Although this is already rather old, let me chime in, there's one crucial point that hasn't been addressed before.
First, the timings of the different programmes on my box. Since I'm on a 64-bit linux system, they show somewhat different characteristics: using
Integer instead of
Int64 does not improve performance as it would with a 32-bit GHC, where each
Int64 operation would incur the cost of a C-call while the computations with
Integers fitting in signed 32-bit integers don't need a foreign call (since only few operations exceed that range here,
Integer is the better choice on a 32-bit GHC).
- C: 0.3 seconds
- Original Haskell: 14.24 seconds, using
Integer instead of
Int64: 33.96 seconds
- KennyTM's improved version: 5.55 seconds, using
Int: 1.85 seconds
- Chris Kuklewicz's version: 5.73 seconds, using
Int: 1.90 seconds
- FUZxxl's version: 3.56 seconds, using
quotRem instead of
divMod: 1.79 seconds
So what have we?
- Calculate the length with an accumulator so the compiler can transform it (basically) into a loop
- Don't recalculate the sequence lengths for the comparisons
- Don't use
divMod when it's not necessary,
quotRem are much faster
What is still missing?
if (j % 2 == 0)
j = j / 2;
j = 3 * j + 1;
Any C compiler I have used transforms the test
j % 2 == 0 into a bit-masking and doesn't use a division instruction. GHC does not (yet) do that. So testing
even n or computing
n `quotRem` 2 is quite an expensive operation. Replacing
nextNumber in KennyTM's
Integer version with
nextNumber :: Integer -> Integer
| fromInteger n .&. 1 == (0 :: Int) = n `quot` 2
| otherwise = 3*n+1
reduces its running time to 3.25 seconds (Note: for
n `quot` 2 is faster than
n `shiftR` 1, that takes 12.69 seconds!).
Doing the same in the
Int version reduces its running time to 0.41 seconds. For
Ints, the bit-shift for division by 2 is a bit faster than the
quot operation, reducing its running time to 0.39 seconds.
Eliminating the construction of the list (that doesn't appear in the C version either),
module Main (main) where
result :: Int
result = findMax 0 0 1
findMax :: Int -> Int -> Int -> Int
findMax start len can
| can > 1000000 = start
| canlen > len = findMax can canlen (can+1)
| otherwise = findMax start len (can+1)
canlen = findLen 1 can
findLen :: Int -> Int -> Int
findLen l 1 = l
findLen l n
| n .&. 1 == 0 = findLen (l+1) (n `shiftR` 1)
| otherwise = findLen (l+1) (3*n+1)
main :: IO ()
main = print result
yields a further small speedup, resulting in a running time of 0.37 seconds.
So the Haskell version that's in close correspondence to the C version doesn't take that much longer, it's a factor of ~1.3.
Well, let's be fair, there's an inefficiency in the C version that's not present in the Haskell versions,
if (this_terms > terms)
terms = this_terms;
longest = i;
appearing in the inner loop. Lifting that out of the inner loop in the C version reduces its running time to 0.27 seconds, making the factor ~1.4.