// SPDX-License-Identifier: GPL-3.0-or-later #ifndef NETDATA_API_QUERIES_DES_H #define NETDATA_API_QUERIES_DES_H #include "../query.h" #include "../rrdr.h" struct tg_des { NETDATA_DOUBLE alpha; NETDATA_DOUBLE alpha_other; NETDATA_DOUBLE beta; NETDATA_DOUBLE beta_other; NETDATA_DOUBLE level; NETDATA_DOUBLE trend; size_t count; }; static size_t tg_des_max_window_size = 15; static inline void tg_des_init(void) { long long ret = config_get_number(CONFIG_SECTION_WEB, "des max tg_des_window", (long long)tg_des_max_window_size); if(ret <= 1) { config_set_number(CONFIG_SECTION_WEB, "des max tg_des_window", (long long)tg_des_max_window_size); } else { tg_des_max_window_size = (size_t) ret; } } static inline NETDATA_DOUBLE tg_des_window(RRDR *r, struct tg_des *g) { (void)g; NETDATA_DOUBLE points; if(r->view.group == 1) { // provide a running DES points = (NETDATA_DOUBLE)r->time_grouping.points_wanted; } else { // provide a SES with flush points points = (NETDATA_DOUBLE)r->view.group; } // https://en.wikipedia.org/wiki/Moving_average#Exponential_moving_average // A commonly used value for alpha is 2 / (N + 1) return (points > (NETDATA_DOUBLE)tg_des_max_window_size) ? (NETDATA_DOUBLE)tg_des_max_window_size : points; } static inline void tg_des_set_alpha(RRDR *r, struct tg_des *g) { // https://en.wikipedia.org/wiki/Moving_average#Exponential_moving_average // A commonly used value for alpha is 2 / (N + 1) g->alpha = 2.0 / (tg_des_window(r, g) + 1.0); g->alpha_other = 1.0 - g->alpha; //info("alpha for chart '%s' is " CALCULATED_NUMBER_FORMAT, r->st->name, g->alpha); } static inline void tg_des_set_beta(RRDR *r, struct tg_des *g) { // https://en.wikipedia.org/wiki/Moving_average#Exponential_moving_average // A commonly used value for alpha is 2 / (N + 1) g->beta = 2.0 / (tg_des_window(r, g) + 1.0); g->beta_other = 1.0 - g->beta; //info("beta for chart '%s' is " CALCULATED_NUMBER_FORMAT, r->st->name, g->beta); } static inline void tg_des_create(RRDR *r, const char *options __maybe_unused) { struct tg_des *g = (struct tg_des *)onewayalloc_mallocz(r->internal.owa, sizeof(struct tg_des)); tg_des_set_alpha(r, g); tg_des_set_beta(r, g); g->level = 0.0; g->trend = 0.0; g->count = 0; r->time_grouping.data = g; } // resets when switches dimensions // so, clear everything to restart static inline void tg_des_reset(RRDR *r) { struct tg_des *g = (struct tg_des *)r->time_grouping.data; g->level = 0.0; g->trend = 0.0; g->count = 0; // fprintf(stderr, "\nDES: "); } static inline void tg_des_free(RRDR *r) { onewayalloc_freez(r->internal.owa, r->time_grouping.data); r->time_grouping.data = NULL; } static inline void tg_des_add(RRDR *r, NETDATA_DOUBLE value) { struct tg_des *g = (struct tg_des *)r->time_grouping.data; if(likely(g->count > 0)) { // we have at least a number so far if(unlikely(g->count == 1)) { // the second value we got g->trend = value - g->trend; g->level = value; } // for the values, except the first NETDATA_DOUBLE last_level = g->level; g->level = (g->alpha * value) + (g->alpha_other * (g->level + g->trend)); g->trend = (g->beta * (g->level - last_level)) + (g->beta_other * g->trend); } else { // the first value we got g->level = g->trend = value; } g->count++; //fprintf(stderr, "value: " CALCULATED_NUMBER_FORMAT ", level: " CALCULATED_NUMBER_FORMAT ", trend: " CALCULATED_NUMBER_FORMAT "\n", value, g->level, g->trend); } static inline NETDATA_DOUBLE tg_des_flush(RRDR *r, RRDR_VALUE_FLAGS *rrdr_value_options_ptr) { struct tg_des *g = (struct tg_des *)r->time_grouping.data; if(unlikely(!g->count || !netdata_double_isnumber(g->level))) { *rrdr_value_options_ptr |= RRDR_VALUE_EMPTY; return 0.0; } //fprintf(stderr, " RESULT for %zu values = " CALCULATED_NUMBER_FORMAT " \n", g->count, g->level); return g->level; } #endif //NETDATA_API_QUERIES_DES_H