// -----------------------------------------------------------------------
//
// Original Triangle code by Jonathan Richard Shewchuk, http://www.cs.cmu.edu/~quake/triangle.html
// Triangle.NET code by Christian Woltering, http://triangle.codeplex.com/
//
// -----------------------------------------------------------------------
namespace UnityEngine.U2D.Animation.TriangleNet
.Meshing
{
using System;
using System.Collections.Generic;
using Animation.TriangleNet.Geometry;
using Animation.TriangleNet.Logging;
using Animation.TriangleNet.Meshing.Iterators;
using Animation.TriangleNet.Topology;
internal class ConstraintMesher
{
IPredicates predicates;
Mesh mesh;
Behavior behavior;
TriangleLocator locator;
List viri;
ILog logger;
public ConstraintMesher(Mesh mesh, Configuration config)
{
this.mesh = mesh;
this.predicates = config.Predicates();
this.behavior = mesh.behavior;
this.locator = mesh.locator;
this.viri = new List();
logger = Log.Instance;
}
///
/// Insert segments into the mesh.
///
/// The polygon.
/// Constraint options.
public void Apply(IPolygon input, ConstraintOptions options)
{
behavior.Poly = input.Segments.Count > 0;
// Copy constraint options
if (options != null)
{
behavior.ConformingDelaunay = options.ConformingDelaunay;
behavior.Convex = options.Convex;
behavior.NoBisect = options.SegmentSplitting;
if (behavior.ConformingDelaunay)
{
behavior.Quality = true;
}
}
//if (input.EdgeMarkers != null)
//{
// behavior.UseBoundaryMarkers = true;
//}
behavior.useRegions = input.Regions.Count > 0;
// Ensure that no vertex can be mistaken for a triangular bounding
// box vertex in insertvertex().
mesh.infvertex1 = null;
mesh.infvertex2 = null;
mesh.infvertex3 = null;
if (behavior.useSegments)
{
// Segments will be introduced next.
mesh.checksegments = true;
// Insert PSLG segments and/or convex hull segments.
FormSkeleton(input);
}
if (behavior.Poly && (mesh.triangles.Count > 0))
{
// Copy holes and regions
mesh.holes.AddRange(input.Holes);
mesh.regions.AddRange(input.Regions);
// Carve out holes and concavities.
CarveHoles();
}
}
///
/// Find the holes and infect them. Find the area constraints and infect
/// them. Infect the convex hull. Spread the infection and kill triangles.
/// Spread the area constraints.
///
private void CarveHoles()
{
Otri searchtri = default(Otri);
Vertex searchorg, searchdest;
LocateResult intersect;
Triangle[] regionTris = null;
var dummytri = mesh.dummytri;
if (!mesh.behavior.Convex)
{
// Mark as infected any unprotected triangles on the boundary.
// This is one way by which concavities are created.
InfectHull();
}
if (!mesh.behavior.NoHoles)
{
// Infect each triangle in which a hole lies.
foreach (var hole in mesh.holes)
{
// Ignore holes that aren't within the bounds of the mesh.
if (mesh.bounds.Contains(hole))
{
// Start searching from some triangle on the outer boundary.
searchtri.tri = dummytri;
searchtri.orient = 0;
searchtri.Sym();
// Ensure that the hole is to the left of this boundary edge;
// otherwise, locate() will falsely report that the hole
// falls within the starting triangle.
searchorg = searchtri.Org();
searchdest = searchtri.Dest();
if (predicates.CounterClockwise(searchorg, searchdest, hole) > 0.0)
{
// Find a triangle that contains the hole.
intersect = mesh.locator.Locate(hole, ref searchtri);
if ((intersect != LocateResult.Outside) && (!searchtri.IsInfected()))
{
// Infect the triangle. This is done by marking the triangle
// as infected and including the triangle in the virus pool.
searchtri.Infect();
viri.Add(searchtri.tri);
}
}
}
}
}
// Now, we have to find all the regions BEFORE we carve the holes, because locate() won't
// work when the triangulation is no longer convex. (Incidentally, this is the reason why
// regional attributes and area constraints can't be used when refining a preexisting mesh,
// which might not be convex; they can only be used with a freshly triangulated PSLG.)
if (mesh.regions.Count > 0)
{
int i = 0;
regionTris = new Triangle[mesh.regions.Count];
// Find the starting triangle for each region.
foreach (var region in mesh.regions)
{
regionTris[i] = dummytri;
// Ignore region points that aren't within the bounds of the mesh.
if (mesh.bounds.Contains(region.point))
{
// Start searching from some triangle on the outer boundary.
searchtri.tri = dummytri;
searchtri.orient = 0;
searchtri.Sym();
// Ensure that the region point is to the left of this boundary
// edge; otherwise, locate() will falsely report that the
// region point falls within the starting triangle.
searchorg = searchtri.Org();
searchdest = searchtri.Dest();
if (predicates.CounterClockwise(searchorg, searchdest, region.point) > 0.0)
{
// Find a triangle that contains the region point.
intersect = mesh.locator.Locate(region.point, ref searchtri);
if ((intersect != LocateResult.Outside) && (!searchtri.IsInfected()))
{
// Record the triangle for processing after the
// holes have been carved.
regionTris[i] = searchtri.tri;
regionTris[i].label = region.id;
regionTris[i].area = region.area;
}
}
}
i++;
}
}
if (viri.Count > 0)
{
// Carve the holes and concavities.
Plague();
}
if (regionTris != null)
{
var iterator = new RegionIterator(mesh);
for (int i = 0; i < regionTris.Length; i++)
{
if (regionTris[i].id != Mesh.DUMMY)
{
// Make sure the triangle under consideration still exists.
// It may have been eaten by the virus.
if (!Otri.IsDead(regionTris[i]))
{
// Apply one region's attribute and/or area constraint.
iterator.Process(regionTris[i]);
}
}
}
}
// Free up memory (virus pool should be empty anyway).
viri.Clear();
}
///
/// Create the segments of a triangulation, including PSLG segments and edges
/// on the convex hull.
///
private void FormSkeleton(IPolygon input)
{
// The segment endpoints.
Vertex p, q;
mesh.insegments = 0;
if (behavior.Poly)
{
// If the input vertices are collinear, there is no triangulation,
// so don't try to insert segments.
if (mesh.triangles.Count == 0)
{
return;
}
// If segments are to be inserted, compute a mapping
// from vertices to triangles.
if (input.Segments.Count > 0)
{
mesh.MakeVertexMap();
}
// Read and insert the segments.
foreach (var seg in input.Segments)
{
mesh.insegments++;
p = seg.GetVertex(0);
q = seg.GetVertex(1);
if ((p.x == q.x) && (p.y == q.y))
{
if (Log.Verbose)
{
logger.Warning("Endpoints of segment (IDs " + p.id + "/" + q.id + ") are coincident.",
"Mesh.FormSkeleton()");
}
}
else
{
InsertSegment(p, q, seg.Label);
}
}
}
if (behavior.Convex || !behavior.Poly)
{
// Enclose the convex hull with subsegments.
MarkHull();
}
}
#region Carving holes
///
/// Virally infect all of the triangles of the convex hull that are not
/// protected by subsegments. Where there are subsegments, set boundary
/// markers as appropriate.
///
private void InfectHull()
{
Otri hulltri = default(Otri);
Otri nexttri = default(Otri);
Otri starttri = default(Otri);
Osub hullsubseg = default(Osub);
Vertex horg, hdest;
var dummytri = mesh.dummytri;
// Find a triangle handle on the hull.
hulltri.tri = dummytri;
hulltri.orient = 0;
hulltri.Sym();
// Remember where we started so we know when to stop.
hulltri.Copy(ref starttri);
// Go once counterclockwise around the convex hull.
do
{
// Ignore triangles that are already infected.
if (!hulltri.IsInfected())
{
// Is the triangle protected by a subsegment?
hulltri.Pivot(ref hullsubseg);
if (hullsubseg.seg.hash == Mesh.DUMMY)
{
// The triangle is not protected; infect it.
if (!hulltri.IsInfected())
{
hulltri.Infect();
viri.Add(hulltri.tri);
}
}
else
{
// The triangle is protected; set boundary markers if appropriate.
if (hullsubseg.seg.boundary == 0)
{
hullsubseg.seg.boundary = 1;
horg = hulltri.Org();
hdest = hulltri.Dest();
if (horg.label == 0)
{
horg.label = 1;
}
if (hdest.label == 0)
{
hdest.label = 1;
}
}
}
}
// To find the next hull edge, go clockwise around the next vertex.
hulltri.Lnext();
hulltri.Oprev(ref nexttri);
while (nexttri.tri.id != Mesh.DUMMY)
{
nexttri.Copy(ref hulltri);
hulltri.Oprev(ref nexttri);
}
}
while (!hulltri.Equals(starttri));
}
///
/// Spread the virus from all infected triangles to any neighbors not
/// protected by subsegments. Delete all infected triangles.
///
///
/// This is the procedure that actually creates holes and concavities.
///
/// This procedure operates in two phases. The first phase identifies all
/// the triangles that will die, and marks them as infected. They are
/// marked to ensure that each triangle is added to the virus pool only
/// once, so the procedure will terminate.
///
/// The second phase actually eliminates the infected triangles. It also
/// eliminates orphaned vertices.
///
void Plague()
{
Otri testtri = default(Otri);
Otri neighbor = default(Otri);
Osub neighborsubseg = default(Osub);
Vertex testvertex;
Vertex norg, ndest;
var dummysub = mesh.dummysub;
var dummytri = mesh.dummytri;
bool killorg;
// Loop through all the infected triangles, spreading the virus to
// their neighbors, then to their neighbors' neighbors.
for (int i = 0; i < viri.Count; i++)
{
// WARNING: Don't use foreach, mesh.viri list may get modified.
testtri.tri = viri[i];
// A triangle is marked as infected by messing with one of its pointers
// to subsegments, setting it to an illegal value. Hence, we have to
// temporarily uninfect this triangle so that we can examine its
// adjacent subsegments.
// TODO: Not true in the C# version (so we could skip this).
testtri.Uninfect();
// Check each of the triangle's three neighbors.
for (testtri.orient = 0; testtri.orient < 3; testtri.orient++)
{
// Find the neighbor.
testtri.Sym(ref neighbor);
// Check for a subsegment between the triangle and its neighbor.
testtri.Pivot(ref neighborsubseg);
// Check if the neighbor is nonexistent or already infected.
if ((neighbor.tri.id == Mesh.DUMMY) || neighbor.IsInfected())
{
if (neighborsubseg.seg.hash != Mesh.DUMMY)
{
// There is a subsegment separating the triangle from its
// neighbor, but both triangles are dying, so the subsegment
// dies too.
mesh.SubsegDealloc(neighborsubseg.seg);
if (neighbor.tri.id != Mesh.DUMMY)
{
// Make sure the subsegment doesn't get deallocated again
// later when the infected neighbor is visited.
neighbor.Uninfect();
neighbor.SegDissolve(dummysub);
neighbor.Infect();
}
}
}
else
{ // The neighbor exists and is not infected.
if (neighborsubseg.seg.hash == Mesh.DUMMY)
{
// There is no subsegment protecting the neighbor, so
// the neighbor becomes infected.
neighbor.Infect();
// Ensure that the neighbor's neighbors will be infected.
viri.Add(neighbor.tri);
}
else
{
// The neighbor is protected by a subsegment.
// Remove this triangle from the subsegment.
neighborsubseg.TriDissolve(dummytri);
// The subsegment becomes a boundary. Set markers accordingly.
if (neighborsubseg.seg.boundary == 0)
{
neighborsubseg.seg.boundary = 1;
}
norg = neighbor.Org();
ndest = neighbor.Dest();
if (norg.label == 0)
{
norg.label = 1;
}
if (ndest.label == 0)
{
ndest.label = 1;
}
}
}
}
// Remark the triangle as infected, so it doesn't get added to the
// virus pool again.
testtri.Infect();
}
foreach (var virus in viri)
{
testtri.tri = virus;
// Check each of the three corners of the triangle for elimination.
// This is done by walking around each vertex, checking if it is
// still connected to at least one live triangle.
for (testtri.orient = 0; testtri.orient < 3; testtri.orient++)
{
testvertex = testtri.Org();
// Check if the vertex has already been tested.
if (testvertex != null)
{
killorg = true;
// Mark the corner of the triangle as having been tested.
testtri.SetOrg(null);
// Walk counterclockwise about the vertex.
testtri.Onext(ref neighbor);
// Stop upon reaching a boundary or the starting triangle.
while ((neighbor.tri.id != Mesh.DUMMY) &&
(!neighbor.Equals(testtri)))
{
if (neighbor.IsInfected())
{
// Mark the corner of this triangle as having been tested.
neighbor.SetOrg(null);
}
else
{
// A live triangle. The vertex survives.
killorg = false;
}
// Walk counterclockwise about the vertex.
neighbor.Onext();
}
// If we reached a boundary, we must walk clockwise as well.
if (neighbor.tri.id == Mesh.DUMMY)
{
// Walk clockwise about the vertex.
testtri.Oprev(ref neighbor);
// Stop upon reaching a boundary.
while (neighbor.tri.id != Mesh.DUMMY)
{
if (neighbor.IsInfected())
{
// Mark the corner of this triangle as having been tested.
neighbor.SetOrg(null);
}
else
{
// A live triangle. The vertex survives.
killorg = false;
}
// Walk clockwise about the vertex.
neighbor.Oprev();
}
}
if (killorg)
{
// Deleting vertex
testvertex.type = VertexType.UndeadVertex;
mesh.undeads++;
}
}
}
// Record changes in the number of boundary edges, and disconnect
// dead triangles from their neighbors.
for (testtri.orient = 0; testtri.orient < 3; testtri.orient++)
{
testtri.Sym(ref neighbor);
if (neighbor.tri.id == Mesh.DUMMY)
{
// There is no neighboring triangle on this edge, so this edge
// is a boundary edge. This triangle is being deleted, so this
// boundary edge is deleted.
mesh.hullsize--;
}
else
{
// Disconnect the triangle from its neighbor.
neighbor.Dissolve(dummytri);
// There is a neighboring triangle on this edge, so this edge
// becomes a boundary edge when this triangle is deleted.
mesh.hullsize++;
}
}
// Return the dead triangle to the pool of triangles.
mesh.TriangleDealloc(testtri.tri);
}
// Empty the virus pool.
viri.Clear();
}
#endregion
#region Segment insertion
///
/// Find the first triangle on the path from one point to another.
///
///
///
///
/// The return value notes whether the destination or apex of the found
/// triangle is collinear with the two points in question.
///
/// Finds the triangle that intersects a line segment drawn from the
/// origin of 'searchtri' to the point 'searchpoint', and returns the result
/// in 'searchtri'. The origin of 'searchtri' does not change, even though
/// the triangle returned may differ from the one passed in. This routine
/// is used to find the direction to move in to get from one point to
/// another.
///
private FindDirectionResult FindDirection(ref Otri searchtri, Vertex searchpoint)
{
Otri checktri = default(Otri);
Vertex startvertex;
Vertex leftvertex, rightvertex;
double leftccw, rightccw;
bool leftflag, rightflag;
startvertex = searchtri.Org();
rightvertex = searchtri.Dest();
leftvertex = searchtri.Apex();
// Is 'searchpoint' to the left?
leftccw = predicates.CounterClockwise(searchpoint, startvertex, leftvertex);
leftflag = leftccw > 0.0;
// Is 'searchpoint' to the right?
rightccw = predicates.CounterClockwise(startvertex, searchpoint, rightvertex);
rightflag = rightccw > 0.0;
if (leftflag && rightflag)
{
// 'searchtri' faces directly away from 'searchpoint'. We could go left
// or right. Ask whether it's a triangle or a boundary on the left.
searchtri.Onext(ref checktri);
if (checktri.tri.id == Mesh.DUMMY)
{
leftflag = false;
}
else
{
rightflag = false;
}
}
while (leftflag)
{
// Turn left until satisfied.
searchtri.Onext();
if (searchtri.tri.id == Mesh.DUMMY)
{
logger.Error("Unable to find a triangle on path.", "Mesh.FindDirection().1");
throw new Exception("Unable to find a triangle on path.");
}
leftvertex = searchtri.Apex();
rightccw = leftccw;
leftccw = predicates.CounterClockwise(searchpoint, startvertex, leftvertex);
leftflag = leftccw > 0.0;
}
while (rightflag)
{
// Turn right until satisfied.
searchtri.Oprev();
if (searchtri.tri.id == Mesh.DUMMY)
{
logger.Error("Unable to find a triangle on path.", "Mesh.FindDirection().2");
throw new Exception("Unable to find a triangle on path.");
}
rightvertex = searchtri.Dest();
leftccw = rightccw;
rightccw = predicates.CounterClockwise(startvertex, searchpoint, rightvertex);
rightflag = rightccw > 0.0;
}
if (leftccw == 0.0)
{
return FindDirectionResult.Leftcollinear;
}
else if (rightccw == 0.0)
{
return FindDirectionResult.Rightcollinear;
}
else
{
return FindDirectionResult.Within;
}
}
///
/// Find the intersection of an existing segment and a segment that is being
/// inserted. Insert a vertex at the intersection, splitting an existing subsegment.
///
///
///
///
///
/// The segment being inserted connects the apex of splittri to endpoint2.
/// splitsubseg is the subsegment being split, and MUST adjoin splittri.
/// Hence, endpoints of the subsegment being split are the origin and
/// destination of splittri.
///
/// On completion, splittri is a handle having the newly inserted
/// intersection point as its origin, and endpoint1 as its destination.
///
private void SegmentIntersection(ref Otri splittri, ref Osub splitsubseg, Vertex endpoint2)
{
Osub opposubseg = default(Osub);
Vertex endpoint1;
Vertex torg, tdest;
Vertex leftvertex, rightvertex;
Vertex newvertex;
InsertVertexResult success;
var dummysub = mesh.dummysub;
double ex, ey;
double tx, ty;
double etx, ety;
double split, denom;
// Find the other three segment endpoints.
endpoint1 = splittri.Apex();
torg = splittri.Org();
tdest = splittri.Dest();
// Segment intersection formulae; see the Antonio reference.
tx = tdest.x - torg.x;
ty = tdest.y - torg.y;
ex = endpoint2.x - endpoint1.x;
ey = endpoint2.y - endpoint1.y;
etx = torg.x - endpoint2.x;
ety = torg.y - endpoint2.y;
denom = ty * ex - tx * ey;
if (denom == 0.0)
{
logger.Error("Attempt to find intersection of parallel segments.",
"Mesh.SegmentIntersection()");
throw new Exception("Attempt to find intersection of parallel segments.");
}
split = (ey * etx - ex * ety) / denom;
// Create the new vertex.
newvertex = new Vertex(
torg.x + split * (tdest.x - torg.x),
torg.y + split * (tdest.y - torg.y),
splitsubseg.seg.boundary
#if USE_ATTRIBS
, mesh.nextras
#endif
);
newvertex.hash = mesh.hash_vtx++;
newvertex.id = newvertex.hash;
#if USE_ATTRIBS
// Interpolate its attributes.
for (int i = 0; i < mesh.nextras; i++)
{
newvertex.attributes[i] = torg.attributes[i] + split * (tdest.attributes[i] - torg.attributes[i]);
}
#endif
#if USE_Z
newvertex.z = torg.z + split * (tdest.z - torg.z);
#endif
mesh.vertices.Add(newvertex.hash, newvertex);
// Insert the intersection vertex. This should always succeed.
success = mesh.InsertVertex(newvertex, ref splittri, ref splitsubseg, false, false);
if (success != InsertVertexResult.Successful)
{
logger.Error("Failure to split a segment.", "Mesh.SegmentIntersection()");
throw new Exception("Failure to split a segment.");
}
// Record a triangle whose origin is the new vertex.
newvertex.tri = splittri;
if (mesh.steinerleft > 0)
{
mesh.steinerleft--;
}
// Divide the segment into two, and correct the segment endpoints.
splitsubseg.Sym();
splitsubseg.Pivot(ref opposubseg);
splitsubseg.Dissolve(dummysub);
opposubseg.Dissolve(dummysub);
do
{
splitsubseg.SetSegOrg(newvertex);
splitsubseg.Next();
}
while (splitsubseg.seg.hash != Mesh.DUMMY);
do
{
opposubseg.SetSegOrg(newvertex);
opposubseg.Next();
}
while (opposubseg.seg.hash != Mesh.DUMMY);
// Inserting the vertex may have caused edge flips. We wish to rediscover
// the edge connecting endpoint1 to the new intersection vertex.
FindDirection(ref splittri, endpoint1);
rightvertex = splittri.Dest();
leftvertex = splittri.Apex();
if ((leftvertex.x == endpoint1.x) && (leftvertex.y == endpoint1.y))
{
splittri.Onext();
}
else if ((rightvertex.x != endpoint1.x) || (rightvertex.y != endpoint1.y))
{
logger.Error("Topological inconsistency after splitting a segment.", "Mesh.SegmentIntersection()");
throw new Exception("Topological inconsistency after splitting a segment.");
}
// 'splittri' should have destination endpoint1.
}
///
/// Scout the first triangle on the path from one endpoint to another, and check
/// for completion (reaching the second endpoint), a collinear vertex, or the
/// intersection of two segments.
///
///
///
///
/// Returns true if the entire segment is successfully inserted, and false
/// if the job must be finished by ConstrainedEdge().
///
/// If the first triangle on the path has the second endpoint as its
/// destination or apex, a subsegment is inserted and the job is done.
///
/// If the first triangle on the path has a destination or apex that lies on
/// the segment, a subsegment is inserted connecting the first endpoint to
/// the collinear vertex, and the search is continued from the collinear
/// vertex.
///
/// If the first triangle on the path has a subsegment opposite its origin,
/// then there is a segment that intersects the segment being inserted.
/// Their intersection vertex is inserted, splitting the subsegment.
///
private bool ScoutSegment(ref Otri searchtri, Vertex endpoint2, int newmark)
{
Otri crosstri = default(Otri);
Osub crosssubseg = default(Osub);
Vertex leftvertex, rightvertex;
FindDirectionResult collinear;
collinear = FindDirection(ref searchtri, endpoint2);
rightvertex = searchtri.Dest();
leftvertex = searchtri.Apex();
if (((leftvertex.x == endpoint2.x) && (leftvertex.y == endpoint2.y)) ||
((rightvertex.x == endpoint2.x) && (rightvertex.y == endpoint2.y)))
{
// The segment is already an edge in the mesh.
if ((leftvertex.x == endpoint2.x) && (leftvertex.y == endpoint2.y))
{
searchtri.Lprev();
}
// Insert a subsegment, if there isn't already one there.
mesh.InsertSubseg(ref searchtri, newmark);
return true;
}
else if (collinear == FindDirectionResult.Leftcollinear)
{
// We've collided with a vertex between the segment's endpoints.
// Make the collinear vertex be the triangle's origin.
searchtri.Lprev();
mesh.InsertSubseg(ref searchtri, newmark);
// Insert the remainder of the segment.
return ScoutSegment(ref searchtri, endpoint2, newmark);
}
else if (collinear == FindDirectionResult.Rightcollinear)
{
// We've collided with a vertex between the segment's endpoints.
mesh.InsertSubseg(ref searchtri, newmark);
// Make the collinear vertex be the triangle's origin.
searchtri.Lnext();
// Insert the remainder of the segment.
return ScoutSegment(ref searchtri, endpoint2, newmark);
}
else
{
searchtri.Lnext(ref crosstri);
crosstri.Pivot(ref crosssubseg);
// Check for a crossing segment.
if (crosssubseg.seg.hash == Mesh.DUMMY)
{
return false;
}
else
{
// Insert a vertex at the intersection.
SegmentIntersection(ref crosstri, ref crosssubseg, endpoint2);
crosstri.Copy(ref searchtri);
mesh.InsertSubseg(ref searchtri, newmark);
// Insert the remainder of the segment.
return ScoutSegment(ref searchtri, endpoint2, newmark);
}
}
}
///
/// Enforce the Delaunay condition at an edge, fanning out recursively from
/// an existing vertex. Pay special attention to stacking inverted triangles.
///
///
/// Indicates whether or not fixuptri is to the left of
/// the segment being inserted. (Imagine that the segment is pointing up from
/// endpoint1 to endpoint2.)
///
/// This is a support routine for inserting segments into a constrained
/// Delaunay triangulation.
///
/// The origin of fixuptri is treated as if it has just been inserted, and
/// the local Delaunay condition needs to be enforced. It is only enforced
/// in one sector, however, that being the angular range defined by
/// fixuptri.
///
/// This routine also needs to make decisions regarding the "stacking" of
/// triangles. (Read the description of ConstrainedEdge() below before
/// reading on here, so you understand the algorithm.) If the position of
/// the new vertex (the origin of fixuptri) indicates that the vertex before
/// it on the polygon is a reflex vertex, then "stack" the triangle by
/// doing nothing. (fixuptri is an inverted triangle, which is how stacked
/// triangles are identified.)
///
/// Otherwise, check whether the vertex before that was a reflex vertex.
/// If so, perform an edge flip, thereby eliminating an inverted triangle
/// (popping it off the stack). The edge flip may result in the creation
/// of a new inverted triangle, depending on whether or not the new vertex
/// is visible to the vertex three edges behind on the polygon.
///
/// If neither of the two vertices behind the new vertex are reflex
/// vertices, fixuptri and fartri, the triangle opposite it, are not
/// inverted; hence, ensure that the edge between them is locally Delaunay.
///
private void DelaunayFixup(ref Otri fixuptri, bool leftside)
{
Otri neartri = default(Otri);
Otri fartri = default(Otri);
Osub faredge = default(Osub);
Vertex nearvertex, leftvertex, rightvertex, farvertex;
fixuptri.Lnext(ref neartri);
neartri.Sym(ref fartri);
// Check if the edge opposite the origin of fixuptri can be flipped.
if (fartri.tri.id == Mesh.DUMMY)
{
return;
}
neartri.Pivot(ref faredge);
if (faredge.seg.hash != Mesh.DUMMY)
{
return;
}
// Find all the relevant vertices.
nearvertex = neartri.Apex();
leftvertex = neartri.Org();
rightvertex = neartri.Dest();
farvertex = fartri.Apex();
// Check whether the previous polygon vertex is a reflex vertex.
if (leftside)
{
if (predicates.CounterClockwise(nearvertex, leftvertex, farvertex) <= 0.0)
{
// leftvertex is a reflex vertex too. Nothing can
// be done until a convex section is found.
return;
}
}
else
{
if (predicates.CounterClockwise(farvertex, rightvertex, nearvertex) <= 0.0)
{
// rightvertex is a reflex vertex too. Nothing can
// be done until a convex section is found.
return;
}
}
if (predicates.CounterClockwise(rightvertex, leftvertex, farvertex) > 0.0)
{
// fartri is not an inverted triangle, and farvertex is not a reflex
// vertex. As there are no reflex vertices, fixuptri isn't an
// inverted triangle, either. Hence, test the edge between the
// triangles to ensure it is locally Delaunay.
if (predicates.InCircle(leftvertex, farvertex, rightvertex, nearvertex) <= 0.0)
{
return;
}
// Not locally Delaunay; go on to an edge flip.
}
// else fartri is inverted; remove it from the stack by flipping.
mesh.Flip(ref neartri);
fixuptri.Lprev(); // Restore the origin of fixuptri after the flip.
// Recursively process the two triangles that result from the flip.
DelaunayFixup(ref fixuptri, leftside);
DelaunayFixup(ref fartri, leftside);
}
///
/// Force a segment into a constrained Delaunay triangulation by deleting the
/// triangles it intersects, and triangulating the polygons that form on each
/// side of it.
///
///
///
///
///
/// Generates a single subsegment connecting 'endpoint1' to 'endpoint2'.
/// The triangle 'starttri' has 'endpoint1' as its origin. 'newmark' is the
/// boundary marker of the segment.
///
/// To insert a segment, every triangle whose interior intersects the
/// segment is deleted. The union of these deleted triangles is a polygon
/// (which is not necessarily monotone, but is close enough), which is
/// divided into two polygons by the new segment. This routine's task is
/// to generate the Delaunay triangulation of these two polygons.
///
/// You might think of this routine's behavior as a two-step process. The
/// first step is to walk from endpoint1 to endpoint2, flipping each edge
/// encountered. This step creates a fan of edges connected to endpoint1,
/// including the desired edge to endpoint2. The second step enforces the
/// Delaunay condition on each side of the segment in an incremental manner:
/// proceeding along the polygon from endpoint1 to endpoint2 (this is done
/// independently on each side of the segment), each vertex is "enforced"
/// as if it had just been inserted, but affecting only the previous
/// vertices. The result is the same as if the vertices had been inserted
/// in the order they appear on the polygon, so the result is Delaunay.
///
/// In truth, ConstrainedEdge() interleaves these two steps. The procedure
/// walks from endpoint1 to endpoint2, and each time an edge is encountered
/// and flipped, the newly exposed vertex (at the far end of the flipped
/// edge) is "enforced" upon the previously flipped edges, usually affecting
/// only one side of the polygon (depending upon which side of the segment
/// the vertex falls on).
///
/// The algorithm is complicated by the need to handle polygons that are not
/// convex. Although the polygon is not necessarily monotone, it can be
/// triangulated in a manner similar to the stack-based algorithms for
/// monotone polygons. For each reflex vertex (local concavity) of the
/// polygon, there will be an inverted triangle formed by one of the edge
/// flips. (An inverted triangle is one with negative area - that is, its
/// vertices are arranged in clockwise order - and is best thought of as a
/// wrinkle in the fabric of the mesh.) Each inverted triangle can be
/// thought of as a reflex vertex pushed on the stack, waiting to be fixed
/// later.
///
/// A reflex vertex is popped from the stack when a vertex is inserted that
/// is visible to the reflex vertex. (However, if the vertex behind the
/// reflex vertex is not visible to the reflex vertex, a new inverted
/// triangle will take its place on the stack.) These details are handled
/// by the DelaunayFixup() routine above.
///
private void ConstrainedEdge(ref Otri starttri, Vertex endpoint2, int newmark)
{
Otri fixuptri = default(Otri), fixuptri2 = default(Otri);
Osub crosssubseg = default(Osub);
Vertex endpoint1;
Vertex farvertex;
double area;
bool collision;
bool done;
endpoint1 = starttri.Org();
starttri.Lnext(ref fixuptri);
mesh.Flip(ref fixuptri);
// 'collision' indicates whether we have found a vertex directly
// between endpoint1 and endpoint2.
collision = false;
done = false;
do
{
farvertex = fixuptri.Org();
// 'farvertex' is the extreme point of the polygon we are "digging"
// to get from endpoint1 to endpoint2.
if ((farvertex.x == endpoint2.x) && (farvertex.y == endpoint2.y))
{
fixuptri.Oprev(ref fixuptri2);
// Enforce the Delaunay condition around endpoint2.
DelaunayFixup(ref fixuptri, false);
DelaunayFixup(ref fixuptri2, true);
done = true;
}
else
{
// Check whether farvertex is to the left or right of the segment being
// inserted, to decide which edge of fixuptri to dig through next.
area = predicates.CounterClockwise(endpoint1, endpoint2, farvertex);
if (area == 0.0)
{
// We've collided with a vertex between endpoint1 and endpoint2.
collision = true;
fixuptri.Oprev(ref fixuptri2);
// Enforce the Delaunay condition around farvertex.
DelaunayFixup(ref fixuptri, false);
DelaunayFixup(ref fixuptri2, true);
done = true;
}
else
{
if (area > 0.0)
{
// farvertex is to the left of the segment.
fixuptri.Oprev(ref fixuptri2);
// Enforce the Delaunay condition around farvertex, on the
// left side of the segment only.
DelaunayFixup(ref fixuptri2, true);
// Flip the edge that crosses the segment. After the edge is
// flipped, one of its endpoints is the fan vertex, and the
// destination of fixuptri is the fan vertex.
fixuptri.Lprev();
}
else
{
// farvertex is to the right of the segment.
DelaunayFixup(ref fixuptri, false);
// Flip the edge that crosses the segment. After the edge is
// flipped, one of its endpoints is the fan vertex, and the
// destination of fixuptri is the fan vertex.
fixuptri.Oprev();
}
// Check for two intersecting segments.
fixuptri.Pivot(ref crosssubseg);
if (crosssubseg.seg.hash == Mesh.DUMMY)
{
mesh.Flip(ref fixuptri); // May create inverted triangle at left.
}
else
{
// We've collided with a segment between endpoint1 and endpoint2.
collision = true;
// Insert a vertex at the intersection.
SegmentIntersection(ref fixuptri, ref crosssubseg, endpoint2);
done = true;
}
}
}
}
while (!done);
// Insert a subsegment to make the segment permanent.
mesh.InsertSubseg(ref fixuptri, newmark);
// If there was a collision with an interceding vertex, install another
// segment connecting that vertex with endpoint2.
if (collision)
{
// Insert the remainder of the segment.
if (!ScoutSegment(ref fixuptri, endpoint2, newmark))
{
ConstrainedEdge(ref fixuptri, endpoint2, newmark);
}
}
}
///
/// Insert a PSLG segment into a triangulation.
///
///
///
///
private void InsertSegment(Vertex endpoint1, Vertex endpoint2, int newmark)
{
Otri searchtri1 = default(Otri), searchtri2 = default(Otri);
Vertex checkvertex = null;
var dummytri = mesh.dummytri;
// Find a triangle whose origin is the segment's first endpoint.
searchtri1 = endpoint1.tri;
if (searchtri1.tri != null)
{
checkvertex = searchtri1.Org();
}
if (checkvertex != endpoint1)
{
// Find a boundary triangle to search from.
searchtri1.tri = dummytri;
searchtri1.orient = 0;
searchtri1.Sym();
// Search for the segment's first endpoint by point location.
if (locator.Locate(endpoint1, ref searchtri1) != LocateResult.OnVertex)
{
logger.Error("Unable to locate PSLG vertex in triangulation.", "Mesh.InsertSegment().1");
throw new Exception("Unable to locate PSLG vertex in triangulation.");
}
}
// Remember this triangle to improve subsequent point location.
locator.Update(ref searchtri1);
// Scout the beginnings of a path from the first endpoint
// toward the second.
if (ScoutSegment(ref searchtri1, endpoint2, newmark))
{
// The segment was easily inserted.
return;
}
// The first endpoint may have changed if a collision with an intervening
// vertex on the segment occurred.
endpoint1 = searchtri1.Org();
// Find a triangle whose origin is the segment's second endpoint.
checkvertex = null;
searchtri2 = endpoint2.tri;
if (searchtri2.tri != null)
{
checkvertex = searchtri2.Org();
}
if (checkvertex != endpoint2)
{
// Find a boundary triangle to search from.
searchtri2.tri = dummytri;
searchtri2.orient = 0;
searchtri2.Sym();
// Search for the segment's second endpoint by point location.
if (locator.Locate(endpoint2, ref searchtri2) != LocateResult.OnVertex)
{
logger.Error("Unable to locate PSLG vertex in triangulation.", "Mesh.InsertSegment().2");
throw new Exception("Unable to locate PSLG vertex in triangulation.");
}
}
// Remember this triangle to improve subsequent point location.
locator.Update(ref searchtri2);
// Scout the beginnings of a path from the second endpoint
// toward the first.
if (ScoutSegment(ref searchtri2, endpoint1, newmark))
{
// The segment was easily inserted.
return;
}
// The second endpoint may have changed if a collision with an intervening
// vertex on the segment occurred.
endpoint2 = searchtri2.Org();
// Insert the segment directly into the triangulation.
ConstrainedEdge(ref searchtri1, endpoint2, newmark);
}
///
/// Cover the convex hull of a triangulation with subsegments.
///
private void MarkHull()
{
Otri hulltri = default(Otri);
Otri nexttri = default(Otri);
Otri starttri = default(Otri);
// Find a triangle handle on the hull.
hulltri.tri = mesh.dummytri;
hulltri.orient = 0;
hulltri.Sym();
// Remember where we started so we know when to stop.
hulltri.Copy(ref starttri);
// Go once counterclockwise around the convex hull.
do
{
// Create a subsegment if there isn't already one here.
mesh.InsertSubseg(ref hulltri, 1);
// To find the next hull edge, go clockwise around the next vertex.
hulltri.Lnext();
hulltri.Oprev(ref nexttri);
while (nexttri.tri.id != Mesh.DUMMY)
{
nexttri.Copy(ref hulltri);
hulltri.Oprev(ref nexttri);
}
}
while (!hulltri.Equals(starttri));
}
#endregion
}
}