When Haskell is trying to resolve `MonadError e m`

it, by default, scours both the `e`

and `m`

parameters together looking for any pair which happens to have an instance. This is especially hard if we don't have an `e`

showing up anywhere in the type signature outside of the constraint itself

```
unitError :: MonadError e m => m ()
unitError = return ()
```

The functional dependency says that once we've resolved `m`

, there can be only one `e`

that works. That lets the above fragment compile as it reassures Haskell that there's enough information there for it to have a non-ambiguous type.

Without the functional dependency, Haskell would complain that `unitError`

is ambiguous because it could be valid for any type `e`

and we don't have any way to know what that type is—the information has somehow evaporated into thin air.

For `MonadError`

the functional dependency usually means that the monad itself is parameterized by the error type. For instance, here's an instance

```
instance MonadError e (Either e) where
thowError = Left
catchError (Left e) f = f e
catchError (Right a) _ = Right a
```

Where `e ~ e`

and `m ~ Either e`

and we see that `m`

does indeed uniquely identify a single `e`

which could be valid.

Functional dependencies are "nearly" equivalent to Type Families as well. Type Families are sometimes a little easier to digest. For instance, here's a `MonadError`

class, TypeFamilies style

```
{-# LANGUAGE TypeFamilies #-}
class MonadError m where
type Err m
throwError :: Err m -> m a
catchError :: m a -> (Err m -> m a) -> m a
instance MonadError (Either e) where
type Err (Either e) = e
throwError = Left
catchError (Left e) f = f e
catchError (Right a) _ = Right a
```

Here, `Err`

is a type function which takes a `m`

to its particular error type `e`

and the notion if there being exactly one `e`

equal to `Err m`

for any `m`

comes naturally from our understanding of functions.