public Geometry Output()
{
Geometry geo = new Geometry();
// Vertices and normals
geo.Vertices = new Vector3 [] {
new Vector3( Size.x / 2, 0, -Size.y / 2), // bottom right
new Vector3(-Size.x / 2, 0, -Size.y / 2), // bottom left
new Vector3(-Size.x / 2, 0, Size.y / 2), // top left
new Vector3( Size.x / 2, 0, Size.y / 2) // top right
};
Vector3 normal = new Vector3(0f, 1f, 0f);
geo.Normals = new Vector3 [] {normal, normal, normal, normal};
Vector4 tangent = new Vector4(1f, 0f, 0f, -1f);
geo.Tangents = new Vector4 [] {tangent, tangent, tangent, tangent};
geo.Polygons = new int[] {0, 4};
// UV
geo.UV = new Vector2 [] {
new Vector2(1f, 1f),
new Vector2(0f, 0f),
new Vector2(0f, 1f),
new Vector2(1f, 1f)
};
// Surface
switch (Surface) {
case Surface.None:
geo.Triangles = new int[0];
break;
case Surface.Triangulate:
geo.Triangles = new int [] {
0, 1, 2,
2, 3, 0
};
break;
case Surface.Converge:
var conv = new Converge(geo);
conv.Point = Center;
conv.RecalculateNormals = false;
geo = conv.Output();
break;
}
geo.ApplyOrientation(Orientation);
geo.Offset(Center);
// Orientation
return geo;
}
public Geometry Output()
{
Geometry geo = new Geometry(3);
// http://upload.wikimedia.org/wikipedia/commons/9/9a/Degree-Radian_Conversion.svg
float radius = 2 * Height / 3;
geo.Vertices = new Vector3[3];
for (int i = 0; i < 3; i++) {
float degrees = 90 + 120 * i;
float radians = Mathf.PI / 180 * degrees;
float cos = Mathf.Cos(radians);
float sin = Mathf.Sin(radians);
geo.Vertices[2 - i] = new Vector3(cos * radius, 0f, sin * radius);
}
// Normals
Vector3 normal = new Vector3(0f, 1f, 0f);
geo.Normals = new Vector3 [] {normal, normal, normal};
// UV
geo.UV = new Vector2 [] {
new Vector2(1.0f, 0.0f),
new Vector2(0.0f, 0.0f),
new Vector2(0.5f, 1.0f)
};
// Triangles
if (Surface) {
geo.Triangles = new int [] {0, 1, 2};
} else {
geo.Triangles = new int[0];
}
// Polygons
geo.Polygons = new int[] {0, 3};
geo.ApplyOrientation(Orientation);
geo.Offset(Center);
// Orientation
return geo;
}
public Geometry Output()
{
if (Segments < 3) {
Debug.LogError("Sphere error: Spheres must have at least 3 segments");
}
Geometry geo = new Geometry(
Segments*(Segments+1),
(Segments*2) * (Segments-1) * 3 -Segments*6, // (Segments*2) = # triangles in a ring, (Segments-1) = # of rings in sphere
Segments*2
);
float tau = Mathf.PI * 2;
int triIndex = 0;
// Longitudes (meridians)
for (int i = 0; i < Segments; i++) {
float lonAng = Mathf.PI/2 + (Mathf.PI * i / (Segments - 1));
float lonSin = Mathf.Sin(lonAng) * Radius;
float lonCos = Mathf.Cos(lonAng) * Radius;
// Latitudes (parallels)
int offset = i * (Segments + 1);
// We iterate one additional time to create an overlapping longitude
// at the UV seam
for (int l = 0; l < Segments + 1; l++) {
float latAng = tau * l / Segments;
float latCos = Mathf.Cos(latAng) * lonCos;
float latSin = Mathf.Sin(latAng) * lonCos;
// Vertices, Normals, UV
geo.Vertices[offset + Segments - l] = new Vector3(latCos, lonSin, latSin);
geo.Normals[offset + Segments - l] = new Vector3(latCos, lonSin, latSin);
geo.UV[offset + Segments - l] = new Vector2(latAng / tau, (lonSin+Radius) / (Radius*2));
// Tangents
geo.Tangents[offset + Segments - l] = new Vector4(-latSin, 0f, latCos, -1).normalized;
}
// Polygons
var polyOrigin = geo.Polygons[i*2 ] = offset;
var polyLength = geo.Polygons[i*2+1] = Segments+1;
if (i > 0) {
for (int t = 0; t < polyLength-1; t++) {
// First Triangle
if (i < Segments-1) {
geo.Triangles[triIndex++] = polyOrigin + t;
geo.Triangles[triIndex++] = polyOrigin + t + 1;
geo.Triangles[triIndex++] = polyOrigin + t - polyLength + 1;
}
// Second Triangle
if (i > 1) {
geo.Triangles[triIndex++] = polyOrigin + t;
geo.Triangles[triIndex++] = polyOrigin + t - polyLength + 1;
geo.Triangles[triIndex++] = polyOrigin + t - polyLength;
}
}
}
}
geo.Offset(Center);
geo.ApplyOrientation(Orientation);
return geo;
}
public Geometry Output()
{
bool isOpen = Mathf.Abs(EndAngle - StartAngle) < 360;
bool hasMidPoint = (Opening == OpeningType.Sector && isOpen) ||
(Opening == OpeningType.Sector && Surface);
int vertexCount = Segments;
if (isOpen) vertexCount++;
if (hasMidPoint) vertexCount++;
Geometry geo = new Geometry(vertexCount);
int arcVertices = Segments + (isOpen || hasMidPoint ? 1 : 0);
// Vertices, Normals
for (int i = 0; i < arcVertices; i++) {
int seg = Segments + (hasMidPoint ? 0 : 0);
float angle = StartAngle + ((EndAngle-StartAngle) * i / seg);
float h = Mathf.Cos(angle * Mathf.Deg2Rad) * Radius;
float v = Mathf.Sin(angle * Mathf.Deg2Rad) * Radius;
geo.Vertices[arcVertices - i - 1] = new Vector3(h, 0f, v);
geo.Normals[arcVertices - i - 1] = Vector3.up;
}
if (hasMidPoint) {
geo.Vertices[vertexCount-1] = Vector3.zero;
geo.Normals[vertexCount-1] = Vector3.up;
}
if (Surface) {
var triangulate = new Triangulate(geo);
geo = triangulate.Output();
if (!isOpen && Opening == OpeningType.Sector) {
System.Array.Resize<int>(ref geo.Triangles, geo.Triangles.Length + 3);
geo.Triangles[geo.Triangles.Length-3] = 0;
geo.Triangles[geo.Triangles.Length-2] = Segments;
geo.Triangles[geo.Triangles.Length-1] = Segments-1;
}
}
// Polygon
if (hasMidPoint && !isOpen) {
geo.Polygons = new int[] {0, vertexCount-1};
} else {
geo.Polygons = new int[] {0, vertexCount};
}
geo.ApplyOrientation(Orientation);
geo.Offset(Center);
return geo;
}