Years ago, I solved a problem via dynamic programming:


The solution was coded in Python.

As part of expanding my horizons, I recently started learning OCaml/F#. What better way to test the waters, than by doing a direct port of the imperative code I wrote in Python to F# - and start from there, moving in steps towards a functional programming solution.

The results of this first, direct port... are disconcerting:

Under Python:

  bash$ time python fitToSize.py
  real    0m1.482s
  user    0m1.413s
  sys     0m0.067s

Under FSharp:

  bash$ time mono ./fitToSize.exe
  real    0m2.235s
  user    0m2.427s
  sys     0m0.063s

(in case you noticed the "mono" above: I tested under Windows as well, with Visual Studio - same speed).

I am... puzzled, to say the least. Python runs code faster than F# ? A compiled binary, using the .NET runtime, runs SLOWER than Python's interpreted code?!?!

I know about startup costs of VMs (mono in this case) and how JITs improve things for languages like Python, but still... I expected a speedup, not a slowdown!

Have I done something wrong, perhaps?

I have uploaded the code here:


Note that the F# code is more or less a direct, line-by-line translation of the Python code.

P.S. There are of course other gains, e.g. the static type safety offered by F# - but if the resulting speed of an imperative algorithm is worse under F# ... I am disappointed, to say the least.

EDIT: Direct access, as requested in the comments:

the Python code: https://gist.github.com/950697

the FSharp code: https://gist.github.com/950699

  • 7
    Please use something like gist.github.com to upload your code... it really sucks having to download a tar.gz file to see your code
    – razenha
    May 1, 2011 at 17:56
  • 7
    It's myths, all myths. It's not compiled that is faster, or interpreted that is faster, or native that is faster, or jitted that is faster. Only faster is faster. Live by that. May 1, 2011 at 17:59
  • 4
    I don't have Python to test it, but the F# version completes in ~1.5 sec on my Intel Core 2 Duo CPU (2.26 GHz) (on Windows, using fsi.exe and the #time timing). However, I dind't try to understand your code - I think you'll more likely get a useful answer if you post some simple F# code that you're trying to optimize (because not everybody will want to analyse your two samples). May 1, 2011 at 18:16
  • 1
    Also, translating code line-by-line from Python is a good way to start exploring the F# syntax, but it doesn't really show you any of the benefits of F#. I believe you could have more fun if you tried to solve the problem using more idiomatic functional style (it probably won't be faster, but it will quite likely be more readable and shorter). May 1, 2011 at 18:22
  • 3
    On my machine, Python runs in 1.2 secs and the F# version in 1.8 secs. What this benchmark probably shows, is that Python has an excellent Dictionary implementation, maybe with optimizations for pairs as keys.
    – wmeyer
    May 1, 2011 at 18:39

4 Answers 4


Dr Jon Harrop, whom I contacted over e-mail, explained what is going on:

The problem is simply that the program has been optimized for Python. This is common when the programmer is more familiar with one language than the other, of course. You just have to learn a different set of rules that dictate how F# programs should be optimized... Several things jumped out at me such as the use of a "for i in 1..n do" loop rather than a "for i=1 to n do" loop (which is faster in general but not significant here), repeatedly doing List.mapi on a list to mimic an array index (which allocated intermediate lists unnecessarily) and your use of the F# TryGetValue for Dictionary which allocates unnecessarily (the .NET TryGetValue that accepts a ref is faster in general but not so much here)

... but the real killer problem turned out to be your use of a hash table to implement a dense 2D matrix. Using a hash table is ideal in Python because its hash table implementation has been extremely well optimized (as evidenced by the fact that your Python code is running as fast as F# compiled to native code!) but arrays are a much better way to represent dense matrices, particularly when you want a default value of zero.

The funny part is that when I first coded this algorithm, I DID use a table -- I changed the implementation to a dictionary for reasons of clarity (avoiding the array boundary checks made the code simpler - and much easier to reason about).

Jon transformed my code (back :-)) into its array version, and it runs at 100x speed.

Moral of the story:

  • F# Dictionary needs work... when using tuples as keys, compiled F# is slower than interpreted Python's hash tables!
  • Obvious, but no harm in repeating: Cleaner code sometimes means... much slower code.

Thank you, Jon -- much appreciated.

EDIT: the fact that replacing Dictionary with Array makes F# finally run at the speeds a compiled language is expected to run, doesn't negate the need for a fix in Dictionary's speed (I hope F# people from MS are reading this). Other algorithms depend on dictionaries/hashes, and can't be easily switched to using arrays; making programs suffer "interpreter-speeds" whenever one uses a Dictionary, is arguably, a bug. If, as some have said in the comments, the problem is not with F# but with .NET Dictionary, then I'd argue that this... is a bug in .NET!

EDIT2: The clearest solution, that doesn't require the algorithm to switch to arrays (some algorithms simply won't be amenable to that) is to change this:

let optimalResults = new Dictionary<_,_>()

into this:

let optimalResults = new Dictionary<_,_>(HashIdentity.Structural)

This change makes the F# code run 2.7x times faster, thus finally beating Python (1.6x faster). The weird thing is that tuples by default use structural comparison, so in principle, the comparisons done by the Dictionary on the keys are the same (with or without Structural). Dr Harrop theorizes that the speed difference may be attributed to virtual dispatch: "AFAIK, .NET does little to optimize virtual dispatch away and the cost of virtual dispatch is extremely high on modern hardware because it is a "computed goto" that jumps the program counter to an unpredictable location and, consequently, undermines branch prediction logic and will almost certainly cause the entire CPU pipeline to be flushed and reloaded".

In plain words, and as suggested by Don Syme (look at the bottom 3 answers), "be explicit about the use of structural hashing when using reference-typed keys in conjunction with the .NET collections". (Dr. Harrop in the comments below also says that we should always use Structural comparisons when using .NET collections).

Dear F# team in MS, if there is a way to automatically fix this, please do.

  • 13
    Note: 1. F# dictionaries are just .NET dictionaries. 2. Python dictionaries are not implemented in Python (probably in C).
    – wmeyer
    May 1, 2011 at 18:58
  • 7
    Apparently using Dictionary(HashIdentity.Structural) makes it a lot faster (probably faster than Python). Replacing tuples (which are heap allocated) with structs should also improve performance significantly. BTW, I think you should also accept this answer if you can.
    – J D
    May 2, 2011 at 10:07
  • 12
    @ttsiodras: I don't follow your logic. The only reason your Python beat your F# is that you forgot to provide the HashIdentity.Structural equality comparer that you should always provide in F#. Just making that one minor change makes the F# faster than your Python. If you then use structs instead of tuples and use the .NET TryGetValue instead of the F# extension method and presize the hash table, the F# becomes 7× faster than before which is several times faster than your Python. So you cannot conclude that Dictionary is inefficient.
    – J D
    May 2, 2011 at 14:16
  • 7
    @kvb, @Jon: I googled a lot and found this: cs.hubfs.net/forums/thread/654.aspx (navigate to the bottom). Don Syme clearly admits that for tuples, F# should use Structural comparisons BY DEFAULT, just like Python does. He says that "We'll add it to our list" back in 2006, but 5 years later, apparently this hasn't made it in... And, funny thing, "This can be very confusing for newcomers from other languages and also can lead to subtle bugs in a larger code base.". Yep, indeed :-)
    – ttsiodras
    May 2, 2011 at 14:43
  • 3
    @ttsiodras - actually, the tuple type has changed since then, so that the default equality and hashing behavior work as expected. That is, the example in that thread of getting different results from multiple calls to (1, 2, 3).GetHashCode() no longer occurs. It's just that the performance characteristics of the built-in equality and hashing operations aren't as fast as using HashIdentity.Structural.
    – kvb
    May 2, 2011 at 15:12

As Jon Harrop has pointed out, simply constructing the dictionaries using Dictionary(HashIdentity.Structural) gives a major performance improvement (a factor of 3 on my computer). This is almost certainly the minimally invasive change you need to make to get better performance than Python, and keeps your code idiomatic (as opposed to replacing tuples with structs, etc.) and parallel to the Python implementation.


Edit: I was wrong, it's not a question of value type vs reference type. The performance problem was related to the hash function, as explained in other comments. I keep my answer here because there's an interessant discussion. My code partially fixed the performance issue, but this is not the clean and recommended solution.


On my computer, I made your sample run twice as fast by replacing the tuple with a struct. This means, the equivalent F# code should run faster than your Python code. I don't agree with the comments saying that .NET hashtables are slow, I believe there's no significant difference with Python or other languages implementations. Also, I don't agree with the "You can't 1-to-1 translate code expect it to be faster": F# code will generally be faster than Python for most tasks (static typing is very helpful to the compiler). In your sample, most of the time is spent doing hashtable lookups, so it's fair to imagine that both languages should be almost as fast.

I think the performance issue is related to gabage collection (but I haven't checked with a profiler). The reason why using tuples can be slower here than structures has been discussed in a SO question ( Why is the new Tuple type in .Net 4.0 a reference type (class) and not a value type (struct)) and a MSDN page (Building tuples):

If they are reference types, this means there can be lots of garbage generated if you are changing elements in a tuple in a tight loop. [...] F# tuples were reference types, but there was a feeling from the team that they could realize a performance improvement if two, and perhaps three, element tuples were value types instead. Some teams that had created internal tuples had used value instead of reference types, because their scenarios were very sensitive to creating lots of managed objects.

Of course, as Jon said in another comment, the obvious optimization in your example is to replace hashtables with arrays. Arrays are obviously much faster (integer index, no hashing, no collision handling, no reallocation, more compact), but this is very specific to your problem, and it doesn't explain the performance difference with Python (as far as I know, Python code is using hashtables, not arrays).

To reproduce my 50% speedup, here is the full code: http://pastebin.com/nbYrEi5d

In short, I replaced the tuple with this type:

type Tup = {x: int; y: int}

Also, it seems like a detail, but you should move the List.mapi (fun i x -> (i,x)) fileSizes out of the enclosing loop. I believe Python enumerate does not actually allocate a list (so it's fair to allocate the list only once in F#, or use Seq module, or use a mutable counter).

  • About your List.mapi comment: I did try my own "seq"-based enumerate: let enumerate c = seq { let idx = ref 0 for elem in c do yield (!idx, elem) idx := !idx + 1 } ... but it had no impact - speed was still slow. As I said above, turns out the culprit is the bad performance of .NET Dictionary...
    – ttsiodras
    May 1, 2011 at 19:06
  • @ttsiodras: I don't think so. With my change, the code is a bit faster than the Python implementation, this means dictionaries are not that slow in .NET. Of course, arrays are much faster than hashtables when you know the index, but you're changing the algorithm.
    – Laurent
    May 1, 2011 at 20:24
  • 1
    @ttsiodras - structural identity is an F# concept which the underlying .NET framework is completely unaware of, so the .NET dictionary type can't use it as the default.
    – kvb
    May 2, 2011 at 14:02
  • 2
    Is there really still a danger of getting reference equality in the current version of F#? With tuple keys in Dictionaries that does not seem to be the case. Can it happen in other circumstances with structural F# types?
    – wmeyer
    May 2, 2011 at 14:54
  • 1
    @wmeyer - Tuples define their equality and hashing in terms of their constituent values' equality and hashing. If their values' equality and hashing are already structural, then the tuples will have structural equality and hashing, too (such as with int*int). However, if their values are not structural, then the tuple's equality and hashing will not be structural either (such as with int[]*int[]). F#'s = operator and hash function behave structurally even on these types, as does the HashIdentity.Structural equality comparer.
    – kvb
    May 2, 2011 at 16:16

Hmm.. if the hashtable is the major bottleneck, then it is properly the hash function itself. Havn't look at the specific hash function but For one of the most common hash functions namely

((a * x + b) % p) % q

The modulus operation % is painfully slow, if p and q is of the form 2^k - 1, we can do modulus with an and, add and a shift operation.

Dietzfelbingers universal hash function h_a : [2^w] -> [2^l]

lowerbound(((a * x) % 2^w)/2^(w-l))

Where is a random odd seed of w-bit.

It can be computed by (a*x) >> (w-l), which is magnitudes of speed faster than the first hash function. I had to implement a hash table with linked list as collision handling. It took 10 minutes to implement and test, we had to test it with both functions, and analyse the differens of speed. The second hash function had as I remember around 4-10 times of speed gain dependend on the size of the table. But the thing to learn here is if your programs bottleneck is hashtable lookup the hash function has to be fast too

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge that you have read and understand our privacy policy and code of conduct.

Not the answer you're looking for? Browse other questions tagged or ask your own question.