/// <summary>
/// Inserts a new site into the Subdivision, connecting it to the vertices of
/// the containing triangle (or quadrilateral, if the split point falls on an
/// existing edge).
/// </summary>
/// <remarks>
/// <para>
/// This method does NOT maintain the Delaunay condition. If desired, this must
/// be checked and enforced by the caller.
/// </para>
/// <para>
/// This method does NOT check if the inserted vertex falls on an edge. This
/// must be checked by the caller, since this situation may cause erroneous
/// triangulation
/// </para>
/// </remarks>
/// <param name="v">the vertex to insert</param>
/// <returns>a new quad edge terminating in v</returns>
public QuadEdge InsertSite(Vertex v)
{
var e = Locate(v);
if ((v.Equals(e.Orig, _tolerance)) || (v.Equals(e.Dest, _tolerance)))
{
return(e); // point already in subdivision.
}
// Connect the new point to the vertices of the containing
// triangle (or quadrilateral, if the new point fell on an
// existing edge.)
var baseQE = MakeEdge(e.Orig, v);
QuadEdge.Splice(baseQE, e);
var startEdge = baseQE;
do
{
baseQE = Connect(e, baseQE.Sym);
e = baseQE.OPrev;
} while (e.LNext != startEdge);
return(startEdge);
}
/// <summary>
/// Gets the Voronoi cell around a site specified
/// by the origin of a QuadEdge.
/// </summary>
/// <remarks>
/// The userData of the polygon is set to be the <see cref="Coordinate" />
/// of the site. This allows attaching external
/// data associated with the site to this cell polygon.
/// </remarks>
/// <param name="qe">a quadedge originating at the cell site</param>
/// <param name="geomFact">a factory for building the polygon</param>
/// <returns>a polygon indicating the cell extent</returns>
public Polygon GetVoronoiCellPolygon(QuadEdge qe, GeometryFactory geomFact)
{
var cellPts = new List <Coordinate>();
var startQE = qe;
do
{
// Coordinate cc = circumcentre(qe);
// use previously computed circumcentre
var cc = qe.Rot.Orig.Coordinate;
cellPts.Add(cc);
// move to next triangle CW around vertex
qe = qe.OPrev;
} while (qe != startQE);
var coordList = new CoordinateList();
coordList.AddAll(cellPts, false);
coordList.CloseRing();
if (coordList.Count < 4)
{
Debug.WriteLine(coordList);
coordList.Add(coordList[coordList.Count - 1], true);
}
var pts = coordList.ToCoordinateArray();
var cellPoly = geomFact.CreatePolygon(geomFact.CreateLinearRing(pts));
var v = startQE.Orig;
cellPoly.UserData = v.Coordinate;
return(cellPoly);
}
/// <summary>
/// Locates the edge between the given vertices, if it exists in the
/// subdivision.
/// </summary>
/// <param name="p0">a coordinate</param>
/// <param name="p1">another coordinate</param>
/// <returns>the edge joining the coordinates, if present,
/// or null if no such edge exists
/// </returns>
public QuadEdge Locate(Coordinate p0, Coordinate p1)
{
// find an edge containing one of the points
QuadEdge e = _locator.Locate(new Vertex(p0));
if (e == null)
{
return(null);
}
// normalize so that p0 is origin of base edge
QuadEdge baseQE = e;
if (e.Dest.Coordinate.Equals2D(p0))
{
baseQE = e.Sym;
}
// check all edges around origin of base edge
QuadEdge locEdge = baseQE;
do
{
if (locEdge.Dest.Coordinate.Equals2D(p1))
{
return(locEdge);
}
locEdge = locEdge.ONext;
} while (locEdge != baseQE);
return(null);
}
/// <summary>
/// Creates a new QuadEdge connecting the destination of a to the origin of b,
/// in such a way that all three have the same left face after the connection
/// is complete. The quadedge is recorded in the edges list.
/// </summary>
/// <param name="a">A quadedge</param>
/// <param name="b">A quadedge</param>
/// <returns>A quadedge</returns>
public QuadEdge Connect(QuadEdge a, QuadEdge b)
{
var q = QuadEdge.Connect(a, b);
_quadEdges.Add(q);
return(q);
}
/// <summary>
/// Creates a new quadedge, recording it in the edges list.
/// </summary>
/// <param name="o">The origin vertex</param>
/// <param name="d">The destination vertex</param>
/// <returns>A new quadedge</returns>
public QuadEdge MakeEdge(Vertex o, Vertex d)
{
var q = QuadEdge.MakeEdge(o, d);
_quadEdges.Add(q);
return(q);
}
/// <summary>
/// Creates a new QuadEdge connecting the destination of a to the origin of
/// b, in such a way that all three have the same left face after the
/// connection is complete. Additionally, the data pointers of the new edge
/// are set.
/// </summary>
/// <returns>the connected edge</returns>
public static QuadEdge Connect(QuadEdge a, QuadEdge b)
{
QuadEdge e = MakeEdge(a.Dest, b.Orig);
Splice(e, a.LNext);
Splice(e.Sym, b);
return e;
}
/// <summary>
/// Tests whether a QuadEdge is an edge on the border of the frame facets and
/// the internal facets. E.g. an edge which does not itself touch a frame
/// vertex, but which touches an edge which does.
/// </summary>
/// <param name="e">the edge to test</param>
/// <returns>true if the edge is on the border of the frame</returns>
public bool IsFrameBorderEdge(QuadEdge e)
{
// MD debugging
var leftTri = new QuadEdge[3];
GetTriangleEdges(e, leftTri);
// System.out.println(new QuadEdgeTriangle(leftTri).ToString());
var rightTri = new QuadEdge[3];
GetTriangleEdges(e.Sym, rightTri);
// System.out.println(new QuadEdgeTriangle(rightTri).ToString());
// check other vertex of triangle to left of edge
var vLeftTriOther = e.LNext.Dest;
if (IsFrameVertex(vLeftTriOther))
{
return(true);
}
// check other vertex of triangle to right of edge
var vRightTriOther = e.Sym.LNext.Dest;
if (IsFrameVertex(vRightTriOther))
{
return(true);
}
return(false);
}
/// <summary>
/// Gets all primary quadedges in the subdivision.
/// A primary edge is a <see cref="QuadEdge"/>
/// which occupies the 0'th position in its array of associated quadedges.
/// These provide the unique geometric edges of the triangulation.
/// </summary>
/// <param name="includeFrame">true if the frame edges are to be included</param>
/// <returns>a List of QuadEdges</returns>
public IList <QuadEdge> GetPrimaryEdges(bool includeFrame)
{
_visitedKey++;
var edges = new List <QuadEdge>();
var edgeStack = new Stack <QuadEdge>();
edgeStack.Push(_startingEdge);
var visitedEdges = new HashSet <QuadEdge>();
while (edgeStack.Count > 0)
{
var edge = edgeStack.Pop();
if (!visitedEdges.Contains(edge))
{
QuadEdge priQE = edge.GetPrimary();
if (includeFrame || !IsFrameEdge(priQE))
{
edges.Add(priQE);
}
edgeStack.Push(edge.ONext);
edgeStack.Push(edge.Sym.ONext);
visitedEdges.Add(edge);
visitedEdges.Add(edge.Sym);
}
}
return(edges);
}
/// <summary>
/// Tests whether a <see cref="Vertex"/> is the start or end vertex of a
/// <see cref="QuadEdge"/>, up to the subdivision tolerance distance.
/// </summary>
/// <param name="e" />
/// <param name="v" />
/// <returns>true if the vertex is a endpoint of the edge</returns>
public bool IsVertexOfEdge(QuadEdge e, Vertex v)
{
if ((v.Equals(e.Orig, _tolerance)) || (v.Equals(e.Dest, _tolerance)))
{
return(true);
}
return(false);
}
/// <summary>
/// Tests whether a QuadEdge is an edge incident on a frame triangle vertex.
/// </summary>
/// <param name="e">the edge to test</param>
/// <returns>true if the edge is connected to the frame triangle</returns>
public bool IsFrameEdge(QuadEdge e)
{
if (IsFrameVertex(e.Orig) || IsFrameVertex(e.Dest))
{
return(true);
}
return(false);
}
/// <summary>
/// Creates a new QuadEdge connecting the destination of a to the origin of
/// b, in such a way that all three have the same left face after the
/// connection is complete. Additionally, the data pointers of the new edge
/// are set.
/// </summary>
/// <returns>the connected edge</returns>
public static QuadEdge Connect(QuadEdge a, QuadEdge b)
{
var e = MakeEdge(a.Dest, b.Orig);
Splice(e, a.LNext);
Splice(e.Sym, b);
return(e);
}
/// <summary>
/// Gets the edges for the triangle to the left of the given <see cref="QuadEdge"/>.
/// </summary>
/// <param name="startQE" />
/// <param name="triEdge" />
/// <exception cref="ArgumentException">if the edges do not form a triangle</exception>
public static void GetTriangleEdges(QuadEdge startQE, QuadEdge[] triEdge)
{
triEdge[0] = startQE;
triEdge[1] = triEdge[0].LNext;
triEdge[2] = triEdge[1].LNext;
if (triEdge[2].LNext != triEdge[0])
throw new ArgumentException("Edges do not form a triangle");
}
/// <summary>
/// Tests whether a {@link Coordinate} lies on a {@link QuadEdge}, up to a
/// tolerance determined by the subdivision tolerance.
/// </summary>
/// <param name="e">a QuadEdge</param>
/// <param name="p">a point</param>
/// <returns>true if the vertex lies on the edge</returns>
public bool IsOnEdge(QuadEdge e, Coordinate p)
{
seg.SetCoordinates(e.Orig.Coordinate, e.Dest.Coordinate);
double dist = seg.Distance(p);
// heuristic (hack?)
return(dist < _edgeCoincidenceTolerance);
}
/// <summary>
/// Tests if this quadedge and another have the same line segment geometry
/// with the same orientation.
/// </summary>
/// <param name="qe">a quadege</param>
/// <returns>true if the quadedges are based on the same line segment</returns>
public bool EqualsOriented(QuadEdge qe)
{
if (Orig.Coordinate.Equals2D(qe.Orig.Coordinate) &&
Dest.Coordinate.Equals2D(qe.Dest.Coordinate))
{
return(true);
}
return(false);
}
/// <summary>
/// Creates a new triangle from the given edges.
/// </summary>
/// <param name="edge">An array of the edges of the triangle in CCW order</param>
public QuadEdgeTriangle(QuadEdge[] edge)
{
_edge = (QuadEdge[]) edge.Clone();
// link the quadedges back to this triangle
for (int i = 0; i < 3; i++)
{
edge[i].Data = this;
}
}
private static QuadEdge[] CopyOf(QuadEdge[] edge)
{
var res = new QuadEdge[edge.Length];
for (int i = 0; i < edge.Length; i++)
{
res[i] = edge[i];
}
return(res);
}
/// <summary>
/// Gets the edges for the triangle to the left of the given <see cref="QuadEdge"/>.
/// </summary>
/// <param name="startQE" />
/// <param name="triEdge" />
/// <exception cref="ArgumentException">if the edges do not form a triangle</exception>
public static void GetTriangleEdges(QuadEdge startQE, QuadEdge[] triEdge)
{
triEdge[0] = startQE;
triEdge[1] = triEdge[0].LNext;
triEdge[2] = triEdge[1].LNext;
if (triEdge[2].LNext != triEdge[0])
{
throw new ArgumentException("Edges do not form a triangle");
}
}
/// <summary>
/// Locates an edge of a triangle which contains a location
/// specified by a Vertex v.
/// The edge returned has the
/// property that either v is on e, or e is an edge of a triangle containing v.
/// The search starts from startEdge amd proceeds on the general direction of v.
/// </summary>
/// <remarks>
/// This locate algorithm relies on the subdivision being Delaunay. For
/// non-Delaunay subdivisions, this may loop for ever.
/// </remarks>
/// <param name="v">the location to search for</param>
/// <param name="startEdge">an edge of the subdivision to start searching at</param>
/// <returns>a QuadEdge which contains v, or is on the edge of a triangle containing v</returns>
/// <exception cref="LocateFailureException">
/// if the location algorithm fails to converge in a reasonable
/// number of iterations
/// </exception>
public QuadEdge LocateFromEdge(Vertex v, QuadEdge startEdge)
{
int iter = 0;
int maxIter = _quadEdges.Count;
var e = startEdge;
while (true)
{
iter++;
/*
* So far it has always been the case that failure to locate indicates an
* invalid subdivision. So just fail completely. (An alternative would be
* to perform an exhaustive search for the containing triangle, but this
* would mask errors in the subdivision topology)
*
* This can also happen if two vertices are located very close together,
* since the orientation predicates may experience precision failures.
*/
if (iter > maxIter)
{
throw new LocateFailureException(e.ToLineSegment());
// String msg = "Locate failed to converge (at edge: " + e + ").
// Possible causes include invalid Subdivision topology or very close
// sites";
// System.err.println(msg);
// dumpTriangles();
}
if ((v.Equals(e.Orig)) || (v.Equals(e.Dest)))
{
break;
}
if (v.RightOf(e))
{
e = e.Sym;
}
else if (!v.RightOf(e.ONext))
{
e = e.ONext;
}
else if (!v.RightOf(e.DPrev))
{
e = e.DPrev;
}
else
{
// on edge or in triangle containing edge
break;
}
}
// System.out.println("Locate count: " + iter);
return(e);
}
/// <summary>
/// Creates a new instance of a quad-edge subdivision based on a frame triangle
/// that encloses a supplied bounding box. A new super-bounding box that
/// contains the triangle is computed and stored.
/// </summary>
/// <param name="env">the bounding box to surround</param>
/// <param name="tolerance">the tolerance value for determining if two sites are equal</param>
public QuadEdgeSubdivision(Envelope env, double tolerance)
{
// currentSubdiv = this;
_tolerance = tolerance;
_edgeCoincidenceTolerance = tolerance / EdgeCoincidenceToleranceFactor;
CreateFrame(env);
_startingEdge = InitSubdiv();
_locator = new LastFoundQuadEdgeLocator(this);
}
/// <summary>
/// Creates a new instance of a quad-edge subdivision based on a frame triangle
/// that encloses a supplied bounding box. A new super-bounding box that
/// contains the triangle is computed and stored.
/// </summary>
/// <param name="env">the bouding box to surround</param>
/// <param name="tolerance">the tolerance value for determining if two sites are equal</param>
public QuadEdgeSubdivision(Envelope env, double tolerance)
{
// currentSubdiv = this;
_tolerance = tolerance;
_edgeCoincidenceTolerance = tolerance / EdgeCoincidenceToleranceFactor;
CreateFrame(env);
_startingEdge = InitSubdiv();
_locator = new LastFoundQuadEdgeLocator(this);
}
/// <summary>
/// Tests whether the point pt is contained in the triangle defined by 3 <see cref="QuadEdge"/>es.
/// </summary>
/// <param name="tri">an array containing at least 3 QuadEdges</param>
/// <param name="pt">the point to test</param>
/// <returns>true if the point is contained in the triangle</returns>
public static bool Contains(QuadEdge[] tri, Coordinate pt)
{
var ring = new[]
{
tri[0].Orig.Coordinate,
tri[1].Orig.Coordinate,
tri[2].Orig.Coordinate,
tri[0].Orig.Coordinate
};
return CGAlgorithms.IsPointInRing(pt, ring);
}
/// <summary>
/// Gets the index for the given edge of this triangle
/// </summary>
/// <param name="e">a QuadEdge</param>
/// <returns>the index of the edge in this triangle,<br/>
/// or -1 if the edge is not an edge of this triangle
/// </returns>
public int GetEdgeIndex(QuadEdge e)
{
for (int i = 0; i < 3; i++)
{
if (_edge[i] == e)
{
return(i);
}
}
return(-1);
}
/// <summary>
/// Tests if this quadedge and another have the same line segment geometry,
/// regardless of orientation.
/// </summary>
/// <param name="qe">a quadege</param>
/// <returns>true if the quadedges are based on the same line segment regardless of orientation</returns>
public bool EqualsNonOriented(QuadEdge qe)
{
if (EqualsOriented(qe))
{
return(true);
}
if (EqualsOriented(qe.Sym))
{
return(true);
}
return(false);
}
/// <summary>
/// Turns an edge counterclockwise inside its enclosing quadrilateral.
/// </summary>
/// <param name="e">the quadedge to turn</param>
public static void Swap(QuadEdge e)
{
var a = e.OPrev;
var b = e.Sym.OPrev;
Splice(e, a);
Splice(e.Sym, b);
Splice(e, a.LNext);
Splice(e.Sym, b.LNext);
e.Orig = a.Dest;
e.Dest = b.Dest;
}
/// <summary>
/// Gets all edges which are incident on the origin of the given edge.
/// </summary>
/// <param name="start">the edge to start at</param>
/// <returns>a List of edges which have their origin at the origin of the given
/// edge</returns>
public static IList<QuadEdge> FindEdgesIncidentOnOrigin(QuadEdge start)
{
var incEdge = new List<QuadEdge>();
QuadEdge qe = start;
do
{
incEdge.Add(qe);
qe = qe.ONext;
} while (qe != start);
return incEdge;
}
private QuadEdge InitSubdiv()
{
// build initial subdivision from frame
var ea = MakeEdge(_frameVertex[0], _frameVertex[1]);
var eb = MakeEdge(_frameVertex[1], _frameVertex[2]);
QuadEdge.Splice(ea.Sym, eb);
var ec = MakeEdge(_frameVertex[2], _frameVertex[0]);
QuadEdge.Splice(eb.Sym, ec);
QuadEdge.Splice(ec.Sym, ea);
return(ea);
}
/// <summary>
/// Gets all edges which are incident on the origin of the given edge.
/// </summary>
/// <param name="start">the edge to start at</param>
/// <returns>a List of edges which have their origin at the origin of the given
/// edge</returns>
public static IList <QuadEdge> FindEdgesIncidentOnOrigin(QuadEdge start)
{
var incEdge = new List <QuadEdge>();
QuadEdge qe = start;
do
{
incEdge.Add(qe);
qe = qe.ONext;
} while (qe != start);
return(incEdge);
}
/// <summary>
/// Splices two edges together or apart.
/// Splice affects the two edge rings around the origins of a and b, and, independently, the two
/// edge rings around the left faces of <tt>a</tt> and <tt>b</tt>.
/// In each case, (i) if the two rings are distinct,
/// Splice will combine them into one, or (ii) if the two are the same ring, Splice will break it
/// into two separate pieces. Thus, Splice can be used both to attach the two edges together, and
/// to break them apart.
/// </summary>
/// <param name="a">an edge to splice</param>
/// <param name="b">an edge to splice</param>
public static void Splice(QuadEdge a, QuadEdge b)
{
QuadEdge alpha = a.ONext.Rot;
QuadEdge beta = b.ONext.Rot;
QuadEdge t1 = b.ONext;
QuadEdge t2 = a.ONext;
QuadEdge t3 = beta.ONext;
QuadEdge t4 = alpha.ONext;
a.SetNext(t1);
b.SetNext(t2);
alpha.SetNext(t3);
beta.SetNext(t4);
}
/// <summary>
/// Splices two edges together or apart.
/// Splice affects the two edge rings around the origins of a and b, and, independently, the two
/// edge rings around the left faces of <tt>a</tt> and <tt>b</tt>.
/// In each case, (i) if the two rings are distinct,
/// Splice will combine them into one, or (ii) if the two are the same ring, Splice will break it
/// into two separate pieces. Thus, Splice can be used both to attach the two edges together, and
/// to break them apart.
/// </summary>
/// <param name="a">an edge to splice</param>
/// <param name="b">an edge to splice</param>
public static void Splice(QuadEdge a, QuadEdge b)
{
var alpha = a.ONext.Rot;
var beta = b.ONext.Rot;
var t1 = b.ONext;
var t2 = a.ONext;
var t3 = beta.ONext;
var t4 = alpha.ONext;
a.SetNext(t1);
b.SetNext(t2);
alpha.SetNext(t3);
beta.SetNext(t4);
}
/// <summary>
/// Splices two edges together or apart.
/// Splice affects the two edge rings around the origins of a and b, and, independently, the two
/// edge rings around the left faces of <tt>a</tt> and <tt>b</tt>.
/// In each case, (i) if the two rings are distinct,
/// Splice will combine them into one, or (ii) if the two are the same ring, Splice will break it
/// into two separate pieces. Thus, Splice can be used both to attach the two edges together, and
/// to break them apart.
/// </summary>
/// <param name="a">an edge to splice</param>
/// <param name="b">an edge to splice</param>
public static void Splice(QuadEdge a, QuadEdge b)
{
QuadEdge alpha = a.ONext.Rot;
QuadEdge beta = b.ONext.Rot;
QuadEdge t1 = b.ONext;
QuadEdge t2 = a.ONext;
QuadEdge t3 = beta.ONext;
QuadEdge t4 = alpha.ONext;
a.SetNext(t1);
b.SetNext(t2);
alpha.SetNext(t3);
beta.SetNext(t4);
}
/// <summary>
/// Deletes a quadedge from the subdivision. Linked quadedges are updated to
/// reflect the deletion.
/// </summary>
/// <param name="e">the quadedge to delete</param>
public void Delete(QuadEdge e)
{
QuadEdge.Splice(e, e.OPrev);
QuadEdge.Splice(e.Sym, e.Sym.OPrev);
var eSym = e.Sym;
var eRot = e.Rot;
var eRotSym = e.Rot.Sym;
// this is inefficient on an ArrayList, but this method should be called infrequently
_quadEdges.Remove(e);
_quadEdges.Remove(eSym);
_quadEdges.Remove(eRot);
_quadEdges.Remove(eRotSym);
e.Delete();
eSym.Delete();
eRot.Delete();
eRotSym.Delete();
}
/// <summary>
/// Gets the triangles which are adjacent (include) to a
/// given vertex of this triangle.
/// </summary>
/// <param name="vertexIndex">The vertex to query</param>
/// <returns>A list of the vertex-adjacent triangles</returns>
public IList <QuadEdgeTriangle> GetTrianglesAdjacentToVertex(int vertexIndex)
{
// Assert: isVertex
var adjTris = new List <QuadEdgeTriangle>();
QuadEdge start = GetEdge(vertexIndex);
QuadEdge qe = start;
do
{
var adjTri = (QuadEdgeTriangle)qe.Data;
if (adjTri != null)
{
adjTris.Add(adjTri);
}
qe = qe.ONext;
} while (qe != start);
return(adjTris);
}
/// <summary>
/// Creates a new QuadEdge quartet from <see cref="Vertex"/>o to <see cref="Vertex"/> d.
/// </summary>
/// <param name="o">the origin Vertex</param>
/// <param name="d">the destination Vertex</param>
/// <returns>the new QuadEdge quartet</returns>
public static QuadEdge MakeEdge(Vertex o, Vertex d)
{
QuadEdge q0 = new QuadEdge();
QuadEdge q1 = new QuadEdge();
QuadEdge q2 = new QuadEdge();
QuadEdge q3 = new QuadEdge();
q0.Rot = q1;
q1.Rot = q2;
q2.Rot = q3;
q3.Rot = q0;
q0.SetNext(q0);
q1.SetNext(q3);
q2.SetNext(q2);
q3.SetNext(q1);
QuadEdge baseQE = q0;
baseQE.Orig = o;
baseQE.Dest = d;
return baseQE;
}
/// <summary>
/// Creates a new QuadEdge quartet from <see cref="Vertex"/>o to <see cref="Vertex"/> d.
/// </summary>
/// <param name="o">the origin Vertex</param>
/// <param name="d">the destination Vertex</param>
/// <returns>the new QuadEdge quartet</returns>
public static QuadEdge MakeEdge(Vertex o, Vertex d)
{
var q0 = new QuadEdge();
var q1 = new QuadEdge();
var q2 = new QuadEdge();
var q3 = new QuadEdge();
q0.Rot = q1;
q1.Rot = q2;
q2.Rot = q3;
q3.Rot = q0;
q0.SetNext(q0);
q1.SetNext(q3);
q2.SetNext(q2);
q3.SetNext(q1);
var baseQE = q0;
baseQE.Orig = o;
baseQE.Dest = d;
return(baseQE);
}
/// <summary>
/// Gets a collection of <see cref="QuadEdge"/>s whose origin
/// vertices are a unique set which includes
/// all vertices in the subdivision.
/// The frame vertices can be included if required.
/// </summary>
/// <remarks>
/// This is useful for algorithms which require traversing the
/// subdivision starting at all vertices.
/// Returning a quadedge for each vertex
/// is more efficient than
/// the alternative of finding the actual vertices
/// using <see cref="GetVertices"/> and then locating
/// quadedges attached to them.
/// </remarks>
/// <param name="includeFrame">true if the frame vertices should be included</param>
/// <returns>a collection of QuadEdge with the vertices of the subdivision as their origins</returns>
public IList <QuadEdge> GetVertexUniqueEdges(bool includeFrame)
{
var edges = new List <QuadEdge>();
var visitedVertices = new HashSet <Vertex>();
foreach (var qe in _quadEdges)
{
Vertex v = qe.Orig;
//System.out.println(v);
if (!visitedVertices.Contains(v))
{
visitedVertices.Add(v);
if (includeFrame || !IsFrameVertex(v))
{
edges.Add(qe);
}
}
/*
* Inspect the sym edge as well, since it is
* possible that a vertex is only at the
* dest of all tracked quadedges.
*/
QuadEdge qd = qe.Sym;
Vertex vd = qd.Orig;
//System.out.println(vd);
if (!visitedVertices.Contains(vd))
{
visitedVertices.Add(vd);
if (includeFrame || !IsFrameVertex(vd))
{
edges.Add(qd);
}
}
}
return(edges);
}
/// <summary>
/// Stores the edges for a visited triangle. Also pushes sym (neighbour) edges
/// on stack to visit later.
/// </summary>
/// <param name="edge" />
/// <param name="edgeStack" />
/// <param name="includeFrame" />
/// <param name="visitedEdges"></param>
/// <returns>the visited triangle edges,<br/>
/// or <c>null</c> if the triangle should not be visited (for instance, if it is outer)
/// </returns>
private QuadEdge[] FetchTriangleToVisit(QuadEdge edge, Stack <QuadEdge> edgeStack, bool includeFrame,
HashSet <QuadEdge> visitedEdges)
{
var curr = edge;
int edgeCount = 0;
bool isFrame = false;
do
{
_triEdges[edgeCount] = curr;
if (IsFrameEdge(curr))
{
isFrame = true;
}
// push sym edges to visit next
var sym = curr.Sym;
if (!visitedEdges.Contains(sym))
{
edgeStack.Push(sym);
}
// mark this edge as visited
visitedEdges.Add(curr);
edgeCount++;
curr = curr.LNext;
} while (curr != edge);
if (isFrame && !includeFrame)
{
return(null);
}
return(_triEdges);
}
/// <summary>
/// Tests if this quadedge and another have the same line segment geometry
/// with the same orientation.
/// </summary>
/// <param name="qe">a quadege</param>
/// <returns>true if the quadedges are based on the same line segment</returns>
public bool EqualsOriented(QuadEdge qe)
{
if (Orig.Coordinate.Equals2D(qe.Orig.Coordinate)
&& Dest.Coordinate.Equals2D(qe.Dest.Coordinate))
return true;
return false;
}
/// <summary>
/// Tests whether a QuadEdge is an edge incident on a frame triangle vertex.
/// </summary>
/// <param name="e">the edge to test</param>
/// <returns>true if the edge is connected to the frame triangle</returns>
public bool IsFrameEdge(QuadEdge e)
{
if (IsFrameVertex(e.Orig) || IsFrameVertex(e.Dest))
return true;
return false;
}
/// <summary>
/// Gets the index for the given edge of this triangle
/// </summary>
/// <param name="e">a QuadEdge</param>
/// <returns>the index of the edge in this triangle,<br/>
/// or -1 if the edge is not an edge of this triangle
/// </returns>
public int GetEdgeIndex(QuadEdge e)
{
for (int i = 0; i < 3; i++)
{
if (_edge[i] == e)
return i;
}
return -1;
}
//public QuadEdgeTriangleBuilderVisitor() { }
public void Visit(QuadEdge[] edges)
{
_triangles.Add(new QuadEdgeTriangle(edges));
}
public void Visit(QuadEdge[] triEdges)
{
_triList.Add(new[] { triEdges[0].Orig, triEdges[1].Orig,
triEdges[2].Orig });
}
/// <summary>
/// Deletes a quadedge from the subdivision. Linked quadedges are updated to
/// reflect the deletion.
/// </summary>
/// <param name="e">the quadedge to delete</param>
public void Delete(QuadEdge e)
{
QuadEdge.Splice(e, e.OPrev);
QuadEdge.Splice(e.Sym, e.Sym.OPrev);
QuadEdge eSym = e.Sym;
QuadEdge eRot = e.Rot;
QuadEdge eRotSym = e.Rot.Sym;
// this is inefficient on an ArrayList, but this method should be called infrequently
_quadEdges.Remove(e);
_quadEdges.Remove(eSym);
_quadEdges.Remove(eRot);
_quadEdges.Remove(eRotSym);
e.Delete();
eSym.Delete();
eRot.Delete();
eRotSym.Delete();
}
/// <summary>
/// Tests if this quadedge and another have the same line segment geometry,
/// regardless of orientation.
/// </summary>
/// <param name="qe">a quadege</param>
/// <returns>true if the quadedges are based on the same line segment regardless of orientation</returns>
public bool EqualsNonOriented(QuadEdge qe)
{
if (EqualsOriented(qe))
return true;
if (EqualsOriented(qe.Sym))
return true;
return false;
}
/// <summary>
/// Stores the edges for a visited triangle. Also pushes sym (neighbour) edges
/// on stack to visit later.
/// </summary>
/// <param name="edge" />
/// <param name="edgeStack" />
/// <param name="includeFrame" />
/// <param name="visitedEdges"></param>
/// <returns>the visited triangle edges,<br/>
/// or <value>null</value> if the triangle should not be visited (for instance, if it is outer)
/// </returns>
private QuadEdge[] FetchTriangleToVisit(QuadEdge edge, Stack<QuadEdge> edgeStack, bool includeFrame,
ISet visitedEdges)
{
QuadEdge curr = edge;
int edgeCount = 0;
bool isFrame = false;
do
{
_triEdges[edgeCount] = curr;
if (IsFrameEdge(curr))
isFrame = true;
// push sym edges to visit next
QuadEdge sym = curr.Sym;
if (!visitedEdges.Contains(sym))
edgeStack.Push(sym);
// mark this edge as visited
visitedEdges.Add(curr);
edgeCount++;
curr = curr.LNext;
} while (curr != edge);
if (isFrame && !includeFrame)
return null;
return _triEdges;
}
public void Visit(QuadEdge[] triEdges)
{
var a = triEdges[0].Orig.Coordinate;
var b = triEdges[1].Orig.Coordinate;
var c = triEdges[2].Orig.Coordinate;
// TODO: choose the most accurate circumcentre based on the edges
var cc = Triangle.Circumcentre(a, b, c);
var ccVertex = new Vertex(cc);
// save the circumcentre as the origin for the dual edges originating in this triangle
for (var i = 0; i < 3; i++)
{
triEdges[i].Rot.Orig = ccVertex;
}
}
public void Visit(QuadEdge[] triEdges)
{
_triList.Add((QuadEdge[])triEdges.Clone());
}
public void Visit(QuadEdge[] triEdges)
{
_coordList.Clear();
for (int i = 0; i < 3; i++)
{
var v = triEdges[i].Orig;
_coordList.Add(v.Coordinate);
}
if (_coordList.Count > 0)
{
_coordList.CloseRing();
var pts = _coordList.ToCoordinateArray();
if (pts.Length != 4)
{
//CheckTriangleSize(pts);
return;
}
_triCoords.Add(pts);
}
}
/// <summary>
/// Tests whether a QuadEdge is an edge on the border of the frame facets and
/// the internal facets. E.g. an edge which does not itself touch a frame
/// vertex, but which touches an edge which does.
/// </summary>
/// <param name="e">the edge to test</param>
/// <returns>true if the edge is on the border of the frame</returns>
public bool IsFrameBorderEdge(QuadEdge e)
{
// MD debugging
QuadEdge[] leftTri = new QuadEdge[3];
GetTriangleEdges(e, leftTri);
// System.out.println(new QuadEdgeTriangle(leftTri).toString());
QuadEdge[] rightTri = new QuadEdge[3];
GetTriangleEdges(e.Sym, rightTri);
// System.out.println(new QuadEdgeTriangle(rightTri).toString());
// check other vertex of triangle to left of edge
Vertex vLeftTriOther = e.LNext.Dest;
if (IsFrameVertex(vLeftTriOther))
return true;
// check other vertex of triangle to right of edge
Vertex vRightTriOther = e.Sym.LNext.Dest;
if (IsFrameVertex(vRightTriOther))
return true;
return false;
}
/// <summary>
/// Gets the Voronoi cell around a site specified
/// by the origin of a QuadEdge.
/// </summary>
/// <remarks>
/// The userData of the polygon is set to be the <see cref="Coordinate" />
/// of the site. This allows attaching external
/// data associated with the site to this cell polygon.
/// </remarks>
/// <param name="qe">a quadedge originating at the cell site</param>
/// <param name="geomFact">a factory for building the polygon</param>
/// <returns>a polygon indicating the cell extent</returns>
public IPolygon GetVoronoiCellPolygon(QuadEdge qe, IGeometryFactory geomFact)
{
var cellPts = new List<Coordinate>();
QuadEdge startQE = qe;
do
{
// Coordinate cc = circumcentre(qe);
// use previously computed circumcentre
Coordinate cc = qe.Rot.Orig.Coordinate;
cellPts.Add(cc);
// move to next triangle CW around vertex
qe = qe.OPrev;
} while (qe != startQE);
var coordList = new CoordinateList();
coordList.AddAll(cellPts, false);
coordList.CloseRing();
if (coordList.Count < 4)
{
#if !PCL
Debug.WriteLine(coordList);
#endif
coordList.Add(coordList[coordList.Count - 1], true);
}
Coordinate[] pts = coordList.ToCoordinateArray();
IPolygon cellPoly = geomFact.CreatePolygon(geomFact.CreateLinearRing(pts), null);
Vertex v = startQE.Orig;
cellPoly.UserData = v.Coordinate;
return cellPoly;
}
/// <summary
/// Turns an edge counterclockwise inside its enclosing quadrilateral.
/// </summary>
/// <param name="e">the quadedge to turn</param>
public static void Swap(QuadEdge e)
{
QuadEdge a = e.OPrev;
QuadEdge b = e.Sym.OPrev;
Splice(e, a);
Splice(e.Sym, b);
Splice(e, a.LNext);
Splice(e.Sym, b.LNext);
e.Orig = a.Dest;
e.Dest = b.Dest;
}
/// <summary>
/// Creates a new QuadEdge connecting the destination of a to the origin of b,
/// in such a way that all three have the same left face after the connection
/// is complete. The quadedge is recorded in the edges list.
/// </summary>
/// <param name="a">A quadedge</param>
/// <param name="b">A quadedge</param>
/// <returns>A quadedge</returns>
public QuadEdge Connect(QuadEdge a, QuadEdge b)
{
QuadEdge q = QuadEdge.Connect(a, b);
_quadEdges.Add(q);
return q;
}
/// <summary>
/// Locates an edge of a triangle which contains a location
/// specified by a Vertex v.
/// The edge returned has the
/// property that either v is on e, or e is an edge of a triangle containing v.
/// The search starts from startEdge amd proceeds on the general direction of v.
/// </summary>
/// <remarks>
/// This locate algorithm relies on the subdivision being Delaunay. For
/// non-Delaunay subdivisions, this may loop for ever.
/// </remarks>
/// <param name="v">the location to search for</param>
/// <param name="startEdge">an edge of the subdivision to start searching at</param>
/// <returns>a QuadEdge which contains v, or is on the edge of a triangle containing v</returns>
/// <exception cref="LocateFailureException">
/// if the location algorithm fails to converge in a reasonable
/// number of iterations
/// </exception>
public QuadEdge LocateFromEdge(Vertex v, QuadEdge startEdge)
{
int iter = 0;
int maxIter = _quadEdges.Count;
QuadEdge e = startEdge;
while (true)
{
iter++;
/*
* So far it has always been the case that failure to locate indicates an
* invalid subdivision. So just fail completely. (An alternative would be
* to perform an exhaustive search for the containing triangle, but this
* would mask errors in the subdivision topology)
*
* This can also happen if two vertices are located very close together,
* since the orientation predicates may experience precision failures.
*/
if (iter > maxIter)
{
throw new LocateFailureException(e.ToLineSegment());
// String msg = "Locate failed to converge (at edge: " + e + ").
// Possible causes include invalid Subdivision topology or very close
// sites";
// System.err.println(msg);
// dumpTriangles();
}
if ((v.Equals(e.Orig)) || (v.Equals(e.Dest)))
{
break;
}
if (v.RightOf(e))
{
e = e.Sym;
}
else if (!v.RightOf(e.ONext))
{
e = e.ONext;
}
else if (!v.RightOf(e.DPrev))
{
e = e.DPrev;
}
else
{
// on edge or in triangle containing edge
break;
}
}
// System.out.println("Locate count: " + iter);
return e;
}
public static IGeometry ToPolygon(QuadEdge[] e)
{
var ringPts = new[]
{
e[0].Orig.Coordinate,
e[1].Orig.Coordinate,
e[2].Orig.Coordinate,
e[0].Orig.Coordinate
};
var fact = new GeometryFactory();
ILinearRing ring = fact.CreateLinearRing(ringPts);
IPolygon tri = fact.CreatePolygon(ring, null);
return tri;
}
/// <summary>
/// Tests whether a <see cref="Vertex"/> is the start or end vertex of a
/// <see cref="QuadEdge"/>, up to the subdivision tolerance distance.
/// </summary>
/// <param name="e" />
/// <param name="v" />
/// <returns>true if the vertex is a endpoint of the edge</returns>
public bool IsVertexOfEdge(QuadEdge e, Vertex v)
{
if ((v.Equals(e.Orig, _tolerance)) || (v.Equals(e.Dest, _tolerance)))
{
return true;
}
return false;
}
/// <summary>
/// Sets the connected edge
/// </summary>
/// <param name="next">edge</param>
public void SetNext(QuadEdge next)
{
_next = next;
}
/// <summary>
/// Tests whether a {@link Coordinate} lies on a {@link QuadEdge}, up to a
/// tolerance determined by the subdivision tolerance.
/// </summary>
/// <param name="e">a QuadEdge</param>
/// <param name="p">a point</param>
/// <returns>true if the vertex lies on the edge</returns>
public bool IsOnEdge(QuadEdge e, Coordinate p)
{
seg.SetCoordinates(e.Orig.Coordinate, e.Dest.Coordinate);
double dist = seg.Distance(p);
// heuristic (hack?)
return dist < _edgeCoincidenceTolerance;
}
private bool LeftOf(QuadEdge e)
{
return(IsCcw(e.Orig, e.Dest));
}
/// <summary>
/// Sets the connected edge
/// </summary>
/// <param name="next">edge</param>
public void SetNext(QuadEdge next)
{
_next = next;
}