xref: /openbmc/linux/Documentation/bpf/kfuncs.rst (revision 00d0f31a)
1.. SPDX-License-Identifier: GPL-2.0
2
3.. _kfuncs-header-label:
4
5=============================
6BPF Kernel Functions (kfuncs)
7=============================
8
91. Introduction
10===============
11
12BPF Kernel Functions or more commonly known as kfuncs are functions in the Linux
13kernel which are exposed for use by BPF programs. Unlike normal BPF helpers,
14kfuncs do not have a stable interface and can change from one kernel release to
15another. Hence, BPF programs need to be updated in response to changes in the
16kernel. See :ref:`BPF_kfunc_lifecycle_expectations` for more information.
17
182. Defining a kfunc
19===================
20
21There are two ways to expose a kernel function to BPF programs, either make an
22existing function in the kernel visible, or add a new wrapper for BPF. In both
23cases, care must be taken that BPF program can only call such function in a
24valid context. To enforce this, visibility of a kfunc can be per program type.
25
26If you are not creating a BPF wrapper for existing kernel function, skip ahead
27to :ref:`BPF_kfunc_nodef`.
28
292.1 Creating a wrapper kfunc
30----------------------------
31
32When defining a wrapper kfunc, the wrapper function should have extern linkage.
33This prevents the compiler from optimizing away dead code, as this wrapper kfunc
34is not invoked anywhere in the kernel itself. It is not necessary to provide a
35prototype in a header for the wrapper kfunc.
36
37An example is given below::
38
39        /* Disables missing prototype warnings */
40        __diag_push();
41        __diag_ignore_all("-Wmissing-prototypes",
42                          "Global kfuncs as their definitions will be in BTF");
43
44        __bpf_kfunc struct task_struct *bpf_find_get_task_by_vpid(pid_t nr)
45        {
46                return find_get_task_by_vpid(nr);
47        }
48
49        __diag_pop();
50
51A wrapper kfunc is often needed when we need to annotate parameters of the
52kfunc. Otherwise one may directly make the kfunc visible to the BPF program by
53registering it with the BPF subsystem. See :ref:`BPF_kfunc_nodef`.
54
552.2 Annotating kfunc parameters
56-------------------------------
57
58Similar to BPF helpers, there is sometime need for additional context required
59by the verifier to make the usage of kernel functions safer and more useful.
60Hence, we can annotate a parameter by suffixing the name of the argument of the
61kfunc with a __tag, where tag may be one of the supported annotations.
62
632.2.1 __sz Annotation
64---------------------
65
66This annotation is used to indicate a memory and size pair in the argument list.
67An example is given below::
68
69        __bpf_kfunc void bpf_memzero(void *mem, int mem__sz)
70        {
71        ...
72        }
73
74Here, the verifier will treat first argument as a PTR_TO_MEM, and second
75argument as its size. By default, without __sz annotation, the size of the type
76of the pointer is used. Without __sz annotation, a kfunc cannot accept a void
77pointer.
78
792.2.2 __k Annotation
80--------------------
81
82This annotation is only understood for scalar arguments, where it indicates that
83the verifier must check the scalar argument to be a known constant, which does
84not indicate a size parameter, and the value of the constant is relevant to the
85safety of the program.
86
87An example is given below::
88
89        __bpf_kfunc void *bpf_obj_new(u32 local_type_id__k, ...)
90        {
91        ...
92        }
93
94Here, bpf_obj_new uses local_type_id argument to find out the size of that type
95ID in program's BTF and return a sized pointer to it. Each type ID will have a
96distinct size, hence it is crucial to treat each such call as distinct when
97values don't match during verifier state pruning checks.
98
99Hence, whenever a constant scalar argument is accepted by a kfunc which is not a
100size parameter, and the value of the constant matters for program safety, __k
101suffix should be used.
102
1032.2.2 __uninit Annotation
104-------------------------
105
106This annotation is used to indicate that the argument will be treated as
107uninitialized.
108
109An example is given below::
110
111        __bpf_kfunc int bpf_dynptr_from_skb(..., struct bpf_dynptr_kern *ptr__uninit)
112        {
113        ...
114        }
115
116Here, the dynptr will be treated as an uninitialized dynptr. Without this
117annotation, the verifier will reject the program if the dynptr passed in is
118not initialized.
119
120.. _BPF_kfunc_nodef:
121
1222.3 Using an existing kernel function
123-------------------------------------
124
125When an existing function in the kernel is fit for consumption by BPF programs,
126it can be directly registered with the BPF subsystem. However, care must still
127be taken to review the context in which it will be invoked by the BPF program
128and whether it is safe to do so.
129
1302.4 Annotating kfuncs
131---------------------
132
133In addition to kfuncs' arguments, verifier may need more information about the
134type of kfunc(s) being registered with the BPF subsystem. To do so, we define
135flags on a set of kfuncs as follows::
136
137        BTF_SET8_START(bpf_task_set)
138        BTF_ID_FLAGS(func, bpf_get_task_pid, KF_ACQUIRE | KF_RET_NULL)
139        BTF_ID_FLAGS(func, bpf_put_pid, KF_RELEASE)
140        BTF_SET8_END(bpf_task_set)
141
142This set encodes the BTF ID of each kfunc listed above, and encodes the flags
143along with it. Ofcourse, it is also allowed to specify no flags.
144
145kfunc definitions should also always be annotated with the ``__bpf_kfunc``
146macro. This prevents issues such as the compiler inlining the kfunc if it's a
147static kernel function, or the function being elided in an LTO build as it's
148not used in the rest of the kernel. Developers should not manually add
149annotations to their kfunc to prevent these issues. If an annotation is
150required to prevent such an issue with your kfunc, it is a bug and should be
151added to the definition of the macro so that other kfuncs are similarly
152protected. An example is given below::
153
154        __bpf_kfunc struct task_struct *bpf_get_task_pid(s32 pid)
155        {
156        ...
157        }
158
1592.4.1 KF_ACQUIRE flag
160---------------------
161
162The KF_ACQUIRE flag is used to indicate that the kfunc returns a pointer to a
163refcounted object. The verifier will then ensure that the pointer to the object
164is eventually released using a release kfunc, or transferred to a map using a
165referenced kptr (by invoking bpf_kptr_xchg). If not, the verifier fails the
166loading of the BPF program until no lingering references remain in all possible
167explored states of the program.
168
1692.4.2 KF_RET_NULL flag
170----------------------
171
172The KF_RET_NULL flag is used to indicate that the pointer returned by the kfunc
173may be NULL. Hence, it forces the user to do a NULL check on the pointer
174returned from the kfunc before making use of it (dereferencing or passing to
175another helper). This flag is often used in pairing with KF_ACQUIRE flag, but
176both are orthogonal to each other.
177
1782.4.3 KF_RELEASE flag
179---------------------
180
181The KF_RELEASE flag is used to indicate that the kfunc releases the pointer
182passed in to it. There can be only one referenced pointer that can be passed
183in. All copies of the pointer being released are invalidated as a result of
184invoking kfunc with this flag. KF_RELEASE kfuncs automatically receive the
185protection afforded by the KF_TRUSTED_ARGS flag described below.
186
1872.4.4 KF_TRUSTED_ARGS flag
188--------------------------
189
190The KF_TRUSTED_ARGS flag is used for kfuncs taking pointer arguments. It
191indicates that the all pointer arguments are valid, and that all pointers to
192BTF objects have been passed in their unmodified form (that is, at a zero
193offset, and without having been obtained from walking another pointer, with one
194exception described below).
195
196There are two types of pointers to kernel objects which are considered "valid":
197
1981. Pointers which are passed as tracepoint or struct_ops callback arguments.
1992. Pointers which were returned from a KF_ACQUIRE kfunc.
200
201Pointers to non-BTF objects (e.g. scalar pointers) may also be passed to
202KF_TRUSTED_ARGS kfuncs, and may have a non-zero offset.
203
204The definition of "valid" pointers is subject to change at any time, and has
205absolutely no ABI stability guarantees.
206
207As mentioned above, a nested pointer obtained from walking a trusted pointer is
208no longer trusted, with one exception. If a struct type has a field that is
209guaranteed to be valid as long as its parent pointer is trusted, the
210``BTF_TYPE_SAFE_NESTED`` macro can be used to express that to the verifier as
211follows:
212
213.. code-block:: c
214
215	BTF_TYPE_SAFE_NESTED(struct task_struct) {
216		const cpumask_t *cpus_ptr;
217	};
218
219In other words, you must:
220
2211. Wrap the trusted pointer type in the ``BTF_TYPE_SAFE_NESTED`` macro.
222
2232. Specify the type and name of the trusted nested field. This field must match
224   the field in the original type definition exactly.
225
2262.4.5 KF_SLEEPABLE flag
227-----------------------
228
229The KF_SLEEPABLE flag is used for kfuncs that may sleep. Such kfuncs can only
230be called by sleepable BPF programs (BPF_F_SLEEPABLE).
231
2322.4.6 KF_DESTRUCTIVE flag
233--------------------------
234
235The KF_DESTRUCTIVE flag is used to indicate functions calling which is
236destructive to the system. For example such a call can result in system
237rebooting or panicking. Due to this additional restrictions apply to these
238calls. At the moment they only require CAP_SYS_BOOT capability, but more can be
239added later.
240
2412.4.7 KF_RCU flag
242-----------------
243
244The KF_RCU flag is a weaker version of KF_TRUSTED_ARGS. The kfuncs marked with
245KF_RCU expect either PTR_TRUSTED or MEM_RCU arguments. The verifier guarantees
246that the objects are valid and there is no use-after-free. The pointers are not
247NULL, but the object's refcount could have reached zero. The kfuncs need to
248consider doing refcnt != 0 check, especially when returning a KF_ACQUIRE
249pointer. Note as well that a KF_ACQUIRE kfunc that is KF_RCU should very likely
250also be KF_RET_NULL.
251
252.. _KF_deprecated_flag:
253
2542.4.8 KF_DEPRECATED flag
255------------------------
256
257The KF_DEPRECATED flag is used for kfuncs which are scheduled to be
258changed or removed in a subsequent kernel release. A kfunc that is
259marked with KF_DEPRECATED should also have any relevant information
260captured in its kernel doc. Such information typically includes the
261kfunc's expected remaining lifespan, a recommendation for new
262functionality that can replace it if any is available, and possibly a
263rationale for why it is being removed.
264
265Note that while on some occasions, a KF_DEPRECATED kfunc may continue to be
266supported and have its KF_DEPRECATED flag removed, it is likely to be far more
267difficult to remove a KF_DEPRECATED flag after it's been added than it is to
268prevent it from being added in the first place. As described in
269:ref:`BPF_kfunc_lifecycle_expectations`, users that rely on specific kfuncs are
270encouraged to make their use-cases known as early as possible, and participate
271in upstream discussions regarding whether to keep, change, deprecate, or remove
272those kfuncs if and when such discussions occur.
273
2742.5 Registering the kfuncs
275--------------------------
276
277Once the kfunc is prepared for use, the final step to making it visible is
278registering it with the BPF subsystem. Registration is done per BPF program
279type. An example is shown below::
280
281        BTF_SET8_START(bpf_task_set)
282        BTF_ID_FLAGS(func, bpf_get_task_pid, KF_ACQUIRE | KF_RET_NULL)
283        BTF_ID_FLAGS(func, bpf_put_pid, KF_RELEASE)
284        BTF_SET8_END(bpf_task_set)
285
286        static const struct btf_kfunc_id_set bpf_task_kfunc_set = {
287                .owner = THIS_MODULE,
288                .set   = &bpf_task_set,
289        };
290
291        static int init_subsystem(void)
292        {
293                return register_btf_kfunc_id_set(BPF_PROG_TYPE_TRACING, &bpf_task_kfunc_set);
294        }
295        late_initcall(init_subsystem);
296
2972.6  Specifying no-cast aliases with ___init
298--------------------------------------------
299
300The verifier will always enforce that the BTF type of a pointer passed to a
301kfunc by a BPF program, matches the type of pointer specified in the kfunc
302definition. The verifier, does, however, allow types that are equivalent
303according to the C standard to be passed to the same kfunc arg, even if their
304BTF_IDs differ.
305
306For example, for the following type definition:
307
308.. code-block:: c
309
310	struct bpf_cpumask {
311		cpumask_t cpumask;
312		refcount_t usage;
313	};
314
315The verifier would allow a ``struct bpf_cpumask *`` to be passed to a kfunc
316taking a ``cpumask_t *`` (which is a typedef of ``struct cpumask *``). For
317instance, both ``struct cpumask *`` and ``struct bpf_cpmuask *`` can be passed
318to bpf_cpumask_test_cpu().
319
320In some cases, this type-aliasing behavior is not desired. ``struct
321nf_conn___init`` is one such example:
322
323.. code-block:: c
324
325	struct nf_conn___init {
326		struct nf_conn ct;
327	};
328
329The C standard would consider these types to be equivalent, but it would not
330always be safe to pass either type to a trusted kfunc. ``struct
331nf_conn___init`` represents an allocated ``struct nf_conn`` object that has
332*not yet been initialized*, so it would therefore be unsafe to pass a ``struct
333nf_conn___init *`` to a kfunc that's expecting a fully initialized ``struct
334nf_conn *`` (e.g. ``bpf_ct_change_timeout()``).
335
336In order to accommodate such requirements, the verifier will enforce strict
337PTR_TO_BTF_ID type matching if two types have the exact same name, with one
338being suffixed with ``___init``.
339
340.. _BPF_kfunc_lifecycle_expectations:
341
3423. kfunc lifecycle expectations
343===============================
344
345kfuncs provide a kernel <-> kernel API, and thus are not bound by any of the
346strict stability restrictions associated with kernel <-> user UAPIs. This means
347they can be thought of as similar to EXPORT_SYMBOL_GPL, and can therefore be
348modified or removed by a maintainer of the subsystem they're defined in when
349it's deemed necessary.
350
351Like any other change to the kernel, maintainers will not change or remove a
352kfunc without having a reasonable justification.  Whether or not they'll choose
353to change a kfunc will ultimately depend on a variety of factors, such as how
354widely used the kfunc is, how long the kfunc has been in the kernel, whether an
355alternative kfunc exists, what the norm is in terms of stability for the
356subsystem in question, and of course what the technical cost is of continuing
357to support the kfunc.
358
359There are several implications of this:
360
361a) kfuncs that are widely used or have been in the kernel for a long time will
362   be more difficult to justify being changed or removed by a maintainer. In
363   other words, kfuncs that are known to have a lot of users and provide
364   significant value provide stronger incentives for maintainers to invest the
365   time and complexity in supporting them. It is therefore important for
366   developers that are using kfuncs in their BPF programs to communicate and
367   explain how and why those kfuncs are being used, and to participate in
368   discussions regarding those kfuncs when they occur upstream.
369
370b) Unlike regular kernel symbols marked with EXPORT_SYMBOL_GPL, BPF programs
371   that call kfuncs are generally not part of the kernel tree. This means that
372   refactoring cannot typically change callers in-place when a kfunc changes,
373   as is done for e.g. an upstreamed driver being updated in place when a
374   kernel symbol is changed.
375
376   Unlike with regular kernel symbols, this is expected behavior for BPF
377   symbols, and out-of-tree BPF programs that use kfuncs should be considered
378   relevant to discussions and decisions around modifying and removing those
379   kfuncs. The BPF community will take an active role in participating in
380   upstream discussions when necessary to ensure that the perspectives of such
381   users are taken into account.
382
383c) A kfunc will never have any hard stability guarantees. BPF APIs cannot and
384   will not ever hard-block a change in the kernel purely for stability
385   reasons. That being said, kfuncs are features that are meant to solve
386   problems and provide value to users. The decision of whether to change or
387   remove a kfunc is a multivariate technical decision that is made on a
388   case-by-case basis, and which is informed by data points such as those
389   mentioned above. It is expected that a kfunc being removed or changed with
390   no warning will not be a common occurrence or take place without sound
391   justification, but it is a possibility that must be accepted if one is to
392   use kfuncs.
393
3943.1 kfunc deprecation
395---------------------
396
397As described above, while sometimes a maintainer may find that a kfunc must be
398changed or removed immediately to accommodate some changes in their subsystem,
399usually kfuncs will be able to accommodate a longer and more measured
400deprecation process. For example, if a new kfunc comes along which provides
401superior functionality to an existing kfunc, the existing kfunc may be
402deprecated for some period of time to allow users to migrate their BPF programs
403to use the new one. Or, if a kfunc has no known users, a decision may be made
404to remove the kfunc (without providing an alternative API) after some
405deprecation period so as to provide users with a window to notify the kfunc
406maintainer if it turns out that the kfunc is actually being used.
407
408It's expected that the common case will be that kfuncs will go through a
409deprecation period rather than being changed or removed without warning. As
410described in :ref:`KF_deprecated_flag`, the kfunc framework provides the
411KF_DEPRECATED flag to kfunc developers to signal to users that a kfunc has been
412deprecated. Once a kfunc has been marked with KF_DEPRECATED, the following
413procedure is followed for removal:
414
4151. Any relevant information for deprecated kfuncs is documented in the kfunc's
416   kernel docs. This documentation will typically include the kfunc's expected
417   remaining lifespan, a recommendation for new functionality that can replace
418   the usage of the deprecated function (or an explanation as to why no such
419   replacement exists), etc.
420
4212. The deprecated kfunc is kept in the kernel for some period of time after it
422   was first marked as deprecated. This time period will be chosen on a
423   case-by-case basis, and will typically depend on how widespread the use of
424   the kfunc is, how long it has been in the kernel, and how hard it is to move
425   to alternatives. This deprecation time period is "best effort", and as
426   described :ref:`above<BPF_kfunc_lifecycle_expectations>`, circumstances may
427   sometimes dictate that the kfunc be removed before the full intended
428   deprecation period has elapsed.
429
4303. After the deprecation period the kfunc will be removed. At this point, BPF
431   programs calling the kfunc will be rejected by the verifier.
432
4334. Core kfuncs
434==============
435
436The BPF subsystem provides a number of "core" kfuncs that are potentially
437applicable to a wide variety of different possible use cases and programs.
438Those kfuncs are documented here.
439
4404.1 struct task_struct * kfuncs
441-------------------------------
442
443There are a number of kfuncs that allow ``struct task_struct *`` objects to be
444used as kptrs:
445
446.. kernel-doc:: kernel/bpf/helpers.c
447   :identifiers: bpf_task_acquire bpf_task_release
448
449These kfuncs are useful when you want to acquire or release a reference to a
450``struct task_struct *`` that was passed as e.g. a tracepoint arg, or a
451struct_ops callback arg. For example:
452
453.. code-block:: c
454
455	/**
456	 * A trivial example tracepoint program that shows how to
457	 * acquire and release a struct task_struct * pointer.
458	 */
459	SEC("tp_btf/task_newtask")
460	int BPF_PROG(task_acquire_release_example, struct task_struct *task, u64 clone_flags)
461	{
462		struct task_struct *acquired;
463
464		acquired = bpf_task_acquire(task);
465		if (acquired)
466			/*
467			 * In a typical program you'd do something like store
468			 * the task in a map, and the map will automatically
469			 * release it later. Here, we release it manually.
470			 */
471			bpf_task_release(acquired);
472		return 0;
473	}
474
475
476References acquired on ``struct task_struct *`` objects are RCU protected.
477Therefore, when in an RCU read region, you can obtain a pointer to a task
478embedded in a map value without having to acquire a reference:
479
480.. code-block:: c
481
482	#define private(name) SEC(".data." #name) __hidden __attribute__((aligned(8)))
483	private(TASK) static struct task_struct *global;
484
485	/**
486	 * A trivial example showing how to access a task stored
487	 * in a map using RCU.
488	 */
489	SEC("tp_btf/task_newtask")
490	int BPF_PROG(task_rcu_read_example, struct task_struct *task, u64 clone_flags)
491	{
492		struct task_struct *local_copy;
493
494		bpf_rcu_read_lock();
495		local_copy = global;
496		if (local_copy)
497			/*
498			 * We could also pass local_copy to kfuncs or helper functions here,
499			 * as we're guaranteed that local_copy will be valid until we exit
500			 * the RCU read region below.
501			 */
502			bpf_printk("Global task %s is valid", local_copy->comm);
503		else
504			bpf_printk("No global task found");
505		bpf_rcu_read_unlock();
506
507		/* At this point we can no longer reference local_copy. */
508
509		return 0;
510	}
511
512----
513
514A BPF program can also look up a task from a pid. This can be useful if the
515caller doesn't have a trusted pointer to a ``struct task_struct *`` object that
516it can acquire a reference on with bpf_task_acquire().
517
518.. kernel-doc:: kernel/bpf/helpers.c
519   :identifiers: bpf_task_from_pid
520
521Here is an example of it being used:
522
523.. code-block:: c
524
525	SEC("tp_btf/task_newtask")
526	int BPF_PROG(task_get_pid_example, struct task_struct *task, u64 clone_flags)
527	{
528		struct task_struct *lookup;
529
530		lookup = bpf_task_from_pid(task->pid);
531		if (!lookup)
532			/* A task should always be found, as %task is a tracepoint arg. */
533			return -ENOENT;
534
535		if (lookup->pid != task->pid) {
536			/* bpf_task_from_pid() looks up the task via its
537			 * globally-unique pid from the init_pid_ns. Thus,
538			 * the pid of the lookup task should always be the
539			 * same as the input task.
540			 */
541			bpf_task_release(lookup);
542			return -EINVAL;
543		}
544
545		/* bpf_task_from_pid() returns an acquired reference,
546		 * so it must be dropped before returning from the
547		 * tracepoint handler.
548		 */
549		bpf_task_release(lookup);
550		return 0;
551	}
552
5534.2 struct cgroup * kfuncs
554--------------------------
555
556``struct cgroup *`` objects also have acquire and release functions:
557
558.. kernel-doc:: kernel/bpf/helpers.c
559   :identifiers: bpf_cgroup_acquire bpf_cgroup_release
560
561These kfuncs are used in exactly the same manner as bpf_task_acquire() and
562bpf_task_release() respectively, so we won't provide examples for them.
563
564----
565
566Other kfuncs available for interacting with ``struct cgroup *`` objects are
567bpf_cgroup_ancestor() and bpf_cgroup_from_id(), allowing callers to access
568the ancestor of a cgroup and find a cgroup by its ID, respectively. Both
569return a cgroup kptr.
570
571.. kernel-doc:: kernel/bpf/helpers.c
572   :identifiers: bpf_cgroup_ancestor
573
574.. kernel-doc:: kernel/bpf/helpers.c
575   :identifiers: bpf_cgroup_from_id
576
577Eventually, BPF should be updated to allow this to happen with a normal memory
578load in the program itself. This is currently not possible without more work in
579the verifier. bpf_cgroup_ancestor() can be used as follows:
580
581.. code-block:: c
582
583	/**
584	 * Simple tracepoint example that illustrates how a cgroup's
585	 * ancestor can be accessed using bpf_cgroup_ancestor().
586	 */
587	SEC("tp_btf/cgroup_mkdir")
588	int BPF_PROG(cgrp_ancestor_example, struct cgroup *cgrp, const char *path)
589	{
590		struct cgroup *parent;
591
592		/* The parent cgroup resides at the level before the current cgroup's level. */
593		parent = bpf_cgroup_ancestor(cgrp, cgrp->level - 1);
594		if (!parent)
595			return -ENOENT;
596
597		bpf_printk("Parent id is %d", parent->self.id);
598
599		/* Return the parent cgroup that was acquired above. */
600		bpf_cgroup_release(parent);
601		return 0;
602	}
603
6044.3 struct cpumask * kfuncs
605---------------------------
606
607BPF provides a set of kfuncs that can be used to query, allocate, mutate, and
608destroy struct cpumask * objects. Please refer to :ref:`cpumasks-header-label`
609for more details.
610