2 // Created: 08.09.05 20:32:39
3 // Author: Alexander GRIGORIEV
4 // Copyright: Open Cascade 2005
6 inline Standard_Boolean _compareDist (const RealType aHSize[3],
7 const RealType aDist [3])
9 return (Abs(aDist[0]) > aHSize[0] ||
10 Abs(aDist[1]) > aHSize[1] ||
11 Abs(aDist[2]) > aHSize[2]);
14 inline Standard_Boolean _compareDistD (const gp_XYZ& aHSize,const gp_XYZ& aDist)
16 return (Abs(aDist.X()) > aHSize.X() ||
17 Abs(aDist.Y()) > aHSize.Y() ||
18 Abs(aDist.Z()) > aHSize.Z());
21 //=======================================================================
23 //purpose : Update the box by a point
24 //=======================================================================
26 void Bnd_B3x::Add (const gp_XYZ& thePnt) {
28 myCenter[0] = RealType(thePnt.X());
29 myCenter[1] = RealType(thePnt.Y());
30 myCenter[2] = RealType(thePnt.Z());
35 const RealType aDiff[3] = {
36 RealType(thePnt.X()) - myCenter[0],
37 RealType(thePnt.Y()) - myCenter[1],
38 RealType(thePnt.Z()) - myCenter[2]
40 if (aDiff[0] > myHSize[0]) {
41 const RealType aShift = (aDiff[0] - myHSize[0]) / 2;
42 myCenter[0] += aShift;
43 myHSize [0] += aShift;
44 } else if (aDiff[0] < -myHSize[0]) {
45 const RealType aShift = (aDiff[0] + myHSize[0]) / 2;
46 myCenter[0] += aShift;
47 myHSize [0] -= aShift;
49 if (aDiff[1] > myHSize[1]) {
50 const RealType aShift = (aDiff[1] - myHSize[1]) / 2;
53 } else if (aDiff[1] < -myHSize[1]) {
54 const RealType aShift = (aDiff[1] + myHSize[1]) / 2;
55 myCenter[1] += aShift;
56 myHSize [1] -= aShift;
58 if (aDiff[2] > myHSize[2]) {
59 const RealType aShift = (aDiff[2] - myHSize[2]) / 2;
62 } else if (aDiff[2] < -myHSize[2]) {
63 const RealType aShift = (aDiff[2] + myHSize[2]) / 2;
64 myCenter[2] += aShift;
65 myHSize [2] -= aShift;
70 //=======================================================================
72 //purpose : limit the current box with the internals of theBox
73 //=======================================================================
75 Standard_Boolean Bnd_B3x::Limit (const Bnd_B3x& theBox)
77 Standard_Boolean aResult (Standard_False);
78 const RealType diffC[3] = {
79 theBox.myCenter[0] - myCenter[0],
80 theBox.myCenter[1] - myCenter[1],
81 theBox.myCenter[2] - myCenter[2]
83 const RealType sumH[3] = {
84 theBox.myHSize[0] + myHSize[0],
85 theBox.myHSize[1] + myHSize[1],
86 theBox.myHSize[2] + myHSize[2]
88 // check the condition IsOut
89 if (_compareDist (sumH, diffC) == Standard_False) {
90 const RealType diffH[3] = {
91 theBox.myHSize[0] - myHSize[0],
92 theBox.myHSize[1] - myHSize[1],
93 theBox.myHSize[2] - myHSize[2]
95 if (diffC[0] - diffH[0] > 0.) {
96 const RealType aShift = (diffC[0] - diffH[0]) / 2; // positive
97 myCenter[0] += aShift;
98 myHSize [0] -= aShift;
99 } else if (diffC[0] + diffH[0] < 0.) {
100 const RealType aShift = (diffC[0] + diffH[0]) / 2; // negative
101 myCenter[0] += aShift;
102 myHSize [0] += aShift;
104 if (diffC[1] - diffH[1] > 0.) {
105 const RealType aShift = (diffC[1] - diffH[1]) / 2; // positive
106 myCenter[1] += aShift;
107 myHSize [1] -= aShift;
108 } else if (diffC[1] + diffH[1] < 0.) {
109 const RealType aShift = (diffC[1] + diffH[1]) / 2; // negative
110 myCenter[1] += aShift;
111 myHSize [1] += aShift;
113 if (diffC[2] - diffH[2] > 0.) {
114 const RealType aShift = (diffC[2] - diffH[2]) / 2; // positive
115 myCenter[2] += aShift;
116 myHSize [2] -= aShift;
117 } else if (diffC[2] + diffH[2] < 0.) {
118 const RealType aShift = (diffC[2] + diffH[2]) / 2; // negative
119 myCenter[2] += aShift;
120 myHSize [2] += aShift;
122 aResult = Standard_True;
127 //=======================================================================
128 //function : Transformed
130 //=======================================================================
132 Bnd_B3x Bnd_B3x::Transformed (const gp_Trsf& theTrsf) const
135 const gp_TrsfForm aForm = theTrsf.Form();
136 const Standard_Real aScale = theTrsf.ScaleFactor();
137 const Standard_Real aScaleAbs = Abs(aScale);
138 if (aForm == gp_Identity)
140 else if (aForm== gp_Translation || aForm== gp_PntMirror || aForm== gp_Scale)
142 aResult.myCenter[0] =
143 (RealType)(myCenter[0] * aScale + theTrsf.TranslationPart().X());
144 aResult.myCenter[1] =
145 (RealType)(myCenter[1] * aScale + theTrsf.TranslationPart().Y());
146 aResult.myCenter[2] =
147 (RealType)(myCenter[2] * aScale + theTrsf.TranslationPart().Z());
148 aResult.myHSize[0] = (RealType)(myHSize[0] * aScaleAbs);
149 aResult.myHSize[1] = (RealType)(myHSize[1] * aScaleAbs);
150 aResult.myHSize[2] = (RealType)(myHSize[2] * aScaleAbs);
152 gp_XYZ aCenter ((Standard_Real)myCenter[0],
153 (Standard_Real)myCenter[1],
154 (Standard_Real)myCenter[2]);
155 theTrsf.Transforms (aCenter);
156 aResult.myCenter[0] = (RealType)aCenter.X();
157 aResult.myCenter[1] = (RealType)aCenter.Y();
158 aResult.myCenter[2] = (RealType)aCenter.Z();
160 const Standard_Real * aMat = &theTrsf.HVectorialPart().Value(1,1);
161 aResult.myHSize[0] = (RealType)(aScaleAbs * (Abs(aMat[0]) * myHSize[0]+
162 Abs(aMat[1]) * myHSize[1]+
163 Abs(aMat[2]) * myHSize[2]));
164 aResult.myHSize[1] = (RealType)(aScaleAbs * (Abs(aMat[3]) * myHSize[0]+
165 Abs(aMat[4]) * myHSize[1]+
166 Abs(aMat[5]) * myHSize[2]));
167 aResult.myHSize[2] = (RealType)(aScaleAbs * (Abs(aMat[6]) * myHSize[0]+
168 Abs(aMat[7]) * myHSize[1]+
169 Abs(aMat[8]) * myHSize[2]));
174 //=======================================================================
176 //purpose : Intersection Box - Sphere
177 //=======================================================================
179 Standard_Boolean Bnd_B3x::IsOut (const gp_XYZ& theCenter,
180 const Standard_Real theRadius,
181 const Standard_Boolean isSphereHollow) const
183 Standard_Boolean aResult (Standard_True);
184 if (isSphereHollow == Standard_False) {
185 // vector from the center of the sphere to the nearest box face
186 const Standard_Real aDist[3] = {
187 Abs(theCenter.X()-Standard_Real(myCenter[0])) - Standard_Real(myHSize[0]),
188 Abs(theCenter.Y()-Standard_Real(myCenter[1])) - Standard_Real(myHSize[1]),
189 Abs(theCenter.Z()-Standard_Real(myCenter[2])) - Standard_Real(myHSize[2])
191 Standard_Real aD (0.);
193 aD = aDist[0]*aDist[0];
195 aD += aDist[1]*aDist[1];
197 aD += aDist[2]*aDist[2];
198 aResult = (aD > theRadius*theRadius);
200 const Standard_Real aDistC[3] = {
201 Abs(theCenter.X()-Standard_Real(myCenter[0])),
202 Abs(theCenter.Y()-Standard_Real(myCenter[1])),
203 Abs(theCenter.Z()-Standard_Real(myCenter[2]))
205 // vector from the center of the sphere to the nearest box face
206 Standard_Real aDist[3] = {
207 aDistC[0] - Standard_Real(myHSize[0]),
208 aDistC[1] - Standard_Real(myHSize[1]),
209 aDistC[2] - Standard_Real(myHSize[2])
211 Standard_Real aD (0.);
213 aD = aDist[0]*aDist[0];
215 aD += aDist[1]*aDist[1];
217 aD += aDist[2]*aDist[2];
218 if (aD < theRadius*theRadius) {
219 // the box intersects the solid sphere; check if it is completely
220 // inside the circle (in such case return isOut==True)
221 aDist[0] = aDistC[0] + Standard_Real(myHSize[0]);
222 aDist[1] = aDistC[1] + Standard_Real(myHSize[1]);
223 aDist[2] = aDistC[2] + Standard_Real(myHSize[2]);
224 if (aDist[0]*aDist[0]+aDist[1]*aDist[1]+aDist[2]*aDist[2]
225 > theRadius*theRadius)
226 aResult = Standard_False;
232 //=======================================================================
234 //purpose : Intersection Box - transformed Box
235 //=======================================================================
237 Standard_Boolean Bnd_B3x::IsOut (const Bnd_B3x& theBox,
238 const gp_Trsf& theTrsf) const
240 Standard_Boolean aResult (Standard_False);
241 const gp_TrsfForm aForm = theTrsf.Form();
242 const Standard_Real aScale = theTrsf.ScaleFactor();
243 const Standard_Real aScaleAbs = Abs(aScale);
244 if (aForm == gp_Translation || aForm == gp_Identity ||
245 aForm == gp_PntMirror || aForm == gp_Scale)
248 (Abs (RealType(theBox.myCenter[0]*aScale + theTrsf.TranslationPart().X())
250 > RealType (theBox.myHSize[0]*aScaleAbs) + myHSize[0] ||
251 Abs (RealType(theBox.myCenter[1]*aScale + theTrsf.TranslationPart().Y())
253 > RealType (theBox.myHSize[1]*aScaleAbs) + myHSize[1] ||
254 Abs (RealType(theBox.myCenter[2]*aScale + theTrsf.TranslationPart().Y())
256 > RealType (theBox.myHSize[2]*aScaleAbs) + myHSize[2]);
260 // theBox is transformed and we check the resulting (enlarged) box against
262 const Standard_Real * aMat = &theTrsf.HVectorialPart().Value(1,1);
264 gp_XYZ aCenter ((Standard_Real)theBox.myCenter[0],
265 (Standard_Real)theBox.myCenter[1],
266 (Standard_Real)theBox.myCenter[2]);
267 theTrsf.Transforms (aCenter);
268 const Standard_Real aDist[3] = {
269 aCenter.X() - (Standard_Real)myCenter[0],
270 aCenter.Y() - (Standard_Real)myCenter[1],
271 aCenter.Z() - (Standard_Real)myCenter[2]
273 const Standard_Real aMatAbs[9] = {
274 Abs(aMat[0]), Abs(aMat[1]), Abs(aMat[2]), Abs(aMat[3]), Abs(aMat[4]),
275 Abs(aMat[5]), Abs(aMat[6]), Abs(aMat[7]), Abs(aMat[8])
277 if (Abs(aDist[0]) > (aScaleAbs*(aMatAbs[0]*theBox.myHSize[0]+
278 aMatAbs[1]*theBox.myHSize[1]+
279 aMatAbs[2]*theBox.myHSize[2]) +
280 (Standard_Real)myHSize[0]) ||
281 Abs(aDist[1]) > (aScaleAbs*(aMatAbs[3]*theBox.myHSize[0]+
282 aMatAbs[4]*theBox.myHSize[1]+
283 aMatAbs[5]*theBox.myHSize[2]) +
284 (Standard_Real)myHSize[1]) ||
285 Abs(aDist[2]) > (aScaleAbs*(aMatAbs[6]*theBox.myHSize[0]+
286 aMatAbs[7]*theBox.myHSize[1]+
287 aMatAbs[8]*theBox.myHSize[2]) +
288 (Standard_Real)myHSize[2]))
289 aResult = Standard_True;
292 // theBox is rotated, scaled and translated. We apply the reverse
293 // translation and scaling then check against the rotated box 'this'
294 if ((Abs(aMat[0]*aDist[0]+aMat[3]*aDist[1]+aMat[6]*aDist[2])
295 > theBox.myHSize[0]*aScaleAbs + (aMatAbs[0]*myHSize[0] +
296 aMatAbs[3]*myHSize[1] +
297 aMatAbs[6]*myHSize[2])) ||
298 (Abs(aMat[1]*aDist[0]+aMat[4]*aDist[1]+aMat[7]*aDist[2])
299 > theBox.myHSize[1]*aScaleAbs + (aMatAbs[1]*myHSize[0] +
300 aMatAbs[4]*myHSize[1] +
301 aMatAbs[7]*myHSize[2])) ||
302 (Abs(aMat[2]*aDist[0]+aMat[5]*aDist[1]+aMat[8]*aDist[2])
303 > theBox.myHSize[2]*aScaleAbs + (aMatAbs[2]*myHSize[0] +
304 aMatAbs[5]*myHSize[1] +
305 aMatAbs[8]*myHSize[2])))
306 aResult = Standard_True;
312 //=======================================================================
315 //=======================================================================
317 Standard_Boolean Bnd_B3x::IsOut (const gp_Ax3& thePlane) const
320 return Standard_True;
321 const gp_XYZ& anOrigin = thePlane.Location().XYZ();
322 const gp_XYZ& aDir = thePlane.Direction().XYZ();
323 const gp_XYZ aBoxCenter ((Standard_Real)myCenter[0],
324 (Standard_Real)myCenter[1],
325 (Standard_Real)myCenter[2]);
326 const Standard_Real aDist0 = (aBoxCenter - anOrigin) * aDir;
327 // Find the signed distances from two opposite corners of the box to the plane
328 // If the distances are not the same sign, then the plane crosses the box
329 const Standard_Real aDist1 = // proj of HSize on aDir
330 Standard_Real(myHSize[0]) * Abs(aDir.X()) +
331 Standard_Real(myHSize[1]) * Abs(aDir.Y()) +
332 Standard_Real(myHSize[2]) * Abs(aDir.Z());
333 return ((aDist0 + aDist1) * (aDist0 - aDist1) > 0.);
336 //=======================================================================
339 //=======================================================================
341 Standard_Boolean Bnd_B3x::IsOut (const gp_Ax1& theLine,
342 const Standard_Boolean isRay,
343 const Standard_Real theOverthickness) const
345 const Standard_Real aRes = gp::Resolution() * 100.;
347 return Standard_True;
349 anInter0[2] = {-RealLast(), RealLast()},
350 anInter1[2] = {-RealLast(), RealLast()};
351 const gp_XYZ& aDir = theLine.Direction().XYZ();
352 const gp_XYZ aDiff ((Standard_Real)myCenter[0] - theLine.Location().X(),
353 (Standard_Real)myCenter[1] - theLine.Location().Y(),
354 (Standard_Real)myCenter[2] - theLine.Location().Z());
356 // Find the parameter interval in X dimention
357 Standard_Real aHSize = (Standard_Real)myHSize[0]+theOverthickness;
358 if (aDir.X() > aRes) {
359 anInter0[0]= (aDiff.X() - aHSize) / aDir.X();
360 anInter0[1]= (aDiff.X() + aHSize) / aDir.X();
361 } else if (aDir.X() < -aRes) {
362 anInter0[0]= (aDiff.X() + aHSize) / aDir.X();
363 anInter0[1]= (aDiff.X() - aHSize) / aDir.X();
365 // the line is orthogonal to OX axis. Test for inclusion in box limits
366 if (Abs(aDiff.X()) > aHSize)
367 return Standard_True;
369 // Find the parameter interval in Y dimention
370 aHSize = (Standard_Real)myHSize[1]+theOverthickness;
371 if (aDir.Y() > aRes) {
372 anInter1[0]= (aDiff.Y() - aHSize) / aDir.Y();
373 anInter1[1]= (aDiff.Y() + aHSize) / aDir.Y();
374 } else if (aDir.Y() < -aRes) {
375 anInter1[0]= (aDiff.Y() + aHSize) / aDir.Y();
376 anInter1[1]= (aDiff.Y() - aHSize) / aDir.Y();
378 // the line is orthogonal to OY axis. Test for inclusion in box limits
379 if (Abs(aDiff.Y()) > aHSize)
380 return Standard_True;
382 // Intersect Y-interval with X-interval
383 if (anInter0[0] > (anInter1[1] + aRes) || anInter0[1] < (anInter1[0] - aRes))
384 return Standard_True;
385 if (anInter1[0] > anInter0[0])
386 anInter0[0] = anInter1[0];
387 if (anInter1[1] < anInter0[1])
388 anInter0[1] = anInter1[1];
389 if (isRay && anInter0[1] < -aRes)
390 return Standard_True;
392 // Find the parameter interval in Z dimention
393 aHSize = (Standard_Real)myHSize[2]+theOverthickness;
394 if (aDir.Z() > aRes) {
395 anInter1[0]= (aDiff.Z() - aHSize) / aDir.Z();
396 anInter1[1]= (aDiff.Z() + aHSize) / aDir.Z();
397 } else if (aDir.Z() < -aRes) {
398 anInter1[0]= (aDiff.Z() + aHSize) / aDir.Z();
399 anInter1[1]= (aDiff.Z() - aHSize) / aDir.Z();
401 // the line is orthogonal to OZ axis. Test for inclusion in box limits
402 return (Abs(aDiff.Z()) > aHSize);
403 if (isRay && anInter1[1] < -aRes)
404 return Standard_True;
406 return (anInter0[0] > (anInter1[1]+aRes) || anInter0[1] < (anInter1[0]-aRes));
409 //=======================================================================
411 //purpose : Test the complete inclusion of this box in transformed theOtherBox
412 //=======================================================================
414 Standard_Boolean Bnd_B3x::IsIn (const Bnd_B3x& theBox,
415 const gp_Trsf& theTrsf) const
417 Standard_Boolean aResult (Standard_False);
418 const gp_TrsfForm aForm = theTrsf.Form();
419 const Standard_Real aScale = theTrsf.ScaleFactor();
420 const Standard_Real aScaleAbs = Abs(aScale);
421 if (aForm == gp_Translation || aForm == gp_Identity ||
422 aForm == gp_PntMirror || aForm == gp_Scale)
425 (Abs (RealType(theBox.myCenter[0]*aScale + theTrsf.TranslationPart().X())
427 < RealType (theBox.myHSize[0]*aScaleAbs) - myHSize[0] &&
428 Abs (RealType(theBox.myCenter[1]*aScale + theTrsf.TranslationPart().Y())
430 < RealType (theBox.myHSize[1]*aScaleAbs) - myHSize[1] &&
431 Abs (RealType(theBox.myCenter[2]*aScale + theTrsf.TranslationPart().Y())
433 < RealType (theBox.myHSize[2]*aScaleAbs) - myHSize[2]);
436 // theBox is rotated, scaled and translated. We apply the reverse
437 // translation and scaling then check against the rotated box 'this'
438 const Standard_Real * aMat = &theTrsf.HVectorialPart().Value(1,1);
439 gp_XYZ aCenter ((Standard_Real)theBox.myCenter[0],
440 (Standard_Real)theBox.myCenter[1],
441 (Standard_Real)theBox.myCenter[2]);
442 theTrsf.Transforms (aCenter);
443 const Standard_Real aDist[3] = {
444 aCenter.X() - (Standard_Real)myCenter[0],
445 aCenter.Y() - (Standard_Real)myCenter[1],
446 aCenter.Z() - (Standard_Real)myCenter[2]
448 if ((Abs(aMat[0]*aDist[0]+aMat[3]*aDist[1]+aMat[6]*aDist[2])
449 < theBox.myHSize[0]*aScaleAbs - (Abs(aMat[0])*myHSize[0] +
450 Abs(aMat[3])*myHSize[1] +
451 Abs(aMat[6])*myHSize[2])) &&
452 (Abs(aMat[1]*aDist[0]+aMat[4]*aDist[1]+aMat[7]*aDist[2])
453 < theBox.myHSize[1]*aScaleAbs - (Abs(aMat[1])*myHSize[0] +
454 Abs(aMat[4])*myHSize[1] +
455 Abs(aMat[7])*myHSize[2])) &&
456 (Abs(aMat[2]*aDist[0]+aMat[5]*aDist[1]+aMat[8]*aDist[2])
457 < theBox.myHSize[2]*aScaleAbs - (Abs(aMat[2])*myHSize[0] +
458 Abs(aMat[5])*myHSize[1] +
459 Abs(aMat[8])*myHSize[2])))
460 aResult = Standard_True;