There are three different things in my answer:

a demonstration of a generic technique to get rid of your mutable variable

an algorithim-specific technique that makes it very easy to produce a stream

a link to a generic technique to turn any producer into an on-demand stream

First, let's make your algorithm generic in the basis of the enumeration:

```
let genblocks n =
(* base = [1; ... ; n] *)
let base = Array.to_list (Array.init n (fun i -> i+1)) in
let blocks = ref [] in
let rec loop depth block =
let iter i = loop (depth - 1) (i :: block) in
match depth with
| 0 -> blocks := block :: !blocks
| _ -> List.iter iter base
in
loop n [];
!blocks
```

Without looking at what the code does for now, there is a very easy
way to get rid of the enumeration: turn any function of type `A -> B`

that uses a mutable type with type `C`

into a function of type ```
A *
C -> B * C
```

that receives the state, and returns its modified value --
this is what is called the "state monad". So I will simply add an
additional parameter `blocks`

to your functions `loop`

and `iter`

, and
make it return not `unit`

but `int list list`

:

```
let genblocks n =
let base = Array.to_list (Array.init n (fun i -> i+1)) in
let rec loop depth blocks block =
let iter blocks i = loop (depth - 1) blocks (i :: block) in
match depth with
| 0 -> block :: blocks
| _ -> List.fold_left iter blocks base
in
loop n [] []
```

Now let's look at what this algorithm exactly does:

```
# genblocks 3;;
- : int list list =
[[3; 3; 3]; [2; 3; 3]; [1; 3; 3]; [3; 2; 3]; [2; 2; 3]; [1; 2; 3]; [3; 1; 3];
[2; 1; 3]; [1; 1; 3]; [3; 3; 2]; [2; 3; 2]; [1; 3; 2]; [3; 2; 2]; [2; 2; 2];
[1; 2; 2]; [3; 1; 2]; [2; 1; 2]; [1; 1; 2]; [3; 3; 1]; [2; 3; 1]; [1; 3; 1];
[3; 2; 1]; [2; 2; 1]; [1; 2; 1]; [3; 1; 1]; [2; 1; 1]; [1; 1; 1]]
```

When called with argument 3 (in your code 4 is hardcoded), this
algorithms returns all the 3-combinations of the numbers 1, 2 and
3. Said otherwise, it enumerates all the three-digits numbers in
a numeration system in base 3 (using digits between 1 and 3 instead of
0 and 2 as usual).

There is a very simple way to enumerate numbers that you learned in
school: to go from a number to the next, simply increment
(or decrement) it. In your case, the list starts with the "big" number
and goes to the "small" one, so we're going to decrement. With the
fact that your base is [1; N] rather than [0; N-1], the decrementation
function is written

```
let decr n block =
let rec decr n = function
| [] -> raise Exit
| 1::rest -> n :: decr n rest
| i::rest -> (i - 1) :: rest
in try Some (decr n block) with Exit -> None
```

I made it return None when we reach 0 (in your system, [1;1;1..]) to
easily stop the enumeration at this point.

```
decr 3 [3;3;3];;
- : int list option = Some [2; 3; 3]
# decr 3 [1;2;3];;
- : int list option = Some [3; 1; 3]
# decr 3 [1;1;1];;
- : int list option = None
```

From this function it is trivial to enumerate all digits:

```
let start n = Array.to_list (Array.make n n)
let genblocks n =
let rec gen = function
| None -> []
| Some curr -> curr :: gen (decr n curr)
in gen (Some (start n))
```

But the important point is that the whole state of the generation is
stored in one value only, the current number. So you can easily turn
it into a Stream:

```
let genblocks n =
let curr = ref (Some (start n)) in
Stream.from (fun _ ->
match !curr with
| None -> None
| Some block ->
curr := (decr n block);
Some block
)
# Stream.npeek 100 (genblocks 3);;
- : int list list =
[[3; 3; 3]; [2; 3; 3]; [1; 3; 3]; [3; 2; 3]; [2; 2; 3]; [1; 2; 3]; [3; 1; 3];
[2; 1; 3]; [1; 1; 3]; [3; 3; 2]; [2; 3; 2]; [1; 3; 2]; [3; 2; 2]; [2; 2; 2];
[1; 2; 2]; [3; 1; 2]; [2; 1; 2]; [1; 1; 2]; [3; 3; 1]; [2; 3; 1]; [1; 3; 1];
[3; 2; 1]; [2; 2; 1]; [1; 2; 1]; [3; 1; 1]; [2; 1; 1]; [1; 1; 1]]
```

Is there a generic way to transform producer-driven functions
(that accumulate items at the rythm most natural according to
the problem) into consumer-driven function (that produce elements one
at the time, when decided by the consumer)? Yes, and I explain it in
the following blog post:

Generators, iterators, control and continuations

The big idea is that you can, by mechanic but complex transformations
of your code, make explicit what the "context" of the producer is,
what his current state, as encoded as a complex mess of values and
control flow (which calls have been made, in which conditional branch
are you at this point). This context is then turned into a value, that
you can use, as the "numbers" used here, to derive a consumer-driven
stream.