Storage Class Memory: Avanços e Limitações em Direção às Memórias Universais
Resumo
Recentemente vem chamando a atenção o avanço nas pesquisas de novas tecnologias de memória chamadas de memórias emergentes, memórias persistentes ou Storage Class Memory, (SCM). Nesse texto discutimos as limitações e dificuldades para a criação de uma memória universal que substituiria toda a hierarquia de memórias por uma única memória. As SCM se aproximam das características necessárias para a criação de uma memória universal, mas ainda não as satisfazem completamente. Assim, as SCM podem pragmaticamente serem vistas como uma adição à hierarquia de memória atual, substituindo ou trabalhando em conjunto com as tecnologias SSD, DRAM e SRAM. Neste texto, exploramos o estado atual das SCM e discutimos sua evolução, com o objetivo final de reduzir a latência de memória para a CPU.Referências
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S.Yu and P.Chen. Emerging memory technologies: Recent trends and prospects. IEEE Solid-State Circuits Magazine, 8(2):43–56, 2016.
A. Thomasian. Storage Systems: Organization, Performance, Coding, Reliability, and Their Data Processing. Academic Press, 2021.
X. Dong et al. Nvsim: A circuit-level performance, energy, and area model for emerging nonvolatile memory. IEEE Transactions, 31(7):994–1007, 2012.
R. Gastaldi and G. Campardo. In Search of the Next Memory: Inside the Circuitry from the Oldest to the Emerging Non-Volatile Memories. Springer, 2017.
G.Burr et al. Overview of candidate, device technologies for storage-class memory. IBM Journal of Research and Development, 52(4.5):449–464, 2008.
Intel Corp. Intel 64 and IA-32 Architectures Optimization Reference Manual, 2022.
J.Mittal and S.Mittal. Opportunities for nonvolatile memory systems in extreme-scale high-performance computing. Computing in Science & Engineering, 17(2), 2015.
K.Ando et al. Non-volatile memories. Normally-Off Computing, pages 27–55, 2017.
C. H. Lam. The universal semiconductor memory. In 2012 IEEE 11th International Conference on Solid-State and Integrated Circuit Technology, pages 1–5, 2012.
L.Baldi et al. Emerging memories. In 2013 Proceedings of the European Solid-State Device Research Conference (ESSDERC), pages 30–36, 2013.
M. Marinella. The future of memory. In 2013 IEEE Aerospace Conference, 2013.
M.Rudan et al. Springer Handbook of Semiconductor Devices. Springer, 2023.
R.Freitas and W.Wilcke. Storage-class memory: The next storage system technology. IBM Journal of Research and Development, 52(4.5):439–447, 2008.
S.Yu and P.Chen. Emerging memory technologies: Recent trends and prospects. IEEE Solid-State Circuits Magazine, 8(2):43–56, 2016.
A. Thomasian. Storage Systems: Organization, Performance, Coding, Reliability, and Their Data Processing. Academic Press, 2021.
Publicado
16/05/2024
Como Citar
LAKS, Pedro Ferro; FRANCESQUINI, Emilio.
Storage Class Memory: Avanços e Limitações em Direção às Memórias Universais. In: ESCOLA REGIONAL DE ALTO DESEMPENHO DE SÃO PAULO (ERAD-SP), 15. , 2024, Rio Claro/SP.
Anais [...].
Porto Alegre: Sociedade Brasileira de Computação,
2024
.
p. 73-76.
DOI: https://doi.org/10.5753/eradsp.2024.239863.
