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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?

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1  
I cannot make sense of your second algorithm. –  GregS Nov 25 '10 at 13:16
    
@GregS - please tell me if you think there's a problem - the theory is that it removes values from the left (msb) with multiply/mask versus the right (lsb) with mod/divide. –  Lucky Fruit Nov 25 '10 at 18:13

2 Answers 2

Seeing that you are talking about numbers like 2^128/(N!), it seems that in your problem N is going to be rather small (N < 35 according to my calculations). I suggest taking the original algorithm as a starting point; first switch the direction of the loop:

i = 2;
while (i < N) {
    swap A[N - 1 - i] and A[N - i + k % i]
       k = k / i
       i = i + 1
}

Now change the loop to do several permutations per iteration. I guess the speed of division is the same regardless of the number i, as long as i < 2^32.
Split the range 2...N-1 into sub-ranges so that the product of the numbers in each sub-range is less than 2^32:

2, 3, 4, ..., 12: product is 479001600
13, 14, ..., 19:  product is 253955520
20, 21, ..., 26:  product is 3315312000
27, 28, ..., 32:  product is 652458240
33, 34, 35:       product is 39270

Then, divide the long number k by the products instead of dividing by i. Each iteration will yield a remainder (less than 2^32) and a smaller number k. When you have the remainder, you can work with it in an inner loop using the original algorithm; which will now be faster because it doesn't involve long division.
Here is some code:

static const int rangeCount = 5;
static const int rangeLimit[rangeCount] = {13, 20, 27, 33, 36};
static uint32_t rangeProduct[rangeCount] = {
    479001600,
    253955520,
    3315312000,
    652458240,
    39270
};

for (int rangeIndex = 0; rangeIndex < rangeCount; ++rangeIndex)
{
    // The following two lines involve long division;
    // math libraries probably calculate both quotient and remainder
    // in one function call
    uint32_t rangeRemainder = k % rangeProduct[rangeIndex];
    k /= rangeProduct[rangeIndex];

    // A range starts where the previous range ended
    int rangeStart = (rangeIndex == 0) ? 2 : rangeLimit[rangeIndex - 1];

    // Iterate over range
    for (int i = rangeStart; i < rangeLimit[rangeIndex] && i < n; ++i)
    {
        // The following two lines involve a 32-bit division;
        // it produces both quotient and remainder in one Pentium instruction
        int remainder = rangeRemainder % i;
        rangeRemainder /= i;
        std::swap(permutation[n - 1 - i], permutation[n - i + remainder]);
    }
}

Of course, this code can be extended into more than 128 bits.
Another optimization could involve extraction of powers of 2 from the products of ranges; this might add a slight speedup by making the ranges longer. Not sure whether this is worthwhile (maybe for large values of N, like N=1000).

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Dont know about algorithms, but the ones you use seems pretty simple, so i dont really see how you can optimize the algorithm.

You may use alternative approaches:

  • use ASM (assembler) - from my experience, after a long time trying to figure out how should a certain algorithm would be written in ASM, it ended up being slower than the version generated by the compiler:) Probably because the compiler also knows how to layout the code so the CPU cache would be more efficient, and/or what instructions are actually faster and what situations(this was on GCC/linux).
  • use multi-processing:
    • make your algorithm multithreaded, and make sure you run with the same number of threads as the number of available cpu cores(most cpu's nowdays do have multiple cores/multithreading)
    • make you algorithm capable of running on multiple machines on a network, and devise a way of sending these numbers to machines in a network, so you may use their CPU power.
share|improve this answer
    
-1 because neither of those suggestions are good advice - the first is rarely good advice for any performance problem, and whilst the second is, it doesn't seem like good advice for this problem. I'll happily rescind my vote if you can suggest how it would be parallelised, of course. –  Tom Anderson Dec 8 '10 at 13:21
    
1: custom ASM is good actually, but only if you know what you're doing and if portability is not an actual issue(if it will always run on a specific hardware) 2: i assumed that this algorithm is called lots of times, in a for like loop, otherwise the speed would not really matter. In this scenation the loop may be split in smaller sections and run in parallel. –  Quamis Dec 8 '10 at 13:25

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