论文信息 - Replicate and Bundle (RnB) -- A Mechanism for Relieving Bottlenecks in Data Centers

Replicate and Bundle (RnB) -- A Mechanism for Relieving Bottlenecks in Data Centers

This work addresses the scalability and efficiency of RAM-based storage systems wherein multiple objects must be retrieved per user request. Here, much of the CPU work is per server transaction, not per requested item. Adding servers and spreading the data across them also spreads any given set of requested items across more servers, thereby increasing the total number of server transactions per user request. The resulting poor scalability, dubbed the Multi-get Hole, has been reported in Web 2.0 systems using memcached - a popular memory-based key-value storage system. We present Replicate and Bundle (RnB), a somewhat unintuitive approach: rather than add CPUs, we add memory. Object replicas are mapped “randomly” to servers, and requested objects are bundled, selecting replicas so as to minimize the number of servers accessed per user request and thus the total CPU work per request. We studied RnB via simulation in the context of DRAM-based storage, utilizing micro benchmarks and implemented RnB modules for calibration. Our results show that RnB substantially reduces the number of transactions per request, making operation more efficient. Also, unlike most alternatives, RnB permits flexible growth and relatively easy deployment. Finally, in systems wherein data is replicated for other reasons, RnB is nearly free.

Yitzhak Birk | Shachar Raindel

[1] Azadeh Iranmehr,et al. Trust Management for Semantic Web , 2009, 2009 Second International Conference on Computer and Electrical Engineering.

[2] David R. Karger,et al. Consistent hashing and random trees: distributed caching protocols for relieving hot spots on the World Wide Web , 1997, STOC '97.

[3] Michael Mitzenmacher,et al. The Power of Two Choices in Randomized Load Balancing , 2001, IEEE Trans. Parallel Distributed Syst..

[4] Richard M. Karp,et al. Reducibility Among Combinatorial Problems , 1972, 50 Years of Integer Programming.

[5] Junda Liu,et al. Multi-enterprise networking , 2000 .

[6] Indranil Gupta,et al. Social Network-Aware Disk Management , 2010 .

[7] Pablo Rodriguez,et al. The little engine(s) that could: scaling online social networks , 2010, SIGCOMM '10.

[8] Mendel Rosenblum,et al. Fast crash recovery in RAMCloud , 2011, SOSP.

[9] D. A. Sprott. Urn Models and Their Application—An Approach to Modern Discrete Probability Theory , 1978 .

[10] Jure Leskovec,et al. Signed networks in social media , 2010, CHI.

[11] Lars Backstrom,et al. The Anatomy of the Facebook Social Graph , 2011, ArXiv.

[12] Amar Phanishayee,et al. FAWN: a fast array of wimpy nodes , 2009, SOSP '09.

[13] Michael J. Freedman,et al. Object Storage on CRAQ: High-Throughput Chain Replication for Read-Mostly Workloads , 2009, USENIX Annual Technical Conference.