#include <GlobalDigisAnalyzer.h>

Inheritance diagram for GlobalDigisAnalyzer:

Public Types
typedef std::vector< double >	DoubleVector

typedef std::vector< float >	FloatVector

typedef std::vector< int >	IntVector

typedef std::map< uint32_t, float, std::less< uint32_t > >	MapType

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

Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels

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

	GlobalDigisAnalyzer (const edm::ParameterSet &)

virtual	~GlobalDigisAnalyzer ()

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

virtual void	beginStream (edm::StreamID id) final

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

	DQMEDAnalyzer (void)

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

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

uint32_t	streamId () const

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

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

	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 (std::string const &iProcessName, std::string const &iModuleLabel, bool iPrint, std::vector< char const * > &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 ()

Protected Member Functions
void	bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override

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)

Private Member Functions
void	fillECal (const edm::Event &, const edm::EventSetup &)

void	fillHCal (const edm::Event &, const edm::EventSetup &)

void	fillMuon (const edm::Event &, const edm::EventSetup &)

void	fillTrk (const edm::Event &, const edm::EventSetup &)

Private Attributes
unsigned int	count

edm::EDGetTokenT < CrossingFrame< PCaloHit > >	EBHits_Token_

double	ECalbarrelADCtoGeV_

edm::InputTag	ECalEBSrc_

edm::EDGetTokenT < EBDigiCollection >	ECalEBSrc_Token_

edm::InputTag	ECalEESrc_

edm::EDGetTokenT < EEDigiCollection >	ECalEESrc_Token_

double	ECalendcapADCtoGeV_

edm::InputTag	ECalESSrc_

edm::EDGetTokenT < ESDigiCollection >	ECalESSrc_Token_

std::map< int, double, std::less< int > >	ECalgainConv_

edm::EDGetTokenT < CrossingFrame< PCaloHit > >	EEHits_Token_

edm::EDGetTokenT < CrossingFrame< PCaloHit > >	ESHits_Token_

std::string	fName

int	frequency

bool	getAllProvenances

edm::EDGetTokenT < edm::SortedCollection < HBHEDataFrame > >	HBHEDigi_Token_

edm::InputTag	HCalDigi_

edm::InputTag	HCalSrc_

edm::EDGetTokenT < edm::PCaloHitContainer >	HCalSrc_Token_

edm::EDGetTokenT < edm::SortedCollection < HFDataFrame > >	HFDigi_Token_

std::string	hitsProducer

edm::EDGetTokenT < edm::SortedCollection < HODataFrame > >	HODigi_Token_

std::string	label

MonitorElement *	mehCSCStripADC

MonitorElement *	mehCSCStripn

MonitorElement *	mehCSCWiren

MonitorElement *	mehCSCWireTime

MonitorElement *	mehDtMuonLayer [4]

MonitorElement *	mehDtMuonn [4]

MonitorElement *	mehDtMuonTime [4]

MonitorElement *	mehDtMuonTimevLayer [4]

MonitorElement *	mehEcalAEE [2]

MonitorElement *	mehEcalMaxPos [2]

MonitorElement *	mehEcalMultvAEE [2]

MonitorElement *	mehEcaln [2]

MonitorElement *	mehEcalSHE [2]

MonitorElement *	mehEcalSHEvAEESHE [2]

MonitorElement *	mehEScalADC [3]

MonitorElement *	mehEScaln

MonitorElement *	mehHcalAEE [4]

MonitorElement *	mehHcalAEESHE [4]

MonitorElement *	mehHcaln [4]

MonitorElement *	mehHcalSHE [4]

MonitorElement *	mehHcalSHEvAEE [4]

MonitorElement *	mehRPCMuonn

MonitorElement *	mehRPCRes [5]

MonitorElement *	mehSiPixelADC [7]

MonitorElement *	mehSiPixelCol [7]

MonitorElement *	mehSiPixeln [7]

MonitorElement *	mehSiPixelRow [7]

MonitorElement *	mehSiStripADC [19]

MonitorElement *	mehSiStripn [19]

MonitorElement *	mehSiStripStrip [19]

edm::InputTag	MuCSCStripSrc_

edm::EDGetTokenT < CSCStripDigiCollection >	MuCSCStripSrc_Token_

edm::InputTag	MuCSCWireSrc_

edm::EDGetTokenT < CSCWireDigiCollection >	MuCSCWireSrc_Token_

edm::InputTag	MuDTSrc_

edm::EDGetTokenT < DTDigiCollection >	MuDTSrc_Token_

edm::InputTag	MuRPCSrc_

edm::EDGetTokenT < RPCDigiCollection >	MuRPCSrc_Token_

bool	printProvenanceInfo

edm::EDGetTokenT < edm::PSimHitContainer >	RPCSimHit_Token_

edm::InputTag	SiPxlSrc_

edm::EDGetTokenT < edm::DetSetVector< PixelDigi > >	SiPxlSrc_Token_

edm::InputTag	SiStripSrc_

edm::EDGetTokenT < edm::DetSetVector < SiStripDigi > >	SiStripSrc_Token_

int	theCSCStripPedestalCount

float	theCSCStripPedestalSum

int	verbosity

Additional Inherited Members
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)

Detailed Description

Definition at line 108 of file GlobalDigisAnalyzer.h.

Member Typedef Documentation

typedef std::vector<double> GlobalDigisAnalyzer::DoubleVector

Definition at line 113 of file GlobalDigisAnalyzer.h.

typedef std::vector<float> GlobalDigisAnalyzer::FloatVector

Definition at line 112 of file GlobalDigisAnalyzer.h.

typedef std::vector<int> GlobalDigisAnalyzer::IntVector

Definition at line 114 of file GlobalDigisAnalyzer.h.

typedef std::map<uint32_t,float,std::less<uint32_t> > GlobalDigisAnalyzer::MapType

Definition at line 115 of file GlobalDigisAnalyzer.h.

Constructor & Destructor Documentation

GlobalDigisAnalyzer::GlobalDigisAnalyzer ( const edm::ParameterSet & iPSet )

explicit

Definition at line 13 of file GlobalDigisAnalyzer.cc.

References EBHits_Token_, ECalbarrelADCtoGeV_, ECalEBSrc_, ECalEBSrc_Token_, ECalEESrc_, ECalEESrc_Token_, ECalendcapADCtoGeV_, ECalESSrc_, ECalESSrc_Token_, ECalgainConv_, EEHits_Token_, ESHits_Token_, fName, frequency, EcalMGPAGainRatio::gain12Over6(), EcalMGPAGainRatio::gain6Over1(), getAllProvenances, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), HBHEDigi_Token_, HCalDigi_, HCalSrc_, HCalSrc_Token_, HFDigi_Token_, hitsProducer, HODigi_Token_, HLT_25ns10e33_v2_cff::InputTag, edm::InputTag::instance(), edm::InputTag::label(), MuCSCStripSrc_, MuCSCStripSrc_Token_, MuCSCWireSrc_, MuCSCWireSrc_Token_, MuDTSrc_, MuDTSrc_Token_, MuRPCSrc_, MuRPCSrc_Token_, printProvenanceInfo, RPCSimHit_Token_, SiPxlSrc_, SiPxlSrc_Token_, SiStripSrc_, SiStripSrc_Token_, AlCaHLTBitMon_QueryRunRegistry::string, and verbosity.

                                                                      :
   fName(""), verbosity(0), frequency(0), label(""), getAllProvenances(false),
   printProvenanceInfo(false), hitsProducer(""), theCSCStripPedestalSum(0),
   theCSCStripPedestalCount(0), count(0)
 {
   std::string MsgLoggerCat = "GlobalDigisAnalyzer_GlobalDigisAnalyzer";
 
   // get information from parameter set
   fName = iPSet.getUntrackedParameter<std::string>("Name");
   verbosity = iPSet.getUntrackedParameter<int>("Verbosity");
   frequency = iPSet.getUntrackedParameter<int>("Frequency");
   edm::ParameterSet m_Prov =
     iPSet.getParameter<edm::ParameterSet>("ProvenanceLookup");
   getAllProvenances = 
     m_Prov.getUntrackedParameter<bool>("GetAllProvenances");
   printProvenanceInfo = 
     m_Prov.getUntrackedParameter<bool>("PrintProvenanceInfo");
   hitsProducer = iPSet.getParameter<std::string>("hitsProducer");
   
   //get Labels to use to extract information
   ECalEBSrc_ = iPSet.getParameter<edm::InputTag>("ECalEBSrc");
   ECalEESrc_ = iPSet.getParameter<edm::InputTag>("ECalEESrc");
   ECalESSrc_ = iPSet.getParameter<edm::InputTag>("ECalESSrc");
   HCalSrc_ = iPSet.getParameter<edm::InputTag>("HCalSrc");
   HCalDigi_ = iPSet.getParameter<edm::InputTag>("HCalDigi");
   SiStripSrc_ = iPSet.getParameter<edm::InputTag>("SiStripSrc"); 
   SiPxlSrc_ = iPSet.getParameter<edm::InputTag>("SiPxlSrc");
   MuDTSrc_ = iPSet.getParameter<edm::InputTag>("MuDTSrc");
   MuCSCStripSrc_ = iPSet.getParameter<edm::InputTag>("MuCSCStripSrc");
   MuCSCWireSrc_ = iPSet.getParameter<edm::InputTag>("MuCSCWireSrc");
   MuRPCSrc_ = iPSet.getParameter<edm::InputTag>("MuRPCSrc");
 
   ECalEBSrc_Token_ = consumes<EBDigiCollection>(iPSet.getParameter<edm::InputTag>("ECalEBSrc"));
   ECalEESrc_Token_ = consumes<EEDigiCollection>(iPSet.getParameter<edm::InputTag>("ECalEESrc"));
   ECalESSrc_Token_ = consumes<ESDigiCollection>(iPSet.getParameter<edm::InputTag>("ECalESSrc"));
   HCalSrc_Token_ = consumes<edm::PCaloHitContainer>(iPSet.getParameter<edm::InputTag>("HCalSrc"));
   HBHEDigi_Token_ = consumes<edm::SortedCollection<HBHEDataFrame> >(iPSet.getParameter<edm::InputTag>("HCalDigi"));  
   HODigi_Token_ = consumes<edm::SortedCollection<HODataFrame>>(iPSet.getParameter<edm::InputTag>("HCalDigi"));  
   HFDigi_Token_ = consumes<edm::SortedCollection<HFDataFrame>>(iPSet.getParameter<edm::InputTag>("HCalDigi"));  
   SiStripSrc_Token_ = consumes<edm::DetSetVector<SiStripDigi> >(iPSet.getParameter<edm::InputTag>("SiStripSrc")); 
   SiPxlSrc_Token_ = consumes<edm::DetSetVector<PixelDigi> >(iPSet.getParameter<edm::InputTag>("SiPxlSrc"));
   MuDTSrc_Token_ = consumes<DTDigiCollection>(iPSet.getParameter<edm::InputTag>("MuDTSrc"));
   MuCSCStripSrc_Token_ = consumes<CSCStripDigiCollection>(iPSet.getParameter<edm::InputTag>("MuCSCStripSrc"));
   MuCSCWireSrc_Token_ = consumes<CSCWireDigiCollection>(iPSet.getParameter<edm::InputTag>("MuCSCWireSrc"));
   MuRPCSrc_Token_ = consumes<RPCDigiCollection>(iPSet.getParameter<edm::InputTag>("MuRPCSrc"));
   //
   const std::string barrelHitsName(hitsProducer+"EcalHitsEB");
   const std::string endcapHitsName(hitsProducer+"EcalHitsEE");
   const std::string preshowerHitsName(hitsProducer+"EcalHitsES");
   EBHits_Token_ = consumes<CrossingFrame<PCaloHit> >(edm::InputTag(std::string("mix"), std::string("barrelHitsName")));
   EEHits_Token_ = consumes<CrossingFrame<PCaloHit> >(edm::InputTag(std::string("mix"), std::string("endcapHitsName")));
   ESHits_Token_ = consumes<CrossingFrame<PCaloHit> >(edm::InputTag(std::string("mix"), std::string("preshowerHitsName")));
 
   RPCSimHit_Token_ = consumes<edm::PSimHitContainer>(edm::InputTag(std::string("g4SimHits"), std::string("MuonRPCHits")));
   // use value of first digit to determine default output level (inclusive)
   // 0 is none, 1 is basic, 2 is fill output, 3 is gather output
   verbosity %= 10;
   
   // print out Parameter Set information being used
   if (verbosity >= 0) {
     edm::LogInfo(MsgLoggerCat) 
       << "\n===============================\n"
       << "Initialized as EDAnalyzer with parameter values:\n"
       << "    Name          = " << fName << "\n"
       << "    Verbosity     = " << verbosity << "\n"
       << "    Frequency     = " << frequency << "\n"
       << "    GetProv       = " << getAllProvenances << "\n"
       << "    PrintProv     = " << printProvenanceInfo << "\n"
       << "    ECalEBSrc     = " << ECalEBSrc_.label() 
       << ":" << ECalEBSrc_.instance() << "\n"
       << "    ECalEESrc     = " << ECalEESrc_.label() 
       << ":" << ECalEESrc_.instance() << "\n"
       << "    ECalESSrc     = " << ECalESSrc_.label() 
       << ":" << ECalESSrc_.instance() << "\n"
       << "    HCalSrc       = " << HCalSrc_.label() 
       << ":" << HCalSrc_.instance() << "\n"
       << "    HCalDigi       = " << HCalDigi_.label() 
       << ":" << HCalDigi_.instance() << "\n"
       << "    SiStripSrc    = " << SiStripSrc_.label() 
       << ":" << SiStripSrc_.instance() << "\n" 
       << "    SiPixelSrc    = " << SiPxlSrc_.label()
       << ":" << SiPxlSrc_.instance() << "\n"
       << "    MuDTSrc       = " << MuDTSrc_.label()
       << ":" << MuDTSrc_.instance() << "\n"
       << "    MuCSCStripSrc = " << MuCSCStripSrc_.label()
       << ":" << MuCSCStripSrc_.instance() << "\n"
       << "    MuCSCWireSrc  = " << MuCSCWireSrc_.label()
       << ":" << MuCSCWireSrc_.instance() << "\n"
       << "    MuRPCSrc      = " << MuRPCSrc_.label()
       << ":" << MuRPCSrc_.instance() << "\n"
       << "===============================\n";
   }
   
   // set default constants
   // ECal
   
   ECalbarrelADCtoGeV_ = 0.035;
   ECalendcapADCtoGeV_ = 0.06;
 
   EcalMGPAGainRatio defaultRatios;  
   ECalgainConv_[0] = 0.;
   ECalgainConv_[1] = 1.;
   ECalgainConv_[2] = defaultRatios.gain12Over6() ;
   ECalgainConv_[3] = ECalgainConv_[2]*(defaultRatios.gain6Over1()) ;
   
   if (verbosity >= 0) {
     edm::LogInfo(MsgLoggerCat) 
       << "Modified Calorimeter gain constants: g0 = " << ECalgainConv_[0]
       << ", g1 = " << ECalgainConv_[1] << ", g2 = " << ECalgainConv_[2]
       << ", g3 = " << ECalgainConv_[3];
   }
 }

GlobalDigisAnalyzer::~GlobalDigisAnalyzer ( )

virtual

Definition at line 126 of file GlobalDigisAnalyzer.cc.

126 {}

Member Function Documentation

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

virtual

Implements edm::stream::EDAnalyzerBase.

Definition at line 419 of file GlobalDigisAnalyzer.cc.

References count, ECalbarrelADCtoGeV_, ECalendcapADCtoGeV_, edm::EventID::event(), fillECal(), fillHCal(), fillMuon(), fillTrk(), frequency, edm::EventSetup::get(), edm::Event::getAllProvenance(), getAllProvenances, EcalADCToGeVConstant::getEBValue(), EcalADCToGeVConstant::getEEValue(), i, edm::EventBase::id(), nevt, printProvenanceInfo, edm::ESHandle< class >::product(), edm::EventID::run(), AlCaHLTBitMon_QueryRunRegistry::string, and verbosity.

 {
   std::string MsgLoggerCat = "GlobalDigisAnalyzer_analyze";
   
   // keep track of number of events processed
   ++count;
 
 
   
   // THIS BLOCK MIGRATED HERE FROM beginJob:
   // setup calorimeter constants from service
   edm::ESHandle<EcalADCToGeVConstant> pAgc;
   iSetup.get<EcalADCToGeVConstantRcd>().get(pAgc);
   const EcalADCToGeVConstant* agc = pAgc.product();
   ECalbarrelADCtoGeV_ = agc->getEBValue();
   ECalendcapADCtoGeV_ = agc->getEEValue();
   if (verbosity >= 0) {
     edm::LogInfo(MsgLoggerCat)
       << "Modified Calorimeter ADCtoGeV constants: barrel = " 
       << ECalbarrelADCtoGeV_ << ", endcap = " << ECalendcapADCtoGeV_;
   }
   
 
 
   // get event id information
   edm::RunNumber_t nrun = iEvent.id().run();
   edm::EventNumber_t nevt = iEvent.id().event();
   
   if (verbosity > 0) {
     edm::LogInfo(MsgLoggerCat)
       << "Processing run " << nrun << ", event " << nevt
       << " (" << count << " events total)";
   } else if (verbosity == 0) {
     if (nevt%frequency == 0 || nevt == 1) {
       edm::LogInfo(MsgLoggerCat)
     << "Processing run " << nrun << ", event " << nevt
     << " (" << count << " events total)";
     }
   }
     
   // look at information available in the event
   if (getAllProvenances) {
     
     std::vector<const edm::Provenance*> AllProv;
     iEvent.getAllProvenance(AllProv);
     
     if (verbosity >= 0)
       edm::LogInfo(MsgLoggerCat)
     << "Number of Provenances = " << AllProv.size();
     
     if (printProvenanceInfo && (verbosity >= 0)) {
       TString eventout("\nProvenance info:\n");      
       
       for (unsigned int i = 0; i < AllProv.size(); ++i) {
     eventout += "\n       ******************************";
     eventout += "\n       Module       : ";
     eventout += AllProv[i]->moduleLabel();
     eventout += "\n       ProductID    : ";
     eventout += AllProv[i]->productID().id();
     eventout += "\n       ClassName    : ";
     eventout += AllProv[i]->className();
     eventout += "\n       InstanceName : ";
     eventout += AllProv[i]->productInstanceName();
     eventout += "\n       BranchName   : ";
     eventout += AllProv[i]->branchName();
       }
       eventout += "\n       ******************************\n";
       edm::LogInfo(MsgLoggerCat) << eventout << "\n";
       printProvenanceInfo = false;
     }
     getAllProvenances = false;
   }
   
   // call fill functions
   // gather Ecal information from event
   fillECal(iEvent,  iSetup);
   // gather Hcal information from event
   fillHCal(iEvent, iSetup);
   // gather Track information from event
   fillTrk(iEvent,  iSetup);
   // gather Muon information from event
   fillMuon(iEvent,  iSetup);
   
   if (verbosity > 0)
     edm::LogInfo (MsgLoggerCat)
       << "Done gathering data from event.";
   
   if (verbosity > 2)
     edm::LogInfo (MsgLoggerCat)
       << "Saving event contents:";
     
   return;
 }

void GlobalDigisAnalyzer::bookHistograms	(	DQMStore::IBooker &	iBooker,
		edm::Run const &	,
		edm::EventSetup const &
	)

overrideprotectedvirtual

Implements DQMEDAnalyzer.

Definition at line 128 of file GlobalDigisAnalyzer.cc.

References DQMStore::IBooker::book1D(), DQMStore::IBooker::bookProfile(), i, j, mehCSCStripADC, mehCSCStripn, mehCSCWiren, mehCSCWireTime, mehDtMuonLayer, mehDtMuonn, mehDtMuonTime, mehDtMuonTimevLayer, mehEcalAEE, mehEcalMaxPos, mehEcalMultvAEE, mehEcaln, mehEcalSHE, mehEcalSHEvAEESHE, mehEScalADC, mehEScaln, mehHcalAEE, mehHcalAEESHE, mehHcaln, mehHcalSHE, mehHcalSHEvAEE, mehRPCMuonn, mehRPCRes, mehSiPixelADC, mehSiPixelCol, mehSiPixeln, mehSiPixelRow, mehSiStripADC, mehSiStripn, mehSiStripStrip, MonitorElement::setAxisTitle(), DQMStore::IBooker::setCurrentFolder(), and AlCaHLTBitMon_QueryRunRegistry::string.

                                                                                                         {
   // Si Strip
   std::string SiStripString[19] = {"TECW1", "TECW2", "TECW3", "TECW4", 
                  "TECW5", "TECW6", "TECW7", "TECW8", 
                  "TIBL1", "TIBL2", "TIBL3", "TIBL4", 
                  "TIDW1", "TIDW2", "TIDW3", "TOBL1", 
                  "TOBL2", "TOBL3", "TOBL4"};
   for(int i = 0; i<19; ++i) {
     mehSiStripn[i]=0;
     mehSiStripADC[i]=0;
     mehSiStripStrip[i]=0;
   }
   std::string hcharname, hchartitle;
   iBooker.setCurrentFolder("GlobalDigisV/SiStrips");
   for(int amend = 0; amend < 19; ++amend) { 
     hcharname = "hSiStripn_"+SiStripString[amend];
     hchartitle= SiStripString[amend]+"  Digis";
     mehSiStripn[amend] = iBooker.book1D(hcharname,hchartitle,5000,0.,10000.);
     mehSiStripn[amend]->setAxisTitle("Number of Digis",1);
     mehSiStripn[amend]->setAxisTitle("Count",2);
     
     hcharname = "hSiStripADC_"+SiStripString[amend];
     hchartitle= SiStripString[amend]+" ADC";
     mehSiStripADC[amend] = iBooker.book1D(hcharname,hchartitle,150,0.0,300.);
     mehSiStripADC[amend]->setAxisTitle("ADC",1);
     mehSiStripADC[amend]->setAxisTitle("Count",2);
     
     hcharname = "hSiStripStripADC_"+SiStripString[amend];
     hchartitle= SiStripString[amend]+" Strip";
     mehSiStripStrip[amend] = iBooker.book1D(hcharname,hchartitle,200,0.0,800.);
     mehSiStripStrip[amend]->setAxisTitle("Strip Number",1);
     mehSiStripStrip[amend]->setAxisTitle("Count",2);
   }
   
   //HCal
   std::string HCalString[4] = {"HB", "HE", "HO","HF"}; 
   float calnUpper[4] = {30000.,30000.,30000.,20000.}; 
   float calnLower[4]={0.,0.,0.,0.}; 
   float SHEUpper[4]={1.,1.,1.,1.};
   float SHEvAEEUpper[4] = {5000, 5000, 5000, 5000}; 
   float SHEvAEELower[4] = {-5000, -5000, -5000, -5000}; 
   int SHEvAEEnBins[4] = {200,200,200,200};
   double ProfileUpper[4] = {1.,1.,1.,1.};  
   
   for(int i =0; i<4; ++i) {
     mehHcaln[i]=0;
     mehHcalAEE[i]=0;
     mehHcalSHE[i]=0;
     mehHcalAEESHE[i]=0;
     mehHcalSHEvAEE[i]=0;
   }
   iBooker.setCurrentFolder("GlobalDigisV/HCals");
   
   for(int amend = 0; amend < 4; ++amend) {
     hcharname = "hHcaln_"+HCalString[amend];
     hchartitle= HCalString[amend]+"  digis";
     mehHcaln[amend] = iBooker.book1D(hcharname,hchartitle, 10000, calnLower[amend], 
                 calnUpper[amend]);
     mehHcaln[amend]->setAxisTitle("Number of Digis",1);
     mehHcaln[amend]->setAxisTitle("Count",2);
 
     hcharname = "hHcalAEE_"+HCalString[amend];
     hchartitle= HCalString[amend]+"Cal AEE";
     mehHcalAEE[amend] = iBooker.book1D(hcharname,hchartitle, 60, -10., 50.);
     mehHcalAEE[amend]->setAxisTitle("Analog Equivalent Energy",1);
     mehHcalAEE[amend]->setAxisTitle("Count",2);
 
     hcharname = "hHcalSHE_"+HCalString[amend];
     hchartitle= HCalString[amend]+"Cal SHE";
     mehHcalSHE[amend] = iBooker.book1D(hcharname,hchartitle, 1000, 0.0, 
                   SHEUpper[amend]);
     mehHcalSHE[amend]->setAxisTitle("Simulated Hit Energy",1);
     mehHcalSHE[amend]->setAxisTitle("Count",2);
 
     hcharname = "hHcalAEESHE_"+HCalString[amend];
     hchartitle= HCalString[amend]+"Cal AEE/SHE";
     mehHcalAEESHE[amend] = iBooker.book1D(hcharname, hchartitle, SHEvAEEnBins[amend], 
                  SHEvAEELower[amend], 
                  SHEvAEEUpper[amend]);
     mehHcalAEESHE[amend]->setAxisTitle("ADC / SHE",1);
     mehHcalAEESHE[amend]->setAxisTitle("Count",2);
     
     hcharname = "hHcalSHEvAEE_"+HCalString[amend];
     hchartitle= HCalString[amend]+"Cal SHE vs. AEE";
     mehHcalSHEvAEE[amend] = iBooker.bookProfile(hcharname,hchartitle, 60, -10., 
                        50., 100, 0., 
                        (float)ProfileUpper[amend],"");
     mehHcalSHEvAEE[amend]->setAxisTitle("AEE / SHE",1);
     mehHcalSHEvAEE[amend]->setAxisTitle("SHE",2);
 
   }
   
   //Ecal
   std::string ECalString[2] = {"EB","EE"}; 
   
   for(int i =0; i<2; ++i) {
     mehEcaln[i]=0;
     mehEcalAEE[i]=0;
     mehEcalSHE[i]=0;
     mehEcalMaxPos[i]=0;
     mehEcalMultvAEE[i]=0;
     mehEcalSHEvAEESHE[i]=0;
   }
   iBooker.setCurrentFolder("GlobalDigisV/ECals");
   
   for(int amend = 0; amend < 2; ++amend) {
     hcharname = "hEcaln_"+ECalString[amend];
     hchartitle= ECalString[amend]+"  digis";
     mehEcaln[amend] = iBooker.book1D(hcharname,hchartitle, 3000, 0., 40000.);
     mehEcaln[amend]->setAxisTitle("Number of Digis",1);
     mehEcaln[amend]->setAxisTitle("Count",2);
 
     hcharname = "hEcalAEE_"+ECalString[amend];
     hchartitle= ECalString[amend]+"Cal AEE";
     mehEcalAEE[amend] = iBooker.book1D(hcharname,hchartitle, 1000, 0., 100.);
     mehEcalAEE[amend]->setAxisTitle("Analog Equivalent Energy",1);
     mehEcalAEE[amend]->setAxisTitle("Count",2);
 
     hcharname = "hEcalSHE_"+ECalString[amend];
     hchartitle= ECalString[amend]+"Cal SHE";
     mehEcalSHE[amend] = iBooker.book1D(hcharname,hchartitle, 500, 0., 50.);
     mehEcalSHE[amend]->setAxisTitle("Simulated Hit Energy",1);
     mehEcalSHE[amend]->setAxisTitle("Count",2);
 
     hcharname = "hEcalMaxPos_"+ECalString[amend];
     hchartitle= ECalString[amend]+"Cal MaxPos";
     mehEcalMaxPos[amend] = iBooker.book1D(hcharname,hchartitle,10, 0., 10.);
     mehEcalMaxPos[amend]->setAxisTitle("Maximum Position",1);
     mehEcalMaxPos[amend]->setAxisTitle("Count",2);
     
     hcharname = "hEcalSHEvAEESHE_"+ECalString[amend];
     hchartitle= ECalString[amend]+"Cal SHE vs. AEE/SHE";
     mehEcalSHEvAEESHE[amend] = iBooker.bookProfile(hcharname,hchartitle,1000, 0., 100., 
                       500, 0., 50.,"");
     mehEcalSHEvAEESHE[amend]->setAxisTitle("AEE / SHE",1);
     mehEcalSHEvAEESHE[amend]->setAxisTitle("SHE",2);
 
     hcharname = "hEcalMultvAEE_"+ECalString[amend];
     hchartitle= ECalString[amend]+"Cal Multi vs. AEE";
     mehEcalMultvAEE[amend] = iBooker.bookProfile(hcharname,hchartitle, 1000, 0., 100., 
                     4000, 0., 40000.,"");
     mehEcalMultvAEE[amend]->setAxisTitle("Analog Equivalent Energy",1);
     mehEcalMultvAEE[amend]->setAxisTitle("Number of Digis",2);      
   }
   mehEScaln = 0;
 
   hcharname = "hEcaln_ES";
   hchartitle= "ESCAL  digis";
   mehEScaln = iBooker.book1D(hcharname,hchartitle, 1000, 0., 5000.);
   mehEScaln->setAxisTitle("Number of Digis",1);
   mehEScaln->setAxisTitle("Count",2);
 
   std::string ADCNumber[3] = {"0", "1", "2"};
   for(int i =0; i<3; ++i) {
     mehEScalADC[i] = 0;
     hcharname = "hEcalADC"+ADCNumber[i]+"_ES";
     hchartitle= "ESCAL  ADC"+ADCNumber[i];
     mehEScalADC[i] = iBooker.book1D(hcharname,hchartitle, 1500, 0., 1500.);
     mehEScalADC[i]->setAxisTitle("ADC"+ADCNumber[i],1);
     mehEScalADC[i]->setAxisTitle("Count",2);
   }
   
   //Si Pixels ***DONE***  
   std::string SiPixelString[7] = {"BRL1", "BRL2", "BRL3", "FWD1n", "FWD1p", 
                 "FWD2n", "FWD2p"};
   for(int j =0; j<7; ++j) {
     mehSiPixeln[j]=0;
     mehSiPixelADC[j]=0;
     mehSiPixelRow[j]=0;
     mehSiPixelCol[j]=0;
   }
   
   iBooker.setCurrentFolder("GlobalDigisV/SiPixels");
   for(int amend = 0; amend < 7; ++amend) {
     hcharname = "hSiPixeln_"+SiPixelString[amend];
     hchartitle= SiPixelString[amend]+" Digis";
     if(amend<3) mehSiPixeln[amend] = iBooker.book1D(hcharname,hchartitle,500,0.,1000.);
     else mehSiPixeln[amend] = iBooker.book1D(hcharname,hchartitle,500,0.,1000.);
     mehSiPixeln[amend]->setAxisTitle("Number of Digis",1);
     mehSiPixeln[amend]->setAxisTitle("Count",2);
     
     hcharname = "hSiPixelADC_"+SiPixelString[amend];
     hchartitle= SiPixelString[amend]+" ADC";
     mehSiPixelADC[amend] = iBooker.book1D(hcharname,hchartitle,150,0.0,300.);
     mehSiPixelADC[amend]->setAxisTitle("ADC",1);
     mehSiPixelADC[amend]->setAxisTitle("Count",2);
 
     hcharname = "hSiPixelRow_"+SiPixelString[amend];
     hchartitle= SiPixelString[amend]+" Row";
     mehSiPixelRow[amend] = iBooker.book1D(hcharname,hchartitle,100,0.0,100.);
     mehSiPixelRow[amend]->setAxisTitle("Row Number",1);
     mehSiPixelRow[amend]->setAxisTitle("Count",2);
 
     hcharname = "hSiPixelColumn_"+SiPixelString[amend];
     hchartitle= SiPixelString[amend]+" Column";
     mehSiPixelCol[amend] = iBooker.book1D(hcharname,hchartitle,200,0.0,500.);
     mehSiPixelCol[amend]->setAxisTitle("Column Number",1);
     mehSiPixelCol[amend]->setAxisTitle("Count",2);
   }
 
   //Muons
   iBooker.setCurrentFolder("GlobalDigisV/Muons");
 
   //DT
   std::string MuonString[4] = {"MB1", "MB2", "MB3", "MB4"};
   
   for(int i =0; i < 4; ++i) {
     mehDtMuonn[i] = 0;
     mehDtMuonLayer[i] = 0;
     mehDtMuonTime[i] = 0;
     mehDtMuonTimevLayer[i] = 0;
   }
   
   for(int j = 0; j < 4; ++j) {
     hcharname = "hDtMuonn_"+MuonString[j];
     hchartitle= MuonString[j]+"  digis";
     mehDtMuonn[j] = iBooker.book1D(hcharname,hchartitle,250, 0., 500.);
     mehDtMuonn[j]->setAxisTitle("Number of Digis",1);
     mehDtMuonn[j]->setAxisTitle("Count",2);
 
     hcharname = "hDtLayer_"+MuonString[j];
     hchartitle= MuonString[j]+"  Layer";
     mehDtMuonLayer[j] = iBooker.book1D(hcharname,hchartitle,12, 1., 13.);
     mehDtMuonLayer[j]->setAxisTitle("4 * (SuperLayer - 1) + Layer",1);
     mehDtMuonLayer[j]->setAxisTitle("Count",2);
 
     hcharname = "hDtMuonTime_"+MuonString[j];
     hchartitle= MuonString[j]+"  Time";
     mehDtMuonTime[j] = iBooker.book1D(hcharname,hchartitle,300, 400., 1000.);
     mehDtMuonTime[j]->setAxisTitle("Time",1);
     mehDtMuonTime[j]->setAxisTitle("Count",2);
 
     hcharname = "hDtMuonTimevLayer_"+MuonString[j];
     hchartitle= MuonString[j]+"  Time vs. Layer";
     mehDtMuonTimevLayer[j] = iBooker.bookProfile(hcharname,hchartitle,12, 1., 13., 300, 
                     400., 1000.,"");
     mehDtMuonTimevLayer[j]->setAxisTitle("4 * (SuperLayer - 1) + Layer",1);
     mehDtMuonTimevLayer[j]->setAxisTitle("Time",2);
   }
 
   //CSC 
   mehCSCStripn = 0;
   hcharname = "hCSCStripn";
   hchartitle = "CSC Strip digis";
   mehCSCStripn = iBooker.book1D(hcharname,hchartitle,250, 0., 500.);
   mehCSCStripn->setAxisTitle("Number of Digis",1);
   mehCSCStripn->setAxisTitle("Count",2);
   
   mehCSCStripADC = 0;
   hcharname = "hCSCStripADC";
   hchartitle = "CSC Strip ADC";
   mehCSCStripADC = iBooker.book1D(hcharname,hchartitle, 110, 0., 1100.);
   mehCSCStripADC->setAxisTitle("ADC",1);
   mehCSCStripADC->setAxisTitle("Count",2);
   
   mehCSCWiren = 0;
   hcharname = "hCSCWiren";
   hchartitle = "CSC Wire digis";
   mehCSCWiren = iBooker.book1D(hcharname,hchartitle,250, 0., 500.);
   mehCSCWiren->setAxisTitle("Number of Digis",1);
   mehCSCWiren->setAxisTitle("Count",2);
   
   mehCSCWireTime = 0;
   hcharname = "hCSCWireTime";
   hchartitle = "CSC Wire Time";
   mehCSCWireTime = iBooker.book1D(hcharname,hchartitle,10, 0., 10.);
   mehCSCWireTime->setAxisTitle("Time",1);
   mehCSCWireTime->setAxisTitle("Count",2);
   
   // RPC 
   mehRPCMuonn = 0;
   hcharname = "hRPCMuonn";
   hchartitle = "RPC digis";
   mehCSCStripn = iBooker.book1D(hcharname,hchartitle,250, 0., 500.);
   mehCSCStripn->setAxisTitle("Number of Digis",1);
   mehCSCStripn->setAxisTitle("Count",2);
 
   std::string MuonRPCString[5] = {"Wmin2", "Wmin1", "W0", "Wpu1", "Wpu2"};
   for(int i =0; i < 5; ++i) {
     mehRPCRes[i] = 0;
   }
 
   for(int j = 0; j < 5; ++j) {    
     hcharname = "hRPCRes_"+MuonRPCString[j];
     hchartitle= MuonRPCString[j]+"  Digi - Sim";   
     mehRPCRes[j] = iBooker.book1D(hcharname,hchartitle,200, -8., 8.);
     mehRPCRes[j]->setAxisTitle("Digi - Sim center of strip x",1);
     mehRPCRes[j]->setAxisTitle("Count",2);
   }
 }

void GlobalDigisAnalyzer::fillECal	(	const edm::Event &	iEvent,
		const edm::EventSetup &	iSetup
	)

private

Definition at line 514 of file GlobalDigisAnalyzer.cc.

References ESSample::adc(), EcalMGPASample::adc(), HLT_25ns10e33_v2_cff::barrelHits, EBHits_Token_, ECalbarrelADCtoGeV_, ECalEBSrc_Token_, ECalEESrc_Token_, ECalESSrc_Token_, ECalgainConv_, EEHits_Token_, HLT_25ns10e33_v2_cff::endcapHits, ESHits_Token_, MonitorElement::Fill(), EcalMGPASample::gainId(), edm::Event::getByToken(), i, EEDataFrame::id(), EBDataFrame::id(), GeomDetEnumerators::isBarrel(), edm::HandleBase::isValid(), LogDebug, ESDataFrame::MAXSAMPLES, EcalDataFrame::MAXSAMPLES, mehEcalAEE, mehEcalMaxPos, mehEcalMultvAEE, mehEcaln, mehEcalSHE, mehEcalSHEvAEESHE, mehEScalADC, mehEScaln, edm::Handle< T >::product(), DetId::rawId(), compare_using_db::sample, ESDataFrame::size(), EcalDataFrame::size(), AlCaHLTBitMon_QueryRunRegistry::string, and verbosity.

Referenced by analyze().

 {
   std::string MsgLoggerCat = "GlobalDigisAnalyzer_fillECal";
   
   TString eventout;
   if (verbosity > 0)
     eventout = "\nGathering info:";  
   
   // extract crossing frame from event
   edm::Handle<CrossingFrame<PCaloHit> > crossingFrame;
   
   //extract EB information
   bool isBarrel = true;
   edm::Handle<EBDigiCollection> EcalDigiEB;  
   iEvent.getByToken(ECalEBSrc_Token_, EcalDigiEB);
   bool validDigiEB = true;
   if (!EcalDigiEB.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find EcalDigiEB in event!";
     validDigiEB = false;
   }  
   if (validDigiEB) {
     if ( EcalDigiEB->size() == 0) isBarrel = false;
     
     if (isBarrel) {
       
       // loop over simhits
       MapType ebSimMap;
       iEvent.getByToken(EBHits_Token_,crossingFrame);
       bool validXFrame = true;
       if (!crossingFrame.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find cal barrel crossingFrame in event!";
     validXFrame = false;
       }
       if (validXFrame) {
     std::auto_ptr<MixCollection<PCaloHit> >
       barrelHits(new MixCollection<PCaloHit>(crossingFrame.product()));
     
     // keep track of sum of simhit energy in each crystal
     for (MixCollection<PCaloHit>::MixItr hitItr 
            = barrelHits->begin();
          hitItr != barrelHits->end();
          ++hitItr) {
       
       EBDetId ebid = EBDetId(hitItr->id());
       
       uint32_t crystid = ebid.rawId();
       ebSimMap[crystid] += hitItr->energy();
     }
       }
 
       // loop over digis
       const EBDigiCollection *barrelDigi = EcalDigiEB.product();
       
       std::vector<double> ebAnalogSignal;
       std::vector<double> ebADCCounts;
       std::vector<double> ebADCGains;
       ebAnalogSignal.reserve(EBDataFrame::MAXSAMPLES);
       ebADCCounts.reserve(EBDataFrame::MAXSAMPLES);
       ebADCGains.reserve(EBDataFrame::MAXSAMPLES);
       
       int i = 0;
       for (unsigned int digis=0; digis<EcalDigiEB->size(); ++digis) {
     
     ++i;
     
     EBDataFrame ebdf = (*barrelDigi)[digis];
     int nrSamples = ebdf.size();
     
     EBDetId ebid = ebdf.id () ;
     
     double Emax = 0;
     int Pmax = 0;
     double pedestalPreSample = 0.;
     double pedestalPreSampleAnalog = 0.;
     
     for (int sample = 0 ; sample < nrSamples; ++sample) {
       ebAnalogSignal[sample] = 0.;
       ebADCCounts[sample] = 0.;
       ebADCGains[sample] = -1.;
     }
     
     // calculate maximum energy and pedestal
     for (int sample = 0 ; sample < nrSamples; ++sample) {
       
       EcalMGPASample thisSample = ebdf[sample];
       ebADCCounts[sample] = (thisSample.adc());
       ebADCGains[sample]  = (thisSample.gainId());
       ebAnalogSignal[sample] = 
         (ebADCCounts[sample] * ECalgainConv_[(int)ebADCGains[sample]]
          * ECalbarrelADCtoGeV_);
       if (Emax < ebAnalogSignal[sample]) {
         Emax = ebAnalogSignal[sample];
         Pmax = sample;
       }
       if ( sample < 3 ) {
         pedestalPreSample += ebADCCounts[sample] ;
         pedestalPreSampleAnalog += 
           ebADCCounts[sample] * ECalgainConv_[(int)ebADCGains[sample]]
           * ECalbarrelADCtoGeV_ ;
       }
       
     }
     pedestalPreSample /= 3. ; 
     pedestalPreSampleAnalog /= 3. ; 
     
     // calculate pedestal subtracted digi energy in the crystal
     double Erec = Emax - pedestalPreSampleAnalog
       * ECalgainConv_[(int)ebADCGains[Pmax]];
     
     // gather necessary information
     mehEcalMaxPos[0]->Fill(Pmax);
     mehEcalSHE[0]->Fill(ebSimMap[ebid.rawId()]);
     mehEcalAEE[0]->Fill(Erec);
     //Adding protection against FPE
     if (ebSimMap[ebid.rawId()]!=0) {
       mehEcalSHEvAEESHE[0]->Fill(Erec/ebSimMap[ebid.rawId()],
                      ebSimMap[ebid.rawId()]);
     }
     //else {
     //  std::cout<<"Would have been an FPE! with ebSimMap[ebid.rawId()]==0\n";
     //}
 
     mehEcalMultvAEE[0]->Fill(Pmax,(float)i);
       }
       
       if (verbosity > 1) {
     eventout += "\n          Number of EBDigis collected:.............. ";
     eventout += i;
       }
       mehEcaln[0]->Fill((float)i);
     }
   }
   
   //extract EE information
   bool isEndCap = true;
   edm::Handle<EEDigiCollection> EcalDigiEE;  
   iEvent.getByToken(ECalEESrc_Token_, EcalDigiEE);
   bool validDigiEE = true;
   if (!EcalDigiEE.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find EcalDigiEE in event!";
     validDigiEE = false;
   }  
   if (validDigiEE) {
     if (EcalDigiEE->size() == 0) isEndCap = false;
     
     if (isEndCap) {
       
       // loop over simhits
       MapType eeSimMap;
       iEvent.getByToken(EEHits_Token_,crossingFrame);
       bool validXFrame = true;
       if (!crossingFrame.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find cal endcap crossingFrame in event!";
     validXFrame = false;
       }
       if (validXFrame) {
     std::auto_ptr<MixCollection<PCaloHit> >
       endcapHits(new MixCollection<PCaloHit>(crossingFrame.product()));
     
     // keep track of sum of simhit energy in each crystal
     for (MixCollection<PCaloHit>::MixItr hitItr 
            = endcapHits->begin();
          hitItr != endcapHits->end();
          ++hitItr) {
       
       EEDetId eeid = EEDetId(hitItr->id());
       
       uint32_t crystid = eeid.rawId();
       eeSimMap[crystid] += hitItr->energy();
     }
       }
 
       // loop over digis
       const EEDigiCollection *endcapDigi = EcalDigiEE.product();
       
       std::vector<double> eeAnalogSignal;
       std::vector<double> eeADCCounts;
       std::vector<double> eeADCGains;
       eeAnalogSignal.reserve(EEDataFrame::MAXSAMPLES);
       eeADCCounts.reserve(EEDataFrame::MAXSAMPLES);
       eeADCGains.reserve(EEDataFrame::MAXSAMPLES);
       
       int inc = 0;
       for (unsigned int digis=0; digis<EcalDigiEE->size(); ++digis){ 
     
     ++inc;
     
     EEDataFrame eedf = (*endcapDigi)[digis];
     int nrSamples = eedf.size();
     
     EEDetId eeid = eedf.id () ;
     
     double Emax = 0;
     int Pmax = 0;
     double pedestalPreSample = 0.;
     double pedestalPreSampleAnalog = 0.;
     
     for (int sample = 0 ; sample < nrSamples; ++sample) {
       eeAnalogSignal[sample] = 0.;
       eeADCCounts[sample] = 0.;
       eeADCGains[sample] = -1.;
     }
     
     // calculate maximum enery and pedestal
     for (int sample = 0 ; sample < nrSamples; ++sample) {
       
       EcalMGPASample thisSample = eedf[sample];
       
       eeADCCounts[sample] = (thisSample.adc());
       eeADCGains[sample]  = (thisSample.gainId());
       eeAnalogSignal[sample] = 
         (eeADCCounts[sample] * ECalgainConv_[(int)eeADCGains[sample]]
          * ECalbarrelADCtoGeV_);
       if (Emax < eeAnalogSignal[sample]) {
         Emax = eeAnalogSignal[sample];
         Pmax = sample;
       }
       if ( sample < 3 ) {
         pedestalPreSample += eeADCCounts[sample] ;
         pedestalPreSampleAnalog += 
           eeADCCounts[sample] * ECalgainConv_[(int)eeADCGains[sample]]
           * ECalbarrelADCtoGeV_ ;
       }
       
     }
     pedestalPreSample /= 3. ; 
     pedestalPreSampleAnalog /= 3. ; 
     
     // calculate pedestal subtracted digi energy in the crystal
     double Erec = Emax - pedestalPreSampleAnalog
       * ECalgainConv_[(int)eeADCGains[Pmax]];
     
     // gather necessary information
     mehEcalMaxPos[1]->Fill(Pmax);
     mehEcalSHE[1]->Fill(eeSimMap[eeid.rawId()]);
     mehEcalAEE[1]->Fill(Erec);
     //Adding protection against FPE
         if (eeSimMap[eeid.rawId()]!=0){
       mehEcalSHEvAEESHE[1]->Fill(Erec/eeSimMap[eeid.rawId()],
                      eeSimMap[eeid.rawId()]);
     }
     //else{
     //  std::cout<<"Would have been an FPE! with eeSimMap[eeid.rawId()]==0\n"; 
     //}
     mehEcalMultvAEE[1]->Fill(Pmax,(float)inc);
     
       }
       
       if (verbosity > 1) {
     eventout += "\n          Number of EEDigis collected:.............. ";
     eventout += inc;
       }
       
       mehEcaln[1]->Fill((float)inc);
     }
   }
 
   //extract ES information
   bool isPreshower = true;
   edm::Handle<ESDigiCollection> EcalDigiES;  
   iEvent.getByToken(ECalESSrc_Token_, EcalDigiES);
   bool validDigiES = true;
   if (!EcalDigiES.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find EcalDigiES in event!";
     validDigiES = false;
   } 
   
   // ONLY WHILE GEOMETRY IS REMOVED
   validDigiES = false;
  
   if (validDigiES) {
     if (EcalDigiES->size() == 0) isPreshower = false;
     
     if (isPreshower) {
       
       // loop over simhits
       iEvent.getByToken(ESHits_Token_,crossingFrame);
       bool validXFrame = true;
       if (!crossingFrame.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find cal preshower crossingFrame in event!";
     validXFrame = false;
       }
       if (validXFrame) {
     std::auto_ptr<MixCollection<PCaloHit> >
       preshowerHits(new MixCollection<PCaloHit>(crossingFrame.product()));
     
     // keep track of sum of simhit energy in each crystal
     MapType esSimMap;
     for (MixCollection<PCaloHit>::MixItr hitItr 
            = preshowerHits->begin();
          hitItr != preshowerHits->end();
          ++hitItr) {
       
       ESDetId esid = ESDetId(hitItr->id());
       
       uint32_t crystid = esid.rawId();
       esSimMap[crystid] += hitItr->energy();
     }
       }
 
       // loop over digis
       const ESDigiCollection *preshowerDigi = EcalDigiES.product();
       
       std::vector<double> esADCCounts;
       esADCCounts.reserve(ESDataFrame::MAXSAMPLES);
       
       int i = 0;
       for (unsigned int digis=0; digis<EcalDigiES->size(); ++digis) {
     
     ++i;
     
     
     ESDataFrame esdf = (*preshowerDigi)[digis];
     int nrSamples = esdf.size();
     
     for (int sample = 0 ; sample < nrSamples; ++sample) {
       esADCCounts[sample] = 0.;
     }
     
     // gether ADC counts
     for (int sample = 0 ; sample < nrSamples; ++sample) {
       
       ESSample thisSample = esdf[sample];
       esADCCounts[sample] = (thisSample.adc());
     }
     
     mehEScalADC[0]->Fill(esADCCounts[0]);
     mehEScalADC[1]->Fill(esADCCounts[1]);
     mehEScalADC[2]->Fill(esADCCounts[2]);
     
       }
       
       if (verbosity > 1) {
     eventout += "\n          Number of ESDigis collected:.............. ";
     eventout += i;
       }
       
       mehEScaln->Fill((float)i);
     }
   }
   if (verbosity > 0)
     edm::LogInfo(MsgLoggerCat) << eventout << "\n";
   
   return;
 }

void GlobalDigisAnalyzer::fillHCal	(	const edm::Event &	iEvent,
		const edm::EventSetup &	iSetup
	)

private

Definition at line 874 of file GlobalDigisAnalyzer.cc.

References HcalCoderDb::adc2fC(), MonitorElement::Fill(), edm::EventSetup::get(), edm::Event::getByToken(), HBHEDigi_Token_, HCalSrc_Token_, HFDigi_Token_, HODigi_Token_, ihf, cuy::ii, edm::ESHandleBase::isValid(), edm::HandleBase::isValid(), LogDebug, mehHcalAEE, mehHcalAEESHE, mehHcaln, mehHcalSHE, mehHcalSHEvAEE, HcalCalibrations::pedestal(), edm::Handle< T >::product(), DetId::rawId(), sdHcalBrl, sdHcalEC, sdHcalFwd, sdHcalOut, CaloSamples::size(), AlCaHLTBitMon_QueryRunRegistry::string, and verbosity.

Referenced by analyze().

 {
   std::string MsgLoggerCat = "GlobalDigisAnalyzer_fillHCal";
   
   TString eventout;
   if (verbosity > 0)
     eventout = "\nGathering info:";  
   
   // get calibration info
   edm::ESHandle<HcalDbService> HCalconditions;
   iSetup.get<HcalDbRecord>().get(HCalconditions);
   if (!HCalconditions.isValid()) {
     edm::LogWarning(MsgLoggerCat)
       << "Unable to find HCalconditions in event!";
     return;
   } 
   //HcalCalibrations calibrations;
   CaloSamples tool;
   
   // extract simhit info
   edm::Handle<edm::PCaloHitContainer> hcalHits;
   iEvent.getByToken(HCalSrc_Token_,hcalHits);
   bool validhcalHits = true;
   if (!hcalHits.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find hcalHits in event!";
     validhcalHits = false;
   }  
   MapType fHBEnergySimHits;
   MapType fHEEnergySimHits;
   MapType fHOEnergySimHits;
   MapType fHFEnergySimHits;
   if (validhcalHits) {
     const edm::PCaloHitContainer *simhitResult = hcalHits.product();
     
     for (std::vector<PCaloHit>::const_iterator simhits = simhitResult->begin();
      simhits != simhitResult->end();
      ++simhits) {
       
       HcalDetId detId(simhits->id());
       uint32_t cellid = detId.rawId();
       
       if (detId.subdet() == sdHcalBrl){  
     fHBEnergySimHits[cellid] += simhits->energy(); 
       }
       if (detId.subdet() == sdHcalEC){  
     fHEEnergySimHits[cellid] += simhits->energy(); 
       }    
       if (detId.subdet() == sdHcalOut){  
     fHOEnergySimHits[cellid] += simhits->energy(); 
       }    
       if (detId.subdet() == sdHcalFwd){  
     fHFEnergySimHits[cellid] += simhits->energy(); 
       }    
     } 
   }
 
   // get HBHE information
   edm::Handle<edm::SortedCollection<HBHEDataFrame> > hbhe;
   iEvent.getByToken(HBHEDigi_Token_,hbhe);
   bool validHBHE = true;
   if (!hbhe.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find HBHEDataFrame in event!";
     validHBHE = false;
   }    
 
   if (validHBHE) {
     edm::SortedCollection<HBHEDataFrame>::const_iterator ihbhe;
     
     int iHB = 0;
     int iHE = 0; 
     for (ihbhe = hbhe->begin(); ihbhe != hbhe->end(); ++ihbhe) {
       HcalDetId cell(ihbhe->id()); 
       
       if ((cell.subdet() == sdHcalBrl) || (cell.subdet() == sdHcalEC)) {
     
     //HCalconditions->makeHcalCalibration(cell, &calibrations);
     const HcalCalibrations& calibrations = 
       HCalconditions->getHcalCalibrations(cell);
     const HcalQIECoder *channelCoder = HCalconditions->getHcalCoder(cell);
     const HcalQIEShape *shape = HCalconditions->getHcalShape(channelCoder);
     HcalCoderDb coder(*channelCoder, *shape);
     coder.adc2fC(*ihbhe, tool);
     
     // get HB info
     if (cell.subdet() == sdHcalBrl) {
       
       ++iHB;
       float fDigiSum = 0.0;
       for  (int ii = 0; ii < tool.size(); ++ii) {
         // default ped is 4.5
         int capid = (*ihbhe)[ii].capid();
         fDigiSum += (tool[ii] - calibrations.pedestal(capid));
       }
       
       mehHcalSHE[0]->Fill(fHFEnergySimHits[cell.rawId()]);
       mehHcalAEE[0]->Fill(fDigiSum);
       //Adding protection against FPE
       if (fHFEnergySimHits[cell.rawId()]!=0){
         mehHcalAEESHE[0]->Fill(fDigiSum/fHFEnergySimHits[cell.rawId()]);
       }
       //else {
       //  std::cout<<"It would have been an FPE! with fHFEnergySimHits[cell.rawId()]==0!\n";
       //}
       mehHcalSHEvAEE[0]->Fill(fDigiSum, fHFEnergySimHits[cell.rawId()]);
     }
     
     // get HE info
     if (cell.subdet() == sdHcalEC) {
       
       ++iHE;
       float fDigiSum = 0.0;
       for  (int ii = 0; ii < tool.size(); ++ii) {
         int capid = (*ihbhe)[ii].capid();
         fDigiSum += (tool[ii]-calibrations.pedestal(capid));
       }
       
       mehHcalSHE[1]->Fill(fHFEnergySimHits[cell.rawId()]);
       mehHcalAEE[1]->Fill(fDigiSum);
       //Adding protection against FPE
       if (fHFEnergySimHits[cell.rawId()]!=0){
         mehHcalAEESHE[1]->Fill(fDigiSum/fHFEnergySimHits[cell.rawId()]);
       }
       //else{
       //  std::cout<<"It would have been an FPE! with fHFEnergySimHits[cell.rawId()]==0!\n";
       //}
       mehHcalSHEvAEE[1]->Fill(fDigiSum, fHFEnergySimHits[cell.rawId()]);
     }
       }
     }
   
     if (verbosity > 1) {
       eventout += "\n          Number of HBDigis collected:.............. ";
       eventout += iHB;
     }
     mehHcaln[0]->Fill((float)iHB);
     
     if (verbosity > 1) {
       eventout += "\n          Number of HEDigis collected:.............. ";
       eventout += iHE;
     }
     mehHcaln[1]->Fill((float)iHE);
   }
 
   // get HO information
   edm::Handle<edm::SortedCollection<HODataFrame> > ho;
   iEvent.getByToken(HODigi_Token_,ho);
   bool validHO = true;
   if (!ho.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find HODataFrame in event!";
     validHO = false;
   }    
   if (validHO) {
     edm::SortedCollection<HODataFrame>::const_iterator iho;
     
     int iHO = 0; 
     for (iho = ho->begin(); iho != ho->end(); ++iho) {
       HcalDetId cell(iho->id()); 
       
       if (cell.subdet() == sdHcalOut) {
     
     //HCalconditions->makeHcalCalibration(cell, &calibrations);
     const HcalCalibrations& calibrations = 
       HCalconditions->getHcalCalibrations(cell);
     const HcalQIECoder *channelCoder = HCalconditions->getHcalCoder(cell);
     const HcalQIEShape *shape = HCalconditions->getHcalShape(channelCoder);
     HcalCoderDb coder (*channelCoder, *shape);
     coder.adc2fC(*iho, tool);
     
     ++iHO;
     float fDigiSum = 0.0;
     for  (int ii = 0; ii < tool.size(); ++ii) {
       // default ped is 4.5
       int capid = (*iho)[ii].capid();
       fDigiSum += (tool[ii] - calibrations.pedestal(capid));
     }
     
     mehHcalSHE[2]->Fill(fHFEnergySimHits[cell.rawId()]);
     mehHcalAEE[2]->Fill(fDigiSum);
     //Adding protection against FPE
     if (fHFEnergySimHits[cell.rawId()]!=0){
       mehHcalAEESHE[2]->Fill(fDigiSum/fHFEnergySimHits[cell.rawId()]);
     }
     //else{
     //  std::cout<<"It would have been an FPE! with fHFEnergySimHits[cell.rawId()]==0!\n";
     //}
     mehHcalSHEvAEE[2]->Fill(fDigiSum, fHFEnergySimHits[cell.rawId()]);
       }
     }
     
     if (verbosity > 1) {
       eventout += "\n          Number of HODigis collected:.............. ";
       eventout += iHO;
     }
     mehHcaln[2]->Fill((float)iHO);
   }  
 
   // get HF information
   edm::Handle<edm::SortedCollection<HFDataFrame> > hf;
   iEvent.getByToken(HFDigi_Token_,hf);
   bool validHF = true;
   if (!hf.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find HFDataFrame in event!";
     validHF = false;
   }    
   if (validHF) {
     edm::SortedCollection<HFDataFrame>::const_iterator ihf;
     
     int iHF = 0; 
     for (ihf = hf->begin(); ihf != hf->end(); ++ihf) {
       HcalDetId cell(ihf->id()); 
       
       if (cell.subdet() == sdHcalFwd) {
     
     //HCalconditions->makeHcalCalibration(cell, &calibrations);
     const HcalCalibrations& calibrations = 
       HCalconditions->getHcalCalibrations(cell);
     const HcalQIECoder *channelCoder = HCalconditions->getHcalCoder(cell);
     const HcalQIEShape *shape = HCalconditions->getHcalShape(channelCoder);
     HcalCoderDb coder (*channelCoder, *shape);
     coder.adc2fC(*ihf, tool);
     
     ++iHF;
     float fDigiSum = 0.0;
     for  (int ii = 0; ii < tool.size(); ++ii) {
       // default ped is 1.73077
       int capid = (*ihf)[ii].capid();
       fDigiSum += (tool[ii] - calibrations.pedestal(capid));
     }
     
     mehHcalSHE[3]->Fill(fHFEnergySimHits[cell.rawId()]);
     mehHcalAEE[3]->Fill(fDigiSum);
     //Adding protection against FPE
     if (fHFEnergySimHits[cell.rawId()]!=0){
       mehHcalAEESHE[3]->Fill(fDigiSum/fHFEnergySimHits[cell.rawId()]);
     }
     //else{
     //  std::cout<<"It would have been an FPE! with fHFEnergySimHits[cell.rawId()]==0!\n";
     //}
     mehHcalSHEvAEE[3]->Fill(fDigiSum, fHFEnergySimHits[cell.rawId()]);
       }
     }
   
     if (verbosity > 1) {
       eventout += "\n          Number of HFDigis collected:.............. ";
       eventout += iHF;
     }
     mehHcaln[3]->Fill((float)iHF);
   }
 
   if (verbosity > 0)
     edm::LogInfo(MsgLoggerCat) << eventout << "\n";
   
   return;
 }

void GlobalDigisAnalyzer::fillMuon	(	const edm::Event &	iEvent,
		const edm::EventSetup &	iSetup
	)

private

Definition at line 1405 of file GlobalDigisAnalyzer.cc.

References RPCRoll::centreOfStrip(), MonitorElement::Fill(), HcalObjRepresent::Fill(), edm::EventSetup::get(), edm::Event::getByToken(), edm::ESHandleBase::isValid(), edm::HandleBase::isValid(), j, plotBeamSpotDB::last, LogDebug, mehCSCStripADC, mehCSCStripn, mehCSCWiren, mehCSCWireTime, mehDtMuonLayer, mehDtMuonn, mehDtMuonTime, mehDtMuonTimevLayer, mehRPCMuonn, mehRPCRes, MuCSCStripSrc_Token_, MuCSCWireSrc_Token_, MuDTSrc_Token_, MuRPCSrc_Token_, EcalCondDBWriter_cfi::pedestal, RPCDetId::region(), RPCDetId::ring(), RPCDetId, RPCSimHit_Token_, AlCaHLTBitMon_QueryRunRegistry::string, RecoTauPiZeroBuilderPlugins_cfi::strips, theCSCStripPedestalCount, theCSCStripPedestalSum, verbosity, and x.

Referenced by analyze().

 {
   std::string MsgLoggerCat = "GlobalDigisAnalyzer_fillMuon";
   
   TString eventout;
   if (verbosity > 0)
     eventout = "\nGathering info:";  
   
   // get DT information
   edm::Handle<DTDigiCollection> dtDigis;  
   iEvent.getByToken(MuDTSrc_Token_, dtDigis);
   bool validdtDigis = true;
   if (!dtDigis.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find dtDigis in event!";
     validdtDigis = false;
   }  
   if (validdtDigis) {
     int nDt0 = 0; int nDt1 = 0; int nDt2 = 0; int nDt3 = 0;
     int nDt = 0;
     DTDigiCollection::DigiRangeIterator detUnitIt;
     for (detUnitIt = dtDigis->begin(); detUnitIt != dtDigis->end(); 
      ++detUnitIt) {
       
       const DTLayerId& id = (*detUnitIt).first;
       const DTDigiCollection::Range& range = (*detUnitIt).second;
       for (DTDigiCollection::const_iterator digiIt = range.first;
        digiIt != range.second;
        ++digiIt) {
     
     ++nDt;
     
     DTWireId wireId(id,(*digiIt).wire());
     if (wireId.station() == 1) {
       mehDtMuonLayer[0]->Fill(id.layer());
       mehDtMuonTime[0]->Fill((*digiIt).time());
       mehDtMuonTimevLayer[0]->Fill(id.layer(),(*digiIt).time());
       ++nDt0;
     }
     if (wireId.station() == 2) {
       mehDtMuonLayer[1]->Fill(id.layer());
       mehDtMuonTime[1]->Fill((*digiIt).time());
       mehDtMuonTimevLayer[1]->Fill(id.layer(),(*digiIt).time());
       ++nDt1;
     }
     if (wireId.station() == 3) {
       mehDtMuonLayer[2]->Fill(id.layer());
       mehDtMuonTime[2]->Fill((*digiIt).time());
       mehDtMuonTimevLayer[2]->Fill(id.layer(),(*digiIt).time());
       ++nDt2;
     }
     if (wireId.station() == 4) {
       mehDtMuonLayer[3]->Fill(id.layer());
       mehDtMuonTime[3]->Fill((*digiIt).time());
       mehDtMuonTimevLayer[3]->Fill(id.layer(),(*digiIt).time());
       ++nDt3;
     }
       }
     }
     mehDtMuonn[0]->Fill((float)nDt0);
     mehDtMuonn[1]->Fill((float)nDt1);
     mehDtMuonn[2]->Fill((float)nDt2);
     mehDtMuonn[3]->Fill((float)nDt3);
     
     
     if (verbosity > 1) {
       eventout += "\n          Number of DtMuonDigis collected:.......... ";
       eventout += nDt;
     }
   }
 
   // get CSC Strip information
   edm::Handle<CSCStripDigiCollection> strips;  
   iEvent.getByToken(MuCSCStripSrc_Token_, strips);
   bool validstrips = true;
   if (!strips.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find muon strips in event!";
     validstrips = false;
   }
   
   if (validstrips) {
     int nStrips = 0;
     for (CSCStripDigiCollection::DigiRangeIterator j = strips->begin();
      j != strips->end();
      ++j) {
       
       std::vector<CSCStripDigi>::const_iterator digiItr = (*j).second.first;
       std::vector<CSCStripDigi>::const_iterator last = (*j).second.second;
       
       for ( ; digiItr != last; ++digiItr) {
     ++nStrips;
     
     // average pedestals
     std::vector<int> adcCounts = digiItr->getADCCounts();
     theCSCStripPedestalSum += adcCounts[0];
     theCSCStripPedestalSum += adcCounts[1];
     theCSCStripPedestalCount += 2;
     
     // if there are enough pedestal statistics
     if (theCSCStripPedestalCount > 100) {
       float pedestal = theCSCStripPedestalSum / theCSCStripPedestalCount;
       if (adcCounts[5] > (pedestal + 100)) 
         mehCSCStripADC->Fill(adcCounts[4] - pedestal);
     }
       }
     }
     
     if (verbosity > 1) {
       eventout += "\n          Number of CSCStripDigis collected:........ ";
       eventout += nStrips;
     }
     mehCSCStripn->Fill((float)nStrips);
   }
 
   // get CSC Wire information
   edm::Handle<CSCWireDigiCollection> wires;  
   iEvent.getByToken(MuCSCWireSrc_Token_, wires);
   bool validwires = true;
   if (!wires.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find muon wires in event!";
     validwires = false;
   }  
   
   if (validwires) {
     int nWires = 0;
     for (CSCWireDigiCollection::DigiRangeIterator j = wires->begin();
      j != wires->end();
      ++j) {
       
       std::vector<CSCWireDigi>::const_iterator digiItr = (*j).second.first;
       std::vector<CSCWireDigi>::const_iterator endDigi = (*j).second.second;
       
       for ( ; digiItr != endDigi; ++digiItr) {
     ++nWires;
     mehCSCWireTime->Fill(digiItr->getTimeBin());
       }
     }
     
     if (verbosity > 1) {
       eventout += "\n          Number of CSCWireDigis collected:......... ";
       eventout += nWires;
     }
     mehCSCWiren->Fill((float)nWires); 
   }
 
   // get RPC information
   // Get the RPC Geometry
   edm::ESHandle<RPCGeometry> rpcGeom;
   iSetup.get<MuonGeometryRecord>().get(rpcGeom);
   if (!rpcGeom.isValid()) {
     edm::LogWarning(MsgLoggerCat)
       << "Unable to find RPCGeometryRecord in event!";
     return;
   }
   
   edm::Handle<edm::PSimHitContainer> rpcsimHit;
   iEvent.getByToken(RPCSimHit_Token_, rpcsimHit);
   bool validrpcsim = true;
   if (!rpcsimHit.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find rpcsimHit in event!";
     validrpcsim = false;
   }   
   
   edm::Handle<RPCDigiCollection> rpcDigis;  
   iEvent.getByToken(MuRPCSrc_Token_, rpcDigis);
   bool validrpcdigi = true;
   if (!rpcDigis.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find rpcDigis in event!";
     validrpcdigi = false;
   } 
 
   // ONLY UNTIL PROBLEM WITH RPC DIGIS IS FIGURED OUT
   validrpcdigi = false;
 
   // Loop on simhits
   edm::PSimHitContainer::const_iterator rpcsimIt;
   std::map<RPCDetId, std::vector<double> > allsims;
 
   if (validrpcsim) {
     for (rpcsimIt = rpcsimHit->begin(); rpcsimIt != rpcsimHit->end(); 
      rpcsimIt++) {
       RPCDetId Rsid = (RPCDetId)(*rpcsimIt).detUnitId();
       int ptype = rpcsimIt->particleType();
       
       if (ptype == 13 || ptype == -13) {
     std::vector<double> buff;
     if (allsims.find(Rsid) != allsims.end() ){
       buff= allsims[Rsid];
     }
     buff.push_back(rpcsimIt->localPosition().x());
     allsims[Rsid]=buff;
       }
     }
   }
 
   // CRASH HAPPENS SOMEWHERE HERE IN FOR DECLARATION
   // WHAT IS WRONG WITH rpcDigis?????
   if (validrpcdigi) {
     int nRPC = 0;
     RPCDigiCollection::DigiRangeIterator rpcdetUnitIt;
     for (rpcdetUnitIt = rpcDigis->begin(); rpcdetUnitIt != rpcDigis->end(); 
      ++rpcdetUnitIt) {
       
       const RPCDetId Rsid = (*rpcdetUnitIt).first;      
       const RPCRoll* roll = 
     dynamic_cast<const RPCRoll* >( rpcGeom->roll(Rsid));   
       const RPCDigiCollection::Range& range = (*rpcdetUnitIt).second;
       
       std::vector<double> sims;
       if (allsims.find(Rsid) != allsims.end() ){
     sims = allsims[Rsid];
       }
       
       int ndigi = 0;
       for (RPCDigiCollection::const_iterator rpcdigiIt = range.first;
        rpcdigiIt != range.second;
        ++rpcdigiIt) {
     
     ++ndigi;
     ++nRPC;
       }
       
       if (sims.size() == 1 && ndigi == 1){
     double dis = roll->centreOfStrip(range.first->strip()).x()-sims[0];
     
     if (Rsid.region() == 0 ){
       if (Rsid.ring() == -2)
         mehRPCRes[0]->Fill((float)dis);
       else if (Rsid.ring() == -1)
         mehRPCRes[1]->Fill((float)dis);
       else if (Rsid.ring() == 0)
         mehRPCRes[2]->Fill((float)dis);
       else if (Rsid.ring() == 1)
         mehRPCRes[3]->Fill((float)dis);
       else if (Rsid.ring() == 2)
         mehRPCRes[4]->Fill((float)dis);
     }  
       }
     }
     
     if (verbosity > 1) {
       eventout += "\n          Number of RPCDigis collected:.............. ";
       eventout += nRPC;
     }
     mehRPCMuonn->Fill(float(nRPC));
   }
   
   if (verbosity > 0)
     edm::LogInfo(MsgLoggerCat) << eventout << "\n";
   
   return;
 }

void GlobalDigisAnalyzer::fillTrk	(	const edm::Event &	iEvent,
		const edm::EventSetup &	iSetup
	)

private

Definition at line 1142 of file GlobalDigisAnalyzer.cc.

References begin, edm::DetSetVector< T >::begin(), end, edm::DetSetVector< T >::end(), MonitorElement::Fill(), edm::EventSetup::get(), edm::Event::getByToken(), i, edm::HandleBase::isValid(), LogDebug, mehSiPixelADC, mehSiPixelCol, mehSiPixeln, mehSiPixelRow, mehSiStripADC, mehSiStripn, mehSiStripStrip, edm::ESHandle< class >::product(), TrackerTopology::pxbLayer(), TrackerTopology::pxfDisk(), TrackerTopology::pxfSide(), sdPxlBrl, sdPxlFwd, sdSiTEC, sdSiTIB, sdSiTID, sdSiTOB, SiPxlSrc_Token_, SiStripSrc_Token_, AlCaHLTBitMon_QueryRunRegistry::string, DetId::subdetId(), TrackerTopology::tecWheel(), TrackerTopology::tibLayer(), TrackerTopology::tidWheel(), TrackerTopology::tobLayer(), and verbosity.

Referenced by analyze().

 {
   //Retrieve tracker topology from geometry
   edm::ESHandle<TrackerTopology> tTopoHandle;
   iSetup.get<TrackerTopologyRcd>().get(tTopoHandle);
   const TrackerTopology* const tTopo = tTopoHandle.product();
 
 
   std::string MsgLoggerCat = "GlobalDigisAnalyzer_fillTrk";
   
   TString eventout;
   if (verbosity > 0)
     eventout = "\nGathering info:";  
   
   // get strip information
   edm::Handle<edm::DetSetVector<SiStripDigi> > stripDigis;  
   iEvent.getByToken(SiStripSrc_Token_, stripDigis);
   bool validstripDigis = true;
   if (!stripDigis.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find stripDigis in event!";
     validstripDigis = false;
   }  
   
   if (validstripDigis) {
     int nStripBrl = 0, nStripFwd = 0;
     edm::DetSetVector<SiStripDigi>::const_iterator DSViter;
     for (DSViter = stripDigis->begin(); DSViter != stripDigis->end(); 
      ++DSViter) {
       unsigned int id = DSViter->id;
       DetId detId(id);
       edm::DetSet<SiStripDigi>::const_iterator begin = DSViter->data.begin();
       edm::DetSet<SiStripDigi>::const_iterator end = DSViter->data.end();
       edm::DetSet<SiStripDigi>::const_iterator iter;
       
       // get TIB
       if (detId.subdetId() == sdSiTIB) {
     
     for (iter = begin; iter != end; ++iter) {
       ++nStripBrl;
       if (tTopo->tibLayer(id) == 1) {
         mehSiStripADC[0]->Fill((*iter).adc());
         mehSiStripStrip[0]->Fill((*iter).strip());
       }
       if (tTopo->tibLayer(id) == 2) {
         mehSiStripADC[1]->Fill((*iter).adc());
         mehSiStripStrip[1]->Fill((*iter).strip());
       } 
       if (tTopo->tibLayer(id) == 3) {
         mehSiStripADC[2]->Fill((*iter).adc());
         mehSiStripStrip[2]->Fill((*iter).strip());
       }
       if (tTopo->tibLayer(id) == 4) {
         mehSiStripADC[3]->Fill((*iter).adc());
         mehSiStripStrip[3]->Fill((*iter).strip());
       }
     }
       }
       
       // get TOB
       if (detId.subdetId() == sdSiTOB) {
     
     for (iter = begin; iter != end; ++iter) {
       ++nStripBrl;
       if (tTopo->tobLayer(id) == 1) {
         mehSiStripADC[4]->Fill((*iter).adc());
         mehSiStripStrip[4]->Fill((*iter).strip());
       }
       if (tTopo->tobLayer(id) == 2) {
         mehSiStripADC[5]->Fill((*iter).adc());
         mehSiStripStrip[5]->Fill((*iter).strip());
       } 
       if (tTopo->tobLayer(id) == 3) {
         mehSiStripADC[6]->Fill((*iter).adc());
         mehSiStripStrip[6]->Fill((*iter).strip());
       }
       if (tTopo->tobLayer(id) == 4) {
         mehSiStripADC[7]->Fill((*iter).adc());
         mehSiStripStrip[7]->Fill((*iter).strip());
       }
     }
       }    
       
       // get TID
       if (detId.subdetId() == sdSiTID) {
     
     for (iter = begin; iter != end; ++iter) {
       ++nStripFwd;
       if (tTopo->tidWheel(id) == 1) {
         mehSiStripADC[8]->Fill((*iter).adc());
         mehSiStripStrip[8]->Fill((*iter).strip());
       }
       if (tTopo->tidWheel(id) == 2) {
         mehSiStripADC[9]->Fill((*iter).adc());
         mehSiStripStrip[9]->Fill((*iter).strip());
       }
       if (tTopo->tidWheel(id) == 3) {
         mehSiStripADC[10]->Fill((*iter).adc());
         mehSiStripStrip[10]->Fill((*iter).strip());
       }
     }
       }   
       
       // get TEC
       if (detId.subdetId() == sdSiTEC) {
     
     for (iter = begin; iter != end; ++iter) {
       ++nStripFwd;
       if (tTopo->tecWheel(id) == 1) {
         mehSiStripADC[11]->Fill((*iter).adc());
         mehSiStripStrip[11]->Fill((*iter).strip());
       }
       if (tTopo->tecWheel(id) == 2) {
         mehSiStripADC[12]->Fill((*iter).adc());
         mehSiStripStrip[12]->Fill((*iter).strip());
       }
       if (tTopo->tecWheel(id) == 3) {
         mehSiStripADC[13]->Fill((*iter).adc());
         mehSiStripStrip[13]->Fill((*iter).strip());
       }
       if (tTopo->tecWheel(id) == 4) {
         mehSiStripADC[14]->Fill((*iter).adc());
         mehSiStripStrip[14]->Fill((*iter).strip());
       }
       if (tTopo->tecWheel(id) == 5) {
         mehSiStripADC[15]->Fill((*iter).adc());
         mehSiStripStrip[15]->Fill((*iter).strip());
       }
       if (tTopo->tecWheel(id) == 6) {
         mehSiStripADC[16]->Fill((*iter).adc());
         mehSiStripStrip[16]->Fill((*iter).strip());
       }
       if (tTopo->tecWheel(id) == 7) {
         mehSiStripADC[17]->Fill((*iter).adc());
         mehSiStripStrip[17]->Fill((*iter).strip());
       }
       if (tTopo->tecWheel(id) == 8) {
         mehSiStripADC[18]->Fill((*iter).adc());
         mehSiStripStrip[18]->Fill((*iter).strip());
       }
     }
       }     
     } // end loop over DataSetVector
     
     if (verbosity > 1) {
       eventout += "\n          Number of BrlStripDigis collected:........ ";
       eventout += nStripBrl;
     }
     for(int i = 0; i < 8; ++i) {
       mehSiStripn[i]->Fill((float)nStripBrl);
     }
     
     if (verbosity > 1) {
       eventout += "\n          Number of FrwdStripDigis collected:....... ";
       eventout += nStripFwd;
     }
     for(int i = 8; i < 19; ++i) {
       mehSiStripn[i]->Fill((float)nStripFwd);
     }
   }
 
   // get pixel information
   edm::Handle<edm::DetSetVector<PixelDigi> > pixelDigis;  
   iEvent.getByToken(SiPxlSrc_Token_, pixelDigis);
   bool validpixelDigis = true;
   if (!pixelDigis.isValid()) {
     LogDebug(MsgLoggerCat)
       << "Unable to find pixelDigis in event!";
     validpixelDigis = false;
   }  
   if (validpixelDigis) {
     int nPxlBrl = 0, nPxlFwd = 0;
     edm::DetSetVector<PixelDigi>::const_iterator DPViter;
     for (DPViter = pixelDigis->begin(); DPViter != pixelDigis->end(); 
      ++DPViter) {
       unsigned int id = DPViter->id;
       DetId detId(id);
       edm::DetSet<PixelDigi>::const_iterator begin = DPViter->data.begin();
       edm::DetSet<PixelDigi>::const_iterator end = DPViter->data.end();
       edm::DetSet<PixelDigi>::const_iterator iter;
       
       // get Barrel pixels
       if (detId.subdetId() == sdPxlBrl) {
     
     for (iter = begin; iter != end; ++iter) {
       ++nPxlBrl;
       if (tTopo->pxbLayer(id) == 1) {
         mehSiPixelADC[0]->Fill((*iter).adc());
         mehSiPixelRow[0]->Fill((*iter).row());
         mehSiPixelCol[0]->Fill((*iter).column());
       }
       if (tTopo->pxbLayer(id) == 2) {
         mehSiPixelADC[1]->Fill((*iter).adc());
         mehSiPixelRow[1]->Fill((*iter).row());
         mehSiPixelCol[1]->Fill((*iter).column());
       }
       if (tTopo->pxbLayer(id) == 3) {
         mehSiPixelADC[2]->Fill((*iter).adc());
         mehSiPixelRow[2]->Fill((*iter).row());
         mehSiPixelCol[2]->Fill((*iter).column());
       }
     }
       }
       
       // get Forward pixels
       if (detId.subdetId() == sdPxlFwd) {
     
     for (iter = begin; iter != end; ++iter) {
       ++nPxlFwd;
       if (tTopo->pxfDisk(id) == 1) {
         if (tTopo->pxfSide(id) == 1) {
           mehSiPixelADC[4]->Fill((*iter).adc());
           mehSiPixelRow[4]->Fill((*iter).row());
           mehSiPixelCol[4]->Fill((*iter).column());
         }
         if (tTopo->pxfSide(id) == 2) {
           mehSiPixelADC[3]->Fill((*iter).adc());
           mehSiPixelRow[3]->Fill((*iter).row());
           mehSiPixelCol[3]->Fill((*iter).column());
         }
       }
       if (tTopo->pxfDisk(id) == 2) {
         if (tTopo->pxfSide(id) == 1) {
           
           mehSiPixelADC[6]->Fill((*iter).adc());
           mehSiPixelRow[6]->Fill((*iter).row());
           mehSiPixelCol[6]->Fill((*iter).column());
         }
         if (tTopo->pxfSide(id) == 2) {
           mehSiPixelADC[5]->Fill((*iter).adc());
           mehSiPixelRow[5]->Fill((*iter).row());
           mehSiPixelCol[5]->Fill((*iter).column());
         }
       }
     }
       }
     }
     
     if (verbosity > 1) {
       eventout += "\n          Number of BrlPixelDigis collected:........ ";
       eventout += nPxlBrl;
     }
     for(int i = 0; i < 3; ++i) {
       mehSiPixeln[i]->Fill((float)nPxlBrl);
     }
     
     if (verbosity > 1) {
       eventout += "\n          Number of FrwdPixelDigis collected:....... ";
       eventout += nPxlFwd;
     }
     
     for(int i = 3; i < 7; ++i) {
       mehSiPixeln[i]->Fill((float)nPxlFwd);
     }
   }
 
   if (verbosity > 0)
     edm::LogInfo(MsgLoggerCat) << eventout << "\n";
   
   return;
 }