public static IEnumerable <IPoint> LineIntersections(ILucidLine first, ILucidLine second, bool infinitLines = false)
{
var firstExtent = CalculateExtent(first);
var secondExtent = CalculateExtent(second);
if (infinitLines || GeometryHelper.Intersects(first, second))
{
foreach (var firstLine in from p in first.Vertices.TumblingWindow(2)
select new AlgebraicLine(p.First(), p.Last()))
{
foreach (var secondLine in from p in second.Vertices.TumblingWindow(2)
select new AlgebraicLine(p.First(), p.Last()))
{
var intersection = Intersection(firstLine, secondLine);
if (intersection != null && (infinitLines || (GeometryHelper.Intersects(intersection, firstExtent) && GeometryHelper.Intersects(intersection, secondExtent))))
{
yield return(intersection);
}
}
}
}
}
/// <summary>
/// Finds the largest angular gap between lines that all touch at a reference point
/// and returns the angle, in degrees, of a line passing through the reference point
/// that bisects that widest angle.
/// </summary>
/// <param name="referencePoint">The point of reference for calculating angles.</param>
/// <param name="lines">The lines to avoid</param>
/// <returns>An optimal angle for placment for a point</returns>
public static double GetPlacementAngleAvoidingExistingLines(IPoint referencePoint,
IEnumerable <IEnumerable <IPoint> > existingLines)
{
var lineAngles = new SortedList <double, double>();
foreach (var line in existingLines)
{
var lineVertices = line.ToList();
if (lineVertices.Count < 2)
{
continue;
}
var anglePoints = new List <IPoint>();
if (NearlyCoincident(referencePoint, lineVertices.First(), 0.001))
{
anglePoints.Add(lineVertices[1]);
}
else if (NearlyCoincident(referencePoint, lineVertices.Last(), 0.001))
{
anglePoints.Add(lineVertices[lineVertices.Count - 2]);
}
else
{
var vertices = lineVertices.SlidingWindow(3);
foreach (var window3 in vertices)
{
var v3 = window3.ToList();
if (NearlyCoincident(v3[1].AsVertex(), referencePoint.AsVertex(), 0.001))
{
anglePoints.Add(v3[0]);
anglePoints.Add(v3[2]);
}
}
}
var angles = anglePoints.Select(p => GeometryHelper.Angle(referencePoint, p));
// The angles so far are in the range (-Pi, Pi), but we need them normalized
// to the range (0, 2Pi).
angles = angles.Select(a => a >= 0 ? a : a + 2D * Math.PI);
foreach (var a in angles)
{
if (!lineAngles.ContainsKey(a))
{
lineAngles.Add(a, a);
}
}
}
// Special case: if there is only one line terminating on the reference point,
// then we will recommend placement at a 90 degree angle to that line.
if (lineAngles.Count == 1)
{
var perpendicularAngle = lineAngles.Keys[0] + 0.5 * Math.PI;
return(180D * perpendicularAngle / Math.PI);
}
// Find the bisector angle of the largest angular gap between adjacent line angles.
double bisectorAngle = 0;
double maxDiff = double.MinValue;
for (int i = 0; i < lineAngles.Count; i++)
{
var angle1 = lineAngles.Keys[i];
var angle2 = lineAngles.Keys[(i + 1) % lineAngles.Count];
if (IsPrettyMuchTheSame(angle1, angle2, 0.000001))
{
continue;
}
var diff = angle2 - angle1;
if (diff < 0)
{
diff = 2d * Math.PI + diff;
}
var bisector = angle1 + diff / 2.0D;
if (bisector > 2D * Math.PI)
{
bisector -= 2D * Math.PI;
}
if (diff > maxDiff)
{
maxDiff = diff;
bisectorAngle = bisector;
}
}
return(180D * bisectorAngle / Math.PI);
}
public static IEnumerable <ILucidGeometry> FindNearby(IEnumerable <IPoint> referencePoints, double distance, IEnumerable <ILucidGeometry> geometries, bool recursive = false)
{
var nearbyGeometries = (from g in geometries
let nearbyVertices = from v in g.Vertices
where referencePoints.Where(p => GeometryHelper.DistanceBetween(p, v) < distance).Any()
select v
where nearbyVertices.Any()
select g);
foreach (var geometry in nearbyGeometries)
{
yield return(geometry);
}
if (recursive && nearbyGeometries.Any())
{
foreach (var nearby in FindNearby(nearbyGeometries.SelectMany(g => g.Vertices), distance, geometries.Except(nearbyGeometries), recursive))
{
yield return(nearby);
}
}
}
public bool ExtentOverlaps(LucidPolygon other)
{
return(GeometryHelper.Intersects(this.AsExtent(), other.AsExtent()));
}
public ILucidExtent AsExtent()
{
return(GeometryHelper.CalculateExtent(this));
}
public ILucidExtent Buffer(double bufferSize)
{
return(GeometryHelper.Buffer(this, bufferSize));
}
