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For a part of a divide and conquer algorithm, I have the following question where the data structure is not fixed, so set is not to be taken literally:

Given a set X sorted wrt. some ordering of elements and subsets A and B together consisting of all elements in X, can sorted versions A' and B' of A and B be constructed in time linear in the number of elements in X ?

At the moment I am doing a standard sort at each recursive step giving the recursion

T(n) = 2*T(n/2) + O(n*log n)

for the complexity rather than

T(n) = 2*T(n/2) + O(n)

like in the procedural version, where one can utilize a structure with constant-time lookup on A and B to form A' and B' in linear time.

The added log n factor carries over to the overall complexity, giving O(n* (log n)^2) instead of
O(n* log n).

EDIT: Perhaps I am understanding the term lookup incorrectly. The creation of A' and B' in linear time is easy to do if membership of A and B can be checked in constant time.

I didn't succeed in my attempt at making things clearer by abstracting away the specifics, so here is the actual problem:

I am implementing the algorithm for the closest pair problem. Given a finite collection P of points in the plane it finds a pair of points in P with the minimal distance. It works roughly as follows:

If P has at least 4 points, form Px and Py, the points in P sorted by x- and y-coordinate. By splitting Px form L and R, the left- and right-most halves of points. Recursively compute the closest pair distance in L and R, let d be the minimum of the two. Now the minimum distance in P is either d or the distance from a point in L to a point in R. If the minimal distance is between points from separate halves, it will appear between a pair of points lying in the strip of width 2*d centered around the line x = x0, where x0 is the x-coordinate of a right-most point in L. It turns out that to find a potential minimal distance pair in the strip, it is enough to compute for every point in the the strip its distance to the seven following points if the strip points are in a collection sorted by y-coordinate.

It is in the steps with forming the sorted collections to pass into the recursion and sorting the strip points by y-coordinate where I don't see how to, in Haskell, utilize having sorted P at the beginning of the recursion.

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What Haskell has to do with this? –  n.m. Jul 27 '11 at 10:04
I am implementing this in Haskell. In a language where one have access to a constant-time lookup data structure it is trivial to do, so the question exists because of the characteristics of Haskell. –  user847614 Jul 27 '11 at 10:18
OK, so what lookup, constant-time or otherwise, has to do with this? A list can be partitioned in two in linear time. If it was sorted, the two halves will stay sorted. Why do you need to sort at each recursive step? What are you trying to do? –  n.m. Jul 27 '11 at 10:29
Are you asking if there's a 'set' data structure that has this property? –  augustss Jul 27 '11 at 10:31
@n.m I am not partitioning a sorted data structure. I have the sorted data structure X and a disjoint union of X (A, B) and am asking if, in Haskell, it is possible to form (A', B') in linear time where A' and B' are sorted versions of A and B. What constant-time lookup has to do with this is that in a language with constant-time lookup for some data structure, doing what I want to do is trivial. Specifically I am implementing the closest pair algorithm for points in the plane. –  user847614 Jul 27 '11 at 10:51

2 Answers 2

The following function may interest you:

partition :: (a -> Bool) -> [a] -> ([a], [a])
partition f xs = (filter f xs, filter (not . f) xs)

If you can compute set-membership in constant time, that is, there is a predicate of type a -> Bool that runs in constant time, then partition will run in time linear in the length of its input list. Furthermore, partition is stable, so that if its input list is sorted, then so are both output lists.

I would also like to point out that the above definition is meant to be give the semantics of partition only; the real implementation in GHC only walks its input list once, even if the entire output is forced.

Of course, the real crux of the question is providing a constant-time predicate. The way you phrased the question leaves sets A and B quite unstructured -- you demand that we can handle any particular partitioning. In that case, I don't know of any particularly Haskell-y way of doing constant-time lookup in arbitrary sets. However, often these problems are a bit more structured: often, rather than set-membership, you are actually interested in whether some easily-computable property holds or not. In this case, the above is just what the doctor ordered.

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I know very very little about Haskell but here's a shot anyway.

Given that (A+B) == X can;t you just iterate through X (in the sorted order) and add each element to A' or B' if it exists in A or B? Give linear time lookup of element x in the Sets A and B that would be linear.

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That is exactly what I am doing in my Java implementation, but I don't see yet how to get the linear time lookup in Haskell. –  user847614 Jul 28 '11 at 10:38

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