/* * Copyright 2014-2022 The GmSSL Project. All Rights Reserved. * * Licensed under the Apache License, Version 2.0 (the License); you may * not use this file except in compliance with the License. * * http://www.apache.org/licenses/LICENSE-2.0 */ #include #include #include #include #include #include #include #include #include #include #include #include // generate h1 in [1, n-1] int sm9_z256_hash1(sm9_z256_t h1, const char *id, size_t idlen, uint8_t hid) { SM3_CTX ctx; uint8_t prefix[1] = { SM9_HASH1_PREFIX }; uint8_t ct1[4] = {0x00, 0x00, 0x00, 0x01}; uint8_t ct2[4] = {0x00, 0x00, 0x00, 0x02}; uint8_t Ha[64]; sm3_init(&ctx); sm3_update(&ctx, prefix, sizeof(prefix)); sm3_update(&ctx, (uint8_t *)id, idlen); sm3_update(&ctx, &hid, 1); sm3_update(&ctx, ct1, sizeof(ct1)); sm3_finish(&ctx, Ha); sm3_init(&ctx); sm3_update(&ctx, prefix, sizeof(prefix)); sm3_update(&ctx, (uint8_t *)id, idlen); sm3_update(&ctx, &hid, 1); sm3_update(&ctx, ct2, sizeof(ct2)); sm3_finish(&ctx, Ha + 32); sm9_z256_modn_from_hash(h1, Ha); return 1; } int sm9_sign_master_key_to_der(const SM9_SIGN_MASTER_KEY *msk, uint8_t **out, size_t *outlen) { uint8_t ks[32]; uint8_t Ppubs[1 + 32 * 4]; size_t len = 0; sm9_z256_to_bytes(msk->ks, ks); sm9_z256_twist_point_to_uncompressed_octets(&msk->Ppubs, Ppubs); if (asn1_integer_to_der(ks, sizeof(ks), NULL, &len) != 1 || asn1_bit_octets_to_der(Ppubs, sizeof(Ppubs), NULL, &len) != 1 || asn1_sequence_header_to_der(len, out, outlen) != 1 || asn1_integer_to_der(ks, sizeof(ks), out, outlen) != 1 || asn1_bit_octets_to_der(Ppubs, sizeof(Ppubs), out, outlen) != 1) { gmssl_secure_clear(ks, sizeof(ks)); error_print(); return -1; } gmssl_secure_clear(ks, sizeof(ks)); return 1; } int sm9_sign_master_key_from_der(SM9_SIGN_MASTER_KEY *msk, const uint8_t **in, size_t *inlen) { int ret; const uint8_t *d; size_t dlen; const uint8_t *ks; size_t kslen; const uint8_t *Ppubs; size_t Ppubslen; if ((ret = asn1_sequence_from_der(&d, &dlen, in, inlen)) != 1) { if (ret < 0) error_print(); return ret; } if (asn1_integer_from_der(&ks, &kslen, &d, &dlen) != 1 || asn1_bit_octets_from_der(&Ppubs, &Ppubslen, &d, &dlen) != 1 || asn1_check(kslen == 32) != 1 || asn1_check(Ppubslen == 1 + 32 * 4) != 1 || asn1_length_is_zero(dlen) != 1) { error_print(); return -1; } memset(msk, 0, sizeof(*msk)); sm9_z256_from_bytes(msk->ks, ks); if (sm9_z256_cmp(msk->ks, sm9_z256_order()) >= 0) { error_print(); return -1; } if (sm9_z256_twist_point_from_uncompressed_octets(&msk->Ppubs, Ppubs) != 1) { error_print(); return -1; } return 1; } int sm9_sign_master_public_key_to_der(const SM9_SIGN_MASTER_KEY *mpk, uint8_t **out, size_t *outlen) { uint8_t Ppubs[1 + 32 * 4]; size_t len = 0; sm9_z256_twist_point_to_uncompressed_octets(&mpk->Ppubs, Ppubs); if (asn1_bit_octets_to_der(Ppubs, sizeof(Ppubs), NULL, &len) != 1 || asn1_sequence_header_to_der(len, out, outlen) != 1 || asn1_bit_octets_to_der(Ppubs, sizeof(Ppubs), out, outlen) != 1) { error_print(); return -1; } return 1; } int sm9_sign_master_public_key_from_der(SM9_SIGN_MASTER_KEY *mpk, const uint8_t **in, size_t *inlen) { int ret; const uint8_t *d; size_t dlen; const uint8_t *Ppubs; size_t Ppubslen; if ((ret = asn1_sequence_from_der(&d, &dlen, in, inlen)) != 1) { if (ret < 0) error_print(); return ret; } if (asn1_bit_octets_from_der(&Ppubs, &Ppubslen, &d, &dlen) != 1 || asn1_check(Ppubslen == 1 + 32 * 4) != 1 || asn1_length_is_zero(dlen) != 1) { error_print(); return -1; } memset(mpk, 0, sizeof(*mpk)); if (sm9_z256_twist_point_from_uncompressed_octets(&mpk->Ppubs, Ppubs) != 1) { error_print(); return -1; } return 1; } int sm9_sign_key_to_der(const SM9_SIGN_KEY *key, uint8_t **out, size_t *outlen) { uint8_t ds[65]; uint8_t Ppubs[129]; size_t len = 0; sm9_z256_point_to_uncompressed_octets(&key->ds, ds); sm9_z256_twist_point_to_uncompressed_octets(&key->Ppubs, Ppubs); if (asn1_bit_octets_to_der(ds, sizeof(ds), NULL, &len) != 1 || asn1_bit_octets_to_der(Ppubs, sizeof(Ppubs), NULL, &len) != 1 || asn1_sequence_header_to_der(len, out, outlen) != 1 || asn1_bit_octets_to_der(ds, sizeof(ds), out, outlen) != 1 || asn1_bit_octets_to_der(Ppubs, sizeof(Ppubs), out, outlen) != 1) { gmssl_secure_clear(ds, sizeof(ds)); error_print(); return -1; } gmssl_secure_clear(ds, sizeof(ds)); return 1; } int sm9_sign_key_from_der(SM9_SIGN_KEY *key, const uint8_t **in, size_t *inlen) { int ret; const uint8_t *d; size_t dlen; const uint8_t *ds; size_t dslen; const uint8_t *Ppubs; size_t Ppubslen; if ((ret = asn1_sequence_from_der(&d, &dlen, in, inlen)) != 1) { if (ret < 0) error_print(); return ret; } if (asn1_bit_octets_from_der(&ds, &dslen, &d, &dlen) != 1 || asn1_bit_octets_from_der(&Ppubs, &Ppubslen, &d, &dlen) != 1 || asn1_check(dslen == 65) != 1 || asn1_check(Ppubslen == 129) != 1 || asn1_length_is_zero(dlen) != 1) { error_print(); return -1; } memset(key, 0, sizeof(*key)); if (sm9_z256_point_from_uncompressed_octets(&key->ds, ds) != 1 || sm9_z256_twist_point_from_uncompressed_octets(&key->Ppubs, Ppubs) != 1) { error_print(); return -1; } return 1; } int sm9_enc_master_key_to_der(const SM9_ENC_MASTER_KEY *msk, uint8_t **out, size_t *outlen) { uint8_t ke[32]; uint8_t Ppube[1 + 32 * 2]; size_t len = 0; sm9_z256_to_bytes(msk->ke, ke); sm9_z256_point_to_uncompressed_octets(&msk->Ppube, Ppube); if (asn1_integer_to_der(ke, sizeof(ke), NULL, &len) != 1 || asn1_bit_octets_to_der(Ppube, sizeof(Ppube), NULL, &len) != 1 || asn1_sequence_header_to_der(len, out, outlen) != 1 || asn1_integer_to_der(ke, sizeof(ke), out, outlen) != 1 || asn1_bit_octets_to_der(Ppube, sizeof(Ppube), out, outlen) != 1) { gmssl_secure_clear(ke, sizeof(ke)); error_print(); return -1; } gmssl_secure_clear(ke, sizeof(ke)); return 1; } int sm9_enc_master_key_from_der(SM9_ENC_MASTER_KEY *msk, const uint8_t **in, size_t *inlen) { int ret; const uint8_t *d; size_t dlen; const uint8_t *ke; size_t kelen; const uint8_t *Ppube; size_t Ppubelen; if ((ret = asn1_sequence_from_der(&d, &dlen, in, inlen)) != 1) { if (ret < 0) error_print(); return ret; } if (asn1_integer_from_der(&ke, &kelen, &d, &dlen) != 1 || asn1_bit_octets_from_der(&Ppube, &Ppubelen, &d, &dlen) != 1 || asn1_check(kelen == 32) != 1 || asn1_check(Ppubelen == 1 + 32 * 2) != 1 || asn1_length_is_zero(dlen) != 1) { error_print(); return -1; } memset(msk, 0, sizeof(*msk)); sm9_z256_from_bytes(msk->ke, ke); if (sm9_z256_cmp(msk->ke, sm9_z256_order()) >= 0) { error_print(); return -1; } if (sm9_z256_point_from_uncompressed_octets(&msk->Ppube, Ppube) != 1) { error_print(); return -1; } return 1; } int sm9_enc_master_public_key_to_der(const SM9_ENC_MASTER_KEY *mpk, uint8_t **out, size_t *outlen) { uint8_t Ppube[1 + 32 * 2]; size_t len = 0; sm9_z256_point_to_uncompressed_octets(&mpk->Ppube, Ppube); if (asn1_bit_octets_to_der(Ppube, sizeof(Ppube), NULL, &len) != 1 || asn1_sequence_header_to_der(len, out, outlen) != 1 || asn1_bit_octets_to_der(Ppube, sizeof(Ppube), out, outlen) != 1) { error_print(); return -1; } return 1; } int sm9_enc_master_public_key_from_der(SM9_ENC_MASTER_KEY *mpk, const uint8_t **in, size_t *inlen) { int ret; const uint8_t *d; size_t dlen; const uint8_t *Ppube; size_t Ppubelen; if ((ret = asn1_sequence_from_der(&d, &dlen, in, inlen)) != 1) { if (ret < 0) error_print(); return ret; } if (asn1_bit_octets_from_der(&Ppube, &Ppubelen, &d, &dlen) != 1 || asn1_check(Ppubelen == 1 + 32 * 2) != 1 || asn1_length_is_zero(dlen) != 1) { error_print(); return -1; } memset(mpk, 0, sizeof(*mpk)); if (sm9_z256_point_from_uncompressed_octets(&mpk->Ppube, Ppube) != 1) { error_print(); return -1; } return 1; } int sm9_enc_key_to_der(const SM9_ENC_KEY *key, uint8_t **out, size_t *outlen) { uint8_t de[129]; uint8_t Ppube[65]; size_t len = 0; sm9_z256_twist_point_to_uncompressed_octets(&key->de, de); sm9_z256_point_to_uncompressed_octets(&key->Ppube, Ppube); if (asn1_bit_octets_to_der(de, sizeof(de), NULL, &len) != 1 || asn1_bit_octets_to_der(Ppube, sizeof(Ppube), NULL, &len) != 1 || asn1_sequence_header_to_der(len, out, outlen) != 1 || asn1_bit_octets_to_der(de, sizeof(de), out, outlen) != 1 || asn1_bit_octets_to_der(Ppube, sizeof(Ppube), out, outlen) != 1) { gmssl_secure_clear(de, sizeof(de)); error_print(); return -1; } gmssl_secure_clear(de, sizeof(de)); return 1; } int sm9_enc_key_from_der(SM9_ENC_KEY *key, const uint8_t **in, size_t *inlen) { int ret; const uint8_t *d; size_t dlen; const uint8_t *de; size_t delen; const uint8_t *Ppube; size_t Ppubelen; if ((ret = asn1_sequence_from_der(&d, &dlen, in, inlen)) != 1) { if (ret < 0) error_print(); return ret; } if (asn1_bit_octets_from_der(&de, &delen, &d, &dlen) != 1 || asn1_bit_octets_from_der(&Ppube, &Ppubelen, &d, &dlen) != 1 || asn1_check(delen == 129) != 1 || asn1_check(Ppubelen == 65) != 1 || asn1_length_is_zero(dlen) != 1) { error_print(); return -1; } memset(key, 0, sizeof(*key)); if (sm9_z256_twist_point_from_uncompressed_octets(&key->de, de) != 1 || sm9_z256_point_from_uncompressed_octets(&key->Ppube, Ppube) != 1) { error_print(); return -1; } return 1; } int sm9_sign_master_key_generate(SM9_SIGN_MASTER_KEY *msk) { if (!msk) { error_print(); return -1; } // k = rand(1, n-1) if (sm9_z256_rand_range(msk->ks, sm9_z256_order()) != 1) { error_print(); return -1; } // Ppubs = k * P2 in E'(F_p^2) sm9_z256_twist_point_mul_generator(&msk->Ppubs, msk->ks); return 1; } int sm9_enc_master_key_generate(SM9_ENC_MASTER_KEY *msk) { // k = rand(1, n-1) if (sm9_z256_rand_range(msk->ke, sm9_z256_order()) != 1) { error_print(); return -1; } // Ppube = ke * P1 in E(F_p) sm9_z256_point_mul_generator(&msk->Ppube, msk->ke); return 1; } int sm9_sign_master_key_extract_key(SM9_SIGN_MASTER_KEY *msk, const char *id, size_t idlen, SM9_SIGN_KEY *key) { sm9_z256_t t; // t1 = H1(ID || hid, N) + ks sm9_z256_hash1(t, id, idlen, SM9_HID_SIGN); sm9_z256_modn_add(t, t, msk->ks); if (sm9_z256_is_zero(t)) { // TODO: when this happen, the admin should re-generate the MSK. Some speciall error/warning should return on this! error_print(); return -1; } // t2 = ks * t1^-1 sm9_z256_modn_inv(t, t); sm9_z256_modn_mul(t, t, msk->ks); // ds = t2 * P1 sm9_z256_point_mul_generator(&key->ds, t); key->Ppubs = msk->Ppubs; return 1; } int sm9_enc_master_key_extract_key(SM9_ENC_MASTER_KEY *msk, const char *id, size_t idlen, SM9_ENC_KEY *key) { sm9_z256_t t; // t1 = H1(ID || hid, N) + ke sm9_z256_hash1(t, id, idlen, SM9_HID_ENC); sm9_z256_modn_add(t, t, msk->ke); if (sm9_z256_is_zero(t)) { error_print(); return -1; } // t2 = ke * t1^-1 sm9_z256_modn_inv(t, t); sm9_z256_modn_mul(t, t, msk->ke); // de = t2 * P2 sm9_z256_twist_point_mul_generator(&key->de, t); key->Ppube = msk->Ppube; return 1; } int sm9_exch_master_key_extract_key(SM9_EXCH_MASTER_KEY *msk, const char *id, size_t idlen, SM9_EXCH_KEY *key) { sm9_z256_t t; // t1 = H1(ID || hid, N) + ke sm9_z256_hash1(t, id, idlen, SM9_HID_EXCH); sm9_z256_modn_add(t, t, msk->ke); if (sm9_z256_is_zero(t)) { error_print(); return -1; } // t2 = ke * t1^-1 sm9_z256_modn_inv(t, t); sm9_z256_modn_mul(t, t, msk->ke); // de = t2 * P2 sm9_z256_twist_point_mul_generator(&key->de, t); key->Ppube = msk->Ppube; return 1; } #define OID_SM9 oid_sm_algors,302 static uint32_t oid_sm9[] = { OID_SM9 }; static uint32_t oid_sm9sign[] = { OID_SM9,1 }; static uint32_t oid_sm9keyagreement[] = { OID_SM9,2 }; static uint32_t oid_sm9encrypt[] = { OID_SM9,3 }; static const ASN1_OID_INFO sm9_oids[] = { { OID_sm9, "sm9", oid_sm9, sizeof(oid_sm9)/sizeof(int) }, { OID_sm9sign, "sm9sign", oid_sm9sign, sizeof(oid_sm9sign)/sizeof(int) }, { OID_sm9keyagreement, "sm9keyagreement", oid_sm9keyagreement, sizeof(oid_sm9keyagreement)/sizeof(int) }, { OID_sm9encrypt, "sm9encrypt", oid_sm9encrypt, sizeof(oid_sm9encrypt)/sizeof(int) }, }; static const int sm9_oids_count = sizeof(sm9_oids)/sizeof(sm9_oids[0]); const char *sm9_oid_name(int oid) { const ASN1_OID_INFO *info; if (!(info = asn1_oid_info_from_oid(sm9_oids, sm9_oids_count, oid))) { error_print(); return NULL; } return info->name; } int sm9_oid_from_name(const char *name) { const ASN1_OID_INFO *info; if (!(info = asn1_oid_info_from_name(sm9_oids, sm9_oids_count, name))) { error_print(); return OID_undef; } return info->oid; } int sm9_oid_to_der(int oid, uint8_t **out, size_t *outlen) { const ASN1_OID_INFO *info; if (oid == -1) { // FIXME: check if other oid_to_der support this default == -1 behavior return 0; } if (!(info = asn1_oid_info_from_oid(sm9_oids, sm9_oids_count, oid))) { error_print(); return -1; } if (asn1_object_identifier_to_der(info->nodes, info->nodes_cnt, out, outlen) != 1) { error_print(); return -1; } return 1; } int sm9_oid_from_der(int *oid, const uint8_t **in, size_t *inlen) { int ret; const ASN1_OID_INFO *info; if ((ret = asn1_oid_info_from_der(&info, sm9_oids, sm9_oids_count, in, inlen)) != 1) { if (ret < 0) error_print(); else *oid = -1; return ret; } *oid = info->oid; return 1; } int sm9_algor_to_der(int alg, int params, uint8_t **out, size_t *outlen) { size_t len = 0; if (sm9_oid_to_der(alg, NULL, &len) != 1 || sm9_oid_to_der(params, NULL, &len) < 0 || asn1_sequence_header_to_der(len, out, outlen) != 1 || sm9_oid_to_der(alg, out, outlen) != 1 || sm9_oid_to_der(params, out, outlen) < 0) { error_print(); return -1; } return 1; } int sm9_algor_from_der(int *alg, int *params, const uint8_t **in, size_t *inlen) { int ret; const uint8_t *d; size_t dlen; if ((ret = asn1_sequence_from_der(&d, &dlen, in, inlen)) != 1) { if (ret < 0) error_print(); return ret; } if (sm9_oid_from_der(alg, &d, &dlen) != 1 || sm9_oid_from_der(params, &d, &dlen) < 0 || asn1_length_is_zero(dlen) != 1) { error_print(); return -1; } return 1; } static int sm9_private_key_info_to_der(int alg, int params, const uint8_t *prikey, size_t prikey_len, uint8_t **out, size_t *outlen) { size_t len = 0; if (prikey_len > SM9_MAX_PRIVATE_KEY_SIZE) { error_print(); return -1; } if (asn1_int_to_der(PKCS8_private_key_info_version, NULL, &len) != 1 || sm9_algor_to_der(alg, params, NULL, &len) != 1 || asn1_octet_string_to_der(prikey, prikey_len, NULL, &len) != 1 || asn1_sequence_header_to_der(len, out, outlen) != 1 || asn1_int_to_der(PKCS8_private_key_info_version, out, outlen) != 1 || sm9_algor_to_der(alg, params, out, outlen) != 1 || asn1_octet_string_to_der(prikey, prikey_len, out, outlen) != 1) { error_print(); return -1; } //printf("alg %s params %s prikey_len %zu: SM9_PRIVATE_KEY_INFO_SIZE %zu\n", sm9_oid_name(alg), sm9_oid_name(params), prikey_len, *outlen); return 1; } static int sm9_private_key_info_from_der(int *alg, int *params, const uint8_t **prikey, size_t *prikey_len, const uint8_t **in, size_t *inlen) { int ret; const uint8_t *d; size_t dlen; int ver; if ((ret = asn1_sequence_from_der(&d, &dlen, in, inlen)) != 1) { if (ret < 0) error_print(); else error_print(); return ret; } if (asn1_int_from_der(&ver, &d, &dlen) != 1 || sm9_algor_from_der(alg, params, &d, &dlen) != 1 || asn1_octet_string_from_der(prikey, prikey_len, &d, &dlen) != 1 || asn1_length_is_zero(dlen) != 1) { error_print(); return -1; } if (ver != PKCS8_private_key_info_version) { error_print(); return -1; } if (*prikey_len > SM9_MAX_PRIVATE_KEY_SIZE) { error_print(); return -1; } return 1; } static int sm9_private_key_info_encrypt_to_der(int alg, int params, const uint8_t *prikey, size_t prikey_len, const char *pass, uint8_t **out, size_t *outlen) { int ret = -1; uint8_t pkey_info[SM9_MAX_PRIVATE_KEY_INFO_SIZE]; uint8_t *p = pkey_info; size_t pkey_info_len = 0; uint8_t salt[16]; int iter = 65536; uint8_t iv[16]; uint8_t key[16]; SM4_KEY sm4_key; uint8_t enced_pkey_info[sizeof(pkey_info) + 16]; // cbc-padding of pkey_info size_t enced_pkey_info_len; if (sm9_private_key_info_to_der(alg, params, prikey, prikey_len, &p, &pkey_info_len) != 1 || rand_bytes(salt, sizeof(salt)) != 1 || rand_bytes(iv, sizeof(iv)) != 1 || sm3_pbkdf2(pass, strlen(pass), salt, sizeof(salt), iter, sizeof(key), key) != 1) { error_print(); goto end; } sm4_set_encrypt_key(&sm4_key, key); if (sm4_cbc_padding_encrypt(&sm4_key, iv, pkey_info, pkey_info_len, enced_pkey_info, &enced_pkey_info_len) != 1 || pkcs8_enced_private_key_info_to_der(salt, sizeof(salt), iter, sizeof(key), OID_hmac_sm3, OID_sm4_cbc, iv, sizeof(iv), enced_pkey_info, enced_pkey_info_len, out, outlen) != 1) { error_print(); goto end; } //printf("SM9_ENCED_PRIVATE_KEY_INFO_SIZE %zu\n", *outlen); ret = 1; end: gmssl_secure_clear(pkey_info, sizeof(pkey_info)); gmssl_secure_clear(salt, sizeof(salt)); gmssl_secure_clear(iv, sizeof(iv)); gmssl_secure_clear(key, sizeof(key)); return ret; } static int sm9_private_key_info_decrypt_from_der(int *alg, int *params, uint8_t *prikey, size_t *prikey_len, const char *pass, const uint8_t **in, size_t *inlen) { int ret = -1; const uint8_t *salt; size_t saltlen; int iter; int keylen; int prf; int cipher; const uint8_t *iv; size_t ivlen; uint8_t key[16]; SM4_KEY sm4_key; const uint8_t *enced_pkey_info; size_t enced_pkey_info_len; uint8_t pkey_info[SM9_MAX_PRIVATE_KEY_INFO_SIZE]; const uint8_t *cp = pkey_info; size_t pkey_info_len; const uint8_t *cp_prikey; if (pkcs8_enced_private_key_info_from_der(&salt, &saltlen, &iter, &keylen, &prf, &cipher, &iv, &ivlen, &enced_pkey_info, &enced_pkey_info_len, in, inlen) != 1 || asn1_check(keylen == -1 || keylen == 16) != 1 || asn1_check(prf == - 1 || prf == OID_hmac_sm3) != 1 || asn1_check(cipher == OID_sm4_cbc) != 1 || asn1_check(ivlen == 16) != 1 || asn1_length_le(enced_pkey_info_len, sizeof(pkey_info)) != 1) { error_print(); return -1; } if (sm3_pbkdf2(pass, strlen(pass), salt, saltlen, iter, sizeof(key), key) != 1) { error_print(); goto end; } sm4_set_decrypt_key(&sm4_key, key); if (sm4_cbc_padding_decrypt(&sm4_key, iv, enced_pkey_info, enced_pkey_info_len, pkey_info, &pkey_info_len) != 1 || sm9_private_key_info_from_der(alg, params, &cp_prikey, prikey_len, // the const uint8_t *, must be copy outside &cp, &pkey_info_len) != 1 || asn1_length_is_zero(pkey_info_len) != 1) { error_print(); goto end; } memcpy(prikey, cp_prikey, *prikey_len); ret = 1; end: gmssl_secure_clear(&sm4_key, sizeof(sm4_key)); gmssl_secure_clear(key, sizeof(key)); gmssl_secure_clear(pkey_info, sizeof(pkey_info)); return ret; } int sm9_sign_master_key_info_encrypt_to_der(const SM9_SIGN_MASTER_KEY *msk, const char *pass, uint8_t **out, size_t *outlen) { uint8_t buf[SM9_SIGN_MASTER_KEY_MAX_SIZE]; uint8_t *p = buf; size_t len = 0; if (sm9_sign_master_key_to_der(msk, &p, &len) != 1 || sm9_private_key_info_encrypt_to_der(OID_sm9, OID_sm9sign, buf, len, pass, out, outlen) != 1) { error_print(); return -1; } return 1; } int sm9_sign_master_key_info_decrypt_from_der(SM9_SIGN_MASTER_KEY *msk, const char *pass, const uint8_t **in, size_t *inlen) { int ret = -1; int alg, params; uint8_t prikey[SM9_MAX_PRIVATE_KEY_SIZE]; size_t prikey_len; const uint8_t *cp = prikey; if (sm9_private_key_info_decrypt_from_der(&alg, ¶ms, prikey, &prikey_len, pass, in, inlen) != 1) { error_print(); goto end; } if (alg != OID_sm9) { error_print(); goto end; } if (params != OID_sm9sign) { error_print(); goto end; } if (sm9_sign_master_key_from_der(msk, &cp, &prikey_len) != 1 || asn1_length_is_zero(prikey_len) != 1) { error_print(); goto end; } ret = 1; end: gmssl_secure_clear(prikey, sizeof(prikey)); return ret; } int sm9_sign_master_key_info_encrypt_to_pem(const SM9_SIGN_MASTER_KEY *msk, const char *pass, FILE *fp) { uint8_t buf[SM9_MAX_ENCED_PRIVATE_KEY_INFO_SIZE]; uint8_t *p = buf; size_t len = 0; if (sm9_sign_master_key_info_encrypt_to_der(msk, pass, &p, &len) != 1) { error_print(); return -1; } if (pem_write(fp, PEM_SM9_SIGN_MASTER_KEY, buf, len) != 1) { error_print(); return -1; } return 1; } int sm9_sign_master_key_info_decrypt_from_pem(SM9_SIGN_MASTER_KEY *msk, const char *pass, FILE *fp) { uint8_t buf[SM9_MAX_ENCED_PRIVATE_KEY_INFO_SIZE]; const uint8_t *cp = buf; size_t len; if (pem_read(fp, PEM_SM9_SIGN_MASTER_KEY, buf, &len, sizeof(buf)) != 1 || sm9_sign_master_key_info_decrypt_from_der(msk, pass, &cp, &len) != 1 || asn1_length_is_zero(len) != 1) { error_print(); return -1; } return 1; } int sm9_sign_master_public_key_to_pem(const SM9_SIGN_MASTER_KEY *mpk, FILE *fp) { uint8_t buf[SM9_SIGN_MASTER_PUBLIC_KEY_SIZE]; uint8_t *p = buf; size_t len = 0; if (sm9_sign_master_public_key_to_der(mpk, &p, &len) != 1) { error_print(); return -1; } if (pem_write(fp, PEM_SM9_SIGN_MASTER_PUBLIC_KEY, buf, len) != 1) { error_print(); return -1; } return 1; } int sm9_sign_master_public_key_from_pem(SM9_SIGN_MASTER_KEY *mpk, FILE *fp) { uint8_t buf[512]; const uint8_t *cp = buf; size_t len; if (pem_read(fp, PEM_SM9_SIGN_MASTER_PUBLIC_KEY, buf, &len, sizeof(buf)) != 1 || sm9_sign_master_public_key_from_der(mpk, &cp, &len) != 1 || asn1_length_is_zero(len) != 1) { error_print(); return -1; } return 1; } int sm9_sign_key_info_encrypt_to_der(const SM9_SIGN_KEY *key, const char *pass, uint8_t **out, size_t *outlen) { uint8_t buf[SM9_SIGN_KEY_SIZE]; uint8_t *p = buf; size_t len = 0; if (sm9_sign_key_to_der(key, &p, &len) != 1 || sm9_private_key_info_encrypt_to_der(OID_sm9sign, -1, buf, len, pass, out, outlen) != 1) { error_print(); return -1; } return 1; } int sm9_sign_key_info_decrypt_from_der(SM9_SIGN_KEY *key, const char *pass, const uint8_t **in, size_t *inlen) { int ret = -1; int alg, params; uint8_t prikey[512]; size_t prikey_len; const uint8_t *cp = prikey; if (sm9_private_key_info_decrypt_from_der(&alg, ¶ms, prikey, &prikey_len, pass, in, inlen) != 1) { error_print(); goto end; } if (alg != OID_sm9sign) { error_print(); goto end; } if (params != -1) { error_print(); goto end; } if (sm9_sign_key_from_der(key, &cp, &prikey_len) != 1 || asn1_length_is_zero(prikey_len) != 1) { error_print(); goto end; } ret = 1; end: gmssl_secure_clear(prikey, sizeof(prikey)); return ret; } int sm9_sign_key_info_encrypt_to_pem(const SM9_SIGN_KEY *key, const char *pass, FILE *fp) { uint8_t buf[SM9_MAX_ENCED_PRIVATE_KEY_INFO_SIZE]; uint8_t *p = buf; size_t len = 0; if (sm9_sign_key_info_encrypt_to_der(key, pass, &p, &len) != 1) { error_print(); return -1; } if (pem_write(fp, PEM_SM9_SIGN_PRIVATE_KEY, buf, len) != 1) { error_print(); return -1; } return 1; } int sm9_sign_key_info_decrypt_from_pem(SM9_SIGN_KEY *key, const char *pass, FILE *fp) { uint8_t buf[SM9_MAX_ENCED_PRIVATE_KEY_INFO_SIZE]; const uint8_t *cp = buf; size_t len; if (pem_read(fp, PEM_SM9_SIGN_PRIVATE_KEY, buf, &len, sizeof(buf)) != 1 || sm9_sign_key_info_decrypt_from_der(key, pass, &cp, &len) != 1 || asn1_length_is_zero(len) != 1) { error_print(); return -1; } return 1; } int sm9_enc_master_key_info_encrypt_to_der(const SM9_ENC_MASTER_KEY *msk, const char *pass, uint8_t **out, size_t *outlen) { uint8_t buf[256]; uint8_t *p = buf; size_t len = 0; if (sm9_enc_master_key_to_der(msk, &p, &len) != 1 || sm9_private_key_info_encrypt_to_der(OID_sm9, OID_sm9encrypt, buf, len, pass, out, outlen) != 1) { error_print(); return -1; } return 1; } int sm9_enc_master_key_info_decrypt_from_der(SM9_ENC_MASTER_KEY *msk, const char *pass, const uint8_t **in, size_t *inlen) { int ret = -1; int alg, params; uint8_t prikey[512]; size_t prikey_len; const uint8_t *cp = prikey; if (sm9_private_key_info_decrypt_from_der(&alg, ¶ms, prikey, &prikey_len, pass, in, inlen) != 1) { error_print(); goto end; } if (alg != OID_sm9) { error_print(); goto end; } if (params != OID_sm9encrypt) { error_print(); goto end; } if (sm9_enc_master_key_from_der(msk, &cp, &prikey_len) != 1 || asn1_length_is_zero(prikey_len) != 1) { error_print(); goto end; } ret = 1; end: gmssl_secure_clear(prikey, sizeof(prikey)); return ret; } int sm9_enc_master_key_info_encrypt_to_pem(const SM9_ENC_MASTER_KEY *msk, const char *pass, FILE *fp) { uint8_t buf[SM9_MAX_ENCED_PRIVATE_KEY_INFO_SIZE]; uint8_t *p = buf; size_t len = 0; if (sm9_enc_master_key_info_encrypt_to_der(msk, pass, &p, &len) != 1) { error_print(); return -1; } if (pem_write(fp, PEM_SM9_ENC_MASTER_KEY, buf, len) != 1) { error_print(); return -1; } return 1; } int sm9_enc_master_key_info_decrypt_from_pem(SM9_ENC_MASTER_KEY *msk, const char *pass, FILE *fp) { uint8_t buf[SM9_MAX_ENCED_PRIVATE_KEY_INFO_SIZE]; const uint8_t *cp = buf; size_t len; if (pem_read(fp, PEM_SM9_ENC_MASTER_KEY, buf, &len, sizeof(buf)) != 1 || sm9_enc_master_key_info_decrypt_from_der(msk, pass, &cp, &len) != 1 || asn1_length_is_zero(len) != 1) { error_print(); return -1; } return 1; } int sm9_enc_master_public_key_to_pem(const SM9_ENC_MASTER_KEY *mpk, FILE *fp) { uint8_t buf[1024]; uint8_t *p = buf; size_t len = 0; if (sm9_enc_master_public_key_to_der(mpk, &p, &len) != 1) { error_print(); return -1; } if (pem_write(fp, PEM_SM9_ENC_MASTER_PUBLIC_KEY, buf, len) != 1) { error_print(); return -1; } return 1; } int sm9_enc_master_public_key_from_pem(SM9_ENC_MASTER_KEY *mpk, FILE *fp) { uint8_t buf[512]; const uint8_t *cp = buf; size_t len; if (pem_read(fp, PEM_SM9_ENC_MASTER_PUBLIC_KEY, buf, &len, sizeof(buf)) != 1 || sm9_enc_master_public_key_from_der(mpk, &cp, &len) != 1 || asn1_length_is_zero(len) != 1) { error_print(); return -1; } return 1; } int sm9_enc_key_info_encrypt_to_der(const SM9_ENC_KEY *key, const char *pass, uint8_t **out, size_t *outlen) { uint8_t buf[1024]; uint8_t *p = buf; size_t len = 0; if (sm9_enc_key_to_der(key, &p, &len) != 1 || sm9_private_key_info_encrypt_to_der(OID_sm9encrypt, -1, buf, len, pass, out, outlen) != 1) { error_print(); return -1; } return 1; } int sm9_enc_key_info_decrypt_from_der(SM9_ENC_KEY *key, const char *pass, const uint8_t **in, size_t *inlen) { int ret = -1; int alg, params; uint8_t prikey[512]; size_t prikey_len; const uint8_t *cp = prikey; if (sm9_private_key_info_decrypt_from_der(&alg, ¶ms, prikey, &prikey_len, pass, in, inlen) != 1) { error_print(); goto end; } if (alg != OID_sm9encrypt) { error_print(); goto end; } if (params != -1) { error_print(); goto end; } if (sm9_enc_key_from_der(key, &cp, &prikey_len) != 1 || asn1_length_is_zero(prikey_len) != 1) { error_print(); goto end; } ret = 1; end: gmssl_secure_clear(prikey, sizeof(prikey)); return ret; } int sm9_enc_key_info_encrypt_to_pem(const SM9_ENC_KEY *key, const char *pass, FILE *fp) { uint8_t buf[SM9_MAX_ENCED_PRIVATE_KEY_INFO_SIZE]; uint8_t *p = buf; size_t len = 0; if (sm9_enc_key_info_encrypt_to_der(key, pass, &p, &len) != 1) { error_print(); return -1; } if (pem_write(fp, PEM_SM9_ENC_PRIVATE_KEY, buf, len) != 1) { error_print(); return -1; } return 1; } int sm9_enc_key_info_decrypt_from_pem(SM9_ENC_KEY *key, const char *pass, FILE *fp) { uint8_t buf[SM9_MAX_ENCED_PRIVATE_KEY_INFO_SIZE]; const uint8_t *cp = buf; size_t len; if (pem_read(fp, PEM_SM9_ENC_PRIVATE_KEY, buf, &len, sizeof(buf)) != 1 || sm9_enc_key_info_decrypt_from_der(key, pass, &cp, &len) != 1 || asn1_length_is_zero(len) != 1) { error_print(); return -1; } return 1; } int sm9_sign_master_key_print(FILE *fp, int fmt, int ind, const char *label, const SM9_SIGN_MASTER_KEY *msk) { format_print(fp, fmt, ind, "%s\n", label); ind += 4; sm9_z256_print(fp, fmt, ind, "ks", msk->ks); sm9_z256_twist_point_print(fp, fmt, ind, "Ppubs", &msk->Ppubs); return 1; } int sm9_sign_master_public_key_print(FILE *fp, int fmt, int ind, const char *label, const SM9_SIGN_MASTER_KEY *mpk) { format_print(fp, fmt, ind, "%s\n", label); ind += 4; sm9_z256_twist_point_print(fp, fmt, ind, "Ppubs", &mpk->Ppubs); return 1; } int sm9_sign_key_print(FILE *fp, int fmt, int ind, const char *label, const SM9_SIGN_KEY *key) { format_print(fp, fmt, ind, "%s\n", label); ind += 4; sm9_z256_point_print(fp, fmt, ind, "ds", &key->ds); sm9_z256_twist_point_print(fp, fmt, ind, "Ppubs", &key->Ppubs); return 1; } int sm9_enc_master_key_print(FILE *fp, int fmt, int ind, const char *label, const SM9_ENC_MASTER_KEY *msk) { format_print(fp, fmt, ind, "%s\n", label); ind += 4; sm9_z256_print(fp, fmt, ind, "ke", msk->ke); sm9_z256_point_print(fp, fmt, ind, "Ppube", &msk->Ppube); return 1; } int sm9_enc_master_public_key_print(FILE *fp, int fmt, int ind, const char *label, const SM9_ENC_MASTER_KEY *mpk) { format_print(fp, fmt, ind, "%s\n", label); ind += 4; sm9_z256_point_print(fp, fmt, ind, "Ppube", &mpk->Ppube); return 1; } int sm9_enc_key_print(FILE *fp, int fmt, int ind, const char *label, const SM9_ENC_KEY *key) { format_print(fp, fmt, ind, "%s\n", label); ind += 4; sm9_z256_twist_point_print(fp, fmt, ind, "de", &key->de); sm9_z256_point_print(fp, fmt, ind, "Ppube", &key->Ppube); return 1; } int sm9_signature_print(FILE *fp, int fmt, int ind, const char *label, const uint8_t *sig, size_t siglen) { const uint8_t *d; size_t dlen; const uint8_t *p; size_t len; if (asn1_sequence_from_der(&d, &dlen, &sig, &siglen) != 1 || asn1_length_is_zero(siglen) != 1) { error_print(); return -1; } format_print(fp, fmt, ind, "%s\n", label); ind += 4; if (asn1_octet_string_from_der(&p, &len, &d, &dlen) != 1) goto err; format_bytes(fp, fmt, ind, "h", p, len); if (asn1_bit_octets_from_der(&p, &len, &d, &dlen) != 1) goto err; format_bytes(fp, fmt, ind, "S", p, len); if (asn1_length_is_zero(dlen) != 1) goto err; return 1; err: error_print(); return -1; } int sm9_ciphertext_print(FILE *fp, int fmt, int ind, const char *label, const uint8_t *a, size_t alen) { const uint8_t *d; size_t dlen; int val; const uint8_t *p; size_t len; if (asn1_sequence_from_der(&d, &dlen, &a, &alen) != 1 || asn1_length_is_zero(alen) != 1) { error_print(); return -1; } format_print(fp, fmt, ind, "%s\n", label); ind += 4; if (asn1_int_from_der(&val, &d, &dlen) != 1) goto err; format_print(fp, fmt, ind, "EnType: %d\n", val); if (asn1_bit_octets_from_der(&p, &len, &d, &dlen) != 1) goto err; format_bytes(fp, fmt, ind, "C1", p, len); if (asn1_octet_string_from_der(&p, &len, &d, &dlen) != 1) goto err; format_bytes(fp, fmt, ind, "C3", p, len); if (asn1_octet_string_from_der(&p, &len, &d, &dlen) != 1) goto err; format_bytes(fp, fmt, ind, "CipherText", p, len); if (asn1_length_is_zero(dlen) != 1) goto err; return 1; err: error_print(); return -1; }