Consider the code below :

```
{-# LANGUAGE MultiParamTypeClasses,FlexibleInstances,FunctionalDependencies,UndecidableInstances,FlexibleContexts #-}
class Foo a c | a -> c
instance Foo Int Float
f :: (Foo Int a) => Int -> a
f = undefined
```

Now when I see the inferred type of f in ghci

```
> :t f
> f :: Int -> Float
```

Now If I add the following code

```
g :: Int -> Float
g = undefined
h :: (Foo Int a) => Int -> a
h = g
```

I get the error

```
Could not deduce (a ~ Float)
```

I am not able to understand what has happened here? The restriction `Foo Int a`

should have restricted the type of `h`

to `Int -> Float`

as shown in the inferred type of `f`

.

Is it because type unification is occurring before resolving the instances ?

[Update]

An explanation given by Dan Doel on the cafe mailing list

The answer, I believe, is that the difference between the fundep implementation and type families is local constraint information. Fundeps do no local propagation.

So in your first definition, you've locally provided '

`Int -> a`

', which is acceptable to GHC. Then it figures out externally to the function that '`(Foo Int a) => Int -> a`

' is actually`Int -> Float`

.In the second definition, you're trying to give '

`Int -> Float`

', but GHC only knows locally that you need to provide '`Int -> a`

' with a constraint '`Foo Int a`

' which itwon'tuse to determine that`a ~ Float`

.This is not inherent to fundeps. One could make a version of fundeps that has the local constraint rules (easily so by translating to the new type families stuff). But, the difference is also the reason that overlapping instances are supported for fundeps and not type families. But I won't get into that right now.

I still don't understand what that mean. So still looking for better understandable answer.

entire purposeof fundeps! Go figure... – C. A. McCann Sep 13 '12 at 20:31