You are looking at the documentation of a prior release. To read the documentation of the latest release, please
visit here.
New to KubeDB? Please start here.
Run RabbitMQ with Custom PodTemplate
KubeDB supports providing custom configuration for RabbitMQ via PodTemplate. This tutorial will show you how to use KubeDB to run a RabbitMQ database with custom configuration using PodTemplate.
Before You Begin
At first, 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 kind.
Now, install KubeDB cli on your workstation and KubeDB operator in your cluster following the steps here.
To keep things isolated, this tutorial uses a separate namespace called
demo
throughout this tutorial.$ kubectl create ns demo namespace/demo created
Note: YAML files used in this tutorial are stored in docs/examples/rabbitmq folder in GitHub repository kubedb/docs.
Overview
KubeDB allows providing a template for database pod through spec.podTemplate
. KubeDB operator will pass the information provided in spec.podTemplate
to the PetSet created for RabbitMQ database.
KubeDB accept following fields to set in spec.podTemplate:
- metadata:
- annotations (pod’s annotation)
- labels (pod’s labels)
- controller:
- annotations (petset’s annotation)
- labels (petset’s labels)
- spec:
- volumes
- initContainers
- containers
- imagePullSecrets
- nodeSelector
- affinity
- serviceAccountName
- schedulerName
- tolerations
- priorityClassName
- priority
- securityContext
- livenessProbe
- readinessProbe
- lifecycle
Read about the fields in details in PodTemplate concept,
CRD Configuration
Below is the YAML for the RabbitMQ created in this example. Here, spec.podTemplate.spec.containers[].env
specifies additional environment variables by users.
In this tutorial, we will register additional two additional environment variable on rabbitmq bootstrap. These variables will update rabbitmq base log directory and configure the console logs to only view new logs once accessed.
apiVersion: kubedb.com/v1alpha2
kind: RabbitMQ
metadata:
name: rm-misc-config
namespace: demo
spec:
version: "3.13.2"
replicas: 1
podTemplate:
spec:
containers:
- name: rabbitmq
env:
- name: "RABBITMQ_LOG_BASE"
value: '/var/log/cluster'
- name: "RABBITMQ_CONSOLE_LOG"
value: 'new'
storage:
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 1Gi
storageClassName: standard
storageType: Durable
deletionPolicy: WipeOut
$ kubectl create -f https://github.com/kubedb/docs/raw/v2024.8.21/docs/examples/rabbitmq/configuration/rm-misc-config.yaml
rabbitmq.kubedb.com/rm-misc-config created
Now, wait a few minutes. KubeDB operator will create necessary petset, services, secret etc. If everything goes well, we will see that a pod with the name rm-misc-config-0
has been created.
Check that the petset’s pod is running
$ kubectl get pod -n demo
NAME READY STATUS RESTARTS AGE
rm-misc-config-0 1/1 Running 0 68s
Now, check if the rabbitmq has started with the custom configuration we have provided. We will fetch log in the pod and see the RABBITMQ_LOG_BASE
, the new log directory exists of not.
$ kubectl exec -it -n demo -- bash
## ## RabbitMQ 3.13.2
## ##
########## Copyright (c) 2007-2024 Broadcom Inc and/or its subsidiaries
###### ##
########## Licensed under the MPL 2.0. Website: https://rabbitmq.com
Erlang: 26.2.5 [jit]
TLS Library: OpenSSL - OpenSSL 3.1.5 30 Jan 2024
Release series support status: supported
Doc guides: https://www.rabbitmq.com/docs
Support: https://www.rabbitmq.com/docs/contact
Tutorials: https://www.rabbitmq.com/tutorials
Monitoring: https://www.rabbitmq.com/docs/monitoring
Upgrading: https://www.rabbitmq.com/docs/upgrade
Logs: /var/log/rabbitmq/cluster/[email protected]
<stdout>
So, we can see that that logs are being written to Logs: /var/log/rabbitmq/cluster/[email protected] file.
Custom Sidecar Containers
Here in this example we will add an extra sidecar container with our RabbitMQ container. Suppose, you are running a KubeDB-managed rabbitmq, and you need to monitor the general logs. We can configure rabbitmq to write those logs in any directory, in the prior example we have configured rabbitmq to write logs to /var/log/rabbitmq/cluster
directory. In order to export those logs to some remote monitoring solution (such as, Elasticsearch, Logstash, Kafka or Redis) will use a tool like Filebeat. Filebeat is used to ship logs and files from devices, cloud, containers and hosts. So, it is required to run Filebeat as a sidecar container along with the KubeDB-managed rabbitmq. Here’s a quick demonstration on how to accomplish it.
Firstly, we are going to make our custom filebeat image with our required configuration.
filebeat.inputs:
- type: log
paths:
- /var/log/rabbitmq/cluster
output.console:
pretty: true
Save this yaml with name filebeat.yml
. Now prepare the dockerfile,
FROM elastic/filebeat:7.17.1
COPY filebeat.yml /usr/share/filebeat
USER root
RUN chmod go-w /usr/share/filebeat/filebeat.yml
USER filebeat
Now run these following commands to build and push the docker image to your docker repository.
$ docker build -t repository_name/custom_filebeat:latest .
$ docker push repository_name/custom_filebeat:latest
Now we will deploy our RabbitMQ with custom sidecar container to mount filebeats input directory as a shared directory with rabbitmq’s log base directory. Here is the yaml of our RabbitMQ:
apiVersion: kubedb.com/v1alpha2
kind: RabbitMQ
metadata:
name: rabbitmq-custom-sidecar
namespace: demo
spec:
version: "3.13.2"
replicas: 1
podTemplate:
spec:
containers:
- name: rabbitmq
volumeMounts:
- mountPath: /var/log/rabbitmq/cluster
name: log
readOnly: false
- name: filebeat
image: repository_name/custom_filebeat:latest
volumeMounts:
- mountPath: /var/log/rabbitmq/cluster
name: log
readOnly: true
volumes:
- name: log
emptyDir: {}
storage:
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 1Gi
storageClassName: standard
storageType: Durable
deletionPolicy: WipeOut
$ kubectl create -f https://github.com/kubedb/docs/raw/v2024.8.21/docs/examples/rabbitmq/configuration/rabbitmq-config-sidecar.yaml
rabbitmq.kubedb.com/rabbitmq-custom-sidecar created
Now, wait a few minutes. KubeDB operator will create necessary petset, services, secret etc. If everything goes well, we will see that a pod with the name rabbitmq-custom-sidecar-0
has been created.
Check that the petset’s pod is running
$ kubectl get pod -n demo
NAME READY STATUS RESTARTS AGE
rabbitmq-custom-sidecar-0 2/2 Running 0 33s
Now, Let’s fetch the logs shipped to filebeat console output. The outputs will be generated in json format.
$ kubectl logs -f -n demo rabbitmq-custom-sidecar-0 -c filebeat
We will find the query logs in filebeat console output. So, we have successfully extracted logs from rabbitmq to our sidecar filebeat container.
Using Node Selector
Here in this example we will use node selector to schedule our RabbitMQ pod to a specific node. Applying nodeSelector to the Pod involves several steps. We first need to assign a label to some node that will be later used by the nodeSelector
. Let’s find what nodes exist in your cluster. To get the name of these nodes, you can run:
$ kubectl get nodes --show-labels
NAME STATUS ROLES AGE VERSION LABELS
lke212553-307295-339173d10000 Ready <none> 36m v1.30.3 beta.kubernetes.io/arch=amd64,beta.kubernetes.io/instance-type=g6-dedicated-4,beta.kubernetes.io/os=linux,failure-domain.beta.kubernetes.io/region=ap-south,kubernetes.io/arch=amd64,kubernetes.io/hostname=lke212553-307295-339173d10000,kubernetes.io/os=linux,lke.linode.com/pool-id=307295,node.k8s.linode.com/host-uuid=618158120a299c6fd37f00d01d355ca18794c467,node.kubernetes.io/instance-type=g6-dedicated-4,topology.kubernetes.io/region=ap-south,topology.linode.com/region=ap-south
lke212553-307295-5541798e0000 Ready <none> 36m v1.30.3 beta.kubernetes.io/arch=amd64,beta.kubernetes.io/instance-type=g6-dedicated-4,beta.kubernetes.io/os=linux,failure-domain.beta.kubernetes.io/region=ap-south,kubernetes.io/arch=amd64,kubernetes.io/hostname=lke212553-307295-5541798e0000,kubernetes.io/os=linux,lke.linode.com/pool-id=307295,node.k8s.linode.com/host-uuid=75cfe3dbbb0380f1727efc53f5192897485e95d5,node.kubernetes.io/instance-type=g6-dedicated-4,topology.kubernetes.io/region=ap-south,topology.linode.com/region=ap-south
lke212553-307295-5b53c5520000 Ready <none> 36m v1.30.3 beta.kubernetes.io/arch=amd64,beta.kubernetes.io/instance-type=g6-dedicated-4,beta.kubernetes.io/os=linux,failure-domain.beta.kubernetes.io/region=ap-south,kubernetes.io/arch=amd64,kubernetes.io/hostname=lke212553-307295-5b53c5520000,kubernetes.io/os=linux,lke.linode.com/pool-id=307295,node.k8s.linode.com/host-uuid=792bac078d7ce0e548163b9423416d7d8c88b08f,node.kubernetes.io/instance-type=g6-dedicated-4,topology.kubernetes.io/region=ap-south,topology.linode.com/region=ap-south
As you see, we have three nodes in the cluster: lke212553-307295-339173d10000, lke212553-307295-5541798e0000, and lke212553-307295-5b53c5520000.
Next, select a node to which you want to add a label. For example, let’s say we want to add a new label with the key disktype
and value ssd to the lke212553-307295-5541798e0000
node, which is a node with the SSD storage. To do so, run:
$ kubectl label nodes lke212553-307295-5541798e0000 disktype=ssd
node/lke212553-307295-5541798e0000 labeled
As you noticed, the command above follows the format kubectl label nodes <node-name> <label-key>=<label-value>
.
Finally, let’s verify that the new label was added by running:
$ kubectl get nodes --show-labels
NAME STATUS ROLES AGE VERSION LABELS
lke212553-307295-339173d10000 Ready <none> 41m v1.30.3 beta.kubernetes.io/arch=amd64,beta.kubernetes.io/instance-type=g6-dedicated-4,beta.kubernetes.io/os=linux,failure-domain.beta.kubernetes.io/region=ap-south,kubernetes.io/arch=amd64,kubernetes.io/hostname=lke212553-307295-339173d10000,kubernetes.io/os=linux,lke.linode.com/pool-id=307295,node.k8s.linode.com/host-uuid=618158120a299c6fd37f00d01d355ca18794c467,node.kubernetes.io/instance-type=g6-dedicated-4,topology.kubernetes.io/region=ap-south,topology.linode.com/region=ap-south
lke212553-307295-5541798e0000 Ready <none> 41m v1.30.3 beta.kubernetes.io/arch=amd64,beta.kubernetes.io/instance-type=g6-dedicated-4,beta.kubernetes.io/os=linux,disktype=ssd,failure-domain.beta.kubernetes.io/region=ap-south,kubernetes.io/arch=amd64,kubernetes.io/hostname=lke212553-307295-5541798e0000,kubernetes.io/os=linux,lke.linode.com/pool-id=307295,node.k8s.linode.com/host-uuid=75cfe3dbbb0380f1727efc53f5192897485e95d5,node.kubernetes.io/instance-type=g6-dedicated-4,topology.kubernetes.io/region=ap-south,topology.linode.com/region=ap-south
lke212553-307295-5b53c5520000 Ready <none> 41m v1.30.3 beta.kubernetes.io/arch=amd64,beta.kubernetes.io/instance-type=g6-dedicated-4,beta.kubernetes.io/os=linux,failure-domain.beta.kubernetes.io/region=ap-south,kubernetes.io/arch=amd64,kubernetes.io/hostname=lke212553-307295-5b53c5520000,kubernetes.io/os=linux,lke.linode.com/pool-id=307295,node.k8s.linode.com/host-uuid=792bac078d7ce0e548163b9423416d7d8c88b08f,node.kubernetes.io/instance-type=g6-dedicated-4,topology.kubernetes.io/region=ap-south,topology.linode.com/region=ap-south
As you see, the lke212553-307295-5541798e0000 now has a new label disktype=ssd. To see all labels attached to the node, you can also run:
$ kubectl describe node "lke212553-307295-5541798e0000"
Name: lke212553-307295-5541798e0000
Roles: <none>
Labels: beta.kubernetes.io/arch=amd64
beta.kubernetes.io/instance-type=g6-dedicated-4
beta.kubernetes.io/os=linux
disktype=ssd
failure-domain.beta.kubernetes.io/region=ap-south
kubernetes.io/arch=amd64
kubernetes.io/hostname=lke212553-307295-5541798e0000
kubernetes.io/os=linux
lke.linode.com/pool-id=307295
node.k8s.linode.com/host-uuid=75cfe3dbbb0380f1727efc53f5192897485e95d5
node.kubernetes.io/instance-type=g6-dedicated-4
topology.kubernetes.io/region=ap-south
topology.linode.com/region=ap-south
Along with the disktype=ssd
label we’ve just added, you can see other labels such as beta.kubernetes.io/arch
or kubernetes.io/hostname
. These are all default labels attached to Kubernetes nodes.
Now let’s create a RabbitMQ with this new label as nodeSelector. Below is the yaml we are going to apply:
apiVersion: kubedb.com/v1alpha2
kind: RabbitMQ
metadata:
name: rabbitmq-node-selector
namespace: demo
spec:
version: "3.13.2"
replicas: 1
podTemplate:
spec:
nodeSelector:
disktype: ssd
storage:
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 1Gi
storageClassName: standard
storageType: Durable
deletionPolicy: WipeOut
$ kubectl create -f https://github.com/kubedb/docs/raw/v2024.8.21/docs/examples/rabbitmq/configuration/rabbitmq-node-selector.yaml
rabbitmq.kubedb.com/rabbitmq-node-selector created
Now, wait a few minutes. KubeDB operator will create necessary petset, services, secret etc. If everything goes well, we will see that a pod with the name rabbitmq-node-selector-0
has been created.
Check that the petset’s pod is running
$ kubectl get pods -n demo
NAME READY STATUS RESTARTS AGE
rabbitmq-node-selector-0 1/1 Running 0 60s
As we see the pod is running, you can verify that by running kubectl get pods -n demo rabbitmq-node-selector-0 -o wide
and looking at the “NODE” to which the Pod was assigned.
$ kubectl get pods -n demo rabbitmq-node-selector-0 -o wide
NAME READY STATUS RESTARTS AGE IP NODE NOMINATED NODE READINESS GATES
rabbitmq-node-selector-0 1/1 Running 0 3m19s 10.2.1.7 lke212553-307295-5541798e0000 <none> <none>
We can successfully verify that our pod was scheduled to our desired node.
Using Taints and Tolerations
Here in this example we will use Taints and Tolerations to schedule our rabbitmq pod to a specific node and also prevent from scheduling to nodes. Applying taints and tolerations to the Pod involves several steps. Let’s find what nodes exist in your cluster. To get the name of these nodes, you can run:
$ kubectl get nodes --show-labels
NAME STATUS ROLES AGE VERSION LABELS
lke212553-307295-339173d10000 Ready <none> 36m v1.30.3 beta.kubernetes.io/arch=amd64,beta.kubernetes.io/instance-type=g6-dedicated-4,beta.kubernetes.io/os=linux,failure-domain.beta.kubernetes.io/region=ap-south,kubernetes.io/arch=amd64,kubernetes.io/hostname=lke212553-307295-339173d10000,kubernetes.io/os=linux,lke.linode.com/pool-id=307295,node.k8s.linode.com/host-uuid=618158120a299c6fd37f00d01d355ca18794c467,node.kubernetes.io/instance-type=g6-dedicated-4,topology.kubernetes.io/region=ap-south,topology.linode.com/region=ap-south
lke212553-307295-5541798e0000 Ready <none> 36m v1.30.3 beta.kubernetes.io/arch=amd64,beta.kubernetes.io/instance-type=g6-dedicated-4,beta.kubernetes.io/os=linux,failure-domain.beta.kubernetes.io/region=ap-south,kubernetes.io/arch=amd64,kubernetes.io/hostname=lke212553-307295-5541798e0000,kubernetes.io/os=linux,lke.linode.com/pool-id=307295,node.k8s.linode.com/host-uuid=75cfe3dbbb0380f1727efc53f5192897485e95d5,node.kubernetes.io/instance-type=g6-dedicated-4,topology.kubernetes.io/region=ap-south,topology.linode.com/region=ap-south
lke212553-307295-5b53c5520000 Ready <none> 36m v1.30.3 beta.kubernetes.io/arch=amd64,beta.kubernetes.io/instance-type=g6-dedicated-4,beta.kubernetes.io/os=linux,failure-domain.beta.kubernetes.io/region=ap-south,kubernetes.io/arch=amd64,kubernetes.io/hostname=lke212553-307295-5b53c5520000,kubernetes.io/os=linux,lke.linode.com/pool-id=307295,node.k8s.linode.com/host-uuid=792bac078d7ce0e548163b9423416d7d8c88b08f,node.kubernetes.io/instance-type=g6-dedicated-4,topology.kubernetes.io/region=ap-south,topology.linode.com/region=ap-south
As you see, we have three nodes in the cluster: lke212553-307295-339173d10000, lke212553-307295-5541798e0000, and lke212553-307295-5b53c5520000.
Next, we are going to taint these nodes.
$ kubectl taint nodes lke212553-307295-339173d10000 key1=node1:NoSchedule
node/lke212553-307295-339173d10000 tainted
$ kubectl taint nodes lke212553-307295-5541798e0000 key1=node2:NoSchedule
node/lke212553-307295-5541798e0000 tainted
$ kubectl taint nodes lke212553-307295-5b53c5520000 key1=node3:NoSchedule
node/lke212553-307295-5b53c5520000 tainted
Let’s see our tainted nodes here,
$ kubectl get nodes -o json | jq -r '.items[] | select(.spec.taints != null) | .metadata.name, .spec.taints'
lke212553-307295-339173d10000
[
{
"effect": "NoSchedule",
"key": "key1",
"value": "node1"
}
]
lke212553-307295-5541798e0000
[
{
"effect": "NoSchedule",
"key": "key1",
"value": "node2"
}
]
lke212553-307295-5b53c5520000
[
{
"effect": "NoSchedule",
"key": "key1",
"value": "node3"
}
]
We can see that our taints were successfully assigned. Now let’s try to create a rabbitmq without proper tolerations. Here is the yaml of rabbitmq we are going to create -
apiVersion: kubedb.com/v1alpha2
kind: RabbitMQ
metadata:
name: rabbitmq-without-tolerations
namespace: demo
spec:
version: "3.13.2"
replicas: 1
storage:
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 1Gi
storageClassName: standard
storageType: Durable
deletionPolicy: WipeOut
$ kubectl create -f https://github.com/kubedb/docs/raw/v2024.8.21/docs/examples/rabbitmq/configuration/rabbitmq-without-tolerations.yaml
rabbitmq.kubedb.com/rabbitmq-without-tolerations created
Now, wait a few minutes. KubeDB operator will create necessary petset, services, secret etc. If everything goes well, we will see that a pod with the name rabbitmq-without-tolerations-0
has been created and running.
Check that the petset’s pod is running or not,
$ kubectl get pods -n demo
NAME READY STATUS RESTARTS AGE
rabbitmq-without-tolerations-0 0/1 Pending 0 3m35s
Here we can see that the pod is not running. So let’s describe the pod,
$ kubectl describe pods -n demo rabbitmq-without-tolerations-0
Name: rabbitmq-without-tolerations-0
Namespace: demo
Priority: 0
Service Account: default
Node: <none>
Labels: app.kubernetes.io/component=rabbitmq
app.kubernetes.io/instance=rabbitmq-without-tolerations
app.kubernetes.io/managed-by=kubedb.com
app.kubernetes.io/name=rabbitmqs.kubedb.com
apps.kubernetes.io/pod-index=0
controller-revision-hash=rabbitmq-without-tolerations-5b85f9cd
statefulset.kubernetes.io/pod-name=rabbitmq-without-tolerations-0
Annotations: <none>
Status: Pending
IP:
IPs: <none>
Controlled By: PetSet/rabbitmq-without-tolerations
Containers:
rabbitmq:
Image: ghcr.io/appscode-images/rabbitmq:3.13.2@sha256:7f2537e3dc69dae2cebea3500502e6a2b764b42911881e623195eeed32569217
Ports: 9999/TCP, 9595/TCP
Host Ports: 0/TCP, 0/TCP
SeccompProfile: RuntimeDefault
Limits:
memory: 1Gi
Requests:
cpu: 500m
memory: 1Gi
Mounts:
/config from rabbitmq-config (rw)
/var/run/secrets/kubernetes.io/serviceaccount from kube-api-access-69qx2 (ro)
Conditions:
Type Status
PodScheduled False
Volumes:
rabbitmq-config:
Type: Secret (a volume populated by a Secret)
SecretName: rabbitmq-without-tolerations-config
Optional: false
kube-api-access-69qx2:
Type: Projected (a volume that contains injected data from multiple sources)
TokenExpirationSeconds: 3607
ConfigMapName: kube-root-ca.crt
ConfigMapOptional: <nil>
DownwardAPI: true
QoS Class: Burstable
Node-Selectors: <none>
Tolerations: node.kubernetes.io/not-ready:NoExecute op=Exists for 300s
node.kubernetes.io/unreachable:NoExecute op=Exists for 300s
Topology Spread Constraints: kubernetes.io/hostname:ScheduleAnyway when max skew 1 is exceeded for selector app.kubernetes.io/component=connection-pooler,app.kubernetes.io/instance=rabbitmq-without-tolerations,app.kubernetes.io/managed-by=kubedb.com,app.kubernetes.io/name=rabbitmqs.kubedb.com
topology.kubernetes.io/zone:ScheduleAnyway when max skew 1 is exceeded for selector app.kubernetes.io/component=connection-pooler,app.kubernetes.io/instance=rabbitmq-without-tolerations,app.kubernetes.io/managed-by=kubedb.com,app.kubernetes.io/name=rabbitmqs.kubedb.com
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
Warning FailedScheduling 5m20s default-scheduler 0/3 nodes are available: 1 node(s) had untolerated taint {key1: node1}, 1 node(s) had untolerated taint {key1: node2}, 1 node(s) had untolerated taint {key1: node3}. preemption: 0/3 nodes are available: 3 Preemption is not helpful for scheduling.
Warning FailedScheduling 11s default-scheduler 0/3 nodes are available: 1 node(s) had untolerated taint {key1: node1}, 1 node(s) had untolerated taint {key1: node2}, 1 node(s) had untolerated taint {key1: node3}. preemption: 0/3 nodes are available: 3 Preemption is not helpful for scheduling.
Normal NotTriggerScaleUp 13s (x31 over 5m15s) cluster-autoscaler pod didn't trigger scale-up:
Here we can see that the pod has no tolerations for the tainted nodes and because of that the pod is not able to scheduled.
So, let’s add proper tolerations and create another rabbitmq. Here is the yaml we are going to apply,
apiVersion: kubedb.com/v1alpha2
kind: RabbitMQ
metadata:
name: rabbitmq-with-tolerations
namespace: demo
spec:
version: "3.13.2"
replicas: 1
storage:
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 1Gi
storageClassName: standard
podTemplate:
spec:
tolerations:
- key: "key1"
operator: "Equal"
value: "node1"
effect: "NoSchedule"
deletionPolicy: WipeOut
$ kubectl create -f https://github.com/kubedb/docs/raw/v2024.8.21/docs/examples/rabbitmq/configuration/rabbitmq-with-tolerations.yaml
rabbitmq.kubedb.com/rabbitmq-with-tolerations created
Now, wait a few minutes. KubeDB operator will create necessary petset, services, secret etc. If everything goes well, we will see that a pod with the name rabbitmq-with-tolerations-0
has been created.
Check that the petset’s pod is running
$ kubectl get pods -n demo
NAME READY STATUS RESTARTS AGE
rabbitmq-with-tolerations-0 1/1 Running 0 2m
As we see the pod is running, you can verify that by running kubectl get pods -n demo rabbitmq-with-tolerations-0 -o wide
and looking at the “NODE” to which the Pod was assigned.
$ kubectl get pods -n demo rabbitmq-with-tolerations-0 -o wide
NAME READY STATUS RESTARTS AGE IP NODE NOMINATED NODE READINESS GATES
rabbitmq-with-tolerations-0 1/1 Running 0 3m49s 10.2.0.8 lke212553-307295-339173d10000 <none> <none>
We can successfully verify that our pod was scheduled to the node which it has tolerations.
Cleaning up
To clean up the Kubernetes resources created by this tutorial, run:
kubectl delete -n demo rm rm-misc-config rabbitmq-custom-sidecar rabbitmq-node-selector rabbitmq-with-tolerations rabbitmq-without-tolerations
kubectl delete ns demo
If you would like to uninstall KubeDB operator, please follow the steps here.
Next Steps
- Quickstart rabbitmq with KubeDB Operator.
- Monitor your rabbitmq database with KubeDB using out-of-the-box Prometheus operator.
- Monitor your rabbitmq database with KubeDB using out-of-the-box builtin-Prometheus.
- Detail concepts of rabbitmq object.
- Want to hack on KubeDB? Check our contribution guidelines.