Control plane security

This document describes how cluster control plane components are secured in Google Kubernetes Engine.

Under the Shared Responsibility Model, Google manages the GKE control plane components for you. The control plane includes the Kubernetes API server, etcd, and a number of controllers. Google is responsible for securing the control plane, though you might be able to configure certain options based on your requirements. You are responsible for securing your nodes, containers, and Pods.

Hardened operating system

GKE control plane components run on Container-Optimized OS, which is a security-hardened operating system designed by Google. For a detailed description of the security features built in to Container Optimized OS, see the Container-Optimized OS security overview.

Architecture and isolation

In a GKE cluster, the control plane components run on Compute Engine instances owned by Google, in a Google-managed project. Each instance runs these components for only one customer.

Authentication to the Kubernetes API server and etcd is done the same way it's done for other Google Cloud services. Application-layer Transport Security (ALTS) protects these communications.

Administrative access to the cluster

SSH sessions by Google Site Reliability Engineers are audit logged through Google's internal audit infrastructure, which is available for forensics and security response. For more information, see Administrative access in the Google Security Whitepaper.

etcd security

In Google Cloud Platform, customer content is encrypted at the filesystem layer by default. So disks that host etcd storage for GKE clusters are encrypted at the filesystem layer. For more information, see Encryption at Rest.

etcd listens on two TCP ports. Port 2379 is for etcd clients, like the Kubernetes API server. Port 2379 is bound to the local loopback network interface, so it is only accessible from the VM that is running the Kubernetes API server. Port 2380 is for server-to-server communication. Traffic on port 2380 is encrypted by mutual TLS. That is, each server must prove its identity to the other. In a regional cluster, communication between etcd servers to establish a quorum is encrypted by mutual TLS.

Certificate authority and cluster trust

Each cluster has its own root certificate authority (CA). An internal Google service manages root keys for this CA. Each cluster also has its own CA for etcd. Root keys for the etcd CA are distributed to the metadata of the VMs that run the Kubernetes API server. Communication between nodes and the Kubernetes API server is protected by TLS. For more information, see Cluster Trust.

Vulnerability and patch management

GKE adheres to Google standards for testing, qualifying, and gradually rolling out changes to the control plane. This minimizes the risk of a control plane component becoming unavailable. GKE adheres to a service level agreement that defines many aspects of availability.

GKE control plane components are managed by a team of Google site reliability engineers, and are kept up to date with the latest security patches. This includes patches to the host operating system, Kubernetes components, and containers running on the control plane VMs.

GKE applies new kernel, OS, and Kubernetes-level fixes promptly to control plane VMs. When these contain fixes for known vulnerabilities, additional information is available in the GKE Security Bulletins. GKE scans all Kubernetes system and GKE-specific containers for vulnerabilities using Container Registry Vulnerability Scanning, and keeps the containers patched, benefitting the whole Kubernetes ecosystem.

Google engineers participate in finding, fixing, and disclosing Kubernetes security bugs. And Google pays external security researchers, through the Google-wide vulnerability reward program, to look for security bugs. In some cases, such as the dnsmasq vulnerability in October 2017, GKE has been able to patch all running clusters before the vulnerability became public.

What you can see

The security features discussed previously in this topic are managed by Google. This section and the following section discuss security features that you can monitor and configure.

Audit Logging is enabled by default for clusters created since the release of 1.8.3. This provides a detailed record, available in Stackdriver, of calls made to the Kubernetes API server. You can view the log entries on the Logs page in the GCP console. You can also use BigQuery to view and analyze these logs.

What you can configure

By default, the Kubernetes API server uses a public IP address. You can protect the Kubernetes API server by using master authorized networks and private clusters, which allow you to assign a private IP address to the Kubernetes API server and disable access on the public IP address.

You can handle cluster authentication in GKE by using Cloud IAM as the identity provider. You should ensure that you have disabled Basic Authentication by setting an empty username and password for the MasterAuth configuration. In the same configuration, you can also disable the client certificate, which ensures that you have one less key to think about when locking down access to your cluster.

You can enhance the security of your control plane by doing credential rotation on a regular basis. When credential rotation is initiated, the TLS certificates and cluster certificate authority are rotated automatically. GKE also rotates the IP address of your Kubernetes API server. For more information, see Role-Based Access Control and Credential Rotation.

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