mirror of https://github.com/k3s-io/k3s
703 lines
24 KiB
Go
703 lines
24 KiB
Go
/*
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Copyright 2015 The Kubernetes Authors.
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Licensed under the Apache License, Version 2.0 (the "License");
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you may not use this file except in compliance with the License.
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You may obtain a copy of the License at
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http://www.apache.org/licenses/LICENSE-2.0
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Unless required by applicable law or agreed to in writing, software
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distributed under the License is distributed on an "AS IS" BASIS,
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WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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See the License for the specific language governing permissions and
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limitations under the License.
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*/
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package cache
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import (
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"fmt"
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"sync"
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"time"
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"k8s.io/apimachinery/pkg/runtime"
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"k8s.io/apimachinery/pkg/util/clock"
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utilruntime "k8s.io/apimachinery/pkg/util/runtime"
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"k8s.io/apimachinery/pkg/util/wait"
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"k8s.io/client-go/util/retry"
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"k8s.io/utils/buffer"
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"k8s.io/klog"
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)
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// SharedInformer provides eventually consistent linkage of its
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// clients to the authoritative state of a given collection of
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// objects. An object is identified by its API group, kind/resource,
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// namespace, and name; the `ObjectMeta.UID` is not part of an
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// object's ID as far as this contract is concerned. One
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// SharedInformer provides linkage to objects of a particular API
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// group and kind/resource. The linked object collection of a
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// SharedInformer may be further restricted to one namespace and/or by
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// label selector and/or field selector.
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//
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// The authoritative state of an object is what apiservers provide
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// access to, and an object goes through a strict sequence of states.
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// An object state is either "absent" or present with a
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// ResourceVersion and other appropriate content.
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//
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// A SharedInformer gets object states from apiservers using a
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// sequence of LIST and WATCH operations. Through this sequence the
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// apiservers provide a sequence of "collection states" to the
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// informer, where each collection state defines the state of every
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// object of the collection. No promise --- beyond what is implied by
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// other remarks here --- is made about how one informer's sequence of
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// collection states relates to a different informer's sequence of
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// collection states.
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//
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// A SharedInformer maintains a local cache, exposed by GetStore() and
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// by GetIndexer() in the case of an indexed informer, of the state of
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// each relevant object. This cache is eventually consistent with the
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// authoritative state. This means that, unless prevented by
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// persistent communication problems, if ever a particular object ID X
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// is authoritatively associated with a state S then for every
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// SharedInformer I whose collection includes (X, S) eventually either
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// (1) I's cache associates X with S or a later state of X, (2) I is
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// stopped, or (3) the authoritative state service for X terminates.
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// To be formally complete, we say that the absent state meets any
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// restriction by label selector or field selector.
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//
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// The local cache starts out empty, and gets populated and updated
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// during `Run()`.
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//
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// As a simple example, if a collection of objects is henceforeth
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// unchanging, a SharedInformer is created that links to that
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// collection, and that SharedInformer is `Run()` then that
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// SharedInformer's cache eventually holds an exact copy of that
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// collection (unless it is stopped too soon, the authoritative state
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// service ends, or communication problems between the two
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// persistently thwart achievement).
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//
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// As another simple example, if the local cache ever holds a
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// non-absent state for some object ID and the object is eventually
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// removed from the authoritative state then eventually the object is
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// removed from the local cache (unless the SharedInformer is stopped
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// too soon, the authoritative state service ends, or communication
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// problems persistently thwart the desired result).
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//
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// The keys in the Store are of the form namespace/name for namespaced
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// objects, and are simply the name for non-namespaced objects.
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// Clients can use `MetaNamespaceKeyFunc(obj)` to extract the key for
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// a given object, and `SplitMetaNamespaceKey(key)` to split a key
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// into its constituent parts.
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//
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// A client is identified here by a ResourceEventHandler. For every
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// update to the SharedInformer's local cache and for every client
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// added before `Run()`, eventually either the SharedInformer is
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// stopped or the client is notified of the update. A client added
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// after `Run()` starts gets a startup batch of notifications of
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// additions of the object existing in the cache at the time that
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// client was added; also, for every update to the SharedInformer's
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// local cache after that client was added, eventually either the
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// SharedInformer is stopped or that client is notified of that
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// update. Client notifications happen after the corresponding cache
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// update and, in the case of a SharedIndexInformer, after the
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// corresponding index updates. It is possible that additional cache
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// and index updates happen before such a prescribed notification.
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// For a given SharedInformer and client, the notifications are
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// delivered sequentially. For a given SharedInformer, client, and
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// object ID, the notifications are delivered in order.
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//
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// A client must process each notification promptly; a SharedInformer
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// is not engineered to deal well with a large backlog of
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// notifications to deliver. Lengthy processing should be passed off
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// to something else, for example through a
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// `client-go/util/workqueue`.
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//
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// Each query to an informer's local cache --- whether a single-object
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// lookup, a list operation, or a use of one of its indices --- is
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// answered entirely from one of the collection states received by
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// that informer.
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//
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// A delete notification exposes the last locally known non-absent
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// state, except that its ResourceVersion is replaced with a
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// ResourceVersion in which the object is actually absent.
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type SharedInformer interface {
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// AddEventHandler adds an event handler to the shared informer using the shared informer's resync
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// period. Events to a single handler are delivered sequentially, but there is no coordination
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// between different handlers.
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AddEventHandler(handler ResourceEventHandler)
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// AddEventHandlerWithResyncPeriod adds an event handler to the
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// shared informer using the specified resync period. The resync
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// operation consists of delivering to the handler a create
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// notification for every object in the informer's local cache; it
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// does not add any interactions with the authoritative storage.
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AddEventHandlerWithResyncPeriod(handler ResourceEventHandler, resyncPeriod time.Duration)
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// GetStore returns the informer's local cache as a Store.
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GetStore() Store
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// GetController gives back a synthetic interface that "votes" to start the informer
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GetController() Controller
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// Run starts and runs the shared informer, returning after it stops.
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// The informer will be stopped when stopCh is closed.
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Run(stopCh <-chan struct{})
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// HasSynced returns true if the shared informer's store has been
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// informed by at least one full LIST of the authoritative state
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// of the informer's object collection. This is unrelated to "resync".
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HasSynced() bool
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// LastSyncResourceVersion is the resource version observed when last synced with the underlying
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// store. The value returned is not synchronized with access to the underlying store and is not
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// thread-safe.
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LastSyncResourceVersion() string
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}
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// SharedIndexInformer provides add and get Indexers ability based on SharedInformer.
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type SharedIndexInformer interface {
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SharedInformer
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// AddIndexers add indexers to the informer before it starts.
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AddIndexers(indexers Indexers) error
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GetIndexer() Indexer
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}
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// NewSharedInformer creates a new instance for the listwatcher.
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func NewSharedInformer(lw ListerWatcher, objType runtime.Object, resyncPeriod time.Duration) SharedInformer {
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return NewSharedIndexInformer(lw, objType, resyncPeriod, Indexers{})
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}
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// NewSharedIndexInformer creates a new instance for the listwatcher.
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func NewSharedIndexInformer(lw ListerWatcher, objType runtime.Object, defaultEventHandlerResyncPeriod time.Duration, indexers Indexers) SharedIndexInformer {
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realClock := &clock.RealClock{}
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sharedIndexInformer := &sharedIndexInformer{
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processor: &sharedProcessor{clock: realClock},
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indexer: NewIndexer(DeletionHandlingMetaNamespaceKeyFunc, indexers),
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listerWatcher: lw,
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objectType: objType,
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resyncCheckPeriod: defaultEventHandlerResyncPeriod,
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defaultEventHandlerResyncPeriod: defaultEventHandlerResyncPeriod,
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cacheMutationDetector: NewCacheMutationDetector(fmt.Sprintf("%T", objType)),
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clock: realClock,
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}
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return sharedIndexInformer
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}
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// InformerSynced is a function that can be used to determine if an informer has synced. This is useful for determining if caches have synced.
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type InformerSynced func() bool
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const (
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// syncedPollPeriod controls how often you look at the status of your sync funcs
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syncedPollPeriod = 100 * time.Millisecond
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// initialBufferSize is the initial number of event notifications that can be buffered.
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initialBufferSize = 1024
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)
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// WaitForNamedCacheSync is a wrapper around WaitForCacheSync that generates log messages
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// indicating that the caller identified by name is waiting for syncs, followed by
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// either a successful or failed sync.
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func WaitForNamedCacheSync(controllerName string, stopCh <-chan struct{}, cacheSyncs ...InformerSynced) bool {
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klog.Infof("Waiting for caches to sync for %s", controllerName)
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if !WaitForCacheSync(stopCh, cacheSyncs...) {
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utilruntime.HandleError(fmt.Errorf("unable to sync caches for %s", controllerName))
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return false
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}
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klog.Infof("Caches are synced for %s ", controllerName)
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return true
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}
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// WaitForCacheSync waits for caches to populate. It returns true if it was successful, false
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// if the controller should shutdown
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// callers should prefer WaitForNamedCacheSync()
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func WaitForCacheSync(stopCh <-chan struct{}, cacheSyncs ...InformerSynced) bool {
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err := wait.PollImmediateUntil(syncedPollPeriod,
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func() (bool, error) {
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for _, syncFunc := range cacheSyncs {
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if !syncFunc() {
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return false, nil
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}
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}
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return true, nil
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},
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stopCh)
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if err != nil {
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klog.V(2).Infof("stop requested")
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return false
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}
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klog.V(4).Infof("caches populated")
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return true
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}
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type sharedIndexInformer struct {
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indexer Indexer
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controller Controller
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processor *sharedProcessor
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cacheMutationDetector MutationDetector
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// This block is tracked to handle late initialization of the controller
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listerWatcher ListerWatcher
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objectType runtime.Object
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// resyncCheckPeriod is how often we want the reflector's resync timer to fire so it can call
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// shouldResync to check if any of our listeners need a resync.
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resyncCheckPeriod time.Duration
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// defaultEventHandlerResyncPeriod is the default resync period for any handlers added via
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// AddEventHandler (i.e. they don't specify one and just want to use the shared informer's default
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// value).
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defaultEventHandlerResyncPeriod time.Duration
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// clock allows for testability
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clock clock.Clock
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started, stopped bool
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startedLock sync.Mutex
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// blockDeltas gives a way to stop all event distribution so that a late event handler
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// can safely join the shared informer.
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blockDeltas sync.Mutex
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}
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// dummyController hides the fact that a SharedInformer is different from a dedicated one
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// where a caller can `Run`. The run method is disconnected in this case, because higher
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// level logic will decide when to start the SharedInformer and related controller.
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// Because returning information back is always asynchronous, the legacy callers shouldn't
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// notice any change in behavior.
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type dummyController struct {
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informer *sharedIndexInformer
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}
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func (v *dummyController) Run(stopCh <-chan struct{}) {
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}
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func (v *dummyController) HasSynced() bool {
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return v.informer.HasSynced()
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}
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func (v *dummyController) LastSyncResourceVersion() string {
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return ""
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}
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type updateNotification struct {
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oldObj interface{}
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newObj interface{}
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}
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type addNotification struct {
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newObj interface{}
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}
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type deleteNotification struct {
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oldObj interface{}
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}
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func (s *sharedIndexInformer) Run(stopCh <-chan struct{}) {
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defer utilruntime.HandleCrash()
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fifo := NewDeltaFIFO(MetaNamespaceKeyFunc, s.indexer)
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cfg := &Config{
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Queue: fifo,
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ListerWatcher: s.listerWatcher,
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ObjectType: s.objectType,
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FullResyncPeriod: s.resyncCheckPeriod,
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RetryOnError: false,
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ShouldResync: s.processor.shouldResync,
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Process: s.HandleDeltas,
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}
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func() {
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s.startedLock.Lock()
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defer s.startedLock.Unlock()
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s.controller = New(cfg)
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s.controller.(*controller).clock = s.clock
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s.started = true
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}()
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// Separate stop channel because Processor should be stopped strictly after controller
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processorStopCh := make(chan struct{})
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var wg wait.Group
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defer wg.Wait() // Wait for Processor to stop
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defer close(processorStopCh) // Tell Processor to stop
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wg.StartWithChannel(processorStopCh, s.cacheMutationDetector.Run)
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wg.StartWithChannel(processorStopCh, s.processor.run)
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defer func() {
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s.startedLock.Lock()
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defer s.startedLock.Unlock()
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s.stopped = true // Don't want any new listeners
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}()
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s.controller.Run(stopCh)
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}
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func (s *sharedIndexInformer) HasSynced() bool {
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s.startedLock.Lock()
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defer s.startedLock.Unlock()
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if s.controller == nil {
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return false
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}
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return s.controller.HasSynced()
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}
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func (s *sharedIndexInformer) LastSyncResourceVersion() string {
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s.startedLock.Lock()
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defer s.startedLock.Unlock()
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if s.controller == nil {
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return ""
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}
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return s.controller.LastSyncResourceVersion()
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}
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func (s *sharedIndexInformer) GetStore() Store {
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return s.indexer
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}
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func (s *sharedIndexInformer) GetIndexer() Indexer {
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return s.indexer
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}
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func (s *sharedIndexInformer) AddIndexers(indexers Indexers) error {
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s.startedLock.Lock()
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defer s.startedLock.Unlock()
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if s.started {
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s.blockDeltas.Lock()
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defer s.blockDeltas.Unlock()
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}
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return s.indexer.AddIndexers(indexers)
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}
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func (s *sharedIndexInformer) GetController() Controller {
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return &dummyController{informer: s}
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}
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func (s *sharedIndexInformer) AddEventHandler(handler ResourceEventHandler) {
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s.AddEventHandlerWithResyncPeriod(handler, s.defaultEventHandlerResyncPeriod)
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}
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func determineResyncPeriod(desired, check time.Duration) time.Duration {
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if desired == 0 {
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return desired
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}
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if check == 0 {
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klog.Warningf("The specified resyncPeriod %v is invalid because this shared informer doesn't support resyncing", desired)
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return 0
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}
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if desired < check {
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klog.Warningf("The specified resyncPeriod %v is being increased to the minimum resyncCheckPeriod %v", desired, check)
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return check
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}
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return desired
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}
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const minimumResyncPeriod = 1 * time.Second
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func (s *sharedIndexInformer) AddEventHandlerWithResyncPeriod(handler ResourceEventHandler, resyncPeriod time.Duration) {
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s.startedLock.Lock()
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defer s.startedLock.Unlock()
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if s.stopped {
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klog.V(2).Infof("Handler %v was not added to shared informer because it has stopped already", handler)
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return
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}
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if resyncPeriod > 0 {
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if resyncPeriod < minimumResyncPeriod {
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klog.Warningf("resyncPeriod %d is too small. Changing it to the minimum allowed value of %d", resyncPeriod, minimumResyncPeriod)
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resyncPeriod = minimumResyncPeriod
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}
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if resyncPeriod < s.resyncCheckPeriod {
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if s.started {
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klog.Warningf("resyncPeriod %d is smaller than resyncCheckPeriod %d and the informer has already started. Changing it to %d", resyncPeriod, s.resyncCheckPeriod, s.resyncCheckPeriod)
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resyncPeriod = s.resyncCheckPeriod
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} else {
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// if the event handler's resyncPeriod is smaller than the current resyncCheckPeriod, update
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// resyncCheckPeriod to match resyncPeriod and adjust the resync periods of all the listeners
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// accordingly
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s.resyncCheckPeriod = resyncPeriod
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s.processor.resyncCheckPeriodChanged(resyncPeriod)
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}
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}
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}
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listener := newProcessListener(handler, resyncPeriod, determineResyncPeriod(resyncPeriod, s.resyncCheckPeriod), s.clock.Now(), initialBufferSize)
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if !s.started {
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s.processor.addListener(listener)
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return
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}
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// in order to safely join, we have to
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// 1. stop sending add/update/delete notifications
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// 2. do a list against the store
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// 3. send synthetic "Add" events to the new handler
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// 4. unblock
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s.blockDeltas.Lock()
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defer s.blockDeltas.Unlock()
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s.processor.addListener(listener)
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for _, item := range s.indexer.List() {
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listener.add(addNotification{newObj: item})
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}
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}
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func (s *sharedIndexInformer) HandleDeltas(obj interface{}) error {
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s.blockDeltas.Lock()
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defer s.blockDeltas.Unlock()
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// from oldest to newest
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for _, d := range obj.(Deltas) {
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switch d.Type {
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case Sync, Added, Updated:
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isSync := d.Type == Sync
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s.cacheMutationDetector.AddObject(d.Object)
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if old, exists, err := s.indexer.Get(d.Object); err == nil && exists {
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if err := s.indexer.Update(d.Object); err != nil {
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return err
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}
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s.processor.distribute(updateNotification{oldObj: old, newObj: d.Object}, isSync)
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} else {
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if err := s.indexer.Add(d.Object); err != nil {
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return err
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}
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s.processor.distribute(addNotification{newObj: d.Object}, isSync)
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}
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case Deleted:
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if err := s.indexer.Delete(d.Object); err != nil {
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return err
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}
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s.processor.distribute(deleteNotification{oldObj: d.Object}, false)
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}
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}
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return nil
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}
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type sharedProcessor struct {
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listenersStarted bool
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listenersLock sync.RWMutex
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listeners []*processorListener
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syncingListeners []*processorListener
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clock clock.Clock
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wg wait.Group
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}
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func (p *sharedProcessor) addListener(listener *processorListener) {
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p.listenersLock.Lock()
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defer p.listenersLock.Unlock()
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p.addListenerLocked(listener)
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if p.listenersStarted {
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p.wg.Start(listener.run)
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p.wg.Start(listener.pop)
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}
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}
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func (p *sharedProcessor) addListenerLocked(listener *processorListener) {
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p.listeners = append(p.listeners, listener)
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p.syncingListeners = append(p.syncingListeners, listener)
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}
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|
|
|
func (p *sharedProcessor) distribute(obj interface{}, sync bool) {
|
|
p.listenersLock.RLock()
|
|
defer p.listenersLock.RUnlock()
|
|
|
|
if sync {
|
|
for _, listener := range p.syncingListeners {
|
|
listener.add(obj)
|
|
}
|
|
} else {
|
|
for _, listener := range p.listeners {
|
|
listener.add(obj)
|
|
}
|
|
}
|
|
}
|
|
|
|
func (p *sharedProcessor) run(stopCh <-chan struct{}) {
|
|
func() {
|
|
p.listenersLock.RLock()
|
|
defer p.listenersLock.RUnlock()
|
|
for _, listener := range p.listeners {
|
|
p.wg.Start(listener.run)
|
|
p.wg.Start(listener.pop)
|
|
}
|
|
p.listenersStarted = true
|
|
}()
|
|
<-stopCh
|
|
p.listenersLock.RLock()
|
|
defer p.listenersLock.RUnlock()
|
|
for _, listener := range p.listeners {
|
|
close(listener.addCh) // Tell .pop() to stop. .pop() will tell .run() to stop
|
|
}
|
|
p.wg.Wait() // Wait for all .pop() and .run() to stop
|
|
}
|
|
|
|
// shouldResync queries every listener to determine if any of them need a resync, based on each
|
|
// listener's resyncPeriod.
|
|
func (p *sharedProcessor) shouldResync() bool {
|
|
p.listenersLock.Lock()
|
|
defer p.listenersLock.Unlock()
|
|
|
|
p.syncingListeners = []*processorListener{}
|
|
|
|
resyncNeeded := false
|
|
now := p.clock.Now()
|
|
for _, listener := range p.listeners {
|
|
// need to loop through all the listeners to see if they need to resync so we can prepare any
|
|
// listeners that are going to be resyncing.
|
|
if listener.shouldResync(now) {
|
|
resyncNeeded = true
|
|
p.syncingListeners = append(p.syncingListeners, listener)
|
|
listener.determineNextResync(now)
|
|
}
|
|
}
|
|
return resyncNeeded
|
|
}
|
|
|
|
func (p *sharedProcessor) resyncCheckPeriodChanged(resyncCheckPeriod time.Duration) {
|
|
p.listenersLock.RLock()
|
|
defer p.listenersLock.RUnlock()
|
|
|
|
for _, listener := range p.listeners {
|
|
resyncPeriod := determineResyncPeriod(listener.requestedResyncPeriod, resyncCheckPeriod)
|
|
listener.setResyncPeriod(resyncPeriod)
|
|
}
|
|
}
|
|
|
|
type processorListener struct {
|
|
nextCh chan interface{}
|
|
addCh chan interface{}
|
|
|
|
handler ResourceEventHandler
|
|
|
|
// pendingNotifications is an unbounded ring buffer that holds all notifications not yet distributed.
|
|
// There is one per listener, but a failing/stalled listener will have infinite pendingNotifications
|
|
// added until we OOM.
|
|
// TODO: This is no worse than before, since reflectors were backed by unbounded DeltaFIFOs, but
|
|
// we should try to do something better.
|
|
pendingNotifications buffer.RingGrowing
|
|
|
|
// requestedResyncPeriod is how frequently the listener wants a full resync from the shared informer
|
|
requestedResyncPeriod time.Duration
|
|
// resyncPeriod is how frequently the listener wants a full resync from the shared informer. This
|
|
// value may differ from requestedResyncPeriod if the shared informer adjusts it to align with the
|
|
// informer's overall resync check period.
|
|
resyncPeriod time.Duration
|
|
// nextResync is the earliest time the listener should get a full resync
|
|
nextResync time.Time
|
|
// resyncLock guards access to resyncPeriod and nextResync
|
|
resyncLock sync.Mutex
|
|
}
|
|
|
|
func newProcessListener(handler ResourceEventHandler, requestedResyncPeriod, resyncPeriod time.Duration, now time.Time, bufferSize int) *processorListener {
|
|
ret := &processorListener{
|
|
nextCh: make(chan interface{}),
|
|
addCh: make(chan interface{}),
|
|
handler: handler,
|
|
pendingNotifications: *buffer.NewRingGrowing(bufferSize),
|
|
requestedResyncPeriod: requestedResyncPeriod,
|
|
resyncPeriod: resyncPeriod,
|
|
}
|
|
|
|
ret.determineNextResync(now)
|
|
|
|
return ret
|
|
}
|
|
|
|
func (p *processorListener) add(notification interface{}) {
|
|
p.addCh <- notification
|
|
}
|
|
|
|
func (p *processorListener) pop() {
|
|
defer utilruntime.HandleCrash()
|
|
defer close(p.nextCh) // Tell .run() to stop
|
|
|
|
var nextCh chan<- interface{}
|
|
var notification interface{}
|
|
for {
|
|
select {
|
|
case nextCh <- notification:
|
|
// Notification dispatched
|
|
var ok bool
|
|
notification, ok = p.pendingNotifications.ReadOne()
|
|
if !ok { // Nothing to pop
|
|
nextCh = nil // Disable this select case
|
|
}
|
|
case notificationToAdd, ok := <-p.addCh:
|
|
if !ok {
|
|
return
|
|
}
|
|
if notification == nil { // No notification to pop (and pendingNotifications is empty)
|
|
// Optimize the case - skip adding to pendingNotifications
|
|
notification = notificationToAdd
|
|
nextCh = p.nextCh
|
|
} else { // There is already a notification waiting to be dispatched
|
|
p.pendingNotifications.WriteOne(notificationToAdd)
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
func (p *processorListener) run() {
|
|
// this call blocks until the channel is closed. When a panic happens during the notification
|
|
// we will catch it, **the offending item will be skipped!**, and after a short delay (one second)
|
|
// the next notification will be attempted. This is usually better than the alternative of never
|
|
// delivering again.
|
|
stopCh := make(chan struct{})
|
|
wait.Until(func() {
|
|
// this gives us a few quick retries before a long pause and then a few more quick retries
|
|
err := wait.ExponentialBackoff(retry.DefaultRetry, func() (bool, error) {
|
|
for next := range p.nextCh {
|
|
switch notification := next.(type) {
|
|
case updateNotification:
|
|
p.handler.OnUpdate(notification.oldObj, notification.newObj)
|
|
case addNotification:
|
|
p.handler.OnAdd(notification.newObj)
|
|
case deleteNotification:
|
|
p.handler.OnDelete(notification.oldObj)
|
|
default:
|
|
utilruntime.HandleError(fmt.Errorf("unrecognized notification: %T", next))
|
|
}
|
|
}
|
|
// the only way to get here is if the p.nextCh is empty and closed
|
|
return true, nil
|
|
})
|
|
|
|
// the only way to get here is if the p.nextCh is empty and closed
|
|
if err == nil {
|
|
close(stopCh)
|
|
}
|
|
}, 1*time.Minute, stopCh)
|
|
}
|
|
|
|
// shouldResync deterimines if the listener needs a resync. If the listener's resyncPeriod is 0,
|
|
// this always returns false.
|
|
func (p *processorListener) shouldResync(now time.Time) bool {
|
|
p.resyncLock.Lock()
|
|
defer p.resyncLock.Unlock()
|
|
|
|
if p.resyncPeriod == 0 {
|
|
return false
|
|
}
|
|
|
|
return now.After(p.nextResync) || now.Equal(p.nextResync)
|
|
}
|
|
|
|
func (p *processorListener) determineNextResync(now time.Time) {
|
|
p.resyncLock.Lock()
|
|
defer p.resyncLock.Unlock()
|
|
|
|
p.nextResync = now.Add(p.resyncPeriod)
|
|
}
|
|
|
|
func (p *processorListener) setResyncPeriod(resyncPeriod time.Duration) {
|
|
p.resyncLock.Lock()
|
|
defer p.resyncLock.Unlock()
|
|
|
|
p.resyncPeriod = resyncPeriod
|
|
}
|