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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: G4OpticalSurface.cc,v 1.10 2006/06/29 19:13:08 gunter Exp $ >> 28 // GEANT4 tag $Name: geant4-08-03-patch-01 $ >> 29 // >> 30 // 26 ////////////////////////////////////////////// 31 //////////////////////////////////////////////////////////////////////// 27 // Optical Surface Class Implementation 32 // Optical Surface Class Implementation 28 ////////////////////////////////////////////// 33 //////////////////////////////////////////////////////////////////////// 29 // 34 // 30 // File: G4OpticalSurface.cc 35 // File: G4OpticalSurface.cc 31 // Description: An optical surface class for u 36 // Description: An optical surface class for use in G4OpBoundaryProcess 32 // Version: 2.0 37 // Version: 2.0 33 // Created: 1997-06-26 38 // Created: 1997-06-26 34 // Author: Peter Gumplinger 39 // Author: Peter Gumplinger 35 // updated: 2017-02-24 Mariele Stockhoff a << 40 // mail: gum@triumf.ca >> 41 // 36 ////////////////////////////////////////////// 42 //////////////////////////////////////////////////////////////////////// 37 43 38 #include "G4OpticalSurface.hh" << 44 #include "G4ios.hh" 39 << 40 #include "globals.hh" 45 #include "globals.hh" >> 46 #include "G4OpticalSurface.hh" 41 47 42 #include <zlib.h> << 48 ///////////////////////// 43 << 49 // Class Implementation 44 #include <fstream> << 50 ///////////////////////// 45 #include <iostream> << 51 46 << 52 ////////////// 47 G4OpticalSurface& G4OpticalSurface::operator=( << 53 // Operators 48 { << 54 ////////////// 49 if (this != &right) { << 55 50 theName = right.theName; << 56 const G4OpticalSurface& 51 theType = right.theType; << 57 G4OpticalSurface::operator=(const G4OpticalSurface& right) 52 theModel = right.theModel; << 58 { 53 theFinish = right.theFinish; << 59 if (this != &right) 54 sigma_alpha = right.sigma_alpha; << 60 { 55 polish = right.polish; << 61 theName = right.GetName(); 56 theMaterialPropertiesTable = right.theMate << 62 theModel = right.theModel; 57 << 63 theFinish = right.theFinish; 58 delete[] AngularDistribution; << 64 theType = right.GetType(); 59 AngularDistribution = new G4float[incident << 65 sigma_alpha = right.sigma_alpha; 60 *(AngularDistribution) = *(right.AngularDi << 66 polish = right.polish; 61 << 67 theMaterialPropertiesTable = right.theMaterialPropertiesTable; 62 delete[] AngularDistributionLUT; << 68 } 63 AngularDistributionLUT = new G4float[index << 64 *(AngularDistributionLUT) = *(right.Angula << 65 << 66 delete[] Reflectivity; << 67 Reflectivity = new G4float[RefMax]; << 68 *(Reflectivity) = *(right.Reflectivity); << 69 << 70 delete DichroicVector; << 71 DichroicVector = new G4Physics2DVector(); << 72 *DichroicVector = *(right.DichroicVector); << 73 } << 74 return *this; 69 return *this; 75 } 70 } 76 71 77 G4OpticalSurface::G4OpticalSurface(const G4Str << 72 ///////////////// 78 G4OpticalSurfaceFinish finish, G4SurfaceType << 73 // Constructors 79 : G4SurfaceProperty(name, type), theModel(mo << 74 ///////////////// 80 { << 81 AngularDistribution = nullptr; << 82 << 83 AngularDistributionLUT = nullptr; << 84 Reflectivity = nullptr; << 85 << 86 DichroicVector = nullptr; << 87 << 88 switch (theModel) { << 89 case glisur: << 90 polish = value; << 91 sigma_alpha = 0.0; << 92 break; << 93 case LUT: << 94 case dichroic: << 95 case DAVIS: << 96 ReadDataFile(); << 97 // fall through << 98 case unified: << 99 sigma_alpha = value; << 100 polish = 0.0; << 101 break; << 102 default: << 103 G4Exception("G4OpticalSurface::G4Optical << 104 "Constructor called with INVALID model << 105 } << 106 } << 107 << 108 G4OpticalSurface::~G4OpticalSurface() << 109 { << 110 delete[] AngularDistribution; << 111 << 112 delete[] AngularDistributionLUT; << 113 << 114 delete[] Reflectivity; << 115 << 116 delete DichroicVector; << 117 } << 118 << 119 G4OpticalSurface::G4OpticalSurface(const G4Opt << 120 : G4SurfaceProperty(right.theName, right.the << 121 { << 122 *this = right; << 123 this->theName = right.theName; << 124 this->theType = right.theType; << 125 this->theModel = right.theModel; << 126 this->theFinish = right.theFinish; << 127 this->sigma_alpha = right.sigma_alpha; << 128 this->polish = right.polish; << 129 this->theMaterialPropertiesTable = right.the << 130 << 131 delete[] AngularDistribution; << 132 this->AngularDistribution = new G4float[inci << 133 *(this->AngularDistribution) = *(right.Angul << 134 << 135 delete[] AngularDistributionLUT; << 136 this->AngularDistributionLUT = new G4float[i << 137 *(this->AngularDistributionLUT) = *(right.An << 138 << 139 delete[] Reflectivity; << 140 this->Reflectivity = new G4float[RefMax]; << 141 *(this->Reflectivity) = *(right.Reflectivity << 142 << 143 delete DichroicVector; << 144 this->DichroicVector = new G4Physics2DVector << 145 *(this->DichroicVector) = *(right.DichroicVe << 146 } << 147 << 148 G4bool G4OpticalSurface::operator==(const G4Op << 149 { << 150 return (this == (G4OpticalSurface*)&right); << 151 } << 152 << 153 G4bool G4OpticalSurface::operator!=(const G4Op << 154 { << 155 return (this != (G4OpticalSurface*)&right); << 156 } << 157 << 158 G4int G4OpticalSurface::GetInmax() const { ret << 159 << 160 G4int G4OpticalSurface::GetLUTbins() const { r << 161 << 162 G4int G4OpticalSurface::GetRefMax() const { re << 163 << 164 G4int G4OpticalSurface::GetThetaIndexMax() con << 165 << 166 G4int G4OpticalSurface::GetPhiIndexMax() const << 167 75 168 void G4OpticalSurface::DumpInfo() const << 76 G4OpticalSurface::G4OpticalSurface(const G4String& name, >> 77 G4OpticalSurfaceModel model, >> 78 G4OpticalSurfaceFinish finish, >> 79 G4SurfaceType type, >> 80 G4double value) >> 81 : G4SurfaceProperty(name,type), >> 82 theModel(model), >> 83 theFinish(finish), >> 84 theMaterialPropertiesTable(0) 169 { 85 { 170 // Dump info for surface << 86 if (model == glisur ){ 171 << 87 polish = value; 172 G4cout << " Surface type = " << G4int(the << 88 sigma_alpha = 0.0; 173 << " Surface finish = " << G4int(the << 89 } 174 << " Surface model = " << G4int(the << 90 else if ( model == unified ) { 175 << G4endl << " ----------------- " < << 91 sigma_alpha = value; 176 << 92 polish = 0.0; 177 if (theModel == glisur) { << 93 } 178 G4cout << " polish: " << polish << G4endl; << 94 else { 179 } << 95 G4Exception("G4OpticalSurface::G4OpticalSurface ==> " 180 else { << 96 "Constructor called with INVALID model."); 181 G4cout << " sigma_alpha: " << sigma_alpha << 97 } 182 } << 183 G4cout << G4endl; << 184 } << 185 << 186 void G4OpticalSurface::SetType(const G4Surface << 187 { << 188 theType = type; << 189 ReadDataFile(); << 190 } 98 } 191 99 192 void G4OpticalSurface::SetFinish(const G4Optic << 100 G4OpticalSurface::G4OpticalSurface(const G4OpticalSurface &right) >> 101 : G4SurfaceProperty(right.GetName()) 193 { 102 { 194 theFinish = finish; << 103 *this = right; 195 ReadDataFile(); << 196 } 104 } 197 105 198 void G4OpticalSurface::ReadDataFile() << 106 G4OpticalSurface::~G4OpticalSurface(){} 199 { << 200 // type and finish can be set in either orde << 201 // for consistency. Need to read file on set << 202 switch (theType) { << 203 case dielectric_LUT: << 204 if (AngularDistribution == nullptr) { << 205 AngularDistribution = new G4float[inci << 206 } << 207 ReadLUTFile(); << 208 break; << 209 case dielectric_LUTDAVIS: << 210 if (AngularDistributionLUT == nullptr) { << 211 AngularDistributionLUT = new G4float[i << 212 } << 213 ReadLUTDAVISFile(); << 214 << 215 if (Reflectivity == nullptr) { << 216 Reflectivity = new G4float[RefMax]; << 217 } << 218 ReadReflectivityLUTFile(); << 219 break; << 220 case dielectric_dichroic: << 221 if (DichroicVector == nullptr) { << 222 DichroicVector = new G4Physics2DVector << 223 } << 224 ReadDichroicFile(); << 225 break; << 226 default: << 227 break; << 228 } << 229 } << 230 107 231 void G4OpticalSurface::ReadLUTFile() << 108 G4int G4OpticalSurface::operator==(const G4OpticalSurface &right) const 232 { 109 { 233 G4String readLUTFileName; << 110 return (this == (G4OpticalSurface *) &right); 234 << 235 switch (theFinish) { << 236 case polishedlumirrorglue: << 237 readLUTFileName = "PolishedLumirrorGlue. << 238 break; << 239 case polishedlumirrorair: << 240 readLUTFileName = "PolishedLumirror.z"; << 241 break; << 242 case polishedteflonair: << 243 readLUTFileName = "PolishedTeflon.z"; << 244 break; << 245 case polishedtioair: << 246 readLUTFileName = "PolishedTiO.z"; << 247 break; << 248 case polishedtyvekair: << 249 readLUTFileName = "PolishedTyvek.z"; << 250 break; << 251 case polishedvm2000glue: << 252 readLUTFileName = "PolishedVM2000Glue.z" << 253 break; << 254 case polishedvm2000air: << 255 readLUTFileName = "PolishedVM2000.z"; << 256 break; << 257 case etchedlumirrorglue: << 258 readLUTFileName = "EtchedLumirrorGlue.z" << 259 break; << 260 case etchedlumirrorair: << 261 readLUTFileName = "EtchedLumirror.z"; << 262 break; << 263 case etchedteflonair: << 264 readLUTFileName = "EtchedTeflon.z"; << 265 break; << 266 case etchedtioair: << 267 readLUTFileName = "EtchedTiO.z"; << 268 break; << 269 case etchedtyvekair: << 270 readLUTFileName = "EtchedTyvek.z"; << 271 break; << 272 case etchedvm2000glue: << 273 readLUTFileName = "EtchedVM2000Glue.z"; << 274 break; << 275 case etchedvm2000air: << 276 readLUTFileName = "EtchedVM2000.z"; << 277 break; << 278 case groundlumirrorglue: << 279 readLUTFileName = "GroundLumirrorGlue.z" << 280 break; << 281 case groundlumirrorair: << 282 readLUTFileName = "GroundLumirror.z"; << 283 break; << 284 case groundteflonair: << 285 readLUTFileName = "GroundTeflon.z"; << 286 break; << 287 case groundtioair: << 288 readLUTFileName = "GroundTiO.z"; << 289 break; << 290 case groundtyvekair: << 291 readLUTFileName = "GroundTyvek.z"; << 292 break; << 293 case groundvm2000glue: << 294 readLUTFileName = "GroundVM2000Glue.z"; << 295 break; << 296 case groundvm2000air: << 297 readLUTFileName = "GroundVM2000.z"; << 298 break; << 299 default: << 300 return; << 301 } << 302 << 303 std::istringstream iss; << 304 ReadCompressedFile(readLUTFileName, iss); << 305 << 306 size_t idxmax = incidentIndexMax * thetaInde << 307 for (size_t i = 0; i < idxmax; ++i) { << 308 iss >> AngularDistribution[i]; << 309 } << 310 G4cout << "LUT - data file: " << readLUTFile << 311 } 111 } 312 112 313 void G4OpticalSurface::ReadLUTDAVISFile() << 113 G4int G4OpticalSurface::operator!=(const G4OpticalSurface &right) const 314 { 114 { 315 G4String readLUTDAVISFileName; << 115 return (this != (G4OpticalSurface *) &right); 316 << 317 switch (theFinish) { << 318 case Rough_LUT: << 319 readLUTDAVISFileName = "Rough_LUT.z"; << 320 break; << 321 case RoughTeflon_LUT: << 322 readLUTDAVISFileName = "RoughTeflon_LUT. << 323 break; << 324 case RoughESR_LUT: << 325 readLUTDAVISFileName = "RoughESR_LUT.z"; << 326 break; << 327 case RoughESRGrease_LUT: << 328 readLUTDAVISFileName = "RoughESRGrease_L << 329 break; << 330 case Polished_LUT: << 331 readLUTDAVISFileName = "Polished_LUT.z"; << 332 break; << 333 case PolishedTeflon_LUT: << 334 readLUTDAVISFileName = "PolishedTeflon_L << 335 break; << 336 case PolishedESR_LUT: << 337 readLUTDAVISFileName = "PolishedESR_LUT. << 338 break; << 339 case PolishedESRGrease_LUT: << 340 readLUTDAVISFileName = "PolishedESRGreas << 341 break; << 342 case Detector_LUT: << 343 readLUTDAVISFileName = "Detector_LUT.z"; << 344 break; << 345 default: << 346 return; << 347 } << 348 << 349 std::istringstream iss; << 350 ReadCompressedFile(readLUTDAVISFileName, iss << 351 << 352 for (size_t i = 0; i < indexmax; ++i) { << 353 iss >> AngularDistributionLUT[i]; << 354 } << 355 G4cout << "LUT DAVIS - data file: " << readL << 356 } 116 } >> 117 //////////// >> 118 // Methods >> 119 //////////// 357 120 358 void G4OpticalSurface::ReadReflectivityLUTFile << 121 void G4OpticalSurface::DumpInfo() const 359 { 122 { 360 G4String readReflectivityLUTFileName; << 361 123 362 switch (theFinish) { << 124 // Dump info for surface 363 case Rough_LUT: << 364 readReflectivityLUTFileName = "Rough_LUT << 365 break; << 366 case RoughTeflon_LUT: << 367 readReflectivityLUTFileName = "RoughTefl << 368 break; << 369 case RoughESR_LUT: << 370 readReflectivityLUTFileName = "RoughESR_ << 371 break; << 372 case RoughESRGrease_LUT: << 373 readReflectivityLUTFileName = "RoughESRG << 374 break; << 375 case Polished_LUT: << 376 readReflectivityLUTFileName = "Polished_ << 377 break; << 378 case PolishedTeflon_LUT: << 379 readReflectivityLUTFileName = "PolishedT << 380 break; << 381 case PolishedESR_LUT: << 382 readReflectivityLUTFileName = "PolishedE << 383 break; << 384 case PolishedESRGrease_LUT: << 385 readReflectivityLUTFileName = "PolishedE << 386 break; << 387 case Detector_LUT: << 388 readReflectivityLUTFileName = "Detector_ << 389 break; << 390 default: << 391 return; << 392 } << 393 << 394 std::istringstream iss; << 395 ReadCompressedFile(readReflectivityLUTFileNa << 396 << 397 for (size_t i = 0; i < RefMax; ++i) { << 398 iss >> Reflectivity[i]; << 399 } << 400 G4cout << "LUT DAVIS - reflectivity data fil << 401 << G4endl; << 402 } << 403 125 404 // uncompress one data file into the input str << 126 G4cout << 405 void G4OpticalSurface::ReadCompressedFile(cons << 127 " Surface type = " << G4int(theType) << G4endl << 406 { << 128 " Surface finish = " << G4int(theFinish) << G4endl << 407 G4String* dataString = nullptr; << 129 " Surface model = " << G4int(theModel) << G4endl; 408 G4String path = G4FindDataDir("G4REALSURFACE << 409 G4String compfilename = path + "/" + filenam << 410 // create input stream with binary mode oper << 411 std::ifstream in(compfilename, std::ios::bin << 412 if (in.good()) { << 413 // get current position in the stream (was << 414 G4int fileSize = (G4int)in.tellg(); << 415 // set current position being the beginnin << 416 in.seekg(0, std::ios::beg); << 417 // create (zlib) byte buffer for the data << 418 auto compdata = new Bytef[fileSize]; << 419 while (in) { << 420 in.read((char*)compdata, fileSize); << 421 } << 422 // create (zlib) byte buffer for the uncom << 423 auto complen = (uLongf)(fileSize * 4); << 424 auto uncompdata = new Bytef[complen]; << 425 while (Z_OK != uncompress(uncompdata, &com << 426 // increase uncompressed byte buffer << 427 delete[] uncompdata; << 428 complen *= 2; << 429 uncompdata = new Bytef[complen]; << 430 } << 431 // delete the compressed data buffer << 432 delete[] compdata; << 433 // create a string from uncompressed data << 434 dataString = new G4String((char*)uncompdat << 435 // delete the uncompressed data buffer << 436 delete[] uncompdata; << 437 } << 438 else { << 439 G4ExceptionDescription ed; << 440 ed << "Problem while trying to read " + co << 441 G4Exception("G4OpticalSurface::ReadCompres << 442 return; << 443 } << 444 // create the input string stream from the d << 445 if (dataString != nullptr) { << 446 iss.str(*dataString); << 447 in.close(); << 448 delete dataString; << 449 G4cout << "G4OpticalSurface: data file " < << 450 } << 451 } << 452 130 453 void G4OpticalSurface::ReadDichroicFile() << 131 G4cout << G4endl; 454 { << 455 const char* datadir = G4FindDataDir("G4DICHR << 456 132 457 if (datadir == nullptr) { << 133 G4cout << " Surface parameter " << G4endl; 458 G4Exception("G4OpticalSurface::ReadDichroi << 134 G4cout << " ----------------- " << G4endl; 459 "Environment variable G4DICHROICDATA not << 135 if (theModel == glisur ){ 460 return; << 136 G4cout << polish << G4endl; 461 } << 137 } 462 << 138 else { 463 std::ostringstream ost; << 139 G4cout << sigma_alpha << G4endl; 464 ost << datadir; << 140 } 465 std::ifstream fin(ost.str().c_str()); << 141 G4cout << G4endl; 466 if (! fin.is_open()) { << 467 G4ExceptionDescription ed; << 468 ed << "Dichroic surface data file <" << os << 469 G4Exception("G4OpticalSurface::ReadDichroi << 470 return; << 471 } << 472 << 473 if (! (DichroicVector->Retrieve(fin))) { << 474 G4ExceptionDescription ed; << 475 ed << "Dichroic surface data file <" << os << 476 G4Exception("G4OpticalSurface::ReadDichroi << 477 return; << 478 } << 479 << 480 // DichroicVector->SetBicubicInterpolation( << 481 << 482 G4cout << " *** Dichroic surface data file * << 483 << 484 auto numberOfXNodes = (G4int)DichroicVector- << 485 auto numberOfYNodes = (G4int)DichroicVector- << 486 << 487 G4cout << "numberOfXNodes: " << numberOfXNod << 488 G4cout << "numberOfYNodes: " << numberOfYNod << 489 << 490 if (0 > numberOfXNodes || numberOfXNodes >= << 491 numberOfXNodes = 0; << 492 } << 493 if (0 > numberOfYNodes || numberOfYNodes >= << 494 numberOfYNodes = 0; << 495 } << 496 << 497 G4PV2DDataVector xVector; << 498 G4PV2DDataVector yVector; << 499 << 500 xVector.resize(numberOfXNodes, 0.); << 501 yVector.resize(numberOfYNodes, 0.); << 502 << 503 for (G4int i = 0; i < numberOfXNodes; ++i) { << 504 G4cout << "i: " << DichroicVector->GetX(i) << 505 xVector[i] = DichroicVector->GetX(i); << 506 } << 507 for (G4int j = 0; j < numberOfYNodes; ++j) { << 508 G4cout << "j: " << DichroicVector->GetY(j) << 509 yVector[j] = DichroicVector->GetY(j); << 510 } << 511 << 512 for (G4int j = 0; j < numberOfYNodes; ++j) { << 513 for (G4int i = 0; i < numberOfXNodes; ++i) << 514 G4cout << " i: " << i << " j: " << j << << 515 } << 516 } << 517 } 142 } 518 143