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Is there a way to build e.g. (853467 * 21660421200929) % 100000000000007 without BigInteger libraries (note that each number fits into a 64 bit integer but the multiplication result does not)?

This solution seems inefficient:

int64_t mulmod(int64_t a, int64_t b, int64_t m) {
    if (b < a)
        std::swap(a, b);
    int64_t res = 0;
    for (int64_t i = 0; i < a; i++) {
        res += b;
        res %= m;
    }
    return res;
}
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For one thing, I'd recommend getting rid of the Microsoft extensions and using int64_t. –  chris Aug 28 '12 at 22:29
    
It looks like in this case you could cheat because you don't care about anything greater than parameter __int64 m (or uint64_t for those that favor it) hence you could deal only with 64-bit types. –  MartyE Aug 28 '12 at 22:29
1  
Have you read about the Montgomery reduction algorithm? –  ildjarn Aug 28 '12 at 22:31
    
@ildjarn: No, didn't know about it, thanks for the link! –  Christian Ammer Aug 28 '12 at 22:34
1  
Funny, this would be trivial in x64 assembly. –  harold Aug 28 '12 at 23:01

7 Answers 7

up vote 9 down vote accepted

You should use Russian Peasant multiplication. It uses repeated doubling to compute all the values (b*2^i)%m, and adds them in if the ith bit of a is set.

uint64_t mulmod(uint64_t a, uint64_t b, uint64_t m) {
    int64_t res = 0;
    while (a != 0) {
        if (a & 1) res = (res + b) % m;
        a >>= 1;
        b = (b << 1) % m;
    }
    return res;
}

It improves upon your algorithm because it takes O(log(a)) time, not O(a) time.

Caveats: unsigned, and works only if m is 63 bits or less.

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Keith Randall's answer is good, but as he said, a caveat is that it works only if m is 63 bits or less.

Here is a modification which has two advantages:

  1. It works even if m is 64 bits.
  2. It doesn't need to use the modulo operation, which can be expensive on some processors.

(Note that the res -= m and temp_b -= m lines rely on 64-bit unsigned integer overflow in order to give the expected results. This should be fine since unsigned integer overflow is well-defined in C and C++. For this reason it's important to use unsigned integer types.)

uint64_t mulmod(uint64_t a, uint64_t b, uint64_t m) {
    uint64_t res = 0;
    uint64_t temp_b;

    /* Only needed if b may be >= m */
    if (b >= m) {
        if (m > UINT64_MAX / 2u)
            b -= m;
        else
            b %= m;
    }

    while (a != 0) {
        if (a & 1) {
            /* Add b to res, modulo m, without overflow */
            if (b >= m - res) /* Equiv to if (res + b >= m), without overflow */
                res -= m;
            res += b;
        }
        a >>= 1;

        /* Double b, modulo m */
        temp_b = b;
        if (b >= m - b)       /* Equiv to if (2 * b >= m), without overflow */
            temp_b -= m;
        b += temp_b;
    }
    return res;
}
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Both methods work for me. The first one is the same as yours, but I changed your numbers to excplicit ULL. Second one uses assembler notation, which should work faster. There are also algorithms used in cryptography (RSA and RSA based cryptography mostly I guess), like already mentioned Montgomery reduction as well, but I think it will take time to implement them.

#include <algorithm>
#include <iostream>

__uint64_t mulmod1(__uint64_t a, __uint64_t b, __uint64_t m) {
  if (b < a)
    std::swap(a, b);
  __uint64_t res = 0;
  for (__uint64_t i = 0; i < a; i++) {
    res += b;
    res %= m;
  }
  return res;
}

__uint64_t mulmod2(__uint64_t a, __uint64_t b, __uint64_t m) {
  __uint64_t r;
  __asm__
  ( "mulq %2\n\t"
      "divq %3"
      : "=&d" (r), "+%a" (a)
      : "rm" (b), "rm" (m)
      : "cc"
  );
  return r;
}

int main() {
  using namespace std;
  __uint64_t a = 853467ULL;
  __uint64_t b = 21660421200929ULL;
  __uint64_t c = 100000000000007ULL;

  cout << mulmod1(a, b, c) << endl;
  cout << mulmod2(a, b, c) << endl;
  return 0;
}
share|improve this answer
    
I don't know about inline assembler, does it also use a loop? –  Christian Ammer Aug 28 '12 at 22:55
    
@ChristianAmmer no and it doesn't need one. It uses a double-width multiplication and division is always double-width. It's only in high level languages that the high part of the multiplication suddenly gets lost. –  harold Aug 28 '12 at 23:04
    
This is OK for the example, but if (a * b > (2^64 - 1) * c) it will fail. But I assume the OP means that the implied quotient is a 64-bit value as well. –  Brett Hale Aug 28 '12 at 23:21
    
About loop: I don't know how assembler calculates the multiplication,I mean under the hoos, but on C++ there is no need for a loop, because due to %uint64 we know, that the result is 64bits at most. @Brett 3 numers are 64bit. –  Benjamin Aug 28 '12 at 23:28
    
@Benjamin - I'm just pointing out that the assembly implementation isn't general. Try: a=8534670000000000000, b=216604212009290. Both are 64-bit, but divq will result in an exception. –  Brett Hale Aug 28 '12 at 23:38

You could try something that breaks the multiplication up into additions:

// compute (a * b) % m:

unsigned int multmod(unsigned int a, unsigned int b, unsigned int m)
{
    unsigned int result = 0;

    a %= m;
    b %= m;

    while (b)
    {
        if (b % 2 != 0)
        {
            result = (result + a) % m;
        }

        a = (a * 2) % m;
        b /= 2;
    }

    return result;
}
share|improve this answer
    
+1 for a working solution, I have to think about it to fully understand, but it works because (a * b) == (a * 2) * (b / 2), right? –  Christian Ammer Aug 28 '12 at 22:49
    
It will actually fail for some inputs. a * 2 can overflow and be reduced incorrectly if m is bigger than 1 << 63 (or 1 << 31 if ints are 32 bit). –  harold Aug 28 '12 at 23:12
    
You can in fact reduce by (~0ULL/m) in each step. Eg. for 100000000000007, you can use 131072 (1<<17) instead of 2. That also explains harold's comment; for such large m the stepsize becomes 1 and you make no progress. –  MSalters Aug 28 '12 at 23:27
    
@harold: You're right: The first factor must not have its top bit set. I believe that's the only limitation on the function argument values of the present algorithm, though. –  Kerrek SB Aug 29 '12 at 7:30

An improvement to the repeating doubling algorithm is to check how many bits at once can be calculated without an overflow. An early exit check can be done for both arguments -- speeding up the (unlikely?) event of N not being prime.

e.g. 100000000000007 == 0x00005af3107a4007, which allows 16 (or 17) bits to be calculated per each iteration. The actual number of iterations will be 3 with the example.

// just a conceptual routine
int get_leading_zeroes(uint64_t n)
{
   int a=0;
   while ((n & 0x8000000000000000) == 0) { a++; n<<=1; }
   return a;
}

uint64_t mulmod(uint64_t a, uint64_t b, uint64_t n)
{
     uint64_t result = 0;
     int N = get_leading_zeroes(n);
     uint64_t mask = (1<<N) - 1;
     a %= n;
     b %= n;  // Make sure all values are originally in the proper range?
     // n is not necessarily a prime -- so both a & b can end up being zero
     while (a>0 && b>0)
     {
         result = (result + (b & mask) * a) % n;  // no overflow
         b>>=N;
         a = (a << N) % n;
     }
     return result;
}
share|improve this answer
    
+1, Nice speed improvement, but would recommend a check for n==0 to prevent an infinite loop in get_leading_zeroes(). –  chux Nov 13 at 0:58

I can suggest an improvement for your algorithm.

You actually calculate a * b iteratively by adding each time b, doing modulo after each iteration. It's better to add each time b * x, whereas x is determined so that b * x won't overflow.

int64_t mulmod(int64_t a, int64_t b, int64_t m)
{
    a %= m;
    b %= m;

    int64_t x = 1;
    int64_t bx = b;

    while (x < a)
    {
        int64_t bb = bx * 2;
        if (bb <= bx)
            break; // overflow

        x *= 2;
        bx = bb;
    }

    int64_t ans = 0;

    for (; x < a; a -= x)
        ans = (ans + bx) % m;

    return (ans + a*b) % m;
}
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+1, thanks for this idea –  Christian Ammer Aug 28 '12 at 23:08
1  
Can't you use x=(1<<63-m)/b ? That's rounded down, so b*x <= 1<<63 - m, and it doesn't take a loop to calculate that. Doesn't change big-O, as the number of for-loop iterations decreases by <50%. –  MSalters Aug 28 '12 at 23:39
    
@MSalters: sounds good. –  valdo Sep 1 '12 at 13:25
    
@MSalters: doesn't that introduce a division, which is potentially expensive? –  Craig McQueen Nov 6 '13 at 0:17
    
@CraigMcQueen: Yes, but only one, and there's already a modulo in a loop. –  MSalters Nov 6 '13 at 1:04

If you are using a constant modulus in successive operations, you would benefit from reciprocal division methods. See: Division by Invariant Integers using Multiplication, or the more recent: Improved division by invariant integers. Both are used extensively in the GMP library (not surprisingly). The former method is, or was, used in GCC to transform division and modulo operations by a constant into multiplications and bit shifts. The latency gap between multiply and divide operations is huge, and will only continue to grow.

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