Geant4 Cross Reference |
1 // 1 // 2 // ******************************************* 2 // ******************************************************************** 3 // * License and Disclaimer 3 // * License and Disclaimer * 4 // * 4 // * * 5 // * The Geant4 software is copyright of th 5 // * The Geant4 software is copyright of the Copyright Holders of * 6 // * the Geant4 Collaboration. It is provided 6 // * the Geant4 Collaboration. It is provided under the terms and * 7 // * conditions of the Geant4 Software License 7 // * conditions of the Geant4 Software License, included in the file * 8 // * LICENSE and available at http://cern.ch/ 8 // * LICENSE and available at http://cern.ch/geant4/license . These * 9 // * include a list of copyright holders. 9 // * include a list of copyright holders. * 10 // * 10 // * * 11 // * Neither the authors of this software syst 11 // * Neither the authors of this software system, nor their employing * 12 // * institutes,nor the agencies providing fin 12 // * institutes,nor the agencies providing financial support for this * 13 // * work make any representation or warran 13 // * work make any representation or warranty, express or implied, * 14 // * regarding this software system or assum 14 // * regarding this software system or assume any liability for its * 15 // * use. Please see the license in the file 15 // * use. 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 // G4PDGCodeChecker << 27 // 26 // 28 // Author: Hisaya Kurashige, 17 August 1999 << 27 // $Id: G4PDGCodeChecker.cc,v 1.10 2007/11/14 02:22:08 kurasige Exp $ 29 // ------------------------------------------- << 28 // GEANT4 tag $Name: geant4-09-01-patch-02 $ 30 << 29 // 31 #include "G4PDGCodeChecker.hh" << 30 // 32 << 31 // ---------------------------------------------------------------------- 33 #include "G4PhysicalConstants.hh" << 32 // GEANT 4 class implementation file 34 #include "G4SystemOfUnits.hh" << 33 // >> 34 // History: first implementation, based on object model of >> 35 // 17 Aug 1999 H.Kurashige >> 36 // ********************************************************************** 35 37 36 #include <fstream> 38 #include <fstream> 37 #include <iomanip> 39 #include <iomanip> 38 40 39 G4PDGCodeChecker::G4PDGCodeChecker() : verbose << 41 #include "G4PDGCodeChecker.hh" >> 42 >> 43 ///////////// >> 44 G4PDGCodeChecker::G4PDGCodeChecker() 40 { 45 { 41 // clear QuarkContents << 46 code = 0; 42 for (G4int flavor = 0; flavor < NumberOfQuar << 47 verboseLevel = 3; 43 theQuarkContent[flavor] = 0; << 44 theAntiQuarkContent[flavor] = 0; << 45 } << 46 } 48 } 47 49 48 G4int G4PDGCodeChecker::CheckPDGCode(G4int PDG << 50 ///////////// >> 51 G4int G4PDGCodeChecker::CheckPDGCode( G4int PDGcode, >> 52 G4String particleType) 49 { 53 { 50 code = PDGcode; 54 code = PDGcode; 51 theParticleType = particleType; 55 theParticleType = particleType; 52 56 53 // clear QuarkContents 57 // clear QuarkContents 54 for (G4int flavor = 0; flavor < NumberOfQuar << 58 G4int flavor; 55 theQuarkContent[flavor] = 0; << 59 for (flavor=0; flavor<NumberOfQuarkFlavor; flavor++){ 56 theAntiQuarkContent[flavor] = 0; << 60 theQuarkContent[flavor] =0; >> 61 theAntiQuarkContent[flavor] =0; 57 } 62 } 58 63 59 // check code for nuclei 64 // check code for nuclei 60 if ((theParticleType == "nucleus") || (thePa << 65 if (theParticleType == "nucleus"){ 61 return CheckForNuclei(); 66 return CheckForNuclei(); 62 } 67 } 63 68 64 // get each digit number 69 // get each digit number 65 GetDigits(code); 70 GetDigits(code); 66 71 67 // check code 72 // check code 68 if (theParticleType == "quarks") { << 73 if (theParticleType =="quarks") { 69 return CheckForQuarks(); 74 return CheckForQuarks(); 70 } << 75 71 if (theParticleType == "diquarks") { << 76 } else if (theParticleType =="diquarks") { 72 return CheckForDiQuarks(); 77 return CheckForDiQuarks(); 73 } << 78 74 if (theParticleType == "gluons") { << 79 } else if (theParticleType =="gluons") { 75 return code; // gluons, do not care about << 80 // gluons 76 } << 81 // do not care about 77 if (theParticleType == "meson") { << 82 return code; >> 83 >> 84 } else if (theParticleType == "meson") { 78 return CheckForMesons(); 85 return CheckForMesons(); 79 } << 86 80 if (theParticleType == "baryon") { << 87 } else if (theParticleType == "baryon"){ 81 return CheckForBaryons(); 88 return CheckForBaryons(); >> 89 >> 90 82 } 91 } 83 // No check 92 // No check 84 return code; 93 return code; 85 } 94 } 86 << 95 >> 96 ///////////// 87 G4int G4PDGCodeChecker::CheckForBaryons() 97 G4int G4PDGCodeChecker::CheckForBaryons() 88 { 98 { 89 G4int tempPDGcode = code; << 99 G4int tempPDGcode = code; 90 100 91 if ((quark1 == 0) || (quark2 == 0) || (quark << 101 if ((quark1==0)||(quark2==0)||(quark3==0)){ 92 #ifdef G4VERBOSE 102 #ifdef G4VERBOSE 93 if (verboseLevel > 0) { << 103 if (verboseLevel>1) { 94 G4cout << " G4PDGCodeChecker::CheckPDGCo 104 G4cout << " G4PDGCodeChecker::CheckPDGCode : "; 95 G4cout << " meson has three quark "; 105 G4cout << " meson has three quark "; 96 G4cout << " PDG code=" << code << G4endl << 106 G4cout << " PDG code=" << code <<G4endl; 97 } 107 } 98 #endif 108 #endif 99 return 0; 109 return 0; 100 } 110 } 101 << 111 102 // exceptions << 112 //exceptions 103 if (std::abs(tempPDGcode) % 10000 == 3122) { << 113 if (std::abs(tempPDGcode)%10000 == 3122) { 104 // Lambda 114 // Lambda 105 quark2 = 2; << 115 quark2=2; quark3 = 1; spin = 1; 106 quark3 = 1; << 116 } else if (std::abs(tempPDGcode)%10000 == 3124) { 107 spin = 1; << 108 } << 109 else if (std::abs(tempPDGcode) % 10000 == 31 << 110 // Lambda* 117 // Lambda* 111 quark2 = 2; << 118 quark2=2; quark3 = 1; spin = 3; 112 quark3 = 1; << 119 } else if (std::abs(tempPDGcode)%10000 == 3126) { 113 spin = 3; << 114 } << 115 else if (std::abs(tempPDGcode) % 10000 == 31 << 116 // Lambda* 120 // Lambda* 117 quark2 = 2; << 121 quark2=2; quark3 = 1; spin = 5; 118 quark3 = 1; << 122 } else if (std::abs(tempPDGcode)%10000 == 3128) { 119 spin = 5; << 120 } << 121 else if (std::abs(tempPDGcode) % 10000 == 31 << 122 // Lambda* 123 // Lambda* 123 quark2 = 2; << 124 quark2=2; quark3 = 1; spin = 7; 124 quark3 = 1; << 125 } else if (std::abs(tempPDGcode)%10000 == 4122) { 125 spin = 7; << 126 } << 127 else if (std::abs(tempPDGcode) % 10000 == 41 << 128 // Lambda_c 126 // Lambda_c 129 quark2 = 2; << 127 quark2=2; quark3 = 1; spin = 1; 130 quark3 = 1; << 128 } else if (std::abs(tempPDGcode)%10000 == 4132) { 131 spin = 1; << 132 } << 133 else if (std::abs(tempPDGcode) % 10000 == 51 << 134 // Lambda_b << 135 quark2 = 2; << 136 quark3 = 1; << 137 spin = 1; << 138 } << 139 else if (std::abs(tempPDGcode) % 10000 == 41 << 140 // Xi_c0 129 // Xi_c0 141 quark2 = 3; << 130 quark2=3; quark3 = 1; spin = 1; 142 quark3 = 1; << 131 } else if (std::abs(tempPDGcode)%10000 == 4232) { 143 spin = 1; << 144 } << 145 else if (std::abs(tempPDGcode) % 10000 == 42 << 146 // Xi_c+ 132 // Xi_c+ 147 quark2 = 3; << 133 quark2=3; quark3 = 2; spin = 1; 148 quark3 = 2; << 134 } else if (std::abs(tempPDGcode)%10000 == 2122) { 149 spin = 1; << 135 // Delta+ (spin 1/2) 150 } << 136 quark2=2; quark3 = 1; spin = 1; 151 else if (std::abs(tempPDGcode) % 10000 == 51 << 137 } else if (std::abs(tempPDGcode)%10000 == 1212) { 152 // Xi_b0 << 138 // Delta0 (spin 1/2) 153 quark2 = 3; << 139 quark1=2; quark2 = 1; spin = 1; 154 quark3 = 1; << 140 } else if (std::abs(tempPDGcode)%10000 == 2126) { 155 spin = 1; << 141 // Delta+ (spin 5/2) 156 } << 142 quark2=2; quark3 = 1; spin = 5; 157 else if (std::abs(tempPDGcode) % 10000 == 52 << 143 } else if (std::abs(tempPDGcode)%10000 == 1216) { 158 // Xi_b+ << 144 // Delta0 (spin 5/2) 159 quark2 = 3; << 145 quark1=2; quark2 = 1; spin = 5; 160 quark3 = 2; << 146 } else if (std::abs(tempPDGcode)%10000 == 2128) { 161 spin = 1; << 147 // Delta+ (spin 7/2) 162 } << 148 quark2=2; quark3 = 1; spin = 7; 163 else if (std::abs(tempPDGcode) % 10000 == 21 << 149 } else if (std::abs(tempPDGcode)%10000 == 1218) { 164 // Delta+ (spin 1/2) << 150 // Delta0 (spin 7/2) 165 quark2 = 2; << 151 quark1=2; quark2 = 1; spin = 7; 166 quark3 = 1; << 152 } else if (std::abs(tempPDGcode)%10000 == 2124) { 167 spin = 1; << 153 // N*+ (spin 3/2) 168 } << 154 quark2=2; quark3 = 1; spin = 3; 169 else if (std::abs(tempPDGcode) % 10000 == 12 << 155 } else if (std::abs(tempPDGcode)%10000 == 1214) { 170 // Delta0 (spin 1/2) << 156 // N*0 (spin 3/2) 171 quark1 = 2; << 157 quark1=2; quark2 = 1; spin = 3; 172 quark2 = 1; << 158 } 173 spin = 1; << 174 } << 175 else if (std::abs(tempPDGcode) % 10000 == 21 << 176 // Delta+ (spin 5/2) << 177 quark2 = 2; << 178 quark3 = 1; << 179 spin = 5; << 180 } << 181 else if (std::abs(tempPDGcode) % 10000 == 12 << 182 // Delta0 (spin 5/2) << 183 quark1 = 2; << 184 quark2 = 1; << 185 spin = 5; << 186 } << 187 else if (std::abs(tempPDGcode) % 10000 == 21 << 188 // Delta+ (spin 7/2) << 189 quark2 = 2; << 190 quark3 = 1; << 191 spin = 7; << 192 } << 193 else if (std::abs(tempPDGcode) % 10000 == 12 << 194 // Delta0 (spin 7/2) << 195 quark1 = 2; << 196 quark2 = 1; << 197 spin = 7; << 198 } << 199 else if (std::abs(tempPDGcode) % 10000 == 21 << 200 // N*+ (spin 3/2) << 201 quark2 = 2; << 202 quark3 = 1; << 203 spin = 3; << 204 } << 205 else if (std::abs(tempPDGcode) % 10000 == 12 << 206 // N*0 (spin 3/2) << 207 quark1 = 2; << 208 quark2 = 1; << 209 spin = 3; << 210 } << 211 159 212 // check quark flavor << 160 // check quark flavor 213 if ((quark1 < quark2) || (quark2 < quark3) | << 161 if ((quark1<quark2)||(quark2<quark3)||(quark1<quark3)) { 214 #ifdef G4VERBOSE 162 #ifdef G4VERBOSE 215 if (verboseLevel > 0) { << 163 if (verboseLevel>1) { 216 G4cout << " G4PDGCodeChecker::CheckPDGCo 164 G4cout << " G4PDGCodeChecker::CheckPDGCode : "; 217 G4cout << " illegal code for baryon "; 165 G4cout << " illegal code for baryon "; 218 G4cout << " PDG code=" << code << G4endl << 166 G4cout << " PDG code=" << code <<G4endl; 219 } 167 } 220 #endif 168 #endif 221 return 0; 169 return 0; 222 } 170 } 223 if (quark1 > NumberOfQuarkFlavor) { << 171 if (quark1> NumberOfQuarkFlavor) { 224 #ifdef G4VERBOSE 172 #ifdef G4VERBOSE 225 if (verboseLevel > 0) { << 173 if (verboseLevel>1) { 226 G4cout << " G4PDGCodeChecker::CheckPDGCo 174 G4cout << " G4PDGCodeChecker::CheckPDGCode : "; 227 G4cout << " ??? unknown quark "; 175 G4cout << " ??? unknown quark "; 228 G4cout << " PDG code=" << code << G4endl << 176 G4cout << " PDG code=" << code <<G4endl; 229 } 177 } 230 #endif 178 #endif 231 return 0; 179 return 0; 232 } 180 } >> 181 233 182 234 // Fill Quark contents 183 // Fill Quark contents 235 if (tempPDGcode > 0) { << 184 if (tempPDGcode >0) { 236 theQuarkContent[quark1 - 1]++; << 185 theQuarkContent[quark1-1] ++; 237 theQuarkContent[quark2 - 1]++; << 186 theQuarkContent[quark2-1] ++; 238 theQuarkContent[quark3 - 1]++; << 187 theQuarkContent[quark3-1] ++; 239 } << 188 } else { 240 else { << 189 theAntiQuarkContent[quark1-1] ++; 241 theAntiQuarkContent[quark1 - 1]++; << 190 theAntiQuarkContent[quark2-1] ++; 242 theAntiQuarkContent[quark2 - 1]++; << 191 theAntiQuarkContent[quark3-1] ++; 243 theAntiQuarkContent[quark3 - 1]++; << 244 } 192 } 245 193 246 return code; 194 return code; 247 } 195 } 248 << 196 >> 197 ///////////// 249 G4int G4PDGCodeChecker::CheckForMesons() 198 G4int G4PDGCodeChecker::CheckForMesons() 250 { 199 { 251 G4int tempPDGcode = code; << 200 G4int tempPDGcode = code; 252 201 253 // -- exceptions -- << 202 // -- exceptions -- 254 if (tempPDGcode == 310) spin = 0; // K0s << 203 if (tempPDGcode == 310) spin = 0; //K0s 255 if (tempPDGcode == 130) // K0l << 204 if (tempPDGcode == 130) { //K0l 256 { << 205 spin = 0; 257 spin = 0; << 258 quark2 = 3; 206 quark2 = 3; 259 quark3 = 1; 207 quark3 = 1; 260 } 208 } 261 << 209 262 if ((quark1 != 0) || (quark2 == 0) || (quark << 210 // >> 211 if ((quark1 !=0)||(quark2==0)||(quark3==0)){ 263 #ifdef G4VERBOSE 212 #ifdef G4VERBOSE 264 if (verboseLevel > 0) { << 213 if (verboseLevel>1) { 265 G4cout << " G4PDGCodeChecker::CheckPDGCo 214 G4cout << " G4PDGCodeChecker::CheckPDGCode : "; 266 G4cout << " meson has only quark and ant 215 G4cout << " meson has only quark and anti-quark pair"; 267 G4cout << " PDG code=" << code << G4endl << 216 G4cout << " PDG code=" << code <<G4endl; 268 } 217 } 269 #endif 218 #endif 270 return 0; 219 return 0; 271 } << 220 } 272 if (quark2 < quark3) { << 221 if (quark2<quark3) { 273 #ifdef G4VERBOSE 222 #ifdef G4VERBOSE 274 if (verboseLevel > 0) { << 223 if (verboseLevel>1) { 275 G4cout << " G4PDGCodeChecker::CheckPDGCo 224 G4cout << " G4PDGCodeChecker::CheckPDGCode : "; 276 G4cout << " illegal code for meson "; 225 G4cout << " illegal code for meson "; 277 G4cout << " PDG code=" << code << G4endl << 226 G4cout << " PDG code=" << code <<G4endl; 278 } 227 } 279 #endif 228 #endif 280 return 0; 229 return 0; 281 } 230 } 282 231 283 // check quark flavor 232 // check quark flavor 284 if (quark2 > NumberOfQuarkFlavor) { << 233 if (quark2> NumberOfQuarkFlavor){ 285 #ifdef G4VERBOSE 234 #ifdef G4VERBOSE 286 if (verboseLevel > 0) { << 235 if (verboseLevel>1) { 287 G4cout << " G4PDGCodeChecker::CheckPDGCo 236 G4cout << " G4PDGCodeChecker::CheckPDGCode : "; 288 G4cout << " ??? unknown quark "; 237 G4cout << " ??? unknown quark "; 289 G4cout << " PDG code=" << code << G4endl << 238 G4cout << " PDG code=" << code <<G4endl; 290 } 239 } 291 #endif 240 #endif 292 return 0; 241 return 0; 293 } 242 } 294 243 >> 244 295 // check heavier quark type 245 // check heavier quark type 296 if ((quark2 & 1) != 0) { << 246 if (quark2 & 1) { 297 // down type qurak 247 // down type qurak 298 if (tempPDGcode > 0) { << 248 if (tempPDGcode >0) { 299 theQuarkContent[quark3 - 1] = 1; << 249 theQuarkContent[quark3-1] =1; 300 theAntiQuarkContent[quark2 - 1] = 1; << 250 theAntiQuarkContent[quark2-1] =1; >> 251 } else { >> 252 theQuarkContent[quark2-1] =1; >> 253 theAntiQuarkContent[quark3-1] =1; 301 } 254 } 302 else { << 255 } else { 303 theQuarkContent[quark2 - 1] = 1; << 304 theAntiQuarkContent[quark3 - 1] = 1; << 305 } << 306 } << 307 else { << 308 // up type quark 256 // up type quark 309 if (tempPDGcode > 0) { << 257 if (tempPDGcode >0) { 310 theQuarkContent[quark2 - 1] = 1; << 258 theQuarkContent[quark2-1] =1; 311 theAntiQuarkContent[quark3 - 1] = 1; << 259 theAntiQuarkContent[quark3-1] =1; 312 } << 260 } else { 313 else { << 261 theQuarkContent[quark3-1] =1; 314 theQuarkContent[quark3 - 1] = 1; << 262 theAntiQuarkContent[quark2-1] =1; 315 theAntiQuarkContent[quark2 - 1] = 1; << 316 } 263 } 317 } 264 } 318 return code; 265 return code; 319 } 266 } 320 267 >> 268 >> 269 >> 270 ///////////// 321 G4int G4PDGCodeChecker::CheckForDiQuarks() 271 G4int G4PDGCodeChecker::CheckForDiQuarks() 322 { 272 { 323 if ((quark1 == 0) || (quark2 == 0) || (quark << 273 if ((quark1 ==0) || (quark2 ==0) || (quark3 !=0)) { 324 // quark3 should be 0 274 // quark3 should be 0 325 // --- code is wrong << 275 // --- code is wrong 326 return 0; 276 return 0; 327 } << 277 328 if (quark1 < quark2) { << 278 } else if (quark1 < quark2) { 329 // --- code is wrong << 279 // --- code is wrong 330 return 0; 280 return 0; 331 } << 281 332 if (quark2 > NumberOfQuarkFlavor) { << 282 } else if (quark2>NumberOfQuarkFlavor){ 333 #ifdef G4VERBOSE 283 #ifdef G4VERBOSE 334 if (verboseLevel > 0) { << 284 if (verboseLevel>1) { 335 G4cout << " G4PDGCodeChecker::CheckPDGCo 285 G4cout << " G4PDGCodeChecker::CheckPDGCode : "; 336 G4cout << " ??? unknown quark "; 286 G4cout << " ??? unknown quark "; 337 G4cout << " PDG code=" << code << G4endl << 287 G4cout << " PDG code=" << code <<G4endl; 338 } 288 } 339 #endif 289 #endif 340 return 0; 290 return 0; >> 291 341 } 292 } 342 293 343 // Fill Quark Contents 294 // Fill Quark Contents 344 if (code > 0) { << 295 if (code>0){ 345 theQuarkContent[quark1 - 1] += 1; << 296 theQuarkContent[quark1-1] +=1; 346 theQuarkContent[quark2 - 1] += 1; << 297 theQuarkContent[quark2-1] +=1; 347 } << 298 } else { 348 else { << 299 theAntiQuarkContent[quark1-1] +=1; 349 theAntiQuarkContent[quark1 - 1] += 1; << 300 theAntiQuarkContent[quark2-1] +=1; 350 theAntiQuarkContent[quark2 - 1] += 1; << 351 } 301 } 352 302 353 return code; 303 return code; 354 } 304 } 355 << 305 >> 306 ///////////// 356 G4int G4PDGCodeChecker::CheckForQuarks() 307 G4int G4PDGCodeChecker::CheckForQuarks() 357 { 308 { 358 quark1 = std::abs(code); << 309 if ( std::abs(quark1)>NumberOfQuarkFlavor ) { 359 << 360 if (std::abs(quark1) > NumberOfQuarkFlavor) << 361 #ifdef G4VERBOSE 310 #ifdef G4VERBOSE 362 if (verboseLevel > 0) { << 311 if (verboseLevel>1) { 363 G4cout << " G4PDGCodeChecker::CheckPDGCo 312 G4cout << " G4PDGCodeChecker::CheckPDGCode : "; 364 G4cout << " ??? unknown quark "; 313 G4cout << " ??? unknown quark "; 365 G4cout << " PDG code=" << code << G4endl << 314 G4cout << " PDG code=" << code <<G4endl; 366 } 315 } 367 #endif 316 #endif 368 // --- code is wrong << 317 // --- code is wrong 369 return 0; 318 return 0; 370 } << 319 >> 320 } >> 321 >> 322 quark1 = std::abs(code); 371 323 372 // Fill Quark Contents 324 // Fill Quark Contents 373 if (code > 0) { << 325 if (code>0){ 374 theQuarkContent[quark1 - 1] = 1; << 326 theQuarkContent[quark1-1] =1; 375 } << 327 } else { 376 else { << 328 theAntiQuarkContent[quark1-1] =1; 377 theAntiQuarkContent[quark1 - 1] = 1; << 378 } 329 } 379 return code; 330 return code; 380 } 331 } 381 332 >> 333 ///////////// 382 G4bool G4PDGCodeChecker::CheckCharge(G4double 334 G4bool G4PDGCodeChecker::CheckCharge(G4double thePDGCharge) const 383 { 335 { 384 // check charge 336 // check charge 385 G4double totalCharge = 0.0; 337 G4double totalCharge = 0.0; 386 for (G4int flavor = 0; flavor < NumberOfQuar << 338 for (G4int flavor= 0; flavor<NumberOfQuarkFlavor-1; flavor+=2){ 387 totalCharge += (-1. / 3.) * eplus * theQua << 339 totalCharge += (-1./3.)*eplus*theQuarkContent[flavor]; 388 totalCharge += 1. / 3. * eplus * theAntiQu << 340 totalCharge += 1./3.*eplus*theAntiQuarkContent[flavor]; 389 totalCharge += 2. / 3. * eplus * theQuarkC << 341 totalCharge += 2./3.*eplus*theQuarkContent[flavor+1]; 390 totalCharge += (-2. / 3.) * eplus * theAnt << 342 totalCharge += (-2./3.)*eplus*theAntiQuarkContent[flavor+1]; 391 } 343 } 392 344 393 if (std::fabs(totalCharge - thePDGCharge) > << 345 if (std::abs(totalCharge-thePDGCharge)>0.1*eplus) { 394 #ifdef G4VERBOSE 346 #ifdef G4VERBOSE 395 if (verboseLevel > 0) { << 347 if (verboseLevel>1) { 396 G4cout << " G4PDGCodeChecker::CheckCharg 348 G4cout << " G4PDGCodeChecker::CheckCharge : "; 397 G4cout << " illegal electric charge " << << 349 G4cout << " illegal electric charge " << thePDGCharge/eplus; 398 G4cout << " PDG code=" << code << G4endl << 350 G4cout << " PDG code=" << code <<G4endl; 399 } 351 } 400 #endif 352 #endif 401 return false; 353 return false; 402 } 354 } 403 return true; 355 return true; 404 } 356 } 405 357 >> 358 ///////////// 406 G4int G4PDGCodeChecker::CheckForNuclei() 359 G4int G4PDGCodeChecker::CheckForNuclei() 407 { 360 { 408 G4int pcode = std::abs(code); << 361 G4int pcode = code; 409 if (pcode < 1000000000) { 362 if (pcode < 1000000000) { 410 // non-nuclei << 363 // anti particle 411 return 0; 364 return 0; 412 } 365 } 413 366 414 pcode -= 1000000000; 367 pcode -= 1000000000; 415 G4int LL = pcode / 10000000; << 368 G4int L = pcode/10000000; 416 pcode -= 10000000 * LL; << 369 pcode -= 10000000*L; 417 G4int Z = pcode / 10000; << 370 G4int Z = pcode/10000; 418 pcode -= 10000 * Z; << 371 pcode -= 10000*Z; 419 G4int A = pcode / 10; << 372 G4int A = pcode/10; 420 << 373 421 // Allow neutron balls << 374 if (A < 2 || Z > A-L || L>A || Z<=0 ) { 422 // if (A < 2 || Z > A-LL || LL>A || Z<=0 ) { << 423 if (A < 2 || Z > A - LL || LL > A) { << 424 #ifdef G4VERBOSE 375 #ifdef G4VERBOSE 425 if (verboseLevel > 0) { << 376 if (verboseLevel>1) { 426 G4cout << " G4PDGCodeChecker::CheckPDGCo 377 G4cout << " G4PDGCodeChecker::CheckPDGCode : "; 427 G4cout << " ??? Illegal PDG encoding fo 378 G4cout << " ??? Illegal PDG encoding for nucleus "; 428 G4cout << " PDG code=" << code << G4endl << 379 G4cout << " PDG code=" << code <<G4endl; 429 } 380 } 430 #endif 381 #endif 431 return 0; 382 return 0; 432 } 383 } 433 384 434 G4int n_up = 2 * Z + (A - Z - LL) + LL; << 385 G4int n_up = 2*Z + (A-Z-L) + L; 435 G4int n_down = Z + 2 * (A - Z - LL) + LL; << 386 G4int n_down = Z + 2*(A-Z-L) + L; 436 G4int n_s = LL; << 387 G4int n_s = L; 437 388 438 // Fill Quark contents 389 // Fill Quark contents 439 if (code > 0) { << 390 theQuarkContent[0] = n_up; 440 theQuarkContent[0] = n_up; << 391 theQuarkContent[1] = n_down; 441 theQuarkContent[1] = n_down; << 392 theQuarkContent[2] = n_s; 442 theQuarkContent[2] = n_s; << 393 443 } << 444 else { << 445 // anti_nucleus << 446 theAntiQuarkContent[0] = n_up; << 447 theAntiQuarkContent[1] = n_down; << 448 theAntiQuarkContent[2] = n_s; << 449 } << 450 return code; 394 return code; 451 } 395 } 452 << 396 >> 397 ///////////// 453 void G4PDGCodeChecker::GetDigits(G4int PDGcode 398 void G4PDGCodeChecker::GetDigits(G4int PDGcode) 454 { 399 { 455 G4int temp = std::abs(PDGcode); 400 G4int temp = std::abs(PDGcode); >> 401 >> 402 higherSpin = temp/10000000; >> 403 temp -= G4int(higherSpin*10000000); 456 404 457 higherSpin = temp / 10000000; << 405 exotic = temp/1000000; 458 temp -= G4int(higherSpin * 10000000); << 406 temp -= G4int(exotic*1000000); 459 407 460 exotic = temp / 1000000; << 408 radial = temp/100000; 461 temp -= G4int(exotic * 1000000); << 409 temp -= G4int(radial*100000); 462 410 463 radial = temp / 100000; << 411 multiplet = temp/10000; 464 temp -= G4int(radial * 100000); << 412 temp -= G4int(multiplet*10000); 465 413 466 multiplet = temp / 10000; << 414 quark1 = temp/1000; 467 temp -= G4int(multiplet * 10000); << 415 temp -= G4int(quark1*1000); 468 416 469 quark1 = temp / 1000; << 417 quark2 = temp/100; 470 temp -= G4int(quark1 * 1000); << 418 temp -= G4int(quark2*100); 471 419 472 quark2 = temp / 100; << 420 quark3 = temp/10; 473 temp -= G4int(quark2 * 100); << 421 temp -= G4int(quark3*10); 474 422 475 quark3 = temp / 10; << 423 spin= temp; 476 temp -= G4int(quark3 * 10); << 424 if ((spin ==0) && ( higherSpin !=0 )) { 477 << 425 spin = higherSpin-1; 478 spin = temp; << 426 } else { 479 if ((spin == 0) && (higherSpin != 0)) { << 480 spin = higherSpin - 1; << 481 } << 482 else { << 483 spin -= 1; 427 spin -= 1; 484 } 428 } 485 } 429 } 486 430