# How to find repeated sequences of events

I'm trying to find an efficient algorithm for identifying a reoccurring sequence of characters. Let's say the sequence could be a minimum of 3 characters, yet only returns the maximum length sequence. The dataset could potentially be thousands of characters. Also, I only want to know about the sequence if it's repeated, lets say, 3 times.

As an example: ASHEKBSHEKCSHEDSHEK

"SHEK" occurs 3 times and would be identified. "SHE" occurs 4 times, but isn't identified since "SHEK" is the maximum length sequence that contains that sequence.

Also, no "seed" sequence is fed to the algorithm, it must find them autonomously.

-
Not part of my answer, per se, but may I suggest you look at SWIG and getting your inner-loop work compiled into C++? I've worked on NLP / Machine Learning previously and if-i-could-do-it-over I would put the core algorithms in C++ and link them into the JVM on my computation servers / Hadoop cluster. Just a thought, though... –  sam Nov 10 '11 at 15:15

Looks like Rabin-Karp

http://en.wikipedia.org/wiki/Rabin%E2%80%93Karp_string_search_algorithm

-
using this algorithm actually worked for my implementation. –  tunneling Dec 1 '11 at 15:18

Consider the following algorithm, where:

str is the string of events

T(i) is the suffix tree for the substring str(0..i).

T(i+1) is quickly obtained from T(i), for example using this algorithm

For each character position i in the input string str, traverse a path starting at the root of T(i), along edges, labeled with successive characters from the input, beginning from position i + 1.

This path determines a repeating string. If the path is longer than the previously found paths, record the new max length and the position i + 1.

Update the suffixe tree with str [i+1] and repeat for the next position.

Something like this pseudocode:

max.len = 0
max.off = -1
T = update_suffix_tree (nil, str [0])
for i = 1 to len (str)
r = root (T)
j = i + 1
while j < len (str) and r.child (str [j]) != nil
r = r.child (str [j])
++j

if j - i - 1 > max.len
max.len = j - i - 1
max.off = i + 1

T = update_suffix_tree (T, str [i+1])


In the kth iteration, the inner while is executed for at most n - k iterations and the suffix tree construction is O(k), hence the loop body's complexity is O(n) and it's executed n-1 times, therefore the whole algorithm complexity is O(n^2).

-

Try to create suffix array for string.

Online builder: http://allisons.org/ll/AlgDS/Strings/Suffix/

Check the beginning of consecutive lines in suffix array to match

-

If you consider that there exist \sum(n) / 2 possible starting strings, and you aren't looking for simply a match, but the substring with the most matches, I think your algorithm will have a terrible theoretical complexity if it is to be correct and complete.

However, you might get some practical speed using a Trie. The algorithm would go something like this:

1. For each offset into the string... 1 For each length sub-string...
1. Insert it into the trie. Each node in the trie has a data value (an "count" integer) that you increment by when you visit the node.

Once you've built-up the trie to model your data, delete all the sub-trees from the trie with roots below some optimization threshold (3 in your case).

Those remaining paths should be few enough in number for you to efficiently sort-and-pick the ones you want.

I suggest this as a starting point because the Trie is built to manipulate common prefixes and, as a side-effect, will compress your dataset.

A personal choice I would make would be to identify the location of the sub-strings as a separate process after identifying the ones I want. Otherwise you are going to store every substring location, and that will explode your memory. Your computation is already pretty complex.

Hope this makes some sense! Good luck!

-