For site-so-site ovelay networks, use wireguard, vxlan should be inside of it, if at all. Your "network" is connected by wireguard, and it contains details like vxlan. Even within your network, when crossing security boundaries across untrusted channels, you can use wireguard.
Others mentioned tailscale, it's cool and all but you don't always need it.
As far as security, that's not even the consideration I had in mind, sure wireguard is secure, but that's not why you should have vxlan inside it, you should do so because that's the purpose of wireguard, to connect networks securely across security/trust boundaries. it doesn't even matter if the other protocol is also wireguard, or ssh or whatever, if it is an option, wireguard is always the outermost protocol, if not then ipsec, openvpn,softether,etc..whatever is your choice of secure overlay network protocol gets to be the tunnel protocol.
https://man.openbsd.org/vxlan.4#SECURITY seems unambiguous that it's intended for use in trusted environments (and all else being equal, I'd expect the openbsd man page authors to have reasonable opinions about network security), so it sounds like vxlan over ipsec/wg is probably the better route?
Not super related to the OP but since we're discussing network topologies; I've recently had an insane idea that nfs security sucks, nfs traversing firewalls sucks, kerberos really sucks, and that just wrapping it all in a wireguard pipe is way better.
How deranged would it be to have every nfs client establish a wireguard tunnel and only have nfs traffic go through the tunnel?
> How deranged would it be to have every nfs client establish a wireguard tunnel and only have nfs traffic go through the tunnel?
Sounds good to me. I have my Wireguard tunnel set up so that only traffic intended for hosts that are in the Wireguard network itself are routed over the Wireguard tunnel.
I mostly use it to ssh into different machines. The Wireguard server runs on a VPS on the Internet, and I can connect to it from anywhere (except from networks that filter Wireguard traffic), and that way ssh into my machines at home while I am away from home. Whereas all other normal traffic to other places is unaffected by and unrelated to the tunnel. So for example if I bring my laptop to a coffee shop and I have Wireguard running and I browse the web with a web browser, all my web browsing traffic still gets sent the same normal way that it would even if I didn’t have the tunnel running.
I rarely use NFS nor SMB, but if I wanted to connect either of those I would be able to that as well over this Wireguard setup I have.
I built a NFS3-over-OpenVPN network for a startup about a decade ago; it worked “okay” for transiting an untrusted internal cloud provider network and even over the internet to other datacenters, but ran into mount issues when the outer tunnels dropped a connection during a write. They ran out of money before it had to scale past a few dozen nodes.
Nowadays I would recommend using NFS4+TLS or Gluster+TLS if you need filesystem semantics. Better still would be a proper S3-style or custom REST API that can handle the particulars of whatever strange problem lead to this architecture.
Instead you can create multiple Wireguard interfaces and use policy routing / ECMP / BGP / all the layer 3 tricks, that way you can achieve similar things to what vxlan could give you but at layer 3.
There's a performance benefit to doing it this way too, in some testing I found the wireguard interface can be a bottleneck (there's various offload and multiple core support in Linux, but it still has some overhead).
Agreed. They've also been extremely finnicky from my experience - had cases where large EVPN deployments just blackholed some arbitrary destination MAC until GARPs were sent out of them.
Also IME EVPN is mostly deployed/pushed when clueless app developers expect to have arbitrary L2 reachability across any two points in a (cross DC!) fabric [1], or when they want IP addresses that can follow them around the DC or other dumb shit that they just assumed they can do.
[1] "What do you mean I can't just use UDP broadcast as a pub sub in my application? It works in the office, fix your network!" and the like.
This is the correct answer, routing between subnets is how it’s suppose to work. I think there are some edge cases like DR where it seems like stretching L2 might sound like a good idea, but it practice it gets messy fast.
VXLAN over WireGuard is acceptable if you require a shared L2 boundary.
IPSec over VXLAN is what I recommend if you are doing 10G or above. There is a much higher performance ceiling than WireGuard with IPSec via hardware firewalls. WireGuard is comparatively quite slow performance-wise. Noting Tailscale, since it has been mentioned, has comparatively extremely slow performance.
edit: I'm noticing that a lot of the other replies in this thread are not from network engineers. Among network engineers WireGuard is not very popular due to performance & absence of vendor support. Among software engineers, it is very popular due to ease of use.
At this time, there is no commercial offering for hardware/ASIC WireGuard implementations. The standard WireGuard implementation cannot reach 10G.
The fastest I am aware of is VPP (open-source) & Intel QAT [1], which while it is achieves impressive numbers for large packets (70Gbps @ 512 / 200Gbps @ 1420 on a $20k+ MSRP server), is still not comparable with commercial IPsec offerings [2][3][4] that can achieve 800Gbps+ on a single gateway (and come with the added benefit of relying on a commercial product with support).
There are also solutions like Arista TunnelSec [1] that can achieve IPsec and VXLANsec at line-rate performance (21.6Tbps per chassis)! This is fairly new and fancy though.
While that's true, I'm not sure it's because of something inherent in IPsec vs WireGuard. It's more likely due to the fact that hardware accelerators have been designed to offload encryption routines that IPsec uses.
One wonders what WG perf would look like if it could leverage the same hardware offload.
Exactly this. I would love to see a commercial product with a hardware implementation for WireGuard, but it does not yet exist. IPsec, however, is well supported.
I use vxlan on top of wireguard in my hobby set up. Probably wouldn't recommend it for an actual production use-case. But that is more or less because of how my homelab is setup (Hetzner -> Home about 20ms latency roundtrip).
I considered dropping my root wireguard and setting up just vxlan and flannel, but as I need NAT hole punching I kind of need the wireguard root so that is why i ended up with it.
Going Wireguard inside the vxlan (flannel) in my case, would likely be overkill, unless I wanted my traffic between nodes between regions to be separated from other peers on the network, not sure where that would be useful. It is an easy way of blocking out a peer however, but that could just as well be solved on the "root" wireguard node.
There might be some MTU things that would be messed up going nested wireguard networks.
Is there a WireGuard equivalent that does L2 instead of L3? Need this for a virtual mesh network for homelabbing. I have this exact setup, running VXLAN or GENEVE over WireGuard tunnel using KubeSpan from Talos Linux but I simply think having L2 access would make load balancer much easier
I achieve load balancing by running native wireguard on a vps at hetzner, I've got a native wireguard mesh, I believe Talos can do the same, where the peers are manually set up, or via. tailscale etc. I then tell k3s that it should use the wireguard interface for vxlan, and boom my kubernetes mesh is now connected.
flannel-iface: "wg0" # Talos might have something similar.
I do use some node-labels and affinities to make sure the right pods end up in the right spot. For example the metallb annoucer always has to come from the hetzner node. As mentioned in my reply below, it takes about 20ms roundtrip back to my homelab, so my sites can take a bit of time to load, but it works pretty well otherwise, sort of similar to how cloudflare tunnels would work, except not as polished.
What are your discovery mechanisms? I don't know what exists for automatic peer management with wg. If you're doing bgp evpn for vxlan endpoint discovery then I'd think WG over vxlan would be the easier to manage option.
If you actually want to use vxlan ids to isolate l2 domains, like if you want multiple hypervisors separated by public networks to run groups of VMs on distinct l2 domains, then vxlan over WG seems like the way to go.
BGP is vastly superior to any L2 make-believe trash you can imagine, and amazingly, it often has better hardware offloading support for forwarding and firewalls. For example, 100G switches (L3+) like MikroTik's CRS504 do not support IPv6 in hardware for VXLAN-encapsulated flows, but everything just works if you choose to go the BGP route.
Any ASIC switch released in the last decade from Cisco/Juniper/Arista supports EVPN/VXLAN in hardware. EVPN is built on BGP. This has become the industry standard for new enterprise and cloud deployments.
The lack of support for hardware EVPN is one of the many reasons that Mikrotik is not considered for professional deployments.
If I can source an enterprise Cisco/Juniper/Arista ASIC switch that is 1) rock-solid 2) full featured 3) cheaper - which I can - there is unfortunately no rationale where Mikrotik would be applicable in any professional project of mine.
With that said, I love Mikrotik for what it is: it is very approachable and it fills a niche. I believe it has added a lot of value to the industry and I'm excited to see their products mature.
You can have EoIP over WG with any VLANs you like.
You can have a VXLAN over plain IP, over EoIP, over WG, over IPSec. Only WG and IPSec (with not NULL sec) do providecany semblance ofvencryption in transit
What gave you that idea? Internally, Google uses GRE/GENEVE-like stuff but for reasons that have nothing to do with "preventing compromise" or whatever, but because they're carrying metadata (traces, latency budgets, billing ids.) That is to say, encapsulation is just transport. It's pretty much L3 semantics all the way down... In fact, this is more or less the point: L2 is intractable at scale, as broadcast/multicast doesn't work. However, it's hard to find comparisons to anything you're familiar with at Google scale. They have a myriad of proprietary solutions and custom protocols for routing, even though it's all L3 semantics. To learn more:
For site-so-site ovelay networks, use wireguard, vxlan should be inside of it, if at all. Your "network" is connected by wireguard, and it contains details like vxlan. Even within your network, when crossing security boundaries across untrusted channels, you can use wireguard.
Others mentioned tailscale, it's cool and all but you don't always need it.
As far as security, that's not even the consideration I had in mind, sure wireguard is secure, but that's not why you should have vxlan inside it, you should do so because that's the purpose of wireguard, to connect networks securely across security/trust boundaries. it doesn't even matter if the other protocol is also wireguard, or ssh or whatever, if it is an option, wireguard is always the outermost protocol, if not then ipsec, openvpn,softether,etc..whatever is your choice of secure overlay network protocol gets to be the tunnel protocol.
https://man.openbsd.org/vxlan.4#SECURITY seems unambiguous that it's intended for use in trusted environments (and all else being equal, I'd expect the openbsd man page authors to have reasonable opinions about network security), so it sounds like vxlan over ipsec/wg is probably the better route?
Not super related to the OP but since we're discussing network topologies; I've recently had an insane idea that nfs security sucks, nfs traversing firewalls sucks, kerberos really sucks, and that just wrapping it all in a wireguard pipe is way better.
How deranged would it be to have every nfs client establish a wireguard tunnel and only have nfs traffic go through the tunnel?
> How deranged would it be to have every nfs client establish a wireguard tunnel and only have nfs traffic go through the tunnel?
Sounds good to me. I have my Wireguard tunnel set up so that only traffic intended for hosts that are in the Wireguard network itself are routed over the Wireguard tunnel.
I mostly use it to ssh into different machines. The Wireguard server runs on a VPS on the Internet, and I can connect to it from anywhere (except from networks that filter Wireguard traffic), and that way ssh into my machines at home while I am away from home. Whereas all other normal traffic to other places is unaffected by and unrelated to the tunnel. So for example if I bring my laptop to a coffee shop and I have Wireguard running and I browse the web with a web browser, all my web browsing traffic still gets sent the same normal way that it would even if I didn’t have the tunnel running.
I rarely use NFS nor SMB, but if I wanted to connect either of those I would be able to that as well over this Wireguard setup I have.
I built a NFS3-over-OpenVPN network for a startup about a decade ago; it worked “okay” for transiting an untrusted internal cloud provider network and even over the internet to other datacenters, but ran into mount issues when the outer tunnels dropped a connection during a write. They ran out of money before it had to scale past a few dozen nodes.
Nowadays I would recommend using NFS4+TLS or Gluster+TLS if you need filesystem semantics. Better still would be a proper S3-style or custom REST API that can handle the particulars of whatever strange problem lead to this architecture.
Drop the VXLAN. There's almost never a good reason to stretch L2 over a WAN. Just route stuff across.
This.
Instead you can create multiple Wireguard interfaces and use policy routing / ECMP / BGP / all the layer 3 tricks, that way you can achieve similar things to what vxlan could give you but at layer 3.
There's a performance benefit to doing it this way too, in some testing I found the wireguard interface can be a bottleneck (there's various offload and multiple core support in Linux, but it still has some overhead).
EVPN/VXLAN fabrics are becoming industry standard for new deployments. MACSEC/IPsec is industry standard for site-to-site.
You'd be surprised to know that this is especially popular in cloud! It's just abstracted away (:
EVPN/VXLAN fabrics are becoming cargo culted. In most cases they aren't needed.
Agreed. They've also been extremely finnicky from my experience - had cases where large EVPN deployments just blackholed some arbitrary destination MAC until GARPs were sent out of them.
Also IME EVPN is mostly deployed/pushed when clueless app developers expect to have arbitrary L2 reachability across any two points in a (cross DC!) fabric [1], or when they want IP addresses that can follow them around the DC or other dumb shit that they just assumed they can do.
[1] "What do you mean I can't just use UDP broadcast as a pub sub in my application? It works in the office, fix your network!" and the like.
VXLAN is used in cloud/virtualization networks commonly. VM HA/migration becomes trivial with VXLAN. It also replaces L3VPN/VRFs for private networks.
I don't disagree (:
Though there are definitely use cases where it is needed, and it is way easier to implement earlier than later.
This is the correct answer, routing between subnets is how it’s suppose to work. I think there are some edge cases like DR where it seems like stretching L2 might sound like a good idea, but it practice it gets messy fast.
VXLAN makes sense in the original application, which is to create routable virtual LANs within data centers.
VXLAN over WireGuard is acceptable if you require a shared L2 boundary.
IPSec over VXLAN is what I recommend if you are doing 10G or above. There is a much higher performance ceiling than WireGuard with IPSec via hardware firewalls. WireGuard is comparatively quite slow performance-wise. Noting Tailscale, since it has been mentioned, has comparatively extremely slow performance.
edit: I'm noticing that a lot of the other replies in this thread are not from network engineers. Among network engineers WireGuard is not very popular due to performance & absence of vendor support. Among software engineers, it is very popular due to ease of use.
How is IPSec performance better than wg? I never heard this before, it sounds intriguing.
At this time, there is no commercial offering for hardware/ASIC WireGuard implementations. The standard WireGuard implementation cannot reach 10G.
The fastest I am aware of is VPP (open-source) & Intel QAT [1], which while it is achieves impressive numbers for large packets (70Gbps @ 512 / 200Gbps @ 1420 on a $20k+ MSRP server), is still not comparable with commercial IPsec offerings [2][3][4] that can achieve 800Gbps+ on a single gateway (and come with the added benefit of relying on a commercial product with support).
[1] https://builders.intel.com/docs/networkbuilders/intel-qat-ac...
[2] https://www.juniper.net/content/dam/www/assets/datasheets/us...
[3] https://www.paloaltonetworks.com/apps/pan/public/downloadRes...
[4] https://www.fortinet.com/content/dam/fortinet/assets/data-sh...
There are also solutions like Arista TunnelSec [1] that can achieve IPsec and VXLANsec at line-rate performance (21.6Tbps per chassis)! This is fairly new and fancy though.
[1] https://www.arista.com/assets/data/pdf/Whitepapers/EVPN-Data...
If you have an edge device which implements hardware IPsec at 10g+ but pushes WireGuard to software on an underpowered cpu then sure.
While that's true, I'm not sure it's because of something inherent in IPsec vs WireGuard. It's more likely due to the fact that hardware accelerators have been designed to offload encryption routines that IPsec uses.
One wonders what WG perf would look like if it could leverage the same hardware offload.
Exactly this. I would love to see a commercial product with a hardware implementation for WireGuard, but it does not yet exist. IPsec, however, is well supported.
Whenever I see threads like this, I think its related but I'll be honest, my networking understanding might be limited.
I use Tinc as a daily driver (for personal things) and have yet to come up with a new equivalent, given that I probably should. Does Vxlan help here?
VXLAN is for L2 between campuses. It is commonly used in enterprise and cloud networks.
Tinc is a fantastic piece of software. Very easy to use and configure, and it just works.
These days I lean towards WireGuard simply because it's built into Linux, but Tinc would be my second choice.
I use vxlan on top of wireguard in my hobby set up. Probably wouldn't recommend it for an actual production use-case. But that is more or less because of how my homelab is setup (Hetzner -> Home about 20ms latency roundtrip).
I considered dropping my root wireguard and setting up just vxlan and flannel, but as I need NAT hole punching I kind of need the wireguard root so that is why i ended up with it.
Going Wireguard inside the vxlan (flannel) in my case, would likely be overkill, unless I wanted my traffic between nodes between regions to be separated from other peers on the network, not sure where that would be useful. It is an easy way of blocking out a peer however, but that could just as well be solved on the "root" wireguard node.
There might be some MTU things that would be messed up going nested wireguard networks.
What are you trying to do? Why are you trying to link networks across the public internet?
> Let’s agree going recursive (WireGuard inside VXLAN inside WireGuard) is a bad idea.
But it's not necessarily a bad idea. It depends on the circumstances, even when traversing a public network.
Is there a WireGuard equivalent that does L2 instead of L3? Need this for a virtual mesh network for homelabbing. I have this exact setup, running VXLAN or GENEVE over WireGuard tunnel using KubeSpan from Talos Linux but I simply think having L2 access would make load balancer much easier
You can see my reply below: https://news.ycombinator.com/item?id=46609044 I believe our setups are pretty equivalent.
I achieve load balancing by running native wireguard on a vps at hetzner, I've got a native wireguard mesh, I believe Talos can do the same, where the peers are manually set up, or via. tailscale etc. I then tell k3s that it should use the wireguard interface for vxlan, and boom my kubernetes mesh is now connected.
flannel-iface: "wg0" # Talos might have something similar.
I do use some node-labels and affinities to make sure the right pods end up in the right spot. For example the metallb annoucer always has to come from the hetzner node. As mentioned in my reply below, it takes about 20ms roundtrip back to my homelab, so my sites can take a bit of time to load, but it works pretty well otherwise, sort of similar to how cloudflare tunnels would work, except not as polished.
My setup is here if it is of help
https://git.kjuulh.io/kjuulh/clank-homelab-flux/src/branch/m...
Is this your use case?
https://docs.zerotier.com/bridging/
ZeroTier does L2.
What are your discovery mechanisms? I don't know what exists for automatic peer management with wg. If you're doing bgp evpn for vxlan endpoint discovery then I'd think WG over vxlan would be the easier to manage option.
If you actually want to use vxlan ids to isolate l2 domains, like if you want multiple hypervisors separated by public networks to run groups of VMs on distinct l2 domains, then vxlan over WG seems like the way to go.
For traversing public networks, simply consider BGP over Wireguard. VXLAN is not worth it.
I've used wireguard for a while, not sure why I never considered doing BGP over it, might make for a fun weekend project.
BGP is vastly superior to any L2 make-believe trash you can imagine, and amazingly, it often has better hardware offloading support for forwarding and firewalls. For example, 100G switches (L3+) like MikroTik's CRS504 do not support IPv6 in hardware for VXLAN-encapsulated flows, but everything just works if you choose to go the BGP route.
L2 is a total waste of time.
Any ASIC switch released in the last decade from Cisco/Juniper/Arista supports EVPN/VXLAN in hardware. EVPN is built on BGP. This has become the industry standard for new enterprise and cloud deployments.
The lack of support for hardware EVPN is one of the many reasons that Mikrotik is not considered for professional deployments.
Mikrotik is used for professional deployments all over the world. Right tool for the right job.
People who think one size fits all are not professional.
If I can source an enterprise Cisco/Juniper/Arista ASIC switch that is 1) rock-solid 2) full featured 3) cheaper - which I can - there is unfortunately no rationale where Mikrotik would be applicable in any professional project of mine.
With that said, I love Mikrotik for what it is: it is very approachable and it fills a niche. I believe it has added a lot of value to the industry and I'm excited to see their products mature.
vxlan inception is fun ! said no one ever !
What problem is being solved here?
Tell us why you think so at least.
Reduced MTU chopping off your maximum packet size from all the extra headers and other overhead you're adding?
WG is L3 transport
VXLAN is L2-like tranport over L3
You can have EoIP over WG with any VLANs you like.
You can have a VXLAN over plain IP, over EoIP, over WG, over IPSec. Only WG and IPSec (with not NULL sec) do providecany semblance ofvencryption in transit
And mandatory X\Y problem.
I mean, ultimately, thats how Google routes internally.
IPSec-equivalent, VXLAN-equivalent, IPSec-equivalent.
Prevents any compromised layer from knowing too much about the traffic.
Internal is fine because you control things like MTU so you don't have to worry about packet fragmentation/partial loss.
That seems like an awful amount of overhead for questionable gain.
Links between, and in between data centers use so called jumbo frames with an mtu of over 9000. Not joking.
What gave you that idea? Internally, Google uses GRE/GENEVE-like stuff but for reasons that have nothing to do with "preventing compromise" or whatever, but because they're carrying metadata (traces, latency budgets, billing ids.) That is to say, encapsulation is just transport. It's pretty much L3 semantics all the way down... In fact, this is more or less the point: L2 is intractable at scale, as broadcast/multicast doesn't work. However, it's hard to find comparisons to anything you're familiar with at Google scale. They have a myriad of proprietary solutions and custom protocols for routing, even though it's all L3 semantics. To learn more:
Andromeda https://research.google/pubs/andromeda-performance-isolation...
Orion https://research.google/pubs/orion-googles-software-defined-...
What gave me that idea? Talks and research papers from Google network engineers over the past decade.
Not sure I understand, but why not Tailscale?
In my case, Tailscale does not implement K8S CNI.