Daniele Polencic
Daniele Polencic

Kubernetes Chaos Engineering: Lessons Learned — Part 1

Updated in April 2019


Kubernetes Chaos Engineering: Lessons Learned

When you deploy an application in Kubernetes, your code ends up running on one or more worker nodes.

A node may be a physical machine or VM such as AWS EC2 or Google Compute Engine and having several of them means you can run and scale your application across instances efficiently.

If you have a cluster made of three nodes and decide to scale your application to have four replicas, Kubernetes will spread the replicas across the nodes evenly like so:

The architecture described above works particularly well in case of failures.

If the first node were to be unavailable, the other two could still serve the application.

Meanwhile, Kubernetes has enough time to reschedule the fourth replica to another node.

Even better, if all of the nodes were to become isolated, they could still serve traffic. Let's scale down the application to two replicas:

Now imagine that the three pods belong to a service of type: NodePort.

A NodePort service exposes a port in the range between 30000-32767 in each node in the cluster.

That means that every node can respond to incoming requests, even if the node itself doesn't host the app.

So how does the third node know that it doesn't run the pod and has to route the traffic to one of the other nodes?

Kubernetes has a binary called kube-proxy that runs on each node, and that is in charge of routing the traffic from a service to a specific pod.

You can think of kube-proxy like a receptionist.

The proxy intercepts all the traffic directed to the service and routes it to the right pod.

But how does kube-proxy know where all the pods are?

And how does kube-proxy know about the services?

It doesn't.

The master node knows everything and is in charge of creating the list with all the routing rules.

kube-proxy is in charge of checking and enforcing the rules on the list.

In the simple scenario above, the list looks like this:

It doesn't matter which node the traffic is coming from; kube-proxy knows where the traffic should be forwarded to by looking at the list.

But what happens when kube-proxy crashes?

And what if the list of rules is lost?

What happens when there's no rule to forward the traffic to?

Manabu Sakai had the same questions. So he decided to find out.

Let's assume you have a 2 node cluster on GCP:

bash

kubectl get nodes
NAME        STATUS  ROLES   AGE VERSION
node1       Ready   <none>  17h v1.8.8-gke.0
node2       Ready   <none>  18h v1.8.8-gke.0

And you deployed Manabu's application with:

bash

kubectl create -f https://raw.githubusercontent.com/manabusakai/k8s-hello-world/master/kubernetes/deployment.yml
kubectl create -f https://raw.githubusercontent.com/manabusakai/k8s-hello-world/master/kubernetes/service.yml

The application is simple. It displays the hostname of the current pod in a web page:

App display "Hello World"

You should scale the deployments to ten replicas with:

bash

kubectl scale --replicas 10 deployment/k8s-hello-world

The ten replicas are distributed evenly across the two nodes:

bash

kubectl get pods
NAME                              READY STATUS  NODE
k8s-hello-world-55f48f8c94-7shq5  1/1   Running node1
k8s-hello-world-55f48f8c94-9w5tj  1/1   Running node1
k8s-hello-world-55f48f8c94-cdc64  1/1   Running node2
k8s-hello-world-55f48f8c94-lkdvj  1/1   Running node2
k8s-hello-world-55f48f8c94-npkn6  1/1   Running node1
k8s-hello-world-55f48f8c94-ppsqk  1/1   Running node2
k8s-hello-world-55f48f8c94-sc9pf  1/1   Running node1
k8s-hello-world-55f48f8c94-tjg4n  1/1   Running node2
k8s-hello-world-55f48f8c94-vrkr9  1/1   Running node1
k8s-hello-world-55f48f8c94-xzvlc  1/1   Running node2
Distributing traffic

A Service was created to load balance the requests across the ten replicas:

bash

kubectl get services
NAME              TYPE      CLUSTER-IP      EXTERNAL-IP PORT(S)         AGE
k8s-hello-world   NodePort  100.69.211.31   <none>      8080:30000/TCP  3h
kubernetes        ClusterIP 100.64.0.1      <none>      443/TCP         18h

The service is exposed to the outside world using NodePort on port 30000. In other words, each node has port 30000 opened to the public internet and can accept incoming traffic.

NodePort

But how is the traffic routed from port 30000 to my pod?

kube-proxy is in charge of setting up the rules to route the incoming traffic from port 30000 to one of the ten pods.

You should try to request the node on port 30000:

bash

curl <node ip>:30000

Please note that you can retrieve the node's IP with kubectl get nodes -o wide

The application replies with Hello World! and the hostname of the container is running on.

In the previous command, you should be greeted by Hello world! via <hostname>.

If you keep requesting the same URL, you may notice how sometimes you get the same response and sometimes it changes.

kube-proxy is acting as a load balancer and is looking at the routing list and distributing the traffic across the ten pods.

What's more interesting is that it doesn't matter which node you request.

The response could come from any pod, even one that is not hosted on the same node you requested.

To complete your setup, you should have an external load balancer routing the traffic to your nodes on port 30000.

Load balancer

The load balancer will route the incoming traffic from the internet to one of the two nodes.

If you're confused by how many load balancer-like things we have, let's quickly recap:

  1. Traffic coming from the internet is routed to the primary load balancer
  2. The load balancer forwards the traffic to one of the two nodes on port 30000
  3. The rules set up by kube-proxy route the traffic from the node to a pod
  4. the traffic reaches the pod

Phew! That was long!

It's time to break things

Now that you know how things are plugged in together let's get back to the original question.

What if you tamper with the routing rules?

Will the cluster still work?

Do the pods still serve requests?

Let's go ahead and delete the routing rules.

In a separate shell, you should monitor the application for time and dropped requests.

You could write a loop that every second prints the time and request the application:

bash

while sleep 1;
  do date +%X; curl -sS http://<your load balancer ip>/ | grep ^Hello;
done
10:14:41 Hello world! via k8s-hello-world-55f48f8c94-vrkr9
10:14:43 Hello world! via k8s-hello-world-55f48f8c94-tjg4n
^C

In this case, you have the time in the first column and the response from the pod in the other.

The first call was made to the k8s-hello-world-55f48f8c94-vrkr9 pod at 10:14 and 41 seconds.

The second call was made to the k8s-hello-world-55f48f8c94-tjg4n pod at 10:14 and 43 seconds.

Let's delete the routing rules from the node.

kube-proxy can operate in three modes: userspace, iptables and ipvs. The default since Kubernetes 1.2 is iptables.

Please note that if you're using a cluster with 1.11 or more recent, you might be using ipvs.

In iptables mode, kube-proxy writes the list of routing rules to the node using iptables rules.

So you could log in into one of the node servers and delete the iptables rules with iptables -F.

Please note that iptables -F may interfere with your SSH connection.

If everything went according to plan you should experience something similar to this:

bash

while sleep 1;
  do date +%X; curl -sS http://<your load balancer ip>/ | grep ^Hello;
done
10:14:41 Hello world! via k8s-hello-world-55f48f8c94-xzvlc
10:14:43 Hello world! via k8s-hello-world-55f48f8c94-tjg4n
# this is when `iptables -F` was issued
10:15:10 Hello world! via k8s-hello-world-55f48f8c94-vrkr9
10:15:11 Hello world! via k8s-hello-world-55f48f8c94-vrkr9
^C

As you noticed, it took about 27 seconds from when you dropped the iptables rules and the next response, from 10:14:43 to 10:15:10.

What happened in this 27 seconds?

Why is everything back to normal after 27 seconds?

Perhaps it's just a coincidence. Let's flush the rules again:

bash

while sleep 1;
  do date +%X; curl -sS http://<your load balancer ip>/ | grep ^Hello;
done
11:29:55 Hello world! via k8s-hello-world-55f48f8c94-xzvlc
11:29:56 Hello world! via k8s-hello-world-55f48f8c94-tjg4n
# this is when `iptables -F` was issued
11:30:25 Hello world! via k8s-hello-world-55f48f8c94-npkn6
11:30:27 Hello world! via k8s-hello-world-55f48f8c94-vrkr9
^C

There was a gap of 29 seconds, from 11:29:56 to 11:30:25, but the cluster is back to normal.

Why does it take about 30 seconds to reply?

Is the node receiving traffic despite no routing table?

Maybe you could investigate what happens to the node in this 30 seconds.

In another terminal, you should write a loop to make requests to the application every second. But this time, you should request the node and not the load balancer:

bash

while sleep 1;
  do printf %"s\n" $(curl -sS http://<ip of the node>:30000);
done

And let's drop the iptables rules. The log from the previous command is:

bash

while sleep 1;
  do printf %"s\n" $(curl -sS http://<ip of the node>:30000);
done
Hello world! via k8s-hello-world-55f48f8c94-xzvlc
Hello world! via k8s-hello-world-55f48f8c94-tjg4n
# this is when `iptables -F` was issued
curl: (28) Connection timed out after 10003 milliseconds
curl: (28) Connection timed out after 10004 milliseconds
Hello world! via k8s-hello-world-55f48f8c94-npkn6
Hello world! via k8s-hello-world-55f48f8c94-vrkr9
^C

It shouldn't come as a surprise that connections to the node are timing out after you drop the iptables rules. What's more interesting is that curl waits for ten seconds before giving up.

What if in the previous example the load balancer is waiting for the connection to be made?

That would explain the 30 seconds delay. But it doesn't tell why the node is ready to accept a connection when you wait long enough.

So why is the traffic recovering after 30 seconds?

Who is putting the iptables rules back?

Before you drop the iptables rules, you can inspect them with:

bash

iptables -L

Soon after you drop the rules, you should keep executing iptables -F and notice that the rules are back in a few seconds!

Is this you, kube-proxy?

Yes, it is.

Digging in the official documentation for kube-proxy reveals two interesting flags:

kube-proxy refreshes the iptables rules every 10 to 30 seconds.

If we drop the iptables rules, it will take up to 30 seconds for kube-proxy to realise and restore them back.

That explains why it took 30 seconds to get your node back!

It also explains how routing tables are propagated from the master node to the worker node.

kube-proxy is in charge of syncing them on a regular basis.

In other words, every time a pod is added or deleted, the master node recomputes the routing list.

On a regular interval, kube-proxy syncs the rules into the current node.

Let's recap how Kubernetes and kube-proxy can recover from someone tampering with the iptables rules on the node:

  1. The iptables rules are deleted from the node
  2. A request is forwarded to the load balancer and routed to the node
  3. The node doesn't accept incoming requests, so the load balancer waits
  4. After 30 seconds kube-proxy restores the iptables
  5. The node can serve traffic again. The iptables rules forward the request from the load balancer to the pod
  6. The pod replies to the load balancer with a 30 seconds delay

Waiting for 30 seconds may be unacceptable for your application. You may be interested in tweaking the default refresh interval for kube-proxy.

So where are the settings and how can you change them?

It turns out that there's an agent on the node — the kubelet — that is in charge of starting kube-proxy as a static pod on each node.

The documentation for static pods suggests that the kubelet scans a specific folder and creates all the resources contained in that folder.

If you inspect the kubelet process in the node, you should be able to see the kubelet running with --pod-manifest-path=/etc/kubernetes/manifests.

Running a simple ls reveals the truth:

bash

ls -l /etc/kubernetes/manifests
total 4 -rw-r--r-- 1 root root 1398 Feb 24 08:08 kube-proxy.manifest

And a quick cat of kube-proxy.manifest reveals the content:

kube-proxy.manifest

apiVersion: v1
kind: Pod
metadata:
  name: kube-proxy
spec:
  hostNetwork: true
  containers:
  - name: kube-proxy
    image: gcr.io/google_containers/kube-proxy:v1.8.7-gke.1
    command:
    - /bin/sh
    - -c
    ->
    echo -998 > /proc/$$$/oom_score_adj &&
    exec kube-proxy
    --master=https://35.190.207.197
    --kubeconfig=/var/lib/kube-proxy/kubeconfig
    --cluster-cidr=10.4.0.0/14
    --resource-container=""
    --v=2
    --feature-gates=ExperimentalCriticalPodAnnotation=true
    --iptables-sync-period=30s
    1>>/var/log/kube-proxy.log 2>&1

Please note that the content was truncated and is not shown in full.

Mystery unravelled!

You can see how --iptables-sync-period=30s is used to refresh the iptables rules every 30 seconds.

You could go ahead and modify that command to customise the min and max time to update the iptables rules for that node.

Lessons learned

Dropping iptables rules is similar to make a node unavailable. The traffic is still routed to the node, but the node is not able to forward it further.

Kubernetes can recover from a similar failure by monitoring the state of the routing rules and updating them when necessary.

Many thanks to Manabu Sakai's blog post that was a huge inspiration and to Valentin Ouvrard for investigating the issue with the iptables propagation.

That's all folks!

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