#include <CaloTowerAnalyzer.h>

Inheritance diagram for CaloTowerAnalyzer:

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

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

	CaloTowerAnalyzer (const edm::ParameterSet &)

virtual void	endJob ()

Public Member Functions inherited from edm::EDAnalyzer
	EDAnalyzer ()

std::string	workerType () const

virtual	~EDAnalyzer ()

Private Attributes
bool	allhist_

edm::InputTag	caloTowersLabel_

DQMStore *	dbe_

bool	debug_

double	energyThreshold_

bool	finebinning_

std::string	FolderName_

edm::InputTag	HBHENoiseFilterResultLabel_

MonitorElement *	hCT_emEt_ieta_iphi

MonitorElement *	hCT_emEtvsieta

MonitorElement *	hCT_et_ieta_iphi

MonitorElement *	hCT_etvsieta

MonitorElement *	hCT_hadEt_ieta_iphi

MonitorElement *	hCT_hadEtvsieta

MonitorElement *	hCT_Maxetvsieta

MonitorElement *	hCT_METPhivsieta

MonitorElement *	hCT_METvsieta

MonitorElement *	hCT_MExvsieta

MonitorElement *	hCT_MEyvsieta

MonitorElement *	hCT_Minetvsieta

MonitorElement *	hCT_Nevents

std::vector< MonitorElement * >	hCT_NEvents_HLT

MonitorElement *	hCT_Occ_EM_Et_ieta_iphi

MonitorElement *	hCT_Occ_HAD_Et_ieta_iphi

MonitorElement *	hCT_Occ_ieta_iphi

MonitorElement *	hCT_Occ_Outer_Et_ieta_iphi

MonitorElement *	hCT_Occvsieta

MonitorElement *	hCT_outerEt_ieta_iphi

MonitorElement *	hCT_outerEtvsieta

MonitorElement *	hCT_SETvsieta

std::vector< edm::InputTag >	HLTBitLabel_

edm::InputTag	HLTResultsLabel_

bool	hltselection_

int	Nevents

Additional Inherited Members
Public Types inherited from edm::EDAnalyzer
typedef EDAnalyzer	ModuleType

typedef WorkerT< EDAnalyzer >	WorkerType

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

static void	fillDescriptions (ConfigurationDescriptions &descriptions)

static void	prevalidate (ConfigurationDescriptions &)

Protected Member Functions inherited from edm::EDAnalyzer
CurrentProcessingContext const *	currentContext () const

Detailed Description

Definition at line 20 of file CaloTowerAnalyzer.h.

Constructor & Destructor Documentation

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

explicit

Definition at line 61 of file CaloTowerAnalyzer.cc.

References edm::ParameterSet::exists(), edm::ParameterSet::getParameter(), and edm::ParameterSet::getUntrackedParameter().

 {
 
   caloTowersLabel_            = iConfig.getParameter<edm::InputTag>("CaloTowersLabel");
   HLTResultsLabel_            = iConfig.getParameter<edm::InputTag>("HLTResultsLabel");  
   HBHENoiseFilterResultLabel_ = iConfig.getParameter<edm::InputTag>("HBHENoiseFilterResultLabel");
 
   if(iConfig.exists("HLTBitLabels"))
     HLTBitLabel_         = iConfig.getParameter<std::vector<edm::InputTag> >("HLTBitLabels");
   
   debug_               = iConfig.getParameter<bool>("Debug");
   finebinning_         = iConfig.getUntrackedParameter<bool>("FineBinning"); 
   allhist_             = iConfig.getUntrackedParameter<bool>("AllHist"); 
   FolderName_          = iConfig.getUntrackedParameter<std::string>("FolderName");
 
   hltselection_        = iConfig.getUntrackedParameter<bool>("HLTSelection"); 
   
 }

Member Function Documentation

void CaloTowerAnalyzer::analyze	(	const edm::Event &	iEvent,
		const edm::EventSetup &	iSetup
	)

virtual

Implements edm::EDAnalyzer.

Definition at line 187 of file CaloTowerAnalyzer.cc.

References CaloTower::emEt(), CaloTower::et(), edm::Event::getByLabel(), CaloTower::hadEt(), i, CaloTower::id(), CaloTowerDetId::ieta(), getHLTprescales::index, CaloTowerDetId::iphi(), edm::HandleBase::isValid(), diffTwoXMLs::label, LogDebug, CaloTower::outerEt(), colinearityKinematic::Phi, reco::LeafCandidate::phi(), reco::tau::disc::Pt(), findQualityFiles::size, edm::TriggerNames::triggerIndex(), and edm::Event::triggerNames().

 {
   // Get HLT Results
   edm::Handle<edm::TriggerResults> TheHLTResults;
   iEvent.getByLabel( HLTResultsLabel_ , TheHLTResults);
 
   bool EventPasses = true;
 
   // Make sure handle is valid
   if( TheHLTResults.isValid() && hltselection_ )
     {
       //Get HLT Names
       const edm::TriggerNames & TheTriggerNames = iEvent.triggerNames(*TheHLTResults);
       
       for( unsigned int index = 0 ; index < HLTBitLabel_.size(); index++)
     {
       if( HLTBitLabel_[index].label().size() )
         {
           //Change the default value since HLT requirement has been issued by the user
           if( index == 0 ) EventPasses = false; 
           //Get the HLT bit and check to make sure it is valid
           unsigned int bit = TheTriggerNames.triggerIndex( HLTBitLabel_[index].label().c_str());
           if( bit < TheHLTResults->size() )
         {
           //If any of the HLT names given by the user accept, then the event passes
           if( TheHLTResults->accept( bit ) && !TheHLTResults->error( bit ) )
             {
               EventPasses = true;
               hCT_NEvents_HLT[index]->Fill(1);
             }  
           else 
             hCT_NEvents_HLT[index]->Fill(0);
         }
           else
         {
           edm::LogInfo("OutputInfo") 
             << "The HLT Trigger Name : " << HLTBitLabel_[index].label() << " is not valid for this trigger table " << std::endl;
         }
         }
     }
     }
 
   if( !EventPasses && hltselection_ ) 
     return;
   
   //----------GREG & CHRIS' idea---///
   float ETTowerMin = -1; //GeV
   float METRingMin = -2; // GeV
   
   Nevents++;
   hCT_Nevents->Fill(0);
 
   // ==========================================================
   // Retrieve!
   // ==========================================================
 
   edm::Handle<edm::View<Candidate> > towers;
   iEvent.getByLabel(caloTowersLabel_, towers);
 
   if( (!towers.isValid())) {
     edm::LogInfo("")<<"CaloTowers "<< caloTowersLabel_<<" not found!"<<std::endl;
     return;
   }
 
 
   edm::Handle<bool> HBHENoiseFilterResultHandle;
   iEvent.getByLabel(HBHENoiseFilterResultLabel_, HBHENoiseFilterResultHandle);
   bool HBHENoiseFilterResult = *HBHENoiseFilterResultHandle;
   if (!HBHENoiseFilterResultHandle.isValid()) {
     LogDebug("") << "CaloTowerAnalyzer: Could not find HBHENoiseFilterResult" << std::endl;
   }
 
 
   bool bHcalNoiseFilter = HBHENoiseFilterResult;
 
   if(!bHcalNoiseFilter) return;
 
   edm::View<Candidate>::const_iterator towerCand = towers->begin();
   
   // ==========================================================
   // Fill Histograms!
   // ==========================================================
 
   int CTmin_iphi = 99, CTmax_iphi = -99;
   int CTmin_ieta = 99, CTmax_ieta = -99;
 
   TLorentzVector vMET_EtaRing[83];
   int ActiveRing[83];
   int NActiveTowers[83];
   double SET_EtaRing[83];
   double MinEt_EtaRing[83];
   double MaxEt_EtaRing[83];
   for (int i=0;i<83; i++) 
     {
       ActiveRing[i] = 0;
       NActiveTowers[i] = 0;
       SET_EtaRing[i] = 0;
       MinEt_EtaRing[i] = 0;
       MaxEt_EtaRing[i] = 0;
     }
 
   //rcr for (calotower = towerCollection->begin(); calotower != towerCollection->end(); calotower++) {
     
   for ( ; towerCand != towers->end(); towerCand++)
     {
       const Candidate* candidate = &(*towerCand);
       if (candidate) 
     {
       const CaloTower* calotower = dynamic_cast<const CaloTower*> (candidate);
       if (calotower){
       //math::RhoEtaPhiVector Momentum = calotower->momentum();
       double Tower_ET = calotower->et();
       //double Tower_Energy  = calotower->energy();
       //      double Tower_Eta = calotower->eta();
       double Tower_Phi = calotower->phi();
       //double Tower_EMEnergy = calotower->emEnergy();
       //double Tower_HadEnergy = calotower->hadEnergy();
       double Tower_OuterEt = calotower->outerEt();
       double Tower_EMEt = calotower->emEt();
       double Tower_HadEt = calotower->hadEt();
       //int Tower_EMLV1 = calotower->emLvl1();
       //int Tower_HadLV1 = calotower->hadLv11();
       int Tower_ieta = calotower->id().ieta();
       int Tower_iphi = calotower->id().iphi();
       int EtaRing = 41+Tower_ieta;
       ActiveRing[EtaRing] = 1;
       NActiveTowers[EtaRing]++;
       SET_EtaRing[EtaRing]+=Tower_ET;
       TLorentzVector v_;
       v_.SetPtEtaPhiE(Tower_ET, 0, Tower_Phi, Tower_ET);
       if (Tower_ET>ETTowerMin)
         vMET_EtaRing[EtaRing]-=v_;
       
       // Fill Histograms                                                                                                                                                                                                   
           hCT_Occ_ieta_iphi->Fill(Tower_ieta,Tower_iphi);
           if (calotower->emEt() > 0 && calotower->emEt() + calotower->hadEt() > 0.3)
             hCT_Occ_EM_Et_ieta_iphi->Fill(Tower_ieta,Tower_iphi);
           if (calotower->hadEt() > 0 && calotower->emEt() + calotower->hadEt() > 0.3)
             hCT_Occ_HAD_Et_ieta_iphi->Fill(Tower_ieta,Tower_iphi);
           if (calotower->outerEt() > 0 && calotower->emEt() + calotower->hadEt() > 0.3)
             hCT_Occ_Outer_Et_ieta_iphi->Fill(Tower_ieta,Tower_iphi);
 
       hCT_et_ieta_iphi->Fill(Tower_ieta,Tower_iphi,Tower_ET);
       hCT_emEt_ieta_iphi->Fill(Tower_ieta,Tower_iphi,Tower_EMEt);
       hCT_hadEt_ieta_iphi->Fill(Tower_ieta,Tower_iphi,Tower_HadEt);
       hCT_outerEt_ieta_iphi->Fill(Tower_ieta,Tower_iphi,Tower_OuterEt);
 
       if (allhist_){
       hCT_etvsieta->Fill(Tower_ieta, Tower_ET);
       hCT_emEtvsieta->Fill(Tower_ieta, Tower_EMEt);
       hCT_hadEtvsieta->Fill(Tower_ieta,Tower_HadEt);
       hCT_outerEtvsieta->Fill(Tower_ieta,Tower_OuterEt);
       }
 
       if (Tower_ET > MaxEt_EtaRing[EtaRing])
         MaxEt_EtaRing[EtaRing] = Tower_ET;
       if (Tower_ET < MinEt_EtaRing[EtaRing] && Tower_ET>0)
         MinEt_EtaRing[EtaRing] = Tower_ET;
       
       
       if (Tower_ieta < CTmin_ieta) CTmin_ieta = Tower_ieta;
       if (Tower_ieta > CTmax_ieta) CTmax_ieta = Tower_ieta;
       if (Tower_iphi < CTmin_iphi) CTmin_iphi = Tower_iphi;
       if (Tower_iphi > CTmax_iphi) CTmax_iphi = Tower_iphi;
       } //end if (calotower) ..
     } // end if(candidate) ...
       
     } // end loop over towers
   
       // Fill eta-ring MET quantities
   if (allhist_){
   for (int iEtaRing=0; iEtaRing<83; iEtaRing++)
     { 
       hCT_Minetvsieta->Fill(iEtaRing-41, MinEt_EtaRing[iEtaRing]);  
       hCT_Maxetvsieta->Fill(iEtaRing-41, MaxEt_EtaRing[iEtaRing]);  
       
       if (ActiveRing[iEtaRing])
     {
       if (vMET_EtaRing[iEtaRing].Pt()>METRingMin)
         {
           hCT_METPhivsieta->Fill(iEtaRing-41, vMET_EtaRing[iEtaRing].Phi());
           hCT_MExvsieta->Fill(iEtaRing-41, vMET_EtaRing[iEtaRing].Px());
           hCT_MEyvsieta->Fill(iEtaRing-41, vMET_EtaRing[iEtaRing].Py());
           hCT_METvsieta->Fill(iEtaRing-41, vMET_EtaRing[iEtaRing].Pt());
         }
       hCT_SETvsieta->Fill(iEtaRing-41, SET_EtaRing[iEtaRing]);
       hCT_Occvsieta->Fill(iEtaRing-41, NActiveTowers[iEtaRing]);
     }
     } // ietaring
   }   // allhist_
   
   edm::LogInfo("OutputInfo") << "CT ieta range: " << CTmin_ieta << " " << CTmax_ieta;
   edm::LogInfo("OutputInfo") << "CT iphi range: " << CTmin_iphi << " " << CTmax_iphi;
   
 }

void CaloTowerAnalyzer::beginRun	(	const edm::Run &	iRun,
		const edm::EventSetup &	iSetup
	)

virtual

Reimplemented from edm::EDAnalyzer.

Definition at line 81 of file CaloTowerAnalyzer.cc.

References DQMStore::book1D(), DQMStore::book2D(), dbe_, MonitorElement::getTH2F(), i, diffTwoXMLs::label, cppFunctionSkipper::operator, and DQMStore::setCurrentFolder().

 {
   Nevents = 0;
   // get ahold of back-end interface
   dbe_ = edm::Service<DQMStore>().operator->();
 
   if (dbe_) {
  
     dbe_->setCurrentFolder(FolderName_); 
 
     //Store number of events which pass each HLT bit 
     for(unsigned int i = 0 ; i < HLTBitLabel_.size() ; i++ )
       {
     if( HLTBitLabel_[i].label().size() )
       {
         hCT_NEvents_HLT.push_back( dbe_->book1D("METTask_CT_"+HLTBitLabel_[i].label(),HLTBitLabel_[i].label(),2,-0.5,1.5) );
       }
       }
     
     //--Store number of events used
     hCT_Nevents          = dbe_->book1D("METTask_CT_Nevents","",1,0,1);  
     //--Data integrated over all events and stored by CaloTower(ieta,iphi) 
     hCT_et_ieta_iphi          = dbe_->book2D("METTask_CT_et_ieta_iphi","",83,-41,42, 72,1,73);  
     hCT_et_ieta_iphi->getTH2F()->SetOption("colz");
     hCT_et_ieta_iphi->setAxisTitle("ieta",1);
     hCT_et_ieta_iphi->setAxisTitle("ephi",2);
 
     hCT_emEt_ieta_iphi        = dbe_->book2D("METTask_CT_emEt_ieta_iphi","",83,-41,42, 72,1,73);  
     hCT_emEt_ieta_iphi->getTH2F()->SetOption("colz");
     hCT_emEt_ieta_iphi->setAxisTitle("ieta",1);
     hCT_emEt_ieta_iphi->setAxisTitle("ephi",2);
     hCT_hadEt_ieta_iphi       = dbe_->book2D("METTask_CT_hadEt_ieta_iphi","",83,-41,42, 72,1,73);  
     hCT_hadEt_ieta_iphi->getTH2F()->SetOption("colz");
     hCT_hadEt_ieta_iphi->setAxisTitle("ieta",1);
     hCT_hadEt_ieta_iphi->setAxisTitle("ephi",2);
     hCT_outerEt_ieta_iphi = dbe_->book2D("METTask_CT_outerEt_ieta_iphi","",83,-41,42, 72,1,73);  
     hCT_outerEt_ieta_iphi->getTH2F()->SetOption("colz");
     hCT_outerEt_ieta_iphi->setAxisTitle("ieta",1);
     hCT_outerEt_ieta_iphi->setAxisTitle("ephi",2);
     hCT_Occ_ieta_iphi         = dbe_->book2D("METTask_CT_Occ_ieta_iphi","",83,-41,42, 72,1,73);  
     hCT_Occ_ieta_iphi->getTH2F()->SetOption("colz");
     hCT_Occ_ieta_iphi->setAxisTitle("ieta",1);
     hCT_Occ_ieta_iphi->setAxisTitle("ephi",2);
 
     hCT_Occ_EM_Et_ieta_iphi         = dbe_->book2D("METTask_CT_Occ_EM_Et_ieta_iphi","",83,-41,42, 72,1,73);
     hCT_Occ_EM_Et_ieta_iphi->getTH2F()->SetOption("colz");
     hCT_Occ_EM_Et_ieta_iphi->setAxisTitle("ieta",1);
     hCT_Occ_EM_Et_ieta_iphi->setAxisTitle("ephi",2);
 
     hCT_Occ_HAD_Et_ieta_iphi         = dbe_->book2D("METTask_CT_Occ_HAD_Et_ieta_iphi","",83,-41,42, 72,1,73);
     hCT_Occ_HAD_Et_ieta_iphi->getTH2F()->SetOption("colz");
     hCT_Occ_HAD_Et_ieta_iphi->setAxisTitle("ieta",1);
     hCT_Occ_HAD_Et_ieta_iphi->setAxisTitle("ephi",2);
 
     hCT_Occ_Outer_Et_ieta_iphi         = dbe_->book2D("METTask_CT_Occ_Outer_Et_ieta_iphi","",83,-41,42, 72,1,73);
     hCT_Occ_Outer_Et_ieta_iphi->getTH2F()->SetOption("colz");
     hCT_Occ_Outer_Et_ieta_iphi->setAxisTitle("ieta",1);
     hCT_Occ_Outer_Et_ieta_iphi->setAxisTitle("ephi",2);
 
     //--Data over eta-rings
 
     // CaloTower values
     if(allhist_){
     if(finebinning_)
       {
 
     hCT_etvsieta          = dbe_->book2D("METTask_CT_etvsieta","", 83,-41,42, 10001,0,1001);  
     hCT_Minetvsieta       = dbe_->book2D("METTask_CT_Minetvsieta","", 83,-41,42, 10001,0,1001);  
     hCT_Maxetvsieta       = dbe_->book2D("METTask_CT_Maxetvsieta","", 83,-41,42, 10001,0,1001);  
     hCT_emEtvsieta        = dbe_->book2D("METTask_CT_emEtvsieta","",83,-41,42, 10001,0,1001);  
     hCT_hadEtvsieta       = dbe_->book2D("METTask_CT_hadEtvsieta","",83,-41,42, 10001,0,1001);  
     hCT_outerEtvsieta = dbe_->book2D("METTask_CT_outerEtvsieta","",83,-41,42, 10001,0,1001);  
     // Integrated over phi
 
     hCT_Occvsieta         = dbe_->book2D("METTask_CT_Occvsieta","",83,-41,42, 84,0,84);  
     hCT_SETvsieta         = dbe_->book2D("METTask_CT_SETvsieta","",83,-41,42, 20001,0,2001);  
     hCT_METvsieta         = dbe_->book2D("METTask_CT_METvsieta","",83,-41,42, 20001,0,2001);  
     hCT_METPhivsieta      = dbe_->book2D("METTask_CT_METPhivsieta","",83,-41,42, 80,-4,4);  
     hCT_MExvsieta         = dbe_->book2D("METTask_CT_MExvsieta","",83,-41,42, 10001,-500,501);  
     hCT_MEyvsieta         = dbe_->book2D("METTask_CT_MEyvsieta","",83,-41,42, 10001,-500,501);  
       }
     else 
       {
     
     if(allhist_){
     hCT_etvsieta          = dbe_->book2D("METTask_CT_etvsieta","", 83,-41,42, 200,-0.5,999.5);
         hCT_Minetvsieta       = dbe_->book2D("METTask_CT_Minetvsieta","", 83,-41,42, 200,-0.5,999.5);
         hCT_Maxetvsieta       = dbe_->book2D("METTask_CT_Maxetvsieta","", 83,-41,42, 200,-0.5,999.5);
         hCT_emEtvsieta        = dbe_->book2D("METTask_CT_emEtvsieta","",83,-41,42, 200,-0.5,999.5);
         hCT_hadEtvsieta       = dbe_->book2D("METTask_CT_hadEtvsieta","",83,-41,42, 200,-0.5,999.5);
         hCT_outerEtvsieta = dbe_->book2D("METTask_CT_outerEtvsieta","",83,-41,42, 80,-0.5,399.5);
         // Integrated over phi
     }
 
         hCT_Occvsieta         = dbe_->book2D("METTask_CT_Occvsieta","",83,-41,42, 73,-0.5,72.5);
         hCT_SETvsieta         = dbe_->book2D("METTask_CT_SETvsieta","",83,-41,42, 200,-0.5,1999.5);
         hCT_METvsieta         = dbe_->book2D("METTask_CT_METvsieta","",83,-41,42, 200,-0.5,1999.5);
         hCT_METPhivsieta      = dbe_->book2D("METTask_CT_METPhivsieta","",83,-41,42, 80,-4,4);
         hCT_MExvsieta         = dbe_->book2D("METTask_CT_MExvsieta","",83,-41,42, 100,-499.5,499.5);
         hCT_MEyvsieta         = dbe_->book2D("METTask_CT_MEyvsieta","",83,-41,42, 100,-499.5,499.5);
     
       }
     } // allhist
   }
 }

void CaloTowerAnalyzer::endJob ( void )

virtual

Reimplemented from edm::EDAnalyzer.

Definition at line 383 of file CaloTowerAnalyzer.cc.

384 {

385 }

Member Data Documentation

bool CaloTowerAnalyzer::allhist_

private

Definition at line 42 of file CaloTowerAnalyzer.h.

edm::InputTag CaloTowerAnalyzer::caloTowersLabel_

private

Definition at line 36 of file CaloTowerAnalyzer.h.

DQMStore* CaloTowerAnalyzer::dbe_

private

Definition at line 33 of file CaloTowerAnalyzer.h.

bool CaloTowerAnalyzer::debug_

private

Definition at line 40 of file CaloTowerAnalyzer.h.

double CaloTowerAnalyzer::energyThreshold_

private

Definition at line 41 of file CaloTowerAnalyzer.h.

bool CaloTowerAnalyzer::finebinning_

private

Definition at line 43 of file CaloTowerAnalyzer.h.

std::string CaloTowerAnalyzer::FolderName_

private

Definition at line 45 of file CaloTowerAnalyzer.h.

edm::InputTag CaloTowerAnalyzer::HBHENoiseFilterResultLabel_

private

Definition at line 39 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_emEt_ieta_iphi

private

Definition at line 51 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_emEtvsieta

private

Definition at line 61 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_et_ieta_iphi

private

Definition at line 50 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_etvsieta

private

Definition at line 58 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_hadEt_ieta_iphi

private

Definition at line 52 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_hadEtvsieta

private

Definition at line 62 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_Maxetvsieta

private

Definition at line 60 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_METPhivsieta

private

Definition at line 67 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_METvsieta

private

Definition at line 66 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_MExvsieta

private

Definition at line 68 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_MEyvsieta

private

Definition at line 69 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_Minetvsieta

private

Definition at line 59 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_Nevents

private

Definition at line 49 of file CaloTowerAnalyzer.h.

std::vector<MonitorElement*> CaloTowerAnalyzer::hCT_NEvents_HLT

private

Definition at line 70 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_Occ_EM_Et_ieta_iphi

private

Definition at line 55 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_Occ_HAD_Et_ieta_iphi

private

Definition at line 56 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_Occ_ieta_iphi

private

Definition at line 54 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_Occ_Outer_Et_ieta_iphi

private

Definition at line 57 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_Occvsieta

private

Definition at line 64 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_outerEt_ieta_iphi

private

Definition at line 53 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_outerEtvsieta

private

Definition at line 63 of file CaloTowerAnalyzer.h.

MonitorElement* CaloTowerAnalyzer::hCT_SETvsieta

private

Definition at line 65 of file CaloTowerAnalyzer.h.

std::vector< edm::InputTag > CaloTowerAnalyzer::HLTBitLabel_

private

Definition at line 37 of file CaloTowerAnalyzer.h.

edm::InputTag CaloTowerAnalyzer::HLTResultsLabel_

private

Definition at line 38 of file CaloTowerAnalyzer.h.

bool CaloTowerAnalyzer::hltselection_

private

Definition at line 44 of file CaloTowerAnalyzer.h.

int CaloTowerAnalyzer::Nevents

private

Definition at line 46 of file CaloTowerAnalyzer.h.

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