// SPDX-License-Identifier: GPL-3.0-or-later #include "trimmed_mean.h" // ---------------------------------------------------------------------------- // median struct grouping_trimmed_mean { size_t series_size; size_t next_pos; NETDATA_DOUBLE percent; NETDATA_DOUBLE *series; }; static void grouping_create_trimmed_mean_internal(RRDR *r, const char *options, NETDATA_DOUBLE def) { long entries = r->group; if(entries < 10) entries = 10; struct grouping_trimmed_mean *g = (struct grouping_trimmed_mean *)onewayalloc_callocz(r->internal.owa, 1, sizeof(struct grouping_trimmed_mean)); g->series = onewayalloc_mallocz(r->internal.owa, entries * sizeof(NETDATA_DOUBLE)); g->series_size = (size_t)entries; g->percent = def; if(options && *options) { g->percent = str2ndd(options, NULL); if(!netdata_double_isnumber(g->percent)) g->percent = 0.0; if(g->percent < 0.0) g->percent = 0.0; if(g->percent > 50.0) g->percent = 50.0; } g->percent = 1.0 - ((g->percent / 100.0) * 2.0); r->internal.grouping_data = g; } void grouping_create_trimmed_mean1(RRDR *r, const char *options) { grouping_create_trimmed_mean_internal(r, options, 1.0); } void grouping_create_trimmed_mean2(RRDR *r, const char *options) { grouping_create_trimmed_mean_internal(r, options, 2.0); } void grouping_create_trimmed_mean3(RRDR *r, const char *options) { grouping_create_trimmed_mean_internal(r, options, 3.0); } void grouping_create_trimmed_mean5(RRDR *r, const char *options) { grouping_create_trimmed_mean_internal(r, options, 5.0); } void grouping_create_trimmed_mean10(RRDR *r, const char *options) { grouping_create_trimmed_mean_internal(r, options, 10.0); } void grouping_create_trimmed_mean15(RRDR *r, const char *options) { grouping_create_trimmed_mean_internal(r, options, 15.0); } void grouping_create_trimmed_mean20(RRDR *r, const char *options) { grouping_create_trimmed_mean_internal(r, options, 20.0); } void grouping_create_trimmed_mean25(RRDR *r, const char *options) { grouping_create_trimmed_mean_internal(r, options, 25.0); } // resets when switches dimensions // so, clear everything to restart void grouping_reset_trimmed_mean(RRDR *r) { struct grouping_trimmed_mean *g = (struct grouping_trimmed_mean *)r->internal.grouping_data; g->next_pos = 0; } void grouping_free_trimmed_mean(RRDR *r) { struct grouping_trimmed_mean *g = (struct grouping_trimmed_mean *)r->internal.grouping_data; if(g) onewayalloc_freez(r->internal.owa, g->series); onewayalloc_freez(r->internal.owa, r->internal.grouping_data); r->internal.grouping_data = NULL; } void grouping_add_trimmed_mean(RRDR *r, NETDATA_DOUBLE value) { struct grouping_trimmed_mean *g = (struct grouping_trimmed_mean *)r->internal.grouping_data; if(unlikely(g->next_pos >= g->series_size)) { g->series = onewayalloc_doublesize( r->internal.owa, g->series, g->series_size * sizeof(NETDATA_DOUBLE)); g->series_size *= 2; } g->series[g->next_pos++] = value; } NETDATA_DOUBLE grouping_flush_trimmed_mean(RRDR *r, RRDR_VALUE_FLAGS *rrdr_value_options_ptr) { struct grouping_trimmed_mean *g = (struct grouping_trimmed_mean *)r->internal.grouping_data; NETDATA_DOUBLE value; size_t available_slots = g->next_pos; if(unlikely(!available_slots)) { value = 0.0; *rrdr_value_options_ptr |= RRDR_VALUE_EMPTY; } else if(available_slots == 1) { value = g->series[0]; } else { sort_series(g->series, available_slots); NETDATA_DOUBLE min = g->series[0]; NETDATA_DOUBLE max = g->series[available_slots - 1]; if (min != max) { size_t slots_to_use = (size_t)((NETDATA_DOUBLE)available_slots * g->percent); if(!slots_to_use) slots_to_use = 1; NETDATA_DOUBLE percent_to_use = (NETDATA_DOUBLE)slots_to_use / (NETDATA_DOUBLE)available_slots; NETDATA_DOUBLE percent_delta = g->percent - percent_to_use; NETDATA_DOUBLE percent_interpolation_slot = 0.0; NETDATA_DOUBLE percent_last_slot = 0.0; if(percent_delta > 0.0) { NETDATA_DOUBLE percent_to_use_plus_1_slot = (NETDATA_DOUBLE)(slots_to_use + 1) / (NETDATA_DOUBLE)available_slots; NETDATA_DOUBLE percent_1slot = percent_to_use_plus_1_slot - percent_to_use; percent_interpolation_slot = percent_delta / percent_1slot; percent_last_slot = 1 - percent_interpolation_slot; } int start_slot, stop_slot, step, last_slot, interpolation_slot; if(min >= 0.0 && max >= 0.0) { start_slot = (int)((available_slots - slots_to_use) / 2); stop_slot = start_slot + (int)slots_to_use; last_slot = stop_slot - 1; interpolation_slot = stop_slot; step = 1; } else { start_slot = (int)available_slots - 1 - (int)((available_slots - slots_to_use) / 2); stop_slot = start_slot - (int)slots_to_use; last_slot = stop_slot + 1; interpolation_slot = stop_slot; step = -1; } value = 0.0; for(int slot = start_slot; slot != stop_slot ; slot += step) value += g->series[slot]; size_t counted = slots_to_use; if(percent_interpolation_slot > 0.0 && interpolation_slot >= 0 && interpolation_slot < (int)available_slots) { value += g->series[interpolation_slot] * percent_interpolation_slot; value += g->series[last_slot] * percent_last_slot; counted++; } value = value / (NETDATA_DOUBLE)counted; } else value = min; } if(unlikely(!netdata_double_isnumber(value))) { value = 0.0; *rrdr_value_options_ptr |= RRDR_VALUE_EMPTY; } //log_series_to_stderr(g->series, g->next_pos, value, "trimmed_mean"); g->next_pos = 0; return value; }