将相变存储器架构为可扩展的dram替代品

Proceedings. International Symposium on Computer Architecture Pub Date : 2009-06-15 DOI:10.1145/1555754.1555758

Benjamin C. Lee, Engin Ipek, O. Mutlu, D. Burger

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引用次数: 1491

摘要

由于电荷存储和传感机制对于流行的存储器技术(如DRAM)变得不那么可靠，内存扩展处于危险之中。相比之下，相变存储器(PCM)存储依赖于可扩展的电流和热机制。为了利用PCM作为DRAM替代品的可扩展性，PCM的架构必须能够解决相对较长的延迟、高能量写入和有限的耐用性。我们从对PCM技术参数的基本理解出发，提出了区域中立的架构增强，以解决这些限制，并使PCM与DRAM竞争。基准PCM系统比DRAM系统慢1.6倍，需要2.2倍的能量。缓冲区重组将这种延迟和能量差距减少到1.2倍和1.0倍，使用窄行来减少写能量，使用多行来改善局域性和写合并。部分写入提高了内存的持久性，提供了5.6年的寿命。工艺缩放将进一步降低PCM能源成本并提高耐用性。

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Architecting phase change memory as a scalable dram alternative

Memory scaling is in jeopardy as charge storage and sensing mechanisms become less reliable for prevalent memory technologies, such as DRAM. In contrast, phase change memory (PCM) storage relies on scalable current and thermal mechanisms. To exploit PCM's scalability as a DRAM alternative, PCM must be architected to address relatively long latencies, high energy writes, and finite endurance. We propose, crafted from a fundamental understanding of PCM technology parameters, area-neutral architectural enhancements that address these limitations and make PCM competitive with DRAM. A baseline PCM system is 1.6x slower and requires 2.2x more energy than a DRAM system. Buffer reorganizations reduce this delay and energy gap to 1.2x and 1.0x, using narrow rows to mitigate write energy and multiple rows to improve locality and write coalescing. Partial writes enhance memory endurance, providing 5.6 years of lifetime. Process scaling will further reduce PCM energy costs and improve endurance.

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Proceedings. International Symposium on Computer Architecture

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