Making AliLog true instanton (Jimmy)
[u/mrichter/AliRoot.git] / HMPID / AliHMPIDRecon.h
index b32782a..986507a 100644 (file)
 
 class TClonesArray; //CkovAngle()
 class AliESDtrack;  //CkovAngle()
+class AliHMPIDParam;//general pourpose
 
 class AliHMPIDRecon : public TTask 
 {
 public : 
              AliHMPIDRecon();
-    virtual ~AliHMPIDRecon()                                                          {}
+    virtual ~AliHMPIDRecon() {;} //dtor
 
-
-  void     CkovAngle    (AliESDtrack *pTrk,TClonesArray *pCluLst,Double_t nmean             );     //reconstructed Theta Cerenkov
+  void     InitVars     (Int_t n);                                                                 //init space for variables
+  void     DeleteVars   ()const;                                                                   //delete variables
+  void     CkovAngle    (AliESDtrack *pTrk,TClonesArray *pCluLst,Int_t index,Double_t nmean,Float_t xRa,Float_t yRa );//reconstructed Theta Cerenkov
   Bool_t   FindPhotCkov (Double_t cluX,Double_t cluY,Double_t &thetaCer,Double_t &phiCer    );     //find ckov angle for single photon candidate
   Double_t FindRingCkov (Int_t iNclus                                                       );     //best ckov for ring formed by found photon candidates
-  Double_t FindRingArea (Double_t ckov                                                      )const;//estimated area of ring in cm^2
+  void     FindRingGeom (Double_t ckovAng,Int_t level=1                                     );     //estimated area of ring in cm^2 and portion accepted by geometry
+  TVector2 IntWithEdge  (TVector2 p1,TVector2 p2                                            )const;//find intercection between plane and lines of 2 thetaC
   Int_t    FlagPhot     (Double_t ckov                                                      );     //is photon ckov near most probable track ckov
   Double_t HoughResponse(                                                                   );     //most probable track ckov angle
   void     Propagate    (const TVector3  dir,      TVector3 &pos,Double_t z                 )const;//propagate photon alogn the line  
   void     Refract      (      TVector3 &dir,                    Double_t n1,    Double_t n2)const;//refract photon on the boundary
   TVector2 TracePhot    (Double_t ckovTh,Double_t ckovPh                                    )const;//trace photon created by track to PC 
   TVector2 TraceForward (TVector3 dirCkov                                                   )const;//tracing forward a photon from (x,y) to PC
-  void     RecPhot      (TVector3 dirCkov,Double_t &thetaCer,Double_t &phiCer               );     //theta,phi cerenkov reconstructed
+  void     Lors2Trs     (TVector3 dirCkov,Double_t &thetaCer,Double_t &phiCer               )const;//LORS to TRS 
+  void     Trs2Lors     (TVector3 dirCkov,Double_t &thetaCer,Double_t &phiCer               )const;//TRS to LORS
+  TVector2 GetMip       (                                                                   )const 
+                        {return fMipPos;}                                                          //mip coordinates
+  Double_t GetRingArea  (                                                                   )const
+                        {return fRingArea;}                                                        //area of the current ring in cm^2 
+  Double_t GetRingAcc   (                                                                   )const
+                        {return fRingAcc;}                                                         //portion of the ring ([0,1]) accepted by geometry.To scale n. of photons 
   void     SetTrack     (Double_t xRad,Double_t yRad,Double_t theta,Double_t phi            )
                                 {fTrkDir.SetMagThetaPhi(1,theta,phi);  fTrkPos.Set(xRad,yRad);}    //set track parameter at RAD
   void     SetImpPC     (Double_t xPc,Double_t yPc                                          )
                                 {fPc.Set(xPc,yPc);}                                                //set track impact to PC 
-  Double_t SigLoc       (Double_t ckovTh,Double_t ckovPh,Double_t beta                      )const;//error due to cathode segmetation
-  Double_t SigGeom      (Double_t ckovTh,Double_t ckovPh,Double_t beta                      )const;//error due to unknown photon origin
-  Double_t SigCrom      (Double_t ckovTh,Double_t ckovPh,Double_t beta                      )const;//error due to unknonw photon energy
-  Double_t Sigma2       (Double_t ckovTh,Double_t ckovPh                                    )const;//photon candidate sigma
-  enum ETrackingFlags {kMipDistCut=-9,kMipQdcCut=-5,kNoPhotAccept=-11};
-// HTA hidden track algorithm
-  Bool_t   CkovHiddenTrk    (AliESDtrack *pTrk,TClonesArray *pCluLst,Double_t nmean);              //Pattern recognition without trackinf information
-  Bool_t   CluPreFilter     (TClonesArray *pClu               );                                   //Pre clustering filter to cut bkg clusters
-  Bool_t   DoRecHiddenTrk   (TClonesArray *pClu               );                                   //Calling to the fitted procedures
-  Bool_t   FitEllipse       (Double_t &phiRec                    );                                //Fit clusters with a conical section (kTRUE only for ellipses)
-  Bool_t   FitFree          (Double_t phiRec                     );                                //Fit (th,ph) of the track and ckovFit as result
-  Double_t FunConSect       (Double_t *c,Double_t x,Double_t y   );                                //Function of a general conical section
-  void     SetNClu          (Int_t nclu                          ) {fNClu=nclu;}                   //Setter for # of clusters
-  void     SetClCk          (Int_t i,Bool_t what                 ) {fClCk[i]=what;}                //Setter for cluster flags 
-  void     SetCkovFit       (Double_t ckov                       ) {fCkovFit=ckov;}                //Setter for ckof fitted
-  void     SetTrkFit        (Double_t th,Double_t ph             ) {fThTrkFit = th;fPhTrkFit = ph;}//Setter for (th,ph) of the track
-  void     SetRadXY         (Double_t  x,Double_t y              ) {fRadX = x;fRadY = y;}          //Setter for (th,ph) of the track
-  static void     FunMinEl  (Int_t&/* */,Double_t* /* */,Double_t &f,Double_t *par,Int_t /* */);   //Fit function to find ellipes parameters
-  static void     FunMinPhot(Int_t&/* */,Double_t* /* */,Double_t &f,Double_t *par,Int_t iflag);   //Fit function to minimize thetaCer RMS/Sqrt(n) of n clusters
-  Int_t    IdxMip       ()const {return fIdxMip;}                                                  //Getter index of MIP
-  Double_t MipX         ()const {return fMipX;}                                                    //Getter of x MIP in LORS
-  Double_t MipY         ()const {return fMipY;}                                                    //Getter of y MIP in LORS
-  Double_t MipQ         ()const {return fMipQ;}                                                    //Getter of Q MIP
-  Double_t RadX         ()const {return fRadX;}                                                    //Getter of x at RAD in LORS
-  Double_t RadY         ()const {return fRadY;}                                                    //Getter of y at RAD in LORS
-  Int_t    NClu         ()const {return fNClu;}                                                    //Getter of cluster multiplicity
-  Double_t XClu         (Int_t i)const {return fXClu[i];}                                          //Getter of x clu
-  Double_t YClu         (Int_t i)const {return fYClu[i];}                                          //Getter of y clu
-  Bool_t   ClCk         (Int_t i)const {return fClCk[i];}                                          //Getter of cluster flags
-  Double_t CkovFit      ()const {return fCkovFit;}                                                 //Getter of ckov angle fitted
-  Double_t ThTrkFit     ()const {return fThTrkFit;}                                                //Getter of theta fitted of the track
-  Double_t PhTrkFit     ()const {return fPhTrkFit;}                                                //Getter of phi fitted of the track
+  void     SetMip       (Double_t xmip,Double_t ymip                                        )
+                                {fMipPos.Set(xmip,ymip);}                                          //set track impact to PC
+  enum ETrackingFlags {kNotPerformed=-20,kMipDistCut=-9,kMipQdcCut=-5,kNoPhotAccept=-11,kNoRad = -22};
 //
 protected:
-  Double_t fRadNmean;                          //C6F14 mean refractive index
-  Int_t    fPhotCnt;                           // counter of photons candidate
-  Int_t    fPhotFlag[3000];                    // flags of photon candidates
-  Double_t fPhotCkov[3000];                    // Ckov angles of photon candidates, [rad]
-  Double_t fPhotPhi [3000];                    // phis of photons candidates, [rad]
-  Double_t fPhotWei [3000];                    // weigths of photon candidates
-  Double_t fCkovSigma2;                        // sigma2 of the reconstructed ring
+  Int_t     fPhotCnt;                           // counter of photons candidate
+  Int_t    *fPhotFlag;                          // flags of photon candidates
+  Double_t *fPhotCkov;                          // Ckov angles of photon candidates, [rad]
+  Double_t *fPhotPhi;                           // phis of photons candidates, [rad]
+  Double_t *fPhotWei;                           // weigths of photon candidates
+  Double_t  fCkovSigma2;                        // sigma2 of the reconstructed ring
 
-  Bool_t   fIsWEIGHT;                          // flag to consider weight procedure
-  Float_t  fDTheta;                            // Step for sliding window
-  Float_t  fWindowWidth;                       // Hough width of sliding window
+  Bool_t    fIsWEIGHT;                          // flag to consider weight procedure
+  Float_t   fDTheta;                            // Step for sliding window
+  Float_t   fWindowWidth;                       // Hough width of sliding window
+  
+  Double_t  fRingArea;                          // area of a given ring
+  Double_t  fRingAcc;                           // fraction of the ring accepted by geometry
+  TVector3  fTrkDir;                            // track direction in LORS at RAD
+  TVector2  fTrkPos;                            // track positon in LORS at RAD
+  TVector2  fMipPos;                            // mip positon for a given track
+  TVector2  fPc;                                // track position at PC
+  
+  AliHMPIDParam *fParam;                        // Pointer to AliHMPIDParam
   
-  TVector3 fTrkDir;                            //track direction in LORS at RAD
-  TVector2 fTrkPos;                            //track positon in LORS at RAD
-  TVector2 fPc;                                //track position at PC
-// HTA hidden track algorithm
-  Double_t fMipX;                              //mip X position for Hidden Track Algorithm  
-  Double_t fMipY;                              //mip Y position for Hidden Track Algorithm
-  Double_t fMipQ;                              //mip Q          for Hidden Track Algorithm
-  Double_t fRadX;                              //rad X position for Hidden Track Algorithm  
-  Double_t fRadY;                              //rad Y position for Hidden Track Algorithm
-  Int_t    fIdxMip;                            //mip index in the clus list
-  Int_t    fNClu;                              //n clusters to fit
-  Double_t fXClu[100];                         //container for x clus position
-  Double_t fYClu[100];                         //container for y clus position
-  Bool_t   fClCk[100];                         //flag if cluster is used in fitting
-  Double_t fThTrkFit;                          //theta fitted of the track
-  Double_t fPhTrkFit;                          //phi   fitted of the track
-  Double_t fCkovFit;                           //estimated ring Cherenkov angle
-//
 private:
-  static const Double_t fgkRadThick;                      //radiator thickness
-  static const Double_t fgkWinThick;                      //window thickness
-  static const Double_t fgkGapThick;                      //proximity gap thickness
-  static const Double_t fgkWinIdx;                        //mean refractive index of WIN material (SiO2) 
-  static const Double_t fgkGapIdx;                        //mean refractive index of GAP material (CH4)
-
-  ClassDef(AliHMPIDRecon,0)
+  AliHMPIDRecon(const AliHMPIDRecon& r);              //dummy copy constructor
+  AliHMPIDRecon &operator=(const AliHMPIDRecon& r);   //dummy assignment operator
+//
+  ClassDef(AliHMPIDRecon,1)
 };
 
 #endif // #ifdef AliHMPIDRecon_cxx