Kubernetes provides several built-in security capabilities, including network security, resource isolation, access control, and logging and auditing. One of the more recent security capabilities is a group of plugins known as admission controllers.
Admission controllers enable governance and enforcement of how clusters are used. Kubernetes ships with over 30 admission controllers, which are listed here along with their descriptions. This article assumes you have a basic understanding of admission controllers, but if you are unfamiliar with them, check out Kubernetes reference guide on admission controllers to learn more.
We’ve compiled 11 tips and recommendations to help you operationalize admission controllers for better security:
-
As a first step, enable admission controllers in order to use some of the more advanced security features of Kubernetes, such as pod security policies which enforce configuration baseline for an entire namespace.
-
To turn on an admission controller, use the following command line, replacing what appears after “=” with the name of the admission controller you want to turn on
--enable-admission-plugins=NameOfController,NameOfController2
- To turn off an admission controller, use the following command line, replacing what appears after “=” with the actual name of the admission controller you want to turn off
--disable-admission-plugins=NameOfController,NameOfController2
- Ensure that the following admission controllers are enabled by default:
NamespaceLifecycle,LimitRanger,ServiceAccount,DefaultStorageClass,DefaultTolerationSeconds,MutatingAdmissionWebhook,ValidatingAdmissionWebhook,Priority,ResourceQuota,PodSecurityPolicy
-
In order to validate Kubernetes resources during create, update, and delete operations, enable
ValidatingAdmissionWebhook
-
Consider disabling the
MutatingAdmissionWebhook
admission controller or applying stricter RBAC restrictions as to who can createMutatingWebhookConfiguration
-
You can use
PodSecurityPolicy
admission controller to prevent containers from running as root or ensure the container’s root filesystem is always mounted as read-only. Keep in mind that unless a policy has already been defined in aPodSecurityPolicy
, pods will not be created because the admission controller’s default operation is to reject pod creation in cases where no matching policy is found. -
Create custom, webhook-based admission controllers to:
- Prevent pulling images from unknown registries while allowing only approved registry usage.
- Set policies that prevent insecure deployments. For example, containers using
privileged
flag increase your security risk because they can bypass a lot of security controls. You can avoid this risk by using a webhook-based admission controller that either rejects this type of deployment or overrides theprivileged
flag. - Enforce label validation on objects to ensure proper labels are used, such as every object being assigned to a team or project.
- Automatically add annotations to objects, such as attributing the correct cost center for a “dev” deployment resource.
-
Use admission controllers to audit the configuration of the objects in clusters to prevent insecure and misconfigured objects from getting into your cluster.
-
Admission controllers can be used to identify and correct images deployed without semantic tags by:
- Automatically adding or validating resource limits
- Ensuring reasonable labels are attached to pods
- Making sure image references in product deployments are not using
latest
tags, or tags with a-dev
suffix
- Use
AlwaysPullImages
admission controller to ensure pull policy is set to Always, such as when you want to make sure a user’s private images are only pulled by those who have the credentials to pull them. Without this admission controller, any pod from any user can use an image by merely knowing its name.
Admission controllers are one of the critical pillars of security for Kubernetes, and as a result, a Kubernetes API server that’s not utilizing the correct set of admission controllers will be incomplete and unable to support all of the expected features of Kubernetes.
About the author
More like this
Browse by channel
Automation
The latest on IT automation for tech, teams, and environments
Artificial intelligence
Updates on the platforms that free customers to run AI workloads anywhere
Open hybrid cloud
Explore how we build a more flexible future with hybrid cloud
Security
The latest on how we reduce risks across environments and technologies
Edge computing
Updates on the platforms that simplify operations at the edge
Infrastructure
The latest on the world’s leading enterprise Linux platform
Applications
Inside our solutions to the toughest application challenges
Original shows
Entertaining stories from the makers and leaders in enterprise tech
Products
- Red Hat Enterprise Linux
- Red Hat OpenShift
- Red Hat Ansible Automation Platform
- Cloud services
- See all products
Tools
- Training and certification
- My account
- Customer support
- Developer resources
- Find a partner
- Red Hat Ecosystem Catalog
- Red Hat value calculator
- Documentation
Try, buy, & sell
Communicate
About Red Hat
We’re the world’s leading provider of enterprise open source solutions—including Linux, cloud, container, and Kubernetes. We deliver hardened solutions that make it easier for enterprises to work across platforms and environments, from the core datacenter to the network edge.
Select a language
Red Hat legal and privacy links
- About Red Hat
- Jobs
- Events
- Locations
- Contact Red Hat
- Red Hat Blog
- Diversity, equity, and inclusion
- Cool Stuff Store
- Red Hat Summit