Simulating networks with VPP

The “make test” framework provides a good way to test individual features. However, when testing several features at once - or validating nontrivial configurations - it may prove difficult or impossible to use the unit-test framework.

This note explains how to set up lxc/lxd, and a 5-container testbed to test a split-tunnel nat + ikev2 + ipsec + ipv6 prefix-delegation scenario.

OS / Distro test results

This setup has been tested on an Ubuntu 18.04 LTS system. If you’re feeling adventurous, the same scenario also worked on a recent Ubuntu 20.04 “preview” daily build.

Other distros may work fine, or not at all.

Proxy Server

If you need to use a proxy server e.g. from a lab system, you’ll probably need to set HTTP_PROXY, HTTPS_PROXY, http_proxy and https_proxy in /etc/environment. Directly setting variables in the environment doesn’t work. The lxd snap daemon needs the proxy settings, not the user interface.

Something like so:

HTTP_PROXY=http://my.proxy.server:8080
HTTPS_PROXY=http://my.proxy.server:4333
http_proxy=http://my.proxy.server:8080
https_proxy=http://my.proxy.server:4333

Install and configure lxd

Install the lxd snap. The lxd snap is up to date, as opposed to the results of “sudo apt-get install lxd”.

# snap install lxd
# lxd init

“lxd init” asks several questions. With the exception of the storage pool, take the defaults. To match the configs shown below, create a storage pool named “vpp.” Storage pools of type “zfs” and “files” have been tested successfully.

zfs is more space-efficient. “lxc copy” is infinitely faster with zfs. The path for the zfs storage pool is under /var. Do not replace it with a symbolic link, unless you want to rebuild all of your containers from scratch. Ask me how I know that.

Create three network segments

Aka, linux bridges.

# lxc network create respond
# lxc network create internet
# lxc network create initiate

We’ll explain the test topology in a bit. Stay tuned.

Set up the default container profile

Execute “lxc profile edit default”, and install the following configuration. Note that the “shared” directory should mount your vpp workspaces. With that trick, you can edit code from any of the containers, run vpp without installing it, etc.

config: {}
description: Default LXD profile
devices:
  eth0:
    name: eth0
    network: lxdbr0
    type: nic
  eth1:
    name: eth1
    nictype: bridged
    parent: internet
    type: nic
  eth2:
    name: eth2
    nictype: bridged
    parent: respond
    type: nic
  eth3:
    name: eth3
    nictype: bridged
    parent: initiate
    type: nic
  root:
    path: /
    pool: vpp
    type: disk
  shared:
    path: /scratch
    source: /scratch
    type: disk
name: default

Set up the network configurations

Edit the fake “internet” backbone:

# lxc network edit internet

Install the ip addresses shown below, to avoid having to rebuild the vpp and host configuration:

config:
  ipv4.address: 10.26.68.1/24
  ipv4.dhcp.ranges: 10.26.68.10-10.26.68.50
  ipv4.nat: "true"
  ipv6.address: none
  ipv6.nat: "false"
description: ""
name: internet
type: bridge
used_by:
managed: true
status: Created
locations:
- none

Repeat the process with the “respond” and “initiate” networks, using these configurations:

respond network configuration

config:
  ipv4.address: 10.166.14.1/24
  ipv4.dhcp.ranges: 10.166.14.10-10.166.14.50
  ipv4.nat: "true"
  ipv6.address: none
  ipv6.nat: "false"
description: ""
name: respond
type: bridge
used_by:
managed: true
status: Created
locations:
- none

initiate network configuration

config:
  ipv4.address: 10.219.188.1/24
  ipv4.dhcp.ranges: 10.219.188.10-10.219.188.50
  ipv4.nat: "true"
  ipv6.address: none
  ipv6.nat: "false"
description: ""
name: initiate
type: bridge
used_by:
managed: true
status: Created
locations:
- none

Create a “master” container image

The master container image should be set up so that you can build vpp, ssh into the container, edit source code, run gdb, etc.

Make sure that e.g. public key auth ssh works.

# lxd launch ubuntu:18.04 respond
<spew>
# lxc exec respond bash
respond# cd /scratch/my-vpp-workspace
respond# apt-get install make ssh
respond# make install-dep
respond# exit
# lxc stop respond

Mark the container image privileged. If you forget this step, you’ll trip over a netlink error (-11) aka EAGAIN when you try to roll in the vpp configurations.

# lxc config set respond security.privileged "true"

Duplicate the “master” container image

To avoid having to configure N containers, be sure that the master container image is fully set up before you help it have children:

# lxc copy respond respondhost
# lxc copy respond initiate
# lxc copy respond initiatehost
# lxc copy respond dhcpserver    # optional, to test ipv6 prefix delegation

Install handy script

See below for a handy script which executes lxc commands across the current set of running containers. I call it “lxc-foreach,” feel free to call the script Ishmael if you like.

Examples:

$ lxc-foreach start
<issues "lxc start" for each container in the list>

After a few seconds, use this one to open an ssh connection to each container. The ssh command parses the output of “lxc info,” which displays container ip addresses.

$ lxc-foreach ssh

Here’s the script:

#!/bin/bash

set -u
export containers="respond respondhost initiate initiatehost dhcpserver"

if [ x$1 = "x" ] ; then
    echo missing command
    exit 1
fi

if [ $1 = "ssh" ] ; then
    for c in $containers
    do
        inet=`lxc info $c | grep eth0 | grep -v inet6 | head -1 | cut -f 3`
        if [ x$inet = "x" ] ; then
            echo $c not started
        else
            gnome-terminal --command "/usr/bin/ssh $inet"
        fi
    done
exit 0
fi

for c in $containers
do
    echo lxc $1 $c
    lxc $1 $c
done

exit 0

Test topology

Finally, we’re ready to describe a test topology. First, a picture:

===+======== management lan/bridge lxdbr0 (dhcp) ===========+===
   |                             |                          |
   |                             |                          |
   |                             |                          |
   v                             |                          v
  eth0                           |                         eth0
+------+ eth1                                       eth1 +------+
| respond | 10.26.88.100 <= internet bridge => 10.26.88.101 | initiate |
+------+                                                 +------+
  eth2 / bvi0 10.166.14.2        |       10.219.188.2 eth3 / bvi0
   |                             |                          |
   | ("respond" bridge)             |          ("initiate" bridge) |
   |                             |                          |
   v                             |                          v
  eth2 10.166.14.3               |           eth3 10.219.188.3
+----------+                     |                   +----------+
| respondhost |                     |                   | respondhost |
+----------+                     |                   +----------+
  eth0 (management lan) <========+========> eth0 (management lan)

Test topology discussion

This topology is suitable for testing almost any tunnel encap/decap scenario. The two containers “respondhost” and “initiatehost” are end-stations connected to two vpp instances running on “respond” and “initiate”.

We leverage the Linux end-station network stacks to generate traffic of all sorts.

The so-called “internet” bridge models the public internet. The “respond” and “initiate” bridges connect vpp instances to local hosts

End station configs

The end-station Linux configurations set up the eth2 and eth3 ip addresses shown above, and add tunnel routes to the opposite end-station networks.

respondhost configuration

ifconfig eth2 10.166.14.3/24 up
route add -net 10.219.188.0/24 gw 10.166.14.2

initiatehost configuration

sudo ifconfig eth3 10.219.188.3/24 up
sudo route add -net 10.166.14.0/24 gw 10.219.188.2

VPP configs

Split nat44 / ikev2 + ipsec tunneling, with ipv6 prefix delegation in the “respond” config.

respond configuration

set term pag off

comment { "internet" }
create host-interface name eth1
set int ip address host-eth1 10.26.68.100/24
set int ip6 table host-eth1 0
set int state host-eth1 up

comment { default route via initiate }
ip route add 0.0.0.0/0 via 10.26.68.101

comment { "respond-private-net" }
create host-interface name eth2
bvi create instance 0
set int l2 bridge bvi0 1 bvi
set int ip address bvi0 10.166.14.2/24
set int state bvi0 up
set int l2 bridge host-eth2 1
set int state host-eth2 up


nat44 add interface address host-eth1
set interface nat44 in host-eth2 out host-eth1
nat44 add identity mapping external host-eth1 udp 500
nat44 add identity mapping external host-eth1 udp 4500
comment { nat44 untranslated subnet 10.219.188.0/24 }

comment { responder profile }
ikev2 profile add initiate
ikev2 profile set initiate udp-encap
ikev2 profile set initiate auth rsa-sig cert-file /scratch/setups/respondcert.pem
set ikev2 local key /scratch/setups/initiatekey.pem
ikev2 profile set initiate id local fqdn initiator.my.net
ikev2 profile set initiate id remote fqdn responder.my.net
ikev2 profile set initiate traffic-selector remote ip-range 10.219.188.0 - 10.219.188.255 port-range 0 - 65535 protocol 0
ikev2 profile set initiate traffic-selector local ip-range 10.166.14.0 - 10.166.14.255 port-range 0 - 65535 protocol 0
create ipip tunnel src 10.26.68.100 dst 10.26.68.101
ikev2 profile set initiate tunnel ipip0

comment { ipv6 prefix delegation }
ip6 nd address autoconfig host-eth1 default-route
dhcp6 client host-eth1
dhcp6 pd client host-eth1 prefix group hgw
set ip6 address bvi0 prefix group hgw ::2/56
ip6 nd address autoconfig bvi0 default-route
ip6 nd bvi0 ra-interval 5 3 ra-lifetime 180

set int mtu packet 1390 ipip0
set int unnum ipip0 use host-eth1
ip route add 10.219.188.0/24 via ipip0

initiate configuration

set term pag off

comment { "internet" }
create host-interface name eth1
comment { set dhcp client intfc host-eth1 hostname initiate }
set int ip address host-eth1 10.26.68.101/24
set int state host-eth1 up

comment { default route via "internet gateway" }
comment { ip route add 0.0.0.0/0 via 10.26.68.1 }

comment { "initiate-private-net" }
create host-interface name eth3
bvi create instance 0
set int l2 bridge bvi0 1 bvi
set int ip address bvi0 10.219.188.2/24
set int state bvi0 up
set int l2 bridge host-eth3 1
set int state host-eth3 up

nat44 add interface address host-eth1
set interface nat44 in bvi0 out host-eth1
nat44 add identity mapping external host-eth1 udp 500
nat44 add identity mapping external host-eth1 udp 4500
comment { nat44 untranslated subnet 10.166.14.0/24 }

comment { initiator profile }
ikev2 profile add respond
ikev2 profile set respond udp-encap
ikev2 profile set respond auth rsa-sig cert-file /scratch/setups/initiatecert.pem
set ikev2 local key /scratch/setups/respondkey.pem
ikev2 profile set respond id local fqdn responder.my.net
ikev2 profile set respond id remote fqdn initiator.my.net

ikev2 profile set respond traffic-selector remote ip-range 10.166.14.0 - 10.166.14.255 port-range 0 - 65535 protocol 0
ikev2 profile set respond traffic-selector local ip-range 10.219.188.0 - 10.219.188.255 port-range 0 - 65535 protocol 0

ikev2 profile set respond responder host-eth1 10.26.68.100
ikev2 profile set respond ike-crypto-alg aes-cbc 256  ike-integ-alg sha1-96  ike-dh modp-2048
ikev2 profile set respond esp-crypto-alg aes-cbc 256  esp-integ-alg sha1-96  esp-dh ecp-256
ikev2 profile set respond sa-lifetime 3600 10 5 0

create ipip tunnel src 10.26.68.101 dst 10.26.68.100
ikev2 profile set respond tunnel ipip0
ikev2 initiate sa-init respond

set int mtu packet 1390 ipip0
set int unnum ipip0 use host-eth1
ip route add 10.166.14.0/24 via ipip0

IKEv2 certificate setup

In both of the vpp configurations, you’ll see “/scratch/setups/xxx.pem” mentioned. These certificates are used in the ikev2 key exchange.

Here’s how to generate the certificates:

openssl req -x509 -nodes -newkey rsa:4096 -keyout respondkey.pem -out respondcert.pem -days 3560
openssl x509 -text -noout -in respondcert.pem
openssl req -x509 -nodes -newkey rsa:4096 -keyout initiatekey.pem -out initiatecert.pem -days 3560
openssl x509 -text -noout -in initiatecert.pem

Make sure that the “respond” and “initiate” configurations point to the certificates.

DHCPv6 server setup

If you need an ipv6 dhcp server to test ipv6 prefix delegation, create the “dhcpserver” container as shown above.

Install the “isc-dhcp-server” Debian package:

sudo apt-get install isc-dhcp-server

/etc/dhcp/dhcpd6.conf

Edit the dhcpv6 configuration and add an ipv6 subnet with prefix delegation. For example:

subnet6 2001:db01:0:1::/64 {
        range6 2001:db01:0:1::1 2001:db01:0:1::9;
        prefix6 2001:db01:0:100:: 2001:db01:0:200::/56;
}

Add an ipv6 address on eth1, which is connected to the “internet” bridge, and start the dhcp server. I use the following trivial bash script, which runs the dhcp6 server in the foreground and produces dhcp traffic spew:

#!/bin/bash
ifconfig eth1 inet6 add 2001:db01:0:1::10/64 || true
dhcpd -6 -d -cf /etc/dhcp/dhcpd6.conf

The “|| true” bit keeps going if eth1 already has the indicated ipv6 address.

Container / Host Interoperation

Host / container interoperation is highly desirable. If the host and a set of containers don’t run the same distro and distro version, it’s reasonably likely that the glibc versions won’t match. That, in turn, makes vpp binaries built in one environment fail in the other.

Trying to install multiple versions of glibc - especially at the host level - often ends very badly and is not recommended. It’s not just glibc, either. The dynamic loader ld-linux-xxx-so.2 is glibc version specific.

Fortunately, it’s reasonable easy to build lxd container images based on specific Ubuntu or Debian versions.

Create a custom root filesystem image

First, install the “debootstrap” tool:

sudo apt-get install debootstrap

Make a temp directory, and use debootstrap to populate it. In this example, we create an Ubuntu 20.04 (focal fossa) base image:

# mkdir /tmp/myroot
# debootstrap focal /tmp/myroot http://archive.ubuntu.com/ubuntu

To tinker with the base image (if desired):

# chroot /tmp/myroot
<add packages, etc.>
# exit

Make a compressed tarball of the base image:

# tar zcf /tmp/rootfs.tar.gz -C /tmp/myroot .

Create a “metadata.yaml” file which describes the base image:

architecture: "x86_64"
# To get current date in Unix time, use `date +%s` command
creation_date: 1458040200
properties:
architecture: "x86_64"
description: "My custom Focal Fossa image"
os: "Ubuntu"
release: "focal"

Make a compressed tarball of metadata.yaml:

# tar zcf metadata.tar.gz metadata.yaml

Import the image into lxc / lxd:

$ lxc image import metadata.tar.gz rootfd.tar.gz --alias focal-base

Create a container which uses the customized base image:

$ lxc launch focal-base focaltest
$ lxc exec focaltest bash

The next several steps should be executed in the container, in the bash shell spun up by “lxc exec…”

Configure container networking

In the container, create /etc/netplan/50-cloud-init.yaml:

network:
    version: 2
    ethernets:
        eth0:
            dhcp4: true

Use “cat > /etc/netplan/50-cloud-init.yaml”, and cut-’n-paste if your favorite text editor is AWOL.

Apply the configuration:

# netplan apply

At this point, eth0 should have an ip address, and you should see a default route with “route -n”.

Configure apt

Again, in the container, set up /etc/apt/sources.list via cut-’n-paste from a recently update “focal fossa” host. Something like so:

deb http://us.archive.ubuntu.com/ubuntu/ focal main restricted
deb http://us.archive.ubuntu.com/ubuntu/ focal-updates main restricted
deb http://us.archive.ubuntu.com/ubuntu/ focal universe
deb http://us.archive.ubuntu.com/ubuntu/ focal-updates universe
deb http://us.archive.ubuntu.com/ubuntu/ focal multiverse
deb http://us.archive.ubuntu.com/ubuntu/ focal-updates multiverse
deb http://us.archive.ubuntu.com/ubuntu/ focal-backports main restricted universe multiverse
deb http://security.ubuntu.com/ubuntu focal-security main restricted
deb http://security.ubuntu.com/ubuntu focal-security universe
deb http://security.ubuntu.com/ubuntu focal-security multiverse

“apt-get update” and “apt-install” should produce reasonable results. Suggest “apt-get install make git”.

At this point, you can use the “/scratch” sharepoint (or similar) to execute “make install-dep install-ext-deps” to set up the container with the vpp toolchain; proceed as desired.