/* * Copyright (C) 2017 - This file is part of libecc project * * Authors: * Ryad BENADJILA * Arnaud EBALARD * Jean-Pierre FLORI * * Contributors: * Nicolas VIVET * Karim KHALFALLAH * * This software is licensed under a dual BSD and GPL v2 license. * See LICENSE file at the root folder of the project. */ #include #if defined(WITH_SIG_ECRDSA) && defined(USE_CRYPTOFUZZ) #include #include #include #include #include #include #ifdef VERBOSE_INNER_VALUES #define EC_SIG_ALG "ECRDSA" #endif #include /* NOTE: the following versions of ECRDSA are "raw" with * no hash functions and nonce override. They are DANGEROUS and * should NOT be used in production mode! They are however useful * for corner cases tests and fuzzing. */ /* * NOTE: ISO/IEC 14888-3 standard seems to diverge from the existing implementations * of ECRDSA when treating the message hash, and from the examples of certificates provided * in RFC 7091 and draft-deremin-rfc4491-bis. While in ISO/IEC 14888-3 it is explicitely asked * to proceed with the hash of the message as big endian, the RFCs derived from the Russian * standard expect the hash value to be treated as little endian when importing it as an integer * (this discrepancy is exhibited and confirmed by test vectors present in ISO/IEC 14888-3, and * by X.509 certificates present in the RFCs). This seems (to be confirmed) to be a discrepancy of * ISO/IEC 14888-3 algorithm description that must be fixed there. * * In order to be conservative, libecc uses the Russian standard behavior as expected to be in line with * other implemetations, but keeps the ISO/IEC 14888-3 behavior if forced/asked by the user using * the USE_ISO14888_3_ECRDSA toggle. This allows to keep backward compatibility with previous versions of the * library if needed. * */ #ifndef USE_ISO14888_3_ECRDSA /* Reverses the endiannes of a buffer in place */ ATTRIBUTE_WARN_UNUSED_RET static inline int _reverse_endianness(u8 *buf, u16 buf_size) { u16 i; u8 tmp; int ret; MUST_HAVE((buf != NULL), ret, err); if(buf_size > 1){ for(i = 0; i < (buf_size / 2); i++){ tmp = buf[i]; buf[i] = buf[buf_size - 1 - i]; buf[buf_size - 1 - i] = tmp; } } ret = 0; err: return ret; } #endif #define ECRDSA_SIGN_MAGIC ((word_t)(0xcc97bbc8ada8973cULL)) #define ECRDSA_SIGN_CHECK_INITIALIZED(A, ret, err) \ MUST_HAVE((((const void *)(A)) != NULL) && \ ((A)->magic == ECRDSA_SIGN_MAGIC), ret, err) int ecrdsa_sign_raw(struct ec_sign_context *ctx, const u8 *input, u8 inputlen, u8 *sig, u8 siglen, const u8 *nonce, u8 noncelen) { bitcnt_t q_bit_len, p_bit_len; const ec_priv_key *priv_key; /* NOTE: hash here is not really a hash ... */ u8 h_buf[LOCAL_MIN(255, BIT_LEN_WORDS(NN_MAX_BIT_LEN) * (WORDSIZE / 8))]; prj_pt_src_t G; prj_pt kG; nn_src_t q, x; u8 hsize, r_len, s_len; int ret, iszero; nn tmp, s, rx, ke, k, r, e; #ifdef USE_SIG_BLINDING /* b is the blinding mask */ nn b, binv; b.magic = binv.magic = WORD(0); #endif /* USE_SIG_BLINDING */ tmp.magic = s.magic = rx.magic = ke.magic = WORD(0); k.magic = r.magic = e.magic = WORD(0); kG.magic = WORD(0); /* * First, verify context has been initialized and private * part too. This guarantees the context is an EC-RDSA * signature one and we do not finalize() before init(). */ ret = sig_sign_check_initialized(ctx); EG(ret, err); ECRDSA_SIGN_CHECK_INITIALIZED(&(ctx->sign_data.ecrdsa), ret, err); /* Zero init points */ ret = local_memset(&kG, 0, sizeof(prj_pt)); EG(ret, err); /* Make things more readable */ priv_key = &(ctx->key_pair->priv_key); G = &(priv_key->params->ec_gen); q = &(priv_key->params->ec_gen_order); p_bit_len = priv_key->params->ec_fp.p_bitlen; q_bit_len = priv_key->params->ec_gen_order_bitlen; x = &(priv_key->x); r_len = (u8)ECRDSA_R_LEN(q_bit_len); s_len = (u8)ECRDSA_S_LEN(q_bit_len); hsize = inputlen; MUST_HAVE((NN_MAX_BIT_LEN >= p_bit_len), ret, err); MUST_HAVE((siglen == ECRDSA_SIGLEN(q_bit_len)), ret, err); dbg_nn_print("p", &(priv_key->params->ec_fp.p)); dbg_nn_print("q", q); dbg_priv_key_print("x", priv_key); dbg_pub_key_print("Y", &(ctx->key_pair->pub_key)); dbg_ec_point_print("G", G); /* NOTE: the restart label is removed in CRYPTOFUZZ mode as we trigger MUST_HAVE instead of restarting in this mode. restart: */ /* 2. Get a random value k in ]0, q[ ... */ /* NOTE: copy our input nonce if not NULL */ if(nonce != NULL){ MUST_HAVE((noncelen <= (u8)(BYTECEIL(q_bit_len))), ret, err); ret = nn_init_from_buf(&k, nonce, noncelen); EG(ret, err); } else{ ret = ctx->rand(&k, q); EG(ret, err); } dbg_nn_print("k", &k); #ifdef USE_SIG_BLINDING /* Note: if we use blinding, k and e are multiplied by * a random value b in ]0,q[ */ ret = nn_get_random_mod(&b, q); EG(ret, err); dbg_nn_print("b", &b); #endif /* USE_SIG_BLINDING */ /* 3. Compute W = kG = (Wx, Wy) */ #ifdef USE_SIG_BLINDING /* We use blinding for the scalar multiplication */ ret = prj_pt_mul_blind(&kG, &k, G); EG(ret, err); #else ret = prj_pt_mul(&kG, &k, G); EG(ret, err); #endif /* USE_SIG_BLINDING */ ret = prj_pt_unique(&kG, &kG); EG(ret, err); dbg_nn_print("W_x", &(kG.X.fp_val)); dbg_nn_print("W_y", &(kG.Y.fp_val)); /* 4. Compute r = Wx mod q */ ret = nn_mod(&r, &(kG.X.fp_val), q); EG(ret, err); /* 5. If r is 0, restart the process at step 2. */ /* NOTE: for the CRYPTOFUZZ mode, we do not restart * the procedure but throw an assert exception instead. */ ret = nn_iszero(&r, &iszero); EG(ret, err); MUST_HAVE((!iszero), ret, err); dbg_nn_print("r", &r); /* Export r */ ret = nn_export_to_buf(sig, r_len, &r); EG(ret, err); /* 6. Compute e = OS2I(h) mod q. If e is 0, set e to 1. */ /* NOTE: here we have raw ECRDSA, this is the raw input */ MUST_HAVE((input != NULL), ret, err); /* NOTE: the MUST_HAVE is protected by a preprocessing check * to avoid -Werror=type-limits errors: * "error: comparison is always true due to limited range of data type" */ #if LOCAL_MIN(255, BIT_LEN_WORDS(NN_MAX_BIT_LEN) * (WORDSIZE / 8)) < 255 MUST_HAVE(((u32)inputlen <= sizeof(h_buf)), ret, err); #endif ret = local_memset(h_buf, 0, sizeof(h_buf)); EG(ret, err); ret = local_memcpy(h_buf, input, hsize); EG(ret, err); dbg_buf_print("H(m)", h_buf, hsize); /* NOTE: this handles a discrepancy between ISO/IEC 14888-3 and * Russian standard based RFCs. */ #ifndef USE_ISO14888_3_ECRDSA ret = _reverse_endianness(h_buf, hsize); EG(ret, err); #endif ret = nn_init_from_buf(&tmp, h_buf, hsize); EG(ret, err); ret = local_memset(h_buf, 0, hsize); EG(ret, err); ret = nn_mod(&e, &tmp, q); EG(ret, err); ret = nn_iszero(&e, &iszero); EG(ret, err); if (iszero) { ret = nn_inc(&e, &e); EG(ret, err); } dbg_nn_print("e", &e); #ifdef USE_SIG_BLINDING /* In case of blinding, we blind r and e */ ret = nn_mod_mul(&r, &r, &b, q); EG(ret, err); ret = nn_mod_mul(&e, &e, &b, q); EG(ret, err); #endif /* USE_SIG_BLINDING */ /* Compute s = (rx + ke) mod q */ ret = nn_mod_mul(&rx, &r, x, q); EG(ret, err); ret = nn_mod_mul(&ke, &k, &e, q); EG(ret, err); ret = nn_mod_add(&s, &rx, &ke, q); EG(ret, err); #ifdef USE_SIG_BLINDING /* Unblind s */ /* NOTE: we use Fermat's little theorem inversion for * constant time here. This is possible since q is prime. */ ret = nn_modinv_fermat(&binv, &b, q); EG(ret, err); ret = nn_mod_mul(&s, &s, &binv, q); EG(ret, err); #endif /* USE_SIG_BLINDING */ /* If s is 0, restart the process at step 2. */ /* 10. If s is 0, restart the process at step 4. */ /* NOTE: for the CRYPTOFUZZ mode, we do not restart * the procedure but throw an assert exception instead. */ ret = nn_iszero(&s, &iszero); EG(ret, err); MUST_HAVE((!iszero), ret, err); dbg_nn_print("s", &s); /* Return (r,s) */ ret = nn_export_to_buf(sig + r_len, s_len, &s); EG(ret, err); err: nn_uninit(&r); nn_uninit(&s); nn_uninit(&tmp); nn_uninit(&rx); nn_uninit(&ke); nn_uninit(&k); nn_uninit(&e); prj_pt_uninit(&kG); /* * We can now clear data part of the context. This will clear * magic and avoid further reuse of the whole context. */ if(ctx != NULL){ IGNORE_RET_VAL(local_memset(&(ctx->sign_data.ecrdsa), 0, sizeof(ecrdsa_sign_data))); } /* Clean what remains on the stack */ VAR_ZEROIFY(r_len); VAR_ZEROIFY(s_len); VAR_ZEROIFY(q_bit_len); VAR_ZEROIFY(p_bit_len); VAR_ZEROIFY(hsize); PTR_NULLIFY(priv_key); PTR_NULLIFY(G); PTR_NULLIFY(q); PTR_NULLIFY(x); #ifdef USE_SIG_BLINDING nn_uninit(&b); nn_uninit(&binv); #endif /* USE_SIG_BLINDING */ return ret; } /******************************/ #define ECRDSA_VERIFY_MAGIC ((word_t)(0xa8e16b7e8180cb9aULL)) #define ECRDSA_VERIFY_CHECK_INITIALIZED(A, ret, err) \ MUST_HAVE((((const void *)(A)) != NULL) && \ ((A)->magic == ECRDSA_VERIFY_MAGIC), ret, err) int ecrdsa_verify_raw(struct ec_verify_context *ctx, const u8 *input, u8 inputlen) { prj_pt_src_t G, Y; nn_src_t q; nn tmp, h, r_prime, e, v, u; prj_pt vY, uG; prj_pt_t Wprime; /* NOTE: hash here is not really a hash ... */ u8 h_buf[LOCAL_MIN(255, BIT_LEN_WORDS(NN_MAX_BIT_LEN) * (WORDSIZE / 8))]; nn *r, *s; u8 hsize; int ret, iszero, cmp; tmp.magic = h.magic = r_prime.magic = e.magic = WORD(0); v.magic = u.magic = WORD(0); vY.magic = uG.magic = WORD(0); /* NOTE: we reuse uG for Wprime to optimize local variables */ Wprime = &uG; /* * First, verify context has been initialized and public * part too. This guarantees the context is an EC-RDSA * verification one and we do not finalize() before init(). */ ret = sig_verify_check_initialized(ctx); EG(ret, err); ECRDSA_VERIFY_CHECK_INITIALIZED(&(ctx->verify_data.ecrdsa), ret, err); /* Zero init points */ ret = local_memset(&uG, 0, sizeof(prj_pt)); EG(ret, err); ret = local_memset(&vY, 0, sizeof(prj_pt)); EG(ret, err); /* Make things more readable */ G = &(ctx->pub_key->params->ec_gen); Y = &(ctx->pub_key->y); q = &(ctx->pub_key->params->ec_gen_order); r = &(ctx->verify_data.ecrdsa.r); s = &(ctx->verify_data.ecrdsa.s); hsize = inputlen; /* 2. Compute h = H(m) */ /* NOTE: here we have raw ECRDSA, this is the raw input */ MUST_HAVE((input != NULL), ret, err); /* NOTE: the MUST_HAVE is protected by a preprocessing check * to avoid -Werror=type-limits errors: * "error: comparison is always true due to limited range of data type" */ #if LOCAL_MIN(255, BIT_LEN_WORDS(NN_MAX_BIT_LEN) * (WORDSIZE / 8)) < 255 MUST_HAVE(((u32)inputlen <= sizeof(h_buf)), ret, err); #endif ret = local_memset(h_buf, 0, sizeof(h_buf)); EG(ret, err); ret = local_memcpy(h_buf, input, hsize); EG(ret, err); dbg_buf_print("H(m)", h_buf, hsize); /* NOTE: this handles a discrepancy between ISO/IEC 14888-3 and * Russian standard based RFCs. */ #ifndef USE_ISO14888_3_ECRDSA ret = _reverse_endianness(h_buf, hsize); EG(ret, err); #endif /* 3. Compute e = OS2I(h)^-1 mod q */ ret = nn_init_from_buf(&tmp, h_buf, hsize); EG(ret, err); ret = local_memset(h_buf, 0, hsize); EG(ret, err); ret = nn_mod(&h, &tmp, q); EG(ret, err); /* h = OS2I(h) mod q */ ret = nn_iszero(&h, &iszero); EG(ret, err); if (iszero) { /* If h is equal to 0, set it to 1 */ ret = nn_inc(&h, &h); EG(ret, err); } ret = nn_modinv(&e, &h, q); EG(ret, err); /* e = h^-1 mod q */ /* 4. Compute u = es mod q */ ret = nn_mul(&tmp, &e, s); EG(ret, err); ret = nn_mod(&u, &tmp, q); EG(ret, err); /* 5. Compute v = -er mod q * * Because we only support positive integers, we compute * v = -er mod q = q - (er mod q) (except when er is 0). */ ret = nn_mul(&tmp, &e, r); EG(ret, err); /* tmp = er */ ret = nn_mod(&tmp, &tmp, q); EG(ret, err); /* tmp = er mod q */ ret = nn_mod_neg(&v, &tmp, q); EG(ret, err); /* negate tmp */ /* 6. Compute W' = uG + vY = (W'_x, W'_y) */ ret = prj_pt_mul(&uG, &u, G); EG(ret, err); ret = prj_pt_mul(&vY, &v, Y); EG(ret, err); ret = prj_pt_add(Wprime, &uG, &vY); EG(ret, err); ret = prj_pt_unique(Wprime, Wprime); EG(ret, err); dbg_nn_print("W'_x", &(Wprime->X.fp_val)); dbg_nn_print("W'_y", &(Wprime->Y.fp_val)); /* 7. Compute r' = W'_x mod q */ ret = nn_mod(&r_prime, &(Wprime->X.fp_val), q); EG(ret, err); /* 8. Check r and r' are the same */ ret = nn_cmp(r, &r_prime, &cmp); EG(ret, err); ret = (cmp == 0) ? 0 : -1; err: nn_uninit(&r_prime); nn_uninit(&tmp); nn_uninit(&h); nn_uninit(&e); nn_uninit(&u); nn_uninit(&v); prj_pt_uninit(&vY); prj_pt_uninit(&uG); /* * We can now clear data part of the context. This will clear * magic and avoid further reuse of the whole context. */ if(ctx != NULL){ IGNORE_RET_VAL(local_memset(&(ctx->verify_data.ecrdsa), 0, sizeof(ecrdsa_verify_data))); } /* Clean what remains on the stack */ PTR_NULLIFY(Wprime); PTR_NULLIFY(G); PTR_NULLIFY(Y); PTR_NULLIFY(q); PTR_NULLIFY(r); PTR_NULLIFY(s); VAR_ZEROIFY(hsize); return ret; } #else /* WITH_SIG_ECRDSA && USE_CRYPTOFUZZ */ /* * Dummy definition to avoid the empty translation unit ISO C warning */ typedef int dummy; #endif /* WITH_SIG_ECRDSA */