/* SPDX-License-Identifier: LGPL-2.1-or-later */ #include #include "af-list.h" #include "alloc-util.h" #include "dns-domain.h" #include "format-util.h" #include "resolved-dns-answer.h" #include "resolved-dns-cache.h" #include "resolved-dns-packet.h" #include "string-util.h" /* Never cache more than 4K entries. RFC 1536, Section 5 suggests to * leave DNS caches unbounded, but that's crazy. */ #define CACHE_MAX 4096 /* We never keep any item longer than 2h in our cache */ #define CACHE_TTL_MAX_USEC (2 * USEC_PER_HOUR) /* How long to cache strange rcodes, i.e. rcodes != SUCCESS and != NXDOMAIN (specifically: that's only SERVFAIL for * now) */ #define CACHE_TTL_STRANGE_RCODE_USEC (10 * USEC_PER_SEC) #define CACHEABLE_QUERY_FLAGS (SD_RESOLVED_AUTHENTICATED|SD_RESOLVED_CONFIDENTIAL) typedef enum DnsCacheItemType DnsCacheItemType; typedef struct DnsCacheItem DnsCacheItem; enum DnsCacheItemType { DNS_CACHE_POSITIVE, DNS_CACHE_NODATA, DNS_CACHE_NXDOMAIN, DNS_CACHE_RCODE, /* "strange" RCODE (effective only SERVFAIL for now) */ }; struct DnsCacheItem { DnsCacheItemType type; DnsResourceKey *key; /* The key for this item, i.e. the lookup key */ DnsResourceRecord *rr; /* The RR for this item, i.e. the lookup value for positive queries */ DnsAnswer *answer; /* The full validated answer, if this is an RRset acquired via a "primary" lookup */ DnsPacket *full_packet; /* The full packet this information was acquired with */ int rcode; usec_t until; bool shared_owner:1; uint64_t query_flags; /* SD_RESOLVED_AUTHENTICATED and/or SD_RESOLVED_CONFIDENTIAL */ DnssecResult dnssec_result; int ifindex; int owner_family; union in_addr_union owner_address; unsigned prioq_idx; LIST_FIELDS(DnsCacheItem, by_key); }; /* Returns true if this is a cache item created as result of an explicit lookup, or created as "side-effect" * of another request. "Primary" entries will carry the full answer data (with NSEC, …) that can aso prove * wildcard expansion, non-existance and such, while entries that were created as "side-effect" just contain * immediate RR data for the specified RR key, but nothing else. */ #define DNS_CACHE_ITEM_IS_PRIMARY(item) (!!(item)->answer) static const char *dns_cache_item_type_to_string(DnsCacheItem *item) { assert(item); switch (item->type) { case DNS_CACHE_POSITIVE: return "POSITIVE"; case DNS_CACHE_NODATA: return "NODATA"; case DNS_CACHE_NXDOMAIN: return "NXDOMAIN"; case DNS_CACHE_RCODE: return dns_rcode_to_string(item->rcode); } return NULL; } static DnsCacheItem* dns_cache_item_free(DnsCacheItem *i) { if (!i) return NULL; dns_resource_record_unref(i->rr); dns_resource_key_unref(i->key); dns_answer_unref(i->answer); dns_packet_unref(i->full_packet); return mfree(i); } DEFINE_TRIVIAL_CLEANUP_FUNC(DnsCacheItem*, dns_cache_item_free); static void dns_cache_item_unlink_and_free(DnsCache *c, DnsCacheItem *i) { DnsCacheItem *first; assert(c); if (!i) return; first = hashmap_get(c->by_key, i->key); LIST_REMOVE(by_key, first, i); if (first) assert_se(hashmap_replace(c->by_key, first->key, first) >= 0); else hashmap_remove(c->by_key, i->key); prioq_remove(c->by_expiry, i, &i->prioq_idx); dns_cache_item_free(i); } static bool dns_cache_remove_by_rr(DnsCache *c, DnsResourceRecord *rr) { DnsCacheItem *first, *i; int r; first = hashmap_get(c->by_key, rr->key); LIST_FOREACH(by_key, i, first) { r = dns_resource_record_equal(i->rr, rr); if (r < 0) return r; if (r > 0) { dns_cache_item_unlink_and_free(c, i); return true; } } return false; } static bool dns_cache_remove_by_key(DnsCache *c, DnsResourceKey *key) { DnsCacheItem *first, *i, *n; assert(c); assert(key); first = hashmap_remove(c->by_key, key); if (!first) return false; LIST_FOREACH_SAFE(by_key, i, n, first) { prioq_remove(c->by_expiry, i, &i->prioq_idx); dns_cache_item_free(i); } return true; } void dns_cache_flush(DnsCache *c) { DnsResourceKey *key; assert(c); while ((key = hashmap_first_key(c->by_key))) dns_cache_remove_by_key(c, key); assert(hashmap_size(c->by_key) == 0); assert(prioq_size(c->by_expiry) == 0); c->by_key = hashmap_free(c->by_key); c->by_expiry = prioq_free(c->by_expiry); } static void dns_cache_make_space(DnsCache *c, unsigned add) { assert(c); if (add <= 0) return; /* Makes space for n new entries. Note that we actually allow * the cache to grow beyond CACHE_MAX, but only when we shall * add more RRs to the cache than CACHE_MAX at once. In that * case the cache will be emptied completely otherwise. */ for (;;) { _cleanup_(dns_resource_key_unrefp) DnsResourceKey *key = NULL; DnsCacheItem *i; if (prioq_size(c->by_expiry) <= 0) break; if (prioq_size(c->by_expiry) + add < CACHE_MAX) break; i = prioq_peek(c->by_expiry); assert(i); /* Take an extra reference to the key so that it * doesn't go away in the middle of the remove call */ key = dns_resource_key_ref(i->key); dns_cache_remove_by_key(c, key); } } void dns_cache_prune(DnsCache *c) { usec_t t = 0; assert(c); /* Remove all entries that are past their TTL */ for (;;) { DnsCacheItem *i; char key_str[DNS_RESOURCE_KEY_STRING_MAX]; i = prioq_peek(c->by_expiry); if (!i) break; if (t <= 0) t = now(clock_boottime_or_monotonic()); if (i->until > t) break; /* Depending whether this is an mDNS shared entry * either remove only this one RR or the whole RRset */ log_debug("Removing %scache entry for %s (expired "USEC_FMT"s ago)", i->shared_owner ? "shared " : "", dns_resource_key_to_string(i->key, key_str, sizeof key_str), (t - i->until) / USEC_PER_SEC); if (i->shared_owner) dns_cache_item_unlink_and_free(c, i); else { _cleanup_(dns_resource_key_unrefp) DnsResourceKey *key = NULL; /* Take an extra reference to the key so that it * doesn't go away in the middle of the remove call */ key = dns_resource_key_ref(i->key); dns_cache_remove_by_key(c, key); } } } static int dns_cache_item_prioq_compare_func(const void *a, const void *b) { const DnsCacheItem *x = a, *y = b; return CMP(x->until, y->until); } static int dns_cache_init(DnsCache *c) { int r; assert(c); r = prioq_ensure_allocated(&c->by_expiry, dns_cache_item_prioq_compare_func); if (r < 0) return r; r = hashmap_ensure_allocated(&c->by_key, &dns_resource_key_hash_ops); if (r < 0) return r; return r; } static int dns_cache_link_item(DnsCache *c, DnsCacheItem *i) { DnsCacheItem *first; int r; assert(c); assert(i); r = prioq_put(c->by_expiry, i, &i->prioq_idx); if (r < 0) return r; first = hashmap_get(c->by_key, i->key); if (first) { _cleanup_(dns_resource_key_unrefp) DnsResourceKey *k = NULL; /* Keep a reference to the original key, while we manipulate the list. */ k = dns_resource_key_ref(first->key); /* Now, try to reduce the number of keys we keep */ dns_resource_key_reduce(&first->key, &i->key); if (first->rr) dns_resource_key_reduce(&first->rr->key, &i->key); if (i->rr) dns_resource_key_reduce(&i->rr->key, &i->key); LIST_PREPEND(by_key, first, i); assert_se(hashmap_replace(c->by_key, first->key, first) >= 0); } else { r = hashmap_put(c->by_key, i->key, i); if (r < 0) { prioq_remove(c->by_expiry, i, &i->prioq_idx); return r; } } return 0; } static DnsCacheItem* dns_cache_get(DnsCache *c, DnsResourceRecord *rr) { DnsCacheItem *i; assert(c); assert(rr); LIST_FOREACH(by_key, i, hashmap_get(c->by_key, rr->key)) if (i->rr && dns_resource_record_equal(i->rr, rr) > 0) return i; return NULL; } static usec_t calculate_until(DnsResourceRecord *rr, uint32_t nsec_ttl, usec_t timestamp, bool use_soa_minimum) { uint32_t ttl; usec_t u; assert(rr); ttl = MIN(rr->ttl, nsec_ttl); if (rr->key->type == DNS_TYPE_SOA && use_soa_minimum) { /* If this is a SOA RR, and it is requested, clamp to * the SOA's minimum field. This is used when we do * negative caching, to determine the TTL for the * negative caching entry. See RFC 2308, Section * 5. */ if (ttl > rr->soa.minimum) ttl = rr->soa.minimum; } u = ttl * USEC_PER_SEC; if (u > CACHE_TTL_MAX_USEC) u = CACHE_TTL_MAX_USEC; if (rr->expiry != USEC_INFINITY) { usec_t left; /* Make use of the DNSSEC RRSIG expiry info, if we * have it */ left = LESS_BY(rr->expiry, now(CLOCK_REALTIME)); if (u > left) u = left; } return timestamp + u; } static void dns_cache_item_update_positive( DnsCache *c, DnsCacheItem *i, DnsResourceRecord *rr, DnsAnswer *answer, DnsPacket *full_packet, uint64_t query_flags, bool shared_owner, DnssecResult dnssec_result, usec_t timestamp, int ifindex, int owner_family, const union in_addr_union *owner_address) { assert(c); assert(i); assert(rr); assert(owner_address); i->type = DNS_CACHE_POSITIVE; if (!i->by_key_prev) /* We are the first item in the list, we need to * update the key used in the hashmap */ assert_se(hashmap_replace(c->by_key, rr->key, i) >= 0); dns_resource_record_ref(rr); dns_resource_record_unref(i->rr); i->rr = rr; dns_resource_key_unref(i->key); i->key = dns_resource_key_ref(rr->key); dns_answer_ref(answer); dns_answer_unref(i->answer); i->answer = answer; dns_packet_ref(full_packet); dns_packet_unref(i->full_packet); i->full_packet = full_packet; i->until = calculate_until(rr, UINT32_MAX, timestamp, false); i->query_flags = query_flags & CACHEABLE_QUERY_FLAGS; i->shared_owner = shared_owner; i->dnssec_result = dnssec_result; i->ifindex = ifindex; i->owner_family = owner_family; i->owner_address = *owner_address; prioq_reshuffle(c->by_expiry, i, &i->prioq_idx); } static int dns_cache_put_positive( DnsCache *c, DnsResourceRecord *rr, DnsAnswer *answer, DnsPacket *full_packet, uint64_t query_flags, bool shared_owner, DnssecResult dnssec_result, usec_t timestamp, int ifindex, int owner_family, const union in_addr_union *owner_address) { _cleanup_(dns_cache_item_freep) DnsCacheItem *i = NULL; DnsCacheItem *existing; char key_str[DNS_RESOURCE_KEY_STRING_MAX]; int r, k; assert(c); assert(rr); assert(owner_address); /* Never cache pseudo RRs */ if (dns_class_is_pseudo(rr->key->class)) return 0; if (dns_type_is_pseudo(rr->key->type)) return 0; /* New TTL is 0? Delete this specific entry... */ if (rr->ttl <= 0) { k = dns_cache_remove_by_rr(c, rr); log_debug("%s: %s", k > 0 ? "Removed zero TTL entry from cache" : "Not caching zero TTL cache entry", dns_resource_key_to_string(rr->key, key_str, sizeof key_str)); return 0; } /* Entry exists already? Update TTL, timestamp and owner */ existing = dns_cache_get(c, rr); if (existing) { dns_cache_item_update_positive( c, existing, rr, answer, full_packet, query_flags, shared_owner, dnssec_result, timestamp, ifindex, owner_family, owner_address); return 0; } /* Otherwise, add the new RR */ r = dns_cache_init(c); if (r < 0) return r; dns_cache_make_space(c, 1); i = new(DnsCacheItem, 1); if (!i) return -ENOMEM; *i = (DnsCacheItem) { .type = DNS_CACHE_POSITIVE, .key = dns_resource_key_ref(rr->key), .rr = dns_resource_record_ref(rr), .answer = dns_answer_ref(answer), .full_packet = dns_packet_ref(full_packet), .until = calculate_until(rr, (uint32_t) -1, timestamp, false), .query_flags = query_flags & CACHEABLE_QUERY_FLAGS, .shared_owner = shared_owner, .dnssec_result = dnssec_result, .ifindex = ifindex, .owner_family = owner_family, .owner_address = *owner_address, .prioq_idx = PRIOQ_IDX_NULL, }; r = dns_cache_link_item(c, i); if (r < 0) return r; if (DEBUG_LOGGING) { _cleanup_free_ char *t = NULL; char ifname[IF_NAMESIZE + 1]; (void) in_addr_to_string(i->owner_family, &i->owner_address, &t); log_debug("Added positive %s %s%s cache entry for %s "USEC_FMT"s on %s/%s/%s", FLAGS_SET(i->query_flags, SD_RESOLVED_AUTHENTICATED) ? "authenticated" : "unauthenticated", FLAGS_SET(i->query_flags, SD_RESOLVED_CONFIDENTIAL) ? "confidential" : "non-confidential", i->shared_owner ? " shared" : "", dns_resource_key_to_string(i->key, key_str, sizeof key_str), (i->until - timestamp) / USEC_PER_SEC, i->ifindex == 0 ? "*" : strna(format_ifname(i->ifindex, ifname)), af_to_name_short(i->owner_family), strna(t)); } i = NULL; return 0; } static int dns_cache_put_negative( DnsCache *c, DnsResourceKey *key, int rcode, DnsAnswer *answer, DnsPacket *full_packet, uint64_t query_flags, DnssecResult dnssec_result, uint32_t nsec_ttl, usec_t timestamp, DnsResourceRecord *soa, int owner_family, const union in_addr_union *owner_address) { _cleanup_(dns_cache_item_freep) DnsCacheItem *i = NULL; char key_str[DNS_RESOURCE_KEY_STRING_MAX]; int r; assert(c); assert(key); assert(owner_address); /* Never cache pseudo RR keys. DNS_TYPE_ANY is particularly * important to filter out as we use this as a pseudo-type for * NXDOMAIN entries */ if (dns_class_is_pseudo(key->class)) return 0; if (dns_type_is_pseudo(key->type)) return 0; if (IN_SET(rcode, DNS_RCODE_SUCCESS, DNS_RCODE_NXDOMAIN)) { if (!soa) return 0; /* For negative replies, check if we have a TTL of a SOA */ if (nsec_ttl <= 0 || soa->soa.minimum <= 0 || soa->ttl <= 0) { log_debug("Not caching negative entry with zero SOA/NSEC/NSEC3 TTL: %s", dns_resource_key_to_string(key, key_str, sizeof key_str)); return 0; } } else if (rcode != DNS_RCODE_SERVFAIL) return 0; r = dns_cache_init(c); if (r < 0) return r; dns_cache_make_space(c, 1); i = new(DnsCacheItem, 1); if (!i) return -ENOMEM; *i = (DnsCacheItem) { .type = rcode == DNS_RCODE_SUCCESS ? DNS_CACHE_NODATA : rcode == DNS_RCODE_NXDOMAIN ? DNS_CACHE_NXDOMAIN : DNS_CACHE_RCODE, .query_flags = query_flags & CACHEABLE_QUERY_FLAGS, .dnssec_result = dnssec_result, .owner_family = owner_family, .owner_address = *owner_address, .prioq_idx = PRIOQ_IDX_NULL, .rcode = rcode, .answer = dns_answer_ref(answer), .full_packet = dns_packet_ref(full_packet), }; i->until = i->type == DNS_CACHE_RCODE ? timestamp + CACHE_TTL_STRANGE_RCODE_USEC : calculate_until(soa, nsec_ttl, timestamp, true); if (i->type == DNS_CACHE_NXDOMAIN) { /* NXDOMAIN entries should apply equally to all types, so we use ANY as * a pseudo type for this purpose here. */ i->key = dns_resource_key_new(key->class, DNS_TYPE_ANY, dns_resource_key_name(key)); if (!i->key) return -ENOMEM; /* Make sure to remove any previous entry for this * specific ANY key. (For non-ANY keys the cache data * is already cleared by the caller.) Note that we * don't bother removing positive or NODATA cache * items in this case, because it would either be slow * or require explicit indexing by name */ dns_cache_remove_by_key(c, key); } else i->key = dns_resource_key_ref(key); r = dns_cache_link_item(c, i); if (r < 0) return r; log_debug("Added %s cache entry for %s "USEC_FMT"s", dns_cache_item_type_to_string(i), dns_resource_key_to_string(i->key, key_str, sizeof key_str), (i->until - timestamp) / USEC_PER_SEC); i = NULL; return 0; } static void dns_cache_remove_previous( DnsCache *c, DnsResourceKey *key, DnsAnswer *answer) { DnsResourceRecord *rr; DnsAnswerFlags flags; assert(c); /* First, if we were passed a key (i.e. on LLMNR/DNS, but * not on mDNS), delete all matching old RRs, so that we only * keep complete by_key in place. */ if (key) dns_cache_remove_by_key(c, key); /* Second, flush all entries matching the answer, unless this * is an RR that is explicitly marked to be "shared" between * peers (i.e. mDNS RRs without the flush-cache bit set). */ DNS_ANSWER_FOREACH_FLAGS(rr, flags, answer) { if ((flags & DNS_ANSWER_CACHEABLE) == 0) continue; if (flags & DNS_ANSWER_SHARED_OWNER) continue; dns_cache_remove_by_key(c, rr->key); } } static bool rr_eligible(DnsResourceRecord *rr) { assert(rr); /* When we see an NSEC/NSEC3 RR, we'll only cache it if it is from the lower zone, not the upper zone, since * that's where the interesting bits are (with exception of DS RRs). Of course, this way we cannot derive DS * existence from any cached NSEC/NSEC3, but that should be fine. */ switch (rr->key->type) { case DNS_TYPE_NSEC: return !bitmap_isset(rr->nsec.types, DNS_TYPE_NS) || bitmap_isset(rr->nsec.types, DNS_TYPE_SOA); case DNS_TYPE_NSEC3: return !bitmap_isset(rr->nsec3.types, DNS_TYPE_NS) || bitmap_isset(rr->nsec3.types, DNS_TYPE_SOA); default: return true; } } int dns_cache_put( DnsCache *c, DnsCacheMode cache_mode, DnsResourceKey *key, int rcode, DnsAnswer *answer, DnsPacket *full_packet, uint64_t query_flags, DnssecResult dnssec_result, uint32_t nsec_ttl, int owner_family, const union in_addr_union *owner_address) { DnsResourceRecord *soa = NULL; bool weird_rcode = false; DnsAnswerItem *item; DnsAnswerFlags flags; unsigned cache_keys; usec_t timestamp; int r; assert(c); assert(owner_address); dns_cache_remove_previous(c, key, answer); /* We only care for positive replies and NXDOMAINs, on all other replies we will simply flush the respective * entries, and that's it. (Well, with one further exception: since some DNS zones (akamai!) return SERVFAIL * consistently for some lookups, and forwarders tend to propagate that we'll cache that too, but only for a * short time.) */ if (IN_SET(rcode, DNS_RCODE_SUCCESS, DNS_RCODE_NXDOMAIN)) { if (dns_answer_size(answer) <= 0) { if (key) { char key_str[DNS_RESOURCE_KEY_STRING_MAX]; log_debug("Not caching negative entry without a SOA record: %s", dns_resource_key_to_string(key, key_str, sizeof key_str)); } return 0; } } else { /* Only cache SERVFAIL as "weird" rcode for now. We can add more later, should that turn out to be * beneficial. */ if (rcode != DNS_RCODE_SERVFAIL) return 0; weird_rcode = true; } cache_keys = dns_answer_size(answer); if (key) cache_keys++; /* Make some space for our new entries */ dns_cache_make_space(c, cache_keys); timestamp = now(clock_boottime_or_monotonic()); /* Second, add in positive entries for all contained RRs */ DNS_ANSWER_FOREACH_ITEM(item, answer) { int primary = false; if (!FLAGS_SET(item->flags, DNS_ANSWER_CACHEABLE) || !rr_eligible(item->rr)) continue; if (key) { /* We store the auxiliary RRs and packet data in the cache only if they were in * direct response to the original query. If we cache an RR we also received, and * that is just auxiliary information we can't use the data, hence don't. */ primary = dns_resource_key_match_rr(key, item->rr, NULL); if (primary < 0) return primary; if (primary == 0) { primary = dns_resource_key_match_cname_or_dname(key, item->rr->key, NULL); if (primary < 0) return primary; } } if (!primary) { DnsCacheItem *first; /* Do not replace existing cache items for primary lookups with non-primary * data. After all the primary lookup data is a lot more useful. */ first = hashmap_get(c->by_key, item->rr->key); if (first && DNS_CACHE_ITEM_IS_PRIMARY(first)) return 0; } r = dns_cache_put_positive( c, item->rr, primary ? answer : NULL, primary ? full_packet : NULL, ((item->flags & DNS_ANSWER_AUTHENTICATED) ? SD_RESOLVED_AUTHENTICATED : 0) | (query_flags & SD_RESOLVED_CONFIDENTIAL), item->flags & DNS_ANSWER_SHARED_OWNER, dnssec_result, timestamp, item->ifindex, owner_family, owner_address); if (r < 0) goto fail; } if (!key) /* mDNS doesn't know negative caching, really */ return 0; /* Third, add in negative entries if the key has no RR */ r = dns_answer_match_key(answer, key, NULL); if (r < 0) goto fail; if (r > 0) return 0; /* But not if it has a matching CNAME/DNAME (the negative * caching will be done on the canonical name, not on the * alias) */ r = dns_answer_find_cname_or_dname(answer, key, NULL, NULL); if (r < 0) goto fail; if (r > 0) return 0; /* See https://tools.ietf.org/html/rfc2308, which say that a matching SOA record in the packet is used to * enable negative caching. We apply one exception though: if we are about to cache a weird rcode we do so * regardless of a SOA. */ r = dns_answer_find_soa(answer, key, &soa, &flags); if (r < 0) goto fail; if (r == 0 && !weird_rcode) return 0; if (r > 0) { /* Refuse using the SOA data if it is unsigned, but the key is * signed */ if (FLAGS_SET(query_flags, SD_RESOLVED_AUTHENTICATED) && (flags & DNS_ANSWER_AUTHENTICATED) == 0) return 0; } if (cache_mode == DNS_CACHE_MODE_NO_NEGATIVE) { char key_str[DNS_RESOURCE_KEY_STRING_MAX]; log_debug("Not caching negative entry for: %s, cache mode set to no-negative", dns_resource_key_to_string(key, key_str, sizeof key_str)); return 0; } r = dns_cache_put_negative( c, key, rcode, answer, full_packet, query_flags, dnssec_result, nsec_ttl, timestamp, soa, owner_family, owner_address); if (r < 0) goto fail; return 0; fail: /* Adding all RRs failed. Let's clean up what we already * added, just in case */ if (key) dns_cache_remove_by_key(c, key); DNS_ANSWER_FOREACH_ITEM(item, answer) { if ((item->flags & DNS_ANSWER_CACHEABLE) == 0) continue; dns_cache_remove_by_key(c, item->rr->key); } return r; } static DnsCacheItem *dns_cache_get_by_key_follow_cname_dname_nsec(DnsCache *c, DnsResourceKey *k) { DnsCacheItem *i; const char *n; int r; assert(c); assert(k); /* If we hit some OOM error, or suchlike, we don't care too * much, after all this is just a cache */ i = hashmap_get(c->by_key, k); if (i) return i; n = dns_resource_key_name(k); /* Check if we have an NXDOMAIN cache item for the name, notice that we use * the pseudo-type ANY for NXDOMAIN cache items. */ i = hashmap_get(c->by_key, &DNS_RESOURCE_KEY_CONST(k->class, DNS_TYPE_ANY, n)); if (i && i->type == DNS_CACHE_NXDOMAIN) return i; if (dns_type_may_redirect(k->type)) { /* Check if we have a CNAME record instead */ i = hashmap_get(c->by_key, &DNS_RESOURCE_KEY_CONST(k->class, DNS_TYPE_CNAME, n)); if (i && i->type != DNS_CACHE_NODATA) return i; /* OK, let's look for cached DNAME records. */ for (;;) { if (isempty(n)) return NULL; i = hashmap_get(c->by_key, &DNS_RESOURCE_KEY_CONST(k->class, DNS_TYPE_DNAME, n)); if (i && i->type != DNS_CACHE_NODATA) return i; /* Jump one label ahead */ r = dns_name_parent(&n); if (r <= 0) return NULL; } } if (k->type != DNS_TYPE_NSEC) { /* Check if we have an NSEC record instead for the name. */ i = hashmap_get(c->by_key, &DNS_RESOURCE_KEY_CONST(k->class, DNS_TYPE_NSEC, n)); if (i) return i; } return NULL; } static int answer_add_clamp_ttl( DnsAnswer **answer, DnsResourceRecord *rr, int ifindex, DnsAnswerFlags answer_flags, DnsResourceRecord *rrsig, uint64_t query_flags, usec_t until, usec_t current) { _cleanup_(dns_resource_record_unrefp) DnsResourceRecord *patched = NULL, *patched_rrsig = NULL; int r; assert(answer); assert(rr); if (FLAGS_SET(query_flags, SD_RESOLVED_CLAMP_TTL)) { patched = dns_resource_record_ref(rr); r = dns_resource_record_clamp_ttl(&patched, LESS_BY(until, current) / USEC_PER_SEC); if (r < 0) return r; rr = patched; if (rrsig) { patched_rrsig = dns_resource_record_ref(rrsig); r = dns_resource_record_clamp_ttl(&patched_rrsig, LESS_BY(until, current) / USEC_PER_SEC); if (r < 0) return r; rrsig = patched_rrsig; } } r = dns_answer_add_extend(answer, rr, ifindex, answer_flags, rrsig); if (r < 0) return r; return 0; } int dns_cache_lookup( DnsCache *c, DnsResourceKey *key, uint64_t query_flags, int *ret_rcode, DnsAnswer **ret_answer, DnsPacket **ret_full_packet, uint64_t *ret_query_flags, DnssecResult *ret_dnssec_result) { _cleanup_(dns_packet_unrefp) DnsPacket *full_packet = NULL; _cleanup_(dns_answer_unrefp) DnsAnswer *answer = NULL; char key_str[DNS_RESOURCE_KEY_STRING_MAX]; unsigned n = 0; int r; bool nxdomain = false; DnsCacheItem *j, *first, *nsec = NULL; bool have_authenticated = false, have_non_authenticated = false, have_confidential = false, have_non_confidential = false; usec_t current; int found_rcode = -1; DnssecResult dnssec_result = -1; int have_dnssec_result = -1; assert(c); assert(key); if (key->type == DNS_TYPE_ANY || key->class == DNS_CLASS_ANY) { /* If we have ANY lookups we don't use the cache, so that the caller refreshes via the * network. */ log_debug("Ignoring cache for ANY lookup: %s", dns_resource_key_to_string(key, key_str, sizeof key_str)); goto miss; } first = dns_cache_get_by_key_follow_cname_dname_nsec(c, key); if (!first) { /* If one question cannot be answered we need to refresh */ log_debug("Cache miss for %s", dns_resource_key_to_string(key, key_str, sizeof key_str)); goto miss; } if (FLAGS_SET(query_flags, SD_RESOLVED_CLAMP_TTL)) current = now(clock_boottime_or_monotonic()); LIST_FOREACH(by_key, j, first) { /* If the caller doesn't allow us to answer questions from cache data learned from * "side-effect", skip this entry. */ if (FLAGS_SET(query_flags, SD_RESOLVED_REQUIRE_PRIMARY) && !DNS_CACHE_ITEM_IS_PRIMARY(j)) { log_debug("Primary answer was requested for cache lookup for %s, which we don't have.", dns_resource_key_to_string(key, key_str, sizeof key_str)); goto miss; } if (j->type == DNS_CACHE_NXDOMAIN) nxdomain = true; else if (j->type == DNS_CACHE_RCODE) found_rcode = j->rcode; else if (j->rr) { if (j->rr->key->type == DNS_TYPE_NSEC) nsec = j; n++; } if (FLAGS_SET(j->query_flags, SD_RESOLVED_AUTHENTICATED)) have_authenticated = true; else have_non_authenticated = true; if (FLAGS_SET(j->query_flags, SD_RESOLVED_CONFIDENTIAL)) have_confidential = true; else have_non_confidential = true; if (j->dnssec_result < 0) { have_dnssec_result = false; /* an entry without dnssec result? then invalidate things for good */ dnssec_result = _DNSSEC_RESULT_INVALID; } else if (have_dnssec_result < 0) { have_dnssec_result = true; /* So far no result seen, let's pick this one up */ dnssec_result = j->dnssec_result; } else if (have_dnssec_result > 0 && j->dnssec_result != dnssec_result) { have_dnssec_result = false; /* conflicting result seen? then invalidate for good */ dnssec_result = _DNSSEC_RESULT_INVALID; } /* Append the answer RRs to our answer. Ideally we have the answer object, which we * preferably use. But if the cached entry was generated as "side-effect" of a reply, * i.e. from validated auxiliary records rather than from the main reply, then we use the * individual RRs only instead. */ if (j->answer) { /* Minor optimization, if the full answer object of this and the previous RR is the * same, don't bother adding it again. Typically we store a full RRset here, hence * that should be the case. */ if (!j->by_key_prev || j->answer != j->by_key_prev->answer) { DnsAnswerItem *item; DNS_ANSWER_FOREACH_ITEM(item, j->answer) { r = answer_add_clamp_ttl(&answer, item->rr, item->ifindex, item->flags, item->rrsig, query_flags, j->until, current); if (r < 0) return r; } } } else if (j->rr) { r = answer_add_clamp_ttl(&answer, j->rr, j->ifindex, FLAGS_SET(j->query_flags, SD_RESOLVED_AUTHENTICATED) ? DNS_ANSWER_AUTHENTICATED : 0, NULL, query_flags, j->until, current); if (r < 0) return r; } /* We'll return any packet we have for this. Typically all cache entries for the same key * should come from the same packet anyway, hence it doesn't really matter which packet we * return here, they should all resolve to the same anyway. */ if (!full_packet && j->full_packet) full_packet = dns_packet_ref(j->full_packet); } if (found_rcode >= 0) { log_debug("RCODE %s cache hit for %s", dns_rcode_to_string(found_rcode), dns_resource_key_to_string(key, key_str, sizeof(key_str))); if (ret_rcode) *ret_rcode = found_rcode; if (ret_answer) *ret_answer = TAKE_PTR(answer); if (ret_full_packet) *ret_full_packet = TAKE_PTR(full_packet); if (ret_query_flags) *ret_query_flags = 0; if (ret_dnssec_result) *ret_dnssec_result = dnssec_result; c->n_hit++; return 1; } if (nsec && !IN_SET(key->type, DNS_TYPE_NSEC, DNS_TYPE_DS)) { /* Note that we won't derive information for DS RRs from an NSEC, because we only cache NSEC * RRs from the lower-zone of a zone cut, but the DS RRs are on the upper zone. */ log_debug("NSEC NODATA cache hit for %s", dns_resource_key_to_string(key, key_str, sizeof key_str)); /* We only found an NSEC record that matches our name. If it says the type doesn't exist * report NODATA. Otherwise report a cache miss. */ if (ret_rcode) *ret_rcode = DNS_RCODE_SUCCESS; if (ret_answer) *ret_answer = TAKE_PTR(answer); if (ret_full_packet) *ret_full_packet = TAKE_PTR(full_packet); if (ret_query_flags) *ret_query_flags = nsec->query_flags; if (ret_dnssec_result) *ret_dnssec_result = nsec->dnssec_result; if (!bitmap_isset(nsec->rr->nsec.types, key->type) && !bitmap_isset(nsec->rr->nsec.types, DNS_TYPE_CNAME) && !bitmap_isset(nsec->rr->nsec.types, DNS_TYPE_DNAME)) { c->n_hit++; return 1; } c->n_miss++; return 0; } log_debug("%s cache hit for %s", n > 0 ? "Positive" : nxdomain ? "NXDOMAIN" : "NODATA", dns_resource_key_to_string(key, key_str, sizeof key_str)); if (n <= 0) { c->n_hit++; if (ret_rcode) *ret_rcode = nxdomain ? DNS_RCODE_NXDOMAIN : DNS_RCODE_SUCCESS; if (ret_answer) *ret_answer = TAKE_PTR(answer); if (ret_full_packet) *ret_full_packet = TAKE_PTR(full_packet); if (ret_query_flags) *ret_query_flags = ((have_authenticated && !have_non_authenticated) ? SD_RESOLVED_AUTHENTICATED : 0) | ((have_confidential && !have_non_confidential) ? SD_RESOLVED_CONFIDENTIAL : 0); if (ret_dnssec_result) *ret_dnssec_result = dnssec_result; return 1; } c->n_hit++; if (ret_rcode) *ret_rcode = DNS_RCODE_SUCCESS; if (ret_answer) *ret_answer = TAKE_PTR(answer); if (ret_full_packet) *ret_full_packet = TAKE_PTR(full_packet); if (ret_query_flags) *ret_query_flags = ((have_authenticated && !have_non_authenticated) ? SD_RESOLVED_AUTHENTICATED : 0) | ((have_confidential && !have_non_confidential) ? SD_RESOLVED_CONFIDENTIAL : 0); if (ret_dnssec_result) *ret_dnssec_result = dnssec_result; return n; miss: if (ret_rcode) *ret_rcode = DNS_RCODE_SUCCESS; if (ret_answer) *ret_answer = NULL; if (ret_full_packet) *ret_full_packet = NULL; if (ret_query_flags) *ret_query_flags = 0; if (ret_dnssec_result) *ret_dnssec_result = _DNSSEC_RESULT_INVALID; c->n_miss++; return 0; } int dns_cache_check_conflicts(DnsCache *cache, DnsResourceRecord *rr, int owner_family, const union in_addr_union *owner_address) { DnsCacheItem *i, *first; bool same_owner = true; assert(cache); assert(rr); dns_cache_prune(cache); /* See if there's a cache entry for the same key. If there * isn't there's no conflict */ first = hashmap_get(cache->by_key, rr->key); if (!first) return 0; /* See if the RR key is owned by the same owner, if so, there * isn't a conflict either */ LIST_FOREACH(by_key, i, first) { if (i->owner_family != owner_family || !in_addr_equal(owner_family, &i->owner_address, owner_address)) { same_owner = false; break; } } if (same_owner) return 0; /* See if there's the exact same RR in the cache. If yes, then * there's no conflict. */ if (dns_cache_get(cache, rr)) return 0; /* There's a conflict */ return 1; } int dns_cache_export_shared_to_packet(DnsCache *cache, DnsPacket *p) { unsigned ancount = 0; DnsCacheItem *i; int r; assert(cache); assert(p); HASHMAP_FOREACH(i, cache->by_key) { DnsCacheItem *j; LIST_FOREACH(by_key, j, i) { if (!j->rr) continue; if (!j->shared_owner) continue; r = dns_packet_append_rr(p, j->rr, 0, NULL, NULL); if (r == -EMSGSIZE && p->protocol == DNS_PROTOCOL_MDNS) { /* For mDNS, if we're unable to stuff all known answers into the given packet, * allocate a new one, push the RR into that one and link it to the current one. */ DNS_PACKET_HEADER(p)->ancount = htobe16(ancount); ancount = 0; r = dns_packet_new_query(&p->more, p->protocol, 0, true); if (r < 0) return r; /* continue with new packet */ p = p->more; r = dns_packet_append_rr(p, j->rr, 0, NULL, NULL); } if (r < 0) return r; ancount++; } } DNS_PACKET_HEADER(p)->ancount = htobe16(ancount); return 0; } void dns_cache_dump(DnsCache *cache, FILE *f) { DnsCacheItem *i; if (!cache) return; if (!f) f = stdout; HASHMAP_FOREACH(i, cache->by_key) { DnsCacheItem *j; LIST_FOREACH(by_key, j, i) { fputc('\t', f); if (j->rr) { const char *t; t = dns_resource_record_to_string(j->rr); if (!t) { log_oom(); continue; } fputs(t, f); fputc('\n', f); } else { char key_str[DNS_RESOURCE_KEY_STRING_MAX]; fputs(dns_resource_key_to_string(j->key, key_str, sizeof key_str), f); fputs(" -- ", f); fputs(dns_cache_item_type_to_string(j), f); fputc('\n', f); } } } } bool dns_cache_is_empty(DnsCache *cache) { if (!cache) return true; return hashmap_isempty(cache->by_key); } unsigned dns_cache_size(DnsCache *cache) { if (!cache) return 0; return hashmap_size(cache->by_key); }