#include #include #include #include #include #include #include #include #include #include "helper.c" uint64_t *dec_to_bin(uint64_t d, uint64_t *length) { uint64_t *binary_form = calloc(100, sizeof(uint64_t)); int index = 0; while (d != 0) { binary_form[index] = d % 2; d /= 2; index++; } *length = index; return binary_form; } uint64_t quick_pow(uint64_t *d_binary, uint64_t a, uint64_t n, uint64_t length) { uint64_t *powed = calloc(100, sizeof(uint64_t)); powed[0] = a; for (int i = 1; i <= length; i++) { powed[i] = (uint64_t)(((unsigned __int128)powed[i - 1] * powed[i - 1]) % n); // printf("powed: %ju, index: %d; ", powed[i], (i)); } // check where in the binary are ones uint64_t multiplied = 1; for (int i = 0; i < length; i++) { if (d_binary[i] == 1) { multiplied = (uint64_t)(((unsigned __int128)multiplied * powed[i]) % n); } } // printf("\nbm quick math: %ju; %ju ", multiplied, n); free(powed); return multiplied; } bool prime_test(uint64_t n, int a) { // printf("\n\nprime test: %ju\n", n); // Miller Rabin prime test // choose a base: a, which should be a prime so that (n, a) = 1 // then do 2 rounds of tests provided the first one did not fail // 1: a^d =k 1 mod n // 2: a^(d * 2^r) =k n-1 mod n // d = n-1 / 2^S (where S means how many time did we divide the number till we reached the first odd number) // S: see above // r = {0,... S-1} uint64_t d = n - 1; uint64_t S = 0; while (d % 2 == 0) { d = d / 2; S++; } uint64_t r = S - 1; // this stores the number of elements from 0 to S-1 // round 1 // 1: a^d =k 1 mod n uint64_t length = 0; uint64_t *d_binary = dec_to_bin(d, &length); uint64_t first_qp_res = quick_pow(d_binary, a, n, length); if (first_qp_res == 1) { free(d_binary); return true; } // round 2 // 2: a^(d * 2^r) =k n-1 mod n for (int i = 0; i <= r; i++) { if (first_qp_res == n - 1) { free(d_binary); // printf("true\n"); return true; } else if (first_qp_res < n - 2) { // printf("first_qp_res became smaller then n!!\n"); break; } else { first_qp_res = (uint64_t)(((unsigned __int128)first_qp_res * first_qp_res) % n); } } free(d_binary); return false; } typedef struct { int base; uint64_t prime; } prime_test_t; void *prime_thread_worker(void *arg) { prime_test_t *result_ptr = (prime_test_t *)arg; do { result_ptr->prime = rand64(); // printf("\nGenerating a new prime number (%p). Candidate: ", result_ptr); // printf("%ju", result_ptr->prime); // printf("\n"); } while (!prime_test(result_ptr->prime, result_ptr->base)); return NULL; } typedef struct { uint64_t lnko; __int128 x; __int128 y; } euklidian_result_t; euklidian_result_t euklidian_algorigthm_extended(unsigned __int128 a, unsigned __int128 b) { __int128 r = a % b, q = a / b, k = 1, xk = 0, yk = 1, next_r; __int128 prev_r = b, prev_q, prev_xk = 0, prev_yk = 1, prev_prev_xk = 1, prev_prev_yk = 0; euklidian_result_t res = {0, 0, 0}; while (r != 0) { k++; prev_q = q; q = prev_r / r; next_r = prev_r % r; prev_r = r; r = next_r; xk = xk * prev_q + prev_prev_xk; prev_prev_xk = prev_xk; prev_xk = xk; yk = yk * prev_q + prev_prev_yk; prev_prev_yk = prev_yk; prev_yk = yk; } __int128 x = k % 2 == 0 ? prev_xk : -prev_xk; __int128 y = k % 2 == 0 ? -prev_yk : prev_yk; res.lnko = prev_r; res.x = x; res.y = y; return res; } unsigned __int128 kinai_maradek_tetel(uint64_t *m, uint64_t d, prime_test_t *p, prime_test_t *q) { // sum(i: 1,2): Ci * Yi * Mi mod M // M: P*Q, Mp: M/P, Mq: M/Q unsigned __int128 M = p->prime * q->prime; uint64_t Mp = q->prime; uint64_t Mq = p->prime; // C1: c^(d mod P-1) mod P uint64_t temp_exponent = d % (p->prime - 1); uint64_t exponent_bin_length = 0; uint64_t *exponent_as_binary = dec_to_bin(temp_exponent, &exponent_bin_length); uint64_t c1 = quick_pow(exponent_as_binary, *m, p->prime, exponent_bin_length); free(exponent_as_binary); // C2: c^(d mod Q-1) mod Q temp_exponent = d % (q->prime - 1); exponent_as_binary = dec_to_bin(temp_exponent, &exponent_bin_length); uint64_t c2 = quick_pow(exponent_as_binary, *m, q->prime, exponent_bin_length); free(exponent_as_binary); euklidian_result_t y = euklidian_algorigthm_extended(Mp, Mq); // in the struct the x will mean the y1 and y will mean the y2 // if either of them is less a negative number shift them into postive range with with hte modulo y.x %= p->prime; y.x += p->prime; y.y %= q->prime; y.y += q->prime; unsigned __int128 s1 = (c1 * y.x * Mp) % M; unsigned __int128 s2 = (c2 * y.y * Mq) % M; return (s1 + s2) % M; } unsigned __int128 rsa_encrypt(uint64_t *m, prime_test_t *p, prime_test_t *q) { unsigned __int128 n = p->prime * q->prime; printf("n: "); print_uint128(n); printf("\n"); unsigned __int128 fi_n = (p->prime - 1) * (q->prime - 1); printf("fi_n: "); print_uint128(fi_n); printf("\n"); // 2. kulcsgeneralas uint64_t e = 0; do { e = rand64(); } while (e <= 1 && e >= fi_n && prime_test(e, p->base)); // the p and q base is used everywhere anyways, i wont pass in another arg euklidian_result_t calc_d = euklidian_algorigthm_extended(fi_n, e); // if either of them is less a negative number shift them into postive range with with hte modulo calc_d.x %= fi_n; calc_d.y %= fi_n; unsigned __int128 d = calc_d.y; uint64_t length = 0; uint64_t *nyenye = dec_to_bin(e, &length); unsigned __int128 c = quick_pow(nyenye, *m, n, length); free(nyenye); printf("\nc: "); print_uint128(c); return c; } int main() { uint64_t m = 0; printf("give input for m: \n"); scanf("%ju", &m); srand(time(NULL)); uint64_t base = 2; pthread_t thread_p, thread_q; prime_test_t p = {base, 0}; prime_test_t q = {base, 0}; pthread_create(&thread_p, NULL, prime_thread_worker, &p); pthread_create(&thread_q, NULL, prime_thread_worker, &q); pthread_join(thread_p, NULL); pthread_join(thread_q, NULL); printf("\n"); rsa_encrypt(&m, &p, &q); printf("\nkinai maradek tetel:\n"); unsigned __int128 S = kinai_maradek_tetel(&m, 2263, &p, &q); printf("S: "); print_uint128(S); printf("\n"); return 0; }