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source: code/branches/pickup4/src/external/bullet/LinearMath/btConvexHull.cpp @ 6593

Last change on this file since 6593 was 5781, checked in by rgrieder, 15 years ago
Reverted trunk again. We might want to find a way to delete these revisions again (x3n's changes are still available as diff in the commit mails).
Property svn:eol-style set to `native`
File size: 27.6 KB

Line
1	/*
2	Stan Melax Convex Hull Computation
3	Copyright (c) 2003-2006 Stan Melax http://www.melax.com/
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 <string.h>
17
18	#include "btConvexHull.h"
19	#include "LinearMath/btAlignedObjectArray.h"
20	#include "LinearMath/btMinMax.h"
21	#include "LinearMath/btVector3.h"
22
23
24
25	template <class T>
26	void Swap(T &a,T &b)
27	{
28	T tmp = a;
29	a=b;
30	b=tmp;
31	}
32
33
34	//----------------------------------
35
36	class int3
37	{
38	public:
39	int x,y,z;
40	int3(){};
41	int3(int _x,int _y, int _z){x=_x;y=_y;z=_z;}
42	const int& operator[](int i) const {return (&x)[i];}
43	int& operator[](int i) {return (&x)[i];}
44	};
45
46
47	//------- btPlane ----------
48
49
50	inline btPlane PlaneFlip(const btPlane &plane){return btPlane(-plane.normal,-plane.dist);}
51	inline int operator==( const btPlane &a, const btPlane &b ) { return (a.normal==b.normal && a.dist==b.dist); }
52	inline int coplanar( const btPlane &a, const btPlane &b ) { return (a==b \|\| a==PlaneFlip(b)); }
53
54
55	//--------- Utility Functions ------
56
57	btVector3 PlaneLineIntersection(const btPlane &plane, const btVector3 &p0, const btVector3 &p1);
58	btVector3 PlaneProject(const btPlane &plane, const btVector3 &point);
59
60	btVector3 ThreePlaneIntersection(const btPlane &p0,const btPlane &p1, const btPlane &p2);
61	btVector3 ThreePlaneIntersection(const btPlane &p0,const btPlane &p1, const btPlane &p2)
62	{
63	btVector3 N1 = p0.normal;
64	btVector3 N2 = p1.normal;
65	btVector3 N3 = p2.normal;
66
67	btVector3 n2n3; n2n3 = N2.cross(N3);
68	btVector3 n3n1; n3n1 = N3.cross(N1);
69	btVector3 n1n2; n1n2 = N1.cross(N2);
70
71	btScalar quotient = (N1.dot(n2n3));
72
73	btAssert(btFabs(quotient) > btScalar(0.000001));
74
75	quotient = btScalar(-1.) / quotient;
76	n2n3 *= p0.dist;
77	n3n1 *= p1.dist;
78	n1n2 *= p2.dist;
79	btVector3 potentialVertex = n2n3;
80	potentialVertex += n3n1;
81	potentialVertex += n1n2;
82	potentialVertex *= quotient;
83
84	btVector3 result(potentialVertex.getX(),potentialVertex.getY(),potentialVertex.getZ());
85	return result;
86
87	}
88
89	btScalar DistanceBetweenLines(const btVector3 &ustart, const btVector3 &udir, const btVector3 &vstart, const btVector3 &vdir, btVector3 upoint=NULL, btVector3 vpoint=NULL);
90	btVector3 TriNormal(const btVector3 &v0, const btVector3 &v1, const btVector3 &v2);
91	btVector3 NormalOf(const btVector3 *vert, const int n);
92
93
94	btVector3 PlaneLineIntersection(const btPlane &plane, const btVector3 &p0, const btVector3 &p1)
95	{
96	// returns the point where the line p0-p1 intersects the plane n&d
97	static btVector3 dif;
98	dif = p1-p0;
99	btScalar dn= dot(plane.normal,dif);
100	btScalar t = -(plane.dist+dot(plane.normal,p0) )/dn;
101	return p0 + (dif*t);
102	}
103
104	btVector3 PlaneProject(const btPlane &plane, const btVector3 &point)
105	{
106	return point - plane.normal * (dot(point,plane.normal)+plane.dist);
107	}
108
109	btVector3 TriNormal(const btVector3 &v0, const btVector3 &v1, const btVector3 &v2)
110	{
111	// return the normal of the triangle
112	// inscribed by v0, v1, and v2
113	btVector3 cp=cross(v1-v0,v2-v1);
114	btScalar m=cp.length();
115	if(m==0) return btVector3(1,0,0);
116	return cp*(btScalar(1.0)/m);
117	}
118
119
120	btScalar DistanceBetweenLines(const btVector3 &ustart, const btVector3 &udir, const btVector3 &vstart, const btVector3 &vdir, btVector3 upoint, btVector3 vpoint)
121	{
122	static btVector3 cp;
123	cp = cross(udir,vdir).normalized();
124
125	btScalar distu = -dot(cp,ustart);
126	btScalar distv = -dot(cp,vstart);
127	btScalar dist = (btScalar)fabs(distu-distv);
128	if(upoint)
129	{
130	btPlane plane;
131	plane.normal = cross(vdir,cp).normalized();
132	plane.dist = -dot(plane.normal,vstart);
133	*upoint = PlaneLineIntersection(plane,ustart,ustart+udir);
134	}
135	if(vpoint)
136	{
137	btPlane plane;
138	plane.normal = cross(udir,cp).normalized();
139	plane.dist = -dot(plane.normal,ustart);
140	*vpoint = PlaneLineIntersection(plane,vstart,vstart+vdir);
141	}
142	return dist;
143	}
144
145
146
147
148
149
150
151	#define COPLANAR (0)
152	#define UNDER (1)
153	#define OVER (2)
154	#define SPLIT (OVER\|UNDER)
155	#define PAPERWIDTH (btScalar(0.001))
156
157	btScalar planetestepsilon = PAPERWIDTH;
158
159
160
161	typedef ConvexH::HalfEdge HalfEdge;
162
163	ConvexH::ConvexH(int vertices_size,int edges_size,int facets_size)
164	{
165	vertices.resize(vertices_size);
166	edges.resize(edges_size);
167	facets.resize(facets_size);
168	}
169
170
171	int PlaneTest(const btPlane &p, const btVector3 &v);
172	int PlaneTest(const btPlane &p, const btVector3 &v) {
173	btScalar a = dot(v,p.normal)+p.dist;
174	int flag = (a>planetestepsilon)?OVER:((a<-planetestepsilon)?UNDER:COPLANAR);
175	return flag;
176	}
177
178	int SplitTest(ConvexH &convex,const btPlane &plane);
179	int SplitTest(ConvexH &convex,const btPlane &plane) {
180	int flag=0;
181	for(int i=0;i<convex.vertices.size();i++) {
182	flag \|= PlaneTest(plane,convex.vertices[i]);
183	}
184	return flag;
185	}
186
187	class VertFlag
188	{
189	public:
190	unsigned char planetest;
191	unsigned char junk;
192	unsigned char undermap;
193	unsigned char overmap;
194	};
195	class EdgeFlag
196	{
197	public:
198	unsigned char planetest;
199	unsigned char fixes;
200	short undermap;
201	short overmap;
202	};
203	class PlaneFlag
204	{
205	public:
206	unsigned char undermap;
207	unsigned char overmap;
208	};
209	class Coplanar{
210	public:
211	unsigned short ea;
212	unsigned char v0;
213	unsigned char v1;
214	};
215
216
217
218
219
220
221
222
223	template<class T>
224	int maxdirfiltered(const T *p,int count,const T &dir,btAlignedObjectArray<int> &allow)
225	{
226	btAssert(count);
227	int m=-1;
228	for(int i=0;i<count;i++)
229	if(allow[i])
230	{
231	if(m==-1 \|\| dot(p[i],dir)>dot(p[m],dir))
232	m=i;
233	}
234	btAssert(m!=-1);
235	return m;
236	}
237
238	btVector3 orth(const btVector3 &v);
239	btVector3 orth(const btVector3 &v)
240	{
241	btVector3 a=cross(v,btVector3(0,0,1));
242	btVector3 b=cross(v,btVector3(0,1,0));
243	if (a.length() > b.length())
244	{
245	return a.normalized();
246	} else {
247	return b.normalized();
248	}
249	}
250
251
252	template<class T>
253	int maxdirsterid(const T *p,int count,const T &dir,btAlignedObjectArray<int> &allow)
254	{
255	int m=-1;
256	while(m==-1)
257	{
258	m = maxdirfiltered(p,count,dir,allow);
259	if(allow[m]==3) return m;
260	T u = orth(dir);
261	T v = cross(u,dir);
262	int ma=-1;
263	for(btScalar x = btScalar(0.0) ; x<= btScalar(360.0) ; x+= btScalar(45.0))
264	{
265	btScalar s = btSin(SIMD_RADS_PER_DEG*(x));
266	btScalar c = btCos(SIMD_RADS_PER_DEG*(x));
267	int mb = maxdirfiltered(p,count,dir+(us+vc)*btScalar(0.025),allow);
268	if(ma==m && mb==m)
269	{
270	allow[m]=3;
271	return m;
272	}
273	if(ma!=-1 && ma!=mb) // Yuck - this is really ugly
274	{
275	int mc = ma;
276	for(btScalar xx = x-btScalar(40.0) ; xx <= x ; xx+= btScalar(5.0))
277	{
278	btScalar s = btSin(SIMD_RADS_PER_DEG*(xx));
279	btScalar c = btCos(SIMD_RADS_PER_DEG*(xx));
280	int md = maxdirfiltered(p,count,dir+(us+vc)*btScalar(0.025),allow);
281	if(mc==m && md==m)
282	{
283	allow[m]=3;
284	return m;
285	}
286	mc=md;
287	}
288	}
289	ma=mb;
290	}
291	allow[m]=0;
292	m=-1;
293	}
294	btAssert(0);
295	return m;
296	}
297
298
299
300
301	int operator ==(const int3 &a,const int3 &b);
302	int operator ==(const int3 &a,const int3 &b)
303	{
304	for(int i=0;i<3;i++)
305	{
306	if(a[i]!=b[i]) return 0;
307	}
308	return 1;
309	}
310
311
312	int above(btVector3* vertices,const int3& t, const btVector3 &p, btScalar epsilon);
313	int above(btVector3* vertices,const int3& t, const btVector3 &p, btScalar epsilon)
314	{
315	btVector3 n=TriNormal(vertices[t[0]],vertices[t[1]],vertices[t[2]]);
316	return (dot(n,p-vertices[t[0]]) > epsilon); // EPSILON???
317	}
318	int hasedge(const int3 &t, int a,int b);
319	int hasedge(const int3 &t, int a,int b)
320	{
321	for(int i=0;i<3;i++)
322	{
323	int i1= (i+1)%3;
324	if(t[i]==a && t[i1]==b) return 1;
325	}
326	return 0;
327	}
328	int hasvert(const int3 &t, int v);
329	int hasvert(const int3 &t, int v)
330	{
331	return (t[0]==v \|\| t[1]==v \|\| t[2]==v) ;
332	}
333	int shareedge(const int3 &a,const int3 &b);
334	int shareedge(const int3 &a,const int3 &b)
335	{
336	int i;
337	for(i=0;i<3;i++)
338	{
339	int i1= (i+1)%3;
340	if(hasedge(a,b[i1],b[i])) return 1;
341	}
342	return 0;
343	}
344
345	class btHullTriangle;
346
347
348
349	class btHullTriangle : public int3
350	{
351	public:
352	int3 n;
353	int id;
354	int vmax;
355	btScalar rise;
356	btHullTriangle(int a,int b,int c):int3(a,b,c),n(-1,-1,-1)
357	{
358	vmax=-1;
359	rise = btScalar(0.0);
360	}
361	~btHullTriangle()
362	{
363	}
364	int &neib(int a,int b);
365	};
366
367
368	int &btHullTriangle::neib(int a,int b)
369	{
370	static int er=-1;
371	int i;
372	for(i=0;i<3;i++)
373	{
374	int i1=(i+1)%3;
375	int i2=(i+2)%3;
376	if((this)[i]==a && (this)[i1]==b) return n[i2];
377	if((this)[i]==b && (this)[i1]==a) return n[i2];
378	}
379	btAssert(0);
380	return er;
381	}
382	void HullLibrary::b2bfix(btHullTriangle* s,btHullTriangle*t)
383	{
384	int i;
385	for(i=0;i<3;i++)
386	{
387	int i1=(i+1)%3;
388	int i2=(i+2)%3;
389	int a = (*s)[i1];
390	int b = (*s)[i2];
391	btAssert(m_tris[s->neib(a,b)]->neib(b,a) == s->id);
392	btAssert(m_tris[t->neib(a,b)]->neib(b,a) == t->id);
393	m_tris[s->neib(a,b)]->neib(b,a) = t->neib(b,a);
394	m_tris[t->neib(b,a)]->neib(a,b) = s->neib(a,b);
395	}
396	}
397
398	void HullLibrary::removeb2b(btHullTriangle* s,btHullTriangle*t)
399	{
400	b2bfix(s,t);
401	deAllocateTriangle(s);
402
403	deAllocateTriangle(t);
404	}
405
406	void HullLibrary::checkit(btHullTriangle *t)
407	{
408	(void)t;
409
410	int i;
411	btAssert(m_tris[t->id]==t);
412	for(i=0;i<3;i++)
413	{
414	int i1=(i+1)%3;
415	int i2=(i+2)%3;
416	int a = (*t)[i1];
417	int b = (*t)[i2];
418
419	// release compile fix
420	(void)i1;
421	(void)i2;
422	(void)a;
423	(void)b;
424
425	btAssert(a!=b);
426	btAssert( m_tris[t->n[i]]->neib(b,a) == t->id);
427	}
428	}
429
430	btHullTriangle* HullLibrary::allocateTriangle(int a,int b,int c)
431	{
432	void* mem = btAlignedAlloc(sizeof(btHullTriangle),16);
433	btHullTriangle* tr = new (mem)btHullTriangle(a,b,c);
434	tr->id = m_tris.size();
435	m_tris.push_back(tr);
436
437	return tr;
438	}
439
440	void HullLibrary::deAllocateTriangle(btHullTriangle* tri)
441	{
442	btAssert(m_tris[tri->id]==tri);
443	m_tris[tri->id]=NULL;
444	tri->~btHullTriangle();
445	btAlignedFree(tri);
446	}
447
448
449	void HullLibrary::extrude(btHullTriangle *t0,int v)
450	{
451	int3 t= *t0;
452	int n = m_tris.size();
453	btHullTriangle* ta = allocateTriangle(v,t[1],t[2]);
454	ta->n = int3(t0->n[0],n+1,n+2);
455	m_tris[t0->n[0]]->neib(t[1],t[2]) = n+0;
456	btHullTriangle* tb = allocateTriangle(v,t[2],t[0]);
457	tb->n = int3(t0->n[1],n+2,n+0);
458	m_tris[t0->n[1]]->neib(t[2],t[0]) = n+1;
459	btHullTriangle* tc = allocateTriangle(v,t[0],t[1]);
460	tc->n = int3(t0->n[2],n+0,n+1);
461	m_tris[t0->n[2]]->neib(t[0],t[1]) = n+2;
462	checkit(ta);
463	checkit(tb);
464	checkit(tc);
465	if(hasvert(*m_tris[ta->n[0]],v)) removeb2b(ta,m_tris[ta->n[0]]);
466	if(hasvert(*m_tris[tb->n[0]],v)) removeb2b(tb,m_tris[tb->n[0]]);
467	if(hasvert(*m_tris[tc->n[0]],v)) removeb2b(tc,m_tris[tc->n[0]]);
468	deAllocateTriangle(t0);
469
470	}
471
472	btHullTriangle* HullLibrary::extrudable(btScalar epsilon)
473	{
474	int i;
475	btHullTriangle *t=NULL;
476	for(i=0;i<m_tris.size();i++)
477	{
478	if(!t \|\| (m_tris[i] && t->rise<m_tris[i]->rise))
479	{
480	t = m_tris[i];
481	}
482	}
483	return (t->rise >epsilon)?t:NULL ;
484	}
485
486
487
488
489	int4 HullLibrary::FindSimplex(btVector3 *verts,int verts_count,btAlignedObjectArray<int> &allow)
490	{
491	btVector3 basis[3];
492	basis[0] = btVector3( btScalar(0.01), btScalar(0.02), btScalar(1.0) );
493	int p0 = maxdirsterid(verts,verts_count, basis[0],allow);
494	int p1 = maxdirsterid(verts,verts_count,-basis[0],allow);
495	basis[0] = verts[p0]-verts[p1];
496	if(p0==p1 \|\| basis[0]==btVector3(0,0,0))
497	return int4(-1,-1,-1,-1);
498	basis[1] = cross(btVector3( btScalar(1),btScalar(0.02), btScalar(0)),basis[0]);
499	basis[2] = cross(btVector3(btScalar(-0.02), btScalar(1), btScalar(0)),basis[0]);
500	if (basis[1].length() > basis[2].length())
501	{
502	basis[1].normalize();
503	} else {
504	basis[1] = basis[2];
505	basis[1].normalize ();
506	}
507	int p2 = maxdirsterid(verts,verts_count,basis[1],allow);
508	if(p2 == p0 \|\| p2 == p1)
509	{
510	p2 = maxdirsterid(verts,verts_count,-basis[1],allow);
511	}
512	if(p2 == p0 \|\| p2 == p1)
513	return int4(-1,-1,-1,-1);
514	basis[1] = verts[p2] - verts[p0];
515	basis[2] = cross(basis[1],basis[0]).normalized();
516	int p3 = maxdirsterid(verts,verts_count,basis[2],allow);
517	if(p3==p0\|\|p3==p1\|\|p3==p2) p3 = maxdirsterid(verts,verts_count,-basis[2],allow);
518	if(p3==p0\|\|p3==p1\|\|p3==p2)
519	return int4(-1,-1,-1,-1);
520	btAssert(!(p0==p1\|\|p0==p2\|\|p0==p3\|\|p1==p2\|\|p1==p3\|\|p2==p3));
521	if(dot(verts[p3]-verts[p0],cross(verts[p1]-verts[p0],verts[p2]-verts[p0])) <0) {Swap(p2,p3);}
522	return int4(p0,p1,p2,p3);
523	}
524
525	int HullLibrary::calchullgen(btVector3 *verts,int verts_count, int vlimit)
526	{
527	if(verts_count <4) return 0;
528	if(vlimit==0) vlimit=1000000000;
529	int j;
530	btVector3 bmin(verts),bmax(verts);
531	btAlignedObjectArray<int> isextreme;
532	isextreme.reserve(verts_count);
533	btAlignedObjectArray<int> allow;
534	allow.reserve(verts_count);
535
536	for(j=0;j<verts_count;j++)
537	{
538	allow.push_back(1);
539	isextreme.push_back(0);
540	bmin.setMin (verts[j]);
541	bmax.setMax (verts[j]);
542	}
543	btScalar epsilon = (bmax-bmin).length() * btScalar(0.001);
544	btAssert (epsilon != 0.0);
545
546
547	int4 p = FindSimplex(verts,verts_count,allow);
548	if(p.x==-1) return 0; // simplex failed
549
550
551
552	btVector3 center = (verts[p[0]]+verts[p[1]]+verts[p[2]]+verts[p[3]]) / btScalar(4.0); // a valid interior point
553	btHullTriangle *t0 = allocateTriangle(p[2],p[3],p[1]); t0->n=int3(2,3,1);
554	btHullTriangle *t1 = allocateTriangle(p[3],p[2],p[0]); t1->n=int3(3,2,0);
555	btHullTriangle *t2 = allocateTriangle(p[0],p[1],p[3]); t2->n=int3(0,1,3);
556	btHullTriangle *t3 = allocateTriangle(p[1],p[0],p[2]); t3->n=int3(1,0,2);
557	isextreme[p[0]]=isextreme[p[1]]=isextreme[p[2]]=isextreme[p[3]]=1;
558	checkit(t0);checkit(t1);checkit(t2);checkit(t3);
559
560	for(j=0;j<m_tris.size();j++)
561	{
562	btHullTriangle *t=m_tris[j];
563	btAssert(t);
564	btAssert(t->vmax<0);
565	btVector3 n=TriNormal(verts[(t)[0]],verts[(t)[1]],verts[(*t)[2]]);
566	t->vmax = maxdirsterid(verts,verts_count,n,allow);
567	t->rise = dot(n,verts[t->vmax]-verts[(*t)[0]]);
568	}
569	btHullTriangle *te;
570	vlimit-=4;
571	while(vlimit >0 && ((te=extrudable(epsilon)) != 0))
572	{
573	int3 ti=*te;
574	int v=te->vmax;
575	btAssert(v != -1);
576	btAssert(!isextreme[v]); // wtf we've already done this vertex
577	isextreme[v]=1;
578	//if(v==p0 \|\| v==p1 \|\| v==p2 \|\| v==p3) continue; // done these already
579	j=m_tris.size();
580	while(j--) {
581	if(!m_tris[j]) continue;
582	int3 t=*m_tris[j];
583	if(above(verts,t,verts[v],btScalar(0.01)*epsilon))
584	{
585	extrude(m_tris[j],v);
586	}
587	}
588	// now check for those degenerate cases where we have a flipped triangle or a really skinny triangle
589	j=m_tris.size();
590	while(j--)
591	{
592	if(!m_tris[j]) continue;
593	if(!hasvert(*m_tris[j],v)) break;
594	int3 nt=*m_tris[j];
595	if(above(verts,nt,center,btScalar(0.01)epsilon) \|\| cross(verts[nt[1]]-verts[nt[0]],verts[nt[2]]-verts[nt[1]]).length()< epsilonepsilon*btScalar(0.1) )
596	{
597	btHullTriangle *nb = m_tris[m_tris[j]->n[0]];
598	btAssert(nb);btAssert(!hasvert(*nb,v));btAssert(nb->id<j);
599	extrude(nb,v);
600	j=m_tris.size();
601	}
602	}
603	j=m_tris.size();
604	while(j--)
605	{
606	btHullTriangle *t=m_tris[j];
607	if(!t) continue;
608	if(t->vmax>=0) break;
609	btVector3 n=TriNormal(verts[(t)[0]],verts[(t)[1]],verts[(*t)[2]]);
610	t->vmax = maxdirsterid(verts,verts_count,n,allow);
611	if(isextreme[t->vmax])
612	{
613	t->vmax=-1; // already done that vertex - algorithm needs to be able to terminate.
614	}
615	else
616	{
617	t->rise = dot(n,verts[t->vmax]-verts[(*t)[0]]);
618	}
619	}
620	vlimit --;
621	}
622	return 1;
623	}
624
625	int HullLibrary::calchull(btVector3 *verts,int verts_count, TUIntArray& tris_out, int &tris_count,int vlimit)
626	{
627	int rc=calchullgen(verts,verts_count, vlimit) ;
628	if(!rc) return 0;
629	btAlignedObjectArray<int> ts;
630	int i;
631
632	for(i=0;i<m_tris.size();i++)
633	{
634	if(m_tris[i])
635	{
636	for(int j=0;j<3;j++)
637	ts.push_back((*m_tris[i])[j]);
638	deAllocateTriangle(m_tris[i]);
639	}
640	}
641	tris_count = ts.size()/3;
642	tris_out.resize(ts.size());
643
644	for (i=0;i<ts.size();i++)
645	{
646	tris_out[i] = static_cast<unsigned int>(ts[i]);
647	}
648	m_tris.resize(0);
649
650	return 1;
651	}
652
653
654
655
656
657	bool HullLibrary::ComputeHull(unsigned int vcount,const btVector3 *vertices,PHullResult &result,unsigned int vlimit)
658	{
659
660	int tris_count;
661	int ret = calchull( (btVector3 *) vertices, (int) vcount, result.m_Indices, tris_count, static_cast<int>(vlimit) );
662	if(!ret) return false;
663	result.mIndexCount = (unsigned int) (tris_count*3);
664	result.mFaceCount = (unsigned int) tris_count;
665	result.mVertices = (btVector3*) vertices;
666	result.mVcount = (unsigned int) vcount;
667	return true;
668
669	}
670
671
672	void ReleaseHull(PHullResult &result);
673	void ReleaseHull(PHullResult &result)
674	{
675	if ( result.m_Indices.size() )
676	{
677	result.m_Indices.clear();
678	}
679
680	result.mVcount = 0;
681	result.mIndexCount = 0;
682	result.mVertices = 0;
683	}
684
685
686	//*********************************************************************
687	//*********************************************************************
688	//******** HullLib header
689	//*********************************************************************
690	//*********************************************************************
691
692	//*********************************************************************
693	//*********************************************************************
694	//******** HullLib implementation
695	//*********************************************************************
696	//*********************************************************************
697
698	HullError HullLibrary::CreateConvexHull(const HullDesc &desc, // describes the input request
699	HullResult &result) // contains the resulst
700	{
701	HullError ret = QE_FAIL;
702
703
704	PHullResult hr;
705
706	unsigned int vcount = desc.mVcount;
707	if ( vcount < 8 ) vcount = 8;
708
709	btAlignedObjectArray<btVector3> vertexSource;
710	vertexSource.resize(static_cast<int>(vcount));
711
712	btVector3 scale;
713
714	unsigned int ovcount;
715
716	bool ok = CleanupVertices(desc.mVcount,desc.mVertices, desc.mVertexStride, ovcount, &vertexSource[0], desc.mNormalEpsilon, scale ); // normalize point cloud, remove duplicates!
717
718	if ( ok )
719	{
720
721
722	// if ( 1 ) // scale vertices back to their original size.
723	{
724	for (unsigned int i=0; i<ovcount; i++)
725	{
726	btVector3& v = vertexSource[static_cast<int>(i)];
727	v[0]*=scale[0];
728	v[1]*=scale[1];
729	v[2]*=scale[2];
730	}
731	}
732
733	ok = ComputeHull(ovcount,&vertexSource[0],hr,desc.mMaxVertices);
734
735	if ( ok )
736	{
737
738	// re-index triangle mesh so it refers to only used vertices, rebuild a new vertex table.
739	btAlignedObjectArray<btVector3> vertexScratch;
740	vertexScratch.resize(static_cast<int>(hr.mVcount));
741
742	BringOutYourDead(hr.mVertices,hr.mVcount, &vertexScratch[0], ovcount, &hr.m_Indices[0], hr.mIndexCount );
743
744	ret = QE_OK;
745
746	if ( desc.HasHullFlag(QF_TRIANGLES) ) // if he wants the results as triangle!
747	{
748	result.mPolygons = false;
749	result.mNumOutputVertices = ovcount;
750	result.m_OutputVertices.resize(static_cast<int>(ovcount));
751	result.mNumFaces = hr.mFaceCount;
752	result.mNumIndices = hr.mIndexCount;
753
754	result.m_Indices.resize(static_cast<int>(hr.mIndexCount));
755
756	memcpy(&result.m_OutputVertices[0], &vertexScratch[0], sizeof(btVector3)*ovcount );
757
758	if ( desc.HasHullFlag(QF_REVERSE_ORDER) )
759	{
760
761	const unsigned int *source = &hr.m_Indices[0];
762	unsigned int *dest = &result.m_Indices[0];
763
764	for (unsigned int i=0; i<hr.mFaceCount; i++)
765	{
766	dest[0] = source[2];
767	dest[1] = source[1];
768	dest[2] = source[0];
769	dest+=3;
770	source+=3;
771	}
772
773	}
774	else
775	{
776	memcpy(&result.m_Indices[0], &hr.m_Indices[0], sizeof(unsigned int)*hr.mIndexCount);
777	}
778	}
779	else
780	{
781	result.mPolygons = true;
782	result.mNumOutputVertices = ovcount;
783	result.m_OutputVertices.resize(static_cast<int>(ovcount));
784	result.mNumFaces = hr.mFaceCount;
785	result.mNumIndices = hr.mIndexCount+hr.mFaceCount;
786	result.m_Indices.resize(static_cast<int>(result.mNumIndices));
787	memcpy(&result.m_OutputVertices[0], &vertexScratch[0], sizeof(btVector3)*ovcount );
788
789	// if ( 1 )
790	{
791	const unsigned int *source = &hr.m_Indices[0];
792	unsigned int *dest = &result.m_Indices[0];
793	for (unsigned int i=0; i<hr.mFaceCount; i++)
794	{
795	dest[0] = 3;
796	if ( desc.HasHullFlag(QF_REVERSE_ORDER) )
797	{
798	dest[1] = source[2];
799	dest[2] = source[1];
800	dest[3] = source[0];
801	}
802	else
803	{
804	dest[1] = source[0];
805	dest[2] = source[1];
806	dest[3] = source[2];
807	}
808
809	dest+=4;
810	source+=3;
811	}
812	}
813	}
814	ReleaseHull(hr);
815	}
816	}
817
818	return ret;
819	}
820
821
822
823	HullError HullLibrary::ReleaseResult(HullResult &result) // release memory allocated for this result, we are done with it.
824	{
825	if ( result.m_OutputVertices.size())
826	{
827	result.mNumOutputVertices=0;
828	result.m_OutputVertices.clear();
829	}
830	if ( result.m_Indices.size() )
831	{
832	result.mNumIndices=0;
833	result.m_Indices.clear();
834	}
835	return QE_OK;
836	}
837
838
839	static void addPoint(unsigned int &vcount,btVector3 *p,btScalar x,btScalar y,btScalar z)
840	{
841	// XXX, might be broken
842	btVector3& dest = p[vcount];
843	dest[0] = x;
844	dest[1] = y;
845	dest[2] = z;
846	vcount++;
847	}
848
849	btScalar GetDist(btScalar px,btScalar py,btScalar pz,const btScalar *p2);
850	btScalar GetDist(btScalar px,btScalar py,btScalar pz,const btScalar *p2)
851	{
852
853	btScalar dx = px - p2[0];
854	btScalar dy = py - p2[1];
855	btScalar dz = pz - p2[2];
856
857	return dxdx+dydy+dz*dz;
858	}
859
860
861
862	bool HullLibrary::CleanupVertices(unsigned int svcount,
863	const btVector3 *svertices,
864	unsigned int stride,
865	unsigned int &vcount, // output number of vertices
866	btVector3 *vertices, // location to store the results.
867	btScalar normalepsilon,
868	btVector3& scale)
869	{
870	if ( svcount == 0 ) return false;
871
872	m_vertexIndexMapping.resize(0);
873
874
875	#define EPSILON btScalar(0.000001) /* close enough to consider two btScalaring point numbers to be 'the same'. */
876
877	vcount = 0;
878
879	btScalar recip[3];
880
881	if ( scale )
882	{
883	scale[0] = 1;
884	scale[1] = 1;
885	scale[2] = 1;
886	}
887
888	btScalar bmin[3] = { FLT_MAX, FLT_MAX, FLT_MAX };
889	btScalar bmax[3] = { -FLT_MAX, -FLT_MAX, -FLT_MAX };
890
891	const char vtx = (const char ) svertices;
892
893	// if ( 1 )
894	{
895	for (unsigned int i=0; i<svcount; i++)
896	{
897	const btScalar p = (const btScalar ) vtx;
898
899	vtx+=stride;
900
901	for (int j=0; j<3; j++)
902	{
903	if ( p[j] < bmin[j] ) bmin[j] = p[j];
904	if ( p[j] > bmax[j] ) bmax[j] = p[j];
905	}
906	}
907	}
908
909	btScalar dx = bmax[0] - bmin[0];
910	btScalar dy = bmax[1] - bmin[1];
911	btScalar dz = bmax[2] - bmin[2];
912
913	btVector3 center;
914
915	center[0] = dx*btScalar(0.5) + bmin[0];
916	center[1] = dy*btScalar(0.5) + bmin[1];
917	center[2] = dz*btScalar(0.5) + bmin[2];
918
919	if ( dx < EPSILON \|\| dy < EPSILON \|\| dz < EPSILON \|\| svcount < 3 )
920	{
921
922	btScalar len = FLT_MAX;
923
924	if ( dx > EPSILON && dx < len ) len = dx;
925	if ( dy > EPSILON && dy < len ) len = dy;
926	if ( dz > EPSILON && dz < len ) len = dz;
927
928	if ( len == FLT_MAX )
929	{
930	dx = dy = dz = btScalar(0.01); // one centimeter
931	}
932	else
933	{
934	if ( dx < EPSILON ) dx = len * btScalar(0.05); // 1/5th the shortest non-zero edge.
935	if ( dy < EPSILON ) dy = len * btScalar(0.05);
936	if ( dz < EPSILON ) dz = len * btScalar(0.05);
937	}
938
939	btScalar x1 = center[0] - dx;
940	btScalar x2 = center[0] + dx;
941
942	btScalar y1 = center[1] - dy;
943	btScalar y2 = center[1] + dy;
944
945	btScalar z1 = center[2] - dz;
946	btScalar z2 = center[2] + dz;
947
948	addPoint(vcount,vertices,x1,y1,z1);
949	addPoint(vcount,vertices,x2,y1,z1);
950	addPoint(vcount,vertices,x2,y2,z1);
951	addPoint(vcount,vertices,x1,y2,z1);
952	addPoint(vcount,vertices,x1,y1,z2);
953	addPoint(vcount,vertices,x2,y1,z2);
954	addPoint(vcount,vertices,x2,y2,z2);
955	addPoint(vcount,vertices,x1,y2,z2);
956
957	return true; // return cube
958
959
960	}
961	else
962	{
963	if ( scale )
964	{
965	scale[0] = dx;
966	scale[1] = dy;
967	scale[2] = dz;
968
969	recip[0] = 1 / dx;
970	recip[1] = 1 / dy;
971	recip[2] = 1 / dz;
972
973	center[0]*=recip[0];
974	center[1]*=recip[1];
975	center[2]*=recip[2];
976
977	}
978
979	}
980
981
982
983	vtx = (const char *) svertices;
984
985	for (unsigned int i=0; i<svcount; i++)
986	{
987	const btVector3 p = (const btVector3 )vtx;
988	vtx+=stride;
989
990	btScalar px = p->getX();
991	btScalar py = p->getY();
992	btScalar pz = p->getZ();
993
994	if ( scale )
995	{
996	px = px*recip[0]; // normalize
997	py = py*recip[1]; // normalize
998	pz = pz*recip[2]; // normalize
999	}
1000
1001	// if ( 1 )
1002	{
1003	unsigned int j;
1004
1005	for (j=0; j<vcount; j++)
1006	{
1007	/// XXX might be broken
1008	btVector3& v = vertices[j];
1009
1010	btScalar x = v[0];
1011	btScalar y = v[1];
1012	btScalar z = v[2];
1013
1014	btScalar dx = fabsf(x - px );
1015	btScalar dy = fabsf(y - py );
1016	btScalar dz = fabsf(z - pz );
1017
1018	if ( dx < normalepsilon && dy < normalepsilon && dz < normalepsilon )
1019	{
1020	// ok, it is close enough to the old one
1021	// now let us see if it is further from the center of the point cloud than the one we already recorded.
1022	// in which case we keep this one instead.
1023
1024	btScalar dist1 = GetDist(px,py,pz,center);
1025	btScalar dist2 = GetDist(v[0],v[1],v[2],center);
1026
1027	if ( dist1 > dist2 )
1028	{
1029	v[0] = px;
1030	v[1] = py;
1031	v[2] = pz;
1032
1033	}
1034
1035	break;
1036	}
1037	}
1038
1039	if ( j == vcount )
1040	{
1041	btVector3& dest = vertices[vcount];
1042	dest[0] = px;
1043	dest[1] = py;
1044	dest[2] = pz;
1045	vcount++;
1046	}
1047	m_vertexIndexMapping.push_back(j);
1048	}
1049	}
1050
1051	// ok..now make sure we didn't prune so many vertices it is now invalid.
1052	// if ( 1 )
1053	{
1054	btScalar bmin[3] = { FLT_MAX, FLT_MAX, FLT_MAX };
1055	btScalar bmax[3] = { -FLT_MAX, -FLT_MAX, -FLT_MAX };
1056
1057	for (unsigned int i=0; i<vcount; i++)
1058	{
1059	const btVector3& p = vertices[i];
1060	for (int j=0; j<3; j++)
1061	{
1062	if ( p[j] < bmin[j] ) bmin[j] = p[j];
1063	if ( p[j] > bmax[j] ) bmax[j] = p[j];
1064	}
1065	}
1066
1067	btScalar dx = bmax[0] - bmin[0];
1068	btScalar dy = bmax[1] - bmin[1];
1069	btScalar dz = bmax[2] - bmin[2];
1070
1071	if ( dx < EPSILON \|\| dy < EPSILON \|\| dz < EPSILON \|\| vcount < 3)
1072	{
1073	btScalar cx = dx*btScalar(0.5) + bmin[0];
1074	btScalar cy = dy*btScalar(0.5) + bmin[1];
1075	btScalar cz = dz*btScalar(0.5) + bmin[2];
1076
1077	btScalar len = FLT_MAX;
1078
1079	if ( dx >= EPSILON && dx < len ) len = dx;
1080	if ( dy >= EPSILON && dy < len ) len = dy;
1081	if ( dz >= EPSILON && dz < len ) len = dz;
1082
1083	if ( len == FLT_MAX )
1084	{
1085	dx = dy = dz = btScalar(0.01); // one centimeter
1086	}
1087	else
1088	{
1089	if ( dx < EPSILON ) dx = len * btScalar(0.05); // 1/5th the shortest non-zero edge.
1090	if ( dy < EPSILON ) dy = len * btScalar(0.05);
1091	if ( dz < EPSILON ) dz = len * btScalar(0.05);
1092	}
1093
1094	btScalar x1 = cx - dx;
1095	btScalar x2 = cx + dx;
1096
1097	btScalar y1 = cy - dy;
1098	btScalar y2 = cy + dy;
1099
1100	btScalar z1 = cz - dz;
1101	btScalar z2 = cz + dz;
1102
1103	vcount = 0; // add box
1104
1105	addPoint(vcount,vertices,x1,y1,z1);
1106	addPoint(vcount,vertices,x2,y1,z1);
1107	addPoint(vcount,vertices,x2,y2,z1);
1108	addPoint(vcount,vertices,x1,y2,z1);
1109	addPoint(vcount,vertices,x1,y1,z2);
1110	addPoint(vcount,vertices,x2,y1,z2);
1111	addPoint(vcount,vertices,x2,y2,z2);
1112	addPoint(vcount,vertices,x1,y2,z2);
1113
1114	return true;
1115	}
1116	}
1117
1118	return true;
1119	}
1120
1121	void HullLibrary::BringOutYourDead(const btVector3* verts,unsigned int vcount, btVector3* overts,unsigned int &ocount,unsigned int *indices,unsigned indexcount)
1122	{
1123	btAlignedObjectArray<int>tmpIndices;
1124	tmpIndices.resize(m_vertexIndexMapping.size());
1125	int i;
1126
1127	for (i=0;i<m_vertexIndexMapping.size();i++)
1128	{
1129	tmpIndices[i] = m_vertexIndexMapping[i];
1130	}
1131
1132	TUIntArray usedIndices;
1133	usedIndices.resize(static_cast<int>(vcount));
1134	memset(&usedIndices[0],0,sizeof(unsigned int)*vcount);
1135
1136	ocount = 0;
1137
1138	for (i=0; i<indexcount; i++)
1139	{
1140	unsigned int v = indices[i]; // original array index
1141
1142	btAssert( v >= 0 && v < vcount );
1143
1144	if ( usedIndices[static_cast<int>(v)] ) // if already remapped
1145	{
1146	indices[i] = usedIndices[static_cast<int>(v)]-1; // index to new array
1147	}
1148	else
1149	{
1150
1151	indices[i] = ocount; // new index mapping
1152
1153	overts[ocount][0] = verts[v][0]; // copy old vert to new vert array
1154	overts[ocount][1] = verts[v][1];
1155	overts[ocount][2] = verts[v][2];
1156
1157	for (int k=0;k<m_vertexIndexMapping.size();k++)
1158	{
1159	if (tmpIndices[k]==v)
1160	m_vertexIndexMapping[k]=ocount;
1161	}
1162
1163	ocount++; // increment output vert count
1164
1165	btAssert( ocount >=0 && ocount <= vcount );
1166
1167	usedIndices[static_cast<int>(v)] = ocount; // assign new index remapping
1168
1169
1170	}
1171	}
1172
1173
1174	}

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