#include "align.h" #include "cbd.h" #include "indcpa.h" #include "ntt.h" #include "params.h" #include "poly.h" #include "polyvec.h" #include "randombytes.h" #include "rejsample.h" #include "symmetric.h" #include #include #include /************************************************* * Name: pack_pk * * Description: Serialize the public key as concatenation of the * serialized vector of polynomials pk and the * public seed used to generate the matrix A. * The polynomial coefficients in pk are assumed to * lie in the invertal [0,q], i.e. pk must be reduced * by PQCLEAN_KYBER102490S_AVX2_polyvec_reduce(). * * Arguments: uint8_t *r: pointer to the output serialized public key * polyvec *pk: pointer to the input public-key polyvec * const uint8_t *seed: pointer to the input public seed **************************************************/ static void pack_pk(uint8_t r[KYBER_INDCPA_PUBLICKEYBYTES], polyvec *pk, const uint8_t seed[KYBER_SYMBYTES]) { size_t i; PQCLEAN_KYBER102490S_AVX2_polyvec_tobytes(r, pk); for (i = 0; i < KYBER_SYMBYTES; i++) { r[i + KYBER_POLYVECBYTES] = seed[i]; } } /************************************************* * Name: unpack_pk * * Description: De-serialize public key from a byte array; * approximate inverse of pack_pk * * Arguments: - polyvec *pk: pointer to output public-key polynomial vector * - uint8_t *seed: pointer to output seed to generate matrix A * - const uint8_t *packedpk: pointer to input serialized public key **************************************************/ static void unpack_pk(polyvec *pk, uint8_t seed[KYBER_SYMBYTES], const uint8_t packedpk[KYBER_INDCPA_PUBLICKEYBYTES]) { size_t i; PQCLEAN_KYBER102490S_AVX2_polyvec_frombytes(pk, packedpk); for (i = 0; i < KYBER_SYMBYTES; i++) { seed[i] = packedpk[i + KYBER_POLYVECBYTES]; } } /************************************************* * Name: pack_sk * * Description: Serialize the secret key. * The polynomial coefficients in sk are assumed to * lie in the invertal [0,q], i.e. sk must be reduced * by PQCLEAN_KYBER102490S_AVX2_polyvec_reduce(). * * Arguments: - uint8_t *r: pointer to output serialized secret key * - polyvec *sk: pointer to input vector of polynomials (secret key) **************************************************/ static void pack_sk(uint8_t r[KYBER_INDCPA_SECRETKEYBYTES], polyvec *sk) { PQCLEAN_KYBER102490S_AVX2_polyvec_tobytes(r, sk); } /************************************************* * Name: unpack_sk * * Description: De-serialize the secret key; inverse of pack_sk * * Arguments: - polyvec *sk: pointer to output vector of polynomials (secret key) * - const uint8_t *packedsk: pointer to input serialized secret key **************************************************/ static void unpack_sk(polyvec *sk, const uint8_t packedsk[KYBER_INDCPA_SECRETKEYBYTES]) { PQCLEAN_KYBER102490S_AVX2_polyvec_frombytes(sk, packedsk); } /************************************************* * Name: pack_ciphertext * * Description: Serialize the ciphertext as concatenation of the * compressed and serialized vector of polynomials b * and the compressed and serialized polynomial v. * The polynomial coefficients in b and v are assumed to * lie in the invertal [0,q], i.e. b and v must be reduced * by PQCLEAN_KYBER102490S_AVX2_polyvec_reduce() and PQCLEAN_KYBER102490S_AVX2_poly_reduce(), respectively. * * Arguments: uint8_t *r: pointer to the output serialized ciphertext * poly *pk: pointer to the input vector of polynomials b * poly *v: pointer to the input polynomial v **************************************************/ static void pack_ciphertext(uint8_t r[KYBER_INDCPA_BYTES], polyvec *b, poly *v) { PQCLEAN_KYBER102490S_AVX2_polyvec_compress(r, b); PQCLEAN_KYBER102490S_AVX2_poly_compress(r + KYBER_POLYVECCOMPRESSEDBYTES, v); } /************************************************* * Name: unpack_ciphertext * * Description: De-serialize and decompress ciphertext from a byte array; * approximate inverse of pack_ciphertext * * Arguments: - polyvec *b: pointer to the output vector of polynomials b * - poly *v: pointer to the output polynomial v * - const uint8_t *c: pointer to the input serialized ciphertext **************************************************/ static void unpack_ciphertext(polyvec *b, poly *v, const uint8_t c[KYBER_INDCPA_BYTES]) { PQCLEAN_KYBER102490S_AVX2_polyvec_decompress(b, c); PQCLEAN_KYBER102490S_AVX2_poly_decompress(v, c + KYBER_POLYVECCOMPRESSEDBYTES); } /************************************************* * Name: rej_uniform * * Description: Run rejection sampling on uniform random bytes to generate * uniform random integers mod q * * Arguments: - int16_t *r: pointer to output array * - unsigned int len: requested number of 16-bit integers (uniform mod q) * - const uint8_t *buf: pointer to input buffer (assumed to be uniformly random bytes) * - unsigned int buflen: length of input buffer in bytes * * Returns number of sampled 16-bit integers (at most len) **************************************************/ static unsigned int rej_uniform(int16_t *r, unsigned int len, const uint8_t *buf, unsigned int buflen) { unsigned int ctr, pos; uint16_t val0, val1; ctr = pos = 0; while (ctr < len && pos + 3 <= buflen) { val0 = ((buf[pos + 0] >> 0) | ((uint16_t)buf[pos + 1] << 8)) & 0xFFF; val1 = ((buf[pos + 1] >> 4) | ((uint16_t)buf[pos + 2] << 4)) & 0xFFF; pos += 3; if (val0 < KYBER_Q) { r[ctr++] = val0; } if (ctr < len && val1 < KYBER_Q) { r[ctr++] = val1; } } return ctr; } #define gen_a(A,B) PQCLEAN_KYBER102490S_AVX2_gen_matrix(A,B,0) #define gen_at(A,B) PQCLEAN_KYBER102490S_AVX2_gen_matrix(A,B,1) /************************************************* * Name: PQCLEAN_KYBER102490S_AVX2_gen_matrix * * Description: Deterministically generate matrix A (or the transpose of A) * from a seed. Entries of the matrix are polynomials that look * uniformly random. Performs rejection sampling on output of * a XOF * * Arguments: - polyvec *a: pointer to ouptput matrix A * - const uint8_t *seed: pointer to input seed * - int transposed: boolean deciding whether A or A^T is generated **************************************************/ void PQCLEAN_KYBER102490S_AVX2_gen_matrix(polyvec *a, const uint8_t seed[32], int transposed) { unsigned int ctr, i, j, k; unsigned int buflen, off; uint64_t nonce = 0; ALIGNED_UINT8(REJ_UNIFORM_AVX_NBLOCKS * AES256CTR_BLOCKBYTES) buf; aes256ctr_ctx state; PQCLEAN_KYBER102490S_AVX2_aes256ctr_init(&state, seed, 0); for (i = 0; i < KYBER_K; i++) { for (j = 0; j < KYBER_K; j++) { if (transposed) { nonce = (j << 8) | i; } else { nonce = (i << 8) | j; } state.n = _mm_loadl_epi64((__m128i *)&nonce); PQCLEAN_KYBER102490S_AVX2_aes256ctr_squeezeblocks(buf.coeffs, REJ_UNIFORM_AVX_NBLOCKS, &state); buflen = REJ_UNIFORM_AVX_NBLOCKS * AES256CTR_BLOCKBYTES; ctr = PQCLEAN_KYBER102490S_AVX2_rej_uniform_avx(a[i].vec[j].coeffs, buf.coeffs); while (ctr < KYBER_N) { off = buflen % 3; for (k = 0; k < off; k++) { buf.coeffs[k] = buf.coeffs[buflen - off + k]; } PQCLEAN_KYBER102490S_AVX2_aes256ctr_squeezeblocks(buf.coeffs + off, 1, &state); buflen = off + AES256CTR_BLOCKBYTES; ctr += rej_uniform(a[i].vec[j].coeffs + ctr, KYBER_N - ctr, buf.coeffs, buflen); } PQCLEAN_KYBER102490S_AVX2_poly_nttunpack(&a[i].vec[j]); } } } /************************************************* * Name: PQCLEAN_KYBER102490S_AVX2_indcpa_keypair * * Description: Generates public and private key for the CPA-secure * public-key encryption scheme underlying Kyber * * Arguments: - uint8_t *pk: pointer to output public key * (of length KYBER_INDCPA_PUBLICKEYBYTES bytes) * - uint8_t *sk: pointer to output private key (of length KYBER_INDCPA_SECRETKEYBYTES bytes) **************************************************/ void PQCLEAN_KYBER102490S_AVX2_indcpa_keypair(uint8_t pk[KYBER_INDCPA_PUBLICKEYBYTES], uint8_t sk[KYBER_INDCPA_SECRETKEYBYTES]) { unsigned int i; uint8_t buf[2 * KYBER_SYMBYTES]; const uint8_t *publicseed = buf; const uint8_t *noiseseed = buf + KYBER_SYMBYTES; polyvec a[KYBER_K], e, pkpv, skpv; randombytes(buf, KYBER_SYMBYTES); hash_g(buf, buf, KYBER_SYMBYTES); gen_a(a, publicseed); #define NOISE_NBLOCKS ((KYBER_ETA1*KYBER_N/4)/AES256CTR_BLOCKBYTES) /* Assumes divisibility */ uint64_t nonce = 0; ALIGNED_UINT8(NOISE_NBLOCKS * AES256CTR_BLOCKBYTES + 32) coins; // +32 bytes as required by PQCLEAN_KYBER102490S_AVX2_poly_cbd_eta1 aes256ctr_ctx state; PQCLEAN_KYBER102490S_AVX2_aes256ctr_init(&state, noiseseed, nonce++); for (i = 0; i < KYBER_K; i++) { PQCLEAN_KYBER102490S_AVX2_aes256ctr_squeezeblocks(coins.coeffs, NOISE_NBLOCKS, &state); state.n = _mm_loadl_epi64((__m128i *)&nonce); nonce += 1; PQCLEAN_KYBER102490S_AVX2_poly_cbd_eta1(&skpv.vec[i], coins.vec); } for (i = 0; i < KYBER_K; i++) { PQCLEAN_KYBER102490S_AVX2_aes256ctr_squeezeblocks(coins.coeffs, NOISE_NBLOCKS, &state); state.n = _mm_loadl_epi64((__m128i *)&nonce); nonce += 1; PQCLEAN_KYBER102490S_AVX2_poly_cbd_eta1(&e.vec[i], coins.vec); } PQCLEAN_KYBER102490S_AVX2_polyvec_ntt(&skpv); PQCLEAN_KYBER102490S_AVX2_polyvec_reduce(&skpv); PQCLEAN_KYBER102490S_AVX2_polyvec_ntt(&e); // matrix-vector multiplication for (i = 0; i < KYBER_K; i++) { PQCLEAN_KYBER102490S_AVX2_polyvec_basemul_acc_montgomery(&pkpv.vec[i], &a[i], &skpv); PQCLEAN_KYBER102490S_AVX2_poly_tomont(&pkpv.vec[i]); } PQCLEAN_KYBER102490S_AVX2_polyvec_add(&pkpv, &pkpv, &e); PQCLEAN_KYBER102490S_AVX2_polyvec_reduce(&pkpv); pack_sk(sk, &skpv); pack_pk(pk, &pkpv, publicseed); } /************************************************* * Name: PQCLEAN_KYBER102490S_AVX2_indcpa_enc * * Description: Encryption function of the CPA-secure * public-key encryption scheme underlying Kyber. * * Arguments: - uint8_t *c: pointer to output ciphertext * (of length KYBER_INDCPA_BYTES bytes) * - const uint8_t *m: pointer to input message * (of length KYBER_INDCPA_MSGBYTES bytes) * - const uint8_t *pk: pointer to input public key * (of length KYBER_INDCPA_PUBLICKEYBYTES) * - const uint8_t *coins: pointer to input random coins used as seed * (of length KYBER_SYMBYTES) to deterministically * generate all randomness **************************************************/ void PQCLEAN_KYBER102490S_AVX2_indcpa_enc(uint8_t c[KYBER_INDCPA_BYTES], const uint8_t m[KYBER_INDCPA_MSGBYTES], const uint8_t pk[KYBER_INDCPA_PUBLICKEYBYTES], const uint8_t coins[KYBER_SYMBYTES]) { unsigned int i; uint8_t seed[KYBER_SYMBYTES]; polyvec sp, pkpv, ep, at[KYBER_K], b; poly v, k, epp; unpack_pk(&pkpv, seed, pk); PQCLEAN_KYBER102490S_AVX2_poly_frommsg(&k, m); gen_at(at, seed); #define NOISE_NBLOCKS ((KYBER_ETA1*KYBER_N/4)/AES256CTR_BLOCKBYTES) /* Assumes divisibility */ #define CIPHERTEXTNOISE_NBLOCKS ((KYBER_ETA2*KYBER_N/4)/AES256CTR_BLOCKBYTES) /* Assumes divisibility */ uint64_t nonce = 0; ALIGNED_UINT8(NOISE_NBLOCKS * AES256CTR_BLOCKBYTES + 32) buf; /* +32 bytes as required by PQCLEAN_KYBER102490S_AVX2_poly_cbd_eta1 */ aes256ctr_ctx state; PQCLEAN_KYBER102490S_AVX2_aes256ctr_init(&state, coins, nonce++); for (i = 0; i < KYBER_K; i++) { PQCLEAN_KYBER102490S_AVX2_aes256ctr_squeezeblocks(buf.coeffs, NOISE_NBLOCKS, &state); state.n = _mm_loadl_epi64((__m128i *)&nonce); nonce += 1; PQCLEAN_KYBER102490S_AVX2_poly_cbd_eta1(&sp.vec[i], buf.vec); } for (i = 0; i < KYBER_K; i++) { PQCLEAN_KYBER102490S_AVX2_aes256ctr_squeezeblocks(buf.coeffs, CIPHERTEXTNOISE_NBLOCKS, &state); state.n = _mm_loadl_epi64((__m128i *)&nonce); nonce += 1; PQCLEAN_KYBER102490S_AVX2_poly_cbd_eta2(&ep.vec[i], buf.vec); } PQCLEAN_KYBER102490S_AVX2_aes256ctr_squeezeblocks(buf.coeffs, CIPHERTEXTNOISE_NBLOCKS, &state); state.n = _mm_loadl_epi64((__m128i *)&nonce); nonce += 1; PQCLEAN_KYBER102490S_AVX2_poly_cbd_eta2(&epp, buf.vec); PQCLEAN_KYBER102490S_AVX2_polyvec_ntt(&sp); // matrix-vector multiplication for (i = 0; i < KYBER_K; i++) { PQCLEAN_KYBER102490S_AVX2_polyvec_basemul_acc_montgomery(&b.vec[i], &at[i], &sp); } PQCLEAN_KYBER102490S_AVX2_polyvec_basemul_acc_montgomery(&v, &pkpv, &sp); PQCLEAN_KYBER102490S_AVX2_polyvec_invntt_tomont(&b); PQCLEAN_KYBER102490S_AVX2_poly_invntt_tomont(&v); PQCLEAN_KYBER102490S_AVX2_polyvec_add(&b, &b, &ep); PQCLEAN_KYBER102490S_AVX2_poly_add(&v, &v, &epp); PQCLEAN_KYBER102490S_AVX2_poly_add(&v, &v, &k); PQCLEAN_KYBER102490S_AVX2_polyvec_reduce(&b); PQCLEAN_KYBER102490S_AVX2_poly_reduce(&v); pack_ciphertext(c, &b, &v); } /************************************************* * Name: PQCLEAN_KYBER102490S_AVX2_indcpa_dec * * Description: Decryption function of the CPA-secure * public-key encryption scheme underlying Kyber. * * Arguments: - uint8_t *m: pointer to output decrypted message * (of length KYBER_INDCPA_MSGBYTES) * - const uint8_t *c: pointer to input ciphertext * (of length KYBER_INDCPA_BYTES) * - const uint8_t *sk: pointer to input secret key * (of length KYBER_INDCPA_SECRETKEYBYTES) **************************************************/ void PQCLEAN_KYBER102490S_AVX2_indcpa_dec(uint8_t m[KYBER_INDCPA_MSGBYTES], const uint8_t c[KYBER_INDCPA_BYTES], const uint8_t sk[KYBER_INDCPA_SECRETKEYBYTES]) { polyvec b, skpv; poly v, mp; unpack_ciphertext(&b, &v, c); unpack_sk(&skpv, sk); PQCLEAN_KYBER102490S_AVX2_polyvec_ntt(&b); PQCLEAN_KYBER102490S_AVX2_polyvec_basemul_acc_montgomery(&mp, &skpv, &b); PQCLEAN_KYBER102490S_AVX2_poly_invntt_tomont(&mp); PQCLEAN_KYBER102490S_AVX2_poly_sub(&mp, &v, &mp); PQCLEAN_KYBER102490S_AVX2_poly_reduce(&mp); PQCLEAN_KYBER102490S_AVX2_poly_tomsg(m, &mp); }