You can use `liftM2`

from `Control.Monad`

:

```
liftM2 :: Monad m => (a -> b -> c) -> m a -> m b -> m c
> :t liftM2 (++)
liftM2 (++) :: Monad m => m [a] -> m [a] -> m [a]
```

Alternatively, you could use `do`

notation:

```
(+++) :: Monad m => m [a] -> m [a] -> m [a]
ms1 +++ ms2 = do
s1 <- ms1
s2 <- ms2
return $ s1 ++ s2
```

Both of these are equivalent. In fact, the definition for `liftM2`

is implemented as

```
liftM2 :: Monad m => (a -> b -> c) -> m a -> m b -> m c
liftM2 f m1 m2 = do
val1 <- m1
val2 <- m2
return $ f val1 val2
```

Very simple! All it does is extract the values from two monadic actions and apply a function of 2 arguments to them. This goes with the function `liftM`

which performs this operation for a function of only one argument. Alternatively, as pointed out by others, you can use `IO`

's `Applicative`

instance in `Control.Applicative`

and use the similar `liftA2`

function.

You might notice that generic `Applicative`

s have similar behavior to generic `Monad`

s in certain contexts, and the reason for this is because they're mathematically very similar. In fact, for every `Monad`

, you can make an `Applicative`

out of it. Consequently, you can also make a `Functor`

out of every `Applicative`

. There are a lot of people excited about the Functor-Applicative-Monad proposal that's been around for a while, and is finally going to be implemented in an upcoming version of GHC. They make a very natural hierarchy of `Functor > Applicative > Monad`

.