#include <DQM/TrackerMonitorTrack/src/TrackingMonitor.cc>

Inheritance diagram for TrackingMonitor:

Public Types
using	MVACollection = std::vector< float >

using	QualityMaskCollection = std::vector< unsigned char >

Public Types inherited from DQMEDAnalyzer
typedef dqm::reco::DQMStore	DQMStore

typedef dqm::reco::MonitorElement	MonitorElement

Public Types inherited from edm::stream::EDProducer< edm::GlobalCache< DQMEDAnalyzerGlobalCache >, edm::EndRunProducer, edm::EndLuminosityBlockProducer, edm::Accumulator >
using	CacheTypes = CacheContexts< T... >

using	GlobalCache = typename CacheTypes::GlobalCache

using	HasAbility = AbilityChecker< T... >

using	InputProcessBlockCache = typename CacheTypes::InputProcessBlockCache

using	LuminosityBlockCache = typename CacheTypes::LuminosityBlockCache

using	LuminosityBlockContext = LuminosityBlockContextT< LuminosityBlockCache, RunCache, GlobalCache >

using	LuminosityBlockSummaryCache = typename CacheTypes::LuminosityBlockSummaryCache

using	RunCache = typename CacheTypes::RunCache

using	RunContext = RunContextT< RunCache, GlobalCache >

using	RunSummaryCache = typename CacheTypes::RunSummaryCache

Public Member Functions
void	analyze (const edm::Event &, const edm::EventSetup &) override

void	bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override

virtual void	setMaxMinBin (std::vector< double > &, std::vector< double > &, std::vector< int > &, double, double, int, double, double, int)

virtual void	setNclus (const edm::Event &, std::vector< int > &)

	TrackingMonitor (const edm::ParameterSet &)

	~TrackingMonitor () override

Public Member Functions inherited from DQMEDAnalyzer
void	accumulate (edm::Event const &event, edm::EventSetup const &setup) final

void	beginLuminosityBlock (edm::LuminosityBlock const &lumi, edm::EventSetup const &setup) final

void	beginRun (edm::Run const &run, edm::EventSetup const &setup) final

void	beginStream (edm::StreamID id) final

virtual void	dqmBeginRun (edm::Run const &, edm::EventSetup const &)

	DQMEDAnalyzer ()

void	endLuminosityBlock (edm::LuminosityBlock const &lumi, edm::EventSetup const &setup) final

void	endRun (edm::Run const &run, edm::EventSetup const &setup) final

virtual bool	getCanSaveByLumi ()

Public Member Functions inherited from edm::stream::EDProducer< edm::GlobalCache< DQMEDAnalyzerGlobalCache >, edm::EndRunProducer, edm::EndLuminosityBlockProducer, edm::Accumulator >
	EDProducer ()=default

	EDProducer (const EDProducer &)=delete

bool	hasAbilityToProduceInBeginLumis () const final

bool	hasAbilityToProduceInBeginProcessBlocks () const final

bool	hasAbilityToProduceInBeginRuns () const final

bool	hasAbilityToProduceInEndLumis () const final

bool	hasAbilityToProduceInEndProcessBlocks () const final

bool	hasAbilityToProduceInEndRuns () const final

const EDProducer &	operator= (const EDProducer &)=delete

Private Member Functions
void	doProfileX (TH2 th2, MonitorElement me)

void	doProfileX (MonitorElement th2m, MonitorElement me)

Private Attributes
std::string	AlgoName_

edm::EDGetTokenT< edm::View< reco::Track > >	allTrackToken_

edm::InputTag	bsSrc_

edm::EDGetTokenT< reco::BeamSpot >	bsSrcToken_

std::string	builderName

std::vector< std::string >	ClusterLabels

edm::ParameterSetID	confID_

StringCutObjectSelector< reco::Track, true >	denSelection_

bool	doAllPlots

bool	doAllSeedPlots

bool	doDCAPlots_

bool	doFractionPlot_

bool	doGeneralPropertiesPlots_

bool	doHitPropertiesPlots_

bool	doLumiAnalysis

bool	doMVAPlots

bool	doPlotsVsBX_

bool	doPlotsVsBXlumi_

bool	doPlotsVsGoodPVtx_

bool	doPlotsVsLUMI_

bool	doProfilesVsLS_

bool	doPUmonitoring_

bool	doRegionCandidatePlots

bool	doRegionPlots

bool	doSeedLumiAnalysis_

bool	doSeedNumberPlot

bool	doSeedVsClusterPlot

bool	doTkCandPlots

bool	doTrackerSpecific_

const bool	forceSCAL_

MonitorElement *	FractionCandidatesOverSeeds

MonitorElement *	FractionOfGoodTracks

GenericTriggerEventFlag *	genTriggerEventFlag_

MonitorElement *	GoodTracksFractionVsBX

MonitorElement *	GoodTracksFractionVsGoodPVtx

MonitorElement *	GoodTracksFractionVsLS

MonitorElement *	GoodTracksFractionVsLUMI

std::string	histname

edm::EDGetTokenT< LumiScalersCollection >	lumiscalersToken_

edm::ESGetToken< MagneticField, IdealMagneticFieldRecord >	magneticFieldToken_

std::string	MEFolderName

edm::EDGetTokenT< OnlineLuminosityRecord >	metaDataToken_

std::vector< std::tuple< edm::EDGetTokenT< MVACollection >, edm::EDGetTokenT< QualityMaskCollection > > >	mvaQualityTokens_

edm::EDGetTokenT< edm::View< reco::Track > >	mvaTrackToken_

MonitorElement *	NumberEventsOfVsBX

MonitorElement *	NumberEventsOfVsGoodPVtx

MonitorElement *	NumberEventsOfVsLS

MonitorElement *	NumberEventsOfVsLUMI

MonitorElement *	NumberOfGoodPVtxVsBX

MonitorElement *	NumberOfGoodPVtxVsLS

MonitorElement *	NumberOfGoodPVtxVsLUMI

MonitorElement *	NumberOfGoodPVtxWO0VsBX

MonitorElement *	NumberOfGoodPVtxWO0VsLS

MonitorElement *	NumberOfGoodPVtxWO0VsLUMI

MonitorElement *	NumberOfMeanLayersPerTrack

MonitorElement *	NumberOfMeanRecHitsPerTrack

MonitorElement *	NumberOfPixelClustersVsGoodPVtx

MonitorElement *	NumberOfPixelClustersVsLUMI

MonitorElement *	NumberOfPVtxVsGoodPVtx

MonitorElement *	NumberOfRecHitsPerTrackVsBX

MonitorElement *	NumberOfRecHitsPerTrackVsGoodPVtx

MonitorElement *	NumberOfRecHitsPerTrackVsLS

MonitorElement *	NumberOfRecHitsPerTrackVsLUMI

MonitorElement *	NumberOfSeeds

MonitorElement *	NumberOfSeeds_lumiFlag

MonitorElement *	NumberOfStripClustersVsGoodPVtx

MonitorElement *	NumberOfStripClustersVsLUMI

MonitorElement *	NumberOfTrackCandidates

MonitorElement *	NumberOfTrackingRegions

MonitorElement *	NumberOfTracks

MonitorElement *	NumberofTracks_Hardvtx

MonitorElement *	NumberofTracks_Hardvtx_PUvtx

MonitorElement *	NumberOfTracks_lumiFlag

MonitorElement *	NumberOfTracks_PUvtx

MonitorElement *	NumberOfTracksVsBX

MonitorElement *	NumberOfTracksVsBXlumi

MonitorElement *	NumberOfTracksVsGoodPVtx

MonitorElement *	NumberOfTracksVsLS

MonitorElement *	NumberOfTracksVsLUMI

MonitorElement *	NumberOfTracksVsPUPVtx

MonitorElement *	NumberOfTrkVsClus

std::vector< MonitorElement * >	NumberOfTrkVsClusters

MonitorElement *	NumberOfTrkVsPixelClus

MonitorElement *	NumberOfTrkVsStripClus

StringCutObjectSelector< reco::Track, true >	numSelection_

edm::InputTag	pixelClusterInputTag_

edm::EDGetTokenT< edmNew::DetSetVector< SiPixelCluster > >	pixelClustersToken_

int	pvNDOF_

edm::InputTag	pvSrc_

edm::EDGetTokenT< reco::VertexCollection >	pvSrcToken_

std::string	Quality_

edm::EDGetTokenT< reco::CandidateView >	regionCandidateToken_

edm::EDGetTokenT< TrackingRegionsSeedingLayerSets >	regionLayerSetsToken_

edm::EDGetTokenT< edm::OwnVector< TrackingRegion > >	regionToken_

bool	runTrackBuildingAnalyzerForSeed

edm::EDGetTokenT< std::vector< SeedStopInfo > >	seedStopInfoToken_

std::vector< MonitorElement * >	SeedsVsClusters

edm::EDGetTokenT< edm::View< TrajectorySeed > >	seedToken_

edm::InputTag	stripClusterInputTag_

edm::EDGetTokenT< edmNew::DetSetVector< SiStripCluster > >	stripClustersToken_

GetLumi *	theLumiDetails_

tadqm::TrackAnalyzer *	theTrackAnalyzer

TrackBuildingAnalyzer *	theTrackBuildingAnalyzer

std::vector< VertexMonitor * >	theVertexMonitor

edm::EDGetTokenT< TrackCandidateCollection >	trackCandidateToken_

edm::EDGetTokenT< edm::View< reco::Track > >	trackToken_

edm::ESGetToken< TransientTrackingRecHitBuilder, TransientRecHitRecord >	transientTrackingRecHitBuilderToken_

Additional Inherited Members
Static Public Member Functions inherited from DQMEDAnalyzer
static void	globalEndJob (DQMEDAnalyzerGlobalCache const *)

static void	globalEndLuminosityBlockProduce (edm::LuminosityBlock &lumi, edm::EventSetup const &setup, LuminosityBlockContext const *context)

static void	globalEndRunProduce (edm::Run &run, edm::EventSetup const &setup, RunContext const *context)

static std::unique_ptr< DQMEDAnalyzerGlobalCache >	initializeGlobalCache (edm::ParameterSet const &)

Protected Member Functions inherited from DQMEDAnalyzer
uint64_t	meId () const

Protected Attributes inherited from DQMEDAnalyzer
edm::EDPutTokenT< DQMToken >	lumiToken_

edm::EDPutTokenT< DQMToken >	runToken_

unsigned int	streamId_

Detailed Description

Monitoring source for general quantities related to tracks.

Definition at line 62 of file TrackingMonitor.h.

Member Typedef Documentation

◆ MVACollection

using TrackingMonitor::MVACollection = std::vector<float>

Definition at line 64 of file TrackingMonitor.h.

◆ QualityMaskCollection

using TrackingMonitor::QualityMaskCollection = std::vector<unsigned char>

Definition at line 65 of file TrackingMonitor.h.

Constructor & Destructor Documentation

◆ TrackingMonitor()

TrackingMonitor::TrackingMonitor ( const edm::ParameterSet & iConfig )

explicit

Definition at line 47 of file TrackingMonitor.cc.

References AlgoName_, allTrackToken_, bsSrc_, bsSrcToken_, builderName, c, doAllSeedPlots, doFractionPlot_, doMVAPlots, doPlotsVsBX_, doPlotsVsBXlumi_, doPlotsVsGoodPVtx_, doPlotsVsLUMI_, doPUmonitoring_, doRegionCandidatePlots, doRegionPlots, doTkCandPlots, Exception, edm::ParameterSet::getParameter(), mps_fire::i, edm::EDGetTokenT< T >::isUninitialized(), edm::InputTag::label(), lumiscalersToken_, magneticFieldToken_, metaDataToken_, mvaQualityTokens_, mvaTrackToken_, pixelClusterInputTag_, pixelClustersToken_, TrackerCollisionTrackingMonitor_cfi::primaryVertexInputTags, TrackerCollisionTrackingMonitor_cfi::pvLabels, pvSrc_, pvSrcToken_, Quality_, regionCandidateToken_, regionLayerSetsToken_, ValL1Emulator_cff::regionTag, regionToken_, runTrackBuildingAnalyzerForSeed, seedStopInfoToken_, seedToken_, TrackerCollisionTrackingMonitor_cfi::selPrimaryVertexInputTags, AlCaHLTBitMon_QueryRunRegistry::string, stripClusterInputTag_, stripClustersToken_, makeGlobalPositionRcd_cfg::tag, theLumiDetails_, theTrackAnalyzer, theVertexMonitor, trackCandidateToken_, L1TCSCTF_cfi::trackProducer, trackToken_, transientTrackingRecHitBuilderToken_, and edm::vector_transform().

     : 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::~TrackingMonitor ( )

override

Definition at line 227 of file TrackingMonitor.cc.

References doPUmonitoring_, genTriggerEventFlag_, mps_fire::i, theTrackAnalyzer, theTrackBuildingAnalyzer, and theVertexMonitor.

                                   {
   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_;
 }

Member Function Documentation

◆ analyze()

void TrackingMonitor::analyze	(	const edm::Event &	iEvent,
		const edm::EventSetup &	iSetup
	)

overridevirtual

Reimplemented from DQMEDAnalyzer.

Definition at line 741 of file TrackingMonitor.cc.

References funct::abs(), GenericTriggerEventFlag::accept(), allTrackToken_, TrackBuildingAnalyzer::analyze(), tadqm::TrackAnalyzer::analyze(), cms::cuda::bs, bsSrcToken_, simKBmtfDigis_cfi::bx, ClusterLabels, confID_, COUT, denSelection_, doAllPlots, doAllSeedPlots, doFractionPlot_, doGeneralPropertiesPlots_, doLumiAnalysis, doMVAPlots, doPlotsVsBX_, doPlotsVsBXlumi_, doPlotsVsGoodPVtx_, doPlotsVsLUMI_, doProfilesVsLS_, doPUmonitoring_, doRegionCandidatePlots, doRegionPlots, doSeedLumiAnalysis_, doSeedNumberPlot, doSeedVsClusterPlot, doTkCandPlots, doTrackerSpecific_, dqm::impl::MonitorElement::Fill(), forceSCAL_, DivergingColor::frac, FractionCandidatesOverSeeds, FractionOfGoodTracks, genTriggerEventFlag_, edm::EventSetup::getData(), edm::pset::Registry::getMapped(), GetLumi::getValue(), GoodTracksFractionVsBX, GoodTracksFractionVsGoodPVtx, GoodTracksFractionVsLS, GoodTracksFractionVsLUMI, mps_fire::i, iEvent, edm::pset::Registry::instance(), OnlineLuminosityRecord::instLumi(), reco::Vertex::isFake(), edm::EDGetTokenT< T >::isUninitialized(), edm::HandleBase::isValid(), V0Monitor_cfi::lumiScalers, lumiscalersToken_, magneticFieldToken_, MEFolderName, metaDataToken_, mvaQualityTokens_, mvaTrackToken_, reco::Vertex::ndof(), NumberEventsOfVsBX, NumberEventsOfVsGoodPVtx, NumberEventsOfVsLS, NumberEventsOfVsLUMI, NumberOfGoodPVtxVsBX, NumberOfGoodPVtxVsLS, NumberOfGoodPVtxVsLUMI, NumberOfGoodPVtxWO0VsBX, NumberOfGoodPVtxWO0VsLS, NumberOfGoodPVtxWO0VsLUMI, NumberOfMeanLayersPerTrack, NumberOfMeanRecHitsPerTrack, NumberOfPixelClustersVsGoodPVtx, NumberOfPixelClustersVsLUMI, NumberOfPVtxVsGoodPVtx, NumberOfRecHitsPerTrackVsBX, NumberOfRecHitsPerTrackVsGoodPVtx, NumberOfRecHitsPerTrackVsLS, NumberOfRecHitsPerTrackVsLUMI, NumberOfSeeds, NumberOfSeeds_lumiFlag, NumberOfStripClustersVsGoodPVtx, NumberOfStripClustersVsLUMI, NumberOfTrackCandidates, NumberOfTrackingRegions, NumberOfTracks, NumberofTracks_Hardvtx, NumberofTracks_Hardvtx_PUvtx, NumberOfTracks_lumiFlag, NumberOfTracks_PUvtx, NumberOfTracksVsBX, NumberOfTracksVsBXlumi, NumberOfTracksVsGoodPVtx, NumberOfTracksVsLS, NumberOfTracksVsLUMI, NumberOfTracksVsPUPVtx, NumberOfTrkVsClusters, numSelection_, GenericTriggerEventFlag::on(), reco::Vertex::position(), edm::Handle< T >::product(), MetAnalyzer::pv(), pvNDOF_, pvSrcToken_, regionCandidateToken_, regionLayerSetsToken_, regionToken_, runTrackBuildingAnalyzerForSeed, ElectronSeedTrackRefFix_cfi::seedCollection, seedStopInfoToken_, SeedsVsClusters, seedToken_, tadqm::TrackAnalyzer::setBX(), tadqm::TrackAnalyzer::setLumi(), setNclus(), tadqm::TrackAnalyzer::setNumberOfGoodVertices(), contentValuesCheck::ss, AlCaHLTBitMon_QueryRunRegistry::string, theLumiDetails_, theTrackAnalyzer, theTrackBuildingAnalyzer, theVertexMonitor, HLT_2022v15_cff::track, trackCandidateToken_, JetHT_cfg::trackCollection, reco::Vertex::tracksSize(), trackToken_, transientTrackingRecHitBuilderToken_, parallelization::uint, and reco::Vertex::z().

                                                                                  {
   // 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
 }

◆ bookHistograms()

void TrackingMonitor::bookHistograms	(	DQMStore::IBooker &	ibooker,
		edm::Run const &	iRun,
		edm::EventSetup const &	iSetup
	)

overridevirtual

Implements DQMEDAnalyzer.

Definition at line 240 of file TrackingMonitor.cc.

                                                                                                               {
   // 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);
 }

◆ doProfileX() [1/2]

void TrackingMonitor::doProfileX	(	TH2 *	th2,
		MonitorElement *	me
	)

private

◆ doProfileX() [2/2]

void TrackingMonitor::doProfileX	(	MonitorElement *	th2m,
		MonitorElement *	me
	)

private

◆ setMaxMinBin()

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
	)

virtual

Definition at line 1102 of file TrackingMonitor.cc.

References ClusterLabels, mps_fire::i, trackingParticleMuon_cfi::pmin, and parallelization::uint.

Referenced by bookHistograms().

                                              {
   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;
     }
   }
 }

◆ setNclus()

void TrackingMonitor::setNclus	(	const edm::Event &	iEvent,
		std::vector< int > &	arrayNclus
	)

virtual

Definition at line 1138 of file TrackingMonitor.cc.

References ClusterLabels, mps_fire::i, iEvent, edm::HandleBase::isValid(), pixelClustersToken_, stripClustersToken_, and parallelization::uint.

Referenced by analyze().

                                                                                  {
   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;
     }
   }
 }