-#ifndef AliMUONRecoParam_H
-#define AliMUONRecoParam_H
+#ifndef ALIMUONRECOPARAM_H
+#define ALIMUONRECOPARAM_H
/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
* See cxx source for full Copyright notice */
+// $Id$
+
/// \ingroup rec
/// \class AliMUONRecoParam
/// \brief Class with MUON reconstruction parameters
#include "AliDetectorRecoParam.h"
#include "TString.h"
+#include <TMath.h>
class AliMUONRecoParam : public AliDetectorRecoParam
{
static AliMUONRecoParam *GetLowFluxParam();
static AliMUONRecoParam *GetHighFluxParam();
+ static AliMUONRecoParam *GetCosmicParam();
+ static AliMUONRecoParam *GetCalibrationParam();
+
+ /// set the calibration mode (see GetCalibrationMode() for possible modes)
+ void SetCalibrationMode(Option_t* mode) { fCalibrationMode = mode; fCalibrationMode.ToUpper();}
+
+ Option_t* GetCalibrationMode() const;
- /// set the calibration mode
- void SetCalibrationMode(Option_t* mode) { fCalibrationMode = mode; }
- /// get the calibration mode
- Option_t* GetCalibrationMode() const { return fCalibrationMode.Data(); }
-
/// set the clustering (pre-clustering) mode
- void SetClusteringMode(Option_t* mode) {fClusteringMode = mode;}
+ void SetClusteringMode(Option_t* mode) {fClusteringMode = mode; fClusteringMode.ToUpper();}
/// get the clustering (pre-clustering) mode
Option_t* GetClusteringMode() const {return fClusteringMode.Data();}
+ /// Get the (truncated) average of sigmas of pedestal measurements, i.e. noise, of pads
+ Double_t AverageNoisePadCharge() const { return fAverageNoisePadCharge; }
+ /// Set the average of sigmas of pedestal measurements, i.e. noise, of pads
+ void AverageNoisePadCharge(Double_t noise) { fAverageNoisePadCharge = noise; }
+
+ /// Get the lowest charge we allow for pads
+ Double_t LowestPadCharge() const { return fChargeSigmaCut*fAverageNoisePadCharge; }
+
+ /// Get the cut applied to cut on cluster charge (the charge is cut if below fClusterChargeCut*LowestPadCharge())
+ Double_t ClusterChargeCut() const { return fClusterChargeCut; }
+ /// Set the cut applied to cut on cluster charge (the charge is cut if below fClusterChargeCut*LowestPadCharge())
+ void ClusterChargeCut(Double_t n) { fClusterChargeCut=n; }
+
+ /// Get the lowest possible cluster charge
+ Double_t LowestClusterCharge() const { return ClusterChargeCut()*LowestPadCharge(); }
+
/// set the tracking mode
- void SetTrackingMode(Option_t* mode) {fTrackingMode = mode;}
+ void SetTrackingMode(Option_t* mode) {fTrackingMode = mode; fTrackingMode.ToUpper();}
/// get the tracking mode
Option_t* GetTrackingMode() const {return fTrackingMode.Data();}
/// return the maximum value (GeV/c) of momentum in bending plane
Double_t GetMaxBendingMomentum() const {return fMaxBendingMomentum;}
- /// set the vertex dispersion (cm) in non bending plane (used for original tracking only)
+ /// set the maximum value of the non bending slope
+ void SetMaxNonBendingSlope(Double_t val) {fMaxNonBendingSlope = val;}
+ /// return the maximum value of the non bending slope
+ Double_t GetMaxNonBendingSlope() const {return fMaxNonBendingSlope;}
+ /// set the maximum value of the bending slope
+ void SetMaxBendingSlope(Double_t val) {fMaxBendingSlope = val;}
+ /// return the maximum value of the bending slope
+ Double_t GetMaxBendingSlope() const {return fMaxBendingSlope;}
+
+ /// switch on/off the track selection according to their slope (instead of their impact parameter)
+ void SelectOnTrackSlope(Bool_t flag) {fSelectTrackOnSlope = flag;}
+ /// return kTRUE/kFALSE if tracks are selected according to their slope/impact parameter
+ Bool_t SelectOnTrackSlope() const {return fSelectTrackOnSlope;}
+
+ /// set the vertex dispersion (cm) in non bending plane
void SetNonBendingVertexDispersion(Double_t val) {fNonBendingVertexDispersion = val;}
- /// return the vertex dispersion (cm) in bending plane (used for original tracking only)
+ /// return the vertex dispersion (cm) in non bending plane
Double_t GetNonBendingVertexDispersion() const {return fNonBendingVertexDispersion;}
- /// set the vertex dispersion (cm) in non bending plane (used for original tracking only)
+ /// set the vertex dispersion (cm) in bending plane
void SetBendingVertexDispersion(Double_t val) {fBendingVertexDispersion = val;}
- /// return the vertex dispersion (cm) in bending plane (used for original tracking only)
+ /// return the vertex dispersion (cm) in bending plane
Double_t GetBendingVertexDispersion() const {return fBendingVertexDispersion;}
/// set the maximum distance to the track to search for compatible cluster(s) in non bending direction
Bool_t ImproveTracks() const {return fImproveTracks;}
/// return the cut in sigma to apply on cluster (local chi2) during track improvement
Double_t GetSigmaCutForImprovement() const {return fSigmaCutForImprovement;}
-
+
/// set the cut in sigma to apply on track during trigger hit pattern search
- void SetSigmaCutForTrigger(Double_t val) {fSigmaCutForTrigger = val;}
+ void SetSigmaCutForTrigger(Double_t val) {fSigmaCutForTrigger = val; fMaxNormChi2MatchTrigger = val*val;}
/// return the cut in sigma to apply on track during trigger hit pattern search
Double_t GetSigmaCutForTrigger() const {return fSigmaCutForTrigger;}
+ /// set the cut in strips to apply on trigger track during trigger chamber efficiency
+ void SetStripCutForTrigger(Double_t val) {fStripCutForTrigger = val;}
+ /// return the cut in strips to apply on trigger track during trigger chamber efficiency
+ Double_t GetStripCutForTrigger() const {return fStripCutForTrigger;}
+ /// set the maximum search area in strips to apply on trigger track during trigger chamber efficiency
+ void SetMaxStripAreaForTrigger(Double_t val) {fMaxStripAreaForTrigger = val;}
+ /// return the maximum search area in strips to apply on trigger track during trigger chamber efficiency
+ Double_t GetMaxStripAreaForTrigger() const {return fMaxStripAreaForTrigger;}
- /// set the maximum normalized chi2 of tracking/trigger track matching
- void SetMaxNormChi2MatchTrigger(Double_t val) {fMaxNormChi2MatchTrigger = val;}
/// return the maximum normalized chi2 of tracking/trigger track matching
Double_t GetMaxNormChi2MatchTrigger() const {return fMaxNormChi2MatchTrigger;}
/// return kTRUE/kFALSE if the fast building of track candidates is switched on/off
Bool_t MakeTrackCandidatesFast() const {return fMakeTrackCandidatesFast;}
+ /// switch on/off the building of track candidates starting from 1 cluster in each of the stations 4 and 5
+ void MakeMoreTrackCandidates(Bool_t flag) {fMakeMoreTrackCandidates = flag;}
+ /// return kTRUE/kFALSE if the building of extra track candidates is switched on/off
+ Bool_t MakeMoreTrackCandidates() const {return fMakeMoreTrackCandidates;}
+
/// switch on/off the completion of reconstructed track
void ComplementTracks(Bool_t flag) {fComplementTracks = flag;}
/// return kTRUE/kFALSE if completion of the reconstructed track is switched on/off
Bool_t ComplementTracks() const {return fComplementTracks;}
+ /// remove tracks sharing cluster in stations 1 or 2
+ void RemoveConnectedTracksInSt12(Bool_t flag) {fRemoveConnectedTracksInSt12 = flag;}
+ /// return kTRUE/kFALSE whether tracks sharing cluster in station 1 and 2 must be removed or not
+ Bool_t RemoveConnectedTracksInSt12() const {return fRemoveConnectedTracksInSt12;}
+
/// switch on/off the use of the smoother
void UseSmoother(Bool_t flag) {fUseSmoother = flag;}
/// return kTRUE/kFALSE if the use of the smoother is switched on/off
Bool_t UseSmoother() const {return fUseSmoother;}
+ /// switch on/off a chamber in the reconstruction
+ void UseChamber(Int_t iCh, Bool_t flag) {if (iCh >= 0 && iCh < 10) fUseChamber[iCh] = flag;}
+ /// return kTRUE/kFALSE whether the chamber must be used or not
+ Bool_t UseChamber(Int_t iCh) const {return (iCh >= 0 && iCh < 10) ? fUseChamber[iCh] : kFALSE;}
+
+ /// request or not at least one cluster in the station to validate the track
+ void RequestStation(Int_t iSt, Bool_t flag) {if (iSt >= 0 && iSt < 5) fRequestStation[iSt] = flag;}
+ /// return kTRUE/kFALSE whether at least one cluster is requested in the station to validate the track
+ Bool_t RequestStation(Int_t iSt) const {return (iSt >= 0 && iSt < 5) ? fRequestStation[iSt] : kFALSE;}
+ /// return an integer where first 5 bits are set to 1 if the corresponding station is requested
+ UInt_t RequestedStationMask() const;
+
+ /// set the bypassSt45 value
+ void BypassSt45(Bool_t st4, Bool_t st5);
+
+ /// return kTRUE if we should replace clusters in St 4 and 5 by generated clusters from trigger tracks
+ Bool_t BypassSt45() const { return fBypassSt45==45; }
+
+ /// return kTRUE if we should replace clusters in St 4 by generated clusters from trigger tracks
+ Bool_t BypassSt4() const { return BypassSt45() || fBypassSt45==4 ; }
+
+ /// return kTRUE if we should replace clusters in St 5 by generated clusters from trigger tracks
+ Bool_t BypassSt5() const { return BypassSt45() || fBypassSt45==5 ; }
+
+ /// Set HV threshold for chambers (chamberId=0..9, use -1 to set all chambers equal)
+ void SetHVLimit(Int_t chamberId, Double_t ichamber);
+ /// Retrieve HV limit for chamber (chamberId=0..9)
+ Double_t HVLimit(Int_t chamberId) const;
+
+ /// Set Low and High threshold for pedestal mean
+ void SetPedMeanLimits(float low, float high) { fPedMeanLimits[0]=low; fPedMeanLimits[1]=high; }
+ /// Retrieve low limit of ped mean
+ Float_t PedMeanLowLimit() const { return fPedMeanLimits[0]; }
+ /// Retrieve high limit of ped mean
+ Float_t PedMeanHighLimit() const { return fPedMeanLimits[1]; }
+
+ /// Set Low and High threshold for pedestal sigma
+ void SetPedSigmaLimits(float low, float high) { fPedSigmaLimits[0]=low; fPedSigmaLimits[1]=high; }
+ /// Retrieve low limit of ped sigma
+ Float_t PedSigmaLowLimit() const { return fPedSigmaLimits[0]; }
+ /// Retrieve high limit of ped sigma
+ Float_t PedSigmaHighLimit() const { return fPedSigmaLimits[1]; }
+
+ /// Set Low and High threshold for gain a0 term
+ void SetGainA1Limits(float low, float high) { fGainA1Limits[0]=low; fGainA1Limits[1]=high; }
+ /// Retrieve low limit of a1 (linear term) gain parameter
+ Float_t GainA1LowLimit() const { return fGainA1Limits[0]; }
+ /// Retrieve high limit of a1 (linear term) gain parameter
+ Float_t GainA1HighLimit() const { return fGainA1Limits[1]; }
+
+ /// Set Low and High threshold for gain a1 term
+ void SetGainA2Limits(float low, float high) { fGainA2Limits[0]=low; fGainA2Limits[1]=high; }
+ /// Retrieve low limit of a2 (quadratic term) gain parameter
+ Float_t GainA2LowLimit() const { return fGainA2Limits[0]; }
+ /// Retrieve high limit of a2 (quadratic term) gain parameter
+ Float_t GainA2HighLimit() const { return fGainA2Limits[1]; }
+
+ /// Set Low and High threshold for gain threshold term
+ void SetGainThresLimits(float low, float high) { fGainThresLimits[0]=low; fGainThresLimits[1]=high; }
+ /// Retrieve low limit on threshold gain parameter
+ Float_t GainThresLowLimit() const { return fGainThresLimits[0]; }
+ /// Retrieve high limit on threshold gain parameter
+ Float_t GainThresHighLimit() const { return fGainThresLimits[1]; }
+
+ /// Set the goodness mask (see AliMUONPadStatusMapMaker)
+ void SetPadGoodnessMask(UInt_t mask) { fPadGoodnessMask=mask; }
+ /// Get the goodness mask
+ UInt_t PadGoodnessMask() const { return fPadGoodnessMask; }
+
+ /// Number of sigma cut we must apply when cutting on adc-ped
+ Double_t ChargeSigmaCut() const { return fChargeSigmaCut; }
+
+ /// Number of sigma cut we must apply when cutting on adc-ped
+ void ChargeSigmaCut(Double_t value) { fChargeSigmaCut=value; }
+
+ /// Set the default non bending resolution of chamber iCh
+ void SetDefaultNonBendingReso(Int_t iCh, Double_t val) {if (iCh >= 0 && iCh < 10) fDefaultNonBendingReso[iCh] = val;}
+ /// Get the default non bending resolution of chamber iCh
+ Double_t GetDefaultNonBendingReso(Int_t iCh) const {return (iCh >= 0 && iCh < 10) ? fDefaultNonBendingReso[iCh] : FLT_MAX;}
+ /// Set the default bending resolution of chamber iCh
+ void SetDefaultBendingReso(Int_t iCh, Double_t val) {if (iCh >= 0 && iCh < 10) fDefaultBendingReso[iCh] = val;}
+ /// Get the default bending resolution of chamber iCh
+ Double_t GetDefaultBendingReso(Int_t iCh) const {return (iCh >= 0 && iCh < 10) ? fDefaultBendingReso[iCh] : FLT_MAX;}
+
+ /// Set the maximum number of trigger tracks above which the tracking is cancelled
+ void SetMaxTriggerTracks(Int_t maxTriggerTracks) {fMaxTriggerTracks = maxTriggerTracks;}
+ /// Get the maximum number of trigger tracks above which the tracking is cancelled
+ Int_t GetMaxTriggerTracks() const {return fMaxTriggerTracks;}
+
+ /// Set the maximum number of track candidates above which the tracking abort
+ void SetMaxTrackCandidates(Int_t maxTrackCandidates) {fMaxTrackCandidates = maxTrackCandidates;}
+ /// Get the maximum number of track candidates above which the tracking abort
+ Int_t GetMaxTrackCandidates() const {return fMaxTrackCandidates;}
+
+ /// Set the limits for the acceptable manu occupancy
+ void SetManuOccupancyLimits(float low, float high) { fManuOccupancyLimits[0]=low; fManuOccupancyLimits[1]=high; }
+ /// Retrieve low value of manu occupancy limit
+ Float_t ManuOccupancyLowLimit() const { return fManuOccupancyLimits[0]; }
+ /// Retrieve high value of manu occupancy limit
+ Float_t ManuOccupancyHighLimit() const { return fManuOccupancyLimits[1]; }
+
+ /// Set the limits for the acceptable bp occupancy
+ void SetBuspatchOccupancyLimits(float low, float high) { fBuspatchOccupancyLimits[0]=low; fBuspatchOccupancyLimits[1]=high; }
+ /// Retrieve low value of bp occupancy limit
+ Float_t BuspatchOccupancyLowLimit() const { return fBuspatchOccupancyLimits[0]; }
+ /// Retrieve high value of bp occupancy limit
+ Float_t BuspatchOccupancyHighLimit() const { return fBuspatchOccupancyLimits[1]; }
+
+ /// Set the limits for the acceptable DE occupancy
+ void SetDEOccupancyLimits(float low, float high) { fDEOccupancyLimits[0]=low; fDEOccupancyLimits[1]=high; }
+ /// Retrieve low value of DE occupancy limit
+ Float_t DEOccupancyLowLimit() const { return fDEOccupancyLimits[0]; }
+ /// Retrieve high value of DE occupancy limit
+ Float_t DEOccupancyHighLimit() const { return fDEOccupancyLimits[1]; }
+
+ /// Set the fraction of buspatches outside the occupancy limits
+ void SetFractionOfBuspatchOutsideOccupancyLimit(float v) { fFractionOfBuspatchOutsideOccupancyLimit = v; }
+ /// Get the fraction of buspatches outside the occupancy limits
+ Float_t FractionOfBuspatchOutsideOccupancyLimit() const { return fFractionOfBuspatchOutsideOccupancyLimit; }
+
virtual void Print(Option_t *option = "") const;
+ /// Get the max event size (soft limit)
+ virtual Double_t EventSizeSoftLimit() const { return fEventSizeSoftLimit; }
+
+ /// Get the max event size (hard limit)
+ virtual Double_t EventSizeHardLimit() const { return fEventSizeHardLimit; }
+
+ /// Set the max event size limits
+ virtual void SetEventSizeLimits(Double_t soft, Double_t hard) { fEventSizeSoftLimit=soft; fEventSizeHardLimit=hard; }
+
+ /// Get the percentage of token lost error we allow
+ virtual Double_t TokenLostLimit() const { return fTokenLostLimit; }
+
+ /// Set the percentage of token lost error we allow
+ virtual void SetTokenLostLimit(Double_t limit) { fTokenLostLimit = limit; }
+
+ /// Whether or not we try to recover corrupted raw data
+ virtual Bool_t TryRecover() const { return fTryRecover; }
+
+ /// Set the try recover corrupted raw data (use kTRUE only if you know what you are doing. Should be left to kFALSE by default)
+ virtual void TryRecover(Bool_t flag) { fTryRecover = flag; }
+
+ /// Discard or not the mono-cathod clusters by assigning to them different resolutions (use default values)
+ void DiscardMonoCathodClusters(Bool_t flag) { fDiscardMonoCathodClusters = flag; }
+ /// Discard or not the mono-cathod clusters by assigning to them different resolutions (use given values)
+ void DiscardMonoCathodClusters(Bool_t flag, Double_t resNB, Double_t resB) { fDiscardMonoCathodClusters = flag;
+ fMonoCathodClNonBendingRes = resNB; fMonoCathodClBendingRes = resB; }
+ /// Check whether to discard or not the mono-cathod clusters
+ Bool_t DiscardMonoCathodClusters() const { return fDiscardMonoCathodClusters; }
+ /// Get the non-bending resolution of mono-cathod clusters when the non-bending plane is missing
+ Double_t GetMonoCathodClNonBendingRes() const { return fMonoCathodClNonBendingRes; }
+ /// Get the bending resolution of mono-cathod clusters when the bending plane is missing
+ Double_t GetMonoCathodClBendingRes() const { return fMonoCathodClBendingRes; }
+
+ /// Create object ready to be put in OCDB
+ static TObjArray* Create(const char* settings);
+
+ /// Show what is the OCDB for that run
+ static void Show(Int_t runNumber, const char* ocdbPath="raw://");
+
+private:
+
+ void SetDefaultLimits();
private:
Double32_t fMinBendingMomentum; ///< minimum value (GeV/c) of momentum in bending plane
Double32_t fMaxBendingMomentum; ///< maximum value (GeV/c) of momentum in bending plane
+ Double32_t fMaxNonBendingSlope; ///< maximum value of the non bending slope
+ Double32_t fMaxBendingSlope; ///< maximum value of the bending slope (used only if B = 0)
Double32_t fNonBendingVertexDispersion; ///< vertex dispersion (cm) in non bending plane (used for original tracking only)
Double32_t fBendingVertexDispersion; ///< vertex dispersion (cm) in bending plane (used for original tracking only)
Double32_t fSigmaCutForImprovement; ///< cut in sigma to apply on cluster (local chi2) during track improvement
Double32_t fSigmaCutForTrigger; ///< cut in sigma to apply on track during trigger hit pattern search
+
+ Double32_t fStripCutForTrigger; ///< cut in strips to apply on trigger track during trigger chamber efficiency
+
+ Double32_t fMaxStripAreaForTrigger; ///< max. search area in strips to apply on trigger track during trigger chamber efficiency
Double32_t fMaxNormChi2MatchTrigger; ///< maximum normalized chi2 of tracking/trigger track matching
Bool_t fMakeTrackCandidatesFast; ///< kTRUE to make candidate tracks assuming linear propagation between stations 4 and 5
+ Bool_t fMakeMoreTrackCandidates; ///< kTRUE to make candidate tracks starting from 1 cluster in each of the stations 4 and 5
+
Bool_t fComplementTracks; ///< kTRUE to try to complete the reconstructed tracks by adding missing clusters
Bool_t fImproveTracks; ///< kTRUE to try to improve the reconstructed tracks by removing bad clusters
Bool_t fSaveFullClusterInESD; ///< kTRUE to save all cluster info (including pads) in ESD
- /// calibration mode: GAIN, NOGAIN
- TString fCalibrationMode; ///<\brief calibration mode
+ /// calibration mode: GAIN, NOGAIN, GAINCONSTANTCAPA, INJECTIONGAIN
+ TString fCalibrationMode; ///<\brief calibration mode
+
+ Int_t fBypassSt45; ///< non-zero to use trigger tracks to generate "fake" clusters in St 4 and 5. Can be 0, 4, 5 or 45 only
+
+ Bool_t fUseChamber[10]; ///< kTRUE to use the chamber i in the tracking algorithm
+
+ Bool_t fRequestStation[5]; ///< kTRUE to request at least one cluster in station i to validate the track
+
+ Double32_t fGainA1Limits[2]; ///< Low and High threshold for gain a0 parameter
+ Double32_t fGainA2Limits[2]; ///< Low and High threshold for gain a1 parameter
+ Double32_t fGainThresLimits[2]; ///< Low and High threshold for gain threshold parameter
+ Double32_t fHVSt12Limits[2]; ///< DEPRECATED. See fHVLimits
+ Double32_t fHVSt345Limits[2]; ///< DEPRECATED. See fHVLimits
+ Double32_t fPedMeanLimits[2]; ///< Low and High threshold for pedestal mean
+ Double32_t fPedSigmaLimits[2]; ///< Low and High threshold for pedestal sigma
+
+ UInt_t fPadGoodnessMask; ///< goodness mask (see AliMUONPadStatusMaker)
+
+ Double32_t fChargeSigmaCut; ///< number of sigma to cut on adc-ped
+
+ Double32_t fDefaultNonBendingReso[10]; ///< default chamber resolution in the non-bending direction
+ Double32_t fDefaultBendingReso[10]; ///< default chamber resolution in the bending direction
+
+ Bool_t fRemoveConnectedTracksInSt12; ///< kTRUE to remove tracks sharing cluster in station 1 and 2
+
+ Int_t fMaxTriggerTracks; ///< maximum number of trigger tracks above which the tracking is cancelled
+ Int_t fMaxTrackCandidates; ///< maximum number of track candidates above which the tracking abort
+
+ Bool_t fSelectTrackOnSlope; ///< select track candidates according to their slope (instead of their impact parameter)
+
+ Double32_t fManuOccupancyLimits[2]; ///< low and high thresholds for manu occupancy cut
+ Double32_t fBuspatchOccupancyLimits[2]; ///< low and high thresholds for bus patch occupancy cut
+ Double32_t fDEOccupancyLimits[2]; ///< low and high thresholds for DE occupancy cut
+
+ Double32_t fMissingPadFractionLimit; ///< DEPRECATED
+ Double32_t fFractionOfBuspatchOutsideOccupancyLimit; ///< above this limit, we consider we have too many buspatches out of the allowed occupancy range
+
+ Double32_t fAverageNoisePadCharge; ///< the (truncated, typically at 10%) mean of the sigma of the pedestals, in femto-coulomb
+ Double32_t fClusterChargeCut; ///< the cluster is cut if its charge is below fClusterChargeCut*LowestPadCharge()
+
+ Double32_t fEventSizeSoftLimit; ///< (soft) limit on mean event size per event (KB)
+ Double32_t fEventSizeHardLimit; ///< (hard) limit on mean event size per event (KB)
+
+ Double32_t fTokenLostLimit; ///< limit on the fraction of token lost error per event we allow
+
+ Bool_t fTryRecover; ///< try to recover corrupted raw data
+
+ Double32_t fHVLimit[10]; // HV limit (below which we consider that chamber efficiency is to be considered zero)
+
+ Double32_t fDiscardMonoCathodClusters; // assign a different resolution to mono-cathod clusters in the direction of the missing plane
+ Double32_t fMonoCathodClNonBendingRes; // resolution of mono-cathod clusters in the non-bending direction when the non-bending plane is missing
+ Double32_t fMonoCathodClBendingRes; // resolution of mono-cathod clusters in the bending direction when the bending plane is missing
// functions
void SetLowFluxParam();
void SetHighFluxParam();
+ void SetCosmicParam();
+ void SetCalibrationParam();
-
- ClassDef(AliMUONRecoParam,2) // MUON reco parameters
+ ClassDef(AliMUONRecoParam,170) // MUON reco parameters
+ // we're at 167 not because we had that many versions, but because at some point (version 15->16)
+ // 166 was committed by error, and we did not to go reverse afterwards...
};
#endif