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8

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 = ...


3

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 ...


2

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.


2

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.


1

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, ...


1

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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