//----------------------------------
void getPointsIntersectingSphere(List <int> points, float3 sphereCenter, float sphereRadius)
{
List <SpatialQuadTreeCell> nodes = new List <SpatialQuadTreeCell>();
getLeafCellsIntersectingSphere(nodes, sphereCenter, sphereRadius);
if (nodes.Count == 0)
{
return;
}
Vector3 center = sphereCenter.toVec3();
for (int q = 0; q < nodes.Count; q++)
{
FlightHeightRepQuadCell cell = ((FlightHeightRepQuadCell)nodes[q].mExternalData);
Debug.Assert(cell != null);
for (uint i = (uint)cell.mMinXVert; i < (uint)cell.mMinXVert + mNumXVertsPerCell; i++)
{
for (uint j = (uint)cell.mMinZVert; j < (uint)cell.mMinZVert + mNumZVertsPerCell; j++)
{
uint index = (uint)((i) + mWidth * (j));
Vector3 vert = getWorldspacePoint((int)(i), (int)(j)).toVec3();
if (BMathLib.pointSphereIntersect(ref center, sphereRadius, ref vert))
{
points.Add((int)index);
}
}
}
}
}
//----------------------------------
public void render(bool renderCursor)
{
if (!mRenderHeights)
{
return;
}
List <SpatialQuadTreeCell> nodes = new List <SpatialQuadTreeCell>();
getVisibleNodes(nodes, TerrainGlobals.getTerrain().getFrustum());
//update any visual handles that need it..
for (int i = 0; i < nodes.Count; i++)
{
FlightHeightRepQuadCell cell = ((FlightHeightRepQuadCell)nodes[i].mExternalData);
Debug.Assert(cell != null);
if (cell.mVisualHandle == null)
{
cell.mVisualHandle = newVisualHandle((int)cell.mMinXVert, (int)cell.mMinZVert);
}
renderCell(cell.mVisualHandle);
}
if (renderCursor)
{
((BTerrainFlightBrush)TerrainGlobals.getEditor().getCurrentBrush()).render();
}
}
public void recalculateVisuals()
{
for (uint minx = 0; minx < mNumXLeafCells; minx++)
{
for (uint minz = 0; minz < mNumZLeafCells; minz++)
{
SpatialQuadTreeCell spatialCell = getLeafCellAtGridLoc(minx, minz);
FlightHeightRepQuadCell cell = ((FlightHeightRepQuadCell)spatialCell.mExternalData);
updateVisualHandle(ref cell.mVisualHandle, cell.mMinXVert, cell.mMinZVert);
}
}
}
void recalculateCellBB(SpatialQuadTreeCell spatialCell)
{
BBoundingBox bb = new BBoundingBox();
bb.empty();
FlightHeightRepQuadCell cell = ((FlightHeightRepQuadCell)spatialCell.mExternalData);
for (uint i = (uint)cell.mMinXVert; i <= cell.mMinXVert + mNumXVertsPerCell; i++)
{
for (uint j = (uint)cell.mMinZVert; j <= cell.mMinZVert + mNumZVertsPerCell; j++)
{
if (i >= mWidth || j >= mHeight)
{
continue;
}
float3 worldPos = getWorldspacePoint((int)i, (int)j);
bb.addPoint(worldPos.toVec3());
}
}
spatialCell.setBounds(new float3(bb.min), new float3(bb.max));
bb = null;
}
public void updateAfterPainted(int minX, int minZ, int maxX, int maxZ)
{
//verts are in our local stride.
//find any chunks intersecting these numbers and update them.
uint minXCell = (uint)BMathLib.Clamp((minX / mNumXVertsPerCell) - 1, 0, mNumXLeafCells);
uint minZCell = (uint)BMathLib.Clamp((minZ / mNumZVertsPerCell) - 1, 0, mNumXLeafCells);
uint maxXCell = (uint)BMathLib.Clamp((maxX / mNumXVertsPerCell) + 1, 0, mNumXLeafCells);
uint maxZCell = (uint)BMathLib.Clamp((maxZ / mNumZVertsPerCell) + 1, 0, mNumXLeafCells);
for (uint minx = minXCell; minx < maxXCell; minx++)
{
for (uint minz = minZCell; minz < maxZCell; minz++)
{
SpatialQuadTreeCell spatialCell = getLeafCellAtGridLoc(minx, minz);
FlightHeightRepQuadCell cell = ((FlightHeightRepQuadCell)spatialCell.mExternalData);
updateVisualHandle(ref cell.mVisualHandle, cell.mMinXVert, cell.mMinZVert);
recalculateCellBB(spatialCell);
}
}
mRootCell.updateBoundsFromChildren();
}
bool getClosestIntersectionPoint(float3 rayOrig, float3 rayDir, out float3 intPt)
{
intPt = float3.Empty;
List <SpatialQuadTreeCell> nodes = new List <SpatialQuadTreeCell>();
getLeafCellsIntersectingRay(nodes, rayOrig, rayDir);
if (nodes.Count == 0)
{
return(false);
}
//walk through each cell returned, do a per polygon intersection with each one..
Vector3 origin = rayOrig.toVec3();
Vector3 dir = rayDir.toVec3();
Vector3 closestIntersect = Vector3.Empty;
float closestDist = float.MaxValue;
Vector3[] verts = new Vector3[3];
bool hit = false;
for (int q = 0; q < nodes.Count; q++)
{
FlightHeightRepQuadCell cell = ((FlightHeightRepQuadCell)nodes[q].mExternalData);
Debug.Assert(cell != null);
int minx = (int)(cell.mMinXVert);
int minz = (int)(cell.mMinZVert);
for (uint i = 0; i < mNumXVertsPerCell; i++)
{
for (uint j = 0; j < mNumZVertsPerCell; j++)
{
int tileI = (int)(minx + i);
int tileJ = (int)(minz + j);
if (tileI >= mWidth - 1 || tileJ >= mHeight - 1)
{
continue;
}
bool tHit = false;
Vector3 pt = Vector3.Empty;
float[] h = new float[4];
h[0] = getCompositeHeight(tileI, tileJ);
h[1] = getCompositeHeight(tileI, tileJ + 1);
h[2] = getCompositeHeight(tileI + 1, tileJ);
h[3] = getCompositeHeight(tileI + 1, tileJ + 1);
if (h[0] != cJaggedEmptyValue && h[3] != cJaggedEmptyValue && h[1] != cJaggedEmptyValue)
{
verts[0] = new Vector3(tileI * mTileScale, h[0], (tileJ) * mTileScale);
verts[1] = new Vector3((tileI + 1) * mTileScale, h[3], (tileJ + 1) * mTileScale);
verts[2] = new Vector3(tileI * mTileScale, h[1], (tileJ + 1) * mTileScale);
if (BMathLib.raySegmentIntersectionTriangle(verts, ref origin, ref dir, false, ref pt))
{
Vector3 vec = pt - origin;
//ensure this hit point is the closest to the origin
float len = vec.Length();
if (len < closestDist)
{
closestDist = len;
closestIntersect = pt;
}
hit = true;
}
}
if (h[0] != cJaggedEmptyValue && h[3] != cJaggedEmptyValue && h[2] != cJaggedEmptyValue)
{
verts[0] = new Vector3(tileI * mTileScale, h[0], (tileJ) * mTileScale);
verts[1] = new Vector3((tileI + 1) * mTileScale, h[3], (tileJ + 1) * mTileScale);
verts[2] = new Vector3((tileI + 1) * mTileScale, h[2], (tileJ) * mTileScale);
if (BMathLib.raySegmentIntersectionTriangle(verts, ref origin, ref dir, false, ref pt))
{
Vector3 vec = pt - origin;
//ensure this hit point is the closest to the origin
float len = vec.Length();
if (len < closestDist)
{
closestDist = len;
closestIntersect = pt;
}
hit = true;
}
}
}
}
}
intPt.X = closestIntersect.X;
intPt.Y = closestIntersect.Y;
intPt.Z = closestIntersect.Z;
return(hit);
}
