In this example, we will run a Kubernetes Job with multiple parallel worker processes. You may want to be familiar with the basic, non-parallel, use of Job first.
In this example, as each pod is created, it picks up one unit of work from a task queue, completes it, deletes it from the queue, and exits.
Here is an overview of the steps in this example:
For this example, for simplicity, we will start a single instance of Redis. See the Redis Example for an example of deploying Redis scalably and redundantly.
Start a temporary Pod running Redis and a service so we can find it.
$ kubectl create -f docs/tasks/job/fine-parallel-processing-work-queue/redis-pod.yaml
pod "redis-master" created
$ kubectl create -f docs/tasks/job/fine-parallel-processing-work-queue/redis-service.yaml
service "redis" created
If you’re not working from the source tree, you could also download redis-pod.yaml
and redis-service.yaml
directly.
Now let’s fill the queue with some “tasks”. In our example, our tasks are just strings to be printed.
Start a temporary interactive pod for running the Redis CLI.
$ kubectl run -i --tty temp --image redis --command "/bin/sh"
Waiting for pod default/redis2-c7h78 to be running, status is Pending, pod ready: false
Hit enter for command prompt
Now hit enter, start the redis CLI, and create a list with some work items in it.
# redis-cli -h redis
redis:6379> rpush job2 "apple"
(integer) 1
redis:6379> rpush job2 "banana"
(integer) 2
redis:6379> rpush job2 "cherry"
(integer) 3
redis:6379> rpush job2 "date"
(integer) 4
redis:6379> rpush job2 "fig"
(integer) 5
redis:6379> rpush job2 "grape"
(integer) 6
redis:6379> rpush job2 "lemon"
(integer) 7
redis:6379> rpush job2 "melon"
(integer) 8
redis:6379> rpush job2 "orange"
(integer) 9
redis:6379> lrange job2 0 -1
1) "apple"
2) "banana"
3) "cherry"
4) "date"
5) "fig"
6) "grape"
7) "lemon"
8) "melon"
9) "orange"
So, the list with key job2
will be our work queue.
Note: if you do not have Kube DNS setup correctly, you may need to change
the first step of the above block to redis-cli -h $REDIS_SERVICE_HOST
.
Now we are ready to create an image that we will run.
We will use a python worker program with a redis client to read the messages from the message queue.
A simple Redis work queue client library is provided, called rediswq.py (Download).
The “worker” program in each Pod of the Job uses the work queue client library to get work. Here it is:
worker.py
|
---|
|
If you are working from the source tree,
change directory to the docs/tasks/job/fine-parallel-processing-work-queue/
directory.
Otherwise, download worker.py
, rediswq.py
, and Dockerfile
using above links. Then build the image:
docker build -t job-wq-2 .
For the Docker Hub, tag your app image with
your username and push to the Hub with the below commands. Replace
<username>
with your Hub username.
docker tag job-wq-2 <username>/job-wq-2
docker push <username>/job-wq-2
You need to push to a public repository or configure your cluster to be able to access your private repository.
If you are using Google Container
Registry, tag
your app image with your project ID, and push to GCR. Replace
<project>
with your project ID.
docker tag job-wq-2 gcr.io/<project>/job-wq-2
gcloud docker -- push gcr.io/<project>/job-wq-2
Here is the job definition:
job.yaml
|
---|
|
Be sure to edit the job template to
change gcr.io/myproject
to your own path.
In this example, each pod works on several items from the queue and then exits when there are no more items. Since the workers themselves detect when the workqueue is empty, and the Job controller does not know about the workqueue, it relies on the workers to signal when they are done working. The workers signal that the queue is empty by exiting with success. So, as soon as any worker exits with success, the controller knows the work is done, and the Pods will exit soon. So, we set the completion count of the Job to 1. The job controller will wait for the other pods to complete too.
So, now run the Job:
kubectl create -f ./job.yaml
Now wait a bit, then check on the job.
$ kubectl describe jobs/job-wq-2
Name: job-wq-2
Namespace: default
Selector: controller-uid=b1c7e4e3-92e1-11e7-b85e-fa163ee3c11f
Labels: controller-uid=b1c7e4e3-92e1-11e7-b85e-fa163ee3c11f
job-name=job-wq-2
Annotations: <none>
Parallelism: 2
Completions: <unset>
Start Time: Mon, 11 Jan 2016 17:07:59 -0800
Pods Statuses: 1 Running / 0 Succeeded / 0 Failed
Pod Template:
Labels: controller-uid=b1c7e4e3-92e1-11e7-b85e-fa163ee3c11f
job-name=job-wq-2
Containers:
c:
Image: gcr.io/exampleproject/job-wq-2
Port:
Environment: <none>
Mounts: <none>
Volumes: <none>
Events:
FirstSeen LastSeen Count From SubobjectPath Type Reason Message
--------- -------- ----- ---- ------------- -------- ------ -------
33s 33s 1 {job-controller } Normal SuccessfulCreate Created pod: job-wq-2-lglf8
$ kubectl logs pods/job-wq-2-7r7b2
Worker with sessionID: bbd72d0a-9e5c-4dd6-abf6-416cc267991f
Initial queue state: empty=False
Working on banana
Working on date
Working on lemon
As you can see, one of our pods worked on several work units.
If running a queue service or modifying your containers to use a work queue is inconvenient, you may want to consider one of the other job patterns.
If you have a continuous stream of background processing work to run, then
consider running your background workers with a replicationController
instead,
and consider running a background processing library such as
https://github.com/resque/resque.