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Run Jobs
- 1: Running Automated Tasks with a CronJob
- 2: Coarse Parallel Processing Using a Work Queue
- 3: Fine Parallel Processing Using a Work Queue
- 4: Indexed Job for Parallel Processing with Static Work Assignment
- 5: Job with Pod-to-Pod Communication
- 6: Parallel Processing using Expansions
- 7: Handling retriable and non-retriable pod failures with Pod failure policy
1 - Running Automated Tasks with a CronJob
This page shows how to run automated tasks using Kubernetes CronJob object.
Before you begin
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
Creating a CronJob
Cron jobs require a config file. Here is a manifest for a CronJob that runs a simple demonstration task every minute:
apiVersion: batch/v1
kind: CronJob
metadata:
name: hello
spec:
schedule: "* * * * *"
jobTemplate:
spec:
template:
spec:
containers:
- name: hello
image: busybox:1.28
imagePullPolicy: IfNotPresent
command:
- /bin/sh
- -c
- date; echo Hello from the Kubernetes cluster
restartPolicy: OnFailure
Run the example CronJob by using this command:
kubectl create -f https://k8s.io/examples/application/job/cronjob.yaml
The output is similar to this:
cronjob.batch/hello created
After creating the cron job, get its status using this command:
kubectl get cronjob hello
The output is similar to this:
NAME SCHEDULE SUSPEND ACTIVE LAST SCHEDULE AGE
hello */1 * * * * False 0 <none> 10s
As you can see from the results of the command, the cron job has not scheduled or run any jobs yet. Watch for the job to be created in around one minute:
kubectl get jobs --watch
The output is similar to this:
NAME COMPLETIONS DURATION AGE
hello-4111706356 0/1 0s
hello-4111706356 0/1 0s 0s
hello-4111706356 1/1 5s 5s
Now you've seen one running job scheduled by the "hello" cron job. You can stop watching the job and view the cron job again to see that it scheduled the job:
kubectl get cronjob hello
The output is similar to this:
NAME SCHEDULE SUSPEND ACTIVE LAST SCHEDULE AGE
hello */1 * * * * False 0 50s 75s
You should see that the cron job hello
successfully scheduled a job at the time specified in
LAST SCHEDULE
. There are currently 0 active jobs, meaning that the job has completed or failed.
Now, find the pods that the last scheduled job created and view the standard output of one of the pods.
# Replace "hello-4111706356" with the job name in your system
pods=$(kubectl get pods --selector=job-name=hello-4111706356 --output=jsonpath={.items[*].metadata.name})
Show the pod log:
kubectl logs $pods
The output is similar to this:
Fri Feb 22 11:02:09 UTC 2019
Hello from the Kubernetes cluster
Deleting a CronJob
When you don't need a cron job any more, delete it with kubectl delete cronjob <cronjob name>
:
kubectl delete cronjob hello
Deleting the cron job removes all the jobs and pods it created and stops it from creating additional jobs. You can read more about removing jobs in garbage collection.
2 - Coarse Parallel Processing Using a Work Queue
In this example, we will run a Kubernetes Job with multiple parallel worker processes.
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:
- Start a message queue service. In this example, we use RabbitMQ, but you could use another one. In practice you would set up a message queue service once and reuse it for many jobs.
- Create a queue, and fill it with messages. Each message represents one task to be done. In this example, a message is an integer that we will do a lengthy computation on.
- Start a Job that works on tasks from the queue. The Job starts several pods. Each pod takes one task from the message queue, processes it, and repeats until the end of the queue is reached.
Before you begin
Be familiar with the basic, non-parallel, use of Job.
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
Starting a message queue service
This example uses RabbitMQ, however, you can adapt the example to use another AMQP-type message service.
In practice you could set up a message queue service once in a cluster and reuse it for many jobs, as well as for long-running services.
Start RabbitMQ as follows:
kubectl create -f https://raw.githubusercontent.com/kubernetes/kubernetes/release-1.3/examples/celery-rabbitmq/rabbitmq-service.yaml
service "rabbitmq-service" created
kubectl create -f https://raw.githubusercontent.com/kubernetes/kubernetes/release-1.3/examples/celery-rabbitmq/rabbitmq-controller.yaml
replicationcontroller "rabbitmq-controller" created
We will only use the rabbitmq part from the celery-rabbitmq example.
Testing the message queue service
Now, we can experiment with accessing the message queue. We will create a temporary interactive pod, install some tools on it, and experiment with queues.
First create a temporary interactive Pod.
# Create a temporary interactive container
kubectl run -i --tty temp --image ubuntu:18.04
Waiting for pod default/temp-loe07 to be running, status is Pending, pod ready: false
... [ previous line repeats several times .. hit return when it stops ] ...
Note that your pod name and command prompt will be different.
Next install the amqp-tools
so we can work with message queues.
# Install some tools
root@temp-loe07:/# apt-get update
.... [ lots of output ] ....
root@temp-loe07:/# apt-get install -y curl ca-certificates amqp-tools python dnsutils
.... [ lots of output ] ....
Later, we will make a docker image that includes these packages.
Next, we will check that we can discover the rabbitmq service:
# Note the rabbitmq-service has a DNS name, provided by Kubernetes:
root@temp-loe07:/# nslookup rabbitmq-service
Server: 10.0.0.10
Address: 10.0.0.10#53
Name: rabbitmq-service.default.svc.cluster.local
Address: 10.0.147.152
# Your address will vary.
If Kube-DNS is not set up correctly, the previous step may not work for you. You can also find the service IP in an env var:
# env | grep RABBIT | grep HOST
RABBITMQ_SERVICE_SERVICE_HOST=10.0.147.152
# Your address will vary.
Next we will verify we can create a queue, and publish and consume messages.
# In the next line, rabbitmq-service is the hostname where the rabbitmq-service
# can be reached. 5672 is the standard port for rabbitmq.
root@temp-loe07:/# export BROKER_URL=amqp://guest:guest@rabbitmq-service:5672
# If you could not resolve "rabbitmq-service" in the previous step,
# then use this command instead:
# root@temp-loe07:/# BROKER_URL=amqp://guest:guest@$RABBITMQ_SERVICE_SERVICE_HOST:5672
# Now create a queue:
root@temp-loe07:/# /usr/bin/amqp-declare-queue --url=$BROKER_URL -q foo -d
foo
# Publish one message to it:
root@temp-loe07:/# /usr/bin/amqp-publish --url=$BROKER_URL -r foo -p -b Hello
# And get it back.
root@temp-loe07:/# /usr/bin/amqp-consume --url=$BROKER_URL -q foo -c 1 cat && echo
Hello
root@temp-loe07:/#
In the last command, the amqp-consume
tool takes one message (-c 1
)
from the queue, and passes that message to the standard input of an arbitrary command. In this case, the program cat
prints out the characters read from standard input, and the echo adds a carriage
return so the example is readable.
Filling the Queue with tasks
Now let's fill the queue with some "tasks". In our example, our tasks are strings to be printed.
In a practice, the content of the messages might be:
- names of files to that need to be processed
- extra flags to the program
- ranges of keys in a database table
- configuration parameters to a simulation
- frame numbers of a scene to be rendered
In practice, if there is large data that is needed in a read-only mode by all pods of the Job, you will typically put that in a shared file system like NFS and mount that readonly on all the pods, or the program in the pod will natively read data from a cluster file system like HDFS.
For our example, we will create the queue and fill it using the amqp command line tools. In practice, you might write a program to fill the queue using an amqp client library.
/usr/bin/amqp-declare-queue --url=$BROKER_URL -q job1 -d
job1
for f in apple banana cherry date fig grape lemon melon
do
/usr/bin/amqp-publish --url=$BROKER_URL -r job1 -p -b $f
done
So, we filled the queue with 8 messages.
Create an Image
Now we are ready to create an image that we will run as a job.
We will use the amqp-consume
utility to read the message
from the queue and run our actual program. Here is a very simple
example program:
#!/usr/bin/env python
# Just prints standard out and sleeps for 10 seconds.
import sys
import time
print("Processing " + sys.stdin.readlines()[0])
time.sleep(10)
Give the script execution permission:
chmod +x worker.py
Now, build an image. If you are working in the source
tree, then change directory to examples/job/work-queue-1
.
Otherwise, make a temporary directory, change to it,
download the Dockerfile,
and worker.py. In either case,
build the image with this command:
docker build -t job-wq-1 .
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-1 <username>/job-wq-1
docker push <username>/job-wq-1
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-1 gcr.io/<project>/job-wq-1
gcloud docker -- push gcr.io/<project>/job-wq-1
Defining a Job
Here is a job definition. You'll need to make a copy of the Job and edit the
image to match the name you used, and call it ./job.yaml
.
apiVersion: batch/v1
kind: Job
metadata:
name: job-wq-1
spec:
completions: 8
parallelism: 2
template:
metadata:
name: job-wq-1
spec:
containers:
- name: c
image: gcr.io/<project>/job-wq-1
env:
- name: BROKER_URL
value: amqp://guest:guest@rabbitmq-service:5672
- name: QUEUE
value: job1
restartPolicy: OnFailure
In this example, each pod works on one item from the queue and then exits.
So, the completion count of the Job corresponds to the number of work items
done. So we set, .spec.completions: 8
for the example, since we put 8 items in the queue.
Running the Job
So, now run the Job:
kubectl apply -f ./job.yaml
You can wait for the Job to succeed, with a timeout:
# The check for condition name is case insensitive
kubectl wait --for=condition=complete --timeout=300s job/job-wq-1
Next, check on the Job:
kubectl describe jobs/job-wq-1
Name: job-wq-1
Namespace: default
Selector: controller-uid=41d75705-92df-11e7-b85e-fa163ee3c11f
Labels: controller-uid=41d75705-92df-11e7-b85e-fa163ee3c11f
job-name=job-wq-1
Annotations: <none>
Parallelism: 2
Completions: 8
Start Time: Wed, 06 Sep 2017 16:42:02 +0800
Pods Statuses: 0 Running / 8 Succeeded / 0 Failed
Pod Template:
Labels: controller-uid=41d75705-92df-11e7-b85e-fa163ee3c11f
job-name=job-wq-1
Containers:
c:
Image: gcr.io/causal-jigsaw-637/job-wq-1
Port:
Environment:
BROKER_URL: amqp://guest:guest@rabbitmq-service:5672
QUEUE: job1
Mounts: <none>
Volumes: <none>
Events:
FirstSeen LastSeen Count From SubobjectPath Type Reason Message
───────── ──────── ───── ──── ───────────── ────── ────── ───────
27s 27s 1 {job } Normal SuccessfulCreate Created pod: job-wq-1-hcobb
27s 27s 1 {job } Normal SuccessfulCreate Created pod: job-wq-1-weytj
27s 27s 1 {job } Normal SuccessfulCreate Created pod: job-wq-1-qaam5
27s 27s 1 {job } Normal SuccessfulCreate Created pod: job-wq-1-b67sr
26s 26s 1 {job } Normal SuccessfulCreate Created pod: job-wq-1-xe5hj
15s 15s 1 {job } Normal SuccessfulCreate Created pod: job-wq-1-w2zqe
14s 14s 1 {job } Normal SuccessfulCreate Created pod: job-wq-1-d6ppa
14s 14s 1 {job } Normal SuccessfulCreate Created pod: job-wq-1-p17e0
All the pods for that Job succeeded. Yay.
Alternatives
This approach has the advantage that you do not need to modify your "worker" program to be aware that there is a work queue.
It does require that you run a message queue service. If running a queue service is inconvenient, you may want to consider one of the other job patterns.
This approach creates a pod for every work item. If your work items only take a few seconds, though, creating a Pod for every work item may add a lot of overhead. Consider another example, that executes multiple work items per Pod.
In this example, we use the amqp-consume
utility to read the message
from the queue and run our actual program. This has the advantage that you
do not need to modify your program to be aware of the queue.
A different example, shows how to
communicate with the work queue using a client library.
Caveats
If the number of completions is set to less than the number of items in the queue, then not all items will be processed.
If the number of completions is set to more than the number of items in the queue, then the Job will not appear to be completed, even though all items in the queue have been processed. It will start additional pods which will block waiting for a message.
There is an unlikely race with this pattern. If the container is killed in between the time that the message is acknowledged by the amqp-consume command and the time that the container exits with success, or if the node crashes before the kubelet is able to post the success of the pod back to the api-server, then the Job will not appear to be complete, even though all items in the queue have been processed.
3 - Fine Parallel Processing Using a Work Queue
In this example, we will run a Kubernetes Job with multiple parallel worker processes in a given pod.
In this example, as each pod is created, it picks up one unit of work from a task queue, processes it, and repeats until the end of the queue is reached.
Here is an overview of the steps in this example:
- Start a storage service to hold the work queue. In this example, we use Redis to store our work items. In the previous example, we used RabbitMQ. In this example, we use Redis and a custom work-queue client library because AMQP does not provide a good way for clients to detect when a finite-length work queue is empty. In practice you would set up a store such as Redis once and reuse it for the work queues of many jobs, and other things.
- Create a queue, and fill it with messages. Each message represents one task to be done. In this example, a message is an integer that we will do a lengthy computation on.
- Start a Job that works on tasks from the queue. The Job starts several pods. Each pod takes one task from the message queue, processes it, and repeats until the end of the queue is reached.
Before you begin
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
Be familiar with the basic, non-parallel, use of Job.
Starting Redis
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.
You could also download the following files directly:
Filling the Queue with tasks
Now let's fill the queue with some "tasks". In our example, our tasks are 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
.
Create an Image
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:
#!/usr/bin/env python
import time
import rediswq
host="redis"
# Uncomment next two lines if you do not have Kube-DNS working.
# import os
# host = os.getenv("REDIS_SERVICE_HOST")
q = rediswq.RedisWQ(name="job2", host=host)
print("Worker with sessionID: " + q.sessionID())
print("Initial queue state: empty=" + str(q.empty()))
while not q.empty():
item = q.lease(lease_secs=10, block=True, timeout=2)
if item is not None:
itemstr = item.decode("utf-8")
print("Working on " + itemstr)
time.sleep(10) # Put your actual work here instead of sleep.
q.complete(item)
else:
print("Waiting for work")
print("Queue empty, exiting")
You could also download worker.py
,
rediswq.py
, and
Dockerfile
files, then build
the image:
docker build -t job-wq-2 .
Push the image
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
Defining a Job
Here is the job definition:
apiVersion: batch/v1
kind: Job
metadata:
name: job-wq-2
spec:
parallelism: 2
template:
metadata:
name: job-wq-2
spec:
containers:
- name: c
image: gcr.io/myproject/job-wq-2
restartPolicy: OnFailure
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.
Running the Job
So, now run the Job:
kubectl apply -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
You can wait for the Job to succeed, with a timeout:
# The check for condition name is case insensitive
kubectl wait --for=condition=complete --timeout=300s job/job-wq-2
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.
Alternatives
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 ReplicaSet
instead,
and consider running a background processing library such as
https://github.com/resque/resque.
4 - Indexed Job for Parallel Processing with Static Work Assignment
Kubernetes v1.24 [stable]
In this example, you will run a Kubernetes Job that uses multiple parallel worker processes. Each worker is a different container running in its own Pod. The Pods have an index number that the control plane sets automatically, which allows each Pod to identify which part of the overall task to work on.
The pod index is available in the annotation
batch.kubernetes.io/job-completion-index
as a string representing its
decimal value. In order for the containerized task process to obtain this index,
you can publish the value of the annotation using the downward API
mechanism.
For convenience, the control plane automatically sets the downward API to
expose the index in the JOB_COMPLETION_INDEX
environment variable.
Here is an overview of the steps in this example:
- Define a Job manifest using indexed completion. The downward API allows you to pass the pod index annotation as an environment variable or file to the container.
- Start an
Indexed
Job based on that manifest.
Before you begin
You should already be familiar with the basic, non-parallel, use of Job.
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
Your Kubernetes server must be at or later than version v1.21. To check the version, enterkubectl version
.
Choose an approach
To access the work item from the worker program, you have a few options:
- Read the
JOB_COMPLETION_INDEX
environment variable. The Job controller automatically links this variable to the annotation containing the completion index. - Read a file that contains the completion index.
- Assuming that you can't modify the program, you can wrap it with a script that reads the index using any of the methods above and converts it into something that the program can use as input.
For this example, imagine that you chose option 3 and you want to run the rev utility. This program accepts a file as an argument and prints its content reversed.
rev data.txt
You'll use the rev
tool from the
busybox
container image.
As this is only an example, each Pod only does a tiny piece of work (reversing a short string). In a real workload you might, for example, create a Job that represents the task of producing 60 seconds of video based on scene data. Each work item in the video rendering Job would be to render a particular frame of that video clip. Indexed completion would mean that each Pod in the Job knows which frame to render and publish, by counting frames from the start of the clip.
Define an Indexed Job
Here is a sample Job manifest that uses Indexed
completion mode:
apiVersion: batch/v1
kind: Job
metadata:
name: 'indexed-job'
spec:
completions: 5
parallelism: 3
completionMode: Indexed
template:
spec:
restartPolicy: Never
initContainers:
- name: 'input'
image: 'docker.io/library/bash'
command:
- "bash"
- "-c"
- |
items=(foo bar baz qux xyz)
echo ${items[$JOB_COMPLETION_INDEX]} > /input/data.txt
volumeMounts:
- mountPath: /input
name: input
containers:
- name: 'worker'
image: 'docker.io/library/busybox'
command:
- "rev"
- "/input/data.txt"
volumeMounts:
- mountPath: /input
name: input
volumes:
- name: input
emptyDir: {}
In the example above, you use the builtin JOB_COMPLETION_INDEX
environment
variable set by the Job controller for all containers. An init container
maps the index to a static value and writes it to a file that is shared with the
container running the worker through an emptyDir volume.
Optionally, you can define your own environment variable through the downward
API
to publish the index to containers. You can also choose to load a list of values
from a ConfigMap as an environment variable or file.
Alternatively, you can directly use the downward API to pass the annotation value as a volume file, like shown in the following example:
apiVersion: batch/v1
kind: Job
metadata:
name: 'indexed-job'
spec:
completions: 5
parallelism: 3
completionMode: Indexed
template:
spec:
restartPolicy: Never
containers:
- name: 'worker'
image: 'docker.io/library/busybox'
command:
- "rev"
- "/input/data.txt"
volumeMounts:
- mountPath: /input
name: input
volumes:
- name: input
downwardAPI:
items:
- path: "data.txt"
fieldRef:
fieldPath: metadata.annotations['batch.kubernetes.io/job-completion-index']
Running the Job
Now run the Job:
# This uses the first approach (relying on $JOB_COMPLETION_INDEX)
kubectl apply -f https://kubernetes.io/examples/application/job/indexed-job.yaml
When you create this Job, the control plane creates a series of Pods, one for each index you specified. The value of .spec.parallelism
determines how many can run at once whereas .spec.completions
determines how many Pods the Job creates in total.
Because .spec.parallelism
is less than .spec.completions
, the control plane waits for some of the first Pods to complete before starting more of them.
You can wait for the Job to succeed, with a timeout:
# The check for condition name is case insensitive
kubectl wait --for=condition=complete --timeout=300s job/indexed-job
Now, describe the Job and check that it was successful.
kubectl describe jobs/indexed-job
The output is similar to:
Name: indexed-job
Namespace: default
Selector: controller-uid=bf865e04-0b67-483b-9a90-74cfc4c3e756
Labels: controller-uid=bf865e04-0b67-483b-9a90-74cfc4c3e756
job-name=indexed-job
Annotations: <none>
Parallelism: 3
Completions: 5
Start Time: Thu, 11 Mar 2021 15:47:34 +0000
Pods Statuses: 2 Running / 3 Succeeded / 0 Failed
Completed Indexes: 0-2
Pod Template:
Labels: controller-uid=bf865e04-0b67-483b-9a90-74cfc4c3e756
job-name=indexed-job
Init Containers:
input:
Image: docker.io/library/bash
Port: <none>
Host Port: <none>
Command:
bash
-c
items=(foo bar baz qux xyz)
echo ${items[$JOB_COMPLETION_INDEX]} > /input/data.txt
Environment: <none>
Mounts:
/input from input (rw)
Containers:
worker:
Image: docker.io/library/busybox
Port: <none>
Host Port: <none>
Command:
rev
/input/data.txt
Environment: <none>
Mounts:
/input from input (rw)
Volumes:
input:
Type: EmptyDir (a temporary directory that shares a pod's lifetime)
Medium:
SizeLimit: <unset>
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
Normal SuccessfulCreate 4s job-controller Created pod: indexed-job-njkjj
Normal SuccessfulCreate 4s job-controller Created pod: indexed-job-9kd4h
Normal SuccessfulCreate 4s job-controller Created pod: indexed-job-qjwsz
Normal SuccessfulCreate 1s job-controller Created pod: indexed-job-fdhq5
Normal SuccessfulCreate 1s job-controller Created pod: indexed-job-ncslj
In this example, you run the Job with custom values for each index. You can inspect the output of one of the pods:
kubectl logs indexed-job-fdhq5 # Change this to match the name of a Pod from that Job
The output is similar to:
xuq
5 - Job with Pod-to-Pod Communication
In this example, you will run a Job in Indexed completion mode configured such that the pods created by the Job can communicate with each other using pod hostnames rather than pod IP addresses.
Pods within a Job might need to communicate among themselves. The user workload running in each pod could query the Kubernetes API server to learn the IPs of the other Pods, but it's much simpler to rely on Kubernetes' built-in DNS resolution.
Jobs in Indexed completion mode automatically set the pods' hostname to be in the format of
${jobName}-${completionIndex}
. You can use this format to deterministically build
pod hostnames and enable pod communication without needing to create a client connection to
the Kubernetes control plane to obtain pod hostnames/IPs via API requests.
This configuration is useful for use cases where pod networking is required but you don't want to depend on a network connection with the Kubernetes API server.
Before you begin
You should already be familiar with the basic use of Job.
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
Your Kubernetes server must be at or later than version v1.21. To check the version, enterkubectl version
.
Starting a Job with Pod-to-Pod Communication
To enable pod-to-pod communication using pod hostnames in a Job, you must do the following:
-
Set up a headless service with a valid label selector for the pods created by your Job. The headless service must be in the same namespace as the Job. One easy way to do this is to use the
job-name: <your-job-name>
selector, since thejob-name
label will be automatically added by Kubernetes. This configuration will trigger the DNS system to create records of the hostnames of the pods running your Job. -
Configure the headless service as subdomain service for the Job pods by including the following value in your Job template spec:
subdomain: <headless-svc-name>
Example
Below is a working example of a Job with pod-to-pod communication via pod hostnames enabled. The Job is completed only after all pods successfully ping each other using hostnames.
apiVersion: v1
kind: Service
metadata:
name: headless-svc
spec:
clusterIP: None # clusterIP must be None to create a headless service
selector:
job-name: example-job # must match Job name
---
apiVersion: batch/v1
kind: Job
metadata:
name: example-job
spec:
completions: 3
parallelism: 3
completionMode: Indexed
template:
spec:
subdomain: headless-svc # has to match Service name
restartPolicy: Never
containers:
- name: example-workload
image: bash:latest
command:
- bash
- -c
- |
for i in 0 1 2
do
gotStatus="-1"
wantStatus="0"
while [ $gotStatus -ne $wantStatus ]
do
ping -c 1 example-job-${i}.headless-svc > /dev/null 2>&1
gotStatus=$?
if [ $gotStatus -ne $wantStatus ]; then
echo "Failed to ping pod example-job-${i}.headless-svc, retrying in 1 second..."
sleep 1
fi
done
echo "Successfully pinged pod: example-job-${i}.headless-svc"
done
After applying the example above, reach each other over the network
using: <pod-hostname>.<headless-service-name>
. You should see output similar to the following:
kubectl logs example-job-0-qws42
Failed to ping pod example-job-0.headless-svc, retrying in 1 second...
Successfully pinged pod: example-job-0.headless-svc
Successfully pinged pod: example-job-1.headless-svc
Successfully pinged pod: example-job-2.headless-svc
<pod-hostname>.<headless-service-name>
name format used
in this example would not work with DNS policy set to None
or Default
.
You can learn more about pod DNS policies here.
6 - Parallel Processing using Expansions
This task demonstrates running multiple Jobs based on a common template. You can use this approach to process batches of work in parallel.
For this example there are only three items: apple, banana, and cherry. The sample Jobs process each item by printing a string then pausing.
See using Jobs in real workloads to learn about how this pattern fits more realistic use cases.
Before you begin
You should be familiar with the basic, non-parallel, use of Job.
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
For basic templating you need the command-line utility sed
.
To follow the advanced templating example, you need a working installation of Python, and the Jinja2 template library for Python.
Once you have Python set up, you can install Jinja2 by running:
pip install --user jinja2
Create Jobs based on a template
First, download the following template of a Job to a file called job-tmpl.yaml
.
Here's what you'll download:
apiVersion: batch/v1
kind: Job
metadata:
name: process-item-$ITEM
labels:
jobgroup: jobexample
spec:
template:
metadata:
name: jobexample
labels:
jobgroup: jobexample
spec:
containers:
- name: c
image: busybox:1.28
command: ["sh", "-c", "echo Processing item $ITEM && sleep 5"]
restartPolicy: Never
# Use curl to download job-tmpl.yaml
curl -L -s -O https://k8s.io/examples/application/job/job-tmpl.yaml
The file you downloaded is not yet a valid Kubernetes
manifest.
Instead that template is a YAML representation of a Job object with some placeholders
that need to be filled in before it can be used. The $ITEM
syntax is not meaningful to Kubernetes.
Create manifests from the template
The following shell snippet uses sed
to replace the string $ITEM
with the loop
variable, writing into a temporary directory named jobs
. Run this now:
# Expand the template into multiple files, one for each item to be processed.
mkdir ./jobs
for i in apple banana cherry
do
cat job-tmpl.yaml | sed "s/\$ITEM/$i/" > ./jobs/job-$i.yaml
done
Check if it worked:
ls jobs/
The output is similar to this:
job-apple.yaml
job-banana.yaml
job-cherry.yaml
You could use any type of template language (for example: Jinja2; ERB), or write a program to generate the Job manifests.
Create Jobs from the manifests
Next, create all the Jobs with one kubectl command:
kubectl create -f ./jobs
The output is similar to this:
job.batch/process-item-apple created
job.batch/process-item-banana created
job.batch/process-item-cherry created
Now, check on the jobs:
kubectl get jobs -l jobgroup=jobexample
The output is similar to this:
NAME COMPLETIONS DURATION AGE
process-item-apple 1/1 14s 22s
process-item-banana 1/1 12s 21s
process-item-cherry 1/1 12s 20s
Using the -l
option to kubectl selects only the Jobs that are part
of this group of jobs (there might be other unrelated jobs in the system).
You can check on the Pods as well using the same label selector:
kubectl get pods -l jobgroup=jobexample
The output is similar to:
NAME READY STATUS RESTARTS AGE
process-item-apple-kixwv 0/1 Completed 0 4m
process-item-banana-wrsf7 0/1 Completed 0 4m
process-item-cherry-dnfu9 0/1 Completed 0 4m
We can use this single command to check on the output of all jobs at once:
kubectl logs -f -l jobgroup=jobexample
The output should be:
Processing item apple
Processing item banana
Processing item cherry
Clean up
# Remove the Jobs you created
# Your cluster automatically cleans up their Pods
kubectl delete job -l jobgroup=jobexample
Use advanced template parameters
In the first example, each instance of the template had one parameter, and that parameter was also used in the Job's name. However, names are restricted to contain only certain characters.
This slightly more complex example uses the Jinja template language to generate manifests and then objects from those manifests, with a multiple parameters for each Job.
For this part of the task, you are going to use a one-line Python script to convert the template to a set of manifests.
First, copy and paste the following template of a Job object, into a file called job.yaml.jinja2
:
{% set params = [{ "name": "apple", "url": "http://dbpedia.org/resource/Apple", },
{ "name": "banana", "url": "http://dbpedia.org/resource/Banana", },
{ "name": "cherry", "url": "http://dbpedia.org/resource/Cherry" }]
%}
{% for p in params %}
{% set name = p["name"] %}
{% set url = p["url"] %}
---
apiVersion: batch/v1
kind: Job
metadata:
name: jobexample-{{ name }}
labels:
jobgroup: jobexample
spec:
template:
metadata:
name: jobexample
labels:
jobgroup: jobexample
spec:
containers:
- name: c
image: busybox:1.28
command: ["sh", "-c", "echo Processing URL {{ url }} && sleep 5"]
restartPolicy: Never
{% endfor %}
The above template defines two parameters for each Job object using a list of
python dicts (lines 1-4). A for
loop emits one Job manifest for each
set of parameters (remaining lines).
This example relies on a feature of YAML. One YAML file can contain multiple
documents (Kubernetes manifests, in this case), separated by ---
on a line
by itself.
You can pipe the output directly to kubectl
to create the Jobs.
Next, use this one-line Python program to expand the template:
alias render_template='python -c "from jinja2 import Template; import sys; print(Template(sys.stdin.read()).render());"'
Use render_template
to convert the parameters and template into a single
YAML file containing Kubernetes manifests:
# This requires the alias you defined earlier
cat job.yaml.jinja2 | render_template > jobs.yaml
You can view jobs.yaml
to verify that the render_template
script worked
correctly.
Once you are happy that render_template
is working how you intend,
you can pipe its output into kubectl
:
cat job.yaml.jinja2 | render_template | kubectl apply -f -
Kubernetes accepts and runs the Jobs you created.
Clean up
# Remove the Jobs you created
# Your cluster automatically cleans up their Pods
kubectl delete job -l jobgroup=jobexample
Using Jobs in real workloads
In a real use case, each Job performs some substantial computation, such as rendering a frame
of a movie, or processing a range of rows in a database. If you were rendering a movie
you would set $ITEM
to the frame number. If you were processing rows from a database
table, you would set $ITEM
to represent the range of database rows to process.
In the task, you ran a command to collect the output from Pods by fetching
their logs. In a real use case, each Pod for a Job writes its output to
durable storage before completing. You can use a PersistentVolume for each Job,
or an external storage service. For example, if you are rendering frames for a movie,
use HTTP to PUT
the rendered frame data to a URL, using a different URL for each
frame.
Labels on Jobs and Pods
After you create a Job, Kubernetes automatically adds additional labels that distinguish one Job's pods from another Job's pods.
In this example, each Job and its Pod template have a label:
jobgroup=jobexample
.
Kubernetes itself pays no attention to labels named jobgroup
. Setting a label
for all the Jobs you create from a template makes it convenient to operate on all
those Jobs at once.
In the first example you used a template to
create several Jobs. The template ensures that each Pod also gets the same label, so
you can check on all Pods for these templated Jobs with a single command.
jobgroup
is not special or reserved.
You can pick your own labelling scheme.
There are recommended labels
that you can use if you wish.
Alternatives
If you plan to create a large number of Job objects, you may find that:
- Even using labels, managing so many Jobs is cumbersome.
- If you create many Jobs in a batch, you might place high load on the Kubernetes control plane. Alternatively, the Kubernetes API server could rate limit you, temporarily rejecting your requests with a 429 status.
- You are limited by a resource quota on Jobs: the API server permanently rejects some of your requests when you create a great deal of work in one batch.
There are other job patterns that you can use to process large amounts of work without creating very many Job objects.
You could also consider writing your own controller to manage Job objects automatically.
7 - Handling retriable and non-retriable pod failures with Pod failure policy
Kubernetes v1.26 [beta]
This document shows you how to use the Pod failure policy, in combination with the default Pod backoff failure policy, to improve the control over the handling of container- or Pod-level failure within a Job.
The definition of Pod failure policy may help you to:
- better utilize the computational resources by avoiding unnecessary Pod retries.
- avoid Job failures due to Pod disruptions (such preemption, API-initiated eviction or taint-based eviction).
Before you begin
You should already be familiar with the basic use of Job.
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
Your Kubernetes server must be at or later than version v1.25. To check the version, enterkubectl version
.
Using Pod failure policy to avoid unnecessary Pod retries
With the following example, you can learn how to use Pod failure policy to avoid unnecessary Pod restarts when a Pod failure indicates a non-retriable software bug.
First, create a Job based on the config:
apiVersion: batch/v1
kind: Job
metadata:
name: job-pod-failure-policy-failjob
spec:
completions: 8
parallelism: 2
template:
spec:
restartPolicy: Never
containers:
- name: main
image: docker.io/library/bash:5
command: ["bash"]
args:
- -c
- echo "Hello world! I'm going to exit with 42 to simulate a software bug." && sleep 30 && exit 42
backoffLimit: 6
podFailurePolicy:
rules:
- action: FailJob
onExitCodes:
containerName: main
operator: In
values: [42]
by running:
kubectl create -f job-pod-failure-policy-failjob.yaml
After around 30s the entire Job should be terminated. Inspect the status of the Job by running:
kubectl get jobs -l job-name=job-pod-failure-policy-failjob -o yaml
In the Job status, see a job Failed
condition with the field reason
equal PodFailurePolicy
. Additionally, the message
field contains a
more detailed information about the Job termination, such as:
Container main for pod default/job-pod-failure-policy-failjob-8ckj8 failed with exit code 42 matching FailJob rule at index 0
.
For comparison, if the Pod failure policy was disabled it would take 6 retries of the Pod, taking at least 2 minutes.
Clean up
Delete the Job you created:
kubectl delete jobs/job-pod-failure-policy-failjob
The cluster automatically cleans up the Pods.
Using Pod failure policy to ignore Pod disruptions
With the following example, you can learn how to use Pod failure policy to
ignore Pod disruptions from incrementing the Pod retry counter towards the
.spec.backoffLimit
limit.
-
Create a Job based on the config:
apiVersion: batch/v1 kind: Job metadata: name: job-pod-failure-policy-ignore spec: completions: 4 parallelism: 2 template: spec: restartPolicy: Never containers: - name: main image: docker.io/library/bash:5 command: ["bash"] args: - -c - echo "Hello world! I'm going to exit with 0 (success)." && sleep 90 && exit 0 backoffLimit: 0 podFailurePolicy: rules: - action: Ignore onPodConditions: - type: DisruptionTarget
by running:
kubectl create -f job-pod-failure-policy-ignore.yaml
-
Run this command to check the
nodeName
the Pod is scheduled to:nodeName=$(kubectl get pods -l job-name=job-pod-failure-policy-ignore -o jsonpath='{.items[0].spec.nodeName}')
-
Drain the node to evict the Pod before it completes (within 90s):
kubectl drain nodes/$nodeName --ignore-daemonsets --grace-period=0
-
Inspect the
.status.failed
to check the counter for the Job is not incremented:kubectl get jobs -l job-name=job-pod-failure-policy-ignore -o yaml
-
Uncordon the node:
kubectl uncordon nodes/$nodeName
The Job resumes and succeeds.
For comparison, if the Pod failure policy was disabled the Pod disruption would
result in terminating the entire Job (as the .spec.backoffLimit
is set to 0).
Cleaning up
Delete the Job you created:
kubectl delete jobs/job-pod-failure-policy-ignore
The cluster automatically cleans up the Pods.
Alternatives
You could rely solely on the
Pod backoff failure policy,
by specifying the Job's .spec.backoffLimit
field. However, in many situations
it is problematic to find a balance between setting a low value for .spec.backoffLimit
to avoid unnecessary Pod retries, yet high enough to make sure the Job would
not be terminated by Pod disruptions.