220 lines
9.6 KiB
Go
220 lines
9.6 KiB
Go
// Copyright (c) HashiCorp, Inc.
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// SPDX-License-Identifier: MPL-2.0
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package stream
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import (
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"context"
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"errors"
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"fmt"
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"sync/atomic"
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)
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// eventBuffer is a single-writer, multiple-reader, unlimited length concurrent
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// buffer of events that have been published on a topic. The buffer is
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// effectively just the head of an atomically updated single-linked list. Atomic
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// accesses are usually to be suspected as premature optimization but this
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// specific design has several important features that significantly simplify a
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// lot of our PubSub machinery.
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//
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// The eventBuffer only tracks the most recent set of published events, so
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// if there are no consumers, older events are automatically garbage collected.
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// Consumers are notified of new events by closing a channel on the previous head
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// allowing efficient broadcast to many watchers without having to run multiple
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// goroutines or deliver to O(N) separate channels.
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//
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// Because eventBuffer is a linked list with atomically updated pointers, readers don't
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// have to take a lock and can consume at their own pace. We also don't need a
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// fixed limit on the number of items, which avoids needing to configure
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// buffer length to balance wasting memory, against being able to tolerate
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// occasionally slow readers.
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//
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// The buffer is used to deliver all messages broadcast to a topic for active
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// subscribers to consume, but it is also an effective way to both deliver and
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// optionally cache snapshots per topic and key. By using an eventBuffer,
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// snapshot functions don't have to read the whole snapshot into memory before
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// delivery - they can stream from memdb. However simply by storing a pointer to
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// the first event in the buffer, we can cache the buffered events for future
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// watchers on the same topic. Finally, once we've delivered all the snapshot
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// events to the buffer, we can append a next-element which is the first topic
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// buffer element with a higher index and so consumers can keep reading the
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// same buffer to have subsequent updates streamed after the snapshot is read.
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//
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// A huge benefit here is that caching snapshots becomes very simple - we don't
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// have to do any additional book-keeping to figure out when to truncate the
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// topic buffer to make sure the snapshot is still usable or run into issues
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// where the cached snapshot is no longer useful since the buffer will keep
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// elements around only as long as either the cache or a subscriber need them.
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// So we can use whatever simple timeout logic we like to decide how long to
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// keep caches (or if we should keep them at all) and the buffers will
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// automatically keep the events we need to make that work for exactly the
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// optimal amount of time and no longer.
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//
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// A new buffer is constructed with a sentinel "empty" bufferItem that has a nil
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// Events array. This enables subscribers to start watching for the next update
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// immediately.
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//
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// The zero value eventBuffer is _not_ usable, as it has not been
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// initialized with an empty bufferItem so can not be used to wait for the first
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// published event. Call newEventBuffer to construct a new buffer.
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//
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// Calls to Append or AppendBuffer that mutate the head must be externally
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// synchronized. This allows systems that already serialize writes to append
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// without lock overhead (e.g. a snapshot goroutine appending thousands of
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// events).
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type eventBuffer struct {
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head atomic.Value
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}
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// newEventBuffer creates an eventBuffer ready for use.
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func newEventBuffer() *eventBuffer {
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b := &eventBuffer{}
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b.head.Store(newBufferItem(nil))
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return b
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}
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// Append a set of events from one raft operation to the buffer and notify
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// watchers. Note that events must not have been previously made available to
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// any other goroutine since we may mutate them to ensure ACL Rules are
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// populated. After calling append, the caller must not make any further
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// mutations to the events as they may have been exposed to subscribers in other
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// goroutines. Append only supports a single concurrent caller and must be
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// externally synchronized with other Append, AppendBuffer or AppendErr calls.
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func (b *eventBuffer) Append(events []Event) {
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b.AppendItem(newBufferItem(events))
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}
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// AppendItem joins another buffer which may be the tail of a separate buffer
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// for example a buffer that's had the events from a snapshot appended may
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// finally by linked to the topic buffer for the subsequent events so
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// subscribers can seamlessly consume the updates. Note that Events in item must
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// already be fully populated with ACL rules and must not be mutated further as
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// they may have already been published to subscribers.
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//
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// AppendBuffer only supports a single concurrent caller and must be externally
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// synchronized with other Append, AppendBuffer or AppendErr calls.
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func (b *eventBuffer) AppendItem(item *bufferItem) {
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// First store it as the next node for the old head this ensures once it's
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// visible to new searchers the linked list is already valid. Not sure it
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// matters but this seems nicer.
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oldHead := b.Head()
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oldHead.link.next.Store(item)
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b.head.Store(item)
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// Now it's added invalidate the oldHead to notify waiters
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close(oldHead.link.ch)
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// don't set chan to nil since that will race with readers accessing it.
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}
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// Head returns the current head of the buffer. It will always exist but it may
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// be a "sentinel" empty item with a nil Events slice to allow consumers to
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// watch for the next update. Consumers should always check for empty Events and
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// treat them as no-ops. Will panic if eventBuffer was not initialized correctly
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// with eventBuffer.
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func (b *eventBuffer) Head() *bufferItem {
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return b.head.Load().(*bufferItem)
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}
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// bufferItem represents a set of events published by a single raft operation.
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// The first item returned by a newly constructed buffer will have nil Events.
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// It is a sentinel value which is used to wait on the next events via Next.
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//
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// To iterate to the next event, a Next method may be called which may block if
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// there is no next element yet.
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//
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// Holding a pointer to the item keeps all the events published since in memory
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// so it's important that subscribers don't hold pointers to buffer items after
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// they have been delivered except where it's intentional to maintain a cache or
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// trailing store of events for performance reasons.
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//
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// Subscribers must not mutate the bufferItem or the Events or Encoded payloads
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// inside as these are shared between all readers.
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type bufferItem struct {
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// Events is the set of events published at one raft index. This may be nil as
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// a sentinel value to allow watching for the first event in a buffer. Callers
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// should check and skip nil Events at any point in the buffer. It will also
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// be nil if the producer appends an Error event because they can't complete
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// the request to populate the buffer. Err will be non-nil in this case.
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Events []Event
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// Err is non-nil if the producer can't complete their task and terminates the
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// buffer. Subscribers should return the error to clients and cease attempting
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// to read from the buffer.
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Err error
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// link holds the next pointer and channel. This extra bit of indirection
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// allows us to splice buffers together at arbitrary points without including
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// events in one buffer just for the side-effect of watching for the next set.
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// The link may not be mutated once the event is appended to a buffer.
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link *bufferLink
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}
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type bufferLink struct {
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// next is an atomically updated pointer to the next event in the buffer. It
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// is written exactly once by the single published and will always be set if
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// ch is closed.
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next atomic.Value
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// ch is closed when the next event is published. It should never be mutated
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// (e.g. set to nil) as that is racey, but is closed once when the next event
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// is published. the next pointer will have been set by the time this is
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// closed.
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ch chan struct{}
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}
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// newBufferItem returns a blank buffer item with a link and chan ready to have
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// the fields set and be appended to a buffer.
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func newBufferItem(events []Event) *bufferItem {
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return &bufferItem{
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link: &bufferLink{ch: make(chan struct{})},
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Events: events,
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}
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}
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// Next return the next buffer item in the buffer. It may block until ctx is
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// cancelled or until the next item is published.
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func (i *bufferItem) Next(ctx context.Context, closed <-chan struct{}) (*bufferItem, error) {
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// See if there is already a next value, block if so. Note we don't rely on
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// state change (chan nil) as that's not threadsafe but detecting close is.
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select {
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case <-ctx.Done():
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return nil, ctx.Err()
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case <-closed:
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return nil, fmt.Errorf("subscription closed")
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case <-i.link.ch:
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}
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// If channel closed, there must be a next item to read
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nextRaw := i.link.next.Load()
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if nextRaw == nil {
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// shouldn't be possible
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return nil, errors.New("invalid next item")
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}
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next := nextRaw.(*bufferItem)
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if next.Err != nil {
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return nil, next.Err
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}
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return next, nil
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}
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// NextNoBlock returns true and the next item in the buffer without blocking.
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// If there are no subsequent items it returns false and an empty item.
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// The empty item will be ignored by subscribers, but has the same link as this
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// bufferItem without the Events.
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// When the link.ch of the empty item is closed, subscriptions are notified of
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// the next item.
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func (i *bufferItem) NextNoBlock() (*bufferItem, bool) {
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nextRaw := i.link.next.Load()
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if nextRaw == nil {
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// Return an empty item that can be followed to the next item published.
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return &bufferItem{link: i.link}, false
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}
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return nextRaw.(*bufferItem), true
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}
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// HasEventIndex returns true if index matches the Event.Index of this item. Returns
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// false if there are no events stored in the item, or the index does not match.
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func (i *bufferItem) HasEventIndex(index uint64) bool {
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return len(i.Events) > 0 && i.Events[0].Index == index
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}
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