/* * Copyright (C) 2021 - This file is part of libecc project * * Authors: * Ryad BENADJILA * Arnaud EBALARD * * This software is licensed under a dual BSD and GPL v2 license. * See LICENSE file at the root folder of the project. */ #include #ifdef WITH_SIG_SM2 #include #include #include #include #include #include #ifdef VERBOSE_INNER_VALUES #define EC_SIG_ALG "SM2" #endif #include /* * NOTE: SM2 has an oddity in private key generation when compared to * other EC*DSA style signature algorithms described in ISO14888-3: * the private key x MUST be in ]0, q-1[ instead of ]0, q[ (this is actually * explained by the fact that (1 + x) must be inversible modulo q during the * signature process). * * Hence the following specific key generation function. * */ int sm2_gen_priv_key(ec_priv_key *priv_key) { int ret; nn tmp; tmp.magic = WORD(0); ret = priv_key_check_initialized_and_type(priv_key, SM2); EG(ret, err); /* Get a random value in ]0,q-1[ where q is the group generator order */ ret = nn_init(&tmp, 0); EG(ret, err); ret = nn_dec(&tmp, &(priv_key->params->ec_gen_order)); EG(ret, err); ret = nn_get_random_mod(&(priv_key->x), &tmp); err: nn_uninit(&tmp); return ret; } int sm2_init_pub_key(ec_pub_key *out_pub, const ec_priv_key *in_priv) { prj_pt_src_t G; int ret, cmp; nn tmp; tmp.magic = WORD(0); MUST_HAVE((out_pub != NULL), ret, err); ret = priv_key_check_initialized_and_type(in_priv, SM2); EG(ret, err); /* * We verify that the private key is valid, i.e. in * ]0, q-1[. This excluded q-1 is an oddity but is what the * ISO14888-3:2018 has. */ ret = nn_init(&tmp, 0); EG(ret, err); ret = nn_dec(&tmp, &in_priv->params->ec_gen_order); EG(ret, err); /* If x >= (q - 1), this is an error */ MUST_HAVE((!nn_cmp(&(in_priv->x), &tmp, &cmp)) && (cmp < 0), ret, err); /* Y = xG */ G = &(in_priv->params->ec_gen); /* Zero init public key to be generated */ ret = local_memset(out_pub, 0, sizeof(ec_pub_key)); EG(ret, err); /* Use blinding with scalar_b when computing point scalar multiplication */ ret = prj_pt_mul_blind(&(out_pub->y), &(in_priv->x), G); EG(ret, err); out_pub->key_type = SM2; out_pub->params = in_priv->params; out_pub->magic = PUB_KEY_MAGIC; err: nn_uninit(&tmp); return ret; } int sm2_siglen(u16 p_bit_len, u16 q_bit_len, u8 hsize, u8 blocksize, u8 *siglen) { int ret; MUST_HAVE((siglen != NULL), ret, err); MUST_HAVE((p_bit_len <= CURVES_MAX_P_BIT_LEN) && (q_bit_len <= CURVES_MAX_Q_BIT_LEN) && (hsize <= MAX_DIGEST_SIZE) && (blocksize <= MAX_BLOCK_SIZE), ret, err); (*siglen) = (u8)SM2_SIGLEN(q_bit_len); ret = 0; err: return ret; } /* * Helper to compute Z from user ID, curve parameters, public key and hash * function as defined in section 6.12.4.3 of ISO14888-3:2018. The function * returns 0 on success, -1 on error. On success, the number of bytes * written to Z is provided using Zlen. On input, Zlen provides the size of * Z buffer, which must be large enough for selected hash function (Z has * the digest size of the hash function). 'id' buffer of size 'id_len' must * be smaller than SM2_MAX_ID_LEN (see sm2.h). * * Z = h(ENTL || ID || FE2BS(p, a) || FE2BS(p, b) || FE2BS(p, Gx) || * FE2BS(p, Gy) || FE2BS(p, Yx) || FE2BS(p, Yy)). * * with: * * - GF(p), Finite field of cardinality p. * - Curve Weierstrass Equation y^2 = x^3 + a * x + b. * - ID string containing an identifier of the signer * - G = (Gx, Gy) an element of order q in E. * - entlen is the bit-length of ID and ENTL the two bytes string transformed * from the integer entlen, i.e. ENTL = I2BS(12, entlen). * */ #define Z_INPUT_MAX_LEN (2 + SM2_MAX_ID_LEN + (6 * BYTECEIL(CURVES_MAX_P_BIT_LEN))) ATTRIBUTE_WARN_UNUSED_RET static int sm2_compute_Z(u8 *Z, u16 *Zlen, const u8 *id, u16 id_len, const ec_pub_key *pub_key, hash_alg_type hash_type) { u16 hsize, entlen, p_len; u8 buf[2 * BYTECEIL(CURVES_MAX_P_BIT_LEN)]; const hash_mapping *hm; prj_pt_src_t G, Y; hash_context hctx; bitcnt_t p_bit_len; fp_src_t a, b; int ret; MUST_HAVE((Z != NULL) && (Zlen != NULL), ret, err); MUST_HAVE((id != NULL) && (pub_key != NULL), ret, err); /* Maximum size is Entlen on 16 bits in *bits*, i.e. 8192 bytes */ MUST_HAVE((id_len <= SM2_MAX_ID_LEN), ret, err); ret = pub_key_check_initialized_and_type(pub_key, SM2); EG(ret, err); ret = get_hash_by_type(hash_type, &hm); EG(ret, err); MUST_HAVE((hm != NULL), ret, err); /* Zlen must be large enough to receive digest */ hsize = hm->digest_size; MUST_HAVE((*Zlen) >= hsize, ret, err); /* Make things more readable */ G = &(pub_key->params->ec_gen); Y = &(pub_key->y); p_bit_len = pub_key->params->ec_fp.p_bitlen; p_len = (u8)BYTECEIL(p_bit_len); entlen = (u16)(id_len * 8); a = &(pub_key->params->ec_curve.a); b = &(pub_key->params->ec_curve.b); /* Since we call a callback, sanity check our mapping */ ret = hash_mapping_callbacks_sanity_check(hm); EG(ret, err); ret = hm->hfunc_init(&hctx); EG(ret, err); /* ENTL */ buf[0] = (u8)((entlen >> 8) & 0xff); buf[1] = (u8)(entlen & 0xff); ret = hm->hfunc_update(&hctx, buf, 2); EG(ret, err); /* ID */ ret = hm->hfunc_update(&hctx, id, id_len); EG(ret, err); /* FE2BS(p, a) */ ret = fp_export_to_buf(buf, p_len, a); EG(ret, err); ret = hm->hfunc_update(&hctx, buf, p_len); EG(ret, err); /* FE2BS(p, b) */ ret = fp_export_to_buf(buf, p_len, b); EG(ret, err); ret = hm->hfunc_update(&hctx, buf, p_len); EG(ret, err); /* FE2BS(p, Gx) || FE2BS(p, Gy) */ ret = prj_pt_export_to_aff_buf(G, buf, (u32)(2 * p_len)); EG(ret, err); ret = hm->hfunc_update(&hctx, buf, (u32)(2 * p_len)); EG(ret, err); /* FE2BS(p, Yx) || FE2BS(p, Yy) */ ret = prj_pt_export_to_aff_buf(Y, buf, (u32)(2 * p_len)); EG(ret, err); ret = hm->hfunc_update(&hctx, buf, (u32)(2 * p_len)); EG(ret, err); /* Let's now finalize hash computation */ ret = hm->hfunc_finalize(&hctx, Z); EG(ret, err); dbg_buf_print("Z", Z, hsize); ret = local_memset(buf, 0, sizeof(buf)); EG(ret, err); ret = local_memset(&hctx, 0, sizeof(hctx)); EG(ret, err); (*Zlen) = hsize; err: if (ret && (Zlen != NULL)){ (*Zlen) = 0; } return ret; } /* * Generic *internal* SM2 signature functions (init, update and finalize). * Their purpose is to allow passing a specific hash function (along with * its output size) and the random ephemeral key k, so that compliance * tests against test vectors can be made without ugly hack in the code * itself. * * Global SM2 signature process is as follows (I,U,F provides information * in which function(s) (init(), update() or finalize()) a specific step * is performed): * *| IUF - SM2 signature *| *| UF 1. set M1 = Z || M (See (*) below) *| F 2. Compute H = h(M1) *| F 3. Get a random value k in ]0,q[ *| F 4. Compute W = (W_x,W_y) = kG *| F 5. Compute r = (OS2I(H) + Wx) mod q *| F 6. If r is 0, restart the process at step 3. *| F 7. If r + k is q, restart the process at step 3. *| F 8. Compute s = ((1 + x)^(-1) * (k - rx)) mod q *| F 9. If s is 0, restart the process at step 3. *| F 10. Export r and s * * (*) It is user responsibility to pass the ID string in the optional ancillary * data of the API. */ #define SM2_SIGN_MAGIC ((word_t)(0x324300884035dae8ULL)) #define SM2_SIGN_CHECK_INITIALIZED(A, ret, err) \ MUST_HAVE((((void *)(A)) != NULL) && ((A)->magic == SM2_SIGN_MAGIC), ret, err) int _sm2_sign_init(struct ec_sign_context *ctx) { int ret; u8 Z[Z_INPUT_MAX_LEN]; u16 Zlen; /* First, verify context has been initialized */ ret = sig_sign_check_initialized(ctx); EG(ret, err); /* Additional sanity checks on input params from context */ ret = key_pair_check_initialized_and_type(ctx->key_pair, SM2); EG(ret, err); MUST_HAVE((ctx->h != NULL) && (ctx->h->digest_size <= MAX_DIGEST_SIZE) && (ctx->h->block_size <= MAX_BLOCK_SIZE), ret, err); /* * Initialize hash context stored in our private part of context * and record data init has been done */ /* Since we call a callback, sanity check our mapping */ ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err); ret = ctx->h->hfunc_init(&(ctx->sign_data.sm2.h_ctx)); EG(ret, err); /* Compute Z from the ID */ ret = local_memset(Z, 0, sizeof(Z)); EG(ret, err); Zlen = sizeof(Z); ret = sm2_compute_Z(Z, &Zlen, ctx->adata, ctx->adata_len, &(ctx->key_pair->pub_key), ctx->h->type); EG(ret, err); /* Update the hash function with Z */ /* Since we call a callback, sanity check our mapping */ ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err); ret = ctx->h->hfunc_update(&(ctx->sign_data.sm2.h_ctx), Z, Zlen); EG(ret, err); ctx->sign_data.sm2.magic = SM2_SIGN_MAGIC; err: VAR_ZEROIFY(Zlen); return ret; } int _sm2_sign_update(struct ec_sign_context *ctx, const u8 *chunk, u32 chunklen) { int ret; /* * First, verify context has been initialized and private part too. * This guarantees the context is an SM2 signature one and we do not * update() or finalize() before init(). */ ret = sig_sign_check_initialized(ctx); EG(ret, err); SM2_SIGN_CHECK_INITIALIZED(&(ctx->sign_data.sm2), ret, err); /* 1. Compute h = H(m) */ /* Since we call a callback, sanity check our mapping */ ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err); ret = ctx->h->hfunc_update(&(ctx->sign_data.sm2.h_ctx), chunk, chunklen); err: return ret; } int _sm2_sign_finalize(struct ec_sign_context *ctx, u8 *sig, u8 siglen) { const ec_priv_key *priv_key; u8 hash[MAX_DIGEST_SIZE]; bitcnt_t q_bit_len; u8 hsize, q_len; prj_pt_src_t G; nn_src_t q, x; prj_pt kG; int ret, iszero, cmp; nn k, r, s, tmp, tmp2, tmp3; #ifdef USE_SIG_BLINDING nn b; /* blinding mask */ b.magic = WORD(0); #endif kG.magic = WORD(0); k.magic = r.magic = s.magic = tmp.magic = tmp2.magic = tmp3.magic = WORD(0); /* * First, verify context has been initialized and private part too. * This guarantees the context is an SM2 signature one and we do not * update() or finalize() before init(). */ ret = sig_sign_check_initialized(ctx); EG(ret, err); SM2_SIGN_CHECK_INITIALIZED(&(ctx->sign_data.sm2), ret, err); MUST_HAVE((sig != NULL), ret, err); /* Zero init out point */ ret = local_memset(&kG, 0, sizeof(prj_pt)); EG(ret, err); /* Make things more readable */ priv_key = &(ctx->key_pair->priv_key); q = &(priv_key->params->ec_gen_order); q_bit_len = priv_key->params->ec_gen_order_bitlen; G = &(priv_key->params->ec_gen); q_len = (u8)BYTECEIL(q_bit_len); x = &(priv_key->x); hsize = ctx->h->digest_size; dbg_nn_print("p", &(priv_key->params->ec_fp.p)); dbg_nn_print("q", &(priv_key->params->ec_gen_order)); dbg_priv_key_print("x", priv_key); dbg_ec_point_print("G", &(priv_key->params->ec_gen)); dbg_pub_key_print("Y", &(ctx->key_pair->pub_key)); /* Check given signature buffer length has the expected size */ MUST_HAVE((siglen == SM2_SIGLEN(q_bit_len)), ret, err); ret = local_memset(hash, 0, hsize); EG(ret, err); /* Since we call a callback, sanity check our mapping */ ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err); /* 2. Compute H = h(M1) */ ret = ctx->h->hfunc_finalize(&(ctx->sign_data.sm2.h_ctx), hash); EG(ret, err); dbg_buf_print("h", hash, hsize); restart: /* 3. Get a random value k in ]0,q[ */ #ifdef NO_KNOWN_VECTORS /* NOTE: when we do not need self tests for known vectors, * we can be strict about random function handler! * This allows us to avoid the corruption of such a pointer. */ /* Sanity check on the handler before calling it */ MUST_HAVE(ctx->rand == nn_get_random_mod, ret, err); #endif ret = ctx->rand(&k, q); EG(ret, err); dbg_nn_print("k", &k); /* 4. Compute W = (W_x,W_y) = kG */ #ifdef USE_SIG_BLINDING 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)); /* 5. Compute r = (OS2I(H) + Wx) mod q */ ret = nn_init_from_buf(&tmp, hash, hsize); EG(ret, err); ret = local_memset(hash, 0, hsize); EG(ret, err); dbg_nn_print("OS2I(H)", &tmp); ret = nn_add(&tmp2, &tmp, &(kG.X.fp_val)); EG(ret, err); ret = nn_mod(&r, &tmp2, q); EG(ret, err); dbg_nn_print("r", &r); /* 6. If r is 0, restart the process at step 3. */ ret = nn_iszero(&r, &iszero); EG(ret, err); if (iszero) { goto restart; } /* 7. If r + k is q, restart the process at step 3. */ ret = nn_add(&tmp, &r, q); EG(ret, err); ret = nn_cmp(&tmp, q, &cmp); EG(ret, err); if (cmp == 0) { goto restart; } /* 8. Compute s = ((1 + x)^(-1) * (k - rx)) mod q */ #ifdef USE_SIG_BLINDING /* * With blinding enabled, the computation above is performed in the * following way s = ((b*(1 + x))^(-1) * (kb - (br)x)) mod q */ ret = nn_get_random_mod(&b, q); EG(ret, err); dbg_nn_print("b", &b); ret = nn_inc(&tmp2, x); EG(ret, err); ret = nn_mod_mul(&tmp2, &tmp2, &b, q); EG(ret, err); /* NOTE: we use Fermat's little theorem inversion for * constant time here. This is possible since q is prime. */ ret = nn_modinv_fermat(&tmp, &tmp2, q); EG(ret, err); /* tmp = (b*(1 + x))^(-1) */ dbg_nn_print("(b*(1 + x))^(-1)", &tmp); ret = nn_mod_mul(&tmp3, &r, &b, q); EG(ret, err); /* rb */ ret = nn_mod_mul(&k, &k, &b, q); EG(ret, err); /* kb */ ret = nn_mod_mul(&tmp3, &tmp3, x, q); EG(ret, err); /* (rb)x mod q */ ret = nn_mod_sub(&tmp2, &k, &tmp3, q); EG(ret, err); /* tmp2 = (kb - (rb)x) mod q */ ret = nn_mod_mul(&s, &tmp, &tmp2, q); EG(ret, err); dbg_nn_print("s", &s); #else ret = nn_inc(&tmp2, x); EG(ret, err); /* NOTE: we use Fermat's little theorem inversion for * constant time here. This is possible since q is prime. */ ret = nn_modinv_fermat(&tmp, &tmp2, q); EG(ret, err); /* tmp = (1 + x)^(-1) */ dbg_nn_print("(1 + x)^(-1)", &tmp); ret = nn_mod_mul(&tmp3, &r, x, q); EG(ret, err); /* rx mod q */ ret = nn_mod_sub(&tmp2, &k, &tmp3, q); EG(ret, err); /* tmp2 = (k - rx) mod q */ ret = nn_mod_mul(&s, &tmp, &tmp2, q); EG(ret, err); dbg_nn_print("s", &s); #endif /* 9. If s is 0, restart the process at step 3. */ ret = nn_iszero(&s, &iszero); EG(ret, err); if (iszero) { goto restart; } /* 10. Export r and s */ ret = nn_export_to_buf(sig, q_len, &r); EG(ret, err); ret = nn_export_to_buf(sig + q_len, q_len, &s); err: prj_pt_uninit(&kG); nn_uninit(&k); nn_uninit(&r); nn_uninit(&s); nn_uninit(&tmp); nn_uninit(&tmp2); nn_uninit(&tmp3); #ifdef USE_SIG_BLINDING nn_uninit(&b); #endif /* * We can now clear data part of the context. This will clear * magic and avoid further reuse of the whole context. */ IGNORE_RET_VAL(local_memset(&(ctx->sign_data.sm2), 0, sizeof(sm2_sign_data))); /* Clean what remains on the stack */ PTR_NULLIFY(priv_key); PTR_NULLIFY(G); PTR_NULLIFY(q); PTR_NULLIFY(x); VAR_ZEROIFY(q_len); VAR_ZEROIFY(q_bit_len); VAR_ZEROIFY(hsize); return ret; } /* * Generic *internal* SM2 verification functions (init, update and finalize). * Their purpose is to allow passing a specific hash function (along with * its output size) and the random ephemeral key k, so that compliance * tests against test vectors can be made without ugly hack in the code * itself. * * Global SM2 verification process is as follows (I,U,F provides information * in which function(s) (init(), update() or finalize()) a specific step is * performed): * *| IUF - SM2 verification *| *| I 1. Reject the signature if r or s is 0 or >= q. *| UF 2. Compute h = H(M1) w/ M1 = Z || M (See (*) below) *| F 3. Compute t = r + s mod q *| F 4. Reject signature if t is 0 *| F 5. Compute e = OS2I(h) mod q *| F 6. Compute W' = sG + tY *| F 7. If W' is the point at infinity, reject the signature. *| F 8. Compute r' = (e + W'_x) mod q *| F 9. Accept the signature if and only if r equals r' * * (*) It is user responsibility to pass the ID string in the optional ancillary * data of the API. */ #define SM2_VERIFY_MAGIC ((word_t)(0x9177c61e777f9f22ULL)) #define SM2_VERIFY_CHECK_INITIALIZED(A, ret, err) \ MUST_HAVE((((void *)(A)) != NULL) && ((A)->magic == SM2_VERIFY_MAGIC), ret, err) int _sm2_verify_init(struct ec_verify_context *ctx, const u8 *sig, u8 siglen) { bitcnt_t q_bit_len; u8 q_len; nn_src_t q; nn *r = NULL, *s = NULL; int ret, iszero1, iszero2, cmp1, cmp2; u8 Z[Z_INPUT_MAX_LEN]; u16 Zlen; /* First, verify context has been initialized */ ret = sig_verify_check_initialized(ctx); EG(ret, err); /* Do some sanity checks on input params */ ret = pub_key_check_initialized_and_type(ctx->pub_key, SM2); EG(ret, err); MUST_HAVE((ctx->h != NULL) && (ctx->h->digest_size <= MAX_DIGEST_SIZE) && (ctx->h->block_size <= MAX_BLOCK_SIZE), ret, err); MUST_HAVE((sig != NULL), ret, err); /* Make things more readable */ q = &(ctx->pub_key->params->ec_gen_order); q_bit_len = ctx->pub_key->params->ec_gen_order_bitlen; q_len = (u8)BYTECEIL(q_bit_len); r = &(ctx->verify_data.sm2.r); s = &(ctx->verify_data.sm2.s); /* Check given signature length is the expected one */ MUST_HAVE((siglen == SM2_SIGLEN(q_bit_len)), ret, err); /* Import r and s values from signature buffer */ ret = nn_init_from_buf(r, sig, q_len); EG(ret, err); ret = nn_init_from_buf(s, sig + q_len, q_len); EG(ret, err); dbg_nn_print("r", r); dbg_nn_print("s", s); /* 1. Reject the signature if r or s is 0 or >= q. */ ret = nn_iszero(r, &iszero1); EG(ret, err); ret = nn_iszero(s, &iszero2); EG(ret, err); ret = nn_cmp(r, q, &cmp1); EG(ret, err); ret = nn_cmp(s, q, &cmp2); EG(ret, err); MUST_HAVE((!iszero1) && (cmp1 < 0) && (!iszero2) && (cmp2 < 0), ret, err); /* Initialize the remaining of verify context. */ /* Since we call a callback, sanity check our mapping */ ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err); ret = ctx->h->hfunc_init(&(ctx->verify_data.sm2.h_ctx)); EG(ret, err); /* Compute Z from the ID */ ret = local_memset(Z, 0, sizeof(Z)); EG(ret, err); Zlen = sizeof(Z); ret = sm2_compute_Z(Z, &Zlen, ctx->adata, ctx->adata_len, ctx->pub_key, ctx->h->type); EG(ret, err); /* Update the hash function with Z */ ret = ctx->h->hfunc_update(&(ctx->verify_data.sm2.h_ctx), Z, Zlen); EG(ret, err); ctx->verify_data.sm2.magic = SM2_VERIFY_MAGIC; err: VAR_ZEROIFY(q_len); VAR_ZEROIFY(q_bit_len); VAR_ZEROIFY(Zlen); PTR_NULLIFY(q); PTR_NULLIFY(r); PTR_NULLIFY(s); return ret; } int _sm2_verify_update(struct ec_verify_context *ctx, const u8 *chunk, u32 chunklen) { int ret; /* * First, verify context has been initialized and public part too. This * guarantees the context is a SM2 verification one and we do not * update() or finalize() before init(). */ ret = sig_verify_check_initialized(ctx); EG(ret, err); SM2_VERIFY_CHECK_INITIALIZED(&(ctx->verify_data.sm2), ret, err); /* 2. Compute h = H(M1) w/ M1 = Z || M */ /* Since we call a callback, sanity check our mapping */ ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err); ret = ctx->h->hfunc_update(&(ctx->verify_data.sm2.h_ctx), chunk, chunklen); err: return ret; } int _sm2_verify_finalize(struct ec_verify_context *ctx) { prj_pt sG, tY; prj_pt_t W_prime; nn e, tmp, r_prime; prj_pt_src_t G, Y; u8 hash[MAX_DIGEST_SIZE]; nn_src_t q; nn *s, *r; nn t; u8 hsize; int ret, iszero, cmp; e.magic = tmp.magic = r_prime.magic = t.magic = WORD(0); sG.magic = tY.magic = WORD(0); /* NOTE: we reuse sG for W_prime to optimize local variables */ W_prime = &sG; /* * First, verify context has been initialized and public * part too. This guarantees the context is an SM2 * verification one and we do not finalize() before init(). */ ret = sig_verify_check_initialized(ctx); EG(ret, err); SM2_VERIFY_CHECK_INITIALIZED(&(ctx->verify_data.sm2), ret, err); /* Zero init points */ ret = local_memset(&sG, 0, sizeof(prj_pt)); EG(ret, err); ret = local_memset(&tY, 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); hsize = ctx->h->digest_size; r = &(ctx->verify_data.sm2.r); s = &(ctx->verify_data.sm2.s); /* 2. Compute h = H(M1) w/ M1 = Z || M */ /* Since we call a callback, sanity check our mapping */ ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err); ret = ctx->h->hfunc_finalize(&(ctx->verify_data.sm2.h_ctx), hash); EG(ret, err); dbg_buf_print("h = H(m)", hash, hsize); /* 3. Compute t = r + s mod q */ ret = nn_mod_add(&t, r, s, q); EG(ret, err); /* 4. Reject signature if t is 0 */ ret = nn_iszero(&t, &iszero); EG(ret, err); MUST_HAVE((!iszero), ret, err); /* 5. Compute e = OS2I(h) mod q */ ret = nn_init_from_buf(&tmp, hash, hsize); EG(ret, err); ret = local_memset(hash, 0, hsize); EG(ret, err); dbg_nn_print("h imported as nn", &tmp); ret = nn_mod(&e, &tmp, q); EG(ret, err); dbg_nn_print("e", &e); /* 6. Compute W' = sG + tY */ ret = prj_pt_mul(&sG, s, G); EG(ret, err); ret = prj_pt_mul(&tY, &t, Y); EG(ret, err); ret = prj_pt_add(W_prime, &sG, &tY); EG(ret, err); /* 7. If W' is the point at infinity, reject the signature. */ ret = prj_pt_iszero(W_prime, &iszero); EG(ret, err); MUST_HAVE((!iszero), ret, err); /* 8. Compute r' = (e + W'_x) mod q */ ret = prj_pt_unique(W_prime, W_prime); EG(ret, err); dbg_nn_print("W'_x", &(W_prime->X.fp_val)); dbg_nn_print("W'_y", &(W_prime->Y.fp_val)); /* First, reduce W'_x mod q */ ret = nn_mod(&r_prime, &(W_prime->X.fp_val), q); EG(ret, err); /* Then compute r' = (e + W'_x) mod q */ ret = nn_mod_add(&r_prime, &e, &r_prime, q); EG(ret, err); /* 9. Accept the signature if and only if r equals r' */ ret = nn_cmp(&r_prime, r, &cmp); EG(ret, err); ret = (cmp != 0) ? -1 : 0; err: nn_uninit(&e); nn_uninit(&tmp); nn_uninit(&r_prime); nn_uninit(&t); prj_pt_uninit(&sG); prj_pt_uninit(&tY); /* * We can now clear data part of the context. This will clear * magic and avoid further reuse of the whole context. */ IGNORE_RET_VAL(local_memset(&(ctx->verify_data.sm2), 0, sizeof(sm2_verify_data))); /* Clean what remains on the stack */ PTR_NULLIFY(W_prime); PTR_NULLIFY(G); PTR_NULLIFY(Y); PTR_NULLIFY(q); PTR_NULLIFY(s); PTR_NULLIFY(r); VAR_ZEROIFY(hsize); return ret; } #else /* WITH_SIG_SM2 */ /* * Dummy definition to avoid the empty translation unit ISO C warning */ typedef int dummy; #endif /* WITH_SIG_SM2 */