I am using a base-conversion algorithm to generate a permutation from a large integer (split into 32-bit words).

I use a relatively standard algorithm for this:

```
/* N = count,K is permutation index (0..N!-1) A[N] contains 0..N-1 */
i = 0;
while (N > 1) {
swap A[i] and A[i+(k%N)]
k = k / N
N = N - 1
i = i + 1
}
```

Unfortunately, the divide and modulo each iteration adds up, especially moving to large integers - But, it seems I could just use multiply!

```
/* As before, N is count, K is index, A[N] contains 0..N-1 */
/* Split is arbitrarily 128 (bits), for my current choice of N */
/* "Adjust" is precalculated: (1 << Split)/(N!) */
a = k*Adjust; /* a can be treated as a fixed point fraction */
i = 0;
while (N > 1) {
a = a*N;
index = a >> Split;
a = a & ((1 << Split) - 1); /* actually, just zeroing a register */
swap A[i] and A[i+index]
N = N - 1
i = i + 1
}
```

This is nicer, but doing large integer multiplies is still sluggish.

Question 1:

Is there a way of doing this faster?

Eg. Since I know that N*(N-1) is less than 2^32, could I pull out those numbers from one word, and merge in the 'leftovers'?

Or, is there a way to modify an arithetic decoder to pull out the indicies one at a time?

Question 2:

For the sake of curiosity - if I use multiplication to convert a number to base 10 without the adjustment, then the result is multiplied by (10^digits/2^shift). Is there a tricky way to remove this factor working with the decimal digits? Even with the adjustment factor, this seems like it would be faster -- why wouldn't standard libraries use this vs divide and mod?