AWS-CNI

This guide explains how to set up Cilium in combination with aws-cni. In this hybrid mode, the aws-cni plugin is responsible for setting up the virtual network devices as well as address allocation (IPAM) via ENI. After the initial networking is setup, the Cilium CNI plugin is called to attach eBPF programs to the network devices set up by aws-cni to enforce network policies, perform load-balancing, and encryption.

../../_images/aws-cni-architecture.png

Setup Cluster on AWS

Follow the instructions in the Installation on AWS EKS guide to set up an EKS cluster or use any other method of your preference to set up a Kubernetes cluster.

Ensure that the aws-vpc-cni-k8s plugin is installed. If you have set up an EKS cluster, this is automatically done.

Note

First, make sure you have Helm 3 installed.

If you have (or planning to have) Helm 2 charts (and Tiller) in the same cluster, there should be no issue as both version are mutually compatible in order to support gradual migration. Cilium chart is targeting Helm 3 (v3.0.3 and above).

Download the Cilium release tarball and change to the kubernetes install directory:

curl -LO https://github.com/cilium/cilium/archive/master.tar.gz
tar xzf master.tar.gz
cd cilium-master/install/kubernetes

Deploy Cilium release via Helm:

helm install cilium ./cilium \
  --namespace kube-system \
  --set cni.chainingMode=aws-cni \
  --set masquerade=false \
  --set tunnel=disabled \
  --set nodeinit.enabled=true

This will enable chaining with the aws-cni plugin. It will also disable tunneling. Tunneling is not required as ENI IP addresses can be directly routed in your VPC. You can also disable masquerading for the same reason.

Restart existing pods

The new CNI chaining configuration will not apply to any pod that is already running in the cluster. Existing pods will be reachable and Cilium will load-balance to them but policy enforcement will not apply to them and load-balancing is not performed for traffic originating from existing pods. You must restart these pods in order to invoke the chaining configuration on them.

If you are unsure if a pod is managed by Cilium or not, run kubectl get cep in the respective namespace and see if the pod is listed.

Validate the Installation

You can monitor as Cilium and all required components are being installed:

kubectl -n kube-system get pods --watch
NAME                                    READY   STATUS              RESTARTS   AGE
cilium-operator-cb4578bc5-q52qk         0/1     Pending             0          8s
cilium-s8w5m                            0/1     PodInitializing     0          7s
coredns-86c58d9df4-4g7dd                0/1     ContainerCreating   0          8m57s
coredns-86c58d9df4-4l6b2                0/1     ContainerCreating   0          8m57s

It may take a couple of minutes for all components to come up:

cilium-operator-cb4578bc5-q52qk         1/1     Running   0          4m13s
cilium-s8w5m                            1/1     Running   0          4m12s
coredns-86c58d9df4-4g7dd                1/1     Running   0          13m
coredns-86c58d9df4-4l6b2                1/1     Running   0          13m

Deploy the connectivity test

You can deploy the “connectivity-check” to test connectivity between pods. It is recommended to create a separate namespace for this.

kubectl create ns cilium-test

Deploy the check with:

kubectl apply -n cilium-test -f https://raw.githubusercontent.com/cilium/cilium/HEAD/examples/kubernetes/connectivity-check/connectivity-check.yaml

It will deploy a series of deployments which will use various connectivity paths to connect to each other. Connectivity paths include with and without service load-balancing and various network policy combinations. The pod name indicates the connectivity variant and the readiness and liveness gate indicates success or failure of the test:

$ kubectl get pods -n cilium-test
NAME                                                     READY   STATUS    RESTARTS   AGE
echo-a-76c5d9bd76-q8d99                                  1/1     Running   0          66s
echo-b-795c4b4f76-9wrrx                                  1/1     Running   0          66s
echo-b-host-6b7fc94b7c-xtsff                             1/1     Running   0          66s
host-to-b-multi-node-clusterip-85476cd779-bpg4b          1/1     Running   0          66s
host-to-b-multi-node-headless-dc6c44cb5-8jdz8            1/1     Running   0          65s
pod-to-a-79546bc469-rl2qq                                1/1     Running   0          66s
pod-to-a-allowed-cnp-58b7f7fb8f-lkq7p                    1/1     Running   0          66s
pod-to-a-denied-cnp-6967cb6f7f-7h9fn                     1/1     Running   0          66s
pod-to-b-intra-node-nodeport-9b487cf89-6ptrt             1/1     Running   0          65s
pod-to-b-multi-node-clusterip-7db5dfdcf7-jkjpw           1/1     Running   0          66s
pod-to-b-multi-node-headless-7d44b85d69-mtscc            1/1     Running   0          66s
pod-to-b-multi-node-nodeport-7ffc76db7c-rrw82            1/1     Running   0          65s
pod-to-external-1111-d56f47579-d79dz                     1/1     Running   0          66s
pod-to-external-fqdn-allow-google-cnp-78986f4bcf-btjn7   0/1     Running   0          66s

Note

If you deploy the connectivity check to a single node cluster, pods that check multi-node functionalities will remain in the Pending state. This is expected since these pods need at least 2 nodes to be scheduled successfully.

Specify Environment Variables

Specify the namespace in which Cilium is installed as CILIUM_NAMESPACE environment variable. Subsequent commands reference this environment variable.

export CILIUM_NAMESPACE=kube-system

Enable Hubble

Hubble is a fully distributed networking and security observability platform for cloud native workloads. It is built on top of Cilium and eBPF to enable deep visibility into the communication and behavior of services as well as the networking infrastructure in a completely transparent manner.

  • Hubble can be configured to be in distributed mode or local mode.

    In distributed mode, Hubble listens on a TCP port on the host network. This allows Hubble Relay to communicate with all the Hubble instances in the cluster. Hubble CLI and Hubble UI in turn connect to Hubble Relay to provide cluster-wide networking visibility.

    Note

    In Distributed mode, Hubble runs a gRPC service over HTTP on the host network. It is secured using mutual TLS (mTLS) by default to only allow access to Hubble Relay. Refer to Use custom TLS certificates in distributed mode to manually provide TLS certificates.

    helm upgrade cilium ./cilium \
       --namespace $CILIUM_NAMESPACE \
       --reuse-values \
       --set hubble.enabled=true \
       --set hubble.listenAddress=":4244" \
       --set hubble.metrics.enabled="{dns,drop,tcp,flow,port-distribution,icmp,http}" \
       --set hubble.relay.enabled=true \
       --set hubble.ui.enabled=true
    

    In local mode, Hubble listens on a UNIX domain socket. You can connect to a Hubble instance by running hubble command from inside the Cilium pod. This provides networking visibility for traffic observed by the local Cilium agent.

    helm upgrade cilium ./cilium \
       --namespace $CILIUM_NAMESPACE \
       --reuse-values \
       --set hubble.enabled=true \
       --set hubble.metrics.enabled="{dns,drop,tcp,flow,port-distribution,icmp,http}"
    
  • Restart the Cilium daemonset to allow Cilium agent to pick up the ConfigMap changes:

    kubectl rollout restart -n $CILIUM_NAMESPACE ds/cilium
    
  • To pick one Cilium instance and validate that Hubble is properly configured to listen on a UNIX domain socket:

    kubectl exec -n $CILIUM_NAMESPACE -t ds/cilium -- hubble observe
    
  • (Distributed mode only) To validate that Hubble Relay is running, install the hubble CLI:

    Download the latest hubble release:

    export HUBBLE_VERSION=$(curl -s https://raw.githubusercontent.com/cilium/hubble/master/stable.txt)
    curl -LO "https://github.com/cilium/hubble/releases/download/$HUBBLE_VERSION/hubble-linux-amd64.tar.gz"
    curl -LO "https://github.com/cilium/hubble/releases/download/$HUBBLE_VERSION/hubble-linux-amd64.tar.gz.sha256sum"
    sha256sum --check hubble-linux-amd64.tar.gz.sha256sum
    tar zxf hubble-linux-amd64.tar.gz
    

    and move the hubble CLI to a directory listed in the $PATH environment variable. For example:

    sudo mv hubble /usr/local/bin
    

    Download the latest hubble release:

    export HUBBLE_VERSION=$(curl -s https://raw.githubusercontent.com/cilium/hubble/master/stable.txt)
    curl -LO "https://github.com/cilium/hubble/releases/download/$HUBBLE_VERSION/hubble-darwin-amd64.tar.gz"
    curl -LO "https://github.com/cilium/hubble/releases/download/$HUBBLE_VERSION/hubble-darwin-amd64.tar.gz.sha256sum"
    shasum -a 256 -c hubble-darwin-amd64.tar.gz.sha256sum
    tar zxf hubble-darwin-amd64.tar.gz
    

    and move the hubble CLI to a directory listed in the $PATH environment variable. For example:

    sudo mv hubble /usr/local/bin
    

    Download the latest hubble release:

    curl -LO "https://raw.githubusercontent.com/cilium/hubble/master/stable.txt"
    set /p HUBBLE_VERSION=<stable.txt
    curl -LO "https://github.com/cilium/hubble/releases/download/%HUBBLE_VERSION%/hubble-windows-amd64.tar.gz"
    curl -LO "https://github.com/cilium/hubble/releases/download/%HUBBLE_VERSION%/hubble-windows-amd64.tar.gz.sha256sum"
    certutil -hashfile hubble-windows-amd64.tar.gz SHA256
    type hubble-windows-amd64.tar.gz.sha256sum
    :: verify that the checksum from the two commands above match
    tar zxf hubble-windows-amd64.tar.gz
    

    and move the hubble.exe CLI to a directory listed in the %PATH% environment variable after extracting it from the tarball.

    Once the hubble CLI is installed, set up a port forwarding for hubble-relay service and run hubble observe command:

    kubectl port-forward -n $CILIUM_NAMESPACE svc/hubble-relay --address 0.0.0.0 --address :: 4245:80
    hubble observe --server localhost:4245
    

    (For Linux / MacOS) For convenience, you may set and export the HUBBLE_DEFAULT_SOCKET_PATH environment variable:

    export HUBBLE_DEFAULT_SOCKET_PATH=localhost:4245
    

    This will allow you to use hubble status and hubble observe commands without having to specify the server address via the --server flag.

  • (Distributed mode only) To validate that Hubble UI is properly configured, set up a port forwarding for hubble-ui service:

    kubectl port-forward -n $CILIUM_NAMESPACE svc/hubble-ui --address 0.0.0.0 --address :: 12000:80
    

    and then open http://localhost:12000/.