//-------------------------------------------------------
#include <TError.h>
+#include <TBits.h>
#include "AliTPCtrack.h"
#include "AliComplexCluster.h"
class AliTPCseed;
class AliTPCclusterMI;
class AliTPCTrackerPoint;
-class AliESD;
+class AliESD;
+class AliTPCCalPad;
class TClonesArray;
class AliTPCseed : public AliTPCtrack {
- friend class AliTPCtrackerMI;
public:
AliTPCseed();
virtual ~AliTPCseed();
AliTPCseed(const AliTPCtrack &t);
AliTPCseed(const AliTPCseed &s, Bool_t clusterOwner = kFALSE);
//AliTPCseed(const AliTPCseed &t, Double_t a);
- AliTPCseed(UInt_t index, const Double_t xx[5],
- const Double_t cc[15], Double_t xr, Double_t alpha);
+ AliTPCseed(Double_t xr, Double_t alpha, const Double_t xx[5],
+ const Double_t cc[15], Int_t i);
+ AliTPCseed &operator = (const AliTPCseed & param);
+ static Int_t RefitTrack(AliTPCseed* seed, AliExternalTrackParam * in, AliExternalTrackParam * out);
+ Bool_t RefitTrack(AliTPCseed* seed, Bool_t out);
Int_t Compare(const TObject *o) const;
void Reset(Bool_t all = kTRUE);
Int_t GetProlongation(Double_t xr, Double_t &y, Double_t & z) const;
virtual Double_t GetPredictedChi2(const AliCluster *cluster2) const;
- virtual Int_t Update(const AliCluster* c2, Double_t chi2, UInt_t i);
+ virtual Bool_t Update(const AliCluster* c2, Double_t chi2, Int_t i);
AliTPCTrackerPoint * GetTrackPoint(Int_t i);
- void RebuildSeed(); // rebuild seed to be ready for storing
+ AliTPCclusterMI * GetClusterFast(Int_t irow){ return fClusterPointer[irow];}
+ void SetClusterPointer(Int_t irow, AliTPCclusterMI* cl) {fClusterPointer[irow]=cl;}
Double_t GetDensityFirst(Int_t n);
- Double_t GetSigma2C() const {return fC44;};
+ Double_t GetSigma2C() const {
+ Double_t cnv=GetBz()*kB2C;
+ return GetSigma1Pt2()*cnv*cnv;
+ }
void GetClusterStatistic(Int_t first, Int_t last, Int_t &found, Int_t &foundable, Int_t &shared, Bool_t plus2);
void Modify(Double_t factor);
return pica;
}
+ Double_t GetYat(Double_t x) const;
+
void SetErrorY2(Float_t sy2){fErrorY2=sy2;}
void SetErrorZ2(Float_t sz2){fErrorZ2=sz2;}
Float_t CookdEdx(Double_t low=0.05, Double_t up=0.70, Int_t i1=0, Int_t i2=159, Bool_t onlyused = kFALSE);
+ Float_t CookShape(Int_t type);
+ // Float_t CookShape2(Int_t type,Bool_t withQ);
void CookPID();
- Double_t Bethe(Double_t bg); // return bethe-bloch
- // void CookdEdx2(Double_t low=0.05, Double_t up=0.70);
Bool_t IsActive() const { return !(fRemoval);}
void Desactivate(Int_t reason){ fRemoval = reason;}
+ AliTPCclusterMI* GetClusterPointer(Int_t i) const {return fClusterPointer[i];}
+ Int_t GetSector() const {return fSector;}
+ Float_t GetCurrentSigmaY2() const {return fCurrentSigmaY2;}
+ Float_t GetCurrentSigmaZ2() const {return fCurrentSigmaZ2;}
+ Int_t GetRelativeSector() const {return fRelativeSector;}
+ Char_t GetCircular() const {return fCircular;}
+
+ void SetCurrentSigmaY2(Float_t s) {fCurrentSigmaY2=s;}
+ void SetCurrentSigmaZ2(Float_t s) {fCurrentSigmaZ2=s;}
+ void SetRelativeSector(Int_t r) {fRelativeSector=r;}
+ void SetCircular(Char_t c) {fCircular=c;}
+ void SetIsSeeding(Bool_t s) {fIsSeeding=s;}
+ void SetSeedType(Int_t s) {fSeedType=s;}
+ void SetSeed1(Int_t s) {fSeed1=s;}
+ void SetSeed2(Int_t s) {fSeed2=s;}
+ void SetESD(AliESDtrack* esd) {fEsd=esd;}
+ void SetBSigned(Bool_t s) {fBSigned=s;}
+ void SetSort(Int_t s) {fSort=s;}
+ void SetOverlapLabel(Int_t i, Int_t l) {fOverlapLabels[i]=l;}
+ void SetCurrentCluster(AliTPCclusterMI* cl) {fCurrentCluster=cl;}
+ void SetNoCluster(Int_t n) {fNoCluster=n;}
+ void SetRow(Int_t n) {fRow=n;}
+ void SetSector(Int_t n) {fSector=n;}
+ void SetCurrentClusterIndex1(Int_t n) {fCurrentClusterIndex1=n;}
+ void SetInDead(Bool_t s) {fInDead=s;}
+
+ Double_t TPCrPID(Int_t i) const {return fTPCr[i];}
+ Double_t* TPCrPIDs() {return fTPCr;}
+ Bool_t GetIsSeeding() const {return fIsSeeding;}
+ Int_t GetSeedType() const {return fSeedType;}
+ Int_t GetSeed1() const {return fSeed1;}
+ Int_t GetSeed2() const {return fSeed2;}
+ AliESDtrack* GetESD() {return fEsd;}
+ Float_t GetSDEDX(Int_t i) const {return fSDEDX[i];}
+ Int_t GetNCDEDX(Int_t i) const {return fNCDEDX[i];}
+ Bool_t GetBSigned() const {return fBSigned;}
+ Int_t GetSort() const {return fSort;}
+ Int_t GetOverlapLabel(Int_t i) const {return fOverlapLabels[i];}
+ AliTPCclusterMI* GetCurrentCluster() const {return fCurrentCluster;}
+ Int_t GetNoCluster() const {return fNoCluster;}
+ Int_t GetRow() const {return fRow;}
+ Int_t GetCurrentClusterIndex1() const {return fCurrentClusterIndex1;}
+ Bool_t GetInDead() const {return fInDead;}
+ Float_t GetErrorY2() const {return fErrorY2;}
+ Float_t GetErrorZ2() const {return fErrorZ2;}
+ Float_t GetCMeanSigmaY2p30() const {return fCMeanSigmaY2p30;}
+ Float_t GetCMeanSigmaZ2p30() const {return fCMeanSigmaZ2p30;}
+ Float_t GetCMeanSigmaY2p30R() const {return fCMeanSigmaY2p30R;}
+ Float_t GetCMeanSigmaZ2p30R() const {return fCMeanSigmaZ2p30R;}
//
//
+ void SetClusterMapBit(int ibit, Bool_t state);
+ Bool_t GetClusterMapBit(int ibit);
+ void SetSharedMapBit(int ibit, Bool_t state);
+ Bool_t GetSharedMapBit(int ibit);
+ const TBits& GetClusterMap() const { return fClusterMap; };
+ const TBits& GetSharedMap() const { return fSharedMap; };
+
+ Float_t CookdEdxNorm(Double_t low=0.05, Double_t up=0.70, Int_t type=0, Int_t i1=0, Int_t i2=159, Bool_t shapeNorm=kTRUE, Int_t posNorm=0, Int_t padNorm=0,Int_t returnVal=0);
+
+ Float_t CookdEdxAnalytical(Double_t low=0.05, Double_t up=0.70, Int_t type=0, Int_t i1=0, Int_t i2=159, Int_t returnVal=0);
+
+ static void GetError(AliTPCclusterMI* cluster, AliExternalTrackParam * param,
+ Double_t& erry, Double_t &errz);
+ static void GetShape(AliTPCclusterMI* cluster, AliExternalTrackParam * param,
+ Double_t& rmsy, Double_t &rmsz);
+ static Double_t GetQCorrGeom(Float_t ty, Float_t tz);
+ static Double_t GetQCorrShape(Int_t ipad, Int_t type,Float_t z, Float_t ty, Float_t tz, Float_t q, Float_t thr);
+
private:
// AliTPCseed & operator = (const AliTPCseed &)
// {::Fatal("= operator","Not Implemented\n");return *this;}
AliESDtrack * fEsd; //!
AliTPCclusterMI* fClusterPointer[160]; // array of cluster pointers -
Bool_t fClusterOwner; // indicates the track is owner of cluster
- TClonesArray * fPoints; //!array with points along the track
- TClonesArray * fEPoints; //! array with exact points - calculated in special macro not used in tracking
//---CURRENT VALUES
- Int_t fRow; //!current row number
- Int_t fSector; //!current sector number
- Int_t fRelativeSector; //! index of current relative sector
+ Int_t fRow; // current row number
+ Int_t fSector; // current sector number
+ Int_t fRelativeSector; // index of current relative sector
Float_t fCurrentSigmaY2; //!expected current cluster sigma Y
Float_t fCurrentSigmaZ2; //!expected current cluster sigma Z
+ Float_t fCMeanSigmaY2p30; //! current mean sigma Y2 - mean30%
+ Float_t fCMeanSigmaZ2p30; //! current mean sigma Z2 - mean30%
+ Float_t fCMeanSigmaY2p30R; //! current relative mean sigma Y2 - mean30%
+ Float_t fCMeanSigmaZ2p30R; //! current relative mean sigma Z2 - mean30%
Float_t fErrorY2; //!sigma of current cluster
Float_t fErrorZ2; //!sigma of current cluster
AliTPCclusterMI * fCurrentCluster; //!pointer to the current cluster for prolongation
Float_t fMAngular; // mean angular factor
Char_t fCircular; // indicates curlin track
AliTPCTrackerPoint fTrackPoints[160]; //track points - array track points
- ClassDef(AliTPCseed,1)
+ TBits fClusterMap; // bit is 1 if track has a hit on padrow
+ TBits fSharedMap; // bit is 1 if track shares a hit on padrow
+ ClassDef(AliTPCseed,3)
};