Over the years I wrote a dozen blog posts describing various aspects of using CI/CD in network automation. These blog posts are now collected in the new CI/CD in Networking page that also includes links to related podcasts, webinars, and sample network automation solutions.

A networking engineer attending the Building Next-Generation Data Center online course asked this question:

What is the best practice to connect DC fabric to outside world assuming there are 2 spine switches in the fabric and EVPN VXLAN is used as overlay? Is it a good idea to introduce edge (border) switches, or it is better to connect outside world directly to the spine?

As always, the answer is “it depends,” this time based on:

After figuring out how DHCP relaying works and testing it in a simple lab, I went a step further and tested VRF-aware DHCP relaying.

Lab Topology

I had to make just a few changes to the DHCP relaying lab topology:

• DHCP server is running on CSR 1000v. IOSv DHCP server does not support subnet selection DHCP option and thus doesn’t work with relays that do inter-VRF DHCP relaying.
• I put the link between the DHCP client and DHCP relay into a VRF.

Just in case you wondered why we have eight bits per byte: after Julia Evans investigated this mystery, Steven Bellovin published an excellent overview of the early years of bytes and words.

Vadim Semenov created an interesting solution out of open-source tools (and some glue): a system that tracks, logs, and displays OSPF changes in your network.

It might not be exactly what you’re looking for (and purists would argue it should use BGP-LS), but that’s the beauty of open-source solutions: go and adapt it to your needs, generalizes your fixes, and submit a pull request.

After implementing MLAG functionality with EVPN and having a VXLAN-like fabric transport path between MLAG members, it becomes possible to get rid of the MLAG peer link.

Not surprisingly, most implementations of virtual MLAG peer link remain proprietary. Lukas Krattiger described the details of Cisco’s vPC Fabric Peering implementation in the EVPN Deep Dive webinar.

A few weeks ago I described why EBGP TCP packets have TTL set to one (unless you configured EBGP multihop). Although some people claim that (like NAT) it could be a security feature, it’s not a good one. Generalized TTL Security Mechanism (GTSM, described in RFC 5082) is much better.

Most BGP implementations set TTL field in outgoing EBGP packets to one. That prevents a remote intruder that manages to hijack a host route to an adjacent EBGP peer from forming a BGP session as the TCP replies get lost the moment they hit the first router in the path.

Even though IPv6 could buy its own beer (in US, let alone rest of the world), networking engineers still struggle with its deployment – one of the first questions I got in the ipSpace.net Design Clinic was:

We have been tasked to start IPv6 planning. Can we discuss (for enterprises like us who all of the sudden want IPv6) which design paths to take?

I did my best to answer this question and describe the basics of creating an IPv6 addressing plan. For even more details, watch the IPv6 webinars (most of them at least a few years old, but nothing changed in the IPv6 world in the meantime apart from the SRv6 madness).

I’m always envious of how easy networking challenges seem when you’re solving them in PowerPoint, for example, when an innovation specialist explains how scalability works in leaf-and-spine fabrics in a LinkedIn comment:

One of the main benefits of a CLOS folded spine topology is the scale out spine where you can scale out the number of spine nodes increasing your leaf-spine n-way ECMP as well as minimizing the blast radius with the more spine nodes the more redundancy and resiliency.

Isn’t that wonderful? If you need more bandwidth, sprinkle the magic spine powder on your fabric, add water, and voila! Problem solved. Also, it looks like adding spine switches reduces the blast radius. Who would have known?

After figuring out how DHCP relaying works, I decided to test it out in a lab. netlab has no DHCP configuration module (at the moment); the easiest way forward seemed to be custom configuration templates combined with a few extra attributes.

Lab Topology

This is how I set up the lab: