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I'm playing around with calculating Levenshtein distances in Haskell, and am a little frustrated with the following performance problem. If you implement it most 'normal' way for Haskell, like below (dist), everything works just fine:

dist :: (Ord a) => [a] -> [a] -> Int
dist s1 s2 = ldist s1 s2 (L.length s1, L.length s2)

ldist :: (Ord a) => [a] -> [a] -> (Int, Int) -> Int
ldist _ _ (0, 0) = 0
ldist _ _ (i, 0) = i
ldist _ _ (0, j) = j
ldist s1 s2 (i+1, j+1) = output
  where output | (s1!!(i)) == (s2!!(j)) = ldist s1 s2 (i, j)
               | otherwise = 1 + L.minimum [ldist s1 s2 (i, j)
                                          , ldist s1 s2 (i+1, j)
                                          , ldist s1 s2 (i, j+1)]

But, if you bend your brain a little and implement it as dist', it executes MUCH faster (about 10x).

dist' :: (Ord a) => [a] -> [a] -> Int
dist' o1 o2 = (levenDist o1 o2 [[]])!!0!!0 

levenDist :: (Ord a) => [a] -> [a] -> [[Int]] -> [[Int]]
levenDist s1 s2 arr@([[]]) = levenDist s1 s2 [[0]]
levenDist s1 s2 arr@([]:xs) = levenDist s1 s2 ([(L.length arr) -1]:xs)
levenDist s1 s2 arr@(x:xs) = let
    n1 = L.length s1
    n2 = L.length s2
    n_i = L.length arr
    n_j = L.length x
    match | (s2!!(n_j-1) == s1!!(n_i-2)) = True | otherwise = False
    minCost = if match      then (xs!!0)!!(n2 - n_j + 1) 
                            else L.minimum [(1 + (xs!!0)!!(n2 - n_j + 1))
                                          , (1 + (xs!!0)!!(n2 - n_j + 0))
                                          , (1 + (x!!0))
    dist | (n_i > n1) && (n_j > n2)  = arr 
         | n_j > n2  = []:arr `seq` levenDist s1 s2 $ []:arr
         | n_i == 1 = (n_j:x):xs `seq` levenDist s1 s2 $ (n_j:x):xs
         | otherwise = (minCost:x):xs `seq` levenDist s1 s2 $ (minCost:x):xs
    in dist 

I've tried all the usual seq tricks in the first version, but nothing seems to speed it up. This is a little unsatisfying for me, because I expected the first version to be faster because it doesn't need to evaluate the entire matrix, only the parts it needs.

Does anyone know if it is possible to get these two implementations to perform similarly, or am I just reaping the benefits of tail-recursion optimizations in the latter, and therefore need to live with its unreadability if I want performance?

Thanks, Orion

share|improve this question
Minor style point: don't use !! where you can avoid it. In particular, every someList !! 0 can be replaced with head someList. – Antal Spector-Zabusky Sep 30 '10 at 15:08
Thanks. Quick followup: is !! O(n) where n is the position you're accessing, not the length of the entire list. So someList !! 0 should be the same as head someList, but someList !! bigNumber is O(bigNumber)? – jdo Sep 30 '10 at 17:32
up vote 2 down vote accepted

I don't follow all of your second attempt just yet, but as far as I recall the idea behind the Levenshtein algorithm is to save repeated calculation by using a matrix. In the first piece of code, you are not sharing any calculation and thus you will be repeating lots of calculations. For example, when calculating ldist s1 s2 (5,5) you'll make the calculation for ldist s1 s2 (4,4) at least three separate times (once directly, once via ldist s1 s2 (4,5), once via ldist s1 s2 (5,4)).

What you should do is define an algorithm for generating the matrix (as a list of lists, if you like). I think this is what your second piece of code is doing, but it seems to focus on calculating the matrix in a top-down manner rather than building up the matrix cleanly in an inductive style (the recursive calls in the base case are quite unusual to my eye). Unfortunately I don't have time to write out the whole thing, but thankfully someone else has: look at the first version at this address:

Two more things: one, I'm not sure the Levenshtein algorithm can ever use only part of the matrix anyway, as each entry is dependent on the diagonal, vertical and horizontal neighbour. When you need the value for one corner, you'll inevitably have to evaluate the matrix all the way to the other corner. Secondly, that match | foo = True | otherwise = False line can be replaced by simply match = foo.

share|improve this answer
The reason the second version looks so strange is that I'm building the list up using (x:xs) instead of xs ++ [x], with the expectation that the former is faster for all the reasons stated previously. If I was just adding the next element to the tail of the list (of lists) the code would be much easier to look at than this. – jdo Sep 30 '10 at 16:47
Per the second point, when characters match, dist' should be able to go straight down the diagonal and not eval the adjacent values. When they don't match, then you need to calc all three (redundantly). Presumably--and please correct me if I'm wrong--there is benefit to keeping a running list because every time the same function/arguments are called via a different traversal path the value is "remembered" (unless you actually wanted the matrix afterwards). Or is Haskell's GC more agressive than that? – jdo Sep 30 '10 at 16:56
This is exactly right, the second version is using memoisation while the first one is recursively calling the function on smaller problems. Each time the algorithm moves up and then left, it repeats the same work that was done when it moved left and then up. Each of those subcomputations is wasting time recomputing the whole rest of the table again. It's just doing way too much work, making an O(mn) problem into an O(2^(min m n)) problem, if my mental estimate is anything close to right. With the second (memoised) version, that computation is not repeated. – mokus Sep 30 '10 at 19:24

In the past I've used this very concise version with foldl and scanl from Wikibooks:

distScan :: (Ord a) => [a] -> [a] -> Int
distScan sa sb = last $ foldl transform [0 .. length sa] sb
    transform xs@(x:xs') c = scanl compute (x + 1) (zip3 sa xs xs')
         compute z (c', x, y) = minimum [y + 1, z + 1, x + fromEnum (c' /= c)]

I just ran this simple benchmark using Criterion:

test :: ([Int] -> [Int] -> Int) -> Int -> Int
test f n = f up up + f up down + f up half + f down half
    up = [1..n]
    half = [1..div n 2]
    down = reverse up

main = let n = 20 in defaultMain
  [ bench "Scan" $ nf (test distScan) n
  , bench "Fast" $ nf (test dist') n
  , bench "Slow" $ nf (test dist) n

And the Wikibooks version beats both of yours pretty dramatically:

benchmarking Scan
collecting 100 samples, 51 iterations each, in estimated 683.7163 ms...
mean: 137.1582 us, lb 136.9858 us, ub 137.3391 us, ci 0.950

benchmarking Fast
collecting 100 samples, 11 iterations each, in estimated 732.5262 ms...
mean: 660.6217 us, lb 659.3847 us, ub 661.8530 us, ci 0.950...

Slow is still running after a couple of minutes.

share|improve this answer
+1 for actual data, though there is no explanation as to what causes the slowness it does help to have numbers sometimes. – Matthieu M. Sep 30 '10 at 16:04
Many thanks for this post and putting numbers behind my assertions. The Wikibooks Algorithm Implementation section is fantastic-- I was not previously aware of it. Have not used Criterion, but will in the future. – jdo Sep 30 '10 at 16:43
In my experiments it is still more than 100 times slower than python-Levenshtein. – osa Oct 27 '15 at 1:20
@osa - well, the python version looks like it is really written in C - (link) Also, the Haskell version uses lists instead of ByteString or Text and doesn't use mutation. – ErikR Oct 27 '15 at 2:17

To calculate length you need to evaluate the whole list. It is an expensive, O(n), operation. And what's more important, after that the list will be kept in-memory until you stop referencing the list (=> bigger memory footprint). The rule of thumb is not to use length on lists if lists are expected to be long. The same refers to (!!), it goes from the very head of the list every time, so it is O(n) too. Lists are not designed as a random-access data structure.

Better approach with Haskell lists is to consume them partially. Folds are usually the way to go in similar problems. And Levenshtein distance can be calculated that way (see a link below). I don't know if there are better algorithms.

Another approach is to use a different data structure, not lists. For example, if you need random access, known length etc. take a look at Data.Sequence.Seq.

Existing implementations

The second approach has been used in this implementation of the Levenschtein distance in Haskell (using arrays). You can find foldl-based implementation in the first comment there. BTW, foldl' is usually better than foldl.

share|improve this answer

It is possible to have an O(N*d) algorithm, where d is the Levenshtein distance. Here's a implementation in Lazy ML by Lloyd Allison which exploits laziness to achieve the improved complexity. This works by only computing part of the matrix, that is, a region around the main diagonal that is proportional in width to the Levenshtein distance.

Edit: I just noticed this has been translated to haskell with a nice image showing which elements of the matrix are computed. This should be significantly faster than the above implementations when the sequences are quite similar. Using the above benchmark:

benchmarking Scan
collecting 100 samples, 100 iterations each, in estimated 1.410004 s
mean: 141.8836 us, lb 141.4112 us, ub 142.5126 us, ci 0.950

benchmarking LAllison.d
collecting 100 samples, 169 iterations each, in estimated 1.399984 s
mean: 82.93505 us, lb 82.75058 us, ub 83.19535 us, ci 0.950
share|improve this answer

A more intuitive solution using the data-memocombinators package. Credit goes to this answer. Benchmarks are welcome, as all solutions presented here appear to be much, much slower than python-Levenshtein, which was presumably written in C. Note that I tried substituting arrays of chars instead of strings to no effect.

import Data.MemoCombinators (memo2, integral)

levenshtein :: String -> String -> Int
levenshtein a b = levenshtein' (length a) (length b) where
  levenshtein' = memo2 integral integral levenshtein'' where
    levenshtein'' x y -- take x characters from a and y characters from b
      | x==0 = y
      | y==0 = x
      | a !! (x-1) == b !! (y-1) = levenshtein' (x-1) (y-1)
      | otherwise = 1 + minimum [ levenshtein' (x-1) y, 
        levenshtein' x (y-1), levenshtein' (x-1) (y-1) ]
share|improve this answer

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