Enabling Efficient and Scalable DRAM Read Disturbance Mitigation via New Experimental Insights into Modern DRAM Chips
Abdullah Giray Ya\u{g}l{\i}k\c{c}{\i}
TL;DR
This paper provides detailed experimental insights into modern DRAM chips to develop scalable, efficient mitigation techniques for read disturbance vulnerabilities, crucial for secure and reliable future memory systems.
Contribution
It offers a comprehensive characterization of DRAM read disturbance under various conditions and introduces new mitigation mechanisms that do not rely on proprietary chip knowledge.
Findings
Read disturbance varies significantly across DRAM locations and conditions.
New mitigation techniques leveraging subarray parallelism are effective.
Selective throttling can prevent read disturbance without proprietary info.
Abstract
Increasing storage density exacerbates DRAM read disturbance, a circuit-level vulnerability exploited by system-level attacks. Unfortunately, existing defenses are either ineffective or prohibitively expensive. Efficient mitigation is critical to ensure robust (reliable, secure, and safe) execution in future DRAM-based systems. This dissertation tackles two problems: 1) protecting DRAM-based systems becomes more expensive as technology scaling increases read disturbance vulnerability, and 2) many existing solutions depend on proprietary knowledge of DRAM internals. First, we build a detailed understanding of DRAM read disturbance by rigorously characterizing off-the-shelf modern DRAM chips under varying 1) temperatures, 2) memory access patterns, 3) in-chip locations, and 4) voltage. Our novel observations demystify the implications of large DRAM read disturbance variation on future…
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Taxonomy
TopicsAdvanced Memory and Neural Computing · Low-power high-performance VLSI design · Semiconductor materials and devices