264 research outputs found
Retrospective: RAIDR: Retention-Aware Intelligent DRAM Refresh
Dynamic Random Access Memory (DRAM) is the prevalent memory technology used
to build main memory systems of almost all computers. A fundamental shortcoming
of DRAM is the need to refresh memory cells to keep stored data intact. DRAM
refresh consumes energy and degrades performance. It is also a technology
scaling challenge as its negative effects become worse as DRAM cell size
reduces and DRAM chip capacity increases.
Our ISCA 2012 paper, RAIDR, examines the DRAM refresh problem from a modern
computing systems perspective, demonstrating its projected impact on systems
with higher-capacity DRAM chips expected to be manufactured in the future. It
proposes and evaluates a simple and low-cost solution that greatly reduces the
performance & energy overheads of refresh by exploiting variation in data
retention times across DRAM rows. The key idea is to group the DRAM rows into
bins in terms of their minimum data retention times, store the bins in low-cost
Bloom filters, and refresh rows in different bins at different rates.
Evaluations in our paper (and later works) show that the idea greatly improves
performance & energy efficiency and its benefits increase with DRAM chip
capacity. The paper embodies an approach we have termed system-DRAM co-design.
This short retrospective provides a brief analysis of our RAIDR paper and its
impact. We briefly describe the mindset and circumstances that led to our focus
on the DRAM refresh problem and RAIDR's development, discuss later works that
provided improved analyses and solutions, and make some educated guesses on
what the future may bring on the DRAM refresh problem (and more generally in
DRAM technology scaling).Comment: Selected to the 50th Anniversary of ISCA (ACM/IEEE International
Symposium on Computer Architecture), Commemorative Issue, 202
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