LNXSDK/lib/haxebullet/bullet/BulletCollision/BroadphaseCollision/btDbvtBroadphase.cpp

/*
Bullet Continuous Collision Detection and Physics Library
Copyright (c) 2003-2009 Erwin Coumans  http://bulletphysics.org

This software is provided 'as-is', without any express or implied warranty.
In no event will the authors be held liable for any damages arising from the use of this software.
Permission is granted to anyone to use this software for any purpose, 
including commercial applications, and to alter it and redistribute it freely, 
subject to the following restrictions:

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.
2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
3. This notice may not be removed or altered from any source distribution.
*/

///btDbvtBroadphase implementation by Nathanael Presson

#include "btDbvtBroadphase.h"
#include "LinearMath/btThreads.h"

//
// Profiling
//

#if DBVT_BP_PROFILE||DBVT_BP_ENABLE_BENCHMARK
#include <stdio.h>
#endif

#if DBVT_BP_PROFILE
struct	ProfileScope
{
	__forceinline ProfileScope(btClock& clock,unsigned long& value) :
	m_clock(&clock),m_value(&value),m_base(clock.getTimeMicroseconds())
	{
	}
	__forceinline ~ProfileScope()
	{
		(*m_value)+=m_clock->getTimeMicroseconds()-m_base;
	}
	btClock*		m_clock;
	unsigned long*	m_value;
	unsigned long	m_base;
};
#define	SPC(_value_)	ProfileScope	spc_scope(m_clock,_value_)
#else
#define	SPC(_value_)
#endif

//
// Helpers
//

//
template <typename T>
static inline void	listappend(T* item,T*& list)
{
	item->links[0]=0;
	item->links[1]=list;
	if(list) list->links[0]=item;
	list=item;
}

//
template <typename T>
static inline void	listremove(T* item,T*& list)
{
	if(item->links[0]) item->links[0]->links[1]=item->links[1]; else list=item->links[1];
	if(item->links[1]) item->links[1]->links[0]=item->links[0];
}

//
template <typename T>
static inline int	listcount(T* root)
{
	int	n=0;
	while(root) { ++n;root=root->links[1]; }
	return(n);
}

//
template <typename T>
static inline void	clear(T& value)
{
	static const struct ZeroDummy : T {} zerodummy;
	value=zerodummy;
}

//
// Colliders
//

/* Tree collider	*/ 
struct	btDbvtTreeCollider : btDbvt::ICollide
{
	btDbvtBroadphase*	pbp;
	btDbvtProxy*		proxy;
	btDbvtTreeCollider(btDbvtBroadphase* p) : pbp(p) {}
	void	Process(const btDbvtNode* na,const btDbvtNode* nb)
	{
		if(na!=nb)
		{
			btDbvtProxy*	pa=(btDbvtProxy*)na->data;
			btDbvtProxy*	pb=(btDbvtProxy*)nb->data;
#if DBVT_BP_SORTPAIRS
			if(pa->m_uniqueId>pb->m_uniqueId) 
				btSwap(pa,pb);
#endif
			pbp->m_paircache->addOverlappingPair(pa,pb);
			++pbp->m_newpairs;
		}
	}
	void	Process(const btDbvtNode* n)
	{
		Process(n,proxy->leaf);
	}
};

//
// btDbvtBroadphase
//

//
btDbvtBroadphase::btDbvtBroadphase(btOverlappingPairCache* paircache)
{
	m_deferedcollide	=	false;
	m_needcleanup		=	true;
	m_releasepaircache	=	(paircache!=0)?false:true;
	m_prediction		=	0;
	m_stageCurrent		=	0;
	m_fixedleft			=	0;
	m_fupdates			=	1;
	m_dupdates			=	0;
	m_cupdates			=	10;
	m_newpairs			=	1;
	m_updates_call		=	0;
	m_updates_done		=	0;
	m_updates_ratio		=	0;
	m_paircache			=	paircache? paircache	: new(btAlignedAlloc(sizeof(btHashedOverlappingPairCache),16)) btHashedOverlappingPairCache();
	m_gid				=	0;
	m_pid				=	0;
	m_cid				=	0;
	for(int i=0;i<=STAGECOUNT;++i)
	{
		m_stageRoots[i]=0;
	}
#if BT_THREADSAFE
    m_rayTestStacks.resize(BT_MAX_THREAD_COUNT);
#else
    m_rayTestStacks.resize(1);
#endif
#if DBVT_BP_PROFILE
	clear(m_profiling);
#endif
}

//
btDbvtBroadphase::~btDbvtBroadphase()
{
	if(m_releasepaircache) 
	{
		m_paircache->~btOverlappingPairCache();
		btAlignedFree(m_paircache);
	}
}

//
btBroadphaseProxy*				btDbvtBroadphase::createProxy(	const btVector3& aabbMin,
															  const btVector3& aabbMax,
															  int /*shapeType*/,
															  void* userPtr,
															  int collisionFilterGroup,
															  int collisionFilterMask,
															  btDispatcher* /*dispatcher*/)
{
	btDbvtProxy*		proxy=new(btAlignedAlloc(sizeof(btDbvtProxy),16)) btDbvtProxy(	aabbMin,aabbMax,userPtr,
		collisionFilterGroup,
		collisionFilterMask);

	btDbvtAabbMm aabb = btDbvtVolume::FromMM(aabbMin,aabbMax);

	//bproxy->aabb			=	btDbvtVolume::FromMM(aabbMin,aabbMax);
	proxy->stage		=	m_stageCurrent;
	proxy->m_uniqueId	=	++m_gid;
	proxy->leaf			=	m_sets[0].insert(aabb,proxy);
	listappend(proxy,m_stageRoots[m_stageCurrent]);
	if(!m_deferedcollide)
	{
		btDbvtTreeCollider	collider(this);
		collider.proxy=proxy;
		m_sets[0].collideTV(m_sets[0].m_root,aabb,collider);
		m_sets[1].collideTV(m_sets[1].m_root,aabb,collider);
	}
	return(proxy);
}

//
void							btDbvtBroadphase::destroyProxy(	btBroadphaseProxy* absproxy,
															   btDispatcher* dispatcher)
{
	btDbvtProxy*	proxy=(btDbvtProxy*)absproxy;
	if(proxy->stage==STAGECOUNT)
		m_sets[1].remove(proxy->leaf);
	else
		m_sets[0].remove(proxy->leaf);
	listremove(proxy,m_stageRoots[proxy->stage]);
	m_paircache->removeOverlappingPairsContainingProxy(proxy,dispatcher);
	btAlignedFree(proxy);
	m_needcleanup=true;
}

void	btDbvtBroadphase::getAabb(btBroadphaseProxy* absproxy,btVector3& aabbMin, btVector3& aabbMax ) const
{
	btDbvtProxy*						proxy=(btDbvtProxy*)absproxy;
	aabbMin = proxy->m_aabbMin;
	aabbMax = proxy->m_aabbMax;
}

struct	BroadphaseRayTester : btDbvt::ICollide
{
	btBroadphaseRayCallback& m_rayCallback;
	BroadphaseRayTester(btBroadphaseRayCallback& orgCallback)
		:m_rayCallback(orgCallback)
	{
	}
	void					Process(const btDbvtNode* leaf)
	{
		btDbvtProxy*	proxy=(btDbvtProxy*)leaf->data;
		m_rayCallback.process(proxy);
	}
};	

void	btDbvtBroadphase::rayTest(const btVector3& rayFrom,const btVector3& rayTo, btBroadphaseRayCallback& rayCallback,const btVector3& aabbMin,const btVector3& aabbMax)
{
	BroadphaseRayTester callback(rayCallback);
    btAlignedObjectArray<const btDbvtNode*>* stack = &m_rayTestStacks[0];
#if BT_THREADSAFE
    // for this function to be threadsafe, each thread must have a separate copy
    // of this stack.  This could be thread-local static to avoid dynamic allocations,
    // instead of just a local.
    int threadIndex = btGetCurrentThreadIndex();
    btAlignedObjectArray<const btDbvtNode*> localStack;
    if (threadIndex < m_rayTestStacks.size())
    {
        // use per-thread preallocated stack if possible to avoid dynamic allocations
        stack = &m_rayTestStacks[threadIndex];
    }
    else
    {
        stack = &localStack;
    }
#endif

	m_sets[0].rayTestInternal(	m_sets[0].m_root,
		rayFrom,
		rayTo,
		rayCallback.m_rayDirectionInverse,
		rayCallback.m_signs,
		rayCallback.m_lambda_max,
		aabbMin,
		aabbMax,
        *stack,
		callback);

	m_sets[1].rayTestInternal(	m_sets[1].m_root,
		rayFrom,
		rayTo,
		rayCallback.m_rayDirectionInverse,
		rayCallback.m_signs,
		rayCallback.m_lambda_max,
		aabbMin,
		aabbMax,
        *stack,
		callback);

}


struct	BroadphaseAabbTester : btDbvt::ICollide
{
	btBroadphaseAabbCallback& m_aabbCallback;
	BroadphaseAabbTester(btBroadphaseAabbCallback& orgCallback)
		:m_aabbCallback(orgCallback)
	{
	}
	void					Process(const btDbvtNode* leaf)
	{
		btDbvtProxy*	proxy=(btDbvtProxy*)leaf->data;
		m_aabbCallback.process(proxy);
	}
};	

void	btDbvtBroadphase::aabbTest(const btVector3& aabbMin,const btVector3& aabbMax,btBroadphaseAabbCallback& aabbCallback)
{
	BroadphaseAabbTester callback(aabbCallback);

	const ATTRIBUTE_ALIGNED16(btDbvtVolume)	bounds=btDbvtVolume::FromMM(aabbMin,aabbMax);
		//process all children, that overlap with  the given AABB bounds
	m_sets[0].collideTV(m_sets[0].m_root,bounds,callback);
	m_sets[1].collideTV(m_sets[1].m_root,bounds,callback);

}



//
void							btDbvtBroadphase::setAabb(		btBroadphaseProxy* absproxy,
														  const btVector3& aabbMin,
														  const btVector3& aabbMax,
														  btDispatcher* /*dispatcher*/)
{
	btDbvtProxy*						proxy=(btDbvtProxy*)absproxy;
	ATTRIBUTE_ALIGNED16(btDbvtVolume)	aabb=btDbvtVolume::FromMM(aabbMin,aabbMax);
#if DBVT_BP_PREVENTFALSEUPDATE
	if(NotEqual(aabb,proxy->leaf->volume))
#endif
	{
		bool	docollide=false;
		if(proxy->stage==STAGECOUNT)
		{/* fixed -> dynamic set	*/ 
			m_sets[1].remove(proxy->leaf);
			proxy->leaf=m_sets[0].insert(aabb,proxy);
			docollide=true;
		}
		else
		{/* dynamic set				*/ 
			++m_updates_call;
			if(Intersect(proxy->leaf->volume,aabb))
			{/* Moving				*/ 

				const btVector3	delta=aabbMin-proxy->m_aabbMin;
				btVector3		velocity(((proxy->m_aabbMax-proxy->m_aabbMin)/2)*m_prediction);
				if(delta[0]<0) velocity[0]=-velocity[0];
				if(delta[1]<0) velocity[1]=-velocity[1];
				if(delta[2]<0) velocity[2]=-velocity[2];
				if	(
#ifdef DBVT_BP_MARGIN				
					m_sets[0].update(proxy->leaf,aabb,velocity,DBVT_BP_MARGIN)
#else
					m_sets[0].update(proxy->leaf,aabb,velocity)
#endif
					)
				{
					++m_updates_done;
					docollide=true;
				}
			}
			else
			{/* Teleporting			*/ 
				m_sets[0].update(proxy->leaf,aabb);
				++m_updates_done;
				docollide=true;
			}	
		}
		listremove(proxy,m_stageRoots[proxy->stage]);
		proxy->m_aabbMin = aabbMin;
		proxy->m_aabbMax = aabbMax;
		proxy->stage	=	m_stageCurrent;
		listappend(proxy,m_stageRoots[m_stageCurrent]);
		if(docollide)
		{
			m_needcleanup=true;
			if(!m_deferedcollide)
			{
				btDbvtTreeCollider	collider(this);
				m_sets[1].collideTTpersistentStack(m_sets[1].m_root,proxy->leaf,collider);
				m_sets[0].collideTTpersistentStack(m_sets[0].m_root,proxy->leaf,collider);
			}
		}	
	}
}


//
void							btDbvtBroadphase::setAabbForceUpdate(		btBroadphaseProxy* absproxy,
														  const btVector3& aabbMin,
														  const btVector3& aabbMax,
														  btDispatcher* /*dispatcher*/)
{
	btDbvtProxy*						proxy=(btDbvtProxy*)absproxy;
	ATTRIBUTE_ALIGNED16(btDbvtVolume)	aabb=btDbvtVolume::FromMM(aabbMin,aabbMax);
	bool	docollide=false;
	if(proxy->stage==STAGECOUNT)
	{/* fixed -> dynamic set	*/ 
		m_sets[1].remove(proxy->leaf);
		proxy->leaf=m_sets[0].insert(aabb,proxy);
		docollide=true;
	}
	else
	{/* dynamic set				*/ 
		++m_updates_call;
		/* Teleporting			*/ 
		m_sets[0].update(proxy->leaf,aabb);
		++m_updates_done;
		docollide=true;
	}
	listremove(proxy,m_stageRoots[proxy->stage]);
	proxy->m_aabbMin = aabbMin;
	proxy->m_aabbMax = aabbMax;
	proxy->stage	=	m_stageCurrent;
	listappend(proxy,m_stageRoots[m_stageCurrent]);
	if(docollide)
	{
		m_needcleanup=true;
		if(!m_deferedcollide)
		{
			btDbvtTreeCollider	collider(this);
			m_sets[1].collideTTpersistentStack(m_sets[1].m_root,proxy->leaf,collider);
			m_sets[0].collideTTpersistentStack(m_sets[0].m_root,proxy->leaf,collider);
		}
	}	
}

//
void							btDbvtBroadphase::calculateOverlappingPairs(btDispatcher* dispatcher)
{
	collide(dispatcher);
#if DBVT_BP_PROFILE
	if(0==(m_pid%DBVT_BP_PROFILING_RATE))
	{	
		printf("fixed(%u) dynamics(%u) pairs(%u)\r\n",m_sets[1].m_leaves,m_sets[0].m_leaves,m_paircache->getNumOverlappingPairs());
		unsigned int	total=m_profiling.m_total;
		if(total<=0) total=1;
		printf("ddcollide: %u%% (%uus)\r\n",(50+m_profiling.m_ddcollide*100)/total,m_profiling.m_ddcollide/DBVT_BP_PROFILING_RATE);
		printf("fdcollide: %u%% (%uus)\r\n",(50+m_profiling.m_fdcollide*100)/total,m_profiling.m_fdcollide/DBVT_BP_PROFILING_RATE);
		printf("cleanup:   %u%% (%uus)\r\n",(50+m_profiling.m_cleanup*100)/total,m_profiling.m_cleanup/DBVT_BP_PROFILING_RATE);
		printf("total:     %uus\r\n",total/DBVT_BP_PROFILING_RATE);
		const unsigned long	sum=m_profiling.m_ddcollide+
			m_profiling.m_fdcollide+
			m_profiling.m_cleanup;
		printf("leaked: %u%% (%uus)\r\n",100-((50+sum*100)/total),(total-sum)/DBVT_BP_PROFILING_RATE);
		printf("job counts: %u%%\r\n",(m_profiling.m_jobcount*100)/((m_sets[0].m_leaves+m_sets[1].m_leaves)*DBVT_BP_PROFILING_RATE));
		clear(m_profiling);
		m_clock.reset();
	}
#endif

	performDeferredRemoval(dispatcher);

}

void btDbvtBroadphase::performDeferredRemoval(btDispatcher* dispatcher)
{

	if (m_paircache->hasDeferredRemoval())
	{

		btBroadphasePairArray&	overlappingPairArray = m_paircache->getOverlappingPairArray();

		//perform a sort, to find duplicates and to sort 'invalid' pairs to the end
		overlappingPairArray.quickSort(btBroadphasePairSortPredicate());

		int invalidPair = 0;

		
		int i;

		btBroadphasePair previousPair;
		previousPair.m_pProxy0 = 0;
		previousPair.m_pProxy1 = 0;
		previousPair.m_algorithm = 0;
		
		
		for (i=0;i<overlappingPairArray.size();i++)
		{
		
			btBroadphasePair& pair = overlappingPairArray[i];

			bool isDuplicate = (pair == previousPair);

			previousPair = pair;

			bool needsRemoval = false;

			if (!isDuplicate)
			{
				//important to perform AABB check that is consistent with the broadphase
				btDbvtProxy*		pa=(btDbvtProxy*)pair.m_pProxy0;
				btDbvtProxy*		pb=(btDbvtProxy*)pair.m_pProxy1;
				bool hasOverlap = Intersect(pa->leaf->volume,pb->leaf->volume);

				if (hasOverlap)
				{
					needsRemoval = false;
				} else
				{
					needsRemoval = true;
				}
			} else
			{
				//remove duplicate
				needsRemoval = true;
				//should have no algorithm
				btAssert(!pair.m_algorithm);
			}
			
			if (needsRemoval)
			{
				m_paircache->cleanOverlappingPair(pair,dispatcher);

				pair.m_pProxy0 = 0;
				pair.m_pProxy1 = 0;
				invalidPair++;
			} 
			
		}

		//perform a sort, to sort 'invalid' pairs to the end
		overlappingPairArray.quickSort(btBroadphasePairSortPredicate());
		overlappingPairArray.resize(overlappingPairArray.size() - invalidPair);
	}
}

//
void							btDbvtBroadphase::collide(btDispatcher* dispatcher)
{
	/*printf("---------------------------------------------------------\n");
	printf("m_sets[0].m_leaves=%d\n",m_sets[0].m_leaves);
	printf("m_sets[1].m_leaves=%d\n",m_sets[1].m_leaves);
	printf("numPairs = %d\n",getOverlappingPairCache()->getNumOverlappingPairs());
	{
		int i;
		for (i=0;i<getOverlappingPairCache()->getNumOverlappingPairs();i++)
		{
			printf("pair[%d]=(%d,%d),",i,getOverlappingPairCache()->getOverlappingPairArray()[i].m_pProxy0->getUid(),
				getOverlappingPairCache()->getOverlappingPairArray()[i].m_pProxy1->getUid());
		}
		printf("\n");
	}
*/



	SPC(m_profiling.m_total);
	/* optimize				*/ 
	m_sets[0].optimizeIncremental(1+(m_sets[0].m_leaves*m_dupdates)/100);
	if(m_fixedleft)
	{
		const int count=1+(m_sets[1].m_leaves*m_fupdates)/100;
		m_sets[1].optimizeIncremental(1+(m_sets[1].m_leaves*m_fupdates)/100);
		m_fixedleft=btMax<int>(0,m_fixedleft-count);
	}
	/* dynamic -> fixed set	*/ 
	m_stageCurrent=(m_stageCurrent+1)%STAGECOUNT;
	btDbvtProxy*	current=m_stageRoots[m_stageCurrent];
	if(current)
	{
#if DBVT_BP_ACCURATESLEEPING
		btDbvtTreeCollider	collider(this);
#endif
		do	{
			btDbvtProxy*	next=current->links[1];
			listremove(current,m_stageRoots[current->stage]);
			listappend(current,m_stageRoots[STAGECOUNT]);
#if DBVT_BP_ACCURATESLEEPING
			m_paircache->removeOverlappingPairsContainingProxy(current,dispatcher);
			collider.proxy=current;
			btDbvt::collideTV(m_sets[0].m_root,current->aabb,collider);
			btDbvt::collideTV(m_sets[1].m_root,current->aabb,collider);
#endif
			m_sets[0].remove(current->leaf);
			ATTRIBUTE_ALIGNED16(btDbvtVolume)	curAabb=btDbvtVolume::FromMM(current->m_aabbMin,current->m_aabbMax);
			current->leaf	=	m_sets[1].insert(curAabb,current);
			current->stage	=	STAGECOUNT;	
			current			=	next;
		} while(current);
		m_fixedleft=m_sets[1].m_leaves;
		m_needcleanup=true;
	}
	/* collide dynamics		*/ 
	{
		btDbvtTreeCollider	collider(this);
		if(m_deferedcollide)
		{
			SPC(m_profiling.m_fdcollide);
			m_sets[0].collideTTpersistentStack(m_sets[0].m_root,m_sets[1].m_root,collider);
		}
		if(m_deferedcollide)
		{
			SPC(m_profiling.m_ddcollide);
			m_sets[0].collideTTpersistentStack(m_sets[0].m_root,m_sets[0].m_root,collider);
		}
	}
	/* clean up				*/ 
	if(m_needcleanup)
	{
		SPC(m_profiling.m_cleanup);
		btBroadphasePairArray&	pairs=m_paircache->getOverlappingPairArray();
		if(pairs.size()>0)
		{

			int			ni=btMin(pairs.size(),btMax<int>(m_newpairs,(pairs.size()*m_cupdates)/100));
			for(int i=0;i<ni;++i)
			{
				btBroadphasePair&	p=pairs[(m_cid+i)%pairs.size()];
				btDbvtProxy*		pa=(btDbvtProxy*)p.m_pProxy0;
				btDbvtProxy*		pb=(btDbvtProxy*)p.m_pProxy1;
				if(!Intersect(pa->leaf->volume,pb->leaf->volume))
				{
#if DBVT_BP_SORTPAIRS
					if(pa->m_uniqueId>pb->m_uniqueId) 
						btSwap(pa,pb);
#endif
					m_paircache->removeOverlappingPair(pa,pb,dispatcher);
					--ni;--i;
				}
			}
			if(pairs.size()>0) m_cid=(m_cid+ni)%pairs.size(); else m_cid=0;
		}
	}
	++m_pid;
	m_newpairs=1;
	m_needcleanup=false;
	if(m_updates_call>0)
	{ m_updates_ratio=m_updates_done/(btScalar)m_updates_call; }
	else
	{ m_updates_ratio=0; }
	m_updates_done/=2;
	m_updates_call/=2;
}

//
void							btDbvtBroadphase::optimize()
{
	m_sets[0].optimizeTopDown();
	m_sets[1].optimizeTopDown();
}

//
btOverlappingPairCache*			btDbvtBroadphase::getOverlappingPairCache()
{
	return(m_paircache);
}

//
const btOverlappingPairCache*	btDbvtBroadphase::getOverlappingPairCache() const
{
	return(m_paircache);
}

//
void							btDbvtBroadphase::getBroadphaseAabb(btVector3& aabbMin,btVector3& aabbMax) const
{

	ATTRIBUTE_ALIGNED16(btDbvtVolume)	bounds;

	if(!m_sets[0].empty())
		if(!m_sets[1].empty())	Merge(	m_sets[0].m_root->volume,
			m_sets[1].m_root->volume,bounds);
		else
			bounds=m_sets[0].m_root->volume;
	else if(!m_sets[1].empty())	bounds=m_sets[1].m_root->volume;
	else
		bounds=btDbvtVolume::FromCR(btVector3(0,0,0),0);
	aabbMin=bounds.Mins();
	aabbMax=bounds.Maxs();
}

void btDbvtBroadphase::resetPool(btDispatcher* dispatcher)
{
	
	int totalObjects = m_sets[0].m_leaves + m_sets[1].m_leaves;
	if (!totalObjects)
	{
		//reset internal dynamic tree data structures
		m_sets[0].clear();
		m_sets[1].clear();
		
		m_deferedcollide	=	false;
		m_needcleanup		=	true;
		m_stageCurrent		=	0;
		m_fixedleft			=	0;
		m_fupdates			=	1;
		m_dupdates			=	0;
		m_cupdates			=	10;
		m_newpairs			=	1;
		m_updates_call		=	0;
		m_updates_done		=	0;
		m_updates_ratio		=	0;
		
		m_gid				=	0;
		m_pid				=	0;
		m_cid				=	0;
		for(int i=0;i<=STAGECOUNT;++i)
		{
			m_stageRoots[i]=0;
		}
	}
}

//
void							btDbvtBroadphase::printStats()
{}

//
#if DBVT_BP_ENABLE_BENCHMARK

struct	btBroadphaseBenchmark
{
	struct	Experiment
	{
		const char*			name;
		int					object_count;
		int					update_count;
		int					spawn_count;
		int					iterations;
		btScalar			speed;
		btScalar			amplitude;
	};
	struct	Object
	{
		btVector3			center;
		btVector3			extents;
		btBroadphaseProxy*	proxy;
		btScalar			time;
		void				update(btScalar speed,btScalar amplitude,btBroadphaseInterface* pbi)
		{
			time		+=	speed;
			center[0]	=	btCos(time*(btScalar)2.17)*amplitude+
				btSin(time)*amplitude/2;
			center[1]	=	btCos(time*(btScalar)1.38)*amplitude+
				btSin(time)*amplitude;
			center[2]	=	btSin(time*(btScalar)0.777)*amplitude;
			pbi->setAabb(proxy,center-extents,center+extents,0);
		}
	};
	static int		UnsignedRand(int range=RAND_MAX-1)	{ return(rand()%(range+1)); }
	static btScalar	UnitRand()							{ return(UnsignedRand(16384)/(btScalar)16384); }
	static void		OutputTime(const char* name,btClock& c,unsigned count=0)
	{
		const unsigned long	us=c.getTimeMicroseconds();
		const unsigned long	ms=(us+500)/1000;
		const btScalar		sec=us/(btScalar)(1000*1000);
		if(count>0)
			printf("%s : %u us (%u ms), %.2f/s\r\n",name,us,ms,count/sec);
		else
			printf("%s : %u us (%u ms)\r\n",name,us,ms);
	}
};

void							btDbvtBroadphase::benchmark(btBroadphaseInterface* pbi)
{
	static const btBroadphaseBenchmark::Experiment		experiments[]=
	{
		{"1024o.10%",1024,10,0,8192,(btScalar)0.005,(btScalar)100},
		/*{"4096o.10%",4096,10,0,8192,(btScalar)0.005,(btScalar)100},
		{"8192o.10%",8192,10,0,8192,(btScalar)0.005,(btScalar)100},*/
	};
	static const int										nexperiments=sizeof(experiments)/sizeof(experiments[0]);
	btAlignedObjectArray<btBroadphaseBenchmark::Object*>	objects;
	btClock													wallclock;
	/* Begin			*/ 
	for(int iexp=0;iexp<nexperiments;++iexp)
	{
		const btBroadphaseBenchmark::Experiment&	experiment=experiments[iexp];
		const int									object_count=experiment.object_count;
		const int									update_count=(object_count*experiment.update_count)/100;
		const int									spawn_count=(object_count*experiment.spawn_count)/100;
		const btScalar								speed=experiment.speed;	
		const btScalar								amplitude=experiment.amplitude;
		printf("Experiment #%u '%s':\r\n",iexp,experiment.name);
		printf("\tObjects: %u\r\n",object_count);
		printf("\tUpdate: %u\r\n",update_count);
		printf("\tSpawn: %u\r\n",spawn_count);
		printf("\tSpeed: %f\r\n",speed);
		printf("\tAmplitude: %f\r\n",amplitude);
		srand(180673);
		/* Create objects	*/ 
		wallclock.reset();
		objects.reserve(object_count);
		for(int i=0;i<object_count;++i)
		{
			btBroadphaseBenchmark::Object*	po=new btBroadphaseBenchmark::Object();
			po->center[0]=btBroadphaseBenchmark::UnitRand()*50;
			po->center[1]=btBroadphaseBenchmark::UnitRand()*50;
			po->center[2]=btBroadphaseBenchmark::UnitRand()*50;
			po->extents[0]=btBroadphaseBenchmark::UnitRand()*2+2;
			po->extents[1]=btBroadphaseBenchmark::UnitRand()*2+2;
			po->extents[2]=btBroadphaseBenchmark::UnitRand()*2+2;
			po->time=btBroadphaseBenchmark::UnitRand()*2000;
			po->proxy=pbi->createProxy(po->center-po->extents,po->center+po->extents,0,po,1,1,0,0);
			objects.push_back(po);
		}
		btBroadphaseBenchmark::OutputTime("\tInitialization",wallclock);
		/* First update		*/ 
		wallclock.reset();
		for(int i=0;i<objects.size();++i)
		{
			objects[i]->update(speed,amplitude,pbi);
		}
		btBroadphaseBenchmark::OutputTime("\tFirst update",wallclock);
		/* Updates			*/ 
		wallclock.reset();
		for(int i=0;i<experiment.iterations;++i)
		{
			for(int j=0;j<update_count;++j)
			{				
				objects[j]->update(speed,amplitude,pbi);
			}
			pbi->calculateOverlappingPairs(0);
		}
		btBroadphaseBenchmark::OutputTime("\tUpdate",wallclock,experiment.iterations);
		/* Clean up			*/ 
		wallclock.reset();
		for(int i=0;i<objects.size();++i)
		{
			pbi->destroyProxy(objects[i]->proxy,0);
			delete objects[i];
		}
		objects.resize(0);
		btBroadphaseBenchmark::OutputTime("\tRelease",wallclock);
	}

}
#else
void							btDbvtBroadphase::benchmark(btBroadphaseInterface*)
{}
#endif

#if DBVT_BP_PROFILE
#undef	SPC
#endif