// Copyright 2021 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 storage
import (
"fmt"
"math"
"testing"
"github.com/stretchr/testify/require"
"github.com/prometheus/prometheus/model/histogram"
"github.com/prometheus/prometheus/model/labels"
"github.com/prometheus/prometheus/model/value"
"github.com/prometheus/prometheus/tsdb/chunkenc"
"github.com/prometheus/prometheus/tsdb/chunks"
)
func TestListSeriesIterator(t *testing.T) {
it := NewListSeriesIterator(samples{
fSample{0, 0},
fSample{1, 1},
fSample{1, 1.5},
fSample{2, 2},
fSample{3, 3},
})
// Seek to the first sample with ts=1.
require.Equal(t, chunkenc.ValFloat, it.Seek(1))
ts, v := it.At()
require.Equal(t, int64(1), ts)
require.Equal(t, 1., v)
// Seek one further, next sample still has ts=1.
require.Equal(t, chunkenc.ValFloat, it.Next())
ts, v = it.At()
require.Equal(t, int64(1), ts)
require.Equal(t, 1.5, v)
// Seek again to 1 and make sure we stay where we are.
require.Equal(t, chunkenc.ValFloat, it.Seek(1))
ts, v = it.At()
require.Equal(t, int64(1), ts)
require.Equal(t, 1.5, v)
// Another seek.
require.Equal(t, chunkenc.ValFloat, it.Seek(3))
ts, v = it.At()
require.Equal(t, int64(3), ts)
require.Equal(t, 3., v)
// And we don't go back.
require.Equal(t, chunkenc.ValFloat, it.Seek(2))
ts, v = it.At()
require.Equal(t, int64(3), ts)
require.Equal(t, 3., v)
// Seek beyond the end.
require.Equal(t, chunkenc.ValNone, it.Seek(5))
// And we don't go back. (This exposes issue #10027.)
require.Equal(t, chunkenc.ValNone, it.Seek(2))
}
// TestSeriesSetToChunkSet test the property of SeriesSet that says
// returned series should be iterable even after Next is called.
func TestChunkSeriesSetToSeriesSet(t *testing.T) {
series := []struct {
lbs labels.Labels
samples []chunks.Sample
}{
{
lbs: labels.FromStrings("__name__", "up", "instance", "localhost:8080"),
samples: []chunks.Sample{
fSample{t: 1, f: 1},
fSample{t: 2, f: 2},
fSample{t: 3, f: 3},
fSample{t: 4, f: 4},
},
}, {
lbs: labels.FromStrings("__name__", "up", "instance", "localhost:8081"),
samples: []chunks.Sample{
fSample{t: 1, f: 2},
fSample{t: 2, f: 3},
fSample{t: 3, f: 4},
fSample{t: 4, f: 5},
fSample{t: 5, f: 6},
fSample{t: 6, f: 7},
},
},
}
var chunkSeries []ChunkSeries
for _, s := range series {
chunkSeries = append(chunkSeries, NewListChunkSeriesFromSamples(s.lbs, s.samples))
}
css := NewMockChunkSeriesSet(chunkSeries...)
ss := NewSeriesSetFromChunkSeriesSet(css)
var ssSlice []Series
for ss.Next() {
ssSlice = append(ssSlice, ss.At())
}
require.Len(t, ssSlice, 2)
var iter chunkenc.Iterator
for i, s := range ssSlice {
require.EqualValues(t, series[i].lbs, s.Labels())
iter = s.Iterator(iter)
j := 0
for iter.Next() == chunkenc.ValFloat {
ts, v := iter.At()
require.EqualValues(t, fSample{t: ts, f: v}, series[i].samples[j])
j++
}
}
}
type histogramTest struct {
samples []chunks.Sample
expectedCounterResetHeaders []chunkenc.CounterResetHeader
}
func TestHistogramSeriesToChunks(t *testing.T) {
h1 := &histogram.Histogram{
Count: 7,
ZeroCount: 2,
ZeroThreshold: 0.001,
Sum: 100,
Schema: 0,
PositiveSpans: []histogram.Span{
{Offset: 0, Length: 2},
},
PositiveBuckets: []int64{2, 1}, // Abs: 2, 3
}
// Appendable to h1.
h2 := &histogram.Histogram{
Count: 12,
ZeroCount: 2,
ZeroThreshold: 0.001,
Sum: 100,
Schema: 0,
PositiveSpans: []histogram.Span{
{Offset: 0, Length: 2},
{Offset: 1, Length: 2},
},
PositiveBuckets: []int64{2, 1, -2, 3}, // Abs: 2, 3, 1, 4
}
// Implicit counter reset by reduction in buckets, not appendable.
h2down := &histogram.Histogram{
Count: 10,
ZeroCount: 2,
ZeroThreshold: 0.001,
Sum: 100,
Schema: 0,
PositiveSpans: []histogram.Span{
{Offset: 0, Length: 2},
{Offset: 1, Length: 2},
},
PositiveBuckets: []int64{1, 1, -1, 3}, // Abs: 1, 2, 1, 4
}
fh1 := &histogram.FloatHistogram{
Count: 6,
ZeroCount: 2,
ZeroThreshold: 0.001,
Sum: 100,
Schema: 0,
PositiveSpans: []histogram.Span{
{Offset: 0, Length: 2},
},
PositiveBuckets: []float64{3, 1},
}
// Appendable to fh1.
fh2 := &histogram.FloatHistogram{
Count: 17,
ZeroCount: 2,
ZeroThreshold: 0.001,
Sum: 100,
Schema: 0,
PositiveSpans: []histogram.Span{
{Offset: 0, Length: 2},
{Offset: 1, Length: 2},
},
PositiveBuckets: []float64{4, 2, 7, 2},
}
// Implicit counter reset by reduction in buckets, not appendable.
fh2down := &histogram.FloatHistogram{
Count: 15,
ZeroCount: 2,
ZeroThreshold: 0.001,
Sum: 100,
Schema: 0,
PositiveSpans: []histogram.Span{
{Offset: 0, Length: 2},
{Offset: 1, Length: 2},
},
PositiveBuckets: []float64{2, 2, 7, 2},
}
// Gauge histogram.
gh1 := &histogram.Histogram{
CounterResetHint: histogram.GaugeType,
Count: 7,
ZeroCount: 2,
ZeroThreshold: 0.001,
Sum: 100,
Schema: 0,
PositiveSpans: []histogram.Span{
{Offset: 0, Length: 2},
},
PositiveBuckets: []int64{2, 1}, // Abs: 2, 3
}
gh2 := &histogram.Histogram{
CounterResetHint: histogram.GaugeType,
Count: 12,
ZeroCount: 2,
ZeroThreshold: 0.001,
Sum: 100,
Schema: 0,
PositiveSpans: []histogram.Span{
{Offset: 0, Length: 2},
{Offset: 1, Length: 2},
},
PositiveBuckets: []int64{2, 1, -2, 3}, // Abs: 2, 3, 1, 4
}
// Float gauge histogram.
gfh1 := &histogram.FloatHistogram{
CounterResetHint: histogram.GaugeType,
Count: 6,
ZeroCount: 2,
ZeroThreshold: 0.001,
Sum: 100,
Schema: 0,
PositiveSpans: []histogram.Span{
{Offset: 0, Length: 2},
},
PositiveBuckets: []float64{3, 1},
}
gfh2 := &histogram.FloatHistogram{
CounterResetHint: histogram.GaugeType,
Count: 17,
ZeroCount: 2,
ZeroThreshold: 0.001,
Sum: 100,
Schema: 0,
PositiveSpans: []histogram.Span{
{Offset: 0, Length: 2},
{Offset: 1, Length: 2},
},
PositiveBuckets: []float64{4, 2, 7, 2},
}
staleHistogram := &histogram.Histogram{
Sum: math.Float64frombits(value.StaleNaN),
}
staleFloatHistogram := &histogram.FloatHistogram{
Sum: math.Float64frombits(value.StaleNaN),
}
tests := map[string]histogramTest{
"single histogram to single chunk": {
samples: []chunks.Sample{
hSample{t: 1, h: h1},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset},
},
"two histograms encoded to a single chunk": {
samples: []chunks.Sample{
hSample{t: 1, h: h1},
hSample{t: 2, h: h2},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset},
},
"two histograms encoded to two chunks": {
samples: []chunks.Sample{
hSample{t: 1, h: h2},
hSample{t: 2, h: h1},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset, chunkenc.CounterReset},
},
"histogram and stale sample encoded to two chunks": {
samples: []chunks.Sample{
hSample{t: 1, h: staleHistogram},
hSample{t: 2, h: h1},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset, chunkenc.UnknownCounterReset},
},
"histogram and reduction in bucket encoded to two chunks": {
samples: []chunks.Sample{
hSample{t: 1, h: h1},
hSample{t: 2, h: h2down},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset, chunkenc.CounterReset},
},
// Float histograms.
"single float histogram to single chunk": {
samples: []chunks.Sample{
fhSample{t: 1, fh: fh1},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset},
},
"two float histograms encoded to a single chunk": {
samples: []chunks.Sample{
fhSample{t: 1, fh: fh1},
fhSample{t: 2, fh: fh2},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset},
},
"two float histograms encoded to two chunks": {
samples: []chunks.Sample{
fhSample{t: 1, fh: fh2},
fhSample{t: 2, fh: fh1},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset, chunkenc.CounterReset},
},
"float histogram and stale sample encoded to two chunks": {
samples: []chunks.Sample{
fhSample{t: 1, fh: staleFloatHistogram},
fhSample{t: 2, fh: fh1},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset, chunkenc.UnknownCounterReset},
},
"float histogram and reduction in bucket encoded to two chunks": {
samples: []chunks.Sample{
fhSample{t: 1, fh: fh1},
fhSample{t: 2, fh: fh2down},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset, chunkenc.CounterReset},
},
// Mixed.
"histogram and float histogram encoded to two chunks": {
samples: []chunks.Sample{
hSample{t: 1, h: h1},
fhSample{t: 2, fh: fh2},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset, chunkenc.UnknownCounterReset},
},
"float histogram and histogram encoded to two chunks": {
samples: []chunks.Sample{
fhSample{t: 1, fh: fh1},
hSample{t: 2, h: h2},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset, chunkenc.UnknownCounterReset},
},
"histogram and stale float histogram encoded to two chunks": {
samples: []chunks.Sample{
hSample{t: 1, h: h1},
fhSample{t: 2, fh: staleFloatHistogram},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.UnknownCounterReset, chunkenc.UnknownCounterReset},
},
"single gauge histogram encoded to one chunk": {
samples: []chunks.Sample{
hSample{t: 1, h: gh1},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.GaugeType},
},
"two gauge histograms encoded to one chunk when counter increases": {
samples: []chunks.Sample{
hSample{t: 1, h: gh1},
hSample{t: 2, h: gh2},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.GaugeType},
},
"two gauge histograms encoded to one chunk when counter decreases": {
samples: []chunks.Sample{
hSample{t: 1, h: gh2},
hSample{t: 2, h: gh1},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.GaugeType},
},
"single gauge float histogram encoded to one chunk": {
samples: []chunks.Sample{
fhSample{t: 1, fh: gfh1},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.GaugeType},
},
"two float gauge histograms encoded to one chunk when counter increases": {
samples: []chunks.Sample{
fhSample{t: 1, fh: gfh1},
fhSample{t: 2, fh: gfh2},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.GaugeType},
},
"two float gauge histograms encoded to one chunk when counter decreases": {
samples: []chunks.Sample{
fhSample{t: 1, fh: gfh2},
fhSample{t: 2, fh: gfh1},
},
expectedCounterResetHeaders: []chunkenc.CounterResetHeader{chunkenc.GaugeType},
},
}
for testName, test := range tests {
t.Run(testName, func(t *testing.T) {
testHistogramsSeriesToChunks(t, test)
})
}
}
func testHistogramsSeriesToChunks(t *testing.T, test histogramTest) {
lbs := labels.FromStrings("__name__", "up", "instance", "localhost:8080")
copiedSamples := []chunks.Sample{}
for _, s := range test.samples {
switch cs := s.(type) {
case hSample:
copiedSamples = append(copiedSamples, hSample{t: cs.t, h: cs.h.Copy()})
case fhSample:
copiedSamples = append(copiedSamples, fhSample{t: cs.t, fh: cs.fh.Copy()})
default:
t.Error("internal error, unexpected type")
}
}
series := NewListSeries(lbs, copiedSamples)
encoder := NewSeriesToChunkEncoder(series)
require.EqualValues(t, lbs, encoder.Labels())
chks, err := ExpandChunks(encoder.Iterator(nil))
require.NoError(t, err)
require.Equal(t, len(test.expectedCounterResetHeaders), len(chks))
// Decode all encoded samples and assert they are equal to the original ones.
encodedSamples := chunks.ChunkMetasToSamples(chks)
require.Equal(t, len(test.samples), len(encodedSamples))
for i, s := range test.samples {
encodedSample := encodedSamples[i]
switch expectedSample := s.(type) {
case hSample:
require.Equal(t, chunkenc.ValHistogram, encodedSample.Type(), "expect histogram", fmt.Sprintf("at idx %d", i))
h := encodedSample.H()
// Ignore counter reset if not gauge here, will check on chunk level.
if expectedSample.h.CounterResetHint != histogram.GaugeType {
h.CounterResetHint = histogram.UnknownCounterReset
}
if value.IsStaleNaN(expectedSample.h.Sum) {
require.True(t, value.IsStaleNaN(h.Sum), fmt.Sprintf("at idx %d", i))
continue
}
require.Equal(t, *expectedSample.h, *h.Compact(0), fmt.Sprintf("at idx %d", i))
case fhSample:
require.Equal(t, chunkenc.ValFloatHistogram, encodedSample.Type(), "expect float histogram", fmt.Sprintf("at idx %d", i))
fh := encodedSample.FH()
// Ignore counter reset if not gauge here, will check on chunk level.
if expectedSample.fh.CounterResetHint != histogram.GaugeType {
fh.CounterResetHint = histogram.UnknownCounterReset
}
if value.IsStaleNaN(expectedSample.fh.Sum) {
require.True(t, value.IsStaleNaN(fh.Sum), fmt.Sprintf("at idx %d", i))
continue
}
require.Equal(t, *expectedSample.fh, *fh.Compact(0), fmt.Sprintf("at idx %d", i))
default:
t.Error("internal error, unexpected type")
}
}
for i, expectedCounterResetHint := range test.expectedCounterResetHeaders {
require.Equal(t, expectedCounterResetHint, getCounterResetHint(chks[i]), fmt.Sprintf("chunk at index %d", i))
}
}
func getCounterResetHint(chunk chunks.Meta) chunkenc.CounterResetHeader {
switch chk := chunk.Chunk.(type) {
case *chunkenc.HistogramChunk:
return chk.GetCounterResetHeader()
case *chunkenc.FloatHistogramChunk:
return chk.GetCounterResetHeader()
}
return chunkenc.UnknownCounterReset
}