/* SPDX-License-Identifier: GPL-3.0-or-later */ #include "db.h" #include "lib/cache/cdb_lmdb.h" #include "lib/cache/impl.h" #include #include #include #define MDB_FILE "/data.mdb" int kr_gc_cache_open(const char *cache_path, struct kr_cache *kres_db, knot_db_t ** libknot_db) { char cache_data[strlen(cache_path) + sizeof(MDB_FILE)]; (void)snprintf(cache_data, sizeof(cache_data), "%s" MDB_FILE, cache_path); struct stat st = { 0 }; if (stat(cache_path, &st) || !(st.st_mode & S_IFDIR) || stat(cache_data, &st)) { printf("Error: %s does not exist or is not a LMDB.\n", cache_path); return -ENOENT; } struct kr_cdb_opts opts = { .path = cache_path, .maxsize = 0/*don't resize*/ }; int ret = kr_cache_open(kres_db, NULL, &opts, NULL); if (ret || kres_db->db == NULL) { printf("Error opening Resolver cache (%s).\n", kr_strerror(ret)); return -EINVAL; } *libknot_db = kr_cdb_pt2knot_db_t(kres_db->db); if (*libknot_db == NULL) { printf("Out of memory.\n"); return -ENOMEM; } return 0; } int kr_gc_cache_check_health(struct kr_cache *kres_db, knot_db_t ** libknot_db) { int ret = kr_cache_check_health(kres_db, 0); if (ret == 0) { return 0; } else if (ret != 1) { kr_gc_cache_close(kres_db, *libknot_db); return ret; } /* Cache was reopen. */ free(*libknot_db); *libknot_db = kr_cdb_pt2knot_db_t(kres_db->db); if (*libknot_db == NULL) { printf("Out of memory.\n"); return -ENOMEM; } return 0; } void kr_gc_cache_close(struct kr_cache *kres_db, knot_db_t * knot_db) { free(knot_db); kr_cache_close(kres_db); } int kr_gc_key_consistent(knot_db_val_t key) { const uint8_t *kd = key.data; ssize_t i; /* CACHE_KEY_DEF */ if (key.len >= 2 && kd[0] == '\0') { /* Beware: root zone is special and starts with * a single \0 followed by type sign */ i = 1; } else { /* find the first double zero in the key */ for (i = 2; kd[i - 1] || kd[i - 2]; ++i) { if (kr_fails_assert(i < key.len)) return kr_error(EINVAL); } } // the next character can be used for classification switch (kd[i]) { case 'E': (void)0; // C can't have a variable definition following a label uint16_t type; if (kr_fails_assert(i + 1 + sizeof(type) <= key.len)) return kr_error(EINVAL); memcpy(&type, kd + i + 1, sizeof(type)); return type; case '1': return KNOT_RRTYPE_NSEC; case '3': return KNOT_RRTYPE_NSEC3; case 'S': // the rtt_state entries are considered inconsistent, at least for now return -1; default: kr_assert(!EINVAL); return kr_error(EINVAL); } } /// expects that key is consistent! CACHE_KEY_DEF static uint8_t entry_labels(knot_db_val_t * key, uint16_t rrtype) { uint8_t lab = 0, *p = key->data; while (*p != 0) { while (*p++ != 0) { if (p - (uint8_t *) key->data >= key->len) { return 0; } } lab++; } if (rrtype == KNOT_RRTYPE_NSEC3) { // We don't know the number of labels so easily, // but let's classify everything as directly // below the zone apex (that's most common). ++lab; } return lab; } void debug_printbin(const char *str, unsigned int len) { putchar('"'); for (int idx = 0; idx < len; idx++) { char c = str[idx]; if (isprint(c)) putchar(c); else printf("`%02hhx`", c); } putchar('"'); } /** Return one entry_h reference from a cache DB value. NULL if not consistent/suitable. */ static const struct entry_h *val2entry(const knot_db_val_t val, uint16_t ktype) { if (ktype != KNOT_RRTYPE_NS) return entry_h_consistent(val, ktype); /* Otherwise we have a multi-purpose entry. * Well, for now we simply choose the most suitable entry; * the only realistic collision is DNAME in apex where we'll prefer NS. */ entry_list_t el; if (entry_list_parse(val, el)) return NULL; for (int i = ENTRY_APEX_NSECS_CNT; i < EL_LENGTH; ++i) { if (el[i].len) return entry_h_consistent(el[i], EL2RRTYPE(i)); } /* Only NSEC* meta-data inside. */ return NULL; } int kr_gc_cache_iter(knot_db_t * knot_db, const kr_cache_gc_cfg_t *cfg, kr_gc_iter_callback callback, void *ctx) { unsigned int counter_iter = 0; unsigned int counter_gc_consistent = 0; unsigned int counter_kr_consistent = 0; knot_db_txn_t txn = { 0 }; knot_db_iter_t *it = NULL; const knot_db_api_t *api = knot_db_lmdb_api(); gc_record_info_t info = { 0 }; int64_t now = time(NULL); int ret = api->txn_begin(knot_db, &txn, KNOT_DB_RDONLY); if (ret != KNOT_EOK) { printf("Error starting DB transaction (%s).\n", knot_strerror(ret)); return ret; } it = api->iter_begin(&txn, KNOT_DB_NOOP); // _FIRST is split for easier debugging if (it == NULL) { printf("Error: failed to create an iterator.\n"); api->txn_abort(&txn); return KNOT_ERROR; } it = api->iter_seek(it, NULL, KNOT_DB_FIRST); if (it == NULL) printf("Suspicious: completely empty LMDB at this moment?\n"); int txn_steps = 0; while (it != NULL) { knot_db_val_t key = { 0 }, val = { 0 }; ret = api->iter_key(it, &key); if (ret == KNOT_EOK && key.len == 4 && memcmp("VERS", key.data, 4) == 0) { /* skip DB metadata */ goto skip; } if (ret == KNOT_EOK) { ret = api->iter_val(it, &val); } if (ret != KNOT_EOK) { goto error; } info.entry_size = key.len + val.len; info.valid = false; const int entry_type = kr_gc_key_consistent(key); const struct entry_h *entry = NULL; if (entry_type >= 0) { counter_gc_consistent++; entry = val2entry(val, entry_type); } /* TODO: perhaps improve some details around here: * - rtt_state entries are considered gc_inconsistent; * therefore they'll be the first to get freed (see kr_gc_categorize()) * - xNAME have .rrtype NS * - DNAME hidden on NS name will not be considered here * - if zone has NSEC* meta-data but no NS, it will be seen * here as kr_inconsistent */ if (entry != NULL) { info.valid = true; info.rrtype = entry_type; info.expires_in = entry->time + entry->ttl - now; info.no_labels = entry_labels(&key, entry_type); } counter_iter++; counter_kr_consistent += info.valid; if (VERBOSE_STATUS) { if (!entry_type || !entry) { // don't log fully consistent entries printf ("GC %sconsistent, KR %sconsistent, size %zu, key len %zu: ", entry_type ? "" : "in", entry ? "" : "IN", (key.len + val.len), key.len); debug_printbin(key.data, key.len); printf("\n"); } } ret = callback(&key, &info, ctx); if (ret != KNOT_EOK) { error: printf("Error iterating database (%s).\n", knot_strerror(ret)); api->iter_finish(it); api->txn_abort(&txn); return ret; } skip: // Advance to the next GC item. if (++txn_steps < cfg->ro_txn_items || !cfg->ro_txn_items/*unlimited*/) { it = api->iter_next(it); } else { /* The transaction has been too long; let's reopen it. */ txn_steps = 0; uint8_t key_storage[key.len]; memcpy(key_storage, key.data, key.len); key.data = key_storage; api->iter_finish(it); api->txn_abort(&txn); ret = api->txn_begin(knot_db, &txn, KNOT_DB_RDONLY); if (ret != KNOT_EOK) { printf("Error restarting DB transaction (%s).\n", knot_strerror(ret)); return ret; } it = api->iter_begin(&txn, KNOT_DB_NOOP); if (it == NULL) { printf("Error: failed to create an iterator.\n"); api->txn_abort(&txn); return KNOT_ERROR; } it = api->iter_seek(it, &key, KNOT_DB_GEQ); // NULL here means we'we reached the end } } api->txn_abort(&txn); kr_log_debug(CACHE, "iterated %u items, gc consistent %u, kr consistent %u\n", counter_iter, counter_gc_consistent, counter_kr_consistent); return KNOT_EOK; }