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Comparison and Performance Evaluation of SAN File System

This paper explores the comparison and performance evaluation of SAN file systems, addressing the challenges of explosive data growth and the limitations of classic client/server distributed file systems. It examines the architectures of SAN file systems and discusses key characteristics, advantages, and two different approaches - distributed network-attached storage and hybrid models.

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Comparison and Performance Evaluation of SAN File System

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  1. Comparison and Performance Evaluation of SAN File System Yubing Wang & Qun Cai

  2. Outline • Background (YW) • SAN File System (YW) • Comparison of SAN File Systems (YW) • Performance Evaluation of SAN File Systems (QC)

  3. Background • Explosive Data Growth - Both documents and applications are becoming more media-rich, driving up file sizes. - Continued growth in capacity of memories and disks promotes further file growth. - Requires more graceful management of storage sizes and speeds. - Availability, scalability, and reliability are critical issues. • Classic Client/Server Distributed File Systems – the Problems - Single points of failure leading to low reliability and availability. - No means of high-performance data sharing: low bandwidths due to slow media, high protocol overheads, and server bottlenecks. - Limited scalability: inherent architecture drawback.

  4. Background - continued • Enabling Technologies • Fibre Channel • High bandwidth, low latency network and channel interface. • merges features from both networks and channel interfaces to create a storage interface. • Highly scalable, very flexible topologies. • open, high volume, industry standard. • Network-attached Storage (NAS) • A specialized servers with optimized file systems and thin OS that are tuned for the requirement of file serving. • Using NFS and CIFS for file access protocol. • Architecture

  5. SAN File System • Storage Area Networks (SAN) • NAS + Fibre Channel + Switch + HBA (Host Based Adapter). • Allows direct data transfer between disks and clients. • Architecture. • SAN File Systems • An architecture for distributed file systems based on shared storage. • Fully exploits the special characteristics of Filbre Channel-based LANs. • Key feature is that clients transfer data directly from the device across the SAN. • Example: Global File System (GFS), Central Version File System (CVFS), CXFS(SGI), SANergy (Tivoli Systems).

  6. SAN File Systems - Continued • Key Characteristics and Issues • More than one client may access the data from the same storage device. • Must recognize the existence of other clients accessing the same storage device and file system data and meta-data. • Directly through the meta-data.(GFS) • Through a file manager.(CVFS, CXFS) • Precludes most local file systems: these consider storage devices as owned and accessed by a single host computer. • Key Advantages • Availability is increased since the shared data is not owned by a single host. • Load-balancingis simplified by clients’ ability to access any portion of the shared disks. • Scalability in capacity, connectivity, and bandwidth can be achieved without limitations inherent in file systems designed with central servers.

  7. Two Architectures for SAN FS • Distributed network-attached storage model • making storage a part of the network rather than a part of the local server. • no central server, hosts are peer to peer. • file system in each host should coordinate to meta-data. • examples:GFS. • The Hybrid Network-Attached Storage Model • using meta server(s) as the coordinator of all the metadata traffic. • Real data and meta-data have separate paths. • Examples: CVFS, CXFS

  8. GFS • Global File System (GFS) • Developed at the University of Minnesota. • Using network storage pool – a shared address space of disk blocks. • The storage pool layer implements: locks, striping, name services etc. • Nodes are independent, no file manager. • Using Device Lock to maintain consistency. • Each GFS file system is divided into several Resource Groups (RGs). • Resource groups are designed to distribute file system resources across the entire storage subpool. • Resource groups are essentially a mini-file system. • Each group has a RG block, data bitmaps, dinode bitmaps, dinodes, and data blocks.

  9. CVFS & CXFS • CentralVersion File System (CVFS) • A distributed file system focused on the digital video and film industry. • Transferring data directly between network storage and clients. • Using TCP/IP transports under a client/server model for control and meta-data. • The file access protocol is token-based. • CXFS • A distributed file system in SGI. • Based on the SGI XFS file system. • Transferring data directly between network storage and clients. • Using TCP/IP transports under a client/server model for control and meta-data. • Could have more than one meta-servers.

  10. Comparison – Symmetric or Asymmetric • Symmetric - Any client can perform any file system operation without interacting with another client. • Asymmetric - A client must first make a request through a file manager executing on another host. • GFS is Symmetric - No central file manager (Meta-server). • CVFS and CXFS are asymmetric - Meta operations through meta-servers.

  11. Comparison - Locking • GFS • locking is in devices (shared storage). • similar to test-and-set locks in memory. • each device lock is associated with a logical clock. • many locks per device (up to 1024). • The locking mechanism caused poor scalability of GFS. • CXFS • locking is performed on inodes (File System), in either shared or exclusive mode. • CVFS • Token-based, a Token grants the right to a client to perform an operation on a file. • Tokens are maintained between meta-server and clients.

  12. Comparison - Caching • GFS • GFS cache metadata both on the disk driver caches and client memory . • Device locks maintain the consistency for the disk driver caches. • Locks are polled to determine if metadata in client is stale or not. • CXFS • CXFS buffer cache supports delayed allocation. • CXFS uses transactional logging mechanism to maintain consistency. • CVFS • Metadata is cached locally on the client. • Using a call-back mechanism to maintain consistency. • Certain attributes of metadata are flushed back to meta-server on demand.

  13. Comparison - Sharing • GFS • GFS distributes file system resources across the entire storage subsystem, allowing simultaneous access from multiple machines. • GFS supports both read and write sharing. • CXFS • When using buffered I/O, multiple readers can access the file concurrently, but only a single writer is allowed to the file at a time. • When using direct I/O, multiple readers and writers can all access the file simultaneously. • CVFS • CVFS provides no guarantees about the consistency of write-shared data. • Similar to UNIX semantics, “last writer wins”.

  14. Comparison – Meta-data Operations • GFS • The metadata in GFS (dinode) is partitioned into groups (Resource Groups) for scalability and load balancing. • Metadata can exist at disk, disk cache, and client memory. • Clients serve only local file system requests and act as file mangers for their requests. • CXFS • All the metadata operations are through meta-servers. • Infrequent compared with the data operations directly to the disks. • CVFS • All the metadata operations are through file system manager (FSM). • The message protocol between client and FSM is token-based. • Token contains information describing the file. • Metadata can be cached on clients and only flushed back to FSM on demand.

  15. Comparison – Data Transfer • GFS • GFS does not have a separate data transfer path. • Clients serve only local file system requests and act as file mangers for their requests. storage devices serve data directly to clients. • CXFS • CXFS uses a combination of clustering, read ahead, write behind, and request parallelism in order to exploit its underlying disk array. • CXFS allows applications to use direct I/O to move data directly between application memory and disk array using DMA. • CVFS • The clients locally cache the extent list, which describes the physical location of the file on disk. • Given the information in the extent list and the size of the stripe groups, the client initiates IO to each disk in the stripe disk simultaneously. • To avoid the data copies that are inherent in most protocol, CVFS transfers data directly from the Fibre Channel disks into the user’s application buffers.

  16. Performance Evaluation of SAN File Systems • To address the major aspects of SAN FS performance. • Scalability. • Sharing. • Meta-data operations. • Real data transfer. • Provide Micro-benchmarks to measure the performance of SAN FS. • In application level. • Measurethroughput and response-time.

  17. Related Work • Lmbench (microbenchmark) • Modified Andrew Benchmark • LADDIS from SPEC---NFS performance • Others

  18. Scalability • What to measure? • Number of clients that can be supported. • Aggregate bandwidth that can be achieved. • How to measure? • Increase the client number to saturate the whole system. • The applications include: write files, read files. • The whole file set accessed should be huge, much larger than cache size. • The file size varied exponentially from 8KB to 1GB. • The request (block) size varied from 8KB to 512KB. • For each write, using sync() to force the data to disk.

  19. Sharing • What to measure? • Multiple processes in a single host reading or writing to the same file. • Multiple processes in multiple hosts reading the same file. • Multiple processes in multiple hosts with one process writing a file and rest of the processes reading the same file. • Multiple processes in multiple hosts overwriting the same file. • Multiple processes in multiple hosts appending the same file. • Multiple processes in multiple hosts truncating the same file. • How to measure? • Both throughput and response-time should be measured. • Vary the number of sharing processes and hosts.

  20. Meta-data operations • What to measure? • Directory operations. • File Create and Delete. • File Access and Attribute. • Symbol Link etc. • How to measure? • Measure the response time for each operation. • Need to measure the meta operation performance in a heavily loading environment.

  21. Data Transfer • What to measure? • Read operation response time and throughput. • Writeoperation response time and throughput. • How to measure? • Direct I/O (raw I/O) if supported. • Buffered I/O. • Different read mode: sequential read, random read. • Different write mode: sequential write, random write.

  22. Work in future • Consider more micro-benchmarks for characters of SAN file system • Implement these Micro-benchmarks. • Build a micro-benchmark suite for SAN file system • Build a adaptable and widely-used benchmark to measure SAN file system performance.

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