The short answer is that no, there's no standard way. The slightly longer answer is that you can write a `>&>`

combinator yourself:

```
(>&>) :: Monad m => (a -> m b) -> (a -> m c) -> a -> m c
(f >&> g) x = f x >> g x
```

This does exactly what you want it to do, as you can see from the types. Using this, you have `emptyDirectory >&> copyStubFileTo :: FilePath -> IO ()`

, and so

```
mapM_ (emptyDirectory >&> copyStubFileTo) ["1", "2"]
```

Hoogle doesn't turn up anything for the type signature, unfortunately, so I think it's safe to assume that it doesn't exist.

Now, this wasn't my original implementation of `>&>`

, because I originally looked at it in terms of a similar non-monadic combinator `(&) :: (a -> b) -> (a -> c) -> a -> (b,c)`

, which I find myself reimplementing with some regularity. If you approach this non-monadically and then generalize, you end up with what I think is a collection of useful combinators (which I keep reinventing) that don't seem to exist anywhere standard (even though I feel like at least some of them should). On the chance that you ever want some more general combinators, here they are; none of these seem to exist on Hoogle. (Choosing appropriate precedences is left as an exercise for the interested reader.)

To start, you want `(&) :: (a -> b) -> (a -> c) -> a -> (b,c)`

, which is the non-monadic version of what you want. You can't coalesce the `b`

and `c`

, since they're arbitrary types, so we return a tuple. There's only one sensible function of this type: `(f & g) x = (f x, g x)`

. If we feed this implementation through `pointfree`

, we get something nicer:

```
(&) :: Monad m => m a -> m b -> m (a,b)
(&) = liftM2 (,)
```

This works for functions because `(r ->)`

is a monad (the reader monad); `(&)`

captures the concept of doing two things and collecting both results, and for `(r ->)`

, "doing something" is evaluating a function.

With this, however, you'd have `emptyDirectory & copyStubFileTo :: FilePath -> (IO (), IO ())`

. Oog. We thus want to lift the monad out of the tuple, so we need a function `tupleM :: Monad m => (m a, m b) -> m (a,b)`

. Writing this ourselves, it uses the `&`

function from above:

```
tupleM :: Monad m => (m a, m b) -> m (a,b)
tupleM = uncurry (&)
```

If you look at the types, this actually makes sense, though it might take a few reads (it did for me).

Now, we can define a version of `(&)`

for monadic functions:

```
(<&>) :: Monad m => (a -> m b) -> (a -> m c) -> a -> m (b, c)
f <&> g = tupleM . (f & g)
```

We now have `emptyDirectory <&> copyStubFileTo :: FilePath -> IO ((),())`

, which is an improvement. But we really don't need that tuple (although we might for more interesting operations). Instead, we want `(>&>) :: Monad m => (a -> m b) -> (a -> m c) -> a -> m c`

(the analog of `>>`

), which is what we set out to define (and, in fact, defined above). Since I'm defining all sorts of combinators anyway, I'm going to define this by way of `<.> :: Functor f => (b -> c) -> (a -> f b) -> a -> f c`

(the functorial analogue of `<=<`

from Control.Monad).

```
(<.>) :: Functor f => (b -> c) -> (a -> f b) -> a -> f c
(f <.> g) x = f <$> g x
(>&>) :: (Monad m, Functor m) => (a -> m b) -> (a -> m c) -> a -> m c
f >&> g = snd <.> (f <&> g)
```

(If you don't like the `Functor m`

constraint, replace `<$>`

with ``liftM``

.) What's most interesting about this is that we've arrived at a completely different implementation of `>&>`

. The first implementation focuses on the "do two things" aspect of `>&>`

; the second focus on the "evaluate two functions" aspect. This second one is actually the first implementation I thought of; I didn't try writing the first implementation, because I *assumed* it would be ugly. There's probably a lesson in that :-)