š¾ Archived View for xosc.org āŗ timemachine.gmi captured on 2023-01-29 at 15:52:56. Gemini links have been rewritten to link to archived content
ā¬ ļø Previous capture (2022-06-03)
-=-=-=-=-=-=-
$Id: timemachine.gmi,v 1.2 2022/05/28 14:57:21 cvs Exp $
Time Machine[a] is a backup software by Apple, part of macOS allowing easy and foolproof backups. In a nutshell, it creates incremental backups on a storage medium of your choice and you can access the data either with a graphical client or directly via file system tools. I especially like that you only have to plug in an external USB drive which is immediately recognized, the backup starts and the drive is unmounted as soon as the backup is done. Since Time Machine is Apple only and I use OpenBSD on all my personal machines, I decided to write my own Time Machine like solution.
Turns out, I can solve the goals easily with mostly base software and one program from ports.
At first, we need to manually format the disk and create an encrypted file system on top. Plug in the disk and find the correct device name by looking at the dmesg output:
umass0: using SCSI over Bulk-Only scsibus4 at umass0: 2 targets, initiator 0 sd2 at scsibus4 targ 1 lun 0: <Kingston, DataTraveler 2.0, PMAP> removable serial.09511607BA7195A60256 sd2: 7640MB, 512 bytes/sector, 15646720 sectors
In this example itās sd2. Now we need to format the disk and create an encrypted file system on top of it.
Writing MBR at offset 0. # disklabel -E sd2 Label editor (enter '?' for help at any prompt) sd2> a a offset: [64] size: [15631181] FS type: [4.2BSD] RAID sd2*> w sd2> q
Upon completion you should see a correct disklabel on the disk.
# /dev/rsd2c: type: SCSI disk: SCSI disk label: DataTraveler 2.0 duid: f5a87db156d32c6f flags: bytes/sector: 512 sectors/track: 63 tracks/cylinder: 255 sectors/cylinder: 16065 cylinders: 973 total sectors: 15646720 boundstart: 64 boundend: 15631245 drivedata: 0 16 partitions: # size offset fstype [fsize bsize cpg] a: 15631181 64 RAID c: 15646720 0 unused
Since the disk is later controlled by a script we cannot use a passphrase here, we need to store the decryption password in a file. Use the tool of your choice to generate a strong password and store it in a file. To match the passphrase and the disk, name the file after the disks duid (can been seen in disklabelās output above). As last step, set the fileās permission to 600 so that only the owner can access it. Otherwise, bioctl complains about wrong permissions.
Make sure that you save the file in a secure location on your machine. In my case itās stored in /root and owned by the root user. Further, write the generated password somewhere down in case you need to access your backup disk without (!) having access to your machine! You could print it on a piece of paper and store it somewhere safe.
# cat f5a87db156d32c6f.pw cI5LddxeQDqJ1kYsh2jFy7lXIldh2ifURYrYKfeDCOwCaZ6U6xw4HNgDx6v7 # chmod 600 f5a87db156d32c6f.pw
Now we need to create an encrypted diskabel within the previous one using the fileās content as passphrase:
softraid0: CRYPTO volume attached as sd3 # disklabel -E sd3 Label editor (enter '?' for help at any prompt) sd3> a i offset: [0] size: [15630653] FS type: [4.2BSD] sd3*> w sd3> q No label changes. # disklabel sd3 # /dev/rsd3c: type: SCSI disk: SCSI disk label: SR CRYPTO duid: 4be3be137f4ba195 flags: bytes/sector: 512 sectors/track: 63 tracks/cylinder: 255 sectors/cylinder: 16065 cylinders: 972 total sectors: 15630653 boundstart: 0 boundend: 15630653 drivedata: 0 16 partitions: # size offset fstype [fsize bsize cpg] c: 15630653 0 unused i: 15630624 0 4.2BSD 2048 16384 12960
To double test that everything works as designed, detach and re-attach the disk:
# bioctl -c C -p f5a87db156d32c6f.pw -l /dev/sd2a softraid0 softraid0: CRYPTO volume attached as sd3
Now we create a file system where the backups will be stored. Using the -O 2 option we can force newfs to create a FFS2 file system.
/dev/rsd3i: 7632.1MB in 15630624 sectors of 512 bytes 38 cylinder groups of 202.50MB, 12960 blocks, 25920 inodes each super-block backups (for fsck -b #) at: 160, 414880, 829600, [...] # mount /dev/sd3i /mnt/ # ls -l /mnt/
The external disk is now ready to be used.
Now, we make sure that the disk is recognized by the system as soon as itās connected. This can be easily done with hotplugd[a]. To identify the disk we look at the disklabel of each attached disk and run a script as soon as itās connected.
#!/bin/sh DEVCLASS=$1 DEVNAME=$2 case $DEVCLASS in 2) # disk devices duid=`/sbin/disklabel $DEVNAME 2>&1 | sed -n '/^duid: /s/^duid: //p'` case $duid in f5a87db156d32c6f) # Example USB stick logger -i "Example USB stick attached" sh /root/openbsd-timemachine-backup.sh f5a87db156d32c6f 4be3be137f4ba195 /root/f5a87db156d32c6f.pw ;; esac esac
So what does the script above? It is called by hotplugd every time a device is attached. It checks if a disk is attached (DEVCLASS is 2) and then get the diskās duid from disklabel. If the duid matches the on from the backup disk (f5a87db156d32c6f in our case), it starts a script called /root/openbsd-timemachine-backup.sh. The script gets three parameters:
It also logs some information to syslog to make you aware that a backup disk is connected.
rsnapshot[a] is used for backing up the data. According to the website ārsnapshot is a file system snapshot utility based on rsync. rsnapshot makes it easy to make periodic snapshots of local machines, and remote machines over ssh. The code makes extensive use of hard links whenever possible, to greatly reduce the disk space required.ā So, exactly what weāre looking after.
Install it from ports:
The simplest way to configure it, is to copy the example config from /usr/local/share/examples/rsnapshot/rsnapshot.conf.default to /etc/rsnapshot.conf and adapt it as needed. The things you need to configure to make it work with the script below are as follows:
# -snapshot_root /.snapshots/ +snapshot_root /backup/ # LOCALHOST -#backup /home/ localhost/ +backup / localhost/
Keep the Greek letter names (alpha, beta, ā¦) for the backup levels. Depending on your available backup disk size you might want to tune the number of snapshots to be retained. To make sure that rsnapshot works as expected mount your backup drive to /backup and run it once. Check for errors and resolve them, if needed.
If rsnapshot works as expected we can now configure the script that runs it automatically.
The script[a] is quite simple and just decrypts the disk, mounts it and runs rsnapshot to create an incremental backup. You should not need to change something, however, double check the following points:
Upon the first call, a counter is written to the backup disk. Every 8th run, a rsnapshot gamma backup is done, every 4th run a beta backup, and an alpha backup on all other runs.
!/bin/sh PATH=/bin:/sbin:/usr/bin:/usr/sbin:/usr/local/bin:/usr/local/sbin MNTPOIN=/backup # DUID of the softraid container OUTER_DUID=$1 # DUID of the disk within the decrypted container INNER_DUID=$2 # Location to the file containing the passphrase PASSFILE=$3 # Location to counter file CNTF=${MNTPOIN}/.counter # Wrong number of arguments if [[ -z $OUTER_DUID || -z $INNER_DUID ]]; then logger -i -t error "$(basename $0): DUIDs missing. Abort" exit 1 fi if [[ -z $PASSFILE ]]; then logger -i -t error "$(basename $0): No path to PASSFILE given. Abort" exit 1 else if [[ ! -f $PASSFILE ]]; then logger -i -t error "$(basename $0): Cannot open $PASSFILE. Abort" exit 1 fi fi if [[ -n $(mount | grep ${MNTPOIN}) ]]; then logger -i -t error "$(basename $0): Mount point $MNTPOIN is not empty. Abort" exit 1 fi bioctl -c C -p $PASSFILE -l ${OUTER_DUID}.a softraid0 > /dev/null || exit 1 logger "$(basename $0): Backup disk successfully bio-attached" sync mount -o softdep,noatime ${INNER_DUID}.i $MNTPOIN || exit 1 logger "$(basename $0): Backup disk mounted successfully to $MNTPOIN" # First backup of its kind if [[ ! -f ${CNTF} ]]; then echo "1" > $CNTF fi i=$(cat $CNTF) if [ $((i%8)) -eq 0 ]; then logger "$(basename $0): Iteration ${i}, doing a gamma backup" rsnapshot -q -c /etc/rsnapshot.conf gamma elif [ $((i%4)) -eq 0 ]; then logger "$(basename $0): Iteration ${i}, doing a beta backup" rsnapshot -q -c /etc/rsnapshot.conf beta else logger "$(basename $0): Iteration ${i}, doing an alpha backup" rsnapshot -q -c /etc/rsnapshot.conf alpha fi echo $((i+=1)) > $CNTF sync umount $MNTPOIN || exit 1 logger "$(basename $0): $MNTPOIN successfully unmounted" bioctl -d $INNER_DUID || exit 1 logger "$(basename $0): disk successfully bio-detached"
Once you connect the disk you should see a backup job running and similar output to the following in /var/log/messages (timestamps cut):
sd2: 2861556MB, 512 bytes/sector, 5860466688 sectors root[28211]: 2TB Backup USB disk attached openbsd-timemachine-backup.sh: Backup disk successfully bio-attached sd3 at scsibus3 targ 2 lun 0: <OPENBSD, SR CRYPTO, 006> sd3: 2097095MB, 512 bytes/sector, 4294852016 sectors root: openbsd-timemachine-backup.sh: Backup disk mounted successfully to /backup root: openbsd-timemachine-backup.sh: Iteration 54, doing an alpha backup rsnapshot[6708]: WARNING: /usr/local/bin/rsnapshot -q -c /etc/rsnapshot.conf alpha: completed, but with some warnings root: openbsd-timemachine-backup.sh: /backup successfully unmounted sd3 detached root: openbsd-timemachine-backup.sh: disk successfully bio-detached