private void Start()
{
binaryVals = new int[size + 1, size + 1];
VertexValues = new float[size + 1, size + 1];
for (int x1 = 0; x1 <= size; x1++)
{
for (int y1 = 0; y1 <= size; y1++)
{
binaryVals[x1, y1] = noise((float)x1, (float)y1) > (scale / 2) ? 1 : 0;
VertexValues[x1, y1] = noise((float)x1, (float)y1);
}
}
float noise(float x, float y) => Mathf.PerlinNoise(x / scale, y / scale) * scale;
for (int x = 0; x < size; x++)
{
for (int y = 0; y < size; y++)
{
int g = binaryVals[x, y + 1] * 8 + binaryVals[x + 1, y + 1] * 4 + binaryVals[x + 1, y] * 2 + binaryVals[x, y];
for (int i = 1; i <= 4; i++)
{
Vector3 a = TriangulationTable[g, i * 3 - 3] != -1 ? point(x, y, TriangulationTable[g, i * 3 - 3] - 1) : Vector3.zero;
Vector3 b = TriangulationTable[g, i * 3 - 2] != -1 ? point(x, y, TriangulationTable[g, i * 3 - 2] - 1) : Vector3.zero;
Vector3 c = TriangulationTable[g, i * 3 - 1] != -1 ? point(x, y, TriangulationTable[g, i * 3 - 1] - 1) : Vector3.zero;
if (a != Vector3.zero || b != Vector3.zero || c != Vector3.zero)
{
tris.AddRange(new List <int>()
{
Verts.Count, Verts.Count + 1, Verts.Count + 2
});
Verts.AddRange(new List <Vector3>()
{
a, b, c
});
}
}
}
}
GetComponent <MeshFilter>().mesh = new Mesh()
{
vertices = Verts.ToArray(),
triangles = tris.ToArray()
};
var welder = new MeshWelder(GetComponent <MeshFilter>().mesh);
welder.Weld();
}
void GenerateMapFromNavMesh(ref DiffuseNode[] array)
{
navMesh = NavMesh.CalculateTriangulation();
vertices = navMesh.vertices;
polygons = navMesh.indices;
Mesh m = new Mesh();
m.vertices = vertices;
m.triangles = polygons;
MeshWelder welder = new MeshWelder(m);
welder.Weld();
vertices = m.vertices;
polygons = m.triangles;
size = polygons.Length;
array = new DiffuseNode[size];
arrayColSize = 20;
arrayRowSize = 20;
arrayInfo.ARRAY_MAX = size;
arrayInfo.ARRAY_MIN = 0;
arrayInfo.ARRAY_HALF_WIDTH = arrayInfo.ARRAY_MAX / 2;
DiffuseNode t = new DiffuseNode();
for (int i = arrayInfo.ARRAY_MIN; i < arrayInfo.ARRAY_MAX; i++)
{
t.wall = false;
t.lambda = 1.0f;
t.p = 1.0f;
t.position = vertices[polygons[i]];
t.polygonIndex = polygons[i];
t.arrayIndex = i;
array[i] = t;
array[i].skip = false;
}
}
public GameObject CreateMergedCourse(CombineInstance[] wInstance, CombineInstance[] fInstance)
{
var defMats = GameObject.FindObjectOfType <DefaultMats>();
var holeObj = new GameObject("Hole")
{
tag = "Hole", layer = 10
};
var wallObj = new GameObject("Walls")
{
tag = "HoleWalls", layer = 10
};
var floorObj = new GameObject("Floor")
{
tag = "HoleFloor", layer = 10
};
List <GameObject> objs = new List <GameObject>()
{
wallObj, floorObj
};
foreach (GameObject obj in objs)
{
//Parent to the hole object
obj.transform.parent = holeObj.transform;
//Add Components
//Mesh Filter
MeshFilter mFilter = obj.AddComponent(typeof(MeshFilter)) as MeshFilter;
mFilter.mesh = new Mesh();
switch (obj.name)
{
case "Walls":
mFilter.mesh.CombineMeshes(wInstance);
break;
case "Floor":
mFilter.mesh.CombineMeshes(fInstance);
break;
}
//Mesh Renderer
MeshRenderer mRenderer = obj.AddComponent(typeof(MeshRenderer)) as MeshRenderer;
mRenderer.shadowCastingMode = UnityEngine.Rendering.ShadowCastingMode.TwoSided;
//Rigidbody
Rigidbody rBody = obj.AddComponent(typeof(Rigidbody)) as Rigidbody;
rBody.isKinematic = true;
rBody.useGravity = false;
//Collider(s)
MeshCollider collider = obj.AddComponent(typeof(MeshCollider)) as MeshCollider;
MeshCollider trigger = obj.AddComponent(typeof(MeshCollider)) as MeshCollider;
trigger.convex = true;
trigger.isTrigger = true;
//Collision Checks
obj.AddComponent(typeof(EnvironmentCollisionCheck));
//Set the relevant materials
switch (obj.name)
{
case "Walls":
mRenderer.material = defMats.defaultWalls;
collider.material = defMats.defaultPhysWalls;
break;
case "Floor":
mRenderer.material = defMats.defaultFloors;
collider.material = defMats.defaultPhysFloors;
break;
}
//Double vertice welding
var welder = new MeshWelder(mFilter.mesh);
welder.Weld();
mFilter.mesh.RecalculateNormals();
}
return(holeObj);
}
private void Start()
{
// Slow
Vector3 pos = transform.position;
for (int i = 0; i < HeightSegments; i++)
{
float x = 1 - BiasFunction((float)i / (float)HeightSegments, .2f);
AddSquarePoints(x, Random.Range(-25, 25), new Vector3(pos.x, i * height + pos.y, pos.z), i);
}
float BiasFunction(float x, float Bias) => x *Mathf.Pow(1 - Bias, 3) / (x * Mathf.Pow(1 - Bias, 3) - x + 1);
// Fast
for (int i = 0; i < HeightSegments - 1; i++)
{
addquad(verts[i * 4], verts[i * 4 + 1], verts[(i + 1) * 4 + 1], verts[(i + 1) * 4]);
addquad(verts[i * 4 + 1], verts[i * 4 + 2], verts[(i + 1) * 4 + 2], verts[(i + 1) * 4 + 1]);
addquad(verts[i * 4 + 2], verts[i * 4 + 3], verts[(i + 1) * 4 + 3], verts[(i + 1) * 4 + 2]);
addquad(verts[i * 4 + 3], verts[i * 4], verts[(i + 1) * 4], verts[(i + 1) * 4 + 3]);
}
// Slow
int s = (HeightSegments - 1) * 4;
addquad(verts[s], verts[s + 1], verts[s + 2], verts[s + 3]);
// Fast
float d = verts[(int)(verts.Count / 2) + (int)(verts.Count / 4)].y;
AddTreeSquare(3, Random.Range(-5, 5), new Vector3(pos.x, pos.y + LeavesHeight + (d - (d / 2)), pos.z), true);
AddTreeSquare(2, Random.Range(-5, 5), new Vector3(pos.x, pos.y + LeavesHeight + (d + (height) * 3), pos.z), false);
// Slow
int b = verts.Count - 8;
// Fast
addquad(verts[b], verts[b + 1], verts[b + 5], verts[b + 4]);
addquad(verts[b + 1], verts[b + 2], verts[b + 6], verts[b + 5]);
addquad(verts[b + 2], verts[b + 3], verts[b + 7], verts[b + 6]);
addquad(verts[b], verts[b + 4], verts[b + 7], verts[b + 3]);
// Slow
GetComponent <MeshFilter>().mesh = new Mesh()
{
vertices = verts.ToArray(),
triangles = Triangles.ToArray()
};
// For End
var welder = new MeshWelder(GetComponent <MeshFilter>().mesh);
welder.Weld();
// Slow
GetComponent <MeshFilter>().mesh.RecalculateNormals();
Colors = new Color[GetComponent <MeshFilter>().mesh.vertices.Length];
for (int i = 0; i < GetComponent <MeshFilter>().mesh.vertices.Length; i++)
{
if (i < GetComponent <MeshFilter>().mesh.vertices.Length - 8)
{
Colors[i] = bark;
}
else
{
Colors[i] = Leaves;
}
}
GetComponent <MeshFilter>().mesh.colors = Colors;
}
