Grid, Storage and SRM 1
45 Slides3.46 MB
Grid, Storage and SRM 1
Introduction 2
Storage and Grid Grid applications need to reserve and schedule Compute resources Network resources Storage resources Furthermore, they need Monitor progress status Release resource usage when done For storage resources, they need To put/get files into/from storage spaces Unlike compute/network resources, storage resources are not available when jobs are done files in spaces need to be managed as well Shared, removed, or garbage collected 3
Motivation & Requirements (1) Suppose you want to run a job on your local machine Need to allocate space Need to bring all input files Need to ensure correctness of files transferred Need to monitor and recover from errors What if files don’t fit space? Need to manage file streaming Need to remove files to make space for more files 4
Motivation & Requirements (2) Now, suppose that the machine and storage space is a shared resource Need to do the above for many users Need to enforce quotas Need to ensure fairness of space allocation and scheduling 5
Motivation & Requirements (3) Now, suppose you want to run a job on a Grid Need to access a variety of storage systems mostly remote systems, need to have access permission Need to have special software to access mass storage systems 6
Motivation & Requirements (4) Now, suppose you want to run distributed jobs on the Grid Need to allocate remote spaces Need to move files to remote sites Need to manage file outputs and their movement to destination sites 7
Storage Resource Managers 8
What is SRM? Storage Resource Managers (SRMs) are middleware components whose function is to provide dynamic space allocation file management on shared storage resources on the Grid Different implementations for underlying storage systems are based on the same SRM specification 9
SRMs role in grid SRMs role in the data grid architecture Shared storage space allocation & reservation important for data intensive applications Get/put files from/into spaces archived files on mass storage systems File transfers from/to remote sites, file replication Negotiate transfer protocols File and space management with lifetime support non-blocking (asynchronous) requests Directory management Interoperate with other SRMs 10
Client and Peer-to-Peer Uniform Interface Client (command line) . Uniform SRM interface Client’s site client Client Program Disk Cache Storage Resource Manager Disk Cache network Storage Resource Manager Disk Cache . Site 1 Storage Resource Manager Disk Cache Disk Cache . Site 2 Storage Resource Manager . Disk Cache Disk Cache Site N MSS 11
History 7 year of Storage Resource Management (SRM) activity Experience with system implementations v.1.1 (basic SRM) – 2001 MSS: Castor (CERN), dCache (FNAL, DESY), HPSS (LBNL, ORNL, BNL), JasMINE (Jlab), MSS (NCAR) Disk systems: dCache (FNAL), DPM (CERN), DRM (LBNL) SRM v2.0 spec – 2003 SRM v2.2 – enhancements introduced after WLCG (the World-wide LHC Computing Grid) adopted SRM standard Several implementations of v2.2 Extensive compatibility and interoperability testing MSS: Castor (CERN, RAL), dCache/{Enstore,TSM,OSM,HPSS} (FNAL, DESY), HPSS (LBNL), JasMINE (Jlab), SRB (SINICA, SDSC) Disk systems: BeStMan (LBNL), dCache (FNAL, DESY), DPM (CERN), StoRM (INFN/CNAF, ICTP/EGRID) Open Grid Forum (OGF) Grid Storage Management (GSM-WG) at GGF8, June 2003 SRM collaboration F2F meeting – Sept. 2006 SRM v2.2 spec on OGF recommendation track – Dec. 2007 12
Who’s involved CERN, European Organization for Nuclear Research, Switzerland Deutsches Elektronen-Synchrotron, DESY, Hamburg, Germany Fermi National Accelerator Laboratory, Illinois, USA ICTP/EGRID, Italy INFN/CNAF, Italy Lawrence Berkeley National Laboratory, California, USA Rutherford Appleton Laboratory, Oxfordshire, England Thomas Jefferson National Accelerator Facility, Virginia, USA 13
SRM : Concepts 14
SRM: Main concepts Space reservations Dynamic space management Pinning file in spaces Support abstract concept of a file name: Site URL Temporary assignment of file names for transfer: Transfer URL Directory management and authorization Transfer protocol negotiation Support for peer to peer request Support for asynchronous multi-file requests Support abort, suspend, and resume operations Non-interference with local policies 15
Site URL and Transfer URL Provide: Site URL (SURL) URL known externally – e.g. in Replica Catalogs e.g. srm://ibm.cnaf.infn.it:8444/dteam/test.10193 Get back: Transfer URL (TURL) Path can be different from SURL – SRM internal mapping Protocol chosen by SRM based on request protocol preference e.g. gsiftp://ibm139.cnaf.infn.it:2811//gpfs/sto1/dteam/test.10193 One SURL can have many TURLs Files can be replicated in multiple storage components Files may be in near-line and/or on-line storage In a light-weight SRM (a single file system on disk) SURL may be the same as TURL except protocol File sharing is possible Same physical file, but many requests Needs to be managed by SRM implementation 16
Transfer protocol negotiation Negotiation Client provides an ordered list of preferred transfer protocols SRM returns first protocol from the list it supports Example Client provided protocols list: bbftp, gridftp, ftp SRM returns: gridftp Advantages Easy to introduce new protocols User controls which transfer protocol to use How it is returned? The protocol of the Transfer URL (TURL) Example: bbftp://dm.slac.edu//temp/run11/File678.txt 17
Types of storage and spaces Access latency On-line Storage where files are moved to before their use Near-line Requires latency before files can be accessed Retention quality Custodial (High quality) Output (Middle quality) Replica (Low Quality) Spaces can be reserved in these storage components Spaces can be reserved for a lifetime Space reference handle is returned to client – space token Total space of each type are subject to local SRM policy and/or VO policies Assignment of files to spaces Files can be assigned to any space, provided that their lifetime is shorter than the remaining lifetime of the space 18
Managing spaces Default spaces Files can be put into an SRM without explicit reservation Default spaces are not visible to client Files already in the SRM can be moved to other spaces By srmChangeSpaceForFiles Files already in the SRM can be pinned in spaces By requesting specific files (srmPrepareToGet) By pre-loading them into online space (srmBringOnline) Updating space Resize for more space or release unused space Extend or shorten the lifetime of a space Releasing files from space by a user Release all files that user brought into the space whose lifetime has not expired Move permanent and durable files to near-line storage if supported Release space that was used by user 19
Space reservation Negotiation Client asks for space: Guaranteed C, MaxDesired SRM return: Guaranteed S Guaranteed C, best effort MaxDesired Types of spaces Specified during srmReserveSpace Access Latency (Online, Nearline) Retention Policy (Replica, Output, Custodial) Subject to limits per client (SRM or VO policies) Default: implementation and configuration specific Lifetime Negotiated: Lifetime C requested SRM return: Lifetime S Lifetime C Reference handle SRM returns space reference handle (space token) Client can assign Description User can use srmGetSpaceTokens to recover handles on basis of ownership 20
Directory management Usual unix semantics srmLs, srmMkdir, srmMv, srmRm, srmRmdir A single directory for all spaces No directories for each file type File assignment to spaces is virtual Access control services Support owner/group/world permission ACLs supported – can have one owner, but multiple user and group access permissions Can only be assigned by owner When file is requested from a remote site, SRM should check permission with source site 21
Advanced concepts Composite Storage Element Made of multiple Storage Components e.g. component 1: online-replica component 2: nearline-custodial (with online disk cache) e.g. component1: online-custodial component 2: nearline-custodial (with online disk cache) srmBringOnline can be used to temporarily bring data to the online component for fast access When a file is put into a composite space, SRM may have (temporary) copies on any of the components. Primary Replica When a file is first put into an SRM, that copy is considered as the primary replica A primary replica can be assigned a lifetime The SURL lifetime is the lifetime of the primary replica When other replicas are made, their lifetime cannot exceed the primary replica lifetime Lifetime of a primary replica can only be extended by an SURL owner. 22
SRM v2.2 Interface Data transfer functions to get files into SRM spaces from the client's local system or from other remote storage systems, and to retrieve them srmPrepareToGet, srmPrepareToPut, srmBringOnline, srmCopy Space management functions to reserve, release, and manage spaces, their types and lifetimes. srmReserveSpace, srmReleaseSpace, srmUpdateSpace, srmGetSpaceTokens Lifetime management functions to manage lifetimes of space and files. srmReleaseFiles, srmPutDone, srmExtendFileLifeTime Directory management functions to create/remove directories, rename files, remove files and retrieve file information. srmMkdir, srmRmdir, srmMv, srmRm, srmLs Request management functions to query status of requests and manage requests srmStatusOf{Get,Put,Copy,BringOnline}Request, srmGetRequestSummary, srmGetRequestTokens, srmAbortRequest, srmAbortFiles, srmSuspendRequest, srmResumeRequest Other functions include Discovery and Permission functions srmPing, srmGetTransferProtocols, srmCheckPermission, srmSetPermission, etc. 23
SRM implementations 24
Berkeley Storage Manager (BeStMan) LBNL Java implementation Designed to work with unixbased disk systems As well as MSS to stage/archive from/to its own disk (currently HPSS) Adaptable to other file systems and storages (e.g. NCAR MSS, VU L-Store, TTU Lustre, NERSC GFS) Uses in-memory database (BerkeleyDB) Request Queue Management Security Module Request Processing Network Access Management (GridFTP. FTP, BBFTP, SCP. ) Local Policy Module Multiple transfer protocols Space reservation DISK Management (PFTP, HSI, SCP.) Local Policy Fair request processing File replacement in disk Garbage collection Directory management (no ACLs) Can copy files from/to remote SRMs or GridFTP Servers Can copy entire directory recursively MSS Access Management Large scale data movement of thousands of files Recovers from transient failures (e.g. MSS maintenance, network down) 25
Castor-SRM CERN and Rutherford Appleton Laboratory Request Handler CASTOR Async. Process or Database Clients CASTOR is the HSM in production at CERN Support for multiple tape robots Support for Disk-only storage recently added Designed to meet Large Hadron Collider Computing requirements Maximize throughput from clients to tape (e.g. LHC experiments data taking) C Implementation Reuse of CASTOR software infrastructure Derived SRM specific classes Configurable number of thread pools for both front- and backends ORACLE centric Front and back ends can be distributed on multiple hosts 26
dCache-SRM FNAL and DESY Strict name space and data storage separation Automatic file replication based on access patterns HSM Connectivity (Enstore, OSM, TSM, HPSS, DMF) Automated HSM migration and restore Scales to Peta-byte range on 1000’s of disks Supported protocols: (gsi/krb)FTP, (gsi/krb)dCap, xRoot, NFS 2/3 Separate I/O queues per protocol Resilient dataset management Command line and graphical admin interface Variety of Authorization mechanisms including VOMS Deployed in a large number of institutions worldwide Support SRM 1.1 and SRM 2.2 Dynamic Space Management Request queuing and scheduling Load balancing Robust replication using srmCopy functionality via SRM, (gsi)FTP and http protocols 27
Disk Pool Manager (DPM) CERN Provide a reliable, secure and robust storage system Manages storage on disks only Security GSI for authentication VOMS for authorization Standard POSIX permissions ACLs based on user’s DN and VOMS roles Virtual ids Accounts created on the fly Full SRMv2.2 implementation Standard disk pool manager capabilities Garbage collector Replication of hot files Transfer protocols GridFTP (v1 and v2) Secure RFIO https Xroot Works on Linux 32/64 bits machines Direct data transfer from/to disk server (no bottleneck) Support DICOM backend Requirement from Biomed VO Storage of encrypted files in DPM on the fly local decryption Use of GFAL/srm to get TURLs and decrypt the file Supported database backends MySQL Oracle High availability All servers can be load balanced (except the DPM one) Resilient: all states are kept in the DB at all times 28
Storage Resource Manager (StoRM) INFN/CNAF - ICTP/EGRID It's designed to leverage the advantages of high performing parallel file systems in Grid. Different file systems supported through a driver mechanism: mechanism generic POSIX FS GPFS Lustre XFS It provides the capability to perform local and secure access to storage resources ( file:// access protocol ACLs on data). data StoRM architecture: Frontends: Frontends C/C based, expose the SRM interface Backends: Backends Java based, execute SRM requests. DB: DB based on MySQL DBMS, stores requests data and StoRM metadata. Each component can be replicated and instantiated on a dedicated machine. 29
SRM on SRB SINICA – TWGRID/EGEE SRM as a permanent archival storage system Finished the parts about authorizing users, web service interface and gridftp deployment, and SRBDSI, and some functions like directory functions, permission functions, etc. Currently focusing on the implementation of core (data transfer functions and space management) Use LFC (with a simulated LFC host) to get SURL and use this SURL to connect to SRM server, then get TURL back User Interface User File transfer (gridftp) File transfer (gridftp) SRM API Web Service Core Data server management Gridftp/management API Hostname: t-ap20.grid.sinica.edu.tw File catalog Gridftp/management API Cache repository SRB DSI SRB/gridftp Cache server ( gridftp server) Info: SRB server (SRB-DSI installed) Gridftp management commands Return some information SURL TURL Hostname: fct01.grid.sinica.edu.tw The end point: httpg://fct01.grid.sinica.edu.tw:8443/axis/services/srm Info: Cache server (gridftp server) and SRM interface 30
Interoperability in SRM v2.2 dCache CASTOR Ber kel ey BeStMan Disk DPM SRM Client User/application xroot d BNL SLAC LBNL SRB (iRODS) SDSC SINICA LBNL EGEE 31
SRMs at work Europe : LCG/EGEE 191 deployments, managing more than 10PB 129 DPM/SRM 54 dCache/SRM 7 CASTOR/SRM at CERN, CNAF, PIC, RAL, SINICA StoRM at ICTP/EGRID, INFN/CNAF SRM layer for SRB, SINICA US Estimated at about 30 deployments OSG BeStMan/SRM from LBNL dCache/SRM from FNAL ESG DRM/SRM, HRM/SRM at LANL, LBNL, LLNL, NCAR, ORNL Others BeStMan/SRM adaptation on Lustre file system at Texas Tech BeStMan-Xrootd adaptation at SLAC JasMINE/SRM from TJNAF L-Store/SRM from Vanderbilt Univ. 32
Examples of SRM usage in real production Grid projects 33
HENP STAR experiment Data Replication from BNL to LBNL 1TB/10K files per week on average In production for over 4 years Event processing in Grid Collector Prototype uses SRMs and FastBit indexing embedded in STAR framework STAR analysis framework Job driven data movement 1. 2. 3. 4. 5. 6. Use BeStMan/SRM to bring files into local disk from a remote file repository Execute jobs that access “staged in” files in local disk Job creates an output file on local disk Job uses BeStMan/SRM to moves the output file from local storage to remote archival location SRM cleans up local disk when transfer complete Can use any other SRMs implementing v2.2 34
Data Replication in STAR Anywhere Allocate space on disk Recovers from archiving failures Recovers from file transfer failures Make equivalent Directory SRM-COPY client command Recovers from staging failures srmCopy (files/directories) BNL BROWSE LBNL SRM/BeStMan GET (one file at a time) (performs writes) GridFTP GET (pull mode) SRM/BeStMan (performs reads) RELEASE Disk Cache archive files Network transfer Disk Cache stage files 35
File Tracking Shows Recovery From Transient Failures Total: 45 GBs 36
STAR Analysis scenario (1) Job submission Client Remote sites A site dCache/SRM Worker Nodes Client Job Disk Client Job Disk Client Job Disk Gate Node BeStMan/SRM GridFTP server DPM/SRM Disk Disk Disk Cache DISK CACHE Client Job BeStMan/SRM Disk Disk Cache 37
STAR Analysis scenario (2) SRM Job Client Job submission submission Client Remote sites A site dCache/SRM Worker Nodes Client Job Disk Client Job Disk Client Job Disk Gate Node BeStMan/SRM GridFTP server DPM/SRM Disk Disk Disk Cache DISK CACHE Client Job BeStMan/SRM Disk Disk Cache 38
Earth System Grid Main ESG portal 148.53 TB of data at four locations (NCAR, LBNL, ORNL, LANL) 965,551 files Includes the past 7 years of joint DOE/NSF climate modeling experiments 4713 registered users from 28 countries Downloads to date: 31TB/99,938 files IPCC AR4 ESG portal 28 TB of data at one location 68,400 files Model data from 11 countries Courtesy: http://www.earthsystemgrid.org Generated by a modeling campaign coordinated by the Intergovernmental Panel on Climate Change (IPCC) 818 registered analysis projects from 58 countries Downloads to date: 123TB/543,500 files, 300 GB/day on average 6 00 G B /d a y D aily 7-D ay Average 5 00 4 00 3 00 2 00 1 00 0 39
SRMs in ESG Client Files Selection And Request SRM @ LBNL download SRM @ NCAR Portal Disk Cache SRM @ LANL DiskDisk Cache Cache SRM @ LLNL Disk Cache DISK CACHE DiskDisk Cache Cache NCAR MSS SRM @ ORNL Disk Cache 40
SRM works in concert with other Grid components in ESG LBNL DISK ANL HPSS GridFTP service GridFTP service BeStMan/SRM BeStMan/SRM Storage Resource Storage Resource Management Management RLS RLS GridFTP GridFTP server server XML data catalogs BeStMan/SRM BeStMan/SRM Storage Resource Storage Resource Management Management NCAR ESG Portal ESG Portal LLNL DISK Globus Security infrastructure Globus Security infrastructure IPCC Portal IPCC Portal User DB XML data catalogs FTP server FTP server ISI OPeNDAP-g OPeNDAP-g GridFTP GridFTP server server ESG CA ESG CA RLS RLS LAHFS LAHFS BeStMan/SRM BeStMan/SRM Storage Resource Storage Resource Management Management MCS Metadata Cataloguing Services MCS Metadata Cataloguing Services RLS Replica Location Services RLS Replica Location Services Monitoring Discovery ervices Monitoring Discovery ervices BeStMan/SRM BeStMan/SRM Storage Resource Storage Resource Management Management GridFTP GridFTP server server MyProxy MyProxy ESG Metadata DB RLS RLS GridFTP server GridFTP server ORNL RLS RLS MSS Mass Torage System HPSS DISK DISK LANL RLS RLS DISK BeStMan/SRM BeStMan/SRM Storage Resource Storage Resource Management Management GridFTP GridFTP server server 41
Summary 42
Summary and Current Status Storage Resource Management – essential for Grid Multiple implementations interoperate Permits special purpose implementations for unique storage Permits interchanging one SRM implementation by another Multiple SRM implementations exist and are in production use Particle Physics Data Grids WLCG, EGEE, OSG, Earth System Grid More coming Combustion, Fusion applications Medicine 43
Documents and Support SRM Collaboration and SRM Specifications http://sdm.lbl.gov/srm-wg OGF mailing list : [email protected] SRM developer’s mailing list: [email protected] BeStMan (Berkeley Storage Manager): http://datagrid.lbl.gov/bestman CASTOR (CERN Advanced STORage manager): http://www.cern.ch/castor dCache: http://www.dcache.org DPM (Disk Pool Manager): https://twiki.cern.ch/twiki/bin/view/LCG/DpmInformation StoRM (Storage Resource Manager): http://storm.forge.cnaf.infn.it SRM-SRB: http://lists.grid.sinica.edu.tw/apwiki/SRM-SRB SRB: http://www.sdsc.edu/srb BeStMan-XrootD: http://wt2.slac.stanford.edu/xrootdfs/bestman-xrootd.html Other support info : [email protected] 44
Credits Alex Sim [email protected] Arie Shoshani [email protected] 45
