You can use John Hughes's constant-time append lists, which seem nowadays to be called `DList`

. The representation is a function from lists to lists: the empty list is the identity function; append is composition, and singleton is cons (partially applied). In this representation every enumeration will cost you `n`

allocations, so that may not be so good.

The alternative is to make the same algebra as a data structure:

```
type 'a seq = Empty | Single of 'a | Append of 'a seq * 'a seq
```

Enumeration is a tree walk, which will either cost some stack space or will require some kind of zipper representation. Here's a tree walk that converts to list but uses stack space:

```
let to_list t =
let rec walk t xs = match t with
| Empty -> xs
| Single x -> x :: xs
| Append (t1, t2) -> walk t1 (walk t2 xs) in
walk t []
```

Here's the same, but using constant stack space:

```
let to_list' t =
let rec walk lefts t xs = match t with
| Empty -> finish lefts xs
| Single x -> finish lefts (x :: xs)
| Append (t1, t2) -> walk (t1 :: lefts) t2 xs
and finish lefts xs = match lefts with
| [] -> xs
| t::ts -> walk ts t xs in
walk [] t []
```

You can write a fold function that visits the same elements but doesn't actually reify the list; just replace cons and nil with something more general:

```
val fold : ('a * 'b -> 'b) -> 'b -> 'a seq -> 'b
let fold f z t =
let rec walk lefts t xs = match t with
| Empty -> finish lefts xs
| Single x -> finish lefts (f (x, xs))
| Append (t1, t2) -> walk (t1 :: lefts) t2 xs
and finish lefts xs = match lefts with
| [] -> xs
| t::ts -> walk ts t xs in
walk [] t z
```

That's your linear-time, constant-stack enumeration. Have fun!