Setup All-or-nothing with ready Pods
Some jobs need all pods to be running at the same time to operate; for example, synchronized distributed training or MPI-based jobs which require pod-to-pod communication. On a default Kueue configuration, a pair of such jobs may deadlock if the physical availability of resources do not match the configured quotas in Kueue. The same pair of jobs could run to completion if their pods were scheduled sequentially.
To address this requirement, in version 0.3.0 we introduced an opt-in mechanism
configured via the flag waitForPodsReady
that provides a simple implementation
of the all-or-nothing scheduling. When enabled, the workload is monitored by
Kueue until all of its Pods are ready (meaning scheduled, running, and passing
the optional readiness probe). If not all pods of the workload are ready within
the configured timeout, then the workload is evicted and requeued.
This page shows you how to configure Kueue to use waitForPodsReady
, which
is a simple implementation of the all-or-nothing scheduling.
The intended audience for this page are batch administrators.
Before you begin
Make sure the following conditions are met:
- A Kubernetes cluster is running.
- The kubectl command-line tool has communication with your cluster.
- Kueue is installed in version 0.3.0 or later.
Enabling waitForPodsReady
Follow the instructions described here to install a release version by extending the configuration with the following fields:
waitForPodsReady:
enable: true
timeout: 10m
blockAdmission: true
requeuingStrategy:
timestamp: Eviction | Creation
backoffLimitCount: 5
backoffBaseSeconds: 60
backoffMaxSeconds: 3600
Note
If you update an existing Kueue installation you may need to restart the
kueue-controller-manager
pod in order for Kueue to pick up the updated
configuration. In that case run:
kubectl delete pods --all -n kueue-system
The timeout
(waitForPodsReady.timeout
) is an optional parameter, defaulting to
5 minutes.
When the timeout
expires for an admitted Workload, and the workload’s
pods are not all scheduled yet (i.e., the Workload condition remains
PodsReady=False
), then the Workload’s admission is
cancelled, the corresponding job is suspended and the Workload is re-queued.
The blockAdmission
(waitForPodsReady.blockAdmission
) is an optional parameter.
When enabled, then the workloads are admitted sequentially to prevent deadlock
situations as demonstrated in the example below.
Requeuing Strategy
Note
ThebackoffBaseSeconds
and backoffMaxSeconds
are available in Kueue v0.7.0 and later
The requeuingStrategy
(waitForPodsReady.requeuingStrategy
) contains optional parameters:
timestamp
backoffLimitCount
backoffBaseSeconds
backoffMaxSeconds
The timestamp
field defines which timestamp Kueue uses to order the Workloads in the queue:
Eviction
(default): ThelastTransitionTime
of theEvicted=true
condition withPodsReadyTimeout
reason in a Workload.Creation
: The creationTimestamp in a Workload.
If you want to re-queue a Workload evicted by the PodsReadyTimeout
back to its original place in the queue,
you should set the timestamp to the Creation
.
Kueue will re-queue a Workload evicted by the PodsReadyTimeout
reason until the number of re-queues reaches backoffLimitCount
.
If you don’t specify any value for backoffLimitCount
,
a Workload is repeatedly and endlessly re-queued to the queue based on the timestamp
.
Once the number of re-queues reaches the limit, Kueue deactivates the Workload.
The time to re-queue a workload after each consecutive timeout is increased
exponentially, with the exponent of 2. The first delay is determined by the
backoffBaseSeconds
parameter (defaulting to 60). You can configure the maximum
backoff time by setting the backoffMaxSeconds
(defaulting to 3600). Using the defaults, the
evicted workload is re-queued after approximately 60, 120, 240, ..., 3600, ..., 3600
seconds.
Even if the backoff time reaches the backoffMaxSeconds
, Kueue will continue to re-queue an evicted Workload with the backoffMaxSeconds
until the number of re-queue reaches the backoffLimitCount
.
Example
In this example we demonstrate the impact of enabling waitForPodsReady
in Kueue.
We create two jobs which both require all their pods to be running at the same
time to complete. The cluster has enough resources to support running one of the
jobs at the same time, but not both.
Note
In this example we use a cluster with autoscaling disabled in order to simulate issues with resource provisioning to satisfy the configured cluster quota.1. Preparation
First, check the amount of allocatable memory in your cluster. In many cases this can be done with this command:
TOTAL_ALLOCATABLE=$(kubectl get node --selector='!node-role.kubernetes.io/master,!node-role.kubernetes.io/control-plane' -o jsonpath='{range .items[*]}{.status.allocatable.memory}{"\n"}{end}' | numfmt --from=auto | awk '{s+=$1} END {print s}')
echo $TOTAL_ALLOCATABLE
In our case this outputs 8838569984
which, for the purpose of the example, can
be approximated as 8429Mi
.
Configure ClusterQueue quotas
We configure the memory flavor by doubling the total memory allocatable in our cluster, in order to simulate issues with provisioning.
Save the following cluster queues configuration as cluster-queues.yaml
:
apiVersion: kueue.x-k8s.io/v1beta1
kind: ResourceFlavor
metadata:
name: "default-flavor"
---
apiVersion: kueue.x-k8s.io/v1beta1
kind: ClusterQueue
metadata:
name: "cluster-queue"
spec:
namespaceSelector: {}
resourceGroups:
- coveredResources: ["memory"]
flavors:
- name: "default-flavor"
resources:
- name: "memory"
nominalQuota: 16858Mi # double the value of allocatable memory in the cluster
---
apiVersion: kueue.x-k8s.io/v1beta1
kind: LocalQueue
metadata:
namespace: "default"
name: "user-queue"
spec:
clusterQueue: "cluster-queue"
Then, apply the configuration by:
kubectl apply -f cluster-queues.yaml
Prepare the job template
Save the following job template in the job-template.yaml
file. Note the
_ID_
placeholders which will be replaced to create configurations for the
two jobs. Also, pay attention to configure the memory field for the container
as be 75% of the total allocatable memory per pod. In our case this is
75%*(8429Mi/20)=316Mi
. In this scenario there is not enough resources to
run all pods for both jobs at the same time, risking deadlock.
apiVersion: v1
kind: Service
metadata:
name: svc_ID_
spec:
clusterIP: None
selector:
job-name: job_ID_
ports:
- name: http
protocol: TCP
port: 8080
---
apiVersion: v1
kind: ConfigMap
metadata:
name: script-code_ID_
data:
main.py: |
from http.server import BaseHTTPRequestHandler, HTTPServer
from urllib.request import urlopen
import sys, os, time, logging
logging.basicConfig(stream=sys.stdout, level=logging.DEBUG)
serverPort = 8080
INDEX_COUNT = int(sys.argv[1])
index = int(os.environ.get('JOB_COMPLETION_INDEX'))
logger = logging.getLogger('LOG' + str(index))
class WorkerServer(BaseHTTPRequestHandler):
def do_GET(self):
self.send_response(200)
self.end_headers()
if "exit" in self.path:
self.wfile.write(bytes("Exiting", "utf-8"))
self.wfile.close()
sys.exit(0)
else:
self.wfile.write(bytes("Running", "utf-8"))
def call_until_success(url):
while True:
try:
logger.info("Calling URL: " + url)
with urlopen(url) as response:
response_content = response.read().decode('utf-8')
logger.info("Response content from %s: %s" % (url, response_content))
return
except Exception as e:
logger.warning("Got exception when calling %s: %s" % (url, e))
time.sleep(1)
if __name__ == "__main__":
if index == 0:
for i in range(1, INDEX_COUNT):
call_until_success("http://job_ID_-%d.svc_ID_:8080/ping" % i)
logger.info("All workers running")
time.sleep(10) # sleep 10s to simulate doing something
for i in range(1, INDEX_COUNT):
call_until_success("http://job_ID_-%d.svc_ID_:8080/exit" % i)
logger.info("All workers stopped")
else:
webServer = HTTPServer(("", serverPort), WorkerServer)
logger.info("Server started at port %s" % serverPort)
webServer.serve_forever()
---
apiVersion: batch/v1
kind: Job
metadata:
name: job_ID_
labels:
kueue.x-k8s.io/queue-name: user-queue
spec:
parallelism: 20
completions: 20
completionMode: Indexed
suspend: true
template:
spec:
subdomain: svc_ID_
volumes:
- name: script-volume
configMap:
name: script-code_ID_
containers:
- name: main
image: python:bullseye
command: ["python"]
args:
- /script-path/main.py
- "20"
ports:
- containerPort: 8080
imagePullPolicy: IfNotPresent
resources:
requests:
memory: "316Mi" # choose the value as 75% * (total allocatable memory / 20)
volumeMounts:
- mountPath: /script-path
name: script-volume
restartPolicy: Never
backoffLimit: 0
Additional quick job
We also prepare an additional job to increase the variance in the timings to
make the deadlock more likely. Save the following yaml as quick-job.yaml
:
apiVersion: batch/v1
kind: Job
metadata:
name: quick-job
annotations:
kueue.x-k8s.io/queue-name: user-queue
spec:
parallelism: 50
completions: 50
suspend: true
template:
spec:
restartPolicy: Never
containers:
- name: sleep
image: bash:5
command: ["bash"]
args: ["-c", 'echo "Hello world"']
resources:
requests:
memory: "1"
backoffLimit: 0
2. Induce a deadlock under the default configuration (optional)
Run the jobs
sed 's/_ID_/1/g' job-template.yaml > /tmp/job1.yaml
sed 's/_ID_/2/g' job-template.yaml > /tmp/job2.yaml
kubectl create -f quick-job.yaml
kubectl create -f /tmp/job1.yaml
kubectl create -f /tmp/job2.yaml
After a while check the status of the pods by
kubectl get pods
The output is like this (omitting the pods of the quick-job
for brevity):
NAME READY STATUS RESTARTS AGE
job1-0-9pvs8 1/1 Running 0 28m
job1-1-w9zht 1/1 Running 0 28m
job1-10-fg99v 1/1 Running 0 28m
job1-11-4gspm 1/1 Running 0 28m
job1-12-w5jft 1/1 Running 0 28m
job1-13-8d5jk 1/1 Running 0 28m
job1-14-h5q8x 1/1 Running 0 28m
job1-15-kkv4j 0/1 Pending 0 28m
job1-16-frs8k 0/1 Pending 0 28m
job1-17-g78g8 0/1 Pending 0 28m
job1-18-2ghmt 0/1 Pending 0 28m
job1-19-4w2j5 0/1 Pending 0 28m
job1-2-9s486 1/1 Running 0 28m
job1-3-s9kh4 1/1 Running 0 28m
job1-4-52mj9 1/1 Running 0 28m
job1-5-bpjv5 1/1 Running 0 28m
job1-6-7f7tj 1/1 Running 0 28m
job1-7-pnq7w 1/1 Running 0 28m
job1-8-7s894 1/1 Running 0 28m
job1-9-kz4gt 1/1 Running 0 28m
job2-0-x6xvg 1/1 Running 0 28m
job2-1-flkpj 1/1 Running 0 28m
job2-10-vf4j9 1/1 Running 0 28m
job2-11-ktbld 0/1 Pending 0 28m
job2-12-sf4xb 1/1 Running 0 28m
job2-13-9j7lp 0/1 Pending 0 28m
job2-14-czc6l 1/1 Running 0 28m
job2-15-m77zt 0/1 Pending 0 28m
job2-16-7p7fs 0/1 Pending 0 28m
job2-17-sfdmj 0/1 Pending 0 28m
job2-18-cs4lg 0/1 Pending 0 28m
job2-19-x66dt 0/1 Pending 0 28m
job2-2-hnqjv 1/1 Running 0 28m
job2-3-pkwhw 1/1 Running 0 28m
job2-4-gdtsh 1/1 Running 0 28m
job2-5-6swdc 1/1 Running 0 28m
job2-6-qb6sp 1/1 Running 0 28m
job2-7-grcg4 0/1 Pending 0 28m
job2-8-kg568 1/1 Running 0 28m
job2-9-hvwj8 0/1 Pending 0 28m
These jobs are now deadlock’ed and are not going to be able to make progress.
Cleanup
Clean up the jobs by:
kubectl delete -f quick-job.yaml
kubectl delete -f /tmp/job1.yaml
kubectl delete -f /tmp/job2.yaml
3. Run with waitForPodsReady enabled
Enable waitForPodsReady
Update the Kueue configuration following the instructions here.
Run the jobs
Run the start.sh
script
sed 's/_ID_/1/g' job-template.yaml > /tmp/job1.yaml
sed 's/_ID_/2/g' job-template.yaml > /tmp/job2.yaml
kubectl create -f quick-job.yaml
kubectl create -f /tmp/job1.yaml
kubectl create -f /tmp/job2.yaml
Monitor the progress
Execute the following command in a couple of seconds internals to monitor the progress:
kubectl get pods
We omit the pods of the completed quick
job for brevity.
Output when job1
is starting up, note that job2
remains suspended:
NAME READY STATUS RESTARTS AGE
job1-0-gc284 0/1 ContainerCreating 0 1s
job1-1-xz555 0/1 ContainerCreating 0 1s
job1-10-2ltws 0/1 Pending 0 1s
job1-11-r4778 0/1 ContainerCreating 0 1s
job1-12-xx8mn 0/1 Pending 0 1s
job1-13-glb8j 0/1 Pending 0 1s
job1-14-gnjpg 0/1 Pending 0 1s
job1-15-dzlqh 0/1 Pending 0 1s
job1-16-ljnj9 0/1 Pending 0 1s
job1-17-78tzv 0/1 Pending 0 1s
job1-18-4lhw2 0/1 Pending 0 1s
job1-19-hx6zv 0/1 Pending 0 1s
job1-2-hqlc6 0/1 ContainerCreating 0 1s
job1-3-zx55w 0/1 ContainerCreating 0 1s
job1-4-k2tb4 0/1 Pending 0 1s
job1-5-2zcw2 0/1 ContainerCreating 0 1s
job1-6-m2qzw 0/1 ContainerCreating 0 1s
job1-7-hgp9n 0/1 ContainerCreating 0 1s
job1-8-ss248 0/1 ContainerCreating 0 1s
job1-9-nwqmj 0/1 ContainerCreating 0 1s
Output when job1
is running and job2
is now unsuspended as job
has all
the required resources assigned:
NAME READY STATUS RESTARTS AGE
job1-0-gc284 1/1 Running 0 9s
job1-1-xz555 1/1 Running 0 9s
job1-10-2ltws 1/1 Running 0 9s
job1-11-r4778 1/1 Running 0 9s
job1-12-xx8mn 1/1 Running 0 9s
job1-13-glb8j 1/1 Running 0 9s
job1-14-gnjpg 1/1 Running 0 9s
job1-15-dzlqh 1/1 Running 0 9s
job1-16-ljnj9 1/1 Running 0 9s
job1-17-78tzv 1/1 Running 0 9s
job1-18-4lhw2 1/1 Running 0 9s
job1-19-hx6zv 1/1 Running 0 9s
job1-2-hqlc6 1/1 Running 0 9s
job1-3-zx55w 1/1 Running 0 9s
job1-4-k2tb4 1/1 Running 0 9s
job1-5-2zcw2 1/1 Running 0 9s
job1-6-m2qzw 1/1 Running 0 9s
job1-7-hgp9n 1/1 Running 0 9s
job1-8-ss248 1/1 Running 0 9s
job1-9-nwqmj 1/1 Running 0 9s
job2-0-djnjd 1/1 Running 0 3s
job2-1-trw7b 0/1 Pending 0 2s
job2-10-228cc 0/1 Pending 0 2s
job2-11-2ct8m 0/1 Pending 0 2s
job2-12-sxkqm 0/1 Pending 0 2s
job2-13-md92n 0/1 Pending 0 2s
job2-14-4v2ww 0/1 Pending 0 2s
job2-15-sph8h 0/1 Pending 0 2s
job2-16-2nvk2 0/1 Pending 0 2s
job2-17-f7g6z 0/1 Pending 0 2s
job2-18-9t9xd 0/1 Pending 0 2s
job2-19-tgf5c 0/1 Pending 0 2s
job2-2-9hcsd 0/1 Pending 0 2s
job2-3-557lt 0/1 Pending 0 2s
job2-4-k2d6b 0/1 Pending 0 2s
job2-5-nkkhx 0/1 Pending 0 2s
job2-6-5r76n 0/1 Pending 0 2s
job2-7-pmzb5 0/1 Pending 0 2s
job2-8-xdqtp 0/1 Pending 0 2s
job2-9-c4rcl 0/1 Pending 0 2s
Once job1
completes, it frees the resources required by job2
to run its pods
to make progress. Finally, all jobs complete.
Cleanup
Clean up the jobs by:
kubectl delete -f quick-job.yaml
kubectl delete -f /tmp/job1.yaml
kubectl delete -f /tmp/job2.yaml
Drawbacks
When enabling waitForPodsReady
, the admission of Workloads may
be unnecessarily slowed down by sequencing in case the cluster has enough
resources to support concurrent Workload startup.
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