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Reference Guide
DisplacementVector3D.h
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1// @(#)root/mathcore:$Id$
2// Authors: W. Brown, M. Fischler, L. Moneta 2005
3
4 /**********************************************************************
5 * *
6 * Copyright (c) 2005 , LCG ROOT MathLib Team and *
7 * FNAL LCG ROOT MathLib Team *
8 * *
9 * *
10 **********************************************************************/
11
12// Header source file for class DisplacementVector3D
13//
14// Created by: Lorenzo Moneta at Mon May 30 12:21:43 2005
15// Major rewrite: M. FIschler at Wed Jun 8 2005
16//
17// Last update: $Id$
18//
19
20#ifndef ROOT_Math_GenVector_DisplacementVector3D
21#define ROOT_Math_GenVector_DisplacementVector3D 1
22
24
26
28
30
32
33#include <cassert>
34
35//doxygen tag
36/**
37 @defgroup GenVector GenVector
38 Generic 2D, 3D and 4D vectors classes and their transformations (rotations). More information is available at the
39 home page for \ref Vector
40
41 @ingroup Math
42 */
43
44
45
46
47namespace ROOT {
48
49 namespace Math {
50
51
52//__________________________________________________________________________________________
53 /**
54 Class describing a generic displacement vector in 3 dimensions.
55 This class is templated on the type of Coordinate system.
56 One example is the XYZVector which is a vector based on
57 double precision x,y,z data members by using the
58 ROOT::Math::Cartesian3D<double> Coordinate system.
59 The class is having also an extra template parameter, the coordinate system tag,
60 to be able to identify (tag) vector described in different reference coordinate system,
61 like global or local coordinate systems.
62
63 @ingroup GenVector
64 */
65
66 template <class CoordSystem, class Tag = DefaultCoordinateSystemTag >
68
69 public:
70
71 typedef typename CoordSystem::Scalar Scalar;
72 typedef CoordSystem CoordinateType;
74
75 // ------ ctors ------
76
77 /**
78 Default constructor. Construct an empty object with zero values
79 */
81
82
83 /**
84 Construct from three values of type <em>Scalar</em>.
85 In the case of a XYZVector the values are x,y,z
86 In the case of a polar vector they are r,theta, phi
87 */
89 fCoordinates ( a , b, c ) { }
90
91 /**
92 Construct from a displacement vector expressed in different
93 coordinates, or using a different Scalar type, but with same coordinate system tag
94 */
95 template <class OtherCoords>
97 fCoordinates ( v.Coordinates() ) { }
98
99
100 /**
101 Construct from a position vector expressed in different coordinates
102 but with the same coordinate system tag
103 */
104 template <class OtherCoords>
106 fCoordinates ( p.Coordinates() ) { }
107
108
109 /**
110 Construct from a foreign 3D vector type, for example, Hep3Vector
111 Precondition: v must implement methods x(), y() and z()
112 */
113 template <class ForeignVector>
114 explicit DisplacementVector3D( const ForeignVector & v) :
115 fCoordinates ( Cartesian3D<Scalar>( v.x(), v.y(), v.z() ) ) { }
116
117
118#ifdef LATER
119 /**
120 construct from a generic linear algebra vector of at least size 3
121 implementing operator [].
122 \par v LAVector
123 \par index0 index where coordinates starts (typically zero)
124 It works for all Coordinates types,
125 ( x= v[index0] for Cartesian and r=v[index0] for Polar )
126 */
127 template <class LAVector>
128 DisplacementVector3D(const LAVector & v, size_t index0 ) {
129 fCoordinates = CoordSystem ( v[index0], v[index0+1], v[index0+2] );
130 }
131#endif
132
133 // compiler-generated copy ctor and dtor are fine.
134
135 // ------ assignment ------
136
137 /**
138 Assignment operator from a displacement vector of arbitrary type
139 */
140 template <class OtherCoords>
143 fCoordinates = v.Coordinates();
144 return *this;
145 }
146
147 /**
148 Assignment operator from a position vector
149 (not necessarily efficient unless one or the other is Cartesian)
150 */
151 template <class OtherCoords>
153 ( const PositionVector3D<OtherCoords,Tag> & rhs) {
154 SetXYZ(rhs.x(), rhs.y(), rhs.z());
155 return *this;
156 }
157
158
159 /**
160 Assignment from a foreign 3D vector type, for example, Hep3Vector
161 Precondition: v must implement methods x(), y() and z()
162 */
163 template <class ForeignVector>
164 DisplacementVector3D & operator= ( const ForeignVector & v) {
165 SetXYZ( v.x(), v.y(), v.z() );
166 return *this;
167 }
168
169
170#ifdef LATER
171 /**
172 assign from a generic linear algebra vector of at least size 3
173 implementing operator []. This could be also a C array
174 \par v LAVector
175 \par index0 index where coordinates starts (typically zero)
176 It works for all Coordinates types,
177 ( x= v[index0] for Cartesian and r=v[index0] for Polar )
178 */
179 template <class LAVector>
180 DisplacementVector3D & assignFrom(const LAVector & v, size_t index0 = 0) {
181 fCoordinates = CoordSystem ( v[index0], v[index0+1], v[index0+2] );
182 return *this;
183 }
184#endif
185
186 // ------ Set, Get, and access coordinate data ------
187
188 /**
189 Retrieve a copy of the coordinates object
190 */
191 CoordSystem Coordinates() const {
192 return fCoordinates;
193 }
194
195 /**
196 Set internal data based on a C-style array of 3 Scalar numbers
197 */
199 { fCoordinates.SetCoordinates(src); return *this; }
200
201 /**
202 Set internal data based on 3 Scalar numbers
203 */
205 { fCoordinates.SetCoordinates(a, b, c); return *this; }
206
207 /**
208 Set internal data based on 3 Scalars at *begin to *end
209 */
210 template <class IT>
211#ifndef NDEBUG
213#else
215#endif
216 { IT a = begin; IT b = ++begin; IT c = ++begin;
217 assert (++begin==end);
218 SetCoordinates (*a,*b,*c);
219 return *this;
220 }
221
222 /**
223 get internal data into 3 Scalar numbers
224 */
225 void GetCoordinates( Scalar& a, Scalar& b, Scalar& c ) const
226 { fCoordinates.GetCoordinates(a, b, c); }
227
228 /**
229 get internal data into a C-style array of 3 Scalar numbers
230 */
231 void GetCoordinates( Scalar dest[] ) const
232 { fCoordinates.GetCoordinates(dest); }
233
234 /**
235 get internal data into 3 Scalars at *begin to *end (3 past begin)
236 */
237 template <class IT>
238#ifndef NDEBUG
239 void GetCoordinates( IT begin, IT end ) const
240#else
241 void GetCoordinates( IT begin, IT /* end */ ) const
242#endif
243 { IT a = begin; IT b = ++begin; IT c = ++begin;
244 assert (++begin==end);
245 GetCoordinates (*a,*b,*c);
246 }
247 /**
248 get internal data into 3 Scalars starting at *begin
249 */
250 template <class IT>
251 void GetCoordinates( IT begin) const {
252 Scalar a = Scalar(0);
253 Scalar b = Scalar(0);
254 Scalar c = Scalar(0);
255 GetCoordinates(a, b, c);
256 *begin++ = a;
257 *begin++ = b;
258 *begin = c;
259 }
260
261 /**
262 set the values of the vector from the cartesian components (x,y,z)
263 (if the vector is held in polar or cylindrical eta coordinates,
264 then (x, y, z) are converted to that form)
265 */
267 fCoordinates.SetXYZ(a, b, c);
268 return *this;
269 }
270
271 // ------------------- Equality -----------------
272
273 /**
274 Exact equality
275 */
276 bool operator==(const DisplacementVector3D & rhs) const {
277 return fCoordinates==rhs.fCoordinates;
278 }
279 bool operator!= (const DisplacementVector3D & rhs) const {
280 return !(operator==(rhs));
281 }
282
283 // ------ Individual element access, in various coordinate systems ------
284
285 /**
286 Cartesian X, converting if necessary from internal coordinate system.
287 */
288 Scalar X() const { return fCoordinates.X(); }
289
290 /**
291 Cartesian Y, converting if necessary from internal coordinate system.
292 */
293 Scalar Y() const { return fCoordinates.Y(); }
294
295 /**
296 Cartesian Z, converting if necessary from internal coordinate system.
297 */
298 Scalar Z() const { return fCoordinates.Z(); }
299
300 /**
301 Polar R, converting if necessary from internal coordinate system.
302 */
303 Scalar R() const { return fCoordinates.R(); }
304
305 /**
306 Polar theta, converting if necessary from internal coordinate system.
307 */
308 Scalar Theta() const { return fCoordinates.Theta(); }
309
310 /**
311 Polar phi, converting if necessary from internal coordinate system.
312 */
313 Scalar Phi() const { return fCoordinates.Phi(); }
314
315 /**
316 Polar eta, converting if necessary from internal coordinate system.
317 */
318 Scalar Eta() const { return fCoordinates.Eta(); }
319
320 /**
321 Cylindrical transverse component rho
322 */
323 Scalar Rho() const { return fCoordinates.Rho(); }
324
325 // ----- Other fundamental properties -----
326
327 /**
328 Magnitute squared ( r^2 in spherical coordinate)
329 */
330 Scalar Mag2() const { return fCoordinates.Mag2();}
331
332 /**
333 Transverse component squared (rho^2 in cylindrical coordinates.
334 */
335 Scalar Perp2() const { return fCoordinates.Perp2();}
336
337 /**
338 return unit vector parallel to this (scalar)
339 */
340 template <typename SCALAR = Scalar, typename std::enable_if<std::is_arithmetic<SCALAR>::value>::type * = nullptr>
342 {
343 const auto tot = R();
344 return tot == 0 ? *this : DisplacementVector3D(*this) / tot;
345 }
346
347 /**
348 return unit vector parallel to this (vector)
349 */
350 template <typename SCALAR = Scalar, typename std::enable_if<!std::is_arithmetic<SCALAR>::value>::type * = nullptr>
352 {
353 SCALAR tot = R();
354 tot(tot == SCALAR(0)) = SCALAR(1);
355 return DisplacementVector3D(*this) / tot;
356 }
357
358 // ------ Setting of individual elements present in coordinate system ------
359
360 /**
361 Change X - Cartesian3D coordinates only
362 */
364
365 /**
366 Change Y - Cartesian3D coordinates only
367 */
369
370 /**
371 Change Z - Cartesian3D coordinates only
372 */
374
375 /**
376 Change R - Polar3D coordinates only
377 */
379
380 /**
381 Change Theta - Polar3D coordinates only
382 */
384
385 /**
386 Change Phi - Polar3D or CylindricalEta3D coordinates
387 */
389
390 /**
391 Change Rho - CylindricalEta3D coordinates only
392 */
394
395 /**
396 Change Eta - CylindricalEta3D coordinates only
397 */
398 DisplacementVector3D<CoordSystem, Tag>& SetEta (Scalar etaval) { fCoordinates.SetEta(etaval); return *this;}
399
400
401 // ------ Operations combining two vectors ------
402 // -- need to have the specialized version in order to avoid
403
404 /**
405 Return the scalar (dot) product of two displacement vectors.
406 It is possible to perform the product for any type of vector coordinates,
407 but they must have the same coordinate system tag
408 */
409 template< class OtherCoords >
411 return X()*v.X() + Y()*v.Y() + Z()*v.Z();
412 }
413 /**
414 Return the scalar (dot) product of two vectors.
415 It is possible to perform the product for any classes
416 implementing x(), y() and z() member functions
417 */
418 template< class OtherVector >
419 Scalar Dot( const OtherVector & v) const {
420 return X()*v.x() + Y()*v.y() + Z()*v.z();
421 }
422
423 /**
424 Return vector (cross) product of two displacement vectors,
425 as a vector in the coordinate system of this class.
426 It is possible to perform the product for any type of vector coordinates,
427 but they must have the same coordinate system tag
428 */
429 template <class OtherCoords>
432 result.SetXYZ ( Y()*v.Z() - v.Y()*Z(),
433 Z()*v.X() - v.Z()*X(),
434 X()*v.Y() - v.X()*Y() );
435 return result;
436 }
437 /**
438 Return vector (cross) product of two vectors,
439 as a vector in the coordinate system of this class.
440 It is possible to perform the product for any classes
441 implementing X(), Y() and Z() member functions
442 */
443 template <class OtherVector>
444 DisplacementVector3D Cross( const OtherVector & v) const {
446 result.SetXYZ ( Y()*v.z() - v.y()*Z(),
447 Z()*v.x() - v.z()*X(),
448 X()*v.y() - v.x()*Y() );
449 return result;
450 }
451
452
453
454 /**
455 Self Addition with a displacement vector.
456 */
457 template <class OtherCoords>
460 SetXYZ( X() + v.X(), Y() + v.Y(), Z() + v.Z() );
461 return *this;
462 }
463
464 /**
465 Self Difference with a displacement vector.
466 */
467 template <class OtherCoords>
470 SetXYZ( x() - v.x(), y() - v.y(), z() - v.z() );
471 return *this;
472 }
473
474
475 /**
476 multiply this vector by a scalar quantity
477 */
479 fCoordinates.Scale(a);
480 return *this;
481 }
482
483 /**
484 divide this vector by a scalar quantity
485 */
487 fCoordinates.Scale(1/a);
488 return *this;
489 }
490
491 // The following methods (v*a and v/a) could instead be free functions.
492 // They were moved into the class to solve a problem on AIX.
493
494 /**
495 Multiply a vector by a real number
496 */
498 DisplacementVector3D tmp(*this);
499 tmp *= a;
500 return tmp;
501 }
502
503 /**
504 Negative of the vector
505 */
507 return operator*( Scalar(-1) );
508 }
509
510 /**
511 Positive of the vector, return itself
512 */
513 DisplacementVector3D operator + ( ) const {return *this;}
514
515 /**
516 Division of a vector with a real number
517 */
519 DisplacementVector3D tmp(*this);
520 tmp /= a;
521 return tmp;
522 }
523
524
525 // Methods providing limited backward name compatibility with CLHEP
526
527 Scalar x() const { return fCoordinates.X(); }
528 Scalar y() const { return fCoordinates.Y(); }
529 Scalar z() const { return fCoordinates.Z(); }
530 Scalar r() const { return fCoordinates.R(); }
531 Scalar theta() const { return fCoordinates.Theta(); }
532 Scalar phi() const { return fCoordinates.Phi(); }
533 Scalar eta() const { return fCoordinates.Eta(); }
534 Scalar rho() const { return fCoordinates.Rho(); }
535 Scalar mag2() const { return fCoordinates.Mag2(); }
536 Scalar perp2() const { return fCoordinates.Perp2(); }
537 DisplacementVector3D unit() const {return Unit();}
538
539
540 private:
541
542 CoordSystem fCoordinates; // internal coordinate system
543
544#ifdef NOT_SURE_THIS_SHOULD_BE_FORBIDDEN
545 /**
546 Cross product involving a position vector is inappropriate
547 */
548 template <class T2>
550#endif
551
552 // the following methods should not compile
553
554 // this should not compile (if from a vector or points with different tag
555 template <class OtherCoords, class OtherTag>
557
558 template <class OtherCoords, class OtherTag>
560
561 template <class OtherCoords, class OtherTag>
563
564
565 template <class OtherCoords, class OtherTag>
567
568 template <class OtherCoords, class OtherTag>
570
571 template <class OtherCoords, class OtherTag>
573
574 template<class OtherCoords, class OtherTag >
576
577 template<class OtherCoords, class OtherTag >
579
580
581 };
582
583// ---------- DisplacementVector3D class template ends here ------------
584// ---------------------------------------------------------------------
585
586
587
588 /**
589 Addition of DisplacementVector3D vectors.
590 The (coordinate system) type of the returned vector is defined to
591 be identical to that of the first vector, which is passed by value
592 */
593 template <class CoordSystem1, class CoordSystem2, class U>
594 inline
598 return v1 += v2;
599 }
600
601 /**
602 Difference between two DisplacementVector3D vectors.
603 The (coordinate system) type of the returned vector is defined to
604 be identical to that of the first vector.
605 */
606 template <class CoordSystem1, class CoordSystem2, class U>
607 inline
608 DisplacementVector3D<CoordSystem1,U>
611 return v1 -= v2;
612 }
613
614 //#endif // not __CINT__
615
616 /**
617 Multiplication of a displacement vector by real number a*v
618 */
619 template <class CoordSystem, class U>
620 inline
621 DisplacementVector3D<CoordSystem,U>
624 return v *= a;
625 // Note - passing v by value and using operator *= may save one
626 // copy relative to passing v by const ref and creating a temporary.
627 }
628
629
630 // v1*v2 notation for Cross product of two vectors is omitted,
631 // since it is always confusing as to whether dot product is meant.
632
633
634
635 // ------------- I/O to/from streams -------------
636
637 template <class char_t, class traits_t, class T, class U,
639 nullptr>
640 std::basic_ostream<char_t, traits_t> &operator<<(std::basic_ostream<char_t, traits_t> &os,
641 DisplacementVector3D<T, U> const &v)
642 {
643 if (os) {
644
645 typename T::Scalar a, b, c;
646 v.GetCoordinates(a, b, c);
647
650 typedef GenVector_detail::BitReproducible BR;
651 BR::Output(os, a);
652 BR::Output(os, b);
653 BR::Output(os, c);
654 } else {
657 }
658 }
659 return os;
660 } // op<< <>()
661
662 template <class char_t, class traits_t, class T, class U,
664 nullptr>
665 std::basic_ostream<char_t, traits_t> &operator<<(std::basic_ostream<char_t, traits_t> &os,
666 DisplacementVector3D<T, U> const &v)
667 {
668 if (os) {
669 os << "{ ";
670 for (std::size_t i = 0; i < PositionVector3D<T, U>::Scalar::Size; ++i) {
671 os << "(" << v.x()[i] << "," << v.y()[i] << "," << v.z()[i] << ") ";
672 }
673 os << "}";
674 }
675 return os;
676 } // op<< <>()
677
678 template< class char_t, class traits_t, class T, class U >
679 inline
680 std::basic_istream<char_t,traits_t> &
681 operator >> ( std::basic_istream<char_t,traits_t> & is
683 )
684 {
685 if( !is ) return is;
686
687 typename T::Scalar a, b, c;
688
692 BR::Input(is, a);
693 BR::Input(is, b);
694 BR::Input(is, c);
695 }
696 else {
698 detail::require_delim( is, detail::sep ); is >> b;
699 detail::require_delim( is, detail::sep ); is >> c;
701 }
702
703 if( is )
704 v.SetCoordinates(a, b, c);
705 return is;
706
707 } // op>> <>()
708
709
710
711 } // namespace Math
712
713} // namespace ROOT
714
715
716#endif /* ROOT_Math_GenVector_DisplacementVector3D */
717
SVector< double, 2 > v
Definition: Dict.h:5
#define b(i)
Definition: RSha256.hxx:100
#define c(i)
Definition: RSha256.hxx:101
int type
Definition: TGX11.cxx:120
Class describing a 3D cartesian coordinate system (x, y, z coordinates)
Definition: Cartesian3D.h:44
Class describing a generic displacement vector in 3 dimensions.
DisplacementVector3D< CoordSystem, Tag > & SetCoordinates(IT begin, IT end)
Set internal data based on 3 Scalars at *begin to *end.
Scalar Theta() const
Polar theta, converting if necessary from internal coordinate system.
DisplacementVector3D & operator-=(const DisplacementVector3D< OtherCoords, OtherTag > &)
CoordSystem Coordinates() const
Retrieve a copy of the coordinates object.
DisplacementVector3D< CoordSystem, Tag > & SetRho(Scalar rr)
Change Rho - CylindricalEta3D coordinates only.
DisplacementVector3D & operator=(const DisplacementVector3D< OtherCoords, Tag > &v)
Assignment operator from a displacement vector of arbitrary type.
DisplacementVector3D & operator+=(const DisplacementVector3D< OtherCoords, OtherTag > &)
DisplacementVector3D< CoordSystem, Tag > & SetEta(Scalar etaval)
Change Eta - CylindricalEta3D coordinates only.
Scalar R() const
Polar R, converting if necessary from internal coordinate system.
DisplacementVector3D & operator/=(Scalar a)
divide this vector by a scalar quantity
DisplacementVector3D< CoordSystem, Tag > & SetPhi(Scalar ang)
Change Phi - Polar3D or CylindricalEta3D coordinates.
DisplacementVector3D< CoordSystem, Tag > & SetR(Scalar rr)
Change R - Polar3D coordinates only.
DisplacementVector3D Cross(const OtherVector &v) const
Return vector (cross) product of two vectors, as a vector in the coordinate system of this class.
DisplacementVector3D Unit() const
return unit vector parallel to this (scalar)
DisplacementVector3D operator+() const
Positive of the vector, return itself.
DisplacementVector3D operator-() const
Negative of the vector.
DisplacementVector3D< CoordSystem, Tag > & SetCoordinates(Scalar a, Scalar b, Scalar c)
Set internal data based on 3 Scalar numbers.
DisplacementVector3D< CoordSystem, Tag > & SetY(Scalar yy)
Change Y - Cartesian3D coordinates only.
Scalar X() const
Cartesian X, converting if necessary from internal coordinate system.
DisplacementVector3D< CoordSystem, Tag > & SetZ(Scalar zz)
Change Z - Cartesian3D coordinates only.
void GetCoordinates(Scalar dest[]) const
get internal data into a C-style array of 3 Scalar numbers
DisplacementVector3D(const PositionVector3D< OtherCoords, OtherTag > &)
void GetCoordinates(Scalar &a, Scalar &b, Scalar &c) const
get internal data into 3 Scalar numbers
void GetCoordinates(IT begin) const
get internal data into 3 Scalars starting at *begin
Scalar Y() const
Cartesian Y, converting if necessary from internal coordinate system.
DisplacementVector3D(const PositionVector3D< OtherCoords, Tag > &p)
Construct from a position vector expressed in different coordinates but with the same coordinate syst...
Scalar Dot(const OtherVector &v) const
Return the scalar (dot) product of two vectors.
DisplacementVector3D Cross(const DisplacementVector3D< OtherCoords, Tag > &v) const
Return vector (cross) product of two displacement vectors, as a vector in the coordinate system of th...
DisplacementVector3D< CoordSystem, Tag > & SetTheta(Scalar ang)
Change Theta - Polar3D coordinates only.
DisplacementVector3D operator*(Scalar a) const
Multiply a vector by a real number.
bool operator==(const DisplacementVector3D &rhs) const
Exact equality.
Scalar Rho() const
Cylindrical transverse component rho.
DisplacementVector3D Cross(const DisplacementVector3D< OtherCoords, OtherTag > &) const
bool operator!=(const DisplacementVector3D &rhs) const
DisplacementVector3D unit() const
DisplacementVector3D()
Default constructor.
DisplacementVector3D< CoordSystem, Tag > & SetCoordinates(const Scalar src[])
Set internal data based on a C-style array of 3 Scalar numbers.
DisplacementVector3D(Scalar a, Scalar b, Scalar c)
Construct from three values of type Scalar.
DisplacementVector3D(const ForeignVector &v)
Construct from a foreign 3D vector type, for example, Hep3Vector Precondition: v must implement metho...
DisplacementVector3D & operator=(const PositionVector3D< OtherCoords, OtherTag > &)
Scalar Dot(const DisplacementVector3D< OtherCoords, OtherTag > &) const
Scalar Phi() const
Polar phi, converting if necessary from internal coordinate system.
DisplacementVector3D< CoordSystem, Tag > & SetX(Scalar xx)
Change X - Cartesian3D coordinates only.
Scalar Mag2() const
Magnitute squared ( r^2 in spherical coordinate)
DisplacementVector3D< CoordSystem, Tag > & SetXYZ(Scalar a, Scalar b, Scalar c)
set the values of the vector from the cartesian components (x,y,z) (if the vector is held in polar or...
Scalar Perp2() const
Transverse component squared (rho^2 in cylindrical coordinates.
DisplacementVector3D & operator*=(Scalar a)
multiply this vector by a scalar quantity
DisplacementVector3D operator/(Scalar a) const
Division of a vector with a real number.
Scalar Eta() const
Polar eta, converting if necessary from internal coordinate system.
Scalar Z() const
Cartesian Z, converting if necessary from internal coordinate system.
DisplacementVector3D(const DisplacementVector3D< OtherCoords, Tag > &v)
Construct from a displacement vector expressed in different coordinates, or using a different Scalar ...
void GetCoordinates(IT begin, IT end) const
get internal data into 3 Scalars at *begin to *end (3 past begin)
DisplacementVector3D(const DisplacementVector3D< OtherCoords, OtherTag > &)
Scalar Dot(const DisplacementVector3D< OtherCoords, Tag > &v) const
Return the scalar (dot) product of two displacement vectors.
DisplacementVector3D & operator=(const DisplacementVector3D< OtherCoords, OtherTag > &)
Class describing a generic position vector (point) in 3 dimensions.
Namespace for new Math classes and functions.
double T(double x)
Definition: ChebyshevPol.h:34
char_t get_manip(std::basic_ios< char_t, traits_t > &ios, manip_t m)
Definition: GenVectorIO.h:54
std::basic_istream< char_t, traits_t > & require_delim(std::basic_istream< char_t, traits_t > &is, manip_t m)
Definition: GenVectorIO.h:113
void set_manip(std::basic_ios< char_t, traits_t > &ios, manip_t m, char_t ch)
Definition: GenVectorIO.h:74
std::ostream & operator<<(std::ostream &os, const AxisAngle &a)
Stream Output and Input.
Definition: AxisAngle.cxx:91
std::basic_istream< char_t, traits_t > & operator>>(std::basic_istream< char_t, traits_t > &is, DisplacementVector2D< T, U > &v)
DisplacementVector2D< CoordSystem1, U > operator+(DisplacementVector2D< CoordSystem1, U > v1, const DisplacementVector2D< CoordSystem2, U > &v2)
Addition of DisplacementVector2D vectors.
DisplacementVector2D< CoordSystem1, U > operator-(DisplacementVector2D< CoordSystem1, U > v1, DisplacementVector2D< CoordSystem2, U > const &v2)
Difference between two DisplacementVector2D vectors.
AxisAngle operator*(RotationX const &r1, AxisAngle const &r2)
Multiplication of an axial rotation by an AxisAngle.
Rotation3D::Scalar Scalar
Namespace for new ROOT classes and functions.
Definition: StringConv.hxx:21
const char * Size
Definition: TXMLSetup.cxx:55
auto * a
Definition: textangle.C:12
#define dest(otri, vertexptr)
Definition: triangle.c:1040