# How To Negate A Function?

This might be a really dumb question but..

I have written two quick functions that check if three numbers are in descending or ascending order.

IE 2 3 5 would be true for ascending and false for descending.

1 5 3 would be false for both

I need to make a third function that will work by only calling these first two. I am using GHCi. This third function sees if the numbers are not in any order like the second example above

So it would be like

``````let newfunction = (not)Ascending && (not)Descending
``````

How do I do this though? The /= doesn't work for me

-

## 2 Answers

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)
``````
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Thank you that makes sense –  user1985863 Jan 28 '13 at 7:38
Why `ascending xs = null xs`? I think it should be just `True`. –  Roman Cheplyaka Jan 28 '13 at 9:33
@RomanCheplyaka I think if it were strictly ascending (if `<` were used instead of `<=`) it should've been indeed `ascending s@(_:_:_) = foldr (...) True \$ tails s ; ascending _ = False`. –  Will Ness Jan 28 '13 at 18:49
+1 === 1000! big fan of your posts –  Dave Alperovich Jan 30 '13 at 1:42

ertes' answer can be generalized further by introducing a type class for Boolean algebras:

``````import Control.Applicative (liftA2)

-- | A class for Boolean algebras.
class Boolean a where
top, bot :: a
notP :: a -> a
(^&^), (^|^) :: a -> a -> a

-- Default implementations for all methods
top = notP bot
bot = notP top
a ^&^ b = notP (notP a ^|^ notP b)
a ^|^ b = notP (notP a ^&^ notP b)

instance Boolean Bool where
top   = True
bot   = False
notP  = not
(^&^) = (&&)
(^|^) = (||)

instance Boolean r => Boolean (a -> r) where
top = const top
bot = const bot
notP = (notP .)
(^&^) = liftA2 (^&^)
(^|^) = liftA2 (^|^)

{-
-- We can actually generalize this to any Applicative, but this requires
-- special compiler options:
instance (Applicative f, Boolean a) => Boolean (f a) where
top = pure top
bot = pure bot
notP = fmap notP
(^&^) = liftA2 (^&^)
(^|^) = liftA2 (^|^)
-}
``````

This is similar to the standard `Monoid` class—a `Boolean` is in fact two monoids (`top` with `^&^` and `bot` with `^|^`) related by the DeMorgan laws (the default definitions for `^&^` and `^|^`). But now the operators work not just on one-argument predicates, but on arbitrary arity; for example, now we have `(<=) == ((<) ^|^ (==))`.

In addition, there are other useful "base" instances of `Boolean`; for example, machine-word types can be made into `Boolean` instances in terms of bitwise operations.

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Is there a name for this sort of dual-monoid structure? (And your default implementations for `top` and `bot` are screwed up. You defined each in terms of itself rather than the other.) –  pash Jan 29 '13 at 1:09
Shouldn't that be `(<=) == ((<) ^|^ (==))` or did I completely miss the point? –  pat Jan 29 '13 at 5:56
Nah, I done messed up. Fixed now. –  Luis Casillas Jan 29 '13 at 19:05