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prometheus/storage/remote/codec.go
Filip Petkovski 583f3e587c
Optimize histogram iterators (#13340) 
Optimize histogram iterators

Histogram iterators allocate new objects in the AtHistogram and
AtFloatHistogram methods, which makes calculating rates over long
ranges expensive.

In #13215 we allowed an existing object to be reused
when converting an integer histogram to a float histogram. This commit follows
the same idea and allows injecting an existing object in the AtHistogram and
AtFloatHistogram methods. When the injected value is nil, iterators allocate
new histograms, otherwise they populate and return the injected object.

The commit also adds a CopyTo method to Histogram and FloatHistogram which
is used in the BufferedIterator to overwrite items in the ring instead of making
new copies.

Note that a specialized HPoint pool is needed for all of this to work 
(`matrixSelectorHPool`).

---------

Signed-off-by: Filip Petkovski <filip.petkovsky@gmail.com>
Co-authored-by: George Krajcsovits <krajorama@users.noreply.github.com>
2024-01-23 17:02:14 +01:00

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// Copyright 2017 The Prometheus Authors
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package remote
import (
"compress/gzip"
"errors"
"fmt"
"io"
"math"
"net/http"
"sort"
"strings"
"sync"
"github.com/gogo/protobuf/proto"
"github.com/golang/snappy"
"github.com/prometheus/common/model"
"go.opentelemetry.io/collector/pdata/pmetric/pmetricotlp"
"golang.org/x/exp/slices"
"github.com/prometheus/prometheus/model/exemplar"
"github.com/prometheus/prometheus/model/histogram"
"github.com/prometheus/prometheus/model/labels"
"github.com/prometheus/prometheus/prompb"
"github.com/prometheus/prometheus/storage"
"github.com/prometheus/prometheus/tsdb/chunkenc"
"github.com/prometheus/prometheus/tsdb/chunks"
"github.com/prometheus/prometheus/util/annotations"
)
const (
// decodeReadLimit is the maximum size of a read request body in bytes.
decodeReadLimit = 32 * 1024 * 1024
pbContentType = "application/x-protobuf"
jsonContentType = "application/json"
)
type HTTPError struct {
msg string
status int
}
func (e HTTPError) Error() string {
return e.msg
}
func (e HTTPError) Status() int {
return e.status
}
// DecodeReadRequest reads a remote.Request from a http.Request.
func DecodeReadRequest(r *http.Request) (*prompb.ReadRequest, error) {
compressed, err := io.ReadAll(io.LimitReader(r.Body, decodeReadLimit))
if err != nil {
return nil, err
}
reqBuf, err := snappy.Decode(nil, compressed)
if err != nil {
return nil, err
}
var req prompb.ReadRequest
if err := proto.Unmarshal(reqBuf, &req); err != nil {
return nil, err
}
return &req, nil
}
// EncodeReadResponse writes a remote.Response to a http.ResponseWriter.
func EncodeReadResponse(resp *prompb.ReadResponse, w http.ResponseWriter) error {
data, err := proto.Marshal(resp)
if err != nil {
return err
}
compressed := snappy.Encode(nil, data)
_, err = w.Write(compressed)
return err
}
// ToQuery builds a Query proto.
func ToQuery(from, to int64, matchers []*labels.Matcher, hints *storage.SelectHints) (*prompb.Query, error) {
ms, err := toLabelMatchers(matchers)
if err != nil {
return nil, err
}
var rp *prompb.ReadHints
if hints != nil {
rp = &prompb.ReadHints{
StartMs: hints.Start,
EndMs: hints.End,
StepMs: hints.Step,
Func: hints.Func,
Grouping: hints.Grouping,
By: hints.By,
RangeMs: hints.Range,
}
}
return &prompb.Query{
StartTimestampMs: from,
EndTimestampMs: to,
Matchers: ms,
Hints: rp,
}, nil
}
// ToQueryResult builds a QueryResult proto.
func ToQueryResult(ss storage.SeriesSet, sampleLimit int) (*prompb.QueryResult, annotations.Annotations, error) {
numSamples := 0
resp := &prompb.QueryResult{}
var iter chunkenc.Iterator
for ss.Next() {
series := ss.At()
iter = series.Iterator(iter)
var (
samples []prompb.Sample
histograms []prompb.Histogram
)
for valType := iter.Next(); valType != chunkenc.ValNone; valType = iter.Next() {
numSamples++
if sampleLimit > 0 && numSamples > sampleLimit {
return nil, ss.Warnings(), HTTPError{
msg: fmt.Sprintf("exceeded sample limit (%d)", sampleLimit),
status: http.StatusBadRequest,
}
}
switch valType {
case chunkenc.ValFloat:
ts, val := iter.At()
samples = append(samples, prompb.Sample{
Timestamp: ts,
Value: val,
})
case chunkenc.ValHistogram:
ts, h := iter.AtHistogram(nil)
histograms = append(histograms, HistogramToHistogramProto(ts, h))
case chunkenc.ValFloatHistogram:
ts, fh := iter.AtFloatHistogram(nil)
histograms = append(histograms, FloatHistogramToHistogramProto(ts, fh))
default:
return nil, ss.Warnings(), fmt.Errorf("unrecognized value type: %s", valType)
}
}
if err := iter.Err(); err != nil {
return nil, ss.Warnings(), err
}
resp.Timeseries = append(resp.Timeseries, &prompb.TimeSeries{
Labels: labelsToLabelsProto(series.Labels(), nil),
Samples: samples,
Histograms: histograms,
})
}
return resp, ss.Warnings(), ss.Err()
}
// FromQueryResult unpacks and sorts a QueryResult proto.
func FromQueryResult(sortSeries bool, res *prompb.QueryResult) storage.SeriesSet {
series := make([]storage.Series, 0, len(res.Timeseries))
for _, ts := range res.Timeseries {
if err := validateLabelsAndMetricName(ts.Labels); err != nil {
return errSeriesSet{err: err}
}
lbls := labelProtosToLabels(ts.Labels)
series = append(series, &concreteSeries{labels: lbls, floats: ts.Samples, histograms: ts.Histograms})
}
if sortSeries {
slices.SortFunc(series, func(a, b storage.Series) int {
return labels.Compare(a.Labels(), b.Labels())
})
}
return &concreteSeriesSet{
series: series,
}
}
// NegotiateResponseType returns first accepted response type that this server supports.
// On the empty accepted list we assume that the SAMPLES response type was requested. This is to maintain backward compatibility.
func NegotiateResponseType(accepted []prompb.ReadRequest_ResponseType) (prompb.ReadRequest_ResponseType, error) {
if len(accepted) == 0 {
accepted = []prompb.ReadRequest_ResponseType{prompb.ReadRequest_SAMPLES}
}
supported := map[prompb.ReadRequest_ResponseType]struct{}{
prompb.ReadRequest_SAMPLES: {},
prompb.ReadRequest_STREAMED_XOR_CHUNKS: {},
}
for _, resType := range accepted {
if _, ok := supported[resType]; ok {
return resType, nil
}
}
return 0, fmt.Errorf("server does not support any of the requested response types: %v; supported: %v", accepted, supported)
}
// StreamChunkedReadResponses iterates over series, builds chunks and streams those to the caller.
// It expects Series set with populated chunks.
func StreamChunkedReadResponses(
stream io.Writer,
queryIndex int64,
ss storage.ChunkSeriesSet,
sortedExternalLabels []prompb.Label,
maxBytesInFrame int,
marshalPool *sync.Pool,
) (annotations.Annotations, error) {
var (
chks []prompb.Chunk
lbls []prompb.Label
iter chunks.Iterator
)
for ss.Next() {
series := ss.At()
iter = series.Iterator(iter)
lbls = MergeLabels(labelsToLabelsProto(series.Labels(), lbls), sortedExternalLabels)
maxDataLength := maxBytesInFrame
for _, lbl := range lbls {
maxDataLength -= lbl.Size()
}
frameBytesLeft := maxDataLength
isNext := iter.Next()
// Send at most one series per frame; series may be split over multiple frames according to maxBytesInFrame.
for isNext {
chk := iter.At()
if chk.Chunk == nil {
return ss.Warnings(), fmt.Errorf("StreamChunkedReadResponses: found not populated chunk returned by SeriesSet at ref: %v", chk.Ref)
}
// Cut the chunk.
chks = append(chks, prompb.Chunk{
MinTimeMs: chk.MinTime,
MaxTimeMs: chk.MaxTime,
Type: prompb.Chunk_Encoding(chk.Chunk.Encoding()),
Data: chk.Chunk.Bytes(),
})
frameBytesLeft -= chks[len(chks)-1].Size()
// We are fine with minor inaccuracy of max bytes per frame. The inaccuracy will be max of full chunk size.
isNext = iter.Next()
if frameBytesLeft > 0 && isNext {
continue
}
resp := &prompb.ChunkedReadResponse{
ChunkedSeries: []*prompb.ChunkedSeries{
{Labels: lbls, Chunks: chks},
},
QueryIndex: queryIndex,
}
b, err := resp.PooledMarshal(marshalPool)
if err != nil {
return ss.Warnings(), fmt.Errorf("marshal ChunkedReadResponse: %w", err)
}
if _, err := stream.Write(b); err != nil {
return ss.Warnings(), fmt.Errorf("write to stream: %w", err)
}
// We immediately flush the Write() so it is safe to return to the pool.
marshalPool.Put(&b)
chks = chks[:0]
frameBytesLeft = maxDataLength
}
if err := iter.Err(); err != nil {
return ss.Warnings(), err
}
}
return ss.Warnings(), ss.Err()
}
// MergeLabels merges two sets of sorted proto labels, preferring those in
// primary to those in secondary when there is an overlap.
func MergeLabels(primary, secondary []prompb.Label) []prompb.Label {
result := make([]prompb.Label, 0, len(primary)+len(secondary))
i, j := 0, 0
for i < len(primary) && j < len(secondary) {
switch {
case primary[i].Name < secondary[j].Name:
result = append(result, primary[i])
i++
case primary[i].Name > secondary[j].Name:
result = append(result, secondary[j])
j++
default:
result = append(result, primary[i])
i++
j++
}
}
for ; i < len(primary); i++ {
result = append(result, primary[i])
}
for ; j < len(secondary); j++ {
result = append(result, secondary[j])
}
return result
}
// errSeriesSet implements storage.SeriesSet, just returning an error.
type errSeriesSet struct {
err error
}
func (errSeriesSet) Next() bool {
return false
}
func (errSeriesSet) At() storage.Series {
return nil
}
func (e errSeriesSet) Err() error {
return e.err
}
func (e errSeriesSet) Warnings() annotations.Annotations { return nil }
// concreteSeriesSet implements storage.SeriesSet.
type concreteSeriesSet struct {
cur int
series []storage.Series
}
func (c *concreteSeriesSet) Next() bool {
c.cur++
return c.cur-1 < len(c.series)
}
func (c *concreteSeriesSet) At() storage.Series {
return c.series[c.cur-1]
}
func (c *concreteSeriesSet) Err() error {
return nil
}
func (c *concreteSeriesSet) Warnings() annotations.Annotations { return nil }
// concreteSeries implements storage.Series.
type concreteSeries struct {
labels labels.Labels
floats []prompb.Sample
histograms []prompb.Histogram
}
func (c *concreteSeries) Labels() labels.Labels {
return c.labels.Copy()
}
func (c *concreteSeries) Iterator(it chunkenc.Iterator) chunkenc.Iterator {
if csi, ok := it.(*concreteSeriesIterator); ok {
csi.reset(c)
return csi
}
return newConcreteSeriesIterator(c)
}
// concreteSeriesIterator implements storage.SeriesIterator.
type concreteSeriesIterator struct {
floatsCur int
histogramsCur int
curValType chunkenc.ValueType
series *concreteSeries
}
func newConcreteSeriesIterator(series *concreteSeries) chunkenc.Iterator {
return &concreteSeriesIterator{
floatsCur: -1,
histogramsCur: -1,
curValType: chunkenc.ValNone,
series: series,
}
}
func (c *concreteSeriesIterator) reset(series *concreteSeries) {
c.floatsCur = -1
c.histogramsCur = -1
c.curValType = chunkenc.ValNone
c.series = series
}
// Seek implements storage.SeriesIterator.
func (c *concreteSeriesIterator) Seek(t int64) chunkenc.ValueType {
if c.floatsCur == -1 {
c.floatsCur = 0
}
if c.histogramsCur == -1 {
c.histogramsCur = 0
}
if c.floatsCur >= len(c.series.floats) && c.histogramsCur >= len(c.series.histograms) {
return chunkenc.ValNone
}
// No-op check.
if (c.curValType == chunkenc.ValFloat && c.series.floats[c.floatsCur].Timestamp >= t) ||
((c.curValType == chunkenc.ValHistogram || c.curValType == chunkenc.ValFloatHistogram) && c.series.histograms[c.histogramsCur].Timestamp >= t) {
return c.curValType
}
c.curValType = chunkenc.ValNone
// Binary search between current position and end for both float and histograms samples.
c.floatsCur += sort.Search(len(c.series.floats)-c.floatsCur, func(n int) bool {
return c.series.floats[n+c.floatsCur].Timestamp >= t
})
c.histogramsCur += sort.Search(len(c.series.histograms)-c.histogramsCur, func(n int) bool {
return c.series.histograms[n+c.histogramsCur].Timestamp >= t
})
switch {
case c.floatsCur < len(c.series.floats) && c.histogramsCur < len(c.series.histograms):
// If float samples and histogram samples have overlapping timestamps prefer the float samples.
if c.series.floats[c.floatsCur].Timestamp <= c.series.histograms[c.histogramsCur].Timestamp {
c.curValType = chunkenc.ValFloat
} else {
c.curValType = getHistogramValType(&c.series.histograms[c.histogramsCur])
}
// When the timestamps do not overlap the cursor for the non-selected sample type has advanced too
// far; we decrement it back down here.
if c.series.floats[c.floatsCur].Timestamp != c.series.histograms[c.histogramsCur].Timestamp {
if c.curValType == chunkenc.ValFloat {
c.histogramsCur--
} else {
c.floatsCur--
}
}
case c.floatsCur < len(c.series.floats):
c.curValType = chunkenc.ValFloat
case c.histogramsCur < len(c.series.histograms):
c.curValType = getHistogramValType(&c.series.histograms[c.histogramsCur])
}
return c.curValType
}
func getHistogramValType(h *prompb.Histogram) chunkenc.ValueType {
if h.IsFloatHistogram() {
return chunkenc.ValFloatHistogram
}
return chunkenc.ValHistogram
}
// At implements chunkenc.Iterator.
func (c *concreteSeriesIterator) At() (t int64, v float64) {
if c.curValType != chunkenc.ValFloat {
panic("iterator is not on a float sample")
}
s := c.series.floats[c.floatsCur]
return s.Timestamp, s.Value
}
// AtHistogram implements chunkenc.Iterator.
func (c *concreteSeriesIterator) AtHistogram(*histogram.Histogram) (int64, *histogram.Histogram) {
if c.curValType != chunkenc.ValHistogram {
panic("iterator is not on an integer histogram sample")
}
h := c.series.histograms[c.histogramsCur]
return h.Timestamp, HistogramProtoToHistogram(h)
}
// AtFloatHistogram implements chunkenc.Iterator.
func (c *concreteSeriesIterator) AtFloatHistogram(*histogram.FloatHistogram) (int64, *histogram.FloatHistogram) {
switch c.curValType {
case chunkenc.ValHistogram:
fh := c.series.histograms[c.histogramsCur]
return fh.Timestamp, HistogramProtoToFloatHistogram(fh)
case chunkenc.ValFloatHistogram:
fh := c.series.histograms[c.histogramsCur]
return fh.Timestamp, FloatHistogramProtoToFloatHistogram(fh)
default:
panic("iterator is not on a histogram sample")
}
}
// AtT implements chunkenc.Iterator.
func (c *concreteSeriesIterator) AtT() int64 {
if c.curValType == chunkenc.ValHistogram || c.curValType == chunkenc.ValFloatHistogram {
return c.series.histograms[c.histogramsCur].Timestamp
}
return c.series.floats[c.floatsCur].Timestamp
}
const noTS = int64(math.MaxInt64)
// Next implements chunkenc.Iterator.
func (c *concreteSeriesIterator) Next() chunkenc.ValueType {
peekFloatTS := noTS
if c.floatsCur+1 < len(c.series.floats) {
peekFloatTS = c.series.floats[c.floatsCur+1].Timestamp
}
peekHistTS := noTS
if c.histogramsCur+1 < len(c.series.histograms) {
peekHistTS = c.series.histograms[c.histogramsCur+1].Timestamp
}
c.curValType = chunkenc.ValNone
switch {
case peekFloatTS < peekHistTS:
c.floatsCur++
c.curValType = chunkenc.ValFloat
case peekHistTS < peekFloatTS:
c.histogramsCur++
c.curValType = chunkenc.ValHistogram
case peekFloatTS == noTS && peekHistTS == noTS:
// This only happens when the iterator is exhausted; we set the cursors off the end to prevent
// Seek() from returning anything afterwards.
c.floatsCur = len(c.series.floats)
c.histogramsCur = len(c.series.histograms)
default:
// Prefer float samples to histogram samples if there's a conflict. We advance the cursor for histograms
// anyway otherwise the histogram sample will get selected on the next call to Next().
c.floatsCur++
c.histogramsCur++
c.curValType = chunkenc.ValFloat
}
return c.curValType
}
// Err implements chunkenc.Iterator.
func (c *concreteSeriesIterator) Err() error {
return nil
}
// validateLabelsAndMetricName validates the label names/values and metric names returned from remote read,
// also making sure that there are no labels with duplicate names.
func validateLabelsAndMetricName(ls []prompb.Label) error {
for i, l := range ls {
if l.Name == labels.MetricName && !model.IsValidMetricName(model.LabelValue(l.Value)) {
return fmt.Errorf("invalid metric name: %v", l.Value)
}
if !model.LabelName(l.Name).IsValid() {
return fmt.Errorf("invalid label name: %v", l.Name)
}
if !model.LabelValue(l.Value).IsValid() {
return fmt.Errorf("invalid label value: %v", l.Value)
}
if i > 0 && l.Name == ls[i-1].Name {
return fmt.Errorf("duplicate label with name: %v", l.Name)
}
}
return nil
}
func toLabelMatchers(matchers []*labels.Matcher) ([]*prompb.LabelMatcher, error) {
pbMatchers := make([]*prompb.LabelMatcher, 0, len(matchers))
for _, m := range matchers {
var mType prompb.LabelMatcher_Type
switch m.Type {
case labels.MatchEqual:
mType = prompb.LabelMatcher_EQ
case labels.MatchNotEqual:
mType = prompb.LabelMatcher_NEQ
case labels.MatchRegexp:
mType = prompb.LabelMatcher_RE
case labels.MatchNotRegexp:
mType = prompb.LabelMatcher_NRE
default:
return nil, errors.New("invalid matcher type")
}
pbMatchers = append(pbMatchers, &prompb.LabelMatcher{
Type: mType,
Name: m.Name,
Value: m.Value,
})
}
return pbMatchers, nil
}
// FromLabelMatchers parses protobuf label matchers to Prometheus label matchers.
func FromLabelMatchers(matchers []*prompb.LabelMatcher) ([]*labels.Matcher, error) {
result := make([]*labels.Matcher, 0, len(matchers))
for _, matcher := range matchers {
var mtype labels.MatchType
switch matcher.Type {
case prompb.LabelMatcher_EQ:
mtype = labels.MatchEqual
case prompb.LabelMatcher_NEQ:
mtype = labels.MatchNotEqual
case prompb.LabelMatcher_RE:
mtype = labels.MatchRegexp
case prompb.LabelMatcher_NRE:
mtype = labels.MatchNotRegexp
default:
return nil, errors.New("invalid matcher type")
}
matcher, err := labels.NewMatcher(mtype, matcher.Name, matcher.Value)
if err != nil {
return nil, err
}
result = append(result, matcher)
}
return result, nil
}
func exemplarProtoToExemplar(ep prompb.Exemplar) exemplar.Exemplar {
timestamp := ep.Timestamp
return exemplar.Exemplar{
Labels: labelProtosToLabels(ep.Labels),
Value: ep.Value,
Ts: timestamp,
HasTs: timestamp != 0,
}
}
// HistogramProtoToHistogram extracts a (normal integer) Histogram from the
// provided proto message. The caller has to make sure that the proto message
// represents an integer histogram and not a float histogram, or it panics.
func HistogramProtoToHistogram(hp prompb.Histogram) *histogram.Histogram {
if hp.IsFloatHistogram() {
panic("HistogramProtoToHistogram called with a float histogram")
}
return &histogram.Histogram{
CounterResetHint: histogram.CounterResetHint(hp.ResetHint),
Schema: hp.Schema,
ZeroThreshold: hp.ZeroThreshold,
ZeroCount: hp.GetZeroCountInt(),
Count: hp.GetCountInt(),
Sum: hp.Sum,
PositiveSpans: spansProtoToSpans(hp.GetPositiveSpans()),
PositiveBuckets: hp.GetPositiveDeltas(),
NegativeSpans: spansProtoToSpans(hp.GetNegativeSpans()),
NegativeBuckets: hp.GetNegativeDeltas(),
}
}
// FloatHistogramProtoToFloatHistogram extracts a float Histogram from the
// provided proto message to a Float Histogram. The caller has to make sure that
// the proto message represents a float histogram and not an integer histogram,
// or it panics.
func FloatHistogramProtoToFloatHistogram(hp prompb.Histogram) *histogram.FloatHistogram {
if !hp.IsFloatHistogram() {
panic("FloatHistogramProtoToFloatHistogram called with an integer histogram")
}
return &histogram.FloatHistogram{
CounterResetHint: histogram.CounterResetHint(hp.ResetHint),
Schema: hp.Schema,
ZeroThreshold: hp.ZeroThreshold,
ZeroCount: hp.GetZeroCountFloat(),
Count: hp.GetCountFloat(),
Sum: hp.Sum,
PositiveSpans: spansProtoToSpans(hp.GetPositiveSpans()),
PositiveBuckets: hp.GetPositiveCounts(),
NegativeSpans: spansProtoToSpans(hp.GetNegativeSpans()),
NegativeBuckets: hp.GetNegativeCounts(),
}
}
// HistogramProtoToFloatHistogram extracts and converts a (normal integer) histogram from the provided proto message
// to a float histogram. The caller has to make sure that the proto message represents an integer histogram and not a
// float histogram, or it panics.
func HistogramProtoToFloatHistogram(hp prompb.Histogram) *histogram.FloatHistogram {
if hp.IsFloatHistogram() {
panic("HistogramProtoToFloatHistogram called with a float histogram")
}
return &histogram.FloatHistogram{
CounterResetHint: histogram.CounterResetHint(hp.ResetHint),
Schema: hp.Schema,
ZeroThreshold: hp.ZeroThreshold,
ZeroCount: float64(hp.GetZeroCountInt()),
Count: float64(hp.GetCountInt()),
Sum: hp.Sum,
PositiveSpans: spansProtoToSpans(hp.GetPositiveSpans()),
PositiveBuckets: deltasToCounts(hp.GetPositiveDeltas()),
NegativeSpans: spansProtoToSpans(hp.GetNegativeSpans()),
NegativeBuckets: deltasToCounts(hp.GetNegativeDeltas()),
}
}
func spansProtoToSpans(s []prompb.BucketSpan) []histogram.Span {
spans := make([]histogram.Span, len(s))
for i := 0; i < len(s); i++ {
spans[i] = histogram.Span{Offset: s[i].Offset, Length: s[i].Length}
}
return spans
}
func deltasToCounts(deltas []int64) []float64 {
counts := make([]float64, len(deltas))
var cur float64
for i, d := range deltas {
cur += float64(d)
counts[i] = cur
}
return counts
}
func HistogramToHistogramProto(timestamp int64, h *histogram.Histogram) prompb.Histogram {
return prompb.Histogram{
Count: &prompb.Histogram_CountInt{CountInt: h.Count},
Sum: h.Sum,
Schema: h.Schema,
ZeroThreshold: h.ZeroThreshold,
ZeroCount: &prompb.Histogram_ZeroCountInt{ZeroCountInt: h.ZeroCount},
NegativeSpans: spansToSpansProto(h.NegativeSpans),
NegativeDeltas: h.NegativeBuckets,
PositiveSpans: spansToSpansProto(h.PositiveSpans),
PositiveDeltas: h.PositiveBuckets,
ResetHint: prompb.Histogram_ResetHint(h.CounterResetHint),
Timestamp: timestamp,
}
}
func FloatHistogramToHistogramProto(timestamp int64, fh *histogram.FloatHistogram) prompb.Histogram {
return prompb.Histogram{
Count: &prompb.Histogram_CountFloat{CountFloat: fh.Count},
Sum: fh.Sum,
Schema: fh.Schema,
ZeroThreshold: fh.ZeroThreshold,
ZeroCount: &prompb.Histogram_ZeroCountFloat{ZeroCountFloat: fh.ZeroCount},
NegativeSpans: spansToSpansProto(fh.NegativeSpans),
NegativeCounts: fh.NegativeBuckets,
PositiveSpans: spansToSpansProto(fh.PositiveSpans),
PositiveCounts: fh.PositiveBuckets,
ResetHint: prompb.Histogram_ResetHint(fh.CounterResetHint),
Timestamp: timestamp,
}
}
func spansToSpansProto(s []histogram.Span) []prompb.BucketSpan {
spans := make([]prompb.BucketSpan, len(s))
for i := 0; i < len(s); i++ {
spans[i] = prompb.BucketSpan{Offset: s[i].Offset, Length: s[i].Length}
}
return spans
}
// LabelProtosToMetric unpack a []*prompb.Label to a model.Metric.
func LabelProtosToMetric(labelPairs []*prompb.Label) model.Metric {
metric := make(model.Metric, len(labelPairs))
for _, l := range labelPairs {
metric[model.LabelName(l.Name)] = model.LabelValue(l.Value)
}
return metric
}
func labelProtosToLabels(labelPairs []prompb.Label) labels.Labels {
b := labels.ScratchBuilder{}
for _, l := range labelPairs {
b.Add(l.Name, l.Value)
}
b.Sort()
return b.Labels()
}
// labelsToLabelsProto transforms labels into prompb labels. The buffer slice
// will be used to avoid allocations if it is big enough to store the labels.
func labelsToLabelsProto(lbls labels.Labels, buf []prompb.Label) []prompb.Label {
result := buf[:0]
lbls.Range(func(l labels.Label) {
result = append(result, prompb.Label{
Name: l.Name,
Value: l.Value,
})
})
return result
}
// metricTypeToMetricTypeProto transforms a Prometheus metricType into prompb metricType. Since the former is a string we need to transform it to an enum.
func metricTypeToMetricTypeProto(t model.MetricType) prompb.MetricMetadata_MetricType {
mt := strings.ToUpper(string(t))
v, ok := prompb.MetricMetadata_MetricType_value[mt]
if !ok {
return prompb.MetricMetadata_UNKNOWN
}
return prompb.MetricMetadata_MetricType(v)
}
// DecodeWriteRequest from an io.Reader into a prompb.WriteRequest, handling
// snappy decompression.
func DecodeWriteRequest(r io.Reader) (*prompb.WriteRequest, error) {
compressed, err := io.ReadAll(r)
if err != nil {
return nil, err
}
reqBuf, err := snappy.Decode(nil, compressed)
if err != nil {
return nil, err
}
var req prompb.WriteRequest
if err := proto.Unmarshal(reqBuf, &req); err != nil {
return nil, err
}
return &req, nil
}
func DecodeOTLPWriteRequest(r *http.Request) (pmetricotlp.ExportRequest, error) {
contentType := r.Header.Get("Content-Type")
var decoderFunc func(buf []byte) (pmetricotlp.ExportRequest, error)
switch contentType {
case pbContentType:
decoderFunc = func(buf []byte) (pmetricotlp.ExportRequest, error) {
req := pmetricotlp.NewExportRequest()
return req, req.UnmarshalProto(buf)
}
case jsonContentType:
decoderFunc = func(buf []byte) (pmetricotlp.ExportRequest, error) {
req := pmetricotlp.NewExportRequest()
return req, req.UnmarshalJSON(buf)
}
default:
return pmetricotlp.NewExportRequest(), fmt.Errorf("unsupported content type: %s, supported: [%s, %s]", contentType, jsonContentType, pbContentType)
}
reader := r.Body
// Handle compression.
switch r.Header.Get("Content-Encoding") {
case "gzip":
gr, err := gzip.NewReader(reader)
if err != nil {
return pmetricotlp.NewExportRequest(), err
}
reader = gr
case "":
// No compression.
default:
return pmetricotlp.NewExportRequest(), fmt.Errorf("unsupported compression: %s. Only \"gzip\" or no compression supported", r.Header.Get("Content-Encoding"))
}
body, err := io.ReadAll(reader)
if err != nil {
r.Body.Close()
return pmetricotlp.NewExportRequest(), err
}
if err = r.Body.Close(); err != nil {
return pmetricotlp.NewExportRequest(), err
}
otlpReq, err := decoderFunc(body)
if err != nil {
return pmetricotlp.NewExportRequest(), err
}
return otlpReq, nil
}
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