VictoriaMetrics/app/vmalert/rule/group_test.go
Aliaksandr Valialkin 0078399788
app/vmalert: switch from table-driven tests to f-tests
This makes test code more clear and reduces the number of code lines by 500.
This also simplifies debugging tests. See https://itnext.io/f-tests-as-a-replacement-for-table-driven-tests-in-go-8814a8b19e9e

While at it, consistently use t.Fatal* instead of t.Error* across tests, since t.Error*
requires more boilerplate code, which can result in additional bugs inside tests.
While t.Error* allows writing logging errors for the same, this doesn't simplify fixing
broken tests most of the time.

This is a follow-up for a9525da8a4
2024-07-12 22:41:11 +02:00

750 lines
20 KiB
Go

package rule
import (
"context"
"fmt"
"math"
"os"
"reflect"
"sort"
"testing"
"time"
"gopkg.in/yaml.v2"
"github.com/VictoriaMetrics/VictoriaMetrics/app/vmalert/config"
"github.com/VictoriaMetrics/VictoriaMetrics/app/vmalert/datasource"
"github.com/VictoriaMetrics/VictoriaMetrics/app/vmalert/notifier"
"github.com/VictoriaMetrics/VictoriaMetrics/app/vmalert/remotewrite"
"github.com/VictoriaMetrics/VictoriaMetrics/app/vmalert/templates"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/decimal"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/prompbmarshal"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/promutils"
)
func init() {
// Disable rand sleep on group start during tests in order to speed up test execution.
// Rand sleep is needed only in prod code.
SkipRandSleepOnGroupStart = true
}
func TestMain(m *testing.M) {
if err := templates.Load([]string{}, true); err != nil {
fmt.Println("failed to load template for test")
os.Exit(1)
}
os.Exit(m.Run())
}
func TestUpdateWith(t *testing.T) {
f := func(currentRules, newRules []config.Rule) {
t.Helper()
g := &Group{
Name: "test",
}
qb := &datasource.FakeQuerier{}
for _, r := range currentRules {
r.ID = config.HashRule(r)
g.Rules = append(g.Rules, g.newRule(qb, r))
}
ng := &Group{
Name: "test",
}
for _, r := range newRules {
r.ID = config.HashRule(r)
ng.Rules = append(ng.Rules, ng.newRule(qb, r))
}
err := g.updateWith(ng)
if err != nil {
t.Fatalf("cannot update rule: %s", err)
}
if len(g.Rules) != len(newRules) {
t.Fatalf("expected to have %d rules; got: %d", len(g.Rules), len(newRules))
}
sort.Slice(g.Rules, func(i, j int) bool {
return g.Rules[i].ID() < g.Rules[j].ID()
})
sort.Slice(ng.Rules, func(i, j int) bool {
return ng.Rules[i].ID() < ng.Rules[j].ID()
})
for i, r := range g.Rules {
got, want := r, ng.Rules[i]
if got.ID() != want.ID() {
t.Fatalf("expected to have rule %q; got %q", want, got)
}
if err := CompareRules(t, got, want); err != nil {
t.Fatalf("comparison error: %s", err)
}
}
}
// new rule
f(nil, []config.Rule{
{Alert: "bar"},
})
// update alerting rule
f([]config.Rule{
{
Alert: "foo",
Expr: "up > 0",
For: promutils.NewDuration(time.Second),
Labels: map[string]string{
"bar": "baz",
},
Annotations: map[string]string{
"summary": "{{ $value|humanize }}",
"description": "{{$labels}}",
},
},
{
Alert: "bar",
Expr: "up > 0",
For: promutils.NewDuration(time.Second),
Labels: map[string]string{
"bar": "baz",
},
},
}, []config.Rule{
{
Alert: "foo",
Expr: "up > 10",
For: promutils.NewDuration(time.Second),
Labels: map[string]string{
"baz": "bar",
},
Annotations: map[string]string{
"summary": "none",
},
},
{
Alert: "bar",
Expr: "up > 0",
For: promutils.NewDuration(2 * time.Second),
KeepFiringFor: promutils.NewDuration(time.Minute),
Labels: map[string]string{
"bar": "baz",
},
},
})
// update recording rule
f([]config.Rule{{
Record: "foo",
Expr: "max(up)",
Labels: map[string]string{
"bar": "baz",
},
}}, []config.Rule{{
Record: "foo",
Expr: "min(up)",
Labels: map[string]string{
"baz": "bar",
},
}})
// empty rule
f([]config.Rule{{Alert: "foo"}, {Record: "bar"}}, nil)
// multiple rules
f([]config.Rule{
{Alert: "bar"},
{Alert: "baz"},
{Alert: "foo"},
}, []config.Rule{
{Alert: "baz"},
{Record: "foo"},
})
// replace rule
f([]config.Rule{{Alert: "foo1"}}, []config.Rule{{Alert: "foo2"}})
// replace multiple rules
f([]config.Rule{
{Alert: "foo1"},
{Record: "foo2"},
{Alert: "foo3"},
}, []config.Rule{
{Alert: "foo3"},
{Alert: "foo4"},
{Record: "foo5"},
})
}
func TestGroupStart(t *testing.T) {
const (
rules = `
- name: groupTest
rules:
- alert: VMRows
for: 1ms
expr: vm_rows > 0
labels:
label: bar
host: "{{ $labels.instance }}"
annotations:
summary: "{{ $value }}"
`
)
var groups []config.Group
err := yaml.Unmarshal([]byte(rules), &groups)
if err != nil {
t.Fatalf("failed to parse rules: %s", err)
}
fs := &datasource.FakeQuerier{}
fn := &notifier.FakeNotifier{}
const evalInterval = time.Millisecond
g := NewGroup(groups[0], fs, evalInterval, map[string]string{"cluster": "east-1"})
const inst1, inst2, job = "foo", "bar", "baz"
m1 := metricWithLabels(t, "instance", inst1, "job", job)
m2 := metricWithLabels(t, "instance", inst2, "job", job)
r := g.Rules[0].(*AlertingRule)
alert1 := r.newAlert(m1, time.Now(), nil, nil)
alert1.State = notifier.StateFiring
// add annotations
alert1.Annotations["summary"] = "1"
// add external label
alert1.Labels["cluster"] = "east-1"
// add labels from response
alert1.Labels["job"] = job
alert1.Labels["instance"] = inst1
// add rule labels
alert1.Labels["label"] = "bar"
alert1.Labels["host"] = inst1
// add service labels
alert1.Labels[alertNameLabel] = alert1.Name
alert1.Labels[alertGroupNameLabel] = g.Name
alert1.ID = hash(alert1.Labels)
alert2 := r.newAlert(m2, time.Now(), nil, nil)
alert2.State = notifier.StateFiring
// add annotations
alert2.Annotations["summary"] = "1"
// add external label
alert2.Labels["cluster"] = "east-1"
// add labels from response
alert2.Labels["job"] = job
alert2.Labels["instance"] = inst2
// add rule labels
alert2.Labels["label"] = "bar"
alert2.Labels["host"] = inst2
// add service labels
alert2.Labels[alertNameLabel] = alert2.Name
alert2.Labels[alertGroupNameLabel] = g.Name
alert2.ID = hash(alert2.Labels)
finished := make(chan struct{})
fs.Add(m1)
fs.Add(m2)
go func() {
g.Start(context.Background(), func() []notifier.Notifier { return []notifier.Notifier{fn} }, nil, fs)
close(finished)
}()
waitForIterations := func(n int, interval time.Duration) {
t.Helper()
var cur uint64
prev := g.metrics.iterationTotal.Get()
for i := 0; ; i++ {
if i > 40 {
t.Fatalf("group wasn't able to perform %d evaluations during %d eval intervals", n, i)
}
cur = g.metrics.iterationTotal.Get()
if int(cur-prev) >= n {
return
}
time.Sleep(interval)
}
}
// wait for multiple evaluation iterations
waitForIterations(4, evalInterval)
gotAlerts := fn.GetAlerts()
expectedAlerts := []notifier.Alert{*alert1, *alert2}
compareAlerts(t, expectedAlerts, gotAlerts)
gotAlertsNum := fn.GetCounter()
if gotAlertsNum < len(expectedAlerts)*2 {
t.Fatalf("expected to receive at least %d alerts; got %d instead",
len(expectedAlerts)*2, gotAlertsNum)
}
// reset previous data
fs.Reset()
// and set only one datapoint for response
fs.Add(m1)
// wait for multiple evaluation iterations
waitForIterations(4, evalInterval)
gotAlerts = fn.GetAlerts()
alert2.State = notifier.StateInactive
expectedAlerts = []notifier.Alert{*alert1, *alert2}
compareAlerts(t, expectedAlerts, gotAlerts)
g.Close()
<-finished
}
func TestGetResolveDuration(t *testing.T) {
f := func(groupInterval, maxDuration, resendDelay, resultExpected time.Duration) {
t.Helper()
result := getResolveDuration(groupInterval, resendDelay, maxDuration)
if result != resultExpected {
t.Fatalf("unexpected result; got %s; want %s", result, resultExpected)
}
}
f(0, 0, 0, 0)
f(time.Minute, 0, 0, 4*time.Minute)
f(time.Minute, 0, 2*time.Minute, 8*time.Minute)
f(time.Minute, 4*time.Minute, 4*time.Minute, 4*time.Minute)
f(2*time.Minute, time.Minute, 2*time.Minute, time.Minute)
f(time.Minute, 2*time.Minute, 1*time.Minute, 2*time.Minute)
f(2*time.Minute, 0, 1*time.Minute, 8*time.Minute)
}
func TestGetStaleSeries(t *testing.T) {
ts := time.Now()
e := &executor{
previouslySentSeriesToRW: make(map[uint64]map[string][]prompbmarshal.Label),
}
f := func(r Rule, labels, expLabels [][]prompbmarshal.Label) {
t.Helper()
var tss []prompbmarshal.TimeSeries
for _, l := range labels {
tss = append(tss, newTimeSeriesPB([]float64{1}, []int64{ts.Unix()}, l))
}
staleS := e.getStaleSeries(r, tss, ts)
if staleS == nil && expLabels == nil {
return
}
if len(staleS) != len(expLabels) {
t.Fatalf("expected to get %d stale series, got %d",
len(expLabels), len(staleS))
}
for i, exp := range expLabels {
got := staleS[i]
if !reflect.DeepEqual(exp, got.Labels) {
t.Fatalf("expected to get labels: \n%v;\ngot instead: \n%v",
exp, got.Labels)
}
if len(got.Samples) != 1 {
t.Fatalf("expected to have 1 sample; got %d", len(got.Samples))
}
if !decimal.IsStaleNaN(got.Samples[0].Value) {
t.Fatalf("expected sample value to be %v; got %v", decimal.StaleNaN, got.Samples[0].Value)
}
}
}
// warn: keep in mind, that executor holds the state, so sequence of f calls matters
// single series
f(&AlertingRule{RuleID: 1},
[][]prompbmarshal.Label{toPromLabels(t, "__name__", "job:foo", "job", "foo")},
nil)
f(&AlertingRule{RuleID: 1},
[][]prompbmarshal.Label{toPromLabels(t, "__name__", "job:foo", "job", "foo")},
nil)
f(&AlertingRule{RuleID: 1},
nil,
[][]prompbmarshal.Label{toPromLabels(t, "__name__", "job:foo", "job", "foo")})
f(&AlertingRule{RuleID: 1},
nil,
nil)
// multiple series
f(&AlertingRule{RuleID: 1},
[][]prompbmarshal.Label{
toPromLabels(t, "__name__", "job:foo", "job", "foo"),
toPromLabels(t, "__name__", "job:foo", "job", "bar"),
},
nil)
f(&AlertingRule{RuleID: 1},
[][]prompbmarshal.Label{toPromLabels(t, "__name__", "job:foo", "job", "bar")},
[][]prompbmarshal.Label{toPromLabels(t, "__name__", "job:foo", "job", "foo")})
f(&AlertingRule{RuleID: 1},
[][]prompbmarshal.Label{toPromLabels(t, "__name__", "job:foo", "job", "bar")},
nil)
f(&AlertingRule{RuleID: 1},
nil,
[][]prompbmarshal.Label{toPromLabels(t, "__name__", "job:foo", "job", "bar")})
// multiple rules and series
f(&AlertingRule{RuleID: 1},
[][]prompbmarshal.Label{
toPromLabels(t, "__name__", "job:foo", "job", "foo"),
toPromLabels(t, "__name__", "job:foo", "job", "bar"),
},
nil)
f(&AlertingRule{RuleID: 2},
[][]prompbmarshal.Label{
toPromLabels(t, "__name__", "job:foo", "job", "foo"),
toPromLabels(t, "__name__", "job:foo", "job", "bar"),
},
nil)
f(&AlertingRule{RuleID: 1},
[][]prompbmarshal.Label{toPromLabels(t, "__name__", "job:foo", "job", "bar")},
[][]prompbmarshal.Label{toPromLabels(t, "__name__", "job:foo", "job", "foo")})
f(&AlertingRule{RuleID: 1},
[][]prompbmarshal.Label{toPromLabels(t, "__name__", "job:foo", "job", "bar")},
nil)
}
func TestPurgeStaleSeries(t *testing.T) {
ts := time.Now()
labels := toPromLabels(t, "__name__", "job:foo", "job", "foo")
tss := []prompbmarshal.TimeSeries{newTimeSeriesPB([]float64{1}, []int64{ts.Unix()}, labels)}
f := func(curRules, newRules, expStaleRules []Rule) {
t.Helper()
e := &executor{
previouslySentSeriesToRW: make(map[uint64]map[string][]prompbmarshal.Label),
}
// seed executor with series for
// current rules
for _, rule := range curRules {
e.getStaleSeries(rule, tss, ts)
}
e.purgeStaleSeries(newRules)
if len(e.previouslySentSeriesToRW) != len(expStaleRules) {
t.Fatalf("expected to get %d stale series, got %d",
len(expStaleRules), len(e.previouslySentSeriesToRW))
}
for _, exp := range expStaleRules {
if _, ok := e.previouslySentSeriesToRW[exp.ID()]; !ok {
t.Fatalf("expected to have rule %d; got nil instead", exp.ID())
}
}
}
f(nil, nil, nil)
f(
nil,
[]Rule{&AlertingRule{RuleID: 1}},
nil,
)
f(
[]Rule{&AlertingRule{RuleID: 1}},
nil,
nil,
)
f(
[]Rule{&AlertingRule{RuleID: 1}},
[]Rule{&AlertingRule{RuleID: 2}},
nil,
)
f(
[]Rule{&AlertingRule{RuleID: 1}, &AlertingRule{RuleID: 2}},
[]Rule{&AlertingRule{RuleID: 2}},
[]Rule{&AlertingRule{RuleID: 2}},
)
f(
[]Rule{&AlertingRule{RuleID: 1}, &AlertingRule{RuleID: 2}},
[]Rule{&AlertingRule{RuleID: 1}, &AlertingRule{RuleID: 2}},
[]Rule{&AlertingRule{RuleID: 1}, &AlertingRule{RuleID: 2}},
)
}
func TestFaultyNotifier(t *testing.T) {
fq := &datasource.FakeQuerier{}
fq.Add(metricWithValueAndLabels(t, 1, "__name__", "foo", "job", "bar"))
r := newTestAlertingRule("instant", 0)
r.q = fq
fn := &notifier.FakeNotifier{}
e := &executor{
Notifiers: func() []notifier.Notifier {
return []notifier.Notifier{
&notifier.FaultyNotifier{},
fn,
}
},
}
delay := 5 * time.Second
ctx, cancel := context.WithTimeout(context.Background(), delay)
defer cancel()
go func() {
_ = e.exec(ctx, r, time.Now(), 0, 10)
}()
tn := time.Now()
deadline := tn.Add(delay / 2)
for {
if fn.GetCounter() > 0 {
return
}
if tn.After(deadline) {
break
}
tn = time.Now()
time.Sleep(time.Millisecond * 100)
}
t.Fatalf("alive notifier didn't receive notification by %v", deadline)
}
func TestFaultyRW(t *testing.T) {
fq := &datasource.FakeQuerier{}
fq.Add(metricWithValueAndLabels(t, 1, "__name__", "foo", "job", "bar"))
r := &RecordingRule{
Name: "test",
q: fq,
state: &ruleState{entries: make([]StateEntry, 10)},
}
e := &executor{
Rw: &remotewrite.Client{},
previouslySentSeriesToRW: make(map[uint64]map[string][]prompbmarshal.Label),
}
err := e.exec(context.Background(), r, time.Now(), 0, 10)
if err == nil {
t.Fatalf("expected to get an error from faulty RW client, got nil instead")
}
}
func TestCloseWithEvalInterruption(t *testing.T) {
const (
rules = `
- name: groupTest
rules:
- alert: VMRows
for: 1ms
expr: vm_rows > 0
labels:
label: bar
host: "{{ $labels.instance }}"
annotations:
summary: "{{ $value }}"
`
)
var groups []config.Group
err := yaml.Unmarshal([]byte(rules), &groups)
if err != nil {
t.Fatalf("failed to parse rules: %s", err)
}
const delay = time.Second * 2
fq := &datasource.FakeQuerierWithDelay{Delay: delay}
const evalInterval = time.Millisecond
g := NewGroup(groups[0], fq, evalInterval, nil)
go g.Start(context.Background(), nil, nil, nil)
time.Sleep(evalInterval * 20)
go func() {
g.Close()
}()
deadline := time.Tick(delay / 2)
select {
case <-deadline:
t.Fatalf("deadline for close exceeded")
case <-g.finishedCh:
}
}
func TestGroupStartDelay(t *testing.T) {
g := &Group{}
// interval of 5min and key generate a static delay of 30s
g.Interval = time.Minute * 5
key := uint64(math.MaxUint64 / 10)
f := func(atS, expS string) {
t.Helper()
at, err := time.Parse(time.RFC3339Nano, atS)
if err != nil {
t.Fatal(err)
}
expTS, err := time.Parse(time.RFC3339Nano, expS)
if err != nil {
t.Fatal(err)
}
delay := delayBeforeStart(at, key, g.Interval, g.EvalOffset)
gotStart := at.Add(delay)
if expTS != gotStart {
t.Fatalf("expected to get %v; got %v instead", expTS, gotStart)
}
}
// test group without offset
f("2023-01-01T00:00:00.000+00:00", "2023-01-01T00:00:30.000+00:00")
f("2023-01-01T00:00:00.999+00:00", "2023-01-01T00:00:30.000+00:00")
f("2023-01-01T00:00:29.000+00:00", "2023-01-01T00:00:30.000+00:00")
f("2023-01-01T00:00:31.000+00:00", "2023-01-01T00:05:30.000+00:00")
// test group with offset smaller than above fixed randSleep,
// this way randSleep will always be enough
offset := 20 * time.Second
g.EvalOffset = &offset
f("2023-01-01T00:00:00.000+00:00", "2023-01-01T00:00:30.000+00:00")
f("2023-01-01T00:00:29.000+00:00", "2023-01-01T00:00:30.000+00:00")
f("2023-01-01T00:00:31.000+00:00", "2023-01-01T00:05:30.000+00:00")
// test group with offset bigger than above fixed randSleep,
// this way offset will be added to delay
offset = 3 * time.Minute
g.EvalOffset = &offset
f("2023-01-01T00:00:00.000+00:00", "2023-01-01T00:03:30.000+00:00")
f("2023-01-01T00:00:29.000+00:00", "2023-01-01T00:03:30.000+00:00")
f("2023-01-01T00:01:00.000+00:00", "2023-01-01T00:08:30.000+00:00")
f("2023-01-01T00:03:30.000+00:00", "2023-01-01T00:08:30.000+00:00")
f("2023-01-01T00:07:30.000+00:00", "2023-01-01T00:13:30.000+00:00")
offset = 10 * time.Minute
g.EvalOffset = &offset
// interval of 1h and key generate a static delay of 6m
g.Interval = time.Hour
f("2023-01-01T00:00:00.000+00:00", "2023-01-01T00:16:00.000+00:00")
f("2023-01-01T00:05:00.000+00:00", "2023-01-01T00:16:00.000+00:00")
f("2023-01-01T00:30:00.000+00:00", "2023-01-01T01:16:00.000+00:00")
}
func TestGetPrometheusReqTimestamp(t *testing.T) {
f := func(g *Group, tsOrigin, tsExpected string) {
t.Helper()
originT, _ := time.Parse(time.RFC3339, tsOrigin)
expT, _ := time.Parse(time.RFC3339, tsExpected)
gotTS := g.adjustReqTimestamp(originT)
if !gotTS.Equal(expT) {
t.Fatalf("get wrong prometheus request timestamp: %s; want %s", gotTS, expT)
}
}
offset := 30 * time.Minute
evalDelay := 1 * time.Minute
disableAlign := false
// with query align + default evalDelay
f(&Group{
Interval: time.Hour,
}, "2023-08-28T11:11:00+00:00", "2023-08-28T11:00:00+00:00")
// without query align + default evalDelay
f(&Group{
Interval: time.Hour,
evalAlignment: &disableAlign,
}, "2023-08-28T11:11:00+00:00", "2023-08-28T11:10:30+00:00")
// with eval_offset, find previous offset point + default evalDelay
f(&Group{
EvalOffset: &offset,
Interval: time.Hour,
}, "2023-08-28T11:11:00+00:00", "2023-08-28T10:30:00+00:00")
// with eval_offset + default evalDelay
f(&Group{
EvalOffset: &offset,
Interval: time.Hour,
}, "2023-08-28T11:41:00+00:00", "2023-08-28T11:30:00+00:00")
// 1h interval with eval_delay
f(&Group{
EvalDelay: &evalDelay,
Interval: time.Hour,
}, "2023-08-28T11:41:00+00:00", "2023-08-28T11:00:00+00:00")
// 1m interval with eval_delay
f(&Group{
EvalDelay: &evalDelay,
Interval: time.Minute,
}, "2023-08-28T11:41:13+00:00", "2023-08-28T11:40:00+00:00")
// disable alignment with eval_delay
f(&Group{
EvalDelay: &evalDelay,
Interval: time.Hour,
evalAlignment: &disableAlign,
}, "2023-08-28T11:41:00+00:00", "2023-08-28T11:40:00+00:00")
}
func TestRangeIterator(t *testing.T) {
f := func(ri rangeIterator, resultExpected [][2]time.Time) {
t.Helper()
var j int
for ri.next() {
if len(resultExpected) < j+1 {
t.Fatalf("unexpected result for iterator on step %d: %v - %v", j, ri.s, ri.e)
}
s, e := ri.s, ri.e
expS, expE := resultExpected[j][0], resultExpected[j][1]
if s != expS {
t.Fatalf("expected to get start=%v; got %v", expS, s)
}
if e != expE {
t.Fatalf("expected to get end=%v; got %v", expE, e)
}
j++
}
}
f(rangeIterator{
start: parseTime(t, "2021-01-01T12:00:00.000Z"),
end: parseTime(t, "2021-01-01T12:30:00.000Z"),
step: 5 * time.Minute,
}, [][2]time.Time{
{parseTime(t, "2021-01-01T12:00:00.000Z"), parseTime(t, "2021-01-01T12:05:00.000Z")},
{parseTime(t, "2021-01-01T12:05:00.000Z"), parseTime(t, "2021-01-01T12:10:00.000Z")},
{parseTime(t, "2021-01-01T12:10:00.000Z"), parseTime(t, "2021-01-01T12:15:00.000Z")},
{parseTime(t, "2021-01-01T12:15:00.000Z"), parseTime(t, "2021-01-01T12:20:00.000Z")},
{parseTime(t, "2021-01-01T12:20:00.000Z"), parseTime(t, "2021-01-01T12:25:00.000Z")},
{parseTime(t, "2021-01-01T12:25:00.000Z"), parseTime(t, "2021-01-01T12:30:00.000Z")},
})
f(rangeIterator{
start: parseTime(t, "2021-01-01T12:00:00.000Z"),
end: parseTime(t, "2021-01-01T12:30:00.000Z"),
step: 45 * time.Minute,
}, [][2]time.Time{
{parseTime(t, "2021-01-01T12:00:00.000Z"), parseTime(t, "2021-01-01T12:30:00.000Z")},
{parseTime(t, "2021-01-01T12:30:00.000Z"), parseTime(t, "2021-01-01T12:30:00.000Z")},
})
f(rangeIterator{
start: parseTime(t, "2021-01-01T12:00:12.000Z"),
end: parseTime(t, "2021-01-01T12:00:17.000Z"),
step: time.Second,
}, [][2]time.Time{
{parseTime(t, "2021-01-01T12:00:12.000Z"), parseTime(t, "2021-01-01T12:00:13.000Z")},
{parseTime(t, "2021-01-01T12:00:13.000Z"), parseTime(t, "2021-01-01T12:00:14.000Z")},
{parseTime(t, "2021-01-01T12:00:14.000Z"), parseTime(t, "2021-01-01T12:00:15.000Z")},
{parseTime(t, "2021-01-01T12:00:15.000Z"), parseTime(t, "2021-01-01T12:00:16.000Z")},
{parseTime(t, "2021-01-01T12:00:16.000Z"), parseTime(t, "2021-01-01T12:00:17.000Z")},
})
}
func parseTime(t *testing.T, s string) time.Time {
t.Helper()
tt, err := time.Parse("2006-01-02T15:04:05.000Z", s)
if err != nil {
t.Fatal(err)
}
return tt
}