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oldBasic3DVector.h
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1 #ifndef GeometryVector_oldBasic3DVector_h
2 #define GeometryVector_oldBasic3DVector_h
3 #if ( defined(IN_DICTBUILD) || defined(__CINT__) ) && !defined(__REFLEX__)
4 #define __REFLEX__
5 #endif
11 #ifndef __REFLEX__
13 #endif
14 #include <iosfwd>
15 #include <cmath>
16 
17 
18 namespace detailsBasic3DVector {
19  inline float __attribute__((always_inline)) __attribute__ ((pure))
20  eta(float x, float y, float z) { float t(z/std::sqrt(x*x+y*y)); return ::asinhf(t);}
21  inline double __attribute__((always_inline)) __attribute__ ((pure))
22  eta(double x, double y, double z) { double t(z/std::sqrt(x*x+y*y)); return ::asinh(t);}
23  inline long double __attribute__((always_inline)) __attribute__ ((pure))
24  eta(long double x, long double y, long double z) { long double t(z/std::sqrt(x*x+y*y)); return ::asinhl(t);}
25 }
26 
27 
28 template < typename T>
29 class Basic3DVector {
30 public:
32 
33 
34  typedef T ScalarType;
37  typedef Spherical Polar; // synonym
38 
43  Basic3DVector() : theX(0), theY(0), theZ(0), theW(0) {}
44 
47  theX(p.x()), theY(p.y()), theZ(p.z()), theW(p.w()) {}
48 
50  template <class U>
52  theX(p.x()), theY(p.y()), theZ(p.z()), theW(p.w()) {}
53 
56  theX(p.x()), theY(p.y()), theZ(0), theW(0) {}
57 
66  template <class OtherPoint>
67  explicit Basic3DVector( const OtherPoint& p) :
68  theX(p.x()), theY(p.y()), theZ(p.z()), theW(0) {}
69 
70 
71 #if defined(USE_EXTVECT)
72  template<typename U>
73  Basic3DVector(Vec4<U> const& iv) :
74  theX(iv[0]), theY(iv[1]), theZ(iv[2]), theW(0) {}
75 #elif defined(USE_SSEVECT)
76  // constructor from Vec4
77  template<typename U>
78  Basic3DVector(mathSSE::Vec4<U> const& iv) :
79  theX(iv.arr[0]), theY(iv.arr[1]), theZ(iv.arr[2]), theW(0) {}
80 #endif
81 
82 #ifndef __REFLEX__
83  Basic3DVector( const T& x, const T& y, const T& z, const T& w=0) :
85  theX(x), theY(y), theZ(z), theW(w) {}
86 #else
87  Basic3DVector( const T& x, const T& y, const T& z) :
89  theX(x), theY(y), theZ(z), theW(0) {}
90  Basic3DVector( const T& x, const T& y, const T& z, const T& w) :
91  theX(x), theY(y), theZ(z), theW(w) {}
92 #endif
93 
94 
95 
100  template <typename U>
102  const Geom::Phi<U>& phi, const T& r) {
103  Polar p( theta.value(), phi.value(), r);
104  theX = p.x(); theY = p.y(); theZ = p.z();
105  }
106 
107 
108  T operator[](int i) const { return *((&theX)+i) ;}
109  T & operator[](int i) { return *((&theX)+i);}
110 
111 
112 
114  T x() const { return theX;}
115 
117  T y() const { return theY;}
118 
120  T z() const { return theZ;}
121 
122  T w() const { return theW;}
123 
124 
126 
127 
128  // equality
129  bool operator==(const Basic3DVector& rh) const {
130  return x()==rh.x() && y()==rh.y() && z()==rh.z();
131  }
132 
134  T mag2() const { return x()*x() + y()*y()+z()*z();}
135 
137  T mag() const { return std::sqrt( mag2());}
138 
140  T perp2() const { return x()*x() + y()*y();}
141 
143  T perp() const { return std::sqrt( perp2());}
144 
146  T transverse() const { return perp();}
147 
152  T barePhi() const {return std::atan2(y(),x());}
153  Geom::Phi<T> phi() const {return Geom::Phi<T>(barePhi());}
154 
159  T bareTheta() const {return std::atan2(perp(),z());}
160  Geom::Theta<T> theta() const {return Geom::Theta<T>(std::atan2(perp(),z()));}
161 
166  // T eta() const { return -log( tan( theta()/2.));}
167  T eta() const { return detailsBasic3DVector::eta(x(),y(),z());} // correct
168 
172  Basic3DVector unit() const {
173  T my_mag = mag2();
174  if (my_mag==0) return *this;
175  my_mag = T(1)/std::sqrt(my_mag);
176  return *this * my_mag;
177  }
181  template <class U>
183  theX += p.x();
184  theY += p.y();
185  theZ += p.z();
186  theW += p.w();
187  return *this;
188  }
189 
192  template <class U>
194  theX -= p.x();
195  theY -= p.y();
196  theZ -= p.z();
197  theW -= p.w();
198  return *this;
199  }
200 
202  Basic3DVector operator-() const { return Basic3DVector(-x(),-y(),-z());}
203 
206  theX *= t;
207  theY *= t;
208  theZ *= t;
209  theW *= t;;
210  return *this;
211  }
212 
215  t = T(1)/t;
216  theX *= t;
217  theY *= t;
218  theZ *= t;
219  theW *= t;;
220  return *this;
221  }
222 
224  T dot( const Basic3DVector& v) const {
225  return x()*v.x() + y()*v.y() + z()*v.z();
226  }
227 
233  template <class U>
235  return x()*v.x() + y()*v.y() + z()*v.z();
236  }
237 
240  return Basic3DVector( y()*v.z() - v.y()*z(),
241  z()*v.x() - v.z()*x(),
242  x()*v.y() - v.x()*y());
243  }
244 
251  template <class U>
253  cross( const Basic3DVector<U>& v) const {
254  return Basic3DVector<typename PreciseFloatType<T,U>::Type>( y()*v.z() - v.y()*z(),
255  z()*v.x() - v.z()*x(),
256  x()*v.y() - v.x()*y());
257  }
259 private:
264 }
265 #ifndef __CINT__
266 __attribute__ ((aligned (16)))
267 #endif
268 ;
270 
271 namespace geometryDetails {
272  std::ostream & print3D(std::ostream& s, double x, double y, double z);
273 }
274 
276 template <class T>
277 inline std::ostream & operator<<( std::ostream& s, const Basic3DVector<T>& v) {
278  return geometryDetails::print3D(s, v.x(),v.y(), v.z());
279 }
280 
283 template <class T, class U>
287  return RT(a.x()+b.x(), a.y()+b.y(), a.z()+b.z(), a.w()+b.w());
288 }
289 
290 template <class T, class U>
294  return RT(a.x()-b.x(), a.y()-b.y(), a.z()-b.z(), a.w()-b.w());
295 }
298 template <class T>
299 inline T operator*( const Basic3DVector<T>& v1, const Basic3DVector<T>& v2) {
300  return v1.dot(v2);
301 }
302 
304 template <class T, class U>
306  const Basic3DVector<U>& v2) {
307  return v1.x()*v2.x() + v1.y()*v2.y() + v1.z()*v2.z();
308 }
309 
313 template <class T>
315  return Basic3DVector<T>(v.x()*t, v.y()*t, v.z()*t, v.w()*t);
316 }
317 
319 template <class T>
321  return Basic3DVector<T>(v.x()*t, v.y()*t, v.z()*t, v.w()*t);
322 }
323 
324 template <class T, typename S>
326  return static_cast<T>(t)*v;
327 }
328 
329 template <class T, typename S>
331  return static_cast<T>(t)*v;
332 }
333 
334 
338 template <class T, typename S>
340  T t = T(1)/s;
341  return v*t;
342 }
343 
344 
348 
350 #endif // GeometryVector_Basic3DVector_h
351 
352 
Basic3DVector< typename PreciseFloatType< T, U >::Type > cross(const Basic3DVector< U > &v) const
tuple t
Definition: tree.py:139
int i
Definition: DBlmapReader.cc:9
Basic2DVector< T > xy() const
T y() const
Cartesian y coordinate.
T x() const
Cartesian x coordinate.
T mag() const
The vector magnitude. Equivalent to sqrt(vec.mag2())
T & operator[](int i)
ExtVec< T, 4 > Vec4
Definition: ExtVec.h:74
PreciseFloatType< T, U >::Type dot(const Basic3DVector< U > &v) const
MatrixMeschach operator+(const MatrixMeschach &mat1, const MatrixMeschach &mat2)
T perp2() const
Squared magnitude of transverse component.
Geom::Theta< T > theta() const
T barePhi() const
Basic3DVector unit() const
MatrixMeschach operator-(const MatrixMeschach &mat1, const MatrixMeschach &mat2)
bool operator==(const Basic3DVector &rh) const
Basic3DVector(const Basic3DVector &p)
Copy constructor from same type. Should not be needed but for gcc bug 12685.
Geom::Phi< T > phi() const
float float float z
Basic3DVector< long double > operator/(const Basic3DVector< long double > &v, S s)
Basic3DVector & operator/=(T t)
Scaling by a scalar value (division)
Basic3DVector(const Geom::Theta< U > &theta, const Geom::Phi< U > &phi, const T &r)
T z() const
Cartesian z coordinate.
T sqrt(T t)
Definition: SSEVec.h:48
Basic3DVector & operator*=(T t)
Scaling by a scalar value (multiplication)
Basic3DVector & operator+=(const Basic3DVector< U > &p)
Basic3DVector< T > MathVector
T perp() const
Magnitude of transverse component.
Basic3DVector & operator-=(const Basic3DVector< U > &p)
Basic3DVector< long double > Basic3DVectorLD
T operator[](int i) const
T value() const
Explicit access to value in case implicit conversion not OK.
Definition: Theta.h:25
T value() const
Explicit access to value in case implicit conversion not OK.
Definition: Phi.h:38
Basic3DVector(const Basic3DVector< U > &p)
Copy constructor and implicit conversion from Basic3DVector of different precision.
Basic3DVector(const Basic2DVector< T > &p)
constructor from 2D vector (X and Y from 2D vector, z set to zero)
Basic3DVector< double > Basic3DVectorD
float __attribute__((vector_size(8))) float32x2_t
Definition: ExtVec.h:12
Geom::Spherical2Cartesian< T > Spherical
double b
Definition: hdecay.h:120
double S(const TLorentzVector &, const TLorentzVector &)
Definition: Particle.cc:99
Geom::Cylindrical2Cartesian< T > Cylindrical
T dot(const Basic3DVector &v) const
Scalar product, or &quot;dot&quot; product, with a vector of same type.
float __attribute__((always_inline)) __attribute__((pure)) eta(float x
double a
Definition: hdecay.h:121
T transverse() const
Another name for perp()
T bareTheta() const
Basic3DVector cross(const Basic3DVector &v) const
Vector product, or &quot;cross&quot; product, with a vector of same type.
Basic3DVector< float > Basic3DVectorF
MatrixMeschach operator*(const MatrixMeschach &mat1, const MatrixMeschach &mat2)
std::ostream & print3D(std::ostream &s, double x, double y, double z)
Definition: print.cc:5
Basic3DVector operator-() const
Unary minus, returns a vector with components (-x(),-y(),-z())
long double T
Basic3DVector(const OtherPoint &p)
Definition: Phi.h:20
T mag2() const
The vector magnitude squared. Equivalent to vec.dot(vec)
T dot(const Basic3DVector &rh) const
Scalar product, or &quot;dot&quot; product, with a vector of same type.