G4AdjointCSMatrix.hh

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////////////////////////////////////////////////////////////////////////////////
//  Class:    G4AdjointCSMatrix
//  Author:         L. Desorgher
//  Organisation:   SpaceIT GmbH
//
//  An adjoint CS matrix is used by the model of a reverse process to sample
//  an adjoint secondary (being equivalent to a forward primary). It represents
//  the integration over the energy of the adjoint secondary (therefore the
//  forward primary) of the differential cross section of the equivalent forward
//  discrete process (Ionisation, Brem, PE effect, Compton,..). Each reverse
//  model has its own cross section matrix for a given cut, material couple. It
//  is therefore recomputed after a modification of the cuts by the user.
//
////////////////////////////////////////////////////////////////////////////////
 
#ifndef G4AdjointCSMatrix_h
#define G4AdjointCSMatrix_h 1
 
#include "globals.hh"
#include "G4ParticleDefinition.hh"
 
#include <vector>
 
class G4AdjointCSMatrix
{
 public:
  G4AdjointCSMatrix(G4bool aBool);
  ~G4AdjointCSMatrix();
 
  void Clear();
 
  void AddData(G4double aPrimEnergy, G4double aCS,
               std::vector<double>* aLogSecondEnergyVector,
               std::vector<double>* aLogProbVector, size_t n_pro_decade = 0);
 
  G4bool GetData(unsigned int i, G4double& aPrimEnergy, G4double& aCS,
                 G4double& log0, std::vector<double>*& aLogSecondEnergyVector,
                 std::vector<double>*& aLogProbVector,
                 std::vector<size_t>*& aLogProbVectorIndex);
 
  inline std::vector<double>* GetLogPrimEnergyVector()
  {
    return &fLogPrimEnergyVector;
  }
 
  inline std::vector<double>* GetLogCrossSectionvector()
  {
    return &fLogCrossSectionVector;
  }
 
  inline G4bool IsScatProjToProj() { return fScatProjToProj; }
 
  void Write(G4String file_name);
 
  void Read(G4String file_name);
 
 private:
  std::vector<double> fLogPrimEnergyVector;
  // Adjoint Cross sections as functions of primary energy
  std::vector<double> fLogCrossSectionVector;
 
  std::vector<std::vector<double>*> fLogSecondEnergyMatrix;
  std::vector<std::vector<double>*> fLogProbMatrix;
  // Each column represents the integrated probability of
  // getting a secondary
 
  // index of equidistant LogProb
  std::vector<std::vector<size_t>*> fLogProbMatrixIndex;
  std::vector<double> fLog0Vector;
 
  size_t fNbPrimEnergy = 0;
 
  G4bool fScatProjToProj;
};
#endif