Title :
Scaling to the end of silicon with EDGE architectures
Author :
Burger, Doug ; Keckler, Stephen W. ; McKinley, Kathryn S. ; Dahlin, Mike ; John, Lizy K. ; Lin, Calvin ; Moore, Charles R. ; Burrill, James ; McDonald, Robert G. ; Yoder, William
Author_Institution :
Dept. of Comput. Sci., Texas Univ., Austin, TX, USA
fDate :
7/1/2004 12:00:00 AM
Abstract :
Microprocessor designs are on the verge of a post-RISC era in which companies must introduce new ISAs to address the challenges that modern CMOS technologies pose while also exploiting the massive levels of integration now possible. To meet these challenges, we have developed a new class of ISAs, called explicit data graph execution (EDGE), that will match the characteristics of semiconductor technology over the next decade. The TRIPS architecture is the first instantiation of an EDGE instruction set, a new, post-RISC class of instruction set architectures intended to match semiconductor technology evolution over the next decade, scaling to new levels of power efficiency and high performance.
Keywords :
instruction sets; parallel architectures; reduced instruction set computing; semiconductor technology; CMOS technology; EDGE architecture; TRIPS architecture; explicit data graph execution; microprocessor design; post-RISC instruction set architecture; semiconductor technology; Acceleration; CMOS technology; Clocks; Computer architecture; Instruction sets; Pipeline processing; Processor scheduling; Reduced instruction set computing; Silicon; VLIW;
