This can't be done generically over all `MonadIO`

instances because of the `IO`

type in a negative position. There are some libraries on hackage that do this for specific instances (monad-control, monad-peel), but there's been some debate over whether they are semantically sound, especially with regards to how they handle exceptions and similar weird `IO`

y things.

Edit: Some people seem interested in the positive/negative position distinction. Actually, there's not much to say (and you've probably already heard it, but by a different name). The terminology comes from the world of subtyping.

The intuition behind subtyping is that "`a`

is a subtype of `b`

(which I'll write `a <= b`

) when an `a`

can be used anywhere a `b`

was expected instead". Deciding subtyping is straightforward in a lot of cases; for products, `(a1, a2) <= (b1, b2)`

whenever `a1 <= b1`

and `a2 <= b2`

, for example, which is a very straightforward rule. But there are a few tricky cases; for example, when should we decide that `a1 -> a2 <= b1 -> b2`

?

Well, we have a function `f :: a1 -> a2`

and a context expecting a function of type `b1 -> b2`

. So the context is going to use `f`

's return value as if it were a `b2`

, hence we must require that `a2 <= b2`

. The tricky thing is that the context is going to be supplying `f`

with a `b1`

, even though `f`

is going to use it as if it were an `a1`

. Hence, we must require that `b1 <= a1`

-- which looks backwards from what you might guess! We say that `a2`

and `b2`

are "covariant", or occur in a "positive position", and `a1`

and `b1`

are "contravariant", or occur in a "negative position".

(Quick aside: why "positive" and "negative"? It's motivated by multiplication. Consider these two types:

```
f1 :: ((a1 -> b1) -> c1) -> (d1 -> e1)
f2 :: ((a2 -> b2) -> c2) -> (d2 -> e2)
```

When should `f1`

's type be a subtype of `f2`

's type? I state these facts (exercise: check this using the rule above):

- We should have
`e1 <= e2`

.
- We should have
`d2 <= d1`

.
- We should have
`c2 <= c1`

.
- We should have
`b1 <= b2`

.
- We should have
`a2 <= a1`

.

`e1`

is in a positive position in `d1 -> e1`

, which is in turn in a positive position in the type of `f1`

; moreover, `e1`

is in a positive position in the type of `f1`

overall (since it is covariant, per the fact above). Its position in the whole term is the product of its position in each subterm: positive * positive = positive. Similarly, `d1`

is in a negative position in `d1 -> e1`

, which is in a positive position in the whole type. negative * positive = negative, and the `d`

variables are indeed contravariant. `b1`

is in a positive position in the type `a1 -> b1`

, which is in a negative position in `(a1 -> b1) -> c1`

, which is in a negative position in the whole type. positive * negative * negative = positive, and it's covariant. You get the idea.)

Now, let's take a look at the `MonadIO`

class:

```
class Monad m => MonadIO m where
liftIO :: IO a -> m a
```

We can view this as an explicit declaration of subtyping: we are giving a way to make `IO a`

be a subtype of `m a`

for some concrete `m`

. Right away we know we can take any value with `IO`

constructors in positive positions and turn them into `m`

s. But that's all: we have no way to turn negative `IO`

constructors into `m`

s -- we need a more interesting class for that.