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Geant4/externals/clhep/src/ThreeVector.cc

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Differences between /externals/clhep/src/ThreeVector.cc (Version 11.3.0) and /externals/clhep/src/ThreeVector.cc (Version 10.1.p3)


  1 // -*- C++ -*-                                      1 // -*- C++ -*-
                                                   >>   2 // $Id:$
  2 // -------------------------------------------      3 // ---------------------------------------------------------------------------
  3 //                                                  4 //
  4 // This file is a part of the CLHEP - a Class       5 // This file is a part of the CLHEP - a Class Library for High Energy Physics.
  5 //                                                  6 //
  6 // This is the implementation of the Hep3Vecto      7 // This is the implementation of the Hep3Vector class.
  7 //                                                  8 //
  8 // See also ThreeVectorR.cc for implementation      9 // See also ThreeVectorR.cc for implementation of Hep3Vector methods which 
  9 // would couple in all the HepRotation methods     10 // would couple in all the HepRotation methods.
 10 //                                                 11 //
 11                                                    12 
                                                   >>  13 #ifdef GNUPRAGMA
                                                   >>  14 #pragma implementation
                                                   >>  15 #endif
                                                   >>  16 
 12 #include "CLHEP/Vector/ThreeVector.h"              17 #include "CLHEP/Vector/ThreeVector.h"
 13 #include "CLHEP/Units/PhysicalConstants.h"         18 #include "CLHEP/Units/PhysicalConstants.h"
 14                                                    19 
 15 #include <cmath>                                   20 #include <cmath>
 16 #include <iostream>                                21 #include <iostream>
 17                                                    22 
 18 namespace CLHEP  {                                 23 namespace CLHEP  {
 19                                                    24 
 20 void Hep3Vector::setMag(double ma) {               25 void Hep3Vector::setMag(double ma) {
 21   double factor = mag();                           26   double factor = mag();
 22   if (factor == 0) {                               27   if (factor == 0) {
 23     std::cerr << "Hep3Vector::setMag() - "         28     std::cerr << "Hep3Vector::setMag() - "
 24               << "zero vector can't be stretch     29               << "zero vector can't be stretched" << std::endl;
 25   }else{                                           30   }else{
 26     factor = ma/factor;                            31     factor = ma/factor;
 27     setX(x()*factor);                              32     setX(x()*factor);
 28     setY(y()*factor);                              33     setY(y()*factor);
 29     setZ(z()*factor);                              34     setZ(z()*factor);
 30   }                                                35   }
 31 }                                                  36 }
 32                                                    37 
 33 Hep3Vector & Hep3Vector::rotateUz(const Hep3Ve     38 Hep3Vector & Hep3Vector::rotateUz(const Hep3Vector& NewUzVector) {
 34   // NewUzVector must be normalized !              39   // NewUzVector must be normalized !
 35                                                    40 
 36   double u1 = NewUzVector.x();                     41   double u1 = NewUzVector.x();
 37   double u2 = NewUzVector.y();                     42   double u2 = NewUzVector.y();
 38   double u3 = NewUzVector.z();                     43   double u3 = NewUzVector.z();
 39   double up = u1*u1 + u2*u2;                       44   double up = u1*u1 + u2*u2;
 40                                                    45 
 41   if (up > 0) {                                <<  46   if (up>0) {
 42     up = std::sqrt(up);                        <<  47       up = std::sqrt(up);
 43     double px = (u1 * u3 * x() - u2 * y()) / u <<  48       double px = dx,  py = dy,  pz = dz;
 44     double py = (u2 * u3 * x() + u1 * y()) / u <<  49       dx = (u1*u3*px - u2*py)/up + u1*pz;
 45     double pz = -up * x() + u3 * z();          <<  50       dy = (u2*u3*px + u1*py)/up + u2*pz;
 46     set(px, py, pz);                           <<  51       dz =    -up*px +             u3*pz;
 47   } else if (u3 < 0.) {                        <<  52     }
 48     setX(-x());                                <<  53   else if (u3 < 0.) { dx = -dx; dz = -dz; }      // phi=0  teta=pi
 49     setZ(-z());                                <<  54   else {};
 50   } // phi=0  teta=pi                          << 
 51                                                << 
 52   return *this;                                    55   return *this;
 53 }                                                  56 }
 54                                                    57 
 55 double Hep3Vector::pseudoRapidity() const {        58 double Hep3Vector::pseudoRapidity() const {
 56   double m1 = mag();                               59   double m1 = mag();
 57   if ( m1==  0   ) return  0.0;                    60   if ( m1==  0   ) return  0.0;   
 58   if ( m1==  z() ) return  1.0E72;                 61   if ( m1==  z() ) return  1.0E72;
 59   if ( m1== -z() ) return -1.0E72;                 62   if ( m1== -z() ) return -1.0E72;
 60   return 0.5*std::log( (m1+z())/(m1-z()) );        63   return 0.5*std::log( (m1+z())/(m1-z()) );
 61 }                                                  64 }
 62                                                    65 
 63 std::ostream & operator<< (std::ostream & os,      66 std::ostream & operator<< (std::ostream & os, const Hep3Vector & v) {
 64   return os << "(" << v.x() << "," << v.y() <<     67   return os << "(" << v.x() << "," << v.y() << "," << v.z() << ")";
 65 }                                                  68 }
 66                                                    69 
 67 void ZMinput3doubles ( std::istream & is, cons     70 void ZMinput3doubles ( std::istream & is, const char * type,
 68                        double & x, double & y,     71                        double & x, double & y, double & z );
 69                                                    72 
 70 std::istream & operator>>(std::istream & is, H     73 std::istream & operator>>(std::istream & is, Hep3Vector & v) {
 71   double x, y, z;                                  74   double x, y, z;
 72   ZMinput3doubles ( is, "Hep3Vector", x, y, z      75   ZMinput3doubles ( is, "Hep3Vector", x, y, z );
 73   v.set(x, y, z);                                  76   v.set(x, y, z);
 74   return  is;                                      77   return  is;
 75 }  // operator>>()                                 78 }  // operator>>()
 76                                                    79 
 77 const Hep3Vector HepXHat(1.0, 0.0, 0.0);           80 const Hep3Vector HepXHat(1.0, 0.0, 0.0);
 78 const Hep3Vector HepYHat(0.0, 1.0, 0.0);           81 const Hep3Vector HepYHat(0.0, 1.0, 0.0);
 79 const Hep3Vector HepZHat(0.0, 0.0, 1.0);           82 const Hep3Vector HepZHat(0.0, 0.0, 1.0);
 80                                                    83 
 81 //-------------------                              84 //-------------------
 82 //                                                 85 //
 83 // New methods introduced when ZOOM PhysicsVec     86 // New methods introduced when ZOOM PhysicsVectors was merged in:
 84 //                                                 87 //
 85 //-------------------                              88 //-------------------
 86                                                    89 
 87 Hep3Vector & Hep3Vector::rotateX (double phi1)     90 Hep3Vector & Hep3Vector::rotateX (double phi1) {
 88   double sinphi = std::sin(phi1);                  91   double sinphi = std::sin(phi1);
 89   double cosphi = std::cos(phi1);                  92   double cosphi = std::cos(phi1);
 90   double ty = y() * cosphi - z() * sinphi;     <<  93   double ty;
 91   double tz = z() * cosphi + y() * sinphi;     <<  94   ty = dy * cosphi - dz * sinphi;
 92   setY(ty);                                    <<  95   dz = dz * cosphi + dy * sinphi;
 93   setZ(tz);                                    <<  96   dy = ty;
 94   return *this;                                    97   return *this;
 95 } /* rotateX */                                    98 } /* rotateX */
 96                                                    99 
 97 Hep3Vector & Hep3Vector::rotateY (double phi1)    100 Hep3Vector & Hep3Vector::rotateY (double phi1) {
 98   double sinphi = std::sin(phi1);                 101   double sinphi = std::sin(phi1);
 99   double cosphi = std::cos(phi1);                 102   double cosphi = std::cos(phi1);
100   double tx = x() * cosphi + z() * sinphi;     << 103   double tz;
101   double tz = z() * cosphi - x() * sinphi;     << 104   tz = dz * cosphi - dx * sinphi;
102   setX(tx);                                    << 105   dx = dx * cosphi + dz * sinphi;
103   setZ(tz);                                    << 106   dz = tz;
104   return *this;                                   107   return *this;
105 } /* rotateY */                                   108 } /* rotateY */
106                                                   109 
107 Hep3Vector & Hep3Vector::rotateZ (double phi1)    110 Hep3Vector & Hep3Vector::rotateZ (double phi1) {
108   double sinphi = std::sin(phi1);                 111   double sinphi = std::sin(phi1);
109   double cosphi = std::cos(phi1);                 112   double cosphi = std::cos(phi1);
110   double tx = x() * cosphi - y() * sinphi;     << 113   double tx;
111   double ty = y() * cosphi + x() * sinphi;     << 114   tx = dx * cosphi - dy * sinphi;
112   setX(tx);                                    << 115   dy = dy * cosphi + dx * sinphi;
113   setY(ty);                                    << 116   dx = tx;
114   return *this;                                   117   return *this;
115 } /* rotateZ */                                   118 } /* rotateZ */
116                                                   119 
117 bool Hep3Vector::isNear(const Hep3Vector & v,     120 bool Hep3Vector::isNear(const Hep3Vector & v, double epsilon) const {
118   double limit = dot(v)*epsilon*epsilon;          121   double limit = dot(v)*epsilon*epsilon;
119   return ( (*this - v).mag2() <= limit );         122   return ( (*this - v).mag2() <= limit );
120 } /* isNear() */                                  123 } /* isNear() */
121                                                   124 
122 double Hep3Vector::howNear(const Hep3Vector &     125 double Hep3Vector::howNear(const Hep3Vector & v ) const {
123   // | V1 - V2 | **2  / V1 dot V2, up to 1        126   // | V1 - V2 | **2  / V1 dot V2, up to 1
124   double d   = (*this - v).mag2();                127   double d   = (*this - v).mag2();
125   double vdv = dot(v);                            128   double vdv = dot(v);
126   if ( (vdv > 0) && (d < vdv)  ) {                129   if ( (vdv > 0) && (d < vdv)  ) {
127     return std::sqrt (d/vdv);                     130     return std::sqrt (d/vdv);
128   } else if ( (vdv == 0) && (d == 0) ) {          131   } else if ( (vdv == 0) && (d == 0) ) {
129     return 0;                                     132     return 0;
130   } else {                                        133   } else {
131     return 1;                                     134     return 1;
132   }                                               135   }
133 } /* howNear */                                   136 } /* howNear */
134                                                   137 
135 double Hep3Vector::deltaPhi  (const Hep3Vector    138 double Hep3Vector::deltaPhi  (const Hep3Vector & v2) const {
136   double dphi = v2.getPhi() - getPhi();           139   double dphi = v2.getPhi() - getPhi();
137   if ( dphi > CLHEP::pi ) {                       140   if ( dphi > CLHEP::pi ) {
138     dphi -= CLHEP::twopi;                         141     dphi -= CLHEP::twopi;
139   } else if ( dphi <= -CLHEP::pi ) {              142   } else if ( dphi <= -CLHEP::pi ) {
140     dphi += CLHEP::twopi;                         143     dphi += CLHEP::twopi;
141   }                                               144   }
142   return dphi;                                    145   return dphi;
143 } /* deltaPhi */                                  146 } /* deltaPhi */
144                                                   147 
145 double Hep3Vector::deltaR ( const Hep3Vector &    148 double Hep3Vector::deltaR ( const Hep3Vector & v ) const {
146   double a = eta() - v.eta();                     149   double a = eta() - v.eta();
147   double b = deltaPhi(v);                         150   double b = deltaPhi(v); 
148   return std::sqrt ( a*a + b*b );                 151   return std::sqrt ( a*a + b*b );
149 } /* deltaR */                                    152 } /* deltaR */
150                                                   153 
151 double Hep3Vector::cosTheta(const Hep3Vector &    154 double Hep3Vector::cosTheta(const Hep3Vector & q) const {
152   double arg;                                     155   double arg;
153   double ptot2 = mag2()*q.mag2();                 156   double ptot2 = mag2()*q.mag2();
154   if(ptot2 <= 0) {                                157   if(ptot2 <= 0) {
155     arg = 0.0;                                    158     arg = 0.0;
156   }else{                                          159   }else{
157     arg = dot(q)/std::sqrt(ptot2);                160     arg = dot(q)/std::sqrt(ptot2);
158     if(arg >  1.0) arg =  1.0;                    161     if(arg >  1.0) arg =  1.0;
159     if(arg < -1.0) arg = -1.0;                    162     if(arg < -1.0) arg = -1.0;
160   }                                               163   }
161   return arg;                                     164   return arg;
162 }                                                 165 }
163                                                   166 
164 double Hep3Vector::cos2Theta(const Hep3Vector     167 double Hep3Vector::cos2Theta(const Hep3Vector & q) const {
165   double arg;                                     168   double arg;
166   double ptot2 = mag2();                          169   double ptot2 = mag2();
167   double qtot2 = q.mag2();                        170   double qtot2 = q.mag2();
168   if ( ptot2 == 0 || qtot2 == 0 )  {              171   if ( ptot2 == 0 || qtot2 == 0 )  {
169     arg = 1.0;                                    172     arg = 1.0;
170   }else{                                          173   }else{
171     double pdq = dot(q);                          174     double pdq = dot(q);
172     arg = (pdq/ptot2) * (pdq/qtot2);              175     arg = (pdq/ptot2) * (pdq/qtot2);
173         // More naive methods overflow on vect    176         // More naive methods overflow on vectors which can be squared
174         // but can't be raised to the 4th powe    177         // but can't be raised to the 4th power.
175     if(arg >  1.0) arg =  1.0;                    178     if(arg >  1.0) arg =  1.0;
176  }                                                179  }
177  return arg;                                      180  return arg;
178 }                                                 181 }
179                                                   182 
180 void Hep3Vector::setEta (double eta1) {           183 void Hep3Vector::setEta (double eta1) {
181   double phi1 = 0;                                184   double phi1 = 0;
182   double r1;                                      185   double r1;
183   if ( (x() == 0) && (y() == 0) ) {            << 186   if ( (dx == 0) && (dy == 0) ) {
184     if (z() == 0) {                            << 187     if (dz == 0) {
185       std::cerr << "Hep3Vector::setEta() - "      188       std::cerr << "Hep3Vector::setEta() - "
186                 << "Attempt to set eta of zero    189                 << "Attempt to set eta of zero vector -- vector is unchanged"
187                 << std::endl;                     190                 << std::endl;
188       return;                                     191       return;
189     }                                             192     }
190   std::cerr << "Hep3Vector::setEta() - "          193   std::cerr << "Hep3Vector::setEta() - "
191             << "Attempt to set eta of vector a    194             << "Attempt to set eta of vector along Z axis -- will use phi = 0"
192             << std::endl;                         195             << std::endl;
193     r1 = std::fabs(z());                       << 196     r1 = std::fabs(dz);
194   } else {                                        197   } else {
195     r1 = getR();                                  198     r1 = getR();
196     phi1 = getPhi();                              199     phi1 = getPhi();
197   }                                               200   }
198   double tanHalfTheta = std::exp ( -eta1 );       201   double tanHalfTheta = std::exp ( -eta1 );
199   double cosTheta1 =                              202   double cosTheta1 =
200         (1 - tanHalfTheta*tanHalfTheta) / (1 +    203         (1 - tanHalfTheta*tanHalfTheta) / (1 + tanHalfTheta*tanHalfTheta);
                                                   >> 204   dz = r1 * cosTheta1;
201   double rho1 = r1*std::sqrt(1 - cosTheta1*cos    205   double rho1 = r1*std::sqrt(1 - cosTheta1*cosTheta1);
202   setZ(r1 * cosTheta1);                        << 206   dy = rho1 * std::sin (phi1);
203   setY(rho1 * std::sin (phi1));                << 207   dx = rho1 * std::cos (phi1);
204   setX(rho1 * std::cos (phi1));                << 
205   return;                                         208   return;
206 }                                                 209 }
207                                                   210 
208 void Hep3Vector::setCylTheta (double theta1) {    211 void Hep3Vector::setCylTheta (double theta1) {
209                                                   212 
210   // In cylindrical coords, set theta while ke    213   // In cylindrical coords, set theta while keeping rho and phi fixed
211                                                   214 
212   if ( (x() == 0) && (y() == 0) ) {            << 215   if ( (dx == 0) && (dy == 0) ) {
213     if (z() == 0) {                            << 216     if (dz == 0) {
214       std::cerr << "Hep3Vector::setCylTheta()     217       std::cerr << "Hep3Vector::setCylTheta() - "
215                 << "Attempt to set cylTheta of    218                 << "Attempt to set cylTheta of zero vector -- vector is unchanged"
216                 << std::endl;                     219                 << std::endl;
217       return;                                     220       return;
218     }                                             221     }
219     if (theta1 == 0) {                            222     if (theta1 == 0) {
220       setZ(std::fabs(z()));                    << 223       dz = std::fabs(dz);
221       return;                                     224       return;
222     }                                             225     }
223     if (theta1 == CLHEP::pi) {                    226     if (theta1 == CLHEP::pi) {
224       setZ(-std::fabs(z()));                   << 227       dz = -std::fabs(dz);
225       return;                                     228       return;
226     }                                             229     }
227     std::cerr << "Hep3Vector::setCylTheta() -     230     std::cerr << "Hep3Vector::setCylTheta() - "
228       << "Attempt set cylindrical theta of vec    231       << "Attempt set cylindrical theta of vector along Z axis "
229       << "to a non-trivial value, while keepin    232       << "to a non-trivial value, while keeping rho fixed -- "
230       << "will return zero vector" << std::end    233       << "will return zero vector" << std::endl;
231     setZ(0.0);                                 << 234     dz = 0;
232     return;                                       235     return;
233   }                                               236   }
234   if ( (theta1 < 0) || (theta1 > CLHEP::pi) )     237   if ( (theta1 < 0) || (theta1 > CLHEP::pi) ) {
235     std::cerr << "Hep3Vector::setCylTheta() -     238     std::cerr << "Hep3Vector::setCylTheta() - "
236       << "Setting Cyl theta of a vector based     239       << "Setting Cyl theta of a vector based on a value not in [0, PI]"
237       << std::endl;                               240       << std::endl;
238         // No special return needed if warning    241         // No special return needed if warning is ignored.
239   }                                               242   }
240   double phi1 (getPhi());                         243   double phi1 (getPhi());
241   double rho1 = getRho();                         244   double rho1 = getRho();
242   if ( (theta1 == 0) || (theta1 == CLHEP::pi)     245   if ( (theta1 == 0) || (theta1 == CLHEP::pi) ) {
243     std::cerr << "Hep3Vector::setCylTheta() -     246     std::cerr << "Hep3Vector::setCylTheta() - "
244       << "Attempt to set cylindrical theta to     247       << "Attempt to set cylindrical theta to 0 or PI "
245       << "while keeping rho fixed -- infinite     248       << "while keeping rho fixed -- infinite Z will be computed"
246       << std::endl;                               249       << std::endl;
247       setZ((theta1==0) ? 1.0E72 : -1.0E72);    << 250       dz = (theta1==0) ? 1.0E72 : -1.0E72;
248     return;                                       251     return;
249   }                                               252   }
250   setZ(rho1 / std::tan (theta1));              << 253   dz = rho1 / std::tan (theta1);
251   setY(rho1 * std::sin (phi1));                << 254   dy = rho1 * std::sin (phi1);
252   setX(rho1 * std::cos (phi1));                << 255   dx = rho1 * std::cos (phi1);
253                                                   256 
254 } /* setCylTheta */                               257 } /* setCylTheta */
255                                                   258 
256 void Hep3Vector::setCylEta (double eta1) {        259 void Hep3Vector::setCylEta (double eta1) {
257                                                   260 
258   // In cylindrical coords, set eta while keep    261   // In cylindrical coords, set eta while keeping rho and phi fixed
259                                                   262 
260   double theta1 = 2 * std::atan ( std::exp (-e    263   double theta1 = 2 * std::atan ( std::exp (-eta1) );
261                                                   264 
262         //-| The remaining code is similar to     265         //-| The remaining code is similar to setCylTheta,  The reason for
263         //-| using a copy is so as to be able     266         //-| using a copy is so as to be able to change the messages in the
264         //-| ZMthrows to say eta rather than t    267         //-| ZMthrows to say eta rather than theta.  Besides, we assumedly
265         //-| need not check for theta of 0 or     268         //-| need not check for theta of 0 or PI.
266                                                   269 
267   if ( (x() == 0) && (y() == 0) ) {            << 270   if ( (dx == 0) && (dy == 0) ) {
268     if (z() == 0) {                            << 271     if (dz == 0) {
269       std::cerr << "Hep3Vector::setCylEta() -     272       std::cerr << "Hep3Vector::setCylEta() - "
270         << "Attempt to set cylEta of zero vect    273         << "Attempt to set cylEta of zero vector -- vector is unchanged"
271         << std::endl;                             274         << std::endl;
272       return;                                     275       return;
273     }                                             276     }
274     if (theta1 == 0) {                            277     if (theta1 == 0) {
275       setZ(std::fabs(z()));                    << 278       dz = std::fabs(dz);
276       return;                                     279       return;
277     }                                             280     }
278     if (theta1 == CLHEP::pi) {                    281     if (theta1 == CLHEP::pi) {
279       setZ(-std::fabs(z()));                   << 282       dz = -std::fabs(dz);
280       return;                                     283       return;
281     }                                             284     }
282     std::cerr << "Hep3Vector::setCylEta() - "     285     std::cerr << "Hep3Vector::setCylEta() - "
283       << "Attempt set cylindrical eta of vecto    286       << "Attempt set cylindrical eta of vector along Z axis "
284       << "to a non-trivial value, while keepin    287       << "to a non-trivial value, while keeping rho fixed -- "
285       << "will return zero vector" << std::end    288       << "will return zero vector" << std::endl;
286     setZ(0.0);                                 << 289     dz = 0;
287     return;                                       290     return;
288   }                                               291   }
289   double phi1 (getPhi());                         292   double phi1 (getPhi());
290   double rho1 = getRho();                         293   double rho1 = getRho();
291   setZ(rho1 / std::tan (theta1));              << 294   dz = rho1 / std::tan (theta1);
292   setY(rho1 * std::sin (phi1));                << 295   dy = rho1 * std::sin (phi1);
293   setX(rho1 * std::cos (phi1));                << 296   dx = rho1 * std::cos (phi1);
294                                                   297 
295 } /* setCylEta */                                 298 } /* setCylEta */
296                                                   299 
297                                                   300 
298 Hep3Vector operator/ ( const Hep3Vector & v1,  << 301 Hep3Vector operator/  ( const Hep3Vector & v1, double c ) {
299 //  if (c == 0) {                                 302 //  if (c == 0) {
300 //    std::cerr << "Hep3Vector::operator/ () -    303 //    std::cerr << "Hep3Vector::operator/ () - "
301 //      << "Attempt to divide vector by 0 -- "    304 //      << "Attempt to divide vector by 0 -- "
302 //      << "will produce infinities and/or NAN    305 //      << "will produce infinities and/or NANs" << std::endl;
303 //  }                                             306 //  } 
304   return v1 * (1.0/c);                         << 307   double   oneOverC = 1.0/c;
                                                   >> 308   return Hep3Vector  (  v1.x() * oneOverC,
                                                   >> 309                         v1.y() * oneOverC,
                                                   >> 310                         v1.z() * oneOverC );
305 } /* v / c */                                     311 } /* v / c */
306                                                   312 
307 Hep3Vector & Hep3Vector::operator/= (double c)    313 Hep3Vector & Hep3Vector::operator/= (double c) {
308 //  if (c == 0) {                                 314 //  if (c == 0) {
309 //    std::cerr << "Hep3Vector::operator/ () -    315 //    std::cerr << "Hep3Vector::operator/ () - "
310 //      << "Attempt to do vector /= 0 -- "        316 //      << "Attempt to do vector /= 0 -- "
311 //      << "division by zero would produce inf    317 //      << "division by zero would produce infinite or NAN components"
312 //      << std::endl;                             318 //      << std::endl;
313 //  }                                             319 //  }
314   *this *= 1.0/c;                              << 320   double oneOverC = 1.0/c;
                                                   >> 321   dx *= oneOverC;
                                                   >> 322   dy *= oneOverC;
                                                   >> 323   dz *= oneOverC;
315   return *this;                                   324   return *this;
316 }                                                 325 }
317                                                   326 
318 double Hep3Vector::tolerance = Hep3Vector::Tol    327 double Hep3Vector::tolerance = Hep3Vector::ToleranceTicks * 2.22045e-16;
319                                                   328 
320 }  // namespace CLHEP                             329 }  // namespace CLHEP
321                                                   330