Huaicheng Li, Martin L. Putra, Ronald Shi, Fadhil I. Kurnia, Xing Lin, Jaeyoung Do, Achmad Imam Kistijantoro, Gregory R. Ganger, Haryadi S. Gunawi
{"title":"Flash阵列NVMe I/O确定性接口的扩展与编程","authors":"Huaicheng Li, Martin L. Putra, Ronald Shi, Fadhil I. Kurnia, Xing Lin, Jaeyoung Do, Achmad Imam Kistijantoro, Gregory R. Ganger, Haryadi S. Gunawi","doi":"https://dl.acm.org/doi/10.1145/3568427","DOIUrl":null,"url":null,"abstract":"<p>Predictable latency on flash storage is a long-pursuit goal, yet unpredictability stays due to the unavoidable disturbance from many well-known SSD internal activities. To combat this issue, the recent NVMe IO Determinism (IOD) interface advocates host-level controls to SSD internal management tasks. Although promising, challenges remain on how to exploit it for truly predictable performance.</p><p>We present <span>IODA</span>,<sup>1</sup> an I/O deterministic flash array design built on top of small but powerful extensions to the IOD interface for easy deployment. <span>IODA</span> exploits data redundancy in the context of IOD for a strong latency predictability contract. In <span>IODA</span>, SSDs are expected to quickly fail an I/O on purpose to allow predictable I/Os through proactive data reconstruction. In the case of concurrent internal operations, <span>IODA</span> introduces busy remaining time exposure and predictable-latency-window formulation to guarantee predictable data reconstructions. Overall, <span>IODA</span> only adds five new fields to the NVMe interface and a small modification in the flash firmware while keeping most of the complexity in the host OS. Our evaluation shows that <span>IODA</span> improves the 95–99.99<sup>th</sup> latencies by up to 75×. <span>IODA</span> is also the nearest to the ideal, no disturbance case compared to seven state-of-the-art preemption, suspension, GC coordination, partitioning, tiny-tail flash controller, prediction, and proactive approaches.</p>","PeriodicalId":49113,"journal":{"name":"ACM Transactions on Storage","volume":"1 1","pages":""},"PeriodicalIF":2.1000,"publicationDate":"2023-01-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Extending and Programming the NVMe I/O Determinism Interface for Flash Arrays\",\"authors\":\"Huaicheng Li, Martin L. Putra, Ronald Shi, Fadhil I. Kurnia, Xing Lin, Jaeyoung Do, Achmad Imam Kistijantoro, Gregory R. Ganger, Haryadi S. Gunawi\",\"doi\":\"https://dl.acm.org/doi/10.1145/3568427\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Predictable latency on flash storage is a long-pursuit goal, yet unpredictability stays due to the unavoidable disturbance from many well-known SSD internal activities. To combat this issue, the recent NVMe IO Determinism (IOD) interface advocates host-level controls to SSD internal management tasks. Although promising, challenges remain on how to exploit it for truly predictable performance.</p><p>We present <span>IODA</span>,<sup>1</sup> an I/O deterministic flash array design built on top of small but powerful extensions to the IOD interface for easy deployment. <span>IODA</span> exploits data redundancy in the context of IOD for a strong latency predictability contract. In <span>IODA</span>, SSDs are expected to quickly fail an I/O on purpose to allow predictable I/Os through proactive data reconstruction. 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Extending and Programming the NVMe I/O Determinism Interface for Flash Arrays
Predictable latency on flash storage is a long-pursuit goal, yet unpredictability stays due to the unavoidable disturbance from many well-known SSD internal activities. To combat this issue, the recent NVMe IO Determinism (IOD) interface advocates host-level controls to SSD internal management tasks. Although promising, challenges remain on how to exploit it for truly predictable performance.
We present IODA,1 an I/O deterministic flash array design built on top of small but powerful extensions to the IOD interface for easy deployment. IODA exploits data redundancy in the context of IOD for a strong latency predictability contract. In IODA, SSDs are expected to quickly fail an I/O on purpose to allow predictable I/Os through proactive data reconstruction. In the case of concurrent internal operations, IODA introduces busy remaining time exposure and predictable-latency-window formulation to guarantee predictable data reconstructions. Overall, IODA only adds five new fields to the NVMe interface and a small modification in the flash firmware while keeping most of the complexity in the host OS. Our evaluation shows that IODA improves the 95–99.99th latencies by up to 75×. IODA is also the nearest to the ideal, no disturbance case compared to seven state-of-the-art preemption, suspension, GC coordination, partitioning, tiny-tail flash controller, prediction, and proactive approaches.
期刊介绍:
The ACM Transactions on Storage (TOS) is a new journal with an intent to publish original archival papers in the area of storage and closely related disciplines. Articles that appear in TOS will tend either to present new techniques and concepts or to report novel experiences and experiments with practical systems. Storage is a broad and multidisciplinary area that comprises of network protocols, resource management, data backup, replication, recovery, devices, security, and theory of data coding, densities, and low-power. Potential synergies among these fields are expected to open up new research directions.