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Containervernetzung

OpenStack-Ansible deploys Linux containers (LXC) and uses Linux or Open vSwitch-based bridging between the container and the host interfaces to ensure that all traffic from containers flows over multiple host interfaces. All services in this deployment model use a unique IP address.

This appendix describes how the interfaces are connected and how traffic flows.

For more information about how the OpenStack Networking service (Neutron) uses the interfaces for instance traffic, please see the OpenStack Networking Guide.

Details zur Konfiguration von Netzwerken für Ihre Umgebung finden Sie unter openstack_user_config Einstellungsreferenz.

Physische Hostschnittstellen

In a typical production environment, physical network interfaces are combined in bonded pairs for better redundancy and throughput. Avoid using two ports on the same multiport network card for the same bonded interface, because a network card failure affects both of the physical network interfaces used by the bond. Single (bonded) interfaces are also a supported configuration, but will require the use of VLAN subinterfaces.

Linux Bridges/Switches

The combination of containers and flexible deployment options requires implementation of advanced Linux networking features, such as bridges, switches, and namespaces.

  • Bridges provide layer 2 connectivity (similar to physical switches) among physical, logical, and virtual network interfaces within a host. After a bridge/switch is created, the network interfaces are virtually plugged in to it.

    OpenStack-Ansible uses Linux bridges for control plane connections to LXC containers, and can use Linux bridges or Open vSwitch-based bridges for data plane connections that connect virtual machine instances to the physical network infrastructure.

  • Network namespaces provide logically separate layer 3 environments (similar to VRFs) within a host. Namespaces use virtual interfaces to connect with other namespaces, including the host namespace. These interfaces, often called veth pairs, are virtually plugged in between namespaces similar to patch cables connecting physical devices such as switches and routers.

    Jeder Container verfügt über einen Namespace, der eine Verbindung mit dem Hostnamespace mit einem oder mehreren veth -Paaren herstellt. Sofern nicht anders angegeben, generiert das System zufällige Namen für `` veth``-Paare.

Das folgende Abbild zeigt, wie die Containernetzwerkschnittstellen mit den Bridges und physischen Netzwerkschnittstellen des Hosts verbunden sind:

../../_images/networkcomponents.drawio.png

Netzwerkdiagramme

Hosts mit Diensten, die in Containern ausgeführt werden

Das folgende Diagramm zeigt, wie alle Schnittstellen und Bridges miteinander verbunden sind, um eine Netzwerkverbindung zur OpenStack-Bereitstellung bereitzustellen:

../../_images/networkarch-container-external.drawio.png

The bridge lxcbr0 is configured automatically and provides connectivity for the containers (via eth0) to the outside world, thanks to dnsmasq (dhcp/dns) + NAT.

Bemerkung

Wenn Sie eine zusätzliche Netzwerkkonfiguration für Ihre Container-Schnittstellen benötigen (z. B. Ändern der Routen auf eth1 für Routen im Verwaltungsnetzwerk), passen Sie bitte Ihre Datei openstack_user_config.yml an. Siehe openstack_user_config Einstellungsreferenz für weitere Details.

Neutron Verkehr

Common reference drivers, including ML2/LXB, ML2/OVS, and ML2/OVN, and their respective agents, are responsible for managing the virtual networking infrastructure on each node. OpenStack-Ansible refers to Neutron traffic as „data plane“ traffic, and can consist of flat, vlan, or overlay technologies such as VXLAN and GENEVE.

Neutron agents can be deployed across a variety of hosts, but are typically limited to dedicated network hosts or infrastructure hosts (controller nodes). Neutron agents are deployed „on metal“ and not within an LXC container. Neutron typically requires the operator to define „provider bridge mappings“, which map a provider network name to a physical interface. These provider bridge mappings provide flexibility and abstract physical interface names when creating provider networks.

LinuxBridge Example:

bridge_mappings = physnet1:bond1

Open vSwitch/OVN Example:

bridge_mappings = physnet1:br-ex

OpenStack-Ansible provides two overrides when defining provider networks that can be used for creating the mappings and in some cases, connecting the physical interfaces to provider bridges:

  • host_bind_override

  • network_interface

The host_bind_override override is used for LinuxBridge-based deployments, and requires a physical interface name which will then be used by the LinuxBridge agent for flat and vlan-based provider and tenant network traffic.

The network_interface override is used for Open vSwitch and OVN-based deployments, and requires a physical interface name which will be connected to the provider bridge (ie. br-ex) for flat and vlan-based provider and tenant network traffic.

Bemerkung

Previous versions of OpenStack-Ansible utilized a bridge named br-vlan for flat and vlan-based provider and tenant network traffic. The br-vlan bridge is a leftover of containerized Neutron agents and is no longer useful or recommended.

The following diagrams reflect the differences in the virtual network layout for supported network architectures.

Open Virtual Network (OVN)

Bemerkung

The ML2/OVN (LXB) mechanism driver is deployed by default as of the Zed release of OpenStack-Ansible.

Networking Node
../../_images/networking-ovn-nn.drawio.png
Compute Node
../../_images/networking-ovn-cn.drawio.png

LinuxBridge

Bemerkung

The ML2/LinuxBridge (LXB) mechanism driver is marked as „experimental“ as of the Zed release of OpenStack-Ansible.

Networking Node
../../_images/networking-linuxbridge-nn.drawio.png
Compute Node
../../_images/networking-linuxbridge-cn.drawio.png

Open vSwitch (OVS)

Networking Node
../../_images/networking-openvswitch-nn.drawio.png
Compute Node
../../_images/networking-openvswitch-cn.drawio.png