Virtual IPs and Service Proxies
Every node in a Kubernetes cluster runs a kube-proxy (unless you have deployed your own alternative component in place of kube-proxy
).
The kube-proxy
component is responsible for implementing a virtual IP mechanism for Services of type
other than ExternalName.
A question that pops up every now and then is why Kubernetes relies on proxying to forward inbound traffic to backends. What about other approaches? For example, would it be possible to configure DNS records that have multiple A values (or AAAA for IPv6), and rely on round-robin name resolution?
There are a few reasons for using proxying for Services:
- There is a long history of DNS implementations not respecting record TTLs, and caching the results of name lookups after they should have expired.
- Some apps do DNS lookups only once and cache the results indefinitely.
- Even if apps and libraries did proper re-resolution, the low or zero TTLs on the DNS records could impose a high load on DNS that then becomes difficult to manage.
Later in this page you can read about how various kube-proxy implementations work. Overall, you should note that, when running kube-proxy
, kernel level rules may be modified (for example, iptables rules might get created), which won’t get cleaned up, in some cases until you reboot. Thus, running kube-proxy is something that should only be done by an administrator which understands the consequences of having a low level, privileged network proxying service on a computer. Although the kube-proxy
executable supports a cleanup
function, this function is not an official feature and thus is only available to use as-is.
Some of the details in this reference refer to an example: the back end Pods for a stateless image-processing workload, running with three replicas. Those replicas are fungible—frontends do not care which backend they use. While the actual Pods that compose the backend set may change, the frontend clients should not need to be aware of that, nor should they need to keep track of the set of backends themselves.
Proxy modes
Note that the kube-proxy starts up in different modes, which are determined by its configuration.
- The kube-proxy’s configuration is done via a ConfigMap, and the ConfigMap for kube-proxy effectively deprecates the behavior for almost all of the flags for the kube-proxy.
- The ConfigMap for the kube-proxy does not support live reloading of configuration.
- The ConfigMap parameters for the kube-proxy cannot all be validated and verified on startup. For example, if your operating system doesn’t allow you to run iptables commands, the standard kernel kube-proxy implementation will not work.
iptables
proxy mode
In this mode, kube-proxy watches the Kubernetes control plane for the addition and removal of Service and EndpointSlice objects. For each Service, it installs iptables rules, which capture traffic to the Service’s clusterIP
and port
, and redirect that traffic to one of the Service’s backend sets. For each endpoint, it installs iptables rules which select a backend Pod.
By default, kube-proxy in iptables mode chooses a backend at random.
Using iptables to handle traffic has a lower system overhead, because traffic is handled by Linux netfilter without the need to switch between userspace and the kernel space. This approach is also likely to be more reliable.
If kube-proxy is running in iptables mode and the first Pod that’s selected does not respond, the connection fails. This is different from the old userspace
mode: in that scenario, kube-proxy would detect that the connection to the first Pod had failed and would automatically retry with a different backend Pod.
You can use Pod readiness probes to verify that backend Pods are working OK, so that kube-proxy in iptables mode only sees backends that test out as healthy. Doing this means you avoid having traffic sent via kube-proxy to a Pod that’s known to have failed.
Services overview diagram for iptables proxy
Example
As an example, consider the image processing application described earlier in the page. When the backend Service is created, the Kubernetes control plane assigns a virtual IP address, for example 10.0.0.1. For this example, assume that the Service port is 1234. All of the kube-proxy instances in the cluster observe the creation of the new Service.
When kube-proxy on a node sees a new Service, it installs a series of iptables rules which redirect from the virtual IP address to more iptables rules, defined per Service. The per-Service rules link to further rules for each backend endpoint, and the per- endpoint rules redirect traffic (using destination NAT) to the backends.
When a client connects to the Service’s virtual IP address the iptables rule kicks in. A backend is chosen (either based on session affinity or randomly) and packets are redirected to the backend without rewriting the client IP address.
This same basic flow executes when traffic comes in through a node-port or through a load-balancer, though in those cases the client IP address does get altered.
IPVS proxy mode
In ipvs
mode, kube-proxy watches Kubernetes Services and EndpointSlices, calls netlink
interface to create IPVS rules accordingly and synchronizes IPVS rules with Kubernetes Services and EndpointSlices periodically. This control loop ensures that IPVS status matches the desired state. When accessing a Service, IPVS directs traffic to one of the backend Pods.
The IPVS proxy mode is based on netfilter hook function that is similar to iptables mode, but uses a hash table as the underlying data structure and works in the kernel space. That means kube-proxy in IPVS mode redirects traffic with lower latency than kube-proxy in iptables mode, with much better performance when synchronizing proxy rules. Compared to the other proxy modes, IPVS mode also supports a higher throughput of network traffic.
IPVS provides more options for balancing traffic to backend Pods; these are:
rr
: round-robinlc
: least connection (smallest number of open connections)dh
: destination hashingsh
: source hashingsed
: shortest expected delaynq
: never queue
Note:
To run kube-proxy in IPVS mode, you must make IPVS available on the node before starting kube-proxy.
When kube-proxy starts in IPVS proxy mode, it verifies whether IPVS kernel modules are available. If the IPVS kernel modules are not detected, then kube-proxy falls back to running in iptables proxy mode.
Services overview diagram for IPVS proxy
Session affinity
In these proxy models, the traffic bound for the Service’s IP:Port is proxied to an appropriate backend without the clients knowing anything about Kubernetes or Services or Pods.
If you want to make sure that connections from a particular client are passed to the same Pod each time, you can select the session affinity based on the client’s IP addresses by setting .spec.sessionAffinity
to ClientIP
for a Service (the default is None
).
Session stickiness timeout
You can also set the maximum session sticky time by setting .spec.sessionAffinityConfig.clientIP.timeoutSeconds
appropriately for a Service. (the default value is 10800, which works out to be 3 hours).
Note: On Windows, setting the maximum session sticky time for Services is not supported.
IP address assignment to Services
Unlike Pod IP addresses, which actually route to a fixed destination, Service IPs are not actually answered by a single host. Instead, kube-proxy uses packet processing logic (such as Linux iptables) to define virtual IP addresses which are transparently redirected as needed.
When clients connect to the VIP, their traffic is automatically transported to an appropriate endpoint. The environment variables and DNS for Services are actually populated in terms of the Service’s virtual IP address (and port).
Avoiding collisions
One of the primary philosophies of Kubernetes is that you should not be exposed to situations that could cause your actions to fail through no fault of your own. For the design of the Service resource, this means not making you choose your own port number if that choice might collide with someone else’s choice. That is an isolation failure.
In order to allow you to choose a port number for your Services, we must ensure that no two Services can collide. Kubernetes does that by allocating each Service its own IP address from within the service-cluster-ip-range
CIDR range that is configured for the API server.
To ensure each Service receives a unique IP, an internal allocator atomically updates a global allocation map in etcd prior to creating each Service. The map object must exist in the registry for Services to get IP address assignments, otherwise creations will fail with a message indicating an IP address could not be allocated.
In the control plane, a background controller is responsible for creating that map (needed to support migrating from older versions of Kubernetes that used in-memory locking). Kubernetes also uses controllers to check for invalid assignments (e.g. due to administrator intervention) and for cleaning up allocated IP addresses that are no longer used by any Services.
IP address ranges for Service virtual IP addresses
FEATURE STATE: Kubernetes v1.25 [beta]
Kubernetes divides the ClusterIP
range into two bands, based on the size of the configured service-cluster-ip-range
by using the following formula min(max(16, cidrSize / 16), 256)
. That formula paraphrases as never less than 16 or more than 256, with a graduated step function between them.
Kubernetes prefers to allocate dynamic IP addresses to Services by choosing from the upper band, which means that if you want to assign a specific IP address to a type: ClusterIP
Service, you should manually assign an IP address from the lower band. That approach reduces the risk of a conflict over allocation.
If you disable the ServiceIPStaticSubrange
feature gate then Kubernetes uses a single shared pool for both manually and dynamically assigned IP addresses, that are used for type: ClusterIP
Services.
Traffic policies
You can set the .spec.internalTrafficPolicy
and .spec.externalTrafficPolicy
fields to control how Kubernetes routes traffic to healthy (“ready”) backends.
Internal traffic policy
FEATURE STATE: Kubernetes v1.22 [beta]
You can set the .spec.internalTrafficPolicy
field to control how traffic from internal sources is routed. Valid values are Cluster
and Local
. Set the field to Cluster
to route internal traffic to all ready endpoints and Local
to only route to ready node-local endpoints. If the traffic policy is Local
and there are no node-local endpoints, traffic is dropped by kube-proxy.
External traffic policy
You can set the .spec.externalTrafficPolicy
field to control how traffic from external sources is routed. Valid values are Cluster
and Local
. Set the field to Cluster
to route external traffic to all ready endpoints and Local
to only route to ready node-local endpoints. If the traffic policy is Local
and there are are no node-local endpoints, the kube-proxy does not forward any traffic for the relevant Service.
Traffic to terminating endpoints
FEATURE STATE: Kubernetes v1.26 [beta]
If the ProxyTerminatingEndpoints
feature gate is enabled in kube-proxy and the traffic policy is Local
, that node’s kube-proxy uses a more complicated algorithm to select endpoints for a Service. With the feature enabled, kube-proxy checks if the node has local endpoints and whether or not all the local endpoints are marked as terminating. If there are local endpoints and all of them are terminating, then kube-proxy will forward traffic to those terminating endpoints. Otherwise, kube-proxy will always prefer forwarding traffic to endpoints that are not terminating.
This forwarding behavior for terminating endpoints exist to allow NodePort
and LoadBalancer
Services to gracefully drain connections when using externalTrafficPolicy: Local
.
As a deployment goes through a rolling update, nodes backing a load balancer may transition from N to 0 replicas of that deployment. In some cases, external load balancers can send traffic to a node with 0 replicas in between health check probes. Routing traffic to terminating endpoints ensures that Node’s that are scaling down Pods can gracefully receive and drain traffic to those terminating Pods. By the time the Pod completes termination, the external load balancer should have seen the node’s health check failing and fully removed the node from the backend pool.
What’s next
To learn more about Services, read Connecting Applications with Services.
You can also:
- Read about Services
- Read the API reference for the Service API