/* * Copyright 2014-2026 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 #include #include #include int x509_key_set_sm2_key(X509_KEY *x509_key, const SM2_KEY *sm2_key) { if (!x509_key || !sm2_key) { error_print(); return -1; } memset(x509_key, 0, sizeof(X509_KEY)); x509_key->algor = OID_ec_public_key; x509_key->algor_param = OID_sm2; x509_key->u.sm2_key = *sm2_key; return 1; } #ifdef ENABLE_SECP256R1 int x509_key_set_secp256r1_key(X509_KEY *x509_key, const SECP256R1_KEY *secp256r1_key) { if (!x509_key || !secp256r1_key) { error_print(); return -1; } memset(x509_key, 0, sizeof(X509_KEY)); x509_key->algor = OID_ec_public_key; x509_key->algor_param = OID_secp256r1; x509_key->u.secp256r1_key = *secp256r1_key; return 1; } #endif #ifdef ENABLE_LMS int x509_key_set_lms_key(X509_KEY *x509_key, const LMS_KEY *lms_key) { if (!x509_key || !lms_key) { error_print(); return -1; } memset(x509_key, 0, sizeof(X509_KEY)); x509_key->algor = OID_lms_hashsig; x509_key->algor_param = OID_undef; x509_key->u.lms_key = *lms_key; return 1; } int x509_key_set_hss_key(X509_KEY *x509_key, const HSS_KEY *hss_key) { if (!x509_key || !hss_key) { error_print(); return -1; } memset(x509_key, 0, sizeof(X509_KEY)); x509_key->algor = OID_hss_lms_hashsig; x509_key->algor_param = OID_undef; x509_key->u.hss_key = *hss_key; return 1; } #endif #ifdef ENABLE_XMSS int x509_key_set_xmss_key(X509_KEY *x509_key, const XMSS_KEY *xmss_key) { if (!x509_key || !xmss_key) { error_print(); return -1; } memset(x509_key, 0, sizeof(X509_KEY)); x509_key->algor = OID_xmss_hashsig; x509_key->algor_param = OID_undef; x509_key->u.xmss_key = *xmss_key; return 1; } int x509_key_set_xmssmt_key(X509_KEY *x509_key, const XMSSMT_KEY *xmssmt_key) { if (!x509_key || !xmssmt_key) { error_print(); return -1; } memset(x509_key, 0, sizeof(X509_KEY)); x509_key->algor = OID_xmssmt_hashsig; x509_key->algor_param = OID_undef; x509_key->u.xmssmt_key = *xmssmt_key; return 1; } #endif #ifdef ENABLE_SPHINCS int x509_key_set_sphincs_key(X509_KEY *x509_key, const SPHINCS_KEY *sphincs_key) { if (!x509_key || !sphincs_key) { error_print(); return -1; } memset(x509_key, 0, sizeof(X509_KEY)); x509_key->algor = OID_sphincs_hashsig; x509_key->algor_param = OID_undef; x509_key->u.sphincs_key = *sphincs_key; return 1; } #endif #ifdef ENABLE_KYBER int x509_key_set_kyber_key(X509_KEY *x509_key, const KYBER_KEY *kyber_key) { if (!x509_key || !kyber_key) { error_print(); return -1; } memset(x509_key, 0, sizeof(X509_KEY)); x509_key->algor = OID_kyber_kem; x509_key->algor_param = OID_undef; x509_key->u.kyber_key = *kyber_key; return 1; } #endif #ifdef ENABLE_SM9 int x509_key_set_sm9_sign_master_key(X509_KEY *x509_key, const SM9_SIGN_MASTER_KEY *sm9_sign_master_key) { if (!x509_key || !sm9_sign_master_key) { error_print(); return -1; } memset(x509_key, 0, sizeof(X509_KEY)); x509_key->algor = OID_sm9; x509_key->algor_param = OID_sm9sign; x509_key->u.sm9_sign_master_key = *sm9_sign_master_key; return 1; } int x509_key_set_sm9_sign_key(X509_KEY *x509_key, const SM9_SIGN_KEY *sm9_sign_key) { if (!x509_key || !sm9_sign_key) { error_print(); return -1; } memset(x509_key, 0, sizeof(X509_KEY)); x509_key->algor = OID_sm9sign; x509_key->algor_param = OID_undef; x509_key->u.sm9_sign_key = *sm9_sign_key; return 1; } #endif int x509_key_generate(X509_KEY *key, int algor, const void *param, size_t paramlen) { int param_val; if (!key) { error_print(); return -1; } memset(key, 0, sizeof(X509_KEY)); key->algor = algor; key->algor_param = OID_undef; switch (algor) { case OID_ec_public_key: #ifdef ENABLE_LMS case OID_lms_hashsig: #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: case OID_xmssmt_hashsig: #endif if (!param) { error_print(); return -1; } if (paramlen != sizeof(int)) { error_print(); return -1; } param_val = *(const int *)param; break; #ifdef ENABLE_LMS case OID_hss_lms_hashsig: if (!param) { error_print(); return -1; } if (paramlen < sizeof(int)) { error_print(); return -1; } if (paramlen % sizeof(int)) { error_print(); return -1; } break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: if (param || paramlen) { error_print(); return -1; } break; #endif #ifdef ENABLE_KYBER case OID_kyber_kem: if (param && paramlen != 32) { error_print(); return -1; } break; #endif default: error_print(); return -1; } switch (algor) { case OID_ec_public_key: switch (param_val) { case OID_sm2: if (sm2_key_generate(&key->u.sm2_key) != 1) { error_print(); return -1; } break; #ifdef ENABLE_SECP256R1 case OID_secp256r1: if (secp256r1_key_generate(&key->u.secp256r1_key) != 1) { error_print(); return -1; } break; #endif default: error_print(); return -1; } key->algor_param = param_val; break; #ifdef ENABLE_LMS case OID_lms_hashsig: if (lms_key_generate(&key->u.lms_key, param_val) != 1) { error_print(); return -1; } break; case OID_hss_lms_hashsig: if (hss_key_generate(&key->u.hss_key, (int *)param, paramlen/sizeof(int)) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if (xmss_key_generate(&key->u.xmss_key, param_val) != 1) { error_print(); return -1; } break; case OID_xmssmt_hashsig: if (xmssmt_key_generate(&key->u.xmssmt_key, param_val) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: if (sphincs_key_generate(&key->u.sphincs_key) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_KYBER case OID_kyber_kem: if (kyber_key_generate_ex(&key->u.kyber_key, (uint8_t *)param) != 1) { error_print(); return -1; } break; #endif default: error_print(); return -1; } return 1; } void x509_key_cleanup(X509_KEY *key) { if (key) { switch (key->algor) { case OID_ec_public_key: switch (key->algor_param) { case OID_sm2: gmssl_secure_clear(&key->u.sm2_key, sizeof(SM2_KEY)); break; #ifdef ENABLE_SECP256R1 case OID_secp256r1: secp256r1_key_cleanup(&key->u.secp256r1_key); break; #endif default: error_print(); return; } break; #ifdef ENABLE_LMS case OID_lms_hashsig: lms_key_cleanup(&key->u.lms_key); break; case OID_hss_lms_hashsig: hss_key_cleanup(&key->u.hss_key); break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: xmss_key_cleanup(&key->u.xmss_key); break; case OID_xmssmt_hashsig: xmssmt_key_cleanup(&key->u.xmssmt_key); break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: sphincs_key_cleanup(&key->u.sphincs_key); break; #endif #ifdef ENABLE_KYBER case OID_kyber_kem: kyber_key_cleanup(&key->u.kyber_key); break; #endif #ifdef ENABLE_SM9 case OID_sm9: switch (key->algor_param) { case OID_sm9sign: gmssl_secure_clear(&key->u.sm9_sign_master_key, sizeof(SM9_SIGN_MASTER_KEY)); break; default: error_print(); return; } break; case OID_sm9sign: gmssl_secure_clear(&key->u.sm9_sign_key, sizeof(SM9_SIGN_KEY)); break; #endif default: error_print(); } memset(key, 0, sizeof(X509_KEY)); } } int x509_public_key_to_bytes(const X509_KEY *key, uint8_t **out, size_t *outlen) { if (!key || !outlen) { error_print(); return -1; } switch (key->algor) { case OID_ec_public_key: switch (key->algor_param) { case OID_sm2: if (out && *out) { sm2_z256_point_to_uncompressed_octets(&key->u.sm2_key.public_key, *out); *out += 65; } *outlen += 65; break; #ifdef ENABLE_SECP256R1 case OID_secp256r1: if (secp256r1_public_key_to_bytes(&key->u.secp256r1_key, out, outlen) != 1) { error_print(); return -1; } break; #endif default: error_print(); return -1; } break; #ifdef ENABLE_LMS case OID_lms_hashsig: if (lms_public_key_to_bytes(&key->u.lms_key, out, outlen) != 1) { error_print(); return -1; } break; case OID_hss_lms_hashsig: if (hss_public_key_to_bytes(&key->u.hss_key, out, outlen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if (xmss_public_key_to_bytes(&key->u.xmss_key, out, outlen) != 1) { error_print(); return -1; } break; case OID_xmssmt_hashsig: if (xmssmt_public_key_to_bytes(&key->u.xmssmt_key, out, outlen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: if (sphincs_public_key_to_bytes(&key->u.sphincs_key, out, outlen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_KYBER case OID_kyber_kem: if (kyber_public_key_to_bytes(&key->u.kyber_key, out, outlen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SM9 case OID_sm9: switch (key->algor_param) { case OID_sm9sign: if (sm9_sign_master_public_key_to_bytes(&key->u.sm9_sign_master_key, out, outlen) != 1) { error_print(); return -1; } break; default: error_print(); return -1; } break; case OID_sm9sign: error_print(); return -1; #endif default: error_print(); return -1; } return 1; } int x509_public_key_from_bytes(X509_KEY *key, int algor, int algor_param, const uint8_t **in, size_t *inlen) { if (!key || !in || !(*in) || !inlen) { error_print(); return -1; } memset(key, 0, sizeof(X509_KEY)); key->algor = algor; key->algor_param = algor_param; switch (algor) { case OID_ec_public_key: if (*inlen < 65) { error_print(); return -1; } switch (algor_param) { case OID_sm2: if (sm2_z256_point_from_octets(&key->u.sm2_key.public_key, *in, 65) != 1) { error_print(); return -1; } *in += 65; *inlen -= 65; break; #ifdef ENABLE_SECP256R1 case OID_secp256r1: if (secp256r1_public_key_from_bytes(&key->u.secp256r1_key, in, inlen) != 1) { error_print(); return -1; } break; #endif default: error_print(); return -1; } return 1; } if (algor_param != OID_undef) { error_print(); return -1; } switch (algor) { #ifdef ENABLE_LMS case OID_lms_hashsig: if (lms_public_key_from_bytes(&key->u.lms_key, in, inlen) != 1) { error_print(); return -1; } break; case OID_hss_lms_hashsig: if (hss_public_key_from_bytes(&key->u.hss_key, in, inlen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if (xmss_public_key_from_bytes(&key->u.xmss_key, in, inlen) != 1) { error_print(); return -1; } break; case OID_xmssmt_hashsig: if (xmssmt_public_key_from_bytes(&key->u.xmssmt_key, in, inlen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: if (sphincs_public_key_from_bytes(&key->u.sphincs_key, in, inlen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_KYBER case OID_kyber_kem: if (kyber_public_key_from_bytes(&key->u.kyber_key, in, inlen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SM9 case OID_sm9: switch (key->algor_param) { case OID_sm9sign: if (sm9_sign_master_public_key_from_bytes(&key->u.sm9_sign_master_key, in, inlen) != 1) { error_print(); return -1; } break; default: error_print(); return -1; } break; case OID_sm9sign: error_print(); return -1; #endif default: error_print(); return -1; } return 1; } int x509_public_key_digest_ex(const X509_KEY *key, const DIGEST *digest_algor, uint8_t *dgst, size_t *dgstlen) { uint8_t bits[X509_PUBLIC_KEY_MAX_SIZE]; uint8_t *p = bits; size_t len = 0; if (!digest_algor || !dgst || !dgstlen) { error_print(); return -1; } if (x509_public_key_to_bytes(key, &p, &len) != 1 || digest(digest_algor, bits, len, dgst, dgstlen) != 1) { error_print(); return -1; } return 1; } int x509_public_key_digest(const X509_KEY *key, uint8_t dgst[32]) { size_t dgstlen; if (x509_public_key_digest_ex(key, DIGEST_sm3(), dgst, &dgstlen) != 1 || dgstlen != 32) { error_print(); return -1; } return 1; } int x509_public_key_equ(const X509_KEY *key, const X509_KEY *pub) { int ret; if (!key || !pub) { error_print(); return -1; } if (key->algor != pub->algor) { error_print(); return 0; } if (key->algor_param != pub->algor_param) { error_print(); return 0; } switch (key->algor) { case OID_ec_public_key: if (key->algor_param == OID_sm2) { if ((ret = sm2_public_key_equ(&key->u.sm2_key, &pub->u.sm2_key)) != 1) { error_print(); return ret; } #ifdef ENABLE_SECP256R1 } else if (key->algor_param == OID_secp256r1) { if ((ret = secp256r1_public_key_equ(&key->u.secp256r1_key, &pub->u.secp256r1_key)) != 1) { error_print(); return ret; } #endif } else { error_print(); return -1; } return 1; #ifdef ENABLE_LMS case OID_hss_lms_hashsig: if ((ret = hss_public_key_equ(&key->u.hss_key, &pub->u.hss_key)) != 1) { error_print(); return ret; } return 1; #endif } // sizeof(XXX_PUBLIC_KEY) >= XXX_PUBLIC_KEY_SIZE, depends on compiler switch (key->algor) { #ifdef ENABLE_LMS case OID_lms_hashsig: if (memcmp(&key->u.lms_key, &pub->u.lms_key, sizeof(LMS_PUBLIC_KEY)) != 0) { error_print(); return 0; } break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if (memcmp(&key->u.xmss_key, &pub->u.xmss_key, sizeof(XMSS_PUBLIC_KEY)) != 0) { error_print(); return 0; } break; case OID_xmssmt_hashsig: if (memcmp(&key->u.xmssmt_key, &pub->u.xmssmt_key, sizeof(XMSSMT_PUBLIC_KEY)) != 0) { error_print(); return 0; } break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: if (memcmp(&key->u.sphincs_key, &pub->u.sphincs_key, sizeof(SPHINCS_PUBLIC_KEY)) != 0) { error_print(); return 0; } break; #endif #ifdef ENABLE_KYBER case OID_kyber_kem: if (memcmp(&key->u.kyber_key, &pub->u.kyber_key, sizeof(KYBER_PUBLIC_KEY)) != 0) { error_print(); return 0; } break; #endif #ifdef ENABLE_SM9 case OID_sm9: switch (key->algor_param) { case OID_sm9sign: if (memcmp(&key->u.sm9_sign_master_key, &pub->u.sm9_sign_master_key, sizeof(SM9_SIGN_MASTER_KEY)) != 0) { error_print(); return 0; } break; default: error_print(); return -1; } break; case OID_sm9sign: if (memcmp(&key->u.sm9_sign_key, &pub->u.sm9_sign_key, sizeof(SM9_SIGN_KEY)) != 0) { error_print(); return 0; } break; #endif default: error_print(); return -1; } return 1; } int x509_public_key_print(FILE *fp, int fmt, int ind, const char *label, const X509_KEY *key) { switch (key->algor) { case OID_ec_public_key: if (key->algor_param == OID_sm2) { if (sm2_public_key_print(fp, fmt, ind, label, &key->u.sm2_key) != 1) { error_print(); return -1; } #ifdef ENABLE_SECP256R1 } else if (key->algor_param == OID_secp256r1) { if (secp256r1_public_key_print(fp, fmt, ind, label, &key->u.secp256r1_key) != 1) { error_print(); return -1; } #endif } else { error_print(); return -1; } break; #ifdef ENABLE_LMS case OID_lms_hashsig: if (lms_public_key_print(fp, fmt, ind, label, &key->u.lms_key) != 1) { error_print(); return -1; } break; case OID_hss_lms_hashsig: if (hss_public_key_print(fp, fmt, ind, label, &key->u.hss_key) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if (xmss_public_key_print(fp, fmt, ind, label, &key->u.xmss_key) != 1) { error_print(); return -1; } break; case OID_xmssmt_hashsig: if (xmssmt_public_key_print(fp, fmt, ind, label, &key->u.xmssmt_key) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: if (sphincs_public_key_print(fp, fmt, ind, label, &key->u.sphincs_key) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_KYBER case OID_kyber_kem: if (kyber_public_key_print(fp, fmt, ind, label, &key->u.kyber_key) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SM9 case OID_sm9: switch (key->algor_param) { case OID_sm9sign: if (sm9_sign_master_public_key_print(fp, fmt, ind, label, &key->u.sm9_sign_master_key) != 1) { error_print(); return -1; } break; default: error_print(); return -1; } break; case OID_sm9sign: // TODO: no public key, do we need print ID? error_print(); return -1; #endif default: error_print(); return -1; } return 1; } int x509_public_key_info_to_der(const X509_KEY *x509_key, uint8_t **out, size_t *outlen) { uint8_t keybuf[X509_PUBLIC_KEY_MAX_SIZE]; uint8_t *p = keybuf; size_t keylen = 0; size_t len = 0; if (!x509_key || !outlen) { error_print(); return -1; } if (x509_public_key_to_bytes(x509_key, &p, &keylen) != 1) { error_print(); return -1; } if (x509_public_key_algor_to_der(x509_key->algor, x509_key->algor_param, NULL, &len) != 1 || asn1_bit_octets_to_der(keybuf, keylen, NULL, &len) != 1 || asn1_sequence_header_to_der(len, out, outlen) != 1 || x509_public_key_algor_to_der(x509_key->algor, x509_key->algor_param, out, outlen) != 1 || asn1_bit_octets_to_der(keybuf, keylen, out, outlen) != 1) { error_print(); return -1; } return 1; } int x509_public_key_info_from_der(X509_KEY *x509_key, const uint8_t **in, size_t *inlen) { int ret; const uint8_t *d; size_t dlen; int algor; int algor_param; const uint8_t *pub; size_t publen; if (!x509_key || !in || !(*in) || !inlen) { error_print(); return -1; } if ((ret = asn1_sequence_from_der(&d, &dlen, in, inlen)) != 1) { if (ret < 0) error_print(); return ret; } if (x509_public_key_algor_from_der(&algor, &algor_param, &d, &dlen) != 1 || asn1_bit_octets_from_der(&pub, &publen, &d, &dlen) != 1 || asn1_length_is_zero(dlen) != 1) { error_print(); return -1; } if (x509_public_key_from_bytes(x509_key, algor, algor_param, &pub, &publen) != 1) { error_print(); return -1; } if (publen) { error_print(); return -1; } return 1; } int x509_public_key_info_to_pem(const X509_KEY *a, FILE *fp) { uint8_t buf[512]; uint8_t *p = buf; size_t len = 0; if (x509_public_key_info_to_der(a, &p, &len) != 1) { error_print(); return -1; } if (pem_write(fp, "PUBLIC KEY", buf, len) <= 0) { error_print(); return -1; } return 1; } int x509_public_key_info_from_pem(X509_KEY *a, FILE *fp) { uint8_t buf[512]; const uint8_t *cp = buf; size_t len; if (pem_read(fp, "PUBLIC KEY", buf, &len, sizeof(buf)) != 1) { error_print(); return -1; } if (x509_public_key_info_from_der(a, &cp, &len) != 1 || asn1_length_is_zero(len) != 1) { error_print(); return -1; } return 1; } int x509_public_key_info_print(FILE *fp, int fmt, int ind, const char *label, const uint8_t *d, size_t dlen) { const uint8_t *p = d; size_t len = dlen; int alg; int params; format_print(fp, fmt, ind, "%s\n", label); ind += 4; if (x509_public_key_algor_from_der(&alg, ¶ms, &p, &len) != 1) goto err; if (asn1_sequence_from_der(&p, &len, &d, &dlen) != 1) goto err; x509_public_key_algor_print(fp, fmt, ind, "algorithm", p, len); format_print(fp, fmt, ind, "subjectPublicKey\n"); ind += 4; if (asn1_bit_octets_from_der(&p, &len, &d, &dlen) != 1) goto err; switch (alg) { case OID_ec_public_key: format_bytes(fp, fmt, ind, "ECPoint", p, len); break; case OID_rsa_encryption: rsa_public_key_print(fp, fmt, ind, "RSAPublicKey", p, len); break; #ifdef ENABLE_SM9 case OID_sm9: error_print(); break; #endif #ifdef ENABLE_LMS case OID_lms_hashsig: case OID_hss_lms_hashsig: #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: case OID_xmssmt_hashsig: #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: #endif #ifdef ENABLE_KYBER case OID_kyber_kem: #endif // TODO: print public key without too much details default: format_bytes(fp, fmt, ind, "raw_data", p, len); } if (asn1_length_is_zero(dlen) != 1) goto err; return 1; err: error_print(); return -1; } int x509_private_key_print_ex(FILE *fp, int fmt, int ind, const char *label, const X509_KEY *key) { // TODO: change lms_private_key_print to lms_private_key_print_ex and xmss ... error_print(); return -1; } #define SM2_PRIVATE_KEY_DER_SIZE 121 int ec_private_key_to_der(const X509_KEY *key, int encode_params, int encode_pubkey, uint8_t **out, size_t *outlen) { uint8_t params_buf[16]; // = 10 for sm2, p256 uint8_t pubkey_buf[68]; // = 68 for sm2, p256 uint8_t *params = NULL; uint8_t *pubkey = NULL; size_t params_len = 0; size_t pubkey_len = 0; uint8_t prikey[32]; size_t len = 0; if (!key) { error_print(); return -1; } if (key->algor != OID_ec_public_key) { error_print(); return -1; } if (encode_params) { params = params_buf; if (ec_named_curve_to_der(key->algor_param, ¶ms, ¶ms_len) != 1) { gmssl_secure_clear(prikey, 32); error_print(); return -1; } params = params_buf; } switch (key->algor_param) { case OID_sm2: if (encode_pubkey) { pubkey = pubkey_buf; if (sm2_public_key_to_der(&key->u.sm2_key, &pubkey, &pubkey_len) != 1) { error_print(); return -1; } pubkey = pubkey_buf; } sm2_z256_to_bytes(key->u.sm2_key.private_key, prikey); break; #ifdef ENABLE_SECP256R1 case OID_secp256r1: if (encode_pubkey) { pubkey = pubkey_buf; if (secp256r1_public_key_to_der(&key->u.secp256r1_key, &pubkey, &pubkey_len) != 1) { error_print(); return -1; } pubkey = pubkey_buf; } secp256r1_to_32bytes(key->u.secp256r1_key.private_key, prikey); break; #endif default: error_print(); return -1; } if (asn1_int_to_der(EC_private_key_version, NULL, &len) != 1 || asn1_octet_string_to_der(prikey, 32, NULL, &len) != 1 || asn1_explicit_to_der(0, params, params_len, NULL, &len) < 0 || asn1_explicit_to_der(1, pubkey, pubkey_len, NULL, &len) < 0 || asn1_sequence_header_to_der(len, out, outlen) != 1 || asn1_int_to_der(EC_private_key_version, out, outlen) != 1 || asn1_octet_string_to_der(prikey, 32, out, outlen) != 1 || asn1_explicit_to_der(0, params, params_len, out, outlen) < 0 || asn1_explicit_to_der(1, pubkey, pubkey_len, out, outlen) < 0) { gmssl_secure_clear(prikey, 32); error_print(); return -1; } gmssl_secure_clear(prikey, 32); return 1; } // when params(curve) is omitted in ECPrivateKey, curve should be given explicitly int ec_private_key_from_der(X509_KEY *key, int opt_curve, const uint8_t **in, size_t *inlen) { int ret; const uint8_t *d; size_t dlen; int ver; const uint8_t *prikey; const uint8_t *params; const uint8_t *pubkey; size_t prikey_len, params_len, pubkey_len; int curve; if (!key || !in || !(*in) || !inlen) { error_print(); return -1; } if ((ret = asn1_sequence_from_der(&d, &dlen, in, inlen)) != 1) { if (ret < 0) error_print(); return ret; } if (asn1_int_from_der(&ver, &d, &dlen) != 1 || asn1_octet_string_from_der(&prikey, &prikey_len, &d, &dlen) != 1 || asn1_explicit_from_der(0, ¶ms, ¶ms_len, &d, &dlen) < 0 || asn1_explicit_from_der(1, &pubkey, &pubkey_len, &d, &dlen) < 0 || asn1_check(ver == EC_private_key_version) != 1 || asn1_length_is_zero(dlen) != 1) { error_print(); return -1; } if (!prikey || prikey_len != 32) { error_print(); return -1; } if (params) { if (ec_named_curve_from_der(&curve, ¶ms, ¶ms_len) != 1 || asn1_length_is_zero(params_len) != 1) { error_print(); return -1; } if (curve != opt_curve && opt_curve != OID_undef) { error_print(); return -1; } } else { curve = opt_curve; } memset(key, 0, sizeof(X509_KEY)); if (curve == OID_sm2) { sm2_z256_t sm2_private; SM2_KEY sm2_pub; sm2_z256_from_bytes(sm2_private, prikey); if (sm2_key_set_private_key(&key->u.sm2_key, sm2_private) != 1) { gmssl_secure_clear(sm2_private, sizeof(sm2_z256_t)); error_print(); return -1; } gmssl_secure_clear(sm2_private, sizeof(sm2_z256_t)); if (pubkey) { if (sm2_public_key_from_der(&sm2_pub, &pubkey, &pubkey_len) != 1 || asn1_length_is_zero(pubkey_len) != 1) { error_print(); return -1; } if (sm2_public_key_equ(&key->u.sm2_key, &sm2_pub) != 1) { gmssl_secure_clear(&key->u.sm2_key, sizeof(SM2_KEY)); // sm2_key_cleanup? error_print(); return -1; } } } #ifdef ENABLE_SECP256R1 else if (curve == OID_secp256r1) { secp256r1_t p256_private; SECP256R1_KEY p256_pub; secp256r1_from_32bytes(p256_private, prikey); if (secp256r1_key_set_private_key(&key->u.secp256r1_key, p256_private) != 1) { gmssl_secure_clear(p256_private, sizeof(secp256r1_t)); error_print(); return -1; } gmssl_secure_clear(p256_private, sizeof(secp256r1_t)); if (pubkey) { if (secp256r1_public_key_from_der(&p256_pub, &pubkey, &pubkey_len) != 1 || asn1_length_is_zero(pubkey_len) != 1) { error_print(); return -1; } if (secp256r1_public_key_equ(&key->u.secp256r1_key, &p256_pub) != 1) { secp256r1_key_cleanup(&key->u.secp256r1_key); error_print(); return -1; } } } #endif else { error_print(); return -1; } key->algor = OID_ec_public_key; key->algor_param = curve; return 1; } int x509_private_key_info_print(FILE *fp, int fmt, int ind, const char *label, const uint8_t *d, size_t dlen) { if (sm2_private_key_info_print(fp, fmt, ind, label, d, dlen) != 1) { error_print(); return -1; } return 1; } int x509_private_key_info_to_der(const X509_KEY *key, uint8_t **out, size_t *outlen) { uint8_t private_key[128]; // 121 uint8_t *p = private_key; size_t private_key_len = 0; size_t len = 0; if (!key || !outlen) { error_print(); return -1; } switch (key->algor) { case OID_ec_public_key: if (ec_private_key_to_der(key, X509_ENCODE_EC_PRIVATE_KEY_PARAMS, X509_ENCODE_EC_PRIVATE_KEY_PUBKEY, &p, &private_key_len) != 1) { error_print(); return -1; } break; case OID_lms_hashsig: case OID_hss_lms_hashsig: case OID_xmss_hashsig: case OID_xmssmt_hashsig: case OID_sphincs_hashsig: case OID_kyber_kem: #ifdef ENABLE_SM9 case OID_sm9: #endif // TODO: support these algors, (MUST change private_key[] size)! default: error_print(); return -1; } if (asn1_int_to_der(PKCS8_private_key_info_version, NULL, &len) != 1 || x509_public_key_algor_to_der(key->algor, key->algor_param, NULL, &len) != 1 || asn1_octet_string_to_der(private_key, private_key_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 || x509_public_key_algor_to_der(key->algor, key->algor_param, out, outlen) != 1 || asn1_octet_string_to_der(private_key, private_key_len, out, outlen) != 1) { gmssl_secure_clear(private_key, private_key_len); error_print(); return -1; } gmssl_secure_clear(private_key, private_key_len); return 1; } int x509_private_key_info_from_der(X509_KEY *key, const uint8_t **attrs, size_t *attrslen, const uint8_t **in, size_t *inlen) { int ret; const uint8_t *d; size_t dlen; int version; int algor; int algor_param; const uint8_t *private_key; size_t private_key_len; if (!key || !attrs || !attrslen || !in || !(*in) || !inlen) { error_print(); return -1; } if ((ret = asn1_sequence_from_der(&d, &dlen, in, inlen)) != 1) { if (ret < 0) error_print(); if (ret == 0) error_print(); return ret; } if (asn1_int_from_der(&version, &d, &dlen) != 1 || x509_public_key_algor_from_der(&algor, &algor_param, &d, &dlen) != 1 || asn1_octet_string_from_der(&private_key, &private_key_len, &d, &dlen) != 1 || asn1_implicit_set_from_der(0, attrs, attrslen, &d, &dlen) < 0 || asn1_check(version == PKCS8_private_key_info_version) != 1 || asn1_length_is_zero(dlen) != 1) { error_print(); return -1; } switch (algor) { case OID_ec_public_key: if (ec_private_key_from_der(key, algor_param, &private_key, &private_key_len) != 1 || asn1_length_is_zero(private_key_len) != 1) { error_print(); return -1; } break; #ifdef ENABLE_SM9 case OID_sm9sign: if (algor_param != OID_undef) { error_print(); return -1; } memset(key, 0, sizeof(X509_KEY)); key->algor = algor; key->algor_param = algor_param; if (sm9_sign_key_from_der(&key->u.sm9_sign_key, &private_key, &private_key_len) != 1 || asn1_length_is_zero(private_key_len) != 1) { error_print(); return -1; } break; #endif case OID_lms_hashsig: case OID_hss_lms_hashsig: case OID_xmss_hashsig: case OID_xmssmt_hashsig: case OID_sphincs_hashsig: case OID_kyber_kem: #ifdef ENABLE_SM9 case OID_sm9: #endif default: error_print(); return -1; } return 1; } int x509_private_key_info_encrypt_to_der(const X509_KEY *x509_key, const char *pass, uint8_t **out, size_t *outlen) { int ret = -1; uint8_t private_key_info[168]; // 150 uint8_t *p = private_key_info; size_t private_key_info_len = 0; uint8_t salt[16]; int iter = PKCS8_ENCED_PRIVATE_KEY_INFO_ITER; uint8_t iv[16]; uint8_t key[16]; SM4_KEY sm4_key; uint8_t enced_private_key_info[sizeof(private_key_info) + 32]; size_t enced_private_key_info_len; if (!x509_key || !pass || !outlen) { error_print(); return -1; } if (rand_bytes(salt, sizeof(salt)) != 1 || rand_bytes(iv, sizeof(iv)) != 1) { error_print(); return -1; } if (sm3_pbkdf2(pass, strlen(pass), salt, sizeof(salt), iter, sizeof(key), key) != 1) { error_print(); return -1; } if (x509_private_key_info_to_der(x509_key, &p, &private_key_info_len) != 1) { error_print(); goto end; } sm4_set_encrypt_key(&sm4_key, key); if (sm4_cbc_padding_encrypt(&sm4_key, iv, private_key_info, private_key_info_len, enced_private_key_info, &enced_private_key_info_len) != 1) { error_print(); goto end; } if (pkcs8_enced_private_key_info_to_der(salt, sizeof(salt), iter, sizeof(key), OID_hmac_sm3, OID_sm4_cbc, iv, sizeof(iv), enced_private_key_info, enced_private_key_info_len, out, outlen) != 1) { error_print(); goto end; } ret = 1; end: gmssl_secure_clear(private_key_info, sizeof(private_key_info)); gmssl_secure_clear(key, sizeof(key)); gmssl_secure_clear(&sm4_key, sizeof(sm4_key)); return ret; } int x509_private_key_info_decrypt_from_der(X509_KEY *x509_key, const uint8_t **attrs, size_t *attrs_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_private_key_info; size_t enced_private_key_info_len; // 160 uint8_t private_key_info[168]; const uint8_t *cp = private_key_info; size_t private_key_info_len; if (!x509_key || !attrs || !attrs_len || !pass || !in || !(*in) || !inlen) { error_print(); return -1; } if (pkcs8_enced_private_key_info_from_der(&salt, &saltlen, &iter, &keylen, &prf, &cipher, &iv, &ivlen, &enced_private_key_info, &enced_private_key_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_private_key_info_len, sizeof(private_key_info)) != 1) { error_print(); return -1; } if (enced_private_key_info_len > sizeof(private_key_info)) { // sm4_cbc_padding_decrypt might buffer overflow 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_private_key_info, enced_private_key_info_len, private_key_info, &private_key_info_len) != 1) { error_print(); goto end; } if (x509_private_key_info_from_der(x509_key, attrs, attrs_len, &cp, &private_key_info_len) != 1) { error_print(); goto end; } if (asn1_length_is_zero(private_key_info_len) != 1) { error_print(); goto end; } ret = 1; end: gmssl_secure_clear(&sm4_key, sizeof(sm4_key)); gmssl_secure_clear(key, sizeof(key)); gmssl_secure_clear(private_key_info, sizeof(private_key_info)); return ret; } int x509_private_key_info_encrypt_to_pem(const X509_KEY *key, const char *pass, FILE *fp) { uint8_t buf[1024]; uint8_t *p = buf; size_t len = 0; if (!fp) { error_print(); return -1; } if (x509_private_key_info_encrypt_to_der(key, pass, &p, &len) != 1) { error_print(); return -1; } if (pem_write(fp, "ENCRYPTED PRIVATE KEY", buf, len) != 1) { error_print(); return -1; } return 1; } int x509_private_key_info_decrypt_from_pem(X509_KEY *key, const uint8_t **attrs, size_t *attrslen, const char *pass, FILE *fp) { int ret; uint8_t buf[512]; const uint8_t *cp = buf; size_t len; if (!key || !pass || !fp) { error_print(); return -1; } if ((ret = pem_read(fp, "ENCRYPTED PRIVATE KEY", buf, &len, sizeof(buf))) < 0) { error_print(); return -1; } else if (ret == 0) { return 0; } if (x509_private_key_info_decrypt_from_der(key, attrs, attrslen, pass, &cp, &len) != 1 || asn1_length_is_zero(len) != 1) { error_print(); return -1; } return 1; } int x509_private_key_from_file(X509_KEY *key, int algor, const char *pass, FILE *fp) { if (!key || !fp) { error_print(); return -1; } if (algor == OID_ec_public_key) { int ret; const uint8_t *attrs; size_t attrslen; if (!pass) { error_print(); return -1; } if ((ret = x509_private_key_info_decrypt_from_pem(key, &attrs, &attrslen, pass, fp)) < 0) { error_print(); return -1; } else if (ret == 0) { return 0; // TODO: support return 0 for other algors } } #ifdef ENABLE_LMS else if (algor == OID_lms_hashsig) { uint8_t buf[LMS_PRIVATE_KEY_SIZE]; const uint8_t *cp = buf; size_t len = sizeof(buf); if (fread(buf, 1, len, fp) != len) { error_print(); return -1; } if (lms_private_key_from_bytes(&key->u.lms_key, &cp, &len) != 1) { error_print(); return -1; } if (len) { error_print(); return -1; } } else if (algor == OID_hss_lms_hashsig) { uint8_t buf[HSS_PRIVATE_KEY_MAX_SIZE]; const uint8_t *cp = buf; size_t len = sizeof(buf); if ((len = fread(buf, 1, len, fp)) <= 0) { error_print(); return -1; } if (hss_private_key_from_bytes(&key->u.hss_key, &cp, &len) != 1) { error_print(); return -1; } if (len) { error_print(); return -1; } } #endif #ifdef ENABLE_XMSS else if (algor == OID_xmss_hashsig) { if (xmss_private_key_from_file(&key->u.xmss_key, fp) != 1) { error_print(); return -1; } } else if (algor == OID_xmssmt_hashsig) { if (xmssmt_private_key_from_file(&key->u.xmssmt_key, fp) != 1) { error_print(); return -1; } } #endif #ifdef ENABLE_SPHINCS else if (algor == OID_sphincs_hashsig) { uint8_t buf[SPHINCS_PRIVATE_KEY_SIZE]; const uint8_t *cp = buf; size_t len = sizeof(buf); if (fread(buf, 1, len, fp) != len) { error_print(); return -1; } if (sphincs_private_key_from_bytes(&key->u.sphincs_key, &cp, &len) != 1) { error_print(); return -1; } if (len) { error_print(); return -1; } } #endif #ifdef ENABLE_KYBER else if (algor == OID_kyber_kem) { uint8_t buf[KYBER_PRIVATE_KEY_SIZE]; const uint8_t *cp = buf; size_t len = sizeof(buf); if (fread(buf, 1, len, fp) != len) { error_print(); return -1; } if (kyber_private_key_from_bytes(&key->u.kyber_key, &cp, &len) != 1) { error_print(); return -1; } if (len) { error_print(); return -1; } } #endif else { error_print(); return -1; } return 1; } int x509_private_keys_from_file(X509_KEY *keys, size_t *keys_cnt, size_t max_cnt, int algor, const char *pass, FILE *fp) { size_t i; if (!keys || !keys_cnt || !pass || !fp) { error_print(); return -1; } for (i = 0; i < max_cnt; i++) { int ret; if ((ret = x509_private_key_from_file(&keys[i], algor, pass, fp)) < 0) { error_print(); return -1; } else if (ret == 0) { break; } } *keys_cnt = i; if (i == 0) { return 0; } return 1; } int x509_key_get_sign_algor(const X509_KEY *key, int *algor) { if (!key || !algor) { error_print(); return -1; } switch (key->algor) { case OID_ec_public_key: switch (key->algor_param) { case OID_sm2: *algor = OID_sm2sign_with_sm3; break; #ifdef ENABLE_SECP256R1 case OID_secp256r1: *algor = OID_ecdsa_with_sha256; break; #endif default: error_print(); return -1; } break; #ifdef ENABLE_SM9 case OID_sm9: switch (key->algor_param) { case OID_sm9sign: *algor = OID_sm9sign; break; default: error_print(); return -1; } break; #endif #ifdef ENABLE_LMS case OID_lms_hashsig: case OID_hss_lms_hashsig: #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: case OID_xmssmt_hashsig: #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: #endif *algor = key->algor; break; #ifdef ENABLE_KYBER case OID_kyber_kem: #endif default: error_print(); return -1; } return 1; } int x509_key_get_signature_size(const X509_KEY *key, size_t *siglen) { switch (key->algor) { case OID_ec_public_key: *siglen = SM2_signature_max_size; break; #ifdef ENABLE_SM9 case OID_sm9: *siglen = SM9_SIGNATURE_SIZE; break; #endif #ifdef ENABLE_LMS case OID_lms_hashsig: if (lms_key_get_signature_size(&key->u.lms_key, siglen) != 1) { error_print(); return -1; } break; case OID_hss_lms_hashsig: if (hss_key_get_signature_size(&key->u.hss_key, siglen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if (xmss_key_get_signature_size(&key->u.xmss_key, siglen) != 1) { error_print(); return -1; } break; case OID_xmssmt_hashsig: if (xmssmt_key_get_signature_size(&key->u.xmssmt_key, siglen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: *siglen = SPHINCS_SIGNATURE_SIZE; break; #endif #ifdef ENABLE_KYBER case OID_kyber_kem: error_print(); return -1; #endif default: error_print(); return -1; } return 1; } int x509_sign_init(X509_SIGN_CTX *ctx, X509_KEY *key, const void *args, size_t argslen) { if (!ctx || !key) { error_print(); return -1; } switch (key->algor) { #ifdef ENABLE_SM9 case OID_sm9: #endif #ifdef ENABLE_LMS case OID_lms_hashsig: case OID_hss_lms_hashsig: #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: case OID_xmssmt_hashsig: #endif if (args) { error_print(); return -1; } break; } memset(ctx, 0, sizeof(X509_SIGN_CTX)); switch (key->algor) { case OID_ec_public_key: switch (key->algor_param) { case OID_sm2: if (!args) { args = SM2_DEFAULT_ID; argslen = SM2_DEFAULT_ID_LENGTH; } if (!argslen) { error_print(); return -1; } if (sm2_sign_init(&ctx->u.sm2_sign_ctx, &key->u.sm2_key, args, argslen) != 1) { error_print(); return -1; } ctx->sign_algor = OID_sm2sign_with_sm3; break; #ifdef ENABLE_SECP256R1 case OID_secp256r1: if (ecdsa_sign_init(&ctx->u.ecdsa_sign_ctx, &key->u.secp256r1_key) != 1) { error_print(); return -1; } ctx->sign_algor = OID_ecdsa_with_sha256; break; #endif default: error_print(); return -1; } break; #ifdef ENABLE_LMS case OID_lms_hashsig: if (lms_sign_init(&ctx->u.lms_sign_ctx, &key->u.lms_key) != 1) { error_print(); return -1; } ctx->sign_algor = key->algor; break; case OID_hss_lms_hashsig: if (hss_sign_init(&ctx->u.hss_sign_ctx, &key->u.hss_key) != 1) { error_print(); return -1; } ctx->sign_algor = key->algor; break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if (xmss_sign_init(&ctx->u.xmss_sign_ctx, &key->u.xmss_key) != 1) { error_print(); return -1; } ctx->sign_algor = key->algor; break; case OID_xmssmt_hashsig: if (xmssmt_sign_init(&ctx->u.xmssmt_sign_ctx, &key->u.xmssmt_key) != 1) { error_print(); return -1; } ctx->sign_algor = key->algor; break; #endif // to generate a random signature (instead of a deterministic one), caller should prepare uint8_t rand[16] #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: if (args) { if (argslen != sizeof(sphincs_hash128_t)) { error_print(); return -1; } } if (sphincs_sign_init_ex(&ctx->u.sphincs_sign_ctx, &key->u.sphincs_key, args) != 1) { error_print(); return -1; } ctx->sign_algor = key->algor; break; #endif #ifdef ENABLE_SM9 case OID_sm9sign: if (key->algor_param != OID_undef) { error_print(); return -1; } if (sm9_sign_init(&ctx->u.sm9_sign_ctx) != 1) { error_print(); return -1; } ctx->key = *key; ctx->sign_algor = OID_sm9sign; break; #endif default: error_print(); return -1; } return 1; } int x509_sign_set_signature_size(X509_SIGN_CTX *ctx, size_t siglen) { if (!ctx) { error_print(); return -1; } switch (ctx->sign_algor) { case OID_sm2sign_with_sm3: #ifdef ENABLE_SECP256R1 case OID_ecdsa_with_sha256: #endif switch (siglen) { case SM2_signature_compact_size: case SM2_signature_typical_size: case SM2_signature_max_size: ctx->fixed_siglen = siglen; break; default: error_print(); return -1; } break; default: error_print(); return -1; } return 1; } int x509_sign_update(X509_SIGN_CTX *ctx, const uint8_t *data, size_t datalen) { if (!ctx) { error_print(); return -1; } switch (ctx->sign_algor) { case OID_sm2sign_with_sm3: if (sm2_sign_update(&ctx->u.sm2_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; #ifdef ENABLE_SECP256R1 case OID_ecdsa_with_sha256: if (ecdsa_sign_update(&ctx->u.ecdsa_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SM9 case OID_sm9sign: if (sm9_sign_update(&ctx->u.sm9_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_LMS case OID_lms_hashsig: if (lms_sign_update(&ctx->u.lms_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; case OID_hss_lms_hashsig: if (hss_sign_update(&ctx->u.hss_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if (xmss_sign_update(&ctx->u.xmss_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; case OID_xmssmt_hashsig: if (xmssmt_sign_update(&ctx->u.xmssmt_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: error_print(); return -1; #endif default: error_print(); return -1; } return 1; } int x509_sign_finish(X509_SIGN_CTX *ctx, uint8_t *sig, size_t *siglen) { if (!ctx || !sig || !siglen) { error_print(); return -1; } switch (ctx->sign_algor) { case OID_sm2sign_with_sm3: if (ctx->fixed_siglen) { if (sm2_sign_finish_fixlen(&ctx->u.sm2_sign_ctx, ctx->fixed_siglen, sig) != 1) { error_print(); return -1; } *siglen = ctx->fixed_siglen; } else { if (sm2_sign_finish(&ctx->u.sm2_sign_ctx, sig, siglen) != 1) { error_print(); return -1; } } break; #ifdef ENABLE_SECP256R1 case OID_ecdsa_with_sha256: if (ctx->fixed_siglen) { if (ecdsa_sign_finish_fixlen(&ctx->u.ecdsa_sign_ctx, ctx->fixed_siglen, sig) != 1) { error_print(); return -1; } *siglen = ctx->fixed_siglen; } else { if (ecdsa_sign_finish(&ctx->u.ecdsa_sign_ctx, sig, siglen) != 1) { error_print(); return -1; } } break; #endif #ifdef ENABLE_SM9 case OID_sm9sign: if (sm9_sign_finish(&ctx->u.sm9_sign_ctx, &ctx->key.u.sm9_sign_key, sig, siglen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_LMS case OID_lms_hashsig: if (lms_sign_finish(&ctx->u.lms_sign_ctx, sig, siglen) != 1) { error_print(); return -1; } break; case OID_hss_lms_hashsig: if (hss_sign_finish(&ctx->u.hss_sign_ctx, sig, siglen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if (xmss_sign_finish(&ctx->u.xmss_sign_ctx, sig, siglen) != 1) { error_print(); return -1; } break; case OID_xmssmt_hashsig: if (xmssmt_sign_finish(&ctx->u.xmssmt_sign_ctx, sig, siglen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: error_print(); return -1; #endif default: error_print(); return -1; } return 1; } int x509_sign(X509_SIGN_CTX *ctx, const uint8_t *data, size_t datalen, uint8_t *sig, size_t *siglen) { if (!ctx || !sig || !siglen) { error_print(); return -1; } if (!data || !datalen) { error_print(); return -1; } switch (ctx->sign_algor) { case OID_sm2sign_with_sm3: #ifdef ENABLE_SECP256R1 case OID_ecdsa_with_sha256: #endif #ifdef ENABLE_SM9 case OID_sm9sign: #endif #ifdef ENABLE_LMS case OID_lms_hashsig: case OID_hss_lms_hashsig: #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: case OID_xmssmt_hashsig: #endif if (x509_sign_update(ctx, data, datalen) != 1) { error_print(); return -1; } if (x509_sign_finish(ctx, sig, siglen) != 1) { error_print(); return -1; } break; #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: if (sphincs_sign_prepare(&ctx->u.sphincs_sign_ctx, data, datalen) != 1) { error_print(); return -1; } if (sphincs_sign_update(&ctx->u.sphincs_sign_ctx, data, datalen) != 1) { error_print(); return -1; } if (sphincs_sign_finish(&ctx->u.sphincs_sign_ctx, sig, siglen) != 1) { error_print(); return -1; } break; #endif default: error_print(); return -1; } return 1; } int x509_verify_init(X509_SIGN_CTX *ctx, const X509_KEY *key, const void *args, size_t argslen, const uint8_t *sig, size_t siglen) { if (!ctx || !key || !sig || !siglen) { error_print(); return -1; } switch (key->algor) { #ifdef ENABLE_SM9 case OID_sm9: if (!args || !argslen) { error_print(); return -1; } break; #endif case OID_ec_public_key: break; default: if (args) { error_print(); return -1; } } switch (key->algor) { case OID_ec_public_key: switch (key->algor_param) { case OID_sm2: if (!args) { args = SM2_DEFAULT_ID; argslen = SM2_DEFAULT_ID_LENGTH; } if (!argslen) { error_print(); return -1; } if (sm2_verify_init(&ctx->u.sm2_verify_ctx, &key->u.sm2_key, args, argslen) != 1) { error_print(); return -1; } ctx->sign_algor = OID_sm2sign_with_sm3; ctx->sig = sig; ctx->siglen = siglen; break; #ifdef ENABLE_SECP256R1 case OID_secp256r1: if (ecdsa_verify_init(&ctx->u.ecdsa_sign_ctx, &key->u.secp256r1_key, sig, siglen) != 1) { error_print(); return -1; } ctx->sign_algor = OID_ecdsa_with_sha256; break; #endif default: error_print(); return -1; } break; #ifdef ENABLE_SM9 case OID_sm9: if (key->algor_param != OID_sm9sign) { error_print(); return -1; } if (sm9_verify_init(&ctx->u.sm9_sign_ctx) != 1) { error_print(); return -1; } ctx->key = *key; ctx->sign_algor = OID_sm9sign; ctx->args = args; ctx->argslen = argslen; ctx->sig = sig; ctx->siglen = siglen; break; #endif #ifdef ENABLE_LMS case OID_lms_hashsig: if (lms_verify_init(&ctx->u.lms_sign_ctx, &key->u.lms_key, sig, siglen) != 1) { error_print(); return -1; } ctx->sign_algor = key->algor; break; case OID_hss_lms_hashsig: if (hss_verify_init(&ctx->u.hss_sign_ctx, &key->u.hss_key, sig, siglen) != 1) { error_print(); return -1; } ctx->sign_algor = key->algor; break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if (xmss_verify_init(&ctx->u.xmss_sign_ctx, &key->u.xmss_key, sig, siglen) != 1) { error_print(); return -1; } ctx->sign_algor = key->algor; break; case OID_xmssmt_hashsig: if (xmssmt_verify_init(&ctx->u.xmssmt_sign_ctx, &key->u.xmssmt_key, sig, siglen) != 1) { error_print(); return -1; } ctx->sign_algor = key->algor; break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: if (sphincs_verify_init(&ctx->u.sphincs_sign_ctx, &key->u.sphincs_key, sig, siglen) != 1) { error_print(); return -1; } ctx->sign_algor = key->algor; break; #endif default: error_print(); return -1; } return 1; } int x509_verify_update(X509_SIGN_CTX *ctx, const uint8_t *data, size_t datalen) { switch (ctx->sign_algor) { case OID_sm2sign_with_sm3: if (sm2_verify_update(&ctx->u.sm2_verify_ctx, data, datalen) != 1) { error_print(); return -1; } break; #ifdef ENABLE_SECP256R1 case OID_ecdsa_with_sha256: if (ecdsa_verify_update(&ctx->u.ecdsa_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SM9 case OID_sm9sign: if (sm9_verify_update(&ctx->u.sm9_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_LMS case OID_lms_hashsig: if (lms_verify_update(&ctx->u.lms_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; case OID_hss_lms_hashsig: if (hss_verify_update(&ctx->u.hss_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if (xmss_verify_update(&ctx->u.xmss_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; case OID_xmssmt_hashsig: if (xmssmt_verify_update(&ctx->u.xmssmt_sign_ctx, data, datalen) != 1) { error_print(); return -1; } break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: error_print(); return -1; #endif default: error_print(); return -1; } return 1; } int x509_verify_finish(X509_SIGN_CTX *ctx) { int ret; const char *id; size_t idlen; switch (ctx->sign_algor) { case OID_sm2sign_with_sm3: if ((ret = sm2_verify_finish(&ctx->u.sm2_verify_ctx, ctx->sig, ctx->siglen)) < 0) { error_print(); return -1; } break; #ifdef ENABLE_SECP256R1 case OID_ecdsa_with_sha256: if ((ret = ecdsa_verify_finish(&ctx->u.ecdsa_sign_ctx)) < 0) { error_print(); return -1; } break; #endif #ifdef ENABLE_SM9 case OID_sm9sign: id = ctx->args; idlen = ctx->argslen; fprintf(stderr, "id = %s, idlen = %zu\n", id, idlen); sm9_sign_master_key_print(stderr, 0, 4, "master_key", &ctx->key.u.sm9_sign_master_key); if ((ret = sm9_verify_finish(&ctx->u.sm9_sign_ctx, ctx->sig, ctx->siglen, &ctx->key.u.sm9_sign_master_key, id, idlen)) < 0) { error_print(); return -1; } break; #endif #ifdef ENABLE_LMS case OID_lms_hashsig: if ((ret = lms_verify_finish(&ctx->u.lms_sign_ctx)) < 0) { error_print(); return -1; } break; case OID_hss_lms_hashsig: if ((ret = hss_verify_finish(&ctx->u.hss_sign_ctx)) < 0) { error_print(); return -1; } break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: if ((ret = xmss_verify_finish(&ctx->u.xmss_sign_ctx)) < 0) { error_print(); return -1; } break; case OID_xmssmt_hashsig: if ((ret = xmssmt_verify_finish(&ctx->u.xmssmt_sign_ctx)) < 0) { error_print(); return -1; } break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: error_print(); return -1; #endif default: error_print(); return -1; } return ret; } int x509_verify(X509_SIGN_CTX *ctx, const uint8_t *data, size_t datalen) { int ret; if (!ctx) { error_print(); return -1; } switch (ctx->sign_algor) { case OID_sm2sign_with_sm3: #ifdef ENABLE_SECP256R1 case OID_ecdsa_with_sha256: #endif #ifdef ENABLE_LMS case OID_lms_hashsig: case OID_hss_lms_hashsig: #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: case OID_xmssmt_hashsig: #endif #ifdef ENABLE_SM9 case OID_sm9sign: #endif if (x509_verify_update(ctx, data, datalen) != 1) { error_print(); return -1; } if ((ret = x509_verify_finish(ctx)) < 0) { error_print(); return -1; } break; #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: if (sphincs_verify_update(&ctx->u.sphincs_sign_ctx, data, datalen) != 1) { error_print(); return -1; } if ((ret = sphincs_verify_finish(&ctx->u.sphincs_sign_ctx)) < 0) { error_print(); return -1; } break; #endif default: error_print(); return -1; } return ret; } void x509_sign_ctx_cleanup(X509_SIGN_CTX *ctx) { if (ctx) { switch (ctx->sign_algor) { case OID_sm2sign_with_sm3: gmssl_secure_clear(&ctx->u.sm2_sign_ctx, sizeof(SM2_SIGN_CTX)); break; #ifdef ENABLE_SECP256R1 case OID_ecdsa_with_sha256: gmssl_secure_clear(&ctx->u.ecdsa_sign_ctx, sizeof(ECDSA_SIGN_CTX)); break; #endif #ifdef ENABLE_LMS case OID_lms_hashsig: lms_sign_ctx_cleanup(&ctx->u.lms_sign_ctx); break; case OID_hss_lms_hashsig: hss_sign_ctx_cleanup(&ctx->u.hss_sign_ctx); break; #endif #ifdef ENABLE_XMSS case OID_xmss_hashsig: xmss_sign_ctx_cleanup(&ctx->u.xmss_sign_ctx); break; case OID_xmssmt_hashsig: xmssmt_sign_ctx_cleanup(&ctx->u.xmssmt_sign_ctx); break; #endif #ifdef ENABLE_SPHINCS case OID_sphincs_hashsig: sphincs_sign_ctx_cleanup(&ctx->u.sphincs_sign_ctx); break; #endif #ifdef ENABLE_SM9 case OID_sm9sign: gmssl_secure_clear(&ctx->u.sm9_sign_ctx, sizeof(SM9_SIGN_CTX)); #endif } memset(ctx, 0, sizeof(X509_SIGN_CTX)); } } int x509_key_do_exchange(const X509_KEY *key, const X509_KEY *pub, uint8_t *out, size_t *outlen) { if (!key || !pub || !out || !outlen) { error_print(); return -1; } if (key->algor != pub->algor || key->algor_param != pub->algor_param) { error_print(); return -1; } if (key->algor != OID_ec_public_key) { error_print(); return -1; } switch (key->algor_param) { case OID_sm2: if (sm2_do_ecdh(&key->u.sm2_key, &pub->u.sm2_key, out) != 1) { error_print(); return -1; } break; #ifdef ENABLE_SECP256R1 case OID_secp256r1: if (secp256r1_do_ecdh(&key->u.secp256r1_key, &pub->u.secp256r1_key, out) != 1) { error_print(); return -1; } break; #endif default: error_print(); return -1; } *outlen = 32; return 1; } int x509_key_exchange(const X509_KEY *key, const uint8_t *peer_pub, size_t peer_publen, uint8_t *out, size_t *outlen) { if (!key || !peer_pub || !out || !outlen) { error_print(); return -1; } if (key->algor != OID_ec_public_key) { error_print(); return -1; } if (peer_publen != 65) { error_print(); return -1; } switch (key->algor_param) { case OID_sm2: if (sm2_ecdh(&key->u.sm2_key, peer_pub, out) != 1) { error_print(); return -1; } break; #ifdef ENABLE_SECP256R1 case OID_secp256r1: if (secp256r1_ecdh(&key->u.secp256r1_key, peer_pub, out) != 1) { error_print(); return -1; } break; #endif default: error_print(); return -1; } *outlen = 32; return 1; } int x509_key_encapsulate(const X509_KEY *key, uint8_t *ciphertext, size_t *ciphertext_len, uint8_t secret[32]) { #ifdef ENABLE_KYBER if (!key || !ciphertext || !ciphertext_len || !secret) { error_print(); return -1; } if (key->algor != OID_kyber_kem) { error_print(); return -1; } if (kyber_encap(&key->u.kyber_key, (KYBER_CIPHERTEXT *)ciphertext, secret) != 1) { error_print(); return -1; } *ciphertext_len = sizeof(KYBER_CIPHERTEXT); return 1; #else error_print(); return -1; #endif } int x509_key_decapsulate(const X509_KEY *key, const uint8_t *ciphertext, size_t ciphertext_len, uint8_t secret[32]) { #ifdef ENABLE_KYBER if (!key || !ciphertext || !secret) { error_print(); return -1; } if (key->algor != OID_kyber_kem) { error_print(); return -1; } if (ciphertext_len != sizeof(KYBER_CIPHERTEXT)) { error_print(); return -1; } if (kyber_decap(&key->u.kyber_key, (KYBER_CIPHERTEXT *)ciphertext, secret) != 1) { error_print(); return -1; } return 1; #else error_print(); return -1; #endif }