pqc/crypto_kem/newhope512cca/clean/kem.c
Ko- 4883f2ce89 Add domain separation to NewHope
NewHope announced a new version of their specification that adds
explicit domain separation. This is a port of
https://github.com/newhopecrypto/newhope/commit/607a9d3
2020-05-29 16:41:41 +02:00

120 lines
5.8 KiB
C

#include "api.h"
#include "cpapke.h"
#include "fips202.h"
#include "params.h"
#include "randombytes.h"
#include "verify.h"
#include <string.h>
/*************************************************
* Name: crypto_kem_keypair
*
* Description: Generates public and private key
* for CCA secure NewHope key encapsulation
* mechanism
*
* Arguments: - unsigned char *pk: pointer to output public key (an already allocated array of CRYPTO_PUBLICKEYBYTES bytes)
* - unsigned char *sk: pointer to output private key (an already allocated array of CRYPTO_SECRETKEYBYTES bytes)
*
* Returns 0 (success)
**************************************************/
int PQCLEAN_NEWHOPE512CCA_CLEAN_crypto_kem_keypair(unsigned char *pk, unsigned char *sk) {
size_t i;
PQCLEAN_NEWHOPE512CCA_CLEAN_cpapke_keypair(pk, sk); /* First put the actual secret key into sk */
sk += NEWHOPE_CPAPKE_SECRETKEYBYTES;
for (i = 0; i < NEWHOPE_CPAPKE_PUBLICKEYBYTES; i++) { /* Append the public key for re-encryption */
sk[i] = pk[i];
}
sk += NEWHOPE_CPAPKE_PUBLICKEYBYTES;
shake256(sk, NEWHOPE_SYMBYTES, pk, NEWHOPE_CPAPKE_PUBLICKEYBYTES); /* Append the hash of the public key */
sk += NEWHOPE_SYMBYTES;
randombytes(sk, NEWHOPE_SYMBYTES); /* Append the value s for pseudo-random output on reject */
return 0;
}
/*************************************************
* Name: crypto_kem_enc
*
* Description: Generates cipher text and shared
* secret for given public key
*
* Arguments: - unsigned char *ct: pointer to output cipher text (an already allocated array of CRYPTO_CIPHERTEXTBYTES bytes)
* - unsigned char *ss: pointer to output shared secret (an already allocated array of CRYPTO_BYTES bytes)
* - const unsigned char *pk: pointer to input public key (an already allocated array of CRYPTO_PUBLICKEYBYTES bytes)
*
* Returns 0 (success)
**************************************************/
int PQCLEAN_NEWHOPE512CCA_CLEAN_crypto_kem_enc(unsigned char *ct, unsigned char *ss, const unsigned char *pk) {
unsigned char k_coins_d[3 * NEWHOPE_SYMBYTES]; /* Will contain key, coins, qrom-hash */
unsigned char buf[2 * NEWHOPE_SYMBYTES + 1];
int i;
buf[0] = 0x04;
randombytes(buf + 1, NEWHOPE_SYMBYTES);
shake256(buf + 1, NEWHOPE_SYMBYTES, buf, NEWHOPE_SYMBYTES + 1); /* Don't release system RNG output */
shake256(buf + 1 + NEWHOPE_SYMBYTES, NEWHOPE_SYMBYTES, pk, NEWHOPE_CCAKEM_PUBLICKEYBYTES); /* Multitarget countermeasure for coins + contributory KEM */
buf[0] = 0x08;
shake256(k_coins_d, 3 * NEWHOPE_SYMBYTES, buf, 2 * NEWHOPE_SYMBYTES + 1);
PQCLEAN_NEWHOPE512CCA_CLEAN_cpapke_enc(ct, buf + 1, pk, k_coins_d + NEWHOPE_SYMBYTES); /* coins are in k_coins_d+NEWHOPE_SYMBYTES */
for (i = 0; i < NEWHOPE_SYMBYTES; i++) {
ct[i + NEWHOPE_CPAPKE_CIPHERTEXTBYTES] = k_coins_d[i + 2 * NEWHOPE_SYMBYTES]; /* copy Targhi-Unruh hash into ct */
}
shake256(k_coins_d + NEWHOPE_SYMBYTES, NEWHOPE_SYMBYTES, ct, NEWHOPE_CCAKEM_CIPHERTEXTBYTES); /* overwrite coins in k_coins_d with h(c) */
shake256(ss, NEWHOPE_SYMBYTES, k_coins_d, 2 * NEWHOPE_SYMBYTES); /* hash concatenation of pre-k and h(c) to ss */
return 0;
}
/*************************************************
* Name: crypto_kem_dec
*
* Description: Generates shared secret for given
* cipher text and private key
*
* Arguments: - unsigned char *ss: pointer to output shared secret (an already allocated array of CRYPTO_BYTES bytes)
* - const unsigned char *ct: pointer to input cipher text (an already allocated array of CRYPTO_CIPHERTEXTBYTES bytes)
* - const unsigned char *sk: pointer to input private key (an already allocated array of CRYPTO_SECRETKEYBYTES bytes)
*
* Returns 0 for sucess or -1 for failure
*
* On failure, ss will contain a randomized value.
**************************************************/
int PQCLEAN_NEWHOPE512CCA_CLEAN_crypto_kem_dec(unsigned char *ss, const unsigned char *ct, const unsigned char *sk) {
int i, fail;
unsigned char ct_cmp[NEWHOPE_CCAKEM_CIPHERTEXTBYTES];
unsigned char buf[2 * NEWHOPE_SYMBYTES + 1];
unsigned char k_coins_d[3 * NEWHOPE_SYMBYTES]; /* Will contain key, coins, qrom-hash */
const unsigned char *pk = sk + NEWHOPE_CPAPKE_SECRETKEYBYTES;
buf[0] = 0x08;
PQCLEAN_NEWHOPE512CCA_CLEAN_cpapke_dec(buf + 1, ct, sk);
for (i = 0; i < NEWHOPE_SYMBYTES; i++) { /* Use hash of pk stored in sk */
buf[1 + NEWHOPE_SYMBYTES + i] = sk[NEWHOPE_CCAKEM_SECRETKEYBYTES - 2 * NEWHOPE_SYMBYTES + i];
}
shake256(k_coins_d, 3 * NEWHOPE_SYMBYTES, buf, 2 * NEWHOPE_SYMBYTES + 1);
PQCLEAN_NEWHOPE512CCA_CLEAN_cpapke_enc(ct_cmp, buf + 1, pk, k_coins_d + NEWHOPE_SYMBYTES); /* coins are in k_coins_d+NEWHOPE_SYMBYTES */
for (i = 0; i < NEWHOPE_SYMBYTES; i++) {
ct_cmp[i + NEWHOPE_CPAPKE_CIPHERTEXTBYTES] = k_coins_d[i + 2 * NEWHOPE_SYMBYTES];
}
fail = PQCLEAN_NEWHOPE512CCA_CLEAN_verify(ct, ct_cmp, NEWHOPE_CCAKEM_CIPHERTEXTBYTES);
shake256(k_coins_d + NEWHOPE_SYMBYTES, NEWHOPE_SYMBYTES, ct, NEWHOPE_CCAKEM_CIPHERTEXTBYTES); /* overwrite coins in k_coins_d with h(c) */
PQCLEAN_NEWHOPE512CCA_CLEAN_cmov(k_coins_d, sk + NEWHOPE_CCAKEM_SECRETKEYBYTES - NEWHOPE_SYMBYTES, NEWHOPE_SYMBYTES, (unsigned char) fail); /* Overwrite pre-k with z on re-encryption failure */
shake256(ss, NEWHOPE_SYMBYTES, k_coins_d, 2 * NEWHOPE_SYMBYTES); /* hash concatenation of pre-k and h(c) to k */
return 0;
}