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Task: "Sum the first 15,000,000 even numbers."


nats = [1..] :: [Int]
evens = filter even nats :: [Int]

MySum:: Int
MySum= sum $ take 15000000 evens

...but MySum takes ages. More precisely, about 10-20 times slower than C/C++.

Many times I've found, that a Haskell solution coded naturally is something like 10 times slower than C. I expected that GHC was a very neatly optimizing compiler and task such this don't seem that tough.

So, one would expect something like 1.5-2x slower than C. Where is the problem?

Can this be solved better?

This is the C code I'm comparing it with:

long long sum = 0;
int n = 0, i = 1;

for (;;) {

  if (i % 2 == 0) {
    sum += i;

  if (n == 15000000)


Edit 1: I really know, that it can be computed in O(1). Please, resist.

Edit 2: I really know, that evens are [2,4..] but the function even could be something else O(1) and need to be implemented as a function.

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I believe that my work on [joachim-breitner.de/publications/CallArity-TFP.pdf call arity] makes this much faster, by allowing sum to fuse, so one might try again with GHC 7.9 (the current git HEAD). –  Joachim Breitner May 26 at 21:17
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7 Answers

up vote 23 down vote accepted

Lists are not loops

So don't be surprised if using lists as a loop replacement, you get slower code if the loop body is small.

nats = [1..] :: [Int]
evens = filter even nats :: [Int]

dumbSum :: Int
dumbSum = sum $ take 15000000 evens

sum is not a "good consumer", so GHC is not (yet) able to eliminate the intermediate lists completely.

If you compile with optimisations (and don't export nat), GHC is smart enough to fuse the filter with the enumeration,

Rec {
Main.main_go [Occ=LoopBreaker]
  :: GHC.Prim.Int# -> GHC.Prim.Int# -> [GHC.Types.Int]
[GblId, Arity=1, Caf=NoCafRefs, Str=DmdType L]
Main.main_go =
  \ (x_aV2 :: GHC.Prim.Int#) ->
    let {
      r_au7 :: GHC.Prim.Int# -> [GHC.Types.Int]
      [LclId, Str=DmdType]
      r_au7 =
        case x_aV2 of wild_Xl {
          __DEFAULT -> Main.main_go (GHC.Prim.+# wild_Xl 1);
          9223372036854775807 -> n_r1RR
        } } in
    case GHC.Prim.remInt# x_aV2 2 of _ {
      __DEFAULT -> r_au7;
      0 ->
        let {
          wild_atm :: GHC.Types.Int
          [LclId, Str=DmdType m]
          wild_atm = GHC.Types.I# x_aV2 } in
        let {
          lvl_s1Rp :: [GHC.Types.Int]
          lvl_s1Rp =
              @ GHC.Types.Int wild_atm (GHC.Types.[] @ GHC.Types.Int) } in
        \ (m_aUL :: GHC.Prim.Int#) ->
          case GHC.Prim.<=# m_aUL 1 of _ {
            GHC.Types.False ->
              GHC.Types.: @ GHC.Types.Int wild_atm (r_au7 (GHC.Prim.-# m_aUL 1));
            GHC.Types.True -> lvl_s1Rp
end Rec }

but that's as far as GHC's fusion takes it. You are left with boxing Ints and constructing list cells. If you give it a loop, like you give it to the C compiler,

module Main where

import Data.Bits

main :: IO ()
main = print dumbSum

dumbSum :: Int
dumbSum = go 0 0 1
    go :: Int -> Int -> Int -> Int
    go sm ct n
        | ct >= 15000000 = sm
        | n .&. 1 == 0   = go (sm + n) (ct+1) (n+1)
        | otherwise      = go sm ct (n+1)

you get the approximate relation of running times between the C and the Haskell version you expected.

This sort of algorithm is not what GHC has been taught to optimise well, there are bigger fish to fry elsewhere before the limited manpower is put into these optimisations.

share|improve this answer
Finally a clever answer! That point with exports is excellent among many. –  Cartesius00 Nov 15 '12 at 14:39
How can we force GHC to produce version with unboxed ints? –  Cartesius00 Nov 15 '12 at 14:45
By not having it construct an intermediate list. If you give it the above loop, it works with unboxed Int#s only. If you compile with -fllvm, you can even leave the even n instead of n .&. 1 == 0 there (yet another low-level optimisation that there was not yet time to put in GHC). If something has to be put in a list anywhere, that something has to be boxed, so if you want unboxed, help GHC avoid lists. –  Daniel Fischer Nov 15 '12 at 14:51
Perfect, thank you very much for a neat explanation. –  Cartesius00 Nov 15 '12 at 14:59
@Martin, You've been told again and again in answers that lists aren't loops. Please take it on board. –  AndrewC Nov 15 '12 at 15:24
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The problem why list fusion can't work here is actually rather subtle. Say we define the right RULE to fuse the list away:

import GHC.Base
sum2 :: Num a => [a] -> a
sum2 = sum
{-# NOINLINE [1] sum2 #-}
{-# RULES "sum" forall (f :: forall b. (a->b->b)->b->b).
                sum2 (build f) = f (+) 0 #-}

(The short explanation is that we define sum2 as an alias of sum, which we forbid GHC to inline early, so the RULE has a chance to fire before sum2 gets eliminated. Then we look for sum2 directly next to the list-builder build (see definition) and replace it by direct arithmetic.)

This has mixed success, as it yields the following Core:

Main.$wgo =
  \ (w_s1T4 :: GHC.Prim.Int#) ->
    case GHC.Prim.remInt# w_s1T4 2 of _ {
      __DEFAULT ->
        case w_s1T4 of wild_Xg {
          __DEFAULT -> Main.$wgo (GHC.Prim.+# wild_Xg 1);
          15000000 -> 0
      0 ->
        case w_s1T4 of wild_Xg {
          __DEFAULT ->
            case Main.$wgo (GHC.Prim.+# wild_Xg 1) of ww_s1T7 { __DEFAULT ->
            GHC.Prim.+# wild_Xg ww_s1T7
          15000000 -> 15000000

Which is nice, completely fused code - with the sole problem that we have a call to $wgo in a non-tail-call position. This means that we aren't looking at a loop, but actually at a deeply recursive function, with predictable program results:

Stack space overflow: current size 8388608 bytes.

The root problem here is that the Prelude's list fusion can only fuse right folds, and computing the sum as a right fold directly causes the excessive stack consumption. The obvious fix would be to use a fusion framework that can actually deal with left folds, such as Duncan's stream-fusion package, which actually implements sum fusion.

Another solution would be to hack around it - and implement the left fold using a right fold:

main = print $ foldr (\x c -> c . (+x)) id [2,4..15000000] 0

This actually produces close-to-perfect code with current versions of GHC. On the other hand, this is generally not a good idea as it relies on GHC being smart enough to eliminate the partially applied functions. Already adding a filter into the chain will break that particular optimization.

share|improve this answer
Very nice indeed! –  Cartesius00 Nov 15 '12 at 19:14
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Sum first 15,000,000 even numbers:

{-# LANGUAGE BangPatterns #-}

g :: Integer    -- 15000000*15000001 = 225000015000000
g = go 1 0 0
    go i !a c  | c == 15000000 = a       
    go i !a c  | even i = go (i+1) (a+i) (c+1)
    go i !a c           = go (i+1) a c

ought to be the fastest.

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If you want to be sure to traverse the list only once, you can write the traversal explicitly:

nats = [1..] :: [Int]

requiredOfX :: Int -> Bool -- this way you can write a different requirement
requiredOfX x = even x

dumbSum :: Int
dumbSum = dumbSum' 0 0 nats
  where dumbSum' acc 15000000 _ = acc
        dumbSum' acc count (x:xs)
          | requiredOfX x = dumbSum' (acc + x) (count + 1) xs
          | otherwise     = dumbSum' acc (count + 1) xs
share|improve this answer
But then, if this should be the right solution, we could throw Haskell through the window and stay with C. –  Cartesius00 Nov 15 '12 at 14:32
Most likely GHC optimizes the code in this way, but this way you have an objective comparison of your implementation. Also, I think even if we needed to write functions like this, there would be lots of compelling reasons to use Haskell. –  amindfv Nov 15 '12 at 14:37
@Martin Sure - if the only thing your program does is add up even numbers, it makes very little difference what language you write it in. –  Chris Taylor Nov 15 '12 at 14:38
@Martin Wait.. you think haskell is worse than C because when you choose to not use recursion in haskell, you don't get the benefits of using recursion? When you choose not to use loops or bare recursion in C, how well does that go for you? How fast is your list based solution in C? –  AndrewC Nov 15 '12 at 15:44
@AndrewC if I could award rep points for comments, I would, for that one. Seriously. :) "How fast is your list based solution in C?" This is T-shirts material. :) –  Will Ness Nov 15 '12 at 20:59
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First, you can be clever as young Gauss was and compute the sum in O(1).

Fun stuff aside, your Haskell solution uses lists. I'm quite sure your C/C++ solution doesn't. (Haskell lists are very easy to use so one is tempted to use them even in cases where it might not be appropriate.) Try benchmarking this:

sumBy2 :: Integer -> Integer
sumBy2 = f 0
    f result n | n <= 1     = result
               | otherwise  = f (n + result) (n - 2)

Compile it using GHC with -O2 argument. This function is tail-recursive so compiler can implement it very efficiently.

Update: If you want it using even function, it's possible:

sumBy2 :: Integer -> Integer
sumBy2 = f 0
    f result n | n <= 0     = result
               | even n     = f (n + result) (n - 1)
               | otherwise  = f result (n - 1)

You can also easily make the filtering function a parameter:

sumFilter :: (Integral a) => (a -> Bool) -> a -> a
sumFilter filtfn = f 0
    f result n | n <= 0     = result
               | filtfn n   = f (n + result) (n - 1)
               | otherwise  = f result (n - 1)
share|improve this answer
Well, altough you've cheated and omitted the even function, that could be the answer. But it then means, that GHC is an idiot and cannot optimize even this simple scenario with filter. –  Cartesius00 Nov 15 '12 at 14:36
If one thing is certain, it's that GHC is not an idiot. –  amindfv Nov 15 '12 at 14:40
@amindfv That's definitely true, but the optimizer is far from perfect. –  Cartesius00 Nov 15 '12 at 14:42
@Martin Please post your C/C++ version so that we can compare. –  Petr Pudlák Nov 15 '12 at 15:16
@Martin if ghc is an idiot because it can't optimise this simple code, who's the idiot for rejecting the best optimization - a better algorithm. You're aware of an O(1) algorithm. Use it. When you have a genuine problem with haskell's speed, I'll be interested. Yet another rejection of good programming in favour of racing compilers pointlessly from you. –  AndrewC Nov 15 '12 at 15:54
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Strict version works much faster:

foldl' (+) 0 $ take 15000000 [2, 4..]
share|improve this answer
No, unfortunately, it does NOT. At least on my machine. –  Cartesius00 Nov 15 '12 at 14:11
[2,4...], no the even function is ALSO ESSENTIAL. –  Cartesius00 Nov 15 '12 at 14:12
@Martin: It certainly should. How are you compiling your program? –  Sarah Nov 15 '12 at 14:12
@Sarah You're underestimating GHC. Since the type is given as Int, it makes the other version strict by itself, so there's no difference to foldl' (+) 0. –  Daniel Fischer Nov 15 '12 at 14:22
You are right, I was using the optimizations wrong. –  Sarah Nov 15 '12 at 14:43
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Another thing to note is that nats and evens are so-called Constant Applicative Forms, or CAFs for short. Basically, those correspond to top-level definitions without any arguments. CAFs are a bit of an odd duck, for instance being the reason for the Dreaded Monomorphism Restriction; I'm not sure the language definition even allows CAFs to be inlined.

In my mental model of how Haskell executes, by the time dumbSum returns a value, evens will be evaluated to look something like 2:4: ... : 30000000 : <thunk> and nats to 1:2: ... : 30000000 : <thunk>, where the <thunk>s represent something that's not been looked at yet. If my understanding is correct, these allocations of : do have to happen and can't be optimized away.

So one way of speeding things up without altering your code too much would be to simply write:

dumbSum :: Int
dumbSum = sum . take 15000000 . filter even $ [1..]


dumbSum = sum $ take 15000000 evens where
    nats = [1..]
    evens = filter even nats

On my machine, compiled with -O2, that alone seems to result in a roughly 30% speedup.

I'm no GHC connaisseur (I've never even profiled a Haskell program!), so I could be wildly off the mark, though.

share|improve this answer
no, compiled with -O2, the OP code (plus main = print dumbSum definition) runs standalone in 1MB, but without it, it uses hundreds of MB. I take it to mean that with -O2 the lists aren't retained. –  Will Ness Nov 15 '12 at 21:22
@WillNess: Fair enough, I didn't think to check the space usage. GHC is smarter than I thought it was, then! Thanks for the correction! –  yatima2975 Nov 15 '12 at 21:38
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