(N.B. this combines a bit from both mine and @Gabriel's comments above.)

It's possible for every inhabitant of the `Fix`

ed 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 `Fix Identity`

. `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 `a`

s to apply our `fmap`

'd function to.

This is important for creating `Monad`

s 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 `Fix`

ed point foibles? It "augments" our base functor with the `Pure`

constructor. Thus, for all `Functor f`

, `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`

.

```
return = Pure
```

So you might think of this addition as taking out potentially infinite "tree" of nested `Functor`

s 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.

Now, `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 `Fix`

'd `Functor`

s with `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, `affix`

and `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 `Functor f`

.

So why ever use `Fix`

? Well, sometimes you only want the properties of `Free f Void`

due to some side effect of layering `f`

s. In this case, calling it `Fix f`

makes it more clear that we shouldn't try to `(>>=)`

or `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
`Void`

and `forall a. a`

are isomorphic types in order to see more clearly how the types of `affix`

and `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.

`do`

notation and reuse of combinators from`Control.Monad`

(like`replicateM_`

and`forM_`

in the examples). A common trick is to build up the type using a free monad but then demand that the result has type`FreeT f m Void`

so that it can be converted to the fixed point of a functor. – Gabriel Gonzalez Jun 25 '13 at 21:05`Monad`

instance enriches`Fix`

with two things--definite termination from`return`

and natural "extension" from`(>>=)`

. A regular`(Fix f)`

cannot be guaranteed to have any (finite) values at all (i.e.`(Fix Identity)`

), but`(Free f)`

is always inhabited at least by`Pure`

. – J. Abrahamson Jun 25 '13 at 22:31`Fix`

to`Free`

is if you want to use`do`

notation or combinators from`Control.Monad`

. If you don't need those things and you can assemble`Fix`

values by hand then there is no need to go through the`Free`

intermediate. Just think of`FreeT f m Void`

as a convenient monadic way way to build up values of type`Fix`

that is a bit more beginner friendly. – Gabriel Gonzalez Jun 26 '13 at 1:06`newtype`

which might make it easier for the compiler to rip off layers, but I'm not sure in light of all the final/CPS encodings of`free`

that are lying about. – J. Abrahamson Jun 26 '13 at 6:38