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Please see the license in the file LICENSE and URL above * 16 // * for the full disclaimer and the limitatio 16 // * for the full disclaimer and the limitation of liability. * 17 // * 17 // * * 18 // * This code implementation is the result 18 // * This code implementation is the result of the scientific and * 19 // * technical work of the GEANT4 collaboratio 19 // * technical work of the GEANT4 collaboration. * 20 // * By using, copying, modifying or distri 20 // * By using, copying, modifying or distributing the software (or * 21 // * any work based on the software) you ag 21 // * any work based on the software) you agree to acknowledge its * 22 // * use in resulting scientific publicati 22 // * use in resulting scientific publications, and indicate your * 23 // * acceptance of all terms of the Geant4 Sof 23 // * acceptance of all terms of the Geant4 Software license. * 24 // ******************************************* 24 // ******************************************************************** 25 // 25 // >> 26 // >> 27 // $Id: G4TwistTubsSide.hh,v 1.5 2006/06/29 18:47:58 gunter Exp $ >> 28 // GEANT4 tag $Name: geant4-09-03-patch-01 $ >> 29 // >> 30 // >> 31 // -------------------------------------------------------------------- >> 32 // GEANT 4 class header file >> 33 // >> 34 // 26 // G4TwistTubsSide 35 // G4TwistTubsSide 27 // 36 // 28 // Class description: 37 // Class description: 29 // 38 // 30 // Class describing a twisted boundary surface << 39 // Class describing a twisted boundary surface for a cylinder. 31 40 32 // 01-Aug-2002 - Kotoyo Hoshina (hoshina@hepbu << 41 // Author: 33 // 13-Nov-2003 - O.Link (Oliver.Link@cern.ch), << 42 // 01-Aug-2002 - Kotoyo Hoshina (hoshina@hepburn.s.chiba-u.ac.jp) 34 // from original version in Jupi << 43 // >> 44 // History: >> 45 // 13-Nov-2003 - O.Link (Oliver.Link@cern.ch), Integration in Geant4 >> 46 // from original version in Jupiter-2.5.02 application. 35 // ------------------------------------------- 47 // -------------------------------------------------------------------- 36 #ifndef G4TWISTTUBSSIDE_HH << 48 #ifndef __G4TWISTTUBSSIDE__ 37 #define G4TWISTTUBSSIDE_HH << 49 #define __G4TWISTTUBSSIDE__ 38 50 39 #include "G4VTwistSurface.hh" 51 #include "G4VTwistSurface.hh" 40 52 41 class G4TwistTubsSide : public G4VTwistSurface 53 class G4TwistTubsSide : public G4VTwistSurface 42 { 54 { 43 public: << 55 public: // with description 44 56 45 G4TwistTubsSide(const G4String& na << 57 G4TwistTubsSide(const G4String &name, 46 const G4RotationMatrix& ro << 58 const G4RotationMatrix &rot, // 0.5*(phi-width segment) 47 const G4ThreeVector& tl << 59 const G4ThreeVector &tlate, 48 G4int handedness, << 60 G4int handedness, // R-hand = 1, L-hand = -1 49 const G4double kappa, << 61 const G4double kappa, // tan(TwistAngle/2)/fZHalfLen 50 const EAxis axis0 = kXA << 62 const EAxis axis0 = kXAxis, 51 const EAxis axis1 = kZA << 63 const EAxis axis1 = kZAxis, 52 G4double axis0min = << 64 G4double axis0min = -kInfinity, 53 G4double axis1min = << 65 G4double axis1min = -kInfinity, 54 G4double axis0max = << 66 G4double axis0max = kInfinity, 55 G4double axis1max = << 67 G4double axis1max = kInfinity ); 56 << 68 57 G4TwistTubsSide(const G4String& name, << 69 G4TwistTubsSide(const G4String &name, 58 G4double EndInnerRa << 70 G4double EndInnerRadius[2], 59 G4double EndOuterRa << 71 G4double EndOuterRadius[2], 60 G4double DPhi, << 72 G4double DPhi, 61 G4double EndPhi[2], << 73 G4double EndPhi[2], 62 G4double EndZ[2], << 74 G4double EndZ[2], 63 G4double InnerRadiu << 75 G4double InnerRadius, 64 G4double OuterRadiu << 76 G4double OuterRadius, 65 G4double Kappa, << 77 G4double Kappa, 66 G4int handedness << 78 G4int handedness); 67 << 68 ~G4TwistTubsSide() override; << 69 << 70 G4ThreeVector GetNormal(const G4ThreeVecto << 71 G4bool isGlo << 72 << 73 G4int DistanceToSurface(const G4ThreeVecto << 74 const G4ThreeVecto << 75 G4ThreeVecto << 76 G4double di << 77 G4int ar << 78 G4bool is << 79 EValidate validate << 80 << 81 G4int DistanceToSurface(const G4ThreeVecto << 82 G4ThreeVecto << 83 G4double << 84 G4int << 85 << 86 inline G4ThreeVector ProjectAtPXPZ(const G << 87 G << 88 << 89 inline G4ThreeVector SurfacePoint(G4double << 90 G4bool i << 91 inline G4double GetBoundaryMin(G4double ph << 92 inline G4double GetBoundaryMax(G4double ph << 93 inline G4double GetSurfaceArea() override << 94 void GetFacets( G4int m, G4int n, G4double << 95 G4int faces[][4], G4int is << 96 << 97 G4TwistTubsSide(__void__&); << 98 // Fake default constructor for usage re << 99 // persistency for clients requiring pre << 100 // persistifiable objects. << 101 << 102 private: << 103 79 104 G4double DistanceToPlane(const G4ThreeVect << 80 virtual ~G4TwistTubsSide(); 105 const G4ThreeVect << 81 106 const G4ThreeVect << 82 virtual G4ThreeVector GetNormal(const G4ThreeVector &xx, 107 const G4ThreeVect << 83 G4bool isGlobal = false) ; 108 const G4ThreeVect << 84 109 const G4int << 85 virtual G4int DistanceToSurface(const G4ThreeVector &gp, 110 G4ThreeVect << 86 const G4ThreeVector &gv, 111 G4ThreeVect << 87 G4ThreeVector gxx[], 112 << 88 G4double distance[], 113 G4int GetAreaCode(const G4ThreeVector& xx, << 89 G4int areacode[], 114 G4bool wit << 90 G4bool isvalid[], 115 << 91 EValidate validate = kValidateWithTol); 116 void SetCorners() override; << 92 117 << 93 virtual G4int DistanceToSurface(const G4ThreeVector &gp, 118 void SetCorners( G4double endInnerRad[2], << 94 G4ThreeVector gxx[], 119 G4double endOuterRad[2], << 95 G4double distance[], 120 G4double endPhi[2], << 96 G4int areacode[]); 121 G4double endZ[2] ) ; << 97 >> 98 inline G4ThreeVector ProjectAtPXPZ(const G4ThreeVector &p, >> 99 G4bool isglobal = false) const ; >> 100 >> 101 virtual G4ThreeVector SurfacePoint(G4double, G4double, >> 102 G4bool isGlobal = false) ; >> 103 virtual G4double GetBoundaryMin(G4double phi) ; >> 104 virtual G4double GetBoundaryMax(G4double phi) ; >> 105 virtual G4double GetSurfaceArea() ; >> 106 virtual void GetFacets( G4int m, G4int n, G4double xyz[][3], >> 107 G4int faces[][4], G4int iside ) ; >> 108 >> 109 public: // without description >> 110 >> 111 G4TwistTubsSide(__void__&); >> 112 // Fake default constructor for usage restricted to direct object >> 113 // persistency for clients requiring preallocation of memory for >> 114 // persistifiable objects. >> 115 >> 116 private: >> 117 >> 118 virtual G4double DistanceToPlane(const G4ThreeVector &p, >> 119 const G4ThreeVector &A, >> 120 const G4ThreeVector &B, >> 121 const G4ThreeVector &C, >> 122 const G4ThreeVector &D, >> 123 const G4int parity, >> 124 G4ThreeVector &xx, >> 125 G4ThreeVector &n); >> 126 >> 127 virtual G4int GetAreaCode(const G4ThreeVector &xx, >> 128 G4bool withTol = true); >> 129 >> 130 virtual void SetCorners(); >> 131 >> 132 virtual void SetCorners( G4double endInnerRad[2], >> 133 G4double endOuterRad[2], >> 134 G4double endPhi[2], >> 135 G4double endZ[2] ) ; 122 136 123 void SetBoundaries() override; << 137 virtual void SetBoundaries(); 124 138 125 private: 139 private: 126 140 127 G4double fKappa; // std::ta << 141 G4double fKappa; // std::tan(TwistedAngle/2)/HalfLenZ; 128 }; 142 }; 129 143 130 144 131 //============================================ 145 //======================================================== 132 // inline functions 146 // inline functions 133 //============================================ 147 //======================================================== 134 148 135 inline 149 inline 136 G4ThreeVector G4TwistTubsSide::ProjectAtPXPZ(c << 150 G4ThreeVector G4TwistTubsSide::ProjectAtPXPZ(const G4ThreeVector &p, 137 151 G4bool isglobal) const 138 { 152 { 139 // Get Rho at p.z() on Hyperbolic Surface. 153 // Get Rho at p.z() on Hyperbolic Surface. 140 G4ThreeVector tmpp; 154 G4ThreeVector tmpp; 141 if (isglobal) { tmpp = fRot.inverse()*p - fT << 155 if (isglobal) { 142 else { tmpp = p; } << 156 tmpp = fRot.inverse()*p - fTrans; >> 157 } else { >> 158 tmpp = p; >> 159 } 143 G4ThreeVector xx(p.x(), p.x() * fKappa * p.z 160 G4ThreeVector xx(p.x(), p.x() * fKappa * p.z(), p.z()); 144 if (isglobal) { return (fRot * xx + fTrans); 161 if (isglobal) { return (fRot * xx + fTrans); } 145 return xx; 162 return xx; 146 } 163 } 147 164 148 inline 165 inline 149 G4ThreeVector 166 G4ThreeVector 150 G4TwistTubsSide::SurfacePoint(G4double x, G4do 167 G4TwistTubsSide::SurfacePoint(G4double x, G4double z, G4bool isGlobal) 151 { 168 { 152 G4ThreeVector SurfPoint( x , x * fKappa * z 169 G4ThreeVector SurfPoint( x , x * fKappa * z , z ) ; 153 170 154 if (isGlobal) { return (fRot * SurfPoint + f 171 if (isGlobal) { return (fRot * SurfPoint + fTrans); } 155 return SurfPoint; 172 return SurfPoint; 156 } 173 } 157 174 158 inline 175 inline 159 G4double G4TwistTubsSide::GetBoundaryMin(G4dou 176 G4double G4TwistTubsSide::GetBoundaryMin(G4double) 160 { 177 { 161 return fAxisMin[0] ; // inner radius at z 178 return fAxisMin[0] ; // inner radius at z = 0 162 } 179 } 163 180 164 inline 181 inline 165 G4double G4TwistTubsSide::GetBoundaryMax(G4dou 182 G4double G4TwistTubsSide::GetBoundaryMax(G4double) 166 { 183 { 167 return fAxisMax[0] ; // outer radius at z 184 return fAxisMax[0] ; // outer radius at z = 0 168 } 185 } 169 186 170 inline 187 inline 171 G4double G4TwistTubsSide::GetSurfaceArea() 188 G4double G4TwistTubsSide::GetSurfaceArea() 172 { 189 { 173 // approximation only 190 // approximation only 174 return ( fAxisMax[0] - fAxisMin[0] ) * ( fAx 191 return ( fAxisMax[0] - fAxisMin[0] ) * ( fAxisMax[1] - fAxisMin[1] ) ; 175 } 192 } 176 193 177 #endif 194 #endif 178 195