#include <L1Scalers.h>
Definition at line 17 of file L1Scalers.h.
L1Scalers::L1Scalers | ( | const edm::ParameterSet & | ps | ) |
Constructors.
Definition at line 43 of file L1Scalers.cc.
References LogDebug.
: dbe_(0), nev_(0), verbose_(ps.getUntrackedParameter < bool > ("verbose", false)), l1GtDataSource_( ps.getParameter< edm::InputTag >("l1GtData")), denomIsTech_(ps.getUntrackedParameter <bool> ("denomIsTech", true)), denomBit_(ps.getUntrackedParameter <unsigned int> ("denomBit", 40)), tfIsTech_(ps.getUntrackedParameter <bool> ("tfIsTech", true)), tfBit_(ps.getUntrackedParameter <unsigned int> ("tfBit", 41)), algoSelected_(ps.getUntrackedParameter<std::vector<unsigned int> >("algoMonitorBits", std::vector<unsigned int>())), techSelected_(ps.getUntrackedParameter<std::vector<unsigned int> >("techMonitorBits", std::vector<unsigned int>())), folderName_( ps.getUntrackedParameter< std::string>("dqmFolder", std::string("L1T/L1Scalers_EvF"))), l1scalers_(0), l1techScalers_(0), l1Correlations_(0), bxNum_(0), l1scalersBx_(0), l1techScalersBx_(0), // pixFedSizeBx_(0), // hfEnergyMaxTowerBx_(0), nLumiBlock_(0), l1AlgoCounter_(0), l1TtCounter_(0), // pixFedSize_(0), // hfEnergy_(0), fedStart_(ps.getUntrackedParameter<unsigned int>("firstFED", 0)), fedStop_(ps.getUntrackedParameter<unsigned int>("lastFED", 931)), rateAlgoCounter_(0), rateTtCounter_(0), fedRawCollection_(ps.getParameter<edm::InputTag>("fedRawData")), maskedList_(ps.getUntrackedParameter<std::vector<int> >("maskedChannels", std::vector<int>())), //this is using the ashed index HcalRecHitCollection_(ps.getParameter<edm::InputTag>("HFRecHitCollection")) { LogDebug("Status") << "constructor" ; }
virtual L1Scalers::~L1Scalers | ( | ) | [inline, virtual] |
void L1Scalers::analyze | ( | const edm::Event & | e, |
const edm::EventSetup & | c | ||
) | [virtual] |
empty DecisionWord
Implements edm::EDAnalyzer.
Definition at line 184 of file L1Scalers.cc.
References algoBxDiff_, algoBxDiffLumi_, algoSelected_, begin, L1GtfeWord::bxNr(), bxNum_, cscBxDiff_, cscBxDiffLumi_, denomBit_, denomIsTech_, diffTreeTool::diff, dtBxDiff_, dtBxDiffLumi_, earliestAlgo_, earliestDenom_, earliestTech_, MonitorElement::Fill(), edm::Event::getByLabel(), L1MuGMTReadoutCollection::getRecords(), i, edm::HandleBase::isValid(), j, l1AlgoCounter_, l1Correlations_, l1GtDataSource_, l1scalers_, l1scalersBx_, l1techScalers_, l1techScalersBx_, l1TtCounter_, edm::InputTag::label(), LogDebug, edm::EventBase::luminosityBlock(), nev_, edm::Handle< T >::product(), rateAlgoCounter_, rateTtCounter_, rpcbBxDiff_, rpcbBxDiffLumi_, rpcfBxDiff_, rpcfBxDiffLumi_, matplotRender::t, techBxDiff_, techBxDiffLumi_, techSelected_, tfBit_, and tfIsTech_.
{ nev_++; LogDebug("Status") << "L1Scalers::analyze event " << nev_ ; int myGTFEbx = -1; // get Global Trigger decision and the decision word // these are locally derived edm::Handle<L1GlobalTriggerReadoutRecord> gtRecord; bool t = e.getByLabel(l1GtDataSource_,gtRecord); if ( ! t ) { LogDebug("Product") << "can't find L1GlobalTriggerReadoutRecord " << "with label " << l1GtDataSource_.label() ; } else { // DEBUG //gtRecord->print(std::cout); // DEBUG L1GtfeWord gtfeWord = gtRecord->gtfeWord(); int gtfeBx = gtfeWord.bxNr(); bxNum_->Fill(gtfeBx); myGTFEbx = gtfeBx; bool tfBitGood = false; // First, the default // vector of bool for(int iebx=0; iebx<=4; iebx++) { //Algorithm Bits DecisionWord gtDecisionWord = gtRecord->decisionWord(iebx-2); // DecisionWord gtDecisionWord = gtRecord->decisionWord(); if ( ! gtDecisionWord.empty() ) { // if board not there this is zero // loop over dec. bit to get total rate (no overlap) for ( uint i = 0; i < gtDecisionWord.size(); ++i ) { if ( gtDecisionWord[i] ) { rateAlgoCounter_++; l1AlgoCounter_->Fill(rateAlgoCounter_); break; } } // loop over decision bits for ( uint i = 0; i < gtDecisionWord.size(); ++i ) { if ( gtDecisionWord[i] ) { l1scalers_->Fill(i); l1scalersBx_->Fill(gtfeBx-2+iebx,i); for ( uint j = i + 1; j < gtDecisionWord.size(); ++j ) { if ( gtDecisionWord[j] ) { l1Correlations_->Fill(i,j); l1Correlations_->Fill(j,i); } } } } } // loop over technical triggers // vector of bool again. TechnicalTriggerWord tw = gtRecord->technicalTriggerWord(iebx-2); // TechnicalTriggerWord tw = gtRecord->technicalTriggerWord(); if ( ! tw.empty() ) { // loop over dec. bit to get total rate (no overlap) for ( uint i = 0; i < tw.size(); ++i ) { if ( tw[i] ) { rateTtCounter_++; l1TtCounter_->Fill(rateTtCounter_); break; } } for ( uint i = 0; i < tw.size(); ++i ) { if ( tw[i] ) { l1techScalers_->Fill(i); l1techScalersBx_->Fill(gtfeBx-2+iebx, i); } } // check if bit used to filter timing plots fired in this event // (anywhere in the bx window) if(tfIsTech_){ if(tfBit_ < tw.size()){ if( tw[tfBit_] ) tfBitGood = true; } } } // ! tw.empty }//bx //timing plots earliestDenom_ = 9; earliestAlgo_.clear(); earliestTech_.clear(); for(uint i=0; i < techSelected_.size(); i++) earliestTech_.push_back(9); for(uint i=0; i < algoSelected_.size(); i++) earliestAlgo_.push_back(9); //GMT information edm::Handle<L1MuGMTReadoutCollection> gmtCollection; e.getByLabel(l1GtDataSource_,gmtCollection); if (!gmtCollection.isValid()) { edm::LogInfo("DataNotFound") << "can't find L1MuGMTReadoutCollection with label " << l1GtDataSource_.label() ; } // remember the bx of 1st candidate of each system (9=none) int bx1st[4] = {9, 9, 9, 9}; if(tfBitGood){//to avoid single BSC hits for(int iebx=0; iebx<=4; iebx++) { TechnicalTriggerWord tw = gtRecord->technicalTriggerWord(iebx-2); DecisionWord gtDecisionWord = gtRecord->decisionWord(iebx-2); bool denomBitGood = false; //check if reference bit is valid if(denomIsTech_){ if ( ! tw.empty() ) { if( denomBit_ < tw.size() ){ denomBitGood = true; if( tw[denomBit_] && earliestDenom_==9 ) earliestDenom_ = iebx; } } } else{ if ( ! gtDecisionWord.empty() ) { if( denomBit_ < gtDecisionWord.size() ){ denomBitGood = true; if( gtDecisionWord[denomBit_] && earliestDenom_==9 ) earliestDenom_ = iebx; } } } if(denomBitGood){ //get earliest tech bx's if ( ! tw.empty() ) { for(uint ibit = 0; ibit < techSelected_.size(); ibit++){ if(techSelected_[ibit] < tw.size()){ if(tw[techSelected_[ibit]] && earliestTech_[ibit] == 9) earliestTech_[ibit] = iebx; } } } //get earliest algo bx's if(!gtDecisionWord.empty()){ for(uint ibit = 0; ibit < algoSelected_.size(); ibit++){ if(algoSelected_[ibit] < gtDecisionWord.size()){ if(gtDecisionWord[algoSelected_[ibit]] && earliestAlgo_[ibit] == 9) earliestAlgo_[ibit] = iebx; } } } }//denomBitGood }//bx //get earliest single muon trigger system bx's if (gmtCollection.isValid()) { // get GMT readout collection L1MuGMTReadoutCollection const* gmtrc = gmtCollection.product(); // get record vector std::vector<L1MuGMTReadoutRecord> gmt_records = gmtrc->getRecords(); // loop over records of individual bx's std::vector<L1MuGMTReadoutRecord>::const_iterator RRItr; for( RRItr = gmt_records.begin(); RRItr != gmt_records.end(); RRItr++ ) {//loop from BX=-2 to BX=2 std::vector<L1MuRegionalCand> INPCands[4] = { RRItr->getDTBXCands(), RRItr->getBrlRPCCands(), RRItr->getCSCCands(), RRItr->getFwdRPCCands() }; std::vector<L1MuRegionalCand>::const_iterator INPItr; int BxInEvent = RRItr->getBxInEvent(); // find the first non-empty candidate in this bx for(int i=0; i<4; i++) {//for each single muon trigger system for( INPItr = INPCands[i].begin(); INPItr != INPCands[i].end(); ++INPItr ) { if(!INPItr->empty()) { if(bx1st[i]==9) bx1st[i]=BxInEvent+2;//must go from 0 to 4 (consistent with above) } } } //for(int i=0; i<4; i++) // std::cout << "bx1st[" << i << "] = " << bx1st[i]; //std::cout << std::endl; } }//gmtCollection.isValid //calculated bx difference if(earliestDenom_ != 9){ for(uint ibit = 0; ibit < techSelected_.size(); ibit++){ if(earliestTech_[ibit] != 9){ int diff = earliestTech_[ibit] - earliestDenom_ ; techBxDiff_[ibit]->Fill(diff); techBxDiffLumi_[ibit]->Fill(e.luminosityBlock(), diff); } } for(uint ibit = 0; ibit < algoSelected_.size(); ibit++){ if(earliestAlgo_[ibit] != 9){ int diff = earliestAlgo_[ibit] - earliestDenom_ ; algoBxDiff_[ibit]->Fill(diff); algoBxDiffLumi_[ibit]->Fill(e.luminosityBlock(), diff); } } if(bx1st[0] != 9){ int diff = bx1st[0] - earliestDenom_; dtBxDiff_->Fill(diff); dtBxDiffLumi_->Fill(e.luminosityBlock(), diff); } if(bx1st[1] != 9){ int diff = bx1st[1] - earliestDenom_; rpcbBxDiff_->Fill(diff); rpcbBxDiffLumi_->Fill(e.luminosityBlock(), diff); } if(bx1st[2] != 9){ int diff = bx1st[2] - earliestDenom_; cscBxDiff_->Fill(diff); cscBxDiffLumi_->Fill(e.luminosityBlock(), diff); } if(bx1st[3] != 9){ int diff = bx1st[3] - earliestDenom_; rpcfBxDiff_->Fill(diff); rpcfBxDiffLumi_->Fill(e.luminosityBlock(), diff); } } }//tt41Good } // getbylabel succeeded // // HACK // // getting very basic uncalRH // edm::Handle<FEDRawDataCollection> theRaw; // bool getFed = e.getByLabel(fedRawCollection_, theRaw); // if ( ! getFed ) { // edm::LogInfo("FEDSizeFilter") << fedRawCollection_ << " not available"; // } // else { // got the fed raw data // unsigned int totalFEDsize = 0 ; // for (unsigned int i=fedStart_; i<=fedStop_; ++i) { // LogDebug("Parameter") << "Examining fed " << i << " with size " // << theRaw->FEDData(i).size() ; // totalFEDsize += theRaw->FEDData(i).size() ; // } // pixFedSize_->Fill(totalFEDsize); // if( (myGTFEbx!=-1) ) pixFedSizeBx_->Fill(myGTFEbx,totalFEDsize); // LogDebug("Parameter") << "Total FED size: " << totalFEDsize; // } // // HF - stolen from HLTrigger/special // // getting very basic uncalRH // double maxHFenergy = -1; // edm::Handle<HFRecHitCollection> crudeHits; // bool getHF = e.getByLabel(HcalRecHitCollection_, crudeHits); // if ( ! getHF ) { // LogDebug("Status") << HcalRecHitCollection_ << " not available"; // } // else { // LogDebug("Status") << "Filtering, with " << crudeHits->size() // << " recHits to consider" ; // for ( HFRecHitCollection::const_iterator hitItr = crudeHits->begin(); // hitItr != crudeHits->end(); ++hitItr ) { // HFRecHit hit = (*hitItr); // // masking noisy channels // std::vector<int>::iterator result; // result = std::find( maskedList_.begin(), maskedList_.end(), // HcalDetId(hit.id()).hashed_index() ); // if (result != maskedList_.end()) // continue; // hfEnergy_->Fill(hit.energy()); // if( (hit.energy()>maxHFenergy) ) maxHFenergy = hit.energy(); // } // } // if( (maxHFenergy!=-1 && myGTFEbx!=-1) ) hfEnergyMaxTowerBx_->Fill(myGTFEbx,maxHFenergy); // // END HACK return; }
void L1Scalers::beginJob | ( | void | ) | [virtual] |
BeginJob.
Reimplemented from edm::EDAnalyzer.
Definition at line 82 of file L1Scalers.cc.
References algoBxDiff_, algoBxDiffLumi_, algoSelected_, DQMStore::book1D(), DQMStore::book2D(), DQMStore::bookInt(), bxNum_, cscBxDiff_, cscBxDiffLumi_, dbe_, denomBit_, denomIsTech_, dtBxDiff_, dtBxDiffLumi_, folderName_, l1AlgoCounter_, l1Correlations_, l1scalers_, l1scalersBx_, l1techScalers_, l1techScalersBx_, l1TtCounter_, LogDebug, MAX_LUMI_BIN, MAX_LUMI_SEG, nLumiBlock_, cmsCodeRules::cppFunctionSkipper::operator, rpcbBxDiff_, rpcbBxDiffLumi_, rpcfBxDiff_, rpcfBxDiffLumi_, DQMStore::setCurrentFolder(), DQMStore::setVerbose(), techBxDiff_, techBxDiffLumi_, and techSelected_.
{ LogDebug("Status") << "L1Scalers::beginJob()..."; dbe_ = Service<DQMStore>().operator->(); if (dbe_ ) { dbe_->setVerbose(0); dbe_->setCurrentFolder(folderName_); l1scalers_ = dbe_->book1D("l1AlgoBits", "L1 Algorithm Bits", 128, -0.5, 127.5); l1scalersBx_ = dbe_->book2D("l1AlgoBits_Vs_Bx", "L1 Algorithm Bits vs " "Bunch Number", 3600, -0.5, 3599.5, 128, -0.5, 127.5); l1Correlations_ = dbe_->book2D("l1Correlations", "L1 Algorithm Bits " "Correlations", 128, -0.5, 127.5, 128, -0.5, 127.5); l1techScalers_ = dbe_->book1D("l1TechBits", "L1 Tech. Trigger Bits", 64, -0.5, 63.5); l1techScalersBx_ = dbe_->book2D("l1TechBits_Vs_Bx", "L1 Technical " "Trigger " "Bits vs Bunch Number", 3600, -0.5, 3599.5, 64, -0.5, 63.5); // pixFedSizeBx_ = dbe_->book2D("pixFedSize_Vs_Bx", "Size of Pixel FED data vs " // "Bunch Number", // 3600, -0.5, 3599.5, // 200, 0., 20000.); // hfEnergyMaxTowerBx_ = dbe_->book2D("hfEnergyMaxTower_Vs_Bx", "HF Energy Max Tower vs " // "Bunch Number", // 3600, -0.5, 3599.5, // 100, 0., 500.); bxNum_ = dbe_->book1D("bxNum", "Bunch number from GTFE", 3600, -0.5, 3599.5); nLumiBlock_ = dbe_->bookInt("nLumiBlock"); // l1 total rate l1AlgoCounter_ = dbe_->bookInt("l1AlgoCounter"); l1TtCounter_ = dbe_->bookInt("l1TtCounter"); //int maxNbins = 200; //int maxLumi = 2000; //timing plots std::stringstream sdenom; if(denomIsTech_) sdenom << "tech" ; else sdenom << "algo" ; dbe_->setCurrentFolder(folderName_ + "/Synch"); algoBxDiff_.clear(); algoBxDiff_.clear(); algoBxDiffLumi_.clear(); techBxDiffLumi_.clear(); for(uint ibit = 0; ibit < algoSelected_.size(); ibit++){ std::stringstream ss; ss << algoSelected_[ibit] << "_" << sdenom.str() << denomBit_; algoBxDiff_.push_back(dbe_->book1D("BX_diff_algo"+ ss.str(),"BX_diff_algo"+ ss.str(),9,-4,5)); algoBxDiffLumi_.push_back(dbe_->book2D("BX_diffvslumi_algo"+ ss.str(),"BX_diff_algo"+ss.str(),MAX_LUMI_BIN,-0.5,double(MAX_LUMI_SEG)-0.5,9,-4,5)); //algoBxDiffLumi_[ibit]->setAxisTitle("Lumi Section", 1); } for(uint ibit = 0; ibit < techSelected_.size(); ibit++){ std::stringstream ss; ss << techSelected_[ibit] << "_" << sdenom.str() << denomBit_; techBxDiff_.push_back(dbe_->book1D("BX_diff_tech"+ ss.str(),"BX_diff_tech"+ ss.str(),9,-4,5)); techBxDiffLumi_.push_back(dbe_->book2D("BX_diffvslumi_tech"+ ss.str(),"BX_diff_tech"+ss.str(),MAX_LUMI_BIN,-0.5,double(MAX_LUMI_SEG)-0.5,9,-4,5)); //techBxDiffLumi_[ibit]->setAxisTitle("Lumi Section", 1); } //GMT timing plots std::stringstream ss1; ss1 << "_" << sdenom.str() << denomBit_; dtBxDiff_ = dbe_->book1D("BX_diff_DT" + ss1.str(),"BX_diff_DT" + ss1.str(),9,-4,5); dtBxDiffLumi_ = dbe_->book2D("BX_diffvslumi_DT" + ss1.str(),"BX_diffvslumi_DT" + ss1.str(),MAX_LUMI_BIN,-0.5,double(MAX_LUMI_SEG)-0.5,9,-4,5); cscBxDiff_ = dbe_->book1D("BX_diff_CSC" + ss1.str(),"BX_diff_CSC" + ss1.str(),9,-4,5); cscBxDiffLumi_ = dbe_->book2D("BX_diffvslumi_CSC" + ss1.str(),"BX_diffvslumi_CSC" + ss1.str(),MAX_LUMI_BIN,-0.5,double(MAX_LUMI_SEG)-0.5,9,-4,5); rpcbBxDiff_ = dbe_->book1D("BX_diff_RPCb" + ss1.str(),"BX_diff_RPCb" + ss1.str(),9,-4,5); rpcbBxDiffLumi_ = dbe_->book2D("BX_diffvslumi_RPCb" + ss1.str(),"BX_diffvslumi_RPCb" + ss1.str(),MAX_LUMI_BIN,-0.5,double(MAX_LUMI_SEG)-0.5,9,-4,5); rpcfBxDiff_ = dbe_->book1D("BX_diff_RPCf" + ss1.str(),"BX_diff_RPCf" + ss1.str(),9,-4,5); rpcfBxDiffLumi_ = dbe_->book2D("BX_diffvslumi_RPCf" + ss1.str(),"BX_diffvslumi_RPCf" + ss1.str(),MAX_LUMI_BIN,-0.5,double(MAX_LUMI_SEG)-0.5,9,-4,5); // early triggers // pixFedSize_ = dbe_->book1D("pixFedSize", "Size of Pixel FED data", // 200, 0., 20000.); // hfEnergy_ = dbe_->book1D("hfEnergy", "HF energy", // 100, 0., 500.); } return; }
void L1Scalers::beginRun | ( | const edm::Run & | run, |
const edm::EventSetup & | c | ||
) | [virtual] |
void L1Scalers::endJob | ( | void | ) | [virtual] |
void L1Scalers::endLuminosityBlock | ( | const edm::LuminosityBlock & | lumiSeg, |
const edm::EventSetup & | c | ||
) | [virtual] |
End LumiBlock DQM Client Diagnostic should be performed here
Reimplemented from edm::EDAnalyzer.
Definition at line 483 of file L1Scalers.cc.
References MonitorElement::Fill(), edm::LuminosityBlockBase::id(), edm::LuminosityBlockID::luminosityBlock(), and nLumiBlock_.
{ nLumiBlock_->Fill(lumiSeg.id().luminosityBlock()); }
void L1Scalers::endRun | ( | const edm::Run & | run, |
const edm::EventSetup & | c | ||
) | [virtual] |
std::vector<MonitorElement* > L1Scalers::algoBxDiff_ [private] |
Definition at line 81 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
std::vector<MonitorElement* > L1Scalers::algoBxDiffLumi_ [private] |
Definition at line 83 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
std::vector<unsigned int> L1Scalers::algoSelected_ [private] |
Definition at line 59 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::bxNum_ [private] |
Definition at line 66 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::cscBxDiff_ [private] |
Definition at line 87 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::cscBxDiffLumi_ [private] |
Definition at line 88 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
DQMStore* L1Scalers::dbe_ [private] |
Definition at line 49 of file L1Scalers.h.
Referenced by beginJob().
unsigned int L1Scalers::denomBit_ [private] |
Definition at line 56 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
bool L1Scalers::denomIsTech_ [private] |
Definition at line 55 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::dtBxDiff_ [private] |
Definition at line 85 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::dtBxDiffLumi_ [private] |
Definition at line 86 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
std::vector<int> L1Scalers::earliestAlgo_ [private] |
Definition at line 113 of file L1Scalers.h.
Referenced by analyze().
int L1Scalers::earliestDenom_ [private] |
Definition at line 111 of file L1Scalers.h.
Referenced by analyze().
std::vector<int> L1Scalers::earliestTech_ [private] |
Definition at line 112 of file L1Scalers.h.
Referenced by analyze().
edm::InputTag L1Scalers::fedRawCollection_ [private] |
Definition at line 105 of file L1Scalers.h.
unsigned int L1Scalers::fedStart_ [private] |
Definition at line 99 of file L1Scalers.h.
unsigned int L1Scalers::fedStop_ [private] |
Definition at line 99 of file L1Scalers.h.
std::string L1Scalers::folderName_ [private] |
Definition at line 62 of file L1Scalers.h.
Referenced by beginJob().
Definition at line 108 of file L1Scalers.h.
MonitorElement* L1Scalers::l1AlgoCounter_ [private] |
Definition at line 77 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::l1Correlations_ [private] |
Definition at line 65 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
edm::InputTag L1Scalers::l1GtDataSource_ [private] |
Definition at line 53 of file L1Scalers.h.
Referenced by analyze().
MonitorElement* L1Scalers::l1scalers_ [private] |
Definition at line 63 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::l1scalersBx_ [private] |
Definition at line 70 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::l1techScalers_ [private] |
Definition at line 64 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::l1techScalersBx_ [private] |
Definition at line 71 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::l1TtCounter_ [private] |
Definition at line 78 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
std::vector<int> L1Scalers::maskedList_ [private] |
Definition at line 107 of file L1Scalers.h.
int L1Scalers::nev_ [private] |
Definition at line 50 of file L1Scalers.h.
Referenced by analyze().
MonitorElement* L1Scalers::nLumiBlock_ [private] |
Definition at line 76 of file L1Scalers.h.
Referenced by beginJob(), and endLuminosityBlock().
unsigned int L1Scalers::rateAlgoCounter_ [private] |
Definition at line 101 of file L1Scalers.h.
Referenced by analyze().
unsigned int L1Scalers::rateTtCounter_ [private] |
Definition at line 102 of file L1Scalers.h.
Referenced by analyze().
MonitorElement* L1Scalers::rpcbBxDiff_ [private] |
Definition at line 89 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::rpcbBxDiffLumi_ [private] |
Definition at line 90 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::rpcfBxDiff_ [private] |
Definition at line 91 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
MonitorElement* L1Scalers::rpcfBxDiffLumi_ [private] |
Definition at line 92 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
std::vector<MonitorElement* > L1Scalers::techBxDiff_ [private] |
Definition at line 82 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
std::vector<MonitorElement* > L1Scalers::techBxDiffLumi_ [private] |
Definition at line 84 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
std::vector<unsigned int> L1Scalers::techSelected_ [private] |
Definition at line 60 of file L1Scalers.h.
Referenced by analyze(), and beginJob().
unsigned int L1Scalers::tfBit_ [private] |
Definition at line 58 of file L1Scalers.h.
Referenced by analyze().
bool L1Scalers::tfIsTech_ [private] |
Definition at line 57 of file L1Scalers.h.
Referenced by analyze().
unsigned int L1Scalers::threshold_ [private] |
Definition at line 98 of file L1Scalers.h.
bool L1Scalers::verbose_ [private] |
Definition at line 52 of file L1Scalers.h.