void remove_remaining_interior_verts()
{
HashSet <int> interiorv = new HashSet <int>(MeshIterators.InteriorVertices(fillmesh));
int prev_count = 0;
while (interiorv.Count > 0 && interiorv.Count != prev_count)
{
prev_count = interiorv.Count;
int[] curv = interiorv.ToArray();
foreach (int vid in curv)
{
foreach (int e in fillmesh.VtxEdgesItr(vid))
{
Index2i ev = fillmesh.GetEdgeV(e);
int otherv = (ev.a == vid) ? ev.b : ev.a;
DMesh3.EdgeCollapseInfo info;
MeshResult result = fillmesh.CollapseEdge(otherv, vid, out info);
if (result == MeshResult.Ok)
{
break;
}
}
if (fillmesh.IsVertex(vid) == false)
{
interiorv.Remove(vid);
}
}
}
if (interiorv.Count > 0)
{
Util.gBreakToDebugger();
}
}
DMesh3 ComputeInflation(DMesh3 planarMesh)
{
DMesh3 mesh = new DMesh3(planarMesh);
DijkstraGraphDistance dist = new DijkstraGraphDistance(
mesh.MaxVertexID, false,
(vid) => { return(mesh.IsVertex(vid)); },
(a, b) => { return((float)mesh.GetVertex(a).Distance(mesh.GetVertex(b))); },
mesh.VtxVerticesItr);
foreach (int vid in MeshIterators.BoundaryVertices(mesh))
{
dist.AddSeed(vid, 0);
}
dist.Compute();
float max_dist = dist.MaxDistance;
float[] distances = new float[mesh.MaxVertexID];
foreach (int vid in mesh.VertexIndices())
{
distances[vid] = dist.GetDistance(vid);
}
List <int> local_maxima = new List <int>();
foreach (int vid in MeshIterators.InteriorVertices(mesh))
{
float d = distances[vid];
bool is_maxima = true;
foreach (int nbrid in mesh.VtxVerticesItr(vid))
{
if (distances[nbrid] > d)
{
is_maxima = false;
}
}
if (is_maxima)
{
local_maxima.Add(vid);
}
}
// smooth distances (really should use cotan here!!)
float smooth_alpha = 0.1f;
int smooth_rounds = 5;
foreach (int ri in Interval1i.Range(smooth_rounds))
{
foreach (int vid in mesh.VertexIndices())
{
float cur = distances[vid];
float centroid = 0;
int nbr_count = 0;
foreach (int nbrid in mesh.VtxVerticesItr(vid))
{
centroid += distances[nbrid];
nbr_count++;
}
centroid /= nbr_count;
distances[vid] = (1 - smooth_alpha) * cur + (smooth_alpha) * centroid;
}
}
Vector3d normal = Vector3d.AxisZ;
foreach (int vid in mesh.VertexIndices())
{
if (dist.IsSeed(vid))
{
continue;
}
float h = distances[vid];
// [RMS] there are different options here...
h = 2 * (float)Math.Sqrt(h);
float offset = h;
Vector3d d = mesh.GetVertex(vid);
mesh.SetVertex(vid, d + (Vector3d)(offset * normal));
}
DMesh3 compacted = new DMesh3();
var compactInfo = compacted.CompactCopy(mesh);
IndexUtil.Apply(local_maxima, compactInfo.MapV);
mesh = compacted;
MeshVertexSelection boundary_sel = new MeshVertexSelection(mesh);
HashSet <int> boundaryV = new HashSet <int>(MeshIterators.BoundaryVertices(mesh));
boundary_sel.Select(boundaryV);
boundary_sel.ExpandToOneRingNeighbours();
LaplacianMeshSmoother smoother = new LaplacianMeshSmoother(mesh);
foreach (int vid in boundary_sel)
{
if (boundaryV.Contains(vid))
{
smoother.SetConstraint(vid, mesh.GetVertex(vid), 100.0f, true);
}
else
{
smoother.SetConstraint(vid, mesh.GetVertex(vid), 10.0f, false);
}
}
foreach (int vid in local_maxima)
{
smoother.SetConstraint(vid, mesh.GetVertex(vid), 50, false);
}
bool ok = smoother.SolveAndUpdateMesh();
Util.gDevAssert(ok);
List <int> intVerts = new List <int>(MeshIterators.InteriorVertices(mesh));
MeshIterativeSmooth smooth = new MeshIterativeSmooth(mesh, intVerts.ToArray(), true);
smooth.SmoothType = MeshIterativeSmooth.SmoothTypes.Cotan;
smooth.Rounds = 10;
smooth.Alpha = 0.1f;
smooth.Smooth();
return(mesh);
}