1 / 34

Building a High Performance Mass Storage System for Tier1 LHC site

GRID’2012, July 16 – 21 Dubna , Russia. Building a High Performance Mass Storage System for Tier1 LHC site. Vladimir Sapunenko, INFN-CNAF. Tier1 site at INFN-CNAF. CNAF  is the National Center of INFN ( National Institute of Nuclear Physics) for Research and Development into

duane
Download Presentation

Building a High Performance Mass Storage System for Tier1 LHC site

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. GRID’2012, July 16 – 21 Dubna, Russia Building a High Performance Mass Storage System for Tier1 LHC site Vladimir Sapunenko, INFN-CNAF

  2. Tier1 site at INFN-CNAF CNAF is the National Center of INFN (National Institute of Nuclear Physics) for Research and Development into the field of Information Technologies applied to High-Energy physics experiments. Operational since 2005 Vladimir.Sapunenko@cnaf.infn.it

  3. Tier1 at glance • All 4 LHC experiments • 20 HEP, Space and Astro physics experiments • Computation Farm • 1300 WNs • 130K HEP SPEC • 13K job slots • Storage • 10 PB on disk • 14 PB on tapes Vladimir.Sapunenko@cnaf.infn.it

  4. Mass Storage Challenge • Several PetaBytes of data (online and near-line) need to be accessed at any time from thousands of concurrent processes • Aggregated data throughput required, both on Local Area Network (LAN) and Wide Area Network (WAN), is of the order of several GB/s. • Long term transparent archiving of data is needed • Frequent configuration changes • Independent experiments (with independent production managers and end-users) concur for the usage of disk and tape resources • Chaotic access can lead to traffic jams which must be taken into account as quasi-ordinary situations Vladimir.Sapunenko@cnaf.infn.it

  5. What do we need to doto meet that challenge? • We need to a Mass Storage Solution which has the following features • Grid-enabled • high performance • modular • stable and robust • targeted to large computing centers (as WLCG Tier-1s) • “large” means custodial of O(10) PB of data • simple installation and management • 24x7 operation with limited manpower • centralized administration Vladimir.Sapunenko@cnaf.infn.it

  6. Storage HW • 10 PB of disks • 15 disk arrays • (8x EMC CX3-80, 7x DDN S2A 9950) • ~130 disk servers • 40 10Gb/s Eth (250-300 TB/server) • 90 2x1Gb/s Eth (50-75 TB/server) • 14 PB of tapes • SL8500 tape library (10K slots) • 20 T10000B drives (1TB cartridge) • 10 T10000C drives (5TB cartridge) • 1 TSM server (+1 stand-by) • 13 HSM nodes • ~ 500 SAN ports (FC4/FC8) Vladimir.Sapunenko@cnaf.infn.it

  7. ATLAS: outside view • Disk space used by Atlas, % • INFN’s share is 8% • Data volume processed in 1 month • INFN’s share is 10% • Average efficiency of successfully completed jobs • INFN:the second in global ranking (data from DQ2 Atlas accounting) CNAF Vladimir.Sapunenko@cnaf.infn.it

  8. ATLAS: inside view • 2.3 PB of disk space • 3 DDN S2A9950, 2TB SATA, 8xFC8 • 8 I/O servers (10Gb/s, 24GB RAM, 2xFC8) • 2 metadata servers (1Gb/s, 4GB RAM, 2FC4) • 4 gridFTP servers (10Gb/s,24GB RAM, 2xFC8) • 5 StoRM servers (1Gb/s, 4GB RAM) • 2 HSM servers (1Gb/s, 4GB RAM) 1 week Stats in GB/s to/from LAN (farm) to/from WAN(gridftp) Vladimir.Sapunenko@cnaf.infn.it

  9. LHCB: CPU used at CERN and Tier-1s in 2012 Share of used CPU in succesful jobs CERN CNAF CNAF is the first centre after CERN for CPU used and the last when counted for fraction of CPU time wasted by jobs failing for any reason GRIDKA SARA PIC RAL NIKHEF IN2P3 Share of CPU used in failedjobs The mainreason: stabilityof the storage system ! CNAF Vladimir.Sapunenko@cnaf.infn.it

  10. LHCB • 0.76 PB of disk space • 1 EMC CX4, 1TB SATA, 8xFC4 • 10 I/O servers (2x1Gb/s, 8GB RAM, 2xFC4) • 2 metadata servers (1Gb/s, 8GB RAM, 2xFC4) • 4 gridFTP servers (2x1Gb/s,8GB RAM, 2xFC4) • 3 StoRM servers (1Gb/s, 4GB RAM) • 2 HSM servers (1Gb/s, 4GB RAM) • 0.76 PB of unique file system • 40TB reserved as tape buffer • More space can be used if available Vladimir.Sapunenko@cnaf.infn.it

  11. LHCB data by site CNAF Vladimir.Sapunenko@cnaf.infn.it

  12. ALICE (MonALISA) I/O activity on disk IN: 100 MB/s OUT: 2.1 GB/s I/O activity on tape buffer IN: 5 MB/s OUT: 800 MB/s Vladimir.Sapunenko@cnaf.infn.it

  13. ALICE • 8 XrootD servers • 6 for Disk-only, • 2 for Tape buffer • 8 core 2.2GHz, 10Gb/s, 24GB RAM, 2xFC8 • 2 metadata servers • Storage • DDN S2A 9950, • 1.3PB net space • Two GPFS file systems • 960TB disk-only • 385TB tape buffer • Manages tape recalls directly from GPFS • Custom plug-in to interface XrootD with GEMSS (CNAF’s MSS) • modified method XrdxFtsOfsFile::openin XrootD library • By F. Noferini andV. Vagnoni Vladimir.Sapunenko@cnaf.infn.it

  14. ALICE: Tape Performance • ALICE is doing hard this week reading a lot from the tape buffer Reads from tapes Vladimir.Sapunenko@cnaf.infn.it

  15. Tier1 Storage Group:Tasks and Staff • Tasks: • Disk storage administration (GPFS, GEMSS) • Tape library (ACSLS, TSM) • SAN maintenance, administration • Servers installation and configuration • Services (SRM, FTS, DB) • Monitoring (of all HW and SW components) • Procurement (Tender definition) • HW life circle management and 1st level support • Staff: • Just 5 FTE (“Full Time Equivalent”) • How do we manage all this? Vladimir.Sapunenko@cnaf.infn.it

  16. Our approach • Fault tolerance and Redundancy everywhere but avoiding resources trashing • Using “Active-Active” configurations as much as possible • load of failed elements distributed over remaining (SAN, servers, controllers) • Monitoring and Automated recovery procedures • NAGIOS event handlers • Minimizing number of managed objects • Few butBIGstorage systems • 10Gb servers • High level of optimization • OS and network tuning • Test everything before deploying • A dedicated cluster with all functionality as testing facility (testbed) • Relying on industry standards (GPFS, TSM) • Reducing complexity • TSM rather than HPSS Vladimir.Sapunenko@cnaf.infn.it

  17. Software components • GPFS as a Clustered Parallel File System • TSM as HSM system • StoRM as SRM • GEMSS as interface between StoRMand GPFS and TSM • NAGIOS as alarm and event handling • QUATTOR as system configuration manager • LEMON as monitoring tool Vladimir.Sapunenko@cnaf.infn.it

  18. GPFS • General Parallel File System from IBM • Clustered (fault tolerance and redundancy) • Parallel (scalability) • Used widely in industry (very well documented and supported by user community and by IBM) • Always provide maximum performance (no need to replicate data to increase availability) • Running on AIX, Linux (RH, SL) and Windows  • Is NOT bounded to IBM’s HW! Vladimir.Sapunenko@cnaf.infn.it

  19. GPFS (2) • Advanced High-Availability features • disruption-freemaintainance • servers and storagedevices can beadded or removedwhilekeeping the filesystems online • whenstorageisadded or removed the data can bedynamicallyrebalancedtomaintainoptimal performance • Centralized administration • cluster-wide operations can bemanagedfromanynode in the GPFS cluster • easy administrationmodel, consistentwith standard UNIX file systems • Support standard file system functions • userquotas, snapshots, etc. • Manyotherfeaturesnotfitting in twoslides… Vladimir.Sapunenko@cnaf.infn.it

  20. TSM • Tivoli Storage Manager (IBM) • Very powerful • Simple • DB (db2) management hidden form administrator • Build-in HSM functionality • Transparent data movement • Integrated with GPFS • Widely used in industry • A lot of experience • easy to get technical support ether from IBM or from user community Vladimir.Sapunenko@cnaf.infn.it

  21. StoRM: STOrage Resource Manager StoRM is an implementation of the SRM solution designed to leverage the advantages of cluster file systems (like GPFS) and standard POSIX file systems in a Grid environment developed at INFN-CNAF. • http://storm.forge.cnaf.infn.it • StoRM provides data management capabilities in a Grid environment to share, access and transfer data among heterogeneous and geographically distributed data centers, supporting direct access (native POSIX I/O call) to shared files and directories, as well as other standard Grid access protocols. StoRM is adopted in the context of WLCG computational Grid framework. Vladimir.Sapunenko@cnaf.infn.it

  22. A little bit of history CASTOR was the “traditional” solution for Mass Storage at CNAF for all VO'ssince 2003 Large variety of issues • both at set-up/admin level and at VO’s level (complexity, scalability, stability, …) • successfully used in production, despite large operational overhead In parallel to production, in 2006 we started to search for a potentially more scalable, performing and robust solution • Q1 2007: after massive comparison tests GPFS was chosen as the only solution for disk-based storage (it was already in use at CNAF for a long time before this test) • Q2 2007: StoRM (developed at INFN) implements SRM 2.2 specifications • Q3-Q4 2007: StoRM/GPFS in production for D1T0 for LHCb and Atlas • Clear benefits for both experiments (significantly reduced load on CASTOR) • End 2007: a project started at CNAF to realize a complete grid-enabled HSM solution based on StoRM/GPFS/TSM Vladimir.Sapunenko@cnaf.infn.it

  23. GEMSS • Grid Enabled Mass Storage System • A full HSM (Hierarchical Storage Management) integration of GPFS, TSM and StoRM • combined GPFS and TSM specific features with StoRM to provide a transparent Grid-friendly HSM solution • An interface between GPFS and TSM has been implemented to minimize mechanical operations in tape robotics (mount/unmount, search/rewind) • StoRM has been extended to include the SRM methods required to manage the tapes • Permits minimize management effort and increase reliability • Very positive experience for scalability so far • Based on large GPFS installation in production at CNAF since 2005 with increasing disk space and number of users Vladimir.Sapunenko@cnaf.infn.it

  24. GEMSS Development TimeLine D1T0 Storage Class implemented with StoRM/GPFS for LHCb and ATLAS D0T1 Storage Class implementedwith StoRM/GPFS/TSM for CMS ATLAS, ALICE, (CMS) and LHCb experiments, together with all other non-LHC experiments (Argo, Pamela, Virgo, AMS) use GEMSS in production! 2011 2012 2007 2008 2009 2010 D1T1 Storage Class implementedwith StoRM/GPFS/TSM for LHCb Introduced DMAPI server (to support GPFS 3.3/3.4 GEMSS is used by all LHC and non-LHC experiments in production for all Storage Classes Vladimir.Sapunenko@cnaf.infn.it

  25. Components of GEMSS Disk-centricsystemwithfivebuildingblocks • GPFS: disk-storage software infrastructure • TSM: tape management system • StoRM: SRM service • TSM-GPFS interface • GlobusGridFTP: WAN data transfers Vladimir.Sapunenko@cnaf.infn.it

  26. GEMSS recall system • Selective recall system in GEMSS use 4 processes: yamssEnqueueRecall yamssMonitor, yamssReorderRecall yamssProcessRecall • yamssEnqueueRecall & yamssrReorderRecallmanage a FIFO queue with the files to be recalled, fetches files from the queue and builds sorted lists with optimal file ordering. • yamssProcessRecallactually creates the recall streams, perform the recalls and manages the error conditions (i.e. retries file recall failures…) • yamssMonitoris the supervisor of the reorder and recall phases Vladimir.Sapunenko@cnaf.infn.it

  27. GEMSS interface • Set of administrative commands have been also developed, (for monitoring, stopping and starting migrations and recalls, performance reporting). • Almost 50 user interface commands/daemon some examples: • yamssEnqueueRecall (command) • Simple command line to enqueue into a FIFO the files to recall from tape • yamssLogger (daemon) • Centralized logging facilty. 3 log files (for migrations, premigrations and recalls) are centralized for each YAMSS-managed file system • yamssLs (command) • “ls”-like interface, but in addition prints status of each file: premigrated, migrated, disk-resident. • Shipped as RPM package for installation/distribution • Provides several STAT files for accurate statistic which includes • file name • Time stamp • File size • Tape label Vladimir.Sapunenko@cnaf.infn.it

  28. Pre-production tests ~ 400 MB/s Up to ~ 530 MB/s of tape recalls • ~24 TB of data moved from tape to disk • Recalls of five days typical usage by a large LHC experiment (namely CMS) compacted in one shot and completed in 19h • Files were spread on ~100 tapes • Average throughput: ~400MB/s • 0 failures • Up to 6 drives used for recalls • Simultaneously, up to 3 drives used for migrations of new data files Vladimir.Sapunenko@cnaf.infn.it

  29. GEMSS monitoring • Integration with NAGIOS for alert system, notification and automatic actions (i.e. restarting of failed TSM daemons) • Integration with LEMON monitoring. T10KB Tape drive (SAN traffic) Vladimir.Sapunenko@cnaf.infn.it

  30. GEMSS in production • ~11 PB of data have been migrated to tapes since GEMSS entered in production • (some data was deleted by user => now 8.9PB used) Vladimir.Sapunenko@cnaf.infn.it

  31. ATLAS data re-processing • 4,20% of total processing activity at T1 (170 TB) in 2011 • ATLAS Computing activity involving massivedata recall from tape • High efficiency (99% successful jobs) • Just a few days to complete GPFS <=> TSM traffic • write: recalls for tape to disk for reprocessing read: write to tape from TIER-0 (raw data flow) • Goodperformance for simultaneousread/writeaccess Vladimir.Sapunenko@cnaf.infn.it

  32. Conclusions • We implemented a full HSM system based on GPFS and TSM able to satisfy the requirements of WLCG experiments operating the Large Hadron Collider • StoRM, the SRM service for GPFS, has been extended in order to manage tape support • An interface between GPFS and TSM (GEMSS) was realized in order to perform tape recalls in an optimal order, so achieving great performances • A modification to XrootD library permitted to interface XrootD and GEMMS • GEMSS is the storage solution used in production in our Tier1 as a single integrated system for ALL the LHC and no-LHC experiments. • The recent improvements in GEMSS have increased the level of reliability and performance in the storage access. • Results from the experiment perspective of the latest years of production show the system’s reliability and high performance with moderate effort • GEMSS is the treasure! Vladimir.Sapunenko@cnaf.infn.it

  33. Contributors • Alessandro Cavalli, INFN-CNAF • LucaDell’agnello, INFN-CNAF • Daniele Gregori, INFN-CNAF • Andrea Prosperini, INFN-CNAF • Francesco Noferini, INFNEnrico Fermi Centre • Pier Paolo Ricci, INFN-CNAF • ElisabettaRonchieri, INFN-CNAF • VincenzoVagnoni, INFN Bologna Vladimir.Sapunenko@cnaf.infn.it

  34. Thank you for your attention! Questions? Вопросы? Vladimir.Sapunenko@cnaf.infn.it

More Related