I don't think it is SO difficult.
I have answered the similar question on the friendly site and it was checked by a smaller community:
https://cs.stackexchange.com/questions/20039/detect-closed-shapes-formed-by-points/20247#20247

- Let's look for a more common question - let's take curves instead of polygons. And let's allow them to go out of the picture border, but we'll count only for simple polygons that wholly belong to the picture.
- find all intersections by checking all pairs of segments, belonging to different curves. Of course, filter them before real check for intersection.
- Number all curves 1..n. Set some order of segments in them.
- For every point create a sequence of intersections SOI, so: if it starts from the border end, SOI[1] is null. If not, SOI[1]= (number of the first curve it is intersecting with, the sign of the left movement on the intersecting curve). Go on, writing down into SOI every intersection - number of curve if there is some, or 0 if it is the intersection with the border.
- Obviously, you are looking only for simple bordered areas, that have no curves inside.
- Pieces of curves between two adjacent non-null intersection points we'll call segments.
- Having SOI for each curve:
- for segment of the curve 1, starting from the first point of the segment, make 2 attempts to draw a polygon of segments. It is 2 because you can go to 2 sides along the first intersecting curve.
- For the right attempt, make only left turns, for the left attempt, make only the right turns.
- If you arrive at point with no segment in the correct direction, the attempt fails. If you return to the curve 1, it success. You have a closed area.
- Remember all successful attempts
- Repeat this for all segments of curve 1
- Repeat this for all other curves, checking all found areas against the already found ones. Two same adjacent segments is enough to consider areas equal.

*How to find the orientation of the intersection.*

When segment p(p1,p2) crosses segment q(q1,q2), we can count the vector multiplication of vectors pXq. We are interested in only sign of its Z coordinate - that is out of our plane. If it is +, q crosses p from left to right. If it is -, the q crosses p from right to left.

The Z coordinate of the vector multiplication is counted here as a determinant of matrix:

```
0 0 1
p2x-p1x p2y-p1y 0
q2x-q1x q2y-q1y 0
```

(of course, it could be written more simply, but it is a good memorization trick)

Of course, if you'll change all rights for lefts, nothing really changes in the algorithm as a whole.

Robustlycomputing the intersection of polygons is difficult enough (threoretically, it's easy, but given the limited precision of floating point operations, and the "border case hell" of points/lines being (nearly) coincident, I'd be wary of implementing this on my own). I assume that when you ask for a "relatively fast" algorithm, you want to rule out the obvious one of doing pairwise tests of all polygons and their intersections? How many polygons do you have? – Marco13 Feb 15 '14 at 16:40everypolygon intersectseveryother polygon (and every intersection of pairs of other polygons) anyhow (like in your example!). The only possible optimization that I can currently think of is some sort of en.wikipedia.org/wiki/Bounding_volume_hierarchy to quickly rule out polygons that certainly donotintersect. Might this be a feasible approach for your application case? – Marco13 Feb 15 '14 at 16:57