// SPDX-License-Identifier: GPL-3.0-or-later #include "facets.h" #define FACETS_HISTOGRAM_COLUMNS 150 // the target number of points in a histogram #define FACETS_KEYS_WITH_VALUES_MAX 200 // the max number of keys that can be facets #define FACETS_KEYS_IN_ROW_MAX 500 // the max number of keys in a row #define FACETS_KEYS_HASHTABLE_ENTRIES 15 #define FACETS_VALUES_HASHTABLE_ENTRIES 15 static inline void facets_reset_key(FACET_KEY *k); // ---------------------------------------------------------------------------- static const char id_encoding_characters[64 + 1] = "ABCDEFGHIJKLMNOPQRSTUVWXYZ.abcdefghijklmnopqrstuvwxyz_0123456789"; static const uint8_t id_encoding_characters_reverse[256] = { ['A'] = 0, ['B'] = 1, ['C'] = 2, ['D'] = 3, ['E'] = 4, ['F'] = 5, ['G'] = 6, ['H'] = 7, ['I'] = 8, ['J'] = 9, ['K'] = 10, ['L'] = 11, ['M'] = 12, ['N'] = 13, ['O'] = 14, ['P'] = 15, ['Q'] = 16, ['R'] = 17, ['S'] = 18, ['T'] = 19, ['U'] = 20, ['V'] = 21, ['W'] = 22, ['X'] = 23, ['Y'] = 24, ['Z'] = 25, ['.'] = 26, ['a'] = 27, ['b'] = 28, ['c'] = 29, ['d'] = 30, ['e'] = 31, ['f'] = 32, ['g'] = 33, ['h'] = 34, ['i'] = 35, ['j'] = 36, ['k'] = 37, ['l'] = 38, ['m'] = 39, ['n'] = 40, ['o'] = 41, ['p'] = 42, ['q'] = 43, ['r'] = 44, ['s'] = 45, ['t'] = 46, ['u'] = 47, ['v'] = 48, ['w'] = 49, ['x'] = 50, ['y'] = 51, ['z'] = 52, ['_'] = 53, ['0'] = 54, ['1'] = 55, ['2'] = 56, ['3'] = 57, ['4'] = 58, ['5'] = 59, ['6'] = 60, ['7'] = 61, ['8'] = 62, ['9'] = 63 }; #define FACET_STRING_HASH_SIZE 12 #define FACETS_HASH XXH64_hash_t #define FACETS_HASH_FUNCTION(src, len) XXH3_64bits(src, len) #define FACETS_HASH_ZERO (FACETS_HASH)0 #define FACETS_HASH_UNSAMPLED (FACETS_HASH)(UINT64_MAX - 1) #define FACETS_HASH_ESTIMATED (FACETS_HASH)UINT64_MAX static inline void facets_hash_to_str(FACETS_HASH num, char *out) { out[11] = '\0'; out[10] = id_encoding_characters[num & 63]; num >>= 6; out[9] = id_encoding_characters[num & 63]; num >>= 6; out[8] = id_encoding_characters[num & 63]; num >>= 6; out[7] = id_encoding_characters[num & 63]; num >>= 6; out[6] = id_encoding_characters[num & 63]; num >>= 6; out[5] = id_encoding_characters[num & 63]; num >>= 6; out[4] = id_encoding_characters[num & 63]; num >>= 6; out[3] = id_encoding_characters[num & 63]; num >>= 6; out[2] = id_encoding_characters[num & 63]; num >>= 6; out[1] = id_encoding_characters[num & 63]; num >>= 6; out[0] = id_encoding_characters[num & 63]; } static inline FACETS_HASH str_to_facets_hash(const char *str) { FACETS_HASH num = 0; int shifts = 6 * (FACET_STRING_HASH_SIZE - 2); num |= ((FACETS_HASH)(id_encoding_characters_reverse[(uint8_t)(str[0])])) << shifts; shifts -= 6; num |= ((FACETS_HASH)(id_encoding_characters_reverse[(uint8_t)(str[1])])) << shifts; shifts -= 6; num |= ((FACETS_HASH)(id_encoding_characters_reverse[(uint8_t)(str[2])])) << shifts; shifts -= 6; num |= ((FACETS_HASH)(id_encoding_characters_reverse[(uint8_t)(str[3])])) << shifts; shifts -= 6; num |= ((FACETS_HASH)(id_encoding_characters_reverse[(uint8_t)(str[4])])) << shifts; shifts -= 6; num |= ((FACETS_HASH)(id_encoding_characters_reverse[(uint8_t)(str[5])])) << shifts; shifts -= 6; num |= ((FACETS_HASH)(id_encoding_characters_reverse[(uint8_t)(str[6])])) << shifts; shifts -= 6; num |= ((FACETS_HASH)(id_encoding_characters_reverse[(uint8_t)(str[7])])) << shifts; shifts -= 6; num |= ((FACETS_HASH)(id_encoding_characters_reverse[(uint8_t)(str[8])])) << shifts; shifts -= 6; num |= ((FACETS_HASH)(id_encoding_characters_reverse[(uint8_t)(str[9])])) << shifts; shifts -= 6; num |= ((FACETS_HASH)(id_encoding_characters_reverse[(uint8_t)(str[10])])) << shifts; return num; } static const char *hash_to_static_string(FACETS_HASH hash) { static __thread char hash_str[FACET_STRING_HASH_SIZE]; facets_hash_to_str(hash, hash_str); return hash_str; } static inline bool is_valid_string_hash(const char *s) { if(strlen(s) != FACET_STRING_HASH_SIZE - 1) { netdata_log_error("The user supplied key '%s' does not have the right length for a facets hash.", s); return false; } uint8_t *t = (uint8_t *)s; while(*t) { if(id_encoding_characters_reverse[*t] == 0 && *t != id_encoding_characters[0]) { netdata_log_error("The user supplied key '%s' contains invalid characters for a facets hash.", s); return false; } t++; } return true; } // ---------------------------------------------------------------------------- // hashtable for FACET_VALUE // cleanup hashtable defines #include "../../libnetdata/simple_hashtable_undef.h" struct facet_value; // #define SIMPLE_HASHTABLE_SORT_FUNCTION compare_facet_value #define SIMPLE_HASHTABLE_VALUE_TYPE struct facet_value #define SIMPLE_HASHTABLE_NAME _VALUE #include "../simple_hashtable.h" // ---------------------------------------------------------------------------- // hashtable for FACET_KEY // cleanup hashtable defines #include "../../libnetdata/simple_hashtable_undef.h" struct facet_key; // #define SIMPLE_HASHTABLE_SORT_FUNCTION compare_facet_key #define SIMPLE_HASHTABLE_VALUE_TYPE struct facet_key #define SIMPLE_HASHTABLE_NAME _KEY #include "../simple_hashtable.h" // ---------------------------------------------------------------------------- typedef struct facet_value { FACETS_HASH hash; const char *name; const char *color; uint32_t name_len; bool selected; bool empty; bool unsampled; bool estimated; uint32_t rows_matching_facet_value; uint32_t final_facet_value_counter; uint32_t order; uint32_t *histogram; uint32_t min, max, sum; struct facet_value *prev, *next; } FACET_VALUE; typedef enum { FACET_KEY_VALUE_NONE = 0, FACET_KEY_VALUE_UPDATED = (1 << 0), FACET_KEY_VALUE_EMPTY = (1 << 1), FACET_KEY_VALUE_UNSAMPLED = (1 << 2), FACET_KEY_VALUE_ESTIMATED = (1 << 3), FACET_KEY_VALUE_COPIED = (1 << 4), } FACET_KEY_VALUE_FLAGS; #define facet_key_value_updated(k) ((k)->current_value.flags & FACET_KEY_VALUE_UPDATED) #define facet_key_value_empty(k) ((k)->current_value.flags & FACET_KEY_VALUE_EMPTY) #define facet_key_value_unsampled(k) ((k)->current_value.flags & FACET_KEY_VALUE_UNSAMPLED) #define facet_key_value_estimated(k) ((k)->current_value.flags & FACET_KEY_VALUE_ESTIMATED) #define facet_key_value_empty_or_unsampled_or_estimated(k) ((k)->current_value.flags & (FACET_KEY_VALUE_EMPTY|FACET_KEY_VALUE_UNSAMPLED|FACET_KEY_VALUE_ESTIMATED)) #define facet_key_value_copied(k) ((k)->current_value.flags & FACET_KEY_VALUE_COPIED) struct facet_key { FACETS *facets; FACETS_HASH hash; const char *name; FACET_KEY_OPTIONS options; bool default_selected_for_values; // the default "selected" for all values in the dictionary // members about the current row uint32_t key_found_in_row; uint32_t key_values_selected_in_row; uint32_t order; struct { bool enabled; uint32_t used; FACET_VALUE *ll; SIMPLE_HASHTABLE_VALUE ht; } values; struct { FACETS_HASH hash; FACET_KEY_VALUE_FLAGS flags; const char *raw; uint32_t raw_len; BUFFER *b; FACET_VALUE *v; } current_value; struct { FACET_VALUE *v; } empty_value; struct { FACET_VALUE *v; } unsampled_value; struct { FACET_VALUE *v; } estimated_value; struct { facet_dynamic_row_t cb; void *data; } dynamic; struct { bool view_only; facets_key_transformer_t cb; void *data; } transform; struct facet_key *prev, *next; }; struct facets { SIMPLE_PATTERN *visible_keys; SIMPLE_PATTERN *excluded_keys; SIMPLE_PATTERN *included_keys; FACETS_OPTIONS options; struct { usec_t start_ut; usec_t stop_ut; FACETS_ANCHOR_DIRECTION direction; } anchor; SIMPLE_PATTERN *query; // the full text search pattern size_t keys_filtered_by_query; // the number of fields we do full text search (constant) DICTIONARY *accepted_params; struct { size_t count; FACET_KEY *ll; SIMPLE_HASHTABLE_KEY ht; } keys; struct { // this is like a stack, of the keys that are used as facets size_t used; FACET_KEY *array[FACETS_KEYS_WITH_VALUES_MAX]; } keys_with_values; struct { // this is like a stack, of the keys that need to clean up between each row size_t used; FACET_KEY *array[FACETS_KEYS_IN_ROW_MAX]; } keys_in_row; FACET_ROW *base; // double linked list of the selected facets rows uint32_t items_to_return; uint32_t max_items_to_return; uint32_t order; struct { FACET_ROW_SEVERITY severity; size_t keys_matched_by_query_positive; // the number of fields matched the full text search (per row) size_t keys_matched_by_query_negative; // the number of fields matched the full text search (per row) } current_row; struct { usec_t after_ut; usec_t before_ut; } timeframe; struct { FACET_KEY *key; FACETS_HASH hash; char *chart; bool enabled; uint32_t slots; usec_t slot_width_ut; usec_t after_ut; usec_t before_ut; } histogram; struct { facet_row_severity_t cb; void *data; } severity; struct { FACET_ROW *last_added; size_t first; size_t forwards; size_t backwards; size_t skips_before; size_t skips_after; size_t prepends; size_t appends; size_t shifts; struct { size_t evaluated; size_t matched; size_t unsampled; size_t estimated; size_t created; size_t reused; } rows; struct { size_t registered; size_t unique; } keys; struct { size_t registered; size_t transformed; size_t dynamic; size_t empty; size_t unsampled; size_t estimated; size_t indexed; size_t inserts; size_t conflicts; } values; struct { size_t searches; } fts; } operations; struct { DICTIONARY *used_hashes_registry; } report; }; usec_t facets_row_oldest_ut(FACETS *facets) { if(facets->base) return facets->base->prev->usec; return 0; } usec_t facets_row_newest_ut(FACETS *facets) { if(facets->base) return facets->base->usec; return 0; } uint32_t facets_rows(FACETS *facets) { return facets->items_to_return; } // ---------------------------------------------------------------------------- static void facets_row_free(FACETS *facets __maybe_unused, FACET_ROW *row); static inline void facet_value_is_used(FACET_KEY *k, FACET_VALUE *v); static inline bool facets_key_is_facet(FACETS *facets, FACET_KEY *k); // ---------------------------------------------------------------------------- // The FACET_VALUE index within each FACET_KEY #define foreach_value_in_key(k, v) \ for((v) = (k)->values.ll; (v) ;(v) = (v)->next) #define foreach_value_in_key_done(v) do { ; } while(0) static inline void FACETS_VALUES_INDEX_CREATE(FACET_KEY *k) { k->values.ll = NULL; k->values.used = 0; simple_hashtable_init_VALUE(&k->values.ht, FACETS_VALUES_HASHTABLE_ENTRIES); } static inline void FACETS_VALUES_INDEX_DESTROY(FACET_KEY *k) { FACET_VALUE *v = k->values.ll; while(v) { FACET_VALUE *next = v->next; freez(v->histogram); freez((void *)v->name); freez(v); v = next; } k->values.ll = NULL; k->values.used = 0; k->values.enabled = false; simple_hashtable_destroy_VALUE(&k->values.ht); } static inline const char *facets_key_get_value(FACET_KEY *k) { return facet_key_value_copied(k) ? buffer_tostring(k->current_value.b) : k->current_value.raw; } static inline uint32_t facets_key_get_value_length(FACET_KEY *k) { return facet_key_value_copied(k) ? buffer_strlen(k->current_value.b) : k->current_value.raw_len; } static inline void facets_key_value_copy_to_buffer(FACET_KEY *k) { if(!facet_key_value_copied(k)) { buffer_contents_replace(k->current_value.b, k->current_value.raw, k->current_value.raw_len); k->current_value.flags |= FACET_KEY_VALUE_COPIED; } } static const char *facets_value_dup(const char *s, uint32_t len) { char *d = mallocz(len + 1); if(len) memcpy(d, s, len); d[len] = '\0'; return d; } static inline void FACET_VALUE_ADD_CONFLICT(FACET_KEY *k, FACET_VALUE *v, const FACET_VALUE * const nv) { if(!v->name && !v->name_len && nv->name && nv->name_len) { // an actual value, not a filter v->name = facets_value_dup(nv->name, nv->name_len); v->name_len = nv->name_len; } if(v->name && v->name_len) facet_value_is_used(k, v); internal_fatal(v->name && nv->name && v->name_len == nv->name_len && memcmp(v->name, nv->name, v->name_len) != 0, "value hash conflict: '%s' and '%s' have the same hash '%s'", v->name, nv->name, hash_to_static_string(v->hash)); k->facets->operations.values.conflicts++; } static inline FACET_VALUE *FACET_VALUE_GET_FROM_INDEX(FACET_KEY *k, FACETS_HASH hash) { SIMPLE_HASHTABLE_SLOT_VALUE *slot = simple_hashtable_get_slot_VALUE(&k->values.ht, hash, NULL, true); return SIMPLE_HASHTABLE_SLOT_DATA(slot); } static inline FACET_VALUE *FACET_VALUE_ADD_TO_INDEX(FACET_KEY *k, const FACET_VALUE * const tv) { SIMPLE_HASHTABLE_SLOT_VALUE *slot = simple_hashtable_get_slot_VALUE(&k->values.ht, tv->hash, NULL, true); if(SIMPLE_HASHTABLE_SLOT_DATA(slot)) { // already exists FACET_VALUE *v = SIMPLE_HASHTABLE_SLOT_DATA(slot); FACET_VALUE_ADD_CONFLICT(k, v, tv); return v; } // we have to add it FACET_VALUE *v = mallocz(sizeof(*v)); simple_hashtable_set_slot_VALUE(&k->values.ht, slot, tv->hash, v); memcpy(v, tv, sizeof(*v)); if(v->estimated || v->unsampled) { if(k->values.ll && k->values.ll->estimated) { FACET_VALUE *estimated = k->values.ll; DOUBLE_LINKED_LIST_INSERT_ITEM_AFTER_UNSAFE(k->values.ll, estimated, v, prev, next); } else DOUBLE_LINKED_LIST_PREPEND_ITEM_UNSAFE(k->values.ll, v, prev, next); } else DOUBLE_LINKED_LIST_APPEND_ITEM_UNSAFE(k->values.ll, v, prev, next); k->values.used++; if(!v->selected) v->selected = k->default_selected_for_values; if(v->name && v->name_len) { // an actual value, not a filter v->name = facets_value_dup(v->name, v->name_len); facet_value_is_used(k, v); } else { v->name = NULL; v->name_len = 0; } k->facets->operations.values.inserts++; return v; } static inline void FACET_VALUE_ADD_UNSAMPLED_VALUE_TO_INDEX(FACET_KEY *k) { static const FACET_VALUE tv = { .hash = FACETS_HASH_UNSAMPLED, .name = FACET_VALUE_UNSAMPLED, .name_len = sizeof(FACET_VALUE_UNSAMPLED) - 1, .unsampled = true, .color = "offline", }; k->current_value.hash = FACETS_HASH_UNSAMPLED; if(k->unsampled_value.v) { FACET_VALUE_ADD_CONFLICT(k, k->unsampled_value.v, &tv); k->current_value.v = k->unsampled_value.v; } else { FACET_VALUE *v = FACET_VALUE_ADD_TO_INDEX(k, &tv); v->unsampled = true; k->unsampled_value.v = v; k->current_value.v = v; } } static inline void FACET_VALUE_ADD_ESTIMATED_VALUE_TO_INDEX(FACET_KEY *k) { static const FACET_VALUE tv = { .hash = FACETS_HASH_ESTIMATED, .name = FACET_VALUE_ESTIMATED, .name_len = sizeof(FACET_VALUE_ESTIMATED) - 1, .estimated = true, .color = "generic", }; k->current_value.hash = FACETS_HASH_ESTIMATED; if(k->estimated_value.v) { FACET_VALUE_ADD_CONFLICT(k, k->estimated_value.v, &tv); k->current_value.v = k->estimated_value.v; } else { FACET_VALUE *v = FACET_VALUE_ADD_TO_INDEX(k, &tv); v->estimated = true; k->estimated_value.v = v; k->current_value.v = v; } } static inline void FACET_VALUE_ADD_EMPTY_VALUE_TO_INDEX(FACET_KEY *k) { static const FACET_VALUE tv = { .hash = FACETS_HASH_ZERO, .name = FACET_VALUE_UNSET, .name_len = sizeof(FACET_VALUE_UNSET) - 1, .empty = true, }; k->current_value.hash = FACETS_HASH_ZERO; if(k->empty_value.v) { FACET_VALUE_ADD_CONFLICT(k, k->empty_value.v, &tv); k->current_value.v = k->empty_value.v; } else { FACET_VALUE *v = FACET_VALUE_ADD_TO_INDEX(k, &tv); v->empty = true; k->empty_value.v = v; k->current_value.v = v; } } static inline void FACET_VALUE_ADD_CURRENT_VALUE_TO_INDEX(FACET_KEY *k) { static __thread FACET_VALUE tv = { 0 }; internal_fatal(!facet_key_value_updated(k), "trying to add a non-updated value to the index"); tv.name = facets_key_get_value(k); tv.name_len = facets_key_get_value_length(k); tv.hash = FACETS_HASH_FUNCTION(tv.name, tv.name_len); tv.empty = false; tv.estimated = false; tv.unsampled = false; k->current_value.v = FACET_VALUE_ADD_TO_INDEX(k, &tv); k->facets->operations.values.indexed++; } static inline void FACET_VALUE_ADD_OR_UPDATE_SELECTED(FACET_KEY *k, FACETS_HASH hash) { FACET_VALUE tv = { .hash = hash, .selected = true, .name = NULL, .name_len = 0, }; FACET_VALUE_ADD_TO_INDEX(k, &tv); } // ---------------------------------------------------------------------------- // The FACET_KEY index within each FACET #define foreach_key_in_facets(facets, k) \ for((k) = (facets)->keys.ll; (k) ;(k) = (k)->next) #define foreach_key_in_facets_done(k) do { ; } while(0) static inline void facet_key_late_init(FACETS *facets, FACET_KEY *k) { if(k->values.enabled) return; if(facets_key_is_facet(facets, k)) { FACETS_VALUES_INDEX_CREATE(k); k->values.enabled = true; if(facets->keys_with_values.used < FACETS_KEYS_WITH_VALUES_MAX) facets->keys_with_values.array[facets->keys_with_values.used++] = k; } } static inline void FACETS_KEYS_INDEX_CREATE(FACETS *facets) { facets->keys.ll = NULL; facets->keys.count = 0; facets->keys_with_values.used = 0; simple_hashtable_init_KEY(&facets->keys.ht, FACETS_KEYS_HASHTABLE_ENTRIES); } static inline void FACETS_KEYS_INDEX_DESTROY(FACETS *facets) { FACET_KEY *k = facets->keys.ll; while(k) { FACET_KEY *next = k->next; FACETS_VALUES_INDEX_DESTROY(k); buffer_free(k->current_value.b); freez((void *)k->name); freez(k); k = next; } facets->keys.ll = NULL; facets->keys.count = 0; facets->keys_with_values.used = 0; simple_hashtable_destroy_KEY(&facets->keys.ht); } static inline FACET_KEY *FACETS_KEY_GET_FROM_INDEX(FACETS *facets, FACETS_HASH hash) { SIMPLE_HASHTABLE_SLOT_KEY *slot = simple_hashtable_get_slot_KEY(&facets->keys.ht, hash, NULL, true); return SIMPLE_HASHTABLE_SLOT_DATA(slot); } bool facets_key_name_value_length_is_selected(FACETS *facets, const char *key, size_t key_length, const char *value, size_t value_length) { FACETS_HASH hash = FACETS_HASH_FUNCTION(key, key_length); FACET_KEY *k = FACETS_KEY_GET_FROM_INDEX(facets, hash); if(!k || k->default_selected_for_values) return false; hash = FACETS_HASH_FUNCTION(value, value_length); FACET_VALUE *v = FACET_VALUE_GET_FROM_INDEX(k, hash); return (v && v->selected) ? true : false; } void facets_add_possible_value_name_to_key(FACETS *facets, const char *key, size_t key_length, const char *value, size_t value_length) { FACETS_HASH hash = FACETS_HASH_FUNCTION(key, key_length); FACET_KEY *k = FACETS_KEY_GET_FROM_INDEX(facets, hash); if(!k) return; hash = FACETS_HASH_FUNCTION(value, value_length); FACET_VALUE *v = FACET_VALUE_GET_FROM_INDEX(k, hash); if(v && v->name && v->name_len) return; FACET_VALUE tv = { .hash = hash, .name = value, .name_len = value_length, }; FACET_VALUE_ADD_TO_INDEX(k, &tv); } static void facet_key_set_name(FACET_KEY *k, const char *name, size_t name_length) { internal_fatal(k->name && name && (strncmp(k->name, name, name_length) != 0 || k->name[name_length] != '\0'), "key hash conflict: '%s' and '%s' have the same hash", k->name, name); if(likely(k->name || !name || !name_length)) return; // an actual value, not a filter char buf[name_length + 1]; memcpy(buf, name, name_length); buf[name_length] = '\0'; internal_fatal(strchr(buf, '='), "found = in key"); k->name = strdupz(buf); facet_key_late_init(k->facets, k); } static inline FACET_KEY *FACETS_KEY_CREATE(FACETS *facets, FACETS_HASH hash, const char *name, size_t name_length, FACET_KEY_OPTIONS options) { facets->operations.keys.unique++; FACET_KEY *k = callocz(1, sizeof(*k)); k->hash = hash; k->facets = facets; k->options = options; k->current_value.b = buffer_create(sizeof(FACET_VALUE_UNSET), NULL); k->default_selected_for_values = true; if(!(k->options & FACET_KEY_OPTION_REORDER)) k->order = facets->order++; if((k->options & FACET_KEY_OPTION_FTS) || (facets->options & FACETS_OPTION_ALL_KEYS_FTS)) facets->keys_filtered_by_query++; facet_key_set_name(k, name, name_length); DOUBLE_LINKED_LIST_APPEND_ITEM_UNSAFE(facets->keys.ll, k, prev, next); facets->keys.count++; return k; } static inline FACET_KEY *FACETS_KEY_ADD_TO_INDEX(FACETS *facets, FACETS_HASH hash, const char *name, size_t name_length, FACET_KEY_OPTIONS options) { facets->operations.keys.registered++; SIMPLE_HASHTABLE_SLOT_KEY *slot = simple_hashtable_get_slot_KEY(&facets->keys.ht, hash, NULL, true); if(unlikely(!SIMPLE_HASHTABLE_SLOT_DATA(slot))) { // we have to add it FACET_KEY *k = FACETS_KEY_CREATE(facets, hash, name, name_length, options); simple_hashtable_set_slot_KEY(&facets->keys.ht, slot, hash, k); return k; } // already in the index FACET_KEY *k = SIMPLE_HASHTABLE_SLOT_DATA(slot); facet_key_set_name(k, name, name_length); if(unlikely(k->options & FACET_KEY_OPTION_REORDER)) { k->order = facets->order++; k->options &= ~FACET_KEY_OPTION_REORDER; } return k; } bool facets_key_name_is_filter(FACETS *facets, const char *key) { FACETS_HASH hash = FACETS_HASH_FUNCTION(key, strlen(key)); FACET_KEY *k = FACETS_KEY_GET_FROM_INDEX(facets, hash); return (!k || k->default_selected_for_values) ? false : true; } bool facets_key_name_is_facet(FACETS *facets, const char *key) { size_t key_len = strlen(key); FACETS_HASH hash = FACETS_HASH_FUNCTION(key, key_len); FACET_KEY *k = FACETS_KEY_ADD_TO_INDEX(facets, hash, key, key_len, 0); return (k && (k->options & FACET_KEY_OPTION_FACET)); } // ---------------------------------------------------------------------------- size_t facets_histogram_slots(FACETS *facets) { return facets->histogram.slots; } static usec_t calculate_histogram_bar_width(usec_t after_ut, usec_t before_ut) { // Array of valid durations in seconds static time_t valid_durations_s[] = { 1, 2, 5, 10, 15, 30, // seconds 1 * 60, 2 * 60, 3 * 60, 5 * 60, 10 * 60, 15 * 60, 30 * 60, // minutes 1 * 3600, 2 * 3600, 6 * 3600, 8 * 3600, 12 * 3600, // hours 1 * 86400, 2 * 86400, 3 * 86400, 5 * 86400, 7 * 86400, 14 * 86400, // days 1 * (30*86400) // months }; static int array_size = sizeof(valid_durations_s) / sizeof(valid_durations_s[0]); usec_t duration_ut = before_ut - after_ut; usec_t bar_width_ut = 1 * USEC_PER_SEC; for (int i = array_size - 1; i >= 0; --i) { if (duration_ut / (valid_durations_s[i] * USEC_PER_SEC) >= FACETS_HISTOGRAM_COLUMNS) { bar_width_ut = valid_durations_s[i] * USEC_PER_SEC; break; } } return bar_width_ut; } static inline usec_t facets_histogram_slot_baseline_ut(FACETS *facets, usec_t ut) { usec_t delta_ut = ut % facets->histogram.slot_width_ut; return ut - delta_ut; } void facets_set_timeframe_and_histogram_by_id(FACETS *facets, const char *key_id, usec_t after_ut, usec_t before_ut) { if(after_ut > before_ut) { usec_t t = after_ut; after_ut = before_ut; before_ut = t; } facets->histogram.enabled = true; if(key_id && *key_id && strlen(key_id) == FACET_STRING_HASH_SIZE - 1) { facets->histogram.chart = strdupz(key_id); facets->histogram.hash = str_to_facets_hash(facets->histogram.chart); } else { freez(facets->histogram.chart); facets->histogram.chart = NULL; facets->histogram.hash = FACETS_HASH_ZERO; } facets->timeframe.after_ut = after_ut; facets->timeframe.before_ut = before_ut; facets->histogram.slot_width_ut = calculate_histogram_bar_width(after_ut, before_ut); facets->histogram.after_ut = facets_histogram_slot_baseline_ut(facets, after_ut); facets->histogram.before_ut = facets_histogram_slot_baseline_ut(facets, before_ut) + facets->histogram.slot_width_ut; facets->histogram.slots = (facets->histogram.before_ut - facets->histogram.after_ut) / facets->histogram.slot_width_ut + 1; internal_fatal(after_ut < facets->histogram.after_ut, "histogram after_ut is not less or equal to wanted after_ut"); internal_fatal(before_ut > facets->histogram.before_ut, "histogram before_ut is not more or equal to wanted before_ut"); if(facets->histogram.slots > 1000) { facets->histogram.slots = 1000 + 1; facets->histogram.slot_width_ut = (facets->histogram.before_ut - facets->histogram.after_ut) / 1000; } } void facets_set_timeframe_and_histogram_by_name(FACETS *facets, const char *key_name, usec_t after_ut, usec_t before_ut) { char hash_str[FACET_STRING_HASH_SIZE]; FACETS_HASH hash = FACETS_HASH_FUNCTION(key_name, strlen(key_name)); facets_hash_to_str(hash, hash_str); facets_set_timeframe_and_histogram_by_id(facets, hash_str, after_ut, before_ut); } static inline uint32_t facets_histogram_slot_at_time_ut(FACETS *facets, usec_t usec, FACET_VALUE *v) { if(unlikely(!v->histogram)) v->histogram = callocz(facets->histogram.slots, sizeof(*v->histogram)); usec_t base_ut = facets_histogram_slot_baseline_ut(facets, usec); if(unlikely(base_ut < facets->histogram.after_ut)) base_ut = facets->histogram.after_ut; if(unlikely(base_ut > facets->histogram.before_ut)) base_ut = facets->histogram.before_ut; uint32_t slot = (base_ut - facets->histogram.after_ut) / facets->histogram.slot_width_ut; if(unlikely(slot >= facets->histogram.slots)) slot = facets->histogram.slots - 1; return slot; } static inline void facets_histogram_update_value_slot(FACETS *facets, usec_t usec, FACET_VALUE *v) { uint32_t slot = facets_histogram_slot_at_time_ut(facets, usec, v); v->histogram[slot]++; } static inline void facets_histogram_update_value(FACETS *facets, usec_t usec) { if(!facets->histogram.enabled || !facets->histogram.key || !facets->histogram.key->values.enabled || !facet_key_value_updated(facets->histogram.key) || usec < facets->histogram.after_ut || usec > facets->histogram.before_ut) return; FACET_VALUE *v = facets->histogram.key->current_value.v; facets_histogram_update_value_slot(facets, usec, v); } static usec_t overlap_duration_ut(usec_t start1, usec_t end1, usec_t start2, usec_t end2) { usec_t overlap_start = MAX(start1, start2); usec_t overlap_end = MIN(end1, end2); if (overlap_start < overlap_end) return overlap_end - overlap_start; else return 0; // No overlap } void facets_update_estimations(FACETS *facets, usec_t from_ut, usec_t to_ut, size_t entries) { if(unlikely(!facets->histogram.enabled)) return; if(unlikely(!overlap_duration_ut(facets->histogram.after_ut, facets->histogram.before_ut, from_ut, to_ut))) return; facets->operations.rows.evaluated += entries; facets->operations.rows.matched += entries; facets->operations.rows.estimated += entries; if (!facets->histogram.enabled || !facets->histogram.key || !facets->histogram.key->values.enabled) return; if (from_ut < facets->histogram.after_ut) from_ut = facets->histogram.after_ut; if (to_ut > facets->histogram.before_ut) to_ut = facets->histogram.before_ut; if (!facets->histogram.key->estimated_value.v) FACET_VALUE_ADD_ESTIMATED_VALUE_TO_INDEX(facets->histogram.key); FACET_VALUE *v = facets->histogram.key->estimated_value.v; size_t slots = 0; size_t total_ut = to_ut - from_ut; ssize_t remaining_entries = (ssize_t)entries; size_t slot = facets_histogram_slot_at_time_ut(facets, from_ut, v); for(; slot < facets->histogram.slots ;slot++) { usec_t slot_start_ut = facets->histogram.after_ut + slot * facets->histogram.slot_width_ut; usec_t slot_end_ut = slot_start_ut + facets->histogram.slot_width_ut; if(slot_start_ut > to_ut) break; usec_t overlap_ut = overlap_duration_ut(from_ut, to_ut, slot_start_ut, slot_end_ut); size_t slot_entries = (overlap_ut * entries) / total_ut; v->histogram[slot] += slot_entries; remaining_entries -= (ssize_t)slot_entries; slots++; } // Check if all entries are assigned // This should always be true if the distribution is correct internal_fatal(remaining_entries < 0 || remaining_entries >= (ssize_t)(slots), "distribution of estimations is not accurate - there are %zd remaining entries", remaining_entries); } void facets_row_finished_unsampled(FACETS *facets, usec_t usec) { facets->operations.rows.evaluated++; facets->operations.rows.matched++; facets->operations.rows.unsampled++; if(!facets->histogram.enabled || !facets->histogram.key || !facets->histogram.key->values.enabled || usec < facets->histogram.after_ut || usec > facets->histogram.before_ut) return; if(!facets->histogram.key->unsampled_value.v) FACET_VALUE_ADD_UNSAMPLED_VALUE_TO_INDEX(facets->histogram.key); FACET_VALUE *v = facets->histogram.key->unsampled_value.v; facets_histogram_update_value_slot(facets, usec, v); facets_reset_key(facets->histogram.key); } static const char *facets_key_name_cached(FACET_KEY *k, DICTIONARY *used_hashes_registry) { if(k->name) { if(used_hashes_registry && !k->default_selected_for_values) { char hash_str[FACET_STRING_HASH_SIZE]; facets_hash_to_str(k->hash, hash_str); dictionary_set(used_hashes_registry, hash_str, (void *)k->name, strlen(k->name) + 1); } return k->name; } // key has no name const char *name = "[UNAVAILABLE_FIELD]"; if(used_hashes_registry) { char hash_str[FACET_STRING_HASH_SIZE]; facets_hash_to_str(k->hash, hash_str); const char *s = dictionary_get(used_hashes_registry, hash_str); if(s) name = s; } return name; } static const char *facets_key_value_cached(FACET_KEY *k, FACET_VALUE *v, DICTIONARY *used_hashes_registry) { if(v->empty || v->estimated || v->unsampled) return v->name; if(v->name && v->name_len) { if(used_hashes_registry && !k->default_selected_for_values && v->selected) { char hash_str[FACET_STRING_HASH_SIZE]; facets_hash_to_str(v->hash, hash_str); dictionary_set(used_hashes_registry, hash_str, (void *)v->name, v->name_len + 1); } return v->name; } // key has no name const char *name = "[unavailable field]"; if(used_hashes_registry) { char hash_str[FACET_STRING_HASH_SIZE]; facets_hash_to_str(v->hash, hash_str); const char *s = dictionary_get(used_hashes_registry, hash_str); if(s) name = s; } return name; } static inline void facets_key_value_transformed(FACETS *facets, FACET_KEY *k, FACET_VALUE *v, BUFFER *dst, FACETS_TRANSFORMATION_SCOPE scope) { buffer_flush(dst); if(v->empty || v->unsampled || v->estimated) buffer_strcat(dst, v->name); else if(k->transform.cb && k->transform.view_only) { buffer_contents_replace(dst, v->name, v->name_len); k->transform.cb(facets, dst, scope, k->transform.data); } else buffer_strcat(dst, facets_key_value_cached(k, v, facets->report.used_hashes_registry)); } static inline void facets_histogram_value_names(BUFFER *wb, FACETS *facets __maybe_unused, FACET_KEY *k, const char *key, const char *first_key) { CLEAN_BUFFER *tb = buffer_create(0, NULL); buffer_json_member_add_array(wb, key); { if(first_key) buffer_json_add_array_item_string(wb, first_key); if(k && k->values.enabled) { FACET_VALUE *v; foreach_value_in_key(k, v) { if (unlikely(!v->histogram)) continue; facets_key_value_transformed(facets, k, v, tb, FACETS_TRANSFORM_HISTOGRAM); buffer_json_add_array_item_string(wb, buffer_tostring(tb)); } foreach_value_in_key_done(v); } } buffer_json_array_close(wb); // key } static inline void facets_histogram_value_colors(BUFFER *wb, FACETS *facets __maybe_unused, FACET_KEY *k, const char *key) { buffer_json_member_add_array(wb, key); { if(k && k->values.enabled) { FACET_VALUE *v; foreach_value_in_key(k, v) { if (unlikely(!v->histogram)) continue; buffer_json_add_array_item_string(wb, v->color); } foreach_value_in_key_done(v); } } buffer_json_array_close(wb); // key } static inline void facets_histogram_value_units(BUFFER *wb, FACETS *facets __maybe_unused, FACET_KEY *k, const char *key) { buffer_json_member_add_array(wb, key); { if(k && k->values.enabled) { FACET_VALUE *v; foreach_value_in_key(k, v) { if (unlikely(!v->histogram)) continue; buffer_json_add_array_item_string(wb, "events"); } foreach_value_in_key_done(v); } } buffer_json_array_close(wb); // key } static inline void facets_histogram_value_min(BUFFER *wb, FACETS *facets __maybe_unused, FACET_KEY *k, const char *key) { buffer_json_member_add_array(wb, key); { if(k && k->values.enabled) { FACET_VALUE *v; foreach_value_in_key(k, v) { if (unlikely(!v->histogram)) continue; buffer_json_add_array_item_uint64(wb, v->min); } foreach_value_in_key_done(v); } } buffer_json_array_close(wb); // key } static inline void facets_histogram_value_max(BUFFER *wb, FACETS *facets __maybe_unused, FACET_KEY *k, const char *key) { buffer_json_member_add_array(wb, key); { if(k && k->values.enabled) { FACET_VALUE *v; foreach_value_in_key(k, v) { if (unlikely(!v->histogram)) continue; buffer_json_add_array_item_uint64(wb, v->max); } foreach_value_in_key_done(v); } } buffer_json_array_close(wb); // key } static inline void facets_histogram_value_avg(BUFFER *wb, FACETS *facets __maybe_unused, FACET_KEY *k, const char *key) { buffer_json_member_add_array(wb, key); { if(k && k->values.enabled) { FACET_VALUE *v; foreach_value_in_key(k, v) { if (unlikely(!v->histogram)) continue; buffer_json_add_array_item_double(wb, (double) v->sum / (double) facets->histogram.slots); } foreach_value_in_key_done(v); } } buffer_json_array_close(wb); // key } static inline void facets_histogram_value_arp(BUFFER *wb, FACETS *facets __maybe_unused, FACET_KEY *k, const char *key) { buffer_json_member_add_array(wb, key); { if(k && k->values.enabled) { FACET_VALUE *v; foreach_value_in_key(k, v) { if (unlikely(!v->histogram)) continue; buffer_json_add_array_item_uint64(wb, 0); } foreach_value_in_key_done(v); } } buffer_json_array_close(wb); // key } static inline void facets_histogram_value_con(BUFFER *wb, FACETS *facets __maybe_unused, FACET_KEY *k, const char *key, uint32_t sum) { buffer_json_member_add_array(wb, key); { if(k && k->values.enabled) { FACET_VALUE *v; foreach_value_in_key(k, v) { if (unlikely(!v->histogram)) continue; buffer_json_add_array_item_double(wb, (double) v->sum * 100.0 / (double) sum); } foreach_value_in_key_done(v); } } buffer_json_array_close(wb); // key } static void facets_histogram_generate(FACETS *facets, FACET_KEY *k, BUFFER *wb) { CLEAN_BUFFER *tmp = buffer_create(0, NULL); size_t dimensions = 0; uint32_t min = UINT32_MAX, max = 0, sum = 0, count = 0; if(k && k->values.enabled) { FACET_VALUE *v; foreach_value_in_key(k, v) { if (unlikely(!v->histogram)) continue; dimensions++; v->min = UINT32_MAX; v->max = 0; v->sum = 0; for(uint32_t i = 0; i < facets->histogram.slots ;i++) { uint32_t n = v->histogram[i]; if(n < min) min = n; if(n > max) max = n; sum += n; count++; if(n < v->min) v->min = n; if(n > v->max) v->max = n; v->sum += n; } } foreach_value_in_key_done(v); } buffer_json_member_add_object(wb, "summary"); { // summary.nodes buffer_json_member_add_array(wb, "nodes"); { buffer_json_add_array_item_object(wb); // node { buffer_json_member_add_string(wb, "mg", "default"); buffer_json_member_add_string(wb, "nm", "facets.histogram"); buffer_json_member_add_uint64(wb, "ni", 0); buffer_json_member_add_object(wb, "st"); { buffer_json_member_add_uint64(wb, "ai", 0); buffer_json_member_add_uint64(wb, "code", 200); buffer_json_member_add_string(wb, "msg", ""); } buffer_json_object_close(wb); // st if(dimensions) { buffer_json_member_add_object(wb, "is"); { buffer_json_member_add_uint64(wb, "sl", 1); buffer_json_member_add_uint64(wb, "qr", 1); } buffer_json_object_close(wb); // is buffer_json_member_add_object(wb, "ds"); { buffer_json_member_add_uint64(wb, "sl", dimensions); buffer_json_member_add_uint64(wb, "qr", dimensions); } buffer_json_object_close(wb); // ds } if(count) { buffer_json_member_add_object(wb, "sts"); { buffer_json_member_add_uint64(wb, "min", min); buffer_json_member_add_uint64(wb, "max", max); buffer_json_member_add_double(wb, "avg", (double) sum / (double) count); buffer_json_member_add_double(wb, "con", 100.0); } buffer_json_object_close(wb); // sts } } buffer_json_object_close(wb); // node } buffer_json_array_close(wb); // nodes // summary.contexts buffer_json_member_add_array(wb, "contexts"); { buffer_json_add_array_item_object(wb); // context { buffer_json_member_add_string(wb, "id", "facets.histogram"); if(dimensions) { buffer_json_member_add_object(wb, "is"); { buffer_json_member_add_uint64(wb, "sl", 1); buffer_json_member_add_uint64(wb, "qr", 1); } buffer_json_object_close(wb); // is buffer_json_member_add_object(wb, "ds"); { buffer_json_member_add_uint64(wb, "sl", dimensions); buffer_json_member_add_uint64(wb, "qr", dimensions); } buffer_json_object_close(wb); // ds } if(count) { buffer_json_member_add_object(wb, "sts"); { buffer_json_member_add_uint64(wb, "min", min); buffer_json_member_add_uint64(wb, "max", max); buffer_json_member_add_double(wb, "avg", (double) sum / (double) count); buffer_json_member_add_double(wb, "con", 100.0); } buffer_json_object_close(wb); // sts } } buffer_json_object_close(wb); // context } buffer_json_array_close(wb); // contexts // summary.instances buffer_json_member_add_array(wb, "instances"); { buffer_json_add_array_item_object(wb); // instance { buffer_json_member_add_string(wb, "id", "facets.histogram"); buffer_json_member_add_uint64(wb, "ni", 0); if(dimensions) { buffer_json_member_add_object(wb, "ds"); { buffer_json_member_add_uint64(wb, "sl", dimensions); buffer_json_member_add_uint64(wb, "qr", dimensions); } buffer_json_object_close(wb); // ds } if(count) { buffer_json_member_add_object(wb, "sts"); { buffer_json_member_add_uint64(wb, "min", min); buffer_json_member_add_uint64(wb, "max", max); buffer_json_member_add_double(wb, "avg", (double) sum / (double) count); buffer_json_member_add_double(wb, "con", 100.0); } buffer_json_object_close(wb); // sts } } buffer_json_object_close(wb); // instance } buffer_json_array_close(wb); // instances // summary.dimensions buffer_json_member_add_array(wb, "dimensions"); if(dimensions && k && k->values.enabled) { size_t pri = 0; FACET_VALUE *v; foreach_value_in_key(k, v) { if(unlikely(!v->histogram)) continue; buffer_json_add_array_item_object(wb); // dimension { facets_key_value_transformed(facets, k, v, tmp, FACETS_TRANSFORM_HISTOGRAM); buffer_json_member_add_string(wb, "id", buffer_tostring(tmp)); buffer_json_member_add_object(wb, "ds"); { buffer_json_member_add_uint64(wb, "sl", 1); buffer_json_member_add_uint64(wb, "qr", 1); } buffer_json_object_close(wb); // ds buffer_json_member_add_object(wb, "sts"); { buffer_json_member_add_uint64(wb, "min", v->min); buffer_json_member_add_uint64(wb, "max", v->max); buffer_json_member_add_double(wb, "avg", (double)v->sum / (double)facets->histogram.slots); buffer_json_member_add_double(wb, "con", (double)v->sum * 100.0 / (double)sum); } buffer_json_object_close(wb); // sts buffer_json_member_add_uint64(wb, "pri", pri++); } buffer_json_object_close(wb); // dimension } foreach_value_in_key_done(v); } buffer_json_array_close(wb); // dimensions buffer_json_member_add_array(wb, "labels"); buffer_json_array_close(wb); // labels buffer_json_member_add_array(wb, "alerts"); buffer_json_array_close(wb); // alerts } buffer_json_object_close(wb); // summary buffer_json_member_add_object(wb, "totals"); { buffer_json_member_add_object(wb, "nodes"); { buffer_json_member_add_uint64(wb, "sl", 1); buffer_json_member_add_uint64(wb, "qr", 1); } buffer_json_object_close(wb); // nodes if(dimensions) { buffer_json_member_add_object(wb, "contexts"); { buffer_json_member_add_uint64(wb, "sl", 1); buffer_json_member_add_uint64(wb, "qr", 1); } buffer_json_object_close(wb); // contexts buffer_json_member_add_object(wb, "instances"); { buffer_json_member_add_uint64(wb, "sl", 1); buffer_json_member_add_uint64(wb, "qr", 1); } buffer_json_object_close(wb); // instances buffer_json_member_add_object(wb, "dimensions"); { buffer_json_member_add_uint64(wb, "sl", dimensions); buffer_json_member_add_uint64(wb, "qr", dimensions); } buffer_json_object_close(wb); // dimension } } buffer_json_object_close(wb); // totals buffer_json_member_add_object(wb, "result"); { facets_histogram_value_names(wb, facets, k, "labels", "time"); buffer_json_member_add_object(wb, "point"); { buffer_json_member_add_uint64(wb, "value", 0); buffer_json_member_add_uint64(wb, "arp", 1); buffer_json_member_add_uint64(wb, "pa", 2); } buffer_json_object_close(wb); // point buffer_json_member_add_array(wb, "data"); if(k && k->values.enabled) { usec_t t = facets->histogram.after_ut; for(uint32_t i = 0; i < facets->histogram.slots ;i++) { buffer_json_add_array_item_array(wb); // row { buffer_json_add_array_item_time_ms(wb, t / USEC_PER_SEC); FACET_VALUE *v; foreach_value_in_key(k, v) { if (unlikely(!v->histogram)) continue; buffer_json_add_array_item_array(wb); // point buffer_json_add_array_item_uint64(wb, v->histogram[i]); buffer_json_add_array_item_uint64(wb, 0); // arp - anomaly rate buffer_json_add_array_item_uint64(wb, 0); // pa - point annotation buffer_json_array_close(wb); // point } foreach_value_in_key_done(v); } buffer_json_array_close(wb); // row t += facets->histogram.slot_width_ut; } } buffer_json_array_close(wb); //data } buffer_json_object_close(wb); // result buffer_json_member_add_object(wb, "db"); { buffer_json_member_add_uint64(wb, "tiers", 1); buffer_json_member_add_uint64(wb, "update_every", facets->histogram.slot_width_ut / USEC_PER_SEC); // we should add these only when we know the retention of the db // buffer_json_member_add_time_t(wb, "first_entry", facets->histogram.after_ut / USEC_PER_SEC); // buffer_json_member_add_time_t(wb, "last_entry", facets->histogram.before_ut / USEC_PER_SEC); buffer_json_member_add_string(wb, "units", "events"); buffer_json_member_add_object(wb, "dimensions"); { facets_histogram_value_names(wb, facets, k, "ids", NULL); facets_histogram_value_units(wb, facets, k, "units"); buffer_json_member_add_object(wb, "sts"); { facets_histogram_value_min(wb, facets, k, "min"); facets_histogram_value_max(wb, facets, k, "max"); facets_histogram_value_avg(wb, facets, k, "avg"); facets_histogram_value_arp(wb, facets, k, "arp"); facets_histogram_value_con(wb, facets, k, "con", sum); } buffer_json_object_close(wb); // sts } buffer_json_object_close(wb); // dimensions buffer_json_member_add_array(wb, "per_tier"); { buffer_json_add_array_item_object(wb); // tier0 { buffer_json_member_add_uint64(wb, "tier", 0); buffer_json_member_add_uint64(wb, "queries", 1); buffer_json_member_add_uint64(wb, "points", count); buffer_json_member_add_time_t(wb, "update_every", facets->histogram.slot_width_ut / USEC_PER_SEC); // we should add these only when we know the retention of the db // buffer_json_member_add_time_t(wb, "first_entry", facets->histogram.after_ut / USEC_PER_SEC); // buffer_json_member_add_time_t(wb, "last_entry", facets->histogram.before_ut / USEC_PER_SEC); } buffer_json_object_close(wb); // tier0 } buffer_json_array_close(wb); // per_tier } buffer_json_object_close(wb); // db buffer_json_member_add_object(wb, "view"); { char title[1024 + 1] = "Events Distribution"; FACET_KEY *kt = FACETS_KEY_GET_FROM_INDEX(facets, facets->histogram.hash); if(kt && kt->name) snprintfz(title, sizeof(title) - 1, "Events Distribution by %s", kt->name); buffer_json_member_add_string(wb, "title", title); buffer_json_member_add_time_t(wb, "update_every", facets->histogram.slot_width_ut / USEC_PER_SEC); buffer_json_member_add_time_t(wb, "after", facets->histogram.after_ut / USEC_PER_SEC); buffer_json_member_add_time_t(wb, "before", facets->histogram.before_ut / USEC_PER_SEC); buffer_json_member_add_string(wb, "units", "events"); buffer_json_member_add_string(wb, "chart_type", "stackedBar"); buffer_json_member_add_object(wb, "dimensions"); { buffer_json_member_add_array(wb, "grouped_by"); { buffer_json_add_array_item_string(wb, "dimension"); } buffer_json_array_close(wb); // grouped_by facets_histogram_value_names(wb, facets, k, "ids", NULL); facets_histogram_value_names(wb, facets, k, "names", NULL); facets_histogram_value_colors(wb, facets, k, "colors"); facets_histogram_value_units(wb, facets, k, "units"); buffer_json_member_add_object(wb, "sts"); { facets_histogram_value_min(wb, facets, k, "min"); facets_histogram_value_max(wb, facets, k, "max"); facets_histogram_value_avg(wb, facets, k, "avg"); facets_histogram_value_arp(wb, facets, k, "arp"); facets_histogram_value_con(wb, facets, k, "con", sum); } buffer_json_object_close(wb); // sts } buffer_json_object_close(wb); // dimensions buffer_json_member_add_uint64(wb, "min", min); buffer_json_member_add_uint64(wb, "max", max); } buffer_json_object_close(wb); // view buffer_json_member_add_array(wb, "agents"); { buffer_json_add_array_item_object(wb); // agent { buffer_json_member_add_string(wb, "mg", "default"); buffer_json_member_add_string(wb, "nm", "facets.histogram"); buffer_json_member_add_time_t(wb, "now", now_realtime_sec()); buffer_json_member_add_uint64(wb, "ai", 0); } buffer_json_object_close(wb); // agent } buffer_json_array_close(wb); // agents } // ---------------------------------------------------------------------------- static inline void facet_value_is_used(FACET_KEY *k, FACET_VALUE *v) { if(!k->key_found_in_row) v->rows_matching_facet_value++; k->key_found_in_row++; if(v->selected) k->key_values_selected_in_row++; } static inline bool facets_key_is_facet(FACETS *facets, FACET_KEY *k) { bool included = true, excluded = false, never = false; if(k->options & (FACET_KEY_OPTION_FACET | FACET_KEY_OPTION_NO_FACET | FACET_KEY_OPTION_NEVER_FACET)) { if(k->options & FACET_KEY_OPTION_FACET) { included = true; excluded = false; never = false; } else if(k->options & (FACET_KEY_OPTION_NO_FACET | FACET_KEY_OPTION_NEVER_FACET)) { included = false; excluded = true; never = true; } } else { if (facets->included_keys) { if (!simple_pattern_matches(facets->included_keys, k->name)) included = false; } if (facets->excluded_keys) { if (simple_pattern_matches(facets->excluded_keys, k->name)) { excluded = true; never = true; } } } if(included && !excluded) { k->options |= FACET_KEY_OPTION_FACET; k->options &= ~FACET_KEY_OPTION_NO_FACET; return true; } k->options |= FACET_KEY_OPTION_NO_FACET; k->options &= ~FACET_KEY_OPTION_FACET; if(never) k->options |= FACET_KEY_OPTION_NEVER_FACET; return false; } // ---------------------------------------------------------------------------- FACETS *facets_create(uint32_t items_to_return, FACETS_OPTIONS options, const char *visible_keys, const char *facet_keys, const char *non_facet_keys) { FACETS *facets = callocz(1, sizeof(FACETS)); facets->options = options; FACETS_KEYS_INDEX_CREATE(facets); if(facet_keys && *facet_keys) facets->included_keys = simple_pattern_create(facet_keys, "|", SIMPLE_PATTERN_EXACT, true); if(non_facet_keys && *non_facet_keys) facets->excluded_keys = simple_pattern_create(non_facet_keys, "|", SIMPLE_PATTERN_EXACT, true); if(visible_keys && *visible_keys) facets->visible_keys = simple_pattern_create(visible_keys, "|", SIMPLE_PATTERN_EXACT, true); facets->max_items_to_return = items_to_return > 1 ? items_to_return : 2; facets->anchor.start_ut = 0; facets->anchor.stop_ut = 0; facets->anchor.direction = FACETS_ANCHOR_DIRECTION_BACKWARD; facets->order = 1; return facets; } void facets_destroy(FACETS *facets) { dictionary_destroy(facets->accepted_params); FACETS_KEYS_INDEX_DESTROY(facets); simple_pattern_free(facets->visible_keys); simple_pattern_free(facets->included_keys); simple_pattern_free(facets->excluded_keys); while(facets->base) { FACET_ROW *r = facets->base; DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(facets->base, r, prev, next); facets_row_free(facets, r); } freez(facets->histogram.chart); freez(facets); } void facets_accepted_param(FACETS *facets, const char *param) { if(!facets->accepted_params) facets->accepted_params = dictionary_create(DICT_OPTION_SINGLE_THREADED|DICT_OPTION_DONT_OVERWRITE_VALUE); dictionary_set(facets->accepted_params, param, NULL, 0); } static inline FACET_KEY *facets_register_key_name_length(FACETS *facets, const char *key, size_t key_length, FACET_KEY_OPTIONS options) { return FACETS_KEY_ADD_TO_INDEX(facets, FACETS_HASH_FUNCTION(key, key_length), key, key_length, options); } inline FACET_KEY *facets_register_key_name(FACETS *facets, const char *key, FACET_KEY_OPTIONS options) { return facets_register_key_name_length(facets, key, strlen(key), options); } inline FACET_KEY *facets_register_key_name_transformation(FACETS *facets, const char *key, FACET_KEY_OPTIONS options, facets_key_transformer_t cb, void *data) { FACET_KEY *k = facets_register_key_name(facets, key, options); k->transform.cb = cb; k->transform.data = data; k->transform.view_only = (options & FACET_KEY_OPTION_TRANSFORM_VIEW) ? true : false; return k; } inline FACET_KEY *facets_register_dynamic_key_name(FACETS *facets, const char *key, FACET_KEY_OPTIONS options, facet_dynamic_row_t cb, void *data) { FACET_KEY *k = facets_register_key_name(facets, key, options); k->dynamic.cb = cb; k->dynamic.data = data; return k; } void facets_set_query(FACETS *facets, const char *query) { if(!query) return; facets->query = simple_pattern_create(query, "|", SIMPLE_PATTERN_SUBSTRING, false); } void facets_set_items(FACETS *facets, uint32_t items) { facets->max_items_to_return = items > 1 ? items : 2; } void facets_set_anchor(FACETS *facets, usec_t start_ut, usec_t stop_ut, FACETS_ANCHOR_DIRECTION direction) { facets->anchor.start_ut = start_ut; facets->anchor.stop_ut = stop_ut; facets->anchor.direction = direction; if((facets->anchor.direction == FACETS_ANCHOR_DIRECTION_BACKWARD && facets->anchor.start_ut && facets->anchor.start_ut < facets->anchor.stop_ut) || (facets->anchor.direction == FACETS_ANCHOR_DIRECTION_FORWARD && facets->anchor.stop_ut && facets->anchor.stop_ut < facets->anchor.start_ut)) { internal_error(true, "start and stop anchors are flipped"); facets->anchor.start_ut = stop_ut; facets->anchor.stop_ut = start_ut; } } void facets_enable_slice_mode(FACETS *facets) { facets->options |= FACETS_OPTION_DONT_SEND_EMPTY_VALUE_FACETS | FACETS_OPTION_SORT_FACETS_ALPHABETICALLY; } inline FACET_KEY *facets_register_facet_id(FACETS *facets, const char *key_id, FACET_KEY_OPTIONS options) { if(!is_valid_string_hash(key_id)) return NULL; FACETS_HASH hash = str_to_facets_hash(key_id); internal_error(strcmp(hash_to_static_string(hash), key_id) != 0, "Regenerating the user supplied key, does not produce the same hash string"); FACET_KEY *k = FACETS_KEY_ADD_TO_INDEX(facets, hash, NULL, 0, options); k->options |= FACET_KEY_OPTION_FACET; k->options &= ~FACET_KEY_OPTION_NO_FACET; facet_key_late_init(facets, k); return k; } void facets_register_facet_id_filter(FACETS *facets, const char *key_id, char *value_id, FACET_KEY_OPTIONS options) { FACET_KEY *k = facets_register_facet_id(facets, key_id, options); if(k) { if(is_valid_string_hash(value_id)) { k->default_selected_for_values = false; FACET_VALUE_ADD_OR_UPDATE_SELECTED(k, str_to_facets_hash(value_id)); } } } void facets_set_current_row_severity(FACETS *facets, FACET_ROW_SEVERITY severity) { facets->current_row.severity = severity; } void facets_register_row_severity(FACETS *facets, facet_row_severity_t cb, void *data) { facets->severity.cb = cb; facets->severity.data = data; } void facets_set_additional_options(FACETS *facets, FACETS_OPTIONS options) { facets->options |= options; } // ---------------------------------------------------------------------------- static inline void facets_key_set_unsampled_value(FACETS *facets, FACET_KEY *k) { if(likely(!facet_key_value_updated(k) && facets->keys_in_row.used < FACETS_KEYS_IN_ROW_MAX)) facets->keys_in_row.array[facets->keys_in_row.used++] = k; k->current_value.flags |= FACET_KEY_VALUE_UPDATED | FACET_KEY_VALUE_UNSAMPLED; facets->operations.values.registered++; facets->operations.values.unsampled++; // no need to copy the UNSET value // empty values are exported as empty k->current_value.raw = NULL; k->current_value.raw_len = 0; k->current_value.b->len = 0; k->current_value.flags &= ~FACET_KEY_VALUE_COPIED; if(unlikely(k->values.enabled)) FACET_VALUE_ADD_UNSAMPLED_VALUE_TO_INDEX(k); else { k->key_found_in_row++; k->key_values_selected_in_row++; } } static inline void facets_key_set_empty_value(FACETS *facets, FACET_KEY *k) { if(likely(!facet_key_value_updated(k) && facets->keys_in_row.used < FACETS_KEYS_IN_ROW_MAX)) facets->keys_in_row.array[facets->keys_in_row.used++] = k; k->current_value.flags |= FACET_KEY_VALUE_UPDATED | FACET_KEY_VALUE_EMPTY; facets->operations.values.registered++; facets->operations.values.empty++; // no need to copy the UNSET value // empty values are exported as empty k->current_value.raw = NULL; k->current_value.raw_len = 0; k->current_value.b->len = 0; k->current_value.flags &= ~FACET_KEY_VALUE_COPIED; if(unlikely(k->values.enabled)) FACET_VALUE_ADD_EMPTY_VALUE_TO_INDEX(k); else { k->key_found_in_row++; k->key_values_selected_in_row++; } } static inline void facets_key_check_value(FACETS *facets, FACET_KEY *k) { if(likely(!facet_key_value_updated(k) && facets->keys_in_row.used < FACETS_KEYS_IN_ROW_MAX)) facets->keys_in_row.array[facets->keys_in_row.used++] = k; k->current_value.flags |= FACET_KEY_VALUE_UPDATED; k->current_value.flags &= ~(FACET_KEY_VALUE_EMPTY|FACET_KEY_VALUE_UNSAMPLED|FACET_KEY_VALUE_ESTIMATED); facets->operations.values.registered++; if(k->transform.cb && !k->transform.view_only) { facets->operations.values.transformed++; facets_key_value_copy_to_buffer(k); k->transform.cb(facets, k->current_value.b, FACETS_TRANSFORM_VALUE, k->transform.data); } // bool found = false; // if(strstr(buffer_tostring(k->current_value), "fprintd") != NULL) // found = true; if(facets->query && !facet_key_value_empty_or_unsampled_or_estimated(k) && ((k->options & FACET_KEY_OPTION_FTS) || facets->options & FACETS_OPTION_ALL_KEYS_FTS)) { facets->operations.fts.searches++; facets_key_value_copy_to_buffer(k); switch(simple_pattern_matches_extract(facets->query, buffer_tostring(k->current_value.b), NULL, 0)) { case SP_MATCHED_POSITIVE: facets->current_row.keys_matched_by_query_positive++; break; case SP_MATCHED_NEGATIVE: facets->current_row.keys_matched_by_query_negative++; break; case SP_NOT_MATCHED: break; } } if(k->values.enabled) FACET_VALUE_ADD_CURRENT_VALUE_TO_INDEX(k); else { k->key_found_in_row++; k->key_values_selected_in_row++; } } void facets_add_key_value(FACETS *facets, const char *key, const char *value) { FACET_KEY *k = facets_register_key_name(facets, key, 0); k->current_value.raw = value; k->current_value.raw_len = strlen(value); facets_key_check_value(facets, k); } void facets_add_key_value_length(FACETS *facets, const char *key, size_t key_len, const char *value, size_t value_len) { FACET_KEY *k = facets_register_key_name_length(facets, key, key_len, 0); k->current_value.raw = value; k->current_value.raw_len = value_len; facets_key_check_value(facets, k); } // ---------------------------------------------------------------------------- // FACET_ROW dictionary hooks static void facet_row_key_value_insert_callback(const DICTIONARY_ITEM *item __maybe_unused, void *value, void *data) { FACET_ROW_KEY_VALUE *rkv = value; FACET_ROW *row = data; (void)row; rkv->wb = buffer_create(0, NULL); if(!rkv->empty) buffer_contents_replace(rkv->wb, rkv->tmp, rkv->tmp_len); } static bool facet_row_key_value_conflict_callback(const DICTIONARY_ITEM *item __maybe_unused, void *old_value, void *new_value, void *data) { FACET_ROW_KEY_VALUE *rkv = old_value; FACET_ROW_KEY_VALUE *n_rkv = new_value; FACET_ROW *row = data; (void)row; rkv->empty = n_rkv->empty; if(!rkv->empty) buffer_contents_replace(rkv->wb, n_rkv->tmp, n_rkv->tmp_len); else buffer_flush(rkv->wb); return false; } static void facet_row_key_value_delete_callback(const DICTIONARY_ITEM *item __maybe_unused, void *value, void *data) { FACET_ROW_KEY_VALUE *rkv = value; FACET_ROW *row = data; (void)row; buffer_free(rkv->wb); } // ---------------------------------------------------------------------------- // FACET_ROW management static void facets_row_free(FACETS *facets __maybe_unused, FACET_ROW *row) { dictionary_destroy(row->dict); freez(row); } static FACET_ROW *facets_row_create(FACETS *facets, usec_t usec, FACET_ROW *into) { FACET_ROW *row; if(into) { row = into; facets->operations.rows.reused++; } else { row = callocz(1, sizeof(FACET_ROW)); row->dict = dictionary_create_advanced(DICT_OPTION_SINGLE_THREADED|DICT_OPTION_DONT_OVERWRITE_VALUE|DICT_OPTION_FIXED_SIZE, NULL, sizeof(FACET_ROW_KEY_VALUE)); dictionary_register_insert_callback(row->dict, facet_row_key_value_insert_callback, row); dictionary_register_conflict_callback(row->dict, facet_row_key_value_conflict_callback, row); dictionary_register_delete_callback(row->dict, facet_row_key_value_delete_callback, row); facets->operations.rows.created++; } row->severity = facets->current_row.severity; row->usec = usec; FACET_KEY *k; foreach_key_in_facets(facets, k) { FACET_ROW_KEY_VALUE t = { .tmp = NULL, .tmp_len = 0, .wb = NULL, .empty = true, }; if(facet_key_value_updated(k) && !facet_key_value_empty_or_unsampled_or_estimated(k)) { t.tmp = facets_key_get_value(k); t.tmp_len = facets_key_get_value_length(k); t.empty = false; } dictionary_set(row->dict, k->name, &t, sizeof(t)); } foreach_key_in_facets_done(k); return row; } // ---------------------------------------------------------------------------- static inline FACET_ROW *facets_row_keep_seek_to_position(FACETS *facets, usec_t usec) { if(usec < facets->base->prev->usec) return facets->base->prev; if(usec > facets->base->usec) return facets->base; FACET_ROW *last = facets->operations.last_added; while(last->prev != facets->base->prev && usec > last->prev->usec) { last = last->prev; facets->operations.backwards++; } while(last->next && usec < last->next->usec) { last = last->next; facets->operations.forwards++; } return last; } static void facets_row_keep_first_entry(FACETS *facets, usec_t usec) { facets->operations.last_added = facets_row_create(facets, usec, NULL); DOUBLE_LINKED_LIST_APPEND_ITEM_UNSAFE(facets->base, facets->operations.last_added, prev, next); facets->items_to_return++; facets->operations.first++; } static inline bool facets_is_entry_within_anchor(FACETS *facets, usec_t usec) { if(facets->anchor.start_ut || facets->anchor.stop_ut) { // we have an anchor key // we don't want to keep rows on the other side of the direction switch (facets->anchor.direction) { default: case FACETS_ANCHOR_DIRECTION_BACKWARD: // we need to keep only the smaller timestamps if (facets->anchor.start_ut && usec >= facets->anchor.start_ut) { facets->operations.skips_before++; return false; } if (facets->anchor.stop_ut && usec <= facets->anchor.stop_ut) { facets->operations.skips_after++; return false; } break; case FACETS_ANCHOR_DIRECTION_FORWARD: // we need to keep only the bigger timestamps if (facets->anchor.start_ut && usec <= facets->anchor.start_ut) { facets->operations.skips_after++; return false; } if (facets->anchor.stop_ut && usec >= facets->anchor.stop_ut) { facets->operations.skips_before++; return false; } break; } } return true; } bool facets_row_candidate_to_keep(FACETS *facets, usec_t usec) { return !facets->base || (usec >= facets->base->prev->usec && usec <= facets->base->usec && facets_is_entry_within_anchor(facets, usec)) || facets->items_to_return < facets->max_items_to_return; } static void facets_row_keep(FACETS *facets, usec_t usec) { facets->operations.rows.matched++; if(unlikely(!facets->base)) { // the first row to keep facets_row_keep_first_entry(facets, usec); return; } FACET_ROW *closest = facets_row_keep_seek_to_position(facets, usec); FACET_ROW *to_replace = NULL; if(likely(facets->items_to_return >= facets->max_items_to_return)) { // we have enough items to return already switch(facets->anchor.direction) { default: case FACETS_ANCHOR_DIRECTION_BACKWARD: if(closest == facets->base->prev && usec < closest->usec) { // this is to the end of the list, belonging to the next page facets->operations.skips_after++; return; } // it seems we need to remove an item - the last one to_replace = facets->base->prev; if(closest == to_replace) closest = to_replace->prev; break; case FACETS_ANCHOR_DIRECTION_FORWARD: if(closest == facets->base && usec > closest->usec) { // this is to the beginning of the list, belonging to the next page facets->operations.skips_before++; return; } // it seems we need to remove an item - the first one to_replace = facets->base; if(closest == to_replace) closest = to_replace->next; break; } facets->operations.shifts++; facets->items_to_return--; DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(facets->base, to_replace, prev, next); } internal_fatal(!closest, "FACETS: closest cannot be NULL"); internal_fatal(closest == to_replace, "FACETS: closest cannot be the same as to_replace"); facets->operations.last_added = facets_row_create(facets, usec, to_replace); if(usec < closest->usec) { DOUBLE_LINKED_LIST_INSERT_ITEM_AFTER_UNSAFE(facets->base, closest, facets->operations.last_added, prev, next); facets->operations.appends++; } else { DOUBLE_LINKED_LIST_INSERT_ITEM_BEFORE_UNSAFE(facets->base, closest, facets->operations.last_added, prev, next); facets->operations.prepends++; } facets->items_to_return++; } static inline void facets_reset_key(FACET_KEY *k) { k->key_found_in_row = 0; k->key_values_selected_in_row = 0; k->current_value.flags = FACET_KEY_VALUE_NONE; k->current_value.hash = FACETS_HASH_ZERO; } static void facets_reset_keys_with_value_and_row(FACETS *facets) { size_t entries = facets->keys_in_row.used; for(size_t p = 0; p < entries ;p++) { FACET_KEY *k = facets->keys_in_row.array[p]; facets_reset_key(k); } facets->current_row.severity = FACET_ROW_SEVERITY_NORMAL; facets->current_row.keys_matched_by_query_positive = 0; facets->current_row.keys_matched_by_query_negative = 0; facets->keys_in_row.used = 0; } void facets_rows_begin(FACETS *facets) { FACET_KEY *k; foreach_key_in_facets(facets, k) { facets_reset_key(k); } foreach_key_in_facets_done(k); facets->keys_in_row.used = 0; facets_reset_keys_with_value_and_row(facets); } bool facets_row_finished(FACETS *facets, usec_t usec) { facets->operations.rows.evaluated++; if(unlikely((facets->query && facets->keys_filtered_by_query && (!facets->current_row.keys_matched_by_query_positive || facets->current_row.keys_matched_by_query_negative)) || (facets->timeframe.before_ut && usec > facets->timeframe.before_ut) || (facets->timeframe.after_ut && usec < facets->timeframe.after_ut))) { // this row is not useful // 1. not matched by full text search, or // 2. not in our timeframe facets_reset_keys_with_value_and_row(facets); return false; } bool within_anchor = facets_is_entry_within_anchor(facets, usec); if(unlikely(!within_anchor && (facets->options & FACETS_OPTION_DATA_ONLY))) { facets_reset_keys_with_value_and_row(facets); return false; } size_t entries = facets->keys_with_values.used; size_t total_keys = 0; size_t selected_keys = 0; for(size_t p = 0; p < entries ;p++) { FACET_KEY *k = facets->keys_with_values.array[p]; if(!facet_key_value_updated(k)) { // put the FACET_VALUE_UNSET value into it facets_key_set_empty_value(facets, k); } total_keys++; if(k->key_values_selected_in_row) selected_keys++; if(unlikely(!facets->histogram.key && facets->histogram.hash == k->hash)) facets->histogram.key = k; } if(selected_keys >= total_keys - 1) { size_t found = 0; (void) found; for(size_t p = 0; p < entries; p++) { FACET_KEY *k = facets->keys_with_values.array[p]; size_t counted_by = selected_keys; if(counted_by != total_keys && !k->key_values_selected_in_row) counted_by++; if(counted_by == total_keys) { k->current_value.v->final_facet_value_counter++; found++; } } internal_fatal(!found, "We should find at least one facet to count this row"); } if(selected_keys == total_keys) { // we need to keep this row facets_histogram_update_value(facets, usec); if(within_anchor) facets_row_keep(facets, usec); } facets_reset_keys_with_value_and_row(facets); return selected_keys == total_keys; } // ---------------------------------------------------------------------------- // output const char *facets_severity_to_string(FACET_ROW_SEVERITY severity) { switch(severity) { default: case FACET_ROW_SEVERITY_NORMAL: return "normal"; case FACET_ROW_SEVERITY_DEBUG: return "debug"; case FACET_ROW_SEVERITY_NOTICE: return "notice"; case FACET_ROW_SEVERITY_WARNING: return "warning"; case FACET_ROW_SEVERITY_CRITICAL: return "critical"; } } void facets_accepted_parameters_to_json_array(FACETS *facets, BUFFER *wb, bool with_keys) { buffer_json_member_add_array(wb, "accepted_params"); { if(facets->accepted_params) { void *t; dfe_start_read(facets->accepted_params, t) { buffer_json_add_array_item_string(wb, t_dfe.name); } dfe_done(t); } if(with_keys) { FACET_KEY *k; foreach_key_in_facets(facets, k){ if (!k->values.enabled) continue; buffer_json_add_array_item_string(wb, hash_to_static_string(k->hash)); } foreach_key_in_facets_done(k); } } buffer_json_array_close(wb); // accepted_params } static int facets_keys_reorder_compar(const void *a, const void *b) { const FACET_KEY *ak = *((const FACET_KEY **)a); const FACET_KEY *bk = *((const FACET_KEY **)b); const char *an = ak->name; const char *bn = bk->name; if(!an) an = "0"; if(!bn) bn = "0"; while(*an && ispunct((uint8_t)*an)) an++; while(*bn && ispunct((uint8_t)*bn)) bn++; return strcasecmp(an, bn); } void facets_sort_and_reorder_keys(FACETS *facets) { size_t entries = facets->keys_with_values.used; if(!entries) return; FACET_KEY *keys[entries]; memcpy(keys, facets->keys_with_values.array, sizeof(FACET_KEY *) * entries); qsort(keys, entries, sizeof(FACET_KEY *), facets_keys_reorder_compar); for(size_t i = 0; i < entries ;i++) keys[i]->order = i + 1; } static int facets_key_values_reorder_by_name_compar(const void *a, const void *b) { const FACET_VALUE *av = *((const FACET_VALUE **)a); const FACET_VALUE *bv = *((const FACET_VALUE **)b); const char *an = (av->name && av->name_len) ? av->name : "0"; const char *bn = (bv->name && bv->name_len) ? bv->name : "0"; while(*an && ispunct((uint8_t)*an)) an++; while(*bn && ispunct((uint8_t)*bn)) bn++; int ret = strcasecmp(an, bn); return ret; } static int facets_key_values_reorder_by_count_compar(const void *a, const void *b) { const FACET_VALUE *av = *((const FACET_VALUE **)a); const FACET_VALUE *bv = *((const FACET_VALUE **)b); if(av->final_facet_value_counter < bv->final_facet_value_counter) return 1; if(av->final_facet_value_counter > bv->final_facet_value_counter) return -1; return facets_key_values_reorder_by_name_compar(a, b); } static int facets_key_values_reorder_by_name_numeric_compar(const void *a, const void *b) { const FACET_VALUE *av = *((const FACET_VALUE **)a); const FACET_VALUE *bv = *((const FACET_VALUE **)b); const char *an = (av->name && av->name_len) ? av->name : "0"; const char *bn = (bv->name && bv->name_len) ? bv->name : "0"; if(strcmp(an, FACET_VALUE_UNSET) == 0) an = "0"; if(strcmp(bn, FACET_VALUE_UNSET) == 0) bn = "0"; int64_t ad = str2ll(an, NULL); int64_t bd = str2ll(bn, NULL); if(ad < bd) return -1; if(ad > bd) return 1; return facets_key_values_reorder_by_name_compar(a, b); } static uint32_t facets_sort_and_reorder_values_internal(FACET_KEY *k) { bool all_values_numeric = true; size_t entries = k->values.used; FACET_VALUE *values[entries], *v; uint32_t used = 0; foreach_value_in_key(k, v) { if((k->facets->options & FACETS_OPTION_DONT_SEND_EMPTY_VALUE_FACETS) && v->empty) continue; if(all_values_numeric && !v->empty && v->name && v->name_len) { const char *s = v->name; while(isdigit((uint8_t)*s)) s++; if(*s != '\0') all_values_numeric = false; } values[used++] = v; if(used >= entries) break; } foreach_value_in_key_done(v); if(!used) return 0; if(k->facets->options & FACETS_OPTION_SORT_FACETS_ALPHABETICALLY) { if(all_values_numeric) qsort(values, used, sizeof(FACET_VALUE *), facets_key_values_reorder_by_name_numeric_compar); else qsort(values, used, sizeof(FACET_VALUE *), facets_key_values_reorder_by_name_compar); } else qsort(values, used, sizeof(FACET_VALUE *), facets_key_values_reorder_by_count_compar); for(size_t i = 0; i < used; i++) values[i]->order = i + 1; return used; } static uint32_t facets_sort_and_reorder_values(FACET_KEY *k) { if(!k->values.enabled || !k->values.ll || !k->values.used) return 0; if(!k->transform.cb || !k->transform.view_only || !(k->facets->options & FACETS_OPTION_SORT_FACETS_ALPHABETICALLY)) return facets_sort_and_reorder_values_internal(k); // we have a transformation and has to be sorted alphabetically BUFFER *tb = buffer_create(0, NULL); uint32_t ret = 0; size_t entries = k->values.used; struct { const char *name; uint32_t name_len; } values[entries]; FACET_VALUE *v; uint32_t used = 0; foreach_value_in_key(k, v) { if(used >= entries) break; values[used].name = v->name; values[used].name_len = v->name_len; used++; facets_key_value_transformed(k->facets, k, v, tb, FACETS_TRANSFORM_FACET_SORT); v->name = strdupz(buffer_tostring(tb)); v->name_len = buffer_strlen(tb); } foreach_value_in_key_done(v); ret = facets_sort_and_reorder_values_internal(k); used = 0; foreach_value_in_key(k, v) { if(used >= entries) break; freez((void *)v->name); v->name = values[used].name; v->name_len = values[used].name_len; used++; } foreach_value_in_key_done(v); buffer_free(tb); return ret; } void facets_table_config(BUFFER *wb) { buffer_json_member_add_boolean(wb, "show_ids", false); // do not show the column ids to the user buffer_json_member_add_boolean(wb, "has_history", true); // enable date-time picker with after-before buffer_json_member_add_object(wb, "pagination"); { buffer_json_member_add_boolean(wb, "enabled", true); buffer_json_member_add_string(wb, "key", "anchor"); buffer_json_member_add_string(wb, "column", "timestamp"); buffer_json_member_add_string(wb, "units", "timestamp_usec"); } buffer_json_object_close(wb); // pagination } void facets_report(FACETS *facets, BUFFER *wb, DICTIONARY *used_hashes_registry) { facets->report.used_hashes_registry = used_hashes_registry; if(!(facets->options & FACETS_OPTION_DATA_ONLY)) { facets_table_config(wb); facets_accepted_parameters_to_json_array(facets, wb, true); } // ------------------------------------------------------------------------ // facets if(!(facets->options & FACETS_OPTION_DONT_SEND_FACETS)) { bool show_facets = false; if(facets->options & FACETS_OPTION_DATA_ONLY) { if(facets->options & FACETS_OPTION_SHOW_DELTAS) { buffer_json_member_add_array(wb, "facets_delta"); show_facets = true; } } else { buffer_json_member_add_array(wb, "facets"); show_facets = true; } if(show_facets) { CLEAN_BUFFER *tb = buffer_create(0, NULL); FACET_KEY *k; foreach_key_in_facets(facets, k) { if(!k->values.enabled) continue; if(!facets_sort_and_reorder_values(k)) // no values for this key continue; buffer_json_add_array_item_object(wb); // key { buffer_json_member_add_string(wb, "id", hash_to_static_string(k->hash)); buffer_json_member_add_string(wb, "name", facets_key_name_cached(k , facets->report.used_hashes_registry )); if(!k->order) k->order = facets->order++; buffer_json_member_add_uint64(wb, "order", k->order); buffer_json_member_add_array(wb, "options"); { FACET_VALUE *v; foreach_value_in_key(k, v) { if((facets->options & FACETS_OPTION_DONT_SEND_EMPTY_VALUE_FACETS) && v->empty) continue; if(v->unsampled || v->estimated) continue; buffer_json_add_array_item_object(wb); { buffer_json_member_add_string(wb, "id", hash_to_static_string(v->hash)); facets_key_value_transformed(facets, k, v, tb, FACETS_TRANSFORM_FACET); buffer_json_member_add_string(wb, "name", buffer_tostring(tb)); buffer_json_member_add_uint64(wb, "count", v->final_facet_value_counter); buffer_json_member_add_uint64(wb, "order", v->order); } buffer_json_object_close(wb); } foreach_value_in_key_done(v); } buffer_json_array_close(wb); // options } buffer_json_object_close(wb); // key } foreach_key_in_facets_done(k); buffer_json_array_close(wb); // facets } } // ------------------------------------------------------------------------ // columns buffer_json_member_add_object(wb, "columns"); { size_t field_id = 0; buffer_rrdf_table_add_field( wb, field_id++, "timestamp", "Timestamp", RRDF_FIELD_TYPE_TIMESTAMP, RRDF_FIELD_VISUAL_VALUE, RRDF_FIELD_TRANSFORM_DATETIME_USEC, 0, NULL, NAN, RRDF_FIELD_SORT_DESCENDING|RRDF_FIELD_SORT_FIXED, NULL, RRDF_FIELD_SUMMARY_COUNT, RRDF_FIELD_FILTER_RANGE, RRDF_FIELD_OPTS_WRAP | RRDF_FIELD_OPTS_VISIBLE | RRDF_FIELD_OPTS_UNIQUE_KEY, NULL); buffer_rrdf_table_add_field( wb, field_id++, "rowOptions", "rowOptions", RRDF_FIELD_TYPE_NONE, RRDR_FIELD_VISUAL_ROW_OPTIONS, RRDF_FIELD_TRANSFORM_NONE, 0, NULL, NAN, RRDF_FIELD_SORT_FIXED, NULL, RRDF_FIELD_SUMMARY_COUNT, RRDF_FIELD_FILTER_NONE, RRDF_FIELD_OPTS_DUMMY, NULL); FACET_KEY *k; foreach_key_in_facets(facets, k) { RRDF_FIELD_OPTIONS options = RRDF_FIELD_OPTS_WRAP; bool visible = k->options & (FACET_KEY_OPTION_VISIBLE | FACET_KEY_OPTION_STICKY); if ((facets->options & FACETS_OPTION_ALL_FACETS_VISIBLE && k->values.enabled)) visible = true; if (!visible) visible = simple_pattern_matches(facets->visible_keys, k->name); if (visible) options |= RRDF_FIELD_OPTS_VISIBLE; if (k->options & FACET_KEY_OPTION_MAIN_TEXT) options |= RRDF_FIELD_OPTS_FULL_WIDTH | RRDF_FIELD_OPTS_WRAP; if (k->options & FACET_KEY_OPTION_EXPANDED_FILTER) options |= RRDF_FIELD_OPTS_EXPANDED_FILTER; const char *hash_str = hash_to_static_string(k->hash); buffer_rrdf_table_add_field( wb, field_id++, hash_str, k->name ? k->name : hash_str, RRDF_FIELD_TYPE_STRING, (k->options & FACET_KEY_OPTION_RICH_TEXT) ? RRDF_FIELD_VISUAL_RICH : RRDF_FIELD_VISUAL_VALUE, RRDF_FIELD_TRANSFORM_NONE, 0, NULL, NAN, RRDF_FIELD_SORT_FIXED, NULL, RRDF_FIELD_SUMMARY_COUNT, (k->options & FACET_KEY_OPTION_NEVER_FACET) ? RRDF_FIELD_FILTER_NONE : RRDF_FIELD_FILTER_FACET, options, FACET_VALUE_UNSET); } foreach_key_in_facets_done(k); } buffer_json_object_close(wb); // columns // ------------------------------------------------------------------------ // rows data buffer_json_member_add_array(wb, "data"); { usec_t last_usec = 0; (void)last_usec; for(FACET_ROW *row = facets->base ; row ;row = row->next) { internal_fatal( facets->anchor.start_ut && ( (facets->anchor.direction == FACETS_ANCHOR_DIRECTION_BACKWARD && row->usec >= facets->anchor.start_ut) || (facets->anchor.direction == FACETS_ANCHOR_DIRECTION_FORWARD && row->usec <= facets->anchor.start_ut) ), "Wrong data returned related to %s start anchor!", facets->anchor.direction == FACETS_ANCHOR_DIRECTION_FORWARD ? "forward" : "backward"); internal_fatal(last_usec && row->usec > last_usec, "Wrong order of data returned!"); last_usec = row->usec; buffer_json_add_array_item_array(wb); // each row buffer_json_add_array_item_uint64(wb, row->usec); buffer_json_add_array_item_object(wb); { if(facets->severity.cb) row->severity = facets->severity.cb(facets, row, facets->severity.data); buffer_json_member_add_string(wb, "severity", facets_severity_to_string(row->severity)); } buffer_json_object_close(wb); FACET_KEY *k; foreach_key_in_facets(facets, k) { FACET_ROW_KEY_VALUE *rkv = dictionary_get(row->dict, k->name); if(unlikely(k->dynamic.cb)) { if(unlikely(!rkv)) rkv = dictionary_set(row->dict, k->name, NULL, sizeof(*rkv)); k->dynamic.cb(facets, wb, rkv, row, k->dynamic.data); facets->operations.values.dynamic++; } else { if(!rkv || rkv->empty) { buffer_json_add_array_item_string(wb, NULL); } else if(unlikely(k->transform.cb && k->transform.view_only)) { k->transform.cb(facets, rkv->wb, FACETS_TRANSFORM_DATA, k->transform.data); buffer_json_add_array_item_string(wb, buffer_tostring(rkv->wb)); } else buffer_json_add_array_item_string(wb, buffer_tostring(rkv->wb)); } } foreach_key_in_facets_done(k); buffer_json_array_close(wb); // each row } } buffer_json_array_close(wb); // data if(!(facets->options & FACETS_OPTION_DATA_ONLY)) { buffer_json_member_add_string(wb, "default_sort_column", "timestamp"); buffer_json_member_add_array(wb, "default_charts"); buffer_json_array_close(wb); } // ------------------------------------------------------------------------ // histogram if(facets->histogram.enabled && !(facets->options & FACETS_OPTION_DONT_SEND_HISTOGRAM)) { FACETS_HASH first_histogram_hash = 0; buffer_json_member_add_array(wb, "available_histograms"); { FACET_KEY *k; foreach_key_in_facets(facets, k) { if (!k->values.enabled) continue; if(unlikely(!first_histogram_hash)) first_histogram_hash = k->hash; buffer_json_add_array_item_object(wb); buffer_json_member_add_string(wb, "id", hash_to_static_string(k->hash)); buffer_json_member_add_string(wb, "name", k->name); buffer_json_member_add_uint64(wb, "order", k->order); buffer_json_object_close(wb); } foreach_key_in_facets_done(k); } buffer_json_array_close(wb); { FACET_KEY *k = FACETS_KEY_GET_FROM_INDEX(facets, facets->histogram.hash); if(!k || !k->values.enabled) k = FACETS_KEY_GET_FROM_INDEX(facets, first_histogram_hash); bool show_histogram = false; if(facets->options & FACETS_OPTION_DATA_ONLY) { if(facets->options & FACETS_OPTION_SHOW_DELTAS) { buffer_json_member_add_object(wb, "histogram_delta"); show_histogram = true; } } else { buffer_json_member_add_object(wb, "histogram"); show_histogram = true; } if(show_histogram) { buffer_json_member_add_string(wb, "id", k ? hash_to_static_string(k->hash) : ""); buffer_json_member_add_string(wb, "name", k ? k->name : ""); buffer_json_member_add_object(wb, "chart"); { facets_histogram_generate(facets, k, wb); } buffer_json_object_close(wb); // chart buffer_json_object_close(wb); // histogram } } } // ------------------------------------------------------------------------ // items bool show_items = false; if(facets->options & FACETS_OPTION_DATA_ONLY) { if(facets->options & FACETS_OPTION_SHOW_DELTAS) { buffer_json_member_add_object(wb, "items_delta"); show_items = true; } } else { buffer_json_member_add_object(wb, "items"); show_items = true; } if(show_items) { buffer_json_member_add_uint64(wb, "evaluated", facets->operations.rows.evaluated); buffer_json_member_add_uint64(wb, "matched", facets->operations.rows.matched); buffer_json_member_add_uint64(wb, "unsampled", facets->operations.rows.unsampled); buffer_json_member_add_uint64(wb, "estimated", facets->operations.rows.estimated); buffer_json_member_add_uint64(wb, "returned", facets->items_to_return); buffer_json_member_add_uint64(wb, "max_to_return", facets->max_items_to_return); buffer_json_member_add_uint64(wb, "before", facets->operations.skips_before); buffer_json_member_add_uint64(wb, "after", facets->operations.skips_after + facets->operations.shifts); buffer_json_object_close(wb); // items } // ------------------------------------------------------------------------ // stats buffer_json_member_add_object(wb, "_stats"); { buffer_json_member_add_uint64(wb, "first", facets->operations.first); buffer_json_member_add_uint64(wb, "forwards", facets->operations.forwards); buffer_json_member_add_uint64(wb, "backwards", facets->operations.backwards); buffer_json_member_add_uint64(wb, "skips_before", facets->operations.skips_before); buffer_json_member_add_uint64(wb, "skips_after", facets->operations.skips_after); buffer_json_member_add_uint64(wb, "prepends", facets->operations.prepends); buffer_json_member_add_uint64(wb, "appends", facets->operations.appends); buffer_json_member_add_uint64(wb, "shifts", facets->operations.shifts); buffer_json_member_add_object(wb, "rows"); { buffer_json_member_add_uint64(wb, "created", facets->operations.rows.created); buffer_json_member_add_uint64(wb, "reused", facets->operations.rows.reused); buffer_json_member_add_uint64(wb, "evaluated", facets->operations.rows.evaluated); buffer_json_member_add_uint64(wb, "matched", facets->operations.rows.matched); } buffer_json_object_close(wb); // rows buffer_json_member_add_object(wb, "keys"); { size_t resizes = 0, searches = 0, collisions = 0, used = 0, size = 0, count = 0; count++; used += facets->keys.ht.used; size += facets->keys.ht.size; resizes += facets->keys.ht.resizes; searches += facets->keys.ht.searches; collisions += facets->keys.ht.collisions; buffer_json_member_add_uint64(wb, "registered", facets->operations.keys.registered); buffer_json_member_add_uint64(wb, "unique", facets->operations.keys.unique); buffer_json_member_add_uint64(wb, "hashtables", count); buffer_json_member_add_uint64(wb, "hashtable_used", used); buffer_json_member_add_uint64(wb, "hashtable_size", size); buffer_json_member_add_uint64(wb, "hashtable_searches", searches); buffer_json_member_add_uint64(wb, "hashtable_collisions", collisions); buffer_json_member_add_uint64(wb, "hashtable_resizes", resizes); } buffer_json_object_close(wb); // keys buffer_json_member_add_object(wb, "values"); { size_t resizes = 0, searches = 0, collisions = 0, used = 0, size = 0, count = 0; for(FACET_KEY *k = facets->keys.ll; k ; k = k->next) { count++; used += k->values.ht.used; size += k->values.ht.size; resizes += k->values.ht.resizes; searches += k->values.ht.searches; collisions += k->values.ht.collisions; } buffer_json_member_add_uint64(wb, "registered", facets->operations.values.registered); buffer_json_member_add_uint64(wb, "transformed", facets->operations.values.transformed); buffer_json_member_add_uint64(wb, "dynamic", facets->operations.values.dynamic); buffer_json_member_add_uint64(wb, "empty", facets->operations.values.empty); buffer_json_member_add_uint64(wb, "unsampled", facets->operations.values.unsampled); buffer_json_member_add_uint64(wb, "estimated", facets->operations.values.estimated); buffer_json_member_add_uint64(wb, "indexed", facets->operations.values.indexed); buffer_json_member_add_uint64(wb, "inserts", facets->operations.values.inserts); buffer_json_member_add_uint64(wb, "conflicts", facets->operations.values.conflicts); buffer_json_member_add_uint64(wb, "hashtables", count); buffer_json_member_add_uint64(wb, "hashtable_used", used); buffer_json_member_add_uint64(wb, "hashtable_size", size); buffer_json_member_add_uint64(wb, "hashtable_searches", searches); buffer_json_member_add_uint64(wb, "hashtable_collisions", collisions); buffer_json_member_add_uint64(wb, "hashtable_resizes", resizes); } buffer_json_object_close(wb); // values buffer_json_member_add_object(wb, "fts"); { buffer_json_member_add_uint64(wb, "searches", facets->operations.fts.searches); } buffer_json_object_close(wb); // fts } buffer_json_object_close(wb); // items }