void SpanningTree()
{
var points = RandomPoints(400);
var vertices = points
.Select(p => new Vertex()
{
Location = p
})
.ToList();
var triangulation = Triangulation.CreateDelaunay <Vertex, Face>(vertices);
var edges = triangulation.Cells.SelectMany(f => f.GetEdges())
.Distinct()
.Where(e => e.Length < 0.2f);
var edgeList = edges.ToList();
var graph = edgeList.ToUndirectedGraph <Vertex, Edge>();
var tree = graph.MinimumSpanningTreePrim(GetWeight).ToList();
foreach (var edge in edgeList)
{
edge.Value = 0.3f;
}
foreach (var edge in tree)
{
edge.Value = 1.0f;
}
SetMeshFromEdges(edgeList);
PaintEdges(edgeList);
}
/// <summary>
/// Triangulate cell with the provided vertices.
/// </summary>
/// <param name="vertices">The vertices of the cell.</param>
/// <returns>The triangulation.</returns>
private IEnumerable <DefaultTriangulationCell <MIVertex> > Triangulate(List <Vector3D> vertices)
{
IEnumerable <DefaultTriangulationCell <MIVertex> > triangles = null;
// Convert vertices to objects that work with MIConvexHull library
MIVertex[] miVertices = new MIVertex[vertices.Count];
for (int i = 0; i < vertices.Count; i++)
{
miVertices[i] = new MIVertex(vertices[i].X, vertices[i].Y, vertices[i].Z);
}
if (vertices.Count == 4)
{
// MIConvexHull library cannot create a triangulation from a single tetrahedron
triangles = new List <DefaultTriangulationCell <MIVertex> >()
{
new DefaultTriangulationCell <MIVertex>()
{
Vertices = miVertices
}
};
}
else
{
// More vertices are OK so let the library to triangulate them
var triangulation = Triangulation.CreateDelaunay(miVertices);
triangles = triangulation.Cells;
}
return(triangles);
}
public static Vector2 GetSpawnPoint()
{
var vertices = new Vertex2[4 + spaceships.Count + shots.Count];
var index = 0;
var spaceHalfSize = Game.Size / 2;
vertices[index++] = new Vertex2(-spaceHalfSize.x, -spaceHalfSize.y);
vertices[index++] = new Vertex2(spaceHalfSize.x, -spaceHalfSize.y);
vertices[index++] = new Vertex2(-spaceHalfSize.x, spaceHalfSize.y);
vertices[index++] = new Vertex2(spaceHalfSize.x, spaceHalfSize.y);
foreach (var obj in spaceships)
{
vertices[index++] = new Vertex2(obj.Position.x, obj.Position.y);
}
foreach (var obj in shots)
{
vertices[index++] = new Vertex2(obj.Position.x, obj.Position.y);
}
var triangulation = Triangulation.CreateDelaunay <Vertex2, Cell2>(vertices);
Cell2 maxTriangle = triangulation.Cells.First();
float maxArea = 0;
foreach (var triangle in triangulation.Cells)
{
var area = triangle.Area;
if (area > maxArea)
{
maxArea = area;
maxTriangle = triangle;
}
}
return(maxTriangle.Centroid);
}
/// <summary>
/// returns a list of points of tetrahedrons in a given point cloud
/// </summary>
/// <param name="pointCloud">input point cloud</param>
/// <returns>list of tetrahedrons</returns>
public static List <List <Point> > calculateDelaunayTrianglePoints(PointCloud pointCloud)
{
List <List <Point> > retList = new List <List <Point> >();
try
{
//create vertex list
HashSet <Vertex> vertices = new HashSet <Vertex>();
foreach (Point p in pointCloud.pointcloud_hs)
{
vertices.Add(new Vertex(p.point.X, p.point.Y, p.point.Z));
}
//calculate tetrahedrons
var tetrahedrons = Triangulation.CreateDelaunay <Vertex, Tetrahedron>(vertices).Cells;
foreach (var c in tetrahedrons)
{
List <Point> pL = new List <Point>();
for (int i = 0; i < 4; i++)
{
Point p = new Point(new ANX.Framework.Vector3((float)c.Vertices[i].Position[0], (float)c.Vertices[i].Position[1], (float)c.Vertices[i].Position[2]));
pL.Add(p);
}
retList.Add(pL);
}
}
catch (Exception) { throw; }
return(retList);
}
static TimeSpan TestNDDelau(int dim, int numVert, double size)
{
var vertices = CreateRandomVertices(dim, numVert, size);
return(RunComputation(() =>
{
var r = Triangulation.CreateDelaunay(vertices);
Console.WriteLine(r.Cells.Count());
return r;
}));
}
/// <summary>
/// Ring:划分Delaunay三角网,结果保存于tsData
/// </summary>
/// <param name="depth">深度</param>
/// <param name="interpolateFunc">插值函数</param>
public void MeshRing(
double depth,
Func <IList <Point>, double, double, double, double> interpolateFunc)
{
try
{
triangulations = Triangulation.CreateDelaunay(this.allVerticesList);
this.TsData.VerticesList = new List <Point3D>(this.allVerticesList.Count);
this.TsData.TriLinksList = new List <TriLink>(this.triangulations.Cells.Count());
// 以Dict记录三角形的编号
int num = 1;
foreach (var cell in this.triangulations.Cells)
{
for (int i = 0; i < 3; ++i)
{
var v = cell.Vertices[i];
if (!this.vertexnumDictionary.ContainsKey(v))
{
this.vertexnumDictionary.Add(v, num++);
}
}
// 根据编号写ts的TriLinksList
this.TsData.TriLinksList.Add(new TriLink
{
VertexA = this.vertexnumDictionary[cell.Vertices[0]],
VertexB = this.vertexnumDictionary[cell.Vertices[1]],
VertexC = this.vertexnumDictionary[cell.Vertices[2]]
});
}
// 写ts的VerticesList, 并插值Z
foreach (var kv in this.vertexnumDictionary.OrderBy(n => n.Value))
{
var vPos = kv.Key.Position;
var x = vPos[0];
var y = vPos[1];
var z = interpolateFunc(this.edgeVerticesList, depth, x, y);
this.TsData.VerticesList.Add(new Point3D(x, y, z));
}
}
catch (Exception ex)
{
MessageBox.Show(ex.Message);
return;
}
}
IEnumerable <Edge> DelaunayEdges()
{
var points = go.Select(l => l.transform.position).ToList();
var vertices = points.Select(p => new Vertex()
{
Location = p
}).ToList();
var delaunay = Triangulation.CreateDelaunay <Vertex, Face>(vertices);
var edges = delaunay.Cells
.SelectMany(c => c.GetEdges())
.Distinct();
return(edges);
}
private void FindDelaunayClick(object sender, RoutedEventArgs e)
{
try
{
var now = DateTime.Now;
Del_tetras = Triangulation.CreateDelaunay(vertices).Cells.ToList();
var interval = DateTime.Now - now;
UpdateTimer(interval);
btnDisplay.IsEnabled = btnDisplay.IsDefault = true;
CVXvertices = null; CVXfaces = null; Voro_edges = null; Voro_nodes = null;
}
catch (Exception ex)
{
MessageBox.Show(ex.Message, "Error", MessageBoxButton.OK, MessageBoxImage.Information);
}
}
IEnumerable <Edge> DelaunayEdges(float maxLength)
{
var points = GetPoints(1_000);
var vertices = points.Select(p => new Vertex()
{
Location = p
}).ToList();
var delaunay = Triangulation.CreateDelaunay <Vertex, Face>(vertices);
var edges = delaunay.Cells
.SelectMany(c => c.GetEdges())
.Distinct()
.Where(e => e.Length < maxLength);
return(edges);
}
/// <summary>
/// creates a set of tetrahedrons from a given point cloud
/// </summary>
/// <param name="pPointCloud">the point cloud</param>
/// <returns>a list of tetrahedrons</returns>
static List <Tetrahedron> createDelaunayTetrahedrons(PointCloud pPointCloud)
{
//vars
List <Tetrahedron> retVal = new List <Tetrahedron>();
try
{
//create vertex list
HashSet <Vertex> vertices = new HashSet <Vertex>();
foreach (Point p in pPointCloud.pointcloud_hs)
{
vertices.Add(new Vertex(p.point.X, p.point.Y, p.point.Z));
}
retVal = Triangulation.CreateDelaunay <Vertex, Tetrahedron>(vertices).Cells.ToList();
}
catch (Exception) { throw; }
return(retVal);
}
void BunnyEdges()
{
var points = RandomPoints(400);
var vertices = points
.Select(p => new Vertex()
{
Location = p
})
.ToList();
var triangulation = Triangulation.CreateDelaunay <Vertex, Face>(vertices);
var edges = triangulation.Cells.SelectMany(f => f.GetEdges());
edges = edges.Where(e => e.Length < 0.2f);
var edgeList = edges.ToList();
SetMeshFromEdges(edgeList);
PaintEdges(edgeList);
}
IEnumerator DepthFirstSearchAnimated()
{
var points = RandomPoints(400);
var vertices = points
.Select(p => new Vertex()
{
Location = p
})
.ToList();
var triangulation = Triangulation.CreateDelaunay <Vertex, Face>(vertices);
var edges = triangulation.Cells.SelectMany(f => f.GetEdges())
.Distinct()
.Where(e => e.Length < 0.2f);
var edgeList = edges.ToList();
SetMeshFromEdges(edgeList);
var graph = edgeList.ToUndirectedGraph <Vertex, Edge>();
var sequence = new List <Edge>();
var s = new UndirectedDepthFirstSearchAlgorithm <Vertex, Edge>(graph);
s.ExamineEdge += (o, e) => sequence.Add(e.Edge);
s.Compute(graph.Vertices.First());
foreach (var edge in edgeList)
{
edge.Value = 0.3f;
}
foreach (var edge in sequence)
{
edge.Value = 1;
PaintEdges(edgeList);
yield return(new WaitForSeconds(0.05f));
}
}
/// <summary>
/// Creates a triangulation of random data.
/// For larger data sets it might be a good idea to separate the triangulation calculation
/// from creating the visual so that the triangulation can be computed on a separate threat.
/// </summary>
/// <param name="count">Number of vertices to generate</param>
/// <param name="radius">Radius of the vertices</param>
/// <param name="uniform"></param>
/// <returns>Triangulation</returns>
public static RandomTriangulation Create(int count, double radius, bool uniform)
{
Random rnd = new Random();
List <Vertex> vertices;
if (!uniform)
{
// generate some random points
Func <double> nextRandom = () => 2 * radius * rnd.NextDouble() - radius;
vertices = Enumerable.Range(0, count)
.Select(_ => new Vertex(nextRandom(), nextRandom(), nextRandom()))
.ToList();
}
else
{
vertices = new List <Vertex>();
int d = Math.Max((int)Math.Ceiling(Math.Sqrt(count)) / 2, 3);
double cs = 2 * radius / (d - 1);
for (int i = 0; i < d; i++)
{
for (int j = 0; j < d; j++)
{
for (int k = 0; k < d; k++)
{
vertices.Add(new Vertex(cs * i - cs * (d - 1) / 2, cs * j - cs * (d - 1) / 2, cs * k - cs * (d - 1) / 2));
}
}
}
}
// calculate the triangulation
var config = !uniform
? new TriangulationComputationConfig()
: new TriangulationComputationConfig
{
PointTranslationType = PointTranslationType.TranslateInternal,
PlaneDistanceTolerance = 0.000001,
// the translation radius should be lower than PlaneDistanceTolerance / 2
PointTranslationGenerator = TriangulationComputationConfig.RandomShiftByRadius(0.0000001, 0)
};
var tetrahedrons = Triangulation.CreateDelaunay <Vertex, Tetrahedron>(vertices, config).Cells;
// create a model for each tetrahedron, pick a random color
Model3DGroup model = new Model3DGroup();
foreach (var t in tetrahedrons)
{
var color = Color.FromArgb((byte)255, (byte)rnd.Next(256), (byte)rnd.Next(256), (byte)rnd.Next(256));
model.Children.Add(t.CreateModel(color, radius));
}
//var redMaterial = new MaterialGroup
//{
// Children = new MaterialCollection
// {
// new DiffuseMaterial(Brushes.Red),
// // give it some shine
// new SpecularMaterial(Brushes.LightYellow, 2.0)
// }
//};
//var greenMaterial = new MaterialGroup
//{
// Children = new MaterialCollection
// {
// new DiffuseMaterial(Brushes.Green),
// // give it some shine
// new SpecularMaterial(Brushes.LightYellow, 2.0)
// }
//};
//var blueMaterial = new MaterialGroup
//{
// Children = new MaterialCollection
// {
// new DiffuseMaterial(Brushes.Blue),
// // give it some shine
// new SpecularMaterial(Brushes.LightYellow, 2.0)
// }
//};
//CylinderMesh c = new CylinderMesh() { Length = 10, Radius = 0.5 };
//model.Children.Add(new GeometryModel3D { Geometry = c.Geometry, Material = greenMaterial });
//model.Children.Add(new GeometryModel3D { Geometry = c.Geometry, Material = redMaterial, Transform = new RotateTransform3D(new AxisAngleRotation3D(new Vector3D(0, 0, 1), 90)) });
//model.Children.Add(new GeometryModel3D { Geometry = c.Geometry, Material = blueMaterial, Transform = new RotateTransform3D(new AxisAngleRotation3D(new Vector3D(1, 0, 0), 90)) });
var triangulation = new RandomTriangulation();
triangulation.tetrahedrons = tetrahedrons;
// assign the Visual3DModel property of the ModelVisual3D class
triangulation.Visual3DModel = model;
return(triangulation);
}
/// <summary>
/// Creates a triangulation of random data.
/// For larger data sets it might be a good idea to separate the triangulation calculation
/// from creating the visual so that the triangulation can be computed on a separate threat.
/// </summary>
/// <param name="count">Number of vertices to generate</param>
/// <param name="radius">Radius of the vertices</param>
/// <param name="uniform"></param>
/// <returns>Triangulation</returns>
public static RandomTriangulation Create(int count, double radius, bool uniform, string[] textValue)
{
Random rnd = new Random();
List <Vertex> vertices = new List <Vertex>();
if (!uniform)
{
// generate some random points
//Func<double> nextRandom = () => 2 * radius * rnd.NextDouble() - radius;
//vertices = Enumerable.Range(0, count)
// .Select(_ => new Vertex(nextRandom(), nextRandom(), nextRandom()))
// .ToList();
for (int i = 0; i < textValue.Length; i += 3)
{
vertices.Add(new Vertex(Convert.ToDouble(textValue[i]), Convert.ToDouble(textValue[i + 1]), Convert.ToDouble(textValue[i + 2])));
}
}
else
{
vertices = new List <Vertex>();
int d = Math.Max((int)Math.Ceiling(Math.Sqrt(count)) / 2, 3);
double cs = 2 * radius / (d - 1);
for (int i = 0; i < d; i++)
{
for (int j = 0; j < d; j++)
{
for (int k = 0; k < d; k++)
{
vertices.Add(new Vertex(cs * i - cs * (d - 1) / 2, cs * j - cs * (d - 1) / 2, cs * k - cs * (d - 1) / 2));
}
}
}
}
var tetrahedrons = Triangulation.CreateDelaunay <Vertex, Tetrahedron>(vertices).Cells;
// create a model for each tetrahedron, pick a random color
Model3DGroup model = new Model3DGroup();
foreach (var t in tetrahedrons)
{
var color = Color.FromArgb((byte)255, (byte)rnd.Next(256), (byte)rnd.Next(256), (byte)rnd.Next(256));
model.Children.Add(t.CreateModel(color, radius));
}
//var redMaterial = new MaterialGroup
//{
// Children = new MaterialCollection
// {
// new DiffuseMaterial(Brushes.Red),
// // give it some shine
// new SpecularMaterial(Brushes.LightYellow, 2.0)
// }
//};
//var greenMaterial = new MaterialGroup
//{
// Children = new MaterialCollection
// {
// new DiffuseMaterial(Brushes.Green),
// // give it some shine
// new SpecularMaterial(Brushes.LightYellow, 2.0)
// }
//};
//var blueMaterial = new MaterialGroup
//{
// Children = new MaterialCollection
// {
// new DiffuseMaterial(Brushes.Blue),
// // give it some shine
// new SpecularMaterial(Brushes.LightYellow, 2.0)
// }
//};
//CylinderMesh c = new CylinderMesh() { Length = 10, Radius = 0.5 };
//model.Children.Add(new GeometryModel3D { Geometry = c.Geometry, Material = greenMaterial });
//model.Children.Add(new GeometryModel3D { Geometry = c.Geometry, Material = redMaterial, Transform = new RotateTransform3D(new AxisAngleRotation3D(new Vector3D(0, 0, 1), 90)) });
//model.Children.Add(new GeometryModel3D { Geometry = c.Geometry, Material = blueMaterial, Transform = new RotateTransform3D(new AxisAngleRotation3D(new Vector3D(1, 0, 0), 90)) });
var triangulation = new RandomTriangulation();
triangulation.tetrahedrons = tetrahedrons;
int OBJIndex = 1, OBJTextureIndex = 1;
Dictionary <string, OBJNormalVertex> OBJNormalVertexList = new Dictionary <string, OBJNormalVertex>();
Dictionary <string, string> OBJTextureKeyList = new Dictionary <string, string>();
Dictionary <string, int> OBJTextureList = new Dictionary <string, int>();
foreach (var Element in vertices)
{
string textVertex = string.Format("v {0} {1} {2}", Element.Position[0], Element.Position[1], Element.Position[2]);
string textTexture = string.Format("vt {0} {1}", (Element.Position[0] + 50) / 100, (Element.Position[1] + 50) / 100);
OBJTextureKeyList.Add(textVertex, textTexture);
OBJNormalVertexList.Add(textVertex, new OBJNormalVertex(OBJIndex++, 0, new double[] { 0, 0, 0 }, ""));
if (OBJTextureList.ContainsKey(textTexture) == false)
{
OBJTextureList.Add(textTexture, OBJTextureIndex++);
}
}
foreach (var Element in tetrahedrons)
{
for (int i = 0; i < 3; i++)
{
string textVertex = string.Format("v {0} {1} {2}", Element.Vertices[i].Position[0], Element.Vertices[i].Position[1], Element.Vertices[i].Position[2]);
OBJNormalVertexList[textVertex].count++;
OBJNormalVertexList[textVertex].NormalVertex[0] += Element.Normal[0];
OBJNormalVertexList[textVertex].NormalVertex[1] += Element.Normal[1];
OBJNormalVertexList[textVertex].NormalVertex[2] += Element.Normal[2];
}
}
foreach (var Element in OBJNormalVertexList)
{
Element.Value.ArrangeNormalVertex();
}
using (System.IO.StreamWriter file = new System.IO.StreamWriter(@"C:\Users\DEVMF\Desktop\File\VS\MIConvexHull-master\MIConvexHull-master\Examples\7DelaunayWPF\output.txt"))
{
foreach (var Element in OBJNormalVertexList)
{
file.WriteLine(Element.Key);
}
file.WriteLine();
foreach (var Element in OBJNormalVertexList)
{
file.WriteLine(Element.Value.NormalVertexQuery);
}
file.WriteLine();
foreach (var Element in OBJTextureList)
{
file.WriteLine(Element.Key);
}
file.WriteLine();
foreach (var Element in tetrahedrons)
{
string query1 = string.Format("v {0} {1} {2}", Element.Vertices[0].Position[0], Element.Vertices[0].Position[1], Element.Vertices[0].Position[2]);
string query2 = string.Format("v {0} {1} {2}", Element.Vertices[1].Position[0], Element.Vertices[1].Position[1], Element.Vertices[1].Position[2]);
string query3 = string.Format("v {0} {1} {2}", Element.Vertices[2].Position[0], Element.Vertices[2].Position[1], Element.Vertices[2].Position[2]);
string face1 = string.Format("{0}/{1}/{2}", OBJNormalVertexList[query1].index, OBJTextureList[OBJTextureKeyList[query1]], OBJNormalVertexList[query1].index);
string face2 = string.Format("{0}/{1}/{2}", OBJNormalVertexList[query2].index, OBJTextureList[OBJTextureKeyList[query2]], OBJNormalVertexList[query2].index);
string face3 = string.Format("{0}/{1}/{2}", OBJNormalVertexList[query3].index, OBJTextureList[OBJTextureKeyList[query3]], OBJNormalVertexList[query3].index);
string face = string.Format("f {0} {1} {2}", face1, face2, face3);
file.WriteLine(face);
}
}
//foreach (var Element in OBJVertexAndVormalVertex)
// if (Element.Value.isNegative)
// OBJVertexTexture.Add(Element.Value.vertexTexture, VTindex++);
// assign the Visual3DModel property of the ModelVisual3D class
triangulation.Visual3DModel = model;
return(triangulation);
}
/// <summary>
/// Triangulate cell with the provided vertices.
/// </summary>
/// <param name="vertices">The vertices of the cell.</param>
/// <returns>The triangulation.</returns>
private IEnumerable <DefaultTriangulationCell <MIVertex> > Triangulate(List <Vector2D> vertices)
{
if (vertices.Count == 3)
{
// Convert vertices to objects that work with MIConvexHull library
MIVertex[] miVertices = new MIVertex[vertices.Count];
for (int i = 0; i < vertices.Count; i++)
{
miVertices[i] = new MIVertex(vertices[i].X, vertices[i].Y);
}
// MIConvexHull library cannot create a triangulation from a single triangle
return(new List <DefaultTriangulationCell <MIVertex> >()
{
new DefaultTriangulationCell <MIVertex>()
{
Vertices = miVertices
}
});
}
else if (vertices.Count == 4)
{
// There are problems with 4 vertices in MIConvexHull algorithms. There are multiple issues on their github
Vector2D average = new Vector2D();
for (int i = 0; i < vertices.Count; i++)
{
average.X += vertices[i].X;
average.Y += vertices[i].Y;
}
average.X /= vertices.Count;
average.Y /= vertices.Count;
// Convert vertices to objects that work with MIConvexHull library
List <MIVertex> miVertices = new List <MIVertex>(vertices.Count);
for (int i = 0; i < vertices.Count; i++)
{
miVertices.Add(new MIVertex(vertices[i].X, vertices[i].Y));
}
miVertices.Sort(Comparer <MIVertex> .Create((item1, item2) => {
var position1 = item1.Position;
var position2 = item2.Position;
double a1 = ((Math.Atan2(position1[0] - average.X, position1[1] - average.Y) * 180 / Math.PI) + 360) % 360;
double a2 = ((Math.Atan2(position2[0] - average.X, position2[1] - average.Y) * 180 / Math.PI) + 360) % 360;
return((int)(a1 - a2));
}));
var triangles = new List <DefaultTriangulationCell <MIVertex> >();
for (int i = 1; i < miVertices.Count - 1; i++)
{
MIVertex[] tempVertices = { miVertices[0], miVertices[i], miVertices[i + 1] };
triangles.Add(new DefaultTriangulationCell <MIVertex>()
{
Vertices = tempVertices
});
}
return(triangles);
}
else
{
// Convert vertices to objects that work with MIConvexHull library
MIVertex[] miVertices = new MIVertex[vertices.Count];
for (int i = 0; i < vertices.Count; i++)
{
miVertices[i] = new MIVertex(vertices[i].X, vertices[i].Y);
}
// More vertices are OK so let the library to triangulate them
var triangulation = Triangulation.CreateDelaunay(miVertices);
return(triangulation.Cells);
}
}
/// <summary>
/// Creates a triangulation of random data.
/// For larger data sets it might be a good idea to separate the triangulation calculation
/// from creating the visual so that the triangulation can be computed on a separate threat.
/// </summary>
/// <param name="count">Number of vertices to generate</param>
/// <param name="radius">Radius of the vertices</param>
/// <returns>Triangulation</returns>
public static RandomTriangulation Create(int count, double radius)
{
Random rnd = new Random();
// generate some random points
Func <double> nextRandom = () => 2 * radius * rnd.NextDouble() - radius;
var vertices = Enumerable.Range(0, count)
.Select(_ => new Vertex(nextRandom(), nextRandom(), nextRandom()))
.ToList();
//var vertices = new List<Vertex>();
//int d = 4;
//double cs = 10.0;
//for (int i = 0; i < d; i++)
//{
// for (int j = 0; j < d; j++)
// {
// for (int k = 0; k < d; k++)
// {
// //vertices.Add(new Vertex(10 * i - 20 + rnd.NextDouble(), 10 * j - 20 - rnd.NextDouble(), 10 * k - 20 + rnd.NextDouble()));
// vertices.Add(new Vertex(-10 * i, 10 * j, 10 * k));
// }
// }
//}
// calculate the triangulation
var tetrahedrons = Triangulation.CreateDelaunay <Vertex, Tetrahedron>(vertices).Cells;
// create a model for each tetrahedron, pick a random color
Model3DGroup model = new Model3DGroup();
foreach (var t in tetrahedrons)
{
var color = Color.FromArgb((byte)255, (byte)rnd.Next(256), (byte)rnd.Next(256), (byte)rnd.Next(256));
model.Children.Add(t.CreateModel(color, radius));
}
//var redMaterial = new MaterialGroup
//{
// Children = new MaterialCollection
// {
// new DiffuseMaterial(Brushes.Red),
// // give it some shine
// new SpecularMaterial(Brushes.LightYellow, 2.0)
// }
//};
//var greenMaterial = new MaterialGroup
//{
// Children = new MaterialCollection
// {
// new DiffuseMaterial(Brushes.Green),
// // give it some shine
// new SpecularMaterial(Brushes.LightYellow, 2.0)
// }
//};
//var blueMaterial = new MaterialGroup
//{
// Children = new MaterialCollection
// {
// new DiffuseMaterial(Brushes.Blue),
// // give it some shine
// new SpecularMaterial(Brushes.LightYellow, 2.0)
// }
//};
//CylinderMesh c = new CylinderMesh() { Length = 10, Radius = 0.5 };
//model.Children.Add(new GeometryModel3D { Geometry = c.Geometry, Material = greenMaterial });
//model.Children.Add(new GeometryModel3D { Geometry = c.Geometry, Material = redMaterial, Transform = new RotateTransform3D(new AxisAngleRotation3D(new Vector3D(0, 0, 1), 90)) });
//model.Children.Add(new GeometryModel3D { Geometry = c.Geometry, Material = blueMaterial, Transform = new RotateTransform3D(new AxisAngleRotation3D(new Vector3D(1, 0, 0), 90)) });
var triangulation = new RandomTriangulation();
triangulation.tetrahedrons = tetrahedrons;
// assign the Visual3DModel property of the ModelVisual3D class
triangulation.Visual3DModel = model;
return(triangulation);
}
static TimeSpan TestNDDelau(int dim, int numVert, double size)
{
var vertices = CreateRandomVertices(dim, numVert, size);
return(RunComputation(() => Triangulation.CreateDelaunay(vertices)));
}