#ifndef ALI4VECTOR_H #define ALI4VECTOR_H /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * See cxx source for full Copyright notice */ // $Id$ #include #include #include "Ali3Vector.h" class Ali4Vector { public: Ali4Vector(); // Default constructor for contravariant vector virtual ~Ali4Vector(); // Destructor virtual void SetVector(Double_t v0,Ali3Vector v); // Store contravariant vector virtual void SetVector(Double_t* v,TString f); // Store contravariant vector v^i in frame f virtual void GetVector(Double_t* v,TString f); // Provide contravariant vector v^i in frame f virtual void SetVector(Float_t* v,TString f); // Store contravariant vector v^i in frame f virtual void GetVector(Float_t* v,TString f); // Provide contravariant vector v^i in frame f virtual void SetScalar(Double_t v0,Double_t dv0=0); // Set the scalar part (with error) of v virtual void SetScalarError(Double_t dv0); // Set error on the scalar part of v Double_t GetScalar(); // Provide the scalar part of v virtual void Set3Vector(Ali3Vector v); // Set the 3-vector part of v virtual void Set3Vector(Double_t* v,TString f); // Set the 3-vector part of v in frame f virtual void Set3Vector(Float_t* v,TString f); // Set the 3-vector part of v in frame f Ali3Vector Get3Vector(); // Provide the 3-vector part of v virtual void SetInvariant(Double_t v2,Double_t dv2=0); // Set the Lorentz invariant (with error) virtual void SetInvariantError(Double_t dv2); // Set error on the Lorentz invariant Double_t GetInvariant(); // Provide the Lorentz invariant virtual void SetErrors(Double_t* v,TString f); // Store errors of vector v^i in frame f virtual void GetErrors(Double_t* v,TString f); // Provide errors of vector v^i in frame f virtual void SetErrors(Float_t* v,TString f); // Store errors of vector v^i in frame f virtual void GetErrors(Float_t* v,TString f); // Provide errors of vector v^i in frame f virtual void Info(TString f="car"); // Print contravariant components in frame f Double_t Dot(Ali4Vector& q); // Provide dot product v^i*q_i Double_t GetResultError(); // Provide error on scalar result (e.g. Dot) Ali4Vector operator+(Ali4Vector& q); // Add contravariant vector q Ali4Vector operator-(Ali4Vector& q); // Subtract contravariant vector q Ali4Vector operator*(Double_t s); // Multiply contravariant vector with scalar s Ali4Vector operator/(Double_t s); // Divide contravariant vector by scalar s Ali4Vector& operator+=(Ali4Vector& q); // Add contravariant vector q Ali4Vector& operator-=(Ali4Vector& q); // Subtract contravariant vector q Ali4Vector& operator*=(Double_t s); // Multiply with scalar s Ali4Vector& operator/=(Double_t s); // Divide by scalar s Int_t GetScalarFlag(); // Provide the fScalar flag value Ali3Vector GetVecTrans(); // Provide transverse vector part w.r.t. z-axis Ali3Vector GetVecLong(); // Provide longitudinal vector part w.r.t. z-axis Double_t GetPseudoRapidity(); // Provide pseudorapidity of vector part w.r.t z-axis protected: Double_t fV2; // The Lorentz invariant (v^i*v_i) Double_t fV0; // The scalar part Ali3Vector fV; // The 3-vector part Double_t fDv2; // The error on the Lorentz invariant Double_t fDv0; // The error on the scalar part Double_t fDresult; // The error on the scalar result of an operation (e.g. dotproduct) Int_t fScalar; // Flag denoting scalar mode Double_t GetScaTrans(); // Provide "transverse value" of scalar part w.r.t. z-axis Double_t GetScaLong(); // Provide "longitudinal value" of scalar part w.r.t. z-axis ClassDef(Ali4Vector,1) // Handling of Lorentz 4-vectors in various reference frames. }; #endif