A little less than 2 years ago, we investigated the first Arm server SoC that had a chance to compete with midrange Xeon E5s: the Cavium ThunderX. The SoC showed promise, however the low single-threaded performance and some power management issues relegated the 48-core SoC to more niche markets such as CDN and Web caching. In the end, Cavium's first server SoC was not a real threat to Intel's Xeon.

But Cavium did not give up, and rightfully so: the server market is more attractive than ever. Intel's datacenter group is good for about 20 Billion USD (!) in revenue per year. And even better, profit margins are in 50% range. When you want to profits and cash flow, the server market far outpaces any other hardware market. So following the launch of the ThunderX, Cavium promised to bring out a second iteration: better power management, better single thread performance and even more cores (54).

The trick, of course, is actually getting to a point where you can take on the well-oiled machine that is Intel. Arm, Calxeda, Broadcom, AppliedMicro and many others have made many bold promises over the past 5 years that have never materialized, so there is a great deal of skepticism – and rightfully so – towards new Arm Server SoCs.

However, the new creation of underdog Cavium deserves the benefit of the doubt. Much has changed – much more than the name alone lets on – as Cavium has bought the "Vulcan" design from Avago. Vulcan is a rather ambitious CPU design which was originally designed by the Arm server SoC team of Broadcom, and as a result has a much different heritage than the original ThunderX. At the same time however, based on its experience from the ThunderX, Cavium was able to take what they've learned thus far and have introduced some microarchitectural improvements to the Vulcan design to improve its performance and power.

As a result, ThunderX2 is a much more "brainiac" core than the previous generation. While the ThunderX core had a very short pipeline and could hardly sustain 2 instructions per clock, the Vulcan core was designed to fetch 8 and execute up to 4 instructions per clock. It gets better: 4 simultaneous threads can be active (SMT4), ensuring that the wide back-end is busy most of the time. 32 of those cores at clockspeeds up to 2.5 GHz find a home in the new ThunderX2 SoC.

With up to 128 threads running and no less than eight DDR4 controllers, this CPU should be able to perform well in all server situations. In other words, while the ThunderX (1) was relegated to niche roles, the ThunderX2 is the first Arm server CPU that has a chance to break the server market open.

Sizing Things Up: Specifications Compared
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  • name99 - Thursday, May 24, 2018 - link

    For crying out loud!
    At the very least, if you want to pursue this obsession regarding vectors, look at ARM's SVE (Scalable Vector Extensions). THAT is where ARM is headed in the vector space.
    Fujitsu is implementing these for the cores of its next HPC machines, and they will likely roll out into other ARM cores (maybe Apple first? but who can be sure?) over the next few years.

    To the extent that Cavium has any interest in competing in HPC, if/when they choose to do so it will be on the basis of an SVE implementation, not on the basis of NEON.

    Meanwhile ARMv8 NEON is very much the equivalent of SSE. Not AVX, no, but SSE (in all its versions) yes.
    Reply
  • tuxRoller - Thursday, May 24, 2018 - link

    Nice comment.
    BTW, centriq (rip) only supports(ed) aarch64. I've no idea how much die space that saved, though.
    Reply
  • Wilco1 - Thursday, May 24, 2018 - link

    There is Cortex-A35, smallest AArch64 core so far with FP and Neon.

    However there are still big differences between RISC and CISC. For example it's not feasible for CISC to get anywhere near the same size/perf/power. The mobile Atom debacle has clearly shown it's not feasible to match small and efficient RISCs even with a better process and many billions of dollars...
    Reply
  • peevee - Thursday, May 24, 2018 - link

    It is not 8.2. Reply
  • lmcd - Wednesday, January 23, 2019 - link

    Necro but worth for historic reasons: A35 is AArch32 but ARMv8 Reply
  • ZolaIII - Thursday, May 24, 2018 - link

    It would took them a same. AVX is a SIMD FP extension to the prime architectural instruction set same as NEON and cetera. The strict difference between CISC and RISC architecture is long gone and today's one's are combined & further more implement IVIL SIMDs and more & more of DSP components as MAC's. The train only starts on prime integer instruction set (where by the way ARM is stellar) and then switches it's worker's to FP extensions and accelerated blocks of different kinds. The same way lintel grow up AVX to 512 bit in current use NEON can be scaled up & beyond. Fuitsu worked with ARM on 1024 & 2048 NEON SIMD blocks couple of years ago. Still if you think how FP is a best way to do it you are wrong, DSP's use CP and it's much more efficient power & performance wise but less scalable.

    On what would you like server's to be compared? Almost 90% of enterprise servers run on Linux, even Microsoft is earning more money this day's on Linux than from selling Windows desktop & server's combined.
    You are very ignorant person. Why do you coment about the things you don't know anything about?
    Reply
  • Ryan Smith - Thursday, May 24, 2018 - link

    "I really think Anandtech needs to branch into different websites. Its very strange and unappealing to certain users to have business/consumer/random reviews/phone info all bunched together."

    Although I appreciate the feedback, I must admit that we enjoy doing a variety of things. There are a lot of cool things happening in the technology world, not all of which are in the consumer space. So rare articles like these - and we only publish a few a year - let us keep tabs on what's going on in some of those other markets.
    Reply
  • HStewart - Wednesday, May 23, 2018 - link

    I would think that a lot of this depends what type of applications are running on server. Highly mathematical and especially any with Vectors will be likely different. Also there is no support for Windows based servers which limits which applications can be done - so my guess this will be useless if desiring a VMWave server.

    But it is interesting that it takes a 4SMT to compete with x86 based servers from Intel and AMD and with more cores 32 vs 22/28 depending on version.
    Reply
  • Wilco1 - Wednesday, May 23, 2018 - link

    You're right, on floating point and vectors the results are different. To be precise - even more impressive. See the last page for example where it soundly beats Skylake on OpenFoam and a few other HPC benchmarks. Hence the huge interest from all the HPC companies.

    Note Windows has been running on Arm for quite some time. Microsoft runs Windows Server both on Centriq and ThunderX2. See eg. https://www.youtube.com/watch?v=uF1B5FfFLSA for more info.
    Reply
  • HStewart - Wednesday, May 23, 2018 - link

    Windows on ARM is DOA, Reply

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