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I'm reading the Kubernetes "Getting Started from Scratch" Guide and have arrived at the dreaded Network Section, where they state:

Kubernetes imposes the following fundamental requirements on any networking implementation
(barring any intentional network segmentation policies):
* all containers can communicate with all other containers without NAT
* all nodes can communicate with all containers (and vice-versa) without NAT
* the IP that a container sees itself as is the same IP that others see it as

My first source of confusion is: How is this different than the "standard" Docker model? How is Docker different w.r.t. those 3 Kubernetes requirements?

The article then goes on to summarize how GCE achieves these requirements:

For the Google Compute Engine cluster configuration scripts, we use advanced routing to assign each VM a subnet (default is /24 - 254 IPs). Any traffic bound for that subnet will be routed directly to the VM by the GCE network fabric. This is in addition to the "main" IP address assigned to the VM, which is NAT'ed for outbound internet access. A linux bridge (called cbr0) is configured to exist on that subnet, and is passed to docker's --bridge flag.

My question here is: Which requirement(s) from the 3 above does this paragraph address? More importantly, how does it achieve the requirement(s)? I guess I just don't understand how 1-subnet-per-VM accomplishes: container-container communication, node-container communication, and static IP.


And, as a bonus/stretch concern: Why doesn't Marathon suffer from the same networking concerns as what Kubernetes is addressing here?

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Docker's standard networking configuration picks a container subnet for you out of its chosen defaults. As long as it doesn't conflict with any interfaces on your host, Docker is okay with it.

Then, Docker inserts an iptables MASQUERADE rule that allows containers to talk to the external world using the host's default interface.

Kubernetes' 3 requirements are violated by the fact that subnets are chosen only based on addresses in use on the host, which forces the requirement to NAT all container traffic using the MASQUERADE rule.

Consider the following 3-host Docker setup (a little contrived to highlight things):

Host 1:

eth0: 10.1.2.3

docker0: 172.17.42.1/16

container-A: 172.17.42.2

Host 2:

eth0: 10.1.2.4

docker0: 172.17.42.1/16

container-B: 172.17.42.2

Host 3:

eth0: 172.17.42.2

docker0: 172.18.42.1

Let's say container-B wants to access an HTTP service on port 80 of container-A. You can get docker to expose container-A's port 80 somewhere on Host 1. Then container-B might make a request to 10.1.2.3:43210. This will be received on container-A's port 80, but will look like it came from some random port on 10.1.2.4 because of the NAT on the way out of Host 2. This violates the all containers communicate without NAT and the container sees same IP as others requirements. Try to access container-A's service directly from Host 2 and you get your nodes can communicate with containers without NAT violation.

Now if either of those containers want to talk to Host 3, they're SOL (just a general argument for being careful with the auto-assigned docker0 subnets).

Kubernetes approach on GCE/AWS/Flannel/... is to assign each host VM a subnet carved out of a flat private network. No subnets overlap with VM addresses or with each other. This lets containers and VMs communicate NATlessly.

  • Thanks for such an awesome answer @CJ Cullen (+1) - a few quick followups for you should shore this up for me, and the lightbulbs are already starting to turn on. (1) When you say that Docker chooses a subnet for you, you mean it chooses a subnet mask, right? Can you confirm that what you mean is that the subnet mask is deliberately chosen so as to not to conflict with an IP address in use on the host? If so, how exactly can a subnet mask conflict with a host IP? (2) Why does this "subnet mask" selection strategy force the router to NAT all traffic from the host? – smeeb Sep 30 '15 at 0:49
  • (3) You say "Then container-B might make a request to 10.1.2.3:43210. This will be received on container-A's port 80, but will look like it came from some random port on 10.1.2.4 because of the NAT on the way out of Host 2.” Can you explain this a little more? Why would a request to port 43210 be received on port 80? How does NAT obfuscate the egress IP/port coming from Host 2? – smeeb Sep 30 '15 at 0:51
  • (4) Why is Kubernetes so concerned about not using NAT?!? What’s so bad about it? And finally (I know sorry!) (5) When you say "Now if either of those containers want to talk to Host 3, they're SOL”…why?!? I'm just not seeing it. Thanks again for any and all help/clarity here! – smeeb Sep 30 '15 at 0:51
  • (1) Docker chooses the whole subnet (e.g. 172.17.42.1/16). The subnet mask is just the "/16" part. Docker avoids conflicts w/ addresses in use on the host. For example, if the default interface (or the local nameserver) had the IP 172.17.42.2, Docker wouldn't be able to choose 172.17.42.1/16 (because it includes 172.17.42.2). (2) Because Docker can only look at locally used addresses, the addresses it assigns containers might conflict with other things in your network. It can assume that your host IP is unique on the network (otherwise everything else would break). – CJ Cullen Sep 30 '15 at 3:18
  • (3) In order to expose the service to other machines, you'd have to bind the container port to a host port (see docs.docker.com/articles/networking/#binding-ports). Port 43210 was the host port I chose as an example. (4) Kubernetes' service model depends a flat networking space, among other reasons (see github.com/kubernetes/kubernetes/blob/master/docs/design/…). (5) Host 3 and the containers have the same IP. To communicate, they'll have to do some sort of funky NATing (i.e. how does container-B say "get these packets to Host 3"?). – CJ Cullen Sep 30 '15 at 3:36

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