# Histomorphisms, Zygomorphisms and Futumorphisms specialised to lists

I ended up figuring it out. See the video and slides of a talk I gave:

Original question:

In my effort to understand generic recursion schemes (i.e., that use `Fix`) I have found it useful to write list-only versions of the various schemes. It makes it much easier to understand the actual schemes (without the additional overhead of the `Fix` stuff).

However, I have not yet figured out how to define list-only versions of `zygo` and `futu`.

Here are my specialised definitions so far:

``````cataL :: (a ->        b -> b) -> b -> [a] -> b
cataL f b (a : as) = f a    (cataL f b as)
cataL _ b []       = b

paraL :: (a -> [a] -> b -> b) -> b -> [a] -> b
paraL f b (a : as) = f a as (paraL f b as)
paraL _ b []       = b

-- TODO: histo

-- DONE: zygo (see below)

anaL  :: (b ->       (a, b))               -> b -> [a]
anaL  f b = let (a, b') = f b in a : anaL f b'

anaL' :: (b -> Maybe (a, b))               -> b -> [a]
anaL' f b = case f b of
Just (a, b') -> a : anaL' f b'
Nothing      -> []

apoL :: ([b] -> Maybe (a, Either [b] [a])) -> [b] -> [a]
apoL f b = case f b of
Nothing -> []
Just (x, Left c)  -> x : apoL f c
Just (x, Right e) -> x : e

-- DONE: futu (see below)

hyloL  :: (a -> c -> c) -> c -> (b -> Maybe (a, b)) -> b -> c
hyloL f z g = cataL f z . anaL' g

hyloL' :: (a -> c -> c) -> c -> (c -> Maybe (a, c))      -> c
hyloL' f z g = case g z of
Nothing     -> z
Just (x,z') -> f x (hyloL' f z' g)
``````

How do you define `histo`, `zygo` and `futu` for lists?

• do you know the type signature `zygo` and `futu` should have? – epsilonhalbe Apr 25 '16 at 22:45
• `zygo` `Fix` version: `zygo :: Functor f => (f b -> b) -> (f (a, b) -> a) -> Fix f -> a` – haroldcarr Apr 25 '16 at 23:54
• `futu` `Mu` version: `futu :: (Mu b, Functor (PF b)) => Ann b -> (a -> F b (Futu b a)) -> a -> b` (see see hackage.haskell.org/package/pointless-haskell-0.0.9/docs/…) – haroldcarr Apr 25 '16 at 23:56
• I do not know the list-only type signature - still trying to figure it out. – haroldcarr Apr 27 '16 at 14:59

Zygomorphism is the high-falutin' mathsy name we give to folds built from two semi-mutually recursive functions. I'll give an example.

Imagine a function `pm :: [Int] -> Int` (for plus-minus) which intersperses `+` and `-` alternately through a list of numbers, such that `pm [v,w,x,y,z] = v - (w + (x - (y + z)))`. You can write it out using primitive recursion:

``````lengthEven :: [a] -> Bool
lengthEven = even . length

pm0 [] = 0
pm0 (x:xs) = if lengthEven xs
then x - pm0 xs
else x + pm0 xs
``````

Clearly `pm0` is not compositional - you need to inspect the length of the whole list at each position to determine whether you're adding or subtracting. Paramorphism models primitive recursion of this sort, when the folding function needs to traverse the whole subtree at each iteration of the fold. So we can at least rewrite the code to conform to an established pattern.

``````paraL :: (a -> [a] -> b -> b) -> b -> [a] -> b
paraL f z [] = z
paraL f z (x:xs) = f x xs (paraL f z xs)

pm1 = paraL (\x xs acc -> if lengthEven xs then x - acc else x + acc) 0
``````

But this is inefficient. `lengthEven` traverses the whole list at each iteration of the paramorphism resulting in an O(n2) algorithm.

We can make progress by noting that both `lengthEven` and `para` can be expressed as a catamorphism with `foldr`...

``````cataL = foldr

lengthEven' = cataL (\_ p -> not p) True
paraL' f z = snd . cataL (\x (xs, acc) -> (x:xs, f x xs acc)) ([], z)
``````

... which suggests that we may be able to fuse the two operations into a single pass over the list.

``````pm2 = snd . cataL (\x (isEven, total) -> (not isEven, if isEven
then x - total
else x + total)) (True, 0)
``````

We had a fold which depended on the result of another fold, and we were able to fuse them into one traversal of the list. Zygomorphism captures exactly this pattern.

``````zygoL :: (a -> b -> b) ->  -- a folding function
(a -> b -> c -> c) ->  -- a folding function which depends on the result of the other fold
b -> c ->  -- zeroes for the two folds
[a] -> c
zygoL f g z e = snd . cataL (\x (p, q) -> (f x p, g x p q)) (z, e)
``````

On each iteration of the fold, `f` sees its answer from the last iteration as in a catamorphism, but `g` gets to see both functions' answers. `g` entangles itself with `f`.

We'll write `pm` as a zygomorphism by using the first folding function to count whether the list is even or odd in length and the second one to calculate the total.

``````pm3 = zygoL (\_ p -> not p) (\x isEven total -> if isEven
then x - total
else x + total) True 0
``````

This is classic functional programming style. We have a higher order function doing the heavy lifting of consuming the list; all we had to do was plug in the logic to aggregate results. The construction evidently terminates (you need only prove termination for `foldr`), and it's more efficient than the original hand-written version to boot.

Aside: @AlexR points out in the comments that zygomorphism has a big sister called mutumorphism, which captures mutual recursion in all its glory. `mutu` generalises `zygo` in that both the folding functions are allowed to inspect the other's result from the previous iteration.

``````mutuL :: (a -> b -> c -> b) ->
(a -> b -> c -> c) ->
b -> c ->
[a] -> c
mutuL f g z e = snd . cataL (\x (p, q) -> (f x p q, g x p q)) (z, e)
``````

You recover `zygo` from `mutu` simply by ignoring the extra argument. `zygoL f = mutuL (\x p q -> f x p)`

Of course, all of these folding patterns generalise from lists to the fixpoint of an arbitrary functor:

``````newtype Fix f = Fix { unFix :: f (Fix f) }

cata :: Functor f => (f a -> a) -> Fix f -> a
cata f = f . fmap (cata f) . unFix

para :: Functor f => (f (Fix f, a) -> a) -> Fix f -> a
para f = snd . cata (\x -> (Fix \$ fmap fst x, f x))

zygo :: Functor f => (f b -> b) -> (f (b, a) -> a) -> Fix f -> a
zygo f g = snd . cata (\x -> (f \$ fmap fst x, g x))

mutu :: Functor f => (f (b, a) -> b) -> (f (b, a) -> a) -> Fix f -> a
mutu f g = snd . cata (\x -> (f x, g x))
``````

Compare the definition of `zygo` with that of `zygoL`. Also note that `zygo Fix = para`, and that the latter three folds can be implemented in terms of `cata`. In foldology everything is related to everything else.

You can recover the list version from the generalised version.

``````data ListF a r = Nil_ | Cons_ a r deriving Functor
type List a = Fix (ListF a)

zygoL' :: (a -> b -> b) -> (a -> b -> c -> c) -> b -> c -> List a -> c
zygoL' f g z e = zygo k l
where k Nil_ = z
k (Cons_ x y) = f x y
l Nil_ = e
l (Cons_ x (y, z)) = g x y z

pm4 = zygoL' (\_ p -> not p) (\x isEven total -> if isEven
then x - total
else x + total) True 0
``````
• I'll let someone else provide an answer about futumorphisms because I haven't quite been able to stuff them into my head yet. – Benjamin Hodgson Apr 28 '16 at 10:43
• Do I understand correctly then, that a zygomorphism is a special case of a mutumorphism? – Alex R Apr 28 '16 at 15:36
• @AlexR Yep! `mutu` allows each function to depend on the result of the other, whereas `zygo` allows one function to depend on the result of the other. `mutu` generalises `zygo`. – Benjamin Hodgson Apr 28 '16 at 15:43
• Your use-case-based derivation of list-only `zygo` made it easy to understand the pattern and see when to use it. Thanks! – haroldcarr Apr 30 '16 at 6:07
• One minor observation. In the examples that no longer traverse the list to determine even/odd, the `isEven` name is misleading. As written, it is convention whether ones starts the call with `True` or `False` (or one could traverse the list once before the call to determine). No big deal - and does not take away from the very useful info. Thanks. – haroldcarr May 1 '16 at 3:24

Since no one else has answered for `futu` yet, I'll try to stumble my way through. I'm going to use `ListF a b = Base [a] = ConsF a b | NilF`

Taking the type in `recursion-schemes`: `futu :: Unfoldable t => (a -> Base t (Free (Base t) a)) -> a -> t`.

I'm going to ignore the `Unfoldable` constraint and substitute `[b]` in for `t`.

``````(a -> Base [b] (Free (Base [b]) a)) -> a -> [b]
(a -> ListF b (Free (ListF b) a)) -> a -> [b]
``````

`Free (ListF b) a)` is a list, possibly with an `a`-typed hole at the end. This means that it's isomorphic to `([b], Maybe a)`. So now we have:

``````(a -> ListF b ([b], Maybe a)) -> a -> [b]
``````

Eliminating the last `ListF`, noticing that `ListF a b` is isomorphic to `Maybe (a, b)`:

``````(a -> Maybe (b, ([b], Maybe a))) -> a -> [b]
``````

Now, I'm pretty sure that playing type-tetris leads to the only sensible implementation:

``````futuL f x = case f x of
Nothing -> []
Just (y, (ys, mz)) -> y : (ys ++ fz)
where fz = case mz of
Nothing -> []
Just z -> futuL f z
``````

Summarizing the resulting function, `futuL` takes a seed value and a function which may produce at least one result, and possibly a new seed value if it produced a result.

At first I thought this was equivalent to

``````notFutuL :: (a -> ([b], Maybe a)) -> a -> [b]
notFutuL f x = case f x of
(ys, mx) -> ys ++ case mx of
Nothing -> []
Just x' -> notFutuL f x'
``````

And in practice, perhaps it is, more or less, but the one significant difference is that the real `futu` guarantees productivity (i.e. if `f` always returns, you will never be stuck waiting forever for the next list element).

• Your last point about guaranteeing productivity isn't quite right. It's more subtle than that. `f` certainly could loop forever, or throw an exception; there's no way to be sure in Haskell. The difference is that the second type allows `f` to return an `a` (and continue iteration) without returning any `b`s. In other words `futu` will always terminate if `f` does, whereas `notFutu` can be induced to loop by a terminating `f`. – Benjamin Hodgson Apr 29 '16 at 23:20
• How is your clarification different than my clarification (in the parenthetical)? Not trying to be antagonistic; just curious. – Alex R Apr 30 '16 at 3:16
• Ah, my mistake, I'd entirely misread your comment! Apologies – Benjamin Hodgson Apr 30 '16 at 8:08
• Thanks! BTW: the recursive call to `notFutuL` is missing the `f` argument. – haroldcarr May 1 '16 at 3:25

Histomorphism models dynamic programming, the technique of tabulating the results of previous subcomputations. (It's sometimes called course-of-value induction.) In a histomorphism, the folding function has access to a table of the results of earlier iterations of the fold. Compare this with the catamorphism, where the folding function can only see the result of the last iteration. The histomorphism has the benefit of hindsight - you can see all of history.

Here's the idea. As we consume the input list, the folding algebra will output a sequence of `b`s. `histo` will jot down each `b` as it emerges, attaching it to the table of results. The number of items in the history is equal to the number of list layers you've processed - by the time you've torn down the whole list, the history of your operation will have a length equal to that of the list.

This is what the history of iterating a list(ory) looks like:

``````data History a b = Ancient b | Age a b (History a b)
``````

`History` is a list of pairs of things and results, with an extra result at the end corresponding to the `[]`-thing. We'll pair up each layer of the input list with its corresponding result.

``````cataL = foldr

history :: (a -> History a b -> b) -> b -> [a] -> History a b
history f z = cataL (\x h -> Age x (f x h) h) (Ancient z)
``````

Once you've folded up the whole list from right to left, your final result will be at the top of the stack.

``````headH :: History a b -> b
headH (Ancient x) = x
headH (Age _ x _) = x

histoL :: (a -> History a b -> b) -> b -> [a] -> b
histoL f z = headH . history f z
``````

(It happens that `History a` is a comonad, but `headH` (née `extract`) is all we need to define `histoL`.)

`History` labels each layer of the input list with its corresponding result. The cofree comonad captures the pattern of labelling each layer of an arbitrary structure.

``````data Cofree f a = Cofree { headC :: a, tailC :: f (Cofree f a) }
``````

(I came up with `History` by plugging `ListF` into `Cofree` and simplifying.)

Compare this with the free monad,

``````data Free f a = Free (f (Free f a))
| Return a
``````

`Free` is a coproduct type; `Cofree` is a product type. `Free` layers up a lasagne of `f`s, with values `a` at the bottom of the lasagne. `Cofree` layers up the lasagne with values `a` at each layer. Free monads are generalised externally-labelled trees; cofree comonads are generalised internally-labelled trees.

With `Cofree` in hand, we can generalise from lists to the fixpoint of an arbitrary functor,

``````newtype Fix f = Fix { unFix :: f (Fix f) }

cata :: Functor f => (f b -> b) -> Fix f -> b
cata f = f . fmap (cata f) . unFix

histo :: Functor f => (f (Cofree f b) -> b) -> Fix f -> b
histo f = headC . cata (\x -> Cofree (f x) x)
``````

and once more recover the list version.

``````data ListF a r = Nil_ | Cons_ a r deriving Functor
type List a = Fix (ListF a)
type History' a b = Cofree (ListF a) b

histoL' :: (a -> History' a b -> b) -> b -> List a -> b
histoL' f z = histo g
where g Nil_ = z
g (Cons_ x h) = f x h
``````

Aside: `histo` is the dual of `futu`. Look at their types.

``````histo :: Functor f => (f (Cofree f a) -> a) -> (Fix f -> a)
futu  :: Functor f => (a  ->  f (Free f a)) -> (a -> Fix f)
``````

`futu` is `histo` with the arrows flipped and with `Free` replaced by `Cofree`. Histomorphisms see the past; futumorphisms predict the future. And much like `cata f . ana g` can be fused into a hylomorphism, `histo f . futu g` can be fused into a chronomorphism.

Even if you skip the mathsy parts, this paper by Hinze and Wu features a good, example-driven tutorial on histomorphisms and their usage.