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27.
Figure 1.1 Growth in processor performance over 40 years. This chart plots program performance relative to the VAX 11/780 as measured by the SPEC integer benchmarks
(see Section 1.8). Prior to the mid-1980s, about 22% per year, or every 3.5 years. 52% starting in 1986, or every 2 years, In 2003 the end of Dennard scaling 23% per year until
2011, or every 3.5 years. From 2011 to 2015, less than 12%, or every 8 years. Since 2015, the end of Moore’s Law, 3.5% per year, or every 20 years!
Computer Architecture, A Quantitative Approach: By John Hennessy David Patterson, 6th Edition, 2017
29.
Figure 1.1 Growth in processor performance over 40 years. This chart plots program performance relative to the VAX 11/780 as measured by the SPEC integer benchmarks
(see Section 1.8). Prior to the mid-1980s, about 22% per year, or every 3.5 years. 52% starting in 1986, or every 2 years, In 2003 the end of Dennard scaling 23% per year until
2011, or every 3.5 years. From 2011 to 2015, less than 12%, or every 8 years. Since 2015, the end of Moore’s Law, 3.5% per year, or every 20 years!
Computer Architecture, A Quantitative Approach: By John Hennessy David Patterson, 6th Edition, 2017
30.
• Many core processor
30
cpu core
cache
core core
cache core core
core
core
core core
core core
core
core
core core
dual core many coresingle core
…
Intel Xeon Phi Processor High Performance Programming:
Knights Landing Edition, by James Jeffers, et.al, 2016