The Prelude function `and :: [Bool] -> Bool`

almost does what you want, but it's not monadic. Generally speaking, to lift a one-argument function into a monad, you'll want Control.Monad's `liftM :: Monad m => (a -> b) -> m a -> b a`

; however, to be more general, you can use the Prelude's `fmap :: Functor f => (a -> b) -> f a -> f b`

. All monads are functors^{1}, so this is ok. Thus, you can use

```
fand' :: Functor f => f [Bool] -> f Bool
fand' = fmap and
```

However, at least 90% of the time, I would just write that inline as `fmap and xs`

, or more probably `and <$> xs`

, using Control.Applicative's `<$>`

synonym for `fmap`

.

Of course, as I'm sure you noticed, this isn't what you want. For that, you need the Prelude's `sequence :: Monad m => [m a] -> m [a]`

. You now have a function `[m a] -> m [a]`

, and a function `f [Bool] -> f Bool`

, so we can combine these:

```
mand :: Monad m => [m Bool] -> m Bool
mand = liftM and . sequence
```

I switched to `liftM`

from `fmap`

because, although `fmap`

's "nicer" in some sense, it would impose an additional `Functor m`

constraint. That *shouldn't* be a problem, but it could be for historical reasons, so I played it safe.

Also, you might ask "How would I have ever known about `sequence`

"? The answer to that is the wonderful Hoogle, which allows you to search for Haskell functions by name *or type*. So, since you knew about `liftM :: Monad m => (a -> b) -> m a -> m b`

, you might have realized you needed something like `Monad m => [m a] -> m [a]`

; Hoogling for that does indeed turn up `sequence`

.

**1:** Or, at least, they should be—for historical reasons, though, this isn't always the case.