/* Copyright (C) CZ.NIC, z.s.p.o. * SPDX-License-Identifier: GPL-3.0-or-later */ #include "lib/cache/impl.h" #include "lib/dnssec/ta.h" #include "lib/layer/iterate.h" /* The whole file only exports peek_nosync(). * Forwards for larger chunks of code: */ static int found_exact_hit(kr_layer_t *ctx, knot_pkt_t *pkt, knot_db_val_t val, uint8_t lowest_rank); static int closest_NS(struct kr_cache *cache, struct key *k, entry_list_t el, struct kr_query *qry, bool only_NS, bool is_DS); static int answer_simple_hit(kr_layer_t *ctx, knot_pkt_t *pkt, uint16_t type, const struct entry_h *eh, const void *eh_bound, uint32_t new_ttl); static int answer_dname_hit(kr_layer_t *ctx, knot_pkt_t *pkt, const knot_dname_t *dname_owner, const struct entry_h *eh, const void *eh_bound, uint32_t new_ttl); static int try_wild(struct key *k, struct answer *ans, const knot_dname_t *clencl_name, uint16_t type, uint8_t lowest_rank, const struct kr_query *qry, struct kr_cache *cache); static int peek_encloser( struct key *k, struct answer *ans, int sname_labels, uint8_t lowest_rank, const struct kr_query *qry, struct kr_cache *cache); static int nsec_p_init(struct nsec_p *nsec_p, knot_db_val_t nsec_p_entry, bool with_knot) { const size_t stamp_len = sizeof(uint32_t); if (nsec_p_entry.len <= stamp_len) { /* plain NSEC if equal */ nsec_p->raw = NULL; nsec_p->hash = 0; return kr_ok(); } nsec_p->raw = (uint8_t *)nsec_p_entry.data + stamp_len; nsec_p->hash = nsec_p_mkHash(nsec_p->raw); if (!with_knot) return kr_ok(); /* Convert NSEC3 params to another format. */ const dnssec_binary_t rdata = { .size = nsec_p_rdlen(nsec_p->raw), .data = (uint8_t *)/*const-cast*/nsec_p->raw, }; int ret = dnssec_nsec3_params_from_rdata(&nsec_p->libknot, &rdata); return ret == DNSSEC_EOK ? kr_ok() : kr_error(ret); } static void nsec_p_cleanup(struct nsec_p *nsec_p) { dnssec_binary_free(&nsec_p->libknot.salt); /* We don't really need to clear it, but it's not large. (`salt` zeroed above) */ memset(nsec_p, 0, sizeof(*nsec_p)); } /** Compute new TTL for nsec_p entry, using SOA serial arith. * \param new_ttl (optionally) write the new TTL (even if negative) * \return error code, e.g. kr_error(ESTALE) */ static int nsec_p_ttl(knot_db_val_t entry, const uint32_t timestamp, int32_t *new_ttl) { if (kr_fails_assert(entry.data)) return kr_error(EINVAL); uint32_t stamp; if (!entry.len) return kr_error(ENOENT); if (kr_fails_assert(entry.len >= sizeof(stamp))) return kr_error(EILSEQ); memcpy(&stamp, entry.data, sizeof(stamp)); int32_t newttl = stamp - timestamp; if (new_ttl) *new_ttl = newttl; return newttl < 0 ? kr_error(ESTALE) : kr_ok(); } static uint8_t get_lowest_rank(const struct kr_query *qry, const knot_dname_t *name, const uint16_t type) { /* Shut up linters. */ kr_require(qry && qry->request); /* TODO: move rank handling into the iterator (DNSSEC_* flags)? */ const bool allow_unverified = knot_wire_get_cd(qry->request->qsource.packet->wire) || qry->flags.STUB; /* in stub mode we don't trust RRs anyway ^^ */ if (qry->flags.NONAUTH) { return KR_RANK_INITIAL; /* Note: there's little sense in validation status for non-auth records. * In case of using NONAUTH to get NS IPs, knowing that you ask correct * IP doesn't matter much for security; it matters whether you can * validate the answers from the NS. */ } else if (!allow_unverified) { /* Records not present under any TA don't have their security * verified at all, so we also accept low ranks in that case. */ const bool ta_covers = kr_ta_closest(qry->request->ctx, name, type); /* ^ TODO: performance? TODO: stype - call sites */ if (ta_covers) { return KR_RANK_INSECURE | KR_RANK_AUTH; } /* else fallthrough */ } return KR_RANK_INITIAL | KR_RANK_AUTH; } /** Almost whole .produce phase for the cache module. * \note we don't transition to KR_STATE_FAIL even in case of "unexpected errors". */ int peek_nosync(kr_layer_t *ctx, knot_pkt_t *pkt) { struct kr_request *req = ctx->req; struct kr_query *qry = req->current_query; struct kr_cache *cache = &req->ctx->cache; struct key k_storage, *k = &k_storage; int ret = kr_dname_lf(k->buf, qry->sname, false); if (kr_fails_assert(ret == 0)) return ctx->state; const uint8_t lowest_rank = get_lowest_rank(qry, qry->sname, qry->stype); /**** 1. find the name or the closest (available) zone, not considering wildcards **** 1a. exact name+type match (can be negative, mainly in insecure zones) */ { knot_db_val_t key = key_exact_type_maypkt(k, qry->stype); knot_db_val_t val = { NULL, 0 }; ret = cache_op(cache, read, &key, &val, 1); if (!ret) { /* found an entry: test conditions, materialize into pkt, etc. */ ret = found_exact_hit(ctx, pkt, val, lowest_rank); } } if (!ret) { return KR_STATE_DONE; } else if (kr_fails_assert(ret == kr_error(ENOENT))) { VERBOSE_MSG(qry, "=> exact hit error: %d %s\n", ret, kr_strerror(ret)); return ctx->state; } /* Avoid aggressive answers in STUB mode. * As STUB mode doesn't validate, it wouldn't save the necessary records. * Moreover, this special case avoids unintentional NXDOMAIN on grafted subtrees. */ if (qry->flags.STUB) return ctx->state; /**** 1b. otherwise, find the longest prefix zone/xNAME (with OK time+rank). [...] */ k->zname = qry->sname; ret = kr_dname_lf(k->buf, k->zname, false); /* LATER(optim.): probably remove */ if (kr_fails_assert(ret == 0)) return ctx->state; entry_list_t el; ret = closest_NS(cache, k, el, qry, false, qry->stype == KNOT_RRTYPE_DS); if (ret) { if (kr_fails_assert(ret == kr_error(ENOENT)) || !el[0].len) { return ctx->state; } } switch (k->type) { case KNOT_RRTYPE_CNAME: { const knot_db_val_t v = el[EL_CNAME]; if (kr_fails_assert(v.data && v.len)) return ctx->state; const int32_t new_ttl = get_new_ttl(v.data, qry, qry->sname, KNOT_RRTYPE_CNAME, qry->timestamp.tv_sec); ret = answer_simple_hit(ctx, pkt, KNOT_RRTYPE_CNAME, v.data, knot_db_val_bound(v), new_ttl); return ret == kr_ok() ? KR_STATE_DONE : ctx->state; } case KNOT_RRTYPE_DNAME: { const knot_db_val_t v = el[EL_DNAME]; if (kr_fails_assert(v.data && v.len)) return ctx->state; /* TTL: for simplicity, we just ask for TTL of the generated CNAME. */ const int32_t new_ttl = get_new_ttl(v.data, qry, qry->sname, KNOT_RRTYPE_CNAME, qry->timestamp.tv_sec); ret = answer_dname_hit(ctx, pkt, k->zname, v.data, knot_db_val_bound(v), new_ttl); return ret == kr_ok() ? KR_STATE_DONE : ctx->state; } } /* We have to try proving from NSEC*. */ auto_free char *log_zname = NULL; WITH_VERBOSE(qry) { log_zname = kr_dname_text(k->zname); if (!el[0].len) { VERBOSE_MSG(qry, "=> no NSEC* cached for zone: %s\n", log_zname); } } #if 0 if (!eh) { /* fall back to root hints? */ ret = kr_zonecut_set_sbelt(req->ctx, &qry->zone_cut); if (ret) return ctx->state; kr_assert(!qry->zone_cut.parent); //VERBOSE_MSG(qry, "=> using root hints\n"); //qry->flags.AWAIT_CUT = false; return ctx->state; } /* Now `eh` points to the closest NS record that we've found, * and that's the only place to start - we may either find * a negative proof or we may query upstream from that point. */ kr_zonecut_set(&qry->zone_cut, k->zname); ret = kr_make_query(qry, pkt); // TODO: probably not yet - qname minimization if (ret) return ctx->state; #endif /** Structure for collecting multiple NSEC* + RRSIG records, * in preparation for the answer, and for tracking the progress. */ struct answer ans; memset(&ans, 0, sizeof(ans)); ans.mm = &pkt->mm; const int sname_labels = knot_dname_labels(qry->sname, NULL); /* Try the NSEC* parameters in order, until success. * Let's not mix different parameters for NSEC* RRs in a single proof. */ for (int i = 0; ;) { int32_t log_new_ttl = -123456789; /* visually recognizable value */ ret = nsec_p_ttl(el[i], qry->timestamp.tv_sec, &log_new_ttl); if (!ret || kr_log_is_debug_qry(CACHE, qry)) { nsec_p_init(&ans.nsec_p, el[i], !ret); } if (ret) { VERBOSE_MSG(qry, "=> skipping zone: %s, %s, hash %x;" "new TTL %d, ret %d\n", log_zname, (ans.nsec_p.raw ? "NSEC3" : "NSEC"), (unsigned)ans.nsec_p.hash, (int)log_new_ttl, ret); /* no need for nsec_p_cleanup() in this case */ goto cont; } VERBOSE_MSG(qry, "=> trying zone: %s, %s, hash %x\n", log_zname, (ans.nsec_p.raw ? "NSEC3" : "NSEC"), (unsigned)ans.nsec_p.hash); /**** 2. and 3. inside */ ret = peek_encloser(k, &ans, sname_labels, lowest_rank, qry, cache); nsec_p_cleanup(&ans.nsec_p); if (!ret) break; if (ret < 0) return ctx->state; cont: /* Otherwise we try another nsec_p, if available. */ if (++i == ENTRY_APEX_NSECS_CNT) return ctx->state; /* clear possible partial answers in `ans` (no need to deallocate) */ ans.rcode = 0; memset(&ans.rrsets, 0, sizeof(ans.rrsets)); } /**** 4. add SOA iff needed */ if (ans.rcode != PKT_NOERROR) { /* Assuming k->buf still starts with zone's prefix, * look up the SOA in cache. */ k->buf[0] = k->zlf_len; knot_db_val_t key = key_exact_type(k, KNOT_RRTYPE_SOA); knot_db_val_t val = { NULL, 0 }; ret = cache_op(cache, read, &key, &val, 1); const struct entry_h *eh; if (ret || !(eh = entry_h_consistent_E(val, KNOT_RRTYPE_SOA))) { kr_assert(ret); /* only want to catch `eh` failures */ VERBOSE_MSG(qry, "=> SOA missed\n"); return ctx->state; } /* Check if the record is OK. */ int32_t new_ttl = get_new_ttl(eh, qry, k->zname, KNOT_RRTYPE_SOA, qry->timestamp.tv_sec); if (new_ttl < 0 || eh->rank < lowest_rank || eh->is_packet) { VERBOSE_MSG(qry, "=> SOA unfit %s: rank 0%.2o, new TTL %d\n", (eh->is_packet ? "packet" : "RR"), eh->rank, new_ttl); return ctx->state; } /* Add the SOA into the answer. */ ret = entry2answer(&ans, AR_SOA, eh, knot_db_val_bound(val), k->zname, KNOT_RRTYPE_SOA, new_ttl); if (ret) return ctx->state; } /* Find our target RCODE. */ int real_rcode; switch (ans.rcode) { case PKT_NODATA: case PKT_NOERROR: /* positive wildcarded response */ real_rcode = KNOT_RCODE_NOERROR; break; case PKT_NXDOMAIN: real_rcode = KNOT_RCODE_NXDOMAIN; break; default: kr_assert(false); case 0: /* i.e. nothing was found */ /* LATER(optim.): zone cut? */ VERBOSE_MSG(qry, "=> cache miss\n"); return ctx->state; } if (pkt_renew(pkt, qry->sname, qry->stype) || knot_pkt_begin(pkt, KNOT_ANSWER) ) { kr_assert(false); return ctx->state; } knot_wire_set_rcode(pkt->wire, real_rcode); bool expiring = false; // TODO for (int i = 0; i < sizeof(ans.rrsets) / sizeof(ans.rrsets[0]); ++i) { if (i == 1) knot_pkt_begin(pkt, KNOT_AUTHORITY); if (!ans.rrsets[i].set.rr) continue; expiring = expiring || ans.rrsets[i].set.expiring; ret = pkt_append(pkt, &ans.rrsets[i], ans.rrsets[i].set.rank); if (kr_fails_assert(ret == 0)) return ctx->state; } /* Finishing touches. */ struct kr_qflags * const qf = &qry->flags; qf->EXPIRING = expiring; qf->CACHED = true; qf->NO_MINIMIZE = true; return KR_STATE_DONE; } /** * This is where the high-level "business logic" of aggressive cache is. * \return 0: success (may need SOA); >0: try other nsec_p; <0: exit cache immediately. */ static int peek_encloser( struct key *k, struct answer *ans, const int sname_labels, uint8_t lowest_rank, const struct kr_query *qry, struct kr_cache *cache) { /** Start of NSEC* covering the sname; * it's part of key - the one within zone (read only) */ knot_db_val_t cover_low_kwz = { NULL, 0 }; knot_dname_t cover_hi_storage[KNOT_DNAME_MAXLEN]; /** End of NSEC* covering the sname. */ knot_db_val_t cover_hi_kwz = { .data = cover_hi_storage, .len = sizeof(cover_hi_storage), }; /**** 2. Find a closest (provable) encloser (of sname). */ int clencl_labels = -1; bool clencl_is_tentative = false; if (!ans->nsec_p.raw) { /* NSEC */ int ret = nsec1_encloser(k, ans, sname_labels, &clencl_labels, &cover_low_kwz, &cover_hi_kwz, qry, cache); if (ret) return ret; } else { int ret = nsec3_encloser(k, ans, sname_labels, &clencl_labels, qry, cache); clencl_is_tentative = ret == ABS(ENOENT) && clencl_labels >= 0; /* ^^ Last chance: *positive* wildcard record under this clencl. */ if (ret && !clencl_is_tentative) return ret; } /* We should have either a match or a cover at this point. */ if (kr_fails_assert(ans->rcode == PKT_NODATA || ans->rcode == PKT_NXDOMAIN)) return kr_error(EINVAL); const bool ncloser_covered = ans->rcode == PKT_NXDOMAIN; /** Name of the closest (provable) encloser. */ const knot_dname_t *clencl_name = qry->sname; for (int l = sname_labels; l > clencl_labels; --l) clencl_name = knot_wire_next_label(clencl_name, NULL); /**** 3. source of synthesis checks, in case the next closer name was covered. **** 3a. We want to query for NSEC* of source of synthesis (SS) or its * predecessor, providing us with a proof of its existence or non-existence. */ if (ncloser_covered && !ans->nsec_p.raw) { int ret = nsec1_src_synth(k, ans, clencl_name, cover_low_kwz, cover_hi_kwz, qry, cache); if (ret == AR_SOA) return 0; kr_assert(ret <= 0); if (ret) return ret; } else if (ncloser_covered && ans->nsec_p.raw && !clencl_is_tentative) { int ret = nsec3_src_synth(k, ans, clencl_name, qry, cache); if (ret == AR_SOA) return 0; kr_assert(ret <= 0); if (ret) return ret; } /* else (!ncloser_covered) so no wildcard checks needed, * as we proved that sname exists. */ /**** 3b. find wildcarded answer, if next closer name was covered * and we don't have a full proof yet. (common for NSEC*) */ if (!ncloser_covered) return kr_ok(); /* decrease indentation */ /* Construct key for exact qry->stype + source of synthesis. */ int ret = kr_dname_lf(k->buf, clencl_name, true); if (kr_fails_assert(ret == 0)) return kr_error(ret); const uint16_t types[] = { qry->stype, KNOT_RRTYPE_CNAME }; for (int i = 0; i < (2 - (qry->stype == KNOT_RRTYPE_CNAME)); ++i) { ret = try_wild(k, ans, clencl_name, types[i], lowest_rank, qry, cache); if (ret == kr_ok()) { return kr_ok(); } else if (kr_fails_assert(ret == kr_error(ENOENT) || ret == kr_error(ESTALE))) { return kr_error(ret); } /* else continue */ } /* Neither attempt succeeded, but the NSEC* proofs were found, * so skip trying other parameters, as it seems very unlikely * to turn out differently than by the same wildcard search. */ return kr_error(ENOENT); } static void answer_simple_qflags(struct kr_qflags *qf, const struct entry_h *eh, uint32_t new_ttl) { /* Finishing touches. */ qf->EXPIRING = is_expiring(eh->ttl, new_ttl); qf->CACHED = true; qf->NO_MINIMIZE = true; qf->DNSSEC_INSECURE = kr_rank_test(eh->rank, KR_RANK_INSECURE); if (qf->DNSSEC_INSECURE) { qf->DNSSEC_WANT = false; } } #define CHECK_RET(ret) do { \ if (kr_fails_assert((ret) >= 0)) return kr_error((ret)); \ } while (false) static int answer_simple_hit(kr_layer_t *ctx, knot_pkt_t *pkt, uint16_t type, const struct entry_h *eh, const void *eh_bound, uint32_t new_ttl) { struct kr_request *req = ctx->req; struct kr_query *qry = req->current_query; /* All OK, so start constructing the (pseudo-)packet. */ int ret = pkt_renew(pkt, qry->sname, qry->stype); CHECK_RET(ret); /* Materialize the sets for the answer in (pseudo-)packet. */ struct answer ans; memset(&ans, 0, sizeof(ans)); ans.mm = &pkt->mm; ret = entry2answer(&ans, AR_ANSWER, eh, eh_bound, qry->sname, type, new_ttl); CHECK_RET(ret); /* Put links to the materialized data into the pkt. */ ret = pkt_append(pkt, &ans.rrsets[AR_ANSWER], eh->rank); CHECK_RET(ret); answer_simple_qflags(&qry->flags, eh, new_ttl); VERBOSE_MSG(qry, "=> satisfied by exact %s: rank 0%.2o, new TTL %d\n", (type == KNOT_RRTYPE_CNAME ? "CNAME" : "RRset"), eh->rank, new_ttl); return kr_ok(); } static int answer_dname_hit(kr_layer_t *ctx, knot_pkt_t *pkt, const knot_dname_t *dname_owner, const struct entry_h *eh, const void *eh_bound, uint32_t new_ttl) { struct kr_request *req = ctx->req; struct kr_query *qry = req->current_query; /* All OK, so start constructing the (pseudo-)packet. */ int ret = pkt_renew(pkt, qry->sname, qry->stype); CHECK_RET(ret); /* Materialize the DNAME for the answer in (pseudo-)packet. */ struct answer ans; memset(&ans, 0, sizeof(ans)); ans.mm = &pkt->mm; ret = entry2answer(&ans, AR_ANSWER, eh, eh_bound, dname_owner, KNOT_RRTYPE_DNAME, new_ttl); CHECK_RET(ret); /* Put link to the RRset into the pkt. */ ret = pkt_append(pkt, &ans.rrsets[AR_ANSWER], eh->rank); CHECK_RET(ret); const knot_dname_t *dname_target = knot_dname_target(ans.rrsets[AR_ANSWER].set.rr->rrs.rdata); /* Generate CNAME RRset for the answer in (pseudo-)packet. */ const int AR_CNAME = AR_SOA; knot_rrset_t *rr = ans.rrsets[AR_CNAME].set.rr = knot_rrset_new(qry->sname, KNOT_RRTYPE_CNAME, KNOT_CLASS_IN, new_ttl, ans.mm); CHECK_RET(rr ? kr_ok() : -ENOMEM); const knot_dname_t *cname_target = knot_dname_replace_suffix(qry->sname, knot_dname_labels(dname_owner, NULL), dname_target, ans.mm); CHECK_RET(cname_target ? kr_ok() : -ENOMEM); const int rdata_len = knot_dname_size(cname_target); if (rdata_len <= KNOT_DNAME_MAXLEN && knot_dname_labels(cname_target, NULL) <= KNOT_DNAME_MAXLABELS) { /* Normal case: the target name fits. */ rr->rrs.count = 1; rr->rrs.size = knot_rdata_size(rdata_len); rr->rrs.rdata = mm_alloc(ans.mm, rr->rrs.size); CHECK_RET(rr->rrs.rdata ? kr_ok() : -ENOMEM); knot_rdata_init(rr->rrs.rdata, rdata_len, cname_target); /* Put link to the RRset into the pkt. */ ret = pkt_append(pkt, &ans.rrsets[AR_CNAME], eh->rank); CHECK_RET(ret); } else { /* Note that it's basically a successful answer; name just doesn't fit. */ knot_wire_set_rcode(pkt->wire, KNOT_RCODE_YXDOMAIN); } answer_simple_qflags(&qry->flags, eh, new_ttl); VERBOSE_MSG(qry, "=> satisfied by DNAME+CNAME: rank 0%.2o, new TTL %d\n", eh->rank, new_ttl); return kr_ok(); } #undef CHECK_RET /** TODO: description; see the single call site for now. */ static int found_exact_hit(kr_layer_t *ctx, knot_pkt_t *pkt, knot_db_val_t val, uint8_t lowest_rank) { struct kr_request *req = ctx->req; struct kr_query *qry = req->current_query; int ret = entry_h_seek(&val, qry->stype); if (ret) return ret; const struct entry_h *eh = entry_h_consistent_E(val, qry->stype); if (kr_fails_assert(eh)) return kr_error(ENOENT); // LATER: recovery in case of error, perhaps via removing the entry? // LATER(optim): perhaps optimize the zone cut search int32_t new_ttl = get_new_ttl(eh, qry, qry->sname, qry->stype, qry->timestamp.tv_sec); if (new_ttl < 0 || eh->rank < lowest_rank) { /* Positive record with stale TTL or bad rank. * LATER(optim.): It's unlikely that we find a negative one, * so we might theoretically skip all the cache code. */ VERBOSE_MSG(qry, "=> skipping exact %s: rank 0%.2o (min. 0%.2o), new TTL %d\n", eh->is_packet ? "packet" : "RR", eh->rank, lowest_rank, new_ttl); return kr_error(ENOENT); } const uint8_t *eh_bound = knot_db_val_bound(val); if (eh->is_packet) { /* Note: we answer here immediately, even if it's (theoretically) * possible that we could generate a higher-security negative proof. * Rank is high-enough so we take it to save time searching; * in practice this also helps in some incorrect zones (live-signed). */ return answer_from_pkt (ctx, pkt, qry->stype, eh, eh_bound, new_ttl); } else { return answer_simple_hit(ctx, pkt, qry->stype, eh, eh_bound, new_ttl); } } /** Try to satisfy via wildcard (positively). See the single call site. */ static int try_wild(struct key *k, struct answer *ans, const knot_dname_t *clencl_name, const uint16_t type, const uint8_t lowest_rank, const struct kr_query *qry, struct kr_cache *cache) { knot_db_val_t key = key_exact_type(k, type); /* Find the record. */ knot_db_val_t val = { NULL, 0 }; int ret = cache_op(cache, read, &key, &val, 1); if (!ret) { ret = entry_h_seek(&val, type); } if (ret) { if (kr_fails_assert(ret == kr_error(ENOENT))) VERBOSE_MSG(qry, "=> wildcard: hit error %d %s\n", ret, strerror(abs(ret))); WITH_VERBOSE(qry) { auto_free char *clencl_str = kr_dname_text(clencl_name), *type_str = kr_rrtype_text(type); VERBOSE_MSG(qry, "=> wildcard: not found: *.%s %s\n", clencl_str, type_str); } return ret; } /* Check if the record is OK. */ const struct entry_h *eh = entry_h_consistent_E(val, type); if (kr_fails_assert(eh)) return kr_error(ret); // LATER: recovery in case of error, perhaps via removing the entry? int32_t new_ttl = get_new_ttl(eh, qry, qry->sname, type, qry->timestamp.tv_sec); /* ^^ here we use the *expanded* wildcard name */ if (new_ttl < 0 || eh->rank < lowest_rank || eh->is_packet) { /* Wildcard record with stale TTL, bad rank or packet. */ VERBOSE_MSG(qry, "=> wildcard: skipping %s, rank 0%.2o, new TTL %d\n", eh->is_packet ? "packet" : "RR", eh->rank, new_ttl); return kr_error(ESTALE); } /* Add the RR into the answer. */ ret = entry2answer(ans, AR_ANSWER, eh, knot_db_val_bound(val), qry->sname, type, new_ttl); VERBOSE_MSG(qry, "=> wildcard: answer expanded, ret = %d, new TTL %d\n", ret, (int)new_ttl); if (ret) return kr_error(ret); ans->rcode = PKT_NOERROR; return kr_ok(); } int kr_cache_closest_apex(struct kr_cache *cache, const knot_dname_t *name, bool is_DS, knot_dname_t ** apex) { if (kr_fails_assert(cache && cache->db && name && apex && *apex == NULL)) return kr_error(EINVAL); struct key k_storage, *k = &k_storage; int ret = kr_dname_lf(k->buf, name, false); if (ret) return kr_error(ret); entry_list_t el_; k->zname = name; ret = closest_NS(cache, k, el_, NULL, true, is_DS); if (ret && ret != -abs(ENOENT)) return ret; *apex = knot_dname_copy(k->zname, NULL); if (!*apex) return kr_error(ENOMEM); return kr_ok(); } /** \internal for closest_NS. Check suitability of a single entry, setting k->type if OK. * \return error code, negative iff whole list should be skipped. */ static int check_NS_entry(struct key *k, knot_db_val_t entry, int i, bool exact_match, bool is_DS, const struct kr_query *qry, uint32_t timestamp); /** * Find the longest prefix zone/xNAME (with OK time+rank), starting at k->*. * * The found type is returned via k->type; the values are returned in el. * \note we use k->type = KNOT_RRTYPE_NS also for the nsec_p result. * \param qry can be NULL (-> gettimeofday(), but you lose the stale-serve hook) * \param only_NS don't consider xNAMEs * \return error code */ static int closest_NS(struct kr_cache *cache, struct key *k, entry_list_t el, struct kr_query *qry, const bool only_NS, const bool is_DS) { /* get the current timestamp */ uint32_t timestamp; if (qry) { timestamp = qry->timestamp.tv_sec; } else { struct timeval tv; if (gettimeofday(&tv, NULL)) return kr_error(errno); timestamp = tv.tv_sec; } int zlf_len = k->buf[0]; // LATER(optim): if stype is NS, we check the same value again bool exact_match = true; bool need_zero = true; /* Inspect the NS/xNAME entries, shortening by a label on each iteration. */ do { k->buf[0] = zlf_len; knot_db_val_t key = key_exact_type(k, KNOT_RRTYPE_NS); knot_db_val_t val; int ret = cache_op(cache, read, &key, &val, 1); if (ret == kr_error(ENOENT)) goto next_label; if (kr_fails_assert(ret == 0)) { if (need_zero) memset(el, 0, sizeof(entry_list_t)); return kr_error(ret); } /* Check consistency, find any type; * using `goto` for shortening by another label. */ ret = entry_list_parse(val, el); if (kr_fails_assert(ret == 0)) // do something about it? goto next_label; need_zero = false; /* More types are possible; try in order. * For non-fatal failures just "continue;" to try the next type. */ /* Now a complication - we need to try EL_DNAME before NSEC* * (Unfortunately that's not easy to write very nicely.) */ if (!only_NS) { const int i = EL_DNAME; ret = check_NS_entry(k, el[i], i, exact_match, is_DS, qry, timestamp); if (ret < 0) goto next_label; else if (!ret) { /* We found our match. */ k->zlf_len = zlf_len; return kr_ok(); } } const int el_count = only_NS ? EL_NS + 1 : EL_LENGTH; for (int i = 0; i < el_count; ++i) { if (i == EL_DNAME) continue; ret = check_NS_entry(k, el[i], i, exact_match, is_DS, qry, timestamp); if (ret < 0) goto next_label; else if (!ret) { /* We found our match. */ k->zlf_len = zlf_len; return kr_ok(); } } next_label: /* remove one more label */ exact_match = false; if (k->zname[0] == 0) { /* We miss root NS in cache, but let's at least assume it exists. */ k->type = KNOT_RRTYPE_NS; k->zlf_len = zlf_len; kr_assert(zlf_len == 0); if (need_zero) memset(el, 0, sizeof(entry_list_t)); return kr_error(ENOENT); } zlf_len -= (k->zname[0] + 1); k->zname += (k->zname[0] + 1); k->buf[zlf_len + 1] = 0; } while (true); } static int check_NS_entry(struct key *k, const knot_db_val_t entry, const int i, const bool exact_match, const bool is_DS, const struct kr_query *qry, uint32_t timestamp) { const int ESKIP = ABS(ENOENT); if (!entry.len /* On a zone cut we want DS from the parent zone. */ || (exact_match && is_DS) /* CNAME is interesting only if we * directly hit the name that was asked. * Note that we want it even in the DS case. */ || (i == EL_CNAME && !exact_match) /* DNAME is interesting only if we did NOT * directly hit the name that was asked. */ || (i == EL_DNAME && exact_match) ) { return ESKIP; } uint16_t type; if (i < ENTRY_APEX_NSECS_CNT) { type = KNOT_RRTYPE_NS; int32_t log_new_ttl = -123456789; /* visually recognizable value */ const int err = nsec_p_ttl(entry, timestamp, &log_new_ttl); if (err) { VERBOSE_MSG(qry, "=> skipping unfit nsec_p: new TTL %d, error %d\n", (int)log_new_ttl, err); return ESKIP; } } else { type = EL2RRTYPE(i); /* Find the entry for the type, check positivity, TTL */ const struct entry_h *eh = entry_h_consistent_E(entry, type); if (kr_fails_assert(eh)) { VERBOSE_MSG(qry, "=> EH not consistent\n"); return kr_error(EILSEQ); } const int32_t log_new_ttl = get_new_ttl(eh, qry, k->zname, type, timestamp); const bool ok = /* Not interested in negative bogus or outdated RRs. */ !eh->is_packet && log_new_ttl >= 0 /* For NS any kr_rank is accepted, as insecure or even nonauth is OK */ && (type == KNOT_RRTYPE_NS || eh->rank >= get_lowest_rank(qry, k->zname, type)); WITH_VERBOSE(qry) { if (!ok) { auto_free char *type_str = kr_rrtype_text(type); const char *packet_str = eh->is_packet ? "packet" : "RR"; VERBOSE_MSG(qry, "=> skipping unfit %s %s: rank 0%.2o, new TTL %d\n", type_str, packet_str, eh->rank, (int)log_new_ttl); } } if (!ok) return ESKIP; } k->type = type; return kr_ok(); }