It looks like homework or something so I will give you enough hint so that you can work rest of the details yourself.

```
fmap1 :: (a -> b) -> IO a -> IO b
fmap1 f action =
```

`action`

is as `IO`

action and `f`

is a function from `a`

to `b`

and hence type `a -> b`

.

If you are familiar with monadic bind `>>=`

which has type (simplified for `IO`

monad)

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

Now if you look at

```
action >>= f
```

It means perform the `IO`

action which returns an output (say `out`

of type `a`

) and pass the output to `f`

which is of type `a -> IO b`

and hence `f out`

is of type `IO b`

.

If you look at the second function called `return`

which has type (again simlified for `IO`

monad)

```
return :: a -> IO a
```

It takes a pure value of type `a`

and gives an `IO`

action of type `IO a`

.

Now lets look back to `fmap`

.

```
fmap1 f action
```

which performs the `IO`

action and then runs `f`

on the output of the action and then converts the output to another `IO`

action of type `IO b`

. Therefore

```
fmap1 f action = action >>= g
where
g out = return (f out)
```

Now comes the syntactic sugar of `do`

notation. Which is just to write bind `>>=`

in another way.

In `do`

notation you can get the output of an action by

```
out <- action
```

So bind just reduces to

```
action >>= f = do
out <- action
f out
```

I think now you will be able to convert the definition of fmap to do construct.