ZeeCalibration Class Reference

#include <Calibration/EcalCalibAlgos/src/ZeeCalibration.cc>

Inheritance diagram for ZeeCalibration:

Public Member Functions
void	beginOfJob () override
	Called at beginning of job. More...
Status	duringLoop (const edm::Event &, const edm::EventSetup &) override
	Called at each event. More...
void	endOfJob () override
	Called at end of job. More...
Status	endOfLoop (const edm::EventSetup &, unsigned int iLoop) override
	Called at end of loop. More...
virtual void	produce (edm::Event &, const edm::EventSetup &)
	Dummy implementation (job done in duringLoop) More...
virtual std::shared_ptr< EcalIntercalibConstants >	produceEcalIntercalibConstants (const EcalIntercalibConstantsRcd &iRecord)
	Produce Ecal interCalibrations. More...
void	startingNewLoop (unsigned int iLoop) override
	Called at beginning of loop. More...
	ZeeCalibration (const edm::ParameterSet &iConfig)
	Constructor. More...
	~ZeeCalibration () override
	Destructor. More...
Public Member Functions inherited from edm::ESProducerLooper
	ESProducerLooper ()
std::set< eventsetup::EventSetupRecordKey >	modifyingRecords () const override
Public Member Functions inherited from edm::ESProducer
	ESProducer ()
	ESProducer (const ESProducer &)=delete
ESProxyIndex const *	getTokenIndices (unsigned int iIndex) const
ESRecordIndex const *	getTokenRecordIndices (unsigned int iIndex) const
bool	hasMayConsumes () const noexcept
size_t	numberOfTokenIndices (unsigned int iIndex) const
ESProducer const &	operator= (const ESProducer &)=delete
SerialTaskQueueChain &	queue ()
template<typename Record >
std::optional< std::vector< ESProxyIndex > >	updateFromMayConsumes (unsigned int iIndex, const Record &iRecord) const
void	updateLookup (eventsetup::ESRecordsToProxyIndices const &) final
	~ESProducer () noexcept(false) override
Public Member Functions inherited from edm::ESProxyFactoryProducer
	ESProxyFactoryProducer ()
	ESProxyFactoryProducer (const ESProxyFactoryProducer &)=delete
const ESProxyFactoryProducer &	operator= (const ESProxyFactoryProducer &)=delete
	~ESProxyFactoryProducer () noexcept(false) override
Public Member Functions inherited from edm::eventsetup::DataProxyProvider
void	createKeyedProxies (EventSetupRecordKey const &key, unsigned int nConcurrentIOVs)
	DataProxyProvider ()
	DataProxyProvider (const DataProxyProvider &)=delete
const ComponentDescription &	description () const
void	fillRecordsNotAllowingConcurrentIOVs (std::set< EventSetupRecordKey > &recordsNotAllowingConcurrentIOVs) const
virtual void	initConcurrentIOVs (EventSetupRecordKey const &key, unsigned int nConcurrentIOVs)
bool	isUsingRecord (const EventSetupRecordKey &key) const
KeyedProxies &	keyedProxies (const EventSetupRecordKey &iRecordKey, unsigned int iovIndex=0)
const DataProxyProvider &	operator= (const DataProxyProvider &)=delete
void	setAppendToDataLabel (const edm::ParameterSet &)
void	setDescription (const ComponentDescription &iDescription)
std::set< EventSetupRecordKey >	usingRecords () const
virtual	~DataProxyProvider () noexcept(false)
Public Member Functions inherited from edm::EventSetupRecordIntervalFinder
bool	concurrentFinder () const
const eventsetup::ComponentDescription &	descriptionForFinder () const
	EventSetupRecordIntervalFinder ()
	EventSetupRecordIntervalFinder (const EventSetupRecordIntervalFinder &)=delete
std::set< eventsetup::EventSetupRecordKey >	findingForRecords () const
const ValidityInterval &	findIntervalFor (const eventsetup::EventSetupRecordKey &, const IOVSyncValue &)
bool	nonconcurrentAndIOVNeedsUpdate (const eventsetup::EventSetupRecordKey &key, const IOVSyncValue &syncValue) const
const EventSetupRecordIntervalFinder &	operator= (const EventSetupRecordIntervalFinder &)=delete
void	resetInterval (const eventsetup::EventSetupRecordKey &)
void	setDescriptionForFinder (const eventsetup::ComponentDescription &iDescription)
virtual	~EventSetupRecordIntervalFinder () noexcept(false)
Public Member Functions inherited from edm::EDLooper
	EDLooper ()
	EDLooper (EDLooper const &)=delete
EDLooper &	operator= (EDLooper const &)=delete
	~EDLooper () override
Public Member Functions inherited from edm::EDLooperBase
virtual void	attachTo (ActivityRegistry &)
	Override this method if you need to monitor the state of the processing. More...
virtual void	beginOfJob (EventSetup const &)
void	beginOfJob (EventSetupImpl const &)
void	copyInfo (ScheduleInfo const &)
void	doBeginLuminosityBlock (LuminosityBlockPrincipal &, EventSetupImpl const &, ProcessContext *)
void	doBeginRun (RunPrincipal &, EventSetupImpl const &, ProcessContext *)
Status	doDuringLoop (EventPrincipal &eventPrincipal, EventSetupImpl const &es, ProcessingController &, StreamContext *)
void	doEndLuminosityBlock (LuminosityBlockPrincipal &, EventSetupImpl const &, ProcessContext *)
Status	doEndOfLoop (EventSetupImpl const &es)
void	doEndRun (RunPrincipal &, EventSetupImpl const &, ProcessContext *)
void	doStartingNewLoop ()
	EDLooperBase ()
	EDLooperBase (EDLooperBase const &)=delete
EDLooperBase &	operator= (EDLooperBase const &)=delete
void	prepareForNextLoop (eventsetup::EventSetupProvider *esp)
void	setActionTable (ExceptionToActionTable const *actionTable)
void	setModuleChanger (ModuleChanger *)
virtual	~EDLooperBase () noexcept(false)

Private Member Functions
void	bookHistograms ()
float	computeCoefficientDistanceAtIteration (float v1[250], float v2[250], int size)
float	EvalDPhi (float Phi, float Phi_ref)
float	EvalDR (float Eta, float Eta_ref, float Phi, float Phi_ref)
double	fEtaBarrelBad (double scEta) const
double	fEtaBarrelGood (double scEta) const
double	fEtaEndcapBad (double scEta) const
double	fEtaEndcapGood (double scEta) const
void	fillEleInfo (std::vector< HepMC::GenParticle * > &a, std::map< HepMC::GenParticle *, const reco::GsfElectron * > &b)
void	fillMCInfo (HepMC::GenParticle *mcele)
void	fillMCmap (const std::vector< const reco::GsfElectron * > *electronCollection, const std::vector< HepMC::GenParticle * > &mcEle, std::map< HepMC::GenParticle *, const reco::GsfElectron * > &myMCmap)
double	getEtaCorrection (const reco::GsfElectron *)
std::pair< DetId, double >	getHottestDetId (const std::vector< std::pair< DetId, float > > &mySCRecHits, const EBRecHitCollection *ebhits, const EERecHitCollection *eehits)
void	printStatistics ()
void	resetHistograms ()
void	resetVariables ()
int	ringNumberCorrector (int k)
bool	xtalIsOnModuleBorder (EBDetId myEBDetId)

Private Attributes
char	aHLTNames [6000]
bool	aHLTResults [200]
TString	aNames [200]
char	aTriggerNames [200][30]
bool	aTriggerResults [200]
int	BARREL_ELECTRONS_AFTER_BORDER_CUT
int	BARREL_ELECTRONS_BEFORE_BORDER_CUT
std::string	barrelfile_
Int_t	BBZN
Int_t	BBZN_gg
Int_t	BBZN_t0
Int_t	BBZN_tt
float	calibCoeff [250]
float	calibCoeffError [250]
std::string	calibMode_
double	coefficientDistanceAtIteration [50]
int	CRACK_ELECTRONS_IN_BARREL
int	CRACK_ELECTRONS_IN_ENDCAP
Int_t	EBZN
Int_t	EBZN_gg
Int_t	EBZN_t0
Int_t	EBZN_tt
Int_t	EEZN
Int_t	EEZN_gg
Int_t	EEZN_t0
Int_t	EEZN_tt
std::string	electronCollection_
std::string	electronProducer_
unsigned int	electronSelection_
std::string	endcapfile_
std::string	erechitCollection_
std::string	erechitProducer_
unsigned int	etaBins_
double	etaMax_
double	etaMin_
unsigned int	etBins_
double	etMax_
double	etMin_
int	GOLDEN_ELECTRONS_IN_BARREL
int	GOLDEN_ELECTRONS_IN_ENDCAP
TH1F *	h1_borderElectronClassification_
TH1F *	h1_eleClasses_
TH1F *	h1_electronCosTheta_SC_
TH1F *	h1_electronCosTheta_SC_TK_
TH1F *	h1_electronCosTheta_TK_
TH1F *	h1_eleERecoOverEtrue_
TH1F *	h1_eleEtaResol_
TH1F *	h1_elePhiResol_
TH1F *	h1_eventsAfterBorderSelection_
TH1F *	h1_eventsAfterEWKSelection_
TH1F *	h1_eventsBeforeBorderSelection_
TH1F *	h1_eventsBeforeEWKSelection_
TH1F *	h1_mc_
TH1F *	h1_mcEB_
TH1F *	h1_mcEBParz_ [25]
TH1F *	h1_mcEE_
TH1F *	h1_mcEEParz_ [25]
TH1F *	h1_mcParz_ [25]
TH1F *	h1_nEleReco_
TH1F *	h1_occupancy_
TH1F *	h1_occupancyBarrel_
TH1F *	h1_occupancyEndcap_
TH1F *	h1_occupancyVsEta_
TH1F *	h1_occupancyVsEtaCrack_
TH1F *	h1_occupancyVsEtaGold_
TH1F *	h1_occupancyVsEtaShower_
TH1F *	h1_occupancyVsEtaSilver_
TH1F *	h1_preshowerOverSC_
TH1F *	h1_reco_ZMass_
TH1F *	h1_reco_ZMassBad_
TH1F *	h1_reco_ZMassCorr_
TH1F *	h1_reco_ZMassCorrBB_
TH1F *	h1_reco_ZMassCorrEE_
TH1F *	h1_reco_ZMassGood_
TH1F *	h1_RMin_
TH1F *	h1_RMinZ_
TH1F *	h1_seedOverSC_
TH1F *	h1_weightSumMeanBarrel_
TH1F *	h1_weightSumMeanEndcap_
TH1F *	h1_ZCandMult_
TH1F *	h1_zEtaResol_
TH1F *	h1_zMassResol_
TH1F *	h1_zPhiResol_
TH2F *	h2_chi2_ [25]
TH2F *	h2_coeffVsEta_
TH2F *	h2_coeffVsEtaGrouped_
TH2F *	h2_coeffVsLoop_
TH2F *	h2_fEtaBarrelBad_
TH2F *	h2_fEtaBarrelGood_
TH2F *	h2_fEtaEndcapBad_
TH2F *	h2_fEtaEndcapGood_
TH2F *	h2_iterations_ [25]
TH2F *	h2_miscalRecal_
TH2F *	h2_miscalRecalEB_
TH2F *	h2_miscalRecalEE_
TH2F *	h2_residualSigma_
TH2F *	h2_xtalMiscalibCoeffBarrel_
TH2F *	h2_xtalMiscalibCoeffEndcapMinus_
TH2F *	h2_xtalMiscalibCoeffEndcapPlus_
TH2F *	h2_xtalRecalibCoeffBarrel_ [25]
TH2F *	h2_xtalRecalibCoeffEndcapMinus_ [25]
TH2F *	h2_xtalRecalibCoeffEndcapPlus_ [25]
TH2F *	h2_zMassDiffVsLoop_
TH2F *	h2_zMassVsLoop_
TH2F *	h2_zWidthVsLoop_
TH1F *	h_eleEffEta [2]
TH1F *	h_eleEffEta_ [2]
TH1F *	h_eleEffPhi [2]
TH1F *	h_eleEffPhi_ [2]
TH1F *	h_eleEffPt [2]
TH1F *	h_eleEffPt_ [2]
TH1F *	h_ESCcorrEtrue_ [25]
TH2F *	h_ESCcorrEtrueVsEta_ [25]
TH1F *	h_ESCEtrue_ [25]
TH2F *	h_ESCEtrueVsEta_ [25]
std::vector< unsigned int >	hlAccept_
std::vector< unsigned int >	hlErrors_
std::vector< std::string >	hlNames_
Int_t	hltCount
Int_t	hltNamesLen
edm::InputTag	hlTriggerResults_
std::vector< unsigned int >	hlWasRun_
std::shared_ptr< EcalIntercalibConstants >	ical
bool	init_
float	initCalibCoeff [250]
bool	isfirstcall_
double	loopArray [50]
int	loopFlag_
double	mass
float	mass4tree
float	massDiff4tree
double	maxInvMassCut_
std::string	mcProducer_
Int_t	MCZBB
Int_t	MCZEB
Int_t	MCZEE
double	minInvMassCut_
TTree *	myTree
ZeePlots *	myZeePlots_
ZeeRescaleFactorPlots *	myZeeRescaleFactorPlots_
unsigned int	nAccept_
unsigned int	nErrors_
unsigned int	nEvents_
Int_t	NEVT
float	NewCalibCoeff [250]
unsigned int	nWasRun_
TFile *	outputFile_
std::string	outputFileName_
int	read_events
std::string	RecalibBarrelHits_
std::string	rechitCollection_
std::string	rechitProducer_
std::string	scCollection_
std::string	scIslandCollection_
std::string	scIslandProducer_
std::string	scProducer_
int	SHOWER_ELECTRONS_IN_BARREL
int	SHOWER_ELECTRONS_IN_ENDCAP
double	sigmaArray [50]
double	sigmaErrorArray [50]
int	SILVER_ELECTRONS_IN_BARREL
int	SILVER_ELECTRONS_IN_ENDCAP
ZIterativeAlgorithmWithFit *	theAlgorithm_
unsigned int	theMaxLoops
edm::ParameterSet	theParameterSet
int	TOTAL_ELECTRONS_IN_BARREL
int	TOTAL_ELECTRONS_IN_ENDCAP
Int_t	triggerCount
bool	wantEtaCorrection_

Additional Inherited Members
Public Types inherited from edm::EDLooperBase
enum	Status { kContinue, kStop }
Static Public Member Functions inherited from edm::eventsetup::DataProxyProvider
static void	prevalidate (ConfigurationDescriptions &)
Protected Types inherited from edm::ESProxyFactoryProducer
using	EventSetupRecordKey = eventsetup::EventSetupRecordKey
Protected Types inherited from edm::eventsetup::DataProxyProvider
using	KeyedProxiesVector = std::vector< std::pair< DataKey, std::shared_ptr< DataProxy > >>
Protected Member Functions inherited from edm::ESProducerLooper
void	registerFactoryWithKey (const eventsetup::EventSetupRecordKey &iRecord, std::unique_ptr< eventsetup::ProxyFactoryBase > iFactory, const std::string &iLabel=std::string()) override
void	setIntervalFor (const eventsetup::EventSetupRecordKey &iKey, const IOVSyncValue &iTime, ValidityInterval &oInterval) override
Protected Member Functions inherited from edm::ESProducer
template<typename T >
auto	setWhatProduced (T *iThis, const char *iLabel)
template<typename T >
auto	setWhatProduced (T *iThis, const es::Label &iLabel={})
template<typename T >
auto	setWhatProduced (T *iThis, const std::string &iLabel)
template<typename T , typename TDecorator >
auto	setWhatProduced (T *iThis, const TDecorator &iDec, const es::Label &iLabel={})
template<typename T , typename TReturn , typename TRecord >
auto	setWhatProduced (T *iThis, TReturn(T ::*iMethod)(const TRecord &), const es::Label &iLabel={})
template<typename T , typename TReturn , typename TRecord , typename TArg >
ESConsumesCollectorT< TRecord >	setWhatProduced (T *iThis, TReturn(T ::*iMethod)(const TRecord &), const TArg &iDec, const es::Label &iLabel={})
void	usesResources (std::vector< std::string > const &)
Protected Member Functions inherited from edm::ESProxyFactoryProducer
template<class TFactory >
void	registerFactory (std::unique_ptr< TFactory > iFactory, const std::string &iLabel=std::string())
KeyedProxiesVector	registerProxies (const EventSetupRecordKey &, unsigned int iovIndex) override
Protected Member Functions inherited from edm::eventsetup::DataProxyProvider
template<class T >
void	usingRecord ()
void	usingRecordWithKey (const EventSetupRecordKey &key)
Protected Member Functions inherited from edm::EventSetupRecordIntervalFinder
template<class T >
void	findingRecord ()
void	findingRecordWithKey (const eventsetup::EventSetupRecordKey &)
Protected Member Functions inherited from edm::EDLooperBase
ModuleChanger *	moduleChanger ()
	This only returns a non-zero value during the call to endOfLoop. More...
ScheduleInfo const *	scheduleInfo () const
	This returns a non-zero value after the constructor has been called. More...

Detailed Description

Description: Perform single electron calibration (tested on TB data only).

Implementation: <Notes on="" implementation>="">

Definition at line 71 of file ZeeCalibration.h.

Constructor & Destructor Documentation

ZeeCalibration()

ZeeCalibration::ZeeCalibration

(

const edm::ParameterSet &

iConfig

)

Constructor.

Definition at line 67 of file ZeeCalibration.cc.

                                                             {
#ifdef DEBUG
  std::cout << "[ZeeCalibration] Starting the ctor" << std::endl;
#endif
 
  theMaxLoops = iConfig.getUntrackedParameter<unsigned int>("maxLoops", 0);
 
  wantEtaCorrection_ = iConfig.getUntrackedParameter<bool>("wantEtaCorrection", true);
 
  outputFileName_ = iConfig.getParameter<std::string>("outputFile");
 
  minInvMassCut_ = iConfig.getUntrackedParameter<double>("minInvMassCut", 70.);
  maxInvMassCut_ = iConfig.getUntrackedParameter<double>("maxInvMassCut", 110.);
 
  rechitProducer_ = iConfig.getParameter<std::string>("rechitProducer");
  rechitCollection_ = iConfig.getParameter<std::string>("rechitCollection");
 
  erechitProducer_ = iConfig.getParameter<std::string>("erechitProducer");
  erechitCollection_ = iConfig.getParameter<std::string>("erechitCollection");
 
  scProducer_ = iConfig.getParameter<std::string>("scProducer");
  scCollection_ = iConfig.getParameter<std::string>("scCollection");
 
  scIslandProducer_ = iConfig.getParameter<std::string>("scIslandProducer");
  scIslandCollection_ = iConfig.getParameter<std::string>("scIslandCollection");
 
  calibMode_ = iConfig.getUntrackedParameter<std::string>("ZCalib_CalibType");
 
  mcProducer_ = iConfig.getUntrackedParameter<std::string>("mcProducer", "");
 
  electronProducer_ = iConfig.getParameter<std::string>("electronProducer");
  electronCollection_ = iConfig.getParameter<std::string>("electronCollection");
 
  outputFile_ = TFile::Open(outputFileName_.c_str(), "RECREATE");  // open output file to store histograms
 
  myTree = new TTree("myTree", "myTree");
  //  myTree->Branch("zMass","zMass", &mass);
  myTree->Branch("zMass", &mass4tree, "mass/F");
  myTree->Branch("zMassDiff", &massDiff4tree, "massDiff/F");
 
  barrelfile_ = iConfig.getUntrackedParameter<std::string>("initialMiscalibrationBarrel", "");
  endcapfile_ = iConfig.getUntrackedParameter<std::string>("initialMiscalibrationEndcap", "");
 
  electronSelection_ =
      iConfig.getUntrackedParameter<unsigned int>("electronSelection", 0);  //option for electron selection
 
  etaBins_ = iConfig.getUntrackedParameter<unsigned int>("etaBins", 10);
  etBins_ = iConfig.getUntrackedParameter<unsigned int>("etBins", 10);
 
  etaMin_ = iConfig.getUntrackedParameter<double>("etaMin", 0.);
  etMin_ = iConfig.getUntrackedParameter<double>("etMin", 0.);
  etaMax_ = iConfig.getUntrackedParameter<double>("etaMax", 3.);
  etMax_ = iConfig.getUntrackedParameter<double>("etMax", 100.);
 
  //  new ZeePlots("zeePlots.root");
  //  ZeePlots->bookHistos();
 
  //ZeeCalibrationPLots("zeeCalibPlots");
  //ZeecaPlots->bookHistos(maxsIter);
 
  hlTriggerResults_ = iConfig.getParameter<edm::InputTag>("HLTriggerResults");
 
  theParameterSet = iConfig;
  EcalIndexingTools* myIndexTool = nullptr;
 
  myIndexTool = EcalIndexingTools::getInstance();
 
  myIndexTool->setBinRange(etaBins_, etaMin_, etaMax_, etBins_, etMin_, etMax_);
 
  //creating the algorithm
  theAlgorithm_ = new ZIterativeAlgorithmWithFit(iConfig);
 
  // Tell the framework what data is being produced
  //setWhatProduced(this);
  setWhatProduced(this, &ZeeCalibration::produceEcalIntercalibConstants);
  findingRecord<EcalIntercalibConstantsRcd>();
 
  for (int i = 0; i < 50; i++) {
    coefficientDistanceAtIteration[i] = -1.;
    loopArray[i] = -1.;
    sigmaArray[i] = -1.;
    sigmaErrorArray[i] = -1.;
  }
 
#ifdef DEBUG
  std::cout << "[ZeeCalibration] Done with the ctor" << std::endl;
#endif
}

References barrelfile_, calibMode_, coefficientDistanceAtIteration, gather_cfg::cout, electronCollection_, electronProducer_, electronSelection_, endcapfile_, erechitCollection_, erechitProducer_, etaBins_, etaMax_, etaMin_, etBins_, etMax_, etMin_, EcalIndexingTools::getInstance(), edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), hlTriggerResults_, mps_fire::i, loopArray, mass4tree, massDiff4tree, maxInvMassCut_, mcProducer_, minInvMassCut_, myTree, outputFile_, outputFileName_, produceEcalIntercalibConstants(), rechitCollection_, rechitProducer_, scCollection_, scIslandCollection_, scIslandProducer_, scProducer_, EcalIndexingTools::setBinRange(), edm::ESProducer::setWhatProduced(), sigmaArray, sigmaErrorArray, AlCaHLTBitMon_QueryRunRegistry::string, theAlgorithm_, theMaxLoops, theParameterSet, and wantEtaCorrection_.

~ZeeCalibration()

ZeeCalibration::~ZeeCalibration ( )

override

Destructor.

Definition at line 156 of file ZeeCalibration.cc.

                                {
  //   if (theAlgorithm_)
  //     delete theAlgorithm_;
}

Member Function Documentation

beginOfJob()

void ZeeCalibration::beginOfJob ( )

overridevirtual

Called at beginning of job.

Reimplemented from edm::EDLooperBase.

Definition at line 169 of file ZeeCalibration.cc.

{ isfirstcall_ = true; }

References isfirstcall_.

bookHistograms()

void ZeeCalibration::bookHistograms ( )

private

Definition at line 1496 of file ZeeCalibration.cc.

                                    {
  h1_eventsBeforeEWKSelection_ = new TH1F("h1_eventsBeforeEWKSelection", "h1_eventsBeforeEWKSelection", 5, 0, 5);
  h1_eventsAfterEWKSelection_ = new TH1F("h1_eventsAfterEWKSelection", "h1_eventsAfterEWKSelection", 5, 0, 5);
 
  h1_eventsBeforeBorderSelection_ =
      new TH1F("h1_eventsBeforeBorderSelection", "h1_eventsBeforeBorderSelection", 5, 0, 5);
  h1_eventsAfterBorderSelection_ = new TH1F("h1_eventsAfterBorderSelection", "h1_eventsAfterBorderSelection", 5, 0, 5);
 
  h1_seedOverSC_ = new TH1F("h1_seedOverSC", "h1_seedOverSC", 400, 0., 2.);
 
  myZeePlots_->bookHLTHistograms();
 
  h1_borderElectronClassification_ =
      new TH1F("h1_borderElectronClassification", "h1_borderElectronClassification", 55, -5, 50);
  h1_preshowerOverSC_ = new TH1F("h1_preshowerOverSC", "h1_preshowerOverSC", 400, 0., 1.);
 
  h2_fEtaBarrelGood_ = new TH2F("fEtaBarrelGood", "fEtaBarrelGood", 800, -4., 4., 800, 0.8, 1.2);
  h2_fEtaBarrelGood_->SetXTitle("Eta");
  h2_fEtaBarrelGood_->SetYTitle("1/fEtaBarrelGood");
 
  h2_fEtaBarrelBad_ = new TH2F("fEtaBarrelBad", "fEtaBarrelBad", 800, -4., 4., 800, 0.8, 1.2);
  h2_fEtaBarrelBad_->SetXTitle("Eta");
  h2_fEtaBarrelBad_->SetYTitle("1/fEtaBarrelBad");
 
  h2_fEtaEndcapGood_ = new TH2F("fEtaEndcapGood", "fEtaEndcapGood", 800, -4., 4., 800, 0.8, 1.2);
  h2_fEtaEndcapGood_->SetXTitle("Eta");
  h2_fEtaEndcapGood_->SetYTitle("1/fEtaEndcapGood");
 
  h2_fEtaEndcapBad_ = new TH2F("fEtaEndcapBad", "fEtaEndcapBad", 800, -4., 4., 800, 0.8, 1.2);
  h2_fEtaEndcapBad_->SetXTitle("Eta");
  h2_fEtaEndcapBad_->SetYTitle("1/fEtaEndcapBad");
 
  for (int i = 0; i < 2; i++) {
    char histoName[50];
 
    sprintf(histoName, "h_eleEffEta_%d", i);
    h_eleEffEta_[i] = new TH1F(histoName, histoName, 150, 0., 2.7);
    h_eleEffEta_[i]->SetXTitle("|#eta|");
 
    sprintf(histoName, "h_eleEffPhi_%d", i);
    h_eleEffPhi_[i] = new TH1F(histoName, histoName, 400, -4., 4.);
    h_eleEffPhi_[i]->SetXTitle("Phi");
 
    sprintf(histoName, "h_eleEffPt_%d", i);
    h_eleEffPt_[i] = new TH1F(histoName, histoName, 200, 0., 200.);
    h_eleEffPt_[i]->SetXTitle("p_{T}(GeV/c)");
  }
 
  h2_xtalMiscalibCoeffBarrel_ =
      new TH2F("h2_xtalMiscalibCoeffBarrel", "h2_xtalMiscalibCoeffBarrel", 171, -85, 85, 360, 0, 360);
  h2_xtalMiscalibCoeffEndcapMinus_ =
      new TH2F("h2_xtalMiscalibCoeffEndcapMinus", "h2_xtalMiscalibCoeffEndcapMinus", 100, 0, 100, 100, 0, 100);
  h2_xtalMiscalibCoeffEndcapPlus_ =
      new TH2F("h2_xtalMiscalibCoeffEndcapPlus", "h2_xtalMiscalibCoeffEndcapPlus", 100, 0, 100, 100, 0, 100);
 
  h2_xtalMiscalibCoeffBarrel_->SetXTitle("ieta");
  h2_xtalMiscalibCoeffBarrel_->SetYTitle("iphi");
 
  h2_xtalMiscalibCoeffEndcapMinus_->SetXTitle("ix");
  h2_xtalMiscalibCoeffEndcapMinus_->SetYTitle("iy");
 
  for (int i = 0; i < 25; i++) {
    char histoName[50];
    sprintf(histoName, "h_ESCEtrueVsEta_%d", i);
 
    h_ESCEtrueVsEta_[i] = new TH2F(histoName, histoName, 150, 0., 2.7, 300, 0., 1.5);
    h_ESCEtrueVsEta_[i]->SetXTitle("|#eta|");
    h_ESCEtrueVsEta_[i]->SetYTitle("E_{SC,raw}/E_{MC}");
 
    sprintf(histoName, "h_ESCEtrue_%d", i);
 
    h_ESCEtrue_[i] = new TH1F(histoName, histoName, 300, 0., 1.5);
 
    sprintf(histoName, "h2_chi2_%d", i);
    h2_chi2_[i] = new TH2F(histoName, histoName, 1000, -150, 150, 1000, -1, 5);
 
    sprintf(histoName, "h2_iterations_%d", i);
    h2_iterations_[i] = new TH2F(histoName, histoName, 1000, -150, 150, 1000, -1, 15);
 
    sprintf(histoName, "h_ESCcorrEtrueVsEta_%d", i);
 
    h_ESCcorrEtrueVsEta_[i] = new TH2F(histoName, histoName, 150, 0., 2.7, 300, 0., 1.5);
    h_ESCcorrEtrueVsEta_[i]->SetXTitle("|#eta|");
    h_ESCcorrEtrueVsEta_[i]->SetYTitle("E_{SC,#eta-corr}/E_{MC}");
 
    sprintf(histoName, "h_ESCcorrEtrue_%d", i);
 
    h_ESCcorrEtrue_[i] = new TH1F(histoName, histoName, 300, 0., 1.5);
 
    sprintf(histoName, "h2_xtalRecalibCoeffBarrel_%d", i);
    h2_xtalRecalibCoeffBarrel_[i] = new TH2F(histoName, histoName, 171, -85, 85, 360, 0, 360);
 
    h2_xtalRecalibCoeffBarrel_[i]->SetXTitle("ieta");
    h2_xtalRecalibCoeffBarrel_[i]->SetYTitle("iphi");
 
    sprintf(histoName, "h2_xtalRecalibCoeffEndcapMinus_%d", i);
    h2_xtalRecalibCoeffEndcapMinus_[i] = new TH2F(histoName, histoName, 100, 0, 100, 100, 0, 100);
    h2_xtalRecalibCoeffEndcapMinus_[i]->SetXTitle("ix");
    h2_xtalRecalibCoeffEndcapMinus_[i]->SetYTitle("iy");
 
    sprintf(histoName, "h2_xtalRecalibCoeffEndcapPlus_%d", i);
    h2_xtalRecalibCoeffEndcapPlus_[i] = new TH2F(histoName, histoName, 100, 0, 100, 100, 0, 100);
    h2_xtalRecalibCoeffEndcapPlus_[i]->SetXTitle("ix");
    h2_xtalRecalibCoeffEndcapPlus_[i]->SetYTitle("iy");
  }
 
  /*
  for (int i=0;i<15;i++)
    {
                                                                                                                             
      char histoName[50];
 
      sprintf(histoName,"h_DiffZMassDistr_%d",i);
      h_DiffZMassDistr_[i] = new TH1F(histoName,histoName, 400, -20., 20.);
      h_DiffZMassDistr_[i]->SetXTitle("M_{Z, reco} - M_{Z, MC}");
      h_DiffZMassDistr_[i]->SetYTitle("events");
 
      sprintf(histoName,"h_ZMassDistr_%d",i);
      h_ZMassDistr_[i] = new TH1F(histoName,histoName, 200, 0., 150.);
      h_ZMassDistr_[i]->SetXTitle("RecoZmass (GeV)");
      h_ZMassDistr_[i]->SetYTitle("events");
 
    }
  */
 
  h1_zMassResol_ = new TH1F("zMassResol", "zMassResol", 200, -50., 50.);
  h1_zMassResol_->SetXTitle("M_{Z, reco} - M_{Z, MC}");
  h1_zMassResol_->SetYTitle("events");
 
  h1_eleEtaResol_ = new TH1F("eleEtaResol", "eleEtaResol", 100, -0.01, 0.01);
  h1_eleEtaResol_->SetXTitle("#eta_{reco} - #eta_{MC}");
  h1_eleEtaResol_->SetYTitle("events");
 
  h1_electronCosTheta_TK_ = new TH1F("electronCosTheta_TK", "electronCosTheta_TK", 100, -1, 1);
  h1_electronCosTheta_TK_->SetXTitle("cos #theta_{12}");
  h1_electronCosTheta_TK_->SetYTitle("events");
 
  h1_electronCosTheta_SC_ = new TH1F("electronCosTheta_SC", "electronCosTheta_SC", 100, -1, 1);
  h1_electronCosTheta_SC_->SetXTitle("cos #theta_{12}");
  h1_electronCosTheta_SC_->SetYTitle("events");
 
  h1_electronCosTheta_SC_TK_ = new TH1F("electronCosTheta_SC_TK", "electronCosTheta_SC_TK", 200, -0.1, 0.1);
  h1_electronCosTheta_SC_TK_->SetXTitle("cos #theta_{12}^{SC}/ cos #theta_{12}^{TK} - 1");
  h1_electronCosTheta_SC_TK_->SetYTitle("events");
 
  h1_elePhiResol_ = new TH1F("elePhiResol", "elePhiResol", 100, -0.01, 0.01);
  h1_elePhiResol_->SetXTitle("#phi_{reco} - #phi_{MC}");
  h1_elePhiResol_->SetYTitle("events");
 
  h1_zEtaResol_ = new TH1F("zEtaResol", "zEtaResol", 200, -1., 1.);
  h1_zEtaResol_->SetXTitle("#eta_{Z, reco} - #eta_{Z, MC}");
  h1_zEtaResol_->SetYTitle("events");
 
  h1_zPhiResol_ = new TH1F("zPhiResol", "zPhiResol", 200, -1., 1.);
  h1_zPhiResol_->SetXTitle("#phi_{Z, reco} - #phi_{Z, MC}");
  h1_zPhiResol_->SetYTitle("events");
 
  h1_nEleReco_ = new TH1F("nEleReco", "Number of reco electrons", 10, -0.5, 10.5);
  h1_nEleReco_->SetXTitle("nEleReco");
  h1_nEleReco_->SetYTitle("events");
 
  //  h1_occupancyVsEta_ = new TH1F("occupancyVsEta","occupancyVsEta",EcalRingCalibrationTools::N_RING_TOTAL,0,(float)EcalRingCalibrationTools::N_RING_TOTAL);
 
  h1_occupancyVsEta_ = new TH1F("occupancyVsEta", "occupancyVsEta", 249, -124, 124);
  h1_occupancyVsEta_->SetYTitle("Weighted electron statistics");
  h1_occupancyVsEta_->SetXTitle("Eta channel");
 
  h1_weightSumMeanBarrel_ = new TH1F("weightSumMeanBarrel", "weightSumMeanBarrel", 10000, 0, 10000);
  h1_weightSumMeanEndcap_ = new TH1F("weightSumMeanEndcap", "weightSumMeanEndcap", 10000, 0, 10000);
 
  h1_occupancy_ = new TH1F("occupancy", "occupancy", 1000, 0, 10000);
  h1_occupancy_->SetXTitle("Weighted electron statistics");
 
  h1_occupancyBarrel_ = new TH1F("occupancyBarrel", "occupancyBarrel", 1000, 0, 10000);
  h1_occupancyBarrel_->SetXTitle("Weighted electron statistics");
 
  h1_occupancyEndcap_ = new TH1F("occupancyEndcap", "occupancyEndcap", 1000, 0, 10000);
  h1_occupancyEndcap_->SetXTitle("Weighted electron statistics");
 
  h1_eleClasses_ = new TH1F("eleClasses", "eleClasses", 301, -1, 300);
  h1_eleClasses_->SetXTitle("classCode");
  h1_eleClasses_->SetYTitle("#");
 
  myZeePlots_->bookZMCHistograms();
 
  myZeePlots_->bookZHistograms();
 
  myZeePlots_->bookEleMCHistograms();
 
  myZeePlots_->bookEleHistograms();
 
  h1_ZCandMult_ = new TH1F("ZCandMult", "Multiplicity of Z candidates in one event", 10, -0.5, 10.5);
  h1_ZCandMult_->SetXTitle("ZCandMult");
 
  h1_reco_ZMass_ = new TH1F("reco_ZMass", "Inv. mass of 2 reco Electrons", 200, 0., 150.);
  h1_reco_ZMass_->SetXTitle("reco_ZMass (GeV)");
  h1_reco_ZMass_->SetYTitle("events");
 
  h1_reco_ZMassCorr_ = new TH1F("reco_ZMassCorr", "Inv. mass of 2 corrected reco Electrons", 200, 0., 150.);
  h1_reco_ZMassCorr_->SetXTitle("reco_ZMass (GeV)");
  h1_reco_ZMassCorr_->SetYTitle("events");
 
  h1_reco_ZMassCorrBB_ = new TH1F("reco_ZMassCorrBB", "Inv. mass of 2 corrected reco Electrons", 200, 0., 150.);
  h1_reco_ZMassCorrBB_->SetXTitle("reco_ZMass (GeV)");
  h1_reco_ZMassCorrBB_->SetYTitle("events");
 
  h1_reco_ZMassCorrEE_ = new TH1F("reco_ZMassCorrEE", "Inv. mass of 2 corrected reco Electrons", 200, 0., 150.);
  h1_reco_ZMassCorrEE_->SetXTitle("reco_ZMass (GeV)");
  h1_reco_ZMassCorrEE_->SetYTitle("events");
 
  //  h2_coeffVsEta_= new TH2F("h2_calibCoeffVsEta","h2_calibCoeffVsEta",EcalRingCalibrationTools::N_RING_TOTAL,0, (double)EcalRingCalibrationTools::N_RING_TOTAL, 200, 0., 2.);
 
  h2_coeffVsEta_ = new TH2F("h2_calibCoeffVsEta", "h2_calibCoeffVsEta", 249, -124, 125, 200, 0., 2.);
  h2_coeffVsEta_->SetXTitle("Eta channel");
  h2_coeffVsEta_->SetYTitle("recalibCoeff");
 
  h2_coeffVsEtaGrouped_ =
      new TH2F("h2_calibCoeffVsEtaGrouped", "h2_calibCoeffVsEtaGrouped", 200, 0., 3., 200, 0.6, 1.4);
  h2_coeffVsEtaGrouped_->SetXTitle("|#eta|");
  h2_coeffVsEtaGrouped_->SetYTitle("recalibCoeff");
 
  h2_zMassVsLoop_ = new TH2F("h2_zMassVsLoop", "h2_zMassVsLoop", 1000, 0, 40, 90, 80., 95.);
 
  h2_zMassDiffVsLoop_ = new TH2F("h2_zMassDiffVsLoop", "h2_zMassDiffVsLoop", 1000, 0, 40, 100, -1., 1.);
  h2_zMassDiffVsLoop_->SetXTitle("Iteration");
  h2_zMassDiffVsLoop_->SetYTitle("M_{Z, reco peak} - M_{Z, true}");
 
  h2_zWidthVsLoop_ = new TH2F("h2_zWidthVsLoop", "h2_zWidthVsLoop", 1000, 0, 40, 100, 0., 10.);
 
  h2_coeffVsLoop_ = new TH2F("h2_coeffVsLoop", "h2_coeffVsLoop", 1000, 0, 40, 100, 0., 2.);
 
  h2_residualSigma_ = new TH2F("h2_residualSigma", "h2_residualSigma", 1000, 0, 40, 100, 0., .5);
 
  h2_miscalRecal_ = new TH2F("h2_miscalRecal", "h2_miscalRecal", 500, 0., 2., 500, 0., 2.);
  h2_miscalRecal_->SetXTitle("initCalibCoeff");
  h2_miscalRecal_->SetYTitle("1/RecalibCoeff");
 
  h2_miscalRecalEB_ = new TH2F("h2_miscalRecalEB", "h2_miscalRecalEB", 500, 0., 2., 500, 0., 2.);
  h2_miscalRecalEB_->SetXTitle("initCalibCoeff");
  h2_miscalRecalEB_->SetYTitle("1/RecalibCoeff");
 
  h2_miscalRecalEE_ = new TH2F("h2_miscalRecalEE", "h2_miscalRecalEE", 500, 0., 2., 500, 0., 2.);
  h2_miscalRecalEE_->SetXTitle("initCalibCoeff");
  h2_miscalRecalEE_->SetYTitle("1/RecalibCoeff");
 
  h1_mc_ = new TH1F("h1_residualMiscalib", "h1_residualMiscalib", 200, -0.2, 0.2);
  h1_mcEB_ = new TH1F("h1_residualMiscalibEB", "h1_residualMiscalibEB", 200, -0.2, 0.2);
  h1_mcEE_ = new TH1F("h1_residualMiscalibEE", "h1_residualMiscalibEE", 200, -0.2, 0.2);
 
  for (int i = 0; i < 25; i++) {
    char histoName[50];
    /*     
         sprintf(histoName,"h2_miscalRecalParz_%d",i);
         h2_miscalRecalParz_[i] = new TH2F(histoName,histoName,500, 0., 2., 500, 0., 2.);
         h2_miscalRecalParz_[i]->SetXTitle("initCalibCoeff");
         h2_miscalRecalParz_[i]->SetYTitle("1/recalibCoeff");
         
         sprintf(histoName,"h2_miscalRecalEBParz_%d",i);
         h2_miscalRecalEBParz_[i] = new TH2F(histoName,histoName,500, 0., 2., 500, 0., 2.);
         h2_miscalRecalEBParz_[i]->SetXTitle("initCalibCoeff");
         h2_miscalRecalEBParz_[i]->SetYTitle("1/recalibCoeff");
         
      sprintf(histoName,"h2_miscalRecalEEParz_%d",i);
      h2_miscalRecalEEParz_[i] = new TH2F(histoName,histoName,500, 0., 2., 500, 0., 2.);
      h2_miscalRecalEEParz_[i]->SetXTitle("initCalibCoeff");
      h2_miscalRecalEEParz_[i]->SetYTitle("1/recalibCoeff");
      */
 
    sprintf(histoName, "h1_residualMiscalibParz_%d", i);
    h1_mcParz_[i] = new TH1F(histoName, histoName, 200, -0.2, 0.2);
    sprintf(histoName, "h1_residualMiscalibEBParz_%d", i);
    h1_mcEBParz_[i] = new TH1F(histoName, histoName, 200, -0.2, 0.2);
    sprintf(histoName, "h1_residualMiscalibEEParz_%d", i);
    h1_mcEEParz_[i] = new TH1F(histoName, histoName, 200, -0.2, 0.2);
  }
}

References ZeePlots::bookEleHistograms(), ZeePlots::bookEleMCHistograms(), ZeePlots::bookHLTHistograms(), ZeePlots::bookZHistograms(), ZeePlots::bookZMCHistograms(), h1_borderElectronClassification_, h1_eleClasses_, h1_electronCosTheta_SC_, h1_electronCosTheta_SC_TK_, h1_electronCosTheta_TK_, h1_eleEtaResol_, h1_elePhiResol_, h1_eventsAfterBorderSelection_, h1_eventsAfterEWKSelection_, h1_eventsBeforeBorderSelection_, h1_eventsBeforeEWKSelection_, h1_mc_, h1_mcEB_, h1_mcEBParz_, h1_mcEE_, h1_mcEEParz_, h1_mcParz_, h1_nEleReco_, h1_occupancy_, h1_occupancyBarrel_, h1_occupancyEndcap_, h1_occupancyVsEta_, h1_preshowerOverSC_, h1_reco_ZMass_, h1_reco_ZMassCorr_, h1_reco_ZMassCorrBB_, h1_reco_ZMassCorrEE_, h1_seedOverSC_, h1_weightSumMeanBarrel_, h1_weightSumMeanEndcap_, h1_ZCandMult_, h1_zEtaResol_, h1_zMassResol_, h1_zPhiResol_, h2_chi2_, h2_coeffVsEta_, h2_coeffVsEtaGrouped_, h2_coeffVsLoop_, h2_fEtaBarrelBad_, h2_fEtaBarrelGood_, h2_fEtaEndcapBad_, h2_fEtaEndcapGood_, h2_iterations_, h2_miscalRecal_, h2_miscalRecalEB_, h2_miscalRecalEE_, h2_residualSigma_, h2_xtalMiscalibCoeffBarrel_, h2_xtalMiscalibCoeffEndcapMinus_, h2_xtalMiscalibCoeffEndcapPlus_, h2_xtalRecalibCoeffBarrel_, h2_xtalRecalibCoeffEndcapMinus_, h2_xtalRecalibCoeffEndcapPlus_, h2_zMassDiffVsLoop_, h2_zMassVsLoop_, h2_zWidthVsLoop_, h_eleEffEta_, h_eleEffPhi_, h_eleEffPt_, h_ESCcorrEtrue_, h_ESCcorrEtrueVsEta_, h_ESCEtrue_, h_ESCEtrueVsEta_, HltBtagPostValidation_cff::histoName, mps_fire::i, and myZeePlots_.

Referenced by duringLoop().

computeCoefficientDistanceAtIteration()

float ZeeCalibration::computeCoefficientDistanceAtIteration ( float  v1[250], float  v2[250], int  size  )

private

Definition at line 2007 of file ZeeCalibration.cc.

                                                                                                  {
  float dist(0.);
 
  for (int i = 0; i < size; i++) {
    //    std::cout<< "[ZeeCalibration::computeCoefficientDistanceAtIteration] Adding term "<<pow( v1[i]-v2[i], 2 )<<" from v1 "<<v1[i]<<" and v2 "<<v2[i]<<std::endl;
 
    bool isNearCrack = false;
 
    if (calibMode_ == "RING") {  //exclude non-calibrated rings from computation
 
      isNearCrack = (abs(ringNumberCorrector(i)) == 1 || abs(ringNumberCorrector(i)) == 25 ||
                     abs(ringNumberCorrector(i)) == 26 || abs(ringNumberCorrector(i)) == 45 ||
                     abs(ringNumberCorrector(i)) == 46 || abs(ringNumberCorrector(i)) == 65 ||
                     abs(ringNumberCorrector(i)) == 66 || abs(ringNumberCorrector(i)) == 85 ||
                     abs(ringNumberCorrector(i)) == 86 || abs(ringNumberCorrector(i)) == 124);
    }
 
    if (!isNearCrack)
      dist += pow(v1[i] - v2[i], 2);
  }
 
  dist = sqrt(dist) / size;
 
  return dist;
}

References funct::abs(), calibMode_, mps_fire::i, funct::pow(), ringNumberCorrector(), findQualityFiles::size, and mathSSE::sqrt().

Referenced by endOfLoop().

duringLoop()

edm::EDLooper::Status ZeeCalibration::duringLoop ( const edm::Event &  iEvent, const edm::EventSetup &  iSetup  )

overridevirtual

Called at each event.

START HERE....

Implements edm::EDLooper.

Definition at line 578 of file ZeeCalibration.cc.

                                                                                                {
  using namespace edm;
 
#ifdef DEBUG
  std::cout << "[ZeeCalibration] Entering duringLoop" << std::endl;
#endif
 
  // code that used to be in beginJob
  if (isfirstcall_) {
    //inizializzare la geometria di ecal
    edm::ESHandle<CaloGeometry> pG;
    iSetup.get<CaloGeometryRecord>().get(pG);
    EcalRingCalibrationTools::setCaloGeometry(&(*pG));
 
    myZeePlots_ = new ZeePlots("zeePlots.root");
    //  myZeeRescaleFactorPlots_ = new ZeeRescaleFactorPlots("zeeRescaleFactorPlots.root");
 
    // go to *OUR* rootfile and book histograms
    outputFile_->cd();
    bookHistograms();
 
    std::cout << "[ZeeCalibration::beginOfJob] Histograms booked " << std::endl;
 
    loopFlag_ = 0;
 
    //Read miscalibration map if requested
    CaloMiscalibMapEcal* miscalibMap = nullptr;
    if (!barrelfile_.empty() || !barrelfile_.empty()) {
      miscalibMap = new CaloMiscalibMapEcal();
      miscalibMap->prefillMap();
    }
 
    if (!barrelfile_.empty()) {
      MiscalibReaderFromXMLEcalBarrel barrelreader_(*miscalibMap);
      barrelreader_.parseXMLMiscalibFile(barrelfile_);
#ifdef DEBUG
      std::cout << "[ZeeCalibration::beginOfJob] Parsed EB miscal file" << std::endl;
#endif
    }
 
    if (!endcapfile_.empty()) {
      MiscalibReaderFromXMLEcalEndcap endcapreader_(*miscalibMap);
      endcapreader_.parseXMLMiscalibFile(endcapfile_);
#ifdef DEBUG
      std::cout << "[ZeeCalibration::beginOfJob] Parsed EE miscal file" << std::endl;
#endif
    }
 
    std::cout << "  theAlgorithm_->getNumberOfChannels() " << theAlgorithm_->getNumberOfChannels() << std::endl;
 
    for (int k = 0; k < theAlgorithm_->getNumberOfChannels(); k++) {
      calibCoeff[k] = 1.;
      calibCoeffError[k] = 0.;
 
      std::vector<DetId> ringIds;
 
      if (calibMode_ == "RING")
        ringIds = EcalRingCalibrationTools::getDetIdsInRing(k);
 
      if (calibMode_ == "MODULE")
        ringIds = EcalRingCalibrationTools::getDetIdsInModule(k);
 
      if (calibMode_ == "ABS_SCALE" || calibMode_ == "ETA_ET_MODE")
        ringIds = EcalRingCalibrationTools::getDetIdsInECAL();
 
      if (miscalibMap) {
        initCalibCoeff[k] = 0.;
        for (unsigned int iid = 0; iid < ringIds.size(); ++iid) {
          float miscalib = *(miscalibMap->get().getMap().find(ringIds[iid]));
          //          float miscalib=miscalibMap->get().getMap().find(ringIds[iid])->second; ////////AP
          initCalibCoeff[k] += miscalib;
        }
        initCalibCoeff[k] /= (float)ringIds.size();
        std::cout << k << " " << initCalibCoeff[k] << " " << ringIds.size() << std::endl;
      } else {
        initCalibCoeff[k] = 1.;
      }
    }
 
    ical = std::make_shared<EcalIntercalibConstants>();
 
    for (int k = 0; k < theAlgorithm_->getNumberOfChannels(); k++) {
      //      std::vector<DetId> ringIds = EcalRingCalibrationTools::getDetIdsInRing(k);
 
      std::vector<DetId> ringIds;
 
      if (calibMode_ == "RING")
        ringIds = EcalRingCalibrationTools::getDetIdsInRing(k);
 
      if (calibMode_ == "MODULE")
        ringIds = EcalRingCalibrationTools::getDetIdsInModule(k);
 
      if (calibMode_ == "ABS_SCALE" || calibMode_ == "ETA_ET_MODE")
        ringIds = EcalRingCalibrationTools::getDetIdsInECAL();
 
      for (unsigned int iid = 0; iid < ringIds.size(); ++iid) {
        //  ical->setValue( ringIds[iid], 1. * initCalibCoeff[k] );
 
        if (ringIds[iid].subdetId() == EcalBarrel) {
          EBDetId myEBDetId(ringIds[iid]);
          h2_xtalMiscalibCoeffBarrel_->SetBinContent(
              myEBDetId.ieta() + 86,
              myEBDetId.iphi(),
              *(miscalibMap->get().getMap().find(ringIds[iid])));  //fill TH2 with miscalibCoeff
        }
 
        if (ringIds[iid].subdetId() == EcalEndcap) {
          EEDetId myEEDetId(ringIds[iid]);
          if (myEEDetId.zside() < 0)
            h2_xtalMiscalibCoeffEndcapMinus_->SetBinContent(
                myEEDetId.ix(),
                myEEDetId.iy(),
                *(miscalibMap->get().getMap().find(ringIds[iid])));  //fill TH2 with miscalibCoeff
 
          if (myEEDetId.zside() > 0)
            h2_xtalMiscalibCoeffEndcapPlus_->SetBinContent(
                myEEDetId.ix(),
                myEEDetId.iy(),
                *(miscalibMap->get().getMap().find(ringIds[iid])));  //fill TH2 with miscalibCoeff
        }
 
        ical->setValue(ringIds[iid], *(miscalibMap->get().getMap().find(ringIds[iid])));
      }
 
      read_events = 0;
      init_ = false;
    }
    isfirstcall_ = false;
  }  // if isfirstcall
 
 
  for (unsigned int iHLT = 0; iHLT < 200; ++iHLT) {
    aHLTResults[iHLT] = false;
  }
 
#ifdef DEBUG
  std::cout << "[ZeeCalibration::duringLoop] Done with initializing aHLTresults[] " << std::endl;
#endif
 
  edm::Handle<edm::TriggerResults> hltTriggerResultHandle;
  iEvent.getByLabel(hlTriggerResults_, hltTriggerResultHandle);
 
  if (!hltTriggerResultHandle.isValid()) {
    //std::cout << "invalid handle for HLT TriggerResults" << std::endl;
  } else {
    hltCount = hltTriggerResultHandle->size();
 
    if (loopFlag_ == 0)
      myZeePlots_->fillHLTInfo(hltTriggerResultHandle);
 
#ifdef DEBUG
    std::cout << "[ZeeCalibration::duringLoop] Done with myZeePlots_->fillHLTInfo(hltTriggerResultHandle); "
              << std::endl;
#endif
 
    for (int i = 0; i < hltCount; i++) {
      aHLTResults[i] = hltTriggerResultHandle->accept(i);
 
      //HLT bit 32 = HLT1Electron
      //HLT bit 34 = HLT2Electron
      //HLT bit 35 = HLT2ElectronRelaxed
    }
 
    if (!aHLTResults[32] && !aHLTResults[34] && !aHLTResults[35])
      return kContinue;
  }
 
#ifdef DEBUG
  std::cout << "[ZeeCalibration::duringLoop] End HLT section" << std::endl;
#endif
 
 
  std::vector<HepMC::GenParticle*> mcEle;
 
  float myGenZMass(-1);
 
  if (!mcProducer_.empty()) {
    //DUMP GENERATED Z MASS - BEGIN
    Handle<HepMCProduct> hepProd;
    //   iEvent.getByLabel( "source", hepProd ) ;
    iEvent.getByLabel(mcProducer_, hepProd);
 
    const HepMC::GenEvent* myGenEvent = hepProd->GetEvent();
 
    if (loopFlag_ == 0)
      myZeePlots_->fillZMCInfo(&(*myGenEvent));
 
#ifdef DEBUG
    std::cout << "[ZeeCalibration::duringLoop] Done with myZeePlots_->fillZMCInfo( & (*myGenEvent) ); " << std::endl;
#endif
 
    for (HepMC::GenEvent::particle_const_iterator p = myGenEvent->particles_begin(); p != myGenEvent->particles_end();
         ++p) {
      //return a pointer to MC Z in the event
      if ((*p)->pdg_id() == 23 && (*p)->status() == 2) {
        myGenZMass = (*p)->momentum().m();
      }
    }
    //DUMP GENERATED Z MASS - END
 
    if (loopFlag_ == 0)
      myZeePlots_->fillEleMCInfo(&(*myGenEvent));
 
    //loop over MC positrons and find the closest MC positron in (eta,phi) phace space - begin
    HepMC::GenParticle MCele;
 
    for (HepMC::GenEvent::particle_const_iterator p = myGenEvent->particles_begin(); p != myGenEvent->particles_end();
         ++p) {
      if (abs((*p)->pdg_id()) == 11) {
        mcEle.push_back((*p));
        MCele = *(*p);
      }
    }
 
    if (mcEle.size() == 2 && fabs(mcEle[0]->momentum().eta()) < 2.4 && fabs(mcEle[1]->momentum().eta()) < 2.4) {
      NEVT++;
 
      if (fabs(mcEle[0]->momentum().eta()) < 1.479 && fabs(mcEle[1]->momentum().eta()) < 1.479)
        MCZBB++;
 
      if ((fabs(mcEle[0]->momentum().eta()) > 1.479 && fabs(mcEle[1]->momentum().eta()) < 1.479) ||
          (fabs(mcEle[0]->momentum().eta()) < 1.479 && fabs(mcEle[1]->momentum().eta()) > 1.479))
        MCZEB++;
 
      if (fabs(mcEle[0]->momentum().eta()) > 1.479 && fabs(mcEle[1]->momentum().eta()) > 1.479)
        MCZEE++;
    }
  }
 
  // Get EBRecHits
  Handle<EBRecHitCollection> phits;
  try {
    iEvent.getByLabel(rechitProducer_, rechitCollection_, phits);
  } catch (std::exception& ex) {
    std::cerr << "Error! can't get the product EBRecHitCollection " << std::endl;
  }
  const EBRecHitCollection* hits = phits.product();  // get a ptr to the product
 
  // Get EERecHits
  Handle<EERecHitCollection> ephits;
  try {
    iEvent.getByLabel(erechitProducer_, erechitCollection_, ephits);
  } catch (std::exception& ex) {
    std::cerr << "Error! can't get the product EERecHitCollection " << std::endl;
  }
  const EERecHitCollection* ehits = ephits.product();  // get a ptr to the product
 
  //Get Hybrid SuperClusters
  Handle<reco::SuperClusterCollection> pSuperClusters;
  try {
    iEvent.getByLabel(scProducer_, scCollection_, pSuperClusters);
  } catch (std::exception& ex) {
    std::cerr << "Error! can't get the product SuperClusterCollection " << std::endl;
  }
  const reco::SuperClusterCollection* scCollection = pSuperClusters.product();
 
#ifdef DEBUG
  std::cout << "scCollection->size()" << scCollection->size() << std::endl;
  for (reco::SuperClusterCollection::const_iterator scIt = scCollection->begin(); scIt != scCollection->end(); scIt++) {
    std::cout << scIt->energy() << std::endl;
  }
#endif
 
  //Get Island SuperClusters
  Handle<reco::SuperClusterCollection> pIslandSuperClusters;
  try {
    iEvent.getByLabel(scIslandProducer_, scIslandCollection_, pIslandSuperClusters);
  } catch (std::exception& ex) {
    std::cerr << "Error! can't get the product IslandSuperClusterCollection " << std::endl;
  }
  const reco::SuperClusterCollection* scIslandCollection = pIslandSuperClusters.product();
 
#ifdef DEBUG
  std::cout << "scCollection->size()" << scIslandCollection->size() << std::endl;
#endif
 
  if ((scCollection->size() + scIslandCollection->size()) < 2)
    return kContinue;
 
  // Get Electrons
  Handle<reco::GsfElectronCollection> pElectrons;
  try {
    iEvent.getByLabel(electronProducer_, electronCollection_, pElectrons);
  } catch (std::exception& ex) {
    std::cerr << "Error! can't get the product ElectronCollection " << std::endl;
  }
  const reco::GsfElectronCollection* electronCollection = pElectrons.product();
 
  /*
  //reco-mc association map
  std::map<HepMC::GenParticle*,const reco::PixelMatchGsfElectron*> myMCmap;
  
    fillMCmap(&(*electronCollection),mcEle,myMCmap);
    
    fillEleInfo(mcEle,myMCmap);
  */
 
  if (electronCollection->size() < 2)
    return kContinue;
 
  if (!hits && !ehits) {
    std::cout << "!hits" << std::endl;
    return kContinue;
  }
 
  if (hits->empty() && ehits->empty()) {
    std::cout << "hits->size() == 0" << std::endl;
    return kContinue;
  }
 
  if (!electronCollection) {
    std::cout << "!electronCollection" << std::endl;
    return kContinue;
  }
 
  if (electronCollection->empty()) {
    std::cout << "electronCollection->size() == 0" << std::endl;
    return kContinue;
  }
 
 
  read_events++;
 
  //  std::cout << "read_events = " << read_events << std::endl;
 
 
#ifdef DEBUG
  std::cout << " Starting with myZeePlots_->fillEleInfo(electronCollection); " << std::endl;
#endif
 
  if (loopFlag_ == 0)
    myZeePlots_->fillEleInfo(electronCollection);
 
#ifdef DEBUG
  std::cout << " Done with myZeePlots_->fillEleInfo(electronCollection); " << std::endl;
#endif
 
  //FILL an electron vector - end
  //###################################Electron-SC association: begin#####################################################
  //Filling new ElectronCollection with new SC ref and calibElectron container
  std::vector<calib::CalibElectron> calibElectrons;
  //std::map< const calib::CalibElectron* , const reco::SuperCluster* > eleScMap;
 
  //#####################################Electron-SC association map: end#####################################################
  for (unsigned int e_it = 0; e_it != electronCollection->size(); e_it++) {
    calibElectrons.push_back(calib::CalibElectron(&((*electronCollection)[e_it]), hits, ehits));
#ifdef DEBUG
    std::cout << calibElectrons.back().getRecoElectron()->superCluster()->energy() << " "
              << calibElectrons.back().getRecoElectron()->energy() << std::endl;
#endif
    //      h1_recoEleEnergy_->Fill(calibElectrons.back().getRecoElectron()->superCluster()->energy());
  }
  //  if (iLoop == 0)
  //fillCalibElectrons(calibElectrons);
 
#ifdef DEBUG
  std::cout << "Filled histos" << std::endl;
#endif
 
  //COMBINATORY FOR Z MASS - begin
  std::vector<std::pair<calib::CalibElectron*, calib::CalibElectron*> > zeeCandidates;
  int myBestZ = -1;
 
  mass = -1.;
  double DeltaMinvMin(5000.);
 
  if (calibElectrons.size() < 2)
    return kContinue;
 
  for (unsigned int e_it = 0; e_it != calibElectrons.size() - 1; e_it++) {
    for (unsigned int p_it = e_it + 1; p_it != calibElectrons.size(); p_it++) {
#ifdef DEBUG
      std::cout << e_it << " " << calibElectrons[e_it].getRecoElectron()->charge() << " " << p_it << " "
                << calibElectrons[p_it].getRecoElectron()->charge() << std::endl;
#endif
      if (calibElectrons[e_it].getRecoElectron()->charge() * calibElectrons[p_it].getRecoElectron()->charge() != -1)
        continue;
 
      mass = ZeeKinematicTools::calculateZMass_withTK(
          std::pair<calib::CalibElectron*, calib::CalibElectron*>(&(calibElectrons[e_it]), &(calibElectrons[p_it])));
 
      if (mass < 0)
        continue;
 
#ifdef DEBUG
      std::cout << "#######################mass " << mass << std::endl;
#endif
 
      zeeCandidates.push_back(
          std::pair<calib::CalibElectron*, calib::CalibElectron*>(&(calibElectrons[e_it]), &(calibElectrons[p_it])));
      double DeltaMinv = fabs(mass - MZ);
 
      if (DeltaMinv < DeltaMinvMin) {
        DeltaMinvMin = DeltaMinv;
        myBestZ = zeeCandidates.size() - 1;
      }
    }
  }
 
  //  h_DeltaZMassDistr_[loopFlag_]->Fill( (mass-MZ) / MZ );
 
  //  zeeCa->Fill(zeeCandidates);
  //
  h1_ZCandMult_->Fill(zeeCandidates.size());
 
  if (zeeCandidates.empty() || myBestZ == -1)
    return kContinue;
 
  if (loopFlag_ == 0)
    myZeePlots_->fillZInfo(zeeCandidates[myBestZ]);
 
#ifdef DEBUG
  std::cout << "Found ZCandidates " << myBestZ << std::endl;
#endif
 
  //  h1_zMassResol_ ->Fill(mass-myGenZMass);
 
 
  int class1 = zeeCandidates[myBestZ].first->getRecoElectron()->classification();
  int class2 = zeeCandidates[myBestZ].second->getRecoElectron()->classification();
 
  h1_eleClasses_->Fill(class1);
  h1_eleClasses_->Fill(class2);
 
  std::cout << "BEFORE " << std::endl;
 
  //  myZeePlots_->fillEleClassesPlots( zeeCandidates[myBestZ].first );
  //myZeePlots_->fillEleClassesPlots( zeeCandidates[myBestZ].second );
 
  std::cout << "AFTER " << std::endl;
 
 
  if (class1 < 100)
    //    h1_Elec_->Fill(1);
    TOTAL_ELECTRONS_IN_BARREL++;
  if (class1 >= 100)
    TOTAL_ELECTRONS_IN_ENDCAP++;
 
  if (class2 < 100)
    TOTAL_ELECTRONS_IN_BARREL++;
  if (class2 >= 100)
    TOTAL_ELECTRONS_IN_ENDCAP++;
 
  if (class1 == 0)
    GOLDEN_ELECTRONS_IN_BARREL++;
  if (class1 == 100)
    GOLDEN_ELECTRONS_IN_ENDCAP++;
  if (class1 == 10 || class1 == 20)
    SILVER_ELECTRONS_IN_BARREL++;
  if (class1 == 110 || class1 == 120)
    SILVER_ELECTRONS_IN_ENDCAP++;
  if (class1 >= 30 && class1 <= 34)
    SHOWER_ELECTRONS_IN_BARREL++;
  if (class1 >= 130 && class1 <= 134)
    SHOWER_ELECTRONS_IN_ENDCAP++;
  if (class1 == 40)
    CRACK_ELECTRONS_IN_BARREL++;
  if (class1 == 140)
    CRACK_ELECTRONS_IN_ENDCAP++;
 
  if (class2 == 0)
    GOLDEN_ELECTRONS_IN_BARREL++;
  if (class2 == 100)
    GOLDEN_ELECTRONS_IN_ENDCAP++;
  if (class2 == 10 || class2 == 20)
    SILVER_ELECTRONS_IN_BARREL++;
  if (class2 == 110 || class2 == 120)
    SILVER_ELECTRONS_IN_ENDCAP++;
  if (class2 >= 30 && class2 <= 34)
    SHOWER_ELECTRONS_IN_BARREL++;
  if (class2 >= 130 && class2 <= 134)
    SHOWER_ELECTRONS_IN_ENDCAP++;
  if (class2 == 40)
    CRACK_ELECTRONS_IN_BARREL++;
  if (class2 == 140)
    CRACK_ELECTRONS_IN_ENDCAP++;
 
 
 
  DetId firstElehottestDetId =
      getHottestDetId(
          zeeCandidates[myBestZ].first->getRecoElectron()->superCluster()->seed()->hitsAndFractions(), hits, ehits)
          .first;
  DetId secondElehottestDetId =
      getHottestDetId(
          zeeCandidates[myBestZ].second->getRecoElectron()->superCluster()->seed()->hitsAndFractions(), hits, ehits)
          .first;
 
  bool firstElectronIsOnModuleBorder(false);
  bool secondElectronIsOnModuleBorder(false);
 
  h1_eventsBeforeBorderSelection_->Fill(1);
 
  if (class1 < 100) {
    if (firstElehottestDetId.subdetId() == EcalBarrel)
      firstElectronIsOnModuleBorder = xtalIsOnModuleBorder(firstElehottestDetId);
 
    BARREL_ELECTRONS_BEFORE_BORDER_CUT++;
 
    if (firstElehottestDetId.subdetId() == EcalBarrel && !firstElectronIsOnModuleBorder)
      BARREL_ELECTRONS_AFTER_BORDER_CUT++;
  }
 
  if (class2 < 100) {
    if (secondElehottestDetId.subdetId() == EcalBarrel)
      secondElectronIsOnModuleBorder = xtalIsOnModuleBorder(secondElehottestDetId);
 
    BARREL_ELECTRONS_BEFORE_BORDER_CUT++;
 
    if (secondElehottestDetId.subdetId() == EcalBarrel && !secondElectronIsOnModuleBorder)
      BARREL_ELECTRONS_AFTER_BORDER_CUT++;
  }
 
  if (class1 < 100) {
    if (firstElehottestDetId.subdetId() == EcalBarrel && firstElectronIsOnModuleBorder) {
      h1_borderElectronClassification_->Fill(class1);
      return kContinue;
    }
  }
 
  if (class2 < 100) {
    if (secondElehottestDetId.subdetId() == EcalBarrel && secondElectronIsOnModuleBorder) {
      h1_borderElectronClassification_->Fill(class2);
      return kContinue;
    }
  }
 
  h1_eventsAfterBorderSelection_->Fill(1);
 
  if (class1 < 100 && class2 < 100) {
    BBZN++;
    if (class1 == 0 && class2 == 0)
      BBZN_gg++;
    if (class1 < 21 && class2 < 21)
      BBZN_tt++;
    if (class1 < 21 || class2 < 21)
      BBZN_t0++;
  }
 
  if (class1 >= 100 && class2 >= 100) {
    EEZN++;
    if (class1 == 100 && class2 == 100)
      EEZN_gg++;
    if (class1 < 121 && class2 < 121)
      EEZN_tt++;
    if (class1 < 121 || class2 < 121)
      EEZN_t0++;
  }
 
  if ((class1 < 100 && class2 >= 100) || (class2 < 100 && class1 >= 100)) {
    EBZN++;
    if ((class1 == 0 && class2 == 100) || (class2 == 0 && class1 == 100))
      EBZN_gg++;
    if ((class1 < 21 && class2 < 121) || (class2 < 21 && class1 < 121))
      EBZN_tt++;
    if (class2 < 21 || class1 < 21 || class2 < 121 || class1 < 121)
      EBZN_t0++;
  }
 
 
  if (myBestZ == -1)
    return kContinue;
 
  bool invMassBool = ((mass > minInvMassCut_) && (mass < maxInvMassCut_));
 
  bool selectionBool = false;
  //0 = all electrons (but no crack)
 
 
  float theta1 = 2. * atan(exp(-zeeCandidates[myBestZ].first->getRecoElectron()->superCluster()->eta()));
  bool ET_1 = ((zeeCandidates[myBestZ].first->getRecoElectron()->superCluster()->energy() * sin(theta1)) > 20.);
 
  float theta2 = 2. * atan(exp(-zeeCandidates[myBestZ].second->getRecoElectron()->superCluster()->eta()));
  bool ET_2 = ((zeeCandidates[myBestZ].second->getRecoElectron()->superCluster()->energy() * sin(theta2)) > 20.);
 
  bool HoE_1 = (zeeCandidates[myBestZ].first->getRecoElectron()->hadronicOverEm() < 0.115);
  bool HoE_2 = (zeeCandidates[myBestZ].second->getRecoElectron()->hadronicOverEm() < 0.115);
 
  bool DeltaPhiIn_1 = (zeeCandidates[myBestZ].first->getRecoElectron()->deltaPhiSuperClusterTrackAtVtx() < 0.090);
  bool DeltaPhiIn_2 = (zeeCandidates[myBestZ].second->getRecoElectron()->deltaPhiSuperClusterTrackAtVtx() < 0.090);
 
  bool DeltaEtaIn_1 = (zeeCandidates[myBestZ].first->getRecoElectron()->deltaEtaSuperClusterTrackAtVtx() < 0.0090);
  bool DeltaEtaIn_2 = (zeeCandidates[myBestZ].second->getRecoElectron()->deltaEtaSuperClusterTrackAtVtx() < 0.0090);
 
  h1_eventsBeforeEWKSelection_->Fill(1);
 
  if (!(invMassBool && ET_1 && ET_2 && HoE_1 && HoE_2 && DeltaPhiIn_1 && DeltaPhiIn_2 && DeltaEtaIn_1 && DeltaEtaIn_2))
    return kContinue;
 
  h1_eventsAfterEWKSelection_->Fill(1);
 
 
  int c1st = zeeCandidates[myBestZ].first->getRecoElectron()->classification();
  int c2nd = zeeCandidates[myBestZ].second->getRecoElectron()->classification();
  if (electronSelection_ == 0)
    selectionBool = (myBestZ != -1 && c1st != 40 && c1st != 40 && c2nd != 40 && c2nd != 140);
 
  //1 = all electrons are Golden, BB or Narrow
 
  if (electronSelection_ == 1)
    selectionBool =
        (myBestZ != -1 && (c1st == 0 || c1st == 10 || c1st == 20 || c1st == 100 || c1st == 110 || c1st == 120) &&
         (c2nd == 0 || c2nd == 10 || c2nd == 20 || c2nd == 100 || c2nd == 110 || c2nd == 120));
 
  //2 = all electrons are Golden
  if (electronSelection_ == 2)
    selectionBool = (myBestZ != -1 && (c1st == 0 || c1st == 100) && (c2nd == 0 || c2nd == 100));
  //3 = all electrons are showering
  if (electronSelection_ == 3)
    selectionBool = (myBestZ != -1 && ((c1st >= 30 && c1st <= 34) || ((c1st >= 130 && c1st <= 134))) &&
                     ((c2nd >= 30 && c2nd <= 34) || ((c2nd >= 130 && c2nd <= 134)))
 
    );
 
  //4 = all Barrel electrons are Golden, BB or Narrow; take all Endcap electrons
 
  if (electronSelection_ == 4)
    selectionBool = (myBestZ != -1 && (
 
                                          ((c1st == 0 || c1st == 10 || c1st == 20) && c2nd >= 100 && c2nd != 140)
 
                                          ||
 
                                          ((c2nd == 0 || c2nd == 10 || c2nd == 20) && c1st >= 100 && c1st != 140)
 
                                              ));
 
  //5 = all Endcap electrons (but no crack)
 
  if (electronSelection_ == 5)
    selectionBool = (myBestZ != -1 && c1st >= 100 && c2nd >= 100 && c1st != 140 && c2nd != 140);
 
  //6 = all Barrel electrons (but no crack)
 
  if (electronSelection_ == 6)
    selectionBool = (myBestZ != -1 && c1st < 100 && c2nd < 100 && c1st != 40 && c2nd != 40);
 
  //7 = this eliminates the events which have 1 ele in the Barrel and 1 in the Endcap
 
  if (electronSelection_ == 7)
    selectionBool = (myBestZ != -1 && !(c1st < 100 && c2nd >= 100) && !(c1st >= 100 && c2nd < 100));
 
  float ele1EnergyCorrection(1.);
  float ele2EnergyCorrection(1.);
 
  if (invMassBool && selectionBool && wantEtaCorrection_) {
    ele1EnergyCorrection = getEtaCorrection(zeeCandidates[myBestZ].first->getRecoElectron());
    ele2EnergyCorrection = getEtaCorrection(zeeCandidates[myBestZ].second->getRecoElectron());
  }
 
  if (invMassBool && selectionBool) {
    h1_electronCosTheta_SC_->Fill(
        ZeeKinematicTools::cosThetaElectrons_SC(zeeCandidates[myBestZ], ele1EnergyCorrection, ele2EnergyCorrection));
    h1_electronCosTheta_TK_->Fill(
        ZeeKinematicTools::cosThetaElectrons_TK(zeeCandidates[myBestZ], ele1EnergyCorrection, ele2EnergyCorrection));
    h1_electronCosTheta_SC_TK_->Fill(
        ZeeKinematicTools::cosThetaElectrons_SC(zeeCandidates[myBestZ], ele1EnergyCorrection, ele2EnergyCorrection) /
            ZeeKinematicTools::cosThetaElectrons_TK(
                zeeCandidates[myBestZ], ele1EnergyCorrection, ele2EnergyCorrection) -
        1.);
 
    if (!mcProducer_.empty()) {
      h1_zMassResol_->Fill(mass - myGenZMass);
 
      //reco-mc association map - begin
 
      std::map<HepMC::GenParticle*, const reco::GsfElectron*> myMCmap;
 
      std::vector<const reco::GsfElectron*> dauElectronCollection;
 
      dauElectronCollection.push_back(zeeCandidates[myBestZ].first->getRecoElectron());
      dauElectronCollection.push_back(zeeCandidates[myBestZ].second->getRecoElectron());
 
      fillMCmap(&dauElectronCollection, mcEle, myMCmap);
      fillEleInfo(mcEle, myMCmap);
      //h_DiffZMassDistr_[loopFlag_]->Fill( (mass-myGenZMass) );
    }
 
    //PUT f(eta) IN OUR Zee ALGORITHM
    theAlgorithm_->addEvent(zeeCandidates[myBestZ].first,
                            zeeCandidates[myBestZ].second,
                            MZ * sqrt(ele1EnergyCorrection * ele2EnergyCorrection));
 
    h1_reco_ZMass_->Fill(ZeeKinematicTools::calculateZMass_withTK(zeeCandidates[myBestZ]));
 
    h1_reco_ZMassCorr_->Fill(ZeeKinematicTools::calculateZMassWithCorrectedElectrons_withTK(
        zeeCandidates[myBestZ], ele1EnergyCorrection, ele2EnergyCorrection));
 
    int c1st = zeeCandidates[myBestZ].first->getRecoElectron()->classification();
    int c2nd = zeeCandidates[myBestZ].second->getRecoElectron()->classification();
    if (c1st < 100 && c2nd < 100)
      h1_reco_ZMassCorrBB_->Fill(ZeeKinematicTools::calculateZMassWithCorrectedElectrons_withTK(
          zeeCandidates[myBestZ], ele1EnergyCorrection, ele2EnergyCorrection));
 
    if (c1st >= 100 && c2nd >= 100)
      h1_reco_ZMassCorrEE_->Fill(ZeeKinematicTools::calculateZMassWithCorrectedElectrons_withTK(
          zeeCandidates[myBestZ], ele1EnergyCorrection, ele2EnergyCorrection));
 
    mass4tree = ZeeKinematicTools::calculateZMassWithCorrectedElectrons_withTK(
        zeeCandidates[myBestZ], ele1EnergyCorrection, ele2EnergyCorrection);
 
    massDiff4tree = ZeeKinematicTools::calculateZMassWithCorrectedElectrons_withTK(
                        zeeCandidates[myBestZ], ele1EnergyCorrection, ele2EnergyCorrection) -
                    myGenZMass;
 
    //      h_ZMassDistr_[loopFlag_]->Fill(ZeeKinematicTools::calculateZMassWithCorrectedElectrons_withTK(zeeCandidates[myBestZ],ele1EnergyCorrection,ele2EnergyCorrection));
 
    myTree->Fill();
  }
 
#ifdef DEBUG
  std::cout << "Added event to algorithm" << std::endl;
#endif
 
  return kContinue;
}

References funct::abs(), edm::HLTGlobalStatus::accept(), ZIterativeAlgorithmWithFit::addEvent(), aHLTResults, BARREL_ELECTRONS_AFTER_BORDER_CUT, BARREL_ELECTRONS_BEFORE_BORDER_CUT, barrelfile_, BBZN, BBZN_gg, BBZN_t0, BBZN_tt, bookHistograms(), ZeeKinematicTools::calculateZMass_withTK(), ZeeKinematicTools::calculateZMassWithCorrectedElectrons_withTK(), calibCoeff, calibCoeffError, calibMode_, EcnaPython_AdcPeg12_S1_10_R170298_1_0_150_Dee0::cerr, ALCARECOTkAlJpsiMuMu_cff::charge, ZeeKinematicTools::cosThetaElectrons_SC(), ZeeKinematicTools::cosThetaElectrons_TK(), gather_cfg::cout, CRACK_ELECTRONS_IN_BARREL, CRACK_ELECTRONS_IN_ENDCAP, EBZN, EBZN_gg, EBZN_t0, EBZN_tt, EcalBarrel, EcalEndcap, EEZN, EEZN_gg, EEZN_t0, EEZN_tt, pdwgLeptonRecoSkim_cfi::electronCollection, electronCollection_, electronProducer_, electronSelection_, edm::SortedCollection< T, SORT >::empty(), endcapfile_, erechitCollection_, erechitProducer_, PVValHelper::eta, cppFunctionSkipper::exception, JetChargeProducer_cfi::exp, ZeePlots::fillEleInfo(), fillEleInfo(), ZeePlots::fillEleMCInfo(), ZeePlots::fillHLTInfo(), fillMCmap(), ZeePlots::fillZInfo(), ZeePlots::fillZMCInfo(), EcalCondObjectContainer< T >::find(), dqmdumpme::first, dqmMemoryStats::float, GenParticle::GenParticle, edm::EventSetup::get(), CaloMiscalibMapEcal::get(), get, EcalRingCalibrationTools::getDetIdsInECAL(), EcalRingCalibrationTools::getDetIdsInModule(), EcalRingCalibrationTools::getDetIdsInRing(), getEtaCorrection(), edm::HepMCProduct::GetEvent(), getHottestDetId(), EcalCondObjectContainer< T >::getMap(), ZIterativeAlgorithmWithFit::getNumberOfChannels(), GOLDEN_ELECTRONS_IN_BARREL, GOLDEN_ELECTRONS_IN_ENDCAP, h1_borderElectronClassification_, h1_eleClasses_, h1_electronCosTheta_SC_, h1_electronCosTheta_SC_TK_, h1_electronCosTheta_TK_, h1_eventsAfterBorderSelection_, h1_eventsAfterEWKSelection_, h1_eventsBeforeBorderSelection_, h1_eventsBeforeEWKSelection_, h1_reco_ZMass_, h1_reco_ZMassCorr_, h1_reco_ZMassCorrBB_, h1_reco_ZMassCorrEE_, h1_ZCandMult_, h1_zMassResol_, h2_xtalMiscalibCoeffBarrel_, h2_xtalMiscalibCoeffEndcapMinus_, h2_xtalMiscalibCoeffEndcapPlus_, hfClusterShapes_cfi::hits, hltCount, hlTriggerResults_, mps_fire::i, ical, EBDetId::ieta(), iEvent, init_, initCalibCoeff, EBDetId::iphi(), isfirstcall_, edm::HandleBase::isValid(), EEDetId::ix(), EEDetId::iy(), dqmdumpme::k, edm::EDLooperBase::kContinue, loopFlag_, mass, mass4tree, massDiff4tree, maxInvMassCut_, mcProducer_, MCZBB, MCZEB, MCZEE, minInvMassCut_, myTree, myZeePlots_, MZ, NEVT, outputFile_, AlCaHLTBitMon_ParallelJobs::p, MiscalibReaderFromXML::parseXMLMiscalibFile(), CaloMiscalibMapEcal::prefillMap(), edm::Handle< T >::product(), read_events, rechitCollection_, rechitProducer_, cleanAndMergeSuperClusters_cfi::scCollection, scCollection_, scIslandCollection_, scIslandProducer_, scProducer_, edm::second(), EcalRingCalibrationTools::setCaloGeometry(), SHOWER_ELECTRONS_IN_BARREL, SHOWER_ELECTRONS_IN_ENDCAP, SILVER_ELECTRONS_IN_BARREL, SILVER_ELECTRONS_IN_ENDCAP, funct::sin(), edm::HLTGlobalStatus::size(), mathSSE::sqrt(), DetId::subdetId(), theAlgorithm_, TOTAL_ELECTRONS_IN_BARREL, TOTAL_ELECTRONS_IN_ENDCAP, wantEtaCorrection_, xtalIsOnModuleBorder(), and EEDetId::zside().

endOfJob()

void ZeeCalibration::endOfJob ( )

overridevirtual

Called at end of job.

if not ETA_ET MODE - begin

if not ETA_ET MODE - end

Reimplemented from edm::EDLooperBase.

Definition at line 172 of file ZeeCalibration.cc.

                              {
  printStatistics();
 
  if (calibMode_ != "ETA_ET_MODE") {
 
    //Writing out calibration coefficients
    calibXMLwriter* barrelWriter = new calibXMLwriter(EcalBarrel);
    for (int ieta = -EBDetId::MAX_IETA; ieta <= EBDetId::MAX_IETA; ++ieta) {
      if (ieta == 0)
        continue;
      for (int iphi = EBDetId::MIN_IPHI; iphi <= EBDetId::MAX_IPHI; ++iphi) {
        // make an EBDetId since we need EBDetId::rawId() to be used as the key for the pedestals
        if (EBDetId::validDetId(ieta, iphi)) {
          EBDetId ebid(ieta, iphi);
          barrelWriter->writeLine(ebid, *(ical->getMap().find(ebid.rawId())));
        }
      }
    }
 
    calibXMLwriter* endcapWriter = new calibXMLwriter(EcalEndcap);
    for (int iX = EEDetId::IX_MIN; iX <= EEDetId::IX_MAX; ++iX) {
      for (int iY = EEDetId::IY_MIN; iY <= EEDetId::IY_MAX; ++iY) {
        // make an EEDetId since we need EEDetId::rawId() to be used as the key for the pedestals
        if (EEDetId::validDetId(iX, iY, 1)) {
          EEDetId eeid(iX, iY, 1);
          endcapWriter->writeLine(eeid, *(ical->getMap().find(eeid.rawId())));
        }
        if (EEDetId::validDetId(iX, iY, -1)) {
          EEDetId eeid(iX, iY, -1);
          endcapWriter->writeLine(eeid, *(ical->getMap().find(eeid.rawId())));
        }
      }
    }
 
  }  
 
  std::cout << "Writing  histos..." << std::endl;
  outputFile_->cd();
 
  //  zeeplts->Write();
 
  h1_eventsBeforeEWKSelection_->Write();
  h1_eventsAfterEWKSelection_->Write();
 
  h1_eventsBeforeBorderSelection_->Write();
  h1_eventsAfterBorderSelection_->Write();
 
  h1_borderElectronClassification_->Write();
 
  h2_xtalMiscalibCoeffBarrel_->Write();
  h2_xtalMiscalibCoeffEndcapMinus_->Write();
  h2_xtalMiscalibCoeffEndcapPlus_->Write();
 
  h1_electronCosTheta_SC_->Write();
  h1_electronCosTheta_TK_->Write();
  h1_electronCosTheta_SC_TK_->Write();
 
  h1_zMassResol_->Write();
  h1_zEtaResol_->Write();
  h1_zPhiResol_->Write();
  h1_eleEtaResol_->Write();
  h1_elePhiResol_->Write();
  h1_seedOverSC_->Write();
  h1_preshowerOverSC_->Write();
 
  for (unsigned int i = 0; i < 25; i++) {
    if (i < theMaxLoops) {
      h_ESCEtrueVsEta_[i]->Write();
      h_ESCEtrue_[i]->Write();
 
      h_ESCcorrEtrueVsEta_[i]->Write();
      h_ESCcorrEtrue_[i]->Write();
 
      h2_chi2_[i]->Write();
      h2_iterations_[i]->Write();
 
      //      h_DiffZMassDistr_[i]->Write();
 
      //h_ZMassDistr_[i]->Write();
    }
  }
 
  h2_fEtaBarrelGood_->Write();
  h2_fEtaBarrelBad_->Write();
  h2_fEtaEndcapGood_->Write();
  h2_fEtaEndcapBad_->Write();
  h1_eleClasses_->Write();
 
  h_eleEffEta_[0]->Write();
  h_eleEffPhi_[0]->Write();
  h_eleEffPt_[0]->Write();
 
  h_eleEffEta_[1]->Write();
  h_eleEffPhi_[1]->Write();
  h_eleEffPt_[1]->Write();
 
  int j = 0;
 
  int flag = 0;
 
  Double_t mean[25] = {0.};
  Double_t num[25] = {0.};
  Double_t meanErr[25] = {0.};
  Float_t rms[25] = {0.};
  Float_t tempRms[10][25];
 
  for (int ia = 0; ia < 10; ia++) {
    for (int ib = 0; ib < 25; ib++) {
      tempRms[ia][ib] = 0.;
    }
  }
 
  int aa = 0;
 
  for (int k = 0; k < theAlgorithm_->getNumberOfChannels(); k++) {
    bool isNearCrack = false;
 
    if (calibMode_ == "RING") {
      isNearCrack = (abs(ringNumberCorrector(k)) == 1 || abs(ringNumberCorrector(k)) == 25 ||
                     abs(ringNumberCorrector(k)) == 26 || abs(ringNumberCorrector(k)) == 45 ||
                     abs(ringNumberCorrector(k)) == 46 || abs(ringNumberCorrector(k)) == 65 ||
                     abs(ringNumberCorrector(k)) == 66 || abs(ringNumberCorrector(k)) == 85 ||
                     abs(ringNumberCorrector(k)) == 86 || abs(ringNumberCorrector(k)) == 124);
    }
 
    if (k < 85) {
      if ((k + 1) % 5 != 0) {
        if (!isNearCrack) {
          mean[j] += calibCoeff[k];
          mean[j] += calibCoeff[169 - k];
 
          num[j] += 2.;
 
          //meanErr[j]+= calibCoeffError[k];
          //meanErr[j]+= calibCoeffError[169 - k];
 
          meanErr[j] += 1. / pow(calibCoeffError[k], 2);
          meanErr[j] += 1. / pow(calibCoeffError[169 - k], 2);
 
          tempRms[aa][j] += calibCoeff[k];
          aa++;
          tempRms[aa][j] += calibCoeff[169 - k];
          aa++;
        }
      }
 
      else {
        if (!isNearCrack) {
          mean[j] += calibCoeff[k];
          mean[j] += calibCoeff[169 - k];
 
          num[j] += 2.;
 
          //meanErr[j]+= calibCoeffError[k];
          //meanErr[j]+= calibCoeffError[169 - k];
 
          meanErr[j] += 1. / pow(calibCoeffError[k], 2);
          meanErr[j] += 1. / pow(calibCoeffError[169 - k], 2);
 
          tempRms[aa][j] += calibCoeff[k];
          aa++;
          tempRms[aa][j] += calibCoeff[169 - k];
          aa++;
        }
        j++;
        aa = 0;
      }
    }
    //EE begin
 
    if (k >= 170 && k <= 204) {
      if (flag < 4) {
        //make groups of 5 Xtals in #eta
        mean[j] += calibCoeff[k] / 10.;
        mean[j] += calibCoeff[k + 39] / 10.;
 
        meanErr[j] += calibCoeffError[k] / 30.;
        meanErr[j] += calibCoeffError[k + 39] / 30.;
 
        tempRms[aa][j] += calibCoeff[k];
        aa++;
        tempRms[aa][j] += calibCoeff[k + 39];
        aa++;
 
        flag++;
      }
 
      else if (flag == 4) {
        //make groups of 5 Xtals in #eta
        mean[j] += calibCoeff[k] / 10.;
        mean[j] += calibCoeff[k + 39] / 10.;
 
        meanErr[j] += calibCoeffError[k] / 30.;
        meanErr[j] += calibCoeffError[k + 39] / 30.;
 
        tempRms[aa][j] += calibCoeff[k];
        aa++;
        tempRms[aa][j] += calibCoeff[k + 39];
        aa++;
 
        flag = 0;
        //    std::cout<<" index(>85) "<<k<<" j is "<<j<<" mean[j] is "<<mean[j]<<std::endl;
        j++;
        aa = 0;
      }
    }
    if (k >= 205 && k <= 208) {
      mean[j] += calibCoeff[k] / 8.;
      mean[j] += calibCoeff[k + 39] / 8.;
 
      meanErr[j] += calibCoeffError[k] / 30.;
      meanErr[j] += calibCoeffError[k + 39] / 30.;
 
      tempRms[aa][j] += calibCoeff[k];
      aa++;
      tempRms[aa][j] += calibCoeff[k + 39];
      aa++;
    }
    //EE end
 
    /*
      for(int jj =0; jj< 25; jj++){ 
      if(meanErr[jj] > 0.)
    std::cout<<" meanErr[jj] before sqrt: "<<meanErr[jj]<<std::endl;
 
    meanErr[jj] = 1./sqrt( meanErr[jj] );
 
    std::cout<<" meanErr[jj] after sqrt: "<<meanErr[jj]<<std::endl;
      }
      */
 
    if (!isNearCrack) {
      h2_coeffVsEta_->Fill(ringNumberCorrector(k), calibCoeff[k]);
      h2_miscalRecal_->Fill(initCalibCoeff[k], 1. / calibCoeff[k]);
      h1_mc_->Fill(initCalibCoeff[k] * calibCoeff[k] - 1.);
 
      if (k < 170) {
        h2_miscalRecalEB_->Fill(initCalibCoeff[k], 1. / calibCoeff[k]);
        h1_mcEB_->Fill(initCalibCoeff[k] * calibCoeff[k] - 1.);
      }
 
      if (k >= 170) {
        h2_miscalRecalEE_->Fill(initCalibCoeff[k], 1. / calibCoeff[k]);
        h1_mcEE_->Fill(initCalibCoeff[k] * calibCoeff[k] - 1.);
      }
    }
  }
 
  for (int ic = 0; ic < 17; ic++) {
    mean[ic] = mean[ic] / num[ic];  //find mean of recalib coeff on group of rings
    //meanErr[ic] = meanErr[ic] / ( sqrt( num[ic] ) * num[ic] ); //find mean of recalib coeff on group of rings
    meanErr[ic] = 1. / sqrt(meanErr[ic]);  //find mean of recalib coeff on group of rings
  }
 
  //build array of RMS
  for (int ic = 0; ic < 25; ic++) {
    for (int id = 0; id < 10; id++) {
      if (tempRms[id][ic] > 0.) {
        rms[ic] += (tempRms[id][ic] - mean[j]) * (tempRms[id][ic] - mean[j]);
      }
    }
    rms[ic] /= 10.;  //this is approximate
    rms[ic] = sqrt(rms[ic]);
  }
 
  //build array of RMS
 
  Double_t xtalEta[25] = {1.4425, 1.3567, 1.2711, 1.1855, 1.10,   1.01,   0.92,   0.83,   0.7468,
                          0.6612, 0.5756, 0.4897, 0.3985, 0.3117, 0.2250, 0.1384, 0.0487, 1.546,
                          1.651,  1.771,  1.908,  2.071,  2.267,  2.516,  2.8};
 
  Double_t zero[25] = {0.026};  //interval/sqrt(12)
 
  for (int j = 0; j < 25; j++)
    h2_coeffVsEtaGrouped_->Fill(xtalEta[j], mean[j]);
 
  //  for(int sho = 0; sho <25; sho++)
  //cout<<"xtalEta[j] "<< xtalEta[sho]<<" mean[j]  "<<mean[sho]<<"  err[j] "<<meanErr[sho]<<std::endl;
 
  TProfile* px = h2_coeffVsEta_->ProfileX("coeffVsEtaProfile");
  px->SetXTitle("Eta channel");
  px->SetYTitle("recalibCoeff");
  px->Write();
 
  h2_coeffVsEta_->Write();
  h2_coeffVsEtaGrouped_->Write();
  h2_zMassVsLoop_->Write();
  h2_zMassDiffVsLoop_->Write();
  h2_zWidthVsLoop_->Write();
  h2_coeffVsLoop_->Write();
  h2_miscalRecal_->Write();
  h1_mc_->Write();
  h2_miscalRecalEB_->Write();
  h1_mcEB_->Write();
  h2_miscalRecalEE_->Write();
  h1_mcEE_->Write();
 
  h2_residualSigma_->Write();
 
  const ZIterativeAlgorithmWithFit::ZIterativeAlgorithmWithFitPlots* algoHistos = theAlgorithm_->getHistos();
 
  double weightSumMeanBarrel = 0.;
  double weightSumMeanEndcap = 0.;
 
  for (int iIteration = 0; iIteration < theAlgorithm_->getNumberOfIterations(); iIteration++)
    for (int iChannel = 0; iChannel < theAlgorithm_->getNumberOfChannels(); iChannel++) {
      if (iIteration == (theAlgorithm_->getNumberOfIterations() - 1)) {
        if (iChannel < 170)
          weightSumMeanBarrel += algoHistos->weightedRescaleFactor[iIteration][iChannel]->Integral() / 170.;
 
        if (iChannel >= 170)
          weightSumMeanEndcap += algoHistos->weightedRescaleFactor[iIteration][iChannel]->Integral() / 78.;
 
        h1_occupancyVsEta_->Fill((Double_t)ringNumberCorrector(iChannel),
                                 algoHistos->weightedRescaleFactor[iIteration][iChannel]->Integral());
 
        h1_occupancy_->Fill(algoHistos->weightedRescaleFactor[iIteration][iChannel]->Integral());
 
        if (iChannel < 170)
          h1_occupancyBarrel_->Fill(algoHistos->weightedRescaleFactor[iIteration][iChannel]->Integral());
 
        if (iChannel >= 170)
          h1_occupancyEndcap_->Fill(algoHistos->weightedRescaleFactor[iIteration][iChannel]->Integral());
 
#ifdef DEBUG
        std::cout << "Writing weighted integral for channel " << ringNumberCorrector(iChannel) << " ,value "
                  << algoHistos->weightedRescaleFactor[iIteration][iChannel]->Integral() << std::endl;
#endif
      }
    }
 
  //  std::cout<<"Done! Closing output file... "<<std::endl;
 
  h1_weightSumMeanBarrel_->Fill(weightSumMeanBarrel);
  h1_weightSumMeanEndcap_->Fill(weightSumMeanEndcap);
 
  std::cout << "Weight sum mean on channels in Barrel is :" << weightSumMeanBarrel << std::endl;
  std::cout << "Weight sum mean on channels in Endcap is :" << weightSumMeanEndcap << std::endl;
 
  h1_weightSumMeanBarrel_->Write();
  h1_weightSumMeanEndcap_->Write();
 
  h1_occupancyVsEta_->Write();
  h1_occupancy_->Write();
  h1_occupancyBarrel_->Write();
  h1_occupancyEndcap_->Write();
 
  myTree->Write();
 
  TGraphErrors* graph = new TGraphErrors(25, xtalEta, mean, zero, meanErr);
  graph->Draw("APL");
  graph->Write();
 
  double zero50[50] = {0.};
 
  TGraphErrors* residualSigmaGraph = new TGraphErrors(50, loopArray, sigmaArray, zero50, sigmaErrorArray);
  residualSigmaGraph->SetName("residualSigmaGraph");
  residualSigmaGraph->Draw("APL");
  residualSigmaGraph->Write();
 
  TGraphErrors* coefficientDistanceAtIterationGraph =
      new TGraphErrors(50, loopArray, coefficientDistanceAtIteration, zero50, zero50);
  coefficientDistanceAtIterationGraph->SetName("coefficientDistanceAtIterationGraph");
  coefficientDistanceAtIterationGraph->Draw("APL");
  coefficientDistanceAtIterationGraph->Write();
 
  Float_t noError[250] = {0.};
 
  Float_t ringInd[250];
  for (int i = 0; i < 250; i++)
    ringInd[i] = ringNumberCorrector(i);
 
  TGraphErrors* graphCoeff =
      new TGraphErrors(theAlgorithm_->getNumberOfChannels(), ringInd, calibCoeff, noError, calibCoeffError);
  graphCoeff->SetName("graphCoeff");
  graphCoeff->Draw("APL");
  graphCoeff->Write();
 
  //   outputFile_->Write();//this automatically writes all histos on file
 
  h1_ZCandMult_->Write();
  h1_reco_ZMass_->Write();
 
  h1_reco_ZMassCorr_->Write();
  h1_reco_ZMassCorrBB_->Write();
  h1_reco_ZMassCorrEE_->Write();
 
  outputFile_->Close();
 
  myZeePlots_->writeEleHistograms();
  myZeePlots_->writeMCEleHistograms();
  myZeePlots_->writeZHistograms();
  myZeePlots_->writeMCZHistograms();
 
  // myZeeRescaleFactorPlots_ = new ZeeRescaleFactorPlots("zeeRescaleFactorPlots.root");
  //myZeeRescaleFactorPlots_->writeHistograms( theAlgorithm_ );
 
  //  delete myZeeRescaleFactorPlots_;
}

References funct::abs(), calibCoeff, calibCoeffError, calibMode_, coefficientDistanceAtIteration, gather_cfg::cout, EcalBarrel, EcalEndcap, RemoveAddSevLevel::flag, ZIterativeAlgorithmWithFit::getHistos(), ZIterativeAlgorithmWithFit::getNumberOfChannels(), ZIterativeAlgorithmWithFit::getNumberOfIterations(), h1_borderElectronClassification_, h1_eleClasses_, h1_electronCosTheta_SC_, h1_electronCosTheta_SC_TK_, h1_electronCosTheta_TK_, h1_eleEtaResol_, h1_elePhiResol_, h1_eventsAfterBorderSelection_, h1_eventsAfterEWKSelection_, h1_eventsBeforeBorderSelection_, h1_eventsBeforeEWKSelection_, h1_mc_, h1_mcEB_, h1_mcEE_, h1_occupancy_, h1_occupancyBarrel_, h1_occupancyEndcap_, h1_occupancyVsEta_, h1_preshowerOverSC_, h1_reco_ZMass_, h1_reco_ZMassCorr_, h1_reco_ZMassCorrBB_, h1_reco_ZMassCorrEE_, h1_seedOverSC_, h1_weightSumMeanBarrel_, h1_weightSumMeanEndcap_, h1_ZCandMult_, h1_zEtaResol_, h1_zMassResol_, h1_zPhiResol_, h2_chi2_, h2_coeffVsEta_, h2_coeffVsEtaGrouped_, h2_coeffVsLoop_, h2_fEtaBarrelBad_, h2_fEtaBarrelGood_, h2_fEtaEndcapBad_, h2_fEtaEndcapGood_, h2_iterations_, h2_miscalRecal_, h2_miscalRecalEB_, h2_miscalRecalEE_, h2_residualSigma_, h2_xtalMiscalibCoeffBarrel_, h2_xtalMiscalibCoeffEndcapMinus_, h2_xtalMiscalibCoeffEndcapPlus_, h2_zMassDiffVsLoop_, h2_zMassVsLoop_, h2_zWidthVsLoop_, h_eleEffEta_, h_eleEffPhi_, h_eleEffPt_, h_ESCcorrEtrue_, h_ESCcorrEtrueVsEta_, h_ESCEtrue_, h_ESCEtrueVsEta_, mps_fire::i, cuy::ib, ical, triggerObjects_cff::id, LEDCalibrationChannels::ieta, initCalibCoeff, LEDCalibrationChannels::iphi, EEDetId::IX_MAX, EEDetId::IX_MIN, EEDetId::IY_MAX, EEDetId::IY_MIN, dqmiolumiharvest::j, dqmdumpme::k, loopArray, EBDetId::MAX_IETA, EBDetId::MAX_IPHI, SiStripPI::mean, EBDetId::MIN_IPHI, myTree, myZeePlots_, EgammaValidation_cff::num, outputFile_, funct::pow(), printStatistics(), multPhiCorr_741_25nsDY_cfi::px, DetId::rawId(), ringNumberCorrector(), SiStripPI::rms, sigmaArray, sigmaErrorArray, mathSSE::sqrt(), theAlgorithm_, theMaxLoops, EBDetId::validDetId(), EEDetId::validDetId(), ZIterativeAlgorithmWithFit::ZIterativeAlgorithmWithFitPlots::weightedRescaleFactor, ZeePlots::writeEleHistograms(), calibXMLwriter::writeLine(), ZeePlots::writeMCEleHistograms(), ZeePlots::writeMCZHistograms(), ZeePlots::writeZHistograms(), and SiPixelPI::zero.

endOfLoop()

edm::EDLooper::Status ZeeCalibration::endOfLoop ( const edm::EventSetup &  iSetup, unsigned int  iLoop  )

overridevirtual

Called at end of loop.

Implements edm::EDLooperBase.

Definition at line 1328 of file ZeeCalibration.cc.

                                                                                           {
  double par[3];
  double errpar[3];
  double zChi2;
  int zIters;
 
  ZIterativeAlgorithmWithFit::gausfit(h1_reco_ZMass_, par, errpar, 2., 2., &zChi2, &zIters);
 
  h2_zMassVsLoop_->Fill(loopFlag_, par[1]);
 
  h2_zMassDiffVsLoop_->Fill(loopFlag_, (par[1] - MZ) / MZ);
 
  h2_zWidthVsLoop_->Fill(loopFlag_, par[2]);
 
 
  std::cout << "[ZeeCalibration] Ending loop " << iLoop << std::endl;
  //RUN the algorithm
  theAlgorithm_->iterate();
 
  const std::vector<float>& optimizedCoefficients = theAlgorithm_->getOptimizedCoefficients();
  const std::vector<float>& optimizedCoefficientsError = theAlgorithm_->getOptimizedCoefficientsError();
  //const std::vector<float>& weightSum = theAlgorithm_->getWeightSum();
  const std::vector<float>& optimizedChi2 = theAlgorithm_->getOptimizedChiSquare();
  const std::vector<int>& optimizedIterations = theAlgorithm_->getOptimizedIterations();
 
  //#ifdef DEBUG
  std::cout << "Optimized coefficients " << optimizedCoefficients.size() << std::endl;
  //#endif
 
  //  h2_coeffVsLoop_->Fill(loopFlag_, optimizedCoefficients[75]); //show the evolution of just 1 ring coefficient (well chosen...)
 
  for (unsigned int ieta = 0; ieta < optimizedCoefficients.size(); ieta++) {
    NewCalibCoeff[ieta] = calibCoeff[ieta] * optimizedCoefficients[ieta];
 
    h2_chi2_[loopFlag_]->Fill(ringNumberCorrector(ieta), optimizedChi2[ieta]);
    h2_iterations_[loopFlag_]->Fill(ringNumberCorrector(ieta), optimizedIterations[ieta]);
  }
 
  coefficientDistanceAtIteration[loopFlag_] =
      computeCoefficientDistanceAtIteration(calibCoeff, NewCalibCoeff, optimizedCoefficients.size());
 
  std::cout << "Iteration # : " << loopFlag_ << " CoefficientDistanceAtIteration "
            << coefficientDistanceAtIteration[loopFlag_] << std::endl;
  std::cout << "size " << optimizedCoefficients.size() << std::endl;
 
  for (unsigned int ieta = 0; ieta < optimizedCoefficients.size(); ieta++) {
    calibCoeff[ieta] *= optimizedCoefficients[ieta];
    calibCoeffError[ieta] =
        calibCoeff[ieta] * sqrt(pow(optimizedCoefficientsError[ieta] / optimizedCoefficients[ieta], 2) +
                                pow(calibCoeffError[ieta] / calibCoeff[ieta], 2));
    //calibCoeffError[ieta] = optimizedCoefficientsError[ieta];
 
#ifdef DEBUG
    std::cout << ieta << " " << optimizedCoefficients[ieta] << std::endl;
#endif
 
    std::vector<DetId> ringIds;
 
    if (calibMode_ == "RING")
      ringIds = EcalRingCalibrationTools::getDetIdsInRing(ieta);
 
    if (calibMode_ == "MODULE")
      ringIds = EcalRingCalibrationTools::getDetIdsInModule(ieta);
 
    if (calibMode_ == "ABS_SCALE" || calibMode_ == "ETA_ET_MODE")
      ringIds = EcalRingCalibrationTools::getDetIdsInECAL();
 
    for (unsigned int iid = 0; iid < ringIds.size(); ++iid) {
      if (ringIds[iid].subdetId() == EcalBarrel) {
        EBDetId myEBDetId(ringIds[iid]);
        h2_xtalRecalibCoeffBarrel_[loopFlag_]->SetBinContent(
            myEBDetId.ieta() + 86,
            myEBDetId.iphi(),
            100 * (calibCoeff[ieta] * initCalibCoeff[ieta] - 1.));  //fill TH2 with recalibCoeff
      }
 
      if (ringIds[iid].subdetId() == EcalEndcap) {
        EEDetId myEEDetId(ringIds[iid]);
        if (myEEDetId.zside() < 0)
          h2_xtalRecalibCoeffEndcapMinus_[loopFlag_]->SetBinContent(
              myEEDetId.ix(),
              myEEDetId.iy(),
              100 * (calibCoeff[ieta] * initCalibCoeff[ieta] - 1.));  //fill TH2 with recalibCoeff
 
        if (myEEDetId.zside() > 0)
          h2_xtalRecalibCoeffEndcapPlus_[loopFlag_]->SetBinContent(
              myEEDetId.ix(),
              myEEDetId.iy(),
              100 * (calibCoeff[ieta] * initCalibCoeff[ieta] - 1.));  //fill TH2 with recalibCoeff
      }
 
      ical->setValue(ringIds[iid], *(ical->getMap().find(ringIds[iid])) * optimizedCoefficients[ieta]);
    }
  }
 
 
  for (int k = 0; k < theAlgorithm_->getNumberOfChannels(); k++) {
    bool isNearCrack =
        (abs(ringNumberCorrector(k)) == 1 || abs(ringNumberCorrector(k)) == 25 || abs(ringNumberCorrector(k)) == 26 ||
         abs(ringNumberCorrector(k)) == 45 || abs(ringNumberCorrector(k)) == 46 || abs(ringNumberCorrector(k)) == 65 ||
         abs(ringNumberCorrector(k)) == 66 || abs(ringNumberCorrector(k)) == 85 || abs(ringNumberCorrector(k)) == 86 ||
         abs(ringNumberCorrector(k)) == 124);
 
    if (!isNearCrack) {
      //    h2_miscalRecalParz_[iLoop]->Fill( initCalibCoeff[k], 1./calibCoeff[k] );
      h1_mcParz_[iLoop]->Fill(initCalibCoeff[k] * calibCoeff[k] - 1.);
 
      if (k < 170) {
        //h2_miscalRecalEBParz_[iLoop]->Fill( initCalibCoeff[k], 1./calibCoeff[k] );
        h1_mcEBParz_[iLoop]->Fill(initCalibCoeff[k] * calibCoeff[k] - 1.);
      }
 
      if (k >= 170) {
        //h2_miscalRecalEEParz_[iLoop]->Fill( initCalibCoeff[k], 1./calibCoeff[k] );
        h1_mcEEParz_[iLoop]->Fill(initCalibCoeff[k] * calibCoeff[k] - 1.);
      }
    }
  }
 
  double parResidual[3];
  double errparResidual[3];
  double zResChi2;
  int zResIters;
 
  ZIterativeAlgorithmWithFit::gausfit(h1_mcParz_[iLoop], parResidual, errparResidual, 3., 3., &zResChi2, &zResIters);
  //h1_mcParz_[iLoop]->Fit("gaus");
 
  h2_residualSigma_->Fill(loopFlag_ + 1, parResidual[2]);
  loopArray[loopFlag_] = loopFlag_ + 1;
  sigmaArray[loopFlag_] = parResidual[2];
  sigmaErrorArray[loopFlag_] = errparResidual[2];
 
  std::cout << "Fit on residuals, sigma is " << parResidual[2] << " +/- " << errparResidual[2] << std::endl;
 
  outputFile_->cd();
 
  //  h2_miscalRecalParz_[iLoop]->Write();
  h1_mcParz_[iLoop]->Write();
 
  //h2_miscalRecalEBParz_[iLoop]->Write();
  h1_mcEBParz_[iLoop]->Write();
 
  //h2_miscalRecalEEParz_[iLoop]->Write();
  h1_mcEEParz_[iLoop]->Write();
  h2_xtalRecalibCoeffBarrel_[loopFlag_]->Write();
  h2_xtalRecalibCoeffEndcapPlus_[loopFlag_]->Write();
  h2_xtalRecalibCoeffEndcapMinus_[loopFlag_]->Write();
 
 
  loopFlag_++;
 
#ifdef DEBUG
  std::cout << " loopFlag_ is " << loopFlag_ << std::endl;
#endif
 
  if (iLoop == theMaxLoops - 1 || iLoop >= theMaxLoops)
    return kStop;
  else
    return kContinue;
}

References funct::abs(), calibCoeff, calibCoeffError, calibMode_, coefficientDistanceAtIteration, computeCoefficientDistanceAtIteration(), gather_cfg::cout, EcalBarrel, EcalEndcap, ZIterativeAlgorithmWithFit::gausfit(), EcalRingCalibrationTools::getDetIdsInECAL(), EcalRingCalibrationTools::getDetIdsInModule(), EcalRingCalibrationTools::getDetIdsInRing(), ZIterativeAlgorithmWithFit::getNumberOfChannels(), ZIterativeAlgorithmWithFit::getOptimizedChiSquare(), ZIterativeAlgorithmWithFit::getOptimizedCoefficients(), ZIterativeAlgorithmWithFit::getOptimizedCoefficientsError(), ZIterativeAlgorithmWithFit::getOptimizedIterations(), h1_mcEBParz_, h1_mcEEParz_, h1_mcParz_, h1_reco_ZMass_, h2_chi2_, h2_iterations_, h2_residualSigma_, h2_xtalRecalibCoeffBarrel_, h2_xtalRecalibCoeffEndcapMinus_, h2_xtalRecalibCoeffEndcapPlus_, h2_zMassDiffVsLoop_, h2_zMassVsLoop_, h2_zWidthVsLoop_, ical, EBDetId::ieta(), LEDCalibrationChannels::ieta, initCalibCoeff, EBDetId::iphi(), ZIterativeAlgorithmWithFit::iterate(), EEDetId::ix(), EEDetId::iy(), dqmdumpme::k, edm::EDLooperBase::kContinue, edm::EDLooperBase::kStop, loopArray, loopFlag_, MZ, NewCalibCoeff, outputFile_, funct::pow(), ringNumberCorrector(), sigmaArray, sigmaErrorArray, mathSSE::sqrt(), theAlgorithm_, theMaxLoops, and EEDetId::zside().

EvalDPhi()

float ZeeCalibration::EvalDPhi ( float  Phi, float  Phi_ref  )

private

Definition at line 1852 of file ZeeCalibration.cc.

                                                       {
  if (Phi < 0)
    Phi = 2 * TMath::Pi() + Phi;
  if (Phi_ref < 0)
    Phi_ref = 2 * TMath::Pi() + Phi_ref;
  return (Phi - Phi_ref);
}

References VtxSmearedParameters_cfi::Phi, and Pi.

EvalDR()

float ZeeCalibration::EvalDR ( float  Eta, float  Eta_ref, float  Phi, float  Phi_ref  )

private

Definition at line 1837 of file ZeeCalibration.cc.

                                                                               {
  if (Phi < 0)
    Phi = 2 * TMath::Pi() + Phi;
  if (Phi_ref < 0)
    Phi_ref = 2 * TMath::Pi() + Phi_ref;
  float DPhi = Phi - Phi_ref;
  if (fabs(DPhi) > TMath::Pi())
    DPhi = 2 * TMath::Pi() - fabs(DPhi);
 
  float DEta = Eta - Eta_ref;
 
  float DR = sqrt(DEta * DEta + DPhi * DPhi);
  return DR;
}

References mitigatedMETSequence_cff::DPhi, VtxSmearedParameters_cfi::Phi, Pi, and mathSSE::sqrt().

Referenced by fillMCmap().

fEtaBarrelBad()

double ZeeCalibration::fEtaBarrelBad ( double  scEta ) const

private

Definition at line 1773 of file ZeeCalibration.cc.

                                                       {
  float p0 = 1.00153e+00;
  float p1 = 3.29331e-02;
  float p2 = 1.21187e-03;
 
  double x = (double)fabs(scEta);
 
  return 1. / (p0 + p1 * x * x + p2 * x * x * x * x);
}

References p1, p2, and x.

Referenced by getEtaCorrection().

fEtaBarrelGood()

double ZeeCalibration::fEtaBarrelGood ( double  scEta ) const

private

Definition at line 1805 of file ZeeCalibration.cc.

                                                        {
  float p0 = 9.99782e-01;
  float p1 = 1.26983e-02;
  float p2 = 2.16344e-03;
 
  double x = (double)fabs(scEta);
 
  return 1. / (p0 + p1 * x * x + p2 * x * x * x * x);
}

References p1, p2, and x.

Referenced by getEtaCorrection().

fEtaEndcapBad()

double ZeeCalibration::fEtaEndcapBad ( double  scEta ) const

private

Definition at line 1795 of file ZeeCalibration.cc.

                                                       {
  float p0 = 1.17382e+00;
  float p1 = -6.52319e-02;
  float p2 = 6.26108e-03;
 
  double x = (double)fabs(scEta);
 
  return 1. / (p0 + p1 * x * x + p2 * x * x * x * x);
}

References p1, p2, and x.

Referenced by getEtaCorrection().

fEtaEndcapGood()

double ZeeCalibration::fEtaEndcapGood ( double  scEta ) const

private

Definition at line 1783 of file ZeeCalibration.cc.

                                                        {
  // f(eta) for the first 3 classes (100, 110 and 120)
  // Ivica's new corrections 01/06
  float p0 = 1.06819e+00;
  float p1 = -1.53189e-02;
  float p2 = 4.01707e-04;
 
  double x = (double)fabs(scEta);
 
  return 1. / (p0 + p1 * x * x + p2 * x * x * x * x);
}

References p1, p2, and x.

Referenced by getEtaCorrection().

fillEleInfo()

void ZeeCalibration::fillEleInfo ( std::vector< HepMC::GenParticle * > &  a, std::map< HepMC::GenParticle *, const reco::GsfElectron * > &  b  )

private

Definition at line 1860 of file ZeeCalibration.cc.

                                                                                                    {
  for (unsigned int i = 0; i < mcEle.size(); i++) {
    h_eleEffEta_[0]->Fill(fabs(mcEle[i]->momentum().pseudoRapidity()));
    h_eleEffPhi_[0]->Fill(mcEle[i]->momentum().phi());
    h_eleEffPt_[0]->Fill(mcEle[i]->momentum().perp());
 
    std::map<HepMC::GenParticle*, const reco::GsfElectron*>::const_iterator mIter = associationMap.find(mcEle[i]);
    if (mIter == associationMap.end())
      continue;
 
    if ((*mIter).second) {
      const reco::GsfElectron* myEle = (*mIter).second;
 
      h_eleEffEta_[1]->Fill(fabs(mcEle[i]->momentum().pseudoRapidity()));
      h_eleEffPhi_[1]->Fill(mcEle[i]->momentum().phi());
      h_eleEffPt_[1]->Fill(mcEle[i]->momentum().perp());
      h1_eleEtaResol_->Fill(myEle->eta() - mcEle[i]->momentum().eta());
      h1_elePhiResol_->Fill(myEle->phi() - mcEle[i]->momentum().phi());
 
      const reco::SuperCluster* mySC = &(*(myEle->superCluster()));
      if (/*fabs(mySC->position().eta()) < 2.4*/ true) {
        //      if(myEle->classification()>=100)std::cout<<"mySC->preshowerEnergy()"<<mySC->preshowerEnergy()<<std::endl;
 
        h_ESCEtrue_[loopFlag_]->Fill(mySC->energy() / mcEle[i]->momentum().e());
        h_ESCEtrueVsEta_[loopFlag_]->Fill(fabs(mySC->position().eta()), mySC->energy() / mcEle[i]->momentum().e());
 
        double corrSCenergy = (mySC->energy()) / getEtaCorrection(myEle);
        h_ESCcorrEtrue_[loopFlag_]->Fill(corrSCenergy / mcEle[i]->momentum().e());
        h_ESCcorrEtrueVsEta_[loopFlag_]->Fill(fabs(mySC->position().eta()), corrSCenergy / mcEle[i]->momentum().e());
 
        //        std::vector<DetId> mySCRecHits = mySC->seed()->getHitsByDetId();
 
        h1_seedOverSC_->Fill(mySC->seed()->energy() / mySC->energy());
        h1_preshowerOverSC_->Fill(mySC->preshowerEnergy() / mySC->energy());
      }
    }
  }
}

References MillePedeFileConverter_cfg::e, reco::CaloCluster::energy(), reco::LeafCandidate::eta(), getEtaCorrection(), h1_eleEtaResol_, h1_elePhiResol_, h1_preshowerOverSC_, h1_seedOverSC_, h_eleEffEta_, h_eleEffPhi_, h_eleEffPt_, h_ESCcorrEtrue_, h_ESCcorrEtrueVsEta_, h_ESCEtrue_, h_ESCEtrueVsEta_, mps_fire::i, loopFlag_, perp(), phi, reco::LeafCandidate::phi(), reco::CaloCluster::position(), reco::SuperCluster::preshowerEnergy(), reco::SuperCluster::seed(), and reco::GsfElectron::superCluster().

Referenced by duringLoop().

fillMCInfo()

void ZeeCalibration::fillMCInfo ( HepMC::GenParticle *  mcele )

private

fillMCmap()

void ZeeCalibration::fillMCmap ( const std::vector< const reco::GsfElectron * > *  electronCollection, const std::vector< HepMC::GenParticle * > &  mcEle, std::map< HepMC::GenParticle *, const reco::GsfElectron * > &  myMCmap  )

private

Definition at line 1817 of file ZeeCalibration.cc.

                                                                                           {
  for (unsigned int i = 0; i < mcEle.size(); i++) {
    float minDR = 0.1;
    const reco::GsfElectron* myMatchEle = nullptr;
    for (unsigned int j = 0; j < electronCollection->size(); j++) {
      float dr = EvalDR(mcEle[i]->momentum().pseudoRapidity(),
                        (*(*electronCollection)[j]).eta(),
                        mcEle[i]->momentum().phi(),
                        (*(*electronCollection)[j]).phi());
      if (dr < minDR) {
        myMatchEle = (*electronCollection)[j];
        minDR = dr;
      }
    }
    myMCmap.insert(std::pair<HepMC::GenParticle*, const reco::GsfElectron*>(mcEle[i], myMatchEle));
  }
}

References flavorHistoryFilter_cfi::dr, pdwgLeptonRecoSkim_cfi::electronCollection, PVValHelper::eta, EvalDR(), mps_fire::i, dqmiolumiharvest::j, PDWG_EXOHSCP_cff::minDR, and phi.

Referenced by duringLoop().

getEtaCorrection()

double ZeeCalibration::getEtaCorrection ( const reco::GsfElectron *  ele )

private

Definition at line 1928 of file ZeeCalibration.cc.

                                                                  {
  double correction(1.);
 
  int c = ele->classification();
  if (c == 0 || c == 10 || c == 20)
    correction = fEtaBarrelGood(ele->superCluster()->eta());
 
  if (c == 100 || c == 110 || c == 120)
    correction = fEtaEndcapGood(ele->superCluster()->eta());
 
  if (c == 30 || c == 31 || c == 32 || c == 33 || c == 34)
    correction = fEtaBarrelBad(ele->superCluster()->eta());
 
  if (c == 130 || c == 131 || c == 132 || c == 133 || c == 134)
    correction = fEtaEndcapBad(ele->superCluster()->eta());
 
  return correction;
}

References HltBtagPostValidation_cff::c, reco::GsfElectron::classification(), pfMETCorrectionType0_cfi::correction, fEtaBarrelBad(), fEtaBarrelGood(), fEtaEndcapBad(), fEtaEndcapGood(), and reco::GsfElectron::superCluster().

Referenced by duringLoop(), and fillEleInfo().

getHottestDetId()

std::pair< DetId, double > ZeeCalibration::getHottestDetId ( const std::vector< std::pair< DetId, float > > &  mySCRecHits, const EBRecHitCollection *  ebhits, const EERecHitCollection *  eehits  )

private

Definition at line 1947 of file ZeeCalibration.cc.

                                                                                           {
  double maxEnergy = -9999.;
  const EcalRecHit* hottestRecHit = nullptr;
 
  std::pair<DetId, double> myPair(DetId(0), -9999.);
 
  for (std::vector<std::pair<DetId, float> >::const_iterator idIt = mySCRecHits.begin(); idIt != mySCRecHits.end();
       idIt++) {
    if (idIt->first.subdetId() == EcalBarrel) {
      hottestRecHit = &(*(ebhits->find((*idIt).first)));
 
      if (hottestRecHit == &(*(ebhits->end()))) {
        std::cout << "@@@@@@@@@@@@@@@@@@@@@@@@@@@ NO RECHIT FOUND SHOULD NEVER HAPPEN" << std::endl;
        continue;
      }
    } else if (idIt->first.subdetId() == EcalEndcap) {
      hottestRecHit = &(*(eehits->find((*idIt).first)));
      if (hottestRecHit == &(*(eehits->end()))) {
        std::cout << "@@@@@@@@@@@@@@@@@@@@@@@@@@@ NO RECHIT FOUND SHOULD NEVER HAPPEN" << std::endl;
        continue;
      }
    }
 
    //std::cout<<"[getHottestDetId] hottestRecHit->energy() "<<hottestRecHit->energy()<<std::endl;
 
    if (hottestRecHit && hottestRecHit->energy() > maxEnergy) {
      maxEnergy = hottestRecHit->energy();
 
      myPair.first = hottestRecHit->id();
      myPair.second = maxEnergy;
    }
 
  }  //end loop to find hottest RecHit
 
  //std::cout<<"[ZeeCalibration::getHottestDetId] going to return..."<<std::endl;
 
  return myPair;
}

References gather_cfg::cout, EcalBarrel, EcalEndcap, edm::SortedCollection< T, SORT >::end(), EcalRecHit::energy(), edm::SortedCollection< T, SORT >::find(), EcalRecHit::id(), particleFlowClusterECALTimeSelected_cfi::maxEnergy, and trackerHitRTTI::vector.

Referenced by duringLoop().

printStatistics()

void ZeeCalibration::printStatistics ( )

private

Definition at line 2111 of file ZeeCalibration.cc.

                                     {
  std::cout << "[ CHECK ON BARREL ELECTRON NUMBER ]"
            << " first " << BARREL_ELECTRONS_BEFORE_BORDER_CUT << " second " << TOTAL_ELECTRONS_IN_BARREL << std::endl;
 
  std::cout << "[ EFFICIENCY OF THE BORDER SELECTION ]"
            << (float)BARREL_ELECTRONS_AFTER_BORDER_CUT / (float)BARREL_ELECTRONS_BEFORE_BORDER_CUT << std::endl;
 
  std::cout << "[ EFFICIENCY OF THE GOLDEN SELECTION ] BARREL: "
            << (float)GOLDEN_ELECTRONS_IN_BARREL / (float)TOTAL_ELECTRONS_IN_BARREL
            << " ENDCAP: " << (float)GOLDEN_ELECTRONS_IN_ENDCAP / (float)TOTAL_ELECTRONS_IN_ENDCAP << std::endl;
 
  std::cout << "[ EFFICIENCY OF THE SILVER SELECTION ] BARREL: "
            << (float)SILVER_ELECTRONS_IN_BARREL / (float)TOTAL_ELECTRONS_IN_BARREL
            << " ENDCAP: " << (float)SILVER_ELECTRONS_IN_ENDCAP / (float)TOTAL_ELECTRONS_IN_ENDCAP << std::endl;
 
  std::cout << "[ EFFICIENCY OF THE SHOWER SELECTION ] BARREL: "
            << (float)SHOWER_ELECTRONS_IN_BARREL / (float)TOTAL_ELECTRONS_IN_BARREL
            << " ENDCAP: " << (float)SHOWER_ELECTRONS_IN_ENDCAP / (float)TOTAL_ELECTRONS_IN_ENDCAP << std::endl;
 
  std::cout << "[ EFFICIENCY OF THE CRACK SELECTION ] BARREL: "
            << (float)CRACK_ELECTRONS_IN_BARREL / (float)TOTAL_ELECTRONS_IN_BARREL
            << " ENDCAP: " << (float)CRACK_ELECTRONS_IN_ENDCAP / (float)TOTAL_ELECTRONS_IN_ENDCAP << std::endl;
 
  std::ofstream fout("ZeeStatistics.txt");
 
  if (!fout) {
    std::cout << "Cannot open output file.\n";
  }
 
  fout << "ZeeStatistics" << std::endl;
 
  fout << "##########################RECO#########################" << std::endl;
  fout << "##################Zee with Barrel-Barrel electrons: " << BBZN << std::endl;
 
  fout << "Golden-Golden fraction: " << (float)BBZN_gg / BBZN << " 3-3 fraction is " << (float)BBZN_tt / BBZN
       << " 3-whatever fraction is " << (float)BBZN_t0 / BBZN << std::endl;
  fout << "##################Zee with Barrel-Endcap electrons: " << EBZN << std::endl;
  fout << "Golden-Golden fraction: " << (float)EBZN_gg / EBZN << " 3-3 fraction is " << (float)EBZN_tt / EBZN
       << " 3-whatever fraction is " << (float)EBZN_t0 / EBZN << std::endl;
  fout << "##################Zee with Endcap-Endcap electrons: " << EEZN << std::endl;
  fout << "Golden-Golden fraction: " << (float)EEZN_gg / EEZN << " 3-3 fraction is " << (float)EEZN_tt / EEZN
       << " 3-whatever fraction is " << (float)EEZN_t0 / EEZN << std::endl;
 
  fout << "\n" << std::endl;
 
  fout << "##########################GEN#########################" << std::endl;
  fout << "##################Zee with Barrel-Barrel electrons: " << (float)MCZBB / NEVT << std::endl;
  fout << "##################Zee with Barrel-Endcap electrons: " << (float)MCZEB / NEVT << std::endl;
  fout << "##################Zee with Endcap-Endcap electrons: " << (float)MCZEE / NEVT << std::endl;
 
  fout.close();
}

References BARREL_ELECTRONS_AFTER_BORDER_CUT, BARREL_ELECTRONS_BEFORE_BORDER_CUT, BBZN, BBZN_gg, BBZN_t0, BBZN_tt, gather_cfg::cout, CRACK_ELECTRONS_IN_BARREL, CRACK_ELECTRONS_IN_ENDCAP, EBZN, EBZN_gg, EBZN_t0, EBZN_tt, EEZN, EEZN_gg, EEZN_t0, EEZN_tt, dqmMemoryStats::float, groupFilesInBlocks::fout, GOLDEN_ELECTRONS_IN_BARREL, GOLDEN_ELECTRONS_IN_ENDCAP, MCZBB, MCZEB, MCZEE, NEVT, SHOWER_ELECTRONS_IN_BARREL, SHOWER_ELECTRONS_IN_ENDCAP, SILVER_ELECTRONS_IN_BARREL, SILVER_ELECTRONS_IN_ENDCAP, TOTAL_ELECTRONS_IN_BARREL, and TOTAL_ELECTRONS_IN_ENDCAP.

Referenced by endOfJob().

produce()

virtual void ZeeCalibration::produce ( edm::Event &  , const edm::EventSetup &    )

inlinevirtual

Dummy implementation (job done in duringLoop)

Definition at line 80 of file ZeeCalibration.h.

{};

produceEcalIntercalibConstants()

std::shared_ptr< EcalIntercalibConstants > ZeeCalibration::produceEcalIntercalibConstants ( const EcalIntercalibConstantsRcd &  iRecord )

virtual

Produce Ecal interCalibrations.

Definition at line 163 of file ZeeCalibration.cc.

                                               {
  std::cout << "@SUB=ZeeCalibration::produceEcalIntercalibConstants" << std::endl;
  return ical;
}

References gather_cfg::cout, and ical.

Referenced by ZeeCalibration().

resetHistograms()

void ZeeCalibration::resetHistograms ( )

private

Definition at line 2067 of file ZeeCalibration.cc.

                                     {
  h1_eventsBeforeEWKSelection_->Reset();
  h1_eventsAfterEWKSelection_->Reset();
 
  h1_eventsBeforeBorderSelection_->Reset();
  h1_eventsAfterBorderSelection_->Reset();
 
  for (int i = 0; i < 2; i++) {
    h_eleEffEta_[i]->Reset();
    h_eleEffPhi_[i]->Reset();
    h_eleEffPt_[i]->Reset();
  }
 
  h1_seedOverSC_->Reset();
  h1_preshowerOverSC_->Reset();
 
  h1_eleEtaResol_->Reset();
  h1_elePhiResol_->Reset();
 
  h1_zMassResol_->Reset();
 
  h1_electronCosTheta_TK_->Reset();
  h1_electronCosTheta_SC_->Reset();
  h1_electronCosTheta_SC_TK_->Reset();
 
  h2_fEtaBarrelGood_->Reset();
  h2_fEtaBarrelBad_->Reset();
  h2_fEtaEndcapGood_->Reset();
  h2_fEtaEndcapBad_->Reset();
  h1_eleClasses_->Reset();
 
  h1_ZCandMult_->Reset();
  h1_reco_ZMass_->Reset();
  h1_reco_ZMassCorr_->Reset();
  h1_reco_ZMassCorrBB_->Reset();
  h1_reco_ZMassCorrEE_->Reset();
  h1_occupancyVsEta_->Reset();
  h1_occupancy_->Reset();
  h1_occupancyBarrel_->Reset();
  h1_occupancyEndcap_->Reset();
 
  return;
}

References h1_eleClasses_, h1_electronCosTheta_SC_, h1_electronCosTheta_SC_TK_, h1_electronCosTheta_TK_, h1_eleEtaResol_, h1_elePhiResol_, h1_eventsAfterBorderSelection_, h1_eventsAfterEWKSelection_, h1_eventsBeforeBorderSelection_, h1_eventsBeforeEWKSelection_, h1_occupancy_, h1_occupancyBarrel_, h1_occupancyEndcap_, h1_occupancyVsEta_, h1_preshowerOverSC_, h1_reco_ZMass_, h1_reco_ZMassCorr_, h1_reco_ZMassCorrBB_, h1_reco_ZMassCorrEE_, h1_seedOverSC_, h1_ZCandMult_, h1_zMassResol_, h2_fEtaBarrelBad_, h2_fEtaBarrelGood_, h2_fEtaEndcapBad_, h2_fEtaEndcapGood_, h_eleEffEta_, h_eleEffPhi_, h_eleEffPt_, and mps_fire::i.

Referenced by startingNewLoop().

resetVariables()

void ZeeCalibration::resetVariables ( )

private

Definition at line 2033 of file ZeeCalibration.cc.

                                    {
  BBZN = 0;
  EBZN = 0;
  EEZN = 0;
  BBZN_gg = 0;
  EBZN_gg = 0;
  EEZN_gg = 0;
 
  BBZN_tt = 0;
  EBZN_tt = 0;
  EEZN_tt = 0;
 
  BBZN_t0 = 0;
  EBZN_t0 = 0;
  EEZN_t0 = 0;
 
  TOTAL_ELECTRONS_IN_BARREL = 0;
  TOTAL_ELECTRONS_IN_ENDCAP = 0;
 
  GOLDEN_ELECTRONS_IN_BARREL = 0;
  GOLDEN_ELECTRONS_IN_ENDCAP = 0;
  SILVER_ELECTRONS_IN_BARREL = 0;
  SILVER_ELECTRONS_IN_ENDCAP = 0;
  SHOWER_ELECTRONS_IN_BARREL = 0;
  SHOWER_ELECTRONS_IN_ENDCAP = 0;
  CRACK_ELECTRONS_IN_BARREL = 0;
  CRACK_ELECTRONS_IN_ENDCAP = 0;
 
  BARREL_ELECTRONS_BEFORE_BORDER_CUT = 0;
  BARREL_ELECTRONS_AFTER_BORDER_CUT = 0;
 
  return;
}

References BARREL_ELECTRONS_AFTER_BORDER_CUT, BARREL_ELECTRONS_BEFORE_BORDER_CUT, BBZN, BBZN_gg, BBZN_t0, BBZN_tt, CRACK_ELECTRONS_IN_BARREL, CRACK_ELECTRONS_IN_ENDCAP, EBZN, EBZN_gg, EBZN_t0, EBZN_tt, EEZN, EEZN_gg, EEZN_t0, EEZN_tt, GOLDEN_ELECTRONS_IN_BARREL, GOLDEN_ELECTRONS_IN_ENDCAP, SHOWER_ELECTRONS_IN_BARREL, SHOWER_ELECTRONS_IN_ENDCAP, SILVER_ELECTRONS_IN_BARREL, SILVER_ELECTRONS_IN_ENDCAP, TOTAL_ELECTRONS_IN_BARREL, and TOTAL_ELECTRONS_IN_ENDCAP.

Referenced by startingNewLoop().

ringNumberCorrector()

int ZeeCalibration::ringNumberCorrector ( int  k )

private

Definition at line 1900 of file ZeeCalibration.cc.

                                             {
  int index = -999;
 
  if (calibMode_ == "RING") {
    if (k >= 0 && k <= 84)
      index = k - 85;
 
    if (k >= 85 && k <= 169)
      index = k - 84;
 
    if (k >= 170 && k <= 208)
      index = -k + 84;
 
    if (k >= 209 && k <= 247)
      index = k - 123;
 
  }
 
  else if (calibMode_ == "MODULE") {
    if (k >= 0 && k <= 71)
      index = k - 72;
 
    if (k >= 72 && k <= 143)
      index = k - 71;
  }
  return index;
}

References calibMode_, and dqmdumpme::k.

Referenced by computeCoefficientDistanceAtIteration(), endOfJob(), and endOfLoop().

startingNewLoop()

void ZeeCalibration::startingNewLoop ( unsigned int  iLoop )

overridevirtual

Called at beginning of loop.

Implements edm::EDLooperBase.

Definition at line 1313 of file ZeeCalibration.cc.

                                                       {
  std::cout << "[ZeeCalibration] Starting loop number " << iLoop << std::endl;
 
  theAlgorithm_->resetIteration();
 
  resetVariables();
 
  resetHistograms();
 
#ifdef DEBUG
  std::cout << "[ZeeCalibration] exiting from startingNewLoop" << std::endl;
#endif
}

References gather_cfg::cout, resetHistograms(), ZIterativeAlgorithmWithFit::resetIteration(), resetVariables(), and theAlgorithm_.

xtalIsOnModuleBorder()

bool ZeeCalibration::xtalIsOnModuleBorder ( EBDetId  myEBDetId )

private

Definition at line 1988 of file ZeeCalibration.cc.

                                                           {
  bool myBool(false);
 
  short ieta = myEBDetId.ieta();
  short iphi = myEBDetId.iphi();
 
  //  std::cout<<"[xtalIsOnModuleBorder] ieta: "<<ieta<<" iphi "<<iphi<<std::endl;
 
  myBool = (abs(ieta) == 1 || abs(ieta) == 25 || abs(ieta) == 26 || abs(ieta) == 45 || abs(ieta) == 46 ||
            abs(ieta) == 65 || abs(ieta) == 66 || abs(ieta) == 85);
 
  for (int i = 0; i < 19; i++) {
    if (iphi == (20 * i + 1) || iphi == 20 * i)
      myBool = true;
  }
 
  return myBool;
}

References funct::abs(), mps_fire::i, EBDetId::ieta(), LEDCalibrationChannels::ieta, EBDetId::iphi(), and LEDCalibrationChannels::iphi.

Referenced by duringLoop().

Member Data Documentation

aHLTNames

char ZeeCalibration::aHLTNames[6000]

private

Definition at line 361 of file ZeeCalibration.h.

aHLTResults

bool ZeeCalibration::aHLTResults[200]

private

Definition at line 364 of file ZeeCalibration.h.

Referenced by duringLoop().

aNames

TString ZeeCalibration::aNames[200]

private

Definition at line 363 of file ZeeCalibration.h.

aTriggerNames

char ZeeCalibration::aTriggerNames[200][30]

private

Definition at line 357 of file ZeeCalibration.h.

aTriggerResults

bool ZeeCalibration::aTriggerResults[200]

private

Definition at line 358 of file ZeeCalibration.h.

BARREL_ELECTRONS_AFTER_BORDER_CUT

int ZeeCalibration::BARREL_ELECTRONS_AFTER_BORDER_CUT

private

Definition at line 324 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

BARREL_ELECTRONS_BEFORE_BORDER_CUT

int ZeeCalibration::BARREL_ELECTRONS_BEFORE_BORDER_CUT

private

Definition at line 323 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

barrelfile_

std::string ZeeCalibration::barrelfile_

private

Definition at line 174 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

BBZN

Int_t ZeeCalibration::BBZN

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

BBZN_gg

Int_t ZeeCalibration::BBZN_gg

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

BBZN_t0

Int_t ZeeCalibration::BBZN_t0

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

BBZN_tt

Int_t ZeeCalibration::BBZN_tt

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

calibCoeff

float ZeeCalibration::calibCoeff[250]

private

Definition at line 188 of file ZeeCalibration.h.

Referenced by duringLoop(), endOfJob(), and endOfLoop().

calibCoeffError

float ZeeCalibration::calibCoeffError[250]

private

Definition at line 190 of file ZeeCalibration.h.

Referenced by duringLoop(), endOfJob(), and endOfLoop().

calibMode_

std::string ZeeCalibration::calibMode_

private

Definition at line 159 of file ZeeCalibration.h.

Referenced by computeCoefficientDistanceAtIteration(), duringLoop(), endOfJob(), endOfLoop(), ringNumberCorrector(), and ZeeCalibration().

coefficientDistanceAtIteration

double ZeeCalibration::coefficientDistanceAtIteration[50]

private

Definition at line 321 of file ZeeCalibration.h.

Referenced by endOfJob(), endOfLoop(), and ZeeCalibration().

CRACK_ELECTRONS_IN_BARREL

int ZeeCalibration::CRACK_ELECTRONS_IN_BARREL

private

Definition at line 338 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

CRACK_ELECTRONS_IN_ENDCAP

int ZeeCalibration::CRACK_ELECTRONS_IN_ENDCAP

private

Definition at line 339 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

EBZN

Int_t ZeeCalibration::EBZN

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

EBZN_gg

Int_t ZeeCalibration::EBZN_gg

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

EBZN_t0

Int_t ZeeCalibration::EBZN_t0

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

EBZN_tt

Int_t ZeeCalibration::EBZN_tt

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

EEZN

Int_t ZeeCalibration::EEZN

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

EEZN_gg

Int_t ZeeCalibration::EEZN_gg

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

EEZN_t0

Int_t ZeeCalibration::EEZN_t0

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

EEZN_tt

Int_t ZeeCalibration::EEZN_tt

private

Definition at line 307 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

electronCollection_

std::string ZeeCalibration::electronCollection_

private

Definition at line 162 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

electronProducer_

std::string ZeeCalibration::electronProducer_

private

Definition at line 161 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

electronSelection_

unsigned int ZeeCalibration::electronSelection_

private

Definition at line 316 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

endcapfile_

std::string ZeeCalibration::endcapfile_

private

Definition at line 175 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

erechitCollection_

std::string ZeeCalibration::erechitCollection_

private

Definition at line 151 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

erechitProducer_

std::string ZeeCalibration::erechitProducer_

private

Definition at line 150 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

etaBins_

unsigned int ZeeCalibration::etaBins_

private

Definition at line 166 of file ZeeCalibration.h.

Referenced by ZeeCalibration().

etaMax_

double ZeeCalibration::etaMax_

private

Definition at line 171 of file ZeeCalibration.h.

Referenced by ZeeCalibration().

etaMin_

double ZeeCalibration::etaMin_

private

Definition at line 169 of file ZeeCalibration.h.

Referenced by ZeeCalibration().

etBins_

unsigned int ZeeCalibration::etBins_

private

Definition at line 167 of file ZeeCalibration.h.

Referenced by ZeeCalibration().

etMax_

double ZeeCalibration::etMax_

private

Definition at line 172 of file ZeeCalibration.h.

Referenced by ZeeCalibration().

etMin_

double ZeeCalibration::etMin_

private

Definition at line 170 of file ZeeCalibration.h.

Referenced by ZeeCalibration().

GOLDEN_ELECTRONS_IN_BARREL

int ZeeCalibration::GOLDEN_ELECTRONS_IN_BARREL

private

Definition at line 329 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

GOLDEN_ELECTRONS_IN_ENDCAP

int ZeeCalibration::GOLDEN_ELECTRONS_IN_ENDCAP

private

Definition at line 330 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

h1_borderElectronClassification_

TH1F* ZeeCalibration::h1_borderElectronClassification_

private

Definition at line 305 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), and endOfJob().

h1_eleClasses_

TH1F* ZeeCalibration::h1_eleClasses_

private

Definition at line 217 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_electronCosTheta_SC_

TH1F* ZeeCalibration::h1_electronCosTheta_SC_

private

Definition at line 302 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_electronCosTheta_SC_TK_

TH1F* ZeeCalibration::h1_electronCosTheta_SC_TK_

private

Definition at line 303 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_electronCosTheta_TK_

TH1F* ZeeCalibration::h1_electronCosTheta_TK_

private

Definition at line 301 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_eleERecoOverEtrue_

TH1F* ZeeCalibration::h1_eleERecoOverEtrue_

private

Definition at line 239 of file ZeeCalibration.h.

h1_eleEtaResol_

TH1F* ZeeCalibration::h1_eleEtaResol_

private

Definition at line 241 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), fillEleInfo(), and resetHistograms().

h1_elePhiResol_

TH1F* ZeeCalibration::h1_elePhiResol_

private

Definition at line 242 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), fillEleInfo(), and resetHistograms().

h1_eventsAfterBorderSelection_

TH1F* ZeeCalibration::h1_eventsAfterBorderSelection_

private

Definition at line 210 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_eventsAfterEWKSelection_

TH1F* ZeeCalibration::h1_eventsAfterEWKSelection_

private

Definition at line 207 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_eventsBeforeBorderSelection_

TH1F* ZeeCalibration::h1_eventsBeforeBorderSelection_

private

Definition at line 209 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_eventsBeforeEWKSelection_

TH1F* ZeeCalibration::h1_eventsBeforeEWKSelection_

private

Definition at line 206 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_mc_

TH1F* ZeeCalibration::h1_mc_

private

Definition at line 262 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h1_mcEB_

TH1F* ZeeCalibration::h1_mcEB_

private

Definition at line 271 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h1_mcEBParz_

TH1F* ZeeCalibration::h1_mcEBParz_[25]

private

Definition at line 272 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfLoop().

h1_mcEE_

TH1F* ZeeCalibration::h1_mcEE_

private

Definition at line 275 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h1_mcEEParz_

TH1F* ZeeCalibration::h1_mcEEParz_[25]

private

Definition at line 276 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfLoop().

h1_mcParz_

TH1F* ZeeCalibration::h1_mcParz_[25]

private

Definition at line 263 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfLoop().

h1_nEleReco_

TH1F* ZeeCalibration::h1_nEleReco_

private

Definition at line 216 of file ZeeCalibration.h.

Referenced by bookHistograms().

h1_occupancy_

TH1F* ZeeCalibration::h1_occupancy_

private

Definition at line 297 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and resetHistograms().

h1_occupancyBarrel_

TH1F* ZeeCalibration::h1_occupancyBarrel_

private

Definition at line 298 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and resetHistograms().

h1_occupancyEndcap_

TH1F* ZeeCalibration::h1_occupancyEndcap_

private

Definition at line 299 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and resetHistograms().

h1_occupancyVsEta_

TH1F* ZeeCalibration::h1_occupancyVsEta_

private

Definition at line 292 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and resetHistograms().

h1_occupancyVsEtaCrack_

TH1F* ZeeCalibration::h1_occupancyVsEtaCrack_

private

Definition at line 295 of file ZeeCalibration.h.

h1_occupancyVsEtaGold_

TH1F* ZeeCalibration::h1_occupancyVsEtaGold_

private

Definition at line 293 of file ZeeCalibration.h.

h1_occupancyVsEtaShower_

TH1F* ZeeCalibration::h1_occupancyVsEtaShower_

private

Definition at line 296 of file ZeeCalibration.h.

h1_occupancyVsEtaSilver_

TH1F* ZeeCalibration::h1_occupancyVsEtaSilver_

private

Definition at line 294 of file ZeeCalibration.h.

h1_preshowerOverSC_

TH1F* ZeeCalibration::h1_preshowerOverSC_

private

Definition at line 224 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), fillEleInfo(), and resetHistograms().

h1_reco_ZMass_

TH1F* ZeeCalibration::h1_reco_ZMass_

private

Definition at line 229 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), endOfLoop(), and resetHistograms().

h1_reco_ZMassBad_

TH1F* ZeeCalibration::h1_reco_ZMassBad_

private

Definition at line 235 of file ZeeCalibration.h.

h1_reco_ZMassCorr_

TH1F* ZeeCalibration::h1_reco_ZMassCorr_

private

Definition at line 231 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_reco_ZMassCorrBB_

TH1F* ZeeCalibration::h1_reco_ZMassCorrBB_

private

Definition at line 232 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_reco_ZMassCorrEE_

TH1F* ZeeCalibration::h1_reco_ZMassCorrEE_

private

Definition at line 233 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_reco_ZMassGood_

TH1F* ZeeCalibration::h1_reco_ZMassGood_

private

Definition at line 234 of file ZeeCalibration.h.

h1_RMin_

TH1F* ZeeCalibration::h1_RMin_

private

Definition at line 237 of file ZeeCalibration.h.

h1_RMinZ_

TH1F* ZeeCalibration::h1_RMinZ_

private

Definition at line 238 of file ZeeCalibration.h.

h1_seedOverSC_

TH1F* ZeeCalibration::h1_seedOverSC_

private

Definition at line 223 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), fillEleInfo(), and resetHistograms().

h1_weightSumMeanBarrel_

TH1F* ZeeCalibration::h1_weightSumMeanBarrel_

private

Definition at line 289 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h1_weightSumMeanEndcap_

TH1F* ZeeCalibration::h1_weightSumMeanEndcap_

private

Definition at line 290 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h1_ZCandMult_

TH1F* ZeeCalibration::h1_ZCandMult_

private

Definition at line 236 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_zEtaResol_

TH1F* ZeeCalibration::h1_zEtaResol_

private

Definition at line 227 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h1_zMassResol_

TH1F* ZeeCalibration::h1_zMassResol_

private

Definition at line 226 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), endOfJob(), and resetHistograms().

h1_zPhiResol_

TH1F* ZeeCalibration::h1_zPhiResol_

private

Definition at line 228 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h2_chi2_

TH2F* ZeeCalibration::h2_chi2_[25]

private

Definition at line 278 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and endOfLoop().

h2_coeffVsEta_

TH2F* ZeeCalibration::h2_coeffVsEta_

private

Definition at line 253 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h2_coeffVsEtaGrouped_

TH2F* ZeeCalibration::h2_coeffVsEtaGrouped_

private

Definition at line 254 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h2_coeffVsLoop_

TH2F* ZeeCalibration::h2_coeffVsLoop_

private

Definition at line 258 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h2_fEtaBarrelBad_

TH2F* ZeeCalibration::h2_fEtaBarrelBad_

private

Definition at line 213 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and resetHistograms().

h2_fEtaBarrelGood_

TH2F* ZeeCalibration::h2_fEtaBarrelGood_

private

Definition at line 212 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and resetHistograms().

h2_fEtaEndcapBad_

TH2F* ZeeCalibration::h2_fEtaEndcapBad_

private

Definition at line 215 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and resetHistograms().

h2_fEtaEndcapGood_

TH2F* ZeeCalibration::h2_fEtaEndcapGood_

private

Definition at line 214 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and resetHistograms().

h2_iterations_

TH2F* ZeeCalibration::h2_iterations_[25]

private

Definition at line 279 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and endOfLoop().

h2_miscalRecal_

TH2F* ZeeCalibration::h2_miscalRecal_

private

Definition at line 260 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h2_miscalRecalEB_

TH2F* ZeeCalibration::h2_miscalRecalEB_

private

Definition at line 269 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h2_miscalRecalEE_

TH2F* ZeeCalibration::h2_miscalRecalEE_

private

Definition at line 273 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfJob().

h2_residualSigma_

TH2F* ZeeCalibration::h2_residualSigma_

private

Definition at line 268 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and endOfLoop().

h2_xtalMiscalibCoeffBarrel_

TH2F* ZeeCalibration::h2_xtalMiscalibCoeffBarrel_

private

Definition at line 285 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), and endOfJob().

h2_xtalMiscalibCoeffEndcapMinus_

TH2F* ZeeCalibration::h2_xtalMiscalibCoeffEndcapMinus_

private

Definition at line 286 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), and endOfJob().

h2_xtalMiscalibCoeffEndcapPlus_

TH2F* ZeeCalibration::h2_xtalMiscalibCoeffEndcapPlus_

private

Definition at line 287 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), and endOfJob().

h2_xtalRecalibCoeffBarrel_

TH2F* ZeeCalibration::h2_xtalRecalibCoeffBarrel_[25]

private

Definition at line 281 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfLoop().

h2_xtalRecalibCoeffEndcapMinus_

TH2F* ZeeCalibration::h2_xtalRecalibCoeffEndcapMinus_[25]

private

Definition at line 282 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfLoop().

h2_xtalRecalibCoeffEndcapPlus_

TH2F* ZeeCalibration::h2_xtalRecalibCoeffEndcapPlus_[25]

private

Definition at line 283 of file ZeeCalibration.h.

Referenced by bookHistograms(), and endOfLoop().

h2_zMassDiffVsLoop_

TH2F* ZeeCalibration::h2_zMassDiffVsLoop_

private

Definition at line 256 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and endOfLoop().

h2_zMassVsLoop_

TH2F* ZeeCalibration::h2_zMassVsLoop_

private

Definition at line 255 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and endOfLoop().

h2_zWidthVsLoop_

TH2F* ZeeCalibration::h2_zWidthVsLoop_

private

Definition at line 257 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and endOfLoop().

h_eleEffEta

TH1F* ZeeCalibration::h_eleEffEta[2]

private

Definition at line 219 of file ZeeCalibration.h.

h_eleEffEta_

TH1F* ZeeCalibration::h_eleEffEta_[2]

private

Definition at line 244 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), fillEleInfo(), and resetHistograms().

h_eleEffPhi

TH1F* ZeeCalibration::h_eleEffPhi[2]

private

Definition at line 220 of file ZeeCalibration.h.

h_eleEffPhi_

TH1F* ZeeCalibration::h_eleEffPhi_[2]

private

Definition at line 245 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), fillEleInfo(), and resetHistograms().

h_eleEffPt

TH1F* ZeeCalibration::h_eleEffPt[2]

private

Definition at line 221 of file ZeeCalibration.h.

h_eleEffPt_

TH1F* ZeeCalibration::h_eleEffPt_[2]

private

Definition at line 246 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), fillEleInfo(), and resetHistograms().

h_ESCcorrEtrue_

TH1F* ZeeCalibration::h_ESCcorrEtrue_[25]

private

Definition at line 250 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and fillEleInfo().

h_ESCcorrEtrueVsEta_

TH2F* ZeeCalibration::h_ESCcorrEtrueVsEta_[25]

private

Definition at line 251 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and fillEleInfo().

h_ESCEtrue_

TH1F* ZeeCalibration::h_ESCEtrue_[25]

private

Definition at line 247 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and fillEleInfo().

h_ESCEtrueVsEta_

TH2F* ZeeCalibration::h_ESCEtrueVsEta_[25]

private

Definition at line 248 of file ZeeCalibration.h.

Referenced by bookHistograms(), endOfJob(), and fillEleInfo().

hlAccept_

std::vector<unsigned int> ZeeCalibration::hlAccept_

private

Definition at line 350 of file ZeeCalibration.h.

hlErrors_

std::vector<unsigned int> ZeeCalibration::hlErrors_

private

Definition at line 351 of file ZeeCalibration.h.

hlNames_

std::vector<std::string> ZeeCalibration::hlNames_

private

Definition at line 353 of file ZeeCalibration.h.

hltCount

Int_t ZeeCalibration::hltCount

private

Definition at line 360 of file ZeeCalibration.h.

Referenced by duringLoop().

hltNamesLen

Int_t ZeeCalibration::hltNamesLen

private

Definition at line 362 of file ZeeCalibration.h.

hlTriggerResults_

edm::InputTag ZeeCalibration::hlTriggerResults_

private

Definition at line 341 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

hlWasRun_

std::vector<unsigned int> ZeeCalibration::hlWasRun_

private

Definition at line 349 of file ZeeCalibration.h.

ical

std::shared_ptr<EcalIntercalibConstants> ZeeCalibration::ical

private

Definition at line 193 of file ZeeCalibration.h.

Referenced by duringLoop(), endOfJob(), endOfLoop(), and produceEcalIntercalibConstants().

init_

bool ZeeCalibration::init_

private

Definition at line 354 of file ZeeCalibration.h.

Referenced by duringLoop().

initCalibCoeff

float ZeeCalibration::initCalibCoeff[250]

private

Definition at line 191 of file ZeeCalibration.h.

Referenced by duringLoop(), endOfJob(), and endOfLoop().

isfirstcall_

bool ZeeCalibration::isfirstcall_

private

Definition at line 366 of file ZeeCalibration.h.

Referenced by beginOfJob(), and duringLoop().

loopArray

double ZeeCalibration::loopArray[50]

private

Definition at line 318 of file ZeeCalibration.h.

Referenced by endOfJob(), endOfLoop(), and ZeeCalibration().

loopFlag_

int ZeeCalibration::loopFlag_

private

Definition at line 186 of file ZeeCalibration.h.

Referenced by duringLoop(), endOfLoop(), and fillEleInfo().

mass

double ZeeCalibration::mass

private

Definition at line 179 of file ZeeCalibration.h.

Referenced by Particle.Particle::__str__(), ZMuMuRochCorAnalyzer.DiMuon::__str__(), DiObject.DiMuon::__str__(), and duringLoop().

mass4tree

float ZeeCalibration::mass4tree

private

Definition at line 181 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

massDiff4tree

float ZeeCalibration::massDiff4tree

private

Definition at line 182 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

maxInvMassCut_

double ZeeCalibration::maxInvMassCut_

private

Definition at line 178 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

mcProducer_

std::string ZeeCalibration::mcProducer_

private

Definition at line 158 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

MCZBB

Int_t ZeeCalibration::MCZBB

private

Definition at line 308 of file ZeeCalibration.h.

Referenced by duringLoop(), and printStatistics().

MCZEB

Int_t ZeeCalibration::MCZEB

private

Definition at line 308 of file ZeeCalibration.h.

Referenced by duringLoop(), and printStatistics().

MCZEE

Int_t ZeeCalibration::MCZEE

private

Definition at line 308 of file ZeeCalibration.h.

Referenced by duringLoop(), and printStatistics().

minInvMassCut_

double ZeeCalibration::minInvMassCut_

private

Definition at line 177 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

myTree

TTree* ZeeCalibration::myTree

private

Definition at line 144 of file ZeeCalibration.h.

Referenced by duringLoop(), endOfJob(), and ZeeCalibration().

myZeePlots_

ZeePlots* ZeeCalibration::myZeePlots_

private

Definition at line 197 of file ZeeCalibration.h.

Referenced by bookHistograms(), duringLoop(), and endOfJob().

myZeeRescaleFactorPlots_

ZeeRescaleFactorPlots* ZeeCalibration::myZeeRescaleFactorPlots_

private

Definition at line 198 of file ZeeCalibration.h.

nAccept_

unsigned int ZeeCalibration::nAccept_

private

Definition at line 346 of file ZeeCalibration.h.

nErrors_

unsigned int ZeeCalibration::nErrors_

private

Definition at line 347 of file ZeeCalibration.h.

nEvents_

unsigned int ZeeCalibration::nEvents_

private

Definition at line 343 of file ZeeCalibration.h.

NEVT

Int_t ZeeCalibration::NEVT

private

Definition at line 308 of file ZeeCalibration.h.

Referenced by duringLoop(), and printStatistics().

NewCalibCoeff

float ZeeCalibration::NewCalibCoeff[250]

private

Definition at line 189 of file ZeeCalibration.h.

Referenced by endOfLoop().

nWasRun_

unsigned int ZeeCalibration::nWasRun_

private

Definition at line 345 of file ZeeCalibration.h.

outputFile_

TFile* ZeeCalibration::outputFile_

private

Definition at line 310 of file ZeeCalibration.h.

Referenced by duringLoop(), endOfJob(), endOfLoop(), and ZeeCalibration().

outputFileName_

std::string ZeeCalibration::outputFileName_

private

Definition at line 146 of file ZeeCalibration.h.

Referenced by ZeeCalibration().

read_events

int ZeeCalibration::read_events

private

Definition at line 184 of file ZeeCalibration.h.

Referenced by duringLoop().

RecalibBarrelHits_

std::string ZeeCalibration::RecalibBarrelHits_

private

Definition at line 164 of file ZeeCalibration.h.

rechitCollection_

std::string ZeeCalibration::rechitCollection_

private

Definition at line 149 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

rechitProducer_

std::string ZeeCalibration::rechitProducer_

private

Definition at line 148 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

scCollection_

std::string ZeeCalibration::scCollection_

private

Definition at line 153 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

scIslandCollection_

std::string ZeeCalibration::scIslandCollection_

private

Definition at line 156 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

scIslandProducer_

std::string ZeeCalibration::scIslandProducer_

private

Definition at line 155 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

scProducer_

std::string ZeeCalibration::scProducer_

private

Definition at line 152 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().

SHOWER_ELECTRONS_IN_BARREL

int ZeeCalibration::SHOWER_ELECTRONS_IN_BARREL

private

Definition at line 335 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

SHOWER_ELECTRONS_IN_ENDCAP

int ZeeCalibration::SHOWER_ELECTRONS_IN_ENDCAP

private

Definition at line 336 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

sigmaArray

double ZeeCalibration::sigmaArray[50]

private

Definition at line 319 of file ZeeCalibration.h.

Referenced by endOfJob(), endOfLoop(), and ZeeCalibration().

sigmaErrorArray

double ZeeCalibration::sigmaErrorArray[50]

private

Definition at line 320 of file ZeeCalibration.h.

Referenced by endOfJob(), endOfLoop(), and ZeeCalibration().

SILVER_ELECTRONS_IN_BARREL

int ZeeCalibration::SILVER_ELECTRONS_IN_BARREL

private

Definition at line 332 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

SILVER_ELECTRONS_IN_ENDCAP

int ZeeCalibration::SILVER_ELECTRONS_IN_ENDCAP

private

Definition at line 333 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

theAlgorithm_

ZIterativeAlgorithmWithFit* ZeeCalibration::theAlgorithm_

private

Definition at line 195 of file ZeeCalibration.h.

Referenced by duringLoop(), endOfJob(), endOfLoop(), startingNewLoop(), and ZeeCalibration().

theMaxLoops

unsigned int ZeeCalibration::theMaxLoops

private

Definition at line 312 of file ZeeCalibration.h.

Referenced by endOfJob(), endOfLoop(), and ZeeCalibration().

theParameterSet

edm::ParameterSet ZeeCalibration::theParameterSet

private

Definition at line 202 of file ZeeCalibration.h.

Referenced by ZeeCalibration().

TOTAL_ELECTRONS_IN_BARREL

int ZeeCalibration::TOTAL_ELECTRONS_IN_BARREL

private

Definition at line 326 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

TOTAL_ELECTRONS_IN_ENDCAP

int ZeeCalibration::TOTAL_ELECTRONS_IN_ENDCAP

private

Definition at line 327 of file ZeeCalibration.h.

Referenced by duringLoop(), printStatistics(), and resetVariables().

triggerCount

Int_t ZeeCalibration::triggerCount

private

Definition at line 356 of file ZeeCalibration.h.

wantEtaCorrection_

bool ZeeCalibration::wantEtaCorrection_

private

Definition at line 314 of file ZeeCalibration.h.

Referenced by duringLoop(), and ZeeCalibration().