// // ******************************************************************** // * License and Disclaimer * // * * // * The Geant4 software is copyright of the Copyright Holders of * // * the Geant4 Collaboration. It is provided under the terms and * // * conditions of the Geant4 Software License, included in the file * // * LICENSE and available at http://cern.ch/geant4/license . These * // * include a list of copyright holders. * // * * // * 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. Please see the license in the file LICENSE and URL above * // * for the full disclaimer and the limitation of liability. * // * * // * This code implementation is the result of the scientific and * // * technical work of the GEANT4 collaboration. * // * By using, copying, modifying or distributing the software (or * // * any work based on the software) you agree to acknowledge its * // * use in resulting scientific publications, and indicate your * // * acceptance of all terms of the Geant4 Software license. * // ******************************************************************** // // // $Id: G4Para.hh 69788 2013-05-15 12:06:57Z gcosmo $ // // // -------------------------------------------------------------------- // GEANT 4 class header file // // G4Para // // Class description: // // A G4Parallepiped, essentially a box with half lengths dx,dy,dz // `skewed' so that there are angles theta & phi of the polar line // joining the faces at +-dz in z, and alpha formed by the y axis // and the plane joinng the centre of the faces G4Parallel to the // z-x plane at -dy and +dy. // // A G4Para is defined by: // dx,dy,dz - Half-length in x,y,z // alpha - Angle formed by the y axis and by the plane joining // the centre of the faces G4Parallel to the z-x plane // at -dy and +dy // theta - Polar angle of the line joining the centres of the // faces at -dz and +dz in z // phi - Azimuthal angle of the line joining the centres of the // faces at -dz and +dz in z // Member data: // // Note that the angles parameters are not stored - precomputed trig is // stored instead. // // fDx Half-length in x // fDy Half-length in y // fDz Half-length in z // // fTalpha Tan of alpha // fTthetaCphi Tan theta * Cos phi // fTthetaSphi Tan theta * Sin phi // History: // 21.3.94 P.Kent Old C++ code converted to tolerant geometry // 31.10.96 V.Grichine Modifications according G4Box/Tubs before to commit // 18.11.99 V.Grichine , kUndefined was added to ESide // -------------------------------------------------------------------- #ifndef G4Para_HH #define G4Para_HH #include "G4CSGSolid.hh" class G4Para : public G4CSGSolid { public: // with description G4Para(const G4String& pName, G4double pDx, G4double pDy, G4double pDz, G4double pAlpha, G4double pTheta, G4double pPhi); G4Para(const G4String& pName, const G4ThreeVector pt[8]); virtual ~G4Para(); // Accessors inline G4double GetZHalfLength() const; inline G4ThreeVector GetSymAxis() const; inline G4double GetYHalfLength() const; inline G4double GetXHalfLength() const; inline G4double GetTanAlpha() const; // Modifiers inline void SetXHalfLength(G4double val); inline void SetYHalfLength(G4double val); inline void SetZHalfLength(G4double val); inline void SetAlpha(G4double alpha); inline void SetTanAlpha(G4double val); inline void SetThetaAndPhi(double pTheta, double pPhi); void SetAllParameters(G4double pDx, G4double pDy, G4double pDz, G4double pAlpha, G4double pTheta, G4double pPhi); // Other methods of solid inline G4double GetCubicVolume(); inline G4double GetSurfaceArea(); void ComputeDimensions(G4VPVParameterisation* p, const G4int n, const G4VPhysicalVolume* pRep); G4bool CalculateExtent(const EAxis pAxis, const G4VoxelLimits& pVoxelLimit, const G4AffineTransform& pTransform, G4double& pMin, G4double& pMax) const; EInside Inside(const G4ThreeVector& p) const; G4ThreeVector SurfaceNormal( const G4ThreeVector& p) const; G4double DistanceToIn(const G4ThreeVector& p, const G4ThreeVector& v) const; G4double DistanceToIn(const G4ThreeVector& p) const; G4double DistanceToOut(const G4ThreeVector& p, const G4ThreeVector& v, const G4bool calcNorm=G4bool(false), G4bool *validNorm=0, G4ThreeVector *n=0) const; G4double DistanceToOut(const G4ThreeVector& p) const; G4GeometryType GetEntityType() const; G4ThreeVector GetPointOnSurface() const; G4VSolid* Clone() const; std::ostream& StreamInfo(std::ostream& os) const; // Visualisation functions void DescribeYourselfTo (G4VGraphicsScene& scene) const; G4Polyhedron* CreatePolyhedron () const; G4NURBS* CreateNURBS () const; public: // without description G4Para(__void__&); // Fake default constructor for usage restricted to direct object // persistency for clients requiring preallocation of memory for // persistifiable objects. G4Para(const G4Para& rhs); G4Para& operator=(const G4Para& rhs); // Copy constructor and assignment operator. protected: // without description G4ThreeVectorList* CreateRotatedVertices(const G4AffineTransform& pTransform) const; private: G4ThreeVector ApproxSurfaceNormal( const G4ThreeVector& p) const; // Algorithm for SurfaceNormal() following the original // specification for points not on the surface G4ThreeVector GetPointOnPlane(G4ThreeVector p0, G4ThreeVector p1, G4ThreeVector p2, G4ThreeVector p3, G4double& area) const; // Returns a random point on the surface of one of the faces. private: G4double fDx,fDy,fDz; G4double fTalpha,fTthetaCphi,fTthetaSphi; }; #include "G4Para.icc" #endif