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authorMaxim Cournoyer <maxim.cournoyer@gmail.com>2019-07-14 20:50:23 +0900
committerMaxim Cournoyer <maxim.cournoyer@gmail.com>2020-05-20 08:30:35 -0400
commitb460ba7992a0b4af2ddb5927dcf062784539ef7b (patch)
tree4d77d01574da9a7aedf31dc3f16e94d82fa31adb /doc
parentfa35fb58c84d1c1741e4e63c0b37074e35ed2a61 (diff)
downloadguix-b460ba7992a0b4af2ddb5927dcf062784539ef7b.tar.gz
bootloader: grub: Allow booting from a Btrfs subvolume.
* gnu/bootloader/grub.scm (strip-mount-point): Remove procedure.
(normalize-file): Add procedure.
(grub-configuration-file): New BTRFS-SUBVOLUME-FILE-NAME parameter.  When
defined, prepend its value to the kernel and initrd file names, using the
NORMALIZE-FILE procedure.  Adjust the call to EYE-CANDY to pass the
BTRFS-SUBVOLUME-FILE-NAME argument.  Normalize the KEYMAP file as well.
(eye-candy): Add a BTRFS-SUBVOLUME-FILE-NAME parameter, and use it, along with
the NORMALIZE-FILE procedure, to normalize the FONT-FILE and IMAGE nested
variables.  Adjust doc.
* gnu/bootloader/depthcharge.scm (depthcharge-configuration-file): Adapt.
* gnu/bootloader/extlinux.scm (extlinux-configuration-file): Likewise.
* gnu/system/file-systems.scm (btrfs-subvolume?)
(btrfs-store-subvolume-file-name): New procedures.
* gnu/system.scm (operating-system-bootcfg): Specify the Btrfs
subvolume file name the store resides on to the
`operating-system-bootcfg' procedure, using the new
BTRFS-SUBVOLUME-FILE-NAME argument.
* doc/guix.texi (File Systems): Add a Btrfs subsection to document the use of
subvolumes.
* gnu/tests/install.scm (%btrfs-root-on-subvolume-os)
(%btrfs-root-on-subvolume-os-source)
(%btrfs-root-on-subvolume-installation-script)
(%test-btrfs-root-on-subvolume-os): New variables.
Diffstat (limited to 'doc')
-rw-r--r--doc/guix.texi104
1 files changed, 104 insertions, 0 deletions
diff --git a/doc/guix.texi b/doc/guix.texi
index 05f2d595b2..216422fe31 100644
--- a/doc/guix.texi
+++ b/doc/guix.texi
@@ -11782,6 +11782,110 @@ and unmount user-space FUSE file systems.  This requires the
 @code{fuse.ko} kernel module to be loaded.
 @end defvr
 
+@node Btrfs file system
+@subsection Btrfs file system
+
+The Btrfs has special features, such as subvolumes, that merit being
+explained in more details.  The following section attempts to cover
+basic as well as complex uses of a Btrfs file system with the Guix
+System.
+
+In its simplest usage, a Btrfs file system can be described, for
+example, by:
+
+@lisp
+(file-system
+  (mount-point "/home")
+  (type "btrfs")
+  (device (file-system-label "my-home")))
+@end lisp
+
+The example below is more complex, as it makes use of a Btrfs
+subvolume, named @code{rootfs}.  The parent Btrfs file system is labeled
+@code{my-btrfs-pool}, and is located on an encrypted device (hence the
+dependency on @code{mapped-devices}):
+
+@lisp
+(file-system
+  (device (file-system-label "my-btrfs-pool"))
+  (mount-point "/")
+  (type "btrfs")
+  (options "subvol=rootfs")
+  (dependencies mapped-devices))
+@end lisp
+
+Some bootloaders, for example GRUB, only mount a Btrfs partition at its
+top level during the early boot, and rely on their configuration to
+refer to the correct subvolume path within that top level.  The
+bootloaders operating in this way typically produce their configuration
+on a running system where the Btrfs partitions are already mounted and
+where the subvolume information is readily available.  As an example,
+@command{grub-mkconfig}, the configuration generator command shipped
+with GRUB, reads @file{/proc/self/mountinfo} to determine the top-level
+path of a subvolume.
+
+The Guix System produces a bootloader configuration using the operating
+system configuration as its sole input; it is therefore necessary to
+extract the subvolume name on which @file{/gnu/store} lives (if any)
+from that operating system configuration.  To better illustrate,
+consider a subvolume named 'rootfs' which contains the root file system
+data.  In such situation, the GRUB bootloader would only see the top
+level of the root Btrfs partition, e.g.:
+
+@example
+/                   (top level)
+├── rootfs          (subvolume directory)
+    ├── gnu         (normal directory)
+        ├── store   (normal directory)
+[...]
+@end example
+
+Thus, the subvolume name must be prepended to the @file{/gnu/store} path
+of the kernel, initrd binaries and any other files referred to in the
+GRUB configuration that must be found during the early boot.
+
+The next example shows a nested hierarchy of subvolumes and
+directories:
+
+@example
+/                   (top level)
+├── rootfs          (subvolume)
+    ├── gnu         (normal directory)
+        ├── store   (subvolume)
+[...]
+@end example
+
+This scenario would work without mounting the 'store' subvolume.
+Mounting 'rootfs' is sufficient, since the subvolume name matches its
+intended mount point in the file system hierarchy.  Alternatively, the
+'store' subvolume could be referred to by setting the @code{subvol}
+option to either @code{/rootfs/gnu/store} or @code{rootfs/gnu/store}.
+
+Finally, a more contrived example of nested subvolumes:
+
+@example
+/                           (top level)
+├── root-snapshots          (subvolume)
+    ├── root-current        (subvolume)
+        ├── guix-store      (subvolume)
+[...]
+@end example
+
+Here, the 'guix-store' subvolume doesn't match its intended mount point,
+so it is necessary to mount it.  The subvolume must be fully specified,
+by passing its file name to the @code{subvol} option.  To illustrate,
+the 'guix-store' subvolume could be mounted on @file{/gnu/store} by using
+a file system declaration such as:
+
+@lisp
+(file-system
+  (device (file-system-label "btrfs-pool-1"))
+  (mount-point "/gnu/store")
+  (type "btrfs")
+  (options "subvol=root-snapshots/root-current/guix-store,\
+compress-force=zstd,space_cache=v2"))
+@end lisp
+
 @node Mapped Devices
 @section Mapped Devices