Not Quite a Pentium, Not Quite an Atom: The Larrabee Core

Intel gave us enough information about Larrabee to begin a discussion of specifications, but not enough to even begin making any conclusions. We'll start with what we pretty much already know.

Intel's Larrabee is built out of a number of x86 cores that look, at a very high level, like this:

Each core is a dual-issue, in-order architecture loosely derived from the original Pentium microprocessor. The Pentium core was modified to include support for 64-bit operations, the updates to the x86 instruction set, larger caches, 4-way SMT/Hyper Threading and a 16-wide vector ALU.

While the team that ended up working on Atom may have originally worked on the Larrabee cores, there are some significant differences between Larrabee and Atom. Atom is geared towards much higher single threaded performance, with a deeper pipeline, a larger L2 cache and additional microarchitectural tweaks to improve general desktop performance.

  Intel Larrabee Core Intel Pentium Core (P54C) Intel Atom Core
Manufacturing Process 45nm 0.60µm 45nm
Simultaneous Multi-Threading 4-way 1-way 2-way
Issue Width dual-issue dual-issue dual-issue
Pipeline Depth 5-stages (?) 5-stages 16-stages
Scalar Execution Resources 2 x Integer ALUs (?)
1 x FPU (?)
2 x Integer ALUs
1 x FPU
2 x Integer ALUs
1 x FPU
Vector Execution Resources 16-wide Vector ALU None 1 x SIMD SSE
L1 Cache (I/D) 32KB/32KB 8KB/8KB 32KB/24KB
L2 Cache 256KB None (External) 512KB
ISA 64-bit x86
SSEn support?
Parallel/Graphics?
32-bit x86 64-bit x86
Full Merom ISA compatibility

 

Larrabee on the other hand is more Pentium-like to begin with; Intel states that Larrabee's execution pipeline is "short" and followed up with us by saying that it's closer to the 5-stage pipeline of the original Pentium than the 16-stage pipeline of Atom. While both Atom and Larrabee support SMT (Simultaneous Multi-Threading), Larrabee can work on four threads concurrently compared to two on Atom and one on the original Pentium.

L1 cache sizes are similar between Larrabee and Atom, but Larrabee gets a full 32KB data cache compared to 24KB on Atom. If you remember back to our architectural discussion of Atom, the smaller L1 D-cache was a side effect of going to a register file instead of a small signal array for the cache. Die size increased but operating voltage decreased, forcing Atom to have a smaller L1 D-cache but enabling it to reach lower power targets. Larrabee is a little less constrained and thus we have conventional balanced L1 caches, at 4x the size of that in the original Pentium.

The Pentium had no on-die L2 cache, it relied on external SRAM to be installed on the motherboard. In order to maintain good desktop performance Atom came equipped with a 512KB L2 cache, while each Larrabee core will feature a 256KB L2 cache. Larrabee's architecture does stress the importance of large, fast caches as you'll soon see, but 256KB is the right size for Intel's architecture at this point. Larrabee's default OpenGL/DirectX renderer is tile based and it turns out that most 64x64 or 128x128 tiles with 32-bit color/32-bit Z can fit in a 128KB space, leaving an additional 128KB left over for caching additional data. And remember, this is just on one Larrabee core - the whole GPU will be built out of many more.

The big difference between Larrabee, Pentium and Atom is in the vector execution side. The original Pentium had no SIMD units, Atom added support for SSE and Larrabee takes a giant leap with a massive 16-wide vector ALU. This unit is able to work on up to 16 32-bit floating point operations simultaneously, making it far wider than any of the aforementioned cores. Given the nature of the applications that Larrabee will be targeting, such a wide vector unit makes total sense.

Other changes to the Pentium core that made it into Larrabee are things like 64-bit x86 support and hardware prefetchers, although it is unknown as to how these compare to Atom's prefetchers. It is a fair guess to say that prefetching will include optimizations for data parallel situations, but whether this is in addition to other prefetch technology or a replacement for it is something we'll have to wait to find out.

The Design Experiment: Could Intel Build a GPU? Drilling Deeper and Making the AMD/NVIDIA Comparison
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  • Griswold - Monday, August 4, 2008 - link

    You seem to be confused. Time for a nap.
  • MDme - Monday, August 4, 2008 - link

    but AMD will have Cinema 2.0. did you see that demo? by 2010, AMD will have the RV990 or whatever...and Nvidia will have GT400?
  • phaxmohdem - Monday, August 4, 2008 - link

    Considering how long it took nVidia to release a single GPU significantly faster than G80, I'd be shocked if we wee GT300 by 2009/2010. however a GTX 295GT X2 ULTRA OC is not out of the question ;)
  • shuffle2 - Monday, August 4, 2008 - link

    mm², how hard is that to write? >.>
  • 1prophet - Monday, August 4, 2008 - link

    They need to hit one out of the park with the drivers (software)as well.
  • jltate - Tuesday, August 5, 2008 - link

    I've got a bunch of comments, so I'll just list them all here.

    SSE doesn't have fused multiply-add operations. Larrabee does -- thus that 10 core processor could perform a peak of 320 floating point operations per cycle (it's mentioned in the SIGGRAPH paper).

    Larrabee's programming model is variable width -- the hardware can and likely will be augmented in the future to perform more than just 16 operations in parallel.

    The ring bus between cores was stated to be for each group of 16. Intel stated that for more than 16 cores they'd use "multiple short-linked rings".

    Also, the diagram only shows one memory controller on one side with fixed function logic on the other, not two memory controllers as you showed on page 5 of your article. However, Intel stated in the paper that the configuration and number of processors, fixed function blocks and I/O controllers would be implementation dependent. So in effect it could very well have a half-dozen 64-bit interfaces like G80.

    My forecast? This thing will rock. I for one simply cannot wait.
  • Laura Wilson - Monday, August 4, 2008 - link

    that's the truth

    they say they know this. it sounds like they know this ... we'll see what happens :-)
  • gigahertz20 - Monday, August 4, 2008 - link

    I'm going to predict Larrabee will provide a huge boost of performance over Intel's current crappy integrated graphic solutions, but will not be able to compete with AMD/ATI's and Nvidia's high end GPU's when it (Larrabee) finally launches. If Intel can deliver a monster that can push 100+ FPS in Crysis and doesn't cost so much that it breaks the bank like the current Nvidia GTX 280's, then they will have a real winner! When it finally launches though, who knows what AMD/ATI and Nvidia will have out to compete against it, wonder if Intel is just trying to push out a mainstream chip or go high end as well...guess I need to read the rest of the article :)
  • JEDIYoda - Tuesday, August 5, 2008 - link

    dreaming again huh??? you people who want top notch performance without having to pay for it....rofl..hahaha
  • FITCamaro - Monday, August 4, 2008 - link

    This isn't mean to compete with their IGPs. At least not initially.

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