pqc/crypto_sign/rainbowIIIc-classic/clean/blas_comm.c
Matthias J. Kannwischer 1fca5ec068 unsigned -> unsigned int
2019-07-24 10:42:15 +02:00

143 рядки
5.1 KiB
C

/// @file blas_comm.c
/// @brief The standard implementations for blas_comm.h
///
#include "blas_comm.h"
#include "blas.h"
#include "gf.h"
#include "rainbow_config.h"
#include <stdint.h>
#include <string.h>
void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_set_zero(uint8_t *b, unsigned int _num_byte) {
gf256v_add(b, b, _num_byte);
}
/// @brief get an element from GF(256) vector .
///
/// @param[in] a - the input vector a.
/// @param[in] i - the index in the vector a.
/// @return the value of the element.
///
uint8_t PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_get_ele(const uint8_t *a, unsigned int i) {
return a[i];
}
unsigned int PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_is_zero(const uint8_t *a, unsigned int _num_byte) {
uint8_t r = 0;
while (_num_byte--) {
r |= a[0];
a++;
}
return (0 == r);
}
/// polynomial multplication
/// School boook
void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_polymul(uint8_t *c, const uint8_t *a, const uint8_t *b, unsigned int _num) {
PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_set_zero(c, _num * 2 - 1);
for (unsigned int i = 0; i < _num; i++) {
gf256v_madd(c + i, a, b[i], _num);
}
}
static void gf256mat_prod_ref(uint8_t *c, const uint8_t *matA, unsigned int n_A_vec_byte, unsigned int n_A_width, const uint8_t *b) {
PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_set_zero(c, n_A_vec_byte);
for (unsigned int i = 0; i < n_A_width; i++) {
gf256v_madd(c, matA, b[i], n_A_vec_byte);
matA += n_A_vec_byte;
}
}
void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256mat_mul(uint8_t *c, const uint8_t *a, const uint8_t *b, unsigned int len_vec) {
unsigned int n_vec_byte = len_vec;
for (unsigned int k = 0; k < len_vec; k++) {
PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_set_zero(c, n_vec_byte);
const uint8_t *bk = b + n_vec_byte * k;
for (unsigned int i = 0; i < len_vec; i++) {
gf256v_madd(c, a + n_vec_byte * i, bk[i], n_vec_byte);
}
c += n_vec_byte;
}
}
static unsigned int gf256mat_gauss_elim_ref(uint8_t *mat, unsigned int h, unsigned int w) {
unsigned int r8 = 1;
for (unsigned int i = 0; i < h; i++) {
uint8_t *ai = mat + w * i;
unsigned int skip_len_align4 = i & ((unsigned int)~0x3);
for (unsigned int j = i + 1; j < h; j++) {
uint8_t *aj = mat + w * j;
gf256v_predicated_add(ai + skip_len_align4, !PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256_is_nonzero(ai[i]), aj + skip_len_align4, w - skip_len_align4);
}
r8 &= PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256_is_nonzero(ai[i]);
uint8_t pivot = ai[i];
pivot = PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256_inv(pivot);
gf256v_mul_scalar(ai + skip_len_align4, pivot, w - skip_len_align4);
for (unsigned int j = 0; j < h; j++) {
if (i == j) {
continue;
}
uint8_t *aj = mat + w * j;
gf256v_madd(aj + skip_len_align4, ai + skip_len_align4, aj[i], w - skip_len_align4);
}
}
return r8;
}
static unsigned int gf256mat_solve_linear_eq_ref(uint8_t *sol, const uint8_t *inp_mat, const uint8_t *c_terms, unsigned int n) {
uint8_t mat[64 * 64];
for (unsigned int i = 0; i < n; i++) {
memcpy(mat + i * (n + 1), inp_mat + i * n, n);
mat[i * (n + 1) + n] = c_terms[i];
}
unsigned int r8 = PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256mat_gauss_elim(mat, n, n + 1);
for (unsigned int i = 0; i < n; i++) {
sol[i] = mat[i * (n + 1) + n];
}
return r8;
}
static inline void gf256mat_submat(uint8_t *mat2, unsigned int w2, unsigned int st, const uint8_t *mat, unsigned int w, unsigned int h) {
for (unsigned int i = 0; i < h; i++) {
for (unsigned int j = 0; j < w2; j++) {
mat2[i * w2 + j] = mat[i * w + st + j];
}
}
}
unsigned int PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256mat_inv(uint8_t *inv_a, const uint8_t *a, unsigned int H, uint8_t *buffer) {
uint8_t *aa = buffer;
for (unsigned int i = 0; i < H; i++) {
uint8_t *ai = aa + i * 2 * H;
PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_set_zero(ai, 2 * H);
gf256v_add(ai, a + i * H, H);
ai[H + i] = 1;
}
unsigned int r8 = PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256mat_gauss_elim(aa, H, 2 * H);
gf256mat_submat(inv_a, H, H, aa, 2 * H, H);
return r8;
}
// choosing the implementations depends on the macros _BLAS_AVX2_ and _BLAS_SSE
#define gf256mat_prod_impl gf256mat_prod_ref
#define gf256mat_gauss_elim_impl gf256mat_gauss_elim_ref
#define gf256mat_solve_linear_eq_impl gf256mat_solve_linear_eq_ref
void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256mat_prod(uint8_t *c, const uint8_t *matA, unsigned int n_A_vec_byte, unsigned int n_A_width, const uint8_t *b) {
gf256mat_prod_impl(c, matA, n_A_vec_byte, n_A_width, b);
}
unsigned int PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256mat_gauss_elim(uint8_t *mat, unsigned int h, unsigned int w) {
return gf256mat_gauss_elim_impl(mat, h, w);
}
unsigned int PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256mat_solve_linear_eq(uint8_t *sol, const uint8_t *inp_mat, const uint8_t *c_terms, unsigned int n) {
return gf256mat_solve_linear_eq_impl(sol, inp_mat, c_terms, n);
}