Let's see if we can do something half-elegant, without depending on *1 <= n <= 10*.

- Instead of looping we'll of course use recursion.
- Instead of an if for terminating the recursion, we'll use an
**array of function pointers**!

(We still need comparison operators, such as `<`

and `==`

.)

**EDIT:** damaru used the function pointers trick first.

This gives: [*All code is untested, no C compiler under hand!*]

```
typedef int (*unary_fptr)(int);
int ret_1(int n) {
return 1;
}
int fact(int n) {
unary_fptr ret_1_or_fact[] = {ret_1, fact};
return multiply(ret_1_or_fact[n > 1](sub_1(n)), n);
}
```

We still need to implement `sub_1`

and `multiply`

. Let's start with `sub_1`

, which is a simple recursion on the bits until the carry stops (if you don't understand this, the similar `add_1`

at the end is simpler to think about):

```
int identity(int n) {
return n;
}
int sub_1(int n) {
unary_fptr sub_1_or_identity[] = {sub_1, identity};
int lsb = n & 1;
int rest = sub_1_or_identity[lsb](n >> 1);
return (rest << 1) | (lsb ^ 1);
}
```

`multiply`

: The simplest I can think of is Russian Peasant multiplication, which reduces it to binary shifts and addition. With conditionals, a recursive formulation would look like this:

```
/* If we could use conditionals */
int multiply(int a, int b) {
int subproduct;
if(a <= 1) {
subproduct = 0;
} else {
subproduct = multiply(a >> 1, b << 1);
}
if(a & 1) {
return add(b, subproduct);
} else {
return subproduct;
}
}
```

Without conditionals, we have to use the dispatch array trick twice:

```
typedef int (*binary_fptr)(int, int);
int ret_0(int a, int b) {
return 0;
}
int multiply(int a, int b) {
binary_fptr ret_0_or_multiply = {ret_0, multiply};
int subproduct = ret_0_or_multiply[a >= 2](a >> 1, b << 1);
binary_fptr ret_0_or_add = {ret_0, add};
return ret_0_or_add[a & 1](subproduct, b);
}
```

Now all we miss is `add`

. You should by now guess how it will go - a simultaneous recursion over bits of the two numbers, which reduces the problem to shifts and `add_1`

:

```
int add(int a, int b) {
int lsb = (a & 1) ^ (b & 1);
int carry = (a & 1) & (b & 1);
binary_fptr ret_0_or_add = {ret_0, add};
int subsum = ret_0_or_add[(a >= 2) & (b >= 2)](a >> 1, b>> 1);
unary_fptr identity_or_add_1 = {identity, add_1};
return identity_or_add_1[carry](subsum << 1);
}
```

and `add_1`

is a simple recursion over bits until the carry stops:

```
int add_1(int n) {
unary_fptr identity_or_add_1[] = {identity, add_1};
int lsb = n & 1;
int rest = identity_or_add_1[lsb](n >> 1);
return (rest << 1) | (lsb ^ 1);
}
```

That's it I think! [*As noted above all code is untested!*]