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Consider the modified Euler problem #4 -- "Find the maximum palindromic number which is a product of two numbers between 100 and 9999."

rev :: Int -> Int
rev x = rev' x 0

rev' :: Int -> Int -> Int
rev' n r
    | n == 0 = r
    | otherwise = rev' (n `div` 10) (r * 10 + n `mod` 10)

pali :: Int -> Bool
pali x = x == rev x

main :: IO ()
main = print . maximum $ [ x*y | x <- nums, y <- nums, pali (x*y)]
        nums = [9999,9998..100]
  • This Haskell solution using -O2 and ghc 7.4.1 takes about 18 seconds.
  • The similar C solution takes 0.1 second.

So Haskell is 180 times slower. What's wrong with my solution? I assume that this type of problems Haskell solves pretty well.

Appendix - analogue C solution:

#define A   100
#define B   9999
int ispali(int n)
    int n0=n, k=0;
    while (n>0) {
        k = 10*k + n%10;
        n /= 10;
    return n0 == k;
int main(void)
    int max = 0;
    for (int i=B; i>=A; i--)
        for (int j=B; j>=A; j--) {
            if (i*j > max && ispali(i*j))
                max = i*j;      }
    printf("%d\n", max);
share|improve this question
How similar is the C solution? – Fred Foo Oct 25 '12 at 16:23
@larsmans I appended the C solution. – Cartesius00 Oct 25 '12 at 16:25
Why not simply head instead of maximum? The list is sorted in descending order, so the first element is the maximum. – Rafael Caetano Oct 25 '12 at 17:31
@RafaelCaetano, the list is absolutely not in descending order. There are two loops nestedt. Test it with [9,8..1] to convince yourself. – Nicolas Dudebout Oct 25 '12 at 18:31
@NicolasDudebout, you're right of course, I was careless in my comment. Though I suppose there's a nice way of traversing the list of products in descending order... – Rafael Caetano Oct 25 '12 at 22:50
up vote 9 down vote accepted

The similar C solution

That is a common misconception.

Lists are not loops!

And using lists to emulate loops has performance implications unless the compiler is able to eliminate the list from the code.

If you want to compare apples to apples, write the Haskell structure more or less equivalent to a loop, a tail recursive worker (with strict accumulator, though often the compiler is smart enough to figure out the strictness by itself).

Now let's take a more detailed look. For comparison, the C, compiled with gcc -O3, takes ~0.08 seconds here, the original Haskell, compiled with ghc -O2 takes ~20.3 seconds, with ghc -O2 -fllvm ~19.9 seconds. Pretty terrible.

One mistake in the original code is to use div and mod. The C code uses the equivalent of quot and rem, which map to the machine division instructions and are faster than div and mod. For positive arguments, the semantics are the same, so whenever you know that the arguments are always non-negative, never use div and mod.

Changing that, the running time becomes ~15.4 seconds when compiling with the native code generator, and ~2.9 seconds when compiling with the LLVM backend.

The difference is due to the fact that even the machine division operations are quite slow, and LLVM replaces the division/remainder with a multiply-and-shift operation. Doing the same by hand for the native backend (actually, a slightly better replacement taking advantage of the fact that I know the arguments will always be non-negative) brings its time down to ~2.2 seconds.

We're getting closer, but are still a far cry from the C.

That is due to the lists. The code still builds a list of palindromes (and traverses a list of Ints for the two factors).

Since lists cannot contain unboxed elements, that means there is a lot of boxing and unboxing going on in the code, that takes time.

So let us eliminate the lists, and take a look at the result of translating the C to Haskell:

module Main (main) where

a :: Int
a = 100

b :: Int
b = 9999

ispali :: Int -> Bool
ispali n = go n 0
    go 0 acc = acc == n
    go m acc = go (m `quot` 10) (acc * 10 + (m `rem` 10))

maxpal :: Int
maxpal = go 0 b
    go mx i
        | i < a = mx
        | otherwise = go (inner mx b) (i-1)
            inner m j
                | j < a = m
                | p > m && ispali p = inner p (j-1)
                | otherwise = inner m (j-1)
                    p = i*j

main :: IO ()
main = print maxpal

The nested loop is translated to two nested worker functions, we use an accumulator to store the largest palindrome found so far. Compiled with ghc -O2, that runs in ~0.18 seconds, with ghc -O2 -fllvm it runs in ~0.14 seconds (yes, LLVM is better at optimising loops than the native code generator).

Still not quite there, but a factor of about 2 isn't too bad.

Maybe some find the following where the loop is abstracted out more readable, the generated core is for all intents and purposes identical (modulo a switch of argument order), and the performance of course the same:

module Main (main) where

a :: Int
a = 100

b :: Int
b = 9999

ispali :: Int -> Bool
ispali n = go n 0
    go 0 acc = acc == n
    go m acc = go (m `quot` 10) (acc * 10 + (m `rem` 10))

downto :: Int -> Int -> a -> (a -> Int -> a) -> a
downto high low acc fun = go high acc
    go i acc
        | i < low   = acc
        | otherwise = go (i-1) (fun acc i)

maxpal :: Int
maxpal = downto b a 0 $ \m i ->
            downto b a m $ \mx j ->
                let p = i*j
                in if mx < p && ispali p then p else mx

main :: IO ()
main = print maxpal
share|improve this answer
A factor of two speed difference isn't bad, but the readability difference really hurts. – Daniel Wagner Oct 25 '12 at 19:11
@DanielWagner You're looking at the wrong stuff. Take a look at the generated core, that's much more readable without the lists ;) But I wouldn't mind if GHC became better at eliminating lists either. Unfortunately, I have no idea how that could be done. – Daniel Fischer Oct 25 '12 at 19:18
Even if I were to accept that you might read core instead of source Haskell, you're really going to try to argue that the core is more readable than the C? From what I can see, the C code is both more readable and faster than any of the functional versions -- I think that's pretty unusual and a bit painful. – Daniel Wagner Oct 25 '12 at 19:19
No, I wasn't quite serious with the first part (the ;) unfortunately went on the next line). But of course I read the core too if I'm interested in performance. I don't find it that unusual that C is more readable for such tasks that map very well to C's concepts and not so well to Haskell's. And the speed difference, well, it's not so easy to beat a mature C compiler at its bread-and-butter stuff, we have to live with that for a few years to come. – Daniel Fischer Oct 25 '12 at 19:26
@DanielFischer Well, maybe the right answer is the bread-and-butter part of your comment :) Answer accepted. – Cartesius00 Oct 25 '12 at 20:09

@axblount is at least partly right; the following modification makes the program run almost three times as fast as the original:

maxPalindrome = foldl f 0
  where f a x | x > a && pali x = x
              | otherwise       = a

main :: IO ()
main = print . maxPalindrome $ [x * y | x <- nums, y <- nums]
  where nums = [9999,9998..100]

That still leaves a factor 60 slowdown, though.

share|improve this answer
BTW, see haskell.org/haskellwiki/Foldr_Foldl_Foldl'; -- foldl' is generally preferable to foldl – ShreevatsaR Oct 25 '12 at 16:57
@ShreevatsaR: I tried foldl' as well, it wasn't any faster. Feel free to edit it into the answer, though. – Fred Foo Oct 25 '12 at 16:58
are you using ghc -O2 ? Wonder why it's still so slow compared to what I wrote. – ErikR Oct 25 '12 at 17:01
The three times as fast comes from foldl' (or foldl) with -O2 – Nicolas Dudebout Oct 25 '12 at 17:07

This is more true to what the C code is doing:

maxpali :: [Int] -> Int
maxpali xs = go xs 0
    go [] m     = m
    go (x:xs) m = if x > m && pali(x) then go xs x else go xs m

main :: IO()
main = print . maxpali $ [ x*y | x <- nums, y <- nums ]
  where nums = [9999,9998..100]

On my box this takes 2 seconds vs .5 for the C version.

share|improve this answer
This gives the same speedup than @larsmans solution. – Nicolas Dudebout Oct 25 '12 at 17:02

Haskell may be storing that entire list [ x*y | x <- nums, y <- nums, pali (x*y)] where as the C solution calculates the maximum on the fly. I'm not sure about this.

Also the C solution will only calculate ispali if the product beats the previous maximum. I would bet Haskell calculates are palindrome products regardless of whether x*y is a possible max.

share|improve this answer
The list shouldn't be stored, that defeats the purpose of laziness. The second part might be part of the problem, though. – Fred Foo Oct 25 '12 at 16:34
The second one is true, the first one is not, and I'd upvote this answer if first part weren't there. – ShreevatsaR Oct 25 '12 at 16:36
@larsmans To find the maximum it will have to evaluate every element of the list. so it will have to store a lazy representation of every element of the list. – axblount Oct 25 '12 at 16:36
Haskell solution allocates 4 MB on the heap. – Cartesius00 Oct 25 '12 at 16:39
I've edited so more people could upvote. :) You've nailed one of the reasons for the OP's Haskell code inefficiency. larsmans's code (based on your answer) runs ~7 times faster then OP's. Then, using loops as in Daniel's answer gives it another ~9x speedup on my box. – Will Ness Oct 26 '12 at 10:14

It seems to me that you are having a branch prediction problem. In the C code, you have two nested loops and as soon as a palindrome is seen in the inner loop, the rest of the inner loop will be skipped very fast.

The way you feed this list of products instead of the nested loops I am not sure that ghc is doing any of this prediction.

share|improve this answer

Another way to write this is to use two folds, instead of one fold over the flattened list:

-- foldl g0 0 [x*y | x<-[b-1,b-2..a], y<-[b-1,b-2..a], pali(x*y)]      (A)
-- foldl g1 0 [x*y | x<-[b-1,b-2..a], y<-[b-1,b-2..a]]                 (B)
-- foldl g2 0 [ [x*y | y<-[b-1,b-2..a]] | x<-[b-1,b-2..a]]             (C)

maxpal b a = foldl f1 0 [b-1,b-2..a]                              --   (D)
    f1 m x = foldl f2 m [b-1,b-2..a]
        f2 m y | p>m && pali p = p
               | otherwise     = m  
           where p = x*y

main = print $ maxpal 10000 100

Seems to run much faster than (B) (as in larsmans's answer), too (only 3x - 4x slower then the following loops-based code). Fusing foldl and enumFromThenTo definitions gets us the "functional loops" code (as in DanielFischer's answer),

maxpal_loops b a = f (b-1) 0                                      --   (E)
    f x m | x < a     = m 
          | otherwise = g (b-1) m 
        g y m | y < a         = f (x-1) m
              | p>m && pali p = g (y-1) p 
              | otherwise     = g (y-1) m
           where p = x*y

The (C) variant is very suggestive of further algorithmic improvements (that's outside the scope of the original Q of course) that exploit the hidden order in the lists, destroyed by the flattening:

{- foldl g2 0 [ [x*y | y<-[b-1,b-2..a]] | x<-[b-1,b-2..a]]             (C)
   foldl g2 0 [ [x*y | y<-[x,  x-1..a]] | x<-[b-1,b-2..a]]             (C1)
   foldl g0 0 [ safehead 0 . filter pali $
                [x*y | y<-[x,  x-1..a]] | x<-[b-1,b-2..a]]             (C2)
   fst $ until ... (\(m,s)-> (max m .
                safehead 0 . filter pali . takeWhile (> m) $
                                                   head s, tail s))          
           (0,[ [x*y | y<-[x,  x-1..a]] | x<-[b-1,b-2..a]])            (C3)
   safehead 0 $ filter pali $ mergeAllDescending
              [ [x*y | y<-[x,  x-1..a]] | x<-[b-1,b-2..a]]             (C4)

(C3) can stop as soon as the head x*y in a sub-list is smaller than the currently found maximum. It is what short-cutting functional loops code could achieve, but not (C4), which is guaranteed to find the maximal palindromic number first. Plus, for list-based code its algorithmic nature is more visually apparent, IMO.

share|improve this answer

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