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periodic_enqueuer.go
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/
periodic_enqueuer.go
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package work
import (
"fmt"
"math/rand"
"time"
"github.com/gomodule/redigo/redis"
"github.com/robfig/cron"
)
const (
periodicEnqueuerSleep = 2 * time.Minute
periodicEnqueuerHorizon = 4 * time.Minute
)
type periodicEnqueuer struct {
namespace string
pool *redis.Pool
periodicJobs []*periodicJob
scheduledPeriodicJobs []*scheduledPeriodicJob
stopChan chan struct{}
doneStoppingChan chan struct{}
}
type periodicJob struct {
jobName string
spec string
schedule cron.Schedule
}
type scheduledPeriodicJob struct {
scheduledAt time.Time
scheduledAtEpoch int64
*periodicJob
}
func newPeriodicEnqueuer(namespace string, pool *redis.Pool, periodicJobs []*periodicJob) *periodicEnqueuer {
return &periodicEnqueuer{
namespace: namespace,
pool: pool,
periodicJobs: periodicJobs,
stopChan: make(chan struct{}),
doneStoppingChan: make(chan struct{}),
}
}
func (pe *periodicEnqueuer) start() {
go pe.loop()
}
func (pe *periodicEnqueuer) stop() {
pe.stopChan <- struct{}{}
<-pe.doneStoppingChan
}
func (pe *periodicEnqueuer) loop() {
// Begin reaping periodically
timer := time.NewTimer(periodicEnqueuerSleep + time.Duration(rand.Intn(30))*time.Second)
defer timer.Stop()
if pe.shouldEnqueue() {
err := pe.enqueue()
if err != nil {
logError("periodic_enqueuer.loop.enqueue", err)
}
}
for {
select {
case <-pe.stopChan:
pe.doneStoppingChan <- struct{}{}
return
case <-timer.C:
timer.Reset(periodicEnqueuerSleep + time.Duration(rand.Intn(30))*time.Second)
if pe.shouldEnqueue() {
err := pe.enqueue()
if err != nil {
logError("periodic_enqueuer.loop.enqueue", err)
}
}
}
}
}
func (pe *periodicEnqueuer) enqueue() error {
now := nowEpochSeconds()
nowTime := time.Unix(now, 0)
horizon := nowTime.Add(periodicEnqueuerHorizon)
conn := pe.pool.Get()
defer conn.Close()
for _, pj := range pe.periodicJobs {
for t := pj.schedule.Next(nowTime); t.Before(horizon); t = pj.schedule.Next(t) {
epoch := t.Unix()
id := makeUniquePeriodicID(pj.jobName, pj.spec, epoch)
job := &Job{
Name: pj.jobName,
ID: id,
// This is technically wrong, but this lets the bytes be identical for the same periodic job instance. If we don't do this, we'd need to use a different approach -- probably giving each periodic job its own history of the past 100 periodic jobs, and only scheduling a job if it's not in the history.
EnqueuedAt: epoch,
Args: nil,
}
rawJSON, err := job.serialize()
if err != nil {
return err
}
_, err = conn.Do("ZADD", redisKeyScheduled(pe.namespace), epoch, rawJSON)
if err != nil {
return err
}
}
}
_, err := conn.Do("SET", redisKeyLastPeriodicEnqueue(pe.namespace), now)
return err
}
func (pe *periodicEnqueuer) shouldEnqueue() bool {
conn := pe.pool.Get()
defer conn.Close()
lastEnqueue, err := redis.Int64(conn.Do("GET", redisKeyLastPeriodicEnqueue(pe.namespace)))
if err == redis.ErrNil {
return true
} else if err != nil {
logError("periodic_enqueuer.should_enqueue", err)
return true
}
return lastEnqueue < (nowEpochSeconds() - int64(periodicEnqueuerSleep/time.Minute))
}
func makeUniquePeriodicID(name, spec string, epoch int64) string {
return fmt.Sprintf("periodic:%s:%s:%d", name, spec, epoch)
}