package streamaggr import ( "slices" "sync" "time" "github.com/VictoriaMetrics/VictoriaMetrics/lib/bytesutil" "github.com/VictoriaMetrics/VictoriaMetrics/lib/logger" "github.com/VictoriaMetrics/VictoriaMetrics/lib/prompbmarshal" "github.com/VictoriaMetrics/VictoriaMetrics/lib/promutils" "github.com/VictoriaMetrics/metrics" ) // Deduplicator deduplicates samples per each time series. type Deduplicator struct { da *dedupAggr dropLabels []string wg sync.WaitGroup stopCh chan struct{} ms *metrics.Set dedupFlushDuration *metrics.Histogram dedupFlushTimeouts *metrics.Counter } // NewDeduplicator returns new deduplicator, which deduplicates samples per each time series. // // The de-duplicated samples are passed to pushFunc once per dedupInterval. // // An optional dropLabels list may contain label names, which must be dropped before de-duplicating samples. // Common case is to drop `replica`-like labels from samples received from HA datasources. // // MustStop must be called on the returned deduplicator in order to free up occupied resources. func NewDeduplicator(pushFunc PushFunc, dedupInterval time.Duration, dropLabels []string) *Deduplicator { d := &Deduplicator{ da: newDedupAggr(), dropLabels: dropLabels, stopCh: make(chan struct{}), ms: metrics.NewSet(), } ms := d.ms _ = ms.NewGauge(`vm_streamaggr_dedup_state_size_bytes`, func() float64 { return float64(d.da.sizeBytes()) }) _ = ms.NewGauge(`vm_streamaggr_dedup_state_items_count`, func() float64 { return float64(d.da.itemsCount()) }) d.dedupFlushDuration = ms.GetOrCreateHistogram(`vm_streamaggr_dedup_flush_duration_seconds`) d.dedupFlushTimeouts = ms.GetOrCreateCounter(`vm_streamaggr_dedup_flush_timeouts_total`) metrics.RegisterSet(ms) d.wg.Add(1) go func() { defer d.wg.Done() d.runFlusher(pushFunc, dedupInterval) }() return d } // MustStop stops d. func (d *Deduplicator) MustStop() { metrics.UnregisterSet(d.ms) d.ms = nil close(d.stopCh) d.wg.Wait() } // Push pushes tss to d. func (d *Deduplicator) Push(tss []prompbmarshal.TimeSeries) { ctx := getDeduplicatorPushCtx() pss := ctx.pss labels := &ctx.labels buf := ctx.buf dropLabels := d.dropLabels for _, ts := range tss { if len(dropLabels) > 0 { labels.Labels = dropSeriesLabels(labels.Labels[:0], ts.Labels, dropLabels) } else { labels.Labels = append(labels.Labels[:0], ts.Labels...) } if len(labels.Labels) == 0 { continue } labels.Sort() bufLen := len(buf) buf = lc.Compress(buf, labels.Labels) key := bytesutil.ToUnsafeString(buf[bufLen:]) for _, s := range ts.Samples { pss = append(pss, pushSample{ key: key, value: s.Value, timestamp: s.Timestamp, }) } } d.da.pushSamples(pss) ctx.pss = pss ctx.buf = buf putDeduplicatorPushCtx(ctx) } func dropSeriesLabels(dst, src []prompbmarshal.Label, labelNames []string) []prompbmarshal.Label { for _, label := range src { if !slices.Contains(labelNames, label.Name) { dst = append(dst, label) } } return dst } func (d *Deduplicator) runFlusher(pushFunc PushFunc, dedupInterval time.Duration) { t := time.NewTicker(dedupInterval) defer t.Stop() for { select { case <-d.stopCh: return case <-t.C: d.flush(pushFunc, dedupInterval) } } } func (d *Deduplicator) flush(pushFunc PushFunc, dedupInterval time.Duration) { startTime := time.Now() timestamp := startTime.UnixMilli() d.da.flush(func(pss []pushSample) { ctx := getDeduplicatorFlushCtx() tss := ctx.tss labels := ctx.labels samples := ctx.samples for _, ps := range pss { labelsLen := len(labels) labels = decompressLabels(labels, ps.key) samplesLen := len(samples) samples = append(samples, prompbmarshal.Sample{ Value: ps.value, Timestamp: timestamp, }) tss = append(tss, prompbmarshal.TimeSeries{ Labels: labels[labelsLen:], Samples: samples[samplesLen:], }) } pushFunc(tss) ctx.tss = tss ctx.labels = labels ctx.samples = samples putDeduplicatorFlushCtx(ctx) }, true) duration := time.Since(startTime) d.dedupFlushDuration.Update(duration.Seconds()) if duration > dedupInterval { d.dedupFlushTimeouts.Inc() logger.Warnf("deduplication couldn't be finished in the configured dedupInterval=%s; it took %.03fs; "+ "possible solutions: increase dedupInterval; reduce samples' ingestion rate", dedupInterval, duration.Seconds()) } } type deduplicatorPushCtx struct { pss []pushSample labels promutils.Labels buf []byte } func (ctx *deduplicatorPushCtx) reset() { clear(ctx.pss) ctx.pss = ctx.pss[:0] ctx.labels.Reset() ctx.buf = ctx.buf[:0] } func getDeduplicatorPushCtx() *deduplicatorPushCtx { v := deduplicatorPushCtxPool.Get() if v == nil { return &deduplicatorPushCtx{} } return v.(*deduplicatorPushCtx) } func putDeduplicatorPushCtx(ctx *deduplicatorPushCtx) { ctx.reset() deduplicatorPushCtxPool.Put(ctx) } var deduplicatorPushCtxPool sync.Pool type deduplicatorFlushCtx struct { tss []prompbmarshal.TimeSeries labels []prompbmarshal.Label samples []prompbmarshal.Sample } func (ctx *deduplicatorFlushCtx) reset() { clear(ctx.tss) ctx.tss = ctx.tss[:0] clear(ctx.labels) ctx.labels = ctx.labels[:0] clear(ctx.samples) ctx.samples = ctx.samples[:0] } func getDeduplicatorFlushCtx() *deduplicatorFlushCtx { v := deduplicatorFlushCtxPool.Get() if v == nil { return &deduplicatorFlushCtx{} } return v.(*deduplicatorFlushCtx) } func putDeduplicatorFlushCtx(ctx *deduplicatorFlushCtx) { ctx.reset() deduplicatorFlushCtxPool.Put(ctx) } var deduplicatorFlushCtxPool sync.Pool