The simplest way is to use `fmap`

, which has the following type:

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

`IO`

implements `Functor`

, which means that we can specialize the above type by substituting `IO`

for `f`

to get:

```
fmap :: (a -> b) -> IO a -> IO b
```

In other words, we take some function that converts `a`

s to `b`

s, and use that to change the result of an `IO`

action. For example:

```
getLine :: IO String
>>> getLine
Test<Enter>
Test
>>> fmap (map toUpper) getLine
Test<Enter>
TEST
```

What just happened there? Well, `map toUpper`

has type:

```
map toUpper :: String -> String
```

It takes a `String`

as an argument, and returns a `String`

as a result. Specifically, it uppercases the entire string.

Now, let's look at the type of `fmap (map toUpper)`

:

```
fmap (map toUpper) :: IO String -> IO String
```

We've upgraded our function to work on `IO`

values. It transforms the result of an `IO`

action to return an upper-cased string.

We can also implement this using `do`

notation, to:

```
getUpperCase :: IO String
getUpperCase = do
str <- getLine
return (map toUpper str)
>>> getUpperCase
Test<Enter>
TEST
```

It turns out that every monad has the following property:

```
fmap f m = do
x <- m
return (f x)
```

In other words, if any type implements `Monad`

, then it should always be able to implement `Functor`

, too, using the above definition. In fact, we can always use the `liftM`

as the default implementation of `fmap`

:

```
liftM :: (Monad m) => (a -> b) -> m a -> m b
liftM f m = do
x <- m
return (f x)
```

`liftM`

is identical to `fmap`

, except specialized to monads, which are not as general as functors.

So if you want to transform the result of an `IO`

action, you can either use:

`fmap`

,
`liftM`

, or
`do`

notation

It's really up to you which one you prefer. I personally recommend `fmap`

.