* Owen DeLong
On Nov 4, 2012, at 1:55 AM, Tore Anderson <tore.anderson@redpill-linpro.com> wrote:
* Owen DeLong
What do you get from SIIT that you don't get from dual stack in a datacenter?
In no particular order:
- Single stack is much simpler than dual stack. A single stack to configure, a single ACL to write, a single service address to monitor, staff needs to know only a single protocol, deveopment staff needs only develop and do QA for a single protocol, it's a single topology to document, a single IGP to run and monitor, a single protocol to debug and troubleshoot, one less attack vector for the bad guys, and so on. I have a strong feeling that the reason why dual stack failed so miserably as a transition mechanism was precisely because of the fact that it adds significant complexity and operational overhead, compared to single stack.
Except that with SIIT, you're still dealing with two stacks, just moving the place where you deal with them around a bit. Further, you're adding the complication of NAT into your world (SIIT is a form of NAT whether you care to admit that to yourself or not).
The difference is that only a small number of people will need to deal with the two stacks, in a small number of places. They way I envision it, the networking staff would ideally operate SIIT a logical function on the data centre's access routers, or their in their backbone's core/border routers. A typical data centre operator/content provider has a vastly larger number of servers, applications, systems administrators, and software developers, than they have routers and network administrators. By making IPv4 end-user connectivity a service provided by the network, you make the amount of dual stack-related complexity a fraction of what it would be if you had to run dual stack on every server and in every application. I have no problem admitting that SIIT is a form of NAT. It is. The «T» in both cases stands for «Translation», after all.
- IPv4 address conservation. If you're running out of IPv4 addresses, you cannot use dual stack, as dual stack does nothing to reduce your dependency on IPv4 compared to single stack IPv4. With dual stack, you'll be using (at least) one IPv4 address per server, plus a bit of overhead due to the server LAN prefixes needing to be rounded up to the nearest power or two (or higher if you want to accommodate for future growth), plus overhead due to the network infrastructure. With SIIT, on the other hand, you'll be using a single IPv4 address per publicly available service - one /32 out of a pool, with nothing going to waste due to aggregation, network infrastructure, and so on.
Since you end up dealing with NAT anyway, why not just use NAT for IPv4 conservation. It's what most engineers are already used to dealing with and you don't lose anything between it and SIIT. Further, for SIIT to work, you don't really conserve any IPv4 addresses, since address conservation requires state.
Nope! The «S» in SIIT stands for «Stateless». That is the beauty of it. NAT44, on the other hand, is stateful, a very undesirable trait. Suddenly, things like flows per second and flow initiation rate is relevant for the overall performance of the architecture. It requires flows to pass bidirectionally across a single instance - the servers' default route must point to the NAT44, and a failure will cause the disruption of all existing flows. It is probably possible to find ways to avoid some or all of these problems, but it comes at the expense of added complexity. SIIT, on the other hand, is stateless, so you can use anycasting with normal routing protocols or load balancing using ECMP. A failure handled just like any IP re-routing event. You don't need the server's default route to point to the SIIT box, it is just a regular IPv6 route (typically a /96). You don't even have to run it in your own network. Assuming we have IPv6 connectivity between us, I could sell you SIIT service over the Internet or via a direct peering. (I'll be happy to give you a demo just for fun, give me an IPv6 address and I'll map up a public IPv4 front-end address for you in our SIIT deployment.) Finally, by putting your money into NAT44 for IPv4 conservation, you have accomplished exactly *nothing* when it comes to IPv6 deployment. You'll still have to go down the dual stack route, with the added complexity that will cause. With SIIT, you can kill both birds with one stone.
- Promotes first-class native IPv6 deployment. Not that dual stack isn't native IPv6 too, but I do have the impression that often, IPv6 in a dual stacked environment is a second class citizen. IPv6 might be only partially deployed, not monitored as well as IPv4, or that there are architectural dependencies on IPv4 in the application stack, so that you cannot just shut off IPv4 and expect it to continue to work fine on IPv6 only. With SIIT, you get only a single, first-class, citizen - IPv6. And it'll be the only IPv6 migration/transition/deployment project you'll ever have to do. When the time comes to discontinue support for IPv4, you just remove your IN A records and shut down the SIIT gateway(s), there will be no need to touch the application stack at all.
Treating IPv6 as a second class citizen is a choice, not an inherent consequence of dual-stack. IPv6 certainly isn't a second class citizen on my network or on Hurricane Electric's network.
Agreed, and I have no reason to doubt that HE does dual stack really well. That said, I don't think HE is the type of organisation for which SIIT makes the most sense - certainly not for your ISP activities. The type of organisation I picture using SIIT, is one that operates a bunch of servers and application cluster, i.e., they are controlling the entire service stack, and making them available to the internet through a small number of host names. Most internet content providers would fall in this category, including my own employer. -- Tore Anderson Redpill Linpro AS - http://www.redpill-linpro.com/