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Linux/tools/memory-model/Documentation/access-marking.txt

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  1 MARKING SHARED-MEMORY ACCESSES
  2 ==============================
  3 
  4 This document provides guidelines for marking intentionally concurrent
  5 normal accesses to shared memory, that is "normal" as in accesses that do
  6 not use read-modify-write atomic operations.  It also describes how to
  7 document these accesses, both with comments and with special assertions
  8 processed by the Kernel Concurrency Sanitizer (KCSAN).  This discussion
  9 builds on an earlier LWN article [1] and Linux Foundation mentorship
 10 session [2].
 11 
 12 
 13 ACCESS-MARKING OPTIONS
 14 ======================
 15 
 16 The Linux kernel provides the following access-marking options:
 17 
 18 1.      Plain C-language accesses (unmarked), for example, "a = b;"
 19 
 20 2.      Data-race marking, for example, "data_race(a = b);"
 21 
 22 3.      READ_ONCE(), for example, "a = READ_ONCE(b);"
 23         The various forms of atomic_read() also fit in here.
 24 
 25 4.      WRITE_ONCE(), for example, "WRITE_ONCE(a, b);"
 26         The various forms of atomic_set() also fit in here.
 27 
 28 5.      __data_racy, for example "int __data_racy a;"
 29 
 30 6.      KCSAN's negative-marking assertions, ASSERT_EXCLUSIVE_ACCESS()
 31         and ASSERT_EXCLUSIVE_WRITER(), are described in the
 32         "ACCESS-DOCUMENTATION OPTIONS" section below.
 33 
 34 These may be used in combination, as shown in this admittedly improbable
 35 example:
 36 
 37         WRITE_ONCE(a, b + data_race(c + d) + READ_ONCE(e));
 38 
 39 Neither plain C-language accesses nor data_race() (#1 and #2 above) place
 40 any sort of constraint on the compiler's choice of optimizations [3].
 41 In contrast, READ_ONCE() and WRITE_ONCE() (#3 and #4 above) restrict the
 42 compiler's use of code-motion and common-subexpression optimizations.
 43 Therefore, if a given access is involved in an intentional data race,
 44 using READ_ONCE() for loads and WRITE_ONCE() for stores is usually
 45 preferable to data_race(), which in turn is usually preferable to plain
 46 C-language accesses.  It is permissible to combine #2 and #3, for example,
 47 data_race(READ_ONCE(a)), which will both restrict compiler optimizations
 48 and disable KCSAN diagnostics.
 49 
 50 KCSAN will complain about many types of data races involving plain
 51 C-language accesses, but marking all accesses involved in a given data
 52 race with one of data_race(), READ_ONCE(), or WRITE_ONCE(), will prevent
 53 KCSAN from complaining.  Of course, lack of KCSAN complaints does not
 54 imply correct code.  Therefore, please take a thoughtful approach
 55 when responding to KCSAN complaints.  Churning the code base with
 56 ill-considered additions of data_race(), READ_ONCE(), and WRITE_ONCE()
 57 is unhelpful.
 58 
 59 In fact, the following sections describe situations where use of
 60 data_race() and even plain C-language accesses is preferable to
 61 READ_ONCE() and WRITE_ONCE().
 62 
 63 
 64 Use of the data_race() Macro
 65 ----------------------------
 66 
 67 Here are some situations where data_race() should be used instead of
 68 READ_ONCE() and WRITE_ONCE():
 69 
 70 1.      Data-racy loads from shared variables whose values are used only
 71         for diagnostic purposes.
 72 
 73 2.      Data-racy reads whose values are checked against marked reload.
 74 
 75 3.      Reads whose values feed into error-tolerant heuristics.
 76 
 77 4.      Writes setting values that feed into error-tolerant heuristics.
 78 
 79 
 80 Data-Racy Reads for Approximate Diagnostics
 81 
 82 Approximate diagnostics include lockdep reports, monitoring/statistics
 83 (including /proc and /sys output), WARN*()/BUG*() checks whose return
 84 values are ignored, and other situations where reads from shared variables
 85 are not an integral part of the core concurrency design.
 86 
 87 In fact, use of data_race() instead READ_ONCE() for these diagnostic
 88 reads can enable better checking of the remaining accesses implementing
 89 the core concurrency design.  For example, suppose that the core design
 90 prevents any non-diagnostic reads from shared variable x from running
 91 concurrently with updates to x.  Then using plain C-language writes
 92 to x allows KCSAN to detect reads from x from within regions of code
 93 that fail to exclude the updates.  In this case, it is important to use
 94 data_race() for the diagnostic reads because otherwise KCSAN would give
 95 false-positive warnings about these diagnostic reads.
 96 
 97 If it is necessary to both restrict compiler optimizations and disable
 98 KCSAN diagnostics, use both data_race() and READ_ONCE(), for example,
 99 data_race(READ_ONCE(a)).
100 
101 In theory, plain C-language loads can also be used for this use case.
102 However, in practice this will have the disadvantage of causing KCSAN
103 to generate false positives because KCSAN will have no way of knowing
104 that the resulting data race was intentional.
105 
106 
107 Data-Racy Reads That Are Checked Against Marked Reload
108 
109 The values from some reads are not implicitly trusted.  They are instead
110 fed into some operation that checks the full value against a later marked
111 load from memory, which means that the occasional arbitrarily bogus value
112 is not a problem.  For example, if a bogus value is fed into cmpxchg(),
113 all that happens is that this cmpxchg() fails, which normally results
114 in a retry.  Unless the race condition that resulted in the bogus value
115 recurs, this retry will with high probability succeed, so no harm done.
116 
117 However, please keep in mind that a data_race() load feeding into
118 a cmpxchg_relaxed() might still be subject to load fusing on some
119 architectures.  Therefore, it is best to capture the return value from
120 the failing cmpxchg() for the next iteration of the loop, an approach
121 that provides the compiler much less scope for mischievous optimizations.
122 Capturing the return value from cmpxchg() also saves a memory reference
123 in many cases.
124 
125 In theory, plain C-language loads can also be used for this use case.
126 However, in practice this will have the disadvantage of causing KCSAN
127 to generate false positives because KCSAN will have no way of knowing
128 that the resulting data race was intentional.
129 
130 
131 Reads Feeding Into Error-Tolerant Heuristics
132 
133 Values from some reads feed into heuristics that can tolerate occasional
134 errors.  Such reads can use data_race(), thus allowing KCSAN to focus on
135 the other accesses to the relevant shared variables.  But please note
136 that data_race() loads are subject to load fusing, which can result in
137 consistent errors, which in turn are quite capable of breaking heuristics.
138 Therefore use of data_race() should be limited to cases where some other
139 code (such as a barrier() call) will force the occasional reload.
140 
141 Note that this use case requires that the heuristic be able to handle
142 any possible error.  In contrast, if the heuristics might be fatally
143 confused by one or more of the possible erroneous values, use READ_ONCE()
144 instead of data_race().
145 
146 In theory, plain C-language loads can also be used for this use case.
147 However, in practice this will have the disadvantage of causing KCSAN
148 to generate false positives because KCSAN will have no way of knowing
149 that the resulting data race was intentional.
150 
151 
152 Writes Setting Values Feeding Into Error-Tolerant Heuristics
153 
154 The values read into error-tolerant heuristics come from somewhere,
155 for example, from sysfs.  This means that some code in sysfs writes
156 to this same variable, and these writes can also use data_race().
157 After all, if the heuristic can tolerate the occasional bogus value
158 due to compiler-mangled reads, it can also tolerate the occasional
159 compiler-mangled write, at least assuming that the proper value is in
160 place once the write completes.
161 
162 Plain C-language stores can also be used for this use case.  However,
163 in kernels built with CONFIG_KCSAN_ASSUME_PLAIN_WRITES_ATOMIC=n, this
164 will have the disadvantage of causing KCSAN to generate false positives
165 because KCSAN will have no way of knowing that the resulting data race
166 was intentional.
167 
168 
169 Use of Plain C-Language Accesses
170 --------------------------------
171 
172 Here are some example situations where plain C-language accesses should
173 used instead of READ_ONCE(), WRITE_ONCE(), and data_race():
174 
175 1.      Accesses protected by mutual exclusion, including strict locking
176         and sequence locking.
177 
178 2.      Initialization-time and cleanup-time accesses.  This covers a
179         wide variety of situations, including the uniprocessor phase of
180         system boot, variables to be used by not-yet-spawned kthreads,
181         structures not yet published to reference-counted or RCU-protected
182         data structures, and the cleanup side of any of these situations.
183 
184 3.      Per-CPU variables that are not accessed from other CPUs.
185 
186 4.      Private per-task variables, including on-stack variables, some
187         fields in the task_struct structure, and task-private heap data.
188 
189 5.      Any other loads for which there is not supposed to be a concurrent
190         store to that same variable.
191 
192 6.      Any other stores for which there should be neither concurrent
193         loads nor concurrent stores to that same variable.
194 
195         But note that KCSAN makes two explicit exceptions to this rule
196         by default, refraining from flagging plain C-language stores:
197 
198         a.      No matter what.  You can override this default by building
199                 with CONFIG_KCSAN_ASSUME_PLAIN_WRITES_ATOMIC=n.
200 
201         b.      When the store writes the value already contained in
202                 that variable.  You can override this default by building
203                 with CONFIG_KCSAN_REPORT_VALUE_CHANGE_ONLY=n.
204 
205         c.      When one of the stores is in an interrupt handler and
206                 the other in the interrupted code.  You can override this
207                 default by building with CONFIG_KCSAN_INTERRUPT_WATCHER=y.
208 
209 Note that it is important to use plain C-language accesses in these cases,
210 because doing otherwise prevents KCSAN from detecting violations of your
211 code's synchronization rules.
212 
213 
214 Use of __data_racy
215 ------------------
216 
217 Adding the __data_racy type qualifier to the declaration of a variable
218 causes KCSAN to treat all accesses to that variable as if they were
219 enclosed by data_race().  However, __data_racy does not affect the
220 compiler, though one could imagine hardened kernel builds treating the
221 __data_racy type qualifier as if it was the volatile keyword.
222 
223 Note well that __data_racy is subject to the same pointer-declaration
224 rules as are other type qualifiers such as const and volatile.
225 For example:
226 
227         int __data_racy *p; // Pointer to data-racy data.
228         int *__data_racy p; // Data-racy pointer to non-data-racy data.
229 
230 
231 ACCESS-DOCUMENTATION OPTIONS
232 ============================
233 
234 It is important to comment marked accesses so that people reading your
235 code, yourself included, are reminded of the synchronization design.
236 However, it is even more important to comment plain C-language accesses
237 that are intentionally involved in data races.  Such comments are
238 needed to remind people reading your code, again, yourself included,
239 of how the compiler has been prevented from optimizing those accesses
240 into concurrency bugs.
241 
242 It is also possible to tell KCSAN about your synchronization design.
243 For example, ASSERT_EXCLUSIVE_ACCESS(foo) tells KCSAN that any
244 concurrent access to variable foo by any other CPU is an error, even
245 if that concurrent access is marked with READ_ONCE().  In addition,
246 ASSERT_EXCLUSIVE_WRITER(foo) tells KCSAN that although it is OK for there
247 to be concurrent reads from foo from other CPUs, it is an error for some
248 other CPU to be concurrently writing to foo, even if that concurrent
249 write is marked with data_race() or WRITE_ONCE().
250 
251 Note that although KCSAN will call out data races involving either
252 ASSERT_EXCLUSIVE_ACCESS() or ASSERT_EXCLUSIVE_WRITER() on the one hand
253 and data_race() writes on the other, KCSAN will not report the location
254 of these data_race() writes.
255 
256 
257 EXAMPLES
258 ========
259 
260 As noted earlier, the goal is to prevent the compiler from destroying
261 your concurrent algorithm, to help the human reader, and to inform
262 KCSAN of aspects of your concurrency design.  This section looks at a
263 few examples showing how this can be done.
264 
265 
266 Lock Protection With Lockless Diagnostic Access
267 -----------------------------------------------
268 
269 For example, suppose a shared variable "foo" is read only while a
270 reader-writer spinlock is read-held, written only while that same
271 spinlock is write-held, except that it is also read locklessly for
272 diagnostic purposes.  The code might look as follows:
273 
274         int foo;
275         DEFINE_RWLOCK(foo_rwlock);
276 
277         void update_foo(int newval)
278         {
279                 write_lock(&foo_rwlock);
280                 foo = newval;
281                 do_something(newval);
282                 write_unlock(&foo_rwlock);
283         }
284 
285         int read_foo(void)
286         {
287                 int ret;
288 
289                 read_lock(&foo_rwlock);
290                 do_something_else();
291                 ret = foo;
292                 read_unlock(&foo_rwlock);
293                 return ret;
294         }
295 
296         void read_foo_diagnostic(void)
297         {
298                 pr_info("Current value of foo: %d\n", data_race(foo));
299         }
300 
301 The reader-writer lock prevents the compiler from introducing concurrency
302 bugs into any part of the main algorithm using foo, which means that
303 the accesses to foo within both update_foo() and read_foo() can (and
304 should) be plain C-language accesses.  One benefit of making them be
305 plain C-language accesses is that KCSAN can detect any erroneous lockless
306 reads from or updates to foo.  The data_race() in read_foo_diagnostic()
307 tells KCSAN that data races are expected, and should be silently
308 ignored.  This data_race() also tells the human reading the code that
309 read_foo_diagnostic() might sometimes return a bogus value.
310 
311 If it is necessary to suppress compiler optimization and also detect
312 buggy lockless writes, read_foo_diagnostic() can be updated as follows:
313 
314         void read_foo_diagnostic(void)
315         {
316                 pr_info("Current value of foo: %d\n", data_race(READ_ONCE(foo)));
317         }
318 
319 Alternatively, given that KCSAN is to ignore all accesses in this function,
320 this function can be marked __no_kcsan and the data_race() can be dropped:
321 
322         void __no_kcsan read_foo_diagnostic(void)
323         {
324                 pr_info("Current value of foo: %d\n", READ_ONCE(foo));
325         }
326 
327 However, in order for KCSAN to detect buggy lockless writes, your kernel
328 must be built with CONFIG_KCSAN_ASSUME_PLAIN_WRITES_ATOMIC=n.  If you
329 need KCSAN to detect such a write even if that write did not change
330 the value of foo, you also need CONFIG_KCSAN_REPORT_VALUE_CHANGE_ONLY=n.
331 If you need KCSAN to detect such a write happening in an interrupt handler
332 running on the same CPU doing the legitimate lock-protected write, you
333 also need CONFIG_KCSAN_INTERRUPT_WATCHER=y.  With some or all of these
334 Kconfig options set properly, KCSAN can be quite helpful, although
335 it is not necessarily a full replacement for hardware watchpoints.
336 On the other hand, neither are hardware watchpoints a full replacement
337 for KCSAN because it is not always easy to tell hardware watchpoint to
338 conditionally trap on accesses.
339 
340 
341 Lock-Protected Writes With Lockless Reads
342 -----------------------------------------
343 
344 For another example, suppose a shared variable "foo" is updated only
345 while holding a spinlock, but is read locklessly.  The code might look
346 as follows:
347 
348         int foo;
349         DEFINE_SPINLOCK(foo_lock);
350 
351         void update_foo(int newval)
352         {
353                 spin_lock(&foo_lock);
354                 WRITE_ONCE(foo, newval);
355                 ASSERT_EXCLUSIVE_WRITER(foo);
356                 do_something(newval);
357                 spin_unlock(&foo_wlock);
358         }
359 
360         int read_foo(void)
361         {
362                 do_something_else();
363                 return READ_ONCE(foo);
364         }
365 
366 Because foo is read locklessly, all accesses are marked.  The purpose
367 of the ASSERT_EXCLUSIVE_WRITER() is to allow KCSAN to check for a buggy
368 concurrent write, whether marked or not.
369 
370 
371 Lock-Protected Writes With Heuristic Lockless Reads
372 ---------------------------------------------------
373 
374 For another example, suppose that the code can normally make use of
375 a per-data-structure lock, but there are times when a global lock
376 is required.  These times are indicated via a global flag.  The code
377 might look as follows, and is based loosely on nf_conntrack_lock(),
378 nf_conntrack_all_lock(), and nf_conntrack_all_unlock():
379 
380         bool global_flag;
381         DEFINE_SPINLOCK(global_lock);
382         struct foo {
383                 spinlock_t f_lock;
384                 int f_data;
385         };
386 
387         /* All foo structures are in the following array. */
388         int nfoo;
389         struct foo *foo_array;
390 
391         void do_something_locked(struct foo *fp)
392         {
393                 /* This works even if data_race() returns nonsense. */
394                 if (!data_race(global_flag)) {
395                         spin_lock(&fp->f_lock);
396                         if (!smp_load_acquire(&global_flag)) {
397                                 do_something(fp);
398                                 spin_unlock(&fp->f_lock);
399                                 return;
400                         }
401                         spin_unlock(&fp->f_lock);
402                 }
403                 spin_lock(&global_lock);
404                 /* global_lock held, thus global flag cannot be set. */
405                 spin_lock(&fp->f_lock);
406                 spin_unlock(&global_lock);
407                 /*
408                  * global_flag might be set here, but begin_global()
409                  * will wait for ->f_lock to be released.
410                  */
411                 do_something(fp);
412                 spin_unlock(&fp->f_lock);
413         }
414 
415         void begin_global(void)
416         {
417                 int i;
418 
419                 spin_lock(&global_lock);
420                 WRITE_ONCE(global_flag, true);
421                 for (i = 0; i < nfoo; i++) {
422                         /*
423                          * Wait for pre-existing local locks.  One at
424                          * a time to avoid lockdep limitations.
425                          */
426                         spin_lock(&fp->f_lock);
427                         spin_unlock(&fp->f_lock);
428                 }
429         }
430 
431         void end_global(void)
432         {
433                 smp_store_release(&global_flag, false);
434                 spin_unlock(&global_lock);
435         }
436 
437 All code paths leading from the do_something_locked() function's first
438 read from global_flag acquire a lock, so endless load fusing cannot
439 happen.
440 
441 If the value read from global_flag is true, then global_flag is
442 rechecked while holding ->f_lock, which, if global_flag is now false,
443 prevents begin_global() from completing.  It is therefore safe to invoke
444 do_something().
445 
446 Otherwise, if either value read from global_flag is true, then after
447 global_lock is acquired global_flag must be false.  The acquisition of
448 ->f_lock will prevent any call to begin_global() from returning, which
449 means that it is safe to release global_lock and invoke do_something().
450 
451 For this to work, only those foo structures in foo_array[] may be passed
452 to do_something_locked().  The reason for this is that the synchronization
453 with begin_global() relies on momentarily holding the lock of each and
454 every foo structure.
455 
456 The smp_load_acquire() and smp_store_release() are required because
457 changes to a foo structure between calls to begin_global() and
458 end_global() are carried out without holding that structure's ->f_lock.
459 The smp_load_acquire() and smp_store_release() ensure that the next
460 invocation of do_something() from do_something_locked() will see those
461 changes.
462 
463 
464 Lockless Reads and Writes
465 -------------------------
466 
467 For another example, suppose a shared variable "foo" is both read and
468 updated locklessly.  The code might look as follows:
469 
470         int foo;
471 
472         int update_foo(int newval)
473         {
474                 int ret;
475 
476                 ret = xchg(&foo, newval);
477                 do_something(newval);
478                 return ret;
479         }
480 
481         int read_foo(void)
482         {
483                 do_something_else();
484                 return READ_ONCE(foo);
485         }
486 
487 Because foo is accessed locklessly, all accesses are marked.  It does
488 not make sense to use ASSERT_EXCLUSIVE_WRITER() in this case because
489 there really can be concurrent lockless writers.  KCSAN would
490 flag any concurrent plain C-language reads from foo, and given
491 CONFIG_KCSAN_ASSUME_PLAIN_WRITES_ATOMIC=n, also any concurrent plain
492 C-language writes to foo.
493 
494 
495 Lockless Reads and Writes, But With Single-Threaded Initialization
496 ------------------------------------------------------------------
497 
498 For yet another example, suppose that foo is initialized in a
499 single-threaded manner, but that a number of kthreads are then created
500 that locklessly and concurrently access foo.  Some snippets of this code
501 might look as follows:
502 
503         int foo;
504 
505         void initialize_foo(int initval, int nkthreads)
506         {
507                 int i;
508 
509                 foo = initval;
510                 ASSERT_EXCLUSIVE_ACCESS(foo);
511                 for (i = 0; i < nkthreads; i++)
512                         kthread_run(access_foo_concurrently, ...);
513         }
514 
515         /* Called from access_foo_concurrently(). */
516         int update_foo(int newval)
517         {
518                 int ret;
519 
520                 ret = xchg(&foo, newval);
521                 do_something(newval);
522                 return ret;
523         }
524 
525         /* Also called from access_foo_concurrently(). */
526         int read_foo(void)
527         {
528                 do_something_else();
529                 return READ_ONCE(foo);
530         }
531 
532 The initialize_foo() uses a plain C-language write to foo because there
533 are not supposed to be concurrent accesses during initialization.  The
534 ASSERT_EXCLUSIVE_ACCESS() allows KCSAN to flag buggy concurrent unmarked
535 reads, and the ASSERT_EXCLUSIVE_ACCESS() call further allows KCSAN to
536 flag buggy concurrent writes, even if:  (1) Those writes are marked or
537 (2) The kernel was built with CONFIG_KCSAN_ASSUME_PLAIN_WRITES_ATOMIC=y.
538 
539 
540 Checking Stress-Test Race Coverage
541 ----------------------------------
542 
543 When designing stress tests it is important to ensure that race conditions
544 of interest really do occur.  For example, consider the following code
545 fragment:
546 
547         int foo;
548 
549         int update_foo(int newval)
550         {
551                 return xchg(&foo, newval);
552         }
553 
554         int xor_shift_foo(int shift, int mask)
555         {
556                 int old, new, newold;
557 
558                 newold = data_race(foo); /* Checked by cmpxchg(). */
559                 do {
560                         old = newold;
561                         new = (old << shift) ^ mask;
562                         newold = cmpxchg(&foo, old, new);
563                 } while (newold != old);
564                 return old;
565         }
566 
567         int read_foo(void)
568         {
569                 return READ_ONCE(foo);
570         }
571 
572 If it is possible for update_foo(), xor_shift_foo(), and read_foo() to be
573 invoked concurrently, the stress test should force this concurrency to
574 actually happen.  KCSAN can evaluate the stress test when the above code
575 is modified to read as follows:
576 
577         int foo;
578 
579         int update_foo(int newval)
580         {
581                 ASSERT_EXCLUSIVE_ACCESS(foo);
582                 return xchg(&foo, newval);
583         }
584 
585         int xor_shift_foo(int shift, int mask)
586         {
587                 int old, new, newold;
588 
589                 newold = data_race(foo); /* Checked by cmpxchg(). */
590                 do {
591                         old = newold;
592                         new = (old << shift) ^ mask;
593                         ASSERT_EXCLUSIVE_ACCESS(foo);
594                         newold = cmpxchg(&foo, old, new);
595                 } while (newold != old);
596                 return old;
597         }
598 
599 
600         int read_foo(void)
601         {
602                 ASSERT_EXCLUSIVE_ACCESS(foo);
603                 return READ_ONCE(foo);
604         }
605 
606 If a given stress-test run does not result in KCSAN complaints from
607 each possible pair of ASSERT_EXCLUSIVE_ACCESS() invocations, the
608 stress test needs improvement.  If the stress test was to be evaluated
609 on a regular basis, it would be wise to place the above instances of
610 ASSERT_EXCLUSIVE_ACCESS() under #ifdef so that they did not result in
611 false positives when not evaluating the stress test.
612 
613 
614 REFERENCES
615 ==========
616 
617 [1] "Concurrency bugs should fear the big bad data-race detector (part 2)"
618     https://lwn.net/Articles/816854/
619 
620 [2] "The Kernel Concurrency Sanitizer"
621     https://www.linuxfoundation.org/webinars/the-kernel-concurrency-sanitizer
622 
623 [3] "Who's afraid of a big bad optimizing compiler?"
624     https://lwn.net/Articles/793253/

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