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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 // J.L. Chuma, TRIUMF, 31-Oct-1996 << 26 // 27 // last modified: 19-Dec-1996 << 27 // 28 // Modified by J.L.Chuma, 05-May-97 << 28 // J.L. Chuma, TRIUMF, 31-Oct-1996 29 // M. Kelsey 29-Aug-2011 -- Use G4Allocator fo << 29 // last modified: 19-Dec-1996 30 << 30 // Modified by J.L.Chuma, 05-May-97 >> 31 31 #include "G4ReactionProduct.hh" 32 #include "G4ReactionProduct.hh" 32 33 33 G4Allocator<G4ReactionProduct>*& aRPAllocator( << 34 { << 35 G4ThreadLocalStatic G4Allocator<G4Reaction << 36 return _instance; << 37 } << 38 << 39 G4ReactionProduct::G4ReactionProduct() : 34 G4ReactionProduct::G4ReactionProduct() : 40 theParticleDefinition(NULL), 35 theParticleDefinition(NULL), 41 formationTime(0.0), 36 formationTime(0.0), 42 hasInitialStateParton(false), 37 hasInitialStateParton(false), 43 mass(0.0), 38 mass(0.0), 44 totalEnergy(0.0), 39 totalEnergy(0.0), 45 kineticEnergy(0.0), 40 kineticEnergy(0.0), 46 timeOfFlight(0.0), 41 timeOfFlight(0.0), 47 side(0), 42 side(0), 48 theCreatorModel(-1), << 49 theParentResonanceDef(nullptr), << 50 theParentResonanceID(0), << 51 NewlyAdded(false), 43 NewlyAdded(false), 52 MayBeKilled(true) 44 MayBeKilled(true) 53 { 45 { 54 SetMomentum( 0.0, 0.0, 0.0 ); 46 SetMomentum( 0.0, 0.0, 0.0 ); 55 SetPositionInNucleus( 0.0, 0.0, 0.0 ); 47 SetPositionInNucleus( 0.0, 0.0, 0.0 ); 56 } 48 } 57 49 58 G4ReactionProduct::G4ReactionProduct( 50 G4ReactionProduct::G4ReactionProduct( 59 const G4ParticleDefinition *aParticleDefinit << 51 G4ParticleDefinition *aParticleDefinition ) 60 { 52 { 61 SetMomentum( 0.0, 0.0, 0.0 ); 53 SetMomentum( 0.0, 0.0, 0.0 ); 62 SetPositionInNucleus( 0.0, 0.0, 0.0 ); 54 SetPositionInNucleus( 0.0, 0.0, 0.0 ); 63 formationTime = 0.0; 55 formationTime = 0.0; 64 hasInitialStateParton = false; 56 hasInitialStateParton = false; 65 theParticleDefinition = aParticleDefinitio 57 theParticleDefinition = aParticleDefinition; 66 mass = aParticleDefinition->GetPDGMass(); 58 mass = aParticleDefinition->GetPDGMass(); 67 totalEnergy = mass; 59 totalEnergy = mass; 68 kineticEnergy = 0.0; 60 kineticEnergy = 0.0; 69 (aParticleDefinition->GetPDGEncoding()<0) 61 (aParticleDefinition->GetPDGEncoding()<0) ? timeOfFlight=-1.0 : timeOfFlight=1.0; 70 side = 0; 62 side = 0; 71 theCreatorModel = -1; << 72 theParentResonanceDef = nullptr; << 73 theParentResonanceID = 0; << 74 NewlyAdded = false; 63 NewlyAdded = false; 75 MayBeKilled = true; 64 MayBeKilled = true; 76 } 65 } 77 66 78 G4ReactionProduct::G4ReactionProduct( 67 G4ReactionProduct::G4ReactionProduct( 79 const G4ReactionProduct &right ) 68 const G4ReactionProduct &right ) 80 { 69 { 81 theParticleDefinition = right.theParticleD 70 theParticleDefinition = right.theParticleDefinition; 82 positionInNucleus = right.positionInNucleu 71 positionInNucleus = right.positionInNucleus; 83 formationTime = right.formationTime; 72 formationTime = right.formationTime; 84 hasInitialStateParton = right.hasInitialSt 73 hasInitialStateParton = right.hasInitialStateParton; 85 momentum = right.momentum; 74 momentum = right.momentum; 86 mass = right.mass; 75 mass = right.mass; 87 totalEnergy = right.totalEnergy; 76 totalEnergy = right.totalEnergy; 88 kineticEnergy = right.kineticEnergy; 77 kineticEnergy = right.kineticEnergy; 89 timeOfFlight = right.timeOfFlight; 78 timeOfFlight = right.timeOfFlight; 90 side = right.side; 79 side = right.side; 91 theCreatorModel = right.theCreatorModel; << 92 theParentResonanceDef = right.theParentRes << 93 theParentResonanceID = right.theParentReso << 94 NewlyAdded = right.NewlyAdded; 80 NewlyAdded = right.NewlyAdded; 95 MayBeKilled = right.MayBeKilled; 81 MayBeKilled = right.MayBeKilled; 96 } 82 } 97 83 98 G4ReactionProduct &G4ReactionProduct::operato 84 G4ReactionProduct &G4ReactionProduct::operator=( 99 const G4ReactionProduct &right ) 85 const G4ReactionProduct &right ) 100 { 86 { 101 if( this != &right ) { 87 if( this != &right ) { 102 theParticleDefinition = right.theParticl 88 theParticleDefinition = right.theParticleDefinition; 103 positionInNucleus = right.positionInNucl 89 positionInNucleus = right.positionInNucleus; 104 formationTime = right.formationTime; 90 formationTime = right.formationTime; 105 hasInitialStateParton = right.hasInitial 91 hasInitialStateParton = right.hasInitialStateParton; 106 momentum = right.momentum; 92 momentum = right.momentum; 107 mass = right.mass; 93 mass = right.mass; 108 totalEnergy = right.totalEnergy; 94 totalEnergy = right.totalEnergy; 109 kineticEnergy = right.kineticEnergy; 95 kineticEnergy = right.kineticEnergy; 110 timeOfFlight = right.timeOfFlight; 96 timeOfFlight = right.timeOfFlight; 111 side = right.side; 97 side = right.side; 112 theCreatorModel = right.theCreatorModel; << 113 theParentResonanceDef = right.theParentR << 114 theParentResonanceID = right.theParentRe << 115 NewlyAdded = right.NewlyAdded; 98 NewlyAdded = right.NewlyAdded; 116 MayBeKilled = right.MayBeKilled; 99 MayBeKilled = right.MayBeKilled; 117 } 100 } 118 return *this; 101 return *this; 119 } 102 } 120 103 121 G4ReactionProduct &G4ReactionProduct::operato 104 G4ReactionProduct &G4ReactionProduct::operator=( 122 const G4DynamicParticle &right ) 105 const G4DynamicParticle &right ) 123 { 106 { 124 theParticleDefinition = right.GetDefinitio 107 theParticleDefinition = right.GetDefinition(); 125 SetPositionInNucleus( 0.0, 0.0, 0.0 ); 108 SetPositionInNucleus( 0.0, 0.0, 0.0 ); 126 formationTime = 0.0; 109 formationTime = 0.0; 127 hasInitialStateParton = false; 110 hasInitialStateParton = false; 128 momentum = right.GetMomentum(); 111 momentum = right.GetMomentum(); 129 mass = right.GetDefinition()->GetPDGMass() 112 mass = right.GetDefinition()->GetPDGMass(); 130 totalEnergy = right.GetTotalEnergy(); 113 totalEnergy = right.GetTotalEnergy(); 131 kineticEnergy = right.GetKineticEnergy(); 114 kineticEnergy = right.GetKineticEnergy(); 132 (right.GetDefinition()->GetPDGEncoding()<0 115 (right.GetDefinition()->GetPDGEncoding()<0) ? timeOfFlight=-1.0 : timeOfFlight=1.0; 133 side = 0; 116 side = 0; 134 theCreatorModel = -1; << 135 theParentResonanceDef = nullptr; << 136 theParentResonanceID = 0; << 137 NewlyAdded = false; 117 NewlyAdded = false; 138 MayBeKilled = true; 118 MayBeKilled = true; 139 return *this; 119 return *this; 140 } 120 } 141 121 142 G4ReactionProduct &G4ReactionProduct::operato 122 G4ReactionProduct &G4ReactionProduct::operator=( 143 const G4HadProjectile &right ) 123 const G4HadProjectile &right ) 144 { 124 { 145 theParticleDefinition = right.GetDefinitio << 125 theParticleDefinition = const_cast<G4ParticleDefinition *>(right.GetDefinition()); 146 SetPositionInNucleus( 0.0, 0.0, 0.0 ); 126 SetPositionInNucleus( 0.0, 0.0, 0.0 ); 147 formationTime = 0.0; 127 formationTime = 0.0; 148 hasInitialStateParton = false; 128 hasInitialStateParton = false; 149 momentum = right.Get4Momentum().vect(); 129 momentum = right.Get4Momentum().vect(); 150 mass = right.GetDefinition()->GetPDGMass() 130 mass = right.GetDefinition()->GetPDGMass(); 151 totalEnergy = right.Get4Momentum().e(); 131 totalEnergy = right.Get4Momentum().e(); 152 kineticEnergy = right.GetKineticEnergy(); 132 kineticEnergy = right.GetKineticEnergy(); 153 (right.GetDefinition()->GetPDGEncoding()<0 133 (right.GetDefinition()->GetPDGEncoding()<0) ? timeOfFlight=-1.0 : timeOfFlight=1.0; 154 side = 0; 134 side = 0; 155 theCreatorModel = -1; << 156 theParentResonanceDef = nullptr; << 157 theParentResonanceID = 0; << 158 NewlyAdded = false; 135 NewlyAdded = false; 159 MayBeKilled = true; 136 MayBeKilled = true; 160 return *this; 137 return *this; 161 } 138 } 162 139 163 void G4ReactionProduct::SetDefinitionAndUpdat 140 void G4ReactionProduct::SetDefinitionAndUpdateE( 164 const G4ParticleDefinition *aParticleDefinit << 141 G4ParticleDefinition *aParticleDefinition ) 165 { G4double aKineticEnergy = GetKineticEne << 142 { >> 143 G4double aKineticEnergy = GetKineticEnergy(); 166 G4double pp = GetMomentum().mag(); 144 G4double pp = GetMomentum().mag(); 167 G4ThreeVector aMomentum = GetMomentum(); 145 G4ThreeVector aMomentum = GetMomentum(); 168 SetDefinition( aParticleDefinition ); 146 SetDefinition( aParticleDefinition ); 169 SetKineticEnergy( aKineticEnergy ); 147 SetKineticEnergy( aKineticEnergy ); 170 if( pp > DBL_MIN ) 148 if( pp > DBL_MIN ) 171 SetMomentum( aMomentum * (std::sqrt(aKin 149 SetMomentum( aMomentum * (std::sqrt(aKineticEnergy*aKineticEnergy + 172 2*aKinetic 150 2*aKineticEnergy*GetMass())/pp) ); 173 } 151 } 174 152 175 void G4ReactionProduct::SetDefinition( 153 void G4ReactionProduct::SetDefinition( 176 const G4ParticleDefinition *aParticleDefinit << 154 G4ParticleDefinition *aParticleDefinition ) 177 { 155 { 178 theParticleDefinition = aParticleDefinitio 156 theParticleDefinition = aParticleDefinition; 179 mass = aParticleDefinition->GetPDGMass(); 157 mass = aParticleDefinition->GetPDGMass(); 180 totalEnergy = mass; 158 totalEnergy = mass; 181 kineticEnergy = 0.0; 159 kineticEnergy = 0.0; 182 (aParticleDefinition->GetPDGEncoding()<0) 160 (aParticleDefinition->GetPDGEncoding()<0) ? 183 timeOfFlight=-1.0 : timeOfFlight=1.0; 161 timeOfFlight=-1.0 : timeOfFlight=1.0; 184 } 162 } 185 163 186 void G4ReactionProduct::SetMomentum( 164 void G4ReactionProduct::SetMomentum( 187 const G4double x, const G4double y, const G4 165 const G4double x, const G4double y, const G4double z ) 188 { 166 { 189 momentum.setX( x ); 167 momentum.setX( x ); 190 momentum.setY( y ); 168 momentum.setY( y ); 191 momentum.setZ( z ); 169 momentum.setZ( z ); 192 } 170 } 193 171 194 void G4ReactionProduct::SetMomentum( 172 void G4ReactionProduct::SetMomentum( 195 const G4double x, const G4double y ) 173 const G4double x, const G4double y ) 196 { 174 { 197 momentum.setX( x ); 175 momentum.setX( x ); 198 momentum.setY( y ); 176 momentum.setY( y ); 199 } 177 } 200 178 201 void G4ReactionProduct::SetMomentum( const G4 179 void G4ReactionProduct::SetMomentum( const G4double z ) 202 { 180 { 203 momentum.setZ( z ); 181 momentum.setZ( z ); 204 } 182 } 205 183 206 void G4ReactionProduct::SetZero() 184 void G4ReactionProduct::SetZero() 207 { 185 { 208 SetMomentum( 0.0, 0.0, 0.0 ); 186 SetMomentum( 0.0, 0.0, 0.0 ); 209 totalEnergy = 0.0; 187 totalEnergy = 0.0; 210 kineticEnergy = 0.0; 188 kineticEnergy = 0.0; 211 mass = 0.0; 189 mass = 0.0; 212 timeOfFlight = 0.0; 190 timeOfFlight = 0.0; 213 side = 0; 191 side = 0; 214 theCreatorModel = -1; << 215 theParentResonanceDef = nullptr; << 216 theParentResonanceID = 0; << 217 NewlyAdded = false; 192 NewlyAdded = false; 218 SetPositionInNucleus( 0.0, 0.0, 0.0 ); 193 SetPositionInNucleus( 0.0, 0.0, 0.0 ); 219 formationTime = 0.0; 194 formationTime = 0.0; 220 hasInitialStateParton = false; 195 hasInitialStateParton = false; 221 } 196 } 222 197 223 void G4ReactionProduct::Lorentz( 198 void G4ReactionProduct::Lorentz( 224 const G4ReactionProduct &p1, const G4Reacti 199 const G4ReactionProduct &p1, const G4ReactionProduct &p2 ) 225 { 200 { 226 G4ThreeVector p1M = p1.momentum; 201 G4ThreeVector p1M = p1.momentum; 227 G4ThreeVector p2M = p2.momentum; 202 G4ThreeVector p2M = p2.momentum; 228 G4double p1x = p1M.x(); G4double p1y = p1M 203 G4double p1x = p1M.x(); G4double p1y = p1M.y(); G4double p1z = p1M.z(); 229 G4double p2x = p2M.x(); G4double p2y = p2M 204 G4double p2x = p2M.x(); G4double p2y = p2M.y(); G4double p2z = p2M.z(); 230 G4double a = ( (p1x*p2x+p1y*p2y+p1z*p2z)/( 205 G4double a = ( (p1x*p2x+p1y*p2y+p1z*p2z)/(p2.totalEnergy+p2.mass) - 231 p1.totalEnergy ) / p2.mass; 206 p1.totalEnergy ) / p2.mass; 232 G4double x = p1x+a*p2x; 207 G4double x = p1x+a*p2x; 233 G4double y = p1y+a*p2y; 208 G4double y = p1y+a*p2y; 234 G4double z = p1z+a*p2z; 209 G4double z = p1z+a*p2z; 235 G4double p = std::sqrt(x*x+y*y+z*z); 210 G4double p = std::sqrt(x*x+y*y+z*z); 236 SetMass( p1.mass ); 211 SetMass( p1.mass ); 237 SetTotalEnergy( std::sqrt( (p1.mass+p)*(p1 212 SetTotalEnergy( std::sqrt( (p1.mass+p)*(p1.mass+p) - 2.*p1.mass*p ) ); 238 //SetTotalEnergy( std::sqrt( p1.mass*p1.ma 213 //SetTotalEnergy( std::sqrt( p1.mass*p1.mass + x*x + y*y + z*z ) ); 239 SetMomentum( x, y, z ); 214 SetMomentum( x, y, z ); 240 } 215 } 241 216 242 G4double G4ReactionProduct::Angle( 217 G4double G4ReactionProduct::Angle( 243 const G4ReactionProduct& p ) const 218 const G4ReactionProduct& p ) const 244 { 219 { 245 G4ThreeVector tM = momentum; 220 G4ThreeVector tM = momentum; 246 G4ThreeVector pM = p.momentum; 221 G4ThreeVector pM = p.momentum; 247 G4double tx = tM.x(); G4double ty = tM.y() 222 G4double tx = tM.x(); G4double ty = tM.y(); G4double tz = tM.z(); 248 G4double px = pM.x(); G4double py = pM.y() 223 G4double px = pM.x(); G4double py = pM.y(); G4double pz = pM.z(); 249 G4double a = std::sqrt( ( px*px + py*py + 224 G4double a = std::sqrt( ( px*px + py*py + pz*pz ) * ( tx*tx + ty*ty + tz*tz ) ); 250 if( a == 0.0 ) { 225 if( a == 0.0 ) { 251 return 0.0; 226 return 0.0; 252 } else { 227 } else { 253 a = ( tx*px + ty*py + tz*pz ) / a; 228 a = ( tx*px + ty*py + tz*pz ) / a; 254 if( std::abs(a) > 1.0 ) { a<0.0 ? a=-1.0 << 229 if( std::fabs(a) > 1.0 ) { a<0.0 ? a=-1.0 : a=1.0; } 255 return std::acos( a ); 230 return std::acos( a ); 256 } 231 } 257 } 232 } 258 233 259 G4ReactionProduct operator+( 234 G4ReactionProduct operator+( 260 const G4ReactionProduct& p1, const G4Reactio 235 const G4ReactionProduct& p1, const G4ReactionProduct& p2 ) 261 { 236 { 262 G4double totEnergy = p1.totalEnergy + p2.t 237 G4double totEnergy = p1.totalEnergy + p2.totalEnergy; 263 G4double x = p1.momentum.x() + p2.momentum 238 G4double x = p1.momentum.x() + p2.momentum.x(); 264 G4double y = p1.momentum.y() + p2.momentum 239 G4double y = p1.momentum.y() + p2.momentum.y(); 265 G4double z = p1.momentum.z() + p2.momentum 240 G4double z = p1.momentum.z() + p2.momentum.z(); 266 G4double newMass = totEnergy*totEnergy - ( 241 G4double newMass = totEnergy*totEnergy - ( x*x + y*y + z*z ); 267 if( newMass < 0.0 ) 242 if( newMass < 0.0 ) 268 newMass = -1. * std::sqrt( -newMass ); 243 newMass = -1. * std::sqrt( -newMass ); 269 else 244 else 270 newMass = std::sqrt( newMass ); 245 newMass = std::sqrt( newMass ); 271 G4ReactionProduct result; 246 G4ReactionProduct result; 272 result.SetMass( newMass ); 247 result.SetMass( newMass ); 273 result.SetMomentum( x, y, z ); 248 result.SetMomentum( x, y, z ); 274 result.SetTotalEnergy( totEnergy ); 249 result.SetTotalEnergy( totEnergy ); 275 result.SetPositionInNucleus( 0.0, 0.0, 0.0 250 result.SetPositionInNucleus( 0.0, 0.0, 0.0 ); 276 result.SetFormationTime(0.0); 251 result.SetFormationTime(0.0); 277 result.HasInitialStateParton(false); 252 result.HasInitialStateParton(false); 278 return result; 253 return result; 279 } 254 } 280 255 281 G4ReactionProduct operator-( 256 G4ReactionProduct operator-( 282 const G4ReactionProduct& p1, const G4Reactio 257 const G4ReactionProduct& p1, const G4ReactionProduct& p2 ) 283 { 258 { 284 G4double totEnergy = p1.totalEnergy - p2.t 259 G4double totEnergy = p1.totalEnergy - p2.totalEnergy; 285 G4double x = p1.momentum.x() - p2.momentum 260 G4double x = p1.momentum.x() - p2.momentum.x(); 286 G4double y = p1.momentum.y() - p2.momentum 261 G4double y = p1.momentum.y() - p2.momentum.y(); 287 G4double z = p1.momentum.z() - p2.momentum 262 G4double z = p1.momentum.z() - p2.momentum.z(); 288 G4double newMass = totEnergy*totEnergy - ( 263 G4double newMass = totEnergy*totEnergy - ( x*x + y*y + z*z ); 289 if( newMass < 0.0 ) 264 if( newMass < 0.0 ) 290 newMass = -1. * std::sqrt( -newMass ); 265 newMass = -1. * std::sqrt( -newMass ); 291 else 266 else 292 newMass = std::sqrt( newMass ); 267 newMass = std::sqrt( newMass ); 293 G4ReactionProduct result; 268 G4ReactionProduct result; 294 result.SetMass( newMass ); 269 result.SetMass( newMass ); 295 result.SetMomentum( x, y, z ); 270 result.SetMomentum( x, y, z ); 296 result.SetTotalEnergy( totEnergy ); 271 result.SetTotalEnergy( totEnergy ); 297 result.SetPositionInNucleus( 0.0, 0.0, 0.0 272 result.SetPositionInNucleus( 0.0, 0.0, 0.0 ); 298 result.SetFormationTime(0.0); 273 result.SetFormationTime(0.0); 299 result.HasInitialStateParton(false); 274 result.HasInitialStateParton(false); 300 return result; 275 return result; 301 } 276 } 302 /* end of code */ 277 /* end of code */ 303 278 304 279