There is actually a `not`

function for booleans, but as always you have to get the types right. Say your existing functions have the following type:

```
ascending :: (Ord a) => [a] -> Bool
ascending (x1:x2:xs) = x1 <= x2 && ascending (x2:xs)
ascending _ = True
descending :: (Ord a) => [a] -> Bool
descending (x1:x2:xs) = x1 >= x2 && descending (x2:xs)
descending _ = True
```

Requiring both means that the lists have to be equal, because that's the only way for them to be both ascending and descending in the sense I have defined above:

```
both xs = ascending xs && descending xs
```

To invert booleans there is the `not`

function:

```
not :: Bool -> Bool
```

Then being neither is expressed with this function:

```
neither xs = not (ascending xs || descending xs)
```

This is, of course, the same as:

```
neither xs = not (ascending xs) && not (descending xs)
```

You can use applicative style with the reader functor to make this look a bit more pleasing:

```
import Control.Applicative
both = liftA2 (&&) ascending descending
neither = not . liftA2 (||) ascending descending
```

Or alternatively:

```
neither = liftA2 (&&) (not . ascending) (not . descending)
```

**More**: This gives rise to a notion of predicates:

```
type Predicate a = a -> Bool
```

A predicate is a boolean function. The two functions `ascending`

and `descending`

defined above are predicates. Instead inverting booleans, you can invert predicates:

```
notP :: Predicate a -> Predicate a
notP = (not .)
```

And instead of conjunction and disjunction on booleans, we can have them on predicates, which allows writing composite predicates more nicely:

```
(^&^) :: Predicate a -> Predicate a -> Predicate a
(^&^) = liftA2 (&&)
(^|^) :: Predicate a -> Predicate a -> Predicate a
(^|^) = liftA2 (||)
```

This lets us write `both`

and `neither`

really nicely:

```
both = ascending ^&^ descending
neither = notP ascending ^&^ notP descending
```

The following law holds for predicates,

```
notP a ^&^ notP b = notP (a ^|^ b)
```

so we can rewrite `neither`

even more nicely:

```
neither = notP (ascending ^|^ descending)
```