Added the magnetic field as a static member of the AliL3Transform class,

[u/mrichter/AliRoot.git] / RALICE / AliTrack.h

#ifndef ALITRACK_H
#define ALITRACK_H

/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 * See cxx source for full Copyright notice                               */

// $Id$


#include "TObject.h"
#include "TObjArray.h"
#include "TArrayD.h"
 
#include "AliSignal.h"
#include "AliBoost.h"
#include "AliPosition.h"
 
class AliTrack : public TObject,public Ali4Vector
{
 public:
  AliTrack();                       // Default constructor
  ~AliTrack();                      // Destructor
  AliTrack(AliTrack& t);            // Copy constructor
  void Reset();                     // Reset all values to 0
  void Set4Momentum(Ali4Vector& p); // Set track 4-momentum
  void Set3Momentum(Ali3Vector& p); // Set track 3-momentum
  void SetMass(Double_t m,Double_t dm=0); // Set particle mass and error
  void SetMass();                   // Set mass and error to mass hypothesis with highest prob.
  void SetCharge(Float_t q);        // Set particle charge
  void Info(TString f="car");       // Print track information for coord. frame f
  void List(TString f="car");       // Print track and decay level 1 information for coord. frame f
  void ListAll(TString f="car");    // Print track and all decay level information for coord. frame f
  Ali3Vector Get3Momentum();        // Provide track 3-momentum
  Double_t GetMomentum();           // Provide value of track 3-momentum
  Double_t GetMass();               // Provide particle mass
  Float_t GetCharge();              // Provide particle charge
  Double_t GetEnergy();             // Provide particle total energy
  void Decay(Double_t m1,Double_t m2,Double_t thcms,Double_t phicms); // Perform 2-body decay
  Int_t GetNdecay();                // Provide number of decay products
  AliTrack* GetDecayTrack(Int_t j); // Access to decay produced track number j
  void AddSignal(AliSignal& s);     // Relate an AliSignal to this track
  void RemoveSignal(AliSignal& s);  // Remove related AliSignal from this track
  Int_t GetNsignals();              // Provide number of related AliSignals
  AliSignal* GetSignal(Int_t j);    // Access to the related AliSignal number j
  void SetBeginPoint(AliPosition p);// Set the track begin-point
  AliPosition GetBeginPoint();      // Provide the track begin-point
  void SetEndPoint(AliPosition p);  // Set the track end-point
  AliPosition GetEndPoint();        // Provide the track end-point
  void AddMassHypothesis(Double_t prob,Double_t m,Double_t dm=0); // Add mass hypothesis data
  Int_t GetNMassHypotheses();                // Provide number of mass hypotheses
  Double_t GetMassHypothesis(Int_t j=0);     // Provide mass of jth hypothesis 
  Double_t GetMassHypothesisProb(Int_t j=0); // Provide prob. of jth mass hypothesis 
  void RemoveMassHypothesis(Int_t j);        // Remove the jth mass hypothesis 
  Double_t GetPt();                 // Provide trans. momentum w.r.t. z-axis
  Double_t GetPl();                 // Provide long. momentum w.r.t. z-axis
  Double_t GetEt();                 // Provide trans. energy w.r.t. z-axis
  Double_t GetEl();                 // Provide long. energy w.r.t. z-axis
  Double_t GetMt();                 // Provide trans. mass w.r.t. z-axis
  Double_t GetMt(Int_t j);          // Provide trans. mass w.r.t. z-axis and jth mass hypothesis
  Double_t GetRapidity();           // Provide rapidity value w.r.t. z-axis
  void SetImpactPoint(AliPosition p,TString q); // Set the impact-point in plane "q=0"
  AliPosition GetImpactPoint(TString q);        // Provide the impact-point in plane "q=0"
  void SetId(Int_t id);             // Set the user defined identifier
  Int_t GetId();                    // Provide the user defined identifier
  void SetClosestPoint(AliPosition p); // Set position p as point of closest approach w.r.t. some reference
  AliPosition GetClosestPoint();       // Provide point of closest approach w.r.t. some reference
  void SetChi2(Float_t chi2);       // Set the chi-squared value of the track fit
  void SetNdf(Int_t ndf);           // Set the number of degrees of freedom for the track fit
  Float_t GetChi2();                // Provide the chi-squared value of the track fit
  Int_t GetNdf();                   // Provide the number of degrees of freedom for the track fit

 
 protected:
  void Init();           // Initialisation of pointers etc...
  Float_t fQ;            // The charge of the particle
  Int_t fNdec;           // The number of decay products
  TObjArray* fDecays;    // The array of decay produced tracks
  Int_t fNsig;           // The number of related AliSignals
  TObjArray* fSignals;   // The array of related AliSignals
  AliPosition fBegin;    // The begin-point of the track 
  AliPosition fEnd;      // The end-point of the track 
  Int_t fNmasses;        // The number of mass hypotheses
  TArrayD* fMasses;      // The various mass hypotheses
  TArrayD* fDmasses;     // The errors on the various masses
  TArrayD* fPmasses;     // The probabilities of the various mass hypotheses
  AliPosition fImpactXY; // The (extrapolated) impact-point in the plane z=0
  AliPosition fImpactXZ; // The (extrapolated) impact-point in the plane y=0
  AliPosition fImpactYZ; // The (extrapolated) impact-point in the plane x=0
  Int_t fUserId;         // The user defined identifier
  AliPosition fClosest;  // The (extrapolated) point of closest approach w.r.t some reference
  Float_t fChi2;         // The Chi-squared of the track fit
  Int_t fNdf;            // The number of degrees of freedom of the track fit

 private:
  void Dump(AliTrack* t,Int_t n,TString f); // Recursively print all decay levels
 
 ClassDef(AliTrack,1) // Handling of the attributes of a reconstructed particle track.
};
#endif