#include <EcalTPGParamBuilder.h>

Inheritance diagram for EcalTPGParamBuilder:

Public Member Functions
void	analyze (const edm::Event &evt, const edm::EventSetup &evtSetup) override

void	beginJob () override

	EcalTPGParamBuilder (edm::ParameterSet const &pSet)

	~EcalTPGParamBuilder () override

Public Member Functions inherited from edm::one::EDAnalyzer<>
	EDAnalyzer ()=default

	EDAnalyzer (const EDAnalyzer &)=delete

SerialTaskQueue *	globalLuminosityBlocksQueue () final

SerialTaskQueue *	globalRunsQueue () final

const EDAnalyzer &	operator= (const EDAnalyzer &)=delete

bool	wantsGlobalLuminosityBlocks () const final

bool	wantsGlobalRuns () const final

bool	wantsInputProcessBlocks () const final

bool	wantsProcessBlocks () const final

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

	EDAnalyzerBase ()

ModuleDescription const &	moduleDescription () const

bool	wantsStreamLuminosityBlocks () const

bool	wantsStreamRuns () const

	~EDAnalyzerBase () override

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

void	convertCurrentProcessAlias (std::string const &processName)
	Convert "@currentProcess" in InputTag process names to the actual current process name. More...

	EDConsumerBase ()

	EDConsumerBase (EDConsumerBase const &)=delete

	EDConsumerBase (EDConsumerBase &&)=default

ESProxyIndex const *	esGetTokenIndices (edm::Transition iTrans) const

std::vector< ESProxyIndex > const &	esGetTokenIndicesVector (edm::Transition iTrans) const

std::vector< ESRecordIndex > const &	esGetTokenRecordIndicesVector (edm::Transition iTrans) const

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

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

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

std::vector< ProductResolverIndexAndSkipBit > const &	itemsToGetFrom (BranchType iType) const

void	labelsForToken (EDGetToken iToken, Labels &oLabels) const

void	modulesWhoseProductsAreConsumed (std::array< std::vector< ModuleDescription const > , NumBranchTypes > &modulesAll, std::vector< ModuleProcessName > &modulesInPreviousProcesses, ProductRegistry const &preg, std::map< std::string, ModuleDescription const *> const &labelsToDesc, std::string const &processName) const

EDConsumerBase const &	operator= (EDConsumerBase const &)=delete

EDConsumerBase &	operator= (EDConsumerBase &&)=default

bool	registeredToConsume (ProductResolverIndex, bool, BranchType) const

bool	registeredToConsumeMany (TypeID const &, BranchType) const

void	selectInputProcessBlocks (ProductRegistry const &productRegistry, ProcessBlockHelperBase const &processBlockHelperBase)

ProductResolverIndexAndSkipBit	uncheckedIndexFrom (EDGetToken) const

void	updateLookup (BranchType iBranchType, ProductResolverIndexHelper const &, bool iPrefetchMayGet)

void	updateLookup (eventsetup::ESRecordsToProxyIndices const &)

virtual	~EDConsumerBase () noexcept(false)

Private Member Functions
bool	checkIfOK (EcalPedestals::Item item)

void	computeFineGrainEBParameters (uint &lowRatio, uint &highRatio, uint &lowThreshold, uint &highThreshold, uint &lut)

void	computeFineGrainEEParameters (uint &threshold, uint &lut_strip, uint &lut_tower)

bool	computeLinearizerParam (double theta, double gainRatio, double calibCoeff, std::string subdet, int &mult, int &shift)

void	computeLUT (int *lut, std::string det="EB")

std::vector< unsigned int >	computeWeights (EcalShapeBase &shape, TH1F *histo)

void	create_header ()

void	getCoeff (coeffStruc &coeff, const EcalGainRatioMap &gainMap, uint rawId)

void	getCoeff (coeffStruc &coeff, const EcalPedestalsMap &pedMap, uint rawId)

void	getCoeff (coeffStruc &coeff, const std::map< EcalLogicID, MonPedestalsDat > &pedMap, const EcalLogicID &logicId)

void	getCoeff (coeffStruc &coeff, const EcalIntercalibConstantMap &calibMap, const EcalLaserAlphaMap &laserAlphaMap, uint rawId, std::string &ss)

std::pair< std::string, int >	getCrate (int tcc)

std::string	getDet (int tcc)

int	getEtaSlice (int tccId, int towerInTCC)

int	getGCTRegionEta (int tteta)

int	getGCTRegionPhi (int ttphi)

bool	realignBaseline (linStruc &lin, float forceBase12, int cmsswid)

int	uncodeWeight (double weight, int complement2=7)

double	uncodeWeight (int iweight, int complement2=7)

Private Attributes
int	bst_conf_id_

int	btt_conf_id_

int	bxt_conf_id_

int	coke_conf_id_

unsigned int	complement2_

EcalTPGDBApp *	db_

bool	DBEE_

unsigned int	DBrunNb_

int	del_conf_id_

std::map< int, std::vector< int > >	delays_EB_

std::map< int, std::vector< int > >	delays_EE_

edm::ESGetToken< EcalADCToGeVConstant, EcalADCToGeVConstantRcd >	ecalADCToGeVConstantToken_

edm::ESGetToken< EcalGainRatios, EcalGainRatiosRcd >	ecalGainRatiosToken_

edm::ESGetToken< EcalIntercalibConstants, EcalIntercalibConstantsRcd >	ecalIntercalibConstantsToken_

edm::ESGetToken< EcalLaserAlphas, EcalLaserAlphasRcd >	ecalLaserAlphasToken_

edm::ESGetToken< EcalLaserAPDPNRatios, EcalLaserAPDPNRatiosRcd >	ecalLaserAPDPNRatiosToken_

edm::ESGetToken< EcalElectronicsMapping, EcalMappingRcd >	ecalmappingToken_

edm::ESGetToken< EcalPedestals, EcalPedestalsRcd >	ecalPedestalsToken_

double	Et_sat_EB_

double	Et_sat_EE_

const EcalTrigTowerConstituentsMap *	eTTmap_

edm::ESGetToken< EcalTrigTowerConstituentsMap, IdealGeometryRecord >	eTTmapToken_

double	FG_highRatio_EB_

double	FG_highThreshold_EB_

double	FG_lowRatio_EB_

double	FG_lowThreshold_EB_

unsigned int	FG_lut_EB_

unsigned int	FG_lut_strip_EE_

unsigned int	FG_lut_tower_EE_

double	FG_Threshold_EE_

int	fgr_conf_id_

int	forcedPedestalValue_

bool	forceEtaSlice_

std::ofstream *	geomFile_

bool	H2_

int	lin_conf_id_

int	lut_conf_id_

double	LUT_constant_EB_

double	LUT_constant_EE_

double	LUT_noise_EB_

double	LUT_noise_EE_

std::string	LUT_option_

double	LUT_stochastic_EB_

double	LUT_stochastic_EE_

double	LUT_threshold_EB_

double	LUT_threshold_EE_

int	m_write_bst

int	m_write_btt

int	m_write_bxt

int	m_write_del

int	m_write_fgr

int	m_write_lin

int	m_write_lut

int	m_write_ped

int	m_write_sli

int	m_write_spi

int	m_write_wei

int	m_write_wei2

unsigned int	nSample_

Char_t	ntupleCrate_ [10]

Char_t	ntupleDet_ [10]

Int_t *	ntupleInts_

std::ofstream *	out_file_

int	ped_conf_id_

unsigned int	pedestal_offset_

std::map< int, std::vector< int > >	phases_EB_

std::map< int, std::vector< int > >	phases_EE_

unsigned int	sampleMax_

unsigned int	SFGVB_lut_

int	SFGVB_SpikeKillingThreshold_

unsigned int	SFGVB_Threshold_

EBShape	shapeEB_

EEShape	shapeEE_

int	sli_conf_id_

unsigned int	sliding_

int	spi_conf_id_

std::string	tag_

const CaloSubdetectorGeometry *	theBarrelGeometry_

edm::ESGetToken< CaloSubdetectorGeometry, EcalBarrelGeometryRecord >	theBarrelGeometryToken_

const CaloSubdetectorGeometry *	theEndcapGeometry_

edm::ESGetToken< CaloSubdetectorGeometry, EcalEndcapGeometryRecord >	theEndcapGeometryToken_

const EcalElectronicsMapping *	theMapping_

std::string	TimingDelays_EB_

std::string	TimingDelays_EE_

std::string	TimingPhases_EB_

std::string	TimingPhases_EE_

bool	TPmode_DisableEBEvenPeakFinder_

bool	TPmode_DisableEEEvenPeakFinder_

bool	TPmode_EnableEBOddFilter_

bool	TPmode_EnableEBOddPeakFinder_

bool	TPmode_EnableEEOddFilter_

bool	TPmode_EnableEEOddPeakFinder_

unsigned int	TPmode_FenixEBStripInfobit2_

unsigned int	TPmode_FenixEBStripOutput_

unsigned int	TPmode_FenixEBTcpInfobit1_

unsigned int	TPmode_FenixEBTcpOutput_

unsigned int	TPmode_FenixEEStripInfobit2_

unsigned int	TPmode_FenixEEStripOutput_

unsigned int	TPmode_FenixEETcpInfobit1_

unsigned int	TPmode_FenixEETcpOutput_

std::string	Transparency_Corr_

std::map< int, double >	Transparency_Correction_

double	TTF_highThreshold_EB_

double	TTF_highThreshold_EE_

double	TTF_lowThreshold_EB_

double	TTF_lowThreshold_EE_

bool	useInterCalibration_

bool	useTransparencyCorr_

bool	useTransverseEnergy_

int	version_

int	wei2_conf_id_

int	wei_conf_id_

bool	weight_even_computeFromShape_

std::string	weight_even_idMapFile_

std::string	weight_even_weightGroupFile_

std::string	weight_odd_idMapFile_

std::string	weight_odd_weightGroupFile_

double	weight_timeShift_

bool	weight_unbias_recovery_

bool	weight_useDoubleWeights_

bool	writeToDB_

bool	writeToFiles_

double	xtal_LSB_EB_

double	xtal_LSB_EE_

Static Private Attributes
static constexpr uint	NWEIGHTS = 5

Additional Inherited Members
Public Types inherited from edm::one::EDAnalyzerBase
typedef EDAnalyzerBase	ModuleType

Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels

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

static void	fillDescriptions (ConfigurationDescriptions &descriptions)

static void	prevalidate (ConfigurationDescriptions &descriptions)

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

template<BranchType B = InEvent>
EDConsumerBaseAdaptor< B >	consumes (edm::InputTag tag) noexcept

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

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

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

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

void	consumesMany (const TypeToGet &id)

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

template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto	esConsumes ()

template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag const &tag)

template<Transition Tr = Transition::Event>
constexpr auto	esConsumes ()

template<Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag tag)

template<Transition Tr = Transition::Event>
ESGetTokenGeneric	esConsumes (eventsetup::EventSetupRecordKey const &iRecord, eventsetup::DataKey const &iKey)
	Used with EventSetupRecord::doGet. More...

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

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

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

void	resetItemsToGetFrom (BranchType iType)

Detailed Description

Definition at line 72 of file EcalTPGParamBuilder.h.

Constructor & Destructor Documentation

◆ EcalTPGParamBuilder()

EcalTPGParamBuilder::EcalTPGParamBuilder ( edm::ParameterSet const & pSet )

explicit

Definition at line 41 of file EcalTPGParamBuilder.cc.

References bst_conf_id_, btt_conf_id_, visDQMUpload::buf, bxt_conf_id_, coke_conf_id_, db_, DBEE_, del_conf_id_, delays_EB_, delays_EE_, Et_sat_EB_, Et_sat_EE_, FG_highRatio_EB_, FG_highThreshold_EB_, FG_lowRatio_EB_, FG_lowThreshold_EB_, FG_lut_EB_, FG_lut_strip_EE_, FG_lut_tower_EE_, FG_Threshold_EE_, fgr_conf_id_, forcedPedestalValue_, forceEtaSlice_, geomFile_, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), H2_, createfilelist::int, lin_conf_id_, lut_conf_id_, LUT_constant_EB_, LUT_constant_EE_, LUT_noise_EB_, LUT_noise_EE_, LUT_option_, LUT_stochastic_EB_, LUT_stochastic_EE_, LUT_threshold_EB_, LUT_threshold_EE_, m_write_bst, m_write_btt, m_write_bxt, m_write_del, m_write_fgr, m_write_lin, m_write_lut, m_write_ped, m_write_sli, m_write_spi, m_write_wei, m_write_wei2, MillePedeFileConverter_cfg::out, out_file_, L1TdeCSCTF_cfi::outFile, ped_conf_id_, pedestal_offset_, phases_EB_, phases_EE_, sampleMax_, SFGVB_lut_, SFGVB_SpikeKillingThreshold_, SFGVB_Threshold_, funct::sin(), sli_conf_id_, sliding_, spi_conf_id_, contentValuesCheck::ss, AlCaHLTBitMon_QueryRunRegistry::string, tag_, TimingDelays_EB_, TimingDelays_EE_, TimingPhases_EB_, TimingPhases_EE_, TPmode_DisableEBEvenPeakFinder_, TPmode_DisableEEEvenPeakFinder_, TPmode_EnableEBOddFilter_, TPmode_EnableEBOddPeakFinder_, TPmode_EnableEEOddFilter_, TPmode_EnableEEOddPeakFinder_, TPmode_FenixEBStripInfobit2_, TPmode_FenixEBStripOutput_, TPmode_FenixEBTcpInfobit1_, TPmode_FenixEBTcpOutput_, TPmode_FenixEEStripInfobit2_, TPmode_FenixEEStripOutput_, TPmode_FenixEETcpInfobit1_, TPmode_FenixEETcpOutput_, Transparency_Corr_, TTF_highThreshold_EB_, TTF_highThreshold_EE_, TTF_lowThreshold_EB_, TTF_lowThreshold_EE_, useInterCalibration_, useTransparencyCorr_, useTransverseEnergy_, version_, wei2_conf_id_, wei_conf_id_, weight_even_computeFromShape_, weight_even_idMapFile_, weight_even_weightGroupFile_, weight_odd_idMapFile_, weight_odd_weightGroupFile_, weight_timeShift_, weight_unbias_recovery_, weight_useDoubleWeights_, writeToDB_, and writeToFiles_.

     : theEndcapGeometryToken_(esConsumes(edm::ESInputTag("", "EcalEndcap"))),
       theBarrelGeometryToken_(esConsumes(edm::ESInputTag("", "EcalBarrel"))),
       eTTmapToken_(esConsumes()),
       ecalmappingToken_(esConsumes()),
       ecalLaserAlphasToken_(esConsumes()),
       ecalLaserAPDPNRatiosToken_(esConsumes()),
       ecalPedestalsToken_(esConsumes()),
       ecalIntercalibConstantsToken_(esConsumes()),
       ecalGainRatiosToken_(esConsumes()),
       ecalADCToGeVConstantToken_(esConsumes()),
       xtal_LSB_EB_(0),
       xtal_LSB_EE_(0),
       nSample_(5),
       complement2_(7),
       shapeEB_(consumesCollector()),  // EBShape, EEShape are fetched now from DB (2018.05.22 K. Theofilatos)
       shapeEE_(consumesCollector()) {
   ped_conf_id_ = 0;
   lin_conf_id_ = 0;
   lut_conf_id_ = 0;
   wei_conf_id_ = 0;
   wei2_conf_id_ = 0;
   fgr_conf_id_ = 0;
   sli_conf_id_ = 0;
   spi_conf_id_ = 0;  //modif-alex 21/01/11
   del_conf_id_ = 0;  //modif-alex 21/01/11
   bxt_conf_id_ = 0;
   btt_conf_id_ = 0;
   bst_conf_id_ = 0;
   coke_conf_id_ = 0;
   tag_ = "";
   version_ = 0;
 
   m_write_ped = 1;
   m_write_lin = 1;
   m_write_lut = 1;
   m_write_wei = 1;
   m_write_wei2 = 1;
   m_write_fgr = 1;
   m_write_sli = 1;
   m_write_spi = 1;  //modif-alex 21/01/11
   m_write_del = 1;  //modif-alex 21/01/11
   m_write_bxt = 1;
   m_write_btt = 1;
   m_write_bst = 1;
 
   writeToDB_ = pSet.getParameter<bool>("writeToDB");
   DBEE_ = pSet.getParameter<bool>("allowDBEE");
   string DBsid = pSet.getParameter<std::string>("DBsid");
   string DBuser = pSet.getParameter<std::string>("DBuser");
   string DBpass = pSet.getParameter<std::string>("DBpass");
   //uint32_t DBport = pSet.getParameter<unsigned int>("DBport") ;
 
   tag_ = pSet.getParameter<std::string>("TPGtag");
   version_ = pSet.getParameter<unsigned int>("TPGversion");
 
   m_write_ped = pSet.getParameter<unsigned int>("TPGWritePed");
   m_write_lin = pSet.getParameter<unsigned int>("TPGWriteLin");
   m_write_lut = pSet.getParameter<unsigned int>("TPGWriteLut");
   m_write_wei = pSet.getParameter<unsigned int>("TPGWriteWei");
   m_write_wei2 = pSet.getParameter<unsigned int>("TPGWriteWei2");
   m_write_fgr = pSet.getParameter<unsigned int>("TPGWriteFgr");
   m_write_sli = pSet.getParameter<unsigned int>("TPGWriteSli");
   m_write_spi = pSet.getParameter<unsigned int>("TPGWriteSpi");  //modif-alex 21/01/11
   m_write_del = pSet.getParameter<unsigned int>("TPGWriteDel");  //modif-alex 21/01/11
   m_write_bxt = pSet.getParameter<unsigned int>("TPGWriteBxt");
   m_write_btt = pSet.getParameter<unsigned int>("TPGWriteBtt");
   m_write_bst = pSet.getParameter<unsigned int>("TPGWriteBst");
 
   btt_conf_id_ = m_write_btt;
   bxt_conf_id_ = m_write_bxt;
   bst_conf_id_ = m_write_bst;
 
   if (m_write_ped != 0 && m_write_ped != 1)
     ped_conf_id_ = m_write_ped;
 
   if (writeToDB_)
     edm::LogInfo("TopInfo") << "data will be saved with tag and version=" << tag_ << ".version" << version_ << "\n";
   db_ = new EcalTPGDBApp(DBsid, DBuser, DBpass);
 
   writeToFiles_ = pSet.getParameter<bool>("writeToFiles");
   if (writeToFiles_) {
     std::string outFile = pSet.getParameter<std::string>("outFile");
     out_file_ = new std::ofstream(outFile.c_str(), std::ios::out);
   }
   geomFile_ = new std::ofstream("geomFile.txt", std::ios::out);
 
   useTransverseEnergy_ = pSet.getParameter<bool>("useTransverseEnergy");
 
   Et_sat_EB_ = pSet.getParameter<double>("Et_sat_EB");
   Et_sat_EE_ = pSet.getParameter<double>("Et_sat_EE");
   sliding_ = pSet.getParameter<unsigned int>("sliding");
   weight_timeShift_ = pSet.getParameter<double>("weight_timeShift");
   sampleMax_ = pSet.getParameter<unsigned int>("weight_sampleMax");
   weight_unbias_recovery_ = pSet.getParameter<bool>("weight_unbias_recovery");
 
   weight_even_computeFromShape_ = pSet.getParameter<bool>("weight_even_computeFromShape");
   weight_even_idMapFile_ = pSet.getParameter<std::string>("weight_even_idMapFile");
   weight_even_weightGroupFile_ = pSet.getParameter<std::string>("weight_even_weightGroupFile");
   weight_odd_idMapFile_ = pSet.getParameter<std::string>("weight_odd_idMapFile");
   weight_odd_weightGroupFile_ = pSet.getParameter<std::string>("weight_odd_weightGroupFile");
 
   weight_useDoubleWeights_ = pSet.getParameter<bool>("weight_useDoubleWeights");
   TPmode_EnableEBOddFilter_ = pSet.getParameter<bool>("TPmode_EnableEBOddFilter");
   TPmode_EnableEEOddFilter_ = pSet.getParameter<bool>("TPmode_EnableEEOddFilter");
   TPmode_EnableEBOddPeakFinder_ = pSet.getParameter<bool>("TPmode_EnableEBOddPeakFinder");
   TPmode_EnableEEOddPeakFinder_ = pSet.getParameter<bool>("TPmode_EnableEEOddPeakFinder");
   TPmode_DisableEBEvenPeakFinder_ = pSet.getParameter<bool>("TPmode_DisableEBEvenPeakFinder");
   TPmode_DisableEEEvenPeakFinder_ = pSet.getParameter<bool>("TPmode_DisableEEEvenPeakFinder");
   TPmode_FenixEBStripOutput_ = pSet.getParameter<unsigned int>("TPmode_FenixEBStripOutput");
   TPmode_FenixEEStripOutput_ = pSet.getParameter<unsigned int>("TPmode_FenixEEStripOutput");
   TPmode_FenixEBStripInfobit2_ = pSet.getParameter<unsigned int>("TPmode_FenixEBStripInfobit2");
   TPmode_FenixEEStripInfobit2_ = pSet.getParameter<unsigned int>("TPmode_FenixEEStripInfobit2");
   TPmode_FenixEBTcpOutput_ = pSet.getParameter<unsigned int>("TPmode_FenixEBTcpOutput");
   TPmode_FenixEBTcpInfobit1_ = pSet.getParameter<unsigned int>("TPmode_FenixEBTcpInfobit1");
   TPmode_FenixEETcpOutput_ = pSet.getParameter<unsigned int>("TPmode_FenixEETcpOutput");
   TPmode_FenixEETcpInfobit1_ = pSet.getParameter<unsigned int>("TPmode_FenixEETcpInfobit1");
 
   forcedPedestalValue_ = pSet.getParameter<int>("forcedPedestalValue");
   forceEtaSlice_ = pSet.getParameter<bool>("forceEtaSlice");
 
   LUT_option_ = pSet.getParameter<std::string>("LUT_option");
   LUT_threshold_EB_ = pSet.getParameter<double>("LUT_threshold_EB");
   LUT_threshold_EE_ = pSet.getParameter<double>("LUT_threshold_EE");
   LUT_stochastic_EB_ = pSet.getParameter<double>("LUT_stochastic_EB");
   LUT_noise_EB_ = pSet.getParameter<double>("LUT_noise_EB");
   LUT_constant_EB_ = pSet.getParameter<double>("LUT_constant_EB");
   LUT_stochastic_EE_ = pSet.getParameter<double>("LUT_stochastic_EE");
   LUT_noise_EE_ = pSet.getParameter<double>("LUT_noise_EE");
   LUT_constant_EE_ = pSet.getParameter<double>("LUT_constant_EE");
 
   TTF_lowThreshold_EB_ = pSet.getParameter<double>("TTF_lowThreshold_EB");
   TTF_highThreshold_EB_ = pSet.getParameter<double>("TTF_highThreshold_EB");
   TTF_lowThreshold_EE_ = pSet.getParameter<double>("TTF_lowThreshold_EE");
   TTF_highThreshold_EE_ = pSet.getParameter<double>("TTF_highThreshold_EE");
 
   FG_lowThreshold_EB_ = pSet.getParameter<double>("FG_lowThreshold_EB");
   FG_highThreshold_EB_ = pSet.getParameter<double>("FG_highThreshold_EB");
   FG_lowRatio_EB_ = pSet.getParameter<double>("FG_lowRatio_EB");
   FG_highRatio_EB_ = pSet.getParameter<double>("FG_highRatio_EB");
   FG_lut_EB_ = pSet.getParameter<unsigned int>("FG_lut_EB");
   FG_Threshold_EE_ = pSet.getParameter<double>("FG_Threshold_EE");
   FG_lut_strip_EE_ = pSet.getParameter<unsigned int>("FG_lut_strip_EE");
   FG_lut_tower_EE_ = pSet.getParameter<unsigned int>("FG_lut_tower_EE");
   SFGVB_Threshold_ = pSet.getParameter<unsigned int>("SFGVB_Threshold");
   SFGVB_lut_ = pSet.getParameter<unsigned int>("SFGVB_lut");
   SFGVB_SpikeKillingThreshold_ = pSet.getParameter<int>("SFGVB_SpikeKillingThreshold");  //modif-alex 21/01/11
   pedestal_offset_ = pSet.getParameter<unsigned int>("pedestal_offset");
 
   useInterCalibration_ = pSet.getParameter<bool>("useInterCalibration");
   H2_ = pSet.getUntrackedParameter<bool>("H2", false);
 
   useTransparencyCorr_ = false;
   useTransparencyCorr_ = pSet.getParameter<bool>("useTransparencyCorr");            //modif-alex-25/04/2012
   Transparency_Corr_ = pSet.getParameter<std::string>("transparency_corrections");  //modif-alex-30/01/2012
 
   //modif-alex-23/02/2011
   //convert the spike killing first from GeV to ADC (10 bits)
   //depending on the saturation scale: Et_sat_EB_
   if (SFGVB_SpikeKillingThreshold_ == -1 || (SFGVB_SpikeKillingThreshold_ > Et_sat_EB_))
     SFGVB_SpikeKillingThreshold_ = 1023;  //nokilling
   else
     SFGVB_SpikeKillingThreshold_ = int(SFGVB_SpikeKillingThreshold_ * 1024 / Et_sat_EB_);
   edm::LogInfo("TopInfo") << "INFO:SPIKE KILLING THRESHOLD (ADC)=" << SFGVB_SpikeKillingThreshold_ << "\n";
 
   //modif-alex-02/02/11
   //TIMING information
   TimingDelays_EB_ = pSet.getParameter<std::string>("timing_delays_EB");
   TimingDelays_EE_ = pSet.getParameter<std::string>("timing_delays_EE");
   TimingPhases_EB_ = pSet.getParameter<std::string>("timing_phases_EB");
   TimingPhases_EE_ = pSet.getParameter<std::string>("timing_phases_EE");
 
   std::ostringstream ss;
   //  edm::LogInfo("TopInfo") << "INFO: READING timing files" << "\n";
   ss << "INFO: READING timing files\n";
   std::ifstream delay_eb(TimingDelays_EB_.c_str());
   if (!delay_eb)
     edm::LogError("TopInfo") << "ERROR: File " << TimingDelays_EB_.c_str() << " could not be opened"
                              << "\n";
   std::ifstream delay_ee(TimingDelays_EE_.c_str());
   if (!delay_ee)
     edm::LogError("TopInfo") << "ERROR: File " << TimingDelays_EE_.c_str() << " could not be opened"
                              << "\n";
   std::ifstream phase_eb(TimingPhases_EB_.c_str());
   if (!phase_eb)
     edm::LogError("TopInfo") << "ERROR: File " << TimingPhases_EB_.c_str() << " could not be opened"
                              << "\n";
   std::ifstream phase_ee(TimingPhases_EE_.c_str());
   if (!phase_ee)
     edm::LogError("TopInfo") << "ERROR: File " << TimingPhases_EE_.c_str() << " could not be opened"
                              << "\n";
 
   char buf[1024];
   //READING DELAYS EB
   delay_eb.getline(buf, sizeof(buf), '\n');
   while (delay_eb) {
     std::stringstream sin(buf);
 
     int tcc;
     sin >> tcc;
 
     vector<int> vec_delays_eb;
     for (int ieb = 0; ieb < 68; ++ieb) {
       int time_delay = -1;
       sin >> time_delay;
       vec_delays_eb.push_back(time_delay);
       if (time_delay == -1)
         edm::LogError("TopInfo") << "ERROR:Barrel timing delay -1, check file"
                                  << "\n";
     }
 
     if (vec_delays_eb.size() != 68)
       edm::LogError("TopInfo") << "ERROR:Barrel timing delay wrong, not enough towers, check file"
                                << "\n";
 
     if (delays_EB_.find(tcc) == delays_EB_.end())
       delays_EB_.insert(make_pair(tcc, vec_delays_eb));
 
     //    edm::LogInfo("TopInfo") << tcc << "\n";
     ss << tcc;
     for (unsigned int ieb = 0; ieb < vec_delays_eb.size(); ++ieb)
       //      edm::LogInfo("TopInfo") << vec_delays_eb[ieb] << "\n";
       ss << " " << vec_delays_eb[ieb];
     delay_eb.getline(buf, sizeof(buf), '\n');
     ss << "\n";
   }  //loop delay file EB
   delay_eb.close();
 
   //READING PHASES EB
   phase_eb.getline(buf, sizeof(buf), '\n');
   while (phase_eb) {
     std::stringstream sin(buf);
     int tcc;
     sin >> tcc;
 
     vector<int> vec_phases_eb;
     for (unsigned int ieb = 0; ieb < 68; ++ieb) {
       int time_phase = -1;
       sin >> time_phase;
       vec_phases_eb.push_back(time_phase);
       if (time_phase == -1)
         edm::LogError("TopInfo") << "ERROR:Barrel timing phase -1, check file"
                                  << "\n";
     }
 
     if (vec_phases_eb.size() != 68)
       edm::LogError("TopInfo") << "ERROR:Barrel timing phase wrong, not enough towers, check file"
                                << "\n";
 
     if (phases_EB_.find(tcc) == phases_EB_.end())
       phases_EB_.insert(make_pair(tcc, vec_phases_eb));
 
     //    edm::LogInfo("TopInfo") << tcc << "\n";
     ss << tcc;
     for (unsigned int ieb = 0; ieb < vec_phases_eb.size(); ++ieb)
       //      edm::LogInfo("TopInfo") << vec_phases_eb[ieb] << "\n";
       ss << " " << vec_phases_eb[ieb];
     phase_eb.getline(buf, sizeof(buf), '\n');
     ss << "\n";
   }  //loop phase file EB
   phase_eb.close();
 
   //READING DELAYS EE//------------------------------------------------
   delay_ee.getline(buf, sizeof(buf), '\n');
   while (delay_ee) {
     std::stringstream sin(buf);
     int tcc;
     sin >> tcc;
 
     vector<int> vec_delays_ee;
     for (unsigned int iee = 0; iee < 48; ++iee) {
       int time_delay = -1;
       sin >> time_delay;
       vec_delays_ee.push_back(time_delay);
       if (time_delay == -1)
         edm::LogError("TopInfo") << "ERROR:EE timing delay -1, check file"
                                  << "\n";
     }
 
     if (vec_delays_ee.size() != 48)
       edm::LogError("TopInfo") << "ERROR:EE timing delay wrong, not enough towers, check file"
                                << "\n";
 
     if (delays_EE_.find(tcc) == delays_EE_.end())
       delays_EE_.insert(make_pair(tcc, vec_delays_ee));
 
     //    edm::LogInfo("TopInfo") << tcc << "\n";
     ss << tcc;
     for (unsigned int iee = 0; iee < vec_delays_ee.size(); ++iee)
       //      edm::LogInfo("TopInfo") << vec_delays_ee[iee] << "\n";
       ss << " " << vec_delays_ee[iee];
     ss << "\n";
     delay_ee.getline(buf, sizeof(buf), '\n');
   }  //loop delay file EE
   delay_ee.close();
 
   //READING PHASES EE
   phase_ee.getline(buf, sizeof(buf), '\n');
   while (phase_ee) {
     std::stringstream sin(buf);
     int tcc;
     sin >> tcc;
 
     vector<int> vec_phases_ee;
     for (unsigned int iee = 0; iee < 48; ++iee) {
       int time_phase = -1;
       sin >> time_phase;
       vec_phases_ee.push_back(time_phase);
       if (time_phase == -1)
         edm::LogError("TopInfo") << "ERROR:EE timing phase -1, check file"
                                  << "\n";
     }
 
     if (vec_phases_ee.size() != 48)
       edm::LogError("TopInfo") << "ERROR:EE timing phase wrong, not enough towers, check file"
                                << "\n";
 
     if (phases_EE_.find(tcc) == phases_EE_.end())
       phases_EE_.insert(make_pair(tcc, vec_phases_ee));
     //    edm::LogInfo("TopInfo") << tcc << "\n";
     ss << tcc;
     for (unsigned int iee = 0; iee < vec_phases_ee.size(); ++iee)
       //      edm::LogInfo("TopInfo") << vec_phases_ee[iee] << "\n";
       ss << " " << vec_phases_ee[iee];
     ss << "\n";
     phase_ee.getline(buf, sizeof(buf), '\n');
   }  //loop phase file EE
   phase_ee.close();
 
   //  edm::LogInfo("TopInfo") << "INFO: DONE reading timing files for EB and EE" << "\n";
   ss << "INFO: DONE reading timing files for EB and EE\n";
   edm::LogInfo("TopInfo") << ss.str();
 }

◆ ~EcalTPGParamBuilder()

EcalTPGParamBuilder::~EcalTPGParamBuilder ( )

override

Definition at line 375 of file EcalTPGParamBuilder.cc.

References out_file_, and writeToFiles_.

                                           {
   if (writeToFiles_) {
     (*out_file_) << "EOF" << std::endl;
     out_file_->close();
     delete out_file_;
   }
 }

Member Function Documentation

◆ analyze()

void EcalTPGParamBuilder::analyze	(	const edm::Event &	evt,
		const edm::EventSetup &	evtSetup
	)

overridevirtual

Implements edm::one::EDAnalyzerBase.

Definition at line 419 of file EcalTPGParamBuilder.cc.

                                                                                     {
   using namespace edm;
   using namespace std;
 
   // geometry
   eTTmap_ = &evtSetup.getData(eTTmapToken_);
   theEndcapGeometry_ = &evtSetup.getData(theEndcapGeometryToken_);
   theBarrelGeometry_ = &evtSetup.getData(theBarrelGeometryToken_);
 
   // electronics mapping
   theMapping_ = &evtSetup.getData(ecalmappingToken_);
 
   // get record for alpha
   std::ostringstream ss;
   ss << "EcalLaserDbAnalyzer::analyze\n";
   const EcalLaserAlphaMap& laserAlphaMap = evtSetup.getData(ecalLaserAlphasToken_).getMap();  // map of apdpns
   ss << "EcalLaserDbAnalyzer::analyze-> got EcalLaserDbRecord: \n";
 
   //modif-alex-27-july-2015-+ Jean june 2016 beg
   // use alpha to check
   EcalLaserAlphaMap::const_iterator italpha;
   int cnt = 0;
   // Barrel loop
   for (italpha = laserAlphaMap.barrelItems().begin(); italpha != laserAlphaMap.barrelItems().end(); ++italpha) {
     if (cnt % 1000 == 0) {
       EBDetId ebdetid = EBDetId::unhashIndex(cnt);
       ss << " Barrel ALPHA = " << (*italpha) << " cmsswId " << ebdetid.rawId() << "\n";
     }
     cnt++;
   }
   ss << "Number of barrel Alpha parameters : " << cnt << "\n";
   // Endcap loop
   cnt = 0;
   for (italpha = laserAlphaMap.endcapItems().begin(); italpha != laserAlphaMap.endcapItems().end(); ++italpha) {
     if (cnt % 1000 == 0) {
       EEDetId eedetid = EEDetId::unhashIndex(cnt);
       ss << "EndCap ALPHA = " << (*italpha) << " cmsswId " << eedetid.rawId() << "\n";
     }
     cnt++;
   }
   ss << "Number of Endcap Alpha parameters : " << cnt << "\n";
   edm::LogInfo("TopInfo") << ss.str();
   ss.str("");
   //modif-alex-27-july-2015 +-Jean june 2016-end
 
   //modif-alex-30/01/2012   displaced in analyze Jean 2018
   ss.str("");
   if (useTransparencyCorr_) {
     if (Transparency_Corr_ != "tag") {  // Jean 2018
       edm::LogInfo("TopInfo") << "INFO: READING transparency correction files"
                               << "\n";
       ss << "INFO: READING transparency correction files\n";
       std::ifstream transparency(Transparency_Corr_.c_str());
       if (!transparency)
         edm::LogError("TopInfo") << "ERROR: File " << Transparency_Corr_.c_str() << " could not be opened"
                                  << "\n";
 
       char buf[1024];
       transparency.getline(buf, sizeof(buf), '\n');
       int xtalcounter = 0;
       while (transparency) {
         std::stringstream sin(buf);
 
         int raw_xtal_id;
         sin >> raw_xtal_id;
 
         double xtal_trans_corr;
         sin >> xtal_trans_corr;
 
         //      edm::LogInfo("TopInfo") << raw_xtal_id << " " << xtal_trans_corr << "\n";
         ss << raw_xtal_id << " " << xtal_trans_corr << "\n";
 
         Transparency_Correction_.insert(make_pair(raw_xtal_id, xtal_trans_corr));
 
         xtalcounter++;
         transparency.getline(buf, sizeof(buf), '\n');
       }  //loop transparency
       transparency.close();
       ss << "INFO: DONE transparency correction files " << xtalcounter << "\n";
       edm::LogInfo("TopInfo") << ss.str();
       ss.str("");
     }       // file
     else {  // Jean 2018
       edm::LogInfo("TopInfo") << "INFO: READING transparency correction tag"
                               << "\n";
       //      std::cout << "new feature, read a tag" << std::endl;
       const EcalLaserAPDPNRatios* lratio = &evtSetup.getData(ecalLaserAPDPNRatiosToken_);
       //      std::cout << " laser map size " << lratio->getLaserMap().size() << std::endl;
 
       EcalLaserAPDPNRatios::EcalLaserAPDPNRatiosMap::const_iterator itratio;
       // Barrel loop
       for (int ib = 0; ib < 61200; ib++) {
         EBDetId ebdetid = EBDetId::unhashIndex(ib);
         itratio = lratio->getLaserMap().find(ebdetid.rawId());
         //  std::cout  << ib << " " << ebdetid.rawId() << " Barrel APDPNRatios = " << (*itratio).p1 << " " << (*itratio).p2 << " " << (*itratio).p3 << std::endl;
         Transparency_Correction_.insert(make_pair(ebdetid.rawId(), (*itratio).p2));
       }
       // Endcap loop
       for (int ie = 0; ie < 14648; ie++) {
         EEDetId eedetid = EEDetId::unhashIndex(ie);
         itratio = lratio->getLaserMap().find(eedetid.rawId());
         //  std::cout  << ie << " " << eedetid.rawId() << " Endcap APDPNRatios = " << (*itratio).p1 << " " << (*itratio).p2 << " " << (*itratio).p3 << std::endl;
         Transparency_Correction_.insert(make_pair(eedetid.rawId(), (*itratio).p2));
       }
       ss << "INFO: DONE transparency correction tag\n";
       edm::LogInfo("TopInfo") << ss.str();
       ss.str("");
     }  // Jean 2018
   }    //if transparency
 
   // histo
   TFile saving("EcalTPGParam.root", "recreate");
   saving.cd();
   TH2F* ICEB = new TH2F("ICEB", "IC: Barrel", 360, 1, 361, 172, -86, 86);
   ICEB->GetYaxis()->SetTitle("eta index");
   ICEB->GetXaxis()->SetTitle("phi index");
   TH2F* tpgFactorEB = new TH2F("tpgFactorEB", "tpgFactor: Barrel", 360, 1, 361, 172, -86, 86);
   tpgFactorEB->GetYaxis()->SetTitle("eta index");
   tpgFactorEB->GetXaxis()->SetTitle("phi index");
 
   TH2F* ICEEPlus = new TH2F("ICEEPlus", "IC: Plus Endcap", 120, -9, 111, 120, -9, 111);
   ICEEPlus->GetYaxis()->SetTitle("y index");
   ICEEPlus->GetXaxis()->SetTitle("x index");
   TH2F* tpgFactorEEPlus = new TH2F("tpgFactorEEPlus", "tpgFactor: Plus Endcap", 120, -9, 111, 120, -9, 111);
   tpgFactorEEPlus->GetYaxis()->SetTitle("y index");
   tpgFactorEEPlus->GetXaxis()->SetTitle("x index");
   TH2F* ICEEMinus = new TH2F("ICEEMinus", "IC: Minus Endcap", 120, -9, 111, 120, -9, 111);
   ICEEMinus->GetYaxis()->SetTitle("y index");
   ICEEMinus->GetXaxis()->SetTitle("x index");
   TH2F* tpgFactorEEMinus = new TH2F("tpgFactorEEMinus", "tpgFactor: Minus Endcap", 120, -9, 111, 120, -9, 111);
   tpgFactorEEMinus->GetYaxis()->SetTitle("y index");
   tpgFactorEEMinus->GetXaxis()->SetTitle("x index");
 
   TH2F* IC = new TH2F("IC", "IC", 720, -acos(-1.), acos(-1.), 600, -3., 3.);
   IC->GetYaxis()->SetTitle("eta");
   IC->GetXaxis()->SetTitle("phi");
   TH2F* tpgFactor = new TH2F("tpgFactor", "tpgFactor", 720, -acos(-1.), acos(-1.), 600, -3., 3.);
   tpgFactor->GetYaxis()->SetTitle("eta");
   tpgFactor->GetXaxis()->SetTitle("phi");
 
   TH1F* hshapeEB = new TH1F("shapeEB", "shapeEB", 250, 0., 10.);
   TH1F* hshapeEE = new TH1F("shapeEE", "shapeEE", 250, 0., 10.);
 
   TTree* ntuple = new TTree("tpgmap", "TPG geometry map");
   const std::string branchFloat[26] = {
       "fed",    "tcc",    "tower", "stripInTower", "xtalInStrip", "CCU",      "VFE",     "xtalInVFE", "xtalInCCU",
       "ieta",   "iphi",   "ix",    "iy",           "iz",          "hashedId", "ic",      "cmsswId",   "dbId",
       "ietaTT", "iphiTT", "TCCch", "TCCslot",      "SLBch",       "SLBslot",  "ietaGCT", "iphiGCT"};
   ntupleInts_ = new Int_t[26];
   for (int i = 0; i < 26; i++)
     ntuple->Branch(branchFloat[i].c_str(), &ntupleInts_[i], (branchFloat[i] + string("/I")).c_str());
   ntuple->Branch("det", ntupleDet_, "det/C");
   ntuple->Branch("crate", ntupleCrate_, "crate/C");
 
   TNtuple* ntupleSpike = new TNtuple("spikeParam", "Spike parameters", "gainId:theta:G:g:ped:pedLin");
 
   // Initialization section //
   list<uint32_t> towerListEB;
   list<uint32_t> stripListEB;
   list<uint32_t> towerListEE;
   list<uint32_t> stripListEE;
   list<uint32_t>::iterator itList;
 
   map<int, uint32_t> stripMapEB;               // <EcalLogicId.hashed, strip elec id>
   map<int, uint32_t> stripMapEE;               // <EcalLogicId.hashed, strip elec id>
   map<uint32_t, uint32_t> stripMapEBsintheta;  // <strip elec id, sintheta>
 
   // Pedestals
 
   EcalPedestalsMap pedMap;
 
   if (m_write_ped == 1) {
     ss << "Getting the pedestals from offline DB...\n";
 
     pedMap = evtSetup.getData(ecalPedestalsToken_).getMap();
 
     const auto& pedMapEB = pedMap.barrelItems();
     const auto& pedMapEE = pedMap.endcapItems();
     EcalPedestalsMapIterator pedIter;
     int nPed = 0;
     for (pedIter = pedMapEB.begin(); pedIter != pedMapEB.end() && nPed < 10; ++pedIter, ++nPed) {
       const auto aped = (*pedIter);
       ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
     }
     for (pedIter = pedMapEE.begin(); pedIter != pedMapEE.end() && nPed < 10; ++pedIter, ++nPed) {
       const auto aped = (*pedIter);
       ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
     }
   } else if (m_write_ped == 0) {
     ss << "Getting the pedestals from previous configuration\n";
 
     EcalPedestals peds;
 
     FEConfigMainInfo fe_main_info;
     fe_main_info.setConfigTag(tag_);
     ss << "trying to read previous tag if it exists tag=" << tag_ << ".version" << version_ << "\n";
     db_->fetchConfigSet(&fe_main_info);
     if (fe_main_info.getPedId() > 0)
       ped_conf_id_ = fe_main_info.getPedId();
 
     FEConfigPedInfo fe_ped_info;
     fe_ped_info.setId(ped_conf_id_);
     db_->fetchConfigSet(&fe_ped_info);
     std::map<EcalLogicID, FEConfigPedDat> dataset_TpgPed;
     db_->fetchDataSet(&dataset_TpgPed, &fe_ped_info);
 
     typedef std::map<EcalLogicID, FEConfigPedDat>::const_iterator CIfeped;
     EcalLogicID ecid_xt;
     FEConfigPedDat rd_ped;
     int icells = 0;
     for (CIfeped p = dataset_TpgPed.begin(); p != dataset_TpgPed.end(); p++) {
       ecid_xt = p->first;
       rd_ped = p->second;
 
       std::string ecid_name = ecid_xt.getName();
 
       // EB data
       if (ecid_name == "EB_crystal_number") {
         int sm_num = ecid_xt.getID1();
         int xt_num = ecid_xt.getID2();
 
         EBDetId ebdetid(sm_num, xt_num, EBDetId::SMCRYSTALMODE);
         EcalPedestals::Item item;
         item.mean_x1 = rd_ped.getPedMeanG1();
         item.mean_x6 = rd_ped.getPedMeanG6();
         item.mean_x12 = rd_ped.getPedMeanG12();
         item.rms_x1 = 0.5;
         item.rms_x6 = 1.;
         item.rms_x12 = 1.2;
 
         if (icells < 10)
           ss << " copy the EB data "
              << " ped = " << item.mean_x12 << "\n";
 
         peds.insert(std::make_pair(ebdetid.rawId(), item));
 
         ++icells;
       } else if (ecid_name == "EE_crystal_number") {
         // EE data
         int z = ecid_xt.getID1();
         int x = ecid_xt.getID2();
         int y = ecid_xt.getID3();
         EEDetId eedetid(x, y, z, EEDetId::XYMODE);
         EcalPedestals::Item item;
         item.mean_x1 = rd_ped.getPedMeanG1();
         item.mean_x6 = rd_ped.getPedMeanG6();
         item.mean_x12 = rd_ped.getPedMeanG12();
         item.rms_x1 = 0.5;
         item.rms_x6 = 1.;
         item.rms_x12 = 1.2;
 
         peds.insert(std::make_pair(eedetid.rawId(), item));
         ++icells;
       }
     }
 
     pedMap = peds.getMap();
 
     const auto& pedMapEB = pedMap.barrelItems();
     const auto& pedMapEE = pedMap.endcapItems();
     EcalPedestalsMapIterator pedIter;
     int nPed = 0;
     for (pedIter = pedMapEB.begin(); pedIter != pedMapEB.end() && nPed < 10; ++pedIter, ++nPed) {
       const auto aped = (*pedIter);
       ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
     }
     for (pedIter = pedMapEE.begin(); pedIter != pedMapEE.end() && nPed < 10; ++pedIter, ++nPed) {
       const auto aped = (*pedIter);
       ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
     }
 
   } else if (m_write_ped > 1) {
     ss << "Getting the pedestals from configuration number" << m_write_ped << "\n";
 
     EcalPedestals peds;
 
     FEConfigPedInfo fe_ped_info;
     fe_ped_info.setId(m_write_ped);
     db_->fetchConfigSet(&fe_ped_info);
     std::map<EcalLogicID, FEConfigPedDat> dataset_TpgPed;
     db_->fetchDataSet(&dataset_TpgPed, &fe_ped_info);
 
     typedef std::map<EcalLogicID, FEConfigPedDat>::const_iterator CIfeped;
     EcalLogicID ecid_xt;
     FEConfigPedDat rd_ped;
     int icells = 0;
     for (CIfeped p = dataset_TpgPed.begin(); p != dataset_TpgPed.end(); p++) {
       ecid_xt = p->first;
       rd_ped = p->second;
 
       std::string ecid_name = ecid_xt.getName();
 
       // EB data
       if (ecid_name == "EB_crystal_number") {
         if (icells < 10)
           edm::LogInfo("TopInfo") << " copy the EB data "
                                   << " icells = " << icells << "\n";
         int sm_num = ecid_xt.getID1();
         int xt_num = ecid_xt.getID2();
 
         EBDetId ebdetid(sm_num, xt_num, EBDetId::SMCRYSTALMODE);
         EcalPedestals::Item item;
         item.mean_x1 = (unsigned int)rd_ped.getPedMeanG1();
         item.mean_x6 = (unsigned int)rd_ped.getPedMeanG6();
         item.mean_x12 = (unsigned int)rd_ped.getPedMeanG12();
         item.rms_x1 = 0.5;
         item.rms_x6 = 1.;
         item.rms_x12 = 1.2;
 
         peds.insert(std::make_pair(ebdetid.rawId(), item));
         ++icells;
       } else if (ecid_name == "EE_crystal_number") {
         // EE data
         int z = ecid_xt.getID1();
         int x = ecid_xt.getID2();
         int y = ecid_xt.getID3();
         EEDetId eedetid(x, y, z, EEDetId::XYMODE);
         EcalPedestals::Item item;
         item.mean_x1 = (unsigned int)rd_ped.getPedMeanG1();
         item.mean_x6 = (unsigned int)rd_ped.getPedMeanG6();
         item.mean_x12 = (unsigned int)rd_ped.getPedMeanG12();
         item.rms_x1 = 0.5;
         item.rms_x6 = 1.;
         item.rms_x12 = 1.2;
 
         peds.insert(std::make_pair(eedetid.rawId(), item));
         ++icells;
       }
     }
 
     pedMap = peds.getMap();
 
     const auto& pedMapEB = pedMap.barrelItems();
     const auto& pedMapEE = pedMap.endcapItems();
     EcalPedestalsMapIterator pedIter;
     int nPed = 0;
     for (pedIter = pedMapEB.begin(); pedIter != pedMapEB.end() && nPed < 10; ++pedIter, ++nPed) {
       const auto aped = (*pedIter);
       ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
     }
     for (pedIter = pedMapEE.begin(); pedIter != pedMapEE.end() && nPed < 10; ++pedIter, ++nPed) {
       const auto aped = (*pedIter);
       ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
     }
   }
 
   edm::LogInfo("TopInfo") << ss.str();
   ss.str("");
 
   // Intercalib constants
   ss << "Getting intercalib from offline DB...\n";
   const EcalIntercalibConstants* intercalib = &evtSetup.getData(ecalIntercalibConstantsToken_);
   const EcalIntercalibConstantMap& calibMap = intercalib->getMap();
   const auto& calibMapEB = calibMap.barrelItems();
   const auto& calibMapEE = calibMap.endcapItems();
   EcalIntercalibConstantMap::const_iterator calIter;
   int nCal = 0;
   for (calIter = calibMapEB.begin(); calIter != calibMapEB.end() && nCal < 10; ++calIter, ++nCal) {
     ss << (*calIter) << "\n";
   }
   for (calIter = calibMapEE.begin(); calIter != calibMapEE.end() && nCal < 10; ++calIter, ++nCal) {
     ss << (*calIter) << "\n";
   }
   edm::LogInfo("TopInfo") << ss.str();
   ss.str("");
   float calibvec[1700];
   if (H2_) {
     edm::LogInfo("TopInfo") << "H2: overwriting IC coef with file"
                             << "\n";
     std::ifstream calibfile("calib_sm36.txt", std::ios::out);
     int idata, icry;
     float fdata, fcali;
     std::string strdata;
     if (calibfile.is_open()) {
       calibfile >> strdata >> strdata >> strdata >> strdata >> strdata;
       while (!calibfile.eof()) {
         calibfile >> idata >> icry >> fcali >> fdata >> fdata;
         calibvec[icry - 1] = fcali;
         if (calibfile.eof()) {
           break;  // avoid last line duplication
         }
       }
     }
   }
 
   // Gain Ratios
   ss << "Getting the gain ratios from offline DB...\n";
   const EcalGainRatioMap& gainMap = evtSetup.getData(ecalGainRatiosToken_).getMap();
   const auto& gainMapEB = gainMap.barrelItems();
   const auto& gainMapEE = gainMap.endcapItems();
   EcalGainRatioMap::const_iterator gainIter;
   int nGain = 0;
   for (gainIter = gainMapEB.begin(); gainIter != gainMapEB.end() && nGain < 10; ++gainIter, ++nGain) {
     const auto& aGain = (*gainIter);
     ss << aGain.gain12Over6() << ", " << aGain.gain6Over1() * aGain.gain12Over6() << "\n";
   }
   for (gainIter = gainMapEE.begin(); gainIter != gainMapEE.end() && nGain < 10; ++gainIter, ++nGain) {
     const auto& aGain = (*gainIter);
     ss << aGain.gain12Over6() << ", " << aGain.gain6Over1() * aGain.gain12Over6() << "\n";
   }
   edm::LogInfo("TopInfo") << ss.str();
   ss.str("");
 
   // ADCtoGeV
   ss << "Getting the ADC to GeV from offline DB...\n";
   const EcalADCToGeVConstant* ADCToGeV = &evtSetup.getData(ecalADCToGeVConstantToken_);
   xtal_LSB_EB_ = ADCToGeV->getEBValue();
   xtal_LSB_EE_ = ADCToGeV->getEEValue();
   ss << "xtal_LSB_EB_ = " << xtal_LSB_EB_ << "\n";
   ss << "xtal_LSB_EE_ = " << xtal_LSB_EE_ << "\n";
 
   vector<EcalLogicID> my_EcalLogicId;
   vector<EcalLogicID> my_TTEcalLogicId;
   vector<EcalLogicID> my_StripEcalLogicId;
   EcalLogicID my_EcalLogicId_EB;
   // Endcap identifiers
   EcalLogicID my_EcalLogicId_EE;
   vector<EcalLogicID> my_TTEcalLogicId_EE;
   vector<EcalLogicID> my_RTEcalLogicId_EE;
   vector<EcalLogicID> my_StripEcalLogicId1_EE;
   vector<EcalLogicID> my_StripEcalLogicId2_EE;
   vector<EcalLogicID> my_CrystalEcalLogicId_EE;
   vector<EcalLogicID> my_TTEcalLogicId_EB_by_TCC;
   vector<EcalLogicID> my_StripEcalLogicId_EE_strips_by_TCC;
 
   my_EcalLogicId_EB = db_->getEcalLogicID("EB", EcalLogicID::NULLID, EcalLogicID::NULLID, EcalLogicID::NULLID, "EB");
   my_EcalLogicId_EE = db_->getEcalLogicID("EE", EcalLogicID::NULLID, EcalLogicID::NULLID, EcalLogicID::NULLID, "EE");
   my_EcalLogicId = db_->getEcalLogicIDSetOrdered(
       "EB_crystal_number", 1, 36, 1, 1700, EcalLogicID::NULLID, EcalLogicID::NULLID, "EB_crystal_number", 12);
   my_TTEcalLogicId = db_->getEcalLogicIDSetOrdered(
       "EB_trigger_tower", 1, 36, 1, 68, EcalLogicID::NULLID, EcalLogicID::NULLID, "EB_trigger_tower", 12);
   my_StripEcalLogicId = db_->getEcalLogicIDSetOrdered(
       "EB_VFE", 1, 36, 1, 68, 1, 5, "EB_VFE", 123);  //last digi means ordered 1st by SM,then TT, then strip
   ss << "got the 3 ecal barrel logic id set\n";
 
   // EE crystals identifiers
   my_CrystalEcalLogicId_EE =
       db_->getEcalLogicIDSetOrdered("EE_crystal_number", -1, 1, 0, 200, 0, 200, "EE_crystal_number", 123);
 
   // EE Strip identifiers
   // DCC=601-609 TT = ~40 EEstrip = 5
   my_StripEcalLogicId1_EE =
       db_->getEcalLogicIDSetOrdered("ECAL_readout_strip", 601, 609, 1, 100, 0, 5, "ECAL_readout_strip", 123);
   // EE Strip identifiers
   // DCC=646-654 TT = ~40 EEstrip = 5
   my_StripEcalLogicId2_EE =
       db_->getEcalLogicIDSetOrdered("ECAL_readout_strip", 646, 654, 1, 100, 0, 5, "ECAL_readout_strip", 123);
   // ----> modif here 31/1/2011
   // EE Strip identifiers by TCC tower strip
   // TCC=1-108 TT = ~40 EEstrip = 1-5
   my_StripEcalLogicId_EE_strips_by_TCC =
       db_->getEcalLogicIDSetOrdered("EE_trigger_strip", 1, 108, 1, 100, 1, 5, "EE_trigger_strip", 123);
 
   // ----> modif here 31/1/2011
   // ECAL Barrel trigger towers by TCC/tower identifiers
   // TTC=38-72 TT = 1-68
   my_TTEcalLogicId_EB_by_TCC = db_->getEcalLogicIDSetOrdered(
       "ECAL_trigger_tower", 1, 108, 1, 68, EcalLogicID::NULLID, EcalLogicID::NULLID, "ECAL_trigger_tower", 12);
 
   // EE TT identifiers
   // TTC=72 TT = 1440
   my_TTEcalLogicId_EE = db_->getEcalLogicIDSetOrdered(
       "EE_trigger_tower", 1, 108, 1, 40, EcalLogicID::NULLID, EcalLogicID::NULLID, "EE_trigger_tower", 12);
 
   // EE TT identifiers
   // TTC=72 TT = 1440
   my_RTEcalLogicId_EE = db_->getEcalLogicIDSetOrdered(
       "EE_readout_tower", 1, 1000, 1, 100, EcalLogicID::NULLID, EcalLogicID::NULLID, "EE_readout_tower", 12);
   edm::LogInfo("TopInfo") << ss.str();
   ss.str("");
 
   if (writeToDB_) {
     ss << "Getting the latest ids for this tag (latest version) "
        << "\n";
 
     FEConfigMainInfo fe_main_info;
     fe_main_info.setConfigTag(tag_);
 
     ss << "trying to read previous tag if it exists tag=" << tag_ << ".version" << version_ << "\n";
 
     db_->fetchConfigSet(&fe_main_info);
     if (fe_main_info.getPedId() > 0 && ped_conf_id_ == 0)
       ped_conf_id_ = fe_main_info.getPedId();
     lin_conf_id_ = fe_main_info.getLinId();
     lut_conf_id_ = fe_main_info.getLUTId();
     wei_conf_id_ = fe_main_info.getWeiId();
     wei2_conf_id_ = fe_main_info.getWei2Id();
     fgr_conf_id_ = fe_main_info.getFgrId();
     sli_conf_id_ = fe_main_info.getSliId();
     spi_conf_id_ = fe_main_info.getSpiId();  //modif-alex 21/01/11
     del_conf_id_ = fe_main_info.getTimId();  //modif-alex 21/01/11
     coke_conf_id_ = fe_main_info.getCokeId();
     if (fe_main_info.getBxtId() > 0 && bxt_conf_id_ == 0)
       bxt_conf_id_ = fe_main_info.getBxtId();
     if (fe_main_info.getBttId() > 0 && btt_conf_id_ == 0)
       btt_conf_id_ = fe_main_info.getBttId();
     if (fe_main_info.getBstId() > 0 && bst_conf_id_ == 0)
       bst_conf_id_ = fe_main_info.getBstId();
     // those that are not written specifically in this program are propagated
     // from the previous record with the same tag and the highest version
   }
 
   // Compute linearization coeff section //
 
   map<EcalLogicID, FEConfigPedDat> pedset;
   map<EcalLogicID, FEConfigLinDat> linset;
   map<EcalLogicID, FEConfigLinParamDat> linparamset;
   map<EcalLogicID, FEConfigLUTParamDat> lutparamset;
   map<EcalLogicID, FEConfigFgrParamDat> fgrparamset;
 
   map<int, linStruc> linEtaSlice;
   map<vector<int>, linStruc> linMap;
 
   // count number of strip per tower
   int NbOfStripPerTCC[108][68];
   for (int i = 0; i < 108; i++)
     for (int j = 0; j < 68; j++)
       NbOfStripPerTCC[i][j] = 0;
   const std::vector<DetId>& ebCells = theBarrelGeometry_->getValidDetIds(DetId::Ecal, EcalBarrel);
   const std::vector<DetId>& eeCells = theEndcapGeometry_->getValidDetIds(DetId::Ecal, EcalEndcap);
   for (vector<DetId>::const_iterator it = ebCells.begin(); it != ebCells.end(); ++it) {
     EBDetId id(*it);
     const EcalTrigTowerDetId towid = id.tower();
     const EcalTriggerElectronicsId elId = theMapping_->getTriggerElectronicsId(id);
     int tccNb = theMapping_->TCCid(towid);
     int towerInTCC = theMapping_->iTT(towid);
     int stripInTower = elId.pseudoStripId();
     if (stripInTower > NbOfStripPerTCC[tccNb - 1][towerInTCC - 1])
       NbOfStripPerTCC[tccNb - 1][towerInTCC - 1] = stripInTower;
   }
   for (vector<DetId>::const_iterator it = eeCells.begin(); it != eeCells.end(); ++it) {
     EEDetId id(*it);
     const EcalTrigTowerDetId towid = (*eTTmap_).towerOf(id);
     const EcalTriggerElectronicsId elId = theMapping_->getTriggerElectronicsId(id);
     int tccNb = theMapping_->TCCid(towid);
     int towerInTCC = theMapping_->iTT(towid);
     int stripInTower = elId.pseudoStripId();
     if (stripInTower > NbOfStripPerTCC[tccNb - 1][towerInTCC - 1])
       NbOfStripPerTCC[tccNb - 1][towerInTCC - 1] = stripInTower;
   }
 
   // loop on EB xtals
   if (writeToFiles_)
     (*out_file_) << "COMMENT ====== barrel crystals ====== " << std::endl;
 
   // special case of eta slices
   for (vector<DetId>::const_iterator it = ebCells.begin(); it != ebCells.end(); ++it) {
     EBDetId id(*it);
     double theta = theBarrelGeometry_->getGeometry(id)->getPosition().theta();
     if (!useTransverseEnergy_)
       theta = acos(0.);
     const EcalTrigTowerDetId towid = id.tower();
     const EcalTriggerElectronicsId elId = theMapping_->getTriggerElectronicsId(id);
     int dccNb = theMapping_->DCCid(towid);
     int tccNb = theMapping_->TCCid(towid);
     int towerInTCC = theMapping_->iTT(towid);  // from 1 to 68 (EB)
     int stripInTower = elId.pseudoStripId();   // from 1 to 5
     int xtalInStrip = elId.channelId();        // from 1 to 5
     const EcalElectronicsId Id = theMapping_->getElectronicsId(id);
     int CCUid = Id.towerId();
     int VFEid = Id.stripId();
     int xtalInVFE = Id.xtalId();
     int xtalWithinCCUid = 5 * (VFEid - 1) + xtalInVFE - 1;  // Evgueni expects [0,24]
 
     (*geomFile_) << "dccNb = " << dccNb << " tccNb = " << tccNb << " towerInTCC = " << towerInTCC
                  << " stripInTower = " << stripInTower << " xtalInStrip = " << xtalInStrip << " CCUid = " << CCUid
                  << " VFEid = " << VFEid << " xtalInVFE = " << xtalInVFE << " xtalWithinCCUid = " << xtalWithinCCUid
                  << " ieta = " << id.ieta() << " iphi = " << id.iphi() << " xtalhashedId = " << id.hashedIndex()
                  << " xtalNb = " << id.ic() << " ietaTT = " << towid.ieta() << " iphiTT = " << towid.iphi()
                  << std::endl;
 
     int TCCch = towerInTCC;
     int SLBslot = int((towerInTCC - 1) / 8.) + 1;
     int SLBch = (towerInTCC - 1) % 8 + 1;
     int cmsswId = id.rawId();
     int ixtal = (id.ism() - 1) * 1700 + (id.ic() - 1);
     EcalLogicID logicId = my_EcalLogicId[ixtal];
     int dbId = logicId.getLogicID();
     int val[] = {dccNb + 600,
                  tccNb,
                  towerInTCC,
                  stripInTower,
                  xtalInStrip,
                  CCUid,
                  VFEid,
                  xtalInVFE,
                  xtalWithinCCUid,
                  id.ieta(),
                  id.iphi(),
                  -999,
                  -999,
                  towid.ieta() / abs(towid.ieta()),
                  id.hashedIndex(),
                  id.ic(),
                  cmsswId,
                  dbId,
                  towid.ieta(),
                  towid.iphi(),
                  TCCch,
                  getCrate(tccNb).second,
                  SLBch,
                  SLBslot,
                  getGCTRegionEta(towid.ieta()),
                  getGCTRegionPhi(towid.iphi())};
     for (int i = 0; i < 26; i++)
       ntupleInts_[i] = val[i];
 
     strcpy(ntupleDet_, getDet(tccNb).c_str());
     strcpy(ntupleCrate_, getCrate(tccNb).first.c_str());
     ntuple->Fill();
 
     if (tccNb == 37 && stripInTower == 3 && xtalInStrip == 3 && (towerInTCC - 1) % 4 == 0) {
       int etaSlice = towid.ietaAbs();
       coeffStruc coeff;
       //getCoeff(coeff, calibMap, id.rawId()) ;
       //modif-alex-27-july-2015
       string str;
       getCoeff(coeff, calibMap, laserAlphaMap, id.rawId(), str);
       ss << str;
       getCoeff(coeff, gainMap, id.rawId());
       getCoeff(coeff, pedMap, id.rawId());
       linStruc lin;
       for (int i = 0; i < 3; i++) {
         lin.pedestal_[i] = coeff.pedestals_[i];
         lin.mult_[i] = 0;
         lin.shift_[i] = 0;
         int mult = 0;
         int shift = 0;
         bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EB", mult, shift);
         if (!ok) {
           //If the mult is impossible to compute
           if (mult > 255) {
             edm::LogError("TopInfo") << "ByEtaSlice: unable to compute the parameters for SM=" << id.ism()
                                      << " xt=" << id.ic() << " " << dec << id.rawId() << " gainId=" << i
                                      << ", mult too large! forced to mult=255, shift=0\n";
             lin.mult_[i] = 255;
             lin.shift_[i] = 0;
           } else if (mult < 128) {
             edm::LogError("TopInfo") << "ByEtaSlice: unable to compute the parameters for SM=" << id.ism()
                                      << " xt=" << id.ic() << " " << dec << id.rawId() << " gainId=" << i
                                      << ", mult too small! forced to mult=128, shift=15\n";
             ;
             lin.mult_[i] = 128;
             lin.shift_[i] = 15;
           }
         } else {
           lin.mult_[i] = mult;
           lin.shift_[i] = shift;
         }
       }
 
       bool ok(true);
       if (forcedPedestalValue_ == -2)
         ok = realignBaseline(lin, 0, id.rawId());
       if (!ok)
         ss << "SM=" << id.ism() << " xt=" << id.ic() << " " << dec << id.rawId() << "\n";
       linEtaSlice[etaSlice] = lin;
     }
   }
 
   // general case
   for (vector<DetId>::const_iterator it = ebCells.begin(); it != ebCells.end(); ++it) {
     EBDetId id(*it);
     double theta = theBarrelGeometry_->getGeometry(id)->getPosition().theta();
     if (!useTransverseEnergy_)
       theta = acos(0.);
     const EcalTrigTowerDetId towid = id.tower();
     towerListEB.push_back(towid.rawId());
     const EcalTriggerElectronicsId elId = theMapping_->getTriggerElectronicsId(id);
     stripListEB.push_back(elId.rawId() & 0xfffffff8);
     int dccNb = theMapping_->DCCid(towid);
     //int tccNb = theMapping_->TCCid(towid) ;
     int towerInTCC = theMapping_->iTT(towid);  // from 1 to 68 (EB)
     //int stripInTower = elId.pseudoStripId() ;  // from 1 to 5
     //int xtalInStrip = elId.channelId() ;       // from 1 to 5
     const EcalElectronicsId Id = theMapping_->getElectronicsId(id);
     int CCUid = Id.towerId();
     int VFEid = Id.stripId();
     int xtalInVFE = Id.xtalId();
     int xtalWithinCCUid = 5 * (VFEid - 1) + xtalInVFE - 1;  // Evgueni expects [0,24]
     int etaSlice = towid.ietaAbs();
 
     // hashed index of strip EcalLogicID:
     int hashedStripLogicID = 68 * 5 * (id.ism() - 1) + 5 * (towerInTCC - 1) + (VFEid - 1);
     stripMapEB[hashedStripLogicID] = elId.rawId() & 0xfffffff8;
     stripMapEBsintheta[elId.rawId() & 0xfffffff8] = SFGVB_Threshold_ + abs(int(sin(theta) * pedestal_offset_));
 
     //modif-debug
     /*
     FEConfigFgrEEStripDat stripdebug;
     EcalLogicID thestrip_debug = my_StripEcalLogicId[hashedStripLogicID] ;
     if(towid.ieta() == 6 && towid.iphi() == 7){
       std::cout << "xtal info=" << id << " VFE=" << VFEid << std::endl;
       std::cout << "TOWER DEBUG ieta=" << towid.ieta() << " iphi=" << towid.iphi() << " SFGVB=" << SFGVB_Threshold_ + abs(int(sin(theta)*pedestal_offset_)) 
         << " dbId=" << (elId.rawId() & 0xfffffff8) << " " << hashedStripLogicID << " " << thestrip_debug.getLogicID() << std::endl;  //modif-debug
     }//EB+3 TT24
     */
     //std::cout<<std::dec<<SFGVB_Threshold_ + abs(int(sin(theta)*pedestal_offset_))<<" "<<SFGVB_Threshold_<<" "<<abs(int(sin(theta)*pedestal_offset_))<<std::endl ;
 
     FEConfigPedDat pedDB;
     FEConfigLinDat linDB;
     if (writeToFiles_)
       (*out_file_) << "CRYSTAL " << dec << id.rawId() << std::endl;
     //  if (writeToDB_) logicId = db_->getEcalLogicID ("EB_crystal_number", id.ism(), id.ic()) ;
 
     coeffStruc coeff;
     //getCoeff(coeff, calibMap, id.rawId()) ;
     //modif-alex-27-july-2015
     std::string str;
     getCoeff(coeff, calibMap, laserAlphaMap, id.rawId(), str);
     ss << str;
 
     if (H2_)
       coeff.calibCoeff_ = calibvec[id.ic() - 1];
     getCoeff(coeff, gainMap, id.rawId());
     getCoeff(coeff, pedMap, id.rawId());
     ICEB->Fill(id.iphi(), id.ieta(), coeff.calibCoeff_);
     IC->Fill(theBarrelGeometry_->getGeometry(id)->getPosition().phi(),
              theBarrelGeometry_->getGeometry(id)->getPosition().eta(),
              coeff.calibCoeff_);
 
     vector<int> xtalCCU;
     xtalCCU.push_back(dccNb + 600);
     xtalCCU.push_back(CCUid);
     xtalCCU.push_back(xtalWithinCCUid);
     xtalCCU.push_back(id.rawId());
 
     // compute and fill linearization parameters
     // case of eta slice
     if (forceEtaSlice_) {
       map<int, linStruc>::const_iterator itLin = linEtaSlice.find(etaSlice);
       if (itLin != linEtaSlice.end()) {
         linMap[xtalCCU] = itLin->second;
         if (writeToFiles_) {
           for (int i = 0; i < 3; i++)
             (*out_file_) << hex << " 0x" << itLin->second.pedestal_[i] << " 0x" << itLin->second.mult_[i] << " 0x"
                          << itLin->second.shift_[i] << std::endl;
         }
         if (writeToDB_) {
           for (int i = 0; i < 3; i++) {
             if (i == 0) {
               pedDB.setPedMeanG12(itLin->second.pedestal_[i]);
               linDB.setMultX12(itLin->second.mult_[i]);
               linDB.setShift12(itLin->second.shift_[i]);
             } else if (i == 1) {
               pedDB.setPedMeanG6(itLin->second.pedestal_[i]);
               linDB.setMultX6(itLin->second.mult_[i]);
               linDB.setShift6(itLin->second.shift_[i]);
             } else if (i == 2) {
               pedDB.setPedMeanG1(itLin->second.pedestal_[i]);
               linDB.setMultX1(itLin->second.mult_[i]);
               linDB.setShift1(itLin->second.shift_[i]);
             }
           }
         }
         float factor = float(itLin->second.mult_[0]) * pow(2., -itLin->second.shift_[0]) / xtal_LSB_EB_;
         tpgFactorEB->Fill(id.iphi(), id.ieta(), factor);
         tpgFactor->Fill(theBarrelGeometry_->getGeometry(id)->getPosition().phi(),
                         theBarrelGeometry_->getGeometry(id)->getPosition().eta(),
                         factor);
       } else
         ss << "current EtaSlice = " << etaSlice << " not found in the EtaSlice map"
            << "\n";
     } else {
       // general case
       linStruc lin;
       int forceBase12 = 0;
       double invSinTheta = 1. / sin(theta);
       for (int i = 0; i < 3; i++) {
         lin.pedestal_[i] = coeff.pedestals_[i];
         lin.mult_[i] = 0;
         lin.shift_[i] = 0;
         int mult = 0;
         int shift = 0;
         bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EB", mult, shift);
         if (!ok) {
           //If the mult is impossible to compute
           if (mult > 255) {
             edm::LogError("TopInfo") << "unable to compute the parameters for " << dec << id.rawId()
                                      << ", EB, gainId=" << i << ", mult too large! forced to mult=255, shift=0\n";
             lin.mult_[i] = 255;
             lin.shift_[i] = 0;
           } else if (mult < 128) {
             edm::LogError("TopInfo") << "unable to compute the parameters for " << dec << id.rawId()
                                      << ", EB, gainId=" << i << ", mult too small! forced to mult=128, shift=15\n";
             lin.mult_[i] = 128;
             lin.shift_[i] = 15;
           }
         } else {
           lin.mult_[i] = mult;
           lin.shift_[i] = shift;
         }
         // Force baseline for gain 12 also when mult not ok and the value is set to default
         if (forcedPedestalValue_ == -3 && i == 0) {
           double G = mult * pow(2.0, -(shift + 2));
           double g = G * invSinTheta;
           double base = double(coeff.pedestals_[i]) - pedestal_offset_ / g;
           if (base < 0.)
             base = 0;
           forceBase12 = int(base);
         }
       }
 
       bool ok(true);
       if (forcedPedestalValue_ == -2)
         ok = realignBaseline(lin, 0, id.rawId());
       else if (forcedPedestalValue_ == -3)
         ok = realignBaseline(lin, forceBase12, id.rawId());
       if (!ok)
         ss << "SM=" << id.ism() << " xt=" << id.ic() << " " << dec << id.rawId() << "\n";
 
       for (int i = 0; i < 3; i++) {
         if (writeToFiles_)
           (*out_file_) << hex << " 0x" << lin.pedestal_[i] << " 0x" << lin.mult_[i] << " 0x" << lin.shift_[i]
                        << std::endl;
         if (writeToDB_) {
           if (i == 0) {
             pedDB.setPedMeanG12(lin.pedestal_[i]);
             linDB.setMultX12(lin.mult_[i]);
             linDB.setShift12(lin.shift_[i]);
           } else if (i == 1) {
             pedDB.setPedMeanG6(lin.pedestal_[i]);
             linDB.setMultX6(lin.mult_[i]);
             linDB.setShift6(lin.shift_[i]);
           } else if (i == 2) {
             pedDB.setPedMeanG1(lin.pedestal_[i]);
             linDB.setMultX1(lin.mult_[i]);
             linDB.setShift1(lin.shift_[i]);
           }
         }
         if (i == 0) {
           float factor = float(lin.mult_[i]) * pow(2., -lin.shift_[i]) / xtal_LSB_EB_;
           tpgFactorEB->Fill(id.iphi(), id.ieta(), factor);
           tpgFactor->Fill(theBarrelGeometry_->getGeometry(id)->getPosition().phi(),
                           theBarrelGeometry_->getGeometry(id)->getPosition().eta(),
                           factor);
         }
         double G = lin.mult_[i] * pow(2.0, -(lin.shift_[i] + 2));
         double g = G * invSinTheta;
         float val[] = {float(i),
                        float(theta),
                        float(G),
                        float(g),
                        float(coeff.pedestals_[i]),
                        float(lin.pedestal_[i])};  // first arg = gainId (0 means gain12)
         ntupleSpike->Fill(val);
       }
       linMap[xtalCCU] = lin;
     }
     if (writeToDB_) {
       // 1700 crystals/SM in the ECAL barrel
       int ixtal = (id.ism() - 1) * 1700 + (id.ic() - 1);
       EcalLogicID logicId = my_EcalLogicId[ixtal];
       pedset[logicId] = pedDB;
       linset[logicId] = linDB;
     }
   }  //ebCells
 
   if (writeToDB_) {
     // EcalLogicID  of the whole barrel is: my_EcalLogicId_EB
     FEConfigLinParamDat linparam;
     linparam.setETSat(Et_sat_EB_);
     linparamset[my_EcalLogicId_EB] = linparam;
 
     FEConfigFgrParamDat fgrparam;
     fgrparam.setFGlowthresh(FG_lowThreshold_EB_);
     fgrparam.setFGhighthresh(FG_highThreshold_EB_);
     fgrparam.setFGlowratio(FG_lowRatio_EB_);
     fgrparam.setFGhighratio(FG_highRatio_EB_);
     fgrparamset[my_EcalLogicId_EB] = fgrparam;
 
     FEConfigLUTParamDat lutparam;
     lutparam.setETSat(Et_sat_EB_);
     lutparam.setTTThreshlow(TTF_lowThreshold_EB_);
     lutparam.setTTThreshhigh(TTF_highThreshold_EB_);
     lutparamset[my_EcalLogicId_EB] = lutparam;
   }
 
   // loop on EE xtals
   if (writeToFiles_)
     (*out_file_) << "COMMENT ====== endcap crystals ====== " << std::endl;
 
   // special case of eta slices
   for (vector<DetId>::const_iterator it = eeCells.begin(); it != eeCells.end(); ++it) {
     EEDetId id(*it);
     double theta = theEndcapGeometry_->getGeometry(id)->getPosition().theta();
     if (!useTransverseEnergy_)
       theta = acos(0.);
     const EcalTrigTowerDetId towid = (*eTTmap_).towerOf(id);
     const EcalTriggerElectronicsId elId = theMapping_->getTriggerElectronicsId(id);
     const EcalElectronicsId Id = theMapping_->getElectronicsId(id);
     int dccNb = Id.dccId();
     int tccNb = theMapping_->TCCid(towid);
     int towerInTCC = theMapping_->iTT(towid);
     int stripInTower = elId.pseudoStripId();
     int xtalInStrip = elId.channelId();
     int CCUid = Id.towerId();
     int VFEid = Id.stripId();
     int xtalInVFE = Id.xtalId();
     int xtalWithinCCUid = 5 * (VFEid - 1) + xtalInVFE - 1;  // Evgueni expects [0,24]
 
     // Creating the stripMap for EE
     bool foundStripLogic = false;
     for (EcalLogicID& stripLogicId : my_StripEcalLogicId1_EE) {
       if (stripLogicId.getID1() == 600 + dccNb && stripLogicId.getID2() == CCUid && stripLogicId.getID3() == VFEid) {
         stripMapEE[stripLogicId.getLogicID()] = elId.rawId() & 0xfffffff8;
         foundStripLogic = true;
         break;
       }
     }
     if (!foundStripLogic) {
       for (EcalLogicID& stripLogicId : my_StripEcalLogicId2_EE) {
         if (stripLogicId.getID1() == 600 + dccNb && stripLogicId.getID2() == CCUid && stripLogicId.getID3() == VFEid) {
           stripMapEE[stripLogicId.getLogicID()] = elId.rawId() & 0xfffffff8;
           foundStripLogic = true;
           break;
         }
       }
     }
     if (!foundStripLogic) {
       edm::LogWarning("TopInfo") << "Strip ID not found for DCC: " << 600 + dccNb << " CCU: " << CCUid
                                  << " VFEid: " << VFEid;
     }
 
     (*geomFile_) << "dccNb = " << dccNb << " tccNb = " << tccNb << " towerInTCC = " << towerInTCC
                  << " stripInTower = " << stripInTower << " xtalInStrip = " << xtalInStrip << " CCUid = " << CCUid
                  << " VFEid = " << VFEid << " xtalInVFE = " << xtalInVFE << " xtalWithinCCUid = " << xtalWithinCCUid
                  << " ix = " << id.ix() << " iy = " << id.iy() << " xtalhashedId = " << id.hashedIndex()
                  << " xtalNb = " << id.isc() << " ietaTT = " << towid.ieta() << " iphiTT = " << towid.iphi()
                  << std::endl;
 
     int TCCch = stripInTower;
     int SLBslot, SLBch;
     if (towerInTCC < 5) {
       SLBslot = 1;
       SLBch = 4 + towerInTCC;
     } else {
       SLBslot = int((towerInTCC - 5) / 8.) + 2;
       SLBch = (towerInTCC - 5) % 8 + 1;
     }
     for (int j = 0; j < towerInTCC - 1; j++)
       TCCch += NbOfStripPerTCC[tccNb - 1][j];
 
     int cmsswId = id.rawId();
     EcalLogicID logicId;
     int iz = id.positiveZ();
     if (iz == 0)
       iz = -1;
     for (int k = 0; k < (int)my_CrystalEcalLogicId_EE.size(); k++) {
       int z = my_CrystalEcalLogicId_EE[k].getID1();
       int x = my_CrystalEcalLogicId_EE[k].getID2();
       int y = my_CrystalEcalLogicId_EE[k].getID3();
       if (id.ix() == x && id.iy() == y && iz == z)
         logicId = my_CrystalEcalLogicId_EE[k];
     }
     int dbId = logicId.getLogicID();
 
     int val[] = {dccNb + 600,
                  tccNb,
                  towerInTCC,
                  stripInTower,
                  xtalInStrip,
                  CCUid,
                  VFEid,
                  xtalInVFE,
                  xtalWithinCCUid,
                  -999,
                  -999,
                  id.ix(),
                  id.iy(),
                  towid.ieta() / abs(towid.ieta()),
                  id.hashedIndex(),
                  id.ic(),
                  cmsswId,
                  dbId,
                  towid.ieta(),
                  towid.iphi(),
                  TCCch,
                  getCrate(tccNb).second,
                  SLBch,
                  SLBslot,
                  getGCTRegionEta(towid.ieta()),
                  getGCTRegionPhi(towid.iphi())};
     for (int i = 0; i < 26; i++)
       ntupleInts_[i] = val[i];
     strcpy(ntupleDet_, getDet(tccNb).c_str());
     strcpy(ntupleCrate_, getCrate(tccNb).first.c_str());
     ntuple->Fill();
 
     if ((tccNb == 76 || tccNb == 94) && stripInTower == 1 && xtalInStrip == 3 && (towerInTCC - 1) % 4 == 0) {
       int etaSlice = towid.ietaAbs();
       coeffStruc coeff;
       //getCoeff(coeff, calibMap, id.rawId()) ;
       //modif-alex-27-july-2015
       std::string str;
       getCoeff(coeff, calibMap, laserAlphaMap, id.rawId(), str);
       ss << str;
       getCoeff(coeff, gainMap, id.rawId());
       getCoeff(coeff, pedMap, id.rawId());
       linStruc lin;
       for (int i = 0; i < 3; i++) {
         lin.pedestal_[i] = coeff.pedestals_[i];
         lin.mult_[i] = 0;
         lin.shift_[i] = 0;
         int mult = 0;
         int shift = 0;
         bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EE", mult, shift);
         if (!ok) {
           //If the mult is impossible to compute
           if (mult > 255) {
             edm::LogError("TopInfo") << "ByEtaSlice: unable to compute the parameters for Quadrant=" << id.iquadrant()
                                      << " xt=" << id.ic() << " " << dec << id.rawId() << " gainId=" << i
                                      << ", mult too large! forced to mult=255, shift=0\n";
             lin.mult_[i] = 255;
             lin.shift_[i] = 0;
           } else if (mult < 128) {
             edm::LogError("TopInfo") << "ByEtaSlice: unable to compute the parameters for Quadrant=" << id.iquadrant()
                                      << " xt=" << id.ic() << " " << dec << id.rawId() << " gainId=" << i
                                      << ", mult too small! forced to mult=128, shift=15\n";
             ;
             lin.mult_[i] = 128;
             lin.shift_[i] = 15;
           }
         } else {
           lin.mult_[i] = mult;
           lin.shift_[i] = shift;
         }
       }
 
       bool ok(true);
       if (forcedPedestalValue_ == -2 || forcedPedestalValue_ == -3)
         ok = realignBaseline(lin, 0, id.rawId());
       if (!ok)
         ss << "Quadrant=" << id.iquadrant() << " xt=" << id.ic() << " " << dec << id.rawId() << "\n";
 
       linEtaSlice[etaSlice] = lin;
     }
   }
 
   // general case
   for (vector<DetId>::const_iterator it = eeCells.begin(); it != eeCells.end(); ++it) {
     EEDetId id(*it);
     double theta = theEndcapGeometry_->getGeometry(id)->getPosition().theta();
     if (!useTransverseEnergy_)
       theta = acos(0.);
     const EcalTrigTowerDetId towid = (*eTTmap_).towerOf(id);
     const EcalTriggerElectronicsId elId = theMapping_->getTriggerElectronicsId(id);
     const EcalElectronicsId Id = theMapping_->getElectronicsId(id);
     towerListEE.push_back(towid.rawId());
     // special case of towers in inner rings of EE
     if (towid.ietaAbs() == 27 || towid.ietaAbs() == 28) {
       EcalTrigTowerDetId additionalTower(towid.zside(), towid.subDet(), towid.ietaAbs(), towid.iphi() + 1);
       towerListEE.push_back(additionalTower.rawId());
     }
     stripListEE.push_back(elId.rawId() & 0xfffffff8);
 
     int dccNb = Id.dccId();
     //int tccNb = theMapping_->TCCid(towid) ;
     //int towerInTCC = theMapping_->iTT(towid) ;
     //int stripInTower = elId.pseudoStripId() ;
     //int xtalInStrip = elId.channelId() ;
     int CCUid = Id.towerId();
     int VFEid = Id.stripId();
     int xtalInVFE = Id.xtalId();
     int xtalWithinCCUid = 5 * (VFEid - 1) + xtalInVFE - 1;  // Evgueni expects [0,24]
     int etaSlice = towid.ietaAbs();
 
     EcalLogicID logicId;
     FEConfigPedDat pedDB;
     FEConfigLinDat linDB;
     if (writeToFiles_)
       (*out_file_) << "CRYSTAL " << dec << id.rawId() << std::endl;
     if (writeToDB_ && DBEE_) {
       int iz = id.positiveZ();
       if (iz == 0)
         iz = -1;
       for (int k = 0; k < (int)my_CrystalEcalLogicId_EE.size(); k++) {
         int z = my_CrystalEcalLogicId_EE[k].getID1();
         int x = my_CrystalEcalLogicId_EE[k].getID2();
         int y = my_CrystalEcalLogicId_EE[k].getID3();
         if (id.ix() == x && id.iy() == y && iz == z) {
           logicId = my_CrystalEcalLogicId_EE[k];
         }
       }
     }
 
     coeffStruc coeff;
     //getCoeff(coeff, calibMap, id.rawId()) ;
     //modif-alex-27-july-2015
     string str;
     getCoeff(coeff, calibMap, laserAlphaMap, id.rawId(), str);
     ss << str;
     getCoeff(coeff, gainMap, id.rawId());
     getCoeff(coeff, pedMap, id.rawId());
     if (id.zside() > 0)
       ICEEPlus->Fill(id.ix(), id.iy(), coeff.calibCoeff_);
     else
       ICEEMinus->Fill(id.ix(), id.iy(), coeff.calibCoeff_);
     IC->Fill(theEndcapGeometry_->getGeometry(id)->getPosition().phi(),
              theEndcapGeometry_->getGeometry(id)->getPosition().eta(),
              coeff.calibCoeff_);
 
     vector<int> xtalCCU;
     xtalCCU.push_back(dccNb + 600);
     xtalCCU.push_back(CCUid);
     xtalCCU.push_back(xtalWithinCCUid);
     xtalCCU.push_back(id.rawId());
 
     // compute and fill linearization parameters
     // case of eta slice
     if (forceEtaSlice_) {
       map<int, linStruc>::const_iterator itLin = linEtaSlice.find(etaSlice);
       if (itLin != linEtaSlice.end()) {
         linMap[xtalCCU] = itLin->second;
         if (writeToFiles_) {
           for (int i = 0; i < 3; i++)
             (*out_file_) << hex << " 0x" << itLin->second.pedestal_[i] << " 0x" << itLin->second.mult_[i] << " 0x"
                          << itLin->second.shift_[i] << std::endl;
         }
         if (writeToDB_ && DBEE_) {
           for (int i = 0; i < 3; i++) {
             if (i == 0) {
               pedDB.setPedMeanG12(itLin->second.pedestal_[i]);
               linDB.setMultX12(itLin->second.mult_[i]);
               linDB.setShift12(itLin->second.shift_[i]);
             } else if (i == 1) {
               pedDB.setPedMeanG6(itLin->second.pedestal_[i]);
               linDB.setMultX6(itLin->second.mult_[i]);
               linDB.setShift6(itLin->second.shift_[i]);
             } else if (i == 2) {
               pedDB.setPedMeanG1(itLin->second.pedestal_[i]);
               linDB.setMultX1(itLin->second.mult_[i]);
               linDB.setShift1(itLin->second.shift_[i]);
             }
           }
         }
         float factor = float(itLin->second.mult_[0]) * pow(2., -itLin->second.shift_[0]) / xtal_LSB_EE_;
         if (id.zside() > 0)
           tpgFactorEEPlus->Fill(id.ix(), id.iy(), factor);
         else
           tpgFactorEEMinus->Fill(id.ix(), id.iy(), factor);
         tpgFactor->Fill(theEndcapGeometry_->getGeometry(id)->getPosition().phi(),
                         theEndcapGeometry_->getGeometry(id)->getPosition().eta(),
                         factor);
       } else
         ss << "current EtaSlice = " << etaSlice << " not found in the EtaSlice map"
            << "\n";
     } else {
       // general case
       linStruc lin;
       for (int i = 0; i < 3; i++) {
         lin.pedestal_[i] = coeff.pedestals_[i];
         lin.mult_[i] = 0;
         lin.shift_[i] = 0;
         int mult = 0;
         int shift = 0;
         bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EE", mult, shift);
         if (!ok) {
           //If the mult is impossible to compute
           if (mult > 255) {
             edm::LogError("TopInfo") << "unable to compute the parameters for " << dec << id.rawId()
                                      << ", EE, gainId=" << i << ", mult too large! forced to mult=255, shift=0\n";
             lin.mult_[i] = 255;
             lin.shift_[i] = 0;
           } else if (mult < 128) {
             edm::LogError("TopInfo") << "unable to compute the parameters for " << dec << id.rawId()
                                      << ", EE, gainId=" << i << ", mult too small! forced to mult=128, shift=15\n";
             lin.mult_[i] = 128;
             lin.shift_[i] = 15;
           }
         } else {
           lin.mult_[i] = mult;
           lin.shift_[i] = shift;
         }
       }
 
       bool ok(true);
       if (forcedPedestalValue_ == -2 || forcedPedestalValue_ == -3)
         ok = realignBaseline(lin, 0, id.rawId());
       if (!ok)
         ss << "Quadrant=" << id.iquadrant() << " xt=" << id.ic() << " " << dec << id.rawId() << "\n";
 
       for (int i = 0; i < 3; i++) {
         if (writeToFiles_)
           (*out_file_) << hex << " 0x" << lin.pedestal_[i] << " 0x" << lin.mult_[i] << " 0x" << lin.shift_[i]
                        << std::endl;
         if (writeToDB_ && DBEE_) {
           if (i == 0) {
             pedDB.setPedMeanG12(lin.pedestal_[i]);
             linDB.setMultX12(lin.mult_[i]);
             linDB.setShift12(lin.shift_[i]);
           } else if (i == 1) {
             pedDB.setPedMeanG6(lin.pedestal_[i]);
             linDB.setMultX6(lin.mult_[i]);
             linDB.setShift6(lin.shift_[i]);
           } else if (i == 2) {
             pedDB.setPedMeanG1(lin.pedestal_[i]);
             linDB.setMultX1(lin.mult_[i]);
             linDB.setShift1(lin.shift_[i]);
           }
         }
         if (i == 0) {
           float factor = float(lin.mult_[i]) * pow(2., -lin.shift_[i]) / xtal_LSB_EE_;
           if (id.zside() > 0)
             tpgFactorEEPlus->Fill(id.ix(), id.iy(), factor);
           else
             tpgFactorEEMinus->Fill(id.ix(), id.iy(), factor);
           tpgFactor->Fill(theEndcapGeometry_->getGeometry(id)->getPosition().phi(),
                           theEndcapGeometry_->getGeometry(id)->getPosition().eta(),
                           factor);
         }
       }
       linMap[xtalCCU] = lin;
     }
     if (writeToDB_ && DBEE_) {
       pedset[logicId] = pedDB;
       linset[logicId] = linDB;
     }
   }  //eeCells
   edm::LogInfo("TopInfo") << ss.str();
   ss.str("");
 
   if (writeToDB_) {
     // EcalLogicID  of the whole barrel is: my_EcalLogicId_EB
     FEConfigLinParamDat linparam;
     linparam.setETSat(Et_sat_EE_);
     linparamset[my_EcalLogicId_EE] = linparam;
 
     FEConfigLUTParamDat lutparam;
     lutparam.setETSat(Et_sat_EE_);
     lutparam.setTTThreshlow(TTF_lowThreshold_EE_);
     lutparam.setTTThreshhigh(TTF_highThreshold_EE_);
     lutparamset[my_EcalLogicId_EE] = lutparam;
 
     FEConfigFgrParamDat fgrparam;
     fgrparam.setFGlowthresh(FG_Threshold_EE_);
     fgrparam.setFGhighthresh(FG_Threshold_EE_);
     fgrparamset[my_EcalLogicId_EE] = fgrparam;
   }
 
   if (writeToDB_) {
     ostringstream ltag;
     ltag.str("EB_");
     ltag << Et_sat_EB_ << "_EE_" << Et_sat_EE_;
     std::string lin_tag = ltag.str();
     ss << " LIN tag " << lin_tag << "\n";
 
     if (m_write_ped == 1) {
       ped_conf_id_ = db_->writeToConfDB_TPGPedestals(pedset, 1, "from_OfflineDB");
     } else {
       ss << "the ped id =" << ped_conf_id_ << " will be used for the pedestals "
          << "\n";
     }
 
     if (m_write_lin == 1)
       lin_conf_id_ = db_->writeToConfDB_TPGLinearCoef(linset, linparamset, 1, lin_tag);
   }
 
   // Evgueni interface
   std::ofstream evgueni("TPG_hardcoded.hh", std::ios::out);
   evgueni << "void getLinParamTPG_hardcoded(int fed, int ccu, int xtal," << std::endl;
   evgueni << "                        int & mult12, int & shift12, int & base12," << std::endl;
   evgueni << "                        int & mult6, int & shift6, int & base6," << std::endl;
   evgueni << "                        int & mult1, int & shift1, int & base1)" << std::endl;
   evgueni << "{" << std::endl;
   evgueni << "  mult12 = 0 ; shift12 = 0 ; base12 = 0 ; mult6 = 0 ; shift6 = 0 ; base6 = 0 ; mult1 = 0 ; shift1 = 0 ; "
              "base1 = 0 ;"
           << std::endl;
   map<vector<int>, linStruc>::const_iterator itLinMap;
   for (itLinMap = linMap.begin(); itLinMap != linMap.end(); itLinMap++) {
     vector<int> xtalInCCU = itLinMap->first;
     evgueni << "  if (fed==" << xtalInCCU[0] << " && ccu==" << xtalInCCU[1] << " && xtal==" << xtalInCCU[2] << ") {";
     evgueni << "  mult12 = " << itLinMap->second.mult_[0] << " ; shift12 = " << itLinMap->second.shift_[0]
             << " ; base12 = " << itLinMap->second.pedestal_[0] << " ; ";
     evgueni << "  mult6 = " << itLinMap->second.mult_[1] << " ; shift6 = " << itLinMap->second.shift_[1]
             << " ; base6 = " << itLinMap->second.pedestal_[1] << " ; ";
     evgueni << "  mult1 = " << itLinMap->second.mult_[2] << " ; shift1 = " << itLinMap->second.shift_[2]
             << " ; base1 = " << itLinMap->second.pedestal_[2] << " ; ";
     evgueni << "  return ;}" << std::endl;
   }
   evgueni << "}" << std::endl;
   evgueni.close();
 
   // Compute weights section //
 
   std::map<int, int> weights_map_even;
   std::map<int, int> weights_map_odd;
 
   if (weight_even_computeFromShape_) {
     // Computing the weights from shapes, 1 set for EB and 1 for EE only
     shapeEB_.setEventSetup(evtSetup);  // EBShape, EEShape are fetched now from DB (2018.05.22 K. Theofilatos)
     shapeEE_.setEventSetup(evtSetup);
     const int NWEIGROUPS = 2;
     std::vector<unsigned int> weights[NWEIGROUPS];
     weights[0] = computeWeights(shapeEB_, hshapeEB);
     weights[1] = computeWeights(shapeEE_, hshapeEE);
 
     map<EcalLogicID, FEConfigWeightGroupDat> dataset;
 
     for (int igrp = 0; igrp < NWEIGROUPS; igrp++) {
       if (weights[igrp].size() == EcalTPGParamBuilder::NWEIGHTS) {
         if (writeToFiles_) {
           (*out_file_) << std::endl;
           (*out_file_) << "WEIGHT " << dec << igrp << std::endl;
           for (unsigned int sample = 0; sample < EcalTPGParamBuilder::NWEIGHTS; sample++)
             (*out_file_) << "0x" << hex << weights[igrp][sample] << " ";
           (*out_file_) << std::endl;
           (*out_file_) << std::endl;
         }
         if (writeToDB_) {
           ss << "going to write the weights for group:" << igrp << "\n";
           FEConfigWeightGroupDat gut;
           gut.setWeightGroupId(igrp);
           //PP WARNING: weights order is reverted when stored in the DB
           gut.setWeight0(weights[igrp][4]);
           gut.setWeight1(weights[igrp][3] +
                          0x80);  //0x80 to identify the max of the pulse in the FENIX (doesn't exist in emulator)
           gut.setWeight2(weights[igrp][2]);
           gut.setWeight3(weights[igrp][1]);
           gut.setWeight4(weights[igrp][0]);
           EcalLogicID ecid = EcalLogicID("DUMMY", igrp, igrp);  //1 dummy ID per group
           // Fill the dataset
           dataset[ecid] = gut;
         }
       }
     }
     // now we store in the DB the correspondence btw channels and groups
     map<EcalLogicID, FEConfigWeightDat> dataset2;
     // EB loop
     for (int ich = 0; ich < (int)my_StripEcalLogicId.size(); ich++) {
       FEConfigWeightDat wut;
       int igroup = 0;  // this group is for EB
       weights_map_even[stripMapEB[ich]] = 0;
       wut.setWeightGroupId(igroup);
       dataset2[my_StripEcalLogicId[ich]] = wut;
     }
 
     // EE loop
     for (EcalLogicID& stripLogicId : my_StripEcalLogicId1_EE) {
       FEConfigWeightDat wut;
       int igroup = 1;  // this group is for EE
       weights_map_even[stripMapEE[stripLogicId.getLogicID()]] = 1;
       wut.setWeightGroupId(igroup);
       // Fill the dataset
       dataset2[stripLogicId] = wut;
     }
     // EE loop 2 (we had to split the ids of EE in 2 vectors to avoid crash!)
     for (EcalLogicID& stripLogicId : my_StripEcalLogicId2_EE) {
       FEConfigWeightDat wut;
       int igroup = 1;  // this group is for EE
       weights_map_even[stripMapEE[stripLogicId.getLogicID()]] = 1;
       wut.setWeightGroupId(igroup);
       // Fill the dataset
       dataset2[stripLogicId] = wut;
     }
 
     if (writeToDB_) {
       // Insert the datasets
       ostringstream wtag;
       wtag.str("");
       wtag << "Shape_NGroups_" << NWEIGROUPS;
       std::string weight_tag = wtag.str();
       ss << " weight tag " << weight_tag << "\n";
       if (m_write_wei == 1)
         wei_conf_id_ = db_->writeToConfDB_TPGWeight(dataset, dataset2, NWEIGROUPS, weight_tag);
     }
   } else {
     // Read Even weights from file.
     std::vector<std::vector<unsigned int>> weights_even;
 
     std::ifstream file(weight_even_weightGroupFile_);
     std::string line;
     while (std::getline(file, line)) {
       std::istringstream iss(line);
       std::vector<unsigned int> wei_group_even;
       for (std::string s; iss >> s;)
         wei_group_even.push_back(stoi(s));
       weights_even.push_back(wei_group_even);
     }
     int nweigroups_even = weights_even.size();
 
     std::ifstream file2(weight_even_idMapFile_);
     std::string line2;
     while (std::getline(file2, line2)) {
       std::istringstream iss(line2);
       int ch_id, wei_gr;
       iss >> std::dec >> ch_id;
       iss >> std::dec >> wei_gr;
       int wei_group = wei_gr;
       if (wei_group > nweigroups_even - 1) {
         edm::LogError("TopInfo") << "Associating strip: " << ch_id << " to non-existing weight group: " << wei_gr
                                  << "\n";
       }
       weights_map_even[ch_id] = wei_group;
     }
 
     map<EcalLogicID, FEConfigWeightGroupDat> dataset_even;
 
     for (int igrp = 0; igrp < nweigroups_even; igrp++) {
       if (weights_even[igrp].size() == EcalTPGParamBuilder::NWEIGHTS) {
         if (writeToFiles_) {
           (*out_file_) << std::endl;
           (*out_file_) << "WEIGHT " << dec << igrp << std::endl;
           for (unsigned int sample = 0; sample < EcalTPGParamBuilder::NWEIGHTS; sample++)
             (*out_file_) << "0x" << hex << weights_even[igrp][sample] << " ";
           (*out_file_) << std::endl;
           (*out_file_) << std::endl;
         }
         if (writeToDB_) {
           ss << "going to write the weights for group:" << igrp << "\n";
           FEConfigWeightGroupDat gut;
           gut.setWeightGroupId(igrp);
           //PP WARNING: weights order is reverted when stored in the DB
           gut.setWeight0(weights_even[igrp][4]);
           gut.setWeight1(weights_even[igrp][3] +
                          0x80);  //0x80 to identify the max of the pulse in the FENIX (doesn't exist in emulator)
           gut.setWeight2(weights_even[igrp][2]);
           gut.setWeight3(weights_even[igrp][1]);
           gut.setWeight4(weights_even[igrp][0]);
           EcalLogicID ecid = EcalLogicID("DUMMY", igrp, igrp);  //1 dummy ID per group
           // Fill the dataset
           dataset_even[ecid] = gut;
         }
       }
     }
     if (writeToDB_) {
       // now we store in the DB the correspondence btw channels and groups
       map<EcalLogicID, FEConfigWeightDat> dataset_even_idmap;
       // EB loop
       for (int ich = 0; ich < (int)my_StripEcalLogicId.size(); ich++) {
         FEConfigWeightDat wut;
         int igroup = weights_map_even[stripMapEB[ich]];  // this group is for EB
         wut.setWeightGroupId(igroup);
         dataset_even_idmap[my_StripEcalLogicId[ich]] = wut;
       }
       // EE loop
       for (EcalLogicID& stripLogicId : my_StripEcalLogicId1_EE) {
         FEConfigWeightDat wut;
         int igroup = weights_map_even[stripMapEE[stripLogicId.getLogicID()]];
         wut.setWeightGroupId(igroup);
         // Fill the dataset
         dataset_even_idmap[stripLogicId] = wut;
       }
       // EE loop 2 (we had to split the ids of EE in 2 vectors to avoid crash!)
       for (EcalLogicID& stripLogicId : my_StripEcalLogicId2_EE) {
         FEConfigWeightDat wut;
         int igroup = weights_map_even[stripMapEE[stripLogicId.getLogicID()]];  // this group is for EE
         wut.setWeightGroupId(igroup);
         // Fill the dataset
         dataset_even_idmap[stripLogicId] = wut;
       }
       // Insert the datasets
       ostringstream wtag;
       wtag.str("");
       wtag << "Shape_even_NGroups_" << nweigroups_even;
       std::string weight_tag = wtag.str();
       ss << " weight tag " << weight_tag << "\n";
       if (m_write_wei == 1)
         wei_conf_id_ = db_->writeToConfDB_TPGWeight(dataset_even, dataset_even_idmap, nweigroups_even, weight_tag);
     }
   }
 
   //+=========================================================== Odd weights
   if (weight_useDoubleWeights_) {
     // Odd weights are always read from file
     std::vector<std::vector<unsigned int>> weights_odd;
     std::ifstream file3(weight_odd_weightGroupFile_);
     std::string line3;
     while (std::getline(file3, line3)) {
       std::istringstream iss(line3);
       std::vector<unsigned int> wei_group_odd;
       for (std::string s; iss >> s;)
         wei_group_odd.push_back(stoi(s));
       weights_odd.push_back(wei_group_odd);
     }
     int nweigroups_odd = weights_odd.size();
 
     std::ifstream file4(weight_odd_idMapFile_);
     std::string line4;
     while (std::getline(file4, line4)) {
       std::istringstream iss(line4);
       int ch_id, wei_gr;
       iss >> std::dec >> ch_id;
       iss >> std::dec >> wei_gr;
       int wei_group = wei_gr;
       if (wei_group > nweigroups_odd - 1) {
         edm::LogError("TopInfo") << "Associating strip: " << ch_id << " to non-existing weight group: " << wei_gr
                                  << "\n";
       }
       weights_map_odd[ch_id] = wei_group;
     }
 
     map<EcalLogicID, FEConfigOddWeightGroupDat> dataset_odd;
 
     for (int igrp = 0; igrp < nweigroups_odd; igrp++) {
       if (weights_odd[igrp].size() == EcalTPGParamBuilder::NWEIGHTS) {
         if (writeToFiles_) {
           (*out_file_) << std::endl;
           (*out_file_) << "WEIGHT_ODD " << dec << igrp << std::endl;
           for (unsigned int sample = 0; sample < EcalTPGParamBuilder::NWEIGHTS; sample++)
             (*out_file_) << "0x" << hex << weights_odd[igrp][sample] << " ";
           (*out_file_) << std::endl;
           (*out_file_) << std::endl;
         }
         if (writeToDB_) {
           ss << "going to write the weights for group:" << igrp << "\n";
           FEConfigOddWeightGroupDat gut;
           gut.setWeightGroupId(igrp);
           //PP WARNING: weights order is reverted when stored in the DB
           gut.setWeight0(weights_odd[igrp][4]);
           gut.setWeight1(weights_odd[igrp][3] +
                          0x80);  //0x80 to identify the max of the pulse in the FENIX (doesn't exist in emulator)
           gut.setWeight2(weights_odd[igrp][2]);
           gut.setWeight3(weights_odd[igrp][1]);
           gut.setWeight4(weights_odd[igrp][0]);
           EcalLogicID ecid = EcalLogicID("DUMMY", igrp, igrp);  //1 dummy ID per group
           // Fill the dataset
           dataset_odd[ecid] = gut;
         }
       }
     }
     // TP MODE configuration
     if (writeToFiles_) {
       (*out_file_) << std::endl;
       (*out_file_) << "TP_MODE " << std::endl;
       (*out_file_) << TPmode_EnableEBOddFilter_ << std::endl;
       (*out_file_) << TPmode_EnableEEOddFilter_ << std::endl;
       (*out_file_) << TPmode_EnableEBOddPeakFinder_ << std::endl;
       (*out_file_) << TPmode_EnableEEOddPeakFinder_ << std::endl;
       (*out_file_) << TPmode_DisableEBEvenPeakFinder_ << std::endl;
       (*out_file_) << TPmode_DisableEEEvenPeakFinder_ << std::endl;
       (*out_file_) << TPmode_FenixEBStripOutput_ << std::endl;
       (*out_file_) << TPmode_FenixEEStripOutput_ << std::endl;
       (*out_file_) << TPmode_FenixEBStripInfobit2_ << std::endl;
       (*out_file_) << TPmode_FenixEEStripInfobit2_ << std::endl;
       (*out_file_) << TPmode_FenixEBTcpOutput_ << std::endl;
       (*out_file_) << TPmode_FenixEBTcpInfobit1_ << std::endl;
       (*out_file_) << TPmode_FenixEETcpOutput_ << std::endl;
       (*out_file_) << TPmode_FenixEETcpInfobit1_ << std::endl;
       (*out_file_) << 0 << std::endl;  // FenixPar15-18 are placeholder parameters for future use
       (*out_file_) << 0 << std::endl;
       (*out_file_) << 0 << std::endl;
       (*out_file_) << 0 << std::endl;
       (*out_file_) << std::endl;
     }
 
     if (writeToDB_) {
       // now we store in the DB the correspondence btw channels and groups
       map<EcalLogicID, FEConfigOddWeightDat> dataset_odd_idmap;
 
       // EB loop
       for (int ich = 0; ich < (int)my_StripEcalLogicId.size(); ich++) {
         FEConfigOddWeightDat wut;
         int igroup = weights_map_odd[stripMapEB[ich]];  // this group is for EB
         wut.setWeightGroupId(igroup);
         dataset_odd_idmap[my_StripEcalLogicId[ich]] = wut;
       }
       // EE loop
       for (auto& stripLogicId : my_StripEcalLogicId1_EE) {
         FEConfigOddWeightDat wut;
         int igroup = weights_map_odd[stripMapEE[stripLogicId.getLogicID()]];
         wut.setWeightGroupId(igroup);
         // Fill the dataset
         dataset_odd_idmap[stripLogicId] = wut;
       }
       // EE loop 2 (we had to split the ids of EE in 2 vectors to avoid crash!)
       for (auto& stripLogicId : my_StripEcalLogicId2_EE) {
         FEConfigOddWeightDat wut;
         int igroup = weights_map_odd[stripMapEE[stripLogicId.getLogicID()]];  // this group is for EE
         wut.setWeightGroupId(igroup);
         // Fill the dataset
         dataset_odd_idmap[stripLogicId] = wut;
       }
       // TP mode on DB
       map<EcalLogicID, FEConfigOddWeightModeDat> dataset_tpmode;
       FEConfigOddWeightModeDat tp_mode;
       tp_mode.setEnableEBOddFilter(TPmode_EnableEBOddFilter_);
       tp_mode.setEnableEEOddFilter(TPmode_EnableEEOddFilter_);
       tp_mode.setEnableEBOddPeakFinder(TPmode_EnableEBOddPeakFinder_);
       tp_mode.setEnableEEOddPeakFinder(TPmode_EnableEEOddPeakFinder_);
       tp_mode.setDisableEBEvenPeakFinder(TPmode_DisableEBEvenPeakFinder_);
       tp_mode.setDisableEEEvenPeakFinder(TPmode_DisableEEEvenPeakFinder_);
       tp_mode.setFenixEBStripOutput(TPmode_FenixEBStripOutput_);
       tp_mode.setFenixEEStripOutput(TPmode_FenixEEStripOutput_);
       tp_mode.setFenixEBStripInfobit2(TPmode_FenixEBStripInfobit2_);
       tp_mode.setFenixEEStripInfobit2(TPmode_FenixEEStripInfobit2_);
       tp_mode.setFenixEBTcpOutput(TPmode_FenixEBTcpOutput_);
       tp_mode.setFenixEBTcpInfoBit1(TPmode_FenixEBTcpInfobit1_);
       tp_mode.setFenixEETcpOutput(TPmode_FenixEETcpOutput_);
       tp_mode.setFenixEETcpInfoBit1(TPmode_FenixEETcpInfobit1_);
       dataset_tpmode[my_StripEcalLogicId[0]] = tp_mode;  // The LogicID is not used in reality....
 
       // Insert the datasets
       ostringstream wtag;
       wtag.str("");
       wtag << "Shape_odd_NGroups_" << nweigroups_odd;
       std::string weight_tag = wtag.str();
       ss << " weight tag " << weight_tag << "\n";
       if (m_write_wei2 == 1)
         wei2_conf_id_ = db_->writeToConfDB_TPGWeight_doubleWeights(
             dataset_odd, dataset_odd_idmap, dataset_tpmode, nweigroups_odd, weight_tag);
     }
 
   } else {
     // If useDoubleWeight == False we need to use the default
     // wei2_conf_id=1 and save a blank TP mode and blank Odd weight group
     if (writeToFiles_) {
       // single set of ODD weights ==0 is written to the txt file
       (*out_file_) << "WEIGHT_ODD " << dec << 0 << std::endl;
       for (unsigned int sample = 0; sample < EcalTPGParamBuilder::NWEIGHTS; sample++)
         (*out_file_) << "0x0"
                      << " ";
       (*out_file_) << std::endl << std::endl;
 
       // Default TP mode with Run2 config == all parameters to 0
       (*out_file_) << "TP_MODE " << std::endl;
       for (int m = 0; m < 18; m++)
         (*out_file_) << 0 << std::endl;
       (*out_file_) << std::endl;
     }
     wei2_conf_id_ = 1;  // special value that is interpreted by online DAQ code as Run2 configuration
   }
 
   edm::LogInfo("TopInfo") << ss.str();
   ss.str("");
 
   // Compute FG section //
 
   // barrel
   unsigned int lowRatio, highRatio, lowThreshold, highThreshold, lutFG;
   computeFineGrainEBParameters(lowRatio, highRatio, lowThreshold, highThreshold, lutFG);
   if (writeToFiles_) {
     (*out_file_) << std::endl;
     (*out_file_) << "FG 0" << std::endl;
     (*out_file_) << hex << "0x" << lowThreshold << " 0x" << highThreshold << " 0x" << lowRatio << " 0x" << highRatio
                  << " 0x" << lutFG << std::endl;
   }
 
   // endcap
   unsigned int threshold, lut_tower;
   unsigned int lut_strip;
   computeFineGrainEEParameters(threshold, lut_strip, lut_tower);
 
   // and here we store the fgr part
 
   if (writeToDB_) {
     ss << "going to write the fgr "
        << "\n";
     map<EcalLogicID, FEConfigFgrGroupDat> dataset;
     // we create 1 group
     int NFGRGROUPS = 1;
     for (int ich = 0; ich < NFGRGROUPS; ich++) {
       FEConfigFgrGroupDat gut;
       gut.setFgrGroupId(ich);
       gut.setThreshLow(lowRatio);
       gut.setThreshHigh(highRatio);
       gut.setRatioLow(lowThreshold);
       gut.setRatioHigh(highThreshold);
       gut.setLUTValue(lutFG);
       EcalLogicID ecid = EcalLogicID("DUMMY", ich, ich);
       // Fill the dataset
       dataset[ecid] = gut;  // we use any logic id but different, because it is in any case ignored...
     }
 
     // now we store in the DB the correspondence btw channels and groups
     map<EcalLogicID, FEConfigFgrDat> dataset2;
     for (auto& id : my_TTEcalLogicId) {
       FEConfigFgrDat wut;
       int igroup = 0;
       wut.setFgrGroupId(igroup);
       // Fill the dataset
       // the logic ids are ordered by SM (1,...36) and TT (1,...68)
       dataset2[id] = wut;
     }
 
     // endcap loop
     for (auto& id : my_RTEcalLogicId_EE) {
       //    std::cout << " endcap FGR " << std::endl;
       FEConfigFgrDat wut;
       int igroup = 0;
       wut.setFgrGroupId(igroup);
       // Fill the dataset
       // the logic ids are ordered by .... ?
       // you have to calculate the right index here
       dataset2[id] = wut;
     }
 
     // endcap TT loop for the FEfgr EE Tower
     map<EcalLogicID, FEConfigFgrEETowerDat> dataset3;
     for (auto& id : my_TTEcalLogicId_EE) {
       FEConfigFgrEETowerDat fgreett;
       fgreett.setLutValue(lut_tower);
       dataset3[id] = fgreett;
     }
 
     // endcap strip loop for the FEfgr EE strip
     // and barrel strip loop for the spike parameters (same structure than EE FGr)
     map<EcalLogicID, FEConfigFgrEEStripDat> dataset4;
     for (auto& id : my_StripEcalLogicId1_EE) {
       FEConfigFgrEEStripDat zut;
       zut.setThreshold(threshold);
       zut.setLutFgr(lut_strip);
       dataset4[id] = zut;
     }
     for (auto& id : my_StripEcalLogicId2_EE) {
       FEConfigFgrEEStripDat zut;
       zut.setThreshold(threshold);
       zut.setLutFgr(lut_strip);
       // Fill the dataset
       dataset4[id] = zut;
     }
     for (int ich = 0; ich < (int)my_StripEcalLogicId.size(); ich++) {
       // EB
       FEConfigFgrEEStripDat zut;
       EcalLogicID thestrip = my_StripEcalLogicId[ich];
       uint32_t elStripId = stripMapEB[ich];
       map<uint32_t, uint32_t>::const_iterator it = stripMapEBsintheta.find(elStripId);
       if (it != stripMapEBsintheta.end())
         zut.setThreshold(it->second);
       else {
         edm::LogError("TopInfo") << "ERROR: strip SFGVB threshold parameter not found for that strip:"
                                  << thestrip.getID1() << " " << thestrip.getID3() << " " << thestrip.getID3() << "\n";
         edm::LogError("TopInfo") << " using value = " << SFGVB_Threshold_ + pedestal_offset_ << "\n";
         zut.setThreshold(SFGVB_Threshold_ + pedestal_offset_);
       }
       zut.setLutFgr(SFGVB_lut_);
       // Fill the dataset
       dataset4[thestrip] = zut;
     }
 
     // Insert the dataset
     ostringstream wtag;
     wtag.str("");
     wtag << "FGR_" << lutFG << "_N_" << NFGRGROUPS << "_eb_" << FG_lowThreshold_EB_ << "_EB_" << FG_highThreshold_EB_;
     std::string weight_tag = wtag.str();
     ss << " weight tag " << weight_tag << "\n";
     if (m_write_fgr == 1)
       fgr_conf_id_ =
           db_->writeToConfDB_TPGFgr(dataset, dataset2, fgrparamset, dataset3, dataset4, NFGRGROUPS, weight_tag);
 
     //modif-alex 21/01/11
     map<EcalLogicID, FEConfigSpikeDat> datasetspike;  //loob EB TT
     for (auto& id : my_TTEcalLogicId) {
       FEConfigSpikeDat spiketh;
       spiketh.setSpikeThreshold(SFGVB_SpikeKillingThreshold_);
       datasetspike[id] = spiketh;
     }  //loop EB TT towers
 
     //modif-alex 21/01/11
     ostringstream stag;
     stag.str("");
     stag << "SpikeTh" << SFGVB_SpikeKillingThreshold_;
     std::string spike_tag = stag.str();
     ss << " spike tag " << spike_tag << "\n";
     if (m_write_spi == 1)
       spi_conf_id_ = db_->writeToConfDB_Spike(datasetspike, spike_tag);  //modif-alex 21/01/11
 
     //modif-alex 31/01/11
     //DELAYS EB
     map<EcalLogicID, FEConfigTimingDat>
         datasetdelay;  // the loop goes from TCC 38 to 72 and throught the towers from 1 to 68
     for (int ich = 0; ich < (int)my_TTEcalLogicId_EB_by_TCC.size(); ich++) {
       FEConfigTimingDat delay;
 
       EcalLogicID logiciddelay = my_TTEcalLogicId_EB_by_TCC[ich];
       int id1_tcc = logiciddelay.getID1();  // the TCC
       int id2_tt = logiciddelay.getID2();   // the tower
       std::map<int, vector<int>>::const_iterator ittEB = delays_EB_.find(id1_tcc);
       std::vector<int> TimingDelaysEB = ittEB->second;
 
       if (ittEB != delays_EB_.end()) {
         if (TimingDelaysEB[id2_tt - 1] == -1) {
           edm::LogError("TopInfo") << "ERROR: Barrel timing delay not specified, check file, putting default value 1"
                                    << "\n";
           delay.setTimingPar1(1);
         } else
           delay.setTimingPar1(TimingDelaysEB[id2_tt - 1]);
       } else {
         edm::LogError("TopInfo") << "ERROR:Barrel Could not find delay parameter for that trigger tower "
                                  << "\n";
         edm::LogError("TopInfo") << "Using default value = 1"
                                  << "\n";
         delay.setTimingPar1(1);
       }
 
       std::map<int, vector<int>>::const_iterator ittpEB = phases_EB_.find(id1_tcc);
       std::vector<int> TimingPhasesEB = ittpEB->second;
 
       if (ittpEB != phases_EB_.end()) {
         if (TimingPhasesEB[id2_tt - 1] == -1) {
           edm::LogError("TopInfo") << "ERROR: Barrel timing phase not specified, check file, putting default value 0"
                                    << "\n";
           delay.setTimingPar2(0);
         } else
           delay.setTimingPar2(TimingPhasesEB[id2_tt - 1]);
       } else {
         edm::LogError("TopInfo") << "ERROR:Barrel Could not find phase parameter for that trigger tower "
                                  << "\n";
         edm::LogError("TopInfo") << "Using default value = 0"
                                  << "\n";
         delay.setTimingPar2(0);
       }
 
       ss << ich << " tcc=" << id1_tcc << " TT=" << id2_tt << " logicId=" << logiciddelay.getLogicID()
          << " delay=" << TimingDelaysEB[id2_tt - 1] << " phase=" << TimingPhasesEB[id2_tt - 1] << "\n";
 
       //delay.setTimingPar1(1);
       //delay.setTimingPar2(2);
       datasetdelay[logiciddelay] = delay;
     }  //loop EB TT towers
 
     //DELAYS EE
     int stripindex = 0;
     int tccin = 1;
     for (int ich = 0; ich < (int)my_StripEcalLogicId_EE_strips_by_TCC.size(); ich++) {
       FEConfigTimingDat delay;
 
       EcalLogicID logiciddelay = my_StripEcalLogicId_EE_strips_by_TCC[ich];
       int id1_tcc = logiciddelay.getID1();  // the TCC
       int id2_tt = logiciddelay.getID2();   // the tower
       int id3_st = logiciddelay.getID3();   // the strip
 
       //reset strip counter
       if (id1_tcc != tccin) {
         tccin = id1_tcc;
         stripindex = 0;
       }
 
       std::map<int, vector<int>>::const_iterator ittEE = delays_EE_.find(id1_tcc);
       std::vector<int> TimingDelaysEE = ittEE->second;
 
       if (ittEE != delays_EE_.end()) {
         if (TimingDelaysEE[stripindex] == -1) {
           edm::LogError("TopInfo") << "ERROR: Endcap timing delay not specified, check file, putting default value 1"
                                    << "\n";
           delay.setTimingPar1(1);
         } else
           delay.setTimingPar1(TimingDelaysEE[stripindex]);
       } else {
         edm::LogError("TopInfo") << "ERROR:Endcap Could not find delay parameter for that trigger tower "
                                  << "\n";
         edm::LogError("TopInfo") << "Using default value = 1"
                                  << "\n";
         delay.setTimingPar1(1);
       }
 
       std::map<int, vector<int>>::const_iterator ittpEE = phases_EE_.find(id1_tcc);
       std::vector<int> TimingPhasesEE = ittpEE->second;
 
       if (ittpEE != phases_EE_.end()) {
         if (TimingPhasesEE[stripindex] == -1) {
           edm::LogError("TopInfo") << "ERROR: Endcap timing phase not specified, check file, putting default value 0"
                                    << "\n";
           delay.setTimingPar2(0);
         } else
           delay.setTimingPar2(TimingPhasesEE[stripindex]);
       } else {
         edm::LogError("TopInfo") << "ERROR:Endcap Could not find phase parameter for that trigger tower "
                                  << "\n";
         edm::LogError("TopInfo") << "Using default value = 0"
                                  << "\n";
         delay.setTimingPar2(0);
       }
 
       ss << ich << " stripindex=" << stripindex << " tcc=" << id1_tcc << " TT=" << id2_tt << " id3_st=" << id3_st
          << " logicId=" << logiciddelay.getLogicID() << " delay=" << TimingDelaysEE[stripindex]
          << " phase=" << TimingPhasesEE[stripindex] << "\n";
 
       //delay.setTimingPar1(1);
       //delay.setTimingPar2(2);
       datasetdelay[logiciddelay] = delay;
       stripindex++;
     }  //loop EE strip towers
 
     ostringstream de_tag;
     de_tag.str("");
     de_tag << "DelaysFromFile";
     std::string delay_tag = de_tag.str();
     ss << " delay tag " << delay_tag << "\n";
     if (m_write_del == 1)
       del_conf_id_ = db_->writeToConfDB_Delay(datasetdelay, delay_tag);  //modif-alex 31/01/11
 
   }  //write to DB
 
   if (writeToDB_) {
     ss << "going to write the sliding "
        << "\n";
     map<EcalLogicID, FEConfigSlidingDat> dataset;
     for (auto& id : my_StripEcalLogicId) {
       FEConfigSlidingDat wut;
       wut.setSliding(sliding_);
       // Fill the dataset
       // the logic ids are ordered by SM (1,...36) , TT (1,...68) and strip (1..5)
       dataset[id] = wut;
     }
 
     // endcap loop
     for (auto& id : my_StripEcalLogicId1_EE) {
       FEConfigSlidingDat wut;
       wut.setSliding(sliding_);
       dataset[id] = wut;
     }
     for (auto& id : my_StripEcalLogicId2_EE) {
       FEConfigSlidingDat wut;
       wut.setSliding(sliding_);
       dataset[id] = wut;
     }
 
     // Insert the dataset
     ostringstream wtag;
     wtag.str("");
     wtag << "Sliding_" << sliding_;
     std::string justatag = wtag.str();
     ss << " sliding tag " << justatag << "\n";
     int iov_id = 0;  // just a parameter ...
     if (m_write_sli == 1)
       sli_conf_id_ = db_->writeToConfDB_TPGSliding(dataset, iov_id, justatag);
   }
 
   // Compute LUT section //
 
   int lut_EB[1024], lut_EE[1024];
 
   // barrel
   computeLUT(lut_EB, "EB");
   if (writeToFiles_) {
     (*out_file_) << std::endl;
     (*out_file_) << "LUT 0" << std::endl;
     for (int i = 0; i < 1024; i++)
       (*out_file_) << "0x" << hex << lut_EB[i] << std::endl;
     (*out_file_) << std::endl;
   }
 
   // endcap
   computeLUT(lut_EE, "EE");
   // check first if lut_EB and lut_EE are the same
   bool newLUT(false);
   for (int i = 0; i < 1024; i++)
     if (lut_EE[i] != lut_EB[i])
       newLUT = true;
   if (newLUT && writeToFiles_) {
     (*out_file_) << std::endl;
     (*out_file_) << "LUT 1" << std::endl;
     for (int i = 0; i < 1024; i++)
       (*out_file_) << "0x" << hex << lut_EE[i] << std::endl;
     (*out_file_) << std::endl;
   }
 
   if (writeToDB_) {
     map<EcalLogicID, FEConfigLUTGroupDat> dataset;
     // we create 1 LUT group
     int NLUTGROUPS = 0;
     int ich = 0;
     FEConfigLUTGroupDat lut;
     lut.setLUTGroupId(ich);
     for (int i = 0; i < 1024; i++) {
       lut.setLUTValue(i, lut_EB[i]);
     }
     EcalLogicID ecid = EcalLogicID("DUMMY", ich, ich);
     // Fill the dataset
     dataset[ecid] = lut;  // we use any logic id but different, because it is in any case ignored...
 
     ich++;
 
     FEConfigLUTGroupDat lute;
     lute.setLUTGroupId(ich);
     for (int i = 0; i < 1024; i++) {
       lute.setLUTValue(i, lut_EE[i]);
     }
     EcalLogicID ecide = EcalLogicID("DUMMY", ich, ich);
     // Fill the dataset
     dataset[ecide] = lute;  // we use any logic id but different, because it is in any case ignored...
 
     ich++;
 
     NLUTGROUPS = ich;
 
     // now we store in the DB the correspondence btw channels and LUT groups
     map<EcalLogicID, FEConfigLUTDat> dataset2;
     // in this case I decide in a stupid way which channel belongs to which group
     for (auto& id : my_TTEcalLogicId) {
       FEConfigLUTDat lut;
       int igroup = 0;
       lut.setLUTGroupId(igroup);
       // calculate the right TT - in the vector they are ordered by SM and by TT
       // Fill the dataset
       dataset2[id] = lut;
     }
 
     // endcap loop
     for (auto& id : my_TTEcalLogicId_EE) {
       FEConfigLUTDat lut;
       int igroup = 1;
       lut.setLUTGroupId(igroup);
       // calculate the right TT
       // Fill the dataset
       dataset2[id] = lut;
     }
 
     // Insert the dataset
     ostringstream ltag;
     ltag.str("");
     ltag << LUT_option_ << "_NGroups_" << NLUTGROUPS;
     std::string lut_tag = ltag.str();
     ss << " LUT tag " << lut_tag << "\n";
     if (m_write_lut == 1)
       lut_conf_id_ = db_->writeToConfDB_TPGLUT(dataset, dataset2, lutparamset, NLUTGROUPS, lut_tag);
   }
 
   // last we insert the FE_CONFIG_MAIN table
   if (writeToDB_) {
     //int conf_id_=db_->writeToConfDB_TPGMain(ped_conf_id_,lin_conf_id_, lut_conf_id_, fgr_conf_id_,
     //              sli_conf_id_, wei_conf_id_, bxt_conf_id_, btt_conf_id_, tag_, version_) ;
     int conf_id_ = db_->writeToConfDB_TPGMain(ped_conf_id_,
                                               lin_conf_id_,
                                               lut_conf_id_,
                                               fgr_conf_id_,
                                               sli_conf_id_,
                                               wei_conf_id_,
                                               wei2_conf_id_,
                                               spi_conf_id_,
                                               del_conf_id_,
                                               bxt_conf_id_,
                                               btt_conf_id_,
                                               bst_conf_id_,
                                               coke_conf_id_,
                                               tag_,
                                               version_);  //modif-alex 21/01/11
 
     ss << "\n Conf ID = " << conf_id_ << "\n";
   }
 
   // loop on strips and associate them with  values //
 
   // Barrel
   stripListEB.sort();
   stripListEB.unique();
   ss << "Number of EB strips=" << dec << stripListEB.size() << "\n";
   if (writeToFiles_) {
     (*out_file_) << std::endl;
     for (itList = stripListEB.begin(); itList != stripListEB.end(); itList++) {
       (*out_file_) << "STRIP_EB " << dec << (*itList) << std::endl;
       (*out_file_) << hex << "0x" << sliding_ << std::endl;
       (*out_file_) << hex << "0x" << weights_map_even[(*itList)] << " ";
       if (weight_useDoubleWeights_)
         (*out_file_) << hex << "0x" << weights_map_odd[(*itList)] << std::endl;
       else
         (*out_file_) << "0x0" << std::endl;
       (*out_file_) << "0x" << stripMapEBsintheta[(*itList)] << " 0x" << SFGVB_lut_ << std::endl;
     }
   }
 
   // Endcap
   stripListEE.sort();
   stripListEE.unique();
   ss << "Number of EE strips=" << dec << stripListEE.size() << "\n";
   if (writeToFiles_) {
     (*out_file_) << std::endl;
     for (itList = stripListEE.begin(); itList != stripListEE.end(); itList++) {
       (*out_file_) << "STRIP_EE " << dec << (*itList) << std::endl;
       (*out_file_) << hex << "0x" << sliding_ << std::endl;
       (*out_file_) << hex << "0x" << weights_map_even[(*itList)] << " ";
       if (weight_useDoubleWeights_)
         (*out_file_) << hex << "0x" << weights_map_odd[(*itList)] << std::endl;
       else
         (*out_file_) << "0x0" << std::endl;
       (*out_file_) << hex << "0x" << threshold << " 0x" << lut_strip << std::endl;
     }
   }
   edm::LogInfo("TopInfo") << ss.str();
   ss.str("");
 
   // loop on towers and associate them with default values //
 
   // Barrel
   towerListEB.sort();
   towerListEB.unique();
   ss << "Number of EB towers=" << dec << towerListEB.size() << "\n";
   if (writeToFiles_) {
     (*out_file_) << std::endl;
     for (itList = towerListEB.begin(); itList != towerListEB.end(); itList++) {
       (*out_file_) << "TOWER_EB " << dec << (*itList) << std::endl;
       (*out_file_) << " 0\n 0\n";
       (*out_file_) << " " << SFGVB_SpikeKillingThreshold_ << std::endl;  //modif-alex
     }
   }
 
   // Endcap
   towerListEE.sort();
   towerListEE.unique();
   ss << "Number of EE towers=" << dec << towerListEE.size() << "\n";
   if (writeToFiles_) {
     (*out_file_) << std::endl;
     for (itList = towerListEE.begin(); itList != towerListEE.end(); itList++) {
       (*out_file_) << "TOWER_EE " << dec << (*itList) << std::endl;
       if (newLUT)
         (*out_file_) << " 1\n";
       else
         (*out_file_) << " 0\n";
       (*out_file_) << hex << "0x" << lut_tower << std::endl;
     }
   }
   edm::LogInfo("TopInfo") << ss.str();
   ss.str("");
 
   // store control histos //
   ICEB->Write();
   tpgFactorEB->Write();
   ICEEPlus->Write();
   tpgFactorEEPlus->Write();
   ICEEMinus->Write();
   tpgFactorEEMinus->Write();
   IC->Write();
   tpgFactor->Write();
   hshapeEB->Write();
   hshapeEE->Write();
   ntuple->Write();
   ntupleSpike->Write();
   saving.Close();
 }

◆ beginJob()

void EcalTPGParamBuilder::beginJob ( )

overridevirtual

Reimplemented from edm::one::EDAnalyzerBase.

Definition at line 2559 of file EcalTPGParamBuilder.cc.

References create_header(), TauDecayModes::dec, DetId::Ecal, EcalBarrel, EcalEndcap, Et_sat_EB_, Et_sat_EE_, FG_highRatio_EB_, FG_highThreshold_EB_, FG_lowRatio_EB_, FG_lowThreshold_EB_, FG_Threshold_EE_, DetId::rawId(), TTF_highThreshold_EB_, TTF_highThreshold_EE_, TTF_lowThreshold_EB_, TTF_lowThreshold_EE_, and writeToFiles_.

                                    {
   using namespace edm;
   using namespace std;
 
   edm::LogInfo("TopInfo") << "we are in beginJob\n";
 
   create_header();
 
   DetId eb(DetId::Ecal, EcalBarrel);
   DetId ee(DetId::Ecal, EcalEndcap);
 
   if (writeToFiles_) {
     (*out_file_) << "PHYSICS_EB " << dec << eb.rawId() << std::endl;
     (*out_file_) << Et_sat_EB_ << " " << TTF_lowThreshold_EB_ << " " << TTF_highThreshold_EB_ << std::endl;
     (*out_file_) << FG_lowThreshold_EB_ << " " << FG_highThreshold_EB_ << " " << FG_lowRatio_EB_ << " "
                  << FG_highRatio_EB_ << std::endl;
     //(*out_file_) << SFGVB_SpikeKillingThreshold_ << std::endl; //modif-alex02/02/2011
     (*out_file_) << std::endl;
 
     (*out_file_) << "PHYSICS_EE " << dec << ee.rawId() << std::endl;
     (*out_file_) << Et_sat_EE_ << " " << TTF_lowThreshold_EE_ << " " << TTF_highThreshold_EE_ << std::endl;
     (*out_file_) << FG_Threshold_EE_ << " " << -1 << " " << -1 << " " << -1 << std::endl;
     (*out_file_) << std::endl;
   }
 }

◆ checkIfOK()

bool EcalTPGParamBuilder::checkIfOK ( EcalPedestals::Item item )

private

Definition at line 383 of file EcalTPGParamBuilder.cc.

References B2GTnPMonitor_cfi::item, and mps_fire::result.

                                                           {
   bool result = true;
   if (item.mean_x1 < 150. || item.mean_x1 > 250)
     result = false;
   if (item.mean_x6 < 150. || item.mean_x6 > 250)
     result = false;
   if (item.mean_x12 < 150. || item.mean_x12 > 250)
     result = false;
   if (item.rms_x1 < 0 || item.rms_x1 > 2)
     result = false;
   if (item.rms_x6 < 0 || item.rms_x6 > 3)
     result = false;
   if (item.rms_x12 < 0 || item.rms_x12 > 5)
     result = false;
   return result;
 }

◆ computeFineGrainEBParameters()

void EcalTPGParamBuilder::computeFineGrainEBParameters	(	uint &	lowRatio,
		uint &	highRatio,
		uint &	lowThreshold,
		uint &	highThreshold,
		uint &	lut
	)

private

Definition at line 3089 of file EcalTPGParamBuilder.cc.

References Et_sat_EB_, FG_highRatio_EB_, FG_highThreshold_EB_, FG_lowRatio_EB_, FG_lowThreshold_EB_, FG_lut_EB_, and createfilelist::int.

Referenced by analyze().

                                                                           {
   lowRatio = int(0x80 * FG_lowRatio_EB_ + 0.5);
   if (lowRatio > 0x7f)
     lowRatio = 0x7f;
   highRatio = int(0x80 * FG_highRatio_EB_ + 0.5);
   if (highRatio > 0x7f)
     highRatio = 0x7f;
 
   // lsb at the stage of the FG calculation is:
   double lsb_FG = Et_sat_EB_ / 1024. / 4;
   lowThreshold = int(FG_lowThreshold_EB_ / lsb_FG + 0.5);
   if (lowThreshold > 0xff)
     lowThreshold = 0xff;
   highThreshold = int(FG_highThreshold_EB_ / lsb_FG + 0.5);
   if (highThreshold > 0xff)
     highThreshold = 0xff;
 
   // FG lut: FGVB response is LUT(adress) where adress is:
   // bit3: maxof2/ET >= lowRatio, bit2: maxof2/ET >= highRatio, bit1: ET >= lowThreshold, bit0: ET >= highThreshold
   // FGVB =1 if jet-like (veto active), =0 if E.M.-like
   // the condition for jet-like is: ET>Threshold and  maxof2/ET < Ratio (only TT with enough energy are vetoed)
 
   // With the following lut, what matters is only max(TLow, Thigh) and max(Elow, Ehigh)
   // So, jet-like if maxof2/ettot<max(TLow, Thigh) && ettot >= max(Elow, Ehigh)
   if (FG_lut_EB_ == 0)
     lut = 0x0888;
   else
     lut = FG_lut_EB_;  // let's use the users value (hope he/she knows what he/she does!)
 }

◆ computeFineGrainEEParameters()

void EcalTPGParamBuilder::computeFineGrainEEParameters	(	uint &	threshold,
		uint &	lut_strip,
		uint &	lut_tower
	)

private

Definition at line 3123 of file EcalTPGParamBuilder.cc.

References Et_sat_EE_, FG_lut_strip_EE_, FG_lut_tower_EE_, FG_Threshold_EE_, createfilelist::int, and remoteMonitoring_LASER_era2018_cfg::threshold.

Referenced by analyze().

                                                                                 {
   // lsb for EE:
   double lsb_FG = Et_sat_EE_ / 1024.;  // FIXME is it true????
   threshold = int(FG_Threshold_EE_ / lsb_FG + 0.5);
   lut_strip = FG_lut_strip_EE_;
   lut_tower = FG_lut_tower_EE_;
 }

◆ computeLinearizerParam()

bool EcalTPGParamBuilder::computeLinearizerParam	(	double	theta,
		double	gainRatio,
		double	calibCoeff,
		std::string	subdet,
		int &	mult,
		int &	shift
	)

private

Definition at line 2585 of file EcalTPGParamBuilder.cc.

References Et_sat_EB_, Et_sat_EE_, createfilelist::int, VarParsing::mult, particleFlowDisplacedVertex_cfi::ratio, edm::shift, funct::sin(), sliding_, theta(), xtal_LSB_EB_, and xtal_LSB_EE_.

Referenced by analyze().

                                                                                                 {
   /*
     Linearization coefficient are determined in order to satisfy:
     tpg(ADC_sat) = 1024
     where: 
     tpg() is a model of the linearized tpg response on 10b 
     ADC_sat is the number of ADC count corresponding the Et_sat, the maximum scale of the transverse energy
     
     Since we have:
     Et_sat = xtal_LSB * ADC_sat * gainRatio * calibCoeff * sin(theta)
     and a simple model of tpg() being given by:
     tpg(X) = [ (X*mult) >> (shift+2) ] >> (sliding+shiftDet) 
     we must satisfy:
     [ (Et_sat/(xtal_LSB * gainRatio * calibCoeff * sin(theta)) * mult) >> (shift+2) ] >> (sliding+shiftDet) = 1024 
     that is:
     mult = 1024/Et_sat * xtal_LSB * gainRatio * calibCoeff * sin(theta) * 2^-(sliding+shiftDet+2) * 2^-shift
     mult = factor * 2^-shift
   */
 
   // case barrel:
   int shiftDet = 2;  //fixed, due to FE FENIX TCP format
   double ratio = xtal_LSB_EB_ / Et_sat_EB_;
   // case endcap:
   if (subdet == "EE") {
     shiftDet = 2;  //applied in TCC-EE and not in FE FENIX TCP... This parameters is setable in the TCC-EE
     //shiftDet = 0 ; //was like this before with FE bug
     ratio = xtal_LSB_EE_ / Et_sat_EE_;
   }
 
   //modif-alex-30/01/2012
   //std::cout << "calibCoeff="<<calibCoeff<<endl;
 
   double factor = 1024 * ratio * gainRatio * calibCoeff * sin(theta) * (1 << (sliding_ + shiftDet + 2));
   // Let's try first with shift = 0 (trivial solution)
   mult = (int)(factor + 0.5);
   for (shift = 0; shift < 15; shift++) {
     if (mult >= 128 && mult < 256)
       return true;
     factor *= 2;
     mult = (int)(factor + 0.5);
   }
   edm::LogError("TopInfo") << "too bad we did not manage to calculate the factor for calib=" << calibCoeff << "\n";
   return false;
 }

◆ computeLUT()

void EcalTPGParamBuilder::computeLUT	(	int *	lut,
		std::string	det = `"EB"`
	)

private

Definition at line 2893 of file EcalTPGParamBuilder.cc.

References Et_sat_EB_, Et_sat_EE_, EcalMonitorTask_cff::func, mps_fire::i, createfilelist::int, dqmiolumiharvest::j, LUT_constant_EB_, LUT_constant_EE_, LUT_noise_EB_, LUT_noise_EE_, LUT_option_, LUT_stochastic_EB_, LUT_stochastic_EE_, LUT_threshold_EB_, LUT_threshold_EE_, oneOverEtResolEt(), TTF_highThreshold_EB_, TTF_highThreshold_EE_, TTF_lowThreshold_EB_, and TTF_lowThreshold_EE_.

Referenced by analyze().

                                                             {
   double Et_sat = Et_sat_EB_;
   double LUT_threshold = LUT_threshold_EB_;
   double LUT_stochastic = LUT_stochastic_EB_;
   double LUT_noise = LUT_noise_EB_;
   double LUT_constant = LUT_constant_EB_;
   double TTF_lowThreshold = TTF_lowThreshold_EB_;
   double TTF_highThreshold = TTF_highThreshold_EB_;
   if (det == "EE") {
     Et_sat = Et_sat_EE_;
     LUT_threshold = LUT_threshold_EE_;
     LUT_stochastic = LUT_stochastic_EE_;
     LUT_noise = LUT_noise_EE_;
     LUT_constant = LUT_constant_EE_;
     TTF_lowThreshold = TTF_lowThreshold_EE_;
     TTF_highThreshold = TTF_highThreshold_EE_;
   }
 
   // initialisation with identity
   for (int i = 0; i < 1024; i++) {
     lut[i] = i;
     if (lut[i] > 0xff)
       lut[i] = 0xff;
   }
 
   // case linear LUT
   if (LUT_option_ == "Linear") {
     int mylut = 0;
     for (int i = 0; i < 1024; i++) {
       lut[i] = mylut;
       if ((i + 1) % 4 == 0)
         mylut++;
       //if ((i+1)%8 == 0 ) mylut++ ;//modif-alex 16/12/2010 LSB==500MeV ONLY USED FOR BEAMV4 key
     }
   }
 
   // case LUT following Ecal resolution
   if (LUT_option_ == "EcalResolution") {
     TF1* func = new TF1("func", oneOverEtResolEt, 0., Et_sat, 3);
     func->SetParameters(LUT_stochastic, LUT_noise, LUT_constant);
     double norm = func->Integral(0., Et_sat);
     for (int i = 0; i < 1024; i++) {
       double Et = i * Et_sat / 1024.;
       lut[i] = int(0xff * func->Integral(0., Et) / norm + 0.5);
     }
   }
 
   // Now, add TTF thresholds to LUT and apply LUT threshold if needed
   for (int j = 0; j < 1024; j++) {
     double Et_GeV = Et_sat / 1024 * (j + 0.5);
     if (Et_GeV <= LUT_threshold)
       lut[j] = 0;  // LUT threshold
     int ttf = 0x0;
     if (Et_GeV >= TTF_highThreshold)
       ttf = 3;
     if (Et_GeV >= TTF_lowThreshold && Et_GeV < TTF_highThreshold)
       ttf = 1;
     ttf = ttf << 8;
     lut[j] += ttf;
   }
 }

◆ computeWeights()

std::vector< unsigned int > EcalTPGParamBuilder::computeWeights	(	EcalShapeBase &	shape,
		TH1F *	histo
	)

private

Definition at line 2774 of file EcalTPGParamBuilder.cc.

References complement2_, submitPVResolutionJobs::count, CustomPhysics_cfi::gamma, timingPdfMaker::histo, createfilelist::int, SiStripPI::max, SiStripPI::min, nSample_, funct::pow(), ecalGpuTask_cfi::sample, sampleMax_, l1trig_cff::shape, contentValuesCheck::ss, protons_cff::time, HLT_2023v12_cff::timeMax, uncodeWeight(), mps_merge::weight, weight_timeShift_, and weight_unbias_recovery_.

Referenced by analyze().

                                                                                              {
   std::ostringstream ss;
   ss << "Computing Weights...\n";
   double timeMax = shape.timeOfMax() - shape.timeOfThr();  // timeMax w.r.t begining of pulse
   double max = shape(timeMax);
 
   double sumf = 0.;
   double sumf2 = 0.;
   for (unsigned int sample = 0; sample < nSample_; sample++) {
     double time = timeMax - ((double)sampleMax_ - (double)sample) * 25.;
     time -= weight_timeShift_;
     sumf += shape(time) / max;
     sumf2 += shape(time) / max * shape(time) / max;
     for (int subtime = 0; subtime < 25; subtime++)
       histo->Fill(float(sample * 25. + subtime) / 25., shape(time + subtime));
   }
   double lambda = 1. / (sumf2 - sumf * sumf / nSample_);
   double gamma = -lambda * sumf / nSample_;
   double* weight = new double[nSample_];
   for (unsigned int sample = 0; sample < nSample_; sample++) {
     double time = timeMax - ((double)sampleMax_ - (double)sample) * 25.;
     time -= weight_timeShift_;
     weight[sample] = lambda * shape(time) / max + gamma;
   }
 
   int* iweight = new int[nSample_];
   for (unsigned int sample = 0; sample < nSample_; sample++)
     iweight[sample] = uncodeWeight(weight[sample], complement2_);
 
   // Let's check:
   int isumw = 0;
   for (unsigned int sample = 0; sample < nSample_; sample++)
     isumw += iweight[sample];
   unsigned int imax = (unsigned int)(pow(2., int(complement2_)) - 1);
   isumw = (isumw & imax);
 
   double ampl = 0.;
   double sumw = 0.;
   for (unsigned int sample = 0; sample < nSample_; sample++) {
     double time = timeMax - ((double)sampleMax_ - (double)sample) * 25.;
     time -= weight_timeShift_;
     ampl += weight[sample] * shape(time);
     sumw += weight[sample];
     ss << "weight=" << weight[sample] << " shape=" << shape(time) << "\n";
   }
   ss << "Weights: sum=" << isumw << " in float =" << uncodeWeight(isumw, complement2_) << " sum of floats =" << sumw
      << "\n";
   ss << "Weights: sum (weight*shape) = " << ampl << "\n";
 
   // Let's correct for bias if any
   if (weight_unbias_recovery_) {
     int count = 0;
     while (isumw != 0 && count < 10) {
       double min = 99.;
       unsigned int index = 0;
       if ((isumw & (1 << (complement2_ - 1))) != 0) {
         // add 1:
         ss << "Correcting for bias: adding 1\n";
         for (unsigned int sample = 0; sample < nSample_; sample++) {
           int new_iweight = iweight[sample] + 1;
           double new_weight = uncodeWeight(new_iweight, complement2_);
           if (fabs(new_weight - weight[sample]) < min) {
             min = fabs(new_weight - weight[sample]);
             index = sample;
           }
         }
         iweight[index]++;
       } else {
         // Sub 1:
         ss << "Correcting for bias: subtracting 1\n";
         for (unsigned int sample = 0; sample < nSample_; sample++) {
           int new_iweight = iweight[sample] - 1;
           double new_weight = uncodeWeight(new_iweight, complement2_);
           if (fabs(new_weight - weight[sample]) < min) {
             min = fabs(new_weight - weight[sample]);
             index = sample;
           }
         }
         iweight[index]--;
       }
       isumw = 0;
       for (unsigned int sample = 0; sample < nSample_; sample++)
         isumw += iweight[sample];
       imax = (unsigned int)(pow(2., int(complement2_)) - 1);
       isumw = (isumw & imax);
       ss << "Correcting weight number: " << index << " sum weights = " << isumw << "\n";
       count++;
     }
   }
 
   // let's check again
   isumw = 0;
   for (unsigned int sample = 0; sample < nSample_; sample++)
     isumw += iweight[sample];
   imax = (unsigned int)(pow(2., int(complement2_)) - 1);
   isumw = (isumw & imax);
   ampl = 0.;
   for (unsigned int sample = 0; sample < nSample_; sample++) {
     double time = timeMax - ((double)sampleMax_ - (double)sample) * 25.;
     time -= weight_timeShift_;
     double new_weight = uncodeWeight(iweight[sample], complement2_);
     sumw += uncodeWeight(iweight[sample], complement2_);
     ampl += new_weight * shape(time);
     ss << "weight unbiased after integer conversion=" << new_weight << " shape=" << shape(time) << "\n";
   }
   ss << "Weights: sum=" << isumw << " in float =" << uncodeWeight(isumw, complement2_) << " sum of floats =" << sumw
      << "\n";
   ss << "Weights: sum (weight*shape) = " << ampl << "\n";
   edm::LogInfo("TopInfo") << ss.str();
 
   std::vector<unsigned int> theWeights;
   for (unsigned int sample = 0; sample < nSample_; sample++)
     theWeights.push_back(iweight[sample]);
 
   delete[] weight;
   delete[] iweight;
   return theWeights;
 }

◆ create_header()

void EcalTPGParamBuilder::create_header ( )

private

Definition at line 2631 of file EcalTPGParamBuilder.cc.

References writeToFiles_.

Referenced by beginJob().

                                         {
   if (!writeToFiles_)
     return;
   (*out_file_) << "COMMENT put your comments here" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           physics EB structure" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
   (*out_file_) << "COMMENT  EtSaturation (GeV), ttf_threshold_Low (GeV), ttf_threshold_High (GeV)" << std::endl;
   (*out_file_) << "COMMENT  FG_lowThreshold (GeV), FG_highThreshold (GeV), FG_lowRatio, FG_highRatio" << std::endl;
   //(*out_file_) <<"COMMENT  SFGVB_SpikeKillingThreshold (GeV)"<<std::endl ; //modif-alex-02/02/2011
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           physics EE structure" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
   (*out_file_) << "COMMENT  EtSaturation (GeV), ttf_threshold_Low (GeV), ttf_threshold_High (GeV)" << std::endl;
   (*out_file_) << "COMMENT  FG_Threshold (GeV), dummy, dummy, dummy" << std::endl;
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           crystal structure (same for EB and EE)" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
   (*out_file_) << "COMMENT  ped, mult, shift [gain12]" << std::endl;
   (*out_file_) << "COMMENT  ped, mult, shift [gain6]" << std::endl;
   (*out_file_) << "COMMENT  ped, mult, shift [gain1]" << std::endl;
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           strip EB structure" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
   (*out_file_) << "COMMENT  sliding_window" << std::endl;
   (*out_file_) << "COMMENT  even_weightGroupId  odd_weightGroupId" << std::endl;
   (*out_file_) << "COMMENT  threshold_sfg lut_sfg" << std::endl;
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           strip EE structure" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
   (*out_file_) << "COMMENT  sliding_window" << std::endl;
   (*out_file_) << "COMMENT  even_weightGroupId  odd_weightGroupId" << std::endl;
   (*out_file_) << "COMMENT  threshold_fg lut_fg" << std::endl;
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           tower EB structure" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
   (*out_file_) << "COMMENT  LUTGroupId" << std::endl;
   (*out_file_) << "COMMENT  FgGroupId" << std::endl;
   (*out_file_) << "COMMENT  spike_killing_threshold" << std::endl;  //modif alex
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           tower EE structure" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
   (*out_file_) << "COMMENT  LUTGroupId" << std::endl;
   (*out_file_) << "COMMENT  tower_lut_fg" << std::endl;
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           Even Weight structure" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
   (*out_file_) << "COMMENT  Weight even" << std::endl;
   (*out_file_) << "COMMENT  weightGroupId" << std::endl;
   (*out_file_) << "COMMENT  w0, w1, w2, w3, w4" << std::endl;
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           Odd Weight structure" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
   (*out_file_) << "COMMENT  Weight odd" << std::endl;
   (*out_file_) << "COMMENT  weightGroupId" << std::endl;
   (*out_file_) << "COMMENT  w0, w1, w2, w3, w4" << std::endl;
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           TP mode" << std::endl;
   (*out_file_) << "COMMENT EnableEBOddFilter" << std::endl;
   (*out_file_) << "COMMENT EnableEEOddFilter" << std::endl;
   (*out_file_) << "COMMENT EnableEBOddPeakFinder" << std::endl;
   (*out_file_) << "COMMENT EnableEEOddPeakFinder" << std::endl;
   (*out_file_) << "COMMENT DisableEBEvenPeakFinder" << std::endl;
   (*out_file_) << "COMMENT DisableEEEvenPeakFinder" << std::endl;
   (*out_file_) << "COMMENT FenixEBStripOutput" << std::endl;
   (*out_file_) << "COMMENT FenixEEStripOutput" << std::endl;
   (*out_file_) << "COMMENT FenixEBStripInfobit2" << std::endl;
   (*out_file_) << "COMMENT FenixEEStripInfobit2" << std::endl;
   (*out_file_) << "COMMENT EBFenixTcpOutput" << std::endl;
   (*out_file_) << "COMMENT EBFenixTcpInfobit1" << std::endl;
   (*out_file_) << "COMMENT EEFenixTcpOutput" << std::endl;
   (*out_file_) << "COMMENT EEFenixTcpInfobit1" << std::endl;
   (*out_file_) << "COMMENT FenixPar15" << std::endl;
   (*out_file_) << "COMMENT FenixPar16" << std::endl;
   (*out_file_) << "COMMENT FenixPar17" << std::endl;
   (*out_file_) << "COMMENT FenixPar18" << std::endl;
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           lut structure" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
   (*out_file_) << "COMMENT  LUTGroupId" << std::endl;
   (*out_file_) << "COMMENT  LUT[1-1024]" << std::endl;
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT           fg EB structure" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
   (*out_file_) << "COMMENT  FgGroupId" << std::endl;
   (*out_file_) << "COMMENT  el, eh, tl, th, lut_fg" << std::endl;
   (*out_file_) << "COMMENT =================================" << std::endl;
   (*out_file_) << "COMMENT" << std::endl;
 }

◆ getCoeff() [1/4]

void EcalTPGParamBuilder::getCoeff	(	coeffStruc &	coeff,
		const EcalGainRatioMap &	gainMap,
		uint	rawId
	)

private

Referenced by analyze().

◆ getCoeff() [2/4]

void EcalTPGParamBuilder::getCoeff	(	coeffStruc &	coeff,
		const EcalPedestalsMap &	pedMap,
		uint	rawId
	)

private

◆ getCoeff() [3/4]

void EcalTPGParamBuilder::getCoeff	(	coeffStruc &	coeff,
		const std::map< EcalLogicID, MonPedestalsDat > &	pedMap,
		const EcalLogicID &	logicId
	)

private

Definition at line 3070 of file EcalTPGParamBuilder.cc.

References EcalLogicID::getID1(), EcalLogicID::getID2(), EcalLogicID::getID3(), MonPedestalsDat::getPedMeanG1(), MonPedestalsDat::getPedMeanG12(), MonPedestalsDat::getPedMeanG6(), createfilelist::int, and coeffStruc::pedestals_.

                                                                {
   // get current pedestal
   coeff.pedestals_[0] = 0;
   coeff.pedestals_[1] = 0;
   coeff.pedestals_[2] = 0;
 
   map<EcalLogicID, MonPedestalsDat>::const_iterator it = pedMap.find(logicId);
   if (it != pedMap.end()) {
     MonPedestalsDat ped = it->second;
     coeff.pedestals_[0] = int(ped.getPedMeanG12() + 0.5);
     coeff.pedestals_[1] = int(ped.getPedMeanG6() + 0.5);
     coeff.pedestals_[2] = int(ped.getPedMeanG1() + 0.5);
   } else
     edm::LogError("TopInfo") << "getCoeff: " << logicId.getID1() << ", " << logicId.getID2() << ", " << logicId.getID3()
                              << " not found in map<EcalLogicID, MonPedestalsDat\n";
 }

◆ getCoeff() [4/4]

void EcalTPGParamBuilder::getCoeff	(	coeffStruc &	coeff,
		const EcalIntercalibConstantMap &	calibMap,
		const EcalLaserAlphaMap &	laserAlphaMap,
		uint	rawId,
		std::string &	ss
	)

private

Definition at line 2955 of file EcalTPGParamBuilder.cc.

References coeffStruc::calibCoeff_, EcalCondObjectContainer< T >::end(), EcalCondObjectContainer< T >::find(), funct::pow(), contentValuesCheck::ss, DetId::subdetId(), Transparency_Correction_, useInterCalibration_, and useTransparencyCorr_.

                                                   {
   // get current intercalibration coeff
   coeff.calibCoeff_ = 1.;
   if (!useInterCalibration_)
     return;
   EcalIntercalibConstantMap::const_iterator icalit = calibMap.find(rawId);
 
   //modif-alex-30/01/2012
   std::map<int, double>::const_iterator itCorr = Transparency_Correction_.find(rawId);
   double icorr = 1.0;
   double alpha_factor = 1.0;
 
   if (useTransparencyCorr_) {
     icorr = itCorr->second;
     if (itCorr != Transparency_Correction_.end()) {
       stringstream ss;
       ss << rawId;
       stringstream ss1;
       ss1 << icorr;
       stringstream ss2;
       ss2 << (*icalit);
       st = "Transparency correction found for xtal " + ss.str() + " corr=" + ss1.str() + " intercalib=" + ss2.str() +
            "\n";
     } else
       edm::LogError("TopInfo") << "ERROR = Transparency correction not found for xtal " << rawId << "\n";
 
     //modif-alex-27-july-2015
     DetId ECALdetid(rawId);
     //    ss << "DETID=" << ECALdetid.subdetId() << "\n";
     stringstream ss;
     ss << ECALdetid.subdetId();
     st += "DETID=" + ss.str() + "\n";
     if (ECALdetid.subdetId() == 1) {  //ECAL BARREL
       EBDetId barrel_detid(rawId);
       EcalLaserAlphaMap::const_iterator italpha = laserAlphaMap.find(barrel_detid);
       if (italpha != laserAlphaMap.end())
         alpha_factor = (*italpha);
       else
         edm::LogError("TopInfo") << "ERROR:LaserAlphe parameter note found!!"
                                  << "\n";
     }
     if (ECALdetid.subdetId() == 2) {  //ECAL ENDCAP
       EEDetId endcap_detid(rawId);
       EcalLaserAlphaMap::const_iterator italpha = laserAlphaMap.find(endcap_detid);
       if (italpha != laserAlphaMap.end())
         alpha_factor = (*italpha);
       else
         edm::LogError("TopInfo") << "ERROR:LaserAlphe parameter note found!!"
                                  << "\n";
     }
 
   }  //transparency corrections applied
 
   //if( icalit != calibMap.end() ) coeff.calibCoeff_ = (*icalit) ;
   //if( icalit != calibMap.end() ) coeff.calibCoeff_ = (*icalit)/icorr; //modif-alex-30/01/2010 tansparency corrections
   //  ss << "rawId " << (*icalit) << " " << icorr << " " << alpha_factor << "\n";
   stringstream ss;
   ss << (*icalit);
   stringstream ss1;
   ss1 << icorr;
   stringstream ss2;
   ss2 << alpha_factor;
   st += "rawId " + ss.str() + " " + ss1.str() + " " + ss2.str() + "\n";
   if (icalit != calibMap.end())
     coeff.calibCoeff_ =
         (*icalit) /
         std::pow(icorr, alpha_factor);  //modif-alex-27/07/2015 tansparency corrections with alpha parameters
 
   else
     edm::LogError("TopInfo") << "getCoeff: " << rawId << " not found in EcalIntercalibConstantMap"
                              << "\n";
 }

◆ getCrate()

std::pair< std::string, int > EcalTPGParamBuilder::getCrate ( int tcc )

private

Definition at line 3225 of file EcalTPGParamBuilder.cc.

References AlCaHLTBitMon_QueryRunRegistry::string.

Referenced by analyze().

                                                              {
   std::stringstream crate;
   std::string pos;
   int slot = 0;
 
   crate << "S2D";
   if (tcc >= 40 && tcc <= 42) {
     crate << "02d";
     slot = 5 + (tcc - 40) * 6;
   }
   if (tcc >= 43 && tcc <= 45) {
     crate << "03d";
     slot = 5 + (tcc - 43) * 6;
   }
   if (tcc >= 37 && tcc <= 39) {
     crate << "04d";
     slot = 5 + (tcc - 37) * 6;
   }
   if (tcc >= 52 && tcc <= 54) {
     crate << "06d";
     slot = 5 + (tcc - 52) * 6;
   }
   if (tcc >= 46 && tcc <= 48) {
     crate << "07d";
     slot = 5 + (tcc - 46) * 6;
   }
   if (tcc >= 49 && tcc <= 51) {
     crate << "08d";
     slot = 5 + (tcc - 49) * 6;
   }
   if (tcc >= 58 && tcc <= 60) {
     crate << "02h";
     slot = 5 + (tcc - 58) * 6;
   }
   if (tcc >= 61 && tcc <= 63) {
     crate << "03h";
     slot = 5 + (tcc - 61) * 6;
   }
   if (tcc >= 55 && tcc <= 57) {
     crate << "04h";
     slot = 5 + (tcc - 55) * 6;
   }
   if (tcc >= 70 && tcc <= 72) {
     crate << "06h";
     slot = 5 + (tcc - 70) * 6;
   }
   if (tcc >= 64 && tcc <= 66) {
     crate << "07h";
     slot = 5 + (tcc - 64) * 6;
   }
   if (tcc >= 67 && tcc <= 69) {
     crate << "08h";
     slot = 5 + (tcc - 67) * 6;
   }
 
   if (tcc >= 76 && tcc <= 81) {
     crate << "02l";
     if (tcc % 2 == 0)
       slot = 2 + (tcc - 76) * 3;
     else
       slot = 4 + (tcc - 77) * 3;
   }
   if (tcc >= 94 && tcc <= 99) {
     crate << "02l";
     if (tcc % 2 == 0)
       slot = 3 + (tcc - 94) * 3;
     else
       slot = 5 + (tcc - 95) * 3;
   }
 
   if (tcc >= 22 && tcc <= 27) {
     crate << "03l";
     if (tcc % 2 == 0)
       slot = 2 + (tcc - 22) * 3;
     else
       slot = 4 + (tcc - 23) * 3;
   }
   if (tcc >= 4 && tcc <= 9) {
     crate << "03l";
     if (tcc % 2 == 0)
       slot = 3 + (tcc - 4) * 3;
     else
       slot = 5 + (tcc - 5) * 3;
   }
 
   if (tcc >= 82 && tcc <= 87) {
     crate << "07l";
     if (tcc % 2 == 0)
       slot = 2 + (tcc - 82) * 3;
     else
       slot = 4 + (tcc - 83) * 3;
   }
   if (tcc >= 100 && tcc <= 105) {
     crate << "07l";
     if (tcc % 2 == 0)
       slot = 3 + (tcc - 100) * 3;
     else
       slot = 5 + (tcc - 101) * 3;
   }
 
   if (tcc >= 28 && tcc <= 33) {
     crate << "08l";
     if (tcc % 2 == 0)
       slot = 2 + (tcc - 28) * 3;
     else
       slot = 4 + (tcc - 29) * 3;
   }
   if (tcc >= 10 && tcc <= 15) {
     crate << "08l";
     if (tcc % 2 == 0)
       slot = 3 + (tcc - 10) * 3;
     else
       slot = 5 + (tcc - 11) * 3;
   }
 
   if (tcc == 34) {
     crate << "04l";
     slot = 2;
   }
   if (tcc == 16) {
     crate << "04l";
     slot = 3;
   }
   if (tcc == 35) {
     crate << "04l";
     slot = 4;
   }
   if (tcc == 17) {
     crate << "04l";
     slot = 5;
   }
   if (tcc == 36) {
     crate << "04l";
     slot = 8;
   }
   if (tcc == 18) {
     crate << "04l";
     slot = 9;
   }
   if (tcc == 19) {
     crate << "04l";
     slot = 10;
   }
   if (tcc == 1) {
     crate << "04l";
     slot = 11;
   }
   if (tcc == 20) {
     crate << "04l";
     slot = 14;
   }
   if (tcc == 2) {
     crate << "04l";
     slot = 15;
   }
   if (tcc == 21) {
     crate << "04l";
     slot = 16;
   }
   if (tcc == 3) {
     crate << "04l";
     slot = 17;
   }
 
   if (tcc == 88) {
     crate << "06l";
     slot = 2;
   }
   if (tcc == 106) {
     crate << "06l";
     slot = 3;
   }
   if (tcc == 89) {
     crate << "06l";
     slot = 4;
   }
   if (tcc == 107) {
     crate << "06l";
     slot = 5;
   }
   if (tcc == 90) {
     crate << "06l";
     slot = 8;
   }
   if (tcc == 108) {
     crate << "06l";
     slot = 9;
   }
   if (tcc == 73) {
     crate << "06l";
     slot = 10;
   }
   if (tcc == 91) {
     crate << "06l";
     slot = 11;
   }
   if (tcc == 74) {
     crate << "06l";
     slot = 14;
   }
   if (tcc == 92) {
     crate << "06l";
     slot = 15;
   }
   if (tcc == 75) {
     crate << "06l";
     slot = 16;
   }
   if (tcc == 93) {
     crate << "06l";
     slot = 17;
   }
 
   return std::pair<std::string, int>(crate.str(), slot);
 }

◆ getDet()

std::string EcalTPGParamBuilder::getDet ( int tcc )

private

Definition at line 3187 of file EcalTPGParamBuilder.cc.

Referenced by analyze().

                                              {
   std::stringstream sdet;
 
   if (tcc > 36 && tcc < 55)
     sdet << "EB-" << tcc - 36;
   else if (tcc >= 55 && tcc < 73)
     sdet << "EB+" << tcc - 54;
   else if (tcc <= 36)
     sdet << "EE-";
   else
     sdet << "EE+";
 
   if (tcc <= 36 || tcc >= 73) {
     if (tcc >= 73)
       tcc -= 72;
     if (tcc == 1 || tcc == 18 || tcc == 19 || tcc == 36)
       sdet << 7;
     else if (tcc == 2 || tcc == 3 || tcc == 20 || tcc == 21)
       sdet << 8;
     else if (tcc == 4 || tcc == 5 || tcc == 22 || tcc == 23)
       sdet << 9;
     else if (tcc == 6 || tcc == 7 || tcc == 24 || tcc == 25)
       sdet << 1;
     else if (tcc == 8 || tcc == 9 || tcc == 26 || tcc == 27)
       sdet << 2;
     else if (tcc == 10 || tcc == 11 || tcc == 28 || tcc == 29)
       sdet << 3;
     else if (tcc == 12 || tcc == 13 || tcc == 30 || tcc == 31)
       sdet << 4;
     else if (tcc == 14 || tcc == 15 || tcc == 32 || tcc == 33)
       sdet << 5;
     else if (tcc == 16 || tcc == 17 || tcc == 34 || tcc == 35)
       sdet << 6;
   }
 
   return sdet.str();
 }

◆ getEtaSlice()

int EcalTPGParamBuilder::getEtaSlice	(	int	tccId,
		int	towerInTCC
	)

private

Definition at line 400 of file EcalTPGParamBuilder.cc.

References ecaldqm::tccId().

                                                               {
   int etaSlice = (towerInTCC - 1) / 4 + 1;
   // barrel
   if (tccId > 36 && tccId < 73)
     return etaSlice;
   //endcap
   else {
     if (tccId >= 1 && tccId <= 18)
       etaSlice += 21;  // inner -
     else if (tccId >= 19 && tccId <= 36)
       etaSlice += 17;  // outer -
     else if (tccId >= 91 && tccId <= 108)
       etaSlice += 21;  // inner +
     else if (tccId >= 73 && tccId <= 90)
       etaSlice += 17;  // outer +
   }
   return etaSlice;
 }

◆ getGCTRegionEta()

int EcalTPGParamBuilder::getGCTRegionEta ( int tteta )

private

Definition at line 3178 of file EcalTPGParamBuilder.cc.

Referenced by analyze().

                                                   {
   int gcteta = 0;
   if (tteta > 0)
     gcteta = (tteta - 1) / 4 + 11;
   else if (tteta < 0)
     gcteta = (tteta + 1) / 4 + 10;
   return gcteta;
 }

◆ getGCTRegionPhi()

int EcalTPGParamBuilder::getGCTRegionPhi ( int ttphi )

private

Definition at line 3168 of file EcalTPGParamBuilder.cc.

Referenced by analyze().

                                                   {
   int gctphi = 0;
   gctphi = (ttphi + 1) / 4;
   if (ttphi <= 2)
     gctphi = 0;
   if (ttphi >= 71)
     gctphi = 0;
   return gctphi;
 }

◆ realignBaseline()

bool EcalTPGParamBuilder::realignBaseline	(	linStruc &	lin,
		float	forceBase12,
		int	cmsswid
	)

private

Definition at line 3133 of file EcalTPGParamBuilder.cc.

References newFWLiteAna::base, dqmMemoryStats::float, mps_fire::i, linStruc::mult_, convertSQLiteXML::ok, linStruc::pedestal_, funct::pow(), and linStruc::shift_.

Referenced by analyze().

                                                                                        {
   bool ok(true);
   float base[3] = {forceBase12, float(lin.pedestal_[1]), float(lin.pedestal_[2])};
   for (int i = 1; i < 3; i++) {
     if (lin.mult_[i] > 0) {
       base[i] = float(lin.pedestal_[i]) - float(lin.mult_[0]) / float(lin.mult_[i]) *
                                               pow(2., -(lin.shift_[0] - lin.shift_[i])) * (lin.pedestal_[0] - base[0]);
     } else
       base[i] = 0;
   }
   for (int i = 0; i < 3; i++) {
     if (base[i] < 0) {
       edm::LogError("TopInfo") << "PROBLEM in realignBaseline: xtal=" << cmsswid << " base= " << base[i] << ", "
                                << lin.pedestal_[i] << " for gainId[0-2]=" << i << " ==> smaller than 0 ==> set to 0"
                                << "  mult12:" << lin.mult_[0] << " mult:" << lin.mult_[i]
                                << " ped12:" << lin.pedestal_[0] << " ped:" << lin.pedestal_[i] << "  base12:" << base[0]
                                << " shift12:" << lin.shift_[0] << " shift: " << lin.shift_[i] << "\n";
       lin.pedestal_[i] = 0;
       ok = false;
     } else if (base[i] > 1024) {
       edm::LogError("TopInfo") << "PROBLEM in realignBaseline: xtal=" << cmsswid << " base= " << base[i] << ", "
                                << lin.pedestal_[i] << " for gainId[0-2]=" << i
                                << " ==> larger than 1024 ==> set to 1024"
                                << "  mult12:" << lin.mult_[0] << " mult:" << lin.mult_[i]
                                << " ped12:" << lin.pedestal_[0] << " ped:" << lin.pedestal_[i] << "  base12:" << base[0]
                                << " shift12:" << lin.shift_[0] << " shift: " << lin.shift_[i] << "\n";
       lin.pedestal_[i] = 1024;
       ok = false;
     } else {
       lin.pedestal_[i] = base[i];
     }
   }
   return ok;
 }

◆ uncodeWeight() [1/2]

int EcalTPGParamBuilder::uncodeWeight	(	double	weight,
		int	complement2 = `7`
	)

private

Definition at line 2755 of file EcalTPGParamBuilder.cc.

References createfilelist::int, SiStripPI::max, and funct::pow().

Referenced by computeWeights().

                                                                     {
   int iweight;
   unsigned int max = (unsigned int)(pow(2., complement2) - 1);
   if (weight > 0)
     iweight = int((1 << 6) * weight + 0.5);  // +0.5 for rounding pb
   else
     iweight = max - int(-weight * (1 << 6) + 0.5) + 1;
   iweight = iweight & max;
   return iweight;
 }

◆ uncodeWeight() [2/2]

double EcalTPGParamBuilder::uncodeWeight	(	int	iweight,
		int	complement2 = `7`
	)

private

Definition at line 2766 of file EcalTPGParamBuilder.cc.

References funct::pow(), and mps_merge::weight.

                                                                      {
   double weight = double(iweight) / pow(2., 6.);
   // test if negative weight:
   if ((iweight & (1 << (complement2 - 1))) != 0)
     weight = (double(iweight) - pow(2., complement2)) / pow(2., 6.);
   return weight;
 }

Member Data Documentation

◆ bst_conf_id_

int EcalTPGParamBuilder::bst_conf_id_

private

Definition at line 212 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ btt_conf_id_

int EcalTPGParamBuilder::btt_conf_id_

private

Definition at line 211 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ bxt_conf_id_

int EcalTPGParamBuilder::bxt_conf_id_

private

Definition at line 210 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ coke_conf_id_

int EcalTPGParamBuilder::coke_conf_id_

private

Definition at line 213 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ complement2_

unsigned int EcalTPGParamBuilder::complement2_

private

Definition at line 156 of file EcalTPGParamBuilder.h.

Referenced by computeWeights().

◆ db_

EcalTPGDBApp* EcalTPGParamBuilder::db_

private

Definition at line 195 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ DBEE_

bool EcalTPGParamBuilder::DBEE_

private

Definition at line 199 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ DBrunNb_

unsigned int EcalTPGParamBuilder::DBrunNb_

private

Definition at line 198 of file EcalTPGParamBuilder.h.

◆ del_conf_id_

int EcalTPGParamBuilder::del_conf_id_

private

Definition at line 209 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ delays_EB_

std::map<int, std::vector<int> > EcalTPGParamBuilder::delays_EB_

private

Definition at line 182 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ delays_EE_

std::map<int, std::vector<int> > EcalTPGParamBuilder::delays_EE_

private

Definition at line 184 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ ecalADCToGeVConstantToken_

edm::ESGetToken<EcalADCToGeVConstant, EcalADCToGeVConstantRcd> EcalTPGParamBuilder::ecalADCToGeVConstantToken_

private

Definition at line 123 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ ecalGainRatiosToken_

edm::ESGetToken<EcalGainRatios, EcalGainRatiosRcd> EcalTPGParamBuilder::ecalGainRatiosToken_

private

Definition at line 122 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ ecalIntercalibConstantsToken_

edm::ESGetToken<EcalIntercalibConstants, EcalIntercalibConstantsRcd> EcalTPGParamBuilder::ecalIntercalibConstantsToken_

private

Definition at line 121 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ ecalLaserAlphasToken_

edm::ESGetToken<EcalLaserAlphas, EcalLaserAlphasRcd> EcalTPGParamBuilder::ecalLaserAlphasToken_

private

Definition at line 118 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ ecalLaserAPDPNRatiosToken_

edm::ESGetToken<EcalLaserAPDPNRatios, EcalLaserAPDPNRatiosRcd> EcalTPGParamBuilder::ecalLaserAPDPNRatiosToken_

private

Definition at line 119 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ ecalmappingToken_

edm::ESGetToken<EcalElectronicsMapping, EcalMappingRcd> EcalTPGParamBuilder::ecalmappingToken_

private

Definition at line 115 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ ecalPedestalsToken_

edm::ESGetToken<EcalPedestals, EcalPedestalsRcd> EcalTPGParamBuilder::ecalPedestalsToken_

private

Definition at line 120 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ Et_sat_EB_

double EcalTPGParamBuilder::Et_sat_EB_

private

Definition at line 127 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), computeFineGrainEBParameters(), computeLinearizerParam(), computeLUT(), and EcalTPGParamBuilder().

◆ Et_sat_EE_

double EcalTPGParamBuilder::Et_sat_EE_

private

Definition at line 127 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), computeFineGrainEEParameters(), computeLinearizerParam(), computeLUT(), and EcalTPGParamBuilder().

◆ eTTmap_

const EcalTrigTowerConstituentsMap* EcalTPGParamBuilder::eTTmap_

private

Definition at line 114 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ eTTmapToken_

edm::ESGetToken<EcalTrigTowerConstituentsMap, IdealGeometryRecord> EcalTPGParamBuilder::eTTmapToken_

private

Definition at line 113 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ FG_highRatio_EB_

double EcalTPGParamBuilder::FG_highRatio_EB_

private

Definition at line 163 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), computeFineGrainEBParameters(), and EcalTPGParamBuilder().

◆ FG_highThreshold_EB_

double EcalTPGParamBuilder::FG_highThreshold_EB_

private

Definition at line 163 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), computeFineGrainEBParameters(), and EcalTPGParamBuilder().

◆ FG_lowRatio_EB_

double EcalTPGParamBuilder::FG_lowRatio_EB_

private

Definition at line 163 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), computeFineGrainEBParameters(), and EcalTPGParamBuilder().

◆ FG_lowThreshold_EB_

double EcalTPGParamBuilder::FG_lowThreshold_EB_

private

Definition at line 163 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), computeFineGrainEBParameters(), and EcalTPGParamBuilder().

◆ FG_lut_EB_

unsigned int EcalTPGParamBuilder::FG_lut_EB_

private

Definition at line 164 of file EcalTPGParamBuilder.h.

Referenced by computeFineGrainEBParameters(), and EcalTPGParamBuilder().

◆ FG_lut_strip_EE_

unsigned int EcalTPGParamBuilder::FG_lut_strip_EE_

private

Definition at line 166 of file EcalTPGParamBuilder.h.

Referenced by computeFineGrainEEParameters(), and EcalTPGParamBuilder().

◆ FG_lut_tower_EE_

unsigned int EcalTPGParamBuilder::FG_lut_tower_EE_

private

Definition at line 166 of file EcalTPGParamBuilder.h.

Referenced by computeFineGrainEEParameters(), and EcalTPGParamBuilder().

◆ FG_Threshold_EE_

double EcalTPGParamBuilder::FG_Threshold_EE_

private

Definition at line 165 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), computeFineGrainEEParameters(), and EcalTPGParamBuilder().

◆ fgr_conf_id_

int EcalTPGParamBuilder::fgr_conf_id_

private

Definition at line 204 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ forcedPedestalValue_

int EcalTPGParamBuilder::forcedPedestalValue_

private

Definition at line 167 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ forceEtaSlice_

bool EcalTPGParamBuilder::forceEtaSlice_

private

Definition at line 168 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ geomFile_

std::ofstream* EcalTPGParamBuilder::geomFile_

private

Definition at line 194 of file EcalTPGParamBuilder.h.

Referenced by EcalTPGParamBuilder().

◆ H2_

bool EcalTPGParamBuilder::H2_

private

Definition at line 171 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ lin_conf_id_

int EcalTPGParamBuilder::lin_conf_id_

private

Definition at line 202 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ lut_conf_id_

int EcalTPGParamBuilder::lut_conf_id_

private

Definition at line 203 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ LUT_constant_EB_

double EcalTPGParamBuilder::LUT_constant_EB_

private

Definition at line 159 of file EcalTPGParamBuilder.h.

Referenced by computeLUT(), and EcalTPGParamBuilder().

◆ LUT_constant_EE_

double EcalTPGParamBuilder::LUT_constant_EE_

private

Definition at line 160 of file EcalTPGParamBuilder.h.

Referenced by computeLUT(), and EcalTPGParamBuilder().

◆ LUT_noise_EB_

double EcalTPGParamBuilder::LUT_noise_EB_

private

Definition at line 159 of file EcalTPGParamBuilder.h.

Referenced by computeLUT(), and EcalTPGParamBuilder().

◆ LUT_noise_EE_

double EcalTPGParamBuilder::LUT_noise_EE_

private

Definition at line 160 of file EcalTPGParamBuilder.h.

Referenced by computeLUT(), and EcalTPGParamBuilder().

◆ LUT_option_

std::string EcalTPGParamBuilder::LUT_option_

private

Definition at line 157 of file EcalTPGParamBuilder.h.

Referenced by analyze(), computeLUT(), and EcalTPGParamBuilder().

◆ LUT_stochastic_EB_

double EcalTPGParamBuilder::LUT_stochastic_EB_

private

Definition at line 159 of file EcalTPGParamBuilder.h.

Referenced by computeLUT(), and EcalTPGParamBuilder().

◆ LUT_stochastic_EE_

double EcalTPGParamBuilder::LUT_stochastic_EE_

private

Definition at line 160 of file EcalTPGParamBuilder.h.

Referenced by computeLUT(), and EcalTPGParamBuilder().

◆ LUT_threshold_EB_

double EcalTPGParamBuilder::LUT_threshold_EB_

private

Definition at line 158 of file EcalTPGParamBuilder.h.

Referenced by computeLUT(), and EcalTPGParamBuilder().

◆ LUT_threshold_EE_

double EcalTPGParamBuilder::LUT_threshold_EE_

private

Definition at line 158 of file EcalTPGParamBuilder.h.

Referenced by computeLUT(), and EcalTPGParamBuilder().

◆ m_write_bst

int EcalTPGParamBuilder::m_write_bst

private

Definition at line 227 of file EcalTPGParamBuilder.h.

Referenced by EcalTPGParamBuilder().

◆ m_write_btt

int EcalTPGParamBuilder::m_write_btt

private

Definition at line 226 of file EcalTPGParamBuilder.h.

Referenced by EcalTPGParamBuilder().

◆ m_write_bxt

int EcalTPGParamBuilder::m_write_bxt

private

Definition at line 225 of file EcalTPGParamBuilder.h.

Referenced by EcalTPGParamBuilder().

◆ m_write_del

int EcalTPGParamBuilder::m_write_del

private

Definition at line 224 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ m_write_fgr

int EcalTPGParamBuilder::m_write_fgr

private

Definition at line 221 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ m_write_lin

int EcalTPGParamBuilder::m_write_lin

private

Definition at line 217 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ m_write_lut

int EcalTPGParamBuilder::m_write_lut

private

Definition at line 218 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ m_write_ped

int EcalTPGParamBuilder::m_write_ped

private

Definition at line 216 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ m_write_sli

int EcalTPGParamBuilder::m_write_sli

private

Definition at line 222 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ m_write_spi

int EcalTPGParamBuilder::m_write_spi

private

Definition at line 223 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ m_write_wei

int EcalTPGParamBuilder::m_write_wei

private

Definition at line 219 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ m_write_wei2

int EcalTPGParamBuilder::m_write_wei2

private

Definition at line 220 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ nSample_

unsigned int EcalTPGParamBuilder::nSample_

private

Definition at line 155 of file EcalTPGParamBuilder.h.

Referenced by computeWeights().

◆ ntupleCrate_

Char_t EcalTPGParamBuilder::ntupleCrate_[10]

private

Definition at line 231 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ ntupleDet_

Char_t EcalTPGParamBuilder::ntupleDet_[10]

private

Definition at line 230 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ ntupleInts_

Int_t* EcalTPGParamBuilder::ntupleInts_

private

Definition at line 229 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ NWEIGHTS

constexpr uint EcalTPGParamBuilder::NWEIGHTS = 5

staticprivate

Definition at line 137 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ out_file_

std::ofstream* EcalTPGParamBuilder::out_file_

private

Definition at line 193 of file EcalTPGParamBuilder.h.

Referenced by analyze(), EcalTPGParamBuilder(), and ~EcalTPGParamBuilder().

◆ ped_conf_id_

int EcalTPGParamBuilder::ped_conf_id_

private

Definition at line 201 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ pedestal_offset_

unsigned int EcalTPGParamBuilder::pedestal_offset_

private

Definition at line 169 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ phases_EB_

std::map<int, std::vector<int> > EcalTPGParamBuilder::phases_EB_

private

Definition at line 183 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ phases_EE_

std::map<int, std::vector<int> > EcalTPGParamBuilder::phases_EE_

private

Definition at line 185 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ sampleMax_

unsigned int EcalTPGParamBuilder::sampleMax_

private

Definition at line 129 of file EcalTPGParamBuilder.h.

Referenced by computeWeights(), and EcalTPGParamBuilder().

◆ SFGVB_lut_

unsigned int EcalTPGParamBuilder::SFGVB_lut_

private

Definition at line 169 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ SFGVB_SpikeKillingThreshold_

int EcalTPGParamBuilder::SFGVB_SpikeKillingThreshold_

private

Definition at line 170 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ SFGVB_Threshold_

unsigned int EcalTPGParamBuilder::SFGVB_Threshold_

private

Definition at line 169 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ shapeEB_

EBShape EcalTPGParamBuilder::shapeEB_

private

Definition at line 190 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ shapeEE_

EEShape EcalTPGParamBuilder::shapeEE_

private

Definition at line 191 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ sli_conf_id_

int EcalTPGParamBuilder::sli_conf_id_

private

Definition at line 205 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ sliding_

unsigned int EcalTPGParamBuilder::sliding_

private

Definition at line 128 of file EcalTPGParamBuilder.h.

Referenced by analyze(), computeLinearizerParam(), and EcalTPGParamBuilder().

◆ spi_conf_id_

int EcalTPGParamBuilder::spi_conf_id_

private

Definition at line 208 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ tag_

std::string EcalTPGParamBuilder::tag_

private

Definition at line 214 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ theBarrelGeometry_

const CaloSubdetectorGeometry* EcalTPGParamBuilder::theBarrelGeometry_

private

Definition at line 112 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ theBarrelGeometryToken_

edm::ESGetToken<CaloSubdetectorGeometry, EcalBarrelGeometryRecord> EcalTPGParamBuilder::theBarrelGeometryToken_

private

Definition at line 110 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ theEndcapGeometry_

const CaloSubdetectorGeometry* EcalTPGParamBuilder::theEndcapGeometry_

private

Definition at line 111 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ theEndcapGeometryToken_

edm::ESGetToken<CaloSubdetectorGeometry, EcalEndcapGeometryRecord> EcalTPGParamBuilder::theEndcapGeometryToken_

private

Definition at line 109 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ theMapping_

const EcalElectronicsMapping* EcalTPGParamBuilder::theMapping_

private

Definition at line 116 of file EcalTPGParamBuilder.h.

Referenced by analyze().

◆ TimingDelays_EB_

std::string EcalTPGParamBuilder::TimingDelays_EB_

private

Definition at line 178 of file EcalTPGParamBuilder.h.

Referenced by EcalTPGParamBuilder().

◆ TimingDelays_EE_

std::string EcalTPGParamBuilder::TimingDelays_EE_

private

Definition at line 179 of file EcalTPGParamBuilder.h.

Referenced by EcalTPGParamBuilder().

◆ TimingPhases_EB_

std::string EcalTPGParamBuilder::TimingPhases_EB_

private

Definition at line 180 of file EcalTPGParamBuilder.h.

Referenced by EcalTPGParamBuilder().

◆ TimingPhases_EE_

std::string EcalTPGParamBuilder::TimingPhases_EE_

private

Definition at line 181 of file EcalTPGParamBuilder.h.

Referenced by EcalTPGParamBuilder().

◆ TPmode_DisableEBEvenPeakFinder_

bool EcalTPGParamBuilder::TPmode_DisableEBEvenPeakFinder_

private

Definition at line 144 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_DisableEEEvenPeakFinder_

bool EcalTPGParamBuilder::TPmode_DisableEEEvenPeakFinder_

private

Definition at line 145 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_EnableEBOddFilter_

bool EcalTPGParamBuilder::TPmode_EnableEBOddFilter_

private

Definition at line 140 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_EnableEBOddPeakFinder_

bool EcalTPGParamBuilder::TPmode_EnableEBOddPeakFinder_

private

Definition at line 142 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_EnableEEOddFilter_

bool EcalTPGParamBuilder::TPmode_EnableEEOddFilter_

private

Definition at line 141 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_EnableEEOddPeakFinder_

bool EcalTPGParamBuilder::TPmode_EnableEEOddPeakFinder_

private

Definition at line 143 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_FenixEBStripInfobit2_

unsigned int EcalTPGParamBuilder::TPmode_FenixEBStripInfobit2_

private

Definition at line 148 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_FenixEBStripOutput_

unsigned int EcalTPGParamBuilder::TPmode_FenixEBStripOutput_

private

Definition at line 146 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_FenixEBTcpInfobit1_

unsigned int EcalTPGParamBuilder::TPmode_FenixEBTcpInfobit1_

private

Definition at line 151 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_FenixEBTcpOutput_

unsigned int EcalTPGParamBuilder::TPmode_FenixEBTcpOutput_

private

Definition at line 150 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_FenixEEStripInfobit2_

unsigned int EcalTPGParamBuilder::TPmode_FenixEEStripInfobit2_

private

Definition at line 149 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_FenixEEStripOutput_

unsigned int EcalTPGParamBuilder::TPmode_FenixEEStripOutput_

private

Definition at line 147 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_FenixEETcpInfobit1_

unsigned int EcalTPGParamBuilder::TPmode_FenixEETcpInfobit1_

private

Definition at line 153 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ TPmode_FenixEETcpOutput_

unsigned int EcalTPGParamBuilder::TPmode_FenixEETcpOutput_

private

Definition at line 152 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ Transparency_Corr_

std::string EcalTPGParamBuilder::Transparency_Corr_

private

Definition at line 174 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ Transparency_Correction_

std::map<int, double> EcalTPGParamBuilder::Transparency_Correction_

private

Definition at line 188 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and getCoeff().

◆ TTF_highThreshold_EB_

double EcalTPGParamBuilder::TTF_highThreshold_EB_

private

Definition at line 161 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), computeLUT(), and EcalTPGParamBuilder().

◆ TTF_highThreshold_EE_

double EcalTPGParamBuilder::TTF_highThreshold_EE_

private

Definition at line 162 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), computeLUT(), and EcalTPGParamBuilder().

◆ TTF_lowThreshold_EB_

double EcalTPGParamBuilder::TTF_lowThreshold_EB_

private

Definition at line 161 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), computeLUT(), and EcalTPGParamBuilder().

◆ TTF_lowThreshold_EE_

double EcalTPGParamBuilder::TTF_lowThreshold_EE_

private

Definition at line 162 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), computeLUT(), and EcalTPGParamBuilder().

◆ useInterCalibration_

bool EcalTPGParamBuilder::useInterCalibration_

private

Definition at line 171 of file EcalTPGParamBuilder.h.

Referenced by EcalTPGParamBuilder(), and getCoeff().

◆ useTransparencyCorr_

bool EcalTPGParamBuilder::useTransparencyCorr_

private

Definition at line 175 of file EcalTPGParamBuilder.h.

Referenced by analyze(), EcalTPGParamBuilder(), and getCoeff().

◆ useTransverseEnergy_

bool EcalTPGParamBuilder::useTransverseEnergy_

private

Definition at line 125 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ version_

int EcalTPGParamBuilder::version_

private

Definition at line 215 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ wei2_conf_id_

int EcalTPGParamBuilder::wei2_conf_id_

private

Definition at line 207 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ wei_conf_id_

int EcalTPGParamBuilder::wei_conf_id_

private

Definition at line 206 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ weight_even_computeFromShape_

bool EcalTPGParamBuilder::weight_even_computeFromShape_

private

Definition at line 132 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ weight_even_idMapFile_

std::string EcalTPGParamBuilder::weight_even_idMapFile_

private

Definition at line 133 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ weight_even_weightGroupFile_

std::string EcalTPGParamBuilder::weight_even_weightGroupFile_

private

Definition at line 134 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ weight_odd_idMapFile_

std::string EcalTPGParamBuilder::weight_odd_idMapFile_

private

Definition at line 135 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ weight_odd_weightGroupFile_

std::string EcalTPGParamBuilder::weight_odd_weightGroupFile_

private

Definition at line 136 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ weight_timeShift_

double EcalTPGParamBuilder::weight_timeShift_

private

Definition at line 130 of file EcalTPGParamBuilder.h.

Referenced by computeWeights(), and EcalTPGParamBuilder().

◆ weight_unbias_recovery_

bool EcalTPGParamBuilder::weight_unbias_recovery_

private

Definition at line 131 of file EcalTPGParamBuilder.h.

Referenced by computeWeights(), and EcalTPGParamBuilder().

◆ weight_useDoubleWeights_

bool EcalTPGParamBuilder::weight_useDoubleWeights_

private

Definition at line 139 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ writeToDB_

bool EcalTPGParamBuilder::writeToDB_

private

Definition at line 196 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and EcalTPGParamBuilder().

◆ writeToFiles_

bool EcalTPGParamBuilder::writeToFiles_

private

Definition at line 197 of file EcalTPGParamBuilder.h.

Referenced by analyze(), beginJob(), create_header(), EcalTPGParamBuilder(), and ~EcalTPGParamBuilder().

◆ xtal_LSB_EB_

double EcalTPGParamBuilder::xtal_LSB_EB_

private

Definition at line 126 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and computeLinearizerParam().

◆ xtal_LSB_EE_

double EcalTPGParamBuilder::xtal_LSB_EE_

private

Definition at line 126 of file EcalTPGParamBuilder.h.

Referenced by analyze(), and computeLinearizerParam().

Public Member Functions

Private Member Functions

Private Attributes

Static Private Attributes

Additional Inherited Members

Detailed Description

Constructor & Destructor Documentation

◆ EcalTPGParamBuilder()

◆ ~EcalTPGParamBuilder()

Member Function Documentation

◆ analyze()

◆ beginJob()

◆ checkIfOK()

◆ computeFineGrainEBParameters()

◆ computeFineGrainEEParameters()

◆ computeLinearizerParam()

◆ computeLUT()

◆ computeWeights()

◆ create_header()

◆ getCoeff() [1/4]

◆ getCoeff() [2/4]

◆ getCoeff() [3/4]

◆ getCoeff() [4/4]

◆ getCrate()

◆ getDet()

◆ getEtaSlice()

◆ getGCTRegionEta()

◆ getGCTRegionPhi()

◆ realignBaseline()

◆ uncodeWeight() [1/2]

◆ uncodeWeight() [2/2]

Member Data Documentation

◆ bst_conf_id_

◆ btt_conf_id_

◆ bxt_conf_id_

◆ coke_conf_id_

◆ complement2_

◆ db_

◆ DBEE_

◆ DBrunNb_

◆ del_conf_id_

◆ delays_EB_

◆ delays_EE_

◆ ecalADCToGeVConstantToken_

◆ ecalGainRatiosToken_

◆ ecalIntercalibConstantsToken_

◆ ecalLaserAlphasToken_

◆ ecalLaserAPDPNRatiosToken_

◆ ecalmappingToken_

◆ ecalPedestalsToken_

◆ Et_sat_EB_

◆ Et_sat_EE_

◆ eTTmap_

◆ eTTmapToken_

◆ FG_highRatio_EB_

◆ FG_highThreshold_EB_

◆ FG_lowRatio_EB_

◆ FG_lowThreshold_EB_

◆ FG_lut_EB_

◆ FG_lut_strip_EE_

◆ FG_lut_tower_EE_

◆ FG_Threshold_EE_

◆ fgr_conf_id_

◆ forcedPedestalValue_

◆ forceEtaSlice_

◆ geomFile_

◆ H2_

◆ lin_conf_id_

◆ lut_conf_id_

◆ LUT_constant_EB_

◆ LUT_constant_EE_

◆ LUT_noise_EB_

◆ LUT_noise_EE_

◆ LUT_option_

◆ LUT_stochastic_EB_

◆ LUT_stochastic_EE_

◆ LUT_threshold_EB_

◆ LUT_threshold_EE_

◆ m_write_bst

◆ m_write_btt