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I have number of simple polygons which do not intersect each other but some polygons may be embedded into others.

For example:

|                                            |
|   +----------------+          +--------+   |
|   |                |         /         |   |
|   |   +--------+   |        /          |   |
|   |   |        |   |       /  +----(2)-+   |
|   |   |        |   |      /   |            |
|   |   +----(3)-+   |     /    |   +---+    |
|   |                |    +-----+   |   |    |
|   +------------(2)-+              +(2)+    |
|                                            |

How to find out the "depth" of all the polygons? In other words, how to find out by how many polygons a polygon is encompassed by? The "depth" are the numbers in parentheses.

I could count how many times a point of a polygon is inside of all the other polygons but this has quadratic complexity. How to compute those depths faster?

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What data structure(s) are you using to store your polygons ? –  High Performance Mark Jan 17 '13 at 17:41
[[v1, v2, v3], [v4, v5, v6, v7], [v8, v9, ... - basically a flat list, without any tree-like structure, if that's what you meant. –  Ecir Hana Jan 17 '13 at 17:47
@EcirHana by simple polygons do you actually mean simple polygons or do you mean rectangular axis-aligned simple polygons ? –  mmgp Jan 17 '13 at 19:35
@EcirHana this is handled by the paper "Polygon Nesting and Robustness", I might include a answer later if no one gives it earlier. –  mmgp Jan 17 '13 at 20:02
If you need to know the depth of a given polygon P, and you have a point O garanteed to be outside (of every polygons), perhaps counting the number of polygons uniquely intersected by the segment between O and the vertex of P closest to O could work. –  didierc Jan 18 '13 at 0:48

4 Answers 4

Put your polygons into some kind of spatial lookup structure, for example an R-tree based on the minimum bounding rectangles for the polygons. Then you should be able to compute the containment relation that you're after in O(n log n). (Unless you're in a pathological case where many of the minimum bounding rectangles for your polygons overlap, which seems unlikely based on your description.)

Edited to add: of course, you don't rely on the R-tree to tell you if one polygon is inside another (it's based on minimum bounding rectangles so it can only give you an approximation). You use the R-tree to cheaply identify candidate inclusions which you then verify in the expensive way (checking that a point in one polygon is inside the other).

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This is a very simplistic approach that doesn't need pathological cases at all to fail. Suppose there is a large polygon shaped like a "C", if we put a square in the free empty area of "C", why would you say that this square is contained by the other polygon ? Or maybe this is the pathological case and I'm adding unneeded requirements to a question that isn't mine. –  mmgp Jan 18 '13 at 1:00
@mmgp: You've misunderstood my proposal. See the edit. –  Gareth Rees Jan 18 '13 at 1:06
Thanks for the answer but I don't think it will work. The problem is the time needed to build the lookup structure as it wont be reused again (i.e. the polygons may be different every time). Also, bboxes may or may not overlap, that's 50% and that's a lot :). –  Ecir Hana Jan 18 '13 at 8:17
It costs O(n log n) to build the R-tree, so I don't think that's a concern. –  Gareth Rees Jan 18 '13 at 10:51
@EcirHana this will work, building up an spatial index can be extremly fast, i recommend using an PMR bucket Rectangle quadtree as spatial index. –  AlexWien Mar 30 '13 at 2:27

(This approach follows a similar idea to @GarethRees 's: first, cheaply discover which pairs of polygons you don't need to check for inclusion. Once the number of pairs still needed to check is acceptable, do the exact (expensive) geometric check.)

It's easy to calculate for each polygon p the bounding rectangle, i.e. the left, right, top and bottom, so let's do that first. E.g. for left: p.L = min { x : (x,y) is a vertex of p } Time is linear in the number of points.

To avoid having to compare each polygon to each other one, you could divide up the area into a 2x2 grid. Suppose the width and height of the area are respectively given by Dx and Dy, then you can create nine sets top,bottom,left,right,topright,topleft,bottomright,bottomleft,rest and do the following:

for p in polygons:
    in_top    = p.B > Dy/2
    in_bottom = p.T < Dy/2
    in_left   = p.R < Dx/2
    in_right  = p.L > Dx/2 
    if in_top:
        if in_left:
            add p to topleft
        elsif in_right:
            add p to topright
            add p to top
    elsif in_bottom:
        if in_left:
            add p to bottomleft
        elsif in_right:
            add p to bottomright
            add p to bottom

    if in_right and not (in_top or in_bottom):
        add p to right
    elsif in_left and not (in_top or in_bottom):
        add p to left

    if not (in_top or in_bottom or in_left or in_right):
        add p to rest

This is again linear time. Each polygon has been binned into its most "tightly" containing sector. What have you gained by this? Well, you know for example that for any polygon p in left there can't possibly be any inclusion relationship with set right, so you don't need to compare them. Likewise between bottomleft and right, bottomleft and topleft, and so on. Here is what it would look like on your example:

|                      |                     |
|   +----------------+ |        +--------+   |
|   |                | |       /         |   |
|   |   +--------+   | |      /          |   |
|___|___|________|___|_|____ /__+===d(2)=+___|_ Dy/2
|   |   |        |   | |    /   |            |
|   |   +---b(3)-+   | |   /    |   +---+    |
|   |                | |  +-----+   |   |    |
|   +-----------c(2)-+ |            e(2)+    |
|                      |                     |

So rest = {a}, top = {}, bottom = {}, left = {b,c}, right = {d}

topleft = {}, topright = {}, bottomleft = {}, bottomright = {e}

So basically now you need to compare (with the expensive exact check) at most b to c, d to e, and a to all others -- in fact, if you order the checks in a clever way, you won't need to compare a to all others, because inclusion is transitive, so if you notice that c includes b, and a includes c, then you do not need to check if a includes b.

Another point is that you can apply the above reasoning recursively. Say for example the set topright is too big for your taste; you can then apply the same technique by further dividing up that subregion (just need to get the book-keeping right).

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Thanks for the detailed answer! Unfortunately, I'm really interested in those "expensive exact" checks. I'm aware that I could use spatial hashing, bounding boxes or bounding hierarchies but as far as I understand none of them speeds up the worst case. The paper "Polygon Nesting and Robustness" mentioned above by @mmgp seems to be closest to the right approach but it's a bit difficult to transform it to working code. –  Ecir Hana Jan 29 '13 at 15:13
@EcirHana : I am editing the answer to include such a check. –  mitchus Jan 29 '13 at 15:18
before you do, what complexity do they have? –  Ecir Hana Jan 29 '13 at 15:20
@EcirHana : the number of vertices of polygon 1 times the number of vertices of polygon 2. –  mitchus Jan 29 '13 at 15:22
Divided by two, yes. This is what I propose in the question myself and would like to improve on it. –  Ecir Hana Jan 29 '13 at 15:25

Seems to me you get get away with sorting the polygons, using a test of whether one is inside another as the comparison operator.

Step 1

Suppose we define the relation '<' between polygons as follows: A < B iff A is inside B. It so happens that if A < B and B < C, then A < C (i.e. if polygon A is inside B and B is inside C, then A must be inside C). Now, we have a strict weak ordering between arbitrary polygons.

[Edit: You'd need to use some sort of point-inside-non-convex-polygon test, but presumably you are doing that already.]

Step 2

Sort the polygons according to this comparison using your favorite comparison-based sorting algorithm. For instance, merge sort has a worst-case time complexity of O(nlogn) comparisons where n is the number of polygons.

[Edit: This is the important step, because it gets rid of the quadratic complexity.]

Step 3

Ensure that the "largest" (i.e. outermost) element is first on your sorted array of polygons. (Reverse the list if necessary to achieve this - it is linear on the number of polygons).

Step 4

Now the "largest" (i.e. outermost) polygon should be the first element.

[Edit: In fact, the polygons have been sorted according to their depth. However, two polygons that have the same depth may appear in different orders depending on whether the sort was stable. This doesn't matter to us; what we are interested in is the change in depth.]

We will now assign a depth to each polygon as follows. Firstly, initialize the depth of each one to 0 ([Edit: initialize to 1, according to the example]). Next, iterate through your sorted list, but this time compare each element p only to the next element p+1. If (p+1 < p) is true, then increment the depth of p+1. Else, set the depth of p+1 to be the same as the depth of p.

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What if none of the polygons is nested? I.e., what if all of the polygons are "outermost"? –  Ecir Hana Mar 29 '13 at 22:48
Then under any order, they would be considered sorted, and they would all have a depth of 0 since every comparison < will return false. Isn't that what you want? –  maditya Mar 29 '13 at 23:05
Also, just realized your "outermost" depth should be 1 (according to your example). This is achieved by initializing the depth to 1 instead of 0 in Step 4. –  maditya Mar 29 '13 at 23:08
What I try to say is that sorting performs n log n comparisons and each comparison has linear complexity. So it's O(n n log n) - worse than the naive version from the question. –  Ecir Hana Mar 30 '13 at 1:16

Step 1: Orient your polygons in the same direction, say counter-clockwise.

Step 2: For any point (x, y) for which you need to compute the "depth" for compute the total winding number. This can be done in a number of ways; the fastest one in practice is to compute the SIGNED number of intersections between the horizontal (or vertical) ray originating in (x, y).

In particular, the depth for each polygon would be the depth of any of its vertices.

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Step 2 has linear complexity and I have to repeat it for all the polygons so it has the same quadratic complexity as the original approach above. –  Ecir Hana Aug 28 '13 at 10:23

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