Geant4 10.7.0
Toolkit for the simulation of the passage of particles through matter
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G4AssemblyVolume.hh
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1//
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25//
26// Class G4AssemblyVolume
27//
28// Class description:
29//
30// G4AssemblyVolume is a helper class to make the build process of geometry
31// easier. It allows one to combine several volumes together in an arbitrary way
32// in 3D space and then work with the result as with a single logical volume
33// for placement.
34// The resulting objects are independent copies of each of the assembled
35// logical volumes. The placements are not, however, bound one to each other
36// when placement is done. They are seen as independent physical volumes in
37// space.
38
39// Radovan Chytracek, John Apostolakis, Gabriele Cosmo: created - November 2000
40// Ivana Hrivnacova: extended to support assembly of assemblies
41// of volumes and reflections - March 2006
42// ----------------------------------------------------------------------
43#ifndef G4_ASSEMBLYVOLUME_H
44#define G4_ASSEMBLYVOLUME_H
45
46#include <vector>
47
48#include "G4Transform3D.hh"
49#include "G4AssemblyTriplet.hh"
50
52
54{
55 public: // with description
56
59 G4ThreeVector& translation,
60 G4RotationMatrix* rotation);
62 //
63 // Constructors & destructor.
64 // At destruction all the generated physical volumes and associated
65 // rotation matrices of the imprints will be destroyed.
66 //
67 // The rotation matrix passed as argument can be nullptr (identity) or an
68 // address even of an object on the upper stack frame. During assembly
69 // imprint, a new matrix is created anyway and it is kept track of it so
70 // it can be automatically deleted later at the end of the application.
71 // This policy is adopted since user has no control on the way the
72 // rotations are combined.
73
74 void AddPlacedVolume( G4LogicalVolume* pPlacedVolume,
75 G4ThreeVector& translation,
76 G4RotationMatrix* rotation);
77 //
78 // Place the given volume 'pPlacedVolume' inside the assembly.
79 //
80 // The adopted approach:
81 //
82 // - Place it w.r.t. the assembly coordinate system.
83 // This step is applied to each of the participating volumes.
84 //
85 // The other possible approaches:
86 //
87 // - Place w.r.t. the firstly added volume.
88 // When placed the first, the virtual coordinate system becomes
89 // the coordinate system of the first one.
90 // Every next volume being added into the assembly will be placed
91 // w.r.t to the first one.
92 //
93 // - Place w.r.t the last placed volume.
94 // When placed the first, the virtual coordinate system becomes
95 // the coordinate system of the first one.
96 // Every next volume being added into the assembly will be placed
97 // w.r.t to the previous one.
98 //
99 // The rotation matrix passed as argument can be nullptr (identity) or an
100 // address even of an object on the upper stack frame. During assembly
101 // imprint, a new matrix is created anyway and it is kept track of it so
102 // it can be automatically deleted later at the end of the application.
103 // This policy is adopted since user has no control on the way the
104 // rotations are combined.
105
106 void AddPlacedVolume( G4LogicalVolume* pPlacedVolume,
107 G4Transform3D& transformation);
108 //
109 // The same as previous, but takes complete 3D transformation in space
110 // as its argument.
111
112 void AddPlacedAssembly( G4AssemblyVolume* pAssembly,
113 G4Transform3D& transformation);
114 //
115 // The same as previous AddPlacedVolume(), but takes an assembly volume
116 // as its argument.
117
118 void AddPlacedAssembly( G4AssemblyVolume* pAssembly,
119 G4ThreeVector& translation,
120 G4RotationMatrix* rotation);
121 //
122 // The same as above AddPlacedVolume(), but takes an assembly volume
123 // as its argument with translation and rotation.
124
125 void MakeImprint( G4LogicalVolume* pMotherLV,
126 G4ThreeVector& translationInMother,
127 G4RotationMatrix* pRotationInMother,
128 G4int copyNumBase = 0,
129 G4bool surfCheck = false );
130 //
131 // Creates instance of an assembly volume inside the given mother volume.
132
133 void MakeImprint( G4LogicalVolume* pMotherLV,
134 G4Transform3D& transformation,
135 G4int copyNumBase = 0,
136 G4bool surfCheck = false );
137 //
138 // The same as previous Imprint() method, but takes complete 3D
139 // transformation in space as its argument.
140
141 inline std::vector<G4VPhysicalVolume*>::iterator GetVolumesIterator();
142 inline std::size_t TotalImprintedVolumes() const;
143 //
144 // Methods to access the physical volumes imprinted with the assembly.
145 inline G4Transform3D& GetImprintTransformation(unsigned int imprintID);
146 // Method to access transformation for each imprint
147
148 inline std::vector<G4AssemblyTriplet>::iterator GetTripletsIterator();
149 inline std::size_t TotalTriplets() const;
150 //
151 // Methods to access the triplets which are part of the assembly
152
153 inline unsigned int GetImprintsCount() const;
154 //
155 // Return the number of made imprints.
156
157 unsigned int GetInstanceCount() const;
158 //
159 // Return the number of existing instance of G4AssemblyVolume class.
160
161 inline unsigned int GetAssemblyID() const;
162 //
163 // Return instance number of this concrete object.
164
165 protected:
166
167 inline void SetInstanceCount( unsigned int value );
168 inline void SetAssemblyID( unsigned int value );
169
170 void InstanceCountPlus();
171 void InstanceCountMinus();
172
173 inline void SetImprintsCount( unsigned int value );
174 inline void ImprintsCountPlus();
175 inline void ImprintsCountMinus();
176 //
177 // Internal counting mechanism, used to compute unique the names of
178 // physical volumes created by MakeImprint() methods.
179
180 private:
181
182 void MakeImprint( G4AssemblyVolume* pAssembly,
183 G4LogicalVolume* pMotherLV,
184 G4Transform3D& transformation,
185 G4int copyNumBase = 0,
186 G4bool surfCheck = false );
187 //
188 // Function for placement of the given assembly in the given mother
189 // (called recursively if the assembly contains an assembly).
190
191 private:
192
193 std::vector<G4AssemblyTriplet> fTriplets;
194 //
195 // Participating volumes represented as a vector of
196 // <logical volume, translation, rotation>.
197
198 std::vector<G4VPhysicalVolume*> fPVStore;
199 //
200 // We need to keep list of physical volumes created by MakeImprint() method
201 // in order to be able to cleanup the objects when not needed anymore.
202 // This requires the user to keep assembly objects in memory during the
203 // whole job or during the life-time of G4Navigator, logical volume store
204 // and physical volume store keep pointers to physical volumes generated by
205 // the assembly volume.
206 // When an assembly object is about to die it will destroy all its
207 // generated physical volumes and rotation matrices as well !
208
209 unsigned int fImprintsCounter;
210 //
211 // Number of imprints of the given assembly volume.
212
213 static G4ThreadLocal unsigned int fsInstanceCounter;
214 //
215 // Class instance counter.
216
217 unsigned int fAssemblyID = 0;
218 //
219 // Assembly object ID derived from instance counter at construction time.
220
221 std::map<unsigned int, G4Transform3D> fImprintsTransf;
222 //
223 // Container of transformations for each imprint (used by GDML persistency)
224};
225
226#include "G4AssemblyVolume.icc"
227
228#endif // G4_ASSEMBLYVOLUME_H
bool G4bool
Definition: G4Types.hh:86
int G4int
Definition: G4Types.hh:85
unsigned int GetImprintsCount() const
void MakeImprint(G4LogicalVolume *pMotherLV, G4ThreeVector &translationInMother, G4RotationMatrix *pRotationInMother, G4int copyNumBase=0, G4bool surfCheck=false)
G4Transform3D & GetImprintTransformation(unsigned int imprintID)
std::vector< G4VPhysicalVolume * >::iterator GetVolumesIterator()
void ImprintsCountMinus()
std::vector< G4AssemblyTriplet >::iterator GetTripletsIterator()
void SetAssemblyID(unsigned int value)
void AddPlacedAssembly(G4AssemblyVolume *pAssembly, G4Transform3D &transformation)
unsigned int GetAssemblyID() const
void SetInstanceCount(unsigned int value)
void AddPlacedVolume(G4LogicalVolume *pPlacedVolume, G4ThreeVector &translation, G4RotationMatrix *rotation)
void ImprintsCountPlus()
void SetImprintsCount(unsigned int value)
std::size_t TotalTriplets() const
unsigned int GetInstanceCount() const
std::size_t TotalImprintedVolumes() const
#define G4ThreadLocal
Definition: tls.hh:77