Tag :: Ipv6

Tagging traffic with a drop precedence is a method that can be used to differentiate traffic flows over a given

This feature allows a Data Center (DC) operator to incrementally migrate their VXLAN network from IPv4 to IPv6

This feature extends the capabilities of event monitor to include IPv6 Route and IPv6 Neighbor event logging.

Starting with EOS release 4.22.0F, the EVPN VXLAN L3 Gateway using EVPN IRB supports routing traffic from one IPV6

Starting with EOS release 4.22.0F, the EVPN VXLAN L3 Gateway using EVPN IRB supports routing traffic from IPV6 host to

Starting with EOS release 4.22.0F, the EVPN VXLAN L3 Gateway using EVPN IRB supports routing traffic from one IPV6

This feature introduces support for scaling both IPv4 and IPv6 hosts on our devices. Existing MDB profiles offer a maximum host scale of 128k with unique MAC rewrites. However, if hosts share the MAC rewrites, the scale can reach up to 204k. To address this issue, we are introducing a new MDB profile that will support a host scale of up to 192k when each host has a unique MAC rewrite. If hosts share the MAC rewrites, the scale can reach up to 256k.

IPv6 multicast routing protocols are used to distribute IPv6 datagrams to one or more recipients. IPv6 PIM builds and maintains multicast routing using reverse path forwarding (RPF) based on the unicast routing table. IPv6 PIM is protocol-independent and can use routing tables consisting of OSPFv3, IPv6 BGP or static routes, for RPF lookup. MLD is used to discover multicast hosts and maintain group membership on a directly attached link.

The document describes an extension of the decap group feature, that allows IPv6 addresses to be configured and used

This feature enables IPv6 access control list (ACLs) on cloudEOS and Caravan devices, providing access control on incoming traffic (ingress direction). ACLs use packet classification to mark certain packets going through the packet processor pipeline and then take configured action against them. Rules are defined based on various fields of packets.

This feature allows the user to match the 20 bit IPV6 flow label using the Qos Policy Map and allows to classify the flow-label controlled traffic.

The flow-label match for QoS policy map can be achieved by using the TCAM profile “qos-match-ipv6-flow-label” which is available from EOS 4.27.2F onwards. 

This solution allows delivery of IPv6 multicast traffic in an IP-VRF using an IPv4 multicast in the underlay network. The protocol used to build multicast trees in the underlay network is PIM Sparse Mode.

This solution allows delivery of both IPv4 and IPv6 multicast traffic in an IP-VRF using an IPv6 multicast in the underlay network. The protocol used to build multicast trees in the underlay network is IPv6 PIM-SSM.

This feature makes a switch act as a neighbor discovery proxy for an IPv6 subnets. It can be used in conjunction with BUM

This configuration command features an IPv6 Neighbor Discovery (ND) option (called Boot File URL (BFURL) option)

With this feature, IPv4 and IPv6 packets matching a static nexthop-group route can be encapsulated within an IP-in-IP tunnel and forwarded

The document describes an extension of the decap group feature, that allows IPv6 addresses to be configured and used

The document describes an extension of the decap group feature, that allows IPv6 addresses to be configured and used as part of a group. IP-in-IP packets with v6 destination matching a configured decap group IP will be decapsulated and forwarded based on the inner header. That will allow any IP-to-IP packet type to be decapsulated, i.e. IPv4 in IPv4, IPv4 in IPv6, IPv6 in IPv4 and IPv6 in IPv6.

This feature adds support for PIM SSM (Source Specific Multicast) for IPv6 Multicast Routing on platforms listed

This document is an extension to the Decap Group feature, that allows IPv6 addresses to be configured and used as part of a decap group. Now we will be able to configure IPv6 prefixes as a decap group. Tunneled packets with IPv6 destination matching to a configured prefix decap group will be decapsulated and forwarded based on the inner header. IP-in-IP tunnel type will be supported for prefix based decap groups.

With the 8.9 release, some operations in CloudVision Wi Fi (CVW) that used IPv4 addresses of Wi Fi clients and access

This feature implements RFC6119, which allows the extension of IS IS protocol to carry IPv6 Traffic Engineering

MAP T is a double stateless NAT64 translation technology. It allows an internet service provider to share IPv4

In networks where source and destination of multicast traffic all reside in the same VLAN, IPv6 multicast traffic is flooded to all ports in the VLAN by default. MLD snooping can be enabled to optimize the inefficient transmission, pruning out ports with no receivers.

This solution optimizes the delivery of multicast to a VLAN over an Ethernet VPN (EVPN) network. Without this solution IPv6 multicast traffic in a VLAN is flooded to all Provider Edge(PE) devices which contain the VLAN.

Multipath color is a new multicast multipath mode for controlling PIM RPF selection. In the default multipath

This feature adds support for making the various OSPFv3 counters accessible via CLI.

A router keeps track of the total number of LSAs for each OSPFv3 instance. The LSA Limit feature provides a mechanism to

Overlay IPv6 routing over VXLAN Tunnel is simply routing IPv6 packets in and out of VXLAN Tunnels, similar to

This feature supports generation of non host routes for the IPv6 neighbor entries learnt on an SVI interface. These

Overlay IPv6 routing over VXLAN tunnel using an anycast gateway (direct routing) has been previously supported using the “ipv6 virtual-router” configuration for both the data-plane and EVPN (or CVX) control-plane learning environments. 

This feature allows an operator to configure a centralized routing topology with an IPv6 VXLAN underlay. This is useful for customers who want to use an anycast (VARP) gateway for routing over an IPv6 control plane. VARP allows multiple switches to simultaneously route packets from a common IP address in an active-active router configuration. Each switch is configured with the virtual IP address and a common virtual MAC address.