1 Semantics and Behavior of Atomic and
6 This document is intended to serve as a guide to Linux port
7 maintainers on how to implement atomic counter, bitops, and spinlock
10 The atomic_t type should be defined as a signed integer.
11 Also, it should be made opaque such that any kind of cast to a normal
12 C integer type will fail. Something like the following should
15 typedef struct { volatile int counter; } atomic_t;
17 Historically, counter has been declared volatile. This is now discouraged.
18 See Documentation/volatile-considered-harmful.txt for the complete rationale.
20 local_t is very similar to atomic_t. If the counter is per CPU and only
21 updated by one CPU, local_t is probably more appropriate. Please see
22 Documentation/local_ops.txt for the semantics of local_t.
24 The first operations to implement for atomic_t's are the initializers and
27 #define ATOMIC_INIT(i) { (i) }
28 #define atomic_set(v, i) ((v)->counter = (i))
30 The first macro is used in definitions, such as:
32 static atomic_t my_counter = ATOMIC_INIT(1);
34 The initializer is atomic in that the return values of the atomic operations
35 are guaranteed to be correct reflecting the initialized value if the
36 initializer is used before runtime. If the initializer is used at runtime, a
37 proper implicit or explicit read memory barrier is needed before reading the
38 value with atomic_read from another thread.
40 The second interface can be used at runtime, as in:
42 struct foo { atomic_t counter; };
47 k = kmalloc(sizeof(*k), GFP_KERNEL);
50 atomic_set(&k->counter, 0);
52 The setting is atomic in that the return values of the atomic operations by
53 all threads are guaranteed to be correct reflecting either the value that has
54 been set with this operation or set with another operation. A proper implicit
55 or explicit memory barrier is needed before the value set with the operation
56 is guaranteed to be readable with atomic_read from another thread.
60 #define atomic_read(v) ((v)->counter)
62 which simply reads the counter value currently visible to the calling thread.
63 The read is atomic in that the return value is guaranteed to be one of the
64 values initialized or modified with the interface operations if a proper
65 implicit or explicit memory barrier is used after possible runtime
66 initialization by any other thread and the value is modified only with the
67 interface operations. atomic_read does not guarantee that the runtime
68 initialization by any other thread is visible yet, so the user of the
69 interface must take care of that with a proper implicit or explicit memory
72 *** WARNING: atomic_read() and atomic_set() DO NOT IMPLY BARRIERS! ***
74 Some architectures may choose to use the volatile keyword, barriers, or inline
75 assembly to guarantee some degree of immediacy for atomic_read() and
76 atomic_set(). This is not uniformly guaranteed, and may change in the future,
77 so all users of atomic_t should treat atomic_read() and atomic_set() as simple
78 C statements that may be reordered or optimized away entirely by the compiler
79 or processor, and explicitly invoke the appropriate compiler and/or memory
80 barrier for each use case. Failure to do so will result in code that may
81 suddenly break when used with different architectures or compiler
82 optimizations, or even changes in unrelated code which changes how the
83 compiler optimizes the section accessing atomic_t variables.
85 *** YOU HAVE BEEN WARNED! ***
87 Now, we move onto the atomic operation interfaces typically implemented with
88 the help of assembly code.
90 void atomic_add(int i, atomic_t *v);
91 void atomic_sub(int i, atomic_t *v);
92 void atomic_inc(atomic_t *v);
93 void atomic_dec(atomic_t *v);
95 These four routines add and subtract integral values to/from the given
96 atomic_t value. The first two routines pass explicit integers by
97 which to make the adjustment, whereas the latter two use an implicit
98 adjustment value of "1".
100 One very important aspect of these two routines is that they DO NOT
101 require any explicit memory barriers. They need only perform the
102 atomic_t counter update in an SMP safe manner.
106 int atomic_inc_return(atomic_t *v);
107 int atomic_dec_return(atomic_t *v);
109 These routines add 1 and subtract 1, respectively, from the given
110 atomic_t and return the new counter value after the operation is
113 Unlike the above routines, it is required that explicit memory
114 barriers are performed before and after the operation. It must be
115 done such that all memory operations before and after the atomic
116 operation calls are strongly ordered with respect to the atomic
119 For example, it should behave as if a smp_mb() call existed both
120 before and after the atomic operation.
122 If the atomic instructions used in an implementation provide explicit
123 memory barrier semantics which satisfy the above requirements, that is
128 int atomic_add_return(int i, atomic_t *v);
129 int atomic_sub_return(int i, atomic_t *v);
131 These behave just like atomic_{inc,dec}_return() except that an
132 explicit counter adjustment is given instead of the implicit "1".
133 This means that like atomic_{inc,dec}_return(), the memory barrier
134 semantics are required.
138 int atomic_inc_and_test(atomic_t *v);
139 int atomic_dec_and_test(atomic_t *v);
141 These two routines increment and decrement by 1, respectively, the
142 given atomic counter. They return a boolean indicating whether the
143 resulting counter value was zero or not.
145 It requires explicit memory barrier semantics around the operation as
148 int atomic_sub_and_test(int i, atomic_t *v);
150 This is identical to atomic_dec_and_test() except that an explicit
151 decrement is given instead of the implicit "1". It requires explicit
152 memory barrier semantics around the operation.
154 int atomic_add_negative(int i, atomic_t *v);
156 The given increment is added to the given atomic counter value. A
157 boolean is return which indicates whether the resulting counter value
158 is negative. It requires explicit memory barrier semantics around the
163 int atomic_xchg(atomic_t *v, int new);
165 This performs an atomic exchange operation on the atomic variable v, setting
166 the given new value. It returns the old value that the atomic variable v had
167 just before the operation.
169 int atomic_cmpxchg(atomic_t *v, int old, int new);
171 This performs an atomic compare exchange operation on the atomic value v,
172 with the given old and new values. Like all atomic_xxx operations,
173 atomic_cmpxchg will only satisfy its atomicity semantics as long as all
174 other accesses of *v are performed through atomic_xxx operations.
176 atomic_cmpxchg requires explicit memory barriers around the operation.
178 The semantics for atomic_cmpxchg are the same as those defined for 'cas'
183 int atomic_add_unless(atomic_t *v, int a, int u);
185 If the atomic value v is not equal to u, this function adds a to v, and
186 returns non zero. If v is equal to u then it returns zero. This is done as
189 atomic_add_unless requires explicit memory barriers around the operation
190 unless it fails (returns 0).
192 atomic_inc_not_zero, equivalent to atomic_add_unless(v, 1, 0)
195 If a caller requires memory barrier semantics around an atomic_t
196 operation which does not return a value, a set of interfaces are
197 defined which accomplish this:
199 void smp_mb__before_atomic_dec(void);
200 void smp_mb__after_atomic_dec(void);
201 void smp_mb__before_atomic_inc(void);
202 void smp_mb__after_atomic_inc(void);
204 For example, smp_mb__before_atomic_dec() can be used like so:
207 smp_mb__before_atomic_dec();
208 atomic_dec(&obj->ref_count);
210 It makes sure that all memory operations preceding the atomic_dec()
211 call are strongly ordered with respect to the atomic counter
212 operation. In the above example, it guarantees that the assignment of
213 "1" to obj->dead will be globally visible to other cpus before the
214 atomic counter decrement.
216 Without the explicit smp_mb__before_atomic_dec() call, the
217 implementation could legally allow the atomic counter update visible
218 to other cpus before the "obj->dead = 1;" assignment.
220 The other three interfaces listed are used to provide explicit
221 ordering with respect to memory operations after an atomic_dec() call
222 (smp_mb__after_atomic_dec()) and around atomic_inc() calls
223 (smp_mb__{before,after}_atomic_inc()).
225 A missing memory barrier in the cases where they are required by the
226 atomic_t implementation above can have disastrous results. Here is
227 an example, which follows a pattern occurring frequently in the Linux
228 kernel. It is the use of atomic counters to implement reference
229 counting, and it works such that once the counter falls to zero it can
230 be guaranteed that no other entity can be accessing the object:
232 static void obj_list_add(struct obj *obj, struct list_head *head)
235 list_add(&obj->list, head);
238 static void obj_list_del(struct obj *obj)
240 list_del(&obj->list);
244 static void obj_destroy(struct obj *obj)
250 struct obj *obj_list_peek(struct list_head *head)
252 if (!list_empty(head)) {
255 obj = list_entry(head->next, struct obj, list);
256 atomic_inc(&obj->refcnt);
266 spin_lock(&global_list_lock);
267 obj = obj_list_peek(&global_list);
268 spin_unlock(&global_list_lock);
272 if (atomic_dec_and_test(&obj->refcnt))
277 void obj_timeout(struct obj *obj)
279 spin_lock(&global_list_lock);
281 spin_unlock(&global_list_lock);
283 if (atomic_dec_and_test(&obj->refcnt))
287 (This is a simplification of the ARP queue management in the
288 generic neighbour discover code of the networking. Olaf Kirch
289 found a bug wrt. memory barriers in kfree_skb() that exposed
290 the atomic_t memory barrier requirements quite clearly.)
292 Given the above scheme, it must be the case that the obj->active
293 update done by the obj list deletion be visible to other processors
294 before the atomic counter decrement is performed.
296 Otherwise, the counter could fall to zero, yet obj->active would still
297 be set, thus triggering the assertion in obj_destroy(). The error
298 sequence looks like this:
301 obj_poke() obj_timeout()
302 obj = obj_list_peek();
303 ... gains ref to obj, refcnt=2
306 ... visibility delayed ...
307 atomic_dec_and_test()
308 ... refcnt drops to 1 ...
309 atomic_dec_and_test()
310 ... refcount drops to 0 ...
312 BUG() triggers since obj->active
314 obj->active update visibility occurs
316 With the memory barrier semantics required of the atomic_t operations
317 which return values, the above sequence of memory visibility can never
318 happen. Specifically, in the above case the atomic_dec_and_test()
319 counter decrement would not become globally visible until the
320 obj->active update does.
322 As a historical note, 32-bit Sparc used to only allow usage of
323 24-bits of its atomic_t type. This was because it used 8 bits
324 as a spinlock for SMP safety. Sparc32 lacked a "compare and swap"
325 type instruction. However, 32-bit Sparc has since been moved over
326 to a "hash table of spinlocks" scheme, that allows the full 32-bit
327 counter to be realized. Essentially, an array of spinlocks are
328 indexed into based upon the address of the atomic_t being operated
329 on, and that lock protects the atomic operation. Parisc uses the
332 Another note is that the atomic_t operations returning values are
333 extremely slow on an old 386.
335 We will now cover the atomic bitmask operations. You will find that
336 their SMP and memory barrier semantics are similar in shape and scope
337 to the atomic_t ops above.
339 Native atomic bit operations are defined to operate on objects aligned
340 to the size of an "unsigned long" C data type, and are least of that
341 size. The endianness of the bits within each "unsigned long" are the
342 native endianness of the cpu.
344 void set_bit(unsigned long nr, volatile unsigned long *addr);
345 void clear_bit(unsigned long nr, volatile unsigned long *addr);
346 void change_bit(unsigned long nr, volatile unsigned long *addr);
348 These routines set, clear, and change, respectively, the bit number
349 indicated by "nr" on the bit mask pointed to by "ADDR".
351 They must execute atomically, yet there are no implicit memory barrier
352 semantics required of these interfaces.
354 int test_and_set_bit(unsigned long nr, volatile unsigned long *addr);
355 int test_and_clear_bit(unsigned long nr, volatile unsigned long *addr);
356 int test_and_change_bit(unsigned long nr, volatile unsigned long *addr);
358 Like the above, except that these routines return a boolean which
359 indicates whether the changed bit was set _BEFORE_ the atomic bit
362 WARNING! It is incredibly important that the value be a boolean,
363 ie. "0" or "1". Do not try to be fancy and save a few instructions by
364 declaring the above to return "long" and just returning something like
365 "old_val & mask" because that will not work.
367 For one thing, this return value gets truncated to int in many code
368 paths using these interfaces, so on 64-bit if the bit is set in the
369 upper 32-bits then testers will never see that.
371 One great example of where this problem crops up are the thread_info
372 flag operations. Routines such as test_and_set_ti_thread_flag() chop
373 the return value into an int. There are other places where things
374 like this occur as well.
376 These routines, like the atomic_t counter operations returning values,
377 require explicit memory barrier semantics around their execution. All
378 memory operations before the atomic bit operation call must be made
379 visible globally before the atomic bit operation is made visible.
380 Likewise, the atomic bit operation must be visible globally before any
381 subsequent memory operation is made visible. For example:
384 if (test_and_set_bit(0, &obj->flags))
388 The implementation of test_and_set_bit() must guarantee that
389 "obj->dead = 1;" is visible to cpus before the atomic memory operation
390 done by test_and_set_bit() becomes visible. Likewise, the atomic
391 memory operation done by test_and_set_bit() must become visible before
392 "obj->killed = 1;" is visible.
394 Finally there is the basic operation:
396 int test_bit(unsigned long nr, __const__ volatile unsigned long *addr);
398 Which returns a boolean indicating if bit "nr" is set in the bitmask
399 pointed to by "addr".
401 If explicit memory barriers are required around clear_bit() (which
402 does not return a value, and thus does not need to provide memory
403 barrier semantics), two interfaces are provided:
405 void smp_mb__before_clear_bit(void);
406 void smp_mb__after_clear_bit(void);
408 They are used as follows, and are akin to their atomic_t operation
411 /* All memory operations before this call will
412 * be globally visible before the clear_bit().
414 smp_mb__before_clear_bit();
417 /* The clear_bit() will be visible before all
418 * subsequent memory operations.
420 smp_mb__after_clear_bit();
422 There are two special bitops with lock barrier semantics (acquire/release,
423 same as spinlocks). These operate in the same way as their non-_lock/unlock
424 postfixed variants, except that they are to provide acquire/release semantics,
425 respectively. This means they can be used for bit_spin_trylock and
426 bit_spin_unlock type operations without specifying any more barriers.
428 int test_and_set_bit_lock(unsigned long nr, unsigned long *addr);
429 void clear_bit_unlock(unsigned long nr, unsigned long *addr);
430 void __clear_bit_unlock(unsigned long nr, unsigned long *addr);
432 The __clear_bit_unlock version is non-atomic, however it still implements
433 unlock barrier semantics. This can be useful if the lock itself is protecting
434 the other bits in the word.
436 Finally, there are non-atomic versions of the bitmask operations
437 provided. They are used in contexts where some other higher-level SMP
438 locking scheme is being used to protect the bitmask, and thus less
439 expensive non-atomic operations may be used in the implementation.
440 They have names similar to the above bitmask operation interfaces,
441 except that two underscores are prefixed to the interface name.
443 void __set_bit(unsigned long nr, volatile unsigned long *addr);
444 void __clear_bit(unsigned long nr, volatile unsigned long *addr);
445 void __change_bit(unsigned long nr, volatile unsigned long *addr);
446 int __test_and_set_bit(unsigned long nr, volatile unsigned long *addr);
447 int __test_and_clear_bit(unsigned long nr, volatile unsigned long *addr);
448 int __test_and_change_bit(unsigned long nr, volatile unsigned long *addr);
450 These non-atomic variants also do not require any special memory
453 The routines xchg() and cmpxchg() need the same exact memory barriers
454 as the atomic and bit operations returning values.
456 Spinlocks and rwlocks have memory barrier expectations as well.
457 The rule to follow is simple:
459 1) When acquiring a lock, the implementation must make it globally
460 visible before any subsequent memory operation.
462 2) When releasing a lock, the implementation must make it such that
463 all previous memory operations are globally visible before the
466 Which finally brings us to _atomic_dec_and_lock(). There is an
467 architecture-neutral version implemented in lib/dec_and_lock.c,
468 but most platforms will wish to optimize this in assembler.
470 int _atomic_dec_and_lock(atomic_t *atomic, spinlock_t *lock);
472 Atomically decrement the given counter, and if will drop to zero
473 atomically acquire the given spinlock and perform the decrement
474 of the counter to zero. If it does not drop to zero, do nothing
477 It is actually pretty simple to get the memory barrier correct.
478 Simply satisfy the spinlock grab requirements, which is make
479 sure the spinlock operation is globally visible before any
480 subsequent memory operation.
482 We can demonstrate this operation more clearly if we define
483 an abstract atomic operation:
485 long cas(long *mem, long old, long new);
487 "cas" stands for "compare and swap". It atomically:
489 1) Compares "old" with the value currently at "mem".
490 2) If they are equal, "new" is written to "mem".
491 3) Regardless, the current value at "mem" is returned.
493 As an example usage, here is what an atomic counter update
496 void example_atomic_inc(long *counter)
504 ret = cas(counter, old, new);
510 Let's use cas() in order to build a pseudo-C atomic_dec_and_lock():
512 int _atomic_dec_and_lock(atomic_t *atomic, spinlock_t *lock)
519 old = atomic_read(atomic);
525 ret = cas(atomic, old, new);
537 Now, as far as memory barriers go, as long as spin_lock()
538 strictly orders all subsequent memory operations (including
539 the cas()) with respect to itself, things will be fine.
541 Said another way, _atomic_dec_and_lock() must guarantee that
542 a counter dropping to zero is never made visible before the
543 spinlock being acquired.
545 Note that this also means that for the case where the counter
546 is not dropping to zero, there are no memory ordering