#include <HcalRecHitClient.h>
Definition at line 10 of file HcalRecHitClient.h.
HcalRecHitClient::HcalRecHitClient | ( | ) | [inline] |
Constructors.
Definition at line 15 of file HcalRecHitClient.h.
References HcalBaseDQClient::name_.
{name_="";};
HcalRecHitClient::HcalRecHitClient | ( | std::string | myname | ) |
Definition at line 20 of file HcalRecHitClient.cc.
References HcalBaseDQClient::name_.
{ name_=myname; }
HcalRecHitClient::HcalRecHitClient | ( | std::string | myname, |
const edm::ParameterSet & | ps | ||
) |
Definition at line 25 of file HcalRecHitClient.cc.
References HcalBaseDQClient::badChannelStatusMask_, HcalBaseDQClient::cloneME_, HcalBaseDQClient::debug_, HcalBaseDQClient::enableCleanup_, HcalBaseDQClient::enoughevents_, edm::ParameterSet::getUntrackedParameter(), HcalBaseDQClient::minerrorrate_, HcalBaseDQClient::minevents_, HcalBaseDQClient::name_, HcalBaseDQClient::Online_, HcalBaseDQClient::prefixME_, HcalBaseDQClient::ProblemCells, HcalBaseDQClient::ProblemCellsByDepth, HcalBaseDQClient::subdir_, and HcalBaseDQClient::validHtmlOutput_.
{ name_=myname; enableCleanup_ = ps.getUntrackedParameter<bool>("enableCleanup",false); debug_ = ps.getUntrackedParameter<int>("debug",0); prefixME_ = ps.getUntrackedParameter<std::string>("subSystemFolder","Hcal/"); if (prefixME_.substr(prefixME_.size()-1,prefixME_.size())!="/") prefixME_.append("/"); subdir_ = ps.getUntrackedParameter<std::string>("RecHitFolder","RecHitMonitor_Hcal/"); // RecHitMonitor_Hcal if (subdir_.size()>0 && subdir_.substr(subdir_.size()-1,subdir_.size())!="/") subdir_.append("/"); subdir_=prefixME_+subdir_; validHtmlOutput_ = ps.getUntrackedParameter<bool>("RecHit_validHtmlOutput",true); cloneME_ = ps.getUntrackedParameter<bool>("cloneME", true); badChannelStatusMask_ = ps.getUntrackedParameter<int>("RecHit_BadChannelStatusMask", ps.getUntrackedParameter<int>("BadChannelStatusMask", 0)); // identify channel status values to mask minerrorrate_ = ps.getUntrackedParameter<double>("RecHit_minerrorrate", ps.getUntrackedParameter<double>("minerrorrate",0.01)); minevents_ = ps.getUntrackedParameter<int>("RecHit_minevents", ps.getUntrackedParameter<int>("minevents",1)); enoughevents_=false; Online_ = ps.getUntrackedParameter<bool>("online",false); ProblemCells=0; ProblemCellsByDepth=0; }
HcalRecHitClient::~HcalRecHitClient | ( | ) |
Destructor.
void HcalRecHitClient::analyze | ( | void | ) | [virtual] |
Reimplemented from HcalBaseDQClient.
Definition at line 55 of file HcalRecHitClient.cc.
References HcalObjRepresent::CalcIeta(), calculateProblems(), HcalBaseDQClient::cloneME_, gather_cfg::cout, HcalBaseDQClient::debug_, EtaPhiHists::depth, HcalBaseDQClient::dqmStore_, eta(), MonitorElement::Fill(), HcalObjRepresent::FillUnphysicalHEHFBins(), DQMStore::get(), HcalBarrel, HcalEndcap, HcalEtaPhiHistNames(), HcalForward, HcalOuter, i, isHB(), isHE(), isHF(), isHO(), meEnergyByDepth, meEnergyThreshByDepth, meHBEnergy_1D, meHBEnergyRMS_1D, meHBEnergyRMSThresh_1D, meHBEnergyThresh_1D, meHEEnergy_1D, meHEEnergyRMS_1D, meHEEnergyRMSThresh_1D, meHEEnergyThresh_1D, meHFEnergy_1D, meHFEnergyRMS_1D, meHFEnergyRMSThresh_1D, meHFEnergyThresh_1D, meHOEnergy_1D, meHOEnergyRMS_1D, meHOEnergyRMSThresh_1D, meHOEnergyThresh_1D, meTimeByDepth, meTimeThreshByDepth, HcalBaseDQClient::name(), phi, funct::pow(), MonitorElement::Reset(), alignCSCRings::s, mathSSE::sqrt(), HcalBaseDQClient::subdir_, and validDetId().
Referenced by endRun().
{ if (debug_>2) std::cout <<"\tHcalRecHitClient::analyze()"<<std::endl; TH2F* OccupancyByDepth[4]; TH2F* SumEnergyByDepth[4]; TH2F* SumTimeByDepth[4]; TH2F* SqrtSumEnergy2ByDepth[4]; TH2F* OccupancyThreshByDepth[4]; TH2F* SumEnergyThreshByDepth[4]; TH2F* SumTimeThreshByDepth[4]; TH2F* SqrtSumEnergy2ThreshByDepth[4]; std::vector<std::string> name = HcalEtaPhiHistNames(); MonitorElement* me; bool gotHistos=true; for (int i=0;i<4;++i) { std::string s=subdir_+"Distributions_AllRecHits/"+name[i]+"RecHit Occupancy"; me=dqmStore_->get(s.c_str()); if (me==0) {if (debug_>0) std::cout <<"Could not get histogram "<<s<<std::endl; gotHistos=false; break;} OccupancyByDepth[i]=HcalUtilsClient::getHisto<TH2F*>(me, cloneME_, OccupancyByDepth[i], debug_); s=subdir_+"Distributions_AllRecHits/sumplots/"+name[i]+"RecHit Summed Energy GeV"; me=dqmStore_->get(s.c_str()); if (me==0) {if (debug_>0) std::cout <<"Could not get histogram "<<s<<std::endl; gotHistos=false; break;} SumEnergyByDepth[i]=HcalUtilsClient::getHisto<TH2F*>(me, cloneME_, SumEnergyByDepth[i], debug_); s=subdir_+"Distributions_AllRecHits/sumplots/"+name[i]+"RecHit Summed Time nS"; me=dqmStore_->get(s.c_str()); if (me==0) {if (debug_>0) std::cout <<"Could not get histogram "<<s<<std::endl; gotHistos=false; break;} SumTimeByDepth[i]=HcalUtilsClient::getHisto<TH2F*>(me, cloneME_, SumTimeByDepth[i], debug_); s=subdir_+"Distributions_AllRecHits/sumplots/"+name[i]+"RecHit Sqrt Summed Energy2 GeV"; me=dqmStore_->get(s.c_str()); if (me==0) {if (debug_>0) std::cout <<"Could not get histogram "<<s<<std::endl; gotHistos=false; break;} SqrtSumEnergy2ByDepth[i]=HcalUtilsClient::getHisto<TH2F*>(me, cloneME_, SqrtSumEnergy2ByDepth[i], debug_); // Threshold histograms s=subdir_+"Distributions_PassedMinBias/"+name[i]+"Above Threshold RecHit Occupancy"; me=dqmStore_->get(s.c_str()); if (me==0) {if (debug_>0) std::cout <<"Could not get histogram "<<s<<std::endl; gotHistos=false; break;} OccupancyThreshByDepth[i]=HcalUtilsClient::getHisto<TH2F*>(me, cloneME_, OccupancyThreshByDepth[i], debug_); s=subdir_+"Distributions_PassedMinBias/sumplots/"+name[i]+"Above Threshold RecHit Summed Energy GeV"; me=dqmStore_->get(s.c_str()); if (me==0) {if (debug_>0) std::cout <<"Could not get histogram "<<s<<std::endl; gotHistos=false; break;} SumEnergyThreshByDepth[i]=HcalUtilsClient::getHisto<TH2F*>(me, cloneME_, SumEnergyThreshByDepth[i], debug_); s=subdir_+"Distributions_PassedMinBias/sumplots/"+name[i]+"Above Threshold RecHit Summed Time nS"; me=dqmStore_->get(s.c_str()); if (me==0) {if (debug_>0) std::cout <<"Could not get histogram "<<s<<std::endl; gotHistos=false; break;} SumTimeThreshByDepth[i]=HcalUtilsClient::getHisto<TH2F*>(me, cloneME_, SumTimeThreshByDepth[i], debug_); s=subdir_+"Distributions_PassedMinBias/sumplots/"+name[i]+"Above Threshold RecHit Sqrt Summed Energy2 GeV"; me=dqmStore_->get(s.c_str()); if (me==0) {if (debug_>0) std::cout <<"Could not get histogram "<<s<<std::endl; gotHistos=false; break;} SqrtSumEnergy2ThreshByDepth[i]=HcalUtilsClient::getHisto<TH2F*>(me, cloneME_, SqrtSumEnergy2ThreshByDepth[i], debug_); } if (gotHistos==false) { if (debug_>0) std::cout <<"<HcalRecHitClient::calculateProblems()> Not all histograms could be found; skipping normalization"<<std::endl; return; } // Clear histograms before re-filling meHBEnergy_1D->Reset(); meHBEnergyRMS_1D->Reset(); meHEEnergy_1D->Reset(); meHEEnergyRMS_1D->Reset(); meHOEnergy_1D->Reset(); meHOEnergyRMS_1D->Reset(); meHFEnergy_1D->Reset(); meHFEnergyRMS_1D->Reset(); meHBEnergyThresh_1D->Reset(); meHBEnergyRMSThresh_1D->Reset(); meHEEnergyThresh_1D->Reset(); meHEEnergyRMSThresh_1D->Reset(); meHOEnergyThresh_1D->Reset(); meHOEnergyRMSThresh_1D->Reset(); meHFEnergyThresh_1D->Reset(); meHFEnergyRMSThresh_1D->Reset(); for (int mydepth=0;mydepth<4;++mydepth) { for (int eta=0;eta<OccupancyByDepth[mydepth]->GetNbinsX();++eta) { // eta+1=1: ieta = -42 // eta+1=13: ieta = -29 for (int phi=0;phi<72;++phi) { if (OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1)>0) { // fill 1D plots if (isHB(eta,mydepth+1)) { if (validDetId(HcalBarrel, CalcIeta(HcalBarrel, eta, mydepth+1), phi+1, mydepth+1)) { meHBEnergy_1D->Fill(SumEnergyByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1)); meHBEnergyRMS_1D->Fill(sqrt(pow(SqrtSumEnergy2ByDepth[mydepth]->GetBinContent(eta+1, phi+1),2)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1)-pow(SumEnergyByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1),2))); } } else if (isHE(eta,mydepth+1)) { if (validDetId(HcalEndcap, CalcIeta(HcalEndcap, eta, mydepth+1), phi+1, mydepth+1)) { meHEEnergy_1D->Fill(SumEnergyByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1)); meHEEnergyRMS_1D->Fill(sqrt(pow(SqrtSumEnergy2ByDepth[mydepth]->GetBinContent(eta+1, phi+1),2)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1)-pow(SumEnergyByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1),2))); } } else if (isHO(eta,mydepth+1)) { if (validDetId(HcalOuter, CalcIeta(HcalOuter, eta, mydepth+1), phi+1, mydepth+1)) { meHOEnergy_1D->Fill(SumEnergyByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1)); meHOEnergyRMS_1D->Fill(sqrt(pow(SqrtSumEnergy2ByDepth[mydepth]->GetBinContent(eta+1, phi+1),2)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1)-pow(SumEnergyByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1),2))); } } else if (isHF(eta,mydepth+1)) { if (validDetId(HcalForward, CalcIeta(HcalForward, eta, mydepth+1), phi+1, mydepth+1)) { meHFEnergy_1D->Fill(SumEnergyByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1)); meHFEnergyRMS_1D->Fill(sqrt(pow(SqrtSumEnergy2ByDepth[mydepth]->GetBinContent(eta+1, phi+1),2)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1)-pow(SumEnergyByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1),2))); } } // normalize 2D plots by number of events meEnergyByDepth->depth[mydepth]->setBinContent(eta+1, phi+1, SumEnergyByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1)); meTimeByDepth->depth[mydepth]->setBinContent(eta+1, phi+1, SumTimeByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyByDepth[mydepth]->GetBinContent(eta+1, phi+1)); } // (OccupancyByDepth[mydepth]->GetBinContent(eta+1,phi+1)>0) if (OccupancyThreshByDepth[mydepth]==0) continue; if (OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)>0) { // fill 1D plots if (isHB(eta,mydepth+1)) { if (validDetId(HcalBarrel, CalcIeta(HcalBarrel, eta, mydepth+1), phi+1, mydepth+1)) { meHBEnergyThresh_1D->Fill(SumEnergyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)); double RMS=pow(SqrtSumEnergy2ThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1),2)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1,phi+1)-pow(SumEnergyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1),2); RMS=pow(fabs(RMS),0.5); meHBEnergyRMSThresh_1D->Fill(RMS); } } else if (isHE(eta,mydepth+1)) { if (validDetId(HcalEndcap, CalcIeta(HcalEndcap, eta, mydepth+1), phi+1, mydepth+1)) { meHEEnergyThresh_1D->Fill(SumEnergyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)); double RMS=pow(SqrtSumEnergy2ThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1),2)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1,phi+1)-pow(SumEnergyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1),2); RMS=pow(fabs(RMS),0.5); meHEEnergyRMSThresh_1D->Fill(RMS); } } else if (isHO(eta,mydepth+1)) { if (validDetId(HcalOuter, CalcIeta(HcalOuter, eta, mydepth+1), phi+1, mydepth+1)) { meHOEnergyThresh_1D->Fill(SumEnergyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)); double RMS=pow(SqrtSumEnergy2ThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1),2)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1,phi+1)-pow(SumEnergyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1),2); RMS=pow(fabs(RMS),0.5); meHOEnergyRMSThresh_1D->Fill(RMS); } } else if (isHF(eta,mydepth+1)) { if (validDetId(HcalForward, CalcIeta(HcalForward, eta, mydepth+1), phi+1, mydepth+1)) { meHFEnergyThresh_1D->Fill(SumEnergyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)); double RMS=pow(SqrtSumEnergy2ThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1),2)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1,phi+1)-pow(SumEnergyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1),2); RMS=pow(fabs(RMS),0.5); meHFEnergyRMSThresh_1D->Fill(RMS); } } // fill 2D plots meEnergyThreshByDepth->depth[mydepth]->setBinContent(eta+1, phi+1, SumEnergyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)); meTimeThreshByDepth->depth[mydepth]->setBinContent(eta+1, phi+1, SumTimeThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)/OccupancyThreshByDepth[mydepth]->GetBinContent(eta+1, phi+1)); } } // for (int phi=0;phi<72;++phi) } // for (int eta=0;eta<OccupancyByDepth->..;++eta) } // for (int mydepth=0;...) FillUnphysicalHEHFBins(*meEnergyByDepth); FillUnphysicalHEHFBins(*meTimeByDepth); FillUnphysicalHEHFBins(*meEnergyThreshByDepth); FillUnphysicalHEHFBins(*meTimeThreshByDepth); calculateProblems(); }
void HcalRecHitClient::beginJob | ( | void | ) | [virtual] |
Reimplemented from HcalBaseDQClient.
Definition at line 355 of file HcalRecHitClient.cc.
References gather_cfg::cout, HcalBaseDQClient::debug_, HcalBaseDQClient::dqmStore_, cmsCodeRules::cppFunctionSkipper::operator, and DQMStore::showDirStructure().
{ dqmStore_ = edm::Service<DQMStore>().operator->(); if (debug_>0) { std::cout <<"<HcalRecHitClient::beginJob()> Displaying dqmStore directory structure:"<<std::endl; dqmStore_->showDirStructure(); } }
void HcalRecHitClient::beginRun | ( | void | ) | [virtual] |
Reimplemented from HcalBaseDQClient.
Definition at line 366 of file HcalRecHitClient.cc.
References DQMStore::book1D(), DQMStore::book2D(), gather_cfg::cout, HcalBaseDQClient::debug_, EtaPhiHists::depth, HcalBaseDQClient::dqmStore_, MonitorElement::getName(), i, meEnergyByDepth, meEnergyThreshByDepth, meHBEnergy_1D, meHBEnergyRMS_1D, meHBEnergyRMSThresh_1D, meHBEnergyThresh_1D, meHEEnergy_1D, meHEEnergyRMS_1D, meHEEnergyRMSThresh_1D, meHEEnergyThresh_1D, meHFEnergy_1D, meHFEnergyRMS_1D, meHFEnergyRMSThresh_1D, meHFEnergyThresh_1D, meHOEnergy_1D, meHOEnergyRMS_1D, meHOEnergyRMSThresh_1D, meHOEnergyThresh_1D, meTimeByDepth, meTimeThreshByDepth, nevts_, HcalBaseDQClient::ProblemCells, HcalBaseDQClient::ProblemCellsByDepth, HcalBaseDQClient::problemnames_, DQMStore::setCurrentFolder(), EtaPhiHists::setup(), HcalBaseDQClient::subdir_, x, and detailsBasic3DVector::y.
{ if (debug_>1) std::cout <<"<HcalRecHitClient::endRun>"<<std::endl; if (!dqmStore_) { if (debug_>0) std::cout <<"<HcalRecHitClient::beginRun> dqmStore does not exist!"<<std::endl; return; } dqmStore_->setCurrentFolder(subdir_); problemnames_.clear(); ProblemCells=dqmStore_->book2D(" ProblemRecHits", "Problem RecHit Rate for all HCAL;ieta;iphi", 85,-42.5,42.5, 72,0.5,72.5); problemnames_.push_back(ProblemCells->getName()); if (debug_>1) std::cout << "Tried to create ProblemCells Monitor Element in directory "<<subdir_<<" \t Failed? "<<(ProblemCells==0)<<std::endl; dqmStore_->setCurrentFolder(subdir_+"problem_rechits"); ProblemCellsByDepth=new EtaPhiHists(); ProblemCellsByDepth->setup(dqmStore_," Problem RecHit Rate"); for (unsigned int i=0; i<ProblemCellsByDepth->depth.size();++i) problemnames_.push_back(ProblemCellsByDepth->depth[i]->getName()); nevts_=0; dqmStore_->setCurrentFolder(subdir_+"Distributions_AllRecHits"); meEnergyByDepth = new EtaPhiHists(); meEnergyByDepth->setup(dqmStore_,"RecHit Average Energy","GeV"); meTimeByDepth = new EtaPhiHists(); meTimeByDepth->setup(dqmStore_,"RecHit Average Time","nS"); // set all average times to -1000 by default (so that they don't show up on plots for (unsigned int i=0;i<meTimeByDepth->depth.size();++i) { (meTimeByDepth->depth[i]->getTH2F())->SetMinimum(-150); (meTimeByDepth->depth[i]->getTH2F())->SetMaximum(150); int etabins=(meTimeByDepth->depth[i]->getTH2F())->GetNbinsX(); int phibins=(meTimeByDepth->depth[i]->getTH2F())->GetNbinsY(); for (int x=1;x<=etabins;++x) for (int y=1;y<=phibins;++y) meTimeByDepth->depth[i]->setBinContent(x,y,-1000); } dqmStore_->setCurrentFolder(subdir_+"Distributions_PassedMinBias"); meEnergyThreshByDepth = new EtaPhiHists(); meEnergyThreshByDepth->setup(dqmStore_,"Above Threshold RecHit Average Energy","GeV"); meTimeThreshByDepth = new EtaPhiHists(); meTimeThreshByDepth->setup(dqmStore_,"Above Threshold RecHit Average Time","nS"); // set all average times to -1000 by default (so that they don't show up on plots for (unsigned int i=0;i<meTimeThreshByDepth->depth.size();++i) { (meTimeThreshByDepth->depth[i]->getTH2F())->SetMinimum(-150); (meTimeThreshByDepth->depth[i]->getTH2F())->SetMaximum(150); int etabins=(meTimeThreshByDepth->depth[i]->getTH2F())->GetNbinsX(); int phibins=(meTimeThreshByDepth->depth[i]->getTH2F())->GetNbinsY(); for (int x=1;x<=etabins;++x) for (int y=1;y<=phibins;++y) meTimeThreshByDepth->depth[i]->setBinContent(x,y,-1000); } dqmStore_->setCurrentFolder(subdir_+"Distributions_AllRecHits/rechit_1D_plots/"); meHBEnergy_1D=dqmStore_->book1D("HB_energy_1D","HB Average Energy Per RecHit;Energy (GeV)",200,-5,15); meHEEnergy_1D=dqmStore_->book1D("HE_energy_1D","HE Average Energy Per RecHit;Energy (GeV)",200,-5,15); meHOEnergy_1D=dqmStore_->book1D("HO_energy_1D","HO Average Energy Per RecHit;Energy (GeV)",200,-10,20); meHFEnergy_1D=dqmStore_->book1D("HF_energy_1D","HF Average Energy Per RecHit;Energy (GeV)",200,-5,15); meHBEnergyRMS_1D=dqmStore_->book1D("HB_energy_RMS_1D","HB Energy RMS Per RecHit;Energy (GeV)",250,0,5); meHEEnergyRMS_1D=dqmStore_->book1D("HE_energy_RMS_1D","HE Energy RMS Per RecHit;Energy (GeV)",250,0,5); meHOEnergyRMS_1D=dqmStore_->book1D("HO_energy_RMS_1D","HO Energy RMS Per RecHit;Energy (GeV)",250,0,5); meHFEnergyRMS_1D=dqmStore_->book1D("HF_energy_RMS_1D","HF Energy RMS Per RecHit;Energy (GeV)",250,0,5); dqmStore_->setCurrentFolder(subdir_+"Distributions_PassedMinBias/rechit_1D_plots/"); meHBEnergyThresh_1D=dqmStore_->book1D("HB_energyThresh_1D","HB Average Energy Per RecHit Above Threshold;Energy (GeV)",200,-5,35); meHEEnergyThresh_1D=dqmStore_->book1D("HE_energyThresh_1D","HE Average Energy Per RecHit Above Threshold;Energy (GeV)",200,-5,35); meHOEnergyThresh_1D=dqmStore_->book1D("HO_energyThresh_1D","HO Average Energy Per RecHit Above Threshold;Energy (GeV)",300,-10,50); meHFEnergyThresh_1D=dqmStore_->book1D("HF_energyThresh_1D","HF Average Energy Per RecHit Above Threshold;Energy (GeV)",200,-5,95); meHBEnergyRMSThresh_1D=dqmStore_->book1D("HB_energy_RMSThresh_1D","HB Energy RMS Per RecHit Above Threshold;Energy (GeV)",200,0,10); meHEEnergyRMSThresh_1D=dqmStore_->book1D("HE_energy_RMSThresh_1D","HE Energy RMS Per RecHit Above Threshold;Energy (GeV)",200,0,10); meHOEnergyRMSThresh_1D=dqmStore_->book1D("HO_energy_RMSThresh_1D","HO Energy RMS Per RecHit Above Threshold;Energy (GeV)",200,0,10); meHFEnergyRMSThresh_1D=dqmStore_->book1D("HF_energy_RMSThresh_1D","HF Energy RMS Per RecHit Above Threshold;Energy (GeV)",200,0,20); }
void HcalRecHitClient::calculateProblems | ( | void | ) | [virtual] |
Reimplemented from HcalBaseDQClient.
Definition at line 247 of file HcalRecHitClient.cc.
References HcalBaseDQClient::badstatusmap, HcalObjRepresent::CalcIeta(), gather_cfg::cout, HcalBaseDQClient::debug_, EtaPhiHists::depth, HcalBaseDQClient::dqmStore_, HcalBaseDQClient::enoughevents_, eta(), MonitorElement::Fill(), HcalObjRepresent::FillUnphysicalHEHFBins(), MonitorElement::getBinContent(), MonitorElement::getTH2F(), HcalBarrel, HcalEmpty, HcalEndcap, HcalEtaPhiHistNames(), HcalForward, HcalOuter, isHB(), isHE(), isHF(), isHO(), min, HcalBaseDQClient::minerrorrate_, HcalBaseDQClient::minevents_, HcalBaseDQClient::name(), phi, HcalBaseDQClient::ProblemCells, HcalBaseDQClient::ProblemCellsByDepth, MonitorElement::Reset(), and MonitorElement::setBinContent().
Referenced by analyze().
{ if (debug_>2) std::cout <<"\t\tHcalRecHitClient::calculateProblems()"<<std::endl; if(!dqmStore_) return; double totalevents=0; int etabins=0, phibins=0, zside=0; double problemvalue=0; std::vector<std::string> name = HcalEtaPhiHistNames(); // use this to get EtaPhiHistograms that feed problem calculation, once they exist (see analyze function for example usage of HcalEtaPhiHistNames()) // Get histograms used in determining rechit problem rate, // and get totalevents from their underflow bins. // No such problem histograms are defined so far. enoughevents_=true; if (totalevents==0) return; // Clear away old problems if (ProblemCells!=0) { ProblemCells->Reset(); (ProblemCells->getTH2F())->SetMaximum(1.05); (ProblemCells->getTH2F())->SetMinimum(0.); } for (unsigned int d=0;d<ProblemCellsByDepth->depth.size();++d) { if (ProblemCellsByDepth->depth[d]!=0) { ProblemCellsByDepth->depth[d]->Reset(); (ProblemCellsByDepth->depth[d]->getTH2F())->SetMaximum(1.05); (ProblemCellsByDepth->depth[d]->getTH2F())->SetMinimum(0.); } } for (unsigned int d=0;d<ProblemCellsByDepth->depth.size();++d) { if (ProblemCellsByDepth->depth[d]==0) continue; // Get total events from some future histogram //totalevents=DigiPresentByDepth[d]->GetBinContent(0); // get totalevents from each depth, in case they differ if (totalevents==0 || totalevents<minevents_) continue; etabins=(ProblemCellsByDepth->depth[d]->getTH2F())->GetNbinsX(); phibins=(ProblemCellsByDepth->depth[d]->getTH2F())->GetNbinsY(); problemvalue=0; for (int eta=0;eta<etabins;++eta) { int ieta=CalcIeta(eta,d+1); if (ieta==-9999) continue; for (int phi=0;phi<phibins;++phi) { problemvalue=0; // Add histograms here when rechit testing decided upon /*if (DigiPresentByDepth[d]!=0 && DigiPresentByDepth[d]->GetBinContent(eta+1,phi+1)>0) problemvalue=totalevents; */ if (problemvalue==0) continue; problemvalue/=totalevents; // problem value is a rate; should be between 0 and 1 problemvalue = std::min(1.,problemvalue); zside=0; if (isHF(eta,d+1)) // shift ieta by 1 for HF ieta<0 ? zside = -1 : zside = 1; // For problem cells that exceed our allowed rate, // set the values to 999 if the cells are already marked in the status database if (problemvalue>minerrorrate_) { HcalSubdetector subdet=HcalEmpty; if (isHB(eta,d+1))subdet=HcalBarrel; else if (isHE(eta,d+1)) subdet=HcalEndcap; else if (isHF(eta,d+1)) subdet=HcalForward; else if (isHO(eta,d+1)) subdet=HcalOuter; HcalDetId hcalid(subdet, ieta, phi+1, (int)(d+1)); if (badstatusmap.find(hcalid)!=badstatusmap.end()) problemvalue=999; } ProblemCellsByDepth->depth[d]->setBinContent(eta+1,phi+1,problemvalue); if (ProblemCells!=0) ProblemCells->Fill(ieta+zside,phi+1,problemvalue); } // loop on phi } // loop on eta } // loop on depth if (ProblemCells==0) { if (debug_>0) std::cout <<"<HcalRecHitClient::analyze> ProblemCells histogram does not exist!"<<std::endl; return; } // Normalization of ProblemCell plot, in the case where there are errors in multiple depths etabins=(ProblemCells->getTH2F())->GetNbinsX(); phibins=(ProblemCells->getTH2F())->GetNbinsY(); for (int eta=0;eta<etabins;++eta) { for (int phi=0;phi<phibins;++phi) { if (ProblemCells->getBinContent(eta+1,phi+1)>1. && ProblemCells->getBinContent(eta+1,phi+1)<999) ProblemCells->setBinContent(eta+1,phi+1,1.); } } FillUnphysicalHEHFBins(*ProblemCellsByDepth); FillUnphysicalHEHFBins(ProblemCells); return; }
void HcalRecHitClient::cleanup | ( | void | ) | [virtual] |
void HcalRecHitClient::endJob | ( | void | ) | [virtual] |
void HcalRecHitClient::endRun | ( | void | ) | [virtual] |
Reimplemented from HcalBaseDQClient.
Definition at line 449 of file HcalRecHitClient.cc.
References analyze(), gather_cfg::cout, and HcalBaseDQClient::debug_.
bool HcalRecHitClient::hasErrors_Temp | ( | void | ) | [virtual] |
Reimplemented from HcalBaseDQClient.
Definition at line 458 of file HcalRecHitClient.cc.
References HcalObjRepresent::CalcIeta(), gather_cfg::cout, HcalBaseDQClient::debug_, EtaPhiHists::depth, MonitorElement::getTH2F(), HcalBaseDQClient::minerrorrate_, HcalBaseDQClient::ProblemCells, and HcalBaseDQClient::ProblemCellsByDepth.
{ if (!ProblemCells) { if (debug_>1) std::cout <<"<HcalRecHitClient::hasErrors_Temp> ProblemCells histogram does not exist!"<<std::endl; return false; } int problemcount=0; int ieta=-9999; for (int depth=0;depth<4; ++depth) { int etabins = (ProblemCells->getTH2F())->GetNbinsX(); int phibins = (ProblemCells->getTH2F())->GetNbinsY(); for (int hist_eta=0;hist_eta<etabins;++hist_eta) { for (int hist_phi=0; hist_phi<phibins;++hist_phi) { ieta=CalcIeta(hist_eta,depth+1); if (ieta==-9999) continue; if (ProblemCellsByDepth->depth[depth]==0) continue; if (ProblemCellsByDepth->depth[depth]->getBinContent(hist_eta,hist_phi)>minerrorrate_) ++problemcount; } // for (int hist_phi=1;...) } // for (int hist_eta=1;...) } // for (int depth=0;...) if (problemcount>0) return true; return false; }
bool HcalRecHitClient::hasOther_Temp | ( | void | ) | [virtual] |
Reimplemented from HcalBaseDQClient.
Definition at line 491 of file HcalRecHitClient.cc.
{return false;}
bool HcalRecHitClient::hasWarnings_Temp | ( | void | ) | [virtual] |
Reimplemented from HcalBaseDQClient.
Definition at line 490 of file HcalRecHitClient.cc.
{return false;}
void HcalRecHitClient::setup | ( | void | ) | [virtual] |
bool HcalRecHitClient::test_enabled | ( | void | ) | [virtual] |
Reimplemented from HcalBaseDQClient.
Definition at line 492 of file HcalRecHitClient.cc.
{return true;}
void HcalRecHitClient::updateChannelStatus | ( | std::map< HcalDetId, unsigned int > & | myqual | ) | [virtual] |
Reimplemented from HcalBaseDQClient.
Definition at line 496 of file HcalRecHitClient.cc.
{ // rechit quality not used to update channel status yet; see dead cell client for example } //void HcalRecHitClient::updateChannelStatus
EtaPhiHists* HcalRecHitClient::meEnergyByDepth [private] |
Definition at line 40 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
Definition at line 41 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
MonitorElement* HcalRecHitClient::meHBEnergy_1D [private] |
Definition at line 47 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
MonitorElement* HcalRecHitClient::meHBEnergyRMS_1D [private] |
Definition at line 52 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
Definition at line 62 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
Definition at line 57 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
MonitorElement* HcalRecHitClient::meHEEnergy_1D [private] |
Definition at line 48 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
MonitorElement* HcalRecHitClient::meHEEnergyRMS_1D [private] |
Definition at line 53 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
Definition at line 63 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
Definition at line 58 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
MonitorElement* HcalRecHitClient::meHFEnergy_1D [private] |
Definition at line 50 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
MonitorElement* HcalRecHitClient::meHFEnergyRMS_1D [private] |
Definition at line 55 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
Definition at line 65 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
Definition at line 60 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
MonitorElement* HcalRecHitClient::meHOEnergy_1D [private] |
Definition at line 49 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
MonitorElement* HcalRecHitClient::meHOEnergyRMS_1D [private] |
Definition at line 54 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
Definition at line 64 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
Definition at line 59 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
Definition at line 44 of file HcalRecHitClient.h.
Definition at line 45 of file HcalRecHitClient.h.
EtaPhiHists* HcalRecHitClient::meTimeByDepth [private] |
Definition at line 42 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
EtaPhiHists* HcalRecHitClient::meTimeThreshByDepth [private] |
Definition at line 43 of file HcalRecHitClient.h.
Referenced by analyze(), and beginRun().
int HcalRecHitClient::nevts_ [private] |
Definition at line 38 of file HcalRecHitClient.h.
Referenced by beginRun().