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author | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-07 15:26:00 +0000 |
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committer | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-07 15:26:00 +0000 |
commit | 830407e88f9d40d954356c3754f2647f91d5c06a (patch) | |
tree | d6a0ece6feea91f3c656166dbaa884ef8a29740e /lib/cache/nsec1.c | |
parent | Initial commit. (diff) | |
download | knot-resolver-upstream.tar.xz knot-resolver-upstream.zip |
Adding upstream version 5.6.0.upstream/5.6.0upstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to '')
-rw-r--r-- | lib/cache/nsec1.c | 488 |
1 files changed, 488 insertions, 0 deletions
diff --git a/lib/cache/nsec1.c b/lib/cache/nsec1.c new file mode 100644 index 0000000..4554303 --- /dev/null +++ b/lib/cache/nsec1.c @@ -0,0 +1,488 @@ +/* Copyright (C) CZ.NIC, z.s.p.o. <knot-resolver@labs.nic.cz> + * SPDX-License-Identifier: GPL-3.0-or-later + */ + +/** @file + * Implementation of NSEC (1) handling. Prototypes in ./impl.h + */ + +#include "lib/cache/impl.h" +#include "lib/dnssec/nsec.h" +#include "lib/layer/iterate.h" + + +/** Reconstruct a name into a buffer (assuming length at least KNOT_DNAME_MAXLEN). + * \return kr_ok() or error code (<0). */ +static int dname_wire_reconstruct(knot_dname_t *buf, const struct key *k, + knot_db_val_t kwz) +{ + /* Reconstruct from key: first the ending, then zone name. */ + int ret = knot_dname_lf2wire(buf, kwz.len, kwz.data); + if (kr_fails_assert(ret >= 0)) { + VERBOSE_MSG(NULL, "=> NSEC: LF2wire ret = %d\n", ret); + return ret; + } + /* The last written byte is the zero label for root -> overwrite. */ + knot_dname_t *zone_start = buf + ret - 1; + if (kr_fails_assert(*zone_start == '\0')) + return kr_error(EFAULT); + ret = knot_dname_to_wire(zone_start, k->zname, KNOT_DNAME_MAXLEN - kwz.len); + if (kr_fails_assert(ret == k->zlf_len + 1)) + return ret < 0 ? ret : kr_error(EILSEQ); + return kr_ok(); +} + + +knot_db_val_t key_NSEC1(struct key *k, const knot_dname_t *name, bool add_wildcard) +{ + /* we basically need dname_lf with two bytes added + * on a correct place within the name (the cut) */ + int ret; + const bool ok = k && name + && !(ret = kr_dname_lf(k->buf, name, add_wildcard)); + if (kr_fails_assert(ok)) + return (knot_db_val_t){ NULL, 0 }; + + uint8_t *begin = k->buf + 1 + k->zlf_len; /* one byte after zone's zero */ + uint8_t *end = k->buf + 1 + k->buf[0]; /* we don't use the final zero in key, + * but move it anyway */ + if (kr_fails_assert(end >= begin)) + return (knot_db_val_t){ NULL, 0 }; + int key_len; + if (end > begin) { + memmove(begin + 2, begin, end - begin); + key_len = k->buf[0] + 1; + } else { + key_len = k->buf[0] + 2; + } + /* CACHE_KEY_DEF: key == zone's dname_lf + '\0' + '1' + dname_lf + * of the name within the zone without the final 0. Iff the latter is empty, + * there's no zero to cut and thus the key_len difference. + */ + begin[0] = 0; + begin[1] = '1'; /* tag for NSEC1 */ + k->type = KNOT_RRTYPE_NSEC; + + /* + VERBOSE_MSG(NULL, "<> key_NSEC1; name: "); + kr_dname_print(name, add_wildcard ? "*." : "" , " "); + kr_log_debug(CACHE, "(zone name LF length: %d; total key length: %d)\n", + k->zlf_len, key_len); + */ + + return (knot_db_val_t){ k->buf + 1, key_len }; +} + + +/** Assuming that k1 < k4, find where k2 is. (Considers DNS wrap-around.) + * + * \return Intuition: position of k2 among kX. + * 0: k2 < k1; 1: k1 == k2; 2: k1 is a prefix of k2 < k4; + * 3: k1 < k2 < k4 (and not 2); 4: k2 == k4; 5: k2 > k4 + * \note k1.data may be NULL, meaning assumption that k1 < k2 and not a prefix + * (i.e. return code will be > 2) + */ +static int kwz_between(knot_db_val_t k1, knot_db_val_t k2, knot_db_val_t k4) +{ + kr_require(k2.data && k4.data); + /* CACHE_KEY_DEF; we need to beware of one key being a prefix of another */ + int ret_maybe; /**< result, assuming we confirm k2 < k4 */ + if (k1.data) { + const int cmp12 = memcmp(k1.data, k2.data, MIN(k1.len, k2.len)); + if (cmp12 == 0 && k1.len == k2.len) /* iff k1 == k2 */ + return 1; + if (cmp12 > 0 || (cmp12 == 0 && k1.len > k2.len)) /* iff k1 > k2 */ + return 0; + ret_maybe = cmp12 == 0 ? 2 : 3; + } else { + ret_maybe = 3; + } + if (k4.len == 0) { /* wrap-around */ + return k2.len > 0 ? ret_maybe : 4; + } else { + const int cmp24 = memcmp(k2.data, k4.data, MIN(k2.len, k4.len)); + if (cmp24 == 0 && k2.len == k4.len) /* iff k2 == k4 */ + return 4; + if (cmp24 > 0 || (cmp24 == 0 && k2.len > k4.len)) /* iff k2 > k4 */ + return 5; + return ret_maybe; + } +} + + +/** NSEC1 range search. + * + * \param key Pass output of key_NSEC1(k, ...) + * \param value[out] The raw data of the NSEC cache record (optional; consistency checked). + * \param exact_match[out] Whether the key was matched exactly or just covered (optional). + * \param kwz_low[out] Output the low end of covering NSEC, pointing within DB (optional). + * \param kwz_high[in,out] Storage for the high end of covering NSEC (optional). + * It's only set if !exact_match. + * \param new_ttl[out] New TTL of the NSEC (optional). + * \return Error message or NULL. + * \note The function itself does *no* bitmap checks, e.g. RFC 6840 sec. 4. + */ +static const char * find_leq_NSEC1(struct kr_cache *cache, const struct kr_query *qry, + const knot_db_val_t key, const struct key *k, knot_db_val_t *value, + bool *exact_match, knot_db_val_t *kwz_low, knot_db_val_t *kwz_high, + uint32_t *new_ttl) +{ + /* Do the cache operation. */ + const size_t nwz_off = key_nwz_off(k); + if (kr_fails_assert(key.data && key.len >= nwz_off)) + return "range search ERROR"; + knot_db_val_t key_nsec = key; + knot_db_val_t val = { NULL, 0 }; + int ret = cache_op(cache, read_leq, &key_nsec, &val); + if (ret < 0) { + if (kr_fails_assert(ret == kr_error(ENOENT))) { + return "range search ERROR"; + } else { + return "range search miss"; + } + } + if (value) { + *value = val; + } + /* Check consistency, TTL, rank. */ + const bool is_exact = (ret == 0); + if (exact_match) { + *exact_match = is_exact; + } + const struct entry_h *eh = entry_h_consistent_NSEC(val); + if (!eh) { + /* This might be just finding something else than NSEC1 entry, + * in case we searched before the very first one in the zone. */ + return "range search found inconsistent entry"; + } + /* Passing just zone name instead of owner, as we don't + * have it reconstructed at this point. */ + int32_t new_ttl_ = get_new_ttl(eh, qry, k->zname, KNOT_RRTYPE_NSEC, + qry->timestamp.tv_sec); + if (new_ttl_ < 0 || !kr_rank_test(eh->rank, KR_RANK_SECURE)) { + return "range search found stale or insecure entry"; + /* TODO: remove the stale record *and* retry, + * in case we haven't run off. Perhaps start by in_zone check. */ + } + if (new_ttl) { + *new_ttl = new_ttl_; + } + if (kwz_low) { + *kwz_low = (knot_db_val_t){ + .data = (uint8_t *)key_nsec.data + nwz_off, + .len = key_nsec.len - nwz_off, + }; /* CACHE_KEY_DEF */ + } + if (is_exact) { + /* Nothing else to do. */ + return NULL; + } + /* The NSEC starts strictly before our target name; + * now check that it still belongs into that zone. */ + const bool nsec_in_zone = key_nsec.len >= nwz_off + /* CACHE_KEY_DEF */ + && memcmp(key.data, key_nsec.data, nwz_off) == 0; + if (!nsec_in_zone) { + return "range search miss (!nsec_in_zone)"; + } + /* We know it starts before sname, so let's check the other end. + * 1. construct the key for the next name - kwz_hi. */ + /* it's *full* name ATM */ + /* Technical complication: memcpy is safe for unaligned case (on non-x86) */ + __typeof__(((knot_rdata_t *)NULL)->len) next_len; + const uint8_t *next_data; + { /* next points to knot_rdata_t but possibly unaligned */ + const uint8_t *next = eh->data + KR_CACHE_RR_COUNT_SIZE; + memcpy(&next_len, next + offsetof(knot_rdata_t, len), sizeof(next_len)); + next_data = next + offsetof(knot_rdata_t, data); + } + if (kr_fails_assert(KR_CACHE_RR_COUNT_SIZE == 2 && get_uint16(eh->data) != 0)) { + return "ERROR"; /* TODO: more checks? */ + } + /* + WITH_VERBOSE { + VERBOSE_MSG(qry, "=> NSEC: next name: "); + kr_dname_print(next, "", "\n"); + } + */ + knot_dname_t ch_buf[KNOT_DNAME_MAXLEN]; + knot_dname_t *chs = kwz_high ? kwz_high->data : ch_buf; + if (kr_fails_assert(chs)) + return "EINVAL"; + + { + /* Lower-case chs; see also RFC 6840 5.1. + * LATER(optim.): we do lots of copying etc. */ + knot_dname_t lower_buf[KNOT_DNAME_MAXLEN]; + ret = knot_dname_to_wire(lower_buf, next_data, + MIN(next_len, KNOT_DNAME_MAXLEN)); + if (ret < 0) { /* _ESPACE */ + return "range search found record with incorrect contents"; + } + knot_dname_to_lower(lower_buf); + ret = kr_dname_lf(chs, lower_buf, false); + } + + if (kr_fails_assert(ret == 0)) + return "ERROR"; + knot_db_val_t kwz_hi = { /* skip the zone name */ + .data = chs + 1 + k->zlf_len, + .len = chs[0] - k->zlf_len, + }; + if (kr_fails_assert((ssize_t)(kwz_hi.len) >= 0)) + return "ERROR"; + /* 2. do the actual range check. */ + const knot_db_val_t kwz_sname = { + .data = (void *)/*const-cast*/(k->buf + 1 + nwz_off), + .len = k->buf[0] - k->zlf_len, + }; + if (kr_fails_assert((ssize_t)(kwz_sname.len) >= 0)) + return "ERROR"; + bool covers = /* we know for sure that the low end is before kwz_sname */ + 3 == kwz_between((knot_db_val_t){ NULL, 0 }, kwz_sname, kwz_hi); + if (!covers) { + return "range search miss (!covers)"; + } + if (kwz_high) { + *kwz_high = kwz_hi; + } + return NULL; +} + + +int nsec1_encloser(struct key *k, struct answer *ans, + const int sname_labels, int *clencl_labels, + knot_db_val_t *cover_low_kwz, knot_db_val_t *cover_hi_kwz, + const struct kr_query *qry, struct kr_cache *cache) +{ + static const int ESKIP = ABS(ENOENT); + /* Basic sanity check. */ + const bool ok = k && ans && clencl_labels && cover_low_kwz && cover_hi_kwz + && qry && cache; + if (kr_fails_assert(ok)) + return kr_error(EINVAL); + + /* Find a previous-or-equal name+NSEC in cache covering the QNAME, + * checking TTL etc. */ + knot_db_val_t key = key_NSEC1(k, qry->sname, false); + knot_db_val_t val = { NULL, 0 }; + bool exact_match; + uint32_t new_ttl; + const char *err = find_leq_NSEC1(cache, qry, key, k, &val, + &exact_match, cover_low_kwz, cover_hi_kwz, &new_ttl); + if (err) { + VERBOSE_MSG(qry, "=> NSEC sname: %s\n", err); + return ESKIP; + } + + /* Get owner name of the record. */ + const knot_dname_t *owner; + knot_dname_t owner_buf[KNOT_DNAME_MAXLEN]; + if (exact_match) { + owner = qry->sname; + } else { + int ret = dname_wire_reconstruct(owner_buf, k, *cover_low_kwz); + if (unlikely(ret)) return ESKIP; + owner = owner_buf; + } + /* Basic checks OK -> materialize data. */ + { + const struct entry_h *nsec_eh = val.data; + int ret = entry2answer(ans, AR_NSEC, nsec_eh, knot_db_val_bound(val), + owner, KNOT_RRTYPE_NSEC, new_ttl); + if (ret) return kr_error(ret); + } + + /* Final checks, split for matching vs. covering our sname. */ + const knot_rrset_t *nsec_rr = ans->rrsets[AR_NSEC].set.rr; + const uint8_t *bm = knot_nsec_bitmap(nsec_rr->rrs.rdata); + uint16_t bm_size = knot_nsec_bitmap_len(nsec_rr->rrs.rdata); + if (kr_fails_assert(bm)) + return kr_error(EFAULT); + + if (exact_match) { + if (kr_nsec_bitmap_nodata_check(bm, bm_size, qry->stype, nsec_rr->owner) != 0) { + VERBOSE_MSG(qry, + "=> NSEC sname: match but failed type check\n"); + return ESKIP; + } + /* NODATA proven; just need to add SOA+RRSIG later */ + VERBOSE_MSG(qry, "=> NSEC sname: match proved NODATA, new TTL %d\n", + new_ttl); + ans->rcode = PKT_NODATA; + return kr_ok(); + } /* else */ + + /* Inexact match. First check if sname is delegated by that NSEC. */ + const int nsec_matched = knot_dname_matched_labels(nsec_rr->owner, qry->sname); + const bool is_sub = nsec_matched == knot_dname_labels(nsec_rr->owner, NULL); + if (is_sub && kr_nsec_children_in_zone_check(bm, bm_size) != 0) { + VERBOSE_MSG(qry, "=> NSEC sname: covered but delegated (or error)\n"); + return ESKIP; + } + /* NXDOMAIN proven *except* for wildcards. */ + WITH_VERBOSE(qry) { + auto_free char *owner_str = kr_dname_text(nsec_rr->owner), + *next_str = kr_dname_text(knot_nsec_next(nsec_rr->rrs.rdata)); + VERBOSE_MSG(qry, "=> NSEC sname: covered by: %s -> %s, new TTL %d\n", + owner_str, next_str, new_ttl); + } + + /* Find label count of the closest encloser. + * Both endpoints in an NSEC do exist (though possibly in a child zone) + * and any prefixes of those names as well (empty non-terminals), + * but nothing else exists inside this "triangle". + * + * Note that we have to lower-case the next name for comparison, + * even though we have canonicalized NSEC already; see RFC 6840 5.1. + * LATER(optim.): it might be faster to use the LFs we already have. + */ + knot_dname_t next[KNOT_DNAME_MAXLEN]; + int ret = knot_dname_to_wire(next, knot_nsec_next(nsec_rr->rrs.rdata), sizeof(next)); + if (kr_fails_assert(ret >= 0)) + return kr_error(ret); + knot_dname_to_lower(next); + *clencl_labels = MAX( + nsec_matched, + knot_dname_matched_labels(qry->sname, next) + ); + + /* Empty non-terminals don't need to have + * a matching NSEC record. */ + if (sname_labels == *clencl_labels) { + ans->rcode = PKT_NODATA; + VERBOSE_MSG(qry, + "=> NSEC sname: empty non-terminal by the same RR\n"); + } else { + ans->rcode = PKT_NXDOMAIN; + } + return kr_ok(); +} + +/** Verify non-existence after kwz_between() call. */ +static bool nonexistence_ok(int cmp, const knot_rrset_t *rrs) +{ + if (cmp == 3) { + return true; + } + if (cmp != 2) { + return false; + } + const uint8_t *bm = knot_nsec_bitmap(rrs->rrs.rdata); + uint16_t bm_size = knot_nsec_bitmap_len(rrs->rrs.rdata); + return kr_nsec_children_in_zone_check(bm, bm_size) != 0; +} + +int nsec1_src_synth(struct key *k, struct answer *ans, const knot_dname_t *clencl_name, + knot_db_val_t cover_low_kwz, knot_db_val_t cover_hi_kwz, + const struct kr_query *qry, struct kr_cache *cache) +{ + /* Construct key for the source of synthesis. */ + knot_db_val_t key = key_NSEC1(k, clencl_name, true); + const size_t nwz_off = key_nwz_off(k); + if (kr_fails_assert(key.data && key.len >= nwz_off)) + return kr_error(1); + /* Check if our sname-covering NSEC also covers/matches SS. */ + knot_db_val_t kwz = { + .data = (uint8_t *)key.data + nwz_off, + .len = key.len - nwz_off, + }; + if (kr_fails_assert((ssize_t)(kwz.len) >= 0)) + return kr_error(EINVAL); + const int cmp = kwz_between(cover_low_kwz, kwz, cover_hi_kwz); + if (nonexistence_ok(cmp, ans->rrsets[AR_NSEC].set.rr)) { + VERBOSE_MSG(qry, "=> NSEC wildcard: covered by the same RR\n"); + return AR_SOA; + } + const knot_rrset_t *nsec_rr = NULL; /**< the wildcard proof NSEC */ + bool exact_match; /**< whether it matches the source of synthesis */ + if (cmp == 1) { + exact_match = true; + nsec_rr = ans->rrsets[AR_NSEC].set.rr; + } else { + /* Try to find the NSEC for SS. */ + knot_db_val_t val = { NULL, 0 }; + knot_db_val_t wild_low_kwz = { NULL, 0 }; + uint32_t new_ttl; + const char *err = find_leq_NSEC1(cache, qry, key, k, &val, + &exact_match, &wild_low_kwz, NULL, &new_ttl); + if (err) { + VERBOSE_MSG(qry, "=> NSEC wildcard: %s\n", err); + return kr_ok(); + } + /* Materialize the record into answer (speculatively). */ + knot_dname_t owner[KNOT_DNAME_MAXLEN]; + int ret = dname_wire_reconstruct(owner, k, wild_low_kwz); + if (ret) return kr_error(ret); + const struct entry_h *nsec_eh = val.data; + ret = entry2answer(ans, AR_WILD, nsec_eh, knot_db_val_bound(val), + owner, KNOT_RRTYPE_NSEC, new_ttl); + if (ret) return kr_error(ret); + nsec_rr = ans->rrsets[AR_WILD].set.rr; + } + + if (kr_fails_assert(nsec_rr)) + return kr_error(EFAULT); + const uint8_t *bm = knot_nsec_bitmap(nsec_rr->rrs.rdata); + uint16_t bm_size = knot_nsec_bitmap_len(nsec_rr->rrs.rdata); + int ret; + struct answer_rrset * const arw = &ans->rrsets[AR_WILD]; + if (kr_fails_assert(bm)) { + ret = kr_error(EFAULT); + goto clean_wild; + } + if (!exact_match) { + /* Finish verification that the source of synthesis doesn't exist. */ + const int nsec_matched = + knot_dname_matched_labels(nsec_rr->owner, clencl_name); + /* we don't need to use the full source of synthesis ^ */ + const bool is_sub = + nsec_matched == knot_dname_labels(nsec_rr->owner, NULL); + if (is_sub && kr_nsec_children_in_zone_check(bm, bm_size) != 0) { + VERBOSE_MSG(qry, + "=> NSEC wildcard: covered but delegated (or error)\n"); + ret = kr_ok(); + goto clean_wild; + } + /* We have a record proving wildcard non-existence. */ + WITH_VERBOSE(qry) { + auto_free char *owner_str = kr_dname_text(nsec_rr->owner), + *next_str = kr_dname_text(knot_nsec_next(nsec_rr->rrs.rdata)); + VERBOSE_MSG(qry, "=> NSEC wildcard: covered by: %s -> %s, new TTL %d\n", + owner_str, next_str, nsec_rr->ttl); + } + return AR_SOA; + } + + /* The wildcard exists. Find if it's NODATA - check type bitmap. */ + if (kr_nsec_bitmap_nodata_check(bm, bm_size, qry->stype, nsec_rr->owner) == 0) { + /* NODATA proven; just need to add SOA+RRSIG later */ + WITH_VERBOSE(qry) { + const char *msg_start = "=> NSEC wildcard: match proved NODATA"; + if (arw->set.rr) { + auto_free char *owner_str = kr_dname_text(nsec_rr->owner); + VERBOSE_MSG(qry, "%s: %s, new TTL %d\n", + msg_start, owner_str, nsec_rr->ttl); + } else { + /* don't repeat the RR if it's the same */ + VERBOSE_MSG(qry, "%s, by the same RR\n", msg_start); + } + } + ans->rcode = PKT_NODATA; + return AR_SOA; + + } /* else */ + /* The data probably exists -> don't add this NSEC + * and (later) try to find the real wildcard data */ + VERBOSE_MSG(qry, "=> NSEC wildcard: should exist (or error)\n"); + ans->rcode = PKT_NOERROR; + ret = kr_ok(); +clean_wild: + if (arw->set.rr) { /* we may have matched AR_NSEC */ + knot_rrset_free(arw->set.rr, ans->mm); + arw->set.rr = NULL; + knot_rdataset_clear(&arw->sig_rds, ans->mm); + } + return ret; +} + |