| Geant4 Cross Reference |
>> 1 // This code implementation is the intellectual property of
>> 2 // the GEANT4 collaboration.
>> 3 //
>> 4 // By copying, distributing or modifying the Program (or any work
>> 5 // based on the Program) you indicate your acceptance of this statement,
>> 6 // and all its terms.
>> 7 //
>> 8 // $Id: G4VTrajectory.hh,v 1.5 2000/11/11 06:34:11 tsasaki Exp $
>> 9 // GEANT4 tag $Name: geant4-03-01 $
>> 10 //
>> 11 //
>> 12 //---------------------------------------------------------------
>> 13 //
>> 14 // G4VTrajectory.hh
>> 15 //
>> 16 // class description:
>> 17 // This is the abstract base class of a trajectory.
1 // 18 //
2 // ******************************************* <<
3 // * License and Disclaimer <<
4 // * <<
5 // * The Geant4 software is copyright of th <<
6 // * the Geant4 Collaboration. It is provided <<
7 // * conditions of the Geant4 Software License <<
8 // * LICENSE and available at http://cern.ch/ <<
9 // * include a list of copyright holders. <<
10 // * <<
11 // * Neither the authors of this software syst <<
12 // * institutes,nor the agencies providing fin <<
13 // * work make any representation or warran <<
14 // * regarding this software system or assum <<
15 // * use. Please see the license in the file <<
16 // * for the full disclaimer and the limitatio <<
17 // * <<
18 // * This code implementation is the result <<
19 // * technical work of the GEANT4 collaboratio <<
20 // * By using, copying, modifying or distri <<
21 // * any work based on the software) you ag <<
22 // * use in resulting scientific publicati <<
23 // * acceptance of all terms of the Geant4 Sof <<
24 // ******************************************* <<
25 // <<
26 // G4VTrajectory <<
27 // <<
28 // Class description: <<
29 // <<
30 // This class is the abstract base class repre <<
31 // a particle being tracked. <<
32 // Its concrete class includes information of: <<
33 // 1) List of trajectory points composing <<
34 // 2) Static information of the particle w <<
35 // 3) Track ID and parent particle ID of t <<
36 <<
37 // Contact: 19 // Contact:
38 // Questions and comments to this code shoul 20 // Questions and comments to this code should be sent to
39 // Katsuya Amako (e-mail: Katsuya.Amako@k 21 // Katsuya Amako (e-mail: Katsuya.Amako@kek.jp)
40 // Makoto Asai (e-mail: asai@slac.stanf << 22 // Makoto Asai (e-mail: asai@kekvax.kek.jp)
41 // Takashi Sasaki (e-mail: Takashi.Sasaki@ 23 // Takashi Sasaki (e-mail: Takashi.Sasaki@kek.jp)
42 // ------------------------------------------- << 24 //
43 #ifndef G4VTrajectory_hh << 25 // ---------------------------------------------------------------
44 #define G4VTrajectory_hh 1 <<
45 <<
46 #include "G4ThreeVector.hh" <<
47 #include "globals.hh" <<
48 26
49 #include <map> << 27 #ifndef G4VTrajectory_h
50 #include <vector> << 28 #define G4VTrajectory_h 1
51 29
52 class G4Step; 30 class G4Step;
53 class G4VTrajectoryPoint; << 31 #include "G4VTrajectoryPoint.hh"
54 class G4AttDef; << 32 #include "globals.hh"
55 class G4AttValue; <<
56 33
57 class G4VTrajectory 34 class G4VTrajectory
58 { 35 {
59 public: << 36 public: // without description
60 // Constructor/Destrcutor << 37
61 G4VTrajectory() = default; << 38 G4VTrajectory() {;}
62 virtual ~G4VTrajectory() = default; << 39 virtual ~G4VTrajectory() {;}
63 << 40
64 // Equality operator << 41 inline int operator == (const G4VTrajectory& right){return (this==&right);}
65 G4bool operator==(const G4VTrajectory& right << 42
66 << 43 virtual void ShowTrajectory() const = 0;
67 // Cloning with the master thread allocator << 44 virtual void DrawTrajectory(G4int i_mode=0) const = 0;
68 // Each concrete class should implement its << 45 virtual void AppendStep(const G4Step*) = 0;
69 // This method is used only in the sub-event << 46 virtual int GetPointEntries() const = 0;
70 virtual G4VTrajectory* CloneForMaster() cons << 47 virtual G4VTrajectoryPoint* GetPoint(int) const = 0;
71 << 48 virtual void MergeTrajectory(G4VTrajectory*) = 0;
72 // Accessors <<
73 virtual G4int GetTrackID() const = 0; <<
74 virtual G4int GetParentID() const = 0; <<
75 virtual G4String GetParticleName() const = 0 <<
76 <<
77 // Charge is that of G4DynamicParticle <<
78 virtual G4double GetCharge() const = 0; <<
79 <<
80 // Zero will be returned if the particle doe <<
81 virtual G4int GetPDGEncoding() const = 0; <<
82 <<
83 // Momentum at the origin of the track in gl <<
84 virtual G4ThreeVector GetInitialMomentum() c <<
85 <<
86 // Returns the number of trajectory points <<
87 virtual G4int GetPointEntries() const = 0; <<
88 <<
89 // Returns i-th trajectory point <<
90 virtual G4VTrajectoryPoint* GetPoint(G4int i <<
91 <<
92 // Converts attributes in trajectory (and tr <<
93 // needed) to ostream. A default implementat <<
94 // may be used or may be overridden in the c <<
95 // the user needs to follow with new-line or <<
96 // depending on the nature of os <<
97 virtual void ShowTrajectory(std::ostream& os <<
98 <<
99 // Draw the trajectory. A default implementa <<
100 // class may be used or may be overridden in <<
101 virtual void DrawTrajectory() const; <<
102 <<
103 // If implemented by a derived class, return <<
104 // attribute definitions for the attribute v <<
105 // must test the validity of this pointer. S <<
106 // example of a concrete implementation of t <<
107 virtual const std::map<G4String, G4AttDef>* <<
108 <<
109 // If implemented by a derived class, return <<
110 // of attribute values suitable, e.g., for p <<
111 // refer to an attribute definition in the a <<
112 // the key. The user must test the validity <<
113 // must be non-zero and conform to the G4Att <<
114 // checked with G4AttCheck) and delete the l <<
115 // G4Trajectory for an example of a concrete <<
116 // method and G4VTrajectory::ShowTrajectory <<
117 virtual std::vector<G4AttValue>* CreateAttVa <<
118 <<
119 // Methods invoked exclusively by G4Tracking <<
120 virtual void AppendStep(const G4Step* aStep) <<
121 virtual void MergeTrajectory(G4VTrajectory* <<
122 }; 49 };
123 50
124 #endif 51 #endif
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125 62