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|
/* Copyright (C) CZ.NIC, z.s.p.o. <knot-resolver@labs.nic.cz>
* SPDX-License-Identifier: GPL-3.0-or-later
*/
#include <errno.h>
#include <limits.h>
#include <sys/stat.h>
#include <sys/time.h>
#include <time.h>
#include <unistd.h>
#include <libknot/descriptor.h>
#include <libknot/dname.h>
#include <libknot/errcode.h>
#include <libknot/rrtype/rrsig.h>
#include <uv.h>
#include "contrib/base32hex.h"
#include "contrib/cleanup.h"
#include "contrib/ucw/lib.h"
#include "lib/cache/api.h"
#include "lib/cache/cdb_lmdb.h"
#include "lib/defines.h"
#include "lib/dnssec/nsec3.h"
#include "lib/generic/trie.h"
#include "lib/resolve.h"
#include "lib/rplan.h"
#include "lib/utils.h"
#include "lib/cache/impl.h"
/* TODO:
* - Reconsider when RRSIGs are put in and retrieved from the cache.
* Currently it's always done, which _might_ be spurious, depending
* on how kresd will use the returned result.
* There's also the "problem" that kresd ATM does _not_ ask upstream
* with DO bit in some cases.
*/
/** Cache version */
static const uint16_t CACHE_VERSION = 7;
/** Key size */
#define KEY_HSIZE (sizeof(uint8_t) + sizeof(uint16_t))
#define KEY_SIZE (KEY_HSIZE + KNOT_DNAME_MAXLEN)
/** @internal Forward declarations of the implementation details
* \param needs_pkt[out] optionally set *needs_pkt = true;
* We do that when some RRset wasn't stashed to aggressive cache,
* even though it might have taken part in a successful DNSSEC proof:
* 1. any opt-out NSEC3, as they typically aren't much use aggressively anyway
* 2. some kinds of minimal NSEC* ranges, as they'd seem more trouble than worth:
* - extremely short range of covered names limits the benefits severely
* - the type-set is often a lie, either a working lie, e.g. CloudFlare's
* black lies, or even a non-working lie, e.g. DVE-2018-0003
* 3. some kinds of "weird" RRsets, to get at least some caching on them
*/
static ssize_t stash_rrset(struct kr_cache *cache, const struct kr_query *qry,
const knot_rrset_t *rr, const knot_rrset_t *rr_sigs, uint32_t timestamp,
uint8_t rank, trie_t *nsec_pmap, knot_mm_t *pool, bool *needs_pkt);
/** Preliminary checks before stash_rrset(). Don't call if returns <= 0. */
static int stash_rrset_precond(const knot_rrset_t *rr, const struct kr_query *qry/*logs*/);
/** @internal Ensure the cache version is right, possibly by clearing it. */
static int assert_right_version(struct kr_cache *cache)
{
/* Check cache ABI version. */
/* CACHE_KEY_DEF: to avoid collisions with kr_cache_match(). */
uint8_t key_str[4] = "VERS";
knot_db_val_t key = { .data = key_str, .len = sizeof(key_str) };
knot_db_val_t val = { NULL, 0 };
int ret = cache_op(cache, read, &key, &val, 1);
if (ret == 0 && val.len == sizeof(CACHE_VERSION)
&& memcmp(val.data, &CACHE_VERSION, sizeof(CACHE_VERSION)) == 0) {
ret = kr_ok();
} else {
int oldret = ret;
/* Version doesn't match or we were unable to read it, possibly because DB is empty.
* Recreate cache and write version key. */
ret = cache_op(cache, count);
if (ret != 0) { /* Log for non-empty cache to limit noise on fresh start. */
kr_log_info(CACHE, "incompatible cache database detected, purging\n");
if (oldret) {
kr_log_debug(CACHE, "reading version returned: %d\n", oldret);
} else if (val.len != sizeof(CACHE_VERSION)) {
kr_log_debug(CACHE, "version has bad length: %d\n", (int)val.len);
} else {
uint16_t ver;
memcpy(&ver, val.data, sizeof(ver));
kr_log_debug(CACHE, "version has bad value: %d instead of %d\n",
(int)ver, (int)CACHE_VERSION);
}
}
ret = cache_op(cache, clear);
}
/* Rewrite the entry even if it isn't needed. Because of cache-size-changing
* possibility it's good to always perform some write during opening of cache. */
if (ret == 0) {
/* Key/Val is invalidated by cache purge, recreate it */
val.data = /*const-cast*/(void *)&CACHE_VERSION;
val.len = sizeof(CACHE_VERSION);
ret = cache_op(cache, write, &key, &val, 1);
}
kr_cache_commit(cache);
return ret;
}
int kr_cache_open(struct kr_cache *cache, const struct kr_cdb_api *api, struct kr_cdb_opts *opts, knot_mm_t *mm)
{
if (kr_fails_assert(cache))
return kr_error(EINVAL);
memset(cache, 0, sizeof(*cache));
/* Open cache */
if (!api)
api = kr_cdb_lmdb();
cache->api = api;
int ret = cache->api->open(&cache->db, &cache->stats, opts, mm);
if (ret == 0) {
ret = assert_right_version(cache);
// The included write also committed maxsize increase to the file.
}
if (ret == 0 && opts->maxsize) {
/* If some maxsize is requested and it's smaller than in-file maxsize,
* LMDB only restricts our env without changing the in-file maxsize.
* That is worked around by reopening (found no other reliable way). */
cache->api->close(cache->db, &cache->stats);
struct kr_cdb_opts opts2;
memcpy(&opts2, opts, sizeof(opts2));
opts2.maxsize = 0;
ret = cache->api->open(&cache->db, &cache->stats, &opts2, mm);
}
char *fpath = kr_absolutize_path(opts->path, "data.mdb");
if (kr_fails_assert(fpath)) {
/* non-critical, but still */
fpath = "<ENOMEM>";
} else {
kr_cache_emergency_file_to_remove = fpath;
}
if (ret == 0 && opts->maxsize) {
size_t maxsize = cache->api->get_maxsize(cache->db);
if (maxsize > opts->maxsize) kr_log_warning(CACHE,
"Warning: real cache size is %zu instead of the requested %zu bytes."
" To reduce the size you need to remove the file '%s' by hand.\n",
maxsize, opts->maxsize, fpath);
}
if (ret != 0)
return ret;
cache->ttl_min = KR_CACHE_DEFAULT_TTL_MIN;
cache->ttl_max = KR_CACHE_DEFAULT_TTL_MAX;
kr_cache_make_checkpoint(cache);
return 0;
}
const char *kr_cache_emergency_file_to_remove = NULL;
#define cache_isvalid(cache) ((cache) && (cache)->api && (cache)->db)
void kr_cache_close(struct kr_cache *cache)
{
kr_cache_check_health(cache, -1);
if (cache_isvalid(cache)) {
cache_op(cache, close);
cache->db = NULL;
}
free(/*const-cast*/(char*)kr_cache_emergency_file_to_remove);
kr_cache_emergency_file_to_remove = NULL;
}
int kr_cache_commit(struct kr_cache *cache)
{
if (!cache_isvalid(cache)) {
return kr_error(EINVAL);
}
if (cache->api->commit) {
return cache_op(cache, commit);
}
return kr_ok();
}
int kr_cache_clear(struct kr_cache *cache)
{
if (!cache_isvalid(cache)) {
return kr_error(EINVAL);
}
int ret = cache_op(cache, clear);
if (ret == 0) {
kr_cache_make_checkpoint(cache);
ret = assert_right_version(cache);
}
return ret;
}
/* When going stricter, BEWARE of breaking entry_h_consistent_NSEC() */
struct entry_h * entry_h_consistent_E(knot_db_val_t data, uint16_t type)
{
(void) type; /* unused, for now */
if (!data.data) return NULL;
/* Length checks. */
if (data.len < offsetof(struct entry_h, data))
return NULL;
const struct entry_h *eh = data.data;
if (eh->is_packet) {
uint16_t pkt_len;
if (data.len < offsetof(struct entry_h, data) + sizeof(pkt_len)) {
return NULL;
}
memcpy(&pkt_len, eh->data, sizeof(pkt_len));
if (data.len < offsetof(struct entry_h, data) + sizeof(pkt_len)
+ pkt_len) {
return NULL;
}
}
bool ok = true;
ok = ok && kr_rank_check(eh->rank);
ok = ok && (!kr_rank_test(eh->rank, KR_RANK_BOGUS)
|| eh->is_packet);
ok = ok && (eh->is_packet || !eh->has_optout);
return ok ? /*const-cast*/(struct entry_h *)eh : NULL;
}
int32_t get_new_ttl(const struct entry_h *entry, const struct kr_query *qry,
const knot_dname_t *owner, uint16_t type, uint32_t now)
{
int32_t diff = now - entry->time;
if (diff < 0) {
/* We may have obtained the record *after* the request started. */
diff = 0;
}
int32_t res = entry->ttl - diff;
if (res < 0 && owner && qry && qry->stale_cb) {
/* Stale-serving decision, delegated to a callback. */
int res_stale = qry->stale_cb(res, owner, type, qry);
if (res_stale >= 0) {
VERBOSE_MSG(qry, "responding with stale answer\n");
/* LATER: Perhaps we could use a more specific Stale
* NXDOMAIN Answer code for applicable responses. */
kr_request_set_extended_error(qry->request, KNOT_EDNS_EDE_STALE, "6Q6X");
return res_stale;
}
}
return res;
}
int32_t kr_cache_ttl(const struct kr_cache_p *peek, const struct kr_query *qry,
const knot_dname_t *name, uint16_t type)
{
const struct entry_h *eh = peek->raw_data;
return get_new_ttl(eh, qry, name, type, qry->timestamp.tv_sec);
}
/** Check that no label contains a zero character, incl. a log trace.
*
* We refuse to work with those, as LF and our cache keys might become ambiguous.
* Assuming uncompressed name, as usual.
* CACHE_KEY_DEF
*/
static bool check_dname_for_lf(const knot_dname_t *n, const struct kr_query *qry/*logging*/)
{
const bool ret = knot_dname_size(n) == strlen((const char *)n) + 1;
if (!ret && kr_log_is_debug_qry(CACHE, qry)) {
auto_free char *n_str = kr_dname_text(n);
VERBOSE_MSG(qry, "=> skipping zero-containing name %s\n", n_str);
}
return ret;
}
/** Return false on types to be ignored. Meant both for sname and direct cache requests. */
static bool check_rrtype(uint16_t type, const struct kr_query *qry/*logging*/)
{
const bool ret = !knot_rrtype_is_metatype(type)
&& type != KNOT_RRTYPE_RRSIG;
if (!ret && kr_log_is_debug_qry(CACHE, qry)) {
auto_free char *type_str = kr_rrtype_text(type);
VERBOSE_MSG(qry, "=> skipping RR type %s\n", type_str);
}
return ret;
}
/** Like key_exact_type() but omits a couple checks not holding for pkt cache. */
knot_db_val_t key_exact_type_maypkt(struct key *k, uint16_t type)
{
if (kr_fails_assert(check_rrtype(type, NULL)))
return (knot_db_val_t){ NULL, 0 };
switch (type) {
case KNOT_RRTYPE_RRSIG: /* no RRSIG query caching, at least for now */
kr_assert(false);
return (knot_db_val_t){ NULL, 0 };
/* xNAME lumped into NS. */
case KNOT_RRTYPE_CNAME:
case KNOT_RRTYPE_DNAME:
type = KNOT_RRTYPE_NS;
default:
break;
}
int name_len = k->buf[0];
k->buf[name_len + 1] = 0; /* make sure different names can never match */
k->buf[name_len + 2] = 'E'; /* tag for exact name+type matches */
memcpy(k->buf + name_len + 3, &type, 2);
k->type = type;
/* CACHE_KEY_DEF: key == dname_lf + '\0' + 'E' + RRTYPE */
return (knot_db_val_t){ k->buf + 1, name_len + 4 };
}
/** The inside for cache_peek(); implementation separated to ./peek.c */
int peek_nosync(kr_layer_t *ctx, knot_pkt_t *pkt);
/** function for .produce phase */
int cache_peek(kr_layer_t *ctx, knot_pkt_t *pkt)
{
struct kr_request *req = ctx->req;
struct kr_query *qry = req->current_query;
/* We first check various exit-conditions and then call the _real function. */
if (!kr_cache_is_open(&req->ctx->cache)
|| ctx->state & (KR_STATE_FAIL|KR_STATE_DONE) || qry->flags.NO_CACHE
|| (qry->flags.CACHE_TRIED && !qry->stale_cb)
|| !check_rrtype(qry->stype, qry) /* LATER: some other behavior for some of these? */
|| qry->sclass != KNOT_CLASS_IN) {
return ctx->state; /* Already resolved/failed or already tried, etc. */
}
/* ATM cache only peeks for qry->sname and that would be useless
* to repeat on every iteration, so disable it from now on.
* LATER(optim.): assist with more precise QNAME minimization. */
qry->flags.CACHE_TRIED = true;
if (qry->stype == KNOT_RRTYPE_NSEC) {
VERBOSE_MSG(qry, "=> skipping stype NSEC\n");
return ctx->state;
}
if (!check_dname_for_lf(qry->sname, qry)) {
return ctx->state;
}
int ret = peek_nosync(ctx, pkt);
kr_cache_commit(&req->ctx->cache);
return ret;
}
/** It's simply inside of cycle taken out to decrease indentation. \return error code. */
static int stash_rrarray_entry(ranked_rr_array_t *arr, int arr_i,
const struct kr_query *qry, struct kr_cache *cache,
int *unauth_cnt, trie_t *nsec_pmap, bool *needs_pkt);
/** Stash a single nsec_p. \return 0 (errors are ignored). */
static int stash_nsec_p(const knot_dname_t *dname, const char *nsec_p_v,
struct kr_cache *cache, uint32_t timestamp, knot_mm_t *pool,
const struct kr_query *qry/*logging*/);
/** The whole .consume phase for the cache module. */
int cache_stash(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;
/* Note: we cache even in KR_STATE_FAIL. For example,
* BOGUS answer can go to +cd cache even without +cd request. */
if (!kr_cache_is_open(cache) || !qry
|| qry->flags.CACHED || !check_rrtype(knot_pkt_qtype(pkt), qry)
|| qry->sclass != KNOT_CLASS_IN) {
return ctx->state;
}
/* Do not cache truncated answers, at least for now. LATER */
if (knot_wire_get_tc(pkt->wire)) {
return ctx->state;
}
int unauth_cnt = 0;
bool needs_pkt = false;
if (qry->flags.STUB) {
needs_pkt = true;
goto stash_packet;
}
/* Stash individual records. */
ranked_rr_array_t *selected[] = kr_request_selected(req);
trie_t *nsec_pmap = trie_create(&req->pool);
if (kr_fails_assert(nsec_pmap))
goto finally;
for (int psec = KNOT_ANSWER; psec <= KNOT_ADDITIONAL; ++psec) {
ranked_rr_array_t *arr = selected[psec];
/* uncached entries are located at the end */
for (ssize_t i = arr->len - 1; i >= 0; --i) {
ranked_rr_array_entry_t *entry = arr->at[i];
if (entry->qry_uid != qry->uid || entry->dont_cache) {
continue;
/* TODO: probably safe to break on uid mismatch but maybe not worth it */
}
int ret = stash_rrarray_entry(
arr, i, qry, cache, &unauth_cnt, nsec_pmap,
/* ADDITIONAL RRs are considered non-essential
* in our (resolver) answers */
(psec == KNOT_ADDITIONAL ? NULL : &needs_pkt));
if (ret) {
VERBOSE_MSG(qry, "=> stashing RRs errored out\n");
goto finally;
}
/* LATER(optim.): maybe filter out some type-rank combinations
* that won't be useful as separate RRsets. */
}
}
trie_it_t *it;
for (it = trie_it_begin(nsec_pmap); !trie_it_finished(it); trie_it_next(it)) {
stash_nsec_p((const knot_dname_t *)trie_it_key(it, NULL),
(const char *)*trie_it_val(it),
cache, qry->timestamp.tv_sec, &req->pool, req->current_query);
}
trie_it_free(it);
/* LATER(optim.): typically we also have corresponding NS record in the list,
* so we might save a cache operation. */
stash_packet:
if (qry->flags.PKT_IS_SANE && check_dname_for_lf(knot_pkt_qname(pkt), qry)) {
stash_pkt(pkt, qry, req, needs_pkt);
}
finally:
if (unauth_cnt) {
VERBOSE_MSG(qry, "=> stashed also %d nonauth RRsets\n", unauth_cnt);
};
kr_cache_commit(cache);
return ctx->state; /* we ignore cache-stashing errors */
}
/** Preliminary checks before stash_rrset(). Don't call if returns <= 0. */
static int stash_rrset_precond(const knot_rrset_t *rr, const struct kr_query *qry/*logs*/)
{
if (kr_fails_assert(rr && rr->rclass == KNOT_CLASS_IN))
return kr_error(EINVAL);
if (!check_rrtype(rr->type, qry))
return kr_ok();
if (!check_dname_for_lf(rr->owner, qry))
return kr_ok();
return 1/*proceed*/;
}
/** Return true on some cases of NSEC* RRsets covering minimal ranges.
* Also include some abnormal RR cases; qry is just for logging. */
static bool rrset_has_min_range_or_weird(const knot_rrset_t *rr, const struct kr_query *qry)
{
if (rr->rrs.count != 1) {
kr_assert(rr->rrs.count > 0);
if (rr->type == KNOT_RRTYPE_NSEC || rr->type == KNOT_RRTYPE_NSEC3
|| rr->rrs.count == 0) {
return true; /*< weird */
}
}
bool ret; /**< NOT used for the weird cases */
if (rr->type == KNOT_RRTYPE_NSEC) {
if (!check_dname_for_lf(rr->owner, qry))
return true; /*< weird, probably filtered even before this point */
ret = !check_dname_for_lf(knot_nsec_next(rr->rrs.rdata), qry);
/* ^^ Zero inside the next-name label means it's probably a minimal range,
* and anyway it's problematic for our aggressive cache (comparisons).
* Real-life examples covered:
* NSEC: name -> \000.name (e.g. typical foobar.CloudFlare.net)
* NSEC: name -> name\000 (CloudFlare on delegations)
*/
} else if (rr->type == KNOT_RRTYPE_NSEC3) {
if (knot_nsec3_next_len(rr->rrs.rdata) != NSEC3_HASH_LEN
|| *rr->owner != NSEC3_HASH_TXT_LEN) {
return true; /*< weird */
}
/* Let's work on the binary hashes. Find if they "differ by one",
* by constructing the owner hash incremented by one and comparing. */
uint8_t owner_hash[NSEC3_HASH_LEN];
if (base32hex_decode(rr->owner + 1, NSEC3_HASH_TXT_LEN,
owner_hash, NSEC3_HASH_LEN) != NSEC3_HASH_LEN) {
return true; /*< weird */
}
for (int i = NSEC3_HASH_LEN - 1; i >= 0; --i) {
if (++owner_hash[i] != 0) break;
}
const uint8_t *next_hash = knot_nsec3_next(rr->rrs.rdata);
ret = memcmp(owner_hash, next_hash, NSEC3_HASH_LEN) == 0;
} else {
return false;
}
if (ret) VERBOSE_MSG(qry, "=> minimized NSEC* range detected\n");
return ret;
}
static ssize_t stash_rrset(struct kr_cache *cache, const struct kr_query *qry,
const knot_rrset_t *rr, const knot_rrset_t *rr_sigs, uint32_t timestamp,
uint8_t rank, trie_t *nsec_pmap, knot_mm_t *pool, bool *needs_pkt)
{
if (kr_rank_test(rank, KR_RANK_BOGUS)) {
WITH_VERBOSE(qry) {
auto_free char *type_str = kr_rrtype_text(rr->type);
VERBOSE_MSG(qry, "=> skipping bogus RR set %s\n", type_str);
}
return kr_ok();
}
if (rr->type == KNOT_RRTYPE_NSEC3 && rr->rrs.count
&& kr_nsec3_limited_rdata(rr->rrs.rdata)) {
/* This shouldn't happen often, thanks to downgrades during validation. */
VERBOSE_MSG(qry, "=> skipping NSEC3 with too many iterations\n");
return kr_ok();
}
if (kr_fails_assert(cache && stash_rrset_precond(rr, qry) > 0))
return kr_error(EINVAL);
int ret = kr_ok();
if (rrset_has_min_range_or_weird(rr, qry))
goto return_needs_pkt;
const int wild_labels = rr_sigs == NULL ? 0 :
knot_dname_labels(rr->owner, NULL) - knot_rrsig_labels(rr_sigs->rrs.rdata);
if (wild_labels < 0)
goto return_needs_pkt;
const knot_dname_t *encloser = rr->owner; /**< the closest encloser name */
for (int i = 0; i < wild_labels; ++i) {
encloser = knot_dname_next_label(encloser);
}
/* Construct the key under which RRs will be stored,
* and add corresponding nsec_pmap item (if necessary). */
struct key k_storage, *k = &k_storage;
knot_db_val_t key;
switch (rr->type) {
case KNOT_RRTYPE_NSEC3:
/* Skip opt-out NSEC3 sets. */
if (KNOT_NSEC3_FLAG_OPT_OUT & knot_nsec3_flags(rr->rrs.rdata))
goto return_needs_pkt;
/* fall through */
case KNOT_RRTYPE_NSEC:
/* Skip any NSEC*s that aren't validated or are suspicious. */
if (!kr_rank_test(rank, KR_RANK_SECURE) || rr->rrs.count != 1)
goto return_needs_pkt;
if (kr_fails_assert(rr_sigs && rr_sigs->rrs.count && rr_sigs->rrs.rdata)) {
ret = kr_error(EINVAL);
goto return_needs_pkt;
}
const knot_dname_t *signer = knot_rrsig_signer_name(rr_sigs->rrs.rdata);
const int signer_size = knot_dname_size(signer);
k->zlf_len = signer_size - 1;
void **npp = NULL;
if (nsec_pmap) {
npp = trie_get_ins(nsec_pmap, (const char *)signer, signer_size);
if (kr_fails_assert(npp))
return kr_error(ENOMEM);
}
if (rr->type == KNOT_RRTYPE_NSEC) {
key = key_NSEC1(k, encloser, wild_labels);
break;
}
kr_require(rr->type == KNOT_RRTYPE_NSEC3);
const knot_rdata_t * const rdata = rr->rrs.rdata;
if (rdata->len <= 4) {
ret = kr_error(EILSEQ); /*< data from outside; less trust */
goto return_needs_pkt;
}
const int np_dlen = nsec_p_rdlen(rdata->data);
if (np_dlen > rdata->len) {
ret = kr_error(EILSEQ);
goto return_needs_pkt;
}
key = key_NSEC3(k, encloser, nsec_p_mkHash(rdata->data));
if (npp && !*npp) {
*npp = mm_alloc(pool, np_dlen);
if (kr_fails_assert(*npp))
break;
memcpy(*npp, rdata->data, np_dlen);
}
break;
default:
ret = kr_dname_lf(k->buf, encloser, wild_labels);
if (kr_fails_assert(ret == 0))
goto return_needs_pkt;
key = key_exact_type(k, rr->type);
}
/* Compute in-cache size for the new data. */
const knot_rdataset_t *rds_sigs = rr_sigs ? &rr_sigs->rrs : NULL;
const int rr_ssize = rdataset_dematerialize_size(&rr->rrs);
if (kr_fails_assert(rr_ssize == to_even(rr_ssize)))
return kr_error(EINVAL);
knot_db_val_t val_new_entry = {
.data = NULL,
.len = offsetof(struct entry_h, data) + rr_ssize
+ rdataset_dematerialize_size(rds_sigs),
};
/* Prepare raw memory for the new entry. */
ret = entry_h_splice(&val_new_entry, rank, key, k->type, rr->type,
rr->owner, qry, cache, timestamp);
if (ret) return kr_ok(); /* some aren't really errors */
if (kr_fails_assert(val_new_entry.data))
return kr_error(EFAULT);
/* Write the entry itself. */
struct entry_h *eh = val_new_entry.data;
memset(eh, 0, offsetof(struct entry_h, data));
eh->time = timestamp;
eh->ttl = rr->ttl;
eh->rank = rank;
rdataset_dematerialize(&rr->rrs, eh->data);
rdataset_dematerialize(rds_sigs, eh->data + rr_ssize);
if (kr_fails_assert(entry_h_consistent_E(val_new_entry, rr->type)))
return kr_error(EINVAL);
#if 0 /* Occasionally useful when debugging some kinds of changes. */
{
kr_cache_commit(cache);
knot_db_val_t val = { NULL, 0 };
ret = cache_op(cache, read, &key, &val, 1);
if (ret != kr_error(ENOENT)) { // ENOENT might happen in some edge case, I guess
kr_assert(!ret);
entry_list_t el;
entry_list_parse(val, el);
}
}
#endif
/* Verbose-log some not-too-common cases. */
WITH_VERBOSE(qry) { if (kr_rank_test(rank, KR_RANK_AUTH)
|| rr->type == KNOT_RRTYPE_NS) {
auto_free char *type_str = kr_rrtype_text(rr->type),
*encl_str = kr_dname_text(encloser);
VERBOSE_MSG(qry, "=> stashed %s%s %s, rank 0%.2o, "
"%d B total, incl. %d RRSIGs\n",
(wild_labels ? "*." : ""), encl_str, type_str, rank,
(int)val_new_entry.len, (rr_sigs ? rr_sigs->rrs.count : 0)
);
} }
return (ssize_t) val_new_entry.len;
return_needs_pkt:
if (needs_pkt) *needs_pkt = true;
return ret;
}
static int stash_rrarray_entry(ranked_rr_array_t *arr, int arr_i,
const struct kr_query *qry, struct kr_cache *cache,
int *unauth_cnt, trie_t *nsec_pmap, bool *needs_pkt)
{
ranked_rr_array_entry_t *entry = arr->at[arr_i];
if (entry->cached) {
return kr_ok();
}
const knot_rrset_t *rr = entry->rr;
if (rr->type == KNOT_RRTYPE_RRSIG) {
return kr_ok(); /* reduce verbose logging from the following call */
}
int ret = stash_rrset_precond(rr, qry);
if (ret <= 0) {
return ret;
}
/* Try to find corresponding signatures, always. LATER(optim.): speed. */
ranked_rr_array_entry_t *entry_rrsigs = NULL;
const knot_rrset_t *rr_sigs = NULL;
for (ssize_t j = arr->len - 1; j >= 0; --j) {
/* TODO: ATM we assume that some properties are the same
* for all RRSIGs in the set (esp. label count). */
ranked_rr_array_entry_t *e = arr->at[j];
if (kr_fails_assert(!e->in_progress))
return kr_error(EINVAL);
bool ok = e->qry_uid == qry->uid && !e->cached
&& e->rr->type == KNOT_RRTYPE_RRSIG
&& knot_rrsig_type_covered(e->rr->rrs.rdata) == rr->type
&& knot_dname_is_equal(rr->owner, e->rr->owner);
if (!ok) continue;
entry_rrsigs = e;
rr_sigs = e->rr;
break;
}
ssize_t written = stash_rrset(cache, qry, rr, rr_sigs, qry->timestamp.tv_sec,
entry->rank, nsec_pmap, &qry->request->pool, needs_pkt);
if (written < 0) {
kr_log_error(CACHE, "[%05u.%02u] stash failed, ret = %d\n", qry->request->uid,
qry->uid, ret);
return (int) written;
}
if (written > 0) {
/* Mark entry as cached for the rest of the query processing */
entry->cached = true;
if (entry_rrsigs) {
entry_rrsigs->cached = true;
}
if (!kr_rank_test(entry->rank, KR_RANK_AUTH) && rr->type != KNOT_RRTYPE_NS) {
*unauth_cnt += 1;
}
}
return kr_ok();
}
static int stash_nsec_p(const knot_dname_t *dname, const char *nsec_p_v,
struct kr_cache *cache, uint32_t timestamp, knot_mm_t *pool,
const struct kr_query *qry/*logging*/)
{
uint32_t valid_until = timestamp + cache->ttl_max;
/* LATER(optim.): be more precise here ^^ and reduce calls. */
static const int32_t ttl_margin = 3600;
const uint8_t *nsec_p = (const uint8_t *)nsec_p_v;
int data_stride = sizeof(valid_until) + nsec_p_rdlen(nsec_p);
unsigned int log_hash = 0xFeeeFeee; /* this type is simpler for printf args */
auto_free char *log_dname = NULL;
WITH_VERBOSE(qry) {
log_hash = nsec_p_v ? nsec_p_mkHash((const uint8_t *)nsec_p_v) : 0;
log_dname = kr_dname_text(dname);
}
/* Find what's in the cache. */
struct key k_storage, *k = &k_storage;
int ret = kr_dname_lf(k->buf, dname, false);
if (ret) return kr_error(ret);
knot_db_val_t key = key_exact_type(k, KNOT_RRTYPE_NS);
knot_db_val_t val_orig = { NULL, 0 };
ret = cache_op(cache, read, &key, &val_orig, 1);
if (ret && ret != -ABS(ENOENT)) {
VERBOSE_MSG(qry, "=> EL read failed (ret: %d)\n", ret);
return kr_ok();
}
/* Prepare new entry_list_t so we can just write at el[0]. */
entry_list_t el;
int log_refresh_by = 0;
if (ret == -ABS(ENOENT)) {
memset(el, 0, sizeof(el));
} else {
ret = entry_list_parse(val_orig, el);
if (ret) {
VERBOSE_MSG(qry, "=> EL parse failed (ret: %d)\n", ret);
return kr_error(0);
}
/* Find the index to replace. */
int i_replace = ENTRY_APEX_NSECS_CNT - 1;
for (int i = 0; i < ENTRY_APEX_NSECS_CNT; ++i) {
if (el[i].len != data_stride) continue;
if (nsec_p && memcmp(nsec_p, (uint8_t *)el[i].data + sizeof(uint32_t),
data_stride - sizeof(uint32_t)) != 0) {
continue;
}
/* Save a cache operation if TTL extended only a little. */
uint32_t valid_orig;
memcpy(&valid_orig, el[i].data, sizeof(valid_orig));
const int32_t ttl_extended_by = valid_until - valid_orig;
if (ttl_extended_by < ttl_margin) {
VERBOSE_MSG(qry,
"=> nsec_p stash for %s skipped (extra TTL: %d, hash: %x)\n",
log_dname, ttl_extended_by, log_hash);
return kr_ok();
}
i_replace = i;
log_refresh_by = ttl_extended_by;
break;
}
/* Shift the other indices: move the first `i_replace` blocks
* by one position. */
if (i_replace) {
memmove(&el[1], &el[0], sizeof(el[0]) * i_replace);
}
}
/* Prepare old data into a buffer. See entry_h_splice() for why. LATER(optim.) */
el[0].len = data_stride;
el[0].data = NULL;
knot_db_val_t val;
val.len = entry_list_serial_size(el),
val.data = mm_alloc(pool, val.len),
entry_list_memcpy(val.data, el);
/* Prepare the new data chunk */
memcpy(el[0].data, &valid_until, sizeof(valid_until));
if (nsec_p) {
memcpy((uint8_t *)el[0].data + sizeof(valid_until), nsec_p,
data_stride - sizeof(valid_until));
}
/* Write it all to the cache */
ret = cache_op(cache, write, &key, &val, 1);
mm_free(pool, val.data);
if (ret || !val.data) {
VERBOSE_MSG(qry, "=> EL write failed (ret: %d)\n", ret);
return kr_ok();
}
if (log_refresh_by) {
VERBOSE_MSG(qry, "=> nsec_p stashed for %s (refresh by %d, hash: %x)\n",
log_dname, log_refresh_by, log_hash);
} else {
VERBOSE_MSG(qry, "=> nsec_p stashed for %s (new, hash: %x)\n",
log_dname, log_hash);
}
return kr_ok();
}
int kr_cache_insert_rr(struct kr_cache *cache,
const knot_rrset_t *rr, const knot_rrset_t *rrsig,
uint8_t rank, uint32_t timestamp, bool ins_nsec_p)
{
int err = stash_rrset_precond(rr, NULL);
if (err <= 0) {
return kr_ok();
}
trie_t *nsec_pmap = NULL;
knot_mm_t *pool = NULL;
if (ins_nsec_p && (rr->type == KNOT_RRTYPE_NSEC || rr->type == KNOT_RRTYPE_NSEC3)) {
pool = mm_ctx_mempool2(4096);
nsec_pmap = trie_create(pool);
kr_assert(pool && nsec_pmap);
}
ssize_t written = stash_rrset(cache, NULL, rr, rrsig, timestamp, rank,
nsec_pmap, pool, NULL);
if (nsec_pmap) {
trie_it_t *it;
for (it = trie_it_begin(nsec_pmap); !trie_it_finished(it); trie_it_next(it)) {
stash_nsec_p((const knot_dname_t *)trie_it_key(it, NULL),
(const char *)*trie_it_val(it),
cache, timestamp, pool, NULL);
}
trie_it_free(it);
mm_ctx_delete(pool);
}
if (written >= 0) {
return kr_ok();
}
return (int) written;
}
static int peek_exact_real(struct kr_cache *cache, const knot_dname_t *name, uint16_t type,
struct kr_cache_p *peek)
{
if (!check_rrtype(type, NULL) || !check_dname_for_lf(name, NULL)) {
return kr_error(ENOTSUP);
}
struct key k_storage, *k = &k_storage;
int ret = kr_dname_lf(k->buf, name, false);
if (ret) return kr_error(ret);
knot_db_val_t key = key_exact_type(k, type);
knot_db_val_t val = { NULL, 0 };
ret = cache_op(cache, read, &key, &val, 1);
if (!ret) ret = entry_h_seek(&val, type);
if (ret) return kr_error(ret);
const struct entry_h *eh = entry_h_consistent_E(val, type);
if (!eh || eh->is_packet) {
// TODO: no packets, but better get rid of whole kr_cache_peek_exact().
return kr_error(ENOENT);
}
*peek = (struct kr_cache_p){
.time = eh->time,
.ttl = eh->ttl,
.rank = eh->rank,
.raw_data = val.data,
.raw_bound = knot_db_val_bound(val),
};
return kr_ok();
}
int kr_cache_peek_exact(struct kr_cache *cache, const knot_dname_t *name, uint16_t type,
struct kr_cache_p *peek)
{ /* Just wrap with extra verbose logging. */
const int ret = peek_exact_real(cache, name, type, peek);
if (false && kr_log_is_debug(CACHE, NULL)) { /* too noisy for usual --verbose */
auto_free char *type_str = kr_rrtype_text(type),
*name_str = kr_dname_text(name);
const char *result_str = (ret == kr_ok() ? "hit" :
(ret == kr_error(ENOENT) ? "miss" : "error"));
VERBOSE_MSG(NULL, "_peek_exact: %s %s %s (ret: %d)",
type_str, name_str, result_str, ret);
}
return ret;
}
int kr_cache_remove(struct kr_cache *cache, const knot_dname_t *name, uint16_t type)
{
if (!cache_isvalid(cache)) {
return kr_error(EINVAL);
}
if (!cache->api->remove) {
return kr_error(ENOSYS);
}
struct key k_storage, *k = &k_storage;
int ret = kr_dname_lf(k->buf, name, false);
if (ret) return kr_error(ret);
knot_db_val_t key = key_exact_type(k, type);
return cache_op(cache, remove, &key, 1);
}
int kr_cache_match(struct kr_cache *cache, const knot_dname_t *name,
bool exact_name, knot_db_val_t keyval[][2], int maxcount)
{
if (!cache_isvalid(cache)) {
return kr_error(EINVAL);
}
if (!cache->api->match) {
return kr_error(ENOSYS);
}
struct key k_storage, *k = &k_storage;
int ret = kr_dname_lf(k->buf, name, false);
if (ret) return kr_error(ret);
// use a mock type
knot_db_val_t key = key_exact_type(k, KNOT_RRTYPE_A);
/* CACHE_KEY_DEF */
key.len -= sizeof(uint16_t); /* the type */
if (!exact_name) {
key.len -= 2; /* '\0' 'E' */
if (name[0] == '\0') ++key.len; /* the root name is special ATM */
}
return cache_op(cache, match, &key, keyval, maxcount);
}
int kr_unpack_cache_key(knot_db_val_t key, knot_dname_t *buf, uint16_t *type)
{
if (key.data == NULL || buf == NULL || type == NULL) {
return kr_error(EINVAL);
}
int len = -1;
const char *tag, *key_data = key.data;
for (tag = key_data + 1; tag < key_data + key.len; ++tag) {
/* CACHE_KEY_DEF */
if (tag[-1] == '\0' && (tag == key_data + 1 || tag[-2] == '\0')) {
if (tag[0] != 'E') return kr_error(EINVAL);
len = tag - 1 - key_data;
break;
}
}
if (len == -1 || len > KNOT_DNAME_MAXLEN) {
return kr_error(EINVAL);
}
int ret = knot_dname_lf2wire(buf, len, key.data);
if (ret < 0) {
return kr_error(ret);
}
/* CACHE_KEY_DEF: jump over "\0 E/1" */
memcpy(type, tag + 1, sizeof(uint16_t));
return kr_ok();
}
int kr_cache_remove_subtree(struct kr_cache *cache, const knot_dname_t *name,
bool exact_name, int maxcount)
{
if (!cache_isvalid(cache)) {
return kr_error(EINVAL);
}
knot_db_val_t keyval[maxcount][2], keys[maxcount];
int ret = kr_cache_match(cache, name, exact_name, keyval, maxcount);
if (ret <= 0) { /* ENOENT -> nothing to remove */
return (ret == KNOT_ENOENT) ? 0 : ret;
}
const int count = ret;
/* Duplicate the key strings, as deletion may invalidate the pointers. */
int i;
for (i = 0; i < count; ++i) {
keys[i].len = keyval[i][0].len;
keys[i].data = malloc(keys[i].len);
if (!keys[i].data) {
ret = kr_error(ENOMEM);
goto cleanup;
}
memcpy(keys[i].data, keyval[i][0].data, keys[i].len);
}
ret = cache_op(cache, remove, keys, count);
cleanup:
kr_cache_commit(cache); /* Sync even after just kr_cache_match(). */
/* Free keys */
while (--i >= 0) {
free(keys[i].data);
}
return ret;
}
static void health_timer_cb(uv_timer_t *health_timer)
{
struct kr_cache *cache = health_timer->data;
if (cache)
cache_op(cache, check_health);
/* We don't do anything with the return code. For example, in some situations
* the file may not exist (temporarily), and we just expect to be more lucky
* when the timer fires again. */
}
int kr_cache_check_health(struct kr_cache *cache, int interval)
{
if (interval == 0)
return cache_op(cache, check_health);
if (interval < 0) {
if (!cache->health_timer)
return kr_ok(); // tolerate stopping a "stopped" timer
uv_close((uv_handle_t *)cache->health_timer, (uv_close_cb)free);
cache->health_timer->data = NULL;
cache->health_timer = NULL;
return kr_ok();
}
if (!cache->health_timer) {
/* We avoid depending on daemon's symbols by using uv_default_loop. */
cache->health_timer = malloc(sizeof(*cache->health_timer));
if (!cache->health_timer) return kr_error(ENOMEM);
uv_loop_t *loop = uv_default_loop();
kr_require(loop);
int ret = uv_timer_init(loop, cache->health_timer);
if (ret) {
free(cache->health_timer);
cache->health_timer = NULL;
return kr_error(ret);
}
cache->health_timer->data = cache;
}
kr_assert(cache->health_timer->data);
return kr_error(uv_timer_start(cache->health_timer, health_timer_cb, interval, interval));
}
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