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<?xml version='1.0'?>
<!DOCTYPE refentry PUBLIC "-//OASIS//DTD DocBook XML V4.5//EN"
"http://www.oasis-open.org/docbook/xml/4.2/docbookx.dtd">
<!-- SPDX-License-Identifier: LGPL-2.1-or-later -->
<refentry id="repart.d" conditional='ENABLE_REPART'
xmlns:xi="http://www.w3.org/2001/XInclude">
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<refentryinfo>
<title>repart.d</title>
<productname>systemd</productname>
</refentryinfo>
<refmeta>
<refentrytitle>repart.d</refentrytitle>
<manvolnum>5</manvolnum>
</refmeta>
<refnamediv>
<refname>repart.d</refname>
<refpurpose>Partition Definition Files for Automatic Boot-Time Repartitioning</refpurpose>
</refnamediv>
<refsynopsisdiv>
<para><literallayout><filename>/etc/repart.d/*.conf</filename>
<filename>/run/repart.d/*.conf</filename>
<filename>/usr/lib/repart.d/*.conf</filename>
</literallayout></para>
</refsynopsisdiv>
<refsect1>
<title>Description</title>
<para><filename>repart.d/*.conf</filename> files describe basic properties of partitions of block
devices of the local system. They may be used to declare types, names and sizes of partitions that shall
exist. The
<citerefentry><refentrytitle>systemd-repart</refentrytitle><manvolnum>8</manvolnum></citerefentry>
service reads these files and attempts to add new partitions currently missing and enlarge existing
partitions according to these definitions. Operation is generally incremental, i.e. when applied, what
exists already is left intact, and partitions are never shrunk, moved or deleted.</para>
<para>These definition files are useful for implementing operating system images that are prepared and
delivered with minimally sized images (for example lacking any state or swap partitions), and which on
first boot automatically take possession of any remaining disk space following a few basic rules.</para>
<para>Currently, support for partition definition files is only implemented for GPT partitition
tables.</para>
<para>Partition files are generally matched against any partitions already existing on disk in a simple
algorithm: the partition files are sorted by their filename (ignoring the directory prefix), and then
compared in order against existing partitions matching the same partition type UUID. Specifically, the
first existing partition with a specific partition type UUID is assigned the first definition file with
the same partition type UUID, and the second existing partition with a specific type UUID the second
partition file with the same type UUID, and so on. Any left-over partition files that have no matching
existing partition are assumed to define new partition that shall be created. Such partitions are
appended to the end of the partition table, in the order defined by their names utilizing the first
partition slot greater than the highest slot number currently in use. Any existing partitions that have
no matching partition file are left as they are.</para>
<para>Note that these definitions may only be used to create and initialize new partitions or to grow
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existing ones. In the latter case it will not grow the contained files systems however; separate
mechanisms, such as
<citerefentry><refentrytitle>systemd-growfs</refentrytitle><manvolnum>8</manvolnum></citerefentry> may be
used to grow the file systems inside of these partitions. Partitions may also be marked for automatic
growing via the <varname>GrowFileSystem=</varname> setting, in which case the file system is grown on
first mount by tools that respect this flag. See below for details.</para>
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</refsect1>
<refsect1>
<title>[Partition] Section Options</title>
<variablelist>
<varlistentry>
<term><varname>Type=</varname></term>
<listitem><para>The GPT partition type UUID to match. This may be a GPT partition type UUID such as
<constant>4f68bce3-e8cd-4db1-96e7-fbcaf984b709</constant>, or one of the following special
identifiers:</para>
<table>
<title>GPT partition type identifiers</title>
<tgroup cols='2' align='left' colsep='1' rowsep='1'>
<colspec colname="name" />
<colspec colname="explanation" />
<thead>
<row>
<entry>Identifier</entry>
<entry>Explanation</entry>
</row>
</thead>
<tbody>
<row>
<entry><constant>esp</constant></entry>
<entry>EFI System Partition</entry>
</row>
<row>
<entry><constant>xbootldr</constant></entry>
<entry>Extended Boot Loader Partition</entry>
</row>
<row>
<entry><constant>swap</constant></entry>
<entry>Swap partition</entry>
</row>
<row>
<entry><constant>home</constant></entry>
<entry>Home (<filename>/home/</filename>) partition</entry>
</row>
<row>
<entry><constant>srv</constant></entry>
<entry>Server data (<filename>/srv/</filename>) partition</entry>
</row>
<row>
<entry><constant>var</constant></entry>
<entry>Variable data (<filename>/var/</filename>) partition</entry>
</row>
<row>
<entry><constant>tmp</constant></entry>
<entry>Temporary data (<filename>/var/tmp/</filename>) partition</entry>
</row>
<row>
<entry><constant>linux-generic</constant></entry>
<entry>Generic Linux file system partition</entry>
</row>
<row>
<entry><constant>root</constant></entry>
<entry>Root file system partition type appropriate for the local architecture (an alias for an architecture root file system partition type listed below, e.g. <constant>root-x86-64</constant>)</entry>
</row>
<row>
<entry><constant>root-verity</constant></entry>
<entry>Verity data for the root file system partition for the local architecture</entry>
</row>
<row>
<entry><constant>root-secondary</constant></entry>
<entry>Root file system partition of the secondary architecture of the local architecture (usually the matching 32bit architecture for the local 64bit architecture)</entry>
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</row>
<row>
<entry><constant>root-secondary-verity</constant></entry>
<entry>Verity data for the root file system partition of the secondary architecture</entry>
</row>
<row>
<entry><constant>root-x86</constant></entry>
<entry>Root file system partition for the x86 (32bit, aka i386) architecture</entry>
</row>
<row>
<entry><constant>root-x86-verity</constant></entry>
<entry>Verity data for the x86 (32bit) root file system partition</entry>
</row>
<row>
<entry><constant>root-x86-64</constant></entry>
<entry>Root file system partition for the x86_64 (64bit, aka amd64) architecture</entry>
</row>
<row>
<entry><constant>root-x86-64-verity</constant></entry>
<entry>Verity data for the x86_64 (64bit) root file system partition</entry>
</row>
<row>
<entry><constant>root-arm</constant></entry>
<entry>Root file system partition for the ARM (32bit) architecture</entry>
</row>
<row>
<entry><constant>root-arm-verity</constant></entry>
<entry>Verity data for the ARM (32bit) root file system partition</entry>
</row>
<row>
<entry><constant>root-arm64</constant></entry>
<entry>Root file system partition for the ARM (64bit, aka aarch64) architecture</entry>
</row>
<row>
<entry><constant>root-arm64-verity</constant></entry>
<entry>Verity data for the ARM (64bit, aka aarch64) root file system partition</entry>
</row>
<row>
<entry><constant>root-ia64</constant></entry>
<entry>Root file system partition for the ia64 architecture</entry>
</row>
<row>
<entry><constant>root-ia64-verity</constant></entry>
<entry>Verity data for the ia64 root file system partition</entry>
</row>
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<row>
<entry><constant>root-loongarch64</constant></entry>
<entry>Root file system partition for the LoongArch 64-bit architecture</entry>
</row>
<row>
<entry><constant>root-loongarch64-verity</constant></entry>
<entry>Verity data for the LoongArch 64-bit root file system partition</entry>
</row>
<row>
<entry><constant>root-riscv32</constant></entry>
<entry>Root file system partition for the RISC-V 32-bit architecture</entry>
</row>
<row>
<entry><constant>root-riscv32-verity</constant></entry>
<entry>Verity data for the RISC-V 32-bit root file system partition</entry>
</row>
<row>
<entry><constant>root-riscv64</constant></entry>
<entry>Root file system partition for the RISC-V 64-bit architecture</entry>
</row>
<row>
<entry><constant>root-riscv64-verity</constant></entry>
<entry>Verity data for the RISC-V 64-bit root file system partition</entry>
</row>
<row>
<entry><constant>usr</constant></entry>
<entry><filename>/usr/</filename> file system partition type appropriate for the local architecture (an alias for an architecture <filename>/usr/</filename> file system partition type listed below, e.g. <constant>usr-x86-64</constant>)</entry>
</row>
<row>
<entry><constant>usr-verity</constant></entry>
<entry>Verity data for the <filename>/usr/</filename> file system partition for the local architecture</entry>
</row>
<row>
<entry><constant>usr-secondary</constant></entry>
<entry><filename>/usr/</filename> file system partition of the secondary architecture of the local architecture (usually the matching 32bit architecture for the local 64bit architecture)</entry>
</row>
<row>
<entry><constant>usr-secondary-verity</constant></entry>
<entry>Verity data for the <filename>/usr/</filename> file system partition of the secondary architecture</entry>
</row>
<row>
<entry><constant>usr-x86</constant></entry>
<entry><filename>/usr/</filename> file system partition for the x86 (32bit, aka i386) architecture</entry>
</row>
<row>
<entry><constant>usr-x86-verity</constant></entry>
<entry>Verity data for the x86 (32bit) <filename>/usr/</filename> file system partition</entry>
</row>
<row>
<entry><constant>usr-x86-64</constant></entry>
<entry><filename>/usr/</filename> file system partition for the x86_64 (64bit, aka amd64) architecture</entry>
</row>
<row>
<entry><constant>usr-x86-64-verity</constant></entry>
<entry>Verity data for the x86_64 (64bit) <filename>/usr/</filename> file system partition</entry>
</row>
<row>
<entry><constant>usr-arm</constant></entry>
<entry><filename>/usr/</filename> file system partition for the ARM (32bit) architecture</entry>
</row>
<row>
<entry><constant>usr-arm-verity</constant></entry>
<entry>Verity data for the ARM (32bit) <filename>/usr/</filename> file system partition</entry>
</row>
<row>
<entry><constant>usr-arm64</constant></entry>
<entry><filename>/usr/</filename> file system partition for the ARM (64bit, aka aarch64) architecture</entry>
</row>
<row>
<entry><constant>usr-arm64-verity</constant></entry>
<entry>Verity data for the ARM (64bit, aka aarch64) <filename>/usr/</filename> file system partition</entry>
</row>
<row>
<entry><constant>usr-ia64</constant></entry>
<entry><filename>/usr/</filename> file system partition for the ia64 architecture</entry>
</row>
<row>
<entry><constant>usr-ia64-verity</constant></entry>
<entry>Verity data for the ia64 <filename>/usr/</filename> file system partition</entry>
</row>
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<row>
<entry><constant>usr-loongarch64</constant></entry>
<entry><filename>/usr/</filename> file system partition for the LoongArch 64-bit architecture</entry>
</row>
<row>
<entry><constant>usr-loongarch64-verity</constant></entry>
<entry>Verity data for the LoongArch 64-bit <filename>/usr/</filename> file system partition</entry>
</row>
<row>
<entry><constant>usr-riscv32</constant></entry>
<entry><filename>/usr/</filename> file system partition for the RISC-V 32-bit architecture</entry>
</row>
<row>
<entry><constant>usr-riscv32-verity</constant></entry>
<entry>Verity data for the RISC-V 32-bit <filename>/usr/</filename> file system partition</entry>
</row>
<row>
<entry><constant>usr-riscv64</constant></entry>
<entry><filename>/usr/</filename> file system partition for the RISC-V 64-bit architecture</entry>
</row>
<row>
<entry><constant>usr-riscv64-verity</constant></entry>
<entry>Verity data for the RISC-V 64-bit <filename>/usr/</filename> file system partition</entry>
</row>
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</tbody>
</tgroup>
</table>
<para>This setting defaults to <constant>linux-generic</constant>.</para>
<para>Most of the partition type UUIDs listed above are defined in the <ulink
url="https://systemd.io/DISCOVERABLE_PARTITIONS">Discoverable Partitions
Specification</ulink>.</para></listitem>
</varlistentry>
<varlistentry>
<term><varname>Label=</varname></term>
<listitem><para>The textual label to assign to the partition if none is assigned yet. Note that this
setting is not used for matching. It is also not used when a label is already set for an existing
partition. It is thus only used when a partition is newly created or when an existing one had a no
label set (that is: an empty label). If not specified a label derived from the partition type is
automatically used. Simple specifier expansion is supported, see below.</para></listitem>
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</varlistentry>
<varlistentry>
<term><varname>UUID=</varname></term>
<listitem><para>The UUID to assign to the partition if none is assigned yet. Note that this
setting is not used for matching. It is also not used when a UUID is already set for an existing
partition. It is thus only used when a partition is newly created or when an existing one had a
all-zero UUID set. If not specified a UUID derived from the partition type is automatically
used.</para></listitem>
</varlistentry>
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<varlistentry>
<term><varname>Priority=</varname></term>
<listitem><para>A numeric priority to assign to this partition, in the range -2147483648…2147483647,
with smaller values indicating higher priority, and higher values indicating smaller priority. This
priority is used in case the configured size constraints on the defined partitions do not permit
fitting all partitions onto the available disk space. If the partitions do not fit, the highest
numeric partition priority of all defined partitions is determined, and all defined partitions with
this priority are removed from the list of new partitions to create (which may be multiple, if the
same priority is used for multiple partitions). The fitting algorithm is then tried again. If the
partitions still do not fit, the now highest numeric partition priority is determined, and the
matching partitions removed too, and so on. Partitions of a priority of 0 or lower are never
removed. If all partitions with a priority above 0 are removed and the partitions still do not fit on
the device the operation fails. Note that this priority has no effect on ordering partitions, for
that use the alphabetical order of the filenames of the partition definition files. Defaults to
0.</para></listitem>
</varlistentry>
<varlistentry>
<term><varname>Weight=</varname></term>
<listitem><para>A numeric weight to assign to this partition in the range 0…1000000. Available disk
space is assigned the defined partitions according to their relative weights (subject to the size
constraints configured with <varname>SizeMinBytes=</varname>, <varname>SizeMaxBytes=</varname>), so
that a partition with weight 2000 gets double the space as one with weight 1000, and a partition with
weight 333 a third of that. Defaults to 1000.</para>
<para>The <varname>Weight=</varname> setting is used to distribute available disk space in an
"elastic" fashion, based on the disk size and existing partitions. If a partition shall have a fixed
size use both <varname>SizeMinBytes=</varname> and <varname>SizeMaxBytes=</varname> with the same
value in order to fixate the size to one value, in which case the weight has no
effect.</para></listitem>
</varlistentry>
<varlistentry>
<term><varname>PaddingWeight=</varname></term>
<listitem><para>Similar to <varname>Weight=</varname> but sets a weight for the free space after the
partition (the "padding"). When distributing available space the weights of all partitions and all
defined padding is summed, and then each partition and padding gets the fraction defined by its
weight. Defaults to 0, i.e. by default no padding is applied.</para>
<para>Padding is useful if empty space shall be left for later additions or a safety margin at the
end of the device or between partitions.</para></listitem>
</varlistentry>
<varlistentry>
<term><varname>SizeMinBytes=</varname></term>
<term><varname>SizeMaxBytes=</varname></term>
<listitem><para>Specifies minimum and maximum size constraints in bytes. Takes the usual K, M, G, T,
… suffixes (to the base of 1024). If <varname>SizeMinBytes=</varname> is specified the partition is
created at or grown to at least the specified size. If <varname>SizeMaxBytes=</varname> is specified
the partition is created at or grown to at most the specified size. The precise size is determined
through the weight value value configured with <varname>Weight=</varname>, see above. When
<varname>SizeMinBytes=</varname> is set equal to <varname>SizeMaxBytes=</varname> the configured
weight has no effect as the partition is explicitly sized to the specified fixed value. Note that
partitions are never created smaller than 4096 bytes, and since partitions are never shrunk the
previous size of the partition (in case the partition already exists) is also enforced as lower bound
for the new size. The values should be specified as multiples of 4096 bytes, and are rounded upwards
(in case of <varname>SizeMinBytes=</varname>) or downwards (in case of
<varname>SizeMaxBytes=</varname>) otherwise. If the backing device does not provide enough space to
fulfill the constraints placing the partition will fail. For partitions that shall be created,
depending on the setting of <varname>Priority=</varname> (see above) the partition might be dropped
and the placing algorithm restarted. By default a minimum size constraint of 10M and no maximum size
constraint is set.</para></listitem>
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</varlistentry>
<varlistentry>
<term><varname>PaddingMinBytes=</varname></term>
<term><varname>PaddingMaxBytes=</varname></term>
<listitem><para>Specifies minimum and maximum size constraints in bytes for the free space after the
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partition (the "padding"). Semantics are similar to <varname>SizeMinBytes=</varname> and
<varname>SizeMaxBytes=</varname>, except that unlike partition sizes free space can be shrunk and can
be as small as zero. By default no size constraints on padding are set, so that only
<varname>PaddingWeight=</varname> determines the size of the padding applied.</para></listitem>
</varlistentry>
<varlistentry>
<term><varname>CopyBlocks=</varname></term>
repart: add CopyBlocks=auto support When using systemd-repart as an installer that replicates the install medium on another medium it is useful to reference the root partition/usr partition or verity data that is currently booted, in particular in A/B scenarios where we have two copies and want to reference the one we currently use. Let's add a CopyBlocks=auto for this case: for a partition that uses that we'll copy a suitable partition from the host. CopyBlocks=auto finds the partition to copy like this: based on the configured partition type uuid we determine the usual mount point (i.e. for the /usr partition type we determine /usr/, and so on). We then figure out the block device behind that path, through dm-verity and dm-crypt if necessary. Finally, we compare the partition type uuid of the partition found that way with the one we are supposed to fill and only use it if it matches (the latter is primarily important on dm-verity setups where a volume is likely backed by two partitions and we need to find the right one). This is particularly fun to use in conjunction with --image= (where we'll restrict the device search onto the specify device, for security reasons), as this allows "duplicating" an image like this: # systemd-repart --image=source.raw --empty=create --size=auto target.raw If the right repart data is embedded into "source.raw" this will be able to create and initialize a partition table on target.raw that carrries all needed partitions, and will stream the source's file systems onto it as configured.
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<listitem><para>Takes a path to a regular file, block device node or directory, or the special value
<literal>auto</literal>. If specified and the partition is newly created, the data from the specified
path is written to the newly created partition, on the block level. If a directory is specified, the
backing block device of the file system the directory is on is determined, and the data read directly
from that. This option is useful to efficiently replicate existing file systems onto new partitions
on the block level — for example to build a simple OS installer or an OS image builder.</para>
<para>If the special value <literal>auto</literal> is specified, the source to copy from is
automatically picked up from the running system (or the image specified with
<option>--image=</option> — if used). A partition that matches both the configured partition type (as
declared with <varname>Type=</varname> described above), and the currently mounted directory
appropriate for that partition type is determined. For example, if the partition type is set to
repart: add CopyBlocks=auto support When using systemd-repart as an installer that replicates the install medium on another medium it is useful to reference the root partition/usr partition or verity data that is currently booted, in particular in A/B scenarios where we have two copies and want to reference the one we currently use. Let's add a CopyBlocks=auto for this case: for a partition that uses that we'll copy a suitable partition from the host. CopyBlocks=auto finds the partition to copy like this: based on the configured partition type uuid we determine the usual mount point (i.e. for the /usr partition type we determine /usr/, and so on). We then figure out the block device behind that path, through dm-verity and dm-crypt if necessary. Finally, we compare the partition type uuid of the partition found that way with the one we are supposed to fill and only use it if it matches (the latter is primarily important on dm-verity setups where a volume is likely backed by two partitions and we need to find the right one). This is particularly fun to use in conjunction with --image= (where we'll restrict the device search onto the specify device, for security reasons), as this allows "duplicating" an image like this: # systemd-repart --image=source.raw --empty=create --size=auto target.raw If the right repart data is embedded into "source.raw" this will be able to create and initialize a partition table on target.raw that carrries all needed partitions, and will stream the source's file systems onto it as configured.
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<literal>root</literal> the partition backing the root directory (<filename>/</filename>) is used as
source to copy from — if its partition type is set to <literal>root</literal> as well. If the
declared type is <literal>usr</literal> the partition backing <filename>/usr/</filename> is used as
source to copy blocks from — if its partition type is set to <literal>usr</literal> too. The logic is
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capable of automatically tracking down the backing partitions for encrypted and Verity-enabled
repart: add CopyBlocks=auto support When using systemd-repart as an installer that replicates the install medium on another medium it is useful to reference the root partition/usr partition or verity data that is currently booted, in particular in A/B scenarios where we have two copies and want to reference the one we currently use. Let's add a CopyBlocks=auto for this case: for a partition that uses that we'll copy a suitable partition from the host. CopyBlocks=auto finds the partition to copy like this: based on the configured partition type uuid we determine the usual mount point (i.e. for the /usr partition type we determine /usr/, and so on). We then figure out the block device behind that path, through dm-verity and dm-crypt if necessary. Finally, we compare the partition type uuid of the partition found that way with the one we are supposed to fill and only use it if it matches (the latter is primarily important on dm-verity setups where a volume is likely backed by two partitions and we need to find the right one). This is particularly fun to use in conjunction with --image= (where we'll restrict the device search onto the specify device, for security reasons), as this allows "duplicating" an image like this: # systemd-repart --image=source.raw --empty=create --size=auto target.raw If the right repart data is embedded into "source.raw" this will be able to create and initialize a partition table on target.raw that carrries all needed partitions, and will stream the source's file systems onto it as configured.
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volumes. <literal>CopyBlocks=auto</literal> is useful for implementing "self-replicating" systems,
i.e. systems that are their own installer.</para>
<para>The file specified here must have a size that is a multiple of the basic block size 512 and not
be empty. If this option is used, the size allocation algorithm is slightly altered: the partition is
created as least as big as required to fit the data in, i.e. the data size is an additional minimum
size value taken into consideration for the allocation algorithm, similar to and in addition to the
<varname>SizeMin=</varname> value configured above.</para>
<para>This option has no effect if the partition it is declared for already exists, i.e. existing
data is never overwritten. Note that the data is copied in before the partition table is updated,
i.e. before the partition actually is persistently created. This provides robustness: it is
guaranteed that the partition either doesn't exist or exists fully populated; it is not possible that
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the partition exists but is not or only partially populated.</para>
<para>This option cannot be combined with <varname>Format=</varname> or
<varname>CopyFiles=</varname>.</para></listitem>
</varlistentry>
<varlistentry>
<term><varname>Format=</varname></term>
<listitem><para>Takes a file system name, such as <literal>ext4</literal>, <literal>btrfs</literal>,
<literal>xfs</literal> or <literal>vfat</literal>, or the special value <literal>swap</literal>. If
specified and the partition is newly created it is formatted with the specified file system (or as
swap device). The file system UUID and label are automatically derived from the partition UUID and
label. If this option is used, the size allocation algorithm is slightly altered: the partition is
created as least as big as required for the minimal file system of the specified type (or 4KiB if the
minimal size is not known).</para>
<para>This option has no effect if the partition already exists.</para>
<para>Similar to the behaviour of <varname>CopyBlocks=</varname> the file system is formatted before
the partition is created, ensuring that the partition only ever exists with a fully initialized
file system.</para>
<para>This option cannot be combined with <varname>CopyBlocks=</varname>.</para></listitem>
</varlistentry>
<varlistentry>
<term><varname>CopyFiles=</varname></term>
<listitem><para>Takes a pair of colon separated absolute file system paths. The first path refers to
a source file or directory on the host, the second path refers to a target in the file system of the
newly created partition and formatted file system. This setting may be used to copy files or
directories from the host into the file system that is created due to the <varname>Format=</varname>
option. If <varname>CopyFiles=</varname> is used without <varname>Format=</varname> specified
explicitly, <literal>Format=</literal> with a suitable default is implied (currently
<literal>ext4</literal>, but this may change in the future). This option may be used multiple times
to copy multiple files or directories from host into the newly formatted file system. The colon and
second path may be omitted in which case the source path is also used as the target path (relative to
the root of the newly created file system). If the source path refers to a directory it is copied
recursively.</para>
<para>This option has no effect if the partition already exists: it cannot be used to copy additional
files into an existing partition, it may only be used to populate a file system created anew.</para>
<para>The copy operation is executed before the file system is registered in the partition table,
thus ensuring that a file system populated this way only ever exists fully initialized.</para>
<para>This option cannot be combined with <varname>CopyBlocks=</varname>.</para>
<para>When <command>systemd-repart</command> is invoked with the <option>--image=</option> or
<option>--root=</option> command line switches the source paths specified are taken relative to the
specified root directory or disk image root.</para></listitem>
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</varlistentry>
repart: add high-level setting for creating dirs in formatted file systems So far we already had the CopyFiles= option in systemd-repart drop-in files, as a mechanism for populating freshly formatted file systems with files and directories. This adds MakeDirectories= in similar style, and creates simple directories as listed. The option is of course entirely redundant, since the same can be done with CopyFiles= simply by copying in a directory. It's kinda nice to encode the dirs to create directly in the drop-in files however, instead of providing a directory subtree to copy in somehere, to make the files more self-contained — since often just creating dirs is entirely sufficient. The main usecase for this are GPT OS images that carry only a /usr/ tree, and for which a root file system is only formatted on first boot via repart. Without any additional CopyFiles=/MakeDirectories= configuration these root file systems are entirely empty of course initially. To mount in the /usr/ tree, a directory inode for /usr/ to mount over needs to be created. systemd-nspawn will do so automatically when booting up the image, as will the initrd during boot. However, this requires the image to be writable – which is OK for npawn and initrd-based boots, but there are plenty tools where read-only operation is desirable after repart ran, before the image was booted for the first time. Specifically, "systemd-dissect" opens the image in read-only to inspect its contents, and this will only work of /usr/ can be properly mounted. Moreover systemd-dissect --mount --read-only won't succeed either if the fs is read-only. Via MakeDirectories= we now provide a way that ensures that the image can be mounted/inspected in a fully read-only way immediately after systemd-repart completed. Specifically, let's consider a GPT disk image shipping with a file usr/lib/repart.d/50-root.conf: [Partition] Type=root Format=btrfs MakeDirectories=/usr MakeDirectories=/efi With this in place systemd-repart will create a root partition when run, and add /usr and /efi into it as directory inods. This ensures that the whole image can then be mounted truly read-only anf /usr and /efi can be overmounted by the /usr partition and the ESP.
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<varlistentry>
<term><varname>MakeDirectories=</varname></term>
<listitem><para>Takes one or more absolute paths, separated by whitespace, each declaring a directory
repart: add high-level setting for creating dirs in formatted file systems So far we already had the CopyFiles= option in systemd-repart drop-in files, as a mechanism for populating freshly formatted file systems with files and directories. This adds MakeDirectories= in similar style, and creates simple directories as listed. The option is of course entirely redundant, since the same can be done with CopyFiles= simply by copying in a directory. It's kinda nice to encode the dirs to create directly in the drop-in files however, instead of providing a directory subtree to copy in somehere, to make the files more self-contained — since often just creating dirs is entirely sufficient. The main usecase for this are GPT OS images that carry only a /usr/ tree, and for which a root file system is only formatted on first boot via repart. Without any additional CopyFiles=/MakeDirectories= configuration these root file systems are entirely empty of course initially. To mount in the /usr/ tree, a directory inode for /usr/ to mount over needs to be created. systemd-nspawn will do so automatically when booting up the image, as will the initrd during boot. However, this requires the image to be writable – which is OK for npawn and initrd-based boots, but there are plenty tools where read-only operation is desirable after repart ran, before the image was booted for the first time. Specifically, "systemd-dissect" opens the image in read-only to inspect its contents, and this will only work of /usr/ can be properly mounted. Moreover systemd-dissect --mount --read-only won't succeed either if the fs is read-only. Via MakeDirectories= we now provide a way that ensures that the image can be mounted/inspected in a fully read-only way immediately after systemd-repart completed. Specifically, let's consider a GPT disk image shipping with a file usr/lib/repart.d/50-root.conf: [Partition] Type=root Format=btrfs MakeDirectories=/usr MakeDirectories=/efi With this in place systemd-repart will create a root partition when run, and add /usr and /efi into it as directory inods. This ensures that the whole image can then be mounted truly read-only anf /usr and /efi can be overmounted by the /usr partition and the ESP.
2021-03-20 16:05:28 +03:00
to create within the new file system. Behaviour is similar to <varname>CopyFiles=</varname>, but
instead of copying in a set of files this just creates the specified directories with the default
mode of 0755 owned by the root user and group, plus all their parent directories (with the same
ownership and access mode). To configure directories with different ownership or access mode, use
<varname>CopyFiles=</varname> and specify a source tree to copy containing appropriately
owned/configured directories. This option may be used more than once to create multiple
directories. When <varname>CopyFiles=</varname> and <varname>MakeDirectories=</varname> are used
together the former is applied first. If a directory listed already exists no operation is executed
(in particular, the ownership/access mode of the directories is left as is).</para>
<para>The primary usecase for this option is to create a minimal set of directories that may be
mounted over by other partitions contained in the same disk image. For example, a disk image where
the root file system is formatted at first boot might want to automatically pre-create
<filename>/usr/</filename> in it this way, so that the <literal>usr</literal> partition may
over-mount it.</para>
<para>Consider using
<citerefentry><refentrytitle>systemd-tmpfiles</refentrytitle><manvolnum>8</manvolnum></citerefentry>
with its <option>--image=</option> option to pre-create other, more complex directory hierarchies (as
well as other inodes) with fine-grained control of ownership, access modes and other file
attributes.</para></listitem>
</varlistentry>
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<varlistentry>
<term><varname>Encrypt=</varname></term>
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<listitem><para>Takes one of <literal>off</literal>, <literal>key-file</literal>,
<literal>tpm2</literal> and <literal>key-file+tpm2</literal> (alternatively, also accepts a boolean
value, which is mapped to <literal>off</literal> when false, and <literal>key-file</literal> when
true). Defaults to <literal>off</literal>. If not <literal>off</literal> the partition will be
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formatted with a LUKS2 superblock, before the blocks configured with <varname>CopyBlocks=</varname>
are copied in or the file system configured with <varname>Format=</varname> is created.</para>
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<para>The LUKS2 UUID is automatically derived from the partition UUID in a stable fashion. If
<literal>key-file</literal> or <literal>key-file+tpm2</literal> is used, a key is added to the LUKS2
superblock, configurable with the <option>--key-file=</option> option to
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<command>systemd-repart</command>. If <literal>tpm2</literal> or <literal>key-file+tpm2</literal> is
used, a key is added to the LUKS2 superblock that is enrolled to the local TPM2 chip, as configured
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with the <option>--tpm2-device=</option> and <option>--tpm2-pcrs=</option> options to
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<command>systemd-repart</command>.</para>
<para>When used this slightly alters the size allocation logic as the implicit, minimal size limits
of <varname>Format=</varname> and <varname>CopyBlocks=</varname> are increased by the space necessary
for the LUKS2 superblock (see above).</para>
<para>This option has no effect if the partition already exists.</para></listitem>
</varlistentry>
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<varlistentry>
<term><varname>FactoryReset=</varname></term>
<listitem><para>Takes a boolean argument. If specified the partition is marked for removal during a
factory reset operation. This functionality is useful to implement schemes where images can be reset
into their original state by removing partitions and creating them anew. Defaults to off.</para></listitem>
</varlistentry>
<varlistentry>
<term><varname>Flags=</varname></term>
<listitem><para>Configures the 64bit GPT partition flags field to set for the partition when creating
it. This option has no effect if the partition already exists. If not specified the flags values is
set to all zeroes, except for the three bits that can also be configured via
<varname>NoAuto=</varname>, <varname>ReadOnly=</varname> and <varname>GrowFileSystem=</varname>; see
below for details on the defaults for these three flags. Specify the flags value in hexadecimal (by
prefixing it with <literal>0x</literal>), binary (prefix <literal>0b</literal>) or decimal (no
prefix).</para></listitem>
</varlistentry>
<varlistentry>
<term><varname>NoAuto=</varname></term>
<term><varname>ReadOnly=</varname></term>
<term><varname>GrowFileSystem=</varname></term>
<listitem><para>Configures the No-Auto, Read-Only and Grow-File-System partition flags (bit 63, 60
and 59) of the partition table entry, as defined by the <ulink
url="https://systemd.io/DISCOVERABLE_PARTITIONS">Discoverable Partitions Specification</ulink>. Only
available for partition types supported by the specification. This option is a friendly way to set
bits 63, 60 and 59 of the partition flags value without setting any of the other bits, and may be set
via <varname>Flags=</varname> too, see above.</para>
<para>If <varname>Flags=</varname> is used in conjunction with one or more of
<varname>NoAuto=</varname>/<varname>ReadOnly=</varname>/<varname>GrowFileSystem=</varname> the latter
control the value of the relevant flags, i.e. the high-level settings
<varname>NoAuto=</varname>/<varname>ReadOnly=</varname>/<varname>GrowFileSystem=</varname> override
the relevant bits of the low-level setting <varname>Flags=</varname>.</para>
<para>Note that the three flags affect only automatic partition mounting, as implemented by
<citerefentry><refentrytitle>systemd-gpt-auto-generator</refentrytitle><manvolnum>8</manvolnum></citerefentry>
or the <option>--image=</option> option of various commands (such as
<citerefentry><refentrytitle>systemd-nspawn</refentrytitle><manvolnum>1</manvolnum></citerefentry>). It
has no effect on explicit mounts, such as those done via <citerefentry
project='man-pages'><refentrytitle>mount</refentrytitle><manvolnum>8</manvolnum></citerefentry> or
<citerefentry
project='man-pages'><refentrytitle>fstab</refentrytitle><manvolnum>5</manvolnum></citerefentry>.</para>
<para>If both bit 50 and 59 are set for a partition (i.e. the partition is marked both read-only and
marked for file system growing) the latter is typically without effect: the read-only flag takes
precedence in most tools reading these flags, and since growing the file system involves writing to
the partition it is consequently ignored.</para>
<para><varname>NoAuto=</varname> defaults to off. <varname>ReadOnly=</varname> defaults to on for
Verity partition types, and off for all others. <varname>GrowFileSystem=</varname> defaults to on for
all partition types that support it, except if the partition is marked read-only (and thus
effectively, defaults to off for Verity partitions).</para></listitem>
</varlistentry>
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</variablelist>
</refsect1>
<refsect1>
<title>Specifiers</title>
<para>Specifiers may be used in the <varname>Label=</varname>, <varname>CopyBlocks=</varname>,
<varname>CopyFiles=</varname>, <varname>MakeDirectories=</varname> settings. The following expansions are
understood:</para>
<table class='specifiers'>
<title>Specifiers available</title>
<tgroup cols='3' align='left' colsep='1' rowsep='1'>
<colspec colname="spec" />
<colspec colname="mean" />
<colspec colname="detail" />
<thead>
<row>
<entry>Specifier</entry>
<entry>Meaning</entry>
<entry>Details</entry>
</row>
</thead>
<tbody>
<xi:include href="standard-specifiers.xml" xpointer="a"/>
<xi:include href="standard-specifiers.xml" xpointer="A"/>
<xi:include href="standard-specifiers.xml" xpointer="b"/>
<xi:include href="standard-specifiers.xml" xpointer="B"/>
<xi:include href="standard-specifiers.xml" xpointer="H"/>
<xi:include href="standard-specifiers.xml" xpointer="l"/>
<xi:include href="standard-specifiers.xml" xpointer="m"/>
<xi:include href="standard-specifiers.xml" xpointer="M"/>
<xi:include href="standard-specifiers.xml" xpointer="o"/>
<xi:include href="standard-specifiers.xml" xpointer="v"/>
<xi:include href="standard-specifiers.xml" xpointer="w"/>
<xi:include href="standard-specifiers.xml" xpointer="W"/>
<xi:include href="standard-specifiers.xml" xpointer="T"/>
<xi:include href="standard-specifiers.xml" xpointer="V"/>
<xi:include href="standard-specifiers.xml" xpointer="percent"/>
</tbody>
</tgroup>
</table>
</refsect1>
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<refsect1>
<title>Examples</title>
<example>
<title>Grow the root partition to the full disk size at first boot</title>
<para>With the following file the root partition is automatically grown to the full disk if possible during boot.</para>
<para><programlisting># /usr/lib/repart.d/50-root.conf
[Partition]
Type=root
</programlisting></para>
</example>
<example>
<title>Create a swap and home partition automatically on boot, if missing</title>
<para>The home partition gets all available disk space while the swap partition gets 1G at most and 64M
at least. We set a priority > 0 on the swap partition to ensure the swap partition is not used if not
enough space is available. For every three bytes assigned to the home partition the swap partition gets
assigned one.</para>
<para><programlisting># /usr/lib/repart.d/60-home.conf
[Partition]
Type=home
</programlisting></para>
<para><programlisting># /usr/lib/repart.d/70-swap.conf
[Partition]
Type=swap
SizeMinBytes=64M
SizeMaxBytes=1G
Priority=1
Weight=333
</programlisting></para>
</example>
<example>
<title>Create B partitions in an A/B Verity setup, if missing</title>
<para>Let's say the vendor intends to update OS images in an A/B setup, i.e. with two root partitions
(and two matching Verity partitions) that shall be used alternatingly during upgrades. To minimize
image sizes the original image is shipped only with one root and one Verity partition (the "A" set),
and the second root and Verity partitions (the "B" set) shall be created on first boot on the free
space on the medium.</para>
<para><programlisting># /usr/lib/repart.d/50-root.conf
[Partition]
Type=root
SizeMinBytes=512M
SizeMaxBytes=512M
</programlisting></para>
<para><programlisting># /usr/lib/repart.d/60-root-verity.conf
[Partition]
Type=root-verity
SizeMinBytes=64M
SizeMaxBytes=64M
</programlisting></para>
<para>The definitions above cover the "A" set of root partition (of a fixed 512M size) and Verity
partition for the root partition (of a fixed 64M size). Let's use symlinks to create the "B" set of
partitions, since after all they shall have the same properties and sizes as the "A" set.</para>
<para><programlisting># ln -s 50-root.conf /usr/lib/repart.d/70-root-b.conf
# ln -s 60-root-verity.conf /usr/lib/repart.d/80-root-verity-b.conf
</programlisting></para>
</example>
</refsect1>
<refsect1>
<title>See Also</title>
<para>
<citerefentry><refentrytitle>systemd</refentrytitle><manvolnum>1</manvolnum></citerefentry>,
<citerefentry><refentrytitle>systemd-repart</refentrytitle><manvolnum>8</manvolnum></citerefentry>,
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<citerefentry project='man-pages'><refentrytitle>sfdisk</refentrytitle><manvolnum>8</manvolnum></citerefentry>,
<citerefentry><refentrytitle>systemd-cryptenroll</refentrytitle><manvolnum>1</manvolnum></citerefentry>
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</para>
</refsect1>
</refentry>