# Most efficient way to calculate Levenshtein distance

I just implemented a best match file search algorithm to find the closest match to a string in a dictionary. After profiling my code, I found out that the overwhelming majority of time is spent calculating the distance between the query and the possible results. I am currently implementing the algorithm to calculate the Levenshtein Distance using a 2-D array, which makes the implementation an O(n^2) operation. I was hoping someone could suggest a faster way of doing the same.

Here's my implementation:

``````public int calculate(String root,String query)
{
int arr[][] = new int[root.length()+2][query.length()+2];

for(int i=2;i<root.length()+2;i++)
{
arr[i][0] = (int)root.charAt(i-2);
arr[i][1] = (i-1);
}

for(int i=2;i<query.length()+2;i++)
{
arr[0][i] = (int)query.charAt(i-2);
arr[1][i] = (i-1);
}

for(int i=2;i<root.length()+2;i++)
for(int j=2;j<query.length()+2;j++)
{
int diff=0;
if(arr[0][j]!=arr[i][0])
diff = 1;
arr[i][j]=min((arr[i-1][j]+1),(arr[i][j-1]+1),(arr[i-1][j-1]+diff));
}

return arr[root.length()+1][query.length()+1];
}

public int min(int n1, int n2, int n3)
{
return (int)Math.min(n1,Math.min(n2,n3));
}
``````
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yes, the other things are efficient enough. I profiled my code and found that the bottleneck was calculating the levenshtein distance which is why I'm trying to optimize that bit right now. I'm implementing the improvement mentioned in the wikipedia article and I'll follow it up with an implementation of the VP-tree to see which one is more efficient. –  efficiencyIsBliss Jul 6 '10 at 13:56
about "using a 2-D array, which makes the implementation an O(n^2) operation": calculating a Levenshtein distance between two sequences with no constraints is already an O(n^2) operation irrespective of how much memory you use -- using a 2-D array just slows you down and wastes memory; only O(n) memory is required. –  John Machin Jul 7 '10 at 0:58

The wikipedia entry on Levenshtein distance has useful suggestions for optimizing the computation -- the most applicable one in your case is that if you can put a bound `k` on the maximum distance of interest (anything beyond that might as well be infinity!) you can reduce the computation to `O(n times k)` instead of `O(n squared)` (basically by giving up as soon as the minimum possible distance becomes `> k`).

Since you're looking for the closest match, you can progressively decrease `k` to the distance of the best match found so far -- this won't affect the worst case behavior (as the matches might be in decreasing order of distance, meaning you'll never bail out any sooner) but average case should improve.

I believe that, if you need to get substantially better performance, you may have to accept some strong compromise that computes a more approximate distance (and so gets "a reasonably good match" rather than necessarily the optimal one).

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I just found the same and was about to post it here. Thanks! –  efficiencyIsBliss Jul 6 '10 at 2:57
You can always create with a small set of matches using whatever "approximate distance" metric you come up with, then use real Levenshtein to rank those. –  kibibu Jul 6 '10 at 4:06
I read up on the optimization that the above post talks of, but I can't honestly say I get it. I'm not sure how to implement it either. Can someone offer some help? –  efficiencyIsBliss Jul 7 '10 at 2:29
@Dharmesh, not in comments -- way too cramped -- but a separate question on finding closest neighbor (the main optimization you can perform being to not fully compute the distance in most cases -- and that optimization is only possible because you want the nearest neighbor, not for all distance computation tasks!) ideally with some samples of typical/interesting roots and sets of queries, should elicit lots of help (be sure to tag it as "algorithm" too!). –  Alex Martelli Jul 7 '10 at 3:35
@Alex: that optimisation is also possible if the OP wanted to find all "likely" matches, "likely" being defined as e.g. `distance(query,candidate)/max(len(query),len(candidate)) < some_threshold_fraction` –  John Machin Jul 7 '10 at 7:31

I know this is very late but it is relevant to the discussion at hand.

As mentioned by others, if all you want to do is check whether the edit distance between two strings is within some threshold k, you can reduce the time complexity to O(kn). A more precise expression would be O((2k+1)n). You take a strip which spans k cells either side of the diagonal cell (length of strip 2k+1) and compute the values of cells lying on this strip.

Interestingly, there's been an improvement by Li et. al. and this has been further reduced to O((k+1)n).

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Commons-lang has a pretty fast implementation. See http://www.merriampark.com/ldjava.htm.

Here's my translation of that into Scala:

``````// The code below is based on code from the Apache Commons lang project.
/*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with this
* licenses this file to You under the Apache License, Version 2.0 (the
* "License"); you may not use this file except in compliance with the
*
*
* Unless required by applicable law or agreed to in writing, software
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
* License for the specific language governing permissions and limitations
*/
/**
* assert(levenshtein("algorithm", "altruistic")==6)
* assert(levenshtein("1638452297", "444488444")==9)
* assert(levenshtein("", "") == 0)
* assert(levenshtein("", "a") == 1)
* assert(levenshtein("aaapppp", "") == 7)
* assert(levenshtein("frog", "fog") == 1)
* assert(levenshtein("fly", "ant") == 3)
* assert(levenshtein("elephant", "hippo") == 7)
* assert(levenshtein("hippo", "elephant") == 7)
* assert(levenshtein("hippo", "zzzzzzzz") == 8)
* assert(levenshtein("hello", "hallo") == 1)
*
*/
def levenshtein(s: CharSequence, t: CharSequence, max: Int = Int.MaxValue) = {
import scala.annotation.tailrec
def impl(s: CharSequence, t: CharSequence, n: Int, m: Int) = {
// Inside impl n <= m!
val p = new Array[Int](n + 1) // 'previous' cost array, horizontally
val d = new Array[Int](n + 1) // cost array, horizontally

@tailrec def fillP(i: Int) {
p(i) = i
if (i < n) fillP(i + 1)
}
fillP(0)

@tailrec def eachJ(j: Int, t_j: Char, d: Array[Int], p: Array[Int]): Int = {
d(0) = j
@tailrec def eachI(i: Int) {
val a = d(i - 1) + 1
val b = p(i) + 1
d(i) = if (a < b) a else {
val c = if (s.charAt(i - 1) == t_j) p(i - 1) else p(i - 1) + 1
if (b < c) b else c
}
if (i < n)
eachI(i + 1)
}
eachI(1)

if (j < m)
eachJ(j + 1, t.charAt(j), p, d)
else
d(n)
}
eachJ(1, t.charAt(0), d, p)
}

val n = s.length
val m = t.length
if (n == 0) m else if (m == 0) n else {
if (n > m) impl(t, s, m, n) else impl(s, t, n, m)
}
``````

}

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