This tutorial will get you up and running with Dapr in a Kubernetes cluster. We'll be deploying the same applications from Hello World. To recap, the Python App generates messages and the Node app consumes and persists them. The following architecture diagram illustrates the components that make up this sample:
This sample requires you to have the following installed on your machine:
Also, unless you have already done so, clone the repository with the samples and cd
into the right directory:
git clone https://github.com/dapr/samples.git
cd samples
The first thing you need is an RBAC enabled Kubernetes cluster. This could be running on your machine using Minikube, or it could be a fully-fledged cluser in Azure using AKS.
Once you have a cluster, follow the steps below to deploy Dapr to it. For more details, look here
Please note, that using the CLI does not support non-default namespaces.
If you need a non-default namespace, Helm has to be used (see below).
$ dapr init --kubernetes
ℹ️ Note: this installation is recommended for testing purposes. For production environments, please use Helm
⌛ Making the jump to hyperspace...
✅ Deploying the Dapr Operator to your cluster...
✅ Success! Dapr has been installed. To verify, run 'kubectl get pods -w' in your terminal
Dapr can use a number of different state stores (Redis, CosmosDB, DynamoDB, Cassandra, etc) to persist and retrieve state. For this demo, we'll use Redis.
- Follow these steps to create a Redis store.
- Once your store is created, add the keys to the
redis.yaml
file in thedeploy
directory.Note: the
redis.yaml
file provided in this sample takes plain text secrets. In a production-grade application, follow secret management instructions to securely manage your secrets. - Apply the
redis.yaml
file:kubectl apply -f ./deploy/redis.yaml
and observe that your state store was successfully configured!
component.dapr.io "statestore" configured
kubectl apply -f ./deploy/node.yaml
This will deploy our Node.js app to Kubernetes. The Dapr control plane will automatically inject the Dapr sidecar to our Pod. If you take a look at the node.yaml
file, you will see how Dapr is enabled for that deployment:
dapr.io/enabled: true
- this tells the Dapr control plane to inject a sidecar to this deployment.
dapr.io/id: nodeapp
- this assigns a unique id or name to the Dapr application, so it can be sent messages to and communicated with by other Dapr apps.
You'll also see the container image that we're deploying. If you want to update the code and deploy a new image, see Next Steps section.
This deployment provisions an External IP. Wait until the IP is visible: (may take a few minutes)
kubectl get svc nodeapp
Note: Minikube users cannot see the external IP. Instead, you can use
minikube service [service_name]
to access loadbalancer without external IP.
Once you have an external IP, save it. You can also export it to a variable:
export NODE_APP=$(kubectl get svc nodeapp --output 'jsonpath={.status.loadBalancer.ingress[0].ip}')
Next, let's take a quick look at our python app. Navigate to the python app in the kubernetes sample: cd samples/2.hello-kubernetes/python
and open app.py
.
At a quick glance, this is a basic python app that posts JSON messages to localhost:3500
, which is the default listening port for Dapr. We invoke our Node.js application's neworder
endpoint by posting to v1.0/invoke/nodeapp/method/neworder
. Our message contains some data
with an orderId that increments once per second:
n = 0
while True:
n += 1
message = {"data": {"orderId": n}}
try:
response = requests.post(dapr_url, json=message)
except Exception as e:
print(e)
time.sleep(1)
Let's deploy the python app to your Kubernetes cluster:
kubectl apply -f ./deploy/python.yaml
Now let's just wait for the pod to be in Running
state:
kubectl get pods --selector=app=python -w
Now that we have our Node.js and python applications deployed, let's watch messages come through.
Get the logs of our Node.js app:
kubectl logs --selector=app=node -c node
If all went well, you should see logs like this:
Got a new order! Order ID: 1
Successfully persisted state
Got a new order! Order ID: 2
Successfully persisted state
Got a new order! Order ID: 3
Successfully persisted state
Hit the Node.js app's order endpoint to get the latest order. Grab the external IP address that we saved before and, append "/order" and perform a GET request against it (enter it into your browser, use Postman, or curl it!):
curl $NODE_APP/order
{"orderID":"42"}
You should see the latest JSON in response!
Once you're done using the sample, you can spin down your Kubernetes resources by navigating to the ./deploy
directory and running:
kubectl delete -f .
This will spin down each resource defined by the .yaml files in the deploy
directory, including the state component.
Now that you're successfully working with Dapr, you probably want to update the sample code to fit your scenario. The Node.js and Python apps that make up this sample are deployed from container images hosted on a private Azure Container Registry. To create new images with updated code, you'll first need to install docker on your machine. Next, follow these steps:
- Update Node or Python code as you see fit!
- Navigate to the directory of the app you want to build a new image for.
- Run
docker build -t <YOUR_IMAGE_NAME> .
. You can name your image whatever you like. If you're planning on hosting it on docker hub, then it should start with<YOUR_DOCKERHUB_USERNAME>/
. - Once your image has built you can see it on your machines by running
docker images
. - To publish your docker image to docker hub (or another registry), first login:
docker login
. Then rundocker push <YOUR IMAGE NAME>
. - Update your .yaml file to reflect the new image name.
- Deploy your updated Dapr enabled app:
kubectl apply -f <YOUR APP NAME>.yaml
.