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The reason is that Matlab uses double floating-point arithmetic by default. A number as large as 688^79 can't be represented accurately as a double. (The largest integer than can be accurately represented as a double is on the order of 2^53). To obtain the right result you can use symbolic variables, which ensures you don't lose accuracy: >> x = ...


We know that p is less than max, then n % p is less than max. They are both unsigned, that means that n % p is positive, and smaller than p. Unsigned overflow is well-defined, so if n % p * 2 exceeds p, we can compute it as n % p - p + n % p, which will not overflow, so together it will look like this: unsigned m = n % p; unsigned r; if (p - m < m) // m ...


if (count % 4 == 0) { // Stuff } The key being that acting every n loops is accomplished by using mod n == 0, for any n. Also, you only need one counter for any number such actions.


My calculator is sending me the same answer than Wolfram, it also calculated the value for 688^79 so I would tend to believe Wolfram is right. You probably have overrun the capacities of Matlab with such a huge number and it is why it did not send the right answer.


Even though I dislike dealing with AT&T syntax and GCC's "extended asm constraints", I think this works (it worked in my, admittedly limited, tests) uint32_t f(uint32_t n, uint32_t p) { uint32_t res; asm ( "xorl %%edx, %%edx\n\t" "addl %%eax, %%eax\n\t" "adcl %%edx, %%edx\n\t" "subl $1, %%eax\n\t" "sbbl $0, ...


FWIW, this version seems to be avoid any overflows: std::uint32_t f(std::uint32_t n, std::uint32_t p) { auto m = n%p; if (m <= p/2) { return (m==0)*p+2*m-1; } return p-2*(p-m)-1; } Demo. The idea is that if an overflow would occur in 2*m-1, we can work with p-2*(p-m)-1, which avoids this by multiplying 2 with the modular ...

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