The solution provided by rgrinberg can be generalized so that we can memoize any function. I am going to use associtive lists insetad of hashtables. But it does not really matter, you can easily convert all my examples to use hashtables.

First, here is a function `memo`

which takes another function and returns its memoized version. It is what nlucaroni suggested in one of the comments:

```
let memo f =
let m = ref [] in
fun x ->
try
List.assoc x !m
with
Not_found ->
let y = f x in
m := (x, y) :: !m ;
y
```

The function `memo f`

keeps a list `m`

of results computed so far. When asked to compute `f x`

it first checks `m`

to see if `f x`

has been computed already. If yes, it returns the result, otherwise it actually computes `f x`

, stores the result in `m`

, and returns it.

There is a problem with the above `memo`

in case `f`

is recursive. Once `memo`

calls `f`

to compute `f x`

, any recursive calls made by `f`

will not be intercepted by `memo`

. To solve this problem we need to do two things:

In the definition of such a recursive `f`

we need to substitute recursive calls with calls to a function "to be provided later" (this will be the memoized version of `f`

).

In `memo f`

we need to provide `f`

with the promised "function which you should call when you want to make a recursive call".

This leads to the following solution:

```
let memo_rec f =
let m = ref [] in
let rec g x =
try
List.assoc x !m
with
Not_found ->
let y = f g x in
m := (x, y) :: !m ;
y
in
g
```

To demonstrate how this works, let us memoize the naive Fibonacci function. We need to write it so that it accepts an extra argument, which I will call `self`

. This argument is what the function should use instead of recursively calling itself:

```
let rec fib self = function
0 -> 1
| 1 -> 1
| n -> self (n - 1) + self (n - 2)
```

Now to get the memoized `fib`

, we compute

```
let fib_memoized = memo_rec fib
```

You are welcome to try it out to see that `fib_memoized 50`

returns instantly. (This is not so for `memo f`

where `f`

is the usual naive recursive definition.)