enabled, the packets comprise TCP and UDP packets and they can be marked with DSCP code points. Multicast is not supported in that
network.
RRoCE packets are received and transmitted on specific interfaces called lite-subinterfaces. These interfaces are similar to the normal
Layer 3 physical interfaces except for the extra provisioning that they offer to enable the VLAN ID for encapsulation.
You can configure a physical interface or a Layer 3 Port Channel interface as a lite subinterface. When you configure a lite subinterface, only
tagged IP packets with VLAN encapsulation are processed and routed. All other data packets are discarded.
A normal Layer 3 physical interface processes only untagged packets and makes routing decisions based on the default Layer 3 VLAN ID
(4095).
To enable routing of RRoCE packets, the VLAN ID is mapped to the default VLAN ID of 4095 using VLAN translation. After the VLAN
translation, the RRoCE packets are processed in the same way as normal IP packets that a Layer 3 interface receives and routes in the
egress direction. At the egress interface, the VLAN ID is appended to the packet and transmitted out of the interface as a tagged packet
with the dot1Q value preserved.
To provide lossless service for RRoCE, the QoS service policy must be configured in the ingress and egress directions on lite sub interfaces.
Preserving 802.1Q VLAN Tag Value for Lite
Subinterfaces
This functionality is supported on the platform.
All the frames in a Layer 2 VLAN are identified using a tag defined in the IEEE 802.1Q standard to determine the VLAN to which the frames
or traffic are relevant or associated. Such frames are encapsulated with the 802.1Q tags. If a single VLAN is configured in a network
topology, all the traffic packets contain the same do1q tag, which is the tag value of the 802.1Q header. If a VLAN is split into multiple,
different sub-VLANs, each VLAN is denoted by a unique 8021.Q tag to enable the nodes that receive the traffic frames determine the
VLAN for which the frames are destined.
Typically, a Layer 3 physical interface processes only untagged or priority-tagged packets. Tagged packets that are received on Layer 3
physical interfaces are dropped. To enable the routing of tagged packets, the port that receives such tagged packets needs to be
configured as a switchport and must be bound to a VLAN as a tagged member port.
A lite subinterface is similar to a normal Layer 3 physical interface, except that additional provisioning is performed to set the VLAN ID for
encapsulation.
A physical interface or a Layer 3 Port channel interface can be configured as a lite subinterface. Once a lite subinterface is configured, only
tagged IP packets with encapsulation VLAN ID are processed and routed. All other data packets are discarded except the Layer 2 and Layer
3 control frames. It is not required for a VLAN ID to be preserved (in the hardware or the OS application) when a VLAN ID, used for
encapsulation, is associated with a physical/Port-channel interface. Normal VLANs and VLAN encapsulation can exist simultaneously and
any non-unicast traffic received on a normal VLAN is not flooded using lite subinterfaces whose encapsulation VLAN ID matches with that
of the normal VLAN ID.
You can use the
encapsulation dot1q
vlan-id
command in INTERFACE mode to configure lite subinterfaces.
Flex Hash and Optimized Boot-Up
343
Содержание S4048T-ON
Страница 1: ...Dell Configuration Guide for the S4048 ON System 9 11 2 1 ...
Страница 148: ...Figure 10 BFD Three Way Handshake State Changes 148 Bidirectional Forwarding Detection BFD ...
Страница 251: ...Dell Control Plane Policing CoPP 251 ...
Страница 363: ... RPM Synchronization GARP VLAN Registration Protocol GVRP 363 ...
Страница 511: ...Figure 64 Inspecting the LAG Configuration Link Aggregation Control Protocol LACP 511 ...
Страница 512: ...Figure 65 Inspecting Configuration of LAG 10 on ALPHA 512 Link Aggregation Control Protocol LACP ...
Страница 515: ...Figure 67 Inspecting a LAG Port on BRAVO Using the show interface Command Link Aggregation Control Protocol LACP 515 ...
Страница 516: ...Figure 68 Inspecting LAG 10 Using the show interfaces port channel Command 516 Link Aggregation Control Protocol LACP ...
Страница 558: ...Figure 84 Configuring Interfaces for MSDP 558 Multicast Source Discovery Protocol MSDP ...
Страница 559: ...Figure 85 Configuring OSPF and BGP for MSDP Multicast Source Discovery Protocol MSDP 559 ...
Страница 560: ...Figure 86 Configuring PIM in Multiple Routing Domains 560 Multicast Source Discovery Protocol MSDP ...
Страница 564: ...Figure 88 MSDP Default Peer Scenario 2 564 Multicast Source Discovery Protocol MSDP ...
Страница 565: ...Figure 89 MSDP Default Peer Scenario 3 Multicast Source Discovery Protocol MSDP 565 ...
Страница 729: ...protocol spanning tree pvst no disable vlan 300 bridge priority 4096 Per VLAN Spanning Tree Plus PVST 729 ...
Страница 841: ...Figure 115 Single and Double Tag TPID Match Service Provider Bridging 841 ...
Страница 842: ...Figure 116 Single and Double Tag First byte TPID Match 842 Service Provider Bridging ...