vendor/github.com/jonboulle/clockwork/clockwork.go - voltha-go - Gitiles

 package clockwork

 import (
 	"sync"
 	"time"
 )

 // Clock provides an interface that packages can use instead of directly
 // using the time module, so that chronology-related behavior can be tested
 type Clock interface {
 	After(d time.Duration) <-chan time.Time
 	Sleep(d time.Duration)
 	Now() time.Time
 	Since(t time.Time) time.Duration
 	NewTicker(d time.Duration) Ticker
 }

 // FakeClock provides an interface for a clock which can be
 // manually advanced through time
 type FakeClock interface {
 	Clock
 	// Advance advances the FakeClock to a new point in time, ensuring any existing
 	// sleepers are notified appropriately before returning
 	Advance(d time.Duration)
 	// BlockUntil will block until the FakeClock has the given number of
 	// sleepers (callers of Sleep or After)
 	BlockUntil(n int)
 }

 // NewRealClock returns a Clock which simply delegates calls to the actual time
 // package; it should be used by packages in production.
 func NewRealClock() Clock {
 	return &realClock{}
 }

 // NewFakeClock returns a FakeClock implementation which can be
 // manually advanced through time for testing. The initial time of the
 // FakeClock will be an arbitrary non-zero time.
 func NewFakeClock() FakeClock {
 	// use a fixture that does not fulfill Time.IsZero()
 	return NewFakeClockAt(time.Date(1984, time.April, 4, 0, 0, 0, 0, time.UTC))
 }

 // NewFakeClockAt returns a FakeClock initialised at the given time.Time.
 func NewFakeClockAt(t time.Time) FakeClock {
 	return &fakeClock{
 		time: t,
 	}
 }

 type realClock struct{}

 func (rc *realClock) After(d time.Duration) <-chan time.Time {
 	return time.After(d)
 }

 func (rc *realClock) Sleep(d time.Duration) {
 	time.Sleep(d)
 }

 func (rc *realClock) Now() time.Time {
 	return time.Now()
 }

 func (rc *realClock) Since(t time.Time) time.Duration {
 	return rc.Now().Sub(t)
 }

 func (rc *realClock) NewTicker(d time.Duration) Ticker {
 	return &realTicker{time.NewTicker(d)}
 }

 type fakeClock struct {
 	sleepers []*sleeper
 	blockers []*blocker
 	time     time.Time

 	l sync.RWMutex
 }

 // sleeper represents a caller of After or Sleep
 type sleeper struct {
 	until time.Time
 	done  chan time.Time
 }

 // blocker represents a caller of BlockUntil
 type blocker struct {
 	count int
 	ch    chan struct{}
 }

 // After mimics time.After; it waits for the given duration to elapse on the
 // fakeClock, then sends the current time on the returned channel.
 func (fc *fakeClock) After(d time.Duration) <-chan time.Time {
 	fc.l.Lock()
 	defer fc.l.Unlock()
 	now := fc.time
 	done := make(chan time.Time, 1)
 	if d.Nanoseconds() <= 0 {
 		// special case - trigger immediately
 		done <- now
 	} else {
 		// otherwise, add to the set of sleepers
 		s := &sleeper{
 			until: now.Add(d),
 			done:  done,
 		}
 		fc.sleepers = append(fc.sleepers, s)
 		// and notify any blockers
 		fc.blockers = notifyBlockers(fc.blockers, len(fc.sleepers))
 	}
 	return done
 }

 // notifyBlockers notifies all the blockers waiting until the
 // given number of sleepers are waiting on the fakeClock. It
 // returns an updated slice of blockers (i.e. those still waiting)
 func notifyBlockers(blockers []*blocker, count int) (newBlockers []*blocker) {
 	for _, b := range blockers {
 		if b.count == count {
 			close(b.ch)
 		} else {
 			newBlockers = append(newBlockers, b)
 		}
 	}
 	return
 }

 // Sleep blocks until the given duration has passed on the fakeClock
 func (fc *fakeClock) Sleep(d time.Duration) {
 	<-fc.After(d)
 }

 // Time returns the current time of the fakeClock
 func (fc *fakeClock) Now() time.Time {
 	fc.l.RLock()
 	t := fc.time
 	fc.l.RUnlock()
 	return t
 }

 // Since returns the duration that has passed since the given time on the fakeClock
 func (fc *fakeClock) Since(t time.Time) time.Duration {
 	return fc.Now().Sub(t)
 }

 func (fc *fakeClock) NewTicker(d time.Duration) Ticker {
 	ft := &fakeTicker{
 		c:      make(chan time.Time, 1),
 		stop:   make(chan bool, 1),
 		clock:  fc,
 		period: d,
 	}
 	ft.runTickThread()
 	return ft
 }

 // Advance advances fakeClock to a new point in time, ensuring channels from any
 // previous invocations of After are notified appropriately before returning
 func (fc *fakeClock) Advance(d time.Duration) {
 	fc.l.Lock()
 	defer fc.l.Unlock()
 	end := fc.time.Add(d)
 	var newSleepers []*sleeper
 	for _, s := range fc.sleepers {
 		if end.Sub(s.until) >= 0 {
 			s.done <- end
 		} else {
 			newSleepers = append(newSleepers, s)
 		}
 	}
 	fc.sleepers = newSleepers
 	fc.blockers = notifyBlockers(fc.blockers, len(fc.sleepers))
 	fc.time = end
 }

 // BlockUntil will block until the fakeClock has the given number of sleepers
 // (callers of Sleep or After)
 func (fc *fakeClock) BlockUntil(n int) {
 	fc.l.Lock()
 	// Fast path: current number of sleepers is what we're looking for
 	if len(fc.sleepers) == n {
 		fc.l.Unlock()
 		return
 	}
 	// Otherwise, set up a new blocker
 	b := &blocker{
 		count: n,
 		ch:    make(chan struct{}),
 	}
 	fc.blockers = append(fc.blockers, b)
 	fc.l.Unlock()
 	<-b.ch
 }
	package clockwork

	import (
	"sync"
	"time"
	)

	// Clock provides an interface that packages can use instead of directly
	// using the time module, so that chronology-related behavior can be tested
	type Clock interface {
	After(d time.Duration) <-chan time.Time
	Sleep(d time.Duration)
	Now() time.Time
	Since(t time.Time) time.Duration
	NewTicker(d time.Duration) Ticker
	}

	// FakeClock provides an interface for a clock which can be
	// manually advanced through time
	type FakeClock interface {
	Clock
	// Advance advances the FakeClock to a new point in time, ensuring any existing
	// sleepers are notified appropriately before returning
	Advance(d time.Duration)
	// BlockUntil will block until the FakeClock has the given number of
	// sleepers (callers of Sleep or After)
	BlockUntil(n int)
	}

	// NewRealClock returns a Clock which simply delegates calls to the actual time
	// package; it should be used by packages in production.
	func NewRealClock() Clock {
	return &realClock{}
	}

	// NewFakeClock returns a FakeClock implementation which can be
	// manually advanced through time for testing. The initial time of the
	// FakeClock will be an arbitrary non-zero time.
	func NewFakeClock() FakeClock {
	// use a fixture that does not fulfill Time.IsZero()
	return NewFakeClockAt(time.Date(1984, time.April, 4, 0, 0, 0, 0, time.UTC))
	}

	// NewFakeClockAt returns a FakeClock initialised at the given time.Time.
	func NewFakeClockAt(t time.Time) FakeClock {
	return &fakeClock{
	time: t,
	}
	}

	type realClock struct{}

	func (rc *realClock) After(d time.Duration) <-chan time.Time {
	return time.After(d)
	}

	func (rc *realClock) Sleep(d time.Duration) {
	time.Sleep(d)
	}

	func (rc *realClock) Now() time.Time {
	return time.Now()
	}

	func (rc *realClock) Since(t time.Time) time.Duration {
	return rc.Now().Sub(t)
	}

	func (rc *realClock) NewTicker(d time.Duration) Ticker {
	return &realTicker{time.NewTicker(d)}
	}

	type fakeClock struct {
	sleepers []*sleeper
	blockers []*blocker
	time time.Time

	l sync.RWMutex
	}

	// sleeper represents a caller of After or Sleep
	type sleeper struct {
	until time.Time
	done chan time.Time
	}

	// blocker represents a caller of BlockUntil
	type blocker struct {
	count int
	ch chan struct{}
	}

	// After mimics time.After; it waits for the given duration to elapse on the
	// fakeClock, then sends the current time on the returned channel.
	func (fc *fakeClock) After(d time.Duration) <-chan time.Time {
	fc.l.Lock()
	defer fc.l.Unlock()
	now := fc.time
	done := make(chan time.Time, 1)
	if d.Nanoseconds() <= 0 {
	// special case - trigger immediately
	done <- now
	} else {
	// otherwise, add to the set of sleepers
	s := &sleeper{
	until: now.Add(d),
	done: done,
	}
	fc.sleepers = append(fc.sleepers, s)
	// and notify any blockers
	fc.blockers = notifyBlockers(fc.blockers, len(fc.sleepers))
	}
	return done
	}

	// notifyBlockers notifies all the blockers waiting until the
	// given number of sleepers are waiting on the fakeClock. It
	// returns an updated slice of blockers (i.e. those still waiting)
	func notifyBlockers(blockers []blocker, count int) (newBlockers []blocker) {
	for _, b := range blockers {
	if b.count == count {
	close(b.ch)
	} else {
	newBlockers = append(newBlockers, b)
	}
	}
	return
	}

	// Sleep blocks until the given duration has passed on the fakeClock
	func (fc *fakeClock) Sleep(d time.Duration) {
	<-fc.After(d)
	}

	// Time returns the current time of the fakeClock
	func (fc *fakeClock) Now() time.Time {
	fc.l.RLock()
	t := fc.time
	fc.l.RUnlock()
	return t
	}

	// Since returns the duration that has passed since the given time on the fakeClock
	func (fc *fakeClock) Since(t time.Time) time.Duration {
	return fc.Now().Sub(t)
	}

	func (fc *fakeClock) NewTicker(d time.Duration) Ticker {
	ft := &fakeTicker{
	c: make(chan time.Time, 1),
	stop: make(chan bool, 1),
	clock: fc,
	period: d,
	}
	ft.runTickThread()
	return ft
	}

	// Advance advances fakeClock to a new point in time, ensuring channels from any
	// previous invocations of After are notified appropriately before returning
	func (fc *fakeClock) Advance(d time.Duration) {
	fc.l.Lock()
	defer fc.l.Unlock()
	end := fc.time.Add(d)
	var newSleepers []*sleeper
	for _, s := range fc.sleepers {
	if end.Sub(s.until) >= 0 {
	s.done <- end
	} else {
	newSleepers = append(newSleepers, s)
	}
	}
	fc.sleepers = newSleepers
	fc.blockers = notifyBlockers(fc.blockers, len(fc.sleepers))
	fc.time = end
	}

	// BlockUntil will block until the fakeClock has the given number of sleepers
	// (callers of Sleep or After)
	func (fc *fakeClock) BlockUntil(n int) {
	fc.l.Lock()
	// Fast path: current number of sleepers is what we're looking for
	if len(fc.sleepers) == n {
	fc.l.Unlock()
	return
	}
	// Otherwise, set up a new blocker
	b := &blocker{
	count: n,
	ch: make(chan struct{}),
	}
	fc.blockers = append(fc.blockers, b)
	fc.l.Unlock()
	<-b.ch
	}