Provided by: fssync_1.6-1.1_all bug

NAME

       fssync - File system synchronization tool (1-way, over SSH)

SYNOPSIS

       fssync -d db -r root [option...] host

DESCRIPTION

       fssync  is  a  1-way  file-synchronization  tool  that tracks inodes and maintains a local
       database of files that are on the remote side, making it able to:

       · handle efficiently a huge number of dirs/files

       · detect renames/moves and hard-links

       It aims at minimizing network traffic and synchronizing every detail of a file system:

       · all types of inode: file, dir, block/character/fifo, socket, symlink

       · preserve hard links

       · modification time, ownership/permission/ACL, extended attributes

       · sparse files

       Other features:

       · it can be configured to exclude files from synchronization

       · fssync can be interrupted and resumed at any time, making it tolerant to random failures
         (e.g. network error)

       · algorithm  to  synchronize  file  content is designed to handle big files like VM images
         efficiently, by updating fixed-size modified blocks in-place

       Main usage of fssync is to prevent data loss in case of hardware failure, where  RAID1  is
       not possible (e.g. in laptops).

       On  Btrfs  [1]  file  systems, fssync is an useful alternative to btrfs send (and receive)
       commands, thanks to filtering capabilities. This can be combined with  Btrfs  snapshotting
       at destination side for a full backup solution.

USAGE

       Use fssync --help to get the complete list of options.

       The  most important thing to remember is that the local database must match exactly what's
       on the destination host:

       · Files that are copied on the destination host must not be modified.  And nothing  should
         be manually created inside destination directories.  If you still want to access data on
         remote host, you should do it  through  a  read-only  bind  mounts  (requires  Linux  >=
         2.6.26).

       · You must have 1 database per destination, if you plan to have several copies of the same
         source directory.

       Look at -c option if you wonder whether your database matches the destination directory.

       First run of fssync:

       · The easiest way is to let fssync do everything. Specify a non-existing file path  to  -d
         option  and  a  empty or non-existing destination directory (see -R option). fssync will
         automatically creates the database and copy all dirs/files to remote host.

       · A faster way may be to do the initial copy  by  other  means,  like  a  raw  copy  of  a
         partition.  If  you're  absolutely sure the source and destination are exactly the same,
         you can initialize the database by specifying - as host. If inode numbers are  the  same
         on  both sides, which is the case if data were copied at block level, you can modify the
         source partition while you are initializing the DB on the destination one, and get  back
         the DB locally.

       An example of wrapper around fssync, with a filter, can be found at examples/fssync_home

       fssync  does never descend directories on other filesystems. Inodes masked by mount points
       are also skipped, so they  should  be  unmounted  temporarily  if  you  want  them  to  be
       synchronized. The same result can be achieved by synchronizing from a bind mount.

       See  also the NONE cipher switching [3] patch if you don't need encryption and you want to
       speed up your SSH connection.

HOW IT WORKS

       fssync maintains a single SQLite table of all dirs/files that are on the remote side. Each
       row  matches a path, with its inode (on local side), other metadata (on remote side) and a
       checked flag.

       When running, fssync iterates recursively through all local dirs/files and for  each  path
       that  is  not  ignored (see -f option), it queries the DB to decide what to do. If already
       checked, path is skipped immediately. When  a  path  is  synchronized,  it  is  marked  as
       checked.  At  the end, all rows that are not checked corresponds to paths that don't exist
       anymore. Once they are deleted on the remote side, all checked flags are reset.

   Failure tolerance
       In fact, fssync doesn't require that the database matches perfectly  the  destination.  It
       tolerates some differences in order to recover any interrupted synchronization caused by a
       network failure, a file operation error, or anything other than an operating system  crash
       of the local host (or something similar like a power failure).

       In  most cases, this is done by the remote host, which automatically create (or overwrite)
       an inode of the expected type if necessary. The only exception is  that  the  remote  will
       never delete a non-empty directory on its own.  For most complex cases, fssync journalizes
       the operation in the database: in case of failure, fssync will be able to recover on  next
       sync.

   Race conditions
       A  race  condition  means that other processes on the local host are modifying inodes that
       fssync is synchronizing. fssync handles any kind of race condition.  In fact,  fssync  has
       nothing to do for most cases.

       When  a  race  condition  happens,  fssync does not guarantee that the remote data is in a
       consistent state. Each sync always  fixes  existing  inconsistencies  but  may  introduces
       others, so fssync is not suitable for hot backuping of databases.

       With Btrfs, you can get consistency by snapshotting at source side.

SIMILAR PROJECTS

       The  idea  of maintaining a local database actually comes from csync2 [4].  I was about to
       adopt it when I realized that I really needed a tool that always detects renames/moves  of
       big files. That's why I see fssync as a partial rewrite of csync2, with inode tracking and
       without bidirectional synchronization.  The local database really makes  fssync  &  csync2
       faster than the well-known rsync [5].

SEE ALSO

       sqlite3(1), ssh(1)

BUGS/LIMITATIONS/TODO

       1. For  performance  reasons, the SQLite database is never flushed to disk while fssync is
          running. Which means that  if  the  operating  system  crashes,  the  DB  might  become
          corrupted,  and  even  if it isn't, it may not reflect anymore the status of the remote
          host and later runs may fail (for example, fssync refuses to replace a non-empty folder
          it doesn't know by a non-folder).  So in any case, it is advised to rebuild the DB.

          If  the  DB is not corrupted and you don't want to rebuild it, you can try to update it
          by running fssync again as soon as possible, so that the  same  changes  are  replayed.
          fssync  should  be able to detect that all remote operations are already performed. See
          also -c and -F options.

       2. fssync should not trash the page cache by using posix_fadvise(2).  Unfortunately, Linux
          does  not implement POSIX_FADV_NOREUSE yet (see https://lkml.org/lkml/2011/6/24/136 for
          more information).  We could do like  Bup  [2],  which  uses  information  returned  by
          mincore(2) in order to eject pages after save more selectively [6].

       3. fssync  process on remote side might leave parent directories with wrong permissions or
          modification times if it is terminated during specific operation like recovery (at  the
          very  beginning),  cleanup (at the end), rename (if a directory is moved). That is, all
          operations that need to temporarily alter  a  directory  that  is  not  being  checked.
          "Wontfix"  for  now,  because  it is unlikely to happen and any solution would be quite
          heavy, for little benefit.

       4. What is not synchronized:

          · access & change times: I won't implement it.

          · inode flags (see chattr(1) and lsattr(1)): some flags like C or c  are  important  on
            Btrfs so this could be a nice improvement, at least if it was implemented partially.

          · file-system specific properties ?

       5. Add  2 options to map specific users or groups. You may want this if you get permission
          errors and this is  certainly  a  better  solution  than  an  option  not  to  preserve
          ownership.  Currently,  on  destination  host,  you  must either run fssync as root, or
          configure security so that it is allowed to change ownership with same uid/gid than  on
          source (or with same user/group names if --map-users option is given).

       6. Don't  rely  on  permissions  settings to prevent access to inodes on destination side.
          This is because metadata are synchronized after data (in the case of  a  directory,  it
          means  all inodes under this directory is synchronized before its metadata) and in some
          cases, an attacker could access to sensitive  data  while  fssync  is  running.  Access
          should be denied on a parent directory of your destination tree (or at the root of this
          tree if you're careful enough to keep it secure on source side).

NOTES

       [1]  https://btrfs.wiki.kernel.org/

       [2]  https://github.com/bup/bup

       [3]  http://www.psc.edu/networking/projects/hpn-ssh/

       [4]  http://oss.linbit.com/csync2/

       [5]  http://rsync.samba.org/

       [6]  https://github.com/bup/bup/commit/b062252a5bca9b64d7b3034b6fd181424641f61e

AUTHOR

       Julien Muchembled <jm@jmuchemb.eu>

                                                                                        FSSYNC(1)