We will need `TypeFamilies`

for this solution.

```
{-# LANGUAGE TypeFamilies #-}
```

The idea is to define a class `Pred`

for n-ary predicates:

```
class Pred a where
type Arg a k :: *
split :: a -> (Bool -> r) -> Arg a r
```

The problem is all about re-shuffling arguments to the predicates, so this is what the class aims to do. The associated type `Arg`

is supposed to give access to the arguments of an n-ary predicate by replacing the final `Bool`

with `k`

, so if we have a type

```
X = arg1 -> arg2 -> ... -> argn -> Bool
```

then

```
Arg X k = arg1 -> arg2 -> ... -> argn -> k
```

This will allow us to build the right result type of `conjunction`

where all arguments of the two predicates are to be collected.

The function `split`

takes a predicate of type `a`

and a continuation of type `Bool -> r`

and will produce something of type `Arg a r`

. The idea of `split`

is that if we know what to do with the `Bool`

we obtain from the predicate in the end, then we can do other things (`r`

) in between.

Not surprisingly, we'll need two instances, one for `Bool`

and one for functions for which the target is already a predicate:

```
instance Pred Bool where
type Arg Bool k = k
split b k = k b
```

A `Bool`

has no arguments, so `Arg Bool k`

simply returns `k`

. Also, for `split`

, we have the `Bool`

already, so we can immediately apply the continuation.

```
instance Pred r => Pred (a -> r) where
type Arg (a -> r) k = a -> Arg r k
split f k x = split (f x) k
```

If we have a predicate of type `a -> r`

, then `Arg (a -> r) k`

must start with `a ->`

, and we continue by calling `Arg`

recursively on `r`

. For `split`

, we can now take three arguments, the `x`

being of type `a`

. We can feed `x`

to `f`

and then call `split`

on the result.

Once we have defined the `Pred`

class, it is easy to define `conjunction`

:

```
conjunction :: (Pred a, Pred b) => a -> b -> Arg a (Arg b Bool)
conjunction x y = split x (\ xb -> split y (\ yb -> xb && yb))
```

The function takes two predicates and returns something of type `Arg a (Arg b Bool)`

. Let's look at the example:

```
> :t conjunction (>) not
conjunction (>) not
:: Ord a => Arg (a -> a -> Bool) (Arg (Bool -> Bool) Bool)
```

GHCi doesn't expand this type, but we can. The type is equivalent to

```
Ord a => a -> a -> Bool -> Bool
```

which is exactly what we want. We can test a number of examples, too:

```
> conjunction (>) not 4 2 False
True
> conjunction (>) not 4 2 True
False
> conjunction (>) not 2 2 False
False
```

Note that using the `Pred`

class, it is trivial to write other functions (like `disjunction`

), too.