checklist.rst 26 KB

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  1. .. SPDX-License-Identifier: GPL-2.0
  2. ================================
  3. Review Checklist for RCU Patches
  4. ================================
  5. This document contains a checklist for producing and reviewing patches
  6. that make use of RCU. Violating any of the rules listed below will
  7. result in the same sorts of problems that leaving out a locking primitive
  8. would cause. This list is based on experiences reviewing such patches
  9. over a rather long period of time, but improvements are always welcome!
  10. 0. Is RCU being applied to a read-mostly situation? If the data
  11. structure is updated more than about 10% of the time, then you
  12. should strongly consider some other approach, unless detailed
  13. performance measurements show that RCU is nonetheless the right
  14. tool for the job. Yes, RCU does reduce read-side overhead by
  15. increasing write-side overhead, which is exactly why normal uses
  16. of RCU will do much more reading than updating.
  17. Another exception is where performance is not an issue, and RCU
  18. provides a simpler implementation. An example of this situation
  19. is the dynamic NMI code in the Linux 2.6 kernel, at least on
  20. architectures where NMIs are rare.
  21. Yet another exception is where the low real-time latency of RCU's
  22. read-side primitives is critically important.
  23. One final exception is where RCU readers are used to prevent
  24. the ABA problem (https://en.wikipedia.org/wiki/ABA_problem)
  25. for lockless updates. This does result in the mildly
  26. counter-intuitive situation where rcu_read_lock() and
  27. rcu_read_unlock() are used to protect updates, however, this
  28. approach can provide the same simplifications to certain types
  29. of lockless algorithms that garbage collectors do.
  30. 1. Does the update code have proper mutual exclusion?
  31. RCU does allow *readers* to run (almost) naked, but *writers* must
  32. still use some sort of mutual exclusion, such as:
  33. a. locking,
  34. b. atomic operations, or
  35. c. restricting updates to a single task.
  36. If you choose #b, be prepared to describe how you have handled
  37. memory barriers on weakly ordered machines (pretty much all of
  38. them -- even x86 allows later loads to be reordered to precede
  39. earlier stores), and be prepared to explain why this added
  40. complexity is worthwhile. If you choose #c, be prepared to
  41. explain how this single task does not become a major bottleneck
  42. on large systems (for example, if the task is updating information
  43. relating to itself that other tasks can read, there by definition
  44. can be no bottleneck). Note that the definition of "large" has
  45. changed significantly: Eight CPUs was "large" in the year 2000,
  46. but a hundred CPUs was unremarkable in 2017.
  47. 2. Do the RCU read-side critical sections make proper use of
  48. rcu_read_lock() and friends? These primitives are needed
  49. to prevent grace periods from ending prematurely, which
  50. could result in data being unceremoniously freed out from
  51. under your read-side code, which can greatly increase the
  52. actuarial risk of your kernel.
  53. As a rough rule of thumb, any dereference of an RCU-protected
  54. pointer must be covered by rcu_read_lock(), rcu_read_lock_bh(),
  55. rcu_read_lock_sched(), or by the appropriate update-side lock.
  56. Explicit disabling of preemption (preempt_disable(), for example)
  57. can serve as rcu_read_lock_sched(), but is less readable and
  58. prevents lockdep from detecting locking issues. Acquiring a
  59. raw spinlock also enters an RCU read-side critical section.
  60. The guard(rcu)() and scoped_guard(rcu) primitives designate
  61. the remainder of the current scope or the next statement,
  62. respectively, as the RCU read-side critical section. Use of
  63. these guards can be less error-prone than rcu_read_lock(),
  64. rcu_read_unlock(), and friends.
  65. Please note that you *cannot* rely on code known to be built
  66. only in non-preemptible kernels. Such code can and will break,
  67. especially in kernels built with CONFIG_PREEMPT_COUNT=y.
  68. Letting RCU-protected pointers "leak" out of an RCU read-side
  69. critical section is every bit as bad as letting them leak out
  70. from under a lock. Unless, of course, you have arranged some
  71. other means of protection, such as a lock or a reference count
  72. *before* letting them out of the RCU read-side critical section.
  73. 3. Does the update code tolerate concurrent accesses?
  74. The whole point of RCU is to permit readers to run without
  75. any locks or atomic operations. This means that readers will
  76. be running while updates are in progress. There are a number
  77. of ways to handle this concurrency, depending on the situation:
  78. a. Use the RCU variants of the list and hlist update
  79. primitives to add, remove, and replace elements on
  80. an RCU-protected list. Alternatively, use the other
  81. RCU-protected data structures that have been added to
  82. the Linux kernel.
  83. This is almost always the best approach.
  84. b. Proceed as in (a) above, but also maintain per-element
  85. locks (that are acquired by both readers and writers)
  86. that guard per-element state. Fields that the readers
  87. refrain from accessing can be guarded by some other lock
  88. acquired only by updaters, if desired.
  89. This also works quite well.
  90. c. Make updates appear atomic to readers. For example,
  91. pointer updates to properly aligned fields will
  92. appear atomic, as will individual atomic primitives.
  93. Sequences of operations performed under a lock will *not*
  94. appear to be atomic to RCU readers, nor will sequences
  95. of multiple atomic primitives. One alternative is to
  96. move multiple individual fields to a separate structure,
  97. thus solving the multiple-field problem by imposing an
  98. additional level of indirection.
  99. This can work, but is starting to get a bit tricky.
  100. d. Carefully order the updates and the reads so that readers
  101. see valid data at all phases of the update. This is often
  102. more difficult than it sounds, especially given modern
  103. CPUs' tendency to reorder memory references. One must
  104. usually liberally sprinkle memory-ordering operations
  105. through the code, making it difficult to understand and
  106. to test. Where it works, it is better to use things
  107. like smp_store_release() and smp_load_acquire(), but in
  108. some cases the smp_mb() full memory barrier is required.
  109. As noted earlier, it is usually better to group the
  110. changing data into a separate structure, so that the
  111. change may be made to appear atomic by updating a pointer
  112. to reference a new structure containing updated values.
  113. 4. Weakly ordered CPUs pose special challenges. Almost all CPUs
  114. are weakly ordered -- even x86 CPUs allow later loads to be
  115. reordered to precede earlier stores. RCU code must take all of
  116. the following measures to prevent memory-corruption problems:
  117. a. Readers must maintain proper ordering of their memory
  118. accesses. The rcu_dereference() primitive ensures that
  119. the CPU picks up the pointer before it picks up the data
  120. that the pointer points to. This really is necessary
  121. on Alpha CPUs.
  122. The rcu_dereference() primitive is also an excellent
  123. documentation aid, letting the person reading the
  124. code know exactly which pointers are protected by RCU.
  125. Please note that compilers can also reorder code, and
  126. they are becoming increasingly aggressive about doing
  127. just that. The rcu_dereference() primitive therefore also
  128. prevents destructive compiler optimizations. However,
  129. with a bit of devious creativity, it is possible to
  130. mishandle the return value from rcu_dereference().
  131. Please see rcu_dereference.rst for more information.
  132. The rcu_dereference() primitive is used by the
  133. various "_rcu()" list-traversal primitives, such
  134. as the list_for_each_entry_rcu(). Note that it is
  135. perfectly legal (if redundant) for update-side code to
  136. use rcu_dereference() and the "_rcu()" list-traversal
  137. primitives. This is particularly useful in code that
  138. is common to readers and updaters. However, lockdep
  139. will complain if you access rcu_dereference() outside
  140. of an RCU read-side critical section. See lockdep.rst
  141. to learn what to do about this.
  142. Of course, neither rcu_dereference() nor the "_rcu()"
  143. list-traversal primitives can substitute for a good
  144. concurrency design coordinating among multiple updaters.
  145. b. If the list macros are being used, the list_add_tail_rcu()
  146. and list_add_rcu() primitives must be used in order
  147. to prevent weakly ordered machines from misordering
  148. structure initialization and pointer planting.
  149. Similarly, if the hlist macros are being used, the
  150. hlist_add_head_rcu() primitive is required.
  151. c. If the list macros are being used, the list_del_rcu()
  152. primitive must be used to keep list_del()'s pointer
  153. poisoning from inflicting toxic effects on concurrent
  154. readers. Similarly, if the hlist macros are being used,
  155. the hlist_del_rcu() primitive is required.
  156. The list_replace_rcu() and hlist_replace_rcu() primitives
  157. may be used to replace an old structure with a new one
  158. in their respective types of RCU-protected lists.
  159. d. Rules similar to (4b) and (4c) apply to the "hlist_nulls"
  160. type of RCU-protected linked lists.
  161. e. Updates must ensure that initialization of a given
  162. structure happens before pointers to that structure are
  163. publicized. Use the rcu_assign_pointer() primitive
  164. when publicizing a pointer to a structure that can
  165. be traversed by an RCU read-side critical section.
  166. 5. If any of call_rcu(), call_srcu(), call_rcu_tasks(), or
  167. call_rcu_tasks_trace() is used, the callback function may be
  168. invoked from softirq context, and in any case with bottom halves
  169. disabled. In particular, this callback function cannot block.
  170. If you need the callback to block, run that code in a workqueue
  171. handler scheduled from the callback. The queue_rcu_work()
  172. function does this for you in the case of call_rcu().
  173. 6. Since synchronize_rcu() can block, it cannot be called
  174. from any sort of irq context. The same rule applies
  175. for synchronize_srcu(), synchronize_rcu_expedited(),
  176. synchronize_srcu_expedited(), synchronize_rcu_tasks(),
  177. synchronize_rcu_tasks_rude(), and synchronize_rcu_tasks_trace().
  178. The expedited forms of these primitives have the same semantics
  179. as the non-expedited forms, but expediting is more CPU intensive.
  180. Use of the expedited primitives should be restricted to rare
  181. configuration-change operations that would not normally be
  182. undertaken while a real-time workload is running. Note that
  183. IPI-sensitive real-time workloads can use the rcupdate.rcu_normal
  184. kernel boot parameter to completely disable expedited grace
  185. periods, though this might have performance implications.
  186. In particular, if you find yourself invoking one of the expedited
  187. primitives repeatedly in a loop, please do everyone a favor:
  188. Restructure your code so that it batches the updates, allowing
  189. a single non-expedited primitive to cover the entire batch.
  190. This will very likely be faster than the loop containing the
  191. expedited primitive, and will be much much easier on the rest
  192. of the system, especially to real-time workloads running on the
  193. rest of the system. Alternatively, instead use asynchronous
  194. primitives such as call_rcu().
  195. 7. As of v4.20, a given kernel implements only one RCU flavor, which
  196. is RCU-sched for PREEMPTION=n and RCU-preempt for PREEMPTION=y.
  197. If the updater uses call_rcu() or synchronize_rcu(), then
  198. the corresponding readers may use: (1) rcu_read_lock() and
  199. rcu_read_unlock(), (2) any pair of primitives that disables
  200. and re-enables softirq, for example, rcu_read_lock_bh() and
  201. rcu_read_unlock_bh(), or (3) any pair of primitives that disables
  202. and re-enables preemption, for example, rcu_read_lock_sched() and
  203. rcu_read_unlock_sched(). If the updater uses synchronize_srcu()
  204. or call_srcu(), then the corresponding readers must use
  205. srcu_read_lock() and srcu_read_unlock(), and with the same
  206. srcu_struct. The rules for the expedited RCU grace-period-wait
  207. primitives are the same as for their non-expedited counterparts.
  208. Similarly, it is necessary to correctly use the RCU Tasks flavors:
  209. a. If the updater uses synchronize_rcu_tasks() or
  210. call_rcu_tasks(), then the readers must refrain from
  211. executing voluntary context switches, that is, from
  212. blocking.
  213. b. If the updater uses call_rcu_tasks_trace()
  214. or synchronize_rcu_tasks_trace(), then the
  215. corresponding readers must use rcu_read_lock_trace()
  216. and rcu_read_unlock_trace().
  217. c. If an updater uses synchronize_rcu_tasks_rude(),
  218. then the corresponding readers must use anything that
  219. disables preemption, for example, preempt_disable()
  220. and preempt_enable().
  221. Mixing things up will result in confusion and broken kernels, and
  222. has even resulted in an exploitable security issue. Therefore,
  223. when using non-obvious pairs of primitives, commenting is
  224. of course a must. One example of non-obvious pairing is
  225. the XDP feature in networking, which calls BPF programs from
  226. network-driver NAPI (softirq) context. BPF relies heavily on RCU
  227. protection for its data structures, but because the BPF program
  228. invocation happens entirely within a single local_bh_disable()
  229. section in a NAPI poll cycle, this usage is safe. The reason
  230. that this usage is safe is that readers can use anything that
  231. disables BH when updaters use call_rcu() or synchronize_rcu().
  232. 8. Although synchronize_rcu() is slower than is call_rcu(),
  233. it usually results in simpler code. So, unless update
  234. performance is critically important, the updaters cannot block,
  235. or the latency of synchronize_rcu() is visible from userspace,
  236. synchronize_rcu() should be used in preference to call_rcu().
  237. Furthermore, kfree_rcu() and kvfree_rcu() usually result
  238. in even simpler code than does synchronize_rcu() without
  239. synchronize_rcu()'s multi-millisecond latency. So please take
  240. advantage of kfree_rcu()'s and kvfree_rcu()'s "fire and forget"
  241. memory-freeing capabilities where it applies.
  242. An especially important property of the synchronize_rcu()
  243. primitive is that it automatically self-limits: if grace periods
  244. are delayed for whatever reason, then the synchronize_rcu()
  245. primitive will correspondingly delay updates. In contrast,
  246. code using call_rcu() should explicitly limit update rate in
  247. cases where grace periods are delayed, as failing to do so can
  248. result in excessive realtime latencies or even OOM conditions.
  249. Ways of gaining this self-limiting property when using call_rcu(),
  250. kfree_rcu(), or kvfree_rcu() include:
  251. a. Keeping a count of the number of data-structure elements
  252. used by the RCU-protected data structure, including
  253. those waiting for a grace period to elapse. Enforce a
  254. limit on this number, stalling updates as needed to allow
  255. previously deferred frees to complete. Alternatively,
  256. limit only the number awaiting deferred free rather than
  257. the total number of elements.
  258. One way to stall the updates is to acquire the update-side
  259. mutex. (Don't try this with a spinlock -- other CPUs
  260. spinning on the lock could prevent the grace period
  261. from ever ending.) Another way to stall the updates
  262. is for the updates to use a wrapper function around
  263. the memory allocator, so that this wrapper function
  264. simulates OOM when there is too much memory awaiting an
  265. RCU grace period. There are of course many other
  266. variations on this theme.
  267. b. Limiting update rate. For example, if updates occur only
  268. once per hour, then no explicit rate limiting is
  269. required, unless your system is already badly broken.
  270. Older versions of the dcache subsystem take this approach,
  271. guarding updates with a global lock, limiting their rate.
  272. c. Trusted update -- if updates can only be done manually by
  273. superuser or some other trusted user, then it might not
  274. be necessary to automatically limit them. The theory
  275. here is that superuser already has lots of ways to crash
  276. the machine.
  277. d. Periodically invoke rcu_barrier(), permitting a limited
  278. number of updates per grace period.
  279. The same cautions apply to call_srcu(), call_rcu_tasks(), and
  280. call_rcu_tasks_trace(). This is why there is an srcu_barrier(),
  281. rcu_barrier_tasks(), and rcu_barrier_tasks_trace(), respectively.
  282. Note that although these primitives do take action to avoid
  283. memory exhaustion when any given CPU has too many callbacks,
  284. a determined user or administrator can still exhaust memory.
  285. This is especially the case if a system with a large number of
  286. CPUs has been configured to offload all of its RCU callbacks onto
  287. a single CPU, or if the system has relatively little free memory.
  288. 9. All RCU list-traversal primitives, which include
  289. rcu_dereference(), list_for_each_entry_rcu(), and
  290. list_for_each_safe_rcu(), must be either within an RCU read-side
  291. critical section or must be protected by appropriate update-side
  292. locks. RCU read-side critical sections are delimited by
  293. rcu_read_lock() and rcu_read_unlock(), or by similar primitives
  294. such as rcu_read_lock_bh() and rcu_read_unlock_bh(), in which
  295. case the matching rcu_dereference() primitive must be used in
  296. order to keep lockdep happy, in this case, rcu_dereference_bh().
  297. The reason that it is permissible to use RCU list-traversal
  298. primitives when the update-side lock is held is that doing so
  299. can be quite helpful in reducing code bloat when common code is
  300. shared between readers and updaters. Additional primitives
  301. are provided for this case, as discussed in lockdep.rst.
  302. One exception to this rule is when data is only ever added to
  303. the linked data structure, and is never removed during any
  304. time that readers might be accessing that structure. In such
  305. cases, READ_ONCE() may be used in place of rcu_dereference()
  306. and the read-side markers (rcu_read_lock() and rcu_read_unlock(),
  307. for example) may be omitted.
  308. 10. Conversely, if you are in an RCU read-side critical section,
  309. and you don't hold the appropriate update-side lock, you *must*
  310. use the "_rcu()" variants of the list macros. Failing to do so
  311. will break Alpha, cause aggressive compilers to generate bad code,
  312. and confuse people trying to understand your code.
  313. 11. Any lock acquired by an RCU callback must be acquired elsewhere
  314. with softirq disabled, e.g., via spin_lock_bh(). Failing to
  315. disable softirq on a given acquisition of that lock will result
  316. in deadlock as soon as the RCU softirq handler happens to run
  317. your RCU callback while interrupting that acquisition's critical
  318. section.
  319. 12. RCU callbacks can be and are executed in parallel. In many cases,
  320. the callback code simply wrappers around kfree(), so that this
  321. is not an issue (or, more accurately, to the extent that it is
  322. an issue, the memory-allocator locking handles it). However,
  323. if the callbacks do manipulate a shared data structure, they
  324. must use whatever locking or other synchronization is required
  325. to safely access and/or modify that data structure.
  326. Do not assume that RCU callbacks will be executed on the same
  327. CPU that executed the corresponding call_rcu(), call_srcu(),
  328. call_rcu_tasks(), or call_rcu_tasks_trace(). For example, if
  329. a given CPU goes offline while having an RCU callback pending,
  330. then that RCU callback will execute on some surviving CPU.
  331. (If this was not the case, a self-spawning RCU callback would
  332. prevent the victim CPU from ever going offline.) Furthermore,
  333. CPUs designated by rcu_nocbs= might well *always* have their
  334. RCU callbacks executed on some other CPUs, in fact, for some
  335. real-time workloads, this is the whole point of using the
  336. rcu_nocbs= kernel boot parameter.
  337. In addition, do not assume that callbacks queued in a given order
  338. will be invoked in that order, even if they all are queued on the
  339. same CPU. Furthermore, do not assume that same-CPU callbacks will
  340. be invoked serially. For example, in recent kernels, CPUs can be
  341. switched between offloaded and de-offloaded callback invocation,
  342. and while a given CPU is undergoing such a switch, its callbacks
  343. might be concurrently invoked by that CPU's softirq handler and
  344. that CPU's rcuo kthread. At such times, that CPU's callbacks
  345. might be executed both concurrently and out of order.
  346. 13. Unlike most flavors of RCU, it *is* permissible to block in an
  347. SRCU read-side critical section (demarked by srcu_read_lock()
  348. and srcu_read_unlock()), hence the "SRCU": "sleepable RCU".
  349. As with RCU, guard(srcu)() and scoped_guard(srcu) forms are
  350. available, and often provide greater ease of use. Please note
  351. that if you don't need to sleep in read-side critical sections,
  352. you should be using RCU rather than SRCU, because RCU is almost
  353. always faster and easier to use than is SRCU.
  354. Also unlike other forms of RCU, explicit initialization
  355. and cleanup is required either at build time via
  356. DEFINE_SRCU(), DEFINE_STATIC_SRCU(), DEFINE_SRCU_FAST(),
  357. or DEFINE_STATIC_SRCU_FAST() or at runtime via either
  358. init_srcu_struct() or init_srcu_struct_fast() and
  359. cleanup_srcu_struct(). These last three are passed a
  360. `struct srcu_struct` that defines the scope of a given
  361. SRCU domain. Once initialized, the srcu_struct is passed
  362. to srcu_read_lock(), srcu_read_unlock() synchronize_srcu(),
  363. synchronize_srcu_expedited(), and call_srcu(). A given
  364. synchronize_srcu() waits only for SRCU read-side critical
  365. sections governed by srcu_read_lock() and srcu_read_unlock()
  366. calls that have been passed the same srcu_struct. This property
  367. is what makes sleeping read-side critical sections tolerable --
  368. a given subsystem delays only its own updates, not those of other
  369. subsystems using SRCU. Therefore, SRCU is less prone to OOM the
  370. system than RCU would be if RCU's read-side critical sections
  371. were permitted to sleep.
  372. The ability to sleep in read-side critical sections does not
  373. come for free. First, corresponding srcu_read_lock() and
  374. srcu_read_unlock() calls must be passed the same srcu_struct.
  375. Second, grace-period-detection overhead is amortized only
  376. over those updates sharing a given srcu_struct, rather than
  377. being globally amortized as they are for other forms of RCU.
  378. Therefore, SRCU should be used in preference to rw_semaphore
  379. only in extremely read-intensive situations, or in situations
  380. requiring SRCU's read-side deadlock immunity or low read-side
  381. realtime latency. You should also consider percpu_rw_semaphore
  382. when you need lightweight readers.
  383. SRCU's expedited primitive (synchronize_srcu_expedited())
  384. never sends IPIs to other CPUs, so it is easier on
  385. real-time workloads than is synchronize_rcu_expedited().
  386. It is also permissible to sleep in RCU Tasks Trace read-side
  387. critical section, which are delimited by rcu_read_lock_trace()
  388. and rcu_read_unlock_trace(). However, this is a specialized
  389. flavor of RCU, and you should not use it without first checking
  390. with its current users. In most cases, you should instead
  391. use SRCU. As with RCU and SRCU, guard(rcu_tasks_trace)() and
  392. scoped_guard(rcu_tasks_trace) are available, and often provide
  393. greater ease of use.
  394. Note that rcu_assign_pointer() relates to SRCU just as it does to
  395. other forms of RCU, but instead of rcu_dereference() you should
  396. use srcu_dereference() in order to avoid lockdep splats.
  397. 14. The whole point of call_rcu(), synchronize_rcu(), and friends
  398. is to wait until all pre-existing readers have finished before
  399. carrying out some otherwise-destructive operation. It is
  400. therefore critically important to *first* remove any path
  401. that readers can follow that could be affected by the
  402. destructive operation, and *only then* invoke call_rcu(),
  403. synchronize_rcu(), or friends.
  404. Because these primitives only wait for pre-existing readers, it
  405. is the caller's responsibility to guarantee that any subsequent
  406. readers will execute safely.
  407. 15. The various RCU read-side primitives do *not* necessarily contain
  408. memory barriers. You should therefore plan for the CPU
  409. and the compiler to freely reorder code into and out of RCU
  410. read-side critical sections. It is the responsibility of the
  411. RCU update-side primitives to deal with this.
  412. For SRCU readers, you can use smp_mb__after_srcu_read_unlock()
  413. immediately after an srcu_read_unlock() to get a full barrier.
  414. 16. Use CONFIG_PROVE_LOCKING, CONFIG_DEBUG_OBJECTS_RCU_HEAD, and the
  415. __rcu sparse checks to validate your RCU code. These can help
  416. find problems as follows:
  417. CONFIG_PROVE_LOCKING:
  418. check that accesses to RCU-protected data structures
  419. are carried out under the proper RCU read-side critical
  420. section, while holding the right combination of locks,
  421. or whatever other conditions are appropriate.
  422. CONFIG_DEBUG_OBJECTS_RCU_HEAD:
  423. check that you don't pass the same object to call_rcu()
  424. (or friends) before an RCU grace period has elapsed
  425. since the last time that you passed that same object to
  426. call_rcu() (or friends).
  427. CONFIG_RCU_STRICT_GRACE_PERIOD:
  428. combine with KASAN to check for pointers leaked out
  429. of RCU read-side critical sections. This Kconfig
  430. option is tough on both performance and scalability,
  431. and so is limited to four-CPU systems.
  432. __rcu sparse checks:
  433. tag the pointer to the RCU-protected data structure
  434. with __rcu, and sparse will warn you if you access that
  435. pointer without the services of one of the variants
  436. of rcu_dereference().
  437. These debugging aids can help you find problems that are
  438. otherwise extremely difficult to spot.
  439. 17. If you pass a callback function defined within a module
  440. to one of call_rcu(), call_srcu(), call_rcu_tasks(), or
  441. call_rcu_tasks_trace(), then it is necessary to wait for all
  442. pending callbacks to be invoked before unloading that module.
  443. Note that it is absolutely *not* sufficient to wait for a grace
  444. period! For example, synchronize_rcu() implementation is *not*
  445. guaranteed to wait for callbacks registered on other CPUs via
  446. call_rcu(). Or even on the current CPU if that CPU recently
  447. went offline and came back online.
  448. You instead need to use one of the barrier functions:
  449. - call_rcu() -> rcu_barrier()
  450. - call_srcu() -> srcu_barrier()
  451. - call_rcu_tasks() -> rcu_barrier_tasks()
  452. - call_rcu_tasks_trace() -> rcu_barrier_tasks_trace()
  453. However, these barrier functions are absolutely *not* guaranteed
  454. to wait for a grace period. For example, if there are no
  455. call_rcu() callbacks queued anywhere in the system, rcu_barrier()
  456. can and will return immediately.
  457. So if you need to wait for both a grace period and for all
  458. pre-existing callbacks, you will need to invoke both functions,
  459. with the pair depending on the flavor of RCU:
  460. - Either synchronize_rcu() or synchronize_rcu_expedited(),
  461. together with rcu_barrier()
  462. - Either synchronize_srcu() or synchronize_srcu_expedited(),
  463. together with and srcu_barrier()
  464. - synchronize_rcu_tasks() and rcu_barrier_tasks()
  465. - synchronize_tasks_trace() and rcu_barrier_tasks_trace()
  466. If necessary, you can use something like workqueues to execute
  467. the requisite pair of functions concurrently.
  468. See rcubarrier.rst for more information.