bool Sphere::IntersectBox( aabb& a_Box )
{
	float dmin = 0;
	vector3 v1 = a_Box.GetPos(), v2 = a_Box.GetPos() + a_Box.GetSize();
	if (m_Centre.x < v1.x) 
	{
		dmin = dmin + (m_Centre.x - v1.x) * (m_Centre.x - v1.x);
	}
	else if (m_Centre.x > v2.x)
	{
		dmin = dmin + (m_Centre.x - v2.x) * (m_Centre.x - v2.x);
	}
	if (m_Centre.y < v1.y)
	{
		dmin = dmin + (m_Centre.y - v1.y) * (m_Centre.y - v1.y);
	}
	else if (m_Centre.y > v2.y)
	{
		dmin = dmin + (m_Centre.y - v2.y) * (m_Centre.y - v2.y);
	}
	if (m_Centre.z < v1.z)
	{
		dmin = dmin + (m_Centre.z - v1.z) * (m_Centre.z - v1.z);
	}
	else if (m_Centre.z > v2.z)
	{
		dmin = dmin + (m_Centre.z - v2.z) * (m_Centre.z - v2.z);
	}
	return (dmin <= m_SqRadius);
}
Esempio n. 2
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bool PlanePrim::IntersectBox( aabb& a_Box )
{
	vector3 v[2];
	v[0] = a_Box.GetPos(), v[1] = a_Box.GetPos() + a_Box.GetSize();
	int side1, side2 = 0, i = 0;
	for ( side1 = 0, side2 = 0, i = 0; i < 8; i++ )
	{
		vector3 p( v[i & 1].x, v[(i >> 1) & 1].y, v[(i >> 2) & 1].z );
		if ((DOT( p, m_Plane.N ) + m_Plane.D) < 0) side1++; else side2++;
	}
	if ((side1 == 0) || (side2 == 0)) return false; else return true;
}
Esempio n. 3
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void KDTree::GetBoxVertex(aabb box, Point3 *Pos)
{
	Point3 start;
	Point3 end;
	for(int i = 0; i< 3; i++)
	{
		start.cell[i] = box.GetPos().cell[i];
		end.cell[i] = box.GetPos().cell[i] + box.GetSize().cell[i];
	}

	Pos[0].set(start);
	Pos[6].set(end);

	Pos[1].set(Point3(end.x,start.y,start.z));
	Pos[2].set(Point3(end.x,start.y,end.z));
	Pos[3].set(Point3(start.x,start.y,end.z));

	Pos[4].set(Point3(start.x,end.y,start.z));
	Pos[5].set(Point3(end.x,end.y,start.z));
	Pos[7].set(Point3(start.x,end.y,end.z));
}
Esempio n. 4
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void KDTree::Optimize(KDTreeNode* R,Side s,aabb AABB)
{
	if(!R) return;
	while(R->Type != LEFT)
	{
		if(s-2*R->m_Axis>=0&&s-2*R->m_Axis<=1)
		{
			if(s%2==0)
				R = R->m_rchild;
			else 
				R = R->m_lchild;

		}

		else if(R->m_Split >=AABB.GetPos().cell[R->m_Axis]+AABB.GetSize().cell[R->m_Axis])
			R = R->m_lchild;

		else if(R->m_Split <= AABB.GetPos().cell[R->m_Axis])
			R = R->m_rchild;

		else
			break;
	}
}
Esempio n. 5
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bool KDTree::findOptimalSplitPositon(TriangleList *list,aabb &box,int depth, real &splitPosition,aabb &frontBox, aabb &backBox)
{
	bool foundOptimalSplit = false;

	//make a list of the split position candidates
	int axis = depth % Dimension;    
	real pos1 = box.GetPos().cell[axis];//the rangle of the axis direction within the box
	real pos2 = box.GetPos().cell[axis] + box.GetSize().cell[axis];

	bool *pright = new bool[list->GetCount()];
	TriangleNode *tempList = list->GetHead();
	SplitList* SList = new SplitList();
	int aidx = 0;
	while(tempList)
	{
		real pos;
		pright[aidx++]= true;
		for(int i=0;i<3;i++)
		{
			pos = tempList->GetVertex(i).cell[axis];
			if((pos >= pos1)&&(pos <= pos2)) SList->InsertSplitPos(pos);
		}
		tempList = tempList->GetNext();
	}

	//determine nlcount / nrcont for each split position
	aabb tempFrontBox = box;
	aabb tempBackBox = box;
	float tempFrontBoxp1 = tempFrontBox.GetPos().cell[axis];
	float tempBackBoxp2 = tempBackBox.GetPos().cell[axis] + tempBackBox.GetSize().cell[axis];
	SplitNode* splist = SList->GetHead();
	while(splist!=NULL)
	{
		tempBackBox.GetPos().cell[axis] = splist->splitpos;
		tempBackBox.GetSize().cell[axis] = pos2 - splist->splitpos;
		tempFrontBox.GetSize().cell[axis] = splist->splitpos - pos1;

		float tempFrontBoxp2 = tempFrontBox.GetPos().cell[axis] + tempFrontBox.GetSize().cell[axis];
		float tempBackBoxp1 = tempBackBox.GetPos().cell[axis];
		tempList = list->GetHead();
		int i = 0;
		while(tempList)
		{
			if(pright[i])
			{
				int position = partitionTriangle(tempList,depth,splist->splitpos);
				switch(position)
				{
				case kdBefore:
					splist->nlcount++;
					pright[i]=false;
					break;
				case kdAfter:
					splist->nrcount++;
					break;
				case kdIntersection:
					splist->nlcount++;
					splist->nrcount++;
					break;
				}
			}else
			{
				splist->nlcount++;
			}
			tempList = tempList->GetNext();
		}
		splist = splist->next;
		i++;
	}
	delete pright;

	float bestPos = 0.0;
	float lowCost = caculateSingleVoxelCost(list->GetCount(),box);
	float bestCost = lowCost;
	splist = SList->GetHead();
	while(splist)
	{
		tempBackBox.GetPos().cell[axis] = splist->splitpos;
		tempBackBox.GetSize().cell[axis] = pos2 - splist->splitpos;
		tempFrontBox.GetSize().cell[axis] = splist->splitpos - pos1;

		real splitcost = cTraversal * lowCost + caculateCost(splist,tempFrontBox,tempBackBox);
		if(splitcost < lowCost)
		{
			foundOptimalSplit = true;
			bestCost = splitcost;
			bestPos = splist->splitpos;
			frontBox = tempFrontBox;
			backBox = tempBackBox;
			
		}
		splist = splist->next;
	}
	splitPosition = bestPos;
	return foundOptimalSplit;
}