package promql import ( "flag" "fmt" "math" "sort" "strings" "sync" "sync/atomic" "time" "github.com/VictoriaMetrics/VictoriaMetrics/app/vmselect/netstorage" "github.com/VictoriaMetrics/VictoriaMetrics/app/vmselect/querystats" "github.com/VictoriaMetrics/VictoriaMetrics/lib/decimal" "github.com/VictoriaMetrics/VictoriaMetrics/lib/storage" "github.com/VictoriaMetrics/metrics" "github.com/VictoriaMetrics/metricsql" ) var ( treatDotsAsIsInRegexps = flag.Bool("search.treatDotsAsIsInRegexps", false, "Whether to treat dots as is in regexp label filters used in queries. "+ `For example, foo{bar=~"a.b.c"} will be automatically converted to foo{bar=~"a\\.b\\.c"}, i.e. all the dots in regexp filters will be automatically escaped `+ `in order to match only dot char instead of matching any char. Dots in ".+", ".*" and ".{n}" regexps aren't escaped. `+ `This option is DEPRECATED in favor of {__graphite__="a.*.c"} syntax for selecting metrics matching the given Graphite metrics filter`) ) // Exec executes q for the given ec. func Exec(ec *EvalConfig, q string, isFirstPointOnly bool) ([]netstorage.Result, error) { if querystats.Enabled() { startTime := time.Now() ac := ec.AuthToken defer querystats.RegisterQuery(ac.AccountID, ac.ProjectID, q, ec.End-ec.Start, startTime) } ec.validate() e, err := parsePromQLWithCache(q) if err != nil { return nil, err } qid := activeQueriesV.Add(ec, q) rv, err := evalExpr(ec, e) activeQueriesV.Remove(qid) if err != nil { return nil, err } if isFirstPointOnly { // Remove all the points except the first one from every time series. for _, ts := range rv { ts.Values = ts.Values[:1] ts.Timestamps = ts.Timestamps[:1] } } maySort := maySortResults(e, rv) result, err := timeseriesToResult(rv, maySort) if err != nil { return nil, err } if n := ec.RoundDigits; n < 100 { for i := range result { values := result[i].Values for j, v := range values { values[j] = decimal.RoundToDecimalDigits(v, n) } } } return result, err } func maySortResults(e metricsql.Expr, tss []*timeseries) bool { switch v := e.(type) { case *metricsql.FuncExpr: switch strings.ToLower(v.Name) { case "sort", "sort_desc", "sort_by_label", "sort_by_label_desc": return false } case *metricsql.AggrFuncExpr: switch strings.ToLower(v.Name) { case "topk", "bottomk", "outliersk", "topk_max", "topk_min", "topk_avg", "topk_median", "bottomk_max", "bottomk_min", "bottomk_avg", "bottomk_median": return false } } return true } func timeseriesToResult(tss []*timeseries, maySort bool) ([]netstorage.Result, error) { tss = removeNaNs(tss) result := make([]netstorage.Result, len(tss)) m := make(map[string]struct{}, len(tss)) bb := bbPool.Get() for i, ts := range tss { bb.B = marshalMetricNameSorted(bb.B[:0], &ts.MetricName) if _, ok := m[string(bb.B)]; ok { return nil, fmt.Errorf(`duplicate output timeseries: %s`, stringMetricName(&ts.MetricName)) } m[string(bb.B)] = struct{}{} rs := &result[i] rs.MetricName.CopyFrom(&ts.MetricName) rs.Values = append(rs.Values[:0], ts.Values...) rs.Timestamps = append(rs.Timestamps[:0], ts.Timestamps...) } bbPool.Put(bb) if maySort { sort.Slice(result, func(i, j int) bool { return metricNameLess(&result[i].MetricName, &result[j].MetricName) }) } return result, nil } func metricNameLess(a, b *storage.MetricName) bool { if string(a.MetricGroup) != string(b.MetricGroup) { return string(a.MetricGroup) < string(b.MetricGroup) } // Metric names for a and b match. Compare tags. // Tags must be already sorted by the caller, so just compare them. ats := a.Tags bts := b.Tags for i := range ats { if i >= len(bts) { // a contains more tags than b and all the previous tags were identical, // so a is considered bigger than b. return false } at := &ats[i] bt := &bts[i] if string(at.Key) != string(bt.Key) { return string(at.Key) < string(bt.Key) } if string(at.Value) != string(bt.Value) { return string(at.Value) < string(bt.Value) } } return len(ats) < len(bts) } func removeNaNs(tss []*timeseries) []*timeseries { rvs := tss[:0] for _, ts := range tss { allNans := true for _, v := range ts.Values { if !math.IsNaN(v) { allNans = false break } } if allNans { // Skip timeseries with all NaNs. continue } rvs = append(rvs, ts) } for i := len(rvs); i < len(tss); i++ { // Zero unused time series, so GC could reclaim them. tss[i] = nil } return rvs } func adjustCmpOps(e metricsql.Expr) metricsql.Expr { metricsql.VisitAll(e, func(expr metricsql.Expr) { be, ok := expr.(*metricsql.BinaryOpExpr) if !ok { return } if !metricsql.IsBinaryOpCmp(be.Op) { return } if isNumberExpr(be.Right) || !isScalarExpr(be.Left) { return } // Convert 'num cmpOp query' expression to `query reverseCmpOp num` expression // like Prometheus does. For instance, `0.5 < foo` must be converted to `foo > 0.5` // in order to return valid values for `foo` that are bigger than 0.5. be.Right, be.Left = be.Left, be.Right be.Op = getReverseCmpOp(be.Op) }) return e } func isNumberExpr(e metricsql.Expr) bool { _, ok := e.(*metricsql.NumberExpr) return ok } func isScalarExpr(e metricsql.Expr) bool { if isNumberExpr(e) { return true } if fe, ok := e.(*metricsql.FuncExpr); ok { // time() returns scalar in PromQL - see https://prometheus.io/docs/prometheus/latest/querying/functions/#time return strings.ToLower(fe.Name) == "time" } return false } func getReverseCmpOp(op string) string { switch op { case ">": return "<" case "<": return ">" case ">=": return "<=" case "<=": return ">=" default: // there is no need in changing `==` and `!=`. return op } } func parsePromQLWithCache(q string) (metricsql.Expr, error) { pcv := parseCacheV.Get(q) if pcv == nil { e, err := metricsql.Parse(q) if err == nil { e = metricsql.Optimize(e) e = adjustCmpOps(e) if *treatDotsAsIsInRegexps { e = escapeDotsInRegexpLabelFilters(e) } } pcv = &parseCacheValue{ e: e, err: err, } parseCacheV.Put(q, pcv) } if pcv.err != nil { return nil, pcv.err } return pcv.e, nil } func escapeDotsInRegexpLabelFilters(e metricsql.Expr) metricsql.Expr { metricsql.VisitAll(e, func(expr metricsql.Expr) { me, ok := expr.(*metricsql.MetricExpr) if !ok { return } for i := range me.LabelFilters { f := &me.LabelFilters[i] if f.IsRegexp { f.Value = escapeDots(f.Value) } } }) return e } func escapeDots(s string) string { dotsCount := strings.Count(s, ".") if dotsCount <= 0 { return s } result := make([]byte, 0, len(s)+2*dotsCount) for i := 0; i < len(s); i++ { if s[i] == '.' && (i == 0 || s[i-1] != '\\') && (i+1 == len(s) || i+1 < len(s) && s[i+1] != '*' && s[i+1] != '+' && s[i+1] != '{') { // Escape a dot if the following conditions are met: // - if it isn't escaped already, i.e. if there is no `\` char before the dot. // - if there is no regexp modifiers such as '+', '*' or '{' after the dot. result = append(result, '\\', '.') } else { result = append(result, s[i]) } } return string(result) } var parseCacheV = func() *parseCache { pc := &parseCache{ m: make(map[string]*parseCacheValue), } metrics.NewGauge(`vm_cache_requests_total{type="promql/parse"}`, func() float64 { return float64(pc.Requests()) }) metrics.NewGauge(`vm_cache_misses_total{type="promql/parse"}`, func() float64 { return float64(pc.Misses()) }) metrics.NewGauge(`vm_cache_entries{type="promql/parse"}`, func() float64 { return float64(pc.Len()) }) return pc }() const parseCacheMaxLen = 10e3 type parseCacheValue struct { e metricsql.Expr err error } type parseCache struct { // Move atomic counters to the top of struct for 8-byte alignment on 32-bit arch. // See https://github.com/VictoriaMetrics/VictoriaMetrics/issues/212 requests uint64 misses uint64 m map[string]*parseCacheValue mu sync.RWMutex } func (pc *parseCache) Requests() uint64 { return atomic.LoadUint64(&pc.requests) } func (pc *parseCache) Misses() uint64 { return atomic.LoadUint64(&pc.misses) } func (pc *parseCache) Len() uint64 { pc.mu.RLock() n := len(pc.m) pc.mu.RUnlock() return uint64(n) } func (pc *parseCache) Get(q string) *parseCacheValue { atomic.AddUint64(&pc.requests, 1) pc.mu.RLock() pcv := pc.m[q] pc.mu.RUnlock() if pcv == nil { atomic.AddUint64(&pc.misses, 1) } return pcv } func (pc *parseCache) Put(q string, pcv *parseCacheValue) { pc.mu.Lock() overflow := len(pc.m) - parseCacheMaxLen if overflow > 0 { // Remove 10% of items from the cache. overflow = int(float64(len(pc.m)) * 0.1) for k := range pc.m { delete(pc.m, k) overflow-- if overflow <= 0 { break } } } pc.m[q] = pcv pc.mu.Unlock() }