This architecture example augments Open vSwitch: Provider networks to support a nearly limitless quantity of entirely virtual networks. Although the Networking service supports VLAN self-service networks, this example focuses on VXLAN self-service networks. For more information on self-service networks, see Self-service networks.
Add one network node with the following components:
Modify the compute nodes with the following components:
Note
You can keep the DHCP and metadata agents on each compute node or move them to the network node.
The following figure shows components and connectivity for one self-service network and one untagged (flat) provider network. In this particular case, the instance resides on the same compute node as the DHCP agent for the network. If the DHCP agent resides on another compute node, the latter only contains a DHCP namespace and with a port on the OVS integration bridge.
Use the following example configuration as a template to add support for self-service networks to an existing operational environment that supports provider networks.
In the neutron.conf
file:
Enable routing and allow overlapping IP address ranges.
[DEFAULT]
service_plugins = router
allow_overlapping_ips = True
In the ml2_conf.ini
file:
Add vxlan
to type drivers and project network types.
[ml2]
type_drivers = flat,vlan,vxlan
tenant_network_types = vxlan
Enable the layer-2 population mechanism driver.
[ml2]
mechanism_drivers = openvswitch,l2population
Configure the VXLAN network ID (VNI) range.
[ml2_type_vxlan]
vni_ranges = VNI_START:VNI_END
Replace VNI_START
and VNI_END
with appropriate numerical
values.
Restart the following services:
Install the Networking service OVS layer-2 agent and layer-3 agent.
Install OVS.
In the neutron.conf
file, configure common options:
[DEFAULT]
core_plugin = ml2
auth_strategy = keystone
[database]
# ...
[keystone_authtoken]
# ...
[nova]
# ...
[agent]
# ...
See the Installation Tutorials and Guides and
Configuration Reference for your OpenStack
release to obtain the appropriate additional configuration for the
[DEFAULT]
, [database]
, [keystone_authtoken]
, [nova]
, and
[agent]
sections.
Start the following services:
Create the OVS provider bridge br-provider
:
$ ovs-vsctl add-br br-provider
Add the provider network interface as a port on the OVS provider
bridge br-provider
:
$ ovs-vsctl add-port br-provider PROVIDER_INTERFACE
Replace PROVIDER_INTERFACE
with the name of the underlying interface
that handles provider networks. For example, eth1
.
In the openvswitch_agent.ini
file, configure the layer-2 agent.
[ovs]
bridge_mappings = provider:br-provider
local_ip = OVERLAY_INTERFACE_IP_ADDRESS
[agent]
tunnel_types = vxlan
l2_population = True
[securitygroup]
firewall_driver = iptables_hybrid
Replace OVERLAY_INTERFACE_IP_ADDRESS
with the IP address of the
interface that handles VXLAN overlays for self-service networks.
In the l3_agent.ini
file, configure the layer-3 agent.
[DEFAULT]
interface_driver = openvswitch
external_network_bridge =
Note
The external_network_bridge
option intentionally contains
no value.
Start the following services:
In the openvswitch_agent.ini
file, enable VXLAN support including
layer-2 population.
[ovs]
local_ip = OVERLAY_INTERFACE_IP_ADDRESS
[agent]
tunnel_types = vxlan
l2_population = True
Replace OVERLAY_INTERFACE_IP_ADDRESS
with the IP address of the
interface that handles VXLAN overlays for self-service networks.
Restart the following services:
Source the administrative project credentials.
Verify presence and operation of the agents.
$ openstack network agent list
+--------------------------------------+--------------------+----------+-------------------+-------+-------+---------------------------+
| ID | Agent Type | Host | Availability Zone | Alive | State | Binary |
+--------------------------------------+--------------------+----------+-------------------+-------+-------+---------------------------+
| 1236bbcb-e0ba-48a9-80fc-81202ca4fa51 | Metadata agent | compute2 | | True | UP | neutron-metadata-agent |
| 457d6898-b373-4bb3-b41f-59345dcfb5c5 | Open vSwitch agent | compute2 | | True | UP | neutron-openvswitch-agent |
| 71f15e84-bc47-4c2a-b9fb-317840b2d753 | DHCP agent | compute2 | nova | True | UP | neutron-dhcp-agent |
| 8805b962-de95-4e40-bdc2-7a0add7521e8 | L3 agent | network1 | nova | True | UP | neutron-l3-agent |
| a33cac5a-0266-48f6-9cac-4cef4f8b0358 | Open vSwitch agent | network1 | | True | UP | neutron-openvswitch-agent |
| a6c69690-e7f7-4e56-9831-1282753e5007 | Metadata agent | compute1 | | True | UP | neutron-metadata-agent |
| af11f22f-a9f4-404f-9fd8-cd7ad55c0f68 | DHCP agent | compute1 | nova | True | UP | neutron-dhcp-agent |
| bcfc977b-ec0e-4ba9-be62-9489b4b0e6f1 | Open vSwitch agent | compute1 | | True | UP | neutron-openvswitch-agent |
+--------------------------------------+--------------------+----------+-------------------+-------+-------+---------------------------+
The configuration supports multiple VXLAN self-service networks. For simplicity, the following procedure creates one self-service network and a router with a gateway on the flat provider network. The router uses NAT for IPv4 network traffic and directly routes IPv6 network traffic.
Note
IPv6 connectivity with self-service networks often requires addition of static routes to nodes and physical network infrastructure.
Source the administrative project credentials.
Update the provider network to support external connectivity for self-service networks.
$ openstack network set --external provider1
Note
This command provides no output.
Source a regular (non-administrative) project credentials.
Create a self-service network.
$ openstack network create selfservice1
+-------------------------+--------------+
| Field | Value |
+-------------------------+--------------+
| admin_state_up | UP |
| mtu | 1450 |
| name | selfservice1 |
| port_security_enabled | True |
| router:external | Internal |
| shared | False |
| status | ACTIVE |
+-------------------------+--------------+
Create a IPv4 subnet on the self-service network.
$ openstack subnet create --subnet-range 192.0.2.0/24 \
--network selfservice1 --dns-nameserver 8.8.4.4 selfservice1-v4
+-------------------+---------------------------+
| Field | Value |
+-------------------+---------------------------+
| allocation_pools | 192.0.2.2-192.0.2.254 |
| cidr | 192.0.2.0/24 |
| dns_nameservers | 8.8.4.4 |
| enable_dhcp | True |
| gateway_ip | 192.0.2.1 |
| ip_version | 4 |
| name | selfservice1-v4 |
+-------------------+---------------------------+
Create a IPv6 subnet on the self-service network.
$ openstack subnet create --subnet-range fd00:192:0:2::/64 --ip-version 6 \
--ipv6-ra-mode slaac --ipv6-address-mode slaac --network selfservice1 \
--dns-nameserver 2001:4860:4860::8844 selfservice1-v6
+-------------------+------------------------------------------------------+
| Field | Value |
+-------------------+------------------------------------------------------+
| allocation_pools | fd00:192:0:2::2-fd00:192:0:2:ffff:ffff:ffff:ffff |
| cidr | fd00:192:0:2::/64 |
| dns_nameservers | 2001:4860:4860::8844 |
| enable_dhcp | True |
| gateway_ip | fd00:192:0:2::1 |
| ip_version | 6 |
| ipv6_address_mode | slaac |
| ipv6_ra_mode | slaac |
| name | selfservice1-v6 |
+-------------------+------------------------------------------------------+
Create a router.
$ openstack router create router1
+-----------------------+---------+
| Field | Value |
+-----------------------+---------+
| admin_state_up | UP |
| name | router1 |
| status | ACTIVE |
+-----------------------+---------+
Add the IPv4 and IPv6 subnets as interfaces on the router.
$ openstack router add subnet router1 selfservice1-v4
$ openstack router add subnet router1 selfservice1-v6
Note
These commands provide no output.
Add the provider network as the gateway on the router.
$ openstack router set --external-gateway provider1 router1
On each compute node, verify creation of a second qdhcp
namespace.
# ip netns
qdhcp-8b868082-e312-4110-8627-298109d4401c
qdhcp-8fbc13ca-cfe0-4b8a-993b-e33f37ba66d1
On the network node, verify creation of the qrouter
namespace.
# ip netns
qrouter-17db2a15-e024-46d0-9250-4cd4d336a2cc
Source a regular (non-administrative) project credentials.
Create the appropriate security group rules to allow ping
and SSH
access instances using the network.
$ openstack security group rule create --proto icmp default
+------------------+-----------+
| Field | Value |
+------------------+-----------+
| direction | ingress |
| ethertype | IPv4 |
| protocol | icmp |
| remote_ip_prefix | 0.0.0.0/0 |
+------------------+-----------+
$ openstack security group rule create --ethertype IPv6 --proto ipv6-icmp default
+-----------+-----------+
| Field | Value |
+-----------+-----------+
| direction | ingress |
| ethertype | IPv6 |
| protocol | ipv6-icmp |
+-----------+-----------+
$ openstack security group rule create --proto tcp --dst-port 22 default
+------------------+-----------+
| Field | Value |
+------------------+-----------+
| direction | ingress |
| ethertype | IPv4 |
| port_range_max | 22 |
| port_range_min | 22 |
| protocol | tcp |
| remote_ip_prefix | 0.0.0.0/0 |
+------------------+-----------+
$ openstack security group rule create --ethertype IPv6 --proto tcp --dst-port 22 default
+------------------+-----------+
| Field | Value |
+------------------+-----------+
| direction | ingress |
| ethertype | IPv6 |
| port_range_max | 22 |
| port_range_min | 22 |
| protocol | tcp |
+------------------+-----------+
Launch an instance with an interface on the self-service network. For example, a CirrOS image using flavor ID 1.
$ openstack server create --flavor 1 --image cirros --nic net-id=NETWORK_ID selfservice-instance1
Replace NETWORK_ID
with the ID of the self-service network.
Determine the IPv4 and IPv6 addresses of the instance.
$ openstack server list
+--------------------------------------+-----------------------+--------+--------------------------------------------------------------+
| ID | Name | Status | Networks |
+--------------------------------------+-----------------------+--------+--------------------------------------------------------------+
| c055cdb0-ebb4-4d65-957c-35cbdbd59306 | selfservice-instance1 | ACTIVE | selfservice1=192.0.2.4, fd00:192:0:2:f816:3eff:fe30:9cb0 |
+--------------------------------------+-----------------------+--------+--------------------------------------------------------------+
Warning
The IPv4 address resides in a private IP address range (RFC1918). Thus, the Networking service performs source network address translation (SNAT) for the instance to access external networks such as the Internet. Access from external networks such as the Internet to the instance requires a floating IPv4 address. The Networking service performs destination network address translation (DNAT) from the floating IPv4 address to the instance IPv4 address on the self-service network. On the other hand, the Networking service architecture for IPv6 lacks support for NAT due to the significantly larger address space and complexity of NAT. Thus, floating IP addresses do not exist for IPv6 and the Networking service only performs routing for IPv6 subnets on self-service networks. In other words, you cannot rely on NAT to “hide” instances with IPv4 and IPv6 addresses or only IPv6 addresses and must properly implement security groups to restrict access.
On the controller node or any host with access to the provider network,
ping
the IPv6 address of the instance.
$ ping6 -c 4 fd00:192:0:2:f816:3eff:fe30:9cb0
PING fd00:192:0:2:f816:3eff:fe30:9cb0(fd00:192:0:2:f816:3eff:fe30:9cb0) 56 data bytes
64 bytes from fd00:192:0:2:f816:3eff:fe30:9cb0: icmp_seq=1 ttl=63 time=2.08 ms
64 bytes from fd00:192:0:2:f816:3eff:fe30:9cb0: icmp_seq=2 ttl=63 time=1.88 ms
64 bytes from fd00:192:0:2:f816:3eff:fe30:9cb0: icmp_seq=3 ttl=63 time=1.55 ms
64 bytes from fd00:192:0:2:f816:3eff:fe30:9cb0: icmp_seq=4 ttl=63 time=1.62 ms
--- fd00:192:0:2:f816:3eff:fe30:9cb0 ping statistics ---
4 packets transmitted, 4 received, 0% packet loss, time 3004ms
rtt min/avg/max/mdev = 1.557/1.788/2.085/0.217 ms
Optionally, enable IPv4 access from external networks such as the Internet to the instance.
Create a floating IPv4 address on the provider network.
$ openstack floating ip create provider1
+-------------+--------------------------------------+
| Field | Value |
+-------------+--------------------------------------+
| fixed_ip | None |
| id | 22a1b088-5c9b-43b4-97f3-970ce5df77f2 |
| instance_id | None |
| ip | 203.0.113.16 |
| pool | provider1 |
+-------------+--------------------------------------+
Associate the floating IPv4 address with the instance.
$ openstack server add floating ip selfservice-instance1 203.0.113.16
Note
This command provides no output.
On the controller node or any host with access to the provider network,
ping
the floating IPv4 address of the instance.
$ ping -c 4 203.0.113.16
PING 203.0.113.16 (203.0.113.16) 56(84) bytes of data.
64 bytes from 203.0.113.16: icmp_seq=1 ttl=63 time=3.41 ms
64 bytes from 203.0.113.16: icmp_seq=2 ttl=63 time=1.67 ms
64 bytes from 203.0.113.16: icmp_seq=3 ttl=63 time=1.47 ms
64 bytes from 203.0.113.16: icmp_seq=4 ttl=63 time=1.59 ms
--- 203.0.113.16 ping statistics ---
4 packets transmitted, 4 received, 0% packet loss, time 3005ms
rtt min/avg/max/mdev = 1.473/2.040/3.414/0.798 ms
Obtain access to the instance.
Test IPv4 and IPv6 connectivity to the Internet or other external network.
The following sections describe the flow of network traffic in several common scenarios. North-south network traffic travels between an instance and external network such as the Internet. East-west network traffic travels between instances on the same or different networks. In all scenarios, the physical network infrastructure handles switching and routing among provider networks and external networks such as the Internet. Each case references one or more of the following components:
For instances with a fixed IPv4 address, the network node performs SNAT on north-south traffic passing from self-service to external networks such as the Internet. For instances with a fixed IPv6 address, the network node performs conventional routing of traffic between self-service and external networks.
The following steps involve compute node 1:
veth
pair.veth
pair.The following steps involve the network node:
int-br-provider
patch port (19) forwards
the packet to the OVS provider bridge phy-br-provider
patch port (20).Note
Return traffic follows similar steps in reverse. However, without a floating IPv4 address, hosts on the provider or external networks cannot originate connections to instances on the self-service network.
For instances with a floating IPv4 address, the network node performs SNAT on north-south traffic passing from the instance to external networks such as the Internet and DNAT on north-south traffic passing from external networks to the instance. Floating IP addresses and NAT do not apply to IPv6. Thus, the network node routes IPv6 traffic in this scenario.
The following steps involve the network node:
phy-br-provider
port (4) forwards the
packet to the OVS integration bridge int-br-provider
port (5).patch-tun
patch port (10) forwards the
packet to the OVS tunnel bridge patch-int
patch port (11).The following steps involve the compute node:
patch-int
patch port (17) forwards the packet
to the OVS integration bridge patch-tun
patch port (18).veth
pair.veth
pair.Note
Egress instance traffic flows similar to north-south scenario 1, except SNAT changes the source IP address of the packet to the floating IPv4 address rather than the router IP address on the provider network.
Instances with a fixed IPv4/IPv6 address or floating IPv4 address on the same network communicate directly between compute nodes containing those instances.
By default, the VXLAN protocol lacks knowledge of target location and uses multicast to discover it. After discovery, it stores the location in the local forwarding database. In large deployments, the discovery process can generate a significant amount of network that all nodes must process. To eliminate the latter and generally increase efficiency, the Networking service includes the layer-2 population mechanism driver that automatically populates the forwarding database for VXLAN interfaces. The example configuration enables this driver. For more information, see ML2 plug-in.
The following steps involve compute node 1:
veth
pair.veth
pair.The following steps involve compute node 2:
patch-int
patch port (13) forwards the packet
to the OVS integration bridge patch-tun
patch port (14).veth
pair.veth
pair.Note
Return traffic follows similar steps in reverse.
Instances using a fixed IPv4/IPv6 address or floating IPv4 address communicate via router on the network node. The self-service networks must reside on the same router.
Note
Both instances reside on the same compute node to illustrate how VXLAN enables multiple overlays to use the same layer-3 network.
The following steps involve the compute node:
veth
pair.veth
pair.patch-tun
patch port (6) forwards the
packet to the OVS tunnel bridge patch-int
patch port (7).The following steps involve the network node:
patch-int
patch port (13) forwards the packet to
the OVS integration bridge patch-tun
patch port (14).patch-tun
patch port (19) forwards the
packet to the OVS tunnel bridge patch-int
patch port (20).The following steps involve the compute node:
patch-int
patch port (26) forwards the packet
to the OVS integration bridge patch-tun
patch port (27).veth
pair.veth
pair.Note
Return traffic follows similar steps in reverse.
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