Rocking Team » Processors

Intel’s forthcoming many core processor codenamed ‘Larrabee’

Alex Jose — Thu, 03 Dec 2009 09:03:26 +0000

Intel Corporation is presenting a paper at the SIGGRAPH 2008 industry conference in Los Angeles on Aug. 12 that describes features and capabilities of its first-ever forthcoming “many-core” blueprint or architecture codenamed “Larrabee.”

Details unveiled in the SIGGRAPH paper include a new approach to the software rendering 3-D pipeline, a many-core (many processor engines in a product) programming model and performance analysis for several applications.

Larrabee

The first product based on Larrabee will target the personal computer graphics market and is expected in 2009 or 2010. Larrabee will be the industry’s first many-core x86 Intel architecture, meaning it will be based on an array of many processors. The individual processors are similar to the Intel processors that power the Internet and the laptops, PCs and servers that access and network to it.

Larrabee is expected to kick start an industry-wide effort to create and optimize software for the dozens, hundreds and thousands of cores expected to power future computers. Intel has a number of internal teams, projects and software-related efforts underway to speed the transition, but the tera-scale research program has been the single largest investment in Intel’s technology research and has partnered with more than 400 universities, DARPA and companies such as Microsoft and HP to move the industry in this direction.

Over time, the consistency of Intel architecture and thus developer freedom afforded by the Larrabee architecture will bring about massive innovation in many areas and market segments. For example, while current games keep getting more and more realistic, they do so within a rigid and limited framework. Working directly with some of the world’s top 3-D graphics experts, Larrabee will give developers of games and APIs (Application Programming Interface) a blank canvas onto which they can innovate like never before.

Initial product implementations of the Larrabee architecture will target discrete graphics applications, support DirectX and OpenGL, and run existing games and programs. Additionally, a broad potential range of highly parallel applications including scientific and engineering software will benefit from the Larrabee native C/C++ programming model.

Additional details of the Larrabee architecture discussed in this paper include:

The Larrabee architecture has a pipeline derived from the dual-issue Intel Pentium® processor, which uses a short execution pipeline with a fully coherent cache structure. The Larrabee architecture provides significant modern enhancements such as a wide vector processing unit (VPU), multi-threading, 64-bit extensions and sophisticated pre-fetching. This will enable a massive increase in available computational power combined with the familiarity and ease of programming of the Intel architecture.
Larrabee also includes a select few fixed function logic blocks to support graphics and other applications. These units are carefully chosen to balance strong performance per watt, yet contribute to the flexibility and programmability of the architecture.
A coherent on-die 2nd level cache allows efficient inter-processor communication and high-bandwidth local data to be access by CPU cores, making the writing of software programs simpler.
The Larrabee native programming model supports a variety of highly parallel applications, including those that use irregular data structures. This enables development of graphics APIs, rapid innovation of new graphics algorithms, and true general purpose computation on the graphics processor with established PC software development tools.
Larrabee features task scheduling which is performed entirely with software, rather than in fixed function logic. Therefore rendering pipelines and other complex software systems can adjust their resource scheduling based each workload’s unique computing demand.
The Larrabee architecture supports four execution threads per core with separate register sets per thread. This allows the use of a simple efficient in-order pipeline, but retains many of the latency-hiding benefits of more complex out-of-order pipelines when running highly parallel applications.
The Larrabee architecture uses a 1024 bits-wide, bi-directional ring network (i.e., 512 bits in each direction) to allow agents to communicate with each other in low latency manner resulting in super fast communication between cores.
The Larrabee architecture fully supports IEEE standards for single and double precision floating-point arithmetic. Support for these standards is a pre-requisite for many types of tasks including financial applications.

Review : Intel Core i7 Processor Extreme Edition

Alex Jose — Wed, 07 Oct 2009 08:46:25 +0000

Product information

3.20 GHz core speed
8 processing threads with Intel® HT technology
8 MB of Intel® Smart Cache
3 Channels of DDR3 1066 MHz memory

The good: Fastest high-end desktop CPU; supporting motherboard supports both graphics card vendors’ multicard technologies.

The bad: Requires an expensive new motherboard; chipset needs three memory sticks for maximum efficiency.

The bottom line: Thanks to an expensive new motherboard requirement, Intel’s new Core i7 desktop processors will remain enthusiast and professional-level parts until more affordable complementary hardware comes out later next year. Speed never comes cheap, however, and if you’re willing to spend for it now, you’ll find yourself in possession of the fastest CPU on the market.

The Core i7 965 Extreme Edition runs at 3.20GHz and features a QPI (QuickPath Interface) throughput of 6.4GT/s, which is the key difference here. The mainstream versions of the processor include the Core i7 920 and 940, clocked at 2.66GHz and 2.93GHz, respectively. These more affordable processors feature a QPI throughput of just 4.8GT/s, so it will be interesting to discover what kind of impact this has on performance.

Intel Quad Core Processor,Xeon 7300 Specifications

abyvettoor — Fri, 12 Dec 2008 06:59:04 +0000

Intel has announced the industry’s first quad-core processors named Xeon,specifically designed for multi-processor (MP) servers. The energy efficient Xeon 7300 family delivers “more than twice the performance and more than three times the performance per watt over the company’s previous generation dual-core products.” They are available with frequencies up to 2.93GHz at 130 watts and 8MB of L2 cache. The 7300 series utilizes Virtualization Technology and offers up to four times the memory capacity of Intel’s previous MP platforms.

The 7300 series includes X7350 (2.93GHz, 8MB, 130W), L7345 (1.86GHz, 8MB, 50W), E7340 (2.40GHz, 8MB, 80W), E7330 (2.40GHz, 6MB, 80W), E7320 (2.13GHz, 4MB, 80W), and E7310 (1.6GHz, 4MB, 80W) processors. The price for 7300 series ranges from $856 to $2,301 in quantities of 1,000.

An advice provided by INTEL

deepak — Mon, 06 Oct 2008 12:59:25 +0000

A serious advice has been provided by the world’s one of the famous processor manufacturers INTEL, that motherboard and RAM vendors about their new X58+Core i7 combo and to abide to a strict memory voltage limit of 1.65 volts limit. If the advice is not followed, they have warned that the CPU will get fried.

These all started when the photos of ASUS P6T Deluxe motherboard showing the severe warning of ” According to Intel CPU SPEC , DIMMs with voltage setting over 1.65V may damage the CPU permenantly. We recommend you install the DIMMs with the voltage setting below 1.65V” gets public. It was a a big sticker over the DIMM slot. ASUS has admitted that the story is true.

Since many memory vendors offer faster RAM kits that operate at higher voltage levels, this may arise as a big big problem. For eg: OCZ Reaper PC3-14400 operates at 1.9V, Mushkin’s XP Series uses 1.9-1.95V while Corsair’s Dominator high-end takes you all the way up to 2.1V. Some series like DDR3 JEDEC specs really have nothing to worry since they require only a 1.5V to operate.

However, Mushkin have already started to work on this problem. They will re-design their kit specifically to suit the X58/Core i7 combo and should be out sometime next month. But except Mushkin, all others have kept a dead silence about this problem.

Intel is not yet able to explain why the memory voltage would damage the CPU. This may appear to be a great threat to the integrated memory controller of the Nehalam. People importing the Core i7 should make sure that they get a compatible RAM kit or they will have to underclock it.

AMD unimpressed with Intel six shooter

deepak — Thu, 18 Sep 2008 14:30:45 +0000

As you might expect, Advanced Micro Devices is keeping its chin up amid the ticktocking it’s taking from rival Intel in the server space. This week’s launch of the six-core “Dunnington” Xeon MP processors – which plug into four-socket and larger machines – made a lot of noise for Intel and its partners, but AMD wants you to be realistic about the prospects for processors in this part of the server space.

It also wants everyone to understand that the Dunnington Xeons aren’t out-gunning its quad-core “Barcelona” Opterons by all that much – if at all.

First, here’s a little server space DNA to keep in mind.

According to John Fruehe, manager of worldwide market development for AMD and a former Compaq and Hewlett-Packard marketeer, the basic distribution of x86 and x64 server sales, quarter to quarter and year to year, is like this: About 20 per cent of the machinery shipped is single-socket boxes, about 70 per cent is for two-socket boxes, and around 10 percent accounts for four-socket machines. That leaves just a tiny slice for eight-socket or larger x64 iron.

While the bigger boxes generate larger sales and lots of profits – which is why vendors even bother – big x64 iron is still a market that has yet to unseated RISC/Unix or proprietary iron. To be sure, AMD, Intel, and their respective partners have been trying to do this, but their efforts are often half-hearted since these same partners usually have a highly profitable non-x64 line to protect.

That server distribution has not changed all that much in the past decade or so, says Fruehe, but he does concede that the combination of virtualization and server consolidation is driving customers to buy bigger boxes than they might have only a few years ago.

This is true across all platforms, by the way. And mainframes and proprietary servers like IBM’s AS/400 and its successors have already undergone the virtualization crunch (and their revenue drops in the past decade are due in part to the widespread adoption of virtualization and the consolidation of footprints).

But none of this is meant to imply that AMD doesn’t like the four-socket server space. “While the eight-way server is not a volume market, and it is not growing dramatically, the four-socket server is still a real stronghold for us,” says Fruehe. One of the reasons, he says, is that the HyperTransport interconnect and the integrated memory controllers of the Opteron architecture gives AMD a performance advantage, clock for clock and core for core, compared to Xeons.

Intel’s front side bus architecture just doesn’t scale as well – and this matters on bigger boxes. That’s why the future “Nehalem” Xeons and “Tukwila” Itaniums will use the QuickPath Interconnect, Intel’s riff on the Opteron interconnect, including on-chip memory controllers.

To make up for the shortcomings in the 1.07GHz front side buses of the Dunnington Xeons, Intel has used the 45 nanometer process to squeeze up to 16MB of L3 cache on the chip. This cache helps mask I/O bottlenecks, and so do the three 2MB L2 caches that are shared by core pairs on the chip. But even with that, Fruehe is not impressed.

“Intel added 50 per cent more cores and got what looks like a 31 per cent more performance on virtualization,” he says. Of course, the average workload is seeing around 35 per cent more work being done, which is better than the virtualization benchmarks show, and databases are seeing as much as a 50 per cent boost according to Intel’s test.

What AMD intends to focus on to sell Barcelonas against Dunningtons is heat. The “Tigerton” quad-core Xeon MP predecessor to Dunnington was implemented in 65 nanometer processes, and Intel could ship standard parts at an 80 watt thermal design point (TDP). Dunnington, using a 45 nanometer process that implies a cooler chip, actually has a 90 watt TDP because of all that extra cache and the extra two cores. The top-end six-core Dunnington chip, which runs at 2.66 GHz, is still a 130-watt part, just like the fastest Tigerton.

“The majority of the world looks at the top bin parts and tells vendors that these are great for benchmarks, but these are not the chips that most people buy,” says Fruehe. As you might expect, these expensive parts run a bit faster, but a whole lot hotter. The standard parts are where AMD and Intel are competing for most sales.

What Intel does have and what AMD has not been able to get since the advent of the Opteron line is big iron based on its x64 chips. IBM, NEC, and Unisys have 16-socket Xeon boxes that could use Tigerton and now Dunnington chips, while the biggest commercial Opteron boxes are the eight-socket DL785 from Hewlett-Packard and X4600 from Sun Microsystems. Motherboard makers Tyan and Super Micro also sell eight-way machines and boards to OEMs.

AMD is also planning to remind customers that the Dunnington machines use Fully Buffered DIMMs, which consume 10 to 11 watts per memory stick, compared to the DDR2 main memory used with Opterons, which consume 4 to 5 watts per stick of the same capacity. All this heat adds up inside a big box.

While the current Barcelona Opterons, which top out at 2.3GHz, have to fend off the Dunningtons at the high-end and the Harpertown Xeons in the two-socket space, help is on the way. Fruehe reiterated that the “Shanghai” 45 nanometer shrink of the Barcelona chips are expected in two-socket (2000 series) and four-socket and larger (8000 series) servers in the fourth quarter of this year.

AMD will not only ship these Shanghai chips for revenue, but AMD’s partners will have boxes in the field before the end of the year. The Shanghai Opterons will have 6MB of L3 cache (triple that in the Barcelonas), higher clock speeds, and various tweaks in the instruction stream that will deliver somewhere between 15 and 30 per cent more performance for Opteron customers.