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source: code/archive/tutorial5/src/external/bullet/BulletCollision/NarrowPhaseCollision/btGjkPairDetector.cpp @ 11947

Last change on this file since 11947 was 8393, checked in by rgrieder, 15 years ago

Updated Bullet from v2.77 to v2.78.
(I'm not going to make a branch for that since the update from 2.74 to 2.77 hasn't been tested that much either).

You will HAVE to do a complete RECOMPILE! I tested with MSVC and MinGW and they both threw linker errors at me.

Property svn:eol-style set to native

File size: 13.7 KB

Line
1	/*
2	Bullet Continuous Collision Detection and Physics Library
3	Copyright (c) 2003-2006 Erwin Coumans http://continuousphysics.com/Bullet/
4
5	This software is provided 'as-is', without any express or implied warranty.
6	In no event will the authors be held liable for any damages arising from the use of this software.
7	Permission is granted to anyone to use this software for any purpose,
8	including commercial applications, and to alter it and redistribute it freely,
9	subject to the following restrictions:
10
11	1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required.
12	2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
13	3. This notice may not be removed or altered from any source distribution.
14	*/
15
16	#include "btGjkPairDetector.h"
17	#include "BulletCollision/CollisionShapes/btConvexShape.h"
18	#include "BulletCollision/NarrowPhaseCollision/btSimplexSolverInterface.h"
19	#include "BulletCollision/NarrowPhaseCollision/btConvexPenetrationDepthSolver.h"
20
21
22
23	#if defined(DEBUG) \|\| defined (_DEBUG)
24	//#define TEST_NON_VIRTUAL 1
25	#include <stdio.h> //for debug printf
26	#ifdef __SPU__
27	#include <spu_printf.h>
28	#define printf spu_printf
29	//#define DEBUG_SPU_COLLISION_DETECTION 1
30	#endif //__SPU__
31	#endif
32
33	//must be above the machine epsilon
34	#define REL_ERROR2 btScalar(1.0e-6)
35
36	//temp globals, to improve GJK/EPA/penetration calculations
37	int gNumDeepPenetrationChecks = 0;
38	int gNumGjkChecks = 0;
39
40
41	btGjkPairDetector::btGjkPairDetector(const btConvexShape* objectA,const btConvexShape* objectB,btSimplexSolverInterface* simplexSolver,btConvexPenetrationDepthSolver* penetrationDepthSolver)
42	:m_cachedSeparatingAxis(btScalar(0.),btScalar(1.),btScalar(0.)),
43	m_penetrationDepthSolver(penetrationDepthSolver),
44	m_simplexSolver(simplexSolver),
45	m_minkowskiA(objectA),
46	m_minkowskiB(objectB),
47	m_shapeTypeA(objectA->getShapeType()),
48	m_shapeTypeB(objectB->getShapeType()),
49	m_marginA(objectA->getMargin()),
50	m_marginB(objectB->getMargin()),
51	m_ignoreMargin(false),
52	m_lastUsedMethod(-1),
53	m_catchDegeneracies(1)
54	{
55	}
56	btGjkPairDetector::btGjkPairDetector(const btConvexShape* objectA,const btConvexShape* objectB,int shapeTypeA,int shapeTypeB,btScalar marginA, btScalar marginB, btSimplexSolverInterface* simplexSolver,btConvexPenetrationDepthSolver* penetrationDepthSolver)
57	:m_cachedSeparatingAxis(btScalar(0.),btScalar(1.),btScalar(0.)),
58	m_penetrationDepthSolver(penetrationDepthSolver),
59	m_simplexSolver(simplexSolver),
60	m_minkowskiA(objectA),
61	m_minkowskiB(objectB),
62	m_shapeTypeA(shapeTypeA),
63	m_shapeTypeB(shapeTypeB),
64	m_marginA(marginA),
65	m_marginB(marginB),
66	m_ignoreMargin(false),
67	m_lastUsedMethod(-1),
68	m_catchDegeneracies(1)
69	{
70	}
71
72	void btGjkPairDetector::getClosestPoints(const ClosestPointInput& input,Result& output,class btIDebugDraw* debugDraw,bool swapResults)
73	{
74	(void)swapResults;
75
76	getClosestPointsNonVirtual(input,output,debugDraw);
77	}
78
79	#ifdef __SPU__
80	void btGjkPairDetector::getClosestPointsNonVirtual(const ClosestPointInput& input,Result& output,class btIDebugDraw* debugDraw)
81	#else
82	void btGjkPairDetector::getClosestPointsNonVirtual(const ClosestPointInput& input,Result& output,class btIDebugDraw* debugDraw)
83	#endif
84	{
85	m_cachedSeparatingDistance = 0.f;
86
87	btScalar distance=btScalar(0.);
88	btVector3 normalInB(btScalar(0.),btScalar(0.),btScalar(0.));
89	btVector3 pointOnA,pointOnB;
90	btTransform localTransA = input.m_transformA;
91	btTransform localTransB = input.m_transformB;
92	btVector3 positionOffset = (localTransA.getOrigin() + localTransB.getOrigin()) * btScalar(0.5);
93	localTransA.getOrigin() -= positionOffset;
94	localTransB.getOrigin() -= positionOffset;
95
96	bool check2d = m_minkowskiA->isConvex2d() && m_minkowskiB->isConvex2d();
97
98	btScalar marginA = m_marginA;
99	btScalar marginB = m_marginB;
100
101	gNumGjkChecks++;
102
103	#ifdef DEBUG_SPU_COLLISION_DETECTION
104	spu_printf("inside gjk\n");
105	#endif
106	//for CCD we don't use margins
107	if (m_ignoreMargin)
108	{
109	marginA = btScalar(0.);
110	marginB = btScalar(0.);
111	#ifdef DEBUG_SPU_COLLISION_DETECTION
112	spu_printf("ignoring margin\n");
113	#endif
114	}
115
116	m_curIter = 0;
117	int gGjkMaxIter = 1000;//this is to catch invalid input, perhaps check for #NaN?
118	m_cachedSeparatingAxis.setValue(0,1,0);
119
120	bool isValid = false;
121	bool checkSimplex = false;
122	bool checkPenetration = true;
123	m_degenerateSimplex = 0;
124
125	m_lastUsedMethod = -1;
126
127	{
128	btScalar squaredDistance = BT_LARGE_FLOAT;
129	btScalar delta = btScalar(0.);
130
131	btScalar margin = marginA + marginB;
132
133
134
135	m_simplexSolver->reset();
136
137	for ( ; ; )
138	//while (true)
139	{
140
141	btVector3 seperatingAxisInA = (-m_cachedSeparatingAxis)* input.m_transformA.getBasis();
142	btVector3 seperatingAxisInB = m_cachedSeparatingAxis* input.m_transformB.getBasis();
143
144	#if 1
145
146	btVector3 pInA = m_minkowskiA->localGetSupportVertexWithoutMarginNonVirtual(seperatingAxisInA);
147	btVector3 qInB = m_minkowskiB->localGetSupportVertexWithoutMarginNonVirtual(seperatingAxisInB);
148
149	// btVector3 pInA = localGetSupportingVertexWithoutMargin(m_shapeTypeA, m_minkowskiA, seperatingAxisInA,input.m_convexVertexData[0]);//, &featureIndexA);
150	// btVector3 qInB = localGetSupportingVertexWithoutMargin(m_shapeTypeB, m_minkowskiB, seperatingAxisInB,input.m_convexVertexData[1]);//, &featureIndexB);
151
152	#else
153	#ifdef __SPU__
154	btVector3 pInA = m_minkowskiA->localGetSupportVertexWithoutMarginNonVirtual(seperatingAxisInA);
155	btVector3 qInB = m_minkowskiB->localGetSupportVertexWithoutMarginNonVirtual(seperatingAxisInB);
156	#else
157	btVector3 pInA = m_minkowskiA->localGetSupportingVertexWithoutMargin(seperatingAxisInA);
158	btVector3 qInB = m_minkowskiB->localGetSupportingVertexWithoutMargin(seperatingAxisInB);
159	#ifdef TEST_NON_VIRTUAL
160	btVector3 pInAv = m_minkowskiA->localGetSupportingVertexWithoutMargin(seperatingAxisInA);
161	btVector3 qInBv = m_minkowskiB->localGetSupportingVertexWithoutMargin(seperatingAxisInB);
162	btAssert((pInAv-pInA).length() < 0.0001);
163	btAssert((qInBv-qInB).length() < 0.0001);
164	#endif //
165	#endif //__SPU__
166	#endif
167
168
169	btVector3 pWorld = localTransA(pInA);
170	btVector3 qWorld = localTransB(qInB);
171
172	#ifdef DEBUG_SPU_COLLISION_DETECTION
173	spu_printf("got local supporting vertices\n");
174	#endif
175
176	if (check2d)
177	{
178	pWorld[2] = 0.f;
179	qWorld[2] = 0.f;
180	}
181
182	btVector3 w = pWorld - qWorld;
183	delta = m_cachedSeparatingAxis.dot(w);
184
185	// potential exit, they don't overlap
186	if ((delta > btScalar(0.0)) && (delta * delta > squaredDistance * input.m_maximumDistanceSquared))
187	{
188	m_degenerateSimplex = 10;
189	checkSimplex=true;
190	//checkPenetration = false;
191	break;
192	}
193
194	//exit 0: the new point is already in the simplex, or we didn't come any closer
195	if (m_simplexSolver->inSimplex(w))
196	{
197	m_degenerateSimplex = 1;
198	checkSimplex = true;
199	break;
200	}
201	// are we getting any closer ?
202	btScalar f0 = squaredDistance - delta;
203	btScalar f1 = squaredDistance * REL_ERROR2;
204
205	if (f0 <= f1)
206	{
207	if (f0 <= btScalar(0.))
208	{
209	m_degenerateSimplex = 2;
210	} else
211	{
212	m_degenerateSimplex = 11;
213	}
214	checkSimplex = true;
215	break;
216	}
217
218	#ifdef DEBUG_SPU_COLLISION_DETECTION
219	spu_printf("addVertex 1\n");
220	#endif
221	//add current vertex to simplex
222	m_simplexSolver->addVertex(w, pWorld, qWorld);
223	#ifdef DEBUG_SPU_COLLISION_DETECTION
224	spu_printf("addVertex 2\n");
225	#endif
226	btVector3 newCachedSeparatingAxis;
227
228	//calculate the closest point to the origin (update vector v)
229	if (!m_simplexSolver->closest(newCachedSeparatingAxis))
230	{
231	m_degenerateSimplex = 3;
232	checkSimplex = true;
233	break;
234	}
235
236	if(newCachedSeparatingAxis.length2()<REL_ERROR2)
237	{
238	m_cachedSeparatingAxis = newCachedSeparatingAxis;
239	m_degenerateSimplex = 6;
240	checkSimplex = true;
241	break;
242	}
243
244	btScalar previousSquaredDistance = squaredDistance;
245	squaredDistance = newCachedSeparatingAxis.length2();
246	#if 0
247	///warning: this termination condition leads to some problems in 2d test case see Bullet/Demos/Box2dDemo
248	if (squaredDistance>previousSquaredDistance)
249	{
250	m_degenerateSimplex = 7;
251	squaredDistance = previousSquaredDistance;
252	checkSimplex = false;
253	break;
254	}
255	#endif //
256
257
258	//redundant m_simplexSolver->compute_points(pointOnA, pointOnB);
259
260	//are we getting any closer ?
261	if (previousSquaredDistance - squaredDistance <= SIMD_EPSILON * previousSquaredDistance)
262	{
263	// m_simplexSolver->backup_closest(m_cachedSeparatingAxis);
264	checkSimplex = true;
265	m_degenerateSimplex = 12;
266
267	break;
268	}
269
270	m_cachedSeparatingAxis = newCachedSeparatingAxis;
271
272	//degeneracy, this is typically due to invalid/uninitialized worldtransforms for a btCollisionObject
273	if (m_curIter++ > gGjkMaxIter)
274	{
275	#if defined(DEBUG) \|\| defined (_DEBUG) \|\| defined (DEBUG_SPU_COLLISION_DETECTION)
276
277	printf("btGjkPairDetector maxIter exceeded:%i\n",m_curIter);
278	printf("sepAxis=(%f,%f,%f), squaredDistance = %f, shapeTypeA=%i,shapeTypeB=%i\n",
279	m_cachedSeparatingAxis.getX(),
280	m_cachedSeparatingAxis.getY(),
281	m_cachedSeparatingAxis.getZ(),
282	squaredDistance,
283	m_minkowskiA->getShapeType(),
284	m_minkowskiB->getShapeType());
285
286	#endif
287	break;
288
289	}
290
291
292	bool check = (!m_simplexSolver->fullSimplex());
293	//bool check = (!m_simplexSolver->fullSimplex() && squaredDistance > SIMD_EPSILON * m_simplexSolver->maxVertex());
294
295	if (!check)
296	{
297	//do we need this backup_closest here ?
298	// m_simplexSolver->backup_closest(m_cachedSeparatingAxis);
299	m_degenerateSimplex = 13;
300	break;
301	}
302	}
303
304	if (checkSimplex)
305	{
306	m_simplexSolver->compute_points(pointOnA, pointOnB);
307	normalInB = m_cachedSeparatingAxis;
308	btScalar lenSqr =m_cachedSeparatingAxis.length2();
309
310	//valid normal
311	if (lenSqr < 0.0001)
312	{
313	m_degenerateSimplex = 5;
314	}
315	if (lenSqr > SIMD_EPSILON*SIMD_EPSILON)
316	{
317	btScalar rlen = btScalar(1.) / btSqrt(lenSqr );
318	normalInB *= rlen; //normalize
319	btScalar s = btSqrt(squaredDistance);
320
321	btAssert(s > btScalar(0.0));
322	pointOnA -= m_cachedSeparatingAxis * (marginA / s);
323	pointOnB += m_cachedSeparatingAxis * (marginB / s);
324	distance = ((btScalar(1.)/rlen) - margin);
325	isValid = true;
326
327	m_lastUsedMethod = 1;
328	} else
329	{
330	m_lastUsedMethod = 2;
331	}
332	}
333
334	bool catchDegeneratePenetrationCase =
335	(m_catchDegeneracies && m_penetrationDepthSolver && m_degenerateSimplex && ((distance+margin) < 0.01));
336
337	//if (checkPenetration && !isValid)
338	if (checkPenetration && (!isValid \|\| catchDegeneratePenetrationCase ))
339	{
340	//penetration case
341
342	//if there is no way to handle penetrations, bail out
343	if (m_penetrationDepthSolver)
344	{
345	// Penetration depth case.
346	btVector3 tmpPointOnA,tmpPointOnB;
347
348	gNumDeepPenetrationChecks++;
349	m_cachedSeparatingAxis.setZero();
350
351	bool isValid2 = m_penetrationDepthSolver->calcPenDepth(
352	*m_simplexSolver,
353	m_minkowskiA,m_minkowskiB,
354	localTransA,localTransB,
355	m_cachedSeparatingAxis, tmpPointOnA, tmpPointOnB,
356	debugDraw,input.m_stackAlloc
357	);
358
359
360	if (isValid2)
361	{
362	btVector3 tmpNormalInB = tmpPointOnB-tmpPointOnA;
363	btScalar lenSqr = tmpNormalInB.length2();
364	if (lenSqr <= (SIMD_EPSILON*SIMD_EPSILON))
365	{
366	tmpNormalInB = m_cachedSeparatingAxis;
367	lenSqr = m_cachedSeparatingAxis.length2();
368	}
369
370	if (lenSqr > (SIMD_EPSILON*SIMD_EPSILON))
371	{
372	tmpNormalInB /= btSqrt(lenSqr);
373	btScalar distance2 = -(tmpPointOnA-tmpPointOnB).length();
374	//only replace valid penetrations when the result is deeper (check)
375	if (!isValid \|\| (distance2 < distance))
376	{
377	distance = distance2;
378	pointOnA = tmpPointOnA;
379	pointOnB = tmpPointOnB;
380	normalInB = tmpNormalInB;
381	isValid = true;
382	m_lastUsedMethod = 3;
383	} else
384	{
385	m_lastUsedMethod = 8;
386	}
387	} else
388	{
389	m_lastUsedMethod = 9;
390	}
391	} else
392
393	{
394	///this is another degenerate case, where the initial GJK calculation reports a degenerate case
395	///EPA reports no penetration, and the second GJK (using the supporting vector without margin)
396	///reports a valid positive distance. Use the results of the second GJK instead of failing.
397	///thanks to Jacob.Langford for the reproduction case
398	///http://code.google.com/p/bullet/issues/detail?id=250
399
400
401	if (m_cachedSeparatingAxis.length2() > btScalar(0.))
402	{
403	btScalar distance2 = (tmpPointOnA-tmpPointOnB).length()-margin;
404	//only replace valid distances when the distance is less
405	if (!isValid \|\| (distance2 < distance))
406	{
407	distance = distance2;
408	pointOnA = tmpPointOnA;
409	pointOnB = tmpPointOnB;
410	pointOnA -= m_cachedSeparatingAxis * marginA ;
411	pointOnB += m_cachedSeparatingAxis * marginB ;
412	normalInB = m_cachedSeparatingAxis;
413	normalInB.normalize();
414	isValid = true;
415	m_lastUsedMethod = 6;
416	} else
417	{
418	m_lastUsedMethod = 5;
419	}
420	}
421	}
422
423	}
424
425	}
426	}
427
428
429
430	if (isValid && ((distance < 0) \|\| (distance*distance < input.m_maximumDistanceSquared)))
431	{
432	#if 0
433	///some debugging
434	// if (check2d)
435	{
436	printf("n = %2.3f,%2.3f,%2.3f. ",normalInB[0],normalInB[1],normalInB[2]);
437	printf("distance = %2.3f exit=%d deg=%d\n",distance,m_lastUsedMethod,m_degenerateSimplex);
438	}
439	#endif
440
441	m_cachedSeparatingAxis = normalInB;
442	m_cachedSeparatingDistance = distance;
443
444	output.addContactPoint(
445	normalInB,
446	pointOnB+positionOffset,
447	distance);
448
449	}
450
451
452	}
453
454
455
456
457

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