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serialize pk/ct

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This commit is contained in:
Leon Botros 2019-08-23 11:30:02 +02:00
parent 1fc2f51f82
commit 537d2a1ac0
3 changed files with 81 additions and 66 deletions
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49
crypto_kem/ledakemlt12/leaktime/kem.c
View File

@ -6,51 +6,47 @@
#include <string.h> #include <string.h>
/*
static void pack_pk(uint8_t *pk_bytes, publicKeyNiederreiter_t *pk) { static void pack_pk(uint8_t *pk_bytes, publicKeyNiederreiter_t *pk) {
size_t i; for (size_t i = 0; i < N0 - 1; i++) {
for (i = 0; i < N0 - 1; i++) {
PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_tobytes(pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B, PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_tobytes(pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B,
pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT); pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT);
} }
} }
static void unpack_pk(publicKeyNiederreiter_t *pk, const uint8_t *pk_bytes) { static void unpack_pk(publicKeyNiederreiter_t *pk, const uint8_t *pk_bytes) {
size_t i; for (size_t i = 0; i < N0 - 1; i++) {
for (i = 0; i < N0 - 1; i++) {
PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_frombytes(pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT, PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_frombytes(pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT,
pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B); pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B);
} }
} }
static void pack_ct(uint8_t *sk_bytes, DIGIT *ct) { #define pack_ct(sk_bytes, ct) PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_tobytes(sk_bytes, ct);
PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_tobytes(sk_bytes, ct); #define unpack_ct(ct, ct_bytes) PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_frombytes(ct, ct_bytes)
}
static void unpack_ct(DIGIT *ct, const uint8_t *ct_bytes) {
PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_frombytes(ct, ct_bytes);
}
/*
static void pack_error(uint8_t *error_bytes, DIGIT *error_digits) { static void pack_error(uint8_t *error_bytes, DIGIT *error_digits) {
size_t i; size_t i;
for (i = 0; i < N0; i++) { for (i = 0; i < N0; i++) {
PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_tobytes(error_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B, PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_tobytes(error_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B,
error_digits + i * NUM_DIGITS_GF2X_ELEMENT); error_digits + i * NUM_DIGITS_GF2X_ELEMENT);
} }
} }*/
*/
/* IND-CCA2 Keygen */ /* IND-CCA2 Keygen */
int PQCLEAN_LEDAKEMLT12_LEAKTIME_crypto_kem_keypair(uint8_t *pk, uint8_t *sk) { int PQCLEAN_LEDAKEMLT12_LEAKTIME_crypto_kem_keypair(uint8_t *pk, uint8_t *sk) {
publicKeyNiederreiter_t niederreiter_pk;
PQCLEAN_LEDAKEMLT12_LEAKTIME_niederreiter_keygen((publicKeyNiederreiter_t *) pk, PQCLEAN_LEDAKEMLT12_LEAKTIME_niederreiter_keygen(&niederreiter_pk, (privateKeyNiederreiter_t *) sk);
(privateKeyNiederreiter_t *) sk);
pack_pk(pk, &niederreiter_pk);
return 0; return 0;
} }
/* IND-CCA2 Encapsulation */ /* IND-CCA2 Encapsulation */
int PQCLEAN_LEDAKEMLT12_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const uint8_t *pk) { int PQCLEAN_LEDAKEMLT12_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const uint8_t *pk) {
publicKeyNiederreiter_t niederreiter_pk;
DIGIT syndrome[NUM_DIGITS_GF2X_ELEMENT];
AES_XOF_struct hashedAndTruncatedSeed_expander; AES_XOF_struct hashedAndTruncatedSeed_expander;
POSITION_T errorPos[NUM_ERRORS_T]; POSITION_T errorPos[NUM_ERRORS_T];
DIGIT error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT]; DIGIT error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT];
@ -62,8 +58,11 @@ int PQCLEAN_LEDAKEMLT12_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const
uint8_t hashedAndTruncatedErrorVector[TRNG_BYTE_LENGTH] = {0}; uint8_t hashedAndTruncatedErrorVector[TRNG_BYTE_LENGTH] = {0};
uint8_t maskedSeed[TRNG_BYTE_LENGTH]; uint8_t maskedSeed[TRNG_BYTE_LENGTH];
unpack_pk(&niederreiter_pk, pk);
randombytes(seed, TRNG_BYTE_LENGTH); randombytes(seed, TRNG_BYTE_LENGTH);
memcpy(ss_input, seed, TRNG_BYTE_LENGTH); memcpy(ss_input, seed, TRNG_BYTE_LENGTH);
HASH_FUNCTION(ss, ss_input, 2 * TRNG_BYTE_LENGTH); HASH_FUNCTION(ss, ss_input, 2 * TRNG_BYTE_LENGTH);
HASH_FUNCTION(hashedSeed, seed, TRNG_BYTE_LENGTH); HASH_FUNCTION(hashedSeed, seed, TRNG_BYTE_LENGTH);
@ -78,19 +77,23 @@ int PQCLEAN_LEDAKEMLT12_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const
memcpy(hashedAndTruncatedErrorVector, hashedErrorVector, TRNG_BYTE_LENGTH); memcpy(hashedAndTruncatedErrorVector, hashedErrorVector, TRNG_BYTE_LENGTH);
for (int i = 0; i < TRNG_BYTE_LENGTH; ++i) { for (size_t i = 0; i < TRNG_BYTE_LENGTH; ++i) {
maskedSeed[i] = seed[i] ^ hashedAndTruncatedErrorVector[i]; maskedSeed[i] = seed[i] ^ hashedAndTruncatedErrorVector[i];
} }
PQCLEAN_LEDAKEMLT12_LEAKTIME_niederreiter_encrypt((DIGIT *) ct, (const publicKeyNiederreiter_t *)pk, error_vector); PQCLEAN_LEDAKEMLT12_LEAKTIME_niederreiter_encrypt(syndrome,
(const publicKeyNiederreiter_t *) &niederreiter_pk, error_vector);
pack_ct(ct, syndrome);
memcpy(ct + (NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B), maskedSeed, TRNG_BYTE_LENGTH); memcpy(ct + (NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B), maskedSeed, TRNG_BYTE_LENGTH);
return 0; return 0;
} }
/* INDCCA2 Decapsulation */ /* IND-CCA2 Decapsulation */
int PQCLEAN_LEDAKEMLT12_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct, const uint8_t *sk) { int PQCLEAN_LEDAKEMLT12_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct, const uint8_t *sk) {
DIGIT syndrome[NUM_DIGITS_GF2X_ELEMENT];
AES_XOF_struct hashedAndTruncatedSeed_expander; AES_XOF_struct hashedAndTruncatedSeed_expander;
POSITION_T reconstructed_errorPos[NUM_ERRORS_T]; POSITION_T reconstructed_errorPos[NUM_ERRORS_T];
DIGIT reconstructed_error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT]; DIGIT reconstructed_error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT];
@ -102,9 +105,10 @@ int PQCLEAN_LEDAKEMLT12_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct,
uint8_t hashedAndTruncated_decoded_seed[TRNG_BYTE_LENGTH] = {0}; uint8_t hashedAndTruncated_decoded_seed[TRNG_BYTE_LENGTH] = {0};
uint8_t ss_input[2 * TRNG_BYTE_LENGTH], tail[TRNG_BYTE_LENGTH] = {0}; uint8_t ss_input[2 * TRNG_BYTE_LENGTH], tail[TRNG_BYTE_LENGTH] = {0};
unpack_ct(syndrome, ct);
int decode_ok = PQCLEAN_LEDAKEMLT12_LEAKTIME_niederreiter_decrypt(decoded_error_vector, int decode_ok = PQCLEAN_LEDAKEMLT12_LEAKTIME_niederreiter_decrypt(decoded_error_vector,
(const privateKeyNiederreiter_t *)sk, (const privateKeyNiederreiter_t *)sk, syndrome);
(DIGIT *)ct);
HASH_FUNCTION(hashedErrorVector, HASH_FUNCTION(hashedErrorVector,
(const uint8_t *) decoded_error_vector, (const uint8_t *) decoded_error_vector,
@ -129,7 +133,8 @@ int PQCLEAN_LEDAKEMLT12_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct,
PQCLEAN_LEDAKEMLT12_LEAKTIME_expand_error(reconstructed_error_vector, reconstructed_errorPos); PQCLEAN_LEDAKEMLT12_LEAKTIME_expand_error(reconstructed_error_vector, reconstructed_errorPos);
int equal = PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_verify(decoded_error_vector, reconstructed_error_vector, N0 * NUM_DIGITS_GF2X_ELEMENT); int equal = PQCLEAN_LEDAKEMLT12_LEAKTIME_gf2x_verify(decoded_error_vector,
reconstructed_error_vector, N0 * NUM_DIGITS_GF2X_ELEMENT);
// equal == 0, if the reconstructed error vector match !!! // equal == 0, if the reconstructed error vector match !!!
int decryptOk = (decode_ok == 1 && equal == 0); int decryptOk = (decode_ok == 1 && equal == 0);

49
crypto_kem/ledakemlt32/leaktime/kem.c
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@ -6,51 +6,47 @@
#include <string.h> #include <string.h>
/*
static void pack_pk(uint8_t *pk_bytes, publicKeyNiederreiter_t *pk) { static void pack_pk(uint8_t *pk_bytes, publicKeyNiederreiter_t *pk) {
size_t i; for (size_t i = 0; i < N0 - 1; i++) {
for (i = 0; i < N0 - 1; i++) {
PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_tobytes(pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B, PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_tobytes(pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B,
pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT); pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT);
} }
} }
static void unpack_pk(publicKeyNiederreiter_t *pk, const uint8_t *pk_bytes) { static void unpack_pk(publicKeyNiederreiter_t *pk, const uint8_t *pk_bytes) {
size_t i; for (size_t i = 0; i < N0 - 1; i++) {
for (i = 0; i < N0 - 1; i++) {
PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_frombytes(pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT, PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_frombytes(pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT,
pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B); pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B);
} }
} }
static void pack_ct(uint8_t *sk_bytes, DIGIT *ct) { #define pack_ct(sk_bytes, ct) PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_tobytes(sk_bytes, ct);
PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_tobytes(sk_bytes, ct); #define unpack_ct(ct, ct_bytes) PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_frombytes(ct, ct_bytes)
}
static void unpack_ct(DIGIT *ct, const uint8_t *ct_bytes) {
PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_frombytes(ct, ct_bytes);
}
/*
static void pack_error(uint8_t *error_bytes, DIGIT *error_digits) { static void pack_error(uint8_t *error_bytes, DIGIT *error_digits) {
size_t i; size_t i;
for (i = 0; i < N0; i++) { for (i = 0; i < N0; i++) {
PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_tobytes(error_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B, PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_tobytes(error_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B,
error_digits + i * NUM_DIGITS_GF2X_ELEMENT); error_digits + i * NUM_DIGITS_GF2X_ELEMENT);
} }
} }*/
*/
/* IND-CCA2 Keygen */ /* IND-CCA2 Keygen */
int PQCLEAN_LEDAKEMLT32_LEAKTIME_crypto_kem_keypair(uint8_t *pk, uint8_t *sk) { int PQCLEAN_LEDAKEMLT32_LEAKTIME_crypto_kem_keypair(uint8_t *pk, uint8_t *sk) {
publicKeyNiederreiter_t niederreiter_pk;
PQCLEAN_LEDAKEMLT32_LEAKTIME_niederreiter_keygen((publicKeyNiederreiter_t *) pk, PQCLEAN_LEDAKEMLT32_LEAKTIME_niederreiter_keygen(&niederreiter_pk, (privateKeyNiederreiter_t *) sk);
(privateKeyNiederreiter_t *) sk);
pack_pk(pk, &niederreiter_pk);
return 0; return 0;
} }
/* IND-CCA2 Encapsulation */ /* IND-CCA2 Encapsulation */
int PQCLEAN_LEDAKEMLT32_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const uint8_t *pk) { int PQCLEAN_LEDAKEMLT32_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const uint8_t *pk) {
publicKeyNiederreiter_t niederreiter_pk;
DIGIT syndrome[NUM_DIGITS_GF2X_ELEMENT];
AES_XOF_struct hashedAndTruncatedSeed_expander; AES_XOF_struct hashedAndTruncatedSeed_expander;
POSITION_T errorPos[NUM_ERRORS_T]; POSITION_T errorPos[NUM_ERRORS_T];
DIGIT error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT]; DIGIT error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT];
@ -62,8 +58,11 @@ int PQCLEAN_LEDAKEMLT32_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const
uint8_t hashedAndTruncatedErrorVector[TRNG_BYTE_LENGTH] = {0}; uint8_t hashedAndTruncatedErrorVector[TRNG_BYTE_LENGTH] = {0};
uint8_t maskedSeed[TRNG_BYTE_LENGTH]; uint8_t maskedSeed[TRNG_BYTE_LENGTH];
unpack_pk(&niederreiter_pk, pk);
randombytes(seed, TRNG_BYTE_LENGTH); randombytes(seed, TRNG_BYTE_LENGTH);
memcpy(ss_input, seed, TRNG_BYTE_LENGTH); memcpy(ss_input, seed, TRNG_BYTE_LENGTH);
HASH_FUNCTION(ss, ss_input, 2 * TRNG_BYTE_LENGTH); HASH_FUNCTION(ss, ss_input, 2 * TRNG_BYTE_LENGTH);
HASH_FUNCTION(hashedSeed, seed, TRNG_BYTE_LENGTH); HASH_FUNCTION(hashedSeed, seed, TRNG_BYTE_LENGTH);
@ -78,19 +77,23 @@ int PQCLEAN_LEDAKEMLT32_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const
memcpy(hashedAndTruncatedErrorVector, hashedErrorVector, TRNG_BYTE_LENGTH); memcpy(hashedAndTruncatedErrorVector, hashedErrorVector, TRNG_BYTE_LENGTH);
for (int i = 0; i < TRNG_BYTE_LENGTH; ++i) { for (size_t i = 0; i < TRNG_BYTE_LENGTH; ++i) {
maskedSeed[i] = seed[i] ^ hashedAndTruncatedErrorVector[i]; maskedSeed[i] = seed[i] ^ hashedAndTruncatedErrorVector[i];
} }
PQCLEAN_LEDAKEMLT32_LEAKTIME_niederreiter_encrypt((DIGIT *) ct, (const publicKeyNiederreiter_t *)pk, error_vector); PQCLEAN_LEDAKEMLT32_LEAKTIME_niederreiter_encrypt(syndrome,
(const publicKeyNiederreiter_t *) &niederreiter_pk, error_vector);
pack_ct(ct, syndrome);
memcpy(ct + (NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B), maskedSeed, TRNG_BYTE_LENGTH); memcpy(ct + (NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B), maskedSeed, TRNG_BYTE_LENGTH);
return 0; return 0;
} }
/* INDCCA2 Decapsulation */ /* IND-CCA2 Decapsulation */
int PQCLEAN_LEDAKEMLT32_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct, const uint8_t *sk) { int PQCLEAN_LEDAKEMLT32_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct, const uint8_t *sk) {
DIGIT syndrome[NUM_DIGITS_GF2X_ELEMENT];
AES_XOF_struct hashedAndTruncatedSeed_expander; AES_XOF_struct hashedAndTruncatedSeed_expander;
POSITION_T reconstructed_errorPos[NUM_ERRORS_T]; POSITION_T reconstructed_errorPos[NUM_ERRORS_T];
DIGIT reconstructed_error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT]; DIGIT reconstructed_error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT];
@ -102,9 +105,10 @@ int PQCLEAN_LEDAKEMLT32_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct,
uint8_t hashedAndTruncated_decoded_seed[TRNG_BYTE_LENGTH] = {0}; uint8_t hashedAndTruncated_decoded_seed[TRNG_BYTE_LENGTH] = {0};
uint8_t ss_input[2 * TRNG_BYTE_LENGTH], tail[TRNG_BYTE_LENGTH] = {0}; uint8_t ss_input[2 * TRNG_BYTE_LENGTH], tail[TRNG_BYTE_LENGTH] = {0};
unpack_ct(syndrome, ct);
int decode_ok = PQCLEAN_LEDAKEMLT32_LEAKTIME_niederreiter_decrypt(decoded_error_vector, int decode_ok = PQCLEAN_LEDAKEMLT32_LEAKTIME_niederreiter_decrypt(decoded_error_vector,
(const privateKeyNiederreiter_t *)sk, (const privateKeyNiederreiter_t *)sk, syndrome);
(DIGIT *)ct);
HASH_FUNCTION(hashedErrorVector, HASH_FUNCTION(hashedErrorVector,
(const uint8_t *) decoded_error_vector, (const uint8_t *) decoded_error_vector,
@ -129,7 +133,8 @@ int PQCLEAN_LEDAKEMLT32_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct,
PQCLEAN_LEDAKEMLT32_LEAKTIME_expand_error(reconstructed_error_vector, reconstructed_errorPos); PQCLEAN_LEDAKEMLT32_LEAKTIME_expand_error(reconstructed_error_vector, reconstructed_errorPos);
int equal = PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_verify(decoded_error_vector, reconstructed_error_vector, N0 * NUM_DIGITS_GF2X_ELEMENT); int equal = PQCLEAN_LEDAKEMLT32_LEAKTIME_gf2x_verify(decoded_error_vector,
reconstructed_error_vector, N0 * NUM_DIGITS_GF2X_ELEMENT);
// equal == 0, if the reconstructed error vector match !!! // equal == 0, if the reconstructed error vector match !!!
int decryptOk = (decode_ok == 1 && equal == 0); int decryptOk = (decode_ok == 1 && equal == 0);

49
crypto_kem/ledakemlt52/leaktime/kem.c
View File

@ -6,51 +6,47 @@
#include <string.h> #include <string.h>
/*
static void pack_pk(uint8_t *pk_bytes, publicKeyNiederreiter_t *pk) { static void pack_pk(uint8_t *pk_bytes, publicKeyNiederreiter_t *pk) {
size_t i; for (size_t i = 0; i < N0 - 1; i++) {
for (i = 0; i < N0 - 1; i++) {
PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_tobytes(pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B, PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_tobytes(pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B,
pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT); pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT);
} }
} }
static void unpack_pk(publicKeyNiederreiter_t *pk, const uint8_t *pk_bytes) { static void unpack_pk(publicKeyNiederreiter_t *pk, const uint8_t *pk_bytes) {
size_t i; for (size_t i = 0; i < N0 - 1; i++) {
for (i = 0; i < N0 - 1; i++) {
PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_frombytes(pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT, PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_frombytes(pk->Mtr + i * NUM_DIGITS_GF2X_ELEMENT,
pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B); pk_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B);
} }
} }
static void pack_ct(uint8_t *sk_bytes, DIGIT *ct) { #define pack_ct(sk_bytes, ct) PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_tobytes(sk_bytes, ct);
PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_tobytes(sk_bytes, ct); #define unpack_ct(ct, ct_bytes) PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_frombytes(ct, ct_bytes)
}
static void unpack_ct(DIGIT *ct, const uint8_t *ct_bytes) {
PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_frombytes(ct, ct_bytes);
}
/*
static void pack_error(uint8_t *error_bytes, DIGIT *error_digits) { static void pack_error(uint8_t *error_bytes, DIGIT *error_digits) {
size_t i; size_t i;
for (i = 0; i < N0; i++) { for (i = 0; i < N0; i++) {
PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_tobytes(error_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B, PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_tobytes(error_bytes + i * NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B,
error_digits + i * NUM_DIGITS_GF2X_ELEMENT); error_digits + i * NUM_DIGITS_GF2X_ELEMENT);
} }
} }*/
*/
/* IND-CCA2 Keygen */ /* IND-CCA2 Keygen */
int PQCLEAN_LEDAKEMLT52_LEAKTIME_crypto_kem_keypair(uint8_t *pk, uint8_t *sk) { int PQCLEAN_LEDAKEMLT52_LEAKTIME_crypto_kem_keypair(uint8_t *pk, uint8_t *sk) {
publicKeyNiederreiter_t niederreiter_pk;
PQCLEAN_LEDAKEMLT52_LEAKTIME_niederreiter_keygen((publicKeyNiederreiter_t *) pk, PQCLEAN_LEDAKEMLT52_LEAKTIME_niederreiter_keygen(&niederreiter_pk, (privateKeyNiederreiter_t *) sk);
(privateKeyNiederreiter_t *) sk);
pack_pk(pk, &niederreiter_pk);
return 0; return 0;
} }
/* IND-CCA2 Encapsulation */ /* IND-CCA2 Encapsulation */
int PQCLEAN_LEDAKEMLT52_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const uint8_t *pk) { int PQCLEAN_LEDAKEMLT52_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const uint8_t *pk) {
publicKeyNiederreiter_t niederreiter_pk;
DIGIT syndrome[NUM_DIGITS_GF2X_ELEMENT];
AES_XOF_struct hashedAndTruncatedSeed_expander; AES_XOF_struct hashedAndTruncatedSeed_expander;
POSITION_T errorPos[NUM_ERRORS_T]; POSITION_T errorPos[NUM_ERRORS_T];
DIGIT error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT]; DIGIT error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT];
@ -62,8 +58,11 @@ int PQCLEAN_LEDAKEMLT52_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const
uint8_t hashedAndTruncatedErrorVector[TRNG_BYTE_LENGTH] = {0}; uint8_t hashedAndTruncatedErrorVector[TRNG_BYTE_LENGTH] = {0};
uint8_t maskedSeed[TRNG_BYTE_LENGTH]; uint8_t maskedSeed[TRNG_BYTE_LENGTH];
unpack_pk(&niederreiter_pk, pk);
randombytes(seed, TRNG_BYTE_LENGTH); randombytes(seed, TRNG_BYTE_LENGTH);
memcpy(ss_input, seed, TRNG_BYTE_LENGTH); memcpy(ss_input, seed, TRNG_BYTE_LENGTH);
HASH_FUNCTION(ss, ss_input, 2 * TRNG_BYTE_LENGTH); HASH_FUNCTION(ss, ss_input, 2 * TRNG_BYTE_LENGTH);
HASH_FUNCTION(hashedSeed, seed, TRNG_BYTE_LENGTH); HASH_FUNCTION(hashedSeed, seed, TRNG_BYTE_LENGTH);
@ -78,19 +77,23 @@ int PQCLEAN_LEDAKEMLT52_LEAKTIME_crypto_kem_enc(uint8_t *ct, uint8_t *ss, const
memcpy(hashedAndTruncatedErrorVector, hashedErrorVector, TRNG_BYTE_LENGTH); memcpy(hashedAndTruncatedErrorVector, hashedErrorVector, TRNG_BYTE_LENGTH);
for (int i = 0; i < TRNG_BYTE_LENGTH; ++i) { for (size_t i = 0; i < TRNG_BYTE_LENGTH; ++i) {
maskedSeed[i] = seed[i] ^ hashedAndTruncatedErrorVector[i]; maskedSeed[i] = seed[i] ^ hashedAndTruncatedErrorVector[i];
} }
PQCLEAN_LEDAKEMLT52_LEAKTIME_niederreiter_encrypt((DIGIT *) ct, (const publicKeyNiederreiter_t *)pk, error_vector); PQCLEAN_LEDAKEMLT52_LEAKTIME_niederreiter_encrypt(syndrome,
(const publicKeyNiederreiter_t *) &niederreiter_pk, error_vector);
pack_ct(ct, syndrome);
memcpy(ct + (NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B), maskedSeed, TRNG_BYTE_LENGTH); memcpy(ct + (NUM_DIGITS_GF2X_ELEMENT * DIGIT_SIZE_B), maskedSeed, TRNG_BYTE_LENGTH);
return 0; return 0;
} }
/* INDCCA2 Decapsulation */ /* IND-CCA2 Decapsulation */
int PQCLEAN_LEDAKEMLT52_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct, const uint8_t *sk) { int PQCLEAN_LEDAKEMLT52_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct, const uint8_t *sk) {
DIGIT syndrome[NUM_DIGITS_GF2X_ELEMENT];
AES_XOF_struct hashedAndTruncatedSeed_expander; AES_XOF_struct hashedAndTruncatedSeed_expander;
POSITION_T reconstructed_errorPos[NUM_ERRORS_T]; POSITION_T reconstructed_errorPos[NUM_ERRORS_T];
DIGIT reconstructed_error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT]; DIGIT reconstructed_error_vector[N0 * NUM_DIGITS_GF2X_ELEMENT];
@ -102,9 +105,10 @@ int PQCLEAN_LEDAKEMLT52_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct,
uint8_t hashedAndTruncated_decoded_seed[TRNG_BYTE_LENGTH] = {0}; uint8_t hashedAndTruncated_decoded_seed[TRNG_BYTE_LENGTH] = {0};
uint8_t ss_input[2 * TRNG_BYTE_LENGTH], tail[TRNG_BYTE_LENGTH] = {0}; uint8_t ss_input[2 * TRNG_BYTE_LENGTH], tail[TRNG_BYTE_LENGTH] = {0};
unpack_ct(syndrome, ct);
int decode_ok = PQCLEAN_LEDAKEMLT52_LEAKTIME_niederreiter_decrypt(decoded_error_vector, int decode_ok = PQCLEAN_LEDAKEMLT52_LEAKTIME_niederreiter_decrypt(decoded_error_vector,
(const privateKeyNiederreiter_t *)sk, (const privateKeyNiederreiter_t *)sk, syndrome);
(DIGIT *)ct);
HASH_FUNCTION(hashedErrorVector, HASH_FUNCTION(hashedErrorVector,
(const uint8_t *) decoded_error_vector, (const uint8_t *) decoded_error_vector,
@ -129,7 +133,8 @@ int PQCLEAN_LEDAKEMLT52_LEAKTIME_crypto_kem_dec(uint8_t *ss, const uint8_t *ct,
PQCLEAN_LEDAKEMLT52_LEAKTIME_expand_error(reconstructed_error_vector, reconstructed_errorPos); PQCLEAN_LEDAKEMLT52_LEAKTIME_expand_error(reconstructed_error_vector, reconstructed_errorPos);
int equal = PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_verify(decoded_error_vector, reconstructed_error_vector, N0 * NUM_DIGITS_GF2X_ELEMENT); int equal = PQCLEAN_LEDAKEMLT52_LEAKTIME_gf2x_verify(decoded_error_vector,
reconstructed_error_vector, N0 * NUM_DIGITS_GF2X_ELEMENT);
// equal == 0, if the reconstructed error vector match !!! // equal == 0, if the reconstructed error vector match !!!
int decryptOk = (decode_ok == 1 && equal == 0); int decryptOk = (decode_ok == 1 && equal == 0);