5 guestfs - Library for accessing and modifying virtual machine images
11 guestfs_h *handle = guestfs_create ();
12 guestfs_add_drive (handle, "guest.img");
13 guestfs_launch (handle);
14 guestfs_wait_ready (handle);
15 guestfs_mount (handle, "/dev/sda1", "/");
16 guestfs_touch (handle, "/hello");
17 guestfs_sync (handle);
18 guestfs_close (handle);
22 Libguestfs is a library for accessing and modifying guest disk images.
23 Amongst the things this is good for: making batch configuration
24 changes to guests, getting disk used/free statistics (see also:
25 virt-df), migrating between virtualization systems (see also:
26 virt-p2v), performing partial backups, performing partial guest
27 clones, cloning guests and changing registry/UUID/hostname info, and
30 Libguestfs uses Linux kernel and qemu code, and can access any type of
31 guest filesystem that Linux and qemu can, including but not limited
32 to: ext2/3/4, btrfs, FAT and NTFS, LVM, many different disk partition
33 schemes, qcow, qcow2, vmdk.
35 Libguestfs provides ways to enumerate guest storage (eg. partitions,
36 LVs, what filesystem is in each LV, etc.). It can also run commands
37 in the context of the guest. Also you can access filesystems over FTP.
39 Libguestfs is a library that can be linked with C and C++ management
40 programs (or management programs written in other languages, if people
41 contribute the language bindings). You can also use it from shell
42 scripts or the command line.
44 You don't need to be root to use libguestfs, although obviously you do
45 need enough permissions to access the disk images.
47 =head1 CONNECTION MANAGEMENT
49 If you are using the high-level API, then you should call the
50 functions in the following order:
52 guestfs_h *handle = guestfs_create ();
54 guestfs_add_drive (handle, "guest.img");
55 /* call guestfs_add_drive additional times if the guest has
59 guestfs_launch (handle);
60 guestfs_wait_ready (handle);
62 /* now you can examine what partitions, LVs etc are available
63 * you have to mount / at least
65 guestfs_mount (handle, "/dev/sda1", "/");
67 /* now you can perform actions on the guest disk image */
68 guestfs_touch (handle, "/hello");
70 /* you only need to call guestfs_sync if you have made
71 * changes to the guest image
73 guestfs_sync (handle);
75 guestfs_close (handle);
77 C<guestfs_wait_ready> and all of the actions including C<guestfs_sync>
78 are blocking calls. You can use the low-level event API to do
79 non-blocking operations instead.
81 All functions that return integers, return C<-1> on error. See
82 section ERROR HANDLING below for how to handle errors.
86 C<guestfs_h> is the opaque type representing a connection handle.
87 Create a handle by calling C<guestfs_create>. Call C<guestfs_close>
88 to free the handle and release all resources used.
90 Handles and operations on handles are not thread safe. However you
91 can use a separate handle for each thread (but not on the same disk
96 guestfs_h *guestfs_create (void);
98 Create a connection handle.
100 You have to call C<guestfs_add_drive> on the handle at least once.
101 See CONFIGURATION MANAGEMENT section below.
103 This function returns a non-NULL pointer to a handle on success or
106 After configuring the handle, you have to call C<guestfs_launch> and
107 C<guestfs_wait_ready>.
109 You may also want to configure error handling for the handle. See
110 ERROR HANDLING section below.
114 void guestfs_close (guestfs_h *handle);
116 This closes the connection handle and frees up all resources used.
118 =head2 guestfs_launch, guestfs_wait_ready
120 int guestfs_launch (guestfs_h *handle);
121 int guestfs_wait_ready (guestfs_h *handle);
123 Internally libguestfs is implemented by running a virtual machine
124 using L<qemu(1)>. These calls are necessary in order to boot the
125 virtual machine. More discussion of this is available in the section
126 STATE MACHINE AND LOW-LEVEL EVENT API below.
128 You should call these two functions after configuring the handle
129 (eg. adding drives) but before performing any actions.
131 =head2 guestfs_kill_subprocess
133 int guestfs_kill_subprocess (guestfs_h *handle);
135 This kills the qemu subprocess. You should never need to call this.
137 =head1 CONFIGURATION MANAGEMENT
139 The configuration functions allow you to configure which drive images
140 will be examined or modified, and set other aspects of the L<qemu(1)>
141 virtual machine that we will be running. You need to call only
142 C<guestfs_add_drive> at least once for each guest image that you want
145 =head2 guestfs_add_drive
147 int guestfs_add_drive (guestfs_h *handle, const char *filename);
149 This function adds a virtual machine disk image C<filename> to the
150 guest. The first time you call this function, the disk appears as IDE
151 disk 0 (C</dev/sda>) in the guest, the second time as C</dev/sdb>, and
154 You don't necessarily need to be root when using libguestfs. However
155 you obviously do need sufficient permissions to access the filename
156 for whatever operations you want to perform (ie. read access if you
157 just want to read the image or write access if you want to modify the
160 This is equivalent to the qemu parameter C<-drive file=filename>.
162 =head2 guestfs_add_cdrom
164 int guestfs_add_cdrom (guestfs_h *handle, const char *filename);
166 This function adds a virtual CD-ROM disk image to the guest.
168 This is equivalent to the qemu parameter C<-cdrom filename>.
170 =head2 guestfs_config
172 int guestfs_config (guestfs_h *handle,
173 const char *qemu_param, const char *qemu_value);
175 This can be used to add arbitrary qemu command line parameters
176 of the form C<-param value>. Actually it's not quite arbitrary - we
177 prevent you from setting some parameters which would interfere with
178 parameters that we use.
180 The first character of C<qemu_param> string must be a C<-> (dash).
182 C<qemu_value> can be NULL.
184 =head1 ERROR HANDLING
186 The convention in all functions that return C<int> is that they return
187 C<-1> to indicate an error. You can get additional information on
188 errors by calling C<guestfs_set_error_handler>. The default error
189 handler prints the information string to C<stderr>.
191 Out of memory errors are handled differently. The default action is
192 to call L<abort(3)>. If this is undesirable, then you can set a
193 handler using C<guestfs_set_out_of_memory_handler>.
195 =head2 guestfs_set_error_handler
197 typedef void (*guestfs_error_handler_cb) (guestfs_h *handle,
200 void guestfs_set_error_handler (guestfs_h *handle,
201 guestfs_error_handler_cb cb,
204 The callback C<cb> will be called if there is an error. The
205 parameters passed to the callback are an opaque data pointer and the
206 error message string.
208 The default handler prints messages on C<stderr>.
210 If you set C<cb> to C<NULL> then I<no> handler is called and the error
211 message is completely discarded.
213 =head2 guestfs_get_error_handler
215 guestfs_error_handler_cb guestfs_get_error_handler (guestfs_h *handle,
218 Returns the current error handler callback.
220 =head2 guestfs_set_out_of_memory_handler
222 typedef void (*guestfs_abort_cb) (void);
223 int guestfs_set_out_of_memory_handler (guestfs_h *handle,
226 The callback C<cb> will be called if there is an out of memory
227 situation. I<Note this callback must not return>.
229 The default is to call L<abort(3)>.
231 You cannot set C<cb> to C<NULL>. You can't ignore out of memory
234 =head2 guestfs_get_out_of_memory_handler
236 guestfs_abort_fn guestfs_get_out_of_memory_handler (guestfs_h *handle);
238 This returns the current out of memory handler.
242 =head2 guestfs_set_autosync
244 void guestfs_set_autosync (guestfs_h *handle, int autosync);
246 If C<autosync> is true, this enables autosync. Libguestfs will make a
247 best effort attempt to run C<guestfs_sync> when the handle is closed
248 (also if the program exits without closing handles).
250 =head2 guestfs_get_autosync
252 int guestfs_get_autosync (guestfs_h *handle);
254 Get the autosync flag.
256 =head1 VERBOSE MESSAGES
258 =head2 guestfs_set_verbose
260 void guestfs_set_verbose (guestfs_h *handle, int verbose);
262 If C<verbose> is true, this turns on verbose messages (to C<stderr>).
264 Verbose messages are disabled unless the environment variable
265 C<LIBGUESTFS_DEBUG> is defined and set to C<1>.
267 =head2 guestfs_get_verbose
269 int guestfs_get_verbose (guestfs_h *handle);
271 This returns the verbose messages flag.
273 =head1 HIGH-LEVEL API ACTIONS
277 =head1 STATE MACHINE AND LOW-LEVEL EVENT API
279 Internally, libguestfs is implemented by running a virtual machine
280 using L<qemu(1)>. QEmu runs as a child process of the main program,
281 and most of this discussion won't make sense unless you understand
282 that the complexity is dealing with the (asynchronous) actions of the
286 ___________________ _________________________
288 | main program | | qemu +-----------------+|
289 | | | | Linux kernel ||
290 +-------------------+ | +-----------------+|
291 | libguestfs <-------------->| guestfsd ||
292 | | | +-----------------+|
293 \___________________/ \_________________________/
295 The diagram above shows libguestfs communicating with the guestfsd
296 daemon running inside the qemu child process. There are several
297 points of failure here: qemu can fail to start, the virtual machine
298 inside qemu can fail to boot, guestfsd can fail to start or not
299 establish communication, any component can start successfully but fail
300 asynchronously later, and so on.
304 libguestfs uses a state machine to model the child process:
315 / | \ \ guestfs_launch
321 / | guestfs_wait_ready
326 \______/ <------ \________/
328 The normal transitions are (1) CONFIG (when the handle is created, but
329 there is no child process), (2) LAUNCHING (when the child process is
330 booting up), (3) alternating between READY and BUSY as commands are
331 issued to, and carried out by, the child process.
333 The guest may be killed by C<guestfs_kill_subprocess>, or may die
334 asynchronously at any time (eg. due to some internal error), and that
335 causes the state to transition back to CONFIG.
337 Configuration commands for qemu such as C<guestfs_add_drive> can only
338 be issued when in the CONFIG state.
340 The high-level API offers two calls that go from CONFIG through
341 LAUNCHING to READY. C<guestfs_launch> is a non-blocking call that
342 starts up the child process, immediately moving from CONFIG to
343 LAUNCHING. C<guestfs_wait_ready> blocks until the child process is
344 READY to accept commands (or until some failure or timeout). The
345 low-level event API described below provides a non-blocking way to
346 replace C<guestfs_wait_ready>.
348 High-level API actions such as C<guestfs_mount> can only be issued
349 when in the READY state. These high-level API calls block waiting for
350 the command to be carried out (ie. the state to transition to BUSY and
351 then back to READY). But using the low-level event API, you get
352 non-blocking versions. (But you can still only carry out one
353 operation per handle at a time - that is a limitation of the
354 communications protocol we use).
356 Finally, the child process sends asynchronous messages back to the
357 main program, such as kernel log messages. Mostly these are ignored
358 by the high-level API, but using the low-level event API you can
359 register to receive these messages.
361 =head2 SETTING CALLBACKS TO HANDLE EVENTS
363 The child process generates events in some situations. Current events
364 include: receiving a reply message after some action, receiving a log
365 message, the child process exits, &c.
367 Use the C<guestfs_set_*_callback> functions to set a callback for
368 different types of events.
370 Only I<one callback of each type> can be registered for each handle.
371 Calling C<guestfs_set_*_callback> again overwrites the previous
372 callback of that type. Cancel all callbacks of this type by calling
373 this function with C<cb> set to C<NULL>.
375 =head2 NON-BLOCKING ACTIONS
377 XXX NOT IMPLEMENTED YET XXX
379 C<guestfs_set_reply_callback> is the most interesting callback to
380 play with, since it allows you to perform actions without blocking.
387 guestfs_main_loop_run (); /* --> blocks, then calls my_cb */
392 guestfs_set_reply_callback (handle, my_cb, data);
393 guestfs_nb_[action] (handle, [other parameters ...]);
394 /* returns immediately */
397 my_cb (guestfs_h *handle, void *data, XDR *xdr)
399 retval = guestfs_nb_[action]_r (handle, xdr);
403 There are C<guestfs_nb_*> and C<guestfs_nb_*_r> functions
404 corresponding to every C<guestfs_*> action in the high-level API.
406 =head2 guestfs_set_reply_callback
408 typedef void (*guestfs_reply_cb) (guestfs_h *g, void *opaque, XDR *xdr);
409 void guestfs_set_reply_callback (guestfs_h *handle,
413 The callback function C<cb> will be called whenever a reply is
414 received from the child process. (This corresponds to a transition
415 from the BUSY state to the READY state).
417 Note that the C<xdr> that you get in the callback is in C<XDR_DECODE>
418 mode, and you need to consume it before you return from the callback
419 function (since it gets destroyed after).
421 =head2 guestfs_set_log_message_callback
423 typedef void (*guestfs_log_message_cb) (guestfs_h *g, void *opaque,
425 void guestfs_set_log_message_callback (guestfs_h *handle,
426 guestfs_log_message_cb cb,
429 The callback function C<cb> will be called whenever qemu or the guest
430 writes anything to the console.
432 Use this function to capture kernel messages and similar.
434 Normally there is no log message handler, and log messages are just
437 =head2 guestfs_set_subprocess_quit_callback
439 typedef void (*guestfs_subprocess_quit_cb) (guestfs_h *g, void *opaque);
440 void guestfs_set_subprocess_quit_callback (guestfs_h *handle,
441 guestfs_subprocess_quit_cb cb,
444 The callback function C<cb> will be called when the child process
445 quits, either asynchronously or if killed by
446 C<guestfs_kill_subprocess>. (This corresponds to a transition from
447 any state to the CONFIG state).
449 =head2 guestfs_set_launch_done_callback
451 typedef void (*guestfs_launch_done_cb) (guestfs_h *g, void *opaque);
452 void guestfs_set_launch_done_callback (guestfs_h *handle,
456 The callback function C<cb> will be called when the child process
457 becomes ready first time after it has been launched. (This
458 corresponds to a transition from LAUNCHING to the READY state).
460 You can use this instead of C<guestfs_wait_ready> to implement a
461 non-blocking wait for the child process to finish booting up.
463 =head2 EVENT MAIN LOOP
465 To use the low-level event API, you have to provide an event "main
466 loop". You can write your own, but if you don't want to write one,
467 two are provided for you:
471 =item libguestfs-select
473 A simple main loop that is implemented using L<select(2)>.
475 This is the default main loop unless you call C<guestfs_set_main_loop>
476 or C<guestfs_glib_set_main_loop>.
478 =item libguestfs-glib
480 An implementation which can be used with GLib and GTK+ programs. You
481 can use this to write graphical (GTK+) programs which use libguestfs
482 without hanging during long or slow operations.
486 =head2 guestfs_set_main_loop
488 void guestfs_set_main_loop (guestfs_main_loop *);
490 This call sets the current main loop to the list of callbacks
491 contained in the C<guestfs_main_loop> structure.
493 Only one main loop implementation can be used by libguestfs, so
494 calling this replaces the previous one. (So this is something that
495 has to be done by the main program, but only the main program "knows"
496 that it is a GTK+ program or whatever).
498 You should call this early in the main program, certainly before
499 calling C<guestfs_create>.
501 =head2 guestfs_glib_set_main_loop
503 void guestfs_glib_set_main_loop (GMainLoop *);
505 This helper calls C<guestfs_set_main_loop> with the correct callbacks
506 for integrating with the GLib main loop.
508 The libguestfs-glib main loop is contained in a separate library, so
509 that libguestfs doesn't depend on the whole of GLib:
512 #include <guestfs-glib.h>
517 g_main_loop_new (g_main_context_default (), 1);
519 guestfs_glib_set_main_loop (loop);
521 g_main_loop_run (loop);
524 To use this main loop you must link with C<-lguestfs-glib>. (See also
525 the GLib and GTK+ documentation).
527 =head2 guestfs_main_loop_run
529 void guestfs_main_loop_run (void);
531 This calls the main loop.
533 For some types of main loop you may want or prefer to call another
534 function, eg. C<g_main_loop_run>, or the main loop may already be
535 invoked by another part of your program. In those cases, ignore this
538 =head2 guestfs_main_loop_quit
540 void guestfs_main_loop_quit (void);
542 This instructs the main loop to quit. In other words,
543 C<guestfs_main_loop_run> will return.
545 For some types of main loop you may want or prefer to call another
546 function, eg. C<g_main_loop_quit>. In those cases, ignore this call.
548 =head2 WRITING A CUSTOM MAIN LOOP
550 This isn't documented. Please see the libguestfs-select and
551 libguestfs-glib implementations.
563 Richard W.M. Jones (C<rjones at redhat dot com>)
567 Copyright (C) 2009 Red Hat Inc.
568 L<http://et.redhat.com/~rjones/libguestfs>
570 This library is free software; you can redistribute it and/or
571 modify it under the terms of the GNU Lesser General Public
572 License as published by the Free Software Foundation; either
573 version 2 of the License, or (at your option) any later version.
575 This library is distributed in the hope that it will be useful,
576 but WITHOUT ANY WARRANTY; without even the implied warranty of
577 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
578 Lesser General Public License for more details.
580 You should have received a copy of the GNU Lesser General Public
581 License along with this library; if not, write to the Free Software
582 Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA