StaR: Breaking the Scalability Limit for RDMA

Xizheng Wang, Guo Chen, Xijin Yin, Huichen Dai, Bojie Li, Binzhang Fu, Kun Tan
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引用次数: 8

Abstract

Due to its superior performance, Remote Direct Memory Access (RDMA) has been widely deployed in data center networks. It provides applications with ultra-high throughput, ultra-low latency, and far lower CPU utilization than TCP/IP software network stack. However, the connection states that must be stored on the RDMA NIC (RNIC) and the small NIC memory result in poor scalability. The performance drops significantly when the RNIC needs to maintain a large number of concurrent connections.We propose StaR (Stateless RDMA), which solves the scalability problem of RDMA by transferring states to the other communication end. Leveraging the asymmetric communication pattern in data center applications, StaR lets the communication end with low concurrency save states for the other end with high concurrency, thus making the RNIC on the bottleneck side to be stateless. We have implemented StaR on an FPGA board with 10Gbps network port and evaluated its performance on a testbed with 9 machines all equipped with StaR NICs. The experimental results show that in high concurrency scenarios, the throughput of StaR can reach up to 4.13x and 1.35x of the original RNIC and the latest software-based solution, respectively.
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StaR:打破RDMA的可扩展性限制
RDMA (Remote Direct Memory Access)由于其优越的性能,在数据中心网络中得到了广泛的应用。它为应用程序提供了比TCP/IP软件网络堆栈更高的吞吐量、更低的延迟和更低的CPU利用率。但是,必须存储在RDMA网卡(RNIC)上的连接状态和较小的网卡内存导致可扩展性较差。当RNIC需要维护大量并发连接时,性能会明显下降。我们提出了StaR(无状态RDMA),它通过向另一端传输状态来解决RDMA的可扩展性问题。利用数据中心应用程序中的非对称通信模式,StaR允许具有低并发性的通信端为具有高并发性的另一端保存状态,从而使瓶颈端的RNIC处于无状态状态。我们在带有10Gbps网络端口的FPGA板上实现了StaR,并在配备StaR网卡的9台机器的测试台上对其性能进行了评估。实验结果表明,在高并发场景下,StaR的吞吐量分别可以达到原始RNIC和最新基于软件的解决方案的4.13倍和1.35倍。
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