k3s/vendor/k8s.io/apimachinery/pkg/watch/mux.go

261 lines
7.5 KiB
Go

/*
Copyright 2014 The Kubernetes Authors.
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/
package watch
import (
"sync"
"k8s.io/apimachinery/pkg/runtime"
"k8s.io/apimachinery/pkg/runtime/schema"
)
// FullChannelBehavior controls how the Broadcaster reacts if a watcher's watch
// channel is full.
type FullChannelBehavior int
const (
WaitIfChannelFull FullChannelBehavior = iota
DropIfChannelFull
)
// Buffer the incoming queue a little bit even though it should rarely ever accumulate
// anything, just in case a few events are received in such a short window that
// Broadcaster can't move them onto the watchers' queues fast enough.
const incomingQueueLength = 25
// Broadcaster distributes event notifications among any number of watchers. Every event
// is delivered to every watcher.
type Broadcaster struct {
// TODO: see if this lock is needed now that new watchers go through
// the incoming channel.
lock sync.Mutex
watchers map[int64]*broadcasterWatcher
nextWatcher int64
distributing sync.WaitGroup
incoming chan Event
// How large to make watcher's channel.
watchQueueLength int
// If one of the watch channels is full, don't wait for it to become empty.
// Instead just deliver it to the watchers that do have space in their
// channels and move on to the next event.
// It's more fair to do this on a per-watcher basis than to do it on the
// "incoming" channel, which would allow one slow watcher to prevent all
// other watchers from getting new events.
fullChannelBehavior FullChannelBehavior
}
// NewBroadcaster creates a new Broadcaster. queueLength is the maximum number of events to queue per watcher.
// It is guaranteed that events will be distributed in the order in which they occur,
// but the order in which a single event is distributed among all of the watchers is unspecified.
func NewBroadcaster(queueLength int, fullChannelBehavior FullChannelBehavior) *Broadcaster {
m := &Broadcaster{
watchers: map[int64]*broadcasterWatcher{},
incoming: make(chan Event, incomingQueueLength),
watchQueueLength: queueLength,
fullChannelBehavior: fullChannelBehavior,
}
m.distributing.Add(1)
go m.loop()
return m
}
const internalRunFunctionMarker = "internal-do-function"
// a function type we can shoehorn into the queue.
type functionFakeRuntimeObject func()
func (obj functionFakeRuntimeObject) GetObjectKind() schema.ObjectKind {
return schema.EmptyObjectKind
}
func (obj functionFakeRuntimeObject) DeepCopyObject() runtime.Object {
if obj == nil {
return nil
}
// funcs are immutable. Hence, just return the original func.
return obj
}
// Execute f, blocking the incoming queue (and waiting for it to drain first).
// The purpose of this terrible hack is so that watchers added after an event
// won't ever see that event, and will always see any event after they are
// added.
func (b *Broadcaster) blockQueue(f func()) {
var wg sync.WaitGroup
wg.Add(1)
b.incoming <- Event{
Type: internalRunFunctionMarker,
Object: functionFakeRuntimeObject(func() {
defer wg.Done()
f()
}),
}
wg.Wait()
}
// Watch adds a new watcher to the list and returns an Interface for it.
// Note: new watchers will only receive new events. They won't get an entire history
// of previous events.
func (m *Broadcaster) Watch() Interface {
var w *broadcasterWatcher
m.blockQueue(func() {
m.lock.Lock()
defer m.lock.Unlock()
id := m.nextWatcher
m.nextWatcher++
w = &broadcasterWatcher{
result: make(chan Event, m.watchQueueLength),
stopped: make(chan struct{}),
id: id,
m: m,
}
m.watchers[id] = w
})
return w
}
// WatchWithPrefix adds a new watcher to the list and returns an Interface for it. It sends
// queuedEvents down the new watch before beginning to send ordinary events from Broadcaster.
// The returned watch will have a queue length that is at least large enough to accommodate
// all of the items in queuedEvents.
func (m *Broadcaster) WatchWithPrefix(queuedEvents []Event) Interface {
var w *broadcasterWatcher
m.blockQueue(func() {
m.lock.Lock()
defer m.lock.Unlock()
id := m.nextWatcher
m.nextWatcher++
length := m.watchQueueLength
if n := len(queuedEvents) + 1; n > length {
length = n
}
w = &broadcasterWatcher{
result: make(chan Event, length),
stopped: make(chan struct{}),
id: id,
m: m,
}
m.watchers[id] = w
for _, e := range queuedEvents {
w.result <- e
}
})
return w
}
// stopWatching stops the given watcher and removes it from the list.
func (m *Broadcaster) stopWatching(id int64) {
m.lock.Lock()
defer m.lock.Unlock()
w, ok := m.watchers[id]
if !ok {
// No need to do anything, it's already been removed from the list.
return
}
delete(m.watchers, id)
close(w.result)
}
// closeAll disconnects all watchers (presumably in response to a Shutdown call).
func (m *Broadcaster) closeAll() {
m.lock.Lock()
defer m.lock.Unlock()
for _, w := range m.watchers {
close(w.result)
}
// Delete everything from the map, since presence/absence in the map is used
// by stopWatching to avoid double-closing the channel.
m.watchers = map[int64]*broadcasterWatcher{}
}
// Action distributes the given event among all watchers.
func (m *Broadcaster) Action(action EventType, obj runtime.Object) {
m.incoming <- Event{action, obj}
}
// Shutdown disconnects all watchers (but any queued events will still be distributed).
// You must not call Action or Watch* after calling Shutdown. This call blocks
// until all events have been distributed through the outbound channels. Note
// that since they can be buffered, this means that the watchers might not
// have received the data yet as it can remain sitting in the buffered
// channel.
func (m *Broadcaster) Shutdown() {
close(m.incoming)
m.distributing.Wait()
}
// loop receives from m.incoming and distributes to all watchers.
func (m *Broadcaster) loop() {
// Deliberately not catching crashes here. Yes, bring down the process if there's a
// bug in watch.Broadcaster.
for event := range m.incoming {
if event.Type == internalRunFunctionMarker {
event.Object.(functionFakeRuntimeObject)()
continue
}
m.distribute(event)
}
m.closeAll()
m.distributing.Done()
}
// distribute sends event to all watchers. Blocking.
func (m *Broadcaster) distribute(event Event) {
m.lock.Lock()
defer m.lock.Unlock()
if m.fullChannelBehavior == DropIfChannelFull {
for _, w := range m.watchers {
select {
case w.result <- event:
case <-w.stopped:
default: // Don't block if the event can't be queued.
}
}
} else {
for _, w := range m.watchers {
select {
case w.result <- event:
case <-w.stopped:
}
}
}
}
// broadcasterWatcher handles a single watcher of a broadcaster
type broadcasterWatcher struct {
result chan Event
stopped chan struct{}
stop sync.Once
id int64
m *Broadcaster
}
// ResultChan returns a channel to use for waiting on events.
func (mw *broadcasterWatcher) ResultChan() <-chan Event {
return mw.result
}
// Stop stops watching and removes mw from its list.
func (mw *broadcasterWatcher) Stop() {
mw.stop.Do(func() {
close(mw.stopped)
mw.m.stopWatching(mw.id)
})
}