/* $NetBSD: opensslrsa_link.c,v 1.12 2025/01/26 16:25:24 christos Exp $ */ /* * Copyright (C) Internet Systems Consortium, Inc. ("ISC") * * SPDX-License-Identifier: MPL-2.0 * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, you can obtain one at https://mozilla.org/MPL/2.0/. * * See the COPYRIGHT file distributed with this work for additional * information regarding copyright ownership. */ /*! \file */ #include #include #include #include #include #include #include #if OPENSSL_VERSION_NUMBER >= 0x30000000L #include #include #endif #include #include #include #include #include #include "dst_internal.h" #include "dst_openssl.h" #include "dst_parse.h" #include "openssl_shim.h" #define DST_RET(a) \ { \ ret = a; \ goto err; \ } typedef struct rsa_components { bool bnfree; const BIGNUM *e, *n, *d, *p, *q, *dmp1, *dmq1, *iqmp; } rsa_components_t; static isc_result_t opensslrsa_components_get(const dst_key_t *key, rsa_components_t *c, bool private) { REQUIRE(c->e == NULL && c->n == NULL && c->d == NULL && c->p == NULL && c->q == NULL && c->dmp1 == NULL && c->dmq1 == NULL && c->iqmp == NULL); EVP_PKEY *pub = key->keydata.pkeypair.pub; EVP_PKEY *priv = key->keydata.pkeypair.priv; if (private && priv == NULL) { return DST_R_INVALIDPRIVATEKEY; } /* * NOTE: Errors regarding private compoments are ignored. * * OpenSSL allows omitting the parameters for CRT based calculations * (factors, exponents, coefficients). Only the 'd' parameter is * mandatory for software keys. * * However, for a label based keys, all private key component queries * can fail if they key is e.g. on a hardware device. */ #if OPENSSL_VERSION_NUMBER >= 0x30000000L if (EVP_PKEY_get_bn_param(pub, OSSL_PKEY_PARAM_RSA_E, (BIGNUM **)&c->e) == 1) { c->bnfree = true; if (EVP_PKEY_get_bn_param(pub, OSSL_PKEY_PARAM_RSA_N, (BIGNUM **)&c->n) != 1) { return dst__openssl_toresult(DST_R_OPENSSLFAILURE); } if (!private) { return ISC_R_SUCCESS; } (void)EVP_PKEY_get_bn_param(priv, OSSL_PKEY_PARAM_RSA_D, (BIGNUM **)&c->d); (void)EVP_PKEY_get_bn_param(priv, OSSL_PKEY_PARAM_RSA_FACTOR1, (BIGNUM **)&c->p); (void)EVP_PKEY_get_bn_param(priv, OSSL_PKEY_PARAM_RSA_FACTOR2, (BIGNUM **)&c->q); (void)EVP_PKEY_get_bn_param(priv, OSSL_PKEY_PARAM_RSA_EXPONENT1, (BIGNUM **)&c->dmp1); (void)EVP_PKEY_get_bn_param(priv, OSSL_PKEY_PARAM_RSA_EXPONENT2, (BIGNUM **)&c->dmq1); (void)EVP_PKEY_get_bn_param(priv, OSSL_PKEY_PARAM_RSA_COEFFICIENT1, (BIGNUM **)&c->iqmp); ERR_clear_error(); return ISC_R_SUCCESS; } else { ERR_clear_error(); } #endif #if OPENSSL_VERSION_NUMBER < 0x30000000L || OPENSSL_API_LEVEL < 30000 const RSA *rsa = EVP_PKEY_get0_RSA(pub); if (rsa == NULL) { return dst__openssl_toresult(DST_R_OPENSSLFAILURE); } RSA_get0_key(rsa, &c->n, &c->e, &c->d); if (c->e == NULL || c->n == NULL) { return dst__openssl_toresult(DST_R_OPENSSLFAILURE); } if (!private) { return ISC_R_SUCCESS; } rsa = EVP_PKEY_get0_RSA(priv); if (rsa == NULL) { return dst__openssl_toresult(DST_R_OPENSSLFAILURE); } RSA_get0_factors(rsa, &c->p, &c->q); RSA_get0_crt_params(rsa, &c->dmp1, &c->dmq1, &c->iqmp); return ISC_R_SUCCESS; #else return DST_R_OPENSSLFAILURE; #endif } static void opensslrsa_components_free(rsa_components_t *c) { if (!c->bnfree) { return; } /* * NOTE: BN_free() frees the components of the BIGNUM, and if it was * created by BN_new(), also the structure itself. BN_clear_free() * additionally overwrites the data before the memory is returned to the * system. If a is NULL, nothing is done. */ BN_free((BIGNUM *)c->e); BN_free((BIGNUM *)c->n); BN_clear_free((BIGNUM *)c->d); BN_clear_free((BIGNUM *)c->p); BN_clear_free((BIGNUM *)c->q); BN_clear_free((BIGNUM *)c->dmp1); BN_clear_free((BIGNUM *)c->dmq1); BN_clear_free((BIGNUM *)c->iqmp); c->bnfree = false; } static bool opensslrsa_valid_key_alg(unsigned int key_alg) { switch (key_alg) { case DST_ALG_RSASHA1: case DST_ALG_NSEC3RSASHA1: case DST_ALG_RSASHA256: case DST_ALG_RSASHA512: return true; default: return false; } } static isc_result_t opensslrsa_createctx(dst_key_t *key, dst_context_t *dctx) { EVP_MD_CTX *evp_md_ctx; const EVP_MD *type = NULL; UNUSED(key); REQUIRE(dctx != NULL && dctx->key != NULL); REQUIRE(opensslrsa_valid_key_alg(dctx->key->key_alg)); /* * Reject incorrect RSA key lengths. */ switch (dctx->key->key_alg) { case DST_ALG_RSASHA1: case DST_ALG_NSEC3RSASHA1: /* From RFC 3110 */ if (dctx->key->key_size > 4096) { return ISC_R_FAILURE; } break; case DST_ALG_RSASHA256: /* From RFC 5702 */ if (dctx->key->key_size < 512 || dctx->key->key_size > 4096) { return ISC_R_FAILURE; } break; case DST_ALG_RSASHA512: /* From RFC 5702 */ if (dctx->key->key_size < 1024 || dctx->key->key_size > 4096) { return ISC_R_FAILURE; } break; default: UNREACHABLE(); } evp_md_ctx = EVP_MD_CTX_create(); if (evp_md_ctx == NULL) { return dst__openssl_toresult(ISC_R_NOMEMORY); } switch (dctx->key->key_alg) { case DST_ALG_RSASHA1: case DST_ALG_NSEC3RSASHA1: type = EVP_sha1(); /* SHA1 + RSA */ break; case DST_ALG_RSASHA256: type = EVP_sha256(); /* SHA256 + RSA */ break; case DST_ALG_RSASHA512: type = EVP_sha512(); break; default: UNREACHABLE(); } if (!EVP_DigestInit_ex(evp_md_ctx, type, NULL)) { EVP_MD_CTX_destroy(evp_md_ctx); return dst__openssl_toresult3( dctx->category, "EVP_DigestInit_ex", ISC_R_FAILURE); } dctx->ctxdata.evp_md_ctx = evp_md_ctx; return ISC_R_SUCCESS; } static void opensslrsa_destroyctx(dst_context_t *dctx) { EVP_MD_CTX *evp_md_ctx = NULL; REQUIRE(dctx != NULL && dctx->key != NULL); REQUIRE(opensslrsa_valid_key_alg(dctx->key->key_alg)); evp_md_ctx = dctx->ctxdata.evp_md_ctx; if (evp_md_ctx != NULL) { EVP_MD_CTX_destroy(evp_md_ctx); dctx->ctxdata.evp_md_ctx = NULL; } } static isc_result_t opensslrsa_adddata(dst_context_t *dctx, const isc_region_t *data) { EVP_MD_CTX *evp_md_ctx = NULL; REQUIRE(dctx != NULL && dctx->key != NULL); REQUIRE(opensslrsa_valid_key_alg(dctx->key->key_alg)); evp_md_ctx = dctx->ctxdata.evp_md_ctx; if (!EVP_DigestUpdate(evp_md_ctx, data->base, data->length)) { return dst__openssl_toresult3( dctx->category, "EVP_DigestUpdate", ISC_R_FAILURE); } return ISC_R_SUCCESS; } static isc_result_t opensslrsa_sign(dst_context_t *dctx, isc_buffer_t *sig) { dst_key_t *key = NULL; isc_region_t r; unsigned int siglen = 0; EVP_MD_CTX *evp_md_ctx = NULL; EVP_PKEY *pkey = NULL; REQUIRE(dctx != NULL && dctx->key != NULL); REQUIRE(opensslrsa_valid_key_alg(dctx->key->key_alg)); key = dctx->key; evp_md_ctx = dctx->ctxdata.evp_md_ctx; pkey = key->keydata.pkeypair.priv; isc_buffer_availableregion(sig, &r); if (r.length < (unsigned int)EVP_PKEY_size(pkey)) { return ISC_R_NOSPACE; } if (!EVP_SignFinal(evp_md_ctx, r.base, &siglen, pkey)) { return dst__openssl_toresult3(dctx->category, "EVP_SignFinal", ISC_R_FAILURE); } isc_buffer_add(sig, siglen); return ISC_R_SUCCESS; } static bool opensslrsa_check_exponent_bits(EVP_PKEY *pkey, int maxbits) { /* Always use the new API first with OpenSSL 3.x. */ #if OPENSSL_VERSION_NUMBER >= 0x30000000L BIGNUM *e = NULL; if (EVP_PKEY_get_bn_param(pkey, OSSL_PKEY_PARAM_RSA_E, &e) == 1) { int bits = BN_num_bits(e); BN_free(e); return bits < maxbits; } #endif /* Use old API for the OpenSSL ENGINE support, even with OpenSSL 3.x */ #if OPENSSL_VERSION_NUMBER < 0x30000000L || OPENSSL_API_LEVEL < 30000 const RSA *rsa = EVP_PKEY_get0_RSA(pkey); if (rsa != NULL) { const BIGNUM *ce = NULL; RSA_get0_key(rsa, NULL, &ce, NULL); if (ce != NULL) { return BN_num_bits(ce) < maxbits; } } #endif return false; } static isc_result_t opensslrsa_verify2(dst_context_t *dctx, int maxbits, const isc_region_t *sig) { dst_key_t *key = NULL; int status = 0; EVP_MD_CTX *evp_md_ctx = NULL; EVP_PKEY *pkey = NULL; REQUIRE(dctx != NULL && dctx->key != NULL); REQUIRE(opensslrsa_valid_key_alg(dctx->key->key_alg)); key = dctx->key; evp_md_ctx = dctx->ctxdata.evp_md_ctx; pkey = key->keydata.pkeypair.pub; if (maxbits != 0 && !opensslrsa_check_exponent_bits(pkey, maxbits)) { return DST_R_VERIFYFAILURE; } status = EVP_VerifyFinal(evp_md_ctx, sig->base, sig->length, pkey); switch (status) { case 1: return ISC_R_SUCCESS; case 0: return dst__openssl_toresult(DST_R_VERIFYFAILURE); default: return dst__openssl_toresult3(dctx->category, "EVP_VerifyFinal", DST_R_VERIFYFAILURE); } } static isc_result_t opensslrsa_verify(dst_context_t *dctx, const isc_region_t *sig) { return opensslrsa_verify2(dctx, 0, sig); } #if OPENSSL_VERSION_NUMBER < 0x30000000L || OPENSSL_API_LEVEL < 30000 static int progress_cb(int p, int n, BN_GENCB *cb) { void (*fptr)(int); UNUSED(n); fptr = BN_GENCB_get_arg(cb); if (fptr != NULL) { fptr(p); } return 1; } static isc_result_t opensslrsa_generate_pkey(unsigned int key_size, const char *label, BIGNUM *e, void (*callback)(int), EVP_PKEY **retkey) { RSA *rsa = NULL; EVP_PKEY *pkey = NULL; BN_GENCB *cb = NULL; isc_result_t ret; UNUSED(label); rsa = RSA_new(); pkey = EVP_PKEY_new(); if (rsa == NULL || pkey == NULL) { DST_RET(dst__openssl_toresult(DST_R_OPENSSLFAILURE)); } if (EVP_PKEY_set1_RSA(pkey, rsa) != 1) { DST_RET(dst__openssl_toresult(DST_R_OPENSSLFAILURE)); } if (callback != NULL) { cb = BN_GENCB_new(); if (cb == NULL) { DST_RET(dst__openssl_toresult(ISC_R_NOMEMORY)); } BN_GENCB_set(cb, progress_cb, (void *)callback); } if (RSA_generate_key_ex(rsa, key_size, e, cb) != 1) { DST_RET(dst__openssl_toresult2("RSA_generate_key_ex", DST_R_OPENSSLFAILURE)); } *retkey = pkey; pkey = NULL; ret = ISC_R_SUCCESS; err: EVP_PKEY_free(pkey); RSA_free(rsa); BN_GENCB_free(cb); return ret; } static isc_result_t opensslrsa_build_pkey(bool private, rsa_components_t *c, EVP_PKEY **retpkey) { isc_result_t ret; EVP_PKEY *pkey = NULL; RSA *rsa = RSA_new(); int status; REQUIRE(c->bnfree); if (c->n == NULL || c->e == NULL) { if (private) { DST_RET(DST_R_INVALIDPRIVATEKEY); } DST_RET(DST_R_INVALIDPUBLICKEY); } if (rsa == NULL) { DST_RET(dst__openssl_toresult2("RSA_new", DST_R_OPENSSLFAILURE)); } if (RSA_set0_key(rsa, (BIGNUM *)c->n, (BIGNUM *)c->e, (BIGNUM *)c->d) != 1) { DST_RET(dst__openssl_toresult2("RSA_set0_key", DST_R_OPENSSLFAILURE)); } c->n = NULL; c->e = NULL; c->d = NULL; if (c->p != NULL || c->q != NULL) { if (RSA_set0_factors(rsa, (BIGNUM *)c->p, (BIGNUM *)c->q) != 1) { DST_RET(dst__openssl_toresult2("RSA_set0_factors", DST_R_OPENSSLFAILURE)); } c->p = NULL; c->q = NULL; } if (c->dmp1 != NULL || c->dmq1 != NULL || c->iqmp != NULL) { if (RSA_set0_crt_params(rsa, (BIGNUM *)c->dmp1, (BIGNUM *)c->dmq1, (BIGNUM *)c->iqmp) == 0) { DST_RET(dst__openssl_toresult2("RSA_set0_crt_params", DST_R_OPENSSLFAILURE)); } c->dmp1 = NULL; c->dmq1 = NULL; c->iqmp = NULL; } pkey = EVP_PKEY_new(); if (pkey == NULL) { DST_RET(dst__openssl_toresult2("EVP_PKEY_new", DST_R_OPENSSLFAILURE)); } status = EVP_PKEY_set1_RSA(pkey, rsa); if (status != 1) { DST_RET(dst__openssl_toresult2("EVP_PKEY_set1_RSA", DST_R_OPENSSLFAILURE)); } *retpkey = pkey; pkey = NULL; ret = ISC_R_SUCCESS; err: EVP_PKEY_free(pkey); RSA_free(rsa); opensslrsa_components_free(c); return ret; } #else static int progress_cb(EVP_PKEY_CTX *ctx) { void (*fptr)(int); fptr = EVP_PKEY_CTX_get_app_data(ctx); if (fptr != NULL) { int p = EVP_PKEY_CTX_get_keygen_info(ctx, 0); fptr(p); } return 1; } static isc_result_t opensslrsa_generate_pkey_with_uri(size_t key_size, const char *label, EVP_PKEY **retkey) { EVP_PKEY_CTX *ctx = NULL; OSSL_PARAM params[4]; char *uri = UNCONST(label); isc_result_t ret; int status; params[0] = OSSL_PARAM_construct_utf8_string("pkcs11_uri", uri, 0); params[1] = OSSL_PARAM_construct_utf8_string( "pkcs11_key_usage", (char *)"digitalSignature", 0); params[2] = OSSL_PARAM_construct_size_t("rsa_keygen_bits", &key_size); params[3] = OSSL_PARAM_construct_end(); ctx = EVP_PKEY_CTX_new_from_name(NULL, "RSA", "provider=pkcs11"); if (ctx == NULL) { DST_RET(dst__openssl_toresult2("EVP_PKEY_CTX_new_from_name", DST_R_OPENSSLFAILURE)); } status = EVP_PKEY_keygen_init(ctx); if (status != 1) { DST_RET(dst__openssl_toresult2("EVP_PKEY_keygen_init", DST_R_OPENSSLFAILURE)); } status = EVP_PKEY_CTX_set_params(ctx, params); if (status != 1) { DST_RET(dst__openssl_toresult2("EVP_PKEY_CTX_set_params", DST_R_OPENSSLFAILURE)); } status = EVP_PKEY_generate(ctx, retkey); if (status != 1) { DST_RET(dst__openssl_toresult2("EVP_PKEY_generate", DST_R_OPENSSLFAILURE)); } ret = ISC_R_SUCCESS; err: EVP_PKEY_CTX_free(ctx); return ret; } static isc_result_t opensslrsa_generate_pkey(unsigned int key_size, const char *label, BIGNUM *e, void (*callback)(int), EVP_PKEY **retkey) { EVP_PKEY_CTX *ctx; isc_result_t ret; if (label != NULL) { return opensslrsa_generate_pkey_with_uri(key_size, label, retkey); } ctx = EVP_PKEY_CTX_new_from_name(NULL, "RSA", NULL); if (ctx == NULL) { DST_RET(dst__openssl_toresult(DST_R_OPENSSLFAILURE)); } if (EVP_PKEY_keygen_init(ctx) != 1) { DST_RET(dst__openssl_toresult(DST_R_OPENSSLFAILURE)); } if (EVP_PKEY_CTX_set_rsa_keygen_bits(ctx, (int)key_size) != 1) { DST_RET(dst__openssl_toresult(DST_R_OPENSSLFAILURE)); } if (EVP_PKEY_CTX_set1_rsa_keygen_pubexp(ctx, e) != 1) { DST_RET(dst__openssl_toresult(DST_R_OPENSSLFAILURE)); } if (callback != NULL) { EVP_PKEY_CTX_set_app_data(ctx, (void *)callback); EVP_PKEY_CTX_set_cb(ctx, progress_cb); } if (EVP_PKEY_keygen(ctx, retkey) != 1) { DST_RET(dst__openssl_toresult2("EVP_PKEY_keygen", DST_R_OPENSSLFAILURE)); } ret = ISC_R_SUCCESS; err: EVP_PKEY_CTX_free(ctx); return ret; } static isc_result_t opensslrsa_build_pkey(bool private, rsa_components_t *c, EVP_PKEY **retpkey) { isc_result_t ret; int status; OSSL_PARAM_BLD *bld = NULL; OSSL_PARAM *params = NULL; EVP_PKEY_CTX *ctx = NULL; bld = OSSL_PARAM_BLD_new(); if (bld == NULL) { DST_RET(dst__openssl_toresult2("OSSL_PARAM_BLD_new", DST_R_OPENSSLFAILURE)); } if (OSSL_PARAM_BLD_push_BN(bld, OSSL_PKEY_PARAM_RSA_N, c->n) != 1 || OSSL_PARAM_BLD_push_BN(bld, OSSL_PKEY_PARAM_RSA_E, c->e) != 1) { DST_RET(dst__openssl_toresult2("OSSL_PARAM_BLD_push_BN", DST_R_OPENSSLFAILURE)); } if (c->d != NULL && OSSL_PARAM_BLD_push_BN(bld, OSSL_PKEY_PARAM_RSA_D, c->d) != 1) { DST_RET(dst__openssl_toresult2("OSSL_PARAM_BLD_push_BN", DST_R_OPENSSLFAILURE)); } if (c->p != NULL && OSSL_PARAM_BLD_push_BN(bld, OSSL_PKEY_PARAM_RSA_FACTOR1, c->p) != 1) { DST_RET(dst__openssl_toresult2("OSSL_PARAM_BLD_push_BN", DST_R_OPENSSLFAILURE)); } if (c->q != NULL && OSSL_PARAM_BLD_push_BN(bld, OSSL_PKEY_PARAM_RSA_FACTOR2, c->q) != 1) { DST_RET(dst__openssl_toresult2("OSSL_PARAM_BLD_push_BN", DST_R_OPENSSLFAILURE)); } if (c->dmp1 != NULL && OSSL_PARAM_BLD_push_BN(bld, OSSL_PKEY_PARAM_RSA_EXPONENT1, c->dmp1) != 1) { DST_RET(dst__openssl_toresult2("OSSL_PARAM_BLD_push_BN", DST_R_OPENSSLFAILURE)); } if (c->dmq1 != NULL && OSSL_PARAM_BLD_push_BN(bld, OSSL_PKEY_PARAM_RSA_EXPONENT2, c->dmq1) != 1) { DST_RET(dst__openssl_toresult2("OSSL_PARAM_BLD_push_BN", DST_R_OPENSSLFAILURE)); } if (c->iqmp != NULL && OSSL_PARAM_BLD_push_BN(bld, OSSL_PKEY_PARAM_RSA_COEFFICIENT1, c->iqmp) != 1) { DST_RET(dst__openssl_toresult2("OSSL_PARAM_BLD_push_BN", DST_R_OPENSSLFAILURE)); } params = OSSL_PARAM_BLD_to_param(bld); if (params == NULL) { DST_RET(dst__openssl_toresult2("OSSL_PARAM_BLD_to_param", DST_R_OPENSSLFAILURE)); } ctx = EVP_PKEY_CTX_new_from_name(NULL, "RSA", NULL); if (ctx == NULL) { DST_RET(dst__openssl_toresult2("EVP_PKEY_CTX_new_from_name", DST_R_OPENSSLFAILURE)); } status = EVP_PKEY_fromdata_init(ctx); if (status != 1) { DST_RET(dst__openssl_toresult2("EVP_PKEY_fromdata_init", DST_R_OPENSSLFAILURE)); } status = EVP_PKEY_fromdata( ctx, retpkey, private ? EVP_PKEY_KEYPAIR : EVP_PKEY_PUBLIC_KEY, params); if (status != 1) { DST_RET(dst__openssl_toresult2("EVP_PKEY_fromdata", DST_R_OPENSSLFAILURE)); } ret = ISC_R_SUCCESS; err: EVP_PKEY_CTX_free(ctx); OSSL_PARAM_free(params); OSSL_PARAM_BLD_free(bld); return ret; } #endif /* OPENSSL_VERSION_NUMBER < 0x30000000L || OPENSSL_API_LEVEL < 30000 */ static isc_result_t opensslrsa_generate(dst_key_t *key, int exp, void (*callback)(int)) { isc_result_t ret; BIGNUM *e = BN_new(); EVP_PKEY *pkey = NULL; if (e == NULL) { DST_RET(dst__openssl_toresult(DST_R_OPENSSLFAILURE)); } /* * Reject incorrect RSA key lengths. */ switch (key->key_alg) { case DST_ALG_RSASHA1: case DST_ALG_NSEC3RSASHA1: /* From RFC 3110 */ if (key->key_size > 4096) { DST_RET(DST_R_INVALIDPARAM); } break; case DST_ALG_RSASHA256: /* From RFC 5702 */ if (key->key_size < 512 || key->key_size > 4096) { DST_RET(DST_R_INVALIDPARAM); } break; case DST_ALG_RSASHA512: /* From RFC 5702 */ if (key->key_size < 1024 || key->key_size > 4096) { DST_RET(DST_R_INVALIDPARAM); } break; default: UNREACHABLE(); } if (exp == 0) { /* RSA_F4 0x10001 */ BN_set_bit(e, 0); BN_set_bit(e, 16); } else { /* (phased-out) F5 0x100000001 */ BN_set_bit(e, 0); BN_set_bit(e, 32); } ret = opensslrsa_generate_pkey(key->key_size, key->label, e, callback, &pkey); if (ret != ISC_R_SUCCESS) { goto err; } key->keydata.pkeypair.pub = pkey; key->keydata.pkeypair.priv = pkey; pkey = NULL; ret = ISC_R_SUCCESS; err: EVP_PKEY_free(pkey); BN_free(e); return ret; } static isc_result_t opensslrsa_todns(const dst_key_t *key, isc_buffer_t *data) { isc_region_t r; unsigned int e_bytes; unsigned int mod_bytes; isc_result_t ret; rsa_components_t c = { 0 }; REQUIRE(key->keydata.pkeypair.pub != NULL); isc_buffer_availableregion(data, &r); ret = opensslrsa_components_get(key, &c, false); if (ret != ISC_R_SUCCESS) { goto err; } mod_bytes = BN_num_bytes(c.n); e_bytes = BN_num_bytes(c.e); if (e_bytes < 256) { /*%< key exponent is <= 2040 bits */ if (r.length < 1) { DST_RET(ISC_R_NOSPACE); } isc_buffer_putuint8(data, (uint8_t)e_bytes); isc_region_consume(&r, 1); } else { if (r.length < 3) { DST_RET(ISC_R_NOSPACE); } isc_buffer_putuint8(data, 0); isc_buffer_putuint16(data, (uint16_t)e_bytes); isc_region_consume(&r, 3); } if (r.length < e_bytes + mod_bytes) { DST_RET(ISC_R_NOSPACE); } BN_bn2bin(c.e, r.base); isc_region_consume(&r, e_bytes); BN_bn2bin(c.n, r.base); isc_region_consume(&r, mod_bytes); isc_buffer_add(data, e_bytes + mod_bytes); ret = ISC_R_SUCCESS; err: opensslrsa_components_free(&c); return ret; } static isc_result_t opensslrsa_fromdns(dst_key_t *key, isc_buffer_t *data) { isc_result_t ret; isc_region_t r; unsigned int e_bytes; unsigned int length; rsa_components_t c = { .bnfree = true }; REQUIRE(opensslrsa_valid_key_alg(key->key_alg)); isc_buffer_remainingregion(data, &r); if (r.length == 0) { DST_RET(ISC_R_SUCCESS); } length = r.length; if (r.length < 1) { DST_RET(DST_R_INVALIDPUBLICKEY); } e_bytes = *r.base; isc_region_consume(&r, 1); if (e_bytes == 0) { if (r.length < 2) { DST_RET(DST_R_INVALIDPUBLICKEY); } e_bytes = (*r.base) << 8; isc_region_consume(&r, 1); e_bytes += *r.base; isc_region_consume(&r, 1); } if (r.length < e_bytes) { DST_RET(DST_R_INVALIDPUBLICKEY); } c.e = BN_bin2bn(r.base, e_bytes, NULL); isc_region_consume(&r, e_bytes); c.n = BN_bin2bn(r.base, r.length, NULL); if (c.e == NULL || c.n == NULL) { DST_RET(ISC_R_NOMEMORY); } isc_buffer_forward(data, length); key->key_size = BN_num_bits(c.n); ret = opensslrsa_build_pkey(false, &c, &key->keydata.pkeypair.pub); err: opensslrsa_components_free(&c); return ret; } static isc_result_t opensslrsa_tofile(const dst_key_t *key, const char *directory) { isc_result_t ret; dst_private_t priv = { 0 }; unsigned char *bufs[8] = { NULL }; unsigned short i = 0; rsa_components_t c = { 0 }; if (key->external) { return dst__privstruct_writefile(key, &priv, directory); } ret = opensslrsa_components_get(key, &c, true); if (ret != ISC_R_SUCCESS) { goto err; } priv.elements[i].tag = TAG_RSA_MODULUS; priv.elements[i].length = BN_num_bytes(c.n); bufs[i] = isc_mem_get(key->mctx, priv.elements[i].length); BN_bn2bin(c.n, bufs[i]); priv.elements[i].data = bufs[i]; i++; priv.elements[i].tag = TAG_RSA_PUBLICEXPONENT; priv.elements[i].length = BN_num_bytes(c.e); bufs[i] = isc_mem_get(key->mctx, priv.elements[i].length); BN_bn2bin(c.e, bufs[i]); priv.elements[i].data = bufs[i]; i++; if (c.d != NULL) { priv.elements[i].tag = TAG_RSA_PRIVATEEXPONENT; priv.elements[i].length = BN_num_bytes(c.d); INSIST(i < ARRAY_SIZE(bufs)); bufs[i] = isc_mem_get(key->mctx, priv.elements[i].length); BN_bn2bin(c.d, bufs[i]); priv.elements[i].data = bufs[i]; i++; } if (c.p != NULL) { priv.elements[i].tag = TAG_RSA_PRIME1; priv.elements[i].length = BN_num_bytes(c.p); INSIST(i < ARRAY_SIZE(bufs)); bufs[i] = isc_mem_get(key->mctx, priv.elements[i].length); BN_bn2bin(c.p, bufs[i]); priv.elements[i].data = bufs[i]; i++; } if (c.q != NULL) { priv.elements[i].tag = TAG_RSA_PRIME2; priv.elements[i].length = BN_num_bytes(c.q); INSIST(i < ARRAY_SIZE(bufs)); bufs[i] = isc_mem_get(key->mctx, priv.elements[i].length); BN_bn2bin(c.q, bufs[i]); priv.elements[i].data = bufs[i]; i++; } if (c.dmp1 != NULL) { priv.elements[i].tag = TAG_RSA_EXPONENT1; priv.elements[i].length = BN_num_bytes(c.dmp1); INSIST(i < ARRAY_SIZE(bufs)); bufs[i] = isc_mem_get(key->mctx, priv.elements[i].length); BN_bn2bin(c.dmp1, bufs[i]); priv.elements[i].data = bufs[i]; i++; } if (c.dmq1 != NULL) { priv.elements[i].tag = TAG_RSA_EXPONENT2; priv.elements[i].length = BN_num_bytes(c.dmq1); INSIST(i < ARRAY_SIZE(bufs)); bufs[i] = isc_mem_get(key->mctx, priv.elements[i].length); BN_bn2bin(c.dmq1, bufs[i]); priv.elements[i].data = bufs[i]; i++; } if (c.iqmp != NULL) { priv.elements[i].tag = TAG_RSA_COEFFICIENT; priv.elements[i].length = BN_num_bytes(c.iqmp); INSIST(i < ARRAY_SIZE(bufs)); bufs[i] = isc_mem_get(key->mctx, priv.elements[i].length); BN_bn2bin(c.iqmp, bufs[i]); priv.elements[i].data = bufs[i]; i++; } if (key->engine != NULL) { priv.elements[i].tag = TAG_RSA_ENGINE; priv.elements[i].length = (unsigned short)strlen(key->engine) + 1; priv.elements[i].data = (unsigned char *)key->engine; i++; } if (key->label != NULL) { priv.elements[i].tag = TAG_RSA_LABEL; priv.elements[i].length = (unsigned short)strlen(key->label) + 1; priv.elements[i].data = (unsigned char *)key->label; i++; } priv.nelements = i; ret = dst__privstruct_writefile(key, &priv, directory); err: for (i = 0; i < ARRAY_SIZE(bufs); i++) { if (bufs[i] != NULL) { isc_mem_put(key->mctx, bufs[i], priv.elements[i].length); } } opensslrsa_components_free(&c); return ret; } static isc_result_t opensslrsa_fromlabel(dst_key_t *key, const char *engine, const char *label, const char *pin); static isc_result_t opensslrsa_parse(dst_key_t *key, isc_lex_t *lexer, dst_key_t *pub) { dst_private_t priv; isc_result_t ret; int i; isc_mem_t *mctx = NULL; const char *engine = NULL, *label = NULL; EVP_PKEY *pkey = NULL; rsa_components_t c = { .bnfree = true }; REQUIRE(key != NULL); REQUIRE(opensslrsa_valid_key_alg(key->key_alg)); mctx = key->mctx; /* read private key file */ ret = dst__privstruct_parse(key, DST_ALG_RSA, lexer, mctx, &priv); if (ret != ISC_R_SUCCESS) { goto err; } if (key->external) { if (priv.nelements != 0 || pub == NULL) { DST_RET(DST_R_INVALIDPRIVATEKEY); } key->keydata.pkeypair.pub = pub->keydata.pkeypair.pub; key->keydata.pkeypair.priv = pub->keydata.pkeypair.priv; pub->keydata.pkeypair.pub = NULL; pub->keydata.pkeypair.priv = NULL; key->key_size = pub->key_size; DST_RET(ISC_R_SUCCESS); } for (i = 0; i < priv.nelements; i++) { switch (priv.elements[i].tag) { case TAG_RSA_ENGINE: engine = (char *)priv.elements[i].data; break; case TAG_RSA_LABEL: label = (char *)priv.elements[i].data; break; default: break; } } /* * Is this key stored in a HSM? * See if we can fetch it. */ if (label != NULL) { ret = opensslrsa_fromlabel(key, engine, label, NULL); if (ret != ISC_R_SUCCESS) { DST_RET(ret); } /* Check that the public component matches if given */ if (pub != NULL && EVP_PKEY_eq(key->keydata.pkeypair.pub, pub->keydata.pkeypair.pub) != 1) { DST_RET(DST_R_INVALIDPRIVATEKEY); } DST_RET(ISC_R_SUCCESS); } for (i = 0; i < priv.nelements; i++) { BIGNUM *bn; switch (priv.elements[i].tag) { case TAG_RSA_ENGINE: continue; case TAG_RSA_LABEL: continue; default: bn = BN_bin2bn(priv.elements[i].data, priv.elements[i].length, NULL); if (bn == NULL) { DST_RET(ISC_R_NOMEMORY); } switch (priv.elements[i].tag) { case TAG_RSA_MODULUS: c.n = bn; break; case TAG_RSA_PUBLICEXPONENT: c.e = bn; break; case TAG_RSA_PRIVATEEXPONENT: c.d = bn; break; case TAG_RSA_PRIME1: c.p = bn; break; case TAG_RSA_PRIME2: c.q = bn; break; case TAG_RSA_EXPONENT1: c.dmp1 = bn; break; case TAG_RSA_EXPONENT2: c.dmq1 = bn; break; case TAG_RSA_COEFFICIENT: c.iqmp = bn; break; default: BN_clear_free(bn); } } } /* Basic sanity check for public key portion */ if (c.n == NULL || c.e == NULL) { DST_RET(DST_R_INVALIDPRIVATEKEY); } if (BN_num_bits(c.e) > RSA_MAX_PUBEXP_BITS) { DST_RET(ISC_R_RANGE); } key->key_size = BN_num_bits(c.n); ret = opensslrsa_build_pkey(true, &c, &pkey); if (ret != ISC_R_SUCCESS) { goto err; } /* Check that the public component matches if given */ if (pub != NULL && EVP_PKEY_eq(pkey, pub->keydata.pkeypair.pub) != 1) { DST_RET(DST_R_INVALIDPRIVATEKEY); } key->keydata.pkeypair.pub = pkey; key->keydata.pkeypair.priv = pkey; pkey = NULL; err: opensslrsa_components_free(&c); EVP_PKEY_free(pkey); if (ret != ISC_R_SUCCESS) { key->keydata.generic = NULL; } dst__privstruct_free(&priv, mctx); isc_safe_memwipe(&priv, sizeof(priv)); return ret; } static isc_result_t opensslrsa_fromlabel(dst_key_t *key, const char *engine, const char *label, const char *pin) { EVP_PKEY *privpkey = NULL, *pubpkey = NULL; isc_result_t ret; ret = dst__openssl_fromlabel(EVP_PKEY_RSA, engine, label, pin, &pubpkey, &privpkey); if (ret != ISC_R_SUCCESS) { goto err; } if (!opensslrsa_check_exponent_bits(pubpkey, RSA_MAX_PUBEXP_BITS)) { DST_RET(ISC_R_RANGE); } if (engine != NULL) { key->engine = isc_mem_strdup(key->mctx, engine); } key->label = isc_mem_strdup(key->mctx, label); key->key_size = EVP_PKEY_bits(privpkey); key->keydata.pkeypair.priv = privpkey; key->keydata.pkeypair.pub = pubpkey; privpkey = NULL; pubpkey = NULL; err: EVP_PKEY_free(privpkey); EVP_PKEY_free(pubpkey); return ret; } static dst_func_t opensslrsa_functions = { opensslrsa_createctx, NULL, /*%< createctx2 */ opensslrsa_destroyctx, opensslrsa_adddata, opensslrsa_sign, opensslrsa_verify, opensslrsa_verify2, NULL, /*%< computesecret */ dst__openssl_keypair_compare, NULL, /*%< paramcompare */ opensslrsa_generate, dst__openssl_keypair_isprivate, dst__openssl_keypair_destroy, opensslrsa_todns, opensslrsa_fromdns, opensslrsa_tofile, opensslrsa_parse, NULL, /*%< cleanup */ opensslrsa_fromlabel, NULL, /*%< dump */ NULL, /*%< restore */ }; /* * An RSA public key with 2048 bits */ static const unsigned char e_bytes[] = "\x01\x00\x01"; static const unsigned char n_bytes[] = "\xc3\x90\x07\xbe\xf1\x85\xfc\x1a\x43\xb1\xa5\x15\xce\x71\x34\xfc\xc1" "\x87\x27\x28\x38\xa4\xcf\x7c\x1a\x82\xa8\xdc\x04\x14\xd0\x3f\xb4\xfe" "\x20\x4a\xdd\xd9\x0d\xd7\xcd\x61\x8c\xbd\x61\xa8\x10\xb5\x63\x1c\x29" "\x15\xcb\x41\xee\x43\x91\x7f\xeb\xa5\x2c\xab\x81\x75\x0d\xa3\x3d\xe4" "\xc8\x49\xb9\xca\x5a\x55\xa1\xbb\x09\xd1\xfb\xcd\xa2\xd2\x12\xa4\x85" "\xdf\xa5\x65\xc9\x27\x2d\x8b\xd7\x8b\xfe\x6d\xc4\xd1\xd9\x83\x1c\x91" "\x7d\x3d\xd0\xa4\xcd\xe1\xe7\xb9\x7a\x11\x38\xf9\x8b\x3c\xec\x30\xb6" "\x36\xb9\x92\x64\x81\x56\x3c\xbc\xf9\x49\xfb\xba\x82\xb7\xa0\xfa\x65" "\x79\x83\xb9\x4c\xa7\xfd\x53\x0b\x5a\xe4\xde\xf9\xfc\x38\x7e\xb5\x2c" "\xa0\xc3\xb2\xfc\x7c\x38\xb0\x63\x50\xaf\x00\xaa\xb2\xad\x49\x54\x1e" "\x8b\x11\x88\x9b\x6e\xae\x3b\x23\xa3\xdd\x53\x51\x80\x7a\x0b\x91\x4e" "\x6d\x32\x01\xbd\x17\x81\x12\x64\x9f\x84\xae\x76\x53\x1a\x63\xa0\xda" "\xcc\x45\x04\x72\xb0\xa7\xfb\xfa\x02\x39\x53\xc1\x83\x1f\x88\x54\x47" "\x88\x63\x20\x71\x5d\xe2\xaa\x7c\x53\x39\x5e\x35\x25\xee\xe6\x5c\x15" "\x5e\x14\xbe\x99\xde\x25\x19\xe7\x13\xdb\xce\xa3\xd3\x6c\x5c\xbb\x0e" "\x6b"; static const unsigned char sha1_sig[] = "\x69\x99\x89\x28\xe0\x38\x34\x91\x29\xb6\xac\x4b\xe9\x51\xbd\xbe\xc8" "\x1a\x2d\xb6\xca\x99\xa3\x9f\x6a\x8b\x94\x5a\x51\x37\xd5\x8d\xae\x87" "\xed\xbc\x8e\xb8\xa3\x60\x6b\xf6\xe6\x72\xfc\x26\x2a\x39\x2b\xfe\x88" "\x1a\xa9\xd1\x93\xc7\xb9\xf8\xb6\x45\xa1\xf9\xa1\x56\x78\x7b\x00\xec" "\x33\x83\xd4\x93\x25\x48\xb3\x50\x09\xd0\xbc\x7f\xac\x67\xc7\xa2\x7f" "\xfc\xf6\x5a\xef\xf8\x5a\xad\x52\x74\xf5\x71\x34\xd9\x3d\x33\x8b\x4d" "\x99\x64\x7e\x14\x59\xbe\xdf\x26\x8a\x67\x96\x6c\x1f\x79\x85\x10\x0d" "\x7f\xd6\xa4\xba\x57\x41\x03\x71\x4e\x8c\x17\xd5\xc4\xfb\x4a\xbe\x66" "\x45\x15\x45\x0c\x02\xe0\x10\xe1\xbb\x33\x8d\x90\x34\x3c\x94\xa4\x4c" "\x7c\xd0\x5e\x90\x76\x80\x59\xb2\xfa\x54\xbf\xa9\x86\xb8\x84\x1e\x28" "\x48\x60\x2f\x9e\xa4\xbc\xd4\x9c\x20\x27\x16\xac\x33\xcb\xcf\xab\x93" "\x7a\x3b\x74\xa0\x18\x92\xa1\x4f\xfc\x52\x19\xee\x7a\x13\x73\xba\x36" "\xaf\x78\x5d\xb6\x1f\x96\x76\x15\x73\xee\x04\xa8\x70\x27\xf7\xe7\xfa" "\xe8\xf6\xc8\x5f\x4a\x81\x56\x0a\x94\xf3\xc6\x98\xd2\x93\xc4\x0b\x49" "\x6b\x44\xd3\x73\xa2\xe3\xef\x5d\x9e\x68\xac\xa7\x42\xb1\xbb\x65\xbe" "\x59"; static const unsigned char sha256_sig[] = "\x0f\x8c\xdb\xe6\xb6\x21\xc8\xc5\x28\x76\x7d\xf6\xf2\x3b\x78\x47\x77" "\x03\x34\xc5\x5e\xc0\xda\x42\x41\xc0\x0f\x97\xd3\xd0\x53\xa1\xd6\x87" "\xe4\x16\x29\x9a\xa5\x59\xf4\x01\xad\xc9\x04\xe7\x61\xe2\xcb\x79\x73" "\xce\xe0\xa6\x85\xe5\x10\x8c\x4b\xc5\x68\x3b\x96\x42\x3f\x56\xb3\x6d" "\x89\xc4\xff\x72\x36\xf2\x3f\xed\xe9\xb8\xe3\xae\xab\x3c\xb7\xaa\xf7" "\x1f\x8f\x26\x6b\xee\xc1\xac\x72\x89\x23\x8b\x7a\xd7\x8c\x84\xf3\xf5" "\x97\xa8\x8d\xd3\xef\xb2\x5e\x06\x04\x21\xdd\x28\xa2\x28\x83\x68\x9b" "\xac\x34\xdd\x36\x33\xda\xdd\xa4\x59\xc7\x5a\x4d\xf3\x83\x06\xd5\xc0" "\x0d\x1f\x4f\x47\x2f\x9f\xcc\xc2\x0d\x21\x1e\x82\xb9\x3d\xf3\xa4\x1a" "\xa6\xd8\x0e\x72\x1d\x71\x17\x1c\x54\xad\x37\x3e\xa4\x0e\x70\x86\x53" "\xfb\x40\xad\xb9\x14\xf8\x8d\x93\xbb\xd7\xe7\x31\xce\xe0\x98\xda\x27" "\x1c\x18\x8e\xd8\x85\xcb\xa7\xb1\x18\xac\x8c\xa8\x9d\xa9\xe2\xf6\x30" "\x95\xa4\x81\xf4\x1c\xa0\x31\xd5\xc7\x9d\x28\x33\xee\x7f\x08\x4f\xcb" "\xd1\x14\x17\xdf\xd0\x88\x78\x47\x29\xaf\x6c\xb2\x62\xa6\x30\x87\x29" "\xaa\x80\x19\x7d\x2f\x05\xe3\x7e\x23\x73\x88\x08\xcc\xbd\x50\x46\x09" "\x2a"; static const unsigned char sha512_sig[] = "\x15\xda\x87\x87\x1f\x76\x08\xd3\x9d\x3a\xb9\xd2\x6a\x0e\x3b\x7d\xdd" "\xec\x7d\xc4\x6d\x26\xf5\x04\xd3\x76\xc7\x83\xc4\x81\x69\x35\xe9\x47" "\xbf\x49\xd1\xc0\xf9\x01\x4e\x0a\x34\x5b\xd0\xec\x6e\xe2\x2e\xe9\x2d" "\x00\xfd\xe0\xa0\x28\x54\x53\x19\x49\x6d\xd2\x58\xb9\x47\xfa\x45\xad" "\xd2\x1d\x52\xac\x80\xcb\xfc\x91\x97\x84\x58\x5f\xab\x21\x62\x60\x79" "\xb8\x8a\x83\xe1\xf1\xcb\x05\x4c\x92\x56\x62\xd9\xbf\xa7\x81\x34\x23" "\xdf\xd7\xa7\xc4\xdf\xde\x96\x00\x57\x4b\x78\x85\xb9\x3b\xdd\x3f\x98" "\x88\x59\x1d\x48\xcf\x5a\xa8\xb7\x2a\x8b\x77\x93\x8e\x38\x3a\x0c\xa7" "\x8a\x5f\xe6\x9f\xcb\xf0\x9a\x6b\xb6\x91\x04\x8b\x69\x6a\x37\xee\xa2" "\xad\x5f\x31\x20\x96\xd6\x51\x80\xbf\x62\x48\xb8\xe4\x94\x10\x86\x4e" "\xf2\x22\x1e\xa4\xd5\x54\xfe\xe1\x35\x49\xaf\xf8\x62\xfc\x11\xeb\xf7" "\x3d\xd5\x5e\xaf\x11\xbd\x3d\xa9\x3a\x9f\x7f\xe8\xb4\x0d\xa2\xbb\x1c" "\xbd\x4c\xed\x9e\x81\xb1\xec\xd3\xea\xaa\x03\xe3\x14\xdf\x8c\xb3\x78" "\x85\x5e\x87\xad\xec\x41\x1a\xa9\x4f\xd2\xe6\xc6\xbe\xfa\xb8\x10\xea" "\x74\x25\x36\x0c\x23\xe2\x24\xb7\x21\xb7\x0d\xaf\xf6\xb4\x31\xf5\x75" "\xf1"; static isc_result_t check_algorithm(unsigned char algorithm) { rsa_components_t c = { .bnfree = true }; EVP_MD_CTX *evp_md_ctx = EVP_MD_CTX_create(); EVP_PKEY *pkey = NULL; const EVP_MD *type = NULL; const unsigned char *sig = NULL; isc_result_t ret = ISC_R_SUCCESS; size_t len; if (evp_md_ctx == NULL) { DST_RET(ISC_R_NOMEMORY); } switch (algorithm) { case DST_ALG_RSASHA1: case DST_ALG_NSEC3RSASHA1: type = EVP_sha1(); /* SHA1 + RSA */ sig = sha1_sig; len = sizeof(sha1_sig) - 1; break; case DST_ALG_RSASHA256: type = EVP_sha256(); /* SHA256 + RSA */ sig = sha256_sig; len = sizeof(sha256_sig) - 1; break; case DST_ALG_RSASHA512: type = EVP_sha512(); sig = sha512_sig; len = sizeof(sha512_sig) - 1; break; default: DST_RET(ISC_R_NOTIMPLEMENTED); } if (type == NULL) { DST_RET(ISC_R_NOTIMPLEMENTED); } /* * Construct pkey. */ c.e = BN_bin2bn(e_bytes, sizeof(e_bytes) - 1, NULL); c.n = BN_bin2bn(n_bytes, sizeof(n_bytes) - 1, NULL); if (c.e == NULL || c.n == NULL) { DST_RET(ISC_R_NOMEMORY); } ret = opensslrsa_build_pkey(false, &c, &pkey); if (ret != ISC_R_SUCCESS) { goto err; } /* * Check that we can verify the signature. */ if (EVP_DigestInit_ex(evp_md_ctx, type, NULL) != 1 || EVP_DigestUpdate(evp_md_ctx, "test", 4) != 1 || EVP_VerifyFinal(evp_md_ctx, sig, len, pkey) != 1) { DST_RET(ISC_R_NOTIMPLEMENTED); } err: opensslrsa_components_free(&c); EVP_PKEY_free(pkey); EVP_MD_CTX_destroy(evp_md_ctx); ERR_clear_error(); return ret; } isc_result_t dst__opensslrsa_init(dst_func_t **funcp, unsigned char algorithm) { isc_result_t result; REQUIRE(funcp != NULL); result = check_algorithm(algorithm); if (result == ISC_R_SUCCESS) { if (*funcp == NULL) { *funcp = &opensslrsa_functions; } } else if (result == ISC_R_NOTIMPLEMENTED) { result = ISC_R_SUCCESS; } return result; }