ZFS-PROGRAM
Section: Maintenance Commands (8)
Index
- NAME
-
- SYNOPSIS
-
- DESCRIPTION
-
- OPTIONS
-
- LUA INTERFACE
-
- Arguments
-
- Return Values
-
- Fatal Errors
-
- Lua to C Value Conversion
-
- LUA STANDARD LIBRARY
-
- ZFS API
-
- Function Arguments
-
- Function Return Values
-
- API Functions
-
- EXAMPLES
-
- Example 1
-
- Example 2
-
- Example 3
-
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BSD mandoc
NAME
zfs program
- executes ZFS channel programs
SYNOPSIS
zfs program
[-jn
]
[-t instruction-limit
]
[-m memory-limit
]
pool
script
DESCRIPTION
The ZFS channel program interface allows ZFS administrative operations to be
run programmatically as a Lua script.
The entire script is executed atomically, with no other administrative
operations taking effect concurrently.
A library of ZFS calls is made available to channel program scripts.
Channel programs may only be run with root privileges.
A modified version of the Lua 5.2 interpreter is used to run channel program
scripts.
The Lua 5.2 manual can be found at:
Lk http://www.lua.org/manual/5.2/
The channel program given by
script
will be run on
pool
and any attempts to access or modify other pools will cause an error.
OPTIONS
- -j
-
Display channel program output in JSON format. When this flag is specified and
standard output is empty - channel program encountered an error. The details of
such an error will be printed to standard error in plain text.
- -n
-
Executes a read-only channel program, which runs faster.
The program cannot change on-disk state by calling functions from the
zfs.sync submodule.
The program can be used to gather information such as properties and
determining if changes would succeed (zfs.check.*).
Without this flag, all pending changes must be synced to disk before a
channel program can complete.
- -t instruction-limit
-
Limit the number of Lua instructions to execute.
If a channel program executes more than the specified number of instructions,
it will be stopped and an error will be returned.
The default limit is 10 million instructions, and it can be set to a maximum of
100 million instructions.
- -m memory-limit
-
Memory limit, in bytes.
If a channel program attempts to allocate more memory than the given limit, it
will be stopped and an error returned.
The default memory limit is 10 MB, and can be set to a maximum of 100 MB.
All remaining argument strings will be passed directly to the Lua script as
described in the
Sx LUA INTERFACE
section below.
LUA INTERFACE
A channel program can be invoked either from the command line, or via a library
call to
Fn lzc_channel_program .
Arguments
Arguments passed to the channel program are converted to a Lua table.
If invoked from the command line, extra arguments to the Lua script will be
accessible as an array stored in the argument table with the key 'argv':
args = ...
argv = args["argv"]
-- argv == {1="arg1", 2="arg2", ...}
If invoked from the libZFS interface, an arbitrary argument list can be
passed to the channel program, which is accessible via the same
"..." syntax in Lua:
args = ...
-- args == {"foo"="bar", "baz"={...}, ...}
Note that because Lua arrays are 1-indexed, arrays passed to Lua from the
libZFS interface will have their indices incremented by 1.
That is, the element
in
arr[0]
in a C array passed to a channel program will be stored in
arr[1]
when accessed from Lua.
Return Values
Lua return statements take the form:
return ret0, ret1, ret2, ...
Return statements returning multiple values are permitted internally in a
channel program script, but attempting to return more than one value from the
top level of the channel program is not permitted and will throw an error.
However, tables containing multiple values can still be returned.
If invoked from the command line, a return statement:
a = {foo="bar", baz=2}
return a
Will be output formatted as:
Channel program fully executed with return value:
return:
baz: 2
foo: 'bar'
Fatal Errors
If the channel program encounters a fatal error while running, a non-zero exit
status will be returned.
If more information about the error is available, a singleton list will be
returned detailing the error:
error: "error string, including Lua stack trace"
If a fatal error is returned, the channel program may have not executed at all,
may have partially executed, or may have fully executed but failed to pass a
return value back to userland.
If the channel program exhausts an instruction or memory limit, a fatal error
will be generated and the program will be stopped, leaving the program partially
executed.
No attempt is made to reverse or undo any operations already performed.
Note that because both the instruction count and amount of memory used by a
channel program are deterministic when run against the same inputs and
filesystem state, as long as a channel program has run successfully once, you
can guarantee that it will finish successfully against a similar size system.
If a channel program attempts to return too large a value, the program will
fully execute but exit with a nonzero status code and no return value.
Note:
ZFS API functions do not generate Fatal Errors when correctly invoked, they
return an error code and the channel program continues executing.
See the
Sx ZFS API
section below for function-specific details on error return codes.
Lua to C Value Conversion
When invoking a channel program via the libZFS interface, it is necessary to
translate arguments and return values from Lua values to their C equivalents,
and vice-versa.
There is a correspondence between nvlist values in C and Lua tables.
A Lua table which is returned from the channel program will be recursively
converted to an nvlist, with table values converted to their natural
equivalents:
string -> string
number -> int64
boolean -> boolean_value
nil -> boolean (no value)
table -> nvlist
Likewise, table keys are replaced by string equivalents as follows:
string -> no change
number -> signed decimal string ("%lld")
boolean -> "true" | "false"
Any collision of table key strings (for example, the string "true" and a
true boolean value) will cause a fatal error.
Lua numbers are represented internally as signed 64-bit integers.
LUA STANDARD LIBRARY
The following Lua built-in base library functions are available:
assert rawlen
collectgarbage rawget
error rawset
getmetatable select
ipairs setmetatable
next tonumber
pairs tostring
rawequal type
All functions in the
coroutine
string
and
table
built-in submodules are also available.
A complete list and documentation of these modules is available in the Lua
manual.
The following functions base library functions have been disabled and are
not available for use in channel programs:
dofile
loadfile
load
pcall
print
xpcall
ZFS API
Function Arguments
Each API function takes a fixed set of required positional arguments and
optional keyword arguments.
For example, the destroy function takes a single positional string argument
(the name of the dataset to destroy) and an optional "defer" keyword boolean
argument.
When using parentheses to specify the arguments to a Lua function, only
positional arguments can be used:
zfs.sync.destroy("rpool@snap")
To use keyword arguments, functions must be called with a single argument that
is a Lua table containing entries mapping integers to positional arguments and
strings to keyword arguments:
zfs.sync.destroy({1="rpool@snap", defer=true})
The Lua language allows curly braces to be used in place of parenthesis as
syntactic sugar for this calling convention:
zfs.sync.snapshot{"rpool@snap", defer=true}
Function Return Values
If an API function succeeds, it returns 0.
If it fails, it returns an error code and the channel program continues
executing.
API functions do not generate Fatal Errors except in the case of an
unrecoverable internal file system error.
In addition to returning an error code, some functions also return extra
details describing what caused the error.
This extra description is given as a second return value, and will always be a
Lua table, or Nil if no error details were returned.
Different keys will exist in the error details table depending on the function
and error case.
Any such function may be called expecting a single return value:
errno = zfs.sync.promote(dataset)
Or, the error details can be retrieved:
errno, details = zfs.sync.promote(dataset)
if (errno == EEXIST) then
assert(details ~= Nil)
list_of_conflicting_snapshots = details
end
The following global aliases for API function error return codes are defined
for use in channel programs:
EPERM ECHILD ENODEV ENOSPC
ENOENT EAGAIN ENOTDIR ESPIPE
ESRCH ENOMEM EISDIR EROFS
EINTR EACCES EINVAL EMLINK
EIO EFAULT ENFILE EPIPE
ENXIO ENOTBLK EMFILE EDOM
E2BIG EBUSY ENOTTY ERANGE
ENOEXEC EEXIST ETXTBSY EDQUOT
EBADF EXDEV EFBIG
API Functions
For detailed descriptions of the exact behavior of any zfs administrative
operations, see the main
zfs(1)
manual page.
- zfs.debug(msg)
-
Record a debug message in the zfs_dbgmsg log.
A log of these messages can be printed via mdb's "::zfs_dbgmsg" command, or
can be monitored live by running:
dtrace -n 'zfs-dbgmsg{trace(stringof(arg0))}'
msg (string)
Debug message to be printed.
- zfs.exists(dataset)
-
Returns true if the given dataset exists, or false if it doesn't.
A fatal error will be thrown if the dataset is not in the target pool.
That is, in a channel program running on rpool,
zfs.exists("rpool/nonexistent_fs") returns false, but
zfs.exists("somepool/fs_that_may_exist") will error.
dataset (string)
Dataset to check for existence.
Must be in the target pool.
- zfs.get_prop(dataset, property)
-
Returns two values.
First, a string, number or table containing the property value for the given
dataset.
Second, a string containing the source of the property (i.e. the name of the
dataset in which it was set or nil if it is readonly).
Throws a Lua error if the dataset is invalid or the property doesn't exist.
Note that Lua only supports int64 number types whereas ZFS number properties
are uint64.
This means very large values (like guid) may wrap around and appear negative.
dataset (string)
Filesystem or snapshot path to retrieve properties from.
property (string)
Name of property to retrieve.
All filesystem, snapshot and volume properties are supported except
for 'mounted' and 'iscsioptions.'
Also supports the 'written@snap' and 'written#bookmark' properties and
the '<user|group><quota|used>@id' properties, though the id must be in numeric
form.
- zfs.sync submodule
-
The sync submodule contains functions that modify the on-disk state.
They are executed in "syncing context".
The available sync submodule functions are as follows:
- zfs.sync.destroy(dataset, [defer=true|false])
-
Destroy the given dataset.
Returns 0 on successful destroy, or a nonzero error code if the dataset could
not be destroyed (for example, if the dataset has any active children or
clones).
dataset (string)
Filesystem or snapshot to be destroyed.
[optional] defer (boolean)
Valid only for destroying snapshots.
If set to true, and the snapshot has holds or clones, allows the snapshot to be
marked for deferred deletion rather than failing.
- zfs.sync.promote(dataset)
-
Promote the given clone to a filesystem.
Returns 0 on successful promotion, or a nonzero error code otherwise.
If EEXIST is returned, the second return value will be an array of the clone's
snapshots whose names collide with snapshots of the parent filesystem.
dataset (string)
Clone to be promoted.
- zfs.sync.rollback(filesystem)
-
Rollback to the previous snapshot for a dataset.
Returns 0 on successful rollback, or a nonzero error code otherwise.
Rollbacks can be performed on filesystems or zvols, but not on snapshots
or mounted datasets.
EBUSY is returned in the case where the filesystem is mounted.
filesystem (string)
Filesystem to rollback.
- zfs.sync.snapshot(dataset)
-
Create a snapshot of a filesystem.
Returns 0 if the snapshot was successfully created,
and a nonzero error code otherwise.
Note: Taking a snapshot will fail on any pool older than legacy version 27.
To enable taking snapshots from ZCP scripts, the pool must be upgraded.
dataset (string)
Name of snapshot to create.
- zfs.check submodule
-
For each function in the zfs.sync submodule, there is a corresponding zfs.check
function which performs a "dry run" of the same operation.
Each takes the same arguments as its zfs.sync counterpart and returns 0 if the
operation would succeed, or a non-zero error code if it would fail, along with
any other error details.
That is, each has the same behavior as the corresponding sync function except
for actually executing the requested change.
For example,
zfs.check.destroy(fs)
returns 0 if
zfs.sync.destroy(fs)
would successfully destroy the dataset.
The available zfs.check functions are:
- zfs.check.destroy(dataset, [defer=true|false])
-
- zfs.check.promote(dataset)
-
- zfs.check.rollback(filesystem)
-
- zfs.check.snapshot(dataset)
-
- zfs.list submodule
-
The zfs.list submodule provides functions for iterating over datasets and
properties.
Rather than returning tables, these functions act as Lua iterators, and are
generally used as follows:
for child in zfs.list.children("rpool") do
...
end
The available zfs.list functions are:
- zfs.list.clones(snapshot)
-
Iterate through all clones of the given snapshot.
snapshot (string)
Must be a valid snapshot path in the current pool.
- zfs.list.snapshots(dataset)
-
Iterate through all snapshots of the given dataset.
Each snapshot is returned as a string containing the full dataset name, e.g.
"pool/fs@snap".
dataset (string)
Must be a valid filesystem or volume.
- zfs.list.children(dataset)
-
Iterate through all direct children of the given dataset.
Each child is returned as a string containing the full dataset name, e.g.
"pool/fs/child".
dataset (string)
Must be a valid filesystem or volume.
- zfs.list.properties(dataset)
-
Iterate through all user properties for the given dataset.
dataset (string)
Must be a valid filesystem, snapshot, or volume.
- zfs.list.system_properties(dataset)
-
Returns an array of strings, the names of the valid system (non-user defined)
properties for the given dataset.
Throws a Lua error if the dataset is invalid.
dataset (string)
Must be a valid filesystem, snapshot or volume.
EXAMPLES
Example 1
The following channel program recursively destroys a filesystem and all its
snapshots and children in a naive manner.
Note that this does not involve any error handling or reporting.
function destroy_recursive(root)
for child in zfs.list.children(root) do
destroy_recursive(child)
end
for snap in zfs.list.snapshots(root) do
zfs.sync.destroy(snap)
end
zfs.sync.destroy(root)
end
destroy_recursive("pool/somefs")
Example 2
A more verbose and robust version of the same channel program, which
properly detects and reports errors, and also takes the dataset to destroy
as a command line argument, would be as follows:
succeeded = {}
failed = {}
function destroy_recursive(root)
for child in zfs.list.children(root) do
destroy_recursive(child)
end
for snap in zfs.list.snapshots(root) do
err = zfs.sync.destroy(snap)
if (err ~= 0) then
failed[snap] = err
else
succeeded[snap] = err
end
end
err = zfs.sync.destroy(root)
if (err ~= 0) then
failed[root] = err
else
succeeded[root] = err
end
end
args = ...
argv = args["argv"]
destroy_recursive(argv[1])
results = {}
results["succeeded"] = succeeded
results["failed"] = failed
return results
Example 3
The following function performs a forced promote operation by attempting to
promote the given clone and destroying any conflicting snapshots.
function force_promote(ds)
errno, details = zfs.check.promote(ds)
if (errno == EEXIST) then
assert(details ~= Nil)
for i, snap in ipairs(details) do
zfs.sync.destroy(ds .. "@" .. snap)
end
elseif (errno ~= 0) then
return errno
end
return zfs.sync.promote(ds)
end