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authorJosselin Poiret <dev@jpoiret.xyz>2021-11-15 20:26:31 +0000
committerLudovic Courtès <ludo@gnu.org>2021-11-23 10:24:28 +0100
commit9685c0637decec77880cec65547a2e57c300761a (patch)
tree6ffa1dce1a123549de4ca8dbfd0dc05010dc97ef /doc/guix.texi
parent4af3262d9857405aff0a4a855403247f0f485e15 (diff)
downloadguix-9685c0637decec77880cec65547a2e57c300761a.tar
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doc: Add new Swap Space section.
* doc/guix.texi (operating-system Reference): Update swap-devices. * doc/guix.texi (Swap Space): Add it. * gnu/system/examples/desktop.tmpl: Add swap-devices example. Signed-off-by: Ludovic Courtès <ludo@gnu.org>
Diffstat (limited to 'doc/guix.texi')
-rw-r--r--doc/guix.texi147
1 files changed, 110 insertions, 37 deletions
diff --git a/doc/guix.texi b/doc/guix.texi
index 8b86d55075..2a166e3a89 100644
--- a/doc/guix.texi
+++ b/doc/guix.texi
@@ -319,6 +319,7 @@ System Configuration
* operating-system Reference:: Detail of operating-system declarations.
* File Systems:: Configuring file system mounts.
* Mapped Devices:: Block device extra processing.
+* Swap Space:: Backing RAM with disk space.
* User Accounts:: Specifying user accounts.
* Keyboard Layout:: How the system interprets key strokes.
* Locales:: Language and cultural convention settings.
@@ -2515,10 +2516,9 @@ system relative to this path. If you have opted for @file{/boot/efi} as an
EFI mount point for example, mount it at @file{/mnt/boot/efi} now so it is
found by @code{guix system init} afterwards.
-Finally, if you plan to use one or more swap partitions (@pxref{Memory
-Concepts, swap space,, libc, The GNU C Library Reference Manual}), make
-sure to initialize them with @command{mkswap}. Assuming you have one
-swap partition on @file{/dev/sda3}, you would run:
+Finally, if you plan to use one or more swap partitions (@pxref{Swap
+Space}), make sure to initialize them with @command{mkswap}. Assuming
+you have one swap partition on @file{/dev/sda3}, you would run:
@example
mkswap /dev/sda3
@@ -13987,6 +13987,7 @@ instance to support new system services.
* operating-system Reference:: Detail of operating-system declarations.
* File Systems:: Configuring file system mounts.
* Mapped Devices:: Block device extra processing.
+* Swap Space:: Backing RAM with disk space.
* User Accounts:: Specifying user accounts.
* Keyboard Layout:: How the system interprets key strokes.
* Locales:: Language and cultural convention settings.
@@ -14155,7 +14156,7 @@ configuration, but with a few modifications.
@cindex encrypted disk
The configuration for a typical ``desktop'' usage, with an encrypted
-root partition, the X11 display
+root partition, a swap file on the root partition, the X11 display
server, GNOME and Xfce (users can choose which of these desktop
environments to use at the log-in screen by pressing @kbd{F1}), network
management, power management, and more, would look like this:
@@ -14353,38 +14354,9 @@ A list of mapped devices. @xref{Mapped Devices}.
@item @code{file-systems}
A list of file systems. @xref{File Systems}.
-@cindex swap devices
-@cindex swap space
@item @code{swap-devices} (default: @code{'()})
-A list of UUIDs, file system labels, or strings identifying devices or
-files to be used for ``swap
-space'' (@pxref{Memory Concepts,,, libc, The GNU C Library Reference
-Manual}). Here are some examples:
-
-@table @code
-@item (list (uuid "4dab5feb-d176-45de-b287-9b0a6e4c01cb"))
-Use the swap partition with the given UUID@. You can learn the UUID of a
-Linux swap partition by running @command{swaplabel @var{device}}, where
-@var{device} is the @file{/dev} file name of that partition.
-
-@item (list (file-system-label "swap"))
-Use the partition with label @code{swap}. Again, the
-@command{swaplabel} command allows you to view and change the label of a
-Linux swap partition.
-
-@item (list "/swapfile")
-Use the file @file{/swapfile} as swap space.
-
-@item (list "/dev/sda3" "/dev/sdb2")
-Use the @file{/dev/sda3} and @file{/dev/sdb2} partitions as swap space.
-We recommend referring to swap devices by UUIDs or labels as shown above
-instead.
-@end table
-
-It is possible to specify a swap file in a file system on a mapped
-device (under @file{/dev/mapper}), provided that the necessary device
-mapping and file system are also specified. @xref{Mapped Devices} and
-@ref{File Systems}.
+@cindex swap devices
+A list of swap spaces. @xref{Swap Space}.
@item @code{users} (default: @code{%base-user-accounts})
@itemx @code{groups} (default: @code{%base-groups})
@@ -14974,7 +14946,8 @@ It is also desirable to encrypt swap space, since swap space may contain
sensitive data. One way to accomplish that is to use a swap file in a
file system on a device mapped via LUKS encryption. In this way, the
swap file is encrypted because the entire device is encrypted.
-@xref{Preparing for Installation,,Disk Partitioning}, for an example.
+@xref{Swap Space}, or @xref{Preparing for Installation,,Disk
+Partitioning}, for an example.
A RAID device formed of the partitions @file{/dev/sda1} and @file{/dev/sdb1}
may be declared as follows:
@@ -15006,6 +14979,106 @@ Devices @file{/dev/mapper/vg0-alpha} and @file{/dev/mapper/vg0-beta} can
then be used as the @code{device} of a @code{file-system} declaration
(@pxref{File Systems}).
+@node Swap Space
+@section Swap Space
+@cindex swap space
+
+Swap space, as it is commonly called, is a disk area specifically
+designated for paging: the process in charge of memory management
+(the Linux kernel or Hurd's default pager) can decide that some memory
+pages stored in RAM which belong to a running program but are unused
+should be stored on disk instead. It unloads those from the RAM,
+freeing up precious fast memory, and writes them to the swap space. If
+the program tries to access that very page, the memory management
+process loads it back into memory for the program to use.
+
+A common misconception about swap is that it is only useful when small
+amounts of RAM are available to the system. However, it should be noted
+that kernels often use all available RAM for disk access caching to make
+I/O faster, and thus paging out unused portions of program memory will
+expand the RAM available for such caching.
+
+For a more detailed description of how memory is managed from the
+viewpoint of a monolithic kernel, @xref{Memory
+Concepts,,, libc, The GNU C Library Reference Manual}.
+
+The Linux kernel has support for swap partitions and swap files: the
+former uses a whole disk partition for paging, whereas the second uses a
+file on a file system for that (the file system driver needs to support
+it). On a comparable setup, both have the same performance, so one
+should consider ease of use when deciding between them. Partitions are
+``simpler'' and do not need file system support, but need to be
+allocated at disk formatting time (logical volumes notwithstanding),
+whereas files can be allocated and deallocated at any time.
+
+Note that swap space is not zeroed on shutdown, so sensitive data (such
+as passwords) may linger on it if it was paged out. As such, you should
+consider having your swap reside on an encrypted device (@pxref{Mapped
+Devices}).
+
+@deftp {Data Type} swap-space
+Objects of this type represent swap spaces. They contain the following
+members:
+
+@table @asis
+@item @code{target}
+The device or file to use, either a UUID, a @code{file-system-label} or
+a string, as in the definition of a @code{file-system} (@pxref{File
+Systems}).
+
+@item @code{dependencies} (default: @code{'()})
+A list of @code{file-system} or @code{mapped-device} objects, upon which
+the availability of the space depends. Note that just like for
+@code{file-system} objects, dependencies which are needed for boot and
+mounted in early userspace are not managed by the Shepherd, and so
+automatically filtered out for you.
+
+@item @code{priority} (default: @code{#f})
+Only supported by the Linux kernel. Either @code{#f} to disable swap
+priority, or an integer between 0 and 32767. The kernel will first use
+swap spaces of higher priority when paging, and use same priority spaces
+on a round-robin basis. The kernel will use swap spaces without a set
+priority after prioritized spaces, and in the order that they appeared in
+(not round-robin).
+
+@item @code{discard?} (default: @code{#f})
+Only supported by the Linux kernel. When true, the kernel will notify
+the disk controller of discarded pages, for example with the TRIM
+operation on Solid State Drives.
+
+@end table
+@end deftp
+
+Here are some examples:
+
+@lisp
+(swap-space (target (uuid "4dab5feb-d176-45de-b287-9b0a6e4c01cb")))
+@end lisp
+
+Use the swap partition with the given UUID@. You can learn the UUID of a
+Linux swap partition by running @command{swaplabel @var{device}}, where
+@var{device} is the @file{/dev} file name of that partition.
+
+@lisp
+(swap-space
+ (target (file-system-label "swap"))
+ (dependencies (list lvm-device)))
+@end lisp
+
+Use the partition with label @code{swap}, which can be found after the
+@var{lvm-device} mapped device has been opened. Again, the
+@command{swaplabel} command allows you to view and change the label of a
+Linux swap partition.
+
+@lisp
+(swap-space
+ (target "/btrfs/swapfile")
+ (dependencies (list btrfs-fs)))
+@end lisp
+
+Use the file @file{/btrfs/swapfile} as swap space, which is present on the
+@var{btrfs-fs} filesystem.
+
@node User Accounts
@section User Accounts