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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 // $Id: G4NeutronCaptureXS.cc 71324 2013-06-13 16:58:55Z gcosmo $ >> 27 // 26 // ------------------------------------------- 28 // ------------------------------------------------------------------- 27 // 29 // 28 // GEANT4 Class file 30 // GEANT4 Class file 29 // 31 // 30 // 32 // 31 // File name: G4NeutronCaptureXS 33 // File name: G4NeutronCaptureXS 32 // 34 // 33 // Author Ivantchenko, Geant4, 3-Aug-09 35 // Author Ivantchenko, Geant4, 3-Aug-09 34 // 36 // 35 // Modifications: 37 // Modifications: 36 // 38 // 37 39 38 #include <fstream> 40 #include <fstream> 39 #include <sstream> 41 #include <sstream> 40 #include <thread> << 41 42 42 #include "G4SystemOfUnits.hh" 43 #include "G4SystemOfUnits.hh" 43 #include "G4NeutronCaptureXS.hh" 44 #include "G4NeutronCaptureXS.hh" 44 #include "G4Material.hh" << 45 #include "G4Element.hh" 45 #include "G4Element.hh" >> 46 #include "G4ElementTable.hh" 46 #include "G4PhysicsLogVector.hh" 47 #include "G4PhysicsLogVector.hh" >> 48 #include "G4PhysicsVector.hh" 47 #include "G4DynamicParticle.hh" 49 #include "G4DynamicParticle.hh" 48 #include "G4ElementTable.hh" << 49 #include "G4IsotopeList.hh" << 50 #include "G4HadronicParameters.hh" << 51 #include "Randomize.hh" 50 #include "Randomize.hh" 52 #include "G4Log.hh" << 53 #include "G4AutoLock.hh" << 54 51 55 G4ElementData* G4NeutronCaptureXS::data = null << 52 using namespace std; 56 G4String G4NeutronCaptureXS::gDataDirectory = << 57 53 58 static std::once_flag applyOnce; << 54 const G4int G4NeutronCaptureXS::amin[] = {0, 59 << 55 0, 0, 6, 0,10,12,14,16, 0, 0, //1-10 60 namespace << 56 0, 0, 0,28, 0, 0, 0,36, 0,40, //11-20 61 { << 57 0, 0, 0, 0, 0,54, 0,58,63,64, //21-30 62 G4Mutex neutronCaptureXSMutex = G4MUTEX_INIT << 58 0,70, 0, 0, 0, 0, 0, 0, 0,90, //31-40 63 const G4int MAXZCAPTURE = 92; << 59 0, 0, 0, 0, 0, 0,107,106, 0,112, //41-50 64 } << 60 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, //51-60 >> 61 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, //61-70 >> 62 0, 0, 0,180, 0, 0, 0, 0, 0, 0, //71-80 >> 63 0,204, 0, 0, 0, 0, 0, 0, 0, 0, //81-90 >> 64 0,235}; >> 65 const G4int G4NeutronCaptureXS::amax[] = {0, >> 66 0, 0, 7, 0,11,13,15,18, 0, 0, //1-10 >> 67 0, 0, 0,30, 0, 0, 0,40, 0,48, //11-20 >> 68 0, 0, 0, 0, 0,58, 0,64,65,70, //21-30 >> 69 0,76, 0, 0, 0, 0, 0, 0, 0,96, //31-40 >> 70 0, 0, 0, 0, 0, 0,109,116, 0,124, //41-50 >> 71 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, //51-60 >> 72 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, //61-70 >> 73 0, 0, 0,186, 0, 0, 0, 0, 0, 0, //71-80 >> 74 0,208, 0, 0, 0, 0, 0, 0, 0, 0, //81-90 >> 75 0,238}; 65 76 66 G4NeutronCaptureXS::G4NeutronCaptureXS() 77 G4NeutronCaptureXS::G4NeutronCaptureXS() 67 : G4VCrossSectionDataSet(Default_Name()), << 78 : G4VCrossSectionDataSet("G4NeutronCaptureXS"), 68 emax(20*CLHEP::MeV), elimit(1.0e-5*CLHEP::e << 79 emax(20*MeV),elimit(1.0e-10*eV) 69 { 80 { 70 verboseLevel = 0; << 81 // verboseLevel = 0; 71 if (verboseLevel > 0) { << 82 if(verboseLevel > 0){ 72 G4cout << "G4NeutronCaptureXS::G4NeutronC 83 G4cout << "G4NeutronCaptureXS::G4NeutronCaptureXS: Initialise for Z < " 73 << MAXZCAPTURE << G4endl; 84 << MAXZCAPTURE << G4endl; 74 } 85 } 75 logElimit = G4Log(elimit); << 86 data.SetName("NeutronCapture"); 76 if (nullptr == data) { << 87 work.resize(13,0); 77 data = new G4ElementData(MAXZCAPTURE+1); << 88 temp.resize(13,0.0); 78 data->SetName("nCapture"); << 89 isInitialized = false; 79 FindDirectoryPath(); << 80 } << 81 } 90 } 82 91 >> 92 G4NeutronCaptureXS::~G4NeutronCaptureXS() >> 93 {} >> 94 83 void G4NeutronCaptureXS::CrossSectionDescripti 95 void G4NeutronCaptureXS::CrossSectionDescription(std::ostream& outFile) const 84 { 96 { 85 outFile << "G4NeutronCaptureXS calculates th 97 outFile << "G4NeutronCaptureXS calculates the neutron capture cross sections\n" 86 << "on nuclei using data from the hi 98 << "on nuclei using data from the high precision neutron database.\n" 87 << "These data are simplified and sm 99 << "These data are simplified and smoothed over the resonance region\n" 88 << "in order to reduce CPU time. G4N << 100 << "in order to reduce CPU time. G4NeutronCaptureXS is valid up to\n" 89 << "above 20 MeV for all targets. Fo << 101 << "20 MeV for all targets through U.\n"; 90 << "Uranium is used.\n"; << 91 } 102 } 92 103 93 G4bool 104 G4bool 94 G4NeutronCaptureXS::IsElementApplicable(const 105 G4NeutronCaptureXS::IsElementApplicable(const G4DynamicParticle*, 95 G4int, const G4Material*) 106 G4int, const G4Material*) 96 { 107 { 97 return true; 108 return true; 98 } 109 } 99 110 100 G4bool 111 G4bool 101 G4NeutronCaptureXS::IsIsoApplicable(const G4Dy 112 G4NeutronCaptureXS::IsIsoApplicable(const G4DynamicParticle*, 102 G4int, G4int, << 113 G4int /*ZZ*/, G4int /*AA*/, 103 const G4Element*, const G4Material 114 const G4Element*, const G4Material*) 104 { 115 { 105 return true; 116 return true; 106 } 117 } 107 118 108 G4double 119 G4double 109 G4NeutronCaptureXS::GetElementCrossSection(con 120 G4NeutronCaptureXS::GetElementCrossSection(const G4DynamicParticle* aParticle, 110 G4int Z, const G4Material*) 121 G4int Z, const G4Material*) 111 { 122 { 112 G4double xs = 0.0; 123 G4double xs = 0.0; 113 G4double ekin = aParticle->GetKineticEnergy( 124 G4double ekin = aParticle->GetKineticEnergy(); 114 if (ekin < emax) { << 125 if(ekin > emax || Z < 1 || Z >= MAXZCAPTURE) { return xs; } 115 xs = ElementCrossSection(ekin, aParticle-> << 126 if(ekin < elimit) { ekin = elimit; } 116 } << 117 return xs; << 118 } << 119 127 120 G4double << 128 G4PhysicsVector* pv = data.GetElementData(Z); 121 G4NeutronCaptureXS::ComputeCrossSectionPerElem << 129 122 const G4ParticleDefi << 130 // element was not initialised 123 const G4Element* elm << 131 if(!pv) { 124 const G4Material*) << 132 Initialise(Z); 125 { << 133 pv = data.GetElementData(Z); 126 G4double xs = 0.0; << 134 if(!pv) { return xs; } 127 if (ekin < emax) { << 128 xs = ElementCrossSection(ekin, loge, elm-> << 129 } 135 } 130 return xs; << 131 } << 132 136 133 G4double << 137 G4double e1 = pv->Energy(0); 134 G4NeutronCaptureXS::ElementCrossSection(G4doub << 138 if(ekin < e1) { xs = (*pv)[0]*std::sqrt(e1/ekin); } 135 { << 139 else if(ekin <= pv->GetMaxEnergy()) { xs = pv->Value(ekin); } 136 G4int Z = std::min(ZZ, MAXZCAPTURE); << 140 137 G4double ekin = eKin; << 141 if(verboseLevel > 0){ 138 G4double logEkin = logE; << 142 G4cout << "ekin= " << ekin << ", xs= " << xs << G4endl; 139 if (ekin < elimit) { << 140 ekin = elimit; << 141 logEkin = logElimit; << 142 } << 143 << 144 auto pv = GetPhysicsVector(Z); << 145 const G4double e0 = pv->Energy(0); << 146 G4double xs = (ekin >= e0) ? pv->LogVectorVa << 147 : (*pv)[0]*std::sqrt(e0/ekin); << 148 << 149 #ifdef G4VERBOSE << 150 if (verboseLevel > 1){ << 151 G4cout << "Ekin= " << ekin/CLHEP::MeV << 152 << " ElmXScap(b)= " << xs/CLHEP::b << 153 } 143 } 154 #endif << 155 return xs; 144 return xs; 156 } 145 } 157 146 158 G4double << 159 G4NeutronCaptureXS::ComputeIsoCrossSection(G4d << 160 const G4ParticleDefinition* << 161 G4int Z, G4int A, << 162 const G4Isotope*, const G4E << 163 const G4Material*) << 164 { << 165 return IsoCrossSection(ekin, loge, Z, A); << 166 } << 167 << 168 G4double 147 G4double 169 G4NeutronCaptureXS::GetIsoCrossSection(const G 148 G4NeutronCaptureXS::GetIsoCrossSection(const G4DynamicParticle* aParticle, 170 G4int Z, G4int A, 149 G4int Z, G4int A, 171 const G4Isotope*, const G4Eleme 150 const G4Isotope*, const G4Element*, 172 const G4Material*) 151 const G4Material*) 173 { 152 { 174 return IsoCrossSection(aParticle->GetKinetic << 153 G4double xs = 0.0; 175 aParticle->GetLogKine << 154 G4double ekin = aParticle->GetKineticEnergy(); 176 Z, A); << 155 if(ekin <= emax && Z > 0 && Z < MAXZCAPTURE) { >> 156 xs = IsoCrossSection(ekin, Z, A); >> 157 } >> 158 return xs; 177 } 159 } 178 160 179 G4double G4NeutronCaptureXS::IsoCrossSection(G << 161 G4double G4NeutronCaptureXS::IsoCrossSection(G4double ekin, G4int Z, G4int A) 180 G << 181 { 162 { 182 G4double xs = 0.0; 163 G4double xs = 0.0; 183 if (eKin > emax) { return xs; } << 164 if(ekin < elimit) { ekin = elimit; } 184 165 185 G4int Z = std::min(ZZ, MAXZCAPTURE); << 166 G4PhysicsVector* pv = data.GetElementData(Z); 186 G4double ekin = eKin; << 167 187 G4double logEkin = logE; << 168 // element was not initialised 188 if (ekin < elimit) { << 169 if(!pv) { 189 ekin = elimit; << 170 Initialise(Z); 190 logEkin = logElimit; << 171 pv = data.GetElementData(Z); 191 } << 172 if(!pv) { return xs; } 192 << 173 } 193 auto pv = GetPhysicsVector(Z); << 174 G4PhysicsVector* pviso = data.GetComponentDataByID(Z, A); 194 if (pv == nullptr) { return xs; } << 175 if(pviso) { pv = pviso; } 195 << 176 196 // use isotope x-section if possible << 177 G4double e1 = pv->Energy(1); 197 if (data->GetNumberOfComponents(Z) > 0) { << 178 if(ekin < e1) { xs = (*pv)[1]*std::sqrt(e1/ekin); } 198 G4PhysicsVector* pviso = data->GetComponen << 179 else if(ekin <= pv->GetMaxEnergy()) { xs = pv->Value(ekin); } 199 if(pviso != nullptr) { << 180 200 const G4double e0 = pviso->Energy(0); << 181 if(verboseLevel > 0){ 201 xs = (ekin >= e0) ? pviso->LogVectorValu << 182 G4cout << "G4NeutronCaptureXS::IsoCrossSection: Ekin(MeV)= " << ekin/MeV 202 : (*pviso)[0]*std::sqrt(e0/ekin); << 183 << " xs(b)= " << xs/barn 203 #ifdef G4VERBOSE << 184 << " Z= " << Z << " A= " << A << " " << pv->GetVectorLength() 204 if(verboseLevel > 0) { << 185 << G4endl; 205 G4cout << "G4NeutronCaptureXS::IsoXS: Ekin(M << 206 << " xs(b)= " << xs/barn << 207 << " Z= " << Z << " A= " << A << G4 << 208 } << 209 #endif << 210 return xs; << 211 } << 212 } << 213 // isotope data are not available or applica << 214 const G4double e0 = pv->Energy(0); << 215 xs = (ekin >= e0) ? pv->LogVectorValue(ekin, << 216 : (*pv)[0]*std::sqrt(e0/ekin); << 217 #ifdef G4VERBOSE << 218 if (verboseLevel > 0) { << 219 G4cout << "G4NeutronCaptureXS::IsoXS: Ekin << 220 << " xs(b)= " << xs/barn << 221 << " Z= " << Z << " A= " << A << " no i << 222 } 186 } 223 #endif << 224 return xs; 187 return xs; 225 } 188 } 226 189 227 const G4Isotope* << 190 G4Isotope* G4NeutronCaptureXS::SelectIsotope(const G4Element* anElement, 228 G4NeutronCaptureXS::SelectIsotope(const G4Elem << 191 G4double kinEnergy) 229 G4double kinEnergy, G4double logE) << 230 { 192 { 231 G4int nIso = (G4int)anElement->GetNumberOfIs << 193 G4int nIso = anElement->GetNumberOfIsotopes(); 232 const G4Isotope* iso = anElement->GetIsotope << 194 G4IsotopeVector* isoVector = anElement->GetIsotopeVector(); 233 << 195 G4Isotope* iso = (*isoVector)[0]; 234 //G4cout << "SelectIsotope NIso= " << nIso < << 235 if(1 == nIso) { return iso; } << 236 196 237 // more than 1 isotope 197 // more than 1 isotope 238 G4int Z = anElement->GetZasInt(); << 198 if(1 < nIso) { 239 if (nullptr == data->GetElementData(Z)) { In << 199 G4int Z = G4lrint(anElement->GetZ()); 240 << 200 if(Z >= MAXZCAPTURE) { Z = MAXZCAPTURE-1; } 241 const G4double* abundVector = anElement->Get << 201 G4double* abundVector = anElement->GetRelativeAbundanceVector(); 242 G4double q = G4UniformRand(); << 202 G4double q = G4UniformRand(); 243 G4double sum = 0.0; << 203 G4double sum = 0.0; 244 << 204 245 // is there isotope wise cross section? << 205 // is there isotope wise cross section? 246 G4int j; << 206 if(0 == amin[Z]) { 247 if (Z > MAXZCAPTURE || 0 == data->GetNumberO << 207 for (G4int j = 0; j<nIso; ++j) { 248 for (j = 0; j<nIso; ++j) { << 208 sum += abundVector[j]; 249 sum += abundVector[j]; << 209 if(q <= sum) { 250 if(q <= sum) { << 210 iso = (*isoVector)[j]; 251 iso = anElement->GetIsotope(j); << 211 break; 252 break; << 212 } >> 213 } >> 214 } else { >> 215 size_t nmax = data.GetNumberOfComponents(Z); >> 216 if(temp.size() < nmax) { temp.resize(nmax,0.0); } >> 217 for (size_t i=0; i<nmax; ++i) { >> 218 G4int A = (*isoVector)[i]->GetN(); >> 219 sum += abundVector[i]*IsoCrossSection(kinEnergy, Z, A); >> 220 temp[i] = sum; >> 221 } >> 222 sum *= q; >> 223 for (size_t j = 0; j<nmax; ++j) { >> 224 if(temp[j] >= sum) { >> 225 iso = (*isoVector)[j]; >> 226 break; >> 227 } 253 } 228 } 254 } << 255 return iso; << 256 } << 257 G4int nn = (G4int)temp.size(); << 258 if (nn < nIso) { temp.resize(nIso, 0.); } << 259 << 260 for (j=0; j<nIso; ++j) { << 261 sum += abundVector[j]*IsoCrossSection(kinE << 262 anElement->GetIsotope(j)->GetN()); << 263 temp[j] = sum; << 264 } << 265 sum *= q; << 266 for (j = 0; j<nIso; ++j) { << 267 if (temp[j] >= sum) { << 268 iso = anElement->GetIsotope(j); << 269 break; << 270 } 229 } 271 } 230 } 272 return iso; 231 return iso; 273 } 232 } 274 233 275 void 234 void 276 G4NeutronCaptureXS::BuildPhysicsTable(const G4 235 G4NeutronCaptureXS::BuildPhysicsTable(const G4ParticleDefinition& p) 277 { 236 { 278 if (verboseLevel > 0){ << 237 if(isInitialized) { return; } >> 238 if(verboseLevel > 0){ 279 G4cout << "G4NeutronCaptureXS::BuildPhysic 239 G4cout << "G4NeutronCaptureXS::BuildPhysicsTable for " 280 << p.GetParticleName() << G4endl; 240 << p.GetParticleName() << G4endl; 281 } 241 } 282 if (p.GetParticleName() != "neutron") { << 242 if(p.GetParticleName() != "neutron") { 283 G4ExceptionDescription ed; 243 G4ExceptionDescription ed; 284 ed << p.GetParticleName() << " is a wrong 244 ed << p.GetParticleName() << " is a wrong particle type -" 285 << " only neutron is allowed"; 245 << " only neutron is allowed"; 286 G4Exception("G4NeutronCaptureXS::BuildPhys 246 G4Exception("G4NeutronCaptureXS::BuildPhysicsTable(..)","had012", 287 FatalException, ed, ""); 247 FatalException, ed, ""); 288 return; 248 return; 289 } 249 } >> 250 isInitialized = true; 290 251 291 // it is possible re-initialisation for the << 252 // check environment variable 292 const G4ElementTable* table = G4Element::Get << 253 // Build the complete string identifying the file with the data set 293 << 254 char* path = getenv("G4NEUTRONXSDATA"); 294 // initialise static tables only once << 255 295 std::call_once(applyOnce, [this]() { isIniti << 256 // Access to elements 296 << 257 const G4ElementTable* theElmTable = G4Element::GetElementTable(); 297 if (isInitializer) { << 258 size_t numOfElm = G4Element::GetNumberOfElements(); 298 G4AutoLock l(&neutronCaptureXSMutex); << 259 if(numOfElm > 0) { 299 // Access to elements << 260 for(size_t i=0; i<numOfElm; ++i) { 300 for ( auto const & elm : *table ) { << 261 G4int Z = G4int(((*theElmTable)[i])->GetZ()); 301 G4int Z = std::max( 1, std::min( elm->Ge << 262 if(Z < 1) { Z = 1; } 302 if ( nullptr == data->GetElementData(Z) << 263 else if(Z >= MAXZCAPTURE) { Z = MAXZCAPTURE-1; } >> 264 //G4cout << "Z= " << Z << G4endl; >> 265 // Initialisation >> 266 if(!data.GetElementData(Z)) { Initialise(Z, path); } 303 } 267 } 304 l.unlock(); << 305 } 268 } 306 << 307 // prepare isotope selection << 308 std::size_t nIso = temp.size(); << 309 for ( auto const & elm : *table ) { << 310 std::size_t n = elm->GetNumberOfIsotopes() << 311 if (n > nIso) { nIso = n; } << 312 } << 313 temp.resize(nIso, 0.0); << 314 } 269 } 315 270 316 const G4String& G4NeutronCaptureXS::FindDirect << 271 void 317 { << 272 G4NeutronCaptureXS::Initialise(G4int Z, const char* p) 318 // build the complete string identifying the << 319 if(gDataDirectory.empty()) { << 320 std::ostringstream ost; << 321 ost << G4HadronicParameters::Instance()->G << 322 gDataDirectory = ost.str(); << 323 } << 324 return gDataDirectory; << 325 } << 326 << 327 void G4NeutronCaptureXS::InitialiseOnFly(G4int << 328 { 273 { 329 G4AutoLock l(&neutronCaptureXSMutex); << 274 if(data.GetElementData(Z)) { return; } 330 Initialise(Z); << 275 const char* path = p; 331 l.unlock(); << 332 } << 333 276 334 void G4NeutronCaptureXS::Initialise(G4int Z) << 277 // check environment variable 335 { << 278 if(!p) { 336 if (nullptr != data->GetElementData(Z)) { re << 279 path = getenv("G4NEUTRONXSDATA"); >> 280 if (!path) { >> 281 G4Exception("G4NeutronCaptureXS::Initialise(..)","had013",FatalException, >> 282 "Environment variable G4NEUTRONXSDATA is not defined"); >> 283 return; >> 284 } >> 285 } 337 286 338 // upload element data 287 // upload element data 339 std::ostringstream ost; 288 std::ostringstream ost; 340 ost << FindDirectoryPath() << Z ; << 289 ost << path << "/cap" << Z ; 341 G4PhysicsVector* v = RetrieveVector(ost, tru 290 G4PhysicsVector* v = RetrieveVector(ost, true); 342 data->InitialiseForElement(Z, v); << 291 data.InitialiseForElement(Z, v); 343 292 344 // upload isotope data 293 // upload isotope data 345 G4bool noComp = true; << 294 if(amin[Z] > 0) { 346 if (amin[Z] < amax[Z]) { << 295 size_t n = 0; >> 296 size_t i = 0; >> 297 size_t nmax = (size_t)(amax[Z]-amin[Z]+1); >> 298 if(work.size() < nmax) { work.resize(nmax,0); } 347 for(G4int A=amin[Z]; A<=amax[Z]; ++A) { 299 for(G4int A=amin[Z]; A<=amax[Z]; ++A) { 348 std::ostringstream ost1; 300 std::ostringstream ost1; 349 ost1 << gDataDirectory << Z << "_" << A; << 301 ost1 << path << "/cap" << Z << "_" << A; 350 G4PhysicsVector* v1 = RetrieveVector(ost << 302 v = RetrieveVector(ost1, false); 351 if (nullptr != v1) { << 303 if(v) { ++n; } 352 if (noComp) { << 304 work[i] = v; 353 G4int nmax = amax[Z] - A + 1; << 305 ++i; 354 data->InitialiseForComponent(Z, nmax); << 306 } 355 noComp = false; << 307 data.InitialiseForComponent(Z, n); 356 } << 308 for(size_t j=0; j<i; ++j) { 357 data->AddComponent(Z, A, v1); << 309 if(work[j]) { data.AddComponent(Z, amin[Z]+j, work[j]); } 358 } << 359 } 310 } 360 } 311 } 361 // no components case << 362 if (noComp) { data->InitialiseForComponent(Z << 363 } 312 } 364 313 365 G4PhysicsVector* 314 G4PhysicsVector* 366 G4NeutronCaptureXS::RetrieveVector(std::ostrin 315 G4NeutronCaptureXS::RetrieveVector(std::ostringstream& ost, G4bool warn) 367 { 316 { 368 G4PhysicsLogVector* v = nullptr; << 317 G4PhysicsLogVector* v = 0; 369 std::ifstream filein(ost.str().c_str()); 318 std::ifstream filein(ost.str().c_str()); 370 if (!filein.is_open()) { << 319 if (!(filein)) { 371 if (warn) { << 320 if(!warn) { return v; } 372 G4ExceptionDescription ed; << 321 G4ExceptionDescription ed; 373 ed << "Data file <" << ost.str().c_str() << 322 ed << "Data file <" << ost.str().c_str() 374 << "> is not opened!"; << 323 << "> is not opened!"; 375 G4Exception("G4NeutronCaptureXS::Retriev << 324 G4Exception("G4NeutronCaptureXS::RetrieveVector(..)","had014", 376 FatalException, ed, "Check G4PARTICLEXSD << 325 FatalException, ed, "Check G4NEUTRONXSDATA"); 377 } << 326 }else{ 378 } else { << 327 if(verboseLevel > 1) { 379 if (verboseLevel > 1) { << 380 G4cout << "File " << ost.str() 328 G4cout << "File " << ost.str() 381 << " is opened by G4NeutronCaptureXS" < 329 << " is opened by G4NeutronCaptureXS" << G4endl; 382 } 330 } 383 // retrieve data from DB 331 // retrieve data from DB 384 v = new G4PhysicsLogVector(); 332 v = new G4PhysicsLogVector(); 385 if (!v->Retrieve(filein, true)) { << 333 if(!v->Retrieve(filein, true)) { 386 G4ExceptionDescription ed; 334 G4ExceptionDescription ed; 387 ed << "Data file <" << ost.str().c_str() 335 ed << "Data file <" << ost.str().c_str() 388 << "> is not retrieved!"; 336 << "> is not retrieved!"; 389 G4Exception("G4NeutronCaptureXS::Retriev 337 G4Exception("G4NeutronCaptureXS::RetrieveVector(..)","had015", 390 FatalException, ed, "Check G4PARTICLEXSD << 338 FatalException, ed, "Check G4NEUTRONXSDATA"); 391 } 339 } 392 } 340 } 393 return v; 341 return v; 394 } 342 } 395 343