tailscale/tstest/clock_test.go

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// Copyright (c) Tailscale Inc & AUTHORS
// SPDX-License-Identifier: BSD-3-Clause
package tstest
import (
"slices"
"sync/atomic"
"testing"
"time"
"tailscale.com/tstime"
)
func TestClockWithDefinedStartTime(t *testing.T) {
t.Parallel()
tests := []struct {
name string
start time.Time
step time.Duration
wants []time.Time // The return values of sequential calls to Now().
}{
{
name: "increment ms",
start: time.Unix(12345, 1000),
step: 1000,
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 2000),
time.Unix(12345, 3000),
time.Unix(12345, 4000),
},
},
{
name: "increment second",
start: time.Unix(12345, 1000),
step: time.Second,
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12346, 1000),
time.Unix(12347, 1000),
time.Unix(12348, 1000),
},
},
{
name: "no increment",
start: time.Unix(12345, 1000),
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 1000),
time.Unix(12345, 1000),
time.Unix(12345, 1000),
},
},
}
for _, tt := range tests {
tt := tt
t.Run(tt.name, func(t *testing.T) {
t.Parallel()
clock := NewClock(ClockOpts{
Start: tt.start,
Step: tt.step,
})
if start := clock.GetStart(); !start.Equal(tt.start) {
t.Errorf("clock has start %v, want %v", start, tt.start)
}
if step := clock.GetStep(); step != tt.step {
t.Errorf("clock has step %v, want %v", step, tt.step)
}
for i := range tt.wants {
if got := clock.Now(); !got.Equal(tt.wants[i]) {
t.Errorf("step %v: clock.Now() = %v, want %v", i, got, tt.wants[i])
}
if got := clock.PeekNow(); !got.Equal(tt.wants[i]) {
t.Errorf("step %v: clock.PeekNow() = %v, want %v", i, got, tt.wants[i])
}
}
})
}
}
func TestClockWithDefaultStartTime(t *testing.T) {
t.Parallel()
tests := []struct {
name string
step time.Duration
wants []time.Duration // The return values of sequential calls to Now() after added to Start()
}{
{
name: "increment ms",
step: 1000,
wants: []time.Duration{
0,
1000,
2000,
3000,
},
},
{
name: "increment second",
step: time.Second,
wants: []time.Duration{
0 * time.Second,
1 * time.Second,
2 * time.Second,
3 * time.Second,
},
},
{
name: "no increment",
wants: []time.Duration{0, 0, 0, 0},
},
}
for _, tt := range tests {
tt := tt
t.Run(tt.name, func(t *testing.T) {
t.Parallel()
clock := NewClock(ClockOpts{
Step: tt.step,
})
start := clock.GetStart()
if step := clock.GetStep(); step != tt.step {
t.Errorf("clock has step %v, want %v", step, tt.step)
}
for i := range tt.wants {
want := start.Add(tt.wants[i])
if got := clock.Now(); !got.Equal(want) {
t.Errorf("step %v: clock.Now() = %v, want %v", i, got, tt.wants[i])
}
if got := clock.PeekNow(); !got.Equal(want) {
t.Errorf("step %v: clock.PeekNow() = %v, want %v", i, got, tt.wants[i])
}
}
})
}
}
func TestZeroInitClock(t *testing.T) {
t.Parallel()
var clock Clock
start := clock.GetStart()
if step := clock.GetStep(); step != 0 {
t.Errorf("clock has step %v, want 0", step)
}
for i := range 10 {
if got := clock.Now(); !got.Equal(start) {
t.Errorf("step %v: clock.Now() = %v, want %v", i, got, start)
}
if got := clock.PeekNow(); !got.Equal(start) {
t.Errorf("step %v: clock.PeekNow() = %v, want %v", i, got, start)
}
}
}
func TestClockSetStep(t *testing.T) {
t.Parallel()
type stepInfo struct {
when int
step time.Duration
}
tests := []struct {
name string
start time.Time
step time.Duration
stepChanges []stepInfo
wants []time.Time // The return values of sequential calls to Now().
}{
{
name: "increment ms then s",
start: time.Unix(12345, 1000),
step: 1000,
stepChanges: []stepInfo{
{
when: 4,
step: time.Second,
},
},
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 2000),
time.Unix(12345, 3000),
time.Unix(12345, 4000),
time.Unix(12346, 4000),
time.Unix(12347, 4000),
time.Unix(12348, 4000),
time.Unix(12349, 4000),
},
},
{
name: "multiple changes over time",
start: time.Unix(12345, 1000),
step: 1,
stepChanges: []stepInfo{
{
when: 2,
step: time.Second,
},
{
when: 4,
step: 0,
},
{
when: 6,
step: 1000,
},
},
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 1001),
time.Unix(12346, 1001),
time.Unix(12347, 1001),
time.Unix(12347, 1001),
time.Unix(12347, 1001),
time.Unix(12347, 2001),
time.Unix(12347, 3001),
},
},
{
name: "multiple changes at once",
start: time.Unix(12345, 1000),
step: 1,
stepChanges: []stepInfo{
{
when: 2,
step: time.Second,
},
{
when: 2,
step: 0,
},
{
when: 2,
step: 1000,
},
},
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 1001),
time.Unix(12345, 2001),
time.Unix(12345, 3001),
},
},
{
name: "changes at start",
start: time.Unix(12345, 1000),
step: 0,
stepChanges: []stepInfo{
{
when: 0,
step: time.Second,
},
{
when: 0,
step: 1000,
},
},
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 2000),
time.Unix(12345, 3000),
time.Unix(12345, 4000),
},
},
}
for _, tt := range tests {
tt := tt
t.Run(tt.name, func(t *testing.T) {
t.Parallel()
clock := NewClock(ClockOpts{
Start: tt.start,
Step: tt.step,
})
wantStep := tt.step
changeIndex := 0
for i := range tt.wants {
for len(tt.stepChanges) > changeIndex && tt.stepChanges[changeIndex].when == i {
wantStep = tt.stepChanges[changeIndex].step
clock.SetStep(wantStep)
changeIndex++
}
if start := clock.GetStart(); !start.Equal(tt.start) {
t.Errorf("clock has start %v, want %v", start, tt.start)
}
if step := clock.GetStep(); step != wantStep {
t.Errorf("clock has step %v, want %v", step, tt.step)
}
if got := clock.Now(); !got.Equal(tt.wants[i]) {
t.Errorf("step %v: clock.Now() = %v, want %v", i, got, tt.wants[i])
}
if got := clock.PeekNow(); !got.Equal(tt.wants[i]) {
t.Errorf("step %v: clock.PeekNow() = %v, want %v", i, got, tt.wants[i])
}
}
})
}
}
func TestClockAdvance(t *testing.T) {
t.Parallel()
type advanceInfo struct {
when int
advance time.Duration
}
tests := []struct {
name string
start time.Time
step time.Duration
advances []advanceInfo
wants []time.Time // The return values of sequential calls to Now().
}{
{
name: "increment ms then advance 1s",
start: time.Unix(12345, 1000),
step: 1000,
advances: []advanceInfo{
{
when: 4,
advance: time.Second,
},
},
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 2000),
time.Unix(12345, 3000),
time.Unix(12345, 4000),
time.Unix(12346, 4000),
time.Unix(12346, 5000),
time.Unix(12346, 6000),
time.Unix(12346, 7000),
},
},
{
name: "multiple advances over time",
start: time.Unix(12345, 1000),
step: 1,
advances: []advanceInfo{
{
when: 2,
advance: time.Second,
},
{
when: 4,
advance: 0,
},
{
when: 6,
advance: 1000,
},
},
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 1001),
time.Unix(12346, 1001),
time.Unix(12346, 1002),
time.Unix(12346, 1002),
time.Unix(12346, 1003),
time.Unix(12346, 2003),
time.Unix(12346, 2004),
},
},
{
name: "multiple advances at once",
start: time.Unix(12345, 1000),
step: 1,
advances: []advanceInfo{
{
when: 2,
advance: time.Second,
},
{
when: 2,
advance: 0,
},
{
when: 2,
advance: 1000,
},
},
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 1001),
time.Unix(12346, 2001),
time.Unix(12346, 2002),
},
},
{
name: "changes at start",
start: time.Unix(12345, 1000),
step: 5,
advances: []advanceInfo{
{
when: 0,
advance: time.Second,
},
{
when: 0,
advance: 1000,
},
},
wants: []time.Time{
time.Unix(12346, 2000),
time.Unix(12346, 2005),
time.Unix(12346, 2010),
time.Unix(12346, 2015),
},
},
}
for _, tt := range tests {
tt := tt
t.Run(tt.name, func(t *testing.T) {
t.Parallel()
clock := NewClock(ClockOpts{
Start: tt.start,
Step: tt.step,
})
wantStep := tt.step
changeIndex := 0
for i := range tt.wants {
for len(tt.advances) > changeIndex && tt.advances[changeIndex].when == i {
clock.Advance(tt.advances[changeIndex].advance)
changeIndex++
}
if start := clock.GetStart(); !start.Equal(tt.start) {
t.Errorf("clock has start %v, want %v", start, tt.start)
}
if step := clock.GetStep(); step != wantStep {
t.Errorf("clock has step %v, want %v", step, tt.step)
}
if got := clock.Now(); !got.Equal(tt.wants[i]) {
t.Errorf("step %v: clock.Now() = %v, want %v", i, got, tt.wants[i])
}
if got := clock.PeekNow(); !got.Equal(tt.wants[i]) {
t.Errorf("step %v: clock.PeekNow() = %v, want %v", i, got, tt.wants[i])
}
}
})
}
}
func expectNoTicks(t *testing.T, tickC <-chan time.Time) {
t.Helper()
select {
case tick := <-tickC:
t.Errorf("wanted no ticks, got %v", tick)
default:
}
}
func TestSingleTicker(t *testing.T) {
t.Parallel()
type testStep struct {
stop bool
reset time.Duration
resetAbsolute time.Time
setStep time.Duration
advance time.Duration
advanceRealTime time.Duration
wantTime time.Time
wantTicks []time.Time
}
tests := []struct {
name string
realTimeOpts *ClockOpts
start time.Time
step time.Duration
period time.Duration
channelSize int
steps []testStep
}{
{
name: "no tick advance",
start: time.Unix(12345, 0),
period: time.Second,
steps: []testStep{
{
advance: time.Second - 1,
wantTime: time.Unix(12345, 999_999_999),
},
},
},
{
name: "no tick step",
start: time.Unix(12345, 0),
step: time.Second - 1,
period: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12345, 999_999_999),
},
},
},
{
name: "single tick advance exact",
start: time.Unix(12345, 0),
period: time.Second,
steps: []testStep{
{
advance: time.Second,
wantTime: time.Unix(12346, 0),
wantTicks: []time.Time{time.Unix(12346, 0)},
},
},
},
{
name: "single tick advance extra",
start: time.Unix(12345, 0),
period: time.Second,
steps: []testStep{
{
advance: time.Second + 1,
wantTime: time.Unix(12346, 1),
wantTicks: []time.Time{time.Unix(12346, 0)},
},
},
},
{
name: "single tick step exact",
start: time.Unix(12345, 0),
step: time.Second,
period: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 0),
wantTicks: []time.Time{time.Unix(12346, 0)},
},
},
},
{
name: "single tick step extra",
start: time.Unix(12345, 0),
step: time.Second + 1,
period: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 1),
wantTicks: []time.Time{time.Unix(12346, 0)},
},
},
},
{
name: "single tick per advance",
start: time.Unix(12345, 0),
period: 3 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
advance: 4 * time.Second,
wantTime: time.Unix(12349, 0),
wantTicks: []time.Time{time.Unix(12348, 0)},
},
{
advance: 2 * time.Second,
wantTime: time.Unix(12351, 0),
wantTicks: []time.Time{time.Unix(12351, 0)},
},
{
advance: 2 * time.Second,
wantTime: time.Unix(12353, 0),
},
{
advance: 2 * time.Second,
wantTime: time.Unix(12355, 0),
wantTicks: []time.Time{time.Unix(12354, 0)},
},
},
},
{
name: "single tick per step",
start: time.Unix(12345, 0),
step: 2 * time.Second,
period: 3 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
},
{
wantTime: time.Unix(12349, 0),
wantTicks: []time.Time{time.Unix(12348, 0)},
},
{
wantTime: time.Unix(12351, 0),
wantTicks: []time.Time{time.Unix(12351, 0)},
},
{
wantTime: time.Unix(12353, 0),
},
{
wantTime: time.Unix(12355, 0),
wantTicks: []time.Time{time.Unix(12354, 0)},
},
},
},
{
name: "multiple tick per advance",
start: time.Unix(12345, 0),
period: time.Second,
channelSize: 3,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
advance: 2 * time.Second,
wantTime: time.Unix(12347, 0),
wantTicks: []time.Time{
time.Unix(12346, 0),
time.Unix(12347, 0),
},
},
{
advance: 4 * time.Second,
wantTime: time.Unix(12351, 0),
wantTicks: []time.Time{
time.Unix(12348, 0),
time.Unix(12349, 0),
time.Unix(12350, 0),
// fourth tick dropped due to channel size
},
},
},
},
{
name: "multiple tick per step",
start: time.Unix(12345, 0),
step: 3 * time.Second,
period: 2 * time.Second,
channelSize: 3,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12348, 0),
wantTicks: []time.Time{
time.Unix(12347, 0),
},
},
{
wantTime: time.Unix(12351, 0),
wantTicks: []time.Time{
time.Unix(12349, 0),
time.Unix(12351, 0),
},
},
{
wantTime: time.Unix(12354, 0),
wantTicks: []time.Time{
time.Unix(12353, 0),
},
},
{
wantTime: time.Unix(12357, 0),
wantTicks: []time.Time{
time.Unix(12355, 0),
time.Unix(12357, 0),
},
},
},
},
{
name: "stop",
start: time.Unix(12345, 0),
step: 2 * time.Second,
period: time.Second,
channelSize: 3,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
wantTicks: []time.Time{
time.Unix(12346, 0),
time.Unix(12347, 0),
},
},
{
stop: true,
wantTime: time.Unix(12349, 0),
},
{
wantTime: time.Unix(12351, 0),
},
{
advance: 10 * time.Second,
wantTime: time.Unix(12361, 0),
},
},
},
{
name: "reset while running",
start: time.Unix(12345, 0),
period: 2 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
advance: time.Second,
wantTime: time.Unix(12346, 0),
},
{
advance: time.Second,
wantTime: time.Unix(12347, 0),
wantTicks: []time.Time{
time.Unix(12347, 0),
},
},
{
advance: time.Second,
reset: time.Second,
wantTime: time.Unix(12348, 0),
wantTicks: []time.Time{
time.Unix(12348, 0),
},
},
{
setStep: 5 * time.Second,
reset: 10 * time.Second,
wantTime: time.Unix(12353, 0),
},
{
wantTime: time.Unix(12358, 0),
wantTicks: []time.Time{
time.Unix(12358, 0),
},
},
},
},
{
name: "reset while stopped",
start: time.Unix(12345, 0),
step: time.Second,
period: 2 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 0),
},
{
wantTime: time.Unix(12347, 0),
wantTicks: []time.Time{
time.Unix(12347, 0),
},
},
{
stop: true,
wantTime: time.Unix(12348, 0),
},
{
wantTime: time.Unix(12349, 0),
},
{
reset: time.Second,
wantTime: time.Unix(12350, 0),
wantTicks: []time.Time{
time.Unix(12350, 0),
},
},
{
wantTime: time.Unix(12351, 0),
wantTicks: []time.Time{
time.Unix(12351, 0),
},
},
},
},
{
name: "reset absolute",
start: time.Unix(12345, 0),
step: time.Second,
period: 2 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 0),
},
{
wantTime: time.Unix(12347, 0),
wantTicks: []time.Time{
time.Unix(12347, 0),
},
},
{
reset: time.Second,
resetAbsolute: time.Unix(12354, 50),
advance: 7 * time.Second,
wantTime: time.Unix(12354, 0),
},
{
wantTime: time.Unix(12355, 0),
wantTicks: []time.Time{
time.Unix(12354, 50),
},
},
{
wantTime: time.Unix(12356, 0),
wantTicks: []time.Time{
time.Unix(12355, 50),
},
},
},
},
{
name: "follow real time",
realTimeOpts: new(ClockOpts),
start: time.Unix(12345, 0),
period: 2 * time.Second,
channelSize: 3,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
advanceRealTime: 5 * time.Second,
wantTime: time.Unix(12350, 0),
wantTicks: []time.Time{
time.Unix(12347, 0),
time.Unix(12349, 0),
},
},
{
advance: 5 * time.Second,
wantTime: time.Unix(12355, 0),
wantTicks: []time.Time{
time.Unix(12351, 0),
time.Unix(12353, 0),
time.Unix(12355, 0),
},
},
},
},
}
for _, tt := range tests {
tt := tt
t.Run(tt.name, func(t *testing.T) {
t.Parallel()
var realTimeClockForTestClock tstime.Clock
var realTimeClock *Clock
if tt.realTimeOpts != nil {
realTimeClock = NewClock(*tt.realTimeOpts)
// Passing realTimeClock into newClockInternal results in a
// non-nil interface with a nil pointer, so this is necessary.
realTimeClockForTestClock = realTimeClock
}
clock := newClockInternal(ClockOpts{
Start: tt.start,
Step: tt.step,
TimerChannelSize: tt.channelSize,
FollowRealTime: realTimeClock != nil,
}, realTimeClockForTestClock)
tc, tickC := clock.NewTicker(tt.period)
tickControl := tc.(*Ticker)
t.Cleanup(tickControl.Stop)
expectNoTicks(t, tickC)
for i, step := range tt.steps {
if step.stop {
tickControl.Stop()
}
if !step.resetAbsolute.IsZero() {
tickControl.ResetAbsolute(step.resetAbsolute, step.reset)
} else if step.reset > 0 {
tickControl.Reset(step.reset)
}
if step.setStep > 0 {
clock.SetStep(step.setStep)
}
if step.advance > 0 {
clock.Advance(step.advance)
}
if step.advanceRealTime > 0 {
realTimeClock.Advance(step.advanceRealTime)
}
if now := clock.Now(); !step.wantTime.IsZero() && !now.Equal(step.wantTime) {
t.Errorf("step %v now = %v, want %v", i, now, step.wantTime)
}
for j, want := range step.wantTicks {
select {
case tick := <-tickC:
if tick.Equal(want) {
continue
}
t.Errorf("step %v tick %v = %v, want %v", i, j, tick, want)
default:
t.Errorf("step %v tick %v missing", i, j)
}
}
expectNoTicks(t, tickC)
}
})
}
}
func TestSingleTimer(t *testing.T) {
t.Parallel()
type testStep struct {
stop bool
stopReturn bool // The expected return value for Stop() if stop is true.
reset time.Duration
resetAbsolute time.Time
resetReturn bool // The expected return value for Reset() or ResetAbsolute().
setStep time.Duration
advance time.Duration
advanceRealTime time.Duration
wantTime time.Time
wantTicks []time.Time
}
tests := []struct {
name string
realTimeOpts *ClockOpts
start time.Time
step time.Duration
delay time.Duration
steps []testStep
}{
{
name: "no tick advance",
start: time.Unix(12345, 0),
delay: time.Second,
steps: []testStep{
{
advance: time.Second - 1,
wantTime: time.Unix(12345, 999_999_999),
},
},
},
{
name: "no tick step",
start: time.Unix(12345, 0),
step: time.Second - 1,
delay: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12345, 999_999_999),
},
},
},
{
name: "single tick advance exact",
start: time.Unix(12345, 0),
delay: time.Second,
steps: []testStep{
{
advance: time.Second,
wantTime: time.Unix(12346, 0),
wantTicks: []time.Time{time.Unix(12346, 0)},
},
{
advance: time.Second,
wantTime: time.Unix(12347, 0),
},
},
},
{
name: "single tick advance extra",
start: time.Unix(12345, 0),
delay: time.Second,
steps: []testStep{
{
advance: time.Second + 1,
wantTime: time.Unix(12346, 1),
wantTicks: []time.Time{time.Unix(12346, 0)},
},
{
advance: time.Second,
wantTime: time.Unix(12347, 1),
},
},
},
{
name: "single tick step exact",
start: time.Unix(12345, 0),
step: time.Second,
delay: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 0),
wantTicks: []time.Time{time.Unix(12346, 0)},
},
{
wantTime: time.Unix(12347, 0),
},
},
},
{
name: "single tick step extra",
start: time.Unix(12345, 0),
step: time.Second + 1,
delay: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 1),
wantTicks: []time.Time{time.Unix(12346, 0)},
},
{
wantTime: time.Unix(12347, 2),
},
},
},
{
name: "reset for single tick per advance",
start: time.Unix(12345, 0),
delay: 3 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
advance: 4 * time.Second,
wantTime: time.Unix(12349, 0),
wantTicks: []time.Time{time.Unix(12348, 0)},
},
{
resetAbsolute: time.Unix(12351, 0),
advance: 2 * time.Second,
wantTime: time.Unix(12351, 0),
wantTicks: []time.Time{time.Unix(12351, 0)},
},
{
reset: 3 * time.Second,
advance: 2 * time.Second,
wantTime: time.Unix(12353, 0),
},
{
advance: 2 * time.Second,
wantTime: time.Unix(12355, 0),
wantTicks: []time.Time{time.Unix(12354, 0)},
},
{
advance: 10 * time.Second,
wantTime: time.Unix(12365, 0),
},
},
},
{
name: "reset for single tick per step",
start: time.Unix(12345, 0),
step: 2 * time.Second,
delay: 3 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
},
{
wantTime: time.Unix(12349, 0),
wantTicks: []time.Time{time.Unix(12348, 0)},
},
{
reset: time.Second,
wantTime: time.Unix(12351, 0),
wantTicks: []time.Time{time.Unix(12350, 0)},
},
{
resetAbsolute: time.Unix(12354, 0),
wantTime: time.Unix(12353, 0),
},
{
wantTime: time.Unix(12355, 0),
wantTicks: []time.Time{time.Unix(12354, 0)},
},
},
},
{
name: "reset while active",
start: time.Unix(12345, 0),
step: 2 * time.Second,
delay: 3 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
},
{
reset: 3 * time.Second,
resetReturn: true,
wantTime: time.Unix(12349, 0),
},
{
resetAbsolute: time.Unix(12354, 0),
resetReturn: true,
wantTime: time.Unix(12351, 0),
},
{
wantTime: time.Unix(12353, 0),
},
{
wantTime: time.Unix(12355, 0),
wantTicks: []time.Time{time.Unix(12354, 0)},
},
},
},
{
name: "stop after fire",
start: time.Unix(12345, 0),
step: 2 * time.Second,
delay: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
wantTicks: []time.Time{time.Unix(12346, 0)},
},
{
stop: true,
wantTime: time.Unix(12349, 0),
},
{
wantTime: time.Unix(12351, 0),
},
{
advance: 10 * time.Second,
wantTime: time.Unix(12361, 0),
},
},
},
{
name: "stop before fire",
start: time.Unix(12345, 0),
step: 2 * time.Second,
delay: time.Second,
steps: []testStep{
{
stop: true,
stopReturn: true,
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
},
{
wantTime: time.Unix(12349, 0),
},
{
wantTime: time.Unix(12351, 0),
},
{
advance: 10 * time.Second,
wantTime: time.Unix(12361, 0),
},
},
},
{
name: "stop after reset",
start: time.Unix(12345, 0),
step: 2 * time.Second,
delay: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
wantTicks: []time.Time{time.Unix(12346, 0)},
},
{
reset: 10 * time.Second,
wantTime: time.Unix(12349, 0),
},
{
stop: true,
stopReturn: true,
wantTime: time.Unix(12351, 0),
},
{
advance: 10 * time.Second,
wantTime: time.Unix(12361, 0),
},
},
},
{
name: "reset while running",
start: time.Unix(12345, 0),
delay: 2 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
advance: time.Second,
wantTime: time.Unix(12346, 0),
},
{
advance: time.Second,
wantTime: time.Unix(12347, 0),
wantTicks: []time.Time{
time.Unix(12347, 0),
},
},
{
advance: time.Second,
reset: time.Second,
wantTime: time.Unix(12348, 0),
wantTicks: []time.Time{
time.Unix(12348, 0),
},
},
{
setStep: 5 * time.Second,
reset: 10 * time.Second,
wantTime: time.Unix(12353, 0),
},
{
wantTime: time.Unix(12358, 0),
wantTicks: []time.Time{
time.Unix(12358, 0),
},
},
},
},
{
name: "reset while stopped",
start: time.Unix(12345, 0),
step: time.Second,
delay: 2 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 0),
},
{
stop: true,
stopReturn: true,
wantTime: time.Unix(12347, 0),
},
{
wantTime: time.Unix(12348, 0),
},
{
wantTime: time.Unix(12349, 0),
},
{
reset: time.Second,
wantTime: time.Unix(12350, 0),
wantTicks: []time.Time{
time.Unix(12350, 0),
},
},
{
wantTime: time.Unix(12351, 0),
},
},
},
{
name: "reset absolute",
start: time.Unix(12345, 0),
step: time.Second,
delay: 2 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 0),
},
{
wantTime: time.Unix(12347, 0),
wantTicks: []time.Time{
time.Unix(12347, 0),
},
},
{
resetAbsolute: time.Unix(12354, 50),
advance: 7 * time.Second,
wantTime: time.Unix(12354, 0),
},
{
wantTime: time.Unix(12355, 0),
wantTicks: []time.Time{
time.Unix(12354, 50),
},
},
{
wantTime: time.Unix(12356, 0),
},
},
},
{
name: "follow real time",
realTimeOpts: new(ClockOpts),
start: time.Unix(12345, 0),
delay: 2 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
advanceRealTime: 5 * time.Second,
wantTime: time.Unix(12350, 0),
wantTicks: []time.Time{
time.Unix(12347, 0),
},
},
{
reset: 2 * time.Second,
advance: 5 * time.Second,
wantTime: time.Unix(12355, 0),
wantTicks: []time.Time{
time.Unix(12352, 0),
},
},
},
},
}
for _, tt := range tests {
tt := tt
t.Run(tt.name, func(t *testing.T) {
t.Parallel()
var realTimeClockForTestClock tstime.Clock
var realTimeClock *Clock
if tt.realTimeOpts != nil {
realTimeClock = NewClock(*tt.realTimeOpts)
// Passing realTimeClock into newClockInternal results in a
// non-nil interface with a nil pointer, so this is necessary.
realTimeClockForTestClock = realTimeClock
}
clock := newClockInternal(ClockOpts{
Start: tt.start,
Step: tt.step,
FollowRealTime: realTimeClock != nil,
}, realTimeClockForTestClock)
tc, tickC := clock.NewTimer(tt.delay)
timerControl := tc.(*Timer)
t.Cleanup(func() { timerControl.Stop() })
expectNoTicks(t, tickC)
for i, step := range tt.steps {
if step.stop {
if got := timerControl.Stop(); got != step.stopReturn {
t.Errorf("step %v Stop returned %v, want %v", i, got, step.stopReturn)
}
}
if !step.resetAbsolute.IsZero() {
if got := timerControl.ResetAbsolute(step.resetAbsolute); got != step.resetReturn {
t.Errorf("step %v Reset returned %v, want %v", i, got, step.resetReturn)
}
}
if step.reset > 0 {
if got := timerControl.Reset(step.reset); got != step.resetReturn {
t.Errorf("step %v Reset returned %v, want %v", i, got, step.resetReturn)
}
}
if step.setStep > 0 {
clock.SetStep(step.setStep)
}
if step.advance > 0 {
clock.Advance(step.advance)
}
if step.advanceRealTime > 0 {
realTimeClock.Advance(step.advanceRealTime)
}
if now := clock.Now(); !step.wantTime.IsZero() && !now.Equal(step.wantTime) {
t.Errorf("step %v now = %v, want %v", i, now, step.wantTime)
}
for j, want := range step.wantTicks {
select {
case tick := <-tickC:
if tick.Equal(want) {
continue
}
t.Errorf("step %v tick %v = %v, want %v", i, j, tick, want)
default:
t.Errorf("step %v tick %v missing", i, j)
}
}
expectNoTicks(t, tickC)
}
})
}
}
type testEvent struct {
fireTimes []time.Time
scheduleTimes []time.Time
}
func (te *testEvent) Fire(t time.Time) time.Time {
var ret time.Time
te.fireTimes = append(te.fireTimes, t)
if len(te.scheduleTimes) > 0 {
ret = te.scheduleTimes[0]
te.scheduleTimes = te.scheduleTimes[1:]
}
return ret
}
func TestEventManager(t *testing.T) {
t.Parallel()
var em eventManager
testEvents := []testEvent{
{
scheduleTimes: []time.Time{
time.Unix(12300, 0), // step 1
time.Unix(12340, 0), // step 1
time.Unix(12345, 0), // step 1
time.Unix(12346, 0), // step 1
time.Unix(12347, 0), // step 3
time.Unix(12348, 0), // step 4
time.Unix(12349, 0), // step 4
},
},
{
scheduleTimes: []time.Time{
time.Unix(12350, 0), // step 4
time.Unix(12360, 0), // step 5
time.Unix(12370, 0), // rescheduled
time.Unix(12380, 0), // step 6
time.Unix(12381, 0), // step 6
time.Unix(12382, 0), // step 6
time.Unix(12393, 0), // stopped
},
},
{
scheduleTimes: []time.Time{
time.Unix(12350, 1), // step 4
time.Unix(12360, 1), // rescheduled
time.Unix(12370, 1), // step 6
time.Unix(12380, 1), // step 6
time.Unix(12381, 1), // step 6
time.Unix(12382, 1), // step 6
time.Unix(12383, 1), // step 6
},
},
{
scheduleTimes: []time.Time{
time.Unix(12355, 0), // step 5
time.Unix(12365, 0), // step 5
time.Unix(12370, 0), // step 6
time.Unix(12390, 0), // step 6
time.Unix(12391, 0), // step 7
time.Unix(12392, 0), // step 7
time.Unix(12393, 0), // step 7
},
},
{
scheduleTimes: []time.Time{
time.Unix(100000, 0), // step 7
},
},
{
scheduleTimes: []time.Time{
time.Unix(12346, 0), // step 1
},
},
{
scheduleTimes: []time.Time{
time.Unix(12305, 0), // step 5
},
},
{
scheduleTimes: []time.Time{
time.Unix(12372, 0), // step 6
time.Unix(12374, 0), // step 6
time.Unix(12376, 0), // step 6
time.Unix(12386, 0), // step 6
time.Unix(12396, 0), // step 7
},
},
}
steps := []struct {
reschedule []int
stop []int
advanceTo time.Time
want map[int][]time.Time
waitingEvents int
}{
{
advanceTo: time.Unix(12345, 0),
},
{
reschedule: []int{0, 1, 2, 3, 4, 5}, // add 0, 1, 2, 3, 4, 5
advanceTo: time.Unix(12346, 0),
want: map[int][]time.Time{
0: {
time.Unix(12300, 0),
time.Unix(12340, 0),
time.Unix(12345, 0),
time.Unix(12346, 0),
},
5: {
time.Unix(12346, 0),
},
},
waitingEvents: 5, // scheduled 0, 1, 2, 3, 4, 5; retired 5
},
{
advanceTo: time.Unix(12346, 50),
waitingEvents: 5, // no change
},
{
advanceTo: time.Unix(12347, 50),
want: map[int][]time.Time{
0: {
time.Unix(12347, 0),
},
},
waitingEvents: 5, // no change
},
{
advanceTo: time.Unix(12350, 50),
want: map[int][]time.Time{
0: {
time.Unix(12348, 0),
time.Unix(12349, 0),
},
1: {
time.Unix(12350, 0),
},
2: {
time.Unix(12350, 1),
},
},
waitingEvents: 4, // retired 0
},
{
reschedule: []int{6, 7}, // add 6, 7
stop: []int{2},
advanceTo: time.Unix(12365, 0),
want: map[int][]time.Time{
1: {
time.Unix(12360, 0),
},
3: {
time.Unix(12355, 0),
time.Unix(12365, 0),
},
6: {
time.Unix(12305, 0),
},
},
waitingEvents: 4, // scheduled 6, 7; retired 2, 5
},
{
reschedule: []int{1, 2}, // update 1; add 2
stop: []int{6},
advanceTo: time.Unix(12390, 0),
want: map[int][]time.Time{
1: {
time.Unix(12380, 0),
time.Unix(12381, 0),
time.Unix(12382, 0),
},
2: {
time.Unix(12370, 1),
time.Unix(12380, 1),
time.Unix(12381, 1),
time.Unix(12382, 1),
time.Unix(12383, 1),
},
3: {
time.Unix(12370, 0),
time.Unix(12390, 0),
},
7: {
time.Unix(12372, 0),
time.Unix(12374, 0),
time.Unix(12376, 0),
time.Unix(12386, 0),
},
},
waitingEvents: 3, // scheduled 2, retired 2, stopped 6
},
{
stop: []int{1}, // no-op: already stopped
advanceTo: time.Unix(200000, 0),
want: map[int][]time.Time{
3: {
time.Unix(12391, 0),
time.Unix(12392, 0),
time.Unix(12393, 0),
},
4: {
time.Unix(100000, 0),
},
7: {
time.Unix(12396, 0),
},
},
waitingEvents: 0, // retired 3, 4, 7
},
{
advanceTo: time.Unix(300000, 0),
},
}
for i, step := range steps {
for _, idx := range step.reschedule {
ev := &testEvents[idx]
t := ev.scheduleTimes[0]
ev.scheduleTimes = ev.scheduleTimes[1:]
em.Reschedule(ev, t)
}
for _, idx := range step.stop {
ev := &testEvents[idx]
em.Reschedule(ev, time.Time{})
}
em.AdvanceTo(step.advanceTo)
for j := range testEvents {
if !slices.Equal(testEvents[j].fireTimes, step.want[j]) {
t.Errorf("step %v event %v fire times = %v, want %v", i, j, testEvents[j].fireTimes, step.want[j])
}
testEvents[j].fireTimes = nil
}
}
}
func TestClockFollowRealTime(t *testing.T) {
t.Parallel()
type advanceInfo struct {
when int
advanceTestClock time.Duration
advanceTestClockTo time.Time
advanceRealTimeClock time.Duration
}
tests := []struct {
name string
start time.Time
wantStart time.Time // This may differ from start when start.IsZero().
realTimeClockOpts ClockOpts
advances []advanceInfo
wants []time.Time // The return values of sequential calls to Now().
}{
{
name: "increment ms then advance 1s",
start: time.Unix(12345, 1000),
wantStart: time.Unix(12345, 1000),
advances: []advanceInfo{
{
when: 1,
advanceRealTimeClock: 1000,
},
{
when: 2,
advanceRealTimeClock: 1000,
},
{
when: 3,
advanceRealTimeClock: 1000,
},
{
when: 4,
advanceTestClock: time.Second,
},
{
when: 5,
advanceRealTimeClock: 1000,
},
{
when: 6,
advanceRealTimeClock: 1000,
},
{
when: 7,
advanceRealTimeClock: 1000,
},
},
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 2000),
time.Unix(12345, 3000),
time.Unix(12345, 4000),
time.Unix(12346, 4000),
time.Unix(12346, 5000),
time.Unix(12346, 6000),
time.Unix(12346, 7000),
},
},
{
name: "multiple advances over time",
start: time.Unix(12345, 1000),
wantStart: time.Unix(12345, 1000),
advances: []advanceInfo{
{
when: 1,
advanceRealTimeClock: 1,
},
{
when: 2,
advanceTestClock: time.Second,
},
{
when: 3,
advanceRealTimeClock: 1,
},
{
when: 4,
advanceTestClock: 0,
},
{
when: 5,
advanceRealTimeClock: 1,
},
{
when: 6,
advanceTestClock: 1000,
},
{
when: 7,
advanceRealTimeClock: 1,
},
},
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 1001),
time.Unix(12346, 1001),
time.Unix(12346, 1002),
time.Unix(12346, 1002),
time.Unix(12346, 1003),
time.Unix(12346, 2003),
time.Unix(12346, 2004),
},
},
{
name: "multiple advances at once",
start: time.Unix(12345, 1000),
wantStart: time.Unix(12345, 1000),
advances: []advanceInfo{
{
when: 1,
advanceRealTimeClock: 1,
},
{
when: 2,
advanceTestClock: time.Second,
},
{
when: 2,
advanceTestClock: 0,
},
{
when: 2,
advanceTestClock: 1000,
},
{
when: 3,
advanceRealTimeClock: 1,
},
},
wants: []time.Time{
time.Unix(12345, 1000),
time.Unix(12345, 1001),
time.Unix(12346, 2001),
time.Unix(12346, 2002),
},
},
{
name: "changes at start",
start: time.Unix(12345, 1000),
wantStart: time.Unix(12345, 1000),
advances: []advanceInfo{
{
when: 0,
advanceTestClock: time.Second,
},
{
when: 0,
advanceTestClock: 1000,
},
{
when: 1,
advanceRealTimeClock: 5,
},
{
when: 2,
advanceRealTimeClock: 5,
},
{
when: 3,
advanceRealTimeClock: 5,
},
},
wants: []time.Time{
time.Unix(12346, 2000),
time.Unix(12346, 2005),
time.Unix(12346, 2010),
time.Unix(12346, 2015),
},
},
{
name: "start from current time",
realTimeClockOpts: ClockOpts{
Start: time.Unix(12345, 0),
},
wantStart: time.Unix(12345, 0),
advances: []advanceInfo{
{
when: 1,
advanceTestClock: time.Second,
},
{
when: 2,
advanceRealTimeClock: 10 * time.Second,
},
{
when: 3,
advanceTestClock: time.Minute,
},
{
when: 4,
advanceRealTimeClock: time.Hour,
},
{
when: 5,
advanceTestClockTo: time.Unix(100, 0),
},
{
when: 6,
advanceRealTimeClock: time.Hour,
},
},
wants: []time.Time{
time.Unix(12345, 0),
time.Unix(12346, 0),
time.Unix(12356, 0),
time.Unix(12416, 0),
time.Unix(16016, 0),
time.Unix(100, 0),
time.Unix(3700, 0),
},
},
}
for _, tt := range tests {
tt := tt
t.Run(tt.name, func(t *testing.T) {
t.Parallel()
realTimeClock := NewClock(tt.realTimeClockOpts)
clock := newClockInternal(ClockOpts{
Start: tt.start,
FollowRealTime: true,
}, realTimeClock)
changeIndex := 0
for i := range tt.wants {
for len(tt.advances) > changeIndex && tt.advances[changeIndex].when == i {
advance := tt.advances[changeIndex]
if advance.advanceTestClockTo.IsZero() {
clock.Advance(advance.advanceTestClock)
} else {
clock.AdvanceTo(advance.advanceTestClockTo)
}
realTimeClock.Advance(advance.advanceRealTimeClock)
changeIndex++
}
if start := clock.GetStart(); !start.Equal(tt.wantStart) {
t.Errorf("clock has start %v, want %v", start, tt.wantStart)
}
if got := clock.Now(); !got.Equal(tt.wants[i]) {
t.Errorf("step %v: clock.Now() = %v, want %v", i, got, tt.wants[i])
}
if got := clock.PeekNow(); !got.Equal(tt.wants[i]) {
t.Errorf("step %v: clock.PeekNow() = %v, want %v", i, got, tt.wants[i])
}
}
})
}
}
func TestAfterFunc(t *testing.T) {
t.Parallel()
type testStep struct {
stop bool
stopReturn bool // The expected return value for Stop() if stop is true.
reset time.Duration
resetAbsolute time.Time
resetReturn bool // The expected return value for Reset() or ResetAbsolute().
setStep time.Duration
advance time.Duration
advanceRealTime time.Duration
wantTime time.Time
wantTick bool
}
tests := []struct {
name string
realTimeOpts *ClockOpts
start time.Time
step time.Duration
delay time.Duration
steps []testStep
}{
{
name: "no tick advance",
start: time.Unix(12345, 0),
delay: time.Second,
steps: []testStep{
{
advance: time.Second - 1,
wantTime: time.Unix(12345, 999_999_999),
},
},
},
{
name: "no tick step",
start: time.Unix(12345, 0),
step: time.Second - 1,
delay: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12345, 999_999_999),
},
},
},
{
name: "single tick advance exact",
start: time.Unix(12345, 0),
delay: time.Second,
steps: []testStep{
{
advance: time.Second,
wantTime: time.Unix(12346, 0),
wantTick: true,
},
{
advance: time.Second,
wantTime: time.Unix(12347, 0),
},
},
},
{
name: "single tick advance extra",
start: time.Unix(12345, 0),
delay: time.Second,
steps: []testStep{
{
advance: time.Second + 1,
wantTime: time.Unix(12346, 1),
wantTick: true,
},
{
advance: time.Second,
wantTime: time.Unix(12347, 1),
},
},
},
{
name: "single tick step exact",
start: time.Unix(12345, 0),
step: time.Second,
delay: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 0),
wantTick: true,
},
{
wantTime: time.Unix(12347, 0),
},
},
},
{
name: "single tick step extra",
start: time.Unix(12345, 0),
step: time.Second + 1,
delay: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 1),
wantTick: true,
},
{
wantTime: time.Unix(12347, 2),
},
},
},
{
name: "reset for single tick per advance",
start: time.Unix(12345, 0),
delay: 3 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
advance: 4 * time.Second,
wantTime: time.Unix(12349, 0),
wantTick: true,
},
{
resetAbsolute: time.Unix(12351, 0),
advance: 2 * time.Second,
wantTime: time.Unix(12351, 0),
wantTick: true,
},
{
reset: 3 * time.Second,
advance: 2 * time.Second,
wantTime: time.Unix(12353, 0),
},
{
advance: 2 * time.Second,
wantTime: time.Unix(12355, 0),
wantTick: true,
},
{
advance: 10 * time.Second,
wantTime: time.Unix(12365, 0),
},
},
},
{
name: "reset for single tick per step",
start: time.Unix(12345, 0),
step: 2 * time.Second,
delay: 3 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
},
{
wantTime: time.Unix(12349, 0),
wantTick: true,
},
{
reset: time.Second,
wantTime: time.Unix(12351, 0),
wantTick: true,
},
{
resetAbsolute: time.Unix(12354, 0),
wantTime: time.Unix(12353, 0),
},
{
wantTime: time.Unix(12355, 0),
wantTick: true,
},
},
},
{
name: "reset while active",
start: time.Unix(12345, 0),
step: 2 * time.Second,
delay: 3 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
},
{
reset: 3 * time.Second,
resetReturn: true,
wantTime: time.Unix(12349, 0),
},
{
resetAbsolute: time.Unix(12354, 0),
resetReturn: true,
wantTime: time.Unix(12351, 0),
},
{
wantTime: time.Unix(12353, 0),
},
{
wantTime: time.Unix(12355, 0),
wantTick: true,
},
},
},
{
name: "stop after fire",
start: time.Unix(12345, 0),
step: 2 * time.Second,
delay: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
wantTick: true,
},
{
stop: true,
wantTime: time.Unix(12349, 0),
},
{
wantTime: time.Unix(12351, 0),
},
{
advance: 10 * time.Second,
wantTime: time.Unix(12361, 0),
},
},
},
{
name: "stop before fire",
start: time.Unix(12345, 0),
step: 2 * time.Second,
delay: time.Second,
steps: []testStep{
{
stop: true,
stopReturn: true,
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
},
{
wantTime: time.Unix(12349, 0),
},
{
wantTime: time.Unix(12351, 0),
},
{
advance: 10 * time.Second,
wantTime: time.Unix(12361, 0),
},
},
},
{
name: "stop after reset",
start: time.Unix(12345, 0),
step: 2 * time.Second,
delay: time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12347, 0),
wantTick: true,
},
{
reset: 10 * time.Second,
wantTime: time.Unix(12349, 0),
},
{
stop: true,
stopReturn: true,
wantTime: time.Unix(12351, 0),
},
{
advance: 10 * time.Second,
wantTime: time.Unix(12361, 0),
},
},
},
{
name: "reset while running",
start: time.Unix(12345, 0),
delay: 2 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
advance: time.Second,
wantTime: time.Unix(12346, 0),
},
{
advance: time.Second,
wantTime: time.Unix(12347, 0),
wantTick: true,
},
{
advance: time.Second,
reset: time.Second,
wantTime: time.Unix(12348, 0),
wantTick: true,
},
{
setStep: 5 * time.Second,
reset: 10 * time.Second,
wantTime: time.Unix(12353, 0),
},
{
wantTime: time.Unix(12358, 0),
wantTick: true,
},
},
},
{
name: "reset while stopped",
start: time.Unix(12345, 0),
step: time.Second,
delay: 2 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 0),
},
{
stop: true,
stopReturn: true,
wantTime: time.Unix(12347, 0),
},
{
wantTime: time.Unix(12348, 0),
},
{
wantTime: time.Unix(12349, 0),
},
{
reset: time.Second,
wantTime: time.Unix(12350, 0),
wantTick: true,
},
{
wantTime: time.Unix(12351, 0),
},
},
},
{
name: "reset absolute",
start: time.Unix(12345, 0),
step: time.Second,
delay: 2 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
wantTime: time.Unix(12346, 0),
},
{
wantTime: time.Unix(12347, 0),
wantTick: true,
},
{
resetAbsolute: time.Unix(12354, 50),
advance: 7 * time.Second,
wantTime: time.Unix(12354, 0),
},
{
wantTime: time.Unix(12355, 0),
wantTick: true,
},
{
wantTime: time.Unix(12356, 0),
},
},
},
{
name: "follow real time",
realTimeOpts: new(ClockOpts),
start: time.Unix(12345, 0),
delay: 2 * time.Second,
steps: []testStep{
{
wantTime: time.Unix(12345, 0),
},
{
advanceRealTime: 5 * time.Second,
wantTime: time.Unix(12350, 0),
wantTick: true,
},
{
reset: 2 * time.Second,
advance: 5 * time.Second,
wantTime: time.Unix(12355, 0),
wantTick: true,
},
},
},
}
for _, tt := range tests {
tt := tt
t.Run(tt.name, func(t *testing.T) {
t.Parallel()
var realTimeClockForTestClock tstime.Clock
var realTimeClock *Clock
if tt.realTimeOpts != nil {
realTimeClock = NewClock(*tt.realTimeOpts)
// Passing realTimeClock into newClockInternal results in a
// non-nil interface with a nil pointer, so this is necessary.
realTimeClockForTestClock = realTimeClock
}
var gotTick atomic.Bool
clock := newClockInternal(ClockOpts{
Start: tt.start,
Step: tt.step,
FollowRealTime: realTimeClock != nil,
}, realTimeClockForTestClock)
tc := clock.AfterFunc(tt.delay, func() {
if gotTick.Swap(true) == true {
t.Error("multiple ticks detected")
}
})
timerControl := tc.(*Timer)
t.Cleanup(func() { timerControl.Stop() })
if gotTick.Load() {
t.Error("initial tick detected, want none")
}
for i, step := range tt.steps {
if step.stop {
if got := timerControl.Stop(); got != step.stopReturn {
t.Errorf("step %v Stop returned %v, want %v", i, got, step.stopReturn)
}
}
if !step.resetAbsolute.IsZero() {
if got := timerControl.ResetAbsolute(step.resetAbsolute); got != step.resetReturn {
t.Errorf("step %v Reset returned %v, want %v", i, got, step.resetReturn)
}
}
if step.reset > 0 {
if got := timerControl.Reset(step.reset); got != step.resetReturn {
t.Errorf("step %v Reset returned %v, want %v", i, got, step.resetReturn)
}
}
if step.setStep > 0 {
clock.SetStep(step.setStep)
}
if step.advance > 0 {
clock.Advance(step.advance)
}
if step.advanceRealTime > 0 {
realTimeClock.Advance(step.advanceRealTime)
}
if now := clock.Now(); !step.wantTime.IsZero() && !now.Equal(step.wantTime) {
t.Errorf("step %v now = %v, want %v", i, now, step.wantTime)
}
if got := gotTick.Swap(false); got != step.wantTick {
t.Errorf("step %v tick %v, want %v", i, got, step.wantTick)
}
}
})
}
}
func TestSince(t *testing.T) {
t.Parallel()
tests := []struct {
name string
start time.Time
since time.Time
want time.Duration
}{
{
name: "positive",
start: time.Unix(12345, 1000),
since: time.Unix(11111, 1000),
want: 1234 * time.Second,
},
{
name: "negative",
start: time.Unix(12345, 1000),
since: time.Unix(15436, 1000),
want: -3091 * time.Second,
},
{
name: "zero",
start: time.Unix(12345, 1000),
since: time.Unix(12345, 1000),
want: 0,
},
}
for _, tt := range tests {
tt := tt
t.Run(tt.name, func(t *testing.T) {
t.Parallel()
clock := NewClock(ClockOpts{
Start: tt.start,
})
got := clock.Since(tt.since)
if got != tt.want {
t.Errorf("Since duration %v, want %v", got, tt.want)
}
})
}
}