(N.B. this combines a bit from both mine and @Gabriel's comments above.)
It's possible for every inhabitant of the
Fixed point of a
Functor to be infinite, i.e.
let x = (Fix (Id x)) in x === (Fix (Id (Fix (Id ...)))) is the only inhabitant of
Free differs immediately from
Fix in that it ensures there is at least one finite inhabitant of
Free f. In fact, if
Fix f has any infinite inhabitants then
Free f has infinitely many finite inhabitants.
Another immediate side-effect of this unboundedness is that
Functor f => Fix f isn't a
Functor anymore. We'd need to implement
fmap :: Functor f => (a -> b) -> (f a -> f b), but
Fix has "filled all the holes" in
f a that used to contain the
a, so we no longer have any
as to apply our
fmap'd function to.
This is important for creating
Monads because we'd like to implement
return :: a -> Free f a and have, say, this law hold
fmap f . return = return . f, but it doesn't even make sense in a
Functor f => Fix f.
So how does
Free "fix" these
Fixed point foibles? It "augments" our base functor with the
Pure constructor. Thus, for all
Pure :: a -> Free f a. This is our guaranteed-to-be-finite inhabitant of the type. It also immediately gives us a well-behaved definition of
return = Pure
So you might think of this addition as taking out potentially infinite "tree" of nested
Functors created by
Fix and mixing in some number of "living" buds, represented by
Pure. We create new buds using
return which might be interpreted as a promise to "return" to that bud later and add more computation. In fact, that's exactly what
flip (>>=) :: (a -> Free f b) -> (Free f a -> Free f b) does. Given a "continuation" function
f :: a -> Free f b which can be applied to types
a, we recurse down our tree returning to each
Pure a and replacing it with the continuation computed as
f a. This lets us "grow" our tree.
Free is clearly more general than
Fix. To drive this home, it's possible to see any type
Functor f => Fix f as a subtype of the corresponding
Free f a! Simply choose
a ~ Void where we have
data Void = Void Void (i.e., a type that cannot be constructed, is the empty type, has no instances).
To make it more clear, we can break our
break :: Fix f -> Free f a and then try to invert it with
affix :: Free f Void -> Fix f.
break (Fix f) = Free (fmap break f)
affix (Free f) = Fix (fmap affix f)
Note first that
affix does not need to handle the
Pure x case because in this case
x :: Void and thus cannot really be there, so
Pure x is absurd and we'll just ignore it.
Also note that
break's return type is a little subtle since the
a type only appears in the return type,
Free f a, such that it's completely inaccessible to any user of
break. "Completely inaccessible" and "cannot be instantiated" give us the first hint that, despite the types,
break are inverses, but we can just prove it.
(break . affix) (Free f)
=== [definition of affix]
break (Fix (fmap affix f))
=== [definition of break]
Free (fmap break (fmap affix f))
=== [definition of (.)]
Free ( (fmap break . fmap affix) f )
=== [functor coherence laws]
Free (fmap (break . affix) f)
which should show (co-inductively, or just intuitively, perhaps) that
(break . affix) is an identity. The other direction goes through in a completely identical fashion.
So, hopefully this shows that
Free f is larger than
Fix f for all
So why ever use
Fix? Well, sometimes you only want the properties of
Free f Void due to some side effect of layering
fs. In this case, calling it
Fix f makes it more clear that we shouldn't try to
fmap over the type. Furthermore, since
Fix is just a
newtype it might be easier for the compiler to "compile away" layers of
Fix since it only plays a semantic role anyway.
- Note: we can more formally talk about how
forall a. a are isomorphic types in order to see more clearly how the types of
break are harmonious. For instance, we have
absurd :: Void -> a as
absurd (Void v) = absurd v and
unabsurd :: (forall a. a) -> Void as
unabsurd a = a. But these get a little silly.