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 // 26 // >> 27 // $Id: G4ASCIITreeSceneHandler.cc 66870 2013-01-14 23:38:59Z adotti $ 27 // 28 // 28 // 29 // 29 // John Allison 5th April 2001 30 // John Allison 5th April 2001 30 // A scene handler to dump geometry hierarchy. 31 // A scene handler to dump geometry hierarchy. 31 // Based on a provisional G4ASCIITreeGraphicsS 32 // Based on a provisional G4ASCIITreeGraphicsScene (was in modeling). 32 33 33 #include "G4ASCIITreeSceneHandler.hh" 34 #include "G4ASCIITreeSceneHandler.hh" 34 35 35 #include "G4ASCIITree.hh" 36 #include "G4ASCIITree.hh" 36 #include "G4ASCIITreeMessenger.hh" 37 #include "G4ASCIITreeMessenger.hh" 37 #include "G4VSolid.hh" 38 #include "G4VSolid.hh" 38 #include "G4PhysicalVolumeModel.hh" 39 #include "G4PhysicalVolumeModel.hh" 39 #include "G4VPhysicalVolume.hh" 40 #include "G4VPhysicalVolume.hh" 40 #include "G4LogicalVolume.hh" 41 #include "G4LogicalVolume.hh" 41 #include "G4VPVParameterisation.hh" 42 #include "G4VPVParameterisation.hh" 42 #include "G4Polyhedron.hh" 43 #include "G4Polyhedron.hh" 43 #include "G4UnitsTable.hh" 44 #include "G4UnitsTable.hh" 44 #include "G4Material.hh" 45 #include "G4Material.hh" 45 #include "G4Scene.hh" 46 #include "G4Scene.hh" 46 #include "G4ModelingParameters.hh" 47 #include "G4ModelingParameters.hh" 47 #include "G4PhysicalVolumeMassScene.hh" 48 #include "G4PhysicalVolumeMassScene.hh" 48 #include "G4VSensitiveDetector.hh" 49 #include "G4VSensitiveDetector.hh" 49 #include "G4VReadOutGeometry.hh" 50 #include "G4VReadOutGeometry.hh" 50 #include "G4TransportationManager.hh" 51 #include "G4TransportationManager.hh" 51 #include "G4AttCheck.hh" << 52 #include "G4AttValue.hh" << 53 52 54 G4ASCIITreeSceneHandler::G4ASCIITreeSceneHandl 53 G4ASCIITreeSceneHandler::G4ASCIITreeSceneHandler 55 (G4VGraphicsSystem& system, 54 (G4VGraphicsSystem& system, 56 const G4String& name): 55 const G4String& name): 57 G4VTreeSceneHandler(system, name), 56 G4VTreeSceneHandler(system, name), 58 fpOutFile(0), 57 fpOutFile(0), 59 fpLastPV(0), 58 fpLastPV(0), 60 fLastCopyNo(-99), 59 fLastCopyNo(-99), 61 fLastNonSequentialCopyNo(-99) 60 fLastNonSequentialCopyNo(-99) 62 {} 61 {} 63 62 64 G4ASCIITreeSceneHandler::~G4ASCIITreeSceneHand 63 G4ASCIITreeSceneHandler::~G4ASCIITreeSceneHandler () {} 65 64 66 void G4ASCIITreeSceneHandler::BeginModeling () 65 void G4ASCIITreeSceneHandler::BeginModeling () { 67 66 68 G4VTreeSceneHandler::BeginModeling (); // T 67 G4VTreeSceneHandler::BeginModeling (); // To re-use "culling off" code. 69 68 70 const G4ASCIITree* pSystem = (G4ASCIITree*)G 69 const G4ASCIITree* pSystem = (G4ASCIITree*)GetGraphicsSystem(); 71 const G4String& outFileName = pSystem -> Get 70 const G4String& outFileName = pSystem -> GetOutFileName(); 72 if (outFileName == "G4cout") { 71 if (outFileName == "G4cout") { 73 fpOutFile = &G4cout; 72 fpOutFile = &G4cout; 74 } else { 73 } else { 75 fOutFile.open (outFileName); 74 fOutFile.open (outFileName); 76 fpOutFile = &fOutFile; 75 fpOutFile = &fOutFile; 77 } 76 } 78 77 79 static G4bool firstTime = true; << 78 G4cout << "G4ASCIITreeSceneHandler::BeginModeling: writing to "; 80 if (firstTime) { << 79 if (outFileName == "G4cout") { 81 firstTime = false; << 80 G4cout << "G4 standard output (G4cout)"; 82 G4cout << "G4ASCIITreeSceneHandler::BeginM << 81 } else { 83 if (outFileName == "G4cout") { << 82 G4cout << "file \"" << outFileName << "\""; 84 G4cout << "G4 standard output (G4cout)"; << 85 } else { << 86 G4cout << "file \"" << outFileName << "\ << 87 } << 88 G4cout << G4endl; << 89 << 90 WriteHeader (G4cout); G4cout << G4endl; << 91 } 83 } 92 << 84 G4cout << G4endl; >> 85 >> 86 WriteHeader (G4cout); G4cout << G4endl; 93 if (outFileName != "G4cout") { 87 if (outFileName != "G4cout") { 94 WriteHeader (fOutFile); fOutFile << std::e 88 WriteHeader (fOutFile); fOutFile << std::endl; 95 } 89 } 96 } 90 } 97 91 98 void G4ASCIITreeSceneHandler::WriteHeader (std 92 void G4ASCIITreeSceneHandler::WriteHeader (std::ostream& os) 99 { 93 { 100 const G4ASCIITree* pSystem = (G4ASCIITree*)G 94 const G4ASCIITree* pSystem = (G4ASCIITree*)GetGraphicsSystem(); 101 const G4int verbosity = pSystem->GetVerbosit 95 const G4int verbosity = pSystem->GetVerbosity(); 102 const G4int detail = verbosity % 10; 96 const G4int detail = verbosity % 10; 103 os << "# Set verbosity with \"/vis/ASCIITre 97 os << "# Set verbosity with \"/vis/ASCIITree/verbose <verbosity>\":"; 104 for (size_t i = 0; 98 for (size_t i = 0; 105 i < G4ASCIITreeMessenger::fVerbosityGui 99 i < G4ASCIITreeMessenger::fVerbosityGuidance.size(); ++i) { 106 os << "\n# " << G4ASCIITreeMessenger::fVe 100 os << "\n# " << G4ASCIITreeMessenger::fVerbosityGuidance[i]; 107 } 101 } 108 os << "\n# Now printing with verbosity " << 102 os << "\n# Now printing with verbosity " << verbosity; 109 os << "\n# Format is: PV:n"; 103 os << "\n# Format is: PV:n"; 110 if (detail >= 1) os << " / LV (SD,RO)"; 104 if (detail >= 1) os << " / LV (SD,RO)"; 111 if (detail >= 2) os << " / Solid(type)"; 105 if (detail >= 2) os << " / Solid(type)"; 112 if (detail >= 3) os << ", volume, density"; 106 if (detail >= 3) os << ", volume, density"; 113 if (detail >= 5) os << ", daughter-subtracte 107 if (detail >= 5) os << ", daughter-subtracted volume and mass"; 114 if (detail >= 6) os << ", physical volume du << 115 if (detail >= 7) os << ", polyhedron dump"; << 116 os << 108 os << 117 "\n# Abbreviations: PV = Physical Volume, 109 "\n# Abbreviations: PV = Physical Volume, LV = Logical Volume," 118 "\n# SD = Sensitive Detect 110 "\n# SD = Sensitive Detector, RO = Read Out Geometry."; 119 } 111 } 120 112 121 void G4ASCIITreeSceneHandler::EndModeling () { 113 void G4ASCIITreeSceneHandler::EndModeling () { 122 const G4ASCIITree* pSystem = (G4ASCIITree*) 114 const G4ASCIITree* pSystem = (G4ASCIITree*) GetGraphicsSystem(); 123 const G4int verbosity = pSystem->GetVerbosit 115 const G4int verbosity = pSystem->GetVerbosity(); 124 const G4int detail = verbosity % 10; 116 const G4int detail = verbosity % 10; 125 const G4String& outFileName = pSystem -> Get 117 const G4String& outFileName = pSystem -> GetOutFileName(); 126 118 127 // Output left over copy number, if any... 119 // Output left over copy number, if any... 128 if (fLastCopyNo != fLastNonSequentialCopyNo) 120 if (fLastCopyNo != fLastNonSequentialCopyNo) { 129 if (fLastCopyNo == fLastNonSequentialCopyN 121 if (fLastCopyNo == fLastNonSequentialCopyNo + 1) *fpOutFile << ','; 130 else *fpOutFile << '-'; 122 else *fpOutFile << '-'; 131 *fpOutFile << fLastCopyNo; 123 *fpOutFile << fLastCopyNo; 132 } 124 } 133 // Output outstanding rest of line, if any.. 125 // Output outstanding rest of line, if any... 134 if (!fRestOfLine.str().empty()) *fpOutFile < 126 if (!fRestOfLine.str().empty()) *fpOutFile << fRestOfLine.str(); 135 fRestOfLine.str(""); 127 fRestOfLine.str(""); 136 fpLastPV = 0; 128 fpLastPV = 0; 137 fLastPVName.clear(); 129 fLastPVName.clear(); 138 fLastCopyNo = -99; 130 fLastCopyNo = -99; 139 fLastNonSequentialCopyNo = -99; 131 fLastNonSequentialCopyNo = -99; 140 132 141 // This detail to G4cout regardless of outFi 133 // This detail to G4cout regardless of outFileName... 142 if (detail >= 4) { 134 if (detail >= 4) { 143 G4cout << "Calculating mass(es)..." << G4e 135 G4cout << "Calculating mass(es)..." << G4endl; 144 const std::vector<G4Scene::Model>& models 136 const std::vector<G4Scene::Model>& models = fpScene->GetRunDurationModelList(); 145 std::vector<G4Scene::Model>::const_iterato 137 std::vector<G4Scene::Model>::const_iterator i; 146 for (i = models.begin(); i != models.end() 138 for (i = models.begin(); i != models.end(); ++i) { 147 G4PhysicalVolumeModel* pvModel = 139 G4PhysicalVolumeModel* pvModel = 148 dynamic_cast<G4PhysicalVolumeModel*>(i->fpMo 140 dynamic_cast<G4PhysicalVolumeModel*>(i->fpModel); 149 if (pvModel) { 141 if (pvModel) { 150 const G4ModelingParameters* tempMP = << 142 if (pvModel->GetTopPhysicalVolume() == 151 pvModel->GetModelingParameters(); << 143 G4TransportationManager::GetTransportationManager() 152 G4ModelingParameters mp; // Default - << 144 ->GetNavigatorForTracking()->GetWorldVolume()) { 153 pvModel->SetModelingParameters (&mp); << 145 const G4ModelingParameters* tempMP = 154 G4PhysicalVolumeMassScene massScene(pv << 146 pvModel->GetModelingParameters(); 155 pvModel->DescribeYourselfTo (massScene << 147 G4ModelingParameters mp; // Default - no culling. 156 G4double volume = massScene.GetVolume( << 148 pvModel->SetModelingParameters (&mp); 157 G4double mass = massScene.GetMass(); << 149 G4PhysicalVolumeMassScene massScene(pvModel); 158 << 150 pvModel->DescribeYourselfTo (massScene); 159 G4cout << "Overall volume of \"" << 151 G4double volume = massScene.GetVolume(); 160 << pvModel->GetTopPhysicalVolume()->Ge << 152 G4double mass = massScene.GetMass(); 161 << "\":" << 153 162 << pvModel->GetTopPhysicalVolume()->Ge << 154 G4cout << "Overall volume of \"" 163 << ", is " << 155 << pvModel->GetTopPhysicalVolume()->GetName() 164 << G4BestUnit (volume, "Volume") << 156 << "\":" 165 << " and the daughter-included mass"; << 157 << pvModel->GetTopPhysicalVolume()->GetCopyNo() 166 G4int requestedDepth = pvModel->GetReq << 158 << ", is " 167 if (requestedDepth == G4PhysicalVolume << 159 << G4BestUnit (volume, "Volume") 168 G4cout << " to unlimited depth"; << 160 << " and the daughter-included mass"; 169 } else { << 161 G4int requestedDepth = pvModel->GetRequestedDepth(); 170 G4cout << ", ignoring daughters at d << 162 if (requestedDepth == G4PhysicalVolumeModel::UNLIMITED) { 171 << requestedDepth << 163 G4cout << " to unlimited depth"; 172 << " and below,"; << 164 } else { 173 } << 165 G4cout << ", ignoring daughters at depth " 174 G4cout << " is " << G4BestUnit (mass, << 166 << requestedDepth 175 << G4endl; << 167 << " and below,"; 176 << 168 } 177 pvModel->SetModelingParameters (tempMP << 169 G4cout << " is " << G4BestUnit (mass, "Mass") >> 170 << G4endl; >> 171 >> 172 pvModel->SetModelingParameters (tempMP); >> 173 } 178 } 174 } 179 } 175 } 180 } 176 } 181 177 182 if (outFileName != "G4cout") { 178 if (outFileName != "G4cout") { 183 fOutFile.close(); 179 fOutFile.close(); 184 G4cout << "Output file \"" << outFileName 180 G4cout << "Output file \"" << outFileName << "\" closed." << G4endl; 185 } 181 } 186 fLVSet.clear(); 182 fLVSet.clear(); 187 fReplicaSet.clear(); 183 fReplicaSet.clear(); 188 G4cout << "G4ASCIITreeSceneHandler::EndModel 184 G4cout << "G4ASCIITreeSceneHandler::EndModeling" << G4endl; 189 G4VTreeSceneHandler::EndModeling (); // To 185 G4VTreeSceneHandler::EndModeling (); // To re-use "culling off" code. 190 } 186 } 191 187 192 void G4ASCIITreeSceneHandler::RequestPrimitive 188 void G4ASCIITreeSceneHandler::RequestPrimitives(const G4VSolid& solid) { 193 189 194 G4PhysicalVolumeModel* pPVModel = 190 G4PhysicalVolumeModel* pPVModel = 195 dynamic_cast<G4PhysicalVolumeModel*>(fpMod 191 dynamic_cast<G4PhysicalVolumeModel*>(fpModel); 196 if (!pPVModel) return; // Not from a G4Phys 192 if (!pPVModel) return; // Not from a G4PhysicalVolumeModel. 197 193 198 // This call comes from a G4PhysicalVolumeMo 194 // This call comes from a G4PhysicalVolumeModel. drawnPVPath is 199 // the path of the current drawn (non-culled 195 // the path of the current drawn (non-culled) volume in terms of 200 // drawn (non-culled) ancestors. Each node << 196 // drawn (non-culled) ancesters. Each node is identified by a 201 // PVNodeID object, which is a physical volu 197 // PVNodeID object, which is a physical volume and copy number. It 202 // is a vector of PVNodeIDs corresponding to 198 // is a vector of PVNodeIDs corresponding to the geometry hierarchy 203 // actually selected, i.e., not culled. 199 // actually selected, i.e., not culled. 204 // The following typedef's already set in he 200 // The following typedef's already set in header file... 205 //typedef G4PhysicalVolumeModel::G4PhysicalV 201 //typedef G4PhysicalVolumeModel::G4PhysicalVolumeNodeID PVNodeID; 206 //typedef std::vector<PVNodeID> PVPath; 202 //typedef std::vector<PVNodeID> PVPath; 207 const PVPath& drawnPVPath = pPVModel->GetDra 203 const PVPath& drawnPVPath = pPVModel->GetDrawnPVPath(); 208 //G4int currentDepth = pPVModel->GetCurrentD 204 //G4int currentDepth = pPVModel->GetCurrentDepth(); 209 G4VPhysicalVolume* pCurrentPV = pPVModel->Ge 205 G4VPhysicalVolume* pCurrentPV = pPVModel->GetCurrentPV(); 210 const G4String& currentPVName = pCurrentPV-> << 211 const G4int currentCopyNo = pCurrentPV->GetC << 212 G4LogicalVolume* pCurrentLV = pPVModel->GetC 206 G4LogicalVolume* pCurrentLV = pPVModel->GetCurrentLV(); 213 G4Material* pCurrentMaterial = pPVModel->Get 207 G4Material* pCurrentMaterial = pPVModel->GetCurrentMaterial(); 214 208 215 G4ASCIITree* pSystem = (G4ASCIITree*)GetGrap 209 G4ASCIITree* pSystem = (G4ASCIITree*)GetGraphicsSystem(); 216 G4int verbosity = pSystem->GetVerbosity(); 210 G4int verbosity = pSystem->GetVerbosity(); 217 G4int detail = verbosity % 10; 211 G4int detail = verbosity % 10; 218 212 219 // If verbosity < 10 suppress unnecessary re << 213 if (verbosity < 10 && pCurrentPV->IsReplicated()) { 220 // Repeated simple replicas can always be su << 214 // See if this has been a replica found before with same mother LV... 221 // Paramaterisations can only be suppressed << 222 // size, density, etc., are in principle dif << 223 const G4bool isParameterised = pCurrentPV->G << 224 const G4bool isSimpleReplica = pCurrentPV->I << 225 const G4bool isAmenableToSupression = << 226 (verbosity < 10 && isSimpleReplica) || (verb << 227 if (isAmenableToSupression) { << 228 // See if this has been found before with << 229 PVPath::const_reverse_iterator thisID = dr 215 PVPath::const_reverse_iterator thisID = drawnPVPath.rbegin(); 230 PVPath::const_reverse_iterator motherID = 216 PVPath::const_reverse_iterator motherID = ++drawnPVPath.rbegin(); 231 G4bool ignore = false; 217 G4bool ignore = false; 232 for (ReplicaSetIterator i = fReplicaSet.be 218 for (ReplicaSetIterator i = fReplicaSet.begin(); i != fReplicaSet.end(); 233 ++i) { << 219 ++i) { 234 if (i->back().GetPhysicalVolume()->GetLo 220 if (i->back().GetPhysicalVolume()->GetLogicalVolume() == 235 thisID->GetPhysicalVolume()->GetLogi << 221 thisID->GetPhysicalVolume()->GetLogicalVolume()) { 236 // For each one previously found (if m << 222 // For each one previously found (if more than one, they must 237 // have different mothers)... << 223 // have different mothers)... 238 // To avoid compilation errors on VC++ << 224 // To avoid compilation errors on VC++ .Net 7.1... 239 // Previously: << 225 // Previously: 240 // PVNodeID previousMotherID = ++(i- << 226 // PVNodeID previousMotherID = ++(i->rbegin()); 241 // (Should that have been: PVNodeID::c << 227 // (Should that have been: PVNodeID::const_iterator previousMotherID?) 242 // Replace << 228 // Replace 243 // previousMotherID == i->rend() << 229 // previousMotherID == i->rend() 244 // by << 230 // by 245 // i->size() <= 1 << 231 // i->size() <= 1 246 // Replace << 232 // Replace 247 // previousMotherID != i->rend() << 233 // previousMotherID != i->rend() 248 // by << 234 // by 249 // i->size() > 1 << 235 // i->size() > 1 250 // Replace << 236 // Replace 251 // previousMotherID-> << 237 // previousMotherID-> 252 // by << 238 // by 253 // (*i)[i->size() - 2]. << 239 // (*i)[i->size() - 2]. 254 if (motherID == drawnPVPath.rend() && << 240 if (motherID == drawnPVPath.rend() && 255 i->size() <= 1) << 241 i->size() <= 1) 256 ignore = true; // Both have no moth << 242 ignore = true; // Both have no mother. 257 if (motherID != drawnPVPath.rend() && << 243 if (motherID != drawnPVPath.rend() && 258 i->size() > 1 && << 244 i->size() > 1 && 259 motherID->GetPhysicalVolume()->Get << 245 motherID->GetPhysicalVolume()->GetLogicalVolume() == 260 (*i)[i->size() - 2].GetPhysicalVol << 246 (*i)[i->size() - 2].GetPhysicalVolume()->GetLogicalVolume()) 261 ignore = true; // Same mother LV... << 247 ignore = true; // Same mother LV... 262 } 248 } 263 } 249 } 264 if (ignore) { 250 if (ignore) { 265 pPVModel->CurtailDescent(); 251 pPVModel->CurtailDescent(); 266 return; 252 return; 267 } 253 } 268 } 254 } 269 255 270 // Now suppress printing for volumes with th << 256 const G4String& currentPVName = pCurrentPV->GetName(); 271 // copy number - but not if they are paramet << 257 const G4int currentCopyNo = pCurrentPV->GetCopyNo(); 272 // taken out above (those that are "amenable << 258 273 // taken out). << 259 if (verbosity < 10 && 274 if (verbosity < 10 && !isParameterised && << 275 currentPVName == fLastPVName && 260 currentPVName == fLastPVName && 276 currentCopyNo != fLastCopyNo) { 261 currentCopyNo != fLastCopyNo) { >> 262 // For low verbosity, trap series of G4PVPlacements with the same name but >> 263 // different copy number (replicas should have been taken out above)... 277 // Check... 264 // Check... 278 if (isAmenableToSupression) { << 265 if (pCurrentPV->IsReplicated()) { 279 G4Exception("G4ASCIITreeSceneHandler::Re 266 G4Exception("G4ASCIITreeSceneHandler::RequestPrimitives", 280 "vistree0001", 267 "vistree0001", 281 JustWarning, 268 JustWarning, 282 "Volume amenable to suppressed printing << 269 "Replica unexpected"); 283 } 270 } 284 // Check mothers are identical... 271 // Check mothers are identical... 285 else if (pCurrentLV == (fpLastPV? fpLastPV 272 else if (pCurrentLV == (fpLastPV? fpLastPV->GetLogicalVolume(): 0)) { 286 if (currentCopyNo != fLastCopyNo + 1) { 273 if (currentCopyNo != fLastCopyNo + 1) { 287 // Non-sequential copy number... 274 // Non-sequential copy number... 288 *fpOutFile << ',' << currentCopyNo; 275 *fpOutFile << ',' << currentCopyNo; 289 fLastNonSequentialCopyNo = currentCopyNo; 276 fLastNonSequentialCopyNo = currentCopyNo; 290 } 277 } 291 fLastCopyNo = currentCopyNo; 278 fLastCopyNo = currentCopyNo; 292 pPVModel->CurtailDescent(); 279 pPVModel->CurtailDescent(); 293 return; 280 return; 294 } 281 } 295 } 282 } 296 fpLastPV = pCurrentPV; 283 fpLastPV = pCurrentPV; 297 284 298 // High verbosity or a new or otherwise non- << 285 // High verbosity or a new G4VPhysicalVolume... 299 // Output copy number, if any, from previous 286 // Output copy number, if any, from previous invocation... 300 if (fLastCopyNo != fLastNonSequentialCopyNo) 287 if (fLastCopyNo != fLastNonSequentialCopyNo) { 301 if (fLastCopyNo == fLastNonSequentialCopyN 288 if (fLastCopyNo == fLastNonSequentialCopyNo + 1) *fpOutFile << ','; 302 else *fpOutFile << '-'; 289 else *fpOutFile << '-'; 303 *fpOutFile << fLastCopyNo; 290 *fpOutFile << fLastCopyNo; 304 } 291 } 305 // Output rest of line, if any, from previou 292 // Output rest of line, if any, from previous invocation... 306 if (!fRestOfLine.str().empty()) *fpOutFile < 293 if (!fRestOfLine.str().empty()) *fpOutFile << fRestOfLine.str(); 307 fRestOfLine.str(""); 294 fRestOfLine.str(""); 308 fLastPVName = currentPVName; 295 fLastPVName = currentPVName; 309 fLastCopyNo = currentCopyNo; 296 fLastCopyNo = currentCopyNo; 310 fLastNonSequentialCopyNo = currentCopyNo; 297 fLastNonSequentialCopyNo = currentCopyNo; 311 // Start next line... << 312 // Indent according to drawn path depth... 298 // Indent according to drawn path depth... 313 for (size_t i = 0; i < drawnPVPath.size(); i 299 for (size_t i = 0; i < drawnPVPath.size(); i++ ) *fpOutFile << " "; >> 300 // Start next line... 314 *fpOutFile << "\"" << currentPVName 301 *fpOutFile << "\"" << currentPVName 315 << "\":" << currentCopyNo; 302 << "\":" << currentCopyNo; 316 303 317 if (pCurrentPV->IsReplicated()) { 304 if (pCurrentPV->IsReplicated()) { 318 if (verbosity < 10) { 305 if (verbosity < 10) { 319 // Add printing for replicas (when repli 306 // Add printing for replicas (when replicas are ignored)... 320 EAxis axis; 307 EAxis axis; 321 G4int nReplicas; 308 G4int nReplicas; 322 G4double width; 309 G4double width; 323 G4double offset; 310 G4double offset; 324 G4bool consuming; 311 G4bool consuming; 325 pCurrentPV->GetReplicationData(axis,nRep 312 pCurrentPV->GetReplicationData(axis,nReplicas,width,offset,consuming); 326 G4VPVParameterisation* pP = pCurrentPV-> 313 G4VPVParameterisation* pP = pCurrentPV->GetParameterisation(); 327 if (pP) { 314 if (pP) { 328 if (detail < 3) { 315 if (detail < 3) { 329 fReplicaSet.insert(drawnPVPath); 316 fReplicaSet.insert(drawnPVPath); 330 if (nReplicas > 2) fRestOfLine << '-'; 317 if (nReplicas > 2) fRestOfLine << '-'; 331 else fRestOfLine << ','; 318 else fRestOfLine << ','; 332 fRestOfLine << nReplicas - 1 319 fRestOfLine << nReplicas - 1 333 << " (" << nReplicas << " parametris 320 << " (" << nReplicas << " parametrised volumes)"; 334 } 321 } 335 } 322 } 336 else { 323 else { 337 fReplicaSet.insert(drawnPVPath); 324 fReplicaSet.insert(drawnPVPath); 338 if (nReplicas > 2) fRestOfLine << '-'; 325 if (nReplicas > 2) fRestOfLine << '-'; 339 else fRestOfLine << ','; 326 else fRestOfLine << ','; 340 fRestOfLine << nReplicas - 1 327 fRestOfLine << nReplicas - 1 341 << " (" << nReplicas << " replicas)"; 328 << " (" << nReplicas << " replicas)"; 342 } 329 } 343 } 330 } 344 } else { 331 } else { 345 if (fLVSet.find(pCurrentLV) != fLVSet.end( 332 if (fLVSet.find(pCurrentLV) != fLVSet.end()) { 346 if (verbosity < 10) { 333 if (verbosity < 10) { 347 // Add printing for repeated LV (if it has d 334 // Add printing for repeated LV (if it has daughters)... 348 if (pCurrentLV->GetNoDaughters()) fRestOfLin 335 if (pCurrentLV->GetNoDaughters()) fRestOfLine << " (repeated LV)"; 349 // ...and curtail descent. 336 // ...and curtail descent. 350 pPVModel->CurtailDescent(); 337 pPVModel->CurtailDescent(); 351 } 338 } 352 } 339 } 353 } 340 } 354 341 355 if (detail >= 1) { 342 if (detail >= 1) { 356 fRestOfLine << " / \"" 343 fRestOfLine << " / \"" 357 << pCurrentLV->GetName() << "\""; 344 << pCurrentLV->GetName() << "\""; 358 G4VSensitiveDetector* sd = pCurrentLV->Get 345 G4VSensitiveDetector* sd = pCurrentLV->GetSensitiveDetector(); 359 if (sd) { 346 if (sd) { 360 fRestOfLine << " (SD=\"" << sd->GetName( 347 fRestOfLine << " (SD=\"" << sd->GetName() << "\""; 361 G4VReadOutGeometry* roGeom = sd->GetROge 348 G4VReadOutGeometry* roGeom = sd->GetROgeometry(); 362 if (roGeom) { 349 if (roGeom) { 363 fRestOfLine << ",RO=\"" << roGeom->GetName() 350 fRestOfLine << ",RO=\"" << roGeom->GetName() << "\""; 364 } 351 } 365 fRestOfLine << ")"; 352 fRestOfLine << ")"; 366 } 353 } 367 } 354 } 368 355 369 if (detail >= 2) { 356 if (detail >= 2) { 370 fRestOfLine << " / \"" 357 fRestOfLine << " / \"" 371 << solid.GetName() 358 << solid.GetName() 372 << "\"(" 359 << "\"(" 373 << solid.GetEntityType() << ")"; 360 << solid.GetEntityType() << ")"; 374 } 361 } 375 362 376 if (detail >= 3) { 363 if (detail >= 3) { 377 fRestOfLine << ", " 364 fRestOfLine << ", " 378 << G4BestUnit(((G4VSolid&)solid).GetCubicV 365 << G4BestUnit(((G4VSolid&)solid).GetCubicVolume(),"Volume") 379 << ", "; 366 << ", "; 380 if (pCurrentMaterial) { 367 if (pCurrentMaterial) { 381 fRestOfLine 368 fRestOfLine 382 << G4BestUnit(pCurrentMaterial->GetDensity() 369 << G4BestUnit(pCurrentMaterial->GetDensity(), "Volumic Mass") 383 << " (" << pCurrentMaterial->GetName() << ") 370 << " (" << pCurrentMaterial->GetName() << ")"; 384 } else { 371 } else { 385 fRestOfLine << "(No material)"; 372 fRestOfLine << "(No material)"; 386 } 373 } 387 } 374 } 388 375 389 if (detail >= 5) { 376 if (detail >= 5) { 390 if (pCurrentMaterial) { 377 if (pCurrentMaterial) { 391 G4Material* pMaterial = const_cast<G4Mat 378 G4Material* pMaterial = const_cast<G4Material*>(pCurrentMaterial); 392 // ...and find daughter-subtracted mass. 379 // ...and find daughter-subtracted mass... 393 G4double daughter_subtracted_mass = pCur 380 G4double daughter_subtracted_mass = pCurrentLV->GetMass 394 (pCurrentPV->IsParameterised(), // Force if 381 (pCurrentPV->IsParameterised(), // Force if parametrised. 395 false, // Do not propagate - calculate for 382 false, // Do not propagate - calculate for this volume minus 396 // volume of daughters. 383 // volume of daughters. 397 pMaterial); 384 pMaterial); 398 G4double daughter_subtracted_volume = 385 G4double daughter_subtracted_volume = 399 daughter_subtracted_mass / pCurrentMaterial- 386 daughter_subtracted_mass / pCurrentMaterial->GetDensity(); 400 fRestOfLine << ", " 387 fRestOfLine << ", " 401 << G4BestUnit(daughter_subtracted_volume 388 << G4BestUnit(daughter_subtracted_volume,"Volume") 402 << ", " 389 << ", " 403 << G4BestUnit(daughter_subtracted_mass," 390 << G4BestUnit(daughter_subtracted_mass,"Mass"); 404 } 391 } 405 } << 406 << 407 if (detail >= 6) { << 408 std::vector<G4AttValue>* attValues = pPVMo << 409 const std::map<G4String,G4AttDef>* attDefs << 410 fRestOfLine << '\n' << G4AttCheck(attValue << 411 delete attValues; << 412 } << 413 << 414 if (detail >= 7) { << 415 G4Polyhedron* polyhedron = solid.GetPolyhe << 416 fRestOfLine << "\nLocal polyhedron coordin << 417 const G4Transform3D& transform = pPVModel- << 418 polyhedron->Transform(transform); << 419 fRestOfLine << "\nGlobal polyhedron coordi << 420 } 392 } 421 393 422 if (fLVSet.find(pCurrentLV) == fLVSet.end()) 394 if (fLVSet.find(pCurrentLV) == fLVSet.end()) { 423 fLVSet.insert(pCurrentLV); // Record new 395 fLVSet.insert(pCurrentLV); // Record new logical volume. 424 } 396 } 425 397 426 fRestOfLine << std::endl; 398 fRestOfLine << std::endl; 427 399 428 return; 400 return; 429 } 401 } 430 402