import Data.List
a = foldl' (+) 0 [1..99999999]
main = putStrLn $ show $ a

This program takes a while to run. But a does not depend on anything and thus is constant. It could be perfectly calculated at compile time. Why is not GHC optimizing for this? Is there a flag for it to do so, or should I just replace that kind of constant calculation by the values themselves?

  • 1
    a isn't actually quite constant because it's polymorphic. GHC deduces the type as (Num a, Enum a) => a, which internally translates to a function requiring class dictionary arguments. (However even if you make it a :: Int, the value will be calculated only at runtime.) – leftaroundabout Sep 8 '13 at 12:40
  • 4
    What you are talking about is called supercompilation and it's not quite as easy as you make it seem. It's a research subject and I believe some people are testing this with Haskell, but it's nowhere near production ready. You can get it with some Template Haskell hackery, but it's not generally recommended. – kqr Sep 8 '13 at 13:31

This is not a perfect solution, but as kqr already remarked you can of course achieve your goal with Template Haskell:

{-# LANGUAGE TemplateHaskell #-}

import Language.Haskell.TH
import Data.List

a :: Integer
a = $( return . LitE . IntegerL $ foldl' (+) 0 [1..99999999] )

main = print a

This generates the integer literal 4999999950000000 from the fold expression, before actually starting to compile the program.


This is the same as the discussion covered by this reddit thread. Basically, what you want is but a simple case which is uncommon in practice. Optimizing with constant folding quickly turns into problems regarding Gödel's theorem and the Halting problem.

  • 4
    Why can't there just be a pragma that says "compute this at compile time" so that the responsibility of proving termination is on the programmer? – Gabriel Gonzalez Sep 8 '13 at 18:24
  • 3
    I don't understand how that applies. All I'm asking is a compiler pragma that tells ghc to try to compute the value at compile time. If it doesn't terminate, then I'm okay with that. – Gabriel Gonzalez Sep 8 '13 at 18:36
  • 4
    That's fine with me. I don't mind if I don't know if it will terminate. Like I said, the burden of worrying about termination on the programmer, and I'm happy to wait until I'm tired of waiting. – Gabriel Gonzalez Sep 8 '13 at 19:17
  • 4
    I don't know if I'm right, but that's okay. Like I said, just let me worry about that. After all, Haskell already has UndecidableInstances which moves the burden of proof of decidability to the programmer, so why is this any different? Just let the programmer worry about whether or not it is decidable. – Gabriel Gonzalez Sep 8 '13 at 19:23
  • 1
    @MihaiMaruseac Human-provided annotations are a relatively common strategy for giving the compiler facts about individual special cases that are impossible to deduce automatically in general. unsafePerformIO and friends are in fact exactly this; by using them you assert that it is okay to perform this particular IO action as if it was a pure function, and the resulting disaster if you were wrong is your problem. Mercury's versions of the same things are explicitly called "promises", and it even has one about termination analysis. – Ben Sep 9 '13 at 2:35

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