Wen using functional dependencies, I frequently hit the *Coverage Condition*. It is possible to lift it with `UndecidableInstances`

, but I usually try to stay away from that extension.

Here is a somewhat contrived example, that works without `UndecidableInstances`

:

```
{-# Language MultiParamTypeClasses, FunctionalDependencies, FlexibleInstances #-}
data Result = Result String
deriving (Eq, Show)
data Arguments a b = Arguments a b
class Applyable a b | a -> b where
apply :: a -> b -> Result
instance Applyable (Arguments a b) (a -> b -> Result) where
(Arguments a b) `apply` f = f a b
```

When I make the result type more generic, the Coverage Condition fails (hence requiring `UndecidableInstances`

):

```
{-# Language MultiParamTypeClasses, FunctionalDependencies, FlexibleInstances, UndecidableInstances #-}
data Result a = Result a
deriving (Eq, Show)
data Arguments a b = Arguments a b
class Applyable a b c | a -> b c where
apply :: a -> b -> Result c
instance Applyable (Arguments a b) (a -> b -> Result c) c where
(Arguments a b) `apply` f = f a b
```

I thought that because `b`

and `c`

are both determined by `a`

, the more generic code should not cause any problems, so my questions:

- Are there any possible issues with using
`UndecidableInstances`

here - Can I model the above scenario without relying on
`UndecidableInstances`

(maybe with type families?)

`UndecidableInstances`

. The worst that can happen is that the type checker starts looping (and tells you about it, I think). You can make the coverage condition more and more clever, but it will never do everything you could want since that's undecidable. – augustss Jan 31 '12 at 8:29