Minikube: Network Policy

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Sumber: https://minikube.sigs.k8s.io/docs/handbook/network_policy/

Network Policy Controlling traffic flowing through the cluster minikube allows users to create and test network policies in the local Kubernetes cluster. This is useful since it allows the network policies to be, considered, built, and evaluated during the application development, as an integral part of the process rather than “bolted on” at the end of development.

Kubernetes NetworkPolicies allow the control of pod network traffic passing through the cluster, at the IP address or port level (OSI layer 3 or 4). The linked page provides much more information about the functionality and implementation.

However, the prerequisites note that Network policies are implemented by the Container Network Interface (CNI) network plugin. Therefore to use or test network policies in any Kubernetes cluster, you must be using a networking solution which supports NetworkPolicy. Creating a NetworkPolicy resource without a controller that implements it will have no effect.

A vanilla minikube installation (minikube start) does not support any NetworkPolicies, since the default CNI, Kindnet, does not support Network Policies, by design.

However, minikube can support NetworkPolicies if a supported CNI, such as Calico, is installed. In addition, in this scenario both Kubernetes network policy and Calico network policy are supported.

Calico network policy provides a richer set of policy capabilities than Kubernetes network policy including:

policy ordering/priority deny rules more flexible match rules Enabling Calico on a minikube cluster It is possible to replace the CNI on a running minikube cluster, but it is significantly easier to simply append the --cni calico flag to the minikube start command when following the instructions on the Get Started! page to build the minikube cluster with Calico installed from the outset.

Kubernetes Network Policy example The Kubernetes documentation on declaring network policy is a good place to start to understand the possibilities. In addition, the tutorials in Further reading below give much more guidance.

The YAML below from the Kubernetes NetworkPolicies documentation shows a very simple default ingress isolation policy or a namespace by creating a NetworkPolicy that selects all pods but does not allow any ingress traffic to those pods.

--- apiVersion: networking.k8s.io/v1 kind: NetworkPolicy metadata:

 name: default-deny-ingress

spec:

 podSelector: {}
 policyTypes:
 - Ingress

Calico Network Policy example The Calico network policy documentation is the best place to learn about the extended feature set of Calico network policy and how it coexists with Kubernetes network policy.

The YAML below from the Calico policy tutorial shows a very simple default deny Global Calico Network Policy (not available with vanilla Kubernetes network policy) that is often used as a starting point for an effective zero-trust network model. Note that Global Calico Network Policies are not namespaced and affect all pods that match the policy selector. In contrast, Kubernetes Network Policies are namespaced, so you would need to create a default deny policy per namespace to achieve the same effect. In this example pods in the kube-system namespace are excluded to keep Kubernetes itself running smoothly.

--- apiVersion: projectcalico.org/v3 kind: GlobalNetworkPolicy metadata:

 name: default-deny

spec:

 selector: projectcalico.org/namespace != "kube-system"
 types:
 - Ingress
 - Egress

Further reading This Advanced Kubernetes policy tutorial gives an example of what can be achieved with Kubernetes network policy. It walks through using Kubernetes NetworkPolicy to define more complex network policies.

This Calico policy tutorial demonstrates the extended functionalities Calico network policy offers over and above vanilla Kubernetes network policies. To demonstrate this, this tutorial follows a similar approach to the tutorial above, but instead uses Calico network policies and highlights differences between the two policy types, making use of features that are not available in Kubernetes network policies


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