# Levenshtein Distance Algorithm better than O(n*m)?

I have been looking for an advanced levenshtein distance algorithm, and the best I have found so far is O(n*m) where n and m are the lengths of the two strings. The reason why the algorithm is at this scale is because of space, not time, with the creation of a matrix of the two strings such as this one:

Is there a publicly-available levenshtein algorithm which is better than O(n*m)? I am not averse to looking at advanced computer science papers & research, but haven't been able to find anything. I have found one company, Exorbyte, which supposedly has built a super-advanced and super-fast Levenshtein algorithm but of course that is a trade secret. I am building an iPhone app which I would like to use the Levenshtein distance calculation. There is an objective-c implementation available, but with the limited amount of memory on iPods and iPhones, I'd like to find a better algorithm if possible.

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Are you interested in reducing the time complexity or the space complexity ? The average time complexity can be reduced O(n + d^2), where n is the length of the longer string and d is the edit distance. If you are only interested in the edit distance and not interested in reconstructing the edit sequence, you only need to keep the last two rows of the matrix in memory, so that will be order(n).

If you can afford to approximate, there are poly-logarithmic approximations.

For the O(n +d^2) algorithm look for Ukkonen's optimization or its enhancement Enhanced Ukkonen. The best approximation that I know of is this one by Andoni, Krauthgamer, Onak

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This is very helpful, thanks! – Jason Nov 1 '10 at 10:08
I use this for DNA alignment; We check for the length of the sequences first since the logic for updating the Ukkonen barrier is heavier then just calculating the whole array. Also, take a look at "Time Warps, String Edits, and Macromolecules: The Theory and Practice of Sequence Comparison" for some more details. – nlucaroni Dec 13 '10 at 22:05
The original paper for the Ukkonen Approximate String Matching Algorithm is, cs.helsinki.fi/u/ukkonen/InfCont85.PDF. – nlucaroni Dec 13 '10 at 22:07
Actually, you don't need the last two rows of the matrix. The last row, plus the previous number in the current row, is enough. Also note that implementing Levenshtein this way is significantly faster than using the full matrix, probably due to CPU caching. – larsga Jan 4 '13 at 11:26

I found another optimization that claims to be O(max(m, n)):

http://en.wikibooks.org/wiki/Algorithm_Implementation/Strings/Levenshtein_distance#C

(the second C implementation)

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The OP was takling about time complexity, not memory – Antoine Apr 28 '15 at 16:29

If you only want the threshold function - eg, to test if the distance is under a certain threshold - you can reduce the time and space complexity by only calculating the n values either side of the main diagonal in the array. You can also use Levenshtein Automata to evaluate many words against a single base word in O(n) time - and the construction of the automatons can be done in O(m) time, too.

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Thank you, that gave me an idea on my implementation. – n8. Oct 20 '14 at 18:48

Look in Wiki - they have some ideas to improve this algorithm to better space complexity: