Abstract

This paper describes a novel cache architecture suitable for merged DRAM/logic LSIs, called variable line-size cache or VLS cache, for resolving the above-mentioned dilemma. The VLS cache can make good use of the high on-chip memory bandwidth by means of larger cache lines and, at the same time, alleviate the negative effects of larger cache-line size by partitioning each large cache line into multiple sub-lines and allowing every sub-line to work as an independent cache line. The number of sub-lines involved when a cache replacement occurs can be determined depending on the characteristics of programs. This paper also evaluates the cost/performance improvements attainable by the VLS cache and compares it with those of conventional cache architectures. As a result, it is observed that a VLS cache reduces the average memory-access time by 16:4% while it increases the hardware cost by only 13%, compared to a conventional direct-mapped cache with fixed 32-byte lines.