Bullet Collision Detection & Physics Library
btDbvt.cpp
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1/*
2Bullet Continuous Collision Detection and Physics Library
3Copyright (c) 2003-2006 Erwin Coumans http://continuousphysics.com/Bullet/
4
5This software is provided 'as-is', without any express or implied warranty.
6In no event will the authors be held liable for any damages arising from the use of this software.
7Permission is granted to anyone to use this software for any purpose,
8including commercial applications, and to alter it and redistribute it freely,
9subject to the following restrictions:
10
111. 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.
122. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
133. This notice may not be removed or altered from any source distribution.
14*/
16
17#include "btDbvt.h"
18
19//
22
23//
25{
27 void Process(const btDbvtNode* n) { nodes.push_back(n); }
28};
29
30//
31static DBVT_INLINE int indexof(const btDbvtNode* node)
32{
33 return(node->parent->childs[1]==node);
34}
35
36//
38 const btDbvtVolume& b)
39{
40#if (DBVT_MERGE_IMPL==DBVT_IMPL_SSE)
41 ATTRIBUTE_ALIGNED16( char locals[sizeof(btDbvtAabbMm)]);
42 btDbvtVolume* ptr = (btDbvtVolume*) locals;
43 btDbvtVolume& res=*ptr;
44#else
45 btDbvtVolume res;
46#endif
47 Merge(a,b,res);
48 return(res);
49}
50
51// volume+edge lengths
53{
54 const btVector3 edges=a.Lengths();
55 return( edges.x()*edges.y()*edges.z()+
56 edges.x()+edges.y()+edges.z());
57}
58
59//
60static void getmaxdepth(const btDbvtNode* node,int depth,int& maxdepth)
61{
62 if(node->isinternal())
63 {
64 getmaxdepth(node->childs[0],depth+1,maxdepth);
65 getmaxdepth(node->childs[1],depth+1,maxdepth);
66 } else maxdepth=btMax(maxdepth,depth);
67}
68
69//
70static DBVT_INLINE void deletenode( btDbvt* pdbvt,
71 btDbvtNode* node)
72{
73 btAlignedFree(pdbvt->m_free);
74 pdbvt->m_free=node;
75}
76
77//
78static void recursedeletenode( btDbvt* pdbvt,
79 btDbvtNode* node)
80{
81 if(!node->isleaf())
82 {
83 recursedeletenode(pdbvt,node->childs[0]);
84 recursedeletenode(pdbvt,node->childs[1]);
85 }
86 if(node==pdbvt->m_root) pdbvt->m_root=0;
87 deletenode(pdbvt,node);
88}
89
90//
92 btDbvtNode* parent,
93 void* data)
94{
95 btDbvtNode* node;
96 if(pdbvt->m_free)
97 { node=pdbvt->m_free;pdbvt->m_free=0; }
98 else
99 { node=new(btAlignedAlloc(sizeof(btDbvtNode),16)) btDbvtNode(); }
100 node->parent = parent;
101 node->data = data;
102 node->childs[1] = 0;
103 return(node);
104}
105
106//
108 btDbvtNode* parent,
109 const btDbvtVolume& volume,
110 void* data)
111{
112 btDbvtNode* node=createnode(pdbvt,parent,data);
113 node->volume=volume;
114 return(node);
115}
116
117//
119 btDbvtNode* parent,
120 const btDbvtVolume& volume0,
121 const btDbvtVolume& volume1,
122 void* data)
123{
124 btDbvtNode* node=createnode(pdbvt,parent,data);
125 Merge(volume0,volume1,node->volume);
126 return(node);
127}
128
129//
130static void insertleaf( btDbvt* pdbvt,
131 btDbvtNode* root,
132 btDbvtNode* leaf)
133{
134 if(!pdbvt->m_root)
135 {
136 pdbvt->m_root = leaf;
137 leaf->parent = 0;
138 }
139 else
140 {
141 if(!root->isleaf())
142 {
143 do {
144 root=root->childs[Select( leaf->volume,
145 root->childs[0]->volume,
146 root->childs[1]->volume)];
147 } while(!root->isleaf());
148 }
149 btDbvtNode* prev=root->parent;
150 btDbvtNode* node=createnode(pdbvt,prev,leaf->volume,root->volume,0);
151 if(prev)
152 {
153 prev->childs[indexof(root)] = node;
154 node->childs[0] = root;root->parent=node;
155 node->childs[1] = leaf;leaf->parent=node;
156 do {
157 if(!prev->volume.Contain(node->volume))
158 Merge(prev->childs[0]->volume,prev->childs[1]->volume,prev->volume);
159 else
160 break;
161 node=prev;
162 } while(0!=(prev=node->parent));
163 }
164 else
165 {
166 node->childs[0] = root;root->parent=node;
167 node->childs[1] = leaf;leaf->parent=node;
168 pdbvt->m_root = node;
169 }
170 }
171}
172
173//
175 btDbvtNode* leaf)
176{
177 if(leaf==pdbvt->m_root)
178 {
179 pdbvt->m_root=0;
180 return(0);
181 }
182 else
183 {
184 btDbvtNode* parent=leaf->parent;
185 btDbvtNode* prev=parent->parent;
186 btDbvtNode* sibling=parent->childs[1-indexof(leaf)];
187 if(prev)
188 {
189 prev->childs[indexof(parent)]=sibling;
190 sibling->parent=prev;
191 deletenode(pdbvt,parent);
192 while(prev)
193 {
194 const btDbvtVolume pb=prev->volume;
195 Merge(prev->childs[0]->volume,prev->childs[1]->volume,prev->volume);
196 if(NotEqual(pb,prev->volume))
197 {
198 prev=prev->parent;
199 } else break;
200 }
201 return(prev?prev:pdbvt->m_root);
202 }
203 else
204 {
205 pdbvt->m_root=sibling;
206 sibling->parent=0;
207 deletenode(pdbvt,parent);
208 return(pdbvt->m_root);
209 }
210 }
211}
212
213//
214static void fetchleaves(btDbvt* pdbvt,
215 btDbvtNode* root,
216 tNodeArray& leaves,
217 int depth=-1)
218{
219 if(root->isinternal()&&depth)
220 {
221 fetchleaves(pdbvt,root->childs[0],leaves,depth-1);
222 fetchleaves(pdbvt,root->childs[1],leaves,depth-1);
223 deletenode(pdbvt,root);
224 }
225 else
226 {
227 leaves.push_back(root);
228 }
229}
230
231//
232static bool leftOfAxis( const btDbvtNode* node,
233 const btVector3& org,
234 const btVector3& axis)
235{
236 return btDot(axis, node->volume.Center() - org) <= 0;
237}
238
239
240// Partitions leaves such that leaves[0, n) are on the
241// left of axis, and leaves[n, count) are on the right
242// of axis. returns N.
243static int split( btDbvtNode** leaves,
244 int count,
245 const btVector3& org,
246 const btVector3& axis)
247{
248 int begin=0;
249 int end=count;
250 for(;;)
251 {
252 while(begin!=end && leftOfAxis(leaves[begin],org,axis))
253 {
254 ++begin;
255 }
256
257 if(begin==end)
258 {
259 break;
260 }
261
262 while(begin!=end && !leftOfAxis(leaves[end-1],org,axis))
263 {
264 --end;
265 }
266
267 if(begin==end)
268 {
269 break;
270 }
271
272 // swap out of place nodes
273 --end;
274 btDbvtNode* temp=leaves[begin];
275 leaves[begin]=leaves[end];
276 leaves[end]=temp;
277 ++begin;
278 }
279
280 return begin;
281}
282
283//
285 int count)
286{
287#if DBVT_MERGE_IMPL==DBVT_IMPL_SSE
288 ATTRIBUTE_ALIGNED16(char locals[sizeof(btDbvtVolume)]);
289 btDbvtVolume* ptr = (btDbvtVolume*) locals;
290 btDbvtVolume& volume=*ptr;
291 volume=leaves[0]->volume;
292#else
293 btDbvtVolume volume=leaves[0]->volume;
294#endif
295 for(int i=1,ni=count;i<ni;++i)
296 {
297 Merge(volume,leaves[i]->volume,volume);
298 }
299 return(volume);
300}
301
302//
303static void bottomup( btDbvt* pdbvt,
304 btDbvtNode** leaves,
305 int count)
306{
307 while(count>1)
308 {
309 btScalar minsize=SIMD_INFINITY;
310 int minidx[2]={-1,-1};
311 for(int i=0;i<count;++i)
312 {
313 for(int j=i+1;j<count;++j)
314 {
315 const btScalar sz=size(merge(leaves[i]->volume,leaves[j]->volume));
316 if(sz<minsize)
317 {
318 minsize = sz;
319 minidx[0] = i;
320 minidx[1] = j;
321 }
322 }
323 }
324 btDbvtNode* n[] = {leaves[minidx[0]],leaves[minidx[1]]};
325 btDbvtNode* p = createnode(pdbvt,0,n[0]->volume,n[1]->volume,0);
326 p->childs[0] = n[0];
327 p->childs[1] = n[1];
328 n[0]->parent = p;
329 n[1]->parent = p;
330 leaves[minidx[0]] = p;
331 leaves[minidx[1]] = leaves[count-1];
332 --count;
333 }
334}
335
336//
337static btDbvtNode* topdown(btDbvt* pdbvt,
338 btDbvtNode** leaves,
339 int count,
340 int bu_treshold)
341{
342 static const btVector3 axis[]={btVector3(1,0,0),
343 btVector3(0,1,0),
344 btVector3(0,0,1)};
345 btAssert(bu_treshold>2);
346 if(count>1)
347 {
348 if(count>bu_treshold)
349 {
350 const btDbvtVolume vol=bounds(leaves,count);
351 const btVector3 org=vol.Center();
352 int partition;
353 int bestaxis=-1;
354 int bestmidp=count;
355 int splitcount[3][2]={{0,0},{0,0},{0,0}};
356 int i;
357 for( i=0;i<count;++i)
358 {
359 const btVector3 x=leaves[i]->volume.Center()-org;
360 for(int j=0;j<3;++j)
361 {
362 ++splitcount[j][btDot(x,axis[j])>0?1:0];
363 }
364 }
365 for( i=0;i<3;++i)
366 {
367 if((splitcount[i][0]>0)&&(splitcount[i][1]>0))
368 {
369 const int midp=(int)btFabs(btScalar(splitcount[i][0]-splitcount[i][1]));
370 if(midp<bestmidp)
371 {
372 bestaxis=i;
373 bestmidp=midp;
374 }
375 }
376 }
377 if(bestaxis>=0)
378 {
379 partition=split(leaves,count,org,axis[bestaxis]);
380 btAssert(partition!=0 && partition!=count);
381 }
382 else
383 {
384 partition=count/2+1;
385 }
386 btDbvtNode* node=createnode(pdbvt,0,vol,0);
387 node->childs[0]=topdown(pdbvt,&leaves[0],partition,bu_treshold);
388 node->childs[1]=topdown(pdbvt,&leaves[partition],count-partition,bu_treshold);
389 node->childs[0]->parent=node;
390 node->childs[1]->parent=node;
391 return(node);
392 }
393 else
394 {
395 bottomup(pdbvt,leaves,count);
396 return(leaves[0]);
397 }
398 }
399 return(leaves[0]);
400}
401
402//
404{
405 btDbvtNode* p=n->parent;
406 btAssert(n->isinternal());
407 if(p>n)
408 {
409 const int i=indexof(n);
410 const int j=1-i;
411 btDbvtNode* s=p->childs[j];
412 btDbvtNode* q=p->parent;
413 btAssert(n==p->childs[i]);
414 if(q) q->childs[indexof(p)]=n; else r=n;
415 s->parent=n;
416 p->parent=n;
417 n->parent=q;
418 p->childs[0]=n->childs[0];
419 p->childs[1]=n->childs[1];
420 n->childs[0]->parent=p;
421 n->childs[1]->parent=p;
422 n->childs[i]=p;
423 n->childs[j]=s;
424 btSwap(p->volume,n->volume);
425 return(p);
426 }
427 return(n);
428}
429
430#if 0
431static DBVT_INLINE btDbvtNode* walkup(btDbvtNode* n,int count)
432{
433 while(n&&(count--)) n=n->parent;
434 return(n);
435}
436#endif
437
438//
439// Api
440//
441
442//
444{
445 m_root = 0;
446 m_free = 0;
447 m_lkhd = -1;
448 m_leaves = 0;
449 m_opath = 0;
450}
451
452//
454{
455 clear();
456}
457
458//
460{
461 if(m_root)
464 m_free=0;
465 m_lkhd = -1;
466 m_stkStack.clear();
467 m_opath = 0;
468
469}
470
471//
473{
474 if(m_root)
475 {
476 tNodeArray leaves;
477 leaves.reserve(m_leaves);
478 fetchleaves(this,m_root,leaves);
479 bottomup(this,&leaves[0],leaves.size());
480 m_root=leaves[0];
481 }
482}
483
484//
485void btDbvt::optimizeTopDown(int bu_treshold)
486{
487 if(m_root)
488 {
489 tNodeArray leaves;
490 leaves.reserve(m_leaves);
491 fetchleaves(this,m_root,leaves);
492 m_root=topdown(this,&leaves[0],leaves.size(),bu_treshold);
493 }
494}
495
496//
498{
499 if(passes<0) passes=m_leaves;
500 if(m_root&&(passes>0))
501 {
502 do {
503 btDbvtNode* node=m_root;
504 unsigned bit=0;
505 while(node->isinternal())
506 {
507 node=sort(node,m_root)->childs[(m_opath>>bit)&1];
508 bit=(bit+1)&(sizeof(unsigned)*8-1);
509 }
510 update(node);
511 ++m_opath;
512 } while(--passes);
513 }
514}
515
516//
517btDbvtNode* btDbvt::insert(const btDbvtVolume& volume,void* data)
518{
519 btDbvtNode* leaf=createnode(this,0,volume,data);
520 insertleaf(this,m_root,leaf);
521 ++m_leaves;
522 return(leaf);
523}
524
525//
526void btDbvt::update(btDbvtNode* leaf,int lookahead)
527{
528 btDbvtNode* root=removeleaf(this,leaf);
529 if(root)
530 {
531 if(lookahead>=0)
532 {
533 for(int i=0;(i<lookahead)&&root->parent;++i)
534 {
535 root=root->parent;
536 }
537 } else root=m_root;
538 }
539 insertleaf(this,root,leaf);
540}
541
542//
544{
545 btDbvtNode* root=removeleaf(this,leaf);
546 if(root)
547 {
548 if(m_lkhd>=0)
549 {
550 for(int i=0;(i<m_lkhd)&&root->parent;++i)
551 {
552 root=root->parent;
553 }
554 } else root=m_root;
555 }
556 leaf->volume=volume;
557 insertleaf(this,root,leaf);
558}
559
560//
561bool btDbvt::update(btDbvtNode* leaf,btDbvtVolume& volume,const btVector3& velocity,btScalar margin)
562{
563 if(leaf->volume.Contain(volume)) return(false);
564 volume.Expand(btVector3(margin,margin,margin));
565 volume.SignedExpand(velocity);
566 update(leaf,volume);
567 return(true);
568}
569
570//
571bool btDbvt::update(btDbvtNode* leaf,btDbvtVolume& volume,const btVector3& velocity)
572{
573 if(leaf->volume.Contain(volume)) return(false);
574 volume.SignedExpand(velocity);
575 update(leaf,volume);
576 return(true);
577}
578
579//
581{
582 if(leaf->volume.Contain(volume)) return(false);
583 volume.Expand(btVector3(margin,margin,margin));
584 update(leaf,volume);
585 return(true);
586}
587
588//
590{
591 removeleaf(this,leaf);
592 deletenode(this,leaf);
593 --m_leaves;
594}
595
596//
597void btDbvt::write(IWriter* iwriter) const
598{
600 nodes.nodes.reserve(m_leaves*2);
601 enumNodes(m_root,nodes);
602 iwriter->Prepare(m_root,nodes.nodes.size());
603 for(int i=0;i<nodes.nodes.size();++i)
604 {
605 const btDbvtNode* n=nodes.nodes[i];
606 int p=-1;
607 if(n->parent) p=nodes.nodes.findLinearSearch(n->parent);
608 if(n->isinternal())
609 {
610 const int c0=nodes.nodes.findLinearSearch(n->childs[0]);
611 const int c1=nodes.nodes.findLinearSearch(n->childs[1]);
612 iwriter->WriteNode(n,i,p,c0,c1);
613 }
614 else
615 {
616 iwriter->WriteLeaf(n,i,p);
617 }
618 }
619}
620
621//
622void btDbvt::clone(btDbvt& dest,IClone* iclone) const
623{
624 dest.clear();
625 if(m_root!=0)
626 {
628 stack.reserve(m_leaves);
629 stack.push_back(sStkCLN(m_root,0));
630 do {
631 const int i=stack.size()-1;
632 const sStkCLN e=stack[i];
633 btDbvtNode* n=createnode(&dest,e.parent,e.node->volume,e.node->data);
634 stack.pop_back();
635 if(e.parent!=0)
636 e.parent->childs[i&1]=n;
637 else
638 dest.m_root=n;
639 if(e.node->isinternal())
640 {
641 stack.push_back(sStkCLN(e.node->childs[0],n));
642 stack.push_back(sStkCLN(e.node->childs[1],n));
643 }
644 else
645 {
646 iclone->CloneLeaf(n);
647 }
648 } while(stack.size()>0);
649 }
650}
651
652//
654{
655 int depth=0;
656 if(node) getmaxdepth(node,1,depth);
657 return(depth);
658}
659
660//
662{
663 if(node->isinternal())
664 return(countLeaves(node->childs[0])+countLeaves(node->childs[1]));
665 else
666 return(1);
667}
668
669//
671{
672 if(node->isinternal())
673 {
674 extractLeaves(node->childs[0],leaves);
675 extractLeaves(node->childs[1],leaves);
676 }
677 else
678 {
679 leaves.push_back(node);
680 }
681}
682
683//
684#if DBVT_ENABLE_BENCHMARK
685
686#include <stdio.h>
687#include <stdlib.h>
688#include "LinearMath/btQuickProf.h"
689
690/*
691q6600,2.4ghz
692
693/Ox /Ob2 /Oi /Ot /I "." /I "..\.." /I "..\..\src" /D "NDEBUG" /D "_LIB" /D "_WINDOWS" /D "_CRT_SECURE_NO_DEPRECATE" /D "_CRT_NONSTDC_NO_DEPRECATE" /D "WIN32"
694/GF /FD /MT /GS- /Gy /arch:SSE2 /Zc:wchar_t- /Fp"..\..\out\release8\build\libbulletcollision\libbulletcollision.pch"
695/Fo"..\..\out\release8\build\libbulletcollision\\"
696/Fd"..\..\out\release8\build\libbulletcollision\bulletcollision.pdb"
697/W3 /nologo /c /Wp64 /Zi /errorReport:prompt
698
699Benchmarking dbvt...
700World scale: 100.000000
701Extents base: 1.000000
702Extents range: 4.000000
703Leaves: 8192
704sizeof(btDbvtVolume): 32 bytes
705sizeof(btDbvtNode): 44 bytes
706[1] btDbvtVolume intersections: 3499 ms (-1%)
707[2] btDbvtVolume merges: 1934 ms (0%)
708[3] btDbvt::collideTT: 5485 ms (-21%)
709[4] btDbvt::collideTT self: 2814 ms (-20%)
710[5] btDbvt::collideTT xform: 7379 ms (-1%)
711[6] btDbvt::collideTT xform,self: 7270 ms (-2%)
712[7] btDbvt::rayTest: 6314 ms (0%),(332143 r/s)
713[8] insert/remove: 2093 ms (0%),(1001983 ir/s)
714[9] updates (teleport): 1879 ms (-3%),(1116100 u/s)
715[10] updates (jitter): 1244 ms (-4%),(1685813 u/s)
716[11] optimize (incremental): 2514 ms (0%),(1668000 o/s)
717[12] btDbvtVolume notequal: 3659 ms (0%)
718[13] culling(OCL+fullsort): 2218 ms (0%),(461 t/s)
719[14] culling(OCL+qsort): 3688 ms (5%),(2221 t/s)
720[15] culling(KDOP+qsort): 1139 ms (-1%),(7192 t/s)
721[16] insert/remove batch(256): 5092 ms (0%),(823704 bir/s)
722[17] btDbvtVolume select: 3419 ms (0%)
723*/
724
725struct btDbvtBenchmark
726{
727 struct NilPolicy : btDbvt::ICollide
728 {
729 NilPolicy() : m_pcount(0),m_depth(-SIMD_INFINITY),m_checksort(true) {}
730 void Process(const btDbvtNode*,const btDbvtNode*) { ++m_pcount; }
731 void Process(const btDbvtNode*) { ++m_pcount; }
732 void Process(const btDbvtNode*,btScalar depth)
733 {
734 ++m_pcount;
735 if(m_checksort)
736 { if(depth>=m_depth) m_depth=depth; else printf("wrong depth: %f (should be >= %f)\r\n",depth,m_depth); }
737 }
738 int m_pcount;
739 btScalar m_depth;
740 bool m_checksort;
741 };
742 struct P14 : btDbvt::ICollide
743 {
744 struct Node
745 {
746 const btDbvtNode* leaf;
747 btScalar depth;
748 };
749 void Process(const btDbvtNode* leaf,btScalar depth)
750 {
751 Node n;
752 n.leaf = leaf;
753 n.depth = depth;
754 }
755 static int sortfnc(const Node& a,const Node& b)
756 {
757 if(a.depth<b.depth) return(+1);
758 if(a.depth>b.depth) return(-1);
759 return(0);
760 }
762 };
763 struct P15 : btDbvt::ICollide
764 {
765 struct Node
766 {
767 const btDbvtNode* leaf;
768 btScalar depth;
769 };
770 void Process(const btDbvtNode* leaf)
771 {
772 Node n;
773 n.leaf = leaf;
774 n.depth = dot(leaf->volume.Center(),m_axis);
775 }
776 static int sortfnc(const Node& a,const Node& b)
777 {
778 if(a.depth<b.depth) return(+1);
779 if(a.depth>b.depth) return(-1);
780 return(0);
781 }
783 btVector3 m_axis;
784 };
785 static btScalar RandUnit()
786 {
787 return(rand()/(btScalar)RAND_MAX);
788 }
789 static btVector3 RandVector3()
790 {
791 return(btVector3(RandUnit(),RandUnit(),RandUnit()));
792 }
793 static btVector3 RandVector3(btScalar cs)
794 {
795 return(RandVector3()*cs-btVector3(cs,cs,cs)/2);
796 }
797 static btDbvtVolume RandVolume(btScalar cs,btScalar eb,btScalar es)
798 {
799 return(btDbvtVolume::FromCE(RandVector3(cs),btVector3(eb,eb,eb)+RandVector3()*es));
800 }
801 static btTransform RandTransform(btScalar cs)
802 {
803 btTransform t;
804 t.setOrigin(RandVector3(cs));
805 t.setRotation(btQuaternion(RandUnit()*SIMD_PI*2,RandUnit()*SIMD_PI*2,RandUnit()*SIMD_PI*2).normalized());
806 return(t);
807 }
808 static void RandTree(btScalar cs,btScalar eb,btScalar es,int leaves,btDbvt& dbvt)
809 {
810 dbvt.clear();
811 for(int i=0;i<leaves;++i)
812 {
813 dbvt.insert(RandVolume(cs,eb,es),0);
814 }
815 }
816};
817
819{
820 static const btScalar cfgVolumeCenterScale = 100;
821 static const btScalar cfgVolumeExentsBase = 1;
822 static const btScalar cfgVolumeExentsScale = 4;
823 static const int cfgLeaves = 8192;
824 static const bool cfgEnable = true;
825
826 //[1] btDbvtVolume intersections
827 bool cfgBenchmark1_Enable = cfgEnable;
828 static const int cfgBenchmark1_Iterations = 8;
829 static const int cfgBenchmark1_Reference = 3499;
830 //[2] btDbvtVolume merges
831 bool cfgBenchmark2_Enable = cfgEnable;
832 static const int cfgBenchmark2_Iterations = 4;
833 static const int cfgBenchmark2_Reference = 1945;
834 //[3] btDbvt::collideTT
835 bool cfgBenchmark3_Enable = cfgEnable;
836 static const int cfgBenchmark3_Iterations = 512;
837 static const int cfgBenchmark3_Reference = 5485;
838 //[4] btDbvt::collideTT self
839 bool cfgBenchmark4_Enable = cfgEnable;
840 static const int cfgBenchmark4_Iterations = 512;
841 static const int cfgBenchmark4_Reference = 2814;
842 //[5] btDbvt::collideTT xform
843 bool cfgBenchmark5_Enable = cfgEnable;
844 static const int cfgBenchmark5_Iterations = 512;
845 static const btScalar cfgBenchmark5_OffsetScale = 2;
846 static const int cfgBenchmark5_Reference = 7379;
847 //[6] btDbvt::collideTT xform,self
848 bool cfgBenchmark6_Enable = cfgEnable;
849 static const int cfgBenchmark6_Iterations = 512;
850 static const btScalar cfgBenchmark6_OffsetScale = 2;
851 static const int cfgBenchmark6_Reference = 7270;
852 //[7] btDbvt::rayTest
853 bool cfgBenchmark7_Enable = cfgEnable;
854 static const int cfgBenchmark7_Passes = 32;
855 static const int cfgBenchmark7_Iterations = 65536;
856 static const int cfgBenchmark7_Reference = 6307;
857 //[8] insert/remove
858 bool cfgBenchmark8_Enable = cfgEnable;
859 static const int cfgBenchmark8_Passes = 32;
860 static const int cfgBenchmark8_Iterations = 65536;
861 static const int cfgBenchmark8_Reference = 2105;
862 //[9] updates (teleport)
863 bool cfgBenchmark9_Enable = cfgEnable;
864 static const int cfgBenchmark9_Passes = 32;
865 static const int cfgBenchmark9_Iterations = 65536;
866 static const int cfgBenchmark9_Reference = 1879;
867 //[10] updates (jitter)
868 bool cfgBenchmark10_Enable = cfgEnable;
869 static const btScalar cfgBenchmark10_Scale = cfgVolumeCenterScale/10000;
870 static const int cfgBenchmark10_Passes = 32;
871 static const int cfgBenchmark10_Iterations = 65536;
872 static const int cfgBenchmark10_Reference = 1244;
873 //[11] optimize (incremental)
874 bool cfgBenchmark11_Enable = cfgEnable;
875 static const int cfgBenchmark11_Passes = 64;
876 static const int cfgBenchmark11_Iterations = 65536;
877 static const int cfgBenchmark11_Reference = 2510;
878 //[12] btDbvtVolume notequal
879 bool cfgBenchmark12_Enable = cfgEnable;
880 static const int cfgBenchmark12_Iterations = 32;
881 static const int cfgBenchmark12_Reference = 3677;
882 //[13] culling(OCL+fullsort)
883 bool cfgBenchmark13_Enable = cfgEnable;
884 static const int cfgBenchmark13_Iterations = 1024;
885 static const int cfgBenchmark13_Reference = 2231;
886 //[14] culling(OCL+qsort)
887 bool cfgBenchmark14_Enable = cfgEnable;
888 static const int cfgBenchmark14_Iterations = 8192;
889 static const int cfgBenchmark14_Reference = 3500;
890 //[15] culling(KDOP+qsort)
891 bool cfgBenchmark15_Enable = cfgEnable;
892 static const int cfgBenchmark15_Iterations = 8192;
893 static const int cfgBenchmark15_Reference = 1151;
894 //[16] insert/remove batch
895 bool cfgBenchmark16_Enable = cfgEnable;
896 static const int cfgBenchmark16_BatchCount = 256;
897 static const int cfgBenchmark16_Passes = 16384;
898 static const int cfgBenchmark16_Reference = 5138;
899 //[17] select
900 bool cfgBenchmark17_Enable = cfgEnable;
901 static const int cfgBenchmark17_Iterations = 4;
902 static const int cfgBenchmark17_Reference = 3390;
903
904 btClock wallclock;
905 printf("Benchmarking dbvt...\r\n");
906 printf("\tWorld scale: %f\r\n",cfgVolumeCenterScale);
907 printf("\tExtents base: %f\r\n",cfgVolumeExentsBase);
908 printf("\tExtents range: %f\r\n",cfgVolumeExentsScale);
909 printf("\tLeaves: %u\r\n",cfgLeaves);
910 printf("\tsizeof(btDbvtVolume): %u bytes\r\n",sizeof(btDbvtVolume));
911 printf("\tsizeof(btDbvtNode): %u bytes\r\n",sizeof(btDbvtNode));
912 if(cfgBenchmark1_Enable)
913 {// Benchmark 1
914 srand(380843);
917 volumes.resize(cfgLeaves);
918 results.resize(cfgLeaves);
919 for(int i=0;i<cfgLeaves;++i)
920 {
921 volumes[i]=btDbvtBenchmark::RandVolume(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale);
922 }
923 printf("[1] btDbvtVolume intersections: ");
924 wallclock.reset();
925 for(int i=0;i<cfgBenchmark1_Iterations;++i)
926 {
927 for(int j=0;j<cfgLeaves;++j)
928 {
929 for(int k=0;k<cfgLeaves;++k)
930 {
931 results[k]=Intersect(volumes[j],volumes[k]);
932 }
933 }
934 }
935 const int time=(int)wallclock.getTimeMilliseconds();
936 printf("%u ms (%i%%)\r\n",time,(time-cfgBenchmark1_Reference)*100/time);
937 }
938 if(cfgBenchmark2_Enable)
939 {// Benchmark 2
940 srand(380843);
943 volumes.resize(cfgLeaves);
944 results.resize(cfgLeaves);
945 for(int i=0;i<cfgLeaves;++i)
946 {
947 volumes[i]=btDbvtBenchmark::RandVolume(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale);
948 }
949 printf("[2] btDbvtVolume merges: ");
950 wallclock.reset();
951 for(int i=0;i<cfgBenchmark2_Iterations;++i)
952 {
953 for(int j=0;j<cfgLeaves;++j)
954 {
955 for(int k=0;k<cfgLeaves;++k)
956 {
957 Merge(volumes[j],volumes[k],results[k]);
958 }
959 }
960 }
961 const int time=(int)wallclock.getTimeMilliseconds();
962 printf("%u ms (%i%%)\r\n",time,(time-cfgBenchmark2_Reference)*100/time);
963 }
964 if(cfgBenchmark3_Enable)
965 {// Benchmark 3
966 srand(380843);
967 btDbvt dbvt[2];
968 btDbvtBenchmark::NilPolicy policy;
969 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt[0]);
970 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt[1]);
971 dbvt[0].optimizeTopDown();
972 dbvt[1].optimizeTopDown();
973 printf("[3] btDbvt::collideTT: ");
974 wallclock.reset();
975 for(int i=0;i<cfgBenchmark3_Iterations;++i)
976 {
977 btDbvt::collideTT(dbvt[0].m_root,dbvt[1].m_root,policy);
978 }
979 const int time=(int)wallclock.getTimeMilliseconds();
980 printf("%u ms (%i%%)\r\n",time,(time-cfgBenchmark3_Reference)*100/time);
981 }
982 if(cfgBenchmark4_Enable)
983 {// Benchmark 4
984 srand(380843);
985 btDbvt dbvt;
986 btDbvtBenchmark::NilPolicy policy;
987 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt);
988 dbvt.optimizeTopDown();
989 printf("[4] btDbvt::collideTT self: ");
990 wallclock.reset();
991 for(int i=0;i<cfgBenchmark4_Iterations;++i)
992 {
993 btDbvt::collideTT(dbvt.m_root,dbvt.m_root,policy);
994 }
995 const int time=(int)wallclock.getTimeMilliseconds();
996 printf("%u ms (%i%%)\r\n",time,(time-cfgBenchmark4_Reference)*100/time);
997 }
998 if(cfgBenchmark5_Enable)
999 {// Benchmark 5
1000 srand(380843);
1001 btDbvt dbvt[2];
1003 btDbvtBenchmark::NilPolicy policy;
1004 transforms.resize(cfgBenchmark5_Iterations);
1005 for(int i=0;i<transforms.size();++i)
1006 {
1007 transforms[i]=btDbvtBenchmark::RandTransform(cfgVolumeCenterScale*cfgBenchmark5_OffsetScale);
1008 }
1009 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt[0]);
1010 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt[1]);
1011 dbvt[0].optimizeTopDown();
1012 dbvt[1].optimizeTopDown();
1013 printf("[5] btDbvt::collideTT xform: ");
1014 wallclock.reset();
1015 for(int i=0;i<cfgBenchmark5_Iterations;++i)
1016 {
1017 btDbvt::collideTT(dbvt[0].m_root,dbvt[1].m_root,transforms[i],policy);
1018 }
1019 const int time=(int)wallclock.getTimeMilliseconds();
1020 printf("%u ms (%i%%)\r\n",time,(time-cfgBenchmark5_Reference)*100/time);
1021 }
1022 if(cfgBenchmark6_Enable)
1023 {// Benchmark 6
1024 srand(380843);
1025 btDbvt dbvt;
1027 btDbvtBenchmark::NilPolicy policy;
1028 transforms.resize(cfgBenchmark6_Iterations);
1029 for(int i=0;i<transforms.size();++i)
1030 {
1031 transforms[i]=btDbvtBenchmark::RandTransform(cfgVolumeCenterScale*cfgBenchmark6_OffsetScale);
1032 }
1033 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt);
1034 dbvt.optimizeTopDown();
1035 printf("[6] btDbvt::collideTT xform,self: ");
1036 wallclock.reset();
1037 for(int i=0;i<cfgBenchmark6_Iterations;++i)
1038 {
1039 btDbvt::collideTT(dbvt.m_root,dbvt.m_root,transforms[i],policy);
1040 }
1041 const int time=(int)wallclock.getTimeMilliseconds();
1042 printf("%u ms (%i%%)\r\n",time,(time-cfgBenchmark6_Reference)*100/time);
1043 }
1044 if(cfgBenchmark7_Enable)
1045 {// Benchmark 7
1046 srand(380843);
1047 btDbvt dbvt;
1050 btDbvtBenchmark::NilPolicy policy;
1051 rayorg.resize(cfgBenchmark7_Iterations);
1052 raydir.resize(cfgBenchmark7_Iterations);
1053 for(int i=0;i<rayorg.size();++i)
1054 {
1055 rayorg[i]=btDbvtBenchmark::RandVector3(cfgVolumeCenterScale*2);
1056 raydir[i]=btDbvtBenchmark::RandVector3(cfgVolumeCenterScale*2);
1057 }
1058 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt);
1059 dbvt.optimizeTopDown();
1060 printf("[7] btDbvt::rayTest: ");
1061 wallclock.reset();
1062 for(int i=0;i<cfgBenchmark7_Passes;++i)
1063 {
1064 for(int j=0;j<cfgBenchmark7_Iterations;++j)
1065 {
1066 btDbvt::rayTest(dbvt.m_root,rayorg[j],rayorg[j]+raydir[j],policy);
1067 }
1068 }
1069 const int time=(int)wallclock.getTimeMilliseconds();
1070 unsigned rays=cfgBenchmark7_Passes*cfgBenchmark7_Iterations;
1071 printf("%u ms (%i%%),(%u r/s)\r\n",time,(time-cfgBenchmark7_Reference)*100/time,(rays*1000)/time);
1072 }
1073 if(cfgBenchmark8_Enable)
1074 {// Benchmark 8
1075 srand(380843);
1076 btDbvt dbvt;
1077 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt);
1078 dbvt.optimizeTopDown();
1079 printf("[8] insert/remove: ");
1080 wallclock.reset();
1081 for(int i=0;i<cfgBenchmark8_Passes;++i)
1082 {
1083 for(int j=0;j<cfgBenchmark8_Iterations;++j)
1084 {
1085 dbvt.remove(dbvt.insert(btDbvtBenchmark::RandVolume(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale),0));
1086 }
1087 }
1088 const int time=(int)wallclock.getTimeMilliseconds();
1089 const int ir=cfgBenchmark8_Passes*cfgBenchmark8_Iterations;
1090 printf("%u ms (%i%%),(%u ir/s)\r\n",time,(time-cfgBenchmark8_Reference)*100/time,ir*1000/time);
1091 }
1092 if(cfgBenchmark9_Enable)
1093 {// Benchmark 9
1094 srand(380843);
1095 btDbvt dbvt;
1097 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt);
1098 dbvt.optimizeTopDown();
1099 dbvt.extractLeaves(dbvt.m_root,leaves);
1100 printf("[9] updates (teleport): ");
1101 wallclock.reset();
1102 for(int i=0;i<cfgBenchmark9_Passes;++i)
1103 {
1104 for(int j=0;j<cfgBenchmark9_Iterations;++j)
1105 {
1106 dbvt.update(const_cast<btDbvtNode*>(leaves[rand()%cfgLeaves]),
1107 btDbvtBenchmark::RandVolume(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale));
1108 }
1109 }
1110 const int time=(int)wallclock.getTimeMilliseconds();
1111 const int up=cfgBenchmark9_Passes*cfgBenchmark9_Iterations;
1112 printf("%u ms (%i%%),(%u u/s)\r\n",time,(time-cfgBenchmark9_Reference)*100/time,up*1000/time);
1113 }
1114 if(cfgBenchmark10_Enable)
1115 {// Benchmark 10
1116 srand(380843);
1117 btDbvt dbvt;
1120 vectors.resize(cfgBenchmark10_Iterations);
1121 for(int i=0;i<vectors.size();++i)
1122 {
1123 vectors[i]=(btDbvtBenchmark::RandVector3()*2-btVector3(1,1,1))*cfgBenchmark10_Scale;
1124 }
1125 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt);
1126 dbvt.optimizeTopDown();
1127 dbvt.extractLeaves(dbvt.m_root,leaves);
1128 printf("[10] updates (jitter): ");
1129 wallclock.reset();
1130
1131 for(int i=0;i<cfgBenchmark10_Passes;++i)
1132 {
1133 for(int j=0;j<cfgBenchmark10_Iterations;++j)
1134 {
1135 const btVector3& d=vectors[j];
1136 btDbvtNode* l=const_cast<btDbvtNode*>(leaves[rand()%cfgLeaves]);
1138 dbvt.update(l,v);
1139 }
1140 }
1141 const int time=(int)wallclock.getTimeMilliseconds();
1142 const int up=cfgBenchmark10_Passes*cfgBenchmark10_Iterations;
1143 printf("%u ms (%i%%),(%u u/s)\r\n",time,(time-cfgBenchmark10_Reference)*100/time,up*1000/time);
1144 }
1145 if(cfgBenchmark11_Enable)
1146 {// Benchmark 11
1147 srand(380843);
1148 btDbvt dbvt;
1149 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt);
1150 dbvt.optimizeTopDown();
1151 printf("[11] optimize (incremental): ");
1152 wallclock.reset();
1153 for(int i=0;i<cfgBenchmark11_Passes;++i)
1154 {
1155 dbvt.optimizeIncremental(cfgBenchmark11_Iterations);
1156 }
1157 const int time=(int)wallclock.getTimeMilliseconds();
1158 const int op=cfgBenchmark11_Passes*cfgBenchmark11_Iterations;
1159 printf("%u ms (%i%%),(%u o/s)\r\n",time,(time-cfgBenchmark11_Reference)*100/time,op/time*1000);
1160 }
1161 if(cfgBenchmark12_Enable)
1162 {// Benchmark 12
1163 srand(380843);
1166 volumes.resize(cfgLeaves);
1167 results.resize(cfgLeaves);
1168 for(int i=0;i<cfgLeaves;++i)
1169 {
1170 volumes[i]=btDbvtBenchmark::RandVolume(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale);
1171 }
1172 printf("[12] btDbvtVolume notequal: ");
1173 wallclock.reset();
1174 for(int i=0;i<cfgBenchmark12_Iterations;++i)
1175 {
1176 for(int j=0;j<cfgLeaves;++j)
1177 {
1178 for(int k=0;k<cfgLeaves;++k)
1179 {
1180 results[k]=NotEqual(volumes[j],volumes[k]);
1181 }
1182 }
1183 }
1184 const int time=(int)wallclock.getTimeMilliseconds();
1185 printf("%u ms (%i%%)\r\n",time,(time-cfgBenchmark12_Reference)*100/time);
1186 }
1187 if(cfgBenchmark13_Enable)
1188 {// Benchmark 13
1189 srand(380843);
1190 btDbvt dbvt;
1192 btDbvtBenchmark::NilPolicy policy;
1193 vectors.resize(cfgBenchmark13_Iterations);
1194 for(int i=0;i<vectors.size();++i)
1195 {
1196 vectors[i]=(btDbvtBenchmark::RandVector3()*2-btVector3(1,1,1)).normalized();
1197 }
1198 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt);
1199 dbvt.optimizeTopDown();
1200 printf("[13] culling(OCL+fullsort): ");
1201 wallclock.reset();
1202 for(int i=0;i<cfgBenchmark13_Iterations;++i)
1203 {
1204 static const btScalar offset=0;
1205 policy.m_depth=-SIMD_INFINITY;
1206 dbvt.collideOCL(dbvt.m_root,&vectors[i],&offset,vectors[i],1,policy);
1207 }
1208 const int time=(int)wallclock.getTimeMilliseconds();
1209 const int t=cfgBenchmark13_Iterations;
1210 printf("%u ms (%i%%),(%u t/s)\r\n",time,(time-cfgBenchmark13_Reference)*100/time,(t*1000)/time);
1211 }
1212 if(cfgBenchmark14_Enable)
1213 {// Benchmark 14
1214 srand(380843);
1215 btDbvt dbvt;
1217 btDbvtBenchmark::P14 policy;
1218 vectors.resize(cfgBenchmark14_Iterations);
1219 for(int i=0;i<vectors.size();++i)
1220 {
1221 vectors[i]=(btDbvtBenchmark::RandVector3()*2-btVector3(1,1,1)).normalized();
1222 }
1223 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt);
1224 dbvt.optimizeTopDown();
1225 policy.m_nodes.reserve(cfgLeaves);
1226 printf("[14] culling(OCL+qsort): ");
1227 wallclock.reset();
1228 for(int i=0;i<cfgBenchmark14_Iterations;++i)
1229 {
1230 static const btScalar offset=0;
1231 policy.m_nodes.resize(0);
1232 dbvt.collideOCL(dbvt.m_root,&vectors[i],&offset,vectors[i],1,policy,false);
1233 policy.m_nodes.quickSort(btDbvtBenchmark::P14::sortfnc);
1234 }
1235 const int time=(int)wallclock.getTimeMilliseconds();
1236 const int t=cfgBenchmark14_Iterations;
1237 printf("%u ms (%i%%),(%u t/s)\r\n",time,(time-cfgBenchmark14_Reference)*100/time,(t*1000)/time);
1238 }
1239 if(cfgBenchmark15_Enable)
1240 {// Benchmark 15
1241 srand(380843);
1242 btDbvt dbvt;
1244 btDbvtBenchmark::P15 policy;
1245 vectors.resize(cfgBenchmark15_Iterations);
1246 for(int i=0;i<vectors.size();++i)
1247 {
1248 vectors[i]=(btDbvtBenchmark::RandVector3()*2-btVector3(1,1,1)).normalized();
1249 }
1250 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt);
1251 dbvt.optimizeTopDown();
1252 policy.m_nodes.reserve(cfgLeaves);
1253 printf("[15] culling(KDOP+qsort): ");
1254 wallclock.reset();
1255 for(int i=0;i<cfgBenchmark15_Iterations;++i)
1256 {
1257 static const btScalar offset=0;
1258 policy.m_nodes.resize(0);
1259 policy.m_axis=vectors[i];
1260 dbvt.collideKDOP(dbvt.m_root,&vectors[i],&offset,1,policy);
1261 policy.m_nodes.quickSort(btDbvtBenchmark::P15::sortfnc);
1262 }
1263 const int time=(int)wallclock.getTimeMilliseconds();
1264 const int t=cfgBenchmark15_Iterations;
1265 printf("%u ms (%i%%),(%u t/s)\r\n",time,(time-cfgBenchmark15_Reference)*100/time,(t*1000)/time);
1266 }
1267 if(cfgBenchmark16_Enable)
1268 {// Benchmark 16
1269 srand(380843);
1270 btDbvt dbvt;
1272 btDbvtBenchmark::RandTree(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale,cfgLeaves,dbvt);
1273 dbvt.optimizeTopDown();
1274 batch.reserve(cfgBenchmark16_BatchCount);
1275 printf("[16] insert/remove batch(%u): ",cfgBenchmark16_BatchCount);
1276 wallclock.reset();
1277 for(int i=0;i<cfgBenchmark16_Passes;++i)
1278 {
1279 for(int j=0;j<cfgBenchmark16_BatchCount;++j)
1280 {
1281 batch.push_back(dbvt.insert(btDbvtBenchmark::RandVolume(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale),0));
1282 }
1283 for(int j=0;j<cfgBenchmark16_BatchCount;++j)
1284 {
1285 dbvt.remove(batch[j]);
1286 }
1287 batch.resize(0);
1288 }
1289 const int time=(int)wallclock.getTimeMilliseconds();
1290 const int ir=cfgBenchmark16_Passes*cfgBenchmark16_BatchCount;
1291 printf("%u ms (%i%%),(%u bir/s)\r\n",time,(time-cfgBenchmark16_Reference)*100/time,int(ir*1000.0/time));
1292 }
1293 if(cfgBenchmark17_Enable)
1294 {// Benchmark 17
1295 srand(380843);
1299 volumes.resize(cfgLeaves);
1300 results.resize(cfgLeaves);
1301 indices.resize(cfgLeaves);
1302 for(int i=0;i<cfgLeaves;++i)
1303 {
1304 indices[i]=i;
1305 volumes[i]=btDbvtBenchmark::RandVolume(cfgVolumeCenterScale,cfgVolumeExentsBase,cfgVolumeExentsScale);
1306 }
1307 for(int i=0;i<cfgLeaves;++i)
1308 {
1309 btSwap(indices[i],indices[rand()%cfgLeaves]);
1310 }
1311 printf("[17] btDbvtVolume select: ");
1312 wallclock.reset();
1313 for(int i=0;i<cfgBenchmark17_Iterations;++i)
1314 {
1315 for(int j=0;j<cfgLeaves;++j)
1316 {
1317 for(int k=0;k<cfgLeaves;++k)
1318 {
1319 const int idx=indices[k];
1320 results[idx]=Select(volumes[idx],volumes[j],volumes[k]);
1321 }
1322 }
1323 }
1324 const int time=(int)wallclock.getTimeMilliseconds();
1325 printf("%u ms (%i%%)\r\n",time,(time-cfgBenchmark17_Reference)*100/time);
1326 }
1327 printf("\r\n\r\n");
1328}
1329#endif
#define btAlignedFree(ptr)
#define btAlignedAlloc(size, alignment)
static DBVT_INLINE btScalar size(const btDbvtVolume &a)
Definition: btDbvt.cpp:52
static bool leftOfAxis(const btDbvtNode *node, const btVector3 &org, const btVector3 &axis)
Definition: btDbvt.cpp:232
btAlignedObjectArray< const btDbvtNode * > tConstNodeArray
Definition: btDbvt.cpp:21
static void getmaxdepth(const btDbvtNode *node, int depth, int &maxdepth)
Definition: btDbvt.cpp:60
static btDbvtNode * removeleaf(btDbvt *pdbvt, btDbvtNode *leaf)
Definition: btDbvt.cpp:174
static int split(btDbvtNode **leaves, int count, const btVector3 &org, const btVector3 &axis)
Definition: btDbvt.cpp:243
static void insertleaf(btDbvt *pdbvt, btDbvtNode *root, btDbvtNode *leaf)
Definition: btDbvt.cpp:130
static void recursedeletenode(btDbvt *pdbvt, btDbvtNode *node)
Definition: btDbvt.cpp:78
static DBVT_INLINE btDbvtVolume merge(const btDbvtVolume &a, const btDbvtVolume &b)
Definition: btDbvt.cpp:37
static DBVT_INLINE btDbvtNode * createnode(btDbvt *pdbvt, btDbvtNode *parent, void *data)
Definition: btDbvt.cpp:91
static btDbvtVolume bounds(btDbvtNode **leaves, int count)
Definition: btDbvt.cpp:284
static void fetchleaves(btDbvt *pdbvt, btDbvtNode *root, tNodeArray &leaves, int depth=-1)
Definition: btDbvt.cpp:214
static DBVT_INLINE btDbvtNode * sort(btDbvtNode *n, btDbvtNode *&r)
Definition: btDbvt.cpp:403
static DBVT_INLINE int indexof(const btDbvtNode *node)
Definition: btDbvt.cpp:31
static void bottomup(btDbvt *pdbvt, btDbvtNode **leaves, int count)
Definition: btDbvt.cpp:303
static btDbvtNode * topdown(btDbvt *pdbvt, btDbvtNode **leaves, int count, int bu_treshold)
Definition: btDbvt.cpp:337
static DBVT_INLINE void deletenode(btDbvt *pdbvt, btDbvtNode *node)
Definition: btDbvt.cpp:70
btAlignedObjectArray< btDbvtNode * > tNodeArray
btDbvt implementation by Nathanael Presson
Definition: btDbvt.cpp:20
DBVT_INLINE bool Intersect(const btDbvtAabbMm &a, const btDbvtAabbMm &b)
Definition: btDbvt.h:534
DBVT_INLINE void Merge(const btDbvtAabbMm &a, const btDbvtAabbMm &b, btDbvtAabbMm &r)
Definition: btDbvt.h:667
DBVT_INLINE bool NotEqual(const btDbvtAabbMm &a, const btDbvtAabbMm &b)
Definition: btDbvt.h:690
#define DBVT_INLINE
Definition: btDbvt.h:55
DBVT_INLINE int Select(const btDbvtAabbMm &o, const btDbvtAabbMm &a, const btDbvtAabbMm &b)
Definition: btDbvt.h:588
const T & btMax(const T &a, const T &b)
Definition: btMinMax.h:29
btScalar dot(const btQuaternion &q1, const btQuaternion &q2)
Calculate the dot product between two quaternions.
Definition: btQuaternion.h:878
#define SIMD_PI
Definition: btScalar.h:504
float btScalar
The btScalar type abstracts floating point numbers, to easily switch between double and single floati...
Definition: btScalar.h:292
#define ATTRIBUTE_ALIGNED16(a)
Definition: btScalar.h:82
btScalar btFabs(btScalar x)
Definition: btScalar.h:475
#define SIMD_INFINITY
Definition: btScalar.h:522
void btSwap(T &a, T &b)
Definition: btScalar.h:621
#define btAssert(x)
Definition: btScalar.h:131
btScalar btDot(const btVector3 &v1, const btVector3 &v2)
Return the dot product between two vectors.
Definition: btVector3.h:901
The btAlignedObjectArray template class uses a subset of the stl::vector interface for its methods It...
int size() const
return the number of elements in the array
int findLinearSearch(const T &key) const
void resize(int newsize, const T &fillData=T())
void push_back(const T &_Val)
The btClock is a portable basic clock that measures accurate time in seconds, use for profiling.
Definition: btQuickprof.h:25
void reset()
Resets the initial reference time.
unsigned long long int getTimeMilliseconds()
Returns the time in ms since the last call to reset or since the btClock was created.
The btQuaternion implements quaternion to perform linear algebra rotations in combination with btMatr...
Definition: btQuaternion.h:55
The btTransform class supports rigid transforms with only translation and rotation and no scaling/she...
Definition: btTransform.h:34
void setRotation(const btQuaternion &q)
Set the rotational element by btQuaternion.
Definition: btTransform.h:165
void setOrigin(const btVector3 &origin)
Set the translational element.
Definition: btTransform.h:150
btVector3 can be used to represent 3D points and vectors.
Definition: btVector3.h:84
const btScalar & z() const
Return the z value.
Definition: btVector3.h:591
const btScalar & x() const
Return the x value.
Definition: btVector3.h:587
const btScalar & y() const
Return the y value.
Definition: btVector3.h:589
DBVT_INLINE bool Contain(const btDbvtAabbMm &a) const
Definition: btDbvt.h:473
DBVT_INLINE void SignedExpand(const btVector3 &e)
Definition: btDbvt.h:465
static btDbvtAabbMm FromMM(const btVector3 &mi, const btVector3 &mx)
Definition: btDbvt.h:425
DBVT_INLINE const btVector3 & Mins() const
Definition: btDbvt.h:136
static btDbvtAabbMm FromCE(const btVector3 &c, const btVector3 &e)
Definition: btDbvt.h:411
DBVT_INLINE const btVector3 & Maxs() const
Definition: btDbvt.h:137
DBVT_INLINE void Expand(const btVector3 &e)
Definition: btDbvt.h:459
DBVT_INLINE btVector3 Center() const
Definition: btDbvt.h:133
DBVT_INLINE btVector3 Lengths() const
Definition: btDbvt.h:134
tConstNodeArray nodes
Definition: btDbvt.cpp:26
void Process(const btDbvtNode *n)
Definition: btDbvt.cpp:27
DBVT_INLINE bool isinternal() const
Definition: btDbvt.h:183
btDbvtNode * childs[2]
Definition: btDbvt.h:186
btDbvtNode * parent
Definition: btDbvt.h:181
void * data
Definition: btDbvt.h:187
btDbvtVolume volume
Definition: btDbvt.h:180
DBVT_INLINE bool isleaf() const
Definition: btDbvt.h:182
virtual void CloneLeaf(btDbvtNode *)
Definition: btDbvt.h:252
virtual void WriteLeaf(const btDbvtNode *, int index, int parent)=0
virtual void Prepare(const btDbvtNode *root, int numnodes)=0
virtual void WriteNode(const btDbvtNode *, int index, int parent, int child0, int child1)=0
btDbvtNode * parent
Definition: btDbvt.h:225
const btDbvtNode * node
Definition: btDbvt.h:224
The btDbvt class implements a fast dynamic bounding volume tree based on axis aligned bounding boxes ...
Definition: btDbvt.h:199
void optimizeBottomUp()
Definition: btDbvt.cpp:472
btDbvtNode * insert(const btDbvtVolume &box, void *data)
Definition: btDbvt.cpp:517
void optimizeIncremental(int passes)
Definition: btDbvt.cpp:497
void optimizeTopDown(int bu_treshold=128)
Definition: btDbvt.cpp:485
static DBVT_PREFIX void collideOCL(const btDbvtNode *root, const btVector3 *normals, const btScalar *offsets, const btVector3 &sortaxis, int count, DBVT_IPOLICY, bool fullsort=true)
Definition: btDbvt.h:1189
~btDbvt()
Definition: btDbvt.cpp:453
unsigned m_opath
Definition: btDbvt.h:266
static void benchmark()
Definition: btDbvt.h:295
static DBVT_PREFIX void enumNodes(const btDbvtNode *root, DBVT_IPOLICY)
Definition: btDbvt.h:707
void write(IWriter *iwriter) const
Definition: btDbvt.cpp:597
void update(btDbvtNode *leaf, int lookahead=-1)
Definition: btDbvt.cpp:526
btAlignedObjectArray< sStkNN > m_stkStack
Definition: btDbvt.h:269
btDbvtNode * m_free
Definition: btDbvt.h:263
void clone(btDbvt &dest, IClone *iclone=0) const
Definition: btDbvt.cpp:622
static DBVT_PREFIX void rayTest(const btDbvtNode *root, const btVector3 &rayFrom, const btVector3 &rayTo, DBVT_IPOLICY)
rayTest is a re-entrant ray test, and can be called in parallel as long as the btAlignedAlloc is thre...
Definition: btDbvt.h:1060
static DBVT_PREFIX void collideKDOP(const btDbvtNode *root, const btVector3 *normals, const btScalar *offsets, int count, DBVT_IPOLICY)
Definition: btDbvt.h:1134
int m_leaves
Definition: btDbvt.h:265
void clear()
Definition: btDbvt.cpp:459
static void extractLeaves(const btDbvtNode *node, btAlignedObjectArray< const btDbvtNode * > &leaves)
Definition: btDbvt.cpp:670
btDbvt()
Definition: btDbvt.cpp:443
static int countLeaves(const btDbvtNode *node)
Definition: btDbvt.cpp:661
btDbvtNode * m_root
Definition: btDbvt.h:262
int m_lkhd
Definition: btDbvt.h:264
void remove(btDbvtNode *leaf)
Definition: btDbvt.cpp:589
DBVT_PREFIX void collideTT(const btDbvtNode *root0, const btDbvtNode *root1, DBVT_IPOLICY)
Definition: btDbvt.h:738
static int maxdepth(const btDbvtNode *node)
Definition: btDbvt.cpp:653