#ifndef ALITRDCALIBRAFILLHISTO_H #define ALITRDCALIBRAFILLHISTO_H /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * See cxx source for full Copyright notice */ /* $Id$ */ /////////////////////////////////////////////////////////////////////////////// // // // TRD calibration class for the HLT parameters // // // /////////////////////////////////////////////////////////////////////////////// #ifndef ROOT_TObject # include #endif #ifndef ROOT_TProfile2D # include #endif class TProfile2D; class TObjArray; class TH1F; class TH2I; class TH2F; class TH2; class TLinearFitter; class TTreeSRedirector; class AliLog; class AliRawReader; class AliTRDCalibraMode; class AliTRDCalibraVector; class AliTRDCalibraVdriftLinearFit; class AliTRDcluster; class AliTRDtrackV1; class AliTRDseedV1; class AliTRDgeometry; class AliTRDCalDet; class AliTRDCalROC; class AliTRDcalibDB; class AliTRDdigitsManager; class AliTRDSignalIndex; struct eventHeaderStruct; class AliTRDCalibraFillHisto : public TObject { public: // Instance static AliTRDCalibraFillHisto *Instance(); static void Terminate(); static void Destroy(); void DestroyDebugStreamer(); AliTRDCalibraFillHisto(const AliTRDCalibraFillHisto &c); AliTRDCalibraFillHisto &operator=(const AliTRDCalibraFillHisto &) { return *this; } // Functions for initialising and filling with AliTRDtrackV1 Bool_t Init2Dhistos(Int_t nboftimebin = -1); Bool_t InitCalDet(); Bool_t UpdateHistogramsV1(const AliTRDtrackV1 *t); // Process events DAQ Int_t ProcessEventDAQ(AliRawReader *rawReader); // Is Pad on Bool_t IsPadOn(Int_t detector, Int_t row, Int_t col) const; // Functions for write void Write2d(const Char_t *filename = "TRD.calibration.root", Bool_t append = kFALSE); //For the statistics Double_t *StatH(TH2 *ch, Int_t i); Double_t *GetMeanMedianRMSNumberCH(); Double_t *GetMeanMedianRMSNumberLinearFitter() const; // LinearFitter void AnalyseLinearFitter(); // // Set of Get the variables // void SetIsHLT(Bool_t isHLT = kTRUE) { fIsHLT = isHLT; } Bool_t IsHLT() const { return fIsHLT; } // Choice to fill or not the 2D void SetPH2dOn(Bool_t ph2don = kTRUE) { fPH2dOn = ph2don; } void SetCH2dOn(Bool_t ch2don = kTRUE) { fCH2dOn = ch2don; } void SetPRF2dOn(Bool_t prf2don = kTRUE) { fPRF2dOn = prf2don; } void SetHisto2d(Bool_t histo2d = kTRUE) { fHisto2d = histo2d; } void SetVector2d(Bool_t vector2d = kTRUE) { fVector2d = vector2d; } void SetLinearFitterOn(Bool_t linearfitteron = kTRUE) { fLinearFitterOn = linearfitteron;} void SetLinearFitterDebugOn(Bool_t debug = kTRUE) { fLinearFitterDebugOn = debug; } void SetFirstRunGain(Int_t firstRunGain) { fFirstRunGain = firstRunGain; } void SetVersionGainUsed(Int_t versionGainUsed) { fVersionGainUsed = versionGainUsed; } void SetSubVersionGainUsed(Int_t subVersionGainUsed) { fSubVersionGainUsed = subVersionGainUsed; } void SetFirstRunGainLocal(Int_t firstRunGainLocal) { fFirstRunGainLocal = firstRunGainLocal; } void SetVersionGainLocalUsed(Int_t versionGainLocalUsed) { fVersionGainLocalUsed = versionGainLocalUsed; } void SetSubVersionGainLocalUsed(Int_t subVersionGainLocalUsed) { fSubVersionGainLocalUsed = subVersionGainLocalUsed; } void SetFirstRunVdrift(Int_t firstRunVdrift) { fFirstRunVdrift = firstRunVdrift; } void SetVersionVdriftUsed(Int_t versionVdriftUsed) { fVersionVdriftUsed = versionVdriftUsed; } void SetSubVersionVdriftUsed(Int_t subVersionVdriftUsed) { fSubVersionVdriftUsed = subVersionVdriftUsed; } Bool_t GetPH2dOn() const { return fPH2dOn; } Bool_t GetCH2dOn() const { return fCH2dOn; } Bool_t GetPRF2dOn() const { return fPRF2dOn; } Bool_t GetHisto2d() const { return fHisto2d; } Bool_t GetVector2d() const { return fVector2d; } Bool_t GetLinearFitterOn() const { return fLinearFitterOn; } Bool_t GetLinearFitterDebugOn() const { return fLinearFitterDebugOn; } Int_t GetVersionGainUsed() const { return fVersionGainUsed; } Int_t GetSubVersionGainUsed() const { return fSubVersionGainUsed; } Int_t GetVersionVdriftUsed() const { return fVersionVdriftUsed; } Int_t GetSubVersionVdriftUsed() const { return fSubVersionVdriftUsed; } // Get stuff that are filled TH2I *GetCH2d(); TProfile2D *GetPH2d(Int_t nbtimebin=24, Float_t samplefrequency= 10.0); TProfile2D *GetPRF2d() const { return fPRF2d; } TObjArray GetLinearFitterArray() const { return fLinearFitterArray; } TLinearFitter *GetLinearFitter(Int_t detector, Bool_t force=kFALSE); AliTRDCalibraVdriftLinearFit *GetVdriftLinearFit() const { return fLinearVdriftFit; } // How to fill the 2D void SetRelativeScale(Float_t relativeScale); void SetThresholdClusterPRF2(Float_t thresholdClusterPRF2) { fThresholdClusterPRF2 = thresholdClusterPRF2; } void SetLimitChargeIntegration(Bool_t limitChargeIntegration) { fLimitChargeIntegration = limitChargeIntegration; } void SetFillWithZero(Bool_t fillWithZero) { fFillWithZero = fillWithZero; } void SetNormalizeNbOfCluster(Bool_t normalizeNbOfCluster) { fNormalizeNbOfCluster = normalizeNbOfCluster; } void SetMaxCluster(Float_t maxCluster) { fMaxCluster = maxCluster; } void SetNbMaxCluster(Short_t nbMaxCluster) { fNbMaxCluster = nbMaxCluster; } void SetNz(Int_t i, Short_t nz); void SetNrphi(Int_t i, Short_t nrphi); void SetAllTogether(Int_t i); void SetPerSuperModule(Int_t i); void SetProcent(Float_t procent) { fProcent = procent; } void SetDifference(Short_t difference) { fDifference = difference; } void SetNumberClusters(Short_t numberClusters) { if(numberClusters >= 0) fNumberClusters = numberClusters; } void SetNumberClustersf(Short_t numberClustersf) { fNumberClustersf = numberClustersf; } void SetNumberClustersProcent(Float_t numberClustersProcent) { fNumberClustersProcent = numberClustersProcent; } void SetThresholdClustersDAQ(Float_t thresholdClustersDAQ) { fThresholdClustersDAQ = thresholdClustersDAQ; } void SetNumberRowDAQ(Short_t numberRowDAQ) { fNumberRowDAQ = numberRowDAQ; } void SetNumberColDAQ(Short_t numberColDAQ) { fNumberColDAQ = numberColDAQ; } void SetNumberBinCharge(Short_t numberBinCharge) { fNumberBinCharge = numberBinCharge; } void SetNumberBinPRF(Short_t numberBinPRF) { fNumberBinPRF = numberBinPRF; } void SetNumberGroupsPRF(Short_t numberGroupsPRF); Float_t GetRelativeScale() const { return fRelativeScale; } Float_t GetThresholdClusterPRF2() const { return fThresholdClusterPRF2; } Bool_t GetLimitChargeIntegration() const { return fLimitChargeIntegration; } Bool_t GetFillWithZero() const { return fFillWithZero; } Bool_t GetNormalizeNbOfCluster() const { return fNormalizeNbOfCluster; } Float_t GetMaxCluster() const { return fMaxCluster; } Short_t GetNbMaxCluster() const { return fNbMaxCluster; } Float_t GetProcent() const { return fProcent; } Short_t GetDifference() const { return fDifference; } Short_t GetNumberClusters() const { return fNumberClusters; } Short_t GetNumberClustersf() const { return fNumberClustersf; } Short_t GetNumberBinCharge() const { return fNumberBinCharge; } Short_t GetNumberBinPRF() const { return fNumberBinPRF; } Short_t GetNumberGroupsPRF() const { return fNgroupprf; } Int_t *GetEntriesLinearFitter() const { return fEntriesLinearFitter; } // Debug void SetDebugLevel(Short_t level) { fDebugLevel = level; } // Vector method AliTRDCalibraVector *GetCalibraVector() const { return fCalibraVector; } protected: // Geometry AliTRDgeometry *fGeo; //! The TRD geometry // calibration DB AliTRDcalibDB *fCalibDB; //! The pointer to the TRDcalibDB instance // Is HLT Bool_t fIsHLT; // Now if HLT, the per detector // Choice to fill or not the 2D Bool_t fCH2dOn; // Chose to fill the 2D histos or vectors for the relative gain calibration Bool_t fPH2dOn; // Chose to fill the 2D histos or vectors for the drift velocity and T0 Bool_t fPRF2dOn; // Chose to fill the 2D histos or vectors for the pad response function calibration Bool_t fHisto2d; // Chose to fill the 2D histos Bool_t fVector2d; // Chose to fill vectors Bool_t fLinearFitterOn; // Method with linear fit for drift velocity Bool_t fLinearFitterDebugOn; // Method with linear fit for drift velocity // How to fill the 2D Float_t fRelativeScale; // Scale of the deposited charge Float_t fThresholdClusterPRF2; // Threshold on cluster pad signals Bool_t fLimitChargeIntegration; // Integration range for the gain calibration Bool_t fFillWithZero; // Fill with zero or not the average pulse height Bool_t fNormalizeNbOfCluster; // Normalize with the number of cluster for the gain Float_t fMaxCluster; // Max amplitude of one cluster Short_t fNbMaxCluster; // Number of tb at the end // Back correction Int_t fFirstRunGain; // FirstRunGain Int_t fVersionGainUsed; // VersionGainUsed Int_t fSubVersionGainUsed; // SubVersionGainUsed Int_t fFirstRunGainLocal; // FirstRunGainLocal Int_t fVersionGainLocalUsed; // VersionGainUsed Int_t fSubVersionGainLocalUsed;// SubVersionGainUsed Int_t fFirstRunVdrift; // FirstRunVdrift Int_t fVersionVdriftUsed; // VersionVdriftUsed Int_t fSubVersionVdriftUsed; // SubVersionVdriftUsed // Calibration mode AliTRDCalibraMode *fCalibraMode; // Calibration mode //For debugging TTreeSRedirector *fDebugStreamer; //!Debug streamer Short_t fDebugLevel; // Flag for debugging // // Internal variables // // Fill the 2D histos in the offline tracking Int_t fDetectorPreviousTrack; // Change of detector Int_t fMCMPrevious; // Change of MCM Int_t fROBPrevious; // Change of ROB Short_t fNumberClusters; // Minimum number of clusters in the tracklets Short_t fNumberClustersf; // Maximum number of clusters in the tracklets Float_t fNumberClustersProcent; // Procent of number of time bins for fNumberClusters Float_t fThresholdClustersDAQ; // Threshold clusters for DAQ algorithm Short_t fNumberRowDAQ; // Size of the spot for DAQ algorithm Short_t fNumberColDAQ; // Size of the spot for DAQ algorithm Float_t fProcent; // Limit to take the info of the most important calibration group if the track goes through 2 groups (CH) Short_t fDifference; // Limit to take the info of the most important calibration group if the track goes through 2 groups (CH) Int_t fNumberTrack; // How many tracks could be used (Debug for the moment) Int_t fNumberUsedCh[2]; // How many tracks have been really used for the gain (0, strict; 1 with fProcent) Int_t fNumberUsedPh[2]; // How many tracks have been really used for the drift velocity (0, strict; 1 with fDifference) Int_t fTimeMax; // Number of time bins Float_t fSf; // Sampling frequence Short_t fNumberBinCharge; // Number of bins for the gain factor Short_t fNumberBinPRF; // Number of bin for the PRF Short_t fNgroupprf; // Number of groups in tnp bins for PRF /2.0 // Variables per tracklet Float_t *fAmpTotal; // Energy deposited in the calibration group by the track Short_t *fPHPlace; // Calibration group of PH Float_t *fPHValue; // PH Bool_t fGoodTracklet; // Good tracklet TLinearFitter *fLinearFitterTracklet; // linear fitter tracklet //Statistics Int_t *fEntriesCH; // Number of entries CH Int_t *fEntriesLinearFitter; // Number of entries LinearFitter // // Vector method // AliTRDCalibraVector *fCalibraVector; // The vector object // Histograms to store the info from the digits, from the tracklets or from the tracks TProfile2D *fPH2d; // 2D average pulse height TProfile2D *fPRF2d; // 2D PRF TH2I *fCH2d; // 2D deposited charge TObjArray fLinearFitterArray; // TObjArray of Linear Fitters for the detectors AliTRDCalibraVdriftLinearFit *fLinearVdriftFit; // Info Linear Fit // Current calib object: to correct for the database used AliTRDCalDet *fCalDetGain; // Current calib object gain AliTRDCalROC *fCalROCGain; // Current calib object gain // // A lot of internal functions...... // Init Bool_t InitCalPad(Int_t detector); // // Create the 2D histo to be filled Online void CreateCH2d(Int_t nn); void CreatePH2d(Int_t nn); void CreatePRF2d(Int_t nn); // Calibration with AliTRDtrackV1 void FillTheInfoOfTheTrackPH(); void FillTheInfoOfTheTrackCH(Int_t nbclusters); Bool_t FindP1TrackPHtrackletV1(const AliTRDseedV1 *tracklet, Int_t nbclusters); Bool_t HandlePRFtrackletV1(const AliTRDseedV1 *tracklet, Int_t nbclusters); void ResetfVariablestracklet(); void StoreInfoCHPHtrack(const AliTRDcluster *cl,const Double_t dqdl,const Int_t *group,const Int_t row,const Int_t col,const AliTRDcluster *cls=0x0); void FillCH2d(Int_t x, Float_t y); // Calibration on DAQ Int_t FillDAQ(Double_t phvalue[16][144][36]); Bool_t UpdateDAQ(Int_t det, Int_t /*row*/, Int_t /*col*/, Int_t timebin, Float_t signal, Int_t nbtimebins); // row col calibration groups stuff Bool_t LocalisationDetectorXbins(Int_t detector); Int_t CalculateTotalNumberOfBins(Int_t i); void CheckGoodTrackletV0(const Int_t detector,const Int_t row,const Int_t col); void CheckGoodTrackletV1(const AliTRDcluster *cl); Int_t CalculateCalibrationGroup(Int_t i, Int_t row, Int_t col) const; // Clear void ClearHistos(); // Some basic geometry function virtual Int_t GetLayer(Int_t d) const; virtual Int_t GetStack(Int_t d) const; virtual Int_t GetSector(Int_t d) const; // Instance of this class and so on static AliTRDCalibraFillHisto *fgInstance; // Instance static Bool_t fgTerminated; // If terminated private: // This is a singleton, contructor is private! AliTRDCalibraFillHisto(); virtual ~AliTRDCalibraFillHisto(); ClassDef(AliTRDCalibraFillHisto,4) // TRD Calibration class }; #endif