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According to the GHC docs:

...GHC will only inline the function if it is fully applied, where "fully applied" means applied to as many arguments as appear (syntactically) on the LHS of the function definition.

Where the example given is two semantically-equivalent definitions:

comp1 :: (b -> c) -> (a -> b) -> a -> c
{-# INLINE comp1 #-}
comp1 f g = \x -> f (g x)

comp2 :: (b -> c) -> (a -> b) -> a -> c
{-# INLINE comp2 #-}
comp2 f g x = f (g x)

My questions:

  1. Is it only in the presence of INLINE pragmas that we get this strict behavior (i.e. strict syntactic view of LHS, RHS inlined w/out optimizations)?

  2. when no INLINE pragmas are given, does GHC ever transform a function like comp2 to comp1?

  3. if not, why? Is it too difficult in general for the compiler to look at the semantics of the function and decide how much and where to partially-apply and INLINE?

  4. what would happen if GHC just transformed all functions into a cascade of let... in expressions with lambdas and no bindings on the LHS?

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2 Answers 2

This is a good question. I read through the Secrets of the Glasgow Haskell Compiler Inliner paper for some clues, but didn't find much.

Here's a hand-wavy explanation. GHC actually at times takes comp1 to comp2 -- which it calls "eta expansion". See this thread for some details: http://www.haskell.org/pipermail/glasgow-haskell-users/2011-October/020979.html

There also is (or was) a problem where this eta expansion can subtly change strictness. See this commit to the docs (which doesn't seem to be in the current ones, so either they haven't been rebuilt, or this has been fixed, not sure which): http://permalink.gmane.org/gmane.comp.lang.haskell.cvs.ghc/57721

In any case the above thread has SPJ explaining why we typically want to go in that direction whenever possible. So to deliberately go in the other direction in order to improve inlining seems a bit silly. As the secrets paper discusses, inlining promiscuously is not the greatest idea -- making the pragma even more of a blunt hammer so that functions got inlined whether or not it made sense to do so would probably hurt more than help overall, not to mention increase code bloat, since modules would have to keep the different levels of eta-shifted functions around all at once.

Anyway, as someone very much not a core GHC dev, that's what seems most likely to me.

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That was very helpful, sclv. Thanks and have some karma! I'll leave the question open in case the gods of GHC descend and cast away all ignorance. –  jberryman Aug 4 '12 at 3:17

What if, in this example, c is itself a function type? I'm not clear how your proposal would work out in that scenario.

In any event, there are definitely cases where you don't want all of a function's arguments "pulled to the front." For example, you might have some code like this:

foo :: [Int] -> Int -> Int -> Int
foo list = let
  -- expensive precomputation here
  bar x y = ...
  in \ x y -> bar x y

You want foo to get partially applied, and then for multiple applications of the resulting function to share the expensive precomputation work. If instead you pulled it forward as foo list x y, you wouldn't get to share that expensive precomputation. (I've encountered this case in serious applications.)

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Thanks for the reply. I noticed I mixed up comp1 and comp2 in my second question (now corrected), which I think was confusing things. Sorry! I understand why we'd want partial-application and sharing, I'm more trying to figure out if and how GHC ever optimizes functions by moving arguments to the RHS, and if it doesn't then why, given all the frequent benefits of doing so by hand. –  jberryman Jul 27 '12 at 16:37
Ah, I see. You're arguing a transformation of comp2 to comp1, as currently specified, to encourage inlining. –  Louis Wasserman Jul 27 '12 at 17:06

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