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Comparing Snapshots
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It is also possible to set additional options for sharing datasets through <acronym>NFS</acronym>, such as <option>-alldirs</option>, <option>-maproot</option> and <option>-network</option>. To set additional options to a dataset shared through NFS, enter:
<prompt>#</prompt> <userinput> zfs set sharenfs="-alldirs,-maproot=<replaceable>root</replaceable>,-network=<replaceable></replaceable>" <replaceable>mypool/usr/home</replaceable></userinput>
Managing Snapshots
<link linkend="zfs-term-snapshot">Snapshots</link> are one of the most powerful features of <acronym>ZFS</acronym>. A snapshot provides a read-only, point-in-time copy of the dataset. With Copy-On-Write (<acronym>COW</acronym>), snapshots can be created quickly by preserving the older version of the data on disk. If no snapshots exist, space is reclaimed for future use when data is rewritten or deleted. Snapshots preserve disk space by recording only the differences between the current dataset and a previous version. Snapshots are allowed only on whole datasets, not on individual files or directories. When a snapshot is created from a dataset, everything contained in it is duplicated. This includes the file system properties, files, directories, permissions, and so on. Snapshots use no additional space when they are first created, only consuming space as the blocks they reference are changed. Recursive snapshots taken with <option>-r</option> create a snapshot with the same name on the dataset and all of its children, providing a consistent moment-in-time snapshot of all of the file systems. This can be important when an application has files on multiple datasets that are related or dependent upon each other. Without snapshots, a backup would have copies of the files from different points in time.
Snapshots in <acronym>ZFS</acronym> provide a variety of features that even other file systems with snapshot functionality lack. A typical example of snapshot use is to have a quick way of backing up the current state of the file system when a risky action like a software installation or a system upgrade is performed. If the action fails, the snapshot can be rolled back and the system has the same state as when the snapshot was created. If the upgrade was successful, the snapshot can be deleted to free up space. Without snapshots, a failed upgrade often requires a restore from backup, which is tedious, time consuming, and may require downtime during which the system cannot be used. Snapshots can be rolled back quickly, even while the system is running in normal operation, with little or no downtime. The time savings are enormous with multi-terabyte storage systems and the time required to copy the data from backup. Snapshots are not a replacement for a complete backup of a pool, but can be used as a quick and easy way to store a copy of the dataset at a specific point in time.
Creating Snapshots
Snapshots are created with <command>zfs snapshot <replaceable>dataset</replaceable>@<replaceable>snapshotname</replaceable></command>. Adding <option>-r</option> creates a snapshot recursively, with the same name on all child datasets.
Create a recursive snapshot of the entire pool:
<prompt>#</prompt> <userinput>zfs list -t all</userinput>
mypool 780M 93.2G 144K none
mypool/ROOT 777M 93.2G 144K none
mypool/ROOT/default 777M 93.2G 777M /
mypool/tmp 176K 93.2G 176K /tmp
mypool/usr 616K 93.2G 144K /usr
mypool/usr/home 184K 93.2G 184K /usr/home
mypool/usr/ports 144K 93.2G 144K /usr/ports
mypool/usr/src 144K 93.2G 144K /usr/src
mypool/var 1.29M 93.2G 616K /var
mypool/var/crash 148K 93.2G 148K /var/crash
mypool/var/log 178K 93.2G 178K /var/log
mypool/var/mail 144K 93.2G 144K /var/mail
mypool/var/newname 87.5K 93.2G 87.5K /var/newname
mypool/var/newname@new_snapshot_name 0 - 87.5K -
mypool/var/tmp 152K 93.2G 152K /var/tmp
<prompt>#</prompt> <userinput>zfs snapshot -r <replaceable>mypool@my_recursive_snapshot</replaceable></userinput>
<prompt>#</prompt> <userinput>zfs list -t snapshot</userinput>
mypool@my_recursive_snapshot 0 - 144K -
mypool/ROOT@my_recursive_snapshot 0 - 144K -
mypool/ROOT/default@my_recursive_snapshot 0 - 777M -
mypool/tmp@my_recursive_snapshot 0 - 176K -
mypool/usr@my_recursive_snapshot 0 - 144K -
mypool/usr/home@my_recursive_snapshot 0 - 184K -
mypool/usr/ports@my_recursive_snapshot 0 - 144K -
mypool/usr/src@my_recursive_snapshot 0 - 144K -
mypool/var@my_recursive_snapshot 0 - 616K -
mypool/var/crash@my_recursive_snapshot 0 - 148K -
mypool/var/log@my_recursive_snapshot 0 - 178K -
mypool/var/mail@my_recursive_snapshot 0 - 144K -
mypool/var/newname@new_snapshot_name 0 - 87.5K -
mypool/var/newname@my_recursive_snapshot 0 - 87.5K -
mypool/var/tmp@my_recursive_snapshot 0 - 152K -
Snapshots are not shown by a normal <command>zfs list</command> operation. To list snapshots, <option>-t snapshot</option> is appended to <command>zfs list</command>. <option>-t all</option> displays both file systems and snapshots.
Snapshots are not mounted directly, so no path is shown in the <literal>MOUNTPOINT</literal> column. There is no mention of available disk space in the <literal>AVAIL</literal> column, as snapshots cannot be written to after they are created. Compare the snapshot to the original dataset from which it was created:
<prompt>#</prompt> <userinput>zfs list -rt all <replaceable>mypool/usr/home</replaceable></userinput>
mypool/usr/home 184K 93.2G 184K /usr/home
mypool/usr/home@my_recursive_snapshot 0 - 184K -
Displaying both the dataset and the snapshot together reveals how snapshots work in <link linkend="zfs-term-cow">COW</link> fashion. They save only the changes (<emphasis>delta</emphasis>) that were made and not the complete file system contents all over again. This means that snapshots take little space when few changes are made. Space usage can be made even more apparent by copying a file to the dataset, then making a second snapshot:
<prompt>#</prompt> <userinput>cp <replaceable>/etc/passwd</replaceable> <replaceable>/var/tmp</replaceable></userinput>
<prompt>#</prompt> <userinput>zfs snapshot <replaceable>mypool/var/tmp</replaceable>@<replaceable>after_cp</replaceable></userinput>
<prompt>#</prompt> <userinput>zfs list -rt all <replaceable>mypool/var/tmp</replaceable></userinput>
mypool/var/tmp 206K 93.2G 118K /var/tmp
mypool/var/tmp@my_recursive_snapshot 88K - 152K -
mypool/var/tmp@after_cp 0 - 118K -
The second snapshot contains only the changes to the dataset after the copy operation. This yields enormous space savings. Notice that the size of the snapshot <replaceable>mypool/var/tmp@my_recursive_snapshot</replaceable> also changed in the <literal>USED</literal> column to indicate the changes between itself and the snapshot taken afterwards.
Comparing Snapshots
ZFS provides a built-in command to compare the differences in content between two snapshots. This is helpful when many snapshots were taken over time and the user wants to see how the file system has changed over time. For example, <command>zfs diff</command> lets a user find the latest snapshot that still contains a file that was accidentally deleted. Doing this for the two snapshots that were created in the previous section yields this output:
<prompt>#</prompt> <userinput>zfs list -rt all <replaceable>mypool/var/tmp</replaceable></userinput>
mypool/var/tmp 206K 93.2G 118K /var/tmp
mypool/var/tmp@my_recursive_snapshot 88K - 152K -
mypool/var/tmp@after_cp 0 - 118K -
<prompt>#</prompt> <userinput>zfs diff <replaceable>mypool/var/tmp@my_recursive_snapshot</replaceable></userinput>
M /var/tmp/
+ /var/tmp/passwd
The command lists the changes between the specified snapshot (in this case <literal><replaceable>mypool/var/tmp@my_recursive_snapshot</replaceable></literal>) and the live file system. The first column shows the type of change:
The path or file was added.
The path or file was deleted.
The path or file was modified.
The path or file was renamed.
Comparing the output with the table, it becomes clear that <filename><replaceable>passwd</replaceable></filename> was added after the snapshot <literal><replaceable>mypool/var/tmp@my_recursive_snapshot</replaceable></literal> was created. This also resulted in a modification to the parent directory mounted at <literal><replaceable>/var/tmp</replaceable></literal>.
Comparing two snapshots is helpful when using the <acronym>ZFS</acronym> replication feature to transfer a dataset to a different host for backup purposes.
Compare two snapshots by providing the full dataset name and snapshot name of both datasets:
<prompt>#</prompt> <userinput>cp /var/tmp/passwd /var/tmp/passwd.copy</userinput>
<prompt>#</prompt> <userinput>zfs snapshot <replaceable>mypool/var/tmp@diff_snapshot</replaceable></userinput>
<prompt>#</prompt> <userinput>zfs diff <replaceable>mypool/var/tmp@my_recursive_snapshot</replaceable> <replaceable>mypool/var/tmp@diff_snapshot</replaceable></userinput>
M /var/tmp/
+ /var/tmp/passwd
+ /var/tmp/passwd.copy
<prompt>#</prompt> <userinput>zfs diff <replaceable>mypool/var/tmp@my_recursive_snapshot</replaceable> <replaceable>mypool/var/tmp@after_cp</replaceable></userinput>
M /var/tmp/
+ /var/tmp/passwd
A backup administrator can compare two snapshots received from the sending host and determine the actual changes in the dataset. See the <link linkend="zfs-zfs-send">Replication</link> section for more information.
Snapshot Rollback


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