The primary source (I think) for `loeb`

is Dan Piponi's blog, *A Neighborhood of Infinity*. There he explains the whole concept in greater detail. I'll replicate a little bit of that as an answer and add some examples.

`loeb`

implements a strange kind of lazy recursion

```
loeb :: Functor a => a (a x -> x) -> a x
loeb x = fmap (\a -> a (loeb x)) x
```

Let's imagine we have a type `a`

, where `Functor a`

, and an `a`

-algebra (a function of type `a x -> x`

). You might think of this as a way of computing a value from a structure of values. For instance, here are a few `[]`

-algebras:

```
length :: [Int] -> Int
(!! 3) :: [a] -> a
const 3 :: Num a => [a] -> a
\l -> l !! 2 + l !! 3 :: Num a => [a] -> a
```

We can see that these `a`

-algebras can use both values stored in the `Functor`

and the structure of the `Functor`

itself.

Another way to think of `d :: a x -> x`

is as a value of `x`

which requires some context–a whole `Functor`

ized value `a x`

–in order to be computed. Perhaps this interpretation is more clearly written as `Reader (a x) x`

, emphasizing that this is just a value of `x`

which is delayed, awaiting the `a x`

context to be produced.

```
type Delay q x = q -> x
```

Using these ideas we can describe `loeb`

as follows. We're given a `f`

-structure containing some `Delay`

ed values, where `f`

is a `Functor`

```
Functor f, f (Delay q x)
```

Naturally, if we were given a `q`

then we could convert this into a not delayed form. In fact, there's only one (non-cheating) function that does this polymorphically:

```
force :: Functor f => f (Delay q x) -> q -> f x
force f q = fmap ($ q) f
```

What `loeb`

does is handle the extra tricky case where `q`

is actually `force f q`

, the very result of this function. If you're familiar with `fix`

, this is exactly how we can produce this result.

```
loeb :: Functor a => a (Delay (a x) x) -> a x
loeb f = fix (force f)
```

So to make an example, we simply must build a structure containing `Delay`

ed values. One natural example of this is to use the list examples from before

```
> loeb [ length :: [Int] -> Int
, const 3 :: [Int] -> Int
, const 5 :: [Int] -> Int
, (!! 2) :: [Int] -> Int
, (\l -> l !! 2 + l !! 3) :: [Int] -> Int
]
[5, 3, 5, 5, 10]
```

Here we can see that the list is full of values delayed waiting on the result of evaluating the list. This computation can proceed exactly because there are no loops in data dependency, so the whole thing can just be determined lazily. For instance, `const 3`

and `const 5`

are both immediately available as values. `length`

requires that we know the length of the list but none of the values contained so it also proceeds immediately on our fixed-length list. The interesting ones are the values delayed waiting on other values from inside our result list, but since `(!! 2)`

only ends up depending on the third value of the result list, which is determined by `const 5`

and thus can be immediately available, the computation moves forward. The same idea happens with `(\l -> l !! 2 + l !! 3)`

.

So there you have it: `loeb`

completes this strange kind of delayed value recursion. We can use it on any kind of `Functor`

, though. All we need to do is to think of some useful `Delay`

ed values.

Chris Kuklewicz's comment notes that there's not a lot you could do interestingly with `Maybe`

as your functor. That's because all of the delayed values over `Maybe`

take the form

```
maybe (default :: a) (f :: a -> a) :: Maybe a -> a
```

and all of the interesting values of `Maybe (Delay (Maybe a) a)`

ought to be `Just (maybe default f)`

since `loeb Nothing = Nothing`

. So at the end of the day, the `default`

value never even gets used---we always just have that

```
loeb (Just (maybe default f)) == fix f
```

so we may as well write that directly.

`loeb g = x where x = g <*> pure x`

. Reminds us of`fix f = x where x = f $ x`

. – Will Ness Jan 8 at 13:47