An efficient reverse-lookup table based strategy for solving the synonym and cache coherence problem in virtually indexed, virtually tagged caches

Virtually indexed and virtually tagged (VIVT) caches are an attractive option for micro-processor level-1 caches, because of their fast response time and because they are cheaper to implement than more complex caches such as virtually-indexed physical-tagged (VIPT) caches. The level-1 VIVT cache bec...

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Hauptverfasser: Desai, Madhav P, Deshmukh, Aniket
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Sprache:eng
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Zusammenfassung:Virtually indexed and virtually tagged (VIVT) caches are an attractive option for micro-processor level-1 caches, because of their fast response time and because they are cheaper to implement than more complex caches such as virtually-indexed physical-tagged (VIPT) caches. The level-1 VIVT cache becomes even simpler to construct if it is implemented as a direct-mapped cache (VIVT-DM cache). However, VIVT and VIVT-DM caches have some drawbacks. When the number of sets in the cache is larger than the smallest page size, there is a possibility of synonyms (two or more virtual addresses mapped to the same physical address) existing in the cache. Further, maintenance of cache coherence across multiple processors requires a physical to virtual translation mechanism in the hardware. We describe a simple, efficient reverse lookup table based approach to address the synonym and the coherence problems in VIVT (both set associative and direct-mapped) caches. In particular, the proposed scheme does not disturb the critical memory access paths in a typical micro-processor, and requires a low overhead for its implementation. We have implemented and validated the scheme in the AJIT 32-bit microprocessor core (an implementation of the SPARC-V8 ISA) and the implementation uses approximately 2% of the gates and 5.3% of the memory bits in the processor core.
DOI:10.48550/arxiv.2108.00444