# Can this be solved with a line sweep algorithm?

Edit: Now I think this is a sweep line problem. (see update2 at the bottom)

In this problem we are given `N` objects and `M` constraints. (`N` can be `200k`, `M` can be `100k`). Each object is either black, or white. Each constraint is in the form `(x, y)` and means that in the range of objects `x..y`, there is exactly one white object; the rest are black. We would like to determine the maximum number of white objects that can exist, or if it isn't possible to satisfy the constraints.

I observe that if a constraint is fully contained in another, the inner constraint will dictate where a white object can be placed. Also, if there are several non-intersecting constraints contained within another, it should be impossible since it violates the fact that there can only be one white object per constraint. The algorithm should be fast enough to run under 2-3 seconds.

Update: One of the answers mentions the exact cover problem; is this a specialized instance that isn't NP-complete?

Update2: If we change each constraint into a begin and end event, and sort these events, could we just systematically sweep across these events and assign white objects?

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"Also, if there are several non-intersecting constraints contained within another, it should be impossible since it violates the fact that there can only be one white object per constraint." I don't follow; when are constraints both non-intersecting and contained within another? I assumed by "contained within another" you meant of the form (x,y) (u,v) where x <= u < v <= y, but the intersection then clearly is (u,v). If that is the case, this kind of nested constraint can be solved by placing one white vertex in the innermost constraint and the coloring the rest of the outermost const. black. –  G. Bach Apr 6 '13 at 17:12
Yes that is what I meant and now that I think of it, do you think just greedily determining the white objects by processing/simulating something could just work? –  Zheyang Shen Apr 6 '13 at 17:14
This is perhaps a better match for cs.stackexchange.com... –  vonbrand Apr 6 '13 at 17:24
This doesn't look like a graph problem at all. Where are the edges? –  n.m. Apr 6 '13 at 17:25
Hm I'm not certain about greedy, it does seem to me that after reducing the constraint system, you should be able to do that and apply combinatorial methods. Maybe it'll help to think about reduction rules you can derive for the constraint system. For example, assume you have three constraints (a,c) (b,f) (d,e) with a<= b <= c < d <= e <=f. You then know that you can reduce (a,c) to (a,b) because the nested constraint (b,f) (d,e) will force you to color (b,c) black. That's where I would start. I think there should be a couple more reduction rules than that example illustrates. –  G. Bach Apr 6 '13 at 17:27

Yes, there's a (point)-sweep algorithm. This one is sort of inelegant, but I think it works.

First, sweep for nested intervals. Process begin and end events in sorted order (tiebreakers left to you) and keep a list of active intervals not known to contain another interval. To handle a begin event, append the corresponding interval. To handle an end event, check whether the corresponding interval `I` has been removed. If not, remove `I` and all of the remaining intervals `J` before `I` from the list. For each such `J`, append two intervals whose union is the set difference `J \ I` to a list of blacked out intervals.

Second, sweep to contract the blacked out intervals. In other words, delete the objects known to be black, renumber, and adjust the constraints accordingly. If an entire constraint is blacked out, then there is no solution.

Third, sweep to solve the problem on what are now non-nested intervals. The greedy solution is provably optimal.

Example: suppose I have half-open constraints [0, 4), [1, 3), [2, 5). The first sweep creates blackouts [0, 1) and [3, 4). The second sweep leaves constraints [a, c), [a, c), [b, d).* The greedy sweep places white objects at new locations a, c, d (old locations 1, 4, 5).

Illustration of the second sweep:

``````0 1 2 3 4 5  old coordinates
[       )
[   )
[     )
**    **     blackouts
a b   c d  new coordinates
[       )
[   )
[     )
``````
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Can you elaborate on the first step? What if the intervals aren't fully intersecting? –  Zheyang Shen Apr 7 '13 at 17:14
`I` is always a subinterval of `J`. If `I1` and `I2` overlap but don't nest, nothing happens yet. –  David Eisenstat Apr 7 '13 at 17:17
Added a small example. –  David Eisenstat Apr 7 '13 at 17:43
`a` is the first object not in a blackout interval. `b` is the second... –  David Eisenstat Apr 7 '13 at 18:38
So I suppose my overarching question is: how do you map the old coordinates to the new coordinates, if the old coordinate has been blacked out? –  Zheyang Shen Apr 7 '13 at 19:38