registry/docs/proxy/scheduler/scheduler.go

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package scheduler
import (
"encoding/json"
"fmt"
"time"
"github.com/docker/distribution/context"
"github.com/docker/distribution/registry/storage/driver"
)
// onTTLExpiryFunc is called when a repositories' TTL expires
type expiryFunc func(string) error
const (
entryTypeBlob = iota
entryTypeManifest
)
// schedulerEntry represents an entry in the scheduler
// fields are exported for serialization
type schedulerEntry struct {
Key string `json:"Key"`
Expiry time.Time `json:"ExpiryData"`
EntryType int `json:"EntryType"`
}
// New returns a new instance of the scheduler
func New(ctx context.Context, driver driver.StorageDriver, path string) *TTLExpirationScheduler {
return &TTLExpirationScheduler{
entries: make(map[string]schedulerEntry),
addChan: make(chan schedulerEntry),
stopChan: make(chan bool),
driver: driver,
pathToStateFile: path,
ctx: ctx,
stopped: true,
}
}
// TTLExpirationScheduler is a scheduler used to perform actions
// when TTLs expire
type TTLExpirationScheduler struct {
entries map[string]schedulerEntry
addChan chan schedulerEntry
stopChan chan bool
driver driver.StorageDriver
ctx context.Context
pathToStateFile string
stopped bool
onBlobExpire expiryFunc
onManifestExpire expiryFunc
}
// addChan allows more TTLs to be pushed to the scheduler
type addChan chan schedulerEntry
// stopChan allows the scheduler to be stopped - used for testing.
type stopChan chan bool
// OnBlobExpire is called when a scheduled blob's TTL expires
func (ttles *TTLExpirationScheduler) OnBlobExpire(f expiryFunc) {
ttles.onBlobExpire = f
}
// OnManifestExpire is called when a scheduled manifest's TTL expires
func (ttles *TTLExpirationScheduler) OnManifestExpire(f expiryFunc) {
ttles.onManifestExpire = f
}
// AddBlob schedules a blob cleanup after ttl expires
func (ttles *TTLExpirationScheduler) AddBlob(dgst string, ttl time.Duration) error {
if ttles.stopped {
return fmt.Errorf("scheduler not started")
}
ttles.add(dgst, ttl, entryTypeBlob)
return nil
}
// AddManifest schedules a manifest cleanup after ttl expires
func (ttles *TTLExpirationScheduler) AddManifest(repoName string, ttl time.Duration) error {
if ttles.stopped {
return fmt.Errorf("scheduler not started")
}
ttles.add(repoName, ttl, entryTypeManifest)
return nil
}
// Start starts the scheduler
func (ttles *TTLExpirationScheduler) Start() error {
return ttles.start()
}
func (ttles *TTLExpirationScheduler) add(key string, ttl time.Duration, eType int) {
entry := schedulerEntry{
Key: key,
Expiry: time.Now().Add(ttl),
EntryType: eType,
}
ttles.addChan <- entry
}
func (ttles *TTLExpirationScheduler) stop() {
ttles.stopChan <- true
}
func (ttles *TTLExpirationScheduler) start() error {
err := ttles.readState()
if err != nil {
return err
}
if !ttles.stopped {
return fmt.Errorf("Scheduler already started")
}
context.GetLogger(ttles.ctx).Infof("Starting cached object TTL expiration scheduler...")
ttles.stopped = false
go ttles.mainloop()
return nil
}
// mainloop uses a select statement to listen for events. Most of its time
// is spent in waiting on a TTL to expire but can be interrupted when TTLs
// are added.
func (ttles *TTLExpirationScheduler) mainloop() {
for {
if ttles.stopped {
return
}
nextEntry, ttl := nextExpiringEntry(ttles.entries)
if len(ttles.entries) == 0 {
context.GetLogger(ttles.ctx).Infof("scheduler mainloop(): Nothing to do, sleeping...")
} else {
context.GetLogger(ttles.ctx).Infof("scheduler mainloop(): Sleeping for %s until cleanup of %s", ttl, nextEntry.Key)
}
select {
case <-time.After(ttl):
var f expiryFunc
switch nextEntry.EntryType {
case entryTypeBlob:
f = ttles.onBlobExpire
case entryTypeManifest:
f = ttles.onManifestExpire
default:
f = func(repoName string) error {
return fmt.Errorf("Unexpected scheduler entry type")
}
}
if err := f(nextEntry.Key); err != nil {
context.GetLogger(ttles.ctx).Errorf("Scheduler error returned from OnExpire(%s): %s", nextEntry.Key, err)
}
delete(ttles.entries, nextEntry.Key)
if err := ttles.writeState(); err != nil {
context.GetLogger(ttles.ctx).Errorf("Error writing scheduler state: %s", err)
}
case entry := <-ttles.addChan:
context.GetLogger(ttles.ctx).Infof("Adding new scheduler entry for %s with ttl=%s", entry.Key, entry.Expiry.Sub(time.Now()))
ttles.entries[entry.Key] = entry
if err := ttles.writeState(); err != nil {
context.GetLogger(ttles.ctx).Errorf("Error writing scheduler state: %s", err)
}
break
case <-ttles.stopChan:
if err := ttles.writeState(); err != nil {
context.GetLogger(ttles.ctx).Errorf("Error writing scheduler state: %s", err)
}
ttles.stopped = true
}
}
}
func nextExpiringEntry(entries map[string]schedulerEntry) (*schedulerEntry, time.Duration) {
if len(entries) == 0 {
return nil, 24 * time.Hour
}
// todo:(richardscothern) this is a primitive o(n) algorithm
// but n will never be *that* big and it's all in memory. Investigate
// time.AfterFunc for heap based expiries
first := true
var nextEntry schedulerEntry
for _, entry := range entries {
if first {
nextEntry = entry
first = false
continue
}
if entry.Expiry.Before(nextEntry.Expiry) {
nextEntry = entry
}
}
// Dates may be from the past if the scheduler has
// been restarted, set their ttl to 0
if nextEntry.Expiry.Before(time.Now()) {
nextEntry.Expiry = time.Now()
return &nextEntry, 0
}
return &nextEntry, nextEntry.Expiry.Sub(time.Now())
}
func (ttles *TTLExpirationScheduler) writeState() error {
jsonBytes, err := json.Marshal(ttles.entries)
if err != nil {
return err
}
err = ttles.driver.PutContent(ttles.ctx, ttles.pathToStateFile, jsonBytes)
if err != nil {
return err
}
return nil
}
func (ttles *TTLExpirationScheduler) readState() error {
if _, err := ttles.driver.Stat(ttles.ctx, ttles.pathToStateFile); err != nil {
switch err := err.(type) {
case driver.PathNotFoundError:
return nil
default:
return err
}
}
bytes, err := ttles.driver.GetContent(ttles.ctx, ttles.pathToStateFile)
if err != nil {
return err
}
err = json.Unmarshal(bytes, &ttles.entries)
if err != nil {
return err
}
return nil
}