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TRotMatrix.cxx
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1// @(#)root/g3d:$Id$
2// Author: Rene Brun 14/09/95
3
4/*************************************************************************
5 * Copyright (C) 1995-2000, Rene Brun and Fons Rademakers. *
6 * All rights reserved. *
7 * *
8 * For the licensing terms see $ROOTSYS/LICENSE. *
9 * For the list of contributors see $ROOTSYS/README/CREDITS. *
10 *************************************************************************/
11
12#include "TRotMatrix.h"
13#include "TBuffer.h"
14#include "TGeometry.h"
15#include "TMath.h"
16
18
19/** \class TRotMatrix
20\ingroup g3d
21Manages a detector rotation matrix. See class TGeometry.
22*/
23
24////////////////////////////////////////////////////////////////////////////////
25/// RotMatrix default constructor.
26
28{
29 for (int i=0;i<9;i++) fMatrix[i] = 0;
30 fNumber = 0;
31 fPhi = 0;
32 fPsi = 0;
33 fTheta = 0;
34 fType = 0;
35}
36
37////////////////////////////////////////////////////////////////////////////////
38/// RotMatrix normal constructor.
39
40TRotMatrix::TRotMatrix(const char *name, const char *title, Double_t *matrix)
41 :TNamed(name,title)
42{
43 fNumber = 0;
44 fPhi = 0;
45 fPsi = 0;
46 fTheta = 0;
47 fType = 0;
48
49 if (!matrix) { Error("ctor","No rotation is supplied"); return; }
50
51 SetMatrix(matrix);
52 if (!gGeometry) gGeometry = new TGeometry();
55}
56
57////////////////////////////////////////////////////////////////////////////////
58/// RotMatrix normal constructor.
59
60TRotMatrix::TRotMatrix(const char *name, const char *title, Double_t theta, Double_t phi, Double_t psi)
61 :TNamed(name,title)
62{
63 printf("ERROR: This form of TRotMatrix constructor not implemented yet\n");
64
65 Int_t i;
66 fTheta = theta;
67 fPhi = phi;
68 fPsi = psi;
69 fType = 2;
70 for (i=0;i<9;i++) fMatrix[i] = 0;
71 fMatrix[0] = 1; fMatrix[4] = 1; fMatrix[8] = 1;
72
73 if (!gGeometry) gGeometry = new TGeometry();
76}
77
78////////////////////////////////////////////////////////////////////////////////
79/// RotMatrix normal constructor defined a la GEANT.
80///
81/// The TRotMatrix constructor with six angles uses the GEANT convention:
82///
83/// theta1 is the polar angle of the x-prim axis in the main reference system
84/// (MRS), theta2 and theta3 have the same meaning for the y-prim and z-prim
85/// axis.
86///
87/// Phi1 is the azimuthal angle of the x-prim in the MRS and phi2 and phi3
88/// have the same meaning for y-prim and z-prim.
89///
90///
91/// for example, the unit matrix is defined in the following way.
92/// ~~~ {.cpp}
93/// x-prim || x, y-prim || y, z-prim || z
94///
95/// means: theta1=90, theta2=90, theta3=0, phi1=0, phi2=90, phi3=0
96/// ~~~
97
98TRotMatrix::TRotMatrix(const char *name, const char *title, Double_t theta1, Double_t phi1
99 , Double_t theta2, Double_t phi2
100 , Double_t theta3, Double_t phi3)
101 :TNamed(name,title)
102{
103 SetAngles(theta1,phi1,theta2,phi2,theta3,phi3);
104
105 if (!gGeometry) gGeometry = new TGeometry();
108}
109
110////////////////////////////////////////////////////////////////////////////////
111/// RotMatrix default destructor.
112
114{
116}
117
118////////////////////////////////////////////////////////////////////////////////
119/// Returns the value of the determinant of this matrix
120
122{
123 return
124 fMatrix[0] * (fMatrix[4]*fMatrix[8] - fMatrix[7]*fMatrix[5])
125 - fMatrix[3] * (fMatrix[1]*fMatrix[8] - fMatrix[7]*fMatrix[2])
126 + fMatrix[6] * (fMatrix[1]*fMatrix[5] - fMatrix[4]*fMatrix[2]);
127}
128
129////////////////////////////////////////////////////////////////////////////////
130/// Convert this matrix to the OpenGL [4x4]
131///
132/// ~~~ {.cpp}
133/// [ fMatrix[0] fMatrix[1] fMatrix[2] 0 ]
134/// [ fMatrix[3] fMatrix[4] fMatrix[5] 0 ]
135/// [ fMatrix[6] fMatrix[7] fMatrix[8] 0 ]
136/// [ 0 0 0 1 ]
137/// ~~~
138///
139/// Input:
140///
141/// Double_t *rGLMatrix: pointer to Double_t 4x4 buffer array
142///
143/// Return:
144///
145/// Double_t*: pointer to the input buffer
146
148{
149 Double_t *glmatrix = rGLMatrix;
150 const Double_t *matrix = fMatrix;
151 if (rGLMatrix)
152 {
153 for (Int_t i=0;i<3;i++) {
154 for (Int_t j=0;j<3;j++) memcpy(glmatrix,matrix,3*sizeof(Double_t));
155 matrix += 3;
156 glmatrix += 3;
157 *glmatrix = 0.0;
158 glmatrix++;
159 }
160 for (Int_t j=0;j<3;j++) {
161 *glmatrix = 0.0;
162 glmatrix++;
163 }
164 *glmatrix = 1.0;
165 }
166 return rGLMatrix;
167}
168
169////////////////////////////////////////////////////////////////////////////////
170/// theta1 is the polar angle of the x-prim axis in the main reference system
171/// (MRS), theta2 and theta3 have the same meaning for the y-prim and z-prim
172/// axis.
173///
174/// Phi1 is the azimuthal angle of the x-prim in the MRS and phi2 and phi3
175/// have the same meaning for y-prim and z-prim.
176///
177///
178/// for example, the unit matrix is defined in the following way.
179///
180/// ~~~ {.cpp}
181/// x-prim || x, y-prim || y, z-prim || z
182///
183/// means: theta1=90, theta2=90, theta3=0, phi1=0, phi2=90, phi3=0
184/// ~~~
185
187 Double_t theta2, Double_t phi2,Double_t theta3, Double_t phi3)
188{
189 const Double_t degrad = 0.0174532925199432958;
190
191 fTheta = theta1;
192 fPhi = phi1;
193 fPsi = theta2;
194
195 fType = 2;
196 if (!strcmp(GetName(),"Identity")) fType = 0;
197
198 fMatrix[0] = TMath::Sin(theta1*degrad)*TMath::Cos(phi1*degrad);
199 fMatrix[1] = TMath::Sin(theta1*degrad)*TMath::Sin(phi1*degrad);
200 fMatrix[2] = TMath::Cos(theta1*degrad);
201 fMatrix[3] = TMath::Sin(theta2*degrad)*TMath::Cos(phi2*degrad);
202 fMatrix[4] = TMath::Sin(theta2*degrad)*TMath::Sin(phi2*degrad);
203 fMatrix[5] = TMath::Cos(theta2*degrad);
204 fMatrix[6] = TMath::Sin(theta3*degrad)*TMath::Cos(phi3*degrad);
205 fMatrix[7] = TMath::Sin(theta3*degrad)*TMath::Sin(phi3*degrad);
206 fMatrix[8] = TMath::Cos(theta3*degrad);
207
209 return fMatrix;
210}
211
212////////////////////////////////////////////////////////////////////////////////
213/// copy predefined 3x3 matrix into TRotMatrix object
214
216{
217 fTheta = 0;
218 fPhi = 0;
219 fPsi = 0;
220 fType = 0;
221 if (!matrix) return;
222 fType = 2;
223 memcpy(fMatrix,matrix,9*sizeof(Double_t));
225}
226
227////////////////////////////////////////////////////////////////////////////////
228/// Checks whether the determinant of this
229/// matrix defines the reflection transformation
230/// and set the "reflection" flag if any
231
233{
235 if (Determinant() < 0) { fType=1; SetBit(kReflection);}
236}
237
238////////////////////////////////////////////////////////////////////////////////
239/// Stream an object of class TRotMatrix.
240
242{
243 if (R__b.IsReading()) {
244 UInt_t R__s, R__c;
245 Version_t R__v = R__b.ReadVersion(&R__s, &R__c);
246 if (R__v > 1) {
247 R__b.ReadClassBuffer(TRotMatrix::Class(), this, R__v, R__s, R__c);
248 return;
249 }
250 //====process old versions before automatic schema evolution
251 TNamed::Streamer(R__b);
252 R__b >> fNumber;
253 R__b >> fType;
254 R__b >> fTheta;
255 R__b >> fPhi;
256 R__b >> fPsi;
258 R__b.CheckByteCount(R__s, R__c, TRotMatrix::IsA());
259 //====end of old versions
260
261 } else {
263 }
264}
short Version_t
Definition RtypesCore.h:65
#define ClassImp(name)
Definition Rtypes.h:382
char name[80]
Definition TGX11.cxx:110
R__EXTERN TGeometry * gGeometry
Definition TGeometry.h:158
Buffer base class used for serializing objects.
Definition TBuffer.h:43
virtual Version_t ReadVersion(UInt_t *start=nullptr, UInt_t *bcnt=nullptr, const TClass *cl=nullptr)=0
virtual Int_t CheckByteCount(UInt_t startpos, UInt_t bcnt, const TClass *clss)=0
virtual Int_t ReadClassBuffer(const TClass *cl, void *pointer, const TClass *onfile_class=nullptr)=0
Bool_t IsReading() const
Definition TBuffer.h:86
virtual Int_t ReadStaticArray(Bool_t *b)=0
virtual Int_t WriteClassBuffer(const TClass *cl, void *pointer)=0
virtual Int_t GetSize() const
Return the capacity of the collection, i.e.
TGeometry description.
Definition TGeometry.h:39
THashList * GetListOfMatrices() const
Definition TGeometry.h:78
TObject * Remove(TObject *obj) override
Remove object from the list.
void Add(TObject *obj) override
Definition TList.h:81
The TNamed class is the base class for all named ROOT classes.
Definition TNamed.h:29
const char * GetName() const override
Returns name of object.
Definition TNamed.h:47
void Streamer(TBuffer &) override
Stream an object of class TObject.
void SetBit(UInt_t f, Bool_t set)
Set or unset the user status bits as specified in f.
Definition TObject.cxx:786
virtual void Error(const char *method, const char *msgfmt,...) const
Issue error message.
Definition TObject.cxx:993
void ResetBit(UInt_t f)
Definition TObject.h:198
Manages a detector rotation matrix.
Definition TRotMatrix.h:28
virtual const Double_t * SetAngles(Double_t theta1, Double_t phi1, Double_t theta2, Double_t phi2, Double_t theta3, Double_t phi3)
theta1 is the polar angle of the x-prim axis in the main reference system (MRS), theta2 and theta3 ha...
TClass * IsA() const override
Definition TRotMatrix.h:66
Double_t fTheta
Definition TRotMatrix.h:35
Double_t fPsi
Definition TRotMatrix.h:37
static TClass * Class()
void Streamer(TBuffer &) override
Stream an object of class TRotMatrix.
Double_t fPhi
Definition TRotMatrix.h:36
~TRotMatrix() override
RotMatrix default destructor.
Int_t fNumber
Definition TRotMatrix.h:33
virtual void SetReflection()
Checks whether the determinant of this matrix defines the reflection transformation and set the "refl...
virtual void SetMatrix(const Double_t *matrix)
copy predefined 3x3 matrix into TRotMatrix object
TRotMatrix()
RotMatrix default constructor.
Double_t fMatrix[9]
Definition TRotMatrix.h:38
Int_t fType
Definition TRotMatrix.h:34
virtual Double_t Determinant() const
Returns the value of the determinant of this matrix.
virtual Double_t * GetGLMatrix(Double_t *rGLMatrix) const
Convert this matrix to the OpenGL [4x4].
Double_t Cos(Double_t)
Returns the cosine of an angle of x radians.
Definition TMath.h:594
Double_t Sin(Double_t)
Returns the sine of an angle of x radians.
Definition TMath.h:588