path: root/ovn/CONTAINERS.OpenStack.md

Integration of Containers with OVN and OpenStack
------------------------------------------------

Isolation between containers is weaker than isolation between VMs, so
some environments deploy containers for different tenants in separate
VMs as an additional security measure.  This document describes creation of
containers inside VMs and how they can be made part of the logical networks
securely.  The created logical network can include VMs, containers and
physical machines as endpoints.  To better understand the proposed integration
of containers with OVN and OpenStack, this document describes the end to end
workflow with an example.

* A OpenStack tenant creates a VM (say VM-A) with a single network interface
that belongs to a management logical network.  The VM is meant to host
containers.  OpenStack Nova chooses the hypervisor on which VM-A is created.

* A Neutron port may have been created in advance and passed in to Nova
with the request to create a new VM.  If not, Nova will issue a request
to Neutron to create a new port.  The ID of the logical port from
Neutron will also be used as the vif-id for the virtual network
interface (VIF) of VM-A.

* When VM-A is created on a hypervisor, its VIF gets added to the
Open vSwitch integration bridge.  This creates a row in the Interface table
of the Open_vSwitch database.  As explained in the [IntegrationGuide.md],
the vif-id associated with the VM network interface gets added in the
external_ids:iface-id column of the newly created row in the Interface table.

* Since VM-A belongs to a logical network, it gets an IP address.  This IP
address is used to spawn containers (either manually or through container
orchestration systems) inside that VM and to monitor the health of the
created containers.

* The vif-id associated with the VM's network interface can be obtained by
making a call to Neutron using tenant credentials.

* This flow assumes a component called a "container network plugin".
If you take Docker as an example for containers, you could envision
the plugin to be either a wrapper around Docker or a feature of Docker itself
that understands how to perform part of this workflow to get a container
connected to a logical network managed by Neutron.  The rest of the flow
refers to this logical component that does not yet exist as the
"container network plugin".

* All the calls to Neutron will need tenant credentials.  These calls can
either be made from inside the tenant VM as part of a container network plugin
or from outside the tenant VM (if the tenant is not comfortable using temporary
Keystone tokens from inside the tenant VMs).  For simplicity, this document
explains the work flow using the former method.

* The container hosting VM will need Open vSwitch installed in it.  The only
work for Open vSwitch inside the VM is to tag network traffic coming from
containers.

* When a container needs to be created inside the VM with a container network
interface that is expected to be attached to a particular logical switch, the
network plugin in that VM chooses any unused VLAN (This VLAN tag only needs to
be unique inside that VM.  This limits the number of container interfaces to
4096 inside a single VM).  This VLAN tag is stripped out in the hypervisor
by OVN and is only useful as a context (or metadata) for OVN.

* The container network plugin then makes a call to Neutron to create a
logical port.  In addition to all the inputs that a call to create a port in
Neutron that are currently needed, it sends the vif-id and the VLAN tag as
inputs.

* Neutron in turn will verify that the vif-id belongs to the tenant in question
and then uses the OVN specific plugin to create a new row in the Logical_Port
table of the OVN Northbound Database.  Neutron responds back with an
IP address and MAC address for that network interface.  So Neutron becomes
the IPAM system and provides unique IP and MAC addresses across VMs and
containers in the same logical network.

* The Neutron API call above to create a logical port for the container
could add a relatively significant amount of time to container creation.
However, an optimization is possible here.  Logical ports could be
created in advance and reused by the container system doing container
orchestration.  Additional Neutron API calls would only be needed if the
port needs to be attached to a different logical network.

* When a container is eventually deleted, the network plugin in that VM
may make a call to Neutron to delete that port.  Neutron in turn will
delete the entry in the Logical_Port table of the OVN Northbound Database.

As an example, consider Docker containers.  Since Docker currently does not
have a network plugin feature, this example uses a hypothetical wrapper
around Docker to make calls to Neutron.

* Create a Logical switch, e.g.:

```
% ovn-docker --cred=cca86bd13a564ac2a63ddf14bf45d37f create network LS1
```

The above command will make a call to Neutron with the credentials to create
a logical switch.  The above is optional if the logical switch has already
been created from outside the VM.

* List networks available to the tenant.

```
% ovn-docker --cred=cca86bd13a564ac2a63ddf14bf45d37f list networks
```

* Create a container and attach a interface to the previously created switch
as a logical port.

```
% ovn-docker --cred=cca86bd13a564ac2a63ddf14bf45d37f --vif-id=$VIF_ID \
--network=LS1 run -d --net=none ubuntu:14.04 /bin/sh -c \
"while true; do echo hello world; sleep 1; done"
```

The above command will make a call to Neutron with all the inputs it currently
needs to create a logical port.  In addition, it passes the $VIF_ID and a
unused VLAN.  Neutron will add that information in OVN and return back
a MAC address and IP address for that interface.  ovn-docker will then create
a veth pair, insert one end inside the container as 'eth0' and the other end
as a port of a local OVS bridge as an access port of the chosen VLAN.

[IntegrationGuide.md]:IntegrationGuide.md