/* * 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 #include #include #include /* Required for HP/UX (and others?) */ #include #include #include #include #include #include #include #include #include #include #include #include #include "tsig_p.h" #define TSIG_MAGIC ISC_MAGIC('T', 'S', 'I', 'G') #define VALID_TSIG_KEY(x) ISC_MAGIC_VALID(x, TSIG_MAGIC) #ifndef DNS_TSIG_MAXGENERATEDKEYS #define DNS_TSIG_MAXGENERATEDKEYS 4096 #endif /* ifndef DNS_TSIG_MAXGENERATEDKEYS */ #define is_response(msg) ((msg->flags & DNS_MESSAGEFLAG_QR) != 0) #define BADTIMELEN 6 static unsigned char hmacmd5_ndata[] = "\010hmac-md5\007sig-alg\003reg\003int"; static unsigned char hmacmd5_offsets[] = { 0, 9, 17, 21, 25 }; static dns_name_t const hmacmd5 = DNS_NAME_INITABSOLUTE(hmacmd5_ndata, hmacmd5_offsets); const dns_name_t *dns_tsig_hmacmd5_name = &hmacmd5; static unsigned char gsstsig_ndata[] = "\010gss-tsig"; static unsigned char gsstsig_offsets[] = { 0, 9 }; static dns_name_t const gsstsig = DNS_NAME_INITABSOLUTE(gsstsig_ndata, gsstsig_offsets); const dns_name_t *dns_tsig_gssapi_name = &gsstsig; /* * Since Microsoft doesn't follow its own standard, we will use this * alternate name as a second guess. */ static unsigned char gsstsigms_ndata[] = "\003gss\011microsoft\003com"; static unsigned char gsstsigms_offsets[] = { 0, 4, 14, 18 }; static dns_name_t const gsstsigms = DNS_NAME_INITABSOLUTE(gsstsigms_ndata, gsstsigms_offsets); const dns_name_t *dns_tsig_gssapims_name = &gsstsigms; static unsigned char hmacsha1_ndata[] = "\011hmac-sha1"; static unsigned char hmacsha1_offsets[] = { 0, 10 }; static dns_name_t const hmacsha1 = DNS_NAME_INITABSOLUTE(hmacsha1_ndata, hmacsha1_offsets); const dns_name_t *dns_tsig_hmacsha1_name = &hmacsha1; static unsigned char hmacsha224_ndata[] = "\013hmac-sha224"; static unsigned char hmacsha224_offsets[] = { 0, 12 }; static dns_name_t const hmacsha224 = DNS_NAME_INITABSOLUTE(hmacsha224_ndata, hmacsha224_offsets); const dns_name_t *dns_tsig_hmacsha224_name = &hmacsha224; static unsigned char hmacsha256_ndata[] = "\013hmac-sha256"; static unsigned char hmacsha256_offsets[] = { 0, 12 }; static dns_name_t const hmacsha256 = DNS_NAME_INITABSOLUTE(hmacsha256_ndata, hmacsha256_offsets); const dns_name_t *dns_tsig_hmacsha256_name = &hmacsha256; static unsigned char hmacsha384_ndata[] = "\013hmac-sha384"; static unsigned char hmacsha384_offsets[] = { 0, 12 }; static dns_name_t const hmacsha384 = DNS_NAME_INITABSOLUTE(hmacsha384_ndata, hmacsha384_offsets); const dns_name_t *dns_tsig_hmacsha384_name = &hmacsha384; static unsigned char hmacsha512_ndata[] = "\013hmac-sha512"; static unsigned char hmacsha512_offsets[] = { 0, 12 }; static dns_name_t const hmacsha512 = DNS_NAME_INITABSOLUTE(hmacsha512_ndata, hmacsha512_offsets); const dns_name_t *dns_tsig_hmacsha512_name = &hmacsha512; static const struct { const dns_name_t *name; unsigned int dstalg; } known_algs[] = { { &hmacmd5, DST_ALG_HMACMD5 }, { &gsstsig, DST_ALG_GSSAPI }, { &gsstsigms, DST_ALG_GSSAPI }, { &hmacsha1, DST_ALG_HMACSHA1 }, { &hmacsha224, DST_ALG_HMACSHA224 }, { &hmacsha256, DST_ALG_HMACSHA256 }, { &hmacsha384, DST_ALG_HMACSHA384 }, { &hmacsha512, DST_ALG_HMACSHA512 } }; static isc_result_t tsig_verify_tcp(isc_buffer_t *source, dns_message_t *msg); static void tsig_log(dns_tsigkey_t *key, int level, const char *fmt, ...) ISC_FORMAT_PRINTF(3, 4); static void cleanup_ring(dns_tsig_keyring_t *ring); static void tsigkey_free(dns_tsigkey_t *key); bool dns__tsig_algvalid(unsigned int alg) { return (alg == DST_ALG_HMACMD5 || alg == DST_ALG_HMACSHA1 || alg == DST_ALG_HMACSHA224 || alg == DST_ALG_HMACSHA256 || alg == DST_ALG_HMACSHA384 || alg == DST_ALG_HMACSHA512); } static void tsig_log(dns_tsigkey_t *key, int level, const char *fmt, ...) { va_list ap; char message[4096]; char namestr[DNS_NAME_FORMATSIZE]; char creatorstr[DNS_NAME_FORMATSIZE]; if (!isc_log_wouldlog(dns_lctx, level)) { return; } if (key != NULL) { dns_name_format(&key->name, namestr, sizeof(namestr)); } else { strlcpy(namestr, "", sizeof(namestr)); } if (key != NULL && key->generated && key->creator) { dns_name_format(key->creator, creatorstr, sizeof(creatorstr)); } else { strlcpy(creatorstr, "", sizeof(creatorstr)); } va_start(ap, fmt); vsnprintf(message, sizeof(message), fmt, ap); va_end(ap); if (key != NULL && key->generated) { isc_log_write(dns_lctx, DNS_LOGCATEGORY_DNSSEC, DNS_LOGMODULE_TSIG, level, "tsig key '%s' (%s): %s", namestr, creatorstr, message); } else { isc_log_write(dns_lctx, DNS_LOGCATEGORY_DNSSEC, DNS_LOGMODULE_TSIG, level, "tsig key '%s': %s", namestr, message); } } static void remove_fromring(dns_tsigkey_t *tkey) { if (tkey->generated) { ISC_LIST_UNLINK(tkey->ring->lru, tkey, link); tkey->ring->generated--; } (void)dns_rbt_deletename(tkey->ring->keys, &tkey->name, false); } static void adjust_lru(dns_tsigkey_t *tkey) { if (tkey->generated) { RWLOCK(&tkey->ring->lock, isc_rwlocktype_write); /* * We may have been removed from the LRU list between * removing the read lock and acquiring the write lock. */ if (ISC_LINK_LINKED(tkey, link) && tkey->ring->lru.tail != tkey) { ISC_LIST_UNLINK(tkey->ring->lru, tkey, link); ISC_LIST_APPEND(tkey->ring->lru, tkey, link); } RWUNLOCK(&tkey->ring->lock, isc_rwlocktype_write); } } /* * A supplemental routine just to add a key to ring. Note that reference * counter should be counted separately because we may be adding the key * as part of creation of the key, in which case the reference counter was * already initialized. Also note we don't need RWLOCK for the reference * counter: it's protected by a separate lock. */ static isc_result_t keyring_add(dns_tsig_keyring_t *ring, const dns_name_t *name, dns_tsigkey_t *tkey) { isc_result_t result; RWLOCK(&ring->lock, isc_rwlocktype_write); ring->writecount++; /* * Do on the fly cleaning. Find some nodes we might not * want around any more. */ if (ring->writecount > 10) { cleanup_ring(ring); ring->writecount = 0; } result = dns_rbt_addname(ring->keys, name, tkey); if (result == ISC_R_SUCCESS) { if (tkey->generated) { /* * Add the new key to the LRU list and remove the * least recently used key if there are too many * keys on the list. */ ISC_LIST_APPEND(ring->lru, tkey, link); if (ring->generated++ > ring->maxgenerated) { remove_fromring(ISC_LIST_HEAD(ring->lru)); } } tkey->ring = ring; } RWUNLOCK(&ring->lock, isc_rwlocktype_write); return (result); } isc_result_t dns_tsigkey_createfromkey(const dns_name_t *name, const dns_name_t *algorithm, dst_key_t *dstkey, bool generated, const dns_name_t *creator, isc_stdtime_t inception, isc_stdtime_t expire, isc_mem_t *mctx, dns_tsig_keyring_t *ring, dns_tsigkey_t **key) { dns_tsigkey_t *tkey; isc_result_t ret; unsigned int refs = 0; unsigned int dstalg = 0; REQUIRE(key == NULL || *key == NULL); REQUIRE(name != NULL); REQUIRE(algorithm != NULL); REQUIRE(mctx != NULL); REQUIRE(key != NULL || ring != NULL); tkey = isc_mem_get(mctx, sizeof(dns_tsigkey_t)); dns_name_init(&tkey->name, NULL); dns_name_dup(name, mctx, &tkey->name); (void)dns_name_downcase(&tkey->name, &tkey->name, NULL); /* Check against known algorithm names */ dstalg = dns__tsig_algfromname(algorithm); if (dstalg != 0) { /* * 'algorithm' must be set to a static pointer * so that dns__tsig_algallocated() can compare them. */ tkey->algorithm = dns__tsig_algnamefromname(algorithm); if (dstkey != NULL && dst_key_alg(dstkey) != dstalg) { ret = DNS_R_BADALG; goto cleanup_name; } } else { dns_name_t *tmpname; if (dstkey != NULL) { ret = DNS_R_BADALG; goto cleanup_name; } tmpname = isc_mem_get(mctx, sizeof(dns_name_t)); dns_name_init(tmpname, NULL); dns_name_dup(algorithm, mctx, tmpname); (void)dns_name_downcase(tmpname, tmpname, NULL); tkey->algorithm = tmpname; } if (creator != NULL) { tkey->creator = isc_mem_get(mctx, sizeof(dns_name_t)); dns_name_init(tkey->creator, NULL); dns_name_dup(creator, mctx, tkey->creator); } else { tkey->creator = NULL; } tkey->key = NULL; if (dstkey != NULL) { dst_key_attach(dstkey, &tkey->key); } tkey->ring = ring; if (key != NULL) { refs = 1; } if (ring != NULL) { refs++; } isc_refcount_init(&tkey->refs, refs); tkey->generated = generated; tkey->inception = inception; tkey->expire = expire; tkey->mctx = NULL; isc_mem_attach(mctx, &tkey->mctx); ISC_LINK_INIT(tkey, link); tkey->magic = TSIG_MAGIC; if (ring != NULL) { ret = keyring_add(ring, name, tkey); if (ret != ISC_R_SUCCESS) { goto cleanup_refs; } } /* * Ignore this if it's a GSS key, since the key size is meaningless. */ if (dstkey != NULL && dst_key_size(dstkey) < 64 && dstalg != DST_ALG_GSSAPI) { char namestr[DNS_NAME_FORMATSIZE]; dns_name_format(name, namestr, sizeof(namestr)); isc_log_write(dns_lctx, DNS_LOGCATEGORY_DNSSEC, DNS_LOGMODULE_TSIG, ISC_LOG_INFO, "the key '%s' is too short to be secure", namestr); } if (key != NULL) { *key = tkey; } return (ISC_R_SUCCESS); cleanup_refs: tkey->magic = 0; while (refs-- > 0) { isc_refcount_decrement0(&tkey->refs); } isc_refcount_destroy(&tkey->refs); if (tkey->key != NULL) { dst_key_free(&tkey->key); } if (tkey->creator != NULL) { dns_name_free(tkey->creator, mctx); isc_mem_put(mctx, tkey->creator, sizeof(dns_name_t)); } if (dns__tsig_algallocated(tkey->algorithm)) { dns_name_t *tmpname; DE_CONST(tkey->algorithm, tmpname); if (dns_name_dynamic(tmpname)) { dns_name_free(tmpname, mctx); } isc_mem_put(mctx, tmpname, sizeof(dns_name_t)); } cleanup_name: dns_name_free(&tkey->name, mctx); isc_mem_put(mctx, tkey, sizeof(dns_tsigkey_t)); return (ret); } /* * Find a few nodes to destroy if possible. */ static void cleanup_ring(dns_tsig_keyring_t *ring) { isc_result_t result; dns_rbtnodechain_t chain; dns_name_t foundname; dns_fixedname_t fixedorigin; dns_name_t *origin; isc_stdtime_t now; dns_rbtnode_t *node; dns_tsigkey_t *tkey; /* * Start up a new iterator each time. */ isc_stdtime_get(&now); dns_name_init(&foundname, NULL); origin = dns_fixedname_initname(&fixedorigin); again: dns_rbtnodechain_init(&chain); result = dns_rbtnodechain_first(&chain, ring->keys, &foundname, origin); if (result != ISC_R_SUCCESS && result != DNS_R_NEWORIGIN) { dns_rbtnodechain_invalidate(&chain); return; } for (;;) { node = NULL; dns_rbtnodechain_current(&chain, &foundname, origin, &node); tkey = node->data; if (tkey != NULL) { if (tkey->generated && isc_refcount_current(&tkey->refs) == 1 && tkey->inception != tkey->expire && tkey->expire < now) { tsig_log(tkey, 2, "tsig expire: deleting"); /* delete the key */ dns_rbtnodechain_invalidate(&chain); remove_fromring(tkey); goto again; } } result = dns_rbtnodechain_next(&chain, &foundname, origin); if (result != ISC_R_SUCCESS && result != DNS_R_NEWORIGIN) { dns_rbtnodechain_invalidate(&chain); return; } } } static void destroyring(dns_tsig_keyring_t *ring) { isc_refcount_destroy(&ring->references); dns_rbt_destroy(&ring->keys); isc_rwlock_destroy(&ring->lock); isc_mem_putanddetach(&ring->mctx, ring, sizeof(dns_tsig_keyring_t)); } /* * Look up the DST_ALG_ constant for a given name. */ unsigned int dns__tsig_algfromname(const dns_name_t *algorithm) { int i; int n = sizeof(known_algs) / sizeof(*known_algs); for (i = 0; i < n; ++i) { const dns_name_t *name = known_algs[i].name; if (algorithm == name || dns_name_equal(algorithm, name)) { return (known_algs[i].dstalg); } } return (0); } /* * Convert an algorithm name into a pointer to the * corresponding pre-defined dns_name_t structure. */ const dns_name_t * dns__tsig_algnamefromname(const dns_name_t *algorithm) { int i; int n = sizeof(known_algs) / sizeof(*known_algs); for (i = 0; i < n; ++i) { const dns_name_t *name = known_algs[i].name; if (algorithm == name || dns_name_equal(algorithm, name)) { return (name); } } return (NULL); } /* * Test whether the passed algorithm is NOT a pointer to one of the * pre-defined known algorithms (and therefore one that has been * dynamically allocated). * * This will return an incorrect result if passed a dynamically allocated * dns_name_t that happens to match one of the pre-defined names. */ bool dns__tsig_algallocated(const dns_name_t *algorithm) { int i; int n = sizeof(known_algs) / sizeof(*known_algs); for (i = 0; i < n; ++i) { const dns_name_t *name = known_algs[i].name; if (algorithm == name) { return (false); } } return (true); } static isc_result_t restore_key(dns_tsig_keyring_t *ring, isc_stdtime_t now, FILE *fp) { dst_key_t *dstkey = NULL; char namestr[1024]; char creatorstr[1024]; char algorithmstr[1024]; char keystr[4096]; unsigned int inception, expire; int n; isc_buffer_t b; dns_name_t *name, *creator, *algorithm; dns_fixedname_t fname, fcreator, falgorithm; isc_result_t result; unsigned int dstalg; n = fscanf(fp, "%1023s %1023s %u %u %1023s %4095s\n", namestr, creatorstr, &inception, &expire, algorithmstr, keystr); if (n == EOF) { return (ISC_R_NOMORE); } if (n != 6) { return (ISC_R_FAILURE); } if (isc_serial_lt(expire, now)) { return (DNS_R_EXPIRED); } name = dns_fixedname_initname(&fname); isc_buffer_init(&b, namestr, strlen(namestr)); isc_buffer_add(&b, strlen(namestr)); result = dns_name_fromtext(name, &b, dns_rootname, 0, NULL); if (result != ISC_R_SUCCESS) { return (result); } creator = dns_fixedname_initname(&fcreator); isc_buffer_init(&b, creatorstr, strlen(creatorstr)); isc_buffer_add(&b, strlen(creatorstr)); result = dns_name_fromtext(creator, &b, dns_rootname, 0, NULL); if (result != ISC_R_SUCCESS) { return (result); } algorithm = dns_fixedname_initname(&falgorithm); isc_buffer_init(&b, algorithmstr, strlen(algorithmstr)); isc_buffer_add(&b, strlen(algorithmstr)); result = dns_name_fromtext(algorithm, &b, dns_rootname, 0, NULL); if (result != ISC_R_SUCCESS) { return (result); } dstalg = dns__tsig_algfromname(algorithm); if (dstalg == 0) { return (DNS_R_BADALG); } result = dst_key_restore(name, dstalg, DNS_KEYOWNER_ENTITY, DNS_KEYPROTO_DNSSEC, dns_rdataclass_in, ring->mctx, keystr, &dstkey); if (result != ISC_R_SUCCESS) { return (result); } result = dns_tsigkey_createfromkey(name, algorithm, dstkey, true, creator, inception, expire, ring->mctx, ring, NULL); if (dstkey != NULL) { dst_key_free(&dstkey); } return (result); } static void dump_key(dns_tsigkey_t *tkey, FILE *fp) { char *buffer = NULL; int length = 0; char namestr[DNS_NAME_FORMATSIZE]; char creatorstr[DNS_NAME_FORMATSIZE]; char algorithmstr[DNS_NAME_FORMATSIZE]; isc_result_t result; REQUIRE(tkey != NULL); REQUIRE(fp != NULL); dns_name_format(&tkey->name, namestr, sizeof(namestr)); dns_name_format(tkey->creator, creatorstr, sizeof(creatorstr)); dns_name_format(tkey->algorithm, algorithmstr, sizeof(algorithmstr)); result = dst_key_dump(tkey->key, tkey->mctx, &buffer, &length); if (result == ISC_R_SUCCESS) { fprintf(fp, "%s %s %u %u %s %.*s\n", namestr, creatorstr, tkey->inception, tkey->expire, algorithmstr, length, buffer); } if (buffer != NULL) { isc_mem_put(tkey->mctx, buffer, length); } } isc_result_t dns_tsigkeyring_dumpanddetach(dns_tsig_keyring_t **ringp, FILE *fp) { isc_result_t result; dns_rbtnodechain_t chain; dns_name_t foundname; dns_fixedname_t fixedorigin; dns_name_t *origin; isc_stdtime_t now; dns_rbtnode_t *node; dns_tsigkey_t *tkey; dns_tsig_keyring_t *ring; REQUIRE(ringp != NULL && *ringp != NULL); ring = *ringp; *ringp = NULL; if (isc_refcount_decrement(&ring->references) > 1) { return (DNS_R_CONTINUE); } isc_stdtime_get(&now); dns_name_init(&foundname, NULL); origin = dns_fixedname_initname(&fixedorigin); dns_rbtnodechain_init(&chain); result = dns_rbtnodechain_first(&chain, ring->keys, &foundname, origin); if (result != ISC_R_SUCCESS && result != DNS_R_NEWORIGIN) { dns_rbtnodechain_invalidate(&chain); goto destroy; } for (;;) { node = NULL; dns_rbtnodechain_current(&chain, &foundname, origin, &node); tkey = node->data; if (tkey != NULL && tkey->generated && tkey->expire >= now) { dump_key(tkey, fp); } result = dns_rbtnodechain_next(&chain, &foundname, origin); if (result != ISC_R_SUCCESS && result != DNS_R_NEWORIGIN) { dns_rbtnodechain_invalidate(&chain); if (result == ISC_R_NOMORE) { result = ISC_R_SUCCESS; } goto destroy; } } destroy: destroyring(ring); return (result); } const dns_name_t * dns_tsigkey_identity(const dns_tsigkey_t *tsigkey) { REQUIRE(tsigkey == NULL || VALID_TSIG_KEY(tsigkey)); if (tsigkey == NULL) { return (NULL); } if (tsigkey->generated) { return (tsigkey->creator); } else { return (&tsigkey->name); } } isc_result_t dns_tsigkey_create(const dns_name_t *name, const dns_name_t *algorithm, unsigned char *secret, int length, bool generated, const dns_name_t *creator, isc_stdtime_t inception, isc_stdtime_t expire, isc_mem_t *mctx, dns_tsig_keyring_t *ring, dns_tsigkey_t **key) { dst_key_t *dstkey = NULL; isc_result_t result; unsigned int dstalg = 0; REQUIRE(length >= 0); if (length > 0) { REQUIRE(secret != NULL); } dstalg = dns__tsig_algfromname(algorithm); if (dns__tsig_algvalid(dstalg)) { if (secret != NULL) { isc_buffer_t b; isc_buffer_init(&b, secret, length); isc_buffer_add(&b, length); result = dst_key_frombuffer( name, dstalg, DNS_KEYOWNER_ENTITY, DNS_KEYPROTO_DNSSEC, dns_rdataclass_in, &b, mctx, &dstkey); if (result != ISC_R_SUCCESS) { return (result); } } } else if (length > 0) { return (DNS_R_BADALG); } result = dns_tsigkey_createfromkey(name, algorithm, dstkey, generated, creator, inception, expire, mctx, ring, key); if (dstkey != NULL) { dst_key_free(&dstkey); } return (result); } void dns_tsigkey_attach(dns_tsigkey_t *source, dns_tsigkey_t **targetp) { REQUIRE(VALID_TSIG_KEY(source)); REQUIRE(targetp != NULL && *targetp == NULL); isc_refcount_increment(&source->refs); *targetp = source; } static void tsigkey_free(dns_tsigkey_t *key) { REQUIRE(VALID_TSIG_KEY(key)); key->magic = 0; dns_name_free(&key->name, key->mctx); if (dns__tsig_algallocated(key->algorithm)) { dns_name_t *name; DE_CONST(key->algorithm, name); dns_name_free(name, key->mctx); isc_mem_put(key->mctx, name, sizeof(dns_name_t)); } if (key->key != NULL) { dst_key_free(&key->key); } if (key->creator != NULL) { dns_name_free(key->creator, key->mctx); isc_mem_put(key->mctx, key->creator, sizeof(dns_name_t)); } isc_mem_putanddetach(&key->mctx, key, sizeof(dns_tsigkey_t)); } void dns_tsigkey_detach(dns_tsigkey_t **keyp) { REQUIRE(keyp != NULL && VALID_TSIG_KEY(*keyp)); dns_tsigkey_t *key = *keyp; *keyp = NULL; if (isc_refcount_decrement(&key->refs) == 1) { isc_refcount_destroy(&key->refs); tsigkey_free(key); } } void dns_tsigkey_setdeleted(dns_tsigkey_t *key) { REQUIRE(VALID_TSIG_KEY(key)); REQUIRE(key->ring != NULL); RWLOCK(&key->ring->lock, isc_rwlocktype_write); remove_fromring(key); RWUNLOCK(&key->ring->lock, isc_rwlocktype_write); } isc_result_t dns_tsig_sign(dns_message_t *msg) { dns_tsigkey_t *key = NULL; dns_rdata_any_tsig_t tsig, querytsig; unsigned char data[128]; isc_buffer_t databuf, sigbuf; isc_buffer_t *dynbuf = NULL; dns_name_t *owner = NULL; dns_rdata_t *rdata = NULL; dns_rdatalist_t *datalist = NULL; dns_rdataset_t *dataset = NULL; isc_region_t r; isc_stdtime_t now; isc_mem_t *mctx; dst_context_t *ctx = NULL; isc_result_t ret; unsigned char badtimedata[BADTIMELEN]; unsigned int sigsize = 0; bool response; REQUIRE(msg != NULL); key = dns_message_gettsigkey(msg); REQUIRE(VALID_TSIG_KEY(key)); /* * If this is a response, there should be a TSIG in the query with the * the exception if this is a TKEY request (see RFC 3645, Section 2.2). */ response = is_response(msg); if (response && msg->querytsig == NULL) { if (msg->tkey != 1) { return (DNS_R_EXPECTEDTSIG); } } mctx = msg->mctx; tsig.mctx = mctx; tsig.common.rdclass = dns_rdataclass_any; tsig.common.rdtype = dns_rdatatype_tsig; ISC_LINK_INIT(&tsig.common, link); dns_name_init(&tsig.algorithm, NULL); dns_name_clone(key->algorithm, &tsig.algorithm); if (msg->fuzzing) { now = msg->fuzztime; } else { isc_stdtime_get(&now); } tsig.timesigned = now + msg->timeadjust; tsig.fudge = DNS_TSIG_FUDGE; tsig.originalid = msg->id; isc_buffer_init(&databuf, data, sizeof(data)); if (response) { tsig.error = msg->querytsigstatus; } else { tsig.error = dns_rcode_noerror; } if (tsig.error != dns_tsigerror_badtime) { tsig.otherlen = 0; tsig.other = NULL; } else { isc_buffer_t otherbuf; tsig.otherlen = BADTIMELEN; tsig.other = badtimedata; isc_buffer_init(&otherbuf, tsig.other, tsig.otherlen); isc_buffer_putuint48(&otherbuf, tsig.timesigned); } if ((key->key != NULL) && (tsig.error != dns_tsigerror_badsig) && (tsig.error != dns_tsigerror_badkey)) { unsigned char header[DNS_MESSAGE_HEADERLEN]; isc_buffer_t headerbuf; uint16_t digestbits; bool querytsig_ok = false; /* * If it is a response, we assume that the request MAC * has validated at this point. This is why we include a * MAC length > 0 in the reply. */ ret = dst_context_create(key->key, mctx, DNS_LOGCATEGORY_DNSSEC, true, 0, &ctx); if (ret != ISC_R_SUCCESS) { return (ret); } /* * If this is a response, and if there was a TSIG in * the query, digest the request's MAC. * * (Note: querytsig should be non-NULL for all * responses except TKEY responses. Those may be signed * with the newly-negotiated TSIG key even if the query * wasn't signed.) */ if (response && msg->querytsig != NULL) { dns_rdata_t querytsigrdata = DNS_RDATA_INIT; INSIST(msg->verified_sig); ret = dns_rdataset_first(msg->querytsig); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } dns_rdataset_current(msg->querytsig, &querytsigrdata); ret = dns_rdata_tostruct(&querytsigrdata, &querytsig, NULL); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } isc_buffer_putuint16(&databuf, querytsig.siglen); if (isc_buffer_availablelength(&databuf) < querytsig.siglen) { ret = ISC_R_NOSPACE; goto cleanup_context; } isc_buffer_putmem(&databuf, querytsig.signature, querytsig.siglen); isc_buffer_usedregion(&databuf, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } querytsig_ok = true; } /* * Digest the header. */ isc_buffer_init(&headerbuf, header, sizeof(header)); dns_message_renderheader(msg, &headerbuf); isc_buffer_usedregion(&headerbuf, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } /* * Digest the remainder of the message. */ isc_buffer_usedregion(msg->buffer, &r); isc_region_consume(&r, DNS_MESSAGE_HEADERLEN); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } if (msg->tcp_continuation == 0) { /* * Digest the name, class, ttl, alg. */ dns_name_toregion(&key->name, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } isc_buffer_clear(&databuf); isc_buffer_putuint16(&databuf, dns_rdataclass_any); isc_buffer_putuint32(&databuf, 0); /* ttl */ isc_buffer_usedregion(&databuf, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } dns_name_toregion(&tsig.algorithm, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } } /* Digest the timesigned and fudge */ isc_buffer_clear(&databuf); if (tsig.error == dns_tsigerror_badtime && querytsig_ok) { tsig.timesigned = querytsig.timesigned; } isc_buffer_putuint48(&databuf, tsig.timesigned); isc_buffer_putuint16(&databuf, tsig.fudge); isc_buffer_usedregion(&databuf, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } if (msg->tcp_continuation == 0) { /* * Digest the error and other data length. */ isc_buffer_clear(&databuf); isc_buffer_putuint16(&databuf, tsig.error); isc_buffer_putuint16(&databuf, tsig.otherlen); isc_buffer_usedregion(&databuf, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } /* * Digest other data. */ if (tsig.otherlen > 0) { r.length = tsig.otherlen; r.base = tsig.other; ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } } } ret = dst_key_sigsize(key->key, &sigsize); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } tsig.signature = isc_mem_get(mctx, sigsize); isc_buffer_init(&sigbuf, tsig.signature, sigsize); ret = dst_context_sign(ctx, &sigbuf); if (ret != ISC_R_SUCCESS) { goto cleanup_signature; } dst_context_destroy(&ctx); digestbits = dst_key_getbits(key->key); if (digestbits != 0) { unsigned int bytes = (digestbits + 7) / 8; if (querytsig_ok && bytes < querytsig.siglen) { bytes = querytsig.siglen; } if (bytes > isc_buffer_usedlength(&sigbuf)) { bytes = isc_buffer_usedlength(&sigbuf); } tsig.siglen = bytes; } else { tsig.siglen = isc_buffer_usedlength(&sigbuf); } } else { tsig.siglen = 0; tsig.signature = NULL; } ret = dns_message_gettemprdata(msg, &rdata); if (ret != ISC_R_SUCCESS) { goto cleanup_signature; } isc_buffer_allocate(msg->mctx, &dynbuf, 512); ret = dns_rdata_fromstruct(rdata, dns_rdataclass_any, dns_rdatatype_tsig, &tsig, dynbuf); if (ret != ISC_R_SUCCESS) { goto cleanup_dynbuf; } dns_message_takebuffer(msg, &dynbuf); if (tsig.signature != NULL) { isc_mem_put(mctx, tsig.signature, sigsize); tsig.signature = NULL; } ret = dns_message_gettempname(msg, &owner); if (ret != ISC_R_SUCCESS) { goto cleanup_rdata; } dns_name_copy(&key->name, owner); ret = dns_message_gettemprdatalist(msg, &datalist); if (ret != ISC_R_SUCCESS) { goto cleanup_owner; } ret = dns_message_gettemprdataset(msg, &dataset); if (ret != ISC_R_SUCCESS) { goto cleanup_rdatalist; } datalist->rdclass = dns_rdataclass_any; datalist->type = dns_rdatatype_tsig; ISC_LIST_APPEND(datalist->rdata, rdata, link); RUNTIME_CHECK(dns_rdatalist_tordataset(datalist, dataset) == ISC_R_SUCCESS); msg->tsig = dataset; msg->tsigname = owner; /* Windows does not like the tsig name being compressed. */ msg->tsigname->attributes |= DNS_NAMEATTR_NOCOMPRESS; return (ISC_R_SUCCESS); cleanup_rdatalist: dns_message_puttemprdatalist(msg, &datalist); cleanup_owner: dns_message_puttempname(msg, &owner); goto cleanup_rdata; cleanup_dynbuf: isc_buffer_free(&dynbuf); cleanup_rdata: dns_message_puttemprdata(msg, &rdata); cleanup_signature: if (tsig.signature != NULL) { isc_mem_put(mctx, tsig.signature, sigsize); } cleanup_context: if (ctx != NULL) { dst_context_destroy(&ctx); } return (ret); } isc_result_t dns_tsig_verify(isc_buffer_t *source, dns_message_t *msg, dns_tsig_keyring_t *ring1, dns_tsig_keyring_t *ring2) { dns_rdata_any_tsig_t tsig, querytsig; isc_region_t r, source_r, header_r, sig_r; isc_buffer_t databuf; unsigned char data[32]; dns_name_t *keyname; dns_rdata_t rdata = DNS_RDATA_INIT; isc_stdtime_t now; isc_result_t ret; dns_tsigkey_t *tsigkey; dst_key_t *key = NULL; unsigned char header[DNS_MESSAGE_HEADERLEN]; dst_context_t *ctx = NULL; isc_mem_t *mctx; uint16_t addcount, id; unsigned int siglen; unsigned int alg; bool response; REQUIRE(source != NULL); REQUIRE(DNS_MESSAGE_VALID(msg)); tsigkey = dns_message_gettsigkey(msg); response = is_response(msg); REQUIRE(tsigkey == NULL || VALID_TSIG_KEY(tsigkey)); msg->verify_attempted = 1; msg->verified_sig = 0; msg->tsigstatus = dns_tsigerror_badsig; if (msg->tcp_continuation) { if (tsigkey == NULL || msg->querytsig == NULL) { return (DNS_R_UNEXPECTEDTSIG); } return (tsig_verify_tcp(source, msg)); } /* * There should be a TSIG record... */ if (msg->tsig == NULL) { return (DNS_R_EXPECTEDTSIG); } /* * If this is a response and there's no key or query TSIG, there * shouldn't be one on the response. */ if (response && (tsigkey == NULL || msg->querytsig == NULL)) { return (DNS_R_UNEXPECTEDTSIG); } mctx = msg->mctx; /* * If we're here, we know the message is well formed and contains a * TSIG record. */ keyname = msg->tsigname; ret = dns_rdataset_first(msg->tsig); if (ret != ISC_R_SUCCESS) { return (ret); } dns_rdataset_current(msg->tsig, &rdata); ret = dns_rdata_tostruct(&rdata, &tsig, NULL); if (ret != ISC_R_SUCCESS) { return (ret); } dns_rdata_reset(&rdata); if (response) { ret = dns_rdataset_first(msg->querytsig); if (ret != ISC_R_SUCCESS) { return (ret); } dns_rdataset_current(msg->querytsig, &rdata); ret = dns_rdata_tostruct(&rdata, &querytsig, NULL); if (ret != ISC_R_SUCCESS) { return (ret); } } /* * Do the key name and algorithm match that of the query? */ if (response && (!dns_name_equal(keyname, &tsigkey->name) || !dns_name_equal(&tsig.algorithm, &querytsig.algorithm))) { msg->tsigstatus = dns_tsigerror_badkey; tsig_log(msg->tsigkey, 2, "key name and algorithm do not match"); return (DNS_R_TSIGVERIFYFAILURE); } /* * Get the current time. */ if (msg->fuzzing) { now = msg->fuzztime; } else { isc_stdtime_get(&now); } /* * Find dns_tsigkey_t based on keyname. */ if (tsigkey == NULL) { ret = ISC_R_NOTFOUND; if (ring1 != NULL) { ret = dns_tsigkey_find(&tsigkey, keyname, &tsig.algorithm, ring1); } if (ret == ISC_R_NOTFOUND && ring2 != NULL) { ret = dns_tsigkey_find(&tsigkey, keyname, &tsig.algorithm, ring2); } if (ret != ISC_R_SUCCESS) { msg->tsigstatus = dns_tsigerror_badkey; ret = dns_tsigkey_create(keyname, &tsig.algorithm, NULL, 0, false, NULL, now, now, mctx, NULL, &msg->tsigkey); if (ret != ISC_R_SUCCESS) { return (ret); } tsig_log(msg->tsigkey, 2, "unknown key"); return (DNS_R_TSIGVERIFYFAILURE); } msg->tsigkey = tsigkey; } key = tsigkey->key; /* * Check digest length. */ alg = dst_key_alg(key); ret = dst_key_sigsize(key, &siglen); if (ret != ISC_R_SUCCESS) { return (ret); } if (dns__tsig_algvalid(alg)) { if (tsig.siglen > siglen) { tsig_log(msg->tsigkey, 2, "signature length too big"); return (DNS_R_FORMERR); } if (tsig.siglen > 0 && (tsig.siglen < 10 || tsig.siglen < ((siglen + 1) / 2))) { tsig_log(msg->tsigkey, 2, "signature length below minimum"); return (DNS_R_FORMERR); } } if (tsig.siglen > 0) { uint16_t addcount_n; sig_r.base = tsig.signature; sig_r.length = tsig.siglen; ret = dst_context_create(key, mctx, DNS_LOGCATEGORY_DNSSEC, false, 0, &ctx); if (ret != ISC_R_SUCCESS) { return (ret); } if (response) { isc_buffer_init(&databuf, data, sizeof(data)); isc_buffer_putuint16(&databuf, querytsig.siglen); isc_buffer_usedregion(&databuf, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } if (querytsig.siglen > 0) { r.length = querytsig.siglen; r.base = querytsig.signature; ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } } } /* * Extract the header. */ isc_buffer_usedregion(source, &r); memmove(header, r.base, DNS_MESSAGE_HEADERLEN); isc_region_consume(&r, DNS_MESSAGE_HEADERLEN); /* * Decrement the additional field counter. */ memmove(&addcount, &header[DNS_MESSAGE_HEADERLEN - 2], 2); addcount_n = ntohs(addcount); addcount = htons((uint16_t)(addcount_n - 1)); memmove(&header[DNS_MESSAGE_HEADERLEN - 2], &addcount, 2); /* * Put in the original id. */ id = htons(tsig.originalid); memmove(&header[0], &id, 2); /* * Digest the modified header. */ header_r.base = (unsigned char *)header; header_r.length = DNS_MESSAGE_HEADERLEN; ret = dst_context_adddata(ctx, &header_r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } /* * Digest all non-TSIG records. */ isc_buffer_usedregion(source, &source_r); r.base = source_r.base + DNS_MESSAGE_HEADERLEN; r.length = msg->sigstart - DNS_MESSAGE_HEADERLEN; ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } /* * Digest the key name. */ dns_name_toregion(&tsigkey->name, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } isc_buffer_init(&databuf, data, sizeof(data)); isc_buffer_putuint16(&databuf, tsig.common.rdclass); isc_buffer_putuint32(&databuf, msg->tsig->ttl); isc_buffer_usedregion(&databuf, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } /* * Digest the key algorithm. */ dns_name_toregion(tsigkey->algorithm, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } isc_buffer_clear(&databuf); isc_buffer_putuint48(&databuf, tsig.timesigned); isc_buffer_putuint16(&databuf, tsig.fudge); isc_buffer_putuint16(&databuf, tsig.error); isc_buffer_putuint16(&databuf, tsig.otherlen); isc_buffer_usedregion(&databuf, &r); ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } if (tsig.otherlen > 0) { r.base = tsig.other; r.length = tsig.otherlen; ret = dst_context_adddata(ctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } } ret = dst_context_verify(ctx, &sig_r); if (ret == DST_R_VERIFYFAILURE) { ret = DNS_R_TSIGVERIFYFAILURE; tsig_log(msg->tsigkey, 2, "signature failed to verify(1)"); goto cleanup_context; } else if (ret != ISC_R_SUCCESS) { goto cleanup_context; } msg->verified_sig = 1; } else if (!response || (tsig.error != dns_tsigerror_badsig && tsig.error != dns_tsigerror_badkey)) { tsig_log(msg->tsigkey, 2, "signature was empty"); return (DNS_R_TSIGVERIFYFAILURE); } /* * Here at this point, the MAC has been verified. Even if any of * the following code returns a TSIG error, the reply will be * signed and WILL always include the request MAC in the digest * computation. */ /* * Is the time ok? */ if (now + msg->timeadjust > tsig.timesigned + tsig.fudge) { msg->tsigstatus = dns_tsigerror_badtime; tsig_log(msg->tsigkey, 2, "signature has expired"); ret = DNS_R_CLOCKSKEW; goto cleanup_context; } else if (now + msg->timeadjust < tsig.timesigned - tsig.fudge) { msg->tsigstatus = dns_tsigerror_badtime; tsig_log(msg->tsigkey, 2, "signature is in the future"); ret = DNS_R_CLOCKSKEW; goto cleanup_context; } if (dns__tsig_algvalid(alg)) { uint16_t digestbits = dst_key_getbits(key); if (tsig.siglen > 0 && digestbits != 0 && tsig.siglen < ((digestbits + 7) / 8)) { msg->tsigstatus = dns_tsigerror_badtrunc; tsig_log(msg->tsigkey, 2, "truncated signature length too small"); ret = DNS_R_TSIGVERIFYFAILURE; goto cleanup_context; } if (tsig.siglen > 0 && digestbits == 0 && tsig.siglen < siglen) { msg->tsigstatus = dns_tsigerror_badtrunc; tsig_log(msg->tsigkey, 2, "signature length too small"); ret = DNS_R_TSIGVERIFYFAILURE; goto cleanup_context; } } if (response && tsig.error != dns_rcode_noerror) { msg->tsigstatus = tsig.error; if (tsig.error == dns_tsigerror_badtime) { ret = DNS_R_CLOCKSKEW; } else { ret = DNS_R_TSIGERRORSET; } goto cleanup_context; } msg->tsigstatus = dns_rcode_noerror; ret = ISC_R_SUCCESS; cleanup_context: if (ctx != NULL) { dst_context_destroy(&ctx); } return (ret); } static isc_result_t tsig_verify_tcp(isc_buffer_t *source, dns_message_t *msg) { dns_rdata_any_tsig_t tsig, querytsig; isc_region_t r, source_r, header_r, sig_r; isc_buffer_t databuf; unsigned char data[32]; dns_name_t *keyname; dns_rdata_t rdata = DNS_RDATA_INIT; isc_stdtime_t now; isc_result_t ret; dns_tsigkey_t *tsigkey; dst_key_t *key = NULL; unsigned char header[DNS_MESSAGE_HEADERLEN]; uint16_t addcount, id; bool has_tsig = false; isc_mem_t *mctx; unsigned int siglen; unsigned int alg; REQUIRE(source != NULL); REQUIRE(msg != NULL); REQUIRE(dns_message_gettsigkey(msg) != NULL); REQUIRE(msg->tcp_continuation == 1); REQUIRE(msg->querytsig != NULL); msg->verified_sig = 0; msg->tsigstatus = dns_tsigerror_badsig; if (!is_response(msg)) { return (DNS_R_EXPECTEDRESPONSE); } mctx = msg->mctx; tsigkey = dns_message_gettsigkey(msg); key = tsigkey->key; /* * Extract and parse the previous TSIG */ ret = dns_rdataset_first(msg->querytsig); if (ret != ISC_R_SUCCESS) { return (ret); } dns_rdataset_current(msg->querytsig, &rdata); ret = dns_rdata_tostruct(&rdata, &querytsig, NULL); if (ret != ISC_R_SUCCESS) { return (ret); } dns_rdata_reset(&rdata); /* * If there is a TSIG in this message, do some checks. */ if (msg->tsig != NULL) { has_tsig = true; keyname = msg->tsigname; ret = dns_rdataset_first(msg->tsig); if (ret != ISC_R_SUCCESS) { goto cleanup_querystruct; } dns_rdataset_current(msg->tsig, &rdata); ret = dns_rdata_tostruct(&rdata, &tsig, NULL); if (ret != ISC_R_SUCCESS) { goto cleanup_querystruct; } /* * Do the key name and algorithm match that of the query? */ if (!dns_name_equal(keyname, &tsigkey->name) || !dns_name_equal(&tsig.algorithm, &querytsig.algorithm)) { msg->tsigstatus = dns_tsigerror_badkey; ret = DNS_R_TSIGVERIFYFAILURE; tsig_log(msg->tsigkey, 2, "key name and algorithm do not match"); goto cleanup_querystruct; } /* * Check digest length. */ alg = dst_key_alg(key); ret = dst_key_sigsize(key, &siglen); if (ret != ISC_R_SUCCESS) { goto cleanup_querystruct; } if (dns__tsig_algvalid(alg)) { if (tsig.siglen > siglen) { tsig_log(tsigkey, 2, "signature length too big"); ret = DNS_R_FORMERR; goto cleanup_querystruct; } if (tsig.siglen > 0 && (tsig.siglen < 10 || tsig.siglen < ((siglen + 1) / 2))) { tsig_log(tsigkey, 2, "signature length below minimum"); ret = DNS_R_FORMERR; goto cleanup_querystruct; } } } if (msg->tsigctx == NULL) { ret = dst_context_create(key, mctx, DNS_LOGCATEGORY_DNSSEC, false, 0, &msg->tsigctx); if (ret != ISC_R_SUCCESS) { goto cleanup_querystruct; } /* * Digest the length of the query signature */ isc_buffer_init(&databuf, data, sizeof(data)); isc_buffer_putuint16(&databuf, querytsig.siglen); isc_buffer_usedregion(&databuf, &r); ret = dst_context_adddata(msg->tsigctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } /* * Digest the data of the query signature */ if (querytsig.siglen > 0) { r.length = querytsig.siglen; r.base = querytsig.signature; ret = dst_context_adddata(msg->tsigctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } } } /* * Extract the header. */ isc_buffer_usedregion(source, &r); memmove(header, r.base, DNS_MESSAGE_HEADERLEN); isc_region_consume(&r, DNS_MESSAGE_HEADERLEN); /* * Decrement the additional field counter if necessary. */ if (has_tsig) { uint16_t addcount_n; memmove(&addcount, &header[DNS_MESSAGE_HEADERLEN - 2], 2); addcount_n = ntohs(addcount); addcount = htons((uint16_t)(addcount_n - 1)); memmove(&header[DNS_MESSAGE_HEADERLEN - 2], &addcount, 2); /* * Put in the original id. * * XXX Can TCP transfers be forwarded? How would that * work? */ id = htons(tsig.originalid); memmove(&header[0], &id, 2); } /* * Digest the modified header. */ header_r.base = (unsigned char *)header; header_r.length = DNS_MESSAGE_HEADERLEN; ret = dst_context_adddata(msg->tsigctx, &header_r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } /* * Digest all non-TSIG records. */ isc_buffer_usedregion(source, &source_r); r.base = source_r.base + DNS_MESSAGE_HEADERLEN; if (has_tsig) { r.length = msg->sigstart - DNS_MESSAGE_HEADERLEN; } else { r.length = source_r.length - DNS_MESSAGE_HEADERLEN; } ret = dst_context_adddata(msg->tsigctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } /* * Digest the time signed and fudge. */ if (has_tsig) { isc_buffer_init(&databuf, data, sizeof(data)); isc_buffer_putuint48(&databuf, tsig.timesigned); isc_buffer_putuint16(&databuf, tsig.fudge); isc_buffer_usedregion(&databuf, &r); ret = dst_context_adddata(msg->tsigctx, &r); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } sig_r.base = tsig.signature; sig_r.length = tsig.siglen; if (tsig.siglen == 0) { if (tsig.error != dns_rcode_noerror) { msg->tsigstatus = tsig.error; if (tsig.error == dns_tsigerror_badtime) { ret = DNS_R_CLOCKSKEW; } else { ret = DNS_R_TSIGERRORSET; } } else { tsig_log(msg->tsigkey, 2, "signature is empty"); ret = DNS_R_TSIGVERIFYFAILURE; } goto cleanup_context; } ret = dst_context_verify(msg->tsigctx, &sig_r); if (ret == DST_R_VERIFYFAILURE) { tsig_log(msg->tsigkey, 2, "signature failed to verify(2)"); ret = DNS_R_TSIGVERIFYFAILURE; goto cleanup_context; } else if (ret != ISC_R_SUCCESS) { goto cleanup_context; } msg->verified_sig = 1; /* * Here at this point, the MAC has been verified. Even * if any of the following code returns a TSIG error, * the reply will be signed and WILL always include the * request MAC in the digest computation. */ /* * Is the time ok? */ if (msg->fuzzing) { now = msg->fuzztime; } else { isc_stdtime_get(&now); } if (now + msg->timeadjust > tsig.timesigned + tsig.fudge) { msg->tsigstatus = dns_tsigerror_badtime; tsig_log(msg->tsigkey, 2, "signature has expired"); ret = DNS_R_CLOCKSKEW; goto cleanup_context; } else if (now + msg->timeadjust < tsig.timesigned - tsig.fudge) { msg->tsigstatus = dns_tsigerror_badtime; tsig_log(msg->tsigkey, 2, "signature is in the future"); ret = DNS_R_CLOCKSKEW; goto cleanup_context; } alg = dst_key_alg(key); ret = dst_key_sigsize(key, &siglen); if (ret != ISC_R_SUCCESS) { goto cleanup_context; } if (dns__tsig_algvalid(alg)) { uint16_t digestbits = dst_key_getbits(key); if (tsig.siglen > 0 && digestbits != 0 && tsig.siglen < ((digestbits + 7) / 8)) { msg->tsigstatus = dns_tsigerror_badtrunc; tsig_log(msg->tsigkey, 2, "truncated signature length " "too small"); ret = DNS_R_TSIGVERIFYFAILURE; goto cleanup_context; } if (tsig.siglen > 0 && digestbits == 0 && tsig.siglen < siglen) { msg->tsigstatus = dns_tsigerror_badtrunc; tsig_log(msg->tsigkey, 2, "signature length too small"); ret = DNS_R_TSIGVERIFYFAILURE; goto cleanup_context; } } if (tsig.error != dns_rcode_noerror) { msg->tsigstatus = tsig.error; if (tsig.error == dns_tsigerror_badtime) { ret = DNS_R_CLOCKSKEW; } else { ret = DNS_R_TSIGERRORSET; } goto cleanup_context; } } msg->tsigstatus = dns_rcode_noerror; ret = ISC_R_SUCCESS; cleanup_context: /* * Except in error conditions, don't destroy the DST context * for unsigned messages; it is a running sum till the next * TSIG signed message. */ if ((ret != ISC_R_SUCCESS || has_tsig) && msg->tsigctx != NULL) { dst_context_destroy(&msg->tsigctx); } cleanup_querystruct: dns_rdata_freestruct(&querytsig); return (ret); } isc_result_t dns_tsigkey_find(dns_tsigkey_t **tsigkey, const dns_name_t *name, const dns_name_t *algorithm, dns_tsig_keyring_t *ring) { dns_tsigkey_t *key; isc_stdtime_t now; isc_result_t result; REQUIRE(tsigkey != NULL); REQUIRE(*tsigkey == NULL); REQUIRE(name != NULL); REQUIRE(ring != NULL); RWLOCK(&ring->lock, isc_rwlocktype_write); cleanup_ring(ring); RWUNLOCK(&ring->lock, isc_rwlocktype_write); isc_stdtime_get(&now); RWLOCK(&ring->lock, isc_rwlocktype_read); key = NULL; result = dns_rbt_findname(ring->keys, name, 0, NULL, (void *)&key); if (result == DNS_R_PARTIALMATCH || result == ISC_R_NOTFOUND) { RWUNLOCK(&ring->lock, isc_rwlocktype_read); return (ISC_R_NOTFOUND); } if (algorithm != NULL && !dns_name_equal(key->algorithm, algorithm)) { RWUNLOCK(&ring->lock, isc_rwlocktype_read); return (ISC_R_NOTFOUND); } if (key->inception != key->expire && isc_serial_lt(key->expire, now)) { /* * The key has expired. */ RWUNLOCK(&ring->lock, isc_rwlocktype_read); RWLOCK(&ring->lock, isc_rwlocktype_write); remove_fromring(key); RWUNLOCK(&ring->lock, isc_rwlocktype_write); return (ISC_R_NOTFOUND); } #if 0 /* * MPAXXX We really should look at the inception time. */ if (key->inception != key->expire && isc_serial_lt(key->inception, now)) { RWUNLOCK(&ring->lock, isc_rwlocktype_read); adjust_lru(key); return (ISC_R_NOTFOUND); } #endif /* if 0 */ isc_refcount_increment(&key->refs); RWUNLOCK(&ring->lock, isc_rwlocktype_read); adjust_lru(key); *tsigkey = key; return (ISC_R_SUCCESS); } static void free_tsignode(void *node, void *_unused) { dns_tsigkey_t *key; REQUIRE(node != NULL); UNUSED(_unused); key = node; if (key->generated) { if (ISC_LINK_LINKED(key, link)) { ISC_LIST_UNLINK(key->ring->lru, key, link); } } dns_tsigkey_detach(&key); } isc_result_t dns_tsigkeyring_create(isc_mem_t *mctx, dns_tsig_keyring_t **ringp) { isc_result_t result; dns_tsig_keyring_t *ring; REQUIRE(mctx != NULL); REQUIRE(ringp != NULL); REQUIRE(*ringp == NULL); ring = isc_mem_get(mctx, sizeof(dns_tsig_keyring_t)); isc_rwlock_init(&ring->lock, 0, 0); ring->keys = NULL; result = dns_rbt_create(mctx, free_tsignode, NULL, &ring->keys); if (result != ISC_R_SUCCESS) { isc_rwlock_destroy(&ring->lock); isc_mem_put(mctx, ring, sizeof(dns_tsig_keyring_t)); return (result); } ring->writecount = 0; ring->mctx = NULL; ring->generated = 0; ring->maxgenerated = DNS_TSIG_MAXGENERATEDKEYS; ISC_LIST_INIT(ring->lru); isc_mem_attach(mctx, &ring->mctx); isc_refcount_init(&ring->references, 1); *ringp = ring; return (ISC_R_SUCCESS); } isc_result_t dns_tsigkeyring_add(dns_tsig_keyring_t *ring, const dns_name_t *name, dns_tsigkey_t *tkey) { isc_result_t result; REQUIRE(VALID_TSIG_KEY(tkey)); REQUIRE(tkey->ring == NULL); REQUIRE(name != NULL); result = keyring_add(ring, name, tkey); if (result == ISC_R_SUCCESS) { isc_refcount_increment(&tkey->refs); } return (result); } void dns_tsigkeyring_attach(dns_tsig_keyring_t *source, dns_tsig_keyring_t **target) { REQUIRE(source != NULL); REQUIRE(target != NULL && *target == NULL); isc_refcount_increment(&source->references); *target = source; } void dns_tsigkeyring_detach(dns_tsig_keyring_t **ringp) { dns_tsig_keyring_t *ring; REQUIRE(ringp != NULL); REQUIRE(*ringp != NULL); ring = *ringp; *ringp = NULL; if (isc_refcount_decrement(&ring->references) == 1) { destroyring(ring); } } void dns_keyring_restore(dns_tsig_keyring_t *ring, FILE *fp) { isc_stdtime_t now; isc_result_t result; isc_stdtime_get(&now); do { result = restore_key(ring, now, fp); if (result == ISC_R_NOMORE) { return; } if (result == DNS_R_BADALG || result == DNS_R_EXPIRED) { result = ISC_R_SUCCESS; } } while (result == ISC_R_SUCCESS); }