Open vSwitch: Provider networks

Open vSwitch: Provider networks

This architecture example provides layer-2 connectivity between instances and the physical network infrastructure using VLAN (802.1q) tagging. It supports one untagged (flat) network and up to 4095 tagged (VLAN) networks. The actual quantity of VLAN networks depends on the physical network infrastructure. For more information on provider networks, see Provider networks.

Warning

Linux distributions often package older releases of Open vSwitch that can introduce issues during operation with the Networking service. We recommend using at least the latest long-term stable (LTS) release of Open vSwitch for the best experience and support from Open vSwitch. See http://www.openvswitch.org for available releases and the installation instructions for

Prerequisites

One controller node with the following components:

  • Two network interfaces: management and provider.
  • OpenStack Networking server service and ML2 plug-in.

Two compute nodes with the following components:

  • Two network interfaces: management and provider.
  • OpenStack Networking Open vSwitch (OVS) layer-2 agent, DHCP agent, metadata agent, and any dependencies including OVS.

Note

Larger deployments typically deploy the DHCP and metadata agents on a subset of compute nodes to increase performance and redundancy. However, too many agents can overwhelm the message bus. Also, to further simplify any deployment, you can omit the metadata agent and use a configuration drive to provide metadata to instances.

Architecture

Provider networks using OVS - overview

The following figure shows components and connectivity for one untagged (flat) 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 with a port on the OVS integration bridge.

Provider networks using OVS - components and connectivity - one network

The following figure describes virtual connectivity among components for two tagged (VLAN) networks. Essentially, all networks use a single OVS integration bridge with different internal VLAN tags. The internal VLAN tags almost always differ from the network VLAN assignment in the Networking service. Similar to the untagged network case, the DHCP agent may reside on a different compute node.

Provider networks using OVS - components and connectivity - multiple networks

Note

These figures omit the controller node because it does not handle instance network traffic.

Example configuration

Use the following example configuration as a template to deploy provider networks in your environment.

Controller node

  1. Install the Networking service components that provide the neutron-server service and ML2 plug-in.

  2. 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.

    • Disable service plug-ins because provider networks do not require any. However, this breaks portions of the dashboard that manage the Networking service. See the Newton Install Tutorials and Guides for more information.

      [DEFAULT]
      service_plugins =
      
    • Enable two DHCP agents per network so both compute nodes can provide DHCP service provider networks.

      [DEFAULT]
      dhcp_agents_per_network = 2
      
    • If necessary, configure MTU.

  3. In the ml2_conf.ini file:

    • Configure drivers and network types:

      [ml2]
      type_drivers = flat,vlan
      tenant_network_types =
      mechanism_drivers = openvswitch
      extension_drivers = port_security
      
    • Configure network mappings:

      [ml2_type_flat]
      flat_networks = provider
      
      [ml2_type_vlan]
      network_vlan_ranges = provider
      

      Note

      The tenant_network_types option contains no value because the architecture does not support self-service networks.

      Note

      The provider value in the network_vlan_ranges option lacks VLAN ID ranges to support use of arbitrary VLAN IDs.

  4. Populate the database.

    # su -s /bin/sh -c "neutron-db-manage --config-file /etc/neutron/neutron.conf \
      --config-file /etc/neutron/plugins/ml2/ml2_conf.ini upgrade head" neutron
    
  5. Start the following services:

    • Server

Compute nodes

  1. Install the Networking service OVS layer-2 agent, DHCP agent, and metadata agent.

  2. Install OVS.

  3. 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.

  4. In the openvswitch_agent.ini file, configure the OVS agent:

    [ovs]
    bridge_mappings = provider:br-provider
    
    [securitygroup]
    firewall_driver = iptables_hybrid
    
  5. In the dhcp_agent.ini file, configure the DHCP agent:

    [DEFAULT]
    interface_driver = openvswitch
    enable_isolated_metadata = True
    force_metadata = True
    

    Note

    The force_metadata option forces the DHCP agent to provide a host route to the metadata service on 169.254.169.254 regardless of whether the subnet contains an interface on a router, thus maintaining similar and predictable metadata behavior among subnets.

  6. In the metadata_agent.ini file, configure the metadata agent:

    [DEFAULT]
    nova_metadata_ip = controller
    metadata_proxy_shared_secret = METADATA_SECRET
    

    The value of METADATA_SECRET must match the value of the same option in the [neutron] section of the nova.conf file.

  7. Start the following services:

    • OVS
  8. Create the OVS provider bridge br-provider:

    $ ovs-vsctl add-br br-provider
    
  9. 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.

  10. Start the following services:

    • OVS agent
    • DHCP agent
    • Metadata agent

Verify service operation

  1. Source the administrative project credentials.

  2. 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        |
    | 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 |
    +--------------------------------------+--------------------+----------+-------------------+-------+-------+---------------------------+
    

Create initial networks

The configuration supports one flat or multiple VLAN provider networks. For simplicity, the following procedure creates one flat provider network.

  1. Source the administrative project credentials.

  2. Create a flat network.

    $ openstack network create --share --provider-physical-network provider \
      --provider-network-type flat provider1
    +---------------------------+-----------+-
    | Field                     | Value     |
    +---------------------------+-----------+
    | admin_state_up            | UP        |
    | mtu                       | 1500      |
    | name                      | provider1 |
    | port_security_enabled     | True      |
    | provider:network_type     | flat      |
    | provider:physical_network | provider  |
    | provider:segmentation_id  | None      |
    | router:external           | Internal  |
    | shared                    | True      |
    | status                    | ACTIVE    |
    +---------------------------+-----------+
    

    Note

    The share option allows any project to use this network. To limit access to provider networks, see Role-Based Access Control (RBAC).

    Note

    To create a VLAN network instead of a flat network, change --provider:network_type flat to --provider-network-type vlan and add --provider-segment with a value referencing the VLAN ID.

  3. Create a IPv4 subnet on the provider network.

    $ openstack subnet create --subnet-range 203.0.113.0/24 --gateway 203.0.113.1 \
      --network provider1 --allocation-pool start=203.0.113.11,end=203.0.113.250 \
      --dns-nameserver 8.8.4.4 provider1-v4
    +-------------------+----------------------------+
    | Field             | Value                      |
    +-------------------+----------------------------+
    | allocation_pools  | 203.0.113.11-203.0.113.250 |
    | cidr              | 203.0.113.0/24             |
    | dns_nameservers   | 8.8.4.4                    |
    | enable_dhcp       | True                       |
    | gateway_ip        | 203.0.113.1                |
    | ip_version        | 4                          |
    | name              | provider1-v4               |
    +-------------------+----------------------------+
    

    Note

    Enabling DHCP causes the Networking service to provide DHCP which can interfere with existing DHCP services on the physical network infrastructure.

  4. Create a IPv6 subnet on the provider network.

    $ openstack subnet create --subnet-range fd00:203:0:113::/64 --gateway fd00:203:0:113::1 \
      --ip-version 6 --ipv6-address-mode slaac --network provider1 \
      --dns-nameserver 2001:4860:4860::8844 provider1-v6
    +-------------------+------------------------------------------------------+
    | Field             | Value                                                |
    +-------------------+------------------------------------------------------+
    | allocation_pools  | fd00:203:0:113::2-fd00:203:0:113:ffff:ffff:ffff:ffff |
    | cidr              | fd00:203:0:113::/64                                  |
    | dns_nameservers   | 2001:4860:4860::8844                                 |
    | enable_dhcp       | True                                                 |
    | gateway_ip        | fd00:203:0:113::1                                    |
    | ip_version        | 6                                                    |
    | ipv6_address_mode | slaac                                                |
    | ipv6_ra_mode      | None                                                 |
    | name              | provider1-v6                                         |
    +-------------------+------------------------------------------------------+
    

    Note

    The Networking service uses the layer-3 agent to provide router advertisement. Provider networks rely on physical network infrastructure for layer-3 services rather than the layer-3 agent. Thus, the physical network infrastructure must provide router advertisement on provider networks for proper operation of IPv6.

Verify network operation

  1. On each compute node, verify creation of the qdhcp namespace.

    # ip netns
    qdhcp-8b868082-e312-4110-8627-298109d4401c
    
  2. Source a regular (non-administrative) project credentials.

  3. 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       |
    +------------------+-----------+
    
  4. Launch an instance with an interface on the provider network. For example, a CirrOS image using flavor ID 1.

    $ openstack server create --flavor 1 --image cirros \
      --nic net-id=NETWORK_ID provider-instance1
    

    Replace NETWORK_ID with the ID of the provider network.

  5. Determine the IPv4 and IPv6 addresses of the instance.

    $ openstack server list
    +--------------------------------------+--------------------+--------+------------------------------------------------------------+------------+
    | ID                                   | Name               | Status | Networks                                                   | Image Name |
    +--------------------------------------+--------------------+--------+------------------------------------------------------------+------------+
    | 018e0ae2-b43c-4271-a78d-62653dd03285 | provider-instance1 | ACTIVE | provider1=203.0.113.13, fd00:203:0:113:f816:3eff:fe58:be4e | cirros     |
    +--------------------------------------+--------------------+--------+------------------------------------------------------------+------------+
    
  6. On the controller node or any host with access to the provider network, ping the IPv4 and IPv6 addresses of the instance.

    $ ping -c 4 203.0.113.13
    PING 203.0.113.13 (203.0.113.13) 56(84) bytes of data.
    64 bytes from 203.0.113.13: icmp_req=1 ttl=63 time=3.18 ms
    64 bytes from 203.0.113.13: icmp_req=2 ttl=63 time=0.981 ms
    64 bytes from 203.0.113.13: icmp_req=3 ttl=63 time=1.06 ms
    64 bytes from 203.0.113.13: icmp_req=4 ttl=63 time=0.929 ms
    
    --- 203.0.113.13 ping statistics ---
    4 packets transmitted, 4 received, 0% packet loss, time 3002ms
    rtt min/avg/max/mdev = 0.929/1.539/3.183/0.951 ms
    
    $ ping6 -c 4 fd00:203:0:113:f816:3eff:fe58:be4e
    PING fd00:203:0:113:f816:3eff:fe58:be4e(fd00:203:0:113:f816:3eff:fe58:be4e) 56 data bytes
    64 bytes from fd00:203:0:113:f816:3eff:fe58:be4e icmp_seq=1 ttl=64 time=1.25 ms
    64 bytes from fd00:203:0:113:f816:3eff:fe58:be4e icmp_seq=2 ttl=64 time=0.683 ms
    64 bytes from fd00:203:0:113:f816:3eff:fe58:be4e icmp_seq=3 ttl=64 time=0.762 ms
    64 bytes from fd00:203:0:113:f816:3eff:fe58:be4e icmp_seq=4 ttl=64 time=0.486 ms
    
    --- fd00:203:0:113:f816:3eff:fe58:be4e ping statistics ---
    4 packets transmitted, 4 received, 0% packet loss, time 2999ms
    rtt min/avg/max/mdev = 0.486/0.796/1.253/0.282 ms
    
  7. Obtain access to the instance.

  8. Test IPv4 and IPv6 connectivity to the Internet or other external network.

Network traffic flow

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:

  • Provider network 1 (VLAN)
    • VLAN ID 101 (tagged)
    • IP address ranges 203.0.113.0/24 and fd00:203:0:113::/64
    • Gateway (via physical network infrastructure)
      • IP addresses 203.0.113.1 and fd00:203:0:113:0::1
  • Provider network 2 (VLAN)
    • VLAN ID 102 (tagged)
    • IP address range 192.0.2.0/24 and fd00:192:0:2::/64
    • Gateway
      • IP addresses 192.0.2.1 and fd00:192:0:2::1
  • Instance 1
    • IP addresses 203.0.113.101 and fd00:203:0:113:0::101
  • Instance 2
    • IP addresses 192.0.2.101 and fd00:192:0:2:0::101

North-south

  • The instance resides on compute node 1 and uses provider network 1.
  • The instance sends a packet to a host on the Internet.

The following steps involve compute node 1.

  1. The instance interface (1) forwards the packet to the security group bridge instance port (2) via veth pair.
  2. Security group rules (3) on the security group bridge handle firewalling and connection tracking for the packet.
  3. The security group bridge OVS port (4) forwards the packet to the OVS integration bridge security group port (5) via veth pair.
  4. The OVS integration bridge adds an internal VLAN tag to the packet.
  5. The OVS integration bridge int-br-provider patch port (6) forwards the packet to the OVS provider bridge phy-br-provider patch port (7).
  6. The OVS provider bridge swaps the internal VLAN tag with actual VLAN tag 101.
  7. The OVS provider bridge provider network port (8) forwards the packet to the physical network interface (9).
  8. The physical network interface forwards the packet to the physical network infrastructure switch (10).

The following steps involve the physical network infrastructure:

  1. The switch removes VLAN tag 101 from the packet and forwards it to the router (11).
  2. The router routes the packet from the provider network (12) to the external network (13) and forwards the packet to the switch (14).
  3. The switch forwards the packet to the external network (15).
  4. The external network (16) receives the packet.
Provider networks using Open vSwitch - network traffic flow - north/south

Note

Return traffic follows similar steps in reverse.

East-west scenario 1: Instances on the same network

Instances on the same network communicate directly between compute nodes containing those instances.

  • Instance 1 resides on compute node 1 and uses provider network 1.
  • Instance 2 resides on compute node 2 and uses provider network 1.
  • Instance 1 sends a packet to instance 2.

The following steps involve compute node 1:

  1. The instance 1 interface (1) forwards the packet to the security group bridge instance port (2) via veth pair.
  2. Security group rules (3) on the security group bridge handle firewalling and connection tracking for the packet.
  3. The security group bridge OVS port (4) forwards the packet to the OVS integration bridge security group port (5) via veth pair.
  4. The OVS integration bridge adds an internal VLAN tag to the packet.
  5. The OVS integration bridge int-br-provider patch port (6) forwards the packet to the OVS provider bridge phy-br-provider patch port (7).
  6. The OVS provider bridge swaps the internal VLAN tag with actual VLAN tag 101.
  7. The OVS provider bridge provider network port (8) forwards the packet to the physical network interface (9).
  8. The physical network interface forwards the packet to the physical network infrastructure switch (10).

The following steps involve the physical network infrastructure:

  1. The switch forwards the packet from compute node 1 to compute node 2 (11).

The following steps involve compute node 2:

  1. The physical network interface (12) forwards the packet to the OVS provider bridge provider network port (13).
  2. The OVS provider bridge phy-br-provider patch port (14) forwards the packet to the OVS integration bridge int-br-provider patch port (15).
  3. The OVS integration bridge swaps the actual VLAN tag 101 with the internal VLAN tag.
  4. The OVS integration bridge security group port (16) forwards the packet to the security group bridge OVS port (17).
  5. Security group rules (18) on the security group bridge handle firewalling and connection tracking for the packet.
  6. The security group bridge instance port (19) forwards the packet to the instance 2 interface (20) via veth pair.
Provider networks using Open vSwitch - network traffic flow - east/west scenario 1

Note

Return traffic follows similar steps in reverse.

East-west scenario 2: Instances on different networks

Instances communicate via router on the physical network infrastructure.

  • Instance 1 resides on compute node 1 and uses provider network 1.
  • Instance 2 resides on compute node 1 and uses provider network 2.
  • Instance 1 sends a packet to instance 2.

Note

Both instances reside on the same compute node to illustrate how VLAN tagging enables multiple logical layer-2 networks to use the same physical layer-2 network.

The following steps involve the compute node:

  1. The instance 1 interface (1) forwards the packet to the security group bridge instance port (2) via veth pair.
  2. Security group rules (3) on the security group bridge handle firewalling and connection tracking for the packet.
  3. The security group bridge OVS port (4) forwards the packet to the OVS integration bridge security group port (5) via veth pair.
  4. The OVS integration bridge adds an internal VLAN tag to the packet.
  5. The OVS integration bridge int-br-provider patch port (6) forwards the packet to the OVS provider bridge phy-br-provider patch port (7).
  6. The OVS provider bridge swaps the internal VLAN tag with actual VLAN tag 101.
  7. The OVS provider bridge provider network port (8) forwards the packet to the physical network interface (9).
  8. The physical network interface forwards the packet to the physical network infrastructure switch (10).

The following steps involve the physical network infrastructure:

  1. The switch removes VLAN tag 101 from the packet and forwards it to the router (11).
  2. The router routes the packet from provider network 1 (12) to provider network 2 (13).
  3. The router forwards the packet to the switch (14).
  4. The switch adds VLAN tag 102 to the packet and forwards it to compute node 1 (15).

The following steps involve the compute node:

  1. The physical network interface (16) forwards the packet to the OVS provider bridge provider network port (17).
  2. The OVS provider bridge phy-br-provider patch port (18) forwards the packet to the OVS integration bridge int-br-provider patch port (19).
  3. The OVS integration bridge swaps the actual VLAN tag 102 with the internal VLAN tag.
  4. The OVS integration bridge security group port (20) removes the internal VLAN tag and forwards the packet to the security group bridge OVS port (21).
  5. Security group rules (22) on the security group bridge handle firewalling and connection tracking for the packet.
  6. The security group bridge instance port (23) forwards the packet to the instance 2 interface (24) via veth pair.
Provider networks using Open vSwitch - network traffic flow - east/west scenario 2

Note

Return traffic follows similar steps in reverse.

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