TrackingMonitor.cc

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/*
 *  See header file for a description of this class.
 **
 *  \author Suchandra Dutta , Giorgia Mila
 */

#include "DataFormats/TrackReco/interface/Track.h"
#include "DataFormats/TrackReco/interface/TrackFwd.h"
#include "TrackingTools/TransientTrack/interface/TransientTrackBuilder.h"
#include "TrackingTools/Records/interface/TransientTrackRecord.h"
#include "TrackingTools/TransientTrack/interface/TransientTrack.h"

#include "FWCore/MessageLogger/interface/MessageLogger.h"
#include "FWCore/Utilities/interface/InputTag.h"
#include "FWCore/Utilities/interface/transform.h"
#include "DQMServices/Core/interface/DQMStore.h"
#include "DQM/TrackingMonitor/interface/TrackBuildingAnalyzer.h"
#include "DQM/TrackingMonitor/interface/TrackAnalyzer.h"
#include "DQM/TrackingMonitor/interface/VertexMonitor.h"
#include "DQM/TrackingMonitor/interface/TrackingMonitor.h"

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

#include "TrackingTools/TrajectoryState/interface/TrajectoryStateTransform.h"
#include "TrackingTools/PatternTools/interface/TSCBLBuilderNoMaterial.h"
#include "TrackingTools/PatternTools/interface/TSCPBuilderNoMaterial.h"
#include "DataFormats/BeamSpot/interface/BeamSpot.h"
#include "CommonTools/TriggerUtils/interface/GenericTriggerEventFlag.h"
#include "DataFormats/Common/interface/DetSetVectorNew.h"

#include "DataFormats/Candidate/interface/Candidate.h"
#include "DataFormats/Candidate/interface/CandidateFwd.h"

#include "DQM/TrackingMonitor/interface/GetLumi.h"

#include <string>

#ifdef VI_DEBUG
#define COUT(x) std::cout << x << ' '
#else
#define COUT(x) LogDebug(x)
#endif

// TrackingMonitor
// ----------------------------------------------------------------------------------//

TrackingMonitor::TrackingMonitor(const edm::ParameterSet& iConfig)
    : confID_(iConfig.id()),
      theTrackBuildingAnalyzer(new TrackBuildingAnalyzer(iConfig)),
      NumberOfTracks(nullptr),
      NumberOfMeanRecHitsPerTrack(nullptr),
      NumberOfMeanLayersPerTrack(nullptr)
      //    , NumberOfGoodTracks(NULL)
      ,
      FractionOfGoodTracks(nullptr),
      NumberOfTrackingRegions(nullptr),
      NumberOfSeeds(nullptr),
      NumberOfSeeds_lumiFlag(nullptr),
      NumberOfTrackCandidates(nullptr),
      FractionCandidatesOverSeeds(nullptr)
      //    , NumberOfGoodTrkVsClus(NULL)
      ,
      NumberEventsOfVsLS(nullptr),
      NumberOfTracksVsLS(nullptr)
      //    , NumberOfGoodTracksVsLS(NULL)
      ,
      GoodTracksFractionVsLS(nullptr)
      //    , GoodTracksNumberOfRecHitsPerTrackVsLS(NULL)
      // ADD by Mia for PU monitoring
      // vertex plots to be moved in ad hoc class
      ,
      NumberOfGoodPVtxVsLS(nullptr),
      NumberOfGoodPVtxWO0VsLS(nullptr),
      NumberEventsOfVsBX(nullptr),
      NumberOfTracksVsBX(nullptr),
      GoodTracksFractionVsBX(nullptr),
      NumberOfRecHitsPerTrackVsBX(nullptr),
      NumberOfGoodPVtxVsBX(nullptr),
      NumberOfGoodPVtxWO0VsBX(nullptr),
      NumberOfTracksVsBXlumi(nullptr),
      NumberOfTracksVsGoodPVtx(nullptr),
      NumberOfTracksVsPUPVtx(nullptr),
      NumberEventsOfVsGoodPVtx(nullptr),
      GoodTracksFractionVsGoodPVtx(nullptr),
      NumberOfRecHitsPerTrackVsGoodPVtx(nullptr),
      NumberOfPVtxVsGoodPVtx(nullptr),
      NumberOfPixelClustersVsGoodPVtx(nullptr),
      NumberOfStripClustersVsGoodPVtx(nullptr),
      NumberEventsOfVsLUMI(nullptr),
      NumberOfTracksVsLUMI(nullptr),
      GoodTracksFractionVsLUMI(nullptr),
      NumberOfRecHitsPerTrackVsLUMI(nullptr),
      NumberOfGoodPVtxVsLUMI(nullptr),
      NumberOfGoodPVtxWO0VsLUMI(nullptr),
      NumberOfPixelClustersVsLUMI(nullptr),
      NumberOfStripClustersVsLUMI(nullptr),
      NumberOfTracks_lumiFlag(nullptr)
      //    , NumberOfGoodTracks_lumiFlag(NULL)

      ,
      builderName(iConfig.getParameter<std::string>("TTRHBuilder")),
      doTrackerSpecific_(iConfig.getParameter<bool>("doTrackerSpecific")),
      doLumiAnalysis(iConfig.getParameter<bool>("doLumiAnalysis")),
      doProfilesVsLS_(iConfig.getParameter<bool>("doProfilesVsLS")),
      doAllSeedPlots(iConfig.getParameter<bool>("doSeedParameterHistos")),
      doAllPlots(iConfig.getParameter<bool>("doAllPlots")),
      doGeneralPropertiesPlots_(iConfig.getParameter<bool>("doGeneralPropertiesPlots")),
      doHitPropertiesPlots_(iConfig.getParameter<bool>("doHitPropertiesPlots")),
      doTkCandPlots(iConfig.getParameter<bool>("doTrackCandHistos")),
      doPUmonitoring_(iConfig.getParameter<bool>("doPUmonitoring")),
      genTriggerEventFlag_(new GenericTriggerEventFlag(
          iConfig.getParameter<edm::ParameterSet>("genericTriggerEventPSet"), consumesCollector(), *this)),
      numSelection_(iConfig.getParameter<std::string>("numCut")),
      denSelection_(iConfig.getParameter<std::string>("denCut")),
      pvNDOF_(iConfig.getParameter<int>("pvNDOF")),
      forceSCAL_(iConfig.getParameter<bool>("forceSCAL")) {
  edm::ConsumesCollector c{consumesCollector()};
  theTrackAnalyzer = new tadqm::TrackAnalyzer(iConfig, c);

  // input tags for collections from the configuration
  bsSrc_ = iConfig.getParameter<edm::InputTag>("beamSpot");
  pvSrc_ = iConfig.getParameter<edm::InputTag>("primaryVertex");
  bsSrcToken_ = consumes<reco::BeamSpot>(bsSrc_);
  pvSrcToken_ = mayConsume<reco::VertexCollection>(pvSrc_);

  lumiscalersToken_ = consumes<LumiScalersCollection>(iConfig.getParameter<edm::InputTag>("scal"));
  metaDataToken_ = consumes<OnlineLuminosityRecord>(iConfig.getParameter<edm::InputTag>("metadata"));

  edm::InputTag alltrackProducer = iConfig.getParameter<edm::InputTag>("allTrackProducer");
  edm::InputTag trackProducer = iConfig.getParameter<edm::InputTag>("TrackProducer");
  edm::InputTag tcProducer = iConfig.getParameter<edm::InputTag>("TCProducer");
  edm::InputTag seedProducer = iConfig.getParameter<edm::InputTag>("SeedProducer");
  allTrackToken_ = consumes<edm::View<reco::Track> >(alltrackProducer);
  trackToken_ = consumes<edm::View<reco::Track> >(trackProducer);
  trackCandidateToken_ = consumes<TrackCandidateCollection>(tcProducer);
  seedToken_ = consumes<edm::View<TrajectorySeed> >(seedProducer);
  seedStopInfoToken_ = consumes<std::vector<SeedStopInfo> >(tcProducer);

  doMVAPlots = iConfig.getParameter<bool>("doMVAPlots");
  if (doMVAPlots) {
    mvaQualityTokens_ = edm::vector_transform(
        iConfig.getParameter<std::vector<std::string> >("MVAProducers"), [&](const std::string& tag) {
          return std::make_tuple(consumes<MVACollection>(edm::InputTag(tag, "MVAValues")),
                                 consumes<QualityMaskCollection>(edm::InputTag(tag, "QualityMasks")));
        });
    mvaTrackToken_ = consumes<edm::View<reco::Track> >(iConfig.getParameter<edm::InputTag>("TrackProducerForMVA"));
  }

  doRegionPlots = iConfig.getParameter<bool>("doRegionPlots");
  doRegionCandidatePlots = iConfig.getParameter<bool>("doRegionCandidatePlots");
  if (doRegionPlots) {
    const auto& regionTag = iConfig.getParameter<edm::InputTag>("RegionProducer");
    if (!regionTag.label().empty()) {
      regionToken_ = consumes<edm::OwnVector<TrackingRegion> >(regionTag);
    }
    const auto& regionLayersTag = iConfig.getParameter<edm::InputTag>("RegionSeedingLayersProducer");
    if (!regionLayersTag.label().empty()) {
      if (!regionToken_.isUninitialized()) {
        throw cms::Exception("Configuration")
            << "Only one of 'RegionProducer' and 'RegionSeedingLayersProducer' can be non-empty, now both are.";
      }
      regionLayerSetsToken_ = consumes<TrackingRegionsSeedingLayerSets>(regionLayersTag);
    } else if (regionToken_.isUninitialized()) {
      throw cms::Exception("Configuration") << "With doRegionPlots=True either 'RegionProducer' or "
                                               "'RegionSeedingLayersProducer' must be non-empty, now both are empty.";
    }

    if (doRegionCandidatePlots) {
      regionCandidateToken_ = consumes<reco::CandidateView>(iConfig.getParameter<edm::InputTag>("RegionCandidates"));
    }
  }

  edm::InputTag stripClusterInputTag_ = iConfig.getParameter<edm::InputTag>("stripCluster");
  edm::InputTag pixelClusterInputTag_ = iConfig.getParameter<edm::InputTag>("pixelCluster");
  stripClustersToken_ = mayConsume<edmNew::DetSetVector<SiStripCluster> >(stripClusterInputTag_);
  pixelClustersToken_ = mayConsume<edmNew::DetSetVector<SiPixelCluster> >(pixelClusterInputTag_);

  runTrackBuildingAnalyzerForSeed =
      (doAllSeedPlots || iConfig.getParameter<bool>("doSeedPTHisto") || iConfig.getParameter<bool>("doSeedETAHisto") ||
       iConfig.getParameter<bool>("doSeedPHIHisto") || iConfig.getParameter<bool>("doSeedPHIVsETAHisto") ||
       iConfig.getParameter<bool>("doSeedThetaHisto") || iConfig.getParameter<bool>("doSeedQHisto") ||
       iConfig.getParameter<bool>("doSeedDxyHisto") || iConfig.getParameter<bool>("doSeedDzHisto") ||
       iConfig.getParameter<bool>("doSeedNRecHitsHisto") || iConfig.getParameter<bool>("doSeedNVsPhiProf") ||
       iConfig.getParameter<bool>("doSeedNVsEtaProf"));

  if (doTkCandPlots || doAllSeedPlots || runTrackBuildingAnalyzerForSeed) {
    magneticFieldToken_ = esConsumes<MagneticField, IdealMagneticFieldRecord>();
    transientTrackingRecHitBuilderToken_ =
        esConsumes<TransientTrackingRecHitBuilder, TransientRecHitRecord>(edm::ESInputTag("", builderName));
  }

  doFractionPlot_ = true;
  if (alltrackProducer.label() == trackProducer.label())
    doFractionPlot_ = false;

  Quality_ = iConfig.getParameter<std::string>("Quality");
  AlgoName_ = iConfig.getParameter<std::string>("AlgoName");

  // get flag from the configuration
  doPlotsVsBXlumi_ = iConfig.getParameter<bool>("doPlotsVsBXlumi");
  if (doPlotsVsBXlumi_)
    theLumiDetails_ = new GetLumi(iConfig.getParameter<edm::ParameterSet>("BXlumiSetup"), c);
  doPlotsVsGoodPVtx_ = iConfig.getParameter<bool>("doPlotsVsGoodPVtx");
  doPlotsVsLUMI_ = iConfig.getParameter<bool>("doPlotsVsLUMI");
  doPlotsVsBX_ = iConfig.getParameter<bool>("doPlotsVsBX");

  if (doPUmonitoring_) {
    std::vector<edm::InputTag> primaryVertexInputTags =
        iConfig.getParameter<std::vector<edm::InputTag> >("primaryVertexInputTags");
    std::vector<edm::InputTag> selPrimaryVertexInputTags =
        iConfig.getParameter<std::vector<edm::InputTag> >("selPrimaryVertexInputTags");
    std::vector<std::string> pvLabels = iConfig.getParameter<std::vector<std::string> >("pvLabels");

    if (primaryVertexInputTags.size() == pvLabels.size() and
        primaryVertexInputTags.size() == selPrimaryVertexInputTags.size()) {
      for (size_t i = 0; i < primaryVertexInputTags.size(); i++) {
        edm::InputTag iPVinputTag = primaryVertexInputTags[i];
        edm::InputTag iSelPVinputTag = selPrimaryVertexInputTags[i];
        std::string iPVlabel = pvLabels[i];

        theVertexMonitor.push_back(new VertexMonitor(iConfig, iPVinputTag, iSelPVinputTag, iPVlabel, c));
      }
    }
  }
}

TrackingMonitor::~TrackingMonitor() {
  if (theTrackAnalyzer)
    delete theTrackAnalyzer;
  if (theTrackBuildingAnalyzer)
    delete theTrackBuildingAnalyzer;
  if (doPUmonitoring_)
    for (size_t i = 0; i < theVertexMonitor.size(); i++)
      if (theVertexMonitor[i])
        delete theVertexMonitor[i];
  if (genTriggerEventFlag_)
    delete genTriggerEventFlag_;
}

void TrackingMonitor::bookHistograms(DQMStore::IBooker& ibooker, edm::Run const& iRun, edm::EventSetup const& iSetup) {
  // parameters from the configuration
  auto const* conf = edm::pset::Registry::instance()->getMapped(confID_);
  assert(conf != nullptr);
  std::string Quality = conf->getParameter<std::string>("Quality");
  std::string AlgoName = conf->getParameter<std::string>("AlgoName");
  MEFolderName = conf->getParameter<std::string>("FolderName");
  std::string Folder = MEFolderName.substr(0, 2);

  // test for the Quality veriable validity
  if (!Quality_.empty()) {
    if (Quality_ != "highPurity" && Quality_ != "tight" && Quality_ != "loose") {
      edm::LogWarning("TrackingMonitor") << "Qualty Name is invalid, using no quality criterea by default";
      Quality_ = "";
    }
  }

  // use the AlgoName and Quality Name
  std::string CategoryName = !Quality_.empty() ? AlgoName_ + "_" + Quality_ : AlgoName_;

  // get binning from the configuration
  int TKNoBin = conf->getParameter<int>("TkSizeBin");
  double TKNoMin = conf->getParameter<double>("TkSizeMin");
  double TKNoMax = conf->getParameter<double>("TkSizeMax");

  int TCNoBin = conf->getParameter<int>("TCSizeBin");
  double TCNoMin = conf->getParameter<double>("TCSizeMin");
  double TCNoMax = conf->getParameter<double>("TCSizeMax");

  int TKNoSeedBin = conf->getParameter<int>("TkSeedSizeBin");
  double TKNoSeedMin = conf->getParameter<double>("TkSeedSizeMin");
  double TKNoSeedMax = conf->getParameter<double>("TkSeedSizeMax");

  //int RecHitBin = conf->getParameter<int>("RecHitBin");
  double RecHitMin = conf->getParameter<double>("RecHitMin");
  double RecHitMax = conf->getParameter<double>("RecHitMax");

  int MeanHitBin = conf->getParameter<int>("MeanHitBin");
  double MeanHitMin = conf->getParameter<double>("MeanHitMin");
  double MeanHitMax = conf->getParameter<double>("MeanHitMax");

  int MeanLayBin = conf->getParameter<int>("MeanLayBin");
  double MeanLayMin = conf->getParameter<double>("MeanLayMin");
  double MeanLayMax = conf->getParameter<double>("MeanLayMax");

  int LSBin = conf->getParameter<int>("LSBin");
  int LSMin = conf->getParameter<double>("LSMin");
  int LSMax = conf->getParameter<double>("LSMax");

  std::string StateName = conf->getParameter<std::string>("MeasurementState");
  if (StateName != "OuterSurface" && StateName != "InnerSurface" && StateName != "ImpactPoint" &&
      StateName != "default" && StateName != "All") {
    // print warning
    edm::LogWarning("TrackingMonitor") << "State Name is invalid, using 'ImpactPoint' by default";
  }

  ibooker.setCurrentFolder(MEFolderName);

  // book the General Property histograms
  // ---------------------------------------------------------------------------------//

  if (doGeneralPropertiesPlots_ || doAllPlots) {
    ibooker.setCurrentFolder(MEFolderName + "/GeneralProperties");

    histname = "NumberOfTracks_" + CategoryName;
    // MODIFY by Mia in order to cope w/ high multiplicity
    NumberOfTracks = ibooker.book1D(histname, histname, TKNoBin, TKNoMin, TKNoMax);
    NumberOfTracks->setAxisTitle("Number of Tracks per Event", 1);
    NumberOfTracks->setAxisTitle("Number of Events", 2);

    if (Folder == "Tr") {
      histname = "NumberOfTracks_PUvtx_" + CategoryName;
      NumberOfTracks_PUvtx = ibooker.book1D(histname, histname, TKNoBin, TKNoMin, TKNoMax);
      NumberOfTracks_PUvtx->setAxisTitle("Number of Tracks per Event (matched a PU vertex)", 1);
      NumberOfTracks_PUvtx->setAxisTitle("Number of Events", 2);

      histname = "NumberofTracks_Hardvtx_" + CategoryName;
      NumberofTracks_Hardvtx =
          ibooker.book1D(histname, histname, TKNoBin / 10, TKNoMin, ((TKNoMax - TKNoMin) / 10) - 0.5);
      NumberofTracks_Hardvtx->setAxisTitle("Number of Tracks per Event (matched main vertex)", 1);
      NumberofTracks_Hardvtx->setAxisTitle("Number of Events", 2);

      histname = "NumberofTracks_Hardvtx_PUvtx_" + CategoryName;
      NumberofTracks_Hardvtx_PUvtx = ibooker.book1D(histname, histname, 2, 0., 2.);
      NumberofTracks_Hardvtx_PUvtx->setAxisTitle("Number of Tracks per PU/Hard vertex", 1);
      NumberofTracks_Hardvtx_PUvtx->setAxisTitle("Number of Tracks", 2);
      NumberofTracks_Hardvtx_PUvtx->setBinLabel(1, "PU_Vertex");
      NumberofTracks_Hardvtx_PUvtx->setBinLabel(2, "Hard_Vertex");
    }

    histname = "NumberOfMeanRecHitsPerTrack_" + CategoryName;
    NumberOfMeanRecHitsPerTrack = ibooker.book1D(histname, histname, MeanHitBin, MeanHitMin, MeanHitMax);
    NumberOfMeanRecHitsPerTrack->setAxisTitle("Mean number of valid RecHits per Track", 1);
    NumberOfMeanRecHitsPerTrack->setAxisTitle("Entries", 2);

    histname = "NumberOfMeanLayersPerTrack_" + CategoryName;
    NumberOfMeanLayersPerTrack = ibooker.book1D(histname, histname, MeanLayBin, MeanLayMin, MeanLayMax);
    NumberOfMeanLayersPerTrack->setAxisTitle("Mean number of Layers per Track", 1);
    NumberOfMeanLayersPerTrack->setAxisTitle("Entries", 2);

    if (doFractionPlot_) {
      histname = "FractionOfGoodTracks_" + CategoryName;
      FractionOfGoodTracks = ibooker.book1D(histname, histname, 101, -0.005, 1.005);
      FractionOfGoodTracks->setAxisTitle("Fraction of Tracks (w.r.t. generalTracks)", 1);
      FractionOfGoodTracks->setAxisTitle("Entries", 2);
    }
  }

  if (doLumiAnalysis) {
    // add by Mia in order to deal with LS transitions
    ibooker.setCurrentFolder(MEFolderName + "/LSanalysis");
    auto scope = DQMStore::IBooker::UseLumiScope(ibooker);

    histname = "NumberOfTracks_lumiFlag_" + CategoryName;
    NumberOfTracks_lumiFlag = ibooker.book1D(histname, histname, TKNoBin, TKNoMin, TKNoMax);
    NumberOfTracks_lumiFlag->setAxisTitle("Number of Tracks per Event", 1);
    NumberOfTracks_lumiFlag->setAxisTitle("Number of Events", 2);
  }

  // book profile plots vs LS :
  //---------------------------

  if (doProfilesVsLS_ || doAllPlots) {
    ibooker.setCurrentFolder(MEFolderName + "/GeneralProperties");

    histname = "NumberOfTracksVsLS_" + CategoryName;
    NumberOfTracksVsLS = ibooker.bookProfile(histname, histname, LSBin, LSMin, LSMax, TKNoMin, TKNoMax, "");
    NumberOfTracksVsLS->getTH1()->SetCanExtend(TH1::kAllAxes);
    NumberOfTracksVsLS->setAxisTitle("#Lumi section", 1);
    NumberOfTracksVsLS->setAxisTitle("Number of  Tracks", 2);

    histname = "NumberOfRecHitsPerTrackVsLS_" + CategoryName;
    NumberOfRecHitsPerTrackVsLS =
        ibooker.bookProfile(histname, histname, LSBin, LSMin, LSMax, RecHitMin, RecHitMax * 5, "");
    NumberOfRecHitsPerTrackVsLS->getTH1()->SetCanExtend(TH1::kAllAxes);
    NumberOfRecHitsPerTrackVsLS->setAxisTitle("#Lumi section", 1);
    NumberOfRecHitsPerTrackVsLS->setAxisTitle("Mean number of Valid RecHits per track", 2);

    histname = "NumberEventsVsLS_" + CategoryName;
    NumberEventsOfVsLS = ibooker.book1D(histname, histname, LSBin, LSMin, LSMax);
    NumberEventsOfVsLS->getTH1()->SetCanExtend(TH1::kAllAxes);
    NumberEventsOfVsLS->setAxisTitle("#Lumi section", 1);
    NumberEventsOfVsLS->setAxisTitle("Number of events", 2);

    edm::ParameterSet ParametersGoodPVtx = conf->getParameter<edm::ParameterSet>("GoodPVtx");

    double GoodPVtxMin = ParametersGoodPVtx.getParameter<double>("GoodPVtxMin");
    double GoodPVtxMax = ParametersGoodPVtx.getParameter<double>("GoodPVtxMax");

    histname = "NumberOfGoodPVtxVsLS_" + CategoryName;
    NumberOfGoodPVtxVsLS =
        ibooker.bookProfile(histname, histname, LSBin, LSMin, LSMax, GoodPVtxMin, 3. * GoodPVtxMax, "");
    NumberOfGoodPVtxVsLS->getTH1()->SetCanExtend(TH1::kAllAxes);
    NumberOfGoodPVtxVsLS->setAxisTitle("#Lumi section", 1);
    NumberOfGoodPVtxVsLS->setAxisTitle("Mean number of good PV", 2);

    histname = "NumberOfGoodPVtxWO0VsLS_" + CategoryName;
    NumberOfGoodPVtxWO0VsLS =
        ibooker.bookProfile(histname, histname, LSBin, LSMin, LSMax, GoodPVtxMin, 3. * GoodPVtxMax, "");
    NumberOfGoodPVtxWO0VsLS->setAxisTitle("#Lumi section", 1);
    NumberOfGoodPVtxWO0VsLS->setAxisTitle("Mean number of good PV", 2);

    if (doFractionPlot_) {
      histname = "GoodTracksFractionVsLS_" + CategoryName;
      GoodTracksFractionVsLS = ibooker.bookProfile(histname, histname, LSBin, LSMin, LSMax, 0, 1.1, "");
      GoodTracksFractionVsLS->getTH1()->SetCanExtend(TH1::kAllAxes);
      GoodTracksFractionVsLS->setAxisTitle("#Lumi section", 1);
      GoodTracksFractionVsLS->setAxisTitle("Fraction of Good Tracks", 2);
    }

    if (doPlotsVsBX_ || doAllPlots) {
      ibooker.setCurrentFolder(MEFolderName + "/BXanalysis");
      int BXBin = 3564;
      double BXMin = 0.5;
      double BXMax = 3564.5;

      histname = "NumberEventsVsBX_" + CategoryName;
      NumberEventsOfVsBX = ibooker.book1D(histname, histname, BXBin, BXMin, BXMax);
      NumberEventsOfVsBX->setAxisTitle("BX", 1);
      NumberEventsOfVsBX->setAxisTitle("Number of events", 2);

      histname = "NumberOfTracksVsBX_" + CategoryName;
      NumberOfTracksVsBX = ibooker.bookProfile(histname, histname, BXBin, BXMin, BXMax, TKNoMin, TKNoMax * 3., "");
      NumberOfTracksVsBX->setAxisTitle("BX", 1);
      NumberOfTracksVsBX->setAxisTitle("Number of  Tracks", 2);

      histname = "NumberOfRecHitsPerTrackVsBX_" + CategoryName;
      NumberOfRecHitsPerTrackVsBX =
          ibooker.bookProfile(histname, histname, BXBin, BXMin, BXMax, RecHitMin, RecHitMax * 5, "");
      NumberOfRecHitsPerTrackVsBX->setAxisTitle("BX", 1);
      NumberOfRecHitsPerTrackVsBX->setAxisTitle("Mean number of Valid RecHits per track", 2);

      histname = "NumberOfGoodPVtxVsBX_" + CategoryName;
      NumberOfGoodPVtxVsBX =
          ibooker.bookProfile(histname, histname, BXBin, BXMin, BXMax, GoodPVtxMin, 3. * GoodPVtxMax, "");
      NumberOfGoodPVtxVsBX->setAxisTitle("BX", 1);
      NumberOfGoodPVtxVsBX->setAxisTitle("Mean number of good PV", 2);

      histname = "NumberOfGoodPVtxWO0VsBX_" + CategoryName;
      NumberOfGoodPVtxWO0VsBX =
          ibooker.bookProfile(histname, histname, BXBin, BXMin, BXMax, GoodPVtxMin, 3. * GoodPVtxMax, "");
      NumberOfGoodPVtxWO0VsBX->setAxisTitle("BX", 1);
      NumberOfGoodPVtxWO0VsBX->setAxisTitle("Mean number of good PV", 2);

      if (doFractionPlot_) {
        histname = "GoodTracksFractionVsBX_" + CategoryName;
        GoodTracksFractionVsBX = ibooker.bookProfile(histname, histname, BXBin, BXMin, BXMax, 0, 1.1, "");
        GoodTracksFractionVsBX->setAxisTitle("BX", 1);
        GoodTracksFractionVsBX->setAxisTitle("Fraction of Good Tracks", 2);
      }
    }
  }

  // book PU monitoring plots :
  //---------------------------

  if (doPUmonitoring_) {
    for (size_t i = 0; i < theVertexMonitor.size(); i++)
      theVertexMonitor[i]->initHisto(ibooker);
  }

  if (doPlotsVsGoodPVtx_) {
    ibooker.setCurrentFolder(MEFolderName + "/PUmonitoring");
    // get binning from the configuration
    int PVBin = conf->getParameter<int>("PVBin");
    float PVMin = conf->getParameter<double>("PVMin");
    float PVMax = conf->getParameter<double>("PVMax");

    histname = "NumberOfTracksVsGoodPVtx";
    NumberOfTracksVsGoodPVtx = ibooker.bookProfile(histname, histname, PVBin, PVMin, PVMax, TKNoMin, TKNoMax * 5., "");
    NumberOfTracksVsGoodPVtx->setAxisTitle("Number of PV", 1);
    NumberOfTracksVsGoodPVtx->setAxisTitle("Mean number of Tracks per Event", 2);

    histname = "NumberOfTracksVsPUPVtx";
    NumberOfTracksVsPUPVtx = ibooker.bookProfile(histname, histname, PVBin, PVMin, PVMax, 0., TKNoMax * 5., "");
    NumberOfTracksVsPUPVtx->setAxisTitle("Number of PU", 1);
    NumberOfTracksVsPUPVtx->setAxisTitle("Mean number of Tracks per PUvtx", 2);

    histname = "NumberEventsVsGoodPVtx";
    NumberEventsOfVsGoodPVtx = ibooker.book1D(histname, histname, PVBin, PVMin, PVMax);
    NumberEventsOfVsGoodPVtx->setAxisTitle("Number of good PV (PU)", 1);
    NumberEventsOfVsGoodPVtx->setAxisTitle("Number of events", 2);

    if (doFractionPlot_) {
      histname = "GoodTracksFractionVsGoodPVtx";
      GoodTracksFractionVsGoodPVtx = ibooker.bookProfile(histname, histname, PVBin, PVMin, PVMax, 0., 1.1, "");
      GoodTracksFractionVsGoodPVtx->setAxisTitle("Number of good PV (PU)", 1);
      GoodTracksFractionVsGoodPVtx->setAxisTitle("Mean fraction of good tracks", 2);
    }

    histname = "NumberOfRecHitsPerTrackVsGoodPVtx";
    NumberOfRecHitsPerTrackVsGoodPVtx = ibooker.bookProfile(histname, histname, PVBin, PVMin, PVMax, 0., 200., "");
    NumberOfRecHitsPerTrackVsGoodPVtx->setAxisTitle("Number of good PV (PU)", 1);
    NumberOfRecHitsPerTrackVsGoodPVtx->setAxisTitle("Mean number of valid rechits per Tracks", 2);

    histname = "NumberOfPVtxVsGoodPVtx";
    NumberOfPVtxVsGoodPVtx = ibooker.bookProfile(histname, histname, PVBin, PVMin, PVMax, 0., 3. * PVMax, "");
    NumberOfPVtxVsGoodPVtx->setAxisTitle("Number of good PV (PU)", 1);
    NumberOfPVtxVsGoodPVtx->setAxisTitle("Mean number of vertices", 2);

    double NClusPxMin = conf->getParameter<double>("NClusPxMin");
    double NClusPxMax = conf->getParameter<double>("NClusPxMax");
    histname = "NumberOfPixelClustersVsGoodPVtx";
    NumberOfPixelClustersVsGoodPVtx =
        ibooker.bookProfile(histname, histname, PVBin, PVMin, PVMax, NClusPxMin, 3. * NClusPxMax, "");
    NumberOfPixelClustersVsGoodPVtx->setAxisTitle("Number of good PV (PU)", 1);
    NumberOfPixelClustersVsGoodPVtx->setAxisTitle("Mean number of pixel clusters", 2);

    double NClusStrMin = conf->getParameter<double>("NClusStrMin");
    double NClusStrMax = conf->getParameter<double>("NClusStrMax");
    histname = "NumberOfStripClustersVsGoodPVtx";
    NumberOfStripClustersVsGoodPVtx =
        ibooker.bookProfile(histname, histname, PVBin, PVMin, PVMax, NClusStrMin, 3. * NClusStrMax, "");
    NumberOfStripClustersVsGoodPVtx->setAxisTitle("Number of good PV (PU)", 1);
    NumberOfStripClustersVsGoodPVtx->setAxisTitle("Mean number of strip clusters", 2);
  }

  if (doPlotsVsLUMI_ || doAllPlots) {
    ibooker.setCurrentFolder(MEFolderName + "/LUMIanalysis");
    int LUMIBin = conf->getParameter<int>("LUMIBin");
    float LUMIMin = conf->getParameter<double>("LUMIMin");
    float LUMIMax = conf->getParameter<double>("LUMIMax");

    histname = "NumberEventsVsLUMI";
    NumberEventsOfVsLUMI = ibooker.book1D(histname, histname, LUMIBin, LUMIMin, LUMIMax);
    NumberEventsOfVsLUMI->setAxisTitle("scal lumi [10e30 Hz cm^{-2}]", 1);
    NumberEventsOfVsLUMI->setAxisTitle("Number of events", 2);

    histname = "NumberOfTracksVsLUMI";
    NumberOfTracksVsLUMI = ibooker.bookProfile(histname, histname, LUMIBin, LUMIMin, LUMIMax, TKNoMin, TKNoMax * 3, "");
    NumberOfTracksVsLUMI->setAxisTitle("scal lumi [10e30 Hz cm^{-2}]", 1);
    NumberOfTracksVsLUMI->setAxisTitle("Mean number of vertices", 2);

    if (doFractionPlot_) {
      histname = "GoodTracksFractionVsLUMI";
      GoodTracksFractionVsLUMI = ibooker.bookProfile(histname, histname, LUMIBin, LUMIMin, LUMIMax, 0., 1.1, "");
      GoodTracksFractionVsLUMI->setAxisTitle("scal lumi [10e30 Hz cm^{-2}]", 1);
      GoodTracksFractionVsLUMI->setAxisTitle("Mean number of vertices", 2);
    }

    histname = "NumberOfRecHitsPerTrackVsLUMI";
    NumberOfRecHitsPerTrackVsLUMI =
        ibooker.bookProfile(histname, histname, LUMIBin, LUMIMin, LUMIMax, RecHitMin, RecHitMax * 5, "");
    NumberOfRecHitsPerTrackVsLUMI->setAxisTitle("scal lumi [10e30 Hz cm^{-2}]", 1);
    NumberOfRecHitsPerTrackVsLUMI->setAxisTitle("Mean number of vertices", 2);

    double PVMin = conf->getParameter<double>("PVMin");
    double PVMax = conf->getParameter<double>("PVMax");

    histname = "NumberOfGoodPVtxVsLUMI";
    NumberOfGoodPVtxVsLUMI = ibooker.bookProfile(histname, histname, LUMIBin, LUMIMin, LUMIMax, PVMin, 3. * PVMax, "");
    NumberOfGoodPVtxVsLUMI->setAxisTitle("scal lumi [10e30 Hz cm^{-2}]", 1);
    NumberOfGoodPVtxVsLUMI->setAxisTitle("Mean number of vertices", 2);

    histname = "NumberOfGoodPVtxWO0VsLUMI";
    NumberOfGoodPVtxWO0VsLUMI =
        ibooker.bookProfile(histname, histname, LUMIBin, LUMIMin, LUMIMax, PVMin, 3. * PVMax, "");
    NumberOfGoodPVtxWO0VsLUMI->setAxisTitle("scal lumi [10e30 Hz cm^{-2}]", 1);
    NumberOfGoodPVtxWO0VsLUMI->setAxisTitle("Mean number of vertices", 2);

    double NClusPxMin = conf->getParameter<double>("NClusPxMin");
    double NClusPxMax = conf->getParameter<double>("NClusPxMax");
    histname = "NumberOfPixelClustersVsGoodPVtx";
    NumberOfPixelClustersVsLUMI =
        ibooker.bookProfile(histname, histname, LUMIBin, LUMIMin, LUMIMax, NClusPxMin, 3. * NClusPxMax, "");
    NumberOfPixelClustersVsLUMI->setAxisTitle("scal lumi [10e30 Hz cm^{-2}]", 1);
    NumberOfPixelClustersVsLUMI->setAxisTitle("Mean number of pixel clusters", 2);

    double NClusStrMin = conf->getParameter<double>("NClusStrMin");
    double NClusStrMax = conf->getParameter<double>("NClusStrMax");
    histname = "NumberOfStripClustersVsLUMI";
    NumberOfStripClustersVsLUMI =
        ibooker.bookProfile(histname, histname, LUMIBin, LUMIMin, LUMIMax, NClusStrMin, 3. * NClusStrMax, "");
    NumberOfStripClustersVsLUMI->setAxisTitle("scal lumi [10e30 Hz cm^{-2}]", 1);
    NumberOfStripClustersVsLUMI->setAxisTitle("Mean number of strip clusters", 2);
  }

  if (doPlotsVsBXlumi_) {
    ibooker.setCurrentFolder(MEFolderName + "/PUmonitoring");
    // get binning from the configuration
    edm::ParameterSet BXlumiParameters = conf->getParameter<edm::ParameterSet>("BXlumiSetup");
    int BXlumiBin = BXlumiParameters.getParameter<int>("BXlumiBin");
    double BXlumiMin = BXlumiParameters.getParameter<double>("BXlumiMin");
    double BXlumiMax = BXlumiParameters.getParameter<double>("BXlumiMax");

    histname = "NumberOfTracksVsBXlumi_" + CategoryName;
    NumberOfTracksVsBXlumi =
        ibooker.bookProfile(histname, histname, BXlumiBin, BXlumiMin, BXlumiMax, TKNoMin, 3. * TKNoMax, "");
    NumberOfTracksVsBXlumi->setAxisTitle("lumi BX [10^{30}Hzcm^{-2}]", 1);
    NumberOfTracksVsBXlumi->setAxisTitle("Mean number of Tracks", 2);
  }

  if (doLumiAnalysis) {
    auto scope = DQMStore::IBooker::UseLumiScope(ibooker);
    theTrackAnalyzer->initHisto(ibooker, iSetup, *conf);
  } else {
    theTrackAnalyzer->initHisto(ibooker, iSetup, *conf);
  }

  // book the Seed Property histograms
  // ---------------------------------------------------------------------------------//

  ibooker.setCurrentFolder(MEFolderName + "/TrackBuilding");

  doSeedNumberPlot = conf->getParameter<bool>("doSeedNumberHisto");
  doSeedLumiAnalysis_ = conf->getParameter<bool>("doSeedLumiAnalysis");
  doSeedVsClusterPlot = conf->getParameter<bool>("doSeedVsClusterHisto");

  edm::InputTag seedProducer = conf->getParameter<edm::InputTag>("SeedProducer");

  if (doAllSeedPlots || doSeedNumberPlot) {
    ibooker.setCurrentFolder(MEFolderName + "/TrackBuilding");
    histname = "NumberOfSeeds_" + seedProducer.label() + "_" + CategoryName;
    NumberOfSeeds = ibooker.book1D(histname, histname, TKNoSeedBin, TKNoSeedMin, TKNoSeedMax);
    NumberOfSeeds->setAxisTitle("Number of Seeds per Event", 1);
    NumberOfSeeds->setAxisTitle("Number of Events", 2);

    if (doSeedLumiAnalysis_) {
      ibooker.setCurrentFolder(MEFolderName + "/LSanalysis");
      auto scope = DQMStore::IBooker::UseLumiScope(ibooker);
      histname = "NumberOfSeeds_lumiFlag_" + seedProducer.label() + "_" + CategoryName;
      NumberOfSeeds_lumiFlag = ibooker.book1D(histname, histname, TKNoSeedBin, TKNoSeedMin, TKNoSeedMax);
      NumberOfSeeds_lumiFlag->setAxisTitle("Number of Seeds per Event", 1);
      NumberOfSeeds_lumiFlag->setAxisTitle("Number of Events", 2);
    }
  }

  if (doAllSeedPlots || doSeedVsClusterPlot) {
    ibooker.setCurrentFolder(MEFolderName + "/TrackBuilding");

    ClusterLabels = conf->getParameter<std::vector<std::string> >("ClusterLabels");

    std::vector<double> histoMin, histoMax;
    std::vector<int> histoBin;  //these vectors are for max min and nbins in histograms

    int NClusPxBin = conf->getParameter<int>("NClusPxBin");
    double NClusPxMin = conf->getParameter<double>("NClusPxMin");
    double NClusPxMax = conf->getParameter<double>("NClusPxMax");

    int NClusStrBin = conf->getParameter<int>("NClusStrBin");
    double NClusStrMin = conf->getParameter<double>("NClusStrMin");
    double NClusStrMax = conf->getParameter<double>("NClusStrMax");

    setMaxMinBin(
        histoMin, histoMax, histoBin, NClusStrMin, NClusStrMax, NClusStrBin, NClusPxMin, NClusPxMax, NClusPxBin);

    for (uint i = 0; i < ClusterLabels.size(); i++) {
      histname = "SeedsVsClusters_" + seedProducer.label() + "_Vs_" + ClusterLabels[i] + "_" + CategoryName;
      SeedsVsClusters.push_back(dynamic_cast<MonitorElement*>(ibooker.book2D(
          histname, histname, histoBin[i], histoMin[i], histoMax[i], TKNoSeedBin, TKNoSeedMin, TKNoSeedMax)));
      SeedsVsClusters[i]->setAxisTitle("Number of Clusters", 1);
      SeedsVsClusters[i]->setAxisTitle("Number of Seeds", 2);
      SeedsVsClusters[i]->getTH2F()->SetCanExtend(TH1::kAllAxes);
    }
  }

  if (doRegionPlots) {
    ibooker.setCurrentFolder(MEFolderName + "/TrackBuilding");

    int regionBin = conf->getParameter<int>("RegionSizeBin");
    double regionMin = conf->getParameter<double>("RegionSizeMin");
    double regionMax = conf->getParameter<double>("RegionSizeMax");

    histname = "TrackingRegionsNumberOf_" + seedProducer.label() + "_" + CategoryName;
    NumberOfTrackingRegions = ibooker.book1D(histname, histname, regionBin, regionMin, regionMax);
    NumberOfTrackingRegions->setAxisTitle("Number of TrackingRegions per Event", 1);
    NumberOfTrackingRegions->setAxisTitle("Number of Events", 2);
  }

  if (doTkCandPlots) {
    ibooker.setCurrentFolder(MEFolderName + "/TrackBuilding");

    edm::InputTag tcProducer = conf->getParameter<edm::InputTag>("TCProducer");

    histname = "NumberOfTrackCandidates_" + tcProducer.label() + "_" + CategoryName;
    NumberOfTrackCandidates = ibooker.book1D(histname, histname, TCNoBin, TCNoMin, TCNoMax);
    NumberOfTrackCandidates->setAxisTitle("Number of Track Candidates per Event", 1);
    NumberOfTrackCandidates->setAxisTitle("Number of Event", 2);

    histname = "FractionOfCandOverSeeds_" + tcProducer.label() + "_" + CategoryName;
    FractionCandidatesOverSeeds = ibooker.book1D(histname, histname, 101, 0., 1.01);
    FractionCandidatesOverSeeds->setAxisTitle("Number of Track Candidates / Number of Seeds per Event", 1);
    FractionCandidatesOverSeeds->setAxisTitle("Number of Event", 2);
  }

  theTrackBuildingAnalyzer->initHisto(ibooker, *conf);

  if (doTrackerSpecific_ || doAllPlots) {
    ClusterLabels = conf->getParameter<std::vector<std::string> >("ClusterLabels");

    std::vector<double> histoMin, histoMax;
    std::vector<int> histoBin;  //these vectors are for max min and nbins in histograms

    int NClusStrBin = conf->getParameter<int>("NClusStrBin");
    double NClusStrMin = conf->getParameter<double>("NClusStrMin");
    double NClusStrMax = conf->getParameter<double>("NClusStrMax");

    int NClusPxBin = conf->getParameter<int>("NClusPxBin");
    double NClusPxMin = conf->getParameter<double>("NClusPxMin");
    double NClusPxMax = conf->getParameter<double>("NClusPxMax");

    edm::ParameterSet ParametersNTrk2D = conf->getParameter<edm::ParameterSet>("NTrk2D");
    int NTrk2DBin = ParametersNTrk2D.getParameter<int>("NTrk2DBin");
    double NTrk2DMin = ParametersNTrk2D.getParameter<double>("NTrk2DMin");
    double NTrk2DMax = ParametersNTrk2D.getParameter<double>("NTrk2DMax");

    setMaxMinBin(
        histoMin, histoMax, histoBin, NClusStrMin, NClusStrMax, NClusStrBin, NClusPxMin, NClusPxMax, NClusPxBin);

    ibooker.setCurrentFolder(MEFolderName + "/HitProperties");

    for (uint i = 0; i < ClusterLabels.size(); i++) {
      ibooker.setCurrentFolder(MEFolderName + "/HitProperties");
      histname = "TracksVs" + ClusterLabels[i] + "Cluster_" + CategoryName;
      NumberOfTrkVsClusters.push_back(dynamic_cast<MonitorElement*>(
          ibooker.book2D(histname, histname, histoBin[i], histoMin[i], histoMax[i], NTrk2DBin, NTrk2DMin, NTrk2DMax)));
      std::string title = "Number of " + ClusterLabels[i] + " Clusters";
      if (ClusterLabels[i] == "Tot")
        title = "# of Clusters in (Pixel+Strip) Detectors";
      NumberOfTrkVsClusters[i]->setAxisTitle(title, 1);
      NumberOfTrkVsClusters[i]->setAxisTitle("Number of Tracks", 2);
      NumberOfTrkVsClusters[i]->getTH1()->SetCanExtend(TH1::kXaxis);
    }
  }

  // Initialize the GenericTriggerEventFlag
  if (genTriggerEventFlag_->on())
    genTriggerEventFlag_->initRun(iRun, iSetup);
}

/*
// -- BeginRun
//---------------------------------------------------------------------------------//
void TrackingMonitor::beginRun(const edm::Run& iRun, const edm::EventSetup& iSetup)
{
  
}
*/

// -- Analyse
// ---------------------------------------------------------------------------------//
void TrackingMonitor::analyze(const edm::Event& iEvent, const edm::EventSetup& iSetup) {
  // Filter out events if Trigger Filtering is requested
  if (genTriggerEventFlag_->on() && !genTriggerEventFlag_->accept(iEvent, iSetup))
    return;
  auto const* conf = edm::pset::Registry::instance()->getMapped(confID_);
  MEFolderName = conf->getParameter<std::string>("FolderName");
  std::string Folder = MEFolderName.substr(0, 2);
  float lumi = -1.;
  if (forceSCAL_) {
    edm::Handle<LumiScalersCollection> lumiScalers = iEvent.getHandle(lumiscalersToken_);
    if (lumiScalers.isValid() && !lumiScalers->empty()) {
      LumiScalersCollection::const_iterator scalit = lumiScalers->begin();
      lumi = scalit->instantLumi();
    }
  } else {
    edm::Handle<OnlineLuminosityRecord> metaData = iEvent.getHandle(metaDataToken_);
    if (metaData.isValid())
      lumi = metaData->instLumi();
  }

  if (doPlotsVsLUMI_ || doAllPlots)
    NumberEventsOfVsLUMI->Fill(lumi);

  //  Analyse the tracks
  //  if the collection is empty, do not fill anything
  // ---------------------------------------------------------------------------------//

  size_t bx = iEvent.bunchCrossing();
  if (doPlotsVsBX_ || doAllPlots)
    NumberEventsOfVsBX->Fill(bx);

  // get the track collection
  edm::Handle<edm::View<reco::Track> > trackHandle = iEvent.getHandle(trackToken_);

  int numberOfTracks_den = 0;
  edm::Handle<edm::View<reco::Track> > allTrackHandle = iEvent.getHandle(allTrackToken_);
  if (allTrackHandle.isValid()) {
    for (edm::View<reco::Track>::const_iterator track = allTrackHandle->begin(); track != allTrackHandle->end();
         ++track) {
      if (denSelection_(*track))
        numberOfTracks_den++;
    }
  }

  edm::Handle<reco::VertexCollection> pvHandle = iEvent.getHandle(pvSrcToken_);
  reco::Vertex const* pv0 = nullptr;
  if (pvHandle.isValid()) {
    pv0 = &pvHandle->front();
    //--- pv fake (the pv collection should have size==1 and the pv==beam spot)
    if (pv0->isFake() ||
        pv0->tracksSize() == 0
        // definition of goodOfflinePrimaryVertex
        || pv0->ndof() < pvNDOF_ || pv0->z() > 24.)
      pv0 = nullptr;
  }

  if (trackHandle.isValid()) {
    int numberOfTracks = trackHandle->size();
    int numberOfTracks_num = 0;
    int numberOfTracks_pv0 = 0;

    const edm::View<reco::Track>& trackCollection = *trackHandle;
    // calculate the mean # rechits and layers
    int totalRecHits = 0, totalLayers = 0;

    theTrackAnalyzer->setNumberOfGoodVertices(iEvent);
    theTrackAnalyzer->setBX(iEvent);
    theTrackAnalyzer->setLumi(iEvent, iSetup);
    for (edm::View<reco::Track>::const_iterator track = trackCollection.begin(); track != trackCollection.end();
         ++track) {
      if (doPlotsVsBX_ || doAllPlots)
        NumberOfRecHitsPerTrackVsBX->Fill(bx, track->numberOfValidHits());
      if (numSelection_(*track)) {
        numberOfTracks_num++;
        if (pv0 && std::abs(track->dz(pv0->position())) < 0.15)
          ++numberOfTracks_pv0;
      }

      if (doProfilesVsLS_ || doAllPlots)
        NumberOfRecHitsPerTrackVsLS->Fill(static_cast<double>(iEvent.id().luminosityBlock()),
                                          track->numberOfValidHits());

      if (doPlotsVsLUMI_ || doAllPlots)
        NumberOfRecHitsPerTrackVsLUMI->Fill(lumi, track->numberOfValidHits());

      totalRecHits += track->numberOfValidHits();
      totalLayers += track->hitPattern().trackerLayersWithMeasurement();

      // do analysis per track
      theTrackAnalyzer->analyze(iEvent, iSetup, *track);
    }

    double frac = -1.;
    //      if (numberOfAllTracks > 0) frac = static_cast<double>(numberOfTracks)/static_cast<double>(numberOfAllTracks);
    if (numberOfTracks_den > 0)
      frac = static_cast<double>(numberOfTracks_num) / static_cast<double>(numberOfTracks_den);

    if (doGeneralPropertiesPlots_ || doAllPlots) {
      NumberOfTracks->Fill(double(numberOfTracks));

      if (Folder == "Tr") {
        NumberofTracks_Hardvtx->Fill(double(numberOfTracks_pv0));
        NumberOfTracks_PUvtx->Fill(double(numberOfTracks - numberOfTracks_pv0));
        NumberofTracks_Hardvtx_PUvtx->Fill(0.5, double(numberOfTracks_pv0));
        NumberofTracks_Hardvtx_PUvtx->Fill(1.5, double(numberOfTracks - numberOfTracks_pv0));
      }

      if (doPlotsVsBX_ || doAllPlots)
        NumberOfTracksVsBX->Fill(bx, numberOfTracks);
      if (doPlotsVsLUMI_ || doAllPlots)
        NumberOfTracksVsLUMI->Fill(lumi, numberOfTracks);
      if (doFractionPlot_) {
        FractionOfGoodTracks->Fill(frac);

        if (doFractionPlot_) {
          if (doPlotsVsBX_ || doAllPlots)
            GoodTracksFractionVsBX->Fill(bx, frac);
          if (doPlotsVsLUMI_ || doAllPlots)
            GoodTracksFractionVsLUMI->Fill(lumi, frac);
        }
      }
      if (numberOfTracks > 0) {
        double meanRecHits = static_cast<double>(totalRecHits) / static_cast<double>(numberOfTracks);
        double meanLayers = static_cast<double>(totalLayers) / static_cast<double>(numberOfTracks);
        NumberOfMeanRecHitsPerTrack->Fill(meanRecHits);
        NumberOfMeanLayersPerTrack->Fill(meanLayers);
      }
    }

    if (doProfilesVsLS_ || doAllPlots) {
      float nLS = static_cast<double>(iEvent.id().luminosityBlock());
      NumberEventsOfVsLS->Fill(nLS);
      NumberOfTracksVsLS->Fill(nLS, numberOfTracks);
      if (doFractionPlot_)
        GoodTracksFractionVsLS->Fill(nLS, frac);
    }

    if (doLumiAnalysis) {
      NumberOfTracks_lumiFlag->Fill(numberOfTracks);
    }

    //  Analyse the Track Building variables
    //  if the collection is empty, do not fill anything
    // ---------------------------------------------------------------------------------//

    // fill the TrackCandidate info
    if (doTkCandPlots) {
      // magnetic field
      MagneticField const& theMF = iSetup.getData(magneticFieldToken_);

      // get the candidate collection
      edm::Handle<TrackCandidateCollection> theTCHandle = iEvent.getHandle(trackCandidateToken_);
      const TrackCandidateCollection& theTCCollection = *theTCHandle;

      if (theTCHandle.isValid()) {
        // get the beam spot
        edm::Handle<reco::BeamSpot> recoBeamSpotHandle = iEvent.getHandle(bsSrcToken_);
        const reco::BeamSpot& bs = *recoBeamSpotHandle;

        NumberOfTrackCandidates->Fill(theTCCollection.size());

        // get the seed collection
        edm::Handle<edm::View<TrajectorySeed> > seedHandle = iEvent.getHandle(seedToken_);
        const edm::View<TrajectorySeed>& seedCollection = *seedHandle;
        if (seedHandle.isValid() && !seedCollection.empty())
          FractionCandidatesOverSeeds->Fill(double(theTCCollection.size()) / double(seedCollection.size()));

        TransientTrackingRecHitBuilder const& theTTRHBuilder = iSetup.getData(transientTrackingRecHitBuilderToken_);
        for (TrackCandidateCollection::const_iterator cand = theTCCollection.begin(); cand != theTCCollection.end();
             ++cand) {
          theTrackBuildingAnalyzer->analyze(iEvent, iSetup, *cand, bs, theMF, theTTRHBuilder);
        }
      } else {
        edm::LogWarning("TrackingMonitor") << "No Track Candidates in the event.  Not filling associated histograms";
      }

      if (doMVAPlots) {
        // Get MVA and quality mask collections
        std::vector<const MVACollection*> mvaCollections;
        std::vector<const QualityMaskCollection*> qualityMaskCollections;

        edm::Handle<edm::View<reco::Track> > htracks = iEvent.getHandle(mvaTrackToken_);

        edm::Handle<MVACollection> hmva;
        edm::Handle<QualityMaskCollection> hqual;
        for (const auto& tokenTpl : mvaQualityTokens_) {
          hmva = iEvent.getHandle(std::get<0>(tokenTpl));
          hqual = iEvent.getHandle(std::get<1>(tokenTpl));
          mvaCollections.push_back(hmva.product());
          qualityMaskCollections.push_back(hqual.product());
        }
        theTrackBuildingAnalyzer->analyze(*htracks, mvaCollections, qualityMaskCollections);
      }
    }

    //plots for trajectory seeds

    if (doAllSeedPlots || doSeedNumberPlot || doSeedVsClusterPlot || runTrackBuildingAnalyzerForSeed) {
      // get the seed collection
      edm::Handle<edm::View<TrajectorySeed> > seedHandle = iEvent.getHandle(seedToken_);

      // fill the seed info
      if (seedHandle.isValid()) {
        const auto& seedCollection = *seedHandle;

        if (doAllSeedPlots || doSeedNumberPlot) {
          NumberOfSeeds->Fill(seedCollection.size());
          if (doSeedLumiAnalysis_)
            NumberOfSeeds_lumiFlag->Fill(seedCollection.size());
        }

        if (doAllSeedPlots || doSeedVsClusterPlot) {
          std::vector<int> NClus;
          setNclus(iEvent, NClus);
          for (uint i = 0; i < ClusterLabels.size(); i++) {
            SeedsVsClusters[i]->Fill(NClus[i], seedCollection.size());
          }
        }

        if (doAllSeedPlots || runTrackBuildingAnalyzerForSeed) {
          edm::Handle<std::vector<SeedStopInfo> > stopHandle = iEvent.getHandle(seedStopInfoToken_);
          const auto& seedStopInfo = *stopHandle;

          if (seedStopInfo.size() == seedCollection.size()) {
            //here duplication of mag field and be informations is needed to allow seed and track cand histos to be independent
            // magnetic field
            MagneticField const& theMF = iSetup.getData(magneticFieldToken_);

            // get the beam spot
            edm::Handle<reco::BeamSpot> recoBeamSpotHandle = iEvent.getHandle(bsSrcToken_);
            const reco::BeamSpot& bs = *recoBeamSpotHandle;

            TransientTrackingRecHitBuilder const& theTTRHBuilder = iSetup.getData(transientTrackingRecHitBuilderToken_);
            for (size_t i = 0; i < seedCollection.size(); ++i) {
              theTrackBuildingAnalyzer->analyze(
                  iEvent, iSetup, seedCollection[i], seedStopInfo[i], bs, theMF, theTTRHBuilder);
            }
          } else {
            edm::LogWarning("TrackingMonitor")
                << "Seed collection size (" << seedCollection.size()
                << ") differs from seed stop info collection size (" << seedStopInfo.size()
                << "). This is a sign of inconsistency in the configuration. Not filling associated histograms.";
          }
        }

      } else {
        edm::LogWarning("TrackingMonitor") << "No Trajectory seeds in the event.  Not filling associated histograms";
      }
    }

    // plots for tracking regions
    if (doRegionPlots) {
      if (!regionToken_.isUninitialized()) {
        edm::Handle<edm::OwnVector<TrackingRegion> > hregions = iEvent.getHandle(regionToken_);
        const auto& regions = *hregions;
        NumberOfTrackingRegions->Fill(regions.size());

        theTrackBuildingAnalyzer->analyze(regions);
      } else if (!regionLayerSetsToken_.isUninitialized()) {
        edm::Handle<TrackingRegionsSeedingLayerSets> hregions = iEvent.getHandle(regionLayerSetsToken_);
        const auto& regions = *hregions;
        NumberOfTrackingRegions->Fill(regions.regionsSize());

        theTrackBuildingAnalyzer->analyze(regions);
      }

      if (doRegionCandidatePlots) {
        edm::Handle<reco::CandidateView> hcandidates = iEvent.getHandle(regionCandidateToken_);
        theTrackBuildingAnalyzer->analyze(*hcandidates);
      }
    }

    if (doTrackerSpecific_ || doAllPlots) {
      std::vector<int> NClus;
      setNclus(iEvent, NClus);
      for (uint i = 0; i < ClusterLabels.size(); i++) {
        NumberOfTrkVsClusters[i]->Fill(NClus[i], numberOfTracks);
      }
    }

    if (doPUmonitoring_) {
      // do vertex monitoring
      for (size_t i = 0; i < theVertexMonitor.size(); i++)
        theVertexMonitor[i]->analyze(iEvent, iSetup);
    }
    if (doPlotsVsGoodPVtx_) {
      size_t totalNumGoodPV = 0;
      if (pvHandle.isValid()) {
        for (reco::VertexCollection::const_iterator pv = pvHandle->begin(); pv != pvHandle->end(); ++pv) {
          //--- pv fake (the pv collection should have size==1 and the pv==beam spot)
          if (pv->isFake() || pv->tracksSize() == 0)
            continue;

          // definition of goodOfflinePrimaryVertex
          if (pv->ndof() < pvNDOF_ || pv->z() > 24.)
            continue;
          totalNumGoodPV++;
        }

        NumberEventsOfVsGoodPVtx->Fill(float(totalNumGoodPV));
        NumberOfTracksVsGoodPVtx->Fill(float(totalNumGoodPV), numberOfTracks);
        if (totalNumGoodPV > 1)
          NumberOfTracksVsPUPVtx->Fill(totalNumGoodPV - 1,
                                       double(numberOfTracks - numberOfTracks_pv0) / double(totalNumGoodPV - 1));
        NumberOfPVtxVsGoodPVtx->Fill(float(totalNumGoodPV), pvHandle->size());

        for (edm::View<reco::Track>::const_iterator track = trackCollection.begin(); track != trackCollection.end();
             ++track) {
          NumberOfRecHitsPerTrackVsGoodPVtx->Fill(float(totalNumGoodPV), track->numberOfValidHits());
        }

        if (doProfilesVsLS_ || doAllPlots)
          NumberOfGoodPVtxVsLS->Fill(static_cast<double>(iEvent.id().luminosityBlock()), totalNumGoodPV);
        if (doPlotsVsBX_ || doAllPlots)
          NumberOfGoodPVtxVsBX->Fill(bx, float(totalNumGoodPV));

        if (doFractionPlot_)
          GoodTracksFractionVsGoodPVtx->Fill(float(totalNumGoodPV), frac);

        if (doPlotsVsLUMI_ || doAllPlots)
          NumberOfGoodPVtxVsLUMI->Fill(lumi, float(totalNumGoodPV));
      }

      std::vector<int> NClus;
      setNclus(iEvent, NClus);
      std::ostringstream ss;
      ss << "VI stat " << totalNumGoodPV << ' ' << numberOfTracks;
      for (uint i = 0; i < ClusterLabels.size(); i++) {
        ss << ' ' << NClus[i];
        if (doPlotsVsLUMI_ || doAllPlots) {
          if (ClusterLabels[i] == "Pix")
            NumberOfPixelClustersVsLUMI->Fill(lumi, NClus[i]);
          if (ClusterLabels[i] == "Strip")
            NumberOfStripClustersVsLUMI->Fill(lumi, NClus[i]);
        }
        if (ClusterLabels[i] == "Pix")
          NumberOfPixelClustersVsGoodPVtx->Fill(float(totalNumGoodPV), NClus[i]);
        if (ClusterLabels[i] == "Strip")
          NumberOfStripClustersVsGoodPVtx->Fill(float(totalNumGoodPV), NClus[i]);
      }
      COUT(MEFolderName) << ss.str() << std::endl;
      if (doPlotsVsBXlumi_) {
        double bxlumi = theLumiDetails_->getValue(iEvent);
        NumberOfTracksVsBXlumi->Fill(bxlumi, numberOfTracks);
      }

      if (doProfilesVsLS_ || doAllPlots)
        if (totalNumGoodPV != 0)
          NumberOfGoodPVtxWO0VsLS->Fill(static_cast<double>(iEvent.id().luminosityBlock()), float(totalNumGoodPV));
      if (doPlotsVsBX_ || doAllPlots)
        if (totalNumGoodPV != 0)
          NumberOfGoodPVtxWO0VsBX->Fill(bx, float(totalNumGoodPV));
      if (doPlotsVsLUMI_ || doAllPlots)
        if (totalNumGoodPV != 0)
          NumberOfGoodPVtxWO0VsLUMI->Fill(lumi, float(totalNumGoodPV));

    }  // PU monitoring

  }  // trackHandle is valid
}

void TrackingMonitor::setMaxMinBin(std::vector<double>& arrayMin,
                                   std::vector<double>& arrayMax,
                                   std::vector<int>& arrayBin,
                                   double smin,
                                   double smax,
                                   int sbin,
                                   double pmin,
                                   double pmax,
                                   int pbin) {
  arrayMin.resize(ClusterLabels.size());
  arrayMax.resize(ClusterLabels.size());
  arrayBin.resize(ClusterLabels.size());

  for (uint i = 0; i < ClusterLabels.size(); ++i) {
    if (ClusterLabels[i] == "Pix") {
      arrayMin[i] = pmin;
      arrayMax[i] = pmax;
      arrayBin[i] = pbin;
    } else if (ClusterLabels[i] == "Strip") {
      arrayMin[i] = smin;
      arrayMax[i] = smax;
      arrayBin[i] = sbin;
    } else if (ClusterLabels[i] == "Tot") {
      arrayMin[i] = smin;
      arrayMax[i] = smax + pmax;
      arrayBin[i] = sbin;
    } else {
      edm::LogWarning("TrackingMonitor") << "Cluster Label " << ClusterLabels[i]
                                         << " not defined, using strip parameters ";
      arrayMin[i] = smin;
      arrayMax[i] = smax;
      arrayBin[i] = sbin;
    }
  }
}

void TrackingMonitor::setNclus(const edm::Event& iEvent, std::vector<int>& arrayNclus) {
  int ncluster_pix = -1;
  int ncluster_strip = -1;

  edm::Handle<edmNew::DetSetVector<SiStripCluster> > strip_clusters = iEvent.getHandle(stripClustersToken_);
  edm::Handle<edmNew::DetSetVector<SiPixelCluster> > pixel_clusters = iEvent.getHandle(pixelClustersToken_);

  if (strip_clusters.isValid() && pixel_clusters.isValid()) {
    ncluster_pix = (*pixel_clusters).dataSize();
    ncluster_strip = (*strip_clusters).dataSize();
  }

  arrayNclus.resize(ClusterLabels.size());
  for (uint i = 0; i < ClusterLabels.size(); ++i) {
    if (ClusterLabels[i] == "Pix")
      arrayNclus[i] = ncluster_pix;
    else if (ClusterLabels[i] == "Strip")
      arrayNclus[i] = ncluster_strip;
    else if (ClusterLabels[i] == "Tot")
      arrayNclus[i] = ncluster_pix + ncluster_strip;
    else {
      edm::LogWarning("TrackingMonitor") << "Cluster Label " << ClusterLabels[i]
                                         << " not defined using stri parametrs ";
      arrayNclus[i] = ncluster_strip;
    }
  }
}
DEFINE_FWK_MODULE(TrackingMonitor);