An implementation of (this)[http://stackoverflow.com/a/14859713/256138] stack overflow answer prior:

```
#include <stdint.h>
#include <tuple>
#include <iostream>
typedef std::tuple< uint32_t, uint32_t > split_t;
split_t split( uint64_t a )
{
static const uint32_t mask = -1;
auto retval = std::make_tuple( mask&a, ( a >> 32 ) );
// std::cout << "(" << std::get<0>(retval) << "," << std::get<1>(retval) << ")\n";
return retval;
}
typedef std::tuple< uint64_t, uint64_t, uint64_t, uint64_t > cross_t;
template<typename Lambda>
cross_t cross( split_t lhs, split_t rhs, Lambda&& op )
{
return std::make_tuple(
op(std::get<0>(lhs), std::get<0>(rhs)),
op(std::get<1>(lhs), std::get<0>(rhs)),
op(std::get<0>(lhs), std::get<1>(rhs)),
op(std::get<1>(lhs), std::get<1>(rhs))
);
}
// c must have high bit unset:
uint64_t a_times_2_k_mod_c( uint64_t a, unsigned k, uint64_t c )
{
a %= c;
for (unsigned i = 0; i < k; ++i)
{
a <<= 1;
a %= c;
}
return a;
}
// c must have about 2 high bits unset:
uint64_t a_times_b_mod_c( uint64_t a, uint64_t b, uint64_t c )
{
// ensure a and b are < c:
a %= c;
b %= c;
auto Z = cross( split(a), split(b), [](uint32_t lhs, uint32_t rhs)->uint64_t {
return (uint64_t)lhs * (uint64_t)rhs;
} );
uint64_t to_the_0;
uint64_t to_the_32_a;
uint64_t to_the_32_b;
uint64_t to_the_64;
std::tie( to_the_0, to_the_32_a, to_the_32_b, to_the_64 ) = Z;
// std::cout << to_the_0 << "+ 2^32 *(" << to_the_32_a << "+" << to_the_32_b << ") + 2^64 * " << to_the_64 << "\n";
// this line is the one that requires 2 high bits in c to be clear
// if you just add 2 of them then do a %c, then add the third and do
// a %c, you can relax the requirement to "one high bit must be unset":
return
(to_the_0
+ a_times_2_k_mod_c(to_the_32_a+to_the_32_b, 32, c) // + will not overflow!
+ a_times_2_k_mod_c(to_the_64, 64, c) )
%c;
}
int main()
{
uint64_t retval = a_times_b_mod_c( 19010000000000000000, 1011000000000000, 1231231231231211 );
std::cout << retval << "\n";
}
```

The idea here is to split your 64 bit integer into a pair of 32 bit integers, which are safe to multiply in 64 bit land.

We express `a*b`

as `(a_high * 2^32 + a_low) * (b_high * 2^32 + b_low)`

, do the 4-fold multiplication (keeping track of the `2^32`

factors without storing them in our bits), then note that doing `a * 2^k % c`

can be done via a series of `k`

repeats of this pattern: `((a*2 %c) *2%c)...`

. So we can take this 3 to 4 element polynomial of 64 bit integers in `2^32`

and reduce it without having to worry about things.

The expensive part is the `a_times_2_k_mod_c`

function (the only loop).

You can make it go many times faster if you know that `c`

has more than one high bit clear.

You could instead replace the `a %= c`

with subtraction `a -= (a>=c)*c;`

Doing both isn't all that practical.

Live example