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Geant4/examples/advanced/hadrontherapy/src/HadrontherapyDetectorConstruction.cc

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Differences between /examples/advanced/hadrontherapy/src/HadrontherapyDetectorConstruction.cc (Version 11.3.0) and /examples/advanced/hadrontherapy/src/HadrontherapyDetectorConstruction.cc (Version 10.0.p1)


  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 *
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 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 // Hadrontherapy advanced example for Geant4   <<  26 // This is the *BASIC* version of Hadrontherapy, a Geant4-based application
 27 // See more at: https://twiki.cern.ch/twiki/bi <<  27 // See more at: http://g4advancedexamples.lngs.infn.it/Examples/hadrontherapy
                                                   >>  28 //
                                                   >>  29 // Visit the Hadrontherapy web site (http://www.lns.infn.it/link/Hadrontherapy) to request 
                                                   >>  30 // the *COMPLETE* version of this program, together with its documentation;
                                                   >>  31 // Hadrontherapy (both basic and full version) are supported by the Italian INFN
                                                   >>  32 // Institute in the framework of the MC-INFN Group
                                                   >>  33 //
                                                   >>  34 
 28                                                    35 
 29 #include "G4UnitsTable.hh"                         36 #include "G4UnitsTable.hh"
 30 #include "G4SDManager.hh"                          37 #include "G4SDManager.hh"
 31 #include "G4RunManager.hh"                         38 #include "G4RunManager.hh"
 32 #include "G4GeometryManager.hh"                    39 #include "G4GeometryManager.hh"
 33 #include "G4SolidStore.hh"                         40 #include "G4SolidStore.hh"
 34 #include "G4PhysicalVolumeStore.hh"                41 #include "G4PhysicalVolumeStore.hh"
 35 #include "G4LogicalVolumeStore.hh"                 42 #include "G4LogicalVolumeStore.hh"
 36 #include "G4Box.hh"                                43 #include "G4Box.hh"
 37 #include "G4LogicalVolume.hh"                      44 #include "G4LogicalVolume.hh"
 38 #include "G4ThreeVector.hh"                        45 #include "G4ThreeVector.hh"
 39 #include "G4PVPlacement.hh"                        46 #include "G4PVPlacement.hh"
 40 #include "globals.hh"                              47 #include "globals.hh"
 41 #include "G4Transform3D.hh"                        48 #include "G4Transform3D.hh"
 42 #include "G4RotationMatrix.hh"                     49 #include "G4RotationMatrix.hh"
 43 #include "G4Colour.hh"                             50 #include "G4Colour.hh"
 44 #include "G4UserLimits.hh"                         51 #include "G4UserLimits.hh"
 45 #include "G4UnitsTable.hh"                         52 #include "G4UnitsTable.hh"
 46 #include "G4VisAttributes.hh"                      53 #include "G4VisAttributes.hh"
 47 #include "G4NistManager.hh"                        54 #include "G4NistManager.hh"
                                                   >>  55 
 48 #include "HadrontherapyDetectorConstruction.hh     56 #include "HadrontherapyDetectorConstruction.hh"
 49 #include "HadrontherapyDetectorROGeometry.hh"      57 #include "HadrontherapyDetectorROGeometry.hh"
 50 #include "HadrontherapyDetectorMessenger.hh"       58 #include "HadrontherapyDetectorMessenger.hh"
 51 #include "HadrontherapyDetectorSD.hh"              59 #include "HadrontherapyDetectorSD.hh"
 52 #include "HadrontherapyMatrix.hh"                  60 #include "HadrontherapyMatrix.hh"
 53 #include "HadrontherapyLet.hh"                     61 #include "HadrontherapyLet.hh"
 54 #include "PassiveProtonBeamLine.hh"                62 #include "PassiveProtonBeamLine.hh"
 55 #include "BESTPassiveProtonBeamLine.hh"        <<  63 #include "HadrontherapyAnalysisManager.hh"
 56 #include "HadrontherapyMatrix.hh"              << 
 57                                                << 
 58 #include "HadrontherapyRBE.hh"                 << 
 59 #include "G4SystemOfUnits.hh"                      64 #include "G4SystemOfUnits.hh"
 60                                                    65 
 61 #include <cmath>                                   66 #include <cmath>
 62                                                    67 
 63                                                << 
 64                                                << 
 65 HadrontherapyDetectorConstruction* Hadronthera     68 HadrontherapyDetectorConstruction* HadrontherapyDetectorConstruction::instance = 0;
 66 //////////////////////////////////////////////     69 /////////////////////////////////////////////////////////////////////////////
 67 HadrontherapyDetectorConstruction::Hadronthera     70 HadrontherapyDetectorConstruction::HadrontherapyDetectorConstruction(G4VPhysicalVolume* physicalTreatmentRoom)
 68 : motherPhys(physicalTreatmentRoom), // pointe <<  71   : motherPhys(physicalTreatmentRoom), // pointer to WORLD volume 
 69 detectorSD(0), detectorROGeometry(0), matrix(0 <<  72     detectorSD(0), detectorROGeometry(0), matrix(0), 
 70 phantom(0), detector(0),                       <<  73     phantom(0), detector(0),
 71 phantomLogicalVolume(0), detectorLogicalVolume <<  74     phantomLogicalVolume(0), detectorLogicalVolume(0), 
 72 phantomPhysicalVolume(0), detectorPhysicalVolu <<  75     phantomPhysicalVolume(0), detectorPhysicalVolume(0),
 73 aRegion(0)                                     <<  76     aRegion(0)
 74 {                                              <<  77 {
 75                                                <<  78   HadrontherapyAnalysisManager::GetInstance();
 76                                                <<  79 
 77     /* NOTE! that the HadrontherapyDetectorCon <<  80   /* NOTE! that the HadrontherapyDetectorConstruction class
 78      * does NOT inherit from G4VUserDetectorCo <<  81    * does NOT inherit from G4VUserDetectorConstruction G4 class
 79      * So the Construct() mandatory virtual me <<  82    * So the Construct() mandatory virtual method is inside another geometric class
 80      * like the passiveProtonBeamLIne, ...     <<  83    * like the passiveProtonBeamLIne, ...
 81      */                                        <<  84    */
 82                                                <<  85 
 83     // Messenger to change parameters of the p <<  86   // Messenger to change parameters of the phantom/detector geometry
 84     detectorMessenger = new HadrontherapyDetec <<  87   detectorMessenger = new HadrontherapyDetectorMessenger(this);
 85                                                <<  88 
 86     // Default detector voxels size            <<  89   // Default detector voxels size
 87     // 200 slabs along the beam direction (X)  <<  90   // 200 slabs along the beam direction (X)
 88     sizeOfVoxelAlongX = 200 *um;               <<  91   sizeOfVoxelAlongX = 200 *um; 
 89     sizeOfVoxelAlongY = 4 *cm;                 <<  92   sizeOfVoxelAlongY = 4 *cm; 
 90     sizeOfVoxelAlongZ = 4 *cm;                 <<  93   sizeOfVoxelAlongZ = 4 *cm; 
 91                                                <<  94 
 92     // Define here the material of the water p <<  95   // Define here the material of the water phantom and of the detector
 93     SetPhantomMaterial("G4_WATER");            <<  96   SetPhantomMaterial("G4_WATER"); 
 94     // Construct geometry (messenger commands) <<  97   // Construct geometry (messenger commands)
 95     // SetDetectorSize(4.*cm, 4.*cm, 4.*cm);   <<  98   SetDetectorSize(4.*cm, 4.*cm, 4.*cm);
 96     SetDetectorSize(4. *cm, 4. *cm, 4. *cm);   <<  99   SetPhantomSize(40. *cm, 40. *cm, 40. *cm);
 97     SetPhantomSize(40. *cm, 40. *cm, 40. *cm); << 100   SetPhantomPosition(G4ThreeVector(20. *cm, 0. *cm, 0. *cm));
 98                                                << 101   SetDetectorToPhantomPosition(G4ThreeVector(0. *cm, 18. *cm, 18. *cm));
 99     SetPhantomPosition(G4ThreeVector(20. *cm,  << 102   SetDetectorPosition();
100     SetDetectorToPhantomPosition(G4ThreeVector << 103 //GetDetectorToWorldPosition();
101     SetDetectorPosition();                     << 104 
102     //GetDetectorToWorldPosition();            << 105 
103                                                << 106   // Write virtual parameters to the real ones and check for consistency      
104     // Write virtual parameters to the real on << 107   UpdateGeometry();
105     UpdateGeometry();                          << 
106                                                << 
107                                                << 
108                                                << 
109 }                                                 108 }
110                                                   109 
111 //////////////////////////////////////////////    110 /////////////////////////////////////////////////////////////////////////////
112 HadrontherapyDetectorConstruction::~Hadronther    111 HadrontherapyDetectorConstruction::~HadrontherapyDetectorConstruction()
113 {                                              << 112 { 
114     delete detectorROGeometry;                 << 113     delete detectorROGeometry;  
115     delete matrix;                             << 114     delete matrix;  
116     delete detectorMessenger;                     115     delete detectorMessenger;
117 }                                                 116 }
118                                                   117 
119 ////////////////////////////////////////////// << 118 
120 HadrontherapyDetectorConstruction* Hadronthera    119 HadrontherapyDetectorConstruction* HadrontherapyDetectorConstruction::GetInstance()
121 {                                                 120 {
122     return instance;                           << 121 
                                                   >> 122   return instance;
123 }                                                 123 }
124                                                   124 
                                                   >> 125 
125 //////////////////////////////////////////////    126 /////////////////////////////////////////////////////////////////////////////
126 // ConstructPhantom() is the method that const << 127 // ConstructPhantom() is the method that reconstuct a water box (called phantom 
127 // (or water phantom) in the usual Medical phy << 128 // (or water phantom) in the usual Medical physicists slang). 
128 // A water phantom can be considered a good ap << 129 // A water phantom can be considered a good
                                                   >> 130 // approximation of a an human body. 
129 void HadrontherapyDetectorConstruction::Constr    131 void HadrontherapyDetectorConstruction::ConstructPhantom()
130 {                                                 132 {
131     // Definition of the solid volume of the P    133     // Definition of the solid volume of the Phantom
132     phantom = new G4Box("Phantom",             << 134     phantom = new G4Box("Phantom", 
133                         phantomSizeX/2,        << 135       phantomSizeX/2, 
134                         phantomSizeY/2,        << 136       phantomSizeY/2, 
135                         phantomSizeZ/2);       << 137       phantomSizeZ/2);
136                                                << 138     
137     // Definition of the logical volume of the << 139 // Definition of the logical volume of the Phantom
138     phantomLogicalVolume = new G4LogicalVolume << 140     phantomLogicalVolume = new G4LogicalVolume(phantom, 
139                                                << 141                phantomMaterial, 
140                                                << 142                "phantomLog", 0, 0, 0);
141                                                << 143   
142     // Definition of the physics volume of the    144     // Definition of the physics volume of the Phantom
143     phantomPhysicalVolume = new G4PVPlacement(    145     phantomPhysicalVolume = new G4PVPlacement(0,
144                                                << 146                                       phantomPosition,
145                                                << 147               "phantomPhys",
146                                                << 148               phantomLogicalVolume,
147                                                << 149               motherPhys,
148                                                << 150               false,
149                                                << 151               0);
150                                                << 152 
151     // Visualisation attributes of the phantom << 153 // Visualisation attributes of the phantom
152     red = new G4VisAttributes(G4Colour(255/255    154     red = new G4VisAttributes(G4Colour(255/255., 0/255. ,0/255.));
153     red -> SetVisibility(true);                   155     red -> SetVisibility(true);
154     red -> SetForceSolid(true);                   156     red -> SetForceSolid(true);
155     red -> SetForceWireframe(true);               157     red -> SetForceWireframe(true);
156     phantomLogicalVolume -> SetVisAttributes(r    158     phantomLogicalVolume -> SetVisAttributes(red);
157 }                                                 159 }
158                                                   160 
159 //////////////////////////////////////////////    161 /////////////////////////////////////////////////////////////////////////////
160 // ConstructDetector() is the method the recon << 162 // ConstructDetector() it the method the reconstruct a detector region 
161 // inside the water phantom. It is a volume, l << 163 // inside the water phantom. It is a volume, located inside the water phantom
                                                   >> 164 // and with two coincident faces:
162 //                                                165 //
163 //           **************************           166 //           **************************
164 //           *    water phantom       *        << 167 //           *   water phantom        *
165 //           *                        *           168 //           *                        *
166 //           *                        *           169 //           *                        *
167 //           *---------------         *           170 //           *---------------         *
168 //  Beam     *              -         *           171 //  Beam     *              -         *
169 //  ----->   * detector     -         *           172 //  ----->   * detector     -         *
170 //           *              -         *           173 //           *              -         *
171 //           *---------------         *           174 //           *---------------         *
172 //           *                        *           175 //           *                        *
173 //           *                        *           176 //           *                        *
174 //           *                        *           177 //           *                        *
175 //           **************************           178 //           **************************
176 //                                                179 //
177 // The detector can be dived in slices or voxe << 180 // The detector is the volume that can be dived in slices or voxelized
178 // and inside it different quantities (dose di << 181 // and in it we can collect a number of usefull information:
179 // can be stored.                              << 182 // dose distribution, fluence distribution, LET and so on
180 void HadrontherapyDetectorConstruction::Constr    183 void HadrontherapyDetectorConstruction::ConstructDetector()
181                                                << 
182 {                                                 184 {
                                                   >> 185 
183     // Definition of the solid volume of the D    186     // Definition of the solid volume of the Detector
184     detector = new G4Box("Detector",           << 187     detector = new G4Box("Detector", 
185                                                << 188        detectorSizeX/2, 
186                          phantomSizeX/2,       << 189        detectorSizeY/2, 
187                                                << 190        detectorSizeZ/2);
188                          phantomSizeY/2,       << 
189                                                << 
190                          phantomSizeZ/2);      << 
191                                                   191     
192     // Definition of the logic volume of the P    192     // Definition of the logic volume of the Phantom
193     detectorLogicalVolume = new G4LogicalVolum    193     detectorLogicalVolume = new G4LogicalVolume(detector,
194                                                << 194             detectorMaterial,
195                                                << 195             "DetectorLog",
196                                                << 196             0,0,0);
197     // Definition of the physical volume of th << 197 // Definition of the physical volume of the Phantom 
198     detectorPhysicalVolume = new G4PVPlacement << 198     detectorPhysicalVolume = new G4PVPlacement(0, 
199                                                << 199                  detectorPosition, // Setted by displacement 
200                                                << 200                  "DetectorPhys", 
201                                                << 201                  detectorLogicalVolume, 
202                                                << 202                  phantomPhysicalVolume, 
203                                                << 203                  false,0);
204                                                << 204 
205     // Visualisation attributes of the detecto << 205 // Visualisation attributes of the detector 
206     skyBlue = new G4VisAttributes( G4Colour(13    206     skyBlue = new G4VisAttributes( G4Colour(135/255. , 206/255. ,  235/255. ));
207     skyBlue -> SetVisibility(true);               207     skyBlue -> SetVisibility(true);
208     skyBlue -> SetForceSolid(true);               208     skyBlue -> SetForceSolid(true);
209     //skyBlue -> SetForceWireframe(true);         209     //skyBlue -> SetForceWireframe(true);
210     detectorLogicalVolume -> SetVisAttributes(    210     detectorLogicalVolume -> SetVisAttributes(skyBlue);
211                                                << 211 
212     // **************                          << 212   // **************
213     // **************                          << 213   // Cut per Region
214     // Cut per Region                          << 214   // **************
215     // **************                          << 215   
216     //                                         << 216   // A smaller cut is fixed in the phantom to calculate the energy deposit with the
217     // A smaller cut is fixed in the phantom t << 217   // required accuracy 
218     // required accuracy                       << 
219     if (!aRegion)                                 218     if (!aRegion)
220     {                                             219     {
221         aRegion = new G4Region("DetectorLog"); << 220   aRegion = new G4Region("DetectorLog");
222         detectorLogicalVolume -> SetRegion(aRe << 221   detectorLogicalVolume -> SetRegion(aRegion);
223         aRegion->AddRootLogicalVolume( detecto << 222   aRegion -> AddRootLogicalVolume(detectorLogicalVolume);
224     }                                             223     }
                                                   >> 224 
225 }                                                 225 }
226                                                   226 
                                                   >> 227 
227 //////////////////////////////////////////////    228 ///////////////////////////////////////////////////////////////////////
                                                   >> 229 
228 void HadrontherapyDetectorConstruction::Initia    230 void HadrontherapyDetectorConstruction::InitializeDetectorROGeometry(
229                                                << 231                      HadrontherapyDetectorROGeometry* RO,
230                                                << 232                      G4ThreeVector 
231                                                << 233                      detectorToWorldPosition)
232 {                                              << 234 {
233     RO->Initialize(detectorToWorldPosition,    << 235   RO->Initialize(detectorToWorldPosition,
234                    detectorSizeX/2,            << 236      detectorSizeX/2,
235                    detectorSizeY/2,            << 237      detectorSizeY/2,
236                    detectorSizeZ/2,            << 238      detectorSizeZ/2,
237                    numberOfVoxelsAlongX,       << 239      numberOfVoxelsAlongX,
238                    numberOfVoxelsAlongY,       << 240      numberOfVoxelsAlongY,
239                    numberOfVoxelsAlongZ);      << 241      numberOfVoxelsAlongZ);
240 }                                              << 
241 void HadrontherapyDetectorConstruction::Virtua << 
242 {                                              << 
243                                                << 
244     //Virtual  plane                           << 
245     VirtualLayerPosition = G4ThreeVector(0*cm, << 
246     NewSource= Varbool;                        << 
247     if(NewSource == true)                      << 
248     {                                          << 
249        // std::cout<<"trr"<<std::endl;         << 
250         G4Material* airNist =  G4NistManager:: << 
251                                                << 
252         solidVirtualLayer = new G4Box("Virtual << 
253                                       1.*um,   << 
254                                       20.*cm,  << 
255                                       40.*cm); << 
256                                                << 
257         logicVirtualLayer = new G4LogicalVolum << 
258                                                << 
259                                                << 
260                                                << 
261                                                << 
262         physVirtualLayer= new G4PVPlacement(0, << 
263                                             "V << 
264                                             lo << 
265                                             mo << 
266                                             fa << 
267                                             0) << 
268                                                << 
269         logicVirtualLayer -> SetVisAttributes( << 
270     }                                          << 
271                                                << 
272                                                << 
273                                                << 
274                                                << 
275 }                                                 242 }
276                                                   243 
277                                                   244 
278 ////////////////////////////////////////////// << 245 
                                                   >> 246 
                                                   >> 247 
                                                   >> 248 /////////////////////////////////////////////////////////
                                                   >> 249 
279 void  HadrontherapyDetectorConstruction::Param    250 void  HadrontherapyDetectorConstruction::ParametersCheck()
280 {                                                 251 {
281     // Check phantom/detector sizes & relative    252     // Check phantom/detector sizes & relative position
282     if (!IsInside(detectorSizeX,               << 253     if (!IsInside(detectorSizeX, 
283                   detectorSizeY,               << 254     detectorSizeY, 
284                   detectorSizeZ,               << 255     detectorSizeZ,
285                   phantomSizeX,                << 256     phantomSizeX,
286                   phantomSizeY,                << 257     phantomSizeY,
287                   phantomSizeZ,                << 258     phantomSizeZ,
288                   detectorToPhantomPosition    << 259     detectorToPhantomPosition
289                   ))                           << 260     ))
290         G4Exception("HadrontherapyDetectorCons << 261       G4Exception("HadrontherapyDetectorConstruction::ParametersCheck()", "Hadrontherapy0001", FatalException, "Error: Detector is not fully inside Phantom!");
291                                                << 262 
292     // Check Detector sizes respect to the vox    263     // Check Detector sizes respect to the voxel ones
293                                                << 264 
294     if ( detectorSizeX < sizeOfVoxelAlongX) {     265     if ( detectorSizeX < sizeOfVoxelAlongX) {
295         G4Exception("HadrontherapyDetectorCons << 266       G4Exception("HadrontherapyDetectorConstruction::ParametersCheck()", "Hadrontherapy0002", FatalException, "Error:  Detector X size must be bigger or equal than that of Voxel X!");
296     }                                             267     }
297     if ( detectorSizeY < sizeOfVoxelAlongY) {     268     if ( detectorSizeY < sizeOfVoxelAlongY) {
298         G4Exception(" HadrontherapyDetectorCon << 269       G4Exception(" HadrontherapyDetectorConstruction::ParametersCheck()", "Hadrontherapy0003", FatalException, "Error:  Detector Y size must be bigger or equal than that of Voxel Y!");
299     }                                             270     }
300     if ( detectorSizeZ < sizeOfVoxelAlongZ) {     271     if ( detectorSizeZ < sizeOfVoxelAlongZ) {
301         G4Exception(" HadrontherapyDetectorCon << 272       G4Exception(" HadrontherapyDetectorConstruction::ParametersCheck()", "Hadrontherapy0004", FatalException, "Error:  Detector Z size must be bigger or equal than that of Voxel Z!");
302     }                                             273     }
                                                   >> 274 
303 }                                                 275 }
                                                   >> 276 /////////////////
                                                   >> 277 // MESSENGERS //
                                                   >> 278 ////////////////
304                                                   279 
305 ////////////////////////////////////////////// << 
306 G4bool HadrontherapyDetectorConstruction::SetP    280 G4bool HadrontherapyDetectorConstruction::SetPhantomMaterial(G4String material)
307 {                                                 281 {
308                                                << 282 
309     if (G4Material* pMat = G4NistManager::Inst    283     if (G4Material* pMat = G4NistManager::Instance()->FindOrBuildMaterial(material, false) )
310     {                                             284     {
311         phantomMaterial  = pMat;               << 285   phantomMaterial  = pMat;
312         detectorMaterial = pMat;               << 286   detectorMaterial = pMat;
313         if (detectorLogicalVolume && phantomLo << 287   if (detectorLogicalVolume && phantomLogicalVolume) 
314         {                                      << 288   {
315             detectorLogicalVolume -> SetMateri << 289       detectorLogicalVolume -> SetMaterial(pMat); 
316             phantomLogicalVolume ->  SetMateri << 290       phantomLogicalVolume ->  SetMaterial(pMat);
317                                                << 291 
318             G4RunManager::GetRunManager() -> P << 292       G4RunManager::GetRunManager() -> PhysicsHasBeenModified();
319             G4RunManager::GetRunManager() -> G << 293       G4RunManager::GetRunManager() -> GeometryHasBeenModified();
320             G4cout << "The material of Phantom << 294       G4cout << "The material of Phantom/Detector has been changed to " << material << G4endl;
321         }                                      << 295   }
322     }                                             296     }
323     else                                          297     else
324     {                                             298     {
325         G4cout << "WARNING: material \"" << ma << 299   G4cout << "WARNING: material \"" << material << "\" doesn't exist in NIST elements/materials"
326         " table [located in $G4INSTALL/source/ << 300       " table [located in $G4INSTALL/source/materials/src/G4NistMaterialBuilder.cc]" << G4endl; 
327         G4cout << "Use command \"/parameter/ni << 301   G4cout << "Use command \"/parameter/nist\" to see full materials list!" << G4endl; 
328         return false;                          << 302   return false;
329     }                                             303     }
330                                                << 304 
331     return true;                                  305     return true;
332 }                                                 306 }
333 //////////////////////////////////////////////    307 /////////////////////////////////////////////////////////////////////////////
334 void HadrontherapyDetectorConstruction::SetPha    308 void HadrontherapyDetectorConstruction::SetPhantomSize(G4double sizeX, G4double sizeY, G4double sizeZ)
335 {                                                 309 {
336     if (sizeX > 0.) phantomSizeX = sizeX;         310     if (sizeX > 0.) phantomSizeX = sizeX;
337     if (sizeY > 0.) phantomSizeY = sizeY;         311     if (sizeY > 0.) phantomSizeY = sizeY;
338     if (sizeZ > 0.) phantomSizeZ = sizeZ;         312     if (sizeZ > 0.) phantomSizeZ = sizeZ;
339 }                                                 313 }
340                                                << 314 /////////////////////////////////////////////////////////////////////////////
341 //////////////////////////////////////////////    315 /////////////////////////////////////////////////////////////////////////////
342 void HadrontherapyDetectorConstruction::SetDet    316 void HadrontherapyDetectorConstruction::SetDetectorSize(G4double sizeX, G4double sizeY, G4double sizeZ)
343 {                                                 317 {
344     if (sizeX > 0.) {detectorSizeX = sizeX;}      318     if (sizeX > 0.) {detectorSizeX = sizeX;}
345     if (sizeY > 0.) {detectorSizeY = sizeY;}      319     if (sizeY > 0.) {detectorSizeY = sizeY;}
346     if (sizeZ > 0.) {detectorSizeZ = sizeZ;}      320     if (sizeZ > 0.) {detectorSizeZ = sizeZ;}
347     SetVoxelSize(sizeOfVoxelAlongX, sizeOfVoxe    321     SetVoxelSize(sizeOfVoxelAlongX, sizeOfVoxelAlongY, sizeOfVoxelAlongZ);
348 }                                                 322 }
349                                                << 
350 //////////////////////////////////////////////    323 /////////////////////////////////////////////////////////////////////////////
                                                   >> 324 
351 void HadrontherapyDetectorConstruction::SetVox    325 void HadrontherapyDetectorConstruction::SetVoxelSize(G4double sizeX, G4double sizeY, G4double sizeZ)
352 {                                                 326 {
353     if (sizeX > 0.) {sizeOfVoxelAlongX = sizeX    327     if (sizeX > 0.) {sizeOfVoxelAlongX = sizeX;}
354     if (sizeY > 0.) {sizeOfVoxelAlongY = sizeY    328     if (sizeY > 0.) {sizeOfVoxelAlongY = sizeY;}
355     if (sizeZ > 0.) {sizeOfVoxelAlongZ = sizeZ    329     if (sizeZ > 0.) {sizeOfVoxelAlongZ = sizeZ;}
356 }                                                 330 }
357                                                << 
358 ////////////////////////////////////////////// << 
359 void HadrontherapyDetectorConstruction::SetPha    331 void HadrontherapyDetectorConstruction::SetPhantomPosition(G4ThreeVector pos)
360 {                                                 332 {
361     phantomPosition = pos;                        333     phantomPosition = pos;
362 }                                                 334 }
363                                                   335 
364 //////////////////////////////////////////////    336 /////////////////////////////////////////////////////////////////////////////
365 void HadrontherapyDetectorConstruction::SetDet    337 void HadrontherapyDetectorConstruction::SetDetectorToPhantomPosition(G4ThreeVector displ)
366 {                                                 338 {
367     detectorToPhantomPosition = displ;            339     detectorToPhantomPosition = displ;
368 }                                                 340 }
369                                                << 
370 void HadrontherapyDetectorConstruction::SetVir << 
371 {                                              << 
372                                                << 
373     VirtualLayerPosition = position;           << 
374     physVirtualLayer->SetTranslation(VirtualLa << 
375                                                << 
376 }                                              << 
377 //////////////////////////////////////////////    341 /////////////////////////////////////////////////////////////////////////////
378 void HadrontherapyDetectorConstruction::Update    342 void HadrontherapyDetectorConstruction::UpdateGeometry()
379 {                                                 343 {
380     /*                                         << 344   /* 
381      * Check parameters consistency            << 345    * Check parameters consistency
382      */                                        << 346    */
383     ParametersCheck();                         << 347   ParametersCheck();
384                                                << 348   
385     G4GeometryManager::GetInstance() -> OpenGe << 349   G4GeometryManager::GetInstance() -> OpenGeometry();
386     if (phantom)                               << 350   if (phantom)
387     {                                             351     {
388         phantom -> SetXHalfLength(phantomSizeX << 352       phantom -> SetXHalfLength(phantomSizeX/2);
389         phantom -> SetYHalfLength(phantomSizeY << 353       phantom -> SetYHalfLength(phantomSizeY/2);
390         phantom -> SetZHalfLength(phantomSizeZ << 354       phantom -> SetZHalfLength(phantomSizeZ/2);
391                                                << 355       phantomPhysicalVolume -> SetTranslation(phantomPosition);
392         phantomPhysicalVolume -> SetTranslatio << 
393     }                                             356     }
394     else   ConstructPhantom();                 << 357   else   ConstructPhantom();
395                                                << 358   
396                                                << 359   // Get the center of the detector 
397     // Get the center of the detector          << 360   SetDetectorPosition();
398     SetDetectorPosition();                     << 361   if (detector)
399     if (detector)                              << 
400     {                                          << 
401                                                << 
402         detector -> SetXHalfLength(detectorSiz << 
403         detector -> SetYHalfLength(detectorSiz << 
404         detector -> SetZHalfLength(detectorSiz << 
405                                                << 
406         detectorPhysicalVolume -> SetTranslati << 
407     }                                          << 
408     else    ConstructDetector();               << 
409                                                << 
410     //std::cout<<NewSource<<std::endl;         << 
411     /*if(NewSource)                            << 
412      {                                         << 
413      std::cout<<"via"<<std::endl;              << 
414      }*/                                       << 
415                                                << 
416                                                << 
417     // std::cout<<"i"<<std::endl;              << 
418     // std::cout<<VirtualLayerPosition<<std::e << 
419     // physVirtualLayer->SetTranslation(Virtua << 
420                                                << 
421                                                << 
422                                                << 
423                                                << 
424                                                << 
425     // Round to nearest integer number of voxe << 
426                                                << 
427     numberOfVoxelsAlongX = G4lrint(detectorSiz << 
428     sizeOfVoxelAlongX = ( detectorSizeX / numb << 
429     numberOfVoxelsAlongY = G4lrint(detectorSiz << 
430     sizeOfVoxelAlongY = ( detectorSizeY / numb << 
431     numberOfVoxelsAlongZ = G4lrint(detectorSiz << 
432     sizeOfVoxelAlongZ = ( detectorSizeZ / numb << 
433     PassiveProtonBeamLine *ppbl= (PassiveProto << 
434                                                << 
435     G4RunManager::GetRunManager()->GetUserDete << 
436                                                << 
437     HadrontherapyDetectorROGeometry* RO = (Had << 
438                                                << 
439     //Set parameters, either for the Construct << 
440     RO->Initialize(GetDetectorToWorldPosition( << 
441                    detectorSizeX/2,            << 
442                    detectorSizeY/2,            << 
443                    detectorSizeZ/2,            << 
444                    numberOfVoxelsAlongX,       << 
445                    numberOfVoxelsAlongY,       << 
446                    numberOfVoxelsAlongZ);      << 
447                                                << 
448     //This method below has an effect only if  << 
449     RO->UpdateROGeometry();                    << 
450                                                << 
451                                                << 
452                                                << 
453     volumeOfVoxel = sizeOfVoxelAlongX * sizeOf << 
454     massOfVoxel = detectorMaterial -> GetDensi << 
455     //  This will clear the existing matrix (t << 
456     matrix = HadrontherapyMatrix::GetInstance( << 
457                                                << 
458                                                << 
459                                                << 
460                                                << 
461                                                << 
462     // Initialize RBE                          << 
463     HadrontherapyRBE::CreateInstance(numberOfV << 
464                                                << 
465     // Comment out the line below if let calcu << 
466     // Initialize LET with energy of primaries << 
467     if ( (let = HadrontherapyLet::GetInstance( << 
468     {                                             362     {
469         HadrontherapyLet::GetInstance() -> Ini << 363       detector -> SetXHalfLength(detectorSizeX/2);
                                                   >> 364       detector -> SetYHalfLength(detectorSizeY/2);
                                                   >> 365       detector -> SetZHalfLength(detectorSizeZ/2);
                                                   >> 366       detectorPhysicalVolume -> SetTranslation(detectorPosition);
470     }                                             367     }
471                                                << 368   else    ConstructDetector();
472                                                << 369   
473     // Initialize analysis                     << 370   // Round to nearest integer number of voxel 
474     // Inform the kernel about the new geometr << 371 
475     G4RunManager::GetRunManager() -> GeometryH << 372   numberOfVoxelsAlongX = G4lrint(detectorSizeX / sizeOfVoxelAlongX);
476     G4RunManager::GetRunManager() -> PhysicsHa << 373 
477                                                << 374   sizeOfVoxelAlongX = ( detectorSizeX / numberOfVoxelsAlongX );
478     PrintParameters();                         << 375   
479                                                << 376   numberOfVoxelsAlongY = G4lrint(detectorSizeY / sizeOfVoxelAlongY);
480     // CheckOverlaps();                        << 377 
481 }                                              << 378   sizeOfVoxelAlongY = ( detectorSizeY / numberOfVoxelsAlongY );
482                                                << 379     
483 ////////////////////////////////////////////// << 380   numberOfVoxelsAlongZ = G4lrint(detectorSizeZ / sizeOfVoxelAlongZ);
484 //Check of the geometry                        << 381   
485 ////////////////////////////////////////////// << 382   sizeOfVoxelAlongZ = ( detectorSizeZ / numberOfVoxelsAlongZ );
486 void HadrontherapyDetectorConstruction::CheckO << 383   
487 {                                              << 384   PassiveProtonBeamLine *ppbl= (PassiveProtonBeamLine*) 
488     G4PhysicalVolumeStore* thePVStore = G4Phys << 385   
489     G4cout << thePVStore->size() << " physical << 386   G4RunManager::GetRunManager()->GetUserDetectorConstruction();
490     G4bool overlapFlag = false;                << 387   
491     G4int res=1000;                            << 388   
492     G4double tol=0.; //tolerance               << 389   HadrontherapyDetectorROGeometry* RO = (HadrontherapyDetectorROGeometry*) ppbl->GetParallelWorld(0);
493     for (size_t i=0;i<thePVStore->size();i++)  << 390   
                                                   >> 391    //Set parameters, either for the Construct() or for the UpdateROGeometry()
                                                   >> 392   RO->Initialize(GetDetectorToWorldPosition(),
                                                   >> 393      detectorSizeX/2,
                                                   >> 394      detectorSizeY/2,
                                                   >> 395      detectorSizeZ/2,
                                                   >> 396      numberOfVoxelsAlongX,
                                                   >> 397      numberOfVoxelsAlongY,
                                                   >> 398      numberOfVoxelsAlongZ);
                                                   >> 399   
                                                   >> 400   //This method below has an effect only if the RO geometry is already built.
                                                   >> 401   RO->UpdateROGeometry();
                                                   >> 402  
                                                   >> 403   volumeOfVoxel = sizeOfVoxelAlongX * sizeOfVoxelAlongY * sizeOfVoxelAlongZ;
                                                   >> 404   massOfVoxel = detectorMaterial -> GetDensity() * volumeOfVoxel;
                                                   >> 405   //  This will clear the existing matrix (together with all data inside it)! 
                                                   >> 406   matrix = HadrontherapyMatrix::GetInstance(numberOfVoxelsAlongX, 
                                                   >> 407               numberOfVoxelsAlongY,
                                                   >> 408               numberOfVoxelsAlongZ,
                                                   >> 409               massOfVoxel);
                                                   >> 410               
                                                   >> 411               
                                                   >> 412 // Comment out the line below if let calculation is not needed! 
                                                   >> 413   // Initialize LET with energy of primaries and clear data inside       
                                                   >> 414   if ( (let = HadrontherapyLet::GetInstance(this)) )
494     {                                             415     {
495         //overlapFlag = (*thePVStore)[i]->Chec << 416       HadrontherapyLet::GetInstance() -> Initialize();
496         overlapFlag = (*thePVStore)[i]->CheckO << 417     }             
497     if (overlapFlag)                           << 418               
498         G4cout << "Check: there are overlappin << 419   
                                                   >> 420   // Initialize analysis
                                                   >> 421 #ifdef G4ANALYSIS_USE_ROOT
                                                   >> 422   HadrontherapyAnalysisManager* analysis = HadrontherapyAnalysisManager::GetInstance();
                                                   >> 423   analysis -> flush();     // Finalize the root file 
                                                   >> 424   analysis -> book();
                                                   >> 425 #endif
                                                   >> 426   // Inform the kernel about the new geometry
                                                   >> 427   G4RunManager::GetRunManager() -> GeometryHasBeenModified();
                                                   >> 428   G4RunManager::GetRunManager() -> PhysicsHasBeenModified();
                                                   >> 429   
                                                   >> 430   PrintParameters();
499 }                                                 431 }
500                                                   432 
501 ////////////////////////////////////////////// << 
502 void HadrontherapyDetectorConstruction::PrintP    433 void HadrontherapyDetectorConstruction::PrintParameters()
503 {                                                 434 {
504                                                << 
505     G4cout << "The (X,Y,Z) dimensions of the p << 
506     G4BestUnit( phantom -> GetXHalfLength()*2. << 
507     G4BestUnit( phantom -> GetYHalfLength()*2. << 
508     G4BestUnit( phantom -> GetZHalfLength()*2. << 
509                                                << 
510     G4cout << "The (X,Y,Z) dimensions of the d << 
511     G4BestUnit( detector -> GetXHalfLength()*2 << 
512     G4BestUnit( detector -> GetYHalfLength()*2 << 
513     G4BestUnit( detector -> GetZHalfLength()*2 << 
514                                                << 
515     G4cout << "Displacement between Phantom an << 
516     G4cout << "DX= "<< G4BestUnit(phantomPosit << 
517     "DY= "<< G4BestUnit(phantomPosition.getY() << 
518     "DZ= "<< G4BestUnit(phantomPosition.getZ() << 
519                                                << 
520     G4cout << "The (X,Y,Z) sizes of the Voxels << 
521     G4BestUnit(sizeOfVoxelAlongX, "Length")  < << 
522     G4BestUnit(sizeOfVoxelAlongY, "Length")  < << 
523     G4BestUnit(sizeOfVoxelAlongZ, "Length") << << 
524                                                << 
525     G4cout << "The number of Voxels along (X,Y << 
526     numberOfVoxelsAlongX  << ',' <<            << 
527     numberOfVoxelsAlongY  <<','  <<            << 
528     numberOfVoxelsAlongZ  << ')' << G4endl;    << 
529 }                                              << 
530                                                   435 
                                                   >> 436     G4cout << "The (X,Y,Z) dimensions of the phantom are : (" << 
                                                   >> 437   G4BestUnit( phantom -> GetXHalfLength()*2., "Length") << ',' << 
                                                   >> 438   G4BestUnit( phantom -> GetYHalfLength()*2., "Length") << ',' << 
                                                   >> 439   G4BestUnit( phantom -> GetZHalfLength()*2., "Length") << ')' << G4endl; 
                                                   >> 440     
                                                   >> 441     G4cout << "The (X,Y,Z) dimensions of the detector are : (" << 
                                                   >> 442   G4BestUnit( detector -> GetXHalfLength()*2., "Length") << ',' << 
                                                   >> 443   G4BestUnit( detector -> GetYHalfLength()*2., "Length") << ',' << 
                                                   >> 444   G4BestUnit( detector -> GetZHalfLength()*2., "Length") << ')' << G4endl; 
                                                   >> 445 
                                                   >> 446     G4cout << "Displacement between Phantom and World is: "; 
                                                   >> 447     G4cout << "DX= "<< G4BestUnit(phantomPosition.getX(),"Length") << 
                                                   >> 448   "DY= "<< G4BestUnit(phantomPosition.getY(),"Length") << 
                                                   >> 449   "DZ= "<< G4BestUnit(phantomPosition.getZ(),"Length") << G4endl;
                                                   >> 450 
                                                   >> 451     G4cout << "The (X,Y,Z) sizes of the Voxels are: (" << 
                                                   >> 452   G4BestUnit(sizeOfVoxelAlongX, "Length")  << ',' << 
                                                   >> 453   G4BestUnit(sizeOfVoxelAlongY, "Length")  << ',' << 
                                                   >> 454   G4BestUnit(sizeOfVoxelAlongZ, "Length") << ')' << G4endl;
                                                   >> 455 
                                                   >> 456     G4cout << "The number of Voxels along (X,Y,Z) is: (" << 
                                                   >> 457   numberOfVoxelsAlongX  << ',' <<
                                                   >> 458   numberOfVoxelsAlongY  <<','  <<
                                                   >> 459   numberOfVoxelsAlongZ  << ')' << G4endl;
531                                                   460 
                                                   >> 461 }
532                                                   462