# Subsequence of strings

I implemented a python function that returns the longest common subsequence of 2 strings. Now, I'd like to implement a function that returns the longest common subsequence of any number of strings.

I found this help for 3 strings:

``````dp[i, j, k] = / 1 + dp[i - 1, j - 1, k - 1] if A[i] = B[j] = C[k]
\ max(dp[i - 1, j, k], dp[i, j - 1, k], dp[i, j, k - 1]) otherwise
``````

But I don't really understand this hint. So, I'd be thankful if anybody could help me. Best regards, Mark

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if this is homework, please use the `homework` tag, thanks! –  ninjagecko May 23 '12 at 21:28
By "found help" do you mean stackoverflow.com/questions/4705276/…? –  Ben May 23 '12 at 21:29
@ninjagecko: No, it's just a problem I'm interested in. –  MarkF6 May 23 '12 at 22:03
@Ben: Exactly :) –  MarkF6 May 23 '12 at 22:03

The LCS problem is NPComplete for an unbound number of string n. meaning, there is no known polynomial algorithm capable of solving this. Also meaning that you can drop the DP solution :p

Here's a link to an heuristic method to approximate the LCS of multiple strings.

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Thanks a lot :) –  MarkF6 May 23 '12 at 22:05

You could do this in `O(N log(N))` time (where N is combined length of sequences) by doing something akin to a binary search with a rolling hash.

Note that the length of the longest possible common sequence is the length of the smallest sequence, `smallestLength`. Proceed as follows:

Initialization:

• assume the length of the longest common subsequence (which we call `a`) is `a` = `smallestLength/2`

Algorithm:

• `iteration_number += 1`
• scan through all lists (in parallel if you want!) and perform a rolling hash; this will generate len(list)-(a-1) hashes for each list
• insert all the hashes into a set data structure (one set per list) to achieve O(1) lookup time
• check to see if any of the hashes collide (take the intersection of all the sets): if there are one or more collisions, manually confirm that there is an `a`-length subsequence common subsequence in those positions, since the hashes might be wrong (though this will never occur in practice if you choose a sufficiently fine hash)
• did you find a shared sequence?
• if you find such a sequence, repeat the above steps, but increase the assumed length like you would in binary search (add `smallestlength/2**iteration_number`)
• if you don't find such a sequence, repeat the above steps, but decrease the assumed length like you would in a binary search (subtract `smallestlength/2**iteration_number`)
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Did I... just find an O(numseq*seqlen log(numseq*seqlen)) solution to an algorithm that Wikipedia only has an exponential O(numseq*(seqlen^numseq)) solution to, and claims is NP-hard?... –  ninjagecko May 23 '12 at 21:50
Indeed :) assuming it is correct :p –  lcfseth May 23 '12 at 21:52
@all Thanks a lot! –  MarkF6 May 23 '12 at 22:04
Ah no, this is only an algorithm to find the en.wikipedia.org/wiki/Longest_common_substring_problem ; this is different from the en.wikipedia.org/wiki/Longest-common_subsequence_problem (a subsequence of `abcde` might for example be `b,d,e`, whereas a substring must be continuous, e.g. `bcd`) –  ninjagecko May 23 '12 at 23:42
In fact: There's a difference between subsequence and substring. Example for subsequence: "Hello", "Lopez" --> "e, o" Example for substring: "Hello", "Lopez" --> "" –  MarkF6 May 24 '12 at 8:05