ARM based servers hold the promise of extremely low power and excellent performance per Watt ratios. It's theoretically possible to place an incredible number of servers into a single rack; there are already implementations with as many as 1000 ARM servers in one rack (48 server nodes in a 2U chassis). What's more, all of those nodes consume less than 5KW combined (or around 5W per quad-core ARM node). But whenever a new technology is hyped, it's important to remain objective. The media loves to rave about new trends and people like reading about "some new thing"; however, at the end of the day the system administrator has to keep his IT services working and convince his boss to invest in new technologies.

At first sight, the relatively low performance per core of ARM CPUs seems like a bad match for servers. The dominant CPU in the server market is without doubt Intel's Xeon. The success of the Xeon family is largely rooted in its excellent single-threaded (or per core) performance at moderate power levels (70-95W). Combine this exceptional single-threaded performance with a decent core count and you get good performance in almost any kind of application. Economies of scale and the resulting price levels are also very important, but the server market has been more than willing to pay a little extra if the response times are lower and the energy bills moderate.

A data point proving that single-threaded performance is still important is the evolution of the T-series of Oracle (or Sun if you prefer). The Sun T3 had 16 cores with 128 threads; the T4 however had only 8 cores with 8 threads each, and CEO Larry Ellison touted more than once that single-threaded performance was massively improved, up to five times faster. Do we really need another server with a flock of slow but energy efficient cores? Has history not taught us that a few "bulls" is better than "a flock of chickens"?

History has also shown that the amount of memory per server is very important. Many HPC and virtualization applications are limited by the amount of RAM. The current Cortex-A9 generation of ARM CPUs has a 32-bit address bus and does not support more than 4GB.

And yet, the interest in ARM-based servers is growing, and there is more to it than just hype. Yes, ARM-based CPUs still lack the number crunching power and the massive amount of DIMM slots that Xeon's memory controller can handle, but ARM CPUs score extremely well when it comes to cost and power consumption.

ARM based CPU have also made giant steps forward when it comes to performance. To give you a few data points: a dual ARM Cortex-A9 at 1.2GHz (Samsung Exynos 1.2GHz) introduced in 2011 compresses more than 10 times faster than the typical ARM 11 based cores in 2008. The SunSpider performance increased by a factor 20 according to Anand's measurements on the iPhones (though part of that is almost certainly thanks to browser and software optimizations). The latest ARM Cortex-A15 is again quite a bit more powerful, offering about 50% higher performance. The A57 will add 64-bit support and is estimated to deliver 20 to 30% higher performance. In short, the single-threaded performance is increasing quickly, and the same is true for the amount of RAM that can be addresssed. The ARM Cortex-A9 is limited to 4GB but the Cortex-A15 should be able to address 16GB while the A57 will be able to address a lot more.

It is likely just a matter of time before ARM products can start to chip away at segments of the server market. How much time? The best way to find out is to look at the most mature ARM server shipping today: the Calxeda based Boston Viridis. Just what can this server handle today, where does it have the potential to succeed, and what are its shortcomings? Let's find out.

It's a Cluster, Not a Server
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  • Gigaplex - Tuesday, March 12, 2013 - link

    I wouldn't call that a spectacular performance per watt ratio. It's a bit faster than the Xeon under a cherry picked benchmark (much slower under others), and is only marginally lower power. Best case it's an 80% improvement over Sandy Bridge with regards to performance per watt, and Atom wasn't represented. Considering all the hype, I was expecting something a little more... exciting. Ignoring Ivy Bridge improvements, Haswell isn't far off. Reply
  • spronkey - Tuesday, March 12, 2013 - link

    Yeah... I agree. It also only seems to really come into its own in high concurrency. The Xeons idle quite similarly in terms of power - what happens if you compare it to more Xeon cores? It seems like on a per core basis, Intel still has the advantage on both fronts? Reply
  • spronkey - Tuesday, March 12, 2013 - link

    I would also point out that the A15 has already been compared against Sandy and Ivy cores and come up short in performance per watt; so I'm very interested to see what the next step for these ARM node servers is. Reply
  • JohanAnandtech - Wednesday, March 13, 2013 - link

    I warned against the hype in the first sentences. :-) ARM CPUs are still rather weak and not a good match for most applications. However, the fact that we could actually find a case where they do a lot better than the current Xeon systems was surprising to me. Reply
  • wsw1982 - Wednesday, April 03, 2013 - link

    No, it should not surprise any people regarding how picky the use case is. I mean, I do think you can find a use case the ARM 11 output perform Xeon. E.g. Serving 1 web request per hour :) Reply
  • LogOver - Tuesday, March 12, 2013 - link

    24 servers ran inside 24 VM's on Xeon server, while for ARM server you used the 24 physical server nodes... Hmm... Does not seems to me like apple to apple comparison. Why not to compare, for example, 16 physical nodes on both, xeon and arm servers? Reply
  • haplo602 - Wednesday, March 13, 2013 - link

    And how do you slice the Xeon server into 16 physical nodes ? It does not support any kind of HW partitioning that I am aware of. On the other hand the Calxeda machine is a cluster by design. If you try 16 Xeon nodes you'll go through the roof with power. Reply
  • Colin1497 - Wednesday, March 13, 2013 - link

    I think the question is this:

    Was 24 VM's optimal for the Xeon? Since we're visualizing the Xeon, why 24? Just because you had 24 ARM nodes? Would the Xeon done better with 4VM's? Or 16? Or 1000? 24 seems arbitrary.
    Reply
  • JohanAnandtech - Wednesday, March 13, 2013 - link

    We tested with 16 as I briefly mentioned in the conclusion. The 2650L did 170 responses/s per VM, or about 40% better. Total Throughput = 2.7k/s, while with 24, 2.9 K/s. THe flexibility that the Xeon has to reduce the number of VMs if higher throughput is necessary is definitely an advantage, but the performance numbers are not that different with different VM configs. Reply
  • Kurge - Wednesday, March 13, 2013 - link

    How about with 0 VM's? Just run it on the metal. Reply

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