public virtual void ProcessTriangle(ObjectArray<Vector3> triangle, int partId, int triangleIndex)
		{
			TriangleShape triangleShape = new TriangleShape(triangle[0], triangle[1], triangle[2]);
			triangleShape.Margin = m_triangleCollisionMargin;

			VoronoiSimplexSolver simplexSolver = new VoronoiSimplexSolver();
			GjkEpaPenetrationDepthSolver gjkEpaPenetrationSolver = new GjkEpaPenetrationDepthSolver();

			//#define  USE_SUBSIMPLEX_CONVEX_CAST 1
			//if you reenable USE_SUBSIMPLEX_CONVEX_CAST see commented ref code below
#if USE_SUBSIMPLEX_CONVEX_CAST
	        SubsimplexConvexCast convexCaster = new SubsimplexConvexCast(m_convexShape, triangleShape, simplexSolver);
#else
			//btGjkConvexCast	convexCaster(m_convexShape,&triangleShape,&simplexSolver);
			ContinuousConvexCollision convexCaster = new ContinuousConvexCollision(m_convexShape,triangleShape,simplexSolver,gjkEpaPenetrationSolver);
#endif //#USE_SUBSIMPLEX_CONVEX_CAST
	
			CastResult castResult = new CastResult();
			castResult.m_fraction = 1f;
			if (convexCaster.CalcTimeOfImpact(ref m_convexShapeFrom,ref m_convexShapeTo,ref m_triangleToWorld, ref m_triangleToWorld, castResult))
			{
				//add hit
				if (castResult.m_normal.LengthSquared() > 0.0001f)
				{					
					if (castResult.m_fraction < m_hitFraction)
					{
						/* btContinuousConvexCast's normal is already in world space */
						/*
                        #ifdef USE_SUBSIMPLEX_CONVEX_CAST
				                        //rotate normal into worldspace
				                        castResult.m_normal = m_convexShapeFrom.getBasis() * castResult.m_normal;
                        #endif //USE_SUBSIMPLEX_CONVEX_CAST
                        */
						castResult.m_normal.Normalize();

						ReportHit (ref castResult.m_normal,ref castResult.m_hitPoint,castResult.m_fraction,partId,triangleIndex);
					}
				}
			}
		}
		public void ProcessTriangle(ObjectArray<Vector3> triangle, int partId, int triangleIndex)
		{
			//do a swept sphere for now
			Matrix ident = Matrix.Identity;
			CastResult castResult = new CastResult();
			castResult.m_fraction = m_hitFraction;
			SphereShape	pointShape = new SphereShape(m_ccdSphereRadius);
			TriangleShape triShape = new TriangleShape(triangle[0],triangle[1],triangle[2]);
			VoronoiSimplexSolver	simplexSolver = new VoronoiSimplexSolver();
			SubSimplexConvexCast convexCaster = new SubSimplexConvexCast(pointShape,triShape,simplexSolver);
			//GjkConvexCast	convexCaster(&pointShape,convexShape,&simplexSolver);
			//ContinuousConvexCollision convexCaster(&pointShape,convexShape,&simplexSolver,0);
			//local space?

			if (convexCaster.CalcTimeOfImpact(ref m_ccdSphereFromTrans,ref m_ccdSphereToTrans,
			                                  ref ident,ref ident,castResult))
			{
				if (m_hitFraction > castResult.m_fraction)
				{
					m_hitFraction = castResult.m_fraction;
				}
			}

		}
	    public override float CalculateTimeOfImpact(CollisionObject body0,CollisionObject body1,DispatcherInfo dispatchInfo,ManifoldResult resultOut)
        {
	        ///Rather then checking ALL pairs, only calculate TOI when motion exceeds threshold

	        ///Linear motion for one of objects needs to exceed m_ccdSquareMotionThreshold
	        ///body0.m_worldTransform,
	        float resultFraction = 1.0f;


	        float squareMot0 = (body0.GetInterpolationWorldTransform().Translation - body0.GetWorldTransform().Translation).LengthSquared();
	        float squareMot1 = (body1.GetInterpolationWorldTransform().Translation - body1.GetWorldTransform().Translation).LengthSquared();

	        if (squareMot0 < body0.GetCcdSquareMotionThreshold() &&
		        squareMot1 < body1.GetCcdSquareMotionThreshold())
            {
		        return resultFraction;
            }

	        //An adhoc way of testing the Continuous Collision Detection algorithms
	        //One object is approximated as a sphere, to simplify things
	        //Starting in penetration should report no time of impact
	        //For proper CCD, better accuracy and handling of 'allowed' penetration should be added
	        //also the mainloop of the physics should have a kind of toi queue (something like Brian Mirtich's application of Timewarp for Rigidbodies)


	        /// Convex0 against sphere for Convex1
	        {
		        ConvexShape convex0 = (ConvexShape)(body0.GetCollisionShape());

		        SphereShape	sphere1 = new SphereShape(body1.GetCcdSweptSphereRadius()); //todo: allow non-zero sphere sizes, for better approximation
		        CastResult result = new CastResult();
		        VoronoiSimplexSolver voronoiSimplex = new VoronoiSimplexSolver();
		        //SubsimplexConvexCast ccd0(&sphere,min0,&voronoiSimplex);
		        ///Simplification, one object is simplified as a sphere
		        GjkConvexCast ccd1 = new GjkConvexCast( convex0 ,sphere1,voronoiSimplex);
		        //ContinuousConvexCollision ccd(min0,min1,&voronoiSimplex,0);
		        if (ccd1.CalcTimeOfImpact(body0.GetWorldTransform(),body0.GetInterpolationWorldTransform(),
			        body1.GetWorldTransform(),body1.GetInterpolationWorldTransform(),result))
		        {

			        //store result.m_fraction in both bodies

			        if (body0.GetHitFraction()> result.m_fraction)
                    {
				        body0.SetHitFraction( result.m_fraction );
                    }

			        if (body1.GetHitFraction() > result.m_fraction)
                    {
				        body1.SetHitFraction( result.m_fraction);
                    }

			        if (resultFraction > result.m_fraction)
                    {
				        resultFraction = result.m_fraction;
                    }

		        }
	        }

	        /// Sphere (for convex0) against Convex1
	        {
		        ConvexShape convex1 = (ConvexShape)(body1.GetCollisionShape());

		        SphereShape	sphere0 = new SphereShape(body0.GetCcdSweptSphereRadius()); //todo: allow non-zero sphere sizes, for better approximation
		        CastResult result = new CastResult();
		        VoronoiSimplexSolver voronoiSimplex = new VoronoiSimplexSolver();
		        //SubsimplexConvexCast ccd0(&sphere,min0,&voronoiSimplex);
		        ///Simplification, one object is simplified as a sphere
		        GjkConvexCast ccd1 = new GjkConvexCast(sphere0,convex1,voronoiSimplex);
		        //ContinuousConvexCollision ccd(min0,min1,&voronoiSimplex,0);
		        if (ccd1.CalcTimeOfImpact(body0.GetWorldTransform(),body0.GetInterpolationWorldTransform(),
			        body1.GetWorldTransform(),body1.GetInterpolationWorldTransform(),result))
		        {

			        //store result.m_fraction in both bodies

			        if (body0.GetHitFraction()	> result.m_fraction)
                    {
				        body0.SetHitFraction( result.m_fraction);
                    }

			        if (body1.GetHitFraction() > result.m_fraction)
                    {
				        body1.SetHitFraction( result.m_fraction);
                    }

			        if (resultFraction > result.m_fraction)
                    {
				        resultFraction = result.m_fraction;
                    }

		        }
	        }

	        return resultFraction;
        }
Example #4
0
    /// objectQuerySingle performs a collision detection query and calls the resultCallback. It is used internally by rayTest.
    public static void	ObjectQuerySingle(ConvexShape castShape,ref Matrix convexFromTrans,ref Matrix convexToTrans,
					  CollisionObject collisionObject,CollisionShape collisionShape,
					  ref Matrix colObjWorldTransform,
					  ConvexResultCallback resultCallback, float allowedPenetration)
    {
	    if (collisionShape.IsConvex())
	    {
		    //BT_PROFILE("convexSweepConvex");
		    CastResult castResult = new CastResult();
		    castResult.m_allowedPenetration = allowedPenetration;
		    castResult.m_fraction = resultCallback.m_closestHitFraction;//float(1.);//??

		    ConvexShape convexShape = (ConvexShape) collisionShape;
		    VoronoiSimplexSolver simplexSolver = new VoronoiSimplexSolver();
		    GjkEpaPenetrationDepthSolver gjkEpaPenetrationSolver = new GjkEpaPenetrationDepthSolver();
    		
		    ContinuousConvexCollision convexCaster1 = new ContinuousConvexCollision(castShape,convexShape,simplexSolver, gjkEpaPenetrationSolver);
		    //btGjkConvexCast convexCaster2(castShape,convexShape,&simplexSolver);
		    //btSubsimplexConvexCast convexCaster3(castShape,convexShape,&simplexSolver);

		    IConvexCast castPtr = convexCaster1;
		
		    if (castPtr.CalcTimeOfImpact(ref convexFromTrans,ref convexToTrans,ref colObjWorldTransform,ref colObjWorldTransform,castResult))
		    {
			    //add hit
			    if (castResult.m_normal.LengthSquared() > 0.0001f)
			    {
				    if (castResult.m_fraction < resultCallback.m_closestHitFraction)
				    {
					    castResult.m_normal.Normalize();
					    LocalConvexResult localConvexResult = new LocalConvexResult
								    (
									    collisionObject,
									    null,
									    ref castResult.m_normal,
									    ref castResult.m_hitPoint,
									    castResult.m_fraction
								    );

					    bool normalInWorldSpace = true;
					    resultCallback.AddSingleResult(localConvexResult, normalInWorldSpace);

				    }
			    }
		    }
	    } 
        else 
        {
		    if (collisionShape.IsConcave())
		    {
			    if (collisionShape.ShapeType==BroadphaseNativeTypes.TRIANGLE_MESH_SHAPE_PROXYTYPE)
			    {
				    //BT_PROFILE("convexSweepbtBvhTriangleMesh");
				    BvhTriangleMeshShape triangleMesh = (BvhTriangleMeshShape)collisionShape;
				    Matrix worldTocollisionObject = Matrix.Invert(colObjWorldTransform);
				    Vector3 convexFromLocal = Vector3.Transform(convexFromTrans.Translation,worldTocollisionObject);
				    Vector3  convexToLocal = Vector3.Transform(convexToTrans.Translation,worldTocollisionObject);
				    // rotation of box in local mesh space = MeshRotation^-1 * ConvexToRotation

				    Matrix rotationXform = MathUtil.BasisMatrix(ref worldTocollisionObject) *  MathUtil.BasisMatrix(ref convexToTrans);

				    BridgeTriangleConvexcastCallback tccb = new BridgeTriangleConvexcastCallback(castShape, ref convexFromTrans,ref convexToTrans,resultCallback,collisionObject,triangleMesh, ref colObjWorldTransform);
				    tccb.m_hitFraction = resultCallback.m_closestHitFraction;
				    Vector3 boxMinLocal = new Vector3();
                    Vector3 boxMaxLocal = new Vector3();
				    castShape.GetAabb(ref rotationXform, ref boxMinLocal, ref boxMaxLocal);
				    triangleMesh.PerformConvexCast(tccb,ref convexFromLocal,ref convexToLocal,ref boxMinLocal, ref boxMaxLocal);
			    } 
                else
			    {
				    //BT_PROFILE("convexSweepConcave");
				    ConcaveShape concaveShape = (ConcaveShape)collisionShape;
				    Matrix worldTocollisionObject = Matrix.Invert(colObjWorldTransform);
				    Vector3 convexFromLocal = Vector3.Transform(convexFromTrans.Translation,worldTocollisionObject);
				    Vector3 convexToLocal = Vector3.Transform(convexToTrans.Translation,worldTocollisionObject);
				    // rotation of box in local mesh space = MeshRotation^-1 * ConvexToRotation
                    Matrix rotationXform = MathUtil.BasisMatrix(ref worldTocollisionObject) * MathUtil.BasisMatrix(ref convexToTrans);

                    BridgeTriangleConvexcastCallback2 tccb = new BridgeTriangleConvexcastCallback2(castShape, ref convexFromTrans, ref convexToTrans, resultCallback, collisionObject, concaveShape, ref colObjWorldTransform);
				    tccb.m_hitFraction = resultCallback.m_closestHitFraction;
				    Vector3 boxMinLocal = new Vector3();
                    Vector3 boxMaxLocal = new Vector3();
				    castShape.GetAabb(ref rotationXform, ref boxMinLocal, ref boxMaxLocal);

				    Vector3  rayAabbMinLocal = convexFromLocal;
                    MathUtil.VectorMin(ref convexToLocal,ref rayAabbMinLocal);
                    //rayAabbMinLocal.setMin(convexToLocal);
				    Vector3  rayAabbMaxLocal = convexFromLocal;
                    //rayAabbMaxLocal.setMax(convexToLocal);
                    MathUtil.VectorMax(ref convexToLocal,ref rayAabbMaxLocal);

				    rayAabbMinLocal += boxMinLocal;
				    rayAabbMaxLocal += boxMaxLocal;
				    concaveShape.ProcessAllTriangles(tccb,ref rayAabbMinLocal,ref rayAabbMaxLocal);
			    }
            } 
            else 
            {
			    ///@todo : use AABB tree or other BVH acceleration structure!
			    if (collisionShape.IsCompound())
			    {
                    //BT_PROFILE("convexSweepCompound");
                    CompoundShape compoundShape = (CompoundShape)collisionShape;
				    for (int i=0;i<compoundShape.GetNumChildShapes();i++)
				    {
					    Matrix childTrans = compoundShape.GetChildTransform(i);
					    CollisionShape childCollisionShape = compoundShape.GetChildShape(i);
					    Matrix childWorldTrans = MathUtil.BulletMatrixMultiply(colObjWorldTransform,childTrans);
					    // replace collision shape so that callback can determine the triangle
					    CollisionShape saveCollisionShape = collisionObject.GetCollisionShape();
					    collisionObject.InternalSetTemporaryCollisionShape((CollisionShape)childCollisionShape);

                        LocalInfoAdder my_cb = new LocalInfoAdder(i, resultCallback);
					    my_cb.m_closestHitFraction = resultCallback.m_closestHitFraction;


					    ObjectQuerySingle(castShape, ref convexFromTrans,ref convexToTrans,
						    collisionObject,
						    childCollisionShape,
						    ref childWorldTrans,
						    my_cb, allowedPenetration);
					    // restore
					    collisionObject.InternalSetTemporaryCollisionShape(saveCollisionShape);
				    }
			    }
		    }
	    }
    }
Example #5
0
    public virtual void	RayTestSingle(ref Matrix rayFromTrans,ref Matrix rayToTrans,
					  CollisionObject collisionObject,
					  CollisionShape collisionShape,
					  ref Matrix colObjWorldTransform,
					  RayResultCallback resultCallback)
    {
	    SphereShape pointShape = new SphereShape(0.0f);
	    pointShape.Margin = 0f;
	    ConvexShape castShape = pointShape;

	    if (collisionShape.IsConvex())
	    {
    //		BT_PROFILE("rayTestConvex");
		    CastResult castResult = new CastResult();
		    castResult.m_fraction = resultCallback.m_closestHitFraction;

		    ConvexShape convexShape = (ConvexShape)collisionShape;
            VoronoiSimplexSolver simplexSolver = new VoronoiSimplexSolver();
    //#define USE_SUBSIMPLEX_CONVEX_CAST 1
    //#ifdef USE_SUBSIMPLEX_CONVEX_CAST
            
            // FIXME - MAN - convexcat here seems to make big difference to forklift.
            SubSimplexConvexCast convexCaster = new SubSimplexConvexCast(castShape, convexShape, simplexSolver);

            //GjkConvexCast convexCaster = new GjkConvexCast(castShape, convexShape, simplexSolver);


    //#else
		    //btGjkConvexCast	convexCaster(castShape,convexShape,&simplexSolver);
		    //btContinuousConvexCollision convexCaster(castShape,convexShape,&simplexSolver,0);
    //#endif //#USE_SUBSIMPLEX_CONVEX_CAST

		    if (convexCaster.CalcTimeOfImpact(ref rayFromTrans,ref rayToTrans,ref colObjWorldTransform,ref colObjWorldTransform,castResult))
		    {
			    //add hit
			    if (castResult.m_normal.LengthSquared() > 0.0001f)
			    {
				    if (castResult.m_fraction < resultCallback.m_closestHitFraction)
				    {

                        //if (resultCallback.m_closestHitFraction != 1f)
                        //{
                        //    int ibreak = 0;
                        //    convexCaster.calcTimeOfImpact(ref rayFromTrans, ref rayToTrans, ref colObjWorldTransform, ref colObjWorldTransform, castResult);
                        //}

    //#ifdef USE_SUBSIMPLEX_CONVEX_CAST
					    //rotate normal into worldspace
					    castResult.m_normal = Vector3.TransformNormal(castResult.m_normal,rayFromTrans);
    //#endif //USE_SUBSIMPLEX_CONVEX_CAST

					    castResult.m_normal.Normalize();
					    LocalRayResult localRayResult = new LocalRayResult(
							    collisionObject,
							    null,
							    ref castResult.m_normal,
							    castResult.m_fraction
						    );

					    bool normalInWorldSpace = true;
					    resultCallback.AddSingleResult(localRayResult, normalInWorldSpace);

				    }
			    }
		    }
            castResult.Cleanup();
	    } 
        else 
        {
		    if (collisionShape.IsConcave())
		    {
    //			BT_PROFILE("rayTestConcave");
		    	if (collisionShape.ShapeType==BroadphaseNativeTypes.TRIANGLE_MESH_SHAPE_PROXYTYPE && collisionShape is BvhTriangleMeshShape)
	    		{
				    ///optimized version for btBvhTriangleMeshShape
					BvhTriangleMeshShape triangleMesh = (BvhTriangleMeshShape)collisionShape;
				    Matrix worldTocollisionObject = Matrix.Invert(colObjWorldTransform);
				    Vector3 rayFromLocal = Vector3.Transform(rayFromTrans.Translation,worldTocollisionObject);
				    Vector3 rayToLocal = Vector3.Transform(rayToTrans.Translation,worldTocollisionObject);

                    Matrix transform = Matrix.Identity;
				    BridgeTriangleRaycastCallback rcb = new BridgeTriangleRaycastCallback(ref rayFromLocal,ref rayToLocal, resultCallback,collisionObject,triangleMesh,ref transform);
				    rcb.m_hitFraction = resultCallback.m_closestHitFraction;
				    triangleMesh.PerformRaycast(rcb,ref rayFromLocal,ref rayToLocal);
                    rcb.Cleanup();
			    } 
                else
			    {
				    //generic (slower) case
				    ConcaveShape concaveShape = (ConcaveShape)collisionShape;

				    Matrix worldTocollisionObject = Matrix.Invert(colObjWorldTransform);

				    Vector3 rayFromLocal = Vector3.Transform(rayFromTrans.Translation,worldTocollisionObject);
				    Vector3 rayToLocal = Vector3.Transform(rayToTrans.Translation,worldTocollisionObject);

				    //ConvexCast::CastResult
                    Matrix transform = Matrix.Identity;
                    BridgeTriangleConcaveRaycastCallback rcb = new BridgeTriangleConcaveRaycastCallback(ref rayFromLocal, ref rayToLocal, resultCallback, collisionObject, concaveShape,ref transform);
				    rcb.m_hitFraction = resultCallback.m_closestHitFraction;

				    Vector3 rayAabbMinLocal = rayFromLocal;
				    MathUtil.VectorMin(ref rayToLocal,ref rayAabbMinLocal);
				    Vector3 rayAabbMaxLocal = rayFromLocal;
                    MathUtil.VectorMax(ref rayToLocal,ref rayAabbMaxLocal);

				    concaveShape.ProcessAllTriangles(rcb,ref rayAabbMinLocal,ref rayAabbMaxLocal);
                    rcb.Cleanup();
			    }
		    } 
            else 
            {
                // BT_PROFILE("rayTestCompound");
			    ///@todo: use AABB tree or other BVH acceleration structure, see btDbvt
			    if (collisionShape.IsCompound())
			    {
				    CompoundShape compoundShape = (CompoundShape)(collisionShape);
				    int i=0;
				    for (i=0;i<compoundShape.GetNumChildShapes();i++)
				    {
					    Matrix childTrans = compoundShape.GetChildTransform(i);
					    CollisionShape childCollisionShape = compoundShape.GetChildShape(i);
					    Matrix childWorldTrans = MathUtil.BulletMatrixMultiply(colObjWorldTransform,childTrans) ;
					    // replace collision shape so that callback can determine the triangle
					    CollisionShape saveCollisionShape = collisionObject.GetCollisionShape();
					    collisionObject.InternalSetTemporaryCollisionShape((CollisionShape)childCollisionShape);

                        LocalInfoAdder2 my_cb = new LocalInfoAdder2(i, resultCallback);
					    my_cb.m_closestHitFraction = resultCallback.m_closestHitFraction;
					
					    RayTestSingle(ref rayFromTrans,ref rayToTrans,
						    collisionObject,
						    childCollisionShape,
						    ref childWorldTrans,
						    my_cb);
					    // restore
					    collisionObject.InternalSetTemporaryCollisionShape(saveCollisionShape);
                        my_cb.cleanup();
				    }
			    }
		    }
	    }
    }
	public DefaultCollisionConfiguration(DefaultCollisionConstructionInfo constructionInfo)
    {
    	m_simplexSolver = new VoronoiSimplexSolver();
        m_pdSolver = new GjkEpaPenetrationDepthSolver();
        //m_pdSolver = new MinkowskiPenetrationDepthSolver();
        m_useEpaPenetrationAlgorithm = true;
//#define USE_EPA 1
//#ifdef USE_EPA
//    mem = btAlignedAlloc(sizeof(btGjkEpaPenetrationDepthSolver),16);
//    m_pdSolver = new (mem)btGjkEpaPenetrationDepthSolver;
//#else
//    mem = btAlignedAlloc(sizeof(btMinkowskiPenetrationDepthSolver),16);
//    m_pdSolver = new (mem)btMinkowskiPenetrationDepthSolver;
//#endif//USE_EPA	
	

	    //default CreationFunctions, filling the m_doubleDispatch table
	    m_convexConvexCreateFunc = new ConvexConvexCreateFunc(m_simplexSolver,m_pdSolver);
	    m_convexConcaveCreateFunc = new ConvexConcaveCreateFunc();
	    m_swappedConvexConcaveCreateFunc = new SwappedConvexConcaveCreateFunc();
	    m_compoundCreateFunc = new CompoundCreateFunc();
	    m_swappedCompoundCreateFunc = new SwappedCompoundCreateFunc();
	    m_emptyCreateFunc = new EmptyCreateFunc();
	
    	m_sphereSphereCF = new SphereSphereCreateFunc();
//#ifdef USE_BUGGY_SPHERE_BOX_ALGORITHM
//    mem = btAlignedAlloc(sizeof(btSphereBoxCollisionAlgorithm::CreateFunc),16);
//    m_sphereBoxCF = new(mem) btSphereBoxCollisionAlgorithm::CreateFunc;
//    mem = btAlignedAlloc(sizeof(btSphereBoxCollisionAlgorithm::CreateFunc),16);
//    m_boxSphereCF = new (mem)btSphereBoxCollisionAlgorithm::CreateFunc;
//    m_boxSphereCF->m_swapped = true;
//#endif //USE_BUGGY_SPHERE_BOX_ALGORITHM

	    m_sphereTriangleCF = new SphereTriangleCreateFunc();
	    m_triangleSphereCF = new SphereTriangleCreateFunc();
	    m_triangleSphereCF.m_swapped = true;
    	
	    m_boxBoxCF = new BoxBoxCreateFunc();

	    //convex versus plane
	    m_convexPlaneCF = new ConvexPlaneCreateFunc();
	    m_planeConvexCF = new ConvexPlaneCreateFunc();
	    m_planeConvexCF.m_swapped = true;
    	
	    ///calculate maximum element size, big enough to fit any collision algorithm in the memory pool
        //int maxSize = sizeof(btConvexConvexAlgorithm);
        //int maxSize2 = sizeof(btConvexConcaveCollisionAlgorithm);
        //int maxSize3 = sizeof(btCompoundCollisionAlgorithm);
        //int sl = sizeof(btConvexSeparatingDistanceUtil);
        //sl = sizeof(btGjkPairDetector);
        //int	collisionAlgorithmMaxElementSize = btMax(maxSize,maxSize2);
        //collisionAlgorithmMaxElementSize = btMax(collisionAlgorithmMaxElementSize,maxSize3);

        //if (constructionInfo.m_stackAlloc)
        //{
        //    m_ownsStackAllocator = false;
        //    this->m_stackAlloc = constructionInfo.m_stackAlloc;
        //} else
        //{
        //    m_ownsStackAllocator = true;
        //    void* mem = btAlignedAlloc(sizeof(btStackAlloc),16);
        //    m_stackAlloc = new(mem)btStackAlloc(constructionInfo.m_defaultStackAllocatorSize);
        //}
    		
        //if (constructionInfo.m_persistentManifoldPool)
        //{
        //    m_ownsPersistentManifoldPool = false;
        //    m_persistentManifoldPool = constructionInfo.m_persistentManifoldPool;
        //} else
        //{
        //    m_ownsPersistentManifoldPool = true;
        //    void* mem = btAlignedAlloc(sizeof(btPoolAllocator),16);
        //    m_persistentManifoldPool = new (mem) btPoolAllocator(sizeof(btPersistentManifold),constructionInfo.m_defaultMaxPersistentManifoldPoolSize);
        //}
    	
        //if (constructionInfo.m_collisionAlgorithmPool)
        //{
        //    m_ownsCollisionAlgorithmPool = false;
        //    m_collisionAlgorithmPool = constructionInfo.m_collisionAlgorithmPool;
        //} else
        //{
        //    m_ownsCollisionAlgorithmPool = true;
        //    void* mem = btAlignedAlloc(sizeof(btPoolAllocator),16);
        //    m_collisionAlgorithmPool = new(mem) btPoolAllocator(collisionAlgorithmMaxElementSize,constructionInfo.m_defaultMaxCollisionAlgorithmPoolSize);
        //}
    }