# Effects of monomorphism restriction on type class constraints

This code breaks when a type declaration for `baz` is added:

``````baz (x:y:_) = x == y
baz [_] = baz []
baz [] = False
``````

A common explanation (see Why can't I declare the inferred type? for an example) is that it's because of polymorphic recursion.

But that explanation doesn't explain why the effect disappears with another polymorphically recursive example:

``````foo f (x:y:_) = f x y
foo f [_] = foo f []
foo f [] = False
``````

It also doesn't explain why GHC thinks the recursion is monomorphic without type declaration.

Can the explanation of the example with `reads` in http://www.haskell.org/onlinereport/decls.html#sect4.5.5 be applied to my `baz` case?

I.e. adding a signature removes monomorphism restriction, and without the restriction an ambiguity of right-side [] appears, with an 'inherently ambigous' type of `forall a . Eq a => [a]`?

-

The equations for `baz` are in one binding group, generalisation is done after the entire group has been typed. Without a type signature, that means `baz` is assumed to have a monotype, so the type of `[]` in the recursive call is given by that (look at ghc's -ddump-simpl output). With a type signature, the compiler is explicitly told that the function is polymorphic, so it can't assume the type of `[]` in the recursive call to be the same, hence it's ambiguous.

As John L said, in `foo`, the type is fixed by the occurrence of `f` - as long as `f` has a monotype. You can create the same ambiguity by giving `f` the same type as `(==)` (which requires `Rank2Types`),

``````{-# LANGUAGE Rank2Types #-}
foo :: Eq b => (forall a. Eq a => a -> a -> Bool) -> [b] -> Bool
foo f (x:y:_) = f x y
foo f[_] = foo f []
foo _ [] = False
``````

That gives

``````Ambiguous type variable `b0' in the constraint:
(Eq b0) arising from a use of `foo'
Probable fix: add a type signature that fixes these type variable(s)
In the expression: foo f []
In an equation for `foo': foo f [_] = foo f []
``````
-
The rank 2 version of `foo` is inspiring too, thank you! I start finally to grasp what shallow types are. –  nponeccop Nov 25 '11 at 15:47
+1 Nice! Excuse me while I go play with my new understanding of Rank 2 types. ( ideone.com/RajuI ) –  Dan Burton Nov 25 '11 at 19:31
Your second example isn't polymorphically recursive. This is because the function `f` appears on both the LHS and RHS of the recursive definition. Also consider the type of `foo`, `(a -> a -> Bool) -> [a] -> Bool`. This fixes the list element type to be identical to the type of `f`'s arguments. As a result, GHC can determine that the empty list on the RHS must have the same type as the input list.
I don't think that the `reads` example is applicable to the `baz` case, because GHC is able to compile `baz` with no type signature and the monomorphism restriction disabled. Therefore I expect that GHC's type algorithm has some other mechanism by which it removes the ambiguity.