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I was hacking around with some old Haskell code and stumbled upon a surprising optimization. After a little profiling I noticed the runtime spent a fair amount of time in the following function:

divisorCount = product . map ((+1).snd) . factorise'

I assumed that the majority of the work was being done in factorise', but for brevity's sake I should change the function to:

divisorCount = product . map (succ.snd) . factorise'

When I recompiled and reran the program, to my surprise the runtime went from 0.495s to 0.325s! That's a pretty significant speed increase!

Why did that simple change cause such a dramatic performance increase? What could GHC optimize in the second function that it could not in the first?

Notes:

  • using GHC version 7.6.3

  • Both benchmarks were compiled with -O2

  • Both benchmark runtimes were amortized over 10 trials

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Boilerplate question: which optimization level you used? –  duplode May 6 '14 at 18:40
    
@duplode Can't believe I left that out, -O2 –  recursion.ninja May 6 '14 at 18:42
3  
Looking at the GHC Core usually helps in these cases. –  chi May 6 '14 at 19:08
2  
What I find extra surprising is that the succ definition from instance Enum Int actually checks whether its argument is maxBound before adding. Edit: I guess this probably means a strictness issue… maybe your first definition builds up thunks that are only evaluated by product, while the second version at least evaluates every number (up to the (+1)s, that is) before taking the product? –  gspr May 6 '14 at 20:11
    
Try (1+) instead of (+1). –  augustss May 6 '14 at 22:39

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