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

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Differences between /examples/advanced/hadrontherapy/src/HadrontherapyMatrix.cc (Version 11.3.0) and /examples/advanced/hadrontherapy/src/HadrontherapyMatrix.cc (Version 9.6.p2)


  1 //                                                  1 //
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 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 //
 28                                                    34 
 29 #include <fstream>                                 35 #include <fstream>
 30 #include <iostream>                                36 #include <iostream>
 31 #include <sstream>                                 37 #include <sstream>
 32 #include <iomanip>                                 38 #include <iomanip>
 33                                                    39 
 34 #include "HadrontherapyMatrix.hh"                  40 #include "HadrontherapyMatrix.hh"
                                                   >>  41 #include "HadrontherapyAnalysisManager.hh"
 35 #include "HadrontherapyPrimaryGeneratorAction.     42 #include "HadrontherapyPrimaryGeneratorAction.hh"
 36 #include "globals.hh"                              43 #include "globals.hh"
 37 #include "G4SystemOfUnits.hh"                      44 #include "G4SystemOfUnits.hh"
 38 #include "G4RunManager.hh"                         45 #include "G4RunManager.hh"
 39 #include "G4ParticleGun.hh"                        46 #include "G4ParticleGun.hh"
 40 #include "HadrontherapySteppingAction.hh"      << 
 41 #include "HadrontherapyAnalysisFileMessenger.h << 
 42 #include "G4SystemOfUnits.hh"                  << 
 43 #include <time.h>                              << 
 44                                                << 
 45 HadrontherapyAnalysis* HadrontherapyAnalysis:: << 
 46 ////////////////////////////////////////////// << 
 47                                                << 
 48 HadrontherapyAnalysis::HadrontherapyAnalysis() << 
 49 {                                              << 
 50     fMess = new HadrontherapyAnalysisFileMesse << 
 51 }                                              << 
 52                                                << 
 53 ////////////////////////////////////////////// << 
 54 HadrontherapyAnalysis::~HadrontherapyAnalysis( << 
 55 {                                              << 
 56     delete fMess;                              << 
 57 }                                              << 
 58                                                << 
 59 ////////////////////////////////////////////// << 
 60 HadrontherapyAnalysis* HadrontherapyAnalysis:: << 
 61                                                << 
 62     if (instance == 0) instance = new Hadronth << 
 63     return instance;                           << 
 64 }                                              << 
 65                                                    47 
                                                   >>  48 // Units definition: CLHEP/Units/SystemOfUnits.h
                                                   >>  49 //
 66 HadrontherapyMatrix* HadrontherapyMatrix::inst     50 HadrontherapyMatrix* HadrontherapyMatrix::instance = NULL;
 67 G4bool HadrontherapyMatrix::secondary = false;     51 G4bool HadrontherapyMatrix::secondary = false;
 68                                                    52 
 69                                                << 
 70 // Only return a pointer to matrix                 53 // Only return a pointer to matrix
 71 HadrontherapyMatrix* HadrontherapyMatrix::GetI <<  54 HadrontherapyMatrix* HadrontherapyMatrix::GetInstance() 
 72 {                                                  55 {
 73     return instance;                           <<  56   return instance;
 74 }                                                  57 }
 75                                                <<  58   // This STATIC method delete (!) the old matrix and rewrite a new object returning a pointer to it
 76 ////////////////////////////////////////////// <<  59   // TODO A check on the parameters is required!
 77 // This STATIC method delete (!) the old matri <<  60 HadrontherapyMatrix* HadrontherapyMatrix::GetInstance(G4int voxelX, G4int voxelY, G4int voxelZ, G4double mass)  
 78 // TODO A check on the parameters is required! <<  61 {
 79 HadrontherapyMatrix* HadrontherapyMatrix::GetI <<  62   if (instance) delete instance;
 80 {                                              <<  63   instance = new HadrontherapyMatrix(voxelX, voxelY, voxelZ, mass);
 81     if (instance) delete instance;             <<  64   instance -> Initialize(); 
 82     instance = new HadrontherapyMatrix(voxelX, <<  65   return instance;
 83     instance -> Initialize();                  << 
 84     return instance;                           << 
 85 }                                                  66 }
 86                                                << 
 87 ////////////////////////////////////////////// << 
 88 HadrontherapyMatrix::HadrontherapyMatrix(G4int     67 HadrontherapyMatrix::HadrontherapyMatrix(G4int voxelX, G4int voxelY, G4int voxelZ, G4double mass):
 89     stdFile("Dose.out"),                           68     stdFile("Dose.out"),
 90     doseUnit(gray)                                 69     doseUnit(gray)
 91 {                                              <<  70 {  
 92     // Number of the voxels of the phantom     <<  71   // Number of the voxels of the phantom
 93     // For Y = Z = 1 the phantom is divided in <<  72   // For Y = Z = 1 the phantom is divided in slices (and not in voxels)
 94     // orthogonal to the beam axis             <<  73   // orthogonal to the beam axis
 95     numberOfVoxelAlongX = voxelX;              <<  74   numberOfVoxelAlongX = voxelX;
 96     numberOfVoxelAlongY = voxelY;              <<  75   numberOfVoxelAlongY = voxelY;
 97     numberOfVoxelAlongZ = voxelZ;              <<  76   numberOfVoxelAlongZ = voxelZ; 
 98     massOfVoxel = mass;                        <<  77   massOfVoxel = mass;
 99                                                <<  78   // Create the dose matrix
100                                                <<  79   matrix = new G4double[numberOfVoxelAlongX*numberOfVoxelAlongY*numberOfVoxelAlongZ];
101     // Create the dose matrix                  <<  80   if (matrix)
102     matrix = new G4double[numberOfVoxelAlongX* <<  81   {
103     if (matrix)                                <<  82     G4cout << "HadrontherapyMatrix: Memory space to store physical dose into " <<  
104     {                                          <<  83     numberOfVoxelAlongX*numberOfVoxelAlongY*numberOfVoxelAlongZ <<
105         G4cout << "HadrontherapyMatrix: Memory <<  84     " voxels has been allocated " << G4endl;
106                   numberOfVoxelAlongX*numberOf <<  85   }
107                   " voxels has been allocated  <<  86   else G4Exception("HadrontherapyMatrix::HadrontherapyMatrix()", "Hadrontherapy0005", FatalException, "Can't allocate memory to store physical dose!");
108     }                                          <<  87     // Hit voxel (TrackID) marker
109                                                <<  88     // This array mark the status of voxel, if a hit occur, with the trackID of the particle
110     else G4Exception("HadrontherapyMatrix::Had <<  89     // Must be initialized
111                                                <<  90   hitTrack = new G4int[numberOfVoxelAlongX*numberOfVoxelAlongY*numberOfVoxelAlongZ];
112                                                <<  91   ClearHitTrack();
113     // Hit voxel (TrackID) marker              << 
114     // This array mark the status of voxel, if << 
115     // Must be initialized                     << 
116                                                << 
117     hitTrack = new G4int[numberOfVoxelAlongX*n << 
118     ClearHitTrack();                           << 
119 }                                                  92 }
120                                                    93 
121 //////////////////////////////////////////////     94 /////////////////////////////////////////////////////////////////////////////
122 HadrontherapyMatrix::~HadrontherapyMatrix()        95 HadrontherapyMatrix::~HadrontherapyMatrix()
123 {                                                  96 {
124     delete[] matrix;                               97     delete[] matrix;
125     delete[] hitTrack;                             98     delete[] hitTrack;
                                                   >>  99     // free fluences/dose data memory
126     Clear();                                      100     Clear();
127 }                                                 101 }
128                                                   102 
129 //////////////////////////////////////////////    103 /////////////////////////////////////////////////////////////////////////////
130 void HadrontherapyMatrix::Clear()                 104 void HadrontherapyMatrix::Clear()
131 {                                                 105 {
132     for (size_t i=0; i<ionStore.size(); i++)      106     for (size_t i=0; i<ionStore.size(); i++)
133     {                                             107     {
134         delete[] ionStore[i].dose;             << 108   delete[] ionStore[i].dose; 
135         delete[] ionStore[i].fluence;          << 109   delete[] ionStore[i].fluence; 
136     }                                             110     }
137     ionStore.clear();                             111     ionStore.clear();
138 }                                                 112 }
139                                                   113 
140 //////////////////////////////////////////////    114 /////////////////////////////////////////////////////////////////////////////
141 // Initialise the elements of the matrix to ze    115 // Initialise the elements of the matrix to zero
142                                                << 
143 void HadrontherapyMatrix::Initialize()            116 void HadrontherapyMatrix::Initialize()
144 {                                              << 117 { 
145     // Clear ions store                           118     // Clear ions store
146     Clear();                                      119     Clear();
147     // Clear dose                                 120     // Clear dose
148     for(int i=0;i<numberOfVoxelAlongX*numberOf    121     for(int i=0;i<numberOfVoxelAlongX*numberOfVoxelAlongY*numberOfVoxelAlongZ;i++)
149     {                                             122     {
150         matrix[i] = 0;                         << 123     matrix[i] = 0;
151     }                                             124     }
152 }                                                 125 }
153                                                << 126   /////////////////////////////////////////////////////////////////////////////
154 ////////////////////////////////////////////// << 127   /////////////////////////////////////////////////////////////////////////////
155 // Print generated nuclides list               << 128   // Print generated nuclides list
156                                                << 
157 ////////////////////////////////////////////// << 
158 void HadrontherapyMatrix::PrintNuclides()         129 void HadrontherapyMatrix::PrintNuclides()
159 {                                                 130 {
160     for (size_t i=0; i<ionStore.size(); i++)      131     for (size_t i=0; i<ionStore.size(); i++)
161     {                                             132     {
162         G4cout << ionStore[i].name << G4endl;  << 133     G4cout << ionStore[i].name << G4endl;
163     }                                             134     }
164 }                                                 135 }
165                                                << 136   /////////////////////////////////////////////////////////////////////////////
166 ////////////////////////////////////////////// << 137   // Clear Hit voxel (TrackID) markers
167 // Clear Hit voxel (TrackID) markers           << 
168                                                << 
169 void HadrontherapyMatrix::ClearHitTrack()         138 void HadrontherapyMatrix::ClearHitTrack()
170 {                                                 139 {
171     for(G4int i=0; i<numberOfVoxelAlongX*numbe << 140   for(G4int i=0; i<numberOfVoxelAlongX*numberOfVoxelAlongY*numberOfVoxelAlongZ; i++) hitTrack[i] = 0;
172 }                                                 141 }
173                                                << 142   // Return Hit status
174 // Return Hit status                           << 
175 G4int* HadrontherapyMatrix::GetHitTrack(G4int     143 G4int* HadrontherapyMatrix::GetHitTrack(G4int i, G4int j, G4int k)
176 {                                                 144 {
177     return &(hitTrack[Index(i,j,k)]);          << 145   return &(hitTrack[Index(i,j,k)]);
178 }                                                 146 }
179                                                << 
180 //////////////////////////////////////////////    147 /////////////////////////////////////////////////////////////////////////////
181 // Dose methods...                                148 // Dose methods...
182 // Fill DOSE/fluence matrix for secondary part << 149 // Fill DOSE/fluence matrix for secondary particles: 
183 // If fluence parameter is true (default value << 150 // If fluence parameter is true (default value is FALSE) then fluence at voxel (i, j, k) is increased. 
184 // The energyDeposit parameter fill the dose m << 151 // The energyDeposit parameter fill the dose matrix for voxel (i,j,k) 
185 //////////////////////////////////////////////    152 /////////////////////////////////////////////////////////////////////////////
                                                   >> 153 
186 G4bool HadrontherapyMatrix::Fill(G4int trackID    154 G4bool HadrontherapyMatrix::Fill(G4int trackID,
187                                  G4ParticleDef << 155          G4ParticleDefinition* particleDef,
188                                  G4int i, G4in << 156          G4int i, G4int j, G4int k, 
189                                  G4double ener << 157          G4double energyDeposit,
190                                  G4bool fluenc << 158          G4bool fluence) 
191 {                                                 159 {
192                                                << 
193     if ( (energyDeposit <=0. && !fluence) || !    160     if ( (energyDeposit <=0. && !fluence) || !secondary) return false;
194                                                << 161     // Get Particle Data Group particle ID 
195     // Get Particle Data Group particle ID     << 
196     G4int PDGencoding = particleDef -> GetPDGE    162     G4int PDGencoding = particleDef -> GetPDGEncoding();
197     PDGencoding -= PDGencoding%10;                163     PDGencoding -= PDGencoding%10;
198                                                << 164   
199     // Search for already allocated data...       165     // Search for already allocated data...
200     for (size_t l=0; l < ionStore.size(); l++)    166     for (size_t l=0; l < ionStore.size(); l++)
201     {                                             167     {
202         if (ionStore[l].PDGencoding == PDGenco << 168     if (ionStore[l].PDGencoding == PDGencoding ) 
203         {   // Is it a primary or a secondary  << 169     {   // Is it a primary or a secondary particle? 
204                                                << 170       if ( (trackID ==1 && ionStore[l].isPrimary) || (trackID !=1 && !ionStore[l].isPrimary))
205             if ( (trackID ==1 && ionStore[l].i << 171       {
206             {                                  << 172         if (energyDeposit > 0.) ionStore[l].dose[Index(i, j, k)] += energyDeposit;
207                 if (energyDeposit > 0.)        << 173         
208                                                << 174           // Fill a matrix per each ion with the fluence
209                     ionStore[l].dose[Index(i,  << 175         if (fluence) ionStore[l].fluence[Index(i, j, k)]++;
210                                                << 176         return true;
211                 // Fill a matrix per each ion  << 177       }
212                                                << 178     }
213                 if (fluence) ionStore[l].fluen << 
214                 return true;                   << 
215             }                                  << 
216         }                                      << 
217     }                                             179     }
                                                   >> 180   
218     G4int Z = particleDef-> GetAtomicNumber();    181     G4int Z = particleDef-> GetAtomicNumber();
219     G4int A = particleDef-> GetAtomicMass();      182     G4int A = particleDef-> GetAtomicMass();
220     G4String fullName = particleDef -> GetPart << 
221     G4String name = fullName.substr (0, fullNa << 
222                                                   183 
223     // Let's put a new particle in our store.. << 184     G4String fullName = particleDef -> GetParticleName();
224     ion newIon =                               << 185     G4String name = fullName.substr (0, fullName.find("[") ); // cut excitation energy  
                                                   >> 186   // Let's put a new particle in our store...
                                                   >> 187     ion newIon = 
225     {                                             188     {
226         (trackID == 1) ? true:false,           << 189     (trackID == 1) ? true:false,
227         PDGencoding,                           << 190     PDGencoding,
228         name,                                  << 191     name,
229         name.length(),                         << 192     name.length(), 
230         Z,                                     << 193     Z, 
231         A,                                     << 194     A, 
232         new G4double[numberOfVoxelAlongX * num << 195     new G4double[numberOfVoxelAlongX * numberOfVoxelAlongY * numberOfVoxelAlongZ],
233         new unsigned int[numberOfVoxelAlongX * << 196     new unsigned int[numberOfVoxelAlongX * numberOfVoxelAlongY * numberOfVoxelAlongZ]
234     };                                         << 197     }; 
235                                                << 198     // Initialize data
236                                                << 
237     // Initialize data                         << 
238     if (newIon.dose && newIon.fluence)            199     if (newIon.dose && newIon.fluence)
239     {                                             200     {
240         for(G4int q=0; q<numberOfVoxelAlongX*n << 201     for(G4int q=0; q<numberOfVoxelAlongX*numberOfVoxelAlongY*numberOfVoxelAlongZ; q++)
241         {                                      << 202     {
242             newIon.dose[q] = 0.;               << 203       newIon.dose[q] = 0.;
243             newIon.fluence[q] = 0;             << 204       newIon.fluence[q] = 0;
244         }                                      << 205     }
245                                                << 206     if (energyDeposit > 0.) newIon.dose[Index(i, j, k)] += energyDeposit;
246         if (energyDeposit > 0.) newIon.dose[In << 207     if (fluence) newIon.fluence[Index(i, j, k)]++;
247         if (fluence) newIon.fluence[Index(i, j << 208     
248                                                << 209     ionStore.push_back(newIon);
249         ionStore.push_back(newIon);            << 210     
250         return true;                           << 211     // TODO Put some verbosity check
                                                   >> 212     /*
                                                   >> 213      G4cout << "Memory space to store the DOSE/FLUENCE into " <<  
                                                   >> 214      numberOfVoxelAlongX*numberOfVoxelAlongY*numberOfVoxelAlongZ << 
                                                   >> 215      " voxels has been allocated for the nuclide " << newIon.name << 
                                                   >> 216      " (Z = " << Z << ", A = " << A << ")" << G4endl ;
                                                   >> 217      */
                                                   >> 218     return true;
251     }                                             219     }
252                                                << 
253     else // XXX Out of memory! XXX                220     else // XXX Out of memory! XXX
254                                                << 
255     {                                             221     {
256         return false;                          << 222     return false;
257     }                                             223     }
                                                   >> 224   
258 }                                                 225 }
259                                                << 226   
260 ////////////////////////////////////////////// << 227   /////////////////////////////////////////////////////////////////////////////
261 ////////////////////////////////////////////// << 228   /////////////////////////////////////////////////////////////////////////////
262 // Methods to store data to filenames...       << 229   // Methods to store data to filenames...
263 ////////////////////////////////////////////// << 230   ////////////////////////////////////////////////////////////////////////////
264 ////////////////////////////////////////////// << 231   ////////////////////////////////////////////////////////////////////////////
265 //                                             << 232   //
266 // General method to store matrix data to file << 233   // General method to store matrix data to filename
267 void HadrontherapyMatrix::StoreMatrix(G4String    234 void HadrontherapyMatrix::StoreMatrix(G4String file, void* data, size_t psize)
268 {                                                 235 {
269     if (data)                                     236     if (data)
270     {                                             237     {
271         ofs.open(file, std::ios::out);         << 238     ofs.open(file, std::ios::out);
272         if (ofs.is_open())                     << 239     if (ofs.is_open())
273         {                                      << 240     {
274             for(G4int i = 0; i < numberOfVoxel << 241       for(G4int i = 0; i < numberOfVoxelAlongX; i++) 
275                 for(G4int j = 0; j < numberOfV << 242         for(G4int j = 0; j < numberOfVoxelAlongY; j++) 
276                     for(G4int k = 0; k < numbe << 243           for(G4int k = 0; k < numberOfVoxelAlongZ; k++) 
277                     {                          << 244           {
278                         G4int n = Index(i, j,  << 245             G4int n = Index(i, j, k);
279                                                << 246               // Check for data type: u_int, G4double, XXX 
280                         if (psize == sizeof(un << 247             if (psize == sizeof(unsigned int))
281                         {                      << 248             {
282                             unsigned int* pdat << 249               unsigned int* pdata = (unsigned int*)data;
283                                                << 250               if (pdata[n]) ofs << i << '\t' << j << '\t' <<
284                             if (pdata[n])      << 251                 k << '\t' << pdata[n] << G4endl;
285                                                << 252             }
286                                 ofs << i << '\ << 253             else if (psize == sizeof(G4double))
287                         }                      << 254             {
288                                                << 255               G4double* pdata = (G4double*)data;
289                         else if (psize == size << 256               if (pdata[n]) ofs << i << '\t' << j << '\t' <<
290                                                << 257                 k << '\t' << pdata[n] << G4endl;
291                         {                      << 258             }
292                             G4double* pdata =  << 259           }
293                             if (pdata[n]) ofs  << 260       ofs.close();
294                         }                      << 261     }
295                     }                          << 
296             ofs.close();                       << 
297         }                                      << 
298     }                                             262     }
299 }                                                 263 }
300                                                   264 
301 ////////////////////////////////////////////// << 265   // Store fluence per single ion in multiple files
302 // Store fluence per single ion in multiple fi << 
303 void HadrontherapyMatrix::StoreFluenceData()      266 void HadrontherapyMatrix::StoreFluenceData()
304 {                                                 267 {
305     for (size_t i=0; i < ionStore.size(); i++)    268     for (size_t i=0; i < ionStore.size(); i++){
306         StoreMatrix(ionStore[i].name + "_Fluen << 269     StoreMatrix(ionStore[i].name + "_Fluence.out", ionStore[i].fluence, sizeof(unsigned int));
307     }                                             270     }
308 }                                                 271 }
309                                                << 272   // Store dose per single ion in multiple files
310 ////////////////////////////////////////////// << 
311 // Store dose per single ion in multiple files << 
312 void HadrontherapyMatrix::StoreDoseData()         273 void HadrontherapyMatrix::StoreDoseData()
313 {                                                 274 {
314                                                << 275   
315     for (size_t i=0; i < ionStore.size(); i++)    276     for (size_t i=0; i < ionStore.size(); i++){
316         StoreMatrix(ionStore[i].name + "_Dose. << 277     StoreMatrix(ionStore[i].name + "_Dose.out", ionStore[i].dose, sizeof(G4double));
317     }                                             278     }
318 }                                                 279 }
319                                                << 280   /////////////////////////////////////////////////////////////////////////
320 ////////////////////////////////////////////// << 281   // Store dose for all ions into a single file and into ntuples.
321 // Store dose into a single file               << 282   // Please note that this function is called via messenger commands
322 // or in histograms. Please, note that this fu << 283   // defined in the HadrontherapyAnalysisFileMessenger.cc class file
323 // messenger commands                          << 
324 // defined in the HadrontherapyAnalysisFileMes << 
325 void HadrontherapyMatrix::StoreDoseFluenceAsci    284 void HadrontherapyMatrix::StoreDoseFluenceAscii(G4String file)
326 {                                                 285 {
327 #define width 15L                                 286 #define width 15L
328     filename = (file=="") ? stdFile:file;         287     filename = (file=="") ? stdFile:file;
329                                                << 
330     // Sort like periodic table                   288     // Sort like periodic table
331                                                << 
332     std::sort(ionStore.begin(), ionStore.end()    289     std::sort(ionStore.begin(), ionStore.end());
333     G4cout << "Dose is being written to " << f    290     G4cout << "Dose is being written to " << filename << G4endl;
334     ofs.open(filename, std::ios::out);            291     ofs.open(filename, std::ios::out);
335                                                << 
336     if (ofs.is_open())                            292     if (ofs.is_open())
337     {                                             293     {
338         // Write the voxels index and the list << 294   // Write the voxels index and the list of particles/ions 
339         //ofs << std::setprecision(6) << std:: << 295   ofs << std::setprecision(6) << std::left <<
340         ofs << "i" << '\t' << "j" << '\t' << " << 296       "i\tj\tk\t"; 
341         G4cout << "i" << '\t' << "j" << '\t' < << 297   // Total dose 
342                                                << 298   ofs << std::setw(width) << "Dose(Gy)";
343         // Total dose                          << 299   if (secondary)
344         ofs <<'\t' <<"Dose(Gy)";               << 300   {
345         //ofs << std::setw(width) << "Dose(Gy) << 301       for (size_t l=0; l < ionStore.size(); l++)
346         G4cout << '\t' << "Dose(Gy)";          << 302       {
347                                                << 303     G4String a = (ionStore[l].isPrimary) ? "_1":""; // is it a primary?
348         G4String fluence = "_f";               << 304     ofs << std::setw(width) << ionStore[l].name + a <<
349         if (secondary)                         << 305         std::setw(width) << ionStore[l].name  + a;
350         {                                      << 306       }
351             for (size_t l=0; l < ionStore.size << 307       ofs << G4endl;
352             {                                  << 308 
353                 G4String a = (ionStore[l].isPr << 309       /*
354                                                << 310        * PDGencondig
355                // ofs << std::setw(width) << i << 311        */
356                //        std::setw(width) << i << 312       /*
357                                                << 313       ofs << std::setprecision(6) << std::left <<
358                 ofs << '\t' << ionStore[l].nam << 314       "0\t0\t0\t"; 
359                           '\t' << ionStore[l]. << 315 
360                                                << 316       // Total dose 
361                 G4cout << '\t' << ionStore[l]. << 317       ofs << std::setw(width) << '0';
362                           '\t' << ionStore[l]. << 318       for (size_t l=0; l < ionStore.size(); l++)
363                                                << 319       {
364             }                                  << 320       ofs << std::setw(width) << ionStore[l].PDGencoding  <<
365             //ofs << G4endl;                   << 321       std::setw(width) << ionStore[l].PDGencoding;
366         }                                      << 322       }
367                                                << 323       ofs << G4endl;
368         // Write data                          << 324       */
369         for(G4int i = 0; i < numberOfVoxelAlon << 325   }
370             for(G4int j = 0; j < numberOfVoxel << 326   // Write data
371                 for(G4int k = 0; k < numberOfV << 327   for(G4int i = 0; i < numberOfVoxelAlongX; i++) 
372                 {                              << 328       for(G4int j = 0; j < numberOfVoxelAlongY; j++) 
373                     G4int n = Index(i, j, k);  << 329     for(G4int k = 0; k < numberOfVoxelAlongZ; k++) 
374                                                << 330     {
375                     if (matrix[n])             << 331         G4int n = Index(i, j, k);
376                     {                          << 332         // Write only not identically null data lines
377                         ofs << G4endl;         << 333         if (matrix[n])
378                         ofs << i << '\t' << j  << 334         {
379                                                << 335       ofs << G4endl;
380                         // Total dose          << 336       ofs << i << '\t' << j << '\t' << k << '\t';
381                         //ofs << std::setw(wid << 337       // Total dose 
382                         ofs << (matrix[n]/mass << 338       ofs << std::setw(width) << (matrix[n]/massOfVoxel)/doseUnit; 
383                                                << 339       if (secondary)
384                         if (secondary)         << 340       {
385                         {                      << 341           for (size_t l=0; l < ionStore.size(); l++)
386                             for (size_t l=0; l << 342           {
387                             {                  << 343         // Fill ASCII file rows
388                                 // Fill ASCII  << 344         ofs << std::setw(width) << ionStore[l].dose[n]/massOfVoxel/doseUnit <<
389                                 //ofs << std:: << 345             std::setw(width) << ionStore[l].fluence[n]; 
390                                 //       std:: << 346           }
391                                                << 347       }
392                                  ofs << '\t' < << 348         }
393                                      '\t' << i << 349     }
394                             }                  << 350   ofs.close();
395                         }                      << 351     }
396                     }                          << 352 }
397                 }                              << 353 /////////////////////////////////////////////////////////////////////////////
398         ofs.close();                           << 354 
399     }                                          << 355 #ifdef G4ANALYSIS_USE_ROOT
400 }                                              << 356 void HadrontherapyMatrix::StoreDoseFluenceRoot()
401 ////////////////////////////////////////////// << 
402 void HadrontherapyMatrix::Fill(G4int i, G4int  << 
403                                G4double energy << 
404 {                                                 357 {
405     if (matrix)                                << 358     HadrontherapyAnalysisManager* analysis = HadrontherapyAnalysisManager::GetInstance();
406         matrix[Index(i,j,k)] += energyDeposit; << 359     if (analysis -> IsTheTFile())
                                                   >> 360     {
                                                   >> 361   for(G4int i = 0; i < numberOfVoxelAlongX; i++) 
                                                   >> 362       for(G4int j = 0; j < numberOfVoxelAlongY; j++) 
                                                   >> 363     for(G4int k = 0; k < numberOfVoxelAlongZ; k++) 
                                                   >> 364     {
                                                   >> 365         G4int n = Index(i, j, k);
                                                   >> 366         for (size_t l=0; l < ionStore.size(); l++)
                                                   >> 367 
                                                   >> 368         {
                                                   >> 369       // Do the same work for .root file: fill dose/fluence ntuple  
                                                   >> 370       analysis -> FillVoxelFragmentTuple( i, j, k, 
                                                   >> 371         ionStore[l].A, 
                                                   >> 372         ionStore[l].Z, 
                                                   >> 373         ionStore[l].dose[n]/massOfVoxel/doseUnit, 
                                                   >> 374         ionStore[l].fluence[n] );
407                                                   375 
408     // Store the energy deposit in the matrix  << 
409     // to the phantom voxel                    << 
410 }                                              << 
411                                                   376 
                                                   >> 377         }
                                                   >> 378     }
                                                   >> 379     }
                                                   >> 380 }
                                                   >> 381 #endif
412                                                   382 
                                                   >> 383 void HadrontherapyMatrix::Fill(G4int i, G4int j, G4int k, 
                                                   >> 384              G4double energyDeposit)
                                                   >> 385 {
                                                   >> 386     if (matrix)
                                                   >> 387     matrix[Index(i,j,k)] += energyDeposit;
                                                   >> 388   
                                                   >> 389     // Store the energy deposit in the matrix element corresponding 
                                                   >> 390     // to the phantom voxel  
                                                   >> 391 }
                                                   >> 392 void HadrontherapyMatrix::TotalEnergyDeposit()
                                                   >> 393 {
                                                   >> 394     // Convert energy deposited to dose.
                                                   >> 395     // Store the information of the matrix in a ntuple and in 
                                                   >> 396     // a 1D Histogram
                                                   >> 397 #ifdef G4ANALYSIS_USE_ROOT
                                                   >> 398       HadrontherapyAnalysisManager* analysis = HadrontherapyAnalysisManager::GetInstance();
                                                   >> 399 #endif
413                                                   400 
                                                   >> 401     if (matrix)
                                                   >> 402     {  
                                                   >> 403   for(G4int i = 0; i < numberOfVoxelAlongX; i++) 
                                                   >> 404       for(G4int j = 0; j < numberOfVoxelAlongY; j++) 
                                                   >> 405     for(G4int k = 0; k < numberOfVoxelAlongZ; k++)
                                                   >> 406     {
                                                   >> 407 #ifdef G4ANALYSIS_USE_ROOT
                                                   >> 408         G4int n = Index(i,j,k);
                                                   >> 409         if (analysis -> IsTheTFile() )
                                                   >> 410         {
                                                   >> 411       analysis -> FillEnergyDeposit(i, j, k, matrix[n]/massOfVoxel/doseUnit);
                                                   >> 412       analysis -> BraggPeak(i, matrix[n]/massOfVoxel/doseUnit);
                                                   >> 413         }
                                                   >> 414 #endif
                                                   >> 415     }
                                                   >> 416     }
                                                   >> 417 }
414                                                   418 
415                                                   419