| Geant4 Cross Reference |
1 // 1 //
2 // ******************************************* 2 // ********************************************************************
3 // * License and Disclaimer 3 // * License and Disclaimer *
4 // * 4 // * *
5 // * The Geant4 software is copyright of th 5 // * The Geant4 software is copyright of the Copyright Holders of *
6 // * the Geant4 Collaboration. It is provided 6 // * the Geant4 Collaboration. It is provided under the terms and *
7 // * conditions of the Geant4 Software License 7 // * conditions of the Geant4 Software License, included in the file *
8 // * LICENSE and available at http://cern.ch/ 8 // * LICENSE and available at http://cern.ch/geant4/license . These *
9 // * include a list of copyright holders. 9 // * include a list of copyright holders. *
10 // * 10 // * *
11 // * Neither the authors of this software syst 11 // * Neither the authors of this software system, nor their employing *
12 // * institutes,nor the agencies providing fin 12 // * institutes,nor the agencies providing financial support for this *
13 // * work make any representation or warran 13 // * work make any representation or warranty, express or implied, *
14 // * regarding this software system or assum 14 // * regarding this software system or assume any liability for its *
15 // * use. Please see the license in the file 15 // * use. Please see the license in the file LICENSE and URL above *
16 // * for the full disclaimer and the limitatio 16 // * for the full disclaimer and the limitation of liability. *
17 // * 17 // * *
18 // * This code implementation is the result 18 // * This code implementation is the result of the scientific and *
19 // * technical work of the GEANT4 collaboratio 19 // * technical work of the GEANT4 collaboration. *
20 // * By using, copying, modifying or distri 20 // * By using, copying, modifying or distributing the software (or *
21 // * any work based on the software) you ag 21 // * any work based on the software) you agree to acknowledge its *
22 // * use in resulting scientific publicati 22 // * use in resulting scientific publications, and indicate your *
23 // * acceptance of all terms of the Geant4 Sof 23 // * acceptance of all terms of the Geant4 Software license. *
24 // ******************************************* 24 // ********************************************************************
25 // 25 //
26 // G4VScoringMesh <<
27 // 26 //
28 // Class description: << 27 // $Id: G4VScoringMesh.hh 68735 2013-04-05 09:49:13Z gcosmo $
29 // 28 //
30 // This class represents a multi-functional de << 29
31 // command-based scorer for parallel world sco <<
32 // parallel world mesh geometry <<
33 // <<
34 // Author: Makoto Asai <<
35 // ------------------------------------------- <<
36 #ifndef G4VScoringMesh_h 30 #ifndef G4VScoringMesh_h
37 #define G4VScoringMesh_h 1 31 #define G4VScoringMesh_h 1
38 32
39 #include "globals.hh" 33 #include "globals.hh"
40 #include "G4THitsMap.hh" 34 #include "G4THitsMap.hh"
41 #include "G4RotationMatrix.hh" 35 #include "G4RotationMatrix.hh"
42 #include "G4StatDouble.hh" <<
43 <<
44 #include <map> <<
45 36
46 class G4VPhysicalVolume; 37 class G4VPhysicalVolume;
47 class G4LogicalVolume; 38 class G4LogicalVolume;
48 class G4MultiFunctionalDetector; 39 class G4MultiFunctionalDetector;
49 class G4VPrimitiveScorer; 40 class G4VPrimitiveScorer;
50 class G4VSDFilter; 41 class G4VSDFilter;
51 class G4VScoreColorMap; 42 class G4VScoreColorMap;
52 class G4ParallelWorldProcess; <<
53 43
54 class G4VScoringMesh << 44 #include <map>
55 { <<
56 public: <<
57 enum class MeshShape <<
58 { <<
59 box, <<
60 cylinder, <<
61 sphere, <<
62 realWorldLogVol, <<
63 probe, <<
64 undefined = -1 <<
65 }; <<
66 using EventScore = G4THitsMap<G4double>; <<
67 using RunScore = G4THitsMap<G4StatDouble <<
68 using MeshScoreMap = std::map<G4String, RunS <<
69 45
70 public: << 46 enum MeshShape { boxMesh, cylinderMesh, sphereMesh };
>> 47 typedef std::map<G4String,G4THitsMap<G4double>* > MeshScoreMap;
>> 48 // class description:
>> 49 //
>> 50 // This class represents a parallel world for interactive scoring purposes.
>> 51 //
71 52
>> 53 class G4VScoringMesh
>> 54 {
>> 55 public:
72 G4VScoringMesh(const G4String& wName); 56 G4VScoringMesh(const G4String& wName);
73 virtual ~G4VScoringMesh() = default; << 57 virtual ~G4VScoringMesh();
>> 58
>> 59 public: // with description
>> 60 // a pure virtual function to construct this mesh geometry
>> 61 virtual void Construct(G4VPhysicalVolume* fWorldPhys)=0;
74 62
75 virtual void Construct(G4VPhysicalVolume* fW <<
76 virtual void WorkerConstruct(G4VPhysicalVolu 63 virtual void WorkerConstruct(G4VPhysicalVolume* fWorldPhys);
77 64
78 // list infomration of this mesh << 65 // list infomration of this mesh
79 virtual void List() const; 66 virtual void List() const;
80 << 67
>> 68 public: // with description
81 // get the world name 69 // get the world name
82 // If this ScoringMesh is for parallel world << 70 inline const G4String& GetWorldName() const
83 // parallel world If this ScoringMesh is for << 71 { return fWorldName; }
84 // returns name of logical volume <<
85 inline const G4String& GetWorldName() const <<
86 // get whether this mesh is active or not 72 // get whether this mesh is active or not
87 inline G4bool IsActive() const { return fAct << 73 inline G4bool IsActive() const
>> 74 { return fActive; }
88 // set an activity of this mesh 75 // set an activity of this mesh
89 inline void Activate(G4bool vl = true) { fAc << 76 inline void Activate(G4bool vl = true)
>> 77 { fActive = vl; }
90 // get the shape of this mesh 78 // get the shape of this mesh
91 inline MeshShape GetShape() const { return f << 79 inline MeshShape GetShape() const
>> 80 { return fShape; }
92 // accumulate hits in a registered primitive 81 // accumulate hits in a registered primitive scorer
93 void Accumulate(G4THitsMap<G4double>* map); << 82 void Accumulate(G4THitsMap<G4double> * map);
94 void Accumulate(G4THitsMap<G4StatDouble>* ma <<
95 // merge same kind of meshes 83 // merge same kind of meshes
96 void Merge(const G4VScoringMesh* scMesh); << 84 void Merge(const G4VScoringMesh * scMesh);
97 // dump information of primitive socrers reg 85 // dump information of primitive socrers registered in this mesh
98 void Dump(); 86 void Dump();
99 // draw a projected quantity on a current vi 87 // draw a projected quantity on a current viewer
100 void DrawMesh(const G4String& psName, G4VSco << 88 void DrawMesh(const G4String& psName,G4VScoreColorMap* colorMap,G4int axflg=111);
101 G4int axflg = 111); <<
102 // draw a column of a quantity on a current 89 // draw a column of a quantity on a current viewer
103 void DrawMesh(const G4String& psName, G4int << 90 void DrawMesh(const G4String& psName,G4int idxPlane,G4int iColumn,G4VScoreColorMap* colorMap);
104 G4VScoreColorMap* colorMap); <<
105 // draw a projected quantity on a current vi 91 // draw a projected quantity on a current viewer
106 virtual void Draw(RunScore* map, G4VScoreCol << 92 virtual void Draw(std::map<G4int, G4double*> * map, G4VScoreColorMap* colorMap, G4int axflg=111) = 0;
107 G4int axflg = 111) = 0; <<
108 // draw a column of a quantity on a current 93 // draw a column of a quantity on a current viewer
109 virtual void DrawColumn(RunScore* map, G4VSc << 94 virtual void DrawColumn(std::map<G4int, G4double*> * map, G4VScoreColorMap* colorMap,
110 G4int idxProj, G4int << 95 G4int idxProj, G4int idxColumn) = 0;
111 // reset registered primitive scorers 96 // reset registered primitive scorers
112 void ResetScore(); 97 void ResetScore();
113 98
114 // Following set/get methods make sense only <<
115 // set size of this mesh 99 // set size of this mesh
116 void SetSize(G4double size[3]); 100 void SetSize(G4double size[3]);
117 // get size of this mesh 101 // get size of this mesh
118 G4ThreeVector GetSize() const; 102 G4ThreeVector GetSize() const;
119 // set starting and span angles (used only f <<
120 void SetAngles(G4double, G4double); <<
121 // get angles (used only for tube segment) <<
122 inline G4double GetStartAngle() const { retu <<
123 inline G4double GetAngleSpan() const { retur <<
124 // set position of center of this mesh 103 // set position of center of this mesh
125 void SetCenterPosition(G4double centerPositi 104 void SetCenterPosition(G4double centerPosition[3]);
126 // get position of center of this mesh 105 // get position of center of this mesh
127 G4ThreeVector GetTranslation() const { retur << 106 G4ThreeVector GetTranslation() const {return fCenterPosition;}
128 // set a rotation angle around the x axis 107 // set a rotation angle around the x axis
129 void RotateX(G4double delta); 108 void RotateX(G4double delta);
130 // set a rotation angle around the y axis 109 // set a rotation angle around the y axis
131 void RotateY(G4double delta); 110 void RotateY(G4double delta);
132 // set a rotation angle around the z axis 111 // set a rotation angle around the z axis
133 void RotateZ(G4double delta); 112 void RotateZ(G4double delta);
134 // get a rotation matrix 113 // get a rotation matrix
135 inline G4RotationMatrix GetRotationMatrix() << 114 G4RotationMatrix GetRotationMatrix() const {
136 { << 115 if(fRotationMatrix) return *fRotationMatrix;
137 if(fRotationMatrix != nullptr) << 116 else return G4RotationMatrix::IDENTITY;
138 return *fRotationMatrix; <<
139 return G4RotationMatrix::IDENTITY; <<
140 } 117 }
141 <<
142 // set number of segments of this mesh 118 // set number of segments of this mesh
143 void SetNumberOfSegments(G4int nSegment[3]); 119 void SetNumberOfSegments(G4int nSegment[3]);
144 // get number of segments of this mesh 120 // get number of segments of this mesh
145 void GetNumberOfSegments(G4int nSegment[3]); 121 void GetNumberOfSegments(G4int nSegment[3]);
146 122
147 // register a primitive scorer to the MFD & << 123 // register a primitive scorer to the MFD & set it to the current primitive scorer
148 // scorer << 124 void SetPrimitiveScorer(G4VPrimitiveScorer * ps);
149 void SetPrimitiveScorer(G4VPrimitiveScorer* <<
150 // register a filter to a current primtive s 125 // register a filter to a current primtive scorer
151 void SetFilter(G4VSDFilter* filter); << 126 void SetFilter(G4VSDFilter * filter);
152 // set a primitive scorer to the current one 127 // set a primitive scorer to the current one by the name
153 void SetCurrentPrimitiveScorer(const G4Strin << 128 void SetCurrentPrimitiveScorer(const G4String & name);
154 // find registered primitive scorer by the n 129 // find registered primitive scorer by the name
155 G4bool FindPrimitiveScorer(const G4String& p << 130 G4bool FindPrimitiveScorer(const G4String & psname);
156 // get whether current primitive scorer is s 131 // get whether current primitive scorer is set or not
157 inline G4bool IsCurrentPrimitiveScorerNull() << 132 G4bool IsCurrentPrimitiveScorerNull() {
158 { << 133 if(fCurrentPS == NULL) return true;
159 return fCurrentPS == nullptr; << 134 else return false;
160 } 135 }
161 // get unit of primitive scorer by the name 136 // get unit of primitive scorer by the name
162 G4String GetPSUnit(const G4String& psname); << 137 G4String GetPSUnit(const G4String & psname);
163 // get unit of current primitive scorer 138 // get unit of current primitive scorer
164 G4String GetCurrentPSUnit(); 139 G4String GetCurrentPSUnit();
165 // set unit of current primitive scorer 140 // set unit of current primitive scorer
166 void SetCurrentPSUnit(const G4String& unit); 141 void SetCurrentPSUnit(const G4String& unit);
167 // get unit value of primitive scorer by the 142 // get unit value of primitive scorer by the name
168 G4double GetPSUnitValue(const G4String& psna << 143 G4double GetPSUnitValue(const G4String & psname);
169 // set PS name to be drawn 144 // set PS name to be drawn
170 inline void SetDrawPSName(const G4String& ps << 145 void SetDrawPSName(const G4String & psname) {fDrawPSName = psname;}
171 146
172 // get axis names of the hierarchical divisi 147 // get axis names of the hierarchical division in the divided order
173 void GetDivisionAxisNames(G4String divisionA 148 void GetDivisionAxisNames(G4String divisionAxisNames[3]);
174 149
175 // set current primitive scorer to NULL 150 // set current primitive scorer to NULL
176 void SetNullToCurrentPrimitiveScorer() { fCu << 151 void SetNullToCurrentPrimitiveScorer() {fCurrentPS = NULL;}
177 // set verbose level 152 // set verbose level
178 inline void SetVerboseLevel(G4int vl) { verb << 153 inline void SetVerboseLevel(G4int vl)
>> 154 { verboseLevel = vl; }
179 // get the primitive scorer map 155 // get the primitive scorer map
180 inline MeshScoreMap GetScoreMap() const { re << 156 inline MeshScoreMap GetScoreMap() const
>> 157 { return fMap; }
181 // get whether this mesh setup has been read 158 // get whether this mesh setup has been ready
182 inline G4bool ReadyForQuantity() const { ret << 159 inline G4bool ReadyForQuantity() const
>> 160 { return (sizeIsSet && nMeshIsSet); }
183 161
184 // protected: << 162 protected:
185 // get registered primitive socrer by the na 163 // get registered primitive socrer by the name
186 G4VPrimitiveScorer* GetPrimitiveScorer(const << 164 G4VPrimitiveScorer * GetPrimitiveScorer(const G4String & name);
187 165
188 inline void SetMeshElementLogical(G4LogicalV << 166 protected:
189 { << 167 G4String fWorldName;
190 fMeshElementLogical = val; << 168 G4VPrimitiveScorer * fCurrentPS;
191 } << 169 G4bool fConstructed;
192 inline G4LogicalVolume* GetMeshElementLogica << 170 G4bool fActive;
193 { <<
194 return fMeshElementLogical; <<
195 } <<
196 <<
197 inline void SetParallelWorldProcess(G4Parall <<
198 { <<
199 fParallelWorldProcess = proc; <<
200 } <<
201 inline G4ParallelWorldProcess* GetParallelWo <<
202 { <<
203 return fParallelWorldProcess; <<
204 } <<
205 inline void GeometryHasBeenDestroyed() <<
206 { <<
207 fGeometryHasBeenDestroyed = true; <<
208 fMeshElementLogical = nullptr; <<
209 } <<
210 <<
211 // Geometry hirarchy level (bottom = 0) to b <<
212 // This is used only for real-world scorer <<
213 inline void SetCopyNumberLevel(G4int val) { <<
214 inline G4int GetCopyNumberLevel() const { re <<
215 <<
216 inline G4bool LayeredMassFlg() { return laye <<
217 <<
218 protected: <<
219 <<
220 // a pure virtual function to construct this <<
221 virtual void SetupGeometry(G4VPhysicalVolume <<
222 <<
223 protected: <<
224 <<
225 G4String fWorldName; <<
226 G4VPrimitiveScorer* fCurrentPS; <<
227 G4bool fConstructed; <<
228 G4bool fActive; <<
229 MeshShape fShape; 171 MeshShape fShape;
230 172
231 G4double fSize[3]; 173 G4double fSize[3];
232 G4double fAngle[2]; <<
233 G4ThreeVector fCenterPosition; 174 G4ThreeVector fCenterPosition;
234 G4RotationMatrix* fRotationMatrix; << 175 G4RotationMatrix * fRotationMatrix;
235 G4int fNSegment[3]; 176 G4int fNSegment[3];
236 177
237 MeshScoreMap fMap; << 178 std::map<G4String, G4THitsMap<G4double>* > fMap;
238 G4MultiFunctionalDetector* fMFD; << 179 G4MultiFunctionalDetector * fMFD;
239 180
240 G4int verboseLevel; 181 G4int verboseLevel;
241 182
242 G4bool sizeIsSet; 183 G4bool sizeIsSet;
243 G4bool nMeshIsSet; 184 G4bool nMeshIsSet;
244 185
245 G4String fDrawUnit; 186 G4String fDrawUnit;
246 G4double fDrawUnitValue; 187 G4double fDrawUnitValue;
247 G4String fDrawPSName; 188 G4String fDrawPSName;
248 189
249 G4String fDivisionAxisNames[3]; 190 G4String fDivisionAxisNames[3];
250 191
251 G4LogicalVolume* fMeshElementLogical; << 192 G4LogicalVolume * fMeshElementLogical;
252 193
253 G4ParallelWorldProcess* fParallelWorldProces << 194 public:
254 G4bool fGeometryHasBeenDestroyed; << 195 inline void SetMeshElementLogical(G4LogicalVolume* val)
255 << 196 { fMeshElementLogical = val; }
256 G4int copyNumberLevel; << 197 inline G4LogicalVolume* GetMeshElementLogical() const
257 << 198 { return fMeshElementLogical; }
258 // This flag may be set to true for Probe sc <<
259 // There is no public set method for this bo <<
260 // to true through SetMaterial() method of P <<
261 G4bool layeredMassFlg; <<
262 }; 199 };
263 200
264 #endif 201 #endif
>> 202
265 203