for simple problems like fibonacci, writing CPS is *relatively* straightforward

```
let fibonacciCPS n =
let rec fibonacci_cont a cont =
if a <= 2 then cont 1
else
fibonacci_cont (a - 2) (fun x ->
fibonacci_cont (a - 1) (fun y ->
cont(x + y)))
fibonacci_cont n (fun x -> x)
```

However, in the case of the rod-cutting exemple from here (or the book intro to algo), the number of closure is not always equal to 2, and can't be hard coded.

I imagine one has to change the intermediate variables to sequences.

(I like to think of the continuation as a contract saying "when you have the value, pass it on to me, then i'll pass it on to my boss after treatment" or something along those line, which defers the actual execution)

For the rod cutting, we have

```
//rod cutting
let p = [|1;5;8;9;10;17;17;20;24;30|]
let rec r n = seq { yield p.[n-1]; for i in 1..(n-1) -> (p.[i-1] + r (n-i)) } |> Seq.max
[1 .. 10] |> List.map (fun i -> i, r i)
```

In this case, I will need to attached the newly created continuation

```
let cont' = fun (results: _ array) -> cont(seq { yield p.[n-1]; for i in 1..(n-1) -> (p.[i-1] + ks.[n-i]) } |> Seq.max)
```

to the "cartesian product" continuation made by the returning subproblems. Has anyone seen a CPS version of rod-cutting / has any tips on this ?