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|
==========================================
Setting Up a Service VM as an IPv6 vRouter
==========================================
Now we can start to set up a service VM as an IPv6 vRouter. For exemplary purpose, we assume:
* The hostname of Open Daylight Controller Node is ``opnfv-odl-controller``, and the host IP address is
``192.168.0.30``
* The hostname of OpenStack Controller Node is ``opnfv-os-controller``, and the host IP address
is ``192.168.0.10``
* The hostname of OpenStack Compute Node is ``opnfv-os-compute``, and the host IP address is ``192.168.0.20``
* We use ``opnfv`` as username to login.
* We use ``devstack`` to install OpenStack Kilo, and the directory is ``~/devstack``
* Note: all IP addresses as shown below are for exemplary purpose.
****************************************************
Note: Disable Security Groups in OpenStack ML2 Setup
****************************************************
Please note that Security Groups feature has been disabled automatically through ``local.conf`` configuration file
during the setup procedure of OpenStack in both `Controller Node <./2-ipv6-configguide-os-controller.html>`_
and `Compute Node <./3-ipv6-configguide-os-compute.html>`_ using ``devstack``.
If you are installing OpenStack using a different installer (i.e. not with ``devstack``), please make sure
that Security Groups are disabled in the setup.
**Please refer to**
`here <./5-ipv6-configguide-scenario-1-native-os.html#note-disable-security-groups-in-openstack-ml2-setup>`_
**for the notes in** ``Section 2.4``, **steps** ``OS-NATIVE-SEC-1`` **through** ``OS-NATIVE-SEC-3``.
***************************************************
Source the Credentials in OpenStack Controller Node
***************************************************
**SETUP-SVM-1**: Login with username ``opnfv`` in OpenStack Controller Node ``opnfv-os-controller``.
Start a new terminal, and change directory to where OpenStack is installed.
.. code-block:: bash
cd ~/devstack
**SETUP-SVM-2**: Source the credentials.
.. code-block:: bash
# source the tenant credentials in devstack
opnfv@opnfv-os-controller:~/devstack$ source openrc admin demo
Please **NOTE** that the method of sourcing tenant credentials may vary depending on installers.
**Please refer to relevant documentation of installers if you encounter any issue**.
**************************************
Add External Connectivity to ``br-ex``
**************************************
Because we need to manually create networks/subnets to achieve the IPv6 vRouter, we have used the flag
``NEUTRON_CREATE_INITIAL_NETWORKS=False`` in ``local.conf`` file. When this flag is set to False,
``devstack`` does not create any networks/subnets during the setup phase.
Now we have to move the physical interface (i.e. the public network interface) to ``br-ex``,
including moving the public IP address and setting up default route. **Please note that this step
may already have been done when you use a different installer to deploy OpenStack because that installer
may have already moved the physical interface to** ``br-ex`` **during deployment**.
In OpenStack Controller Node ``opnfv-os-controller``, ``eth1`` is configured to provide external/public connectivity
for both IPv4 and IPv6 (optional). So let us add this interface to ``br-ex`` and move the IP address, including the
default route from ``eth1`` to ``br-ex``.
**SETUP-SVM-3**: Add ``eth1`` to ``br-ex`` and move the IP address and the default route from ``eth1`` to ``br-ex``
.. code-block:: bash
sudo ip addr del 198.59.156.113/24 dev eth1
sudo ovs-vsctl add-port br-ex eth1
sudo ifconfig eth1 up
sudo ip addr add 198.59.156.113/24 dev br-ex
sudo ifconfig br-ex up
sudo ip route add default via 198.59.156.1 dev br-ex
Please note that:
* The IP address ``198.59.156.113`` and related subnet and gateway addressed in the command
below are for exemplary purpose. **Please replace them with the IP addresses of your actual network**.
* **This can be automated in /etc/network/interfaces**.
**SETUP-SVM-4**: Verify that ``br-ex`` now has the original external IP address, and that the default route is on
``br-ex``
.. code-block:: bash
opnfv@opnfv-os-controller:~/devstack$ ip a s br-ex
38: br-ex: <BROADCAST,UP,LOWER_UP> mtu 1430 qdisc noqueue state UNKNOWN group default
link/ether 00:50:56:82:42:d1 brd ff:ff:ff:ff:ff:ff
inet 198.59.156.113/24 brd 198.59.156.255 scope global br-ex
valid_lft forever preferred_lft forever
inet6 fe80::543e:28ff:fe70:4426/64 scope link
valid_lft forever preferred_lft forever
opnfv@opnfv-os-controller:~/devstack$
opnfv@opnfv-os-controller:~/devstack$ ip route
default via 198.59.156.1 dev br-ex
192.168.0.0/24 dev eth0 proto kernel scope link src 192.168.0.10
192.168.122.0/24 dev virbr0 proto kernel scope link src 192.168.122.1
198.59.156.0/24 dev br-ex proto kernel scope link src 198.59.156.113
Please note that The IP addresses above are exemplary purpose
********************************************************
Create IPv4 Subnet and Router with External Connectivity
********************************************************
**SETUP-SVM-5**: Create a Neutron router ``ipv4-router`` which needs to provide external connectivity.
.. code-block:: bash
neutron router-create ipv4-router
**SETUP-SVM-6**: Create an external network/subnet ``ext-net`` using the appropriate values based on the
data-center physical network setup.
Please **NOTE** that if you use a different installer, i.e. NOT ``devstack``, your installer
may have already created an external network during installation. Under this circumstance,
you may only need to create the subnet of ``ext-net``. When you create the subnet, you must
use the same name of external network that your installer creates.
.. code-block:: bash
# If you use a different installer and it has already created an external work,
# Please skip this command "net-create"
neutron net-create --router:external ext-net
# If you use a different installer and it has already created an external work,
# Change the name "ext-net" to match the name of external network that your installer has created
neutron subnet-create --disable-dhcp --allocation-pool start=198.59.156.251,end=198.59.156.254 --gateway 198.59.156.1 ext-net 198.59.156.0/24
Please note that the IP addresses in the command above are for exemplary purpose. **Please replace the IP addresses of
your actual network**.
**SETUP-SVM-7**: Associate the ``ext-net`` to the Neutron router ``ipv4-router``.
.. code-block:: bash
# If you use a different installer and it has already created an external work,
# Change the name "ext-net" to match the name of external network that your installer has created
neutron router-gateway-set ipv4-router ext-net
**SETUP-SVM-8**: Create an internal/tenant IPv4 network ``ipv4-int-network1``
.. code-block:: bash
neutron net-create ipv4-int-network1
**SETUP-SVM-9**: Create an IPv4 subnet ``ipv4-int-subnet1`` in the internal network ``ipv4-int-network1``
.. code-block:: bash
neutron subnet-create --name ipv4-int-subnet1 --dns-nameserver 8.8.8.8 ipv4-int-network1 20.0.0.0/24
**SETUP-SVM-10**: Associate the IPv4 internal subnet ``ipv4-int-subnet1`` to the Neutron router ``ipv4-router``.
.. code-block:: bash
neutron router-interface-add ipv4-router ipv4-int-subnet1
********************************************************
Create IPv6 Subnet and Router with External Connectivity
********************************************************
Now, let us create a second neutron router where we can "manually" spawn a ``radvd`` daemon to simulate an external
IPv6 router.
**SETUP-SVM-11**: Create a second Neutron router ``ipv6-router`` which needs to provide external connectivity
.. code-block:: bash
neutron router-create ipv6-router
**SETUP-SVM-12**: Associate the ``ext-net`` to the Neutron router ``ipv6-router``
.. code-block:: bash
# If you use a different installer and it has already created an external work,
# Change the name "ext-net" to match the name of external network that your installer has created
neutron router-gateway-set ipv6-router ext-net
**SETUP-SVM-13**: Create a second internal/tenant IPv4 network ``ipv4-int-network2``
.. code-block:: bash
neutron net-create ipv4-int-network2
**SETUP-SVM-14**: Create an IPv4 subnet ``ipv4-int-subnet2`` for the ``ipv6-router`` internal network
``ipv4-int-network2``
.. code-block:: bash
neutron subnet-create --name ipv4-int-subnet2 --dns-nameserver 8.8.8.8 ipv4-int-network2 10.0.0.0/24
**SETUP-SVM-15**: Associate the IPv4 internal subnet ``ipv4-int-subnet2`` to the Neutron router ``ipv6-router``.
.. code-block:: bash
neutron router-interface-add ipv6-router ipv4-int-subnet2
**************************************************
Prepare Image, Metadata and Keypair for Service VM
**************************************************
**SETUP-SVM-16**: Download ``fedora22`` image which would be used as ``vRouter``
.. code-block:: bash
wget https://download.fedoraproject.org/pub/fedora/linux/releases/22/Cloud/x86_64/Images/Fedora-Cloud-Base-22-20150521.x86_64.qcow2
glance image-create --name 'Fedora22' --disk-format qcow2 --container-format bare --file ./Fedora-Cloud-Base-22-20150521.x86_64.qcow2
**SETUP-SVM-17**: Create a keypair
.. code-block:: bash
nova keypair-add vRouterKey > ~/vRouterKey
**SETUP-SVM-18**: Create ports for ``vRouter`` and both the VMs with some specific MAC addresses.
.. code-block:: bash
neutron port-create --name eth0-vRouter --mac-address fa:16:3e:11:11:11 ipv4-int-network2
neutron port-create --name eth1-vRouter --mac-address fa:16:3e:22:22:22 ipv4-int-network1
neutron port-create --name eth0-VM1 --mac-address fa:16:3e:33:33:33 ipv4-int-network1
neutron port-create --name eth0-VM2 --mac-address fa:16:3e:44:44:44 ipv4-int-network1
**********************************************************************************************************
Boot Service VM (``vRouter``) with ``eth0`` on ``ipv4-int-network2`` and ``eth1`` on ``ipv4-int-network1``
**********************************************************************************************************
Let us boot the service VM (``vRouter``) with ``eth0`` interface on ``ipv4-int-network2`` connecting to ``ipv6-router``,
and ``eth1`` interface on ``ipv4-int-network1`` connecting to ``ipv4-router``.
**SETUP-SVM-19**: Boot the ``vRouter`` using ``Fedora22`` image on the OpenStack Compute Node with hostname
``opnfv-os-compute``
.. code-block:: bash
nova boot --image Fedora22 --flavor m1.small --user-data /opt/stack/opnfv_os_ipv6_poc/metadata.txt --availability-zone nova:opnfv-os-compute --nic port-id=$(neutron port-list | grep -w eth0-vRouter | awk '{print $2}') --nic port-id=$(neutron port-list | grep -w eth1-vRouter | awk '{print $2}') --key-name vRouterKey vRouter
Please **note** that ``/opt/stack/opnfv_os_ipv6_poc/metadata.txt`` is used to enable the ``vRouter`` to automatically
spawn a ``radvd``, and
* Act as an IPv6 vRouter which advertises the RA (Router Advertisements) with prefix
``2001:db8:0:2::/64`` on its internal interface (``eth1``).
* Forward IPv6 traffic from internal interface (``eth1``)
**SETUP-SVM-20**: Verify that ``Fedora22`` image boots up successfully and vRouter has ``ssh`` keys properly injected
.. code-block:: bash
nova list
nova console-log vRouter
Please note that **it may take a few minutes** for the necessary packages to get installed and ``ssh`` keys
to be injected.
.. code-block:: bash
# Sample Output
[ 762.884523] cloud-init[871]: ec2: #############################################################
[ 762.909634] cloud-init[871]: ec2: -----BEGIN SSH HOST KEY FINGERPRINTS-----
[ 762.931626] cloud-init[871]: ec2: 2048 e3:dc:3d:4a:bc:b6:b0:77:75:a1:70:a3:d0:2a:47:a9 (RSA)
[ 762.957380] cloud-init[871]: ec2: -----END SSH HOST KEY FINGERPRINTS-----
[ 762.979554] cloud-init[871]: ec2: #############################################################
*******************************************
Boot Two Other VMs in ``ipv4-int-network1``
*******************************************
In order to verify that the setup is working, let us create two cirros VMs with ``eth1`` interface on the
``ipv4-int-network1``, i.e., connecting to ``vRouter`` ``eth1`` interface for internal network.
We will have to configure appropriate ``mtu`` on the VMs' interface by taking into account the tunneling
overhead and any physical switch requirements. If so, push the ``mtu`` to the VM either using ``dhcp``
options or via ``meta-data``.
**SETUP-SVM-21**: Create VM1 on OpenStack Controller Node with hostname ``opnfv-os-controller``
.. code-block:: bash
nova boot --image cirros-0.3.4-x86_64-uec --flavor m1.tiny --nic port-id=$(neutron port-list | grep -w eth0-VM1 | awk '{print $2}') --availability-zone nova:opnfv-os-controller --key-name vRouterKey --user-data /opt/stack/opnfv_os_ipv6_poc/set_mtu.sh VM1
**SETUP-SVM-22**: Create VM2 on OpenStack Compute Node with hostname ``opnfv-os-compute``
.. code-block:: bash
nova boot --image cirros-0.3.4-x86_64-uec --flavor m1.tiny --nic port-id=$(neutron port-list | grep -w eth0-VM2 | awk '{print $2}') --availability-zone nova:opnfv-os-compute --key-name vRouterKey --user-data /opt/stack/opnfv_os_ipv6_poc/set_mtu.sh VM2
**SETUP-SVM-23**: Confirm that both the VMs are successfully booted.
.. code-block:: bash
nova list
nova console-log VM1
nova console-log VM2
**********************************
Spawn ``RADVD`` in ``ipv6-router``
**********************************
Let us manually spawn a ``radvd`` daemon inside ``ipv6-router`` namespace to simulate an external router.
First of all, we will have to identify the ``ipv6-router`` namespace and move to the namespace.
Please **NOTE** that in case of HA (High Availability) deployment model where multiple controller
nodes are used, ``ipv6-router`` created in step **SETUP-SVM-11** could be in any of the controller
node. Thus you need to identify in which controller node ``ipv6-router`` is created in order to manually
spawn ``radvd`` daemon inside the ``ipv6-router`` namespace in steps **SETUP-SVM-24** through
**SETUP-SVM-30**. The following command in Neutron will display the controller on which the
``ipv6-router`` is spawned.
.. code-block:: bash
neutron l3-agent-list-hosting-router ipv6-router
Then you login to that controller and execute steps **SETUP-SVM-24**
through **SETUP-SVM-30**
**SETUP-SVM-24**: identify the ``ipv6-router`` namespace and move to the namespace
.. code-block:: bash
sudo ip netns exec qrouter-$(neutron router-list | grep -w ipv6-router | awk '{print $2}') bash
**SETUP-SVM-25**: Upon successful execution of the above command, you will be in the router namespace.
Now let us configure the IPv6 address on the <qr-xxx> interface.
.. code-block:: bash
export router_interface=$(ip a s | grep -w "global qr-*" | awk '{print $7}')
ip -6 addr add 2001:db8:0:1::1 dev $router_interface
**SETUP-SVM-26**: Update the sample file ``/opt/stack/opnfv_os_ipv6_poc/scenario2/radvd.conf``
with ``$router_interface``.
.. code-block:: bash
cp /opt/stack/opnfv_os_ipv6_poc/scenario2/radvd.conf /tmp/radvd.$router_interface.conf
sed -i 's/$router_interface/'$router_interface'/g' /tmp/radvd.$router_interface.conf
**SETUP-SVM-27**: Spawn a ``radvd`` daemon to simulate an external router. This ``radvd`` daemon advertises an IPv6
subnet prefix of ``2001:db8:0:1::/64`` using RA (Router Advertisement) on its $router_interface so that ``eth0``
interface of ``vRouter`` automatically configures an IPv6 SLAAC address.
.. code-block:: bash
$radvd -C /tmp/radvd.$router_interface.conf -p /tmp/br-ex.pid.radvd -m syslog
**SETUP-SVM-28**: Add an IPv6 downstream route pointing to the ``eth0`` interface of vRouter.
.. code-block:: bash
ip -6 route add 2001:db8:0:2::/64 via 2001:db8:0:1:f816:3eff:fe11:1111
**SETUP-SVM-29**: The routing table should now look similar to something shown below.
.. code-block:: bash
ip -6 route show
2001:db8:0:1::1 dev qr-42968b9e-62 proto kernel metric 256
2001:db8:0:1::/64 dev qr-42968b9e-62 proto kernel metric 256 expires 86384sec
2001:db8:0:2::/64 via 2001:db8:0:1:f816:3eff:fe11:1111 dev qr-42968b9e-62 proto ra metric 1024 expires 29sec
fe80::/64 dev qg-3736e0c7-7c proto kernel metric 256
fe80::/64 dev qr-42968b9e-62 proto kernel metric 256
**SETUP-SVM-30**: If all goes well, the IPv6 addresses assigned to the VMs would be as shown as follows:
.. code-block:: bash
vRouter eth0 interface would have the following IPv6 address: 2001:db8:0:1:f816:3eff:fe11:1111/64
vRouter eth1 interface would have the following IPv6 address: 2001:db8:0:2::1/64
VM1 would have the following IPv6 address: 2001:db8:0:2:f816:3eff:fe33:3333/64
VM2 would have the following IPv6 address: 2001:db8:0:2:f816:3eff:fe44:4444/64
********************************
Testing to Verify Setup Complete
********************************
Now, let us ``SSH`` to those VMs, e.g. VM1 and / or VM2 and / or vRouter, to confirm that
it has successfully configured the IPv6 address using ``SLAAC`` with prefix
``2001:db8:0:2::/64`` from ``vRouter``.
We use ``floatingip`` mechanism to achieve ``SSH``.
**SETUP-SVM-31**: Now we can ``SSH`` to VMs. You can execute the following command.
.. code-block:: bash
# 1. Create a floatingip and associate it with VM1, VM2 and vRouter (to the port id that is passed).
# If you use a different installer and it has already created an external work,
# Change the name "ext-net" to match the name of external network that your installer has created
neutron floatingip-create --port-id $(neutron port-list | grep -w eth0-VM1 | \
awk '{print $2}') ext-net
neutron floatingip-create --port-id $(neutron port-list | grep -w eth0-VM2 | \
awk '{print $2}') ext-net
neutron floatingip-create --port-id $(neutron port-list | grep -w eth1-vRouter | \
awk '{print $2}') ext-net
# 2. To know / display the floatingip associated with VM1, VM2 and vRouter.
neutron floatingip-list -F floating_ip_address -F port_id | grep $(neutron port-list | \
grep -w eth0-VM1 | awk '{print $2}') | awk '{print $2}'
neutron floatingip-list -F floating_ip_address -F port_id | grep $(neutron port-list | \
grep -w eth0-VM2 | awk '{print $2}') | awk '{print $2}'
neutron floatingip-list -F floating_ip_address -F port_id | grep $(neutron port-list | \
grep -w eth1-vRouter | awk '{print $2}') | awk '{print $2}'
# 3. To ssh to the vRouter, VM1 and VM2, user can execute the following command.
ssh -i ~/vRouterKey fedora@<floating-ip-of-vRouter>
ssh -i ~/vRouterKey cirros@<floating-ip-of-VM1>
ssh -i ~/vRouterKey cirros@<floating-ip-of-VM2>
If everything goes well, ``ssh`` will be successful and you will be logged into those VMs.
Run some commands to verify that IPv6 addresses are configured on ``eth0`` interface.
**SETUP-SVM-32**: Show an IPv6 address with a prefix of ``2001:db8:0:2::/64``
.. code-block:: bash
ip address show
**SETUP-SVM-33**: ping some external IPv6 address, e.g. ``ipv6-router``
.. code-block:: bash
ping6 2001:db8:0:1::1
If the above ping6 command succeeds, it implies that ``vRouter`` was able to successfully forward the IPv6 traffic
to reach external ``ipv6-router``.
**********
Next Steps
**********
Congratulations, you have completed the setup of using a service VM to act as an IPv6 vRouter. This setup allows further
open innovation by any 3rd-party. Please refer to relevant sections in User's Guide for further value-added services on
this IPv6 vRouter.
|