package netstorage import ( "container/heap" "errors" "flag" "fmt" "io" "net" "net/http" "regexp" "sort" "strings" "sync" "sync/atomic" "time" "github.com/VictoriaMetrics/VictoriaMetrics/app/vmselect/searchutils" "github.com/VictoriaMetrics/VictoriaMetrics/lib/bytesutil" "github.com/VictoriaMetrics/VictoriaMetrics/lib/cgroup" "github.com/VictoriaMetrics/VictoriaMetrics/lib/encoding" "github.com/VictoriaMetrics/VictoriaMetrics/lib/fasttime" "github.com/VictoriaMetrics/VictoriaMetrics/lib/handshake" "github.com/VictoriaMetrics/VictoriaMetrics/lib/httpserver" "github.com/VictoriaMetrics/VictoriaMetrics/lib/logger" "github.com/VictoriaMetrics/VictoriaMetrics/lib/netutil" "github.com/VictoriaMetrics/VictoriaMetrics/lib/querytracer" "github.com/VictoriaMetrics/VictoriaMetrics/lib/storage" "github.com/VictoriaMetrics/VictoriaMetrics/lib/syncwg" "github.com/VictoriaMetrics/metrics" "github.com/cespare/xxhash/v2" "github.com/valyala/fastrand" ) var ( replicationFactor = flag.Int("replicationFactor", 1, "How many copies of every time series is available on vmstorage nodes. "+ "See -replicationFactor command-line flag for vminsert nodes") maxSamplesPerSeries = flag.Int("search.maxSamplesPerSeries", 30e6, "The maximum number of raw samples a single query can scan per each time series. See also -search.maxSamplesPerQuery") maxSamplesPerQuery = flag.Int("search.maxSamplesPerQuery", 1e9, "The maximum number of raw samples a single query can process across all time series. This protects from heavy queries, which select unexpectedly high number of raw samples. See also -search.maxSamplesPerSeries") vmstorageDialTimeout = flag.Duration("vmstorageDialTimeout", 5*time.Second, "Timeout for establishing RPC connections from vmselect to vmstorage") ) // Result is a single timeseries result. // // ProcessSearchQuery returns Result slice. type Result struct { // The name of the metric. MetricName storage.MetricName // Values are sorted by Timestamps. Values []float64 Timestamps []int64 } func (r *Result) reset() { r.MetricName.Reset() r.Values = r.Values[:0] r.Timestamps = r.Timestamps[:0] } // Results holds results returned from ProcessSearchQuery. type Results struct { tr storage.TimeRange deadline searchutils.Deadline tbf *tmpBlocksFile packedTimeseries []packedTimeseries } // Len returns the number of results in rss. func (rss *Results) Len() int { return len(rss.packedTimeseries) } // Cancel cancels rss work. func (rss *Results) Cancel() { putTmpBlocksFile(rss.tbf) rss.tbf = nil } type timeseriesWork struct { mustStop *uint32 rss *Results pts *packedTimeseries f func(rs *Result, workerID uint) error doneCh chan error rowsProcessed int } func (tsw *timeseriesWork) reset() { tsw.mustStop = nil tsw.rss = nil tsw.pts = nil tsw.f = nil if n := len(tsw.doneCh); n > 0 { logger.Panicf("BUG: tsw.doneCh must be empty during reset; it contains %d items instead", n) } tsw.rowsProcessed = 0 } func getTimeseriesWork() *timeseriesWork { v := tswPool.Get() if v == nil { v = ×eriesWork{ doneCh: make(chan error, 1), } } return v.(*timeseriesWork) } func putTimeseriesWork(tsw *timeseriesWork) { tsw.reset() tswPool.Put(tsw) } var tswPool sync.Pool func scheduleTimeseriesWork(workChs []chan *timeseriesWork, tsw *timeseriesWork) { if len(workChs) == 1 { // Fast path for a single worker workChs[0] <- tsw return } attempts := 0 for { idx := fastrand.Uint32n(uint32(len(workChs))) select { case workChs[idx] <- tsw: return default: attempts++ if attempts >= len(workChs) { workChs[idx] <- tsw return } } } } func (tsw *timeseriesWork) do(r *Result, workerID uint) error { if atomic.LoadUint32(tsw.mustStop) != 0 { return nil } rss := tsw.rss if rss.deadline.Exceeded() { atomic.StoreUint32(tsw.mustStop, 1) return fmt.Errorf("timeout exceeded during query execution: %s", rss.deadline.String()) } if err := tsw.pts.Unpack(r, rss.tbf, rss.tr); err != nil { atomic.StoreUint32(tsw.mustStop, 1) return fmt.Errorf("error during time series unpacking: %w", err) } if len(r.Timestamps) > 0 { if err := tsw.f(r, workerID); err != nil { atomic.StoreUint32(tsw.mustStop, 1) return err } } tsw.rowsProcessed = len(r.Values) return nil } func timeseriesWorker(ch <-chan *timeseriesWork, workerID uint) { v := resultPool.Get() if v == nil { v = &result{} } r := v.(*result) for tsw := range ch { err := tsw.do(&r.rs, workerID) tsw.doneCh <- err } currentTime := fasttime.UnixTimestamp() if cap(r.rs.Values) > 1024*1024 && 4*len(r.rs.Values) < cap(r.rs.Values) && currentTime-r.lastResetTime > 10 { // Reset r.rs in order to preseve memory usage after processing big time series with millions of rows. r.rs = Result{} r.lastResetTime = currentTime } resultPool.Put(r) } type result struct { rs Result lastResetTime uint64 } var resultPool sync.Pool // RunParallel runs f in parallel for all the results from rss. // // f shouldn't hold references to rs after returning. // workerID is the id of the worker goroutine that calls f. // Data processing is immediately stopped if f returns non-nil error. // // rss becomes unusable after the call to RunParallel. func (rss *Results) RunParallel(qt *querytracer.Tracer, f func(rs *Result, workerID uint) error) error { qt = qt.NewChild("parallel process of fetched data") defer func() { putTmpBlocksFile(rss.tbf) rss.tbf = nil }() // Spin up local workers. // // Do not use a global workChs with a global pool of workers, since it may lead to a deadlock in the following case: // - RunParallel is called with f, which blocks without forward progress. // - All the workers in the global pool became blocked in f. // - workChs is filled up, so it cannot accept new work items from other RunParallel calls. workers := len(rss.packedTimeseries) if workers > gomaxprocs { workers = gomaxprocs } if workers < 1 { workers = 1 } workChs := make([]chan *timeseriesWork, workers) var workChsWG sync.WaitGroup for i := 0; i < workers; i++ { workChs[i] = make(chan *timeseriesWork, 16) workChsWG.Add(1) go func(workerID int) { defer workChsWG.Done() timeseriesWorker(workChs[workerID], uint(workerID)) }(i) } // Feed workers with work. tsws := make([]*timeseriesWork, len(rss.packedTimeseries)) var mustStop uint32 for i := range rss.packedTimeseries { tsw := getTimeseriesWork() tsw.rss = rss tsw.pts = &rss.packedTimeseries[i] tsw.f = f tsw.mustStop = &mustStop scheduleTimeseriesWork(workChs, tsw) tsws[i] = tsw } seriesProcessedTotal := len(rss.packedTimeseries) rss.packedTimeseries = rss.packedTimeseries[:0] // Wait until work is complete. var firstErr error rowsProcessedTotal := 0 for _, tsw := range tsws { if err := <-tsw.doneCh; err != nil && firstErr == nil { // Return just the first error, since other errors are likely duplicate the first error. firstErr = err } rowsReadPerSeries.Update(float64(tsw.rowsProcessed)) rowsProcessedTotal += tsw.rowsProcessed putTimeseriesWork(tsw) } rowsReadPerQuery.Update(float64(rowsProcessedTotal)) seriesReadPerQuery.Update(float64(seriesProcessedTotal)) // Shut down local workers for _, workCh := range workChs { close(workCh) } workChsWG.Wait() qt.Donef("series=%d, samples=%d", seriesProcessedTotal, rowsProcessedTotal) return firstErr } var ( rowsReadPerSeries = metrics.NewHistogram(`vm_rows_read_per_series`) rowsReadPerQuery = metrics.NewHistogram(`vm_rows_read_per_query`) seriesReadPerQuery = metrics.NewHistogram(`vm_series_read_per_query`) ) var gomaxprocs = cgroup.AvailableCPUs() type packedTimeseries struct { metricName string addrs []tmpBlockAddr } type unpackWorkItem struct { addr tmpBlockAddr tr storage.TimeRange } type unpackWork struct { ws []unpackWorkItem tbf *tmpBlocksFile sbs []*sortBlock doneCh chan error } func (upw *unpackWork) reset() { ws := upw.ws for i := range ws { w := &ws[i] w.addr = tmpBlockAddr{} w.tr = storage.TimeRange{} } upw.ws = upw.ws[:0] upw.tbf = nil sbs := upw.sbs for i := range sbs { sbs[i] = nil } upw.sbs = upw.sbs[:0] if n := len(upw.doneCh); n > 0 { logger.Panicf("BUG: upw.doneCh must be empty; it contains %d items now", n) } } func (upw *unpackWork) unpack(tmpBlock *storage.Block) { for _, w := range upw.ws { sb := getSortBlock() if err := sb.unpackFrom(tmpBlock, upw.tbf, w.addr, w.tr); err != nil { putSortBlock(sb) upw.doneCh <- fmt.Errorf("cannot unpack block: %w", err) return } upw.sbs = append(upw.sbs, sb) } upw.doneCh <- nil } func getUnpackWork() *unpackWork { v := unpackWorkPool.Get() if v != nil { return v.(*unpackWork) } return &unpackWork{ doneCh: make(chan error, 1), } } func putUnpackWork(upw *unpackWork) { upw.reset() unpackWorkPool.Put(upw) } var unpackWorkPool sync.Pool func scheduleUnpackWork(workChs []chan *unpackWork, uw *unpackWork) { if len(workChs) == 1 { // Fast path for a single worker workChs[0] <- uw return } attempts := 0 for { idx := fastrand.Uint32n(uint32(len(workChs))) select { case workChs[idx] <- uw: return default: attempts++ if attempts >= len(workChs) { workChs[idx] <- uw return } } } } func unpackWorker(ch <-chan *unpackWork) { v := tmpBlockPool.Get() if v == nil { v = &storage.Block{} } tmpBlock := v.(*storage.Block) for upw := range ch { upw.unpack(tmpBlock) } tmpBlockPool.Put(v) } var tmpBlockPool sync.Pool // unpackBatchSize is the maximum number of blocks that may be unpacked at once by a single goroutine. // // It is better to load a single goroutine for up to one second on a system with many CPU cores // in order to reduce inter-CPU memory ping-pong. // A single goroutine can unpack up to 40 millions of rows per second, while a single block contains up to 8K rows. // So the batch size should be 40M / 8K = 5K. var unpackBatchSize = 5000 // Unpack unpacks pts to dst. func (pts *packedTimeseries) Unpack(dst *Result, tbf *tmpBlocksFile, tr storage.TimeRange) error { dst.reset() if err := dst.MetricName.Unmarshal(bytesutil.ToUnsafeBytes(pts.metricName)); err != nil { return fmt.Errorf("cannot unmarshal metricName %q: %w", pts.metricName, err) } // Spin up local workers. // Do not use global workers pool, since it increases inter-CPU memory ping-poing, // which reduces the scalability on systems with many CPU cores. addrsLen := len(pts.addrs) workers := addrsLen / unpackBatchSize if workers > gomaxprocs { workers = gomaxprocs } if workers < 1 { workers = 1 } workChs := make([]chan *unpackWork, workers) var workChsWG sync.WaitGroup for i := 0; i < workers; i++ { // Use unbuffered channel on purpose, since there are high chances // that only a single unpackWork is needed to unpack. // The unbuffered channel should reduce inter-CPU ping-pong in this case, // which should improve the performance in a system with many CPU cores. workChs[i] = make(chan *unpackWork) workChsWG.Add(1) go func(workerID int) { defer workChsWG.Done() unpackWorker(workChs[workerID]) }(i) } // Feed workers with work upws := make([]*unpackWork, 0, 1+addrsLen/unpackBatchSize) upw := getUnpackWork() upw.tbf = tbf for _, addr := range pts.addrs { if len(upw.ws) >= unpackBatchSize { scheduleUnpackWork(workChs, upw) upws = append(upws, upw) upw = getUnpackWork() upw.tbf = tbf } upw.ws = append(upw.ws, unpackWorkItem{ addr: addr, tr: tr, }) } scheduleUnpackWork(workChs, upw) upws = append(upws, upw) pts.addrs = pts.addrs[:0] // Wait until work is complete samples := 0 sbs := make([]*sortBlock, 0, addrsLen) var firstErr error for _, upw := range upws { if err := <-upw.doneCh; err != nil && firstErr == nil { // Return the first error only, since other errors are likely the same. firstErr = err } if firstErr == nil { for _, sb := range upw.sbs { samples += len(sb.Timestamps) } if *maxSamplesPerSeries <= 0 || samples < *maxSamplesPerSeries { sbs = append(sbs, upw.sbs...) } else { firstErr = fmt.Errorf("cannot process more than %d samples per series; either increase -search.maxSamplesPerSeries "+ "or reduce time range for the query", *maxSamplesPerSeries) } } if firstErr != nil { for _, sb := range upw.sbs { putSortBlock(sb) } } putUnpackWork(upw) } // Shut down local workers for _, workCh := range workChs { close(workCh) } workChsWG.Wait() if firstErr != nil { return firstErr } dedupInterval := storage.GetDedupInterval() mergeSortBlocks(dst, sbs, dedupInterval) return nil } func getSortBlock() *sortBlock { v := sbPool.Get() if v == nil { return &sortBlock{} } return v.(*sortBlock) } func putSortBlock(sb *sortBlock) { sb.reset() sbPool.Put(sb) } var sbPool sync.Pool var metricRowsSkipped = metrics.NewCounter(`vm_metric_rows_skipped_total{name="vmselect"}`) func mergeSortBlocks(dst *Result, sbh sortBlocksHeap, dedupInterval int64) { // Skip empty sort blocks, since they cannot be passed to heap.Init. src := sbh sbh = sbh[:0] for _, sb := range src { if len(sb.Timestamps) == 0 { putSortBlock(sb) continue } sbh = append(sbh, sb) } if len(sbh) == 0 { return } heap.Init(&sbh) for { top := sbh[0] heap.Pop(&sbh) if len(sbh) == 0 { dst.Timestamps = append(dst.Timestamps, top.Timestamps[top.NextIdx:]...) dst.Values = append(dst.Values, top.Values[top.NextIdx:]...) putSortBlock(top) break } sbNext := sbh[0] tsNext := sbNext.Timestamps[sbNext.NextIdx] idxNext := len(top.Timestamps) if top.Timestamps[idxNext-1] > tsNext { idxNext = top.NextIdx for top.Timestamps[idxNext] <= tsNext { idxNext++ } } dst.Timestamps = append(dst.Timestamps, top.Timestamps[top.NextIdx:idxNext]...) dst.Values = append(dst.Values, top.Values[top.NextIdx:idxNext]...) if idxNext < len(top.Timestamps) { top.NextIdx = idxNext heap.Push(&sbh, top) } else { // Return top to the pool. putSortBlock(top) } } timestamps, values := storage.DeduplicateSamples(dst.Timestamps, dst.Values, dedupInterval) dedups := len(dst.Timestamps) - len(timestamps) dedupsDuringSelect.Add(dedups) dst.Timestamps = timestamps dst.Values = values } var dedupsDuringSelect = metrics.NewCounter(`vm_deduplicated_samples_total{type="select"}`) type sortBlock struct { Timestamps []int64 Values []float64 NextIdx int } func (sb *sortBlock) reset() { sb.Timestamps = sb.Timestamps[:0] sb.Values = sb.Values[:0] sb.NextIdx = 0 } func (sb *sortBlock) unpackFrom(tmpBlock *storage.Block, tbf *tmpBlocksFile, addr tmpBlockAddr, tr storage.TimeRange) error { tmpBlock.Reset() tbf.MustReadBlockAt(tmpBlock, addr) if err := tmpBlock.UnmarshalData(); err != nil { return fmt.Errorf("cannot unmarshal block: %w", err) } sb.Timestamps, sb.Values = tmpBlock.AppendRowsWithTimeRangeFilter(sb.Timestamps[:0], sb.Values[:0], tr) skippedRows := tmpBlock.RowsCount() - len(sb.Timestamps) metricRowsSkipped.Add(skippedRows) return nil } type sortBlocksHeap []*sortBlock func (sbh sortBlocksHeap) Len() int { return len(sbh) } func (sbh sortBlocksHeap) Less(i, j int) bool { a := sbh[i] b := sbh[j] return a.Timestamps[a.NextIdx] < b.Timestamps[b.NextIdx] } func (sbh sortBlocksHeap) Swap(i, j int) { sbh[i], sbh[j] = sbh[j], sbh[i] } func (sbh *sortBlocksHeap) Push(x interface{}) { *sbh = append(*sbh, x.(*sortBlock)) } func (sbh *sortBlocksHeap) Pop() interface{} { a := *sbh v := a[len(a)-1] *sbh = a[:len(a)-1] return v } // RegisterMetricNames registers metric names from mrs in the storage. func RegisterMetricNames(qt *querytracer.Tracer, mrs []storage.MetricRow, deadline searchutils.Deadline) error { qt = qt.NewChild("register metric names") defer qt.Done() // Split mrs among available vmstorage nodes. mrsPerNode := make([][]storage.MetricRow, len(storageNodes)) for _, mr := range mrs { idx := 0 if len(storageNodes) > 1 { // There is no need in using the same hash as for time series distribution in vminsert, // since RegisterMetricNames is used only in Graphite Tags API. h := xxhash.Sum64(mr.MetricNameRaw) idx = int(h % uint64(len(storageNodes))) } mrsPerNode[idx] = append(mrsPerNode[idx], mr) } // Push mrs to storage nodes in parallel. snr := startStorageNodesRequest(qt, true, func(qt *querytracer.Tracer, idx int, sn *storageNode) interface{} { sn.registerMetricNamesRequests.Inc() err := sn.registerMetricNames(qt, mrsPerNode[idx], deadline) if err != nil { sn.registerMetricNamesErrors.Inc() } return &err }) // Collect results err := snr.collectAllResults(func(result interface{}) error { errP := result.(*error) return *errP }) if err != nil { return fmt.Errorf("cannot register series on all the vmstorage nodes: %w", err) } return nil } // DeleteSeries deletes time series matching the given sq. func DeleteSeries(qt *querytracer.Tracer, sq *storage.SearchQuery, deadline searchutils.Deadline) (int, error) { qt = qt.NewChild("delete series: %s", sq) defer qt.Done() requestData := sq.Marshal(nil) // Send the query to all the storage nodes in parallel. type nodeResult struct { deletedCount int err error } snr := startStorageNodesRequest(qt, true, func(qt *querytracer.Tracer, idx int, sn *storageNode) interface{} { sn.deleteSeriesRequests.Inc() deletedCount, err := sn.deleteSeries(qt, requestData, deadline) if err != nil { sn.deleteSeriesErrors.Inc() } return &nodeResult{ deletedCount: deletedCount, err: err, } }) // Collect results deletedTotal := 0 err := snr.collectAllResults(func(result interface{}) error { nr := result.(*nodeResult) if nr.err != nil { return nr.err } deletedTotal += nr.deletedCount return nil }) if err != nil { return deletedTotal, fmt.Errorf("cannot delete time series on all the vmstorage nodes: %w", err) } return deletedTotal, nil } // LabelNames returns label names matching the given sq until the given deadline. func LabelNames(qt *querytracer.Tracer, denyPartialResponse bool, sq *storage.SearchQuery, maxLabelNames int, deadline searchutils.Deadline) ([]string, bool, error) { qt = qt.NewChild("get labels: %s", sq) defer qt.Done() if deadline.Exceeded() { return nil, false, fmt.Errorf("timeout exceeded before starting the query processing: %s", deadline.String()) } requestData := sq.Marshal(nil) // Send the query to all the storage nodes in parallel. type nodeResult struct { labelNames []string err error } snr := startStorageNodesRequest(qt, denyPartialResponse, func(qt *querytracer.Tracer, idx int, sn *storageNode) interface{} { sn.labelNamesRequests.Inc() labelNames, err := sn.getLabelNames(qt, requestData, maxLabelNames, deadline) if err != nil { sn.labelNamesErrors.Inc() err = fmt.Errorf("cannot get labels from vmstorage %s: %w", sn.connPool.Addr(), err) } return &nodeResult{ labelNames: labelNames, err: err, } }) // Collect results var labelNames []string isPartial, err := snr.collectResults(partialLabelNamesResults, func(result interface{}) error { nr := result.(*nodeResult) if nr.err != nil { return nr.err } labelNames = append(labelNames, nr.labelNames...) return nil }) qt.Printf("get %d non-duplicated labels", len(labelNames)) if err != nil { return nil, isPartial, fmt.Errorf("cannot fetch labels from vmstorage nodes: %w", err) } // Deduplicate labels labelNames = deduplicateStrings(labelNames) qt.Printf("get %d unique labels after de-duplication", len(labelNames)) if maxLabelNames > 0 && maxLabelNames < len(labelNames) { labelNames = labelNames[:maxLabelNames] } // Sort labelNames like Prometheus does sort.Strings(labelNames) qt.Printf("sort %d labels", len(labelNames)) return labelNames, isPartial, nil } // GraphiteTags returns Graphite tags until the given deadline. func GraphiteTags(qt *querytracer.Tracer, accountID, projectID uint32, denyPartialResponse bool, filter string, limit int, deadline searchutils.Deadline) ([]string, bool, error) { qt = qt.NewChild("get graphite tags: filter=%s, limit=%d", filter, limit) defer qt.Done() if deadline.Exceeded() { return nil, false, fmt.Errorf("timeout exceeded before starting the query processing: %s", deadline.String()) } sq := storage.NewSearchQuery(accountID, projectID, 0, 0, nil, 0) labels, isPartial, err := LabelNames(qt, denyPartialResponse, sq, 0, deadline) if err != nil { return nil, false, err } // Substitute "__name__" with "name" for Graphite compatibility for i := range labels { if labels[i] != "__name__" { continue } // Prevent from duplicate `name` tag. // See https://github.com/VictoriaMetrics/VictoriaMetrics/issues/942 if hasString(labels, "name") { labels = append(labels[:i], labels[i+1:]...) } else { labels[i] = "name" sort.Strings(labels) } break } if len(filter) > 0 { labels, err = applyGraphiteRegexpFilter(filter, labels) if err != nil { return nil, false, err } } if limit > 0 && limit < len(labels) { labels = labels[:limit] } return labels, isPartial, nil } func hasString(a []string, s string) bool { for _, x := range a { if x == s { return true } } return false } // LabelValues returns label values matching the given labelName and sq until the given deadline. func LabelValues(qt *querytracer.Tracer, denyPartialResponse bool, labelName string, sq *storage.SearchQuery, maxLabelValues int, deadline searchutils.Deadline) ([]string, bool, error) { qt = qt.NewChild("get values for label %s: %s", labelName, sq) defer qt.Done() if deadline.Exceeded() { return nil, false, fmt.Errorf("timeout exceeded before starting the query processing: %s", deadline.String()) } requestData := sq.Marshal(nil) // Send the query to all the storage nodes in parallel. type nodeResult struct { labelValues []string err error } snr := startStorageNodesRequest(qt, denyPartialResponse, func(qt *querytracer.Tracer, idx int, sn *storageNode) interface{} { sn.labelValuesRequests.Inc() labelValues, err := sn.getLabelValues(qt, labelName, requestData, maxLabelValues, deadline) if err != nil { sn.labelValuesErrors.Inc() err = fmt.Errorf("cannot get label values from vmstorage %s: %w", sn.connPool.Addr(), err) } return &nodeResult{ labelValues: labelValues, err: err, } }) // Collect results var labelValues []string isPartial, err := snr.collectResults(partialLabelValuesResults, func(result interface{}) error { nr := result.(*nodeResult) if nr.err != nil { return nr.err } labelValues = append(labelValues, nr.labelValues...) return nil }) qt.Printf("get %d non-duplicated label values", len(labelValues)) if err != nil { return nil, isPartial, fmt.Errorf("cannot fetch label values from vmstorage nodes: %w", err) } // Deduplicate label values labelValues = deduplicateStrings(labelValues) qt.Printf("get %d unique label values after de-duplication", len(labelValues)) // Sort labelValues like Prometheus does if maxLabelValues > 0 && maxLabelValues < len(labelValues) { labelValues = labelValues[:maxLabelValues] } sort.Strings(labelValues) qt.Printf("sort %d label values", len(labelValues)) return labelValues, isPartial, nil } // GraphiteTagValues returns tag values for the given tagName until the given deadline. func GraphiteTagValues(qt *querytracer.Tracer, accountID, projectID uint32, denyPartialResponse bool, tagName, filter string, limit int, deadline searchutils.Deadline) ([]string, bool, error) { qt = qt.NewChild("get graphite tag values for tagName=%s, filter=%s, limit=%d", tagName, filter, limit) defer qt.Done() if deadline.Exceeded() { return nil, false, fmt.Errorf("timeout exceeded before starting the query processing: %s", deadline.String()) } if tagName == "name" { tagName = "" } sq := storage.NewSearchQuery(accountID, projectID, 0, 0, nil, 0) tagValues, isPartial, err := LabelValues(qt, denyPartialResponse, tagName, sq, 0, deadline) if err != nil { return nil, false, err } if len(filter) > 0 { tagValues, err = applyGraphiteRegexpFilter(filter, tagValues) if err != nil { return nil, false, err } } if limit > 0 && limit < len(tagValues) { tagValues = tagValues[:limit] } return tagValues, isPartial, nil } // TagValueSuffixes returns tag value suffixes for the given tagKey and the given tagValuePrefix. // // It can be used for implementing https://graphite-api.readthedocs.io/en/latest/api.html#metrics-find func TagValueSuffixes(qt *querytracer.Tracer, accountID, projectID uint32, denyPartialResponse bool, tr storage.TimeRange, tagKey, tagValuePrefix string, delimiter byte, maxSuffixes int, deadline searchutils.Deadline) ([]string, bool, error) { qt = qt.NewChild("get tag value suffixes for tagKey=%s, tagValuePrefix=%s, maxSuffixes=%d, timeRange=%s", tagKey, tagValuePrefix, maxSuffixes, &tr) defer qt.Done() if deadline.Exceeded() { return nil, false, fmt.Errorf("timeout exceeded before starting the query processing: %s", deadline.String()) } // Send the query to all the storage nodes in parallel. type nodeResult struct { suffixes []string err error } snr := startStorageNodesRequest(qt, denyPartialResponse, func(qt *querytracer.Tracer, idx int, sn *storageNode) interface{} { sn.tagValueSuffixesRequests.Inc() suffixes, err := sn.getTagValueSuffixes(qt, accountID, projectID, tr, tagKey, tagValuePrefix, delimiter, maxSuffixes, deadline) if err != nil { sn.tagValueSuffixesErrors.Inc() err = fmt.Errorf("cannot get tag value suffixes for tr=%s, tagKey=%q, tagValuePrefix=%q, delimiter=%c from vmstorage %s: %w", tr.String(), tagKey, tagValuePrefix, delimiter, sn.connPool.Addr(), err) } return &nodeResult{ suffixes: suffixes, err: err, } }) // Collect results m := make(map[string]struct{}) isPartial, err := snr.collectResults(partialTagValueSuffixesResults, func(result interface{}) error { nr := result.(*nodeResult) if nr.err != nil { return nr.err } for _, suffix := range nr.suffixes { m[suffix] = struct{}{} } return nil }) if err != nil { return nil, isPartial, fmt.Errorf("cannot fetch tag value suffixes from vmstorage nodes: %w", err) } suffixes := make([]string, 0, len(m)) for suffix := range m { suffixes = append(suffixes, suffix) } return suffixes, isPartial, nil } func deduplicateStrings(a []string) []string { m := make(map[string]bool, len(a)) for _, s := range a { m[s] = true } a = a[:0] for s := range m { a = append(a, s) } return a } // TSDBStatus returns tsdb status according to https://prometheus.io/docs/prometheus/latest/querying/api/#tsdb-stats // // It accepts aribtrary filters on time series in sq. func TSDBStatus(qt *querytracer.Tracer, denyPartialResponse bool, sq *storage.SearchQuery, focusLabel string, topN int, deadline searchutils.Deadline) (*storage.TSDBStatus, bool, error) { qt = qt.NewChild("get tsdb stats: %s, focusLabel=%q, topN=%d", sq, focusLabel, topN) defer qt.Done() if deadline.Exceeded() { return nil, false, fmt.Errorf("timeout exceeded before starting the query processing: %s", deadline.String()) } requestData := sq.Marshal(nil) // Send the query to all the storage nodes in parallel. type nodeResult struct { status *storage.TSDBStatus err error } snr := startStorageNodesRequest(qt, denyPartialResponse, func(qt *querytracer.Tracer, idx int, sn *storageNode) interface{} { sn.tsdbStatusRequests.Inc() status, err := sn.getTSDBStatus(qt, requestData, focusLabel, topN, deadline) if err != nil { sn.tsdbStatusErrors.Inc() err = fmt.Errorf("cannot obtain tsdb status from vmstorage %s: %w", sn.connPool.Addr(), err) } return &nodeResult{ status: status, err: err, } }) // Collect results. var statuses []*storage.TSDBStatus isPartial, err := snr.collectResults(partialTSDBStatusResults, func(result interface{}) error { nr := result.(*nodeResult) if nr.err != nil { return nr.err } statuses = append(statuses, nr.status) return nil }) if err != nil { return nil, isPartial, fmt.Errorf("cannot fetch tsdb status from vmstorage nodes: %w", err) } status := mergeTSDBStatuses(statuses, topN) return status, isPartial, nil } func mergeTSDBStatuses(statuses []*storage.TSDBStatus, topN int) *storage.TSDBStatus { totalSeries := uint64(0) totalLabelValuePairs := uint64(0) seriesCountByMetricName := make(map[string]uint64) seriesCountByLabelName := make(map[string]uint64) seriesCountByFocusLabelValue := make(map[string]uint64) seriesCountByLabelValuePair := make(map[string]uint64) labelValueCountByLabelName := make(map[string]uint64) for _, st := range statuses { totalSeries += st.TotalSeries totalLabelValuePairs += st.TotalLabelValuePairs for _, e := range st.SeriesCountByMetricName { seriesCountByMetricName[e.Name] += e.Count } for _, e := range st.SeriesCountByLabelName { seriesCountByLabelName[e.Name] += e.Count } for _, e := range st.SeriesCountByFocusLabelValue { seriesCountByFocusLabelValue[e.Name] += e.Count } for _, e := range st.SeriesCountByLabelValuePair { seriesCountByLabelValuePair[e.Name] += e.Count } for _, e := range st.LabelValueCountByLabelName { // The same label values may exist in multiple vmstorage nodes. // So select the maximum label values count in order to get the value close to reality. if e.Count > labelValueCountByLabelName[e.Name] { labelValueCountByLabelName[e.Name] = e.Count } } } return &storage.TSDBStatus{ TotalSeries: totalSeries, TotalLabelValuePairs: totalLabelValuePairs, SeriesCountByMetricName: toTopHeapEntries(seriesCountByMetricName, topN), SeriesCountByLabelName: toTopHeapEntries(seriesCountByLabelName, topN), SeriesCountByFocusLabelValue: toTopHeapEntries(seriesCountByFocusLabelValue, topN), SeriesCountByLabelValuePair: toTopHeapEntries(seriesCountByLabelValuePair, topN), LabelValueCountByLabelName: toTopHeapEntries(labelValueCountByLabelName, topN), } } func toTopHeapEntries(m map[string]uint64, topN int) []storage.TopHeapEntry { a := make([]storage.TopHeapEntry, 0, len(m)) for name, count := range m { a = append(a, storage.TopHeapEntry{ Name: name, Count: count, }) } sort.Slice(a, func(i, j int) bool { if a[i].Count != a[j].Count { return a[i].Count > a[j].Count } return a[i].Name < a[j].Name }) if len(a) > topN { a = a[:topN] } return a } // SeriesCount returns the number of unique series. func SeriesCount(qt *querytracer.Tracer, accountID, projectID uint32, denyPartialResponse bool, deadline searchutils.Deadline) (uint64, bool, error) { qt = qt.NewChild("get series count") defer qt.Done() if deadline.Exceeded() { return 0, false, fmt.Errorf("timeout exceeded before starting the query processing: %s", deadline.String()) } // Send the query to all the storage nodes in parallel. type nodeResult struct { n uint64 err error } snr := startStorageNodesRequest(qt, denyPartialResponse, func(qt *querytracer.Tracer, idx int, sn *storageNode) interface{} { sn.seriesCountRequests.Inc() n, err := sn.getSeriesCount(qt, accountID, projectID, deadline) if err != nil { sn.seriesCountErrors.Inc() err = fmt.Errorf("cannot get series count from vmstorage %s: %w", sn.connPool.Addr(), err) } return &nodeResult{ n: n, err: err, } }) // Collect results var n uint64 isPartial, err := snr.collectResults(partialSeriesCountResults, func(result interface{}) error { nr := result.(*nodeResult) if nr.err != nil { return nr.err } n += nr.n return nil }) if err != nil { return 0, isPartial, fmt.Errorf("cannot fetch series count from vmstorage nodes: %w", err) } return n, isPartial, nil } type tmpBlocksFileWrapper struct { mu sync.Mutex tbf *tmpBlocksFile m map[string][]tmpBlockAddr orderedMetricNames []string } func (tbfw *tmpBlocksFileWrapper) RegisterEmptyBlock(mb *storage.MetricBlock) { metricName := mb.MetricName tbfw.mu.Lock() if addrs := tbfw.m[string(metricName)]; addrs == nil { // An optimization for big number of time series with long names: store only a single copy of metricNameStr // in both tbfw.orderedMetricNames and tbfw.m. tbfw.orderedMetricNames = append(tbfw.orderedMetricNames, string(metricName)) tbfw.m[tbfw.orderedMetricNames[len(tbfw.orderedMetricNames)-1]] = []tmpBlockAddr{{}} } tbfw.mu.Unlock() } func (tbfw *tmpBlocksFileWrapper) RegisterAndWriteBlock(mb *storage.MetricBlock) error { bb := tmpBufPool.Get() bb.B = storage.MarshalBlock(bb.B[:0], &mb.Block) tbfw.mu.Lock() addr, err := tbfw.tbf.WriteBlockData(bb.B) tmpBufPool.Put(bb) if err == nil { metricName := mb.MetricName addrs := tbfw.m[string(metricName)] addrs = append(addrs, addr) if len(addrs) > 1 { tbfw.m[string(metricName)] = addrs } else { // An optimization for big number of time series with long names: store only a single copy of metricNameStr // in both tbfw.orderedMetricNames and tbfw.m. tbfw.orderedMetricNames = append(tbfw.orderedMetricNames, string(metricName)) tbfw.m[tbfw.orderedMetricNames[len(tbfw.orderedMetricNames)-1]] = addrs } } tbfw.mu.Unlock() return err } var metricNamePool = &sync.Pool{ New: func() interface{} { return &storage.MetricName{} }, } // ExportBlocks searches for time series matching sq and calls f for each found block. // // f is called in parallel from multiple goroutines. // It is the responsibility of f to call b.UnmarshalData before reading timestamps and values from the block. // It is the responsibility of f to filter blocks according to the given tr. func ExportBlocks(qt *querytracer.Tracer, sq *storage.SearchQuery, deadline searchutils.Deadline, f func(mn *storage.MetricName, b *storage.Block, tr storage.TimeRange) error) error { qt = qt.NewChild("export blocks: %s", sq) defer qt.Done() if deadline.Exceeded() { return fmt.Errorf("timeout exceeded before starting data export: %s", deadline.String()) } tr := storage.TimeRange{ MinTimestamp: sq.MinTimestamp, MaxTimestamp: sq.MaxTimestamp, } var wg syncwg.WaitGroup var stopped uint32 var blocksRead uint64 var samples uint64 processBlock := func(mb *storage.MetricBlock) error { wg.Add(1) defer wg.Done() if atomic.LoadUint32(&stopped) != 0 { return nil } mn := metricNamePool.Get().(*storage.MetricName) if err := mn.Unmarshal(mb.MetricName); err != nil { return fmt.Errorf("cannot unmarshal metricName: %w", err) } if err := f(mn, &mb.Block, tr); err != nil { return err } mn.Reset() metricNamePool.Put(mn) atomic.AddUint64(&blocksRead, 1) atomic.AddUint64(&samples, uint64(mb.Block.RowsCount())) return nil } _, err := processSearchQuery(qt, true, sq, processBlock, deadline) // Make sure processBlock isn't called anymore in order to prevent from data races. atomic.StoreUint32(&stopped, 1) wg.Wait() qt.Printf("export blocks=%d, samples=%d", blocksRead, samples) if err != nil { return fmt.Errorf("error occured during export: %w", err) } return nil } // SearchMetricNames returns all the metric names matching sq until the given deadline. // // The returned metric names must be unmarshaled via storage.MetricName.UnmarshalString(). func SearchMetricNames(qt *querytracer.Tracer, denyPartialResponse bool, sq *storage.SearchQuery, deadline searchutils.Deadline) ([]string, bool, error) { qt = qt.NewChild("fetch metric names: %s", sq) defer qt.Done() if deadline.Exceeded() { return nil, false, fmt.Errorf("timeout exceeded before starting to search metric names: %s", deadline.String()) } requestData := sq.Marshal(nil) // Send the query to all the storage nodes in parallel. type nodeResult struct { metricNames []string err error } snr := startStorageNodesRequest(qt, denyPartialResponse, func(qt *querytracer.Tracer, idx int, sn *storageNode) interface{} { sn.searchMetricNamesRequests.Inc() metricNames, err := sn.processSearchMetricNames(qt, requestData, deadline) if err != nil { sn.searchMetricNamesErrors.Inc() err = fmt.Errorf("cannot search metric names on vmstorage %s: %w", sn.connPool.Addr(), err) } return &nodeResult{ metricNames: metricNames, err: err, } }) // Collect results. metricNamesMap := make(map[string]struct{}) isPartial, err := snr.collectResults(partialSearchMetricNamesResults, func(result interface{}) error { nr := result.(*nodeResult) if nr.err != nil { return nr.err } for _, metricName := range nr.metricNames { metricNamesMap[metricName] = struct{}{} } return nil }) if err != nil { return nil, isPartial, fmt.Errorf("cannot fetch metric names from vmstorage nodes: %w", err) } metricNames := make([]string, len(metricNamesMap)) for metricName := range metricNamesMap { metricNames = append(metricNames, metricName) } sort.Strings(metricNames) qt.Printf("sort %d metric names", len(metricNames)) return metricNames, isPartial, nil } // ProcessSearchQuery performs sq until the given deadline. // // Results.RunParallel or Results.Cancel must be called on the returned Results. func ProcessSearchQuery(qt *querytracer.Tracer, denyPartialResponse bool, sq *storage.SearchQuery, deadline searchutils.Deadline) (*Results, bool, error) { qt = qt.NewChild("fetch matching series: %s", sq) defer qt.Done() if deadline.Exceeded() { return nil, false, fmt.Errorf("timeout exceeded before starting the query processing: %s", deadline.String()) } // Setup search. tr := storage.TimeRange{ MinTimestamp: sq.MinTimestamp, MaxTimestamp: sq.MaxTimestamp, } tbfw := &tmpBlocksFileWrapper{ tbf: getTmpBlocksFile(), m: make(map[string][]tmpBlockAddr), } var wg syncwg.WaitGroup var stopped uint32 var blocksRead uint64 var samples uint64 processBlock := func(mb *storage.MetricBlock) error { wg.Add(1) defer wg.Done() if atomic.LoadUint32(&stopped) != 0 { return nil } atomic.AddUint64(&blocksRead, 1) n := atomic.AddUint64(&samples, uint64(mb.Block.RowsCount())) if *maxSamplesPerQuery > 0 && n > uint64(*maxSamplesPerQuery) { return fmt.Errorf("cannot select more than -search.maxSamplesPerQuery=%d samples; possible solutions: to increase the -search.maxSamplesPerQuery; to reduce time range for the query; to use more specific label filters in order to select lower number of series", *maxSamplesPerQuery) } if err := tbfw.RegisterAndWriteBlock(mb); err != nil { return fmt.Errorf("cannot write MetricBlock to temporary blocks file: %w", err) } return nil } isPartial, err := processSearchQuery(qt, denyPartialResponse, sq, processBlock, deadline) // Make sure processBlock isn't called anymore in order to protect from data races. atomic.StoreUint32(&stopped, 1) wg.Wait() if err != nil { putTmpBlocksFile(tbfw.tbf) return nil, false, fmt.Errorf("error occured during search: %w", err) } if err := tbfw.tbf.Finalize(); err != nil { putTmpBlocksFile(tbfw.tbf) return nil, false, fmt.Errorf("cannot finalize temporary blocks file with %d time series: %w", len(tbfw.m), err) } qt.Printf("fetch unique series=%d, blocks=%d, samples=%d, bytes=%d", len(tbfw.m), blocksRead, samples, tbfw.tbf.Len()) var rss Results rss.tr = tr rss.deadline = deadline rss.tbf = tbfw.tbf pts := make([]packedTimeseries, len(tbfw.orderedMetricNames)) for i, metricName := range tbfw.orderedMetricNames { pts[i] = packedTimeseries{ metricName: metricName, addrs: tbfw.m[metricName], } } rss.packedTimeseries = pts return &rss, isPartial, nil } func processSearchQuery(qt *querytracer.Tracer, denyPartialResponse bool, sq *storage.SearchQuery, processBlock func(mb *storage.MetricBlock) error, deadline searchutils.Deadline) (bool, error) { requestData := sq.Marshal(nil) // Send the query to all the storage nodes in parallel. snr := startStorageNodesRequest(qt, denyPartialResponse, func(qt *querytracer.Tracer, idx int, sn *storageNode) interface{} { sn.searchRequests.Inc() err := sn.processSearchQuery(qt, requestData, processBlock, deadline) if err != nil { sn.searchErrors.Inc() err = fmt.Errorf("cannot perform search on vmstorage %s: %w", sn.connPool.Addr(), err) } return &err }) // Collect results. isPartial, err := snr.collectResults(partialSearchResults, func(result interface{}) error { errP := result.(*error) return *errP }) if err != nil { return isPartial, fmt.Errorf("cannot fetch query results from vmstorage nodes: %w", err) } return isPartial, nil } type storageNodesRequest struct { denyPartialResponse bool resultsCh chan interface{} } func startStorageNodesRequest(qt *querytracer.Tracer, denyPartialResponse bool, f func(qt *querytracer.Tracer, idx int, sn *storageNode) interface{}) *storageNodesRequest { resultsCh := make(chan interface{}, len(storageNodes)) for idx, sn := range storageNodes { qtChild := qt.NewChild("rpc at vmstorage %s", sn.connPool.Addr()) go func(idx int, sn *storageNode) { result := f(qtChild, idx, sn) resultsCh <- result qtChild.Done() }(idx, sn) } return &storageNodesRequest{ denyPartialResponse: denyPartialResponse, resultsCh: resultsCh, } } func (snr *storageNodesRequest) collectAllResults(f func(result interface{}) error) error { for i := 0; i < len(storageNodes); i++ { result := <-snr.resultsCh if err := f(result); err != nil { // Immediately return the error to the caller without waiting for responses from other vmstorage nodes - // they will be processed in brackground. return err } } return nil } func (snr *storageNodesRequest) collectResults(partialResultsCounter *metrics.Counter, f func(result interface{}) error) (bool, error) { var errsPartial []error resultsCollected := 0 for i := 0; i < len(storageNodes); i++ { // There is no need in timer here, since all the goroutines executing the f function // passed to startStorageNodesRequest must be finished until the deadline. result := <-snr.resultsCh if err := f(result); err != nil { var er *errRemote if errors.As(err, &er) { // Immediately return the error reported by vmstorage to the caller, // since such errors usually mean misconfiguration at vmstorage. // The misconfiguration must be known by the caller, so it is fixed ASAP. return false, err } errsPartial = append(errsPartial, err) if snr.denyPartialResponse && len(errsPartial) >= *replicationFactor { // Return the error to the caller if partial responses are denied // and the number of partial responses reach -replicationFactor, // since this means that the response is partial. return false, err } continue } resultsCollected++ if resultsCollected > len(storageNodes)-*replicationFactor { // There is no need in waiting for the remaining results, // because the collected results contain all the data according to the given -replicationFactor. // This should speed up responses when a part of vmstorage nodes are slow and/or temporarily unavailable. // See https://github.com/VictoriaMetrics/VictoriaMetrics/issues/711 // // It is expected that cap(snr.resultsCh) == len(storageNodes), otherwise goroutine leak is possible. return false, nil } } if len(errsPartial) < *replicationFactor { // Assume that the result is full if the the number of failing vmstorage nodes // is smaller than the -replicationFactor. return false, nil } if len(errsPartial) == len(storageNodes) { // All the vmstorage nodes returned error. // Return only the first error, since it has no sense in returning all errors. return false, errsPartial[0] } // Return partial results. // This allows gracefully degrade vmselect in the case // if a part of vmstorage nodes are temporarily unavailable. partialResultsCounter.Inc() // Do not return the error, since it may spam logs on busy vmselect // serving high amounts of requests. partialErrorsLogger.Warnf("%d out of %d vmstorage nodes were unavailable during the query; a sample error: %s", len(errsPartial), len(storageNodes), errsPartial[0]) return true, nil } var partialErrorsLogger = logger.WithThrottler("partialErrors", 10*time.Second) type storageNode struct { connPool *netutil.ConnPool // The number of concurrent queries to storageNode. concurrentQueries *metrics.Counter // The number of RegisterMetricNames requests to storageNode. registerMetricNamesRequests *metrics.Counter // The number of RegisterMetricNames request errors to storageNode. registerMetricNamesErrors *metrics.Counter // The number of DeleteSeries requests to storageNode. deleteSeriesRequests *metrics.Counter // The number of DeleteSeries request errors to storageNode. deleteSeriesErrors *metrics.Counter // The number of requests to labelNames. labelNamesRequests *metrics.Counter // The number of errors during requests to labelNames. labelNamesErrors *metrics.Counter // The number of requests to labelValues. labelValuesRequests *metrics.Counter // The number of errors during requests to labelValuesOnTimeRange. labelValuesErrors *metrics.Counter // The number of requests to tagValueSuffixes. tagValueSuffixesRequests *metrics.Counter // The number of errors during requests to tagValueSuffixes. tagValueSuffixesErrors *metrics.Counter // The number of requests to tsdb status. tsdbStatusRequests *metrics.Counter // The number of errors during requests to tsdb status. tsdbStatusErrors *metrics.Counter // The number of requests to seriesCount. seriesCountRequests *metrics.Counter // The number of errors during requests to seriesCount. seriesCountErrors *metrics.Counter // The number of searchMetricNames requests to storageNode. searchMetricNamesRequests *metrics.Counter // The number of searchMetricNames errors to storageNode. searchMetricNamesErrors *metrics.Counter // The number of search requests to storageNode. searchRequests *metrics.Counter // The number of search request errors to storageNode. searchErrors *metrics.Counter // The number of metric blocks read. metricBlocksRead *metrics.Counter // The number of read metric rows. metricRowsRead *metrics.Counter } func (sn *storageNode) registerMetricNames(qt *querytracer.Tracer, mrs []storage.MetricRow, deadline searchutils.Deadline) error { if len(mrs) == 0 { return nil } f := func(bc *handshake.BufferedConn) error { return sn.registerMetricNamesOnConn(bc, mrs) } return sn.execOnConnWithPossibleRetry(qt, "registerMetricNames_v3", f, deadline) } func (sn *storageNode) deleteSeries(qt *querytracer.Tracer, requestData []byte, deadline searchutils.Deadline) (int, error) { var deletedCount int f := func(bc *handshake.BufferedConn) error { n, err := sn.deleteSeriesOnConn(bc, requestData) if err != nil { return err } deletedCount = n return nil } if err := sn.execOnConnWithPossibleRetry(qt, "deleteSeries_v5", f, deadline); err != nil { return 0, err } return deletedCount, nil } func (sn *storageNode) getLabelNames(qt *querytracer.Tracer, requestData []byte, maxLabelNames int, deadline searchutils.Deadline) ([]string, error) { var labels []string f := func(bc *handshake.BufferedConn) error { ls, err := sn.getLabelNamesOnConn(bc, requestData, maxLabelNames) if err != nil { return err } labels = ls return nil } if err := sn.execOnConnWithPossibleRetry(qt, "labelNames_v5", f, deadline); err != nil { return nil, err } return labels, nil } func (sn *storageNode) getLabelValues(qt *querytracer.Tracer, labelName string, requestData []byte, maxLabelValues int, deadline searchutils.Deadline) ([]string, error) { var labelValues []string f := func(bc *handshake.BufferedConn) error { lvs, err := sn.getLabelValuesOnConn(bc, labelName, requestData, maxLabelValues) if err != nil { return err } labelValues = lvs return nil } if err := sn.execOnConnWithPossibleRetry(qt, "labelValues_v5", f, deadline); err != nil { return nil, err } return labelValues, nil } func (sn *storageNode) getTagValueSuffixes(qt *querytracer.Tracer, accountID, projectID uint32, tr storage.TimeRange, tagKey, tagValuePrefix string, delimiter byte, maxSuffixes int, deadline searchutils.Deadline) ([]string, error) { var suffixes []string f := func(bc *handshake.BufferedConn) error { ss, err := sn.getTagValueSuffixesOnConn(bc, accountID, projectID, tr, tagKey, tagValuePrefix, delimiter, maxSuffixes) if err != nil { return err } suffixes = ss return nil } if err := sn.execOnConnWithPossibleRetry(qt, "tagValueSuffixes_v4", f, deadline); err != nil { return nil, err } return suffixes, nil } func (sn *storageNode) getTSDBStatus(qt *querytracer.Tracer, requestData []byte, focusLabel string, topN int, deadline searchutils.Deadline) (*storage.TSDBStatus, error) { var status *storage.TSDBStatus f := func(bc *handshake.BufferedConn) error { st, err := sn.getTSDBStatusOnConn(bc, requestData, focusLabel, topN) if err != nil { return err } status = st return nil } if err := sn.execOnConnWithPossibleRetry(qt, "tsdbStatus_v5", f, deadline); err != nil { return nil, err } return status, nil } func (sn *storageNode) getSeriesCount(qt *querytracer.Tracer, accountID, projectID uint32, deadline searchutils.Deadline) (uint64, error) { var n uint64 f := func(bc *handshake.BufferedConn) error { nn, err := sn.getSeriesCountOnConn(bc, accountID, projectID) if err != nil { return err } n = nn return nil } if err := sn.execOnConnWithPossibleRetry(qt, "seriesCount_v4", f, deadline); err != nil { return 0, err } return n, nil } func (sn *storageNode) processSearchMetricNames(qt *querytracer.Tracer, requestData []byte, deadline searchutils.Deadline) ([]string, error) { var metricNames []string f := func(bc *handshake.BufferedConn) error { mns, err := sn.processSearchMetricNamesOnConn(bc, requestData) if err != nil { return err } metricNames = mns return nil } if err := sn.execOnConnWithPossibleRetry(qt, "searchMetricNames_v3", f, deadline); err != nil { return nil, err } return metricNames, nil } func (sn *storageNode) processSearchQuery(qt *querytracer.Tracer, requestData []byte, processBlock func(mb *storage.MetricBlock) error, deadline searchutils.Deadline) error { f := func(bc *handshake.BufferedConn) error { if err := sn.processSearchQueryOnConn(bc, requestData, processBlock); err != nil { return err } return nil } return sn.execOnConnWithPossibleRetry(qt, "search_v7", f, deadline) } func (sn *storageNode) execOnConnWithPossibleRetry(qt *querytracer.Tracer, funcName string, f func(bc *handshake.BufferedConn) error, deadline searchutils.Deadline) error { qtChild := qt.NewChild("rpc call %s()", funcName) err := sn.execOnConn(qtChild, funcName, f, deadline) qtChild.Done() if err == nil { return nil } var er *errRemote var ne net.Error if errors.As(err, &er) || errors.As(err, &ne) && ne.Timeout() { // There is no sense in repeating the query on errors induced by vmstorage (errRemote) or on network timeout errors. return err } // Repeat the query in the hope the error was temporary. qtChild = qt.NewChild("retry rpc call %s() after error", funcName) err = sn.execOnConn(qtChild, funcName, f, deadline) qtChild.Done() return err } func (sn *storageNode) execOnConn(qt *querytracer.Tracer, funcName string, f func(bc *handshake.BufferedConn) error, deadline searchutils.Deadline) error { sn.concurrentQueries.Inc() defer sn.concurrentQueries.Dec() d := time.Unix(int64(deadline.Deadline()), 0) nowSecs := fasttime.UnixTimestamp() currentTime := time.Unix(int64(nowSecs), 0) timeout := d.Sub(currentTime) if timeout <= 0 { return fmt.Errorf("request timeout reached: %s", deadline.String()) } bc, err := sn.connPool.Get() if err != nil { return fmt.Errorf("cannot obtain connection from a pool: %w", err) } // Extend the connection deadline by 2 seconds, so the remote storage could return `timeout` error // without the need to break the connection. connDeadline := d.Add(2 * time.Second) if err := bc.SetDeadline(connDeadline); err != nil { _ = bc.Close() logger.Panicf("FATAL: cannot set connection deadline: %s", err) } if err := writeBytes(bc, []byte(funcName)); err != nil { // Close the connection instead of returning it to the pool, // since it may be broken. _ = bc.Close() return fmt.Errorf("cannot send funcName=%q to the server: %w", funcName, err) } // Send query trace flag traceEnabled := qt.Enabled() if err := writeBool(bc, traceEnabled); err != nil { // Close the connection instead of returning it to the pool, // since it may be broken. _ = bc.Close() return fmt.Errorf("cannot send traceEnabled=%v for funcName=%q to the server: %w", traceEnabled, funcName, err) } // Send the remaining timeout instead of deadline to remote server, since it may have different time. timeoutSecs := uint32(timeout.Seconds() + 1) if err := writeUint32(bc, timeoutSecs); err != nil { // Close the connection instead of returning it to the pool, // since it may be broken. _ = bc.Close() return fmt.Errorf("cannot send timeout=%d for funcName=%q to the server: %w", timeout, funcName, err) } // Execute the rpc function. if err := f(bc); err != nil { remoteAddr := bc.RemoteAddr() var er *errRemote if errors.As(err, &er) { // Remote error. The connection may be re-used. Return it to the pool. _ = readTrace(qt, bc) sn.connPool.Put(bc) } else { // Local error. // Close the connection instead of returning it to the pool, // since it may be broken. _ = bc.Close() } if deadline.Exceeded() { return fmt.Errorf("cannot execute funcName=%q on vmstorage %q with timeout %s: %w", funcName, remoteAddr, deadline.String(), err) } return fmt.Errorf("cannot execute funcName=%q on vmstorage %q: %w", funcName, remoteAddr, err) } // Read trace from the response if err := readTrace(qt, bc); err != nil { // Close the connection instead of returning it to the pool, // since it may be broken. _ = bc.Close() return err } // Return the connection back to the pool, assuming it is healthy. sn.connPool.Put(bc) return nil } func readTrace(qt *querytracer.Tracer, bc *handshake.BufferedConn) error { bb := traceJSONBufPool.Get() var err error bb.B, err = readBytes(bb.B[:0], bc, maxTraceJSONSize) if err != nil { return fmt.Errorf("cannot read trace from the server: %w", err) } if err := qt.AddJSON(bb.B); err != nil { return fmt.Errorf("cannot parse trace read from the server: %w", err) } traceJSONBufPool.Put(bb) return nil } var traceJSONBufPool bytesutil.ByteBufferPool const maxTraceJSONSize = 1024 * 1024 type errRemote struct { msg string } func (er *errRemote) Error() string { return er.msg } func newErrRemote(buf []byte) error { err := &errRemote{ msg: string(buf), } if !strings.Contains(err.msg, "denyQueriesOutsideRetention") { return err } return &httpserver.ErrorWithStatusCode{ Err: err, StatusCode: http.StatusServiceUnavailable, } } func (sn *storageNode) registerMetricNamesOnConn(bc *handshake.BufferedConn, mrs []storage.MetricRow) error { // Send the request to sn. if err := writeUint64(bc, uint64(len(mrs))); err != nil { return fmt.Errorf("cannot send metricsCount to conn: %w", err) } for i, mr := range mrs { if err := writeBytes(bc, mr.MetricNameRaw); err != nil { return fmt.Errorf("cannot send MetricNameRaw #%d to conn: %w", i+1, err) } if err := writeUint64(bc, uint64(mr.Timestamp)); err != nil { return fmt.Errorf("cannot send Timestamp #%d to conn: %w", i+1, err) } } if err := bc.Flush(); err != nil { return fmt.Errorf("cannot flush registerMetricNames request to conn: %w", err) } // Read response error. buf, err := readBytes(nil, bc, maxErrorMessageSize) if err != nil { return fmt.Errorf("cannot read error message: %w", err) } if len(buf) > 0 { return newErrRemote(buf) } return nil } func (sn *storageNode) deleteSeriesOnConn(bc *handshake.BufferedConn, requestData []byte) (int, error) { // Send the request to sn if err := writeBytes(bc, requestData); err != nil { return 0, fmt.Errorf("cannot send deleteSeries request to conn: %w", err) } if err := bc.Flush(); err != nil { return 0, fmt.Errorf("cannot flush deleteSeries request to conn: %w", err) } // Read response error. buf, err := readBytes(nil, bc, maxErrorMessageSize) if err != nil { return 0, fmt.Errorf("cannot read error message: %w", err) } if len(buf) > 0 { return 0, newErrRemote(buf) } // Read deletedCount deletedCount, err := readUint64(bc) if err != nil { return 0, fmt.Errorf("cannot read deletedCount value: %w", err) } return int(deletedCount), nil } const maxLabelNameSize = 16 * 1024 * 1024 func (sn *storageNode) getLabelNamesOnConn(bc *handshake.BufferedConn, requestData []byte, maxLabelNames int) ([]string, error) { // Send the request to sn. if err := writeBytes(bc, requestData); err != nil { return nil, fmt.Errorf("cannot write requestData: %w", err) } if err := writeLimit(bc, maxLabelNames); err != nil { return nil, fmt.Errorf("cannot write maxLabelNames=%d: %w", maxLabelNames, err) } if err := bc.Flush(); err != nil { return nil, fmt.Errorf("cannot flush request to conn: %w", err) } // Read response error. buf, err := readBytes(nil, bc, maxErrorMessageSize) if err != nil { return nil, fmt.Errorf("cannot read error message: %w", err) } if len(buf) > 0 { return nil, newErrRemote(buf) } // Read response var labels []string for { buf, err = readBytes(buf[:0], bc, maxLabelNameSize) if err != nil { return nil, fmt.Errorf("cannot read labels: %w", err) } if len(buf) == 0 { // Reached the end of the response return labels, nil } labels = append(labels, string(buf)) } } const maxLabelValueSize = 16 * 1024 * 1024 func (sn *storageNode) getLabelValuesOnConn(bc *handshake.BufferedConn, labelName string, requestData []byte, maxLabelValues int) ([]string, error) { // Send the request to sn. if err := writeBytes(bc, []byte(labelName)); err != nil { return nil, fmt.Errorf("cannot send labelName=%q to conn: %w", labelName, err) } if err := writeBytes(bc, requestData); err != nil { return nil, fmt.Errorf("cannot write requestData: %w", err) } if err := writeLimit(bc, maxLabelValues); err != nil { return nil, fmt.Errorf("cannot write maxLabelValues=%d: %w", maxLabelValues, err) } if err := bc.Flush(); err != nil { return nil, fmt.Errorf("cannot flush labelName to conn: %w", err) } // Read response error. buf, err := readBytes(nil, bc, maxErrorMessageSize) if err != nil { return nil, fmt.Errorf("cannot read error message: %w", err) } if len(buf) > 0 { return nil, newErrRemote(buf) } // Read response labelValues, _, err := readLabelValues(buf, bc) if err != nil { return nil, err } return labelValues, nil } func readLabelValues(buf []byte, bc *handshake.BufferedConn) ([]string, []byte, error) { var labelValues []string for { var err error buf, err = readBytes(buf[:0], bc, maxLabelValueSize) if err != nil { return nil, buf, fmt.Errorf("cannot read labelValue: %w", err) } if len(buf) == 0 { // Reached the end of the response return labelValues, buf, nil } labelValues = append(labelValues, string(buf)) } } func (sn *storageNode) getTagValueSuffixesOnConn(bc *handshake.BufferedConn, accountID, projectID uint32, tr storage.TimeRange, tagKey, tagValuePrefix string, delimiter byte, maxSuffixes int) ([]string, error) { // Send the request to sn. if err := sendAccountIDProjectID(bc, accountID, projectID); err != nil { return nil, err } if err := writeTimeRange(bc, tr); err != nil { return nil, err } if err := writeBytes(bc, []byte(tagKey)); err != nil { return nil, fmt.Errorf("cannot send tagKey=%q to conn: %w", tagKey, err) } if err := writeBytes(bc, []byte(tagValuePrefix)); err != nil { return nil, fmt.Errorf("cannot send tagValuePrefix=%q to conn: %w", tagValuePrefix, err) } if err := writeByte(bc, delimiter); err != nil { return nil, fmt.Errorf("cannot send delimiter=%c to conn: %w", delimiter, err) } if err := writeLimit(bc, maxSuffixes); err != nil { return nil, fmt.Errorf("cannot send maxSuffixes=%d to conn: %w", maxSuffixes, err) } if err := bc.Flush(); err != nil { return nil, fmt.Errorf("cannot flush request to conn: %w", err) } // Read response error. buf, err := readBytes(nil, bc, maxErrorMessageSize) if err != nil { return nil, fmt.Errorf("cannot read error message: %w", err) } if len(buf) > 0 { return nil, newErrRemote(buf) } // Read response. // The response may contain empty suffix, so it is prepended with the number of the following suffixes. suffixesCount, err := readUint64(bc) if err != nil { return nil, fmt.Errorf("cannot read the number of tag value suffixes: %w", err) } suffixes := make([]string, 0, suffixesCount) for i := 0; i < int(suffixesCount); i++ { buf, err = readBytes(buf[:0], bc, maxLabelValueSize) if err != nil { return nil, fmt.Errorf("cannot read tag value suffix #%d: %w", i+1, err) } suffixes = append(suffixes, string(buf)) } return suffixes, nil } func (sn *storageNode) getTSDBStatusOnConn(bc *handshake.BufferedConn, requestData []byte, focusLabel string, topN int) (*storage.TSDBStatus, error) { // Send the request to sn. if err := writeBytes(bc, requestData); err != nil { return nil, fmt.Errorf("cannot write requestData: %w", err) } if err := writeBytes(bc, []byte(focusLabel)); err != nil { return nil, fmt.Errorf("cannot write focusLabel=%q: %w", focusLabel, err) } // topN shouldn't exceed 32 bits, so send it as uint32. if err := writeUint32(bc, uint32(topN)); err != nil { return nil, fmt.Errorf("cannot send topN=%d to conn: %w", topN, err) } if err := bc.Flush(); err != nil { return nil, fmt.Errorf("cannot flush tsdbStatus args to conn: %w", err) } // Read response error. buf, err := readBytes(nil, bc, maxErrorMessageSize) if err != nil { return nil, fmt.Errorf("cannot read error message: %w", err) } if len(buf) > 0 { return nil, newErrRemote(buf) } // Read response return readTSDBStatus(bc) } func readTSDBStatus(bc *handshake.BufferedConn) (*storage.TSDBStatus, error) { totalSeries, err := readUint64(bc) if err != nil { return nil, fmt.Errorf("cannot read totalSeries: %w", err) } totalLabelValuePairs, err := readUint64(bc) if err != nil { return nil, fmt.Errorf("cannot read totalLabelValuePairs: %w", err) } seriesCountByMetricName, err := readTopHeapEntries(bc) if err != nil { return nil, fmt.Errorf("cannot read seriesCountByMetricName: %w", err) } seriesCountByLabelName, err := readTopHeapEntries(bc) if err != nil { return nil, fmt.Errorf("cannot read seriesCountByLabelName: %w", err) } seriesCountByFocusLabelValue, err := readTopHeapEntries(bc) if err != nil { return nil, fmt.Errorf("cannot read seriesCountByFocusLabelValue: %w", err) } seriesCountByLabelValuePair, err := readTopHeapEntries(bc) if err != nil { return nil, fmt.Errorf("cannot read seriesCountByLabelValuePair: %w", err) } labelValueCountByLabelName, err := readTopHeapEntries(bc) if err != nil { return nil, fmt.Errorf("cannot read labelValueCountByLabelName: %w", err) } status := &storage.TSDBStatus{ TotalSeries: totalSeries, TotalLabelValuePairs: totalLabelValuePairs, SeriesCountByMetricName: seriesCountByMetricName, SeriesCountByLabelName: seriesCountByLabelName, SeriesCountByFocusLabelValue: seriesCountByFocusLabelValue, SeriesCountByLabelValuePair: seriesCountByLabelValuePair, LabelValueCountByLabelName: labelValueCountByLabelName, } return status, nil } func readTopHeapEntries(bc *handshake.BufferedConn) ([]storage.TopHeapEntry, error) { n, err := readUint64(bc) if err != nil { return nil, fmt.Errorf("cannot read the number of topHeapEntries: %w", err) } var a []storage.TopHeapEntry var buf []byte for i := uint64(0); i < n; i++ { buf, err = readBytes(buf[:0], bc, maxLabelNameSize) if err != nil { return nil, fmt.Errorf("cannot read label name: %w", err) } count, err := readUint64(bc) if err != nil { return nil, fmt.Errorf("cannot read label count: %w", err) } a = append(a, storage.TopHeapEntry{ Name: string(buf), Count: count, }) } return a, nil } func (sn *storageNode) getSeriesCountOnConn(bc *handshake.BufferedConn, accountID, projectID uint32) (uint64, error) { // Send the request to sn. if err := sendAccountIDProjectID(bc, accountID, projectID); err != nil { return 0, err } if err := bc.Flush(); err != nil { return 0, fmt.Errorf("cannot flush seriesCount args to conn: %w", err) } // Read response error. buf, err := readBytes(nil, bc, maxErrorMessageSize) if err != nil { return 0, fmt.Errorf("cannot read error message: %w", err) } if len(buf) > 0 { return 0, newErrRemote(buf) } // Read response n, err := readUint64(bc) if err != nil { return 0, fmt.Errorf("cannot read series count: %w", err) } return n, nil } // maxMetricBlockSize is the maximum size of serialized MetricBlock. const maxMetricBlockSize = 1024 * 1024 // maxErrorMessageSize is the maximum size of error message received // from vmstorage. const maxErrorMessageSize = 64 * 1024 func (sn *storageNode) processSearchMetricNamesOnConn(bc *handshake.BufferedConn, requestData []byte) ([]string, error) { // Send the requst to sn. if err := writeBytes(bc, requestData); err != nil { return nil, fmt.Errorf("cannot write requestData: %w", err) } if err := bc.Flush(); err != nil { return nil, fmt.Errorf("cannot flush requestData to conn: %w", err) } // Read response error. buf, err := readBytes(nil, bc, maxErrorMessageSize) if err != nil { return nil, fmt.Errorf("cannot read error message: %w", err) } if len(buf) > 0 { return nil, newErrRemote(buf) } // Read metricNames from response. metricNamesCount, err := readUint64(bc) if err != nil { return nil, fmt.Errorf("cannot read metricNamesCount: %w", err) } metricNames := make([]string, metricNamesCount) for i := int64(0); i < int64(metricNamesCount); i++ { buf, err = readBytes(buf[:0], bc, maxMetricNameSize) if err != nil { return nil, fmt.Errorf("cannot read metricName #%d: %w", i+1, err) } metricNames[i] = string(buf) } return metricNames, nil } const maxMetricNameSize = 64 * 1024 func (sn *storageNode) processSearchQueryOnConn(bc *handshake.BufferedConn, requestData []byte, processBlock func(mb *storage.MetricBlock) error) error { // Send the request to sn. if err := writeBytes(bc, requestData); err != nil { return fmt.Errorf("cannot write requestData: %w", err) } if err := bc.Flush(); err != nil { return fmt.Errorf("cannot flush requestData to conn: %w", err) } // Read response error. buf, err := readBytes(nil, bc, maxErrorMessageSize) if err != nil { return fmt.Errorf("cannot read error message: %w", err) } if len(buf) > 0 { return newErrRemote(buf) } // Read response. It may consist of multiple MetricBlocks. blocksRead := 0 var mb storage.MetricBlock for { buf, err = readBytes(buf[:0], bc, maxMetricBlockSize) if err != nil { return fmt.Errorf("cannot read MetricBlock #%d: %w", blocksRead, err) } if len(buf) == 0 { // Reached the end of the response return nil } tail, err := mb.Unmarshal(buf) if err != nil { return fmt.Errorf("cannot unmarshal MetricBlock #%d: %w", blocksRead, err) } if len(tail) != 0 { return fmt.Errorf("non-empty tail after unmarshaling MetricBlock #%d: (len=%d) %q", blocksRead, len(tail), tail) } blocksRead++ sn.metricBlocksRead.Inc() sn.metricRowsRead.Add(mb.Block.RowsCount()) if err := processBlock(&mb); err != nil { return fmt.Errorf("cannot process MetricBlock #%d: %w", blocksRead, err) } } } func writeTimeRange(bc *handshake.BufferedConn, tr storage.TimeRange) error { if err := writeUint64(bc, uint64(tr.MinTimestamp)); err != nil { return fmt.Errorf("cannot send minTimestamp=%d to conn: %w", tr.MinTimestamp, err) } if err := writeUint64(bc, uint64(tr.MaxTimestamp)); err != nil { return fmt.Errorf("cannot send maxTimestamp=%d to conn: %w", tr.MaxTimestamp, err) } return nil } func writeLimit(bc *handshake.BufferedConn, limit int) error { if limit < 0 { limit = 0 } if limit > 1<<31-1 { limit = 1<<31 - 1 } limitU32 := uint32(limit) if err := writeUint32(bc, limitU32); err != nil { return fmt.Errorf("cannot write limit=%d to conn: %w", limitU32, err) } return nil } func writeBytes(bc *handshake.BufferedConn, buf []byte) error { sizeBuf := encoding.MarshalUint64(nil, uint64(len(buf))) if _, err := bc.Write(sizeBuf); err != nil { return err } _, err := bc.Write(buf) return err } func writeUint32(bc *handshake.BufferedConn, n uint32) error { buf := encoding.MarshalUint32(nil, n) _, err := bc.Write(buf) return err } func writeUint64(bc *handshake.BufferedConn, n uint64) error { buf := encoding.MarshalUint64(nil, n) _, err := bc.Write(buf) return err } func writeBool(bc *handshake.BufferedConn, b bool) error { var buf [1]byte if b { buf[0] = 1 } _, err := bc.Write(buf[:]) return err } func writeByte(bc *handshake.BufferedConn, b byte) error { var buf [1]byte buf[0] = b _, err := bc.Write(buf[:]) return err } func sendAccountIDProjectID(bc *handshake.BufferedConn, accountID, projectID uint32) error { if err := writeUint32(bc, accountID); err != nil { return fmt.Errorf("cannot send accountID=%d to conn: %w", accountID, err) } if err := writeUint32(bc, projectID); err != nil { return fmt.Errorf("cannot send projectID=%d to conn: %w", projectID, err) } return nil } func readBytes(buf []byte, bc *handshake.BufferedConn, maxDataSize int) ([]byte, error) { buf = bytesutil.ResizeNoCopyMayOverallocate(buf, 8) if n, err := io.ReadFull(bc, buf); err != nil { return buf, fmt.Errorf("cannot read %d bytes with data size: %w; read only %d bytes", len(buf), err, n) } dataSize := encoding.UnmarshalUint64(buf) if dataSize > uint64(maxDataSize) { return buf, fmt.Errorf("too big data size: %d; it mustn't exceed %d bytes", dataSize, maxDataSize) } buf = bytesutil.ResizeNoCopyMayOverallocate(buf, int(dataSize)) if dataSize == 0 { return buf, nil } if n, err := io.ReadFull(bc, buf); err != nil { return buf, fmt.Errorf("cannot read data with size %d: %w; read only %d bytes", dataSize, err, n) } return buf, nil } func readUint64(bc *handshake.BufferedConn) (uint64, error) { var buf [8]byte if _, err := io.ReadFull(bc, buf[:]); err != nil { return 0, fmt.Errorf("cannot read uint64: %w", err) } n := encoding.UnmarshalUint64(buf[:]) return n, nil } var storageNodes []*storageNode // InitStorageNodes initializes storage nodes' connections to the given addrs. func InitStorageNodes(addrs []string) { if len(addrs) == 0 { logger.Panicf("BUG: addrs must be non-empty") } for _, addr := range addrs { if _, _, err := net.SplitHostPort(addr); err != nil { // Automatically add missing port. addr += ":8401" } sn := &storageNode{ // There is no need in requests compression, since they are usually very small. connPool: netutil.NewConnPool("vmselect", addr, handshake.VMSelectClient, 0, *vmstorageDialTimeout), concurrentQueries: metrics.NewCounter(fmt.Sprintf(`vm_concurrent_queries{name="vmselect", addr=%q}`, addr)), registerMetricNamesRequests: metrics.NewCounter(fmt.Sprintf(`vm_requests_total{action="registerMetricNames", type="rpcClient", name="vmselect", addr=%q}`, addr)), registerMetricNamesErrors: metrics.NewCounter(fmt.Sprintf(`vm_request_errors_total{action="registerMetricNames", type="rpcClient", name="vmselect", addr=%q}`, addr)), deleteSeriesRequests: metrics.NewCounter(fmt.Sprintf(`vm_requests_total{action="deleteSeries", type="rpcClient", name="vmselect", addr=%q}`, addr)), deleteSeriesErrors: metrics.NewCounter(fmt.Sprintf(`vm_request_errors_total{action="deleteSeries", type="rpcClient", name="vmselect", addr=%q}`, addr)), labelNamesRequests: metrics.NewCounter(fmt.Sprintf(`vm_requests_total{action="labelNames", type="rpcClient", name="vmselect", addr=%q}`, addr)), labelNamesErrors: metrics.NewCounter(fmt.Sprintf(`vm_request_errors_total{action="labelNames", type="rpcClient", name="vmselect", addr=%q}`, addr)), labelValuesRequests: metrics.NewCounter(fmt.Sprintf(`vm_requests_total{action="labelValues", type="rpcClient", name="vmselect", addr=%q}`, addr)), labelValuesErrors: metrics.NewCounter(fmt.Sprintf(`vm_request_errors_total{action="labelValues", type="rpcClient", name="vmselect", addr=%q}`, addr)), tagValueSuffixesRequests: metrics.NewCounter(fmt.Sprintf(`vm_requests_total{action="tagValueSuffixes", type="rpcClient", name="vmselect", addr=%q}`, addr)), tagValueSuffixesErrors: metrics.NewCounter(fmt.Sprintf(`vm_request_errors_total{action="tagValueSuffixes", type="rpcClient", name="vmselect", addr=%q}`, addr)), tsdbStatusRequests: metrics.NewCounter(fmt.Sprintf(`vm_requests_total{action="tsdbStatus", type="rpcClient", name="vmselect", addr=%q}`, addr)), tsdbStatusErrors: metrics.NewCounter(fmt.Sprintf(`vm_request_errors_total{action="tsdbStatus", type="rpcClient", name="vmselect", addr=%q}`, addr)), seriesCountRequests: metrics.NewCounter(fmt.Sprintf(`vm_requests_total{action="seriesCount", type="rpcClient", name="vmselect", addr=%q}`, addr)), seriesCountErrors: metrics.NewCounter(fmt.Sprintf(`vm_request_errors_total{action="seriesCount", type="rpcClient", name="vmselect", addr=%q}`, addr)), searchMetricNamesRequests: metrics.NewCounter(fmt.Sprintf(`vm_requests_total{action="searchMetricNames", type="rpcClient", name="vmselect", addr=%q}`, addr)), searchMetricNamesErrors: metrics.NewCounter(fmt.Sprintf(`vm_request_errors_total{action="searchMetricNames", type="rpcClient", name="vmselect", addr=%q}`, addr)), searchRequests: metrics.NewCounter(fmt.Sprintf(`vm_requests_total{action="search", type="rpcClient", name="vmselect", addr=%q}`, addr)), searchErrors: metrics.NewCounter(fmt.Sprintf(`vm_request_errors_total{action="search", type="rpcClient", name="vmselect", addr=%q}`, addr)), metricBlocksRead: metrics.NewCounter(fmt.Sprintf(`vm_metric_blocks_read_total{name="vmselect", addr=%q}`, addr)), metricRowsRead: metrics.NewCounter(fmt.Sprintf(`vm_metric_rows_read_total{name="vmselect", addr=%q}`, addr)), } storageNodes = append(storageNodes, sn) } } // Stop gracefully stops netstorage. func Stop() { // Nothing to do at the moment. } var ( partialLabelNamesResults = metrics.NewCounter(`vm_partial_results_total{action="labelNames", name="vmselect"}`) partialLabelValuesResults = metrics.NewCounter(`vm_partial_results_total{action="labelValues", name="vmselect"}`) partialTagValueSuffixesResults = metrics.NewCounter(`vm_partial_results_total{action="tagValueSuffixes", name="vmselect"}`) partialTSDBStatusResults = metrics.NewCounter(`vm_partial_results_total{action="tsdbStatus", name="vmselect"}`) partialSeriesCountResults = metrics.NewCounter(`vm_partial_results_total{action="seriesCount", name="vmselect"}`) partialSearchMetricNamesResults = metrics.NewCounter(`vm_partial_results_total{action="searchMetricNames", name="vmselect"}`) partialSearchResults = metrics.NewCounter(`vm_partial_results_total{action="search", name="vmselect"}`) ) func applyGraphiteRegexpFilter(filter string, ss []string) ([]string, error) { // Anchor filter regexp to the beginning of the string as Graphite does. // See https://github.com/graphite-project/graphite-web/blob/3ad279df5cb90b211953e39161df416e54a84948/webapp/graphite/tags/localdatabase.py#L157 filter = "^(?:" + filter + ")" re, err := regexp.Compile(filter) if err != nil { return nil, fmt.Errorf("cannot parse regexp filter=%q: %w", filter, err) } dst := ss[:0] for _, s := range ss { if re.MatchString(s) { dst = append(dst, s) } } return dst, nil }