@hammar already pointed out the problem that `maximum`

is too lazy, and how to resolve that (using `foldl1'`

, the strict version of `foldl1`

).

But there are further inefficiencies in the code.

```
cSeq n = length $ game n
```

`cSeq`

lets `game`

construct a list, only to calculate its length. Unfortunately, `length`

is not a "good consumer", so the construction of the intermediate list is not fused away. That's quite a bit of unnecessary allocation and costs time. Eliminating these lists

```
cSeq n = coll (1 :: Int) n
where
coll acc 1 = acc
coll acc m
| even m = coll (acc + 1) (m `div` 2)
| otherwise = coll (acc + 1) (3*m+1)
```

cuts down the allocation by something like 65% and the running time by about 20% (still slow). Next point, you're using `div`

, which performs a sign check in addition to the normal division. Since all numbers involved are positive, using `quot`

instead does speed it up a bit more (not much here, but it will become important later).

The next big point is that, since you haven't given type signatures, the type of the numbers (except where it was determined by the use of `length`

or by the expression type signature `(1 :: Int)`

in my rewrite) is `Integer`

. The operations on `Integer`

are considerably slower than the corresponding operations on `Int`

, so if possible, you should use `Int`

(or `Word`

) rather than `Integer`

when speed matters. If you have a 64-bit GHC, `Int`

is sufficient for these computations, that reduces the running time by about half when using `div`

, by about 70% when using `quot`

, when using the native code generator, and when using the LLVM backend, the running time is reduced by about 70% when using `div`

and by about 95% when using `quot`

.

The difference between the native code generator and the LLVM backend is mostly due to some elementary low-level optimisations.

`even`

and `odd`

are defined

```
even, odd :: (Integral a) => a -> Bool
even n = n `rem` 2 == 0
odd = not . even
```

in `GHC.Real`

. When the type is `Int`

, LLVM knows to replace the division by 2 used to determine the modulus with a bitwise and (`n .&. 1 == 0`

). The native code generator does not (yet) do many of these low-level optimisations. If you do that by hand, the code produced by the NCG and the LLVM backend performs nearly identically.

When using `div`

, both, the NCG and LLVM, are not able to replace the division with a short shift-and-add sequence, so you get the relatively slow machine division instruction with the sign-test. With `quot`

, both are able to do that for `Int`

, so you get much faster code.

The knowledge that all occurring numbers are positive allows us to replace the division by 2 with a simple right shift, without any code to correct for negative arguments, that speeds up the code produced by the LLVM backend by another ~33%, oddly it doesn't make a difference for the NCG.

So from the original that took eight second plus/minus a bit (a little less with the NCG, a little more with the LLVM backend), we've gone to

```
module Main (main)
where
import Data.List
import Data.Bits
main = print (answer (1000000 :: Int))
-- Count the length of the sequences
-- count' creates a tuple with the second value
-- being the starting number of the game
-- and the first value being the total
-- length of the chain
count' n = (cSeq n, n)
cSeq n = go (1 :: Int) n
where
go !acc 1 = acc
go acc m
| even' m = go (acc+1) (m `shiftR` 1)
| otherwise = go (acc+1) (3*m+1)
even' :: Int -> Bool
even' m = m .&. 1 == 0
-- Find the maximum chain value of the game
answer n = foldl1' max $ map count' [1..n]
```

which takes 0.37 seconds with the NCG, and 0.27 seconds with the LLVM backend on my setup.

A minute improvement in running time, but a huge reduction of allocation can be obtained by replacing the `foldl1' max`

with a manual recursion,

```
answer n = go 1 1 2
where
go ml mi i
| n < i = (ml,mi)
| l > ml = go l i (i+1)
| otherwise = go ml mi (i+1)
where
l = cSeq i
```

that makes it 0.35 resp. 0.25 seconds (and produces a tiny `52,936 bytes allocated in the heap`

).

Now if that is still too slow, you can worry about a good memoisation strategy. The best I know^{(1)} is to use an unboxed array to store the chain lengths for the numbers not exceeding the limit,

```
{-# LANGUAGE BangPatterns #-}
module Main (main) where
import System.Environment (getArgs)
import Data.Array.ST
import Data.Array.Base
import Control.Monad.ST
import Data.Bits
main :: IO ()
main = do
args <- getArgs
let bd = case args of
a:_ -> read a
_ -> 100000
print $ mxColl bd
mxColl :: Int -> (Int,Int)
mxColl bd = runST $ do
arr <- newArray (0,bd) 0
unsafeWrite arr 1 1
goColl arr bd 1 1 2
goColl :: STUArray s Int Int -> Int -> Int -> Int -> Int -> ST s (Int,Int)
goColl arr bd ms ml i
| bd < i = return (ms,ml)
| otherwise = do
nln <- collatzLength arr bd i
if ml < nln
then goColl arr bd i nln (i+1)
else goColl arr bd ms ml (i+1)
collatzLength :: STUArray s Int Int -> Int -> Int -> ST s Int
collatzLength arr bd n = go 1 n
where
go !l 1 = return l
go l m
| bd < m = go (l+1) $ case m .&. 1 of
0 -> m `shiftR` 1
_ -> 3*m+1
| otherwise = do
l' <- unsafeRead arr m
case l' of
0 -> do
l'' <- go 1 $ case m .&. 1 of
0 -> m `shiftR` 1
_ -> 3*m+1
unsafeWrite arr m (l''+1)
return (l + l'')
_ -> return (l+l'-1)
```

which does the job for a limit of 1000000 in 0.04 seconds when compiled with the NCG, 0.05 with the LLVM backend (apparently, that is not as good at optimising `STUArray`

code as the NCG is).

If you don't have a 64-bit GHC, you can't simply use `Int`

, since that would overflow then for some inputs.
But the overwhelming part of the computation is still performed in `Int`

range, so you should use that where possible and only move to `Integer`

where required.

```
switch :: Int
switch = (maxBound - 1) `quot` 3
back :: Integer
back = 2 * fromIntegral (maxBound :: Int)
cSeq :: Int -> Int
cSeq n = goInt 1 n
where
goInt acc 1 = acc
goInt acc m
| m .&. 1 == 0 = goInt (acc+1) (m `shiftR` 1)
| m > switch = goInteger (acc+1) (3*toInteger m + 1)
| otherwise = goInt (acc+1) (3*m+1)
goInteger acc m
| fromInteger m .&. (1 :: Int) == 1 = goInteger (acc+1) (3*m+1)
| m > back = goInteger (acc+1) (m `quot` 2) -- yup, quot is faster than shift for Integer here
| otherwise = goInt (acc + 1) (fromInteger $ m `quot` 2)
```

makes it harder to optimise the loop(s), so it is slower than the single loop using `Int`

, but still decent. Here (where the `Integer`

loop is never run), it takes 0.42 seconds with the NCG and 0.37 with the LLVM backend (which is pretty much the same as using `quot`

in the pure `Int`

version).

Using a similar trick for the memoised version has similar consequences, it's considerably slower than the pure `Int`

version, but still blazingly fast compared to unmemoised versions.

^{(1)} For this special (type of) problem, where you need to memoise the results for a contiguous range of arguments. For other problems, a `Map`

or some other data structure will be the better choice.

`maximum`

may be the culprit here (it's often too lazy). Try with`foldl1' max`

instead of`maximum`

. – hammar Oct 5 '12 at 7:37`foldl1 max`

gives the same error – Ron Watkins Oct 5 '12 at 7:42`foldl1'`

, not`foldl1`

. The apostrophe is important, as it's the strict version. – hammar Oct 5 '12 at 7:43