The GHC optimizer seems to not be doing as well as it should. Still, you can probably build a much better implementation of
sum' using tail recursion and strict values.
Something like (using Bang Patterns):
sum' :: [Int] -> Int
sum' = sumt 0
sumt :: Int -> [Int] -> Int
sumt !n  = n
sumt !n (x:xs) = sumt (n + x) xs
I havent tested that, but I would bet it gets closer to the
Of course, you are still holding out on the optimizer to get rid of the list. You could just use the same algorithm as you do in c (using
int i and a goto):
sumToX x = sumToX' 0 1 x
sumToX' :: Int -> Int -> Int -> Int
sumToX' !n !i x = if (i <= x) then sumToX' (n+i) (i+1) x else n
You still hope that GHC does loop unwinding at the imperative level.
I havent tested any of this, btw.
EDIT: thought I should point out that
sum [1..1000000] really should be
500000500000 and is only
1784293664 because of an integer overflow. Why you would ever need to calculate this becomes an open question. Anyways, using
ghc -O2 and a naive tail recursive version with no bang patterns (which should be exactly the sum in the standard lib) got me
Which made me think that the problem was just your GHC. But, it seems my machine is just faster, because the c ran at
sumToX (with or without bang patterns) gets half way there
Edit 2: After disassembling code I think my answer to why the c is still twice as fast (as the list free version) is this: GHC has a lot more overhead before it ever gets to calling
main. GHC generates a fair bit of runtime junk. Obviously this gets amortized on real code, but compare to the beauty GCC generates:
0x0000000100000f00 <main+0>: push %rbp
0x0000000100000f01 <main+1>: mov %rsp,%rbp
0x0000000100000f04 <main+4>: mov $0x2,%eax
0x0000000100000f09 <main+9>: mov $0x1,%esi
0x0000000100000f0e <main+14>: xchg %ax,%ax
0x0000000100000f10 <main+16>: add %eax,%esi
0x0000000100000f12 <main+18>: inc %eax
0x0000000100000f14 <main+20>: cmp $0xf4241,%eax
0x0000000100000f19 <main+25>: jne 0x100000f10 <main+16>
0x0000000100000f1b <main+27>: lea 0x14(%rip),%rdi # 0x100000f36
0x0000000100000f22 <main+34>: xor %eax,%eax
0x0000000100000f24 <main+36>: leaveq
0x0000000100000f25 <main+37>: jmpq 0x100000f30 <dyld_stub_printf>
Now, I'm not much of an X86 assembly programmer, but that looks more or less perfect.
Okay, I have graduate school applications to work on. No more.