Documentation/livepatch/callbacks.rst - linux - Git at Google

 ======================
 (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.)
	======================
	(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.)