Difference between revisions of "GPU621/History of Parallel Computing"

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(Demise of Single-Core and Rise of Multi-Core Systems)
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-> History and development of supercomputers and their parallel computing nature (incl. modern supercomputers -> world's fastest supercomputer)
 
-> History and development of supercomputers and their parallel computing nature (incl. modern supercomputers -> world's fastest supercomputer)
 +
 +
Update 2 (11/27/2020):
 +
 +
-> Add new content(Demise of Single-Core and Rise of Multi-Core Systems)
 +
 +
Update 3 (11/29/2020):
 +
 +
-> Add new content(Domination of Two Semiconductor Giants Intel and AMD In Multi-core Processor Development)
  
  
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=== Transition from Single to Multi-Core ===
 
=== Transition from Single to Multi-Core ===
  
The transition from single to multi-core systems came from the need to address the limitations of manufacturing technologies for single-core systems. Single-core systems suffered by several limiting factors such as individual transistor gate size, physical limits in the design of integrated circuits which caused significant heat dissipation, and synchronization issues with coherency of data. Some instruction-level parallelism methods were used to improve single-core performance such as superscalar pipelining which enables the processor to execute multiple instruction pipelines concurrently within a single clock cycle, but they were not suited for many applications. Such issues with instruction-level parallelism were predominantly dictated by the disparity between the speed by which the processor operated and the access latency of system memory, which costed the processor many cycles by having to stall and wait for the fetch operation from system memory to complete.
+
The transition from single to multi-core systems came from the need to address the limitations of manufacturing technologies for single-core systems. Single-core systems suffered by several limiting factors such as individual transistor gate size, physical limits in the design of integrated circuits which caused significant heat dissipation, and synchronization issues with the coherency of data. Some instruction-level parallelism methods were used to improve single-core performance such as superscalar pipelining which enables the processor to execute multiple instruction pipelines concurrently within a single clock cycle, but they were not suited for many applications. Such issues with instruction-level parallelism were predominantly dictated by the disparity between the speed by which the processor operated and the access latency of system memory, which costed the processor many cycles by having to stall and wait for the fetch operation from system memory to complete.
  
  
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The world's first true multi-core processor was called the POWER4, created in 2001 by IBM. It incorporated 2 physical cores on a single CPU die and implemented IBM's PowerPC 64-bit instruction set architecture (ISA). It was used in IBM's line of workstations, servers, and supercomputers at the time, namely the RS/6000 and AS/400 systems.
 
The world's first true multi-core processor was called the POWER4, created in 2001 by IBM. It incorporated 2 physical cores on a single CPU die and implemented IBM's PowerPC 64-bit instruction set architecture (ISA). It was used in IBM's line of workstations, servers, and supercomputers at the time, namely the RS/6000 and AS/400 systems.
 +
 +
== Domination of Two Semiconductor Giants Intel and AMD In Multi-core Processor Development ==
 +
 +
=== Early Product Launches ===
 +
 +
After the initial multicore processor introduction, on April 18, 2005 Intel announced that computer manufacturers Alienware, Dell and Velocity Micro started selling desktop PCs and workstations based on Intel's first dual-core processor-based platform.  This dual-core processor-based systems were trying to attract computer hobbyists and entertainment enthusiasts.
 +
 +
The next month May 2005, AMD released Athlon 64 X2 which was the first dual core desktop processor series and Turion processor which were designed for low power consumption mobile processor segments. AMD was intending for the Turion to compete against Intel’s mobile processors, initially the Pentinum M and later the Intel Core and Intel Core 2 processors. 
 +
 +
Intel released Core series was also the first Intel processor used as the main CPU in an Apple Macintosh computer on January 2006. The Core Duo was the CPU for the first-generation MacBook Pro, while the Core Solo appeared in Apple's Mac Mini line. Core Duo signified the beginning of Apple's shift to Intel processors across the entire Mac line. The successor to Core is the mobile version of the Intel Core 2 line of processors using cores based upon the Intel Core microarchitecture, released on July 27, 2006. The release of the mobile version of Intel Core 2 marked the reunification of Intel's desktop and mobile product lines as Core 2 processors were released for desktops and notebooks. The Core 2 architecture hit a wide range of devices, but Intel needed to produce something less expensive for the ultra-low-budget and portable markets. This led to the creation of Intel's Atom between 2008 and 2009, which used a 26mm2 die, less than one-fourth the size of the first Core 2 dies.
 +
Meanwhile, AMD launched Phenom dual-, triple- and quad-core versions to target a budget desktop processor market. AMD considered the quad core Phenoms to be the first "true" quad core design, as these processors were a monolithic multi-core design meaning all cores on the same silicon die, unlike Intel's Core 2 Quad series which were a multi-chip module (MCM) design. The processors were on the Socket AM2+ platform.
 +
 +
On August 8 2008, Intel announced the Nehalem microprocessor, which represents the new Core i7 brand of high-end microprocessors to replace the Core 2 Duo microprocessors. This brand targeted the business and high-end consumer markets for both desktop and laptop computers.
 +
Later during the year Intel planned to add more chips into the Intel Celeron E1000 dual-core lineup, creating a comprehensive family of affordable chips with two processing engines, additionally to target cost-effective desktops. The launch of low-cost dual-core Intel Celeron E1000-series processors would caused the chip giant’s rival AMD to either waterfall prices of its entry-level single-core AMD Athlon LE and AMD Sempron chips, or to introduce value dual-core processors as well and reconsider pricing of single-core offerings.
 +
 +
With the processor market in a highly competitive state, Intel had kept pushing their advantage. Therefore, it reworked the Core architecture to create Nehalem, which adds numerous enhancements. Intel released Core i3, i5, and i7. Core i7 was officially launched on November 17, 2008 as a family of three quad-core processor desktop models, further models started appearing throughout 2009. Intel intended the Core i3 as the new low-end of the performance processor line from Intel, following the retirement of the Core 2 brand.
 +
 +
=== AMD vs Intel in 2010s ===
 +
 +
Intel continued to grow its market share with the tick-tock improvement cycle of its Core series of microprocessors since the 2006 release of Core microarchitecture and continuing for the next ten years. Thus, AMD has been almost completely absent for many years due to AMD’s primary competitor Intel. However, AMD officially announced a new series of processors, named "Ryzen", during its New Horizon summit on December 13, 2016 and introduced Ryzen 1000 series processors in February 2017, featuring up to 8 cores and 16 threads, which launched on March 2, 2017. Ryzen was released as the return of AMD to the high-end CPU market, offering a product stack able to compete with Intel at every level. Having more processing cores, Ryzen processors offer greater multi-threaded performance at the same price point relative to Intel's Core processors. Since the release of Ryzen, AMD's CPU market share has increased while Intel appears to have stagnated.
 +
 +
=== Multi-core Processor Today ===
 +
 +
Today, multicore processor makers including AMD and Intel have been continuously improving their processors to satisfy the high demand of consumers. As of today(November, 2020), Intel and AMD both made announcements to release newer version of its core brand; 11th Gen Intel Core processors with Intel Iris Xe graphics and Ryzen 5000 Series desktop processor lineup powered by the new “Zen 3” architecture respectively.
 +
 +
Currently in 2020 the global multi-core processors market has been significantly more competitive. Today’s market has been segmented into dual-core processors, quad-core processors, octa-core processors, and hexa-core processors. It’s apparent the increasing advancement in high-performance computing, graphics and visualization technologies is anticipated to boost the growth of the multi-core processor.

Revision as of 22:16, 29 November 2020


GPU621/DPS921 | Participants | Groups and Projects | Resources | Glossary

History of Parallel Computing and the Advantage of Multi-core Systems

We will be looking into the history and evolution in parallel computing by focusing on three distinct timelines:

1) The earliest developments of multi-core systems and how it gave rise to the realization of parallel programming

2) How chip makers marketed this new frontier in computing, specifically towards enterprise businesses being the primary target audience

3) How quickly it gained traction and when the two semiconductor giants Intel and AMD decided to introduce multi-core processors to domestic users, thus making parallel computing more widely available

From each of these timelines, we will be inspecting certain key events and how they impacted other events in their progression. This will help us understand how parallel computing came into fruition, its role and impact in many industries today, and what the future may hold going forward.

Group Members

Omri Golan

Patrick Keating

Yuka Sadaoka


Progress

Update 1 (11/12/2020):

-> Basic definition of parallel computing

-> Research on limitation of single-core systems and subsequent advent of multi-core with respect to parallel computing capabilities

-> Earliest development and usage of parallel computing

-> History and development of supercomputers and their parallel computing nature (incl. modern supercomputers -> world's fastest supercomputer)

Update 2 (11/27/2020):

-> Add new content(Demise of Single-Core and Rise of Multi-Core Systems)

Update 3 (11/29/2020):

-> Add new content(Domination of Two Semiconductor Giants Intel and AMD In Multi-core Processor Development)


Demise of Single-Core and Rise of Multi-Core Systems

Parallel Programming vs. Concurrent Programming

Parallel computing is the idea that large problems can be split into smaller tasks, and these tasks are independent of each other running simultaneously on more than one processor. This concept is different from concurrent programming, which is the composition of multiple processes that may begin and end at different times, but are managed by the host system’s task scheduler which frequently switches between them. This gives off the illusion of multi-tasking as multiple tasks are in progress on a single processor. Concurrent computing can occur on both single and multi-core processors, whereas parallel computing takes advantage of distributing the workload across multiple physical processors. Thus, parallel computing is hardware-dependent.

Transition from Single to Multi-Core

The transition from single to multi-core systems came from the need to address the limitations of manufacturing technologies for single-core systems. Single-core systems suffered by several limiting factors such as individual transistor gate size, physical limits in the design of integrated circuits which caused significant heat dissipation, and synchronization issues with the coherency of data. Some instruction-level parallelism methods were used to improve single-core performance such as superscalar pipelining which enables the processor to execute multiple instruction pipelines concurrently within a single clock cycle, but they were not suited for many applications. Such issues with instruction-level parallelism were predominantly dictated by the disparity between the speed by which the processor operated and the access latency of system memory, which costed the processor many cycles by having to stall and wait for the fetch operation from system memory to complete.


As manufacturing processes evolved in accordance with Moore’s Law which saw the size of a transistor shrink, it allowed for the number of transistors packed onto a single processor die (the physical silicon chip itself) to double roughly every two years. This enabled the available space on a processor die to grow, allowing more cores to fit on it than before. This led to an increased demand in thread-level parallelism which many applications benefitted from and were better suited for. The addition of multiple cores on a processor also increased the system's overall parallel computing capabilities.

Developments in the first Multi-Core Processors

The death of single-core processors came at the time of the Pentium 4, when, as mentioned above, excessive heat and power consumption became an issue. At this point, multi-core processors such as the Pentium D were introduced. However, Pentium D was not considered a “true” multi-core processor as what is considered today by definition, due to its design of being two separate single-core dies placed beside each other in the same processor package.


The world's first true multi-core processor was called the POWER4, created in 2001 by IBM. It incorporated 2 physical cores on a single CPU die and implemented IBM's PowerPC 64-bit instruction set architecture (ISA). It was used in IBM's line of workstations, servers, and supercomputers at the time, namely the RS/6000 and AS/400 systems.

Domination of Two Semiconductor Giants Intel and AMD In Multi-core Processor Development

Early Product Launches

After the initial multicore processor introduction, on April 18, 2005 Intel announced that computer manufacturers Alienware, Dell and Velocity Micro started selling desktop PCs and workstations based on Intel's first dual-core processor-based platform. This dual-core processor-based systems were trying to attract computer hobbyists and entertainment enthusiasts.

The next month May 2005, AMD released Athlon 64 X2 which was the first dual core desktop processor series and Turion processor which were designed for low power consumption mobile processor segments. AMD was intending for the Turion to compete against Intel’s mobile processors, initially the Pentinum M and later the Intel Core and Intel Core 2 processors.

Intel released Core series was also the first Intel processor used as the main CPU in an Apple Macintosh computer on January 2006. The Core Duo was the CPU for the first-generation MacBook Pro, while the Core Solo appeared in Apple's Mac Mini line. Core Duo signified the beginning of Apple's shift to Intel processors across the entire Mac line. The successor to Core is the mobile version of the Intel Core 2 line of processors using cores based upon the Intel Core microarchitecture, released on July 27, 2006. The release of the mobile version of Intel Core 2 marked the reunification of Intel's desktop and mobile product lines as Core 2 processors were released for desktops and notebooks. The Core 2 architecture hit a wide range of devices, but Intel needed to produce something less expensive for the ultra-low-budget and portable markets. This led to the creation of Intel's Atom between 2008 and 2009, which used a 26mm2 die, less than one-fourth the size of the first Core 2 dies. Meanwhile, AMD launched Phenom dual-, triple- and quad-core versions to target a budget desktop processor market. AMD considered the quad core Phenoms to be the first "true" quad core design, as these processors were a monolithic multi-core design meaning all cores on the same silicon die, unlike Intel's Core 2 Quad series which were a multi-chip module (MCM) design. The processors were on the Socket AM2+ platform.

On August 8 2008, Intel announced the Nehalem microprocessor, which represents the new Core i7 brand of high-end microprocessors to replace the Core 2 Duo microprocessors. This brand targeted the business and high-end consumer markets for both desktop and laptop computers. Later during the year Intel planned to add more chips into the Intel Celeron E1000 dual-core lineup, creating a comprehensive family of affordable chips with two processing engines, additionally to target cost-effective desktops. The launch of low-cost dual-core Intel Celeron E1000-series processors would caused the chip giant’s rival AMD to either waterfall prices of its entry-level single-core AMD Athlon LE and AMD Sempron chips, or to introduce value dual-core processors as well and reconsider pricing of single-core offerings.

With the processor market in a highly competitive state, Intel had kept pushing their advantage. Therefore, it reworked the Core architecture to create Nehalem, which adds numerous enhancements. Intel released Core i3, i5, and i7. Core i7 was officially launched on November 17, 2008 as a family of three quad-core processor desktop models, further models started appearing throughout 2009. Intel intended the Core i3 as the new low-end of the performance processor line from Intel, following the retirement of the Core 2 brand.

AMD vs Intel in 2010s

Intel continued to grow its market share with the tick-tock improvement cycle of its Core series of microprocessors since the 2006 release of Core microarchitecture and continuing for the next ten years. Thus, AMD has been almost completely absent for many years due to AMD’s primary competitor Intel. However, AMD officially announced a new series of processors, named "Ryzen", during its New Horizon summit on December 13, 2016 and introduced Ryzen 1000 series processors in February 2017, featuring up to 8 cores and 16 threads, which launched on March 2, 2017. Ryzen was released as the return of AMD to the high-end CPU market, offering a product stack able to compete with Intel at every level. Having more processing cores, Ryzen processors offer greater multi-threaded performance at the same price point relative to Intel's Core processors. Since the release of Ryzen, AMD's CPU market share has increased while Intel appears to have stagnated.

Multi-core Processor Today

Today, multicore processor makers including AMD and Intel have been continuously improving their processors to satisfy the high demand of consumers. As of today(November, 2020), Intel and AMD both made announcements to release newer version of its core brand; 11th Gen Intel Core processors with Intel Iris Xe graphics and Ryzen 5000 Series desktop processor lineup powered by the new “Zen 3” architecture respectively.

Currently in 2020 the global multi-core processors market has been significantly more competitive. Today’s market has been segmented into dual-core processors, quad-core processors, octa-core processors, and hexa-core processors. It’s apparent the increasing advancement in high-performance computing, graphics and visualization technologies is anticipated to boost the growth of the multi-core processor.