You're correct, the type is `y :: [IO String]`

.

Well, there are essentially main two parts here:

## How to turn [IO String] into IO [String]

`[IO String]`

is a list of of `IO`

actions and what we need is an IO action that carries a list of strings (that is, `IO [String]`

). Luckily, the function sequence provides exactly what we need:

```
sequence :: Monad m => [m a] -> m [a]
y' = sequence y :: IO [String]
```

Now the `mapM`

function can simplify this, and we can rewrite `y'`

as:

```
y' = mapM readFile directoryContents
```

`mapM`

does the sequence for us.

## How to get at the [String]

Our type is now `IO [String]`

, so the question is now "How do we get the [String] out of the IO?" This is what the function `>>=`

(bind) does:

```
(>>=) :: Monad m => m a -> (a -> m b) -> m b
-- Specialized to IO, that type is:
(>>=) :: IO a -> (a -> IO b) -> IO b
```

We also have a function `return :: Monad m => a -> m a`

which can put a value "into" `IO`

.

So with these two functions, if we have some function `f :: [String] -> SomeType`

, we can write:

```
ourResult = y' >>= (\theStringList -> return (f theStringList)) :: IO SomeType
```

Functions can be "chained" together with the `>>=`

function. This can be a bit unreadable at times, so Haskell provides `do`

notation to make things visually simpler:

```
ourResult = do
theStringList <- y'
return $ f theStringList
```

The compiler internally turns this into `y' >>= (\theStringList -> f theStringList)`

, which is the same as the `y' >>= f`

that we had before.

## Putting it all together

We probably don't actually want `y'`

floating around, so we can eliminate that and arrive at:

```
ourResult = do
theStringList <- mapM readFile directoryContents
return $ f theStringList
```

## Even more simplification

It turns out, this doesn't actually need the full power of `>>=`

. In fact, all we need is `fmap`

! This is because the function `f`

only has one argument "inside" of `IO`

and we aren't using any other previous `IO`

result: we're making a result then immediately using it.

Using the law

```
fmap f xs == xs >>= return . f
```

we can rewrite the `>>=`

code to use fmap like this:

```
ourResult = fmap f (mapM readFile directoryContents)
```

If we want to be even more terse, there is an infix synonym for `fmap`

called `<$>`

:

```
ourResult = f <$> mapM readFile directoryContents
```