sequential_handler.go - external/github.com/godbus/dbus - Git at Google

 package dbus

 import (
 	"sync"
 )

 // NewSequentialSignalHandler returns an instance of a new
 // signal handler that guarantees sequential processing of signals. It is a
 // guarantee of this signal handler that signals will be written to
 // channels in the order they are received on the DBus connection.
 func NewSequentialSignalHandler() SignalHandler {
 	return &sequentialSignalHandler{}
 }

 type sequentialSignalHandler struct {
 	mu      sync.RWMutex
 	closed  bool
 	signals []*sequentialSignalChannelData
 }

 func (sh *sequentialSignalHandler) DeliverSignal(intf, name string, signal *Signal) {
 	sh.mu.RLock()
 	defer sh.mu.RUnlock()
 	if sh.closed {
 		return
 	}
 	for _, scd := range sh.signals {
 		scd.deliver(signal)
 	}
 }

 func (sh *sequentialSignalHandler) Terminate() {
 	sh.mu.Lock()
 	defer sh.mu.Unlock()
 	if sh.closed {
 		return
 	}

 	for _, scd := range sh.signals {
 		scd.close()
 		close(scd.ch)
 	}
 	sh.closed = true
 	sh.signals = nil
 }

 func (sh *sequentialSignalHandler) AddSignal(ch chan<- *Signal) {
 	sh.mu.Lock()
 	defer sh.mu.Unlock()
 	if sh.closed {
 		return
 	}
 	sh.signals = append(sh.signals, newSequentialSignalChannelData(ch))
 }

 func (sh *sequentialSignalHandler) RemoveSignal(ch chan<- *Signal) {
 	sh.mu.Lock()
 	defer sh.mu.Unlock()
 	if sh.closed {
 		return
 	}
 	for i := len(sh.signals) - 1; i >= 0; i-- {
 		if ch == sh.signals[i].ch {
 			sh.signals[i].close()
 			copy(sh.signals[i:], sh.signals[i+1:])
 			sh.signals[len(sh.signals)-1] = nil
 			sh.signals = sh.signals[:len(sh.signals)-1]
 		}
 	}
 }

 type sequentialSignalChannelData struct {
 	ch   chan<- *Signal
 	in   chan *Signal
 	done chan struct{}
 }

 func newSequentialSignalChannelData(ch chan<- *Signal) *sequentialSignalChannelData {
 	scd := &sequentialSignalChannelData{
 		ch:   ch,
 		in:   make(chan *Signal),
 		done: make(chan struct{}),
 	}
 	go scd.bufferSignals()
 	return scd
 }

 func (scd *sequentialSignalChannelData) bufferSignals() {
 	defer close(scd.done)

 	// Ensure that signals are delivered to scd.ch in the same
 	// order they are received from scd.in.
 	var queue []*Signal
 	for {
 		if len(queue) == 0 {
 			signal, ok := <- scd.in
 			if !ok {
 				return
 			}
 			queue = append(queue, signal)
 		}
 		select {
 		case scd.ch <- queue[0]:
 			copy(queue, queue[1:])
 			queue[len(queue)-1] = nil
 			queue = queue[:len(queue)-1]
 		case signal, ok := <-scd.in:
 			if !ok {
 				return
 			}
 			queue = append(queue, signal)
 		}
 	}
 }

 func (scd *sequentialSignalChannelData) deliver(signal *Signal) {
 	scd.in <- signal
 }

 func (scd *sequentialSignalChannelData) close() {
 	close(scd.in)
 	// Ensure that bufferSignals() has exited and won't attempt
 	// any future sends on scd.ch
 	<-scd.done
 }
	package dbus

	import (
	"sync"
	)

	// NewSequentialSignalHandler returns an instance of a new
	// signal handler that guarantees sequential processing of signals. It is a
	// guarantee of this signal handler that signals will be written to
	// channels in the order they are received on the DBus connection.
	func NewSequentialSignalHandler() SignalHandler {
	return &sequentialSignalHandler{}
	}

	type sequentialSignalHandler struct {
	mu sync.RWMutex
	closed bool
	signals []*sequentialSignalChannelData
	}

	func (sh sequentialSignalHandler) DeliverSignal(intf, name string, signal Signal) {
	sh.mu.RLock()
	defer sh.mu.RUnlock()
	if sh.closed {
	return
	}
	for _, scd := range sh.signals {
	scd.deliver(signal)
	}
	}

	func (sh *sequentialSignalHandler) Terminate() {
	sh.mu.Lock()
	defer sh.mu.Unlock()
	if sh.closed {
	return
	}

	for _, scd := range sh.signals {
	scd.close()
	close(scd.ch)
	}
	sh.closed = true
	sh.signals = nil
	}

	func (sh sequentialSignalHandler) AddSignal(ch chan<- Signal) {
	sh.mu.Lock()
	defer sh.mu.Unlock()
	if sh.closed {
	return
	}
	sh.signals = append(sh.signals, newSequentialSignalChannelData(ch))
	}

	func (sh sequentialSignalHandler) RemoveSignal(ch chan<- Signal) {
	sh.mu.Lock()
	defer sh.mu.Unlock()
	if sh.closed {
	return
	}
	for i := len(sh.signals) - 1; i >= 0; i-- {
	if ch == sh.signals[i].ch {
	sh.signals[i].close()
	copy(sh.signals[i:], sh.signals[i+1:])
	sh.signals[len(sh.signals)-1] = nil
	sh.signals = sh.signals[:len(sh.signals)-1]
	}
	}
	}

	type sequentialSignalChannelData struct {
	ch chan<- *Signal
	in chan *Signal
	done chan struct{}
	}

	func newSequentialSignalChannelData(ch chan<- Signal) sequentialSignalChannelData {
	scd := &sequentialSignalChannelData{
	ch: ch,
	in: make(chan *Signal),
	done: make(chan struct{}),
	}
	go scd.bufferSignals()
	return scd
	}

	func (scd *sequentialSignalChannelData) bufferSignals() {
	defer close(scd.done)

	// Ensure that signals are delivered to scd.ch in the same
	// order they are received from scd.in.
	var queue []*Signal
	for {
	if len(queue) == 0 {
	signal, ok := <- scd.in
	if !ok {
	return
	}
	queue = append(queue, signal)
	}
	select {
	case scd.ch <- queue[0]:
	copy(queue, queue[1:])
	queue[len(queue)-1] = nil
	queue = queue[:len(queue)-1]
	case signal, ok := <-scd.in:
	if !ok {
	return
	}
	queue = append(queue, signal)
	}
	}
	}

	func (scd sequentialSignalChannelData) deliver(signal Signal) {
	scd.in <- signal
	}

	func (scd *sequentialSignalChannelData) close() {
	close(scd.in)
	// Ensure that bufferSignals() has exited and won't attempt
	// any future sends on scd.ch
	<-scd.done
	}