/* $NetBSD: dst_parse.c,v 1.9.2.2 2024/02/25 15:46:49 martin Exp $ */ /* * Copyright (C) Internet Systems Consortium, Inc. ("ISC") * * SPDX-License-Identifier: MPL-2.0 AND ISC * * 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. */ /* * Copyright (C) Network Associates, Inc. * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND ISC AND NETWORK ASSOCIATES DISCLAIMS * ALL WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL ISC BE LIABLE * FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR * IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include "dst_parse.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "dst_internal.h" #include "isc/result.h" #define DST_AS_STR(t) ((t).value.as_textregion.base) #define PRIVATE_KEY_STR "Private-key-format:" #define ALGORITHM_STR "Algorithm:" #define TIMING_NTAGS (DST_MAX_TIMES + 1) static const char *timetags[TIMING_NTAGS] = { "Created:", "Publish:", "Activate:", "Revoke:", "Inactive:", "Delete:", "DSPublish:", "SyncPublish:", "SyncDelete:", NULL, NULL, NULL, NULL }; #define NUMERIC_NTAGS (DST_MAX_NUMERIC + 1) static const char *numerictags[NUMERIC_NTAGS] = { "Predecessor:", "Successor:", "MaxTTL:", "RollPeriod:", NULL, NULL, NULL }; struct parse_map { const int value; const char *tag; }; static struct parse_map map[] = { { TAG_RSA_MODULUS, "Modulus:" }, { TAG_RSA_PUBLICEXPONENT, "PublicExponent:" }, { TAG_RSA_PRIVATEEXPONENT, "PrivateExponent" ":" }, { TAG_RSA_PRIME1, "Prime1:" }, { TAG_RSA_PRIME2, "Prime2:" }, { TAG_RSA_EXPONENT1, "Exponent1:" }, { TAG_RSA_EXPONENT2, "Exponent2:" }, { TAG_RSA_COEFFICIENT, "Coefficient:" }, { TAG_RSA_ENGINE, "Engine:" }, { TAG_RSA_LABEL, "Label:" }, { TAG_DH_PRIME, "Prime(p):" }, { TAG_DH_GENERATOR, "Generator(g):" }, { TAG_DH_PRIVATE, "Private_value(x):" }, { TAG_DH_PUBLIC, "Public_value(y):" }, { TAG_ECDSA_PRIVATEKEY, "PrivateKey:" }, { TAG_ECDSA_ENGINE, "Engine:" }, { TAG_ECDSA_LABEL, "Label:" }, { TAG_EDDSA_PRIVATEKEY, "PrivateKey:" }, { TAG_EDDSA_ENGINE, "Engine:" }, { TAG_EDDSA_LABEL, "Label:" }, { TAG_HMACMD5_KEY, "Key:" }, { TAG_HMACMD5_BITS, "Bits:" }, { TAG_HMACSHA1_KEY, "Key:" }, { TAG_HMACSHA1_BITS, "Bits:" }, { TAG_HMACSHA224_KEY, "Key:" }, { TAG_HMACSHA224_BITS, "Bits:" }, { TAG_HMACSHA256_KEY, "Key:" }, { TAG_HMACSHA256_BITS, "Bits:" }, { TAG_HMACSHA384_KEY, "Key:" }, { TAG_HMACSHA384_BITS, "Bits:" }, { TAG_HMACSHA512_KEY, "Key:" }, { TAG_HMACSHA512_BITS, "Bits:" }, { 0, NULL } }; static int find_value(const char *s, const unsigned int alg) { int i; for (i = 0; map[i].tag != NULL; i++) { if (strcasecmp(s, map[i].tag) == 0 && (TAG_ALG(map[i].value) == alg)) { return (map[i].value); } } return (-1); } static const char * find_tag(const int value) { int i; for (i = 0;; i++) { if (map[i].tag == NULL) { return (NULL); } else if (value == map[i].value) { return (map[i].tag); } } } static int find_metadata(const char *s, const char *tags[], int ntags) { int i; for (i = 0; i < ntags; i++) { if (tags[i] != NULL && strcasecmp(s, tags[i]) == 0) { return (i); } } return (-1); } static int find_timedata(const char *s) { return (find_metadata(s, timetags, TIMING_NTAGS)); } static int find_numericdata(const char *s) { return (find_metadata(s, numerictags, NUMERIC_NTAGS)); } static int check_rsa(const dst_private_t *priv, bool external) { int i, j; bool have[RSA_NTAGS]; bool ok; unsigned int mask; if (external) { return ((priv->nelements == 0) ? 0 : -1); } for (i = 0; i < RSA_NTAGS; i++) { have[i] = false; } for (j = 0; j < priv->nelements; j++) { for (i = 0; i < RSA_NTAGS; i++) { if (priv->elements[j].tag == TAG(DST_ALG_RSA, i)) { break; } } if (i == RSA_NTAGS) { return (-1); } have[i] = true; } mask = (1ULL << TAG_SHIFT) - 1; if (have[TAG_RSA_ENGINE & mask]) { ok = have[TAG_RSA_MODULUS & mask] && have[TAG_RSA_PUBLICEXPONENT & mask] && have[TAG_RSA_LABEL & mask]; } else { ok = have[TAG_RSA_MODULUS & mask] && have[TAG_RSA_PUBLICEXPONENT & mask] && have[TAG_RSA_PRIVATEEXPONENT & mask] && have[TAG_RSA_PRIME1 & mask] && have[TAG_RSA_PRIME2 & mask] && have[TAG_RSA_EXPONENT1 & mask] && have[TAG_RSA_EXPONENT2 & mask] && have[TAG_RSA_COEFFICIENT & mask]; } return (ok ? 0 : -1); } static int check_dh(const dst_private_t *priv) { int i, j; if (priv->nelements != DH_NTAGS) { return (-1); } for (i = 0; i < DH_NTAGS; i++) { for (j = 0; j < priv->nelements; j++) { if (priv->elements[j].tag == TAG(DST_ALG_DH, i)) { break; } } if (j == priv->nelements) { return (-1); } } return (0); } static int check_ecdsa(const dst_private_t *priv, bool external) { int i, j; bool have[ECDSA_NTAGS]; bool ok; unsigned int mask; if (external) { return ((priv->nelements == 0) ? 0 : -1); } for (i = 0; i < ECDSA_NTAGS; i++) { have[i] = false; } for (j = 0; j < priv->nelements; j++) { for (i = 0; i < ECDSA_NTAGS; i++) { if (priv->elements[j].tag == TAG(DST_ALG_ECDSA256, i)) { break; } } if (i == ECDSA_NTAGS) { return (-1); } have[i] = true; } mask = (1ULL << TAG_SHIFT) - 1; if (have[TAG_ECDSA_ENGINE & mask]) { ok = have[TAG_ECDSA_LABEL & mask]; } else { ok = have[TAG_ECDSA_PRIVATEKEY & mask]; } return (ok ? 0 : -1); } static int check_eddsa(const dst_private_t *priv, bool external) { int i, j; bool have[EDDSA_NTAGS]; bool ok; unsigned int mask; if (external) { return ((priv->nelements == 0) ? 0 : -1); } for (i = 0; i < EDDSA_NTAGS; i++) { have[i] = false; } for (j = 0; j < priv->nelements; j++) { for (i = 0; i < EDDSA_NTAGS; i++) { if (priv->elements[j].tag == TAG(DST_ALG_ED25519, i)) { break; } } if (i == EDDSA_NTAGS) { return (-1); } have[i] = true; } mask = (1ULL << TAG_SHIFT) - 1; if (have[TAG_EDDSA_ENGINE & mask]) { ok = have[TAG_EDDSA_LABEL & mask]; } else { ok = have[TAG_EDDSA_PRIVATEKEY & mask]; } return (ok ? 0 : -1); } static int check_hmac_md5(const dst_private_t *priv, bool old) { int i, j; if (priv->nelements != HMACMD5_NTAGS) { /* * If this is a good old format and we are accepting * the old format return success. */ if (old && priv->nelements == OLD_HMACMD5_NTAGS && priv->elements[0].tag == TAG_HMACMD5_KEY) { return (0); } return (-1); } /* * We must be new format at this point. */ for (i = 0; i < HMACMD5_NTAGS; i++) { for (j = 0; j < priv->nelements; j++) { if (priv->elements[j].tag == TAG(DST_ALG_HMACMD5, i)) { break; } } if (j == priv->nelements) { return (-1); } } return (0); } static int check_hmac_sha(const dst_private_t *priv, unsigned int ntags, unsigned int alg) { unsigned int i, j; if (priv->nelements != ntags) { return (-1); } for (i = 0; i < ntags; i++) { for (j = 0; j < priv->nelements; j++) { if (priv->elements[j].tag == TAG(alg, i)) { break; } } if (j == priv->nelements) { return (-1); } } return (0); } static int check_data(const dst_private_t *priv, const unsigned int alg, bool old, bool external) { /* XXXVIX this switch statement is too sparse to gen a jump table. */ switch (alg) { case DST_ALG_RSA: case DST_ALG_RSASHA1: case DST_ALG_NSEC3RSASHA1: case DST_ALG_RSASHA256: case DST_ALG_RSASHA512: return (check_rsa(priv, external)); case DST_ALG_DH: return (check_dh(priv)); case DST_ALG_ECDSA256: case DST_ALG_ECDSA384: return (check_ecdsa(priv, external)); case DST_ALG_ED25519: case DST_ALG_ED448: return (check_eddsa(priv, external)); case DST_ALG_HMACMD5: return (check_hmac_md5(priv, old)); case DST_ALG_HMACSHA1: return (check_hmac_sha(priv, HMACSHA1_NTAGS, alg)); case DST_ALG_HMACSHA224: return (check_hmac_sha(priv, HMACSHA224_NTAGS, alg)); case DST_ALG_HMACSHA256: return (check_hmac_sha(priv, HMACSHA256_NTAGS, alg)); case DST_ALG_HMACSHA384: return (check_hmac_sha(priv, HMACSHA384_NTAGS, alg)); case DST_ALG_HMACSHA512: return (check_hmac_sha(priv, HMACSHA512_NTAGS, alg)); default: return (DST_R_UNSUPPORTEDALG); } } void dst__privstruct_free(dst_private_t *priv, isc_mem_t *mctx) { int i; if (priv == NULL) { return; } for (i = 0; i < priv->nelements; i++) { if (priv->elements[i].data == NULL) { continue; } memset(priv->elements[i].data, 0, MAXFIELDSIZE); isc_mem_put(mctx, priv->elements[i].data, MAXFIELDSIZE); } priv->nelements = 0; } isc_result_t dst__privstruct_parse(dst_key_t *key, unsigned int alg, isc_lex_t *lex, isc_mem_t *mctx, dst_private_t *priv) { int n = 0, major, minor, check; isc_buffer_t b; isc_token_t token; unsigned char *data = NULL; unsigned int opt = ISC_LEXOPT_EOL; isc_stdtime_t when; isc_result_t ret; bool external = false; REQUIRE(priv != NULL); priv->nelements = 0; memset(priv->elements, 0, sizeof(priv->elements)); #define NEXTTOKEN(lex, opt, token) \ do { \ ret = isc_lex_gettoken(lex, opt, token); \ if (ret != ISC_R_SUCCESS) \ goto fail; \ } while (0) #define READLINE(lex, opt, token) \ do { \ ret = isc_lex_gettoken(lex, opt, token); \ if (ret == ISC_R_EOF) \ break; \ else if (ret != ISC_R_SUCCESS) \ goto fail; \ } while ((*token).type != isc_tokentype_eol) /* * Read the description line. */ NEXTTOKEN(lex, opt, &token); if (token.type != isc_tokentype_string || strcmp(DST_AS_STR(token), PRIVATE_KEY_STR) != 0) { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } NEXTTOKEN(lex, opt, &token); if (token.type != isc_tokentype_string || (DST_AS_STR(token))[0] != 'v') { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } if (sscanf(DST_AS_STR(token), "v%d.%d", &major, &minor) != 2) { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } if (major > DST_MAJOR_VERSION) { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } /* * Store the private key format version number */ dst_key_setprivateformat(key, major, minor); READLINE(lex, opt, &token); /* * Read the algorithm line. */ NEXTTOKEN(lex, opt, &token); if (token.type != isc_tokentype_string || strcmp(DST_AS_STR(token), ALGORITHM_STR) != 0) { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } NEXTTOKEN(lex, opt | ISC_LEXOPT_NUMBER, &token); if (token.type != isc_tokentype_number || token.value.as_ulong != (unsigned long)dst_key_alg(key)) { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } READLINE(lex, opt, &token); /* * Read the key data. */ for (n = 0; n < MAXFIELDS; n++) { int tag; isc_region_t r; do { ret = isc_lex_gettoken(lex, opt, &token); if (ret == ISC_R_EOF) { goto done; } if (ret != ISC_R_SUCCESS) { goto fail; } } while (token.type == isc_tokentype_eol); if (token.type != isc_tokentype_string) { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } if (strcmp(DST_AS_STR(token), "External:") == 0) { external = true; goto next; } /* Numeric metadata */ tag = find_numericdata(DST_AS_STR(token)); if (tag >= 0) { INSIST(tag < NUMERIC_NTAGS); NEXTTOKEN(lex, opt | ISC_LEXOPT_NUMBER, &token); if (token.type != isc_tokentype_number) { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } dst_key_setnum(key, tag, token.value.as_ulong); goto next; } /* Timing metadata */ tag = find_timedata(DST_AS_STR(token)); if (tag >= 0) { INSIST(tag < TIMING_NTAGS); NEXTTOKEN(lex, opt, &token); if (token.type != isc_tokentype_string) { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } ret = dns_time32_fromtext(DST_AS_STR(token), &when); if (ret != ISC_R_SUCCESS) { goto fail; } dst_key_settime(key, tag, when); goto next; } /* Key data */ tag = find_value(DST_AS_STR(token), alg); if (tag < 0 && minor > DST_MINOR_VERSION) { goto next; } else if (tag < 0) { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } priv->elements[n].tag = tag; data = isc_mem_get(mctx, MAXFIELDSIZE); isc_buffer_init(&b, data, MAXFIELDSIZE); ret = isc_base64_tobuffer(lex, &b, -1); if (ret != ISC_R_SUCCESS) { goto fail; } isc_buffer_usedregion(&b, &r); priv->elements[n].length = r.length; priv->elements[n].data = r.base; priv->nelements++; next: READLINE(lex, opt, &token); data = NULL; } done: if (external && priv->nelements != 0) { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } check = check_data(priv, alg, true, external); if (check < 0) { ret = DST_R_INVALIDPRIVATEKEY; goto fail; } else if (check != ISC_R_SUCCESS) { ret = check; goto fail; } key->external = external; return (ISC_R_SUCCESS); fail: dst__privstruct_free(priv, mctx); if (data != NULL) { isc_mem_put(mctx, data, MAXFIELDSIZE); } return (ret); } isc_result_t dst__privstruct_writefile(const dst_key_t *key, const dst_private_t *priv, const char *directory) { FILE *fp; isc_result_t result; char filename[NAME_MAX]; char tmpname[NAME_MAX]; char buffer[MAXFIELDSIZE * 2]; isc_stdtime_t when; uint32_t value; isc_buffer_t b; isc_buffer_t fileb; isc_buffer_t tmpb; isc_region_t r; int major, minor; mode_t mode; int i, ret; REQUIRE(priv != NULL); ret = check_data(priv, dst_key_alg(key), false, key->external); if (ret < 0) { return (DST_R_INVALIDPRIVATEKEY); } else if (ret != ISC_R_SUCCESS) { return (ret); } isc_buffer_init(&fileb, filename, sizeof(filename)); result = dst_key_buildfilename(key, DST_TYPE_PRIVATE, directory, &fileb); if (result != ISC_R_SUCCESS) { return (result); } result = isc_file_mode(filename, &mode); if (result == ISC_R_SUCCESS && mode != (S_IRUSR | S_IWUSR)) { /* File exists; warn that we are changing its permissions */ int level; level = ISC_LOG_WARNING; isc_log_write(dns_lctx, DNS_LOGCATEGORY_GENERAL, DNS_LOGMODULE_DNSSEC, level, "Permissions on the file %s " "have changed from 0%o to 0600 as " "a result of this operation.", filename, (unsigned int)mode); } isc_buffer_init(&tmpb, tmpname, sizeof(tmpname)); result = dst_key_buildfilename(key, DST_TYPE_TEMPLATE, directory, &tmpb); if (result != ISC_R_SUCCESS) { return (result); } fp = dst_key_open(tmpname, S_IRUSR | S_IWUSR); if (fp == NULL) { return (DST_R_WRITEERROR); } dst_key_getprivateformat(key, &major, &minor); if (major == 0 && minor == 0) { major = DST_MAJOR_VERSION; minor = DST_MINOR_VERSION; } /* XXXDCL return value should be checked for full filesystem */ fprintf(fp, "%s v%d.%d\n", PRIVATE_KEY_STR, major, minor); fprintf(fp, "%s %u ", ALGORITHM_STR, dst_key_alg(key)); /* XXXVIX this switch statement is too sparse to gen a jump table. */ switch (dst_key_alg(key)) { case DST_ALG_DH: fprintf(fp, "(DH)\n"); break; case DST_ALG_RSASHA1: fprintf(fp, "(RSASHA1)\n"); break; case DST_ALG_NSEC3RSASHA1: fprintf(fp, "(NSEC3RSASHA1)\n"); break; case DST_ALG_RSASHA256: fprintf(fp, "(RSASHA256)\n"); break; case DST_ALG_RSASHA512: fprintf(fp, "(RSASHA512)\n"); break; case DST_ALG_ECDSA256: fprintf(fp, "(ECDSAP256SHA256)\n"); break; case DST_ALG_ECDSA384: fprintf(fp, "(ECDSAP384SHA384)\n"); break; case DST_ALG_ED25519: fprintf(fp, "(ED25519)\n"); break; case DST_ALG_ED448: fprintf(fp, "(ED448)\n"); break; case DST_ALG_HMACMD5: fprintf(fp, "(HMAC_MD5)\n"); break; case DST_ALG_HMACSHA1: fprintf(fp, "(HMAC_SHA1)\n"); break; case DST_ALG_HMACSHA224: fprintf(fp, "(HMAC_SHA224)\n"); break; case DST_ALG_HMACSHA256: fprintf(fp, "(HMAC_SHA256)\n"); break; case DST_ALG_HMACSHA384: fprintf(fp, "(HMAC_SHA384)\n"); break; case DST_ALG_HMACSHA512: fprintf(fp, "(HMAC_SHA512)\n"); break; default: fprintf(fp, "(?)\n"); break; } for (i = 0; i < priv->nelements; i++) { const char *s; s = find_tag(priv->elements[i].tag); r.base = priv->elements[i].data; r.length = priv->elements[i].length; isc_buffer_init(&b, buffer, sizeof(buffer)); result = isc_base64_totext(&r, sizeof(buffer), "", &b); if (result != ISC_R_SUCCESS) { return (dst_key_cleanup(tmpname, fp)); } isc_buffer_usedregion(&b, &r); fprintf(fp, "%s %.*s\n", s, (int)r.length, r.base); } if (key->external) { fprintf(fp, "External:\n"); } /* Add the metadata tags */ if (major > 1 || (major == 1 && minor >= 3)) { for (i = 0; i < NUMERIC_NTAGS; i++) { result = dst_key_getnum(key, i, &value); if (result != ISC_R_SUCCESS) { continue; } if (numerictags[i] != NULL) { fprintf(fp, "%s %u\n", numerictags[i], value); } } for (i = 0; i < TIMING_NTAGS; i++) { result = dst_key_gettime(key, i, &when); if (result != ISC_R_SUCCESS) { continue; } isc_buffer_init(&b, buffer, sizeof(buffer)); result = dns_time32_totext(when, &b); if (result != ISC_R_SUCCESS) { return (dst_key_cleanup(tmpname, fp)); } isc_buffer_usedregion(&b, &r); if (timetags[i] != NULL) { fprintf(fp, "%s %.*s\n", timetags[i], (int)r.length, r.base); } } } result = dst_key_close(tmpname, fp, filename); return (result); } /*! \file */