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How do I make a Constant Applicative Form into, well, not a Constant Applicative Form, to stop it being retained for the lifetime of the program?

I've tried this approach:

-- | Dummy parameter to avoid creating a CAF
twoTrues :: () -> [[[Bool]]]
twoTrues _ = map (++ (True : repeat False)) . trueBlock <$> [1..]

but it doesn't seem to work - the profile shows it as still being retained and still marks it as a CAF.

I've found one relevant Google result on this, a reply by Simon Peyton-Jones to Neil Mitchell who asked precisely this question - but that answer refers to a dead link, unfortunately.

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7 Answers 7

A complete example

Here's a little example that shows the situation:

module A where

big :: () -> [Int]
big _ = [1..10^7]

Looks like a function, right? But what does GHC do? It floats the enum to the top level!

A.big1 :: [Int]
[ Unf=Unf{Src=<vanilla>, TopLvl=True, Arity=0, Value=False,
         ConLike=False, Cheap=False, Expandable=False,
         Guidance=IF_ARGS [] 7 0}]
A.big1 =
  case A.$wf1 10 A.big2 of ww_sDD { __DEFAULT ->
  eftInt 1 ww_sDD
  }

A.big :: () -> [Int]
[Arity=1,    
 Unf=Unf{Src=InlineStable, TopLvl=True, Arity=1, Value=True,
         ConLike=True, Cheap=True, Expandable=True,
         Guidance=ALWAYS_IF(unsat_ok=True,boring_ok=True)
         Tmpl= \ _ -> A.big1}]
A.big = \ _ -> A.big1

Ooops!


So what can we do?

Turn off optimizations

That works, -Onot, but not desirable:

A.big :: () -> [Int]
[GblId, Arity=1]
A.big =
  \ _ ->
    enumFromTo
      @ Int
      $fEnumInt
      (I# 1)
      (^
         @ Int
         @ Type.Integer
         $fNumInt
         $fIntegralInteger
         (I# 10)
         (smallInteger 7))

Don't inline, and more functons

Make everything into a function, including the enumFromTo, plumbing the parameter through to the workers:

big :: () -> [Int]
big u = myEnumFromTo u 1 (10^7)
{-# NOINLINE big #-}

myEnumFromTo :: () -> Int -> Int -> [Int]
myEnumFromTo _ n m = enumFromTo n m
{-# NOINLINE myEnumFromTo #-}

Now we are finally CAF-free! Even with -O2

A.myEnumFromTo [InlPrag=NOINLINE]
  :: () -> Int -> Int -> [Int]
A.myEnumFromTo =
  \ _ (n_afx :: Int) (m_afy :: Int) ->
    $fEnumInt_$cenumFromTo n_afx m_afy

A.big [InlPrag=NOINLINE] :: () -> [Int]
A.big = \ (u_abx :: ()) -> A.myEnumFromTo u_abx A.$s^2 lvl3_rEe

Yay.


What doesn't work?

Turn off -ffull-laziness

The full laziness transformation floats definitions outwards. It is on by default with -O1 or above. Let's try turning it off with -fno-full-laziness. However, it doesn't work.

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1  
How am I supposed to use big ()? If I write main = do { print $ length $ big (); print $ length $ big () }, the common subexpression elimination is applied to the expression big () and it is floated to the top level (according to the core produced by GHC 7.0.3), and the program requires a lot of space, invalidating the whole effort to avoid sharing made in your answer. –  Tsuyoshi Ito Jul 8 '11 at 16:50
up vote 5 down vote accepted

Generalise. If you have a constant value, can you generalise this to a function of some variable? The naming of my function in the question, twoTrues, immediately suggests that this constant is the third in a sequence zeroTrues, oneTrue, twoTrues, threeTrues etc. - and indeed it is. So generalising twoTrues into a function nTrues which takes a parameter n and deleting twoTrues, would eliminate one CAF from the program.

As it happens, in this case, I had only considered the cases zeroTrues, oneTrue and twoTrues for my program because that was all I needed, but my program could naturally be extended to deal with nTrues for n > 2 - so generalising to nTrues would mean it would make sense to "generalise all the way up" to the users of zeroTrues, oneTrue etc. That would not always be the case.

Note: there might still be other CAFs to deal with, either in the code, or produced by GHC's "optimisations" (which are not really optimisations in these pathological cases).

This answer may involve more work by the programmer than is strictly necessary, however. It isn't actually necessary to generalise, as Don's answer shows.

On the other hand, in some cases, generalising a constant can make it more clear what you are actually doing, and aid reusability. It can even reveal ways to compute a series of values in a better systematic way, and/or more efficiently.

A note about this particular case (which can be ignored): In this particular case, I would not want to make nTrues itself into an infinite list (which would be a CAF again, reintroducing the original problem!) rather than a function. One reason is that while twoTrues could be useful in the form of an infinite list, I can't see how it would be useful (in my application, anyway) for nTrues to be in the form of an infinite list.

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It seems to be a long-standing problem http://hackage.haskell.org/trac/ghc/ticket/917 . And in my opinion a critical one.

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1  
It's an open research question, however. –  Don Stewart Jul 7 '11 at 17:37
    
It is sad that we have to fight the optimizer and do trial-and-error (modify a code, compile, see the core, repeat until you get a desired core) to avoid this problem. –  Tsuyoshi Ito Jul 7 '11 at 22:09
    
@Don Stewart is there any open discussion about this question? I'd like to see any proposals, arguments and counterarguments. May be interesting. –  ivan vadovič Jul 12 '11 at 23:00
    
@ivanvadovič In theory, the compiler have the right to conclude that since () does not contain anything, it can be optimised out. So the idea is to avoid () as a parameter since they can always be eliminated. Instead, whenever you want to use () as a parameter, replace it with an unused type variable. –  Earth Engine Jan 13 at 22:20

With the introduction of a dummy parameter, you also have to make it look like the result actually depends on the parameter. Otherwise, GHC's cleverness might turn it into a CAF again.

I suggest the following:

twoTrues u = map (++ (True : repeat False)) . trueBlock <$> [(u `seq` 1)..]
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You need to hide the fact that the rhs is a CAF from the optimizer. Something like this should do it.

twoTrues :: () -> [[[Bool]]]
twoTrues u = map (++ (True : repeat (false u))) . trueBlock <$> [1..]

{-# NOINLINE false #-}
false :: () -> Bool
false _ = False
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I think the [1..] will be floated to the top level no matter what though. –  Don Stewart May 22 '11 at 22:17
    
Ah, yes. You need to hide that one too. Some more obfuscated code should do. :) –  augustss May 22 '11 at 22:20

Whenever you use () as a parameter, what you are going to say is actually

Although I have declared a parameter here, I am not interesting in what it is and I am not going to do anything with its value.

You are not interesting in it, because () does not have anything interesting at all; you are not going to do anything with it, because you can do nothing with ().

The problem of it is that the compiler have the right to optimise it out since there is only one possible value to pass so its use is always predictable and so why not assume it? But it moves it back to CAF and makes the idea does not work.

Fortunately, there is another way to do so. Look at the following modification of twoTrues:

twoTrues :: a -> [[[Bool]]]
twoTrues _ = map (++ (True : repeat False)) . trueBlock <$> [1..]

Now you can use twoTrues like this:

map concat $ twoTrues()

Since a is an unused type parameter, the caller can pass anything. And because you don't know what it would be so you have no idea what you can do with it. This is actually forcing you to ignore its value. So it is basically declaring the same statement I mentioned before.

Of cause, you can now pass any thing (including undefined) to that function. But it does not matter and actually it is this possibility makes this trick workable, since the compiler can no longer predict how this function being used. When the human user sees this function they should know what you are going to say here and conclude passing () is the easiest, but even if they don't and passing something else, it would not break anything and since Haskell is lazy the additional parameter could never be evaluated at all.

So what if () being used as a result? This is even worse. Since returning () means your function do not do anything at all (in Haskell, all effects of a function shall represented in its return value), the compiler have the right to conclude your function is not necessary.

The conclusion is, () as a type shall not appear in type signatures unless used with some other type (i.e. in IO ()).

EDIT

Now one may wonder, if there is only one way to implement a -> String from a String, why the compiler cannot conclude they are the same. The answer turn out to be that you actually have two way to implement this.

usual :: a -> String
usual _ = "Hello World!"

unusual :: a -> String
unusual a = seq a "Hello World!"

For almost all input, usual value = unusual value, but usual undefined is "Hello World!" whilst unusual undefined is undefined.

In a human point of view, unusual is pretty unusual, because it forces to evaluate a value unrelated to the final result. If in any case you do need such a thing, simply call seq would be easier. Furthermore, since Haskell is by default lazy, if you want to define a function that is strict, you'd better document this behavior. So if you see such a signature without additional documentation you have the right to assume it is implemented in the usual way.

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The simplest possible solution might be to tell the compiler to inline it. (Note: this answer is untested. If it doesn't work, please comment below.)

Even if (hypothetically) the compiler refuses to inline it for some reason, you can use cpp instead, by #defining it:

#define twoTrues (map (++ (True : repeat False)) . trueBlock <$> [1..])

(although with that approach, of course, it won't appear in the module's interface, so you can only use it within that module).

The -cpp option tells GHC to preprocess the input file with cpp.

Inlining would mean duplicating the code n times if you refer to twoTrues in n>1 places. However, while that's theoretically undesirable, it's probably not going to be a significant problem in practice.

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