`FlexibleContexts`

is often used with type families. For example, when using `GHC.Generics`

, it's common to see signatures like

```
foo :: (Generic a, GFoo (Rep a)) => Int -> a -> a
```

This can be seen as a variation of the `MultiParamTypeClasses`

usage:

```
class (Generic a, rep ~ Rep a) => MPGeneric rep a
instance (Generic a, rep ~ Rep a) => MPGeneric rep a
mpFoo :: (MPGeneric rep a, GFoo rep) => Int -> a -> a
```

As AJFarmar pointed out, `FlexibleContexts`

is also useful with neither MPTCs nor type families. Here's a simple example:

```
newtype Ap f a = Ap (f a)
deriving instance Show (f a) => Show (Ap f a)
```

The alternative approach using `Show1`

is significantly more awkward.

A more involved example is provided by AJFarmar's comment:

```
data Free f a = Pure a | Free (f (Free f a))
deriving instance (Show a, Show (f (Free f a))) => Show (Free f a)
```

This brings in `UndecidableInstances`

as well, since it's recursive, but it does a good job of explaining just what it needs to be able to show `Free f a`

. In bleeding-edge GHC Haskell, an alternative would be to use `QuantifiedConstraints`

:

```
deriving instance (Show a, forall x. Show x => Show (f x)) => Show (Free f a)
```

but this is overkill because we only need to show `f`

applied to `Free f a`

.

`C0 a0, C1 a1 ... Cn an`

, where`C`

is a class and`a`

is a type variable mentioned in the instance head. It exists because sometimes very complex constraints are needed to properly express your program logic - this is essentially the motivation behindalltypechecker extensions.