mirror of https://github.com/hashicorp/consul
235 lines
7.7 KiB
Go
235 lines
7.7 KiB
Go
package cache
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import (
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"context"
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"fmt"
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"reflect"
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"time"
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"github.com/hashicorp/consul/lib"
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)
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// UpdateEvent is a struct summarizing an update to a cache entry
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type UpdateEvent struct {
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// CorrelationID is used by the Notify API to allow correlation of updates
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// with specific requests. We could return the full request object and
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// cachetype for consumers to match against the calls they made but in
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// practice it's cleaner for them to choose the minimal necessary unique
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// identifier given the set of things they are watching. They might even
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// choose to assign random IDs for example.
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CorrelationID string
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Result interface{}
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Meta ResultMeta
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Err error
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}
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// Notify registers a desire to be updated about changes to a cache result.
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//
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// It is a helper that abstracts code from performing their own "blocking" query
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// logic against a cache key to watch for changes and to maintain the key in
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// cache actively. It will continue to perform blocking Get requests until the
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// context is canceled.
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//
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// The passed context must be canceled or timeout in order to free resources
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// and stop maintaining the value in cache. Typically request-scoped resources
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// do this but if a long-lived context like context.Background is used, then the
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// caller must arrange for it to be canceled when the watch is no longer
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// needed.
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//
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// The passed chan may be buffered or unbuffered, if the caller doesn't consume
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// fast enough it will block the notification loop. When the chan is later
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// drained, watching resumes correctly. If the pause is longer than the
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// cachetype's TTL, the result might be removed from the local cache. Even in
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// this case though when the chan is drained again, the new Get will re-fetch
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// the entry from servers and resume notification behavior transparently.
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//
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// The chan is passed in to allow multiple cached results to be watched by a
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// single consumer without juggling extra goroutines per watch. The
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// correlationID is opaque and will be returned in all UpdateEvents generated by
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// result of watching the specified request so the caller can set this to any
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// value that allows them to disambiguate between events in the returned chan
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// when sharing a chan between multiple cache entries. If the chan is closed,
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// the notify loop will terminate.
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func (c *Cache) Notify(ctx context.Context, t string, r Request,
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correlationID string, ch chan<- UpdateEvent) error {
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// Get the type that we're fetching
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c.typesLock.RLock()
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tEntry, ok := c.types[t]
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c.typesLock.RUnlock()
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if !ok {
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return fmt.Errorf("unknown type in cache: %s", t)
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}
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if tEntry.Type.SupportsBlocking() {
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go c.notifyBlockingQuery(ctx, t, r, correlationID, ch)
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} else {
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info := r.CacheInfo()
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if info.MaxAge == 0 {
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return fmt.Errorf("Cannot use Notify for polling cache types without specifying the MaxAge")
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}
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go c.notifyPollingQuery(ctx, t, r, correlationID, ch, info.MaxAge)
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}
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return nil
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}
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func (c *Cache) notifyBlockingQuery(ctx context.Context, t string, r Request, correlationID string, ch chan<- UpdateEvent) {
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// Always start at 0 index to deliver the initial (possibly currently cached
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// value).
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index := uint64(0)
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failures := uint(0)
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for {
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// Check context hasn't been canceled
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if ctx.Err() != nil {
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return
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}
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// Blocking request
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res, meta, err := c.getWithIndex(t, r, index)
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// Check context hasn't been canceled
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if ctx.Err() != nil {
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return
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}
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// Check the index of the value returned in the cache entry to be sure it
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// changed
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if index < meta.Index {
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u := UpdateEvent{correlationID, res, meta, err}
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select {
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case ch <- u:
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case <-ctx.Done():
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return
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}
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// Update index for next request
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index = meta.Index
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}
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// Handle errors with backoff. Badly behaved blocking calls that returned
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// a zero index are considered as failures since we need to not get stuck
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// in a busy loop.
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wait := 0 * time.Second
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if err == nil && meta.Index > 0 {
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failures = 0
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} else {
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failures++
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wait = backOffWait(failures)
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}
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if wait > 0 {
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select {
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case <-time.After(wait):
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case <-ctx.Done():
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return
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}
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}
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// Sanity check we always request blocking on second pass
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if index < 1 {
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index = 1
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}
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}
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}
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func (c *Cache) notifyPollingQuery(ctx context.Context, t string, r Request, correlationID string, ch chan<- UpdateEvent, maxAge time.Duration) {
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index := uint64(0)
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failures := uint(0)
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var lastValue interface{} = nil
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for {
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// Check context hasn't been canceled
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if ctx.Err() != nil {
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return
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}
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// Make the request
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res, meta, err := c.getWithIndex(t, r, index)
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// Check context hasn't been canceled
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if ctx.Err() != nil {
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return
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}
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// Check for a change in the value or an index change
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if index < meta.Index || !reflect.DeepEqual(lastValue, res) {
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u := UpdateEvent{correlationID, res, meta, err}
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select {
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case ch <- u:
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case <-ctx.Done():
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return
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}
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// Update index and lastValue
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lastValue = res
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index = meta.Index
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}
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// Reset or increment failure counter
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if err == nil {
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failures = 0
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} else {
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failures++
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}
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// Determining how long to wait before the next poll is complicated.
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// First off the happy path and the error path waits are handled distinctly
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//
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// Once fetching the data through the cache returns an error (and until a
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// non-error value is returned) the wait time between each round of the loop
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// gets controlled by the backOffWait function. Because we would have waited
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// at least until the age of the cached data was too old the error path should
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// immediately retry the fetch and backoff on the time as needed for persistent
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// failures which potentially will wait much longer than the MaxAge of the request
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//
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// When on the happy path we just need to fetch from the cache often enough to ensure
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// that the data is not older than the MaxAge. Therefore after fetching the data from
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// the cache we can sleep until the age of that data would exceed the MaxAge. Sometimes
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// this will be for the MaxAge duration (like when only a single notify was executed so
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// only 1 go routine is keeping the cache updated). Other times this will be some smaller
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// duration than MaxAge (when multiple notify calls were executed and this go routine just
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// got data back from the cache that was a cache hit after the other go routine fetched it
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// without a hit). We cannot just set MustRevalidate on the request and always sleep for MaxAge
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// as this would eliminate the single-flighting of these requests in the cache and
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// the efficiencies gained by it.
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if failures > 0 {
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errWait := backOffWait(failures)
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select {
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case <-time.After(errWait):
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case <-ctx.Done():
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return
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}
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} else {
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// Default to immediately re-poll. This only will happen if the data
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// we just got out of the cache is already too stale
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pollWait := 0 * time.Second
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// Calculate when the cached data's Age will get too stale and
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// need to be re-queried. When the data's Age already exceeds the
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// maxAge the pollWait value is left at 0 to immediately re-poll
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if meta.Age <= maxAge {
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pollWait = maxAge - meta.Age
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}
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// Add a small amount of random jitter to the polling time. One
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// purpose of the jitter is to ensure that the next time
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// we fetch from the cache the data will be stale (unless another
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// notify go routine has updated it while this one is sleeping).
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// Without this it would be possible to wake up, fetch the data
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// again where the age of the data is strictly equal to the MaxAge
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// and then immediately have to re-fetch again. That wouldn't
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// be terrible but it would expend a bunch more cpu cycles when
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// we can definitely avoid it.
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pollWait += lib.RandomStagger(maxAge / 16)
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select {
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case <-time.After(pollWait):
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case <-ctx.Done():
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return
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}
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}
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}
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}
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