ovn-architecture(7) Open vSwitch Manual ovn-architecture(7) NAME ovn-architecture - Open Virtual Network architecture DESCRIPTION OVN, the Open Virtual Network, is a system to support virtual network abstraction. OVN complements the existing capabilities of OVS to add native support for virtual network abstractions, such as virtual L2 and L3 overlays and security groups. Services such as DHCP are also desir‐ able features. Just like OVS, OVN’s design goal is to have a produc‐ tion-quality implementation that can operate at significant scale. An OVN deployment consists of several components: · A Cloud Management System (CMS), which is OVN’s ultimate client (via its users and administrators). OVN integra‐ tion requires installing a CMS-specific plugin and related software (see below). OVN initially targets OpenStack as CMS. We generally speak of ``the’’ CMS, but one can imagine scenarios in which multiple CMSes manage different parts of an OVN deployment. · An OVN Database physical or virtual node (or, eventually, cluster) installed in a central location. · One or more (usually many) hypervisors. Hypervisors must run Open vSwitch and implement the interface described in IntegrationGuide.md in the OVS source tree. Any hypervi‐ sor platform supported by Open vSwitch is acceptable. · Zero or more gateways. A gateway extends a tunnel-based logical network into a physical network by bidirection‐ ally forwarding packets between tunnels and a physical Ethernet port. This allows non-virtualized machines to participate in logical networks. A gateway may be a physical host, a virtual machine, or an ASIC-based hard‐ ware switch that supports the vtep(5) schema. (Support for the latter will come later in OVN implementation.) Hypervisors and gateways are together called transport node or chassis. The diagram below shows how the major components of OVN and related software interact. Starting at the top of the diagram, we have: · The Cloud Management System, as defined above. · The OVN/CMS Plugin is the component of the CMS that interfaces to OVN. In OpenStack, this is a Neutron plug‐ in. The plugin’s main purpose is to translate the CMS’s notion of logical network configuration, stored in the CMS’s configuration database in a CMS-specific format, into an intermediate representation understood by OVN. This component is necessarily CMS-specific, so a new plugin needs to be developed for each CMS that is inte‐ grated with OVN. All of the components below this one in the diagram are CMS-independent. · The OVN Northbound Database receives the intermediate representation of logical network configuration passed down by the OVN/CMS Plugin. The database schema is meant to be ``impedance matched’’ with the concepts used in a CMS, so that it directly supports notions of logical switches, routers, ACLs, and so on. See ovn-nb(5) for details. The OVN Northbound Database has only two clients: the OVN/CMS Plugin above it and ovn-northd below it. · ovn-northd(8) connects to the OVN Northbound Database above it and the OVN Southbound Database below it. It translates the logical network configuration in terms of conventional network concepts, taken from the OVN North‐ bound Database, into logical datapath flows in the OVN Southbound Database below it. · The OVN Southbound Database is the center of the system. Its clients are ovn-northd(8) above it and ovn-con‐ troller(8) on every transport node below it. The OVN Southbound Database contains three kinds of data: Physical Network (PN) tables that specify how to reach hypervisor and other nodes, Logical Network (LN) tables that describe the logical network in terms of ``logical datapath flows,’’ and Binding tables that link logical network components’ locations to the physical network. The hypervisors populate the PN and Port_Binding tables, whereas ovn-northd(8) populates the LN tables. OVN Southbound Database performance must scale with the number of transport nodes. This will likely require some work on ovsdb-server(1) as we encounter bottlenecks. Clustering for availability may be needed. The remaining components are replicated onto each hypervisor: · ovn-controller(8) is OVN’s agent on each hypervisor and software gateway. Northbound, it connects to the OVN Southbound Database to learn about OVN configuration and status and to populate the PN table and the Chassis col‐ umn in Binding table with the hypervisor’s status. Southbound, it connects to ovs-vswitchd(8) as an OpenFlow controller, for control over network traffic, and to the local ovsdb-server(1) to allow it to monitor and control Open vSwitch configuration. · ovs-vswitchd(8) and ovsdb-server(1) are conventional com‐ ponents of Open vSwitch. CMS | | +-----------|-----------+ | | | | OVN/CMS Plugin | | | | | | | | OVN Northbound DB | | | | | | | | ovn-northd | | | | +-----------|-----------+ | | +-------------------+ | OVN Southbound DB | +-------------------+ | | +------------------+------------------+ | | | HV 1 | | HV n | +---------------|---------------+ . +---------------|---------------+ | | | . | | | | ovn-controller | . | ovn-controller | | | | | . | | | | | | | | | | | | | ovs-vswitchd ovsdb-server | | ovs-vswitchd ovsdb-server | | | | | +-------------------------------+ +-------------------------------+ Chassis Setup Each chassis in an OVN deployment must be configured with an Open vSwitch bridge dedicated for OVN’s use, called the integration bridge. System startup scripts may create this bridge prior to starting ovn-controller if desired. If this bridge does not exist when ovn-con‐ troller starts, it will be created automatically with the default con‐ figuration suggested below. The ports on the integration bridge include: · On any chassis, tunnel ports that OVN uses to maintain logical network connectivity. ovn-controller adds, updates, and removes these tunnel ports. · On a hypervisor, any VIFs that are to be attached to log‐ ical networks. The hypervisor itself, or the integration between Open vSwitch and the hypervisor (described in IntegrationGuide.md) takes care of this. (This is not part of OVN or new to OVN; this is pre-existing integra‐ tion work that has already been done on hypervisors that support OVS.) · On a gateway, the physical port used for logical network connectivity. System startup scripts add this port to the bridge prior to starting ovn-controller. This can be a patch port to another bridge, instead of a physical port, in more sophisticated setups. Other ports should not be attached to the integration bridge. In par‐ ticular, physical ports attached to the underlay network (as opposed to gateway ports, which are physical ports attached to logical networks) must not be attached to the integration bridge. Underlay physical ports should instead be attached to a separate Open vSwitch bridge (they need not be attached to any bridge at all, in fact). The integration bridge should be configured as described below. The effect of each of these settings is documented in ovs-vswitchd.conf.db(5): fail-mode=secure Avoids switching packets between isolated logical net‐ works before ovn-controller starts up. See Controller Failure Settings in ovs-vsctl(8) for more information. other-config:disable-in-band=true Suppresses in-band control flows for the integration bridge. It would be unusual for such flows to show up anyway, because OVN uses a local controller (over a Unix domain socket) instead of a remote controller. It’s pos‐ sible, however, for some other bridge in the same system to have an in-band remote controller, and in that case this suppresses the flows that in-band control would ordinarily set up. See In-Band Control in DESIGN.md for more information. The customary name for the integration bridge is br-int, but another name may be used. Logical Networks A logical network implements the same concepts as physical networks, but they are insulated from the physical network with tunnels or other encapsulations. This allows logical networks to have separate IP and other address spaces that overlap, without conflicting, with those used for physical networks. Logical network topologies can be arranged without regard for the topologies of the physical networks on which they run. Logical network concepts in OVN include: · Logical switches, the logical version of Ethernet switches. · Logical routers, the logical version of IP routers. Log‐ ical switches and routers can be connected into sophisti‐ cated topologies. · Logical datapaths are the logical version of an OpenFlow switch. Logical switches and routers are both imple‐ mented as logical datapaths. Life Cycle of a VIF Tables and their schemas presented in isolation are difficult to under‐ stand. Here’s an example. A VIF on a hypervisor is a virtual network interface attached either to a VM or a container running directly on that hypervisor (This is dif‐ ferent from the interface of a container running inside a VM). The steps in this example refer often to details of the OVN and OVN Northbound database schemas. Please see ovn-sb(5) and ovn-nb(5), respectively, for the full story on these databases. 1. A VIF’s life cycle begins when a CMS administrator creates a new VIF using the CMS user interface or API and adds it to a switch (one implemented by OVN as a logical switch). The CMS updates its own configuration. This includes associating unique, persistent identifier vif-id and Ethernet address mac with the VIF. 2. The CMS plugin updates the OVN Northbound database to include the new VIF, by adding a row to the Logical_Port table. In the new row, name is vif-id, mac is mac, switch points to the OVN logical switch’s Logical_Switch record, and other columns are initialized appropriately. 3. ovn-northd receives the OVN Northbound database update. In turn, it makes the corresponding updates to the OVN Southbound database, by adding rows to the OVN Southbound database Logi‐ cal_Flow table to reflect the new port, e.g. add a flow to recognize that packets destined to the new port’s MAC address should be delivered to it, and update the flow that delivers broadcast and multicast packets to include the new port. It also creates a record in the Binding table and populates all its columns except the column that identifies the chassis. 4. On every hypervisor, ovn-controller receives the Logical_Flow table updates that ovn-northd made in the previous step. As long as the VM that owns the VIF is powered off, ovn-con‐ troller cannot do much; it cannot, for example, arrange to send packets to or receive packets from the VIF, because the VIF does not actually exist anywhere. 5. Eventually, a user powers on the VM that owns the VIF. On the hypervisor where the VM is powered on, the integration between the hypervisor and Open vSwitch (described in Integra‐ tionGuide.md) adds the VIF to the OVN integration bridge and stores vif-id in external-ids:iface-id to indicate that the interface is an instantiation of the new VIF. (None of this code is new in OVN; this is pre-existing integration work that has already been done on hypervisors that support OVS.) 6. On the hypervisor where the VM is powered on, ovn-controller notices external-ids:iface-id in the new Interface. In response, it updates the local hypervisor’s OpenFlow tables so that packets to and from the VIF are properly handled. After‐ ward, in the OVN Southbound DB, it updates the Binding table’s chassis column for the row that links the logical port from external-ids:iface-id to the hypervisor. 7. Some CMS systems, including OpenStack, fully start a VM only when its networking is ready. To support this, ovn-northd notices the chassis column updated for the row in Binding ta‐ ble and pushes this upward by updating the up column in the OVN Northbound database’s Logical_Port table to indicate that the VIF is now up. The CMS, if it uses this feature, can then react by allowing the VM’s execution to proceed. 8. On every hypervisor but the one where the VIF resides, ovn-controller notices the completely populated row in the Binding table. This provides ovn-controller the physical location of the logical port, so each instance updates the OpenFlow tables of its switch (based on logical datapath flows in the OVN DB Logical_Flow table) so that packets to and from the VIF can be properly handled via tunnels. 9. Eventually, a user powers off the VM that owns the VIF. On the hypervisor where the VM was powered off, the VIF is deleted from the OVN integration bridge. 10. On the hypervisor where the VM was powered off, ovn-controller notices that the VIF was deleted. In response, it removes the Chassis column content in the Binding table for the logical port. 11. On every hypervisor, ovn-controller notices the empty Chassis column in the Binding table’s row for the logical port. This means that ovn-controller no longer knows the physical loca‐ tion of the logical port, so each instance updates its Open‐ Flow table to reflect that. 12. Eventually, when the VIF (or its entire VM) is no longer needed by anyone, an administrator deletes the VIF using the CMS user interface or API. The CMS updates its own configura‐ tion. 13. The CMS plugin removes the VIF from the OVN Northbound data‐ base, by deleting its row in the Logical_Port table. 14. ovn-northd receives the OVN Northbound update and in turn updates the OVN Southbound database accordingly, by removing or updating the rows from the OVN Southbound database Logi‐ cal_Flow table and Binding table that were related to the now- destroyed VIF. 15. On every hypervisor, ovn-controller receives the Logical_Flow table updates that ovn-northd made in the previous step. ovn-controller updates OpenFlow tables to reflect the update, although there may not be much to do, since the VIF had already become unreachable when it was removed from the Bind‐ ing table in a previous step. Life Cycle of a Container Interface Inside a VM OVN provides virtual network abstractions by converting information written in OVN_NB database to OpenFlow flows in each hypervisor. Secure virtual networking for multi-tenants can only be provided if OVN controller is the only entity that can modify flows in Open vSwitch. When the Open vSwitch integration bridge resides in the hypervisor, it is a fair assumption to make that tenant workloads running inside VMs cannot make any changes to Open vSwitch flows. If the infrastructure provider trusts the applications inside the con‐ tainers not to break out and modify the Open vSwitch flows, then con‐ tainers can be run in hypervisors. This is also the case when contain‐ ers are run inside the VMs and Open vSwitch integration bridge with flows added by OVN controller resides in the same VM. For both the above cases, the workflow is the same as explained with an example in the previous section ("Life Cycle of a VIF"). This section talks about the life cycle of a container interface (CIF) when containers are created in the VMs and the Open vSwitch integration bridge resides inside the hypervisor. In this case, even if a con‐ tainer application breaks out, other tenants are not affected because the containers running inside the VMs cannot modify the flows in the Open vSwitch integration bridge. When multiple containers are created inside a VM, there are multiple CIFs associated with them. The network traffic associated with these CIFs need to reach the Open vSwitch integration bridge running in the hypervisor for OVN to support virtual network abstractions. OVN should also be able to distinguish network traffic coming from different CIFs. There are two ways to distinguish network traffic of CIFs. One way is to provide one VIF for every CIF (1:1 model). This means that there could be a lot of network devices in the hypervisor. This would slow down OVS because of all the additional CPU cycles needed for the management of all the VIFs. It would also mean that the entity creating the containers in a VM should also be able to create the cor‐ responding VIFs in the hypervisor. The second way is to provide a single VIF for all the CIFs (1:many model). OVN could then distinguish network traffic coming from differ‐ ent CIFs via a tag written in every packet. OVN uses this mechanism and uses VLAN as the tagging mechanism. 1. A CIF’s life cycle begins when a container is spawned inside a VM by the either the same CMS that created the VM or a tenant that owns that VM or even a container Orchestration System that is different than the CMS that initially created the VM. Whoever the entity is, it will need to know the vif-id that is associated with the network interface of the VM through which the container interface’s network traffic is expected to go through. The entity that creates the container interface will also need to choose an unused VLAN inside that VM. 2. The container spawning entity (either directly or through the CMS that manages the underlying infrastructure) updates the OVN Northbound database to include the new CIF, by adding a row to the Logical_Port table. In the new row, name is any unique identifier, parent_name is the vif-id of the VM through which the CIF’s network traffic is expected to go through and the tag is the VLAN tag that identifies the network traffic of that CIF. 3. ovn-northd receives the OVN Northbound database update. In turn, it makes the corresponding updates to the OVN Southbound database, by adding rows to the OVN Southbound database’s Log‐ ical_Flow table to reflect the new port and also by creating a new row in the Binding table and populating all its columns except the column that identifies the chassis. 4. On every hypervisor, ovn-controller subscribes to the changes in the Binding table. When a new row is created by ovn-northd that includes a value in parent_port column of Binding table, the ovn-controller in the hypervisor whose OVN integration bridge has that same value in vif-id in external-ids:iface-id updates the local hypervisor’s OpenFlow tables so that packets to and from the VIF with the particular VLAN tag are properly handled. Afterward it updates the chassis column of the Bind‐ ing to reflect the physical location. 5. One can only start the application inside the container after the underlying network is ready. To support this, ovn-northd notices the updated chassis column in Binding table and updates the up column in the OVN Northbound database’s Logi‐ cal_Port table to indicate that the CIF is now up. The entity responsible to start the container application queries this value and starts the application. 6. Eventually the entity that created and started the container, stops it. The entity, through the CMS (or directly) deletes its row in the Logical_Port table. 7. ovn-northd receives the OVN Northbound update and in turn updates the OVN Southbound database accordingly, by removing or updating the rows from the OVN Southbound database Logi‐ cal_Flow table that were related to the now-destroyed CIF. It also deletes the row in the Binding table for that CIF. 8. On every hypervisor, ovn-controller receives the Logical_Flow table updates that ovn-northd made in the previous step. ovn-controller updates OpenFlow tables to reflect the update. Architectural Life Cycle of a Packet This section describes how a packet travels from one virtual machine or container to another through OVN. This description focuses on the physical treatment of a packet; for a description of the logical life cycle of a packet, please refer to the Logical_Flow table in ovn-sb(5). This section mentions several data and metadata fields, for clarity summarized here: tunnel key When OVN encapsulates a packet in Geneve or another tun‐ nel, it attaches extra data to it to allow the receiving OVN instance to process it correctly. This takes differ‐ ent forms depending on the particular encapsulation, but in each case we refer to it here as the ``tunnel key.’’ See Tunnel Encapsulations, below, for details. logical datapath field A field that denotes the logical datapath through which a packet is being processed. OVN uses the field that Open‐ Flow 1.1+ simply (and confusingly) calls ``metadata’’ to store the logical datapath. (This field is passed across tunnels as part of the tunnel key.) logical input port field A field that denotes the logical port from which the packet entered the logical datapath. OVN stores this in Nicira extension register number 6. (This field is passed across tunnels as part of the tunnel key.) logical output port field A field that denotes the logical port from which the packet will leave the logical datapath. This is initial‐ ized to 0 at the beginning of the logical ingress pipe‐ line. OVN stores this in Nicira extension register num‐ ber 7. (This field is passed across tunnels as part of the tunnel key.) VLAN ID The VLAN ID is used as an interface between OVN and con‐ tainers nested inside a VM (see Life Cycle of a container interface inside a VM, above, for more information). Initially, a VM or container on the ingress hypervisor sends a packet on a port attached to the OVN integration bridge. Then: 1. OpenFlow table 0 performs physical-to-logical translation. It matches the packet’s ingress port. Its actions annotate the packet with logical metadata, by setting the logical datapath field to identify the logical datapath that the packet is traversing and the logical input port field to identify the ingress port. Then it resubmits to table 16 to enter the log‐ ical ingress pipeline. It’s possible that a single ingress physical port maps to mul‐ tiple logical ports with a type of localnet. The logical data‐ path and logical input port fields will be reset and the packet will be resubmitted to table 16 multiple times. Packets that originate from a container nested within a VM are treated in a slightly different way. The originating con‐ tainer can be distinguished based on the VIF-specific VLAN ID, so the physical-to-logical translation flows additionally match on VLAN ID and the actions strip the VLAN header. Fol‐ lowing this step, OVN treats packets from containers just like any other packets. Table 0 also processes packets that arrive from other chassis. It distinguishes them from other packets by ingress port, which is a tunnel. As with packets just entering the OVN pipeline, the actions annotate these packets with logical datapath and logical ingress port metadata. In addition, the actions set the logical output port field, which is available because in OVN tunneling occurs after the logical output port is known. These three pieces of information are obtained from the tunnel encapsulation metadata (see Tunnel Encapsulations for encoding details). Then the actions resubmit to table 33 to enter the logical egress pipeline. 2. OpenFlow tables 16 through 31 execute the logical ingress pipeline from the Logical_Flow table in the OVN Southbound database. These tables are expressed entirely in terms of logical concepts like logical ports and logical datapaths. A big part of ovn-controller’s job is to translate them into equivalent OpenFlow (in particular it translates the table numbers: Logical_Flow tables 0 through 15 become OpenFlow tables 16 through 31). For a given packet, the logical ingress pipeline eventually executes zero or more output actions: · If the pipeline executes no output actions at all, the packet is effectively dropped. · Most commonly, the pipeline executes one output action, which ovn-controller implements by resubmitting the packet to table 32. · If the pipeline can execute more than one output action, then each one is separately resubmitted to ta‐ ble 32. This can be used to send multiple copies of the packet to multiple ports. (If the packet was not modified between the output actions, and some of the copies are destined to the same hypervisor, then using a logical multicast output port would save bandwidth between hypervisors.) 3. OpenFlow tables 32 through 47 implement the output action in the logical ingress pipeline. Specifically, table 32 handles packets to remote hypervisors, table 33 handles packets to the local hypervisor, and table 34 discards packets whose logical ingress and egress port are the same. Each flow in table 32 matches on a logical output port for unicast or multicast logical ports that include a logical port on a remote hypervisor. Each flow’s actions implement sending a packet to the port it matches. For unicast logical output ports on remote hypervisors, the actions set the tunnel key to the correct value, then send the packet on the tunnel port to the correct hypervisor. (When the remote hypervisor receives the packet, table 0 there will recognize it as a tunneled packet and pass it along to table 33.) For multicast logical output ports, the actions send one copy of the packet to each remote hypervisor, in the same way as for unicast destina‐ tions. If a multicast group includes a logical port or ports on the local hypervisor, then its actions also resubmit to ta‐ ble 33. Table 32 also includes a fallback flow that resubmits to table 33 if there is no other match. Flows in table 33 resemble those in table 32 but for logical ports that reside locally rather than remotely. (This includes logical patch ports, which do not have a physical location and effectively reside on every hypervisor.) For unicast logical output ports on the local hypervisor, the actions just resubmit to table 34. For multicast output ports that include one or more logical ports on the local hypervi‐ sor, for each such logical port P, the actions change the log‐ ical output port to P, then resubmit to table 34. Table 34 matches and drops packets for which the logical input and output ports are the same. It resubmits other packets to table 48. 4. OpenFlow tables 48 through 63 execute the logical egress pipe‐ line from the Logical_Flow table in the OVN Southbound data‐ base. The egress pipeline can perform a final stage of vali‐ dation before packet delivery. Eventually, it may execute an output action, which ovn-controller implements by resubmitting to table 64. A packet for which the pipeline never executes output is effectively dropped (although it may have been transmitted through a tunnel across a physical network). The egress pipeline cannot change the logical output port or cause further tunneling. 5. OpenFlow table 64 performs logical-to-physical translation, the opposite of table 0. It matches the packet’s logical egress port. Its actions output the packet to the port attached to the OVN integration bridge that represents that logical port. If the logical egress port is a container nested with a VM, then before sending the packet the actions push on a VLAN header with an appropriate VLAN ID. If the logical egress port is a logical patch port, then table 64 outputs to an OVS patch port that represents the logical patch port. The packet re-enters the OpenFlow flow table from the OVS patch port’s peer in table 0, which identifies the logical datapath and logical input port based on the OVS patch port’s OpenFlow port number. Life Cycle of a VTEP gateway A gateway is a chassis that forwards traffic between the OVN-managed part of a logical network and a physical VLAN, extending a tunnel- based logical network into a physical network. The steps below refer often to details of the OVN and VTEP database schemas. Please see ovn-sb(5), ovn-nb(5) and vtep(5), respectively, for the full story on these databases. 1. A VTEP gateway’s life cycle begins with the administrator reg‐ istering the VTEP gateway as a Physical_Switch table entry in the VTEP database. The ovn-controller-vtep connected to this VTEP database, will recognize the new VTEP gateway and create a new Chassis table entry for it in the OVN_Southbound data‐ base. 2. The administrator can then create a new Logical_Switch table entry, and bind a particular vlan on a VTEP gateway’s port to any VTEP logical switch. Once a VTEP logical switch is bound to a VTEP gateway, the ovn-controller-vtep will detect it and add its name to the vtep_logical_switches column of the Chas‐ sis table in the OVN_Southbound database. Note, the tun‐ nel_key column of VTEP logical switch is not filled at cre‐ ation. The ovn-controller-vtep will set the column when the correponding vtep logical switch is bound to an OVN logical network. 3. Now, the administrator can use the CMS to add a VTEP logical switch to the OVN logical network. To do that, the CMS must first create a new Logical_Port table entry in the OVN_North‐ bound database. Then, the type column of this entry must be set to "vtep". Next, the vtep-logical-switch and vtep-physi‐ cal-switch keys in the options column must also be specified, since multiple VTEP gateways can attach to the same VTEP logi‐ cal switch. 4. The newly created logical port in the OVN_Northbound database and its configuration will be passed down to the OVN_South‐ bound database as a new Port_Binding table entry. The ovn-controller-vtep will recognize the change and bind the logical port to the corresponding VTEP gateway chassis. Con‐ figuration of binding the same VTEP logical switch to a dif‐ ferent OVN logical networks is not allowed and a warning will be generated in the log. 5. Beside binding to the VTEP gateway chassis, the ovn-con‐ troller-vtep will update the tunnel_key column of the VTEP logical switch to the corresponding Datapath_Binding table entry’s tunnel_key for the bound OVN logical network. 6. Next, the ovn-controller-vtep will keep reacting to the con‐ figuration change in the Port_Binding in the OVN_Northbound database, and updating the Ucast_Macs_Remote table in the VTEP database. This allows the VTEP gateway to understand where to forward the unicast traffic coming from the extended external network. 7. Eventually, the VTEP gateway’s life cycle ends when the admin‐ istrator unregisters the VTEP gateway from the VTEP database. The ovn-controller-vtep will recognize the event and remove all related configurations (Chassis table entry and port bind‐ ings) in the OVN_Southbound database. 8. When the ovn-controller-vtep is terminated, all related con‐ figurations in the OVN_Southbound database and the VTEP data‐ base will be cleaned, including Chassis table entries for all registered VTEP gateways and their port bindings, and all Ucast_Macs_Remote table entries and the Logical_Switch tunnel keys. DESIGN DECISIONS Tunnel Encapsulations OVN annotates logical network packets that it sends from one hypervisor to another with the following three pieces of metadata, which are encoded in an encapsulation-specific fashion: · 24-bit logical datapath identifier, from the tunnel_key column in the OVN Southbound Datapath_Binding table. · 15-bit logical ingress port identifier. ID 0 is reserved for internal use within OVN. IDs 1 through 32767, inclu‐ sive, may be assigned to logical ports (see the tun‐ nel_key column in the OVN Southbound Port_Binding table). · 16-bit logical egress port identifier. IDs 0 through 32767 have the same meaning as for logical ingress ports. IDs 32768 through 65535, inclusive, may be assigned to logical multicast groups (see the tunnel_key column in the OVN Southbound Multicast_Group table). For hypervisor-to-hypervisor traffic, OVN supports only Geneve and STT encapsulations, for the following reasons: · Only STT and Geneve support the large amounts of metadata (over 32 bits per packet) that OVN uses (as described above). · STT and Geneve use randomized UDP or TCP source ports that allows efficient distribution among multiple paths in environments that use ECMP in their underlay. · NICs are available to offload STT and Geneve encapsula‐ tion and decapsulation. Due to its flexibility, the preferred encapsulation between hypervisors is Geneve. For Geneve encapsulation, OVN transmits the logical data‐ path identifier in the Geneve VNI. OVN transmits the logical ingress and logical egress ports in a TLV with class 0xffff, type 0, and a 32-bit value encoded as follows, from MSB to LSB: · 1 bits: rsv (0) · 15 bits: ingress port · 16 bits: egress port Environments whose NICs lack Geneve offload may prefer STT encapsula‐ tion for performance reasons. For STT encapsulation, OVN encodes all three pieces of logical metadata in the STT 64-bit tunnel ID as fol‐ lows, from MSB to LSB: · 9 bits: reserved (0) · 15 bits: ingress port · 16 bits: egress port · 24 bits: datapath For connecting to gateways, in addition to Geneve and STT, OVN supports VXLAN, because only VXLAN support is common on top-of-rack (ToR) switches. Currently, gateways have a feature set that matches the capabilities as defined by the VTEP schema, so fewer bits of metadata are necessary. In the future, gateways that do not support encapsula‐ tions with large amounts of metadata may continue to have a reduced feature set. Open vSwitch 2.4.90 OVN Architecture ovn-architecture(7)