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This guide demonstrates how to improve the security of your Kubernetes Engine by applying fine-grained restrictions to network communication. You will provision a simple HTTP server and two client pods in a Kubernetes Engine cluster, then use a Network Policy restrict connections from client pods.

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How to use a Network Policy in Kubernetes Engine

Table of Contents

Introduction

This guide demonstrates how to improve the security of your Kubernetes Engine by applying fine-grained restrictions to network communication.

The Principle of Least Privilege is widely recognized as an important design consideration in enhancing the protection of critical systems from faults and malicious behavior (https://en.wikipedia.org/wiki/Principle_of_least_privilege). It suggests that every component must be able to access only the information and resources that are necessary for its legitimate purpose. This document demonstrates how the Principle of Least Privilege can be implemented within the Kubernetes Engine network layer.

Network connections can be restricted at two tiers of your Kubernetes Engine infrastructure. The first, and coarser grained, mechanism is the application of Firewall Rules at the Network, Subnetwork, and Host levels. These rules are applied outside of the Kubernetes Engine at the VPC level.

While Firewall Rules are a powerful security measure, Kubernetes enables us to define even finer grained rules via Network Policies. Network Policies are used to limit intra-cluster communication. Note that network policies do not apply to pods attached to the host's network namespace.

The steps below will provision a private Kubernetes Engine cluster and a bastion host with which to access it. A bastion host provides a single host that has access to the cluster, which, when combined with a private kubernetes network ensures that the cluster isn't exposed to malicious behavior from the internet at large. Bastions are particularly useful when you do not have VPN access to the cloud network.

Within the cluster, a simple HTTP server and two client pods will be provisioned. This tutorial will then demonstrate how to use a Network Policy and labeling to only allow connections from one of the client pods.

Architecture

For demonstration purposes, you will define a private Kubernetes cluster. Since the cluster is private, neither the API nor the worker nodes will be accessible from the internet. Instead, you will define a bastion host and use a firewall rule to enable access to it. The bastion's IP address is defined as an authorized network for the cluster, which grants it access to the API.

Within the cluster, provision three workloads:

  1. hello-server: this is a simple HTTP server with an internally-accessible endpoint
  2. hello-client-allowed: this is a single pod that repeatedly attempts to access hello-server. The pod is labeled such that the Network Policy will allow it to connect to hello-server.
  3. hello-client-blocked: this runs the same code as hello-client-allowed but the pod is labeled such that the Network Policy will not allow it to connect to hello-server.

architecture

Prerequisites

Run Demo in a Google Cloud Shell

Click the button below to run the demo in a Google Cloud Shell.

Open in Cloud Shell

All the tools for the demo are installed. When using Cloud Shell execute the following command in order to setup gcloud cli. When executing this command please setup your region and zone.

gcloud init

Tools

  1. Terraform >= 0.12.3
  2. Google Cloud SDK version >= 253.0.0
  3. kubectl matching the latest GKE version
  4. bash or bash compatible shell
  5. GNU Make 3.x or later
  6. A Google Cloud Platform project where you have permission to create networks

Install Cloud SDK

The Google Cloud SDK is used to interact with your GCP resources. Installation instructions for multiple platforms are available online.

Install kubectl CLI

The kubectl CLI is used to interteract with both Kubernetes Engine and kubernetes in general. Installation instructions for multiple platforms are available online.

Install Terraform

Terraform is used to automate the manipulation of cloud infrastructure. Its installation instructions are also available online.

Deployment

The steps below will walk you through using terraform to deploy a Kubernetes Engine cluster that you will then use for working with Kubernetes network policies.

Authenticate gcloud

Prior to running this demo, ensure you have authenticated your gcloud client by running the following command:

gcloud auth application-default login

Configure gcloud settings

Run gcloud config list and make sure that compute/zone, compute/region and core/project are populated with values that work for you. You can set their values with the following commands:

# Where the region is us-east1
gcloud config set compute/region us-east1

Updated property [compute/region].
# Where the zone inside the region is us-east1-c
gcloud config set compute/zone us-east1-c

Updated property [compute/zone].
# Where the project name is my-project-name
gcloud config set project my-project-name

Updated property [core/project].

Setup this project

This project requires the following Google Cloud Service APIs to be enabled:

  • compute.googleapis.com
  • container.googleapis.com
  • cloudbuild.googleapis.com

In addition, the terraform configuration takes three parameters to determine where the Kubernetes Engine cluster should be created:

  • project
  • region
  • zone

For simplicity, these parameters are to be specified in a file named terraform.tfvars, in the terraform directory. To ensure the appropriate APIs are enabled and to generate the terraform/terraform.tfvars file based on your gcloud defaults, run:

make setup-project

This will enable the necessary Service APIs, and it will also generate a terraform/terraform.tfvars file with the following keys. The values themselves will match the output of gcloud config list:

cat terraform/terraform.tfvars

project="YOUR_PROJECT"
region="YOUR_REGION"
zone="YOUR_ZONE"

If you need to override any of the defaults, simply replace the desired value(s) to the right of the equals sign(s). Be sure your replacement values are still double-quoted.

Provisioning the Kubernetes Engine Cluster

Next, apply the terraform configuration with:

# From within the project root, use make to apply the terraform
make tf-apply

When prompted if you want to deploy the plan, review the generated plan and enter yes to deploy the environment.

Validation

Once complete, terraform will output a message indicating successful creation of the cluster.

...snip...
google_container_cluster.primary: Still creating... (3m0s elapsed)
google_container_cluster.primary: Still creating... (3m10s elapsed)
google_container_cluster.primary: Still creating... (3m20s elapsed)
google_container_cluster.primary: Still creating... (3m30s elapsed)
google_container_cluster.primary: Creation complete after 3m34s (ID: gke-demo-cluster)

Apply complete! Resources: 5 added, 0 changed, 0 destroyed.

You can also confirm the cluster was created successfully by ensuring that Network Policies are enabled for the new cluster. Verify that networkPolicyConfig.disabled is false and networkPolicy.provider is CALICO.

gcloud container clusters describe gke-demo-cluster | grep  -A1 networkPolicy
  networkPolicyConfig:
    disabled: true
--
networkPolicy:
  provider: CALICO

Now ssh into the bastion for the remaining steps.

gcloud compute ssh gke-demo-bastion

The newly-created cluster will now be available for the standard kubectl commands on the bastion.

Installing the hello server

The test application consists of one simple HTTP server, deployed as hello-server and two clients, one of which will be labeled as app=hello and the other app=not-hello.

All three services can be deployed by applying the hello-app manifests. On the bastion, run:

kubectl apply -f ./manifests/hello-app/

deployment.apps/hello-client-allowed created
deployment.apps/hello-client-blocked created
service/hello-server created
deployment.apps/hello-server created

Use `kubectl get pods`` to verify all three pods have been successfully deployed. You will see one running pod for each of hello-client-allowed, hello-client-blocked, and hello-server deployments.

kubectl get pods
NAME                                      READY     STATUS    RESTARTS   AGE
hello-client-allowed-7d95fcd5d9-t8fsk   |  1/1      Running   0          14m
hello-client-blocked-6497db465d-ckbn8   |  1/1      Running   0          14m
hello-server-7df58f7fb5-nvcvd           |  1/1      Running   0          14m

Confirming default access to the hello server

Open two new terminals and ssh into the bastion on both using the command:

gcloud compute ssh gke-demo-bastion

Tail the logs for the clients in each console:

In the first of the two newly created terminals, tail the "allowed" client:

kubectl logs --tail 10 -f $(kubectl get pods -oname -l app=hello)

In the second newly created terminal, tail the logs of the "blocked" client:

kubectl logs --tail 10 -f $(kubectl get pods -oname -l app=not-hello)

You will notice that both pods are successfully able to connect to the hello-server service. This is because you have not yet defined a Network Policy to restrict access. In each of these windows you should see successful responses from the server.

Hostname: hello-server-7df58f7fb5-nvcvd
Hello, world!
Version: 1.0.0
Hostname: hello-server-7df58f7fb5-nvcvd
Hello, world!
Version: 1.0.0
Hostname: hello-server-7df58f7fb5-nvcvd
...

Restricting access with a Network Policy

In this step you will block access to the hello-server pod from all pods that are not labeled with app=hello.

The policy definition you'll use is contained in manifests/network-policy.yaml

Apply the policy with the following command:

kubectl apply -f ./manifests/network-policy.yaml

networkpolicy.networking.k8s.io/hello-server-allow-from-hello-client created

You'll now see that the output looks like this in the window tailing the "blocked" client:

wget: download timed out
wget: download timed out
wget: download timed out
wget: download timed out
wget: download timed out
wget: download timed out
wget: download timed out
wget: download timed out
wget: download timed out
...

Indicating that the network policy has now prevented communication to the hello-server from the unlabeled pod.

Restricting namespaces with Network Policies

In the previous example, you defined a network policy that restricts connections based on pod labels. It is often useful to instead label entire namespaces, particularly when teams or applications are granted their own namespaces.

You'll now modify the network policy to only allow traffic from a designated namespace, then you'll move the hello-allowed pod into that new namespace.

First, delete the existing network policy and create the namespaced version

kubectl delete -f ./manifests/network-policy.yaml

networkpolicy.networking.k8s.io "hello-server-allow-from-hello-client" deleted
kubectl create -f ./manifests/network-policy-namespaced.yaml

networkpolicy.networking.k8s.io/hello-server-allow-from-hello-client created

Now observe the logs of the hello-allowed-client pod in the default namespace. You will notice it is no longer able to connect to the hello-server.

Finally, deploy a second copy of the hello-clients app into the new namespace.

kubectl -n hello-apps apply -f ./manifests/hello-app/hello-client.yaml

deployment.apps/hello-client-allowed created
deployment.apps/hello-client-blocked created

Validation

Check the logs for the two new hello-app clients and you will see that both clients are able to connect successfully. This is because, as of Kubernetes 1.10.x NetworkPolicies do not support restricting access to pods within a given namespace. You can whitelist by pod label, namespace label, or whitelist the union (ie OR) of both. But you cannot yet whitelist the intersection (ie AND) of pod labels and namespace labels.

View the logs for the "hello"-labeled app in the app in the hello-apps namespace:

kubectl logs --tail 10 -f -n hello-apps $(kubectl get pods -oname -l app=hello -n hello-apps)

Hostname: hello-server-6c6fd59cc9-7fvgp
Hello, world!
Version: 1.0.0
Hostname: hello-server-6c6fd59cc9-7fvgp
Hello, world!
Version: 1.0.0
Hostname: hello-server-6c6fd59cc9-7fvgp
Hello, world!
Version: 1.0.0
Hostname: hello-server-6c6fd59cc9-7fvgp
Hello, world!
Version: 1.0.0
Hostname: hello-server-6c6fd59cc9-7fvgp

Tear Down

Log out of the bastion host and run the following to destroy the environment:

make teardown

...snip...
google_compute_subnetwork.cluster-subnet: Still destroying... (ID: us-east1/kube-net-subnet, 20s elapsed)
google_compute_subnetwork.cluster-subnet: Destruction complete after 25s
google_compute_network.gke-network: Destroying... (ID: kube-net)
google_compute_network.gke-network: Still destroying... (ID: kube-net, 10s elapsed)
google_compute_network.gke-network: Still destroying... (ID: kube-net, 20s elapsed)
google_compute_network.gke-network: Destruction complete after 26s

Destroy complete! Resources: 5 destroyed.

Troubleshooting

The install script fails with a Permission denied when running Terraform

The credentials that Terraform is using do not provide the necessary permissions to create resources in the selected projects. Ensure that the account listed in gcloud config list has necessary permissions to create resources. If it does, regenerate the application default credentials using gcloud auth application-default login.

Invalid fingerprint error during Terraform operations

Terraform occasionally complains about an invalid fingerprint, when updating certain resources. If you see the error below, simply re-run the command. terraform fingerprint error

Relevant Material

This is not an officially supported Google product

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This guide demonstrates how to improve the security of your Kubernetes Engine by applying fine-grained restrictions to network communication. You will provision a simple HTTP server and two client pods in a Kubernetes Engine cluster, then use a Network Policy restrict connections from client pods.

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