% BDSYNC(1) % Rolf Fokkens % July 2017
bdsync – a fast block device synchronizing tool
Client: bdsync [--verbose] [--digest=DIGEST] REMSHCMD LOCDEV REMDEV
Server: bdsync --server [--verbose]
Patch: bdsync --patch[=DSTDEV] [--verbose]
Bdsync can be used to synchronize block devices over a network. It generates a "binary patchfile" in an efficient way by comparing checksums of blocks of the local block device LOCDEV and the remote block device REMDEV.
This binary patchfile can be sent to the remote machine and applied to its block device REMDEV, after which the local blockdev LOCDEV and the remote block device REMDEV are synchronized.
Both LOCDEV, REMDEV and DSTDEV can be true block devices, but may be (image) files as well. When using an image file for DSTDEV (the --patch mode), the --diffsize may be used to resize the image file when appropriate.
bdsync was built to do the only thing rsync isn't able to do: synchronize block devices.
-s, --server : Start bdsync as a server. No further arguments are accepted, all controll is done by standard input and standard output
-p, --patch[=DEVICE] : Make bdsync "patch" a device by applying a bdsync file read from standard input. The device will be determined from the bdsync data unless an (optional) device name DEVICE is specified
-w, --warndev : Makes bdsync (in patch mode) warn if the specified device with the --patch option differs from the device in the patch data
-v, --verbose : Increase the verbosity of bdsync. Can be repeated multiple times.
-h, --hash=DIGEST : Choose any of openssl's digests as a hash for matching blocks on LOCDEV en REMDEV. Default is md5.
-b, --blocksize=BLOCKSIZE : Set the blocksize in bytes for which hashes are calculated on both LOCDEV and REMDEV. Default 4096.
-c, --checksum=DIGEST : Choose any of openssl's digests as a checksum for all LOCDEV data. The checksum will be written to the binary patchfile. Default is none.
-t, --twopass : Makes bdsync first match checksums using large blocks (64 * BLOCKSIZE) and then match checksums using small blocks (BLOCKSIZE). This may reduce systemcall overhead and networktraffic when the "binary patchfile" has limited size.
-r, --remdata : Makes bdsync (in client mode) write the remote data to standard output instead of the local blocks that differs.
-d, --diffsize[=OPTION[,warn]] : Specifies how bdsync (in client mode and patch mode) should handle different sizes of devices. Possible values for OPTION are strict, resize and minsize. When strict is specified, different sizes for LOCDEV and REMDEV are not allowed. When resize is specified, different sizes are accepted and the LOCDEV size is applied to REMDEV in patch mode which is only supported for (image) files (not devices). When minsize is specified, the smallest size of both LOCDEV and REMDEV is considered (excess data is ignored).
When the --diffsize command line option is not specified at all, it defaults to --diffsize=strict. When the --diffsize is specified without any of the additional options, it defaults to --diffsize=resize which is consistent with earlier versions of bdsync.
When the additional warn option is specified, a warning is issued when sizes differ.
-z, --zeroblocks : Makes bdsync (in client mode and server mode) identify zero-filled blocks and optimize hashes for these blocks. This may be usefull for sparse files with lots of zero filled blocks.
-F, --flushcache : This client option makes both bdsync client and server actively inform the OS the data is no longer needed after reading it hence reducing OS buffer cache polution by bdsync. This works especially well when deltas are small, because in that case bdsync itself won't be reading blocks twice.
-P, --progress : This client option makes the client periodically report progress to stderr during operation. The format is:
Where: <pct> is progress in %, <diffsize> is the current size of the generated diff, <pos> is the current position reading LOCDEV, <size> is the total size of LOCDEV, <elapsed s> is the elapsed time in seconds and <remaining s> is an estimate of the remaining time left in seconds.
-H, --help : Display brief help information.
Bdsync assumes a client is connecting to a server. The connection isn't established by the client itself, but by a remote-shell-command REMSHCMD. This REMSHCMD can be any kind of command to make a connection: rsh, ssh, netcat.. If using rsh or ssh REMSHCMD should be the full command to make the connection including the remote bdsync command te be executed in server mode. If using netcat to make the connection, the remote server mode bdsync command should be executed by inetd, xinetd etc.
The --verbose option results in verbose output. In Server mode the output will be sent to syslog. The --verbose option can be repeated raising the verbosity level.
Bdsync can be initiated like this in its most simple form:
bdsync "bdsync -s"
This generates a patchfile DEV.rsync containing the blocks in the /dev/LOCDEV device that differ from the blocks in the /dev/REMDEV device which both are local. A more realistic example is this:
bdsync "ssh doe@remote bdsync --server" /dev/LOCDEV /dev/REMDEV | gzip > DEV.bdsync.gz
When run as john at local the bdsync client makes an ssh connection to remote as user doe and executes a bdsync server by passing it the --server option. The generated patchfile output is passed on to gzip which creates a compressed patchfile DEV.bdsync.gz on local. The patchfile contains all blocks in /dev/LOCDEV at local that differ from /dev/REMDEV at remote.
On the remote machine remote the user doe can apply the patch by executing:
gzip -d < DEV.bdsync.gz | bdsync --patch=/dev/REMDEV
The reason to use a binary patch file instead of instantly patching the remote block device REMDEV is twofold:
Sending over a complete patchfile allows to synchronize in a consistent way in case of an interruption (powerloss, network malfunction) since you can choose to apply the (complete) patchfile or not.
Compression of the patchfile can easily be done, without introducing complexity in bdsync itself.
0 completed successfully
1 invalid or conflicting parameters supplied
2 invalid patch format
3 size mismatch of source and destination blockdevice
4 protocol error
5 checksum error
6 read error
7 failed to collect randomness
8 process management error
9 write error
10 digest error
11 transmission error
12 IO error
13 connection error