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Configuration
- 1: Example: Configuring a Java Microservice
- 1.1: Externalizing config using MicroProfile, ConfigMaps and Secrets
- 1.2: Interactive Tutorial - Configuring a Java Microservice
- 2: Configuring Redis using a ConfigMap
1 - Example: Configuring a Java Microservice
1.1 - Externalizing config using MicroProfile, ConfigMaps and Secrets
In this tutorial you will learn how and why to externalize your microservice’s configuration. Specifically, you will learn how to use Kubernetes ConfigMaps and Secrets to set environment variables and then consume them using MicroProfile Config.
Before you begin
Creating Kubernetes ConfigMaps & Secrets
There are several ways to set environment variables for a Docker container in Kubernetes, including: Dockerfile, kubernetes.yml, Kubernetes ConfigMaps, and Kubernetes Secrets. In the tutorial, you will learn how to use the latter two for setting your environment variables whose values will be injected into your microservices. One of the benefits for using ConfigMaps and Secrets is that they can be re-used across multiple containers, including being assigned to different environment variables for the different containers.
ConfigMaps are API Objects that store non-confidential key-value pairs. In the Interactive Tutorial you will learn how to use a ConfigMap to store the application's name. For more information regarding ConfigMaps, you can find the documentation here.
Although Secrets are also used to store key-value pairs, they differ from ConfigMaps in that they're intended for confidential/sensitive information and are stored using Base64 encoding. This makes secrets the appropriate choice for storing such things as credentials, keys, and tokens, the former of which you'll do in the Interactive Tutorial. For more information on Secrets, you can find the documentation here.
Externalizing Config from Code
Externalized application configuration is useful because configuration usually changes depending on your environment. In order to accomplish this, we'll use Java's Contexts and Dependency Injection (CDI) and MicroProfile Config. MicroProfile Config is a feature of MicroProfile, a set of open Java technologies for developing and deploying cloud-native microservices.
CDI provides a standard dependency injection capability enabling an application to be assembled from collaborating, loosely-coupled beans. MicroProfile Config provides apps and microservices a standard way to obtain config properties from various sources, including the application, runtime, and environment. Based on the source's defined priority, the properties are automatically combined into a single set of properties that the application can access via an API. Together, CDI & MicroProfile will be used in the Interactive Tutorial to retrieve the externally provided properties from the Kubernetes ConfigMaps and Secrets and get injected into your application code.
Many open source frameworks and runtimes implement and support MicroProfile Config. Throughout the interactive tutorial, you'll be using Open Liberty, a flexible open-source Java runtime for building and running cloud-native apps and microservices. However, any MicroProfile compatible runtime could be used instead.
Objectives
- Create a Kubernetes ConfigMap and Secret
- Inject microservice configuration using MicroProfile Config
Example: Externalizing config using MicroProfile, ConfigMaps and Secrets
Start Interactive Tutorial
1.2 - Interactive Tutorial - Configuring a Java Microservice
2 - Configuring Redis using a ConfigMap
This page provides a real world example of how to configure Redis using a ConfigMap and builds upon the Configure Containers Using a ConfigMap task.
Objectives
- Create a ConfigMap with Redis configuration values
- Create a Redis Pod that mounts and uses the created ConfigMap
- Verify that the configuration was correctly applied.
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:
To check the version, enterkubectl version
.
- The example shown on this page works with
kubectl
1.14 and above. - Understand Configure Containers Using a ConfigMap.
Real World Example: Configuring Redis using a ConfigMap
Follow the steps below to configure a Redis cache using data stored in a ConfigMap.
First create a ConfigMap with an empty configuration block:
cat <<EOF >./example-redis-config.yaml
apiVersion: v1
kind: ConfigMap
metadata:
name: example-redis-config
data:
redis-config: ""
EOF
Apply the ConfigMap created above, along with a Redis pod manifest:
kubectl apply -f example-redis-config.yaml
kubectl apply -f https://raw.githubusercontent.com/kubernetes/website/main/content/en/examples/pods/config/redis-pod.yaml
Examine the contents of the Redis pod manifest and note the following:
- A volume named
config
is created byspec.volumes[1]
- The
key
andpath
underspec.volumes[1].items[0]
exposes theredis-config
key from theexample-redis-config
ConfigMap as a file namedredis.conf
on theconfig
volume. - The
config
volume is then mounted at/redis-master
byspec.containers[0].volumeMounts[1]
.
This has the net effect of exposing the data in data.redis-config
from the example-redis-config
ConfigMap above as /redis-master/redis.conf
inside the Pod.
apiVersion: v1
kind: Pod
metadata:
name: redis
spec:
containers:
- name: redis
image: redis:5.0.4
command:
- redis-server
- "/redis-master/redis.conf"
env:
- name: MASTER
value: "true"
ports:
- containerPort: 6379
resources:
limits:
cpu: "0.1"
volumeMounts:
- mountPath: /redis-master-data
name: data
- mountPath: /redis-master
name: config
volumes:
- name: data
emptyDir: {}
- name: config
configMap:
name: example-redis-config
items:
- key: redis-config
path: redis.conf
Examine the created objects:
kubectl get pod/redis configmap/example-redis-config
You should see the following output:
NAME READY STATUS RESTARTS AGE
pod/redis 1/1 Running 0 8s
NAME DATA AGE
configmap/example-redis-config 1 14s
Recall that we left redis-config
key in the example-redis-config
ConfigMap blank:
kubectl describe configmap/example-redis-config
You should see an empty redis-config
key:
Name: example-redis-config
Namespace: default
Labels: <none>
Annotations: <none>
Data
====
redis-config:
Use kubectl exec
to enter the pod and run the redis-cli
tool to check the current configuration:
kubectl exec -it redis -- redis-cli
Check maxmemory
:
127.0.0.1:6379> CONFIG GET maxmemory
It should show the default value of 0:
1) "maxmemory"
2) "0"
Similarly, check maxmemory-policy
:
127.0.0.1:6379> CONFIG GET maxmemory-policy
Which should also yield its default value of noeviction
:
1) "maxmemory-policy"
2) "noeviction"
Now let's add some configuration values to the example-redis-config
ConfigMap:
apiVersion: v1
kind: ConfigMap
metadata:
name: example-redis-config
data:
redis-config: |
maxmemory 2mb
maxmemory-policy allkeys-lru
Apply the updated ConfigMap:
kubectl apply -f example-redis-config.yaml
Confirm that the ConfigMap was updated:
kubectl describe configmap/example-redis-config
You should see the configuration values we just added:
Name: example-redis-config
Namespace: default
Labels: <none>
Annotations: <none>
Data
====
redis-config:
----
maxmemory 2mb
maxmemory-policy allkeys-lru
Check the Redis Pod again using redis-cli
via kubectl exec
to see if the configuration was applied:
kubectl exec -it redis -- redis-cli
Check maxmemory
:
127.0.0.1:6379> CONFIG GET maxmemory
It remains at the default value of 0:
1) "maxmemory"
2) "0"
Similarly, maxmemory-policy
remains at the noeviction
default setting:
127.0.0.1:6379> CONFIG GET maxmemory-policy
Returns:
1) "maxmemory-policy"
2) "noeviction"
The configuration values have not changed because the Pod needs to be restarted to grab updated values from associated ConfigMaps. Let's delete and recreate the Pod:
kubectl delete pod redis
kubectl apply -f https://raw.githubusercontent.com/kubernetes/website/main/content/en/examples/pods/config/redis-pod.yaml
Now re-check the configuration values one last time:
kubectl exec -it redis -- redis-cli
Check maxmemory
:
127.0.0.1:6379> CONFIG GET maxmemory
It should now return the updated value of 2097152:
1) "maxmemory"
2) "2097152"
Similarly, maxmemory-policy
has also been updated:
127.0.0.1:6379> CONFIG GET maxmemory-policy
It now reflects the desired value of allkeys-lru
:
1) "maxmemory-policy"
2) "allkeys-lru"
Clean up your work by deleting the created resources:
kubectl delete pod/redis configmap/example-redis-config
What's next
- Learn more about ConfigMaps.