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Since 2006, parallel computers have continued to evolve.  Besides the increasing number of transistors (as predicted by Moore's law), other designs and architectures have increased in prominence.  These include Chip Multi-Processors, cluster computing, and mobile processors.
Edited from http://wiki.expertiza.ncsu.edu/index.php/Chapter_1:_Nick_Nicholls,_Albert_Chu
 
Since 2006, parallel computers have continued to evolve.  Besides the increasing number of transistors (as predicted by [http://en.wikipedia.org/wiki/Moore%27s_law Moore's law]), other designs and architectures have increased in prominence.  These include Chip Multi-Processors, cluster computing, and mobile processors.


==Transistor Count==
==Transistor Count==
At the most fundamental level of parallel computing development is the transistor count. According to the text, since 1971 the number of transistors on a chip has increased from 2,300 to 167 million in 2006.  By 2011, the transistor count had further increased to 2.6 billion, a 1,130,434x increase from 1971.  The clock frequency has also continued to rise, if a bit slower since 2006.  In 2006, the clock speed was around 2.4GHz, 3,200 times the speed of 750KHz in 1971. By 2011, the high end clock speed of a processor is in the 3.3GHz range.
At the most fundamental level of parallel computing development is the transistor count
<ref name="transcount">http://en.wikipedia.org/wiki/Transistor_count
{{cite web
|        url = http://en.wikipedia.org/wiki/Transistor_count
|      title = Transistor Count
|      last1 =
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| accessdate = October 1, 2013
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. According to the text, since 1971 the number of transistors on a chip has increased from 2,300 to 167 million in 2006.  By 2011, the transistor count had further increased to 2.6 billion, a 1,130,434x increase from 1971.  The clock frequency has also continued to rise.  In 2006, the clock speed was around 2.4GHz, 3,200 times the speed of 750KHz from 1971. By 2011, the high end clock speed of a processor was in the 3.3GHz range.


====Evolution of Intel Processors====
====Evolution of Intel Processors====
{| class="wikitable"
{| class="wikitable"
|+ Table 1.1: Evolution of Intel Processors
|+ Table 1.1: Evolution of Intel Processors
<ref name="intelspecs">http://ark.intel.com/
{{cite web
|        url = http://ark.intel.com/
|      title = Intel Processor Specifications
|      last1 =
|    first1 =
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|      last2 =
|    first2 =
|    middle2 =
|  location =
|      date =
| accessdate = October 1, 2013
|  separator = ,
}}
</ref>
|-
|-
! From
! From
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==Chip Multi-Processors==
==Chip Multi-Processors==


With the sophistication of processors and increasing clock speeds, effort was placed on parallelism. The high clock speed could be broken down into a large pipeline; this large pipeline allowed big performance gains with instruction level parallelism (ILP). Instruction level parallelism is the act of executing multiple instructions at the same time. This would be implemented in a single core, with each stage of the pipeline being executed in each clock cycle. By the 1970s the gains from ILP were significant enough to allow uni-processor systems to reach the level of performance in parallel computers after only a few years. This inhibited adoption of multi-processors as it was costly and not needed. Of course, the performance gains of ILP was soon limited. Once branch prediction had a success rate of 90%, there was little room for further improvement. At this point, the main way of increasing performance was to increase the clock speed. This also meant more power consumption.
With the increasing sophistication of processors and limitations of Silicon on Chip designs, design efforts shifted to parallelism. Instructions could be broken down into a large pipeline. The larger pipeline allowed big performance gains with Instruction Level Parallelism (ILP). Instruction level parallelism is the act of executing multiple instructions at the same time. This would be implemented in a single core, with each stage of the pipeline being executed in each clock cycle. By the 1970s, the gains from ILP were significant enough to allow uni-processor systems to reach the level of performance of parallel computers after only a few years. This inhibited adoption of multi-processor systems since single-processor systems achieved relative performance while being less costly. Over time, the effort to gain improvements from ILP began to have diminishing returns. In single-processor systems, the primary way of increasing performance was to increase the clock speed. As clock speeds increase, power consumption also increases. With parallelism, as long as the instructions are parallelizable, performance can be increased with an increase in processors.
<ref name="cpuperf">http://en.wikipedia.org/wiki/Central_processing_unit#Performance
{{cite web
|        url = http://en.wikipedia.org/wiki/Central_processing_unit#Performance
|      title = CPU Performance
|      last1 =
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| accessdate = October 1, 2013
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</ref>


As the diminishing returns and power inefficiencies of ILP progressed, manufacturers began to turn towards chip multi-processors (i.e. multicore architectures). These systems allowed task parallelism in addition to ILP. For example, one processor can execute multiple tasks simultaneously, and each core can use ILP with pipelining. Driven by the gains of multi-processors, the amount of cores on a chip has continued to increase since 2006. By 2011, Intel and IBM were producing 8-core processors. For servers, AMD was producing up to 16-core processors.
As the diminishing returns and power inefficiencies of ILP progressed, manufacturers began to turn toward on-chip multi-processors (i.e. multi-core architectures). These systems allowed task parallelism in addition to ILP. For example, one processor can simultaneously execute multiple tasks and each core can use ILP with pipelining. Driven by the performance gains of multi-processors, the amount of cores on a chip has continued to increase since 2006. By 2011, Intel and IBM were producing 8-core processors. For servers, AMD was producing up to 16-core processors.
{| class="wikitable"
{| class="wikitable"
|+ Table 1.2: Examples of current multicore processors
|+ Table 1.2: Examples of multi-core processors
|-
|-
! Aspects
! Aspects
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{| class="wikitable"
{| class="wikitable"
|+ Cluster computers 2008 - 2013
|+ Top500.org Cluster computers 2008 - 2013<ref name="top500list">http://www.top500.org/lists/2013/06/
{{cite web
|        url = http://www.top500.org/lists/2013/06/
|      title = Top500.org Supercomputer List
|      last1 =
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|      date = June 2013
| accessdate = October 3, 2013
|  separator = ,
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</ref>
|-
|-
! Date of #1 Rank
! Date of #1 Rank
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! Power Usage
! Power Usage
! Information
! Information
|- valign="top"
| 2009 Jun
| Roadrunner
|
* 129,600 Cores
* 6,480 computing nodes
|
* AMD Opteron 2210 2-core
* IBM PowerXCell8i 8+1 cores
* 104 Terabytes RAM
* Infiniband interconnect
* OS - REHL and Fedora Linux
| 1.46 Petaflops
| 2.5 Megawatts
| Built by IBM, housed in NM, US
|- valign="top"
| 2010 Jun
| Jaguar
|
* 224,162 Cores
* 18,688 computing nodes
|
* AMD Opteron 2435 6-core
* AMD Opteron 1354 4-core
* 360 Terabytes RAM
* Cray Seastar2+, Infiniband interconnects
* OS - Cray Linux
| 2.33 Petaflops
| 7.0 Megawatts
| Built by Cray, housed in Tennessee, US
|- valign="top"
| 2010 Nov
| Tianhe-1A
|
* 186,368 Cores
* 7,168 computing nodes
|
* 2 Xeon X5670 6-core CPUs per node
* 1 Nvidia M2050 GPU per node
* 262 Terabytes RAM
* Arch interconnect (NUDT)
* OS - Linux variant
| 4.7 Petaflops
| 4.0 Megawatts
| Built by NUDT, China
|- valign="top"
|- valign="top"
| 2011 Nov
| 2011 Nov
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| 11.28 Petaflops
| 11.28 Petaflops
| 9.89 Megawatts
| 9.89 Megawatts
| Built by Fujitsu, Housed in Japan, $10M/yr operating cost
| Built by Fujitsu, housed in Japan
|- valign="top"
|- valign="top"
| 2012 Jun
| 2012 Jun
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| 20.13 Petaflops
| 20.13 Petaflops
| 7.9 Megawatts
| 7.9 Megawatts
| Built by IBM, Housed in California, US
| Built by IBM, housed in California, US
|- valign="top"
|- valign="top"
| 2012 Nov
| 2012 Nov
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* TH Express-2 fat tree topology (NUDT)
* TH Express-2 fat tree topology (NUDT)
* OS - NUDT Kylin Linux
* OS - NUDT Kylin Linux
| 33.8 Petaflops
| 54.9 Petaflops
| 17.6 Megawatts
| 17.6 Megawatts
| Built by NUDT, China
| Built by NUDT, China
Line 185: Line 297:


===Trends===
===Trends===
In 2011 the fastest super computer was Japan's K Computer, a cluster computer built by Fujitsu.  Six months later, Sequoia replaced the K Computer as the top ranking cluster computer with a performance of 20.13 petaflops, a seventy-eight percent increase. Titan replaced the Sequoia as number in November 2012, with performance 34% greater than it's predecessor. The June 2013 top leader, Tianhe-2, displaced Titan with a twenty-five percent increase in performance.
In 2011 the fastest super computer was Japan's K Computer, a cluster computer built by Fujitsu.  Six months later, Sequoia replaced the K Computer as the top ranking cluster computer with a performance of 20.13 petaflops, a seventy-eight percent increase. Titan replaced the Sequoia as number in November 2012, with performance thirty-four percent greater than it's predecessor. The June 2013 top leader, Tianhe-2, displaced Titan with a one-hundred percent increase in performance.
 
Since 2008, super computers have trended towards using multi-core processors in the architecture. As of 2013, according to Top500.org data, trends have been to use processors with a high number of cores, eight or more. Most use computing nodes with multiple multi-core CPUs.
 
====Graphical trends for super computers 2008-2013<ref name="top500stats">http://www.top500.org/statistics/sublist/
{{cite web
|        url = http://www.top500.org/statistics/sublist
|      title = CPU Performance
|      last1 =
|    first1 =
|    middle1 =
|      last2 =
|    first2 =
|    middle2 =
|  location =
|      date =
| accessdate = October 1, 2013
|  separator = ,
}}
</ref>====
* [[Media:Top500_cores-per-socket.png|Top500.org Cores per socket]] - In recent years, 8-core have been gaining a large portion of the market-share with 16-core systems a recent player in the market. Single processor systems have been minor use since 2008.
* [[Media:Top500_cores-per-socket-performance.png|Top500.org Performance for cores per socket]] - 8-core systems have the most performance share of the super computer market. 16-core systems place into a very close second place with 12-core systems bringing up third place. In total, these three categories make up 85% of the top performance among super computers.
* [[Media:Top500 interconnect-family.png|Top500.org Interconnects used for super computers]] - Infiniband's interconnect technology makes up the largest portion of the super computer arena. Interconnect systems utilizing gigabit ethernets make up the next largest portion.
* [[Media:Top500 vendors.png|Top500.org Vendor trends of super computers]] - IBM and HP make up nearly half of the super computer market. HP and Cray appear to be on the trend of gaining market share in recent years.


==Mobile Processors==
==Mobile Processors==
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| .5W-1.9W
| .5W-1.9W
|}
|}


==Sources==
==Sources==
====References====
<references/>
====Other sources====
<ol>
<ol>
<li>http://en.wikipedia.org/wiki/Transistor_count</li>
<li>http://ark.intel.com/products/52220/Intel-Core-i3-2310M-Processor-%283M-Cache-2_10-GHz%29</li>
<li>http://www.tomshardware.com/news/intel-ivy-bridge-22nm-cpu-3d-transistor,14093.html</li>
<li>http://www.tomshardware.com/news/intel-ivy-bridge-22nm-cpu-3d-transistor,14093.html</li>
<li>http://www.anandtech.com/show/5091/intel-core-i7-3960x-sandy-bridge-e-review-keeping-the-high-end-alive</li>
<li>http://www.anandtech.com/show/5091/intel-core-i7-3960x-sandy-bridge-e-review-keeping-the-high-end-alive</li>
<li>http://www.chiplist.com/Intel_Core_2_Duo_E4xxx_series_processor_Allendale/tree3f-subsection--2249-/</li>
<li>http://www.chiplist.com/Intel_Core_2_Duo_E4xxx_series_processor_Allendale/tree3f-subsection--2249-/</li>
<li>http://www.pcper.com/reviews/Processors/Intel-Lynnfield-Core-i7-870-and-Core-i5-750-Processor-Review</li>
<li>http://www.pcper.com/reviews/Processors/Intel-Lynnfield-Core-i7-870-and-Core-i5-750-Processor-Review</li>
<li>http://www.intel.com/pressroom/kits/quickreffam.htm#Xeon</li>
<li>http://www.tomshardware.com/reviews/core-i7-980x-gulftown,2573-2.html</li>
<li>http://www.tomshardware.com/reviews/core-i7-980x-gulftown,2573-2.html</li>
<li>http://www.fujitsu.com/global/news/pr/archives/month/2011/20111102-02.html</li>
<li>http://www.fujitsu.com/global/news/pr/archives/month/2011/20111102-02.html</li>
<li>http://ark.intel.com/products/61275</li>
<li>http://www.anandtech.com/show/5096/amd-releases-opteron-4200-valencia-and-6200-interlagos-series</li>
<li>http://www.anandtech.com/show/5096/amd-releases-opteron-4200-valencia-and-6200-interlagos-series</li>
<li>http://www.arm.com/products/processors/cortex-a/cortex-a9.php</li>
<li>http://www.arm.com/products/processors/cortex-a/cortex-a9.php</li>
<li>http://ark.intel.com/products/58917/Intel-Atom-Processor-N2800-(1M-Cache-1_86-GHz)</li>
<li>http://en.wikipedia.org/wiki/SPARC64_VI#SPARC64_VIIIfx</li>
<li>http://en.wikipedia.org/wiki/SPARC64_VI#SPARC64_VIIIfx</li>
<li>http://en.wikipedia.org/wiki/High-availability_cluster</li>
<li>http://en.wikipedia.org/wiki/High-availability_cluster</li>
</ol>
</ol>

Latest revision as of 02:14, 8 October 2013

Edited from http://wiki.expertiza.ncsu.edu/index.php/Chapter_1:_Nick_Nicholls,_Albert_Chu

Since 2006, parallel computers have continued to evolve. Besides the increasing number of transistors (as predicted by Moore's law), other designs and architectures have increased in prominence. These include Chip Multi-Processors, cluster computing, and mobile processors.

Transistor Count

At the most fundamental level of parallel computing development is the transistor count <ref name="transcount">http://en.wikipedia.org/wiki/Transistor_count

</ref> . According to the text, since 1971 the number of transistors on a chip has increased from 2,300 to 167 million in 2006. By 2011, the transistor count had further increased to 2.6 billion, a 1,130,434x increase from 1971. The clock frequency has also continued to rise. In 2006, the clock speed was around 2.4GHz, 3,200 times the speed of 750KHz from 1971. By 2011, the high end clock speed of a processor was in the 3.3GHz range.

Evolution of Intel Processors

Table 1.1: Evolution of Intel Processors <ref name="intelspecs">http://ark.intel.com/ </ref>
From Procs Transistors Specifications New Features
2000 Pentium IV 55 Million 1.4-3GHz hyper-pipelining, SMT
2006 Xeon 167 Million 64-bit, 2GHz, 4MB L2 cache on chip Dual core, virtualization support
2007 Core 2 Allendale 167 Million 1.8-2.6 GHz, 2MB L2 cache 2 CPUs on one die, Trusted Execution Technology
2008 Xeon 820 Million 2.5-2.83 GHz, 6MB L3 cache
2009 Core i7 Lynnfield 774 Million 2.66-2.93 GHz, 8MB L3 cache 2-channel DDR3
2010 Core i7 Gulftown 1.17 Billion 3.2 GHz 32 nm
2011 Core i7 Sandy Bridge EP4 1.2 Billion 3.2-3.3 GHz, 32 KB L1 cache per core, 256 KB L2 cache, 20 MB L3 cache Up to 8 cores
2012 Core i7 Ivy Bridge 1.2 Billion 2.5-3.7 GHz 22 nm, 3D Tri-gate transistors
2013 Core Haswell 1.4 Billion 2.5-3.7 GHz Fully integrated voltage regulator

Chip Multi-Processors

With the increasing sophistication of processors and limitations of Silicon on Chip designs, design efforts shifted to parallelism. Instructions could be broken down into a large pipeline. The larger pipeline allowed big performance gains with Instruction Level Parallelism (ILP). Instruction level parallelism is the act of executing multiple instructions at the same time. This would be implemented in a single core, with each stage of the pipeline being executed in each clock cycle. By the 1970s, the gains from ILP were significant enough to allow uni-processor systems to reach the level of performance of parallel computers after only a few years. This inhibited adoption of multi-processor systems since single-processor systems achieved relative performance while being less costly. Over time, the effort to gain improvements from ILP began to have diminishing returns. In single-processor systems, the primary way of increasing performance was to increase the clock speed. As clock speeds increase, power consumption also increases. With parallelism, as long as the instructions are parallelizable, performance can be increased with an increase in processors. <ref name="cpuperf">http://en.wikipedia.org/wiki/Central_processing_unit#Performance

</ref>

As the diminishing returns and power inefficiencies of ILP progressed, manufacturers began to turn toward on-chip multi-processors (i.e. multi-core architectures). These systems allowed task parallelism in addition to ILP. For example, one processor can simultaneously execute multiple tasks and each core can use ILP with pipelining. Driven by the performance gains of multi-processors, the amount of cores on a chip has continued to increase since 2006. By 2011, Intel and IBM were producing 8-core processors. For servers, AMD was producing up to 16-core processors.

Table 1.2: Examples of multi-core processors
Aspects Intel Sandy Bridge AMD Valencia IBM POWER7
# Cores 4 8 8
Clock Freq. 3.5GHz 3.3GHz 3.55GHz
Clock Type OOO Superscalar OOO Superscalar SIMD
Caches 8MB L3 8MB L3 32MB L3
Chip Power 95 Watts 95 Watts 650 Watts for the whole system

Cluster Computers

The 1990s saw a rise in the use of cluster computers, or distributed super computers. These systems take advantage of the power of individual processors, and combine them to create a powerful unified system. Originally, cluster computers only used uniprocessors, but have since adopted the use of multi-processors. Unfortunately, the cost advantage mentioned by the book has largely dissipated, as many current implementations use expensive, high-end hardware.

One of the newer innovations in cluster computers is high-availability. These types of clusters operate with redundant nodes to minimize downtime when components fail. Such a system uses automated load-balancing algorithms to route traffic when a node fails. In order to function, high-availability clusters must be able to check and change the status of running applications. The applications must also use shared storage, while operating in a way such that its data is protected from corruption.


Top500.org Cluster computers 2008 - 2013<ref name="top500list">http://www.top500.org/lists/2013/06/ </ref>
Date of #1 Rank Name Number of Cores/Nodes Specifications Peak Performance Power Usage Information
2009 Jun Roadrunner
  • 129,600 Cores
  • 6,480 computing nodes
  • AMD Opteron 2210 2-core
  • IBM PowerXCell8i 8+1 cores
  • 104 Terabytes RAM
  • Infiniband interconnect
  • OS - REHL and Fedora Linux
 1.46 Petaflops 2.5 Megawatts Built by IBM, housed in NM, US
2010 Jun Jaguar
  • 224,162 Cores
  • 18,688 computing nodes
  • AMD Opteron 2435 6-core
  • AMD Opteron 1354 4-core
  • 360 Terabytes RAM
  • Cray Seastar2+, Infiniband interconnects
  • OS - Cray Linux
 2.33 Petaflops 7.0 Megawatts Built by Cray, housed in Tennessee, US
2010 Nov Tianhe-1A
  • 186,368 Cores
  • 7,168 computing nodes
  • 2 Xeon X5670 6-core CPUs per node
  • 1 Nvidia M2050 GPU per node
  • 262 Terabytes RAM
  • Arch interconnect (NUDT)
  • OS - Linux variant
 4.7 Petaflops 4.0 Megawatts Built by NUDT, China
2011 Nov K Computer
  • 705,024 Cores
  • 96 computing nodes
  • 2.0GHz 8-core SPARC64 VIIIfx
  • 6 I/O nodes
  • Using Message Passing Interface
  • Tofu 6-dimensional torus interconnect
  • OS - Linux variant
 11.28 Petaflops 9.89 Megawatts Built by Fujitsu, housed in Japan
2012 Jun Sequoia
  • 1,572,864 Cores
  • 98,304 computing nodes
  • 16-core PowerPC A2, Blue Gene/Q
  • 1.5 Petabytes RAM
  • 5-dimensional torus interconnect
  • OS - Linux variant
 20.13 Petaflops 7.9 Megawatts Built by IBM, housed in California, US
2012 Nov Titan
  • 560,640 computing cores
  • AMD Opertons CPUs
  • Nvidia Tesla GPUs
  • 693 Terabytes RAM (CPU + GPU)
  • Cray Gemini interconnect
  • OS - Cray Linux
 27.11 Petaflops 8.2 Megawatts Built by Cray, housed in California, US
2013 Jun Tianhe-2
  • 3,120,000 Cores
  • 16,000 nodes
  • 2 Intel Xeon IvyBridge per node
  • 3 Intel Xeon Phi per node
  • 1.34 Petabytes RAM
  • TH Express-2 fat tree topology (NUDT)
  • OS - NUDT Kylin Linux
 54.9 Petaflops 17.6 Megawatts Built by NUDT, China

Trends

In 2011 the fastest super computer was Japan's K Computer, a cluster computer built by Fujitsu. Six months later, Sequoia replaced the K Computer as the top ranking cluster computer with a performance of 20.13 petaflops, a seventy-eight percent increase. Titan replaced the Sequoia as number in November 2012, with performance thirty-four percent greater than it's predecessor. The June 2013 top leader, Tianhe-2, displaced Titan with a one-hundred percent increase in performance.

Since 2008, super computers have trended towards using multi-core processors in the architecture. As of 2013, according to Top500.org data, trends have been to use processors with a high number of cores, eight or more. Most use computing nodes with multiple multi-core CPUs.

====Graphical trends for super computers 2008-2013<ref name="top500stats">http://www.top500.org/statistics/sublist/

</ref>====

  • Top500.org Cores per socket - In recent years, 8-core have been gaining a large portion of the market-share with 16-core systems a recent player in the market. Single processor systems have been minor use since 2008.
  • Top500.org Performance for cores per socket - 8-core systems have the most performance share of the super computer market. 16-core systems place into a very close second place with 12-core systems bringing up third place. In total, these three categories make up 85% of the top performance among super computers.
  • Top500.org Interconnects used for super computers - Infiniband's interconnect technology makes up the largest portion of the super computer arena. Interconnect systems utilizing gigabit ethernets make up the next largest portion.
  • Top500.org Vendor trends of super computers - IBM and HP make up nearly half of the super computer market. HP and Cray appear to be on the trend of gaining market share in recent years.

Mobile Processors

Due to the popularity of smart phones, there has been significant development on mobile processors. This category of processors has been specifically designed for low power use. To conserve power, these types of processors use dynamic frequency scaling. This technology allows the processor to run at varying clock frequencies based on the current load.

Examples of current mobile processors
Aspects Intel Atom N2800 ARM Cortex-A9
# Cores 2 2
Clock Freq 1.86GHz 800MHz-2000MHz
Cache 1MB L2 4MB L2
Power 35 W .5W-1.9W


Sources

References

<references/>

Other sources

  1. http://www.tomshardware.com/news/intel-ivy-bridge-22nm-cpu-3d-transistor,14093.html
  2. http://www.anandtech.com/show/5091/intel-core-i7-3960x-sandy-bridge-e-review-keeping-the-high-end-alive
  3. http://www.chiplist.com/Intel_Core_2_Duo_E4xxx_series_processor_Allendale/tree3f-subsection--2249-/
  4. http://www.pcper.com/reviews/Processors/Intel-Lynnfield-Core-i7-870-and-Core-i5-750-Processor-Review
  5. http://www.tomshardware.com/reviews/core-i7-980x-gulftown,2573-2.html
  6. http://www.fujitsu.com/global/news/pr/archives/month/2011/20111102-02.html
  7. http://www.anandtech.com/show/5096/amd-releases-opteron-4200-valencia-and-6200-interlagos-series
  8. http://www.arm.com/products/processors/cortex-a/cortex-a9.php
  9. http://en.wikipedia.org/wiki/SPARC64_VI#SPARC64_VIIIfx
  10. http://en.wikipedia.org/wiki/High-availability_cluster
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