Here is my Java implementation of this algorithm:

```
import java.awt.Point;
import java.awt.geom.Line2D;
import java.awt.geom.PathIterator;
import java.util.*;
/**
* Path2D helper functions.
* <p/>
* @author Gili Tzabari
*/
public class Path2Ds
{
/**
* Indicates if a Path2D intersects itself.
* <p/>
* @return true if a Path2D intersects itself
*/
public static boolean isSelfIntersecting(PathIterator path)
{
SortedSet<Line2D> lines = getLines(path);
if (lines.size() <= 1)
return false;
Set<Line2D> candidates = new HashSet<Line2D>();
for (Line2D line: lines)
{
if (Double.compare(line.getP1().distance(line.getP2()), 0) <= 0)
{
// Lines of length 0 do not cause self-intersection
continue;
}
for (Iterator<Line2D> i = candidates.iterator(); i.hasNext();)
{
Line2D candidate = i.next();
// Logic borrowed from Line2D.intersectsLine()
int lineRelativeToCandidate1 = Line2D.relativeCCW(line.getX1(), line.getY1(), line.
getX2(),
line.getY2(), candidate.getX1(), candidate.getY1());
int lineRelativeToCandidate2 = Line2D.relativeCCW(line.getX1(), line.getY1(), line.
getX2(),
line.getY2(), candidate.getX2(), candidate.getY2());
int candidateRelativeToLine1 = Line2D.relativeCCW(candidate.getX1(),
candidate.getY1(),
candidate.getX2(), candidate.getY2(), line.getX1(), line.getY1());
int candidateRelativeToLine2 = Line2D.relativeCCW(candidate.getX1(),
candidate.getY1(),
candidate.getX2(), candidate.getY2(), line.getX2(), line.getY2());
boolean intersection = (lineRelativeToCandidate1 * lineRelativeToCandidate2 <= 0)
&& (candidateRelativeToLine1 * candidateRelativeToLine2 <= 0);
if (intersection)
{
// Lines may share a point, so long as they extend in different directions
if (lineRelativeToCandidate1 == 0 && lineRelativeToCandidate2 != 0)
{
// candidate.P1 shares a point with line
if (candidateRelativeToLine1 == 0 && candidateRelativeToLine2 != 0)
{
// line.P1 == candidate.P1
continue;
}
if (candidateRelativeToLine1 != 0 && candidateRelativeToLine2 == 0)
{
// line.P2 == candidate.P1
continue;
}
// else candidate.P1 intersects line
}
else if (lineRelativeToCandidate1 != 0 && lineRelativeToCandidate2 == 0)
{
// candidate.P2 shares a point with line
if (candidateRelativeToLine1 == 0 && candidateRelativeToLine2 != 0)
{
// line.P1 == candidate.P2
continue;
}
if (candidateRelativeToLine1 != 0 && candidateRelativeToLine2 == 0)
{
// line.P2 == candidate.P2
continue;
}
// else candidate.P2 intersects line
}
else
{
// line and candidate overlap
}
return true;
}
if (candidate.getX2() < line.getX1())
i.remove();
}
candidates.add(line);
}
return false;
}
/**
* Returns all lines in a path. The lines are constructed such that the starting point is found
* on the left (or same x-coordinate) of the ending point.
* <p/>
* @param path the path
* @return the lines, sorted in ascending order of the x-coordinate of the starting point and
* ending point, respectively
*/
private static SortedSet<Line2D> getLines(PathIterator path)
{
double[] coords = new double[6];
SortedSet<Line2D> result = new TreeSet<Line2D>(new Comparator<Line2D>()
{
@Override
public int compare(Line2D o1, Line2D o2)
{
int result = Double.compare(o1.getX1(), o2.getX1());
if (result == 0)
{
// Ensure we are consistent with equals()
return Double.compare(o1.getX2(), o2.getX2());
}
return result;
}
});
if (path.isDone())
return result;
int type = path.currentSegment(coords);
assert (type == PathIterator.SEG_MOVETO): type;
Point.Double startPoint = new Point.Double(coords[0], coords[1]);
Point.Double openPoint = startPoint;
path.next();
while (!path.isDone())
{
type = path.currentSegment(coords);
assert (type != PathIterator.SEG_CUBICTO && type != PathIterator.SEG_QUADTO): type;
switch (type)
{
case PathIterator.SEG_MOVETO:
{
openPoint = startPoint;
break;
}
case PathIterator.SEG_CLOSE:
{
coords[0] = openPoint.x;
coords[1] = openPoint.y;
break;
}
}
Point.Double endPoint = new Point.Double(coords[0], coords[1]);
if (Double.compare(startPoint.getX(), endPoint.getX()) < 0)
result.add(new Line2D.Double(startPoint, endPoint));
else
result.add(new Line2D.Double(endPoint, startPoint));
path.next();
startPoint = endPoint;
}
return result;
}
}
```