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I was so sleepy that I wrote the following code (modified to just show the confusion):

fac s = take 10 [s, s `mod` 1 ..]

maxFactor x = if (s == [])
              then x
              else head    <-- this should be 'head x' instead of just 'head'
  where s = fac x

However, this load into ghci (and compiles) just fine. When I executed maxFactor 1, it complains (of course):

<interactive>:0:1:
    No instance for (Integral ([a0] -> a0))
      arising from a use of `maxFactor'
    Possible fix:
      add an instance declaration for (Integral ([a0] -> a0))
    In the expression: maxFactor 1
    In an equation for `it': it = maxFactor 1

<interactive>:0:11:
    No instance for (Num ([a0] -> a0))
      arising from the literal `1'
    Possible fix: add an instance declaration for (Num ([a0] -> a0))
    In the first argument of `maxFactor', namely `1'
    In the expression: maxFactor 1
    In an equation for `it': it = maxFactor 1

However, I don't understand this behavior:

fac's type is:

fac :: Integral a => a -> [a]

while maxFactor's type is:

maxFactor :: Integral ([a] -> a) => ([a] -> a) -> [a] -> a

Doesn't this mean the following:

  1. the first input to fac must be of typeclass Integral (e.g., fac 10);
  2. since in the definition of maxFactor, there is fac x, x must also be of typeclass Integral, thus, maxFactor's type would be begin with something like maxFactor :: (Integral a) => a ->... then something else? However, if that is the case, then why this code compiles since the return of maxFactor can be x or head, which when following this line of reasoning, does not have the same type?

What am I missing here?

Thanks for any inputs in advance!

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1  
This kind of issue can arise in a much simpler manner. I suspect (but I am no expert) that it can happen whenever the type checker cannot reduce an expression sufficiently. For instance, foo x = 1 + x; bar = foo head -- will fail, but foo x = 1 + x; bar x = foo head -- will compile. –  Sarah Apr 10 '12 at 16:02
    
@Sarah: The example you provide doesn't typecheck because of monomorphism restriction; if you add pragma, it typechecks (there's subtle problem though: GHCi infers type Num ([a] → a) ⇒ [a] → a and you cannot declare bar with this type, you'd need FlexibleContexts for that). –  Vitus Apr 10 '12 at 19:19
    
For what it's worth, if you compile with -Wall (or add that to your default ghci options, so that ghci "compiles" with -Wall) you'll get a warning because you didn't put a type signature on maxFactor. Then, presumably, you'll write maxFactor :: Integral a => a -> a and it will fail to compile. –  MatrixFrog Apr 11 '12 at 7:02
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2 Answers

up vote 7 down vote accepted

in maxFactor the compiler infers that the function argument x necessarily has the same type as head (in your if clause). Since you also call fac on x (which in turn calls mod) it infers that x is also some Integral class type. Consequently, the compiler infers the type

maxFactor :: Integral ([a] -> a) => ([a] -> a) -> [a] -> a

that takes some head-like and integer-like argument... which is unlikely to be a real thing.

I think the fact that you can load that code into GHCi is more a quirk of the interpreter. If you were just compiling the code above, it would fail.

Edit: I guess the issue is that the type checker can make sense of your code, however there probably isn't any sensible way to use it.

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Actually it could compile (My version is 7.2.1) :( Is this a bug in GHC now? I wonder... But still, thanks! –  Ziyao Wei Apr 10 '12 at 15:55
    
@ZiyaoWei not if you try to add those inferred type declarations. –  soulcheck Apr 10 '12 at 15:57
3  
@ZiyaoWei: It's not a bug. GHC can't know there will never be a function [a]->a that is an instance of Integral. –  leftaroundabout Apr 10 '12 at 15:57
    
Looks fishy to me, too. Of course, you could never actually use it in your compiled program. –  Sarah Apr 10 '12 at 15:57
3  
@ZiyaoWei If you want a function to be of class Integral just do it: instance Integral ([a]->a) (you'll need FlexibleInstances to compile it). You'll also have to make it and instance of Num. Exactly what you want the methods to do, well, I'll leave that to you. –  augustss Apr 10 '12 at 16:14
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As you've noticed correctly, the use of function fac inside of maxFactor adds a Integral a constraint on the type of x. So x needs to be of type Integral a => a.

In addition, the compiler sees that maxFactor either returns head, which has type [a]->a or x. Therefore x must have the more specific type Integral ([a]->a) => ([a]->a), and so maxFactor has type

maxFactor :: Integral ([a] -> a) => ([a] -> a) -> ([a] -> a)

which is exactly what you got. There's nothing "wrong" with this definition so far. If you managed to write an instance of Integral type ([a]->a) you could invoke maxFactor without problem. (Obviously maxFactor wouldn't work as expected.)

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