Why is this F# code so slow?

A Levenshtein implementation in C# and F#. The C# version is 10 times faster for two strings of about 1500 chars. C#: 69 ms, F# 867 ms. Why? As far as I can tell, they do the exact same thing? Doesn't matter if it is a Release or a Debug build.

EDIT: If anyone comes here looking specifically for the Edit Distance implementation, it is broken. Working code is here.

C#:

``````private static int min3(int a, int b, int c)
{
return Math.Min(Math.Min(a, b), c);
}

public static int EditDistance(string m, string n)
{
var d1 = new int[n.Length];
for (int x = 0; x < d1.Length; x++) d1[x] = x;
var d0 = new int[n.Length];
for(int i = 1; i < m.Length; i++)
{
d0[0] = i;
var ui = m[i];
for (int j = 1; j < n.Length; j++ )
{
d0[j] = 1 + min3(d1[j], d0[j - 1], d1[j - 1] + (ui == n[j] ? -1 : 0));
}
Array.Copy(d0, d1, d1.Length);
}
return d0[n.Length - 1];
}
``````

F#:

``````let min3(a, b, c) = min a (min b c)

let levenshtein (m:string) (n:string) =
let d1 = Array.init n.Length id
let d0 = Array.create n.Length 0
for i=1 to m.Length-1 do
d0.[0] <- i
let ui = m.[i]
for j=1 to n.Length-1 do
d0.[j] <- 1 + min3(d1.[j], d0.[j-1], d1.[j-1] + if ui = n.[j] then -1 else 0)
Array.blit d0 0 d1 0 n.Length
d0.[n.Length-1]
``````
• What's the performance diff using inline? – gradbot May 24 '11 at 3:59

The problem is that the `min3` function is compiled as a generic function that uses generic comparison (I thought this uses just `IComparable`, but it is actually more complicated - it would use structural comparison for F# types and it's fairly complex logic).

``````> let min3(a, b, c) = min a (min b c);;
val min3 : 'a * 'a * 'a -> 'a when 'a : comparison
``````

In the C# version, the function is not generic (it just takes `int`). You can improve the F# version by adding type annotations (to get the same thing as in C#):

``````let min3(a:int, b, c) = min a (min b c)
``````

...or by making `min3` as `inline` (in which case, it will be specialized to `int` when used):

``````let inline min3(a, b, c) = min a (min b c);;
``````

For a random string `str` of length 300, I get the following numbers:

``````> levenshtein str ("foo" + str);;
Real: 00:00:03.938, CPU: 00:00:03.900, GC gen0: 275, gen1: 1, gen2: 0
val it : int = 3

> levenshtein_inlined str ("foo" + str);;
Real: 00:00:00.068, CPU: 00:00:00.078, GC gen0: 0, gen1: 0, gen2: 0
val it : int = 3
``````
• Why doesn't F# compile min3 as a function that takes int? It already knows enough type information at compile time to do this. This is how it would work if min3 was a C++ template function, so I'm a bit puzzled as to why F# doesn't do this. – sashang May 24 '11 at 0:00
• F# infers it to be as generic as possible, e.g. "for all types X that support comparison". `inline` works like a C++ template, which would specialize to `int` based on the call site. – Brian May 24 '11 at 0:08
• C++ templates behave essentially as F#'s `inline`. The reason why the default behavior is different is because it builds on .Net generics that are handled by the runtime (and, arguably, aren't so great for writing generic numeric code). Using the C++ behavior in F# would, however, lead to code bloat, because F# uses generics a lot more. – Tomas Petricek May 24 '11 at 0:12
• C++ template semantics can lead to code bloat even in C++, and the lack of a convenient way to switch to using a run-time mechanism to avoid that is a hassle at times. However, the fear of code bloat is normally irrational - generally, C++ templates work well. – Steve314 Apr 13 '12 at 1:40
• @Steve314 : It's also generally easy to avoid by refactoring out all code that doesn't use a dependent type, so that code isn't duplicated for different instantiations. – ildjarn Apr 13 '12 at 17:39