private static void TessellatePath(BezierContour contour, PathProperties pathProps, List <Geometry> geoms, TessellationOptions tessellationOptions)
{
UnityEngine.Profiling.Profiler.BeginSample("TessellatePath");
if (pathProps.Stroke != null)
{
Vector2[] vertices;
UInt16[] indices;
VectorUtils.TessellatePath(contour, pathProps, tessellationOptions, out vertices, out indices);
var color = pathProps.Stroke.Color;
if (indices.Length > 0)
{
geoms.Add(new Geometry()
{
Vertices = vertices, Indices = indices, Color = color
});
}
}
UnityEngine.Profiling.Profiler.EndSample();
}
/// <summary>
/// Tessellates a path.
/// </summary>
/// <param name="contour">The path to tessellate</param>
/// <param name="pathProps">The path properties</param>
/// <param name="tessellateOptions">The tessellation options</param>
/// <param name="vertices">The resulting vertices</param>
/// <param name="indices">The resulting triangles</param>
/// <remarks>
/// The individual line segments generated during tessellation are made out of a set of ordered vertices. It is important
/// to honor this ordering so joining and and capping connect properly with the existing vertices without generating dupes.
/// The ordering assumed is as follows:
/// The last two vertices of a piece must be such that the first is generated at the end with a positive half-thickness
/// while the second vertex is at the end too but at a negative half-thickness.
/// No assumptions are enforced for other vertices before the two last vertices.
/// </remarks>
public static void TessellatePath(BezierContour contour, PathProperties pathProps, TessellationOptions tessellateOptions, out Vector2[] vertices, out UInt16[] indices)
{
if (tessellateOptions.StepDistance < Epsilon)
{
throw new Exception("stepDistance too small");
}
if (contour.Segments.Length < 2)
{
vertices = new Vector2[0];
indices = new UInt16[0];
return;
}
UnityEngine.Profiling.Profiler.BeginSample("TessellatePath");
float[] segmentLengths = VectorUtils.SegmentsLengths(contour.Segments, contour.Closed);
// Approximate the number of vertices/indices we need to store the results so we reduce memory reallocations during work
float approxTotalLength = 0.0f;
foreach (var s in segmentLengths)
{
approxTotalLength += s;
}
int approxStepCount = Math.Max((int)(approxTotalLength / tessellateOptions.StepDistance + 0.5f), 2);
if (pathProps.Stroke.Pattern != null)
{
approxStepCount += pathProps.Stroke.Pattern.Length * 2;
}
List <Vector2> verts = new List <Vector2>(approxStepCount * 2 + 32); // A little bit possibly for the endings
List <UInt16> inds = new List <UInt16>((int)(verts.Capacity * 1.5f)); // Usually every 4 verts represent a quad that uses 6 indices
var patternIt = new PathPatternIterator(pathProps.Stroke.Pattern, pathProps.Stroke.PatternOffset);
var pathIt = new PathDistanceForwardIterator(contour.Segments, contour.Closed, tessellateOptions.MaxCordDeviationSquared, tessellateOptions.MaxTanAngleDeviationCosine, tessellateOptions.SamplingStepSize);
JoiningInfo[] joiningInfo = new JoiningInfo[2];
HandleNewSegmentJoining(pathIt, patternIt, joiningInfo, pathProps.Stroke.HalfThickness, segmentLengths);
int rangeIndex = 0;
while (!pathIt.Ended)
{
if (patternIt.IsSolid)
{
TessellateRange(patternIt.SegmentLength, pathIt, patternIt, pathProps, tessellateOptions, joiningInfo, segmentLengths, approxTotalLength, rangeIndex++, verts, inds);
}
else
{
SkipRange(patternIt.SegmentLength, pathIt, patternIt, pathProps, joiningInfo, segmentLengths);
}
patternIt.Advance();
}
vertices = verts.ToArray();
indices = inds.ToArray();
UnityEngine.Profiling.Profiler.EndSample();
}
static Vector2[] TraceShape(BezierContour contour, Stroke stroke, TessellationOptions tessellateOptions)
{
if (tessellateOptions.StepDistance < Epsilon)
{
throw new Exception("stepDistance too small");
}
if (contour.Segments.Length < 2)
{
return(new Vector2[0]);
}
float[] segmentLengths = VectorUtils.SegmentsLengths(contour.Segments, contour.Closed);
// Approximate the number of vertices/indices we need to store the results so we reduce memory reallocations during work
float approxTotalLength = 0.0f;
foreach (var s in segmentLengths)
{
approxTotalLength += s;
}
int approxStepCount = Math.Max((int)(approxTotalLength / tessellateOptions.StepDistance + 0.5f), 2);
var strokePattern = stroke != null ? stroke.Pattern : null;
var strokePatternOffset = stroke != null ? stroke.PatternOffset : 0.0f;
if (strokePattern != null)
{
approxStepCount += strokePattern.Length * 2;
}
List <Vector2> verts = new List <Vector2>(approxStepCount); // A little bit possibly for the endings
var patternIt = new PathPatternIterator(strokePattern, strokePatternOffset);
var pathIt = new PathDistanceForwardIterator(contour.Segments, true, tessellateOptions.MaxCordDeviationSquared, tessellateOptions.MaxTanAngleDeviationCosine, tessellateOptions.SamplingStepSize);
verts.Add(pathIt.EvalCurrent());
while (!pathIt.Ended)
{
float distance = patternIt.SegmentLength;
float startingLength = pathIt.LengthSoFar;
float unitsRemaining = Mathf.Min(tessellateOptions.StepDistance, distance);
bool endedEntirePath = false;
for (;;)
{
var result = pathIt.AdvanceBy(unitsRemaining, out unitsRemaining);
if (result == PathDistanceForwardIterator.Result.Ended)
{
endedEntirePath = true;
break;
}
else if (result == PathDistanceForwardIterator.Result.NewSegment)
{
verts.Add(pathIt.EvalCurrent());
}
if ((unitsRemaining <= Epsilon) &&
!TryGetMoreRemainingUnits(ref unitsRemaining, pathIt, startingLength, distance, tessellateOptions.StepDistance))
{
break;
}
if (result == PathDistanceForwardIterator.Result.Stepped)
{
verts.Add(pathIt.EvalCurrent());
}
}
// Ending
if (endedEntirePath)
{
break;
}
else
{
verts.Add(pathIt.EvalCurrent());
}
patternIt.Advance();
}
if ((verts[0] - verts[verts.Count - 1]).sqrMagnitude < Epsilon)
{
verts.RemoveAt(verts.Count - 1);
}
return(verts.ToArray()); // Why not return verts itself?
}
