Does your GeneralPath contain straight line segments or quadratic or bezier segments? This matters a lot. The algorithm for the straight line is the most straightforward:

Iterate over all points in the path. If two consecutive points are on opposite sides of the line, you have a potential crossing. Then you need to check if the line segment end point is inside or outside the shape relative to the potential crossing, which you get by solving for the intersection of two points (the line and the line formed by the two consecutive points) and seeing if the result is contained in your line segment.

Unfortunately, the curved paths can have two consecutive points with a parenthesis shape between them ")", which your line can pass through while still keeping the iterable points on the same side. If you can get the format with two end points and a single (double) control point(s) that form a bounding triangle (quadrilateral), you can get easy simple solutions (since the curve is guaranteed to fit inside the triangle/quad formed by the three/four points, as long as the line doesn't intersect the triangle/quad, you are good). Unfortunately, this has an ugly part as well--if the line *does* intersect the triangle/quad, you aren't guaranteed anything and have to check closer. As a double unfortunate, I don't know a technique other than normalizing the coordinate system and solving for the zeroes. And that's something I'd look up in a book that I can't seem to find (or wait until another nice SO poster comes along).

... actually, since the curvature properties of the shapes are invariant under rotation, for the closer inspection part you can just rotate the curve points (whether 3 or 4) to be axis aligned. Then do your skinny rectangle trick. That's probably not the cleanest, but it's the most obvious trick.

Come to think of it, why not do the rotation of all the points in the first place? The whole intersection problem is rotation invariant. That would save a lot of code. Just axis-align the line, apply the transformation to the shape, and do your cheeky rectangle trick.