// SPDX-License-Identifier: GPL-3.0-or-later #include "database/engine/rrddiskprotocol.h" #include "rrdengine.h" #include "dbengine-compression.h" /* Default global database instance */ struct rrdengine_instance multidb_ctx_storage_tier0 = { 0 }; struct rrdengine_instance multidb_ctx_storage_tier1 = { 0 }; struct rrdengine_instance multidb_ctx_storage_tier2 = { 0 }; struct rrdengine_instance multidb_ctx_storage_tier3 = { 0 }; struct rrdengine_instance multidb_ctx_storage_tier4 = { 0 }; #define mrg_metric_ctx(metric) (struct rrdengine_instance *)mrg_metric_section(main_mrg, metric) #if RRD_STORAGE_TIERS != 5 #error RRD_STORAGE_TIERS is not 5 - you need to add allocations here #endif struct rrdengine_instance *multidb_ctx[RRD_STORAGE_TIERS] = { 0 }; uint8_t tier_page_type[RRD_STORAGE_TIERS] = { RRDENG_PAGE_TYPE_GORILLA_32BIT, RRDENG_PAGE_TYPE_ARRAY_TIER1, RRDENG_PAGE_TYPE_ARRAY_TIER1, RRDENG_PAGE_TYPE_ARRAY_TIER1, RRDENG_PAGE_TYPE_ARRAY_TIER1}; #if defined(ENV32BIT) size_t tier_page_size[RRD_STORAGE_TIERS] = {2048, 1024, 192, 192, 192}; size_t tier_quota_mb[RRD_STORAGE_TIERS] = {512, 512, 512, 0, 0}; #else size_t tier_page_size[RRD_STORAGE_TIERS] = {4096, 2048, 384, 384, 384}; size_t tier_quota_mb[RRD_STORAGE_TIERS] = {1024, 1024, 1024, 128, 64}; #endif #if RRDENG_PAGE_TYPE_MAX != 2 #error PAGE_TYPE_MAX is not 2 - you need to add allocations here #endif size_t page_type_size[256] = { [RRDENG_PAGE_TYPE_ARRAY_32BIT] = sizeof(storage_number), [RRDENG_PAGE_TYPE_ARRAY_TIER1] = sizeof(storage_number_tier1_t), [RRDENG_PAGE_TYPE_GORILLA_32BIT] = sizeof(storage_number) }; static inline void initialize_single_ctx(struct rrdengine_instance *ctx) { memset(ctx, 0, sizeof(*ctx)); uv_rwlock_init(&ctx->datafiles.rwlock); rw_spinlock_init(&ctx->njfv2idx.spinlock); } __attribute__((constructor)) void initialize_multidb_ctx(void) { multidb_ctx[0] = &multidb_ctx_storage_tier0; multidb_ctx[1] = &multidb_ctx_storage_tier1; multidb_ctx[2] = &multidb_ctx_storage_tier2; multidb_ctx[3] = &multidb_ctx_storage_tier3; multidb_ctx[4] = &multidb_ctx_storage_tier4; for(int i = 0; i < RRD_STORAGE_TIERS ; i++) initialize_single_ctx(multidb_ctx[i]); } int db_engine_journal_check = 0; bool new_dbengine_defaults = false; bool legacy_multihost_db_space = false; int default_rrdeng_disk_quota_mb = RRDENG_DEFAULT_TIER_DISK_SPACE_MB; int default_multidb_disk_quota_mb = RRDENG_DEFAULT_TIER_DISK_SPACE_MB; RRD_BACKFILL default_backfill = RRD_BACKFILL_NEW; #if defined(ENV32BIT) int default_rrdeng_page_cache_mb = 16; int default_rrdeng_extent_cache_mb = 0; #else int default_rrdeng_page_cache_mb = 32; int default_rrdeng_extent_cache_mb = 0; #endif // ---------------------------------------------------------------------------- // metrics groups static inline void rrdeng_page_alignment_acquire(struct pg_alignment *pa) { if(unlikely(!pa)) return; __atomic_add_fetch(&pa->refcount, 1, __ATOMIC_SEQ_CST); } static inline bool rrdeng_page_alignment_release(struct pg_alignment *pa) { if(unlikely(!pa)) return true; if(__atomic_sub_fetch(&pa->refcount, 1, __ATOMIC_SEQ_CST) == 0) { freez(pa); return true; } return false; } // charts call this STORAGE_METRICS_GROUP *rrdeng_metrics_group_get(STORAGE_INSTANCE *si __maybe_unused, nd_uuid_t *uuid __maybe_unused) { struct pg_alignment *pa = callocz(1, sizeof(struct pg_alignment)); rrdeng_page_alignment_acquire(pa); return (STORAGE_METRICS_GROUP *)pa; } // charts call this void rrdeng_metrics_group_release(STORAGE_INSTANCE *si __maybe_unused, STORAGE_METRICS_GROUP *smg) { if(unlikely(!smg)) return; struct pg_alignment *pa = (struct pg_alignment *)smg; rrdeng_page_alignment_release(pa); } // ---------------------------------------------------------------------------- // metric handle for legacy dbs /* This UUID is not unique across hosts */ void rrdeng_generate_unittest_uuid(const char *dim_id, const char *chart_id, nd_uuid_t *ret_uuid) { CLEAN_BUFFER *wb = buffer_create(100, NULL); buffer_sprintf(wb,"%s.%s", dim_id, chart_id); ND_UUID uuid = UUID_generate_from_hash(buffer_tostring(wb), buffer_strlen(wb)); uuid_copy(*ret_uuid, uuid.uuid); } static METRIC *rrdeng_metric_unittest(STORAGE_INSTANCE *si, const char *rd_id, const char *st_id) { struct rrdengine_instance *ctx = (struct rrdengine_instance *)si; nd_uuid_t legacy_uuid; rrdeng_generate_unittest_uuid(rd_id, st_id, &legacy_uuid); return mrg_metric_get_and_acquire(main_mrg, &legacy_uuid, (Word_t) ctx); } // ---------------------------------------------------------------------------- // metric handle void rrdeng_metric_release(STORAGE_METRIC_HANDLE *smh) { METRIC *metric = (METRIC *)smh; mrg_metric_release(main_mrg, metric); } STORAGE_METRIC_HANDLE *rrdeng_metric_dup(STORAGE_METRIC_HANDLE *smh) { METRIC *metric = (METRIC *)smh; return (STORAGE_METRIC_HANDLE *) mrg_metric_dup(main_mrg, metric); } STORAGE_METRIC_HANDLE *rrdeng_metric_get(STORAGE_INSTANCE *si, nd_uuid_t *uuid) { struct rrdengine_instance *ctx = (struct rrdengine_instance *)si; return (STORAGE_METRIC_HANDLE *) mrg_metric_get_and_acquire(main_mrg, uuid, (Word_t) ctx); } static METRIC *rrdeng_metric_create(STORAGE_INSTANCE *si, nd_uuid_t *uuid) { internal_fatal(!si, "DBENGINE: STORAGE_INSTANCE is NULL"); struct rrdengine_instance *ctx = (struct rrdengine_instance *)si; MRG_ENTRY entry = { .uuid = uuid, .section = (Word_t)ctx, .first_time_s = 0, .last_time_s = 0, .latest_update_every_s = 0, }; bool added; METRIC *metric = mrg_metric_add_and_acquire(main_mrg, entry, &added); if (added) __atomic_add_fetch(&ctx->atomic.metrics, 1, __ATOMIC_RELAXED); return metric; } STORAGE_METRIC_HANDLE *rrdeng_metric_get_or_create(RRDDIM *rd, STORAGE_INSTANCE *si) { struct rrdengine_instance *ctx = (struct rrdengine_instance *)si; METRIC *metric; metric = mrg_metric_get_and_acquire(main_mrg, &rd->metric_uuid, (Word_t) ctx); if(unlikely(!metric)) { if(unlikely(unittest_running)) { metric = rrdeng_metric_unittest(si, rrddim_id(rd), rrdset_id(rd->rrdset)); if (metric) uuid_copy(rd->metric_uuid, *mrg_metric_uuid(main_mrg, metric)); } if(likely(!metric)) metric = rrdeng_metric_create(si, &rd->metric_uuid); } #ifdef NETDATA_INTERNAL_CHECKS if(!uuid_eq(rd->metric_uuid, *mrg_metric_uuid(main_mrg, metric))) { char uuid1[UUID_STR_LEN + 1]; char uuid2[UUID_STR_LEN + 1]; uuid_unparse(rd->metric_uuid, uuid1); uuid_unparse(*mrg_metric_uuid(main_mrg, metric), uuid2); fatal("DBENGINE: uuids do not match, asked for metric '%s', but got metric '%s'", uuid1, uuid2); } if(mrg_metric_ctx(metric) != ctx) fatal("DBENGINE: mixed up db instances, asked for metric from %p, got from %p", ctx, mrg_metric_ctx(metric)); #endif return (STORAGE_METRIC_HANDLE *)metric; } // ---------------------------------------------------------------------------- // collect ops static inline void check_and_fix_mrg_update_every(struct rrdeng_collect_handle *handle) { if(unlikely((uint32_t)(handle->update_every_ut / USEC_PER_SEC) != mrg_metric_get_update_every_s(main_mrg, handle->metric))) { internal_error(true, "DBENGINE: collection handle has update every %u, but the metric registry has %u. Fixing it.", (uint32_t)(handle->update_every_ut / USEC_PER_SEC), mrg_metric_get_update_every_s(main_mrg, handle->metric)); if(unlikely(!handle->update_every_ut)) handle->update_every_ut = (usec_t)mrg_metric_get_update_every_s(main_mrg, handle->metric) * USEC_PER_SEC; else mrg_metric_set_update_every(main_mrg, handle->metric, (uint32_t)(handle->update_every_ut / USEC_PER_SEC)); } } static inline bool check_completed_page_consistency(struct rrdeng_collect_handle *handle __maybe_unused) { #ifdef NETDATA_INTERNAL_CHECKS if (unlikely(!handle->pgc_page || !handle->page_entries_max || !handle->page_position || !handle->page_end_time_ut)) return false; struct rrdengine_instance *ctx = mrg_metric_ctx(handle->metric); nd_uuid_t *uuid = mrg_metric_uuid(main_mrg, handle->metric); time_t start_time_s = pgc_page_start_time_s(handle->pgc_page); time_t end_time_s = pgc_page_end_time_s(handle->pgc_page); uint32_t update_every_s = pgc_page_update_every_s(handle->pgc_page); size_t page_length = handle->page_position * CTX_POINT_SIZE_BYTES(ctx); size_t entries = handle->page_position; time_t overwrite_zero_update_every_s = (time_t)(handle->update_every_ut / USEC_PER_SEC); if(end_time_s > max_acceptable_collected_time()) handle->page_flags |= RRDENG_PAGE_COMPLETED_IN_FUTURE; VALIDATED_PAGE_DESCRIPTOR vd = validate_page( uuid, start_time_s, end_time_s, update_every_s, page_length, ctx->config.page_type, entries, 0, // do not check for future timestamps - we inherit the timestamps of the children overwrite_zero_update_every_s, false, "collected", handle->page_flags); return vd.is_valid; #else return true; #endif } /* * Gets a handle for storing metrics to the database. * The handle must be released with rrdeng_store_metric_final(). */ STORAGE_COLLECT_HANDLE *rrdeng_store_metric_init(STORAGE_METRIC_HANDLE *smh, uint32_t update_every, STORAGE_METRICS_GROUP *smg) { METRIC *metric = (METRIC *)smh; struct rrdengine_instance *ctx = mrg_metric_ctx(metric); bool is_1st_metric_writer = true; if(!mrg_metric_set_writer(main_mrg, metric)) { is_1st_metric_writer = false; char uuid[UUID_STR_LEN + 1]; uuid_unparse(*mrg_metric_uuid(main_mrg, metric), uuid); netdata_log_error("DBENGINE: metric '%s' is already collected and should not be collected twice - expect gaps on the charts", uuid); } metric = mrg_metric_dup(main_mrg, metric); struct rrdeng_collect_handle *handle; handle = callocz(1, sizeof(struct rrdeng_collect_handle)); handle->common.seb = STORAGE_ENGINE_BACKEND_DBENGINE; handle->metric = metric; handle->pgc_page = NULL; handle->page_data = NULL; handle->page_data_size = 0; handle->page_position = 0; handle->page_entries_max = 0; handle->update_every_ut = (usec_t)update_every * USEC_PER_SEC; handle->options = is_1st_metric_writer ? RRDENG_1ST_METRIC_WRITER : 0; __atomic_add_fetch(&ctx->atomic.collectors_running, 1, __ATOMIC_RELAXED); if(!is_1st_metric_writer) __atomic_add_fetch(&ctx->atomic.collectors_running_duplicate, 1, __ATOMIC_RELAXED); mrg_metric_set_update_every(main_mrg, metric, update_every); handle->alignment = (struct pg_alignment *)smg; rrdeng_page_alignment_acquire(handle->alignment); // this is important! // if we don't set the page_end_time_ut during the first collection // data collection may be able to go back in time and during the addition of new pages // clean pages may be found matching ours! time_t db_first_time_s, db_last_time_s; mrg_metric_get_retention(main_mrg, metric, &db_first_time_s, &db_last_time_s, NULL); handle->page_end_time_ut = (usec_t)db_last_time_s * USEC_PER_SEC; return (STORAGE_COLLECT_HANDLE *)handle; } void rrdeng_store_metric_flush_current_page(STORAGE_COLLECT_HANDLE *sch) { struct rrdeng_collect_handle *handle = (struct rrdeng_collect_handle *)sch; if (unlikely(!handle->pgc_page)) return; if(pgd_is_empty(handle->page_data)) pgc_page_to_clean_evict_or_release(main_cache, handle->pgc_page); else { check_completed_page_consistency(handle); mrg_metric_set_clean_latest_time_s(main_mrg, handle->metric, pgc_page_end_time_s(handle->pgc_page)); struct rrdengine_instance *ctx = mrg_metric_ctx(handle->metric); time_t start_time_s = pgc_page_start_time_s(handle->pgc_page); time_t end_time_s = pgc_page_end_time_s(handle->pgc_page); uint32_t update_every_s = mrg_metric_get_update_every_s(main_mrg, handle->metric); if (end_time_s && start_time_s && end_time_s > start_time_s && update_every_s) { uint64_t add_samples = (end_time_s - start_time_s) / update_every_s; __atomic_add_fetch(&ctx->atomic.samples, add_samples, __ATOMIC_RELAXED); } pgc_page_hot_to_dirty_and_release(main_cache, handle->pgc_page, false); } mrg_metric_set_hot_latest_time_s(main_mrg, handle->metric, 0); handle->pgc_page = NULL; handle->page_flags = 0; handle->page_position = 0; handle->page_entries_max = 0; handle->page_data = NULL; handle->page_data_size = 0; // important! // we should never zero page end time ut, because this will allow // collection to go back in time // handle->page_end_time_ut = 0; // handle->page_start_time_ut; check_and_fix_mrg_update_every(handle); timing_step(TIMING_STEP_DBENGINE_FLUSH_PAGE); } static void rrdeng_store_metric_create_new_page(struct rrdeng_collect_handle *handle, struct rrdengine_instance *ctx, usec_t point_in_time_ut, PGD *data, size_t data_size) { time_t point_in_time_s = (time_t)(point_in_time_ut / USEC_PER_SEC); const uint32_t update_every_s = (uint32_t)(handle->update_every_ut / USEC_PER_SEC); PGC_ENTRY page_entry = { .section = (Word_t) ctx, .metric_id = mrg_metric_id(main_mrg, handle->metric), .start_time_s = point_in_time_s, .end_time_s = point_in_time_s, .size = data_size, .data = data, .update_every_s = update_every_s, .hot = true }; size_t conflicts = 0; bool added = true; PGC_PAGE *pgc_page = pgc_page_add_and_acquire(main_cache, page_entry, &added); while (unlikely(!added)) { conflicts++; char uuid[UUID_STR_LEN + 1]; uuid_unparse(*mrg_metric_uuid(main_mrg, handle->metric), uuid); #ifdef NETDATA_INTERNAL_CHECKS internal_error(true, #else nd_log_limit_static_global_var(erl, 1, 0); nd_log_limit(&erl, NDLS_DAEMON, NDLP_WARNING, #endif "DBENGINE: metric '%s' new page from %ld to %ld, update every %u, has a conflict in main cache " "with existing %s%s page from %ld to %ld, update every %u - " "is it collected more than once?", uuid, page_entry.start_time_s, page_entry.end_time_s, page_entry.update_every_s, pgc_is_page_hot(pgc_page) ? "hot" : "not-hot", pgc_page_data(pgc_page) == PGD_EMPTY ? " gap" : "", pgc_page_start_time_s(pgc_page), pgc_page_end_time_s(pgc_page), pgc_page_update_every_s(pgc_page) ); pgc_page_release(main_cache, pgc_page); point_in_time_ut -= handle->update_every_ut; point_in_time_s = (time_t)(point_in_time_ut / USEC_PER_SEC); page_entry.start_time_s = point_in_time_s; page_entry.end_time_s = point_in_time_s; pgc_page = pgc_page_add_and_acquire(main_cache, page_entry, &added); } handle->page_entries_max = data_size / CTX_POINT_SIZE_BYTES(ctx); handle->page_start_time_ut = point_in_time_ut; handle->page_end_time_ut = point_in_time_ut; handle->page_position = 1; // zero is already in our data handle->pgc_page = pgc_page; handle->page_flags = conflicts? RRDENG_PAGE_CONFLICT : 0; if(point_in_time_s > max_acceptable_collected_time()) handle->page_flags |= RRDENG_PAGE_CREATED_IN_FUTURE; check_and_fix_mrg_update_every(handle); timing_step(TIMING_STEP_DBENGINE_CREATE_NEW_PAGE); } static size_t aligned_allocation_entries(size_t max_slots, size_t target_slot, time_t now_s) { size_t slots = target_slot; size_t pos = (now_s % max_slots); if(pos > slots) slots += max_slots - pos; else if(pos < slots) slots -= pos; else slots = max_slots; return slots; } static PGD *rrdeng_alloc_new_page_data(struct rrdeng_collect_handle *handle, size_t *data_size, usec_t point_in_time_ut) { struct rrdengine_instance *ctx = mrg_metric_ctx(handle->metric); PGD *d = NULL; size_t max_size = tier_page_size[ctx->config.tier]; size_t max_slots = max_size / CTX_POINT_SIZE_BYTES(ctx); size_t slots = aligned_allocation_entries( max_slots, indexing_partition((Word_t) handle->alignment, max_slots), (time_t) (point_in_time_ut / USEC_PER_SEC) ); if(slots < max_slots / 3) slots = max_slots / 3; if(slots < 3) slots = 3; size_t size = slots * CTX_POINT_SIZE_BYTES(ctx); // internal_error(true, "PAGE ALLOC %zu bytes (%zu max)", size, max_size); internal_fatal(slots < 3 || slots > max_slots, "ooops! wrong distribution of metrics across time"); internal_fatal(size > tier_page_size[ctx->config.tier] || size < CTX_POINT_SIZE_BYTES(ctx) * 2, "ooops! wrong page size"); *data_size = size; switch (ctx->config.page_type) { case RRDENG_PAGE_TYPE_ARRAY_32BIT: case RRDENG_PAGE_TYPE_ARRAY_TIER1: d = pgd_create(ctx->config.page_type, slots); break; case RRDENG_PAGE_TYPE_GORILLA_32BIT: // ignore slots, and use the fixed number of slots per gorilla buffer. // gorilla will automatically add more buffers if needed. d = pgd_create(ctx->config.page_type, RRDENG_GORILLA_32BIT_BUFFER_SLOTS); break; default: fatal("Unknown page type: %uc\n", ctx->config.page_type); } timing_step(TIMING_STEP_DBENGINE_PAGE_ALLOC); return d; } static void rrdeng_store_metric_append_point(STORAGE_COLLECT_HANDLE *sch, const usec_t point_in_time_ut, const NETDATA_DOUBLE n, const NETDATA_DOUBLE min_value, const NETDATA_DOUBLE max_value, const uint16_t count, const uint16_t anomaly_count, const SN_FLAGS flags) { struct rrdeng_collect_handle *handle = (struct rrdeng_collect_handle *)sch; struct rrdengine_instance *ctx = mrg_metric_ctx(handle->metric); if(unlikely(!handle->page_data)) handle->page_data = rrdeng_alloc_new_page_data(handle, &handle->page_data_size, point_in_time_ut); timing_step(TIMING_STEP_DBENGINE_CHECK_DATA); pgd_append_point(handle->page_data, point_in_time_ut, n, min_value, max_value, count, anomaly_count, flags, handle->page_position); timing_step(TIMING_STEP_DBENGINE_PACK); if(unlikely(!handle->pgc_page)) { rrdeng_store_metric_create_new_page(handle, ctx, point_in_time_ut, handle->page_data, handle->page_data_size); // handle->position is set to 1 already } else { // update an existing page pgc_page_hot_set_end_time_s(main_cache, handle->pgc_page, (time_t) (point_in_time_ut / USEC_PER_SEC)); handle->page_end_time_ut = point_in_time_ut; if(unlikely(++handle->page_position >= handle->page_entries_max)) { internal_fatal(handle->page_position > handle->page_entries_max, "DBENGINE: exceeded page max number of points"); handle->page_flags |= RRDENG_PAGE_FULL; rrdeng_store_metric_flush_current_page(sch); } } timing_step(TIMING_STEP_DBENGINE_PAGE_FIN); // update the metric information mrg_metric_set_hot_latest_time_s(main_mrg, handle->metric, (time_t) (point_in_time_ut / USEC_PER_SEC)); timing_step(TIMING_STEP_DBENGINE_MRG_UPDATE); } static void store_metric_next_error_log(struct rrdeng_collect_handle *handle __maybe_unused, usec_t point_in_time_ut __maybe_unused, const char *msg __maybe_unused) { #ifdef NETDATA_INTERNAL_CHECKS time_t point_in_time_s = (time_t)(point_in_time_ut / USEC_PER_SEC); char uuid[UUID_STR_LEN + 1]; uuid_unparse(*mrg_metric_uuid(main_mrg, handle->metric), uuid); BUFFER *wb = NULL; if(handle->pgc_page && handle->page_flags) { wb = buffer_create(0, NULL); collect_page_flags_to_buffer(wb, handle->page_flags); } nd_log_limit_static_global_var(erl, 1, 0); nd_log_limit(&erl, NDLS_DAEMON, NDLP_NOTICE, "DBENGINE: metric '%s' collected point at %ld, %s last collection at %ld, " "update every %ld, %s page from %ld to %ld, position %u (of %u), flags: %s", uuid, point_in_time_s, msg, (time_t)(handle->page_end_time_ut / USEC_PER_SEC), (time_t)(handle->update_every_ut / USEC_PER_SEC), handle->pgc_page ? "current" : "*LAST*", (time_t)(handle->page_start_time_ut / USEC_PER_SEC), (time_t)(handle->page_end_time_ut / USEC_PER_SEC), handle->page_position, handle->page_entries_max, wb ? buffer_tostring(wb) : "" ); buffer_free(wb); #else ; #endif } void rrdeng_store_metric_next(STORAGE_COLLECT_HANDLE *sch, const usec_t point_in_time_ut, const NETDATA_DOUBLE n, const NETDATA_DOUBLE min_value, const NETDATA_DOUBLE max_value, const uint16_t count, const uint16_t anomaly_count, const SN_FLAGS flags) { timing_step(TIMING_STEP_RRDSET_STORE_METRIC); struct rrdeng_collect_handle *handle = (struct rrdeng_collect_handle *)sch; #ifdef NETDATA_INTERNAL_CHECKS if(unlikely(point_in_time_ut > (usec_t)max_acceptable_collected_time() * USEC_PER_SEC)) handle->page_flags |= RRDENG_PAGE_FUTURE_POINT; #endif usec_t delta_ut = point_in_time_ut - handle->page_end_time_ut; if(likely(delta_ut == handle->update_every_ut)) { // happy path ; } else if(unlikely(point_in_time_ut > handle->page_end_time_ut)) { if(handle->pgc_page) { if (unlikely(delta_ut < handle->update_every_ut)) { handle->page_flags |= RRDENG_PAGE_STEP_TOO_SMALL; rrdeng_store_metric_flush_current_page(sch); } else if (unlikely(delta_ut % handle->update_every_ut)) { handle->page_flags |= RRDENG_PAGE_STEP_UNALIGNED; rrdeng_store_metric_flush_current_page(sch); } else { size_t points_gap = delta_ut / handle->update_every_ut; size_t page_remaining_points = handle->page_entries_max - handle->page_position; if (points_gap >= page_remaining_points) { handle->page_flags |= RRDENG_PAGE_BIG_GAP; rrdeng_store_metric_flush_current_page(sch); } else { // loop to fill the gap handle->page_flags |= RRDENG_PAGE_GAP; usec_t stop_ut = point_in_time_ut - handle->update_every_ut; for (usec_t this_ut = handle->page_end_time_ut + handle->update_every_ut; this_ut <= stop_ut; this_ut = handle->page_end_time_ut + handle->update_every_ut) { rrdeng_store_metric_append_point( sch, this_ut, NAN, NAN, NAN, 1, 0, SN_EMPTY_SLOT); } } } } } else if(unlikely(point_in_time_ut < handle->page_end_time_ut)) { handle->page_flags |= RRDENG_PAGE_PAST_COLLECTION; store_metric_next_error_log(handle, point_in_time_ut, "is older than the"); return; } else /* if(unlikely(point_in_time_ut == handle->page_end_time_ut)) */ { handle->page_flags |= RRDENG_PAGE_REPEATED_COLLECTION; store_metric_next_error_log(handle, point_in_time_ut, "is at the same time as the"); return; } timing_step(TIMING_STEP_DBENGINE_FIRST_CHECK); rrdeng_store_metric_append_point(sch, point_in_time_ut, n, min_value, max_value, count, anomaly_count, flags); } /* * Releases the database reference from the handle for storing metrics. * Returns 1 if it's safe to delete the dimension. */ int rrdeng_store_metric_finalize(STORAGE_COLLECT_HANDLE *sch) { struct rrdeng_collect_handle *handle = (struct rrdeng_collect_handle *)sch; struct rrdengine_instance *ctx = mrg_metric_ctx(handle->metric); handle->page_flags |= RRDENG_PAGE_COLLECT_FINALIZE; rrdeng_store_metric_flush_current_page(sch); rrdeng_page_alignment_release(handle->alignment); __atomic_sub_fetch(&ctx->atomic.collectors_running, 1, __ATOMIC_RELAXED); if(!(handle->options & RRDENG_1ST_METRIC_WRITER)) __atomic_sub_fetch(&ctx->atomic.collectors_running_duplicate, 1, __ATOMIC_RELAXED); if((handle->options & RRDENG_1ST_METRIC_WRITER) && !mrg_metric_clear_writer(main_mrg, handle->metric)) internal_fatal(true, "DBENGINE: metric is already released"); time_t first_time_s, last_time_s; mrg_metric_get_retention(main_mrg, handle->metric, &first_time_s, &last_time_s, NULL); mrg_metric_release(main_mrg, handle->metric); freez(handle); if(!first_time_s && !last_time_s) return 1; return 0; } void rrdeng_store_metric_change_collection_frequency(STORAGE_COLLECT_HANDLE *sch, int update_every) { struct rrdeng_collect_handle *handle = (struct rrdeng_collect_handle *)sch; check_and_fix_mrg_update_every(handle); METRIC *metric = handle->metric; usec_t update_every_ut = (usec_t)update_every * USEC_PER_SEC; if(update_every_ut == handle->update_every_ut) return; handle->page_flags |= RRDENG_PAGE_UPDATE_EVERY_CHANGE; rrdeng_store_metric_flush_current_page(sch); mrg_metric_set_update_every(main_mrg, metric, update_every); handle->update_every_ut = update_every_ut; } // ---------------------------------------------------------------------------- // query ops #ifdef NETDATA_INTERNAL_CHECKS SPINLOCK global_query_handle_spinlock = NETDATA_SPINLOCK_INITIALIZER; static struct rrdeng_query_handle *global_query_handle_ll = NULL; static void register_query_handle(struct rrdeng_query_handle *handle) { handle->query_pid = gettid_cached(); handle->started_time_s = now_realtime_sec(); spinlock_lock(&global_query_handle_spinlock); DOUBLE_LINKED_LIST_APPEND_ITEM_UNSAFE(global_query_handle_ll, handle, prev, next); spinlock_unlock(&global_query_handle_spinlock); } static void unregister_query_handle(struct rrdeng_query_handle *handle) { spinlock_lock(&global_query_handle_spinlock); DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(global_query_handle_ll, handle, prev, next); spinlock_unlock(&global_query_handle_spinlock); } #else static void register_query_handle(struct rrdeng_query_handle *handle __maybe_unused) { ; } static void unregister_query_handle(struct rrdeng_query_handle *handle __maybe_unused) { ; } #endif /* * Gets a handle for loading metrics from the database. * The handle must be released with rrdeng_load_metric_final(). */ void rrdeng_load_metric_init(STORAGE_METRIC_HANDLE *smh, struct storage_engine_query_handle *seqh, time_t start_time_s, time_t end_time_s, STORAGE_PRIORITY priority) { usec_t started_ut = now_monotonic_usec(); METRIC *metric = (METRIC *)smh; struct rrdengine_instance *ctx = mrg_metric_ctx(metric); struct rrdeng_query_handle *handle; handle = rrdeng_query_handle_get(); register_query_handle(handle); if (unlikely(priority < STORAGE_PRIORITY_HIGH)) priority = STORAGE_PRIORITY_HIGH; else if (unlikely(priority >= STORAGE_PRIORITY_INTERNAL_MAX_DONT_USE)) priority = STORAGE_PRIORITY_INTERNAL_MAX_DONT_USE - 1; handle->ctx = ctx; handle->metric = metric; handle->priority = priority; // IMPORTANT! // It is crucial not to exceed the db boundaries, because dbengine // now has gap caching, so when a gap is detected a negative page // is inserted into the main cache, to avoid scanning the journals // again for pages matching the gap. time_t db_first_time_s, db_last_time_s; uint32_t db_update_every_s; mrg_metric_get_retention(main_mrg, metric, &db_first_time_s, &db_last_time_s, &db_update_every_s); if(is_page_in_time_range(start_time_s, end_time_s, db_first_time_s, db_last_time_s) == PAGE_IS_IN_RANGE) { handle->start_time_s = MAX(start_time_s, db_first_time_s); handle->end_time_s = MIN(end_time_s, db_last_time_s); handle->now_s = handle->start_time_s; handle->dt_s = db_update_every_s; if (!handle->dt_s) { handle->dt_s = default_rrd_update_every; mrg_metric_set_update_every_s_if_zero(main_mrg, metric, default_rrd_update_every); } seqh->handle = (STORAGE_QUERY_HANDLE *) handle; seqh->start_time_s = handle->start_time_s; seqh->end_time_s = handle->end_time_s; seqh->priority = priority; seqh->seb = STORAGE_ENGINE_BACKEND_DBENGINE; pg_cache_preload(handle); __atomic_add_fetch(&rrdeng_cache_efficiency_stats.query_time_init, now_monotonic_usec() - started_ut, __ATOMIC_RELAXED); } else { handle->start_time_s = start_time_s; handle->end_time_s = end_time_s; handle->now_s = start_time_s; handle->dt_s = db_update_every_s; seqh->handle = (STORAGE_QUERY_HANDLE *) handle; seqh->start_time_s = handle->start_time_s; seqh->end_time_s = 0; seqh->priority = priority; seqh->seb = STORAGE_ENGINE_BACKEND_DBENGINE; } } static bool rrdeng_load_page_next(struct storage_engine_query_handle *seqh, bool debug_this __maybe_unused) { struct rrdeng_query_handle *handle = (struct rrdeng_query_handle *)seqh->handle; struct rrdengine_instance *ctx = mrg_metric_ctx(handle->metric); if (likely(handle->page)) { // we have a page to release pgc_page_release(main_cache, handle->page); handle->page = NULL; pgdc_reset(&handle->pgdc, NULL, UINT32_MAX); } if (unlikely(handle->now_s > seqh->end_time_s)) return false; size_t entries = 0; handle->page = pg_cache_lookup_next(ctx, handle->pdc, handle->now_s, handle->dt_s, &entries); internal_fatal(handle->page && (pgc_page_data(handle->page) == PGD_EMPTY || !entries), "A page was returned, but it is empty - pg_cache_lookup_next() should be handling this case"); if (unlikely(!handle->page || pgc_page_data(handle->page) == PGD_EMPTY || !entries)) return false; time_t page_start_time_s = pgc_page_start_time_s(handle->page); time_t page_end_time_s = pgc_page_end_time_s(handle->page); uint32_t page_update_every_s = pgc_page_update_every_s(handle->page); unsigned position; if(likely(handle->now_s >= page_start_time_s && handle->now_s <= page_end_time_s)) { if(unlikely(entries == 1 || page_start_time_s == page_end_time_s || !page_update_every_s)) { position = 0; handle->now_s = page_start_time_s; } else { position = (handle->now_s - page_start_time_s) * (entries - 1) / (page_end_time_s - page_start_time_s); time_t point_end_time_s = page_start_time_s + position * (time_t) page_update_every_s; while(point_end_time_s < handle->now_s && position + 1 < entries) { // https://github.com/netdata/netdata/issues/14411 // we really need a while() here, because the delta may be // 2 points at higher tiers position++; point_end_time_s = page_start_time_s + position * (time_t) page_update_every_s; } handle->now_s = point_end_time_s; } internal_fatal(position >= entries, "DBENGINE: wrong page position calculation"); } else if(handle->now_s < page_start_time_s) { handle->now_s = page_start_time_s; position = 0; } else { internal_fatal(true, "DBENGINE: this page is entirely in our past and should not be accepted for this query in the first place"); handle->now_s = page_end_time_s; position = entries - 1; } handle->entries = entries; handle->position = position; handle->dt_s = page_update_every_s; pgdc_reset(&handle->pgdc, pgc_page_data(handle->page), handle->position); return true; } // Returns the metric and sets its timestamp into current_time // IT IS REQUIRED TO **ALWAYS** SET ALL RETURN VALUES (current_time, end_time, flags) // IT IS REQUIRED TO **ALWAYS** KEEP TRACK OF TIME, EVEN OUTSIDE THE DATABASE BOUNDARIES STORAGE_POINT rrdeng_load_metric_next(struct storage_engine_query_handle *seqh) { struct rrdeng_query_handle *handle = (struct rrdeng_query_handle *)seqh->handle; STORAGE_POINT sp; if (unlikely(handle->now_s > seqh->end_time_s)) { storage_point_empty(sp, handle->now_s - handle->dt_s, handle->now_s); goto prepare_for_next_iteration; } if (unlikely(!handle->page || handle->position >= handle->entries)) { // We need to get a new page if (!rrdeng_load_page_next(seqh, false)) { handle->now_s = seqh->end_time_s; storage_point_empty(sp, handle->now_s - handle->dt_s, handle->now_s); goto prepare_for_next_iteration; } } sp.start_time_s = handle->now_s - handle->dt_s; sp.end_time_s = handle->now_s; pgdc_get_next_point(&handle->pgdc, handle->position, &sp); prepare_for_next_iteration: internal_fatal(sp.end_time_s < seqh->start_time_s, "DBENGINE: this point is too old for this query"); internal_fatal(sp.end_time_s < handle->now_s, "DBENGINE: this point is too old for this point in time"); handle->now_s += handle->dt_s; handle->position++; return sp; } int rrdeng_load_metric_is_finished(struct storage_engine_query_handle *seqh) { struct rrdeng_query_handle *handle = (struct rrdeng_query_handle *)seqh->handle; return (handle->now_s > seqh->end_time_s); } /* * Releases the database reference from the handle for loading metrics. */ void rrdeng_load_metric_finalize(struct storage_engine_query_handle *seqh) { struct rrdeng_query_handle *handle = (struct rrdeng_query_handle *)seqh->handle; if (handle->page) { pgc_page_release(main_cache, handle->page); pgdc_reset(&handle->pgdc, NULL, UINT32_MAX); } if(!pdc_release_and_destroy_if_unreferenced(handle->pdc, false, false)) __atomic_store_n(&handle->pdc->workers_should_stop, true, __ATOMIC_RELAXED); unregister_query_handle(handle); rrdeng_query_handle_release(handle); seqh->handle = NULL; } time_t rrdeng_load_align_to_optimal_before(struct storage_engine_query_handle *seqh) { struct rrdeng_query_handle *handle = (struct rrdeng_query_handle *)seqh->handle; if(handle->pdc) { rrdeng_prep_wait(handle->pdc); if (handle->pdc->optimal_end_time_s > seqh->end_time_s) seqh->end_time_s = handle->pdc->optimal_end_time_s; } return seqh->end_time_s; } time_t rrdeng_metric_latest_time(STORAGE_METRIC_HANDLE *smh) { METRIC *metric = (METRIC *)smh; time_t latest_time_s = 0; if (metric) latest_time_s = mrg_metric_get_latest_time_s(main_mrg, metric); return latest_time_s; } time_t rrdeng_metric_oldest_time(STORAGE_METRIC_HANDLE *smh) { METRIC *metric = (METRIC *)smh; time_t oldest_time_s = 0; if (metric) oldest_time_s = mrg_metric_get_first_time_s(main_mrg, metric); return oldest_time_s; } bool rrdeng_metric_retention_by_uuid(STORAGE_INSTANCE *si, nd_uuid_t *dim_uuid, time_t *first_entry_s, time_t *last_entry_s) { struct rrdengine_instance *ctx = (struct rrdengine_instance *)si; if (unlikely(!ctx)) { netdata_log_error("DBENGINE: invalid STORAGE INSTANCE to %s()", __FUNCTION__); return false; } METRIC *metric = mrg_metric_get_and_acquire(main_mrg, dim_uuid, (Word_t) ctx); if (unlikely(!metric)) return false; mrg_metric_get_retention(main_mrg, metric, first_entry_s, last_entry_s, NULL); mrg_metric_release(main_mrg, metric); return true; } uint64_t rrdeng_disk_space_max(STORAGE_INSTANCE *si) { struct rrdengine_instance *ctx = (struct rrdengine_instance *)si; return ctx->config.max_disk_space; } uint64_t rrdeng_disk_space_used(STORAGE_INSTANCE *si) { struct rrdengine_instance *ctx = (struct rrdengine_instance *)si; return __atomic_load_n(&ctx->atomic.current_disk_space, __ATOMIC_RELAXED); } uint64_t rrdeng_metrics(STORAGE_INSTANCE *si) { struct rrdengine_instance *ctx = (struct rrdengine_instance *)si; return __atomic_load_n(&ctx->atomic.metrics, __ATOMIC_RELAXED); } uint64_t rrdeng_samples(STORAGE_INSTANCE *si) { struct rrdengine_instance *ctx = (struct rrdengine_instance *)si; return __atomic_load_n(&ctx->atomic.samples, __ATOMIC_RELAXED); } time_t rrdeng_global_first_time_s(STORAGE_INSTANCE *si) { struct rrdengine_instance *ctx = (struct rrdengine_instance *)si; time_t t = __atomic_load_n(&ctx->atomic.first_time_s, __ATOMIC_RELAXED); if(t == LONG_MAX || t < 0) t = 0; return t; } size_t rrdeng_currently_collected_metrics(STORAGE_INSTANCE *si) { struct rrdengine_instance *ctx = (struct rrdengine_instance *)si; return __atomic_load_n(&ctx->atomic.collectors_running, __ATOMIC_RELAXED); } /* * Gathers Database Engine statistics. * Careful when modifying this function. * You must not change the indices of the statistics or user code will break. * You must not exceed RRDENG_NR_STATS or it will crash. */ void rrdeng_get_37_statistics(struct rrdengine_instance *ctx, unsigned long long *array) { if (ctx == NULL) return; array[0] = (uint64_t)__atomic_load_n(&ctx->atomic.collectors_running, __ATOMIC_RELAXED); // API producers array[1] = (uint64_t)__atomic_load_n(&ctx->atomic.inflight_queries, __ATOMIC_RELAXED); // API consumers array[2] = 0; array[3] = 0; array[4] = 0; array[5] = 0; // (uint64_t)ctx->stats.pg_cache_insertions; array[6] = 0; // (uint64_t)ctx->stats.pg_cache_deletions; array[7] = 0; // (uint64_t)ctx->stats.pg_cache_hits; array[8] = 0; // (uint64_t)ctx->stats.pg_cache_misses; array[9] = 0; // (uint64_t)ctx->stats.pg_cache_backfills; array[10] = 0; // (uint64_t)ctx->stats.pg_cache_evictions; array[11] = (uint64_t)__atomic_load_n(&ctx->stats.before_compress_bytes, __ATOMIC_RELAXED); // used array[12] = (uint64_t)__atomic_load_n(&ctx->stats.after_compress_bytes, __ATOMIC_RELAXED); // used array[13] = (uint64_t)__atomic_load_n(&ctx->stats.before_decompress_bytes, __ATOMIC_RELAXED); array[14] = (uint64_t)__atomic_load_n(&ctx->stats.after_decompress_bytes, __ATOMIC_RELAXED); array[15] = (uint64_t)__atomic_load_n(&ctx->stats.io_write_bytes, __ATOMIC_RELAXED); // used array[16] = (uint64_t)__atomic_load_n(&ctx->stats.io_write_requests, __ATOMIC_RELAXED); // used array[17] = (uint64_t)__atomic_load_n(&ctx->stats.io_read_bytes, __ATOMIC_RELAXED); array[18] = (uint64_t)__atomic_load_n(&ctx->stats.io_read_requests, __ATOMIC_RELAXED); // used array[19] = 0; // (uint64_t)__atomic_load_n(&ctx->stats.io_write_extent_bytes, __ATOMIC_RELAXED); array[20] = 0; // (uint64_t)__atomic_load_n(&ctx->stats.io_write_extents, __ATOMIC_RELAXED); array[21] = 0; // (uint64_t)__atomic_load_n(&ctx->stats.io_read_extent_bytes, __ATOMIC_RELAXED); array[22] = 0; // (uint64_t)__atomic_load_n(&ctx->stats.io_read_extents, __ATOMIC_RELAXED); array[23] = (uint64_t)__atomic_load_n(&ctx->stats.datafile_creations, __ATOMIC_RELAXED); array[24] = (uint64_t)__atomic_load_n(&ctx->stats.datafile_deletions, __ATOMIC_RELAXED); array[25] = (uint64_t)__atomic_load_n(&ctx->stats.journalfile_creations, __ATOMIC_RELAXED); array[26] = (uint64_t)__atomic_load_n(&ctx->stats.journalfile_deletions, __ATOMIC_RELAXED); array[27] = 0; // (uint64_t)__atomic_load_n(&ctx->stats.page_cache_descriptors, __ATOMIC_RELAXED); array[28] = (uint64_t)__atomic_load_n(&ctx->stats.io_errors, __ATOMIC_RELAXED); array[29] = (uint64_t)__atomic_load_n(&ctx->stats.fs_errors, __ATOMIC_RELAXED); array[30] = (uint64_t)__atomic_load_n(&global_io_errors, __ATOMIC_RELAXED); // used array[31] = (uint64_t)__atomic_load_n(&global_fs_errors, __ATOMIC_RELAXED); // used array[32] = (uint64_t)__atomic_load_n(&rrdeng_reserved_file_descriptors, __ATOMIC_RELAXED); // used array[33] = 0; // (uint64_t)__atomic_load_n(&ctx->stats.pg_cache_over_half_dirty_events, __ATOMIC_RELAXED); array[34] = (uint64_t)__atomic_load_n(&global_pg_cache_over_half_dirty_events, __ATOMIC_RELAXED); // used array[35] = 0; // (uint64_t)__atomic_load_n(&ctx->stats.flushing_pressure_page_deletions, __ATOMIC_RELAXED); array[36] = (uint64_t)__atomic_load_n(&global_flushing_pressure_page_deletions, __ATOMIC_RELAXED); // used array[37] = 0; //(uint64_t)pg_cache->active_descriptors; fatal_assert(RRDENG_NR_STATS == 38); } static void rrdeng_populate_mrg(struct rrdengine_instance *ctx) { uv_rwlock_rdlock(&ctx->datafiles.rwlock); size_t datafiles = 0; for(struct rrdengine_datafile *df = ctx->datafiles.first; df ;df = df->next) datafiles++; uv_rwlock_rdunlock(&ctx->datafiles.rwlock); ssize_t cpus = (ssize_t)get_netdata_cpus() / (ssize_t)storage_tiers; if(cpus > (ssize_t)datafiles) cpus = (ssize_t)datafiles; if(cpus > (ssize_t)libuv_worker_threads) cpus = (ssize_t)libuv_worker_threads; if(cpus >= (ssize_t)get_netdata_cpus() / 2) cpus = (ssize_t)(get_netdata_cpus() / 2 - 1); if(cpus < 1) cpus = 1; netdata_log_info("DBENGINE: populating retention to MRG from %zu journal files of tier %d, using %zd threads...", datafiles, ctx->config.tier, cpus); if(datafiles > 2) { struct rrdengine_datafile *datafile; datafile = ctx->datafiles.first->prev; if(!(datafile->journalfile->v2.flags & JOURNALFILE_FLAG_IS_AVAILABLE)) datafile = datafile->prev; if(datafile->journalfile->v2.flags & JOURNALFILE_FLAG_IS_AVAILABLE) { journalfile_v2_populate_retention_to_mrg(ctx, datafile->journalfile); datafile->populate_mrg.populated = true; } datafile = ctx->datafiles.first; if(datafile->journalfile->v2.flags & JOURNALFILE_FLAG_IS_AVAILABLE) { journalfile_v2_populate_retention_to_mrg(ctx, datafile->journalfile); datafile->populate_mrg.populated = true; } } ctx->loading.populate_mrg.size = cpus; ctx->loading.populate_mrg.array = callocz(ctx->loading.populate_mrg.size, sizeof(struct completion)); for (size_t i = 0; i < ctx->loading.populate_mrg.size; i++) { completion_init(&ctx->loading.populate_mrg.array[i]); rrdeng_enq_cmd(ctx, RRDENG_OPCODE_CTX_POPULATE_MRG, NULL, &ctx->loading.populate_mrg.array[i], STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL); } } void rrdeng_readiness_wait(struct rrdengine_instance *ctx) { for (size_t i = 0; i < ctx->loading.populate_mrg.size; i++) { completion_wait_for(&ctx->loading.populate_mrg.array[i]); completion_destroy(&ctx->loading.populate_mrg.array[i]); } freez(ctx->loading.populate_mrg.array); ctx->loading.populate_mrg.array = NULL; ctx->loading.populate_mrg.size = 0; netdata_log_info("DBENGINE: tier %d is ready for data collection and queries", ctx->config.tier); } void rrdeng_exit_mode(struct rrdengine_instance *ctx) { __atomic_store_n(&ctx->quiesce.exit_mode, true, __ATOMIC_RELAXED); } /* * Returns 0 on success, negative on error */ int rrdeng_init( struct rrdengine_instance **ctxp, const char *dbfiles_path, unsigned disk_space_mb, size_t tier, time_t max_retention_s) { struct rrdengine_instance *ctx; uint32_t max_open_files; max_open_files = rlimit_nofile.rlim_cur / 4; /* reserve RRDENG_FD_BUDGET_PER_INSTANCE file descriptors for this instance */ rrd_stat_atomic_add(&rrdeng_reserved_file_descriptors, RRDENG_FD_BUDGET_PER_INSTANCE); if (rrdeng_reserved_file_descriptors > max_open_files) { netdata_log_error( "Exceeded the budget of available file descriptors (%u/%u), cannot create new dbengine instance.", (unsigned)rrdeng_reserved_file_descriptors, (unsigned)max_open_files); rrd_stat_atomic_add(&global_fs_errors, 1); rrd_stat_atomic_add(&rrdeng_reserved_file_descriptors, -RRDENG_FD_BUDGET_PER_INSTANCE); return UV_EMFILE; } if(ctxp) { *ctxp = ctx = mallocz(sizeof(*ctx)); initialize_single_ctx(ctx); } else ctx = multidb_ctx[tier]; ctx->config.tier = (int)tier; ctx->config.page_type = tier_page_type[tier]; ctx->config.global_compress_alg = dbengine_default_compression(); strncpyz(ctx->config.dbfiles_path, dbfiles_path, sizeof(ctx->config.dbfiles_path) - 1); ctx->config.dbfiles_path[sizeof(ctx->config.dbfiles_path) - 1] = '\0'; if (disk_space_mb && disk_space_mb < RRDENG_MIN_DISK_SPACE_MB) disk_space_mb = RRDENG_MIN_DISK_SPACE_MB; ctx->config.max_disk_space = disk_space_mb * 1048576LLU; ctx->config.max_retention_s = max_retention_s; ctx->atomic.transaction_id = 1; ctx->quiesce.enabled = false; ctx->atomic.first_time_s = LONG_MAX; ctx->atomic.metrics = 0; ctx->atomic.samples = 0; if (rrdeng_dbengine_spawn(ctx) && !init_rrd_files(ctx)) { // success - we run this ctx too rrdeng_populate_mrg(ctx); return 0; } if (unittest_running) { freez(ctx); if (ctxp) *ctxp = NULL; } rrd_stat_atomic_add(&rrdeng_reserved_file_descriptors, -RRDENG_FD_BUDGET_PER_INSTANCE); return UV_EIO; } size_t rrdeng_collectors_running(struct rrdengine_instance *ctx) { return __atomic_load_n(&ctx->atomic.collectors_running, __ATOMIC_RELAXED); } /* * Returns 0 on success, 1 on error */ int rrdeng_exit(struct rrdengine_instance *ctx) { if (NULL == ctx) return 1; // FIXME - ktsaou - properly cleanup ctx // 1. make sure all collectors are stopped // 2. make new queries will not be accepted (this is quiesce that has already run) // 3. flush this section of the main cache // 4. then wait for completion bool logged = false; size_t count = 10; while(__atomic_load_n(&ctx->atomic.collectors_running, __ATOMIC_RELAXED) && count && !unittest_running) { if(!logged) { netdata_log_info("DBENGINE: waiting for collectors to finish on tier %d...", ctx->config.tier); logged = true; } sleep_usec(100 * USEC_PER_MS); count--; } netdata_log_info("DBENGINE: flushing main cache for tier %d", ctx->config.tier); pgc_flush_all_hot_and_dirty_pages(main_cache, (Word_t)ctx); netdata_log_info("DBENGINE: shutting down tier %d", ctx->config.tier); struct completion completion = {}; completion_init(&completion); rrdeng_enq_cmd(ctx, RRDENG_OPCODE_CTX_SHUTDOWN, NULL, &completion, STORAGE_PRIORITY_BEST_EFFORT, NULL, NULL); completion_wait_for(&completion); completion_destroy(&completion); finalize_rrd_files(ctx); if (unittest_running) //(ctx->config.unittest) freez(ctx); rrd_stat_atomic_add(&rrdeng_reserved_file_descriptors, -RRDENG_FD_BUDGET_PER_INSTANCE); return 0; } void rrdeng_prepare_exit(struct rrdengine_instance *ctx) { if (NULL == ctx) return; // FIXME - ktsaou - properly cleanup ctx // 1. make sure all collectors are stopped completion_init(&ctx->quiesce.completion); rrdeng_enq_cmd(ctx, RRDENG_OPCODE_CTX_QUIESCE, NULL, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL); } static void populate_v2_statistics(struct rrdengine_datafile *datafile, RRDENG_SIZE_STATS *stats) { struct journal_v2_header *j2_header = journalfile_v2_data_acquire(datafile->journalfile, NULL, 0, 0); void *data_start = (void *)j2_header; if(unlikely(!j2_header)) return; stats->extents += j2_header->extent_count; unsigned entries; struct journal_extent_list *extent_list = (void *) (data_start + j2_header->extent_offset); for (entries = 0; entries < j2_header->extent_count; entries++) { stats->extents_compressed_bytes += extent_list->datafile_size; stats->extents_pages += extent_list->pages; extent_list++; } struct journal_metric_list *metric = (void *) (data_start + j2_header->metric_offset); time_t journal_start_time_s = (time_t) (j2_header->start_time_ut / USEC_PER_SEC); stats->metrics += j2_header->metric_count; for (entries = 0; entries < j2_header->metric_count; entries++) { struct journal_page_header *metric_list_header = (void *) (data_start + metric->page_offset); stats->metrics_pages += metric_list_header->entries; struct journal_page_list *descr = (void *) (data_start + metric->page_offset + sizeof(struct journal_page_header)); for (uint32_t idx=0; idx < metric_list_header->entries; idx++) { time_t update_every_s; size_t points = descr->page_length / CTX_POINT_SIZE_BYTES(datafile->ctx); time_t start_time_s = journal_start_time_s + descr->delta_start_s; time_t end_time_s = journal_start_time_s + descr->delta_end_s; if(likely(points > 1)) update_every_s = (time_t) ((end_time_s - start_time_s) / (points - 1)); else { update_every_s = (time_t) (default_rrd_update_every * get_tier_grouping(datafile->ctx->config.tier)); stats->single_point_pages++; } time_t duration_s = (time_t)((end_time_s - start_time_s + update_every_s)); stats->pages_uncompressed_bytes += descr->page_length; stats->pages_duration_secs += duration_s; stats->points += points; stats->page_types[descr->type].pages++; stats->page_types[descr->type].pages_uncompressed_bytes += descr->page_length; stats->page_types[descr->type].pages_duration_secs += duration_s; stats->page_types[descr->type].points += points; if(!stats->first_time_s || (start_time_s - update_every_s) < stats->first_time_s) stats->first_time_s = (start_time_s - update_every_s); if(!stats->last_time_s || end_time_s > stats->last_time_s) stats->last_time_s = end_time_s; descr++; } metric++; } journalfile_v2_data_release(datafile->journalfile); } RRDENG_SIZE_STATS rrdeng_size_statistics(struct rrdengine_instance *ctx) { RRDENG_SIZE_STATS stats = { 0 }; uv_rwlock_rdlock(&ctx->datafiles.rwlock); for(struct rrdengine_datafile *df = ctx->datafiles.first; df ;df = df->next) { stats.datafiles++; populate_v2_statistics(df, &stats); } uv_rwlock_rdunlock(&ctx->datafiles.rwlock); stats.currently_collected_metrics = __atomic_load_n(&ctx->atomic.collectors_running, __ATOMIC_RELAXED); internal_error(stats.metrics_pages != stats.extents_pages + stats.currently_collected_metrics, "DBENGINE: metrics pages is %zu, but extents pages is %zu and API consumers is %zu", stats.metrics_pages, stats.extents_pages, stats.currently_collected_metrics); stats.disk_space = ctx_current_disk_space_get(ctx); stats.max_disk_space = ctx->config.max_disk_space; stats.database_retention_secs = (time_t)(stats.last_time_s - stats.first_time_s); if(stats.extents_pages) stats.average_page_size_bytes = (double)stats.pages_uncompressed_bytes / (double)stats.extents_pages; if(stats.pages_uncompressed_bytes > 0) stats.average_compression_savings = 100.0 - ((double)stats.extents_compressed_bytes * 100.0 / (double)stats.pages_uncompressed_bytes); if(stats.points) stats.average_point_duration_secs = (double)stats.pages_duration_secs / (double)stats.points; if(stats.metrics) { stats.average_metric_retention_secs = (double)stats.pages_duration_secs / (double)stats.metrics; if(stats.database_retention_secs) { double metric_coverage = stats.average_metric_retention_secs / (double)stats.database_retention_secs; double db_retention_days = (double)stats.database_retention_secs / 86400.0; stats.estimated_concurrently_collected_metrics = stats.metrics * metric_coverage; stats.ephemeral_metrics_per_day_percent = ((double)stats.metrics * 100.0 / (double)stats.estimated_concurrently_collected_metrics - 100.0) / (double)db_retention_days; } } // stats.sizeof_metric = 0; stats.sizeof_datafile = struct_natural_alignment(sizeof(struct rrdengine_datafile)) + struct_natural_alignment(sizeof(struct rrdengine_journalfile)); stats.sizeof_page_in_cache = 0; // struct_natural_alignment(sizeof(struct page_cache_descr)); stats.sizeof_point_data = page_type_size[ctx->config.page_type]; stats.sizeof_page_data = tier_page_size[ctx->config.tier]; stats.pages_per_extent = rrdeng_pages_per_extent; // stats.sizeof_metric_in_index = 40; // stats.sizeof_page_in_index = 24; stats.default_granularity_secs = (size_t)default_rrd_update_every * get_tier_grouping(ctx->config.tier); return stats; } struct rrdeng_cache_efficiency_stats rrdeng_get_cache_efficiency_stats(void) { // FIXME - make cache efficiency stats atomic return rrdeng_cache_efficiency_stats; }