/* Copyright (C) 2014-2017 CZ.NIC, z.s.p.o. 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 . */ /** * @file stats.c * @brief Storage for various counters and metrics from query resolution. * * You can either reuse this module to compute statistics or store custom metrics * in it via the extensions. */ #include #include #include #include #include #include #include "lib/layer/iterate.h" #include "lib/rplan.h" #include "lib/module.h" #include "lib/layer.h" #include "lib/resolve.h" /** @internal Compatibility wrapper for Lua < 5.2 */ #if LUA_VERSION_NUM < 502 #define lua_rawlen(L, obj) lua_objlen((L), (obj)) #endif /* Defaults */ #define VERBOSE_MSG(qry, ...) QRVERBOSE(qry, "stat", __VA_ARGS__) #define FREQUENT_PSAMPLE 10 /* Sampling rate, 1 in N */ #ifdef LRU_REP_SIZE #define FREQUENT_COUNT LRU_REP_SIZE /* Size of frequent tables */ #else #define FREQUENT_COUNT 5000 /* Size of frequent tables */ #endif #ifndef UPSTREAMS_COUNT #define UPSTREAMS_COUNT 512 /* Size of recent upstreams */ #endif /** @cond internal Fixed-size map of predefined metrics. */ #define CONST_METRICS(X) \ X(answer,total) X(answer,noerror) X(answer,nodata) X(answer,nxdomain) X(answer,servfail) \ X(answer,cached) X(answer,1ms) X(answer,10ms) X(answer,50ms) X(answer,100ms) \ X(answer,250ms) X(answer,500ms) X(answer,1000ms) X(answer,1500ms) X(answer,slow) \ X(answer,aa) X(answer,tc) X(answer,rd) X(answer,ra) X(answer, ad) X(answer,cd) \ X(answer,edns0) X(answer,do) \ X(query,edns) X(query,dnssec) \ X(const,end) enum const_metric { #define X(a,b) metric_ ## a ## _ ## b, CONST_METRICS(X) #undef X }; struct const_metric_elm { const char *key; size_t val; }; static struct const_metric_elm const_metrics[] = { #define X(a,b) [metric_ ## a ## _ ## b] = { #a "." #b, 0 }, CONST_METRICS(X) #undef X }; /** @endcond */ /** @internal LRU hash of most frequent names. */ typedef lru_t(unsigned) namehash_t; typedef array_t(struct sockaddr_in6) addrlist_t; /** @internal Stats data structure. */ struct stat_data { map_t map; struct { namehash_t *frequent; } queries; struct { addrlist_t q; size_t head; } upstreams; }; /** @internal We don't store/publish port, repurpose it for RTT instead. */ #define sin6_rtt sin6_port /** @internal Add to const map counter */ static inline void stat_const_add(struct stat_data *data, enum const_metric key, ssize_t incr) { const_metrics[key].val += incr; } static int collect_answer(struct stat_data *data, knot_pkt_t *pkt) { stat_const_add(data, metric_answer_total, 1); /* Count per-rcode */ switch(knot_wire_get_rcode(pkt->wire)) { case KNOT_RCODE_NOERROR: if (knot_wire_get_ancount(pkt->wire) > 0) stat_const_add(data, metric_answer_noerror, 1); else stat_const_add(data, metric_answer_nodata, 1); break; case KNOT_RCODE_NXDOMAIN: stat_const_add(data, metric_answer_nxdomain, 1); break; case KNOT_RCODE_SERVFAIL: stat_const_add(data, metric_answer_servfail, 1); break; default: break; } return kr_ok(); } static inline int collect_key(char *key, const knot_dname_t *name, uint16_t type) { memcpy(key, &type, sizeof(type)); int key_len = knot_dname_to_wire((uint8_t *)key + sizeof(type), name, KNOT_DNAME_MAXLEN); if (key_len < 0) { return kr_error(key_len); } return key_len + sizeof(type); } static void collect_sample(struct stat_data *data, struct kr_rplan *rplan, knot_pkt_t *pkt) { /* Sample key = {[2] type, [1-255] owner} */ char key[sizeof(uint16_t) + KNOT_DNAME_MAXLEN]; for (size_t i = 0; i < rplan->resolved.len; ++i) { /* Sample queries leading to iteration */ struct kr_query *qry = rplan->resolved.at[i]; if (qry->flags.CACHED) { continue; } /* Consider 1 in N for frequent sampling. * TODO: redesign the sampling approach. */ if (kr_rand_coin(1, FREQUENT_PSAMPLE)) { int key_len = collect_key(key, qry->sname, qry->stype); if (key_len < 0) { assert(false); continue; } unsigned *count = lru_get_new(data->queries.frequent, key, key_len, NULL); if (count) *count += 1; } } } static int collect_rtt(kr_layer_t *ctx, knot_pkt_t *pkt) { struct kr_request *req = ctx->req; struct kr_query *qry = req->current_query; if (qry->flags.CACHED || !req->upstream.addr) { return ctx->state; } /* Push address and RTT to the ring buffer head */ struct kr_module *module = ctx->api->data; struct stat_data *data = module->data; /* Socket address is encoded into sockaddr_in6 struct that * unions with sockaddr_in and differ in sa_family */ struct sockaddr_in6 *e = &data->upstreams.q.at[data->upstreams.head]; const struct sockaddr *src = req->upstream.addr; switch (src->sa_family) { case AF_INET: memcpy(e, src, sizeof(struct sockaddr_in)); break; case AF_INET6: memcpy(e, src, sizeof(struct sockaddr_in6)); break; default: return ctx->state; } /* Replace port number with the RTT information (cap is UINT16_MAX milliseconds) */ e->sin6_rtt = req->upstream.rtt; /* Advance ring buffer head */ data->upstreams.head = (data->upstreams.head + 1) % UPSTREAMS_COUNT; return ctx->state; } static int collect(kr_layer_t *ctx) { struct kr_request *param = ctx->req; struct kr_module *module = ctx->api->data; struct kr_rplan *rplan = ¶m->rplan; struct stat_data *data = module->data; /* Collect data on final answer */ collect_answer(data, param->answer); collect_sample(data, rplan, param->answer); /* Count cached and unresolved */ if (rplan->resolved.len > 0) { /* Histogram of answer latency. */ struct kr_query *first = rplan->resolved.at[0]; uint64_t elapsed = kr_now() - first->timestamp_mono; if (elapsed <= 1) { stat_const_add(data, metric_answer_1ms, 1); } else if (elapsed <= 10) { stat_const_add(data, metric_answer_10ms, 1); } else if (elapsed <= 50) { stat_const_add(data, metric_answer_50ms, 1); } else if (elapsed <= 100) { stat_const_add(data, metric_answer_100ms, 1); } else if (elapsed <= 250) { stat_const_add(data, metric_answer_250ms, 1); } else if (elapsed <= 500) { stat_const_add(data, metric_answer_500ms, 1); } else if (elapsed <= 1000) { stat_const_add(data, metric_answer_1000ms, 1); } else if (elapsed <= 1500) { stat_const_add(data, metric_answer_1500ms, 1); } else { stat_const_add(data, metric_answer_slow, 1); } /* Observe the final query. */ struct kr_query *last = kr_rplan_last(rplan); stat_const_add(data, metric_answer_cached, last->flags.CACHED); } /* Keep stats of all response header flags; * these don't return bool, so that's why we use !! */ stat_const_add(data, metric_answer_aa, !!knot_wire_get_aa(param->answer->wire)); stat_const_add(data, metric_answer_tc, !!knot_wire_get_tc(param->answer->wire)); stat_const_add(data, metric_answer_rd, !!knot_wire_get_rd(param->answer->wire)); stat_const_add(data, metric_answer_ra, !!knot_wire_get_ra(param->answer->wire)); stat_const_add(data, metric_answer_ad, !!knot_wire_get_ad(param->answer->wire)); stat_const_add(data, metric_answer_cd, !!knot_wire_get_cd(param->answer->wire)); /* EDNS0 stats */ stat_const_add(data, metric_answer_edns0, knot_pkt_has_edns(param->answer)); stat_const_add(data, metric_answer_do, knot_pkt_has_dnssec(param->answer)); /* Query parameters and transport mode */ /* DEPRECATED use new names metric_answer_edns0 and metric_answer_do */ stat_const_add(data, metric_query_edns, knot_pkt_has_edns(param->answer)); stat_const_add(data, metric_query_dnssec, knot_pkt_has_dnssec(param->answer)); return ctx->state; } /** * Set nominal value of a key. * * Input: { key, val } * */ static char* stats_set(void *env, struct kr_module *module, const char *args) { if (args == NULL) return NULL; struct stat_data *data = module->data; auto_free char *pair = strdup(args); char *val = strchr(pair, ' '); if (val) { *val = '\0'; size_t number = strtoul(val + 1, NULL, 10); for (unsigned i = 0; i < metric_const_end; ++i) { if (strcmp(const_metrics[i].key, pair) == 0) { const_metrics[i].val = number; return NULL; } } map_set(&data->map, pair, (void *)number); } return NULL; } /** * Retrieve metrics by key. * * Input: string key * Output: number value */ static char* stats_get(void *env, struct kr_module *module, const char *args) { if (args == NULL) return NULL; struct stat_data *data = module->data; /* Expecting CHAR_BIT to be 8, this is a safe bet */ char *ret = malloc(3 * sizeof(size_t) + 2); if (!ret) { return NULL; } /* Check if it exists in const map. */ for (unsigned i = 0; i < metric_const_end; ++i) { if (strcmp(const_metrics[i].key, args) == 0) { sprintf(ret, "%zu", const_metrics[i].val); return ret; } } /* Check in variable map */ if (!map_contains(&data->map, args)) { free(ret); return NULL; } void *val = map_get(&data->map, args); sprintf(ret, "%zu", (size_t) val); return ret; } static int list_entry(const char *key, void *val, void *baton) { JsonNode *root = baton; size_t number = (size_t) val; json_append_member(root, key, json_mknumber(number)); return 0; } /** * List observed metrics. * * Output: { key: val, ... } */ static char* stats_list(void *env, struct kr_module *module, const char *args) { struct stat_data *data = module->data; JsonNode *root = json_mkobject(); /* Walk const metrics map */ size_t args_len = args ? strlen(args) : 0; for (unsigned i = 0; i < metric_const_end; ++i) { struct const_metric_elm *elm = &const_metrics[i]; if (!args || strncmp(elm->key, args, args_len) == 0) { json_append_member(root, elm->key, json_mknumber(elm->val)); } } map_walk_prefixed(&data->map, (args_len > 0) ? args : "", list_entry, root); char *ret = json_encode(root); json_delete(root); return ret; } /** @internal Helper for dump_list: add a single namehash_t item to JSON. */ static enum lru_apply_do dump_value(const char *key, uint len, unsigned *val, void *baton) { uint16_t key_type = 0; /* Extract query name, type and counter */ memcpy(&key_type, key, sizeof(key_type)); KR_DNAME_GET_STR(key_name, (uint8_t *)key + sizeof(key_type)); KR_RRTYPE_GET_STR(type_str, key_type); /* Convert to JSON object */ JsonNode *json_val = json_mkobject(); json_append_member(json_val, "count", json_mknumber(*val)); json_append_member(json_val, "name", json_mkstring(key_name)); json_append_member(json_val, "type", json_mkstring(type_str)); json_append_element((JsonNode *)baton, json_val); return LRU_APPLY_DO_NOTHING; // keep the item } /** * List frequent names. * * Output: [{ count: , name: , type: }, ... ] */ static char* dump_list(void *env, struct kr_module *module, const char *args, namehash_t *table) { if (!table) { return NULL; } JsonNode *root = json_mkarray(); lru_apply(table, dump_value, root); char *ret = json_encode(root); json_delete(root); return ret; } static char* dump_frequent(void *env, struct kr_module *module, const char *args) { struct stat_data *data = module->data; return dump_list(env, module, args, data->queries.frequent); } static char* clear_frequent(void *env, struct kr_module *module, const char *args) { struct stat_data *data = module->data; lru_reset(data->queries.frequent); return NULL; } static char* dump_upstreams(void *env, struct kr_module *module, const char *args) { struct stat_data *data = module->data; if (!data) { return NULL; } /* Walk the ring backwards until AF_UNSPEC or we hit head. */ JsonNode *root = json_mkobject(); size_t head = data->upstreams.head; for (size_t i = 1; i < UPSTREAMS_COUNT; ++i) { size_t h = (UPSTREAMS_COUNT + head - i) % UPSTREAMS_COUNT; struct sockaddr_in6 *e = &data->upstreams.q.at[h]; if (e->sin6_family == AF_UNSPEC) { break; } /* Convert address to string */ char addr_str[INET6_ADDRSTRLEN]; const char *ret = inet_ntop(e->sin6_family, kr_inaddr((const struct sockaddr *)e), addr_str, sizeof(addr_str)); if (!ret) { break; } /* Append to map with an array encoding RTTs */ JsonNode *json_val = json_find_member(root, addr_str); if (!json_val) { json_val = json_mkarray(); json_append_member(root, addr_str, json_val); } json_append_element(json_val, json_mknumber(e->sin6_rtt)); } /* Encode and return */ char *ret = json_encode(root); json_delete(root); return ret; } /* * Module implementation. */ KR_EXPORT const kr_layer_api_t *stats_layer(struct kr_module *module) { static kr_layer_api_t _layer = { .consume = &collect_rtt, .finish = &collect, }; /* Store module reference */ _layer.data = module; return &_layer; } KR_EXPORT int stats_init(struct kr_module *module) { struct stat_data *data = malloc(sizeof(*data)); if (!data) { return kr_error(ENOMEM); } memset(data, 0, sizeof(*data)); data->map = map_make(NULL); module->data = data; lru_create(&data->queries.frequent, FREQUENT_COUNT, NULL, NULL); /* Initialize ring buffer of recently visited upstreams */ array_init(data->upstreams.q); if (array_reserve(data->upstreams.q, UPSTREAMS_COUNT) != 0) { return kr_error(ENOMEM); } for (size_t i = 0; i < UPSTREAMS_COUNT; ++i) { struct sockaddr *sa = (struct sockaddr *)&data->upstreams.q.at[i]; sa->sa_family = AF_UNSPEC; } return kr_ok(); } KR_EXPORT int stats_deinit(struct kr_module *module) { struct stat_data *data = module->data; if (data) { map_clear(&data->map); lru_free(data->queries.frequent); array_clear(data->upstreams.q); free(data); } return kr_ok(); } KR_EXPORT struct kr_prop *stats_props(void) { static struct kr_prop prop_list[] = { { &stats_set, "set", "Set {key, val} metrics.", }, { &stats_get, "get", "Get metrics for given key.", }, { &stats_list, "list", "List observed metrics.", }, { &dump_frequent, "frequent", "List most frequent queries.", }, { &clear_frequent,"clear_frequent", "Clear frequent queries log.", }, { &dump_upstreams, "upstreams", "List recently seen authoritatives.", }, { NULL, NULL, NULL } }; return prop_list; } KR_MODULE_EXPORT(stats) #undef VERBOSE_MSG