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#include <EcalTPGParamBuilder.h>
Public Member Functions | |
| virtual void | analyze (const edm::Event &evt, const edm::EventSetup &evtSetup) |
| virtual void | beginJob () |
| bool | checkIfOK (EcalPedestals::Item item) |
| EcalTPGParamBuilder (edm::ParameterSet const &pSet) | |
| ~EcalTPGParamBuilder () | |
Private Member Functions | |
| 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, uint rawId) |
| 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) |
| double | uncodeWeight (int iweight, int complement2=7) |
| int | uncodeWeight (double weight, int complement2=7) |
Private Attributes | |
| int | bst_conf_id_ |
| int | btt_conf_id_ |
| int | bxt_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_ |
| double | Et_sat_EB_ |
| double | Et_sat_EE_ |
| edm::ESHandle < EcalTrigTowerConstituentsMap > | eTTmap_ |
| 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 |
| 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_ |
| int | sli_conf_id_ |
| unsigned int | sliding_ |
| int | spi_conf_id_ |
| std::string | tag_ |
| const CaloSubdetectorGeometry * | theBarrelGeometry_ |
| const CaloSubdetectorGeometry * | theEndcapGeometry_ |
| const EcalElectronicsMapping * | theMapping_ |
| std::string | TimingDelays_EB_ |
| std::string | TimingDelays_EE_ |
| std::string | TimingPhases_EB_ |
| std::string | TimingPhases_EE_ |
| double | TTF_highThreshold_EB_ |
| double | TTF_highThreshold_EE_ |
| double | TTF_lowThreshold_EB_ |
| double | TTF_lowThreshold_EE_ |
| bool | useInterCalibration_ |
| bool | useTransverseEnergy_ |
| int | version_ |
| int | wei_conf_id_ |
| double | weight_timeShift_ |
| bool | weight_unbias_recovery_ |
| bool | writeToDB_ |
| bool | writeToFiles_ |
| double | xtal_LSB_EB_ |
| double | xtal_LSB_EE_ |
Definition at line 64 of file EcalTPGParamBuilder.h.
| EcalTPGParamBuilder::EcalTPGParamBuilder | ( | edm::ParameterSet const & | pSet | ) | [explicit] |
Definition at line 54 of file EcalTPGParamBuilder.cc.
References bst_conf_id_, btt_conf_id_, bxt_conf_id_, gather_cfg::cout, db_, DBEE_, del_conf_id_, delays_EB_, delays_EE_, alignCSCRings::e, Et_sat_EB_, Et_sat_EE_, exception, 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_, 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, dbtoconf::out, out_file_, cmsMakeMELists::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_, tag_, TimingDelays_EB_, TimingDelays_EE_, TimingPhases_EB_, TimingPhases_EE_, TTF_highThreshold_EB_, TTF_highThreshold_EE_, TTF_lowThreshold_EB_, TTF_lowThreshold_EE_, useInterCalibration_, useTransverseEnergy_, version_, wei_conf_id_, weight_timeShift_, weight_unbias_recovery_, writeToDB_, and writeToFiles_.
: xtal_LSB_EB_(0), xtal_LSB_EE_(0), nSample_(5), complement2_(7) { ped_conf_id_=0; lin_conf_id_=0; lut_conf_id_=0; wei_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; tag_=""; version_=0; m_write_ped=1; m_write_lin=1; m_write_lut=1; m_write_wei=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_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; try { if (writeToDB_) std::cout << "data will be saved with tag and version="<< tag_<< ".version"<<version_<< endl; db_ = new EcalTPGDBApp(DBsid, DBuser, DBpass) ; } catch (exception &e) { cout << "ERROR: " << e.what() << endl; } catch (...) { cout << "Unknown error caught" << endl; } 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") ; 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) ; //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_); std::cout << "INFO:SPIKE KILLING THRESHOLD (ADC)=" << SFGVB_SpikeKillingThreshold_ << std::endl; //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::cout << "INFO: READING timing files" << std::endl; std::ifstream delay_eb(TimingDelays_EB_.c_str()); if(!delay_eb) std::cout << "ERROR: File " << TimingDelays_EB_.c_str() << " could not be opened" << std::endl; std::ifstream delay_ee(TimingDelays_EE_.c_str()); if(!delay_ee) std::cout << "ERROR: File " << TimingDelays_EE_.c_str() << " could not be opened" << std::endl; std::ifstream phase_eb(TimingPhases_EB_.c_str()); if(!phase_eb) std::cout << "ERROR: File " << TimingPhases_EB_.c_str() << " could not be opened" << std::endl; std::ifstream phase_ee(TimingPhases_EE_.c_str()); if(!phase_ee) std::cout << "ERROR: File " << TimingPhases_EE_.c_str() << " could not be opened" << std::endl; 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) std::cout << "ERROR:Barrel timing delay -1, check file" << std::endl; } if(vec_delays_eb.size()!=68) std::cout << "ERROR:Barrel timing delay wrong, not enough towers, check file" << std::endl; if (delays_EB_.find(tcc) == delays_EB_.end()) delays_EB_.insert(make_pair(tcc,vec_delays_eb)); cout << tcc << " "; for(unsigned int ieb=0; ieb<vec_delays_eb.size(); ++ieb) cout << vec_delays_eb[ieb] << " "; cout << endl; delay_eb.getline(buf,sizeof(buf),'\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) std::cout << "ERROR:Barrel timing phase -1, check file" << std::endl; } if(vec_phases_eb.size()!=68) std::cout << "ERROR:Barrel timing phase wrong, not enough towers, check file" << std::endl; if (phases_EB_.find(tcc) == phases_EB_.end()) phases_EB_.insert(make_pair(tcc,vec_phases_eb)); cout << tcc << " "; for(unsigned int ieb=0; ieb<vec_phases_eb.size(); ++ieb) cout << vec_phases_eb[ieb] << " "; cout << endl; phase_eb.getline(buf,sizeof(buf),'\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) std::cout << "ERROR:EE timing delay -1, check file" << std::endl; } if(vec_delays_ee.size()!=48) std::cout << "ERROR:EE timing delay wrong, not enough towers, check file" << std::endl; if (delays_EE_.find(tcc) == delays_EE_.end()) delays_EE_.insert(make_pair(tcc,vec_delays_ee)); cout << tcc << " "; for(unsigned int iee=0; iee<vec_delays_ee.size(); ++iee) cout << vec_delays_ee[iee] << " "; cout << endl; 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) std::cout << "ERROR:EE timing phase -1, check file" << std::endl; } if(vec_phases_ee.size()!=48) std::cout << "ERROR:EE timing phase wrong, not enough towers, check file" << std::endl; if (phases_EE_.find(tcc) == phases_EE_.end()) phases_EE_.insert(make_pair(tcc,vec_phases_ee)); cout << tcc << " "; for(unsigned int iee=0; iee<vec_phases_ee.size(); ++iee) cout << vec_phases_ee[iee] << " "; cout << endl; phase_ee.getline(buf,sizeof(buf),'\n'); }//loop phase file EE phase_ee.close(); std::cout << "INFO: DONE reading timing files for EB and EE" << std::endl; }
| EcalTPGParamBuilder::~EcalTPGParamBuilder | ( | ) |
Definition at line 324 of file EcalTPGParamBuilder.cc.
References out_file_, and writeToFiles_.
{
if (writeToFiles_) {
(*out_file_ )<<"EOF"<<std::endl ;
out_file_->close() ;
delete out_file_ ;
}
}
| void EcalTPGParamBuilder::analyze | ( | const edm::Event & | evt, |
| const edm::EventSetup & | evtSetup | ||
| ) | [virtual] |
Implements edm::EDAnalyzer.
Definition at line 361 of file EcalTPGParamBuilder.cc.
References abs, Reference_intrackfit_cff::barrel, bst_conf_id_, btt_conf_id_, bxt_conf_id_, coeffStruc::calibCoeff_, EcalTriggerElectronicsId::channelId(), computeFineGrainEBParameters(), computeFineGrainEEParameters(), computeLinearizerParam(), computeLUT(), computeWeights(), gather_cfg::cout, dtDQMMerge_cfg::dataset, db_, DBEE_, EcalElectronicsId::dccId(), EcalElectronicsMapping::DCCid(), del_conf_id_, delays_EB_, delays_EE_, alignCSCRings::e, DetId::Ecal, EcalBarrel, EcalEndcap, Et_sat_EB_, Et_sat_EE_, PV3DBase< T, PVType, FrameType >::eta(), eTTmap_, exception, EcalCondDBInterface::fetchDataSet(), FG_highRatio_EB_, FG_highThreshold_EB_, FG_lowRatio_EB_, FG_lowThreshold_EB_, FG_Threshold_EE_, fgr_conf_id_, first, forcedPedestalValue_, forceEtaSlice_, g, EcalMGPAGainRatio::gain12Over6(), EcalMGPAGainRatio::gain6Over1(), coeffStruc::gainRatio_, edm::EventSetup::get(), FEConfigMainInfo::getBstId(), FEConfigMainInfo::getBttId(), FEConfigMainInfo::getBxtId(), getCoeff(), getCrate(), getDet(), EcalCondDBInterface::getEcalLogicID(), EcalCondDBInterface::getEcalLogicIDSetOrdered(), EcalElectronicsMapping::getElectronicsId(), FEConfigMainInfo::getFgrId(), getGCTRegionEta(), getGCTRegionPhi(), CaloSubdetectorGeometry::getGeometry(), EcalLogicID::getID1(), EcalLogicID::getID2(), EcalLogicID::getID3(), FEConfigMainInfo::getLinId(), EcalLogicID::getLogicID(), FEConfigMainInfo::getLUTId(), EcalCondObjectContainer< T >::getMap(), EcalLogicID::getName(), FEConfigMainInfo::getPedId(), FEConfigPedDat::getPedMeanG1(), FEConfigPedDat::getPedMeanG12(), FEConfigPedDat::getPedMeanG6(), CaloCellGeometry::getPosition(), FEConfigMainInfo::getSliId(), FEConfigMainInfo::getSpiId(), FEConfigMainInfo::getTimId(), EcalElectronicsMapping::getTriggerElectronicsId(), CaloSubdetectorGeometry::getValidDetIds(), FEConfigMainInfo::getWeiId(), H2_, ecalpyutils::hashedIndex(), i, EcalTrigTowerDetId::ieta(), EcalTrigTowerDetId::ietaAbs(), EcalCondObjectContainer< T >::insert(), EcalTrigTowerDetId::iphi(), EcalElectronicsMapping::iTT(), j, gen::k, lin_conf_id_, lumiPlot::lut, lut_conf_id_, LUT_option_, m_write_del, m_write_fgr, m_write_lin, m_write_lut, m_write_ped, m_write_sli, m_write_spi, m_write_wei, VarParsing::mult, linStruc::mult_, ntupleCrate_, ntupleDet_, ntupleInts_, EcalLogicID::NULLID, convertSQLiteXML::ok, dbtoconf::out, out_file_, AlCaHLTBitMon_ParallelJobs::p, ped_conf_id_, linStruc::pedestal_, pedestal_offset_, coeffStruc::pedestals_, phases_EB_, phases_EE_, PV3DBase< T, PVType, FrameType >::phi(), funct::pow(), edm::ESHandle< T >::product(), EcalTriggerElectronicsId::pseudoStripId(), EcalTriggerElectronicsId::rawId(), DetId::rawId(), realignBaseline(), compare_using_db::sample, IODConfig::setConfigTag(), FEConfigLUTParamDat::setETSat(), FEConfigLinParamDat::setETSat(), FEConfigFgrParamDat::setFGhighratio(), FEConfigFgrParamDat::setFGhighthresh(), FEConfigFgrParamDat::setFGlowratio(), FEConfigFgrParamDat::setFGlowthresh(), FEConfigFgrGroupDat::setFgrGroupId(), FEConfigFgrDat::setFgrGroupId(), FEConfigPedInfo::setId(), FEConfigFgrEEStripDat::setLutFgr(), FEConfigLUTDat::setLUTGroupId(), FEConfigLUTGroupDat::setLUTGroupId(), FEConfigLUTGroupDat::setLUTValue(), FEConfigFgrGroupDat::setLUTValue(), FEConfigFgrEETowerDat::setLutValue(), FEConfigLinDat::setMultX1(), FEConfigLinDat::setMultX12(), FEConfigLinDat::setMultX6(), FEConfigPedDat::setPedMeanG1(), FEConfigPedDat::setPedMeanG12(), FEConfigPedDat::setPedMeanG6(), FEConfigFgrGroupDat::setRatioHigh(), FEConfigFgrGroupDat::setRatioLow(), FEConfigLinDat::setShift1(), FEConfigLinDat::setShift12(), FEConfigLinDat::setShift6(), FEConfigSlidingDat::setSliding(), FEConfigSpikeDat::setSpikeThreshold(), FEConfigFgrGroupDat::setThreshHigh(), FEConfigFgrGroupDat::setThreshLow(), FEConfigFgrEEStripDat::setThreshold(), FEConfigTimingDat::setTimingPar1(), FEConfigTimingDat::setTimingPar2(), FEConfigLUTParamDat::setTTThreshhigh(), FEConfigLUTParamDat::setTTThreshlow(), FEConfigWeightGroupDat::setWeight0(), FEConfigWeightGroupDat::setWeight1(), FEConfigWeightGroupDat::setWeight2(), FEConfigWeightGroupDat::setWeight3(), FEConfigWeightGroupDat::setWeight4(), FEConfigWeightDat::setWeightGroupId(), FEConfigWeightGroupDat::setWeightGroupId(), SFGVB_lut_, SFGVB_SpikeKillingThreshold_, SFGVB_Threshold_, edm::shift, linStruc::shift_, EcalSimParameterMap::simParameters(), funct::sin(), findQualityFiles::size, sli_conf_id_, sliding_, EBDetId::SMCRYSTALMODE, spi_conf_id_, EcalElectronicsId::stripId(), EcalTrigTowerDetId::subDet(), tag_, EcalElectronicsMapping::TCCid(), theBarrelGeometry_, theEndcapGeometry_, theMapping_, theta(), PV3DBase< T, PVType, FrameType >::theta(), dtDQMClient_cfg::threshold, CaloSimParameters::timePhase(), EcalElectronicsId::towerId(), funct::true, TTF_highThreshold_EB_, TTF_highThreshold_EE_, TTF_lowThreshold_EB_, TTF_lowThreshold_EE_, useTransverseEnergy_, version_, wei_conf_id_, EcalTPGDBApp::writeToConfDB_Delay(), EcalTPGDBApp::writeToConfDB_Spike(), EcalTPGDBApp::writeToConfDB_TPGFgr(), EcalTPGDBApp::writeToConfDB_TPGLinearCoef(), EcalTPGDBApp::writeToConfDB_TPGLUT(), EcalTPGDBApp::writeToConfDB_TPGMain(), EcalTPGDBApp::writeToConfDB_TPGPedestals(), EcalTPGDBApp::writeToConfDB_TPGSliding(), EcalTPGDBApp::writeToConfDB_TPGWeight(), writeToDB_, writeToFiles_, x, xtal_LSB_EB_, xtal_LSB_EE_, EcalElectronicsId::xtalId(), EEDetId::XYMODE, detailsBasic3DVector::y, z, and EcalTrigTowerDetId::zside().
{
using namespace edm;
using namespace std;
// geometry
ESHandle<CaloGeometry> theGeometry;
ESHandle<CaloSubdetectorGeometry> theEndcapGeometry_handle, theBarrelGeometry_handle;
evtSetup.get<CaloGeometryRecord>().get( theGeometry );
evtSetup.get<EcalEndcapGeometryRecord>().get("EcalEndcap",theEndcapGeometry_handle);
evtSetup.get<EcalBarrelGeometryRecord>().get("EcalBarrel",theBarrelGeometry_handle);
evtSetup.get<IdealGeometryRecord>().get(eTTmap_);
theEndcapGeometry_ = &(*theEndcapGeometry_handle);
theBarrelGeometry_ = &(*theBarrelGeometry_handle);
// electronics mapping
ESHandle< EcalElectronicsMapping > ecalmapping;
evtSetup.get< EcalMappingRcd >().get(ecalmapping);
theMapping_ = ecalmapping.product();
// 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<uint32_t, uint32_t> stripMapEBsintheta ; // <strip elec id, sintheta>
// Pedestals
EcalPedestalsMap pedMap ;
if(m_write_ped == 1) {
std::cout <<"Getting the pedestals from offline DB..."<<endl;
ESHandle<EcalPedestals> pedHandle;
evtSetup.get<EcalPedestalsRcd>().get( pedHandle );
pedMap = pedHandle.product()->getMap() ;
EcalPedestalsMapIterator pedIter ;
int nPed = 0 ;
for (pedIter = pedMap.begin() ; pedIter != pedMap.end() && nPed<10 ; ++pedIter, nPed++) {
EcalPedestals::Item aped = (*pedIter);
std::cout<<aped.mean_x12<<", "<<aped.mean_x6<<", "<<aped.mean_x1<<std::endl ;
}
} else if(m_write_ped==0) {
std::cout <<"Getting the pedestals from previous configuration"<<std::endl;
EcalPedestals peds ;
FEConfigMainInfo fe_main_info;
fe_main_info.setConfigTag(tag_);
try {
std::cout << "trying to read previous tag if it exists tag="<< tag_<< ".version"<<version_<< endl;
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) std::cout << " copy the EB data " << " ped = " << item.mean_x12<< std::endl;
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() ;
EcalPedestalsMapIterator pedIter ;
int nPed = 0 ;
for (pedIter = pedMap.begin() ; pedIter != pedMap.end() && nPed<10 ; ++pedIter, nPed++) {
EcalPedestals::Item aped = (*pedIter);
std::cout<<aped.mean_x12<<", "<<aped.mean_x6<<", "<<aped.mean_x1<<std::endl ;
}
} catch (exception &e) {
cout << " error reading previous pedestals " << endl;
} catch (...) {
cout << "Unknown error reading previous pedestals " << endl;
}
} else if(m_write_ped >1) {
std::cout <<"Getting the pedestals from configuration number"<< m_write_ped <<std::endl;
EcalPedestals peds ;
try {
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) std::cout << " copy the EB data " << " icells = " << icells << std::endl;
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() ;
EcalPedestalsMapIterator pedIter ;
int nPed = 0 ;
for (pedIter = pedMap.begin() ; pedIter != pedMap.end() && nPed<10 ; ++pedIter, nPed++) {
EcalPedestals::Item aped = (*pedIter);
std::cout<<aped.mean_x12<<", "<<aped.mean_x6<<", "<<aped.mean_x1<<std::endl ;
}
} catch (exception &e) {
cout << " error reading previous pedestals " << endl;
} catch (...) {
cout << "Unknown error reading previous pedestals " << endl;
}
}
std::cout<<"...\n"<<std::endl ;
// Intercalib constants
std::cout <<"Getting intercalib from offline DB..."<<endl;
ESHandle<EcalIntercalibConstants> pIntercalib ;
evtSetup.get<EcalIntercalibConstantsRcd>().get(pIntercalib) ;
const EcalIntercalibConstants * intercalib = pIntercalib.product() ;
const EcalIntercalibConstantMap & calibMap = intercalib->getMap() ;
EcalIntercalibConstantMap::const_iterator calIter ;
int nCal = 0 ;
for (calIter = calibMap.begin() ; calIter != calibMap.end() && nCal<10 ; ++calIter, nCal++) {
std::cout<<(*calIter)<<std::endl ;
}
std::cout<<"...\n"<<std::endl ;
float calibvec[1700] ;
if (H2_) {
std::cout<<"H2: overwriting IC coef with file"<<std::endl ;
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
std::cout <<"Getting the gain ratios from offline DB..."<<endl;
ESHandle<EcalGainRatios> pRatio;
evtSetup.get<EcalGainRatiosRcd>().get(pRatio);
const EcalGainRatioMap & gainMap = pRatio.product()->getMap();
EcalGainRatioMap::const_iterator gainIter ;
int nGain = 0 ;
for (gainIter = gainMap.begin() ; gainIter != gainMap.end() && nGain<10 ; ++gainIter, nGain++) {
const EcalMGPAGainRatio & aGain = (*gainIter) ;
std::cout<<aGain.gain12Over6()<<", "<<aGain.gain6Over1() * aGain.gain12Over6()<<std::endl ;
}
std::cout<<"...\n"<<std::endl ;
// ADCtoGeV
std::cout <<"Getting the ADC to GEV from offline DB..."<<endl;
ESHandle<EcalADCToGeVConstant> pADCToGeV ;
evtSetup.get<EcalADCToGeVConstantRcd>().get(pADCToGeV) ;
const EcalADCToGeVConstant * ADCToGeV = pADCToGeV.product() ;
xtal_LSB_EB_ = ADCToGeV->getEBValue() ;
xtal_LSB_EE_ = ADCToGeV->getEEValue() ;
std::cout<<"xtal_LSB_EB_ = "<<xtal_LSB_EB_<<std::endl ;
std::cout<<"xtal_LSB_EE_ = "<<xtal_LSB_EE_<<std::endl ;
std::cout<<std::endl ;
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;
std::cout<<"going to get the ecal logic id set"<< endl;
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
std::cout<<"got the 3 ecal barrel logic id set"<< endl;
// 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 );
std::cout<<"got the end cap logic id set"<< endl;
if (writeToDB_) {
std::cout<<"Getting the latest ids for this tag (latest version) "<< endl;
FEConfigMainInfo fe_main_info;
fe_main_info.setConfigTag(tag_);
try {
std::cout << "trying to read previous tag if it exists tag="<< tag_<< ".version"<<version_<< endl;
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();
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
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
std::cout<<"got it "<< endl;
} catch (exception &e) {
cout << " tag did not exist a new tag will be created " << endl;
} catch (...) {
cout << "Unknown error caught" << endl;
}
}
// 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()<<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] ;
sprintf(ntupleDet_,getDet(tccNb).c_str()) ;
sprintf(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()) ;
getCoeff(coeff, gainMap, id.rawId()) ;
getCoeff(coeff, pedMap, id.rawId()) ;
linStruc lin ;
for (int i=0 ; i<3 ; i++) {
int mult, shift ;
bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EB", mult , shift) ;
if (!ok) std::cout << "unable to compute the parameters for SM="<< id.ism()<<" xt="<< id.ic()<<" " <<dec<<id.rawId()<<std::endl ;
else {
lin.pedestal_[i] = coeff.pedestals_[i] ;
lin.mult_[i] = mult ;
lin.shift_[i] = shift ;
}
}
bool ok(true) ;
if (forcedPedestalValue_ == -2) ok = realignBaseline(lin, 0) ;
if (!ok) std::cout<<"SM="<< id.ism()<<" xt="<< id.ic()<<" " <<dec<<id.rawId()<<std::endl ;
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()) ;
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]) ; }
if (i==1) {pedDB.setPedMeanG6(itLin->second.pedestal_[i]) ; linDB.setMultX6(itLin->second.mult_[i]) ; linDB.setShift6(itLin->second.shift_[i]) ; }
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 std::cout<<"current EtaSlice = "<<etaSlice<<" not found in the EtaSlice map"<<std::endl ;
}
else {
// general case
linStruc lin ;
int forceBase12 = 0 ;
for (int i=0 ; i<3 ; i++) {
int mult, shift ;
bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EB", mult , shift) ;
if (!ok) std::cout << "unable to compute the parameters for SM="<< id.ism()<<" xt="<< id.ic()<<" " <<dec<<id.rawId()<<std::endl ;
else {
//PP begin
// mult = 0 ; shift = 0 ;
// if (CCUid==1 && xtalWithinCCUid==21) {
// if (i==0) {mult = 0x80 ; shift = 0x3 ;}
// if (i==1) {mult = 0x80 ; shift = 0x2 ;}
// if (i==2) {mult = 0xc0 ; shift = 0x0 ;}
// }
//PP end
double base = coeff.pedestals_[i] ;
if (forcedPedestalValue_ == -3 && i==0) {
double G = mult*pow(2.0,-(shift+2)) ;
double g = G/sin(theta) ;
// int pedestal = coeff.pedestals_[i] ;
base = double(coeff.pedestals_[i]) - pedestal_offset_/g ;
if (base<0.) base = 0 ;
forceBase12 = int(base) ;
}
lin.pedestal_[i] = coeff.pedestals_[i] ;
lin.mult_[i] = mult ;
lin.shift_[i] = shift ;
// if (xtalWithinCCUid != 14) {
// forceBase12 = 0 ;
// lin.pedestal_[i] = 0 ;
// lin.mult_[i] = 0 ;
// lin.shift_[i] = 0 ;
// }
}
}
bool ok(true) ;
if (forcedPedestalValue_ == -2) ok = realignBaseline(lin, 0) ;
if (forcedPedestalValue_ == -3) ok = realignBaseline(lin, forceBase12) ;
if (!ok) std::cout<<"SM="<< id.ism()<<" xt="<< id.ic()<<" " <<dec<<id.rawId()<<std::endl ;
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]) ; }
if (i==1) {pedDB.setPedMeanG6(lin.pedestal_[i]) ; linDB.setMultX6(lin.mult_[i]) ; linDB.setShift6(lin.shift_[i]) ; }
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/sin(theta) ;
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]
(*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()<<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] ;
sprintf(ntupleDet_,getDet(tccNb).c_str()) ;
sprintf(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()) ;
getCoeff(coeff, gainMap, id.rawId()) ;
getCoeff(coeff, pedMap, id.rawId()) ;
linStruc lin ;
for (int i=0 ; i<3 ; i++) {
int mult, shift ;
bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EE", mult , shift) ;
if (!ok) std::cout << "unable to compute the parameters for Quadrant="<< id.iquadrant()<<" xt="<< id.ic()<<" " <<dec<<id.rawId()<<std::endl ;
else {
lin.pedestal_[i] = coeff.pedestals_[i] ;
lin.mult_[i] = mult ;
lin.shift_[i] = shift ;
}
}
bool ok(true) ;
if (forcedPedestalValue_ == -2 || forcedPedestalValue_ == -3) ok = realignBaseline(lin, 0) ;
if (!ok) std::cout<<"Quadrant="<< id.iquadrant()<<" xt="<< id.ic()<<" " <<dec<<id.rawId()<<std::endl ;
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()) ;
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]) ; }
if (i==1) {pedDB.setPedMeanG6(itLin->second.pedestal_[i]) ; linDB.setMultX6(itLin->second.mult_[i]) ; linDB.setShift6(itLin->second.shift_[i]) ; }
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 std::cout<<"current EtaSlice = "<<etaSlice<<" not found in the EtaSlice map"<<std::endl ;
}
else {
// general case
linStruc lin ;
for (int i=0 ; i<3 ; i++) {
int mult, shift ;
bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EE", mult , shift) ;
if (!ok) std::cout << "unable to compute the parameters for "<<dec<<id.rawId()<<std::endl ;
else {
lin.pedestal_[i] = coeff.pedestals_[i] ;
lin.mult_[i] = mult ;
lin.shift_[i] = shift ;
}
}
bool ok(true) ;
if (forcedPedestalValue_ == -2 || forcedPedestalValue_ == -3) ok = realignBaseline(lin, 0) ;
if (!ok) std::cout<<"Quadrant="<< id.iquadrant()<<" xt="<< id.ic()<<" " <<dec<<id.rawId()<<std::endl ;
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]) ; }
if (i==1) {pedDB.setPedMeanG6(lin.pedestal_[i]) ; linDB.setMultX6(lin.mult_[i]) ; linDB.setShift6(lin.shift_[i]) ; }
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
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();
std::cout<< " LIN tag "<<lin_tag<<endl;
if(m_write_ped==1) {
ped_conf_id_=db_->writeToConfDB_TPGPedestals(pedset, 1, "from_OfflineDB") ;
} else {
std::cout<< "the ped id ="<<ped_conf_id_<<" will be used for the pedestals "<<std::endl;
}
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,"<<endl ;
evgueni<<" int & mult12, int & shift12, int & base12,"<<endl ;
evgueni<<" int & mult6, int & shift6, int & base6,"<<endl ;
evgueni<<" int & mult1, int & shift1, int & base1)"<<endl ;
evgueni<<"{"<<endl;
evgueni<<" mult12 = 0 ; shift12 = 0 ; base12 = 0 ; mult6 = 0 ; shift6 = 0 ; base6 = 0 ; mult1 = 0 ; shift1 = 0 ; base1 = 0 ;"<<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 ;}" <<endl ;
}
evgueni<<"}" <<endl ;
evgueni.close() ;
// Compute weights section //
const int NWEIGROUPS = 2 ;
std::vector<unsigned int> weights[NWEIGROUPS] ;
#if (CMSSW_VERSION>=340)
EBShape shapeEB ;
EEShape shapeEE ;
weights[0] = computeWeights(shapeEB, hshapeEB) ;
weights[1] = computeWeights(shapeEE, hshapeEE) ;
#else
// loading reference signal representation
EcalSimParameterMap parameterMap;
EBDetId barrel(1,1);
double phase = parameterMap.simParameters(barrel).timePhase();
EcalShape shape(phase);
weights[0] = computeWeights(shape, hshapeEB) ;
weights[1] = weights[0] ;
#endif
map<EcalLogicID, FEConfigWeightGroupDat> dataset;
for (int igrp=0 ; igrp<NWEIGROUPS ; igrp++) {
if (weights[igrp].size() == 5) {
if (writeToFiles_) {
(*out_file_) <<std::endl ;
(*out_file_) <<"WEIGHT "<<igrp<<endl ;
for (unsigned int sample=0 ; sample<5 ; sample++) (*out_file_) << "0x" <<hex<<weights[igrp][sample]<<" " ;
(*out_file_)<<std::endl ;
(*out_file_) <<std::endl ;
}
if (writeToDB_) {
std::cout<<"going to write the weights for groupe:"<<igrp<<endl;
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;
}
}
}
if (writeToDB_) {
// 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
wut.setWeightGroupId(igroup);
dataset2[my_StripEcalLogicId[ich]] = wut;
}
// EE loop
for (int ich=0; ich<(int)my_StripEcalLogicId1_EE.size() ; ich++){
FEConfigWeightDat wut;
int igroup = 1; // this group is for EE
wut.setWeightGroupId(igroup);
// Fill the dataset
dataset2[my_StripEcalLogicId1_EE[ich]] = wut;
}
// EE loop 2 (we had to split the ids of EE in 2 vectors to avoid crash!)
for (int ich=0; ich<(int)my_StripEcalLogicId2_EE.size() ; ich++){
FEConfigWeightDat wut;
int igroup = 1; // this group is for EE
wut.setWeightGroupId(igroup);
// Fill the dataset
dataset2[my_StripEcalLogicId2_EE[ich]] = wut;
}
// Insert the datasets
ostringstream wtag;
wtag.str(""); wtag<<"Shape_NGroups_"<<NWEIGROUPS;
std::string weight_tag=wtag.str();
std::cout<< " weight tag "<<weight_tag<<endl;
if (m_write_wei==1) wei_conf_id_=db_->writeToConfDB_TPGWeight(dataset, dataset2, NWEIGROUPS, weight_tag) ;
}
// 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_) {
std::cout<<"going to write the fgr "<< endl;
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;
// in this case I decide in a stupid way which channel belongs to which group
for (int ich=0; ich<(int)my_TTEcalLogicId.size() ; ich++){
FEConfigFgrDat wut;
int igroup=0;
wut.setFgrGroupId(igroup);
// Fill the dataset
// the logic ids are ordered by SM (1,...36) and TT (1,...68)
// you have to calculate the right index here
dataset2[my_TTEcalLogicId[ich]] = wut;
}
// endcap loop
for (int ich=0; ich<(int)my_RTEcalLogicId_EE.size() ; ich++){
// 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[my_RTEcalLogicId_EE[ich]] = wut;
}
// endcap TT loop for the FEfgr EE Tower
map<EcalLogicID, FEConfigFgrEETowerDat> dataset3;
for (int ich=0; ich<(int)my_TTEcalLogicId_EE.size() ; ich++){
FEConfigFgrEETowerDat fgreett;
fgreett.setLutValue(lut_tower);
dataset3[my_TTEcalLogicId_EE[ich]]=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 (int ich=0; ich<(int)my_StripEcalLogicId1_EE.size() ; ich++){
FEConfigFgrEEStripDat zut;
zut.setThreshold(threshold);
zut.setLutFgr(lut_strip);
dataset4[my_StripEcalLogicId1_EE[ich]] = zut;
}
for (int ich=0; ich<(int)my_StripEcalLogicId2_EE.size() ; ich++){
FEConfigFgrEEStripDat zut;
zut.setThreshold(threshold);
zut.setLutFgr(lut_strip);
// Fill the dataset
dataset4[my_StripEcalLogicId2_EE[ich]] = 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 {
cout<<"ERROR: strip SFGVB threshold parameter not found for that strip:"<<thestrip.getID1()<<" "<<thestrip.getID3()<<" "<<thestrip.getID3()<<endl ;
cout<<" using value = "<<SFGVB_Threshold_+pedestal_offset_<<endl ;
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();
std::cout<< " weight tag "<<weight_tag<<endl;
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 (int ich=0; ich<(int)my_TTEcalLogicId.size() ; ich++){
FEConfigSpikeDat spiketh;
spiketh.setSpikeThreshold(SFGVB_SpikeKillingThreshold_);
datasetspike[my_TTEcalLogicId[ich]] = spiketh;
}//loop EB TT towers
//modif-alex 21/01/11
ostringstream stag;
stag.str(""); stag<<"SpikeTh"<<SFGVB_SpikeKillingThreshold_;
std::string spike_tag=stag.str();
std::cout<< " spike tag "<<spike_tag<<endl;
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=my_TTEcalLogicId_EB_by_TCC[ich].getID1(); // the TCC
int id2_tt =my_TTEcalLogicId_EB_by_TCC[ich].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){
std::cout << "ERROR: Barrel timing delay not specified, check file, putting default value 1" << std::endl;
delay.setTimingPar1(1);
}
else delay.setTimingPar1(TimingDelaysEB[id2_tt-1]);
} else {
std::cout << "ERROR:Barrel Could not find delay parameter for that trigger tower " << std::endl;
std::cout << "Using default value = 1" << std::endl;
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){
std::cout << "ERROR: Barrel timing phase not specified, check file, putting default value 0" << std::endl;
delay.setTimingPar2(0);
}
else delay.setTimingPar2(TimingPhasesEB[id2_tt-1]);
} else {
std::cout << "ERROR:Barrel Could not find phase parameter for that trigger tower " << std::endl;
std::cout << "Using default value = 0" << std::endl;
delay.setTimingPar2(0);
}
std::cout << ich << " tcc=" << id1_tcc << " TT=" << id2_tt << " logicId=" << logiciddelay.getLogicID()
<< " delay=" << TimingDelaysEB[id2_tt-1] << " phase=" << TimingPhasesEB[id2_tt-1] << std::endl;
//delay.setTimingPar1(1);
//delay.setTimingPar2(2);
datasetdelay[my_TTEcalLogicId_EB_by_TCC[ich]] = 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;
//int id1_strip=my_StripEcalLogicId_EE_strips_by_TCC[ich].getID1(); // the TCC
//int id2_strip=my_StripEcalLogicId_EE_strips_by_TCC[ich].getID2(); // the Tower
//int id3_strip=my_StripEcalLogicId_EE_strips_by_TCC[ich].getID3(); // the strip
EcalLogicID logiciddelay = my_StripEcalLogicId_EE_strips_by_TCC[ich] ;
int id1_tcc=my_StripEcalLogicId_EE_strips_by_TCC[ich].getID1(); // the TCC
int id2_tt =my_StripEcalLogicId_EE_strips_by_TCC[ich].getID2(); // the tower
int id3_st =my_StripEcalLogicId_EE_strips_by_TCC[ich].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){
std::cout << "ERROR: Endcap timing delay not specified, check file, putting default value 1" << std::endl;
delay.setTimingPar1(1);
}
else delay.setTimingPar1(TimingDelaysEE[stripindex]);
} else {
std::cout << "ERROR:Endcap Could not find delay parameter for that trigger tower " << std::endl;
std::cout << "Using default value = 1" << std::endl;
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){
std::cout << "ERROR: Endcap timing phase not specified, check file, putting default value 0" << std::endl;
delay.setTimingPar2(0);
}
else delay.setTimingPar2(TimingPhasesEE[stripindex]);
} else {
std::cout << "ERROR:Endcap Could not find phase parameter for that trigger tower " << std::endl;
std::cout << "Using default value = 0" << std::endl;
delay.setTimingPar2(0);
}
std::cout << ich << " stripindex=" << stripindex << " tcc=" << id1_tcc << " TT=" << id2_tt << " id3_st=" << id3_st
<< " logicId=" << logiciddelay.getLogicID()
<< " delay=" << TimingDelaysEE[stripindex] << " phase=" << TimingPhasesEE[stripindex] << std::endl;
//delay.setTimingPar1(1);
//delay.setTimingPar2(2);
datasetdelay[my_StripEcalLogicId_EE_strips_by_TCC[ich]] = delay;
stripindex++;
}//loop EE strip towers
ostringstream de_tag;
de_tag.str(""); de_tag<<"DelaysFromFile";
std::string delay_tag=de_tag.str();
std::cout<< " delay tag "<<delay_tag<<endl;
if(m_write_del==1) del_conf_id_=db_->writeToConfDB_Delay(datasetdelay, delay_tag) ; //modif-alex 31/01/11
} //write to DB
if (writeToDB_) {
std::cout<<"going to write the sliding "<< endl;
map<EcalLogicID, FEConfigSlidingDat> dataset;
// in this case I decide in a stupid way which channel belongs to which group
for (int ich=0; ich<(int)my_StripEcalLogicId.size() ; ich++){
FEConfigSlidingDat wut;
wut.setSliding(sliding_);
// Fill the dataset
// the logic ids are ordered by SM (1,...36) , TT (1,...68) and strip (1..5)
// you have to calculate the right index here
dataset[my_StripEcalLogicId[ich]] = wut;
}
// endcap loop
for (int ich=0; ich<(int)my_StripEcalLogicId1_EE.size() ; ich++){
FEConfigSlidingDat wut;
wut.setSliding(sliding_);
// Fill the dataset
// the logic ids are ordered by fed tower strip
// you have to calculate the right index here
dataset[my_StripEcalLogicId1_EE[ich]] = wut;
}
for (int ich=0; ich<(int)my_StripEcalLogicId2_EE.size() ; ich++){
FEConfigSlidingDat wut;
wut.setSliding(sliding_);
// Fill the dataset
// the logic ids are ordered by ... ?
// you have to calculate the right index here
dataset[my_StripEcalLogicId2_EE[ich]] = wut;
}
// Insert the dataset
ostringstream wtag;
wtag.str(""); wtag<<"Sliding_"<<sliding_;
std::string justatag=wtag.str();
std::cout<< " sliding tag "<<justatag<<endl;
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]<<endl ;
(*out_file_)<<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]<<endl ;
(*out_file_)<<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 (int ich=0; ich<(int)my_TTEcalLogicId.size() ; ich++){
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[my_TTEcalLogicId[ich]] = lut;
}
// endcap loop
for (int ich=0; ich<(int)my_TTEcalLogicId_EE.size() ; ich++){
FEConfigLUTDat lut;
int igroup=1;
lut.setLUTGroupId(igroup);
// calculate the right TT
// Fill the dataset
dataset2[my_TTEcalLogicId_EE[ich]] = lut;
}
// Insert the dataset
ostringstream ltag;
ltag.str(""); ltag<<LUT_option_<<"_NGroups_"<<NLUTGROUPS;
std::string lut_tag=ltag.str();
std::cout<< " LUT tag "<<lut_tag<<endl;
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_, spi_conf_id_, del_conf_id_, bxt_conf_id_, btt_conf_id_, bst_conf_id_, tag_, version_) ; //modif-alex 21/01/11
std::cout << "\n Conf ID = " << conf_id_ << std::endl;
}
// loop on strips and associate them with values //
// Barrel
stripListEB.sort() ;
stripListEB.unique() ;
cout<<"Number of EB strips="<<dec<<stripListEB.size()<<endl ;
if (writeToFiles_) {
(*out_file_) <<std::endl ;
for (itList = stripListEB.begin(); itList != stripListEB.end(); itList++ ) {
(*out_file_) <<"STRIP_EB "<<dec<<(*itList)<<endl ;
(*out_file_) << hex << "0x" <<sliding_<<std::endl ;
(*out_file_) <<"0" <<std::endl ;
(*out_file_) <<"0x"<<stripMapEBsintheta[(*itList)] << " 0x" << SFGVB_lut_ <<std::endl ;
}
}
// Endcap
stripListEE.sort() ;
stripListEE.unique() ;
cout<<"Number of EE strips="<<dec<<stripListEE.size()<<endl ;
if (writeToFiles_) {
(*out_file_) <<std::endl ;
for (itList = stripListEE.begin(); itList != stripListEE.end(); itList++ ) {
(*out_file_) <<"STRIP_EE "<<dec<<(*itList)<<endl ;
(*out_file_) << hex << "0x" <<sliding_<<std::endl ;
(*out_file_) <<" 0" << std::endl ;
(*out_file_)<<hex<<"0x"<<threshold<<" 0x"<<lut_strip<<std::endl ;
}
}
// loop on towers and associate them with default values //
// Barrel
towerListEB.sort() ;
towerListEB.unique() ;
cout<<"Number of EB towers="<<dec<<towerListEB.size()<<endl ;
if (writeToFiles_) {
(*out_file_) <<std::endl ;
for (itList = towerListEB.begin(); itList != towerListEB.end(); itList++ ) {
(*out_file_) <<"TOWER_EB "<<dec<<(*itList)<<endl ;
(*out_file_) <<" 0\n 0\n" ;
(*out_file_) <<" " << SFGVB_SpikeKillingThreshold_ << std::endl; //modif-alex
}
}
// Endcap
towerListEE.sort() ;
towerListEE.unique() ;
cout<<"Number of EE towers="<<dec<<towerListEE.size()<<endl ;
if (writeToFiles_) {
(*out_file_) <<std::endl ;
for (itList = towerListEE.begin(); itList != towerListEE.end(); itList++ ) {
(*out_file_) <<"TOWER_EE "<<dec<<(*itList)<<endl ;
if (newLUT) (*out_file_) <<" 1\n" ;
else (*out_file_) <<" 0\n" ;
(*out_file_)<<hex<<"0x"<<lut_tower<<std::endl ;
}
}
// 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 () ;
}
| void EcalTPGParamBuilder::beginJob | ( | void | ) | [virtual] |
Reimplemented from edm::EDAnalyzer.
Definition at line 1953 of file EcalTPGParamBuilder.cc.
References gather_cfg::cout, create_header(), 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;
std::cout<<"we are in beginJob"<<endl;
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 ;
}
}
| bool EcalTPGParamBuilder::checkIfOK | ( | EcalPedestals::Item | item | ) |
Definition at line 334 of file EcalTPGParamBuilder.cc.
References query::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;
}
| void EcalTPGParamBuilder::computeFineGrainEBParameters | ( | uint & | lowRatio, |
| uint & | highRatio, | ||
| uint & | lowThreshold, | ||
| uint & | highThreshold, | ||
| uint & | lut | ||
| ) | [private] |
Definition at line 2390 of file EcalTPGParamBuilder.cc.
References Et_sat_EB_, FG_highRatio_EB_, FG_highThreshold_EB_, FG_lowRatio_EB_, FG_lowThreshold_EB_, and FG_lut_EB_.
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!)
}
| void EcalTPGParamBuilder::computeFineGrainEEParameters | ( | uint & | threshold, |
| uint & | lut_strip, | ||
| uint & | lut_tower | ||
| ) | [private] |
Definition at line 2416 of file EcalTPGParamBuilder.cc.
References Et_sat_EE_, FG_lut_strip_EE_, FG_lut_tower_EE_, and FG_Threshold_EE_.
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_ ;
}
| bool EcalTPGParamBuilder::computeLinearizerParam | ( | double | theta, |
| double | gainRatio, | ||
| double | calibCoeff, | ||
| std::string | subdet, | ||
| int & | mult, | ||
| int & | shift | ||
| ) | [private] |
Definition at line 1984 of file EcalTPGParamBuilder.cc.
References gather_cfg::cout, Et_sat_EB_, Et_sat_EE_, funct::false, funct::sin(), sliding_, funct::true, 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_ ;
}
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) ;
}
std::cout << "too bad we did not manage to calculate the factor for calib="<<calibCoeff<<endl;
return false ;
}
| void EcalTPGParamBuilder::computeLUT | ( | int * | lut, |
| std::string | det = "EB" |
||
| ) | [private] |
Definition at line 2264 of file EcalTPGParamBuilder.cc.
References Et_sat_EB_, Et_sat_EE_, i, 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_, lumiNorm::norm, 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 ;
}
}
| std::vector< unsigned int > EcalTPGParamBuilder::computeWeights | ( | EcalShapeBase & | shape, |
| TH1F * | histo | ||
| ) | [private] |
Definition at line 222 of file EcalDccWeightBuilder.cc.
References i, alignCSCRings::s, EcalShapeBase::timeToRise(), and tzero.
Referenced by analyze().
{
double sum2 = 0.;
double sum = 0;
result.resize(nWeights);
int nActualWeights = 0;
const double tzero = -(binOfMax-1)*25+timePhase + shape.timeToRise();//ns
for(int i=0; i<nWeights; ++i){
double t_ns = tzero+(iFirst+i)*25;
double s = shape(t_ns);
if(i==iSkip){
continue;
}
result[i] = s;
sum += s;
sum2 += s*s;
++nActualWeights;
}
for(int i=0; i<nWeights; ++i){
if(i==iSkip){
result[i] = 0;
} else{
result[i] = (result[i]-sum/nActualWeights)/(sum2-sum*sum/nActualWeights);
}
}
}
| void EcalTPGParamBuilder::create_header | ( | ) | [private] |
Definition at line 2028 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 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 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 Weight structure"<<std::endl ;
(*out_file_) <<"COMMENT"<<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 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 ;
(*out_file_) <<std::endl ;
}
| void EcalTPGParamBuilder::getCoeff | ( | coeffStruc & | coeff, |
| const EcalIntercalibConstantMap & | calibMap, | ||
| uint | rawId | ||
| ) | [private] |
Referenced by analyze().
| void EcalTPGParamBuilder::getCoeff | ( | coeffStruc & | coeff, |
| const EcalGainRatioMap & | gainMap, | ||
| uint | rawId | ||
| ) | [private] |
| void EcalTPGParamBuilder::getCoeff | ( | coeffStruc & | coeff, |
| const EcalPedestalsMap & | pedMap, | ||
| uint | rawId | ||
| ) | [private] |
| void EcalTPGParamBuilder::getCoeff | ( | coeffStruc & | coeff, |
| const std::map< EcalLogicID, MonPedestalsDat > & | pedMap, | ||
| const EcalLogicID & | logicId | ||
| ) | [private] |
| std::pair< std::string, int > EcalTPGParamBuilder::getCrate | ( | int | tcc | ) | [private] |
Definition at line 2488 of file EcalTPGParamBuilder.cc.
References pos.
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) ;
}
| std::string EcalTPGParamBuilder::getDet | ( | int | tcc | ) | [private] |
Definition at line 2464 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() ;
}
| int EcalTPGParamBuilder::getEtaSlice | ( | int | tccId, |
| int | towerInTCC | ||
| ) | [private] |
Definition at line 346 of file EcalTPGParamBuilder.cc.
{
int etaSlice = (towerInTCC-1)/4+1 ;
// barrel
if (tccId>36 || tccId<73) return etaSlice ;
//endcap
else {
if (tccId >=1 && tccId <= 18) etaSlice += 21 ; // inner -
if (tccId >=19 && tccId <= 36) etaSlice += 17 ; // outer -
if (tccId >=91 && tccId <= 108) etaSlice += 21 ; // inner +
if (tccId >=73 && tccId <= 90) etaSlice += 17 ; // outer +
}
return etaSlice ;
}
| int EcalTPGParamBuilder::getGCTRegionEta | ( | int | tteta | ) | [private] |
Definition at line 2457 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;
}
| int EcalTPGParamBuilder::getGCTRegionPhi | ( | int | ttphi | ) | [private] |
Definition at line 2449 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;
}
| bool EcalTPGParamBuilder::realignBaseline | ( | linStruc & | lin, |
| float | forceBase12 | ||
| ) | [private] |
Definition at line 2425 of file EcalTPGParamBuilder.cc.
References gather_cfg::cout, funct::false, 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++) {
lin.pedestal_[i] = base[i] ;
//cout<<lin.pedestal_[i]<<" "<<base[i]<<endl ;
if (base[i]<0 || lin.pedestal_[i]>1000) {
cout<<"WARNING: base= "<<base[i]<<", "<<lin.pedestal_[i]<<" for gainId[0-2]="<<i<<" ==> forcing at 0"<<endl ;
lin.pedestal_[i] = 0 ;
ok = false ;
}
}
return ok ;
}
| int EcalTPGParamBuilder::uncodeWeight | ( | double | weight, |
| int | complement2 = 7 |
||
| ) | [private] |
Definition at line 2122 of file EcalTPGParamBuilder.cc.
References max(), and funct::pow().
| double EcalTPGParamBuilder::uncodeWeight | ( | int | iweight, |
| int | complement2 = 7 |
||
| ) | [private] |
Definition at line 2132 of file EcalTPGParamBuilder.cc.
References funct::pow(), and CommonMethods::weight().
int EcalTPGParamBuilder::bst_conf_id_ [private] |
Definition at line 157 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::btt_conf_id_ [private] |
Definition at line 156 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::bxt_conf_id_ [private] |
Definition at line 155 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
unsigned int EcalTPGParamBuilder::complement2_ [private] |
Definition at line 112 of file EcalTPGParamBuilder.h.
EcalTPGDBApp* EcalTPGParamBuilder::db_ [private] |
Definition at line 141 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
bool EcalTPGParamBuilder::DBEE_ [private] |
Definition at line 145 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
unsigned int EcalTPGParamBuilder::DBrunNb_ [private] |
Definition at line 144 of file EcalTPGParamBuilder.h.
int EcalTPGParamBuilder::del_conf_id_ [private] |
Definition at line 154 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
std::map<int, std::vector<int> > EcalTPGParamBuilder::delays_EB_ [private] |
Definition at line 134 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
std::map<int, std::vector<int> > EcalTPGParamBuilder::delays_EE_ [private] |
Definition at line 136 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::Et_sat_EB_ [private] |
Definition at line 106 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), computeFineGrainEBParameters(), computeLinearizerParam(), computeLUT(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::Et_sat_EE_ [private] |
Definition at line 106 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), computeFineGrainEEParameters(), computeLinearizerParam(), computeLUT(), and EcalTPGParamBuilder().
Definition at line 101 of file EcalTPGParamBuilder.h.
Referenced by analyze().
double EcalTPGParamBuilder::FG_highRatio_EB_ [private] |
Definition at line 119 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), computeFineGrainEBParameters(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::FG_highThreshold_EB_ [private] |
Definition at line 119 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), computeFineGrainEBParameters(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::FG_lowRatio_EB_ [private] |
Definition at line 119 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), computeFineGrainEBParameters(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::FG_lowThreshold_EB_ [private] |
Definition at line 119 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), computeFineGrainEBParameters(), and EcalTPGParamBuilder().
unsigned int EcalTPGParamBuilder::FG_lut_EB_ [private] |
Definition at line 120 of file EcalTPGParamBuilder.h.
Referenced by computeFineGrainEBParameters(), and EcalTPGParamBuilder().
unsigned int EcalTPGParamBuilder::FG_lut_strip_EE_ [private] |
Definition at line 122 of file EcalTPGParamBuilder.h.
Referenced by computeFineGrainEEParameters(), and EcalTPGParamBuilder().
unsigned int EcalTPGParamBuilder::FG_lut_tower_EE_ [private] |
Definition at line 122 of file EcalTPGParamBuilder.h.
Referenced by computeFineGrainEEParameters(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::FG_Threshold_EE_ [private] |
Definition at line 121 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), computeFineGrainEEParameters(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::fgr_conf_id_ [private] |
Definition at line 150 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::forcedPedestalValue_ [private] |
Definition at line 123 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
bool EcalTPGParamBuilder::forceEtaSlice_ [private] |
Definition at line 124 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
std::ofstream* EcalTPGParamBuilder::geomFile_ [private] |
Definition at line 140 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
bool EcalTPGParamBuilder::H2_ [private] |
Definition at line 127 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::lin_conf_id_ [private] |
Definition at line 148 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::lut_conf_id_ [private] |
Definition at line 149 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::LUT_constant_EB_ [private] |
Definition at line 115 of file EcalTPGParamBuilder.h.
Referenced by computeLUT(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::LUT_constant_EE_ [private] |
Definition at line 116 of file EcalTPGParamBuilder.h.
Referenced by computeLUT(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::LUT_noise_EB_ [private] |
Definition at line 115 of file EcalTPGParamBuilder.h.
Referenced by computeLUT(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::LUT_noise_EE_ [private] |
Definition at line 116 of file EcalTPGParamBuilder.h.
Referenced by computeLUT(), and EcalTPGParamBuilder().
std::string EcalTPGParamBuilder::LUT_option_ [private] |
Definition at line 113 of file EcalTPGParamBuilder.h.
Referenced by analyze(), computeLUT(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::LUT_stochastic_EB_ [private] |
Definition at line 115 of file EcalTPGParamBuilder.h.
Referenced by computeLUT(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::LUT_stochastic_EE_ [private] |
Definition at line 116 of file EcalTPGParamBuilder.h.
Referenced by computeLUT(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::LUT_threshold_EB_ [private] |
Definition at line 114 of file EcalTPGParamBuilder.h.
Referenced by computeLUT(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::LUT_threshold_EE_ [private] |
Definition at line 114 of file EcalTPGParamBuilder.h.
Referenced by computeLUT(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::m_write_bst [private] |
Definition at line 170 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
int EcalTPGParamBuilder::m_write_btt [private] |
Definition at line 169 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
int EcalTPGParamBuilder::m_write_bxt [private] |
Definition at line 168 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
int EcalTPGParamBuilder::m_write_del [private] |
Definition at line 167 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::m_write_fgr [private] |
Definition at line 164 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::m_write_lin [private] |
Definition at line 161 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::m_write_lut [private] |
Definition at line 162 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::m_write_ped [private] |
Definition at line 160 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::m_write_sli [private] |
Definition at line 165 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::m_write_spi [private] |
Definition at line 166 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::m_write_wei [private] |
Definition at line 163 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
unsigned int EcalTPGParamBuilder::nSample_ [private] |
Definition at line 111 of file EcalTPGParamBuilder.h.
Char_t EcalTPGParamBuilder::ntupleCrate_[10] [private] |
Definition at line 174 of file EcalTPGParamBuilder.h.
Referenced by analyze().
Char_t EcalTPGParamBuilder::ntupleDet_[10] [private] |
Definition at line 173 of file EcalTPGParamBuilder.h.
Referenced by analyze().
Int_t* EcalTPGParamBuilder::ntupleInts_ [private] |
Definition at line 172 of file EcalTPGParamBuilder.h.
Referenced by analyze().
std::ofstream* EcalTPGParamBuilder::out_file_ [private] |
Definition at line 139 of file EcalTPGParamBuilder.h.
Referenced by analyze(), EcalTPGParamBuilder(), and ~EcalTPGParamBuilder().
int EcalTPGParamBuilder::ped_conf_id_ [private] |
Definition at line 147 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
unsigned int EcalTPGParamBuilder::pedestal_offset_ [private] |
Definition at line 125 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
std::map<int, std::vector<int> > EcalTPGParamBuilder::phases_EB_ [private] |
Definition at line 135 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
std::map<int, std::vector<int> > EcalTPGParamBuilder::phases_EE_ [private] |
Definition at line 137 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
unsigned int EcalTPGParamBuilder::sampleMax_ [private] |
Definition at line 108 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
unsigned int EcalTPGParamBuilder::SFGVB_lut_ [private] |
Definition at line 125 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::SFGVB_SpikeKillingThreshold_ [private] |
Definition at line 126 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
unsigned int EcalTPGParamBuilder::SFGVB_Threshold_ [private] |
Definition at line 125 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::sli_conf_id_ [private] |
Definition at line 151 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
unsigned int EcalTPGParamBuilder::sliding_ [private] |
Definition at line 107 of file EcalTPGParamBuilder.h.
Referenced by analyze(), computeLinearizerParam(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::spi_conf_id_ [private] |
Definition at line 153 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
std::string EcalTPGParamBuilder::tag_ [private] |
Definition at line 158 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
const CaloSubdetectorGeometry* EcalTPGParamBuilder::theBarrelGeometry_ [private] |
Definition at line 100 of file EcalTPGParamBuilder.h.
Referenced by analyze().
const CaloSubdetectorGeometry* EcalTPGParamBuilder::theEndcapGeometry_ [private] |
Definition at line 99 of file EcalTPGParamBuilder.h.
Referenced by analyze().
const EcalElectronicsMapping* EcalTPGParamBuilder::theMapping_ [private] |
Definition at line 102 of file EcalTPGParamBuilder.h.
Referenced by analyze().
std::string EcalTPGParamBuilder::TimingDelays_EB_ [private] |
Definition at line 130 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
std::string EcalTPGParamBuilder::TimingDelays_EE_ [private] |
Definition at line 131 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
std::string EcalTPGParamBuilder::TimingPhases_EB_ [private] |
Definition at line 132 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
std::string EcalTPGParamBuilder::TimingPhases_EE_ [private] |
Definition at line 133 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
double EcalTPGParamBuilder::TTF_highThreshold_EB_ [private] |
Definition at line 117 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), computeLUT(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::TTF_highThreshold_EE_ [private] |
Definition at line 118 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), computeLUT(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::TTF_lowThreshold_EB_ [private] |
Definition at line 117 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), computeLUT(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::TTF_lowThreshold_EE_ [private] |
Definition at line 118 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), computeLUT(), and EcalTPGParamBuilder().
bool EcalTPGParamBuilder::useInterCalibration_ [private] |
Definition at line 127 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
bool EcalTPGParamBuilder::useTransverseEnergy_ [private] |
Definition at line 104 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::version_ [private] |
Definition at line 159 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
int EcalTPGParamBuilder::wei_conf_id_ [private] |
Definition at line 152 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
double EcalTPGParamBuilder::weight_timeShift_ [private] |
Definition at line 109 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
bool EcalTPGParamBuilder::weight_unbias_recovery_ [private] |
Definition at line 110 of file EcalTPGParamBuilder.h.
Referenced by EcalTPGParamBuilder().
bool EcalTPGParamBuilder::writeToDB_ [private] |
Definition at line 142 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and EcalTPGParamBuilder().
bool EcalTPGParamBuilder::writeToFiles_ [private] |
Definition at line 143 of file EcalTPGParamBuilder.h.
Referenced by analyze(), beginJob(), create_header(), EcalTPGParamBuilder(), and ~EcalTPGParamBuilder().
double EcalTPGParamBuilder::xtal_LSB_EB_ [private] |
Definition at line 105 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and computeLinearizerParam().
double EcalTPGParamBuilder::xtal_LSB_EE_ [private] |
Definition at line 105 of file EcalTPGParamBuilder.h.
Referenced by analyze(), and computeLinearizerParam().
1.7.3