pkg/locker/locker.go - third_party/github.com/moby/moby - Git at Google

 /*
 Package locker provides a mechanism for creating finer-grained locking to help
 free up more global locks to handle other tasks.

 The implementation looks close to a sync.Mutex, however the user must provide a
 reference to use to refer to the underlying lock when locking and unlocking,
 and unlock may generate an error.

 If a lock with a given name does not exist when `Lock` is called, one is
 created.
 Lock references are automatically cleaned up on `Unlock` if nothing else is
 waiting for the lock.
 */
 package locker

 import (
 	"errors"
 	"sync"
 	"sync/atomic"
 )

 // ErrNoSuchLock is returned when the requested lock does not exist
 var ErrNoSuchLock = errors.New("no such lock")

 // Locker provides a locking mechanism based on the passed in reference name
 type Locker struct {
 	mu    sync.Mutex
 	locks map[string]*lockCtr
 }

 // lockCtr is used by Locker to represent a lock with a given name.
 type lockCtr struct {
 	mu sync.Mutex
 	// waiters is the number of waiters waiting to acquire the lock
 	// this is int32 instead of uint32 so we can add `-1` in `dec()`
 	waiters int32
 }

 // inc increments the number of waiters waiting for the lock
 func (l *lockCtr) inc() {
 	atomic.AddInt32(&l.waiters, 1)
 }

 // dec decrements the number of waiters waiting on the lock
 func (l *lockCtr) dec() {
 	atomic.AddInt32(&l.waiters, -1)
 }

 // count gets the current number of waiters
 func (l *lockCtr) count() int32 {
 	return atomic.LoadInt32(&l.waiters)
 }

 // Lock locks the mutex
 func (l *lockCtr) Lock() {
 	l.mu.Lock()
 }

 // Unlock unlocks the mutex
 func (l *lockCtr) Unlock() {
 	l.mu.Unlock()
 }

 // New creates a new Locker
 func New() *Locker {
 	return &Locker{
 		locks: make(map[string]*lockCtr),
 	}
 }

 // Lock locks a mutex with the given name. If it doesn't exist, one is created
 func (l *Locker) Lock(name string) {
 	l.mu.Lock()
 	if l.locks == nil {
 		l.locks = make(map[string]*lockCtr)
 	}

 	nameLock, exists := l.locks[name]
 	if !exists {
 		nameLock = &lockCtr{}
 		l.locks[name] = nameLock
 	}

 	// increment the nameLock waiters while inside the main mutex
 	// this makes sure that the lock isn't deleted if `Lock` and `Unlock` are called concurrently
 	nameLock.inc()
 	l.mu.Unlock()

 	// Lock the nameLock outside the main mutex so we don't block other operations
 	// once locked then we can decrement the number of waiters for this lock
 	nameLock.Lock()
 	nameLock.dec()
 }

 // Unlock unlocks the mutex with the given name
 // If the given lock is not being waited on by any other callers, it is deleted
 func (l *Locker) Unlock(name string) error {
 	l.mu.Lock()
 	nameLock, exists := l.locks[name]
 	if !exists {
 		l.mu.Unlock()
 		return ErrNoSuchLock
 	}

 	if nameLock.count() == 0 {
 		delete(l.locks, name)
 	}
 	nameLock.Unlock()

 	l.mu.Unlock()
 	return nil
 }
	/*
	Package locker provides a mechanism for creating finer-grained locking to help
	free up more global locks to handle other tasks.

	The implementation looks close to a sync.Mutex, however the user must provide a
	reference to use to refer to the underlying lock when locking and unlocking,
	and unlock may generate an error.

	If a lock with a given name does not exist when `Lock` is called, one is
	created.
	Lock references are automatically cleaned up on `Unlock` if nothing else is
	waiting for the lock.
	*/
	package locker

	import (
	"errors"
	"sync"
	"sync/atomic"
	)

	// ErrNoSuchLock is returned when the requested lock does not exist
	var ErrNoSuchLock = errors.New("no such lock")

	// Locker provides a locking mechanism based on the passed in reference name
	type Locker struct {
	mu sync.Mutex
	locks map[string]*lockCtr
	}

	// lockCtr is used by Locker to represent a lock with a given name.
	type lockCtr struct {
	mu sync.Mutex
	// waiters is the number of waiters waiting to acquire the lock
	// this is int32 instead of uint32 so we can add `-1` in `dec()`
	waiters int32
	}

	// inc increments the number of waiters waiting for the lock
	func (l *lockCtr) inc() {
	atomic.AddInt32(&l.waiters, 1)
	}

	// dec decrements the number of waiters waiting on the lock
	func (l *lockCtr) dec() {
	atomic.AddInt32(&l.waiters, -1)
	}

	// count gets the current number of waiters
	func (l *lockCtr) count() int32 {
	return atomic.LoadInt32(&l.waiters)
	}

	// Lock locks the mutex
	func (l *lockCtr) Lock() {
	l.mu.Lock()
	}

	// Unlock unlocks the mutex
	func (l *lockCtr) Unlock() {
	l.mu.Unlock()
	}

	// New creates a new Locker
	func New() *Locker {
	return &Locker{
	locks: make(map[string]*lockCtr),
	}
	}

	// Lock locks a mutex with the given name. If it doesn't exist, one is created
	func (l *Locker) Lock(name string) {
	l.mu.Lock()
	if l.locks == nil {
	l.locks = make(map[string]*lockCtr)
	}

	nameLock, exists := l.locks[name]
	if !exists {
	nameLock = &lockCtr{}
	l.locks[name] = nameLock
	}

	// increment the nameLock waiters while inside the main mutex
	// this makes sure that the lock isn't deleted if `Lock` and `Unlock` are called concurrently
	nameLock.inc()
	l.mu.Unlock()

	// Lock the nameLock outside the main mutex so we don't block other operations
	// once locked then we can decrement the number of waiters for this lock
	nameLock.Lock()
	nameLock.dec()
	}

	// Unlock unlocks the mutex with the given name
	// If the given lock is not being waited on by any other callers, it is deleted
	func (l *Locker) Unlock(name string) error {
	l.mu.Lock()
	nameLock, exists := l.locks[name]
	if !exists {
	l.mu.Unlock()
	return ErrNoSuchLock
	}

	if nameLock.count() == 0 {
	delete(l.locks, name)
	}
	nameLock.Unlock()

	l.mu.Unlock()
	return nil
	}