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Impact of Failure on Interconnection Networks for Large Storage Systems

Impact of Failure on Interconnection Networks for Large Storage Systems. Qin Xin, Ethan L. Miller, Thomas J. E. Schwarz*, Darrell D. E. Long Storage Systems Research Center University of California, Santa Cruz *Department of Computer Engineering Santa Clara University. Problems.

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Impact of Failure on Interconnection Networks for Large Storage Systems

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  1. Impact of Failure on Interconnection Networks for Large Storage Systems Qin Xin, Ethan L. Miller, Thomas J. E. Schwarz*, Darrell D. E. Long Storage Systems Research Center University of California, Santa Cruz *Department of Computer Engineering Santa Clara University

  2. Problems • Reliability is a real concern for large storage systems • A large number of components • Complex interconnections • Human errors • Robust network interconnection is desired • Failures of switches, routers, and network links are common • Organization of nodes and links is crucial • Scale makes things complicated: petabyte storage system --10,000s disks, 100s routers,100,000s links • Robust network topology • Tolerant multi-points of failures without noticeable performance degradation MSST'05

  3. Contributions • Examine various network topologies • Butterfly networks • Mesh structure • Hypercube • Tradeoffs among them: cost, robustness, performance. • Estimate the impacts of link and node failures by simulation • I/O path connectivity • Number of hops in varied degraded modes • Failure impact to its neighborhood MSST'05

  4. Network Topology for Storage Systems • Butterfly networks • Reasonable cost • Poor robustness • Mesh • Brick-structured, good robustness • Relatively long path • Hypercube • Superior robustness • Complex, costly MSST'05

  5. A case study: Failure Scenarios MSST'05

  6. Simulated Results: Connectivity • I/O path connectivity • Measured in “nines”: -log10(1-P), P: m/n, m: # of good requests, n: # of total requests. (3 nines = 99.9%) • Poor connectively when the connection nodes are lost. • Hypercube and mesh are more robust in connectivity than butterfly networks. MSST'05

  7. Simulation Results: Neighborhood butterfly mesh hypercube • Failure impact on network neighborhood • Neighbors suffer in presence of failures. • Hypercube outperforms butterfly & mesh structure in avg. I/O load. MSST'05

  8. Summary • A well-chosen topology can provide robust interconnection. • Neighbors around failures suffer much more than average. • Hypercube structure provides better interconnection in degraded modes than butterfly and mesh structure. MSST'05

  9. Questions? • For further information, please visit: • http://ssrc.cse.ucsc.edu/ • http://www.cs.ucsc.edu/~qxin/ • Thanks to SSRC faculty, students, affiliates, and alumni • Thanks to our sponsors • Lawrence Livermore National Laboratory, Los Alamos National Laboratory, Sandia National Laboratory • Engenio Information Technologies, HP Lab, Hitachi Global Storage Technologies, IBM Research, Intel, LSI Logic, Microsoft Research, Network Appliance, and Veritas • NSF, USENIX MSST'05

  10. Big Picture: A Petabyte-Scale Storage System • Potential for data loss • Thousands of disks • Petabytes of data MSST'05

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