In general, what you can do is this:

```
case getValue of
Right x -> Right $ negate x
e -> e
```

What this does should be clear: it's just like pattern matching in a function argument, but against a value. To do what you need, you have a default case which catches anything not matched, and then return that.

In your particular case, however, you can do something slightly nicer:

```
negate `fmap` getValue
```

Or, with `import Control.Applicative`

, you can use `<$>`

as a synonym for `fmap`

(`negate <$> getValue`

). The `fmap`

function has type `fmap :: Functor f => (a -> b) -> f a -> f b`

. For any functor^{1}, `fmap`

converts a function on ordinary values to a function within the functor. For instance, lists are a functor, and for lists, `fmap = map`

. Here, `Either e`

represents a functor which is either an exception `Left e`

or a value `Right a`

; applying a function to a `Left`

does nothing, but applying a function to a `Right`

applies it within the `Right`

. In other words,

```
instance Functor (Either e) where
fmap _ (Left l) = Left l
fmap f (Right r) = Right $ f r
```

Thus the `case`

version is the direct answer to your question, but your particular example is more nicely approximated by `fmap`

.

**1:** To a first approximation, functors are "containers". If you're not comfortable with the various type classes, I recommed the Typeclassopedia for a comprehensive reference; there are many more tutorials out there, and the best way to get a feel for them is to just play with them. However, the `fmap`

for specific types is often readily usable (especially, in my opinion, when written `<$>`

).