package main import ( "context" "errors" "fmt" "hash/fnv" "net/url" "strconv" "strings" "sync" "time" "github.com/VictoriaMetrics/metrics" "github.com/VictoriaMetrics/VictoriaMetrics/app/vmalert/config" "github.com/VictoriaMetrics/VictoriaMetrics/app/vmalert/datasource" "github.com/VictoriaMetrics/VictoriaMetrics/app/vmalert/notifier" "github.com/VictoriaMetrics/VictoriaMetrics/app/vmalert/remotewrite" "github.com/VictoriaMetrics/VictoriaMetrics/app/vmalert/utils" "github.com/VictoriaMetrics/VictoriaMetrics/lib/decimal" "github.com/VictoriaMetrics/VictoriaMetrics/lib/logger" "github.com/VictoriaMetrics/VictoriaMetrics/lib/prompbmarshal" ) // Group is an entity for grouping rules type Group struct { mu sync.RWMutex Name string File string Rules []Rule Type config.Type Interval time.Duration EvalOffset *time.Duration Limit int Concurrency int Checksum string LastEvaluation time.Time Labels map[string]string Params url.Values Headers map[string]string NotifierHeaders map[string]string doneCh chan struct{} finishedCh chan struct{} // channel accepts new Group obj // which supposed to update current group updateCh chan *Group // evalCancel stores the cancel fn for interrupting // rules evaluation. Used on groups update() and close(). evalCancel context.CancelFunc metrics *groupMetrics } type groupMetrics struct { iterationTotal *utils.Counter iterationDuration *utils.Summary iterationMissed *utils.Counter iterationInterval *utils.Gauge } func newGroupMetrics(g *Group) *groupMetrics { m := &groupMetrics{} labels := fmt.Sprintf(`group=%q, file=%q`, g.Name, g.File) m.iterationTotal = utils.GetOrCreateCounter(fmt.Sprintf(`vmalert_iteration_total{%s}`, labels)) m.iterationDuration = utils.GetOrCreateSummary(fmt.Sprintf(`vmalert_iteration_duration_seconds{%s}`, labels)) m.iterationMissed = utils.GetOrCreateCounter(fmt.Sprintf(`vmalert_iteration_missed_total{%s}`, labels)) m.iterationInterval = utils.GetOrCreateGauge(fmt.Sprintf(`vmalert_iteration_interval_seconds{%s}`, labels), func() float64 { g.mu.RLock() i := g.Interval.Seconds() g.mu.RUnlock() return i }) return m } // merges group rule labels into result map // set2 has priority over set1. func mergeLabels(groupName, ruleName string, set1, set2 map[string]string) map[string]string { r := map[string]string{} for k, v := range set1 { r[k] = v } for k, v := range set2 { if prevV, ok := r[k]; ok { logger.Infof("label %q=%q for rule %q.%q overwritten with external label %q=%q", k, prevV, groupName, ruleName, k, v) } r[k] = v } return r } func newGroup(cfg config.Group, qb datasource.QuerierBuilder, defaultInterval time.Duration, labels map[string]string) *Group { g := &Group{ Type: cfg.Type, Name: cfg.Name, File: cfg.File, Interval: cfg.Interval.Duration(), Limit: cfg.Limit, Concurrency: cfg.Concurrency, Checksum: cfg.Checksum, Params: cfg.Params, Headers: make(map[string]string), NotifierHeaders: make(map[string]string), Labels: cfg.Labels, doneCh: make(chan struct{}), finishedCh: make(chan struct{}), updateCh: make(chan *Group), } if g.Interval == 0 { g.Interval = defaultInterval } if g.Concurrency < 1 { g.Concurrency = 1 } if cfg.EvalOffset != nil { g.EvalOffset = &cfg.EvalOffset.D } for _, h := range cfg.Headers { g.Headers[h.Key] = h.Value } for _, h := range cfg.NotifierHeaders { g.NotifierHeaders[h.Key] = h.Value } g.metrics = newGroupMetrics(g) rules := make([]Rule, len(cfg.Rules)) for i, r := range cfg.Rules { var extraLabels map[string]string // apply external labels if len(labels) > 0 { extraLabels = labels } // apply group labels, it has priority on external labels if len(cfg.Labels) > 0 { extraLabels = mergeLabels(g.Name, r.Name(), extraLabels, g.Labels) } // apply rules labels, it has priority on other labels if len(extraLabels) > 0 { r.Labels = mergeLabels(g.Name, r.Name(), extraLabels, r.Labels) } rules[i] = g.newRule(qb, r) } g.Rules = rules return g } func (g *Group) newRule(qb datasource.QuerierBuilder, rule config.Rule) Rule { if rule.Alert != "" { return newAlertingRule(qb, g, rule) } return newRecordingRule(qb, g, rule) } // ID return unique group ID that consists of // rules file and group Name func (g *Group) ID() uint64 { g.mu.RLock() defer g.mu.RUnlock() hash := fnv.New64a() hash.Write([]byte(g.File)) hash.Write([]byte("\xff")) hash.Write([]byte(g.Name)) hash.Write([]byte(g.Type.Get())) hash.Write([]byte(g.Interval.String())) if g.EvalOffset != nil { hash.Write([]byte(g.EvalOffset.String())) } return hash.Sum64() } // Restore restores alerts state for group rules func (g *Group) Restore(ctx context.Context, qb datasource.QuerierBuilder, ts time.Time, lookback time.Duration) error { for _, rule := range g.Rules { ar, ok := rule.(*AlertingRule) if !ok { continue } if ar.For < 1 { continue } q := qb.BuildWithParams(datasource.QuerierParams{ DataSourceType: g.Type.String(), EvaluationInterval: g.Interval, QueryParams: g.Params, Headers: g.Headers, Debug: ar.Debug, }) if err := ar.Restore(ctx, q, ts, lookback); err != nil { return fmt.Errorf("error while restoring rule %q: %w", rule, err) } } return nil } // updateWith updates existing group with // passed group object. This function ignores group // evaluation interval change. It supposed to be updated // in group.start function. // Not thread-safe. func (g *Group) updateWith(newGroup *Group) error { rulesRegistry := make(map[uint64]Rule) for _, nr := range newGroup.Rules { rulesRegistry[nr.ID()] = nr } for i, or := range g.Rules { nr, ok := rulesRegistry[or.ID()] if !ok { // old rule is not present in the new list // so we mark it for removing g.Rules[i].Close() g.Rules[i] = nil continue } if err := or.UpdateWith(nr); err != nil { return err } delete(rulesRegistry, nr.ID()) } var newRules []Rule for _, r := range g.Rules { if r == nil { // skip nil rules continue } newRules = append(newRules, r) } // add the rest of rules from registry for _, nr := range rulesRegistry { newRules = append(newRules, nr) } // note that g.Interval is not updated here // so the value can be compared later in // group.Start function g.Type = newGroup.Type g.Concurrency = newGroup.Concurrency g.Params = newGroup.Params g.Headers = newGroup.Headers g.NotifierHeaders = newGroup.NotifierHeaders g.Labels = newGroup.Labels g.Limit = newGroup.Limit g.Checksum = newGroup.Checksum g.Rules = newRules return nil } // interruptEval interrupts in-flight rules evaluations // within the group. It is expected that g.evalCancel // will be repopulated after the call. func (g *Group) interruptEval() { g.mu.RLock() defer g.mu.RUnlock() if g.evalCancel != nil { g.evalCancel() } } func (g *Group) close() { if g.doneCh == nil { return } close(g.doneCh) g.interruptEval() <-g.finishedCh g.metrics.iterationDuration.Unregister() g.metrics.iterationTotal.Unregister() g.metrics.iterationMissed.Unregister() g.metrics.iterationInterval.Unregister() for _, rule := range g.Rules { rule.Close() } } var skipRandSleepOnGroupStart bool func (g *Group) start(ctx context.Context, nts func() []notifier.Notifier, rw *remotewrite.Client, rr datasource.QuerierBuilder) { defer func() { close(g.finishedCh) }() // sleep random duration to spread group rules evaluation // over time in order to reduce load on datasource. if !skipRandSleepOnGroupStart { sleepBeforeStart := delayBeforeStart(time.Now(), g.ID(), g.Interval, g.EvalOffset) g.infof("will start in %v", sleepBeforeStart) sleepTimer := time.NewTimer(sleepBeforeStart) select { case <-ctx.Done(): sleepTimer.Stop() return case <-g.doneCh: sleepTimer.Stop() return case <-sleepTimer.C: } } evalTS := time.Now() e := &executor{ rw: rw, notifiers: nts, notifierHeaders: g.NotifierHeaders, previouslySentSeriesToRW: make(map[uint64]map[string][]prompbmarshal.Label), } g.infof("started") eval := func(ctx context.Context, ts time.Time) { g.metrics.iterationTotal.Inc() start := time.Now() if len(g.Rules) < 1 { g.metrics.iterationDuration.UpdateDuration(start) g.LastEvaluation = start return } resolveDuration := getResolveDuration(g.Interval, *resendDelay, *maxResolveDuration) errs := e.execConcurrently(ctx, g.Rules, ts, g.Concurrency, resolveDuration, g.Limit) for err := range errs { if err != nil { logger.Errorf("group %q: %s", g.Name, err) } } g.metrics.iterationDuration.UpdateDuration(start) g.LastEvaluation = start } evalCtx, cancel := context.WithCancel(ctx) g.mu.Lock() g.evalCancel = cancel g.mu.Unlock() defer g.evalCancel() eval(evalCtx, evalTS) t := time.NewTicker(g.Interval) defer t.Stop() // restore the rules state after the first evaluation // so only active alerts can be restored. if rr != nil { err := g.Restore(ctx, rr, evalTS, *remoteReadLookBack) if err != nil { logger.Errorf("error while restoring ruleState for group %q: %s", g.Name, err) } } for { select { case <-ctx.Done(): logger.Infof("group %q: context cancelled", g.Name) return case <-g.doneCh: logger.Infof("group %q: received stop signal", g.Name) return case ng := <-g.updateCh: g.mu.Lock() // it is expected that g.evalCancel will be evoked // somewhere else to unblock group from the rules evaluation. // we recreate the evalCtx and g.evalCancel, so it can // be called again. evalCtx, cancel = context.WithCancel(ctx) g.evalCancel = cancel err := g.updateWith(ng) if err != nil { logger.Errorf("group %q: failed to update: %s", g.Name, err) g.mu.Unlock() continue } // ensure that staleness is tracked for existing rules only e.purgeStaleSeries(g.Rules) e.notifierHeaders = g.NotifierHeaders g.mu.Unlock() g.infof("re-started") case <-t.C: missed := (time.Since(evalTS) / g.Interval) - 1 if missed < 0 { // missed can become < 0 due to irregular delays during evaluation // which can result in time.Since(evalTS) < g.Interval missed = 0 } if missed > 0 { g.metrics.iterationMissed.Inc() } evalTS = evalTS.Add((missed + 1) * g.Interval) eval(evalCtx, evalTS) } } } // delayBeforeStart returns a duration on the interval between [ts..ts+interval]. // delayBeforeStart accounts for `offset`, so returned duration should be always // bigger than the `offset`. func delayBeforeStart(ts time.Time, key uint64, interval time.Duration, offset *time.Duration) time.Duration { var randSleep time.Duration randSleep = time.Duration(float64(interval) * (float64(key) / (1 << 64))) sleepOffset := time.Duration(ts.UnixNano() % interval.Nanoseconds()) if randSleep < sleepOffset { randSleep += interval } randSleep -= sleepOffset // check if `ts` after randSleep is before `offset`, // if it is, add extra eval_offset to randSleep. // see https://github.com/VictoriaMetrics/VictoriaMetrics/issues/3409. if offset != nil { tmpEvalTS := ts.Add(randSleep) if tmpEvalTS.Before(tmpEvalTS.Truncate(interval).Add(*offset)) { randSleep += *offset } } return randSleep.Truncate(time.Second) } func (g *Group) infof(format string, args ...interface{}) { msg := fmt.Sprintf(format, args...) logger.Infof("group %q %s; interval=%v; eval_offset=%v; concurrency=%d", g.Name, msg, g.Interval, g.EvalOffset, g.Concurrency) } // getResolveDuration returns the duration after which firing alert // can be considered as resolved. func getResolveDuration(groupInterval, delta, maxDuration time.Duration) time.Duration { if groupInterval > delta { delta = groupInterval } resolveDuration := delta * 4 if maxDuration > 0 && resolveDuration > maxDuration { resolveDuration = maxDuration } return resolveDuration } type executor struct { notifiers func() []notifier.Notifier notifierHeaders map[string]string rw *remotewrite.Client previouslySentSeriesToRWMu sync.Mutex // previouslySentSeriesToRW stores series sent to RW on previous iteration // map[ruleID]map[ruleLabels][]prompb.Label // where `ruleID` is ID of the Rule within a Group // and `ruleLabels` is []prompb.Label marshalled to a string previouslySentSeriesToRW map[uint64]map[string][]prompbmarshal.Label } func (e *executor) execConcurrently(ctx context.Context, rules []Rule, ts time.Time, concurrency int, resolveDuration time.Duration, limit int) chan error { res := make(chan error, len(rules)) if concurrency == 1 { // fast path for _, rule := range rules { res <- e.exec(ctx, rule, ts, resolveDuration, limit) } close(res) return res } sem := make(chan struct{}, concurrency) go func() { wg := sync.WaitGroup{} for _, rule := range rules { sem <- struct{}{} wg.Add(1) go func(r Rule) { res <- e.exec(ctx, r, ts, resolveDuration, limit) <-sem wg.Done() }(rule) } wg.Wait() close(res) }() return res } var ( alertsFired = metrics.NewCounter(`vmalert_alerts_fired_total`) execTotal = metrics.NewCounter(`vmalert_execution_total`) execErrors = metrics.NewCounter(`vmalert_execution_errors_total`) remoteWriteErrors = metrics.NewCounter(`vmalert_remotewrite_errors_total`) remoteWriteTotal = metrics.NewCounter(`vmalert_remotewrite_total`) ) func (e *executor) exec(ctx context.Context, rule Rule, ts time.Time, resolveDuration time.Duration, limit int) error { execTotal.Inc() tss, err := rule.Exec(ctx, ts, limit) if err != nil { if errors.Is(err, context.Canceled) { // the context can be cancelled on graceful shutdown // or on group update. So no need to handle the error as usual. return nil } execErrors.Inc() return fmt.Errorf("rule %q: failed to execute: %w", rule, err) } if e.rw != nil { pushToRW := func(tss []prompbmarshal.TimeSeries) error { var lastErr error for _, ts := range tss { remoteWriteTotal.Inc() if err := e.rw.Push(ts); err != nil { remoteWriteErrors.Inc() lastErr = fmt.Errorf("rule %q: remote write failure: %w", rule, err) } } return lastErr } if err := pushToRW(tss); err != nil { return err } staleSeries := e.getStaleSeries(rule, tss, ts) if err := pushToRW(staleSeries); err != nil { return err } } ar, ok := rule.(*AlertingRule) if !ok { return nil } alerts := ar.alertsToSend(ts, resolveDuration, *resendDelay) if len(alerts) < 1 { return nil } wg := sync.WaitGroup{} errGr := new(utils.ErrGroup) for _, nt := range e.notifiers() { wg.Add(1) go func(nt notifier.Notifier) { if err := nt.Send(ctx, alerts, e.notifierHeaders); err != nil { errGr.Add(fmt.Errorf("rule %q: failed to send alerts to addr %q: %w", rule, nt.Addr(), err)) } wg.Done() }(nt) } wg.Wait() return errGr.Err() } // getStaledSeries checks whether there are stale series from previously sent ones. func (e *executor) getStaleSeries(rule Rule, tss []prompbmarshal.TimeSeries, timestamp time.Time) []prompbmarshal.TimeSeries { ruleLabels := make(map[string][]prompbmarshal.Label, len(tss)) for _, ts := range tss { // convert labels to strings so we can compare with previously sent series key := labelsToString(ts.Labels) ruleLabels[key] = ts.Labels } rID := rule.ID() var staleS []prompbmarshal.TimeSeries // check whether there are series which disappeared and need to be marked as stale e.previouslySentSeriesToRWMu.Lock() for key, labels := range e.previouslySentSeriesToRW[rID] { if _, ok := ruleLabels[key]; ok { continue } // previously sent series are missing in current series, so we mark them as stale ss := newTimeSeriesPB([]float64{decimal.StaleNaN}, []int64{timestamp.Unix()}, labels) staleS = append(staleS, ss) } // set previous series to current e.previouslySentSeriesToRW[rID] = ruleLabels e.previouslySentSeriesToRWMu.Unlock() return staleS } // purgeStaleSeries deletes references in tracked // previouslySentSeriesToRW list to Rules which aren't present // in the given activeRules list. The method is used when the list // of loaded rules has changed and executor has to remove // references to non-existing rules. func (e *executor) purgeStaleSeries(activeRules []Rule) { newPreviouslySentSeriesToRW := make(map[uint64]map[string][]prompbmarshal.Label) e.previouslySentSeriesToRWMu.Lock() for _, rule := range activeRules { id := rule.ID() prev, ok := e.previouslySentSeriesToRW[id] if ok { // keep previous series for staleness detection newPreviouslySentSeriesToRW[id] = prev } } e.previouslySentSeriesToRW = nil e.previouslySentSeriesToRW = newPreviouslySentSeriesToRW e.previouslySentSeriesToRWMu.Unlock() } func labelsToString(labels []prompbmarshal.Label) string { var b strings.Builder b.WriteRune('{') for i, label := range labels { if len(label.Name) == 0 { b.WriteString("__name__") } else { b.WriteString(label.Name) } b.WriteRune('=') b.WriteString(strconv.Quote(label.Value)) if i < len(labels)-1 { b.WriteRune(',') } } b.WriteRune('}') return b.String() }