Well, let's consider the ways that something like this *could* be simplified. A non-monadic version would I guess look something like `const' f a = const a (f a)`

, which is clearly equivalent to `flip const`

with a more specific type. With the monadic version, however, the result of `f a`

can do arbitrary things to the non-parametric structure of the functor (i.e., what are often called "side effects"), including things that depend on the value of `a`

. What this tells us is that, despite *pretending* like we're discarding the result of `f a`

, we're actually doing nothing of the sort. Returning `a`

unchanged as the parametric part of the functor is far less essential, and we could replace `return`

with something else and still have a conceptually similar function.

So the first thing we can conclude is that it can be seen as a special case of a function like the following:

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

From here, there are two different ways to look for an underlying structure of some sort.

One perspective is to recognize the pattern of **splitting a single argument among multiple functions, then recombining the results**. This is the concept embodied by the `Applicative`

/`Monad`

instances for functions, like so:

```
doBoth :: (Monad m) => (a -> m b) -> (a -> m c) -> a -> m c
doBoth f g = (>>) <$> f <*> g
```

...or, if you prefer:

```
doBoth :: (Monad m) => (a -> m b) -> (a -> m c) -> a -> m c
doBoth = liftA2 (>>)
```

Of course, `liftA2`

is equivalent to `liftM2`

so you might wonder if lifting an operation on monads into another monad has something to do with monad transformers; in general the relationship there is awkward, but in this case it works easily, giving something like this:

```
doBoth :: (Monad m) => ReaderT a m b -> ReaderT a m c -> ReaderT a m c
doBoth = (>>)
```

...modulo appropriate wrapping and such, of course. To specialize back to your original version, the original use of `return`

now needs to be something with type `ReaderT a m a`

, which shouldn't be too hard to recognize as the `ask`

function for reader monads.

The other perspective is to recognize that functions with types like `(Monad m) => a -> m b`

**can be composed directly, much like pure functions**. The function `(<=<) :: Monad m => (b -> m c) -> (a -> m b) -> (a -> m c)`

gives a direct equivalent to function composition `(.) :: (b -> c) -> (a -> b) -> (a -> c)`

, or you can instead make use of `Control.Category`

and the `newtype`

wrapper `Kleisli`

to work with the same thing in a generic way.

We still need to split the argument, however, so what we really need here is a "branching" composition, which `Category`

alone doesn't have; by using `Control.Arrow`

as well we get `(&&&)`

, letting us rewrite the function as follows:

```
doBoth :: (Monad m) => Kleisli m a b -> Kleisli m a c -> Kleisli m a (b, c)
doBoth f g = f &&& g
```

Since we don't care about the result of the first Kleisli arrow, only its side effects, we can discard that half of the tuple in the obvious way:

```
doBoth :: (Monad m) => Kleisli m a b -> Kleisli m a c -> Kleisli m a c
doBoth f g = f &&& g >>> arr snd
```

Which gets us back to the generic form. Specializing to your original, the `return`

now becomes simply `id`

:

```
constKleisli :: (Monad m) => Kleisli m a b -> Kleisli m a a
constKleisli f = f &&& id >>> arr snd
```

Since regular functions are also `Arrow`

s, the definition above works there as well if you generalize the type signature. However, it may be enlightening to expand the definition that results for pure functions and simplify as follows:

`\f x -> (f &&& id >>> arr snd) x`

`\f x -> (snd . (\y -> (f y, id y))) x`

`\f x -> (\y -> snd (f y, y)) x`

`\f x -> (\y -> y) x`

`\f x -> x`

.

So we're back to `flip const`

, as expected!

In short, your function is some variation on either `(>>)`

or `flip const`

, but in a way that relies on the differences--the former using both a `ReaderT`

environment and the `(>>)`

of the underlying monad, the latter using the implicit side-effects of the specific `Arrow`

and the expectation that `Arrow`

side effects happen in a particular order. Because of these details, there's not likely to be any generalization or simplification available. In some sense, the definition you're using is exactly as simple as it needs to be, which is why the alternate definitions I gave are longer and/or involve some amount of wrapping and unwrapping.

A function like this would be a natural addition to a "monad utility library" of some sort. While `Control.Monad`

provides some combinators along those lines, it's far from exhaustive, and I could neither find nor recall any variation on this function in the standard libraries. I would not be at all surprised to find it in one or more utility libraries on hackage, however.

Having mostly dispensed with the question of existence, I can't really offer much guidance on naming beyond what you can take from the discussion above about related concepts.

As a final aside, note also that your function has no control flow choices based on the result of a monadic expression, since executing the expressions no matter what is the main goal. Having a computational structure independent of the parametric content (i.e., the stuff of type `a`

in `Monad m => m a`

) is usually a sign that you don't actually need a full `Monad`

, and could get by with the more general notion of `Applicative`

.

`constF :: Functor f => (a -> f b) -> a -> f a; constF f a = a <$ f a`

– FUZxxl Sep 22 '11 at 17:19`constF = ap (<$)`

Than you can inline it:`foo = getLine >>= (<$) <*> putStrLn`

– FUZxxl Sep 22 '11 at 17:42