#include "aes256ctr.h" #include "align.h" #include "fips202.h" #include "packing.h" #include "params.h" #include "poly.h" #include "polyvec.h" #include "randombytes.h" #include "sign.h" #include "symmetric.h" #include #include /************************************************* * Name: PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign_keypair * * Description: Generates public and private key. * * Arguments: - uint8_t *pk: pointer to output public key (allocated * array of PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_PUBLICKEYBYTES bytes) * - uint8_t *sk: pointer to output private key (allocated * array of PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_SECRETKEYBYTES bytes) * * Returns 0 (success) **************************************************/ int PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign_keypair(uint8_t *pk, uint8_t *sk) { unsigned int i; uint8_t seedbuf[2 * SEEDBYTES + CRHBYTES]; const uint8_t *rho, *rhoprime, *key; uint64_t nonce; aes256ctr_ctx aesctx; polyvecl rowbuf[1]; polyvecl s1, *row = rowbuf; polyveck s2; poly t1, t0; /* Get randomness for rho, rhoprime and key */ randombytes(seedbuf, SEEDBYTES); shake256(seedbuf, 2 * SEEDBYTES + CRHBYTES, seedbuf, SEEDBYTES); rho = seedbuf; rhoprime = rho + SEEDBYTES; key = rhoprime + CRHBYTES; /* Store rho, key */ memcpy(pk, rho, SEEDBYTES); memcpy(sk, rho, SEEDBYTES); memcpy(sk + SEEDBYTES, key, SEEDBYTES); /* Sample short vectors s1 and s2 */ PQCLEAN_DILITHIUM3AES_AVX2_aes256ctr_init(&aesctx, rhoprime, 0); for (i = 0; i < L; ++i) { nonce = i; aesctx.n = _mm_loadl_epi64((__m128i *)&nonce); PQCLEAN_DILITHIUM3AES_AVX2_poly_uniform_eta_preinit(&s1.vec[i], &aesctx); } for (i = 0; i < K; ++i) { nonce = L + i; aesctx.n = _mm_loadl_epi64((__m128i *)&nonce); PQCLEAN_DILITHIUM3AES_AVX2_poly_uniform_eta_preinit(&s2.vec[i], &aesctx); } /* Pack secret vectors */ for (i = 0; i < L; i++) { PQCLEAN_DILITHIUM3AES_AVX2_polyeta_pack(sk + 3 * SEEDBYTES + i * POLYETA_PACKEDBYTES, &s1.vec[i]); } for (i = 0; i < K; i++) { PQCLEAN_DILITHIUM3AES_AVX2_polyeta_pack(sk + 3 * SEEDBYTES + (L + i)*POLYETA_PACKEDBYTES, &s2.vec[i]); } /* Transform s1 */ PQCLEAN_DILITHIUM3AES_AVX2_polyvecl_ntt(&s1); PQCLEAN_DILITHIUM3AES_AVX2_aes256ctr_init(&aesctx, rho, 0); for (i = 0; i < K; i++) { /* Expand matrix row */ for (unsigned int j = 0; j < L; j++) { nonce = (i << 8) + j; aesctx.n = _mm_loadl_epi64((__m128i *)&nonce); PQCLEAN_DILITHIUM3AES_AVX2_poly_uniform_preinit(&row->vec[j], &aesctx); PQCLEAN_DILITHIUM3AES_AVX2_poly_nttunpack(&row->vec[j]); } /* Compute inner-product */ PQCLEAN_DILITHIUM3AES_AVX2_polyvecl_pointwise_acc_montgomery(&t1, row, &s1); PQCLEAN_DILITHIUM3AES_AVX2_poly_invntt_tomont(&t1); /* Add error polynomial */ PQCLEAN_DILITHIUM3AES_AVX2_poly_add(&t1, &t1, &s2.vec[i]); /* Round t and pack t1, t0 */ PQCLEAN_DILITHIUM3AES_AVX2_poly_caddq(&t1); PQCLEAN_DILITHIUM3AES_AVX2_poly_power2round(&t1, &t0, &t1); PQCLEAN_DILITHIUM3AES_AVX2_polyt1_pack(pk + SEEDBYTES + i * POLYT1_PACKEDBYTES, &t1); PQCLEAN_DILITHIUM3AES_AVX2_polyt0_pack(sk + 3 * SEEDBYTES + (L + K)*POLYETA_PACKEDBYTES + i * POLYT0_PACKEDBYTES, &t0); } /* Compute H(rho, t1) and store in secret key */ shake256(sk + 2 * SEEDBYTES, SEEDBYTES, pk, PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_PUBLICKEYBYTES); return 0; } /************************************************* * Name: PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign_signature * * Description: Computes signature. * * Arguments: - uint8_t *sig: pointer to output signature (of length PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_BYTES) * - size_t *siglen: pointer to output length of signature * - uint8_t *m: pointer to message to be signed * - size_t mlen: length of message * - uint8_t *sk: pointer to bit-packed secret key * * Returns 0 (success) **************************************************/ int PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign_signature(uint8_t *sig, size_t *siglen, const uint8_t *m, size_t mlen, const uint8_t *sk) { unsigned int i, n, pos; uint8_t seedbuf[3 * SEEDBYTES + 2 * CRHBYTES]; uint8_t *rho, *tr, *key, *mu, *rhoprime; uint8_t hintbuf[N]; uint8_t *hint = sig + SEEDBYTES + L * POLYZ_PACKEDBYTES; uint64_t nonce = 0; polyvecl mat[K], s1, z; polyveck t0, s2, w1; poly c, tmp; union { polyvecl y; polyveck w0; } tmpv; shake256incctx state; rho = seedbuf; tr = rho + SEEDBYTES; key = tr + SEEDBYTES; mu = key + SEEDBYTES; rhoprime = mu + CRHBYTES; PQCLEAN_DILITHIUM3AES_AVX2_unpack_sk(rho, tr, key, &t0, &s1, &s2, sk); /* Compute CRH(tr, msg) */ shake256_inc_init(&state); shake256_inc_absorb(&state, tr, SEEDBYTES); shake256_inc_absorb(&state, m, mlen); shake256_inc_finalize(&state); shake256_inc_squeeze(mu, CRHBYTES, &state); shake256_inc_ctx_release(&state); shake256(rhoprime, CRHBYTES, key, SEEDBYTES + CRHBYTES); /* Expand matrix and transform vectors */ PQCLEAN_DILITHIUM3AES_AVX2_polyvec_matrix_expand(mat, rho); PQCLEAN_DILITHIUM3AES_AVX2_polyvecl_ntt(&s1); PQCLEAN_DILITHIUM3AES_AVX2_polyveck_ntt(&s2); PQCLEAN_DILITHIUM3AES_AVX2_polyveck_ntt(&t0); aes256ctr_ctx aesctx; PQCLEAN_DILITHIUM3AES_AVX2_aes256ctr_init(&aesctx, rhoprime, 0); rej: /* Sample intermediate vector y */ for (i = 0; i < L; ++i) { aesctx.n = _mm_loadl_epi64((__m128i *)&nonce); nonce++; PQCLEAN_DILITHIUM3AES_AVX2_poly_uniform_gamma1_preinit(&z.vec[i], &aesctx); } /* Matrix-vector product */ tmpv.y = z; PQCLEAN_DILITHIUM3AES_AVX2_polyvecl_ntt(&tmpv.y); PQCLEAN_DILITHIUM3AES_AVX2_polyvec_matrix_pointwise_montgomery(&w1, mat, &tmpv.y); PQCLEAN_DILITHIUM3AES_AVX2_polyveck_invntt_tomont(&w1); /* Decompose w and call the random oracle */ PQCLEAN_DILITHIUM3AES_AVX2_polyveck_caddq(&w1); PQCLEAN_DILITHIUM3AES_AVX2_polyveck_decompose(&w1, &tmpv.w0, &w1); PQCLEAN_DILITHIUM3AES_AVX2_polyveck_pack_w1(sig, &w1); shake256_inc_init(&state); shake256_inc_absorb(&state, mu, CRHBYTES); shake256_inc_absorb(&state, sig, K * POLYW1_PACKEDBYTES); shake256_inc_finalize(&state); shake256_inc_squeeze(sig, SEEDBYTES, &state); shake256_inc_ctx_release(&state); PQCLEAN_DILITHIUM3AES_AVX2_poly_challenge(&c, sig); PQCLEAN_DILITHIUM3AES_AVX2_poly_ntt(&c); /* Compute z, reject if it reveals secret */ for (i = 0; i < L; i++) { PQCLEAN_DILITHIUM3AES_AVX2_poly_pointwise_montgomery(&tmp, &c, &s1.vec[i]); PQCLEAN_DILITHIUM3AES_AVX2_poly_invntt_tomont(&tmp); PQCLEAN_DILITHIUM3AES_AVX2_poly_add(&z.vec[i], &z.vec[i], &tmp); PQCLEAN_DILITHIUM3AES_AVX2_poly_reduce(&z.vec[i]); if (PQCLEAN_DILITHIUM3AES_AVX2_poly_chknorm(&z.vec[i], GAMMA1 - BETA)) { goto rej; } } /* Zero hint vector in signature */ pos = 0; memset(hint, 0, OMEGA); for (i = 0; i < K; i++) { /* Check that subtracting cs2 does not change high bits of w and low bits * do not reveal secret information */ PQCLEAN_DILITHIUM3AES_AVX2_poly_pointwise_montgomery(&tmp, &c, &s2.vec[i]); PQCLEAN_DILITHIUM3AES_AVX2_poly_invntt_tomont(&tmp); PQCLEAN_DILITHIUM3AES_AVX2_poly_sub(&tmpv.w0.vec[i], &tmpv.w0.vec[i], &tmp); PQCLEAN_DILITHIUM3AES_AVX2_poly_reduce(&tmpv.w0.vec[i]); if (PQCLEAN_DILITHIUM3AES_AVX2_poly_chknorm(&tmpv.w0.vec[i], GAMMA2 - BETA)) { goto rej; } /* Compute hints */ PQCLEAN_DILITHIUM3AES_AVX2_poly_pointwise_montgomery(&tmp, &c, &t0.vec[i]); PQCLEAN_DILITHIUM3AES_AVX2_poly_invntt_tomont(&tmp); PQCLEAN_DILITHIUM3AES_AVX2_poly_reduce(&tmp); if (PQCLEAN_DILITHIUM3AES_AVX2_poly_chknorm(&tmp, GAMMA2)) { goto rej; } PQCLEAN_DILITHIUM3AES_AVX2_poly_add(&tmpv.w0.vec[i], &tmpv.w0.vec[i], &tmp); n = PQCLEAN_DILITHIUM3AES_AVX2_poly_make_hint(hintbuf, &tmpv.w0.vec[i], &w1.vec[i]); if (pos + n > OMEGA) { goto rej; } /* Store hints in signature */ memcpy(&hint[pos], hintbuf, n); hint[OMEGA + i] = pos = pos + n; } /* Pack z into signature */ for (i = 0; i < L; i++) { PQCLEAN_DILITHIUM3AES_AVX2_polyz_pack(sig + SEEDBYTES + i * POLYZ_PACKEDBYTES, &z.vec[i]); } *siglen = PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_BYTES; return 0; } /************************************************* * Name: PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign * * Description: Compute signed message. * * Arguments: - uint8_t *sm: pointer to output signed message (allocated * array with PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_BYTES + mlen bytes), * can be equal to m * - size_t *smlen: pointer to output length of signed * message * - const uint8_t *m: pointer to message to be signed * - size_t mlen: length of message * - const uint8_t *sk: pointer to bit-packed secret key * * Returns 0 (success) **************************************************/ int PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign(uint8_t *sm, size_t *smlen, const uint8_t *m, size_t mlen, const uint8_t *sk) { size_t i; for (i = 0; i < mlen; ++i) { sm[PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_BYTES + mlen - 1 - i] = m[mlen - 1 - i]; } PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign_signature(sm, smlen, sm + PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_BYTES, mlen, sk); *smlen += mlen; return 0; } /************************************************* * Name: PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign_verify * * Description: Verifies signature. * * Arguments: - uint8_t *m: pointer to input signature * - size_t siglen: length of signature * - const uint8_t *m: pointer to message * - size_t mlen: length of message * - const uint8_t *pk: pointer to bit-packed public key * * Returns 0 if signature could be verified correctly and -1 otherwise **************************************************/ int PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign_verify(const uint8_t *sig, size_t siglen, const uint8_t *m, size_t mlen, const uint8_t *pk) { unsigned int i, j, pos = 0; /* PQCLEAN_DILITHIUM3AES_AVX2_polyw1_pack writes additional 14 bytes */ ALIGNED_UINT8(K * POLYW1_PACKEDBYTES + 14) buf; uint8_t mu[CRHBYTES]; const uint8_t *hint = sig + SEEDBYTES + L * POLYZ_PACKEDBYTES; uint64_t nonce; aes256ctr_ctx aesctx; polyvecl rowbuf[1]; polyvecl *row = rowbuf; polyvecl z; poly c, w1, h; shake256incctx state; if (siglen != PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_BYTES) { return -1; } /* Compute CRH(H(rho, t1), msg) */ shake256(mu, SEEDBYTES, pk, PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_PUBLICKEYBYTES); shake256_inc_init(&state); shake256_inc_absorb(&state, mu, SEEDBYTES); shake256_inc_absorb(&state, m, mlen); shake256_inc_finalize(&state); shake256_inc_squeeze(mu, CRHBYTES, &state); shake256_inc_ctx_release(&state); /* Expand PQCLEAN_DILITHIUM3AES_AVX2_challenge */ PQCLEAN_DILITHIUM3AES_AVX2_poly_challenge(&c, sig); PQCLEAN_DILITHIUM3AES_AVX2_poly_ntt(&c); /* Unpack z; shortness follows from unpacking */ for (i = 0; i < L; i++) { PQCLEAN_DILITHIUM3AES_AVX2_polyz_unpack(&z.vec[i], sig + SEEDBYTES + i * POLYZ_PACKEDBYTES); PQCLEAN_DILITHIUM3AES_AVX2_poly_ntt(&z.vec[i]); } PQCLEAN_DILITHIUM3AES_AVX2_aes256ctr_init(&aesctx, pk, 0); for (i = 0; i < K; i++) { /* Expand matrix row */ for (j = 0; j < L; j++) { nonce = (i << 8) + j; aesctx.n = _mm_loadl_epi64((__m128i *)&nonce); PQCLEAN_DILITHIUM3AES_AVX2_poly_uniform_preinit(&row->vec[j], &aesctx); PQCLEAN_DILITHIUM3AES_AVX2_poly_nttunpack(&row->vec[j]); } /* Compute i-th row of Az - c2^Dt1 */ PQCLEAN_DILITHIUM3AES_AVX2_polyvecl_pointwise_acc_montgomery(&w1, row, &z); PQCLEAN_DILITHIUM3AES_AVX2_polyt1_unpack(&h, pk + SEEDBYTES + i * POLYT1_PACKEDBYTES); PQCLEAN_DILITHIUM3AES_AVX2_poly_shiftl(&h); PQCLEAN_DILITHIUM3AES_AVX2_poly_ntt(&h); PQCLEAN_DILITHIUM3AES_AVX2_poly_pointwise_montgomery(&h, &c, &h); PQCLEAN_DILITHIUM3AES_AVX2_poly_sub(&w1, &w1, &h); PQCLEAN_DILITHIUM3AES_AVX2_poly_reduce(&w1); PQCLEAN_DILITHIUM3AES_AVX2_poly_invntt_tomont(&w1); /* Get hint polynomial and reconstruct w1 */ memset(h.vec, 0, sizeof(poly)); if (hint[OMEGA + i] < pos || hint[OMEGA + i] > OMEGA) { return -1; } for (j = pos; j < hint[OMEGA + i]; ++j) { /* Coefficients are ordered for strong unforgeability */ if (j > pos && hint[j] <= hint[j - 1]) { return -1; } h.coeffs[hint[j]] = 1; } pos = hint[OMEGA + i]; PQCLEAN_DILITHIUM3AES_AVX2_poly_caddq(&w1); PQCLEAN_DILITHIUM3AES_AVX2_poly_use_hint(&w1, &w1, &h); PQCLEAN_DILITHIUM3AES_AVX2_polyw1_pack(buf.coeffs + i * POLYW1_PACKEDBYTES, &w1); } /* Extra indices are zero for strong unforgeability */ for (j = pos; j < OMEGA; ++j) { if (hint[j]) { return -1; } } /* Call random oracle and verify PQCLEAN_DILITHIUM3AES_AVX2_challenge */ shake256_inc_init(&state); shake256_inc_absorb(&state, mu, CRHBYTES); shake256_inc_absorb(&state, buf.coeffs, K * POLYW1_PACKEDBYTES); shake256_inc_finalize(&state); shake256_inc_squeeze(buf.coeffs, SEEDBYTES, &state); shake256_inc_ctx_release(&state); for (i = 0; i < SEEDBYTES; ++i) { if (buf.coeffs[i] != sig[i]) { return -1; } } return 0; } /************************************************* * Name: PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign_open * * Description: Verify signed message. * * Arguments: - uint8_t *m: pointer to output message (allocated * array with smlen bytes), can be equal to sm * - size_t *mlen: pointer to output length of message * - const uint8_t *sm: pointer to signed message * - size_t smlen: length of signed message * - const uint8_t *pk: pointer to bit-packed public key * * Returns 0 if signed message could be verified correctly and -1 otherwise **************************************************/ int PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign_open(uint8_t *m, size_t *mlen, const uint8_t *sm, size_t smlen, const uint8_t *pk) { size_t i; if (smlen < PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_BYTES) { goto badsig; } *mlen = smlen - PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_BYTES; if (PQCLEAN_DILITHIUM3AES_AVX2_crypto_sign_verify(sm, PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_BYTES, sm + PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_BYTES, *mlen, pk)) { goto badsig; } else { /* All good, copy msg, return 0 */ for (i = 0; i < *mlen; ++i) { m[i] = sm[PQCLEAN_DILITHIUM3AES_AVX2_CRYPTO_BYTES + i]; } return 0; } badsig: /* Signature verification failed */ *mlen = -1; for (i = 0; i < smlen; ++i) { m[i] = 0; } return -1; }