// startLabelValue represents the state where the next byte read from p.buf is // the start of a (quoted) label value (or whitespace leading up to it). func (p *TextParser) startLabelValue() stateFn { if p.skipBlankTab(); p.err != nil { return nil // Unexpected end of input. } if p.currentByte != '"' { p.parseError(fmt.Sprintf("expected '\"' at start of label value, found %q", p.currentByte)) return nil } if p.readTokenAsLabelValue(); p.err != nil { return nil } p.currentLabelPair.Value = proto.String(p.currentToken.String()) // Special treatment of summaries: // - Quantile labels are special, will result in dto.Quantile later. // - Other labels have to be added to currentLabels for signature calculation. if p.currentMF.GetType() == dto.MetricType_SUMMARY { if p.currentLabelPair.GetName() == model.QuantileLabel { if p.currentQuantile, p.err = strconv.ParseFloat(p.currentLabelPair.GetValue(), 64); p.err != nil { // Create a more helpful error message. p.parseError(fmt.Sprintf("expected float as value for 'quantile' label, got %q", p.currentLabelPair.GetValue())) return nil } } else { p.currentLabels[p.currentLabelPair.GetName()] = p.currentLabelPair.GetValue() } } // Similar special treatment of histograms. if p.currentMF.GetType() == dto.MetricType_HISTOGRAM { if p.currentLabelPair.GetName() == model.BucketLabel { if p.currentBucket, p.err = strconv.ParseFloat(p.currentLabelPair.GetValue(), 64); p.err != nil { // Create a more helpful error message. p.parseError(fmt.Sprintf("expected float as value for 'le' label, got %q", p.currentLabelPair.GetValue())) return nil } } else { p.currentLabels[p.currentLabelPair.GetName()] = p.currentLabelPair.GetValue() } } if p.skipBlankTab(); p.err != nil { return nil // Unexpected end of input. } switch p.currentByte { case ',': return p.startLabelName case '}': if p.skipBlankTab(); p.err != nil { return nil // Unexpected end of input. } return p.readingValue default: p.parseError(fmt.Sprintf("unexpected end of label value %q", p.currentLabelPair.Value)) return nil } }
// readingHelp represents the state where the last byte read (now in // p.currentByte) is the first byte of the docstring after 'HELP'. func (p *TextParser) readingHelp() stateFn { if p.currentMF.Help != nil { p.parseError(fmt.Sprintf("second HELP line for metric name %q", p.currentMF.GetName())) return nil } // Rest of line is the docstring. if p.readTokenUntilNewline(true); p.err != nil { return nil // Unexpected end of input. } p.currentMF.Help = proto.String(p.currentToken.String()) return p.startOfLine }
func makeLabelPairs(desc *Desc, labelValues []string) []*dto.LabelPair { totalLen := len(desc.variableLabels) + len(desc.constLabelPairs) if totalLen == 0 { // Super fast path. return nil } if len(desc.variableLabels) == 0 { // Moderately fast path. return desc.constLabelPairs } labelPairs := make([]*dto.LabelPair, 0, totalLen) for i, n := range desc.variableLabels { labelPairs = append(labelPairs, &dto.LabelPair{ Name: proto.String(n), Value: proto.String(labelValues[i]), }) } for _, lp := range desc.constLabelPairs { labelPairs = append(labelPairs, lp) } sort.Sort(LabelPairSorter(labelPairs)) return labelPairs }
func protoLabelSet(base, ext model.LabelSet) []*dto.LabelPair { labels := base.Clone().Merge(ext) delete(labels, model.MetricNameLabel) names := make([]string, 0, len(labels)) for ln := range labels { names = append(names, string(ln)) } sort.Strings(names) pairs := make([]*dto.LabelPair, 0, len(labels)) for _, ln := range names { lv := labels[model.LabelName(ln)] pairs = append(pairs, &dto.LabelPair{ Name: proto.String(ln), Value: proto.String(string(lv)), }) } return pairs }
func (p *TextParser) setOrCreateCurrentMF() { p.currentIsSummaryCount = false p.currentIsSummarySum = false p.currentIsHistogramCount = false p.currentIsHistogramSum = false name := p.currentToken.String() if p.currentMF = p.metricFamiliesByName[name]; p.currentMF != nil { return } // Try out if this is a _sum or _count for a summary/histogram. summaryName := summaryMetricName(name) if p.currentMF = p.metricFamiliesByName[summaryName]; p.currentMF != nil { if p.currentMF.GetType() == dto.MetricType_SUMMARY { if isCount(name) { p.currentIsSummaryCount = true } if isSum(name) { p.currentIsSummarySum = true } return } } histogramName := histogramMetricName(name) if p.currentMF = p.metricFamiliesByName[histogramName]; p.currentMF != nil { if p.currentMF.GetType() == dto.MetricType_HISTOGRAM { if isCount(name) { p.currentIsHistogramCount = true } if isSum(name) { p.currentIsHistogramSum = true } return } } p.currentMF = &dto.MetricFamily{Name: proto.String(name)} p.metricFamiliesByName[name] = p.currentMF }
// startLabelName represents the state where the next byte read from p.buf is // the start of a label name (or whitespace leading up to it). func (p *TextParser) startLabelName() stateFn { if p.skipBlankTab(); p.err != nil { return nil // Unexpected end of input. } if p.currentByte == '}' { if p.skipBlankTab(); p.err != nil { return nil // Unexpected end of input. } return p.readingValue } if p.readTokenAsLabelName(); p.err != nil { return nil // Unexpected end of input. } if p.currentToken.Len() == 0 { p.parseError(fmt.Sprintf("invalid label name for metric %q", p.currentMF.GetName())) return nil } p.currentLabelPair = &dto.LabelPair{Name: proto.String(p.currentToken.String())} if p.currentLabelPair.GetName() == string(model.MetricNameLabel) { p.parseError(fmt.Sprintf("label name %q is reserved", model.MetricNameLabel)) return nil } // Special summary/histogram treatment. Don't add 'quantile' and 'le' // labels to 'real' labels. if !(p.currentMF.GetType() == dto.MetricType_SUMMARY && p.currentLabelPair.GetName() == model.QuantileLabel) && !(p.currentMF.GetType() == dto.MetricType_HISTOGRAM && p.currentLabelPair.GetName() == model.BucketLabel) { p.currentMetric.Label = append(p.currentMetric.Label, p.currentLabelPair) } if p.skipBlankTabIfCurrentBlankTab(); p.err != nil { return nil // Unexpected end of input. } if p.currentByte != '=' { p.parseError(fmt.Sprintf("expected '=' after label name, found %q", p.currentByte)) return nil } return p.startLabelValue }
func (d *json2Decoder) more() error { var entities []struct { BaseLabels model.LabelSet `json:"baseLabels"` Docstring string `json:"docstring"` Metric struct { Type string `json:"type"` Values json.RawMessage `json:"value"` } `json:"metric"` } if err := d.dec.Decode(&entities); err != nil { return err } for _, e := range entities { f := &dto.MetricFamily{ Name: proto.String(string(e.BaseLabels[model.MetricNameLabel])), Help: proto.String(e.Docstring), Type: dto.MetricType_UNTYPED.Enum(), Metric: []*dto.Metric{}, } d.fams = append(d.fams, f) switch e.Metric.Type { case "counter", "gauge": var values []counter002 if err := json.Unmarshal(e.Metric.Values, &values); err != nil { return fmt.Errorf("could not extract %s value: %s", e.Metric.Type, err) } for _, ctr := range values { f.Metric = append(f.Metric, &dto.Metric{ Label: protoLabelSet(e.BaseLabels, ctr.Labels), Untyped: &dto.Untyped{ Value: proto.Float64(ctr.Value), }, }) } case "histogram": var values []histogram002 if err := json.Unmarshal(e.Metric.Values, &values); err != nil { return fmt.Errorf("could not extract %s value: %s", e.Metric.Type, err) } for _, hist := range values { quants := make([]string, 0, len(values)) for q := range hist.Values { quants = append(quants, q) } sort.Strings(quants) for _, q := range quants { value := hist.Values[q] // The correct label is "quantile" but to not break old expressions // this remains "percentile" hist.Labels["percentile"] = model.LabelValue(q) f.Metric = append(f.Metric, &dto.Metric{ Label: protoLabelSet(e.BaseLabels, hist.Labels), Untyped: &dto.Untyped{ Value: proto.Float64(value), }, }) } } default: return fmt.Errorf("unknown metric type %q", e.Metric.Type) } } return nil }
func (r *registry) checkConsistency(metricFamily *dto.MetricFamily, dtoMetric *dto.Metric, desc *Desc, metricHashes map[uint64]struct{}) error { // Type consistency with metric family. if metricFamily.GetType() == dto.MetricType_GAUGE && dtoMetric.Gauge == nil || metricFamily.GetType() == dto.MetricType_COUNTER && dtoMetric.Counter == nil || metricFamily.GetType() == dto.MetricType_SUMMARY && dtoMetric.Summary == nil || metricFamily.GetType() == dto.MetricType_HISTOGRAM && dtoMetric.Histogram == nil || metricFamily.GetType() == dto.MetricType_UNTYPED && dtoMetric.Untyped == nil { return fmt.Errorf( "collected metric %s %s is not a %s", metricFamily.GetName(), dtoMetric, metricFamily.GetType(), ) } // Is the metric unique (i.e. no other metric with the same name and the same label values)? h := fnv.New64a() var buf bytes.Buffer buf.WriteString(metricFamily.GetName()) buf.WriteByte(separatorByte) h.Write(buf.Bytes()) // Make sure label pairs are sorted. We depend on it for the consistency // check. Label pairs must be sorted by contract. But the point of this // method is to check for contract violations. So we better do the sort // now. sort.Sort(LabelPairSorter(dtoMetric.Label)) for _, lp := range dtoMetric.Label { buf.Reset() buf.WriteString(lp.GetValue()) buf.WriteByte(separatorByte) h.Write(buf.Bytes()) } metricHash := h.Sum64() if _, exists := metricHashes[metricHash]; exists { return fmt.Errorf( "collected metric %s %s was collected before with the same name and label values", metricFamily.GetName(), dtoMetric, ) } metricHashes[metricHash] = struct{}{} if desc == nil { return nil // Nothing left to check if we have no desc. } // Desc consistency with metric family. if metricFamily.GetName() != desc.fqName { return fmt.Errorf( "collected metric %s %s has name %q but should have %q", metricFamily.GetName(), dtoMetric, metricFamily.GetName(), desc.fqName, ) } if metricFamily.GetHelp() != desc.help { return fmt.Errorf( "collected metric %s %s has help %q but should have %q", metricFamily.GetName(), dtoMetric, metricFamily.GetHelp(), desc.help, ) } // Is the desc consistent with the content of the metric? lpsFromDesc := make([]*dto.LabelPair, 0, len(dtoMetric.Label)) lpsFromDesc = append(lpsFromDesc, desc.constLabelPairs...) for _, l := range desc.variableLabels { lpsFromDesc = append(lpsFromDesc, &dto.LabelPair{ Name: proto.String(l), }) } if len(lpsFromDesc) != len(dtoMetric.Label) { return fmt.Errorf( "labels in collected metric %s %s are inconsistent with descriptor %s", metricFamily.GetName(), dtoMetric, desc, ) } sort.Sort(LabelPairSorter(lpsFromDesc)) for i, lpFromDesc := range lpsFromDesc { lpFromMetric := dtoMetric.Label[i] if lpFromDesc.GetName() != lpFromMetric.GetName() || lpFromDesc.Value != nil && lpFromDesc.GetValue() != lpFromMetric.GetValue() { return fmt.Errorf( "labels in collected metric %s %s are inconsistent with descriptor %s", metricFamily.GetName(), dtoMetric, desc, ) } } r.mtx.RLock() // Remaining checks need the read lock. defer r.mtx.RUnlock() // Is the desc registered? if _, exist := r.descIDs[desc.id]; !exist { return fmt.Errorf( "collected metric %s %s with unregistered descriptor %s", metricFamily.GetName(), dtoMetric, desc, ) } return nil }
func (r *registry) writePB(encoder expfmt.Encoder) error { var metricHashes map[uint64]struct{} if r.collectChecksEnabled { metricHashes = make(map[uint64]struct{}) } metricChan := make(chan Metric, capMetricChan) wg := sync.WaitGroup{} r.mtx.RLock() metricFamiliesByName := make(map[string]*dto.MetricFamily, len(r.dimHashesByName)) // Scatter. // (Collectors could be complex and slow, so we call them all at once.) wg.Add(len(r.collectorsByID)) go func() { wg.Wait() close(metricChan) }() for _, collector := range r.collectorsByID { go func(collector Collector) { defer wg.Done() collector.Collect(metricChan) }(collector) } r.mtx.RUnlock() // Drain metricChan in case of premature return. defer func() { for _ = range metricChan { } }() // Gather. for metric := range metricChan { // This could be done concurrently, too, but it required locking // of metricFamiliesByName (and of metricHashes if checks are // enabled). Most likely not worth it. desc := metric.Desc() metricFamily, ok := metricFamiliesByName[desc.fqName] if !ok { metricFamily = r.getMetricFamily() defer r.giveMetricFamily(metricFamily) metricFamily.Name = proto.String(desc.fqName) metricFamily.Help = proto.String(desc.help) metricFamiliesByName[desc.fqName] = metricFamily } dtoMetric := r.getMetric() defer r.giveMetric(dtoMetric) if err := metric.Write(dtoMetric); err != nil { // TODO: Consider different means of error reporting so // that a single erroneous metric could be skipped // instead of blowing up the whole collection. return fmt.Errorf("error collecting metric %v: %s", desc, err) } switch { case metricFamily.Type != nil: // Type already set. We are good. case dtoMetric.Gauge != nil: metricFamily.Type = dto.MetricType_GAUGE.Enum() case dtoMetric.Counter != nil: metricFamily.Type = dto.MetricType_COUNTER.Enum() case dtoMetric.Summary != nil: metricFamily.Type = dto.MetricType_SUMMARY.Enum() case dtoMetric.Untyped != nil: metricFamily.Type = dto.MetricType_UNTYPED.Enum() case dtoMetric.Histogram != nil: metricFamily.Type = dto.MetricType_HISTOGRAM.Enum() default: return fmt.Errorf("empty metric collected: %s", dtoMetric) } if r.collectChecksEnabled { if err := r.checkConsistency(metricFamily, dtoMetric, desc, metricHashes); err != nil { return err } } metricFamily.Metric = append(metricFamily.Metric, dtoMetric) } if r.metricFamilyInjectionHook != nil { for _, mf := range r.metricFamilyInjectionHook() { existingMF, exists := metricFamiliesByName[mf.GetName()] if !exists { metricFamiliesByName[mf.GetName()] = mf if r.collectChecksEnabled { for _, m := range mf.Metric { if err := r.checkConsistency(mf, m, nil, metricHashes); err != nil { return err } } } continue } for _, m := range mf.Metric { if r.collectChecksEnabled { if err := r.checkConsistency(existingMF, m, nil, metricHashes); err != nil { return err } } existingMF.Metric = append(existingMF.Metric, m) } } } // Now that MetricFamilies are all set, sort their Metrics // lexicographically by their label values. for _, mf := range metricFamiliesByName { sort.Sort(metricSorter(mf.Metric)) } // Write out MetricFamilies sorted by their name. names := make([]string, 0, len(metricFamiliesByName)) for name := range metricFamiliesByName { names = append(names, name) } sort.Strings(names) for _, name := range names { if err := encoder.Encode(metricFamiliesByName[name]); err != nil { return err } } return nil }
// NewDesc allocates and initializes a new Desc. Errors are recorded in the Desc // and will be reported on registration time. variableLabels and constLabels can // be nil if no such labels should be set. fqName and help must not be empty. // // variableLabels only contain the label names. Their label values are variable // and therefore not part of the Desc. (They are managed within the Metric.) // // For constLabels, the label values are constant. Therefore, they are fully // specified in the Desc. See the Opts documentation for the implications of // constant labels. func NewDesc(fqName, help string, variableLabels []string, constLabels Labels) *Desc { d := &Desc{ fqName: fqName, help: help, variableLabels: variableLabels, } if help == "" { d.err = errors.New("empty help string") return d } if !metricNameRE.MatchString(fqName) { d.err = fmt.Errorf("%q is not a valid metric name", fqName) return d } // labelValues contains the label values of const labels (in order of // their sorted label names) plus the fqName (at position 0). labelValues := make([]string, 1, len(constLabels)+1) labelValues[0] = fqName labelNames := make([]string, 0, len(constLabels)+len(variableLabels)) labelNameSet := map[string]struct{}{} // First add only the const label names and sort them... for labelName := range constLabels { if !checkLabelName(labelName) { d.err = fmt.Errorf("%q is not a valid label name", labelName) return d } labelNames = append(labelNames, labelName) labelNameSet[labelName] = struct{}{} } sort.Strings(labelNames) // ... so that we can now add const label values in the order of their names. for _, labelName := range labelNames { labelValues = append(labelValues, constLabels[labelName]) } // Now add the variable label names, but prefix them with something that // cannot be in a regular label name. That prevents matching the label // dimension with a different mix between preset and variable labels. for _, labelName := range variableLabels { if !checkLabelName(labelName) { d.err = fmt.Errorf("%q is not a valid label name", labelName) return d } labelNames = append(labelNames, "$"+labelName) labelNameSet[labelName] = struct{}{} } if len(labelNames) != len(labelNameSet) { d.err = errors.New("duplicate label names") return d } h := fnv.New64a() var b bytes.Buffer // To copy string contents into, avoiding []byte allocations. for _, val := range labelValues { b.Reset() b.WriteString(val) b.WriteByte(separatorByte) h.Write(b.Bytes()) } d.id = h.Sum64() // Sort labelNames so that order doesn't matter for the hash. sort.Strings(labelNames) // Now hash together (in this order) the help string and the sorted // label names. h.Reset() b.Reset() b.WriteString(help) b.WriteByte(separatorByte) h.Write(b.Bytes()) for _, labelName := range labelNames { b.Reset() b.WriteString(labelName) b.WriteByte(separatorByte) h.Write(b.Bytes()) } d.dimHash = h.Sum64() d.constLabelPairs = make([]*dto.LabelPair, 0, len(constLabels)) for n, v := range constLabels { d.constLabelPairs = append(d.constLabelPairs, &dto.LabelPair{ Name: proto.String(n), Value: proto.String(v), }) } sort.Sort(LabelPairSorter(d.constLabelPairs)) return d }