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Geant4/visualization/gMocren/src/G4GMocrenIO.cc

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Differences between /visualization/gMocren/src/G4GMocrenIO.cc (Version 11.3.0) and /visualization/gMocren/src/G4GMocrenIO.cc (Version 9.4.p2)


  1 //                                                  1 //
  2 // *******************************************      2 // ********************************************************************
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  4 // *                                                4 // *                                                                  *
  5 // * The  Geant4 software  is  copyright of th      5 // * The  Geant4 software  is  copyright of the Copyright Holders  of *
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  7 // * conditions of the Geant4 Software License      7 // * conditions of the Geant4 Software License,  included in the file *
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 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.         *
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 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 *
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 24 // *******************************************     24 // ********************************************************************
 25 //                                                 25 //
 26 //                                                 26 //
                                                   >>  27 // $Id: G4GMocrenIO.cc,v 1.6 2010-11-10 23:53:23 akimura Exp $
                                                   >>  28 // GEANT4 tag $Name: geant4-09-04-patch-02 $
 27 //                                                 29 //
 28 //                                                 30 //
 29 // File I/O manager class for writing or readi     31 // File I/O manager class for writing or reading calcuated dose
 30 // distribution and some event information         32 // distribution and some event information
 31 //                                                 33 //
 32 // Created:  Mar. 31, 2009  Akinori Kimura : r     34 // Created:  Mar. 31, 2009  Akinori Kimura : release for the gMocrenFile driver
 33 //                                                 35 //
 34 //                               Akinori Kimur     36 //                               Akinori Kimura
 35 //                               gMocren home      37 //                               gMocren home page:
 36 //                               http://geant4     38 //                               http://geant4.kek.jp/gMocren/
 37 //                                                 39 //
 38 //                                                 40 //
 39 #include "G4GMocrenIO.hh"                          41 #include "G4GMocrenIO.hh"
 40 #include <iostream>                                42 #include <iostream>
 41 #include <ctime>                                   43 #include <ctime>
 42 #include <sstream>                                 44 #include <sstream>
 43 #include <iomanip>                                 45 #include <iomanip>
 44 #include <cstdlib>                                 46 #include <cstdlib>
 45 #include <cstring>                                 47 #include <cstring>
 46                                                    48 
 47 #include "globals.hh"                              49 #include "globals.hh"
 48 #include "G4VisManager.hh"                         50 #include "G4VisManager.hh"
 49                                                    51 
 50 #if defined(_WIN32)                                52 #if defined(_WIN32)
 51 #define LITTLE_ENDIAN 1234                         53 #define LITTLE_ENDIAN 1234
 52 #define BYTE_ORDER LITTLE_ENDIAN                   54 #define BYTE_ORDER LITTLE_ENDIAN
 53 #endif                                             55 #endif
 54                                                    56 
 55 const int DOSERANGE = 25000;                       57 const int DOSERANGE = 25000;
 56                                                    58 
 57 //----- GMocrenDataPrimitive class in the GMoc     59 //----- GMocrenDataPrimitive class in the GMocrenDataIO class-----//
 58 template <typename T>                              60 template <typename T> 
 59 GMocrenDataPrimitive<T>::GMocrenDataPrimitive      61 GMocrenDataPrimitive<T>::GMocrenDataPrimitive () {
 60   clear();                                         62   clear();
 61 }                                                  63 }
 62 template <typename T>                              64 template <typename T> 
 63 GMocrenDataPrimitive<T>::~GMocrenDataPrimitive     65 GMocrenDataPrimitive<T>::~GMocrenDataPrimitive () {
 64   /*                                               66   /*
 65     std::vector<short *>::iterator itr = image     67     std::vector<short *>::iterator itr = image.begin();
 66     for(; itr != image.end(); itr++) {             68     for(; itr != image.end(); itr++) {
 67     delete [] *itr;                                69     delete [] *itr;
 68     }                                              70     }
 69   */                                               71   */
 70 }                                                  72 }
 71                                                    73 
 72 template <typename T> GMocrenDataPrimitive<T>      74 template <typename T> GMocrenDataPrimitive<T> & 
 73 GMocrenDataPrimitive<T>::operator = (const GMo     75 GMocrenDataPrimitive<T>::operator = (const GMocrenDataPrimitive<T> & _right) {
 74   if (this == &_right) return *this;           << 
 75   for(int i = 0; i < 3; i++) {                     76   for(int i = 0; i < 3; i++) {
 76     kSize[i] = _right.kSize[i];                    77     kSize[i] = _right.kSize[i];
 77     kCenter[i] = _right.kCenter[i];                78     kCenter[i] = _right.kCenter[i];
 78   }                                                79   }
 79   kScale = _right.kScale;                          80   kScale = _right.kScale;
 80   for(int i = 0; i < 2; i++) kMinmax[i] = _rig     81   for(int i = 0; i < 2; i++) kMinmax[i] = _right.kMinmax[i];
 81   int num = kSize[0]*kSize[1];                     82   int num = kSize[0]*kSize[1];
 82   kImage.clear();                                  83   kImage.clear();
 83   for(int z = 0; z < kSize[2]; z++) {              84   for(int z = 0; z < kSize[2]; z++) {
 84     T * img = new T[num];                          85     T * img = new T[num];
 85     for(int i = 0; i < num; i++) img[i] =_righ     86     for(int i = 0; i < num; i++) img[i] =_right.kImage[z][i];
 86     kImage.push_back(img);                         87     kImage.push_back(img);
 87   }                                                88   }
 88   return *this;                                    89   return *this;
 89 }                                                  90 }
 90                                                    91 
 91 template <typename T> GMocrenDataPrimitive<T>      92 template <typename T> GMocrenDataPrimitive<T> & 
 92 GMocrenDataPrimitive<T>::operator + (const GMo     93 GMocrenDataPrimitive<T>::operator + (const GMocrenDataPrimitive<T> & _right) {
 93                                                    94 
 94   GMocrenDataPrimitive<T> rprim;                   95   GMocrenDataPrimitive<T> rprim;
 95   bool stat = true;                                96   bool stat = true;
 96   for(int i = 0; i < 3; i++) {                     97   for(int i = 0; i < 3; i++) {
 97     if(kSize[i] != _right.kSize[i]) stat = fal     98     if(kSize[i] != _right.kSize[i]) stat = false;
 98     if(kCenter[i] != _right.kCenter[i]) stat =     99     if(kCenter[i] != _right.kCenter[i]) stat = false;
 99   }                                               100   }
100   if(!stat) {                                     101   if(!stat) {
101     if (G4VisManager::GetVerbosity() >= G4VisM    102     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
102       G4cout << "Warning: operator + "            103       G4cout << "Warning: operator + "
103        << "         Cannot do the operator +"     104        << "         Cannot do the operator +"
104        << G4endl;                                 105        << G4endl;
105     return *this;                                 106     return *this;
106   }                                               107   }
107                                                   108 
108   rprim.setSize(kSize);                           109   rprim.setSize(kSize);
109   rprim.setCenterPosition(kCenter);               110   rprim.setCenterPosition(kCenter);
110                                                   111   
111   T mms[2] = {9e100,-9e100};                   << 112   T mm[2] = {9e100,-9e100};
112   //if(mms[0] > _right.minmax[0]) mms[0] = _ri << 113   //if(mm[0] > _right.minmax[0]) mm[0] = _right.minmax[0];
113   //if(mms[1] < _right.minmax[1]) mms[1] = _ri << 114   //if(mm[1] < _right.minmax[1]) mm[1] = _right.minmax[1];
114                                                   115 
115   int num = kSize[0]*kSize[1];                    116   int num = kSize[0]*kSize[1];
116   for(int z = 0; z < kSize[2]; z++) {             117   for(int z = 0; z < kSize[2]; z++) {
117     T * img = new T[num];                         118     T * img = new T[num];
118     for(int xy = 0; xy < num; xy++) {             119     for(int xy = 0; xy < num; xy++) {
119       img[xy] = kImage[z][xy] + _right.kImage[    120       img[xy] = kImage[z][xy] + _right.kImage[z][xy];
120       if(mms[0] > img[xy]) mms[0] = img[xy];   << 121       if(mm[0] > img[xy]) mm[0] = img[xy];
121       if(mms[1] < img[xy]) mms[1] = img[xy];   << 122       if(mm[1] < img[xy]) mm[1] = img[xy];
122     }                                             123     }
123     rprim.addImage(img);                          124     rprim.addImage(img);
124   }                                               125   }
125   rprim.setMinMax(mms);                        << 126   rprim.setMinMax(mm);
126                                                   127 
127   T scl = mms[1]/DOSERANGE;                    << 128   T scl = mm[1]/DOSERANGE;
128   rprim.setScale(scl);                            129   rprim.setScale(scl);
129                                                   130 
130   return rprim;                                   131   return rprim;
131 }                                                 132 }
132                                                   133 
133 template <typename T> GMocrenDataPrimitive<T>     134 template <typename T> GMocrenDataPrimitive<T> & 
134 GMocrenDataPrimitive<T>::operator += (const GM    135 GMocrenDataPrimitive<T>::operator += (const GMocrenDataPrimitive<T> & _right) {
135                                                   136 
136   bool stat = true;                               137   bool stat = true;
137   for(int i = 0; i < 3; i++) {                    138   for(int i = 0; i < 3; i++) {
138     if(kSize[i] != _right.kSize[i]) stat = fal    139     if(kSize[i] != _right.kSize[i]) stat = false;
139     if(kCenter[i] != _right.kCenter[i]) stat =    140     if(kCenter[i] != _right.kCenter[i]) stat = false;
140   }                                               141   }
141   if(!stat) {                                     142   if(!stat) {
142     if (G4VisManager::GetVerbosity() >= G4VisM    143     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
143       G4cout << "Warning: operator += " << G4e    144       G4cout << "Warning: operator += " << G4endl
144        << "         Cannot do the operator +="    145        << "         Cannot do the operator +="
145        << G4endl;                                 146        << G4endl;
146     return *this;                                 147     return *this;
147   }                                               148   }
148                                                   149 
149   if(kMinmax[0] > _right.kMinmax[0]) kMinmax[0    150   if(kMinmax[0] > _right.kMinmax[0]) kMinmax[0] = _right.kMinmax[0];
150   if(kMinmax[1] < _right.kMinmax[1]) kMinmax[1    151   if(kMinmax[1] < _right.kMinmax[1]) kMinmax[1] = _right.kMinmax[1];
151                                                   152 
152   int num = kSize[0]*kSize[1];                    153   int num = kSize[0]*kSize[1];
153   for(int z = 0; z < kSize[2]; z++) {             154   for(int z = 0; z < kSize[2]; z++) {
154     for(int xy = 0; xy < num; xy++) {             155     for(int xy = 0; xy < num; xy++) {
155       kImage[z][xy] += _right.kImage[z][xy];      156       kImage[z][xy] += _right.kImage[z][xy];
156       if(kMinmax[0] > kImage[z][xy]) kMinmax[0    157       if(kMinmax[0] > kImage[z][xy]) kMinmax[0] = kImage[z][xy];
157       if(kMinmax[1] < kImage[z][xy]) kMinmax[1    158       if(kMinmax[1] < kImage[z][xy]) kMinmax[1] = kImage[z][xy];
158     }                                             159     }
159   }                                               160   }
160                                                   161 
161   kScale = kMinmax[1]/DOSERANGE;                  162   kScale = kMinmax[1]/DOSERANGE;
162                                                   163 
163   return *this;                                   164   return *this;
164 }                                                 165 }
165                                                   166 
166 template <typename T>                             167 template <typename T> 
167 void GMocrenDataPrimitive<T>::clear() {           168 void GMocrenDataPrimitive<T>::clear() {
168   for(int i = 0; i < 3; i++) {                    169   for(int i = 0; i < 3; i++) {
169     kSize[i] = 0;                                 170     kSize[i] = 0;
170     kCenter[i] = 0.;                              171     kCenter[i] = 0.;
171   }                                               172   }
172   kScale = 1.;                                    173   kScale = 1.;
173   kMinmax[0] = (T)32109;                          174   kMinmax[0] = (T)32109;
174   kMinmax[1] = (T)-32109;                         175   kMinmax[1] = (T)-32109;
175                                                   176 
176   clearImage();                                   177   clearImage();
177 }                                                 178 }
178 template <typename T>                             179 template <typename T> 
179 void GMocrenDataPrimitive<T>::clearImage() {      180 void GMocrenDataPrimitive<T>::clearImage() {
180   typename std::vector<T *>::iterator itr;        181   typename std::vector<T *>::iterator itr;
181   for(itr = kImage.begin(); itr != kImage.end(    182   for(itr = kImage.begin(); itr != kImage.end(); itr++) {
182     delete [] *itr;                               183     delete [] *itr;
183   }                                               184   }
184   kImage.clear();                                 185   kImage.clear();
185 }                                                 186 }
186 template <typename T>                             187 template <typename T> 
187 void GMocrenDataPrimitive<T>::setSize(int _siz    188 void GMocrenDataPrimitive<T>::setSize(int _size[3]) {
188   for(int i = 0; i < 3; i++) kSize[i] = _size[    189   for(int i = 0; i < 3; i++) kSize[i] = _size[i];
189 }                                                 190 }
190 template <typename T>                             191 template <typename T> 
191 void GMocrenDataPrimitive<T>::getSize(int _siz    192 void GMocrenDataPrimitive<T>::getSize(int _size[3]) {
192   for(int i = 0; i < 3; i++) _size[i] = kSize[    193   for(int i = 0; i < 3; i++) _size[i] = kSize[i];
193 }                                                 194 }
194 template <typename T>                             195 template <typename T> 
195 void GMocrenDataPrimitive<T>::setScale(double     196 void GMocrenDataPrimitive<T>::setScale(double & _scale) {
196   kScale = _scale;                                197   kScale = _scale;
197 }                                                 198 }
198 template <typename T>                             199 template <typename T> 
199 double GMocrenDataPrimitive<T>::getScale() {      200 double GMocrenDataPrimitive<T>::getScale() {
200   return kScale;                                  201   return kScale;
201 }                                                 202 }
202 template <typename T>                             203 template <typename T> 
203 void GMocrenDataPrimitive<T>::setMinMax(T _min    204 void GMocrenDataPrimitive<T>::setMinMax(T _minmax[2]) {
204   for(int i = 0; i < 2; i++) kMinmax[i] = _min    205   for(int i = 0; i < 2; i++) kMinmax[i] = _minmax[i];
205 }                                                 206 }
206 template <typename T>                             207 template <typename T> 
207 void GMocrenDataPrimitive<T>::getMinMax(T _min    208 void GMocrenDataPrimitive<T>::getMinMax(T _minmax[2]) {
208   for(int i = 0; i < 2; i++) _minmax[i] = kMin    209   for(int i = 0; i < 2; i++) _minmax[i] = kMinmax[i];
209                                                   210 
210 }                                                 211 }
211 template <typename T>                             212 template <typename T> 
212 void GMocrenDataPrimitive<T>::setImage(std::ve    213 void GMocrenDataPrimitive<T>::setImage(std::vector<T *> & _image) {
213   kImage = _image;                                214   kImage = _image;
214 }                                                 215 }
215 template <typename T>                             216 template <typename T> 
216 void GMocrenDataPrimitive<T>::addImage(T * _im    217 void GMocrenDataPrimitive<T>::addImage(T * _image) {
217   kImage.push_back(_image);                       218   kImage.push_back(_image);
218 }                                                 219 }
219 template <typename T>                             220 template <typename T> 
220 std::vector<T *> & GMocrenDataPrimitive<T>::ge    221 std::vector<T *> & GMocrenDataPrimitive<T>::getImage() {
221   return kImage;                                  222   return kImage;
222 }                                                 223 }
223 template <typename T>                             224 template <typename T> 
224 T * GMocrenDataPrimitive<T>::getImage(int _z)     225 T * GMocrenDataPrimitive<T>::getImage(int _z) {
225   if(_z >= (int)kImage.size())  return 0;         226   if(_z >= (int)kImage.size())  return 0;
226   return kImage[_z];                              227   return kImage[_z];
227 }                                                 228 }
228 template <typename T>                             229 template <typename T> 
229 void GMocrenDataPrimitive<T>::setCenterPositio    230 void GMocrenDataPrimitive<T>::setCenterPosition(float _center[3]) {
230   for(int i = 0; i < 3; i++) kCenter[i] = _cen    231   for(int i = 0; i < 3; i++) kCenter[i] = _center[i];
231 }                                                 232 }
232 template <typename T>                             233 template <typename T> 
233 void GMocrenDataPrimitive<T>::getCenterPositio    234 void GMocrenDataPrimitive<T>::getCenterPosition(float _center[3]) {
234   for(int i = 0; i < 3; i++) _center[i] = kCen    235   for(int i = 0; i < 3; i++) _center[i] = kCenter[i];
235 }                                                 236 }
236 template <typename T>                             237 template <typename T> 
237 void GMocrenDataPrimitive<T>::setName(std::str    238 void GMocrenDataPrimitive<T>::setName(std::string & _name) {
238   kDataName = _name;                              239   kDataName = _name;
239 }                                                 240 }
240 template <typename T>                             241 template <typename T> 
241 std::string GMocrenDataPrimitive<T>::getName()    242 std::string GMocrenDataPrimitive<T>::getName() {
242   return kDataName;                               243   return kDataName;
243 }                                                 244 }
244                                                   245 
245                                                   246 
246                                                   247 
247                                                   248 
248                                                   249 
249 GMocrenTrack::GMocrenTrack() {                    250 GMocrenTrack::GMocrenTrack() {
250     kTrack.clear();                               251     kTrack.clear();
251     for(int i = 0; i < 3; i++) kColor[i] = 0;     252     for(int i = 0; i < 3; i++) kColor[i] = 0;
252 }                                                 253 }
253                                                   254 
254 void GMocrenTrack::addStep(float _startx, floa    255 void GMocrenTrack::addStep(float _startx, float _starty, float _startz,
255          float _endx, float _endy, float _endz    256          float _endx, float _endy, float _endz) {
256   struct Step step;                               257   struct Step step;
257   step.startPoint[0] = _startx;                   258   step.startPoint[0] = _startx;
258   step.startPoint[1] = _starty;                   259   step.startPoint[1] = _starty;
259   step.startPoint[2] = _startz;                   260   step.startPoint[2] = _startz;
260   step.endPoint[0] = _endx;                       261   step.endPoint[0] = _endx;
261   step.endPoint[1] = _endy;                       262   step.endPoint[1] = _endy;
262   step.endPoint[2] = _endz;                       263   step.endPoint[2] = _endz;
263   kTrack.push_back(step);                         264   kTrack.push_back(step);
264 }                                                 265 }
265 void GMocrenTrack::getStep(float & _startx, fl    266 void GMocrenTrack::getStep(float & _startx, float & _starty, float & _startz,
266          float & _endx, float & _endy, float &    267          float & _endx, float & _endy, float & _endz,
267          int _num) {                              268          int _num) {
268   if(_num >= (int)kTrack.size()) {                269   if(_num >= (int)kTrack.size()) {
269     if (G4VisManager::GetVerbosity() >= G4VisM    270     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
270       G4cout << "GMocrenTrack::getStep(...) Er    271       G4cout << "GMocrenTrack::getStep(...) Error: "
271        << "invalid step # : " << _num << G4end    272        << "invalid step # : " << _num << G4endl;
272     return;                                       273     return;
273   }                                               274   }
274                                                   275 
275   _startx = kTrack[_num].startPoint[0];           276   _startx = kTrack[_num].startPoint[0];
276   _starty = kTrack[_num].startPoint[1];           277   _starty = kTrack[_num].startPoint[1];
277   _startz = kTrack[_num].startPoint[2];           278   _startz = kTrack[_num].startPoint[2];
278   _endx = kTrack[_num].endPoint[0];               279   _endx = kTrack[_num].endPoint[0];
279   _endy = kTrack[_num].endPoint[1];               280   _endy = kTrack[_num].endPoint[1];
280   _endz = kTrack[_num].endPoint[2];               281   _endz = kTrack[_num].endPoint[2];
281 }                                                 282 }
282 void GMocrenTrack::translate(std::vector<float    283 void GMocrenTrack::translate(std::vector<float> & _translate) {
283   std::vector<struct Step>::iterator itr = kTr    284   std::vector<struct Step>::iterator itr = kTrack.begin();
284   for(; itr != kTrack.end(); itr++) {             285   for(; itr != kTrack.end(); itr++) {
285     for(int i = 0; i < 3; i++ ) {                 286     for(int i = 0; i < 3; i++ ) {
286       itr->startPoint[i] += _translate[i];        287       itr->startPoint[i] += _translate[i];
287       itr->endPoint[i] += _translate[i];          288       itr->endPoint[i] += _translate[i];
288     }                                             289     }
289   }                                               290   } 
290 }                                                 291 }
291                                                   292 
292                                                   293 
293                                                   294 
294                                                   295 
295                                                   296 
296                                                   297 
297                                                   298 
298                                                   299 
299                                                   300 
300 GMocrenDetector::GMocrenDetector() {              301 GMocrenDetector::GMocrenDetector() {
301     kDetector.clear();                            302     kDetector.clear();
302     for(int i = 0; i < 3; i++) kColor[i] = 0;     303     for(int i = 0; i < 3; i++) kColor[i] = 0;
303 }                                                 304 }
304                                                   305 
305 void GMocrenDetector::addEdge(float _startx, f    306 void GMocrenDetector::addEdge(float _startx, float _starty, float _startz,
306             float _endx, float _endy, float _e    307             float _endx, float _endy, float _endz) {
307   struct Edge edge;                               308   struct Edge edge;
308   edge.startPoint[0] = _startx;                   309   edge.startPoint[0] = _startx;
309   edge.startPoint[1] = _starty;                   310   edge.startPoint[1] = _starty;
310   edge.startPoint[2] = _startz;                   311   edge.startPoint[2] = _startz;
311   edge.endPoint[0] = _endx;                       312   edge.endPoint[0] = _endx;
312   edge.endPoint[1] = _endy;                       313   edge.endPoint[1] = _endy;
313   edge.endPoint[2] = _endz;                       314   edge.endPoint[2] = _endz;
314   kDetector.push_back(edge);                      315   kDetector.push_back(edge);
315 }                                                 316 }
316 void GMocrenDetector::getEdge(float & _startx,    317 void GMocrenDetector::getEdge(float & _startx, float & _starty, float & _startz,
317          float & _endx, float & _endy, float &    318          float & _endx, float & _endy, float & _endz,
318          int _num) {                              319          int _num) {
319   if(_num >= (int)kDetector.size()) {             320   if(_num >= (int)kDetector.size()) {
320     if (G4VisManager::GetVerbosity() >= G4VisM    321     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
321       G4cout << "GMocrenDetector::getEdge(...)    322       G4cout << "GMocrenDetector::getEdge(...) Error: "
322        << "invalid edge # : " << _num << G4end    323        << "invalid edge # : " << _num << G4endl;
323     return;                                       324     return;
324   }                                               325   }
325                                                   326 
326   _startx = kDetector[_num].startPoint[0];        327   _startx = kDetector[_num].startPoint[0];
327   _starty = kDetector[_num].startPoint[1];        328   _starty = kDetector[_num].startPoint[1];
328   _startz = kDetector[_num].startPoint[2];        329   _startz = kDetector[_num].startPoint[2];
329   _endx = kDetector[_num].endPoint[0];            330   _endx = kDetector[_num].endPoint[0];
330   _endy = kDetector[_num].endPoint[1];            331   _endy = kDetector[_num].endPoint[1];
331   _endz = kDetector[_num].endPoint[2];            332   _endz = kDetector[_num].endPoint[2];
332 }                                                 333 }
333 void GMocrenDetector::translate(std::vector<fl    334 void GMocrenDetector::translate(std::vector<float> & _translate) {
334   std::vector<struct Edge>::iterator itr = kDe    335   std::vector<struct Edge>::iterator itr = kDetector.begin();
335   for(; itr != kDetector.end(); itr++) {          336   for(; itr != kDetector.end(); itr++) {
336     for(int i = 0; i < 3; i++) {                  337     for(int i = 0; i < 3; i++) {
337       itr->startPoint[i] += _translate[i];        338       itr->startPoint[i] += _translate[i];
338       itr->endPoint[i] += _translate[i];          339       itr->endPoint[i] += _translate[i];
339     }                                             340     } 
340   }                                               341   }
341 }                                                 342 }
342                                                   343 
343                                                   344 
344                                                   345 
345                                                   346 
346                                                   347 
347                                                   348 
348                                                   349 
349                                                   350 
350                                                   351 
351 // file information                               352 // file information
352 std::string G4GMocrenIO::kId;                     353 std::string G4GMocrenIO::kId;
353 std::string G4GMocrenIO::kVersion = "2.0.0";      354 std::string G4GMocrenIO::kVersion = "2.0.0";
354 int G4GMocrenIO::kNumberOfEvents = 0;             355 int G4GMocrenIO::kNumberOfEvents = 0;
355 char G4GMocrenIO::kLittleEndianInput = true;      356 char G4GMocrenIO::kLittleEndianInput = true;
356                                                   357 
357 #if BYTE_ORDER == LITTLE_ENDIAN                   358 #if BYTE_ORDER == LITTLE_ENDIAN
358 char G4GMocrenIO::kLittleEndianOutput = true;     359 char G4GMocrenIO::kLittleEndianOutput = true;
359 #else                                             360 #else
360 char G4GMocrenIO::kLittleEndianOutput = false;    361 char G4GMocrenIO::kLittleEndianOutput = false; // Big endian
361 #endif                                            362 #endif
362 std::string G4GMocrenIO::kComment;                363 std::string G4GMocrenIO::kComment;
363 //                                                364 //
364 std::string G4GMocrenIO::kFileName = "dose.gdd    365 std::string G4GMocrenIO::kFileName = "dose.gdd";
365                                                   366 
366 //                                                367 //
367 unsigned int G4GMocrenIO::kPointerToModalityDa    368 unsigned int G4GMocrenIO::kPointerToModalityData = 0;
368 std::vector<unsigned int> G4GMocrenIO::kPointe    369 std::vector<unsigned int> G4GMocrenIO::kPointerToDoseDistData;
369 unsigned int G4GMocrenIO::kPointerToROIData =     370 unsigned int G4GMocrenIO::kPointerToROIData = 0;
370 unsigned int G4GMocrenIO::kPointerToTrackData     371 unsigned int G4GMocrenIO::kPointerToTrackData = 0;
371 unsigned int G4GMocrenIO::kPointerToDetectorDa    372 unsigned int G4GMocrenIO::kPointerToDetectorData = 0;
372                                                   373 
373 // modality                                       374 // modality
374 float G4GMocrenIO::kVoxelSpacing[3] = {0., 0.,    375 float G4GMocrenIO::kVoxelSpacing[3] = {0., 0., 0.};
375 class GMocrenDataPrimitive<short>  G4GMocrenIO    376 class GMocrenDataPrimitive<short>  G4GMocrenIO::kModality;
376 std::vector<float> G4GMocrenIO::kModalityImage    377 std::vector<float> G4GMocrenIO::kModalityImageDensityMap;
377 std::string G4GMocrenIO::kModalityUnit = "g/cm    378 std::string G4GMocrenIO::kModalityUnit = "g/cm3       "; // 12 Bytes
378                                                   379 
379 // dose                                           380 // dose
380 std::vector<class GMocrenDataPrimitive<double>    381 std::vector<class GMocrenDataPrimitive<double> > G4GMocrenIO::kDose;
381 std::string G4GMocrenIO::kDoseUnit = "keV         382 std::string G4GMocrenIO::kDoseUnit = "keV         "; // 12 Bytes
382                                                   383 
383 // ROI                                            384 // ROI
384 std::vector<class GMocrenDataPrimitive<short>     385 std::vector<class GMocrenDataPrimitive<short> > G4GMocrenIO::kRoi;
385                                                   386 
386 // track                                          387 // track
387 std::vector<float *> G4GMocrenIO::kSteps;         388 std::vector<float *> G4GMocrenIO::kSteps;
388 std::vector<unsigned char *> G4GMocrenIO::kSte    389 std::vector<unsigned char *> G4GMocrenIO::kStepColors;
389 std::vector<class GMocrenTrack> G4GMocrenIO::k    390 std::vector<class GMocrenTrack> G4GMocrenIO::kTracks;
390                                                   391 
391 // detector                                       392 // detector
392 std::vector<class GMocrenDetector> G4GMocrenIO    393 std::vector<class GMocrenDetector> G4GMocrenIO::kDetectors;
393                                                   394 
394 // verbose                                        395 // verbose
395 int G4GMocrenIO::kVerbose = 0;                    396 int G4GMocrenIO::kVerbose = 0;
396                                                   397 
397 const int IDLENGTH  = 21;                         398 const int IDLENGTH  = 21;
398 const int VERLENGTH = 6;                          399 const int VERLENGTH = 6;
399                                                   400 
400 // constructor                                    401 // constructor
401 G4GMocrenIO::G4GMocrenIO()                        402 G4GMocrenIO::G4GMocrenIO()
402   : kTracksWillBeStored(true) {                   403   : kTracksWillBeStored(true) {
403   ;                                               404   ;
404 }                                                 405 }
405                                                   406 
406 // destructor                                     407 // destructor
407 G4GMocrenIO::~G4GMocrenIO() {                     408 G4GMocrenIO::~G4GMocrenIO() {
408   ;                                               409   ;
409 }                                                 410 }
410                                                   411 
411 // initialize                                     412 // initialize
412 void G4GMocrenIO::initialize() {                  413 void G4GMocrenIO::initialize() {
413                                                   414 
414   kId.clear();                                    415   kId.clear();
415   kVersion = "2.0.0";                             416   kVersion = "2.0.0";
416   kNumberOfEvents = 0;                            417   kNumberOfEvents = 0;
417   kLittleEndianInput = true;                      418   kLittleEndianInput = true;
418 #if BYTE_ORDER == LITTLE_ENDIAN                   419 #if BYTE_ORDER == LITTLE_ENDIAN
419   kLittleEndianOutput = true;                     420   kLittleEndianOutput = true;
420 #else // Big endian                               421 #else // Big endian
421   kLittleEndianOutput = false;                    422   kLittleEndianOutput = false;
422 #endif                                            423 #endif
423   kComment.clear();                               424   kComment.clear();
424   kFileName = "dose.gdd";                         425   kFileName = "dose.gdd";
425   kPointerToModalityData = 0;                     426   kPointerToModalityData = 0;
426   kPointerToDoseDistData.clear();                 427   kPointerToDoseDistData.clear();
427   kPointerToROIData = 0;                          428   kPointerToROIData = 0;
428   kPointerToTrackData = 0;                        429   kPointerToTrackData = 0;
429   // modality                                     430   // modality
430   for(int i = 0; i < 3; i++) kVoxelSpacing[i]     431   for(int i = 0; i < 3; i++) kVoxelSpacing[i] = 0.;
431   kModality.clear();                              432   kModality.clear();
432   kModalityImageDensityMap.clear();               433   kModalityImageDensityMap.clear();
433   kModalityUnit = "g/cm3       "; // 12 Bytes     434   kModalityUnit = "g/cm3       "; // 12 Bytes
434   // dose                                         435   // dose
435   kDose.clear();                                  436   kDose.clear();
436   kDoseUnit = "keV         "; // 12 Bytes         437   kDoseUnit = "keV         "; // 12 Bytes
437   // ROI                                          438   // ROI
438   kRoi.clear();                                   439   kRoi.clear();
439   // track                                        440   // track
440   std::vector<float *>::iterator itr;             441   std::vector<float *>::iterator itr;
441   for(itr = kSteps.begin(); itr != kSteps.end(    442   for(itr = kSteps.begin(); itr != kSteps.end(); itr++) delete [] *itr;
442   kSteps.clear();                                 443   kSteps.clear();
443   std::vector<unsigned char *>::iterator citr;    444   std::vector<unsigned char *>::iterator citr;
444   for(citr = kStepColors.begin(); citr != kSte    445   for(citr = kStepColors.begin(); citr != kStepColors.end(); citr++)
445     delete [] *citr;                              446     delete [] *citr;
446   kStepColors.clear();                            447   kStepColors.clear();
447   kTracksWillBeStored = true;                     448   kTracksWillBeStored = true;
448                                                   449 
449   // verbose                                      450   // verbose
450   kVerbose = 0;                                   451   kVerbose = 0;
451 }                                                 452 }
452                                                   453 
453 bool G4GMocrenIO::storeData() {                   454 bool G4GMocrenIO::storeData() {
454   return storeData4();                            455   return storeData4();
455 }                                                 456 }
456 //                                                457 //
457 bool G4GMocrenIO::storeData(char * _filename)     458 bool G4GMocrenIO::storeData(char * _filename) {
458   return storeData4(_filename);                   459   return storeData4(_filename);
459 }                                                 460 }
460                                                   461 
461 bool G4GMocrenIO::storeData4() {                  462 bool G4GMocrenIO::storeData4() {
462                                                   463 
463   bool DEBUG = false;//                           464   bool DEBUG = false;//
464                                                   465 
465   if(DEBUG || kVerbose > 0)                       466   if(DEBUG || kVerbose > 0)
466     G4cout << ">>>>>>>  store data (ver.4) <<<    467     G4cout << ">>>>>>>  store data (ver.4) <<<<<<<" << G4endl;
467   if(DEBUG || kVerbose > 0)                       468   if(DEBUG || kVerbose > 0)
468     G4cout << "         " << kFileName << G4en    469     G4cout << "         " << kFileName << G4endl;
469                                                   470 
470   // output file open                             471   // output file open
471   std::ofstream ofile(kFileName.c_str(),          472   std::ofstream ofile(kFileName.c_str(),
472           std::ios_base::out|std::ios_base::bi    473           std::ios_base::out|std::ios_base::binary);
473   if(DEBUG || kVerbose > 0)                       474   if(DEBUG || kVerbose > 0)
474     G4cout << "         file open status: " << << 475     G4cout << "         file open status: " << ofile << G4endl;
475                                                   476   
476   // file identifier                              477   // file identifier
477   ofile.write("gMocren ", 8);                     478   ofile.write("gMocren ", 8);
478                                                   479 
479   // file version                                 480   // file version
480   unsigned char ver = 0x04;                       481   unsigned char ver = 0x04;
481   ofile.write((char *)&ver, 1);                   482   ofile.write((char *)&ver, 1);
482                                                   483 
483   // endian                                       484   // endian
484   //ofile.write((char *)&kLittleEndianOutput,     485   //ofile.write((char *)&kLittleEndianOutput, sizeof(char));
485   char littleEndian = 0x01;                       486   char littleEndian = 0x01;
486   ofile.write((char *)&littleEndian, sizeof(ch    487   ofile.write((char *)&littleEndian, sizeof(char));
487   if(DEBUG || kVerbose > 0) {                     488   if(DEBUG || kVerbose > 0) {
488     //G4cout << "Endian: " << (int)kLittleEndi    489     //G4cout << "Endian: " << (int)kLittleEndianOutput << G4endl;
489     G4cout << "Endian: " << (int)littleEndian     490     G4cout << "Endian: " << (int)littleEndian << G4endl;
490   }                                               491   }
491                                                   492 
492   // for inverting the byte order                 493   // for inverting the byte order
493   float ftmp[6];                                  494   float ftmp[6];
494   int itmp[6];                                    495   int itmp[6];
495   short stmp[6];                                  496   short stmp[6];
496                                                   497 
497   // comment length (fixed size)                  498   // comment length (fixed size)
498   int commentLength = 1024;                       499   int commentLength = 1024;
499   if(kLittleEndianOutput) {                       500   if(kLittleEndianOutput) {
500     ofile.write((char *)&commentLength, 4);       501     ofile.write((char *)&commentLength, 4);
501   } else {                                        502   } else {
502     invertByteOrder((char *)&commentLength, it    503     invertByteOrder((char *)&commentLength, itmp[0]);
503     ofile.write((char *)itmp, 4);                 504     ofile.write((char *)itmp, 4);
504   }                                               505   }
505                                                   506 
506   // comment                                      507   // comment 
507   char cmt[1025];                                 508   char cmt[1025];
508   std::strncpy(cmt, kComment.c_str(), 1024);   << 509   for(int i = 0; i < 1025; i++) cmt[i] = '\0';
509   cmt[1024] = '\0';                            << 510   //std::strncpy(cmt, kComment.c_str(), 1024);
510   ofile.write(cmt, 1024);                      << 511   std::strcpy(cmt, kComment.c_str());
                                                   >> 512   ofile.write((char *)cmt, 1024);
511   if(DEBUG || kVerbose > 0) {                     513   if(DEBUG || kVerbose > 0) {
512     G4cout << "Data comment : "                   514     G4cout << "Data comment : "
513         << kComment << G4endl;                    515         << kComment << G4endl;
514   }                                               516   }
515                                                   517 
516   // voxel spacings for all images                518   // voxel spacings for all images
517   if(kLittleEndianOutput) {                       519   if(kLittleEndianOutput) {
518     ofile.write((char *)kVoxelSpacing, 12);       520     ofile.write((char *)kVoxelSpacing, 12);
519   } else {                                        521   } else {
520     for(int j = 0; j < 3; j++)                    522     for(int j = 0; j < 3; j++)
521       invertByteOrder((char *)&kVoxelSpacing[j    523       invertByteOrder((char *)&kVoxelSpacing[j], ftmp[j]);
522     ofile.write((char *)ftmp, 12);                524     ofile.write((char *)ftmp, 12);
523   }                                               525   }
524   if(DEBUG || kVerbose > 0) {                     526   if(DEBUG || kVerbose > 0) {
525     G4cout << "Voxel spacing : ("                 527     G4cout << "Voxel spacing : ("
526         << kVoxelSpacing[0] << ", "               528         << kVoxelSpacing[0] << ", "
527         << kVoxelSpacing[1] << ", "               529         << kVoxelSpacing[1] << ", "
528         << kVoxelSpacing[2]                       530         << kVoxelSpacing[2]
529         << ") mm " << G4endl;                     531         << ") mm " << G4endl;
530   }                                               532   }
531                                                   533 
532   calcPointers4();                                534   calcPointers4();
533   if(!kTracksWillBeStored) kPointerToTrackData    535   if(!kTracksWillBeStored) kPointerToTrackData = 0;
534                                                   536 
535   // offset from file starting point to the mo    537   // offset from file starting point to the modality image data
536   if(kLittleEndianOutput) {                       538   if(kLittleEndianOutput) {
537     ofile.write((char *)&kPointerToModalityDat    539     ofile.write((char *)&kPointerToModalityData, 4);
538   } else {                                        540   } else {
539     invertByteOrder((char *)&kPointerToModalit    541     invertByteOrder((char *)&kPointerToModalityData, itmp[0]);
540     ofile.write((char *)itmp, 4);                 542     ofile.write((char *)itmp, 4);
541   }                                               543   }
542                                                   544 
543   // # of dose distributions                      545   // # of dose distributions
544   //int nDoseDist = (int)pointerToDoseDistData    546   //int nDoseDist = (int)pointerToDoseDistData.size();
545   int nDoseDist = getNumDoseDist();               547   int nDoseDist = getNumDoseDist();
546   if(kLittleEndianOutput) {                       548   if(kLittleEndianOutput) {
547     ofile.write((char *)&nDoseDist, 4);           549     ofile.write((char *)&nDoseDist, 4);
548   } else {                                        550   } else {
549     invertByteOrder((char *)&nDoseDist, itmp[0    551     invertByteOrder((char *)&nDoseDist, itmp[0]);
550     ofile.write((char *)itmp, 4);                 552     ofile.write((char *)itmp, 4);
551   }                                               553   }
552                                                   554 
553   // offset from file starting point to the do    555   // offset from file starting point to the dose image data
554   if(kLittleEndianOutput) {                       556   if(kLittleEndianOutput) {
555     for(int i = 0; i < nDoseDist; i++) {          557     for(int i = 0; i < nDoseDist; i++) {
556       ofile.write((char *)&kPointerToDoseDistD    558       ofile.write((char *)&kPointerToDoseDistData[i], 4);
557     }                                             559     }
558   } else {                                        560   } else {
559     for(int i = 0; i < nDoseDist; i++) {          561     for(int i = 0; i < nDoseDist; i++) {
560       invertByteOrder((char *)&kPointerToDoseD    562       invertByteOrder((char *)&kPointerToDoseDistData[i], itmp[0]);
561       ofile.write((char *)itmp, 4);               563       ofile.write((char *)itmp, 4);
562     }                                             564     }
563   }                                               565   }
564                                                   566 
565   // offset from file starting point to the RO    567   // offset from file starting point to the ROI image data
566   if(kLittleEndianOutput) {                       568   if(kLittleEndianOutput) {
567     ofile.write((char *)&kPointerToROIData, 4)    569     ofile.write((char *)&kPointerToROIData, 4);
568   } else {                                        570   } else {
569     invertByteOrder((char *)&kPointerToROIData    571     invertByteOrder((char *)&kPointerToROIData, itmp[0]);
570     ofile.write((char *)itmp, 4);                 572     ofile.write((char *)itmp, 4);
571   }                                               573   }
572                                                   574 
573   // offset from file starting point to the tr    575   // offset from file starting point to the track data
574   if(kLittleEndianOutput) {                       576   if(kLittleEndianOutput) {
575     ofile.write((char *)&kPointerToTrackData,     577     ofile.write((char *)&kPointerToTrackData, 4);
576   } else {                                        578   } else {
577     invertByteOrder((char *)&kPointerToTrackDa    579     invertByteOrder((char *)&kPointerToTrackData, itmp[0]);
578     ofile.write((char *)itmp, 4);                 580     ofile.write((char *)itmp, 4);
579   }                                               581   }
580                                                   582 
581   // offset from file starting point to the de    583   // offset from file starting point to the detector data
582   if(kLittleEndianOutput) {                       584   if(kLittleEndianOutput) {
583     ofile.write((char *)&kPointerToDetectorDat    585     ofile.write((char *)&kPointerToDetectorData, 4);
584   } else {                                        586   } else {
585     invertByteOrder((char *)&kPointerToDetecto    587     invertByteOrder((char *)&kPointerToDetectorData, itmp[0]);
586     ofile.write((char *)itmp, 4);                 588     ofile.write((char *)itmp, 4);
587   }                                               589   }
588                                                   590 
589   if(DEBUG || kVerbose > 0) {                     591   if(DEBUG || kVerbose > 0) {
590     G4cout << "Each pointer to data : "           592     G4cout << "Each pointer to data : "
591         << kPointerToModalityData << ", ";        593         << kPointerToModalityData << ", ";
592     for(int i = 0; i < nDoseDist; i++) {          594     for(int i = 0; i < nDoseDist; i++) {
593       G4cout << kPointerToDoseDistData[i] << "    595       G4cout << kPointerToDoseDistData[i] << ", ";
594     }                                             596     }
595     G4cout << kPointerToROIData << ", "           597     G4cout << kPointerToROIData << ", "
596         << kPointerToTrackData << ", "            598         << kPointerToTrackData << ", "
597         << kPointerToDetectorData                 599         << kPointerToDetectorData
598         << G4endl;                                600         << G4endl;
599   }                                               601   }
600                                                   602 
601   //----- modality image -----//                  603   //----- modality image -----//
602                                                   604 
603   int size[3];                                    605   int size[3];
604   float scale;                                    606   float scale;
605   short minmax[2];                                607   short minmax[2];
606   float fCenter[3];                               608   float fCenter[3];
607   int iCenter[3];                                 609   int iCenter[3];
608   // modality image size                          610   // modality image size
609   kModality.getSize(size);                        611   kModality.getSize(size);
610                                                   612 
611   if(kLittleEndianOutput) {                       613   if(kLittleEndianOutput) {
612     ofile.write((char *)size, 3*sizeof(int));     614     ofile.write((char *)size, 3*sizeof(int));
613   } else {                                        615   } else {
614     for(int j = 0; j < 3; j++)                    616     for(int j = 0; j < 3; j++)
615       invertByteOrder((char *)&size[j], itmp[j    617       invertByteOrder((char *)&size[j], itmp[j]);
616     ofile.write((char *)itmp, 12);                618     ofile.write((char *)itmp, 12);
617   }                                               619   }
618                                                   620 
619   if(DEBUG || kVerbose > 0) {                     621   if(DEBUG || kVerbose > 0) {
620     G4cout << "Modality image size : ("           622     G4cout << "Modality image size : ("
621         << size[0] << ", "                        623         << size[0] << ", "
622         << size[1] << ", "                        624         << size[1] << ", "
623         << size[2] << ")"                         625         << size[2] << ")"
624         << G4endl;                                626         << G4endl;
625   }                                               627   }
626                                                   628 
627   // modality image max. & min.                   629   // modality image max. & min.
628   kModality.getMinMax(minmax);                    630   kModality.getMinMax(minmax);
629   if(kLittleEndianOutput) {                       631   if(kLittleEndianOutput) {
630     ofile.write((char *)minmax, 4);               632     ofile.write((char *)minmax, 4);
631   } else {                                        633   } else {
632     for(int j = 0; j < 2; j++)                    634     for(int j = 0; j < 2; j++)
633       invertByteOrder((char *)&minmax[j], stmp    635       invertByteOrder((char *)&minmax[j], stmp[j]);
634     ofile.write((char *)stmp, 4);                 636     ofile.write((char *)stmp, 4);
635   }                                               637   }
636                                                   638 
637   // modality image unit                          639   // modality image unit
638   char munit[13] = "g/cm3\0";                     640   char munit[13] = "g/cm3\0";
639   ofile.write((char *)munit, 12);                 641   ofile.write((char *)munit, 12);
640                                                   642 
641   // modality image scale                         643   // modality image scale
642   scale = (float)kModality.getScale();            644   scale = (float)kModality.getScale();
643   if(kLittleEndianOutput) {                       645   if(kLittleEndianOutput) {
644     ofile.write((char *)&scale, 4);               646     ofile.write((char *)&scale, 4);
645   } else {                                        647   } else {
646     invertByteOrder((char *)&scale, ftmp[0]);     648     invertByteOrder((char *)&scale, ftmp[0]);
647     ofile.write((char *)ftmp, 4);                 649     ofile.write((char *)ftmp, 4);
648   }                                               650   }
649   if(DEBUG || kVerbose > 0) {                     651   if(DEBUG || kVerbose > 0) {
650     G4cout << "Modality image min., max., scal    652     G4cout << "Modality image min., max., scale : "
651         << minmax[0] << ", "                      653         << minmax[0] << ", "
652         << minmax[1] << ", "                      654         << minmax[1] << ", "
653         << scale << G4endl;                       655         << scale << G4endl;
654   }                                               656   }
655                                                   657 
656   // modality image                               658   // modality image
657   int psize = size[0]*size[1];                    659   int psize = size[0]*size[1];
658   if(DEBUG || kVerbose > 0) G4cout << "Modalit    660   if(DEBUG || kVerbose > 0) G4cout << "Modality image : ";
659   for(int i = 0; i < size[2]; i++) {              661   for(int i = 0; i < size[2]; i++) {
660     short * image = kModality.getImage(i);        662     short * image = kModality.getImage(i);
661     if(kLittleEndianOutput) {                     663     if(kLittleEndianOutput) {
662       ofile.write((char *)image, psize*sizeof(    664       ofile.write((char *)image, psize*sizeof(short));
663     } else {                                      665     } else {
664       for(int j = 0; j < psize; j++) {            666       for(int j = 0; j < psize; j++) {
665   invertByteOrder((char *)&image[j], stmp[0]);    667   invertByteOrder((char *)&image[j], stmp[0]);
666   ofile.write((char *)stmp, 2);                   668   ofile.write((char *)stmp, 2);
667       }                                           669       }
668     }                                             670     }
669                                                   671 
670     if(DEBUG || kVerbose > 0) G4cout << "[" <<    672     if(DEBUG || kVerbose > 0) G4cout << "[" << i << "]" << image[(size_t)(psize*0.55)] << ", ";
671   }                                               673   }
672   if(DEBUG || kVerbose > 0) G4cout << G4endl;     674   if(DEBUG || kVerbose > 0) G4cout << G4endl;
673                                                   675 
674   // modality desity map for CT value             676   // modality desity map for CT value
675   size_t msize = minmax[1] - minmax[0]+1;         677   size_t msize = minmax[1] - minmax[0]+1;
676   if(DEBUG || kVerbose > 0)                       678   if(DEBUG || kVerbose > 0) 
677     G4cout << "modality image : " << minmax[0]    679     G4cout << "modality image : " << minmax[0] << ", " << minmax[1] << G4endl;
678   float * pdmap = new float[msize];               680   float * pdmap = new float[msize];
679   for(int i = 0; i < (int)msize; i++) pdmap[i]    681   for(int i = 0; i < (int)msize; i++) pdmap[i] =kModalityImageDensityMap[i]; 
680                                                   682 
681   if(kLittleEndianOutput) {                       683   if(kLittleEndianOutput) {
682     ofile.write((char *)pdmap, msize*sizeof(fl    684     ofile.write((char *)pdmap, msize*sizeof(float));
683   } else {                                        685   } else {
684     for(int j = 0; j < (int)msize; j++) {         686     for(int j = 0; j < (int)msize; j++) {
685       invertByteOrder((char *)&pdmap[j], ftmp[    687       invertByteOrder((char *)&pdmap[j], ftmp[0]);
686       ofile.write((char *)ftmp, 4);               688       ofile.write((char *)ftmp, 4);
687     }                                             689     }
688   }                                               690   }
689                                                   691 
690   if(DEBUG || kVerbose > 0) {                     692   if(DEBUG || kVerbose > 0) {
691     G4cout << "density map : " << std::ends;      693     G4cout << "density map : " << std::ends;
692     for(int i = 0; i < (int)msize; i+=50)         694     for(int i = 0; i < (int)msize; i+=50)
693       G4cout <<kModalityImageDensityMap[i] <<     695       G4cout <<kModalityImageDensityMap[i] << ", ";
694     G4cout << G4endl;                             696     G4cout << G4endl;
695   }                                               697   }
696   delete [] pdmap;                                698   delete [] pdmap;
697                                                   699 
698                                                   700 
699   //----- dose distribution image -----//         701   //----- dose distribution image -----//
700                                                   702 
701   if(!isDoseEmpty()) {                            703   if(!isDoseEmpty()) {
702                                                   704 
703     calcDoseDistScale();                          705     calcDoseDistScale();
704                                                   706 
705     for(int ndose = 0; ndose < nDoseDist; ndos    707     for(int ndose = 0; ndose < nDoseDist; ndose++) {
706       // dose distrbution image size              708       // dose distrbution image size
707       kDose[ndose].getSize(size);                 709       kDose[ndose].getSize(size);
708       if(kLittleEndianOutput) {                   710       if(kLittleEndianOutput) {
709   ofile.write((char *)size, 3*sizeof(int));       711   ofile.write((char *)size, 3*sizeof(int));
710       } else {                                    712       } else {
711   for(int j = 0; j < 3; j++)                      713   for(int j = 0; j < 3; j++)
712     invertByteOrder((char *)&size[j], itmp[j])    714     invertByteOrder((char *)&size[j], itmp[j]);
713   ofile.write((char *)itmp, 12);                  715   ofile.write((char *)itmp, 12);
714       }                                           716       }
715       if(DEBUG || kVerbose > 0) {                 717       if(DEBUG || kVerbose > 0) {
716   G4cout << "Dose dist. [" << ndose << "] imag    718   G4cout << "Dose dist. [" << ndose << "] image size : ("
717       << size[0] << ", "                          719       << size[0] << ", "
718       << size[1] << ", "                          720       << size[1] << ", "
719       << size[2] << ")"                           721       << size[2] << ")"
720       << G4endl;                                  722       << G4endl;
721       }                                           723       }
722                                                   724 
723       // dose distribution max. & min.            725       // dose distribution max. & min.
724       getShortDoseDistMinMax(minmax, ndose);      726       getShortDoseDistMinMax(minmax, ndose);
725       if(kLittleEndianOutput) {                   727       if(kLittleEndianOutput) {
726   ofile.write((char *)minmax, 2*2); // sizeof(    728   ofile.write((char *)minmax, 2*2); // sizeof(shorft)*2
727       } else {                                    729       } else {
728   for(int j = 0; j < 2; j++)                      730   for(int j = 0; j < 2; j++)
729     invertByteOrder((char *)&minmax[j], stmp[j    731     invertByteOrder((char *)&minmax[j], stmp[j]);
730   ofile.write((char *)stmp, 4);                   732   ofile.write((char *)stmp, 4);
731       }                                           733       }
732                                                   734 
733       // dose distribution unit                   735       // dose distribution unit
734       char cdunit[13];                            736       char cdunit[13];
735       std::strncpy(cdunit, kDoseUnit.c_str(),  << 737       for(int i = 0; i < 13; i++) cdunit[i] = '\0';
736       cdunit[12] = '\0';                       << 738       std::strcpy(cdunit, kDoseUnit.c_str());
737       ofile.write(cdunit, 12);                 << 739       ofile.write((char *)cdunit, 12);
738       if(DEBUG || kVerbose > 0) {                 740       if(DEBUG || kVerbose > 0) {
739   G4cout << "Dose dist. unit : " << kDoseUnit     741   G4cout << "Dose dist. unit : " << kDoseUnit << G4endl;
740       }                                           742       }
741                                                   743 
742       // dose distribution scaling                744       // dose distribution scaling 
743       double dscale;                              745       double dscale;
744       dscale = getDoseDistScale(ndose);           746       dscale = getDoseDistScale(ndose);
745       scale = float(dscale);                      747       scale = float(dscale);
746       if(kLittleEndianOutput) {                   748       if(kLittleEndianOutput) {
747   ofile.write((char *)&scale, 4);                 749   ofile.write((char *)&scale, 4);
748       } else {                                    750       } else {
749   invertByteOrder((char *)&scale, ftmp[0]);       751   invertByteOrder((char *)&scale, ftmp[0]);
750   ofile.write((char *)ftmp, 4);                   752   ofile.write((char *)ftmp, 4);
751       }                                           753       }
752       if(DEBUG || kVerbose > 0) {                 754       if(DEBUG || kVerbose > 0) {
753   G4cout << "Dose dist. [" << ndose               755   G4cout << "Dose dist. [" << ndose
754       << "] image min., max., scale : "           756       << "] image min., max., scale : "
755       << minmax[0] << ", "                        757       << minmax[0] << ", "
756       << minmax[1] << ", "                        758       << minmax[1] << ", "
757       << scale << G4endl;                         759       << scale << G4endl;
758       }                                           760       }
759                                                   761 
760       // dose distribution image                  762       // dose distribution image
761       int dsize = size[0]*size[1];                763       int dsize = size[0]*size[1];
762       short * dimage = new short[dsize];          764       short * dimage = new short[dsize];
763       for(int z = 0; z < size[2]; z++) {          765       for(int z = 0; z < size[2]; z++) {
764   getShortDoseDist(dimage, z, ndose);             766   getShortDoseDist(dimage, z, ndose);
765   if(kLittleEndianOutput) {                       767   if(kLittleEndianOutput) {
766     ofile.write((char *)dimage, dsize*2); //si    768     ofile.write((char *)dimage, dsize*2); //sizeof(short)
767   } else {                                        769   } else {
768     for(int j = 0; j < dsize; j++) {              770     for(int j = 0; j < dsize; j++) {
769       invertByteOrder((char *)&dimage[j], stmp    771       invertByteOrder((char *)&dimage[j], stmp[0]);
770       ofile.write((char *)stmp, 2);               772       ofile.write((char *)stmp, 2);
771     }                                             773     }
772   }                                               774   }
773                                                   775 
774   if(DEBUG || kVerbose > 0) {                     776   if(DEBUG || kVerbose > 0) {
775     for(int j = 0; j < dsize; j++) {              777     for(int j = 0; j < dsize; j++) {
776       if(dimage[j] < 0)                           778       if(dimage[j] < 0)
777         G4cout << "[" << j << "," << z << "]"     779         G4cout << "[" << j << "," << z << "]"
778       << dimage[j] << ", ";                       780       << dimage[j] << ", ";
779     }                                             781     }
780   }                                               782   }
781       }                                           783       }
782       if(DEBUG || kVerbose > 0) G4cout << G4en    784       if(DEBUG || kVerbose > 0) G4cout << G4endl;
783       delete [] dimage;                           785       delete [] dimage;
784                                                   786 
785       // relative location of the dose distrib    787       // relative location of the dose distribution image for 
786       // the modality image                       788       // the modality image
787       getDoseDistCenterPosition(fCenter, ndose    789       getDoseDistCenterPosition(fCenter, ndose);
788       for(int i = 0; i < 3; i++) iCenter[i] =     790       for(int i = 0; i < 3; i++) iCenter[i] = (int)fCenter[i];
789       if(kLittleEndianOutput) {                   791       if(kLittleEndianOutput) {
790   ofile.write((char *)iCenter, 3*4); // 3*size    792   ofile.write((char *)iCenter, 3*4); // 3*sizeof(int)
791       } else {                                    793       } else {
792   for(int j = 0; j < 3; j++)                      794   for(int j = 0; j < 3; j++)
793     invertByteOrder((char *)&iCenter[j], itmp[    795     invertByteOrder((char *)&iCenter[j], itmp[j]);
794   ofile.write((char *)itmp, 12);                  796   ofile.write((char *)itmp, 12);
795       }                                           797       }
796       if(DEBUG || kVerbose > 0) {                 798       if(DEBUG || kVerbose > 0) {
797   G4cout << "Dose dist. [" << ndose               799   G4cout << "Dose dist. [" << ndose
798       << "]image relative location : ("           800       << "]image relative location : ("
799       << iCenter[0] << ", "                       801       << iCenter[0] << ", "
800       << iCenter[1] << ", "                       802       << iCenter[1] << ", "
801       << iCenter[2] << ")" << G4endl;             803       << iCenter[2] << ")" << G4endl;
802       }                                           804       }
803                                                   805 
804       // dose distribution name                   806       // dose distribution name
805       std::string name = getDoseDistName(ndose    807       std::string name = getDoseDistName(ndose);
806       if(name.size() == 0) name = "dose";         808       if(name.size() == 0) name = "dose";
807       name.resize(80);                            809       name.resize(80);
808       ofile.write((char *)name.c_str(), 80);      810       ofile.write((char *)name.c_str(), 80);
809       if(DEBUG || kVerbose > 0) {                 811       if(DEBUG || kVerbose > 0) {
810   G4cout << "Dose dist. name : " << name << G4    812   G4cout << "Dose dist. name : " << name << G4endl;
811       }                                           813       }
812                                                   814 
813     }                                             815     }
814   }                                               816   }
815                                                   817 
816   //----- ROI image -----//                       818   //----- ROI image -----//
817   if(!isROIEmpty()) {                             819   if(!isROIEmpty()) {
818     // ROI image size                             820     // ROI image size
819     kRoi[0].getSize(size);                        821     kRoi[0].getSize(size);
820     if(kLittleEndianOutput) {                     822     if(kLittleEndianOutput) {
821       ofile.write((char *)size, 3*sizeof(int))    823       ofile.write((char *)size, 3*sizeof(int));
822     } else {                                      824     } else {
823       for(int j = 0; j < 3; j++)                  825       for(int j = 0; j < 3; j++)
824   invertByteOrder((char *)&size[j], itmp[j]);     826   invertByteOrder((char *)&size[j], itmp[j]);
825       ofile.write((char *)itmp, 12);              827       ofile.write((char *)itmp, 12);
826     }                                             828     }
827     if(DEBUG || kVerbose > 0) {                   829     if(DEBUG || kVerbose > 0) {
828       G4cout << "ROI image size : ("              830       G4cout << "ROI image size : ("
829     << size[0] << ", "                            831     << size[0] << ", "
830     << size[1] << ", "                            832     << size[1] << ", "
831     << size[2] << ")"                             833     << size[2] << ")"
832     << G4endl;                                    834     << G4endl;
833     }                                             835     }
834                                                   836 
835     // ROI max. & min.                            837     // ROI max. & min.
836     kRoi[0].getMinMax(minmax);                    838     kRoi[0].getMinMax(minmax);
837     if(kLittleEndianOutput) {                     839     if(kLittleEndianOutput) {
838       ofile.write((char *)minmax, sizeof(short    840       ofile.write((char *)minmax, sizeof(short)*2);
839     } else {                                      841     } else {
840       for(int j = 0; j < 2; j++)                  842       for(int j = 0; j < 2; j++)
841   invertByteOrder((char *)&minmax[j], stmp[j])    843   invertByteOrder((char *)&minmax[j], stmp[j]);
842       ofile.write((char *)stmp, 4);               844       ofile.write((char *)stmp, 4);
843     }                                             845     }
844                                                   846 
845     // ROI distribution scaling                   847     // ROI distribution scaling 
846     scale = (float)kRoi[0].getScale();            848     scale = (float)kRoi[0].getScale();
847     if(kLittleEndianOutput) {                     849     if(kLittleEndianOutput) {
848       ofile.write((char *)&scale, sizeof(float    850       ofile.write((char *)&scale, sizeof(float));
849     } else {                                      851     } else {
850       invertByteOrder((char *)&scale, ftmp[0])    852       invertByteOrder((char *)&scale, ftmp[0]);
851       ofile.write((char *)ftmp, 4);               853       ofile.write((char *)ftmp, 4);
852     }                                             854     }
853     if(DEBUG || kVerbose > 0) {                   855     if(DEBUG || kVerbose > 0) {
854       G4cout << "ROI image min., max., scale :    856       G4cout << "ROI image min., max., scale : "
855     << minmax[0] << ", "                          857     << minmax[0] << ", "
856     << minmax[1] << ", "                          858     << minmax[1] << ", "
857     << scale << G4endl;                           859     << scale << G4endl;
858     }                                             860     }
859                                                   861 
860     // ROI image                                  862     // ROI image
861     int rsize = size[0]*size[1];                  863     int rsize = size[0]*size[1];
862     for(int i = 0; i < size[2]; i++) {            864     for(int i = 0; i < size[2]; i++) {
863       short * rimage = kRoi[0].getImage(i);       865       short * rimage = kRoi[0].getImage(i);
864       if(kLittleEndianOutput) {                   866       if(kLittleEndianOutput) {
865   ofile.write((char *)rimage, rsize*sizeof(sho    867   ofile.write((char *)rimage, rsize*sizeof(short));
866       } else {                                    868       } else {
867   for(int j = 0; j < rsize; j++) {                869   for(int j = 0; j < rsize; j++) {
868     invertByteOrder((char *)&rimage[j], stmp[0    870     invertByteOrder((char *)&rimage[j], stmp[0]);
869     ofile.write((char *)stmp, 2);                 871     ofile.write((char *)stmp, 2);
870   }                                               872   }
871       }                                           873       }
872                                                   874 
873     }                                             875     }
874                                                   876 
875     // ROI relative location                      877     // ROI relative location
876     kRoi[0].getCenterPosition(fCenter);           878     kRoi[0].getCenterPosition(fCenter);
877     for(int i = 0; i < 3; i++) iCenter[i] = (i    879     for(int i = 0; i < 3; i++) iCenter[i] = (int)fCenter[i];
878     if(kLittleEndianOutput) {                     880     if(kLittleEndianOutput) {
879       ofile.write((char *)iCenter, 3*sizeof(in    881       ofile.write((char *)iCenter, 3*sizeof(int));
880     } else {                                      882     } else {
881       for(int j = 0; j < 3; j++)                  883       for(int j = 0; j < 3; j++)
882   invertByteOrder((char *)&iCenter[j], itmp[j]    884   invertByteOrder((char *)&iCenter[j], itmp[j]);
883       ofile.write((char *)itmp, 12);              885       ofile.write((char *)itmp, 12);
884     }                                             886     }
885     if(DEBUG || kVerbose > 0) {                   887     if(DEBUG || kVerbose > 0) {
886       G4cout << "ROI image relative location :    888       G4cout << "ROI image relative location : ("
887     << iCenter[0] << ", "                         889     << iCenter[0] << ", "
888     << iCenter[1] << ", "                         890     << iCenter[1] << ", "
889     << iCenter[2] << ")" << G4endl;               891     << iCenter[2] << ")" << G4endl;
890     }                                             892     }
891   }                                               893   }
892                                                   894 
893   //----- track information -----//               895   //----- track information -----//
894   // number of track                              896   // number of track 
895   if(kPointerToTrackData > 0) {                   897   if(kPointerToTrackData > 0) {
896                                                   898 
897     int ntrk = (int)kTracks.size();            << 899     int ntrk = kTracks.size();
898     if(kLittleEndianOutput) {                     900     if(kLittleEndianOutput) {
899       ofile.write((char *)&ntrk, sizeof(int));    901       ofile.write((char *)&ntrk, sizeof(int));
900     } else {                                      902     } else {
901       invertByteOrder((char *)&ntrk, itmp[0]);    903       invertByteOrder((char *)&ntrk, itmp[0]);
902       ofile.write((char *)itmp, 4);               904       ofile.write((char *)itmp, 4);
903     }                                             905     }
904     if(DEBUG || kVerbose > 0) {                   906     if(DEBUG || kVerbose > 0) {
905       G4cout << "# of tracks : "                  907       G4cout << "# of tracks : "
906     << ntrk << G4endl;                            908     << ntrk << G4endl;
907     }                                             909     }
908                                                   910 
909     for(int nt = 0; nt < ntrk; nt++) {            911     for(int nt = 0; nt < ntrk; nt++) {
910                                                   912 
911       // # of steps in a track                    913       // # of steps in a track
912       int nsteps = kTracks[nt].getNumberOfStep    914       int nsteps = kTracks[nt].getNumberOfSteps();
913       if(kLittleEndianOutput) {                   915       if(kLittleEndianOutput) {
914   ofile.write((char *)&nsteps, sizeof(int));      916   ofile.write((char *)&nsteps, sizeof(int));
915       } else {                                    917       } else {
916   invertByteOrder((char *)&nsteps, itmp[0]);      918   invertByteOrder((char *)&nsteps, itmp[0]);
917   ofile.write((char *)itmp, 4);                   919   ofile.write((char *)itmp, 4);
918       }                                           920       }
919       if(DEBUG || kVerbose > 0) {                 921       if(DEBUG || kVerbose > 0) {
920   G4cout << "# of steps : " << nsteps << G4end    922   G4cout << "# of steps : " << nsteps << G4endl;
921       }                                           923       }
922                                                   924 
923       // track color                              925       // track color
924       unsigned char tcolor[3];                    926       unsigned char tcolor[3];
925       kTracks[nt].getColor(tcolor);               927       kTracks[nt].getColor(tcolor);
926       ofile.write((char *)tcolor, 3);             928       ofile.write((char *)tcolor, 3);
927                                                   929 
928       // steps                                    930       // steps
929       float stepPoints[6];                        931       float stepPoints[6];
930       for(int isteps = 0; isteps < nsteps; ist << 932       for(int ns = 0; ns < nsteps; ns++) {
931   kTracks[nt].getStep(stepPoints[0], stepPoint    933   kTracks[nt].getStep(stepPoints[0], stepPoints[1], stepPoints[2],
932           stepPoints[3], stepPoints[4], stepPo    934           stepPoints[3], stepPoints[4], stepPoints[5],
933           isteps);                             << 935           ns);
934                                                   936 
935   if(kLittleEndianOutput) {                       937   if(kLittleEndianOutput) {
936     ofile.write((char *)stepPoints, sizeof(flo    938     ofile.write((char *)stepPoints, sizeof(float)*6);
937   } else {                                        939   } else {
938     for(int j = 0; j < 6; j++)                    940     for(int j = 0; j < 6; j++)
939       invertByteOrder((char *)&stepPoints[j],     941       invertByteOrder((char *)&stepPoints[j], ftmp[j]);
940     ofile.write((char *)ftmp, 24);                942     ofile.write((char *)ftmp, 24);
941   }                                               943   }
942       }                                           944       }
943     }                                             945     }
944   }                                               946   }
945                                                   947 
946   //----- detector information -----//            948   //----- detector information -----//
947   // number of detectors                          949   // number of detectors
948   if(kPointerToDetectorData > 0) {                950   if(kPointerToDetectorData > 0) {
949     int ndet = (int)kDetectors.size();         << 951     int ndet = kDetectors.size();
950     if(kLittleEndianOutput) {                     952     if(kLittleEndianOutput) {
951       ofile.write((char *)&ndet, sizeof(int));    953       ofile.write((char *)&ndet, sizeof(int));
952     } else {                                      954     } else {
953       invertByteOrder((char *)&ndet, itmp[0]);    955       invertByteOrder((char *)&ndet, itmp[0]);
954       ofile.write((char *)itmp, 4);               956       ofile.write((char *)itmp, 4);
955     }                                             957     }
956     if(DEBUG || kVerbose > 0) {                   958     if(DEBUG || kVerbose > 0) {
957       G4cout << "# of detectors : "               959       G4cout << "# of detectors : "
958     << ndet << G4endl;                            960     << ndet << G4endl;
959     }                                             961     }
960                                                   962 
961     for(int nd = 0; nd < ndet; nd++) {            963     for(int nd = 0; nd < ndet; nd++) {
962                                                   964 
963       // # of edges of a detector                 965       // # of edges of a detector
964       int nedges = kDetectors[nd].getNumberOfE    966       int nedges = kDetectors[nd].getNumberOfEdges();
965       if(kLittleEndianOutput) {                   967       if(kLittleEndianOutput) {
966   ofile.write((char *)&nedges, sizeof(int));      968   ofile.write((char *)&nedges, sizeof(int));
967       } else {                                    969       } else {
968   invertByteOrder((char *)&nedges, itmp[0]);      970   invertByteOrder((char *)&nedges, itmp[0]);
969   ofile.write((char *)itmp, 4);                   971   ofile.write((char *)itmp, 4);
970       }                                           972       }
971       if(DEBUG || kVerbose > 0) {                 973       if(DEBUG || kVerbose > 0) {
972   G4cout << "# of edges in a detector : " << n    974   G4cout << "# of edges in a detector : " << nedges << G4endl;
973       }                                           975       }
974                                                   976 
975       // edges                                    977       // edges
976       float edgePoints[6];                        978       float edgePoints[6];
977       for(int ne = 0; ne < nedges; ne++) {        979       for(int ne = 0; ne < nedges; ne++) {
978   kDetectors[nd].getEdge(edgePoints[0], edgePo    980   kDetectors[nd].getEdge(edgePoints[0], edgePoints[1], edgePoints[2],
979              edgePoints[3], edgePoints[4], edg    981              edgePoints[3], edgePoints[4], edgePoints[5],
980              ne);                                 982              ne);
981                                                   983 
982   if(kLittleEndianOutput) {                       984   if(kLittleEndianOutput) {
983     ofile.write((char *)edgePoints, sizeof(flo    985     ofile.write((char *)edgePoints, sizeof(float)*6);
984   } else {                                        986   } else {
985     for(int j = 0; j < 6; j++)                    987     for(int j = 0; j < 6; j++)
986       invertByteOrder((char *)&edgePoints[j],     988       invertByteOrder((char *)&edgePoints[j], ftmp[j]);
987     ofile.write((char *)ftmp, 24);                989     ofile.write((char *)ftmp, 24);
988   }                                               990   }
989                                                   991 
990   if(DEBUG || kVerbose > 0) {                     992   if(DEBUG || kVerbose > 0) {
991     if(ne < 1) {                                  993     if(ne < 1) {
992       G4cout << " edge : (" << edgePoints[0] <    994       G4cout << " edge : (" << edgePoints[0] << ", "
993           << edgePoints[1] << ", "                995           << edgePoints[1] << ", "
994           << edgePoints[2] << ") - ("             996           << edgePoints[2] << ") - ("
995           << edgePoints[3] << ", "                997           << edgePoints[3] << ", "
996           << edgePoints[4] << ", "                998           << edgePoints[4] << ", "
997           << edgePoints[5] << ")" << G4endl;      999           << edgePoints[5] << ")" << G4endl;
998     }                                             1000     }
999   }                                               1001   }
1000       }                                          1002       }
1001                                                  1003 
1002       // detector color                          1004       // detector color
1003       unsigned char dcolor[3];                   1005       unsigned char dcolor[3];
1004       kDetectors[nd].getColor(dcolor);           1006       kDetectors[nd].getColor(dcolor);
1005       ofile.write((char *)dcolor, 3);            1007       ofile.write((char *)dcolor, 3);
1006       if(DEBUG || kVerbose > 0) {                1008       if(DEBUG || kVerbose > 0) {
1007   G4cout << " rgb : (" << (int)dcolor[0] << "    1009   G4cout << " rgb : (" << (int)dcolor[0] << ", "
1008       << (int)dcolor[1] << ", "                  1010       << (int)dcolor[1] << ", "
1009       << (int)dcolor[2] << ")" << G4endl;        1011       << (int)dcolor[2] << ")" << G4endl;
1010       }                                          1012       }
1011                                                  1013 
1012       // detector name                           1014       // detector name
1013       std::string dname = kDetectors[nd].getN    1015       std::string dname = kDetectors[nd].getName();
1014       dname.resize(80);                          1016       dname.resize(80);
1015       ofile.write((char *)dname.c_str(), 80);    1017       ofile.write((char *)dname.c_str(), 80);
1016       if(DEBUG || kVerbose > 0) {                1018       if(DEBUG || kVerbose > 0) {
1017   G4cout << " detector name : " << dname << G    1019   G4cout << " detector name : " << dname << G4endl;
1018                                                  1020       
1019       }                                          1021       }
1020     }                                            1022     }
1021   }                                              1023   }
1022                                                  1024 
1023   // file end mark                               1025   // file end mark
1024   ofile.write("END", 3);                         1026   ofile.write("END", 3);
1025                                                  1027 
1026   ofile.close();                                 1028   ofile.close();
1027   if(DEBUG || kVerbose > 0)                      1029   if(DEBUG || kVerbose > 0)
1028     G4cout << ">>>> closed gdd file: " << kFi    1030     G4cout << ">>>> closed gdd file: " << kFileName << G4endl;
1029                                                  1031 
1030   return true;                                   1032   return true;
1031 }                                                1033 }
1032 bool G4GMocrenIO::storeData3() {                 1034 bool G4GMocrenIO::storeData3() {
1033                                                  1035 
1034   if(kVerbose > 0) G4cout << ">>>>>>>  store     1036   if(kVerbose > 0) G4cout << ">>>>>>>  store data (ver.3) <<<<<<<" << G4endl;
1035   if(kVerbose > 0) G4cout << "         " << k    1037   if(kVerbose > 0) G4cout << "         " << kFileName << G4endl;
1036                                                  1038 
1037   bool DEBUG = false;//                          1039   bool DEBUG = false;//
1038                                                  1040 
1039   // output file open                            1041   // output file open
1040   std::ofstream ofile(kFileName.c_str(),         1042   std::ofstream ofile(kFileName.c_str(),
1041           std::ios_base::out|std::ios_base::b    1043           std::ios_base::out|std::ios_base::binary);
1042                                                  1044 
1043   // file identifier                             1045   // file identifier
1044   ofile.write("gMocren ", 8);                    1046   ofile.write("gMocren ", 8);
1045                                                  1047 
1046   // file version                                1048   // file version
1047   unsigned char ver = 0x03;                      1049   unsigned char ver = 0x03;
1048   ofile.write((char *)&ver, 1);                  1050   ofile.write((char *)&ver, 1);
1049                                                  1051 
1050   // endian                                      1052   // endian
1051   ofile.write((char *)&kLittleEndianOutput, s    1053   ofile.write((char *)&kLittleEndianOutput, sizeof(char));
1052                                                  1054 
1053   // comment length (fixed size)                 1055   // comment length (fixed size)
1054   int commentLength = 1024;                      1056   int commentLength = 1024;
1055   ofile.write((char *)&commentLength, 4);        1057   ofile.write((char *)&commentLength, 4);
1056                                                  1058 
1057   // comment                                     1059   // comment 
1058   char cmt[1025];                                1060   char cmt[1025];
1059   std::strncpy(cmt, kComment.c_str(), 1024);     1061   std::strncpy(cmt, kComment.c_str(), 1024);
1060   ofile.write((char *)cmt, 1024);                1062   ofile.write((char *)cmt, 1024);
1061   if(DEBUG || kVerbose > 0) {                    1063   if(DEBUG || kVerbose > 0) {
1062     G4cout << "Data comment : "                  1064     G4cout << "Data comment : "
1063         << kComment << G4endl;                   1065         << kComment << G4endl;
1064   }                                              1066   }
1065                                                  1067 
1066   // voxel spacings for all images               1068   // voxel spacings for all images
1067   ofile.write((char *)kVoxelSpacing, 12);        1069   ofile.write((char *)kVoxelSpacing, 12);
1068   if(DEBUG || kVerbose > 0) {                    1070   if(DEBUG || kVerbose > 0) {
1069     G4cout << "Voxel spacing : ("                1071     G4cout << "Voxel spacing : ("
1070         << kVoxelSpacing[0] << ", "              1072         << kVoxelSpacing[0] << ", "
1071         << kVoxelSpacing[1] << ", "              1073         << kVoxelSpacing[1] << ", "
1072         << kVoxelSpacing[2]                      1074         << kVoxelSpacing[2]
1073         << ") mm " << G4endl;                    1075         << ") mm " << G4endl;
1074   }                                              1076   }
1075                                                  1077 
1076   calcPointers3();                               1078   calcPointers3();
1077                                                  1079 
1078   // offset from file starting point to the m    1080   // offset from file starting point to the modality image data
1079   ofile.write((char *)&kPointerToModalityData    1081   ofile.write((char *)&kPointerToModalityData, 4);
1080                                                  1082 
1081   // # of dose distributions                     1083   // # of dose distributions
1082   //int nDoseDist = (int)pointerToDoseDistDat    1084   //int nDoseDist = (int)pointerToDoseDistData.size();
1083   int nDoseDist = getNumDoseDist();              1085   int nDoseDist = getNumDoseDist();
1084   ofile.write((char *)&nDoseDist, 4);            1086   ofile.write((char *)&nDoseDist, 4);
1085                                                  1087 
1086   // offset from file starting point to the d    1088   // offset from file starting point to the dose image data
1087   for(int i = 0; i < nDoseDist; i++) {           1089   for(int i = 0; i < nDoseDist; i++) {
1088     ofile.write((char *)&kPointerToDoseDistDa    1090     ofile.write((char *)&kPointerToDoseDistData[i], 4);
1089   }                                              1091   }
1090                                                  1092 
1091   // offset from file starting point to the R    1093   // offset from file starting point to the ROI image data
1092   ofile.write((char *)&kPointerToROIData, 4);    1094   ofile.write((char *)&kPointerToROIData, 4);
1093                                                  1095 
1094   // offset from file starting point to the t    1096   // offset from file starting point to the track data
1095   ofile.write((char *)&kPointerToTrackData, 4    1097   ofile.write((char *)&kPointerToTrackData, 4);
1096   if(DEBUG || kVerbose > 0) {                    1098   if(DEBUG || kVerbose > 0) {
1097     G4cout << "Each pointer to data : "          1099     G4cout << "Each pointer to data : "
1098         << kPointerToModalityData << ", ";       1100         << kPointerToModalityData << ", ";
1099     for(int i = 0; i < nDoseDist; i++) {         1101     for(int i = 0; i < nDoseDist; i++) {
1100       G4cout << kPointerToDoseDistData[i] <<     1102       G4cout << kPointerToDoseDistData[i] << ", ";
1101     }                                            1103     }
1102     G4cout << kPointerToROIData << ", "          1104     G4cout << kPointerToROIData << ", "
1103         << kPointerToTrackData << G4endl;        1105         << kPointerToTrackData << G4endl;
1104   }                                              1106   }
1105                                                  1107 
1106   //----- modality image -----//                 1108   //----- modality image -----//
1107                                                  1109 
1108   int size[3];                                   1110   int size[3];
1109   float scale;                                   1111   float scale;
1110   short minmax[2];                               1112   short minmax[2];
1111   float fCenter[3];                              1113   float fCenter[3];
1112   int iCenter[3];                                1114   int iCenter[3];
1113   // modality image size                         1115   // modality image size
1114   kModality.getSize(size);                       1116   kModality.getSize(size);
1115   ofile.write((char *)size, 3*sizeof(int));      1117   ofile.write((char *)size, 3*sizeof(int));
1116   if(DEBUG || kVerbose > 0) {                    1118   if(DEBUG || kVerbose > 0) {
1117     G4cout << "Modality image size : ("          1119     G4cout << "Modality image size : ("
1118         << size[0] << ", "                       1120         << size[0] << ", "
1119         << size[1] << ", "                       1121         << size[1] << ", "
1120         << size[2] << ")"                        1122         << size[2] << ")"
1121         << G4endl;                               1123         << G4endl;
1122   }                                              1124   }
1123                                                  1125 
1124   // modality image max. & min.                  1126   // modality image max. & min.
1125   kModality.getMinMax(minmax);                   1127   kModality.getMinMax(minmax);
1126   ofile.write((char *)minmax, 4);                1128   ofile.write((char *)minmax, 4);
1127                                                  1129 
1128   // modality image unit                         1130   // modality image unit
1129   char munit[13] = "g/cm3       ";               1131   char munit[13] = "g/cm3       ";
1130   ofile.write((char *)munit, 12);                1132   ofile.write((char *)munit, 12);
1131                                                  1133 
1132   // modality image scale                        1134   // modality image scale
1133   scale = (float)kModality.getScale();           1135   scale = (float)kModality.getScale();
1134   ofile.write((char *)&scale, 4);                1136   ofile.write((char *)&scale, 4);
1135   if(DEBUG || kVerbose > 0) {                    1137   if(DEBUG || kVerbose > 0) {
1136     G4cout << "Modality image min., max., sca    1138     G4cout << "Modality image min., max., scale : "
1137         << minmax[0] << ", "                     1139         << minmax[0] << ", "
1138         << minmax[1] << ", "                     1140         << minmax[1] << ", "
1139         << scale << G4endl;                      1141         << scale << G4endl;
1140   }                                              1142   }
1141                                                  1143 
1142   // modality image                              1144   // modality image
1143   int psize = size[0]*size[1];                   1145   int psize = size[0]*size[1];
1144   if(DEBUG || kVerbose > 0) G4cout << "Modali    1146   if(DEBUG || kVerbose > 0) G4cout << "Modality image : ";
1145   for(int i = 0; i < size[2]; i++) {             1147   for(int i = 0; i < size[2]; i++) {
1146     short * image = kModality.getImage(i);       1148     short * image = kModality.getImage(i);
1147     ofile.write((char *)image, psize*sizeof(s    1149     ofile.write((char *)image, psize*sizeof(short));
1148                                                  1150 
1149     if(DEBUG || kVerbose > 0) G4cout << "[" <    1151     if(DEBUG || kVerbose > 0) G4cout << "[" << i << "]" << image[(size_t)(psize*0.55)] << ", ";
1150   }                                              1152   }
1151   if(DEBUG || kVerbose > 0) G4cout << G4endl;    1153   if(DEBUG || kVerbose > 0) G4cout << G4endl;
1152                                                  1154 
1153   // modality desity map for CT value            1155   // modality desity map for CT value
1154   size_t msize = minmax[1] - minmax[0]+1;        1156   size_t msize = minmax[1] - minmax[0]+1;
1155   float * pdmap = new float[msize];              1157   float * pdmap = new float[msize];
1156   for(int i = 0; i < (int)msize; i++) pdmap[i    1158   for(int i = 0; i < (int)msize; i++) pdmap[i] =kModalityImageDensityMap[i]; 
1157   ofile.write((char *)pdmap, msize*sizeof(flo    1159   ofile.write((char *)pdmap, msize*sizeof(float));
1158   if(DEBUG || kVerbose > 0) {                    1160   if(DEBUG || kVerbose > 0) {
1159     G4cout << "density map : " << std::ends;     1161     G4cout << "density map : " << std::ends;
1160     for(int i = 0; i < (int)msize; i+=50)        1162     for(int i = 0; i < (int)msize; i+=50)
1161       G4cout <<kModalityImageDensityMap[i] <<    1163       G4cout <<kModalityImageDensityMap[i] << ", ";
1162     G4cout << G4endl;                            1164     G4cout << G4endl;
1163   }                                              1165   }
1164   delete [] pdmap;                               1166   delete [] pdmap;
1165                                                  1167 
1166                                                  1168 
1167   //----- dose distribution image -----//        1169   //----- dose distribution image -----//
1168                                                  1170 
1169   if(!isDoseEmpty()) {                           1171   if(!isDoseEmpty()) {
1170                                                  1172 
1171     calcDoseDistScale();                         1173     calcDoseDistScale();
1172                                                  1174 
1173     for(int ndose = 0; ndose < nDoseDist; ndo    1175     for(int ndose = 0; ndose < nDoseDist; ndose++) {
1174       // dose distrbution image size             1176       // dose distrbution image size
1175       kDose[ndose].getSize(size);                1177       kDose[ndose].getSize(size);
1176       ofile.write((char *)size, 3*sizeof(int)    1178       ofile.write((char *)size, 3*sizeof(int));
1177       if(DEBUG || kVerbose > 0) {                1179       if(DEBUG || kVerbose > 0) {
1178   G4cout << "Dose dist. [" << ndose << "] ima    1180   G4cout << "Dose dist. [" << ndose << "] image size : ("
1179       << size[0] << ", "                         1181       << size[0] << ", "
1180       << size[1] << ", "                         1182       << size[1] << ", "
1181       << size[2] << ")"                          1183       << size[2] << ")"
1182       << G4endl;                                 1184       << G4endl;
1183       }                                          1185       }
1184                                                  1186 
1185       // dose distribution max. & min.           1187       // dose distribution max. & min.
1186       getShortDoseDistMinMax(minmax, ndose);     1188       getShortDoseDistMinMax(minmax, ndose);
1187       ofile.write((char *)minmax, 2*2); // si    1189       ofile.write((char *)minmax, 2*2); // sizeof(shorft)*2
1188                                                  1190 
1189       // dose distribution unit                  1191       // dose distribution unit
1190       ofile.write((char *)kDoseUnit.c_str(),     1192       ofile.write((char *)kDoseUnit.c_str(), 12);
1191       if(DEBUG || kVerbose > 0) {                1193       if(DEBUG || kVerbose > 0) {
1192   G4cout << "Dose dist. unit : " << kDoseUnit    1194   G4cout << "Dose dist. unit : " << kDoseUnit << G4endl;
1193       }                                          1195       }
1194                                                  1196 
1195       // dose distribution scaling               1197       // dose distribution scaling 
1196       double dscale;                             1198       double dscale;
1197       dscale = getDoseDistScale(ndose);          1199       dscale = getDoseDistScale(ndose);
1198       scale = float(dscale);                     1200       scale = float(dscale);
1199       ofile.write((char *)&scale, 4);            1201       ofile.write((char *)&scale, 4);
1200       if(DEBUG || kVerbose > 0) {                1202       if(DEBUG || kVerbose > 0) {
1201   G4cout << "Dose dist. [" << ndose              1203   G4cout << "Dose dist. [" << ndose
1202       << "] image min., max., scale : "          1204       << "] image min., max., scale : "
1203       << minmax[0] << ", "                       1205       << minmax[0] << ", "
1204       << minmax[1] << ", "                       1206       << minmax[1] << ", "
1205       << scale << G4endl;                        1207       << scale << G4endl;
1206       }                                          1208       }
1207                                                  1209 
1208       // dose distribution image                 1210       // dose distribution image
1209       int dsize = size[0]*size[1];               1211       int dsize = size[0]*size[1];
1210       short * dimage = new short[dsize];         1212       short * dimage = new short[dsize];
1211       for(int z = 0; z < size[2]; z++) {         1213       for(int z = 0; z < size[2]; z++) {
1212   getShortDoseDist(dimage, z, ndose);            1214   getShortDoseDist(dimage, z, ndose);
1213   ofile.write((char *)dimage, dsize*2); //siz    1215   ofile.write((char *)dimage, dsize*2); //sizeof(short)
1214                                                  1216 
1215   if(DEBUG || kVerbose > 0) {                    1217   if(DEBUG || kVerbose > 0) {
1216     for(int j = 0; j < dsize; j++) {             1218     for(int j = 0; j < dsize; j++) {
1217       if(dimage[j] < 0)                          1219       if(dimage[j] < 0)
1218         G4cout << "[" << j << "," << z << "]"    1220         G4cout << "[" << j << "," << z << "]"
1219       << dimage[j] << ", ";                      1221       << dimage[j] << ", ";
1220     }                                            1222     }
1221   }                                              1223   }
1222       }                                          1224       }
1223       if(DEBUG || kVerbose > 0) G4cout << G4e    1225       if(DEBUG || kVerbose > 0) G4cout << G4endl;
1224       delete [] dimage;                          1226       delete [] dimage;
1225                                                  1227 
1226       // relative location of the dose distri    1228       // relative location of the dose distribution image for 
1227       // the modality image                      1229       // the modality image
1228       getDoseDistCenterPosition(fCenter, ndos    1230       getDoseDistCenterPosition(fCenter, ndose);
1229       for(int i = 0; i < 3; i++) iCenter[i] =    1231       for(int i = 0; i < 3; i++) iCenter[i] = (int)fCenter[i];
1230       ofile.write((char *)iCenter, 3*4); // 3    1232       ofile.write((char *)iCenter, 3*4); // 3*sizeof(int)
1231       if(DEBUG || kVerbose > 0) {                1233       if(DEBUG || kVerbose > 0) {
1232   G4cout << "Dose dist. [" << ndose              1234   G4cout << "Dose dist. [" << ndose
1233       << "]image relative location : ("          1235       << "]image relative location : ("
1234       << iCenter[0] << ", "                      1236       << iCenter[0] << ", "
1235       << iCenter[1] << ", "                      1237       << iCenter[1] << ", "
1236       << iCenter[2] << ")" << G4endl;            1238       << iCenter[2] << ")" << G4endl;
1237       }                                          1239       }
1238     }                                            1240     }
1239   }                                              1241   }
1240                                                  1242 
1241   //----- ROI image -----//                      1243   //----- ROI image -----//
1242   if(!isROIEmpty()) {                            1244   if(!isROIEmpty()) {
1243     // ROI image size                            1245     // ROI image size
1244     kRoi[0].getSize(size);                       1246     kRoi[0].getSize(size);
1245     ofile.write((char *)size, 3*sizeof(int));    1247     ofile.write((char *)size, 3*sizeof(int));
1246     if(DEBUG || kVerbose > 0) {                  1248     if(DEBUG || kVerbose > 0) {
1247       G4cout << "ROI image size : ("             1249       G4cout << "ROI image size : ("
1248     << size[0] << ", "                           1250     << size[0] << ", "
1249     << size[1] << ", "                           1251     << size[1] << ", "
1250     << size[2] << ")"                            1252     << size[2] << ")"
1251     << G4endl;                                   1253     << G4endl;
1252     }                                            1254     }
1253                                                  1255 
1254     // ROI max. & min.                           1256     // ROI max. & min.
1255     kRoi[0].getMinMax(minmax);                   1257     kRoi[0].getMinMax(minmax);
1256     ofile.write((char *)minmax, sizeof(short)    1258     ofile.write((char *)minmax, sizeof(short)*2);
1257                                                  1259 
1258     // ROI distribution scaling                  1260     // ROI distribution scaling 
1259     scale = (float)kRoi[0].getScale();           1261     scale = (float)kRoi[0].getScale();
1260     ofile.write((char *)&scale, sizeof(float)    1262     ofile.write((char *)&scale, sizeof(float));
1261     if(DEBUG || kVerbose > 0) {                  1263     if(DEBUG || kVerbose > 0) {
1262       G4cout << "ROI image min., max., scale     1264       G4cout << "ROI image min., max., scale : "
1263     << minmax[0] << ", "                         1265     << minmax[0] << ", "
1264     << minmax[1] << ", "                         1266     << minmax[1] << ", "
1265     << scale << G4endl;                          1267     << scale << G4endl;
1266     }                                            1268     }
1267                                                  1269 
1268     // ROI image                                 1270     // ROI image
1269     int rsize = size[0]*size[1];                 1271     int rsize = size[0]*size[1];
1270     for(int i = 0; i < size[2]; i++) {           1272     for(int i = 0; i < size[2]; i++) {
1271       short * rimage = kRoi[0].getImage(i);      1273       short * rimage = kRoi[0].getImage(i);
1272       ofile.write((char *)rimage, rsize*sizeo    1274       ofile.write((char *)rimage, rsize*sizeof(short));
1273                                                  1275 
1274     }                                            1276     }
1275                                                  1277 
1276     // ROI relative location                     1278     // ROI relative location
1277     kRoi[0].getCenterPosition(fCenter);          1279     kRoi[0].getCenterPosition(fCenter);
1278     for(int i = 0; i < 3; i++) iCenter[i] = (    1280     for(int i = 0; i < 3; i++) iCenter[i] = (int)fCenter[i];
1279     ofile.write((char *)iCenter, 3*sizeof(int    1281     ofile.write((char *)iCenter, 3*sizeof(int));
1280     if(DEBUG || kVerbose > 0) {                  1282     if(DEBUG || kVerbose > 0) {
1281       G4cout << "ROI image relative location     1283       G4cout << "ROI image relative location : ("
1282     << iCenter[0] << ", "                        1284     << iCenter[0] << ", "
1283     << iCenter[1] << ", "                        1285     << iCenter[1] << ", "
1284     << iCenter[2] << ")" << G4endl;              1286     << iCenter[2] << ")" << G4endl;
1285     }                                            1287     }
1286   }                                              1288   }
1287                                                  1289 
1288   //----- track information -----//              1290   //----- track information -----//
1289   // number of track                             1291   // number of track 
1290   int ntrk = (int)kSteps.size();              << 1292   int ntrk = kSteps.size();
1291   ofile.write((char *)&ntrk, sizeof(int));       1293   ofile.write((char *)&ntrk, sizeof(int));
1292   if(DEBUG || kVerbose > 0) {                    1294   if(DEBUG || kVerbose > 0) {
1293     G4cout << "# of tracks : "                   1295     G4cout << "# of tracks : "
1294         << ntrk << G4endl;                       1296         << ntrk << G4endl;
1295   }                                              1297   }
1296   // track position                              1298   // track position
1297   for(int i = 0; i < ntrk; i++) {                1299   for(int i = 0; i < ntrk; i++) {
1298     float * tp = kSteps[i];                      1300     float * tp = kSteps[i];
1299     ofile.write((char *)tp, sizeof(float)*6);    1301     ofile.write((char *)tp, sizeof(float)*6);
1300   }                                              1302   }
1301   // track color                                 1303   // track color
1302   int ntcolor = int(kStepColors.size());         1304   int ntcolor = int(kStepColors.size());
1303   if(ntrk != ntcolor)                            1305   if(ntrk != ntcolor) 
1304     if (G4VisManager::GetVerbosity() >= G4Vis    1306     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
1305       G4cout << "# of track color information    1307       G4cout << "# of track color information must be the same as # of tracks." 
1306        << G4endl;                                1308        << G4endl;
1307   unsigned char white[3] = {255,255,255}; //     1309   unsigned char white[3] = {255,255,255}; // default color
1308   for(int i = 0; i < ntrk; i++) {                1310   for(int i = 0; i < ntrk; i++) {
1309     if(i < ntcolor) {                            1311     if(i < ntcolor) {
1310       unsigned char * tcolor = kStepColors[i]    1312       unsigned char * tcolor = kStepColors[i];
1311       ofile.write((char *)tcolor, 3);            1313       ofile.write((char *)tcolor, 3);
1312     } else {                                     1314     } else {
1313       ofile.write((char *)white, 3);             1315       ofile.write((char *)white, 3);
1314     }                                            1316     }
1315   }                                              1317   }
1316                                                  1318   
1317   // file end mark                               1319   // file end mark
1318   ofile.write("END", 3);                         1320   ofile.write("END", 3);
1319                                                  1321 
1320   ofile.close();                                 1322   ofile.close();
1321                                                  1323 
1322   return true;                                   1324   return true;
1323 }                                                1325 }
1324 //                                               1326 //
1325 bool G4GMocrenIO::storeData4(char * _filename    1327 bool G4GMocrenIO::storeData4(char * _filename) {
1326   kFileName = _filename;                         1328   kFileName = _filename;
1327   return storeData4();                           1329   return storeData4();
1328 }                                                1330 }
1329                                                  1331 
1330 // version 2                                     1332 // version 2
1331 bool G4GMocrenIO::storeData2() {                 1333 bool G4GMocrenIO::storeData2() {
1332                                                  1334 
1333   if(kVerbose > 0) G4cout << ">>>>>>>  store     1335   if(kVerbose > 0) G4cout << ">>>>>>>  store data (ver.2) <<<<<<<" << G4endl;
1334   if(kVerbose > 0) G4cout << "         " << k    1336   if(kVerbose > 0) G4cout << "         " << kFileName << G4endl;
1335                                                  1337 
1336   bool DEBUG = false;//                          1338   bool DEBUG = false;//
1337                                                  1339 
1338   // output file open                            1340   // output file open
1339   std::ofstream ofile(kFileName.c_str(),         1341   std::ofstream ofile(kFileName.c_str(),
1340           std::ios_base::out|std::ios_base::b    1342           std::ios_base::out|std::ios_base::binary);
1341                                                  1343 
1342   // file identifier                             1344   // file identifier
1343   ofile.write("GRAPE    ", 8);                   1345   ofile.write("GRAPE    ", 8);
1344                                                  1346 
1345   // file version                                1347   // file version
1346   unsigned char ver = 0x02;                      1348   unsigned char ver = 0x02;
1347   ofile.write((char *)&ver, 1);                  1349   ofile.write((char *)&ver, 1);
1348   // file id for old file format support         1350   // file id for old file format support
1349   ofile.write(kId.c_str(), IDLENGTH);            1351   ofile.write(kId.c_str(), IDLENGTH);
1350   // file version for old file format support    1352   // file version for old file format support
1351   ofile.write(kVersion.c_str(), VERLENGTH);      1353   ofile.write(kVersion.c_str(), VERLENGTH);
1352   // endian                                      1354   // endian
1353   ofile.write((char *)&kLittleEndianOutput, s    1355   ofile.write((char *)&kLittleEndianOutput, sizeof(char));
1354                                                  1356 
1355   /*                                             1357   /*
1356   // event number                                1358   // event number
1357   ofile.write((char *)&numberOfEvents, sizeof    1359   ofile.write((char *)&numberOfEvents, sizeof(int));
1358   float imageSpacing[3];                         1360   float imageSpacing[3]; 
1359   imageSpacing[0] = modalityImageVoxelSpacing    1361   imageSpacing[0] = modalityImageVoxelSpacing[0];
1360   imageSpacing[1] = modalityImageVoxelSpacing    1362   imageSpacing[1] = modalityImageVoxelSpacing[1];
1361   imageSpacing[2] = modalityImageVoxelSpacing    1363   imageSpacing[2] = modalityImageVoxelSpacing[2];
1362   ofile.write((char *)imageSpacing, 12);         1364   ofile.write((char *)imageSpacing, 12);
1363   */                                             1365   */
1364                                                  1366 
1365                                                  1367 
1366   // voxel spacings for all images               1368   // voxel spacings for all images
1367   ofile.write((char *)kVoxelSpacing, 12);        1369   ofile.write((char *)kVoxelSpacing, 12);
1368   if(DEBUG || kVerbose > 0) {                    1370   if(DEBUG || kVerbose > 0) {
1369     G4cout << "Voxel spacing : ("                1371     G4cout << "Voxel spacing : ("
1370         << kVoxelSpacing[0] << ", "              1372         << kVoxelSpacing[0] << ", "
1371         << kVoxelSpacing[1] << ", "              1373         << kVoxelSpacing[1] << ", "
1372         << kVoxelSpacing[2]                      1374         << kVoxelSpacing[2]
1373         << ") mm " << G4endl;                    1375         << ") mm " << G4endl;
1374   }                                              1376   }
1375                                                  1377 
1376   calcPointers2();                               1378   calcPointers2();
1377   // offset from file starting point to the m    1379   // offset from file starting point to the modality image data
1378   ofile.write((char *)&kPointerToModalityData    1380   ofile.write((char *)&kPointerToModalityData, 4);
1379                                                  1381 
1380   // offset from file starting point to the d    1382   // offset from file starting point to the dose image data
1381   ofile.write((char *)&kPointerToDoseDistData    1383   ofile.write((char *)&kPointerToDoseDistData[0], 4);
1382                                                  1384 
1383   // offset from file starting point to the R    1385   // offset from file starting point to the ROI image data
1384   ofile.write((char *)&kPointerToROIData, 4);    1386   ofile.write((char *)&kPointerToROIData, 4);
1385                                                  1387 
1386   // offset from file starting point to the t    1388   // offset from file starting point to the track data
1387   ofile.write((char *)&kPointerToTrackData, 4    1389   ofile.write((char *)&kPointerToTrackData, 4);
1388   if(DEBUG || kVerbose > 0) {                    1390   if(DEBUG || kVerbose > 0) {
1389     G4cout << "Each pointer to data : "          1391     G4cout << "Each pointer to data : "
1390         << kPointerToModalityData << ", "        1392         << kPointerToModalityData << ", "
1391         << kPointerToDoseDistData[0] << ", "     1393         << kPointerToDoseDistData[0] << ", "
1392         << kPointerToROIData << ", "             1394         << kPointerToROIData << ", "
1393         << kPointerToTrackData << G4endl;        1395         << kPointerToTrackData << G4endl;
1394   }                                              1396   }
1395                                                  1397 
1396   //----- modality image -----//                 1398   //----- modality image -----//
1397                                                  1399 
1398   int size[3];                                   1400   int size[3];
1399   float scale;                                   1401   float scale;
1400   short minmax[2];                               1402   short minmax[2];
1401   float fCenter[3];                              1403   float fCenter[3];
1402   int iCenter[3];                                1404   int iCenter[3];
1403   // modality image size                         1405   // modality image size
1404   kModality.getSize(size);                       1406   kModality.getSize(size);
1405   ofile.write((char *)size, 3*sizeof(int));      1407   ofile.write((char *)size, 3*sizeof(int));
1406   if(DEBUG || kVerbose > 0) {                    1408   if(DEBUG || kVerbose > 0) {
1407     G4cout << "Modality image size : ("          1409     G4cout << "Modality image size : ("
1408         << size[0] << ", "                       1410         << size[0] << ", "
1409         << size[1] << ", "                       1411         << size[1] << ", "
1410         << size[2] << ")"                        1412         << size[2] << ")"
1411         << G4endl;                               1413         << G4endl;
1412   }                                              1414   }
1413                                                  1415 
1414   // modality image max. & min.                  1416   // modality image max. & min.
1415   kModality.getMinMax(minmax);                   1417   kModality.getMinMax(minmax);
1416   ofile.write((char *)minmax, 4);                1418   ofile.write((char *)minmax, 4);
1417                                                  1419 
1418   // modality image unit                         1420   // modality image unit
1419   //char munit[13] = "g/cm3       ";             1421   //char munit[13] = "g/cm3       ";
1420   //ofile.write((char *)&munit, 12);             1422   //ofile.write((char *)&munit, 12);
1421                                                  1423   
1422   // modality image scale                        1424   // modality image scale
1423   scale = (float)kModality.getScale();           1425   scale = (float)kModality.getScale();
1424   ofile.write((char *)&scale, 4);                1426   ofile.write((char *)&scale, 4);
1425   if(DEBUG || kVerbose > 0) {                    1427   if(DEBUG || kVerbose > 0) {
1426     G4cout << "Modality image min., max., sca    1428     G4cout << "Modality image min., max., scale : "
1427         << minmax[0] << ", "                     1429         << minmax[0] << ", "
1428         << minmax[1] << ", "                     1430         << minmax[1] << ", "
1429         << scale << G4endl;                      1431         << scale << G4endl;
1430   }                                              1432   }
1431                                                  1433 
1432   // modality image                              1434   // modality image
1433   int psize = size[0]*size[1];                   1435   int psize = size[0]*size[1];
1434   if(DEBUG || kVerbose > 0) G4cout << "Modali    1436   if(DEBUG || kVerbose > 0) G4cout << "Modality image : ";
1435   for(int i = 0; i < size[2]; i++) {             1437   for(int i = 0; i < size[2]; i++) {
1436     short * image =kModality.getImage(i);        1438     short * image =kModality.getImage(i);
1437     ofile.write((char *)image, psize*sizeof(s    1439     ofile.write((char *)image, psize*sizeof(short));
1438                                                  1440 
1439     if(DEBUG || kVerbose > 0) G4cout << "[" <    1441     if(DEBUG || kVerbose > 0) G4cout << "[" << i << "]" << image[(size_t)(psize*0.55)] << ", ";
1440   }                                              1442   }
1441   if(DEBUG || kVerbose > 0) G4cout << G4endl;    1443   if(DEBUG || kVerbose > 0) G4cout << G4endl;
1442                                                  1444 
1443   // modality desity map for CT value            1445   // modality desity map for CT value
1444   size_t msize = minmax[1] - minmax[0]+1;        1446   size_t msize = minmax[1] - minmax[0]+1;
1445   float * pdmap = new float[msize];              1447   float * pdmap = new float[msize];
1446   for(int i = 0; i < (int)msize; i++) pdmap[i    1448   for(int i = 0; i < (int)msize; i++) pdmap[i] =kModalityImageDensityMap[i]; 
1447   ofile.write((char *)pdmap, msize*sizeof(flo    1449   ofile.write((char *)pdmap, msize*sizeof(float));
1448   if(DEBUG || kVerbose > 0) {                    1450   if(DEBUG || kVerbose > 0) {
1449     G4cout << "density map : " << std::ends;     1451     G4cout << "density map : " << std::ends;
1450     for(int i = 0; i < (int)msize; i+=50)        1452     for(int i = 0; i < (int)msize; i+=50)
1451       G4cout <<kModalityImageDensityMap[i] <<    1453       G4cout <<kModalityImageDensityMap[i] << ", ";
1452     G4cout << G4endl;                            1454     G4cout << G4endl;
1453   }                                              1455   }
1454   delete [] pdmap;                               1456   delete [] pdmap;
1455                                                  1457 
1456                                                  1458 
1457   //----- dose distribution image -----//        1459   //----- dose distribution image -----//
1458                                                  1460 
1459   if(!isDoseEmpty()) {                           1461   if(!isDoseEmpty()) {
1460     calcDoseDistScale();                         1462     calcDoseDistScale();
1461                                                  1463 
1462     // dose distrbution image size               1464     // dose distrbution image size
1463     kDose[0].getSize(size);                      1465     kDose[0].getSize(size);
1464     ofile.write((char *)size, 3*sizeof(int));    1466     ofile.write((char *)size, 3*sizeof(int));
1465     if(DEBUG || kVerbose > 0) {                  1467     if(DEBUG || kVerbose > 0) {
1466       G4cout << "Dose dist. image size : ("      1468       G4cout << "Dose dist. image size : ("
1467     << size[0] << ", "                           1469     << size[0] << ", "
1468     << size[1] << ", "                           1470     << size[1] << ", "
1469     << size[2] << ")"                            1471     << size[2] << ")"
1470     << G4endl;                                   1472     << G4endl;
1471     }                                            1473     }
1472                                                  1474 
1473     // dose distribution max. & min.             1475     // dose distribution max. & min.
1474     getShortDoseDistMinMax(minmax);              1476     getShortDoseDistMinMax(minmax);
1475     ofile.write((char *)minmax, sizeof(short)    1477     ofile.write((char *)minmax, sizeof(short)*2);
1476                                                  1478 
1477     // dose distribution scaling                 1479     // dose distribution scaling 
1478     scale = (float)kDose[0].getScale();          1480     scale = (float)kDose[0].getScale();
1479     ofile.write((char *)&scale, sizeof(float)    1481     ofile.write((char *)&scale, sizeof(float));
1480     if(DEBUG || kVerbose > 0) {                  1482     if(DEBUG || kVerbose > 0) {
1481       G4cout << "Dose dist. image min., max.,    1483       G4cout << "Dose dist. image min., max., scale : "
1482     << minmax[0] << ", "                         1484     << minmax[0] << ", "
1483     << minmax[1] << ", "                         1485     << minmax[1] << ", "
1484     << scale << G4endl;                          1486     << scale << G4endl;
1485     }                                            1487     }
1486                                                  1488 
1487     // dose distribution image                   1489     // dose distribution image
1488     int dsize = size[0]*size[1];                 1490     int dsize = size[0]*size[1];
1489     short * dimage = new short[dsize];           1491     short * dimage = new short[dsize];
1490     for(int z = 0; z < size[2]; z++) {           1492     for(int z = 0; z < size[2]; z++) {
1491       getShortDoseDist(dimage, z);               1493       getShortDoseDist(dimage, z);
1492       ofile.write((char *)dimage, dsize*sizeo    1494       ofile.write((char *)dimage, dsize*sizeof(short));
1493                                                  1495 
1494       if(DEBUG || kVerbose > 0) {                1496       if(DEBUG || kVerbose > 0) {
1495   for(int j = 0; j < dsize; j++) {               1497   for(int j = 0; j < dsize; j++) {
1496     if(dimage[j] < 0)                            1498     if(dimage[j] < 0)
1497       G4cout << "[" << j << "," << z << "]"      1499       G4cout << "[" << j << "," << z << "]"
1498           << dimage[j] << ", ";                  1500           << dimage[j] << ", ";
1499   }                                              1501   }
1500       }                                          1502       }
1501     }                                            1503     }
1502     if(DEBUG || kVerbose > 0) G4cout << G4end    1504     if(DEBUG || kVerbose > 0) G4cout << G4endl;
1503     delete [] dimage;                            1505     delete [] dimage;
1504                                                  1506 
1505     // relative location of the dose distribu    1507     // relative location of the dose distribution image for 
1506     // the modality image                        1508     // the modality image
1507     kDose[0].getCenterPosition(fCenter);         1509     kDose[0].getCenterPosition(fCenter);
1508     for(int i = 0; i < 3; i++) iCenter[i] = (    1510     for(int i = 0; i < 3; i++) iCenter[i] = (int)fCenter[i];
1509     ofile.write((char *)iCenter, 3*sizeof(int    1511     ofile.write((char *)iCenter, 3*sizeof(int));
1510     if(DEBUG || kVerbose > 0) {                  1512     if(DEBUG || kVerbose > 0) {
1511       G4cout << "Dose dist. image relative lo    1513       G4cout << "Dose dist. image relative location : ("
1512     << iCenter[0] << ", "                        1514     << iCenter[0] << ", "
1513     << iCenter[1] << ", "                        1515     << iCenter[1] << ", "
1514     << iCenter[2] << ")" << G4endl;              1516     << iCenter[2] << ")" << G4endl;
1515     }                                            1517     }
1516                                                  1518 
1517   }                                              1519   }
1518                                                  1520 
1519   //----- ROI image -----//                      1521   //----- ROI image -----//
1520   if(!isROIEmpty()) {                            1522   if(!isROIEmpty()) {
1521     // ROI image size                            1523     // ROI image size
1522     kRoi[0].getSize(size);                       1524     kRoi[0].getSize(size);
1523     ofile.write((char *)size, 3*sizeof(int));    1525     ofile.write((char *)size, 3*sizeof(int));
1524     if(DEBUG || kVerbose > 0) {                  1526     if(DEBUG || kVerbose > 0) {
1525       G4cout << "ROI image size : ("             1527       G4cout << "ROI image size : ("
1526     << size[0] << ", "                           1528     << size[0] << ", "
1527     << size[1] << ", "                           1529     << size[1] << ", "
1528     << size[2] << ")"                            1530     << size[2] << ")"
1529     << G4endl;                                   1531     << G4endl;
1530     }                                            1532     }
1531                                                  1533 
1532     // ROI max. & min.                           1534     // ROI max. & min.
1533     kRoi[0].getMinMax(minmax);                   1535     kRoi[0].getMinMax(minmax);
1534     ofile.write((char *)minmax, sizeof(short)    1536     ofile.write((char *)minmax, sizeof(short)*2);
1535                                                  1537 
1536     // ROI distribution scaling                  1538     // ROI distribution scaling 
1537     scale = (float)kRoi[0].getScale();           1539     scale = (float)kRoi[0].getScale();
1538     ofile.write((char *)&scale, sizeof(float)    1540     ofile.write((char *)&scale, sizeof(float));
1539     if(DEBUG || kVerbose > 0) {                  1541     if(DEBUG || kVerbose > 0) {
1540       G4cout << "ROI image min., max., scale     1542       G4cout << "ROI image min., max., scale : "
1541     << minmax[0] << ", "                         1543     << minmax[0] << ", "
1542     << minmax[1] << ", "                         1544     << minmax[1] << ", "
1543     << scale << G4endl;                          1545     << scale << G4endl;
1544     }                                            1546     }
1545                                                  1547 
1546     // ROI image                                 1548     // ROI image
1547     int rsize = size[0]*size[1];                 1549     int rsize = size[0]*size[1];
1548     for(int i = 0; i < size[2]; i++) {           1550     for(int i = 0; i < size[2]; i++) {
1549       short * rimage = kRoi[0].getImage(i);      1551       short * rimage = kRoi[0].getImage(i);
1550       ofile.write((char *)rimage, rsize*sizeo    1552       ofile.write((char *)rimage, rsize*sizeof(short));
1551                                                  1553 
1552     }                                            1554     }
1553                                                  1555 
1554     // ROI relative location                     1556     // ROI relative location
1555     kRoi[0].getCenterPosition(fCenter);          1557     kRoi[0].getCenterPosition(fCenter);
1556     for(int i = 0; i < 3; i++) iCenter[i] = (    1558     for(int i = 0; i < 3; i++) iCenter[i] = (int)fCenter[i];
1557     ofile.write((char *)iCenter, 3*sizeof(int    1559     ofile.write((char *)iCenter, 3*sizeof(int));
1558     if(DEBUG || kVerbose > 0) {                  1560     if(DEBUG || kVerbose > 0) {
1559       G4cout << "ROI image relative location     1561       G4cout << "ROI image relative location : ("
1560     << iCenter[0] << ", "                        1562     << iCenter[0] << ", "
1561     << iCenter[1] << ", "                        1563     << iCenter[1] << ", "
1562     << iCenter[2] << ")" << G4endl;              1564     << iCenter[2] << ")" << G4endl;
1563     }                                            1565     }
1564   }                                              1566   }
1565                                                  1567 
1566                                                  1568 
1567   //----- track information -----//              1569   //----- track information -----//
1568   // track                                       1570   // track
1569   int ntrk = (int)kSteps.size();              << 1571   int ntrk = kSteps.size();
1570   ofile.write((char *)&ntrk, sizeof(int));       1572   ofile.write((char *)&ntrk, sizeof(int));
1571   if(DEBUG || kVerbose > 0) {                    1573   if(DEBUG || kVerbose > 0) {
1572     G4cout << "# of tracks : "                   1574     G4cout << "# of tracks : "
1573         << ntrk << G4endl;                       1575         << ntrk << G4endl;
1574   }                                              1576   }
1575   for(int i = 0; i < ntrk; i++) {                1577   for(int i = 0; i < ntrk; i++) {
1576     float * tp = kSteps[i];                      1578     float * tp = kSteps[i];
1577     ofile.write((char *)tp, sizeof(float)*6);    1579     ofile.write((char *)tp, sizeof(float)*6);
1578   }                                              1580   }
1579                                                  1581 
1580                                                  1582 
1581   // file end mark                               1583   // file end mark
1582   ofile.write("END", 3);                         1584   ofile.write("END", 3);
1583                                                  1585 
1584   ofile.close();                                 1586   ofile.close();
1585                                                  1587 
1586   return true;                                   1588   return true;
1587 }                                                1589 }
1588 //                                               1590 //
1589 bool G4GMocrenIO::storeData2(char * _filename    1591 bool G4GMocrenIO::storeData2(char * _filename) {
1590   kFileName = _filename;                         1592   kFileName = _filename;
1591   return storeData();                            1593   return storeData();
1592 }                                                1594 }
1593                                                  1595 
1594 bool G4GMocrenIO::retrieveData() {               1596 bool G4GMocrenIO::retrieveData() {
1595                                                  1597 
1596   // input file open                             1598   // input file open
1597   std::ifstream ifile(kFileName.c_str(), std:    1599   std::ifstream ifile(kFileName.c_str(), std::ios_base::in|std::ios_base::binary);
1598   if(!ifile) {                                   1600   if(!ifile) {
1599     if (G4VisManager::GetVerbosity() >= G4Vis    1601     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
1600       G4cout << "Cannot open file: " << kFile    1602       G4cout << "Cannot open file: " << kFileName
1601        << " in G4GMocrenIO::retrieveData()."     1603        << " in G4GMocrenIO::retrieveData()." << G4endl;
1602     return false;                                1604     return false;
1603   }                                              1605   }
1604                                                  1606 
1605   // file identifier                             1607   // file identifier
1606   char verid[9];                                 1608   char verid[9];
1607   ifile.read((char *)verid, 8);                  1609   ifile.read((char *)verid, 8);
1608   // file version                                1610   // file version
1609   unsigned char ver;                             1611   unsigned char ver;
1610   ifile.read((char *)&ver, 1);                   1612   ifile.read((char *)&ver, 1);
1611   ifile.close();                                 1613   ifile.close();
1612                                                  1614 
1613   if(std::strncmp(verid, "gMocren", 7) == 0)     1615   if(std::strncmp(verid, "gMocren", 7) == 0) {
1614     if(ver == 0x03) {                            1616     if(ver == 0x03) {
1615       G4cout << ">>>>>>>  retrieve data (ver.    1617       G4cout << ">>>>>>>  retrieve data (ver.3) <<<<<<<" << G4endl;
1616       G4cout << "         " << kFileName << G    1618       G4cout << "         " << kFileName << G4endl;
1617       retrieveData3();                           1619       retrieveData3();
1618     } else if (ver == 0x04) {                    1620     } else if (ver == 0x04) {
1619       G4cout << ">>>>>>>  retrieve data (ver.    1621       G4cout << ">>>>>>>  retrieve data (ver.4) <<<<<<<" << G4endl;
1620       G4cout << "         " << kFileName << G    1622       G4cout << "         " << kFileName << G4endl;
1621       retrieveData4();                           1623       retrieveData4();
1622     } else {                                     1624     } else {
1623       if (G4VisManager::GetVerbosity() >= G4V    1625       if (G4VisManager::GetVerbosity() >= G4VisManager::errors) {
1624   G4cout << "Error -- invalid file version :     1626   G4cout << "Error -- invalid file version : " << (int)ver
1625       << G4endl;                                 1627       << G4endl;
1626   G4cout << "         " << kFileName << G4end    1628   G4cout << "         " << kFileName << G4endl;
1627       }                                          1629       }
1628       G4Exception("G4GMocrenIO::retrieveDadta << 1630       std::exit(-1);
1629                   "gMocren2001", FatalExcepti << 
1630                   "Error.");                  << 
1631                                               << 
1632     }                                            1631     }
1633   } else if(std::strncmp(verid, "GRAPE", 5) =    1632   } else if(std::strncmp(verid, "GRAPE", 5) == 0) {
1634     G4cout << ">>>>>>>  retrieve data (ver.2)    1633     G4cout << ">>>>>>>  retrieve data (ver.2) <<<<<<<" << G4endl;
1635     G4cout << "         " << kFileName << G4e    1634     G4cout << "         " << kFileName << G4endl;
1636     retrieveData2();                             1635     retrieveData2();
1637   } else {                                       1636   } else {
1638     if (G4VisManager::GetVerbosity() >= G4Vis    1637     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
1639       G4cout << kFileName << " was not gdd fi    1638       G4cout << kFileName << " was not gdd file." << G4endl;
1640     return false;                                1639     return false;
1641   }                                              1640   }
1642                                                  1641 
1643   return true;                                   1642   return true;
1644 }                                                1643 }
1645                                                  1644 
1646 bool G4GMocrenIO::retrieveData(char * _filena    1645 bool G4GMocrenIO::retrieveData(char * _filename) {
1647   kFileName = _filename;                         1646   kFileName = _filename;
1648   return retrieveData();                         1647   return retrieveData();
1649 }                                                1648 }
1650                                                  1649 
1651 //                                               1650 // 
1652 bool G4GMocrenIO::retrieveData4() {              1651 bool G4GMocrenIO::retrieveData4() {
1653                                                  1652 
1654   bool DEBUG = false;//                          1653   bool DEBUG = false;//
1655                                                  1654 
1656   // input file open                             1655   // input file open
1657   std::ifstream ifile(kFileName.c_str(), std:    1656   std::ifstream ifile(kFileName.c_str(), std::ios_base::in|std::ios_base::binary);
1658   if(!ifile) {                                   1657   if(!ifile) {
1659     if (G4VisManager::GetVerbosity() >= G4Vis    1658     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
1660       G4cout << "Cannot open file: " << kFile    1659       G4cout << "Cannot open file: " << kFileName
1661     << " in G4GMocrenIO::retrieveData3()." <<    1660     << " in G4GMocrenIO::retrieveData3()." << G4endl;
1662     return false;                                1661     return false;
1663   }                                              1662   }
1664                                                  1663 
1665   // data buffer                                 1664   // data buffer
1666   char ctmp[24];                              << 1665   char ctmp[12];
1667                                                  1666 
1668   // file identifier                             1667   // file identifier
1669   char verid[9];                                 1668   char verid[9];
1670   ifile.read((char *)verid, 8);                  1669   ifile.read((char *)verid, 8);
1671                                                  1670 
1672   // file version                                1671   // file version
1673   unsigned char ver;                             1672   unsigned char ver;
1674   ifile.read((char *)&ver, 1);                   1673   ifile.read((char *)&ver, 1);
1675   std::stringstream ss;                          1674   std::stringstream ss;
1676   ss << (int)ver;                                1675   ss << (int)ver;
1677   kVersion = ss.str();                           1676   kVersion = ss.str();
1678   if(DEBUG || kVerbose > 0) G4cout << "File v    1677   if(DEBUG || kVerbose > 0) G4cout << "File version : " << kVersion << G4endl;
1679                                                  1678 
1680   // endian                                      1679   // endian
1681   ifile.read((char *)&kLittleEndianInput, siz    1680   ifile.read((char *)&kLittleEndianInput, sizeof(char));
1682   if(DEBUG || kVerbose > 0) {                    1681   if(DEBUG || kVerbose > 0) {
1683     G4cout << "Endian : ";                       1682     G4cout << "Endian : ";
1684     if(kLittleEndianInput == 1)                  1683     if(kLittleEndianInput == 1) 
1685       G4cout << " little" << G4endl;             1684       G4cout << " little" << G4endl;
1686     else {                                       1685     else {
1687       G4cout << " big" << G4endl;                1686       G4cout << " big" << G4endl;
1688     }                                            1687     }
1689   }                                              1688   }
1690                                                  1689 
1691   // comment length (fixed size)                 1690   // comment length (fixed size)
1692   int clength;                                   1691   int clength;
1693   ifile.read((char *)ctmp, 4);                   1692   ifile.read((char *)ctmp, 4);
1694   convertEndian(ctmp, clength);                  1693   convertEndian(ctmp, clength);
1695   // comment                                     1694   // comment
1696   char cmt[1025];                                1695   char cmt[1025];
1697   ifile.read((char *)cmt, clength);              1696   ifile.read((char *)cmt, clength);
1698   std::string scmt = cmt;                        1697   std::string scmt = cmt;
1699   scmt += '\0';                                  1698   scmt += '\0';
1700   setComment(scmt);                              1699   setComment(scmt);
1701   if(DEBUG || kVerbose > 0) {                    1700   if(DEBUG || kVerbose > 0) {
1702     G4cout << "Data comment : "                  1701     G4cout << "Data comment : "
1703         << kComment << G4endl;                   1702         << kComment << G4endl;
1704   }                                              1703   }
1705                                                  1704 
1706   // voxel spacings for all images               1705   // voxel spacings for all images
1707   ifile.read((char *)ctmp, 12);                  1706   ifile.read((char *)ctmp, 12);
1708   convertEndian(ctmp, kVoxelSpacing[0]);         1707   convertEndian(ctmp, kVoxelSpacing[0]);
1709   convertEndian(ctmp+4, kVoxelSpacing[1]);       1708   convertEndian(ctmp+4, kVoxelSpacing[1]);
1710   convertEndian(ctmp+8, kVoxelSpacing[2]);       1709   convertEndian(ctmp+8, kVoxelSpacing[2]);
1711   if(DEBUG || kVerbose > 0) {                    1710   if(DEBUG || kVerbose > 0) {
1712     G4cout << "Voxel spacing : ("                1711     G4cout << "Voxel spacing : ("
1713         << kVoxelSpacing[0] << ", "              1712         << kVoxelSpacing[0] << ", "
1714         << kVoxelSpacing[1] << ", "              1713         << kVoxelSpacing[1] << ", "
1715         << kVoxelSpacing[2]                      1714         << kVoxelSpacing[2]
1716         << ") mm " << G4endl;                    1715         << ") mm " << G4endl;
1717   }                                              1716   }
1718                                                  1717 
1719                                                  1718 
1720   // offset from file starting point to the m    1719   // offset from file starting point to the modality image data
1721   ifile.read((char *)ctmp, 4);                   1720   ifile.read((char *)ctmp, 4);
1722   convertEndian(ctmp, kPointerToModalityData)    1721   convertEndian(ctmp, kPointerToModalityData);
1723                                                  1722 
1724   // # of dose distributions                     1723   // # of dose distributions
1725   ifile.read((char *)ctmp, 4);                   1724   ifile.read((char *)ctmp, 4);
1726   int nDoseDist;                                 1725   int nDoseDist;
1727   convertEndian(ctmp, nDoseDist);                1726   convertEndian(ctmp, nDoseDist);
1728                                                  1727   
1729   // offset from file starting point to the d    1728   // offset from file starting point to the dose image data
1730   for(int i = 0; i < nDoseDist; i++) {           1729   for(int i = 0; i < nDoseDist; i++) {
1731     ifile.read((char *)ctmp, 4);                 1730     ifile.read((char *)ctmp, 4);
1732     unsigned int dptr;                           1731     unsigned int dptr;
1733     convertEndian(ctmp, dptr);                   1732     convertEndian(ctmp, dptr);
1734     addPointerToDoseDistData(dptr);              1733     addPointerToDoseDistData(dptr);
1735   }                                              1734   }
1736                                                  1735 
1737   // offset from file starting point to the R    1736   // offset from file starting point to the ROI image data
1738   ifile.read((char *)ctmp, 4);                   1737   ifile.read((char *)ctmp, 4);
1739   convertEndian(ctmp, kPointerToROIData);        1738   convertEndian(ctmp, kPointerToROIData);
1740                                                  1739 
1741   // offset from file starting point to the t    1740   // offset from file starting point to the track data
1742   ifile.read((char *)ctmp, 4);                   1741   ifile.read((char *)ctmp, 4);
1743   convertEndian(ctmp, kPointerToTrackData);      1742   convertEndian(ctmp, kPointerToTrackData);
1744                                                  1743 
1745   // offset from file starting point to the d    1744   // offset from file starting point to the detector data
1746   ifile.read((char *)ctmp, 4);                   1745   ifile.read((char *)ctmp, 4);
1747   convertEndian(ctmp, kPointerToDetectorData)    1746   convertEndian(ctmp, kPointerToDetectorData);
1748                                                  1747 
1749   if(DEBUG || kVerbose > 0) {                    1748   if(DEBUG || kVerbose > 0) {
1750     G4cout << "Each pointer to data : "          1749     G4cout << "Each pointer to data : "
1751         << kPointerToModalityData << ", ";       1750         << kPointerToModalityData << ", ";
1752     for(int i = 0; i < nDoseDist; i++)           1751     for(int i = 0; i < nDoseDist; i++)
1753       G4cout << kPointerToDoseDistData[i] <<     1752       G4cout << kPointerToDoseDistData[i] << ", ";
1754     G4cout << kPointerToROIData << ", "          1753     G4cout << kPointerToROIData << ", "
1755         << kPointerToTrackData << ", "           1754         << kPointerToTrackData << ", "
1756         << kPointerToDetectorData                1755         << kPointerToDetectorData
1757         << G4endl;                               1756         << G4endl;
1758   }                                              1757   }
1759                                                  1758 
1760                                                  1759 
1761                                                  1760 
1762   if(kPointerToModalityData == 0 && kPointerT    1761   if(kPointerToModalityData == 0 && kPointerToDoseDistData.size() == 0 &&
1763      kPointerToROIData == 0 && kPointerToTrac    1762      kPointerToROIData == 0 && kPointerToTrackData == 0) {
1764     if(DEBUG || kVerbose > 0) {                  1763     if(DEBUG || kVerbose > 0) {
1765       G4cout << "No data." << G4endl;            1764       G4cout << "No data." << G4endl;
1766     }                                            1765     }
1767     return false;                                1766     return false;
1768   }                                              1767   }
1769                                                  1768 
1770   // event number                                1769   // event number
1771   /* ver 1                                       1770   /* ver 1
1772      ifile.read(ctmp, sizeof(int));              1771      ifile.read(ctmp, sizeof(int));
1773      convertEndian(ctmp, numberOfEvents);        1772      convertEndian(ctmp, numberOfEvents);
1774   */                                             1773   */
1775                                                  1774 
1776   int size[3];                                   1775   int size[3];
1777   float scale;                                   1776   float scale;
1778   double dscale;                                 1777   double dscale;
1779   short minmax[2];                               1778   short minmax[2];
1780   float fCenter[3];                              1779   float fCenter[3];
1781   int iCenter[3];                                1780   int iCenter[3];
1782                                                  1781 
1783   //----- Modality image -----//                 1782   //----- Modality image -----//
1784   // modality image size                         1783   // modality image size
1785   ifile.read(ctmp, 3*sizeof(int));               1784   ifile.read(ctmp, 3*sizeof(int));
1786   convertEndian(ctmp, size[0]);                  1785   convertEndian(ctmp, size[0]);
1787   convertEndian(ctmp+sizeof(int), size[1]);      1786   convertEndian(ctmp+sizeof(int), size[1]);
1788   convertEndian(ctmp+2*sizeof(int), size[2]);    1787   convertEndian(ctmp+2*sizeof(int), size[2]);
1789   if(DEBUG || kVerbose > 0) {                    1788   if(DEBUG || kVerbose > 0) {
1790     G4cout << "Modality image size : ("          1789     G4cout << "Modality image size : ("
1791         << size[0] << ", "                       1790         << size[0] << ", "
1792         << size[1] << ", "                       1791         << size[1] << ", "
1793         << size[2] << ")"                        1792         << size[2] << ")"
1794         << G4endl;                               1793         << G4endl;
1795   }                                              1794   }
1796   kModality.setSize(size);                       1795   kModality.setSize(size);
1797                                                  1796 
1798   // modality image voxel spacing                1797   // modality image voxel spacing
1799   /*                                             1798   /*
1800     ifile.read(ctmp, 3*sizeof(float));           1799     ifile.read(ctmp, 3*sizeof(float));
1801     convertEndian(ctmp, modalityImageVoxelSpa    1800     convertEndian(ctmp, modalityImageVoxelSpacing[0]);
1802     convertEndian(ctmp+sizeof(float), modalit    1801     convertEndian(ctmp+sizeof(float), modalityImageVoxelSpacing[1]);
1803     convertEndian(ctmp+2*sizeof(float), modal    1802     convertEndian(ctmp+2*sizeof(float), modalityImageVoxelSpacing[2]);
1804   */                                             1803   */
1805                                                  1804 
1806   if(kPointerToModalityData != 0) {              1805   if(kPointerToModalityData != 0) {
1807                                                  1806 
1808     // modality density max. & min.              1807     // modality density max. & min.
1809     ifile.read((char *)ctmp, 4);                 1808     ifile.read((char *)ctmp, 4);
1810     convertEndian(ctmp, minmax[0]);              1809     convertEndian(ctmp, minmax[0]);
1811     convertEndian(ctmp+2, minmax[1]);            1810     convertEndian(ctmp+2, minmax[1]);
1812     kModality.setMinMax(minmax);                 1811     kModality.setMinMax(minmax);
1813                                                  1812 
1814     // modality image unit                       1813     // modality image unit
1815     char munit[13];                              1814     char munit[13];
1816     munit[12] = '\0';                            1815     munit[12] = '\0';
1817     ifile.read((char *)munit, 12);               1816     ifile.read((char *)munit, 12);
1818     std::string smunit = munit;                  1817     std::string smunit = munit;
1819     setModalityImageUnit(smunit);                1818     setModalityImageUnit(smunit);
1820                                                  1819 
1821     // modality density scale                    1820     // modality density scale
1822     ifile.read((char *)ctmp, 4);                 1821     ifile.read((char *)ctmp, 4);
1823     convertEndian(ctmp, scale);                  1822     convertEndian(ctmp, scale);
1824     kModality.setScale(dscale = scale);          1823     kModality.setScale(dscale = scale);
1825     if(DEBUG || kVerbose > 0) {                  1824     if(DEBUG || kVerbose > 0) {
1826       G4cout << "Modality image min., max., s    1825       G4cout << "Modality image min., max., scale : "
1827     << minmax[0] << ", "                         1826     << minmax[0] << ", "
1828     << minmax[1] << ", "                         1827     << minmax[1] << ", "
1829     << scale << G4endl;                          1828     << scale << G4endl;
1830     }                                            1829     }
1831                                                  1830 
1832     // modality density                          1831     // modality density
1833     int psize = size[0]*size[1];                 1832     int psize = size[0]*size[1];
1834     if(DEBUG || kVerbose > 0) G4cout << "Moda    1833     if(DEBUG || kVerbose > 0) G4cout << "Modality image (" << psize << "): ";
1835     char * cimage = new char[psize*sizeof(sho    1834     char * cimage = new char[psize*sizeof(short)];
1836     for(int i = 0; i < size[2]; i++) {           1835     for(int i = 0; i < size[2]; i++) {
1837       ifile.read((char *)cimage, psize*sizeof    1836       ifile.read((char *)cimage, psize*sizeof(short));
1838       short * mimage = new short[psize];         1837       short * mimage = new short[psize];
1839       for(int j = 0; j < psize; j++) {           1838       for(int j = 0; j < psize; j++) {
1840   convertEndian(cimage+j*sizeof(short), mimag    1839   convertEndian(cimage+j*sizeof(short), mimage[j]);
1841       }                                          1840       }
1842       kModality.addImage(mimage);                1841       kModality.addImage(mimage);
1843                                                  1842 
1844       if(DEBUG || kVerbose > 0) G4cout << "["    1843       if(DEBUG || kVerbose > 0) G4cout << "[" << i << "]" << mimage[(size_t)(psize*0.55)] << ", ";
1845     }                                            1844     }
1846     if(DEBUG || kVerbose > 0) G4cout << G4end    1845     if(DEBUG || kVerbose > 0) G4cout << G4endl;
1847     delete [] cimage;                            1846     delete [] cimage;
1848                                                  1847 
1849     // modality desity map for CT value          1848     // modality desity map for CT value
1850     size_t msize = minmax[1]-minmax[0]+1;        1849     size_t msize = minmax[1]-minmax[0]+1;
1851     if(DEBUG || kVerbose > 0) G4cout << "msiz    1850     if(DEBUG || kVerbose > 0) G4cout << "msize: " << msize << G4endl;
1852     char * pdmap = new char[msize*sizeof(floa    1851     char * pdmap = new char[msize*sizeof(float)];
1853     ifile.read((char *)pdmap, msize*sizeof(fl    1852     ifile.read((char *)pdmap, msize*sizeof(float));
1854     float ftmp;                                  1853     float ftmp;
1855     for(int i = 0; i < (int)msize; i++) {        1854     for(int i = 0; i < (int)msize; i++) {
1856       convertEndian(pdmap+i*sizeof(float), ft    1855       convertEndian(pdmap+i*sizeof(float), ftmp);
1857       kModalityImageDensityMap.push_back(ftmp    1856       kModalityImageDensityMap.push_back(ftmp); 
1858     }                                            1857     }
1859     delete [] pdmap;                          << 
1860                                               << 
1861     if(DEBUG || kVerbose > 0) {                  1858     if(DEBUG || kVerbose > 0) {
1862       G4cout << "density map : " << std::ends    1859       G4cout << "density map : " << std::ends;
1863       for(int i = 0; i < 10; i++)                1860       for(int i = 0; i < 10; i++)
1864   G4cout <<kModalityImageDensityMap[i] << ",     1861   G4cout <<kModalityImageDensityMap[i] << ", ";
1865       G4cout << G4endl;                          1862       G4cout << G4endl;
1866       for(int i = 0; i < 10; i++) G4cout << "    1863       for(int i = 0; i < 10; i++) G4cout << "..";
1867       G4cout << G4endl;                          1864       G4cout << G4endl;
1868       for(size_t i =kModalityImageDensityMap.    1865       for(size_t i =kModalityImageDensityMap.size() - 10; i <kModalityImageDensityMap.size(); i++)
1869   G4cout <<kModalityImageDensityMap[i] << ",     1866   G4cout <<kModalityImageDensityMap[i] << ", ";
1870       G4cout << G4endl;                          1867       G4cout << G4endl;
1871     }                                            1868     }
1872                                                  1869 
1873   }                                              1870   }
1874                                                  1871 
1875                                                  1872 
1876   //----- dose distribution image -----//        1873   //----- dose distribution image -----//
1877   for(int ndose = 0; ndose < nDoseDist; ndose    1874   for(int ndose = 0; ndose < nDoseDist; ndose++) {
1878                                                  1875 
1879     newDoseDist();                               1876     newDoseDist();
1880                                                  1877 
1881     // dose distrbution image size               1878     // dose distrbution image size
1882     ifile.read((char *)ctmp, 3*sizeof(int));     1879     ifile.read((char *)ctmp, 3*sizeof(int));
1883     convertEndian(ctmp, size[0]);                1880     convertEndian(ctmp, size[0]);
1884     convertEndian(ctmp+sizeof(int), size[1]);    1881     convertEndian(ctmp+sizeof(int), size[1]);
1885     convertEndian(ctmp+2*sizeof(int), size[2]    1882     convertEndian(ctmp+2*sizeof(int), size[2]);
1886     if(DEBUG || kVerbose > 0) {                  1883     if(DEBUG || kVerbose > 0) {
1887       G4cout << "Dose dist. image size : ("      1884       G4cout << "Dose dist. image size : ("
1888     << size[0] << ", "                           1885     << size[0] << ", "
1889     << size[1] << ", "                           1886     << size[1] << ", "
1890     << size[2] << ")"                            1887     << size[2] << ")"
1891     << G4endl;                                   1888     << G4endl;
1892     }                                            1889     }
1893     kDose[ndose].setSize(size);                  1890     kDose[ndose].setSize(size);
1894                                                  1891 
1895     // dose distribution max. & min.             1892     // dose distribution max. & min. 
1896     ifile.read((char *)ctmp, sizeof(short)*2)    1893     ifile.read((char *)ctmp, sizeof(short)*2);
1897     convertEndian(ctmp, minmax[0]);              1894     convertEndian(ctmp, minmax[0]);
1898     convertEndian(ctmp+2, minmax[1]);            1895     convertEndian(ctmp+2, minmax[1]);
1899                                                  1896 
1900     // dose distribution unit                    1897     // dose distribution unit
1901     char dunit[13];                              1898     char dunit[13];
1902     dunit[12] = '\0';                            1899     dunit[12] = '\0';
1903     ifile.read((char *)dunit, 12);               1900     ifile.read((char *)dunit, 12);
1904     std::string sdunit = dunit;                  1901     std::string sdunit = dunit;
1905     setDoseDistUnit(sdunit, ndose);              1902     setDoseDistUnit(sdunit, ndose);
1906     if(DEBUG || kVerbose > 0) {                  1903     if(DEBUG || kVerbose > 0) {
1907       G4cout << "Dose dist. unit : " << kDose    1904       G4cout << "Dose dist. unit : " << kDoseUnit << G4endl;
1908     }                                            1905     }
1909                                                  1906 
1910     // dose distribution scaling                 1907     // dose distribution scaling 
1911     ifile.read((char *)ctmp, 4); // sizeof(fl    1908     ifile.read((char *)ctmp, 4); // sizeof(float)
1912     convertEndian(ctmp, scale);                  1909     convertEndian(ctmp, scale);
1913     kDose[ndose].setScale(dscale = scale);       1910     kDose[ndose].setScale(dscale = scale);
1914                                                  1911 
1915     double dminmax[2];                           1912     double dminmax[2];
1916     for(int i = 0; i < 2; i++) dminmax[i] = m    1913     for(int i = 0; i < 2; i++) dminmax[i] = minmax[i]*dscale;
1917     kDose[ndose].setMinMax(dminmax);             1914     kDose[ndose].setMinMax(dminmax);
1918                                                  1915 
1919     if(DEBUG || kVerbose > 0) {                  1916     if(DEBUG || kVerbose > 0) {
1920       G4cout << "Dose dist. image min., max.,    1917       G4cout << "Dose dist. image min., max., scale : "
1921     << dminmax[0] << ", "                        1918     << dminmax[0] << ", "
1922     << dminmax[1] << ", "                        1919     << dminmax[1] << ", "
1923     << scale << G4endl;                          1920     << scale << G4endl;
1924     }                                            1921     }
1925                                                  1922 
1926     // dose distribution image                   1923     // dose distribution image
1927     int dsize = size[0]*size[1];                 1924     int dsize = size[0]*size[1];
1928     if(DEBUG || kVerbose > 0) G4cout << "Dose    1925     if(DEBUG || kVerbose > 0) G4cout << "Dose dist. (" << dsize << "): ";
1929     char * di = new char[dsize*sizeof(short)]    1926     char * di = new char[dsize*sizeof(short)];
1930     short * shimage = new short[dsize];          1927     short * shimage = new short[dsize];
1931     for(int z = 0; z < size[2]; z++) {           1928     for(int z = 0; z < size[2]; z++) {
1932       ifile.read((char *)di, dsize*sizeof(sho    1929       ifile.read((char *)di, dsize*sizeof(short));
1933       double * dimage = new double[dsize];       1930       double * dimage = new double[dsize];
1934       for(int xy = 0; xy < dsize; xy++) {        1931       for(int xy = 0; xy < dsize; xy++) {
1935   convertEndian(di+xy*sizeof(short), shimage[    1932   convertEndian(di+xy*sizeof(short), shimage[xy]);
1936   dimage[xy] = shimage[xy]*dscale;               1933   dimage[xy] = shimage[xy]*dscale;
1937       }                                          1934       }
1938       kDose[ndose].addImage(dimage);             1935       kDose[ndose].addImage(dimage);
1939                                                  1936 
1940       if(DEBUG || kVerbose > 0) G4cout << "["    1937       if(DEBUG || kVerbose > 0) G4cout << "[" << z << "]" << dimage[(size_t)(dsize*0.55)] << ", ";
1941                                                  1938 
1942       if(DEBUG || kVerbose > 0) {                1939       if(DEBUG || kVerbose > 0) {
1943   for(int j = 0; j < dsize; j++) {               1940   for(int j = 0; j < dsize; j++) {
1944     if(dimage[j] < 0)                            1941     if(dimage[j] < 0)
1945       G4cout << "[" << j << "," << z << "]"      1942       G4cout << "[" << j << "," << z << "]"
1946           << dimage[j] << ", ";                  1943           << dimage[j] << ", ";
1947   }                                              1944   }
1948       }                                          1945       }
1949     }                                            1946     }
1950     delete [] shimage;                           1947     delete [] shimage;
1951     delete [] di;                                1948     delete [] di;
1952     if(DEBUG || kVerbose > 0) G4cout << G4end    1949     if(DEBUG || kVerbose > 0) G4cout << G4endl;
1953                                                  1950 
1954     ifile.read((char *)ctmp, 3*4); // 3*sizeo    1951     ifile.read((char *)ctmp, 3*4); // 3*sizeof(int)
1955     convertEndian(ctmp, iCenter[0]);             1952     convertEndian(ctmp, iCenter[0]);
1956     convertEndian(ctmp+4, iCenter[1]);           1953     convertEndian(ctmp+4, iCenter[1]);
1957     convertEndian(ctmp+8, iCenter[2]);           1954     convertEndian(ctmp+8, iCenter[2]);
1958     for(int i = 0; i < 3; i++) fCenter[i] = (    1955     for(int i = 0; i < 3; i++) fCenter[i] = (float)iCenter[i];
1959     kDose[ndose].setCenterPosition(fCenter);     1956     kDose[ndose].setCenterPosition(fCenter);
1960                                                  1957 
1961     if(DEBUG || kVerbose > 0) {                  1958     if(DEBUG || kVerbose > 0) {
1962       G4cout << "Dose dist. image relative lo    1959       G4cout << "Dose dist. image relative location : ("
1963     << fCenter[0] << ", "                        1960     << fCenter[0] << ", "
1964     << fCenter[1] << ", "                        1961     << fCenter[1] << ", "
1965     << fCenter[2] << ")" << G4endl;              1962     << fCenter[2] << ")" << G4endl;
1966     }                                            1963     }
1967                                                  1964 
1968                                                  1965 
1969     // dose distribution name                    1966     // dose distribution name
1970     char cname[81];                              1967     char cname[81];
1971     ifile.read((char *)cname, 80);               1968     ifile.read((char *)cname, 80);
1972     std::string dosename = cname;                1969     std::string dosename = cname;
1973     setDoseDistName(dosename, ndose);            1970     setDoseDistName(dosename, ndose);
1974     if(DEBUG || kVerbose > 0) {                  1971     if(DEBUG || kVerbose > 0) {
1975       G4cout << "Dose dist. name : " << dosen    1972       G4cout << "Dose dist. name : " << dosename << G4endl;
1976     }                                            1973     }
1977                                                  1974 
1978   }                                              1975   }
1979                                                  1976 
1980   //----- ROI image -----//                      1977   //----- ROI image -----//
1981   if(kPointerToROIData != 0) {                   1978   if(kPointerToROIData != 0) {
1982                                                  1979 
1983     newROI();                                    1980     newROI();
1984                                                  1981 
1985     // ROI image size                            1982     // ROI image size
1986     ifile.read((char *)ctmp, 3*sizeof(int));     1983     ifile.read((char *)ctmp, 3*sizeof(int));
1987     convertEndian(ctmp, size[0]);                1984     convertEndian(ctmp, size[0]);
1988     convertEndian(ctmp+sizeof(int), size[1]);    1985     convertEndian(ctmp+sizeof(int), size[1]);
1989     convertEndian(ctmp+2*sizeof(int), size[2]    1986     convertEndian(ctmp+2*sizeof(int), size[2]);
1990     kRoi[0].setSize(size);                       1987     kRoi[0].setSize(size);
1991     if(DEBUG || kVerbose > 0) {                  1988     if(DEBUG || kVerbose > 0) {
1992       G4cout << "ROI image size : ("             1989       G4cout << "ROI image size : ("
1993     << size[0] << ", "                           1990     << size[0] << ", "
1994     << size[1] << ", "                           1991     << size[1] << ", "
1995     << size[2] << ")"                            1992     << size[2] << ")"
1996     << G4endl;                                   1993     << G4endl;
1997     }                                            1994     }
1998                                                  1995 
1999     // ROI max. & min.                           1996     // ROI max. & min.
2000     ifile.read((char *)ctmp, sizeof(short)*2)    1997     ifile.read((char *)ctmp, sizeof(short)*2);
2001     convertEndian(ctmp, minmax[0]);              1998     convertEndian(ctmp, minmax[0]);
2002     convertEndian(ctmp+sizeof(short), minmax[    1999     convertEndian(ctmp+sizeof(short), minmax[1]);
2003     kRoi[0].setMinMax(minmax);                   2000     kRoi[0].setMinMax(minmax);
2004                                                  2001 
2005     // ROI distribution scaling                  2002     // ROI distribution scaling 
2006     ifile.read((char *)ctmp, sizeof(float));     2003     ifile.read((char *)ctmp, sizeof(float));
2007     convertEndian(ctmp, scale);                  2004     convertEndian(ctmp, scale);
2008     kRoi[0].setScale(dscale = scale);            2005     kRoi[0].setScale(dscale = scale);
2009     if(DEBUG || kVerbose > 0) {                  2006     if(DEBUG || kVerbose > 0) {
2010       G4cout << "ROI image min., max., scale     2007       G4cout << "ROI image min., max., scale : "
2011     << minmax[0] << ", "                         2008     << minmax[0] << ", "
2012     << minmax[1] << ", "                         2009     << minmax[1] << ", "
2013     << scale << G4endl;                          2010     << scale << G4endl;
2014     }                                            2011     }
2015                                                  2012 
2016     // ROI image                                 2013     // ROI image
2017     int rsize = size[0]*size[1];                 2014     int rsize = size[0]*size[1];
2018     char * ri = new char[rsize*sizeof(short)]    2015     char * ri = new char[rsize*sizeof(short)];
2019     for(int i = 0; i < size[2]; i++) {           2016     for(int i = 0; i < size[2]; i++) {
2020       ifile.read((char *)ri, rsize*sizeof(sho    2017       ifile.read((char *)ri, rsize*sizeof(short));
2021       short * rimage = new short[rsize];         2018       short * rimage = new short[rsize];
2022       for(int j = 0; j < rsize; j++) {           2019       for(int j = 0; j < rsize; j++) {
2023   convertEndian(ri+j*sizeof(short), rimage[j]    2020   convertEndian(ri+j*sizeof(short), rimage[j]);
2024       }                                          2021       }
2025       kRoi[0].addImage(rimage);                  2022       kRoi[0].addImage(rimage);
2026                                                  2023 
2027     }                                            2024     }
2028     delete [] ri;                                2025     delete [] ri;
2029                                                  2026 
2030     // ROI relative location                     2027     // ROI relative location
2031     ifile.read((char *)ctmp, 3*sizeof(int));     2028     ifile.read((char *)ctmp, 3*sizeof(int));
2032     convertEndian(ctmp, iCenter[0]);             2029     convertEndian(ctmp, iCenter[0]);
2033     convertEndian(ctmp+sizeof(int), iCenter[1    2030     convertEndian(ctmp+sizeof(int), iCenter[1]);
2034     convertEndian(ctmp+2*sizeof(int), iCenter    2031     convertEndian(ctmp+2*sizeof(int), iCenter[2]);
2035     for(int i = 0; i < 3; i++) fCenter[i] = i    2032     for(int i = 0; i < 3; i++) fCenter[i] = iCenter[i];
2036     kRoi[0].setCenterPosition(fCenter);          2033     kRoi[0].setCenterPosition(fCenter);
2037     if(DEBUG || kVerbose > 0) {                  2034     if(DEBUG || kVerbose > 0) {
2038       G4cout << "ROI image relative location     2035       G4cout << "ROI image relative location : ("
2039     << fCenter[0] << ", "                        2036     << fCenter[0] << ", "
2040     << fCenter[1] << ", "                        2037     << fCenter[1] << ", "
2041     << fCenter[2] << ")" << G4endl;              2038     << fCenter[2] << ")" << G4endl;
2042     }                                            2039     }
2043                                                  2040 
2044   }                                              2041   }
2045                                                  2042 
2046   //----- track information -----//              2043   //----- track information -----//
2047   if(kPointerToTrackData != 0) {                 2044   if(kPointerToTrackData != 0) {
2048                                                  2045 
2049     // track                                     2046     // track
2050     ifile.read((char *)ctmp, sizeof(int));       2047     ifile.read((char *)ctmp, sizeof(int));
2051     int ntrk;                                    2048     int ntrk;
2052     convertEndian(ctmp, ntrk);                   2049     convertEndian(ctmp, ntrk);
2053     if(DEBUG || kVerbose > 0) {                  2050     if(DEBUG || kVerbose > 0) {
2054       G4cout << "# of tracks: " << ntrk << G4    2051       G4cout << "# of tracks: " << ntrk << G4endl;
2055     }                                            2052     }
2056                                                  2053 
2057     // track position                            2054     // track position
2058     unsigned char rgb[3];                        2055     unsigned char rgb[3];
2059     for(int i = 0; i < ntrk; i++) {              2056     for(int i = 0; i < ntrk; i++) {
2060                                                  2057 
2061                                                  2058 
2062       // # of steps in a track                   2059       // # of steps in a track
2063       ifile.read((char *)ctmp, sizeof(int));     2060       ifile.read((char *)ctmp, sizeof(int));
2064       int nsteps;                                2061       int nsteps;
2065       convertEndian(ctmp, nsteps);               2062       convertEndian(ctmp, nsteps);
2066                                                  2063       
2067       // track color                             2064       // track color
2068       ifile.read((char *)rgb, 3);                2065       ifile.read((char *)rgb, 3);
2069                                                  2066 
2070       std::vector<float *> steps;                2067       std::vector<float *> steps;
2071       // steps                                   2068       // steps
2072       for(int j = 0; j < nsteps; j++) {          2069       for(int j = 0; j < nsteps; j++) {
2073                                                  2070 
2074   float * steppoint = new float[6];              2071   float * steppoint = new float[6];
2075   ifile.read((char *)ctmp, sizeof(float)*6);     2072   ifile.read((char *)ctmp, sizeof(float)*6);
2076                                                  2073 
2077   for(int k = 0; k < 6; k++) {                   2074   for(int k = 0; k < 6; k++) {
2078     convertEndian(ctmp+k*sizeof(float), stepp    2075     convertEndian(ctmp+k*sizeof(float), steppoint[k]);
2079   }                                              2076   }
2080                                                  2077   
2081   steps.push_back(steppoint);                    2078   steps.push_back(steppoint);
2082       }                                          2079       }
2083                                                  2080 
2084       // add a track to the track container      2081       // add a track to the track container
2085       addTrack(steps, rgb);                      2082       addTrack(steps, rgb);
2086                                                  2083 
2087       if(DEBUG || kVerbose > 0) {                2084       if(DEBUG || kVerbose > 0) {
2088   if(i < 5) {                                    2085   if(i < 5) {
2089     G4cout << i << ": " ;                        2086     G4cout << i << ": " ;
2090     for(int j = 0; j < 3; j++) G4cout << step    2087     for(int j = 0; j < 3; j++) G4cout << steps[0][j] << " ";
2091     int nstp = (int)steps.size();             << 2088     int nstp = steps.size();
2092     G4cout << "<-> ";                            2089     G4cout << "<-> ";
2093     for(int j = 3; j < 6; j++) G4cout << step    2090     for(int j = 3; j < 6; j++) G4cout << steps[nstp-1][j] << " ";
2094     G4cout << "    rgb( ";                       2091     G4cout << "    rgb( ";
2095     for(int j = 0; j < 3; j++) G4cout << (int    2092     for(int j = 0; j < 3; j++) G4cout << (int)rgb[j] << " ";
2096     G4cout << ")" << G4endl;                     2093     G4cout << ")" << G4endl;
2097   }                                              2094   }
2098       }                                          2095       }
2099     }                                            2096     }
2100                                                  2097 
2101                                                  2098 
2102   }                                              2099   }
2103                                                  2100 
2104                                                  2101 
2105   //----- detector information -----//           2102   //----- detector information -----//
2106   if(kPointerToDetectorData != 0) {              2103   if(kPointerToDetectorData != 0) {
2107                                                  2104 
2108     // number of detectors                       2105     // number of detectors
2109     ifile.read((char *)ctmp, sizeof(int));       2106     ifile.read((char *)ctmp, sizeof(int));
2110     int ndet;                                    2107     int ndet;
2111     convertEndian(ctmp, ndet);                   2108     convertEndian(ctmp, ndet);
2112                                                  2109 
2113     if(DEBUG || kVerbose > 0) {                  2110     if(DEBUG || kVerbose > 0) {
2114       G4cout << "# of detectors : "              2111       G4cout << "# of detectors : "
2115     << ndet << G4endl;                           2112     << ndet << G4endl;
2116     }                                            2113     }
2117                                                  2114 
2118     for(int nd = 0; nd < ndet; nd++) {           2115     for(int nd = 0; nd < ndet; nd++) {
2119                                                  2116 
2120       // # of edges of a detector                2117       // # of edges of a detector
2121       ifile.read((char *)ctmp, sizeof(int));     2118       ifile.read((char *)ctmp, sizeof(int));
2122       int nedges;                                2119       int nedges;
2123       convertEndian(ctmp, nedges);               2120       convertEndian(ctmp, nedges);
2124       if(DEBUG || kVerbose > 0) {                2121       if(DEBUG || kVerbose > 0) {
2125   G4cout << "# of edges in a detector : " <<     2122   G4cout << "# of edges in a detector : " << nedges << G4endl;
2126       }                                          2123       }
2127                                                  2124 
2128       // edges                                   2125       // edges
2129       std::vector<float *> detector;             2126       std::vector<float *> detector;
2130       char cftmp[24];                            2127       char cftmp[24];
2131       for(int ne = 0; ne < nedges; ne++) {       2128       for(int ne = 0; ne < nedges; ne++) {
2132                                                  2129       
2133   ifile.read((char *)cftmp, sizeof(float)*6);    2130   ifile.read((char *)cftmp, sizeof(float)*6);
2134   float * edgePoints = new float[6];             2131   float * edgePoints = new float[6];
2135   for(int j = 0; j < 6; j++) convertEndian(&c    2132   for(int j = 0; j < 6; j++) convertEndian(&cftmp[sizeof(float)*j], edgePoints[j]);
2136   detector.push_back(edgePoints);                2133   detector.push_back(edgePoints);
2137                                                  2134 
2138       }                                          2135       }
2139                                                  2136 
2140       if(DEBUG || kVerbose > 0) {                2137       if(DEBUG || kVerbose > 0) {
2141   G4cout << " first edge : (" << detector[0][    2138   G4cout << " first edge : (" << detector[0][0] << ", "
2142       << detector[0][1] << ", "                  2139       << detector[0][1] << ", "
2143       << detector[0][2] << ") - ("               2140       << detector[0][2] << ") - ("
2144       << detector[0][3] << ", "                  2141       << detector[0][3] << ", "
2145       << detector[0][4] << ", "                  2142       << detector[0][4] << ", "
2146       << detector[0][5] << ")" << G4endl;        2143       << detector[0][5] << ")" << G4endl;
2147       }                                          2144       }
2148                                                  2145 
2149       // detector color                          2146       // detector color
2150       unsigned char dcolor[3];                   2147       unsigned char dcolor[3];
2151       ifile.read((char *)dcolor, 3);             2148       ifile.read((char *)dcolor, 3);
2152       if(DEBUG || kVerbose > 0) {                2149       if(DEBUG || kVerbose > 0) {
2153   G4cout << " detector color : rgb("             2150   G4cout << " detector color : rgb("
2154       << (int)dcolor[0] << ", "                  2151       << (int)dcolor[0] << ", "
2155       << (int)dcolor[1] << ", "                  2152       << (int)dcolor[1] << ", "
2156       << (int)dcolor[2] << G4endl;               2153       << (int)dcolor[2] << G4endl;
2157       }                                          2154       }
2158                                                  2155 
2159                                                  2156 
2160       // detector name                           2157       // detector name
2161       char cname[80];                            2158       char cname[80];
2162       ifile.read((char *)cname, 80);             2159       ifile.read((char *)cname, 80);
2163       std::string dname = cname;                 2160       std::string dname = cname;
2164       if(DEBUG || kVerbose > 0) {                2161       if(DEBUG || kVerbose > 0) {
2165   G4cout << " detector name : " << dname << G    2162   G4cout << " detector name : " << dname << G4endl;
2166       }                                          2163       }
2167                                                  2164 
2168                                                  2165 
2169       addDetector(dname, detector, dcolor);      2166       addDetector(dname, detector, dcolor);
2170                                                  2167 
2171     }                                            2168     }
2172   }                                              2169   }
2173                                                  2170 
2174                                                  2171 
2175   ifile.close();                                 2172   ifile.close();
2176                                                  2173 
2177   return true;                                   2174   return true;
2178 }                                                2175 }
2179 bool G4GMocrenIO::retrieveData4(char * _filen    2176 bool G4GMocrenIO::retrieveData4(char * _filename) {
2180   kFileName = _filename;                         2177   kFileName = _filename;
2181   return retrieveData();                         2178   return retrieveData();
2182 }                                                2179 }
2183                                                  2180 
2184 //                                               2181 // 
2185 bool G4GMocrenIO::retrieveData3() {              2182 bool G4GMocrenIO::retrieveData3() {
2186                                                  2183 
2187   bool DEBUG = false;//                          2184   bool DEBUG = false;//
2188                                                  2185 
2189   // input file open                             2186   // input file open
2190   std::ifstream ifile(kFileName.c_str(), std:    2187   std::ifstream ifile(kFileName.c_str(), std::ios_base::in|std::ios_base::binary);
2191   if(!ifile) {                                   2188   if(!ifile) {
2192     if (G4VisManager::GetVerbosity() >= G4Vis    2189     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
2193       G4cout << "Cannot open file: " << kFile    2190       G4cout << "Cannot open file: " << kFileName
2194     << " in G4GMocrenIO::retrieveData3()." <<    2191     << " in G4GMocrenIO::retrieveData3()." << G4endl;
2195     return false;                                2192     return false;
2196   }                                              2193   }
2197                                                  2194 
2198   // data buffer                                 2195   // data buffer
2199   char ctmp[12];                                 2196   char ctmp[12];
2200                                                  2197 
2201   // file identifier                             2198   // file identifier
2202   char verid[9];                                 2199   char verid[9];
2203   ifile.read((char *)verid, 8);                  2200   ifile.read((char *)verid, 8);
2204                                                  2201 
2205   // file version                                2202   // file version
2206   unsigned char ver;                             2203   unsigned char ver;
2207   ifile.read((char *)&ver, 1);                   2204   ifile.read((char *)&ver, 1);
2208   std::stringstream ss;                          2205   std::stringstream ss;
2209   ss << (int)ver;                                2206   ss << (int)ver;
2210   kVersion = ss.str();                           2207   kVersion = ss.str();
2211   if(DEBUG || kVerbose > 0) G4cout << "File v    2208   if(DEBUG || kVerbose > 0) G4cout << "File version : " << kVersion << G4endl;
2212                                                  2209 
2213   // endian                                      2210   // endian
2214   ifile.read((char *)&kLittleEndianInput, siz    2211   ifile.read((char *)&kLittleEndianInput, sizeof(char));
2215   if(DEBUG || kVerbose > 0) {                    2212   if(DEBUG || kVerbose > 0) {
2216     G4cout << "Endian : ";                       2213     G4cout << "Endian : ";
2217     if(kLittleEndianInput == 1)                  2214     if(kLittleEndianInput == 1) 
2218       G4cout << " little" << G4endl;             2215       G4cout << " little" << G4endl;
2219     else {                                       2216     else {
2220       G4cout << " big" << G4endl;                2217       G4cout << " big" << G4endl;
2221     }                                            2218     }
2222   }                                              2219   }
2223                                                  2220 
2224   // comment length (fixed size)                 2221   // comment length (fixed size)
2225   int clength;                                   2222   int clength;
2226   ifile.read((char *)ctmp, 4);                   2223   ifile.read((char *)ctmp, 4);
2227   convertEndian(ctmp, clength);                  2224   convertEndian(ctmp, clength);
2228   // comment                                     2225   // comment
2229   char cmt[1025];                                2226   char cmt[1025];
2230   ifile.read((char *)cmt, clength);              2227   ifile.read((char *)cmt, clength);
2231   std::string scmt = cmt;                        2228   std::string scmt = cmt;
2232   setComment(scmt);                              2229   setComment(scmt);
2233   if(DEBUG || kVerbose > 0) {                    2230   if(DEBUG || kVerbose > 0) {
2234     G4cout << "Data comment : "                  2231     G4cout << "Data comment : "
2235         << kComment << G4endl;                   2232         << kComment << G4endl;
2236   }                                              2233   }
2237                                                  2234 
2238   // voxel spacings for all images               2235   // voxel spacings for all images
2239   ifile.read((char *)ctmp, 12);                  2236   ifile.read((char *)ctmp, 12);
2240   convertEndian(ctmp, kVoxelSpacing[0]);         2237   convertEndian(ctmp, kVoxelSpacing[0]);
2241   convertEndian(ctmp+4, kVoxelSpacing[1]);       2238   convertEndian(ctmp+4, kVoxelSpacing[1]);
2242   convertEndian(ctmp+8, kVoxelSpacing[2]);       2239   convertEndian(ctmp+8, kVoxelSpacing[2]);
2243   if(DEBUG || kVerbose > 0) {                    2240   if(DEBUG || kVerbose > 0) {
2244     G4cout << "Voxel spacing : ("                2241     G4cout << "Voxel spacing : ("
2245         << kVoxelSpacing[0] << ", "              2242         << kVoxelSpacing[0] << ", "
2246         << kVoxelSpacing[1] << ", "              2243         << kVoxelSpacing[1] << ", "
2247         << kVoxelSpacing[2]                      2244         << kVoxelSpacing[2]
2248         << ") mm " << G4endl;                    2245         << ") mm " << G4endl;
2249   }                                              2246   }
2250                                                  2247 
2251                                                  2248 
2252   // offset from file starting point to the m    2249   // offset from file starting point to the modality image data
2253   ifile.read((char *)ctmp, 4);                   2250   ifile.read((char *)ctmp, 4);
2254   convertEndian(ctmp, kPointerToModalityData)    2251   convertEndian(ctmp, kPointerToModalityData);
2255                                                  2252 
2256   // # of dose distributions                     2253   // # of dose distributions
2257   ifile.read((char *)ctmp, 4);                   2254   ifile.read((char *)ctmp, 4);
2258   int nDoseDist;                                 2255   int nDoseDist;
2259   convertEndian(ctmp, nDoseDist);                2256   convertEndian(ctmp, nDoseDist);
2260                                                  2257   
2261   // offset from file starting point to the d    2258   // offset from file starting point to the dose image data
2262   for(int i = 0; i < nDoseDist; i++) {           2259   for(int i = 0; i < nDoseDist; i++) {
2263     ifile.read((char *)ctmp, 4);                 2260     ifile.read((char *)ctmp, 4);
2264     unsigned int dptr;                           2261     unsigned int dptr;
2265     convertEndian(ctmp, dptr);                   2262     convertEndian(ctmp, dptr);
2266     addPointerToDoseDistData(dptr);              2263     addPointerToDoseDistData(dptr);
2267   }                                              2264   }
2268                                                  2265 
2269   // offset from file starting point to the R    2266   // offset from file starting point to the ROI image data
2270   ifile.read((char *)ctmp, 4);                   2267   ifile.read((char *)ctmp, 4);
2271   convertEndian(ctmp, kPointerToROIData);        2268   convertEndian(ctmp, kPointerToROIData);
2272                                                  2269 
2273   // offset from file starting point to the t    2270   // offset from file starting point to the track data
2274   ifile.read((char *)ctmp, 4);                   2271   ifile.read((char *)ctmp, 4);
2275   convertEndian(ctmp, kPointerToTrackData);      2272   convertEndian(ctmp, kPointerToTrackData);
2276   if(DEBUG || kVerbose > 0) {                    2273   if(DEBUG || kVerbose > 0) {
2277     G4cout << "Each pointer to data : "          2274     G4cout << "Each pointer to data : "
2278         << kPointerToModalityData << ", ";       2275         << kPointerToModalityData << ", ";
2279     for(int i = 0; i < nDoseDist; i++)           2276     for(int i = 0; i < nDoseDist; i++)
2280       G4cout << kPointerToDoseDistData[0] <<     2277       G4cout << kPointerToDoseDistData[0] << ", ";
2281     G4cout << kPointerToROIData << ", "          2278     G4cout << kPointerToROIData << ", "
2282         << kPointerToTrackData << G4endl;        2279         << kPointerToTrackData << G4endl;
2283   }                                              2280   }
2284                                                  2281 
2285   if(kPointerToModalityData == 0 && kPointerT    2282   if(kPointerToModalityData == 0 && kPointerToDoseDistData.size() == 0 &&
2286      kPointerToROIData == 0 && kPointerToTrac    2283      kPointerToROIData == 0 && kPointerToTrackData == 0) {
2287     if(DEBUG || kVerbose > 0) {                  2284     if(DEBUG || kVerbose > 0) {
2288       G4cout << "No data." << G4endl;            2285       G4cout << "No data." << G4endl;
2289     }                                            2286     }
2290     return false;                                2287     return false;
2291   }                                              2288   }
2292                                                  2289 
2293   // event number                                2290   // event number
2294   /* ver 1                                       2291   /* ver 1
2295      ifile.read(ctmp, sizeof(int));              2292      ifile.read(ctmp, sizeof(int));
2296      convertEndian(ctmp, numberOfEvents);        2293      convertEndian(ctmp, numberOfEvents);
2297   */                                             2294   */
2298                                                  2295 
2299   int size[3];                                   2296   int size[3];
2300   float scale;                                   2297   float scale;
2301   double dscale;                                 2298   double dscale;
2302   short minmax[2];                               2299   short minmax[2];
2303   float fCenter[3];                              2300   float fCenter[3];
2304   int iCenter[3];                                2301   int iCenter[3];
2305                                                  2302 
2306   //----- Modality image -----//                 2303   //----- Modality image -----//
2307   // modality image size                         2304   // modality image size
2308   ifile.read(ctmp, 3*sizeof(int));               2305   ifile.read(ctmp, 3*sizeof(int));
2309   convertEndian(ctmp, size[0]);                  2306   convertEndian(ctmp, size[0]);
2310   convertEndian(ctmp+sizeof(int), size[1]);      2307   convertEndian(ctmp+sizeof(int), size[1]);
2311   convertEndian(ctmp+2*sizeof(int), size[2]);    2308   convertEndian(ctmp+2*sizeof(int), size[2]);
2312   if(DEBUG || kVerbose > 0) {                    2309   if(DEBUG || kVerbose > 0) {
2313     G4cout << "Modality image size : ("          2310     G4cout << "Modality image size : ("
2314         << size[0] << ", "                       2311         << size[0] << ", "
2315         << size[1] << ", "                       2312         << size[1] << ", "
2316         << size[2] << ")"                        2313         << size[2] << ")"
2317         << G4endl;                               2314         << G4endl;
2318   }                                              2315   }
2319   kModality.setSize(size);                       2316   kModality.setSize(size);
2320                                                  2317 
2321   // modality image voxel spacing                2318   // modality image voxel spacing
2322   /*                                             2319   /*
2323     ifile.read(ctmp, 3*sizeof(float));           2320     ifile.read(ctmp, 3*sizeof(float));
2324     convertEndian(ctmp, modalityImageVoxelSpa    2321     convertEndian(ctmp, modalityImageVoxelSpacing[0]);
2325     convertEndian(ctmp+sizeof(float), modalit    2322     convertEndian(ctmp+sizeof(float), modalityImageVoxelSpacing[1]);
2326     convertEndian(ctmp+2*sizeof(float), modal    2323     convertEndian(ctmp+2*sizeof(float), modalityImageVoxelSpacing[2]);
2327   */                                             2324   */
2328                                                  2325 
2329   if(kPointerToModalityData != 0) {              2326   if(kPointerToModalityData != 0) {
2330                                                  2327 
2331     // modality density max. & min.              2328     // modality density max. & min.
2332     ifile.read((char *)ctmp, 4);                 2329     ifile.read((char *)ctmp, 4);
2333     convertEndian(ctmp, minmax[0]);              2330     convertEndian(ctmp, minmax[0]);
2334     convertEndian(ctmp+2, minmax[1]);            2331     convertEndian(ctmp+2, minmax[1]);
2335     kModality.setMinMax(minmax);                 2332     kModality.setMinMax(minmax);
2336                                                  2333 
2337     // modality image unit                       2334     // modality image unit
2338     char munit[13];                              2335     char munit[13];
2339     ifile.read((char *)munit, 12);               2336     ifile.read((char *)munit, 12);
2340     std::string smunit = munit;                  2337     std::string smunit = munit;
2341     setModalityImageUnit(smunit);                2338     setModalityImageUnit(smunit);
2342                                                  2339 
2343     // modality density scale                    2340     // modality density scale
2344     ifile.read((char *)ctmp, 4);                 2341     ifile.read((char *)ctmp, 4);
2345     convertEndian(ctmp, scale);                  2342     convertEndian(ctmp, scale);
2346     kModality.setScale(dscale = scale);          2343     kModality.setScale(dscale = scale);
2347     if(DEBUG || kVerbose > 0) {                  2344     if(DEBUG || kVerbose > 0) {
2348       G4cout << "Modality image min., max., s    2345       G4cout << "Modality image min., max., scale : "
2349     << minmax[0] << ", "                         2346     << minmax[0] << ", "
2350     << minmax[1] << ", "                         2347     << minmax[1] << ", "
2351     << scale << G4endl;                          2348     << scale << G4endl;
2352     }                                            2349     }
2353                                                  2350 
2354     // modality density                          2351     // modality density
2355     int psize = size[0]*size[1];                 2352     int psize = size[0]*size[1];
2356     if(DEBUG || kVerbose > 0) G4cout << "Moda    2353     if(DEBUG || kVerbose > 0) G4cout << "Modality image (" << psize << "): ";
2357     char * cimage = new char[psize*sizeof(sho    2354     char * cimage = new char[psize*sizeof(short)];
2358     for(int i = 0; i < size[2]; i++) {           2355     for(int i = 0; i < size[2]; i++) {
2359       ifile.read((char *)cimage, psize*sizeof    2356       ifile.read((char *)cimage, psize*sizeof(short));
2360       short * mimage = new short[psize];         2357       short * mimage = new short[psize];
2361       for(int j = 0; j < psize; j++) {           2358       for(int j = 0; j < psize; j++) {
2362   convertEndian(cimage+j*sizeof(short), mimag    2359   convertEndian(cimage+j*sizeof(short), mimage[j]);
2363       }                                          2360       }
2364       kModality.addImage(mimage);                2361       kModality.addImage(mimage);
2365                                                  2362 
2366       if(DEBUG || kVerbose > 0) G4cout << "["    2363       if(DEBUG || kVerbose > 0) G4cout << "[" << i << "]" << mimage[(size_t)(psize*0.55)] << ", ";
2367     }                                            2364     }
2368     if(DEBUG || kVerbose > 0) G4cout << G4end    2365     if(DEBUG || kVerbose > 0) G4cout << G4endl;
2369     delete [] cimage;                            2366     delete [] cimage;
2370                                                  2367 
2371     // modality desity map for CT value          2368     // modality desity map for CT value
2372     size_t msize = minmax[1]-minmax[0]+1;        2369     size_t msize = minmax[1]-minmax[0]+1;
2373     if(DEBUG || kVerbose > 0) G4cout << "msiz    2370     if(DEBUG || kVerbose > 0) G4cout << "msize: " << msize << G4endl;
2374     char * pdmap = new char[msize*sizeof(floa    2371     char * pdmap = new char[msize*sizeof(float)];
2375     ifile.read((char *)pdmap, msize*sizeof(fl    2372     ifile.read((char *)pdmap, msize*sizeof(float));
2376     float ftmp;                                  2373     float ftmp;
2377     for(int i = 0; i < (int)msize; i++) {        2374     for(int i = 0; i < (int)msize; i++) {
2378       convertEndian(pdmap+i*sizeof(float), ft    2375       convertEndian(pdmap+i*sizeof(float), ftmp);
2379       kModalityImageDensityMap.push_back(ftmp    2376       kModalityImageDensityMap.push_back(ftmp); 
2380     }                                            2377     }
2381     delete [] pdmap;                          << 
2382     if(DEBUG || kVerbose > 0) {                  2378     if(DEBUG || kVerbose > 0) {
2383       G4cout << "density map : " << std::ends    2379       G4cout << "density map : " << std::ends;
2384       for(int i = 0; i < 10; i++)                2380       for(int i = 0; i < 10; i++)
2385   G4cout <<kModalityImageDensityMap[i] << ",     2381   G4cout <<kModalityImageDensityMap[i] << ", ";
2386       G4cout << G4endl;                          2382       G4cout << G4endl;
2387       for(int i = 0; i < 10; i++) G4cout << "    2383       for(int i = 0; i < 10; i++) G4cout << "..";
2388       G4cout << G4endl;                          2384       G4cout << G4endl;
2389       for(size_t i =kModalityImageDensityMap.    2385       for(size_t i =kModalityImageDensityMap.size() - 10; i <kModalityImageDensityMap.size(); i++)
2390   G4cout <<kModalityImageDensityMap[i] << ",     2386   G4cout <<kModalityImageDensityMap[i] << ", ";
2391       G4cout << G4endl;                          2387       G4cout << G4endl;
2392     }                                            2388     }
2393                                                  2389 
2394   }                                              2390   }
2395                                                  2391 
2396                                                  2392 
2397   //----- dose distribution image -----//        2393   //----- dose distribution image -----//
2398   for(int ndose = 0; ndose < nDoseDist; ndose    2394   for(int ndose = 0; ndose < nDoseDist; ndose++) {
2399                                                  2395 
2400     newDoseDist();                               2396     newDoseDist();
2401                                                  2397 
2402     // dose distrbution image size               2398     // dose distrbution image size
2403     ifile.read((char *)ctmp, 3*sizeof(int));     2399     ifile.read((char *)ctmp, 3*sizeof(int));
2404     convertEndian(ctmp, size[0]);                2400     convertEndian(ctmp, size[0]);
2405     convertEndian(ctmp+sizeof(int), size[1]);    2401     convertEndian(ctmp+sizeof(int), size[1]);
2406     convertEndian(ctmp+2*sizeof(int), size[2]    2402     convertEndian(ctmp+2*sizeof(int), size[2]);
2407     if(DEBUG || kVerbose > 0) {                  2403     if(DEBUG || kVerbose > 0) {
2408       G4cout << "Dose dist. image size : ("      2404       G4cout << "Dose dist. image size : ("
2409     << size[0] << ", "                           2405     << size[0] << ", "
2410     << size[1] << ", "                           2406     << size[1] << ", "
2411     << size[2] << ")"                            2407     << size[2] << ")"
2412     << G4endl;                                   2408     << G4endl;
2413     }                                            2409     }
2414     kDose[ndose].setSize(size);                  2410     kDose[ndose].setSize(size);
2415                                                  2411 
2416     // dose distribution max. & min.             2412     // dose distribution max. & min. 
2417     ifile.read((char *)ctmp, sizeof(short)*2)    2413     ifile.read((char *)ctmp, sizeof(short)*2);
2418     convertEndian(ctmp, minmax[0]);              2414     convertEndian(ctmp, minmax[0]);
2419     convertEndian(ctmp+2, minmax[1]);            2415     convertEndian(ctmp+2, minmax[1]);
2420                                                  2416 
2421     // dose distribution unit                    2417     // dose distribution unit
2422     char dunit[13];                              2418     char dunit[13];
2423     ifile.read((char *)dunit, 12);               2419     ifile.read((char *)dunit, 12);
2424     std::string sdunit = dunit;                  2420     std::string sdunit = dunit;
2425     setDoseDistUnit(sdunit, ndose);              2421     setDoseDistUnit(sdunit, ndose);
2426     if(DEBUG || kVerbose > 0) {                  2422     if(DEBUG || kVerbose > 0) {
2427       G4cout << "Dose dist. unit : " << kDose    2423       G4cout << "Dose dist. unit : " << kDoseUnit << G4endl;
2428     }                                            2424     }
2429                                                  2425 
2430     // dose distribution scaling                 2426     // dose distribution scaling 
2431     ifile.read((char *)ctmp, 4); // sizeof(fl    2427     ifile.read((char *)ctmp, 4); // sizeof(float)
2432     convertEndian(ctmp, scale);                  2428     convertEndian(ctmp, scale);
2433     kDose[ndose].setScale(dscale = scale);       2429     kDose[ndose].setScale(dscale = scale);
2434                                                  2430 
2435     double dminmax[2];                           2431     double dminmax[2];
2436     for(int i = 0; i < 2; i++) dminmax[i] = m    2432     for(int i = 0; i < 2; i++) dminmax[i] = minmax[i]*dscale;
2437     kDose[ndose].setMinMax(dminmax);             2433     kDose[ndose].setMinMax(dminmax);
2438                                                  2434 
2439     if(DEBUG || kVerbose > 0) {                  2435     if(DEBUG || kVerbose > 0) {
2440       G4cout << "Dose dist. image min., max.,    2436       G4cout << "Dose dist. image min., max., scale : "
2441     << dminmax[0] << ", "                        2437     << dminmax[0] << ", "
2442     << dminmax[1] << ", "                        2438     << dminmax[1] << ", "
2443     << scale << G4endl;                          2439     << scale << G4endl;
2444     }                                            2440     }
2445                                                  2441 
2446     // dose distribution image                   2442     // dose distribution image
2447     int dsize = size[0]*size[1];                 2443     int dsize = size[0]*size[1];
2448     if(DEBUG || kVerbose > 0) G4cout << "Dose    2444     if(DEBUG || kVerbose > 0) G4cout << "Dose dist. (" << dsize << "): ";
2449     char * di = new char[dsize*sizeof(short)]    2445     char * di = new char[dsize*sizeof(short)];
2450     short * shimage = new short[dsize];          2446     short * shimage = new short[dsize];
2451     for(int z = 0; z < size[2]; z++) {           2447     for(int z = 0; z < size[2]; z++) {
2452       ifile.read((char *)di, dsize*sizeof(sho    2448       ifile.read((char *)di, dsize*sizeof(short));
2453       double * dimage = new double[dsize];       2449       double * dimage = new double[dsize];
2454       for(int xy = 0; xy < dsize; xy++) {        2450       for(int xy = 0; xy < dsize; xy++) {
2455   convertEndian(di+xy*sizeof(short), shimage[    2451   convertEndian(di+xy*sizeof(short), shimage[xy]);
2456   dimage[xy] = shimage[xy]*dscale;               2452   dimage[xy] = shimage[xy]*dscale;
2457       }                                          2453       }
2458       kDose[ndose].addImage(dimage);             2454       kDose[ndose].addImage(dimage);
2459                                                  2455 
2460       if(DEBUG || kVerbose > 0) G4cout << "["    2456       if(DEBUG || kVerbose > 0) G4cout << "[" << z << "]" << dimage[(size_t)(dsize*0.55)] << ", ";
2461                                                  2457 
2462       if(DEBUG || kVerbose > 0) {                2458       if(DEBUG || kVerbose > 0) {
2463   for(int j = 0; j < dsize; j++) {               2459   for(int j = 0; j < dsize; j++) {
2464     if(dimage[j] < 0)                            2460     if(dimage[j] < 0)
2465       G4cout << "[" << j << "," << z << "]"      2461       G4cout << "[" << j << "," << z << "]"
2466           << dimage[j] << ", ";                  2462           << dimage[j] << ", ";
2467   }                                              2463   }
2468       }                                          2464       }
2469     }                                            2465     }
2470     delete [] shimage;                           2466     delete [] shimage;
2471     delete [] di;                                2467     delete [] di;
2472     if(DEBUG || kVerbose > 0) G4cout << G4end    2468     if(DEBUG || kVerbose > 0) G4cout << G4endl;
2473                                                  2469 
2474     ifile.read((char *)ctmp, 3*4); // 3*sizeo    2470     ifile.read((char *)ctmp, 3*4); // 3*sizeof(int)
2475     convertEndian(ctmp, iCenter[0]);             2471     convertEndian(ctmp, iCenter[0]);
2476     convertEndian(ctmp+4, iCenter[1]);           2472     convertEndian(ctmp+4, iCenter[1]);
2477     convertEndian(ctmp+8, iCenter[2]);           2473     convertEndian(ctmp+8, iCenter[2]);
2478     for(int i = 0; i < 3; i++) fCenter[i] = (    2474     for(int i = 0; i < 3; i++) fCenter[i] = (float)iCenter[i];
2479     kDose[ndose].setCenterPosition(fCenter);     2475     kDose[ndose].setCenterPosition(fCenter);
2480                                                  2476 
2481     if(DEBUG || kVerbose > 0) {                  2477     if(DEBUG || kVerbose > 0) {
2482       G4cout << "Dose dist. image relative lo    2478       G4cout << "Dose dist. image relative location : ("
2483     << fCenter[0] << ", "                        2479     << fCenter[0] << ", "
2484     << fCenter[1] << ", "                        2480     << fCenter[1] << ", "
2485     << fCenter[2] << ")" << G4endl;              2481     << fCenter[2] << ")" << G4endl;
2486     }                                            2482     }
2487                                                  2483 
2488                                                  2484 
2489   }                                              2485   }
2490                                                  2486 
2491   //----- ROI image -----//                      2487   //----- ROI image -----//
2492   if(kPointerToROIData != 0) {                   2488   if(kPointerToROIData != 0) {
2493                                                  2489 
2494     newROI();                                    2490     newROI();
2495                                                  2491 
2496     // ROI image size                            2492     // ROI image size
2497     ifile.read((char *)ctmp, 3*sizeof(int));     2493     ifile.read((char *)ctmp, 3*sizeof(int));
2498     convertEndian(ctmp, size[0]);                2494     convertEndian(ctmp, size[0]);
2499     convertEndian(ctmp+sizeof(int), size[1]);    2495     convertEndian(ctmp+sizeof(int), size[1]);
2500     convertEndian(ctmp+2*sizeof(int), size[2]    2496     convertEndian(ctmp+2*sizeof(int), size[2]);
2501     kRoi[0].setSize(size);                       2497     kRoi[0].setSize(size);
2502     if(DEBUG || kVerbose > 0) {                  2498     if(DEBUG || kVerbose > 0) {
2503       G4cout << "ROI image size : ("             2499       G4cout << "ROI image size : ("
2504     << size[0] << ", "                           2500     << size[0] << ", "
2505     << size[1] << ", "                           2501     << size[1] << ", "
2506     << size[2] << ")"                            2502     << size[2] << ")"
2507     << G4endl;                                   2503     << G4endl;
2508     }                                            2504     }
2509                                                  2505 
2510     // ROI max. & min.                           2506     // ROI max. & min.
2511     ifile.read((char *)ctmp, sizeof(short)*2)    2507     ifile.read((char *)ctmp, sizeof(short)*2);
2512     convertEndian(ctmp, minmax[0]);              2508     convertEndian(ctmp, minmax[0]);
2513     convertEndian(ctmp+sizeof(short), minmax[    2509     convertEndian(ctmp+sizeof(short), minmax[1]);
2514     kRoi[0].setMinMax(minmax);                   2510     kRoi[0].setMinMax(minmax);
2515                                                  2511 
2516     // ROI distribution scaling                  2512     // ROI distribution scaling 
2517     ifile.read((char *)ctmp, sizeof(float));     2513     ifile.read((char *)ctmp, sizeof(float));
2518     convertEndian(ctmp, scale);                  2514     convertEndian(ctmp, scale);
2519     kRoi[0].setScale(dscale = scale);            2515     kRoi[0].setScale(dscale = scale);
2520     if(DEBUG || kVerbose > 0) {                  2516     if(DEBUG || kVerbose > 0) {
2521       G4cout << "ROI image min., max., scale     2517       G4cout << "ROI image min., max., scale : "
2522     << minmax[0] << ", "                         2518     << minmax[0] << ", "
2523     << minmax[1] << ", "                         2519     << minmax[1] << ", "
2524     << scale << G4endl;                          2520     << scale << G4endl;
2525     }                                            2521     }
2526                                                  2522 
2527     // ROI image                                 2523     // ROI image
2528     int rsize = size[0]*size[1];                 2524     int rsize = size[0]*size[1];
2529     char * ri = new char[rsize*sizeof(short)]    2525     char * ri = new char[rsize*sizeof(short)];
2530     for(int i = 0; i < size[2]; i++) {           2526     for(int i = 0; i < size[2]; i++) {
2531       ifile.read((char *)ri, rsize*sizeof(sho    2527       ifile.read((char *)ri, rsize*sizeof(short));
2532       short * rimage = new short[rsize];         2528       short * rimage = new short[rsize];
2533       for(int j = 0; j < rsize; j++) {           2529       for(int j = 0; j < rsize; j++) {
2534   convertEndian(ri+j*sizeof(short), rimage[j]    2530   convertEndian(ri+j*sizeof(short), rimage[j]);
2535       }                                          2531       }
2536       kRoi[0].addImage(rimage);                  2532       kRoi[0].addImage(rimage);
2537                                                  2533 
2538     }                                            2534     }
2539     delete [] ri;                                2535     delete [] ri;
2540                                                  2536 
2541     // ROI relative location                     2537     // ROI relative location
2542     ifile.read((char *)ctmp, 3*sizeof(int));     2538     ifile.read((char *)ctmp, 3*sizeof(int));
2543     convertEndian(ctmp, iCenter[0]);             2539     convertEndian(ctmp, iCenter[0]);
2544     convertEndian(ctmp+sizeof(int), iCenter[1    2540     convertEndian(ctmp+sizeof(int), iCenter[1]);
2545     convertEndian(ctmp+2*sizeof(int), iCenter    2541     convertEndian(ctmp+2*sizeof(int), iCenter[2]);
2546     for(int i = 0; i < 3; i++) fCenter[i] = i    2542     for(int i = 0; i < 3; i++) fCenter[i] = iCenter[i];
2547     kRoi[0].setCenterPosition(fCenter);          2543     kRoi[0].setCenterPosition(fCenter);
2548     if(DEBUG || kVerbose > 0) {                  2544     if(DEBUG || kVerbose > 0) {
2549       G4cout << "ROI image relative location     2545       G4cout << "ROI image relative location : ("
2550     << fCenter[0] << ", "                        2546     << fCenter[0] << ", "
2551     << fCenter[1] << ", "                        2547     << fCenter[1] << ", "
2552     << fCenter[2] << ")" << G4endl;              2548     << fCenter[2] << ")" << G4endl;
2553     }                                            2549     }
2554                                                  2550 
2555   }                                              2551   }
2556                                                  2552 
2557   //----- track information -----//              2553   //----- track information -----//
2558   if(kPointerToTrackData != 0) {                 2554   if(kPointerToTrackData != 0) {
2559                                                  2555 
2560     // track                                     2556     // track
2561     ifile.read((char *)ctmp, sizeof(int));       2557     ifile.read((char *)ctmp, sizeof(int));
2562     int ntrk;                                    2558     int ntrk;
2563     convertEndian(ctmp, ntrk);                   2559     convertEndian(ctmp, ntrk);
2564     if(DEBUG || kVerbose > 0) {                  2560     if(DEBUG || kVerbose > 0) {
2565       G4cout << "# of tracks: " << ntrk << G4    2561       G4cout << "# of tracks: " << ntrk << G4endl;
2566     }                                            2562     }
2567                                                  2563 
2568     // v4                                        2564     // v4
2569     std::vector<float *> trkv4;                  2565     std::vector<float *> trkv4;
2570                                                  2566 
2571     // track position                            2567     // track position
2572     for(int i = 0; i < ntrk; i++) {              2568     for(int i = 0; i < ntrk; i++) {
2573       float * tp = new float[6];                 2569       float * tp = new float[6];
2574                                                  2570 
2575       ifile.read((char *)ctmp, sizeof(float)*    2571       ifile.read((char *)ctmp, sizeof(float)*3);
2576       if(DEBUG || kVerbose > 0) if(i < 10) G4    2572       if(DEBUG || kVerbose > 0) if(i < 10) G4cout << i << ": " ;
2577       for(int j = 0; j < 3; j++) {               2573       for(int j = 0; j < 3; j++) {
2578   convertEndian(ctmp+j*sizeof(float), tp[j]);    2574   convertEndian(ctmp+j*sizeof(float), tp[j]);
2579   if(DEBUG || kVerbose > 0) if(i < 10) G4cout    2575   if(DEBUG || kVerbose > 0) if(i < 10) G4cout << tp[j] << ", ";
2580       }                                          2576       }
2581                                                  2577 
2582       ifile.read((char *)ctmp, sizeof(float)*    2578       ifile.read((char *)ctmp, sizeof(float)*3);
2583       for(int j = 0; j < 3; j++) {               2579       for(int j = 0; j < 3; j++) {
2584   convertEndian(ctmp+j*sizeof(float), tp[j+3]    2580   convertEndian(ctmp+j*sizeof(float), tp[j+3]);
2585   if(DEBUG || kVerbose > 0) if(i < 10) G4cout    2581   if(DEBUG || kVerbose > 0) if(i < 10) G4cout << tp[j+3] << ", ";
2586       }                                          2582       }
2587       addTrack(tp);                              2583       addTrack(tp);
2588       if(DEBUG || kVerbose > 0) if(i < 10) G4    2584       if(DEBUG || kVerbose > 0) if(i < 10) G4cout << G4endl;
2589                                                  2585 
2590       // v4                                      2586       // v4
2591       trkv4.push_back(tp);                       2587       trkv4.push_back(tp);
2592     }                                            2588     }
2593                                                  2589 
2594     //v4                                         2590     //v4
2595     unsigned char trkcolorv4[3];                 2591     unsigned char trkcolorv4[3];
2596                                                  2592 
2597     // track color                               2593     // track color
2598     for(int i = 0; i < ntrk; i++) {              2594     for(int i = 0; i < ntrk; i++) {
2599       unsigned char * rgb = new unsigned char    2595       unsigned char * rgb = new unsigned char[3];
2600       ifile.read((char *)rgb, 3);                2596       ifile.read((char *)rgb, 3);
2601       addTrackColor(rgb);                        2597       addTrackColor(rgb);
2602                                                  2598 
2603       // v4                                      2599       // v4
2604       for(int j = 0; j < 3; j++) trkcolorv4[j    2600       for(int j = 0; j < 3; j++) trkcolorv4[j] = rgb[j];
2605       std::vector<float *> trk;                  2601       std::vector<float *> trk;
2606       trk.push_back(trkv4[i]);                   2602       trk.push_back(trkv4[i]);
2607       addTrack(trk, trkcolorv4);                 2603       addTrack(trk, trkcolorv4);
2608                                                  2604 
2609     }                                            2605     }
2610                                                  2606 
2611   }                                              2607   }
2612                                                  2608 
2613   ifile.close();                                 2609   ifile.close();
2614                                                  2610 
2615   return true;                                   2611   return true;
2616 }                                                2612 }
2617 bool G4GMocrenIO::retrieveData3(char * _filen    2613 bool G4GMocrenIO::retrieveData3(char * _filename) {
2618   kFileName = _filename;                         2614   kFileName = _filename;
2619   return retrieveData();                         2615   return retrieveData();
2620 }                                                2616 }
2621                                                  2617 
2622 //                                               2618 // 
2623 bool G4GMocrenIO::retrieveData2() {              2619 bool G4GMocrenIO::retrieveData2() {
2624                                                  2620 
2625   bool DEBUG = false;//                          2621   bool DEBUG = false;//
2626                                                  2622 
2627   // input file open                             2623   // input file open
2628   std::ifstream ifile(kFileName.c_str(), std:    2624   std::ifstream ifile(kFileName.c_str(), std::ios_base::in|std::ios_base::binary);
2629   if(!ifile) {                                   2625   if(!ifile) {
2630     if (G4VisManager::GetVerbosity() >= G4Vis    2626     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
2631       G4cout << "Cannot open file: " << kFile    2627       G4cout << "Cannot open file: " << kFileName
2632     << " in G4GMocrenIO::retrieveData2()." <<    2628     << " in G4GMocrenIO::retrieveData2()." << G4endl;
2633     return false;                                2629     return false;
2634   }                                              2630   }
2635                                                  2631 
2636   // data buffer                                 2632   // data buffer
2637   char ctmp[12];                                 2633   char ctmp[12];
2638                                                  2634 
2639   // file identifier                             2635   // file identifier
2640   char verid[9];                                 2636   char verid[9];
2641   ifile.read((char *)verid, 8);                  2637   ifile.read((char *)verid, 8);
2642                                                  2638 
2643   // file version                                2639   // file version
2644   unsigned char ver;                             2640   unsigned char ver;
2645   ifile.read((char *)&ver, 1);                   2641   ifile.read((char *)&ver, 1);
2646   std::stringstream ss;                          2642   std::stringstream ss;
2647   ss << (int)ver;                                2643   ss << (int)ver;
2648   kVersion = ss.str();                           2644   kVersion = ss.str();
2649   if(DEBUG || kVerbose > 0) G4cout << "File v    2645   if(DEBUG || kVerbose > 0) G4cout << "File version : " << kVersion << G4endl;
2650                                                  2646 
2651   // id of version 1                             2647   // id of version 1
2652   char idtmp[IDLENGTH];                          2648   char idtmp[IDLENGTH];
2653   ifile.read((char *)idtmp, IDLENGTH);           2649   ifile.read((char *)idtmp, IDLENGTH);
2654   kId = idtmp;                                   2650   kId = idtmp;
2655   // version of version 1                        2651   // version of version 1
2656   char vertmp[VERLENGTH];                        2652   char vertmp[VERLENGTH];
2657   ifile.read((char *)vertmp, VERLENGTH);         2653   ifile.read((char *)vertmp, VERLENGTH);
2658                                                  2654 
2659   // endian                                      2655   // endian
2660   ifile.read((char *)&kLittleEndianInput, siz    2656   ifile.read((char *)&kLittleEndianInput, sizeof(char));
2661   if(DEBUG || kVerbose > 0) {                    2657   if(DEBUG || kVerbose > 0) {
2662     G4cout << "Endian : ";                       2658     G4cout << "Endian : ";
2663     if(kLittleEndianInput == 1)                  2659     if(kLittleEndianInput == 1) 
2664       G4cout << " little" << G4endl;             2660       G4cout << " little" << G4endl;
2665     else {                                       2661     else {
2666       G4cout << " big" << G4endl;                2662       G4cout << " big" << G4endl;
2667     }                                            2663     }
2668   }                                              2664   }
2669                                                  2665 
2670   // voxel spacings for all images               2666   // voxel spacings for all images
2671   ifile.read((char *)ctmp, 12);                  2667   ifile.read((char *)ctmp, 12);
2672   convertEndian(ctmp, kVoxelSpacing[0]);         2668   convertEndian(ctmp, kVoxelSpacing[0]);
2673   convertEndian(ctmp+4, kVoxelSpacing[1]);       2669   convertEndian(ctmp+4, kVoxelSpacing[1]);
2674   convertEndian(ctmp+8, kVoxelSpacing[2]);       2670   convertEndian(ctmp+8, kVoxelSpacing[2]);
2675   if(DEBUG || kVerbose > 0) {                    2671   if(DEBUG || kVerbose > 0) {
2676     G4cout << "Voxel spacing : ("                2672     G4cout << "Voxel spacing : ("
2677         << kVoxelSpacing[0] << ", "              2673         << kVoxelSpacing[0] << ", "
2678         << kVoxelSpacing[1] << ", "              2674         << kVoxelSpacing[1] << ", "
2679         << kVoxelSpacing[2]                      2675         << kVoxelSpacing[2]
2680         << ") mm " << G4endl;                    2676         << ") mm " << G4endl;
2681   }                                              2677   }
2682                                                  2678 
2683                                                  2679 
2684   // offset from file starting point to the m    2680   // offset from file starting point to the modality image data
2685   ifile.read((char *)ctmp, 4);                   2681   ifile.read((char *)ctmp, 4);
2686   convertEndian(ctmp, kPointerToModalityData)    2682   convertEndian(ctmp, kPointerToModalityData);
2687                                                  2683 
2688   // offset from file starting point to the d    2684   // offset from file starting point to the dose image data
2689   unsigned int ptddd;                            2685   unsigned int ptddd;
2690   ifile.read((char *)ctmp, 4);                   2686   ifile.read((char *)ctmp, 4);
2691   convertEndian(ctmp, ptddd);                    2687   convertEndian(ctmp, ptddd);
2692   kPointerToDoseDistData.push_back(ptddd);       2688   kPointerToDoseDistData.push_back(ptddd);
2693                                                  2689 
2694   // offset from file starting point to the R    2690   // offset from file starting point to the ROI image data
2695   ifile.read((char *)ctmp, 4);                   2691   ifile.read((char *)ctmp, 4);
2696   convertEndian(ctmp, kPointerToROIData);        2692   convertEndian(ctmp, kPointerToROIData);
2697                                                  2693 
2698   // offset from file starting point to the t    2694   // offset from file starting point to the track data
2699   ifile.read((char *)ctmp, 4);                   2695   ifile.read((char *)ctmp, 4);
2700   convertEndian(ctmp, kPointerToTrackData);      2696   convertEndian(ctmp, kPointerToTrackData);
2701   if(DEBUG || kVerbose > 0) {                    2697   if(DEBUG || kVerbose > 0) {
2702     G4cout << "Each pointer to data : "          2698     G4cout << "Each pointer to data : "
2703         << kPointerToModalityData << ", "        2699         << kPointerToModalityData << ", "
2704         << kPointerToDoseDistData[0] << ", "     2700         << kPointerToDoseDistData[0] << ", "
2705         << kPointerToROIData << ", "             2701         << kPointerToROIData << ", "
2706         << kPointerToTrackData << G4endl;        2702         << kPointerToTrackData << G4endl;
2707   }                                              2703   }
2708                                                  2704 
2709   if(kPointerToModalityData == 0 && kPointerT    2705   if(kPointerToModalityData == 0 && kPointerToDoseDistData.size() == 0 &&
2710      kPointerToROIData == 0 && kPointerToTrac    2706      kPointerToROIData == 0 && kPointerToTrackData == 0) {
2711     if(DEBUG || kVerbose > 0) {                  2707     if(DEBUG || kVerbose > 0) {
2712       G4cout << "No data." << G4endl;            2708       G4cout << "No data." << G4endl;
2713     }                                            2709     }
2714     return false;                                2710     return false;
2715   }                                              2711   }
2716                                                  2712 
2717   // event number                                2713   // event number
2718   /* ver 1                                       2714   /* ver 1
2719      ifile.read(ctmp, sizeof(int));              2715      ifile.read(ctmp, sizeof(int));
2720      convertEndian(ctmp, numberOfEvents);        2716      convertEndian(ctmp, numberOfEvents);
2721   */                                             2717   */
2722                                                  2718 
2723   int size[3];                                   2719   int size[3];
2724   float scale;                                   2720   float scale;
2725   double dscale;                                 2721   double dscale;
2726   short minmax[2];                               2722   short minmax[2];
2727   float fCenter[3];                              2723   float fCenter[3];
2728   int iCenter[3];                                2724   int iCenter[3];
2729                                                  2725 
2730   //----- Modality image -----//                 2726   //----- Modality image -----//
2731   // modality image size                         2727   // modality image size
2732   ifile.read(ctmp, 3*sizeof(int));               2728   ifile.read(ctmp, 3*sizeof(int));
2733   convertEndian(ctmp, size[0]);                  2729   convertEndian(ctmp, size[0]);
2734   convertEndian(ctmp+sizeof(int), size[1]);      2730   convertEndian(ctmp+sizeof(int), size[1]);
2735   convertEndian(ctmp+2*sizeof(int), size[2]);    2731   convertEndian(ctmp+2*sizeof(int), size[2]);
2736   if(DEBUG || kVerbose > 0) {                    2732   if(DEBUG || kVerbose > 0) {
2737     G4cout << "Modality image size : ("          2733     G4cout << "Modality image size : ("
2738         << size[0] << ", "                       2734         << size[0] << ", "
2739         << size[1] << ", "                       2735         << size[1] << ", "
2740         << size[2] << ")"                        2736         << size[2] << ")"
2741         << G4endl;                               2737         << G4endl;
2742   }                                              2738   }
2743   kModality.setSize(size);                       2739   kModality.setSize(size);
2744                                                  2740 
2745   // modality image voxel spacing                2741   // modality image voxel spacing
2746   /*                                             2742   /*
2747     ifile.read(ctmp, 3*sizeof(float));           2743     ifile.read(ctmp, 3*sizeof(float));
2748     convertEndian(ctmp, modalityImageVoxelSpa    2744     convertEndian(ctmp, modalityImageVoxelSpacing[0]);
2749     convertEndian(ctmp+sizeof(float), modalit    2745     convertEndian(ctmp+sizeof(float), modalityImageVoxelSpacing[1]);
2750     convertEndian(ctmp+2*sizeof(float), modal    2746     convertEndian(ctmp+2*sizeof(float), modalityImageVoxelSpacing[2]);
2751   */                                             2747   */
2752                                                  2748 
2753   if(kPointerToModalityData != 0) {              2749   if(kPointerToModalityData != 0) {
2754                                                  2750 
2755     // modality density max. & min.              2751     // modality density max. & min.
2756     ifile.read((char *)ctmp, 4);                 2752     ifile.read((char *)ctmp, 4);
2757     convertEndian(ctmp, minmax[0]);              2753     convertEndian(ctmp, minmax[0]);
2758     convertEndian(ctmp+2, minmax[1]);            2754     convertEndian(ctmp+2, minmax[1]);
2759     kModality.setMinMax(minmax);                 2755     kModality.setMinMax(minmax);
2760                                                  2756 
2761     // modality density scale                    2757     // modality density scale
2762     ifile.read((char *)ctmp, 4);                 2758     ifile.read((char *)ctmp, 4);
2763     convertEndian(ctmp, scale);                  2759     convertEndian(ctmp, scale);
2764     kModality.setScale(dscale = scale);          2760     kModality.setScale(dscale = scale);
2765     if(DEBUG || kVerbose > 0) {                  2761     if(DEBUG || kVerbose > 0) {
2766       G4cout << "Modality image min., max., s    2762       G4cout << "Modality image min., max., scale : "
2767     << minmax[0] << ", "                         2763     << minmax[0] << ", "
2768     << minmax[1] << ", "                         2764     << minmax[1] << ", "
2769     << scale << G4endl;                          2765     << scale << G4endl;
2770     }                                            2766     }
2771                                                  2767 
2772     // modality density                          2768     // modality density
2773     int psize = size[0]*size[1];                 2769     int psize = size[0]*size[1];
2774     if(DEBUG || kVerbose > 0) G4cout << "Moda    2770     if(DEBUG || kVerbose > 0) G4cout << "Modality image (" << psize << "): ";
2775     char * cimage = new char[psize*sizeof(sho    2771     char * cimage = new char[psize*sizeof(short)];
2776     for(int i = 0; i < size[2]; i++) {           2772     for(int i = 0; i < size[2]; i++) {
2777       ifile.read((char *)cimage, psize*sizeof    2773       ifile.read((char *)cimage, psize*sizeof(short));
2778       short * mimage = new short[psize];         2774       short * mimage = new short[psize];
2779       for(int j = 0; j < psize; j++) {           2775       for(int j = 0; j < psize; j++) {
2780   convertEndian(cimage+j*sizeof(short), mimag    2776   convertEndian(cimage+j*sizeof(short), mimage[j]);
2781       }                                          2777       }
2782       kModality.addImage(mimage);                2778       kModality.addImage(mimage);
2783                                                  2779 
2784       if(DEBUG || kVerbose > 0) G4cout << "["    2780       if(DEBUG || kVerbose > 0) G4cout << "[" << i << "]" << mimage[(size_t)(psize*0.55)] << ", ";
2785     }                                            2781     }
2786     if(DEBUG || kVerbose > 0) G4cout << G4end    2782     if(DEBUG || kVerbose > 0) G4cout << G4endl;
2787     delete [] cimage;                            2783     delete [] cimage;
2788                                                  2784 
2789     // modality desity map for CT value          2785     // modality desity map for CT value
2790     size_t msize = minmax[1]-minmax[0]+1;        2786     size_t msize = minmax[1]-minmax[0]+1;
2791     if(DEBUG || kVerbose > 0) G4cout << "msiz    2787     if(DEBUG || kVerbose > 0) G4cout << "msize: " << msize << G4endl;
2792     char * pdmap = new char[msize*sizeof(floa    2788     char * pdmap = new char[msize*sizeof(float)];
2793     ifile.read((char *)pdmap, msize*sizeof(fl    2789     ifile.read((char *)pdmap, msize*sizeof(float));
2794     float ftmp;                                  2790     float ftmp;
2795     for(int i = 0; i < (int)msize; i++) {        2791     for(int i = 0; i < (int)msize; i++) {
2796       convertEndian(pdmap+i*sizeof(float), ft    2792       convertEndian(pdmap+i*sizeof(float), ftmp);
2797       kModalityImageDensityMap.push_back(ftmp    2793       kModalityImageDensityMap.push_back(ftmp); 
2798     }                                            2794     }
2799     delete [] pdmap;                          << 
2800     if(DEBUG || kVerbose > 0) {                  2795     if(DEBUG || kVerbose > 0) {
2801       G4cout << "density map : " << std::ends    2796       G4cout << "density map : " << std::ends;
2802       for(int i = 0; i < 10; i++)                2797       for(int i = 0; i < 10; i++)
2803   G4cout <<kModalityImageDensityMap[i] << ",     2798   G4cout <<kModalityImageDensityMap[i] << ", ";
2804       G4cout << G4endl;                          2799       G4cout << G4endl;
2805       for(int i = 0; i < 10; i++) G4cout << "    2800       for(int i = 0; i < 10; i++) G4cout << "..";
2806       G4cout << G4endl;                          2801       G4cout << G4endl;
2807       for(size_t i =kModalityImageDensityMap.    2802       for(size_t i =kModalityImageDensityMap.size() - 10; i <kModalityImageDensityMap.size(); i++)
2808   G4cout <<kModalityImageDensityMap[i] << ",     2803   G4cout <<kModalityImageDensityMap[i] << ", ";
2809       G4cout << G4endl;                          2804       G4cout << G4endl;
2810     }                                            2805     }
2811                                                  2806 
2812   }                                              2807   }
2813                                                  2808 
2814                                                  2809 
2815   //----- dose distribution image -----//        2810   //----- dose distribution image -----//
2816   if(kPointerToDoseDistData[0] != 0) {           2811   if(kPointerToDoseDistData[0] != 0) {
2817                                                  2812 
2818     newDoseDist();                               2813     newDoseDist();
2819                                                  2814 
2820     // dose distrbution image size               2815     // dose distrbution image size
2821     ifile.read((char *)ctmp, 3*sizeof(int));     2816     ifile.read((char *)ctmp, 3*sizeof(int));
2822     convertEndian(ctmp, size[0]);                2817     convertEndian(ctmp, size[0]);
2823     convertEndian(ctmp+sizeof(int), size[1]);    2818     convertEndian(ctmp+sizeof(int), size[1]);
2824     convertEndian(ctmp+2*sizeof(int), size[2]    2819     convertEndian(ctmp+2*sizeof(int), size[2]);
2825     if(DEBUG || kVerbose > 0) {                  2820     if(DEBUG || kVerbose > 0) {
2826       G4cout << "Dose dist. image size : ("      2821       G4cout << "Dose dist. image size : ("
2827     << size[0] << ", "                           2822     << size[0] << ", "
2828     << size[1] << ", "                           2823     << size[1] << ", "
2829     << size[2] << ")"                            2824     << size[2] << ")"
2830     << G4endl;                                   2825     << G4endl;
2831     }                                            2826     }
2832     kDose[0].setSize(size);                      2827     kDose[0].setSize(size);
2833                                                  2828 
2834     // dose distribution max. & min.             2829     // dose distribution max. & min. 
2835     ifile.read((char *)ctmp, sizeof(short)*2)    2830     ifile.read((char *)ctmp, sizeof(short)*2);
2836     convertEndian(ctmp, minmax[0]);              2831     convertEndian(ctmp, minmax[0]);
2837     convertEndian(ctmp+2, minmax[1]);            2832     convertEndian(ctmp+2, minmax[1]);
2838     // dose distribution scaling                 2833     // dose distribution scaling 
2839     ifile.read((char *)ctmp, sizeof(float));     2834     ifile.read((char *)ctmp, sizeof(float));
2840     convertEndian(ctmp, scale);                  2835     convertEndian(ctmp, scale);
2841     kDose[0].setScale(dscale = scale);           2836     kDose[0].setScale(dscale = scale);
2842                                                  2837 
2843     double dminmax[2];                           2838     double dminmax[2];
2844     for(int i = 0; i < 2; i++) dminmax[i] = m    2839     for(int i = 0; i < 2; i++) dminmax[i] = minmax[i]*dscale;
2845     kDose[0].setMinMax(dminmax);                 2840     kDose[0].setMinMax(dminmax);
2846                                                  2841 
2847     if(DEBUG || kVerbose > 0) {                  2842     if(DEBUG || kVerbose > 0) {
2848       G4cout << "Dose dist. image min., max.,    2843       G4cout << "Dose dist. image min., max., scale : "
2849     << dminmax[0] << ", "                        2844     << dminmax[0] << ", "
2850     << dminmax[1] << ", "                        2845     << dminmax[1] << ", "
2851     << scale << G4endl;                          2846     << scale << G4endl;
2852     }                                            2847     }
2853                                                  2848 
2854     // dose distribution image                   2849     // dose distribution image
2855     int dsize = size[0]*size[1];                 2850     int dsize = size[0]*size[1];
2856     if(DEBUG || kVerbose > 0) G4cout << "Dose    2851     if(DEBUG || kVerbose > 0) G4cout << "Dose dist. (" << dsize << "): ";
2857     char * di = new char[dsize*sizeof(short)]    2852     char * di = new char[dsize*sizeof(short)];
2858     short * shimage = new short[dsize];          2853     short * shimage = new short[dsize];
2859     for(int z = 0; z < size[2]; z++) {           2854     for(int z = 0; z < size[2]; z++) {
2860       ifile.read((char *)di, dsize*sizeof(sho    2855       ifile.read((char *)di, dsize*sizeof(short));
2861       double * dimage = new double[dsize];       2856       double * dimage = new double[dsize];
2862       for(int xy = 0; xy < dsize; xy++) {        2857       for(int xy = 0; xy < dsize; xy++) {
2863   convertEndian(di+xy*sizeof(short), shimage[    2858   convertEndian(di+xy*sizeof(short), shimage[xy]);
2864   dimage[xy] = shimage[xy]*dscale;               2859   dimage[xy] = shimage[xy]*dscale;
2865       }                                          2860       }
2866       kDose[0].addImage(dimage);                 2861       kDose[0].addImage(dimage);
2867                                                  2862 
2868       if(DEBUG || kVerbose > 0) G4cout << "["    2863       if(DEBUG || kVerbose > 0) G4cout << "[" << z << "]" << dimage[(size_t)(dsize*0.55)] << ", ";
2869                                                  2864 
2870       if(DEBUG || kVerbose > 0) {                2865       if(DEBUG || kVerbose > 0) {
2871   for(int j = 0; j < dsize; j++) {               2866   for(int j = 0; j < dsize; j++) {
2872     if(dimage[j] < 0)                            2867     if(dimage[j] < 0)
2873       G4cout << "[" << j << "," << z << "]"      2868       G4cout << "[" << j << "," << z << "]"
2874           << dimage[j] << ", ";                  2869           << dimage[j] << ", ";
2875   }                                              2870   }
2876       }                                          2871       }
2877     }                                            2872     }
2878     delete [] shimage;                           2873     delete [] shimage;
2879     delete [] di;                                2874     delete [] di;
2880     if(DEBUG || kVerbose > 0) G4cout << G4end    2875     if(DEBUG || kVerbose > 0) G4cout << G4endl;
2881                                                  2876 
2882     /* ver 1                                     2877     /* ver 1
2883        float doseDist;                           2878        float doseDist;
2884        int dosePid;                              2879        int dosePid;
2885        double * doseData = new double[numDose    2880        double * doseData = new double[numDoseImageVoxels];
2886        for(int i = 0; i < numDose; i++) {        2881        for(int i = 0; i < numDose; i++) {
2887        ifile.read(ctmp, sizeof(int));            2882        ifile.read(ctmp, sizeof(int));
2888        convertEndian(ctmp, dosePid);             2883        convertEndian(ctmp, dosePid);
2889        for(int j = 0; j < numDoseImageVoxels;    2884        for(int j = 0; j < numDoseImageVoxels; j++) {
2890        ifile.read(ctmp, sizeof(float));          2885        ifile.read(ctmp, sizeof(float));
2891        convertEndian(ctmp, doseDist);            2886        convertEndian(ctmp, doseDist);
2892        doseData[j] = doseDist;                   2887        doseData[j] = doseDist;
2893        }                                         2888        }
2894        setDose(dosePid, doseData);               2889        setDose(dosePid, doseData);
2895        }                                         2890        }
2896        delete [] doseData;                       2891        delete [] doseData;
2897        if(totalDose == NULL) totalDose = new     2892        if(totalDose == NULL) totalDose = new double[numDoseImageVoxels];
2898        for(int i = 0; i < numDoseImageVoxels;    2893        for(int i = 0; i < numDoseImageVoxels; i++) {
2899        ifile.read(ctmp, sizeof(float));          2894        ifile.read(ctmp, sizeof(float));
2900        convertEndian(ctmp, doseDist);            2895        convertEndian(ctmp, doseDist);
2901        totalDose[i] = doseDist;                  2896        totalDose[i] = doseDist;
2902        }                                         2897        }
2903     */                                           2898     */
2904                                                  2899 
2905     /* ver 1                                     2900     /* ver 1
2906     // relative location between the two imag    2901     // relative location between the two images
2907     ifile.read(ctmp, 3*sizeof(float));           2902     ifile.read(ctmp, 3*sizeof(float));
2908     convertEndian(ctmp, relativeLocation[0]);    2903     convertEndian(ctmp, relativeLocation[0]);
2909     convertEndian(ctmp+sizeof(float), relativ    2904     convertEndian(ctmp+sizeof(float), relativeLocation[1]);
2910     convertEndian(ctmp+2*sizeof(float), relat    2905     convertEndian(ctmp+2*sizeof(float), relativeLocation[2]);
2911     */                                           2906     */
2912                                                  2907 
2913     // relative location of the dose distribu    2908     // relative location of the dose distribution image for 
2914     // the modality image                        2909     // the modality image
2915     //ofile.write((char *)relativeLocation, 3    2910     //ofile.write((char *)relativeLocation, 3*sizeof(float));
2916     ifile.read((char *)ctmp, 3*sizeof(int));     2911     ifile.read((char *)ctmp, 3*sizeof(int));
2917     convertEndian(ctmp, iCenter[0]);             2912     convertEndian(ctmp, iCenter[0]);
2918     convertEndian(ctmp+sizeof(int), iCenter[1    2913     convertEndian(ctmp+sizeof(int), iCenter[1]);
2919     convertEndian(ctmp+2*sizeof(int), iCenter    2914     convertEndian(ctmp+2*sizeof(int), iCenter[2]);
2920     for(int i = 0; i < 3; i++) fCenter[i] = (    2915     for(int i = 0; i < 3; i++) fCenter[i] = (float)iCenter[i];
2921     kDose[0].setCenterPosition(fCenter);         2916     kDose[0].setCenterPosition(fCenter);
2922                                                  2917 
2923     if(DEBUG || kVerbose > 0) {                  2918     if(DEBUG || kVerbose > 0) {
2924       G4cout << "Dose dist. image relative lo    2919       G4cout << "Dose dist. image relative location : ("
2925     << fCenter[0] << ", "                        2920     << fCenter[0] << ", "
2926     << fCenter[1] << ", "                        2921     << fCenter[1] << ", "
2927     << fCenter[2] << ")" << G4endl;              2922     << fCenter[2] << ")" << G4endl;
2928     }                                            2923     }
2929                                                  2924 
2930                                                  2925 
2931   }                                              2926   }
2932                                                  2927 
2933   //----- ROI image -----//                      2928   //----- ROI image -----//
2934   if(kPointerToROIData != 0) {                   2929   if(kPointerToROIData != 0) {
2935                                                  2930 
2936     newROI();                                    2931     newROI();
2937                                                  2932 
2938     // ROI image size                            2933     // ROI image size
2939     ifile.read((char *)ctmp, 3*sizeof(int));     2934     ifile.read((char *)ctmp, 3*sizeof(int));
2940     convertEndian(ctmp, size[0]);                2935     convertEndian(ctmp, size[0]);
2941     convertEndian(ctmp+sizeof(int), size[1]);    2936     convertEndian(ctmp+sizeof(int), size[1]);
2942     convertEndian(ctmp+2*sizeof(int), size[2]    2937     convertEndian(ctmp+2*sizeof(int), size[2]);
2943     kRoi[0].setSize(size);                       2938     kRoi[0].setSize(size);
2944     if(DEBUG || kVerbose > 0) {                  2939     if(DEBUG || kVerbose > 0) {
2945       G4cout << "ROI image size : ("             2940       G4cout << "ROI image size : ("
2946     << size[0] << ", "                           2941     << size[0] << ", "
2947     << size[1] << ", "                           2942     << size[1] << ", "
2948     << size[2] << ")"                            2943     << size[2] << ")"
2949     << G4endl;                                   2944     << G4endl;
2950     }                                            2945     }
2951                                                  2946 
2952     // ROI max. & min.                           2947     // ROI max. & min.
2953     ifile.read((char *)ctmp, sizeof(short)*2)    2948     ifile.read((char *)ctmp, sizeof(short)*2);
2954     convertEndian(ctmp, minmax[0]);              2949     convertEndian(ctmp, minmax[0]);
2955     convertEndian(ctmp+sizeof(short), minmax[    2950     convertEndian(ctmp+sizeof(short), minmax[1]);
2956     kRoi[0].setMinMax(minmax);                   2951     kRoi[0].setMinMax(minmax);
2957                                                  2952 
2958     // ROI distribution scaling                  2953     // ROI distribution scaling 
2959     ifile.read((char *)ctmp, sizeof(float));     2954     ifile.read((char *)ctmp, sizeof(float));
2960     convertEndian(ctmp, scale);                  2955     convertEndian(ctmp, scale);
2961     kRoi[0].setScale(dscale = scale);            2956     kRoi[0].setScale(dscale = scale);
2962     if(DEBUG || kVerbose > 0) {                  2957     if(DEBUG || kVerbose > 0) {
2963       G4cout << "ROI image min., max., scale     2958       G4cout << "ROI image min., max., scale : "
2964     << minmax[0] << ", "                         2959     << minmax[0] << ", "
2965     << minmax[1] << ", "                         2960     << minmax[1] << ", "
2966     << scale << G4endl;                          2961     << scale << G4endl;
2967     }                                            2962     }
2968                                                  2963 
2969     // ROI image                                 2964     // ROI image
2970     int rsize = size[0]*size[1];                 2965     int rsize = size[0]*size[1];
2971     char * ri = new char[rsize*sizeof(short)]    2966     char * ri = new char[rsize*sizeof(short)];
2972     for(int i = 0; i < size[2]; i++) {           2967     for(int i = 0; i < size[2]; i++) {
2973       ifile.read((char *)ri, rsize*sizeof(sho    2968       ifile.read((char *)ri, rsize*sizeof(short));
2974       short * rimage = new short[rsize];         2969       short * rimage = new short[rsize];
2975       for(int j = 0; j < rsize; j++) {           2970       for(int j = 0; j < rsize; j++) {
2976   convertEndian(ri+j*sizeof(short), rimage[j]    2971   convertEndian(ri+j*sizeof(short), rimage[j]);
2977       }                                          2972       }
2978       kRoi[0].addImage(rimage);                  2973       kRoi[0].addImage(rimage);
2979                                                  2974 
2980     }                                            2975     }
2981     delete [] ri;                                2976     delete [] ri;
2982                                                  2977 
2983     // ROI relative location                     2978     // ROI relative location
2984     ifile.read((char *)ctmp, 3*sizeof(int));     2979     ifile.read((char *)ctmp, 3*sizeof(int));
2985     convertEndian(ctmp, iCenter[0]);             2980     convertEndian(ctmp, iCenter[0]);
2986     convertEndian(ctmp+sizeof(int), iCenter[1    2981     convertEndian(ctmp+sizeof(int), iCenter[1]);
2987     convertEndian(ctmp+2*sizeof(int), iCenter    2982     convertEndian(ctmp+2*sizeof(int), iCenter[2]);
2988     for(int i = 0; i < 3; i++) fCenter[i] = i    2983     for(int i = 0; i < 3; i++) fCenter[i] = iCenter[i];
2989     kRoi[0].setCenterPosition(fCenter);          2984     kRoi[0].setCenterPosition(fCenter);
2990     if(DEBUG || kVerbose > 0) {                  2985     if(DEBUG || kVerbose > 0) {
2991       G4cout << "ROI image relative location     2986       G4cout << "ROI image relative location : ("
2992     << fCenter[0] << ", "                        2987     << fCenter[0] << ", "
2993     << fCenter[1] << ", "                        2988     << fCenter[1] << ", "
2994     << fCenter[2] << ")" << G4endl;              2989     << fCenter[2] << ")" << G4endl;
2995     }                                            2990     }
2996                                                  2991 
2997   }                                              2992   }
2998                                                  2993 
2999   //----- track information -----//              2994   //----- track information -----//
3000   if(kPointerToTrackData != 0) {                 2995   if(kPointerToTrackData != 0) {
3001                                                  2996 
3002     // track                                     2997     // track
3003     ifile.read((char *)ctmp, sizeof(int));       2998     ifile.read((char *)ctmp, sizeof(int));
3004     int ntrk;                                    2999     int ntrk;
3005     convertEndian(ctmp, ntrk);                   3000     convertEndian(ctmp, ntrk);
3006     if(DEBUG || kVerbose > 0) {                  3001     if(DEBUG || kVerbose > 0) {
3007       G4cout << "# of tracks: " << ntrk << G4    3002       G4cout << "# of tracks: " << ntrk << G4endl;
3008     }                                            3003     }
3009                                                  3004 
3010     //v4                                         3005     //v4
3011     unsigned char trkcolorv4[3] = {255, 0, 0}    3006     unsigned char trkcolorv4[3] = {255, 0, 0};
3012                                                  3007 
3013     for(int i = 0; i < ntrk; i++) {              3008     for(int i = 0; i < ntrk; i++) {
3014       float * tp = new float[6];                 3009       float * tp = new float[6];
3015       // v4                                      3010       // v4
3016       std::vector<float *> trkv4;                3011       std::vector<float *> trkv4;
3017                                                  3012 
3018       ifile.read((char *)ctmp, sizeof(float)*    3013       ifile.read((char *)ctmp, sizeof(float)*3);
3019       if(DEBUG || kVerbose > 0) if(i < 10) G4    3014       if(DEBUG || kVerbose > 0) if(i < 10) G4cout << i << ": " ;
3020       for(int j = 0; j < 3; j++) {               3015       for(int j = 0; j < 3; j++) {
3021   convertEndian(ctmp+j*sizeof(float), tp[j]);    3016   convertEndian(ctmp+j*sizeof(float), tp[j]);
3022   if(DEBUG || kVerbose > 0) if(i < 10) G4cout    3017   if(DEBUG || kVerbose > 0) if(i < 10) G4cout << tp[j] << ", ";
3023       }                                          3018       }
3024                                                  3019 
3025       ifile.read((char *)ctmp, sizeof(float)*    3020       ifile.read((char *)ctmp, sizeof(float)*3);
3026       for(int j = 0; j < 3; j++) {               3021       for(int j = 0; j < 3; j++) {
3027   convertEndian(ctmp+j*sizeof(float), tp[j+3]    3022   convertEndian(ctmp+j*sizeof(float), tp[j+3]);
3028   if(DEBUG || kVerbose > 0) if(i < 10) G4cout    3023   if(DEBUG || kVerbose > 0) if(i < 10) G4cout << tp[j+3] << ", ";
3029       }                                          3024       }
3030                                                  3025 
3031       kSteps.push_back(tp);                      3026       kSteps.push_back(tp);
3032       // v4                                      3027       // v4
3033       trkv4.push_back(tp);                       3028       trkv4.push_back(tp);
3034       addTrack(trkv4, trkcolorv4);               3029       addTrack(trkv4, trkcolorv4);
3035                                                  3030       
3036       if(DEBUG || kVerbose > 0) if(i < 10) G4    3031       if(DEBUG || kVerbose > 0) if(i < 10) G4cout << G4endl;
3037     }                                            3032     }
3038                                                  3033 
3039   }                                              3034   }
3040                                                  3035 
3041   /* ver 1                                       3036   /* ver 1
3042   // track                                       3037   // track
3043   int ntracks;                                   3038   int ntracks;
3044   ifile.read(ctmp, sizeof(int));                 3039   ifile.read(ctmp, sizeof(int));
3045   convertEndian(ctmp, ntracks);                  3040   convertEndian(ctmp, ntracks);
3046   // track displacement                          3041   // track displacement
3047   ifile.read(ctmp, 3*sizeof(float));             3042   ifile.read(ctmp, 3*sizeof(float));
3048   convertEndian(ctmp, trackDisplacement[0]);     3043   convertEndian(ctmp, trackDisplacement[0]);
3049   convertEndian(ctmp+sizeof(float), trackDisp    3044   convertEndian(ctmp+sizeof(float), trackDisplacement[2]); // exchanged with [1]
3050   convertEndian(ctmp+2*sizeof(float), trackDi    3045   convertEndian(ctmp+2*sizeof(float), trackDisplacement[1]);
3051   //                                             3046   //
3052   //for(int i = 0; i < ntracks && i < 100; i+    3047   //for(int i = 0; i < ntracks && i < 100; i++) {
3053   for(int i = 0; i < ntracks; i++) {             3048   for(int i = 0; i < ntracks; i++) {
3054   DicomDoseTrack trk;                            3049   DicomDoseTrack trk;
3055   short trackid, parentid, pid;                  3050   short trackid, parentid, pid;
3056   int npoints;                                   3051   int npoints;
3057   ifile.read(ctmp, sizeof(short));               3052   ifile.read(ctmp, sizeof(short));
3058   convertEndian(ctmp, trackid);                  3053   convertEndian(ctmp, trackid);
3059   trk.setID(trackid);                            3054   trk.setID(trackid);
3060   ifile.read(ctmp, sizeof(short));               3055   ifile.read(ctmp, sizeof(short));
3061   convertEndian(ctmp, parentid);                 3056   convertEndian(ctmp, parentid);
3062   trk.setParentID(parentid);                     3057   trk.setParentID(parentid);
3063   ifile.read(ctmp, sizeof(short));               3058   ifile.read(ctmp, sizeof(short));
3064   convertEndian(ctmp, pid);                      3059   convertEndian(ctmp, pid);
3065   trk.setPID(pid);                               3060   trk.setPID(pid);
3066   ifile.read(ctmp, sizeof(int));                 3061   ifile.read(ctmp, sizeof(int));
3067   convertEndian(ctmp, npoints);                  3062   convertEndian(ctmp, npoints);
3068   for(int i = 0; i < npoints; i++) {             3063   for(int i = 0; i < npoints; i++) {
3069   ifile.read(ctmp, 3*sizeof(float));             3064   ifile.read(ctmp, 3*sizeof(float));
3070   // storing only start and end points           3065   // storing only start and end points
3071   //if(i == 0 || i == npoints - 1) {             3066   //if(i == 0 || i == npoints - 1) {
3072   float * point = new float[3];                  3067   float * point = new float[3];
3073   convertEndian(ctmp, point[0]);                 3068   convertEndian(ctmp, point[0]);
3074   convertEndian(ctmp+sizeof(float), point[1])    3069   convertEndian(ctmp+sizeof(float), point[1]);
3075   convertEndian(ctmp+2*sizeof(float), point[2    3070   convertEndian(ctmp+2*sizeof(float), point[2]);
3076   trk.addPoint(point);                           3071   trk.addPoint(point);
3077   //}                                            3072   //}
3078   }                                              3073   }
3079   track.push_back(trk);                          3074   track.push_back(trk);
3080   }                                              3075   }
3081   */                                             3076   */
3082                                                  3077 
3083   ifile.close();                                 3078   ifile.close();
3084                                                  3079 
3085   return true;                                   3080   return true;
3086 }                                                3081 }
3087                                                  3082 
3088 bool G4GMocrenIO::retrieveData2(char * _filen    3083 bool G4GMocrenIO::retrieveData2(char * _filename) {
3089   kFileName = _filename;                         3084   kFileName = _filename;
3090   return retrieveData();                         3085   return retrieveData();
3091 }                                                3086 }
3092                                                  3087 
3093 void G4GMocrenIO::setID() {                      3088 void G4GMocrenIO::setID() {
3094   time_t t;                                      3089   time_t t;
3095   time(&t);                                      3090   time(&t);
3096                                                  3091 
3097   tm * ti;                                       3092   tm * ti;
3098   ti = localtime(&t);                            3093   ti = localtime(&t);
3099                                                  3094 
3100   char cmonth[12][4] = {"Jan", "Feb", "Mar",     3095   char cmonth[12][4] = {"Jan", "Feb", "Mar", "Apr",
3101       "May", "Jun", "Jul", "Aug",                3096       "May", "Jun", "Jul", "Aug",
3102       "Sep", "Oct", "Nov", "Dec"};               3097       "Sep", "Oct", "Nov", "Dec"};
3103   std::stringstream ss;                          3098   std::stringstream ss;
3104   ss << std::setfill('0')                        3099   ss << std::setfill('0')
3105      << std::setw(2)                             3100      << std::setw(2)
3106      << ti->tm_hour << ":"                       3101      << ti->tm_hour << ":"
3107      << std::setw(2)                             3102      << std::setw(2)
3108      << ti->tm_min << ":"                        3103      << ti->tm_min << ":"
3109      << std::setw(2)                             3104      << std::setw(2)
3110      << ti->tm_sec << ","                        3105      << ti->tm_sec << ","
3111      << cmonth[ti->tm_mon] << "."                3106      << cmonth[ti->tm_mon] << "."
3112      << std::setw(2)                             3107      << std::setw(2)
3113      << ti->tm_mday << ","                       3108      << ti->tm_mday << ","
3114      << ti->tm_year+1900;                        3109      << ti->tm_year+1900;
3115                                                  3110 
3116   kId = ss.str();                                3111   kId = ss.str();
3117 }                                                3112 }
3118                                                  3113 
3119 // get & set the file version                    3114 // get & set the file version
3120 std::string & G4GMocrenIO::getVersion() {retu    3115 std::string & G4GMocrenIO::getVersion() {return kVersion;}
3121 void G4GMocrenIO::setVersion(std::string & _v    3116 void G4GMocrenIO::setVersion(std::string & _version) {kVersion = _version;}
3122                                                  3117 
3123 // set endians of input/output data              3118 // set endians of input/output data
3124 void G4GMocrenIO::setLittleEndianInput(bool _    3119 void G4GMocrenIO::setLittleEndianInput(bool _little) {kLittleEndianInput = _little;}
3125 void G4GMocrenIO::setLittleEndianOutput(bool     3120 void G4GMocrenIO::setLittleEndianOutput(bool _little) {kLittleEndianOutput = _little;}
3126                                                  3121 
3127 // voxel spacing                                 3122 // voxel spacing
3128 void G4GMocrenIO::setVoxelSpacing(float _spac    3123 void G4GMocrenIO::setVoxelSpacing(float _spacing[3]) {
3129   for(int i = 0; i < 3; i++) kVoxelSpacing[i]    3124   for(int i = 0; i < 3; i++) kVoxelSpacing[i] = _spacing[i];
3130 }                                                3125 }
3131 void G4GMocrenIO::getVoxelSpacing(float _spac    3126 void G4GMocrenIO::getVoxelSpacing(float _spacing[3]) {
3132   for(int i = 0; i < 3; i++) _spacing[i] = kV    3127   for(int i = 0; i < 3; i++) _spacing[i] = kVoxelSpacing[i];
3133 }                                                3128 }
3134                                                  3129 
3135 // get & set number of events                    3130 // get & set number of events
3136 int & G4GMocrenIO::getNumberOfEvents() {         3131 int & G4GMocrenIO::getNumberOfEvents() {
3137   return kNumberOfEvents;                        3132   return kNumberOfEvents;
3138 }                                                3133 }
3139 void G4GMocrenIO::setNumberOfEvents(int & _nu    3134 void G4GMocrenIO::setNumberOfEvents(int & _numberOfEvents) {
3140   kNumberOfEvents = _numberOfEvents;             3135   kNumberOfEvents = _numberOfEvents;
3141 }                                                3136 }
3142 void G4GMocrenIO::addOneEvent() {                3137 void G4GMocrenIO::addOneEvent() {
3143   kNumberOfEvents++;                             3138   kNumberOfEvents++;
3144 }                                                3139 }
3145                                                  3140 
3146 // set/get pointer the modality image data       3141 // set/get pointer the modality image data
3147 void G4GMocrenIO::setPointerToModalityData(un    3142 void G4GMocrenIO::setPointerToModalityData(unsigned int & _pointer) {
3148   kPointerToModalityData = _pointer;             3143   kPointerToModalityData = _pointer;
3149 }                                                3144 }
3150 unsigned int G4GMocrenIO::getPointerToModalit    3145 unsigned int G4GMocrenIO::getPointerToModalityData() {
3151   return kPointerToModalityData;                 3146   return kPointerToModalityData;
3152 }                                                3147 }
3153 // set/get pointer the dose distribution imag    3148 // set/get pointer the dose distribution image data
3154 void G4GMocrenIO::addPointerToDoseDistData(un    3149 void G4GMocrenIO::addPointerToDoseDistData(unsigned int & _pointer) {
3155   kPointerToDoseDistData.push_back(_pointer);    3150   kPointerToDoseDistData.push_back(_pointer);
3156 }                                                3151 }
3157 unsigned int G4GMocrenIO::getPointerToDoseDis    3152 unsigned int G4GMocrenIO::getPointerToDoseDistData(int _elem) {
3158   if(kPointerToDoseDistData.size() == 0 ||       3153   if(kPointerToDoseDistData.size() == 0 ||
3159      kPointerToDoseDistData.size() < (size_t)    3154      kPointerToDoseDistData.size() < (size_t)_elem)
3160     return 0;                                    3155     return 0;
3161   else                                           3156   else
3162     return kPointerToDoseDistData[_elem];        3157     return kPointerToDoseDistData[_elem];
3163 }                                                3158 }
3164                                                  3159 
3165 // set/get pointer the ROI image data            3160 // set/get pointer the ROI image data
3166 void G4GMocrenIO::setPointerToROIData(unsigne    3161 void G4GMocrenIO::setPointerToROIData(unsigned int & _pointer) {
3167   kPointerToROIData = _pointer;                  3162   kPointerToROIData = _pointer;
3168 }                                                3163 }
3169 unsigned int G4GMocrenIO::getPointerToROIData    3164 unsigned int G4GMocrenIO::getPointerToROIData() {
3170   return kPointerToROIData;                      3165   return kPointerToROIData;
3171 }                                                3166 }
3172 // set/get pointer the track data                3167 // set/get pointer the track data
3173 void G4GMocrenIO::setPointerToTrackData(unsig    3168 void G4GMocrenIO::setPointerToTrackData(unsigned int & _pointer) {
3174   kPointerToTrackData = _pointer;                3169   kPointerToTrackData = _pointer;
3175 }                                                3170 }
3176 unsigned int G4GMocrenIO::getPointerToTrackDa    3171 unsigned int G4GMocrenIO::getPointerToTrackData() {
3177   return kPointerToTrackData;                    3172   return kPointerToTrackData;
3178 }                                                3173 }
3179                                                  3174 
3180 // calculate pointers for version 4              3175 // calculate pointers for version 4
3181 void G4GMocrenIO::calcPointers4() {              3176 void G4GMocrenIO::calcPointers4() {
3182                                                  3177 
3183   // pointer to modality data                    3178   // pointer to modality data
3184   unsigned int pointer = 1070; // up to "poin    3179   unsigned int pointer = 1070; // up to "pointer to the detector data" except for "pointer to the dose dist data"
3185   int nDoseDist = getNumDoseDist();              3180   int nDoseDist = getNumDoseDist();
3186   pointer += nDoseDist*4;                        3181   pointer += nDoseDist*4;
3187                                                  3182 
3188   setPointerToModalityData(pointer);             3183   setPointerToModalityData(pointer);
3189                                                  3184 
3190   // pointer to dose data                        3185   // pointer to dose data
3191   // ct-density map for modality data            3186   // ct-density map for modality data
3192   int msize[3];                                  3187   int msize[3];
3193   getModalityImageSize(msize);                   3188   getModalityImageSize(msize);
3194   short mminmax[2];                              3189   short mminmax[2];
3195   getModalityImageMinMax(mminmax);               3190   getModalityImageMinMax(mminmax);
3196   int pmsize = 2*msize[0]*msize[1]*msize[2];     3191   int pmsize = 2*msize[0]*msize[1]*msize[2];
3197   int pmmap = 4*(mminmax[1] - mminmax[0] + 1)    3192   int pmmap = 4*(mminmax[1] - mminmax[0] + 1);
3198   pointer += 32 + pmsize + pmmap;                3193   pointer += 32 + pmsize + pmmap;
3199   //                                             3194   //
3200   kPointerToDoseDistData.clear();                3195   kPointerToDoseDistData.clear();
3201   if(nDoseDist == 0) {                           3196   if(nDoseDist == 0) {
3202     unsigned int pointer0 = 0;                   3197     unsigned int pointer0 = 0;
3203     addPointerToDoseDistData(pointer0);          3198     addPointerToDoseDistData(pointer0);
3204   }                                              3199   }
3205   for(int ndose = 0; ndose < nDoseDist; ndose    3200   for(int ndose = 0; ndose < nDoseDist; ndose++) {
3206     addPointerToDoseDistData(pointer);           3201     addPointerToDoseDistData(pointer);
3207     int dsize[3];                                3202     int dsize[3];
3208     getDoseDistSize(dsize);                      3203     getDoseDistSize(dsize);
3209     pointer += 44 + dsize[0]*dsize[1]*dsize[2    3204     pointer += 44 + dsize[0]*dsize[1]*dsize[2]*2 + 80;
3210   }                                              3205   }
3211                                                  3206 
3212   // pointer to roi data                         3207   // pointer to roi data
3213   if(!isROIEmpty()) {                            3208   if(!isROIEmpty()) {
3214     setPointerToROIData(pointer);                3209     setPointerToROIData(pointer);
3215                                                  3210     
3216     int rsize[3];                                3211     int rsize[3];
3217     getROISize(rsize);                           3212     getROISize(rsize);
3218     int prsize = 2*rsize[0]*rsize[1]*rsize[2]    3213     int prsize = 2*rsize[0]*rsize[1]*rsize[2];
3219     pointer += 20 + prsize + 12;                 3214     pointer += 20 + prsize + 12;
3220   } else {                                       3215   } else {
3221     unsigned int pointer0 = 0;                   3216     unsigned int pointer0 = 0;
3222     setPointerToROIData(pointer0);               3217     setPointerToROIData(pointer0);
3223   }                                              3218   }
3224                                                  3219 
3225   // pointer to track data                       3220   // pointer to track data
3226   int ntrk = (int)kTracks.size();             << 3221   int ntrk = kTracks.size();
3227   if(ntrk != 0) {                                3222   if(ntrk != 0) {
3228     setPointerToTrackData(pointer);              3223     setPointerToTrackData(pointer);
3229                                                  3224 
3230     pointer += 4; // # of tracks                 3225     pointer += 4; // # of tracks
3231     for(int nt = 0; nt < ntrk; nt++) {           3226     for(int nt = 0; nt < ntrk; nt++) {
3232       int nsteps = kTracks[nt].getNumberOfSte    3227       int nsteps = kTracks[nt].getNumberOfSteps();
3233       pointer += 4 + 3 + nsteps*(4*6); // # o    3228       pointer += 4 + 3 + nsteps*(4*6); // # of steps + color + steps(float*6)
3234     }                                            3229     }
3235   } else {                                       3230   } else {
3236     unsigned int pointer0 = 0;                   3231     unsigned int pointer0 = 0;
3237     setPointerToTrackData(pointer0);             3232     setPointerToTrackData(pointer0);
3238   }                                              3233   }
3239   if(kVerbose > 0) G4cout << " pointer to the    3234   if(kVerbose > 0) G4cout << " pointer to the track data :"
3240            << kPointerToTrackData << G4endl;     3235            << kPointerToTrackData << G4endl;
3241                                                  3236 
3242   // pointer to detector data                    3237   // pointer to detector data
3243   int ndet = (int)kDetectors.size();          << 3238   int ndet = kDetectors.size();
3244   if(ndet != 0) {                                3239   if(ndet != 0) {
3245     kPointerToDetectorData = pointer;            3240     kPointerToDetectorData = pointer;
3246   } else {                                       3241   } else {
3247     kPointerToDetectorData = 0;                  3242     kPointerToDetectorData = 0;
3248   }                                              3243   }
3249   if(kVerbose > 0) G4cout << " pointer to the    3244   if(kVerbose > 0) G4cout << " pointer to the detector data :"
3250            << kPointerToDetectorData << G4end    3245            << kPointerToDetectorData << G4endl;
3251                                                  3246 
3252 }                                                3247 }
3253                                                  3248 
3254 // calculate pointers for ver.3                  3249 // calculate pointers for ver.3
3255 void G4GMocrenIO::calcPointers3() {              3250 void G4GMocrenIO::calcPointers3() {
3256                                                  3251 
3257   // pointer to modality data                    3252   // pointer to modality data
3258   unsigned int pointer = 1066; // up to "poin    3253   unsigned int pointer = 1066; // up to "pointer to the track data" except for "pointer to the dose dist data"
3259   int nDoseDist = getNumDoseDist();              3254   int nDoseDist = getNumDoseDist();
3260   pointer += nDoseDist*4;                        3255   pointer += nDoseDist*4;
3261                                                  3256 
3262   setPointerToModalityData(pointer);             3257   setPointerToModalityData(pointer);
3263                                                  3258 
3264   // pointer to dose data                        3259   // pointer to dose data
3265   // ct-density map for modality data            3260   // ct-density map for modality data
3266   int msize[3];                                  3261   int msize[3];
3267   getModalityImageSize(msize);                   3262   getModalityImageSize(msize);
3268   short mminmax[2];                              3263   short mminmax[2];
3269   getModalityImageMinMax(mminmax);               3264   getModalityImageMinMax(mminmax);
3270   int pmsize = 2*msize[0]*msize[1]*msize[2];     3265   int pmsize = 2*msize[0]*msize[1]*msize[2];
3271   int pmmap = 4*(mminmax[1] - mminmax[0] + 1)    3266   int pmmap = 4*(mminmax[1] - mminmax[0] + 1);
3272   pointer += 32 + pmsize + pmmap;                3267   pointer += 32 + pmsize + pmmap;
3273   //                                             3268   //
3274   kPointerToDoseDistData.clear();                3269   kPointerToDoseDistData.clear();
3275   if(nDoseDist == 0) {                           3270   if(nDoseDist == 0) {
3276     unsigned int pointer0 = 0;                   3271     unsigned int pointer0 = 0;
3277     addPointerToDoseDistData(pointer0);          3272     addPointerToDoseDistData(pointer0);
3278   }                                              3273   }
3279   for(int ndose = 0; ndose < nDoseDist; ndose    3274   for(int ndose = 0; ndose < nDoseDist; ndose++) {
3280     addPointerToDoseDistData(pointer);           3275     addPointerToDoseDistData(pointer);
3281     int dsize[3];                                3276     int dsize[3];
3282     getDoseDistSize(dsize);                      3277     getDoseDistSize(dsize);
3283     pointer += 44 + dsize[0]*dsize[1]*dsize[2    3278     pointer += 44 + dsize[0]*dsize[1]*dsize[2]*2;
3284   }                                              3279   }
3285                                                  3280 
3286   // pointer to roi data                         3281   // pointer to roi data
3287   if(!isROIEmpty()) {                            3282   if(!isROIEmpty()) {
3288     setPointerToROIData(pointer);                3283     setPointerToROIData(pointer);
3289                                                  3284     
3290     int rsize[3];                                3285     int rsize[3];
3291     getROISize(rsize);                           3286     getROISize(rsize);
3292     int prsize = 2*rsize[0]*rsize[1]*rsize[2]    3287     int prsize = 2*rsize[0]*rsize[1]*rsize[2];
3293     pointer += 20 + prsize + 12;                 3288     pointer += 20 + prsize + 12;
3294   } else {                                       3289   } else {
3295     unsigned int pointer0 = 0;                   3290     unsigned int pointer0 = 0;
3296     setPointerToROIData(pointer0);               3291     setPointerToROIData(pointer0);
3297   }                                              3292   }
3298                                                  3293 
3299   //                                             3294   //
3300   if(getNumTracks() != 0)                        3295   if(getNumTracks() != 0) 
3301     setPointerToTrackData(pointer);              3296     setPointerToTrackData(pointer);
3302   else {                                         3297   else {
3303     unsigned int pointer0 = 0;                   3298     unsigned int pointer0 = 0;
3304     setPointerToTrackData(pointer0);             3299     setPointerToTrackData(pointer0);
3305   }                                              3300   }
3306                                                  3301 
3307 }                                                3302 }
3308                                                  3303 
3309 // calculate pointers for ver.2                  3304 // calculate pointers for ver.2
3310 void G4GMocrenIO::calcPointers2() {              3305 void G4GMocrenIO::calcPointers2() {
3311                                                  3306 
3312   // pointer to modality data                    3307   // pointer to modality data
3313   unsigned int pointer = 65;                     3308   unsigned int pointer = 65;
3314   setPointerToModalityData(pointer);             3309   setPointerToModalityData(pointer);
3315                                                  3310 
3316   // pointer to dose data                        3311   // pointer to dose data
3317   int msize[3];                                  3312   int msize[3];
3318   getModalityImageSize(msize);                   3313   getModalityImageSize(msize);
3319   short mminmax[2];                              3314   short mminmax[2];
3320   getModalityImageMinMax(mminmax);               3315   getModalityImageMinMax(mminmax);
3321   int pmsize = 2*msize[0]*msize[1]*msize[2];     3316   int pmsize = 2*msize[0]*msize[1]*msize[2];
3322   int pmmap = 4*(mminmax[1] - mminmax[0] + 1)    3317   int pmmap = 4*(mminmax[1] - mminmax[0] + 1);
3323   pointer += 20 + pmsize + pmmap;                3318   pointer += 20 + pmsize + pmmap;
3324   int dsize[3];                                  3319   int dsize[3];
3325   getDoseDistSize(dsize);                        3320   getDoseDistSize(dsize);
3326   kPointerToDoseDistData.clear();                3321   kPointerToDoseDistData.clear();
3327   if(dsize[0] != 0) {                            3322   if(dsize[0] != 0) {
3328     kPointerToDoseDistData.push_back(pointer)    3323     kPointerToDoseDistData.push_back(pointer);
3329                                                  3324 
3330     int pdsize = 2*dsize[0]*dsize[1]*dsize[2]    3325     int pdsize = 2*dsize[0]*dsize[1]*dsize[2];
3331     pointer += 20 + pdsize + 12;                 3326     pointer += 20 + pdsize + 12;
3332   } else {                                       3327   } else {
3333     unsigned int pointer0 = 0;                   3328     unsigned int pointer0 = 0;
3334     kPointerToDoseDistData.push_back(pointer0    3329     kPointerToDoseDistData.push_back(pointer0);
3335   }                                              3330   }
3336                                                  3331 
3337   // pointer to roi data                         3332   // pointer to roi data
3338   if(!isROIEmpty())  {                           3333   if(!isROIEmpty())  {
3339     int rsize[3];                                3334     int rsize[3];
3340     getROISize(rsize);                           3335     getROISize(rsize);
3341     setPointerToROIData(pointer);                3336     setPointerToROIData(pointer);
3342     int prsize = 2*rsize[0]*rsize[1]*rsize[2]    3337     int prsize = 2*rsize[0]*rsize[1]*rsize[2];
3343     pointer += 20 + prsize + 12;                 3338     pointer += 20 + prsize + 12;
3344                                                  3339 
3345   } else {                                       3340   } else {
3346     unsigned int pointer0 = 0;                   3341     unsigned int pointer0 = 0;
3347     setPointerToROIData(pointer0);               3342     setPointerToROIData(pointer0);
3348   }                                              3343   }
3349                                                  3344 
3350   //                                             3345   //
3351   if(getNumTracks() != 0)                        3346   if(getNumTracks() != 0) 
3352     setPointerToTrackData(pointer);              3347     setPointerToTrackData(pointer);
3353   else {                                         3348   else {
3354     unsigned int pointer0 = 0;                   3349     unsigned int pointer0 = 0;
3355     setPointerToTrackData(pointer0);             3350     setPointerToTrackData(pointer0);
3356   }                                              3351   }
3357                                                  3352 
3358 }                                                3353 }
3359                                                  3354 
3360                                                  3355 
3361 //----- Modality image -----//                   3356 //----- Modality image -----//
3362 void G4GMocrenIO::getModalityImageSize(int _s    3357 void G4GMocrenIO::getModalityImageSize(int _size[3]) {
3363                                                  3358 
3364   kModality.getSize(_size);                      3359   kModality.getSize(_size);
3365 }                                                3360 }
3366 void G4GMocrenIO::setModalityImageSize(int _s    3361 void G4GMocrenIO::setModalityImageSize(int _size[3]) {
3367                                                  3362 
3368   kModality.setSize(_size);                      3363   kModality.setSize(_size);
3369 }                                                3364 }
3370                                                  3365 
3371 // get & set the modality image size             3366 // get & set the modality image size
3372 void G4GMocrenIO::setModalityImageScale(doubl    3367 void G4GMocrenIO::setModalityImageScale(double & _scale) {
3373                                                  3368 
3374   kModality.setScale(_scale);                    3369   kModality.setScale(_scale);
3375 }                                                3370 }
3376 double G4GMocrenIO::getModalityImageScale() {    3371 double G4GMocrenIO::getModalityImageScale() {
3377                                                  3372 
3378   return kModality.getScale();                   3373   return kModality.getScale();
3379 }                                                3374 }
3380                                                  3375 
3381 // set the modality image in CT                  3376 // set the modality image in CT 
3382 void G4GMocrenIO::setModalityImage(short * _i    3377 void G4GMocrenIO::setModalityImage(short * _image) {
3383                                                  3378 
3384   kModality.addImage(_image);                    3379   kModality.addImage(_image);
3385 }                                                3380 }
3386 short * G4GMocrenIO::getModalityImage(int _z)    3381 short * G4GMocrenIO::getModalityImage(int _z) {
3387                                                  3382   
3388   return kModality.getImage(_z);                 3383   return kModality.getImage(_z);
3389 }                                                3384 }
3390 void G4GMocrenIO::clearModalityImage() {         3385 void G4GMocrenIO::clearModalityImage() {
3391                                                  3386   
3392   kModality.clearImage();                        3387   kModality.clearImage();
3393 }                                                3388 }
3394 // set/get the modality image density map        3389 // set/get the modality image density map
3395 void G4GMocrenIO::setModalityImageDensityMap(    3390 void G4GMocrenIO::setModalityImageDensityMap(std::vector<float> & _map) {
3396   kModalityImageDensityMap = _map;               3391   kModalityImageDensityMap = _map;
3397 }                                                3392 }
3398 std::vector<float> & G4GMocrenIO::getModality    3393 std::vector<float> & G4GMocrenIO::getModalityImageDensityMap() {
3399   return kModalityImageDensityMap;               3394   return kModalityImageDensityMap;
3400 }                                                3395 }
3401 // set the modality image min./max.              3396 // set the modality image min./max.
3402 void G4GMocrenIO::setModalityImageMinMax(shor    3397 void G4GMocrenIO::setModalityImageMinMax(short _minmax[2]) {
3403                                                  3398 
3404   kModality.setMinMax(_minmax);                  3399   kModality.setMinMax(_minmax);
3405 }                                                3400 }  
3406 // get the modality image min./max.              3401 // get the modality image min./max.
3407 void G4GMocrenIO::getModalityImageMinMax(shor    3402 void G4GMocrenIO::getModalityImageMinMax(short _minmax[2]) {
3408                                                  3403 
3409   short minmax[2];                               3404   short minmax[2];
3410   kModality.getMinMax(minmax);                   3405   kModality.getMinMax(minmax);
3411   for(int i = 0; i < 2; i++) _minmax[i] = min    3406   for(int i = 0; i < 2; i++) _minmax[i] = minmax[i];
3412 }                                                3407 }  
3413 short G4GMocrenIO::getModalityImageMax() {       3408 short G4GMocrenIO::getModalityImageMax() {
3414                                                  3409 
3415   short minmax[2];                               3410   short minmax[2];
3416   kModality.getMinMax(minmax);                   3411   kModality.getMinMax(minmax);
3417   return minmax[1];                              3412   return minmax[1];
3418 }                                                3413 }
3419 short G4GMocrenIO::getModalityImageMin() {       3414 short G4GMocrenIO::getModalityImageMin() {
3420                                                  3415 
3421   short minmax[2];                               3416   short minmax[2];
3422   kModality.getMinMax(minmax);                   3417   kModality.getMinMax(minmax);
3423   return minmax[0];                              3418   return minmax[0];
3424 }                                                3419 }
3425 // set/get position of the modality image cen    3420 // set/get position of the modality image center
3426 void G4GMocrenIO::setModalityCenterPosition(f    3421 void G4GMocrenIO::setModalityCenterPosition(float _center[3]) {
3427                                                  3422 
3428   kModality.setCenterPosition(_center);          3423   kModality.setCenterPosition(_center);
3429 }                                                3424 }
3430 void G4GMocrenIO::getModalityCenterPosition(f    3425 void G4GMocrenIO::getModalityCenterPosition(float _center[3]) {
3431                                                  3426 
3432   if(isROIEmpty())                               3427   if(isROIEmpty())
3433     for(int i = 0; i < 3; i++) _center[i] = 0    3428     for(int i = 0; i < 3; i++) _center[i] = 0;
3434   else                                           3429   else 
3435     kModality.getCenterPosition(_center);        3430     kModality.getCenterPosition(_center);
3436 }                                                3431 }
3437 // get & set the modality image unit             3432 // get & set the modality image unit
3438 std::string G4GMocrenIO::getModalityImageUnit    3433 std::string G4GMocrenIO::getModalityImageUnit() {
3439   return kModalityUnit;                          3434   return kModalityUnit;
3440 }                                                3435 }
3441 void G4GMocrenIO::setModalityImageUnit(std::s    3436 void G4GMocrenIO::setModalityImageUnit(std::string & _unit) {
3442   kModalityUnit = _unit;                         3437   kModalityUnit = _unit;
3443 }                                                3438 }
3444 //                                               3439 //
3445 short G4GMocrenIO::convertDensityToHU(float &    3440 short G4GMocrenIO::convertDensityToHU(float & _dens) {
3446   short rval = -1024; // default: air            3441   short rval = -1024; // default: air
3447   int nmap = (int)kModalityImageDensityMap.si    3442   int nmap = (int)kModalityImageDensityMap.size();
3448   if(nmap != 0) {                                3443   if(nmap != 0) {
3449     short minmax[2];                             3444     short minmax[2];
3450     kModality.getMinMax(minmax);                 3445     kModality.getMinMax(minmax);
3451     rval = minmax[1];                            3446     rval = minmax[1];
3452     for(int i = 0; i < nmap; i++) {              3447     for(int i = 0; i < nmap; i++) {
3453       //G4cout << kModalityImageDensityMap[i]    3448       //G4cout << kModalityImageDensityMap[i] << G4endl;
3454       if(_dens <= kModalityImageDensityMap[i]    3449       if(_dens <= kModalityImageDensityMap[i]) {
3455   rval = i + minmax[0];                          3450   rval = i + minmax[0];
3456   break;                                         3451   break;
3457       }                                          3452       }
3458     }                                            3453     }
3459   }                                              3454   }
3460   return rval;                                   3455   return rval;
3461 }                                                3456 }
3462                                                  3457 
3463                                                  3458 
3464 //----- Dose distribution -----//                3459 //----- Dose distribution -----//
3465 //                                               3460 //
3466 void G4GMocrenIO::newDoseDist() {                3461 void G4GMocrenIO::newDoseDist() {
3467   GMocrenDataPrimitive<double> doseData;         3462   GMocrenDataPrimitive<double> doseData;
3468   kDose.push_back(doseData);                     3463   kDose.push_back(doseData);
3469 }                                                3464 }
3470 int G4GMocrenIO::getNumDoseDist() {              3465 int G4GMocrenIO::getNumDoseDist() {
3471   return (int)kDose.size();                      3466   return (int)kDose.size();
3472 }                                                3467 }
3473                                                  3468 
3474 // get & set the dose distribution unit          3469 // get & set the dose distribution unit
3475 std::string G4GMocrenIO::getDoseDistUnit(int     3470 std::string G4GMocrenIO::getDoseDistUnit(int _num) {
3476   // to avoid a warning in the compile proces    3471   // to avoid a warning in the compile process
3477   if(kDoseUnit.size() > static_cast<size_t>(_ << 3472   int dummynum;
                                                   >> 3473   dummynum = _num;
3478                                                  3474 
3479   return kDoseUnit;                              3475   return kDoseUnit;
3480 }                                                3476 }
3481 void G4GMocrenIO::setDoseDistUnit(std::string    3477 void G4GMocrenIO::setDoseDistUnit(std::string & _unit, int _num) {
3482   // to avoid a warning in the compile proces    3478   // to avoid a warning in the compile process
3483   if(_unit.size() > static_cast<size_t>(_num) << 3479   int dummynum;
                                                   >> 3480   dummynum = _num;
3484                                                  3481 
3485   //char unit[13];                               3482   //char unit[13];
3486   //std::strncpy(unit, _unit.c_str(), 12);       3483   //std::strncpy(unit, _unit.c_str(), 12);
3487   //doseUnit = unit;                             3484   //doseUnit = unit;
3488   kDoseUnit = _unit;                             3485   kDoseUnit = _unit;
3489 }                                                3486 }
3490 //                                               3487 //
3491 void G4GMocrenIO::getDoseDistSize(int _size[3    3488 void G4GMocrenIO::getDoseDistSize(int _size[3], int _num) {
3492   if(isDoseEmpty())                              3489   if(isDoseEmpty())
3493     for(int i = 0; i < 3; i++) _size[i] = 0;     3490     for(int i = 0; i < 3; i++) _size[i] = 0;
3494   else                                           3491   else 
3495     kDose[_num].getSize(_size);                  3492     kDose[_num].getSize(_size);
3496 }                                                3493 }
3497 void G4GMocrenIO::setDoseDistSize(int _size[3    3494 void G4GMocrenIO::setDoseDistSize(int _size[3], int _num) {
3498                                                  3495 
3499   kDose[_num].setSize(_size);                    3496   kDose[_num].setSize(_size);
3500                                                  3497 
3501   //resetDose();                                 3498   //resetDose();
3502 }                                                3499 }
3503                                                  3500 
3504 void G4GMocrenIO::setDoseDistMinMax(short _mi    3501 void G4GMocrenIO::setDoseDistMinMax(short _minmax[2], int _num) {
3505                                                  3502 
3506   double minmax[2];                              3503   double minmax[2];
3507   double scale = kDose[_num].getScale();         3504   double scale = kDose[_num].getScale();
3508   for(int i = 0; i < 2; i++) minmax[i] = (dou    3505   for(int i = 0; i < 2; i++) minmax[i] = (double)_minmax[i]*scale;
3509   kDose[_num].setMinMax(minmax);                 3506   kDose[_num].setMinMax(minmax);
3510 }                                                3507 }  
3511 void G4GMocrenIO::getDoseDistMinMax(short _mi    3508 void G4GMocrenIO::getDoseDistMinMax(short _minmax[2], int _num) {
3512                                                  3509 
3513   if(isDoseEmpty())                              3510   if(isDoseEmpty())
3514     for(int i = 0; i < 2; i++) _minmax[i] = 0    3511     for(int i = 0; i < 2; i++) _minmax[i] = 0;
3515   else {                                         3512   else {
3516     double minmax[2];                            3513     double minmax[2];
3517     kDose[_num].getMinMax(minmax);               3514     kDose[_num].getMinMax(minmax);
3518     double scale = kDose[_num].getScale();       3515     double scale = kDose[_num].getScale();
3519     for(int i = 0; i < 2; i++) _minmax[i] = (    3516     for(int i = 0; i < 2; i++) _minmax[i] = (short)(minmax[i]/scale+0.5);
3520   }                                              3517   }
3521 }                                                3518 }  
3522 void G4GMocrenIO::setDoseDistMinMax(double _m    3519 void G4GMocrenIO::setDoseDistMinMax(double _minmax[2], int _num) {
3523                                                  3520 
3524   kDose[_num].setMinMax(_minmax);                3521   kDose[_num].setMinMax(_minmax);
3525 }                                                3522 }  
3526 void G4GMocrenIO::getDoseDistMinMax(double _m    3523 void G4GMocrenIO::getDoseDistMinMax(double _minmax[2], int _num) {
3527                                                  3524 
3528   if(isDoseEmpty())                              3525   if(isDoseEmpty())
3529     for(int i = 0; i < 2; i++) _minmax[i] = 0    3526     for(int i = 0; i < 2; i++) _minmax[i] = 0.;
3530   else                                           3527   else
3531     kDose[_num].getMinMax(_minmax);              3528     kDose[_num].getMinMax(_minmax);
3532 }                                                3529 }  
3533                                                  3530 
3534 // get & set the dose distribution image scal    3531 // get & set the dose distribution image scale
3535 void G4GMocrenIO::setDoseDistScale(double & _    3532 void G4GMocrenIO::setDoseDistScale(double & _scale, int _num) {
3536                                                  3533 
3537   kDose[_num].setScale(_scale);                  3534   kDose[_num].setScale(_scale);
3538 }                                                3535 }
3539 double G4GMocrenIO::getDoseDistScale(int _num    3536 double G4GMocrenIO::getDoseDistScale(int _num) {
3540                                                  3537 
3541   if(isDoseEmpty())                              3538   if(isDoseEmpty())
3542     return 0.;                                   3539     return 0.;
3543   else                                           3540   else 
3544     return kDose[_num].getScale();               3541     return kDose[_num].getScale();
3545 }                                                3542 }
3546                                                  3543 
3547 /*                                               3544 /*
3548   void G4GMocrenIO::initializeShortDoseDist()    3545   void G4GMocrenIO::initializeShortDoseDist() {
3549   ;                                              3546   ;
3550   }                                              3547   }
3551   void G4GMocrenIO::finalizeShortDoseDist() {    3548   void G4GMocrenIO::finalizeShortDoseDist() {
3552   ;                                              3549   ;
3553   }                                              3550   }
3554 */                                               3551 */
3555 // set the dose distribution image               3552 // set the dose distribution image
3556 void G4GMocrenIO::setShortDoseDist(short * _i    3553 void G4GMocrenIO::setShortDoseDist(short * _image, int _num) {
3557                                                  3554 
3558   int size[3];                                   3555   int size[3];
3559   kDose[_num].getSize(size);                     3556   kDose[_num].getSize(size);
3560   int dsize = size[0]*size[1];                   3557   int dsize = size[0]*size[1];
3561   double * ddata = new double[dsize];            3558   double * ddata = new double[dsize];
3562   double scale = kDose[_num].getScale();         3559   double scale = kDose[_num].getScale();
3563   double minmax[2];                              3560   double minmax[2];
3564   kDose[_num].getMinMax(minmax);                 3561   kDose[_num].getMinMax(minmax);
3565   for(int xy = 0; xy < dsize; xy++) {            3562   for(int xy = 0; xy < dsize; xy++) {
3566     ddata[xy] = _image[xy]*scale;                3563     ddata[xy] = _image[xy]*scale;
3567     if(ddata[xy] < minmax[0]) minmax[0] = dda    3564     if(ddata[xy] < minmax[0]) minmax[0] = ddata[xy];
3568     if(ddata[xy] > minmax[1]) minmax[1] = dda    3565     if(ddata[xy] > minmax[1]) minmax[1] = ddata[xy];
3569   }                                              3566   }
3570   kDose[_num].addImage(ddata);                   3567   kDose[_num].addImage(ddata);
3571                                                  3568 
3572   // set min./max.                               3569   // set min./max.
3573   kDose[_num].setMinMax(minmax);                 3570   kDose[_num].setMinMax(minmax);
3574 }                                                3571 }
3575 void G4GMocrenIO::getShortDoseDist(short * _d    3572 void G4GMocrenIO::getShortDoseDist(short * _data, int _z, int _num) {
3576                                                  3573 
3577   if(_data == NULL) {                            3574   if(_data == NULL) {
3578     if (G4VisManager::GetVerbosity() >= G4Vis    3575     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
3579       G4cout << "In G4GMocrenIO::getShortDose    3576       G4cout << "In G4GMocrenIO::getShortDoseDist(), "
3580     << "first argument is NULL pointer. "        3577     << "first argument is NULL pointer. "
3581     << "The argument must be allocated array.    3578     << "The argument must be allocated array."
3582     << G4endl;                                   3579     << G4endl;
3583     G4Exception("G4GMocrenIO::getShortDoseDis << 3580     std::exit(-1);
3584                 "gMocren2002", FatalException << 
3585                 "Error.");                    << 
3586     return;                                   << 
3587   }                                              3581   }
3588                                                  3582 
3589   int size[3];                                   3583   int size[3];
3590   kDose[_num].getSize(size);                     3584   kDose[_num].getSize(size);
3591   //short * shdata = new short[size[0]*size[1    3585   //short * shdata = new short[size[0]*size[1]];
3592   double * ddata = kDose[_num].getImage(_z);     3586   double * ddata = kDose[_num].getImage(_z);
3593   double scale = kDose[_num].getScale();         3587   double scale = kDose[_num].getScale();
3594   for(int xy = 0; xy < size[0]*size[1]; xy++)    3588   for(int xy = 0; xy < size[0]*size[1]; xy++) {
3595     _data[xy] = (short)(ddata[xy]/scale+0.5);    3589     _data[xy] = (short)(ddata[xy]/scale+0.5); //there is never negative value
3596   }                                              3590   }
3597 }                                                3591 }
3598 void G4GMocrenIO::getShortDoseDistMinMax(shor    3592 void G4GMocrenIO::getShortDoseDistMinMax(short _minmax[2], int _num) {
3599   double scale = kDose[_num].getScale();         3593   double scale = kDose[_num].getScale();
3600   double minmax[2];                              3594   double minmax[2];
3601   kDose[_num].getMinMax(minmax);                 3595   kDose[_num].getMinMax(minmax);
3602   for(int i = 0; i < 2; i++)                     3596   for(int i = 0; i < 2; i++)
3603     _minmax[i] = (short)(minmax[i]/scale+0.5)    3597     _minmax[i] = (short)(minmax[i]/scale+0.5);
3604 }                                                3598 }
3605 //                                               3599 //
3606 void G4GMocrenIO::setDoseDist(double * _image    3600 void G4GMocrenIO::setDoseDist(double * _image, int _num) {
3607                                                  3601 
3608   kDose[_num].addImage(_image);                  3602   kDose[_num].addImage(_image);
3609 }                                                3603 }
3610 double * G4GMocrenIO::getDoseDist(int _z, int    3604 double * G4GMocrenIO::getDoseDist(int _z, int _num) {
3611                                                  3605 
3612   double * image;                                3606   double * image;
3613   if(isDoseEmpty()) {                            3607   if(isDoseEmpty()) {
3614     image = 0;                                   3608     image = 0;
3615   } else {                                       3609   } else {
3616     image = kDose[_num].getImage(_z);            3610     image = kDose[_num].getImage(_z);
3617   }                                              3611   }
3618   return image;                                  3612   return image;
3619 }                                                3613 }
3620 /*                                               3614 /*
3621   void G4GMocrenIO::getDoseDist(double * & _i    3615   void G4GMocrenIO::getDoseDist(double * & _image, int _z, int _num) {
3622                                                  3616 
3623   G4cout << " <" << (void*)_image << "> ";       3617   G4cout << " <" << (void*)_image << "> ";
3624   if(isDoseEmpty()) {                            3618   if(isDoseEmpty()) {
3625   _image = 0;                                    3619   _image = 0;
3626   } else {                                       3620   } else {
3627   _image = kDose[_num].getImage(_z);             3621   _image = kDose[_num].getImage(_z);
3628   G4cout << " <" << (void*)_image << "> ";       3622   G4cout << " <" << (void*)_image << "> ";
3629   G4cout << _image[100] << " ";                  3623   G4cout << _image[100] << " ";
3630   }                                              3624   }
3631   }                                              3625   }
3632 */                                               3626 */
3633 bool G4GMocrenIO::addDoseDist(std::vector<dou    3627 bool G4GMocrenIO::addDoseDist(std::vector<double *> & _image, int _num) {
3634                                                  3628 
3635   int size[3];                                   3629   int size[3];
3636   getDoseDistSize(size, _num);                   3630   getDoseDistSize(size, _num);
3637   std::vector<double *> dosedist = kDose[_num    3631   std::vector<double *> dosedist = kDose[_num].getImage();
3638                                                  3632 
3639   int nimg = size[0]*size[1];                    3633   int nimg = size[0]*size[1];
3640   for(int z = 0; z < size[2]; z++) {             3634   for(int z = 0; z < size[2]; z++) {
3641     for(int xy = 0; xy < nimg; xy++) {           3635     for(int xy = 0; xy < nimg; xy++) {
3642       dosedist[z][xy] += _image[z][xy];          3636       dosedist[z][xy] += _image[z][xy];
3643     }                                            3637     }
3644   }                                              3638   }
3645                                                  3639 
3646   return true;                                   3640   return true;
3647 }                                                3641 }
3648 //void setDoseDistDensityMap(float * _map) {d    3642 //void setDoseDistDensityMap(float * _map) {doseImageDensityMap = _map;};
3649 // set the dose distribution image displaceme    3643 // set the dose distribution image displacement
3650 void G4GMocrenIO::setDoseDistCenterPosition(f    3644 void G4GMocrenIO::setDoseDistCenterPosition(float _center[3], int _num) {
3651                                                  3645 
3652   kDose[_num].setCenterPosition(_center);        3646   kDose[_num].setCenterPosition(_center);
3653 }                                                3647 }
3654 void G4GMocrenIO::getDoseDistCenterPosition(f    3648 void G4GMocrenIO::getDoseDistCenterPosition(float _center[3], int _num) {
3655                                                  3649 
3656   if(isDoseEmpty())                              3650   if(isDoseEmpty())
3657     for(int i = 0; i < 3; i++) _center[i] = 0    3651     for(int i = 0; i < 3; i++) _center[i] = 0;
3658   else                                           3652   else 
3659     kDose[_num].getCenterPosition(_center);      3653     kDose[_num].getCenterPosition(_center);
3660 }                                                3654 }
3661 // set & get name of dose distribution           3655 // set & get name of dose distribution
3662 void G4GMocrenIO::setDoseDistName(std::string    3656 void G4GMocrenIO::setDoseDistName(std::string _name, int _num) {
3663                                                  3657 
3664   kDose[_num].setName(_name);                    3658   kDose[_num].setName(_name);
3665 }                                                3659 }
3666 std::string G4GMocrenIO::getDoseDistName(int     3660 std::string G4GMocrenIO::getDoseDistName(int _num) {
3667                                                  3661 
3668   std::string name;                              3662   std::string name;
3669   if(isDoseEmpty())                              3663   if(isDoseEmpty())
3670     return name;                                 3664     return name;
3671   else                                           3665   else 
3672     return kDose[_num].getName();                3666     return kDose[_num].getName();
3673 }                                                3667 }
3674 // copy dose distributions                       3668 // copy dose distributions
3675 void G4GMocrenIO::copyDoseDist(std::vector<cl    3669 void G4GMocrenIO::copyDoseDist(std::vector<class GMocrenDataPrimitive<double> > & _dose) {
3676   std::vector<class GMocrenDataPrimitive<doub    3670   std::vector<class GMocrenDataPrimitive<double> >::iterator itr;
3677   for(itr = kDose.begin(); itr != kDose.end()    3671   for(itr = kDose.begin(); itr != kDose.end(); itr++) {
3678     _dose.push_back(*itr);                       3672     _dose.push_back(*itr);
3679   }                                              3673   }
3680 }                                                3674 }
3681 // merge two dose distributions                  3675 // merge two dose distributions
3682 bool G4GMocrenIO::mergeDoseDist(std::vector<c    3676 bool G4GMocrenIO::mergeDoseDist(std::vector<class GMocrenDataPrimitive<double> > & _dose) {
3683   if(kDose.size() != _dose.size()) {             3677   if(kDose.size() != _dose.size()) {
3684     if (G4VisManager::GetVerbosity() >= G4Vis    3678     if (G4VisManager::GetVerbosity() >= G4VisManager::errors) {
3685       G4cout << "G4GMocrenIO::mergeDoseDist()    3679       G4cout << "G4GMocrenIO::mergeDoseDist() : Error" << G4endl; 
3686       G4cout << "   Unable to merge the dose     3680       G4cout << "   Unable to merge the dose distributions,"<< G4endl;
3687       G4cout << "   because of different size    3681       G4cout << "   because of different size of dose maps."<< G4endl;
3688     }                                            3682     }
3689     return false;                                3683     return false;
3690   }                                              3684   }
3691                                                  3685 
3692   int num = (int)kDose.size();                << 3686   int num = kDose.size();
3693   std::vector<class GMocrenDataPrimitive<doub    3687   std::vector<class GMocrenDataPrimitive<double> >::iterator itr1 = kDose.begin();
3694   std::vector<class GMocrenDataPrimitive<doub    3688   std::vector<class GMocrenDataPrimitive<double> >::iterator itr2 = _dose.begin();
3695   for(int i = 0; i < num; i++, itr1++, itr2++    3689   for(int i = 0; i < num; i++, itr1++, itr2++) {
3696     if (G4VisManager::GetVerbosity() >= G4Vis    3690     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
3697       if(kVerbose > 0)                           3691       if(kVerbose > 0)
3698   G4cout << "merged dose distribution [" << i    3692   G4cout << "merged dose distribution [" << i << "]" << G4endl;
3699     *itr1 += *itr2;                              3693     *itr1 += *itr2;
3700   }                                              3694   }
3701                                                  3695 
3702   return true;                                   3696   return true;
3703 }                                                3697 }
3704 //                                               3698 //
3705 void G4GMocrenIO::clearDoseDistAll() {           3699 void G4GMocrenIO::clearDoseDistAll() {
3706                                                  3700 
3707   if(!isDoseEmpty()) {                           3701   if(!isDoseEmpty()) {
3708     for(int i = 0; i < getNumDoseDist(); i++)    3702     for(int i = 0; i < getNumDoseDist(); i++) {
3709       kDose[i].clear();                          3703       kDose[i].clear();
3710     }                                            3704     }
3711     kDose.clear();                               3705     kDose.clear();
3712   }                                              3706   }
3713 }                                                3707 }
3714 //                                               3708 //
3715 bool G4GMocrenIO::isDoseEmpty() {                3709 bool G4GMocrenIO::isDoseEmpty() {
3716   if(kDose.empty()) {                            3710   if(kDose.empty()) {
3717     //if (G4VisManager::GetVerbosity() >= G4V    3711     //if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
3718     //  G4cout << "!!! dose distribution data    3712     //  G4cout << "!!! dose distribution data is empty." << G4endl;
3719     return true;                                 3713     return true;
3720   } else {                                       3714   } else {
3721     return false;                                3715     return false;
3722   }                                              3716   }
3723 }                                                3717 }
3724                                                  3718 
3725 //                                               3719 //
3726 void G4GMocrenIO::calcDoseDistScale() {          3720 void G4GMocrenIO::calcDoseDistScale() {
3727                                                  3721 
3728   double scale;                                  3722   double scale;
3729   double minmax[2];                              3723   double minmax[2];
3730                                                  3724 
3731   for(int i = 0; i < (int)kDose.size(); i++)     3725   for(int i = 0; i < (int)kDose.size(); i++) {
3732     kDose[i].getMinMax(minmax);                  3726     kDose[i].getMinMax(minmax);
3733     scale = minmax[1]/DOSERANGE;                 3727     scale = minmax[1]/DOSERANGE;
3734     kDose[i].setScale(scale);                    3728     kDose[i].setScale(scale);
3735   }                                              3729   }
3736 }                                                3730 }
3737                                                  3731 
3738                                                  3732 
3739 //----- RoI -----//                              3733 //----- RoI -----//
3740                                                  3734 
3741 // add one RoI data                              3735 // add one RoI data
3742 void G4GMocrenIO::newROI() {                     3736 void G4GMocrenIO::newROI() {
3743   GMocrenDataPrimitive<short>  roiData;          3737   GMocrenDataPrimitive<short>  roiData;
3744   kRoi.push_back(roiData);                       3738   kRoi.push_back(roiData);
3745 }                                                3739 }
3746 int G4GMocrenIO::getNumROI() {                   3740 int G4GMocrenIO::getNumROI() {
3747   return (int)kRoi.size();                       3741   return (int)kRoi.size();
3748 }                                                3742 }
3749                                                  3743 
3750 // set/get the ROI image scale                   3744 // set/get the ROI image scale
3751 void G4GMocrenIO::setROIScale(double & _scale    3745 void G4GMocrenIO::setROIScale(double & _scale, int _num) {
3752                                                  3746 
3753   kRoi[_num].setScale(_scale);                   3747   kRoi[_num].setScale(_scale);
3754 }                                                3748 }
3755 double G4GMocrenIO::getROIScale(int _num) {      3749 double G4GMocrenIO::getROIScale(int _num) {
3756                                                  3750 
3757   if(isROIEmpty())                               3751   if(isROIEmpty())
3758     return 0.;                                   3752     return 0.;
3759   else                                           3753   else 
3760     return kRoi[_num].getScale();                3754     return kRoi[_num].getScale();
3761 }                                                3755 }
3762 // set the ROI image                             3756 // set the ROI image 
3763 void G4GMocrenIO::setROI(short * _image, int     3757 void G4GMocrenIO::setROI(short * _image, int _num) {
3764                                                  3758 
3765   kRoi[_num].addImage(_image);                   3759   kRoi[_num].addImage(_image);
3766 }                                                3760 }
3767 short * G4GMocrenIO::getROI(int _z, int _num)    3761 short * G4GMocrenIO::getROI(int _z, int _num) {
3768                                                  3762 
3769   if(isROIEmpty())                               3763   if(isROIEmpty())
3770     return 0;                                    3764     return 0;
3771   else                                           3765   else 
3772     return kRoi[_num].getImage(_z);              3766     return kRoi[_num].getImage(_z);
3773 }                                                3767 }
3774 // set/get the ROI image size                    3768 // set/get the ROI image size
3775 void G4GMocrenIO::setROISize(int _size[3], in    3769 void G4GMocrenIO::setROISize(int _size[3], int _num) {
3776                                                  3770 
3777   return kRoi[_num].setSize(_size);              3771   return kRoi[_num].setSize(_size);
3778 }                                                3772 }
3779 void G4GMocrenIO::getROISize(int _size[3], in    3773 void G4GMocrenIO::getROISize(int _size[3], int _num) {
3780                                                  3774 
3781   if(isROIEmpty())                               3775   if(isROIEmpty())
3782     for(int i = 0; i < 3; i++) _size[i] = 0;     3776     for(int i = 0; i < 3; i++) _size[i] = 0;
3783   else                                           3777   else 
3784     return kRoi[_num].getSize(_size);            3778     return kRoi[_num].getSize(_size);
3785 }                                                3779 }
3786 // set/get the ROI image min. and max.           3780 // set/get the ROI image min. and max.
3787 void G4GMocrenIO::setROIMinMax(short _minmax[    3781 void G4GMocrenIO::setROIMinMax(short _minmax[2], int _num) {
3788                                                  3782 
3789   kRoi[_num].setMinMax(_minmax);                 3783   kRoi[_num].setMinMax(_minmax);
3790 }                                                3784 }
3791 void G4GMocrenIO::getROIMinMax(short _minmax[    3785 void G4GMocrenIO::getROIMinMax(short _minmax[2], int _num) {
3792                                                  3786 
3793   if(isROIEmpty())                               3787   if(isROIEmpty())
3794     for(int i = 0; i < 2; i++) _minmax[i] = 0    3788     for(int i = 0; i < 2; i++) _minmax[i] = 0;
3795   else                                           3789   else 
3796     kRoi[_num].getMinMax(_minmax);               3790     kRoi[_num].getMinMax(_minmax);
3797 }                                                3791 }
3798 // set/get the ROI image displacement            3792 // set/get the ROI image displacement
3799 void G4GMocrenIO::setROICenterPosition(float     3793 void G4GMocrenIO::setROICenterPosition(float _center[3], int _num) {
3800                                                  3794 
3801   kRoi[_num].setCenterPosition(_center);         3795   kRoi[_num].setCenterPosition(_center);
3802 }                                                3796 }
3803 void G4GMocrenIO::getROICenterPosition(float     3797 void G4GMocrenIO::getROICenterPosition(float _center[3], int _num) {
3804                                                  3798 
3805   if(isROIEmpty())                               3799   if(isROIEmpty())
3806     for(int i = 0; i < 3; i++) _center[i] = 0    3800     for(int i = 0; i < 3; i++) _center[i] = 0;
3807   else                                           3801   else 
3808     kRoi[_num].getCenterPosition(_center);       3802     kRoi[_num].getCenterPosition(_center);
3809 }                                                3803 }
3810 //                                               3804 //
3811 void G4GMocrenIO::clearROIAll() {                3805 void G4GMocrenIO::clearROIAll() {
3812                                                  3806 
3813   if(!isROIEmpty()) {                            3807   if(!isROIEmpty()) {
3814     for(int i = 0; i < getNumROI(); i++) {       3808     for(int i = 0; i < getNumROI(); i++) {
3815       kRoi[i].clear();                           3809       kRoi[i].clear();
3816     }                                            3810     }
3817     kRoi.clear();                                3811     kRoi.clear();
3818   }                                              3812   }
3819 }                                                3813 }
3820 //                                               3814 //
3821 bool G4GMocrenIO::isROIEmpty() {                 3815 bool G4GMocrenIO::isROIEmpty() {
3822   if(kRoi.empty()) {                             3816   if(kRoi.empty()) {
3823     //if (G4VisManager::GetVerbosity() >= G4V    3817     //if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
3824     //  G4cout << "!!! ROI data is empty." <<    3818     //  G4cout << "!!! ROI data is empty." << G4endl;
3825     return true;                                 3819     return true;
3826   } else {                                       3820   } else {
3827     return false;                                3821     return false;
3828   }                                              3822   }
3829 }                                                3823 }
3830                                                  3824 
3831                                                  3825 
3832                                                  3826 
3833 //----- Track information -----//                3827 //----- Track information -----//
3834                                                  3828 
3835 int  G4GMocrenIO::getNumTracks() {               3829 int  G4GMocrenIO::getNumTracks() {
3836   return (int)kSteps.size();                     3830   return (int)kSteps.size();
3837 }                                                3831 }
3838 int  G4GMocrenIO::getNumTracks4() {              3832 int  G4GMocrenIO::getNumTracks4() {
3839   return (int)kTracks.size();                    3833   return (int)kTracks.size();
3840 }                                                3834 }
3841 void G4GMocrenIO::addTrack(float * _tracks) {    3835 void G4GMocrenIO::addTrack(float * _tracks) {
3842   kSteps.push_back(_tracks);                     3836   kSteps.push_back(_tracks);
3843 }                                                3837 }
3844 void G4GMocrenIO::setTracks(std::vector<float    3838 void G4GMocrenIO::setTracks(std::vector<float *> & _tracks) {
3845   kSteps = _tracks;                              3839   kSteps = _tracks;
3846 }                                                3840 }
3847 std::vector<float *> & G4GMocrenIO::getTracks    3841 std::vector<float *> & G4GMocrenIO::getTracks() {
3848   return kSteps;                                 3842   return kSteps;
3849 }                                                3843 }
3850 void G4GMocrenIO::addTrackColor(unsigned char    3844 void G4GMocrenIO::addTrackColor(unsigned char * _colors) {
3851   kStepColors.push_back(_colors);                3845   kStepColors.push_back(_colors);
3852 }                                                3846 }
3853 void G4GMocrenIO::setTrackColors(std::vector<    3847 void G4GMocrenIO::setTrackColors(std::vector<unsigned char *> & _trackColors) {
3854   kStepColors = _trackColors;                    3848   kStepColors = _trackColors;
3855 }                                                3849 }
3856 std::vector<unsigned char *> & G4GMocrenIO::g    3850 std::vector<unsigned char *> & G4GMocrenIO::getTrackColors() {
3857   return kStepColors;                            3851   return kStepColors;
3858 }                                                3852 }
3859 void G4GMocrenIO::copyTracks(std::vector<floa    3853 void G4GMocrenIO::copyTracks(std::vector<float *> & _tracks,
3860              std::vector<unsigned char *> & _    3854              std::vector<unsigned char *> & _colors) {
3861   std::vector<float *>::iterator titr;           3855   std::vector<float *>::iterator titr;
3862   for(titr = kSteps.begin(); titr != kSteps.e    3856   for(titr = kSteps.begin(); titr != kSteps.end(); titr++) {
3863     float * pts = new float[6];                  3857     float * pts = new float[6];
3864     for(int i = 0; i < 6; i++) {                 3858     for(int i = 0; i < 6; i++) {
3865       pts[i] = (*titr)[i];                       3859       pts[i] = (*titr)[i];
3866     }                                            3860     }
3867     _tracks.push_back(pts);                      3861     _tracks.push_back(pts);
3868   }                                              3862   }
3869                                                  3863 
3870   std::vector<unsigned char *>::iterator citr    3864   std::vector<unsigned char *>::iterator citr;
3871   for(citr = kStepColors.begin(); citr != kSt    3865   for(citr = kStepColors.begin(); citr != kStepColors.end(); citr++) {
3872     unsigned char * pts = new unsigned char[3    3866     unsigned char * pts = new unsigned char[3];
3873     for(int i = 0; i < 3; i++) {                 3867     for(int i = 0; i < 3; i++) {
3874       pts[i] = (*citr)[i];                       3868       pts[i] = (*citr)[i];
3875     }                                            3869     }
3876     _colors.push_back(pts);                      3870     _colors.push_back(pts);
3877   }                                              3871   }
3878 }                                                3872 }
3879 void G4GMocrenIO::mergeTracks(std::vector<flo    3873 void G4GMocrenIO::mergeTracks(std::vector<float *> & _tracks,
3880         std::vector<unsigned char *> & _color    3874         std::vector<unsigned char *> & _colors) {
3881   std::vector<float *>::iterator titr;           3875   std::vector<float *>::iterator titr;
3882   for(titr = _tracks.begin(); titr != _tracks    3876   for(titr = _tracks.begin(); titr != _tracks.end(); titr++) {
3883     addTrack(*titr);                             3877     addTrack(*titr);
3884   }                                              3878   }
3885                                                  3879 
3886   std::vector<unsigned char *>::iterator citr    3880   std::vector<unsigned char *>::iterator citr;
3887   for(citr = _colors.begin(); citr != _colors    3881   for(citr = _colors.begin(); citr != _colors.end(); citr++) {
3888     addTrackColor(*citr);                        3882     addTrackColor(*citr);
3889   }                                              3883   }
3890 }                                                3884 }
3891 void G4GMocrenIO::addTrack(std::vector<float     3885 void G4GMocrenIO::addTrack(std::vector<float *> & _steps, unsigned char _color[3]) {
3892                                                  3886 
3893   std::vector<float *>::iterator itr = _steps    3887   std::vector<float *>::iterator itr = _steps.begin();
3894     std::vector<struct GMocrenTrack::Step> st    3888     std::vector<struct GMocrenTrack::Step> steps;
3895     for(; itr != _steps.end(); itr++) {          3889     for(; itr != _steps.end(); itr++) {
3896       struct GMocrenTrack::Step step;            3890       struct GMocrenTrack::Step step;
3897       for(int i = 0; i < 3; i++) {               3891       for(int i = 0; i < 3; i++) {
3898   step.startPoint[i] = (*itr)[i];                3892   step.startPoint[i] = (*itr)[i];
3899   step.endPoint[i] = (*itr)[i+3];                3893   step.endPoint[i] = (*itr)[i+3];
3900       }                                          3894       }
3901       steps.push_back(step);                     3895       steps.push_back(step);
3902     }                                            3896     }
3903     GMocrenTrack track;                          3897     GMocrenTrack track;
3904     track.setTrack(steps);                       3898     track.setTrack(steps);
3905     track.setColor(_color);                      3899     track.setColor(_color);
3906     kTracks.push_back(track);                    3900     kTracks.push_back(track);
3907                                                  3901     
3908 }                                                3902 }
3909 void G4GMocrenIO::getTrack(int _num, std::vec    3903 void G4GMocrenIO::getTrack(int _num, std::vector<float *> & _steps,
3910            std::vector<unsigned char *> & _co    3904            std::vector<unsigned char *> & _color) {
3911                                                  3905 
3912   if(_num > (int)kTracks.size()) {               3906   if(_num > (int)kTracks.size()) {
3913     if (G4VisManager::GetVerbosity() >= G4Vis    3907     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
3914       G4cout << "ERROR in getTrack() : " << G    3908       G4cout << "ERROR in getTrack() : " << G4endl;
3915     G4Exception("G4GMocrenIO::getTrack()",    << 3909     std::exit(-1);
3916                 "gMocren2003", FatalException << 
3917                 "Error.");                    << 
3918   }                                              3910   }
3919   unsigned char * color = new unsigned char[3    3911   unsigned char * color = new unsigned char[3];
3920   kTracks[_num].getColor(color);                 3912   kTracks[_num].getColor(color);
3921   _color.push_back(color);                       3913   _color.push_back(color);
3922                                                  3914 
3923   // steps                                       3915   // steps
3924   int nsteps = kTracks[_num].getNumberOfSteps    3916   int nsteps = kTracks[_num].getNumberOfSteps();
3925   for(int isteps = 0; isteps < nsteps; isteps << 3917   for(int ns = 0; ns < nsteps; ns++) {
3926     float * stepPoints = new float[6];           3918     float * stepPoints = new float[6];
3927     kTracks[_num].getStep(stepPoints[0], step    3919     kTracks[_num].getStep(stepPoints[0], stepPoints[1], stepPoints[2],
3928         stepPoints[3], stepPoints[4], stepPoi    3920         stepPoints[3], stepPoints[4], stepPoints[5],
3929         isteps);                              << 3921         ns);
3930     _steps.push_back(stepPoints);                3922     _steps.push_back(stepPoints);
3931   }                                              3923   }
3932 }                                                3924 }
3933                                                  3925 
3934 void G4GMocrenIO::translateTracks(std::vector    3926 void G4GMocrenIO::translateTracks(std::vector<float> & _translate) {
3935   std::vector<class GMocrenTrack>::iterator i    3927   std::vector<class GMocrenTrack>::iterator itr = kTracks.begin();
3936   for(; itr != kTracks.end(); itr++) {           3928   for(; itr != kTracks.end(); itr++) {
3937     itr->translate(_translate);                  3929     itr->translate(_translate);
3938   }                                              3930   }
3939 }                                                3931 }
3940                                                  3932 
3941                                                  3933 
3942                                                  3934 
3943                                                  3935 
3944 //----- Detector information -----//             3936 //----- Detector information -----//
3945 int  G4GMocrenIO::getNumberOfDetectors() {       3937 int  G4GMocrenIO::getNumberOfDetectors() {
3946   return (int)kDetectors.size();                 3938   return (int)kDetectors.size();
3947 }                                                3939 }
3948 void G4GMocrenIO::addDetector(std::string & _    3940 void G4GMocrenIO::addDetector(std::string & _name,
3949         std::vector<float *> & _det,             3941         std::vector<float *> & _det, 
3950         unsigned char _color[3]) {               3942         unsigned char _color[3]) {
3951                                                  3943 
3952     std::vector<float *>::iterator itr = _det    3944     std::vector<float *>::iterator itr = _det.begin();
3953     std::vector<struct GMocrenDetector::Edge>    3945     std::vector<struct GMocrenDetector::Edge> edges;
3954     for(; itr != _det.end(); itr++) {            3946     for(; itr != _det.end(); itr++) {
3955       struct GMocrenDetector::Edge edge;         3947       struct GMocrenDetector::Edge edge;
3956       for(int i = 0; i < 3; i++) {               3948       for(int i = 0; i < 3; i++) {
3957   edge.startPoint[i] = (*itr)[i];                3949   edge.startPoint[i] = (*itr)[i];
3958   edge.endPoint[i] = (*itr)[i+3];                3950   edge.endPoint[i] = (*itr)[i+3];
3959       }                                          3951       }
3960       edges.push_back(edge);                     3952       edges.push_back(edge);
3961     }                                            3953     }
3962     GMocrenDetector detector;                    3954     GMocrenDetector detector;
3963     detector.setDetector(edges);                 3955     detector.setDetector(edges);
3964     detector.setColor(_color);                   3956     detector.setColor(_color);
3965     detector.setName(_name);                     3957     detector.setName(_name);
3966     kDetectors.push_back(detector);              3958     kDetectors.push_back(detector);
3967                                                  3959     
3968 }                                                3960 }
3969                                                  3961 
3970 void G4GMocrenIO::getDetector(int _num, std::    3962 void G4GMocrenIO::getDetector(int _num, std::vector<float *> & _edges,
3971         std::vector<unsigned char *> & _color    3963         std::vector<unsigned char *> & _color,
3972         std::string & _detName) {                3964         std::string & _detName) {
3973                                                  3965 
3974   if(_num > (int)kDetectors.size()) {            3966   if(_num > (int)kDetectors.size()) {
3975     if (G4VisManager::GetVerbosity() >= G4Vis    3967     if (G4VisManager::GetVerbosity() >= G4VisManager::errors)
3976       G4cout << "ERROR in getDetector() : " <    3968       G4cout << "ERROR in getDetector() : " << G4endl;
3977                                               << 3969     std::exit(-1);
3978     G4Exception("G4GMocrenIO::getDetector()", << 
3979                 "gMocren2004", FatalException << 
3980                 "Error.");                    << 
3981   }                                              3970   }
3982                                                  3971 
3983   _detName = kDetectors[_num].getName();         3972   _detName = kDetectors[_num].getName();
3984                                                  3973 
3985   unsigned char * color = new unsigned char[3    3974   unsigned char * color = new unsigned char[3];
3986   kDetectors[_num].getColor(color);              3975   kDetectors[_num].getColor(color);
3987   _color.push_back(color);                       3976   _color.push_back(color);
3988                                                  3977 
3989   // edges                                       3978   // edges
3990   int nedges = kDetectors[_num].getNumberOfEd    3979   int nedges = kDetectors[_num].getNumberOfEdges();
3991   for(int ne = 0; ne < nedges; ne++) {           3980   for(int ne = 0; ne < nedges; ne++) {
3992     float * edgePoints = new float[6];           3981     float * edgePoints = new float[6];
3993     kDetectors[_num].getEdge(edgePoints[0], e    3982     kDetectors[_num].getEdge(edgePoints[0], edgePoints[1], edgePoints[2],
3994            edgePoints[3], edgePoints[4], edge    3983            edgePoints[3], edgePoints[4], edgePoints[5],
3995            ne);                                  3984            ne);
3996     _edges.push_back(edgePoints);                3985     _edges.push_back(edgePoints);
3997   }                                              3986   }
3998 }                                                3987 }
3999                                                  3988 
4000 void G4GMocrenIO::translateDetector(std::vect    3989 void G4GMocrenIO::translateDetector(std::vector<float> & _translate) {
4001   std::vector<class GMocrenDetector>::iterato    3990   std::vector<class GMocrenDetector>::iterator itr = kDetectors.begin();
4002   for(; itr != kDetectors.end(); itr++) {        3991   for(; itr != kDetectors.end(); itr++) {
4003     itr->translate(_translate);                  3992     itr->translate(_translate);
4004   }                                              3993   }
4005 }                                                3994 }
4006                                                  3995 
4007 // endian conversion                             3996 // endian conversion
4008 template <typename T>                            3997 template <typename T>
4009 void G4GMocrenIO::convertEndian(char * _val,     3998 void G4GMocrenIO::convertEndian(char * _val, T & _rval) {
4010                                                  3999 
4011   if((kLittleEndianOutput && !kLittleEndianIn    4000   if((kLittleEndianOutput && !kLittleEndianInput) ||   // big endian
4012      (!kLittleEndianOutput && kLittleEndianIn    4001      (!kLittleEndianOutput && kLittleEndianInput)) {   // little endian
4013                                                  4002 
4014     const int SIZE = sizeof(_rval);              4003     const int SIZE = sizeof(_rval);
4015     char ctemp;                                  4004     char ctemp;
4016     for(int i = 0; i < SIZE/2; i++) {            4005     for(int i = 0; i < SIZE/2; i++) {
4017       ctemp = _val[i];                           4006       ctemp = _val[i];
4018       _val[i] = _val[SIZE - 1 - i];              4007       _val[i] = _val[SIZE - 1 - i];
4019       _val[SIZE - 1 - i] = ctemp;                4008       _val[SIZE - 1 - i] = ctemp;
4020     }                                            4009     }
4021   }                                              4010   }
4022   _rval = *(T *)_val;                            4011   _rval = *(T *)_val;
4023 }                                                4012 }
4024                                                  4013 
4025 // inversion of byte order                       4014 // inversion of byte order
4026 template <typename T>                            4015 template <typename T>
4027 void G4GMocrenIO::invertByteOrder(char * _val    4016 void G4GMocrenIO::invertByteOrder(char * _val, T & _rval) {
4028                                                  4017 
4029   const int SIZE = sizeof(_rval);                4018   const int SIZE = sizeof(_rval);
4030   //char * cval = new char[SIZE];                4019   //char * cval = new char[SIZE];
4031   union {                                        4020   union {
4032     char cu[16];                                 4021     char cu[16];
4033     T tu;                                        4022     T tu;
4034   } uni;                                         4023   } uni;
4035   for(int i = 0; i < SIZE; i++) {                4024   for(int i = 0; i < SIZE; i++) {
4036     uni.cu[i] = _val[SIZE-1-i];                  4025     uni.cu[i] = _val[SIZE-1-i];
4037     //cval[i] = _val[SIZE-i-1];                  4026     //cval[i] = _val[SIZE-i-1];
4038   }                                              4027   }
4039   //_rval = *(T *)cval;                          4028   //_rval = *(T *)cval;
4040   _rval = uni.tu;                                4029   _rval = uni.tu;
4041   //delete [] cval;                              4030   //delete [] cval;
4042 }                                                4031 }
4043                                                  4032 
4044 //----- kVerbose information -----//             4033 //----- kVerbose information -----//
4045 void G4GMocrenIO::setVerboseLevel(int _level)    4034 void G4GMocrenIO::setVerboseLevel(int _level) {
4046   kVerbose = _level;                             4035   kVerbose = _level;
4047 }                                                4036 }
4048                                                  4037 
4049                                                  4038