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I've been trying to find the optimal solution to the following (interesting?) problem that came up at work: Eventually I settled for a good enough solution but I'd like to know if there's a better one.

Let a1...an be an array of strings.

Let s1...sk be an unordered list of strings, all of them also members of the array.

The task is to find the minimum set of index ranges eleements of s cover in a.

So for example if a = [ "x", "y", "a", "f", "c" ] and s = { "c","y","f" }, the answer would be (1;1), (3;4), assuming that the array is indexed from zero.

a is typically fairly large (hundreds of thousands of elements), while s is relatively small, typically length(s) < log(length(a)).

So the question is: can you find a time-efficient algorithm for this problem? (Space efficiency is not a concern within reasonable limits.)

Just a quick but important update: I need to perform this operation with different s values but the same a a lot. So precomputing stuff based on a is allowed, indeed it is the only way.

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You mean (S0:A4),(S1:A1),(S2:F4)? – Muggen Mar 2 '11 at 21:24
No, I mean that "c" and "f" are consecutive in a, and they span a range between indices 3-4, "y" stands alone, so it's just a range of 1-1. – biziclop Mar 2 '11 at 21:27
ok I see now. thanks. – Muggen Mar 2 '11 at 21:29
I'm guessing it's an important part of the algorithm that the members of "a" aren't necessarily distinct? (Otherwise you just look up the positions of each string in a map, sort them, and coalesce sequential ones). – Chris Nash Mar 2 '11 at 21:43
@Chris Nash No, they are distinct, so this approach works. It just didn't feel optimal somehow. But maybe I have to concede that it is. – biziclop Mar 2 '11 at 21:46
up vote 3 down vote accepted

Build a hash table H(a) to map from element to index: ax->x in O(n) time and space. Then look up each sy in H(a) (in O(1) time on average for a total of O(k) for s) and keep track of the ranges. For that you can use an array of pair(min_index, max_index) sorted by min_index and do a binary search to either locate the range or where you should insert the new 1 element range.
So overall, the solution above would take O( n + k + k * log( nb_ranges ) ) time and O( n + nb_ranges ) space.

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This is what you want, written in python:

def flattened(indexes):
    s, rest = indexes[0], indexes[1:]
    result = (s, s)
    for e in rest:
        if e == result[1] + 1:
            result = (result[0], e)
            yield result
            result = (e, e)
    yield result

a = ["x", "y", "a", "f", "c"]
s = ["c", "y", "f"]

# Create lookup table of ai to index in a
src_indexes = dict((key, i) for i, key in enumerate(a))

# Create sorted list of all indexes into a
raw_dst_indexes = sorted(src_indexes[key] for key in s)

# Convert sorted list of indexes into an array of ranges
dst_indexes = [r for r in flattened(raw_dst_indexes)]

print dst_indexes
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I think you can throw the elements of S into a set or hashtable, anything with near O(1) to check for membership. Then just do a linear scan on A, with a flag to determine if you are currently covering elements in S, and the start position of that cover. Should be O(n + k).

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Well, this was my original idea and it proved to be kinda slow. – biziclop Mar 2 '11 at 21:32

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