Section by Ian Cutress

The launch of Intel’s Ice Lake Xeon Scalable processors has been in the wings for a number of years. The delays to Intel’s 10nm manufacturing process have given a number of setbacks to all of Intel’s proposed 10nm product lines, especially the high performance Xeon family: trying to craft 660 mm2 of silicon on a process is difficult at the best of times. But Intel has 10nm in a place where it is economically viable to start retailing large Xeon processors, and the official launch today of Intel’s 3rd Generation Xeon Scalable is on the back of over 200,000+ units shipped to major customers to date. The new flagship, the Xeon Platinum 8380, has 40 cores, offers PCIe 4.0, and takes advantage of the IPC gain in Intel’s Sunny Cove processor core. We’re testing it against the best in the market.

Intel’s 3rd Generation Xeon Scalable: 10nm Goes Enterprise

Today Intel is launching the full stack of processors under the 3rd Generation Xeon Scalable Ice Lake branding, built upon its 10nm process. These processors, up to 40 cores per socket, are designed solely for single socket and dual socket systems, competing in a market with other x86 and Arm options available. With this new generation, Intel’s offering is aimed to be two-fold: first, the generational uplift compared to 2nd Gen, but also the narrative around selling a solution rather than simply selling a processor.

Intel’s messaging with its new Ice Lake Xeon Scalable (ICX or ICL-SP) steers away from simple single core or multicore performance, and instead is that the unique feature set, such as AVX-512, DLBoost, cryptography acceleration, and security, along with appropriate software optimizations or paired with specialist Intel family products, such as Optane DC Persistent Memory, Agilex FPGAs/SmartNICs, or 800-series Ethernet, offer better performance and better metrics for those actually buying the systems. This angle, Intel believes, puts it in a better position than its competitors that only offer a limited subset of these features, or lack the infrastructure to unite these products under a single easy-to-use brand.


An Wafer of 40-core Ice Lake Xeon 10nm Processors

Nonetheless, the launch of a new generation of products and an expanded portfolio warrants the product to actually be put under test for its raw base performance claims. This generation of Xeon Scalable, Intel’s first on 10nm, uses a newer architecture Sunny Cove core. Benefits of this core, as explained by Intel, start with an extra 20% raw performance increase, enabled through a much wider core with an improved front end and a more execution resources.  Outside of the core, memory bandwidth is improved both by increasing memory channels from six to eight, but also new memory prefetch techniques and optimizations that increases bandwidth up to 100% with another +25% efficiency. The mesh interconnect between the cores also uses updated algorithms to feed IO to and from the cores, and Intel is promoting better power management through independent power management agents inside each IP block.

On top of this, Intel is layering on accelerative features, stating that over the raw performance, software optimized for these accelerators will see a better-than-generational uplift. This starts with the basic core layout, especially as it pertains to SIMD commands such as SSSE, AVX, AVX2, and AVX-512: Intel is enabling better cryptography support across its ISA, enabling AES, SHA, GFNI, and other instructions to run simultaneously across all vector instruction sets. AVX-512 has improved frequencies during more complex bit operations for ICX with smarter mapping between instructions and power draw, offering an extra 10% frequency for all 256-bit instructions. On top of this is Intel’s Speed Select Technologies, such as Performance Profile, Base Frequency improvements, Turbo Frequency improvements, and Core Power assistance to ensure peak per-core performance or quality of service during a heavily utilized system depending on customer requirements. Other new features include Software Guard Extensions, enabling enclave sizes up to 512 GB per socket with select models.

Ice Lake’s Sunny Cove Core: Part 2

The Sunny Cove core has actually already been in the market. Intel has made a consumer variant of the core and a server variant of the core. Ice Lake Xeon has the server variant, with bigger caches and slightly different optimization points, but it’s the consumer variant that we have seen and tested in laptop form. Sunny Cove is part of Intel’s Ice Lake notebook processor portfolio, which we reviewed the performance back on August 1st 2019, which 614 days ago. That length of time between enabling a core for notebooks and enabling the same core (with upgrades for servers) on enterprise is almost unheard of, but indicative of Intel’s troubles in manufacturing.

Nonetheless, in our notebook testing of the Ice Lake core, we saw a raw +17-18% performance over the previous generation, however this was at the expense of 15-20% in frequency. Where the product truly excelled was in memory limited scenarios, where a new memory controller provided better-than-generational uplift. When it comes to this generation of Xeon Scalable processors with the new core, as you see in the review, in non-accelerated workloads we get very much a similar story. That being said, consumer hardware is very often TDP limited, especially laptops! With the new Ice Lake Xeon platform, Intel is boosting the peak TDP from 205 W to 270 W, which also gives additional performance advantages.

The Headline Act: Intel’s Xeon Platinum 8380

The head prefect of Intel’s new processor lineup is the Platinum 8380 - a full fat 40 core behemoth. If we put it side by side with the previous generation processors, there some key specifications to note.

Intel Xeon Comparison: 3rd Gen vs 2nd Gen
Peak vs Peak
Xeon Platinum
8380
AnandTech Xeon Platinum
8280
40 / 80 Cores / Threads 28 / 56
2900 / 3400 / 3000 Base / ST / MT Freq 2700 / 4000 / 3300
50 MB + 60 MB L2 + L3 Cache 28 MB + 38.5 MB
270 W TDP 205 W
PCIe 4.0 x64 PCIe PCIe 3.0 x48
8 x DDR4-3200 DRAM Support 6 x DDR4-2933
4 TB DRAM Capacity 1 TB
200-series Optane 100-series
4 TB Optane
+ 2 TB DRAM
Optane Capacity
Per Socket
1 TB DDR4-2666
+ 1.5 TB 
512 GB SGX Enclave None
1P, 2P Socket Support 1P, 2P, 4P, 8P
3 x 11.2 GT/s UPI Links 3 x 10.4 GT/s
$8099 Price (1ku) $10099*
6258R, 2P Variant
is only $3950

Between these processors, the new flagship has a number of positives:

  • +43% more cores (40 vs 28),
  • nearly double the cache,
  • +33% more PCIe lanes (64 vs 48),
  • 2x the PCIe bandwidth (PCIe 4.0 vs PCIe 3.0)
  • 4x the memory support (4 TB vs 1 TB)
  • SGX Enclave support
  • +7% higher socket-to-socket bandwidth
  • Support for DDR4-3200 Optane DCPMM 200-series
  • Price is down 20%... or up 100% if you compare to 6258R

Though we should perhaps highlight some of the negatives:

  • TDP is up +32% (270 W vs 205 W)
  • ST Frequency is down (3400 MHz vs 4000 MHz)
  • MT Frequency is down (3000 MHz vs 3300 MHz)

If we combine the specification sheet cores and all-core (MT) frequency, Ice Lake actually has about the same efficiency here as the previous generation. Modern high-performance processors often operate well outside the peak efficiency window, however Ice Lake being at a lower frequency would usually suggest that Ice Lake is having to operate closer to the peak efficiency point to stay within a suitable socket TDP than previous generations. This is similar to what we saw in the laptop space.

Features across all Ice Lake Xeon Scalable processors

We’ll dive into the different processors over on the next page, however it is worth noting some of the key features that will apply to all of Intel’s new ICL-SP family. Across the ~40 new processors, including all the media focused parts, the network focused processors, and all the individual optimizations used, all of the processors will have the following:

  • All Ice Lake Xeons will support eight channels of DDR4-3200 at 2DPC (new info)
  • All Ice Lake Xeons will support 4 TB of DRAM per socket
  • All Ice Lake Xeons will support SGX Enclaves (size will vary)
  • All Ice Lake Xeons will support 64x PCIe 4.0 lanes
  • All Ice Lake Xeons will support 2x FMA
  • Platinum/Gold Xeons will support 3x UPI links at 11.2 GT/s, Silver is 2x links at 10.4 GT/s
  • Platinum/Gold Xeons will support 200-series Optane DC Persistent Memory

In the past, Intel has often productized some of these features at will sell the ones that are more capable at a higher cost. This segmentation is often borne from a lack of competition in the market. This time around however, Intel has seen fit to unify some of its segmentation for consistency. The key one in my mind is memory support: at the start of the Xeon Scalable family, Intel started to charge extra for high-capacity memory models. But in light of the competition now offering 4 TB/socket at no extra cost, it would appear that Intel has decided to unify the stack with one memory support option.

Intel 3rd Generation Xeon Scalable: New Socket, New Motherboards

Ice Lake Xeons, now with eight memory channels rather than six, will require a new socket and new motherboards. Ice Lake comes with 4189 pins, and requires an LGA4189-4 ‘Whitley’ motherboard. This is different to the LGA4189-5 ‘Cedar Island’ in use for Cooper Lake, and the two are not interoperable, however they do share a power profile.

This actually brings us onto a point about Intel’s portfolio. Technically 10nm Ice Lake is not the only member of the 3rd Gen Xeon Scalable family – Intel has seen fit to bundle both 14nm Cooper Lake and 10nm Ice Lake under the same heading. Intel is separating the two by stating that Cooper Lake is focused at several specific high volume customers looking to deploy quad-socket and eight-socket systems with specific AI workloads. By comparison, Ice Lake is for the mass market, and limited to two socket systems.

Ice Lake and Cooper Lake both have the ‘3’ in the processor name indicating third generation. Users can tell which ones are Cooper Lake because they end in either H or HL – Ice Lake processors (as we’ll see on the next page) never have H or HL. Most Cooper Lake processors are Platinum models anyway, with a few Xeon Gold. As we go through this review, we’ll focus solely on Ice Lake, given that this is the platform Intel is selling to the mainstream.

This Review

In the lead up to this launch today, Intel provided us with a 2U system featuring two of the top models of Ice Lake Xeon: we have dual 40 core Xeon Platinum 8380s! At the same time, we have also spent time a dual Xeon Gold 6330 system from Supermicro, which has two 28-core processors, and acts as a good comparison to the previous generation Xeon Platinum 8280.

Our review today will cover the processor stack, our benchmarks, power analysis, memory analysis, and some initial conclusions.

Ice Lake Xeon Processor List and Competition
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  • fallaha56 - Tuesday, April 6, 2021 - link

    sure

    but when your 64-core part virtually beats Intel's dual socket 32-core part on performance alone?

    add the energy savings and suddenly it's a 300-400% perf lead
  • Jorgp2 - Tuesday, April 6, 2021 - link

    The fuck?

    You do realize that they put more than CPUs onto servers right?
  • Andrei Frumusanu - Tuesday, April 6, 2021 - link

    We are testing non-production server configurations, all with varying hardware, PSUs, and other setup differences. Socket comparisons remain relatively static between systems.
  • edzieba - Tuesday, April 6, 2021 - link

    Would be interesting to pit the 4309 (or 5315) against the Rocket Lake octacores. Yes, it's a very different platform aimed at a different market, but it would be interesting to see what a hypothetical '10nm Sunny Cove consumer desktop' could have resembled compared to what Rocket Lake's Sunny Cove delivered on 14nm.
  • Jorgp2 - Tuesday, April 6, 2021 - link

    You could also compare it to the 10900x, which is an existing AVX-512 CPU with large L2 caches.
  • Holliday75 - Tuesday, April 6, 2021 - link

    Typical consumer workloads the RL will be better. For typical server workloads the IL will be better. That is the gist of what would be said.
  • ricebunny - Tuesday, April 6, 2021 - link

    These tests are not entirely representative of real world use cases. For open source software, the icc compiler should always be the first choice for Intel chips. The fact that Intel provides such a compiler for free and AMD doesn’t is a perk that you get with owning Intel. It would be foolish not to take advantage of it.
  • Andrei Frumusanu - Tuesday, April 6, 2021 - link

    AMD provides AOCC and there's nothing stopping you from running ICC on AMD either. The relative positioning in that scenario doesn't change, and GCC is the industry standard in that regard in the real world.
  • ricebunny - Tuesday, April 6, 2021 - link

    Thanks for your reply. I was speaking from my experience in HPC: I’ve never compiled code that I intended to run on Intel architectures with anything but icc, except when the environment did not provide me such liberty, which was rare.

    If I were to run the benchmarks, I would build them with the most optimal settings for each architecture using their respective optimizing compilers. I would also make sure that I am using optimized libraries, e.g. Intel MKL and not Open BLAS for Intel architecture, etc.
  • Wilco1 - Tuesday, April 6, 2021 - link

    And I could optimize benchmarks using hand crafted optimal inner loops in assembler. It's possible to double the SPEC score that way. By using such optimized code on a slow CPU, it can *appear* to beat a much faster CPU. And what does that prove exactly? How good one is at cheating?

    If we want to compare different CPUs then the only fair option is to use identical compilers and options like AnandTech does.

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