The algorithm you are looking for is known as an integer partition. I have a couple of implementations at my blog.

**EDIT:** Oscar properly chastized me for my incomplete answer. As penance, I offer this answer, which will hopefully clarify a few things.

I like Oscar's use of streams -- as the author of SRFI-41 I should. But expanding the powerset only to discard most of the results seems a backward way of solving the problem. And I like the simplicity of GoZoner's answer, but not its inefficiency.

Let's start with GoZoner's answer, which I reproduce below with a few small changes:

```
(define (fs n s)
(if (or (<= n 0) (<= s 0)) (list)
(append (if (= n s) (list (list n))
(map (lambda (xs) (cons n xs))
(fs (- n 1) (- s n))))
(fs (- n 1) s))))
```

This produces a list of the output sets:

```
> (fs 10 10)
((10) (9 1) (8 2) (7 3) (7 2 1) (6 4) (6 3 1) (5 4 1) (5 3 2) (4 3 2 1))
```

A simple variant of that function produces the count instead of a list of sets, which shall be the focus of the rest of this answer:

```
(define (f n s)
(if (or (<= s 0) (<= n 0)) 0
(+ (if (= n s) 1
(f (- n 1) (- s n)))
(f (- n 1) s))))
```

And here is a sample run of the function, including timings on my ancient and slow home computer:

```
> (f 10 10)
10
> (time (f 100 100)
(time (f 100 ...))
no collections
1254 ms elapsed cpu time
1435 ms elapsed real time
0 bytes allocated
444793
```

That's quite slow; although it is fine for small inputs, it would be intolerable to evaluate `(f 1000 1000)`

, as the algorithm is exponential. The problem is the same as with the naive fibonacci algorithm; the same sub-problems are re-computed again and again.

A common solution to that problem is memoization. Fortunately, we are programming in Scheme, which makes it easy to encapsulate memoization in a macro:

```
(define-syntax define-memoized
(syntax-rules ()
((_ (f args ...) body ...)
(define f
(let ((results (make-hash hash equal? #f 997)))
(lambda (args ...)
(let ((result (results 'lookup (list args ...))))
(or result
(let ((result (begin body ...)))
(results 'insert (list args ...) result)
result)))))))))
```

We use hash tables from my Standard Prelude and the universal hash function from my blog. Then it is a simple matter to write the memoized version of the function:

```
(define-memoized (f n s)
(if (or (<= s 0) (<= n 0)) 0
(+ (if (= n s) 1
(f (- n 1) (- s n)))
(f (- n 1) s))))
```

Isn't that pretty? The only change is the addition of `-memoized`

in the definition of the function; all of the parameters and the body of the function are the same. But the performance improves greatly:

```
> (time (f 100 100))
(time (f 100 ...))
no collections
62 ms elapsed cpu time
104 ms elapsed real time
1028376 bytes allocated
444793
```

That's an order-of-magnitude improvement with virtually no effort.

But that's not all. Since we know that the problem has "optimal substructure" we can use dynamic programming. Memoization works top-down, and must suspend the current level of recursion, compute (either directly or by lookup) the lower-level solution, then resume computation in the current level of recursion. Dynamic programming, on the other hand, works bottom-up, so sub-solutions are always available when they are needed. Here's the dynamic programming version of our function:

```
(define (f n s)
(let ((fs (make-matrix (+ n 1) (+ s 1) 0)))
(do ((i 1 (+ i 1))) ((< n i))
(do ((j 1 (+ j 1))) ((< s j))
(matrix-set! fs i j
(+ (if (= i j)
1
(matrix-ref fs (- i 1) (max (- j i) 0)))
(matrix-ref fs (- i 1) j)))))
(matrix-ref fs n s)))
```

We used the matrix functions of my Standard Prelude. That's more work than just adding `-memoized`

to an existing function, but the payoff is another order-of-magnitude reduction in run time:

```
> (time (f 100 100))
(time (f 100 ...))
no collections
4 ms elapsed cpu time
4 ms elapsed real time
41624 bytes allocated
444793
> (time (f 1000 1000))
(time (f 1000 ...))
3 collections
649 ms elapsed cpu time, including 103 ms collecting
698 ms elapsed real time, including 132 ms collecting
15982928 bytes allocated, including 10846336 bytes reclaimed
8635565795744155161506
```

We’ve gone from 1254ms to 4ms, which is a rather astonishing range of improvement; the final program is O(*ns*) in both time and space. You can run the program at http://programmingpraxis.codepad.org/Y70sHPc0, which includes all the library code from my blog.

As a special bonus, here is another version of the `define-memoized`

macro. It uses a-lists rather than hash tables, so it's very much slower than the version given above, but when the underlying computation is time-consuming, and you just want a simple way to improve it, this may be just what you need:

```
(define-syntax define-memoized
(syntax-rules ()
((define-memoized (f arg ...) body ...)
(define f
(let ((cache (list)))
(lambda (arg ...)
(cond ((assoc `(,arg ...) cache) => cdr)
(else (let ((val (begin body ...)))
(set! cache (cons (cons `(,arg ...) val) cache))
val)))))))))
```

This is a good use of quasi-quotation and the `=>`

operator in a `cond`

clause for those who are just learning Scheme. I can't remember when I wrote that function -- I've had it laying around for years -- but it has saved me many times when I just needed a quick-and-dirty memoization and didn't care to worry about hash tables and universal hash functions.

This answer will appear tomorrow at my blog. Please drop in and have a look around.

`find`

procedure posted doesn't work. Test it with`(find 10 10)`

, the output is different from the one in the question, and some of the answers don't even add to`10`

. See my answer for a correct implementation – Óscar López May 18 '13 at 0:07