#include <HcalDigiMonitor.h>

Inheritance diagram for HcalDigiMonitor:

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

void	beginLuminosityBlock (const edm::LuminosityBlock &lumiSeg, const edm::EventSetup &c)

void	bookHistograms (DQMStore::IBooker &ib, const edm::Run &run, const edm::EventSetup &c)

void	endJob ()

void	endLuminosityBlock (const edm::LuminosityBlock &lumiSeg, const edm::EventSetup &c)

void	endRun (const edm::Run &run, const edm::EventSetup &c)

	HcalDigiMonitor (const edm::ParameterSet &ps)

template<class DIGI >
int	process_Digi (DIGI &digi, DigiHists &h, int &firstcap)

void	processEvent (const HBHEDigiCollection &hbhe, const HODigiCollection &ho, const HFDigiCollection &hf, const HcalDbService &cond, const HcalUnpackerReport &report, int orN, int bcN)

void	reset ()

void	setup (DQMStore::IBooker &)

	~HcalDigiMonitor ()

Public Member Functions inherited from HcalBaseDQMonitor
	HcalBaseDQMonitor (const edm::ParameterSet &ps)

	HcalBaseDQMonitor ()

virtual	~HcalBaseDQMonitor ()

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

virtual void	beginStream (edm::StreamID id) final

	DQMEDAnalyzer (void)

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

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

uint32_t	streamId () const

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

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

ModuleDescription const &	moduleDescription () const

virtual	~EDAnalyzerBase ()

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

	EDConsumerBase ()

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

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

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

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

void	labelsForToken (EDGetToken iToken, Labels &oLabels) const

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

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

bool	registeredToConsume (ProductHolderIndex, bool, BranchType) const

bool	registeredToConsumeMany (TypeID const &, BranchType) const

void	updateLookup (BranchType iBranchType, ProductHolderIndexHelper const &)

virtual	~EDConsumerBase ()

Private Member Functions
void	fill_Nevents ()

template<class T >
int	process_Digi (T &digi, DigiHists &hist, int &firstcap)

void	setupSubdetHists (DQMStore::IBooker &ib, DigiHists &hist, std::string subdet)

void	UpdateHists (DigiHists &h)

void	zeroCounters ()

Private Attributes
int	alarmer_counter_

int	badcapID [85][72][4]

int	baddigis [85][72][4]

int	baddigisize [85][72][4]

int	badFibBCNOff [85][72][4]

int	badunpackerreport [85][72][4]

edm::ESHandle< HcalDbService >	conditions_

edm::EDGetTokenT < DcsStatusCollection >	dcsStatusToken_

bool	digi_checkadcsum_

bool	digi_checkcapid_

bool	digi_checkdigisize_

bool	digi_checkdverr_

bool	digi_checkoccupancy_

MonitorElement *	DigiBQ

MonitorElement *	DigiBQFrac

EtaPhiHists	DigiErrorOccupancyByDepth

EtaPhiHists	DigiErrorsBadADCSum

EtaPhiHists	DigiErrorsBadCapID

EtaPhiHists	DigiErrorsBadDigiSize

EtaPhiHists	DigiErrorsBadFibBCNOff

EtaPhiHists	DigiErrorsByDepth

EtaPhiHists	DigiErrorsDVErr

int	digierrorsdverr [85][72][4]

MonitorElement *	DigiErrorSpigot

EtaPhiHists	DigiErrorsUnpacker

MonitorElement *	DigiErrorVME

MonitorElement *	DigiExpectedSize

edm::InputTag	digiLabel_

int	DigiMonitor_ExpectedOrbitMessageTime_

MonitorElement *	DigiNum

int	diginum [9072]

EtaPhiHists	DigiOccupancyByDepth

MonitorElement *	DigiOccupancyEta

MonitorElement *	DigiOccupancyPhi

MonitorElement *	DigiOccupancySpigot

MonitorElement *	DigiOccupancyVME

MonitorElement *	DigiSize

int	digisize [20][4]

MonitorElement *	DigiUnpackerErrorCount

MonitorElement *	DigiUnpackerErrorFrac

bool	doFCpeds_

int	errorSpigot [15][36]

int	errorVME [40][18]

bool	excludeBadQPLLs_

bool	excludeHO1P02_

bool	excludeHORing2_

edm::InputTag	FEDRawDataCollection_

edm::EDGetTokenT < FEDRawDataCollection >	FEDRawDataCollectionToken_

MonitorElement *	h_invalid_bcn

MonitorElement *	h_invalid_orbitnumMod103

MonitorElement *	h_valid_digis

int	hbcount_

bool	hbhedcsON

DigiHists	hbHists

MonitorElement *	HBocc_vs_LB

int	hecount_

DigiHists	heHists

MonitorElement *	HEocc_vs_LB

int	hfcount_

bool	hfdcsON

DigiHists	hfHists

int	HFlumibad

MonitorElement *	HFM_shape

MonitorElement *	HFocc_vs_LB

MonitorElement *	HFP_shape

MonitorElement *	HFtiming_etaProfile

MonitorElement *	HFtiming_occupancy2D

MonitorElement *	HFtiming_totaltime2D

edm::InputTag	hltresultsLabel_

int	HO0bad

int	HO12bad

int	hocount_

DigiHists	hoHists

MonitorElement *	HOocc_vs_LB

double	HT_HFM_

double	HT_HFP_

int	knownbadQPLLs

int	maxdigisizeHBHE_

int	maxdigisizeHF_

int	maxdigisizeHO_

std::vector< std::string >	MinBiasHLTBits_

int	mindigisizeHBHE_

int	mindigisizeHF_

int	mindigisizeHO_

int	occupancyErrorEta [85]

int	occupancyErrorEtaPhi [85][72][4]

int	occupancyErrorPhi [72]

int	occupancyEta [85]

int	occupancyEtaPhi [85][72][4]

int	occupancyPhi [72]

int	occupancySpigot [40][36]

int	occupancyVME [40][18]

bool	passedMinBiasHLT_
	Methods, variables accessible only within class code. More...

std::map< HcalDetId, std::vector< double > >	PedestalsByCapId_

double	pedSubtractedADC_ [10]

MonitorElement *	ProblemDigisInLastNLB_HBHEHF_alarm

bool	setupDone_

int	shapeThresh_

int	shapeThreshHB_

int	shapeThreshHE_

int	shapeThreshHF_

int	shapeThreshHO_

bool	shutOffOrbitTest_

edm::EDGetTokenT < HBHEDigiCollection >	tok_hbhe_

edm::EDGetTokenT < HFDigiCollection >	tok_hf_

edm::EDGetTokenT < HFRecHitCollection >	tok_hfrec_

edm::EDGetTokenT < HODigiCollection >	tok_ho_

edm::EDGetTokenT < FEDRawDataCollection >	tok_raw_

edm::EDGetTokenT < edm::TriggerResults >	tok_trigger_

edm::EDGetTokenT < HcalUnpackerReport >	tok_unpack_

uint64_t	uniqcounter [85][72][4]

uint64_t	uniqcounter2 [85][72][4]

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

typedef CacheTypes::GlobalCache	GlobalCache

typedef AbilityChecker< T...>	HasAbility

typedef CacheTypes::LuminosityBlockCache	LuminosityBlockCache

typedef LuminosityBlockContextT < LuminosityBlockCache, RunCache, GlobalCache >	LuminosityBlockContext

typedef CacheTypes::LuminosityBlockSummaryCache	LuminosityBlockSummaryCache

typedef CacheTypes::RunCache	RunCache

typedef RunContextT< RunCache, GlobalCache >	RunContext

typedef CacheTypes::RunSummaryCache	RunSummaryCache

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

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

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

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

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

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

static void	fillDescriptions (ConfigurationDescriptions &descriptions)

static void	prevalidate (ConfigurationDescriptions &descriptions)

Protected Member Functions inherited from HcalBaseDQMonitor
virtual void	cleanup (void)

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

void	getLogicalMap (const edm::EventSetup &c)

bool	IsAllowedCalibType ()

bool	LumiInOrder (int lumisec)

void	SetupEtaPhiHists (DQMStore::IBooker &ib, EtaPhiHists &hh, std::string Name, std::string Units)

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

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

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

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

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

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

void	consumesMany (const TypeToGet &id)

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

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

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

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

Protected Attributes inherited from HcalBaseDQMonitor
std::vector< int >	AllowedCalibTypes_

int	badChannelStatusMask_

int	currentLS

int	currenttype_

int	debug_

bool	enableCleanup_

bool	eventAllowed_

bool	HBpresent_

bool	HEpresent_

bool	HFpresent_

bool	HOpresent_

int	ievt_

std::map< unsigned int, int >	KnownBadCells_

int	levt_

HcalLogicalMap *	logicalMap_

bool	makeDiagnostics_

MonitorElement *	meIevt_

MonitorElement *	meLevt_

bool	mergeRuns_

MonitorElement *	meTevt_

MonitorElement *	meTevtHist_

bool	needLogicalMap_

int	NLumiBlocks_

bool	Online_

std::string	prefixME_

MonitorElement *	ProblemsCurrentLB

MonitorElement *	ProblemsVsLB

MonitorElement *	ProblemsVsLB_HB

MonitorElement *	ProblemsVsLB_HBHEHF

MonitorElement *	ProblemsVsLB_HE

MonitorElement *	ProblemsVsLB_HF

MonitorElement *	ProblemsVsLB_HO

bool	skipOutOfOrderLS_

std::string	subdir_

int	tevt_

Detailed Description

Author: J. Temple - Univ. of Maryland

Definition at line 68 of file HcalDigiMonitor.h.

Constructor & Destructor Documentation

HcalDigiMonitor::HcalDigiMonitor ( const edm::ParameterSet & ps )

Definition at line 12 of file HcalDigiMonitor.cc.

                                                          :HcalBaseDQMonitor(ps)
 {
   Online_                = ps.getUntrackedParameter<bool>("online",false);
   mergeRuns_             = ps.getUntrackedParameter<bool>("mergeRuns",false);
   enableCleanup_         = ps.getUntrackedParameter<bool>("enableCleanup",false);
   debug_                 = ps.getUntrackedParameter<int>("debug",0);
   prefixME_              = ps.getUntrackedParameter<std::string>("subSystemFolder","Hcal/");
   if (prefixME_.substr(prefixME_.size()-1,prefixME_.size())!="/")
     prefixME_.append("/");
   subdir_                = ps.getUntrackedParameter<std::string>("TaskFolder","DigiMonitor_Hcal"); 
   if (subdir_.size()>0 && subdir_.substr(subdir_.size()-1,subdir_.size())!="/")
     subdir_.append("/");
   subdir_=prefixME_+subdir_;
   AllowedCalibTypes_     = ps.getUntrackedParameter<std::vector<int> > ("AllowedCalibTypes");
   skipOutOfOrderLS_      = ps.getUntrackedParameter<bool>("skipOutOfOrderLS",true);
   NLumiBlocks_           = ps.getUntrackedParameter<int>("NLumiBlocks",4000);
   makeDiagnostics_       = ps.getUntrackedParameter<bool>("makeDiagnostics",false);
   digiLabel_             = ps.getUntrackedParameter<edm::InputTag>("digiLabel");
   FEDRawDataCollection_  = ps.getUntrackedParameter<edm::InputTag>("FEDRawDataCollection");
   shapeThresh_           = ps.getUntrackedParameter<int>("shapeThresh",20);
   //shapeThresh_ is used for plotting pulse shapes for all digis with pedestal-subtracted ADC sum > shapeThresh_;
   shapeThreshHB_ = ps.getUntrackedParameter<int>("shapeThreshHB",shapeThresh_);
   shapeThreshHE_ = ps.getUntrackedParameter<int>("shapeThreshHE",shapeThresh_);
   shapeThreshHF_ = ps.getUntrackedParameter<int>("shapeThreshHF",shapeThresh_);
   shapeThreshHO_ = ps.getUntrackedParameter<int>("shapeThreshHO",shapeThresh_);
   
   hltresultsLabel_       = ps.getUntrackedParameter<edm::InputTag>("HLTResultsLabel");
   MinBiasHLTBits_        = ps.getUntrackedParameter<std::vector<std::string> >("MinBiasHLTBits");
   excludeHORing2_       = ps.getUntrackedParameter<bool>("excludeHORing2",false);
   excludeHO1P02_        = ps.getUntrackedParameter<bool>("excludeHO1P02",false);
   excludeBadQPLLs_      = ps.getUntrackedParameter<bool>("excludeBadQPLL",false);
 
   if (debug_>0)
     std::cout <<"<HcalDigiMonitor> Digi shape ADC threshold set to: >" << shapeThresh_ <<" counts above nominal pedestal (3*10)"<< std::endl;
   
   // Specify which tests to run when looking for problem digis
   digi_checkoccupancy_ = ps.getUntrackedParameter<bool>("checkForMissingDigis",false); // off by default -- checked by dead cell monitor
   digi_checkcapid_     = ps.getUntrackedParameter<bool>("checkCapID",true);
   digi_checkdigisize_  = ps.getUntrackedParameter<bool>("checkDigiSize",true);
   digi_checkadcsum_    = ps.getUntrackedParameter<bool>("checkADCsum",true);
   digi_checkdverr_     = ps.getUntrackedParameter<bool>("checkDVerr",true);
   mindigisizeHBHE_     = ps.getUntrackedParameter<int>("minDigiSizeHBHE",1);
   maxdigisizeHBHE_     = ps.getUntrackedParameter<int>("maxDigiSizeHBHE",10);
   mindigisizeHO_       = ps.getUntrackedParameter<int>("minDigiSizeHO",1);
   maxdigisizeHO_       = ps.getUntrackedParameter<int>("maxDigiSizeHO",10);
   mindigisizeHF_       = ps.getUntrackedParameter<int>("minDigiSizeHF",1);
   maxdigisizeHF_       = ps.getUntrackedParameter<int>("maxDigiSizeHF",10);
 
 
   badChannelStatusMask_   = ps.getUntrackedParameter<int>("BadChannelStatusMask",
                                                           ps.getUntrackedParameter<int>("BadChannelStatusMask",
                                             (1<<HcalChannelStatus::HcalCellDead)));  // identify channel status values to mask
   if (debug_>1)
     {
       std::cout <<"<HcalDigiMonitor> Checking for the following problems:"<<std::endl; 
       if (digi_checkcapid_) std::cout <<"\tChecking that cap ID rotation is correct;"<<std::endl;
       if (digi_checkdigisize_)
     {
       std::cout <<"\tChecking that HBHE digi size is between ["<<mindigisizeHBHE_<<" - "<<maxdigisizeHBHE_<<"];"<<std::endl;
       std::cout <<"\tChecking that HO digi size is between ["<<mindigisizeHO_<<" - "<<maxdigisizeHO_<<"];"<<std::endl;
       std::cout <<"\tChecking that HF digi size is between ["<<mindigisizeHF_<<" - "<<maxdigisizeHF_<<"];"<<std::endl;
     }
       if (digi_checkadcsum_) std::cout <<"\tChecking that ADC sum of digi is greater than 0;"<<std::endl; 
       if (digi_checkdverr_) std::cout <<"\tChecking that data valid bit is true and digi error bit is false;\n"<<std::endl;
     }
   
   shutOffOrbitTest_ = ps.getUntrackedParameter<bool>("shutOffOrbitTest",false);
   DigiMonitor_ExpectedOrbitMessageTime_=ps.getUntrackedParameter<int>("ExpectedOrbitMessageTime",3559); // -1 means that orbit mismatches won't be checked
 
   HFtiming_totaltime2D=0;
   HFtiming_occupancy2D=0;
   HFtiming_etaProfile=0;
   HFP_shape=0;
   HFM_shape=0;
   setupDone_=false;
 
   // register for data access
   tok_raw_ = consumes<FEDRawDataCollection>(FEDRawDataCollection_);
   tok_hbhe_ = consumes<HBHEDigiCollection>(digiLabel_);
   tok_ho_ = consumes<HODigiCollection>(digiLabel_);
   tok_hf_ = consumes<HFDigiCollection>(digiLabel_);
   tok_unpack_ = consumes<HcalUnpackerReport>(digiLabel_);
   tok_trigger_ = consumes<edm::TriggerResults>(hltresultsLabel_);
   tok_hfrec_   = consumes<HFRecHitCollection>(ps.getUntrackedParameter<edm::InputTag>("hfRechitLabel"));
 
   //set Token(-s)
   dcsStatusToken_ = consumes<DcsStatusCollection>(std::string("scalersRawToDigi"));
   FEDRawDataCollectionToken_ = consumes<FEDRawDataCollection>(FEDRawDataCollection_);
 }

HcalDigiMonitor::~HcalDigiMonitor ( )

Definition at line 103 of file HcalDigiMonitor.cc.

103 {}

Member Function Documentation

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

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 449 of file HcalDigiMonitor.cc.

References funct::abs(), HcalBaseDQMonitor::analyze(), edm::EventBase::bunchCrossing(), conditions_, gather_cfg::cout, FEDRawData::data(), dcsStatusToken_, HcalBaseDQMonitor::debug_, DigiExpectedSize, digiLabel_, FEDRawDataCollection_, FEDRawDataCollectionToken_, MonitorElement::Fill(), edm::Event::getByToken(), HcalHTRData::getNDD(), HcalDCCHeader::getSourceId(), HcalDCCHeader::getSpigotData(), HcalDCCHeader::getSpigotPresent(), DcsStatus::HBHEa, DcsStatus::HBHEb, DcsStatus::HBHEc, hbhedcsON, HF, DcsStatus::HF, hfdcsON, hltresultsLabel_, HT_HFM_, HT_HFP_, i, HcalBaseDQMonitor::ievt_, HcalBaseDQMonitor::IsAllowedCalibType(), edm::HandleBase::isValid(), relval_steps::k, HcalBaseDQMonitor::LumiInOrder(), edm::EventBase::luminosityBlock(), maxdigisizeHBHE_, maxdigisizeHF_, maxdigisizeHO_, FEDNumbering::MAXHCALFEDID, FEDNumbering::MAXHCALuTCAFEDID, MinBiasHLTBits_, mindigisizeHBHE_, mindigisizeHF_, mindigisizeHO_, FEDNumbering::MINHCALFEDID, FEDNumbering::MINHCALuTCAFEDID, edm::EventBase::orbitNumber(), passedMinBiasHLT_, processEvent(), zeeHLT_cff::report, FEDRawData::size(), edm::TriggerNames::size(), HcalDCCHeader::SPIGOT_COUNT, theHFEtaBounds, tok_hbhe_, tok_hf_, tok_hfrec_, tok_ho_, tok_trigger_, tok_unpack_, edm::TriggerNames::triggerName(), and edm::Event::triggerNames().

 {
   HcalBaseDQMonitor::analyze(e, s);
 
   if (!IsAllowedCalibType()) return;
   if (LumiInOrder(e.luminosityBlock())==false) return;
 
   // Get HLT trigger information for HF timing study
   passedMinBiasHLT_=false;
 
   // check if detectors whether they were ON
   edm::Handle<DcsStatusCollection> dcsStatus;
   e.getByToken(dcsStatusToken_, dcsStatus);
   
   if (dcsStatus.isValid() && dcsStatus->size() != 0) 
     {      
       if ((*dcsStatus)[0].ready(DcsStatus::HBHEa) &&
       (*dcsStatus)[0].ready(DcsStatus::HBHEb) &&   
       (*dcsStatus)[0].ready(DcsStatus::HBHEc))
     {   
       hbhedcsON = true;
       if (debug_) std::cout << "hbhe on" << std::endl;
     } 
       else hbhedcsON = false;
 
       if ((*dcsStatus)[0].ready(DcsStatus::HF))
     {
       hfdcsON = true;
       if (debug_) std::cout << "hf on" << std::endl;
     } 
       else hfdcsON = false;
     }
 
   edm::Handle<edm::TriggerResults> hltRes;
   if (!(e.getByToken(tok_trigger_,hltRes)))
     {
       if (debug_>0) edm::LogWarning("HcalDigiMonitor")<<" Could not get HLT results with tag "<<hltresultsLabel_<<std::endl;
     }
   else
     {
       const edm::TriggerNames & triggerNames = e.triggerNames(*hltRes);
       const unsigned int nTrig(triggerNames.size());
       for (unsigned int i=0;i<nTrig;++i){
       // repeat for minbias triggers
       for (unsigned int k=0;k<MinBiasHLTBits_.size();++k)
         {
           // if (triggerNames.triggerName(i)==MinBiasHLTBits_[k] && hltRes->accept(i))
           if (triggerNames.triggerName(i).find(MinBiasHLTBits_[k])!=std::string::npos && hltRes->accept(i))
         { 
           passedMinBiasHLT_=true;
           break;
         }
         }
     }
     } //else
   
   // Now get collections we need
   HT_HFP_=0;
   HT_HFM_=0;
   //  bool rechitsFound=false;
   edm::Handle<HFRecHitCollection> hf_rechit;
   if (e.getByToken(tok_hfrec_,hf_rechit))
     {
       //      rechitsFound=true;
       for (HFRecHitCollection::const_iterator HF=hf_rechit->begin();HF!=hf_rechit->end();++HF)
     {
       float en=HF->energy();
       int ieta=HF->id().ieta();
       // ieta for HF starts at 29, so subtract away 29 when computing fEta
       double fEta=fabs(0.5*(theHFEtaBounds[abs(ieta)-28]+theHFEtaBounds[abs(ieta)-29]));
       ieta>0 ?  HT_HFP_+=en/cosh(fEta) : HT_HFM_+=en/cosh(fEta);
     }
     }
   else
     {
       // if no rechits found, form above-threshold plots based only on digi comparison to ADC threshold 
       HT_HFP_=999;
       HT_HFM_=999;
     }
 
   // try to get digis
   edm::Handle<HBHEDigiCollection> hbhe_digi;
   edm::Handle<HODigiCollection> ho_digi;
   edm::Handle<HFDigiCollection> hf_digi;
 
   if (!(e.getByToken(tok_hbhe_,hbhe_digi)))
     {
       edm::LogWarning("HcalDigiMonitor")<< digiLabel_<<" hbhe_digi not available";
       return;
     }
   
   if (!(e.getByToken(tok_hf_,hf_digi)))
     {
       edm::LogWarning("HcalDigiMonitor")<< digiLabel_<<" hf_digi not available";
       return;
     }
   if (!(e.getByToken(tok_ho_,ho_digi)))
     {
       edm::LogWarning("HcalDigiMonitor")<< digiLabel_<<" ho_digi not available";
       return;
     }
   edm::Handle<HcalUnpackerReport> report;  
   if (!(e.getByToken(tok_unpack_,report)))
     {
       edm::LogWarning("HcalDigiMonitor")<< digiLabel_<<" unpacker report not available";
       return;
     }
   // try to get Raw Data
   edm::Handle<FEDRawDataCollection> rawraw;
   if ( !(e.getByToken(FEDRawDataCollectionToken_, rawraw)))
     {
       edm::LogWarning("HcalRawDataMonitor")<<" raw data with label "<<FEDRawDataCollection_<<" not available";
       return;
     }
 
   // get the DCC header & trailer (or bail out)
   // this needs to be done better, for now basically getting only one number per HBHE/HO/HF
   // will create a map (dccid, spigot) -> DetID to be used in process_Digi later
   for (int i=FEDNumbering::MINHCALFEDID; 
           i<=FEDNumbering::MAXHCALuTCAFEDID; i++) {
       if (i>FEDNumbering::MAXHCALFEDID && i<FEDNumbering::MINHCALuTCAFEDID)
           continue;
     const FEDRawData& fed = rawraw->FEDData(i);
     if (fed.size()<12) continue;  //At least the size of headers and trailers of a DCC.    
 
     const HcalDCCHeader* dccHeader=(const HcalDCCHeader*)(fed.data());
     if(!dccHeader) return;
     if (debug_>0)
         std::cout << "### Processing FED: " << i << std::endl;
 
     //  For uTCA spigos are useless => by default we have digisize = 4
     //  As of 20.05.2015
     //  HF = 2
     if ((i>=1118 && i<=1122) ||
             (i>=718 && i<=723))
     {
         mindigisizeHF_ = 4;
         maxdigisizeHF_ = 4;
         DigiExpectedSize->Fill(2, 4);
         continue;
     }
 
     //  VME readout contains Number of Time Samples per Digi
     //  uTCA doesn't!
     HcalHTRData htr;  
     for (int spigot=0; spigot<HcalDCCHeader::SPIGOT_COUNT; spigot++) {    
       if (!dccHeader->getSpigotPresent(spigot)) continue;
       
       // Load the given decoder with the pointer and length from this spigot.
       // i.e.     initialize htr, within dcc raw data size.
       dccHeader->getSpigotData(spigot, htr, fed.size()); 
       
       int NTS = htr.getNDD(); //number time slices, in precision channels
       if (debug_>0)
           std::cout << "### Number of TS=" << NTS << std::endl;
       if (NTS==0) continue; // no DAQ data in this HTR (fully zero-suppressed)
       int dccid=dccHeader->getSourceId();
       
       if(dccid==720 && (spigot==12 || spigot==13)) continue; // calibration HTR
       if(dccid==722 && (spigot==12 || spigot==13)) continue; // ZDC HTR
 
       int subdet = -1;
       
       if(dccid >= 700 && dccid<=717)  { subdet = 0; mindigisizeHBHE_ = NTS; maxdigisizeHBHE_ = NTS; } // HBHE
       if((dccid >= 1118 && dccid<=1122) || 
               (dccid>=718 && dccid<=723))  
       { subdet = 2; mindigisizeHF_ = NTS; maxdigisizeHF_ = NTS; }     // HF
       if(dccid >= 724 && dccid<=731)  { subdet = 1; mindigisizeHO_ = NTS; maxdigisizeHO_ = NTS; }     // HO
       
       DigiExpectedSize->Fill(subdet,int(NTS),1);
     }
   }
 
   // all objects grabbed; event is good
   if (debug_>1) std::cout <<"\t<HcalDigiMonitor::analyze>  Processing good event! event # = "<<ievt_<<std::endl;
 
 //  HcalBaseDQMonitor::analyze(e,s); // base class increments ievt_, etc. counters
 
   // Digi collection was grabbed successfully; process the Event
   processEvent(*hbhe_digi, *ho_digi, *hf_digi, *conditions_,
            *report, e.orbitNumber(),e.bunchCrossing());
   
 } //void HcalDigiMonitor::analyze(...)

void HcalDigiMonitor::beginLuminosityBlock	(	const edm::LuminosityBlock &	lumiSeg,
		const edm::EventSetup &	c
	)

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 1177 of file HcalDigiMonitor.cc.

References HcalBaseDQMonitor::beginLuminosityBlock(), HcalBaseDQMonitor::ProblemsCurrentLB, and MonitorElement::Reset().

 {
   HcalBaseDQMonitor::beginLuminosityBlock(lumiSeg,c);
   ProblemsCurrentLB->Reset();
 }

void HcalDigiMonitor::bookHistograms	(	DQMStore::IBooker &	ib,
		const edm::Run &	run,
		const edm::EventSetup &	c
	)

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 342 of file HcalDigiMonitor.cc.

References HcalQIECoder::adc(), HcalBaseDQMonitor::badChannelStatusMask_, HcalBaseDQMonitor::bookHistograms(), conditions_, gather_cfg::cout, HcalBaseDQMonitor::debug_, edm::EventSetup::get(), HcalCondObjectContainer< Item >::getAllChannels(), reco::JetExtendedAssociation::getValue(), HcalCondObjectContainer< Item >::getValues(), DetId::Hcal, i, HcalBaseDQMonitor::KnownBadCells_, HcalBaseDQMonitor::mergeRuns_, AlCaHLTBitMon_ParallelJobs::p, HcalCalibrations::pedestal(), PedestalsByCapId_, edm::ESHandle< class >::product(), reset(), setup(), ntuplemaker::status, and HcalBaseDQMonitor::tevt_.

 {
   HcalBaseDQMonitor::bookHistograms(ib,run,c);
   if (mergeRuns_ && tevt_>0) return; // don't reset counters if merging runs
 
   if (debug_>1) std::cout <<"\t<HcalDigiMonitor::bookHistograms> Getting conditions from DB!"<<std::endl;
   c.get<HcalDbRecord>().get(conditions_);
 
   // Get all pedestals by Cap ID
   edm::ESHandle<HcalChannelQuality> p;
   c.get<HcalChannelQualityRcd>().get("withTopo",p);
   const HcalChannelQuality *chanquality= p.product();
   std::vector<DetId> mydetids = chanquality->getAllChannels();
   PedestalsByCapId_.clear();
 
   for (std::vector<DetId>::const_iterator chan = mydetids.begin();chan!=mydetids.end();++chan)
     {
       if (chan->det()!=DetId::Hcal) continue; // not hcal
       std::vector <double> peds;  // could be ints, right?
       peds.clear();
       HcalCalibrations calibs=conditions_->getHcalCalibrations(*chan);
       const HcalQIECoder* channelCoder = conditions_->getHcalCoder(*chan);
       const HcalQIEShape* shape = conditions_->getHcalShape(channelCoder);
       //double total=0; // use this is we want to calculate average pedestal value
       for (int capid=0;capid<4;++capid)
     {
       // temp_ADC should be an int, right?
       double temp_ADC=channelCoder->adc(*shape,(float)calibs.pedestal(capid),capid);
       peds.push_back(temp_ADC);
       //total=total+temp_ADC;
     }
       //for (int capid=0;capid<4;++capid) peds.push_back(total/4.); // use this if we just want to use average value
       PedestalsByCapId_[*chan]=peds;
     } // loop on DetIds
 
   if (tevt_==0) this->setup(ib); // create all histograms; not necessary if merging runs together
   if (mergeRuns_==false) this->reset(); // call reset at start of all runs
 
   // Get known dead cells for this run
   KnownBadCells_.clear();
   if (badChannelStatusMask_>0)
     {
       edm::ESHandle<HcalChannelQuality> p;
       c.get<HcalChannelQualityRcd>().get("withTopo",p);
       const HcalChannelQuality* chanquality= p.product();
       std::vector<DetId> mydetids = chanquality->getAllChannels();
       for (std::vector<DetId>::const_iterator i = mydetids.begin();
        i!=mydetids.end();
        ++i)
     {
       if (i->det()!=DetId::Hcal) continue; // not an hcal cell
       HcalDetId id=HcalDetId(*i);
       int status=(chanquality->getValues(id))->getValue();
       if ((status & badChannelStatusMask_))
         {
           KnownBadCells_[id.rawId()]=status;
         }
     } 
     } // if (badChannelStatusMask_>0)
 
 } // void HcalDigiMonitor::bookHistograms()

void HcalDigiMonitor::endJob ( void )

Definition at line 154 of file HcalDigiMonitor.cc.

References HcalBaseDQMonitor::cleanup(), gather_cfg::cout, HcalBaseDQMonitor::debug_, and HcalBaseDQMonitor::enableCleanup_.

 {
   if (debug_>0) std::cout <<"HcalDigiMonitor::endJob()"<<std::endl;
   if (enableCleanup_) cleanup(); // when do we force cleanup?
 }

void HcalDigiMonitor::endLuminosityBlock	(	const edm::LuminosityBlock &	lumiSeg,
		const edm::EventSetup &	c
	)

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 1184 of file HcalDigiMonitor.cc.

References alarmer_counter_, fill_Nevents(), hbhedcsON, HcalBaseDQMonitor::HBpresent_, HcalBaseDQMonitor::HEpresent_, hfdcsON, HcalBaseDQMonitor::HFpresent_, HcalBaseDQMonitor::LumiInOrder(), edm::LuminosityBlockBase::luminosityBlock(), ProblemDigisInLastNLB_HBHEHF_alarm, HcalBaseDQMonitor::ProblemsCurrentLB, MonitorElement::Reset(), and zeroCounters().

 {
   if (LumiInOrder(lumiSeg.luminosityBlock())==false) return;
 
   // Reset current LS histogram
   if (ProblemsCurrentLB)
     ProblemsCurrentLB->Reset();
   
   ProblemDigisInLastNLB_HBHEHF_alarm->Reset();
 
   //increase the number of LS counting, for alarmer. Only make alarms for HBHE
   if(hbhedcsON == true && hfdcsON == true && HBpresent_ == 1 && HEpresent_ == 1 && HFpresent_ == 1)
     ++alarmer_counter_; 
   else 
     alarmer_counter_ = 0;
 
   fill_Nevents();
 
   zeroCounters(); // reset counters of good/bad digis
  
   return;
 }

void HcalDigiMonitor::endRun	(	const edm::Run &	run,
		const edm::EventSetup &	c
	)

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 149 of file HcalDigiMonitor.cc.

 {
   // Anything to do here?
 }

void HcalDigiMonitor::fill_Nevents ( )

private

Definition at line 1208 of file HcalDigiMonitor.cc.

Referenced by endLuminosityBlock().

 {
   if (debug_>0)
     std::cout <<"<HcalDigiMonitor> Calling fill_Nevents for event  "<<tevt_<< " (processed events = "<<ievt_<<")"<<std::endl;
   int iPhi, iEta, iDepth;
   //  bool valid=false;
 
   // Fill problems vs. lumi block plots
   ProblemsVsLB->Fill(currentLS,hbHists.count_bad+heHists.count_bad+hoHists.count_bad+hfHists.count_bad);
   ProblemsVsLB_HB->Fill(currentLS,hbHists.count_bad);
   ProblemsVsLB_HE->Fill(currentLS,heHists.count_bad);
   ProblemsVsLB_HO->Fill(currentLS,hoHists.count_bad);
   ProblemsVsLB_HF->Fill(currentLS,hfHists.count_bad);
   ProblemsVsLB_HBHEHF->Fill(currentLS,hbHists.count_bad+heHists.count_bad+hfHists.count_bad);
 
   if( hbHists.count_bad+heHists.count_bad+hfHists.count_bad-knownbadQPLLs< 50 )
     alarmer_counter_ = 0;
       
   if( alarmer_counter_ >= 5 )
     ProblemDigisInLastNLB_HBHEHF_alarm->Fill( std::min(int(hbHists.count_bad+heHists.count_bad+hfHists.count_bad), 99) );
 
   // Fill the number of problem digis in each channel
   if (ProblemsCurrentLB)
     {      
       ProblemsCurrentLB->Fill(-1,-1,1);  // event counter
       ProblemsCurrentLB->Fill(0,0,hbHists.count_bad);
       ProblemsCurrentLB->Fill(1,0,heHists.count_bad);
       ProblemsCurrentLB->Fill(2,0,hoHists.count_bad);
       ProblemsCurrentLB->Fill(3,0,hfHists.count_bad);
       ProblemsCurrentLB->Fill(4,0,HO0bad);
       ProblemsCurrentLB->Fill(5,0,HO12bad);
       ProblemsCurrentLB->Fill(6,0,HFlumibad);
     }
 
   // Fill plots of sums of adjacent digi samples
   for (int i=0;i<10;++i)
     {
       for (int j=0;j<50;++j)
     {
       if (hbHists.tssumplus[j][i]>0) hbHists.TS_sum_plus[i]->Fill(j, hbHists.tssumplus[j][i]);
       if (hbHists.tssumminus[j][i]>0) hbHists.TS_sum_minus[i]->Fill(j, hbHists.tssumminus[j][i]);     
       if (heHists.tssumplus[j][i]>0) heHists.TS_sum_plus[i]->Fill(j, heHists.tssumplus[j][i]); 
       if (heHists.tssumminus[j][i]>0) heHists.TS_sum_minus[i]->Fill(j, heHists.tssumminus[j][i]); 
       if (hoHists.tssumplus[j][i]>0) hoHists.TS_sum_plus[i]->Fill(j, hoHists.tssumplus[j][i]); 
       if (hoHists.tssumminus[j][i]>0) hoHists.TS_sum_minus[i]->Fill(j, hoHists.tssumminus[j][i]); 
       if (hfHists.tssumplus[j][i]>0) hfHists.TS_sum_plus[i]->Fill(j, hfHists.tssumplus[j][i]); 
       if (hfHists.tssumminus[j][i]>0) hfHists.TS_sum_minus[i]->Fill(j, hfHists.tssumminus[j][i]); 
     }
     } // for (int i=0;i<10;++i)
 
   for (int i=0;i<DIGI_NUM;++i)
     {
       if (diginum[i]>0) DigiNum->Fill(i, diginum[i]);
       if (i>=DIGI_SUBDET_NUM) continue;
 
       if (hbHists.count_BQ[i]>0) hbHists.BQ->Fill(i, hbHists.count_BQ[i]);
       if (heHists.count_BQ[i]>0) heHists.BQ->Fill(i, heHists.count_BQ[i]);
       if (hoHists.count_BQ[i]>0) hoHists.BQ->Fill(i, hoHists.count_BQ[i]);
       if (hfHists.count_BQ[i]>0) hfHists.BQ->Fill(i, hfHists.count_BQ[i]);
     }//for int i=0;i<DIGI_NUM;++i)
 
 
   // Fill data-valid/error plots and capid plots
   for (int i=0;i<4;++i)
     {
       if (hbHists.dverr[i]>0) hbHists.DVerr->Fill(i, hbHists.dverr[i]);
       if (heHists.dverr[i]>0) heHists.DVerr->Fill(i, heHists.dverr[i]);
       if (hoHists.dverr[i]>0) hoHists.DVerr->Fill(i, hoHists.dverr[i]);
       if (hfHists.dverr[i]>0) hfHists.DVerr->Fill(i, hfHists.dverr[i]);
 
       if (hbHists.capid[i]>0) hbHists.CapID->Fill(i, hbHists.capid[i]);
       if (heHists.capid[i]>0) heHists.CapID->Fill(i, heHists.capid[i]);
       if (hoHists.capid[i]>0) hoHists.CapID->Fill(i, hoHists.capid[i]);
       if (hfHists.capid[i]>0) hfHists.CapID->Fill(i, hfHists.capid[i]);
     }
 
   for (int i=0;i<200;++i)
     {
       if (hbHists.adc[i]>0) hbHists.ADC->Fill(i, hbHists.adc[i]);
 
       if (heHists.adc[i]>0) heHists.ADC->Fill(i, heHists.adc[i]);
       if (hoHists.adc[i]>0) hoHists.ADC->Fill(i, hoHists.adc[i]);
       if (hfHists.adc[i]>0) hfHists.ADC->Fill(i, hfHists.adc[i]);
 
       if (hbHists.adcsum[i]>0) hbHists.ADCsum->Fill(i, hbHists.adcsum[i]);
       if (heHists.adcsum[i]>0) heHists.ADCsum->Fill(i, heHists.adcsum[i]);
       if (hoHists.adcsum[i]>0) hoHists.ADCsum->Fill(i, hoHists.adcsum[i]);
       if (hfHists.adcsum[i]>0) hfHists.ADCsum->Fill(i, hfHists.adcsum[i]);
     }
 
   for (int i = 0; i < 15; ++i)
     {
       if (hbHists.fibbcnoff[i]>0) hbHists.fibBCNOff->Fill(i-7, 
                               hbHists.fibbcnoff[i]);
       if (heHists.fibbcnoff[i]>0) heHists.fibBCNOff->Fill(i-7, 
                               heHists.fibbcnoff[i]);
       if (hfHists.fibbcnoff[i]>0) hfHists.fibBCNOff->Fill(i-7, 
                               hfHists.fibbcnoff[i]);
       if (hoHists.fibbcnoff[i]>0) hoHists.fibBCNOff->Fill(i-7,
                               hoHists.fibbcnoff[i]);
     }
 
   // Fill plots of bad fraction of digis found
   for (int i=0;i<DIGI_BQ_FRAC_NBINS;++i)
     {
       if (DIGI_BQ_FRAC_NBINS==1) break;
       if (hbHists.count_BQFrac[i]>0) hbHists.BQFrac->Fill(1.*i/(DIGI_BQ_FRAC_NBINS-1), hbHists.count_BQFrac[i]);
       if (heHists.count_BQFrac[i]>0) heHists.BQFrac->Fill(1.*i/(DIGI_BQ_FRAC_NBINS-1), heHists.count_BQFrac[i]);
       if (hoHists.count_BQFrac[i]>0) 
     {
       hoHists.BQFrac->Fill(1.*i/(DIGI_BQ_FRAC_NBINS), hoHists.count_BQFrac[i]);
     }
       if (hfHists.count_BQFrac[i]>0) hfHists.BQFrac->Fill(1.*i/(DIGI_BQ_FRAC_NBINS-1), hfHists.count_BQFrac[i]);
     }//for (int i=0;i<DIGI_BQ_FRAC_NBINS;++i)
 
   // Fill presample plots
   for (int i=0;i<50;++i)
     {
       if (hbHists.count_presample[i]>0) hbHists.presample->Fill(i, hbHists.count_presample[i]);
       if (heHists.count_presample[i]>0) heHists.presample->Fill(i, heHists.count_presample[i]);
       if (hoHists.count_presample[i]>0) hoHists.presample->Fill(i, hoHists.count_presample[i]);
       if (hfHists.count_presample[i]>0) hfHists.presample->Fill(i, hfHists.count_presample[i]);
     } //for (int i=0;i<50;++i)
 
   // Fill shape plots
   for (int i=0;i<10;++i)
     {
       if (hbHists.count_shape[i]>0) hbHists.shape->Fill(i, hbHists.count_shape[i]);
       if (hbHists.count_shapeThresh[i]>0) hbHists.shapeThresh->Fill(i, hbHists.count_shapeThresh[i]);
       if (heHists.count_shape[i]>0) heHists.shape->Fill(i, heHists.count_shape[i]);
       if (heHists.count_shapeThresh[i]>0) heHists.shapeThresh->Fill(i, heHists.count_shapeThresh[i]);
       if (hoHists.count_shape[i]>0) hoHists.shape->Fill(i, hoHists.count_shape[i]);
       if (hoHists.count_shapeThresh[i]>0) hoHists.shapeThresh->Fill(i, hoHists.count_shapeThresh[i]);
       if (hfHists.count_shape[i]>0) hfHists.shape->Fill(i, hfHists.count_shape[i]);
       if (hfHists.count_shapeThresh[i]>0) hfHists.shapeThresh->Fill(i, hfHists.count_shapeThresh[i]);
     }//  for (int i=0;i<10;++i)
 
   // Fill capID difference plots
   for (int i=0;i<8;++i)
     {
       if (hbHists.capIDdiff[i]>0) hbHists.DigiFirstCapID->Fill(i, hbHists.capIDdiff[i]);
       if (heHists.capIDdiff[i]>0) heHists.DigiFirstCapID->Fill(i, heHists.capIDdiff[i]);
       if (hoHists.capIDdiff[i]>0) hoHists.DigiFirstCapID->Fill(i, hoHists.capIDdiff[i]);
       if (hfHists.capIDdiff[i]>0) hfHists.DigiFirstCapID->Fill(i, hfHists.capIDdiff[i]);
     }
 
   // Fill VME plots
   for (int i=0;i<40;++i)
     {
       for (int j=0;j<18;++j)
     {
       if (errorVME[i][j]>0) DigiErrorVME->Fill(i, j,errorVME[i][j]);
       if (occupancyVME[i][j]>0) DigiOccupancyVME->Fill(i, j,occupancyVME[i][j]);
     }
     } //for (int i=0;i<40;++i)
 
   // Fill SPIGOT plots
   for (int i=0;i<HcalDCCHeader::SPIGOT_COUNT;++i)
     {
       for (int j=0;j<36;++j)
     {
       if (errorSpigot[i][j]>0) DigiErrorSpigot->Fill(i, j,errorSpigot[i][j]);
       if (occupancySpigot[i][j]>0) DigiOccupancySpigot->Fill(i, j,occupancySpigot[i][j]);
     }
     } //for (int i=0;i<HcalDCCHeader::SPIGOT_COUNT;++i)
 
   // Loop over subdetectors
   for (int sub=0;sub<4;++sub)
     {
       for (int dsize=0;dsize<20;++dsize)
     {
       if (digisize[dsize][sub]>0)
         DigiSize->Fill(sub,dsize,digisize[dsize][sub]);
     }
     } // for (int sub=0;sub<4;++sub)
 
   // Loop over eta, phi, depth
   for (int d=0;d<4;++d)
     {
       iDepth=d+1;
       DigiErrorsByDepth.depth[d]->setBinContent(0,0,ievt_); // underflow bin contains event counter
       DigiOccupancyByDepth.depth[d]->setBinContent(0,0,ievt_);
       DigiErrorsBadDigiSize.depth[d]->setBinContent(0,0,ievt_);
       DigiErrorsUnpacker.depth[d]->setBinContent(0,0,ievt_);
       DigiErrorsBadFibBCNOff.depth[d]->setBinContent(0,0,ievt_);
 
       for (int phi=0;phi<72;++phi)
     {
       iPhi=phi+1;
       DigiOccupancyPhi->Fill(iPhi,occupancyPhi[phi]);
       for (int eta=0;eta<83;++eta)
         {
           // DigiOccupanyEta uses 'true' ieta (included the overlap at +/- 29)
           iEta=eta-41;
           if (phi==0)
         DigiOccupancyEta->Fill(iEta,occupancyEta[eta]);
           //          valid=false;
     
           // HB
           if (validDetId(HcalBarrel, iEta, iPhi, iDepth))
         {
           //          valid=true;
           if (HBpresent_)
             {
                       int calcEta = CalcEtaBin(HcalBarrel,iEta,iDepth);
 
               DigiOccupancyByDepth.depth[d]->Fill(iEta, iPhi,
                             occupancyEtaPhi[calcEta][phi][d]);
               
               if (makeDiagnostics_)
             {
               DigiErrorsBadCapID.depth[d]->Fill(iEta, iPhi,
                                 badcapID[calcEta][phi][d]);
               DigiErrorsDVErr.depth[d]->Fill(iEta, iPhi,
                              digierrorsdverr[calcEta][phi][d]);
             }
               DigiErrorsBadDigiSize.depth[d]->Fill(iEta, iPhi,
                                baddigisize[calcEta][phi][d]);
               DigiErrorsBadFibBCNOff.depth[d]->Fill(iEta, iPhi,
                                 badFibBCNOff[calcEta][phi][d]);
               DigiErrorsUnpacker.depth[d]->Fill(iEta, iPhi,
                             badunpackerreport[calcEta][phi][d]);
               DigiErrorsByDepth.depth[d]->Fill(iEta, iPhi,
                                baddigis[calcEta][phi][d]);
               // Use this for testing purposes only
               //DigiErrorsByDepth[d]->Fill(iEta, iPhi, ievt_);
             } // if (HBpresent_)
         } // validDetId(HB)
           // HE
           if (validDetId(HcalEndcap, iEta, iPhi, iDepth))
         {
           //          valid=true;
           if (HEpresent_)
             {
                       int calcEta = CalcEtaBin(HcalEndcap,iEta,iDepth);
 
               DigiOccupancyByDepth.depth[d]->Fill(iEta, iPhi,
                             occupancyEtaPhi[calcEta][phi][d]);
               
               if (makeDiagnostics_)
             {
               DigiErrorsBadCapID.depth[d]->Fill(iEta, iPhi,
                                 badcapID[calcEta][phi][d]);
               DigiErrorsDVErr.depth[d]->Fill(iEta, iPhi,
                              digierrorsdverr[calcEta][phi][d]);
             }
               DigiErrorsBadDigiSize.depth[d]->Fill(iEta, iPhi,
                                baddigisize[calcEta][phi][d]);
               DigiErrorsBadFibBCNOff.depth[d]->Fill(iEta, iPhi,
                                 badFibBCNOff[calcEta][phi][d]);
               DigiErrorsUnpacker.depth[d]->Fill(iEta, iPhi,
                             badunpackerreport[calcEta][phi][d]);
               DigiErrorsByDepth.depth[d]->Fill(iEta, iPhi,
                                baddigis[calcEta][phi][d]);
             } // if (HEpresent_)
         } // valid HE found
           // HO
           if (validDetId(HcalOuter,iEta,iPhi,iDepth))
         {
           //          valid=true;
           if (HOpresent_)
             {
                       int calcEta = CalcEtaBin(HcalOuter,iEta,iDepth);
               DigiOccupancyByDepth.depth[d]->Fill(iEta, iPhi,
                               occupancyEtaPhi[calcEta][phi][d]);
               if (makeDiagnostics_)
             {
               DigiErrorsBadCapID.depth[d]->Fill(iEta, iPhi,
                                 badcapID[calcEta][phi][d]);
               DigiErrorsDVErr.depth[d]->Fill(iEta, iPhi,
                              digierrorsdverr[calcEta][phi][d]);
             }
               DigiErrorsBadDigiSize.depth[d]->Fill(iEta, iPhi,
                                baddigisize[calcEta][phi][d]);
               DigiErrorsBadFibBCNOff.depth[d]->Fill(iEta, iPhi,
                                 badFibBCNOff[calcEta][phi][d]);
               DigiErrorsUnpacker.depth[d]->Fill(iEta, iPhi,
                             badunpackerreport[calcEta][phi][d]);
               
               DigiErrorsByDepth.depth[d]->Fill(iEta,iPhi,
                                baddigis[calcEta][phi][d]);
             } // if (HOpresent_)
         }//validDetId(HO)
           // HF
           if (validDetId(HcalForward,iEta,iPhi,iDepth))
         {
           //          valid=true;
           if (HFpresent_)
             {
                       int calcEta = CalcEtaBin(HcalForward,iEta,iDepth);
                       int zside = iEta/abs(iEta);
               DigiOccupancyByDepth.depth[d]->Fill(iEta+zside, iPhi,
                             occupancyEtaPhi[calcEta][phi][d]);
               
               if (makeDiagnostics_)
             {
               DigiErrorsBadCapID.depth[d]->Fill(iEta+zside, iPhi,
                                 badcapID[calcEta][phi][d]);
               DigiErrorsDVErr.depth[d]->Fill(iEta+zside, iPhi,
                              digierrorsdverr[calcEta][phi][d]);
             }
               DigiErrorsBadDigiSize.depth[d]->Fill(iEta+zside, iPhi,
                              baddigisize[calcEta][phi][d]);
               DigiErrorsBadFibBCNOff.depth[d]->Fill(iEta+zside, iPhi,
                              badFibBCNOff[calcEta][phi][d]);
               DigiErrorsUnpacker.depth[d]->Fill(iEta+zside, iPhi,
                             badunpackerreport[calcEta][phi][d]);
               DigiErrorsByDepth.depth[d]->Fill(iEta+zside, iPhi,
                                baddigis[calcEta][phi][d]);
               
             } // if (HFpresent_)
         }
         } // for (int eta=0;...)
     } // for (int phi=0;...)
     } // for (int d=0;...)
 
   // Now fill all the unphysical cell values
   FillUnphysicalHEHFBins(DigiErrorsByDepth);
   if (makeDiagnostics_)
     {
       FillUnphysicalHEHFBins(DigiErrorsBadCapID);
       FillUnphysicalHEHFBins(DigiErrorsDVErr);
     }
   FillUnphysicalHEHFBins(DigiErrorsBadDigiSize);
   FillUnphysicalHEHFBins(DigiOccupancyByDepth);
   FillUnphysicalHEHFBins(DigiErrorsBadFibBCNOff);
   FillUnphysicalHEHFBins(DigiErrorsUnpacker);
 
   //  zeroCounters(); // reset counters of good/bad digis
  
   return;
 } // void HcalDigiMonitor::fill_Nevents()

template<class T >

int HcalDigiMonitor::process_Digi	(	T &	digi,
		DigiHists &	hist,
		int &	firstcap
	)

private

Referenced by processEvent().

template<class DIGI >

int HcalDigiMonitor::process_Digi	(	DIGI &	digi,
		DigiHists &	h,
		int &	firstcap
	)

Definition at line 927 of file HcalDigiMonitor.cc.

References DigiHists::adc, DigiHists::adcsum, badcapID, baddigis, baddigisize, badFibBCNOff, bitUpset(), CalcEtaBin(), DigiHists::capid, DigiHists::capIDdiff, DigiHists::count_bad, DigiHists::count_good, DigiHists::count_presample, DigiHists::count_shape, DigiHists::count_shapeThresh, HcalBaseDQMonitor::currenttype_, digi_checkcapid_, digi_checkdigisize_, digi_checkdverr_, digierrorsdverr, DigiMonitor_ExpectedOrbitMessageTime_, DigiSize, digisize, DigiHists::dverr, errorSpigot, errorVME, alignCSCRings::ff, DigiHists::fibbcnoff, MonitorElement::Fill(), HcalBarrel, HcalEndcap, HcalForward, HcalOuter, HFM_shape, HFP_shape, HFtiming_etaProfile, HFtiming_occupancy2D, HFtiming_totaltime2D, HT_HFM_, HT_HFP_, i, if(), isSiPM(), prof2calltree::last, HcalBaseDQMonitor::makeDiagnostics_, bookConverter::max, maxdigisizeHBHE_, maxdigisizeHF_, maxdigisizeHO_, min(), mindigisizeHBHE_, mindigisizeHF_, mindigisizeHO_, occupancyEta, occupancyEtaPhi, occupancyPhi, occupancySpigot, occupancyVME, hltrates_dqm_sourceclient-live_cfg::offset, HcalBaseDQMonitor::Online_, passedMinBiasHLT_, PedestalsByCapId_, pedSubtractedADC_, shapeThreshHB_, shapeThreshHE_, shapeThreshHF_, shapeThreshHO_, shutOffOrbitTest_, contentValuesCheck::ss, DigiHists::ThreshCount, DigiHists::tssumminus, DigiHists::tssumplus, and uniqcounter.

 {
   int err=0x0;
   bool bitUp = false;
   int ADCcount=0;
 
   int shapeThresh=0;
   
   int mindigisize=1;
   int maxdigisize=10;
 
   if (digi.id().subdet()==HcalBarrel)
     {
       shapeThresh=shapeThreshHB_;
       mindigisize=mindigisizeHBHE_;
       maxdigisize=maxdigisizeHBHE_;
     }
   else if (digi.id().subdet()==HcalEndcap)
     {
       shapeThresh=shapeThreshHE_;
       mindigisize=mindigisizeHBHE_;
       maxdigisize=maxdigisizeHBHE_;
     }
   else if (digi.id().subdet()==HcalOuter)
     {
       shapeThresh=shapeThreshHO_;
       mindigisize=mindigisizeHO_;
       maxdigisize=maxdigisizeHO_;
     }
   else if (digi.id().subdet()==HcalForward)
     {
       shapeThresh=shapeThreshHF_;
       mindigisize=mindigisizeHF_;
       maxdigisize=maxdigisizeHF_;
     }
   int iEta = digi.id().ieta();
   int iPhi = digi.id().iphi();
   int iDepth = digi.id().depth();
   int calcEta = CalcEtaBin(digi.id().subdet(),iEta,iDepth);  
 
   // Check that digi size is correct
   if (digi.size()<mindigisize || digi.size()>maxdigisize)
     {
       if (digi_checkdigisize_) err|=0x1;
       ++baddigisize[calcEta][iPhi-1][iDepth-1];
     }
   // Check digi size; if > 20, increment highest bin of digisize array
   if (digi.size()<20)
     ++digisize[static_cast<int>(digi.size())][digi.id().subdet()-1];
   else
     ++digisize[19][digi.id().subdet()-1];
 
   // loop over time slices of digi to check capID and errors
   ++h.count_presample[digi.presamples()];
 
   // Check CapID rotation
   if (firstcap==-1) firstcap = digi.sample(0).capid();
   int capdif = digi.sample(0).capid() - firstcap;
   //capdif = capdif%3 - capdif/3; // unnecessary?
   // capdif should run from -3 to +3
   if (capdif >-4 && capdif<4)
     ++h.capIDdiff[capdif+3];
   else
       ++h.capIDdiff[7];
 
   int last=-1;
   
   int offset = digi.fiberIdleOffset();
 
   // Only count BCN offset errors if ExpectedOrbitMessage Time is >-1
   // For offline (and thus cfg default), this won't be checked, since
   // we can't keep up to date with changes.
   if (offset != -1000 && DigiMonitor_ExpectedOrbitMessageTime_>-1) 
     {
       // increment counters only for non-zero offsets?
       ++h.fibbcnoff[offset + 7];
       if (offset != 0)
     {
       ++badFibBCNOff[calcEta][iPhi-1][iDepth-1];
       if (shutOffOrbitTest_ == false) err |= 0xF; // not an error if test turned off
     }
     }
 
   int tssum=0;
 
   bool digi_error=false;
 
   const int DigiSize=digi.size();
   for (int i=0;i<10;++i) pedSubtractedADC_[i]=0;
   const int pedSubADCsize=sizeof(pedSubtractedADC_)/sizeof(double);
 
   std::map<HcalDetId, std::vector<double> >::iterator  foundID = PedestalsByCapId_.find(digi.id());
   for (int i=0;i<DigiSize;++i)
     {
       int thisCapid = digi.sample(i).capid();
       if (thisCapid>=0 && thisCapid<4) ++h.capid[thisCapid];
 
       if (makeDiagnostics_)
     {
       if(bitUpset(last,thisCapid)) bitUp=true; // checking capID rotation
       last = thisCapid;
       // Check for digi error bits
       if (digi_checkdverr_)
         {
           if(digi.sample(i).er()) err=(err|0x2);
           if(!digi.sample(i).dv()) err=(err|0x2);
         }
       if ((digi_error==false) && (digi.sample(i).er() || !digi.sample(i).dv()))
         {
           ++digierrorsdverr[calcEta][iPhi-1][iDepth-1];
           digi_error=true; // only count 1 error per digi in this plot
         }
       ++h.dverr[static_cast<int>(2*digi.sample(i).er()+digi.sample(i).dv())];
     } // if (makeDiagnostics_)
 
       h.count_shape[i]+=digi.sample(i).adc();
       
       // Calculate ADC sum of adjacent samples -- still necessary?
       if (i==digi.size()-1) continue;
       tssum= digi.sample(i).adc()+digi.sample(i+1).adc();
       if (tssum<50 && tssum>=0)
     {
       if (iEta>0)
         ++h.tssumplus[tssum][i];
       else
         ++h.tssumminus[tssum][i];
     }
 
       if (digi.sample(i).adc()<0) ++h.adc[0];
       else if (digi.sample(i).adc()<200) ++h.adc[digi.sample(i).adc()];
       else ++h.adc[199];
 
       if (i>=pedSubADCsize) continue; // don't exceed maximum array length when checking digis
       
       if (foundID!=PedestalsByCapId_.end())
     {
       pedSubtractedADC_[i]=digi.sample(i).adc()-(foundID->second)[thisCapid];
       ADCcount+=(int)(digi.sample(i).adc()-(foundID->second)[thisCapid]);
     }
       else
     {
       pedSubtractedADC_[i]=digi.sample(i).adc()-3;
       ADCcount+=digi.sample(i).adc()-3; // default pedestal subtraction of 3 ADC counts
     }
     } // for (int i=0;i<digi.size();++i)
   
   // capid error found
   if(bitUp) 
     {
       if (digi_checkcapid_) err=(err|0x4);
       ++badcapID[calcEta][iPhi-1][iDepth-1];
     }
 
 
   // These plots generally don't get filled, unless we turn off the suppression of bad digis
   if (err>0)
     {
       if(uniqcounter[calcEta][iPhi-1][iDepth-1]<1)  
         {
           ++h.count_bad;
           ++baddigis[calcEta][iPhi-1][iDepth-1];
           ++errorVME[static_cast<int>(2*(digi.elecId().htrSlot()+0.5*digi.elecId().htrTopBottom()))][static_cast<int>(digi.elecId().readoutVMECrateId())];
           ++errorSpigot[static_cast<int>(digi.elecId().spigot())][static_cast<int>(digi.elecId().dccid())];
         }
       uniqcounter[calcEta][iPhi-1][iDepth-1]++; 
 
       return err;
     }
 
   if (ADCcount<0) ADCcount=0;
   if (ADCcount<199)
     ++h.adcsum[ADCcount];
   else
     ++h.adcsum[199]; // effective overflow bin
 
   // require larger threshold to look at pulse shapes
   
   if (ADCcount>shapeThresh && passedMinBiasHLT_  && HT_HFP_>1 && HT_HFM_>1)
     {
       h.ThreshCount->Fill(0,1);
       if (digi.id().subdet()!=HcalOuter || isSiPM(iEta,iPhi, iDepth)==false)
     {
       for (int i=0;i<pedSubADCsize;++i)
         h.count_shapeThresh[i]+=pedSubtractedADC_[i];
     }
     }
 
   // occupancy plots are only filled for good histograms
   ++h.count_good;
   ++occupancyEtaPhi[calcEta][iPhi-1][iDepth-1];
   ++occupancyEta[iEta+41];
   ++occupancyPhi[iPhi-1];
   // htr Slots run from 0-20, incremented by 0.5 for top/bottom
   ++occupancyVME[static_cast<int>(2*(digi.elecId().htrSlot()+0.5*digi.elecId().htrTopBottom()))][static_cast<int>(digi.elecId().readoutVMECrateId())];
   ++occupancySpigot[static_cast<int>(digi.elecId().spigot())][static_cast<int>(digi.elecId().dccid())];
 
   // Pawel's code for HF timing checks -- run only in online mode for non-calib events
   if (digi.id().subdet()==HcalForward 
       && Online_  //only run online 
       && currenttype_==0  // require non-calibration event
       && passedMinBiasHLT_ // require min bias trigger
       )
     {
       int maxtime=-1;
       double maxenergy=-1, fullenergy=0;
       int digisize=digi.size();
       for (int ff=0;ff<digisize;++ff)
     {
       fullenergy+=digi.sample(ff).nominal_fC()-2.5;
       if (digi.sample(ff).nominal_fC()-2.5>maxenergy)
         {
           maxenergy=digi.sample(ff).nominal_fC()-2.5;
           maxtime=ff;
         }
     }
     
       if (maxtime>=2 && maxtime<=5 && maxenergy>20 && maxenergy<100)  // only look between time slices 2-5; anything else should be nonsense
     {
       for (int ff=0;ff<digisize;++ff){
         if(fullenergy>0){
           if(digi.id().ieta()>0)HFP_shape->Fill(ff,(digi.sample(ff).nominal_fC()-2.5)/fullenergy);
           if(digi.id().ieta()<0)HFM_shape->Fill(ff,(digi.sample(ff).nominal_fC()-2.5)/fullenergy);
         }
           }
 
       double time_den=0, time_num=0;
       // form weighted time sum
       int startslice=std::max(0,maxtime-1);
       int endslice=std::min(digisize-1,maxtime+1);
       for (int ss=startslice;ss<=endslice;++ss)
         {
           // subtract 'default' pedestal of 2.5 fC
           time_num+=ss*(digi.sample(ss).nominal_fC()-2.5);
           time_den+=digi.sample(ss).nominal_fC()-2.5;
         }
 
       int myiphi=iPhi;
       if (iDepth==2) ++myiphi;
       if (HFtiming_etaProfile!=0 && time_den!=0)
         HFtiming_etaProfile->Fill(iEta,time_num/time_den);
       if (HFtiming_totaltime2D!=0 && time_den!=0)
         HFtiming_totaltime2D->Fill(iEta,myiphi,time_num/time_den);
       if (HFtiming_occupancy2D!=0 && time_den!=0)
         HFtiming_occupancy2D->Fill(iEta,myiphi,1);
     } //maxtime>-1
     } // if HcalForward
 
   return err;
 } // template <class DIGI> int HcalDigiMonitor::process_Digi

void HcalDigiMonitor::processEvent	(	const HBHEDigiCollection &	hbhe,
		const HODigiCollection &	ho,
		const HFDigiCollection &	hf,
		const HcalDbService &	cond,
		const HcalUnpackerReport &	report,
		int	orN,
		int	bcN
	)

Definition at line 635 of file HcalDigiMonitor.cc.

References funct::abs(), HcalUnpackerReport::bad_quality_begin(), HcalUnpackerReport::bad_quality_end(), baddigis, HcalUnpackerReport::badQualityDigis(), badunpackerreport, edm::SortedCollection< T, SORT >::begin(), CalcEtaBin(), DigiHists::count_bad, DigiHists::count_BQ, DigiHists::count_BQFrac, DigiHists::count_good, counter, HcalBaseDQMonitor::currentLS, HcalDetId::depth(), EtaPhiHists::depth, DIGI_BQ_FRAC_NBINS, DIGI_NUM, DIGI_SUBDET_NUM, DigiBQ, DigiBQFrac, DigiErrorOccupancyByDepth, DigiErrorsBadADCSum, DigiErrorsBadCapID, DigiErrorsBadDigiSize, DigiErrorsBadFibBCNOff, DigiErrorsByDepth, DigiErrorsDVErr, DigiErrorSpigot, DigiErrorsUnpacker, DigiErrorVME, DigiExpectedSize, DigiNum, diginum, DigiOccupancyEta, DigiOccupancyPhi, DigiOccupancySpigot, DigiOccupancyVME, DigiSize, DigiUnpackerErrorCount, DigiUnpackerErrorFrac, edm::SortedCollection< T, SORT >::end(), excludeBadQPLLs_, excludeHO1P02_, excludeHORing2_, MonitorElement::Fill(), h_invalid_bcn, h_invalid_orbitnumMod103, h_valid_digis, hbHists, HBocc_vs_LB, HcalBaseDQMonitor::HBpresent_, HcalBarrel, HcalEndcap, HcalForward, HcalOuter, heHists, HEocc_vs_LB, HcalBaseDQMonitor::HEpresent_, hfHists, HFlumibad, HFocc_vs_LB, HcalBaseDQMonitor::HFpresent_, HO0bad, HO12bad, hoHists, HOocc_vs_LB, HcalBaseDQMonitor::HOpresent_, HBHEDataFrame::id(), HODataFrame::id(), HcalDetId::ieta(), HcalDetId::iphi(), isSiPM(), j, HcalBaseDQMonitor::KnownBadCells_, knownbadQPLLs, process_Digi(), edm::SortedCollection< T, SORT >::size(), HcalDetId::subdet(), uniqcounter2, MonitorElement::update(), and UpdateHists().

Referenced by analyze().

 { 
 
   // Skip events in which minimal good digis found -- still getting some strange (calib?) events through DQM
 
   DigiUnpackerErrorCount->Fill(report.badQualityDigis());
   
   unsigned int allgooddigis= hbhe.size()+ho.size()+hf.size();
 
   // new data format in HCAL marks idle messages in the abort gap as bad capid. 
   // ignore this events. Also, sometimes there are many corrupted digis left 
   // from the QIE reset: ignore if in abort gap
   if(bcN>=3446 && bcN<=3564)
     if( (report.badQualityDigis()>100 && hbhe.size()==0) || (report.badQualityDigis()>1000) )
       return;
 
   // bad threshold:  ignore events in which bad outnumber good by more than 100:1
   // (one RBX in HBHE seems to send valid data occasionally even on QIE resets, which is why we can't just require allgooddigis==0 when looking for events to skip)    
   if ((allgooddigis==0) ||
       (1.*report.badQualityDigis()>100*allgooddigis))
     {
       h_valid_digis->Fill(1);
       if (bcN>-1)
     h_invalid_bcn->Fill(bcN);
       if (orN>-1)
     h_invalid_orbitnumMod103->Fill(orN%103);
       
       return;
     }
   
   h_valid_digis->Fill(0);
 
   // hbHists.count_bad=0;
   // hbHists.count_good=0;
   // heHists.count_bad=0;
   // heHists.count_good=0;
   // hoHists.count_bad=0;
   // hoHists.count_good=0;
   // hfHists.count_bad=0;
   // hfHists.count_good=0;
 
   // int HO0bad=0;
   // int HO12bad=0;
   // int HFlumibad=0;
 
   // Check unpacker report for bad digis
 
   typedef std::vector<DetId> DetIdVector;
 
   for ( DetIdVector::const_iterator baddigi_iter=report.bad_quality_begin(); 
     baddigi_iter != report.bad_quality_end();
     ++baddigi_iter)
     {
       HcalDetId id(baddigi_iter->rawId());
       int rDepth = id.depth();
       int rPhi   = id.iphi();
       int rEta   = id.ieta();
       int binEta = CalcEtaBin(id.subdet(), rEta, rDepth); // why is this here?
       
       if (binEta < 85 && binEta >= 0 
       && (rPhi-1) >= 0 && (rPhi-1)<72 
       && (rDepth-1) >= 0 && (rDepth-1)<4)
     if(uniqcounter2[binEta][rPhi-1][rDepth-1]<1)    
       {
         if (id.subdet()==HcalBarrel) ++hbHists.count_bad;     
         else if (id.subdet()==HcalEndcap) ++heHists.count_bad;
         else if (id.subdet()==HcalForward) 
           {
         ++hfHists.count_bad;
         if (rDepth==1 && (abs(rEta)==33 || abs(rEta)==34)) ++HFlumibad;
         else if (rDepth==2 && (abs(rEta)==35 || abs(rEta)==36)) ++HFlumibad;
           }
         else if (id.subdet()==HcalOuter) 
           {
         // Mark HORing+/-2 channels as present, HO/YB+/-2 has HV off (at 100V).
         if (excludeHORing2_==true && rDepth==4)
           if (abs(rEta)>=11 && abs(rEta)<=15 && !isSiPM(rEta,rPhi,rDepth)) continue;
         
         if (excludeHO1P02_==true)
           if( (rEta>4 && rEta<10) && (rPhi<=10 || rPhi>70) ) continue;
         
         if (KnownBadCells_.find(id)!=KnownBadCells_.end()) continue;
         
         ++hoHists.count_bad;
         if (abs(rEta)<5) ++HO0bad;
         else ++HO12bad;
           }
         else 
           continue; // skip anything that isn't HB, HE, HO, HF
         // extra protection against nonsensical values -- prevents occasional crashes
         
         ++badunpackerreport[binEta][rPhi-1][rDepth-1];
         ++baddigis[binEta][rPhi-1][rDepth-1];  
         
         // QPLL unlocking channels, have to ignore unpacker errors (fix requires opening CMS)
         bool HEM15A = true ? (id.subdet()==HcalEndcap && (rPhi>56 && rPhi<59 && rEta<0)) : false;
         bool HEM15B = true ? (id.subdet()==HcalEndcap && (rPhi>54 && rPhi<57 && rEta<0)) : false;
         bool HBP14A = true ? (id.subdet()==HcalBarrel && (rPhi>50 && rPhi<53 && rEta>0)) : false;
 
         if(excludeBadQPLLs_ && rDepth==1)
           if( HEM15A || HEM15B || HBP14A )
         ++knownbadQPLLs;
         
         uniqcounter2[binEta][rPhi-1][rDepth-1]++;
       }
     }
 
   int firsthbcap=-1;
   int firsthecap=-1;
   int firsthocap=-1;
   int firsthfcap=-1;
   
   for (HBHEDigiCollection::const_iterator j=hbhe.begin(); j!=hbhe.end(); ++j)
     {
     const HBHEDataFrame digi = (const HBHEDataFrame)(*j);
     
     if (digi.id().subdet()==HcalBarrel)
       {
         if (!HBpresent_) continue;
         if (KnownBadCells_.find(digi.id())!=KnownBadCells_.end()) continue;
         
         process_Digi(digi, hbHists, firsthbcap);
 
       }
     else if (digi.id().subdet()==HcalEndcap)
       {
         if (!HEpresent_) continue;
         process_Digi(digi, heHists,firsthecap);
       } 
     }
 
   // // Fill good digis vs lumi block; also fill bad errors?
   HBocc_vs_LB->Fill(currentLS,hbHists.count_good);
   HEocc_vs_LB->Fill(currentLS,heHists.count_good);
 
   // Calculate number of bad quality cells and bad quality fraction
   if (HBpresent_ && (hbHists.count_good>0 || hbHists.count_bad>0))
     {
       int counter=hbHists.count_bad;
       if (counter<DIGI_SUBDET_NUM)
     ++hbHists.count_BQ[counter];
       float counter2 = (1.*hbHists.count_bad)/(hbHists.count_bad+hbHists.count_good)*(DIGI_BQ_FRAC_NBINS-1);
       if (counter2<DIGI_SUBDET_NUM) ++hbHists.count_BQFrac[(int)counter2];
     }
 
   if (HEpresent_ && (heHists.count_good>0 || heHists.count_bad>0))
     {
       int counter=heHists.count_bad;
       if (counter<DIGI_SUBDET_NUM)
     ++heHists.count_BQ[counter];
       float counter2 = (1.*heHists.count_bad)/(heHists.count_bad+heHists.count_good)*(DIGI_BQ_FRAC_NBINS-1);
       if (counter2<DIGI_SUBDET_NUM) ++heHists.count_BQFrac[int(counter2)];
     }
 
   if (HOpresent_)
     {
       for (HODigiCollection::const_iterator j=ho.begin(); j!=ho.end(); ++j)
     {
       const HODataFrame digi = (const HODataFrame)(*j);
       // Mark HORing+/-2 channels as present, HO/YB+/-2 has HV off (at 100V).
       if (excludeHORing2_==true && digi.id().depth()==4)
         if (abs(digi.id().ieta())>=11 && abs(digi.id().ieta())<=15 && 
         !isSiPM(digi.id().ieta(),digi.id().iphi(),digi.id().depth())) continue;
       
       if (excludeHO1P02_==true)   
         if( (digi.id().ieta()>4 && digi.id().ieta()<10) 
         && (digi.id().iphi()<=10 || digi.id().iphi()>70) ) continue;
 
       if (KnownBadCells_.find(digi.id())!=KnownBadCells_.end()) continue;
       
       process_Digi(digi, hoHists, firsthocap);
     } // for (HODigiCollection)
       
       if (hoHists.count_bad>0 || hoHists.count_good>0)
     {
       int counter=hoHists.count_bad;
       if (counter<DIGI_SUBDET_NUM)
         ++hoHists.count_BQ[counter];
 
       float counter2 = (1.*hoHists.count_bad)/(hoHists.count_bad+hoHists.count_good)*(DIGI_BQ_FRAC_NBINS-1);
       if (counter2<DIGI_SUBDET_NUM) ++hoHists.count_BQFrac[int(counter2)];
     }
       HOocc_vs_LB->Fill(currentLS,hoHists.count_good);
     } // if (HOpresent_)
   
   if (HFpresent_)
     {
       for (HFDigiCollection::const_iterator j=hf.begin(); j!=hf.end(); ++j)
     {
       const HFDataFrame digi = (const HFDataFrame)(*j);
       process_Digi(digi, hfHists, firsthfcap);
     } // for (HFDigiCollection)
 
       if (hfHists.count_bad>0 || hfHists.count_good>0)
     {
       int counter=hfHists.count_bad;
       if (counter<DIGI_SUBDET_NUM)
         ++hfHists.count_BQ[counter];
       float counter2 = (1.*hfHists.count_bad)/(hfHists.count_bad+hfHists.count_good)*(DIGI_BQ_FRAC_NBINS-1);
       if (counter2<DIGI_SUBDET_NUM) ++hfHists.count_BQFrac[int(counter2)];
     }
       HFocc_vs_LB->Fill(currentLS,hfHists.count_good);
     } // if (HFpresent_)
   
   // This only counts digis that are present but bad somehow; it does not count digis that are missing
   int count_good=hbHists.count_good+heHists.count_good+hoHists.count_good+hfHists.count_good;
   int count_bad=hbHists.count_bad+heHists.count_bad+hoHists.count_bad+hfHists.count_bad;
 
   if (count_good<DIGI_NUM)
     ++diginum[count_good];
 
   // Fill bad quality histograms
   DigiUnpackerErrorFrac->Fill(1.*report.badQualityDigis()/(report.badQualityDigis()+count_good));
   DigiBQ->Fill(count_bad);
   if (count_bad>0 || count_good>0)
     DigiBQFrac->Fill(1.*count_bad/(count_bad+count_good));
 
   // Call 'update' on all histograms so that they update in online DQM  
   UpdateHists(hbHists);
   UpdateHists(heHists);
   UpdateHists(hoHists);
   UpdateHists(hfHists);
 
   // Now update global (non-subdetector-specific) histograms
   DigiNum->update();
   DigiErrorVME->update();
   DigiErrorSpigot->update();
   DigiBQ->update();
   DigiBQFrac->update();
   DigiUnpackerErrorCount->update();
   DigiUnpackerErrorFrac->update();
 
   // Update eta-phi hists
   for (unsigned int zz=0;zz<DigiErrorOccupancyByDepth.depth.size();++zz)
       DigiErrorOccupancyByDepth.depth[zz]->update();
   for (unsigned int zz=0;zz<DigiErrorsByDepth.depth.size();++zz)
       DigiErrorsByDepth.depth[zz]->update();
   for (unsigned int zz=0;zz<DigiErrorsBadCapID.depth.size();++zz)
       DigiErrorsBadCapID.depth[zz]->update();
   for (unsigned int zz=0;zz<DigiErrorsDVErr.depth.size();++zz)
       DigiErrorsDVErr.depth[zz]->update();
   for (unsigned int zz=0;zz<DigiErrorsBadDigiSize.depth.size();++zz)
       DigiErrorsBadDigiSize.depth[zz]->update();
   for (unsigned int zz=0;zz<DigiErrorsBadADCSum.depth.size();++zz)
       DigiErrorsBadADCSum.depth[zz]->update();
   for (unsigned int zz=0;zz<DigiErrorsUnpacker.depth.size();++zz)
       DigiErrorsUnpacker.depth[zz]->update();
   for (unsigned int zz=0;zz<DigiErrorsBadFibBCNOff.depth.size();++zz)
     DigiErrorsBadFibBCNOff.depth[zz]->update();
 
   DigiOccupancyEta->update();
   DigiOccupancyPhi->update();
   DigiOccupancyVME->update();
   DigiOccupancySpigot->update();
   DigiSize->update();
   DigiExpectedSize->update();
 
   // // Fill problems vs. lumi block plots
   // ProblemsVsLB->Fill(currentLS,count_bad);
   // ProblemsVsLB_HB->Fill(currentLS,hbHists.count_bad);
   // ProblemsVsLB_HE->Fill(currentLS,heHists.count_bad);
   // ProblemsVsLB_HO->Fill(currentLS,hoHists.count_bad);
   // ProblemsVsLB_HF->Fill(currentLS,hfHists.count_bad);
   // ProblemsVsLB_HBHEHF->Fill(currentLS,hbHists.count_bad+heHists.count_bad+hfHists.count_bad);
 
   // // Fill the number of problem digis in each channel
   // ProblemsCurrentLB->Fill(-1,-1,1);  // event counter
   // ProblemsCurrentLB->Fill(0,0,hbHists.count_bad);
   // ProblemsCurrentLB->Fill(1,0,heHists.count_bad);
   // ProblemsCurrentLB->Fill(2,0,hoHists.count_bad);
   // ProblemsCurrentLB->Fill(3,0,hfHists.count_bad);
   // ProblemsCurrentLB->Fill(4,0,HO0bad);
   // ProblemsCurrentLB->Fill(5,0,HO12bad);
   // ProblemsCurrentLB->Fill(6,0,HFlumibad);
 
   // Call fill method every checkNevents
   //fill_Nevents();
   
   return;
 } // void HcalDigiMonitor::processEvent(...)

void HcalDigiMonitor::reset ( void )

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 1733 of file HcalDigiMonitor.cc.

References DigiHists::ADC, DigiHists::ADCsum, alarmer_counter_, DigiHists::BQ, DigiHists::BQFrac, DigiHists::CapID, DigiBQ, DigiBQFrac, DigiErrorOccupancyByDepth, DigiErrorsBadADCSum, DigiErrorsBadCapID, DigiErrorsBadDigiSize, DigiErrorsBadFibBCNOff, DigiErrorsByDepth, DigiErrorsDVErr, DigiErrorSpigot, DigiErrorsUnpacker, DigiErrorVME, DigiHists::DigiFirstCapID, DigiNum, DigiOccupancyByDepth, DigiOccupancyEta, DigiOccupancyPhi, DigiOccupancySpigot, DigiOccupancyVME, DigiUnpackerErrorCount, DigiUnpackerErrorFrac, DigiHists::DVerr, DigiHists::fibBCNOff, hbhedcsON, hbHists, heHists, hfdcsON, hfHists, hoHists, i, knownbadQPLLs, DigiHists::presample, ProblemDigisInLastNLB_HBHEHF_alarm, EtaPhiHists::Reset(), MonitorElement::Reset(), DigiHists::shape, DigiHists::shapeThresh, DigiHists::TS_sum_minus, DigiHists::TS_sum_plus, and zeroCounters().

Referenced by bookHistograms(), and setup().

 {
   // reset the temporary histograms
   zeroCounters();
   
   // then reset the MonitorElements
 
   ProblemDigisInLastNLB_HBHEHF_alarm->Reset();
   alarmer_counter_ = 0;
   knownbadQPLLs    = 0; 
 
   hbhedcsON = true; hfdcsON = true;
 
   DigiErrorsByDepth.Reset();
   DigiErrorsBadCapID.Reset();
   DigiErrorsDVErr.Reset();
   DigiErrorsBadDigiSize.Reset();
   DigiErrorsBadADCSum.Reset();
   DigiErrorsUnpacker.Reset();
   DigiErrorsBadFibBCNOff.Reset();
   DigiOccupancyByDepth.Reset();
   DigiErrorOccupancyByDepth.Reset();
 
   DigiOccupancyEta->Reset();
   DigiOccupancyPhi->Reset();
   DigiOccupancyVME->Reset();
   DigiOccupancySpigot->Reset();
   DigiErrorVME->Reset();
   DigiErrorSpigot->Reset();
   
   DigiBQ->Reset();
   DigiBQFrac->Reset();
   DigiUnpackerErrorCount->Reset();
   DigiUnpackerErrorFrac->Reset();
 
   DigiNum->Reset();
 
   hbHists.shape->Reset();
   hbHists.shapeThresh->Reset();
   hbHists.presample->Reset();
   hbHists.BQ->Reset();
   hbHists.BQFrac->Reset();
   hbHists.DigiFirstCapID->Reset();
   hbHists.DVerr->Reset();
   hbHists.CapID->Reset();
   hbHists.ADC->Reset();
   hbHists.ADCsum->Reset();
   hbHists.fibBCNOff->Reset();
   for (unsigned int i=0;i<hbHists.TS_sum_plus.size();++i)
     hbHists.TS_sum_plus[i]->Reset();
   for (unsigned int i=0;i<hbHists.TS_sum_minus.size();++i)
     hbHists.TS_sum_minus[i]->Reset();
 
   heHists.shape->Reset();
   heHists.shapeThresh->Reset();
   heHists.presample->Reset();
   heHists.BQ->Reset();
   heHists.BQFrac->Reset();
   heHists.DigiFirstCapID->Reset();
   heHists.DVerr->Reset();
   heHists.CapID->Reset();
   heHists.ADC->Reset();
   heHists.ADCsum->Reset();
   heHists.fibBCNOff->Reset();
   for (unsigned int i=0;i<heHists.TS_sum_plus.size();++i)
     heHists.TS_sum_plus[i]->Reset();
   for (unsigned int i=0;i<heHists.TS_sum_minus.size();++i)
     heHists.TS_sum_minus[i]->Reset();
 
   hoHists.shape->Reset();
   hoHists.shapeThresh->Reset();
   hoHists.presample->Reset();
   hoHists.BQ->Reset();
   hoHists.BQFrac->Reset();
   hoHists.DigiFirstCapID->Reset();
   hoHists.DVerr->Reset();
   hoHists.CapID->Reset();
   hoHists.ADC->Reset();
   hoHists.ADCsum->Reset();
   hoHists.fibBCNOff->Reset();
   for (unsigned int i=0;i<hoHists.TS_sum_plus.size();++i)
     hoHists.TS_sum_plus[i]->Reset();
   for (unsigned int i=0;i<hoHists.TS_sum_minus.size();++i)
     hoHists.TS_sum_minus[i]->Reset();
 
   hfHists.shape->Reset();
   hfHists.shapeThresh->Reset();
   hfHists.presample->Reset();
   hfHists.BQ->Reset();
   hfHists.BQFrac->Reset();
   hfHists.DigiFirstCapID->Reset();
   hfHists.DVerr->Reset();
   hfHists.CapID->Reset();
   hfHists.ADC->Reset();
   hfHists.ADCsum->Reset();
   hfHists.fibBCNOff->Reset();
   for (unsigned int i=0;i<hfHists.TS_sum_plus.size();++i)
     hfHists.TS_sum_plus[i]->Reset();
   for (unsigned int i=0;i<hfHists.TS_sum_minus.size();++i)
     hfHists.TS_sum_minus[i]->Reset();
 
   return;
 }

void HcalDigiMonitor::setup ( DQMStore::IBooker & ib )

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 161 of file HcalDigiMonitor.cc.

Referenced by bookHistograms().

 {
   if (setupDone_)
     return;
   setupDone_=true;
   // Call base class setup
   HcalBaseDQMonitor::setup(ib);
 
   /******* Set up all histograms  ********/
   if (debug_>1)
     std::cout <<"<HcalDigiMonitor::setup>  Setting up histograms"<<std::endl;
 
   std::ostringstream name;
   ib.setCurrentFolder(subdir_);
   
   ib.setCurrentFolder(subdir_+"digi_parameters");
   MonitorElement* ExpectedOrbit = ib.bookInt("ExpectedOrbitMessageTime");
   ExpectedOrbit->Fill(DigiMonitor_ExpectedOrbitMessageTime_);
 
   MonitorElement* shapeT = ib.bookInt("DigiShapeThresh");
   shapeT->Fill(shapeThresh_);
   MonitorElement* shapeTHB = ib.bookInt("DigiShapeThreshHB");
   shapeTHB->Fill(shapeThreshHB_);
   MonitorElement* shapeTHE = ib.bookInt("DigiShapeThreshHE");
   shapeTHE->Fill(shapeThreshHE_);
   MonitorElement* shapeTHO = ib.bookInt("DigiShapeThreshHO");
   shapeTHO->Fill(shapeThreshHO_);
   MonitorElement* shapeTHF = ib.bookInt("DigiShapeThreshHF");
   shapeTHF->Fill(shapeThreshHF_);
   
   ib.setCurrentFolder(subdir_+"bad_digis/bad_digi_occupancy");
   SetupEtaPhiHists(ib,DigiErrorsByDepth,"Bad Digi Map","");
   ib.setCurrentFolder(subdir_+"bad_digis/1D_digi_plots");
   ProblemsVsLB=ib.bookProfile("BadDigisVsLB","Number Bad Digis vs Luminosity block;Lumi block;# of Bad digis",
                  NLumiBlocks_,0.5,NLumiBlocks_+0.5,100,0,10000);
   ProblemsVsLB_HB=ib.bookProfile("HB Bad Quality Digis vs LB","HB Bad Quality Digis vs Luminosity Block",
                      NLumiBlocks_,0.5,NLumiBlocks_+0.5,
                      100,0,10000);   
   ProblemsVsLB_HE=ib.bookProfile("HE Bad Quality Digis vs LB","HE Bad Quality Digis vs Luminosity Block",
                      NLumiBlocks_,0.5,NLumiBlocks_+0.5,
                      100,0,10000);
   ProblemsVsLB_HO=ib.bookProfile("HO Bad Quality Digis vs LB","HO Bad Quality Digis vs Luminosity Block",
                      NLumiBlocks_,0.5,NLumiBlocks_+0.5,
                      100,0,10000);
   ProblemsVsLB_HF=ib.bookProfile("HF Bad Quality Digis vs LB","HF Bad Quality Digis vs Luminosity Block",
                      NLumiBlocks_,0.5,NLumiBlocks_+0.5,
                      100,0,10000);
   ProblemsVsLB_HBHEHF=ib.bookProfile("HBHEHF Bad Quality Digis vs LB","HBHEHF Bad Quality Digis vs Luminosity Block",
                      NLumiBlocks_,0.5,NLumiBlocks_+0.5,
                      100,0,10000);
 
   ProblemDigisInLastNLB_HBHEHF_alarm=ib.book1D("ProblemDigisInLastNLB_HBHEHF_alarm",
                           "Total Number of ProblemDigis HBHEHF in last 10 LS. Last bin contains OverFlow",
                           100,0,100);
 
 
   if (makeDiagnostics_) 
     {
       // by default, unpacked digis won't have these errors
       ib.setCurrentFolder(subdir_+"diagnostics/bad_digis/badcapID");
       SetupEtaPhiHists(ib,DigiErrorsBadCapID," Digis with Bad Cap ID Rotation", "");
       ib.setCurrentFolder(subdir_+"diagnostics/bad_digis/data_invalid_error");
       SetupEtaPhiHists(ib,DigiErrorsDVErr," Digis with Data Invalid or Error Bit Set", "");
     }
   
   if (Online_)
     {
       // Special histograms for Pawel's timing study
       ib.setCurrentFolder(subdir_+"HFTimingStudy");
       HFtiming_etaProfile=ib.bookProfile("HFTiming_etaProfile","HFTiming Eta Profile;ieta;average time (time slice)",83,-41.5,41.5,200,0,10);
       HFP_shape=ib.book1D("HFP_signal_shape","HFP signal shape",10,-0.5,9.5);
       HFM_shape=ib.book1D("HFM_signal_shape","HFM signal shape",10,-0.5,9.5);
       ib.setCurrentFolder(subdir_+"HFTimingStudy/sumplots");
       HFtiming_totaltime2D=ib.book2D("HFTiming_Total_Time","HFTiming Total Time",83,-41.5,41.5,72,0.5,72.5);
       HFtiming_occupancy2D=ib.book2D("HFTiming_Occupancy","HFTiming Occupancy",83,-41.5,41.5,72,0.5,72.5);
     }
   
   ib.setCurrentFolder(subdir_+"bad_digis/bad_reportUnpackerErrors");
   SetupEtaPhiHists(ib,DigiErrorsUnpacker," Bad Unpacker Digis", "");
   
   ib.setCurrentFolder(subdir_+"bad_digis/baddigisize");
   SetupEtaPhiHists(ib,DigiErrorsBadDigiSize," Digis with Bad Size", "");
   
   ib.setCurrentFolder(subdir_+"digi_info");
   
   h_valid_digis=ib.book1D("ValidEvents","Events with minimum number of valid digis",2,-0.5,1.5);
   h_valid_digis->setBinLabel(1,"Valid");
   h_valid_digis->setBinLabel(2,"Invalid");
   
   h_invalid_orbitnumMod103=ib.book1D("InvalidDigiEvents_ORN","Orbit Number (mod 103) for Events with Many Unpacker Errors",103,-0.5,102.5);
   h_invalid_bcn=ib.book1D("InvalidDigiEvents_BCN","Bunch Crossing Number fo Events with Many Unpacker Errors",3464,-0.5,3563.5);
 
   DigiSize = ib.book2D("Digi Size", "Digi Size",4,0,4,20,-0.5,19.5);
   DigiSize->setBinLabel(1,"HB",1);
   DigiSize->setBinLabel(2,"HE",1);
   DigiSize->setBinLabel(3,"HO",1);
   DigiSize->setBinLabel(4,"HF",1);
   DigiSize->setAxisTitle("Subdetector",1);
   DigiSize->setAxisTitle("Digi Size",2);
   
   DigiExpectedSize = ib.book2D("Digi Expected Size", "Digi Expected Size",3,0,3,20,-0.5,19.5);
   DigiExpectedSize->setBinLabel(1,"HBHE",1);
   DigiExpectedSize->setBinLabel(2,"HO",1);
   DigiExpectedSize->setBinLabel(3,"HF",1);
   DigiExpectedSize->setAxisTitle("Subdetector",1);
   DigiExpectedSize->setAxisTitle("Digi Expected Size from HTR",2);
   
   ib.setCurrentFolder(subdir_+"bad_digis/badfibBCNoff");
   SetupEtaPhiHists(ib,DigiErrorsBadFibBCNOff," Digis with non-zero Fiber Orbit Msg Idle BCN Offsets", "");
   
   ib.setCurrentFolder(subdir_+"good_digis/1D_digi_plots");
   HBocc_vs_LB=ib.bookProfile("HBoccVsLB","HB digi occupancy vs Luminosity Block;Lumi block;# of Good digis",
                  NLumiBlocks_,0.5,NLumiBlocks_+0.5,
                  0,2600);
   HEocc_vs_LB=ib.bookProfile("HEoccVsLB","HE digi occupancy vs Luminosity Block;Lumi block;# of Good digis",
                  NLumiBlocks_,0.5,NLumiBlocks_+0.5,
                  0,2600);
   HOocc_vs_LB=ib.bookProfile("HOoccVsLB","HO digi occupancy vs Luminosity Block;Lumi block;# of Good digis",
                  NLumiBlocks_,0.5,NLumiBlocks_+0.5,
                  0,2200);
   HFocc_vs_LB=ib.bookProfile("HFoccVsLB","HF digi occupancy vs Luminosity Block;Lumi block;# of Good digis",
                  NLumiBlocks_,0.5,NLumiBlocks_+0.5,
                  0,1800);
   
   ib.setCurrentFolder(subdir_+"good_digis/digi_occupancy");
   SetupEtaPhiHists(ib,DigiOccupancyByDepth," Digi Eta-Phi Occupancy Map","");
   DigiOccupancyPhi= ib.book1D("Digi Phi Occupancy Map",
                   "Digi Phi Occupancy Map;i#phi;# of Events",
                   72,0.5,72.5);
   DigiOccupancyEta= ib.book1D("Digi Eta Occupancy Map",
                   "Digi Eta Occupancy Map;i#eta;# of Events",
                   83,-41.5,41.5);
   DigiOccupancyVME = ib.book2D("Digi VME Occupancy Map",
                    "Digi VME Occupancy Map;HTR Slot;VME Crate Id",
                    40,-0.25,19.75,36,-0.5,35.5);
   
   DigiOccupancySpigot = ib.book2D("Digi Spigot Occupancy Map",
                       "Digi Spigot Occupancy Map;Spigot;DCC Id",
                       HcalDCCHeader::SPIGOT_COUNT,-0.5,HcalDCCHeader::SPIGOT_COUNT-0.5,
                       36,-0.5,35.5);
   
   ib.setCurrentFolder(subdir_+"bad_digis/bad_digi_occupancy");
   DigiErrorVME = ib.book2D("Digi VME Error Map",
                    "Digi VME Error Map;HTR Slot;VME Crate Id",
                    40,-0.25,19.75,18,-0.5,17.5);
   
   DigiErrorSpigot = ib.book2D("Digi Spigot Error Map",
                   "Digi Spigot Error Map;Spigot;DCC Id",
                   HcalDCCHeader::SPIGOT_COUNT,-0.5,HcalDCCHeader::SPIGOT_COUNT-0.5,
                   36,-0.5,35.5);
   
   ib.setCurrentFolder(subdir_+"bad_digis");
   int nbins = sizeof(bins_cellcount_new)/sizeof(float)-1;
 
   DigiBQ = ib.book1D("NumBadQualDigis","Number Bad Qual Digis within Digi Collection",nbins, bins_cellcount_new);
 
   nbins=sizeof(bins_fraccount_new)/sizeof(float)-1;
 
   DigiBQFrac =  ib.book1D("Bad Digi Fraction","Bad Digi Fraction;Bad Quality Digi Fraction for digis in collection; # of Events",
                  nbins, bins_fraccount_new);
   
   nbins = sizeof(bins_cellcount_new)/sizeof(float)-1;
   DigiUnpackerErrorCount = ib.book1D("Unpacker Error Count", "Number of Bad Digis from Unpacker; Bad Unpacker Digis; # of Events",nbins, bins_cellcount_new);
   
   nbins=sizeof(bins_fraccount_new)/sizeof(float)-1;
   DigiUnpackerErrorFrac = ib.book1D("Unpacker Bad Digi Fraction", 
                        "Bad Digis From Unpacker/ (Bad Digis From Unpacker + Good Digis); Bad Unpacker Fraction; # of Events",
                        nbins,bins_fraccount_new);
   
   ib.setCurrentFolder(subdir_+"good_digis/");
   DigiNum = ib.book1D("NumGoodDigis","Number of Digis;# of Good Digis;# of Events",DIGI_NUM+1,-0.5,DIGI_NUM+1-0.5);
     
   setupSubdetHists(ib,hbHists,"HB");
   setupSubdetHists(ib,heHists,"HE");
   setupSubdetHists(ib,hoHists,"HO");
   setupSubdetHists(ib,hfHists,"HF");
 
   this->reset();
   return;
 } // void HcalDigiMonitor::setup()

void HcalDigiMonitor::setupSubdetHists	(	DQMStore::IBooker &	ib,
		DigiHists &	hist,
		std::string	subdet
	)

private

Definition at line 405 of file HcalDigiMonitor.cc.

References DigiHists::ADC, DigiHists::ADCsum, DQMStore::IBooker::book1D(), DigiHists::BQ, DigiHists::BQFrac, DigiHists::CapID, DIGI_BQ_FRAC_NBINS, DigiHists::DigiFirstCapID, DigiHists::DVerr, DigiHists::fibBCNOff, mergeVDriftHistosByStation::name, DigiHists::presample, MonitorElement::setBinLabel(), DQMStore::IBooker::setCurrentFolder(), DigiHists::shape, DigiHists::shapeThresh, HcalBaseDQMonitor::subdir_, DigiHists::ThreshCount, DigiHists::TS_sum_minus, and DigiHists::TS_sum_plus.

Referenced by setup().

 {
   std::stringstream name;
   int nChan=0;
   if (subdet=="HB" || subdet=="HE") nChan=2592;
   else if (subdet == "HO") nChan=2160;
   else if (subdet == "HF") nChan=1728;
 
   ib.setCurrentFolder(subdir_+"digi_info/"+subdet);
   hist.shape = ib.book1D(subdet+" Digi Shape",subdet+" Digi Shape;Time Slice",10,-0.5,9.5);
   hist.shapeThresh = ib.book1D(subdet+" Digi Shape - over thresh",
                   subdet+" Digi Shape - over thresh passing trigger and HF HT cuts;Time slice",
                   10,-0.5,9.5);
   hist.ThreshCount = ib.book1D(subdet+" Total Digis Over Threshold",
                   subdet+" Total Digis Over Threshold",
                   1,-0.5,0.5);
   // Create plots of sums of adjacent time slices
   for (int ts=0;ts<9;++ts)
     {
       name<<subdet<<" Plus Time Slices "<<ts<<" and "<<ts+1;
       hist.TS_sum_plus.push_back(ib.book1D(name.str().c_str(),name.str().c_str(),50, 0., 50.));
       name.str("");
       name<<subdet<<" Minus Time Slices "<<ts<<" and "<<ts+1;
       hist.TS_sum_minus.push_back(ib.book1D(name.str().c_str(),name.str().c_str(),50, 0., 50.));
       name.str("");
     }
   hist.presample= ib.book1D(subdet+" Digi Presamples",subdet+" Digi Presamples",50,-0.5,49.5);
   hist.BQ = ib.book1D(subdet+" Bad Quality Digis",subdet+" Bad Quality Digis",nChan+1,-0.5,nChan+0.5);
   //(hist.BQ->getTH1F())->LabelsOption("v");
   hist.BQFrac = ib.book1D(subdet+" Bad Quality Digi Fraction",subdet+" Bad Quality Digi Fraction",DIGI_BQ_FRAC_NBINS,(0-0.5/(DIGI_BQ_FRAC_NBINS-1)),1+0.5/(DIGI_BQ_FRAC_NBINS-1));
   hist.DigiFirstCapID = ib.book1D(subdet+" Capid 1st Time Slice",subdet+" Capid for 1st Time Slice;CapId (T0)- 1st CapId (T0);# of Events",7,-3.5,3.5);
 
   hist.DVerr = ib.book1D(subdet+" Data Valid Err Bits",subdet+" QIE Data Valid Err Bits",4,-0.5,3.5);
   hist.DVerr ->setBinLabel(1,"Err=0, DV=0",1);
   hist.DVerr ->setBinLabel(2,"Err=0, DV=1",1);
   hist.DVerr ->setBinLabel(3,"Err=1, DV=0",1);
   hist.DVerr ->setBinLabel(4,"Err=1, DV=1",1);
   hist.CapID = ib.book1D(subdet+" CapID",subdet+" CapID",4,-0.5,3.5);
   hist.ADC = ib.book1D(subdet+" ADC count per time slice",subdet+" ADC count per time slice",200,-0.5,199.5);
   hist.ADCsum = ib.book1D(subdet+" ADC sum", subdet+" ADC sum",200,-0.5,199.5);
   hist.fibBCNOff = ib.book1D(subdet+" Fiber Orbit Message Idle BCN Offset", subdet+" Fiber Orbit Message Idle BCN Offset;Offset from Expected",
                  15, -7.5, 7.5);
 }

void HcalDigiMonitor::UpdateHists ( DigiHists & h )

private

Definition at line 1711 of file HcalDigiMonitor.cc.

References DigiHists::ADC, DigiHists::ADCsum, DigiHists::BQ, DigiHists::BQFrac, DigiHists::CapID, DigiHists::DigiFirstCapID, DigiHists::DVerr, DigiHists::fibBCNOff, i, DigiHists::presample, DigiHists::shape, DigiHists::shapeThresh, DigiHists::TS_sum_minus, DigiHists::TS_sum_plus, and MonitorElement::update().

Referenced by processEvent().

 {
   // call update command for all histograms (should make them update when running in online DQM?)
   h.shape->update();
   h.shapeThresh->update();
   h.presample->update();
   h.BQ->update();
   h.BQFrac->update();
   h.DigiFirstCapID->update();
   h.DVerr->update();
   h.CapID->update();
   h.ADC->update();
   h.ADCsum->update();
   h.fibBCNOff->update();
 
   for (unsigned int i=0;i<h.TS_sum_plus.size();++i)
     h.TS_sum_plus[i]->update();
   for (unsigned int i=0;i<h.TS_sum_minus.size();++i)
     h.TS_sum_minus[i]->update();
 } //void HcalDigiMonitor::UpdateHists(DigiHists& h)

void HcalDigiMonitor::zeroCounters ( )

private

Definition at line 1542 of file HcalDigiMonitor.cc.

References DigiHists::adc, DigiHists::adcsum, badcapID, baddigis, baddigisize, badFibBCNOff, badunpackerreport, DigiHists::capid, DigiHists::capIDdiff, DigiHists::count_bad, DigiHists::count_BQ, DigiHists::count_BQFrac, DigiHists::count_good, DigiHists::count_presample, DigiHists::count_shape, DigiHists::count_shapeThresh, ztail::d, DEPTHBINS, DIGI_BQ_FRAC_NBINS, DIGI_NUM, DIGI_SUBDET_NUM, digierrorsdverr, diginum, digisize, DigiHists::dverr, errorSpigot, errorVME, eta(), ETABINS, DigiHists::fibbcnoff, hbHists, heHists, hfHists, HFlumibad, HO0bad, HO12bad, hoHists, i, j, relval_steps::k, knownbadQPLLs, occupancyEta, occupancyEtaPhi, occupancyPhi, occupancySpigot, occupancyVME, phi, PHIBINS, HcalDCCHeader::SPIGOT_COUNT, DigiHists::tssumminus, DigiHists::tssumplus, uniqcounter, and uniqcounter2.

Referenced by endLuminosityBlock(), and reset().

 {
   // Set all histogram counters back to 0
   // Call this after all every N evnets
 
   /******** Zero all counters *******/
   for (int d=0; d<DEPTHBINS; d++) {
     for (int eta=0; eta<ETABINS; eta++) {
       for (int phi=0; phi<PHIBINS; phi++){
     uniqcounter[eta][phi][d] = 0.0;
     uniqcounter2[eta][phi][d] = 0.0;
       }
     }
   }
 
   hbHists.count_bad=0;
   hbHists.count_good=0;
   heHists.count_bad=0;
   heHists.count_good=0;
   hoHists.count_bad=0;
   hoHists.count_good=0;
   hfHists.count_bad=0;
   hfHists.count_good=0;
 
   knownbadQPLLs = 0;
 
   HO0bad=0;
   HO12bad=0;
   HFlumibad=0;
 
   for (int i=0;i<85;++i)
     {
       occupancyEta[i]=0;
       if (i<72)
         occupancyPhi[i]=0;
       for (int j=0;j<72;++j)
         {
           for (int k=0;k<4;++k)
             {
               baddigis[i][j][k]=0;
               badcapID[i][j][k]=0;
               baddigisize[i][j][k]=0;
               occupancyEtaPhi[i][j][k]=0;
               digierrorsdverr[i][j][k]=0;
           badFibBCNOff[i][j][k]=0;
           badunpackerreport[i][j][k]=0;
             }
         } // for (int j=0;j<72;++i)
     } // for (int i=0;i<85;++i)
 
   for (int i=0;i<40;++i)
     {
       for (int j=0;j<18;++j)
     {
       occupancyVME[i][j]=0;
       errorVME[i][j]=0;
     }
     }
 
   for (int i=0;i<HcalDCCHeader::SPIGOT_COUNT;++i)
     {
       for (int j=0;j<36;++j)
     {
       occupancySpigot[i][j]=0;
       errorSpigot[i][j]=0;
     }
     }
 
 
   for (int i=0;i<20;++i)
     {
       for (int j=0;j<4;++j)
     digisize[i][j]=0;
     }
 
   for (int i=0;i<DIGI_NUM;++i)
     {
       diginum[i]=0;
       
       // set all DigiHists counters to 0
       if (i<4)
     {
       hbHists.dverr[i]=0;
       heHists.dverr[i]=0;
       hoHists.dverr[i]=0;
       hfHists.dverr[i]=0;
       hbHists.capid[i]=0;
       heHists.capid[i]=0;
       hoHists.capid[i]=0;
       hfHists.capid[i]=0;
     }
       if (i<8)
     {
       hbHists.capIDdiff[i]=0;
       heHists.capIDdiff[i]=0;
       hoHists.capIDdiff[i]=0;
       hfHists.capIDdiff[i]=0;
     }
 
       if (i<10)
     {
       hbHists.count_shape[i]=0;
       heHists.count_shape[i]=0;
       hoHists.count_shape[i]=0;
       hfHists.count_shape[i]=0;
      
       hbHists.count_shapeThresh[i]=0;
       heHists.count_shapeThresh[i]=0;
       hoHists.count_shapeThresh[i]=0;
       hfHists.count_shapeThresh[i]=0;
     }
       if (i<50)
     {
       hbHists.count_presample[i]=0;
       heHists.count_presample[i]=0;
       hoHists.count_presample[i]=0;
       hfHists.count_presample[i]=0;
       for (int j=0;j<10;++j)
         {
           hbHists.tssumplus[i][j]=0;
           heHists.tssumplus[i][j]=0;
           hoHists.tssumplus[i][j]=0;
           hfHists.tssumplus[i][j]=0;
           hbHists.tssumminus[i][j]=0;
           heHists.tssumminus[i][j]=0;
           hoHists.tssumminus[i][j]=0;
           hfHists.tssumminus[i][j]=0;
         }
     }
 
       if (i<15)
     {
       hbHists.fibbcnoff[i]=0;
       heHists.fibbcnoff[i]=0;
       hoHists.fibbcnoff[i]=0;
       hfHists.fibbcnoff[i]=0;
     }
 
       if (i<200)
     {
       hbHists.adc[i]=0;
       heHists.adc[i]=0;
       hoHists.adc[i]=0;
       hfHists.adc[i]=0;
       hbHists.adcsum[i]=0;
       heHists.adcsum[i]=0;
       hoHists.adcsum[i]=0;
       hfHists.adcsum[i]=0;
     }
       if (i<DIGI_SUBDET_NUM)
     {
       hbHists.count_BQ[i]=0;
       heHists.count_BQ[i]=0;
       hoHists.count_BQ[i]=0;
       hfHists.count_BQ[i]=0;
     }
       if (i<DIGI_BQ_FRAC_NBINS)
     {
       hbHists.count_BQFrac[i]=0;
       heHists.count_BQFrac[i]=0;
       hoHists.count_BQFrac[i]=0;
       hfHists.count_BQFrac[i]=0;
     }
     } // for (int i=0;i<DIGI_NUM;++i)
 
 
   return;
 }

Member Data Documentation

int HcalDigiMonitor::alarmer_counter_

private

Definition at line 122 of file HcalDigiMonitor.h.

Referenced by endLuminosityBlock(), fill_Nevents(), and reset().

int HcalDigiMonitor::badcapID[85][72][4]

private

Definition at line 156 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

int HcalDigiMonitor::baddigis[85][72][4]

private

Definition at line 155 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), processEvent(), and zeroCounters().

int HcalDigiMonitor::baddigisize[85][72][4]

private

Definition at line 157 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

int HcalDigiMonitor::badFibBCNOff[85][72][4]

private

Definition at line 158 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

int HcalDigiMonitor::badunpackerreport[85][72][4]

private

Definition at line 159 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), and zeroCounters().

edm::ESHandle<HcalDbService> HcalDigiMonitor::conditions_

private

Definition at line 228 of file HcalDigiMonitor.h.

Referenced by analyze(), and bookHistograms().

edm::EDGetTokenT<DcsStatusCollection> HcalDigiMonitor::dcsStatusToken_

private

Definition at line 241 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

bool HcalDigiMonitor::digi_checkadcsum_

private

Definition at line 133 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor().

bool HcalDigiMonitor::digi_checkcapid_

private

Definition at line 131 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), and process_Digi().

bool HcalDigiMonitor::digi_checkdigisize_

private

Definition at line 132 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), and process_Digi().

bool HcalDigiMonitor::digi_checkdverr_

private

Definition at line 134 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), and process_Digi().

bool HcalDigiMonitor::digi_checkoccupancy_

private

Definition at line 130 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor().

MonitorElement* HcalDigiMonitor::DigiBQ

private

Definition at line 189 of file HcalDigiMonitor.h.

Referenced by processEvent(), reset(), and setup().

MonitorElement* HcalDigiMonitor::DigiBQFrac

private

Definition at line 190 of file HcalDigiMonitor.h.

Referenced by processEvent(), reset(), and setup().

EtaPhiHists HcalDigiMonitor::DigiErrorOccupancyByDepth

private

Definition at line 184 of file HcalDigiMonitor.h.

Referenced by processEvent(), and reset().

EtaPhiHists HcalDigiMonitor::DigiErrorsBadADCSum

private

Definition at line 149 of file HcalDigiMonitor.h.

Referenced by processEvent(), and reset().

EtaPhiHists HcalDigiMonitor::DigiErrorsBadCapID

private

Definition at line 146 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

EtaPhiHists HcalDigiMonitor::DigiErrorsBadDigiSize

private

Definition at line 148 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

EtaPhiHists HcalDigiMonitor::DigiErrorsBadFibBCNOff

private

Definition at line 151 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

EtaPhiHists HcalDigiMonitor::DigiErrorsByDepth

private

Definition at line 145 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

EtaPhiHists HcalDigiMonitor::DigiErrorsDVErr

private

Definition at line 147 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

int HcalDigiMonitor::digierrorsdverr[85][72][4]

private

Definition at line 161 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

MonitorElement* HcalDigiMonitor::DigiErrorSpigot

private

Definition at line 187 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

EtaPhiHists HcalDigiMonitor::DigiErrorsUnpacker

private

Definition at line 150 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

MonitorElement* HcalDigiMonitor::DigiErrorVME

private

Definition at line 186 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

MonitorElement* HcalDigiMonitor::DigiExpectedSize

private

Definition at line 154 of file HcalDigiMonitor.h.

Referenced by analyze(), processEvent(), and setup().

edm::InputTag HcalDigiMonitor::digiLabel_

private

Definition at line 217 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

int HcalDigiMonitor::DigiMonitor_ExpectedOrbitMessageTime_

private

Definition at line 138 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), process_Digi(), and setup().

MonitorElement* HcalDigiMonitor::DigiNum

private

Definition at line 205 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

int HcalDigiMonitor::diginum[9072]

private

Definition at line 206 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), and zeroCounters().

EtaPhiHists HcalDigiMonitor::DigiOccupancyByDepth

private

Definition at line 169 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), reset(), and setup().

MonitorElement* HcalDigiMonitor::DigiOccupancyEta

private

Definition at line 170 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

MonitorElement* HcalDigiMonitor::DigiOccupancyPhi

private

Definition at line 171 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

MonitorElement* HcalDigiMonitor::DigiOccupancySpigot

private

Definition at line 173 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

MonitorElement* HcalDigiMonitor::DigiOccupancyVME

private

Definition at line 172 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and setup().

MonitorElement* HcalDigiMonitor::DigiSize

private

Definition at line 153 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), processEvent(), and setup().

int HcalDigiMonitor::digisize[20][4]

private

Definition at line 160 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

MonitorElement* HcalDigiMonitor::DigiUnpackerErrorCount

private

Definition at line 191 of file HcalDigiMonitor.h.

Referenced by processEvent(), reset(), and setup().

MonitorElement* HcalDigiMonitor::DigiUnpackerErrorFrac

private

Definition at line 192 of file HcalDigiMonitor.h.

Referenced by processEvent(), reset(), and setup().

bool HcalDigiMonitor::doFCpeds_

private

Definition at line 111 of file HcalDigiMonitor.h.

int HcalDigiMonitor::errorSpigot[15][36]

private

Definition at line 198 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

int HcalDigiMonitor::errorVME[40][18]

private

Definition at line 197 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

bool HcalDigiMonitor::excludeBadQPLLs_

private

Definition at line 102 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), and processEvent().

bool HcalDigiMonitor::excludeHO1P02_

private

Definition at line 101 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), and processEvent().

bool HcalDigiMonitor::excludeHORing2_

private

Definition at line 100 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), and processEvent().

edm::InputTag HcalDigiMonitor::FEDRawDataCollection_

private

Definition at line 218 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

edm::EDGetTokenT<FEDRawDataCollection> HcalDigiMonitor::FEDRawDataCollectionToken_

private

Definition at line 242 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

MonitorElement* HcalDigiMonitor::h_invalid_bcn

private

Definition at line 166 of file HcalDigiMonitor.h.

Referenced by processEvent(), and setup().

MonitorElement* HcalDigiMonitor::h_invalid_orbitnumMod103

private

Definition at line 165 of file HcalDigiMonitor.h.

Referenced by processEvent(), and setup().

MonitorElement* HcalDigiMonitor::h_valid_digis

private

Definition at line 164 of file HcalDigiMonitor.h.

Referenced by processEvent(), and setup().

int HcalDigiMonitor::hbcount_

private

Definition at line 139 of file HcalDigiMonitor.h.

bool HcalDigiMonitor::hbhedcsON

private

Definition at line 124 of file HcalDigiMonitor.h.

Referenced by analyze(), endLuminosityBlock(), and reset().

DigiHists HcalDigiMonitor::hbHists

private

Definition at line 215 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), setup(), and zeroCounters().

MonitorElement* HcalDigiMonitor::HBocc_vs_LB

private

Definition at line 200 of file HcalDigiMonitor.h.

Referenced by processEvent(), and setup().

int HcalDigiMonitor::hecount_

private

Definition at line 139 of file HcalDigiMonitor.h.

DigiHists HcalDigiMonitor::heHists

private

Definition at line 215 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), setup(), and zeroCounters().

MonitorElement* HcalDigiMonitor::HEocc_vs_LB

private

Definition at line 201 of file HcalDigiMonitor.h.

Referenced by processEvent(), and setup().

int HcalDigiMonitor::hfcount_

private

Definition at line 139 of file HcalDigiMonitor.h.

bool HcalDigiMonitor::hfdcsON

private

Definition at line 124 of file HcalDigiMonitor.h.

Referenced by analyze(), endLuminosityBlock(), and reset().

DigiHists HcalDigiMonitor::hfHists

private

Definition at line 215 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), setup(), and zeroCounters().

int HcalDigiMonitor::HFlumibad

private

Definition at line 114 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), and zeroCounters().

MonitorElement* HcalDigiMonitor::HFM_shape

private

Definition at line 213 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), process_Digi(), and setup().

MonitorElement* HcalDigiMonitor::HFocc_vs_LB

private

Definition at line 203 of file HcalDigiMonitor.h.

Referenced by processEvent(), and setup().

MonitorElement* HcalDigiMonitor::HFP_shape

private

Definition at line 212 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), process_Digi(), and setup().

MonitorElement* HcalDigiMonitor::HFtiming_etaProfile

private

Definition at line 211 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), process_Digi(), and setup().

MonitorElement* HcalDigiMonitor::HFtiming_occupancy2D

private

Definition at line 210 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), process_Digi(), and setup().

MonitorElement* HcalDigiMonitor::HFtiming_totaltime2D

private

Definition at line 209 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), process_Digi(), and setup().

edm::InputTag HcalDigiMonitor::hltresultsLabel_

private

Definition at line 230 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

int HcalDigiMonitor::HO0bad

private

Definition at line 114 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), and zeroCounters().

int HcalDigiMonitor::HO12bad

private

Definition at line 114 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), and zeroCounters().

int HcalDigiMonitor::hocount_

private

Definition at line 139 of file HcalDigiMonitor.h.

DigiHists HcalDigiMonitor::hoHists

private

Definition at line 215 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), setup(), and zeroCounters().

MonitorElement* HcalDigiMonitor::HOocc_vs_LB

private

Definition at line 202 of file HcalDigiMonitor.h.

Referenced by processEvent(), and setup().

double HcalDigiMonitor::HT_HFM_

private

Definition at line 233 of file HcalDigiMonitor.h.

Referenced by analyze(), and process_Digi().

double HcalDigiMonitor::HT_HFP_

private

Definition at line 233 of file HcalDigiMonitor.h.

Referenced by analyze(), and process_Digi().

int HcalDigiMonitor::knownbadQPLLs

private

Definition at line 123 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), processEvent(), reset(), and zeroCounters().

int HcalDigiMonitor::maxdigisizeHBHE_

private

Definition at line 126 of file HcalDigiMonitor.h.

Referenced by analyze(), HcalDigiMonitor(), and process_Digi().

int HcalDigiMonitor::maxdigisizeHF_

private

Definition at line 128 of file HcalDigiMonitor.h.

Referenced by analyze(), HcalDigiMonitor(), and process_Digi().

int HcalDigiMonitor::maxdigisizeHO_

private

Definition at line 127 of file HcalDigiMonitor.h.

Referenced by analyze(), HcalDigiMonitor(), and process_Digi().

std::vector<std::string> HcalDigiMonitor::MinBiasHLTBits_

private

Definition at line 231 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

int HcalDigiMonitor::mindigisizeHBHE_

private

Definition at line 126 of file HcalDigiMonitor.h.

Referenced by analyze(), HcalDigiMonitor(), and process_Digi().

int HcalDigiMonitor::mindigisizeHF_

private

Definition at line 128 of file HcalDigiMonitor.h.

Referenced by analyze(), HcalDigiMonitor(), and process_Digi().

int HcalDigiMonitor::mindigisizeHO_

private

Definition at line 127 of file HcalDigiMonitor.h.

Referenced by analyze(), HcalDigiMonitor(), and process_Digi().

int HcalDigiMonitor::occupancyErrorEta[85]

private

Definition at line 195 of file HcalDigiMonitor.h.

int HcalDigiMonitor::occupancyErrorEtaPhi[85][72][4]

private

Definition at line 194 of file HcalDigiMonitor.h.

int HcalDigiMonitor::occupancyErrorPhi[72]

private

Definition at line 196 of file HcalDigiMonitor.h.

int HcalDigiMonitor::occupancyEta[85]

private

Definition at line 178 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

int HcalDigiMonitor::occupancyEtaPhi[85][72][4]

private

Definition at line 177 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

int HcalDigiMonitor::occupancyPhi[72]

private

Definition at line 179 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

int HcalDigiMonitor::occupancySpigot[40][36]

private

Definition at line 181 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

int HcalDigiMonitor::occupancyVME[40][18]

private

Definition at line 180 of file HcalDigiMonitor.h.

Referenced by fill_Nevents(), process_Digi(), and zeroCounters().

bool HcalDigiMonitor::passedMinBiasHLT_

private

Methods, variables accessible only within class code.

Definition at line 99 of file HcalDigiMonitor.h.

Referenced by analyze(), and process_Digi().

std::map<HcalDetId, std::vector<double> > HcalDigiMonitor::PedestalsByCapId_

private

Definition at line 236 of file HcalDigiMonitor.h.

Referenced by bookHistograms(), and process_Digi().

double HcalDigiMonitor::pedSubtractedADC_[10]

private

Definition at line 238 of file HcalDigiMonitor.h.

Referenced by process_Digi().

MonitorElement* HcalDigiMonitor::ProblemDigisInLastNLB_HBHEHF_alarm

private

Definition at line 174 of file HcalDigiMonitor.h.

Referenced by endLuminosityBlock(), fill_Nevents(), reset(), and setup().

bool HcalDigiMonitor::setupDone_

private

Definition at line 112 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), and setup().

int HcalDigiMonitor::shapeThresh_

private

Definition at line 116 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), and setup().

int HcalDigiMonitor::shapeThreshHB_

private

Definition at line 117 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), process_Digi(), and setup().

int HcalDigiMonitor::shapeThreshHE_

private

Definition at line 118 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), process_Digi(), and setup().

int HcalDigiMonitor::shapeThreshHF_

private

Definition at line 119 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), process_Digi(), and setup().

int HcalDigiMonitor::shapeThreshHO_

private

Definition at line 120 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), process_Digi(), and setup().

bool HcalDigiMonitor::shutOffOrbitTest_

private

Definition at line 136 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor(), and process_Digi().

edm::EDGetTokenT<HBHEDigiCollection> HcalDigiMonitor::tok_hbhe_

private

Definition at line 221 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

edm::EDGetTokenT<HFDigiCollection> HcalDigiMonitor::tok_hf_

private

Definition at line 223 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

edm::EDGetTokenT<HFRecHitCollection> HcalDigiMonitor::tok_hfrec_

private

Definition at line 226 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

edm::EDGetTokenT<HODigiCollection> HcalDigiMonitor::tok_ho_

private

Definition at line 222 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

edm::EDGetTokenT<FEDRawDataCollection> HcalDigiMonitor::tok_raw_

private

Definition at line 220 of file HcalDigiMonitor.h.

Referenced by HcalDigiMonitor().

edm::EDGetTokenT<edm::TriggerResults> HcalDigiMonitor::tok_trigger_

private

Definition at line 225 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

edm::EDGetTokenT<HcalUnpackerReport> HcalDigiMonitor::tok_unpack_

private

Definition at line 224 of file HcalDigiMonitor.h.

Referenced by analyze(), and HcalDigiMonitor().

uint64_t HcalDigiMonitor::uniqcounter[85][72][4]

private

Definition at line 140 of file HcalDigiMonitor.h.

Referenced by process_Digi(), and zeroCounters().

uint64_t HcalDigiMonitor::uniqcounter2[85][72][4]

private

Definition at line 141 of file HcalDigiMonitor.h.

Referenced by processEvent(), and zeroCounters().

Public Member Functions

Private Member Functions

Private Attributes

Additional Inherited Members

Detailed Description

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation