

private

Definition at line 81 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegUnmatchedDataOcc2D_

MonitorElement* L1TdeRCT::rctRegUnmatchedDataOcc2D_

private

Definition at line 95 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegUnmatchedEmulOcc1D_

MonitorElement* L1TdeRCT::rctRegUnmatchedEmulOcc1D_

private

Definition at line 82 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctRegUnmatchedEmulOcc2D_

MonitorElement* L1TdeRCT::rctRegUnmatchedEmulOcc2D_

private

Definition at line 96 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

rctSourceData_emData_

edm::EDGetTokenT<L1CaloEmCollection> L1TdeRCT::rctSourceData_emData_

private

Definition at line 262 of file L1TdeRCT.h.

Referenced by analyze().

rctSourceData_rgnData_

edm::EDGetTokenT<L1CaloRegionCollection> L1TdeRCT::rctSourceData_rgnData_

private

Definition at line 261 of file L1TdeRCT.h.

Referenced by analyze().

rctSourceEmul_emEmul_

edm::EDGetTokenT<L1CaloEmCollection> L1TdeRCT::rctSourceEmul_emEmul_

private

Definition at line 260 of file L1TdeRCT.h.

Referenced by analyze().

rctSourceEmul_rgnEmul_

edm::EDGetTokenT<L1CaloRegionCollection> L1TdeRCT::rctSourceEmul_rgnEmul_

private

Definition at line 259 of file L1TdeRCT.h.

Referenced by analyze().

selectBX_

int L1TdeRCT::selectBX_

private

Definition at line 273 of file L1TdeRCT.h.

Referenced by analyze().

singlechannelhistos_

bool L1TdeRCT::singlechannelhistos_

private

Definition at line 257 of file L1TdeRCT.h.

Referenced by analyze(), bookHistograms(), and L1TdeRCT().

trigCount

int L1TdeRCT::trigCount

private

Definition at line 277 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

trigEff_

MonitorElement* L1TdeRCT::trigEff_[396]

private

Definition at line 242 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

trigEffOcc_

MonitorElement* L1TdeRCT::trigEffOcc_[396]

private

Definition at line 243 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

trigEffThresh_

MonitorElement* L1TdeRCT::trigEffThresh_

private

Definition at line 239 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

trigEffThreshOcc_

MonitorElement* L1TdeRCT::trigEffThreshOcc_

private

Definition at line 240 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

trigEffTriggOcc_

MonitorElement* L1TdeRCT::trigEffTriggOcc_[396]

private

Definition at line 244 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

trigEffTriggThreshOcc_

MonitorElement* L1TdeRCT::trigEffTriggThreshOcc_

private

Definition at line 241 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

triggerAlgoNumbers_

MonitorElement* L1TdeRCT::triggerAlgoNumbers_

private

Definition at line 72 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

triggerType_

MonitorElement* L1TdeRCT::triggerType_

private

Definition at line 75 of file L1TdeRCT.h.

Referenced by analyze(), and bookHistograms().

verbose_

bool L1TdeRCT::verbose_

private

Definition at line 256 of file L1TdeRCT.h.

Referenced by analyze(), and L1TdeRCT().