[linux-2.6-block.git] / Documentation / livepatch / callbacks.rst

======================
(Un)patching Callbacks
======================

Livepatch (un)patch-callbacks provide a mechanism for livepatch modules
to execute callback functions when a kernel object is (un)patched.  They
can be considered a **power feature** that **extends livepatching abilities**
to include:

  - Safe updates to global data

  - "Patches" to init and probe functions

  - Patching otherwise unpatchable code (i.e. assembly)

In most cases, (un)patch callbacks will need to be used in conjunction
with memory barriers and kernel synchronization primitives, like
mutexes/spinlocks, or even stop_machine(), to avoid concurrency issues.

1. Motivation
=============

Callbacks differ from existing kernel facilities:

  - Module init/exit code doesn't run when disabling and re-enabling a
    patch.

  - A module notifier can't stop a to-be-patched module from loading.

Callbacks are part of the klp_object structure and their implementation
is specific to that klp_object.  Other livepatch objects may or may not
be patched, irrespective of the target klp_object's current state.

2. Callback types
=================

Callbacks can be registered for the following livepatch actions:

  * Pre-patch
                 - before a klp_object is patched

  * Post-patch
                 - after a klp_object has been patched and is active
                   across all tasks

  * Pre-unpatch
                 - before a klp_object is unpatched (ie, patched code is
                   active), used to clean up post-patch callback
                   resources

  * Post-unpatch
                 - after a klp_object has been patched, all code has
                   been restored and no tasks are running patched code,
                   used to cleanup pre-patch callback resources

3. How it works
===============

Each callback is optional, omitting one does not preclude specifying any
other.  However, the livepatching core executes the handlers in
symmetry: pre-patch callbacks have a post-unpatch counterpart and
post-patch callbacks have a pre-unpatch counterpart.  An unpatch
callback will only be executed if its corresponding patch callback was
executed.  Typical use cases pair a patch handler that acquires and
configures resources with an unpatch handler tears down and releases
those same resources.

A callback is only executed if its host klp_object is loaded.  For
in-kernel vmlinux targets, this means that callbacks will always execute
when a livepatch is enabled/disabled.  For patch target kernel modules,
callbacks will only execute if the target module is loaded.  When a
module target is (un)loaded, its callbacks will execute only if the
livepatch module is enabled.

The pre-patch callback, if specified, is expected to return a status
code (0 for success, -ERRNO on error).  An error status code indicates
to the livepatching core that patching of the current klp_object is not
safe and to stop the current patching request.  (When no pre-patch
callback is provided, the transition is assumed to be safe.)  If a
pre-patch callback returns failure, the kernel's module loader will:

  - Refuse to load a livepatch, if the livepatch is loaded after
    targeted code.

    or:

  - Refuse to load a module, if the livepatch was already successfully
    loaded.

No post-patch, pre-unpatch, or post-unpatch callbacks will be executed
for a given klp_object if the object failed to patch, due to a failed
pre_patch callback or for any other reason.

If a patch transition is reversed, no pre-unpatch handlers will be run
(this follows the previously mentioned symmetry -- pre-unpatch callbacks
will only occur if their corresponding post-patch callback executed).

If the object did successfully patch, but the patch transition never
started for some reason (e.g., if another object failed to patch),
only the post-unpatch callback will be called.

4. Use cases
============

Sample livepatch modules demonstrating the callback API can be found in
samples/livepatch/ directory.  These samples were modified for use in
kselftests and can be found in the lib/livepatch directory.

Global data update
------------------

A pre-patch callback can be useful to update a global variable.  For
example, 75ff39ccc1bd ("tcp: make challenge acks less predictable")
changes a global sysctl, as well as patches the tcp_send_challenge_ack()
function.

In this case, if we're being super paranoid, it might make sense to
patch the data *after* patching is complete with a post-patch callback,
so that tcp_send_challenge_ack() could first be changed to read
sysctl_tcp_challenge_ack_limit with READ_ONCE.

__init and probe function patches support
-----------------------------------------

Although __init and probe functions are not directly livepatch-able, it
may be possible to implement similar updates via pre/post-patch
callbacks.

The commit ``48900cb6af42 ("virtio-net: drop NETIF_F_FRAGLIST")`` change the way that
virtnet_probe() initialized its driver's net_device features.  A
pre/post-patch callback could iterate over all such devices, making a
similar change to their hw_features value.  (Client functions of the
value may need to be updated accordingly.)
Commit	Line	Data
93862e38 JL	1	======================
	2	(Un)patching Callbacks
	3	======================
	4
	5	Livepatch (un)patch-callbacks provide a mechanism for livepatch modules
	6	to execute callback functions when a kernel object is (un)patched. They
d9defe44	7	can be considered a power feature that extends livepatching abilities
93862e38 JL	8	to include:
	9
	10	- Safe updates to global data
	11
	12	- "Patches" to init and probe functions
	13
	14	- Patching otherwise unpatchable code (i.e. assembly)
	15
	16	In most cases, (un)patch callbacks will need to be used in conjunction
	17	with memory barriers and kernel synchronization primitives, like
	18	mutexes/spinlocks, or even stop_machine(), to avoid concurrency issues.
	19
d9defe44 PM	20	1. Motivation
	21	=============
	22
93862e38 JL	23	Callbacks differ from existing kernel facilities:
	24
	25	- Module init/exit code doesn't run when disabling and re-enabling a
	26	patch.
	27
	28	- A module notifier can't stop a to-be-patched module from loading.
	29
	30	Callbacks are part of the klp_object structure and their implementation
	31	is specific to that klp_object. Other livepatch objects may or may not
	32	be patched, irrespective of the target klp_object's current state.
	33
d9defe44 PM	34	2. Callback types
	35	=================
	36
93862e38 JL	37	Callbacks can be registered for the following livepatch actions:
93862e38 JL	38
89e33ea7 MCC	39	* Pre-patch
89e33ea7 MCC	40	- before a klp_object is patched
93862e38	41
89e33ea7 MCC	42	* Post-patch
89e33ea7 MCC	43	- after a klp_object has been patched and is active
93862e38 JL	44	across all tasks
93862e38 JL	45
89e33ea7 MCC	46	* Pre-unpatch
89e33ea7 MCC	47	- before a klp_object is unpatched (ie, patched code is
93862e38 JL	48	active), used to clean up post-patch callback
	49	resources
	50
89e33ea7 MCC	51	* Post-unpatch
89e33ea7 MCC	52	- after a klp_object has been patched, all code has
93862e38 JL	53	been restored and no tasks are running patched code,
	54	used to cleanup pre-patch callback resources
	55
d9defe44 PM	56	3. How it works
	57	===============
	58
93862e38 JL	59	Each callback is optional, omitting one does not preclude specifying any
	60	other. However, the livepatching core executes the handlers in
	61	symmetry: pre-patch callbacks have a post-unpatch counterpart and
	62	post-patch callbacks have a pre-unpatch counterpart. An unpatch
	63	callback will only be executed if its corresponding patch callback was
	64	executed. Typical use cases pair a patch handler that acquires and
	65	configures resources with an unpatch handler tears down and releases
	66	those same resources.
	67
	68	A callback is only executed if its host klp_object is loaded. For
	69	in-kernel vmlinux targets, this means that callbacks will always execute
	70	when a livepatch is enabled/disabled. For patch target kernel modules,
	71	callbacks will only execute if the target module is loaded. When a
	72	module target is (un)loaded, its callbacks will execute only if the
	73	livepatch module is enabled.
	74
	75	The pre-patch callback, if specified, is expected to return a status
	76	code (0 for success, -ERRNO on error). An error status code indicates
	77	to the livepatching core that patching of the current klp_object is not
	78	safe and to stop the current patching request. (When no pre-patch
	79	callback is provided, the transition is assumed to be safe.) If a
	80	pre-patch callback returns failure, the kernel's module loader will:
	81
	82	- Refuse to load a livepatch, if the livepatch is loaded after
	83	targeted code.
	84
	85	or:
	86
	87	- Refuse to load a module, if the livepatch was already successfully
	88	loaded.
	89
	90	No post-patch, pre-unpatch, or post-unpatch callbacks will be executed
	91	for a given klp_object if the object failed to patch, due to a failed
	92	pre_patch callback or for any other reason.
	93
	94	If a patch transition is reversed, no pre-unpatch handlers will be run
	95	(this follows the previously mentioned symmetry -- pre-unpatch callbacks
	96	will only occur if their corresponding post-patch callback executed).
	97
	98	If the object did successfully patch, but the patch transition never
	99	started for some reason (e.g., if another object failed to patch),
	100	only the post-unpatch callback will be called.
	101
d9defe44 PM	102	4. Use cases
d9defe44 PM	103	============
93862e38	104
d9defe44 PM	105	Sample livepatch modules demonstrating the callback API can be found in
	106	samples/livepatch/ directory. These samples were modified for use in
	107	kselftests and can be found in the lib/livepatch directory.
93862e38	108
d9defe44	109	Global data update
93862e38 JL	110	------------------
	111
	112	A pre-patch callback can be useful to update a global variable. For
	113	example, 75ff39ccc1bd ("tcp: make challenge acks less predictable")
	114	changes a global sysctl, as well as patches the tcp_send_challenge_ack()
	115	function.
	116
	117	In this case, if we're being super paranoid, it might make sense to
	118	patch the data after patching is complete with a post-patch callback,
	119	so that tcp_send_challenge_ack() could first be changed to read
	120	sysctl_tcp_challenge_ack_limit with READ_ONCE.
	121
d9defe44	122	__init and probe function patches support
93862e38 JL	123	-----------------------------------------
	124
	125	Although __init and probe functions are not directly livepatch-able, it
	126	may be possible to implement similar updates via pre/post-patch
	127	callbacks.
	128
d9defe44	129	The commit ``48900cb6af42 ("virtio-net: drop NETIF_F_FRAGLIST")`` change the way that
93862e38 JL	130	virtnet_probe() initialized its driver's net_device features. A
	131	pre/post-patch callback could iterate over all such devices, making a
	132	similar change to their hw_features value. (Client functions of the
	133	value may need to be updated accordingly.)