func populateMetric( t ValueType, v float64, labelPairs []*dto.LabelPair, m *dto.Metric, ) error { m.Label = labelPairs switch t { case CounterValue: m.Counter = &dto.Counter{Value: proto.Float64(v)} case GaugeValue: m.Gauge = &dto.Gauge{Value: proto.Float64(v)} case UntypedValue: m.Untyped = &dto.Untyped{Value: proto.Float64(v)} default: return fmt.Errorf("encountered unknown type %v", t) } return nil }
func (s *summary) Write(out *dto.Metric) error { sum := &dto.Summary{} qs := make([]*dto.Quantile, 0, len(s.objectives)) s.bufMtx.Lock() s.mtx.Lock() // Swap bufs even if hotBuf is empty to set new hotBufExpTime. s.swapBufs(time.Now()) s.bufMtx.Unlock() s.flushColdBuf() sum.SampleCount = proto.Uint64(s.cnt) sum.SampleSum = proto.Float64(s.sum) for _, rank := range s.sortedObjectives { var q float64 if s.headStream.Count() == 0 { q = math.NaN() } else { q = s.headStream.Query(rank) } qs = append(qs, &dto.Quantile{ Quantile: proto.Float64(rank), Value: proto.Float64(q), }) } s.mtx.Unlock() if len(qs) > 0 { sort.Sort(quantSort(qs)) } sum.Quantile = qs out.Summary = sum out.Label = s.labelPairs return nil }
func (s *constSummary) Write(out *dto.Metric) error { sum := &dto.Summary{} qs := make([]*dto.Quantile, 0, len(s.quantiles)) sum.SampleCount = proto.Uint64(s.count) sum.SampleSum = proto.Float64(s.sum) for rank, q := range s.quantiles { qs = append(qs, &dto.Quantile{ Quantile: proto.Float64(rank), Value: proto.Float64(q), }) } if len(qs) > 0 { sort.Sort(quantSort(qs)) } sum.Quantile = qs out.Summary = sum out.Label = s.labelPairs return nil }
func TestJSON2Decode(t *testing.T) { f, err := os.Open("testdata/json2") if err != nil { t.Fatal(err) } defer f.Close() dec := newJSON2Decoder(f) var v1 dto.MetricFamily if err := dec.Decode(&v1); err != nil { t.Fatal(err) } exp1 := dto.MetricFamily{ Type: dto.MetricType_UNTYPED.Enum(), Help: proto.String("RPC calls."), Name: proto.String("rpc_calls_total"), Metric: []*dto.Metric{ { Label: []*dto.LabelPair{ { Name: proto.String("job"), Value: proto.String("batch_job"), }, { Name: proto.String("service"), Value: proto.String("zed"), }, }, Untyped: &dto.Untyped{ Value: proto.Float64(25), }, }, { Label: []*dto.LabelPair{ { Name: proto.String("job"), Value: proto.String("batch_job"), }, { Name: proto.String("service"), Value: proto.String("bar"), }, }, Untyped: &dto.Untyped{ Value: proto.Float64(24), }, }, }, } if !reflect.DeepEqual(v1, exp1) { t.Fatalf("Expected %v, got %v", exp1, v1) } var v2 dto.MetricFamily if err := dec.Decode(&v2); err != nil { t.Fatal(err) } exp2 := dto.MetricFamily{ Type: dto.MetricType_UNTYPED.Enum(), Help: proto.String("RPC latency."), Name: proto.String("rpc_latency_microseconds"), Metric: []*dto.Metric{ { Label: []*dto.LabelPair{ { Name: proto.String("percentile"), Value: proto.String("0.010000"), }, { Name: proto.String("service"), Value: proto.String("foo"), }, }, Untyped: &dto.Untyped{ Value: proto.Float64(15), }, }, { Label: []*dto.LabelPair{ { Name: proto.String("percentile"), Value: proto.String("0.990000"), }, { Name: proto.String("service"), Value: proto.String("foo"), }, }, Untyped: &dto.Untyped{ Value: proto.Float64(17), }, }, }, } if !reflect.DeepEqual(v2, exp2) { t.Fatalf("Expected %v, got %v", exp2, v2) } }
func testHandler(t testing.TB) { metricVec := NewCounterVec( CounterOpts{ Name: "name", Help: "docstring", ConstLabels: Labels{"constname": "constvalue"}, }, []string{"labelname"}, ) metricVec.WithLabelValues("val1").Inc() metricVec.WithLabelValues("val2").Inc() varintBuf := make([]byte, binary.MaxVarintLen32) externalMetricFamily := &dto.MetricFamily{ Name: proto.String("externalname"), Help: proto.String("externaldocstring"), Type: dto.MetricType_COUNTER.Enum(), Metric: []*dto.Metric{ { Label: []*dto.LabelPair{ { Name: proto.String("externalconstname"), Value: proto.String("externalconstvalue"), }, { Name: proto.String("externallabelname"), Value: proto.String("externalval1"), }, }, Counter: &dto.Counter{ Value: proto.Float64(1), }, }, }, } marshaledExternalMetricFamily, err := proto.Marshal(externalMetricFamily) if err != nil { t.Fatal(err) } var externalBuf bytes.Buffer l := binary.PutUvarint(varintBuf, uint64(len(marshaledExternalMetricFamily))) _, err = externalBuf.Write(varintBuf[:l]) if err != nil { t.Fatal(err) } _, err = externalBuf.Write(marshaledExternalMetricFamily) if err != nil { t.Fatal(err) } externalMetricFamilyAsBytes := externalBuf.Bytes() externalMetricFamilyAsText := []byte(`# HELP externalname externaldocstring # TYPE externalname counter externalname{externalconstname="externalconstvalue",externallabelname="externalval1"} 1 `) externalMetricFamilyAsProtoText := []byte(`name: "externalname" help: "externaldocstring" type: COUNTER metric: < label: < name: "externalconstname" value: "externalconstvalue" > label: < name: "externallabelname" value: "externalval1" > counter: < value: 1 > > `) externalMetricFamilyAsProtoCompactText := []byte(`name:"externalname" help:"externaldocstring" type:COUNTER metric:<label:<name:"externalconstname" value:"externalconstvalue" > label:<name:"externallabelname" value:"externalval1" > counter:<value:1 > > `) expectedMetricFamily := &dto.MetricFamily{ Name: proto.String("name"), Help: proto.String("docstring"), Type: dto.MetricType_COUNTER.Enum(), Metric: []*dto.Metric{ { Label: []*dto.LabelPair{ { Name: proto.String("constname"), Value: proto.String("constvalue"), }, { Name: proto.String("labelname"), Value: proto.String("val1"), }, }, Counter: &dto.Counter{ Value: proto.Float64(1), }, }, { Label: []*dto.LabelPair{ { Name: proto.String("constname"), Value: proto.String("constvalue"), }, { Name: proto.String("labelname"), Value: proto.String("val2"), }, }, Counter: &dto.Counter{ Value: proto.Float64(1), }, }, }, } marshaledExpectedMetricFamily, err := proto.Marshal(expectedMetricFamily) if err != nil { t.Fatal(err) } var buf bytes.Buffer l = binary.PutUvarint(varintBuf, uint64(len(marshaledExpectedMetricFamily))) _, err = buf.Write(varintBuf[:l]) if err != nil { t.Fatal(err) } _, err = buf.Write(marshaledExpectedMetricFamily) if err != nil { t.Fatal(err) } expectedMetricFamilyAsBytes := buf.Bytes() expectedMetricFamilyAsText := []byte(`# HELP name docstring # TYPE name counter name{constname="constvalue",labelname="val1"} 1 name{constname="constvalue",labelname="val2"} 1 `) expectedMetricFamilyAsProtoText := []byte(`name: "name" help: "docstring" type: COUNTER metric: < label: < name: "constname" value: "constvalue" > label: < name: "labelname" value: "val1" > counter: < value: 1 > > metric: < label: < name: "constname" value: "constvalue" > label: < name: "labelname" value: "val2" > counter: < value: 1 > > `) expectedMetricFamilyAsProtoCompactText := []byte(`name:"name" help:"docstring" type:COUNTER metric:<label:<name:"constname" value:"constvalue" > label:<name:"labelname" value:"val1" > counter:<value:1 > > metric:<label:<name:"constname" value:"constvalue" > label:<name:"labelname" value:"val2" > counter:<value:1 > > `) externalMetricFamilyWithSameName := &dto.MetricFamily{ Name: proto.String("name"), Help: proto.String("inconsistent help string does not matter here"), Type: dto.MetricType_COUNTER.Enum(), Metric: []*dto.Metric{ { Label: []*dto.LabelPair{ { Name: proto.String("constname"), Value: proto.String("constvalue"), }, { Name: proto.String("labelname"), Value: proto.String("different_val"), }, }, Counter: &dto.Counter{ Value: proto.Float64(42), }, }, }, } expectedMetricFamilyMergedWithExternalAsProtoCompactText := []byte(`name:"name" help:"docstring" type:COUNTER metric:<label:<name:"constname" value:"constvalue" > label:<name:"labelname" value:"different_val" > counter:<value:42 > > metric:<label:<name:"constname" value:"constvalue" > label:<name:"labelname" value:"val1" > counter:<value:1 > > metric:<label:<name:"constname" value:"constvalue" > label:<name:"labelname" value:"val2" > counter:<value:1 > > `) type output struct { headers map[string]string body []byte } var scenarios = []struct { headers map[string]string out output collector Collector externalMF []*dto.MetricFamily }{ { // 0 headers: map[string]string{ "Accept": "foo/bar;q=0.2, dings/bums;q=0.8", }, out: output{ headers: map[string]string{ "Content-Type": `text/plain; version=0.0.4`, }, body: []byte{}, }, }, { // 1 headers: map[string]string{ "Accept": "foo/bar;q=0.2, application/quark;q=0.8", }, out: output{ headers: map[string]string{ "Content-Type": `text/plain; version=0.0.4`, }, body: []byte{}, }, }, { // 2 headers: map[string]string{ "Accept": "foo/bar;q=0.2, application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=bla;q=0.8", }, out: output{ headers: map[string]string{ "Content-Type": `text/plain; version=0.0.4`, }, body: []byte{}, }, }, { // 3 headers: map[string]string{ "Accept": "text/plain;q=0.2, application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=delimited;q=0.8", }, out: output{ headers: map[string]string{ "Content-Type": `application/vnd.google.protobuf; proto=io.prometheus.client.MetricFamily; encoding=delimited`, }, body: []byte{}, }, }, { // 4 headers: map[string]string{ "Accept": "application/json", }, out: output{ headers: map[string]string{ "Content-Type": `text/plain; version=0.0.4`, }, body: expectedMetricFamilyAsText, }, collector: metricVec, }, { // 5 headers: map[string]string{ "Accept": "application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=delimited", }, out: output{ headers: map[string]string{ "Content-Type": `application/vnd.google.protobuf; proto=io.prometheus.client.MetricFamily; encoding=delimited`, }, body: expectedMetricFamilyAsBytes, }, collector: metricVec, }, { // 6 headers: map[string]string{ "Accept": "application/json", }, out: output{ headers: map[string]string{ "Content-Type": `text/plain; version=0.0.4`, }, body: externalMetricFamilyAsText, }, externalMF: []*dto.MetricFamily{externalMetricFamily}, }, { // 7 headers: map[string]string{ "Accept": "application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=delimited", }, out: output{ headers: map[string]string{ "Content-Type": `application/vnd.google.protobuf; proto=io.prometheus.client.MetricFamily; encoding=delimited`, }, body: externalMetricFamilyAsBytes, }, externalMF: []*dto.MetricFamily{externalMetricFamily}, }, { // 8 headers: map[string]string{ "Accept": "application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=delimited", }, out: output{ headers: map[string]string{ "Content-Type": `application/vnd.google.protobuf; proto=io.prometheus.client.MetricFamily; encoding=delimited`, }, body: bytes.Join( [][]byte{ externalMetricFamilyAsBytes, expectedMetricFamilyAsBytes, }, []byte{}, ), }, collector: metricVec, externalMF: []*dto.MetricFamily{externalMetricFamily}, }, { // 9 headers: map[string]string{ "Accept": "text/plain", }, out: output{ headers: map[string]string{ "Content-Type": `text/plain; version=0.0.4`, }, body: []byte{}, }, }, { // 10 headers: map[string]string{ "Accept": "application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=bla;q=0.2, text/plain;q=0.5", }, out: output{ headers: map[string]string{ "Content-Type": `text/plain; version=0.0.4`, }, body: expectedMetricFamilyAsText, }, collector: metricVec, }, { // 11 headers: map[string]string{ "Accept": "application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=bla;q=0.2, text/plain;q=0.5;version=0.0.4", }, out: output{ headers: map[string]string{ "Content-Type": `text/plain; version=0.0.4`, }, body: bytes.Join( [][]byte{ externalMetricFamilyAsText, expectedMetricFamilyAsText, }, []byte{}, ), }, collector: metricVec, externalMF: []*dto.MetricFamily{externalMetricFamily}, }, { // 12 headers: map[string]string{ "Accept": "application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=delimited;q=0.2, text/plain;q=0.5;version=0.0.2", }, out: output{ headers: map[string]string{ "Content-Type": `application/vnd.google.protobuf; proto=io.prometheus.client.MetricFamily; encoding=delimited`, }, body: bytes.Join( [][]byte{ externalMetricFamilyAsBytes, expectedMetricFamilyAsBytes, }, []byte{}, ), }, collector: metricVec, externalMF: []*dto.MetricFamily{externalMetricFamily}, }, { // 13 headers: map[string]string{ "Accept": "application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=text;q=0.5, application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=delimited;q=0.4", }, out: output{ headers: map[string]string{ "Content-Type": `application/vnd.google.protobuf; proto=io.prometheus.client.MetricFamily; encoding=text`, }, body: bytes.Join( [][]byte{ externalMetricFamilyAsProtoText, expectedMetricFamilyAsProtoText, }, []byte{}, ), }, collector: metricVec, externalMF: []*dto.MetricFamily{externalMetricFamily}, }, { // 14 headers: map[string]string{ "Accept": "application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=compact-text", }, out: output{ headers: map[string]string{ "Content-Type": `application/vnd.google.protobuf; proto=io.prometheus.client.MetricFamily; encoding=compact-text`, }, body: bytes.Join( [][]byte{ externalMetricFamilyAsProtoCompactText, expectedMetricFamilyAsProtoCompactText, }, []byte{}, ), }, collector: metricVec, externalMF: []*dto.MetricFamily{externalMetricFamily}, }, { // 15 headers: map[string]string{ "Accept": "application/vnd.google.protobuf;proto=io.prometheus.client.MetricFamily;encoding=compact-text", }, out: output{ headers: map[string]string{ "Content-Type": `application/vnd.google.protobuf; proto=io.prometheus.client.MetricFamily; encoding=compact-text`, }, body: bytes.Join( [][]byte{ externalMetricFamilyAsProtoCompactText, expectedMetricFamilyMergedWithExternalAsProtoCompactText, }, []byte{}, ), }, collector: metricVec, externalMF: []*dto.MetricFamily{ externalMetricFamily, externalMetricFamilyWithSameName, }, }, } for i, scenario := range scenarios { registry := newRegistry() registry.collectChecksEnabled = true if scenario.collector != nil { registry.Register(scenario.collector) } if scenario.externalMF != nil { registry.metricFamilyInjectionHook = func() []*dto.MetricFamily { return scenario.externalMF } } writer := &fakeResponseWriter{ header: http.Header{}, } handler := InstrumentHandler("prometheus", registry) request, _ := http.NewRequest("GET", "/", nil) for key, value := range scenario.headers { request.Header.Add(key, value) } handler(writer, request) for key, value := range scenario.out.headers { if writer.Header().Get(key) != value { t.Errorf( "%d. expected %q for header %q, got %q", i, value, key, writer.Header().Get(key), ) } } if !bytes.Equal(scenario.out.body, writer.body.Bytes()) { t.Errorf( "%d. expected %q for body, got %q", i, scenario.out.body, writer.body.Bytes(), ) } } }
GroupField: proto.Int32(6), }, RepBytes: [][]byte{[]byte("sham"), []byte("wow")}, }, }, // Check that a scalar bytes field replaces rather than appends. { src: &pb.OtherMessage{Value: []byte("foo")}, dst: &pb.OtherMessage{Value: []byte("bar")}, want: &pb.OtherMessage{Value: []byte("foo")}, }, { src: &pb.MessageWithMap{ NameMapping: map[int32]string{6: "Nigel"}, MsgMapping: map[int64]*pb.FloatingPoint{ 0x4001: &pb.FloatingPoint{F: proto.Float64(2.0)}, }, ByteMapping: map[bool][]byte{true: []byte("wowsa")}, }, dst: &pb.MessageWithMap{ NameMapping: map[int32]string{ 6: "Bruce", // should be overwritten 7: "Andrew", }, }, want: &pb.MessageWithMap{ NameMapping: map[int32]string{ 6: "Nigel", 7: "Andrew", }, MsgMapping: map[int64]*pb.FloatingPoint{
func testCreateError(t testing.TB) { var scenarios = []struct { in *dto.MetricFamily err string }{ // 0: No metric. { in: &dto.MetricFamily{ Name: proto.String("name"), Help: proto.String("doc string"), Type: dto.MetricType_COUNTER.Enum(), Metric: []*dto.Metric{}, }, err: "MetricFamily has no metrics", }, // 1: No metric name. { in: &dto.MetricFamily{ Help: proto.String("doc string"), Type: dto.MetricType_UNTYPED.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Untyped: &dto.Untyped{ Value: proto.Float64(math.Inf(-1)), }, }, }, }, err: "MetricFamily has no name", }, // 2: Wrong type. { in: &dto.MetricFamily{ Name: proto.String("name"), Help: proto.String("doc string"), Type: dto.MetricType_COUNTER.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Untyped: &dto.Untyped{ Value: proto.Float64(math.Inf(-1)), }, }, }, }, err: "expected counter in metric", }, } for i, scenario := range scenarios { var out bytes.Buffer _, err := MetricFamilyToText(&out, scenario.in) if err == nil { t.Errorf("%d. expected error, got nil", i) continue } if expected, got := scenario.err, err.Error(); strings.Index(got, expected) != 0 { t.Errorf( "%d. expected error starting with %q, got %q", i, expected, got, ) } } }
func testCreate(t testing.TB) { var scenarios = []struct { in *dto.MetricFamily out string }{ // 0: Counter, NaN as value, timestamp given. { in: &dto.MetricFamily{ Name: proto.String("name"), Help: proto.String("two-line\n doc str\\ing"), Type: dto.MetricType_COUNTER.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("labelname"), Value: proto.String("val1"), }, &dto.LabelPair{ Name: proto.String("basename"), Value: proto.String("basevalue"), }, }, Counter: &dto.Counter{ Value: proto.Float64(math.NaN()), }, }, &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("labelname"), Value: proto.String("val2"), }, &dto.LabelPair{ Name: proto.String("basename"), Value: proto.String("basevalue"), }, }, Counter: &dto.Counter{ Value: proto.Float64(.23), }, TimestampMs: proto.Int64(1234567890), }, }, }, out: `# HELP name two-line\n doc str\\ing # TYPE name counter name{labelname="val1",basename="basevalue"} NaN name{labelname="val2",basename="basevalue"} 0.23 1234567890 `, }, // 1: Gauge, some escaping required, +Inf as value, multi-byte characters in label values. { in: &dto.MetricFamily{ Name: proto.String("gauge_name"), Help: proto.String("gauge\ndoc\nstr\"ing"), Type: dto.MetricType_GAUGE.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("name_1"), Value: proto.String("val with\nnew line"), }, &dto.LabelPair{ Name: proto.String("name_2"), Value: proto.String("val with \\backslash and \"quotes\""), }, }, Gauge: &dto.Gauge{ Value: proto.Float64(math.Inf(+1)), }, }, &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("name_1"), Value: proto.String("Björn"), }, &dto.LabelPair{ Name: proto.String("name_2"), Value: proto.String("佖佥"), }, }, Gauge: &dto.Gauge{ Value: proto.Float64(3.14E42), }, }, }, }, out: `# HELP gauge_name gauge\ndoc\nstr"ing # TYPE gauge_name gauge gauge_name{name_1="val with\nnew line",name_2="val with \\backslash and \"quotes\""} +Inf gauge_name{name_1="Björn",name_2="佖佥"} 3.14e+42 `, }, // 2: Untyped, no help, one sample with no labels and -Inf as value, another sample with one label. { in: &dto.MetricFamily{ Name: proto.String("untyped_name"), Type: dto.MetricType_UNTYPED.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Untyped: &dto.Untyped{ Value: proto.Float64(math.Inf(-1)), }, }, &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("name_1"), Value: proto.String("value 1"), }, }, Untyped: &dto.Untyped{ Value: proto.Float64(-1.23e-45), }, }, }, }, out: `# TYPE untyped_name untyped untyped_name -Inf untyped_name{name_1="value 1"} -1.23e-45 `, }, // 3: Summary. { in: &dto.MetricFamily{ Name: proto.String("summary_name"), Help: proto.String("summary docstring"), Type: dto.MetricType_SUMMARY.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Summary: &dto.Summary{ SampleCount: proto.Uint64(42), SampleSum: proto.Float64(-3.4567), Quantile: []*dto.Quantile{ &dto.Quantile{ Quantile: proto.Float64(0.5), Value: proto.Float64(-1.23), }, &dto.Quantile{ Quantile: proto.Float64(0.9), Value: proto.Float64(.2342354), }, &dto.Quantile{ Quantile: proto.Float64(0.99), Value: proto.Float64(0), }, }, }, }, &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("name_1"), Value: proto.String("value 1"), }, &dto.LabelPair{ Name: proto.String("name_2"), Value: proto.String("value 2"), }, }, Summary: &dto.Summary{ SampleCount: proto.Uint64(4711), SampleSum: proto.Float64(2010.1971), Quantile: []*dto.Quantile{ &dto.Quantile{ Quantile: proto.Float64(0.5), Value: proto.Float64(1), }, &dto.Quantile{ Quantile: proto.Float64(0.9), Value: proto.Float64(2), }, &dto.Quantile{ Quantile: proto.Float64(0.99), Value: proto.Float64(3), }, }, }, }, }, }, out: `# HELP summary_name summary docstring # TYPE summary_name summary summary_name{quantile="0.5"} -1.23 summary_name{quantile="0.9"} 0.2342354 summary_name{quantile="0.99"} 0 summary_name_sum -3.4567 summary_name_count 42 summary_name{name_1="value 1",name_2="value 2",quantile="0.5"} 1 summary_name{name_1="value 1",name_2="value 2",quantile="0.9"} 2 summary_name{name_1="value 1",name_2="value 2",quantile="0.99"} 3 summary_name_sum{name_1="value 1",name_2="value 2"} 2010.1971 summary_name_count{name_1="value 1",name_2="value 2"} 4711 `, }, // 4: Histogram { in: &dto.MetricFamily{ Name: proto.String("request_duration_microseconds"), Help: proto.String("The response latency."), Type: dto.MetricType_HISTOGRAM.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Histogram: &dto.Histogram{ SampleCount: proto.Uint64(2693), SampleSum: proto.Float64(1756047.3), Bucket: []*dto.Bucket{ &dto.Bucket{ UpperBound: proto.Float64(100), CumulativeCount: proto.Uint64(123), }, &dto.Bucket{ UpperBound: proto.Float64(120), CumulativeCount: proto.Uint64(412), }, &dto.Bucket{ UpperBound: proto.Float64(144), CumulativeCount: proto.Uint64(592), }, &dto.Bucket{ UpperBound: proto.Float64(172.8), CumulativeCount: proto.Uint64(1524), }, &dto.Bucket{ UpperBound: proto.Float64(math.Inf(+1)), CumulativeCount: proto.Uint64(2693), }, }, }, }, }, }, out: `# HELP request_duration_microseconds The response latency. # TYPE request_duration_microseconds histogram request_duration_microseconds_bucket{le="100"} 123 request_duration_microseconds_bucket{le="120"} 412 request_duration_microseconds_bucket{le="144"} 592 request_duration_microseconds_bucket{le="172.8"} 1524 request_duration_microseconds_bucket{le="+Inf"} 2693 request_duration_microseconds_sum 1.7560473e+06 request_duration_microseconds_count 2693 `, }, // 5: Histogram with missing +Inf bucket. { in: &dto.MetricFamily{ Name: proto.String("request_duration_microseconds"), Help: proto.String("The response latency."), Type: dto.MetricType_HISTOGRAM.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Histogram: &dto.Histogram{ SampleCount: proto.Uint64(2693), SampleSum: proto.Float64(1756047.3), Bucket: []*dto.Bucket{ &dto.Bucket{ UpperBound: proto.Float64(100), CumulativeCount: proto.Uint64(123), }, &dto.Bucket{ UpperBound: proto.Float64(120), CumulativeCount: proto.Uint64(412), }, &dto.Bucket{ UpperBound: proto.Float64(144), CumulativeCount: proto.Uint64(592), }, &dto.Bucket{ UpperBound: proto.Float64(172.8), CumulativeCount: proto.Uint64(1524), }, }, }, }, }, }, out: `# HELP request_duration_microseconds The response latency. # TYPE request_duration_microseconds histogram request_duration_microseconds_bucket{le="100"} 123 request_duration_microseconds_bucket{le="120"} 412 request_duration_microseconds_bucket{le="144"} 592 request_duration_microseconds_bucket{le="172.8"} 1524 request_duration_microseconds_bucket{le="+Inf"} 2693 request_duration_microseconds_sum 1.7560473e+06 request_duration_microseconds_count 2693 `, }, // 6: No metric type, should result in default type Counter. { in: &dto.MetricFamily{ Name: proto.String("name"), Help: proto.String("doc string"), Metric: []*dto.Metric{ &dto.Metric{ Counter: &dto.Counter{ Value: proto.Float64(math.Inf(-1)), }, }, }, }, out: `# HELP name doc string # TYPE name counter name -Inf `, }, } for i, scenario := range scenarios { out := bytes.NewBuffer(make([]byte, 0, len(scenario.out))) n, err := MetricFamilyToText(out, scenario.in) if err != nil { t.Errorf("%d. error: %s", i, err) continue } if expected, got := len(scenario.out), n; expected != got { t.Errorf( "%d. expected %d bytes written, got %d", i, expected, got, ) } if expected, got := scenario.out, out.String(); expected != got { t.Errorf( "%d. expected out=%q, got %q", i, expected, got, ) } } }
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 testTextParse(t testing.TB) { var scenarios = []struct { in string out []*dto.MetricFamily }{ // 0: Empty lines as input. { in: ` `, out: []*dto.MetricFamily{}, }, // 1: Minimal case. { in: ` minimal_metric 1.234 another_metric -3e3 103948 # Even that: no_labels{} 3 # HELP line for non-existing metric will be ignored. `, out: []*dto.MetricFamily{ &dto.MetricFamily{ Name: proto.String("minimal_metric"), Type: dto.MetricType_UNTYPED.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Untyped: &dto.Untyped{ Value: proto.Float64(1.234), }, }, }, }, &dto.MetricFamily{ Name: proto.String("another_metric"), Type: dto.MetricType_UNTYPED.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Untyped: &dto.Untyped{ Value: proto.Float64(-3e3), }, TimestampMs: proto.Int64(103948), }, }, }, &dto.MetricFamily{ Name: proto.String("no_labels"), Type: dto.MetricType_UNTYPED.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Untyped: &dto.Untyped{ Value: proto.Float64(3), }, }, }, }, }, }, // 2: Counters & gauges, docstrings, various whitespace, escape sequences. { in: ` # A normal comment. # # TYPE name counter name{labelname="val1",basename="basevalue"} NaN name {labelname="val2",basename="base\"v\\al\nue"} 0.23 1234567890 # HELP name two-line\n doc str\\ing # HELP name2 doc str"ing 2 # TYPE name2 gauge name2{labelname="val2" ,basename = "basevalue2" } +Inf 54321 name2{ labelname = "val1" , }-Inf `, out: []*dto.MetricFamily{ &dto.MetricFamily{ Name: proto.String("name"), Help: proto.String("two-line\n doc str\\ing"), Type: dto.MetricType_COUNTER.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("labelname"), Value: proto.String("val1"), }, &dto.LabelPair{ Name: proto.String("basename"), Value: proto.String("basevalue"), }, }, Counter: &dto.Counter{ Value: proto.Float64(math.NaN()), }, }, &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("labelname"), Value: proto.String("val2"), }, &dto.LabelPair{ Name: proto.String("basename"), Value: proto.String("base\"v\\al\nue"), }, }, Counter: &dto.Counter{ Value: proto.Float64(.23), }, TimestampMs: proto.Int64(1234567890), }, }, }, &dto.MetricFamily{ Name: proto.String("name2"), Help: proto.String("doc str\"ing 2"), Type: dto.MetricType_GAUGE.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("labelname"), Value: proto.String("val2"), }, &dto.LabelPair{ Name: proto.String("basename"), Value: proto.String("basevalue2"), }, }, Gauge: &dto.Gauge{ Value: proto.Float64(math.Inf(+1)), }, TimestampMs: proto.Int64(54321), }, &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("labelname"), Value: proto.String("val1"), }, }, Gauge: &dto.Gauge{ Value: proto.Float64(math.Inf(-1)), }, }, }, }, }, }, // 3: The evil summary, mixed with other types and funny comments. { in: ` # TYPE my_summary summary my_summary{n1="val1",quantile="0.5"} 110 decoy -1 -2 my_summary{n1="val1",quantile="0.9"} 140 1 my_summary_count{n1="val1"} 42 # Latest timestamp wins in case of a summary. my_summary_sum{n1="val1"} 4711 2 fake_sum{n1="val1"} 2001 # TYPE another_summary summary another_summary_count{n2="val2",n1="val1"} 20 my_summary_count{n2="val2",n1="val1"} 5 5 another_summary{n1="val1",n2="val2",quantile=".3"} -1.2 my_summary_sum{n1="val2"} 08 15 my_summary{n1="val3", quantile="0.2"} 4711 my_summary{n1="val1",n2="val2",quantile="-12.34",} NaN # some # funny comments # HELP # HELP # HELP my_summary # HELP my_summary `, out: []*dto.MetricFamily{ &dto.MetricFamily{ Name: proto.String("fake_sum"), Type: dto.MetricType_UNTYPED.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("n1"), Value: proto.String("val1"), }, }, Untyped: &dto.Untyped{ Value: proto.Float64(2001), }, }, }, }, &dto.MetricFamily{ Name: proto.String("decoy"), Type: dto.MetricType_UNTYPED.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Untyped: &dto.Untyped{ Value: proto.Float64(-1), }, TimestampMs: proto.Int64(-2), }, }, }, &dto.MetricFamily{ Name: proto.String("my_summary"), Type: dto.MetricType_SUMMARY.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("n1"), Value: proto.String("val1"), }, }, Summary: &dto.Summary{ SampleCount: proto.Uint64(42), SampleSum: proto.Float64(4711), Quantile: []*dto.Quantile{ &dto.Quantile{ Quantile: proto.Float64(0.5), Value: proto.Float64(110), }, &dto.Quantile{ Quantile: proto.Float64(0.9), Value: proto.Float64(140), }, }, }, TimestampMs: proto.Int64(2), }, &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("n2"), Value: proto.String("val2"), }, &dto.LabelPair{ Name: proto.String("n1"), Value: proto.String("val1"), }, }, Summary: &dto.Summary{ SampleCount: proto.Uint64(5), Quantile: []*dto.Quantile{ &dto.Quantile{ Quantile: proto.Float64(-12.34), Value: proto.Float64(math.NaN()), }, }, }, TimestampMs: proto.Int64(5), }, &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("n1"), Value: proto.String("val2"), }, }, Summary: &dto.Summary{ SampleSum: proto.Float64(8), }, TimestampMs: proto.Int64(15), }, &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("n1"), Value: proto.String("val3"), }, }, Summary: &dto.Summary{ Quantile: []*dto.Quantile{ &dto.Quantile{ Quantile: proto.Float64(0.2), Value: proto.Float64(4711), }, }, }, }, }, }, &dto.MetricFamily{ Name: proto.String("another_summary"), Type: dto.MetricType_SUMMARY.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Label: []*dto.LabelPair{ &dto.LabelPair{ Name: proto.String("n2"), Value: proto.String("val2"), }, &dto.LabelPair{ Name: proto.String("n1"), Value: proto.String("val1"), }, }, Summary: &dto.Summary{ SampleCount: proto.Uint64(20), Quantile: []*dto.Quantile{ &dto.Quantile{ Quantile: proto.Float64(0.3), Value: proto.Float64(-1.2), }, }, }, }, }, }, }, }, // 4: The histogram. { in: ` # HELP request_duration_microseconds The response latency. # TYPE request_duration_microseconds histogram request_duration_microseconds_bucket{le="100"} 123 request_duration_microseconds_bucket{le="120"} 412 request_duration_microseconds_bucket{le="144"} 592 request_duration_microseconds_bucket{le="172.8"} 1524 request_duration_microseconds_bucket{le="+Inf"} 2693 request_duration_microseconds_sum 1.7560473e+06 request_duration_microseconds_count 2693 `, out: []*dto.MetricFamily{ { Name: proto.String("request_duration_microseconds"), Help: proto.String("The response latency."), Type: dto.MetricType_HISTOGRAM.Enum(), Metric: []*dto.Metric{ &dto.Metric{ Histogram: &dto.Histogram{ SampleCount: proto.Uint64(2693), SampleSum: proto.Float64(1756047.3), Bucket: []*dto.Bucket{ &dto.Bucket{ UpperBound: proto.Float64(100), CumulativeCount: proto.Uint64(123), }, &dto.Bucket{ UpperBound: proto.Float64(120), CumulativeCount: proto.Uint64(412), }, &dto.Bucket{ UpperBound: proto.Float64(144), CumulativeCount: proto.Uint64(592), }, &dto.Bucket{ UpperBound: proto.Float64(172.8), CumulativeCount: proto.Uint64(1524), }, &dto.Bucket{ UpperBound: proto.Float64(math.Inf(+1)), CumulativeCount: proto.Uint64(2693), }, }, }, }, }, }, }, }, } for i, scenario := range scenarios { out, err := parser.TextToMetricFamilies(strings.NewReader(scenario.in)) if err != nil { t.Errorf("%d. error: %s", i, err) continue } if expected, got := len(scenario.out), len(out); expected != got { t.Errorf( "%d. expected %d MetricFamilies, got %d", i, expected, got, ) } for _, expected := range scenario.out { got, ok := out[expected.GetName()] if !ok { t.Errorf( "%d. expected MetricFamily %q, found none", i, expected.GetName(), ) continue } if expected.String() != got.String() { t.Errorf( "%d. expected MetricFamily %s, got %s", i, expected, got, ) } } } }
// readingValue represents the state where the last byte read (now in // p.currentByte) is the first byte of the sample value (i.e. a float). func (p *TextParser) readingValue() stateFn { // When we are here, we have read all the labels, so for the // special case of a summary/histogram, we can finally find out // if the metric already exists. if p.currentMF.GetType() == dto.MetricType_SUMMARY { signature := model.LabelsToSignature(p.currentLabels) if summary := p.summaries[signature]; summary != nil { p.currentMetric = summary } else { p.summaries[signature] = p.currentMetric p.currentMF.Metric = append(p.currentMF.Metric, p.currentMetric) } } else if p.currentMF.GetType() == dto.MetricType_HISTOGRAM { signature := model.LabelsToSignature(p.currentLabels) if histogram := p.histograms[signature]; histogram != nil { p.currentMetric = histogram } else { p.histograms[signature] = p.currentMetric p.currentMF.Metric = append(p.currentMF.Metric, p.currentMetric) } } else { p.currentMF.Metric = append(p.currentMF.Metric, p.currentMetric) } if p.readTokenUntilWhitespace(); p.err != nil { return nil // Unexpected end of input. } value, err := strconv.ParseFloat(p.currentToken.String(), 64) if err != nil { // Create a more helpful error message. p.parseError(fmt.Sprintf("expected float as value, got %q", p.currentToken.String())) return nil } switch p.currentMF.GetType() { case dto.MetricType_COUNTER: p.currentMetric.Counter = &dto.Counter{Value: proto.Float64(value)} case dto.MetricType_GAUGE: p.currentMetric.Gauge = &dto.Gauge{Value: proto.Float64(value)} case dto.MetricType_UNTYPED: p.currentMetric.Untyped = &dto.Untyped{Value: proto.Float64(value)} case dto.MetricType_SUMMARY: // *sigh* if p.currentMetric.Summary == nil { p.currentMetric.Summary = &dto.Summary{} } switch { case p.currentIsSummaryCount: p.currentMetric.Summary.SampleCount = proto.Uint64(uint64(value)) case p.currentIsSummarySum: p.currentMetric.Summary.SampleSum = proto.Float64(value) case !math.IsNaN(p.currentQuantile): p.currentMetric.Summary.Quantile = append( p.currentMetric.Summary.Quantile, &dto.Quantile{ Quantile: proto.Float64(p.currentQuantile), Value: proto.Float64(value), }, ) } case dto.MetricType_HISTOGRAM: // *sigh* if p.currentMetric.Histogram == nil { p.currentMetric.Histogram = &dto.Histogram{} } switch { case p.currentIsHistogramCount: p.currentMetric.Histogram.SampleCount = proto.Uint64(uint64(value)) case p.currentIsHistogramSum: p.currentMetric.Histogram.SampleSum = proto.Float64(value) case !math.IsNaN(p.currentBucket): p.currentMetric.Histogram.Bucket = append( p.currentMetric.Histogram.Bucket, &dto.Bucket{ UpperBound: proto.Float64(p.currentBucket), CumulativeCount: proto.Uint64(uint64(value)), }, ) } default: p.err = fmt.Errorf("unexpected type for metric name %q", p.currentMF.GetName()) } if p.currentByte == '\n' { return p.startOfLine } return p.startTimestamp }