This page shows how to run a replicated stateful application using a StatefulSet controller. The example is a MySQL single-master topology with multiple slaves running asynchronous replication.
Note that this is not a production configuration. In particular, MySQL settings remain on insecure defaults to keep the focus on general patterns for running stateful applications in Kubernetes.
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. If you do not already have a cluster, you can create one by using Minikube, or you can use one of these Kubernetes playgrounds:
To check the version, enter kubectl version
.
You need to either have a dynamic PersistentVolume provisioner with a default StorageClass, or statically provision PersistentVolumes yourself to satisfy the PersistentVolumeClaims used here.
This tutorial assumes you are familiar with PersistentVolumes and StatefulSets, as well as other core concepts like Pods, Services, and ConfigMaps.
Some familiarity with MySQL helps, but this tutorial aims to present general patterns that should be useful for other systems.
The example MySQL deployment consists of a ConfigMap, two Services, and a StatefulSet.
Create the ConfigMap from the following YAML configuration file:
application/mysql/mysql-configmap.yaml
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kubectl apply -f https://k8s.io/examples/application/mysql/mysql-configmap.yaml
This ConfigMap provides my.cnf
overrides that let you independently control
configuration on the MySQL master and slaves.
In this case, you want the master to be able to serve replication logs to slaves
and you want slaves to reject any writes that don’t come via replication.
There’s nothing special about the ConfigMap itself that causes different portions to apply to different Pods. Each Pod decides which portion to look at as it’s initializing, based on information provided by the StatefulSet controller.
Create the Services from the following YAML configuration file:
application/mysql/mysql-services.yaml
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kubectl apply -f https://k8s.io/examples/application/mysql/mysql-services.yaml
The Headless Service provides a home for the DNS entries that the StatefulSet
controller creates for each Pod that’s part of the set.
Because the Headless Service is named mysql
, the Pods are accessible by
resolving <pod-name>.mysql
from within any other Pod in the same Kubernetes
cluster and namespace.
The Client Service, called mysql-read
, is a normal Service with its own
cluster IP that distributes connections across all MySQL Pods that report
being Ready. The set of potential endpoints includes the MySQL master and all
slaves.
Note that only read queries can use the load-balanced Client Service. Because there is only one MySQL master, clients should connect directly to the MySQL master Pod (through its DNS entry within the Headless Service) to execute writes.
Finally, create the StatefulSet from the following YAML configuration file:
application/mysql/mysql-statefulset.yaml
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kubectl apply -f https://k8s.io/examples/application/mysql/mysql-statefulset.yaml
You can watch the startup progress by running:
kubectl get pods -l app=mysql --watch
After a while, you should see all 3 Pods become Running:
NAME READY STATUS RESTARTS AGE
mysql-0 2/2 Running 0 2m
mysql-1 2/2 Running 0 1m
mysql-2 2/2 Running 0 1m
Press Ctrl+C to cancel the watch. If you don’t see any progress, make sure you have a dynamic PersistentVolume provisioner enabled as mentioned in the prerequisites.
This manifest uses a variety of techniques for managing stateful Pods as part of a StatefulSet. The next section highlights some of these techniques to explain what happens as the StatefulSet creates Pods.
The StatefulSet controller starts Pods one at a time, in order by their ordinal index. It waits until each Pod reports being Ready before starting the next one.
In addition, the controller assigns each Pod a unique, stable name of the form
<statefulset-name>-<ordinal-index>
, which results in Pods named mysql-0
,
mysql-1
, and mysql-2
.
The Pod template in the above StatefulSet manifest takes advantage of these properties to perform orderly startup of MySQL replication.
Before starting any of the containers in the Pod spec, the Pod first runs any Init Containers in the order defined.
The first Init Container, named init-mysql
, generates special MySQL config
files based on the ordinal index.
The script determines its own ordinal index by extracting it from the end of
the Pod name, which is returned by the hostname
command.
Then it saves the ordinal (with a numeric offset to avoid reserved values)
into a file called server-id.cnf
in the MySQL conf.d
directory.
This translates the unique, stable identity provided by the StatefulSet
controller into the domain of MySQL server IDs, which require the same
properties.
The script in the init-mysql
container also applies either master.cnf
or
slave.cnf
from the ConfigMap by copying the contents into conf.d
.
Because the example topology consists of a single MySQL master and any number of
slaves, the script simply assigns ordinal 0
to be the master, and everyone
else to be slaves.
Combined with the StatefulSet controller’s
deployment order guarantee,
this ensures the MySQL master is Ready before creating slaves, so they can begin
replicating.
In general, when a new Pod joins the set as a slave, it must assume the MySQL master might already have data on it. It also must assume that the replication logs might not go all the way back to the beginning of time. These conservative assumptions are the key to allow a running StatefulSet to scale up and down over time, rather than being fixed at its initial size.
The second Init Container, named clone-mysql
, performs a clone operation on
a slave Pod the first time it starts up on an empty PersistentVolume.
That means it copies all existing data from another running Pod,
so its local state is consistent enough to begin replicating from the master.
MySQL itself does not provide a mechanism to do this, so the example uses a
popular open-source tool called Percona XtraBackup.
During the clone, the source MySQL server might suffer reduced performance.
To minimize impact on the MySQL master, the script instructs each Pod to clone
from the Pod whose ordinal index is one lower.
This works because the StatefulSet controller always ensures Pod N
is
Ready before starting Pod N+1
.
After the Init Containers complete successfully, the regular containers run.
The MySQL Pods consist of a mysql
container that runs the actual mysqld
server, and an xtrabackup
container that acts as a
sidecar.
The xtrabackup
sidecar looks at the cloned data files and determines if
it’s necessary to initialize MySQL replication on the slave.
If so, it waits for mysqld
to be ready and then executes the
CHANGE MASTER TO
and START SLAVE
commands with replication parameters
extracted from the XtraBackup clone files.
Once a slave begins replication, it remembers its MySQL master and
reconnects automatically if the server restarts or the connection dies.
Also, because slaves look for the master at its stable DNS name
(mysql-0.mysql
), they automatically find the master even if it gets a new
Pod IP due to being rescheduled.
Lastly, after starting replication, the xtrabackup
container listens for
connections from other Pods requesting a data clone.
This server remains up indefinitely in case the StatefulSet scales up, or in
case the next Pod loses its PersistentVolumeClaim and needs to redo the clone.
You can send test queries to the MySQL master (hostname mysql-0.mysql
)
by running a temporary container with the mysql:5.7
image and running the
mysql
client binary.
kubectl run mysql-client --image=mysql:5.7 -i --rm --restart=Never --\
mysql -h mysql-0.mysql <<EOF
CREATE DATABASE test;
CREATE TABLE test.messages (message VARCHAR(250));
INSERT INTO test.messages VALUES ('hello');
EOF
Use the hostname mysql-read
to send test queries to any server that reports
being Ready:
kubectl run mysql-client --image=mysql:5.7 -i -t --rm --restart=Never --\
mysql -h mysql-read -e "SELECT * FROM test.messages"
You should get output like this:
Waiting for pod default/mysql-client to be running, status is Pending, pod ready: false
+---------+
| message |
+---------+
| hello |
+---------+
pod "mysql-client" deleted
To demonstrate that the mysql-read
Service distributes connections across
servers, you can run SELECT @@server_id
in a loop:
kubectl run mysql-client-loop --image=mysql:5.7 -i -t --rm --restart=Never --\
bash -ic "while sleep 1; do mysql -h mysql-read -e 'SELECT @@server_id,NOW()'; done"
You should see the reported @@server_id
change randomly, because a different
endpoint might be selected upon each connection attempt:
+-------------+---------------------+
| @@server_id | NOW() |
+-------------+---------------------+
| 100 | 2006-01-02 15:04:05 |
+-------------+---------------------+
+-------------+---------------------+
| @@server_id | NOW() |
+-------------+---------------------+
| 102 | 2006-01-02 15:04:06 |
+-------------+---------------------+
+-------------+---------------------+
| @@server_id | NOW() |
+-------------+---------------------+
| 101 | 2006-01-02 15:04:07 |
+-------------+---------------------+
You can press Ctrl+C when you want to stop the loop, but it’s useful to keep it running in another window so you can see the effects of the following steps.
To demonstrate the increased availability of reading from the pool of slaves
instead of a single server, keep the SELECT @@server_id
loop from above
running while you force a Pod out of the Ready state.
The readiness probe
for the mysql
container runs the command mysql -h 127.0.0.1 -e 'SELECT 1'
to make sure the server is up and able to execute queries.
One way to force this readiness probe to fail is to break that command:
kubectl exec mysql-2 -c mysql -- mv /usr/bin/mysql /usr/bin/mysql.off
This reaches into the actual container’s filesystem for Pod mysql-2
and
renames the mysql
command so the readiness probe can’t find it.
After a few seconds, the Pod should report one of its containers as not Ready,
which you can check by running:
kubectl get pod mysql-2
Look for 1/2
in the READY
column:
NAME READY STATUS RESTARTS AGE
mysql-2 1/2 Running 0 3m
At this point, you should see your SELECT @@server_id
loop continue to run,
although it never reports 102
anymore.
Recall that the init-mysql
script defined server-id
as 100 + $ordinal
,
so server ID 102
corresponds to Pod mysql-2
.
Now repair the Pod and it should reappear in the loop output after a few seconds:
kubectl exec mysql-2 -c mysql -- mv /usr/bin/mysql.off /usr/bin/mysql
The StatefulSet also recreates Pods if they’re deleted, similar to what a ReplicaSet does for stateless Pods.
kubectl delete pod mysql-2
The StatefulSet controller notices that no mysql-2
Pod exists anymore,
and creates a new one with the same name and linked to the same
PersistentVolumeClaim.
You should see server ID 102
disappear from the loop output for a while
and then return on its own.
If your Kubernetes cluster has multiple Nodes, you can simulate Node downtime (such as when Nodes are upgraded) by issuing a drain.
First determine which Node one of the MySQL Pods is on:
kubectl get pod mysql-2 -o wide
The Node name should show up in the last column:
NAME READY STATUS RESTARTS AGE IP NODE
mysql-2 2/2 Running 0 15m 10.244.5.27 kubernetes-node-9l2t
Then drain the Node by running the following command, which cordons it so
no new Pods may schedule there, and then evicts any existing Pods.
Replace <node-name>
with the name of the Node you found in the last step.
This might impact other applications on the Node, so it’s best to only do this in a test cluster.
kubectl drain <node-name> --force --delete-local-data --ignore-daemonsets
Now you can watch as the Pod reschedules on a different Node:
kubectl get pod mysql-2 -o wide --watch
It should look something like this:
NAME READY STATUS RESTARTS AGE IP NODE
mysql-2 2/2 Terminating 0 15m 10.244.1.56 kubernetes-node-9l2t
[...]
mysql-2 0/2 Pending 0 0s <none> kubernetes-node-fjlm
mysql-2 0/2 Init:0/2 0 0s <none> kubernetes-node-fjlm
mysql-2 0/2 Init:1/2 0 20s 10.244.5.32 kubernetes-node-fjlm
mysql-2 0/2 PodInitializing 0 21s 10.244.5.32 kubernetes-node-fjlm
mysql-2 1/2 Running 0 22s 10.244.5.32 kubernetes-node-fjlm
mysql-2 2/2 Running 0 30s 10.244.5.32 kubernetes-node-fjlm
And again, you should see server ID 102
disappear from the
SELECT @@server_id
loop output for a while and then return.
Now uncordon the Node to return it to a normal state:
kubectl uncordon <node-name>
With MySQL replication, you can scale your read query capacity by adding slaves. With StatefulSet, you can do this with a single command:
kubectl scale statefulset mysql --replicas=5
Watch the new Pods come up by running:
kubectl get pods -l app=mysql --watch
Once they’re up, you should see server IDs 103
and 104
start appearing in
the SELECT @@server_id
loop output.
You can also verify that these new servers have the data you added before they existed:
kubectl run mysql-client --image=mysql:5.7 -i -t --rm --restart=Never --\
mysql -h mysql-3.mysql -e "SELECT * FROM test.messages"
Waiting for pod default/mysql-client to be running, status is Pending, pod ready: false
+---------+
| message |
+---------+
| hello |
+---------+
pod "mysql-client" deleted
Scaling back down is also seamless:
kubectl scale statefulset mysql --replicas=3
Note, however, that while scaling up creates new PersistentVolumeClaims automatically, scaling down does not automatically delete these PVCs. This gives you the choice to keep those initialized PVCs around to make scaling back up quicker, or to extract data before deleting them.
You can see this by running:
kubectl get pvc -l app=mysql
Which shows that all 5 PVCs still exist, despite having scaled the StatefulSet down to 3:
NAME STATUS VOLUME CAPACITY ACCESSMODES AGE
data-mysql-0 Bound pvc-8acbf5dc-b103-11e6-93fa-42010a800002 10Gi RWO 20m
data-mysql-1 Bound pvc-8ad39820-b103-11e6-93fa-42010a800002 10Gi RWO 20m
data-mysql-2 Bound pvc-8ad69a6d-b103-11e6-93fa-42010a800002 10Gi RWO 20m
data-mysql-3 Bound pvc-50043c45-b1c5-11e6-93fa-42010a800002 10Gi RWO 2m
data-mysql-4 Bound pvc-500a9957-b1c5-11e6-93fa-42010a800002 10Gi RWO 2m
If you don’t intend to reuse the extra PVCs, you can delete them:
kubectl delete pvc data-mysql-3
kubectl delete pvc data-mysql-4
Cancel the SELECT @@server_id
loop by pressing Ctrl+C in its terminal,
or running the following from another terminal:
kubectl delete pod mysql-client-loop --now
Delete the StatefulSet. This also begins terminating the Pods.
kubectl delete statefulset mysql
Verify that the Pods disappear. They might take some time to finish terminating.
kubectl get pods -l app=mysql
You’ll know the Pods have terminated when the above returns:
No resources found.
Delete the ConfigMap, Services, and PersistentVolumeClaims.
kubectl delete configmap,service,pvc -l app=mysql
If you manually provisioned PersistentVolumes, you also need to manually delete them, as well as release the underlying resources. If you used a dynamic provisioner, it automatically deletes the PersistentVolumes when it sees that you deleted the PersistentVolumeClaims. Some dynamic provisioners (such as those for EBS and PD) also release the underlying resources upon deleting the PersistentVolumes.
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