private float yIntensity = 0.3F; // Intensity of randomization on the Y axis

    #endregion Fields

    #region Methods

    /**
     * This function generates the heightmap and makes the vertices.
     * Normals are calculated by the MakeVertsUnique() function.
     * Calling this function is required, so there's no need to be save about executing the
     * RecalculateNormals() function
     */
    public void GenerateHeightmap()
    {
        noise = new ex.FractalNoise();
        noise.SetNoise( offsetX, offsetY, seed );

        mesh = GetComponent<MeshFilter>().mesh;
        if( !mesh ) {
            Debug.Log( "Can't find mesh!" );
            return;
        }

        if( landMaterial )
            renderer.material = landMaterial;
        else
            renderer.material.color = Color.magenta;

        Vector3[] vertices = new Vector3[Height * Width];
        Vector2[] uv = new Vector2[Height * Width];

        Vector2 uvScale = new Vector2( 1.0f / ( Width - 1 ), 1.0f / ( Height - 1 ) );
        Vector3 sizeScale = new Vector3( Size.x / ( Width - 1 ), Size.y, Size.z / ( Height - 1 ) );

        int y = 0;
        int x = 0;
        for( y = 0; y < Height; y++ ) {
            for( x = 0; x < Width; x++ ) {

                Vector3 vertex = new Vector3( x, noise.GenerateFractal( amplitude, frequency, octaves, (float) x, (float) y, persistence ), y );
                vertex.y += noise.GeneratePerlin( (float) x, (float) y ) * yIntensity;

                vertices[y*Width + x] = Vector3.Scale( sizeScale, vertex ); // Sets the vertex position on the grid
                uv[y * Width + x] = Vector2.Scale( new Vector2( x, y ), uvScale );

                if( y < Height - 1 && y > 0 && x < Width - 1 && x > 0 ) {       // Don't randomize outer bounds of node because of (future) tiling
                    vertices[y * Width + x].x += Random.Range( -1.0f, 1.0f ) * yIntensity;
                    vertices[y * Width + x].z += Random.Range( -1.0f, 1.0f ) * yIntensity;
                }
            }
        }

        // Build triangle indices: 3 indices into vertex array for each triangle
        int[] triangles = new int[(Height - 1) * (Width - 1) * 6];
        int index = 0;
        for( y = 0; y < Height-1; y++ ) {
            for( x = 0; x < Width-1; x++ ) {
                // For each grid cell output two triangles
                triangles[index++] = (y     * Width) + x;
                triangles[index++] = ((y+1) * Width) + x;
                triangles[index++] = (y     * Width) + x + 1;

                triangles[index++] = ((y+1) * Width) + x;
                triangles[index++] = ((y+1) * Width) + x + 1;
                triangles[index++] = (y     * Width) + x + 1;
            }
        }

        mesh.Clear();

        mesh.vertices = vertices;
        mesh.uv = uv;
        mesh.triangles = triangles;

        MakeVertsUnique();
    }
Exemplo n.º 2
0
    private ex.FractalNoise noise;  // Object of FractalNoise class, namespaced in ex

    /**
     * This function generates the heightmap and makes the vertices.
     * Normals are calculated by the MakeVertsUnique() function.
     * Calling this function is required, so there's no need to be save about executing the
     * RecalculateNormals() function
     */
    public void GenerateHeightmap()
    {
        noise = new ex.FractalNoise();
        noise.SetNoise(offsetX, offsetY, seed);

        mesh = GetComponent <MeshFilter>().mesh;
        if (!mesh)
        {
            Debug.Log("Can't find mesh!");
            return;
        }

        if (landMaterial)
        {
            renderer.material = landMaterial;
        }
        else
        {
            renderer.material.color = Color.magenta;
        }

        Vector3[] vertices = new Vector3[Height * Width];
        Vector2[] uv       = new Vector2[Height * Width];

        Vector2 uvScale   = new Vector2(1.0f / (Width - 1), 1.0f / (Height - 1));
        Vector3 sizeScale = new Vector3(Size.x / (Width - 1), Size.y, Size.z / (Height - 1));

        int y = 0;
        int x = 0;

        for (y = 0; y < Height; y++)
        {
            for (x = 0; x < Width; x++)
            {
                Vector3 vertex = new Vector3(x, noise.GenerateFractal(amplitude, frequency, octaves, (float)x, (float)y, persistence), y);
                vertex.y += noise.GeneratePerlin((float)x, (float)y) * yIntensity;

                vertices[y * Width + x] = Vector3.Scale(sizeScale, vertex);             // Sets the vertex position on the grid
                uv[y * Width + x]       = Vector2.Scale(new Vector2(x, y), uvScale);

                if (y < Height - 1 && y > 0 && x < Width - 1 && x > 0)          // Don't randomize outer bounds of node because of (future) tiling
                {
                    vertices[y * Width + x].x += Random.Range(-1.0f, 1.0f) * yIntensity;
                    vertices[y * Width + x].z += Random.Range(-1.0f, 1.0f) * yIntensity;
                }
            }
        }

        // Build triangle indices: 3 indices into vertex array for each triangle
        int[] triangles = new int[(Height - 1) * (Width - 1) * 6];
        int   index     = 0;

        for (y = 0; y < Height - 1; y++)
        {
            for (x = 0; x < Width - 1; x++)
            {
                // For each grid cell output two triangles
                triangles[index++] = (y * Width) + x;
                triangles[index++] = ((y + 1) * Width) + x;
                triangles[index++] = (y * Width) + x + 1;

                triangles[index++] = ((y + 1) * Width) + x;
                triangles[index++] = ((y + 1) * Width) + x + 1;
                triangles[index++] = (y * Width) + x + 1;
            }
        }

        mesh.Clear();

        mesh.vertices  = vertices;
        mesh.uv        = uv;
        mesh.triangles = triangles;

        MakeVertsUnique();
    }