b486678290
Library -Artifacts
2.0 KiB
2.0 KiB
Voronoi Node
Description
Generates a Voronoi, or Worley, noise based on input UV. Voronoi noise is generated by calculating distances between a pixel and a lattice of points. By offsetting these points by a pseudo-random number, controlled by input Angle Offset, a cluster of cells can be generated. The scale of these cells, and the resulting noise, is controlled by input Cell Density. The output Cells contains the raw cell data.
Ports
Name | Direction | Type | Binding | Description |
---|---|---|---|---|
UV | Input | Vector 2 | UV | Input UV value |
Angle Offset | Input | Float | None | Offset value for points |
Cell Density | Input | Float | None | Density of cells generated |
Out | Output | Float | None | Output noise value |
Cells | Output | Float | None | Raw cell data |
Generated Code Example
The following example code represents one possible outcome of this node.
inline float2 unity_voronoi_noise_randomVector (float2 UV, float offset)
{
float2x2 m = float2x2(15.27, 47.63, 99.41, 89.98);
UV = frac(sin(mul(UV, m)) * 46839.32);
return float2(sin(UV.y*+offset)*0.5+0.5, cos(UV.x*offset)*0.5+0.5);
}
void Unity_Voronoi_float(float2 UV, float AngleOffset, float CellDensity, out float Out, out float Cells)
{
float2 g = floor(UV * CellDensity);
float2 f = frac(UV * CellDensity);
float t = 8.0;
float3 res = float3(8.0, 0.0, 0.0);
for(int y=-1; y<=1; y++)
{
for(int x=-1; x<=1; x++)
{
float2 lattice = float2(x,y);
float2 offset = unity_voronoi_noise_randomVector(lattice + g, AngleOffset);
float d = distance(lattice + offset, f);
if(d < res.x)
{
res = float3(d, offset.x, offset.y);
Out = res.x;
Cells = res.y;
}
}
}
}