package graphite import ( "flag" "fmt" "time" "github.com/VictoriaMetrics/VictoriaMetrics/app/vmselect/graphiteql" "github.com/VictoriaMetrics/VictoriaMetrics/app/vmselect/netstorage" "github.com/VictoriaMetrics/VictoriaMetrics/app/vmselect/searchutils" "github.com/VictoriaMetrics/VictoriaMetrics/lib/cgroup" "github.com/VictoriaMetrics/VictoriaMetrics/lib/logger" "github.com/VictoriaMetrics/VictoriaMetrics/lib/storage" "github.com/VictoriaMetrics/VictoriaMetrics/lib/timerpool" ) var maxGraphiteSeries = flag.Int("search.maxGraphiteSeries", 300e3, "The maximum number of time series, which can be scanned during queries to Graphite Render API. "+ "See https://docs.victoriametrics.com/#graphite-render-api-usage") type evalConfig struct { startTime int64 endTime int64 storageStep int64 deadline searchutils.Deadline currentTime time.Time // xFilesFactor is used for determining when consolidateFunc must be applied. // // 0 means that consolidateFunc should be applied if at least a single non-NaN data point exists on the given step. // 1 means that consolidateFunc should be applied if all the data points are non-NaN on the given step. xFilesFactor float64 // Enforced tag filters etfs [][]storage.TagFilter // originalQuery contains the original query - used for debug logging. originalQuery string } func (ec *evalConfig) pointsLen(step int64) int { return int((ec.endTime - ec.startTime) / step) } func (ec *evalConfig) newTimestamps(step int64) []int64 { pointsLen := ec.pointsLen(step) timestamps := make([]int64, pointsLen) ts := ec.startTime for i := 0; i < pointsLen; i++ { timestamps[i] = ts ts += step } return timestamps } type series struct { Name string Tags map[string]string Timestamps []int64 Values []float64 // holds current path expression like graphite does. pathExpression string expr graphiteql.Expr // consolidateFunc is applied to raw samples in order to generate data points algined to the given step. // see series.consolidate() function for details. consolidateFunc aggrFunc // xFilesFactor is used for determining when consolidateFunc must be applied. // // 0 means that consolidateFunc should be applied if at least a single non-NaN data point exists on the given step. // 1 means that consolidateFunc should be applied if all the data points are non-NaN on the given step. xFilesFactor float64 step int64 } func (s *series) consolidate(ec *evalConfig, step int64) { aggrFunc := s.consolidateFunc if aggrFunc == nil { aggrFunc = aggrAvg } xFilesFactor := s.xFilesFactor if s.xFilesFactor <= 0 { xFilesFactor = ec.xFilesFactor } s.summarize(aggrFunc, ec.startTime, ec.endTime, step, xFilesFactor) } func (s *series) summarize(aggrFunc aggrFunc, startTime, endTime, step int64, xFilesFactor float64) { pointsLen := int((endTime - startTime) / step) timestamps := s.Timestamps values := s.Values dstTimestamps := make([]int64, 0, pointsLen) dstValues := make([]float64, 0, pointsLen) ts := startTime i := 0 for len(dstTimestamps) < pointsLen { tsEnd := ts + step j := i for j < len(timestamps) && timestamps[j] < tsEnd { j++ } if i == j && i > 0 && ts-timestamps[i-1] <= 2000 { // The current [ts ... tsEnd) interval has no samples, // but the last sample on the previous interval [ts - step ... ts) // is closer than 2 seconds to the current interval. // Let's consider that this sample belongs to the current interval, // since such discrepancy could appear because of small jitter in samples' ingestion. i-- } v := aggrFunc.apply(xFilesFactor, values[i:j]) dstTimestamps = append(dstTimestamps, ts) dstValues = append(dstValues, v) ts = tsEnd i = j } // Do not reuse s.Timestamps and s.Values, since they can be too big s.Timestamps = dstTimestamps s.Values = dstValues s.step = step } func execExpr(ec *evalConfig, query string) (nextSeriesFunc, error) { expr, err := graphiteql.Parse(query) if err != nil { return nil, fmt.Errorf("cannot parse %q: %w", query, err) } return evalExpr(ec, expr) } func evalExpr(ec *evalConfig, expr graphiteql.Expr) (nextSeriesFunc, error) { switch t := expr.(type) { case *graphiteql.MetricExpr: return evalMetricExpr(ec, t) case *graphiteql.FuncExpr: return evalFuncExpr(ec, t) default: return nil, fmt.Errorf("unexpected expression type %T; want graphiteql.MetricExpr or graphiteql.FuncExpr; expr: %q", t, t.AppendString(nil)) } } func evalMetricExpr(ec *evalConfig, me *graphiteql.MetricExpr) (nextSeriesFunc, error) { tfs := []storage.TagFilter{{ Key: []byte("__graphite__"), Value: []byte(me.Query), }} tfss := joinTagFilterss(tfs, ec.etfs) sq := storage.NewSearchQuery(ec.startTime, ec.endTime, tfss, *maxGraphiteSeries) return newNextSeriesForSearchQuery(ec, sq, me) } func newNextSeriesForSearchQuery(ec *evalConfig, sq *storage.SearchQuery, expr graphiteql.Expr) (nextSeriesFunc, error) { rss, err := netstorage.ProcessSearchQuery(nil, sq, ec.deadline) if err != nil { return nil, fmt.Errorf("cannot fetch data for %q: %w", sq, err) } seriesCh := make(chan *series, cgroup.AvailableCPUs()) errCh := make(chan error, 1) go func() { err := rss.RunParallel(nil, func(rs *netstorage.Result, _ uint) error { nameWithTags := getCanonicalPath(&rs.MetricName) tags := unmarshalTags(nameWithTags) s := &series{ Name: tags["name"], Tags: tags, Timestamps: append([]int64{}, rs.Timestamps...), Values: append([]float64{}, rs.Values...), expr: expr, pathExpression: string(expr.AppendString(nil)), } s.summarize(aggrAvg, ec.startTime, ec.endTime, ec.storageStep, 0) t := timerpool.Get(30 * time.Second) select { case seriesCh <- s: case <-t.C: logger.Errorf("resource leak when processing the %s (full query: %s); please report this error to VictoriaMetrics developers", expr.AppendString(nil), ec.originalQuery) } timerpool.Put(t) return nil }) close(seriesCh) errCh <- err }() f := func() (*series, error) { s := <-seriesCh if s != nil { return s, nil } err := <-errCh return nil, err } return f, nil } func evalFuncExpr(ec *evalConfig, fe *graphiteql.FuncExpr) (nextSeriesFunc, error) { // Do not lowercase the fe.FuncName, since Graphite function names are case-sensitive. tf := transformFuncs[fe.FuncName] if tf == nil { return nil, fmt.Errorf("unknown function %q", fe.FuncName) } nextSeries, err := tf(ec, fe) if err != nil { return nil, fmt.Errorf("cannot evaluate %s: %w", fe.AppendString(nil), err) } return nextSeries, nil }