private void DrawSubdivision(Subdivision division)
{
// generate new random subdivision if desired
if (division == null)
{
PointD offset = new PointD(OutputBox.Width * 0.2, OutputBox.Height * 0.2);
SizeD scale = new SizeD(OutputBox.Width * 0.6, OutputBox.Height * 0.6);
int count = MersenneTwister.Default.Next(4, 12);
PointD[] points = new PointD[count];
for (int i = 0; i < points.Length; i++)
{
points[i] = new PointD(
offset.X + MersenneTwister.Default.NextDouble() * scale.Width,
offset.Y + MersenneTwister.Default.NextDouble() * scale.Height);
}
// outer bounds for Voronoi pseudo-vertices
double margin = 3 * FontSize;
RectD bounds = new RectD(margin, margin,
OutputBox.Width - 2 * margin, OutputBox.Height - 2 * margin);
var result = Voronoi.FindAll(points, bounds);
division = result.ToVoronoiSubdivision().Source;
}
_division = division;
_division.Validate();
_nearestEdge = -1;
_edges = DrawSubdivision(OutputBox, FontSize, division);
OutputBox.Children.Add(VertexCircle);
}
private void DrawSubdivision(Subdivision division)
{
// default to empty subdivision
if (division == null)
{
division = new Subdivision();
}
_division = division;
_division.Validate();
SubdivisionTest.DrawSubdivision(OutputBox, FontSize, division);
}
private SubdivisionSearch CheckSearch(params LineD[] lines)
{
Subdivision division = Subdivision.FromLines(lines);
division.Validate();
SubdivisionSearch search = new SubdivisionSearch(division);
search.Validate();
CheckVertices(search);
CheckEdges(search);
PointD[] points = new[] {
new PointD(+1, +1), new PointD(+1, -1),
new PointD(-1, +1), new PointD(-1, -1)
};
if (division.Faces.Count == 1)
{
foreach (PointD point in points)
{
Assert.IsTrue(search.Find(point).IsUnboundedFace);
Assert.IsTrue(division.Find(point).IsUnboundedFace);
}
}
else
{
var element = new SubdivisionElement(division.Faces[1]);
foreach (PointD point in points)
{
Assert.AreEqual(element, search.Find(point));
Assert.AreEqual(element, division.Find(point));
}
}
points = new[] {
new PointD(+10, +10), new PointD(+10, -10),
new PointD(-10, +10), new PointD(-10, -10)
};
foreach (PointD point in points)
{
Assert.IsTrue(search.Find(point).IsUnboundedFace);
Assert.IsTrue(division.Find(point).IsUnboundedFace);
}
return(search);
}
/// <summary>
/// Creates a random <see cref="Subdivision"/> with the specified number of full edges and
/// comparison epsilon.</summary>
/// <param name="size">
/// The number of full edges, i.e. half the number of <see cref="Subdivision.Edges"/>, in
/// the returned <see cref="Subdivision"/>.</param>
/// <param name="epsilon">
/// The maximum absolute difference at which two coordinates should be considered equal.
/// </param>
/// <returns>
/// A new random <see cref="Subdivision"/> with the specified <paramref name="size"/> and
/// <paramref name="epsilon"/>.</returns>
private static Subdivision CreateSubdivision(int size, double epsilon)
{
LineD[] lines = new LineD[size];
for (int i = 0; i < size; i++)
{
lines[i] = GeoAlgorithms.RandomLine(0, 0, 1000, 1000);
}
// split random set into non-intersecting line segments
var crossings = MultiLineIntersection.FindSimple(lines, epsilon);
var splitLines = MultiLineIntersection.Split(lines, crossings);
Array.Copy(splitLines, lines, size);
// re-randomize lines to eliminate split ordering
CollectionsUtility.Randomize(lines);
Subdivision division = Subdivision.FromLines(lines);
division.Validate();
return(division);
}
private void OnIntersect(object sender, RoutedEventArgs args)
{
args.Handled = true;
RectD bounds = OutputBounds;
double x = bounds.Left + (double)LeftUpDown.Value;
double y = bounds.Top + (double)TopUpDown.Value;
double dx = (double)WidthUpDown.Value;
double dy = (double)HeightUpDown.Value;
Subdivision rectangle;
if (sender == RectangleButton)
{
rectangle = Subdivision.FromLines(new LineD[] {
new LineD(x, y, x + dx, y),
new LineD(x + dx, y, x + dx, y + dy),
new LineD(x + dx, y + dy, x, y + dy),
new LineD(x, y + dy, x, y)
});
}
else if (sender == DiamondButton)
{
rectangle = Subdivision.FromLines(new LineD[] {
new LineD(x + dx / 2, y, x + dx, y + dy / 2),
new LineD(x + dx, y + dy / 2, x + dx / 2, y + dy),
new LineD(x + dx / 2, y + dy, x, y + dy / 2),
new LineD(x, y + dy / 2, x + dx / 2, y)
});
}
else
{
return;
}
rectangle.Validate();
_division = Subdivision.Intersection(_division, rectangle, out _faceKeys);
_division.Validate();
SubdivisionTest.DrawSubdivision(OutputBox, FontSize, _division);
}
private SubdivisionSearch CheckSearch(Subdivision division)
{
division.Validate();
SubdivisionSearch search = new SubdivisionSearch(division);
search.Validate();
CheckVertices(search);
CheckEdges(search);
foreach (SubdivisionFace face in division.Faces.Values)
{
if (face.OuterEdge == null)
{
continue;
}
PointD centroid = face.OuterEdge.CycleCentroid;
var element = new SubdivisionElement(face);
Assert.AreEqual(element, search.Find(centroid));
Assert.AreEqual(element, division.Find(centroid));
}
return(search);
}
public static Subdivision CreateTriforce(bool test)
{
PointD[] points =
{
new PointD(-5, -4), new PointD(0, 6), new PointD(5, -4),
new PointD(0, 0), new PointD(-1, 2), new PointD(1, 2)
};
LineD[] lines =
{
new LineD(points[0], points[1]), new LineD(points[2], points[1]),
new LineD(points[0], points[2]), new LineD(points[3], points[4]),
new LineD(points[3], points[5]), new LineD(points[4], points[5])
};
Subdivision division = Subdivision.FromLines(lines);
division.Validate();
if (!test)
{
return(division);
}
CollectionAssert.AreEquivalent(lines, division.ToLines());
var edges = division.Edges.Values;
var faces = division.Faces.Values;
CollectionAssert.AreEqual(new[] {
new VertexPair(points[0], edges[0]),
new VertexPair(points[2], edges[2]),
new VertexPair(points[3], edges[6]),
new VertexPair(points[4], edges[7]),
new VertexPair(points[5], edges[9]),
new VertexPair(points[1], edges[1]),
}, division.Vertices);
CollectionAssert.AreEqual(new[] {
new SubdivisionEdge(0, points[0], edges[1], faces[0], edges[3], edges[5]),
new SubdivisionEdge(1, points[1], edges[0], faces[1], edges[4], edges[2]),
new SubdivisionEdge(2, points[2], edges[3], faces[1], edges[1], edges[4]),
new SubdivisionEdge(3, points[1], edges[2], faces[0], edges[5], edges[0]),
new SubdivisionEdge(4, points[0], edges[5], faces[1], edges[2], edges[1]),
new SubdivisionEdge(5, points[2], edges[4], faces[0], edges[0], edges[3]),
new SubdivisionEdge(6, points[3], edges[7], faces[1], edges[10], edges[9]),
new SubdivisionEdge(7, points[4], edges[6], faces[2], edges[8], edges[11]),
new SubdivisionEdge(8, points[3], edges[9], faces[2], edges[11], edges[7]),
new SubdivisionEdge(9, points[5], edges[8], faces[1], edges[6], edges[10]),
new SubdivisionEdge(10, points[4], edges[11], faces[1], edges[9], edges[6]),
new SubdivisionEdge(11, points[5], edges[10], faces[2], edges[7], edges[8]),
}, edges);
CollectionAssert.AreEqual(new[] {
new SubdivisionFace(division, 0, null, new[] { edges[0] }),
new SubdivisionFace(division, 1, edges[1], new[] { edges[6] }),
new SubdivisionFace(division, 2, edges[7], null),
}, faces);
PointD centroid = new PointD(0, -2 / 3.0);
CheckFace(edges[0], new[] { points[0], points[1], points[2] }, -50, centroid);
CheckFace(edges[1], new[] { points[1], points[0], points[2] }, +50, centroid);
centroid = new PointD(0, 4 / 3.0);
CheckFace(edges[6], new[] { points[3], points[4], points[5] }, -2, centroid);
CheckFace(edges[7], new[] { points[4], points[3], points[5] }, +2, centroid);
var cycles = division.GetZeroAreaCycles();
Assert.AreEqual(0, cycles.Count);
return(division);
}
