private void Update()
{
if (requests.Count > 0)
{
MeshRequest request = requests.OrderBy(x => Vector3.SqrMagnitude(x.chunk.centerPos - Observer.transform.position)).First();
requests.Remove(request);
lock (requests) {
ThreadStart thread = delegate {
request.chunk.March(request.callback);
};
thread.Invoke();
}
}
}
/// <summary>
/// Returns the next logical mesh to generate.
/// </summary>
/// <returns></returns>
public static MeshRequest[] getNextRequests()
{
int size = Math.Min(10, getRequestCount());
MeshRequest[] ret = new MeshRequest[size];
lock (requestArray)
{
for (int i = 0; i < ret.Length; i++)
{
ret[i] = getNextRequest();
}
}
return(ret);
}
/// <summary>
/// Adds a request to generate a mesh
/// </summary>
/// <param name="_node">The node the mesh is for</param>
public static void requestMesh(Node _node)
{
MeshRequest req = new MeshRequest
{
node = _node,
pos = _node.position,
LOD = _node.LOD,
isDone = false,
hasDensities = (_node.densityData != null)
};
if (!req.hasDensities)
{
lock (requestArray[req.LOD + 1])
requestArray[req.LOD + 1].Enqueue(req);
}
else
{
lock (requestArray[0])
requestArray[0].Enqueue(req);
}
}
public static void update()
{
if (setMeshQueue.Count > 0)
{
MeshRequest req = setMeshQueue.Dequeue();
req.node.setMesh(req.meshData);
}
for (int i = 0; i < generatorThreads.Length; i++)
{
MeshRequest req;
while ((req = generatorThreads[i].getFinishedMesh()) != null)
{
chunksFinished++;
if (req.node.disposed == false)
{
req.node.densityData = req.densities;
if (req.meshData.triangleArray.Length > 0)
{
setMeshQueue.Enqueue(req);
}
else
{
req.node.setMesh(req.meshData);
}
}
}
}
#region Save/Load threads
Node node;
while ((node = fileThread.getFinishedLoadRequest()) != null)
{
node.regenerateChunk(); nodesLoaded++;
}
#endregion
}
/// <summary>
/// Adds a request to generate a mesh
/// </summary>
/// <param name="_node">The node the mesh is for</param>
public static void requestMesh(Node _node)
{
MeshRequest req = new MeshRequest
{
node = _node,
pos = _node.position,
LOD = _node.LOD,
isDone = false,
hasDensities = (_node.densityData != null)
};
if (!req.hasDensities)
lock (requestArray[req.LOD + 1])
requestArray[req.LOD + 1].Enqueue(req);
else
lock (requestArray[0])
requestArray[0].Enqueue(req);
}
/// <summary>
/// Returns the next logical mesh to generate.
/// </summary>
/// <returns></returns>
public static MeshRequest[] getNextRequests()
{
int size = Math.Min(10, getRequestCount());
MeshRequest[] ret = new MeshRequest[size];
lock (requestArray)
{
for (int i = 0; i < ret.Length; i++)
{
ret[i] = getNextRequest();
}
}
return ret;
}
/// <summary>
/// Generates the mesh data
/// </summary>
public static void GenerateMeshData(MeshRequest request)
{
MeshData meshData = new MeshData();
request.meshData = meshData;
//Check if the node requesting a generation has been disposed
if (request == null || request.node.disposed)
{
meshData.triangleArray = new Vector3[0];
meshData.indexArray = new int[0][];
meshData.uvArray = new Vector2[0];
meshData.normalArray = new Vector3[0];
request.isDone = true;
return;
}
DensityData densityArray = request.densities;
Vector3[, ,] densityNormals = new Vector3[17, 17, 17];
List<Triangle> triangleList = new List<Triangle>();
List<int> subMeshIDList = new List<int>();
int[] subMeshTriCount = new int[QuixelEngine.materials.Length];
Node node = request.node;
request.meshData = meshData;
//Unoptimized generation
densityNormals = new Vector3[18, 18, 18];
if (!request.hasDensities)
{
for (int x = -1; x < 18; x++)
{
for (int y = -1; y < 18; y++)
{
for (int z = -1; z < 18; z++)
{
VoxelData data = calculateDensity(node, new Vector3I(x, y, z));
densityArray.set(x, y, z, data.density);
densityArray.setMaterial(x, y, z, data.material);
}
}
}
}
for (int x = 0; x < 17; x++)
{
for (int y = 0; y < 17; y++)
{
for (int z = 0; z < 17; z++)
{
densityNormals[x, y, z] = calculateDensityNormal(new Vector3I(x, y, z), densityArray, node.LOD);
}
}
}
for (int x = 0; x < 16; x++)
{
for (int y = 0; y < 16; y++)
{
for (int z = 0; z < 16; z++)
{
generateTriangles(node, new Vector3I(x, y, z), triangleList, subMeshIDList, subMeshTriCount, densityArray, densityNormals);
}
}
}
int ppos = 0;
int li = 0;
try
{
meshData.triangleArray = new Vector3[triangleList.Count * 3];
meshData.indexArray = new int[QuixelEngine.materials.Length][];
for (int i = 0; i < QuixelEngine.materials.Length; i++)
meshData.indexArray[i] = new int[(subMeshTriCount[i] * 3) * 3];
meshData.uvArray = new Vector2[meshData.triangleArray.Length];
meshData.normalArray = new Vector3[meshData.triangleArray.Length];
int count = 0;
int[] indCount = new int[QuixelEngine.materials.Length];
for (int i = 0; i < triangleList.Count; i++)
{
ppos = i;
Triangle triangle = triangleList[i];
meshData.triangleArray[count + 2] = triangle.pointOne;
meshData.triangleArray[count + 1] = triangle.pointTwo;
meshData.triangleArray[count + 0] = triangle.pointThree;
meshData.normalArray[count + 2] = triangle.nOne;
meshData.normalArray[count + 1] = triangle.nTwo;
meshData.normalArray[count + 0] = triangle.nThree;
int ind = subMeshIDList[i];
li = subMeshIDList[i];
meshData.indexArray[ind][indCount[ind] + 0] = count + 0;
meshData.indexArray[ind][indCount[ind] + 1] = count + 1;
meshData.indexArray[ind][indCount[ind] + 2] = count + 2;
meshData.uvArray[count + 0] = new Vector2(meshData.triangleArray[count + 0].x, meshData.triangleArray[count + 0].z);
meshData.uvArray[count + 1] = new Vector2(meshData.triangleArray[count + 1].x, meshData.triangleArray[count + 1].z);
meshData.uvArray[count + 2] = new Vector2(meshData.triangleArray[count + 2].x, meshData.triangleArray[count + 2].z);
count += 3;
indCount[subMeshIDList[i]] += 3;
}
}
catch (Exception e)
{
StreamWriter sw = new StreamWriter("Error Log.txt");
sw.WriteLine(e.Message + "\r\n" + e.StackTrace);
for (int i = 0; i < QuixelEngine.materials.Length; i++)
sw.WriteLine(i + ": " + subMeshTriCount[i]);
sw.WriteLine(ppos);
sw.WriteLine(li);
sw.Close();
}
request.isDone = true;
}
/// <summary>
/// Generates the mesh data
/// </summary>
public static void GenerateMeshData(MeshRequest request)
{
MeshData meshData = new MeshData();
request.meshData = meshData;
//Check if the node requesting a generation has been disposed
if (request == null || request.node.disposed)
{
meshData.triangleArray = new Vector3[0];
meshData.indexArray = new int[0][];
meshData.uvArray = new Vector2[0];
meshData.normalArray = new Vector3[0];
request.isDone = true;
return;
}
DensityData densityArray = request.densities;
Vector3[, ,] densityNormals = new Vector3[17, 17, 17];
List <Triangle> triangleList = new List <Triangle>();
List <int> subMeshIDList = new List <int>();
int[] subMeshTriCount = new int[QuixelEngine.materials.Length];
Node node = request.node;
request.meshData = meshData;
//Unoptimized generation
densityNormals = new Vector3[18, 18, 18];
if (!request.hasDensities)
{
for (int x = -1; x < 18; x++)
{
for (int y = -1; y < 18; y++)
{
for (int z = -1; z < 18; z++)
{
VoxelData data = calculateDensity(node, new Vector3I(x, y, z));
densityArray.set(x, y, z, data.density);
densityArray.setMaterial(x, y, z, data.material);
}
}
}
}
for (int x = 0; x < 17; x++)
{
for (int y = 0; y < 17; y++)
{
for (int z = 0; z < 17; z++)
{
densityNormals[x, y, z] = calculateDensityNormal(new Vector3I(x, y, z), densityArray, node.LOD);
}
}
}
for (int x = 0; x < 16; x++)
{
for (int y = 0; y < 16; y++)
{
for (int z = 0; z < 16; z++)
{
generateTriangles(node, new Vector3I(x, y, z), triangleList, subMeshIDList, subMeshTriCount, densityArray, densityNormals);
}
}
}
int ppos = 0;
int li = 0;
try
{
meshData.triangleArray = new Vector3[triangleList.Count * 3];
meshData.indexArray = new int[QuixelEngine.materials.Length][];
for (int i = 0; i < QuixelEngine.materials.Length; i++)
{
meshData.indexArray[i] = new int[(subMeshTriCount[i] * 3) * 3];
}
meshData.uvArray = new Vector2[meshData.triangleArray.Length];
meshData.normalArray = new Vector3[meshData.triangleArray.Length];
int count = 0;
int[] indCount = new int[QuixelEngine.materials.Length];
for (int i = 0; i < triangleList.Count; i++)
{
ppos = i;
Triangle triangle = triangleList[i];
meshData.triangleArray[count + 2] = triangle.pointOne;
meshData.triangleArray[count + 1] = triangle.pointTwo;
meshData.triangleArray[count + 0] = triangle.pointThree;
meshData.normalArray[count + 2] = triangle.nOne;
meshData.normalArray[count + 1] = triangle.nTwo;
meshData.normalArray[count + 0] = triangle.nThree;
int ind = subMeshIDList[i];
li = subMeshIDList[i];
meshData.indexArray[ind][indCount[ind] + 0] = count + 0;
meshData.indexArray[ind][indCount[ind] + 1] = count + 1;
meshData.indexArray[ind][indCount[ind] + 2] = count + 2;
meshData.uvArray[count + 0] = new Vector2(meshData.triangleArray[count + 0].x, meshData.triangleArray[count + 0].z);
meshData.uvArray[count + 1] = new Vector2(meshData.triangleArray[count + 1].x, meshData.triangleArray[count + 1].z);
meshData.uvArray[count + 2] = new Vector2(meshData.triangleArray[count + 2].x, meshData.triangleArray[count + 2].z);
count += 3;
indCount[subMeshIDList[i]] += 3;
}
}
catch (Exception e)
{
StreamWriter sw = new StreamWriter("Error Log.txt");
sw.WriteLine(e.Message + "\r\n" + e.StackTrace);
for (int i = 0; i < QuixelEngine.materials.Length; i++)
{
sw.WriteLine(i + ": " + subMeshTriCount[i]);
}
sw.WriteLine(ppos);
sw.WriteLine(li);
sw.Close();
}
request.isDone = true;
}
