Consider the description of what `mfix`

does:

The fixed point of a monadic computation. `mfix f`

executes the action `f`

only once, with the eventual output fed back as the input.

The word "executes", in the context of `Free`

, means creating layers of the `Functor`

. Thus, "only once" means that in the result of evaluating `mfix f`

, the values held in `Pure`

constructors must fully determine how many layers of the functor are created.

Now, say we have a specific function `once`

that we know will always only create a single `Free`

constructor, plus however many `Pure`

constructors are needed to hold the leaf values. The output of 'once', then, will be only values of type `Free f a`

that are isomorphic to some value of type `f a`

. With this knowledge, we can un-`Free`

the output of `once`

safely, to get a value of type `f a`

.

Now, note that because `mfix`

is required to "execute the action only once", the result of `mfix once`

should, for a conforming instance, contain no additional monadic structure than `once`

creates in a single application. Thus we can deduce that the value obtained from `mfix once`

must also be isomorphic to a value of type `f a`

.

Given any function with type `a -> f a`

for some `Functor`

`f`

, we can wrap the result with a single `Free`

and get a function of type `a -> Free f a`

which satisfies the description of `once`

above, and we've already established that we can unwrap the result of `mfix once`

to get a value of type `f a`

back.

Therefore, a conforming instance `(Functor f) => MonadFix (Free f)`

would imply being able to write, via the wrapping and unwrapping described above, a function `ffix :: (Functor f) => (a -> f a) -> f a`

that would work for all instances of `Functor`

.

That's obviously not a proof that you *can't* write such an instance... but if it were possible, `MonadFix`

would be completely superfluous, because you could just as easily write `ffix`

directly. (And I suppose reimplement it as `mfix`

with a `Monad`

constraint, using `liftM`

. Ugh.)