/*- * Copyright 2016 Vsevolod Stakhov * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "config.h" #include "util.h" #include "rspamd.h" #include "message.h" #include "symbols_cache.h" #include "cfg_file.h" #include "lua/lua_common.h" #include "unix-std.h" #include "contrib/t1ha/t1ha.h" #include "libserver/worker_util.h" #include #define msg_err_cache(...) rspamd_default_log_function (G_LOG_LEVEL_CRITICAL, \ cache->static_pool->tag.tagname, cache->cfg->checksum, \ G_STRFUNC, \ __VA_ARGS__) #define msg_warn_cache(...) rspamd_default_log_function (G_LOG_LEVEL_WARNING, \ cache->static_pool->tag.tagname, cache->cfg->checksum, \ G_STRFUNC, \ __VA_ARGS__) #define msg_info_cache(...) rspamd_default_log_function (G_LOG_LEVEL_INFO, \ cache->static_pool->tag.tagname, cache->cfg->checksum, \ G_STRFUNC, \ __VA_ARGS__) #define msg_debug_cache(...) rspamd_default_log_function (G_LOG_LEVEL_DEBUG, \ cache->static_pool->tag.tagname, cache->cfg->checksum, \ G_STRFUNC, \ __VA_ARGS__) static const guchar rspamd_symbols_cache_magic[8] = {'r', 's', 'c', 2, 0, 0, 0, 0 }; static gint rspamd_symbols_cache_find_symbol_parent (struct symbols_cache *cache, const gchar *name); struct rspamd_symbols_cache_header { guchar magic[8]; guint nitems; guchar checksum[64]; guchar unused[128]; }; struct symbols_cache_order { GPtrArray *d; ref_entry_t ref; }; struct symbols_cache { /* Hash table for fast access */ GHashTable *items_by_symbol; struct symbols_cache_order *items_by_order; GPtrArray *items_by_id; GPtrArray *prefilters; GPtrArray *postfilters; GPtrArray *composites; GPtrArray *idempotent; GList *delayed_deps; GList *delayed_conditions; rspamd_mempool_t *static_pool; guint64 cksum; gdouble total_weight; guint used_items; guint stats_symbols_count; guint64 total_hits; struct rspamd_config *cfg; rspamd_mempool_mutex_t *mtx; gdouble reload_time; gint peak_cb; }; struct counter_data { gdouble mean; gdouble stddev; guint64 number; }; struct item_stat { struct counter_data time_counter; gdouble avg_time; gdouble weight; guint hits; guint64 total_hits; struct counter_data frequency_counter; gdouble avg_frequency; gdouble stddev_frequency; }; struct cache_item { /* This block is likely shared */ struct item_stat *st; guint64 last_count; /* Per process counter */ struct counter_data *cd; gchar *symbol; enum rspamd_symbol_type type; /* Callback data */ symbol_func_t func; gpointer user_data; /* Condition of execution */ gint condition_cb; gboolean enabled; /* Parent symbol id for virtual symbols */ gint parent; /* Priority */ gint priority; gint id; gint frequency_peaks; /* Dependencies */ GPtrArray *deps; GPtrArray *rdeps; }; struct cache_dependency { struct cache_item *item; gchar *sym; gint id; }; struct delayed_cache_dependency { gchar *from; gchar *to; }; struct delayed_cache_condition { gchar *sym; gint cbref; lua_State *L; }; enum rspamd_cache_savepoint_stage { RSPAMD_CACHE_PASS_INIT = 0, RSPAMD_CACHE_PASS_PREFILTERS, RSPAMD_CACHE_PASS_WAIT_PREFILTERS, RSPAMD_CACHE_PASS_FILTERS, RSPAMD_CACHE_PASS_WAIT_FILTERS, RSPAMD_CACHE_PASS_POSTFILTERS, RSPAMD_CACHE_PASS_WAIT_POSTFILTERS, RSPAMD_CACHE_PASS_IDEMPOTENT, RSPAMD_CACHE_PASS_WAIT_IDEMPOTENT, RSPAMD_CACHE_PASS_DONE, }; struct cache_savepoint { guchar *processed_bits; enum rspamd_cache_savepoint_stage pass; guint version; struct rspamd_metric_result *rs; gdouble lim; GPtrArray *waitq; struct symbols_cache_order *order; }; struct rspamd_cache_refresh_cbdata { gdouble last_resort; struct event resort_ev; struct symbols_cache *cache; struct rspamd_worker *w; struct event_base *ev_base; }; /* weight, frequency, time */ #define TIME_ALPHA (1.0) #define WEIGHT_ALPHA (0.1) #define FREQ_ALPHA (0.01) #define SCORE_FUN(w, f, t) (((w) > 0 ? (w) : WEIGHT_ALPHA) \ * ((f) > 0 ? (f) : FREQ_ALPHA) \ / (t > TIME_ALPHA ? t : TIME_ALPHA)) static gboolean rspamd_symbols_cache_check_symbol (struct rspamd_task *task, struct symbols_cache *cache, struct cache_item *item, struct cache_savepoint *checkpoint, gdouble *total_diff); static gboolean rspamd_symbols_cache_check_deps (struct rspamd_task *task, struct symbols_cache *cache, struct cache_item *item, struct cache_savepoint *checkpoint, guint recursion, gboolean check_only); static void rspamd_symbols_cache_disable_symbol_checkpoint (struct rspamd_task *task, struct symbols_cache *cache, const gchar *symbol); static void rspamd_symbols_cache_enable_symbol_checkpoint (struct rspamd_task *task, struct symbols_cache *cache, const gchar *symbol); static void rspamd_symbols_cache_disable_all_symbols (struct rspamd_task *task, struct symbols_cache *cache); static GQuark rspamd_symbols_cache_quark (void) { return g_quark_from_static_string ("symbols-cache"); } static void rspamd_symbols_cache_order_dtor (gpointer p) { struct symbols_cache_order *ord = p; g_ptr_array_free (ord->d, TRUE); g_slice_free1 (sizeof (*ord), ord); } static void rspamd_symbols_cache_order_unref (gpointer p) { struct symbols_cache_order *ord = p; REF_RELEASE (ord); } static struct symbols_cache_order * rspamd_symbols_cache_order_new (gsize nelts) { struct symbols_cache_order *ord; ord = g_slice_alloc (sizeof (*ord)); ord->d = g_ptr_array_sized_new (nelts); REF_INIT_RETAIN (ord, rspamd_symbols_cache_order_dtor); return ord; } static gint postfilters_cmp (const void *p1, const void *p2, gpointer ud) { const struct cache_item *i1 = *(struct cache_item **)p1, *i2 = *(struct cache_item **)p2; double w1, w2; w1 = i1->priority; w2 = i2->priority; if (w1 > w2) { return 1; } else if (w1 < w2) { return -1; } return 0; } static gint prefilters_cmp (const void *p1, const void *p2, gpointer ud) { const struct cache_item *i1 = *(struct cache_item **)p1, *i2 = *(struct cache_item **)p2; double w1, w2; w1 = i1->priority; w2 = i2->priority; if (w1 < w2) { return 1; } else if (w1 > w2) { return -1; } return 0; } static gint cache_logic_cmp (const void *p1, const void *p2, gpointer ud) { const struct cache_item *i1 = *(struct cache_item **)p1, *i2 = *(struct cache_item **)p2; struct symbols_cache *cache = ud; double w1, w2; double weight1, weight2; double f1 = 0, f2 = 0, t1, t2, avg_freq, avg_weight; if (i1->deps->len != 0 || i2->deps->len != 0) { /* TODO: handle complex dependencies */ w1 = 1.0; w2 = 1.0; if (i1->deps->len != 0) { w1 = 1.0 / (i1->deps->len); } if (i2->deps->len != 0) { w2 = 1.0 / (i2->deps->len); } } else if (i1->priority == i2->priority) { avg_freq = ((gdouble)cache->total_hits / cache->used_items); avg_weight = (cache->total_weight / cache->used_items); f1 = (double)i1->st->total_hits / avg_freq; f2 = (double)i2->st->total_hits / avg_freq; weight1 = fabs (i1->st->weight) / avg_weight; weight2 = fabs (i2->st->weight) / avg_weight; t1 = i1->st->avg_time; t2 = i2->st->avg_time; w1 = SCORE_FUN (weight1, f1, t1); w2 = SCORE_FUN (weight2, f2, t2); } else { /* Strict sorting */ w1 = abs (i1->priority); w2 = abs (i2->priority); } if (w2 > w1) { return 1; } else if (w2 < w1) { return -1; } return 0; } /** * Set counter for a symbol */ static double rspamd_set_counter (struct counter_data *cd, gdouble value) { gdouble cerr; /* Cumulative moving average using per-process counter data */ if (cd->number == 0) { cd->mean = 0; cd->stddev = 0; } cd->mean += (value - cd->mean) / (gdouble)(++cd->number); cerr = (value - cd->mean) * (value - cd->mean); cd->stddev += (cerr - cd->stddev) / (gdouble)(cd->number); return cd->mean; } static void rspamd_symbols_cache_resort (struct symbols_cache *cache) { struct symbols_cache_order *ord; guint i; guint64 total_hits = 0; struct cache_item *it; ord = rspamd_symbols_cache_order_new (cache->used_items); for (i = 0; i < cache->used_items; i ++) { it = g_ptr_array_index (cache->items_by_id, i); total_hits += it->st->total_hits; if (!(it->type & (SYMBOL_TYPE_PREFILTER| SYMBOL_TYPE_POSTFILTER| SYMBOL_TYPE_COMPOSITE))) { g_ptr_array_add (ord->d, it); } } cache->total_hits = total_hits; g_ptr_array_sort_with_data (ord->d, cache_logic_cmp, cache); if (cache->items_by_order) { REF_RELEASE (cache->items_by_order); } cache->items_by_order = ord; } /* Sort items in logical order */ static void rspamd_symbols_cache_post_init (struct symbols_cache *cache) { struct cache_item *it, *dit; struct cache_dependency *dep, *rdep; struct delayed_cache_dependency *ddep; struct delayed_cache_condition *dcond; GList *cur; guint i, j; gint id; rspamd_symbols_cache_resort (cache); cur = cache->delayed_deps; while (cur) { ddep = cur->data; id = rspamd_symbols_cache_find_symbol_parent (cache, ddep->from); if (id != -1) { it = g_ptr_array_index (cache->items_by_id, id); } else { it = NULL; } if (it == NULL) { msg_err_cache ("cannot register delayed dependency between %s and %s, " "%s is missing", ddep->from, ddep->to, ddep->from); } else { rspamd_symbols_cache_add_dependency (cache, it->id, ddep->to); } cur = g_list_next (cur); } cur = cache->delayed_conditions; while (cur) { dcond = cur->data; id = rspamd_symbols_cache_find_symbol_parent (cache, dcond->sym); if (id != -1) { it = g_ptr_array_index (cache->items_by_id, id); } else { it = NULL; } if (it == NULL) { msg_err_cache ( "cannot register delayed condition for %s", dcond->sym); luaL_unref (dcond->L, LUA_REGISTRYINDEX, dcond->cbref); } else { rspamd_symbols_cache_add_condition (cache, it->id, dcond->L, dcond->cbref); } cur = g_list_next (cur); } for (i = 0; i < cache->items_by_id->len; i ++) { it = g_ptr_array_index (cache->items_by_id, i); for (j = 0; j < it->deps->len; j ++) { dep = g_ptr_array_index (it->deps, j); dit = g_hash_table_lookup (cache->items_by_symbol, dep->sym); if (dit != NULL) { if (dit->parent != -1) { dit = g_ptr_array_index (cache->items_by_id, dit->parent); } rdep = rspamd_mempool_alloc (cache->static_pool, sizeof (*rdep)); rdep->sym = dep->sym; rdep->item = it; rdep->id = i; g_ptr_array_add (dit->rdeps, rdep); dep->item = dit; dep->id = dit->id; msg_debug_cache ("add dependency from %d on %d", it->id, dit->id); } else { msg_err_cache ("cannot find dependency on symbol %s", dep->sym); } } } g_ptr_array_sort_with_data (cache->prefilters, prefilters_cmp, cache); g_ptr_array_sort_with_data (cache->postfilters, postfilters_cmp, cache); g_ptr_array_sort_with_data (cache->idempotent, postfilters_cmp, cache); } static gboolean rspamd_symbols_cache_load_items (struct symbols_cache *cache, const gchar *name) { struct rspamd_symbols_cache_header *hdr; struct stat st; struct ucl_parser *parser; ucl_object_t *top; const ucl_object_t *cur, *elt; ucl_object_iter_t it; struct cache_item *item, *parent; const guchar *p; gint fd; gpointer map; fd = open (name, O_RDONLY); if (fd == -1) { msg_info_cache ("cannot open file %s, error %d, %s", name, errno, strerror (errno)); return FALSE; } rspamd_file_lock (fd, FALSE); if (fstat (fd, &st) == -1) { rspamd_file_unlock (fd, FALSE); close (fd); msg_info_cache ("cannot stat file %s, error %d, %s", name, errno, strerror (errno)); return FALSE; } if (st.st_size < (gint)sizeof (*hdr)) { rspamd_file_unlock (fd, FALSE); close (fd); errno = EINVAL; msg_info_cache ("cannot use file %s, error %d, %s", name, errno, strerror (errno)); return FALSE; } map = mmap (NULL, st.st_size, PROT_READ, MAP_SHARED, fd, 0); if (map == MAP_FAILED) { rspamd_file_unlock (fd, FALSE); close (fd); msg_info_cache ("cannot mmap file %s, error %d, %s", name, errno, strerror (errno)); return FALSE; } hdr = map; if (memcmp (hdr->magic, rspamd_symbols_cache_magic, sizeof (rspamd_symbols_cache_magic)) != 0) { msg_info_cache ("cannot use file %s, bad magic", name); munmap (map, st.st_size); rspamd_file_unlock (fd, FALSE); close (fd); return FALSE; } parser = ucl_parser_new (0); p = (const guchar *)(hdr + 1); if (!ucl_parser_add_chunk (parser, p, st.st_size - sizeof (*hdr))) { msg_info_cache ("cannot use file %s, cannot parse: %s", name, ucl_parser_get_error (parser)); munmap (map, st.st_size); ucl_parser_free (parser); rspamd_file_unlock (fd, FALSE); close (fd); return FALSE; } top = ucl_parser_get_object (parser); munmap (map, st.st_size); rspamd_file_unlock (fd, FALSE); close (fd); ucl_parser_free (parser); if (top == NULL || ucl_object_type (top) != UCL_OBJECT) { msg_info_cache ("cannot use file %s, bad object", name); ucl_object_unref (top); return FALSE; } it = ucl_object_iterate_new (top); while ((cur = ucl_object_iterate_safe (it, true))) { item = g_hash_table_lookup (cache->items_by_symbol, ucl_object_key (cur)); if (item) { /* Copy saved info */ /* * XXX: don't save or load weight, it should be obtained from the * metric */ #if 0 elt = ucl_object_lookup (cur, "weight"); if (elt) { w = ucl_object_todouble (elt); if (w != 0) { item->weight = w; } } #endif elt = ucl_object_lookup (cur, "time"); if (elt) { item->st->avg_time = ucl_object_todouble (elt); } elt = ucl_object_lookup (cur, "count"); if (elt) { item->st->total_hits = ucl_object_toint (elt); item->last_count = item->st->total_hits; } elt = ucl_object_lookup (cur, "frequency"); if (elt && ucl_object_type (elt) == UCL_OBJECT) { const ucl_object_t *cur; cur = ucl_object_lookup (elt, "avg"); if (cur) { item->st->avg_frequency = ucl_object_todouble (cur); } cur = ucl_object_lookup (elt, "stddev"); if (cur) { item->st->stddev_frequency = ucl_object_todouble (cur); } } if ((item->type & SYMBOL_TYPE_VIRTUAL) && item->parent != -1) { g_assert (item->parent < (gint)cache->items_by_id->len); parent = g_ptr_array_index (cache->items_by_id, item->parent); if (parent->st->weight < item->st->weight) { parent->st->weight = item->st->weight; } /* * We maintain avg_time for virtual symbols equal to the * parent item avg_time */ item->st->avg_time = parent->st->avg_time; } cache->total_weight += fabs (item->st->weight); cache->total_hits += item->st->total_hits; } } ucl_object_iterate_free (it); ucl_object_unref (top); return TRUE; } static gboolean rspamd_symbols_cache_save_items (struct symbols_cache *cache, const gchar *name) { struct rspamd_symbols_cache_header hdr; ucl_object_t *top, *elt, *freq; GHashTableIter it; struct cache_item *item; struct ucl_emitter_functions *efunc; gpointer k, v; gint fd; bool ret; (void)unlink (name); fd = open (name, O_CREAT | O_TRUNC | O_WRONLY | O_EXCL, 00644); if (fd == -1) { msg_info_cache ("cannot open file %s, error %d, %s", name, errno, strerror (errno)); return FALSE; } rspamd_file_lock (fd, FALSE); memset (&hdr, 0, sizeof (hdr)); memcpy (hdr.magic, rspamd_symbols_cache_magic, sizeof (rspamd_symbols_cache_magic)); if (write (fd, &hdr, sizeof (hdr)) == -1) { msg_info_cache ("cannot write to file %s, error %d, %s", name, errno, strerror (errno)); rspamd_file_unlock (fd, FALSE); close (fd); return FALSE; } top = ucl_object_typed_new (UCL_OBJECT); g_hash_table_iter_init (&it, cache->items_by_symbol); while (g_hash_table_iter_next (&it, &k, &v)) { item = v; elt = ucl_object_typed_new (UCL_OBJECT); ucl_object_insert_key (elt, ucl_object_fromdouble (item->st->weight), "weight", 0, false); ucl_object_insert_key (elt, ucl_object_fromdouble (item->st->time_counter.mean), "time", 0, false); ucl_object_insert_key (elt, ucl_object_fromdouble (item->st->total_hits), "count", 0, false); freq = ucl_object_typed_new (UCL_OBJECT); ucl_object_insert_key (freq, ucl_object_fromdouble (item->st->frequency_counter.mean), "avg", 0, false); ucl_object_insert_key (freq, ucl_object_fromdouble (item->st->frequency_counter.stddev), "stddev", 0, false); ucl_object_insert_key (elt, freq, "frequency", 0, false); ucl_object_insert_key (top, elt, k, 0, false); } efunc = ucl_object_emit_fd_funcs (fd); ret = ucl_object_emit_full (top, UCL_EMIT_JSON_COMPACT, efunc, NULL); ucl_object_emit_funcs_free (efunc); ucl_object_unref (top); rspamd_file_unlock (fd, FALSE); close (fd); return ret; } gint rspamd_symbols_cache_add_symbol (struct symbols_cache *cache, const gchar *name, gint priority, symbol_func_t func, gpointer user_data, enum rspamd_symbol_type type, gint parent) { struct cache_item *item = NULL; g_assert (cache != NULL); if (name == NULL && !(type & SYMBOL_TYPE_CALLBACK)) { msg_warn_cache ("no name for non-callback symbol!"); } else if ((type & SYMBOL_TYPE_VIRTUAL) && parent == -1) { msg_warn_cache ("no parent symbol is associated with virtual symbol %s", name); } if (name != NULL && !(type & SYMBOL_TYPE_CALLBACK)) { if (g_hash_table_lookup (cache->items_by_symbol, name) != NULL) { msg_err_cache ("skip duplicate symbol registration for %s", name); return -1; } } if (type & (SYMBOL_TYPE_CLASSIFIER|SYMBOL_TYPE_CALLBACK| SYMBOL_TYPE_PREFILTER|SYMBOL_TYPE_POSTFILTER| SYMBOL_TYPE_IDEMPOTENT)) { type |= SYMBOL_TYPE_NOSTAT; } item = rspamd_mempool_alloc0 (cache->static_pool, sizeof (struct cache_item)); item->st = rspamd_mempool_alloc0_shared (cache->static_pool, sizeof (*item->st)); item->condition_cb = -1; item->enabled = TRUE; /* * We do not share cd to skip locking, instead we'll just calculate it on * save or accumulate */ item->cd = rspamd_mempool_alloc0 (cache->static_pool, sizeof (struct counter_data)); item->func = func; item->user_data = user_data; item->priority = priority; item->type = type; if ((type & SYMBOL_TYPE_FINE) && item->priority == 0) { /* Make priority for negative weighted symbols */ item->priority = 1; } item->id = cache->used_items; item->parent = parent; cache->used_items ++; if (!(item->type & (SYMBOL_TYPE_IDEMPOTENT|SYMBOL_TYPE_NOSTAT|SYMBOL_TYPE_CLASSIFIER))) { if (name != NULL) { cache->cksum = t1ha (name, strlen (name), cache->cksum); } else { cache->cksum = t1ha (&item->id, sizeof (item->id), cache->cksum); } cache->stats_symbols_count ++; } if (name != NULL) { item->symbol = rspamd_mempool_strdup (cache->static_pool, name); msg_debug_cache ("used items: %d, added symbol: %s, %d", cache->used_items, name, item->id); } else { msg_debug_cache ("used items: %d, added unnamed symbol: %d", cache->used_items, item->id); } g_ptr_array_add (cache->items_by_id, item); item->deps = g_ptr_array_new (); item->rdeps = g_ptr_array_new (); rspamd_mempool_add_destructor (cache->static_pool, rspamd_ptr_array_free_hard, item->deps); rspamd_mempool_add_destructor (cache->static_pool, rspamd_ptr_array_free_hard, item->rdeps); if (name != NULL) { g_hash_table_insert (cache->items_by_symbol, item->symbol, item); } if (item->type & SYMBOL_TYPE_PREFILTER) { g_ptr_array_add (cache->prefilters, item); } else if (item->type & SYMBOL_TYPE_IDEMPOTENT) { g_ptr_array_add (cache->idempotent, item); } else if (item->type & SYMBOL_TYPE_POSTFILTER) { g_ptr_array_add (cache->postfilters, item); } else if (item->type & SYMBOL_TYPE_COMPOSITE) { g_ptr_array_add (cache->composites, item); } return item->id; } gboolean rspamd_symbols_cache_add_condition (struct symbols_cache *cache, gint id, lua_State *L, gint cbref) { struct cache_item *item; g_assert (cache != NULL); if (id < 0 || id >= (gint)cache->items_by_id->len) { return FALSE; } item = g_ptr_array_index (cache->items_by_id, id); if (item->condition_cb != -1) { /* We already have a condition, so we need to remove old cbref first */ msg_warn_cache ("rewriting condition for symbol %s", item->symbol); luaL_unref (L, LUA_REGISTRYINDEX, item->condition_cb); } item->condition_cb = cbref; msg_debug_cache ("adding condition at lua ref %d to %s (%d)", cbref, item->symbol, item->id); return TRUE; } void rspamd_symbols_cache_set_peak_callback (struct symbols_cache *cache, gint cbref) { g_assert (cache != NULL); if (cache->peak_cb != -1) { luaL_unref (cache->cfg->lua_state, LUA_REGISTRYINDEX, cache->peak_cb); } cache->peak_cb = cbref; msg_info_cache ("registered peak callback"); } gboolean rspamd_symbols_cache_add_condition_delayed (struct symbols_cache *cache, const gchar *sym, lua_State *L, gint cbref) { gint id; struct delayed_cache_condition *ncond; g_assert (cache != NULL); g_assert (sym != NULL); id = rspamd_symbols_cache_find_symbol_parent (cache, sym); if (id != -1) { /* We already know id, so just register a direct condition */ return rspamd_symbols_cache_add_condition (cache, id, L, cbref); } ncond = g_slice_alloc (sizeof (*ncond)); ncond->sym = g_strdup (sym); ncond->cbref = cbref; ncond->L = L; cache->delayed_conditions = g_list_prepend (cache->delayed_conditions, ncond); return TRUE; } void rspamd_symbols_cache_save (struct symbols_cache *cache) { if (cache != NULL) { if (cache->cfg->cache_filename) { /* Try to sync values to the disk */ if (!rspamd_symbols_cache_save_items (cache, cache->cfg->cache_filename)) { msg_err_cache ("cannot save cache data to %s", cache->cfg->cache_filename); } } } } void rspamd_symbols_cache_destroy (struct symbols_cache *cache) { GList *cur; struct delayed_cache_dependency *ddep; struct delayed_cache_condition *dcond; if (cache != NULL) { rspamd_symbols_cache_save (cache); if (cache->delayed_deps) { cur = cache->delayed_deps; while (cur) { ddep = cur->data; g_free (ddep->from); g_free (ddep->to); g_slice_free1 (sizeof (*ddep), ddep); cur = g_list_next (cur); } g_list_free (cache->delayed_deps); } if (cache->delayed_conditions) { cur = cache->delayed_conditions; while (cur) { dcond = cur->data; g_free (dcond->sym); g_slice_free1 (sizeof (*dcond), dcond); cur = g_list_next (cur); } g_list_free (cache->delayed_conditions); } g_hash_table_destroy (cache->items_by_symbol); rspamd_mempool_delete (cache->static_pool); g_ptr_array_free (cache->items_by_id, TRUE); g_ptr_array_free (cache->prefilters, TRUE); g_ptr_array_free (cache->postfilters, TRUE); g_ptr_array_free (cache->idempotent, TRUE); g_ptr_array_free (cache->composites, TRUE); REF_RELEASE (cache->items_by_order); if (cache->peak_cb != -1) { luaL_unref (cache->cfg->lua_state, LUA_REGISTRYINDEX, cache->peak_cb); } g_slice_free1 (sizeof (*cache), cache); } } struct symbols_cache* rspamd_symbols_cache_new (struct rspamd_config *cfg) { struct symbols_cache *cache; cache = g_slice_alloc0 (sizeof (struct symbols_cache)); cache->static_pool = rspamd_mempool_new (rspamd_mempool_suggest_size (), "symcache"); cache->items_by_symbol = g_hash_table_new (rspamd_str_hash, rspamd_str_equal); cache->items_by_id = g_ptr_array_new (); cache->prefilters = g_ptr_array_new (); cache->postfilters = g_ptr_array_new (); cache->idempotent = g_ptr_array_new (); cache->composites = g_ptr_array_new (); cache->mtx = rspamd_mempool_get_mutex (cache->static_pool); cache->reload_time = cfg->cache_reload_time; cache->total_hits = 1; cache->total_weight = 1.0; cache->cfg = cfg; cache->cksum = 0xdeadbabe; cache->peak_cb = -1; return cache; } gboolean rspamd_symbols_cache_init (struct symbols_cache* cache) { gboolean res; g_assert (cache != NULL); cache->reload_time = cache->cfg->cache_reload_time; /* Just in-memory cache */ if (cache->cfg->cache_filename == NULL) { rspamd_symbols_cache_post_init (cache); return TRUE; } /* Copy saved cache entries */ res = rspamd_symbols_cache_load_items (cache, cache->cfg->cache_filename); rspamd_symbols_cache_post_init (cache); return res; } static void rspamd_symbols_cache_validate_cb (gpointer k, gpointer v, gpointer ud) { struct cache_item *item = v, *parent; struct symbols_cache *cache = (struct symbols_cache *)ud; GList *cur; struct rspamd_metric *m; struct rspamd_symbol *s; gboolean skipped, ghost; gint p1, p2; ghost = item->st->weight == 0 ? TRUE : FALSE; /* Check whether this item is skipped */ skipped = !ghost; g_assert (cache->cfg != NULL); if ((item->type & (SYMBOL_TYPE_NORMAL|SYMBOL_TYPE_VIRTUAL|SYMBOL_TYPE_COMPOSITE|SYMBOL_TYPE_CLASSIFIER)) && g_hash_table_lookup (cache->cfg->metrics_symbols, item->symbol) == NULL) { cur = g_list_first (cache->cfg->metrics_list); while (cur) { m = cur->data; if (m->accept_unknown_symbols) { GList *mlist; skipped = FALSE; item->st->weight = m->unknown_weight; s = rspamd_mempool_alloc0 (cache->static_pool, sizeof (*s)); s->name = item->symbol; s->weight_ptr = &item->st->weight; g_hash_table_insert (m->symbols, item->symbol, s); mlist = g_hash_table_lookup (cache->cfg->metrics_symbols, item->symbol); mlist = g_list_append (mlist, m); g_hash_table_insert (cache->cfg->metrics_symbols, item->symbol, mlist); msg_info_cache ("adding unknown symbol %s to metric %s", item->symbol, m->name); ghost = FALSE; } cur = g_list_next (cur); } } else { skipped = FALSE; } if (skipped) { item->type |= SYMBOL_TYPE_SKIPPED; msg_warn_cache ("symbol %s is not registered in any metric, so skip its check", item->symbol); } if (ghost) { msg_debug_cache ("symbol %s is registered as ghost symbol, it won't be inserted " "to any metric", item->symbol); } if (item->st->weight < 0 && item->priority == 0) { item->priority ++; } if ((item->type & SYMBOL_TYPE_VIRTUAL) && item->parent != -1) { g_assert (item->parent < (gint)cache->items_by_id->len); parent = g_ptr_array_index (cache->items_by_id, item->parent); if (fabs (parent->st->weight) < fabs (item->st->weight)) { parent->st->weight = item->st->weight; } p1 = abs (item->priority); p2 = abs (parent->priority); if (p1 != p2) { parent->priority = MAX (p1, p2); item->priority = parent->priority; } } cache->total_weight += fabs (item->st->weight); } static void rspamd_symbols_cache_metric_validate_cb (gpointer k, gpointer v, gpointer ud) { struct symbols_cache *cache = (struct symbols_cache *)ud; const gchar *sym = k; struct rspamd_symbol *s = (struct rspamd_symbol *)v; gdouble weight; struct cache_item *item; weight = *s->weight_ptr; item = g_hash_table_lookup (cache->items_by_symbol, sym); if (item) { item->st->weight = weight; } } gboolean rspamd_symbols_cache_validate (struct symbols_cache *cache, struct rspamd_config *cfg, gboolean strict) { struct cache_item *item; GHashTableIter it; GList *cur; gpointer k, v; struct rspamd_symbol *sym_def; struct rspamd_metric *metric; gboolean ignore_symbol = FALSE, ret = TRUE; if (cache == NULL) { msg_err ("empty cache is invalid"); return FALSE; } /* Now adjust symbol weights according to default metric */ if (cfg->default_metric != NULL) { g_hash_table_foreach (cfg->default_metric->symbols, rspamd_symbols_cache_metric_validate_cb, cache); } g_hash_table_foreach (cache->items_by_symbol, rspamd_symbols_cache_validate_cb, cache); /* Now check each metric item and find corresponding symbol in a cache */ g_hash_table_iter_init (&it, cfg->metrics_symbols); while (g_hash_table_iter_next (&it, &k, &v)) { ignore_symbol = FALSE; cur = v; while (cur) { metric = cur->data; sym_def = g_hash_table_lookup (metric->symbols, k); if (sym_def && (sym_def->flags & RSPAMD_SYMBOL_FLAG_IGNORE)) { ignore_symbol = TRUE; break; } cur = g_list_next (cur); } if (!ignore_symbol) { item = g_hash_table_lookup (cache->items_by_symbol, k); if (item == NULL) { msg_warn_cache ( "symbol '%s' has its score defined but there is no " "corresponding rule registered", k); if (strict) { ret = FALSE; } } } } return ret; } /* Return true if metric has score that is more than spam score for it */ static gboolean rspamd_symbols_cache_metric_limit (struct rspamd_task *task, struct cache_savepoint *cp) { struct rspamd_metric_result *res; double ms; if (task->flags & RSPAMD_TASK_FLAG_PASS_ALL) { return FALSE; } if (cp->lim == 0.0) { res = task->result; if (res) { ms = rspamd_task_get_required_score (task, res); if (!isnan (ms) && cp->lim < ms) { cp->rs = res; cp->lim = ms; } } } if (cp->rs) { if (cp->rs->score > cp->lim) { return TRUE; } } else { /* No reject score define, always check all rules */ cp->lim = -1; } return FALSE; } static void rspamd_symbols_cache_watcher_cb (gpointer sessiond, gpointer ud) { struct rspamd_task *task = sessiond; struct cache_item *item = ud, *it; struct cache_savepoint *checkpoint; struct symbols_cache *cache; gint i, remain = 0; checkpoint = task->checkpoint; cache = task->cfg->cache; /* Specify that we are done with this item */ setbit (checkpoint->processed_bits, item->id * 2 + 1); if (checkpoint->pass > 0) { for (i = 0; i < (gint)checkpoint->waitq->len; i ++) { it = g_ptr_array_index (checkpoint->waitq, i); if (!isset (checkpoint->processed_bits, it->id * 2)) { if (!rspamd_symbols_cache_check_deps (task, cache, it, checkpoint, 0, TRUE)) { remain ++; } else { msg_debug_task ("watcher for %d, unblocked item %d", item->id, it->id); rspamd_symbols_cache_check_symbol (task, cache, it, checkpoint, NULL); } } } } msg_debug_task ("finished watcher for %d, %ud symbols waiting", item->id, remain); } static gboolean rspamd_symbols_cache_check_symbol (struct rspamd_task *task, struct symbols_cache *cache, struct cache_item *item, struct cache_savepoint *checkpoint, gdouble *total_diff) { guint pending_before, pending_after; double t1 = 0, t2 = 0; gdouble diff; struct rspamd_task **ptask; lua_State *L; gboolean check = TRUE; const gdouble slow_diff_limit = 1e5; if (item->func) { g_assert (item->func != NULL); /* Check has been started */ setbit (checkpoint->processed_bits, item->id * 2); if (!item->enabled || (RSPAMD_TASK_IS_EMPTY (task) && !(item->type & SYMBOL_TYPE_EMPTY))) { check = FALSE; } else if (item->condition_cb != -1) { /* We also executes condition callback to check if we need this symbol */ L = task->cfg->lua_state; lua_rawgeti (L, LUA_REGISTRYINDEX, item->condition_cb); ptask = lua_newuserdata (L, sizeof (struct rspamd_task *)); rspamd_lua_setclass (L, "rspamd{task}", -1); *ptask = task; if (lua_pcall (L, 1, 1, 0) != 0) { msg_info_task ("call to condition for %s failed: %s", item->symbol, lua_tostring (L, -1)); lua_pop (L, 1); } else { check = lua_toboolean (L, -1); lua_pop (L, 1); } } if (check) { pending_before = rspamd_session_events_pending (task->s); /* Watch for events appeared */ rspamd_session_watch_start (task->s, item->id, rspamd_symbols_cache_watcher_cb, item); msg_debug_task ("execute %s, %d", item->symbol, item->id); t1 = rspamd_get_ticks (); item->func (task, item->user_data); t2 = rspamd_get_ticks (); diff = (t2 - t1) * 1e6; if (G_UNLIKELY (RSPAMD_TASK_IS_PROFILING (task))) { rspamd_task_profile_set (task, item->symbol, diff); } if (total_diff) { *total_diff += diff; } if (diff > slow_diff_limit) { msg_info_task ("slow rule: %s: %d ms", item->symbol, (gint)(diff / 1000.)); } if (rspamd_worker_is_normal (task->worker)) { rspamd_set_counter (item->cd, diff); } pending_after = rspamd_session_events_pending (task->s); rspamd_session_watch_stop (task->s); if (pending_before == pending_after) { /* No new events registered */ setbit (checkpoint->processed_bits, item->id * 2 + 1); return TRUE; } return FALSE; } else { msg_debug_task ("skipping check of %s as its start condition is false", item->symbol); setbit (checkpoint->processed_bits, item->id * 2 + 1); return TRUE; } } else { setbit (checkpoint->processed_bits, item->id * 2); setbit (checkpoint->processed_bits, item->id * 2 + 1); return TRUE; } } static gboolean rspamd_symbols_cache_check_deps (struct rspamd_task *task, struct symbols_cache *cache, struct cache_item *item, struct cache_savepoint *checkpoint, guint recursion, gboolean check_only) { struct cache_dependency *dep; guint i; gboolean ret = TRUE; static const guint max_recursion = 20; if (recursion > max_recursion) { msg_err_task ("cyclic dependencies: maximum check level %ud exceed when " "checking dependencies for %s", max_recursion, item->symbol); return TRUE; } if (item->deps != NULL && item->deps->len > 0) { for (i = 0; i < item->deps->len; i ++) { dep = g_ptr_array_index (item->deps, i); if (dep->item == NULL) { /* Assume invalid deps as done */ msg_debug_task ("symbol %s has invalid dependencies from %s", item->symbol, dep->sym); continue; } if (!isset (checkpoint->processed_bits, dep->id * 2 + 1)) { if (!isset (checkpoint->processed_bits, dep->id * 2)) { /* Not started */ if (!check_only) { if (!rspamd_symbols_cache_check_deps (task, cache, dep->item, checkpoint, recursion + 1, check_only)) { gboolean found = FALSE; guint j; struct cache_item *tmp_it; PTR_ARRAY_FOREACH (checkpoint->waitq, j, tmp_it) { if (item->id == tmp_it->id) { found = TRUE; break; } } if (!found) { g_ptr_array_add (checkpoint->waitq, item); } ret = FALSE; msg_debug_task ("delayed dependency %d for symbol %d", dep->id, item->id); } else if (!rspamd_symbols_cache_check_symbol (task, cache, dep->item, checkpoint, NULL)) { /* Now started, but has events pending */ ret = FALSE; msg_debug_task ("started check of %d symbol as dep for " "%d", dep->id, item->id); } else { msg_debug_task ("dependency %d for symbol %d is " "already processed", dep->id, item->id); } } else { ret = FALSE; } } else { /* Started but not finished */ ret = FALSE; } } else { msg_debug_task ("dependency %d for symbol %d is already " "checked", dep->id, item->id); } } } return ret; } static void rspamd_symbols_cache_continuation (void *data) { struct rspamd_task *task = data; rspamd_task_process (task, RSPAMD_TASK_PROCESS_ALL); } static void rspamd_symbols_cache_tm (gint fd, short what, void *data) { struct rspamd_task *task = data; rspamd_session_remove_event (task->s, rspamd_symbols_cache_continuation, data); } static struct cache_savepoint * rspamd_symbols_cache_make_checkpoint (struct rspamd_task *task, struct symbols_cache *cache) { struct cache_savepoint *checkpoint; guint nitems; nitems = cache->items_by_id->len - cache->postfilters->len - cache->prefilters->len - cache->composites->len - cache->idempotent->len; if (nitems != cache->items_by_order->d->len) { /* * Cache has been modified, need to resort it */ msg_info_cache ("symbols cache has been modified since last check:" " old items: %ud, new items: %ud", cache->items_by_order->d->len, nitems); rspamd_symbols_cache_resort (cache); } checkpoint = rspamd_mempool_alloc0 (task->task_pool, sizeof (*checkpoint)); /* Bit 0: check started, Bit 1: check finished */ checkpoint->processed_bits = rspamd_mempool_alloc0 (task->task_pool, NBYTES (cache->used_items) * 2); checkpoint->waitq = g_ptr_array_new (); g_assert (cache->items_by_order != NULL); checkpoint->version = cache->items_by_order->d->len; checkpoint->order = cache->items_by_order; REF_RETAIN (checkpoint->order); rspamd_mempool_add_destructor (task->task_pool, rspamd_symbols_cache_order_unref, checkpoint->order); rspamd_mempool_add_destructor (task->task_pool, rspamd_ptr_array_free_hard, checkpoint->waitq); checkpoint->pass = RSPAMD_CACHE_PASS_INIT; task->checkpoint = checkpoint; task->result = rspamd_create_metric_result (task); return checkpoint; } gboolean rspamd_symbols_cache_process_settings (struct rspamd_task *task, struct symbols_cache *cache) { const ucl_object_t *wl, *cur, *disabled, *enabled; struct rspamd_metric *def; struct rspamd_symbols_group *gr; GHashTableIter gr_it; ucl_object_iter_t it = NULL; gpointer k, v; wl = ucl_object_lookup (task->settings, "whitelist"); if (wl != NULL) { msg_info_task ("<%s> is whitelisted", task->message_id); task->flags |= RSPAMD_TASK_FLAG_SKIP; return TRUE; } enabled = ucl_object_lookup (task->settings, "symbols_enabled"); if (enabled) { /* Disable all symbols but selected */ rspamd_symbols_cache_disable_all_symbols (task, cache); it = NULL; while ((cur = ucl_iterate_object (enabled, &it, true)) != NULL) { rspamd_symbols_cache_enable_symbol_checkpoint (task, cache, ucl_object_tostring (cur)); } } /* Enable groups of symbols */ enabled = ucl_object_lookup (task->settings, "groups_enabled"); def = g_hash_table_lookup (task->cfg->metrics, DEFAULT_METRIC); if (def && enabled) { it = NULL; rspamd_symbols_cache_disable_all_symbols (task, cache); while ((cur = ucl_iterate_object (enabled, &it, true)) != NULL) { if (ucl_object_type (cur) == UCL_STRING) { gr = g_hash_table_lookup (def->groups, ucl_object_tostring (cur)); if (gr) { g_hash_table_iter_init (&gr_it, gr->symbols); while (g_hash_table_iter_next (&gr_it, &k, &v)) { rspamd_symbols_cache_enable_symbol_checkpoint (task, cache, k); } } } } } disabled = ucl_object_lookup (task->settings, "symbols_disabled"); if (disabled) { it = NULL; while ((cur = ucl_iterate_object (disabled, &it, true)) != NULL) { rspamd_symbols_cache_disable_symbol_checkpoint (task, cache, ucl_object_tostring (cur)); } } /* Disable groups of symbols */ disabled = ucl_object_lookup (task->settings, "groups_disabled"); def = g_hash_table_lookup (task->cfg->metrics, DEFAULT_METRIC); if (def && disabled) { it = NULL; while ((cur = ucl_iterate_object (disabled, &it, true)) != NULL) { if (ucl_object_type (cur) == UCL_STRING) { gr = g_hash_table_lookup (def->groups, ucl_object_tostring (cur)); if (gr) { g_hash_table_iter_init (&gr_it, gr->symbols); while (g_hash_table_iter_next (&gr_it, &k, &v)) { rspamd_symbols_cache_disable_symbol_checkpoint (task, cache, k); } } } } } return FALSE; } gboolean rspamd_symbols_cache_process_symbols (struct rspamd_task * task, struct symbols_cache *cache, gint stage) { struct cache_item *item = NULL; struct cache_savepoint *checkpoint; gint i; gdouble total_microseconds = 0; gboolean all_done; gint saved_priority; const gdouble max_microseconds = 3e5; guint start_events_pending; g_assert (cache != NULL); if (task->checkpoint == NULL) { checkpoint = rspamd_symbols_cache_make_checkpoint (task, cache); task->checkpoint = checkpoint; } else { checkpoint = task->checkpoint; } if (stage == RSPAMD_TASK_STAGE_POST_FILTERS && checkpoint->pass < RSPAMD_CACHE_PASS_POSTFILTERS) { checkpoint->pass = RSPAMD_CACHE_PASS_POSTFILTERS; } if (stage == RSPAMD_TASK_STAGE_IDEMPOTENT && checkpoint->pass < RSPAMD_CACHE_PASS_IDEMPOTENT) { checkpoint->pass = RSPAMD_CACHE_PASS_IDEMPOTENT; } msg_debug_task ("symbols processing stage at pass: %d", checkpoint->pass); start_events_pending = rspamd_session_events_pending (task->s); switch (checkpoint->pass) { case RSPAMD_CACHE_PASS_INIT: case RSPAMD_CACHE_PASS_PREFILTERS: /* Check for prefilters */ saved_priority = G_MININT; for (i = 0; i < (gint)cache->prefilters->len; i ++) { item = g_ptr_array_index (cache->prefilters, i); if (!isset (checkpoint->processed_bits, item->id * 2) && !isset (checkpoint->processed_bits, item->id * 2 + 1)) { /* Check priorities */ if (saved_priority == G_MININT) { saved_priority = item->priority; } else { if (item->priority < saved_priority && rspamd_session_events_pending (task->s) > start_events_pending) { /* * Delay further checks as we have higher * priority filters to be processed */ checkpoint->pass = RSPAMD_CACHE_PASS_PREFILTERS; return TRUE; } } rspamd_symbols_cache_check_symbol (task, cache, item, checkpoint, &total_microseconds); } } checkpoint->pass = RSPAMD_CACHE_PASS_WAIT_PREFILTERS; break; case RSPAMD_CACHE_PASS_WAIT_PREFILTERS: all_done = TRUE; for (i = 0; i < (gint)cache->prefilters->len; i ++) { item = g_ptr_array_index (cache->prefilters, i); if (!isset (checkpoint->processed_bits, item->id * 2 + 1)) { all_done = FALSE; break; } } if (all_done || stage == RSPAMD_TASK_STAGE_FILTERS) { checkpoint->pass = RSPAMD_CACHE_PASS_FILTERS; } if (stage == RSPAMD_TASK_STAGE_FILTERS) { return rspamd_symbols_cache_process_symbols (task, cache, stage); } break; case RSPAMD_CACHE_PASS_FILTERS: /* * On the first pass we check symbols that do not have dependencies * If we figure out symbol that has no dependencies satisfied, then * we just save it for another pass */ for (i = 0; i < (gint)checkpoint->version; i ++) { item = g_ptr_array_index (checkpoint->order->d, i); if (item->type & SYMBOL_TYPE_CLASSIFIER) { continue; } if (!(item->type & SYMBOL_TYPE_FINE) && rspamd_session_events_pending (task->s) == 0) { if (rspamd_symbols_cache_metric_limit (task, checkpoint)) { msg_info_task ("<%s> has already scored more than %.2f, so do " "not " "plan more checks", task->message_id, checkpoint->rs->score); continue; } } if (!isset (checkpoint->processed_bits, item->id * 2)) { if (!rspamd_symbols_cache_check_deps (task, cache, item, checkpoint, 0, FALSE)) { gboolean found = FALSE; guint j; struct cache_item *tmp_it; msg_debug_task ("blocked execution of %d unless deps are " "resolved", item->id); PTR_ARRAY_FOREACH (checkpoint->waitq, j, tmp_it) { if (item->id == tmp_it->id) { found = TRUE; break; } } if (!found) { g_ptr_array_add (checkpoint->waitq, item); } continue; } rspamd_symbols_cache_check_symbol (task, cache, item, checkpoint, &total_microseconds); } if (total_microseconds > max_microseconds) { /* Maybe we should stop and check pending events? */ if (rspamd_session_events_pending (task->s) > start_events_pending) { /* Add some timeout event to avoid too long waiting */ #if 0 struct event *ev; struct timeval tv; rspamd_session_add_event (task->s, rspamd_symbols_cache_continuation, task, rspamd_symbols_cache_quark ()); ev = rspamd_mempool_alloc (task->task_pool, sizeof (*ev)); event_set (ev, -1, EV_TIMEOUT, rspamd_symbols_cache_tm, task); event_base_set (task->ev_base, ev); msec_to_tv (50, &tv); event_add (ev, &tv); rspamd_mempool_add_destructor (task->task_pool, (rspamd_mempool_destruct_t)event_del, ev); #endif msg_info_task ("trying to check async events after spending " "%d microseconds processing symbols", (gint)total_microseconds); return TRUE; } } } checkpoint->pass = RSPAMD_CACHE_PASS_WAIT_FILTERS; break; case RSPAMD_CACHE_PASS_WAIT_FILTERS: /* We just go through the blocked symbols and check if they are ready */ for (i = 0; i < (gint)checkpoint->waitq->len; i ++) { item = g_ptr_array_index (checkpoint->waitq, i); if (!isset (checkpoint->processed_bits, item->id * 2)) { if (!rspamd_symbols_cache_check_deps (task, cache, item, checkpoint, 0, FALSE)) { break; } rspamd_symbols_cache_check_symbol (task, cache, item, checkpoint, &total_microseconds); } if (total_microseconds > max_microseconds) { /* Maybe we should stop and check pending events? */ if (rspamd_session_events_pending (task->s) > start_events_pending) { msg_debug_task ("trying to check async events after spending " "%d microseconds processing symbols", (gint)total_microseconds); return TRUE; } } } if (checkpoint->waitq->len == 0 || stage == RSPAMD_TASK_STAGE_POST_FILTERS) { checkpoint->pass = RSPAMD_CACHE_PASS_POSTFILTERS; } if (stage == RSPAMD_TASK_STAGE_POST_FILTERS) { return rspamd_symbols_cache_process_symbols (task, cache, stage); } break; case RSPAMD_CACHE_PASS_POSTFILTERS: /* Check for postfilters */ saved_priority = G_MININT; for (i = 0; i < (gint)cache->postfilters->len; i ++) { item = g_ptr_array_index (cache->postfilters, i); if (!isset (checkpoint->processed_bits, item->id * 2) && !isset (checkpoint->processed_bits, item->id * 2 + 1)) { /* Check priorities */ if (saved_priority == G_MININT) { saved_priority = item->priority; } else { if (item->priority > saved_priority && rspamd_session_events_pending (task->s) > start_events_pending) { /* * Delay further checks as we have higher * priority filters to be processed */ checkpoint->pass = RSPAMD_CACHE_PASS_POSTFILTERS; return TRUE; } } rspamd_symbols_cache_check_symbol (task, cache, item, checkpoint, &total_microseconds); } } checkpoint->pass = RSPAMD_CACHE_PASS_WAIT_POSTFILTERS; break; case RSPAMD_CACHE_PASS_WAIT_POSTFILTERS: all_done = TRUE; for (i = 0; i < (gint)cache->postfilters->len; i ++) { item = g_ptr_array_index (cache->postfilters, i); if (!isset (checkpoint->processed_bits, item->id * 2 + 1)) { all_done = FALSE; break; } } if (all_done) { checkpoint->pass = RSPAMD_CACHE_PASS_IDEMPOTENT; } if (checkpoint->waitq->len == 0 || stage == RSPAMD_TASK_STAGE_IDEMPOTENT) { checkpoint->pass = RSPAMD_CACHE_PASS_IDEMPOTENT; } if (stage == RSPAMD_TASK_STAGE_IDEMPOTENT) { return rspamd_symbols_cache_process_symbols (task, cache, stage); } break; case RSPAMD_CACHE_PASS_IDEMPOTENT: /* Check for postfilters */ saved_priority = G_MININT; for (i = 0; i < (gint)cache->idempotent->len; i ++) { item = g_ptr_array_index (cache->idempotent, i); if (!isset (checkpoint->processed_bits, item->id * 2) && !isset (checkpoint->processed_bits, item->id * 2 + 1)) { /* Check priorities */ if (saved_priority == G_MININT) { saved_priority = item->priority; } else { if (item->priority > saved_priority && rspamd_session_events_pending (task->s) > start_events_pending) { /* * Delay further checks as we have higher * priority filters to be processed */ checkpoint->pass = RSPAMD_CACHE_PASS_IDEMPOTENT; return TRUE; } } rspamd_symbols_cache_check_symbol (task, cache, item, checkpoint, &total_microseconds); } } checkpoint->pass = RSPAMD_CACHE_PASS_WAIT_IDEMPOTENT; break; case RSPAMD_CACHE_PASS_WAIT_IDEMPOTENT: all_done = TRUE; for (i = 0; i < (gint)cache->idempotent->len; i ++) { item = g_ptr_array_index (cache->idempotent, i); if (!isset (checkpoint->processed_bits, item->id * 2 + 1)) { all_done = FALSE; break; } } if (all_done) { checkpoint->pass = RSPAMD_CACHE_PASS_DONE; return TRUE; } break; case RSPAMD_CACHE_PASS_DONE: return TRUE; break; } return FALSE; } struct counters_cbdata { ucl_object_t *top; struct symbols_cache *cache; }; static void rspamd_symbols_cache_counters_cb (gpointer v, gpointer ud) { struct counters_cbdata *cbd = ud; ucl_object_t *obj, *top; struct cache_item *item = v, *parent; top = cbd->top; if (!(item->type & SYMBOL_TYPE_CALLBACK)) { obj = ucl_object_typed_new (UCL_OBJECT); ucl_object_insert_key (obj, ucl_object_fromstring (item->symbol), "symbol", 0, false); if ((item->type & SYMBOL_TYPE_VIRTUAL) && item->parent != -1) { g_assert (item->parent < (gint)cbd->cache->items_by_id->len); parent = g_ptr_array_index (cbd->cache->items_by_id, item->parent); ucl_object_insert_key (obj, ucl_object_fromdouble (item->st->weight), "weight", 0, false); ucl_object_insert_key (obj, ucl_object_fromdouble (parent->st->avg_frequency), "frequency", 0, false); ucl_object_insert_key (obj, ucl_object_fromint (parent->st->total_hits), "hits", 0, false); ucl_object_insert_key (obj, ucl_object_fromdouble (parent->st->avg_time), "time", 0, false); } else { ucl_object_insert_key (obj, ucl_object_fromdouble (item->st->weight), "weight", 0, false); ucl_object_insert_key (obj, ucl_object_fromdouble (item->st->avg_frequency), "frequency", 0, false); ucl_object_insert_key (obj, ucl_object_fromint (item->st->total_hits), "hits", 0, false); ucl_object_insert_key (obj, ucl_object_fromdouble (item->st->avg_time), "time", 0, false); } ucl_array_append (top, obj); } } ucl_object_t * rspamd_symbols_cache_counters (struct symbols_cache * cache) { ucl_object_t *top; struct counters_cbdata cbd; g_assert (cache != NULL); top = ucl_object_typed_new (UCL_ARRAY); cbd.top = top; cbd.cache = cache; g_ptr_array_foreach (cache->items_by_order->d, rspamd_symbols_cache_counters_cb, &cbd); return top; } static void rspamd_symbols_cache_call_peak_cb (struct event_base *ev_base, struct symbols_cache *cache, struct cache_item *item, gdouble cur_value, gdouble cur_err) { lua_State *L = cache->cfg->lua_state; struct event_base **pbase; lua_rawgeti (L, LUA_REGISTRYINDEX, cache->peak_cb); pbase = lua_newuserdata (L, sizeof (*pbase)); *pbase = ev_base; rspamd_lua_setclass (L, "rspamd{ev_base}", -1); lua_pushstring (L, item->symbol); lua_pushnumber (L, item->st->avg_frequency); lua_pushnumber (L, sqrt (item->st->stddev_frequency)); lua_pushnumber (L, cur_value); lua_pushnumber (L, cur_err); if (lua_pcall (L, 6, 0, 0) != 0) { msg_info_cache ("call to peak function for %s failed: %s", item->symbol, lua_tostring (L, -1)); lua_pop (L, 1); } } static void rspamd_symbols_cache_resort_cb (gint fd, short what, gpointer ud) { struct timeval tv; gdouble tm; struct rspamd_cache_refresh_cbdata *cbdata = ud; struct symbols_cache *cache; struct cache_item *item, *parent; guint i; gdouble cur_ticks; cache = cbdata->cache; /* Plan new event */ tm = rspamd_time_jitter (cache->reload_time, 0); cur_ticks = rspamd_get_ticks (); msg_debug_cache ("resort symbols cache, next reload in %.2f seconds", tm); g_assert (cache != NULL); evtimer_set (&cbdata->resort_ev, rspamd_symbols_cache_resort_cb, cbdata); event_base_set (cbdata->ev_base, &cbdata->resort_ev); double_to_tv (tm, &tv); event_add (&cbdata->resort_ev, &tv); if (rspamd_worker_is_normal (cbdata->w)) { rspamd_mempool_lock_mutex (cache->mtx); /* Gather stats from shared execution times */ for (i = 0; i < cache->items_by_id->len; i ++) { item = g_ptr_array_index (cache->items_by_id, i); item->st->total_hits += item->st->hits; item->st->hits = 0; if (item->last_count > 0 && cbdata->w->index == 0) { /* Calculate frequency */ gdouble cur_err, cur_value; cur_value = (item->st->total_hits - item->last_count) / (cur_ticks - cbdata->last_resort); rspamd_set_counter (&item->st->frequency_counter, cur_value); item->st->avg_frequency = item->st->frequency_counter.mean; item->st->stddev_frequency = item->st->frequency_counter.stddev; if (cur_value > 0) { msg_debug_cache ("frequency for %s is %.2f, avg: %.2f", item->symbol, cur_value, item->st->avg_frequency); } cur_err = (item->st->avg_frequency - cur_value); cur_err *= cur_err; /* * TODO: replace magic number */ if (item->st->frequency_counter.number > 10 && cur_err > sqrt (item->st->stddev_frequency) * 3) { item->frequency_peaks ++; msg_debug_cache ("peak found for %s is %.2f, avg: %.2f, " "stddev: %.2f, error: %.2f, peaks: %d", item->symbol, cur_value, item->st->avg_frequency, item->st->stddev_frequency, cur_err, item->frequency_peaks); if (cache->peak_cb != -1) { rspamd_symbols_cache_call_peak_cb (cbdata->ev_base, cache, item, cur_value, cur_err); } } } item->last_count = item->st->total_hits; if (item->cd->number > 0) { if (item->type & (SYMBOL_TYPE_CALLBACK|SYMBOL_TYPE_NORMAL)) { item->st->avg_time = item->cd->mean; rspamd_set_counter (&item->st->time_counter, item->st->avg_time); item->st->avg_time = item->st->time_counter.mean; memset (item->cd, 0, sizeof (*item->cd)); } } } /* Sync virtual symbols */ for (i = 0; i < cache->items_by_id->len; i ++) { item = g_ptr_array_index (cache->items_by_id, i); if (item->parent != -1) { parent = g_ptr_array_index (cache->items_by_id, item->parent); if (parent) { item->st->avg_time = parent->st->avg_time; } } } rspamd_mempool_unlock_mutex (cache->mtx); } cbdata->last_resort = cur_ticks; rspamd_symbols_cache_resort (cache); } void rspamd_symbols_cache_start_refresh (struct symbols_cache * cache, struct event_base *ev_base, struct rspamd_worker *w) { struct timeval tv; gdouble tm; struct rspamd_cache_refresh_cbdata *cbdata; cbdata = rspamd_mempool_alloc0 (cache->static_pool, sizeof (*cbdata)); cbdata->last_resort = rspamd_get_ticks (); cbdata->ev_base = ev_base; cbdata->w = w; cbdata->cache = cache; tm = rspamd_time_jitter (cache->reload_time, 0); msg_debug_cache ("next reload in %.2f seconds", tm); g_assert (cache != NULL); evtimer_set (&cbdata->resort_ev, rspamd_symbols_cache_resort_cb, cbdata); event_base_set (ev_base, &cbdata->resort_ev); double_to_tv (tm, &tv); event_add (&cbdata->resort_ev, &tv); rspamd_mempool_add_destructor (cache->static_pool, (rspamd_mempool_destruct_t)event_del, &cbdata->resort_ev); } void rspamd_symbols_cache_inc_frequency (struct symbols_cache *cache, const gchar *symbol) { struct cache_item *item; g_assert (cache != NULL); item = g_hash_table_lookup (cache->items_by_symbol, symbol); if (item != NULL) { g_atomic_int_inc (&item->st->hits); } } void rspamd_symbols_cache_add_dependency (struct symbols_cache *cache, gint id_from, const gchar *to) { struct cache_item *source; struct cache_dependency *dep; g_assert (id_from < (gint)cache->items_by_id->len); source = g_ptr_array_index (cache->items_by_id, id_from); dep = rspamd_mempool_alloc (cache->static_pool, sizeof (*dep)); dep->id = id_from; dep->sym = rspamd_mempool_strdup (cache->static_pool, to); /* Will be filled later */ dep->item = NULL; g_ptr_array_add (source->deps, dep); } void rspamd_symbols_cache_add_delayed_dependency (struct symbols_cache *cache, const gchar *from, const gchar *to) { struct delayed_cache_dependency *ddep; g_assert (from != NULL); g_assert (to != NULL); ddep = g_slice_alloc (sizeof (*ddep)); ddep->from = g_strdup (from); ddep->to = g_strdup (to); cache->delayed_deps = g_list_prepend (cache->delayed_deps, ddep); } gint rspamd_symbols_cache_find_symbol (struct symbols_cache *cache, const gchar *name) { struct cache_item *item; g_assert (cache != NULL); if (name == NULL) { return -1; } item = g_hash_table_lookup (cache->items_by_symbol, name); if (item != NULL) { return item->id; } return -1; } gboolean rspamd_symbols_cache_stat_symbol (struct symbols_cache *cache, const gchar *name, gdouble *frequency, gdouble *freq_stddev, gdouble *tm, guint *nhits) { struct cache_item *item; g_assert (cache != NULL); if (name == NULL) { return FALSE; } item = g_hash_table_lookup (cache->items_by_symbol, name); if (item != NULL) { *frequency = item->st->avg_frequency; *freq_stddev = sqrt (item->st->stddev_frequency); *tm = item->st->time_counter.mean; if (nhits) { *nhits = item->st->hits; } return TRUE; } return FALSE; } static gint rspamd_symbols_cache_find_symbol_parent (struct symbols_cache *cache, const gchar *name) { struct cache_item *item; g_assert (cache != NULL); if (name == NULL) { return -1; } item = g_hash_table_lookup (cache->items_by_symbol, name); if (item != NULL) { while (item != NULL && item->parent != -1) { item = g_ptr_array_index (cache->items_by_id, item->parent); } return item ? item->id : -1; } return -1; } const gchar * rspamd_symbols_cache_symbol_by_id (struct symbols_cache *cache, gint id) { struct cache_item *item; g_assert (cache != NULL); if (id < 0 || id >= (gint)cache->items_by_id->len) { return NULL; } item = g_ptr_array_index (cache->items_by_id, id); return item->symbol; } guint rspamd_symbols_cache_stats_symbols_count (struct symbols_cache *cache) { g_assert (cache != NULL); return cache->stats_symbols_count; } static void rspamd_symbols_cache_disable_all_symbols (struct rspamd_task *task, struct symbols_cache *cache) { struct cache_savepoint *checkpoint; if (task->checkpoint == NULL) { checkpoint = rspamd_symbols_cache_make_checkpoint (task, cache); task->checkpoint = checkpoint; } else { checkpoint = task->checkpoint; } /* Set all symbols as started + finished to disable their execution */ memset (checkpoint->processed_bits, 0xff, NBYTES (cache->used_items) * 2); } static void rspamd_symbols_cache_disable_symbol_checkpoint (struct rspamd_task *task, struct symbols_cache *cache, const gchar *symbol) { struct cache_savepoint *checkpoint; struct cache_item *item; gint id; if (task->checkpoint == NULL) { checkpoint = rspamd_symbols_cache_make_checkpoint (task, cache); task->checkpoint = checkpoint; } else { checkpoint = task->checkpoint; } id = rspamd_symbols_cache_find_symbol_parent (cache, symbol); if (id > 0) { /* Set executed and finished flags */ item = g_ptr_array_index (cache->items_by_id, id); setbit (checkpoint->processed_bits, item->id * 2); setbit (checkpoint->processed_bits, item->id * 2 + 1); msg_debug_task ("disable execution of %s", symbol); } else { msg_info_task ("cannot disable %s: not found", symbol); } } static void rspamd_symbols_cache_enable_symbol_checkpoint (struct rspamd_task *task, struct symbols_cache *cache, const gchar *symbol) { struct cache_savepoint *checkpoint; struct cache_item *item; gint id; if (task->checkpoint == NULL) { checkpoint = rspamd_symbols_cache_make_checkpoint (task, cache); task->checkpoint = checkpoint; } else { checkpoint = task->checkpoint; } id = rspamd_symbols_cache_find_symbol_parent (cache, symbol); if (id > 0) { /* Set executed and finished flags */ item = g_ptr_array_index (cache->items_by_id, id); clrbit (checkpoint->processed_bits, item->id * 2); clrbit (checkpoint->processed_bits, item->id * 2 + 1); msg_debug_task ("enable execution of %s", symbol); } else { msg_info_task ("cannot enable %s: not found", symbol); } } struct rspamd_abstract_callback_data* rspamd_symbols_cache_get_cbdata (struct symbols_cache *cache, const gchar *symbol) { gint id; struct cache_item *item; g_assert (cache != NULL); g_assert (symbol != NULL); id = rspamd_symbols_cache_find_symbol_parent (cache, symbol); if (id < 0) { return NULL; } item = g_ptr_array_index (cache->items_by_id, id); return item->user_data; } gboolean rspamd_symbols_cache_set_cbdata (struct symbols_cache *cache, const gchar *symbol, struct rspamd_abstract_callback_data *cbdata) { gint id; struct cache_item *item; g_assert (cache != NULL); g_assert (symbol != NULL); id = rspamd_symbols_cache_find_symbol_parent (cache, symbol); if (id < 0) { return FALSE; } item = g_ptr_array_index (cache->items_by_id, id); item->user_data = cbdata; return TRUE; } gboolean rspamd_symbols_cache_is_checked (struct rspamd_task *task, struct symbols_cache *cache, const gchar *symbol) { gint id; struct cache_savepoint *checkpoint; g_assert (cache != NULL); g_assert (symbol != NULL); id = rspamd_symbols_cache_find_symbol_parent (cache, symbol); if (id < 0) { return FALSE; } checkpoint = task->checkpoint; if (checkpoint) { return isset (checkpoint->processed_bits, id * 2); } return FALSE; } void rspamd_symbols_cache_disable_symbol (struct symbols_cache *cache, const gchar *symbol) { gint id; struct cache_item *item; g_assert (cache != NULL); g_assert (symbol != NULL); id = rspamd_symbols_cache_find_symbol_parent (cache, symbol); if (id >= 0) { item = g_ptr_array_index (cache->items_by_id, id); item->enabled = FALSE; } } void rspamd_symbols_cache_enable_symbol (struct symbols_cache *cache, const gchar *symbol) { gint id; struct cache_item *item; g_assert (cache != NULL); g_assert (symbol != NULL); id = rspamd_symbols_cache_find_symbol_parent (cache, symbol); if (id >= 0) { item = g_ptr_array_index (cache->items_by_id, id); item->enabled = TRUE; } } guint64 rspamd_symbols_cache_get_cksum (struct symbols_cache *cache) { g_assert (cache != NULL); return cache->cksum; } gboolean rspamd_symbols_cache_is_symbol_enabled (struct rspamd_task *task, struct symbols_cache *cache, const gchar *symbol) { gint id; struct cache_savepoint *checkpoint; struct cache_item *item; lua_State *L; struct rspamd_task **ptask; gboolean ret = TRUE; g_assert (cache != NULL); g_assert (symbol != NULL); id = rspamd_symbols_cache_find_symbol_parent (cache, symbol); if (id < 0) { return FALSE; } checkpoint = task->checkpoint; item = g_ptr_array_index (cache->items_by_id, id); if (checkpoint) { if (isset (checkpoint->processed_bits, id * 2)) { ret = FALSE; } else { if (item->condition_cb != -1) { /* We also executes condition callback to check if we need this symbol */ L = task->cfg->lua_state; lua_rawgeti (L, LUA_REGISTRYINDEX, item->condition_cb); ptask = lua_newuserdata (L, sizeof (struct rspamd_task *)); rspamd_lua_setclass (L, "rspamd{task}", -1); *ptask = task; if (lua_pcall (L, 1, 1, 0) != 0) { msg_info_task ("call to condition for %s failed: %s", item->symbol, lua_tostring (L, -1)); lua_pop (L, 1); } else { ret = lua_toboolean (L, -1); lua_pop (L, 1); } } } } return ret; } void rspamd_symbols_cache_foreach (struct symbols_cache *cache, void (*func)(gint , const gchar *, gint , gpointer ), gpointer ud) { guint i; struct cache_item *item; PTR_ARRAY_FOREACH (cache->items_by_id, i, item) { func (item->id, item->symbol, item->type, ud); } }