Dcache: Difference between revisions

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* dCache does not allow overwriting files, or modifying existing files (such as by an editor), only moving full files.
* dCache does not allow overwriting files, or modifying existing files (such as by an editor), only moving full files.


The scratch area is purged regularly using a least-recently-used algorithm based on the file creation date.  The time between creation and deletion is not guaranteed and may be as little as a week.
The scratch area is purged regularly using a least-recently-used algorithm based on the time the file was last transferred to a user ("touch" doesn't update the time).  The time between the last use and deletion is not guaranteed and while it is often on the scale of a month or more, it may be as little as a week.


==Other Access Protocols==
==Other Access Protocols==

Revision as of 21:56, 28 January 2019

Introduction

dCache is a system of many disks aggregated across dozens of linux disk servers. The system lets all this hardware look like "one big disk" to the user and hides all the details of exactly where the files are and how they are being transferred. It allows load balancing and optimization, such as serving a popular file from several different machines. The entire system is designed to be high-bandwidth so it can serve data files to thousands of grid nodes simultaneously. For example, all the disk servers have special network paths to the grid nodes. Anytime you transfer data files to/from a grid node, it should be to/from dCache using the dedicated tools. Executables, libraries, and UPS products are transferred by CVMFS or by tarball.

So far, when we refer to data distributed by dCache, we have been referring to event data, where every grid node gets a unique file. There is another case, intermediate between code on CVFMS and event data on dCache - the case of a single large file that needs to be distributed to every node but is too large for CVMFS. An example might be a library of fit templates that is 5 GB. In this case, the ideal solution is stashCache.

When you read or write to this dCache, the request goes through a server "head node", and the system decides which hardware to read or write. There is a database behind the system to track where all the files are logically and physically. Accessing this database adds latency to all commands accessing dCache, so using dCache interactively for code building or analysis, for example, is not efficient and not recommended, please see disk page for build and analysis areas.

You can access the files through several protocols, including a nfs server, which makes dCache look like a simple file system mounted as the /pnfs file system. If you are moving data in and out of dCache using a few interactive processes, you can use simple unix commands: cp, mv, rm. Once you need to move data using may parallel processes, such as to or from grid nodes, please use the tools here.

dCache has a home and a lab home and monitors.

Flavors

There are three flavors of dCache.

  • scratch Anyone can write here, and you should use this area as temporary output for your grid jobs. If space is needed, files are deleted according to a least-recently-used algorithm. Your files may last for as little as one week since the last time you wrote or read them, and technically there is no guaranteed minimum lifetime, so plan ahead.
  • persistent Files written here will stay on disk until the user deletes them, so this area can fill up. Only production files are written here - it is not for general use, though special cases might be considered. The one current exception is that users can write fcl files here instead of uploading them.
  • resilient This is a special purpose area. Files written here are copied to many, about 20, different dCache server nodes. This procedure will allow the files to be accessed efficiently by many gird node trying to read them simultaneously. We expect this area will only be used for gridexport code tarballs, and perhaps other limited cases. Files written here will stay on disk until the user deletes them, so this area can fill up. Users should purge their own areas and the collaboration reserves the right to purge user's files as needed.
  • tape-backed All files written to this area are copied to tape automatically. If space is needed, files are deleted off disk according to a least-recently-used algorithm. As files are requested, they are copied from tape to disk as needed, and a request will hang during tape access. This is the way collaborations "write to tape". Do not copy data to this area - it is carefully organized and only the production scripts can write here. Large datasets should be prestaged from tape to disk before they are read from grid job.

Official production datasets, and user datasets manipulated by the file tools will appear under the following designated dataset areas, corresponding to the above flavors:

  • /pnfs/mu2e/scratch/datasets
  • /pnfs/mu2e/persistent/datasets
  • /pnfs/mu2e/tape

Using the scratch area

On the interactive nodes, you can create your area in scratch dCache:

mkdir /pnfs/mu2e/scratch/users/$USER

If you are moving a few files using a few processes, you can use the unix commands in /pnfs: ls, rm, mv, mkdir, rmdir, chmod, cp, cat, more, less, etc.

/pnfs is not a physical directory, it is an interface to a database and servers, implemented as an nfs server. Because there is latency to database and server access, there are restrictions to this interface that don't usually apply to local disk systems.

  • You should avoid commands which make large demands on the database: "find .", "ls -lr *" and similar. When you use "ls" there is a quick database access of the directory record, but if you use "find" or "ls -l" there is a much slower database access of the full file records, so a plain "ls" is always preferred.
  • Try to keep the number of files in a directory under 1000 to maintain good response time. Avoid excessive numbers of small files, or frequent renaming of files.
  • If you are writing or reading dCache with a large number of processes, such as from a grid job, please use the data transfer tools
  • dCache does not allow overwriting files, or modifying existing files (such as by an editor), only moving full files.

The scratch area is purged regularly using a least-recently-used algorithm based on the time the file was last transferred to a user ("touch" doesn't update the time). The time between the last use and deletion is not guaranteed and while it is often on the scale of a month or more, it may be as little as a week.

Other Access Protocols

While we will typically use nfs protocol for small numbers of accesses, and data transfer tools to read or write files from grid nodes, there are other protocols to access dCache files.

  • dcap the native protocol
    dccp /pnfs/mu2e/scratch/users/$USER/filename .
    

    dccp is installed on mu2egpvm, but it may have to be installed or setup (the product is named dcap) on other nodes

  • root protocol
    root [0] ff = TFile::Open("/pnfs/mu2e/scratch/users/$USER/file")
    

    There are other versions of this access, through different plugins which trigger different authentication, protocols and transfer queues.

  • xrootd protocol

  • webdav There is CS-doc-5050 reference
    curl -1 -L  --cacert $X509_USER_PROXY  --capath /etc/grid-security/certificates  --cert /tmp/x509up_u1311  https://fndca1.fnal.gov:2880/pnfs/fnal.gov/usr/mu2e/scratch/users/rlc/s1
    (not currently working)
    

    Two webdav scripts from Dmitri Litvinsev. Require voms proxy to run

    #!/bin/sh
    # get properties of a file
    if [ ${1:-x} = "x" ]; then
        echo "please provide full file name" 1>&2;
        echo "usage: $0 <file_path>"
        exit 1
    fi
    
    X509_USER_PROXY=/tmp/x509up_u`id -u`
    WEBDAV_HOST=https://fndca4a.fnal.gov:2880
    FILE_PATH=${1}
    
    echo $FILE_PATH
    
    curl  -L --capath /etc/grid-security/certificates \
             --cert ${X509_USER_PROXY} \
             --cacert ${X509_USER_PROXY} \
             --key ${X509_USER_PROXY} \
    	 -s -X PROPFIND -H Depth:1 \
             ${WEBDAV_HOST}${FILE_PATH} \
      --data '<?xml version="1.0" encoding="utf-8"?>
              <D:propfind xmlns:D="DAV:">
                  <D:prop xmlns:R="http://www.dcache.org/2013/webdav"
                          xmlns:S="http://srm.lbl.gov/StorageResourceManager">
                      <R:Checksums/>
                      <S:AccessLatency/>
                      <S:RetentionPolicy/><S:FileLocality/>
                  </D:prop>
              </D:propfind>' | xmllint -format -
    
    


    #!/bin/sh
    # get properties of a files in a dir
    
    if [ ${1:-x} = "x" ]; then
        echo "please provide full file name" 1>&2;
        echo "usage: $0 <file_path>"
        exit 1
    fi
    
    X509_USER_PROXY=/tmp/x509up_u`id -u`
    WEBDAV_HOST=https://fndca4a.fnal.gov:2880
    FILE_PATH=${1}
    
    curl  -L --capath /etc/grid-security/certificates \
             --cert ${X509_USER_PROXY} \
             --cacert ${X509_USER_PROXY} \
             --key ${X509_USER_PROXY} \
    	 -s -X PROPFIND -H Depth:1 \
             ${WEBDAV_HOST}${FILE_PATH} \
      --data '<?xml version="1.0" encoding="utf-8"?>
              <D:propfind xmlns:D="DAV:">
                  <D:prop xmlns:R="http://www.dcache.org/2013/webdav"
                          xmlns:S="http://srm.lbl.gov/StorageResourceManager">
                      <R:Checksums/>
                      <S:FileLocality/>
                  </D:prop>
              </D:propfind>' | xmllint -format -
    
    


  • gridFtp
    kinit
    getcert
    export X509_USER_CERT=/tmp/x509up_u`id -u`
    export X509_USER_KEY=$X509_USER_CERT
    export X509_USER_PROXY=$X509_USER_CERT
    grid-proxy-init
    voms-proxy-init -noregen -rfc -voms fermilab:/fermilab/mu2e/Role=Analysis
    globus-url-copy  gsiftp://fndca1.fnal.gov:2811/scratch/users/$USER/file-name file:///$PWD/file-name