Signed-off-by: Mrunal Patel <mrunalp@gmail.com>
6.7 KiB
Meteor on Kubernetes
This example shows you how to package and run a Meteor app on Kubernetes.
Get started on Google Compute Engine
Meteor uses MongoDB, and we will use the GCEPersistentDisk
type of
volume for persistent storage. Therefore, this example is only
applicable to Google Compute
Engine. Take a look at the
volumes documentation for other options.
First, if you have not already done so:
- Create a Google Cloud Platform project.
- Enable billing.
- Install the gcloud SDK.
Authenticate with gcloud and set the gcloud default project name to point to the project you want to use for your Kubernetes cluster:
gcloud auth login
gcloud config set project <project-name>
Next, start up a Kubernetes cluster:
wget -q -O - https://get.k8s.io | bash
Please see the Google Compute Engine getting started guide for full details and other options for starting a cluster.
Build a container for your Meteor app
To be able to run your Meteor app on Kubernetes you need to build a
Docker container for it first. To do that you need to install
Docker Once you have that you need to add 2
files to your existing Meteor project Dockerfile
and
.dockerignore
.
Dockerfile
should contain the below lines. You should replace the
ROOT_URL
with the actual hostname of your app.
FROM chees/meteor-kubernetes
ENV ROOT_URL http://myawesomeapp.com
The .dockerignore
file should contain the below lines. This tells
Docker to ignore the files on those directories when it's building
your container.
.meteor/local
packages/*/.build*
You can see an example meteor project already set up at: meteor-gke-example. Feel free to use this app for this example.
Note: The next step will not work if you have added mobile platforms to your meteor project. Check with
meteor list-platforms
Now you can build your container by running this in your Meteor project directory:
docker build -t my-meteor .
Pushing to a registry
For the Docker Hub, tag your app image with
your username and push to the Hub with the below commands. Replace
<username>
with your Hub username.
docker tag my-meteor <username>/my-meteor
docker push <username>/my-meteor
For Google Container
Registry, tag
your app image with your project ID, and push to GCR. Replace
<project>
with your project ID.
docker tag my-meteor gcr.io/<project>/my-meteor
gcloud docker -- push gcr.io/<project>/my-meteor
Running
Now that you have containerized your Meteor app it's time to set up
your cluster. Edit meteor-controller.json
and make sure the image:
points to the container you just pushed to
the Docker Hub or GCR.
We will need to provide MongoDB a persistent Kubernetes volume to store its data. See the volumes documentation for options. We're going to use Google Compute Engine persistent disks. Create the MongoDB disk by running:
gcloud compute disks create --size=200GB mongo-disk
Now you can start Mongo using that disk:
kubectl create -f examples/meteor/mongo-pod.json
kubectl create -f examples/meteor/mongo-service.json
Wait until Mongo is started completely and then start up your Meteor app:
kubectl create -f examples/meteor/meteor-service.json
kubectl create -f examples/meteor/meteor-controller.json
Note that meteor-service.json
creates a load balancer, so
your app should be available through the IP of that load balancer once
the Meteor pods are started. We also created the service before creating the rc to
aid the scheduler in placing pods, as the scheduler ranks pod placement according to
service anti-affinity (among other things). You can find the IP of your load balancer
by running:
kubectl get service meteor --template="{{range .status.loadBalancer.ingress}} {{.ip}} {{end}}"
You will have to open up port 80 if it's not open yet in your environment. On Google Compute Engine, you may run the below command.
gcloud compute firewall-rules create meteor-80 --allow=tcp:80 --target-tags kubernetes-node
What is going on?
Firstly, the FROM chees/meteor-kubernetes
line in your Dockerfile
specifies the base image for your Meteor app. The code for that image
is located in the dockerbase/
subdirectory. Open up the Dockerfile
to get an insight of what happens during the docker build
step. The
image is based on the Node.js official image. It then installs Meteor
and copies in your apps' code. The last line specifies what happens
when your app container is run.
ENTRYPOINT MONGO_URL=mongodb://$MONGO_SERVICE_HOST:$MONGO_SERVICE_PORT /usr/local/bin/node main.js
Here we can see the MongoDB host and port information being passed
into the Meteor app. The MONGO_SERVICE...
environment variables are
set by Kubernetes, and point to the service named mongo
specified in
mongo-service.json
. See the environment
documentation for more details.
As you may know, Meteor uses long lasting connections, and requires
sticky sessions. With Kubernetes you can scale out your app easily
with session affinity. The
meteor-service.json
file contains
"sessionAffinity": "ClientIP"
, which provides this for us. See the
service
documentation for
more information.
As mentioned above, the mongo container uses a volume which is mapped
to a persistent disk by Kubernetes. In mongo-pod.json
the container
section specifies the volume:
{
"volumeMounts": [
{
"name": "mongo-disk",
"mountPath": "/data/db"
}
The name mongo-disk
refers to the volume specified outside the
container section:
{
"volumes": [
{
"name": "mongo-disk",
"gcePersistentDisk": {
"pdName": "mongo-disk",
"fsType": "ext4"
}
}
],