Michael already gives a good explanation in his blog article, but I'll try to illustrate it with a (contrived, but relatively small) example.

We need the following extensions:

```
{-# LANGUAGE FlexibleInstances, TypeFamilies #-}
```

Let's define a class that is simpler than `CanFilter`

, with just one parameter. I'm defining two copies of the class, because I want to demonstrate the difference in behaviour between the two instances:

```
class Twice1 f where
twice1 :: f -> f
class Twice2 f where
twice2 :: f -> f
```

Now, let's define an instance for each class. For `Twice1`

, we fix the type variables to be the same directly, and for `Twice2`

, we allow them to be different, but add an equality constraint.

```
instance Twice1 (a -> a) where
twice1 f = f . f
instance (a ~ b) => Twice2 (a -> b) where
twice2 f = f . f
```

In order to show the difference, let us define another overloaded function like this:

```
class Example a where
transform :: Int -> a
instance Example Int where
transform n = n + 1
instance Example Char where
transform _ = 'x'
```

Now we are at a point where we can see a difference. Once we define

```
apply1 x = twice1 transform x
apply2 x = twice2 transform x
```

and ask GHC for the inferred types, we get that

```
apply1 :: (Example a, Twice1 (Int -> a)) => Int -> a
apply2 :: Int -> Int
```

Why is that? Well, the instance for `Twice1`

only fires when source and target type of the function are the same. For `transform`

and the given context, we don't know that. GHC will only apply an instance once the right hand side matches, so we are left with the unresolved context. If we try to say `apply1 0`

, there will be a type error saying that there is still not enough information to resolve the overloading. We have to explicitly specify the result type to be `Int`

in this case to get through.

However, in `Twice2`

, the instance is for any function type. GHC will immediately resolve it (GHC never backtracks, so if an instance clearly matches, it's always chosen), and then try to establish the preconditions: in this case, the equality constraint, which then forces the result type to be `Int`

and allows us to resolve the `Example`

constraint, too. We can say `apply2 0`

without further type annotations.

So this is a rather subtle point about GHC's instance resolution, and the equality constraint here helps GHC's type checker along in a way that requires fewer type annotations by the user.