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1 // 2 // ******************************************************************** 3 // * License and Disclaimer * 4 // * * 5 // * The Geant4 software is copyright of the Copyright Holders of * 6 // * the Geant4 Collaboration. It is provided under the terms and * 7 // * conditions of the Geant4 Software License, included in the file * 8 // * LICENSE and available at http://cern.ch/geant4/license . These * 9 // * include a list of copyright holders. * 10 // * * 11 // * Neither the authors of this software system, nor their employing * 12 // * institutes,nor the agencies providing financial support for this * 13 // * work make any representation or warranty, express or implied, * 14 // * regarding this software system or assume any liability for its * 15 // * use. Please see the license in the file LICENSE and URL above * 16 // * for the full disclaimer and the limitation of liability. * 17 // * * 18 // * This code implementation is the result of the scientific and * 19 // * technical work of the GEANT4 collaboration. * 20 // * By using, copying, modifying or distributing the software (or * 21 // * any work based on the software) you agree to acknowledge its * 22 // * use in resulting scientific publications, and indicate your * 23 // * acceptance of all terms of the Geant4 Software license. * 24 // ******************************************************************** 25 // 26 // G4GDMLParameterisation implementation 27 // 28 // Author: Zoltan Torzsok, November 2007 29 // -------------------------------------------------------------------- 30 31 #include "G4GDMLParameterisation.hh" 32 #include "G4PolyconeHistorical.hh" 33 #include "G4PolyhedraHistorical.hh" 34 35 // -------------------------------------------------------------------- 36 G4int G4GDMLParameterisation::GetSize() const 37 { 38 return (G4int) parameterList.size(); 39 } 40 41 // -------------------------------------------------------------------- 42 void G4GDMLParameterisation::AddParameter(const PARAMETER& newParameter) 43 { 44 parameterList.push_back(newParameter); 45 } 46 47 // -------------------------------------------------------------------- 48 void G4GDMLParameterisation::ComputeTransformation( 49 const G4int index, G4VPhysicalVolume* physvol) const 50 { 51 physvol->SetTranslation(parameterList[index].position); 52 physvol->SetRotation(parameterList[index].pRot); 53 } 54 55 // -------------------------------------------------------------------- 56 void G4GDMLParameterisation::ComputeDimensions(G4Box& box, const G4int index, 57 const G4VPhysicalVolume*) const 58 { 59 box.SetXHalfLength(parameterList[index].dimension[0]); 60 box.SetYHalfLength(parameterList[index].dimension[1]); 61 box.SetZHalfLength(parameterList[index].dimension[2]); 62 } 63 64 // -------------------------------------------------------------------- 65 void G4GDMLParameterisation::ComputeDimensions(G4Trd& trd, const G4int index, 66 const G4VPhysicalVolume*) const 67 { 68 trd.SetXHalfLength1(parameterList[index].dimension[0]); 69 trd.SetXHalfLength2(parameterList[index].dimension[1]); 70 trd.SetYHalfLength1(parameterList[index].dimension[2]); 71 trd.SetYHalfLength2(parameterList[index].dimension[3]); 72 trd.SetZHalfLength(parameterList[index].dimension[4]); 73 } 74 75 // -------------------------------------------------------------------- 76 void G4GDMLParameterisation::ComputeDimensions(G4Trap& trap, const G4int index, 77 const G4VPhysicalVolume*) const 78 { 79 trap.SetAllParameters(parameterList[index].dimension[0], // Dz 80 parameterList[index].dimension[1], // Theta 81 parameterList[index].dimension[2], // Phi 82 parameterList[index].dimension[3], // Dy1 83 parameterList[index].dimension[4], // Dx1 84 parameterList[index].dimension[5], // Dx2 85 parameterList[index].dimension[6], // pAlp1, 86 parameterList[index].dimension[7], // pDy2, 87 parameterList[index].dimension[8], // pDx3, 88 parameterList[index].dimension[9], // pDx4, 89 parameterList[index].dimension[10]); // pAlp2 90 } 91 92 // -------------------------------------------------------------------- 93 void G4GDMLParameterisation::ComputeDimensions(G4Tubs& tubs, const G4int index, 94 const G4VPhysicalVolume*) const 95 { 96 tubs.SetInnerRadius(parameterList[index].dimension[0]); 97 tubs.SetOuterRadius(parameterList[index].dimension[1]); 98 tubs.SetZHalfLength(parameterList[index].dimension[2]); 99 tubs.SetStartPhiAngle(parameterList[index].dimension[3]); 100 tubs.SetDeltaPhiAngle(parameterList[index].dimension[4]); 101 } 102 103 // -------------------------------------------------------------------- 104 void G4GDMLParameterisation::ComputeDimensions(G4Cons& cons, const G4int index, 105 const G4VPhysicalVolume*) const 106 { 107 cons.SetInnerRadiusMinusZ(parameterList[index].dimension[0]); 108 cons.SetOuterRadiusMinusZ(parameterList[index].dimension[1]); 109 cons.SetInnerRadiusPlusZ(parameterList[index].dimension[2]); 110 cons.SetOuterRadiusPlusZ(parameterList[index].dimension[3]); 111 cons.SetZHalfLength(parameterList[index].dimension[4]); 112 cons.SetStartPhiAngle(parameterList[index].dimension[5]); 113 cons.SetDeltaPhiAngle(parameterList[index].dimension[6]); 114 } 115 116 // -------------------------------------------------------------------- 117 void G4GDMLParameterisation::ComputeDimensions(G4Sphere& sphere, 118 const G4int index, 119 const G4VPhysicalVolume*) const 120 { 121 sphere.SetInnerRadius(parameterList[index].dimension[0]); 122 sphere.SetOuterRadius(parameterList[index].dimension[1]); 123 sphere.SetStartPhiAngle(parameterList[index].dimension[2]); 124 sphere.SetDeltaPhiAngle(parameterList[index].dimension[3]); 125 sphere.SetStartThetaAngle(parameterList[index].dimension[4]); 126 sphere.SetDeltaThetaAngle(parameterList[index].dimension[5]); 127 } 128 129 // -------------------------------------------------------------------- 130 void G4GDMLParameterisation::ComputeDimensions(G4Orb& orb, const G4int index, 131 const G4VPhysicalVolume*) const 132 { 133 orb.SetRadius(parameterList[index].dimension[0]); 134 } 135 136 // -------------------------------------------------------------------- 137 void G4GDMLParameterisation::ComputeDimensions(G4Ellipsoid& ellipsoid, 138 const G4int index, 139 const G4VPhysicalVolume*) const 140 { 141 ellipsoid.SetSemiAxis(parameterList[index].dimension[0], 142 parameterList[index].dimension[1], 143 parameterList[index].dimension[2]); 144 ellipsoid.SetZCuts(parameterList[index].dimension[3], 145 parameterList[index].dimension[4]); 146 } 147 148 // -------------------------------------------------------------------- 149 void G4GDMLParameterisation::ComputeDimensions(G4Torus& torus, 150 const G4int index, 151 const G4VPhysicalVolume*) const 152 { 153 torus.SetAllParameters(parameterList[index].dimension[0], // pRmin 154 parameterList[index].dimension[1], // pRmax 155 parameterList[index].dimension[2], // pRtor 156 parameterList[index].dimension[3], // pSPhi 157 parameterList[index].dimension[4]); // pDPhi 158 } 159 160 // -------------------------------------------------------------------- 161 void G4GDMLParameterisation::ComputeDimensions(G4Para& para, const G4int index, 162 const G4VPhysicalVolume*) const 163 { 164 para.SetXHalfLength(parameterList[index].dimension[0]); 165 para.SetYHalfLength(parameterList[index].dimension[1]); 166 para.SetZHalfLength(parameterList[index].dimension[2]); 167 para.SetAlpha(parameterList[index].dimension[3]); 168 para.SetTanAlpha(std::tan(parameterList[index].dimension[3])); 169 para.SetThetaAndPhi(parameterList[index].dimension[4], 170 parameterList[index].dimension[5]); 171 } 172 173 // -------------------------------------------------------------------- 174 void G4GDMLParameterisation::ComputeDimensions(G4Hype& hype, const G4int index, 175 const G4VPhysicalVolume*) const 176 { 177 hype.SetInnerRadius(parameterList[index].dimension[0]); 178 hype.SetOuterRadius(parameterList[index].dimension[1]); 179 hype.SetZHalfLength(parameterList[index].dimension[4]); 180 hype.SetInnerStereo(parameterList[index].dimension[2]); 181 hype.SetOuterStereo(parameterList[index].dimension[3]); 182 } 183 184 // -------------------------------------------------------------------- 185 void G4GDMLParameterisation::ComputeDimensions(G4Polycone& pcone, 186 const G4int index, 187 const G4VPhysicalVolume*) const 188 { 189 G4PolyconeHistorical origparam(*(pcone.GetOriginalParameters())); 190 origparam.Start_angle = parameterList[index].dimension[0]; 191 origparam.Opening_angle = parameterList[index].dimension[1]; 192 origparam.Num_z_planes = (G4int) parameterList[index].dimension[2]; 193 G4int nZplanes = origparam.Num_z_planes; 194 195 for(G4int ii = 0; ii < nZplanes; ++ii) 196 { 197 origparam.Rmin[ii] = parameterList[index].dimension[3 + ii * 3]; 198 origparam.Rmax[ii] = parameterList[index].dimension[4 + ii * 3]; 199 origparam.Z_values[ii] = parameterList[index].dimension[5 + ii * 3]; 200 } 201 202 pcone.SetOriginalParameters(&origparam); // copy values & transfer pointers 203 pcone.Reset(); // reset to new solid parameters 204 } 205 206 // -------------------------------------------------------------------- 207 void G4GDMLParameterisation::ComputeDimensions(G4Polyhedra& polyhedra, 208 const G4int index, 209 const G4VPhysicalVolume*) const 210 { 211 G4PolyhedraHistorical origparam(*(polyhedra.GetOriginalParameters())); 212 origparam.Start_angle = parameterList[index].dimension[0]; 213 origparam.Opening_angle = parameterList[index].dimension[1]; 214 origparam.Num_z_planes = (G4int) parameterList[index].dimension[2]; 215 origparam.numSide = (G4int) parameterList[index].dimension[3]; 216 217 G4int nZplanes = origparam.Num_z_planes; 218 219 for(G4int ii = 0; ii < nZplanes; ++ii) 220 { 221 origparam.Rmin[ii] = parameterList[index].dimension[4 + ii * 3]; 222 origparam.Rmax[ii] = parameterList[index].dimension[5 + ii * 3]; 223 origparam.Z_values[ii] = parameterList[index].dimension[6 + ii * 3]; 224 } 225 polyhedra.SetOriginalParameters( 226 &origparam); // copy values & transfer pointers 227 polyhedra.Reset(); // reset to new solid parameters 228 } 229