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bup-split(1) |
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bup-split(1) |
bup-split - save individual files to bup backup sets
bup split [-t] [-c] [-n name] COMMON_OPTIONS
bup split -b COMMON_OPTIONS
bup split –copy COMMON_OPTIONS
bup split –noop [-t|-b] COMMON_OPTIONS
- COMMON_OPTIONS
- [-r host:path] [-v] [-q] [-d seconds-since-epoch]
[--bench] [--max-pack-size=bytes] [-#] [--bwlimit=bytes]
[--max-pack-objects=n] [--fanout=count] [--keep-boundaries]
[--git-ids | filenames...]
bup split concatenates the contents of the given files (or if no filenames are
given, reads from stdin), splits the content into chunks of around 8k using a
rolling checksum algorithm, and saves the chunks into a bup repository. Chunks
which have previously been stored are not stored again (ie. they are
`deduplicated').
Because of the way the rolling checksum works, chunks tend to be
very stable across changes to a given file, including adding, deleting, and
changing bytes.
For example, if you use bup split to back up an XML dump of a
database, and the XML file changes slightly from one run to the next, nearly
all the data will still be deduplicated and the size of each backup after
the first will typically be quite small.
Another technique is to pipe the output of the tar(1) or cpio(1)
programs to bup split. When individual files in the tarball change slightly
or are added or removed, bup still processes the remainder of the tarball
efficiently. (Note that bup save is usually a more efficient way to
accomplish this, however.)
To get the data back, use bup-join(1).
These options select the primary behavior of the command, with -n being the most
likely choice.
- -n, --name=name
- after creating the dataset, create a git branch named name so that
it can be accessed using that name. If name already exists, the new
dataset will be considered a descendant of the old name. (Thus, you
can continually create new datasets with the same name, and later view the
history of that dataset to see how it has changed over time.) The original
data will also be available as a top-level file named “data”
in the VFS, accessible via bup fuse, bup ftp, etc.
- -t, --tree
- output the git tree id of the resulting dataset.
- -c, --commit
- output the git commit id of the resulting dataset.
- -b, --blobs
- output a series of git blob ids that correspond to the chunks in the
dataset. Incompatible with -n, -t, and -c.
- --noop
- read the data and split it into blocks based on the
“bupsplit” rolling checksum algorithm, but don’t
store anything in the repo. Can be combined with -b or -t to compute (but
not store) the git blobs or tree ids for the dataset. This is mostly
useful for benchmarking and validating the bupsplit algorithm.
Incompatible with -n and -c.
- --copy
- like --noop, but also write the data to stdout. This can be useful for
benchmarking the speed of read+bupsplit+write for large amounts of data.
Incompatible with -n, -t, -c, and -b.
- -r, --remote=host:path
- save the backup set to the given remote server. If path is omitted,
uses the default path on the remote server (you still need to include the
`:'). The connection to the remote server is made with SSH. If
you’d like to specify which port, user or private key to use for
the SSH connection, we recommend you use the ~/.ssh/config file. Even
though the destination is remote, a local bup repository is still
required.
- -d, --date=seconds-since-epoch
- specify the date inscribed in the commit (seconds since 1970-01-01).
- -q, --quiet
- disable progress messages.
- -v, --verbose
- increase verbosity (can be used more than once).
- --git-ids
- stdin is a list of git object ids instead of raw data. bup split will read
the contents of each named git object (if it exists in the bup repository)
and split it. This might be useful for converting a git repository with
large binary files to use bup-style hashsplitting instead. This option is
probably most useful when combined with --keep-boundaries.
- --keep-boundaries
- if multiple filenames are given on the command line, they are normally
concatenated together as if the content all came from a single file. That
is, the set of blobs/trees produced is identical to what it would have
been if there had been a single input file. However, if you use
--keep-boundaries, each file is split separately. You still only get a
single tree or commit or series of blobs, but each blob comes from only
one of the files; the end of one of the input files always ends a
blob.
- --bench
- print benchmark timings to stderr.
- --max-pack-size=bytes
- never create git packfiles larger than the given number of bytes. Default
is 1 billion bytes. Usually there is no reason to change this.
- --max-pack-objects=numobjs
- never create git packfiles with more than the given number of objects.
Default is 200 thousand objects. Usually there is no reason to change
this.
- --fanout=numobjs
- when splitting very large files, try and keep the number of elements in
trees to an average of numobjs.
- --bwlimit=bytes/sec
- don’t transmit more than bytes/sec bytes per second to the
server. This is good for making your backups not suck up all your network
bandwidth. Use a suffix like k, M, or G to specify multiples of 1024,
1024*1024, 1024*1024*1024 respectively.
- -#, --compress=#
- set the compression level to # (a value from 0-9, where 9 is the highest
and 0 is no compression). The default is 1 (fast, loose compression)
-
$ tar -cf - /etc | bup split -r myserver: -n mybackup-tar
tar: Removing leading /' from member names
Indexing objects: 100% (196/196), done.
$ bup join -r myserver: mybackup-tar | tar -tf - | wc -l
1961
bup-join(1), bup-index(1), bup-save(1), bup-on(1), ssh_config(5)
Part of the bup(1) suite.
Avery Pennarun <apenwarr@gmail.com>.
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