protected byte calculateOpacity(Voxel[,,] original, uint x, uint y, uint z, float strength) {
double opacity = original[x, y, z].averageOpacity();
int minX = Mathf.Max((int)x - blurRadius, 0);
int maxX = Mathf.Min((int)x + blurRadius, original.GetLength(0));
int minY = Mathf.Max((int)y - blurRadius, 0);
int maxY = Mathf.Min((int)y + blurRadius, original.GetLength(1));
int minZ = Mathf.Max((int)z - blurRadius, 0);
int maxZ = Mathf.Min((int)z + blurRadius, original.GetLength(2));
int count = 0;
for (int xi = minX; xi < maxX; ++xi) {
for (int yi = minY; yi < maxY; ++yi) {
for (int zi = minZ; zi < maxZ; ++zi) {
++count;
Vector3 diff = new Vector3(x - xi, y - yi, z - zi);
float dis = diff.magnitude;
Voxel value = original[xi, yi, zi];
if (dis < 0.5f || value == null)
continue;
float factor = Mathf.Max((1 - dis / blurRadius) * strength * 0.1f, 0);
opacity = opacity * (1 - factor) + value.averageOpacity() * factor;
}
}
}
return (byte)Mathf.Min((float)opacity, byte.MaxValue);
}
/*
* MUST BE CALLED BEFORE polygonize!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
*/
public static void setup(float voxelSize, byte isolevel, ref Dictionary<int, object> vertices, ref Dictionary<int, byte> materials, ref Voxel[, ,] voxels, Vector3 offset, Vector3[] meshVerts) {
MarchingCubes.isolevel = isolevel;
MarchingCubes.vertices = vertices;
MarchingCubes.materials = materials;
MarchingCubes.voxels = voxels;
MarchingCubes.voxelSize = voxelSize;
MarchingCubes.offset = offset;
MarchingCubes.meshVerts = meshVerts;
}
public override Voxel mutate(LocalApplication app, Index p, LocalAction action, Voxel original) {
CubeAction cAction = (CubeAction)action;
byte newOpacity = (byte)((original.averageOpacity() * (1 - cAction.percentInside) + value.averageOpacity() * (cAction.percentInside)));
byte newSubstance = original.averageMaterialType();
if (overwriteSubstance && cAction.percentInside > 0.5)
newSubstance = value.averageMaterialType();
if (!overwriteShape)
newOpacity = original.averageOpacity();
return new Voxel(newSubstance, newOpacity);
}
protected override Voxel mutate(Application app, Index pos, Action action, Voxel original) {
BlurApp bApp = (BlurApp)app;
BlurAction bAction = (BlurAction)action;
float dis = Mathf.Sqrt(bAction.disSqr);
float actualStrength = strength * (1 - (dis / bApp.radius));
if (actualStrength <= 0)
return original;
byte newOpacity = calculateOpacity(bApp.original, pos.x - app.min.x, pos.y - app.min.y, pos.z - app.min.z, actualStrength);
return new Voxel(original.averageMaterialType(), newOpacity);
}
public CubeModifier(VoxelTree control, Vector3 worldPosition, Vector3 worldDimensions, VoxelHolder value, bool updateMesh)
: base(control, updateMesh)
{
this.value = value.toVoxel();
Vector3 dimensions = worldDimensions / control.voxelSize();
min = control.transform.InverseTransformPoint(worldPosition) / control.voxelSize() - dimensions /2 -Vector3.one *0.5f;
max = min + dimensions;
setMinMax(min, max);
// apply();
}
public override Voxel mutate(LocalApplication app, Index p, LocalAction action, Voxel original) {
SphereApp sApp = (SphereApp)app;
SphereAction sAction = (SphereAction)action;
float dis = Mathf.Sqrt(sAction.disSqr);
float percentInside = Mathf.Min((sAction.maxRadius -dis) /(sAction.maxRadius -sAction.minRadius), 1);
byte newOpacity = (byte)(original.averageOpacity() * (1 -percentInside) + value.averageOpacity() * percentInside);
byte newSubstance = original.averageMaterialType();
if (overwriteSubstance && (dis < sApp.radius || percentInside > 0.5f))
newSubstance = value.averageMaterialType();
if (!overwriteShape)
newOpacity = original.averageOpacity();
return new Voxel(newSubstance, newOpacity);
}
public override int cleanArtifacts(out Voxel simplified, VoxelHolder head, byte level, byte maxLevel, int x, int y, int z)
{
simplified = null;
if (level < maxLevel)
return 0;
Voxel[,,] array = new Voxel[3, 3, 3];
head.putInArray(ref array, new Index(level), (uint)x -1, (uint)y -1, (uint)z -1, (uint)x +2, (uint)y +2, (uint)z +2);
bool solid = isSolid();
foreach(Voxel vox in array) {
if (vox != null && vox.isSolid() != solid)
return 0;
}
simplified = solid? full : empty;
return 1;
}
public override void putInArray(byte level, ref Voxel[,,] array, int x, int y, int z, int xMin, int yMin, int zMin, int xMax, int yMax, int zMax) {
int size = 1 << (VoxelBlock.CHILD_COUNT_POWER *level);
int xStart = Mathf.Max(x, xMin);
int xEnd = Mathf.Min(x +size, xMax);
int yStart = Mathf.Max(y, yMin);
int yEnd = Mathf.Min(y +size, yMax);
int zStart = Mathf.Max(z, zMin);
int zEnd = Mathf.Min(z +size, zMax);
for(int xi=xStart; xi<xEnd; ++xi) {
for(int yi=yStart; yi<yEnd; ++yi) {
for(int zi=zStart; zi<zEnd; ++zi) {
array[xi -xMin, yi -yMin, zi -zMin] = this;
}
}
}
}
public override Voxel mutate(LocalApplication app, Index p, LocalAction action, Voxel original)
{
SphereApp sApp = (SphereApp)app;
SphereAction sAction = (SphereAction)action;
float dis = Mathf.Sqrt(sAction.disSqr);
byte newOpacity = (dis <= sAction.minRadius) ?
value.averageOpacity() :
(byte)((original.averageOpacity() * (dis - sAction.minRadius) + value.averageOpacity() * (sAction.maxRadius - dis)) / 2);
byte newSubstance = original.averageMaterialType();
if (newOpacity >= 2 * original.averageOpacity() ||
(overwriteSubstance && dis < sApp.radius))
newSubstance = value.averageMaterialType();
if (!overwriteShape)
newOpacity = original.averageOpacity();
return new Voxel(newSubstance, newOpacity);
}
public void set(byte detailLevel, int x, int y, int z, Voxel value, Tree control) {
if (detailLevel > 0) {
short factor = (short)(1 << (detailLevel - CHILD_COUNT_POWER));
byte xi = (byte)(x / factor);
byte yi = (byte)(y / factor);
byte zi = (byte)(z / factor);
if (detailLevel == CHILD_COUNT_POWER) {
children[xi, yi, zi] = value;
} else {
if (children[xi, yi, zi].GetType() == typeof(Voxel)) {
if (children[xi, yi, zi].Equals(value)) { ++skippedSubdivisions; return; }
children[xi, yi, zi] = new VoxelBlock((Voxel)children[xi, yi, zi]);
}
((VoxelBlock)children[xi, yi, zi]).set((byte)(detailLevel - CHILD_COUNT_POWER), x - xi * factor, y - yi * factor, z - zi * factor, value, control);
}
} else
set(value);
}
public override Voxel mutate(LocalApplication app, Index p, LocalAction action, Voxel original)
{
return child.mutate(((LineApplication)app).childApp, p, action, original);
}
public override int canSimplify(out Voxel simplification)
{
bool canSimplify = true;
int count = 0;
simplification = null;
for (int xi = 0; xi<CHILD_DIMENSION; ++xi) {
for (int yi = 0; yi<CHILD_DIMENSION; ++yi) {
for (int zi = 0; zi<CHILD_DIMENSION; ++zi) {
Voxel child = null;
count += children[xi, yi, zi].canSimplify(out child);
if (child != null) {
children[xi, yi, zi] = child;
if (simplification == null)
simplification = child;
else
canSimplify = simplification == child && canSimplify;
} else {
canSimplify = false;
}
}
}
}
if (canSimplify)
++count;
else
simplification = null;
return count;
}
public void setToHeightmap(byte detailLevel, int x, int y, int z, ref float[,] map, byte[,] mats, OcTree control)
{
if (detailLevel <= CHILD_COUNT_POWER) {
for (int xi = 0; xi < CHILD_DIMENSION; ++xi) {
for (int zi = 0; zi < CHILD_DIMENSION; ++zi) {
for (int yi = 0; yi < CHILD_DIMENSION; ++yi) {
if (yi + y >= map[x + xi, z + zi])
break;
else if (yi + y >= map[x + xi, z + zi] - 1) {
if (mats[x + xi, z + zi] == byte.MaxValue)
children[xi, yi, zi] = Voxel.empty;
else
children[xi, yi, zi] = new Voxel(mats[x + xi, z + zi], (byte)((map[x + xi, z + zi] - yi - y) * byte.MaxValue));
} else {
if (mats[x + xi, z + zi] == byte.MaxValue)
children[xi, yi, zi] = Voxel.empty;
else
children[xi, yi, zi] = new Voxel(mats[x + xi, z + zi], byte.MaxValue);
}
}
}
}
} else {
int multiplier = (1 << (detailLevel - CHILD_COUNT_POWER));
for (int xi = 0; xi < CHILD_DIMENSION; ++xi) {
for (int zi = 0; zi < CHILD_DIMENSION; ++zi) {
int xMax = x + (xi + 1) * multiplier;
int zMax = z + (zi + 1) * multiplier;
float yMin = float.MaxValue;
float yMax = 0;
bool multipleMaterials = false;
byte material = mats[x, z];
for (int xPos = x + xi * multiplier; xPos < xMax; ++xPos) {
for (int zPos = z + zi * multiplier; zPos < zMax; ++zPos) {
if (map[xPos, zPos] < yMin) yMin = map[xPos, zPos];
if (map[xPos, zPos] > yMax) yMax = map[xPos, zPos];
if (mats[xPos, zPos] != material) multipleMaterials = true;
}
}
if (multipleMaterials) yMin = 0;
int firstUnsolidBlock = Mathf.Min(((int)(yMin - y)) / multiplier, CHILD_DIMENSION);
int lastUnsolidBlock = Mathf.Min(((int)(yMax - y)) / multiplier, CHILD_DIMENSION - 1);
int yi = 0;
for (; yi < firstUnsolidBlock; ++yi) {
if (mats[x + xi * multiplier, z + zi * multiplier] == byte.MaxValue)
children[xi, yi, zi] = Voxel.empty;
else
children[xi, yi, zi] = new Voxel(mats[x + xi * multiplier, z + zi * multiplier], byte.MaxValue);
}
if (lastUnsolidBlock < 0) continue;
for (; yi <= lastUnsolidBlock; ++yi) {
VoxelBlock newChild = new VoxelBlock();
newChild.setToHeightmap((byte)(detailLevel - CHILD_COUNT_POWER), x + xi * multiplier, y + yi * multiplier, z + zi * multiplier, ref map, mats, control);
children[xi, yi, zi] = newChild;
}
}
}
}
control.dirty = true;
}
public VoxelBlock(Voxel fillValue)
{
children = new VoxelHolder[CHILD_DIMENSION, CHILD_DIMENSION, CHILD_DIMENSION];
++blockCount;
set(fillValue);
}
public void setToHeightmap(byte detailLevel, int x, int y, int z, ref float[,] map, byte material, OcTree control)
{
if (detailLevel <= CHILD_COUNT_POWER) {
for (int xi = 0; xi < CHILD_DIMENSION; ++xi) {
for (int zi = 0; zi < CHILD_DIMENSION; ++zi) {
for (int yi = 0; yi < CHILD_DIMENSION; ++yi) {
if (yi + y >= map[x + xi, z + zi])
break;
else if (material == byte.MaxValue) {
children[xi, yi, zi] = Voxel.empty;
} else {
if (yi + y >= map[x + xi, z + zi] - 1) {
byte opacity = (byte)((map[x + xi, z + zi] - yi - y) * byte.MaxValue);
if (opacity > control.isoLevel || children[xi, yi, zi].averageOpacity() <= opacity)
children[xi, yi, zi] = new Voxel(material, opacity);
} else {
children[xi, yi, zi] = new Voxel(material, byte.MaxValue);
}
}
}
}
}
} else {
int multiplier = (1 << (detailLevel - CHILD_COUNT_POWER));
for (int xi = 0; xi < CHILD_DIMENSION; ++xi) {
for (int zi = 0; zi < CHILD_DIMENSION; ++zi) {
int xMax = x + (xi + 1) * multiplier;
int zMax = z + (zi + 1) * multiplier;
float yMin = float.MaxValue;
float yMax = 0;
for (int xPos = x + xi * multiplier; xPos < xMax; ++xPos) {
for (int zPos = z + zi * multiplier; zPos < zMax; ++zPos) {
if (map[xPos, zPos] < yMin) yMin = map[xPos, zPos];
if (map[xPos, zPos] > yMax) yMax = map[xPos, zPos];
}
}
int firstUnsolidBlock = Mathf.Min(((int)(yMin - y)) / multiplier, CHILD_DIMENSION);
int lastUnsolidBlock = Mathf.Min(((int)(yMax - y)) / multiplier, CHILD_DIMENSION - 1);
int yi = 0;
for (; yi < firstUnsolidBlock; ++yi) {
if (material == byte.MaxValue)
children[xi, yi, zi] = Voxel.empty;
else
children[xi, yi, zi] = new Voxel(material, byte.MaxValue);
}
if (lastUnsolidBlock < 0) continue;
for (; yi <= lastUnsolidBlock; ++yi) {
if (children[xi, yi, zi].GetType() == typeof(Voxel))
children[xi, yi, zi] = new VoxelBlock((Voxel)children[xi, yi, zi]);
((VoxelBlock)children[xi, yi, zi]).setToHeightmap((byte)(detailLevel - CHILD_COUNT_POWER), x + xi * multiplier, y + yi * multiplier, z + zi * multiplier, ref map, material, control);
}
}
}
}
control.dirty = true;
}
public void addEdge(VoxelUpdateInfo info, byte x, byte y, byte z)
{
if (vertices == null) return;
bool recalculate = false;
Voxel[, ,] voxels = new Voxel[VERTEX_DIMENSION, VERTEX_DIMENSION, VERTEX_DIMENSION];
if (x == 0/* && xExtend == 0*/) {
recalculate = true;
xExtend = 1;
for (byte yi = (byte)(1 - yExtend); yi < yDim; ++yi) {
for (byte zi = (byte)(1 - zExtend); zi < zDim; ++zi) {
voxels[0, yi, zi] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - xExtend, VOXEL_DIMENSION - 1 + yi, VOXEL_DIMENSION - 1 + zi).toVoxel();
voxels[1, yi, zi] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION, VOXEL_DIMENSION - 1 + yi, VOXEL_DIMENSION - 1 + zi).toVoxel();
}
}
} else if (x == 2/* && xDim < VERTEX_DIMENSION*/) {
recalculate = true;
xDim = VERTEX_DIMENSION;
for (byte yi = (byte)(1 - yExtend); yi < yDim; ++yi) {
for (byte zi = (byte)(1 - zExtend); zi < zDim; ++zi) {
voxels[VOXEL_DIMENSION + 1, yi, zi] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION * 2, VOXEL_DIMENSION - 1 + yi, VOXEL_DIMENSION - 1 + zi).toVoxel();
voxels[VOXEL_DIMENSION, yi, zi] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION * 2 - 1, VOXEL_DIMENSION - 1 + yi, VOXEL_DIMENSION - 1 + zi).toVoxel();
}
}
} else if (y == 0/* && yExtend == 0*/) {
recalculate = true;
yExtend = 1;
for (byte xi = (byte)(1 - xExtend); xi < xDim; ++xi) {
for (byte zi = (byte)(1 - zExtend); zi < zDim; ++zi) {
voxels[xi, 0, zi] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - 1 + xi, VOXEL_DIMENSION - yExtend, VOXEL_DIMENSION - 1 + zi).toVoxel();
voxels[xi, 1, zi] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - 1 + xi, VOXEL_DIMENSION, VOXEL_DIMENSION - 1 + zi).toVoxel();
}
}
} else if (y == 2/* && yDim < VERTEX_DIMENSION*/) {
recalculate = true;
yDim = VERTEX_DIMENSION;
for (byte xi = (byte)(1 - xExtend); xi < xDim; ++xi) {
for (byte zi = (byte)(1 - zExtend); zi < zDim; ++zi) {
voxels[xi, VOXEL_DIMENSION + 1, zi] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - 1 + xi, VOXEL_DIMENSION * 2, VOXEL_DIMENSION - 1 + zi).toVoxel();
voxels[xi, VOXEL_DIMENSION, zi] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - 1 + xi, VOXEL_DIMENSION * 2 - 1, VOXEL_DIMENSION - 1 + zi).toVoxel();
}
}
} else if (z == 0/* && zExtend == 0*/) {
recalculate = true;
zExtend = 1;
for (byte xi = (byte)(1 - xExtend); xi < xDim; ++xi) {
for (byte yi = (byte)(1 - yExtend); yi < yDim; ++yi) {
voxels[xi, yi, 0] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - 1 + xi, VOXEL_DIMENSION - 1 + yi, VOXEL_DIMENSION - zExtend).toVoxel();
voxels[xi, yi, 1] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - 1 + xi, VOXEL_DIMENSION - 1 + yi, VOXEL_DIMENSION).toVoxel();
}
}
} else if (z == 2/* && zDim < VERTEX_DIMENSION*/) {
recalculate = true;
zDim = VERTEX_DIMENSION;
for (byte xi = (byte)(1 - xExtend); xi < xDim; ++xi) {
for (byte yi = (byte)(1 - yExtend); yi < yDim; ++yi) {
voxels[xi, yi, VOXEL_DIMENSION + 1] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - 1 + xi, VOXEL_DIMENSION - 1 + yi, VOXEL_DIMENSION * 2).toVoxel();
voxels[xi, yi, VOXEL_DIMENSION] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - 1 + xi, VOXEL_DIMENSION - 1 + yi, VOXEL_DIMENSION * 2 - 1).toVoxel();
}
}
}
if (recalculate) {
Queue<int[]> triangleSet = new Queue<int[]>();
MarchingCubes.setup(info.size / VOXEL_DIMENSION, control.isoLevel, ref vertices, ref vertexSubstances, ref voxels, position - new Vector3(0.5f, 0.5f, 0.5f) * size / VOXEL_DIMENSION, VERTS);
byte xStart = (byte)(1 - xExtend + (VOXEL_DIMENSION + xExtend - 1) * (x / 2));
byte xEnd = (byte)(2 + (xDim - 2) * ((x + 1) / 2));
byte yStart = (byte)(1 - yExtend + (VOXEL_DIMENSION + yExtend - 1) * (y / 2));
byte yEnd = (byte)(2 + (yDim - 2) * ((y + 1) / 2));
byte zStart = (byte)(1 - zExtend + (VOXEL_DIMENSION + zExtend - 1) * (z / 2));
byte zEnd = (byte)(2 + (zDim - 2) * ((z + 1) / 2));
for (byte xi = xStart, x1 = (byte)(xi + 1); x1 < xEnd; xi = x1++) {
for (byte yi = yStart, y1 = (byte)(yi + 1); y1 < yEnd; yi = y1++) {
for (byte zi = zStart, z1 = (byte)(zi + 1); z1 < zEnd; zi = z1++) {
int[] tris = MarchingCubes.lookupTriangles(xi, yi, zi, x1, y1, z1);
if (tris == null) continue;
triangleSet.Enqueue(tris);
}
}
}
if (vertices.Count < 1) {
return;
}
List<int> newTriangles = new List<int>(TRIS);
List<Vector3> newVertices = new List<Vector3>(VERTS);
List<Vector3> newNorms = new List<Vector3>(NORMS);
int tri = 0;
while (triangleSet.Count > 0) {
int[] triangleList = triangleSet.Dequeue();
for (int i = 0; i < triangleList.Length; ++i) {
if (vertices[triangleList[i]].GetType() == typeof(Vector3)) {
newVertices.Add((Vector3)vertices[triangleList[i]]);
newNorms.Add(Vector3.zero);
vertices[triangleList[i]] = newVertices.Count - 1;
}
newTriangles.Add((int)vertices[triangleList[i]]);
}
tri += triangleList.Length;
}
Vector3[] finalNorms = new Vector3[newNorms.Count];
Array.Copy(NORMS, finalNorms, NORMS.Length);
int oldNormCount = NORMS.Length;
VERTS = newVertices.ToArray();
TRIS = newTriangles.ToArray();
calcNorms();
Array.Copy(NORMS, oldNormCount, finalNorms, oldNormCount, finalNorms.Length - oldNormCount);
NORMS = finalNorms;
}
alignEdge(info, x, y, z);
control.enqueueMeshApply(new ApplyMeshJob(this, info.detailLevel, info.x, info.y, info.z));
}
public CubeMutator(OcTree control, Vector3 worldPosition, Vector3 worldDimensions, VoxelHolder value, bool updateMesh)
{
this.worldPosition = worldPosition;
this.worldDimensions = worldDimensions;
this.value = value.toVoxel();
}
protected override Voxel mutate(Application app, Index p, Action action, Voxel original) {
return mutate((LocalApplication)app, p, (LocalAction)action, original);
}
public abstract void putInArray(ref Voxel[,,] array, Index position, uint xMin, uint yMin, uint zMin, uint xMax, uint yMax, uint zMax);
public abstract int cleanArtifacts(out Voxel simplified, VoxelHolder head, byte level, byte maxLevel, int x, int y, int z);
public abstract int canSimplify(out Voxel simplification);
/*
Linearly interpolate the position where an isosurface cuts
an edge between two vertices, each with their own scalar value
*/
public static void stretchVertex(int x1, int y1, int z1, int x2, int y2, int z2, Voxel valp1, Voxel valp2, int vox) {
float mu = (isolevel - valp1.opacity) / ((float)(valp2.opacity - valp1.opacity));
//float mu = 0.5f;
Vector3 pos = new Vector3(x1 + mu * (x2 - x1), y1 + mu * (y2 - y1), z1 + mu * (z2 - z1)) * voxelSize + offset;
if (vertices.ContainsKey(vox) && vertices[vox].GetType() == typeof(int))
meshVerts[(int)vertices[vox]] = pos;
else
vertices[vox] = pos;
if (valp1.opacity > valp2.opacity)
materials[vox] = valp1.matType;
else
materials[vox] = valp2.matType;
//vertices[vox] = new Vector3(x1, y1, z1) *voxelSize +offset;
//float mu = (valp1) / ((float)(byte.MaxValue));
//vertices[vox] = new Vector3(x1 + mu * (x2 - x1), y1 + mu * (y2 - y1), z1 + mu * (z2 - z1)) * voxelSize;
}
public override int canSimplify(out Voxel simplification) {
simplification = this;
return 0;
}
public SphereMutator(Vector3 worldPosition, float worldRadius, Voxel value)
{
this.value = value;
this.worldPosition = worldPosition;
this.worldRadius = worldRadius;
}
public abstract Voxel mutate(LocalApplication app, Index p, LocalAction action, Voxel original);
public override int cleanArtifacts(out Voxel simplified, VoxelHolder head, byte level, byte maxLevel, int x, int y, int z)
{
int size = 1 << (CHILD_COUNT_POWER *level -CHILD_COUNT_POWER);
int count = 0;
for (int xi = 0; xi<CHILD_DIMENSION; ++xi) {
for (int yi = 0; yi<CHILD_DIMENSION; ++yi) {
for (int zi = 0; zi<CHILD_DIMENSION; ++zi) {
Voxel newChild = null;
count += children[xi, yi, zi].cleanArtifacts(out newChild, head, (byte)(level +CHILD_COUNT_POWER), maxLevel, x +xi *size, y +yi *size, z +zi *size);
if (newChild != null)
children[xi, yi, zi] = newChild;
}
}
}
simplified = null;
return count;
}
//private static int getX(int index, int dimension) {
// return (y * VERTEX_DIMENSION + z) * VERTEX_DIMENSION + x;
//}
//private static int getY(int index, int dimension) {
// return ((VERTEX_DIMENSION + x) * VERTEX_DIMENSION + z) * VERTEX_DIMENSION + y;
//}
//private static int getZ(int index, int dimension) {
// return ((VERTEX_DIMENSION * 2 + x) * VERTEX_DIMENSION + y) * VERTEX_DIMENSION + z;
//}
//private static int getDimension(int index) {
// return index / (VERTEX_DIMENSION * VERTEX_DIMENSION * VERTEX_DIMENSION);
//}
private Voxel[, ,] createVoxelArray(VoxelUpdateInfo info)
{
setDimensions(info);
Voxel[, ,] voxels = new Voxel[VERTEX_DIMENSION, VERTEX_DIMENSION, VERTEX_DIMENSION];
for (byte y = (byte)(1 - yExtend); y < yDim; ++y) {
for (byte z = (byte)(1 - zExtend); z < zDim; ++z) {
voxels[1 - xExtend, y, z] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - xExtend, VOXEL_DIMENSION - 1 + y, VOXEL_DIMENSION - 1 + z).toVoxel();
}
}
for (byte x = (byte)(2 - xExtend); x < xDim; ++x) {
for (byte z = (byte)(1 - zExtend); z < zDim; ++z) {
voxels[x, 1 - yExtend, z] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - 1 + x, VOXEL_DIMENSION - yExtend, VOXEL_DIMENSION - 1 + z).toVoxel();
}
}
for (byte x = (byte)(2 - xExtend); x < xDim; ++x) {
for (byte y = (byte)(2 - yExtend); y < yDim; ++y) {
voxels[x, y, 1 - zExtend] = info.getSub(VOXEL_COUNT_POWER, VOXEL_DIMENSION - 1 + x, VOXEL_DIMENSION - 1 + y, VOXEL_DIMENSION - zExtend).toVoxel();
}
}
return voxels;
}
public override void putInArray(ref Voxel[,,] array, Index position, uint xMin, uint yMin, uint zMin, uint xMax, uint yMax, uint zMax)
{
uint size = 1u << (CHILD_COUNT_POWER *position.depth -CHILD_COUNT_POWER);
for(uint xi=0; xi<CHILD_DIMENSION; ++xi) {
uint xPos = position.x +xi *size;
if (xPos > xMax || xPos +size < xMin)
continue;
for (uint yi=0; yi<CHILD_DIMENSION; ++yi) {
uint yPos = position.y +yi *size;
if (yPos > yMax || yPos +size < yMin)
continue;
for (uint zi=0; zi<CHILD_DIMENSION; ++zi) {
uint zPos = position.z +zi *size;
if (zPos > zMax || zPos +size < zMin)
continue;
children[xi, yi, zi].putInArray(ref array, new Index((byte)(position.depth -1), xPos, yPos, zPos), xMin, yMin, zMin, xMax, yMax, zMax);
}
}
}
}
public Voxel(Voxel other)
{
this.matType = other.matType;
this.opacity = other.opacity;
}
public void set(Voxel fillValue)
{
for (byte xi = 0; xi < CHILD_DIMENSION; ++xi)
for (byte yi = 0; yi < CHILD_DIMENSION; ++yi)
for (byte zi = 0; zi < CHILD_DIMENSION; ++zi)
children[xi, yi, zi] = fillValue;
}
