This tutorial will get you up and running with Dapr in a Kubernetes cluster. You will 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 quickstart:
This quickstart requires you to have the following installed on your machine:
Also, unless you have already done so, clone the repository with the quickstarts and cd into the right directory:
git clone [-b <dapr_version_tag>] https://github.com/dapr/quickstarts.git
cd quickstarts/tutorials/hello-kubernetes
Note: See https://github.com/dapr/quickstarts#supported-dapr-runtime-version for supported tags. Use
git clone https://github.com/dapr/quickstarts.gitwhen using the edge version of dapr runtime.
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 cluster in Azure using AKS.
Follow the steps below to deploy Dapr to Kubernetes using the --dev flag. For more details, see Deploy Dapr on a Kubernetes cluster.
Note: Any previous Dapr installations in the Kubernetes cluster need to be uninstalled first. You can use
dapr uninstall -kto remove Dapr
With the dapr init -k --dev command, the CLI will also install he Redis and Zipkin containers dapr-dev-redis and dapr-dev-zipkin in the default namespace apart from the Dapr control plane in dapr-system namespace. The statestore, pubsub and appconfig default components and configuration are applied in the default Kubernetes namespace if they do not exist. You can use dapr components -k and dapr configurations -kto see these.
dapr init -k --devExpected output in a fresh Kubernetes cluster without Dapr installed:
⌛ Making the jump to hyperspace...
ℹ️ Note: To install Dapr using Helm, see here: https://docs.dapr.io/getting-started/install-dapr-kubernetes/#install-with-helm-advanced
ℹ️ Container images will be pulled from Docker Hub
✅ Deploying the Dapr control plane with latest version to your cluster...
✅ Deploying the Dapr dashboard with latest version to your cluster...
✅ Deploying the Dapr Redis with 17.14.5 version to your cluster...
✅ Deploying the Dapr Zipkin with latest version to your cluster...
ℹ️ Applying "statestore" component to Kubernetes "default" namespace.
ℹ️ Applying "pubsub" component to Kubernetes "default" namespace.
ℹ️ Applying "appconfig" zipkin configuration to Kubernetes "default" namespace.
✅ Success! Dapr has been installed to namespace dapr-system. To verify, run `dapr status -k' in your terminal. To get started, go here: https://aka.ms/dapr-getting-started
dapr status -kYou will see output like the following. All services should show True in the HEALTHY column and Running in the STATUS column before you continue.
NAME NAMESPACE HEALTHY STATUS REPLICAS VERSION AGE CREATED
dapr-dashboard dapr-system True Running 1 0.14.0 41s 2024-07-22 13:53.05
dapr-operator dapr-system True Running 1 1.13.5 42s 2024-07-22 13:53.04
dapr-placement-server dapr-system True Running 1 1.13.5 42s 2024-07-22 13:53.04
dapr-sentry dapr-system True Running 1 1.13.5 42s 2024-07-22 13:53.04
dapr-sidecar-injector dapr-system True Running 1 1.13.5 42s 2024-07-22 13:53.04
Apply the redis.yaml file and observe that your state store was successfully configured!
kubectl apply -f ./deploy/redis.yamlkubectl apply -f ./deploy/node.yamlKubernetes deployments are asyncronous. This means you'll need to wait for the deployment to complete before moving on to the next steps. You can do so with the following command:
kubectl rollout status deploy/nodeappThis will deploy the Node.js app to Kubernetes. The Dapr control plane will automatically inject the Dapr sidecar to the 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/app-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.
dapr.io/enable-api-logging: "true" - this is added to node.yaml file by default to see the API logs.
You'll also see the container image that you're deploying. If you want to update the code and deploy a new image, see Next Steps section.
There are several different ways to access a Kubernetes service depending on which platform you are using. Port forwarding is one consistent way to access a service, whether it is hosted locally or on a cloud Kubernetes provider like AKS.
kubectl port-forward service/nodeapp 8080:80This will make your service available on http://localhost:8080.
Optional: If you are using a public cloud provider, you can substitue your EXTERNAL-IP address instead of port forwarding. You can find it with:
kubectl get svc nodeappTo call the service that you set up port forwarding to, from a command prompt run:
curl http://localhost:8080/portsExpected output:
{"DAPR_HTTP_PORT":"3500","DAPR_GRPC_PORT":"50001"}
Next submit an order to the app
curl --request POST --data "@sample.json" --header Content-Type:application/json http://localhost:8080/neworderExpected output: Empty reply from server
Confirm the order was persisted by requesting it from the app
curl http://localhost:8080/orderExpected output:
{ "orderId": "42" }Optional: Now it would be a good time to get acquainted with the Dapr dashboard. Which is a convenient interface to check status, information and logs of applications running on Dapr. The following command will make it available on http://localhost:9999/.
dapr dashboard -k -p 9999Next, take a quick look at the Python app. Navigate to the Python app in the kubernetes quickstart: cd quickstarts/tutorials/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. You can invoke the Node.js application's neworder endpoint by posting to v1.0/invoke/nodeapp/method/neworder. The 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)Deploy the Python app to your Kubernetes cluster:
kubectl apply -f ./deploy/python.yamlAs with above, the following command will wait for the deployment to complete:
kubectl rollout status deploy/pythonappNow that the Node.js and Python applications are deployed, watch messages come through:
Get the logs of the Node.js app:
kubectl logs --selector=app=node -c node --tail=-1If all went well, you should see logs like this:
Got a new order! Order ID: 1
Successfully persisted state for Order ID: 1
Got a new order! Order ID: 2
Successfully persisted state for Order ID: 2
Got a new order! Order ID: 3
Successfully persisted state for Order ID: 3
Now that the Node.js and Python applications are deployed, watch API call logs come through:
Get the API call logs of the node app:
kubectl logs --selector=app=node -c daprd --tail=-1When save state API calls are made, you should see logs similar to this:
time="2022-04-25T22:46:09.82121774Z" level=info method="POST /v1.0/state/statestore" app_id=nodeapp instance=nodeapp-7dd6648dd4-7hpmh scope=dapr.runtime.http-info type=log ver=1.7.2
time="2022-04-25T22:46:10.828764787Z" level=info method="POST /v1.0/state/statestore" app_id=nodeapp instance=nodeapp-7dd6648dd4-7hpmh scope=dapr.runtime.http-info type=log ver=1.7.2
Get the API call logs of the Python app:
kubectl logs --selector=app=python -c daprd --tail=-1time="2022-04-27T02:47:49.972688145Z" level=info method="POST /neworder" app_id=pythonapp instance=pythonapp-545df48d55-jvj52 scope=dapr.runtime.http-info type=log ver=1.7.2
time="2022-04-27T02:47:50.984994545Z" level=info method="POST /neworder" app_id=pythonapp instance=pythonapp-545df48d55-jvj52 scope=dapr.runtime.http-info type=log ver=1.7.2
Call the Node.js app's order endpoint to get the latest order. Grab the external IP address that you 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, 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.
Note: This will also delete the state store component. If the
--devflag was used for Dapr init, and you want to use thedapr-dev-redisdeployment as state store, replace theredisHostvalue inside./deploy/redis.yamlwithdapr-dev-redis-master:6379and also thesecretKeyRef,namewithdapr-dev-redis. Then run the commandkubectl apply -f ./deploy/redis.yaml, to apply the file again. This will create astatestoreDapr component pointing todapr-dev-redisdeployment.
Now that you're successfully working with Dapr, you probably want to update the code to fit your scenario. The Node.js and Python apps that make up this quickstart 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.
- Explore additional quickstarts and deploy them locally or on Kubernetes.