private void GenerateTerrain(int gx, int gy)
{
FP ax = gx * CellSize;
FP ay = gy * CellSize;
List <Vertices> polys = MarchingSquares.DetectSquares(new AABB(new FPVector2(ax, ay), new FPVector2(ax + CellSize, ay + CellSize)), SubCellSize, SubCellSize, _terrainMap, Iterations, true);
if (polys.Count == 0)
{
return;
}
_bodyMap[gx, gy] = new List <Body>();
// create the scale vector
FPVector2 scale = new FPVector2(1f / PointsPerUnit, 1f / -PointsPerUnit);
// create physics object for this grid cell
foreach (Vertices item in polys)
{
// does this need to be negative?
item.Scale(ref scale);
item.Translate(ref _topLeft);
Vertices simplified = SimplifyTools.CollinearSimplify(item, FP.Zero);
List <Vertices> decompPolys = Triangulate.ConvexPartition(simplified, Decomposer, true, FP.EN3);
foreach (Vertices poly in decompPolys)
{
if (poly.Count > 2)
{
_bodyMap[gx, gy].Add(BodyFactory.CreatePolygon(World, poly, 1, null));
}
}
}
}
/// <summary>
/// Implements "A new algorithm for Boolean operations on general polygons"
/// available here: http://liama.ia.ac.cn/wiki/_media/user:dong:dong_cg_05.pdf
/// Merges two polygons, a subject and a clip with the specified operation. Polygons may not be
/// self-intersecting.
///
/// Warning: May yield incorrect results or even crash if polygons contain collinear points.
/// </summary>
/// <param name="subject">The subject polygon.</param>
/// <param name="clip">The clip polygon, which is added,
/// substracted or intersected with the subject</param>
/// <param name="clipType">The operation to be performed. Either
/// Union, Difference or Intersection.</param>
/// <param name="error">The error generated (if any)</param>
/// <returns>A list of closed polygons, which make up the result of the clipping operation.
/// Outer contours are ordered counter clockwise, holes are ordered clockwise.</returns>
private static List <Vertices> Execute(Vertices subject, Vertices clip, PolyClipType clipType, out PolyClipError error)
{
Debug.Assert(subject.IsSimple() && clip.IsSimple(), "Non simple input!", "Input polygons must be simple (cannot intersect themselves).");
// Copy polygons
Vertices slicedSubject;
Vertices slicedClip;
// Calculate the intersection and touch points between
// subject and clip and add them to both
CalculateIntersections(subject, clip, out slicedSubject, out slicedClip);
// Translate polygons into upper right quadrant
// as the algorithm depends on it
FPVector2 lbSubject = subject.GetAABB().LowerBound;
FPVector2 lbClip = clip.GetAABB().LowerBound;
FPVector2 translate;
FPVector2.Min(ref lbSubject, ref lbClip, out translate);
translate = FPVector2.one - translate;
if (translate != FPVector2.zero)
{
slicedSubject.Translate(ref translate);
slicedClip.Translate(ref translate);
}
// Enforce counterclockwise contours
slicedSubject.ForceCounterClockWise();
slicedClip.ForceCounterClockWise();
List <Edge> subjectSimplices;
List <FP> subjectCoeff;
List <Edge> clipSimplices;
List <FP> clipCoeff;
// Build simplical chains from the polygons and calculate the
// the corresponding coefficients
CalculateSimplicalChain(slicedSubject, out subjectCoeff, out subjectSimplices);
CalculateSimplicalChain(slicedClip, out clipCoeff, out clipSimplices);
List <Edge> resultSimplices;
// Determine the characteristics function for all non-original edges
// in subject and clip simplical chain and combine the edges contributing
// to the result, depending on the clipType
CalculateResultChain(subjectCoeff, subjectSimplices, clipCoeff, clipSimplices, clipType,
out resultSimplices);
List <Vertices> result;
// Convert result chain back to polygon(s)
error = BuildPolygonsFromChain(resultSimplices, out result);
// Reverse the polygon translation from the beginning
// and remove collinear points from output
translate *= -1f;
for (int i = 0; i < result.Count; ++i)
{
result[i].Translate(ref translate);
SimplifyTools.CollinearSimplify(result[i], FP.Zero);
}
return(result);
}