Apache License

http://www.apache.org/licenses/LICENSE-2.0

We’ll start out with some imports. You’ll see below that we’ll need a few more imports than those scaffolded for us. We’ll talk about each one when we use it.

package controller

import (
	"context"
	"fmt"
	"sort"
	"time"

	"github.com/robfig/cron"
	kbatch "k8s.io/api/batch/v1"
	corev1 "k8s.io/api/core/v1"
	metav1 "k8s.io/apimachinery/pkg/apis/meta/v1"
	"k8s.io/apimachinery/pkg/runtime"
	ref "k8s.io/client-go/tools/reference"
	ctrl "sigs.k8s.io/controller-runtime"
	"sigs.k8s.io/controller-runtime/pkg/client"
	"sigs.k8s.io/controller-runtime/pkg/log"

	batchv1 "tutorial.kubebuilder.io/project/api/v1"
)

Next, we’ll need a Clock, which will allow us to fake timing in our tests.

// CronJobReconciler reconciles a CronJob object
type CronJobReconciler struct {
	client.Client
	Scheme *runtime.Scheme
	Clock
}

Clock

type realClock struct{}

func (_ realClock) Now() time.Time { return time.Now() }

// Clock knows how to get the current time.
// It can be used to fake out timing for testing.
type Clock interface {
	Now() time.Time
}

Notice that we need a few more RBAC permissions – since we’re creating and managing jobs now, we’ll need permissions for those, which means adding a couple more markers.

//+kubebuilder:rbac:groups=batch.tutorial.kubebuilder.io,resources=cronjobs,verbs=get;list;watch;create;update;patch;delete
//+kubebuilder:rbac:groups=batch.tutorial.kubebuilder.io,resources=cronjobs/status,verbs=get;update;patch
//+kubebuilder:rbac:groups=batch.tutorial.kubebuilder.io,resources=cronjobs/finalizers,verbs=update
//+kubebuilder:rbac:groups=batch,resources=jobs,verbs=get;list;watch;create;update;patch;delete
//+kubebuilder:rbac:groups=batch,resources=jobs/status,verbs=get

Now, we get to the heart of the controller – the reconciler logic.

var (
	scheduledTimeAnnotation = "batch.tutorial.kubebuilder.io/scheduled-at"
)

// Reconcile is part of the main kubernetes reconciliation loop which aims to
// move the current state of the cluster closer to the desired state.
// TODO(user): Modify the Reconcile function to compare the state specified by
// the CronJob object against the actual cluster state, and then
// perform operations to make the cluster state reflect the state specified by
// the user.
//
// For more details, check Reconcile and its Result here:
// - https://pkg.go.dev/sigs.k8s.io/controller-runtime@v0.17.2/pkg/reconcile
func (r *CronJobReconciler) Reconcile(ctx context.Context, req ctrl.Request) (ctrl.Result, error) {
	log := log.FromContext(ctx)

1: Load the CronJob by name

We’ll fetch the CronJob using our client. All client methods take a context (to allow for cancellation) as their first argument, and the object in question as their last. Get is a bit special, in that it takes a NamespacedName as the middle argument (most don’t have a middle argument, as we’ll see below).

Many client methods also take variadic options at the end.

	var cronJob batchv1.CronJob
	if err := r.Get(ctx, req.NamespacedName, &cronJob); err != nil {
		log.Error(err, "unable to fetch CronJob")
		// we'll ignore not-found errors, since they can't be fixed by an immediate
		// requeue (we'll need to wait for a new notification), and we can get them
		// on deleted requests.
		return ctrl.Result{}, client.IgnoreNotFound(err)
	}

2: List all active jobs, and update the status

To fully update our status, we’ll need to list all child jobs in this namespace that belong to this CronJob. Similarly to Get, we can use the List method to list the child jobs. Notice that we use variadic options to set the namespace and field match (which is actually an index lookup that we set up below).

	var childJobs kbatch.JobList
	if err := r.List(ctx, &childJobs, client.InNamespace(req.Namespace), client.MatchingFields{jobOwnerKey: req.Name}); err != nil {
		log.Error(err, "unable to list child Jobs")
		return ctrl.Result{}, err
	}

Once we have all the jobs we own, we’ll split them into active, successful, and failed jobs, keeping track of the most recent run so that we can record it in status. Remember, status should be able to be reconstituted from the state of the world, so it’s generally not a good idea to read from the status of the root object. Instead, you should reconstruct it every run. That’s what we’ll do here.

We can check if a job is “finished” and whether it succeeded or failed using status conditions. We’ll put that logic in a helper to make our code cleaner.

	// find the active list of jobs
	var activeJobs []*kbatch.Job
	var successfulJobs []*kbatch.Job
	var failedJobs []*kbatch.Job
	var mostRecentTime *time.Time // find the last run so we can update the status

isJobFinished

	isJobFinished := func(job *kbatch.Job) (bool, kbatch.JobConditionType) {
		for _, c := range job.Status.Conditions {
			if (c.Type == kbatch.JobComplete || c.Type == kbatch.JobFailed) && c.Status == corev1.ConditionTrue {
				return true, c.Type
			}
		}

		return false, ""
	}

getScheduledTimeForJob

	getScheduledTimeForJob := func(job *kbatch.Job) (*time.Time, error) {
		timeRaw := job.Annotations[scheduledTimeAnnotation]
		if len(timeRaw) == 0 {
			return nil, nil
		}

		timeParsed, err := time.Parse(time.RFC3339, timeRaw)
		if err != nil {
			return nil, err
		}
		return &timeParsed, nil
	}

	for i, job := range childJobs.Items {
		_, finishedType := isJobFinished(&job)
		switch finishedType {
		case "": // ongoing
			activeJobs = append(activeJobs, &childJobs.Items[i])
		case kbatch.JobFailed:
			failedJobs = append(failedJobs, &childJobs.Items[i])
		case kbatch.JobComplete:
			successfulJobs = append(successfulJobs, &childJobs.Items[i])
		}

		// We'll store the launch time in an annotation, so we'll reconstitute that from
		// the active jobs themselves.
		scheduledTimeForJob, err := getScheduledTimeForJob(&job)
		if err != nil {
			log.Error(err, "unable to parse schedule time for child job", "job", &job)
			continue
		}
		if scheduledTimeForJob != nil {
			if mostRecentTime == nil || mostRecentTime.Before(*scheduledTimeForJob) {
				mostRecentTime = scheduledTimeForJob
			}
		}
	}

	if mostRecentTime != nil {
		cronJob.Status.LastScheduleTime = &metav1.Time{Time: *mostRecentTime}
	} else {
		cronJob.Status.LastScheduleTime = nil
	}
	cronJob.Status.Active = nil
	for _, activeJob := range activeJobs {
		jobRef, err := ref.GetReference(r.Scheme, activeJob)
		if err != nil {
			log.Error(err, "unable to make reference to active job", "job", activeJob)
			continue
		}
		cronJob.Status.Active = append(cronJob.Status.Active, *jobRef)
	}

Here, we’ll log how many jobs we observed at a slightly higher logging level, for debugging. Notice how instead of using a format string, we use a fixed message, and attach key-value pairs with the extra information. This makes it easier to filter and query log lines.

	log.V(1).Info("job count", "active jobs", len(activeJobs), "successful jobs", len(successfulJobs), "failed jobs", len(failedJobs))

Using the data we’ve gathered, we’ll update the status of our CRD. Just like before, we use our client. To specifically update the status subresource, we’ll use the Status part of the client, with the Update method.

The status subresource ignores changes to spec, so it’s less likely to conflict with any other updates, and can have separate permissions.

	if err := r.Status().Update(ctx, &cronJob); err != nil {
		log.Error(err, "unable to update CronJob status")
		return ctrl.Result{}, err
	}

Once we’ve updated our status, we can move on to ensuring that the status of the world matches what we want in our spec.

3: Clean up old jobs according to the history limit

First, we’ll try to clean up old jobs, so that we don’t leave too many lying around.

	// NB: deleting these are "best effort" -- if we fail on a particular one,
	// we won't requeue just to finish the deleting.
	if cronJob.Spec.FailedJobsHistoryLimit != nil {
		sort.Slice(failedJobs, func(i, j int) bool {
			if failedJobs[i].Status.StartTime == nil {
				return failedJobs[j].Status.StartTime != nil
			}
			return failedJobs[i].Status.StartTime.Before(failedJobs[j].Status.StartTime)
		})
		for i, job := range failedJobs {
			if int32(i) >= int32(len(failedJobs))-*cronJob.Spec.FailedJobsHistoryLimit {
				break
			}
			if err := r.Delete(ctx, job, client.PropagationPolicy(metav1.DeletePropagationBackground)); client.IgnoreNotFound(err) != nil {
				log.Error(err, "unable to delete old failed job", "job", job)
			} else {
				log.V(0).Info("deleted old failed job", "job", job)
			}
		}
	}

	if cronJob.Spec.SuccessfulJobsHistoryLimit != nil {
		sort.Slice(successfulJobs, func(i, j int) bool {
			if successfulJobs[i].Status.StartTime == nil {
				return successfulJobs[j].Status.StartTime != nil
			}
			return successfulJobs[i].Status.StartTime.Before(successfulJobs[j].Status.StartTime)
		})
		for i, job := range successfulJobs {
			if int32(i) >= int32(len(successfulJobs))-*cronJob.Spec.SuccessfulJobsHistoryLimit {
				break
			}
			if err := r.Delete(ctx, job, client.PropagationPolicy(metav1.DeletePropagationBackground)); err != nil {
				log.Error(err, "unable to delete old successful job", "job", job)
			} else {
				log.V(0).Info("deleted old successful job", "job", job)
			}
		}
	}

4: Check if we’re suspended

If this object is suspended, we don’t want to run any jobs, so we’ll stop now. This is useful if something’s broken with the job we’re running and we want to pause runs to investigate or putz with the cluster, without deleting the object.

	if cronJob.Spec.Suspend != nil && *cronJob.Spec.Suspend {
		log.V(1).Info("cronjob suspended, skipping")
		return ctrl.Result{}, nil
	}

5: Get the next scheduled run

If we’re not paused, we’ll need to calculate the next scheduled run, and whether or not we’ve got a run that we haven’t processed yet.

getNextSchedule

	getNextSchedule := func(cronJob *batchv1.CronJob, now time.Time) (lastMissed time.Time, next time.Time, err error) {
		sched, err := cron.ParseStandard(cronJob.Spec.Schedule)
		if err != nil {
			return time.Time{}, time.Time{}, fmt.Errorf("Unparseable schedule %q: %v", cronJob.Spec.Schedule, err)
		}

		// for optimization purposes, cheat a bit and start from our last observed run time
		// we could reconstitute this here, but there's not much point, since we've
		// just updated it.
		var earliestTime time.Time
		if cronJob.Status.LastScheduleTime != nil {
			earliestTime = cronJob.Status.LastScheduleTime.Time
		} else {
			earliestTime = cronJob.ObjectMeta.CreationTimestamp.Time
		}
		if cronJob.Spec.StartingDeadlineSeconds != nil {
			// controller is not going to schedule anything below this point
			schedulingDeadline := now.Add(-time.Second * time.Duration(*cronJob.Spec.StartingDeadlineSeconds))

			if schedulingDeadline.After(earliestTime) {
				earliestTime = schedulingDeadline
			}
		}
		if earliestTime.After(now) {
			return time.Time{}, sched.Next(now), nil
		}

		starts := 0
		for t := sched.Next(earliestTime); !t.After(now); t = sched.Next(t) {
			lastMissed = t
			// An object might miss several starts. For example, if
			// controller gets wedged on Friday at 5:01pm when everyone has
			// gone home, and someone comes in on Tuesday AM and discovers
			// the problem and restarts the controller, then all the hourly
			// jobs, more than 80 of them for one hourly scheduledJob, should
			// all start running with no further intervention (if the scheduledJob
			// allows concurrency and late starts).
			//
			// However, if there is a bug somewhere, or incorrect clock
			// on controller's server or apiservers (for setting creationTimestamp)
			// then there could be so many missed start times (it could be off
			// by decades or more), that it would eat up all the CPU and memory
			// of this controller. In that case, we want to not try to list
			// all the missed start times.
			starts++
			if starts > 100 {
				// We can't get the most recent times so just return an empty slice
				return time.Time{}, time.Time{}, fmt.Errorf("Too many missed start times (> 100). Set or decrease .spec.startingDeadlineSeconds or check clock skew.")
			}
		}
		return lastMissed, sched.Next(now), nil
	}

	// figure out the next times that we need to create
	// jobs at (or anything we missed).
	missedRun, nextRun, err := getNextSchedule(&cronJob, r.Now())
	if err != nil {
		log.Error(err, "unable to figure out CronJob schedule")
		// we don't really care about requeuing until we get an update that
		// fixes the schedule, so don't return an error
		return ctrl.Result{}, nil
	}

We’ll prep our eventual request to requeue until the next job, and then figure out if we actually need to run.

	scheduledResult := ctrl.Result{RequeueAfter: nextRun.Sub(r.Now())} // save this so we can re-use it elsewhere
	log = log.WithValues("now", r.Now(), "next run", nextRun)

6: Run a new job if it’s on schedule, not past the deadline, and not blocked by our concurrency policy

If we’ve missed a run, and we’re still within the deadline to start it, we’ll need to run a job.

	if missedRun.IsZero() {
		log.V(1).Info("no upcoming scheduled times, sleeping until next")
		return scheduledResult, nil
	}

	// make sure we're not too late to start the run
	log = log.WithValues("current run", missedRun)
	tooLate := false
	if cronJob.Spec.StartingDeadlineSeconds != nil {
		tooLate = missedRun.Add(time.Duration(*cronJob.Spec.StartingDeadlineSeconds) * time.Second).Before(r.Now())
	}
	if tooLate {
		log.V(1).Info("missed starting deadline for last run, sleeping till next")
		// TODO(directxman12): events
		return scheduledResult, nil
	}

If we actually have to run a job, we’ll need to either wait till existing ones finish, replace the existing ones, or just add new ones. If our information is out of date due to cache delay, we’ll get a requeue when we get up-to-date information.

	// figure out how to run this job -- concurrency policy might forbid us from running
	// multiple at the same time...
	if cronJob.Spec.ConcurrencyPolicy == batchv1.ForbidConcurrent && len(activeJobs) > 0 {
		log.V(1).Info("concurrency policy blocks concurrent runs, skipping", "num active", len(activeJobs))
		return scheduledResult, nil
	}

	// ...or instruct us to replace existing ones...
	if cronJob.Spec.ConcurrencyPolicy == batchv1.ReplaceConcurrent {
		for _, activeJob := range activeJobs {
			// we don't care if the job was already deleted
			if err := r.Delete(ctx, activeJob, client.PropagationPolicy(metav1.DeletePropagationBackground)); client.IgnoreNotFound(err) != nil {
				log.Error(err, "unable to delete active job", "job", activeJob)
				return ctrl.Result{}, err
			}
		}
	}

Once we’ve figured out what to do with existing jobs, we’ll actually create our desired job

constructJobForCronJob

	constructJobForCronJob := func(cronJob *batchv1.CronJob, scheduledTime time.Time) (*kbatch.Job, error) {
		// We want job names for a given nominal start time to have a deterministic name to avoid the same job being created twice
		name := fmt.Sprintf("%s-%d", cronJob.Name, scheduledTime.Unix())

		job := &kbatch.Job{
			ObjectMeta: metav1.ObjectMeta{
				Labels:      make(map[string]string),
				Annotations: make(map[string]string),
				Name:        name,
				Namespace:   cronJob.Namespace,
			},
			Spec: *cronJob.Spec.JobTemplate.Spec.DeepCopy(),
		}
		for k, v := range cronJob.Spec.JobTemplate.Annotations {
			job.Annotations[k] = v
		}
		job.Annotations[scheduledTimeAnnotation] = scheduledTime.Format(time.RFC3339)
		for k, v := range cronJob.Spec.JobTemplate.Labels {
			job.Labels[k] = v
		}
		if err := ctrl.SetControllerReference(cronJob, job, r.Scheme); err != nil {
			return nil, err
		}

		return job, nil
	}

	// actually make the job...
	job, err := constructJobForCronJob(&cronJob, missedRun)
	if err != nil {
		log.Error(err, "unable to construct job from template")
		// don't bother requeuing until we get a change to the spec
		return scheduledResult, nil
	}

	// ...and create it on the cluster
	if err := r.Create(ctx, job); err != nil {
		log.Error(err, "unable to create Job for CronJob", "job", job)
		return ctrl.Result{}, err
	}

	log.V(1).Info("created Job for CronJob run", "job", job)

7: Requeue when we either see a running job or it’s time for the next scheduled run

Finally, we’ll return the result that we prepped above, that says we want to requeue when our next run would need to occur. This is taken as a maximum deadline – if something else changes in between, like our job starts or finishes, we get modified, etc, we might reconcile again sooner.

	// we'll requeue once we see the running job, and update our status
	return scheduledResult, nil
}

Setup

Finally, we’ll update our setup. In order to allow our reconciler to quickly look up Jobs by their owner, we’ll need an index. We declare an index key that we can later use with the client as a pseudo-field name, and then describe how to extract the indexed value from the Job object. The indexer will automatically take care of namespaces for us, so we just have to extract the owner name if the Job has a CronJob owner.

Additionally, we’ll inform the manager that this controller owns some Jobs, so that it will automatically call Reconcile on the underlying CronJob when a Job changes, is deleted, etc.

var (
	jobOwnerKey = ".metadata.controller"
	apiGVStr    = batchv1.GroupVersion.String()
)

// SetupWithManager sets up the controller with the Manager.
func (r *CronJobReconciler) SetupWithManager(mgr ctrl.Manager) error {
	// set up a real clock, since we're not in a test
	if r.Clock == nil {
		r.Clock = realClock{}
	}

	if err := mgr.GetFieldIndexer().IndexField(context.Background(), &kbatch.Job{}, jobOwnerKey, func(rawObj client.Object) []string {
		// grab the job object, extract the owner...
		job := rawObj.(*kbatch.Job)
		owner := metav1.GetControllerOf(job)
		if owner == nil {
			return nil
		}
		// ...make sure it's a CronJob...
		if owner.APIVersion != apiGVStr || owner.Kind != "CronJob" {
			return nil
		}

		// ...and if so, return it
		return []string{owner.Name}
	}); err != nil {
		return err
	}

	return ctrl.NewControllerManagedBy(mgr).
		For(&batchv1.CronJob{}).
		Owns(&kbatch.Job{}).
		Complete(r)
}