/// <summary>
/// GetPartition() takes a connected graph (in the form of a dataset or lightweight graph),
/// and returns a partitioning of the graph created from applying the resilience measure.
/// The minimum number of clusters in the partitioning is given by the instance variable _minK.
/// </summary>
/// <returns>A partition of the instance graph</returns>
public Partition GetPartition()
{
DistanceMatrix mat = null;
if (_data.Type == AbstractDataset.DataType.DistanceMatrix)
{
mat = (DistanceMatrix)_data;
}
else if (_data.Type == AbstractDataset.DataType.PointSet)
{
mat = ((PointSet)_data).GetDistanceMatrix();
}
//Setup our partition with a single cluster, with all points
List <Cluster> clusterList = new List <Cluster> {
new Cluster(0, Enumerable.Range(0, _data.Count).ToList())
};
Partition partition = new Partition(clusterList, _data);
//Dictionary to hold VAT
var vatMap = new Dictionary <int, Scattering>();
//Dictionary to hold subset array
var subsetMap = new Dictionary <int, int[]>();
while (clusterList.Count < _minK)
{
//Calculate the VAT for all values
foreach (var c in partition.Clusters.Where(c => !vatMap.ContainsKey(c.ClusterId)))
{
//We must calculate a graph for this subset of data
List <int> clusterSubset = c.Points.Select(p => p.Id).ToList();
//Now calculate Vat
LightWeightGraph lwg;
if (_data.Type == AbstractDataset.DataType.Graph)
{
bool[] exclusion = new bool[_data.Count];
for (int i = 0; i < _data.Count; i++)
{
exclusion[i] = true;
}
foreach (var p in c.Points)
{
exclusion[p.Id] = false;
}
lwg = new LightWeightGraph((LightWeightGraph)_data, exclusion);
}
else //Distance matrix or Pointset
{
Debug.Assert(mat != null, "mat != null");
var subMatrix = mat.GetReducedDataSet(clusterSubset);
//Generate our graph
lwg = _graphGen.GenerateGraph(subMatrix.Mat);
}
subsetMap.Add(c.ClusterId, clusterSubset.ToArray());
lwg.IsWeighted = _weighted;
Scattering v = new Scattering(lwg, _reassignNodes, _alpha, _beta);
_vatNodeRemovalOrder = v.NodeRemovalOrder;
_vatNumNodesRemoved = v.NumNodesRemoved;
if (_hillClimb)
{
v.HillClimb();
}
////VATClust v = new VATClust(subMatrix.Mat, _weighted, _useKnn, _kNNOffset, _alpha, _beta);
vatMap.Add(c.ClusterId, v);
}
meta.AppendLine("All calculated Scatterings:");
//Now find the minimum vat value
int minVatCluster = 0;
double minVatValue = double.MaxValue;
foreach (var c in vatMap)
{
meta.Append(String.Format("{0} ", c.Value.MinVat));
if (c.Value.MinVat < minVatValue)
{
minVatCluster = c.Key;
minVatValue = c.Value.MinVat;
}
}
meta.AppendLine();
//now merge the partition into the cluster
var minVAT = vatMap[minVatCluster];
var subPartition = minVAT.GetPartition();
var nodeIndexMap = subsetMap[minVatCluster];
meta.AppendFormat("Scattering: MinScattering={0}\r\n", minVAT.MinVat);
meta.AppendFormat("Removed Count:{0} \r\n", minVAT.NumNodesRemoved);
meta.AppendLine(String.Join(",",
minVAT.NodeRemovalOrder.GetRange(0, minVAT.NumNodesRemoved).Select(c => nodeIndexMap[c])));
partition.MergeSubPartition(subPartition, nodeIndexMap, minVatCluster);
vatMap.Remove(minVatCluster);
subsetMap.Remove(minVatCluster);
}
partition.MetaData = meta.ToString();
return(partition);
}
public override void Inject(Scattering scattering, ComputeShader compute, Matrix4x4 viewProj)
{
if (HasShadow)
{
if (GetShadowMapResolution() != m_shadowMap.width)
{
DestroyImmediate(m_shadowMap);
CreateShadowTex();
}
}
//TODO: This doesn't really need to run every frame
UpdateCommandBuffer();
//Setup basic params
Vector4 posRange = transform.position;
posRange.w = 1.0f / (m_light.range * m_light.range);
compute.SetVector("_LightPosRange", posRange);
Vector4 lightStrength = m_light.color * m_light.intensity * FogScatterIntensity;
lightStrength *= 10;
compute.SetVector("_LightColor", lightStrength);
//Per light type things
switch (LightType)
{
case LightType.Directional:
int dirKernel;
if (HasShadow)
{
if (QualitySettings.shadowCascades > 1)
{
dirKernel = scattering.LightDirKernel.GetKernel(ScatterKernel.EShadowMode.Cascaded);
}
else
{
dirKernel = scattering.LightDirKernel.GetKernel(ScatterKernel.EShadowMode.Shadowed);
}
}
else
{
dirKernel = scattering.LightDirKernel.GetKernel(ScatterKernel.EShadowMode.None);
}
compute.SetVector("_LightPosRange", m_light.transform.forward);
if (HasShadow)
{
compute.SetBuffer(dirKernel, "_MatrixBuf", MatrixBuffer);
compute.SetTexture(dirKernel, "_ShadowMapTexture", m_shadowMap);
}
else
{
compute.SetTexture(dirKernel, "_ShadowMapTexture", Texture2D.whiteTexture);
}
scattering.SetLightAccum(dirKernel, false);
Profiler.BeginSample("Dir Light pass");
var tex = scattering.GetDensityTex();
compute.DispatchScaled(dirKernel, tex.width, tex.height, tex.volumeDepth);
Profiler.EndSample();
break;
case LightType.Point:
scattering.SetLightAccum(scattering.LightPointKernel, false);
scattering.InjectObject(viewProj, scattering.LightPointKernel, this);
break;
case LightType.Spot:
int spotKernel =
scattering.LightSpotKernel.GetKernel(HasShadow ? ScatterKernel.EShadowMode.Shadowed : ScatterKernel.EShadowMode.None);
if (HasShadow)
{
Matrix4x4 v = transform.worldToLocalMatrix;
Matrix4x4 p =
GL.GetGPUProjectionMatrix(Matrix4x4.Perspective(m_light.spotAngle, 1.0f,
m_light.shadowNearPlane,
m_light.range), true);
//For some reason z is flipped :(
p *= Matrix4x4.Scale(new Vector3(1.0f, 1.0f, -1.0f));
compute.SetMatrix("_SpotShadowMatrix", p * v);
compute.SetTexture(spotKernel, "_SpotShadow", m_shadowMap);
}
var lightProjMatrix = Matrix4x4.identity;
float d = Mathf.Deg2Rad * m_light.spotAngle * 0.5f;
d = Mathf.Cos(d) / Mathf.Sin(d);
lightProjMatrix[3, 2] = 2f / d;
lightProjMatrix[3, 3] = SpotBaseSize;
var mat = lightProjMatrix * transform.worldToLocalMatrix;
compute.SetMatrix("_SpotMatrix", mat);
if (m_light.cookie != null)
{
compute.SetTexture(spotKernel, "_SpotCookie", m_light.cookie);
}
else
{
compute.SetTexture(spotKernel, "_SpotCookie", scattering.SpotCookie);
}
scattering.SetLightAccum(spotKernel, false);
scattering.InjectObject(viewProj, spotKernel, this);
break;
}
}
public abstract void Inject(Scattering scat, ComputeShader comp, Matrix4x4 viewProj);
