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Geant4/geometry/solids/specific/src/G4QuadrangularFacet.cc

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Differences between /geometry/solids/specific/src/G4QuadrangularFacet.cc (Version 11.3.0) and /geometry/solids/specific/src/G4QuadrangularFacet.cc (Version 9.3.p2)


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 26 //                                                 26 //
 27 // G4QuadrangularFacet class implementation.   << 
 28 //                                                 27 //
 29 // 31 October 2004 P R Truscott, QinetiQ Ltd,  <<  28 // $Id: G4QuadrangularFacet.cc,v 1.7.4.1 2010/09/08 15:54:58 gcosmo Exp $
 30 // 12 October 2012 M Gayer, CERN               <<  29 // GEANT4 tag $Name: geant4-09-03-patch-02 $
 31 //                 New implementation reducing <<  30 //
 32 //                 and considerable CPU speedu <<  31 // %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
 33 //                 implementation of G4Tessell <<  32 //
 34 // 29 February 2016 E Tcherniaev, CERN         <<  33 // MODULE:              G4QuadrangularFacet.cc
 35 //                 Added exhaustive tests to c <<  34 //
 36 //                 quadrangular facet: colline <<  35 // Date:                15/06/2005
 37 //                 degenerate, concave or self <<  36 // Author:              P R Truscott
 38 // ------------------------------------------- <<  37 // Organisation:        QinetiQ Ltd, UK
                                                   >>  38 // Customer:            UK Ministry of Defence : RAO CRP TD Electronic Systems
                                                   >>  39 // Contract:            C/MAT/N03517
                                                   >>  40 //
                                                   >>  41 // %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
                                                   >>  42 //
                                                   >>  43 // CHANGE HISTORY
                                                   >>  44 // --------------
                                                   >>  45 //
                                                   >>  46 // 31 October 2004, P R Truscott, QinetiQ Ltd, UK - Created.
                                                   >>  47 //
                                                   >>  48 // %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
 39                                                    49 
 40 #include "G4QuadrangularFacet.hh"                  50 #include "G4QuadrangularFacet.hh"
 41 #include "geomdefs.hh"                         <<  51 #include "globals.hh"
 42 #include "Randomize.hh"                            52 #include "Randomize.hh"
 43                                                << 
 44 using namespace std;                           << 
 45                                                    53 
 46 //////////////////////////////////////////////     54 ///////////////////////////////////////////////////////////////////////////////
 47 //                                                 55 //
 48 // Constructing two adjacent G4TriangularFacet <<  56 // !!!THIS IS A FUDGE!!!  IT'S TWO ADJACENT G4TRIANGULARFACETS
 49 // Not efficient, but practical...             <<  57 // --- NOT EFFICIENT BUT PRACTICAL.
 50 //                                                 58 //
 51 G4QuadrangularFacet::G4QuadrangularFacet (cons <<  59 G4QuadrangularFacet::G4QuadrangularFacet (const G4ThreeVector Pt0,
 52                                           cons <<  60                  const G4ThreeVector vt1, const G4ThreeVector vt2,
 53                                           cons <<  61                  const G4ThreeVector vt3, G4FacetVertexType vertexType)
 54                                           cons <<  62   : G4VFacet(), facet1(0), facet2(0)
 55                                                << 
 56 {                                                  63 {
 57   G4double delta   =  1.0 * kCarTolerance; //  <<  64   P0        = Pt0;
 58   G4double epsilon = 0.01 * kCarTolerance; //  <<  65   nVertices = 4;
 59                                                << 
 60   G4ThreeVector e1, e2, e3;                    << 
 61   SetVertex(0, vt0);                           << 
 62   if (vertexType == ABSOLUTE)                      66   if (vertexType == ABSOLUTE)
 63   {                                                67   {
 64     SetVertex(1, vt1);                         <<  68     P.push_back(vt1);
 65     SetVertex(2, vt2);                         <<  69     P.push_back(vt2);
 66     SetVertex(3, vt3);                         <<  70     P.push_back(vt3);
 67                                                <<  71   
 68     e1 = vt1 - vt0;                            <<  72     E.push_back(vt1 - P0);
 69     e2 = vt2 - vt0;                            <<  73     E.push_back(vt2 - P0);
 70     e3 = vt3 - vt0;                            <<  74     E.push_back(vt3 - P0);
 71   }                                                75   }
 72   else                                             76   else
 73   {                                                77   {
 74     SetVertex(1, vt0 + vt1);                   <<  78     P.push_back(P0 + vt1);
 75     SetVertex(2, vt0 + vt2);                   <<  79     P.push_back(P0 + vt2);
 76     SetVertex(3, vt0 + vt3);                   <<  80     P.push_back(P0 + vt3);
 77                                                <<  81   
 78     e1 = vt1;                                  <<  82     E.push_back(vt1);
 79     e2 = vt2;                                  <<  83     E.push_back(vt2);
 80     e3 = vt3;                                  <<  84     E.push_back(vt3);
 81   }                                            << 
 82                                                << 
 83   // Check length of sides and diagonals       << 
 84   //                                           << 
 85   G4double leng1 = e1.mag();                   << 
 86   G4double leng2 = (e2-e1).mag();              << 
 87   G4double leng3 = (e3-e2).mag();              << 
 88   G4double leng4 = e3.mag();                   << 
 89                                                << 
 90   G4double diag1 = e2.mag();                   << 
 91   G4double diag2 = (e3-e1).mag();              << 
 92                                                << 
 93   if (leng1 <= delta || leng2 <= delta || leng << 
 94       diag1 <= delta || diag2 <= delta)        << 
 95   {                                            << 
 96     ostringstream message;                     << 
 97     message << "Sides/diagonals of facet are t << 
 98             << "P0 = " << GetVertex(0) << G4en << 
 99             << "P1 = " << GetVertex(1) << G4en << 
100             << "P2 = " << GetVertex(2) << G4en << 
101             << "P3 = " << GetVertex(3) << G4en << 
102             << "Side1 length (P0->P1) = " << l << 
103             << "Side2 length (P1->P2) = " << l << 
104             << "Side3 length (P2->P3) = " << l << 
105             << "Side4 length (P3->P0) = " << l << 
106             << "Diagonal1 length (P0->P2) = "  << 
107             << "Diagonal2 length (P1->P3) = "  << 
108     G4Exception("G4QuadrangularFacet::G4Quadra << 
109                 "GeomSolids1001", JustWarning, << 
110     return;                                    << 
111   }                                            << 
112                                                << 
113   // Check that vertices are not collinear     << 
114   //                                           << 
115   G4double s1 = (e1.cross(e2)).mag()*0.5;      << 
116   G4double s2 = ((e2-e1).cross(e3-e2)).mag()*0 << 
117   G4double s3 = (e2.cross(e3)).mag()*0.5;      << 
118   G4double s4 = (e1.cross(e3)).mag()*0.5;      << 
119                                                << 
120   G4double h1 = 2.*s1 / std::max(std::max(leng << 
121   G4double h2 = 2.*s2 / std::max(std::max(leng << 
122   G4double h3 = 2.*s3 / std::max(std::max(leng << 
123   G4double h4 = 2.*s4 / std::max(std::max(leng << 
124                                                << 
125   if (h1 <= delta || h2 <= delta || h3 <= delt << 
126   {                                            << 
127     ostringstream message;                     << 
128     message << "Facet has three or more collin << 
129             << "P0 = " << GetVertex(0) << G4en << 
130             << "P1 = " << GetVertex(1) << G4en << 
131             << "P2 = " << GetVertex(2) << G4en << 
132             << "P3 = " << GetVertex(3) << G4en << 
133             << "Smallest heights:" << G4endl   << 
134             << "  in triangle P0-P1-P2 = " <<  << 
135             << "  in triangle P1-P2-P3 = " <<  << 
136             << "  in triangle P2-P3-P0 = " <<  << 
137             << "  in triangle P3-P0-P1 = " <<  << 
138     G4Exception("G4QuadrangularFacet::G4Quadra << 
139           "GeomSolids1001", JustWarning, messa << 
140     return;                                    << 
141   }                                                85   }
142                                                    86 
143   // Check that vertices are coplanar by compu <<  87   G4double length1 = E[0].mag();
144   // height of tetrahedron comprising of verti <<  88   G4double length2 = (P[1]-P[0]).mag();
145   //                                           <<  89   G4double length3 = (P[2]-P[1]).mag();
146   G4double smax = std::max( std::max(s1,s2), s <<  90   G4double length4 = E[2].mag();
147   G4double hmin = 0.5 * std::fabs( e1.dot(e2.c <<  91   
148   if (hmin >= epsilon)                         <<  92   G4ThreeVector normal1 = E[0].cross(E[1]).unit();
149   {                                            <<  93   G4ThreeVector normal2 = E[1].cross(E[2]).unit(); 
150     ostringstream message;                     << 
151     message << "Facet is not planar." << G4end << 
152             << "Disrepancy = " << hmin << G4en << 
153             << "P0 = " << GetVertex(0) << G4en << 
154             << "P1 = " << GetVertex(1) << G4en << 
155             << "P2 = " << GetVertex(2) << G4en << 
156             << "P3 = " << GetVertex(3);        << 
157     G4Exception("G4QuadrangularFacet::G4Quadra << 
158           "GeomSolids1001", JustWarning, messa << 
159     return;                                    << 
160   }                                            << 
161                                                    94   
162   // Check that facet is convex by computing c <<  95   if (length1 <= kCarTolerance || length2 <= kCarTolerance ||
163   // of diagonals                              <<  96       length3 <= kCarTolerance || length4 <= kCarTolerance ||
164   //                                           <<  97       normal1.dot(normal2) < 0.9999999999)
165   G4ThreeVector normal = e2.cross(e3-e1);      << 
166   G4double s = kInfinity, t = kInfinity, magni << 
167   if (magnitude2 > delta*delta) // check: magn << 
168   {                                                98   {
169     s = normal.dot(e1.cross(e3-e1)) / magnitud <<  99     G4Exception("G4QuadrangularFacet::G4QuadrangularFacet()",
170     t = normal.dot(e1.cross(e2))    / magnitud << 100                 "InvalidSetup", JustWarning,
                                                   >> 101                 "Length of sides of facet are too small or sides not planar.");
                                                   >> 102     G4cerr << G4endl;
                                                   >> 103     G4cerr << "P0 = " << P0   << G4endl;
                                                   >> 104     G4cerr << "P1 = " << P[0] << G4endl;
                                                   >> 105     G4cerr << "P2 = " << P[1] << G4endl;
                                                   >> 106     G4cerr << "P3 = " << P[2] << G4endl;
                                                   >> 107     G4cerr << "Side lengths = P0->P1" << length1 << G4endl;    
                                                   >> 108     G4cerr << "Side lengths = P1->P2" << length2 << G4endl;    
                                                   >> 109     G4cerr << "Side lengths = P2->P3" << length3 << G4endl;    
                                                   >> 110     G4cerr << "Side lengths = P3->P0" << length4 << G4endl;    
                                                   >> 111     G4cerr << G4endl;
                                                   >> 112     
                                                   >> 113     isDefined     = false;
                                                   >> 114     geometryType  = "G4QuadragularFacet";
                                                   >> 115     surfaceNormal = G4ThreeVector(0.0,0.0,0.0);
171   }                                               116   }
172   if (s <= 0. || s >= 1. || t <= 0. || t >= 1. << 117   else
173   {                                               118   {
174     ostringstream message;                     << 119     isDefined     = true;
175     message << "Facet is not convex." << G4end << 120     geometryType  = "G4QuadrangularFacet";
176             << "Parameters of crosspoint of di << 121     
177             << s << " and " << t << G4endl     << 122     facet1 = new G4TriangularFacet(P0,P[0],P[1],ABSOLUTE);
178             << "should both be within (0,1) ra << 123     facet2 = new G4TriangularFacet(P0,P[1],P[2],ABSOLUTE);
179       << "P0 = " << GetVertex(0) << G4endl     << 124     surfaceNormal = normal1;
180       << "P1 = " << GetVertex(1) << G4endl     << 125     
181       << "P2 = " << GetVertex(2) << G4endl     << 126     G4ThreeVector vtmp = 0.5 * (E[0] + E[1]);
182       << "P3 = " << GetVertex(3);              << 127     circumcentre       = P0 + vtmp;
183     G4Exception("G4QuadrangularFacet::G4Quadra << 128     radiusSqr          = vtmp.mag2();
184           "GeomSolids1001", JustWarning, messa << 129     radius             = std::sqrt(radiusSqr);
185     return;                                    << 130   
                                                   >> 131     for (size_t i=0; i<4; i++) I.push_back(0);
186   }                                               132   }
187                                                << 
188   // Define facet                              << 
189   //                                           << 
190   fFacet1 = G4TriangularFacet(GetVertex(0),Get << 
191   fFacet2 = G4TriangularFacet(GetVertex(0),Get << 
192                                                << 
193   normal = normal.unit();                      << 
194   fFacet1.SetSurfaceNormal(normal);            << 
195   fFacet2.SetSurfaceNormal(normal);            << 
196                                                << 
197   G4ThreeVector vtmp = 0.5 * (e1 + e2);        << 
198   fCircumcentre = GetVertex(0) + vtmp;         << 
199   G4double radiusSqr = vtmp.mag2();            << 
200   fRadius = std::sqrt(radiusSqr);              << 
201   // 29.02.2016 Remark by E.Tcherniaev: comput << 
202   // of fCircumcenter and fRadius is wrong, ho << 
203   // it did not create any problem till now.   << 
204   // Bizarre! Need to investigate!             << 
205 }                                                 133 }
206                                                   134 
207 //////////////////////////////////////////////    135 ///////////////////////////////////////////////////////////////////////////////
208 //                                                136 //
209 G4QuadrangularFacet::~G4QuadrangularFacet () = << 137 G4QuadrangularFacet::~G4QuadrangularFacet ()
210                                                << 
211 ////////////////////////////////////////////// << 
212 //                                             << 
213 G4QuadrangularFacet::G4QuadrangularFacet (cons << 
214   : G4VFacet(rhs)                              << 
215 {                                                 138 {
216   fFacet1 = rhs.fFacet1;                       << 139   delete facet1;
217   fFacet2 = rhs.fFacet2;                       << 140   delete facet2;
218   fRadius = 0.0;                               << 141   
219 }                                              << 142   P.clear();
220                                                << 143   E.clear();
221 ////////////////////////////////////////////// << 144   I.clear();
222 //                                             << 
223 G4QuadrangularFacet &                          << 
224 G4QuadrangularFacet::operator=(const G4Quadran << 
225 {                                              << 
226   if (this == &rhs)  return *this;             << 
227                                                << 
228   fFacet1 = rhs.fFacet1;                       << 
229   fFacet2 = rhs.fFacet2;                       << 
230   fRadius = 0.0;                               << 
231                                                << 
232   return *this;                                << 
233 }                                                 145 }
234                                                   146 
235 //////////////////////////////////////////////    147 ///////////////////////////////////////////////////////////////////////////////
236 //                                                148 //
237 G4VFacet* G4QuadrangularFacet::GetClone ()     << 149 G4VFacet *G4QuadrangularFacet::GetClone ()
238 {                                                 150 {
239   auto c = new G4QuadrangularFacet (GetVertex( << 151   G4QuadrangularFacet *c =
240                                     GetVertex( << 152     new G4QuadrangularFacet (P0, P[0], P[1], P[2], ABSOLUTE);
241   return c;                                    << 153   G4VFacet *cc         = 0;
                                                   >> 154   cc                   = c;
                                                   >> 155   return cc;
242 }                                                 156 }
243                                                   157 
244 //////////////////////////////////////////////    158 ///////////////////////////////////////////////////////////////////////////////
245 //                                                159 //
246 G4ThreeVector G4QuadrangularFacet::Distance (c << 160 G4ThreeVector G4QuadrangularFacet::Distance (const G4ThreeVector &p)
247 {                                                 161 {
248   G4ThreeVector v1 = fFacet1.Distance(p);      << 162   G4ThreeVector v1 = facet1->Distance(p);
249   G4ThreeVector v2 = fFacet2.Distance(p);      << 163   G4ThreeVector v2 = facet2->Distance(p);
250                                                << 164   
251   if (v1.mag2() < v2.mag2()) return v1;           165   if (v1.mag2() < v2.mag2()) return v1;
252   else return v2;                                 166   else return v2;
253 }                                                 167 }
254                                                   168 
255 //////////////////////////////////////////////    169 ///////////////////////////////////////////////////////////////////////////////
256 //                                                170 //
257 G4double G4QuadrangularFacet::Distance (const  << 171 G4double G4QuadrangularFacet::Distance (const G4ThreeVector &p,
258                                                << 172   const G4double)
259 {                                              << 173 {
260   G4double dist = Distance(p).mag();           << 174   /*G4ThreeVector D  = P0 - p;
                                                   >> 175   G4double d       = E[0].dot(D);
                                                   >> 176   G4double e       = E[1].dot(D);
                                                   >> 177   G4double s       = b*e - c*d;
                                                   >> 178   G4double t       = b*d - a*e;*/
                                                   >> 179   G4double dist = kInfinity;
                                                   >> 180   
                                                   >> 181   /*if (s+t > 1.0 || s < 0.0 || t < 0.0)
                                                   >> 182   {
                                                   >> 183     G4ThreeVector D0 = P0 - p;
                                                   >> 184     G4ThreeVector D1 = P[0] - p;
                                                   >> 185     G4ThreeVector D2 = P[1] - p;
                                                   >> 186     
                                                   >> 187     G4double d0 = D0.mag();
                                                   >> 188     G4double d1 = D1.mag();
                                                   >> 189     G4double d2 = D2.mag();
                                                   >> 190     
                                                   >> 191     dist = min(d0, min(d1, d2));
                                                   >> 192     if (dist > minDist) return kInfinity;
                                                   >> 193   }*/
                                                   >> 194   
                                                   >> 195   dist = Distance(p).mag();
                                                   >> 196   
261   return dist;                                    197   return dist;
262 }                                                 198 }
263                                                   199 
264 //////////////////////////////////////////////    200 ///////////////////////////////////////////////////////////////////////////////
265 //                                                201 //
266 G4double G4QuadrangularFacet::Distance (const  << 202 G4double G4QuadrangularFacet::Distance (const G4ThreeVector &p,
267                                         const  << 203                                         const G4double, const G4bool outgoing)
268 {                                                 204 {
269   G4double dist;                               << 205   /*G4ThreeVector D  = P0 - p;
270                                                << 206   G4double d       = E[0].dot(D);
                                                   >> 207   G4double e       = E[1].dot(D);
                                                   >> 208   G4double s       = b*e - c*d;
                                                   >> 209   G4double t       = b*d - a*e;*/
                                                   >> 210   G4double dist = kInfinity;
                                                   >> 211   
                                                   >> 212   /*if (s+t > 1.0 || s < 0.0 || t < 0.0)
                                                   >> 213   {
                                                   >> 214     G4ThreeVector D0 = P0 - p;
                                                   >> 215     G4ThreeVector D1 = P[0] - p;
                                                   >> 216     G4ThreeVector D2 = P[1] - p;
                                                   >> 217     
                                                   >> 218     G4double d0 = D0.mag();
                                                   >> 219     G4double d1 = D1.mag();
                                                   >> 220     G4double d2 = D2.mag();
                                                   >> 221     
                                                   >> 222     dist = min(d0, min(d1, d2));
                                                   >> 223     if (dist > minDist ||
                                                   >> 224       (D0.dot(surfaceNormal) > 0.0 && !outgoing) ||
                                                   >> 225       (D0.dot(surfaceNormal) < 0.0 && outgoing)) return kInfinity;
                                                   >> 226   }*/
                                                   >> 227   
271   G4ThreeVector v = Distance(p);                  228   G4ThreeVector v = Distance(p);
272   G4double dir = v.dot(GetSurfaceNormal());    << 229   G4double dir    = v.dot(surfaceNormal);
273   if ( ((dir > dirTolerance) && (!outgoing))   << 230   if ((dir > dirTolerance && !outgoing) ||
274     || ((dir < -dirTolerance) && outgoing))    << 231       (dir <-dirTolerance && outgoing)) dist = kInfinity;
275     dist = kInfinity;                          << 232   else dist = v.mag();
276   else                                         << 233   
277     dist = v.mag();                            << 
278   return dist;                                    234   return dist;
279 }                                                 235 }
280                                                   236 
281 //////////////////////////////////////////////    237 ///////////////////////////////////////////////////////////////////////////////
282 //                                                238 //
283 G4double G4QuadrangularFacet::Extent (const G4    239 G4double G4QuadrangularFacet::Extent (const G4ThreeVector axis)
284 {                                                 240 {
285   G4double ss  = 0;                            << 241   G4double s  = P0.dot(axis);
286                                                << 242   for (G4ThreeVectorList::iterator it=P.begin(); it!=P.end(); it++)
287   for (G4int i = 0; i <= 3; ++i)               << 
288   {                                               243   {
289     G4double sp = GetVertex(i).dot(axis);      << 244     G4double sp = it->dot(axis);
290     if (sp > ss) ss = sp;                      << 245     if (sp > s) s = sp;
291   }                                               246   }
292   return ss;                                   << 247 
                                                   >> 248   return s;
293 }                                                 249 }
294                                                   250 
295 //////////////////////////////////////////////    251 ///////////////////////////////////////////////////////////////////////////////
296 //                                                252 //
297 G4bool G4QuadrangularFacet::Intersect (const G << 253 G4bool G4QuadrangularFacet::Intersect (const G4ThreeVector &p,
298                                        const G << 254   const G4ThreeVector &v, G4bool outgoing, G4double &distance,
299                                              G << 255   G4double &distFromSurface, G4ThreeVector &normal)
300                                              G << 
301                                              G << 
302                                              G << 
303 {                                                 256 {
304   G4bool intersect =                              257   G4bool intersect =
305     fFacet1.Intersect(p,v,outgoing,distance,di << 258     facet1->Intersect(p,v,outgoing,distance,distFromSurface,normal);
306   if (!intersect) intersect =                  << 259   if (!intersect)
307     fFacet2.Intersect(p,v,outgoing,distance,di << 260   {
                                                   >> 261     intersect = facet2->Intersect(p,v,outgoing,distance,distFromSurface,normal);
                                                   >> 262   }
                                                   >> 263   
308   if (!intersect)                                 264   if (!intersect)
309   {                                               265   {
310     distance = distFromSurface = kInfinity;    << 266     distance        = kInfinity;
311     normal.set(0,0,0);                         << 267     distFromSurface = kInfinity;
                                                   >> 268     normal          = G4ThreeVector(0.0,0.0,0.0);
312   }                                               269   }
                                                   >> 270   
313   return intersect;                               271   return intersect;
314 }                                                 272 }
315                                                   273 
316 ////////////////////////////////////////////// << 274 ////////////////////////////////////////////////////////////////////////
317 //                                                275 //
318 // Auxiliary method to get a uniform random po << 276 // GetPointOnFace
319 //                                                277 //
                                                   >> 278 // Auxiliary method for get a random point on surface
                                                   >> 279 
320 G4ThreeVector G4QuadrangularFacet::GetPointOnF    280 G4ThreeVector G4QuadrangularFacet::GetPointOnFace() const
321 {                                                 281 {
322   G4double s1 = fFacet1.GetArea();             << 282   G4ThreeVector pr;
323   G4double s2 = fFacet2.GetArea();             << 283 
324   return ((s1+s2)*G4UniformRand() < s1) ?      << 284   if ( G4UniformRand() < 0.5 )
325     fFacet1.GetPointOnFace() : fFacet2.GetPoin << 285   {
                                                   >> 286     pr = facet1->GetPointOnFace();
                                                   >> 287   }
                                                   >> 288   else
                                                   >> 289   {
                                                   >> 290     pr = facet2->GetPointOnFace();
                                                   >> 291   }
                                                   >> 292 
                                                   >> 293   return pr;
326 }                                                 294 }
327                                                   295 
328 ////////////////////////////////////////////// << 296 ////////////////////////////////////////////////////////////////////////
329 //                                                297 //
330 // Auxiliary method for returning the surface  << 298 // GetArea
331 //                                                299 //
332 G4double G4QuadrangularFacet::GetArea() const  << 300 // Auxiliary method for returning the surface area
333 {                                              << 
334   G4double area = fFacet1.GetArea() + fFacet2. << 
335   return area;                                 << 
336 }                                              << 
337                                                   301 
338 ////////////////////////////////////////////// << 302 G4double G4QuadrangularFacet::GetArea()
339 //                                             << 
340 G4String G4QuadrangularFacet::GetEntityType () << 
341 {                                                 303 {
342   return "G4QuadrangularFacet";                << 304   if (!area)  { area = facet1->GetArea() + facet2->GetArea(); }
343 }                                              << 
344                                                   305 
345 ////////////////////////////////////////////// << 306   return area;
346 //                                             << 
347 G4ThreeVector G4QuadrangularFacet::GetSurfaceN << 
348 {                                              << 
349   return fFacet1.GetSurfaceNormal();           << 
350 }                                                 307 }
351                                                   308