CMS 3D CMS Logo

Public Member Functions | Private Attributes

L1Scalers Class Reference

#include <L1Scalers.h>

Inheritance diagram for L1Scalers:
edm::EDAnalyzer

List of all members.

Public Member Functions

void analyze (const edm::Event &e, const edm::EventSetup &c)
void beginJob (void)
 BeginJob.
void beginRun (const edm::Run &run, const edm::EventSetup &c)
 BeginRun.
void endJob (void)
void endLuminosityBlock (const edm::LuminosityBlock &lumiSeg, const edm::EventSetup &c)
void endRun (const edm::Run &run, const edm::EventSetup &c)
 EndRun.
 L1Scalers (const edm::ParameterSet &ps)
 Constructors.
virtual ~L1Scalers ()
 Destructor.

Private Attributes

std::vector< MonitorElement * > algoBxDiff_
std::vector< MonitorElement * > algoBxDiffLumi_
std::vector< unsigned int > algoSelected_
MonitorElementbxNum_
MonitorElementcscBxDiff_
MonitorElementcscBxDiffLumi_
DQMStoredbe_
unsigned int denomBit_
bool denomIsTech_
MonitorElementdtBxDiff_
MonitorElementdtBxDiffLumi_
std::vector< int > earliestAlgo_
int earliestDenom_
std::vector< int > earliestTech_
edm::InputTag fedRawCollection_
unsigned int fedStart_
unsigned int fedStop_
std::string folderName_
edm::InputTag HcalRecHitCollection_
MonitorElementl1AlgoCounter_
MonitorElementl1Correlations_
edm::InputTag l1GtDataSource_
MonitorElementl1scalers_
MonitorElementl1scalersBx_
MonitorElementl1techScalers_
MonitorElementl1techScalersBx_
MonitorElementl1TtCounter_
std::vector< int > maskedList_
int nev_
MonitorElementnLumiBlock_
unsigned int rateAlgoCounter_
unsigned int rateTtCounter_
MonitorElementrpcbBxDiff_
MonitorElementrpcbBxDiffLumi_
MonitorElementrpcfBxDiff_
MonitorElementrpcfBxDiffLumi_
std::vector< MonitorElement * > techBxDiff_
std::vector< MonitorElement * > techBxDiffLumi_
std::vector< unsigned int > techSelected_
unsigned int tfBit_
bool tfIsTech_
unsigned int threshold_
bool verbose_

Detailed Description

Definition at line 17 of file L1Scalers.h.


Constructor & Destructor Documentation

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]

Destructor.

Definition at line 24 of file L1Scalers.h.

{};

Member Function Documentation

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]

BeginRun.

Reimplemented from edm::EDAnalyzer.

Definition at line 492 of file L1Scalers.cc.

{
}
void L1Scalers::endJob ( void  ) [virtual]

Reimplemented from edm::EDAnalyzer.

Definition at line 180 of file L1Scalers.cc.

{
}
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]

EndRun.

Reimplemented from edm::EDAnalyzer.

Definition at line 497 of file L1Scalers.cc.

{
}

Member Data Documentation

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().

Definition at line 66 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

Definition at line 87 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

Definition at line 88 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

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().

Definition at line 85 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

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().

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().

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.

Definition at line 77 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

Definition at line 65 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

Definition at line 53 of file L1Scalers.h.

Referenced by analyze().

Definition at line 63 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

Definition at line 70 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

Definition at line 64 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

Definition at line 71 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

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().

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().

Definition at line 89 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

Definition at line 90 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

Definition at line 91 of file L1Scalers.h.

Referenced by analyze(), and beginJob().

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.