df/d7b/TimingClient_8cc_source.html

#include "DQM/EcalMonitorClient/interface/TimingClient.h"


#include "DQM/EcalCommon/interface/EcalDQMCommonUtils.h"


#include "CondFormats/EcalObjects/interface/EcalDQMStatusHelper.h"

#include "CondFormats/EcalObjects/interface/EcalChannelStatusCode.h"


#include "FWCore/ParameterSet/interface/ParameterSet.h"


#include <cmath>


namespace ecaldqm {

  TimingClient::TimingClient()

      : DQWorkerClient(),

        toleranceMean_(0.),

        toleranceMeanFwd_(0.),

        toleranceRMS_(0.),

        toleranceRMSFwd_(0.),

        minChannelEntries_(0),

        minChannelEntriesFwd_(0),

        minTowerEntries_(0),

        minTowerEntriesFwd_(0),

        tailPopulThreshold_(0.) {

    qualitySummaries_.insert("Quality");

    qualitySummaries_.insert("QualitySummary");

  }


  void TimingClient::setParams(edm::ParameterSet const& _params) {

    toleranceMean_ = _params.getUntrackedParameter<double>("toleranceMean");

    toleranceMeanFwd_ = _params.getUntrackedParameter<double>("toleranceMeanFwd");

    toleranceRMS_ = _params.getUntrackedParameter<double>("toleranceRMS");

    toleranceRMSFwd_ = _params.getUntrackedParameter<double>("toleranceRMSFwd");

    minChannelEntries_ = _params.getUntrackedParameter<int>("minChannelEntries");

    minChannelEntriesFwd_ = _params.getUntrackedParameter<int>("minChannelEntriesFwd");

    minTowerEntries_ = _params.getUntrackedParameter<int>("minTowerEntries");

    minTowerEntriesFwd_ = _params.getUntrackedParameter<int>("minChannelEntriesFwd");

    tailPopulThreshold_ = _params.getUntrackedParameter<double>("tailPopulThreshold");

  }


  void TimingClient::producePlots(ProcessType) {

    MESet& meQuality(MEs_.at("Quality"));

    MESet& meMeanSM(MEs_.at("MeanSM"));

    MESet& meMeanAll(MEs_.at("MeanAll"));

    MESet& meFwdBkwdDiff(MEs_.at("FwdBkwdDiff"));

    MESet& meFwdvBkwd(MEs_.at("FwdvBkwd"));

    MESet& meRMSMap(MEs_.at("RMSMap"));

    MESet& meRMSAll(MEs_.at("RMSAll"));

    MESet& meProjEta(MEs_.at("ProjEta"));

    MESet& meProjPhi(MEs_.at("ProjPhi"));

    MESet& meQualitySummary(MEs_.at("QualitySummary"));


    MESet const& sTimeAllMap(sources_.at("TimeAllMap"));

    MESet const& sTimeMap(sources_.at("TimeMap"));

    MESet const& sTimeMapByLS(sources_.at("TimeMapByLS"));

    MESet const& sChStatus(sources_.at("ChStatus"));


    uint32_t mask(1 << EcalDQMStatusHelper::PHYSICS_BAD_CHANNEL_WARNING);


    MESet::iterator qEnd(meQuality.end(GetElectronicsMap()));


    MESet::iterator rItr(GetElectronicsMap(), meRMSMap);

    MESet::const_iterator tItr(GetElectronicsMap(), sTimeMap);

    MESet::const_iterator tLSItr(GetElectronicsMap(), sTimeMapByLS);


    float EBentries(0.), EEentries(0.);

    float EBmean(0.), EEmean(0.);

    float EBrms(0.), EErms(0.);

    for (MESet::iterator qItr(meQuality.beginChannel(GetElectronicsMap())); qItr != qEnd;

         qItr.toNextChannel(GetElectronicsMap())) {

      tItr = qItr;

      rItr = qItr;


      DetId id(qItr->getId());


      int minChannelEntries(minChannelEntries_);

      float meanThresh(toleranceMean_);

      float rmsThresh(toleranceRMS_);


      if (isForward(id)) {

        minChannelEntries = minChannelEntriesFwd_;

        meanThresh = toleranceMeanFwd_;

        rmsThresh = toleranceRMSFwd_;

      }


      bool doMask(meQuality.maskMatches(id, mask, statusManager_, GetTrigTowerMap()));


      float entries(tItr->getBinEntries());


      if (entries < minChannelEntries) {

        qItr->setBinContent(doMask ? kMUnknown : kUnknown);

        rItr->setBinContent(-1.);

        continue;

      }


      float mean(tItr->getBinContent());

      float rms(tItr->getBinError() * sqrt(entries));


      meMeanSM.fill(getEcalDQMSetupObjects(), id, mean);

      meMeanAll.fill(getEcalDQMSetupObjects(), id, mean);

      meProjEta.fill(getEcalDQMSetupObjects(), id, mean);

      meProjPhi.fill(getEcalDQMSetupObjects(), id, mean);

      meRMSAll.fill(getEcalDQMSetupObjects(), id, rms);

      rItr->setBinContent(rms);


      bool negative(false);

      float posTime(0.);


      if (id.subdetId() == EcalBarrel) {

        EBDetId ebid(id);

        if (ebid.zside() < 0) {

          negative = true;

          EBDetId posId(EBDetId::switchZSide(ebid));

          posTime = sTimeMap.getBinContent(getEcalDQMSetupObjects(), posId);

        }

      } else {

        EEDetId eeid(id);

        if (eeid.zside() < 0) {

          negative = true;

          EEDetId posId(EEDetId::switchZSide(eeid));

          posTime = sTimeMap.getBinContent(getEcalDQMSetupObjects(), posId);

        }

      }

      if (negative) {

        meFwdBkwdDiff.fill(getEcalDQMSetupObjects(), id, posTime - mean);

        meFwdvBkwd.fill(getEcalDQMSetupObjects(), id, mean, posTime);

      }


      if (std::abs(mean) > meanThresh || rms > rmsThresh)

        qItr->setBinContent(doMask ? kMBad : kBad);

      else

        qItr->setBinContent(doMask ? kMGood : kGood);


      // For Trend plots:

      tLSItr = qItr;

      float entriesLS(tLSItr->getBinEntries());

      float meanLS(tLSItr->getBinContent());

      float rmsLS(tLSItr->getBinError() * sqrt(entriesLS));

      float chStatus(sChStatus.getBinContent(getEcalDQMSetupObjects(), id));


      if (entriesLS < minChannelEntries)

        continue;

      if (chStatus != EcalChannelStatusCode::kOk)

        continue;  // exclude problematic channels


      // Keep running count of timing mean, rms, and N_hits

      if (id.subdetId() == EcalBarrel) {

        EBmean += meanLS;

        EBrms += rmsLS;

        EBentries += entriesLS;

      } else {

        EEmean += meanLS;

        EErms += rmsLS;

        EEentries += entriesLS;

      }


    }  // channel loop


    // Fill Timing Trend plots at each LS

    MESet& meTrendMean(MEs_.at("TrendMean"));

    MESet& meTrendRMS(MEs_.at("TrendRMS"));

    if (EBentries > 0.) {

      if (std::abs(EBmean) > 0.)

        meTrendMean.fill(getEcalDQMSetupObjects(), EcalBarrel, double(timestamp_.iLumi), EBmean / EBentries);

      if (std::abs(EBrms) > 0.)

        meTrendRMS.fill(getEcalDQMSetupObjects(), EcalBarrel, double(timestamp_.iLumi), EBrms / EBentries);

    }

    if (EEentries > 0.) {

      if (std::abs(EEmean) > 0.)

        meTrendMean.fill(getEcalDQMSetupObjects(), EcalEndcap, double(timestamp_.iLumi), EEmean / EEentries);

      if (std::abs(EErms) > 0.)

        meTrendRMS.fill(getEcalDQMSetupObjects(), EcalEndcap, double(timestamp_.iLumi), EErms / EEentries);

    }


    MESet::iterator qsEnd(meQualitySummary.end(GetElectronicsMap()));


    for (MESet::iterator qsItr(meQualitySummary.beginChannel(GetElectronicsMap())); qsItr != qsEnd;

         qsItr.toNextChannel(GetElectronicsMap())) {

      DetId tId(qsItr->getId());


      std::vector<DetId> ids;


      if (tId.subdetId() == EcalTriggerTower)

        ids = GetTrigTowerMap()->constituentsOf(EcalTrigTowerDetId(tId));

      else

        ids = scConstituents(EcalScDetId(tId));


      int minTowerEntries(minTowerEntries_);

      float meanThresh(toleranceMean_);

      float rmsThresh(toleranceRMS_);


      if (isForward(tId)) {

        minTowerEntries = minTowerEntriesFwd_;

        meanThresh = toleranceMeanFwd_;

        rmsThresh = toleranceRMSFwd_;

      }


      // tower entries != sum(channel entries) because of the difference in timing cut at the source

      float summaryEntries(sTimeAllMap.getBinEntries(getEcalDQMSetupObjects(), tId));


      float towerEntries(0.);

      float towerMean(0.);

      float towerMean2(0.);


      bool doMask(false);


      for (std::vector<DetId>::iterator idItr(ids.begin()); idItr != ids.end(); ++idItr) {

        DetId& id(*idItr);


        doMask |= meQuality.maskMatches(id, mask, statusManager_, GetTrigTowerMap());


        MESet::const_iterator tmItr(GetElectronicsMap(), sTimeMap, id);


        float entries(tmItr->getBinEntries());

        if (entries < 0.)

          continue;

        towerEntries += entries;

        float mean(tmItr->getBinContent());

        towerMean += mean * entries;

        float rms(tmItr->getBinError() * sqrt(entries));

        towerMean2 += (rms * rms + mean * mean) * entries;

      }


      double quality(doMask ? kMUnknown : kUnknown);

      if (towerEntries / ids.size() > minTowerEntries / 25.) {

        if (summaryEntries < towerEntries * (1. - tailPopulThreshold_))  // large timing deviation

          quality = doMask ? kMBad : kBad;

        else {

          towerMean /= towerEntries;

          towerMean2 /= towerEntries;


          float towerRMS(sqrt(towerMean2 - towerMean * towerMean));


          if (std::abs(towerMean) > meanThresh || towerRMS > rmsThresh)

            quality = doMask ? kMBad : kBad;

          else

            quality = doMask ? kMGood : kGood;

        }

      }

      qsItr->setBinContent(quality);

    }

  }


  DEFINE_ECALDQM_WORKER(TimingClient);

}  // namespace ecaldqm