Ejemplo n.º 1
0
func ExampleLabelPairSorter() {
	labelPairs := []*dto.LabelPair{
		&dto.LabelPair{Name: proto.String("status"), Value: proto.String("404")},
		&dto.LabelPair{Name: proto.String("method"), Value: proto.String("get")},
	}

	sort.Sort(prometheus.LabelPairSorter(labelPairs))

	fmt.Println(labelPairs)
	// Output:
	// [name:"method" value:"get"  name:"status" value:"404" ]
}
Ejemplo n.º 2
0
func TestStringEscaping(t *testing.T) {
	testCases := []struct {
		in  *pb.Strings
		out string
	}{
		{
			// Test data from C++ test (TextFormatTest.StringEscape).
			// Single divergence: we don't escape apostrophes.
			&pb.Strings{StringField: proto.String("\"A string with ' characters \n and \r newlines and \t tabs and \001 slashes \\ and  multiple   spaces")},
			"string_field: \"\\\"A string with ' characters \\n and \\r newlines and \\t tabs and \\001 slashes \\\\ and  multiple   spaces\"\n",
		},
		{
			// Test data from the same C++ test.
			&pb.Strings{StringField: proto.String("\350\260\267\346\255\214")},
			"string_field: \"\\350\\260\\267\\346\\255\\214\"\n",
		},
		{
			// Some UTF-8.
			&pb.Strings{StringField: proto.String("\x00\x01\xff\x81")},
			`string_field: "\000\001\377\201"` + "\n",
		},
	}

	for i, tc := range testCases {
		var buf bytes.Buffer
		if err := proto.MarshalText(&buf, tc.in); err != nil {
			t.Errorf("proto.MarsalText: %v", err)
			continue
		}
		s := buf.String()
		if s != tc.out {
			t.Errorf("#%d: Got:\n%s\nExpected:\n%s\n", i, s, tc.out)
			continue
		}

		// Check round-trip.
		pb := new(pb.Strings)
		if err := proto.UnmarshalText(s, pb); err != nil {
			t.Errorf("#%d: UnmarshalText: %v", i, err)
			continue
		}
		if !proto.Equal(pb, tc.in) {
			t.Errorf("#%d: Round-trip failed:\nstart: %v\n  end: %v", i, tc.in, pb)
		}
	}
}
Ejemplo n.º 3
0
func init() {
	ext := &pb.Ext{
		Data: proto.String("extension"),
	}
	if err := proto.SetExtension(cloneTestMessage, pb.E_Ext_More, ext); err != nil {
		panic("SetExtension: " + err.Error())
	}
}
Ejemplo n.º 4
0
// 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 *Parser) 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() == "quantile" {
			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() == "le" {
			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
	}
}
Ejemplo n.º 5
0
// readingHelp represents the state where the last byte read (now in
// p.currentByte) is the first byte of the docstring after 'HELP'.
func (p *Parser) 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
}
Ejemplo n.º 6
0
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
}
Ejemplo n.º 7
0
func newTestMessage() *pb.MyMessage {
	msg := &pb.MyMessage{
		Count: proto.Int32(42),
		Name:  proto.String("Dave"),
		Quote: proto.String(`"I didn't want to go."`),
		Pet:   []string{"bunny", "kitty", "horsey"},
		Inner: &pb.InnerMessage{
			Host:      proto.String("footrest.syd"),
			Port:      proto.Int32(7001),
			Connected: proto.Bool(true),
		},
		Others: []*pb.OtherMessage{
			{
				Key:   proto.Int64(0xdeadbeef),
				Value: []byte{1, 65, 7, 12},
			},
			{
				Weight: proto.Float32(6.022),
				Inner: &pb.InnerMessage{
					Host: proto.String("lesha.mtv"),
					Port: proto.Int32(8002),
				},
			},
		},
		Bikeshed: pb.MyMessage_BLUE.Enum(),
		Somegroup: &pb.MyMessage_SomeGroup{
			GroupField: proto.Int32(8),
		},
		// One normally wouldn't do this.
		// This is an undeclared tag 13, as a varint (wire type 0) with value 4.
		XXX_unrecognized: []byte{13<<3 | 0, 4},
	}
	ext := &pb.Ext{
		Data: proto.String("Big gobs for big rats"),
	}
	if err := proto.SetExtension(msg, pb.E_Ext_More, ext); err != nil {
		panic(err)
	}
	greetings := []string{"adg", "easy", "cow"}
	if err := proto.SetExtension(msg, pb.E_Greeting, greetings); err != nil {
		panic(err)
	}

	// Add an unknown extension. We marshal a pb.Ext, and fake the ID.
	b, err := proto.Marshal(&pb.Ext{Data: proto.String("3G skiing")})
	if err != nil {
		panic(err)
	}
	b = append(proto.EncodeVarint(201<<3|proto.WireBytes), b...)
	proto.SetRawExtension(msg, 201, b)

	// Extensions can be plain fields, too, so let's test that.
	b = append(proto.EncodeVarint(202<<3|proto.WireVarint), 19)
	proto.SetRawExtension(msg, 202, b)

	return msg
}
Ejemplo n.º 8
0
func TestRepeatedNilText(t *testing.T) {
	m := &pb.MessageList{
		Message: []*pb.MessageList_Message{
			nil,
			&pb.MessageList_Message{
				Name: proto.String("Horse"),
			},
			nil,
		},
	}
	want := `Message <nil>
Message {
  name: "Horse"
}
Message <nil>
`
	if s := proto.MarshalTextString(m); s != want {
		t.Errorf(" got: %s\nwant: %s", s, want)
	}
}
Ejemplo n.º 9
0
func (p *Parser) 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
}
Ejemplo n.º 10
0
// 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 *Parser) 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() == "quantile") &&
		!(p.currentMF.GetType() == dto.MetricType_HISTOGRAM && p.currentLabelPair.GetName() == "le") {
		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
}
Ejemplo n.º 11
0
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("externallabelname"),
							Value: proto.String("externalval1"),
						},
						{
							Name:  proto.String("externalconstname"),
							Value: proto.String("externalconstvalue"),
						},
					},
					Counter: &dto.Counter{
						Value: proto.Float64(1),
					},
				},
			},
		},
	}
	marshaledExternalMetricFamily, err := proto.Marshal(externalMetricFamily[0])
	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{externallabelname="externalval1",externalconstname="externalconstvalue"} 1
`)
	externalMetricFamilyAsProtoText := []byte(`name: "externalname"
help: "externaldocstring"
type: COUNTER
metric: <
  label: <
    name: "externallabelname"
    value: "externalval1"
  >
  label: <
    name: "externalconstname"
    value: "externalconstvalue"
  >
  counter: <
    value: 1
  >
>

`)
	externalMetricFamilyAsProtoCompactText := []byte(`name:"externalname" help:"externaldocstring" type:COUNTER metric:<label:<name:"externallabelname" value:"externalval1" > label:<name:"externalconstname" value:"externalconstvalue" > 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 > > 
`)

	type output struct {
		headers map[string]string
		body    []byte
	}

	var scenarios = []struct {
		headers        map[string]string
		out            output
		withCounter    bool
		withExternalMF bool
	}{
		{ // 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,
			},
			withCounter: true,
		},
		{ // 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,
			},
			withCounter: true,
		},
		{ // 6
			headers: map[string]string{
				"Accept": "application/json",
			},
			out: output{
				headers: map[string]string{
					"Content-Type": `text/plain; version=0.0.4`,
				},
				body: externalMetricFamilyAsText,
			},
			withExternalMF: true,
		},
		{ // 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,
			},
			withExternalMF: true,
		},
		{ // 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{},
				),
			},
			withCounter:    true,
			withExternalMF: true,
		},
		{ // 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,
			},
			withCounter: true,
		},
		{ // 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{},
				),
			},
			withCounter:    true,
			withExternalMF: true,
		},
		{ // 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{},
				),
			},
			withCounter:    true,
			withExternalMF: true,
		},
		{ // 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{},
				),
			},
			withCounter:    true,
			withExternalMF: true,
		},
		{ // 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{},
				),
			},
			withCounter:    true,
			withExternalMF: true,
		},
	}
	for i, scenario := range scenarios {
		registry := newRegistry()
		registry.collectChecksEnabled = true

		if scenario.withCounter {
			registry.Register(metricVec)
		}
		if scenario.withExternalMF {
			registry.metricFamilyInjectionHook = func() []*dto.MetricFamily {
				return externalMetricFamily
			}
		}
		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(),
			)
		}
	}
}
Ejemplo n.º 12
0
func (r *registry) writePB(w io.Writer, writeEncoded encoder) (int, 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 0, 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()
		default:
			return 0, fmt.Errorf("empty metric collected: %s", dtoMetric)
		}
		if r.collectChecksEnabled {
			if err := r.checkConsistency(metricFamily, dtoMetric, desc, metricHashes); err != nil {
				return 0, err
			}
		}
		metricFamily.Metric = append(metricFamily.Metric, dtoMetric)
	}

	if r.metricFamilyInjectionHook != nil {
		for _, mf := range r.metricFamilyInjectionHook() {
			if _, exists := metricFamiliesByName[mf.GetName()]; exists {
				return 0, fmt.Errorf("metric family with duplicate name injected: %s", mf)
			}
			metricFamiliesByName[mf.GetName()] = mf
		}
	}

	// 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)

	var written int
	for _, name := range names {
		w, err := writeEncoded(w, metricFamiliesByName[name])
		written += w
		if err != nil {
			return written, err
		}
	}
	return written, nil
}
Ejemplo n.º 13
0
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_UNTYPED && dtoMetric.Untyped == nil {
		return fmt.Errorf(
			"collected metric %q is not a %s",
			dtoMetric, metricFamily.Type,
		)
	}

	// Desc consistency with metric family.
	if metricFamily.GetHelp() != desc.help {
		return fmt.Errorf(
			"collected metric %q has help %q but should have %q",
			dtoMetric, desc.help, metricFamily.GetHelp(),
		)
	}

	// 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 %q are inconsistent with descriptor %s",
			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 %q are inconsistent with descriptor %s",
				dtoMetric, desc,
			)
		}
	}

	// 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(desc.fqName)
	buf.WriteByte(model.SeparatorByte)
	h.Write(buf.Bytes())
	for _, lp := range dtoMetric.Label {
		buf.Reset()
		buf.WriteString(lp.GetValue())
		buf.WriteByte(model.SeparatorByte)
		h.Write(buf.Bytes())
	}
	metricHash := h.Sum64()
	if _, exists := metricHashes[metricHash]; exists {
		return fmt.Errorf(
			"collected metric %q was collected before with the same name and label values",
			dtoMetric,
		)
	}
	metricHashes[metricHash] = struct{}{}

	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 %q with unregistered descriptor %s", dtoMetric, desc)
	}

	return nil
}
Ejemplo n.º 14
0
// 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(model.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(model.SeparatorByte)
	h.Write(b.Bytes())
	for _, labelName := range labelNames {
		b.Reset()
		b.WriteString(labelName)
		b.WriteByte(model.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
}
Ejemplo n.º 15
0
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: No metric type.
		{
			in: &dto.MetricFamily{
				Name: proto.String("name"),
				Help: proto.String("doc string"),
				Metric: []*dto.Metric{
					&dto.Metric{
						Untyped: &dto.Untyped{
							Value: proto.Float64(math.Inf(-1)),
						},
					},
				},
			},
			err: "MetricFamily has no type",
		},
		// 3: 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,
			)
		}
	}

}
Ejemplo n.º 16
0
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
`,
		},
	}

	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,
			)
		}
	}

}
Ejemplo n.º 17
0
func testParse(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,
				)
			}
		}
	}
}
Ejemplo n.º 18
0
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

package proto_test

import (
	"testing"

	pb "./testdata"
	"github.com/coreos/etcd-starter/Godeps/_workspace/src/code.google.com/p/goprotobuf/proto"
)

var cloneTestMessage = &pb.MyMessage{
	Count: proto.Int32(42),
	Name:  proto.String("Dave"),
	Pet:   []string{"bunny", "kitty", "horsey"},
	Inner: &pb.InnerMessage{
		Host:      proto.String("niles"),
		Port:      proto.Int32(9099),
		Connected: proto.Bool(true),
	},
	Others: []*pb.OtherMessage{
		{
			Value: []byte("some bytes"),
		},
	},
	Somegroup: &pb.MyMessage_SomeGroup{
		GroupField: proto.Int32(6),
	},
	RepBytes: [][]byte{[]byte("sham"), []byte("wow")},