Endwall 08/27/2016 (Sat) 06:52:06 No. 430 del
New microchip demonstrates efficiency and scalable design
Posted August 23, 2016; 01:30 p.m. by Adam Hadhazy for the Office of Engineering Communications
https://www.princeton.edu/main/news/archive/S47/19/67G69/index.xml?section=topstories
http://parallel.princeton.edu/piton/

Princeton University researchers have developed a new computer chip that promises to boost the performance of data centers that lie at the core of numerous online services such as email and social media. The chip — called "Piton" after the metal spikes driven by rock climbers into mountainsides to aid in their ascent — was presented Aug. 23 at Hot Chips, a symposium on high-performance chips held in Cupertino, California. Data centers — essentially giant warehouses packed with computer servers — support cloud-based services such as Gmail and Facebook, as well as store the staggeringly voluminous content available via the internet. Yet the computer chips at the heart of the biggest servers that route and process information often differ little from the chips in smaller servers or everyday personal computers.

Princeton University researchers have developed a new computer chip called "Piton" (above) — after the metal spikes driven by rock climbers into mountainsides to aid in their ascent — that was designed specifically for massive computing systems. The chip could substantially increase processing speed while slashing energy usage, and is scalable, meaning that thousands of chips containing millions of independent processors can be connected into a single system. It was presented Aug. 23 at Hot Chips, a symposium on high-performance chips held in Cupertino, California. (Photo by David Wentzlaff, Department of Electrical Engineering) The Princeton researchers designed their chip specifically for massive computing systems. Piton could substantially increase processing speed while slashing energy usage. The chip architecture is scalable — designs can be built that go from a dozen to several thousand cores, which are the independent processors that carry out the instructions in a computer program. Also, the architecture enables thousands of chips to be connected into a single system containing millions of cores. "With Piton, we really sat down and rethought computer architecture in order to build a chip specifically for data centers and the cloud," said David Wentzlaff, a Princeton assistant professor of electrical engineering and associated faculty in the Department of Computer Science. "The chip we've made is among the largest chips ever built in academia and it shows how servers could run far more efficiently and cheaply." The unveiling of Piton is a culmination of years of effort by Wentzlaff and his students. Michael McKeown, Wentzlaff's graduate student, will present at Hot Chips. Mohammad Shahrad, a graduate student in Wentzlaff's Princeton Parallel Group, said that creating "a physical piece of hardware in an academic setting is a rare and very special opportunity for computer architects." The current version of the Piton chip measures 6 millimeters by 6 millimeters. The chip has more than 460 million transistors, each of which are as small as 32 nanometers — too small to be seen by anything but an electron microscope. The bulk of these transistors are contained in 25 cores. Most personal computer chips have four or eight cores. In general, more cores mean faster processing times, so long as software ably exploits the hardware's available cores to run operations in parallel. Therefore, computer manufacturers have turned to multi-core chips to squeeze further gains out of conventional approaches to computer hardware. In recent years companies and academic institutions have produced chips with many dozens of cores — but the readily scalable architecture of Piton can enable thousands of cores on a single chip with half a billion cores in the data center, Wentzlaff said. "What we have with Piton is really a prototype for future commercial server systems that could take advantage of a tremendous number of cores to speed up processing," Wentzlaff said.  The Piton chip's design focuses on exploiting commonality among programs running simultaneously on the same chip. One method to do this is called execution drafting. It works very much like the drafting in bicycle racing, when cyclists conserve energy by riding behind a lead rider who cuts through the air, creating a slipstream...

Princeton researchers have made its design open source and thus available to the public and fellow researchers
http://www.openpiton.org/