You can use a value that isn't determined until the result of a computation in the construction of data in the computation by tying a recursive knot.

The following computation builds a list of values that each hold the total number of items in the list even though the total is computed by the same function that's building the list. The `let`

binding in `zipCount`

passes one of the results of `zipWithAndCount`

as the first argument to `zipWithAndCount`

.

```
zipCount :: [a] -> [(a, Int)]
zipCount xs =
let (count, zipped) = zipWithAndCount count xs
in zipped
zipWithAndCount :: Num n => b -> [a] -> (n, [(a, b)])
zipWithAndCount y [] = (0, [])
zipWithAndCount y (x:xs) =
let (count', zipped') = zipWithAndCount y xs
in (count' + 1, (x, y):zipped')
```

Running this example makes a list where each item holds the count of the total items in the list

```
> zipCount ['a'..'e']
[('a',5),('b',5),('c',5),('d',5),('e',5)]
```

This idea can be applied to Ukkonen's algorithm by passing in the `#`

s that aren't known until the entire result is known.

The general idea of recursively passing a result into a function is called a least fixed point, and is implemented in `Data.Function`

by

```
fix :: (a -> a) -> a
fix f = let x = f x in x
```

We can write `zipCount`

in points-free style in terms of `zipWithAndCount`

and `fix`

.

```
import Data.Function
zipCount :: [a] -> [(a, Int)]
zipCount = snd . fix . (. fst) . flip zipWithAndCount
```

`ST`

and`STRef`

s. You can then`runST`

to get your pure suffix tree at the end. – chi Dec 27 '14 at 17:25