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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 // $Id$ >> 28 // >> 29 // 26 // class G4VPhysicalVolume Implementation 30 // class G4VPhysicalVolume Implementation 27 // 31 // 28 // 15.01.13, G.Cosmo, A.Dotti: Modified for th << 29 // 28.08.96, P.Kent: Replaced transform by rot << 30 // 25.07.96, P.Kent: Modified interface for ne << 31 // 24.07.95, P.Kent: First non-stub version << 32 // ------------------------------------------- 32 // -------------------------------------------------------------------- 33 33 34 #include "G4VPhysicalVolume.hh" 34 #include "G4VPhysicalVolume.hh" 35 35 36 #include "G4PhysicalVolumeStore.hh" 36 #include "G4PhysicalVolumeStore.hh" 37 #include "G4LogicalVolume.hh" 37 #include "G4LogicalVolume.hh" 38 38 39 // This new field helps to use the class G4PVM << 40 // << 41 G4PVManager G4VPhysicalVolume::subInstanceMana << 42 << 43 // These macros change the references to field << 44 // in the class G4PVData. << 45 // << 46 #define G4MT_rot ((subInstanceManager.offset[i << 47 #define G4MT_tx ((subInstanceManager.offset[in << 48 #define G4MT_ty ((subInstanceManager.offset[in << 49 #define G4MT_tz ((subInstanceManager.offset[in << 50 #define G4MT_pvdata (subInstanceManager.offset << 51 << 52 // Constructor: init parameters and register i 39 // Constructor: init parameters and register in Store 53 // 40 // 54 G4VPhysicalVolume::G4VPhysicalVolume( G4Rotati << 41 G4VPhysicalVolume::G4VPhysicalVolume( G4RotationMatrix *pRot, 55 const G4ThreeV << 42 const G4ThreeVector &tlate, 56 const G4String 43 const G4String& pName, 57 G4Logica 44 G4LogicalVolume* pLogical, 58 G4VPhysi 45 G4VPhysicalVolume* ) 59 : flogical(pLogical), fname(pName) << 46 : frot(pRot), ftrans(tlate), flogical(pLogical), >> 47 fname(pName), flmother(0) 60 { 48 { 61 instanceID = subInstanceManager.CreateSubIns << 62 << 63 this->SetRotation( pRot ); // G4MT_rot << 64 this->SetTranslation( tlate ); // G4MT_tra << 65 << 66 // Initialize 'Shadow' data structure - for << 67 pvdata = new G4PVData(); << 68 pvdata->frot = pRot; << 69 pvdata->tx = tlate.x(); << 70 pvdata->ty = tlate.y(); << 71 pvdata->tz = tlate.z(); << 72 << 73 G4PhysicalVolumeStore::Register(this); 49 G4PhysicalVolumeStore::Register(this); 74 } 50 } 75 51 76 // Fake default constructor - sets only member 52 // Fake default constructor - sets only member data and allocates memory 77 // for usage restri 53 // for usage restricted to object persistency. 78 // 54 // 79 G4VPhysicalVolume::G4VPhysicalVolume( __void__ 55 G4VPhysicalVolume::G4VPhysicalVolume( __void__& ) 80 : fname("") << 56 : frot(0), flogical(0), fname(""), flmother(0) 81 { 57 { 82 // Register to store 58 // Register to store 83 // 59 // 84 instanceID = subInstanceManager.CreateSubIns << 85 << 86 G4PhysicalVolumeStore::Register(this); 60 G4PhysicalVolumeStore::Register(this); 87 } 61 } 88 62 89 // Destructor - remove from Store 63 // Destructor - remove from Store 90 // 64 // 91 G4VPhysicalVolume::~G4VPhysicalVolume() 65 G4VPhysicalVolume::~G4VPhysicalVolume() 92 { 66 { 93 delete pvdata; << 94 G4PhysicalVolumeStore::DeRegister(this); 67 G4PhysicalVolumeStore::DeRegister(this); 95 } 68 } 96 69 97 // Set volume name and notify store of the cha << 98 // << 99 void G4VPhysicalVolume::SetName(const G4String << 100 { << 101 fname = pName; << 102 G4PhysicalVolumeStore::GetInstance()->SetMap << 103 } << 104 << 105 // This method is similar to the constructor. << 106 // thread to achieve the same effect as that o << 107 // to register the new created instance. This << 108 // It does not create a new G4VPhysicalVolume << 109 // It only assign the value for the fields enc << 110 // << 111 void G4VPhysicalVolume:: << 112 InitialiseWorker( G4VPhysicalVolume* /*pMaster << 113 G4RotationMatrix *pRot, << 114 const G4ThreeVector &tlate) << 115 { << 116 subInstanceManager.SlaveCopySubInstanceArray << 117 << 118 this->SetRotation( pRot ); // G4MT_rot << 119 this->SetTranslation( tlate ); // G4MT_tran << 120 // G4PhysicalVolumeStore::Register(this); << 121 } << 122 << 123 // Release memory allocated for offset << 124 // << 125 void G4VPhysicalVolume::Clean() << 126 { << 127 subInstanceManager.FreeSlave(); << 128 } << 129 << 130 // This method is similar to the destructor. I << 131 // thread to achieve the partial effect as tha << 132 // For G4VPhysicalVolume instances, nothing mo << 133 // << 134 void G4VPhysicalVolume::TerminateWorker( G4VPh << 135 { << 136 } << 137 << 138 // Returns the private data instance manager. << 139 // << 140 const G4PVManager& G4VPhysicalVolume::GetSubIn << 141 { << 142 return subInstanceManager; << 143 } << 144 << 145 G4int G4VPhysicalVolume::GetMultiplicity() con 70 G4int G4VPhysicalVolume::GetMultiplicity() const 146 { 71 { 147 return 1; 72 return 1; 148 } 73 } 149 74 150 const G4ThreeVector G4VPhysicalVolume::GetTran << 151 { << 152 return G4ThreeVector(G4MT_tx, G4MT_ty, G4MT_ << 153 } << 154 << 155 void G4VPhysicalVolume::SetTranslation(const G << 156 { << 157 G4MT_tx=vec.x(); G4MT_ty=vec.y(); G4MT_tz=ve << 158 } << 159 << 160 const G4RotationMatrix* G4VPhysicalVolume::Get << 161 { << 162 return G4MT_rot; << 163 } << 164 << 165 G4RotationMatrix* G4VPhysicalVolume::GetRotati << 166 { << 167 return G4MT_rot; << 168 } << 169 << 170 void G4VPhysicalVolume::SetRotation(G4Rotation << 171 { << 172 G4MT_rot = pRot; << 173 } << 174 << 175 G4RotationMatrix* G4VPhysicalVolume::GetObject 75 G4RotationMatrix* G4VPhysicalVolume::GetObjectRotation() const 176 { 76 { 177 static G4RotationMatrix aRotM; << 77 static G4RotationMatrix aRotM; 178 static G4RotationMatrix IdentityRM; << 78 static G4RotationMatrix IdentityRM; // Never changed (from "1") 179 << 79 G4RotationMatrix* retval; 180 G4RotationMatrix* retval = &IdentityRM; << 181 80 182 // Insure against frot being a null pointer 81 // Insure against frot being a null pointer 183 if(this->GetRotation() != nullptr) << 82 if(frot) 184 { 83 { 185 aRotM = GetRotation()->inverse(); << 84 aRotM= frot->inverse(); 186 retval= &aRotM; << 85 retval= &aRotM; 187 } 86 } 188 return retval; << 87 else 189 } << 190 << 191 G4RotationMatrix G4VPhysicalVolume::GetObjectR << 192 { << 193 G4RotationMatrix aRotM; // Initialised to << 194 << 195 // Insure against G4MT_rot being a null poin << 196 if(G4MT_rot) << 197 { 88 { 198 aRotM = G4MT_rot->inverse(); << 89 retval= &IdentityRM; 199 } 90 } 200 return aRotM; << 91 return retval; 201 } << 202 << 203 G4ThreeVector G4VPhysicalVolume::GetObjectTra << 204 { << 205 return {G4MT_tx, G4MT_ty, G4MT_tz}; << 206 } << 207 << 208 const G4RotationMatrix* G4VPhysicalVolume::Get << 209 { << 210 return G4MT_rot; << 211 } << 212 << 213 G4ThreeVector G4VPhysicalVolume::GetFrameTran << 214 { << 215 return -G4ThreeVector(G4MT_tx, G4MT_ty, G4MT << 216 } 92 } 217 93 218 // Only implemented for placed and parameteris 94 // Only implemented for placed and parameterised volumes. 219 // Not required for replicas. 95 // Not required for replicas. 220 // 96 // 221 G4bool G4VPhysicalVolume::CheckOverlaps(G4int, << 97 G4bool G4VPhysicalVolume::CheckOverlaps(G4int, G4double, G4bool) 222 { 98 { 223 return false; 99 return false; 224 } 100 } 225 101