public static IEnumerable <double> GetRedAnchorCompletions(SliderPath sliderPath)
{
int start = 0;
int end = 0;
double totalLength = 0;
var anchors = sliderPath.ControlPoints;
for (int i = 0; i < anchors.Count; i++)
{
end++;
if (i == anchors.Count - 1 || anchors[i] != anchors[i + 1])
{
continue;
}
var cpSpan = anchors.GetRange(start, end - start);
var subdivision = new BezierSubdivision(cpSpan);
totalLength += subdivision.SubdividedApproximationLength();
yield return(totalLength / sliderPath.Distance);
start = end;
}
}
public BezierSubdivision Prev() // Previous index at current level
{
var next = new BezierSubdivision(new List <Vector2>(Points), Level, Index - 1);
next.ScaleRight(-1);
next.Reverse();
return(next);
}
public BezierSubdivision Next() // Next index at current level
{
var next = new BezierSubdivision(new List <Vector2>(Points), Level, Index + 1);
next.ScaleLeft(2);
next.Reverse();
return(next);
}
public static IEnumerable <BezierSubdivision> ChopAnchorsLinear(List <Vector2> anchors)
{
for (int i = 1; i < anchors.Count; i++)
{
var subdivision = new BezierSubdivision(new List <Vector2> {
anchors[i - 1], anchors[i]
});
yield return(subdivision);
}
}
public double LengthToT(double length, double precision = 0.1, double tolerance = 0.25) // approximate bezier progress t for a desired path length, t can be > 1
{
if (Length() == 0)
{
return(double.NaN);
}
if (length <= 0)
{
return(0);
}
BezierSubdivision baseSubdivision = null;
LinkedListNode <BezierSubdivision> current = null;
double l = 0;
double lnext = 0;
while (length > lnext)
{
current = current?.Next;
if (current == null)
{
baseSubdivision = baseSubdivision == null ? this : baseSubdivision.Next();
var pathApproximation = new LinkedList <BezierSubdivision>();
pathApproximation.AddLast(baseSubdivision);
Subdivide(ref pathApproximation, tolerance);
current = pathApproximation.First;
}
l = lnext;
lnext += current.Value.ApproximationLength();
}
var curr = current.Value;
while (curr.ApproximationLength() > precision)
{
curr.Children(out var left, out var right);
lnext = l + left.ApproximationLength();
if (length > lnext)
{
curr = right;
l = lnext;
}
else
{
curr = left;
}
}
return((curr.Index + (length - l) / curr.ApproximationLength()) / (1 << curr.Level));
}
public BezierSubdivision Parent() // Parent subdivision (inverse of BezierSubdivide)
{
var parent = new BezierSubdivision(new List <Vector2>(Points), Level - 1, Index >> 1);
if ((Index & 1) == 0)
{
parent.ScaleRight(2);
}
else
{
parent.ScaleLeft(-1);
}
return(parent);
}
public void Children(out BezierSubdivision leftChild, out BezierSubdivision rightChild) // Child subdivisions (BezierSubdivide)
{
var left = new List <Vector2>(Points);
var right = new List <Vector2>(Points);
for (int j = 0; j < Order; j++)
{
for (int i = Order; i > j; i--)
{
left[i] = (left[i] + left[i - 1]) / 2;
right[Order - i] = (right[Order - i] + right[Order - i + 1]) / 2;
}
}
leftChild = new BezierSubdivision(left, Level + 1, Index << 1);
rightChild = new BezierSubdivision(right, Level + 1, Index << 1 | 1);
}
public static IEnumerable <BezierSubdivision> ChopAnchors(List <Vector2> anchors)
{
int start = 0;
int end = 0;
for (int i = 0; i < anchors.Count; i++)
{
end++;
if (i != anchors.Count - 1 && anchors[i] != anchors[i + 1])
{
continue;
}
var cpSpan = anchors.GetRange(start, end - start);
var subdivision = new BezierSubdivision(cpSpan);
yield return(subdivision);
start = end;
}
}
public static List <Vector2> MoveAnchorsToLength(List <Vector2> anchors, PathType pathType, double newLength, out PathType newPathType)
{
var newAnchors = new List <Vector2>();
var sliderPath = new SliderPath(pathType, anchors.ToArray(), newLength);
var maxSliderPath = new SliderPath(pathType, anchors.ToArray());
if (newLength > maxSliderPath.Distance)
{
// Extend linearly
switch (pathType)
{
case PathType.Bezier:
newPathType = PathType.Bezier;
newAnchors.AddRange(anchors);
newAnchors.Add(anchors.Last());
newAnchors.Add(sliderPath.PositionAt(1));
break;
case PathType.Catmull:
case PathType.PerfectCurve:
// Convert to bezier and then extend
newPathType = PathType.Bezier;
newAnchors = BezierConverter.ConvertToBezier(sliderPath).ControlPoints;
newAnchors.Add(anchors.Last());
newAnchors.Add(sliderPath.PositionAt(1));
break;
default:
newPathType = pathType;
newAnchors.AddRange(anchors);
newAnchors[newAnchors.Count - 1] = sliderPath.PositionAt(1);
break;
}
}
else
{
switch (sliderPath.Type)
{
case PathType.Catmull:
case PathType.Bezier:
newPathType = PathType.Bezier;
// Convert in case the path type is catmull
var convert = BezierConverter.ConvertToBezier(sliderPath).ControlPoints;
// Find the last bezier segment and the pixel length at that part
BezierSubdivision subdivision = null;
double totalLength = 0;
foreach (var bezierSubdivision in ChopAnchors(convert))
{
subdivision = bezierSubdivision;
var length = bezierSubdivision.SubdividedApproximationLength();
if (totalLength + length > newLength)
{
break;
}
totalLength += length;
newAnchors.AddRange(bezierSubdivision.Points);
}
if (subdivision == null)
{
break;
}
// Find T for the remaining pixel length
var t = subdivision.LengthToT(newLength - totalLength);
// ScaleRight the BezierSubdivision so the anchors end at T
subdivision.ScaleRight(t);
// Add the scaled anchors
newAnchors.AddRange(subdivision.Points);
break;
case PathType.PerfectCurve:
newPathType = PathType.PerfectCurve;
newAnchors.AddRange(anchors);
newAnchors[1] = sliderPath.PositionAt(0.5);
newAnchors[2] = sliderPath.PositionAt(1);
break;
default:
newPathType = pathType;
if (anchors.Count > 2)
{
// Find the section of the linear slider which contains the slider end
totalLength = 0;
foreach (var bezierSubdivision in ChopAnchorsLinear(anchors))
{
newAnchors.Add(bezierSubdivision.Points[0]);
var length = bezierSubdivision.Length();
if (totalLength + length > newLength)
{
break;
}
totalLength += length;
}
newAnchors.Add(sliderPath.PositionAt(1));
}
else
{
newAnchors.AddRange(anchors);
newAnchors[newAnchors.Count - 1] = sliderPath.PositionAt(1);
}
break;
}
}
return(newAnchors);
}