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Public Types | Public Member Functions | Static Public Member Functions | Private Attributes

ecaldqm::RawDataTask Class Reference

#include <RawDataTask.h>

Inheritance diagram for ecaldqm::RawDataTask:
ecaldqm::DQWorkerTask ecaldqm::DQWorker

List of all members.

Public Types

enum  Constants { nEventTypes = 25 }
enum  MESets {
  kEventTypePreCalib, kEventTypeCalib, kEventTypePostCalib, kCRC,
  kRunNumber, kOrbit, kTriggerType, kL1ADCC,
  kL1AFE, kL1ATCC, kL1ASRP, kBXDCC,
  kBXFE, kBXTCC, kBXSRP, kDesyncByLumi,
  kDesyncTotal, kFEStatus, kFEByLumi, kFEDEntries,
  kFEDFatal, nMESets
}

Public Member Functions

void analyze (const void *, Collections)
void beginEvent (const edm::Event &, const edm::EventSetup &)
void beginLuminosityBlock (const edm::LuminosityBlock &, const edm::EventSetup &)
void bookMEs ()
 RawDataTask (const edm::ParameterSet &, const edm::ParameterSet &)
void runOnRawData (const EcalRawDataCollection &, Collections)
void runOnSource (const FEDRawDataCollection &, Collections)
 ~RawDataTask ()

Static Public Member Functions

static void setMEData (std::vector< MEData > &)

Private Attributes

int bx_
int feL1Offset_
std::string hltTaskFolder_
int hltTaskMode_
int l1A_
int orbit_
int run_
short triggerType_

Detailed Description

Definition at line 11 of file RawDataTask.h.


Member Enumeration Documentation

Enumerator:
nEventTypes 

Definition at line 52 of file RawDataTask.h.

                   {
      nEventTypes = 25
    };
Enumerator:
kEventTypePreCalib 
kEventTypeCalib 
kEventTypePostCalib 
kCRC 
kRunNumber 
kOrbit 
kTriggerType 
kL1ADCC 
kL1AFE 
kL1ATCC 
kL1ASRP 
kBXDCC 
kBXFE 
kBXTCC 
kBXSRP 
kDesyncByLumi 
kDesyncTotal 
kFEStatus 
kFEByLumi 
kFEDEntries 
kFEDFatal 
nMESets 

Reimplemented from ecaldqm::DQWorker.

Definition at line 26 of file RawDataTask.h.

                {
      kEventTypePreCalib, // h1f
      kEventTypeCalib, // h1f
      kEventTypePostCalib, // h1f
      kCRC, // h1f
      kRunNumber, // h1f
      kOrbit, // h1f
      kTriggerType, // h1f
      kL1ADCC, // h1f
      kL1AFE, // h1f
      //      kL1AFEMap, // h2f
      kL1ATCC, // h1f
      kL1ASRP, // h1f
      kBXDCC, // h1f
      kBXFE, // h1f
      kBXTCC, // h1f
      kBXSRP, // h1f
      kDesyncByLumi, // h1f
      kDesyncTotal, // h1f
      kFEStatus, // h1f
      kFEByLumi, // h1f
      kFEDEntries,
      kFEDFatal,
      nMESets
    };

Constructor & Destructor Documentation

data refman pasoursint CMSSW_5_2_7_hltpatch2 src DQM EcalBarrelMonitorTasks src RawDataTask cc ecaldqm::RawDataTask::RawDataTask ( const edm::ParameterSet _params,
const edm::ParameterSet _paths 
)

Definition at line 13 of file RawDataTask.cc.

References edm::ParameterSet::getUntrackedParameter(), edm::ParameterSet::getUntrackedParameterSet(), ecaldqm::kEcalRawData, ecaldqm::kLumiSection, and ecaldqm::kSource.

  {
    collectionMask_ = 
      (0x1 << kLumiSection) |
      (0x1 << kSource) |
      (0x1 << kEcalRawData);

    dependencies_.push_back(std::pair<Collections, Collections>(kEcalRawData, kSource));

    edm::ParameterSet const& commonParams(_params.getUntrackedParameterSet("Common"));

    hltTaskMode_ = commonParams.getUntrackedParameter<int>("hltTaskMode");
    hltTaskFolder_ = commonParams.getUntrackedParameter<std::string>("hltTaskFolder");

    if(hltTaskMode_ != 0 && hltTaskFolder_.size() == 0)
        throw cms::Exception("InvalidConfiguration") << "HLTTask mode needs a folder name";

    if(hltTaskMode_ != 0){
      std::map<std::string, std::string> replacements;
      replacements["hlttask"] = hltTaskFolder_;

      MEs_[kFEDEntries]->name(replacements);
      MEs_[kFEDFatal]->name(replacements);
    }
  }

ecaldqm::RawDataTask::~RawDataTask ( )

Definition at line 48 of file RawDataTask.cc.

  {
  }


Member Function Documentation

void ecaldqm::RawDataTask::analyze ( const void *  _p,
Collections  _collection 
) [inline, virtual]

Reimplemented from ecaldqm::DQWorkerTask.

Definition at line 70 of file RawDataTask.h.

References ecaldqm::kEcalRawData, ecaldqm::kSource, runOnRawData(), and runOnSource().

                                                                         {
    switch(_collection){
    case kSource:
      runOnSource(*static_cast<const FEDRawDataCollection*>(_p), _collection);
      break;
    case kEcalRawData:
      runOnRawData(*static_cast<const EcalRawDataCollection*>(_p), _collection);
      break;
    default:
      break;
    }
  }
void ecaldqm::RawDataTask::beginEvent ( const edm::Event _evt,
const edm::EventSetup  
) [virtual]
void ecaldqm::RawDataTask::beginLuminosityBlock ( const edm::LuminosityBlock ,
const edm::EventSetup  
) [virtual]

Reimplemented from ecaldqm::DQWorker.

Definition at line 124 of file RawDataTask.cc.

References kDesyncByLumi, kFEByLumi, and ecaldqm::DQWorker::MEs_.

  {
    if(MEs_[kDesyncByLumi]->isActive()) MEs_[kDesyncByLumi]->reset();
    if(MEs_[kFEByLumi]->isActive()) MEs_[kFEByLumi]->reset();
  }

void ecaldqm::RawDataTask::bookMEs ( ) [virtual]

Reimplemented from ecaldqm::DQWorker.

Definition at line 53 of file RawDataTask.cc.

References EcalDCCHeaderBlock::BEAMH2, EcalDCCHeaderBlock::BEAMH4, ecaldqm::BlockSize, ecaldqm::BXDesync, EcalDCCHeaderBlock::CALIB_LOCAL, ecaldqm::ChannelId, EcalDCCHeaderBlock::COSMIC, EcalDCCHeaderBlock::COSMICS_GLOBAL, EcalDCCHeaderBlock::COSMICS_LOCAL, ecaldqm::Disabled, ecaldqm::Enabled, ecaldqm::FIFOFull, ecaldqm::FIFOFullL1ADesync, ecaldqm::ForcedZS, EcalDCCHeaderBlock::HALO_GLOBAL, EcalDCCHeaderBlock::HALO_LOCAL, ecaldqm::HeaderError, hltTaskMode_, ecaldqm::HParity, i, kEventTypeCalib, kEventTypePostCalib, kEventTypePreCalib, kFEByLumi, kFEDEntries, kFEDFatal, kFEStatus, ecaldqm::L1ABXDesync, ecaldqm::L1ADesync, EcalDCCHeaderBlock::LASER_DELAY_SCAN, EcalDCCHeaderBlock::LASER_GAP, EcalDCCHeaderBlock::LASER_POWER_SCAN, EcalDCCHeaderBlock::LASER_STD, EcalDCCHeaderBlock::LED_GAP, EcalDCCHeaderBlock::LED_STD, ecaldqm::LinkError, ecaldqm::DQWorker::MEs_, EcalDCCHeaderBlock::MTCC, nEventTypes, ecaldqm::nFEFlags, EcalDCCHeaderBlock::PEDESTAL_25NS_SCAN, EcalDCCHeaderBlock::PEDESTAL_GAP, EcalDCCHeaderBlock::PEDESTAL_OFFSET_SCAN, EcalDCCHeaderBlock::PEDESTAL_STD, EcalDCCHeaderBlock::PHYSICS_GLOBAL, EcalDCCHeaderBlock::PHYSICS_LOCAL, ecaldqm::Suppressed, EcalDCCHeaderBlock::TESTPULSE_GAP, EcalDCCHeaderBlock::TESTPULSE_MGPA, EcalDCCHeaderBlock::TESTPULSE_SCAN_MEM, ecaldqm::Timeout, and ecaldqm::VParity.

  {
    DQWorker::bookMEs();

    if(hltTaskMode_ != 1){
      std::string eventTypes[nEventTypes];
      eventTypes[0] = "UNKNOWN";
      // From DataFormats/EcalRawData/interface/EcalDCCHeaderBlock.h; should move to reflex
      eventTypes[EcalDCCHeaderBlock::COSMIC + 1] = "COSMIC";
      eventTypes[EcalDCCHeaderBlock::BEAMH4 + 1] = "BEAMH4";
      eventTypes[EcalDCCHeaderBlock::BEAMH2 + 1] = "BEAMH2";
      eventTypes[EcalDCCHeaderBlock::MTCC + 1] = "MTCC";
      eventTypes[EcalDCCHeaderBlock::LASER_STD + 1] = "LASER_STD";
      eventTypes[EcalDCCHeaderBlock::LASER_POWER_SCAN + 1] = "LASER_POWER_SCAN";
      eventTypes[EcalDCCHeaderBlock::LASER_DELAY_SCAN + 1] = "LASER_DELAY_SCAN";
      eventTypes[EcalDCCHeaderBlock::TESTPULSE_SCAN_MEM + 1] = "TESTPULSE_SCAN_MEM";
      eventTypes[EcalDCCHeaderBlock::TESTPULSE_MGPA + 1] = "TESTPULSE_MGPA";
      eventTypes[EcalDCCHeaderBlock::PEDESTAL_STD + 1] = "PEDESTAL_STD";
      eventTypes[EcalDCCHeaderBlock::PEDESTAL_OFFSET_SCAN + 1] = "PEDESTAL_OFFSET_SCAN";
      eventTypes[EcalDCCHeaderBlock::PEDESTAL_25NS_SCAN + 1] = "PEDESTAL_25NS_SCAN";
      eventTypes[EcalDCCHeaderBlock::LED_STD + 1] = "LED_STD";
      eventTypes[EcalDCCHeaderBlock::PHYSICS_GLOBAL + 1] = "PHYSICS_GLOBAL";
      eventTypes[EcalDCCHeaderBlock::COSMICS_GLOBAL + 1] = "COSMICS_GLOBAL";
      eventTypes[EcalDCCHeaderBlock::HALO_GLOBAL + 1] = "HALO_GLOBAL";
      eventTypes[EcalDCCHeaderBlock::LASER_GAP + 1] = "LASER_GAP";
      eventTypes[EcalDCCHeaderBlock::TESTPULSE_GAP + 1] = "TESTPULSE_GAP";
      eventTypes[EcalDCCHeaderBlock::PEDESTAL_GAP + 1] = "PEDESTAL_GAP";
      eventTypes[EcalDCCHeaderBlock::LED_GAP + 1] = "LED_GAP";
      eventTypes[EcalDCCHeaderBlock::PHYSICS_LOCAL + 1] = "PHYSICS_LOCAL";
      eventTypes[EcalDCCHeaderBlock::COSMICS_LOCAL + 1] = "COSMICS_LOCAL";
      eventTypes[EcalDCCHeaderBlock::HALO_LOCAL + 1] = "HALO_LOCAL";
      eventTypes[EcalDCCHeaderBlock::CALIB_LOCAL + 1] = "CALIB_LOCAL";

      std::string statuses[nFEFlags];
      statuses[Enabled] = "ENABLED";
      statuses[Disabled] = "DISABLED";
      statuses[Timeout] = "TIMEOUT";
      statuses[HeaderError] = "HEADERERROR";
      statuses[ChannelId] = "CHANNELID";
      statuses[LinkError] = "LINKERROR";
      statuses[BlockSize] = "BLOCKSIZE";
      statuses[Suppressed] = "SUPPRESSED";
      statuses[FIFOFull] = "FIFOFULL";
      statuses[L1ADesync] = "L1ADESYNC";
      statuses[BXDesync] = "BXDESYNC";
      statuses[L1ABXDesync] = "L1ABXDESYNC";
      statuses[FIFOFullL1ADesync] = "FIFOFULLL1ADESYNC";
      statuses[HParity] = "HPARITY";
      statuses[VParity] = "VPARITY";
      statuses[ForcedZS] = "FORCEDZS";

      for(unsigned iME(kEventTypePreCalib); iME < kFEByLumi; iME++)
        MEs_[iME]->book();

      for(int i(1); i <= nEventTypes; i++){
        MEs_[kEventTypePreCalib]->setBinLabel(0, i, eventTypes[i - 1], 1);
        MEs_[kEventTypeCalib]->setBinLabel(0, i, eventTypes[i - 1], 1);
        MEs_[kEventTypePostCalib]->setBinLabel(0, i, eventTypes[i - 1], 1);
      }

      for(int i(1); i <= nFEFlags; i++)
        MEs_[kFEStatus]->setBinLabel(-1, i, statuses[i - 1], 2);
    }

    if(hltTaskMode_ != 0){
      MEs_[kFEDEntries]->book();
      MEs_[kFEDFatal]->book();
    }
  }

void ecaldqm::RawDataTask::runOnRawData ( const EcalRawDataCollection _dcchs,
Collections   
)

Definition at line 167 of file RawDataTask.cc.

References asciidump::at, edm::SortedCollection< T, SORT >::begin(), ecaldqm::BlockSize, bx_, ecaldqm::BXDesync, ecaldqm::ccuExists(), ecaldqm::ChannelId, ecaldqm::dccId(), edm::SortedCollection< T, SORT >::end(), feL1Offset_, lumiContext::fill, ecaldqm::getElectronicsMap(), ecaldqm::HeaderError, hltTaskMode_, ecaldqm::HParity, kBXDCC, kBXFE, kBXSRP, kBXTCC, kDesyncByLumi, kDesyncTotal, ecaldqm::kEEpLow, kEventTypeCalib, kEventTypePostCalib, kEventTypePreCalib, kFEByLumi, kFEStatus, kL1ADCC, kL1AFE, kL1ASRP, kL1ATCC, kOrbit, kRunNumber, kTriggerType, l1A_, ecaldqm::L1ABXDesync, ecaldqm::L1ADesync, ecaldqm::LinkError, ecaldqm::DQWorker::MEs_, orbit_, run_, environment_file_cff::runType, ntuplemaker::status, ecaldqm::Timeout, triggerType_, and ecaldqm::VParity.

Referenced by analyze().

  {
    using namespace std;

    if(hltTaskMode_ == 1) return;

    if(!l1A_){
      // majority vote on L1A.. is there no better implementation?
      map<int, int> l1aCounts;
      for(EcalRawDataCollection::const_iterator dcchItr(_dcchs.begin()); dcchItr != _dcchs.end(); ++dcchItr){
        l1aCounts[dcchItr->getLV1()]++;
      }
      int maxVote(0);
      for(map<int, int>::iterator l1aItr(l1aCounts.begin()); l1aItr != l1aCounts.end(); ++l1aItr){
        if(l1aItr->second > maxVote){
          maxVote = l1aItr->second;
          l1A_ = l1aItr->first;
        }
      }
    }

    for(EcalRawDataCollection::const_iterator dcchItr(_dcchs.begin()); dcchItr != _dcchs.end(); ++dcchItr){
      unsigned dccId(dcchItr->id());

      int dccL1A(dcchItr->getLV1());
      short dccL1AShort(dccL1A & 0xfff);
      int dccBX(dcchItr->getBX());

      if(dcchItr->getRunNumber() != run_) MEs_[kRunNumber]->fill(dccId);
      if(dcchItr->getOrbit() != orbit_) MEs_[kOrbit]->fill(dccId);
      if(dcchItr->getBasicTriggerType() != triggerType_) MEs_[kTriggerType]->fill(dccId);
      if(dccL1A != l1A_) MEs_[kL1ADCC]->fill(dccId);
      if(dccBX != bx_) MEs_[kBXDCC]->fill(dccId);

      const vector<short> &feStatus(dcchItr->getFEStatus());
      const vector<short> &feBxs(dcchItr->getFEBxs());
      const vector<short> &feL1s(dcchItr->getFELv1());

      bool feDesync(false);
      bool statusError(false);

      for(unsigned iFE(0); iFE < feStatus.size(); iFE++){
        if(!ccuExists(dccId, iFE + 1)) continue;

        short status(feStatus[iFE]);

        if(status != BXDesync && status != L1ABXDesync){ // BX desync not detected in the DCC
          if(feBxs[iFE] != dccBX && feBxs[iFE] != -1 && dccBX != -1){
            MEs_[kBXFE]->fill(dccId);
            feDesync = true;
          }
        }

        if(status != L1ADesync && status != L1ABXDesync){
          if(feL1s[iFE] + feL1Offset_ != dccL1AShort && feL1s[iFE] != -1 && dccL1AShort != 0){
            MEs_[kL1AFE]->fill(dccId);
            feDesync = true;
          }
        }

        if(iFE >= 68) continue;

        DetId id(getElectronicsMap()->dccTowerConstituents(dccId, iFE + 1).at(0));
        MEs_[kFEStatus]->fill(id, status + 0.5);

        switch(status){
        case Timeout:
        case HeaderError:
        case ChannelId:
        case LinkError:
        case BlockSize:
        case L1ADesync:
        case BXDesync:
        case L1ABXDesync:
        case HParity:
        case VParity:
          statusError = true;
          break;
        default:
          continue;
        }
      }

      if(feDesync) MEs_[kDesyncByLumi]->fill(dccId);
      if(feDesync) MEs_[kDesyncTotal]->fill(dccId);
      if(statusError) MEs_[kFEByLumi]->fill(dccId);

      const vector<short> &tccBx(dcchItr->getTCCBx());
      const vector<short> &tccL1(dcchItr->getTCCLv1());

      if(tccBx.size() == 4){ // EB uses tccBx[0]; EE uses all
        if(dccId <= kEEmHigh + 1 || dccId >= kEEpLow + 1){
          for(int iTCC(0); iTCC < 4; iTCC++){

            if(tccBx[iTCC] != dccBX && tccBx[iTCC] != -1 && dccBX != -1)
              MEs_[kBXTCC]->fill(dccId);

            if(tccL1[iTCC] != dccL1AShort && tccL1[iTCC] != -1 && dccL1AShort != 0)
              MEs_[kL1ATCC]->fill(dccId);

          }
        }else{

          if(tccBx[0] != dccBX && tccBx[0] != -1 && dccBX != -1)
            MEs_[kBXTCC]->fill(dccId);

          if(tccL1[0] != dccL1AShort && tccL1[0] != -1 && dccL1AShort != 0)
            MEs_[kL1ATCC]->fill(dccId);

        }
      }

      short srpBx(dcchItr->getSRPBx());
      short srpL1(dcchItr->getSRPLv1());

      if(srpBx != dccBX && srpBx != -1 && dccBX != -1)
        MEs_[kBXSRP]->fill(dccId);

      if(srpL1 != dccL1AShort && srpL1 != -1 && dccL1AShort != 0)
        MEs_[kL1ASRP]->fill(dccId);

      const int calibBX(3490);

      short runType(dcchItr->getRunType() + 1);
      if(runType < 0 || runType > 22) runType = 0;
      if(dccBX < calibBX) MEs_[kEventTypePreCalib]->fill(dccId, runType + 0.5, 1. / 54.);
      else if(dccBX == calibBX) MEs_[kEventTypeCalib]->fill(dccId, runType + 0.5, 1. / 54.);
      else MEs_[kEventTypePostCalib]->fill(dccId, runType + 0.5, 1. / 54.);

    }
  }

void ecaldqm::RawDataTask::runOnSource ( const FEDRawDataCollection _fedRaw,
Collections   
)

Definition at line 142 of file RawDataTask.cc.

References FEDRawDataCollection::FEDData(), kCRC, kFEDEntries, kFEDFatal, l1A_, and ecaldqm::DQWorker::MEs_.

Referenced by analyze().

  {
    // Get GT L1 info
    const FEDRawData &gtFED(_fedRaw.FEDData(812));
    if(gtFED.size() > sizeof(uint64_t)){ // FED header is one 64 bit word
      uint32_t *halfHeader((uint32_t *)gtFED.data());
      l1A_ = *(halfHeader + 1) & 0xffffff;
    }

    for(unsigned iFED(601); iFED <= 654; iFED++){
      const FEDRawData& fedData(_fedRaw.FEDData(iFED));
      unsigned length(fedData.size() / sizeof(uint64_t));
      if(length > 1){ // FED header is one 64 bit word
        if(MEs_[kFEDEntries]->isActive()) MEs_[kFEDEntries]->fill(iFED - 600);

        const uint64_t* pData(reinterpret_cast<const uint64_t*>(fedData.data()));
        bool crcError((pData[length - 1] >> 2) & 0x1);

        if(crcError && MEs_[kFEDFatal]->isActive()) MEs_[kFEDFatal]->fill(iFED - 600);
        if(crcError && MEs_[kCRC]->isActive()) MEs_[kCRC]->fill(iFED - 600);
      }
    }
  }
  
void ecaldqm::RawDataTask::setMEData ( std::vector< MEData > &  _data) [static]

Reimplemented from ecaldqm::DQWorker.

Definition at line 301 of file RawDataTask.cc.

References MonitorElement::DQM_KIND_TH1F, MonitorElement::DQM_KIND_TH2F, EcalDQMBinningService::AxisSpecs::high, kBXDCC, kBXFE, kBXSRP, kBXTCC, kCRC, EcalDQMBinningService::kDCC, kDesyncByLumi, kDesyncTotal, EcalDQMBinningService::kEcal, EcalDQMBinningService::kEcal2P, kEventTypeCalib, kEventTypePostCalib, kEventTypePreCalib, kFEByLumi, kFEDEntries, kFEDFatal, kFEStatus, kL1ADCC, kL1AFE, kL1ASRP, kL1ATCC, kOrbit, kRunNumber, EcalDQMBinningService::kSM, EcalDQMBinningService::kSuperCrystal, kTriggerType, EcalDQMBinningService::kUser, EcalDQMBinningService::AxisSpecs::low, EcalDQMBinningService::AxisSpecs::nbins, nEventTypes, and ecaldqm::nFEFlags.

  {
    BinService::AxisSpecs eventTypeAxis;
    eventTypeAxis.nbins = nEventTypes;
    eventTypeAxis.low = 0.;
    eventTypeAxis.high = nEventTypes;

    BinService::AxisSpecs feStatusAxis;
    feStatusAxis.nbins = nFEFlags;
    feStatusAxis.low = 0.;
    feStatusAxis.high = nFEFlags;

    _data[kEventTypePreCalib] = MEData("EventTypePreCalib", BinService::kEcal, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &eventTypeAxis);
    _data[kEventTypeCalib] = MEData("EventTypeCalib", BinService::kEcal, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &eventTypeAxis);
    _data[kEventTypePostCalib] = MEData("EventTypePostCalib", BinService::kEcal, BinService::kUser, MonitorElement::DQM_KIND_TH1F, &eventTypeAxis);
    _data[kCRC] = MEData("CRC", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kRunNumber] = MEData("RunNumber", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kOrbit] = MEData("Orbit", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kTriggerType] = MEData("TriggerType", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kL1ADCC] = MEData("L1ADCC", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kL1AFE] = MEData("L1AFE", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kL1ATCC] = MEData("L1ATCC", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kL1ASRP] = MEData("L1ASRP", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kBXDCC] = MEData("BXDCC", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kBXFE] = MEData("BXFE", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kBXTCC] = MEData("BXTCC", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kBXSRP] = MEData("BXSRP", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kDesyncByLumi] = MEData("DesyncByLumi", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kDesyncTotal] = MEData("DesyncTotal", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kFEStatus] = MEData("FEStatus", BinService::kSM, BinService::kSuperCrystal, MonitorElement::DQM_KIND_TH2F, 0, &feStatusAxis);
    _data[kFEByLumi] = MEData("FEByLumi", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kFEDEntries] = MEData("FEDEntries", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
    _data[kFEDFatal] = MEData("FEDFatal", BinService::kEcal2P, BinService::kDCC, MonitorElement::DQM_KIND_TH1F);
  }


Member Data Documentation

Definition at line 64 of file RawDataTask.h.

Referenced by beginEvent(), and runOnRawData().

Definition at line 66 of file RawDataTask.h.

Referenced by beginEvent(), and runOnRawData().

std::string ecaldqm::RawDataTask::hltTaskFolder_ [private]

Definition at line 60 of file RawDataTask.h.

Definition at line 59 of file RawDataTask.h.

Referenced by bookMEs(), and runOnRawData().

Definition at line 62 of file RawDataTask.h.

Referenced by beginEvent(), runOnRawData(), and runOnSource().

Definition at line 63 of file RawDataTask.h.

Referenced by beginEvent(), and runOnRawData().

Definition at line 61 of file RawDataTask.h.

Referenced by beginEvent(), and runOnRawData().

Definition at line 65 of file RawDataTask.h.

Referenced by beginEvent(), and runOnRawData().