// // ******************************************************************** // * DISCLAIMER * // * * // * The following disclaimer summarizes all the specific disclaimers * // * of contributors to this software. The specific disclaimers,which * // * govern, are listed with their locations in: * // * http://cern.ch/geant4/license * // * * // * Neither the authors of this software system, nor their employing * // * institutes,nor the agencies providing financial support for this * // * work make any representation or warranty, express or implied, * // * regarding this software system or assume any liability for its * // * use. * // * * // * This code implementation is the intellectual property of the * // * GEANT4 collaboration. * // * By copying, distributing or modifying the Program (or any work * // * based on the Program) you indicate your acceptance of this * // * statement, and all its terms. * // ******************************************************************** // // // $Id: G4FieldManager.icc,v 1.9 2003/11/08 03:39:39 japost Exp $ // GEANT4 tag $Name: geant4-06-00-patch-01 $ // // // G4FieldManager inline implementation // // ------------------------------------------------------------------- inline const G4Field* G4FieldManager::GetDetectorField() const { // If pointer is null, should this raise an exception ?? return fDetectorField; } inline G4bool G4FieldManager::DoesFieldExist() const { return (fDetectorField != 0); } inline void G4FieldManager::SetChordFinder(G4ChordFinder *aChordFinder) { fChordFinder= aChordFinder; } inline G4ChordFinder* G4FieldManager::GetChordFinder() { return fChordFinder; } inline G4double G4FieldManager::GetDeltaIntersection() const { return fDelta_Intersection_Val; } inline G4double G4FieldManager::GetDeltaOneStep() const { return fDelta_One_Step_Value; } inline void G4FieldManager::SetDeltaOneStep(G4double valDeltaOneStep) { fDelta_One_Step_Value= valDeltaOneStep; } inline void G4FieldManager::SetDeltaIntersection(G4double valDeltaIntersection) { fDelta_Intersection_Val = valDeltaIntersection; } inline void G4FieldManager::SetAccuraciesWithDeltaOneStep(G4double valDeltaOneStep) { fDelta_One_Step_Value= valDeltaOneStep; fDelta_Intersection_Val = 0.4 * fDelta_One_Step_Value; } inline G4bool G4FieldManager::DoesFieldChangeEnergy() const { return fFieldChangesEnergy;} inline void G4FieldManager::SetFieldChangesEnergy(G4bool value) { fFieldChangesEnergy = value; } inline G4bool G4FieldManager:: FieldHasMagComponent() const { return fMagComponent; } inline void G4FieldManager::SetFieldMagComponent(G4bool value) { fMagComponent = value;} // Minimum for Relative accuracy of any Step inline G4double G4FieldManager::GetMinimumEpsilonStep() const { return fEpsilonMin; } inline void G4FieldManager::SetMinimumEpsilonStep( G4double newEpsMin ) { if( (newEpsMin > 0.0) && (fabs(1.0+newEpsMin) > 1.0) ) { fEpsilonMin = newEpsMin; } } // Maximum for Relative accuracy of any Step inline G4double G4FieldManager::GetMaximumEpsilonStep() const { return fEpsilonMax; } inline void G4FieldManager::SetMaximumEpsilonStep( G4double newEpsMax ) { if( (newEpsMax > 0.0) && (newEpsMax >= fEpsilonMin ) && (fabs(1.0+newEpsMax)>1.0) ) { fEpsilonMax = newEpsMax; } }