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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 // neutron_hp -- source file 26 // neutron_hp -- source file 27 // J.P. Wellisch, Nov-1996 27 // J.P. Wellisch, Nov-1996 28 // A prototype of the low energy neutron trans 28 // A prototype of the low energy neutron transport model. 29 // 29 // 30 // 080612 SampleDiscreteTwoBody contribution f << 30 // 080612 SampleDiscreteTwoBody contribution from Benoit Pirard and Laurent Desorgher (Univ. Bern) #3 31 // #3 << 32 // 31 // 33 // P. Arce, June-2014 Conversion neutron_hp to 32 // P. Arce, June-2014 Conversion neutron_hp to particle_hp 34 // 33 // 35 #include "G4ParticleHPLegendreStore.hh" 34 #include "G4ParticleHPLegendreStore.hh" 36 << 37 #include "G4ParticleHPFastLegendre.hh" << 38 #include "G4ParticleHPInterpolator.hh" << 39 #include "G4ParticleHPVector.hh" 35 #include "G4ParticleHPVector.hh" >> 36 #include "G4ParticleHPInterpolator.hh" >> 37 #include "G4ParticleHPFastLegendre.hh" 40 #include "Randomize.hh" 38 #include "Randomize.hh" 41 << 42 #include <iostream> 39 #include <iostream> 43 40 44 // 080612TK contribution from Benoit Pirard an << 45 G4double G4ParticleHPLegendreStore::SampleDisc << 46 { << 47 G4double result = 0.; << 48 41 >> 42 >> 43 //080612TK contribution from Benoit Pirard and Laurent Desorgher (Univ. Bern) #3 >> 44 G4double G4ParticleHPLegendreStore::SampleDiscreteTwoBody (G4double anEnergy) >> 45 { >> 46 G4double result=0.; >> 47 49 G4int i0; 48 G4int i0; 50 G4int low(0), high(0); 49 G4int low(0), high(0); 51 G4ParticleHPFastLegendre theLeg; 50 G4ParticleHPFastLegendre theLeg; 52 for (i0 = 0; i0 < nEnergy; i0++) { << 51 for (i0=0; i0<nEnergy; i0++) >> 52 { 53 high = i0; 53 high = i0; 54 if (theCoeff[i0].GetEnergy() > anEnergy) b << 54 if(theCoeff[i0].GetEnergy()>anEnergy) break; 55 } 55 } 56 low = std::max(0, high - 1); << 56 low = std::max(0, high-1); 57 G4ParticleHPInterpolator theInt; 57 G4ParticleHPInterpolator theInt; 58 G4double x, x1, x2; 58 G4double x, x1, x2; 59 x = anEnergy; 59 x = anEnergy; 60 x1 = theCoeff[low].GetEnergy(); 60 x1 = theCoeff[low].GetEnergy(); 61 x2 = theCoeff[high].GetEnergy(); 61 x2 = theCoeff[high].GetEnergy(); 62 G4double theNorm = 0; 62 G4double theNorm = 0; 63 G4double try01 = 0, try02 = 0; << 63 G4double try01=0, try02=0; 64 G4double max1, max2, costh; 64 G4double max1, max2, costh; 65 max1 = 0; << 65 max1 = 0; max2 = 0; 66 max2 = 0; << 66 G4int l,m_tmp; 67 G4int l, m_tmp; << 67 for(i0=0; i0<601; i0++) 68 for (i0 = 0; i0 < 601; i0++) { << 68 { 69 costh = G4double(i0 - 300) / 300.; << 69 costh = G4double(i0-300)/300.; 70 try01 = 0.5; << 70 try01 = 0.5; 71 for (m_tmp = 0; m_tmp < theCoeff[low].GetN << 71 for(m_tmp=0; m_tmp<theCoeff[low].GetNumberOfPoly() ; m_tmp++) 72 l = m_tmp + 1; << 72 { 73 try01 += (2. * l + 1) / 2. * theCoeff[lo << 73 l=m_tmp+1; 74 } << 74 try01 += (2.*l+1)/2.*theCoeff[low].GetCoeff(m_tmp)*theLeg.Evaluate(l, costh); 75 if (try01 > max1) max1 = try01; << 75 } 76 try02 = 0.5; << 76 if(try01>max1) max1=try01; 77 for (m_tmp = 0; m_tmp < theCoeff[high].Get << 77 try02 = 0.5; 78 l = m_tmp + 1; << 78 for(m_tmp=0; m_tmp<theCoeff[high].GetNumberOfPoly() ; m_tmp++) 79 try02 += (2. * l + 1) / 2. * theCoeff[hi << 79 { 80 } << 80 l=m_tmp+1; 81 if (try02 > max2) max2 = try02; << 81 try02 += (2.*l+1)/2.*theCoeff[high].GetCoeff(m_tmp)*theLeg.Evaluate(l, costh); 82 } << 82 } >> 83 if(try02>max2) max2=try02; >> 84 } 83 theNorm = theInt.Interpolate(theManager.GetS 85 theNorm = theInt.Interpolate(theManager.GetScheme(high), x, x1, x2, max1, max2); 84 << 86 85 G4double value, random; 87 G4double value, random; 86 G4double v1, v2; 88 G4double v1, v2; 87 G4int icounter = 0; << 89 G4int icounter=0; 88 G4int icounter_max = 1024; << 90 G4int icounter_max=1024; 89 do { << 91 do >> 92 { 90 icounter++; 93 icounter++; 91 if (icounter > icounter_max) { << 94 if ( icounter > icounter_max ) { 92 G4cout << "Loop-counter exceeded the thr << 95 G4cout << "Loop-counter exceeded the threshold value at " << __LINE__ << "th line of " << __FILE__ << "." << G4endl; 93 << __FILE__ << "." << G4endl; << 96 break; 94 break; << 95 } 97 } 96 v1 = 0.5; 98 v1 = 0.5; 97 v2 = 0.5; 99 v2 = 0.5; 98 result = 2. * G4UniformRand() - 1.; << 100 result = 2.*G4UniformRand()-1.; 99 for (m_tmp = 0; m_tmp < theCoeff[low].GetN << 101 for(m_tmp=0; m_tmp<theCoeff[low].GetNumberOfPoly() ; m_tmp++) 100 l = m_tmp + 1; << 102 { 101 G4double legend = theLeg.Evaluate(l, res << 103 l=m_tmp+1; 102 v1 += (2. * l + 1) / 2. * theCoeff[low]. << 104 G4double legend = theLeg.Evaluate(l, result); // @@@ done to avoid optimization error on SUN 103 } << 105 v1 += (2.*l+1)/2.*theCoeff[low].GetCoeff(m_tmp)*legend; 104 for (m_tmp = 0; m_tmp < theCoeff[high].Get << 106 } 105 l = m_tmp + 1; << 107 for(m_tmp=0; m_tmp<theCoeff[high].GetNumberOfPoly() ; m_tmp++) 106 G4double legend = theLeg.Evaluate(l, res << 108 { 107 v2 += (2. * l + 1) / 2. * theCoeff[high] << 109 l=m_tmp+1; 108 } << 110 G4double legend = theLeg.Evaluate(l, result); // @@@ done to avoid optimization error on SUN >> 111 v2 += (2.*l+1)/2.*theCoeff[high].GetCoeff(m_tmp)*legend; >> 112 } 109 // v1 = std::max(0.,v1); // Workaround in 113 // v1 = std::max(0.,v1); // Workaround in case one of the distributions is fully non-physical. 110 // v2 = std::max(0.,v2); << 114 // v2 = std::max(0.,v2); 111 value = theInt.Interpolate(theManager.GetS 115 value = theInt.Interpolate(theManager.GetScheme(high), x, x1, x2, v1, v2); 112 random = G4UniformRand(); 116 random = G4UniformRand(); 113 if (0 >= theNorm) break; // Workaround fo << 117 if(0>=theNorm) break; // Workaround for negative cross-section values. @@@@ 31 May 2000 114 } while (random > value / theNorm); // Loop << 118 } >> 119 while(random>value/theNorm); // Loop checking, 11.05.2015, T. Koi 115 120 116 return result; 121 return result; 117 } 122 } 118 123 119 G4double G4ParticleHPLegendreStore::SampleMax( << 120 { << 121 G4double result = 0.; << 122 124 >> 125 >> 126 G4double G4ParticleHPLegendreStore::SampleMax (G4double anEnergy) >> 127 { >> 128 G4double result=0.; >> 129 123 G4int i0; 130 G4int i0; 124 G4int low(0), high(0); 131 G4int low(0), high(0); 125 G4ParticleHPFastLegendre theLeg; 132 G4ParticleHPFastLegendre theLeg; 126 for (i0 = 0; i0 < nEnergy; i0++) { << 133 for (i0=0; i0<nEnergy; i0++) >> 134 { 127 high = i0; 135 high = i0; 128 if (theCoeff[i0].GetEnergy() > anEnergy) b << 136 if(theCoeff[i0].GetEnergy()>anEnergy) break; 129 } 137 } 130 low = std::max(0, high - 1); << 138 low = std::max(0, high-1); 131 G4ParticleHPInterpolator theInt; 139 G4ParticleHPInterpolator theInt; 132 G4double x, x1, x2; 140 G4double x, x1, x2; 133 x = anEnergy; 141 x = anEnergy; 134 x1 = theCoeff[low].GetEnergy(); 142 x1 = theCoeff[low].GetEnergy(); 135 x2 = theCoeff[high].GetEnergy(); 143 x2 = theCoeff[high].GetEnergy(); 136 G4double theNorm = 0; 144 G4double theNorm = 0; 137 G4double try01 = 0, try02 = 0; << 145 G4double try01=0, try02=0; 138 G4double max1, max2, costh; 146 G4double max1, max2, costh; 139 max1 = 0; << 147 max1 = 0; max2 = 0; 140 max2 = 0; << 141 G4int l; 148 G4int l; 142 for (i0 = 0; i0 < 601; i0++) { << 149 for(i0=0; i0<601; i0++) 143 costh = G4double(i0 - 300) / 300.; << 150 { >> 151 costh = G4double(i0-300)/300.; 144 try01 = 0; 152 try01 = 0; 145 for (l = 0; l < theCoeff[low].GetNumberOfP << 153 for(l=0; l<theCoeff[low].GetNumberOfPoly() ; l++) 146 try01 += (2. * l + 1) / 2. * theCoeff[lo << 154 { 147 } << 155 try01 += (2.*l+1)/2.*theCoeff[low].GetCoeff(l)*theLeg.Evaluate(l, costh); 148 if (try01 > max1) max1 = try01; << 156 } >> 157 if(try01>max1) max1=try01; 149 try02 = 0; 158 try02 = 0; 150 for (l = 0; l < theCoeff[high].GetNumberOf << 159 for(l=0; l<theCoeff[high].GetNumberOfPoly() ; l++) 151 try02 += (2. * l + 1) / 2. * theCoeff[hi << 160 { >> 161 try02 += (2.*l+1)/2.*theCoeff[high].GetCoeff(l)*theLeg.Evaluate(l, costh); 152 } 162 } 153 if (try02 > max2) max2 = try02; << 163 if(try02>max2) max2=try02; 154 } << 164 } 155 theNorm = theInt.Interpolate(theManager.GetS 165 theNorm = theInt.Interpolate(theManager.GetScheme(high), x, x1, x2, max1, max2); 156 << 166 157 G4double value, random; 167 G4double value, random; 158 G4double v1, v2; 168 G4double v1, v2; 159 G4int icounter = 0; << 169 G4int icounter=0; 160 G4int icounter_max = 1024; << 170 G4int icounter_max=1024; 161 do { << 171 do >> 172 { 162 icounter++; 173 icounter++; 163 if (icounter > icounter_max) { << 174 if ( icounter > icounter_max ) { 164 G4cout << "Loop-counter exceeded the thr << 175 G4cout << "Loop-counter exceeded the threshold value at " << __LINE__ << "th line of " << __FILE__ << "." << G4endl; 165 << __FILE__ << "." << G4endl; << 176 break; 166 break; << 167 } 177 } 168 v1 = 0; 178 v1 = 0; 169 v2 = 0; 179 v2 = 0; 170 result = 2. * G4UniformRand() - 1.; << 180 result = 2.*G4UniformRand()-1.; 171 for (l = 0; l < theCoeff[low].GetNumberOfP << 181 for(l=0; l<theCoeff[low].GetNumberOfPoly() ; l++) 172 G4double legend = theLeg.Evaluate(l, res << 182 { 173 v1 += (2. * l + 1) / 2. * theCoeff[low]. << 183 G4double legend = theLeg.Evaluate(l, result); // @@@ done to avoid optimization error on SUN 174 } << 184 v1 += (2.*l+1)/2.*theCoeff[low].GetCoeff(l)*legend; 175 for (l = 0; l < theCoeff[high].GetNumberOf << 185 } 176 G4double legend = theLeg.Evaluate(l, res << 186 for(l=0; l<theCoeff[high].GetNumberOfPoly() ; l++) 177 v2 += (2. * l + 1) / 2. * theCoeff[high] << 187 { 178 } << 188 G4double legend = theLeg.Evaluate(l, result); // @@@ done to avoid optimization error on SUN 179 v1 = std::max(0., v1); // Workaround in c << 189 v2 += (2.*l+1)/2.*theCoeff[high].GetCoeff(l)*legend; 180 v2 = std::max(0., v2); << 190 } >> 191 v1 = std::max(0.,v1); // Workaround in case one of the distributions is fully non-physical. >> 192 v2 = std::max(0.,v2); 181 value = theInt.Interpolate(theManager.GetS 193 value = theInt.Interpolate(theManager.GetScheme(high), x, x1, x2, v1, v2); 182 random = G4UniformRand(); 194 random = G4UniformRand(); 183 if (0 >= theNorm) break; // Workaround fo << 195 if(0>=theNorm) break; // Workaround for negative cross-section values. @@@@ 31 May 2000 184 } while (random > value / theNorm); // Loop << 196 } >> 197 while(random>value/theNorm); // Loop checking, 11.05.2015, T. Koi 185 return result; 198 return result; 186 } 199 } 187 200 188 G4double G4ParticleHPLegendreStore::SampleElas << 189 { << 190 G4double result = 0.; << 191 201 >> 202 G4double G4ParticleHPLegendreStore::SampleElastic (G4double anEnergy) >> 203 { >> 204 G4double result=0.; >> 205 192 G4int i0; 206 G4int i0; 193 G4int low(0), high(0); 207 G4int low(0), high(0); 194 G4ParticleHPFastLegendre theLeg; 208 G4ParticleHPFastLegendre theLeg; 195 for (i0 = 0; i0 < nEnergy; i0++) { << 209 for (i0=0; i0<nEnergy; i0++) >> 210 { 196 high = i0; 211 high = i0; 197 if (theCoeff[i0].GetEnergy() > anEnergy) b << 212 if(theCoeff[i0].GetEnergy()>anEnergy) break; 198 } 213 } 199 low = std::max(0, high - 1); << 214 low = std::max(0, high-1); 200 G4ParticleHPInterpolator theInt; 215 G4ParticleHPInterpolator theInt; 201 G4double x, x1, x2; 216 G4double x, x1, x2; 202 x = anEnergy; 217 x = anEnergy; 203 x1 = theCoeff[low].GetEnergy(); 218 x1 = theCoeff[low].GetEnergy(); 204 x2 = theCoeff[high].GetEnergy(); 219 x2 = theCoeff[high].GetEnergy(); 205 G4double theNorm = 0; 220 G4double theNorm = 0; 206 G4double try01 = 0, try02 = 0, try11 = 0, tr << 221 G4double try01=0, try02=0, try11=0, try12=0; 207 G4double try1, try2; 222 G4double try1, try2; 208 G4int l; 223 G4int l; 209 for (l = 0; l < theCoeff[low].GetNumberOfPol << 224 for(l=0; l<theCoeff[low].GetNumberOfPoly(); l++) 210 try01 += (2. * l + 1) / 2. * theCoeff[low] << 225 { 211 try11 += (2. * l + 1) / 2. * theCoeff[low] << 226 try01 += (2.*l+1)/2.*theCoeff[low].GetCoeff(l)*theLeg.Evaluate(l, -1.); 212 } << 227 try11 += (2.*l+1)/2.*theCoeff[low].GetCoeff(l)*theLeg.Evaluate(l, +1.); 213 for (l = 0; l < theCoeff[high].GetNumberOfPo << 228 } 214 try02 += (2. * l + 1) / 2. * theCoeff[high << 229 for(l=0; l<theCoeff[high].GetNumberOfPoly(); l++) 215 try12 += (2. * l + 1) / 2. * theCoeff[high << 230 { 216 } << 231 try02 += (2.*l+1)/2.*theCoeff[high].GetCoeff(l)*theLeg.Evaluate(l, -1.); >> 232 try12 += (2.*l+1)/2.*theCoeff[high].GetCoeff(l)*theLeg.Evaluate(l, +1.); >> 233 } 217 try1 = theInt.Interpolate(theManager.GetSche 234 try1 = theInt.Interpolate(theManager.GetScheme(high), x, x1, x2, try01, try02); 218 try2 = theInt.Interpolate(theManager.GetSche 235 try2 = theInt.Interpolate(theManager.GetScheme(high), x, x1, x2, try11, try12); 219 theNorm = std::max(try1, try2); 236 theNorm = std::max(try1, try2); 220 << 237 221 G4double value, random; 238 G4double value, random; 222 G4double v1, v2; 239 G4double v1, v2; 223 G4int icounter = 0; << 240 G4int icounter=0; 224 G4int icounter_max = 1024; << 241 G4int icounter_max=1024; 225 do { << 242 do >> 243 { 226 icounter++; 244 icounter++; 227 if (icounter > icounter_max) { << 245 if ( icounter > icounter_max ) { 228 G4cout << "Loop-counter exceeded the thr << 246 G4cout << "Loop-counter exceeded the threshold value at " << __LINE__ << "th line of " << __FILE__ << "." << G4endl; 229 << __FILE__ << "." << G4endl; << 247 break; 230 break; << 231 } 248 } 232 v1 = 0; 249 v1 = 0; 233 v2 = 0; 250 v2 = 0; 234 result = 2. * G4UniformRand() - 1.; << 251 result = 2.*G4UniformRand()-1.; 235 for (l = 0; l < theCoeff[low].GetNumberOfP << 252 for(l=0; l<theCoeff[low].GetNumberOfPoly() ; l++) 236 G4double legend = theLeg.Evaluate(l, res << 253 { 237 v1 += (2. * l + 1) / 2. * theCoeff[low]. << 254 G4double legend = theLeg.Evaluate(l, result); // @@@ done to avoid optimization error on SUN 238 } << 255 v1 += (2.*l+1)/2.*theCoeff[low].GetCoeff(l)*legend; 239 for (l = 0; l < theCoeff[high].GetNumberOf << 256 } 240 G4double legend = theLeg.Evaluate(l, res << 257 for(l=0; l<theCoeff[high].GetNumberOfPoly() ; l++) 241 v2 += (2. * l + 1) / 2. * theCoeff[high] << 258 { 242 } << 259 G4double legend = theLeg.Evaluate(l, result); // @@@ done to avoid optimization error on SUN >> 260 v2 += (2.*l+1)/2.*theCoeff[high].GetCoeff(l)*legend; >> 261 } 243 value = theInt.Interpolate(theManager.GetS 262 value = theInt.Interpolate(theManager.GetScheme(high), x, x1, x2, v1, v2); 244 random = G4UniformRand(); 263 random = G4UniformRand(); 245 } while (random > value / theNorm); // Loop << 264 } 246 << 265 while(random>value/theNorm); // Loop checking, 11.05.2015, T. Koi >> 266 247 return result; 267 return result; 248 } 268 } 249 269 250 G4double G4ParticleHPLegendreStore::Sample(G4d << 270 G4double G4ParticleHPLegendreStore::Sample (G4double energy) // still in interpolation; do not use 251 { 271 { 252 G4int i0; 272 G4int i0; 253 G4int low(0), high(0); 273 G4int low(0), high(0); 254 // G4cout << "G4ParticleHPLegendreStore::Sa << 274 // G4cout << "G4ParticleHPLegendreStore::Sample "<<energy<<" "<<energy<<" "<<nEnergy<<G4endl; 255 for (i0 = 0; i0 < nEnergy; i0++) { << 275 for (i0=0; i0<nEnergy; i0++) 256 // G4cout <<"theCoeff["<<i0<<"].GetEne << 276 { >> 277 // G4cout <<"theCoeff["<<i0<<"].GetEnergy() = "<<theCoeff[i0].GetEnergy()<<G4endl; 257 high = i0; 278 high = i0; 258 if (theCoeff[i0].GetEnergy() > energy) bre << 279 if(theCoeff[i0].GetEnergy()>energy) break; 259 } 280 } 260 low = std::max(0, high - 1); << 281 low = std::max(0, high-1); 261 // G4cout << "G4ParticleHPLegendreStore::Sa << 282 // G4cout << "G4ParticleHPLegendreStore::Sample high, low: "<<high<<", "<<low<<G4endl; 262 G4ParticleHPVector theBuffer; 283 G4ParticleHPVector theBuffer; 263 G4ParticleHPInterpolator theInt; 284 G4ParticleHPInterpolator theInt; 264 G4double x1, x2, y1, y2, y; 285 G4double x1, x2, y1, y2, y; 265 x1 = theCoeff[low].GetEnergy(); 286 x1 = theCoeff[low].GetEnergy(); 266 x2 = theCoeff[high].GetEnergy(); 287 x2 = theCoeff[high].GetEnergy(); 267 // G4cout << "the xes "<<x1<<" "<<x2<<G4end << 288 // G4cout << "the xes "<<x1<<" "<<x2<<G4endl; 268 G4double costh = 0; << 289 G4double costh=0; 269 for (i0 = 0; i0 < 601; i0++) { << 290 for(i0=0; i0<601; i0++) 270 costh = G4double(i0 - 300) / 300.; << 291 { >> 292 costh = G4double(i0-300)/300.; 271 y1 = Integrate(low, costh); 293 y1 = Integrate(low, costh); 272 y2 = Integrate(high, costh); 294 y2 = Integrate(high, costh); 273 y = theInt.Interpolate(theManager.GetSchem 295 y = theInt.Interpolate(theManager.GetScheme(high), energy, x1, x2, y1, y2); 274 theBuffer.SetData(i0, costh, y); 296 theBuffer.SetData(i0, costh, y); 275 // G4cout << "Integration "<<low<<" "< << 297 // G4cout << "Integration "<<low<<" "<<costh<<" "<<y1<<" "<<y2<<" "<<y<<G4endl; 276 } 298 } 277 G4double rand = G4UniformRand(); 299 G4double rand = G4UniformRand(); 278 G4int it; 300 G4int it; 279 for (i0 = 1; i0 < 601; i0++) { << 301 for (i0=1; i0<601; i0++) >> 302 { 280 it = i0; 303 it = i0; 281 if (rand < theBuffer.GetY(i0) / theBuffer. << 304 if(rand < theBuffer.GetY(i0)/theBuffer.GetY(600)) break; 282 // G4cout <<"sampling now "<<i0<<" " << 305 // G4cout <<"sampling now "<<i0<<" " 283 // << theBuffer.GetY(i0)<<" " << 306 // << theBuffer.GetY(i0)<<" " 284 // << theBuffer.GetY(600)<<" " << 307 // << theBuffer.GetY(600)<<" " 285 // << rand<<" " << 308 // << rand<<" " 286 // << theBuffer.GetY(i0)/theBuffer << 309 // << theBuffer.GetY(i0)/theBuffer.GetY(600)<<G4endl;; 287 } 310 } 288 if (it == 601) it = 600; << 311 if(it==601) it=600; 289 // G4cout << "G4ParticleHPLegendreStore::Sa << 312 // G4cout << "G4ParticleHPLegendreStore::Sample it "<<rand<<" "<<it<<G4endl; 290 G4double norm = theBuffer.GetY(600); 313 G4double norm = theBuffer.GetY(600); 291 if (norm == 0) return -DBL_MAX; << 314 if(norm==0) return -DBL_MAX; 292 x1 = theBuffer.GetY(it) / norm; << 315 x1 = theBuffer.GetY(it)/norm; 293 x2 = theBuffer.GetY(it - 1) / norm; << 316 x2 = theBuffer.GetY(it-1)/norm; 294 y1 = theBuffer.GetX(it); 317 y1 = theBuffer.GetX(it); 295 y2 = theBuffer.GetX(it - 1); << 318 y2 = theBuffer.GetX(it-1); 296 // G4cout << "G4ParticleHPLegendreStore::Sa << 319 // G4cout << "G4ParticleHPLegendreStore::Sample x y "<<x1<<" "<<y1<<" "<<x2<<" "<<y2<<G4endl; 297 return theInt.Interpolate(theManager.GetSche 320 return theInt.Interpolate(theManager.GetScheme(high), rand, x1, x2, y1, y2); 298 } 321 } 299 322 300 G4double << 323 G4double G4ParticleHPLegendreStore::Integrate(G4int k, G4double costh) // still in interpolation; not used anymore 301 G4ParticleHPLegendreStore::Integrate(G4int k, << 302 G4double << 303 { 324 { 304 G4double result = 0.; << 325 G4double result=0.; 305 G4ParticleHPFastLegendre theLeg; 326 G4ParticleHPFastLegendre theLeg; 306 // G4cout <<"the COEFFS "<<k<<" "; << 327 // G4cout <<"the COEFFS "<<k<<" "; 307 // G4cout <<theCoeff[k].GetNumberOfPoly()<< << 328 // G4cout <<theCoeff[k].GetNumberOfPoly()<<" "; 308 for (G4int l = 0; l < theCoeff[k].GetNumberO << 329 for(G4int l=0; l<theCoeff[k].GetNumberOfPoly() ; l++) 309 result += theCoeff[k].GetCoeff(l) * theLeg << 330 { 310 // G4cout << theCoeff[k].GetCoeff(l)<<" << 331 result += theCoeff[k].GetCoeff(l)*theLeg.Integrate(l, costh); 311 } << 332 // G4cout << theCoeff[k].GetCoeff(l)<<" "; 312 // G4cout <<G4endl; << 333 } >> 334 // G4cout <<G4endl; 313 return result; 335 return result; 314 } 336 } 315 337