mirror of
https://github.com/prometheus/prometheus.git
synced 2024-12-26 22:19:40 -08:00
32ee1b15de
Fix and improve ingesting exemplars for native histograms. See code comment for a detailed explanation of the algorithm. Note that this changes the current behavior for all kind of samples slightly: We now allow exemplars with the same timestamp as during the last scrape if the value or the labels have changed. Also note that we now do not ingest exemplars without timestamps for native histograms anymore. Signed-off-by: Jeanette Tan <jeanette.tan@grafana.com> Signed-off-by: György Krajcsovits <gyorgy.krajcsovits@grafana.com> Co-authored-by: Björn Rabenstein <github@rabenste.in> --------- Signed-off-by: Jeanette Tan <jeanette.tan@grafana.com> Signed-off-by: György Krajcsovits <gyorgy.krajcsovits@grafana.com> Signed-off-by: zenador <zenador@users.noreply.github.com> Co-authored-by: György Krajcsovits <gyorgy.krajcsovits@grafana.com> Co-authored-by: Björn Rabenstein <github@rabenste.in>
612 lines
20 KiB
Go
612 lines
20 KiB
Go
// Copyright 2021 The Prometheus Authors
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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package textparse
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import (
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"bytes"
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"encoding/binary"
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"errors"
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"fmt"
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"io"
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"math"
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"strings"
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"unicode/utf8"
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"github.com/gogo/protobuf/proto"
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"github.com/gogo/protobuf/types"
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"github.com/prometheus/common/model"
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"github.com/prometheus/prometheus/model/exemplar"
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"github.com/prometheus/prometheus/model/histogram"
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"github.com/prometheus/prometheus/model/labels"
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dto "github.com/prometheus/prometheus/prompb/io/prometheus/client"
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)
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// ProtobufParser is a very inefficient way of unmarshaling the old Prometheus
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// protobuf format and then present it as it if were parsed by a
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// Prometheus-2-style text parser. This is only done so that we can easily plug
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// in the protobuf format into Prometheus 2. For future use (with the final
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// format that will be used for native histograms), we have to revisit the
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// parsing. A lot of the efficiency tricks of the Prometheus-2-style parsing
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// could be used in a similar fashion (byte-slice pointers into the raw
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// payload), which requires some hand-coded protobuf handling. But the current
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// parsers all expect the full series name (metric name plus label pairs) as one
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// string, which is not how things are represented in the protobuf format. If
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// the re-arrangement work is actually causing problems (which has to be seen),
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// that expectation needs to be changed.
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type ProtobufParser struct {
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in []byte // The intput to parse.
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inPos int // Position within the input.
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metricPos int // Position within Metric slice.
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// fieldPos is the position within a Summary or (legacy) Histogram. -2
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// is the count. -1 is the sum. Otherwise it is the index within
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// quantiles/buckets.
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fieldPos int
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fieldsDone bool // true if no more fields of a Summary or (legacy) Histogram to be processed.
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redoClassic bool // true after parsing a native histogram if we need to parse it again as a classic histogram.
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// exemplarReturned is set to true each time an exemplar has been
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// returned, and set back to false upon each Next() call.
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exemplarReturned bool
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// state is marked by the entry we are processing. EntryInvalid implies
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// that we have to decode the next MetricFamily.
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state Entry
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builder labels.ScratchBuilder // held here to reduce allocations when building Labels
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mf *dto.MetricFamily
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// Wether to also parse a classic histogram that is also present as a
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// native histogram.
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parseClassicHistograms bool
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// The following are just shenanigans to satisfy the Parser interface.
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metricBytes *bytes.Buffer // A somewhat fluid representation of the current metric.
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}
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// NewProtobufParser returns a parser for the payload in the byte slice.
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func NewProtobufParser(b []byte, parseClassicHistograms bool) Parser {
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return &ProtobufParser{
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in: b,
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state: EntryInvalid,
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mf: &dto.MetricFamily{},
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metricBytes: &bytes.Buffer{},
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parseClassicHistograms: parseClassicHistograms,
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}
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}
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// Series returns the bytes of a series with a simple float64 as a
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// value, the timestamp if set, and the value of the current sample.
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func (p *ProtobufParser) Series() ([]byte, *int64, float64) {
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var (
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m = p.mf.GetMetric()[p.metricPos]
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ts = m.GetTimestampMs()
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v float64
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)
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switch p.mf.GetType() {
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case dto.MetricType_COUNTER:
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v = m.GetCounter().GetValue()
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case dto.MetricType_GAUGE:
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v = m.GetGauge().GetValue()
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case dto.MetricType_UNTYPED:
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v = m.GetUntyped().GetValue()
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case dto.MetricType_SUMMARY:
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s := m.GetSummary()
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switch p.fieldPos {
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case -2:
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v = float64(s.GetSampleCount())
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case -1:
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v = s.GetSampleSum()
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// Need to detect summaries without quantile here.
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if len(s.GetQuantile()) == 0 {
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p.fieldsDone = true
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}
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default:
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v = s.GetQuantile()[p.fieldPos].GetValue()
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}
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case dto.MetricType_HISTOGRAM, dto.MetricType_GAUGE_HISTOGRAM:
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// This should only happen for a classic histogram.
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h := m.GetHistogram()
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switch p.fieldPos {
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case -2:
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v = h.GetSampleCountFloat()
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if v == 0 {
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v = float64(h.GetSampleCount())
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}
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case -1:
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v = h.GetSampleSum()
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default:
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bb := h.GetBucket()
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if p.fieldPos >= len(bb) {
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v = h.GetSampleCountFloat()
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if v == 0 {
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v = float64(h.GetSampleCount())
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}
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} else {
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v = bb[p.fieldPos].GetCumulativeCountFloat()
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if v == 0 {
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v = float64(bb[p.fieldPos].GetCumulativeCount())
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}
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}
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}
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default:
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panic("encountered unexpected metric type, this is a bug")
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}
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if ts != 0 {
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return p.metricBytes.Bytes(), &ts, v
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}
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// TODO(beorn7): We assume here that ts==0 means no timestamp. That's
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// not true in general, but proto3 originally has no distinction between
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// unset and default. At a later stage, the `optional` keyword was
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// (re-)introduced in proto3, but gogo-protobuf never got updated to
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// support it. (Note that setting `[(gogoproto.nullable) = true]` for
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// the `timestamp_ms` field doesn't help, either.) We plan to migrate
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// away from gogo-protobuf to an actively maintained protobuf
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// implementation. Once that's done, we can simply use the `optional`
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// keyword and check for the unset state explicitly.
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return p.metricBytes.Bytes(), nil, v
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}
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// Histogram returns the bytes of a series with a native histogram as a value,
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// the timestamp if set, and the native histogram in the current sample.
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//
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// The Compact method is called before returning the Histogram (or FloatHistogram).
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//
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// If the SampleCountFloat or the ZeroCountFloat in the proto message is > 0,
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// the histogram is parsed and returned as a FloatHistogram and nil is returned
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// as the (integer) Histogram return value. Otherwise, it is parsed and returned
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// as an (integer) Histogram and nil is returned as the FloatHistogram return
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// value.
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func (p *ProtobufParser) Histogram() ([]byte, *int64, *histogram.Histogram, *histogram.FloatHistogram) {
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var (
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m = p.mf.GetMetric()[p.metricPos]
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ts = m.GetTimestampMs()
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h = m.GetHistogram()
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)
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if p.parseClassicHistograms && len(h.GetBucket()) > 0 {
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p.redoClassic = true
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}
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if h.GetSampleCountFloat() > 0 || h.GetZeroCountFloat() > 0 {
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// It is a float histogram.
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fh := histogram.FloatHistogram{
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Count: h.GetSampleCountFloat(),
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Sum: h.GetSampleSum(),
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ZeroThreshold: h.GetZeroThreshold(),
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ZeroCount: h.GetZeroCountFloat(),
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Schema: h.GetSchema(),
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PositiveSpans: make([]histogram.Span, len(h.GetPositiveSpan())),
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PositiveBuckets: h.GetPositiveCount(),
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NegativeSpans: make([]histogram.Span, len(h.GetNegativeSpan())),
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NegativeBuckets: h.GetNegativeCount(),
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}
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for i, span := range h.GetPositiveSpan() {
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fh.PositiveSpans[i].Offset = span.GetOffset()
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fh.PositiveSpans[i].Length = span.GetLength()
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}
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for i, span := range h.GetNegativeSpan() {
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fh.NegativeSpans[i].Offset = span.GetOffset()
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fh.NegativeSpans[i].Length = span.GetLength()
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}
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if p.mf.GetType() == dto.MetricType_GAUGE_HISTOGRAM {
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fh.CounterResetHint = histogram.GaugeType
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}
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fh.Compact(0)
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if ts != 0 {
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return p.metricBytes.Bytes(), &ts, nil, &fh
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}
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// Nasty hack: Assume that ts==0 means no timestamp. That's not true in
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// general, but proto3 has no distinction between unset and
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// default. Need to avoid in the final format.
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return p.metricBytes.Bytes(), nil, nil, &fh
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}
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sh := histogram.Histogram{
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Count: h.GetSampleCount(),
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Sum: h.GetSampleSum(),
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ZeroThreshold: h.GetZeroThreshold(),
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ZeroCount: h.GetZeroCount(),
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Schema: h.GetSchema(),
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PositiveSpans: make([]histogram.Span, len(h.GetPositiveSpan())),
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PositiveBuckets: h.GetPositiveDelta(),
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NegativeSpans: make([]histogram.Span, len(h.GetNegativeSpan())),
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NegativeBuckets: h.GetNegativeDelta(),
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}
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for i, span := range h.GetPositiveSpan() {
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sh.PositiveSpans[i].Offset = span.GetOffset()
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sh.PositiveSpans[i].Length = span.GetLength()
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}
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for i, span := range h.GetNegativeSpan() {
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sh.NegativeSpans[i].Offset = span.GetOffset()
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sh.NegativeSpans[i].Length = span.GetLength()
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}
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if p.mf.GetType() == dto.MetricType_GAUGE_HISTOGRAM {
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sh.CounterResetHint = histogram.GaugeType
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}
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sh.Compact(0)
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if ts != 0 {
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return p.metricBytes.Bytes(), &ts, &sh, nil
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}
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return p.metricBytes.Bytes(), nil, &sh, nil
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}
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// Help returns the metric name and help text in the current entry.
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// Must only be called after Next returned a help entry.
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// The returned byte slices become invalid after the next call to Next.
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func (p *ProtobufParser) Help() ([]byte, []byte) {
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return p.metricBytes.Bytes(), []byte(p.mf.GetHelp())
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}
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// Type returns the metric name and type in the current entry.
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// Must only be called after Next returned a type entry.
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// The returned byte slices become invalid after the next call to Next.
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func (p *ProtobufParser) Type() ([]byte, MetricType) {
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n := p.metricBytes.Bytes()
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switch p.mf.GetType() {
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case dto.MetricType_COUNTER:
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return n, MetricTypeCounter
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case dto.MetricType_GAUGE:
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return n, MetricTypeGauge
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case dto.MetricType_HISTOGRAM:
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return n, MetricTypeHistogram
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case dto.MetricType_GAUGE_HISTOGRAM:
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return n, MetricTypeGaugeHistogram
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case dto.MetricType_SUMMARY:
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return n, MetricTypeSummary
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}
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return n, MetricTypeUnknown
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}
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// Unit always returns (nil, nil) because units aren't supported by the protobuf
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// format.
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func (p *ProtobufParser) Unit() ([]byte, []byte) {
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return nil, nil
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}
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// Comment always returns nil because comments aren't supported by the protobuf
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// format.
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func (p *ProtobufParser) Comment() []byte {
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return nil
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}
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// Metric writes the labels of the current sample into the passed labels.
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// It returns the string from which the metric was parsed.
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func (p *ProtobufParser) Metric(l *labels.Labels) string {
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p.builder.Reset()
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p.builder.Add(labels.MetricName, p.getMagicName())
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for _, lp := range p.mf.GetMetric()[p.metricPos].GetLabel() {
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p.builder.Add(lp.GetName(), lp.GetValue())
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}
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if needed, name, value := p.getMagicLabel(); needed {
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p.builder.Add(name, value)
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}
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// Sort labels to maintain the sorted labels invariant.
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p.builder.Sort()
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*l = p.builder.Labels()
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return p.metricBytes.String()
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}
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// Exemplar writes the exemplar of the current sample into the passed
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// exemplar. It returns if an exemplar exists or not. In case of a native
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// histogram, the legacy bucket section is still used for exemplars. To ingest
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// all exemplars, call the Exemplar method repeatedly until it returns false.
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func (p *ProtobufParser) Exemplar(ex *exemplar.Exemplar) bool {
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if p.exemplarReturned && p.state == EntrySeries {
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// We only ever return one exemplar per (non-native-histogram) series.
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return false
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}
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m := p.mf.GetMetric()[p.metricPos]
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var exProto *dto.Exemplar
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switch p.mf.GetType() {
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case dto.MetricType_COUNTER:
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exProto = m.GetCounter().GetExemplar()
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case dto.MetricType_HISTOGRAM, dto.MetricType_GAUGE_HISTOGRAM:
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bb := m.GetHistogram().GetBucket()
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isClassic := p.state == EntrySeries
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if p.fieldPos < 0 {
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if isClassic {
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return false // At _count or _sum.
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}
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p.fieldPos = 0 // Start at 1st bucket for native histograms.
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}
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for p.fieldPos < len(bb) {
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exProto = bb[p.fieldPos].GetExemplar()
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if isClassic {
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break
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}
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p.fieldPos++
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// We deliberately drop exemplars with no timestamp only for native histograms.
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if exProto != nil && (isClassic || exProto.GetTimestamp() != nil) {
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break // Found a classic histogram exemplar or a native histogram exemplar with a timestamp.
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}
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}
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// If the last exemplar for native histograms has no timestamp, ignore it.
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if !isClassic && exProto.GetTimestamp() == nil {
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return false
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}
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default:
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return false
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}
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if exProto == nil {
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return false
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}
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ex.Value = exProto.GetValue()
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if ts := exProto.GetTimestamp(); ts != nil {
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ex.HasTs = true
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ex.Ts = ts.GetSeconds()*1000 + int64(ts.GetNanos()/1_000_000)
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}
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p.builder.Reset()
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for _, lp := range exProto.GetLabel() {
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p.builder.Add(lp.GetName(), lp.GetValue())
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}
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p.builder.Sort()
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ex.Labels = p.builder.Labels()
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p.exemplarReturned = true
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return true
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}
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func (p *ProtobufParser) CreatedTimestamp(ct *types.Timestamp) bool {
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var foundCT *types.Timestamp
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switch p.mf.GetType() {
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case dto.MetricType_COUNTER:
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foundCT = p.mf.GetMetric()[p.metricPos].GetCounter().GetCreatedTimestamp()
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case dto.MetricType_SUMMARY:
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foundCT = p.mf.GetMetric()[p.metricPos].GetSummary().GetCreatedTimestamp()
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case dto.MetricType_HISTOGRAM, dto.MetricType_GAUGE_HISTOGRAM:
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foundCT = p.mf.GetMetric()[p.metricPos].GetHistogram().GetCreatedTimestamp()
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default:
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}
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if foundCT == nil {
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return false
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}
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*ct = *foundCT
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return true
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}
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// Next advances the parser to the next "sample" (emulating the behavior of a
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// text format parser). It returns (EntryInvalid, io.EOF) if no samples were
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// read.
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func (p *ProtobufParser) Next() (Entry, error) {
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p.exemplarReturned = false
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switch p.state {
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case EntryInvalid:
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p.metricPos = 0
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p.fieldPos = -2
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n, err := readDelimited(p.in[p.inPos:], p.mf)
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p.inPos += n
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if err != nil {
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return p.state, err
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}
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// Skip empty metric families.
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if len(p.mf.GetMetric()) == 0 {
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return p.Next()
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}
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// We are at the beginning of a metric family. Put only the name
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// into metricBytes and validate only name, help, and type for now.
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name := p.mf.GetName()
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if !model.IsValidMetricName(model.LabelValue(name)) {
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return EntryInvalid, fmt.Errorf("invalid metric name: %s", name)
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}
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if help := p.mf.GetHelp(); !utf8.ValidString(help) {
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return EntryInvalid, fmt.Errorf("invalid help for metric %q: %s", name, help)
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}
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switch p.mf.GetType() {
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case dto.MetricType_COUNTER,
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dto.MetricType_GAUGE,
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dto.MetricType_HISTOGRAM,
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dto.MetricType_GAUGE_HISTOGRAM,
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dto.MetricType_SUMMARY,
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dto.MetricType_UNTYPED:
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// All good.
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default:
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return EntryInvalid, fmt.Errorf("unknown metric type for metric %q: %s", name, p.mf.GetType())
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}
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p.metricBytes.Reset()
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p.metricBytes.WriteString(name)
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p.state = EntryHelp
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case EntryHelp:
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p.state = EntryType
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case EntryType:
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t := p.mf.GetType()
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if (t == dto.MetricType_HISTOGRAM || t == dto.MetricType_GAUGE_HISTOGRAM) &&
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isNativeHistogram(p.mf.GetMetric()[0].GetHistogram()) {
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p.state = EntryHistogram
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} else {
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p.state = EntrySeries
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}
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if err := p.updateMetricBytes(); err != nil {
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return EntryInvalid, err
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}
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case EntryHistogram, EntrySeries:
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if p.redoClassic {
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p.redoClassic = false
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p.state = EntrySeries
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p.fieldPos = -3
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p.fieldsDone = false
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}
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t := p.mf.GetType()
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if p.state == EntrySeries && !p.fieldsDone &&
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(t == dto.MetricType_SUMMARY ||
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t == dto.MetricType_HISTOGRAM ||
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t == dto.MetricType_GAUGE_HISTOGRAM) {
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p.fieldPos++
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} else {
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p.metricPos++
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p.fieldPos = -2
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p.fieldsDone = false
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// If this is a metric family containing native
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// histograms, we have to switch back to native
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// histograms after parsing a classic histogram.
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if p.state == EntrySeries &&
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|
(t == dto.MetricType_HISTOGRAM || t == dto.MetricType_GAUGE_HISTOGRAM) &&
|
|
isNativeHistogram(p.mf.GetMetric()[0].GetHistogram()) {
|
|
p.state = EntryHistogram
|
|
}
|
|
}
|
|
if p.metricPos >= len(p.mf.GetMetric()) {
|
|
p.state = EntryInvalid
|
|
return p.Next()
|
|
}
|
|
if err := p.updateMetricBytes(); err != nil {
|
|
return EntryInvalid, err
|
|
}
|
|
default:
|
|
return EntryInvalid, fmt.Errorf("invalid protobuf parsing state: %d", p.state)
|
|
}
|
|
return p.state, nil
|
|
}
|
|
|
|
func (p *ProtobufParser) updateMetricBytes() error {
|
|
b := p.metricBytes
|
|
b.Reset()
|
|
b.WriteString(p.getMagicName())
|
|
for _, lp := range p.mf.GetMetric()[p.metricPos].GetLabel() {
|
|
b.WriteByte(model.SeparatorByte)
|
|
n := lp.GetName()
|
|
if !model.LabelName(n).IsValid() {
|
|
return fmt.Errorf("invalid label name: %s", n)
|
|
}
|
|
b.WriteString(n)
|
|
b.WriteByte(model.SeparatorByte)
|
|
v := lp.GetValue()
|
|
if !utf8.ValidString(v) {
|
|
return fmt.Errorf("invalid label value: %s", v)
|
|
}
|
|
b.WriteString(v)
|
|
}
|
|
if needed, n, v := p.getMagicLabel(); needed {
|
|
b.WriteByte(model.SeparatorByte)
|
|
b.WriteString(n)
|
|
b.WriteByte(model.SeparatorByte)
|
|
b.WriteString(v)
|
|
}
|
|
return nil
|
|
}
|
|
|
|
// getMagicName usually just returns p.mf.GetType() but adds a magic suffix
|
|
// ("_count", "_sum", "_bucket") if needed according to the current parser
|
|
// state.
|
|
func (p *ProtobufParser) getMagicName() string {
|
|
t := p.mf.GetType()
|
|
if p.state == EntryHistogram || (t != dto.MetricType_HISTOGRAM && t != dto.MetricType_GAUGE_HISTOGRAM && t != dto.MetricType_SUMMARY) {
|
|
return p.mf.GetName()
|
|
}
|
|
if p.fieldPos == -2 {
|
|
return p.mf.GetName() + "_count"
|
|
}
|
|
if p.fieldPos == -1 {
|
|
return p.mf.GetName() + "_sum"
|
|
}
|
|
if t == dto.MetricType_HISTOGRAM || t == dto.MetricType_GAUGE_HISTOGRAM {
|
|
return p.mf.GetName() + "_bucket"
|
|
}
|
|
return p.mf.GetName()
|
|
}
|
|
|
|
// getMagicLabel returns if a magic label ("quantile" or "le") is needed and, if
|
|
// so, its name and value. It also sets p.fieldsDone if applicable.
|
|
func (p *ProtobufParser) getMagicLabel() (bool, string, string) {
|
|
if p.state == EntryHistogram || p.fieldPos < 0 {
|
|
return false, "", ""
|
|
}
|
|
switch p.mf.GetType() {
|
|
case dto.MetricType_SUMMARY:
|
|
qq := p.mf.GetMetric()[p.metricPos].GetSummary().GetQuantile()
|
|
q := qq[p.fieldPos]
|
|
p.fieldsDone = p.fieldPos == len(qq)-1
|
|
return true, model.QuantileLabel, formatOpenMetricsFloat(q.GetQuantile())
|
|
case dto.MetricType_HISTOGRAM, dto.MetricType_GAUGE_HISTOGRAM:
|
|
bb := p.mf.GetMetric()[p.metricPos].GetHistogram().GetBucket()
|
|
if p.fieldPos >= len(bb) {
|
|
p.fieldsDone = true
|
|
return true, model.BucketLabel, "+Inf"
|
|
}
|
|
b := bb[p.fieldPos]
|
|
p.fieldsDone = math.IsInf(b.GetUpperBound(), +1)
|
|
return true, model.BucketLabel, formatOpenMetricsFloat(b.GetUpperBound())
|
|
}
|
|
return false, "", ""
|
|
}
|
|
|
|
var errInvalidVarint = errors.New("protobufparse: invalid varint encountered")
|
|
|
|
// readDelimited is essentially doing what the function of the same name in
|
|
// github.com/matttproud/golang_protobuf_extensions/pbutil is doing, but it is
|
|
// specific to a MetricFamily, utilizes the more efficient gogo-protobuf
|
|
// unmarshaling, and acts on a byte slice directly without any additional
|
|
// staging buffers.
|
|
func readDelimited(b []byte, mf *dto.MetricFamily) (n int, err error) {
|
|
if len(b) == 0 {
|
|
return 0, io.EOF
|
|
}
|
|
messageLength, varIntLength := proto.DecodeVarint(b)
|
|
if varIntLength == 0 || varIntLength > binary.MaxVarintLen32 {
|
|
return 0, errInvalidVarint
|
|
}
|
|
totalLength := varIntLength + int(messageLength)
|
|
if totalLength > len(b) {
|
|
return 0, fmt.Errorf("protobufparse: insufficient length of buffer, expected at least %d bytes, got %d bytes", totalLength, len(b))
|
|
}
|
|
mf.Reset()
|
|
return totalLength, mf.Unmarshal(b[varIntLength:totalLength])
|
|
}
|
|
|
|
// formatOpenMetricsFloat works like the usual Go string formatting of a fleat
|
|
// but appends ".0" if the resulting number would otherwise contain neither a
|
|
// "." nor an "e".
|
|
func formatOpenMetricsFloat(f float64) string {
|
|
// A few common cases hardcoded.
|
|
switch {
|
|
case f == 1:
|
|
return "1.0"
|
|
case f == 0:
|
|
return "0.0"
|
|
case f == -1:
|
|
return "-1.0"
|
|
case math.IsNaN(f):
|
|
return "NaN"
|
|
case math.IsInf(f, +1):
|
|
return "+Inf"
|
|
case math.IsInf(f, -1):
|
|
return "-Inf"
|
|
}
|
|
s := fmt.Sprint(f)
|
|
if strings.ContainsAny(s, "e.") {
|
|
return s
|
|
}
|
|
return s + ".0"
|
|
}
|
|
|
|
// isNativeHistogram returns false iff the provided histograms has no spans at
|
|
// all (neither positive nor negative) and a zero threshold of 0 and a zero
|
|
// count of 0. In principle, this could still be meant to be a native histogram
|
|
// with a zero threshold of 0 and no observations yet. In that case,
|
|
// instrumentation libraries should add a "no-op" span (e.g. length zero, offset
|
|
// zero) to signal that the histogram is meant to be parsed as a native
|
|
// histogram. Failing to do so will cause Prometheus to parse it as a classic
|
|
// histogram as long as no observations have happened.
|
|
func isNativeHistogram(h *dto.Histogram) bool {
|
|
return len(h.GetPositiveSpan()) > 0 ||
|
|
len(h.GetNegativeSpan()) > 0 ||
|
|
h.GetZeroThreshold() > 0 ||
|
|
h.GetZeroCount() > 0
|
|
}
|