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source: code/trunk/src/external/bullet/BulletCollision/Gimpact/btBoxCollision.h @ 5738

Last change on this file since 5738 was 5738, checked in by landauf, 15 years ago
merged libraries2 back to trunk
Property svn:eol-style set to `native`
File size: 17.5 KB

Line
1	#ifndef BT_BOX_COLLISION_H_INCLUDED
2	#define BT_BOX_COLLISION_H_INCLUDED
3
4	/*! \file gim_box_collision.h
5	\author Francisco Len Nßjera
6	*/
7	/*
8	This source file is part of GIMPACT Library.
9
10	For the latest info, see http://gimpact.sourceforge.net/
11
12	Copyright (c) 2007 Francisco Leon Najera. C.C. 80087371.
13	email: projectileman@yahoo.com
14
15
16	This software is provided 'as-is', without any express or implied warranty.
17	In no event will the authors be held liable for any damages arising from the use of this software.
18	Permission is granted to anyone to use this software for any purpose,
19	including commercial applications, and to alter it and redistribute it freely,
20	subject to the following restrictions:
21
22	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.
23	2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
24	3. This notice may not be removed or altered from any source distribution.
25	*/
26
27	#include "LinearMath/btTransform.h"
28
29
30	///Swap numbers
31	#define BT_SWAP_NUMBERS(a,b){ \
32	a = a+b; \
33	b = a-b; \
34	a = a-b; \
35	}\
36
37
38	#define BT_MAX(a,b) (a<b?b:a)
39	#define BT_MIN(a,b) (a>b?b:a)
40
41	#define BT_GREATER(x, y) btFabs(x) > (y)
42
43	#define BT_MAX3(a,b,c) BT_MAX(a,BT_MAX(b,c))
44	#define BT_MIN3(a,b,c) BT_MIN(a,BT_MIN(b,c))
45
46
47
48
49
50
51	enum eBT_PLANE_INTERSECTION_TYPE
52	{
53	BT_CONST_BACK_PLANE = 0,
54	BT_CONST_COLLIDE_PLANE,
55	BT_CONST_FRONT_PLANE
56	};
57
58	//SIMD_FORCE_INLINE bool test_cross_edge_box(
59	// const btVector3 & edge,
60	// const btVector3 & absolute_edge,
61	// const btVector3 & pointa,
62	// const btVector3 & pointb, const btVector3 & extend,
63	// int dir_index0,
64	// int dir_index1
65	// int component_index0,
66	// int component_index1)
67	//{
68	// // dir coords are -z and y
69	//
70	// const btScalar dir0 = -edge[dir_index0];
71	// const btScalar dir1 = edge[dir_index1];
72	// btScalar pmin = pointa[component_index0]dir0 + pointa[component_index1]dir1;
73	// btScalar pmax = pointb[component_index0]dir0 + pointb[component_index1]dir1;
74	// //find minmax
75	// if(pmin>pmax)
76	// {
77	// BT_SWAP_NUMBERS(pmin,pmax);
78	// }
79	// //find extends
80	// const btScalar rad = extend[component_index0] * absolute_edge[dir_index0] +
81	// extend[component_index1] * absolute_edge[dir_index1];
82	//
83	// if(pmin>rad \|\| -rad>pmax) return false;
84	// return true;
85	//}
86	//
87	//SIMD_FORCE_INLINE bool test_cross_edge_box_X_axis(
88	// const btVector3 & edge,
89	// const btVector3 & absolute_edge,
90	// const btVector3 & pointa,
91	// const btVector3 & pointb, btVector3 & extend)
92	//{
93	//
94	// return test_cross_edge_box(edge,absolute_edge,pointa,pointb,extend,2,1,1,2);
95	//}
96	//
97	//
98	//SIMD_FORCE_INLINE bool test_cross_edge_box_Y_axis(
99	// const btVector3 & edge,
100	// const btVector3 & absolute_edge,
101	// const btVector3 & pointa,
102	// const btVector3 & pointb, btVector3 & extend)
103	//{
104	//
105	// return test_cross_edge_box(edge,absolute_edge,pointa,pointb,extend,0,2,2,0);
106	//}
107	//
108	//SIMD_FORCE_INLINE bool test_cross_edge_box_Z_axis(
109	// const btVector3 & edge,
110	// const btVector3 & absolute_edge,
111	// const btVector3 & pointa,
112	// const btVector3 & pointb, btVector3 & extend)
113	//{
114	//
115	// return test_cross_edge_box(edge,absolute_edge,pointa,pointb,extend,1,0,0,1);
116	//}
117
118
119	#define TEST_CROSS_EDGE_BOX_MCR(edge,absolute_edge,pointa,pointb,_extend,i_dir_0,i_dir_1,i_comp_0,i_comp_1)\
120	{\
121	const btScalar dir0 = -edge[i_dir_0];\
122	const btScalar dir1 = edge[i_dir_1];\
123	btScalar pmin = pointa[i_comp_0]dir0 + pointa[i_comp_1]dir1;\
124	btScalar pmax = pointb[i_comp_0]dir0 + pointb[i_comp_1]dir1;\
125	if(pmin>pmax)\
126	{\
127	BT_SWAP_NUMBERS(pmin,pmax); \
128	}\
129	const btScalar abs_dir0 = absolute_edge[i_dir_0];\
130	const btScalar abs_dir1 = absolute_edge[i_dir_1];\
131	const btScalar rad = _extend[i_comp_0] * abs_dir0 + _extend[i_comp_1] * abs_dir1;\
132	if(pmin>rad \|\| -rad>pmax) return false;\
133	}\
134
135
136	#define TEST_CROSS_EDGE_BOX_X_AXIS_MCR(edge,absolute_edge,pointa,pointb,_extend)\
137	{\
138	TEST_CROSS_EDGE_BOX_MCR(edge,absolute_edge,pointa,pointb,_extend,2,1,1,2);\
139	}\
140
141	#define TEST_CROSS_EDGE_BOX_Y_AXIS_MCR(edge,absolute_edge,pointa,pointb,_extend)\
142	{\
143	TEST_CROSS_EDGE_BOX_MCR(edge,absolute_edge,pointa,pointb,_extend,0,2,2,0);\
144	}\
145
146	#define TEST_CROSS_EDGE_BOX_Z_AXIS_MCR(edge,absolute_edge,pointa,pointb,_extend)\
147	{\
148	TEST_CROSS_EDGE_BOX_MCR(edge,absolute_edge,pointa,pointb,_extend,1,0,0,1);\
149	}\
150
151
152	//! Returns the dot product between a vec3f and the col of a matrix
153	SIMD_FORCE_INLINE btScalar bt_mat3_dot_col(
154	const btMatrix3x3 & mat, const btVector3 & vec3, int colindex)
155	{
156	return vec3[0]mat[0][colindex] + vec3[1]mat[1][colindex] + vec3[2]*mat[2][colindex];
157	}
158
159
160	//! Class for transforming a model1 to the space of model0
161	ATTRIBUTE_ALIGNED16 (class) BT_BOX_BOX_TRANSFORM_CACHE
162	{
163	public:
164	btVector3 m_T1to0;//!< Transforms translation of model1 to model 0
165	btMatrix3x3 m_R1to0;//!< Transforms Rotation of model1 to model 0, equal to R0' * R1
166	btMatrix3x3 m_AR;//!< Absolute value of m_R1to0
167
168	SIMD_FORCE_INLINE void calc_absolute_matrix()
169	{
170	// static const btVector3 vepsi(1e-6f,1e-6f,1e-6f);
171	// m_AR[0] = vepsi + m_R1to0[0].absolute();
172	// m_AR[1] = vepsi + m_R1to0[1].absolute();
173	// m_AR[2] = vepsi + m_R1to0[2].absolute();
174
175	int i,j;
176
177	for(i=0;i<3;i++)
178	{
179	for(j=0;j<3;j++ )
180	{
181	m_AR[i][j] = 1e-6f + btFabs(m_R1to0[i][j]);
182	}
183	}
184
185	}
186
187	BT_BOX_BOX_TRANSFORM_CACHE()
188	{
189	}
190
191
192
193	//! Calc the transformation relative 1 to 0. Inverts matrics by transposing
194	SIMD_FORCE_INLINE void calc_from_homogenic(const btTransform & trans0,const btTransform & trans1)
195	{
196
197	btTransform temp_trans = trans0.inverse();
198	temp_trans = temp_trans * trans1;
199
200	m_T1to0 = temp_trans.getOrigin();
201	m_R1to0 = temp_trans.getBasis();
202
203
204	calc_absolute_matrix();
205	}
206
207	//! Calcs the full invertion of the matrices. Useful for scaling matrices
208	SIMD_FORCE_INLINE void calc_from_full_invert(const btTransform & trans0,const btTransform & trans1)
209	{
210	m_R1to0 = trans0.getBasis().inverse();
211	m_T1to0 = m_R1to0 * (-trans0.getOrigin());
212
213	m_T1to0 += m_R1to0*trans1.getOrigin();
214	m_R1to0 *= trans1.getBasis();
215
216	calc_absolute_matrix();
217	}
218
219	SIMD_FORCE_INLINE btVector3 transform(const btVector3 & point) const
220	{
221	return btVector3(m_R1to0[0].dot(point) + m_T1to0.x(),
222	m_R1to0[1].dot(point) + m_T1to0.y(),
223	m_R1to0[2].dot(point) + m_T1to0.z());
224	}
225	};
226
227
228	#define BOX_PLANE_EPSILON 0.000001f
229
230	//! Axis aligned box
231	ATTRIBUTE_ALIGNED16 (class) btAABB
232	{
233	public:
234	btVector3 m_min;
235	btVector3 m_max;
236
237	btAABB()
238	{}
239
240
241	btAABB(const btVector3 & V1,
242	const btVector3 & V2,
243	const btVector3 & V3)
244	{
245	m_min[0] = BT_MIN3(V1[0],V2[0],V3[0]);
246	m_min[1] = BT_MIN3(V1[1],V2[1],V3[1]);
247	m_min[2] = BT_MIN3(V1[2],V2[2],V3[2]);
248
249	m_max[0] = BT_MAX3(V1[0],V2[0],V3[0]);
250	m_max[1] = BT_MAX3(V1[1],V2[1],V3[1]);
251	m_max[2] = BT_MAX3(V1[2],V2[2],V3[2]);
252	}
253
254	btAABB(const btVector3 & V1,
255	const btVector3 & V2,
256	const btVector3 & V3,
257	btScalar margin)
258	{
259	m_min[0] = BT_MIN3(V1[0],V2[0],V3[0]);
260	m_min[1] = BT_MIN3(V1[1],V2[1],V3[1]);
261	m_min[2] = BT_MIN3(V1[2],V2[2],V3[2]);
262
263	m_max[0] = BT_MAX3(V1[0],V2[0],V3[0]);
264	m_max[1] = BT_MAX3(V1[1],V2[1],V3[1]);
265	m_max[2] = BT_MAX3(V1[2],V2[2],V3[2]);
266
267	m_min[0] -= margin;
268	m_min[1] -= margin;
269	m_min[2] -= margin;
270	m_max[0] += margin;
271	m_max[1] += margin;
272	m_max[2] += margin;
273	}
274
275	btAABB(const btAABB &other):
276	m_min(other.m_min),m_max(other.m_max)
277	{
278	}
279
280	btAABB(const btAABB &other,btScalar margin ):
281	m_min(other.m_min),m_max(other.m_max)
282	{
283	m_min[0] -= margin;
284	m_min[1] -= margin;
285	m_min[2] -= margin;
286	m_max[0] += margin;
287	m_max[1] += margin;
288	m_max[2] += margin;
289	}
290
291	SIMD_FORCE_INLINE void invalidate()
292	{
293	m_min[0] = SIMD_INFINITY;
294	m_min[1] = SIMD_INFINITY;
295	m_min[2] = SIMD_INFINITY;
296	m_max[0] = -SIMD_INFINITY;
297	m_max[1] = -SIMD_INFINITY;
298	m_max[2] = -SIMD_INFINITY;
299	}
300
301	SIMD_FORCE_INLINE void increment_margin(btScalar margin)
302	{
303	m_min[0] -= margin;
304	m_min[1] -= margin;
305	m_min[2] -= margin;
306	m_max[0] += margin;
307	m_max[1] += margin;
308	m_max[2] += margin;
309	}
310
311	SIMD_FORCE_INLINE void copy_with_margin(const btAABB &other, btScalar margin)
312	{
313	m_min[0] = other.m_min[0] - margin;
314	m_min[1] = other.m_min[1] - margin;
315	m_min[2] = other.m_min[2] - margin;
316
317	m_max[0] = other.m_max[0] + margin;
318	m_max[1] = other.m_max[1] + margin;
319	m_max[2] = other.m_max[2] + margin;
320	}
321
322	template<typename CLASS_POINT>
323	SIMD_FORCE_INLINE void calc_from_triangle(
324	const CLASS_POINT & V1,
325	const CLASS_POINT & V2,
326	const CLASS_POINT & V3)
327	{
328	m_min[0] = BT_MIN3(V1[0],V2[0],V3[0]);
329	m_min[1] = BT_MIN3(V1[1],V2[1],V3[1]);
330	m_min[2] = BT_MIN3(V1[2],V2[2],V3[2]);
331
332	m_max[0] = BT_MAX3(V1[0],V2[0],V3[0]);
333	m_max[1] = BT_MAX3(V1[1],V2[1],V3[1]);
334	m_max[2] = BT_MAX3(V1[2],V2[2],V3[2]);
335	}
336
337	template<typename CLASS_POINT>
338	SIMD_FORCE_INLINE void calc_from_triangle_margin(
339	const CLASS_POINT & V1,
340	const CLASS_POINT & V2,
341	const CLASS_POINT & V3, btScalar margin)
342	{
343	m_min[0] = BT_MIN3(V1[0],V2[0],V3[0]);
344	m_min[1] = BT_MIN3(V1[1],V2[1],V3[1]);
345	m_min[2] = BT_MIN3(V1[2],V2[2],V3[2]);
346
347	m_max[0] = BT_MAX3(V1[0],V2[0],V3[0]);
348	m_max[1] = BT_MAX3(V1[1],V2[1],V3[1]);
349	m_max[2] = BT_MAX3(V1[2],V2[2],V3[2]);
350
351	m_min[0] -= margin;
352	m_min[1] -= margin;
353	m_min[2] -= margin;
354	m_max[0] += margin;
355	m_max[1] += margin;
356	m_max[2] += margin;
357	}
358
359	//! Apply a transform to an AABB
360	SIMD_FORCE_INLINE void appy_transform(const btTransform & trans)
361	{
362	btVector3 center = (m_max+m_min)*0.5f;
363	btVector3 extends = m_max - center;
364	// Compute new center
365	center = trans(center);
366
367	btVector3 textends(extends.dot(trans.getBasis().getRow(0).absolute()),
368	extends.dot(trans.getBasis().getRow(1).absolute()),
369	extends.dot(trans.getBasis().getRow(2).absolute()));
370
371	m_min = center - textends;
372	m_max = center + textends;
373	}
374
375
376	//! Apply a transform to an AABB
377	SIMD_FORCE_INLINE void appy_transform_trans_cache(const BT_BOX_BOX_TRANSFORM_CACHE & trans)
378	{
379	btVector3 center = (m_max+m_min)*0.5f;
380	btVector3 extends = m_max - center;
381	// Compute new center
382	center = trans.transform(center);
383
384	btVector3 textends(extends.dot(trans.m_R1to0.getRow(0).absolute()),
385	extends.dot(trans.m_R1to0.getRow(1).absolute()),
386	extends.dot(trans.m_R1to0.getRow(2).absolute()));
387
388	m_min = center - textends;
389	m_max = center + textends;
390	}
391
392	//! Merges a Box
393	SIMD_FORCE_INLINE void merge(const btAABB & box)
394	{
395	m_min[0] = BT_MIN(m_min[0],box.m_min[0]);
396	m_min[1] = BT_MIN(m_min[1],box.m_min[1]);
397	m_min[2] = BT_MIN(m_min[2],box.m_min[2]);
398
399	m_max[0] = BT_MAX(m_max[0],box.m_max[0]);
400	m_max[1] = BT_MAX(m_max[1],box.m_max[1]);
401	m_max[2] = BT_MAX(m_max[2],box.m_max[2]);
402	}
403
404	//! Merges a point
405	template<typename CLASS_POINT>
406	SIMD_FORCE_INLINE void merge_point(const CLASS_POINT & point)
407	{
408	m_min[0] = BT_MIN(m_min[0],point[0]);
409	m_min[1] = BT_MIN(m_min[1],point[1]);
410	m_min[2] = BT_MIN(m_min[2],point[2]);
411
412	m_max[0] = BT_MAX(m_max[0],point[0]);
413	m_max[1] = BT_MAX(m_max[1],point[1]);
414	m_max[2] = BT_MAX(m_max[2],point[2]);
415	}
416
417	//! Gets the extend and center
418	SIMD_FORCE_INLINE void get_center_extend(btVector3 & center,btVector3 & extend) const
419	{
420	center = (m_max+m_min)*0.5f;
421	extend = m_max - center;
422	}
423
424	//! Finds the intersecting box between this box and the other.
425	SIMD_FORCE_INLINE void find_intersection(const btAABB & other, btAABB & intersection) const
426	{
427	intersection.m_min[0] = BT_MAX(other.m_min[0],m_min[0]);
428	intersection.m_min[1] = BT_MAX(other.m_min[1],m_min[1]);
429	intersection.m_min[2] = BT_MAX(other.m_min[2],m_min[2]);
430
431	intersection.m_max[0] = BT_MIN(other.m_max[0],m_max[0]);
432	intersection.m_max[1] = BT_MIN(other.m_max[1],m_max[1]);
433	intersection.m_max[2] = BT_MIN(other.m_max[2],m_max[2]);
434	}
435
436
437	SIMD_FORCE_INLINE bool has_collision(const btAABB & other) const
438	{
439	if(m_min[0] > other.m_max[0] \|\|
440	m_max[0] < other.m_min[0] \|\|
441	m_min[1] > other.m_max[1] \|\|
442	m_max[1] < other.m_min[1] \|\|
443	m_min[2] > other.m_max[2] \|\|
444	m_max[2] < other.m_min[2])
445	{
446	return false;
447	}
448	return true;
449	}
450
451	/*! \brief Finds the Ray intersection parameter.
452	\param aabb Aligned box
453	\param vorigin A vec3f with the origin of the ray
454	\param vdir A vec3f with the direction of the ray
455	*/
456	SIMD_FORCE_INLINE bool collide_ray(const btVector3 & vorigin,const btVector3 & vdir) const
457	{
458	btVector3 extents,center;
459	this->get_center_extend(center,extents);;
460
461	btScalar Dx = vorigin[0] - center[0];
462	if(BT_GREATER(Dx, extents[0]) && Dx*vdir[0]>=0.0f) return false;
463	btScalar Dy = vorigin[1] - center[1];
464	if(BT_GREATER(Dy, extents[1]) && Dy*vdir[1]>=0.0f) return false;
465	btScalar Dz = vorigin[2] - center[2];
466	if(BT_GREATER(Dz, extents[2]) && Dz*vdir[2]>=0.0f) return false;
467
468
469	btScalar f = vdir[1] * Dz - vdir[2] * Dy;
470	if(btFabs(f) > extents[1]btFabs(vdir[2]) + extents[2]btFabs(vdir[1])) return false;
471	f = vdir[2] * Dx - vdir[0] * Dz;
472	if(btFabs(f) > extents[0]btFabs(vdir[2]) + extents[2]btFabs(vdir[0]))return false;
473	f = vdir[0] * Dy - vdir[1] * Dx;
474	if(btFabs(f) > extents[0]btFabs(vdir[1]) + extents[1]btFabs(vdir[0]))return false;
475	return true;
476	}
477
478
479	SIMD_FORCE_INLINE void projection_interval(const btVector3 & direction, btScalar &vmin, btScalar &vmax) const
480	{
481	btVector3 center = (m_max+m_min)*0.5f;
482	btVector3 extend = m_max-center;
483
484	btScalar _fOrigin = direction.dot(center);
485	btScalar _fMaximumExtent = extend.dot(direction.absolute());
486	vmin = _fOrigin - _fMaximumExtent;
487	vmax = _fOrigin + _fMaximumExtent;
488	}
489
490	SIMD_FORCE_INLINE eBT_PLANE_INTERSECTION_TYPE plane_classify(const btVector4 &plane) const
491	{
492	btScalar _fmin,_fmax;
493	this->projection_interval(plane,_fmin,_fmax);
494
495	if(plane[3] > _fmax + BOX_PLANE_EPSILON)
496	{
497	return BT_CONST_BACK_PLANE; // 0
498	}
499
500	if(plane[3]+BOX_PLANE_EPSILON >=_fmin)
501	{
502	return BT_CONST_COLLIDE_PLANE; //1
503	}
504	return BT_CONST_FRONT_PLANE;//2
505	}
506
507	SIMD_FORCE_INLINE bool overlapping_trans_conservative(const btAABB & box, btTransform & trans1_to_0) const
508	{
509	btAABB tbox = box;
510	tbox.appy_transform(trans1_to_0);
511	return has_collision(tbox);
512	}
513
514	SIMD_FORCE_INLINE bool overlapping_trans_conservative2(const btAABB & box,
515	const BT_BOX_BOX_TRANSFORM_CACHE & trans1_to_0) const
516	{
517	btAABB tbox = box;
518	tbox.appy_transform_trans_cache(trans1_to_0);
519	return has_collision(tbox);
520	}
521
522	//! transcache is the transformation cache from box to this AABB
523	SIMD_FORCE_INLINE bool overlapping_trans_cache(
524	const btAABB & box,const BT_BOX_BOX_TRANSFORM_CACHE & transcache, bool fulltest) const
525	{
526
527	//Taken from OPCODE
528	btVector3 ea,eb;//extends
529	btVector3 ca,cb;//extends
530	get_center_extend(ca,ea);
531	box.get_center_extend(cb,eb);
532
533
534	btVector3 T;
535	btScalar t,t2;
536	int i;
537
538	// Class I : A's basis vectors
539	for(i=0;i<3;i++)
540	{
541	T[i] = transcache.m_R1to0[i].dot(cb) + transcache.m_T1to0[i] - ca[i];
542	t = transcache.m_AR[i].dot(eb) + ea[i];
543	if(BT_GREATER(T[i], t)) return false;
544	}
545	// Class II : B's basis vectors
546	for(i=0;i<3;i++)
547	{
548	t = bt_mat3_dot_col(transcache.m_R1to0,T,i);
549	t2 = bt_mat3_dot_col(transcache.m_AR,ea,i) + eb[i];
550	if(BT_GREATER(t,t2)) return false;
551	}
552	// Class III : 9 cross products
553	if(fulltest)
554	{
555	int j,m,n,o,p,q,r;
556	for(i=0;i<3;i++)
557	{
558	m = (i+1)%3;
559	n = (i+2)%3;
560	o = i==0?1:0;
561	p = i==2?1:2;
562	for(j=0;j<3;j++)
563	{
564	q = j==2?1:2;
565	r = j==0?1:0;
566	t = T[n]transcache.m_R1to0[m][j] - T[m]transcache.m_R1to0[n][j];
567	t2 = ea[o]transcache.m_AR[p][j] + ea[p]transcache.m_AR[o][j] +
568	eb[r]transcache.m_AR[i][q] + eb[q]transcache.m_AR[i][r];
569	if(BT_GREATER(t,t2)) return false;
570	}
571	}
572	}
573	return true;
574	}
575
576	//! Simple test for planes.
577	SIMD_FORCE_INLINE bool collide_plane(
578	const btVector4 & plane) const
579	{
580	eBT_PLANE_INTERSECTION_TYPE classify = plane_classify(plane);
581	return (classify == BT_CONST_COLLIDE_PLANE);
582	}
583
584	//! test for a triangle, with edges
585	SIMD_FORCE_INLINE bool collide_triangle_exact(
586	const btVector3 & p1,
587	const btVector3 & p2,
588	const btVector3 & p3,
589	const btVector4 & triangle_plane) const
590	{
591	if(!collide_plane(triangle_plane)) return false;
592
593	btVector3 center,extends;
594	this->get_center_extend(center,extends);
595
596	const btVector3 v1(p1 - center);
597	const btVector3 v2(p2 - center);
598	const btVector3 v3(p3 - center);
599
600	//First axis
601	btVector3 diff(v2 - v1);
602	btVector3 abs_diff = diff.absolute();
603	//Test With X axis
604	TEST_CROSS_EDGE_BOX_X_AXIS_MCR(diff,abs_diff,v1,v3,extends);
605	//Test With Y axis
606	TEST_CROSS_EDGE_BOX_Y_AXIS_MCR(diff,abs_diff,v1,v3,extends);
607	//Test With Z axis
608	TEST_CROSS_EDGE_BOX_Z_AXIS_MCR(diff,abs_diff,v1,v3,extends);
609
610
611	diff = v3 - v2;
612	abs_diff = diff.absolute();
613	//Test With X axis
614	TEST_CROSS_EDGE_BOX_X_AXIS_MCR(diff,abs_diff,v2,v1,extends);
615	//Test With Y axis
616	TEST_CROSS_EDGE_BOX_Y_AXIS_MCR(diff,abs_diff,v2,v1,extends);
617	//Test With Z axis
618	TEST_CROSS_EDGE_BOX_Z_AXIS_MCR(diff,abs_diff,v2,v1,extends);
619
620	diff = v1 - v3;
621	abs_diff = diff.absolute();
622	//Test With X axis
623	TEST_CROSS_EDGE_BOX_X_AXIS_MCR(diff,abs_diff,v3,v2,extends);
624	//Test With Y axis
625	TEST_CROSS_EDGE_BOX_Y_AXIS_MCR(diff,abs_diff,v3,v2,extends);
626	//Test With Z axis
627	TEST_CROSS_EDGE_BOX_Z_AXIS_MCR(diff,abs_diff,v3,v2,extends);
628
629	return true;
630	}
631	};
632
633
634	//! Compairison of transformation objects
635	SIMD_FORCE_INLINE bool btCompareTransformsEqual(const btTransform & t1,const btTransform & t2)
636	{
637	if(!(t1.getOrigin() == t2.getOrigin()) ) return false;
638
639	if(!(t1.getBasis().getRow(0) == t2.getBasis().getRow(0)) ) return false;
640	if(!(t1.getBasis().getRow(1) == t2.getBasis().getRow(1)) ) return false;
641	if(!(t1.getBasis().getRow(2) == t2.getBasis().getRow(2)) ) return false;
642	return true;
643	}
644
645
646
647	#endif // GIM_BOX_COLLISION_H_INCLUDED

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