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Chapter 7. Connecting an instance to the physical network

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This chapter contains information about using provider networks to connect instances directly to an external network.

7.1. Overview of the OpenStack Networking topology

OpenStack Networking (neutron) has two categories of services distributed across a number of node types.

  • Neutron server - This service runs the OpenStack Networking API server, which provides the API for end-users and services to interact with OpenStack Networking. This server also integrates with the underlying database to store and retrieve tenant network, router, and loadbalancer details, among others.
  • Neutron agents - These are the services that perform the network functions for OpenStack Networking:

    • neutron-dhcp-agent - manages DHCP IP addressing for tenant private networks.
    • neutron-l3-agent - performs layer 3 routing between tenant private networks, the external network, and others.
    • neutron-lbaas-agent - provisions the LBaaS routers that tenants create.
  • Compute node - This node hosts the hypervisor that runs the virtual machines, also known as instances. A Compute node must be wired directly to the network in order to provide external connectivity for instances. This node is typically where the l2 agents run, such as neutron-openvswitch-agent.

7.1.1. Service placement

The OpenStack Networking services can either run together on the same physical server, or on separate dedicated servers, which are named according to their roles:

  • Controller node - The server that runs API service.
  • Network node - The server that runs the OpenStack Networking agents.
  • Compute node - The hypervisor server that hosts the instances.

The steps in this chapter apply to an environment that contains these three node types. If your deployment has both the Controller and Network node roles on the same physical node, then you must perform the steps from both sections on that server. This also applies for a High Availability (HA) environment, where all three nodes might be running the Controller node and Network node services with HA. As a result, you must complete the steps in sections applicable to Controller and Network nodes on all three nodes.

7.2. Using flat provider networks

The procedures in this section create flat provider networks that can connect instances directly to external networks. You would do this if you have multiple physical networks (for example, physnet1, physnet2) and separate physical interfaces (eth0 -> physnet1, and eth1 -> physnet2), and you need to connect each Compute node and Network node to those external networks.

Note

If you want to connect multiple VLAN-tagged interfaces (on a single NIC) to multiple provider networks, see Section 7.3, “Using VLAN provider networks”.

7.2.1. Configuring the Controller nodes

1. Edit /etc/neutron/plugin.ini (which is symlinked to /etc/neutron/plugins/ml2/ml2_conf.ini), add flat to the existing list of values, and set flat_networks to *:

type_drivers = vxlan,flat
flat_networks =*

2. Create a flat external network and associate it with the configured physical_network. Create this network as a shared network so that other users can connect their instances directly to it:

# openstack network create --provider-network-type flat --provider-physical-network physnet1 --external public01

3. Create a subnet within this external network using the openstack subnet create command, or the OpenStack Dashboard:

# openstack subnet create --dhcp --allocation-pool start=192.168.100.20,end=192.168.100.100 --gateway 192.168.100.1 --network public01 public_subnet

4. Restart the neutron-server service to apply this change:

 # systemctl restart neutron-server.service

7.2.2. Configuring the Network node and Compute nodes

Complete the following steps on the Network node and the Compute nodes so that these nodes can connect to the external network, and can allow instances to communicate directly with the external network

1. Create the Open vSwitch bridge and port. Run the following command to create the external network bridge (br-ex) and add a corresponding port (eth1)

i. Edit /etc/sysconfig/network-scripts/ifcfg-eth1:

DEVICE=eth1
TYPE=OVSPort
DEVICETYPE=ovs
OVS_BRIDGE=br-ex
ONBOOT=yes
NM_CONTROLLED=no
BOOTPROTO=none

ii. Edit /etc/sysconfig/network-scripts/ifcfg-br-ex:

DEVICE=br-ex
TYPE=OVSBridge
DEVICETYPE=ovs
ONBOOT=yes
NM_CONTROLLED=no
BOOTPROTO=none

2. Restart the network service to apply these changes:

 # systemctl restart network.service

3. Configure the physical networks in /etc/neutron/plugins/ml2/openvswitch_agent.ini and map the bridge to the physical network:

Note

For more information on configuring bridge_mappings, see Chapter 11, Configuring bridge mappings.

bridge_mappings = physnet1:br-ex

4. Restart the neutron-openvswitch-agent service on the Network and Compute nodes to apply these changes:

 # systemctl restart neutron-openvswitch-agent

7.2.3. Configuring the Network node

1. Set the external_network_bridge = parameter to an empty value in /etc/neutron/l3_agent.ini to enable the use of external provider networks.

# Name of bridge used for external network traffic. This should be set to
# empty value for the linux bridge
external_network_bridge =

2. Restart neutron-l3-agent to apply these changes:

 # systemctl restart neutron-l3-agent.service
Note

If you have multiple flat provider networks, ensure that each of them has a separate physical interface and bridge to connect them to the external network. Configure the ifcfg-* scripts appropriately and use a comma-separated list for each network when specifying them in bridge_mappings. For more information on configuring bridge_mappings, see Chapter 11, Configuring bridge mappings.

7.2.4. Connecting an instance to the external network

After you create the external network, you can connect an instance to it and test connectivity:

1. Create a new instance.

2. Use the Networking tab in the dashboard to add the new instance directly to the newly-created external network.

7.2.5. How does the flat provider network packet flow work?

This section describes in detail how traffic flows to and from an instance with flat provider network configuration.

The flow of outgoing traffic in a flat provider network

The following diagram describes the packet flow for traffic leaving an instance and arriving directly at an external network. After you configure the br-ex external bridge, add the physical interface to the bridge, and spawn an instance to a Compute node, the resulting configuration of interfaces and bridges resembles the configuration in the following diagram (if using the iptables_hybrid firewall driver):

flat provider out

1. Packets leave the eth0 interface of the instance and arrive at the linux bridge qbr-xx.

2. Bridge qbr-xx is connected to br-int using veth pair qvb-xx <-> qvo-xxx. This is because the bridge is used to apply the inbound/outbound firewall rules defined by the security group.

3. Interface qvb-xx is connected to the qbr-xx linux bridge, and qvoxx is connected to the br-int Open vSwitch (OVS) bridge.

An example configuration of `qbr-xx`Linux bridge:

 # brctl show
qbr269d4d73-e7		8000.061943266ebb	no		qvb269d4d73-e7
							tap269d4d73-e7

The configuration of qvo-xx on br-int:

 # ovs-vsctl show
  Bridge br-int
        fail_mode: secure
            Interface "qvof63599ba-8f"
        Port "qvo269d4d73-e7"
            tag: 5
            Interface "qvo269d4d73-e7"

Note

Port qvo-xx is tagged with the internal VLAN tag associated with the flat provider network. In this example, the VLAN tag is 5. When the packet reaches qvo-xx, the VLAN tag is appended to the packet header.

The packet is then moved to the br-ex OVS bridge using the patch-peer int-br-ex <-> phy-br-ex.

Example configuration of the patch-peer on br-int:

 # ovs-vsctl show
    Bridge br-int
        fail_mode: secure
       Port int-br-ex
            Interface int-br-ex
                type: patch
                options: {peer=phy-br-ex}

Example configuration of the patch-peer on br-ex:

    Bridge br-ex
        Port phy-br-ex
            Interface phy-br-ex
                type: patch
                options: {peer=int-br-ex}
        Port br-ex
            Interface br-ex
                type: internal

When this packet reaches phy-br-ex on br-ex, an OVS flow inside br-ex strips the VLAN tag (5) and forwards it to the physical interface.

In the following example, the output shows the port number of phy-br-ex as 2.

 # ovs-ofctl show br-ex
OFPT_FEATURES_REPLY (xid=0x2): dpid:00003440b5c90dc6
n_tables:254, n_buffers:256
capabilities: FLOW_STATS TABLE_STATS PORT_STATS QUEUE_STATS ARP_MATCH_IP
actions: OUTPUT SET_VLAN_VID SET_VLAN_PCP STRIP_VLAN SET_DL_SRC SET_DL_DST SET_NW_SRC SET_NW_DST SET_NW_TOS SET_TP_SRC SET_TP_DST ENQUEUE

 2(phy-br-ex): addr:ba:b5:7b:ae:5c:a2
     config:     0
     state:      0
     speed: 0 Mbps now, 0 Mbps max

The following output shows any packet that arrives on phy-br-ex (in_port=2) with a VLAN tag of 5 (dl_vlan=5). In addition, an OVS flow in br-ex strips the VLAN tag and forwards the packet to the physical interface.

# ovs-ofctl dump-flows br-ex
NXST_FLOW reply (xid=0x4):
 cookie=0x0, duration=4703.491s, table=0, n_packets=3620, n_bytes=333744, idle_age=0, priority=1 actions=NORMAL
 cookie=0x0, duration=3890.038s, table=0, n_packets=13, n_bytes=1714, idle_age=3764, priority=4,in_port=2,dl_vlan=5 actions=strip_vlan,NORMAL
 cookie=0x0, duration=4702.644s, table=0, n_packets=10650, n_bytes=447632, idle_age=0, priority=2,in_port=2 actions=drop

If the physical interface is another VLAN-tagged interface, then the physical interface adds the tag to the packet.

The flow of incoming traffic in a flat provider network

This section contains information about the flow of incoming traffic from the external network until it arrives at the interface of the instance.

flat provider in

1. Incoming traffic arrives at eth1 on the physical node.

2. The packet passes to the br-ex bridge.

3. The packet moves to br-int via the patch-peer phy-br-ex <--> int-br-ex.

In the following example, int-br-ex uses port number 15. See the entry containing 15(int-br-ex):

 # ovs-ofctl show br-int
OFPT_FEATURES_REPLY (xid=0x2): dpid:00004e67212f644d
n_tables:254, n_buffers:256
capabilities: FLOW_STATS TABLE_STATS PORT_STATS QUEUE_STATS ARP_MATCH_IP
actions: OUTPUT SET_VLAN_VID SET_VLAN_PCP STRIP_VLAN SET_DL_SRC SET_DL_DST SET_NW_SRC SET_NW_DST SET_NW_TOS SET_TP_SRC SET_TP_DST ENQUEUE
 15(int-br-ex): addr:12:4e:44:a9:50:f4
     config:     0
     state:      0
     speed: 0 Mbps now, 0 Mbps max

Observing the traffic flow on br-int

1. When the packet arrives at int-br-ex, an OVS flow rule within the br-int bridge amends the packet to add the internal VLAN tag 5. See the entry for actions=mod_vlan_vid:5:

 # ovs-ofctl dump-flows br-int
NXST_FLOW reply (xid=0x4):
 cookie=0x0, duration=5351.536s, table=0, n_packets=12118, n_bytes=510456, idle_age=0, priority=1 actions=NORMAL
 cookie=0x0, duration=4537.553s, table=0, n_packets=3489, n_bytes=321696, idle_age=0, priority=3,in_port=15,vlan_tci=0x0000 actions=mod_vlan_vid:5,NORMAL
 cookie=0x0, duration=5350.365s, table=0, n_packets=628, n_bytes=57892, idle_age=4538, priority=2,in_port=15 actions=drop
 cookie=0x0, duration=5351.432s, table=23, n_packets=0, n_bytes=0, idle_age=5351, priority=0 actions=drop

2. The second rule manages packets that arrive on int-br-ex (in_port=15) with no VLAN tag (vlan_tci=0x0000): This rule adds VLAN tag 5 to the packet (actions=mod_vlan_vid:5,NORMAL) and forwards it to qvoxxx.

3. qvoxxx accepts the packet and forwards it to qvbxx, after stripping away the VLAN tag.

4. The packet then reaches the instance.

Note

VLAN tag 5 is an example VLAN that was used on a test Compute node with a flat provider network; this value was assigned automatically by neutron-openvswitch-agent. This value may be different for your own flat provider network, and can differ for the same network on two separate Compute nodes.

7.2.6. Troubleshooting instance-physical network connections on flat provider networks

The output provided in Section 7.2.5, “How does the flat provider network packet flow work?” - provides sufficient debugging information for troubleshooting a flat provider network, should anything go wrong. The following steps contain further information about the troubleshooting process.

1. Review the bridge_mappings:

Verify that the physical network name you use (for example, physnet1) is consistent with the contents of the bridge_mapping configuration as shown in this example:

 # grep bridge_mapping /etc/neutron/plugins/ml2/openvswitch_agent.ini
bridge_mappings = physnet1:br-ex

 # openstack network show provider-flat
...
| provider:physical_network | physnet1
...

2. Review the network configuration:

Confirm that the network is created as external, and uses the flat type:

 # openstack network show provider-flat
...
| provider:network_type     | flat                                 |
| router:external           | True                                 |
...

3. Review the patch-peer:

Run the ovs-vsctl show command, and verify that br-int and br-ex are connected using a patch-peer int-br-ex <--> phy-br-ex.

 # ovs-vsctl show
    Bridge br-int
        fail_mode: secure
       Port int-br-ex
            Interface int-br-ex
                type: patch
                options: {peer=phy-br-ex}

Example configuration of the patch-peer on br-ex:

    Bridge br-ex
        Port phy-br-ex
            Interface phy-br-ex
                type: patch
                options: {peer=int-br-ex}
        Port br-ex
            Interface br-ex
                type: internal

This connection is created when you restart the neutron-openvswitch-agent service, if bridge_mapping is correctly configured in /etc/neutron/plugins/ml2/openvswitch_agent.ini. Re-check the bridge_mapping setting if the connection is not created after you restart the service.

Note

For more information on configuring bridge_mappings, see Chapter 11, Configuring bridge mappings.

4. Review the network flows:

Run ovs-ofctl dump-flows br-ex and ovs-ofctl dump-flows br-int and review whether the flows strip the internal VLAN IDs for outgoing packets, and add VLAN IDs for incoming packets. This flow is first added when you spawn an instance to this network on a specific Compute node.

  • If this flow is not created after spawning the instance, verify that the network is created as flat, is external, and that the physical_network name is correct. In addition, review the bridge_mapping settings.
  • Finally, review the ifcfg-br-ex and ifcfg-ethx configuration. Ensure that ethX is added as a port within br-ex, and that ifcfg-br-ex and ifcfg-ethx have an UP flag in the output of ip a.

The following output shows eth1 is a port in br-ex:

    Bridge br-ex
        Port phy-br-ex
            Interface phy-br-ex
                type: patch
                options: {peer=int-br-ex}
        Port "eth1"
            Interface "eth1"

The following example demonstrates that eth1 is configured as an OVS port, and that the kernel knows to transfer all packets from the interface, and send them to the OVS bridge br-ex. This can be observed in the entry: master ovs-system.

 # ip a
5: eth1: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc mq master ovs-system state UP qlen 1000

7.3. Using VLAN provider networks

To connect multiple VLAN-tagged interfaces on a single NIC to multiple provider networks, complete the steps in this section to create VLAN provider networks that can connect instances directly to external networks.This example uses a physical network called physnet1, with a range of VLANs (171-172). The network nodes and compute nodes are connected to the physical network using physical interface eth1. The switch ports that these interfaces connect to must be configured to trunk the required VLAN ranges. Complete the following procedures to configure the VLAN provider networks using the example VLAN IDs and names.

7.3.1. Configuring the Controller nodes

1. Enable the vlan mechanism driver by editing /etc/neutron/plugin.ini (symlinked to /etc/neutron/plugins/ml2/ml2_conf.ini), and add vlan to the existing list of values:

[ml2]
type_drivers = vxlan,flat,vlan

2. Configure the network_vlan_ranges setting to reflect the physical network and VLAN ranges in use:

[ml2_type_vlan]
network_vlan_ranges=physnet1:171:172

3. Restart the neutron-server service to apply the changes:

systemctl restart neutron-server

4. Create the external networks as type vlan, and associate them with the configured physical_network. Used the --shared when you create the external networks so that other users can connect instances directly. Run the following example command to create two networks: one for VLAN 171, and another for VLAN 172:

openstack network create
			--provider-network-type vlan
			--external
			--provider-physical-network physnet1
			--segment 171
			--share

openstack network create
			--provider-network-type vlan
			--external
			--provider-physical-network physnet1
			--segment 172
			--share

5. Create a number of subnets and configure them to use the external network. You can use either openstack subnet create or the dashboard to create these subnets. Ensure that the external subnet details you have received from your network administrator are correctly associated with each VLAN. In this example, VLAN 171 uses subnet 10.65.217.0/24 and VLAN 172 uses 10.65.218.0/24:

openstack subnet create
			--network provider-171
			--subnet-range 10.65.217.0/24
			--dhcp
			--gateway 10.65.217.254
			--subnet-provider-171

openstack subnet create
			--network provider-172
			--subnet-range 10.65.218.0/24
			--dhcp
			--gateway 10.65.218.254
			--subnet-provider-172

7.3.2. Configuring the Network and Compute nodes

Complete the following steps on the Network node and Compute nodes to connect the nodes to the external network, and permit instances to communicate directly with the external network.

1. Create an external network bridge (br-ex), and associate a port (eth1) with it:

  • This example configures eth1 to use br-ex:
/etc/sysconfig/network-scripts/ifcfg-eth1

DEVICE=eth1
TYPE=OVSPort
DEVICETYPE=ovs
OVS_BRIDGE=br-ex
ONBOOT=yes
NM_CONTROLLED=no
BOOTPROTO=none
  • This example configures the br-ex bridge:
/etc/sysconfig/network-scripts/ifcfg-br-ex:

DEVICE=br-ex
TYPE=OVSBridge
DEVICETYPE=ovs
ONBOOT=yes
NM_CONTROLLED=no
BOOTPROTO=none

2. Reboot the node, or restart the network service to apply the networking changes:

# systemctl restart network

3. Configure the physical networks in /etc/neutron/plugins/ml2/openvswitch_agent.ini and map bridges according to the physical network:

bridge_mappings = physnet1:br-ex
Note

For more information on configuring bridge_mappings, see Chapter 11, Configuring bridge mappings.

4. Restart the neutron-openvswitch-agent service on the network nodes and compute nodes to apply the changes:

systemctl restart neutron-openvswitch-agent

7.3.3. Configuring the Network node

1. Set the external_network_bridge = parameter to an empty value in /etc/neutron/l3_agent.ini so that you can use provider external networks (not bridge based external networks) where you add external_network_bridge = br-ex:

# Name of bridge used for external network traffic. This should be set to
# empty value for the linux bridge
external_network_bridge =

2. Restart neutron-l3-agent to apply the changes.

systemctl restart neutron-l3-agent

3. Create a new instance and use the Networking tab in the dashboard to add the new instance directly to the new external network.

7.3.4. How does the VLAN provider network packet flow work?

This section describes in detail how traffic flows to and from an instance with VLAN provider network configuration.

The flow of outgoing traffic in a VLAN provider network

The following diagram describes the packet flow for traffic leaving an instance and arriving directly to a VLAN provider external network. This example uses two instances attached to the two VLAN networks (171 and 172). After you configure br-ex, add a physical interface to it, and spawn an instance to a Compute node, the resulting configuration of interfaces and bridges resembles the configuration in the following diagram:

vlan provider

1. Packets leaving the eth0 interface of the instance arrive at the linux bridge qbr-xx connected to the instance.

2. qbr-xx is connected to br-int using veth pair qvbxx <→ qvoxxx.

3. qvbxx is connected to the linux bridge qbr-xx and qvoxx is connected to the Open vSwitch bridge br-int.

Example configuration of qbr-xx on the Linux bridge.

This example features two instances and two corresponding linux bridges:

# brctl show
bridge name	bridge id		STP enabled	interfaces
qbr84878b78-63		8000.e6b3df9451e0	no		qvb84878b78-63
							tap84878b78-63

qbr86257b61-5d		8000.3a3c888eeae6	no		qvb86257b61-5d
							tap86257b61-5d

The configuration of qvoxx on br-int:

                options: {peer=phy-br-ex}
        Port "qvo86257b61-5d"
            tag: 3

            Interface "qvo86257b61-5d"
        Port "qvo84878b78-63"
            tag: 2
            Interface "qvo84878b78-63"

  • qvoxx is tagged with the internal VLAN tag associated with the VLAN provider network. In this example, the internal VLAN tag 2 is associated with the VLAN provider network provider-171 and VLAN tag 3 is associated with VLAN provider network provider-172. When the packet reaches qvoxx, the this VLAN tag is added to the packet header.
  • The packet is then moved to the br-ex OVS bridge using patch-peer int-br-ex <→ phy-br-ex. Example patch-peer on br-int:
    Bridge br-int
        fail_mode: secure
       Port int-br-ex
            Interface int-br-ex
                type: patch
                options: {peer=phy-br-ex}

Example configuration of the patch peer on br-ex:

    Bridge br-ex
        Port phy-br-ex
            Interface phy-br-ex
                type: patch
                options: {peer=int-br-ex}
        Port br-ex
            Interface br-ex
                type: internal
  • When this packet reaches phy-br-ex on br-ex, an OVS flow inside br-ex replaces the internal VLAN tag with the actual VLAN tag associated with the VLAN provider network.

The output of the following command shows that the port number of phy-br-ex is 4:

# ovs-ofctl show br-ex
 4(phy-br-ex): addr:32:e7:a1:6b:90:3e
     config:     0
     state:      0
     speed: 0 Mbps now, 0 Mbps max

The following command shows any packet that arrives on phy-br-ex (in_port=4) which has VLAN tag 2 (dl_vlan=2). Open vSwitch replaces the VLAN tag with 171 (actions=mod_vlan_vid:171,NORMAL) and forwards the packet to the physical interface. The command also shows any packet that arrives on phy-br-ex (in_port=4) which has VLAN tag 3 (dl_vlan=3). Open vSwitch replaces the VLAN tag with 172 (actions=mod_vlan_vid:172,NORMAL) and forwards the packet to the physical interface. The neutron-openvswitch-agent adds these rules.

# ovs-ofctl dump-flows br-ex
NXST_FLOW reply (xid=0x4):
NXST_FLOW reply (xid=0x4):
 cookie=0x0, duration=6527.527s, table=0, n_packets=29211, n_bytes=2725576, idle_age=0, priority=1 actions=NORMAL
 cookie=0x0, duration=2939.172s, table=0, n_packets=117, n_bytes=8296, idle_age=58, priority=4,in_port=4,dl_vlan=3 actions=mod_vlan_vid:172,NORMAL
 cookie=0x0, duration=6111.389s, table=0, n_packets=145, n_bytes=9368, idle_age=98, priority=4,in_port=4,dl_vlan=2 actions=mod_vlan_vid:171,NORMAL
 cookie=0x0, duration=6526.675s, table=0, n_packets=82, n_bytes=6700, idle_age=2462, priority=2,in_port=4 actions=drop
  • This packet is then forwarded to physical interface eth1.

The flow of incoming traffic in a VLAN provider network

The following example flow was tested on a Compute node using VLAN tag 2 for provider network provider-171 and VLAN tag 3 for provider network provider-172. The flow uses port 18 on the integration bridge br-int.

Your VLAN provider network may require a different configuration. Also, the configuration requirement for a network may differ between two different Compute nodes.

The output of the following command shows int-br-ex with port number 18:

# ovs-ofctl show br-int
 18(int-br-ex): addr:fe:b7:cb:03:c5:c1
     config:     0
     state:      0
     speed: 0 Mbps now, 0 Mbps max

The output of the following command shows the flow rules on br-int.

# ovs-ofctl dump-flows br-int
NXST_FLOW reply (xid=0x4):
 cookie=0x0, duration=6770.572s, table=0, n_packets=1239, n_bytes=127795, idle_age=106, priority=1 actions=NORMAL

 cookie=0x0, duration=3181.679s, table=0, n_packets=2605, n_bytes=246456, idle_age=0,
 priority=3,in_port=18,dl_vlan=172 actions=mod_vlan_vid:3,NORMAL

 cookie=0x0, duration=6353.898s, table=0, n_packets=5077, n_bytes=482582, idle_age=0,
 priority=3,in_port=18,dl_vlan=171 actions=mod_vlan_vid:2,NORMAL

 cookie=0x0, duration=6769.391s, table=0, n_packets=22301, n_bytes=2013101, idle_age=0, priority=2,in_port=18 actions=drop

 cookie=0x0, duration=6770.463s, table=23, n_packets=0, n_bytes=0, idle_age=6770, priority=0 actions=drop

Incoming flow example

This example demonstrates the the following br-int OVS flow:

cookie=0x0, duration=3181.679s, table=0, n_packets=2605, n_bytes=246456, idle_age=0,
priority=3,in_port=18,dl_vlan=172 actions=mod_vlan_vid:3,NORMAL
  • A packet with VLAN tag 172 from the external network reaches the br-ex bridge via eth1 on the physical node
  • The packet moves to br-int via the patch-peer phy-br-ex <-> int-br-ex.
  • The packet matches the flow’s criteria (in_port=18,dl_vlan=172)
  • The flow actions (actions=mod_vlan_vid:3,NORMAL) replace the VLAN tag 172 with internal VLAN tag 3 and forwards the packet to the instance with normal Layer 2 processing.

7.3.5. Troubleshooting instance-physical network connections on VLAN provider networks

Refer to the packet flow described in Section 7.3.4, “How does the VLAN provider network packet flow work?” when troubleshooting connectivity in a VLAN provider network. In addition, review the following configuration options:

1. Verify that physical network name is used consistently. In this example, physnet1 is used consistently while creating the network, and within the bridge_mapping configuration:

# grep bridge_mapping /etc/neutron/plugins/ml2/openvswitch_agent.ini
bridge_mappings = physnet1:br-ex

# openstack network show provider-vlan171
...
| provider:physical_network | physnet1
...

2. Confirm that the network was created as external, is type vlan, and uses the correct segmentation_id value:

# openstack network show provider-vlan171
...
| provider:network_type     | vlan                                 |
| provider:physical_network | physnet1                             |
| provider:segmentation_id  | 171                                  |
...

3. Run ovs-vsctl show and verify that br-int and br-ex are connected using the patch-peer int-br-ex <→ phy-br-ex.
This connection is created while restarting neutron-openvswitch-agent, provided that the bridge_mapping is correctly configured in /etc/neutron/plugins/ml2/openvswitch_agent.ini.
Recheck the bridge_mapping setting if this is not created even after restarting the service.

4. To review the flow of outgoing packets, run ovs-ofctl dump-flows br-ex and ovs-ofctl dump-flows br-int, and verify that the flows map the internal VLAN IDs to the external VLAN ID (segmentation_id). For incoming packets, map the external VLAN ID to the internal VLAN ID.
This flow is added by the neutron OVS agent when you spawn an instance to this network for the first time. If this flow is not created after spawning the instance, ensure that the network is created as vlan, is external, and that the physical_network name is correct. In addition, re-check the bridge_mapping settings.

5. Finally, re-check the ifcfg-br-ex and ifcfg-ethx configuration. Ensure that br-ex includes port ethX, and that both ifcfg-br-ex and ifcfg-ethx have an UP flag in the output of the ip a command.
For example, the following output shows that eth1 is a port in br-ex:

    Bridge br-ex
        Port phy-br-ex
            Interface phy-br-ex
                type: patch
                options: {peer=int-br-ex}
        Port "eth1"
            Interface "eth1"

The following command shows that eth1 has been added as a port, and that the kernel is configured to move all packets from the interface to the OVS bridge br-ex. This is demonstrated by the entry: master ovs-system.

# ip a
5: eth1: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc mq master ovs-system state UP qlen 1000

7.4. Enabling Compute metadata access

Instances connected as described in this chapter are directly attached to the provider external networks, and have external routers configured as their default gateway. No OpenStack Networking (neutron) routers are used. This means that neutron routers cannot be used to proxy metadata requests from instances to the nova-metadata server, which may result in failures while running cloud-init. However, this issue can be resolved by configuring the dhcp agent to proxy metadata requests. You can enable this functionality in /etc/neutron/dhcp_agent.ini. For example:

enable_isolated_metadata = True

7.5. Floating IP addresses

You can use the same network to allocate floating IP addresses to instances, even if the floating IPs are already associated with private networks. The addresses that you allocate as floating IPs from this network are bound to the qrouter-xxx namespace on the Network node, and perform DNAT-SNAT to the associated private IP address. In contrast, the IP addresses that you allocate for direct external network access are bound directly inside the instance, and allow the instance to communicate directly with external network.

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