public void VerifySphereTree()
{
if (leafNode)
{
Debug.Assert(CountChildren() == 0, "leaf child count non-zero");
Debug.Assert(containedShape != null, "leaf shape null");
Debug.Assert(Contains(containedShape), "leaf doesn't contain shape");
}
else
{
int count = CountChildren();
if (parent != null) // Don't make the test for the root node
{
Debug.Assert(count > 0, "non-leaf with no children");
}
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child != null)
{
Debug.Assert(Contains(child), "non-leaf doesn't contain child");
Debug.Assert(child.parent == this, "child doesn't point to parent");
if (!child.leafNode && count == 1)
{
Debug.Assert(child.CountChildren() > 1, "this node has only one child, which has only one child");
}
child.VerifySphereTree();
}
}
}
}
// private string lastLoggedContainer = "";
public SphereTreeNode FindSmallestContainer(CollisionShape shape,
SphereTreeNode lastSphere)
{
// if (lastSphere != null) {
// if (lastSphere.Contains(shape))
// return lastSphere.FindSubsphereContainer(shape);
// else {
// // Move up the parent chain
// while (lastSphere != this) {
// lastSphere = lastSphere.parent;
// Debug.Assert(lastSphere != null, "Parent is null!");
// Debug.Assert(!lastSphere.leafNode);
// if (lastSphere.Contains(shape)) {
// if (MO.DoLog)
// MO.Log(" Container {0} for shape {1}", lastSphere, shape);
// return lastSphere;
// }
// }
// Debug.Assert(false, "Didn't find container!");
// }
// }
SphereTreeNode container = root.FindSubsphereContainer(shape);
// if (MO.DoLog) {
// string s = string.Format(" Returning smallest subsphere container {0} for shape {1}",
// container, shape);
// if (lastLoggedContainer != s) {
// lastLoggedContainer = s;
// MO.Log(s);
// }
// }
return(container);
}
// Test all the parts of a moving object to see if they collide with
// any obstacle
public bool CollideAfterAddingDisplacement(MovingObject mo, Vector3 step, CollisionParms parms)
{
for (int i = 0; i < mo.parts.Count; i++)
{
MovingPart movingPart = mo.parts[i];
collisionTimeStamp++;
movingPart.AddDisplacement(step);
SphereTreeNode s = sphereTree.FindSmallestContainer(movingPart.shape, movingPart.sphere);
//MaybeDumpSphereTree();
movingPart.sphere = s;
partCalls++;
if (s.TestSphereCollision(movingPart.shape, collisionTimeStamp, ref collisionTestCount, parms))
{
// We hit something, so back out the displacements
// added to the parts tested so far
for (int j = 0; j <= i; j++)
{
MovingPart displacedPart = mo.parts[j];
displacedPart.AddDisplacement(-step);
//MaybeDumpSphereTree();
}
return(true);
}
}
return(false);
}
private void RecalculateCenterAndRadius()
{
// Don't adjust the root node
if (parent == null)
{
return;
}
bool foundOne = false;
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child != null)
{
if (foundOne)
{
AdjustCenterAndRadius(child);
}
else
{
foundOne = true;
center = child.center;
radius = child.radius;
}
}
}
}
public bool ShapeCollides(CollisionShape shape, CollisionParms parms)
{
collisionTimeStamp++;
SphereTreeNode s = sphereTree.FindSmallestContainer(shape, null);
return(s.TestSphereCollision(shape, collisionTimeStamp, ref collisionTestCount, parms));
}
public SphereTreeNode FindSubsphereContainerInternal(CollisionShape shape)
{
// If more than one child contains shape, return this
int count = 0;
SphereTreeNode container = null;
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child != null && child.Contains(shape))
{
count++;
container = child;
}
}
if (count > 1)
{
return(this);
}
else if (count == 0)
{
return(null);
}
else
{
container = container.FindSubsphereContainer(shape);
SphereTreeNode result = (container == null ? this : container);
return(result);
}
}
private void ReplaceChild(SphereTreeNode currentChild, SphereTreeNode newChild)
{
if (MO.DoLog)
{
if (newChild == null)
{
MO.Log(" Replacing child {0} with null", currentChild);
}
else
{
MO.Log(" Replacing child {0} with child {1}", currentChild, newChild);
}
}
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child == currentChild)
{
children[i] = newChild;
if (newChild != null)
{
newChild.parent = this;
}
currentChild.parent = null;
return;
}
}
Debug.Assert(false, "Didn't find child");
}
// Test for collision with any object in this sphere
public void FindIntersectingShapes(CollisionShape part,
List <CollisionShape> shapes,
ulong timeStamp,
ref int collisionTestCount,
CollisionParms parms)
{
if (containedShape != null)
{
collisionTestCount++;
parms.swapped = false;
if (Primitives.TestCollisionFunctions[(int)part.ShapeType(),
(int)containedShape.ShapeType()]
(part, containedShape, parms))
{
shapes.Add(containedShape);
}
else
{
containedShape.timeStamp = timeStamp;
}
}
// Iterate over the shapes in this sphere and not wholly
// contained in a subsphere
foreach (CollisionShape obstacle in intersectingShapes)
{
if (obstacle.timeStamp == timeStamp)
{
continue;
}
collisionTestCount++;
parms.swapped = false;
if (Primitives.TestCollisionFunctions[(int)part.ShapeType(), (int)obstacle.ShapeType()]
(part, obstacle, parms))
{
shapes.Add(obstacle);
}
else
{
obstacle.timeStamp = timeStamp;
}
}
// Now iterate over subspheres
for (int i = 0; i < SphereTreeNode.childCount; i++)
{
SphereTreeNode cs = children[i];
if (cs == null)
{
continue;
}
// Skip any sphere that doesn't overlap the part in question
if (!cs.SphereOverlap(part))
{
continue;
}
cs.FindIntersectingShapes(part, shapes, timeStamp, ref collisionTestCount, parms);
}
}
public void Initialize()
{
root = new SphereTreeNode(this);
nodeCount = 1;
shapesAdded = 0;
shapesRemoved = 0;
intersectingShapeCount = 0;
}
public MovingPart(CollisionAPI api, CollisionShape shape)
{
this.shape = shape;
this.api = api;
constantShape = shape;
id = api.SphereTree.GetId();
renderedNodes = null;
RenderedNode.MaybeCreateRenderedNodes(false, shape, id, ref renderedNodes);
sphere = null;
}
private SphereTreeNode FindFirstChild()
{
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child != null)
{
return(child);
}
}
Debug.Assert(false, "Didn't find child!");
return(null);
}
// This constructor for the top node
public SphereTreeNode(Vector3 center, float radius, SphereTree sphereTree)
: base(center, radius)
{
this.sphereTree = sphereTree;
parent = null;
children = new SphereTreeNode[childCount];
containedShape = null;
intersectingShapes = new List <CollisionShape>();
leafNode = false;
sphereTree.idCounter++;
id = sphereTree.idCounter;
sphereTree.nodeCount++;
}
public void Transform(Vector3 scale, Quaternion rotate, Vector3 translate)
{
// TODO: This is a temporary solution, and terribly inefficient.
// I need to update the transforms on the node properly, without
// the remove/add.
RenderedNode.RemoveNodeRendering(id, ref renderedNodes);
shape = constantShape.Clone();
shape.Transform(scale, rotate, translate);
id = api.SphereTree.GetId();
renderedNodes = null;
RenderedNode.MaybeCreateRenderedNodes(false, shape, id, ref renderedNodes);
sphere = null;
}
public void AddCollisionShape(CollisionShape shape)
{
// Called with this equal to the root of the tree
shapesAdded++;
SphereTreeNode s = new SphereTreeNode(shape, this);
if (MO.DoLog)
MO.Log("Adding shape {0} to leaf {1}", shape, s);
root.InsertSphereTreeNode(s);
root.AddToIntersectingShapes(shape);
Debug.Assert(shapesAdded - shapesRemoved <= nodeCount,
"shapesAdded - shapesRemoved > nodeCount!");
MaybeVerifyOrDump();
}
public void DumpSphereTreeInternal(StreamWriter writer, int level)
{
DoIndentation(writer, level);
writer.Write(ToString() + "\n");
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child != null)
{
child.DumpSphereTreeInternal(writer, level + 1);
}
}
}
public SphereTreeNode FindSubsphereContainer(CollisionShape shape)
{
SphereTreeNode container = FindSubsphereContainerInternal(shape);
if (container == null)
{
return(sphereTree.root);
}
else
{
return(container);
}
}
private int CountChildren()
{
int count = 0;
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child != null)
{
count++;
}
}
return(count);
}
// Create a SphereTreeNode leaf node
public SphereTreeNode(CollisionShape shape, SphereTree sphereTree)
: base(shape.center, shape.radius)
{
this.sphereTree = sphereTree;
this.containedShape = shape;
parent = null;
children = new SphereTreeNode[childCount];
intersectingShapes = new List <CollisionShape>();
leafNode = true;
sphereTree.idCounter++;
id = sphereTree.idCounter;
sphereTree.nodeCount++;
RenderedNode.MaybeCreateRenderedNodes(true, shape, id, ref renderedNodes);
}
public void AddCollisionShape(CollisionShape shape)
{
// Called with this equal to the root of the tree
shapesAdded++;
SphereTreeNode s = new SphereTreeNode(shape, this);
if (MO.DoLog)
{
MO.Log("Adding shape {0} to leaf {1}", shape, s);
}
root.InsertSphereTreeNode(s);
root.AddToIntersectingShapes(shape);
Debug.Assert(shapesAdded - shapesRemoved <= nodeCount,
"shapesAdded - shapesRemoved > nodeCount!");
MaybeVerifyOrDump();
}
private void AddToChildIntersectingShapes(CollisionShape shape)
{
if (shape == containedShape)
{
return;
}
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child != null && child.SphereOverlap(shape))
{
child.AddIntersectingShape(shape);
child.AddToChildIntersectingShapes(shape);
}
}
}
public void InsertSphereTreeNode(SphereTreeNode s)
{
Debug.Assert(s.leafNode);
if (leafNode)
{
CombineLeafNodes(s);
parent.RecalculateCenterAndRadius();
return;
}
SphereTreeNode child = null;
for (int i = 0; i < childCount; i++)
{
child = children[i];
if (child != null && child.Contains(s))
{
child.InsertSphereTreeNode(s);
RecalculateCenterAndRadius();
return;
}
}
// Not contained in any child, so create it here
bool inserted = false;
for (int i = 0; i < childCount; i++)
{
if (children[i] == null)
{
s.parent = this;
children[i] = s;
inserted = true;
if (MO.DoLog)
{
MO.Log(" Inserted sphere {0} in parent {1}", s, this);
}
break;
}
}
if (!inserted)
{
child = FindChildToDemote(s);
}
RecalculateCenterAndRadius();
}
private void AddChild(SphereTreeNode s)
{
for (int i = 0; i < childCount; i++)
{
if (children[i] == null)
{
if (MO.DoLog)
{
MO.Log(" Adding child {0} to parent {1}", s, this);
}
children[i] = s;
s.parent = this;
return;
}
}
Debug.Assert(false, "No free slot to add child");
}
public void GetCollisionShapesWithHandleInternal(long handle, List <CollisionShape> shapes)
{
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child != null)
{
if (child.leafNode && child.containedShape.handle == handle)
{
shapes.Add(child.containedShape);
}
else if (!child.leafNode)
{
child.GetCollisionShapesWithHandleInternal(handle, shapes);
}
}
}
}
public void ChangeRendering(bool render)
{
if (leafNode)
{
RenderedNode.ChangeRendering(render, containedShape, id, ref renderedNodes);
}
else
{
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child != null)
{
child.ChangeRendering(render);
}
}
}
}
private void AdjustCenterAndRadius(SphereTreeNode s)
{
// Don't adjust the root node
if (parent == null)
{
return;
}
if (radius == 0)
{
center = s.center;
radius = s.radius;
return;
}
// Adjust the center and radius of this sphere do it
// encompasses s
Vector3 diff = (s.center - center);
float sqDist = diff.Dot(diff);
float rDiff = s.radius - radius;
if (rDiff * rDiff >= sqDist)
{
// One is contained in the other
if (s.radius >= radius)
{
center = s.center;
radius = s.radius;
}
}
else
{
float dist = (float)Math.Sqrt(sqDist);
float oldRadius = radius;
radius = (dist + radius + s.radius) * 0.5f;
if (dist > Primitives.epsilon)
{
center += ((radius - oldRadius) / dist) * diff;
}
}
}
public CollisionShape FindClosestCollision(CollisionShape cap, Vector3 start, Vector3 end,
ref Vector3 intersection)
{
collisionTimeStamp++;
SphereTreeNode s = sphereTree.FindSmallestContainer(cap, null);
CollisionParms parms = new CollisionParms();
parms.genNormals = false;
List <CollisionShape> shapes = new List <CollisionShape>();
s.FindIntersectingShapes(cap, shapes, collisionTimeStamp, ref collisionTestCount, parms);
intersection = Vector3.Zero;
if (shapes.Count == 0)
{
return(null);
}
else
{
collisionTimeStamp++;
return(FindClosestIntersectingShape(shapes, start, end, ref intersection));
}
}
public void AddToIntersectingShapes(CollisionShape shape)
{
if (shape == containedShape || !SphereOverlap(shape))
{
return;
}
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child != null)
{
if (child.Contains(shape))
{
child.AddToIntersectingShapes(shape);
return;
}
}
}
// Not wholly contained in a child so add it to our list
AddIntersectingShape(shape);
// Add it to any child that overlaps
AddToChildIntersectingShapes(shape);
}
private SphereTreeNode CombineLeafNodes(SphereTreeNode s)
{
// Remember my own parent, and remove me from that parent
if (MO.DoLog)
{
MO.Log(" Combined {0} with {1}", this, s);
}
SphereTreeNode myparent = parent;
Debug.Assert(myparent != null, "parent was null!");
parent.RemoveChild(this);
// Make a new non-leaf node node to hold both
SphereTreeNode n = new SphereTreeNode(center, radius, sphereTree);
myparent.AddChild(n);
n.AddChild(this);
n.AddChild(s);
n.RecalculateCenterAndRadius();
if (MO.DoLog)
{
MO.Log(" Made combined node {0} child of {1}", n, myparent);
}
return(n);
}
// private string lastLoggedContainer = "";
public SphereTreeNode FindSmallestContainer(CollisionShape shape,
SphereTreeNode lastSphere)
{
// if (lastSphere != null) {
// if (lastSphere.Contains(shape))
// return lastSphere.FindSubsphereContainer(shape);
// else {
// // Move up the parent chain
// while (lastSphere != this) {
// lastSphere = lastSphere.parent;
// Debug.Assert(lastSphere != null, "Parent is null!");
// Debug.Assert(!lastSphere.leafNode);
// if (lastSphere.Contains(shape)) {
// if (MO.DoLog)
// MO.Log(" Container {0} for shape {1}", lastSphere, shape);
// return lastSphere;
// }
// }
// Debug.Assert(false, "Didn't find container!");
// }
// }
SphereTreeNode container = root.FindSubsphereContainer(shape);
// if (MO.DoLog) {
// string s = string.Format(" Returning smallest subsphere container {0} for shape {1}",
// container, shape);
// if (lastLoggedContainer != s) {
// lastLoggedContainer = s;
// MO.Log(s);
// }
// }
return container;
}
private void ReplaceChild(SphereTreeNode currentChild, SphereTreeNode newChild)
{
if (MO.DoLog) {
if (newChild == null)
MO.Log(" Replacing child {0} with null", currentChild);
else
MO.Log(" Replacing child {0} with child {1}", currentChild, newChild);
}
for (int i=0; i<childCount; i++) {
SphereTreeNode child = children[i];
if (child == currentChild) {
children[i] = newChild;
if (newChild != null)
newChild.parent = this;
currentChild.parent = null;
return;
}
}
Debug.Assert(false, "Didn't find child");
}
private void RemoveChild(SphereTreeNode s)
{
ReplaceChild(s, null);
}
private SphereTreeNode FindChildToDemote(SphereTreeNode s)
{
if (MO.DoLog)
MO.Log(" Demote this {0} s {1}", this, s);
Debug.Assert(s.leafNode, "s isn't a leaf node");
// All children are occupied, and s is not wholly contained in
// any of them. Combine s with some child, creating a
// subordinate. Choose the child whose center is nearest
// s.center. If the child has a larger radius, insert s in
// the child. If the child has a smaller radius, s becomes
// the child, and the child is inserted in s.
float closest = float.MaxValue;
int closestChild = -1;
for (int i=0; i<childCount; i++) {
SphereTreeNode child = children[i];
Debug.Assert(child != null, "Null child!");
float d = Primitives.DistanceSquared(s.center, child.center);
if (d < closest) {
closest = d;
closestChild = i;
}
}
Debug.Assert (closestChild >= 0, "closestChild not found!");
SphereTreeNode cs = children[closestChild];
if (cs.leafNode) {
if (MO.DoLog)
MO.Log(" Calling CombineLeafNodes to combine {0} with {1}", cs, this);
SphereTreeNode n = cs.CombineLeafNodes(s);
children[closestChild] = n;
return n;
}
else if (cs.ChildSlotsFree() > 0) {
cs.AddChild(s);
cs.RecalculateCenterAndRadius();
return cs;
}
else {
SphereTreeNode n = new SphereTreeNode(sphereTree);
RemoveChild(cs);
AddChild(n);
n.AddChild(cs);
n.AddChild(s);
n.RecalculateCenterAndRadius();
if (MO.DoLog)
MO.Log(" In demote, made new node n {0}", n);
return n;
}
}
public int RemoveCollisionShapesWithHandleInternal(long handle)
{
// The dumb version: iterate over all containment spheres
// looking for obstacles with the given handle, returning true
// if a child changed. (The smarter version would maintain an
// index mapping handles to SphereTreeNodes whose
// containedShape or intersectingShapes have a shape with
// that handle.)
//
// This runs bottom-up, to provide an opportunity to coalesce
// the sphere tree.
// intersectingShapes are easy - - just remove if they have a
// matching handle, since their removal doesn't change the tree
int removeCount = 0;
for (int i = 0; i < intersectingShapes.Count; i++)
{
CollisionShape obstacle = intersectingShapes[i];
if (obstacle.handle == handle)
{
if (MO.DoLog)
{
MO.Log(" Removing intersecting shape {0} of {1}", obstacle, this);
}
intersectingShapes.RemoveAt(i);
i--;
sphereTree.intersectingShapeCount--;
Debug.Assert(sphereTree.intersectingShapeCount >= 0, "intersectingShapeCount < 0!");
}
}
// Now handle the children
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
if (child != null)
{
if (child.leafNode && child.containedShape.handle == handle)
{
if (MO.DoLog)
{
MO.Log(" Removing child leaf {0} of {1}", child, this);
}
children[i] = null;
child.parent = null;
RenderedNode.RemoveNodeRendering(child.id, ref child.renderedNodes);
sphereTree.shapesRemoved++;
sphereTree.nodeCount--;
removeCount++;
}
else if (!child.leafNode)
{
removeCount += child.RemoveCollisionShapesWithHandleInternal(handle);
}
}
}
int count = CountChildren();
if (count == 0 && containedShape == null)
{
// This is now a truly pointless node - - remove from its
// parent. Parent will only be null for the root node
if (parent != null)
{
if (MO.DoLog)
{
MO.Log(" Removing branch with no kids {0} of {1}", this, parent);
}
parent.RemoveChild(this);
sphereTree.nodeCount--;
Debug.Assert(sphereTree.nodeCount > 0, "nodeCount <= 0");
return(removeCount);
}
}
else if (count == 1)
{
if (parent != null)
{
// Make my child the child of my parent
if (MO.DoLog)
{
MO.Log(" Replacing 1-child node {0} in parent {1}", this, parent);
}
parent.ReplaceChild(this, FindFirstChild());
sphereTree.nodeCount--;
Debug.Assert(sphereTree.nodeCount > 0, "nodeCount <= 0");
return(removeCount);
}
}
if (removeCount > 0)
{
RecalculateCenterAndRadius();
}
return(removeCount);
}
public MovingPart(CollisionAPI api, CollisionShape shape)
{
this.shape = shape;
this.api = api;
constantShape = shape;
id = api.SphereTree.GetId();
renderedNodes = null;
RenderedNode.MaybeCreateRenderedNodes(false, shape, id, ref renderedNodes);
sphere = null;
}
private SphereTreeNode FindChildToDemote(SphereTreeNode s)
{
if (MO.DoLog)
{
MO.Log(" Demote this {0} s {1}", this, s);
}
Debug.Assert(s.leafNode, "s isn't a leaf node");
// All children are occupied, and s is not wholly contained in
// any of them. Combine s with some child, creating a
// subordinate. Choose the child whose center is nearest
// s.center. If the child has a larger radius, insert s in
// the child. If the child has a smaller radius, s becomes
// the child, and the child is inserted in s.
float closest = float.MaxValue;
int closestChild = -1;
for (int i = 0; i < childCount; i++)
{
SphereTreeNode child = children[i];
Debug.Assert(child != null, "Null child!");
float d = Primitives.DistanceSquared(s.center, child.center);
if (d < closest)
{
closest = d;
closestChild = i;
}
}
Debug.Assert(closestChild >= 0, "closestChild not found!");
SphereTreeNode cs = children[closestChild];
if (cs.leafNode)
{
if (MO.DoLog)
{
MO.Log(" Calling CombineLeafNodes to combine {0} with {1}", cs, this);
}
SphereTreeNode n = cs.CombineLeafNodes(s);
children[closestChild] = n;
return(n);
}
else if (cs.ChildSlotsFree() > 0)
{
cs.AddChild(s);
cs.RecalculateCenterAndRadius();
return(cs);
}
else
{
SphereTreeNode n = new SphereTreeNode(sphereTree);
RemoveChild(cs);
AddChild(n);
n.AddChild(cs);
n.AddChild(s);
n.RecalculateCenterAndRadius();
if (MO.DoLog)
{
MO.Log(" In demote, made new node n {0}", n);
}
return(n);
}
}
private void AddChild(SphereTreeNode s)
{
for (int i=0; i<childCount; i++) {
if (children[i] == null) {
if (MO.DoLog)
MO.Log(" Adding child {0} to parent {1}", s, this);
children[i] = s;
s.parent = this;
return;
}
}
Debug.Assert(false, "No free slot to add child");
}
public void InsertSphereTreeNode(SphereTreeNode s)
{
Debug.Assert(s.leafNode);
if (leafNode) {
CombineLeafNodes (s);
parent.RecalculateCenterAndRadius();
return;
}
SphereTreeNode child = null;
for (int i=0; i<childCount; i++) {
child = children[i];
if (child != null && child.Contains(s)) {
child.InsertSphereTreeNode(s);
RecalculateCenterAndRadius();
return;
}
}
// Not contained in any child, so create it here
bool inserted = false;
for (int i=0; i<childCount; i++) {
if (children[i] == null) {
s.parent = this;
children[i] = s;
inserted = true;
if (MO.DoLog)
MO.Log(" Inserted sphere {0} in parent {1}", s, this);
break;
}
}
if (!inserted)
child = FindChildToDemote(s);
RecalculateCenterAndRadius();
}
// This constructor for the top node
public SphereTreeNode(Vector3 center, float radius, SphereTree sphereTree)
: base(center, radius)
{
this.sphereTree = sphereTree;
parent = null;
children = new SphereTreeNode[childCount];
containedShape = null;
intersectingShapes = new List<CollisionShape>();
leafNode = false;
sphereTree.idCounter++;
id = sphereTree.idCounter;
sphereTree.nodeCount++;
}
// Create a SphereTreeNode leaf node
public SphereTreeNode(CollisionShape shape, SphereTree sphereTree)
: base(shape.center, shape.radius)
{
this.sphereTree = sphereTree;
this.containedShape = shape;
parent = null;
children = new SphereTreeNode[childCount];
intersectingShapes = new List<CollisionShape>();
leafNode = true;
sphereTree.idCounter++;
id = sphereTree.idCounter;
sphereTree.nodeCount++;
RenderedNode.MaybeCreateRenderedNodes(true, shape, id, ref renderedNodes);
}
public void Initialize()
{
root = new SphereTreeNode(this);
nodeCount = 1;
shapesAdded = 0;
shapesRemoved = 0;
intersectingShapeCount = 0;
}
private void AdjustCenterAndRadius(SphereTreeNode s)
{
// Don't adjust the root node
if (parent == null)
return;
if (radius == 0) {
center = s.center;
radius = s.radius;
return;
}
// Adjust the center and radius of this sphere do it
// encompasses s
Vector3 diff = (s.center - center);
float sqDist = diff.Dot(diff);
float rDiff = s.radius - radius;
if (rDiff * rDiff >= sqDist) {
// One is contained in the other
if (s.radius >= radius) {
center = s.center;
radius = s.radius;
}
}
else {
float dist = (float)Math.Sqrt(sqDist);
float oldRadius = radius;
radius = (dist + radius + s.radius) * 0.5f;
if (dist > Primitives.epsilon)
center += ((radius - oldRadius) / dist) * diff;
}
}
private SphereTreeNode CombineLeafNodes(SphereTreeNode s)
{
// Remember my own parent, and remove me from that parent
if (MO.DoLog)
MO.Log(" Combined {0} with {1}", this, s);
SphereTreeNode myparent = parent;
Debug.Assert(myparent != null, "parent was null!");
parent.RemoveChild(this);
// Make a new non-leaf node node to hold both
SphereTreeNode n = new SphereTreeNode(center, radius, sphereTree);
myparent.AddChild(n);
n.AddChild(this);
n.AddChild(s);
n.RecalculateCenterAndRadius();
if (MO.DoLog)
MO.Log(" Made combined node {0} child of {1}", n, myparent);
return n;
}
public void Transform(Vector3 scale, Quaternion rotate, Vector3 translate)
{
// TODO: This is a temporary solution, and terribly inefficient.
// I need to update the transforms on the node properly, without
// the remove/add.
RenderedNode.RemoveNodeRendering(id, ref renderedNodes);
shape = constantShape.Clone();
shape.Transform(scale, rotate, translate);
id = api.SphereTree.GetId();
renderedNodes = null;
RenderedNode.MaybeCreateRenderedNodes(false, shape, id, ref renderedNodes);
sphere = null;
}
private void RemoveChild(SphereTreeNode s)
{
ReplaceChild(s, null);
}