TY - GEN
T1 - Exploiting parallelism in I/O scheduling for access conflict minimization in flash-based solid state drives
AU - Gao, Congming
AU - Shi, Liang
AU - Zhao, Mengying
AU - Xue, Chun Jason
AU - Wu, Kaijie
AU - Sha, Edwin H.-M.
PY - 2014/6
Y1 - 2014/6
N2 - Solid state drives (SSDs) have been widely deployed in personal computers, data centers, and cloud storages. In order to improve performance, SSDs are usually constructed with a number of channels with each channel connecting to a number of NAND flash chips. Despite the rich parallelism offered by multiple channels and multiple chips per channel, recent studies show that the utilization of flash chips (i.e. the number of flash chips being accessed simultaneously) is seriously low. Our study shows that the low chip utilization is caused by the access conflict among I/O requests. In this work, we propose Parallel Issue Queuing (PIQ), a novel I/O scheduler at the host system, to minimize the access conflicts between I/O requests. The proposed PIQ schedules I/O requests without conflicts into the same batch and I/O requests with conflicts into different batches. Hence the multiple I/O requests in one batch can be fulfilled simultaneously by exploiting the rich parallelism of SSD. And because PIQ is implemented at the host side, it can take advantage of rich resource at host system such as main memory and CPU, which makes the overhead negligible. Extensive experimental results show that PIQ delivers significant performance improvement to the applications that have heavy access conflicts. © 2014 IEEE.
AB - Solid state drives (SSDs) have been widely deployed in personal computers, data centers, and cloud storages. In order to improve performance, SSDs are usually constructed with a number of channels with each channel connecting to a number of NAND flash chips. Despite the rich parallelism offered by multiple channels and multiple chips per channel, recent studies show that the utilization of flash chips (i.e. the number of flash chips being accessed simultaneously) is seriously low. Our study shows that the low chip utilization is caused by the access conflict among I/O requests. In this work, we propose Parallel Issue Queuing (PIQ), a novel I/O scheduler at the host system, to minimize the access conflicts between I/O requests. The proposed PIQ schedules I/O requests without conflicts into the same batch and I/O requests with conflicts into different batches. Hence the multiple I/O requests in one batch can be fulfilled simultaneously by exploiting the rich parallelism of SSD. And because PIQ is implemented at the host side, it can take advantage of rich resource at host system such as main memory and CPU, which makes the overhead negligible. Extensive experimental results show that PIQ delivers significant performance improvement to the applications that have heavy access conflicts. © 2014 IEEE.
UR - https://www.scopus.com/pages/publications/84905457563
UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-84905457563&origin=recordpage
U2 - 10.1109/MSST.2014.6855544
DO - 10.1109/MSST.2014.6855544
M3 - RGC 32 - Refereed conference paper (with host publication)
SN - 9781479956715
BT - IEEE Symposium on Mass Storage Systems and Technologies
PB - IEEE Computer Society
T2 - 30th Symposium on Massive Storage Systems and Technologies, MSST 2014
Y2 - 2 June 2014 through 6 June 2014
ER -