more cleaning
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@ -1,17 +1,11 @@
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#ifndef H_Q_MATRICES_GENERATION_H
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#define H_Q_MATRICES_GENERATION_H
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#include "gf2x_limbs.h"
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#include "gf2x_arith.h"
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#include "qc_ldpc_parameters.h"
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#include "rng.h"
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void PQCLEAN_LEDAKEMLT12_CLEAN_generateHPosOnes_HtrPosOnes(
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POSITION_T HPosOnes[N0][DV],
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POSITION_T HtrPosOnes[N0][DV],
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AES_XOF_struct *niederreiter_keys_expander);
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void PQCLEAN_LEDAKEMLT12_CLEAN_generateQsparse(
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POSITION_T pos_ones[N0][M],
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AES_XOF_struct *niederreiter_keys_expander);
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void PQCLEAN_LEDAKEMLT12_CLEAN_generateHPosOnes_HtrPosOnes(POSITION_T HPosOnes[N0][DV], POSITION_T HtrPosOnes[N0][DV], AES_XOF_struct *niederreiter_keys_expander);
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void PQCLEAN_LEDAKEMLT12_CLEAN_generateQsparse(POSITION_T pos_ones[N0][M], AES_XOF_struct *niederreiter_keys_expander);
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#endif
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@ -2,7 +2,7 @@
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LIB=libledakemlt12_clean.a
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HEADERS=api.h bf_decoding.h dfr_test.h gf2x_arith_mod_xPplusOne.h \
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gf2x_arith.h gf2x_limbs.h H_Q_matrices_generation.h \
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gf2x_arith.h H_Q_matrices_generation.h \
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niederreiter.h qc_ldpc_parameters.h rng.h
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OBJECTS=bf_decoding.o dfr_test.o gf2x_arith_mod_xPplusOne.o \
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@ -1,7 +1,7 @@
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#ifndef BF_DECODING_H
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#define BF_DECODING_H
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#include "gf2x_limbs.h"
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#include "gf2x_arith.h"
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#include "qc_ldpc_parameters.h"
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/* Definitions for DFR level 2^-SL with SL=128 */
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@ -11,7 +11,7 @@
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int PQCLEAN_LEDAKEMLT12_CLEAN_bf_decoding(DIGIT err[],
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const POSITION_T HtrPosOnes[N0][DV],
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const POSITION_T QtrPosOnes[N0][M], // N0 vectors containing exp.s of Qtr ones
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const POSITION_T QtrPosOnes[N0][M],
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DIGIT privateSyndrome[]);
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#endif
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@ -1,7 +1,8 @@
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#ifndef GF2X_ARITH_H
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#define GF2X_ARITH_H
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#include "gf2x_limbs.h"
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#include <inttypes.h>
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#include <stddef.h>
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/*
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* Elements of GF(2)[x] are stored in compact dense binary form.
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@ -42,9 +43,12 @@
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* position[A_{0}] == n-1
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*/
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typedef uint64_t DIGIT;
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#define DIGIT_SIZE_B (8)
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#define DIGIT_SIZE_b (DIGIT_SIZE_B << 3)
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#define POSITION_T uint32_t
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#define GF2X_MUL PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mul_comb
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// #define GF2X_MUL gf2x_mul_comb
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static inline void gf2x_add(DIGIT Res[], const DIGIT A[], const DIGIT B[], size_t nr) {
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for (size_t i = 0; i < nr; i++) {
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@ -52,13 +56,8 @@ static inline void gf2x_add(DIGIT Res[], const DIGIT A[], const DIGIT B[], size_
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}
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}
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/* PRE: MAX ALLOWED ROTATION AMOUNT : DIGIT_SIZE_b */
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void PQCLEAN_LEDAKEMLT12_CLEAN_right_bit_shift_n(size_t length, DIGIT in[], unsigned int amount);
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/* PRE: MAX ALLOWED ROTATION AMOUNT : DIGIT_SIZE_b */
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void PQCLEAN_LEDAKEMLT12_CLEAN_left_bit_shift_n(size_t length, DIGIT in[], unsigned int amount);
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void GF2X_MUL(int nr, DIGIT Res[], int na, const DIGIT A[], int nb, const DIGIT B[]);
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#endif
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@ -7,7 +7,7 @@
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static void gf2x_mod(DIGIT out[], const DIGIT in[]) {
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int i, j, posTrailingBit, maskOffset;
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int i, j, posTrailingBit, maskOffset, to_copy;
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DIGIT mask, aux[2 * NUM_DIGITS_GF2X_ELEMENT];
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memcpy(aux, in, 2 * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B);
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@ -46,7 +46,7 @@ static void gf2x_mod(DIGIT out[], const DIGIT in[]) {
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}
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}
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int to_copy = (2 * NUM_DIGITS_GF2X_ELEMENT > NUM_DIGITS_GF2X_ELEMENT) ? NUM_DIGITS_GF2X_ELEMENT : 2 * NUM_DIGITS_GF2X_ELEMENT;
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to_copy = (2 * NUM_DIGITS_GF2X_ELEMENT > NUM_DIGITS_GF2X_ELEMENT) ? NUM_DIGITS_GF2X_ELEMENT : 2 * NUM_DIGITS_GF2X_ELEMENT;
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for (i = 0; i < to_copy; i++) {
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out[NUM_DIGITS_GF2X_ELEMENT - 1 - i] = aux[2 * NUM_DIGITS_GF2X_ELEMENT - 1 - i];
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@ -93,31 +93,19 @@ static void left_bit_shift_wide_n(const int length, DIGIT in[], unsigned int amo
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PQCLEAN_LEDAKEMLT12_CLEAN_left_bit_shift_n(length, in, amount % DIGIT_SIZE_b);
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}
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static uint8_t byte_reverse_with_64bitDIGIT(uint8_t b) {
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b = (uint8_t)((b * 0x0202020202ULL & 0x010884422010ULL) % 1023);
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return b;
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}
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/* https://stackoverflow.com/questions/2182002/convert-big-endian-to-little-endian-in-c-without-using-provided-func */
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static uint64_t swap_uint64( uint64_t val ) {
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val = ((val << 8) & 0xFF00FF00FF00FF00ULL ) | ((val >> 8) & 0x00FF00FF00FF00FFULL );
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val = ((val << 16) & 0xFFFF0000FFFF0000ULL ) | ((val >> 16) & 0x0000FFFF0000FFFFULL );
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return (val << 32) | (val >> 32);
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}
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static DIGIT reverse_digit(const DIGIT b) {
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int i;
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union toReverse_t {
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uint8_t inByte[DIGIT_SIZE_B];
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DIGIT digitValue;
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} toReverse;
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toReverse.digitValue = b;
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for (i = 0; i < DIGIT_SIZE_B; i++) {
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toReverse.inByte[i] = byte_reverse_with_64bitDIGIT(toReverse.inByte[i]);
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}
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return swap_uint64(toReverse.digitValue);
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/* Hackers delight, reverses a uint64_t */
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static DIGIT reverse_digit(DIGIT x) {
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uint64_t t;
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x = (x << 31) | (x >> 33);
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t = (x ^ (x >> 20)) & 0x00000FFF800007FFLL;
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x = (t | (t << 20)) ^ x;
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t = (x ^ (x >> 8)) & 0x00F8000F80700807LL;
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x = (t | (t << 8)) ^ x;
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t = (x ^ (x >> 4)) & 0x0808708080807008LL;
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x = (t | (t << 4)) ^ x;
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t = (x ^ (x >> 2)) & 0x1111111111111111LL;
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x = (t | (t << 2)) ^ x;
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return x;
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}
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_transpose_in_place(DIGIT A[]) {
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@ -137,11 +125,11 @@ void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_transpose_in_place(DIGIT A[]) {
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A[i] = rev2;
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A[NUM_DIGITS_GF2X_ELEMENT - 1 - i] = rev1;
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}
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/*
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if (NUM_DIGITS_GF2X_ELEMENT % 2 == 1) {
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A[NUM_DIGITS_GF2X_ELEMENT / 2] = reverse_digit(A[NUM_DIGITS_GF2X_ELEMENT / 2]);
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}*/
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A[NUM_DIGITS_GF2X_ELEMENT / 2] = reverse_digit(A[NUM_DIGITS_GF2X_ELEMENT / 2]);
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}
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if (slack_bits_amount) {
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PQCLEAN_LEDAKEMLT12_CLEAN_right_bit_shift_n(NUM_DIGITS_GF2X_ELEMENT, A, slack_bits_amount);
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@ -220,7 +208,6 @@ static void gf2x_swap(const int length,
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* (Chapter 11 -- Algorithm 11.44 -- pag 223)
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*
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*/
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int PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_inverse(DIGIT out[], const DIGIT in[]) { /* in^{-1} mod x^P-1 */
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int i;
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@ -533,3 +520,12 @@ void PQCLEAN_LEDAKEMLT12_CLEAN_rand_circulant_blocks_sequence(
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}
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}
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_tobytes(uint8_t *bytes, const DIGIT *poly) {
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size_t i, j;
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for (i = 0; i < NUM_DIGITS_GF2X_ELEMENT; i++) {
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for (j = 0; j < DIGIT_SIZE_B; j++) {
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bytes[i * DIGIT_SIZE_B + j] = (uint8_t) ((poly[i] >> (8 * j)) & 0xFF);
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}
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}
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}
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@ -1,22 +1,18 @@
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#ifndef GF2X_ARITH_MOD_XPLUSONE_H
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#define GF2X_ARITH_MOD_XPLUSONE_H
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#include "gf2x_limbs.h"
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#include "qc_ldpc_parameters.h"
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#include "gf2x_arith.h"
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#include "rng.h"
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#define NUM_BITS_GF2X_ELEMENT (P) // 52147
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#define NUM_DIGITS_GF2X_ELEMENT ((P+DIGIT_SIZE_b-1)/DIGIT_SIZE_b) // 815
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#define NUM_DIGITS_GF2X_ELEMENT ((P+DIGIT_SIZE_b-1)/DIGIT_SIZE_b)
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#define MSb_POSITION_IN_MSB_DIGIT_OF_ELEMENT ((P % DIGIT_SIZE_b) ? (P % DIGIT_SIZE_b)-1 : DIGIT_SIZE_b-1)
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#define NUM_BITS_GF2X_MODULUS (P+1)
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#define NUM_DIGITS_GF2X_MODULUS ((P+1+DIGIT_SIZE_b-1)/DIGIT_SIZE_b)
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#define MSb_POSITION_IN_MSB_DIGIT_OF_MODULUS (P-DIGIT_SIZE_b*(NUM_DIGITS_GF2X_MODULUS-1))
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#define INVALID_POS_VALUE (P)
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#define P_BITS (16) // log_2(p) = 15.6703
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@ -43,8 +39,7 @@ static inline void gf2x_set_coeff(DIGIT poly[], unsigned int exponent, DIGIT val
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/* clear given coefficient */
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DIGIT mask = ~( ((DIGIT) 1) << (DIGIT_SIZE_b - 1 - inDigitIdx));
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poly[digitIdx] = poly[digitIdx] & mask;
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poly[digitIdx] = poly[digitIdx] | (( value & ((DIGIT) 1)) <<
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(DIGIT_SIZE_b - 1 - inDigitIdx));
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poly[digitIdx] = poly[digitIdx] | (( value & ((DIGIT) 1)) << (DIGIT_SIZE_b - 1 - inDigitIdx));
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}
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/* toggles (flips) the coefficient of the x^exponent term as the LSB of a digit */
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@ -58,8 +53,8 @@ static inline void gf2x_toggle_coeff(DIGIT poly[], unsigned int exponent) {
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poly[digitIdx] = poly[digitIdx] ^ mask;
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}
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/* population count for an unsigned 64-bit integer */
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/* population count for an unsigned 64-bit integer
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Source: Hacker's delight, p.66 */
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static int popcount_uint64t(uint64_t x) {
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x -= (x >> 1) & 0x5555555555555555;
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x = (x & 0x3333333333333333) + ((x >> 2) & 0x3333333333333333);
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@ -80,42 +75,6 @@ static inline void gf2x_mod_add(DIGIT Res[], const DIGIT A[], const DIGIT B[]) {
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gf2x_add(Res, A, B, NUM_DIGITS_GF2X_ELEMENT);
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}
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_mul(DIGIT Res[], const DIGIT A[], const DIGIT B[]);
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int PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_inverse(DIGIT out[], const DIGIT in[]);
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/* in place bit-transp. of a(x) % x^P+1, e.g.: a3 a2 a1 a0 --> a1 a2 a3 a0 */
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_transpose_in_place(DIGIT A[]);
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void PQCLEAN_LEDAKEMLT12_CLEAN_rand_circulant_sparse_block(
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POSITION_T *pos_ones,
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int countOnes,
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AES_XOF_struct *seed_expander_ctx);
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void PQCLEAN_LEDAKEMLT12_CLEAN_rand_circulant_blocks_sequence(
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DIGIT sequence[N0 * NUM_DIGITS_GF2X_ELEMENT],
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AES_XOF_struct *seed_expander_ctx);
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_add_sparse(
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int sizeR, POSITION_T Res[],
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int sizeA, const POSITION_T A[],
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int sizeB, const POSITION_T B[]);
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_transpose_in_place_sparse(
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int sizeA,
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POSITION_T A[]);
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_mul_sparse(
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size_t sizeR, POSITION_T Res[],
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size_t sizeA, const POSITION_T A[],
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size_t sizeB, const POSITION_T B[]);
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_mul_dense_to_sparse(
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DIGIT Res[],
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const DIGIT dense[],
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POSITION_T sparse[],
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unsigned int nPos);
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static inline int partition(POSITION_T arr[], int lo, int hi) {
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POSITION_T x = arr[hi];
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POSITION_T tmp;
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@ -155,4 +114,16 @@ static inline void quicksort_sparse(POSITION_T Res[]) {
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}
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}
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_mul(DIGIT Res[], const DIGIT A[], const DIGIT B[]);
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_transpose_in_place(DIGIT A[]);
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void PQCLEAN_LEDAKEMLT12_CLEAN_rand_circulant_sparse_block(POSITION_T *pos_ones, int countOnes, AES_XOF_struct *seed_expander_ctx);
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void PQCLEAN_LEDAKEMLT12_CLEAN_rand_circulant_blocks_sequence(DIGIT *sequence, AES_XOF_struct *seed_expander_ctx);
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_add_sparse(int sizeR, POSITION_T Res[], int sizeA, const POSITION_T A[], int sizeB, const POSITION_T B[]);
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_transpose_in_place_sparse(int sizeA, POSITION_T A[]);
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_mul_sparse(size_t sizeR, POSITION_T Res[], size_t sizeA, const POSITION_T A[], size_t sizeB, const POSITION_T B[]);
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_mul_dense_to_sparse(DIGIT Res[], const DIGIT dense[], POSITION_T sparse[], unsigned int nPos);
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void PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_tobytes(uint8_t *bytes, const DIGIT *poly);
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int PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_inverse(DIGIT out[], const DIGIT in[]);
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#endif
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#ifndef GF2X_LIMBS_H
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#define GF2X_LIMBS_H
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#include "qc_ldpc_parameters.h"
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#include <inttypes.h>
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#include <limits.h>
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#include <stddef.h>
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typedef uint64_t DIGIT;
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#define DIGIT_IS_UINT64
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#define DIGIT_IS_ULLONG
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#define DIGIT_SIZE_B (8)
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#define DIGIT_SIZE_b (DIGIT_SIZE_B << 3)
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#define POSITION_T uint32_t
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#endif
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@ -16,17 +16,10 @@ int PQCLEAN_LEDAKEMLT12_CLEAN_crypto_kem_keypair(unsigned char *pk, unsigned cha
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return 0;
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}
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static void error_tobytes(uint8_t *error_bytes, const uint64_t *error_digits) {
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size_t i, j, k;
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uint64_t t;
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static void pack_error(uint8_t *error_bytes, const DIGIT *error_digits) {
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size_t i;
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for (i = 0; i < N0; i++) {
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for (j = 0; j < NUM_DIGITS_GF2X_ELEMENT; j++) {
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t = error_digits[i * NUM_DIGITS_GF2X_ELEMENT + j];
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for (k = 0; k < DIGIT_SIZE_B; k++) {
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error_bytes[(i * NUM_DIGITS_GF2X_ELEMENT + j) * DIGIT_SIZE_B + k] = (uint8_t) ((t >> (8 * k)) & 0xFF);
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}
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}
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PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_tobytes(error_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B, error_digits + i * NUM_DIGITS_GF2X_ELEMENT);
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}
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}
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@ -41,7 +34,7 @@ int PQCLEAN_LEDAKEMLT12_CLEAN_crypto_kem_enc(unsigned char *ct, unsigned char *s
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randombytes(encapsulated_key_seed, TRNG_BYTE_LENGTH);
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PQCLEAN_LEDAKEMLT12_CLEAN_seedexpander_from_trng(&niederreiter_encap_key_expander, encapsulated_key_seed);
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PQCLEAN_LEDAKEMLT12_CLEAN_rand_circulant_blocks_sequence(error_vector, &niederreiter_encap_key_expander);
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error_tobytes(error_bytes, error_vector);
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pack_error(error_bytes, error_vector);
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HASH_FUNCTION(ss, error_bytes, (N0 * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B));
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PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_encrypt((DIGIT *) ct, (publicKeyNiederreiter_t *) pk, error_vector);
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@ -56,7 +49,7 @@ int PQCLEAN_LEDAKEMLT12_CLEAN_crypto_kem_dec(unsigned char *ss, const unsigned c
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uint8_t decoded_error_bytes[N0 * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B];
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PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_decrypt(decoded_error_vector, (privateKeyNiederreiter_t *)sk, (DIGIT *)ct);
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error_tobytes(decoded_error_bytes, decoded_error_vector);
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pack_error(decoded_error_bytes, decoded_error_vector);
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HASH_FUNCTION(ss, decoded_error_bytes, (N0 * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B));
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return 0;
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|
@ -8,9 +8,7 @@
|
||||
|
||||
#include <string.h>
|
||||
|
||||
void PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_keygen(publicKeyNiederreiter_t *pk,
|
||||
privateKeyNiederreiter_t *sk,
|
||||
AES_XOF_struct *keys_expander) {
|
||||
void PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_keygen(publicKeyNiederreiter_t *pk, privateKeyNiederreiter_t *sk, AES_XOF_struct *keys_expander) {
|
||||
|
||||
// sequence of N0 circ block matrices (p x p): Hi
|
||||
POSITION_T HPosOnes[N0][DV];
|
||||
@ -32,12 +30,8 @@ void PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_keygen(publicKeyNiederreiter_t *pk,
|
||||
int isDFRok = 0;
|
||||
sk->rejections = (int8_t) 0;
|
||||
do {
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_generateHPosOnes_HtrPosOnes(HPosOnes,
|
||||
HtrPosOnes,
|
||||
keys_expander);
|
||||
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_generateQsparse(QPosOnes,
|
||||
keys_expander);
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_generateHPosOnes_HtrPosOnes(HPosOnes, HtrPosOnes, keys_expander);
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_generateQsparse(QPosOnes, keys_expander);
|
||||
for (int i = 0; i < N0; i++) {
|
||||
for (int j = 0; j < DV * M; j++) {
|
||||
LPosOnes[i][j] = INVALID_POS_VALUE;
|
||||
@ -89,10 +83,7 @@ void PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_keygen(publicKeyNiederreiter_t *pk,
|
||||
}
|
||||
|
||||
|
||||
void PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_encrypt(DIGIT *syndrome, // 1 polynomial
|
||||
const publicKeyNiederreiter_t *pk,
|
||||
const DIGIT *err) { // N0 polynomials
|
||||
|
||||
void PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_encrypt(DIGIT *syndrome, const publicKeyNiederreiter_t *pk, const DIGIT *err) {
|
||||
int i;
|
||||
DIGIT saux[NUM_DIGITS_GF2X_ELEMENT];
|
||||
|
||||
@ -101,21 +92,17 @@ void PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_encrypt(DIGIT *syndrome, // 1 polyn
|
||||
for (i = 0; i < N0 - 1; i++) {
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_mul(saux,
|
||||
pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT,
|
||||
err + i * NUM_DIGITS_GF2X_ELEMENT
|
||||
);
|
||||
err + i * NUM_DIGITS_GF2X_ELEMENT);
|
||||
gf2x_mod_add(syndrome, syndrome, saux);
|
||||
} // end for
|
||||
gf2x_mod_add(syndrome, syndrome, err + (N0 - 1)*NUM_DIGITS_GF2X_ELEMENT);
|
||||
}
|
||||
|
||||
|
||||
int PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_decrypt(DIGIT *err, // N0 circ poly
|
||||
const privateKeyNiederreiter_t *sk,
|
||||
const DIGIT *syndrome) {
|
||||
int PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_decrypt(DIGIT *err, const privateKeyNiederreiter_t *sk, const DIGIT *syndrome) {
|
||||
|
||||
AES_XOF_struct niederreiter_decrypt_expander;
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_seedexpander_from_trng(&niederreiter_decrypt_expander,
|
||||
sk->prng_seed);
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_seedexpander_from_trng(&niederreiter_decrypt_expander, sk->prng_seed);
|
||||
|
||||
// sequence of N0 circ block matrices (p x p):
|
||||
POSITION_T HPosOnes[N0][DV];
|
||||
@ -124,8 +111,7 @@ int PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_decrypt(DIGIT *err, // N0 circ poly
|
||||
int rejections = sk->rejections;
|
||||
POSITION_T LPosOnes[N0][DV * M];
|
||||
do {
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_generateHPosOnes_HtrPosOnes(HPosOnes, HtrPosOnes,
|
||||
&niederreiter_decrypt_expander);
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_generateHPosOnes_HtrPosOnes(HPosOnes, HtrPosOnes, &niederreiter_decrypt_expander);
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_generateQsparse(QPosOnes, &niederreiter_decrypt_expander);
|
||||
for (int i = 0; i < N0; i++) {
|
||||
for (int j = 0; j < DV * M; j++) {
|
||||
@ -174,27 +160,24 @@ int PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_decrypt(DIGIT *err, // N0 circ poly
|
||||
for (int i = 0; i < N0; i++) {
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_mul_sparse(DV * M, auxSparse,
|
||||
DV, HPosOnes[i],
|
||||
qBlockWeights[i][N0 - 1], &QPosOnes[i][ M - qBlockWeights[i][N0 - 1] ]
|
||||
);
|
||||
qBlockWeights[i][N0 - 1], &QPosOnes[i][ M - qBlockWeights[i][N0 - 1]]);
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_add_sparse(DV * M, Ln0trSparse,
|
||||
DV * M, Ln0trSparse,
|
||||
DV * M, auxSparse
|
||||
);
|
||||
DV * M, auxSparse);
|
||||
} // end for i
|
||||
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_transpose_in_place_sparse(DV * M, Ln0trSparse);
|
||||
|
||||
DIGIT privateSyndrome[NUM_DIGITS_GF2X_ELEMENT];
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_mul_dense_to_sparse(privateSyndrome,
|
||||
syndrome,
|
||||
Ln0trSparse,
|
||||
DV * M);
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_gf2x_mod_mul_dense_to_sparse(privateSyndrome, syndrome, Ln0trSparse, DV * M);
|
||||
|
||||
/* prepare mockup error vector in case a decoding failure occurs */
|
||||
DIGIT mockup_error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT];
|
||||
memset(mockup_error_vector, 0x00, N0 * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B);
|
||||
memcpy(mockup_error_vector, syndrome, NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B);
|
||||
PQCLEAN_LEDAKEMLT12_CLEAN_seedexpander(&niederreiter_decrypt_expander,
|
||||
((unsigned char *) mockup_error_vector) + (NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B), TRNG_BYTE_LENGTH);
|
||||
((unsigned char *) mockup_error_vector) + (NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B),
|
||||
TRNG_BYTE_LENGTH);
|
||||
|
||||
int decryptOk = 0;
|
||||
memset(err, 0x00, N0 * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B);
|
||||
|
@ -2,7 +2,6 @@
|
||||
#define NIEDERREITER_H
|
||||
|
||||
#include "gf2x_arith_mod_xPplusOne.h"
|
||||
#include "gf2x_limbs.h"
|
||||
#include "qc_ldpc_parameters.h"
|
||||
#include "rng.h"
|
||||
|
||||
@ -21,23 +20,9 @@ typedef struct {
|
||||
// with P coefficients.
|
||||
} publicKeyNiederreiter_t;
|
||||
|
||||
|
||||
|
||||
void PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_keygen(
|
||||
publicKeyNiederreiter_t *pk,
|
||||
privateKeyNiederreiter_t *sk,
|
||||
AES_XOF_struct *keys_expander);
|
||||
|
||||
void PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_encrypt(
|
||||
DIGIT syndrome[],
|
||||
const publicKeyNiederreiter_t *pk,
|
||||
const DIGIT *err);
|
||||
|
||||
// return 1 if everything is ok
|
||||
int PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_decrypt(
|
||||
DIGIT *err,
|
||||
const privateKeyNiederreiter_t *sk,
|
||||
const DIGIT *syndrome);
|
||||
void PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_keygen(publicKeyNiederreiter_t *pk, privateKeyNiederreiter_t *sk, AES_XOF_struct *keys_expander);
|
||||
void PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_encrypt(DIGIT syndrome[], const publicKeyNiederreiter_t *pk, const DIGIT *err);
|
||||
int PQCLEAN_LEDAKEMLT12_CLEAN_niederreiter_decrypt(DIGIT *err, const privateKeyNiederreiter_t *sk, const DIGIT *syndrome);
|
||||
|
||||
|
||||
#endif
|
||||
|
@ -17,10 +17,7 @@ typedef struct {
|
||||
unsigned char ctr[16];
|
||||
} AES_XOF_struct;
|
||||
|
||||
|
||||
int PQCLEAN_LEDAKEMLT12_CLEAN_seedexpander(AES_XOF_struct *ctx, unsigned char *x, size_t xlen);
|
||||
|
||||
/* TRNG_BYTE_LENGTH wide buffer */
|
||||
void PQCLEAN_LEDAKEMLT12_CLEAN_seedexpander_from_trng(AES_XOF_struct *ctx, const unsigned char *trng_entropy);
|
||||
|
||||
#endif
|
||||
|
Loading…
Reference in New Issue
Block a user