public static void TestIsoCurve()
{
var meshSO = OG.Scan.SO;
DMesh3 mesh = new DMesh3(meshSO.Mesh);
DMeshAABBTree3 spatial = new DMeshAABBTree3(mesh, true);
AxisAlignedBox3d bounds = mesh.CachedBounds;
Frame3f plane = new Frame3f(bounds.Center);
Func <Vector3d, double> planeSignedDistanceF = (v) => {
return((v - plane.Origin).Dot(plane.Y));
};
Func <Vector3d, double> sphereDistF = (v) => {
double d = v.Distance(plane.Origin);
return(d - 50.0);
};
MeshIsoCurves iso = new MeshIsoCurves(mesh, sphereDistF);
iso.Compute();
DGraph3Util.Curves curves = DGraph3Util.ExtractCurves(iso.Graph);
foreach (DCurve3 c in curves.Loops)
{
List <Vector3d> verts = new List <Vector3d>(c.Vertices);
for (int i = 0; i < verts.Count; ++i)
{
verts[i] = verts[i] + 0.5 * mesh.GetTriNormal(spatial.FindNearestTriangle(verts[i]));
}
DebugUtil.EmitDebugCurve("curve", verts.ToArray(), true, 1, Colorf.Red, Colorf.Red, meshSO.RootGameObject, false);
}
foreach (DCurve3 c in curves.Paths)
{
List <Vector3d> verts = new List <Vector3d>(c.Vertices);
for (int i = 0; i < verts.Count; ++i)
{
verts[i] = verts[i] + 0.5 * mesh.GetTriNormal(spatial.FindNearestTriangle(verts[i]));
}
DebugUtil.EmitDebugCurve("curve", verts.ToArray(), false, 1, Colorf.Blue, Colorf.Blue, meshSO.RootGameObject, false);
}
//foreach ( Segment3d seg in iso.Graph.Segments()) {
// Vector3d a = seg.P0 + 1.0 * mesh.GetTriNormal(spatial.FindNearestTriangle(seg.P0));
// Vector3d b = seg.P1 + 1.0 * mesh.GetTriNormal(spatial.FindNearestTriangle(seg.P1));
// DebugUtil.EmitDebugLine("seg", a, b, 1.0f, Colorf.Red, meshSO.RootGameObject, false);
//}
}
void update()
{
MeshIsoCurves iso = new MeshIsoCurves(SO.Mesh, (v) => {
return((v - frameL.Origin).Dot(frameL.Z));
});
iso.Compute();
graph = iso.Graph;
localCurves = DGraph3Util.ExtractCurves(graph);
// ugh need xform seq for to/from world...
if (OutputSpace == CoordSpace.WorldCoords)
{
foreach (DCurve3 c in localCurves.Loops)
{
for (int i = 0; i < c.VertexCount; ++i)
{
c[i] = SceneTransforms.TransformTo((Vector3f)c[i], SO, CoordSpace.ObjectCoords, OutputSpace);
}
}
foreach (DCurve3 c in localCurves.Paths)
{
for (int i = 0; i < c.VertexCount; ++i)
{
c[i] = SceneTransforms.TransformTo((Vector3f)c[i], SO, CoordSpace.ObjectCoords, OutputSpace);
}
}
}
else if (OutputSpace == CoordSpace.SceneCoords)
{
TransformSequence xform = SceneTransforms.ObjectToSceneXForm(SO);
foreach (DCurve3 c in localCurves.Loops)
{
for (int i = 0; i < c.VertexCount; ++i)
{
c[i] = xform.TransformP(c[i]);
}
}
foreach (DCurve3 c in localCurves.Paths)
{
for (int i = 0; i < c.VertexCount; ++i)
{
c[i] = xform.TransformP(c[i]);
}
}
}
}
private static bool compute_plane_curves(DMesh3 mesh, DMeshAABBTree3 spatial,
double z, bool is_solid,
out Polygon2d[] loops, out PolyLine2d[] curves)
{
Func <Vector3d, double> planeF = (v) =>
{
return(v.z - z);
};
// find list of triangles that intersect this z-value
PlaneIntersectionTraversal planeIntr = new PlaneIntersectionTraversal(mesh, z);
spatial.DoTraversal(planeIntr);
List <int> triangles = planeIntr.triangles;
// compute intersection iso-curves, which produces a 3D graph of undirected edges
MeshIsoCurves iso = new MeshIsoCurves(mesh, planeF)
{
WantGraphEdgeInfo = true
};
iso.Compute(triangles);
DGraph3 graph = iso.Graph;
if (graph.EdgeCount == 0)
{
loops = new Polygon2d[0];
curves = new PolyLine2d[0];
return(false);
}
// if this is a closed solid, any open spurs in the graph are errors
if (is_solid)
{
DGraph3Util.ErodeOpenSpurs(graph);
}
// [RMS] debug visualization
//DGraph2 graph2 = new DGraph2();
//Dictionary<int, int> mapV = new Dictionary<int, int>();
//foreach (int vid in graph.VertexIndices())
// mapV[vid] = graph2.AppendVertex(graph.GetVertex(vid).xy);
//foreach (int eid in graph.EdgeIndices())
// graph2.AppendEdge(mapV[graph.GetEdge(eid).a], mapV[graph.GetEdge(eid).b]);
//SVGWriter svg = new SVGWriter();
//svg.AddGraph(graph2, SVGWriter.Style.Outline("black", 0.05f));
//foreach (int vid in graph2.VertexIndices()) {
// if (graph2.IsJunctionVertex(vid))
// svg.AddCircle(new Circle2d(graph2.GetVertex(vid), 0.25f), SVGWriter.Style.Outline("red", 0.1f));
// else if (graph2.IsBoundaryVertex(vid))
// svg.AddCircle(new Circle2d(graph2.GetVertex(vid), 0.25f), SVGWriter.Style.Outline("blue", 0.1f));
//}
//svg.Write(string.Format("c:\\meshes\\EXPORT_SLICE_{0}.svg", z));
// extract loops and open curves from graph
DGraph3Util.Curves c = DGraph3Util.ExtractCurves(graph, false, iso.ShouldReverseGraphEdge);
loops = new Polygon2d[c.Loops.Count];
for (int li = 0; li < loops.Length; ++li)
{
DCurve3 loop = c.Loops[li];
loops[li] = new Polygon2d();
foreach (Vector3d v in loop.Vertices)
{
loops[li].AppendVertex(v.xy);
}
}
curves = new PolyLine2d[c.Paths.Count];
for (int pi = 0; pi < curves.Length; ++pi)
{
DCurve3 span = c.Paths[pi];
curves[pi] = new PolyLine2d();
foreach (Vector3d v in span.Vertices)
{
curves[pi].AppendVertex(v.xy);
}
}
return(true);
}
