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;
}
```

`int64_t`

. – chris Aug 28 '12 at 22:29`__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