Assessing IBM's POWER8, Part 1: A Low Level Look at Little Endian
by Johan De Gelas on July 21, 2016 8:45 AM ESTClosing Thoughts
Testing both the IBM POWER8 and the Intel Xeon V4 with an unbiased compiler gave us answers to many of the questions we had. The bandwidth advantage of POWER8's subsystem has been quantified: IBM's most affordeable core can offer twice as much bandwidth than Intel's, at least if your application is not (perfectly) vectorized.
Despite the fact that POWER8 can sustain 8 instructions per clock versus 4 to 5 for modern Intel microarchitectures, chips based on Intel's Broadwell architecture deliver the highest instructions per clock cycle rate in most single threaded situations. The larger OoO buffers (available to a single thread!) and somewhat lower branch misprediction penalty seem to the be most likely causes.
However, the difference is not large: the POWER8 CPU inside the S812LC delivers about 87% of the Xeon's single threaded performance at the same clock. That the POWER8 would excel in memory intensive workloads is not a suprise. However, the fact that the large L2 and eDRAM-based L3 caches offer very low latency (at up to 8 MB) was a surprise to us. That the POWER8 won when using GCC to compile was the logical result but not something we expected.
The POWER8 microarchitecture is clearly built to run at least two threads. On average, two threads gives a massive 43% performance boost, with further peaks of up to 84%. This is in sharp contrast with Intel's SMT, which delivers a 18% performance boost with peaks of up to 32%. Taken further, SMT-4 on the POWER8 chip outright doubles its performance compared to single threaded situations in many of the SPEC CPU subtests.
All in all, the maximum throughput of one POWER8 core is about 43% faster than a similar Broadwell-based Xeon E5 v4. Considering that using more cores hardly ever results in perfect scaling, a POWER8 CPU should be able to keep up with a Xeon with 40 to 60% more cores.
To be fair, we have noticed that the Xeon E5 v4 (Broadwell) consumes less power than its formal TDP specification, in notable contrast to its v3 (Haswell) predecessor. So it must be said that the power consumption of the 10 core POWER8 CPU used here is much higher. On paper this is 190W + 64W Centaur chips, versus 145W for the Intel CPU. Put in practice, we measured 221W at idle on our S812LC, while a similarly equipped Xeon system idled at around 90-100W. So POWER8 should be considered in situations where performance is a higher priority than power consumption, such as databases and (big) data mining. It is not suited for applications that run close to idle much of the time and experience only brief peaks of activity. In those markets, Intel has a large performance-per-watt advantage. But there are definitely opportunities for a more power hungry chip if it can deliver significantly greater performance.
Ultimately the launch of IBM's LC servers deserves our attention: it is a monumental step forward for IBM to compete with Intel in a much larger part of the market. Those servers seem to be competitively priced with similar Xeon systems and can access the same Little Endian data as an x86 server. But can POWER8 based system really deliver a significant performance advantage in real server applications? In the next article we will explore the S812LC and its performance in a real server situations, so stay tuned.
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JohanAnandtech - Thursday, July 28, 2016 - link
Ah, you will have to wait for the improved P8 which is the first Power going after HPC :-)RISC is RISKY! - Tuesday, August 2, 2016 - link
I would support "Brutalizer". Every processor has its strength and weakness. If memory architecture is considered, for the same capacity, Intel is conjested memory, IBM is very distributed and Oracle-Sun is something in between. So Intel will always have memory B/W problem every way. IBM has memory efficiency problem. Oracle in theory doesn't have problem, but with 2 dimm per ch, that look like have problem. Oracle-Sun is for highly branched workload in the real world. Intel is for 1T/Core more of single threaded workloads and IBM is for mixed workloads with 2T-4T/Core priority. So supercomputing workloads will work fast on IBM now, compared to intel and sparc, while analytics and graph and other distributed will work faster on SPARC M7 and S7 (although S7 is resource limited). While for intel, a soft mix of applications and highly customized os is better. Leave the business decisions and the sales price. List prices are twice as much as sales price in the real world. These three processors (xeon e5v4, power8-9, sparc m7-s7) are thoroughly tuned for different work spaces with very little overlap. So there's no point in comparing them other than their specs. Its like comparing a falcon and a lion and a swordfish. Their environments are different even though all of them hunt. Thats in the real world. So benchmarks are not the real proof. We at the university of IITD have lots and lots of intel xeon e5v4, some P8 (10-15 single and dual sockets), and a very few (1-2 two socket M7 and 2 two socket S7). We run anything and every thing on any of these, we get our hands on. And this is the real world conclusion. So don't fight. Its a context centric supply.RISC is RISKY! - Tuesday, August 2, 2016 - link
of processors!rootvgnet - Friday, August 12, 2016 - link
Johan - interesting article, I enjoyed it - especially after I discovered how to get to the next page.As far as the comments go - 1) a good article will get a diverse response (from those with an open, read querying, mind.
2) I agree with those who, in other words are saying: "there is no 'one size fits all'." And my gut reaction is that you are providing a level of detail that assists in determining which platform/processor "fits my need"
Looking forward to part2.