9fd37f951b
- complete the function btrfs_err_str adding some missing cases - sync the enum btrfs_err_code (in libbtrfsutil/btrfs.h) with the rest of the codes (user space and kernel space). - add missing fields to btrfs_raid_array[] for raid1c[34] Signed-off-by: Goffredo Baroncelli <kreijack@inwind.it> Signed-off-by: David Sterba <dsterba@suse.com> |
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.. | ||
python | ||
COPYING | ||
COPYING.LESSER | ||
README.md | ||
btrfs.h | ||
btrfs_tree.h | ||
btrfsutil.h | ||
btrfsutil_internal.h | ||
errors.c | ||
filesystem.c | ||
qgroup.c | ||
stubs.c | ||
stubs.h | ||
subvolume.c |
README.md
libbtrfsutil
libbtrfsutil is a library for managing Btrfs filesystems. It is licensed under
the LGPL. libbtrfsutil provides interfaces for a subset of the operations
offered by the btrfs
command line utility. It also includes official Python
bindings (Python 3 only).
API Overview
This section provides an overview of the interfaces available in libbtrfsutil
as well as example usages. Detailed documentation for the C API can be found in
btrfsutil.h
. Detailed documentation for the Python bindings is
available with pydoc3 btrfsutil
or in the interpreter:
>>> import btrfsutil
>>> help(btrfsutil)
Many functions in the C API have a variant taking a path and a variant taking a
file descriptor. The latter has the same name as the former with an _fd
suffix. The Python bindings for these functions can take a path, a file object,
or a file descriptor.
Error handling is omitted from most of these examples for brevity. Please handle errors in production code.
Error Handling
In the C API, all functions that can return an error return an enum btrfs_util_error
and set errno
. BTRFS_UTIL_OK
(zero) is returned on
success. btrfs_util_strerror()
converts an error code to a string
description suitable for human-friendly error reporting.
enum btrfs_util_err err;
err = btrfs_util_sync("/");
if (err)
fprintf("stderr, %s: %m\n", btrfs_util_strerror(err));
In the Python bindings, functions may raise a BtrfsUtilError
, which is a
subclass of OSError
with an added btrfsutilerror
error code member. Error
codes are available as ERROR_*
constants.
try:
btrfsutil.sync('/')
except btrfsutil.BtrfsUtilError as e:
print(e, file=sys.stderr)
Filesystem Operations
There are several operations which act on the entire filesystem.
Sync
Btrfs can commit all caches for a specific filesystem to disk.
btrfs_util_sync()
forces a sync on the filesystem containing the given file
and waits for it to complete.
btrfs_wait_sync()
waits for a previously started transaction to complete. The
transaction is specified by ID, which may be zero to indicate the current
transaction.
btrfs_start_sync()
asynchronously starts a sync and returns a transaction ID
which can then be passed to btrfs_wait_sync()
.
uint64_t transid;
btrfs_util_sync("/");
btrfs_util_start_sync("/", &transid);
btrfs_util_wait_sync("/", &transid);
btrfs_util_wait_sync("/", 0);
btrfsutil.sync('/')
transid = btrfsutil.start_sync('/')
btrfsutil.wait_sync('/', transid)
btrfsutil.wait_sync('/') # equivalent to wait_sync('/', 0)
All of these functions have _fd
variants.
The equivalent btrfs-progs
command is btrfs filesystem sync
.
Subvolume Operations
Functions which take a file and a subvolume ID can be used in two ways. If zero is given as the subvolume ID, then the given file is used as the subvolume. Otherwise, the given file can be any file in the filesystem, and the subvolume with the given ID is used.
Subvolume Information
btrfs_util_is_subvolume()
returns whether a given file is a subvolume.
btrfs_util_subvolume_id()
returns the ID of the subvolume containing the
given file.
enum btrfs_util_error err;
err = btrfs_util_is_subvolume("/subvol");
if (!err)
printf("Subvolume\n");
else if (err == BTRFS_UTIL_ERROR_NOT_BTRFS || err == BTRFS_UTIL_ERROR_NOT_SUBVOLUME)
printf("Not subvolume\n");
uint64_t id;
btrfs_util_subvolume_id("/subvol", &id);
if btrfsutil.is_subvolume('/subvol'):
print('Subvolume')
else:
print('Not subvolume')
id_ = btrfsutil.subvolume_id('/subvol')
btrfs_util_subvolume_path()
returns the path of the subvolume with the given
ID relative to the filesystem root. This requires CAP_SYS_ADMIN
. The path
must be freed with free()
.
char *path;
btrfs_util_subvolume_path("/", 256, &path);
free(path);
btrfs_util_subvolume_path("/subvol", 0, &path);
free(path);
path = btrfsutil.subvolume_path('/', 256)
path = btrfsutil.subvolume_path('/subvol') # equivalent to subvolume_path('/subvol', 0)
btrfs_util_subvolume_info()
returns information (including ID, parent ID,
UUID) about a subvolume. In the C API, this is returned as a struct btrfs_util_subvolume_info
. The Python bindings use a SubvolumeInfo
object.
This requires CAP_SYS_ADMIN
unless the given subvolume ID is zero and the
kernel supports the BTRFS_IOC_GET_SUBVOL_INFO
ioctl (added in 4.18).
The equivalent btrfs-progs
command is btrfs subvolume show
.
struct btrfs_util_subvolume_info info;
btrfs_util_subvolume_info("/", 256, &info);
btrfs_util_subvolume_info("/subvol", 0, &info);
info = btrfsutil.subvolume_info('/', 256)
info = btrfsutil.subvolume_info('/subvol') # equivalent to subvolume_info('/subvol', 0)
All of these functions have _fd
variants.
Enumeration
An iterator interface is provided for enumerating subvolumes on a filesystem.
In the C API, a struct btrfs_util_subvolume_iterator
is initialized by
btrfs_util_create_subvolume_iterator()
, which takes a top subvolume to
enumerate under and flags. Currently, the only flag is to specify post-order
traversal instead of the default pre-order. This function has an _fd
variant.
btrfs_util_destroy_subvolume_iterator()
must be called to free a previously
created struct btrfs_util_subvolume_iterator
.
btrfs_util_subvolume_iterator_fd()
returns the file descriptor opened by
btrfs_util_create_subvolume_iterator()
which can be used for other functions.
btrfs_util_subvolume_iterator_next()
returns the path (relative to the top
subvolume that the iterator was created with) and ID of the next subvolume.
btrfs_util_subvolume_iterator_next_info()
returns a struct btrfs_subvolume_info
instead of the ID. It is slightly more efficient than
doing separate btrfs_util_subvolume_iterator_next()
and
btrfs_util_subvolume_info()
calls if the subvolume information is needed. The
path returned by these functions must be freed with free()
. When there are no
more subvolumes, they return BTRFS_UTIL_ERROR_STOP_ITERATION
.
struct btrfs_util_subvolume_iterator *iter;
enum btrfs_util_error err;
char *path;
uint64_t id;
struct btrfs_util_subvolume_info info;
btrfs_util_create_subvolume_iterator("/", 256, 0, &iter);
/*
* This is just an example use-case for btrfs_util_subvolume_iterator_fd(). It
* is not necessary.
*/
btrfs_util_sync_fd(btrfs_util_subvolume_iterator_fd(iter));
while (!(err = btrfs_util_subvolume_iterator_next(iter, &path, &id))) {
printf("%" PRIu64 " %s\n", id, path);
free(path);
}
btrfs_util_destroy_subvolume_iterator(iter);
btrfs_util_create_subvolume_iterator("/subvol", 0,
BTRFS_UTIL_SUBVOLUME_ITERATOR_POST_ORDER,
&iter);
while (!(err = btrfs_util_subvolume_iterator_next_info(iter, &path, &info))) {
printf("%" PRIu64 " %" PRIu64 " %s\n", info.id, info.parent_id, path);
free(path);
}
btrfs_util_destroy_subvolume_iterator(iter);
The Python bindings provide this interface as an iterable SubvolumeIterator
class. It should be used as a context manager to ensure that the underlying
file descriptor is closed. Alternatively, it has a close()
method for closing
explicitly. It also has a fileno()
method to get the underlying file
descriptor.
with btrfsutil.SubvolumeIterator('/', 256) as it:
# This is just an example use-case for fileno(). It is not necessary.
btrfsutil.sync(it.fileno())
for path, id_ in it:
print(id_, path)
it = btrfsutil.SubvolumeIterator('/subvol', info=True, post_order=True)
try:
for path, info in it:
print(info.id, info.parent_id, path)
finally:
it.close()
This interface requires CAP_SYS_ADMIN
unless the given top subvolume ID is
zero and the kernel supports the BTRFS_IOC_GET_SUBVOL_ROOTREF
and
BTRFS_IOC_INO_LOOKUP_USER
ioctls (added in 4.18). In the unprivileged case,
subvolumes which cannot be accessed are skipped.
The equivalent btrfs-progs
command is btrfs subvolume list
.
Creation
btrfs_util_create_subvolume()
creates a new subvolume at the given path. The
subvolume can be created asynchronously and inherit from quota groups
(qgroups).
Qgroups to inherit are specified with a struct btrfs_util_qgroup_inherit
,
which is created by btrfs_util_create_qgroup_inherit()
and freed by
btrfs_util_destroy_qgroup_inherit()
. Qgroups are added with
btrfs_util_qgroup_inherit_add_group()
. The list of added groups can be
retrieved with btrfs_util_qgroup_inherit_get_groups()
; note that the returned
array does not need to be freed and is no longer valid when the struct btrfs_util_qgroup_inherit
is freed.
The Python bindings provide a QgroupInherit
class. It has an add_group()
method and a groups
member, which is a list of ints.
btrfs_util_create_subvolume("/subvol2", 0, NULL, NULL);
uint64_t async_transid;
btrfs_util_create_subvolume("/subvol2", 0, &async_transid, NULL);
btrfs_util_wait_sync("/", async_transid);
struct btrfs_util_qgroup_inherit *qgroups;
btrfs_util_create_qgroup_inherit(0, &qgroups);
btrfs_util_qgroup_inherit_add_group(&qgroups, 256);
btrfs_util_create_subvolume("/subvol2", 0, NULL, qgroups);
btrfs_util_destroy_qgroup_inherit(qgroups);
btrfsutil.create_subvolume('/subvol2')
async_transid = btrfsutil.create_subvolume('/subvol2', async_=True)
btrfsutil.wait_sync('/', async_transid)
qgroups = btrfsutil.QgroupInherit()
qgroups.add_group(256)
btrfsutil.create_subvolume('/subvol2', qgroup_inherit=qgroups)
The C API has an _fd
variant which takes a name and a file descriptor
referring to the parent directory.
The equivalent btrfs-progs
command is btrfs subvolume create
.
Snapshotting
Snapshots are created with btrfs_util_create_snapshot()
, which takes a source
path, a destination path, and flags. It can also be asynchronous and inherit
from quota groups; see subvolume creation.
Snapshot creation can be recursive, in which case subvolumes underneath the subvolume being snapshotted will also be snapshotted onto the same location in the new snapshot (note that this is implemented in userspace non-atomically and has the same capability requirements as a subvolume iterator). The newly created snapshot can also be read-only, but not if doing a recursive snapshot.
btrfs_util_create_snapshot("/subvol", "/snapshot", 0, NULL, NULL);
btrfs_util_create_snapshot("/nested_subvol", "/nested_snapshot",
BTRFS_UTIL_CREATE_SNAPSHOT_RECURSIVE, NULL, NULL);
btrfs_util_create_snapshot("/subvol", "/rosnapshot",
BTRFS_UTIL_CREATE_SNAPSHOT_READ_ONLY, NULL, NULL);
btrfsutil.create_snapshot('/subvol', '/snapshot')
btrfsutil.create_snapshot('/nested_subvol', '/nested_snapshot', recursive=True)
btrfsutil.create_snapshot('/subvol', '/rosnapshot', read_only=True)
The C API has two _fd
variants. btrfs_util_create_snapshot_fd()
takes the
source subvolume as a file descriptor. btrfs_util_create_snapshot_fd2()
takes
the source subvolume as a file descriptor and the destination as a name and
parent file descriptor.
The equivalent btrfs-progs
command is btrfs subvolume snapshot
.
Deletion
btrfs_util_delete_subvolume()
takes a subvolume to delete and flags. This
requires CAP_SYS_ADMIN
if the filesystem was not mounted with
user_subvol_rm_allowed
. Deletion may be recursive, in which case all
subvolumes beneath the given subvolume are deleted before the given subvolume
is deleted. This is implemented in user-space non-atomically and has the same
capability requirements as a subvolume iterator.
btrfs_util_delete_subvolume("/subvol", 0);
btrfs_util_delete_subvolume("/nested_subvol",
BTRFS_UTIL_DELETE_SUBVOLUME_RECURSIVE);
btrfsutil.delete_subvolume('/subvol')
btrfsutil.delete_subvolume('/nested_subvol', recursive=True)
The C API has an _fd
variant which takes a name and a file descriptor
referring to the parent directory.
The equivalent btrfs-progs
command is btrfs subvolume delete
.
Deleted Subvolumes
Btrfs lazily cleans up deleted subvolumes. btrfs_util_deleted_subvolumes()
returns an array of subvolume IDs which have been deleted but not yet cleaned
up. The returned array should be freed with free()
.
uint64_t *ids;
size_t n; /* Number of returned IDs. */
btrfs_util_deleted_subvolumes("/", &ids, &n);
free(ids);
The Python binding returns a list of ints.
ids = btrfsutil.deleted_subvolumes('/')
This function also has an _fd
variant. It requires CAP_SYS_ADMIN
.
The closest btrfs-progs
command is btrfs subvolume sync
, which waits for
deleted subvolumes to be cleaned up.
Read-Only Flag
Subvolumes can be set to read-only. btrfs_util_get_subvolume_read_only()
returns whether a subvolume is read-only.
btrfs_util_set_subvolume_read_only()
sets the read-only flag to the desired
value.
bool read_only;
btrfs_util_get_subvolume_read_only("/subvol", &read_only);
btrfs_util_set_subvolume_read_only("/subvol", true);
btrfs_util_set_subvolume_read_only("/subvol", false);
read_only = btrfsutil.get_subvolume_read_only('/subvol')
btrfsutil.set_subvolume_read_only('/subvol', True)
btrfsutil.set_subvolume_read_only('/subvol', False)
Both of these functions have _fd
variants.
The equivalent btrfs-progs
commands are btrfs property get
and btrfs property set
with the ro
property.
Default Subvolume
The default subvolume of a filesystem is the subvolume which is mounted when no
subvol
or subvolid
mount option is passed.
btrfs_util_get_default_subvolume()
gets the ID of the default subvolume for
the filesystem containing the given file.
btrfs_util_set_default_subvolume()
sets the default subvolume.
uint64_t id;
btrfs_util_get_default_subvolume("/", &id);
btrfs_util_set_default_subvolume("/", 256);
btrfs_util_set_default_subvolume("/subvol", 0);
id = btrfsutil.get_default_subvolume('/')
btrfsutil.set_default_subvolume('/', 256)
btrfsutil.set_default_subvolume('/subvol') # equivalent to set_default_subvolume('/subvol', 0)
Both of these functions have an _fd
variant. They both require
CAP_SYS_ADMIN
.
The equivalent btrfs-progs
commands are btrfs subvolume get-default
and
btrfs subvolume set-default
.
Development
The development process for btrfs-progs applies.
libbtrfsutil only includes operations that are done through the filesystem and ioctl interface, not operations that modify the filesystem directly (e.g., mkfs or fsck). This is by design but also a legal necessity, as the filesystem implementation is GPL but libbtrfsutil is LGPL. That is also why the libbtrfsutil code is a reimplementation of the btrfs-progs code rather than a refactoring. Be wary of this when porting functionality.
libbtrfsutil is semantically versioned separately from btrfs-progs. It is the maintainers' responsibility to bump the version as needed (at most once per release of btrfs-progs).
A few guidelines:
- All interfaces must be documented in this README and in
btrfsutil.h
using the kernel-doc style - Error codes should be specific about what exactly failed
- Functions should have a path and an fd variant whenever possible
- Spell out terms in function names, etc. rather than abbreviating whenever possible
- Don't require the Btrfs UAPI headers for any interfaces (e.g., instead of
directly exposing a type from
linux/btrfs_tree.h
, abstract it away in a type specific tolibbtrfsutil
) - Preserve API and ABI compatibility at all times (i.e., we don't want to bump the library major version if we don't have to)
- Include Python bindings for all interfaces
- Write tests for all interfaces