#include "gf.h" #include "parameters.h" #include #include #include /** * @file gf.c * Galois field implementation with multiplication using the pclmulqdq instruction */ static uint16_t gf_reduce(uint64_t x, size_t deg_x); static uint16_t gf_quad(uint64_t a); /** * Returns the integer i such that elt = a^i * where a is the primitive element of GF(2^GF_M). *@returns the logarithm of the given element */ uint16_t PQCLEAN_HQC128_AVX2_gf_log(uint16_t elt) { return log[elt]; } /** * Reduces polynomial x modulo primitive polynomial GF_POLY. * @returns x mod GF_POLY * @param[in] x Polynomial of degree less than 64 * @param[in] deg_x The degree of polynomial x */ static uint16_t gf_reduce(uint64_t x, size_t deg_x) { uint16_t z1, z2, rmdr, dist; uint64_t mod; size_t steps, i, j; // Deduce the number of steps of reduction steps = CEIL_DIVIDE(deg_x - (PARAM_M - 1), PARAM_GF_POLY_M2); // Reduce for (i = 0; i < steps; ++i) { mod = x >> PARAM_M; x &= (1 << PARAM_M) - 1; x ^= mod; z1 = 0; rmdr = PARAM_GF_POLY ^ 1; for (j = PARAM_GF_POLY_WT - 2; j; --j) { z2 = __tzcnt_u16(rmdr); dist = (uint16_t) (z2 - z1); mod <<= dist; x ^= mod; rmdr ^= 1 << z2; z1 = z2; } } return x; } /** * Multiplies two elements of GF(2^GF_M). * @returns the product a*b * @param[in] a Element of GF(2^GF_M) * @param[in] b Element of GF(2^GF_M) */ uint16_t PQCLEAN_HQC128_AVX2_gf_mul(uint16_t a, uint16_t b) { __m128i va = _mm_cvtsi32_si128(a); __m128i vb = _mm_cvtsi32_si128(b); __m128i vab = _mm_clmulepi64_si128(va, vb, 0); uint32_t ab = _mm_cvtsi128_si32(vab); return gf_reduce(ab, 2 * (PARAM_M - 1)); } /** * Squares an element of GF(2^GF_M). * @returns a^2 * @param[in] a Element of GF(2^GF_M) */ uint16_t PQCLEAN_HQC128_AVX2_gf_square(uint16_t a) { uint32_t b = a; uint32_t s = b & 1; for (size_t i = 1; i < PARAM_M; ++i) { b <<= 1; s ^= b & (1 << 2 * i); } return gf_reduce(s, 2 * (PARAM_M - 1)); } /** * Computes the 4th power of an element of GF(2^GF_M). * @returns a^4 * @param[in] a Element of GF(2^GF_M) */ static uint16_t gf_quad(uint64_t a) { uint64_t q = a & 1; for (size_t i = 1; i < PARAM_M; ++i) { a <<= 3; q ^= a & (1ull << 4 * i); } return gf_reduce(q, 4 * (PARAM_M - 1)); } /** * Computes the inverse of an element of GF(2^10), * using a shorter chain of squares and multiplications than fast exponentiation. * @returns the inverse of a * @param[in] a Element of GF(2^10) */ uint16_t PQCLEAN_HQC128_AVX2_gf_inverse(uint16_t a) { uint16_t p; uint16_t a2; a2 = PQCLEAN_HQC128_AVX2_gf_square(a); // a^2 a = PQCLEAN_HQC128_AVX2_gf_mul(a2, a); // a^2.a p = gf_quad(a); // a^8.a^4 a = PQCLEAN_HQC128_AVX2_gf_mul(p, a); // a^8.a^4.a^2.a p = gf_quad(a); // a^32.a^16.a^8.a^4 p = gf_quad(p); // a^128.a^64.a^32.a^16 a = PQCLEAN_HQC128_AVX2_gf_mul(p, a); // a^128.a^64.a^32.a^16.a^8.a^4.a^2.a p = gf_quad(a); // a^512.a^256.a^128.a^64.a^32.a^16.a^8.a^4 p = PQCLEAN_HQC128_AVX2_gf_mul(p, a2); // a^-1 return p; } /** * Returns i modulo 2^GF_M-1. * i must be less than 2*(2^GF_M-1). * Therefore, the return value is either i or i-2^GF_M+1. * @returns i mod (2^GF_M-1) * @param[in] i The integer whose modulo is taken */ uint16_t PQCLEAN_HQC128_AVX2_gf_mod(uint16_t i) { uint16_t tmp = (uint16_t) (i - PARAM_GF_MUL_ORDER); // mask = 0xffff if (i < GF_MUL_ORDER) uint16_t mask = -(tmp >> 15); return tmp + (mask & PARAM_GF_MUL_ORDER); }