# What is the difference between Fix, Mu and Nu in Ed Kmett's recursion scheme package

In Ed Kmett's `recursion-scheme` package, there are three declarations:

``````newtype Fix f = Fix (f (Fix f))

newtype Mu f = Mu (forall a. (f a -> a) -> a)

data Nu f where
Nu :: (a -> f a) -> a -> Nu f
``````

What is the difference between those three data types?

• I don't know too much theory, but I gather that for more proofy languages, `Mu` is the least fixed point and `Nu` is the greatest fixed point. In Haskell, these three are all supposed to be equivalent (I believe). Note that it's super-easy to implement `cata` for `Mu` and `ana` for `Nu`. – dfeuer Aug 9 '17 at 3:50
• Try to solve this kata codewars.com/kata/folding-through-a-fixed-point/haskell – xgrommx Aug 10 '17 at 22:38

`Mu` represents a recursive type as its fold, and `Nu` represents it as its unfold. In Haskell, these are isomorphic, and are different ways to represent the same type. If you pretend that Haskell doesn't have arbitrary recursion, the distinction between these types becomes more interesting: `Mu f` is the least (initial) fixed point of `f`, and `Nu f` is its greatest (terminal) fixed point.

A fixed point of `f` is a type `T` an isomorphism between `T` and `f T`, i.e. a pair of inverse functions `in :: f T -> T`, `out :: T -> f T`. The type `Fix` just uses Haskell's built-in type recursion to declare the isomorphism directly. But you can implement in/out for both `Mu` and `Nu`.

For a concrete example, pretend for a moment that you can't write recursive values. The inhabitants of `Mu Maybe` , i.e. values `:: forall r. (Maybe r -> r) -> r`, are the naturals, {0, 1, 2, ...}; the inhabitants of `Nu Maybe`, i.e. values `:: exists x. (x, x -> Maybe x)`, are the conaturals {0, 1, 2, ..., ∞}. Think about the possible values of these types to see why `Nu Maybe` has an extra inhabitant.

If you want to get some intuition for these types, it can be a fun exercise to implement the following without recursion (roughly in increasing order of difficulty):

• `zeroMu :: Mu Maybe`, `succMu :: Mu Maybe -> Mu Maybe`
• `zeroNu :: Nu Maybe`, `succNu :: Nu Maybe -> Nu Maybe`, `inftyNu :: Nu Maybe`
• `muTofix :: Mu f -> Fix f`, `fixToNu :: Fix f -> Nu f`
• `inMu :: f (Mu f) -> Mu f`, `outMu :: Mu f -> f (Mu f)`
• `inNu :: f (Nu f) -> Nu f`, `outNu :: Nu f -> f (Nu f)`

You can also try to implement these, but they require recursion:

• `nuToFix :: Nu f -> Fix f`, `fixToMu :: Fix f -> Mu f`

`Mu f` is the least fixed point, and `Nu f` is the greatest, so writing a function `:: Mu f -> Nu f` is very easy, but writing a function `:: Nu f -> Mu f` is hard; it's like swimming against the current.

(At one point I was meaning to write a more detailed explanation of these types, but it might be a little too long for this format.)

• Great explanation, thank you! Is there a sources (articles/papers/books) that explain it even more detailed? For example, analogues for term-level fix points and why Nu (as representation a recursive type as its fold) is least fixed point at type level. There is also important links between LFP and initial algebras and also between GFP and terminal coalgebra. – Sergey Cherepanov Sep 1 '18 at 15:21
• I'm sure I'm missing something, but `Nu Maybe` seems to have many more inhabitants - at least many that Haskell happily type-checks. For instance, `Nu Just []`, `Nu Just "abcd"`, `Nu (const Nothing) 42` all seem appropriately typed. What am I getting wrong? – B. Mehta Sep 2 '18 at 4:34
• Wait. Conatural numbers? Is that a thing? – paulotorrens Sep 3 '18 at 16:26
• Sergey Cherepanov: I don't know of one off-hand, though here's a proof of initiality using parametricity. The connection between initial algebras and initial fixed points is sometimes called Lambek's lemma. B. Mehta: In the same way that id :: forall a. a -> a can't distinguish between different inputs, the outside world can't distinguish between Nu Just [] and Nu Just 0. paulotorrens: It's at least an idiomatic name for this type, the one-point compactification of the naturals, for this reason. – shachaf Sep 11 '18 at 18:38
• Updated link for the proof of initiality. – shachaf Sep 18 '18 at 16:04