TrackAnalyzer.h

#ifndef TrackAnalyzer_H
#define TrackAnalyzer_H
// -*- C++ -*-
//
// 
/**\class TrackingAnalyzer TrackingAnalyzer.cc 
Monitoring source for general quantities related to tracks.
*/
// Original Author:  Suchandra Dutta, Giorgia Mila
//         Created:  Thu 28 22:45:30 CEST 2008

#include <memory>
#include <fstream>
#include <unordered_map>
#include "FWCore/Utilities/interface/EDGetToken.h"
#include "FWCore/Framework/interface/ConsumesCollector.h"
#include "FWCore/Framework/interface/Frameworkfwd.h"
#include "FWCore/Framework/interface/EDAnalyzer.h"
#include "FWCore/Framework/interface/Event.h"
#include "FWCore/Framework/interface/MakerMacros.h"
#include "FWCore/ParameterSet/interface/ParameterSet.h"
#include "FWCore/ServiceRegistry/interface/Service.h"
#include "DQMServices/Core/interface/MonitorElement.h"

#include "DataFormats/BeamSpot/interface/BeamSpot.h"
#include "DataFormats/VertexReco/interface/Vertex.h"
#include "DataFormats/VertexReco/interface/VertexFwd.h"

class DQMStore;

class BeamSpot;
class TrackAnalyzer 
{
    public:
        TrackAnalyzer(const edm::ParameterSet&);
	TrackAnalyzer(const edm::ParameterSet&, edm::ConsumesCollector& iC);
        virtual ~TrackAnalyzer();
        virtual void initHisto(DQMStore::IBooker & ibooker, const edm::EventSetup &);

        virtual void analyze(const edm::Event& iEvent, const edm::EventSetup& iSetup, const reco::Track& track);

        void doSoftReset  (DQMStore * dqmStore_);
        void doReset      ();
        void undoSoftReset(DQMStore * dqmStore_);
        void setLumiFlag();
        // Compute and locally store the number of Good vertices found
        // in the event. This information is used as X-axis value in
        // the hit-efficiency plots derived from the hit patter. This
        // ugly design to avoid comuting this very same quantity for
        // each and every track while in the analyze method. A
        // redesign of the class is needed in the future.
        void setNumberOfGoodVertices(const edm::Event &);
        void setBX(const edm::Event &);

    private:
	void initHistos();
        void fillHistosForState(const edm::EventSetup& iSetup, const reco::Track & track, std::string sname);
        void bookHistosForState(std::string sname,DQMStore::IBooker & ibooker);
        void bookHistosForHitProperties(DQMStore::IBooker & ibooker);
	void bookHistosForLScertification(DQMStore::IBooker & ibooker);
	void bookHistosForBeamSpot(DQMStore::IBooker & ibooker);
        void bookHistosForTrackerSpecific(DQMStore::IBooker & ibooker);
        void bookHistosForEfficiencyFromHitPatter(DQMStore::IBooker &ibooker, const edm::EventSetup & iSetup, const std::string suffix);
        void fillHistosForHitProperties(const edm::EventSetup& iSetup, const reco::Track & track, std::string sname);
	void fillHistosForLScertification(const edm::EventSetup& iSetup, const reco::Track & track, std::string sname);
        void fillHistosForTrackerSpecific(const reco::Track & track);
        void fillHistosForEfficiencyFromHitPatter(const reco::Track & track, const std::string suffix, const unsigned int monitoring);

        // ----------member data ---------------------------
	std::string TopFolder_;

	edm::EDGetTokenT<reco::BeamSpot> beamSpotToken_;
	edm::EDGetTokenT<reco::VertexCollection> pvToken_;
	
        edm::ParameterSet conf_;

        bool doTrackerSpecific_;
        bool doAllPlots_;
        bool doBSPlots_;
        bool doPVPlots_;
	bool doDCAPlots_;
	bool doGeneralPropertiesPlots_;
	bool doMeasurementStatePlots_;
	bool doHitPropertiesPlots_;
	bool doRecHitVsPhiVsEtaPerTrack_;
	// ADD by Mia
	bool doLayersVsPhiVsEtaPerTrack_;
	bool doTrackRecHitVsPhiVsEtaPerTrack_;
	bool doTrackLayersVsPhiVsEtaPerTrack_;
	bool doTrack2DChi2Plots_;
	bool doRecHitsPerTrackProfile_;
	// ADD by Mia in order to clean the tracking MEs
	// do not plot *Theta* and TrackPx* and TrackPy*
	bool doThetaPlots_;
	bool doTrackPxPyPlots_;
	// ADD by Mia in order to not plot DistanceOfClosestApproach w.r.t. (0,0,0)
	// the DistanceOfClosestApproach w.r.t. the beam-spot is already shown in DistanceOfClosestApproachToBS
	bool doDCAwrtPVPlots_;
	bool doDCAwrt000Plots_;

	bool doLumiAnalysis_;

	// ADD by Mia in order to turnON test MEs
	bool doTestPlots_;

	//For HI Plots
	bool doHIPlots_;

        // IP significance plots
        bool doSIPPlots_;

        // Compute the hit-finding efficiency using the HitPattern of
        // the reconstructed tracks
        bool doEffFromHitPatternVsPU_;
        bool doEffFromHitPatternVsBX_;
	int  pvNDOF_;
	std::string qualityString_;
	
        struct TkParameterMEs {
	  TkParameterMEs() :
	    TrackP(NULL)
	    , TrackPx(NULL)
	    , TrackPy(NULL)
	    , TrackPz(NULL)
	    , TrackPt(NULL)
	    
	    , TrackPxErr(NULL)
	    , TrackPyErr(NULL)
	    , TrackPzErr(NULL)
	    , TrackPtErr(NULL)
	    , TrackPErr(NULL)
	    
	    , TrackPtErrVsEta(NULL)
	    
	    , TrackQ(NULL)
	    
	    , TrackPhi(NULL)
	    , TrackEta(NULL)
	    , TrackTheta(NULL)
	    
	    , TrackPhiErr(NULL)
	    , TrackEtaErr(NULL)
	    , TrackThetaErr(NULL)
	    
	    , NumberOfRecHitsPerTrackVsPhi(NULL)
	    , NumberOfRecHitsPerTrackVsTheta(NULL)
	    , NumberOfRecHitsPerTrackVsEta(NULL)
	    , NumberOfRecHitVsPhiVsEtaPerTrack(NULL)
	    
	    , NumberOfValidRecHitsPerTrackVsPhi(NULL)
	    , NumberOfValidRecHitsPerTrackVsTheta(NULL)
	    , NumberOfValidRecHitsPerTrackVsEta(NULL)
	    , NumberOfValidRecHitVsPhiVsEtaPerTrack(NULL)

            , NumberOfLostRecHitsPerTrackVsPhi(NULL)
            , NumberOfLostRecHitsPerTrackVsTheta(NULL)
            , NumberOfLostRecHitsPerTrackVsEta(NULL)
            , NumberOfLostRecHitVsPhiVsEtaPerTrack(NULL)

            , NumberOfMIRecHitsPerTrackVsPhi(NULL)
            , NumberOfMIRecHitsPerTrackVsTheta(NULL)
            , NumberOfMIRecHitsPerTrackVsEta(NULL)
            , NumberOfMIRecHitVsPhiVsEtaPerTrack(NULL)

            , NumberOfMORecHitsPerTrackVsPhi(NULL)
            , NumberOfMORecHitsPerTrackVsTheta(NULL)
            , NumberOfMORecHitsPerTrackVsEta(NULL)
            , NumberOfMORecHitVsPhiVsEtaPerTrack(NULL)
    
	    , NumberOfLayersPerTrackVsPhi(NULL)
	    , NumberOfLayersPerTrackVsTheta(NULL)
	    , NumberOfLayersPerTrackVsEta(NULL)

	    , Chi2oNDFVsEta(NULL)
	    , Chi2oNDFVsPhi(NULL)
	    , Chi2oNDFVsTheta(NULL)

	    , Chi2ProbVsEta(NULL)
	    , Chi2ProbVsPhi(NULL)
	    , Chi2ProbVsTheta(NULL)
	  {}
	  
	  MonitorElement* TrackP;
	  MonitorElement* TrackPx;
	  MonitorElement* TrackPy;
	  MonitorElement* TrackPz;
	  MonitorElement* TrackPt;
	  
	  MonitorElement* TrackPxErr;
	  MonitorElement* TrackPyErr;
	  MonitorElement* TrackPzErr;
	  MonitorElement* TrackPtErr;
	  MonitorElement* TrackPErr;
	  
	  MonitorElement* TrackPtErrVsEta;
	  
	  MonitorElement* TrackQ;
	  
	  MonitorElement* TrackPhi;
	  MonitorElement* TrackEta;
          MonitorElement* TrackEtaPhi=nullptr;
          MonitorElement* TrackEtaPhiInner=nullptr;
          MonitorElement* TrackEtaPhiOuter=nullptr;

	  MonitorElement* TrackTheta;
	  
	  MonitorElement* TrackPhiErr;
	  MonitorElement* TrackEtaErr;
	  MonitorElement* TrackThetaErr;
	  
	  MonitorElement* NumberOfRecHitsPerTrackVsPhi;
	  MonitorElement* NumberOfRecHitsPerTrackVsTheta;
	  MonitorElement* NumberOfRecHitsPerTrackVsEta;
	  MonitorElement* NumberOfRecHitVsPhiVsEtaPerTrack;
	  
	  MonitorElement* NumberOfValidRecHitsPerTrackVsPhi;
	  MonitorElement* NumberOfValidRecHitsPerTrackVsTheta;
	  MonitorElement* NumberOfValidRecHitsPerTrackVsEta;
	  MonitorElement* NumberOfValidRecHitVsPhiVsEtaPerTrack;

          MonitorElement* NumberOfLostRecHitsPerTrackVsPhi;
          MonitorElement* NumberOfLostRecHitsPerTrackVsTheta;
          MonitorElement* NumberOfLostRecHitsPerTrackVsEta;
          MonitorElement* NumberOfLostRecHitVsPhiVsEtaPerTrack;

          MonitorElement* NumberOfMIRecHitsPerTrackVsPhi;
          MonitorElement* NumberOfMIRecHitsPerTrackVsTheta;
          MonitorElement* NumberOfMIRecHitsPerTrackVsEta;
          MonitorElement* NumberOfMIRecHitVsPhiVsEtaPerTrack;

          MonitorElement* NumberOfMORecHitsPerTrackVsPhi;
          MonitorElement* NumberOfMORecHitsPerTrackVsTheta;
          MonitorElement* NumberOfMORecHitsPerTrackVsEta;
          MonitorElement* NumberOfMORecHitVsPhiVsEtaPerTrack;

	  MonitorElement* NumberOfLayersPerTrackVsPhi;
	  MonitorElement* NumberOfLayersPerTrackVsTheta;
	  MonitorElement* NumberOfLayersPerTrackVsEta;

	  MonitorElement* Chi2oNDFVsEta;
	  MonitorElement* Chi2oNDFVsPhi;
	  MonitorElement* Chi2oNDFVsTheta;
	  
	  MonitorElement* Chi2ProbVsEta;
	  MonitorElement* Chi2ProbVsPhi;
	  MonitorElement* Chi2ProbVsTheta;
	
	};
        std::map<std::string, TkParameterMEs> TkParameterMEMap;
	
	
	MonitorElement* NumberOfRecHitsPerTrack;
	MonitorElement* NumberOfValidRecHitsPerTrack;
	MonitorElement* NumberOfLostRecHitsPerTrack;
        MonitorElement* NumberOfMIRecHitsPerTrack = nullptr;
        MonitorElement* NumberOfMORecHitsPerTrack = nullptr;

	
	MonitorElement* NumberOfRecHitsPerTrackVsPhi = nullptr;
	MonitorElement* NumberOfRecHitsPerTrackVsTheta = nullptr;
	MonitorElement* NumberOfRecHitsPerTrackVsEta = nullptr;
	MonitorElement* NumberOfRecHitVsPhiVsEtaPerTrack = nullptr;
	
	MonitorElement* NumberOfValidRecHitsPerTrackVsPhi = nullptr;
	MonitorElement* NumberOfValidRecHitsPerTrackVsTheta = nullptr;
	MonitorElement* NumberOfValidRecHitsPerTrackVsEta = nullptr;
	MonitorElement* NumberOfValidRecHitVsPhiVsEtaPerTrack = nullptr;

          MonitorElement* NumberOfLostRecHitsPerTrackVsPhi = nullptr;
          MonitorElement* NumberOfLostRecHitsPerTrackVsTheta = nullptr;
          MonitorElement* NumberOfLostRecHitsPerTrackVsEta = nullptr;
          MonitorElement* NumberOfLostRecHitVsPhiVsEtaPerTrack = nullptr;

          MonitorElement* NumberOfMIRecHitsPerTrackVsPhi = nullptr;
          MonitorElement* NumberOfMIRecHitsPerTrackVsTheta = nullptr;
          MonitorElement* NumberOfMIRecHitsPerTrackVsEta = nullptr;
          MonitorElement* NumberOfMIRecHitVsPhiVsEtaPerTrack = nullptr;

          MonitorElement* NumberOfMORecHitsPerTrackVsPhi = nullptr;
          MonitorElement* NumberOfMORecHitsPerTrackVsTheta = nullptr;
          MonitorElement* NumberOfMORecHitsPerTrackVsEta = nullptr;
          MonitorElement* NumberOfMORecHitVsPhiVsEtaPerTrack = nullptr;

          MonitorElement* ValidFractionPerTrack = nullptr;
          MonitorElement* ValidFractionVsPhiVsEtaPerTrack = nullptr;

	
	MonitorElement* NumberOfLayersPerTrack[4] = {nullptr,nullptr,nullptr,nullptr};
	
	MonitorElement* NumberOfLayersPerTrackVsPhi;
	MonitorElement* NumberOfLayersPerTrackVsTheta;
	MonitorElement* NumberOfLayersPerTrackVsEta;

	MonitorElement* NumberOfLayersVsPhiVsEtaPerTrack[4]= {nullptr,nullptr,nullptr,nullptr};

	MonitorElement* Chi2;
	MonitorElement* Chi2Prob;
	MonitorElement* Chi2oNDF;

	MonitorElement* Chi2oNDFVsEta;
	MonitorElement* Chi2oNDFVsPhi;
	MonitorElement* Chi2oNDFVsTheta;
	
	MonitorElement* Chi2ProbVsEta;
	MonitorElement* Chi2ProbVsPhi;
	MonitorElement* Chi2ProbVsTheta;
	
	MonitorElement* DistanceOfClosestApproach;
	MonitorElement* DistanceOfClosestApproachToBS;
	MonitorElement* DistanceOfClosestApproachToPV;
	MonitorElement* DistanceOfClosestApproachVsTheta;
	MonitorElement* DistanceOfClosestApproachVsPhi;
	MonitorElement* DistanceOfClosestApproachToBSVsPhi;
	MonitorElement* DistanceOfClosestApproachToPVVsPhi;
	MonitorElement* DistanceOfClosestApproachVsEta;
	MonitorElement* xPointOfClosestApproach;
	MonitorElement* xPointOfClosestApproachToPV;
	MonitorElement* xPointOfClosestApproachVsZ0wrt000;
	MonitorElement* xPointOfClosestApproachVsZ0wrtBS;
	MonitorElement* xPointOfClosestApproachVsZ0wrtPV;
	MonitorElement* yPointOfClosestApproach;
	MonitorElement* yPointOfClosestApproachToPV;
	MonitorElement* yPointOfClosestApproachVsZ0wrt000;
	MonitorElement* yPointOfClosestApproachVsZ0wrtBS;
	MonitorElement* yPointOfClosestApproachVsZ0wrtPV;
	MonitorElement* zPointOfClosestApproach;
	MonitorElement* zPointOfClosestApproachToPV;
	MonitorElement* zPointOfClosestApproachVsPhi;
	MonitorElement *algorithm, *oriAlgo;
	MonitorElement *stoppingSource;
	MonitorElement *stoppingSourceVSeta;
	MonitorElement *stoppingSourceVSphi;
	// TESTING MEs
	MonitorElement* TESTDistanceOfClosestApproachToBS;
	MonitorElement* TESTDistanceOfClosestApproachToBSVsPhi;
	
	// add by Mia in order to deal w/ LS transitions
	MonitorElement* Chi2oNDF_lumiFlag;
	MonitorElement* NumberOfRecHitsPerTrack_lumiFlag;

	//new plots for Heavy Ion DQM
	MonitorElement* LongDCASig;
	MonitorElement* TransDCASig;
	MonitorElement* dNdPhi_HighPurity;
	MonitorElement* dNdEta_HighPurity;
	MonitorElement* dNdPt_HighPurity;
	MonitorElement* NhitVsEta_HighPurity;
	MonitorElement* NhitVsPhi_HighPurity;
	MonitorElement* Ptdist_HighPurity;
	MonitorElement* dNhitdPt_HighPurity;

	// IP significance plots
	MonitorElement *sipDxyToBS;
	MonitorElement *sipDzToBS;
	MonitorElement *sip3dToPV;
	MonitorElement *sip2dToPV;
	MonitorElement *sipDxyToPV;
	MonitorElement *sipDzToPV;
	
	struct TkRecHitsPerSubDetMEs {
	  MonitorElement* NumberOfRecHitsPerTrack;
	  MonitorElement* NumberOfRecHitsPerTrackVsPhi;
	  MonitorElement* NumberOfRecHitsPerTrackVsEta;
	  MonitorElement* NumberOfLayersPerTrack;
	  MonitorElement* NumberOfLayersPerTrackVsPhi;
	  MonitorElement* NumberOfLayersPerTrackVsEta;
	  
	  int         detectorId;
	  std::string detectorTag;
	};
        std::map<std::string, TkRecHitsPerSubDetMEs> TkRecHitsPerSubDetMEMap;
	
        struct Key {
          int det;
          int subdet;
	  int monitoring;
          explicit Key(int det, int subdet,int monitoring):det(det),subdet(subdet),monitoring(monitoring){};
          bool operator==(const Key & other) const {
            return (det == other.det && subdet == other.subdet && monitoring == other.monitoring);
          }
        };

        // Trivial hasher function: warning, it only works if det has less than 99 subdets.
        struct KeyHasher {
          std::size_t operator()(const Key& k) const {
            return k.det*100+k.subdet;
          }
        };

        std::unordered_map<Key, MonitorElement *, KeyHasher> hits_valid_;
        std::unordered_map<Key, MonitorElement *, KeyHasher> hits_missing_;
        std::unordered_map<Key, MonitorElement *, KeyHasher> hits_inactive_;
        std::unordered_map<Key, MonitorElement *, KeyHasher> hits_bad_;
        std::unordered_map<Key, MonitorElement *, KeyHasher> hits_total_;
        unsigned int good_vertices_;
        unsigned int bx_;
	enum monQuantity {
	  VsPU,
	  VsBX,
	  END
	};
	std::string monName[monQuantity::END] = { "", "VsBX" };

        std::string histname;  //for naming the histograms according to algorithm used
};
#endif