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I have a set of non-intersecting lines, some of which are connected at vertices. I'm trying to find the smallest polygon, if one exists, that encloses a given point. So, in the image below, out of the list of all the line segments, given the point in red, I want to get the blue ones only. I'm using Python, but could probably adapt an algorithm from other languages; I have no idea what this problem is called.


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I don't think the problem statement is correct (unambiguous). The smallest polygon around the red point can be formed by the vertex to the southwest of the point and by the black line segment east of the point. – Alexey Frunze Apr 22 '13 at 7:36
What I meant was, the smallest polygon formed only from lines that already exist. – Skyler Apr 22 '13 at 16:18
define "smallest" – Cam May 1 '13 at 6:08
@JoshSchultz: Even though the bounty expired, what details were you wanting from n.m.'s answer? – Teepeemm Nov 14 '13 at 19:40
@Teepeemm I was hoping to see an implementation or two, tbh. Perhaps a bit clearer description. I am going to need to implement something like the current top answer, methinks. – Josh Schultz Nov 14 '13 at 20:53

First, remove all line segments that have at least one free endpoint, not coincident with any other segment. Do that repeatedly until no such segment remains.

Now you have a plane nicely subdivided into polygonal areas.

Find a segment closest to your point. Not the closest endpoint but the closest segment, mind you. Find out which direction along the segment you need (your point should be to the right of the directed segment). Go to the endpoint, turn right (that is, take the segment next to the one you came from, counting counterclockwise). Continue going to the next endpoint and turning right until you hit the closest segment again.

Then, check if the polygon encloses the given point. If it is not, then you have found an "island"; remove that polygon and the entire connected component it belongs to, and start over by selecting the nearest segment again. Connected components can be found with a simple DFS.

This gives you a clockwise-oriented polygon. If you want counterclockwise, which is often the default "positive" direction in both the software an the literature, start with the point to your left, and turn left at each intersection.

It surely helps if, given an endpoint, you can quickly find all segments incident with it.

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Then, check if the polygon encloses the given point. – WolframH Apr 22 '13 at 12:23
@WolframH: yes, of course, forgot to add that. A point could be outside of any closed polygon. – n.m. Apr 22 '13 at 12:33
What if the closest line segment is in a different polygon that doesn't enclose the point? – Skyler Apr 22 '13 at 17:01
@Skyler: sorry I keep forgetting to mention important things. it's been a while I've done comp geom algorithms. Answer updated. – n.m. Apr 23 '13 at 3:02
you could brute force construct all possible polygons, then check for inside each. If its a small problem or you need to repeat for multiple points that may be better than trying to be smart about looking for near edges first. – agentp Apr 23 '13 at 20:33

This is really just an implementation of @n.m.'s answer. This is how far I got before the bounty expired; it's completely untested.

def smallestPolygon(point,segments):
    :param point: the point (x,y) to surrond
    :param segments: the line segments ( ( (a,b),(c,d) ) , . . . )
    that will make the polygon
    (assume no duplicates and no intersections)
    :returns: the segments forming the smallest polygon containing the point
    connected = list(segments)

    def endPointMatches(segment1,segment2):
        Which endpoints of segment1 are in segment2 (with (F,F) if they're equal)
        if ( segment1 == segment2 or segment1 == segment2[::-1] ):
            return ( False, False )
        return ( segment1[0] in segment2 , segment1[1] in segment2 )

    keepPruning = True
    while ( keepPruning ):
        keepPruning = False
        for segment in connected:
            from functors import partial
            endPointMatcher = partial(endPointMatches,segment1=segment)
            endPointMatchings = map(endPointMatcher,connected)
            if ( not and(*map(any,zip(*endPointMatchings))) ):
                keepPruning = True

    def xOfIntersection(seg,y):
        :param seg: a line segment ( (x0,y0), (x1,y1) )
        :param y: a y-coordinate
        :returns: the x coordinate so that (x,y) is on the line through the segment
        return seg[0][0]+(y-seg[0][1])*(seg[1][0]-seg[0][0])/(seg[1][1]-seg[0][1])

    def aboveAndBelow(segment):
        return ( segment[0][1] <= point[1] ) != ( segment[1][1] <= point[1] )

    # look for first segment to the right
    closest = None
    smallestDist = float("inf")
    for segment in filter(aboveAndBelow,connected):
        dist = xOfIntersection(segment,point[1])-point[0]
        if ( dist >= 0 and dist < smallestDist ):
            smallestDist = dist
            closest = segment

    # From the bottom of closest:
    # Go to the other end, look at the starting point, turn right until
    # we hit the next segment.  Take that, and repeat until we're back at closest.
    # If there are an even number of segments directly to the right of point[0],
    # then point is not in the polygon we just found, and we need to delete that
    # connected component and start over
    # If there are an odd number, then point is in the polygon we found, and we
    # return the polygon
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If you're doing this a number of times with the same lines and different points, it would be worthwhile preprocessing to figure out all the polygons. Then it's straightforward: draw a line from the point to infinity (conceptually speaking). Every time the you cross a line, increment the crossing count of each polygon the line is a part of. At the end, the first polygon with an odd crossing count is the smallest enclosing polygon. Since any arbitrary line will do just as well as any other (it doesn't even need to be straight), simplify the arithmetic by drawing a vertical or horizontal line, but watch out for crossing actual endpoints.

You could do this without preprocessing by creating the polygons as you cross each line. This basically reduces to n.m.'s algorithm but without all the special case checks.

Note that a line can belong to two polygons. Indeed, it could belong to more, but it's not clear to me how you would tell: consider the following:

|                           |
|   +-------------------+   |
|   |                   |   |
|   |   +-----------+   |   |
|   |   |           |   |   |
|   |   |           |   |   |
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How many polygons would you consider in your example - 3 or 6? How do you find them? – WolframH Apr 23 '13 at 11:05
There are 3 minimal polygons (those that are not parts of other polygons) and exactly 6 segments belong to two polygons each (the two inner &Pi;-shaped polylines). – n.m. Apr 23 '13 at 12:56
@WolframH: There are three polygons, certainly. If you don't know which ones there are, then you have to assume that no polygon includes another. But had the two outer polygons dropped a fraction of a pixel down (two fractions for the outermost one) then you'd have a different reading. – rici Apr 23 '13 at 13:34
@n.m.: I somewhat agree, but how do you define "not parts of other polygons" in a way that excludes islands? Just curious, really... I don't think you can produce any other answer than yours by analysing the individual line segments. – rici Apr 23 '13 at 13:35
@rici: For consistency it is best to operate in terms of polygons with holes. Then islands are not a problem, they are not a part of some other polygon, they just fit in some hole. The implementation is somewhat more complex though. My algorithm does not compute holes. If holes are desirable, they have to be searched for e.g. like follows: given a polygon, start checking all vertices not belonging to it. If a vertex lies inside that polygon, find an eliminate its connected component, then find its outer border; it is a hole. Then check the next remaining vertex etc. – n.m. Apr 23 '13 at 14:30

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