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/* Copyright (C) 2018 CZ.NIC, z.s.p.o. <knot-dns@labs.nic.cz>
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <https://www.gnu.org/licenses/>.
*/
/** @file
* Implementation of NSEC3 handling. Prototypes in ./impl.h
*/
#include "lib/cache/impl.h"
#include "contrib/base32hex.h"
#include "lib/dnssec/nsec.h"
#include "lib/layer/iterate.h"
#include <libknot/rrtype/nsec3.h>
static const knot_db_val_t VAL_EMPTY = { NULL, 0 };
/** Common part: write all but the NSEC3 hash. */
static knot_db_val_t key_NSEC3_common(struct key *k, const knot_dname_t *zname,
const nsec_p_hash_t nsec_p_hash)
{
int ret;
const bool ok = k && zname
&& !(ret = kr_dname_lf(k->buf, zname, false));
if (!ok) {
assert(false);
return VAL_EMPTY;
}
/* CACHE_KEY_DEF: key == zone's dname_lf + '\0' + '3' + nsec_p hash (4B)
* + NSEC3 hash (20B == NSEC3_HASH_LEN binary!)
* LATER(optim.) nsec_p hash: perhaps 2B would give a sufficient probability
* of avoiding collisions.
*/
uint8_t *begin = k->buf + 1 + k->zlf_len; /* one byte after zone's zero */
begin[0] = 0;
begin[1] = '3'; /* tag for NSEC3 */
k->type = KNOT_RRTYPE_NSEC3;
memcpy(begin + 2, &nsec_p_hash, sizeof(nsec_p_hash));
return (knot_db_val_t){
.data = k->buf + 1,
.len = begin + 2 + sizeof(nsec_p_hash) - (k->buf + 1),
};
}
knot_db_val_t key_NSEC3(struct key *k, const knot_dname_t *nsec3_name,
const nsec_p_hash_t nsec_p_hash)
{
knot_db_val_t val = key_NSEC3_common(k, nsec3_name /*only zname required*/,
nsec_p_hash);
if (!val.data) return val;
int len = base32hex_decode(nsec3_name + 1, nsec3_name[0],
knot_db_val_bound(val), KR_CACHE_KEY_MAXLEN - val.len);
if (len != NSEC3_HASH_LEN) {
return VAL_EMPTY;
}
val.len += len;
return val;
}
/** Construct a string key for for NSEC3 predecessor-search, from an non-NSEC3 name.
* \note k->zlf_len and k->zname are assumed to have been correctly set */
static knot_db_val_t key_NSEC3_name(struct key *k, const knot_dname_t *name,
const bool add_wildcard, const struct nsec_p *nsec_p)
{
bool ok = k && name && nsec_p && nsec_p->raw;
if (!ok) return VAL_EMPTY;
knot_db_val_t val = key_NSEC3_common(k, k->zname, nsec_p->hash);
if (!val.data) return val;
/* Make `name` point to correctly wildcarded owner name. */
uint8_t buf[KNOT_DNAME_MAXLEN];
int name_len;
if (add_wildcard) {
buf[0] = '\1';
buf[1] = '*';
name_len = knot_dname_to_wire(buf + 2, name, sizeof(buf) - 2);
if (name_len < 0) return VAL_EMPTY; /* wants wildcard but doesn't fit */
name = buf;
name_len += 2;
} else {
name_len = knot_dname_size(name);
}
/* Append the NSEC3 hash. */
const dnssec_binary_t dname = {
.size = name_len,
.data = (uint8_t *)/*const-cast*/name,
};
#if 0 // LATER(optim.): this requires a patched libdnssec - tries to realloc()
dnssec_binary_t hash = {
.size = KR_CACHE_KEY_MAXLEN - val.len,
.data = val.data + val.len,
};
int ret = dnssec_nsec3_hash(&dname, &nsec_p->libknot, &hash);
if (ret != DNSSEC_EOK) return VAL_EMPTY;
assert(hash.size == NSEC3_HASH_LEN);
#else
dnssec_binary_t hash = { .size = 0, .data = NULL };
int ret = dnssec_nsec3_hash(&dname, &nsec_p->libknot, &hash);
if (ret != DNSSEC_EOK) return VAL_EMPTY;
if (hash.size != NSEC3_HASH_LEN || !hash.data) {
assert(false);
return VAL_EMPTY;
}
memcpy(knot_db_val_bound(val), hash.data, NSEC3_HASH_LEN);
free(hash.data);
#endif
val.len += hash.size;
return val;
}
/** Return h1 < h2, semantically on NSEC3 hashes. */
static inline bool nsec3_hash_ordered(const uint8_t *h1, const uint8_t *h2)
{
return memcmp(h1, h2, NSEC3_HASH_LEN) < 0;
}
/** NSEC3 range search.
*
* \param key Pass output of key_NSEC3(k, ...)
* \param nsec_p Restrict to this NSEC3 parameter-set.
* \param value[out] The raw data of the NSEC3 cache record (optional; consistency checked).
* \param exact_match[out] Whether the key was matched exactly or just covered (optional).
* \param hash_low[out] Output the low end hash of covering NSEC3, pointing within DB (optional).
* \param new_ttl[out] New TTL of the NSEC3 (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_NSEC3(struct kr_cache *cache, const struct kr_query *qry,
const knot_db_val_t key, const struct key *k, const struct nsec_p *nsec_p,
knot_db_val_t *value, bool *exact_match, const uint8_t **hash_low,
uint32_t *new_ttl)
{
/* Do the cache operation. */
const size_t hash_off = key_nsec3_hash_off(k);
if (!key.data || key.len < hash_off) {
assert(false);
return "range search ERROR";
}
knot_db_val_t key_found = key;
knot_db_val_t val = { NULL, 0 };
int ret = cache_op(cache, read_leq, &key_found, &val);
/* ^^ LATER(optim.): incrementing key and doing less-than search
* would probably be slightly more efficient with LMDB,
* but the code complexity would grow considerably. */
if (ret < 0) {
if (ret == kr_error(ENOENT)) {
return "range search miss";
} else {
assert(false);
return "range search ERROR";
}
}
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 NSEC3 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. */
int32_t new_ttl_ = get_new_ttl(eh, qry, k->zname, KNOT_RRTYPE_NSEC3,
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 (hash_low) {
*hash_low = (uint8_t *)key_found.data + hash_off;
}
if (is_exact) {
/* Nothing else to do. */
return NULL;
}
/* The NSEC3 starts strictly before our target name;
* now check that it still belongs into that zone and chain. */
const uint8_t *nsec_p_raw = eh->data + KR_CACHE_RR_COUNT_SIZE
+ 2 /* RDLENGTH from rfc1034 */;
const int nsec_p_len = nsec_p_rdlen(nsec_p_raw);
const bool same_chain = key_found.len == hash_off + NSEC3_HASH_LEN
/* CACHE_KEY_DEF */
&& memcmp(key.data, key_found.data, hash_off) == 0
/* exact comparison of NSEC3 parameters */
&& nsec_p_len == nsec_p_rdlen(nsec_p->raw)
&& memcmp(nsec_p_raw, nsec_p->raw, nsec_p_len) == 0;
if (!same_chain) {
return "range search miss (!same_chain)";
}
/* We know it starts before sname, so let's check the other end.
* A. find the next hash and check its length. */
if (KR_CACHE_RR_COUNT_SIZE != 2 || get_uint16(eh->data) == 0) {
assert(false);
return "ERROR";
/* TODO: more checks? Also, `next` computation is kinda messy. */
}
const uint8_t *hash_next = nsec_p_raw + nsec_p_len
+ sizeof(uint8_t) /* hash length from rfc5155 */;
if (hash_next[-1] != NSEC3_HASH_LEN) {
return "unexpected next hash length";
}
/* B. do the actual range check. */
const uint8_t * const hash_searched = (uint8_t *)key.data + hash_off;
bool covers = /* we know for sure that the low end is before the searched name */
nsec3_hash_ordered(hash_searched, hash_next)
/* and the wrap-around case */
|| nsec3_hash_ordered(hash_next, (const uint8_t *)key_found.data + hash_off);
if (!covers) {
return "range search miss (!covers)";
}
return NULL;
}
/** Extract textual representation of NSEC3 hash from a cache key.
* \param text must have length at least NSEC3_HASH_TXT_LEN+1 (will get 0-terminated). */
static void key_NSEC3_hash2text(const knot_db_val_t key, char *text)
{
assert(key.data && key.len > NSEC3_HASH_LEN);
const uint8_t *hash_raw = knot_db_val_bound(key) - NSEC3_HASH_LEN;
/* CACHE_KEY_DEF ^^ */
int len = base32hex_encode(hash_raw, NSEC3_HASH_LEN, (uint8_t *)text,
NSEC3_HASH_TXT_LEN);
assert(len == NSEC3_HASH_TXT_LEN); (void)len;
text[NSEC3_HASH_TXT_LEN] = '\0';
}
/** 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 knot_dname_t *zname,
const uint8_t *hash_raw)
{
int len = base32hex_encode(hash_raw, NSEC3_HASH_LEN, buf + 1, NSEC3_HASH_TXT_LEN);
if (len != NSEC3_HASH_TXT_LEN) {
assert(false);
return kr_error(EINVAL);
}
buf[0] = len;
int ret = knot_dname_to_wire(buf + 1 + len, zname, KNOT_DNAME_MAXLEN - 1 - len);
return ret < 0 ? kr_error(ret) : kr_ok();
}
static void nsec3_hash2text(const knot_dname_t *owner, char *text)
{
assert(owner[0] == NSEC3_HASH_TXT_LEN);
memcpy(text, owner + 1, MIN(owner[0], NSEC3_HASH_TXT_LEN));
text[NSEC3_HASH_TXT_LEN] = '\0';
}
int nsec3_encloser(struct key *k, struct answer *ans,
const int sname_labels, int *clencl_labels,
const struct kr_query *qry, struct kr_cache *cache)
{
static const int ESKIP = ABS(ENOENT);
/* Basic sanity check. */
const bool ok = k && k->zname && ans && clencl_labels
&& qry && cache;
if (!ok) {
assert(!EINVAL);
return kr_error(EINVAL);
}
/*** Find the closest encloser - cycle: name starting at sname,
* proceeding while longer than zname, shortening by one label on step.
* We need a pair where a name doesn't exist *and* its parent does. */
/* LATER(optim.): perhaps iterate in the other order - that
* should help significantly against deep queries where we have
* a shallow proof in the cache. We can also optimize by using
* only exact search unless we had a match in the previous iteration. */
const int zname_labels = knot_dname_labels(k->zname, NULL);
int last_nxproven_labels = -1;
const knot_dname_t *name = qry->sname;
for (int name_labels = sname_labels; name_labels >= zname_labels;
--name_labels, name += 1 + name[0]) {
/* Find a previous-or-equal NSEC3 in cache covering the name,
* checking TTL etc. */
const knot_db_val_t key = key_NSEC3_name(k, name, false, &ans->nsec_p);
if (!key.data) continue;
WITH_VERBOSE(qry) {
char hash_txt[NSEC3_HASH_TXT_LEN + 1];
key_NSEC3_hash2text(key, hash_txt);
VERBOSE_MSG(qry, "=> NSEC3 depth %d: hash %s\n",
name_labels - zname_labels, hash_txt);
}
knot_db_val_t val = { NULL, 0 };
bool exact_match;
uint32_t new_ttl;
const uint8_t *hash_low;
const char *err = find_leq_NSEC3(cache, qry, key, k, &ans->nsec_p, &val,
&exact_match, &hash_low, &new_ttl);
if (err) {
WITH_VERBOSE(qry) {
auto_free char *name_str = kr_dname_text(name);
VERBOSE_MSG(qry, "=> NSEC3 encloser error for %s: %s\n",
name_str, err);
}
continue;
}
if (exact_match && name_labels != sname_labels
&& name_labels + 1 != last_nxproven_labels) {
/* This name exists (checked rank and TTL), and it's
* neither of the two interesting cases, so we do not
* keep searching for non-existence above this name. */
VERBOSE_MSG(qry,
"=> NSEC3 encloser: only found existence of an ancestor\n");
return ESKIP;
}
/* Optimization: avoid the rest of the last iteration if pointless. */
if (!exact_match && name_labels == zname_labels
&& last_nxproven_labels != name_labels + 1) {
break;
}
/* Basic checks OK -> materialize data, cleaning any previous
* records on that answer index (unsuccessful attempts). */
knot_dname_t owner[KNOT_DNAME_MAXLEN];
{
int ret = dname_wire_reconstruct(owner, k->zname, hash_low);
if (unlikely(ret)) continue;
}
const int ans_id = (exact_match && name_labels + 1 == last_nxproven_labels)
? AR_CPE : AR_NSEC;
{
const struct entry_h *nsec_eh = val.data;
memset(&ans->rrsets[ans_id], 0, sizeof(ans->rrsets[ans_id]));
int ret = entry2answer(ans, ans_id, nsec_eh, knot_db_val_bound(val),
owner, KNOT_RRTYPE_NSEC3, new_ttl);
if (ret) return kr_error(ret);
}
if (!exact_match) {
/* Non-existence proven, but we don't know if `name`
* is the next closer name.
* Note: we don't need to check for the sname being
* delegated away by this record, as with NSEC3 only
* *exact* match on an ancestor could do that. */
last_nxproven_labels = name_labels;
WITH_VERBOSE(qry) {
char hash_low_txt[NSEC3_HASH_TXT_LEN + 1];
nsec3_hash2text(owner, hash_low_txt);
VERBOSE_MSG(qry,
"=> NSEC3 depth %d: covered by %s -> TODO, new TTL %d\n",
name_labels - zname_labels, hash_low_txt, new_ttl);
}
continue;
}
/* Exactly matched NSEC3: two cases, one after another. */
const knot_rrset_t *nsec_rr = ans->rrsets[ans_id].set.rr;
const uint8_t *bm = knot_nsec3_bitmap(nsec_rr->rrs.rdata);
uint16_t bm_size = knot_nsec3_bitmap_len(nsec_rr->rrs.rdata);
assert(bm);
if (name_labels == sname_labels) {
if (kr_nsec_bitmap_nodata_check(bm, bm_size, qry->stype,
nsec_rr->owner) != 0) {
VERBOSE_MSG(qry,
"=> NSEC3 sname: match but failed type check\n");
return ESKIP;
}
/* NODATA proven; just need to add SOA+RRSIG later */
VERBOSE_MSG(qry,
"=> NSEC3 sname: match proved NODATA, new TTL %d\n",
new_ttl);
ans->rcode = PKT_NODATA;
return kr_ok();
} /* else */
assert(name_labels + 1 == last_nxproven_labels);
if (kr_nsec_children_in_zone_check(bm, bm_size) != 0) {
VERBOSE_MSG(qry,
"=> NSEC3 encloser: found but delegated (or error)\n");
return ESKIP;
}
/* NXDOMAIN proven *except* for wildcards. */
WITH_VERBOSE(qry) {
auto_free char *name_str = kr_dname_text(name);
VERBOSE_MSG(qry,
"=> NSEC3 encloser: confirmed as %s, new TTL %d\n",
name_str, new_ttl);
}
*clencl_labels = name_labels;
ans->rcode = PKT_NXDOMAIN;
/* Avoid repeated NSEC3 - remove either if the hashes match.
* This is very unlikely in larger zones: 1/size (per attempt).
* Well, deduplication would happen anyway when the answer
* from cache is read by kresd (internally). */
if (unlikely(0 == memcmp(ans->rrsets[AR_NSEC].set.rr->owner + 1,
ans->rrsets[AR_CPE ].set.rr->owner + 1,
NSEC3_HASH_LEN))) {
memset(&ans->rrsets[AR_CPE], 0, sizeof(ans->rrsets[AR_CPE]));
/* LATER(optim.): perhaps check this earlier and avoid some work? */
}
return kr_ok();
}
/* We've ran out of options. */
if (last_nxproven_labels > 0) {
/* We didn't manage to prove existence of the closest encloser,
* meaning the only chance left is a *positive* wildcard record. */
*clencl_labels = last_nxproven_labels - 1;
ans->rcode = PKT_NXDOMAIN;
/* FIXME: review */
}
return ESKIP;
}
int nsec3_src_synth(struct key *k, struct answer *ans, const knot_dname_t *clencl_name,
const struct kr_query *qry, struct kr_cache *cache)
{
/* Find a previous-or-equal NSEC3 in cache covering or matching
* the source of synthesis, checking TTL etc. */
const knot_db_val_t key = key_NSEC3_name(k, clencl_name, true, &ans->nsec_p);
if (!key.data) return kr_error(1);
WITH_VERBOSE(qry) {
char hash_txt[NSEC3_HASH_TXT_LEN + 1];
key_NSEC3_hash2text(key, hash_txt);
VERBOSE_MSG(qry, "=> NSEC3 wildcard: hash %s\n", hash_txt);
}
knot_db_val_t val = { NULL, 0 };
bool exact_match;
uint32_t new_ttl;
const uint8_t *hash_low;
const char *err = find_leq_NSEC3(cache, qry, key, k, &ans->nsec_p, &val,
&exact_match, &hash_low, &new_ttl);
if (err) {
VERBOSE_MSG(qry, "=> NSEC3 wildcard: %s\n", err);
return kr_ok();
}
/* LATER(optim.): avoid duplicities in answer. */
/* Basic checks OK -> materialize the data (speculatively). */
knot_dname_t owner[KNOT_DNAME_MAXLEN];
{
int ret = dname_wire_reconstruct(owner, k->zname, hash_low);
if (unlikely(ret)) return kr_ok();
const struct entry_h *nsec_eh = val.data;
ret = entry2answer(ans, AR_WILD, nsec_eh, knot_db_val_bound(val),
owner, KNOT_RRTYPE_NSEC3, new_ttl);
if (ret) return kr_error(ret);
}
const knot_rrset_t *nsec_rr = ans->rrsets[AR_WILD].set.rr;
if (!exact_match) {
/* The record proves wildcard non-existence. */
WITH_VERBOSE(qry) {
char hash_low_txt[NSEC3_HASH_TXT_LEN + 1];
nsec3_hash2text(owner, hash_low_txt);
VERBOSE_MSG(qry,
"=> NSEC3 wildcard: covered by %s -> TODO, new TTL %d\n",
hash_low_txt, new_ttl);
}
return AR_SOA;
}
/* The wildcard exists. Find if it's NODATA - check type bitmap. */
const uint8_t *bm = knot_nsec3_bitmap(nsec_rr->rrs.rdata);
uint16_t bm_size = knot_nsec3_bitmap_len(nsec_rr->rrs.rdata);
assert(bm);
if (kr_nsec_bitmap_nodata_check(bm, bm_size, qry->stype, nsec_rr->owner) == 0) {
/* NODATA proven; just need to add SOA+RRSIG later */
VERBOSE_MSG(qry, "=> NSEC3 wildcard: match proved NODATA, new TTL %d\n",
new_ttl);
ans->rcode = PKT_NODATA;
return AR_SOA;
} /* else */
/* The data probably exists -> don't add this NSEC3
* and (later) try to find the real wildcard data */
VERBOSE_MSG(qry, "=> NSEC3 wildcard: should exist (or error)\n");
ans->rcode = PKT_NOERROR;
memset(&ans->rrsets[AR_WILD], 0, sizeof(ans->rrsets[AR_WILD]));
return kr_ok();
}
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