Applications running in a Kubernetes cluster find and communicate with each other, and the outside world, through the Service abstraction. This document explains what happens to the source IP of packets sent to different types of Services, and how you can toggle this behavior according to your needs.
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. If you do not already have a cluster, you can create one by using Minikube, or you can use one of these Kubernetes playgrounds:
To check the version, enter kubectl version
.
This document makes use of the following terms:
You must have a working Kubernetes 1.5 cluster to run the examples in this document. The examples use a small nginx webserver that echoes back the source IP of requests it receives through an HTTP header. You can create it as follows:
$ kubectl run source-ip-app --image=k8s.gcr.io/echoserver:1.4
deployment "source-ip-app" created
Packets sent to ClusterIP from within the cluster are never source NAT’d if
you’re running kube-proxy in iptables mode,
which is the default since Kubernetes 1.2. Kube-proxy exposes its mode through
a proxyMode
endpoint:
$ kubectl get nodes
NAME STATUS AGE VERSION
kubernetes-minion-group-6jst Ready 2h v1.6.0+fff5156
kubernetes-minion-group-cx31 Ready 2h v1.6.0+fff5156
kubernetes-minion-group-jj1t Ready 2h v1.6.0+fff5156
kubernetes-minion-group-6jst $ curl localhost:10249/proxyMode
iptables
You can test source IP preservation by creating a Service over the source IP app:
$ kubectl expose deployment source-ip-app --name=clusterip --port=80 --target-port=8080
service "clusterip" exposed
$ kubectl get svc clusterip
NAME CLUSTER-IP EXTERNAL-IP PORT(S) AGE
clusterip 10.0.170.92 <none> 80/TCP 51s
And hitting the ClusterIP
from a pod in the same cluster:
$ kubectl run busybox -it --image=busybox --restart=Never --rm
Waiting for pod default/busybox to be running, status is Pending, pod ready: false
If you don't see a command prompt, try pressing enter.
# ip addr
1: lo: <LOOPBACK,UP,LOWER_UP> mtu 65536 qdisc noqueue
link/loopback 00:00:00:00:00:00 brd 00:00:00:00:00:00
inet 127.0.0.1/8 scope host lo
valid_lft forever preferred_lft forever
inet6 ::1/128 scope host
valid_lft forever preferred_lft forever
3: eth0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1460 qdisc noqueue
link/ether 0a:58:0a:f4:03:08 brd ff:ff:ff:ff:ff:ff
inet 10.244.3.8/24 scope global eth0
valid_lft forever preferred_lft forever
inet6 fe80::188a:84ff:feb0:26a5/64 scope link
valid_lft forever preferred_lft forever
# wget -qO - 10.0.170.92
CLIENT VALUES:
client_address=10.244.3.8
command=GET
...
If the client pod and server pod are in the same node, the client_address is the client pod’s IP address. However, if the client pod and server pod are in different nodes, the client_address is the client pod’s node flannel IP address.
As of Kubernetes 1.5, packets sent to Services with Type=NodePort
are source NAT’d by default. You can test this by creating a NodePort
Service:
$ kubectl expose deployment source-ip-app --name=nodeport --port=80 --target-port=8080 --type=NodePort
service "nodeport" exposed
$ NODEPORT=$(kubectl get -o jsonpath="{.spec.ports[0].nodePort}" services nodeport)
$ NODES=$(kubectl get nodes -o jsonpath='{ $.items[*].status.addresses[?(@.type=="ExternalIP")].address }')
If you’re running on a cloudprovider, you may need to open up a firewall-rule
for the nodes:nodeport
reported above.
Now you can try reaching the Service from outside the cluster through the node
port allocated above.
$ for node in $NODES; do curl -s $node:$NODEPORT | grep -i client_address; done
client_address=10.180.1.1
client_address=10.240.0.5
client_address=10.240.0.3
Note that these are not the correct client IPs, they’re cluster internal IPs. This is what happens:
node2:nodePort
node2
replaces the source IP address (SNAT) in the packet with its own IP addressnode2
replaces the destination IP on the packet with the pod IPVisually:
client
\ ^
\ \
v \
node 1 <--- node 2
| ^ SNAT
| | --->
v |
endpoint
To avoid this, Kubernetes has a feature to preserve the client source IP
(check here for feature availability).
Setting service.spec.externalTrafficPolicy
to the value Local
will only
proxy requests to local endpoints, never forwarding traffic to other nodes
and thereby preserving the original source IP address. If there are no
local endpoints, packets sent to the node are dropped, so you can rely
on the correct source-ip in any packet processing rules you might apply a
packet that make it through to the endpoint.
Set the service.spec.externalTrafficPolicy
field as follows:
$ kubectl patch svc nodeport -p '{"spec":{"externalTrafficPolicy":"Local"}}'
service "nodeport" patched
Now, re-run the test:
$ for node in $NODES; do curl --connect-timeout 1 -s $node:$NODEPORT | grep -i client_address; done
client_address=104.132.1.79
Note that you only got one reply, with the right client IP, from the one node on which the endpoint pod is running.
This is what happens:
node2:nodePort
, which doesn’t have any endpointsnode1:nodePort
, which does have endpointsVisually:
client
^ / \
/ / \
/ v X
node 1 node 2
^ |
| |
| v
endpoint
As of Kubernetes 1.5, packets sent to Services with Type=LoadBalancer are
source NAT’d by default, because all schedulable Kubernetes nodes in the
Ready
state are eligible for loadbalanced traffic. So if packets arrive
at a node without an endpoint, the system proxies it to a node with an
endpoint, replacing the source IP on the packet with the IP of the node (as
described in the previous section).
You can test this by exposing the source-ip-app through a loadbalancer
$ kubectl expose deployment source-ip-app --name=loadbalancer --port=80 --target-port=8080 --type=LoadBalancer
service "loadbalancer" exposed
$ kubectl get svc loadbalancer
NAME CLUSTER-IP EXTERNAL-IP PORT(S) AGE
loadbalancer 10.0.65.118 104.198.149.140 80/TCP 5m
$ curl 104.198.149.140
CLIENT VALUES:
client_address=10.240.0.5
...
However, if you’re running on Google Kubernetes Engine/GCE, setting the same service.spec.externalTrafficPolicy
field to Local
forces nodes without Service endpoints to remove
themselves from the list of nodes eligible for loadbalanced traffic by
deliberately failing health checks.
Visually:
client
|
lb VIP
/ ^
v /
health check ---> node 1 node 2 <--- health check
200 <--- ^ | ---> 500
| V
endpoint
You can test this by setting the annotation:
$ kubectl patch svc loadbalancer -p '{"spec":{"externalTrafficPolicy":"Local"}}'
You should immediately see the service.spec.healthCheckNodePort
field allocated
by Kubernetes:
$ kubectl get svc loadbalancer -o yaml | grep -i healthCheckNodePort
healthCheckNodePort: 32122
The service.spec.healthCheckNodePort
field points to a port on every node
serving the health check at /healthz
. You can test this:
$ kubectl get pod -o wide -l run=source-ip-app
NAME READY STATUS RESTARTS AGE IP NODE
source-ip-app-826191075-qehz4 1/1 Running 0 20h 10.180.1.136 kubernetes-minion-group-6jst
kubernetes-minion-group-6jst $ curl localhost:32122/healthz
1 Service Endpoints found
kubernetes-minion-group-jj1t $ curl localhost:32122/healthz
No Service Endpoints Found
A service controller running on the master is responsible for allocating the cloud loadbalancer, and when it does so, it also allocates HTTP health checks pointing to this port/path on each node. Wait about 10 seconds for the 2 nodes without endpoints to fail health checks, then curl the lb ip:
$ curl 104.198.149.140
CLIENT VALUES:
client_address=104.132.1.79
...
Cross platform support
As of Kubernetes 1.5, support for source IP preservation through Services with Type=LoadBalancer is only implemented in a subset of cloudproviders (GCP and Azure). The cloudprovider you’re running on might fulfill the request for a loadbalancer in a few different ways:
With a proxy that terminates the client connection and opens a new connection to your nodes/endpoints. In such cases the source IP will always be that of the cloud LB, not that of the client.
With a packet forwarder, such that requests from the client sent to the loadbalancer VIP end up at the node with the source IP of the client, not an intermediate proxy.
Loadbalancers in the first category must use an agreed upon
protocol between the loadbalancer and backend to communicate the true client IP
such as the HTTP X-FORWARDED-FOR
header, or the proxy protocol.
Loadbalancers in the second category can leverage the feature described above
by simply creating an HTTP health check pointing at the port stored in
the service.spec.healthCheckNodePort
field on the Service.
Delete the Services:
$ kubectl delete svc -l run=source-ip-app
Delete the Deployment, ReplicaSet and Pod:
$ kubectl delete deployment source-ip-app