I've just written this function which simply takes a pair whose second value is in some monad, and "pulls the monad out" to cover the whole pair.

``````unSndM :: Monad m => (a, m c) -> m (a, c)
unSndM (x, y) = do y' <- y
return (x, y')
``````

Is there a nicer and/or shorter or point-free or even standard way to express this?

I've got as far as the following, with -XTupleSections turned on...

``````unSndM' :: Monad m => (a, m c) -> m (a, c)
unSndM' (x, y) = y >>= return . (x,)
``````

Thanks!

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Rules of tag `code-golf`: stackoverflow.com/tags/code-golf/info –  Nakilon Oct 22 '10 at 23:53
Fair enough. The site let me add the tag without telling me there were rules associated with it. shrug –  gimboland Oct 23 '10 at 8:52

One minor point: it's possible to write this using only `fmap` (no `>>=`), so you really only need a `Functor` instance:

``````unSndM :: (Functor f) => (a, f c) -> f (a, c)
unSndM (x, y) = fmap ((,) x) y
``````

This version is a bit more general. To answer your question about a pointfree version, we can just ask `pointfree`:

``````travis@sidmouth% pointfree "unSndM (x, y) = fmap ((,) x) y"
unSndM = uncurry (fmap . (,))
``````

So, yes, an even shorter version is possible, but I personally find `uncurry` a bit hard to read and avoid it in most cases.

If I were writing this function in my own code, I'd probably use `<\$>` from `Control.Applicative`, which does shave off one character:

``````unSndM :: (Functor f) => (a, f c) -> f (a, c)
unSndM (x, y) = ((,) x) <\$> y
``````

`<\$>` is just a synonym for `fmap`, and I like that it makes the fact that this is a kind of function application a little clearer.

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The tupling also happens to be ordered conveniently, allowing a definition like `unSmdM = uncurry \$ fmap . (,)`. Interestingly, the type of this function is much more readable/descriptive than either implementation :) –  Anthony Oct 22 '10 at 15:45
I agree, but `unSndM (x, y) = (x,) <\$> y` is pretty close. –  Travis Brown Oct 22 '10 at 15:56
Ooh, I didn't know about pointfree - nice, thanks! (I'd tried hoogle, of course.) Some nice versions here, without any extra imports or modifications to libraries ;-) - thank you. :-) –  gimboland Oct 22 '10 at 22:15
Thanks for the tip about `pointfree`. I've been using `@pl` with lambdabot on #haskell the whole time. –  Ollie Saunders Oct 22 '10 at 23:58
I just love pointfree. It should be part of every Haskell IDE. –  gawi Oct 23 '10 at 1:53

If the `Traversable` and `Foldable` instances for `(,) x)` were in the library (and I suppose I must take some blame for their absence)...

``````instance Traversable ((,) x) where
traverse f (x, y) = (,) x <\$> f y

instance Foldable ((,) x) where
foldMap = foldMapDefault
``````

...then this (sometimes called 'strength') would be a specialisation of `Data.Traversable.sequence`.

``````sequence :: (Traversable t, Monad m) => t (m a) -> m (t a)
``````

so

``````sequence :: (Monad m) => ((,) x) (m a) -> m (((,) x) a)
``````

i.e.

``````sequence :: (Monad m) => (x, m a) -> m (x, a)
``````

In fact, sequence doesn't really use the full power of `Monad`: `Applicative` will do. Moreover, in this case, pairing-with-x is linear, so the `traverse` does only `<\$>` rather than other random combinations of `pure` and `<*>`, and (as has been pointed out elsewhere) you only need `m` to have functorial structure.

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Sounds like the birth of a libraries@ proposal to me :-) –  sclv Oct 22 '10 at 17:37
Nice, and costrength is also sequence! hackage.haskell.org/packages/archive/category-extras/0.53.5/doc/… –  Sjoerd Visscher Oct 22 '10 at 21:06
Astonishing stuff. I knew it looked simple enough that a category theorist must have given it a name already. :-) –  gimboland Oct 22 '10 at 22:29
It's not much of a simplification, but there is a 'sequenceA :: (Traversable t, Applicative f) => t (f a) -> f (t a)' defined in (Data.)Traversible . I figured that since you mentioned "you only need ... functorial structure", you could use it. –  BMeph May 1 '11 at 0:48

I haven't seen it written in any Haskell library (though it's probably in category-extras), but it is generally known as the "tensorial strength" of a monad. See: