#include "gf.h" #include "parameters.h" #include /** * @file gf.c * Galois field implementation with multiplication using lookup tables */ /** * @brief Multiplies nonzero element a by element b * @returns the product a*b * @param[in] a First element of GF(2^PARAM_M) to multiply (cannot be zero) * @param[in] b Second element of GF(2^PARAM_M) to multiply (cannot be zero) */ uint16_t PQCLEAN_HQC128_CLEAN_gf_mul(uint16_t a, uint16_t b) { uint16_t mask; mask = (uint16_t) (-((int32_t) a) >> 31); // a != 0 mask &= (uint16_t) (-((int32_t) b) >> 31); // b != 0 return mask & gf_exp[PQCLEAN_HQC128_CLEAN_gf_mod(gf_log[a] + gf_log[b])]; } /** * @brief Squares an element of GF(2^PARAM_M) * @returns a^2 * @param[in] a Element of GF(2^PARAM_M) */ uint16_t PQCLEAN_HQC128_CLEAN_gf_square(uint16_t a) { int16_t mask = (uint16_t) (-((int32_t) a) >> 31); // a != 0 return mask & gf_exp[PQCLEAN_HQC128_CLEAN_gf_mod(2 * gf_log[a])]; } /** * @brief Computes the inverse of an element of GF(2^PARAM_M) * @returns the inverse of a * @param[in] a Element of GF(2^PARAM_M) */ uint16_t PQCLEAN_HQC128_CLEAN_gf_inverse(uint16_t a) { int16_t mask = (uint16_t) (-((int32_t) a) >> 31); // a != 0 return mask & gf_exp[PARAM_GF_MUL_ORDER - gf_log[a]]; } /** * @brief Returns i modulo 2^PARAM_M-1 * i must be less than 2*(2^PARAM_M-1). * Therefore, the return value is either i or i-2^PARAM_M+1. * @returns i mod (2^PARAM_M-1) * @param[in] i The integer whose modulo is taken */ uint16_t PQCLEAN_HQC128_CLEAN_gf_mod(uint16_t i) { uint16_t tmp = (uint16_t) (i - PARAM_GF_MUL_ORDER); // mask = 0xffff if(i < PARAM_GF_MUL_ORDER) uint16_t mask = -(tmp >> 15); return tmp + (mask & PARAM_GF_MUL_ORDER); }