G4SafetyHelper.hh

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//
// class G4SafetyHelper
//
// Class description:
//
// This class is a helper for physics processes which require 
// knowledge of the safety, and the step size for the 'mass' geometry
 
// First version:  J.Apostolakis,  July 5th, 2006
// --------------------------------------------------------------------
#ifndef G4SAFETYHELPER_HH
#define G4SAFETYHELPER_HH 1
 
#include <vector>
 
#include "G4Types.hh"
#include "G4ThreeVector.hh"
#include "G4Navigator.hh"
 
class G4PathFinder;
 
class G4SafetyHelper
{
  public: // with description
 
    G4SafetyHelper(); 
   ~G4SafetyHelper();
      // Constructor and destructor
 
    G4double CheckNextStep( const G4ThreeVector& position, 
                            const G4ThreeVector& direction,
                            const G4double currentMaxStep,
                                  G4double& newSafety );
      // Return linear step for mass geometry
 
    G4double ComputeSafety( const G4ThreeVector& pGlobalPoint,
                            G4double maxRadius = DBL_MAX );
      // Return safety for all geometries.
      //
      // The 2nd argument is the radius of your interest (e.g. maximum
      // displacement). Giving this you can reduce the average computational
      // cost. If the second argument is not given, this is the real
      // isotropic safety
 
    void Locate(const G4ThreeVector& pGlobalPoint,
                const G4ThreeVector& direction);
      // Locate the point for all geometries
 
    void ReLocateWithinVolume(const G4ThreeVector& pGlobalPoint );
      // Relocate the point in the volume of interest
 
    inline void EnableParallelNavigation(G4bool parallel);
      //  To have parallel worlds considered, must be true.
      //  Alternative is to use single (mass) Navigator directly
 
    void InitialiseNavigator();
      // Check for new navigator for tracking, and reinitialise pointer
 
    inline G4int SetVerboseLevel( G4int lev );
    inline G4VPhysicalVolume* GetWorldVolume();
    inline void SetCurrentSafety(G4double val, const G4ThreeVector& pos);
 
  public: // without description
 
    void InitialiseHelper();
 
  private:
 
    G4PathFinder* fpPathFinder = nullptr;
    G4Navigator* fpMassNavigator = nullptr;
    G4int fMassNavigatorId = -1;
 
    G4bool fUseParallelGeometries = false; 
      // Flag whether to use PathFinder or single (mass) Navigator directly
      // By default, one geometry only
    G4bool fFirstCall = true;
      // Flag of first call
    G4int fVerbose = 0; 
      // Whether to print warning in case of move outside safety
 
    // State used during tracking -- for optimisation
 
    G4ThreeVector fLastSafetyPosition;
    G4double fLastSafety = 0.0;
 
    // const G4double fRecomputeFactor = 0.0;
       // parameter for further optimisation: 
       // if ( move < fact*safety )  do fast recomputation of safety
 
    // End State (tracking)
};
 
// --------------------------------------------------------------------
// Inline definitions
// --------------------------------------------------------------------
 
inline G4int G4SafetyHelper::SetVerboseLevel( G4int lev )
{
  G4int oldlv = fVerbose;
  fVerbose = lev;
  return oldlv;
} 
 
inline
void G4SafetyHelper::EnableParallelNavigation(G4bool parallel) 
{
  fUseParallelGeometries = parallel;
} 
 
inline
G4VPhysicalVolume* G4SafetyHelper::GetWorldVolume()
{
  return fpMassNavigator->GetWorldVolume();
}
 
inline
void G4SafetyHelper::SetCurrentSafety(G4double val, const G4ThreeVector& pos)
{
  fLastSafety = val;
  fLastSafetyPosition = pos;
}
 
#endif