Geant4  10.03.p03
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G4TwistTrapFlatSide Class Reference

#include <G4TwistTrapFlatSide.hh>

Inheritance diagram for G4TwistTrapFlatSide:
Collaboration diagram for G4TwistTrapFlatSide:

Public Member Functions

 G4TwistTrapFlatSide (const G4String &name, G4double PhiTwist, G4double pDx1, G4double pDx2, G4double pDy, G4double pDz, G4double pAlpha, G4double pPhi, G4double pTheta, G4int handedness)
 
virtual ~G4TwistTrapFlatSide ()
 
virtual G4ThreeVector GetNormal (const G4ThreeVector &, G4bool isGlobal=false)
 
virtual G4int DistanceToSurface (const G4ThreeVector &gp, const G4ThreeVector &gv, G4ThreeVector gxx[], G4double distance[], G4int areacode[], G4bool isvalid[], EValidate validate=kValidateWithTol)
 
virtual G4int DistanceToSurface (const G4ThreeVector &gp, G4ThreeVector gxx[], G4double distance[], G4int areacode[])
 
virtual G4ThreeVector SurfacePoint (G4double x, G4double y, G4bool isGlobal=false)
 
virtual G4double GetBoundaryMin (G4double u)
 
virtual G4double GetBoundaryMax (G4double u)
 
virtual G4double GetSurfaceArea ()
 
virtual void GetFacets (G4int m, G4int n, G4double xyz[][3], G4int faces[][4], G4int iside)
 
 G4TwistTrapFlatSide (__void__ &)
 
- Public Member Functions inherited from G4VTwistSurface
 G4VTwistSurface (const G4String &name)
 
 G4VTwistSurface (const G4String &name, const G4RotationMatrix &rot, const G4ThreeVector &tlate, G4int handedness, const EAxis axis1, const EAxis axis2, G4double axis0min=-kInfinity, G4double axis1min=-kInfinity, G4double axis0max=kInfinity, G4double axis1max=kInfinity)
 
virtual ~G4VTwistSurface ()
 
virtual G4int AmIOnLeftSide (const G4ThreeVector &me, const G4ThreeVector &vec, G4bool withTol=true)
 
virtual G4double DistanceToBoundary (G4int areacode, G4ThreeVector &xx, const G4ThreeVector &p)
 
virtual G4double DistanceToIn (const G4ThreeVector &gp, const G4ThreeVector &gv, G4ThreeVector &gxxbest)
 
virtual G4double DistanceToOut (const G4ThreeVector &gp, const G4ThreeVector &gv, G4ThreeVector &gxxbest)
 
virtual G4double DistanceTo (const G4ThreeVector &gp, G4ThreeVector &gxx)
 
void DebugPrint () const
 
virtual G4String GetName () const
 
virtual void GetBoundaryParameters (const G4int &areacode, G4ThreeVector &d, G4ThreeVector &x0, G4int &boundarytype) const
 
virtual G4ThreeVector GetBoundaryAtPZ (G4int areacode, const G4ThreeVector &p) const
 
G4double DistanceToPlaneWithV (const G4ThreeVector &p, const G4ThreeVector &v, const G4ThreeVector &x0, const G4ThreeVector &n0, G4ThreeVector &xx)
 
G4double DistanceToPlane (const G4ThreeVector &p, const G4ThreeVector &x0, const G4ThreeVector &n0, G4ThreeVector &xx)
 
G4double DistanceToPlane (const G4ThreeVector &p, const G4ThreeVector &x0, const G4ThreeVector &t1, const G4ThreeVector &t2, G4ThreeVector &xx, G4ThreeVector &n)
 
G4double DistanceToLine (const G4ThreeVector &p, const G4ThreeVector &x0, const G4ThreeVector &d, G4ThreeVector &xx)
 
G4bool IsAxis0 (G4int areacode) const
 
G4bool IsAxis1 (G4int areacode) const
 
G4bool IsOutside (G4int areacode) const
 
G4bool IsInside (G4int areacode, G4bool testbitmode=false) const
 
G4bool IsBoundary (G4int areacode, G4bool testbitmode=false) const
 
G4bool IsCorner (G4int areacode, G4bool testbitmode=false) const
 
G4bool IsValidNorm () const
 
G4bool IsSameBoundary (G4VTwistSurface *surface1, G4int areacode1, G4VTwistSurface *surface2, G4int areacode2) const
 
G4int GetAxisType (G4int areacode, G4int whichaxis) const
 
G4ThreeVector ComputeGlobalPoint (const G4ThreeVector &lp) const
 
G4ThreeVector ComputeLocalPoint (const G4ThreeVector &gp) const
 
G4ThreeVector ComputeGlobalDirection (const G4ThreeVector &lp) const
 
G4ThreeVector ComputeLocalDirection (const G4ThreeVector &gp) const
 
void SetAxis (G4int i, const EAxis axis)
 
void SetNeighbours (G4VTwistSurface *axis0min, G4VTwistSurface *axis1min, G4VTwistSurface *axis0max, G4VTwistSurface *axis1max)
 
G4int GetNode (G4int i, G4int j, G4int m, G4int n, G4int iside)
 
G4int GetFace (G4int i, G4int j, G4int m, G4int n, G4int iside)
 
G4int GetEdgeVisibility (G4int i, G4int j, G4int m, G4int n, G4int number, G4int orientation)
 
 G4VTwistSurface (__void__ &)
 

Protected Member Functions

virtual G4int GetAreaCode (const G4ThreeVector &xx, G4bool withTol=true)
 
- Protected Member Functions inherited from G4VTwistSurface
G4VTwistSurface ** GetNeighbours ()
 
G4int GetNeighbours (G4int areacode, G4VTwistSurface *surfaces[])
 
G4ThreeVector GetCorner (G4int areacode) const
 
void GetBoundaryAxis (G4int areacode, EAxis axis[]) const
 
void GetBoundaryLimit (G4int areacode, G4double limit[]) const
 
virtual void SetBoundary (const G4int &axiscode, const G4ThreeVector &direction, const G4ThreeVector &x0, const G4int &boundarytype)
 
void SetCorner (G4int areacode, G4double x, G4double y, G4double z)
 

Additional Inherited Members

- Public Types inherited from G4VTwistSurface
enum  EValidate { kDontValidate = 0, kValidateWithTol = 1, kValidateWithoutTol = 2, kUninitialized = 3 }
 
- Static Public Attributes inherited from G4VTwistSurface
static const G4int sOutside = 0x00000000
 
static const G4int sInside = 0x10000000
 
static const G4int sBoundary = 0x20000000
 
static const G4int sCorner = 0x40000000
 
static const G4int sC0Min1Min = 0x40000101
 
static const G4int sC0Max1Min = 0x40000201
 
static const G4int sC0Max1Max = 0x40000202
 
static const G4int sC0Min1Max = 0x40000102
 
static const G4int sAxisMin = 0x00000101
 
static const G4int sAxisMax = 0x00000202
 
static const G4int sAxisX = 0x00000404
 
static const G4int sAxisY = 0x00000808
 
static const G4int sAxisZ = 0x00000C0C
 
static const G4int sAxisRho = 0x00001010
 
static const G4int sAxisPhi = 0x00001414
 
static const G4int sAxis0 = 0x0000FF00
 
static const G4int sAxis1 = 0x000000FF
 
static const G4int sSizeMask = 0x00000303
 
static const G4int sAxisMask = 0x0000FCFC
 
static const G4int sAreaMask = 0XF0000000
 
- Protected Attributes inherited from G4VTwistSurface
EAxis fAxis [2]
 
G4double fAxisMin [2]
 
G4double fAxisMax [2]
 
CurrentStatus fCurStatWithV
 
CurrentStatus fCurStat
 
G4RotationMatrix fRot
 
G4ThreeVector fTrans
 
G4int fHandedness
 
G4SurfCurNormal fCurrentNormal
 
G4bool fIsValidNorm
 
G4double kCarTolerance
 

Detailed Description

Definition at line 50 of file G4TwistTrapFlatSide.hh.

Constructor & Destructor Documentation

G4TwistTrapFlatSide::G4TwistTrapFlatSide ( const G4String name,
G4double  PhiTwist,
G4double  pDx1,
G4double  pDx2,
G4double  pDy,
G4double  pDz,
G4double  pAlpha,
G4double  pPhi,
G4double  pTheta,
G4int  handedness 
)

Definition at line 46 of file G4TwistTrapFlatSide.cc.

57  : G4VTwistSurface(name)
58 {
59  fHandedness = handedness; // +z = +ve, -z = -ve
60 
61  fDx1 = pDx1 ;
62  fDx2 = pDx2 ;
63  fDy = pDy ;
64  fDz = pDz ;
65  fAlpha = pAlpha ;
66  fTAlph = std::tan(fAlpha) ;
67  fPhi = pPhi ;
68  fTheta = pTheta ;
69 
70  fdeltaX = 2 * fDz * std::tan(fTheta) * std::cos(fPhi) ;
71  // dx in surface equation
72  fdeltaY = 2 * fDz * std::tan(fTheta) * std::sin(fPhi) ;
73  // dy in surface equation
74 
75  fPhiTwist = PhiTwist ;
76 
77  fCurrentNormal.normal.set( 0, 0, (fHandedness < 0 ? -1 : 1));
78  // Unit vector, in local coordinate system
80  ? 0.5 * fPhiTwist
81  : -0.5 * fPhiTwist );
82 
83  fTrans.set(
84  fHandedness > 0 ? 0.5*fdeltaX : -0.5*fdeltaX ,
85  fHandedness > 0 ? 0.5*fdeltaY : -0.5*fdeltaY ,
86  fHandedness > 0 ? fDz : -fDz ) ;
87 
88  fIsValidNorm = true;
89 
90 
91  fAxis[0] = kXAxis ;
92  fAxis[1] = kYAxis ;
93  fAxisMin[0] = kInfinity ; // x-Axis cannot be fixed, because it
94  fAxisMax[0] = kInfinity ; // depends on y
95  fAxisMin[1] = -fDy ; // y - axis
96  fAxisMax[1] = fDy ;
97 
98  SetCorners();
99  SetBoundaries();
100 }
void set(double x, double y, double z)
static const G4double kInfinity
Definition: geomdefs.hh:42
G4SurfCurNormal fCurrentNormal
G4double fAxisMax[2]
G4RotationMatrix fRot
G4ThreeVector fTrans
G4double fAxisMin[2]
G4VTwistSurface(const G4String &name)
HepRotation & rotateZ(double delta)
Definition: Rotation.cc:92

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G4TwistTrapFlatSide::~G4TwistTrapFlatSide ( )
virtual

Definition at line 116 of file G4TwistTrapFlatSide.cc.

117 {
118 }
G4TwistTrapFlatSide::G4TwistTrapFlatSide ( __void__ &  a)

Definition at line 106 of file G4TwistTrapFlatSide.cc.

107  : G4VTwistSurface(a), fDx1(0.), fDx2(0.), fDy(0.), fDz(0.), fPhiTwist(0.),
108  fAlpha(0.), fTAlph(0.), fPhi(0.), fTheta(0.), fdeltaX(0.), fdeltaY(0.)
109 {
110 }
std::vector< ExP01TrackerHit * > a
Definition: ExP01Classes.hh:33
G4VTwistSurface(const G4String &name)

Member Function Documentation

G4int G4TwistTrapFlatSide::DistanceToSurface ( const G4ThreeVector gp,
const G4ThreeVector gv,
G4ThreeVector  gxx[],
G4double  distance[],
G4int  areacode[],
G4bool  isvalid[],
EValidate  validate = kValidateWithTol 
)
virtual

Implements G4VTwistSurface.

Definition at line 136 of file G4TwistTrapFlatSide.cc.

143 {
144  fCurStatWithV.ResetfDone(validate, &gp, &gv);
145 
146  if (fCurStatWithV.IsDone()) {
147  G4int i;
148  for (i=0; i<fCurStatWithV.GetNXX(); i++) {
149  gxx[i] = fCurStatWithV.GetXX(i);
150  distance[i] = fCurStatWithV.GetDistance(i);
151  areacode[i] = fCurStatWithV.GetAreacode(i);
152  isvalid[i] = fCurStatWithV.IsValid(i);
153  }
154  return fCurStatWithV.GetNXX();
155  } else {
156  // initialize
157  G4int i;
158  for (i=0; i<2; i++) {
159  distance[i] = kInfinity;
160  areacode[i] = sOutside;
161  isvalid[i] = false;
162  gxx[i].set(kInfinity, kInfinity, kInfinity);
163  }
164  }
165 
168 
169  //
170  // special case!
171  // if p is on surface, distance = 0.
172  //
173 
174  if (std::fabs(p.z()) == 0.) { // if p is on the plane
175  distance[0] = 0;
176  G4ThreeVector xx = p;
177  gxx[0] = ComputeGlobalPoint(xx);
178 
179  if (validate == kValidateWithTol) {
180  areacode[0] = GetAreaCode(xx);
181  if (!IsOutside(areacode[0])) {
182  isvalid[0] = true;
183  }
184  } else if (validate == kValidateWithoutTol) {
185  areacode[0] = GetAreaCode(xx, false);
186  if (IsInside(areacode[0])) {
187  isvalid[0] = true;
188  }
189  } else { // kDontValidate
190  areacode[0] = sInside;
191  isvalid[0] = true;
192  }
193 
194  return 1;
195  }
196  //
197  // special case end
198  //
199 
200  if (v.z() == 0) {
201 
202  fCurStatWithV.SetCurrentStatus(0, gxx[0], distance[0], areacode[0],
203  isvalid[0], 0, validate, &gp, &gv);
204  return 0;
205  }
206 
207  distance[0] = - (p.z() / v.z());
208 
209  G4ThreeVector xx = p + distance[0]*v;
210  gxx[0] = ComputeGlobalPoint(xx);
211 
212  if (validate == kValidateWithTol) {
213  areacode[0] = GetAreaCode(xx);
214  if (!IsOutside(areacode[0])) {
215  if (distance[0] >= 0) isvalid[0] = true;
216  }
217  } else if (validate == kValidateWithoutTol) {
218  areacode[0] = GetAreaCode(xx, false);
219  if (IsInside(areacode[0])) {
220  if (distance[0] >= 0) isvalid[0] = true;
221  }
222  } else { // kDontValidate
223  areacode[0] = sInside;
224  if (distance[0] >= 0) isvalid[0] = true;
225  }
226 
227 
228  fCurStatWithV.SetCurrentStatus(0, gxx[0], distance[0], areacode[0],
229  isvalid[0], 1, validate, &gp, &gv);
230 
231 #ifdef G4TWISTDEBUG
232  G4cerr << "ERROR - G4TwistTrapFlatSide::DistanceToSurface(p,v)" << G4endl;
233  G4cerr << " Name : " << GetName() << G4endl;
234  G4cerr << " xx : " << xx << G4endl;
235  G4cerr << " gxx[0] : " << gxx[0] << G4endl;
236  G4cerr << " dist[0] : " << distance[0] << G4endl;
237  G4cerr << " areacode[0] : " << areacode[0] << G4endl;
238  G4cerr << " isvalid[0] : " << isvalid[0] << G4endl;
239 #endif
240  return 1;
241 }
void set(double x, double y, double z)
G4int GetAreacode(G4int i) const
static const G4double kInfinity
Definition: geomdefs.hh:42
G4ThreeVector ComputeLocalDirection(const G4ThreeVector &gp) const
const char * p
Definition: xmltok.h:285
static const G4int sOutside
G4ThreeVector ComputeGlobalPoint(const G4ThreeVector &lp) const
int G4int
Definition: G4Types.hh:78
double z() const
G4bool IsOutside(G4int areacode) const
G4double GetDistance(G4int i) const
void SetCurrentStatus(G4int i, G4ThreeVector &xx, G4double &dist, G4int &areacode, G4bool &isvalid, G4int nxx, EValidate validate, const G4ThreeVector *p, const G4ThreeVector *v=0)
G4bool IsValid(G4int i) const
G4bool IsInside(G4int areacode, G4bool testbitmode=false) const
static const G4int sInside
virtual G4int GetAreaCode(const G4ThreeVector &xx, G4bool withTol=true)
tuple v
Definition: test.py:18
G4ThreeVector GetXX(G4int i) const
virtual G4String GetName() const
#define G4endl
Definition: G4ios.hh:61
G4ThreeVector ComputeLocalPoint(const G4ThreeVector &gp) const
CurrentStatus fCurStatWithV
G4GLOB_DLL std::ostream G4cerr
void ResetfDone(EValidate validate, const G4ThreeVector *p, const G4ThreeVector *v=0)

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G4int G4TwistTrapFlatSide::DistanceToSurface ( const G4ThreeVector gp,
G4ThreeVector  gxx[],
G4double  distance[],
G4int  areacode[] 
)
virtual

Implements G4VTwistSurface.

Definition at line 246 of file G4TwistTrapFlatSide.cc.

250 {
251  // Calculate distance to plane in local coordinate,
252  // then return distance and global intersection points.
253  //
254 
256 
257  if (fCurStat.IsDone()) {
258  G4int i;
259  for (i=0; i<fCurStat.GetNXX(); i++) {
260  gxx[i] = fCurStat.GetXX(i);
261  distance[i] = fCurStat.GetDistance(i);
262  areacode[i] = fCurStat.GetAreacode(i);
263  }
264  return fCurStat.GetNXX();
265  } else {
266  // initialize
267  G4int i;
268  for (i=0; i<2; i++) {
269  distance[i] = kInfinity;
270  areacode[i] = sOutside;
271  gxx[i].set(kInfinity, kInfinity, kInfinity);
272  }
273  }
274 
276  G4ThreeVector xx;
277 
278  // The plane is placed on origin with making its normal
279  // parallel to z-axis.
280  if (std::fabs(p.z()) <= 0.5 * kCarTolerance)
281  { // if p is on the plane, return 1
282  distance[0] = 0;
283  xx = p;
284  } else {
285  distance[0] = std::fabs(p.z());
286  xx.set(p.x(), p.y(), 0);
287  }
288 
289  gxx[0] = ComputeGlobalPoint(xx);
290  areacode[0] = sInside;
291  G4bool isvalid = true;
292  fCurStat.SetCurrentStatus(0, gxx[0], distance[0], areacode[0],
293  isvalid, 1, kDontValidate, &gp);
294  return 1;
295 
296 }
void set(double x, double y, double z)
G4int GetAreacode(G4int i) const
static const G4double kInfinity
Definition: geomdefs.hh:42
double x() const
const char * p
Definition: xmltok.h:285
static const G4int sOutside
CurrentStatus fCurStat
G4ThreeVector ComputeGlobalPoint(const G4ThreeVector &lp) const
int G4int
Definition: G4Types.hh:78
double z() const
G4double GetDistance(G4int i) const
bool G4bool
Definition: G4Types.hh:79
void SetCurrentStatus(G4int i, G4ThreeVector &xx, G4double &dist, G4int &areacode, G4bool &isvalid, G4int nxx, EValidate validate, const G4ThreeVector *p, const G4ThreeVector *v=0)
static const G4int sInside
double y() const
G4ThreeVector GetXX(G4int i) const
G4ThreeVector ComputeLocalPoint(const G4ThreeVector &gp) const
void ResetfDone(EValidate validate, const G4ThreeVector *p, const G4ThreeVector *v=0)

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G4int G4TwistTrapFlatSide::GetAreaCode ( const G4ThreeVector xx,
G4bool  withTol = true 
)
protectedvirtual

Implements G4VTwistSurface.

Definition at line 298 of file G4TwistTrapFlatSide.cc.

300 {
301 
302  static const G4double ctol = 0.5 * kCarTolerance;
303  G4int areacode = sInside;
304 
305  if (fAxis[0] == kXAxis && fAxis[1] == kYAxis) {
306 
307  G4int yaxis = 1;
308 
309  G4double wmax = xAxisMax(xx.y(), fTAlph ) ;
310  G4double wmin = -xAxisMax(xx.y(), -fTAlph ) ;
311 
312  if (withTol) {
313 
314  G4bool isoutside = false;
315 
316  // test boundary of x-axis
317 
318  if (xx.x() < wmin + ctol) {
319  areacode |= (sAxis0 & (sAxisX | sAxisMin)) | sBoundary;
320  if (xx.x() <= wmin - ctol) isoutside = true;
321 
322  } else if (xx.x() > wmax - ctol) {
323  areacode |= (sAxis0 & (sAxisX | sAxisMax)) | sBoundary;
324  if (xx.x() >= wmax + ctol) isoutside = true;
325  }
326 
327  // test boundary of y-axis
328 
329  if (xx.y() < fAxisMin[yaxis] + ctol) {
330  areacode |= (sAxis1 & (sAxisY | sAxisMin));
331 
332  if (areacode & sBoundary) areacode |= sCorner; // xx is on the corner.
333  else areacode |= sBoundary;
334  if (xx.y() <= fAxisMin[yaxis] - ctol) isoutside = true;
335 
336  } else if (xx.y() > fAxisMax[yaxis] - ctol) {
337  areacode |= (sAxis1 & (sAxisY | sAxisMax));
338 
339  if (areacode & sBoundary) areacode |= sCorner; // xx is on the corner.
340  else areacode |= sBoundary;
341  if (xx.y() >= fAxisMax[yaxis] + ctol) isoutside = true;
342  }
343 
344  // if isoutside = true, clear inside bit.
345  // if not on boundary, add axis information.
346 
347  if (isoutside) {
348  G4int tmpareacode = areacode & (~sInside);
349  areacode = tmpareacode;
350  } else if ((areacode & sBoundary) != sBoundary) {
351  areacode |= (sAxis0 & sAxisX) | (sAxis1 & sAxisY);
352  }
353 
354  } else {
355 
356  // boundary of x-axis
357 
358  if (xx.x() < wmin ) {
359  areacode |= (sAxis0 & (sAxisX | sAxisMin)) | sBoundary;
360  } else if (xx.x() > wmax) {
361  areacode |= (sAxis0 & (sAxisX | sAxisMax)) | sBoundary;
362  }
363 
364  // boundary of y-axis
365 
366  if (xx.y() < fAxisMin[yaxis]) {
367  areacode |= (sAxis1 & (sAxisY | sAxisMin));
368  if (areacode & sBoundary) areacode |= sCorner; // xx is on the corner.
369  else areacode |= sBoundary;
370 
371  } else if (xx.y() > fAxisMax[yaxis]) {
372  areacode |= (sAxis1 & (sAxisY | sAxisMax)) ;
373  if (areacode & sBoundary) areacode |= sCorner; // xx is on the corner.
374  else areacode |= sBoundary;
375  }
376 
377  if ((areacode & sBoundary) != sBoundary) {
378  areacode |= (sAxis0 & sAxisX) | (sAxis1 & sAxisY);
379  }
380  }
381  return areacode;
382  } else {
383  G4Exception("G4TwistTrapFlatSide::GetAreaCode()",
384  "GeomSolids0001", FatalException,
385  "Feature NOT implemented !");
386  }
387 
388  return areacode;
389 }
double x() const
G4double fAxisMax[2]
int G4int
Definition: G4Types.hh:78
static const G4int sAxisX
G4double fAxisMin[2]
static const G4int sAxis1
static const G4int sBoundary
bool G4bool
Definition: G4Types.hh:79
static const G4int sAxis0
static const G4int sAxisMin
static const G4int sAxisY
static const G4int sInside
void G4Exception(const char *originOfException, const char *exceptionCode, G4ExceptionSeverity severity, const char *comments)
Definition: G4Exception.cc:41
static const G4int sCorner
static const G4int sAxisMax
double y() const
double G4double
Definition: G4Types.hh:76

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G4double G4TwistTrapFlatSide::GetBoundaryMax ( G4double  u)
inlinevirtual

Implements G4VTwistSurface.

Definition at line 150 of file G4TwistTrapFlatSide.hh.

151 {
152  return xAxisMax(y, fTAlph ) ;
153 }

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G4double G4TwistTrapFlatSide::GetBoundaryMin ( G4double  u)
inlinevirtual

Implements G4VTwistSurface.

Definition at line 144 of file G4TwistTrapFlatSide.hh.

145 {
146  return -xAxisMax(y, -fTAlph ) ;
147 }

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void G4TwistTrapFlatSide::GetFacets ( G4int  m,
G4int  n,
G4double  xyz[][3],
G4int  faces[][4],
G4int  iside 
)
virtual

Implements G4VTwistSurface.

Definition at line 486 of file G4TwistTrapFlatSide.cc.

488 {
489 
490  G4double x,y ; // the two parameters for the surface equation
491  G4ThreeVector p ; // a point on the surface, given by (z,u)
492 
493  G4int nnode ;
494  G4int nface ;
495 
496  G4double xmin,xmax ;
497 
498  // calculate the (n-1)*(k-1) vertices
499 
500  G4int i,j ;
501 
502  for ( i = 0 ; i<n ; i++ ) {
503 
504  y = -fDy + i*(2*fDy)/(n-1) ;
505 
506  for ( j = 0 ; j<k ; j++ ) {
507 
508  xmin = GetBoundaryMin(y) ;
509  xmax = GetBoundaryMax(y) ;
510  x = xmin + j*(xmax-xmin)/(k-1) ;
511 
512  nnode = GetNode(i,j,k,n,iside) ;
513  p = SurfacePoint(x,y,true) ; // surface point in global coordinate system
514 
515  xyz[nnode][0] = p.x() ;
516  xyz[nnode][1] = p.y() ;
517  xyz[nnode][2] = p.z() ;
518 
519  if ( i<n-1 && j<k-1 ) {
520 
521  nface = GetFace(i,j,k,n,iside) ;
522 
523  if (fHandedness < 0) { // lower side
524  faces[nface][0] = GetEdgeVisibility(i,j,k,n,0,1) * ( GetNode(i ,j ,k,n,iside)+1) ;
525  faces[nface][1] = GetEdgeVisibility(i,j,k,n,1,1) * ( GetNode(i+1,j ,k,n,iside)+1) ;
526  faces[nface][2] = GetEdgeVisibility(i,j,k,n,2,1) * ( GetNode(i+1,j+1,k,n,iside)+1) ;
527  faces[nface][3] = GetEdgeVisibility(i,j,k,n,3,1) * ( GetNode(i ,j+1,k,n,iside)+1) ;
528  } else { // upper side
529  faces[nface][0] = GetEdgeVisibility(i,j,k,n,0,-1) * ( GetNode(i ,j ,k,n,iside)+1) ;
530  faces[nface][1] = GetEdgeVisibility(i,j,k,n,1,-1) * ( GetNode(i ,j+1,k,n,iside)+1) ;
531  faces[nface][2] = GetEdgeVisibility(i,j,k,n,2,-1) * ( GetNode(i+1,j+1,k,n,iside)+1) ;
532  faces[nface][3] = GetEdgeVisibility(i,j,k,n,3,-1) * ( GetNode(i+1,j ,k,n,iside)+1) ;
533  }
534 
535  }
536  }
537  }
538 }
virtual G4ThreeVector SurfacePoint(G4double x, G4double y, G4bool isGlobal=false)
double x() const
const char * p
Definition: xmltok.h:285
tuple x
Definition: test.py:50
int G4int
Definition: G4Types.hh:78
double z() const
const G4int n
virtual G4double GetBoundaryMin(G4double u)
G4int GetNode(G4int i, G4int j, G4int m, G4int n, G4int iside)
virtual G4double GetBoundaryMax(G4double u)
double y() const
G4int GetFace(G4int i, G4int j, G4int m, G4int n, G4int iside)
double G4double
Definition: G4Types.hh:76
G4int GetEdgeVisibility(G4int i, G4int j, G4int m, G4int n, G4int number, G4int orientation)

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G4ThreeVector G4TwistTrapFlatSide::GetNormal ( const G4ThreeVector ,
G4bool  isGlobal = false 
)
virtual

Implements G4VTwistSurface.

Definition at line 123 of file G4TwistTrapFlatSide.cc.

125 {
126  if (isGlobal) {
128  } else {
129  return fCurrentNormal.normal;
130  }
131 }
G4ThreeVector ComputeGlobalDirection(const G4ThreeVector &lp) const
G4SurfCurNormal fCurrentNormal

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G4double G4TwistTrapFlatSide::GetSurfaceArea ( )
inlinevirtual

Implements G4VTwistSurface.

Definition at line 156 of file G4TwistTrapFlatSide.hh.

157 {
158  return 2*(fDx1 + fDx2)*fDy ;
159 }
G4ThreeVector G4TwistTrapFlatSide::SurfacePoint ( G4double  x,
G4double  y,
G4bool  isGlobal = false 
)
inlinevirtual

Implements G4VTwistSurface.

Definition at line 135 of file G4TwistTrapFlatSide.hh.

136 {
137  G4ThreeVector SurfPoint ( x,y,0);
138 
139  if (isGlobal) { return (fRot*SurfPoint + fTrans); }
140  return SurfPoint;
141 }
tuple x
Definition: test.py:50
G4RotationMatrix fRot
G4ThreeVector fTrans

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The documentation for this class was generated from the following files: