Assuming you've already implemented functions to perform math on `uint128`

, you could break the number up into 3 parts and use the built-in 64-bit printing capabilities of printf. Since the largest 64-bit number is 20 digits long, that means all 19-digit decimal numbers can be printed that way, but since the largest 128-bit number is 39 digits long, we can't break it up into only 2 parts, since there's a chance that we might end up with a 20 digit number bigger than the largest 64-bit number.

Here's one way to do it, dividing first by 10^{20} to get a quotient no larger than 3,402,823,669,209,384,634. We then divide the remainder (itself no larger than 10^{20}) by 10^{10} to get another quotient and remainder each less than 10^{20}, which both fit in a 64-bit integer.

```
void print_uint128(uint128 value)
{
// First power of 10 larger than 2^64
static const uint128 tenToThe20 = {7766279631452241920ull, 5ull};
static const uint128 tenToThe10 = {10000000000ull, 0ull};
// Do a 128-bit division; assume we have functions to divide, multiply, and
// subtract 128-bit numbers
uint128 quotient1 = div128(value, tenToThe20);
uint128 remainder1 = sub128(value, mul128(quotient, tenToThe20));
uint128 quotient2 = div128(remainder1, tenToThe10);
uint128 remainder2 = sub128(remainder1, mul128(remainder1, tenToThe10));
// Now print out theresult in 3 parts, being careful not to print
// unnecessary leading 0's
if(quotient1.low != 0)
printf("%llu%010llu%010llu", quotient1.low, quotient2.low, remainder2.low);
else if(quotient2.low != 0)
printf("%llu%010llu", quotient2.low, remainder2.low);
else
printf("%llu", remainder2.low);
}
```