Title :
Performance implications of next generation PowerPC/sup TM/ microprocessor cache architectures
Author_Institution :
Commercial Syst. Eng., Motorola Comput. Group, Tempe, AZ, USA
Abstract :
Modern CISC and RISC microprocessors use sophisticated caching schemes to bridge the performance mismatch between their internal execution units and the capabilities of commodity memory technologies. A variety of cache architectures and organizations have been developed and are finding use in current and future high-performance computer systems. Designers of systems with next-generation PowerPC/sup TM/ microprocessors face similar challenges. System performance implications for various cache architectures (look-aside, in-line, back-side) and cache organizations (direct-mapped, set-associative) need to be understood so that cost-effective cache hierarchies can be built. This paper presents the results of an analysis done at the Motorola Computer Group to characterize the required properties of a cache hierarchy for a next-generation G3 PowerPC superscalar low-power microprocessor.
Keywords :
cache storage; memory architecture; microprocessor chips; performance evaluation; reduced instruction set computing; CISC microprocessors; Motorola Computer Group; RISC microprocessors; back-side buffers; commodity memory technologies; cost-effective cache hierarchies; direct-mapped cache organization; in-line buffers; internal execution units; look-aside buffers; microprocessor cache architectures; next-generation G3 PowerPC superscalar low-power microprocessor; performance mismatch; set-associative cache organization; system performance implications; Bridges; Computer architecture; Costs; Microprocessors; Modems; Power engineering and energy; Power engineering computing; Reduced instruction set computing; System performance; Systems engineering and theory;
Conference_Titel :
Compcon '97. Proceedings, IEEE
Conference_Location :
San Jose, CA, USA
Print_ISBN :
0-8186-7804-6
DOI :
10.1109/CMPCON.1997.584746
