public static void Restore(PolygonFont2d font, BinaryReader reader)
{
int version = reader.ReadInt32();
if (version != SerializerVersion)
{
throw new Exception("PolygonFont2d.Restore: invalid version!");
}
int nc = reader.ReadInt32();
for (int ci = 0; ci < nc; ++ci)
{
int buflen = reader.ReadInt32();
byte[] stringbuf = reader.ReadBytes(buflen);
string s = Encoding.Unicode.GetString(stringbuf);
int numpolys = reader.ReadInt32();
GeneralPolygon2d[] polys = new GeneralPolygon2d[numpolys];
for (int k = 0; k < numpolys; ++k)
{
polys[k] = new GeneralPolygon2d();
gSerialization.Restore(polys[k], reader);
}
font.AddCharacter(s, polys);
}
}
public void AppendPolygon(GeneralPolygon2d poly, int gid = -1)
{
AppendPolygon(poly.Outer, gid);
foreach (var hole in poly.Holes)
{
AppendPolygon(hole, gid);
}
}
public SegmentSet2d(GeneralPolygon2d poly)
{
Segments = new List <Segment2d>(poly.Outer.SegmentItr());
foreach (var hole in poly.Holes)
{
Segments.AddRange(hole.SegmentItr());
}
}
public static void LaplacianSmoothConstrained(GeneralPolygon2d solid, double alpha, int iterations, double max_dist, bool bAllowShrink, bool bAllowGrow)
{
LaplacianSmoothConstrained(solid.Outer, alpha, iterations, max_dist, bAllowShrink, bAllowGrow);
foreach (Polygon2d hole in solid.Holes)
{
CurveUtils2.LaplacianSmoothConstrained(hole, alpha, iterations, max_dist, bAllowShrink, bAllowGrow);
}
}
public static void Store(GeneralPolygon2d polygon, BinaryWriter writer)
{
Store(polygon.Outer, writer);
writer.Write(polygon.Holes.Count);
for (int i = 0; i < polygon.Holes.Count; ++i)
{
Store(polygon.Holes[i], writer);
}
}
/// <summary>
/// Actually computes the insertion. In some cases we would like more info
/// coming back than we get by using Generate() api. Note that resulting
/// mesh is *not* compacted.
/// </summary>
public DMesh3 ComputeResult(out MeshInsertPolygon insertion)
{
AxisAlignedBox2d bounds = Polygon.Bounds;
double padding = 0.1 * bounds.DiagonalLength;
bounds.Expand(padding);
TrivialRectGenerator rectgen = (Subdivisions == 1) ?
new TrivialRectGenerator() : new GriddedRectGenerator()
{
EdgeVertices = Subdivisions
};
rectgen.Width = (float)bounds.Width;
rectgen.Height = (float)bounds.Height;
rectgen.IndicesMap = new Index2i(1, 2);
rectgen.UVMode = UVMode;
rectgen.Clockwise = true; // MeshPolygonInserter assumes mesh faces are CW? (except code says CCW...)
rectgen.Generate();
var base_mesh = new DMesh3();
rectgen.MakeMesh(base_mesh);
var shiftPolygon = new GeneralPolygon2d(Polygon);
Vector2d shift = bounds.Center;
shiftPolygon.Translate(-shift);
var insert = new MeshInsertPolygon()
{
Mesh = base_mesh,
Polygon = shiftPolygon
};
bool bOK = insert.Insert();
if (!bOK)
{
throw new Exception("TriangulatedPolygonGenerator: failed to Insert()");
}
MeshFaceSelection selected = insert.InteriorTriangles;
var editor = new MeshEditor(base_mesh);
editor.RemoveTriangles((tid) => { return(selected.IsSelected(tid) == false); }, true);
var shift3 = new Vector3d(shift.x, shift.y, 0);
MeshTransforms.Translate(base_mesh, shift3);
insertion = insert;
return(base_mesh);
}
public GeneralPolygon2dBoxTree(GeneralPolygon2d poly)
{
Polygon = poly;
OuterTree = new Polygon2dBoxTree(poly.Outer);
int NH = poly.Holes.Count;
if (NH > 0)
{
HoleTrees = new Polygon2dBoxTree[NH];
for (int k = 0; k < NH; ++k)
{
HoleTrees[k] = new Polygon2dBoxTree(poly.Holes[k]);
}
}
}
/// <summary>
/// Resample parametric solid into polygonal solid
/// </summary>
public GeneralPolygon2d Convert(double fSpacingLength, double fSpacingT, double fDeviationTolerance)
{
GeneralPolygon2d poly = new GeneralPolygon2d();
poly.Outer = new Polygon2d(
CurveSampler2.AutoSample(this.outer, fSpacingLength, fSpacingT));
poly.Outer.Simplify(0, fDeviationTolerance);
foreach (var hole in this.Holes)
{
Polygon2d holePoly = new Polygon2d(
CurveSampler2.AutoSample(hole, fSpacingLength, fSpacingT));
holePoly.Simplify(0, fDeviationTolerance);
poly.AddHole(holePoly, false);
}
return(poly);
}
/// <summary>
/// simplify outer and holes of a polygon solid with same thresholds
/// </summary>
public static void Simplify(GeneralPolygon2d solid, double deviationThresh)
{
PolySimplification2 simp = new PolySimplification2(solid.Outer);
simp.SimplifyDeviationThreshold = deviationThresh;
simp.Simplify();
solid.Outer.SetVertices(simp.Result, true);
foreach (var hole in solid.Holes)
{
PolySimplification2 holesimp = new PolySimplification2(hole);
holesimp.SimplifyDeviationThreshold = deviationThresh;
holesimp.Simplify();
hole.SetVertices(holesimp.Result, true);
}
}
public static void Restore(GeneralPolygon2d polygon, BinaryReader reader)
{
Polygon2d outer = new Polygon2d();
Restore(outer, reader);
polygon.Outer = outer;
int hole_count = reader.ReadInt32();
for (int i = 0; i < hole_count; ++i)
{
Polygon2d holepoly = new Polygon2d();
Restore(holepoly, reader);
polygon.AddHole(holepoly, false);
}
}
/// <summary>
/// Find cells that are "inside" the container polygon.
/// Currently based on finding a point inside the cell and then
/// checking that it is also inside the container.
/// This is perhaps not ideal!!
/// </summary>
public List <Polygon2d> ContainedCells(GeneralPolygon2d container)
{
Func <Polygon2d, bool> filterF = (poly) => {
bool bIsCW = poly.IsClockwise;
for (int k = 0; k < poly.VertexCount; k++)
{
Segment2d s = poly.Segment(k);
Vector2d pt = s.Center + MathUtil.Epsilonf * s.Direction.Perp;
if (poly.Contains(pt) == bIsCW)
{
return(container.Contains(pt));
}
}
// give up
return(false);
};
return(CellsToPolygons(filterF));
}
// Finds set of "solid" regions - eg boundary loops with interior holes.
// Result has outer loops being clockwise, and holes counter-clockwise
public SolidRegionInfo FindSolidRegions(double fSimplifyDeviationTol = 0.1, bool bWantCurveSolids = true)
{
List <SmoothLoopElement> valid = new List <SmoothLoopElement>(LoopsItr());
int N = valid.Count;
// precompute bounding boxes
int maxid = 0;
foreach (var v in valid)
{
maxid = Math.Max(maxid, v.ID + 1);
}
AxisAlignedBox2d[] bounds = new AxisAlignedBox2d[maxid];
foreach (var v in valid)
{
bounds[v.ID] = v.Bounds();
}
// copy polygons, simplify if desired
double fClusterTol = 0.0; // don't do simple clustering, can lose corners
double fDeviationTol = fSimplifyDeviationTol;
Polygon2d[] polygons = new Polygon2d[maxid];
foreach (var v in valid)
{
Polygon2d p = new Polygon2d(v.polygon);
if (fClusterTol > 0 || fDeviationTol > 0)
{
p.Simplify(fClusterTol, fDeviationTol);
}
polygons[v.ID] = p;
}
// sort by bbox containment to speed up testing (does it??)
valid.Sort((x, y) => {
return(bounds[x.ID].Contains(bounds[y.ID]) ? -1 : 1);
});
// containment sets
bool[] bIsContained = new bool[N];
Dictionary <int, List <int> > ContainSets = new Dictionary <int, List <int> >();
// construct containment sets
for (int i = 0; i < N; ++i)
{
SmoothLoopElement loopi = valid[i];
Polygon2d polyi = polygons[loopi.ID];
for (int j = 0; j < N; ++j)
{
if (i == j)
{
continue;
}
SmoothLoopElement loopj = valid[j];
Polygon2d polyj = polygons[loopj.ID];
// cannot be contained if bounds are not contained
if (bounds[loopi.ID].Contains(bounds[loopj.ID]) == false)
{
continue;
}
// any other early-outs??
if (polyi.Contains(polyj))
{
if (ContainSets.ContainsKey(i) == false)
{
ContainSets.Add(i, new List <int>());
}
ContainSets[i].Add(j);
bIsContained[j] = true;
}
}
}
List <GeneralPolygon2d> polysolids = new List <GeneralPolygon2d>();
List <PlanarSolid2d> solids = new List <PlanarSolid2d>();
List <SmoothLoopElement> used = new List <SmoothLoopElement>();
// extract solids from containment relationships
foreach (var i in ContainSets.Keys)
{
SmoothLoopElement outer_element = valid[i];
used.Add(outer_element);
if (bIsContained[i])
{
throw new Exception("PlanarComplex.FindSolidRegions: multiply-nested regions not supported!");
}
Polygon2d outer_poly = polygons[outer_element.ID];
IParametricCurve2d outer_loop = (bWantCurveSolids) ? outer_element.source.Clone() : null;
if (outer_poly.IsClockwise == false)
{
outer_poly.Reverse();
if (bWantCurveSolids)
{
outer_loop.Reverse();
}
}
GeneralPolygon2d g = new GeneralPolygon2d();
g.Outer = outer_poly;
PlanarSolid2d s = new PlanarSolid2d();
if (bWantCurveSolids)
{
s.SetOuter(outer_loop, true);
}
foreach (int hi in ContainSets[i])
{
SmoothLoopElement he = valid[hi];
used.Add(he);
Polygon2d hole_poly = polygons[he.ID];
IParametricCurve2d hole_loop = (bWantCurveSolids) ? he.source.Clone() : null;
if (hole_poly.IsClockwise)
{
hole_poly.Reverse();
if (bWantCurveSolids)
{
hole_loop.Reverse();
}
}
try {
g.AddHole(hole_poly);
if (hole_loop != null)
{
s.AddHole(hole_loop);
}
} catch {
// don't add this hole - must intersect or something
// We should have caught this earlier!
}
}
polysolids.Add(g);
if (bWantCurveSolids)
{
solids.Add(s);
}
}
for (int i = 0; i < N; ++i)
{
SmoothLoopElement loopi = valid[i];
if (used.Contains(loopi))
{
continue;
}
Polygon2d outer_poly = polygons[loopi.ID];
IParametricCurve2d outer_loop = (bWantCurveSolids) ? loopi.source.Clone() : null;
if (outer_poly.IsClockwise == false)
{
outer_poly.Reverse();
if (bWantCurveSolids)
{
outer_loop.Reverse();
}
}
GeneralPolygon2d g = new GeneralPolygon2d();
g.Outer = outer_poly;
PlanarSolid2d s = new PlanarSolid2d();
if (bWantCurveSolids)
{
s.SetOuter(outer_loop, true);
}
polysolids.Add(g);
if (bWantCurveSolids)
{
solids.Add(s);
}
}
return(new SolidRegionInfo()
{
Polygons = polysolids,
Solids = (bWantCurveSolids) ? solids : null
});
}
// Finds set of "solid" regions - eg boundary loops with interior holes.
// Result has outer loops being clockwise, and holes counter-clockwise
public SolidRegionInfo FindSolidRegions(FindSolidsOptions options)
{
var validLoops = new List <SmoothLoopElement>(LoopsItr());
int N = validLoops.Count;
// precompute bounding boxes
int maxid = 0;
foreach (var v in validLoops)
{
maxid = Math.Max(maxid, v.ID + 1);
}
var bounds = new AxisAlignedBox2d[maxid];
foreach (var v in validLoops)
{
bounds[v.ID] = v.Bounds();
}
// copy polygons, simplify if desired
double fClusterTol = 0.0; // don't do simple clustering, can lose corners
double fDeviationTol = options.SimplifyDeviationTolerance;
var polygons = new Polygon2d[maxid];
foreach (var v in validLoops)
{
var p = new Polygon2d(v.polygon);
if (fClusterTol > 0 || fDeviationTol > 0)
{
p.Simplify(fClusterTol, fDeviationTol);
}
polygons[v.ID] = p;
}
// sort by bbox containment to speed up testing (does it??)
validLoops.Sort((x, y) =>
{
return(bounds[x.ID].Contains(bounds[y.ID]) ? -1 : 1);
});
// containment sets
bool[] bIsContained = new bool[N];
var ContainSets = new Dictionary <int, List <int> >();
var ContainedParents = new Dictionary <int, List <int> >();
bool bUseOrient = options.TrustOrientations;
bool bWantCurveSolids = options.WantCurveSolids;
bool bCheckHoles = !options.AllowOverlappingHoles;
// construct containment sets
for (int i = 0; i < N; ++i)
{
SmoothLoopElement loopi = validLoops[i];
Polygon2d polyi = polygons[loopi.ID];
for (int j = 0; j < N; ++j)
{
if (i == j)
{
continue;
}
SmoothLoopElement loopj = validLoops[j];
Polygon2d polyj = polygons[loopj.ID];
// if we are preserving orientations, holes cannot contain holes and
// outers cannot contain outers!
if (bUseOrient && loopj.polygon.IsClockwise == loopi.polygon.IsClockwise)
{
continue;
}
// cannot be contained if bounds are not contained
if (bounds[loopi.ID].Contains(bounds[loopj.ID]) == false)
{
continue;
}
// any other early-outs??
if (polyi.Contains(polyj))
{
if (ContainSets.ContainsKey(i) == false)
{
ContainSets.Add(i, new List <int>());
}
ContainSets[i].Add(j);
bIsContained[j] = true;
if (ContainedParents.ContainsKey(j) == false)
{
ContainedParents.Add(j, new List <int>());
}
ContainedParents[j].Add(i);
}
}
}
var polysolids = new List <GeneralPolygon2d>();
var polySolidsInfo = new List <GeneralSolid>();
var solids = new List <PlanarSolid2d>();
var used = new HashSet <SmoothLoopElement>();
var LoopToOuterIndex = new Dictionary <SmoothLoopElement, int>();
var ParentsToProcess = new List <int>();
// The following is a lot of code but it is very similar, just not clear how
// to refactor out the common functionality
// 1) we find all the top-level uncontained polys and add them to the final polys list
// 2a) for any poly contained in those parent-polys, that is not also contained in anything else,
// add as hole to that poly
// 2b) remove all those used parents & holes from consideration
// 2c) now find all the "new" top-level polys
// 3) repeat 2a-c until done all polys
// 4) any remaining polys must be interior solids w/ no holes
// **or** weird leftovers like intersecting polys...
// add all top-level uncontained polys
for (int i = 0; i < N; ++i)
{
SmoothLoopElement loopi = validLoops[i];
if (bIsContained[i])
{
continue;
}
Polygon2d outer_poly = polygons[loopi.ID];
IParametricCurve2d outer_loop = (bWantCurveSolids) ? loopi.source.Clone() : null;
if (outer_poly.IsClockwise == false)
{
outer_poly.Reverse();
if (bWantCurveSolids)
{
outer_loop.Reverse();
}
}
var g = new GeneralPolygon2d();
g.Outer = outer_poly;
var s = new PlanarSolid2d();
if (bWantCurveSolids)
{
s.SetOuter(outer_loop, true);
}
int idx = polysolids.Count;
LoopToOuterIndex[loopi] = idx;
used.Add(loopi);
if (ContainSets.ContainsKey(i))
{
ParentsToProcess.Add(i);
}
polysolids.Add(g);
polySolidsInfo.Add(new GeneralSolid()
{
Outer = loopi
});
if (bWantCurveSolids)
{
solids.Add(s);
}
}
// keep iterating until we processed all parent loops
while (ParentsToProcess.Count > 0)
{
var ContainersToRemove = new List <int>();
// now for all top-level polys that contain children, add those children
// as long as they do not have multiple contain-parents
foreach (int i in ParentsToProcess)
{
SmoothLoopElement parentloop = validLoops[i];
int outer_idx = LoopToOuterIndex[parentloop];
List <int> children = ContainSets[i];
foreach (int childj in children)
{
SmoothLoopElement childLoop = validLoops[childj];
Debug.Assert(used.Contains(childLoop) == false);
// skip multiply-contained children
List <int> parents = ContainedParents[childj];
if (parents.Count > 1)
{
continue;
}
Polygon2d hole_poly = polygons[childLoop.ID];
IParametricCurve2d hole_loop = (bWantCurveSolids) ? childLoop.source.Clone() : null;
if (hole_poly.IsClockwise)
{
hole_poly.Reverse();
if (bWantCurveSolids)
{
hole_loop.Reverse();
}
}
try
{
polysolids[outer_idx].AddHole(hole_poly, bCheckHoles);
polySolidsInfo[outer_idx].Holes.Add(childLoop);
if (hole_loop != null)
{
solids[outer_idx].AddHole(hole_loop);
}
}
catch
{
// don't add this hole - must intersect or something?
// We should have caught this earlier!
}
used.Add(childLoop);
if (ContainSets.ContainsKey(childj))
{
ContainersToRemove.Add(childj);
}
}
ContainersToRemove.Add(i);
}
// remove all containers that are no longer valid
foreach (int ci in ContainersToRemove)
{
ContainSets.Remove(ci);
// have to remove from each ContainedParents list
var keys = new List <int>(ContainedParents.Keys);
foreach (int j in keys)
{
if (ContainedParents[j].Contains(ci))
{
ContainedParents[j].Remove(ci);
}
}
}
ParentsToProcess.Clear();
// ok now find next-level uncontained parents...
for (int i = 0; i < N; ++i)
{
SmoothLoopElement loopi = validLoops[i];
if (used.Contains(loopi))
{
continue;
}
if (ContainSets.ContainsKey(i) == false)
{
continue;
}
List <int> parents = ContainedParents[i];
if (parents.Count > 0)
{
continue;
}
Polygon2d outer_poly = polygons[loopi.ID];
IParametricCurve2d outer_loop = (bWantCurveSolids) ? loopi.source.Clone() : null;
if (outer_poly.IsClockwise == false)
{
outer_poly.Reverse();
if (bWantCurveSolids)
{
outer_loop.Reverse();
}
}
var g = new GeneralPolygon2d();
g.Outer = outer_poly;
var s = new PlanarSolid2d();
if (bWantCurveSolids)
{
s.SetOuter(outer_loop, true);
}
int idx = polysolids.Count;
LoopToOuterIndex[loopi] = idx;
used.Add(loopi);
if (ContainSets.ContainsKey(i))
{
ParentsToProcess.Add(i);
}
polysolids.Add(g);
polySolidsInfo.Add(new GeneralSolid()
{
Outer = loopi
});
if (bWantCurveSolids)
{
solids.Add(s);
}
}
}
// any remaining loops must be top-level
for (int i = 0; i < N; ++i)
{
SmoothLoopElement loopi = validLoops[i];
if (used.Contains(loopi))
{
continue;
}
Polygon2d outer_poly = polygons[loopi.ID];
IParametricCurve2d outer_loop = (bWantCurveSolids) ? loopi.source.Clone() : null;
if (outer_poly.IsClockwise == false)
{
outer_poly.Reverse();
if (bWantCurveSolids)
{
outer_loop.Reverse();
}
}
var g = new GeneralPolygon2d();
g.Outer = outer_poly;
var s = new PlanarSolid2d();
if (bWantCurveSolids)
{
s.SetOuter(outer_loop, true);
}
polysolids.Add(g);
polySolidsInfo.Add(new GeneralSolid()
{
Outer = loopi
});
if (bWantCurveSolids)
{
solids.Add(s);
}
}
return(new SolidRegionInfo()
{
Polygons = polysolids,
PolygonsSources = polySolidsInfo,
Solids = (bWantCurveSolids) ? solids : null
});
}
