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I am fresh in haskell, and I defined a func in Haskell :

febs :: (Integral a)=> a -> a
febs n 
    | n<=0 =0
    | n==1 =1
    | n==2 =1
    | otherwise =febs(n-1)+febs(n-2)

but, it runs so slow, and when I do "febs 30", it will take about 10s, and I do the same func in C++, it runs very fast.

int febs(int n)
{
    if(n == 1 || n ==2)
    {
        return 1;
    }
    return febs(n-1)+febs(n-2);
}

Is there any way to promote my haskell func speed?

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10  
That function is traditionally called "fib" or "fibs" because it gives you the Fibonacci numbers. Just getting my pedantry out of the way :P. –  Tikhon Jelvis Jul 18 '12 at 8:29
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3 Answers

up vote 20 down vote accepted

This is an odd comparison, for the following reasons:

  1. You don't say whether you're compiling the Haskell code, or with what options. If you're just running it in ghci, then of course it will be slow - you're comparing interpreted code with compiled code.

  2. Your Haskell code is polymorphic whereas your C++ code is monomorphic (that is, you've used a type class Integral a => a -> a instead of the concrete type Int -> Int). Your Haskell code is therefore more general than your C++ code, because it can handle arbitrarily large integers instead of being restricted to the range of an Int. It's possible that the compiler will optimize this away, but I'm not certain.

If I put the following code in a file fib.hs

fibs :: Int -> Int
fibs n = if n < 3 then 1 else fibs (n-1) + fibs (n-2)

main = print (fibs 30)

and compile it with ghc -O2 fib.hs then it runs fast enough that it appears instantaneous to me. You should try that, and see how it compares with the C++ code.

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Regarding the polymorphism: does that really have an effect in this case? I'd guess that the function would get inlined or something when you use it, but I'm not an expert. (Assuming you have optimizations on.) Oh, and assuming it has the Int type at the call site. Which, thinking about it, isn't a fair assumption. –  Tikhon Jelvis Jul 18 '12 at 8:32
    
Actually, I'm not sure. I suppose you have to look at the Core, but I'm not experienced enough to do that! –  Chris Taylor Jul 18 '12 at 8:34
1  
Actually, I could just run both versions (with both signatures) and compare the running time. And by "I", I really mean "you" because I'd have to boot into Linux :P. –  Tikhon Jelvis Jul 18 '12 at 8:35
8  
@TikhonJelvis It plays a role. Since it's recursive, it can't be inlined. When compiling with optimisations (always assuming GHC), if it's used monomorphically in the same source file as it's defined, you'll get a specialisation. Without type signature, in main that'd be at Integer, so somewhat slower than with Int. If you define it in a different file than it's used in, unless you make it {-# INLINABLE #-}, you get the very slow polymorphic code. –  Daniel Fischer Jul 18 '12 at 8:39
    
@DanielFischer: That's exactly what I was wondering about. Thanks! –  Tikhon Jelvis Jul 18 '12 at 8:41
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Try compiling with optimization. With GHC 7.4.1 with -O2, your program runs quite quickly:

$ time ./test 
832040

real    0m0.057s
user    0m0.056s
sys     0m0.000s

This is with main = print (febs 30).


Regarding the polymorphism considerations in Chris Taylor's answer, here's febs 40 with OP's polymorphic Fibonacci function:

$ time ./test 
102334155

real    0m5.670s
user    0m5.652s
sys     0m0.004s

And here is a non-polymorphic one, i.e. with OP's signature replaced with Int -> Int:

$ time ./test 
102334155

real    0m0.820s
user    0m0.816s
sys     0m0.000s

Per Tikhon Jelvis' comment, it'd be interesting to see if the speedup is due to replacing Integer with Int, or due to getting rid of polymorphism. Here's the same program again, except with febs moved to a new file per Daniel Fischer's comment, and with with febs :: Integer -> Integer:

$ time ./test 
102334155

real    0m5.648s
user    0m5.624s
sys     0m0.008s

Again, with febs in a different file, and with the same polymorphic signature as originally:

$ time ./test 
102334155

real    0m16.610s
user    0m16.469s
sys     0m0.104s
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Thanks for testing the polymorphic vs monomorphic versions (I'm running Windows, so getting the runtime is a pain!) –  Chris Taylor Jul 18 '12 at 8:38
2  
An Integral type gets defaulted to Integer. I'm curious if the change in performance is just because of Integer vs Int or if the polymorphism also matters. –  Tikhon Jelvis Jul 18 '12 at 8:40
5  
You had the function defined in the same file as main hadn't you? In separate files, with polymorphic code, I get a running time of 15.5s for febs 40, 5.4s for Integer -> Integer and 0.86s for Int -> Int. @TikhonJelvis this would answer your question. And 0.3s for gcc -O3. –  Daniel Fischer Jul 18 '12 at 8:52
2  
You have to tell GHC at the definition site that the function either should be specialised for some types ({-# SPECIALISE foo :: Int -> Int, Word -> Integer #-} [US spelling also accepted]), or - requires GHC >= 7 [perhaps 7.2, not sure] - with an {-# INLINABLE foo #-} pragma that it should expose the function for inlining/optimising/specialising in the interface file. Then (always with -O2) it will be done automatically, at least if the nesting isn't too deep [I can imagine that the optimiser gives up if your call-tree is 1000 polymorphic functions deep]. –  Daniel Fischer Jul 18 '12 at 9:17
2  
Generally, yes. With INLINABLE, a specialised version is generated at the use site. If you use a polymorphic function at one specific type in a lot of modules, each gets its own specialised version, then it can be preferable to use a SPECIALISE pragma to reduce (compiled) code size. –  Daniel Fischer Jul 18 '12 at 9:27
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You could also write the function like this:

fibs = 0:1:zipWith (+) fibs (tail fibs)

It is very fast, even for big 'n' executes immediately:

Prelude> take 1000 fibs 
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1  
Yeah, but that's asymptotically different. I think the real question was about comparing C++ to Haskell, so using a different algorithm would be out. It is good advice in general though. –  Tikhon Jelvis Jul 18 '12 at 8:37
2  
Or, to be even cooler, like this: fibs = 0 : scanl (+) 1 fibs –  Ed'ka Jul 18 '12 at 9:02
    
Thanks a lot, it is a wonderful solution, and I can feel the power of haskell from these codes. –  aasa Jul 18 '12 at 9:02
4  
@Ed'ka Why stop half way? fix ((0:) . scanl (+) 1). –  Daniel Fischer Jul 18 '12 at 9:07
    
I saw a really nice one the other day: `let fibs@(t:fibs') = 1:zipWith (+) fibs fibs' in fibs –  Axman6 Jul 18 '12 at 12:48
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