[GitHub/mt8127/android_kernel_alcatel_ttab.git] / Documentation / spinlocks.txt

Lesson 1: Spin locks

The most basic primitive for locking is spinlock.

static DEFINE_SPINLOCK(xxx_lock);

	unsigned long flags;

	spin_lock_irqsave(&xxx_lock, flags);
	... critical section here ..
	spin_unlock_irqrestore(&xxx_lock, flags);

The above is always safe. It will disable interrupts _locally_, but the
spinlock itself will guarantee the global lock, so it will guarantee that
there is only one thread-of-control within the region(s) protected by that
lock. This works well even under UP also, so the code does _not_ need to
worry about UP vs SMP issues: the spinlocks work correctly under both.

   NOTE! Implications of spin_locks for memory are further described in:

     Documentation/memory-barriers.txt
       (5) LOCK operations.
       (6) UNLOCK operations.

The above is usually pretty simple (you usually need and want only one
spinlock for most things - using more than one spinlock can make things a
lot more complex and even slower and is usually worth it only for
sequences that you _know_ need to be split up: avoid it at all cost if you
aren't sure).

This is really the only really hard part about spinlocks: once you start
using spinlocks they tend to expand to areas you might not have noticed
before, because you have to make sure the spinlocks correctly protect the
shared data structures _everywhere_ they are used. The spinlocks are most
easily added to places that are completely independent of other code (for
example, internal driver data structures that nobody else ever touches).

   NOTE! The spin-lock is safe only when you _also_ use the lock itself
   to do locking across CPU's, which implies that EVERYTHING that
   touches a shared variable has to agree about the spinlock they want
   to use.

----

Lesson 2: reader-writer spinlocks.

If your data accesses have a very natural pattern where you usually tend
to mostly read from the shared variables, the reader-writer locks
(rw_lock) versions of the spinlocks are sometimes useful. They allow multiple
readers to be in the same critical region at once, but if somebody wants
to change the variables it has to get an exclusive write lock.

   NOTE! reader-writer locks require more atomic memory operations than
   simple spinlocks.  Unless the reader critical section is long, you
   are better off just using spinlocks.

The routines look the same as above:

   rwlock_t xxx_lock = __RW_LOCK_UNLOCKED(xxx_lock);

	unsigned long flags;

	read_lock_irqsave(&xxx_lock, flags);
	.. critical section that only reads the info ...
	read_unlock_irqrestore(&xxx_lock, flags);

	write_lock_irqsave(&xxx_lock, flags);
	.. read and write exclusive access to the info ...
	write_unlock_irqrestore(&xxx_lock, flags);

The above kind of lock may be useful for complex data structures like
linked lists, especially searching for entries without changing the list
itself.  The read lock allows many concurrent readers.  Anything that
_changes_ the list will have to get the write lock.

   NOTE! RCU is better for list traversal, but requires careful
   attention to design detail (see Documentation/RCU/listRCU.txt).

Also, you cannot "upgrade" a read-lock to a write-lock, so if you at _any_
time need to do any changes (even if you don't do it every time), you have
to get the write-lock at the very beginning.

   NOTE! We are working hard to remove reader-writer spinlocks in most
   cases, so please don't add a new one without consensus.  (Instead, see
   Documentation/RCU/rcu.txt for complete information.)

----

Lesson 3: spinlocks revisited.

The single spin-lock primitives above are by no means the only ones. They
are the most safe ones, and the ones that work under all circumstances,
but partly _because_ they are safe they are also fairly slow. They are slower
than they'd need to be, because they do have to disable interrupts
(which is just a single instruction on a x86, but it's an expensive one -
and on other architectures it can be worse).

If you have a case where you have to protect a data structure across
several CPU's and you want to use spinlocks you can potentially use
cheaper versions of the spinlocks. IFF you know that the spinlocks are
never used in interrupt handlers, you can use the non-irq versions:

	spin_lock(&lock);
	...
	spin_unlock(&lock);

(and the equivalent read-write versions too, of course). The spinlock will
guarantee the same kind of exclusive access, and it will be much faster. 
This is useful if you know that the data in question is only ever
manipulated from a "process context", ie no interrupts involved. 

The reasons you mustn't use these versions if you have interrupts that
play with the spinlock is that you can get deadlocks:

	spin_lock(&lock);
	...
		<- interrupt comes in:
			spin_lock(&lock);

where an interrupt tries to lock an already locked variable. This is ok if
the other interrupt happens on another CPU, but it is _not_ ok if the
interrupt happens on the same CPU that already holds the lock, because the
lock will obviously never be released (because the interrupt is waiting
for the lock, and the lock-holder is interrupted by the interrupt and will
not continue until the interrupt has been processed). 

(This is also the reason why the irq-versions of the spinlocks only need
to disable the _local_ interrupts - it's ok to use spinlocks in interrupts
on other CPU's, because an interrupt on another CPU doesn't interrupt the
CPU that holds the lock, so the lock-holder can continue and eventually
releases the lock). 

Note that you can be clever with read-write locks and interrupts. For
example, if you know that the interrupt only ever gets a read-lock, then
you can use a non-irq version of read locks everywhere - because they
don't block on each other (and thus there is no dead-lock wrt interrupts. 
But when you do the write-lock, you have to use the irq-safe version. 

For an example of being clever with rw-locks, see the "waitqueue_lock" 
handling in kernel/sched.c - nothing ever _changes_ a wait-queue from
within an interrupt, they only read the queue in order to know whom to
wake up. So read-locks are safe (which is good: they are very common
indeed), while write-locks need to protect themselves against interrupts.

		Linus

----

Reference information:

For dynamic initialization, use spin_lock_init() or rwlock_init() as
appropriate:

   spinlock_t xxx_lock;
   rwlock_t xxx_rw_lock;

   static int __init xxx_init(void)
   {
	spin_lock_init(&xxx_lock);
	rwlock_init(&xxx_rw_lock);
	...
   }

   module_init(xxx_init);

For static initialization, use DEFINE_SPINLOCK() / DEFINE_RWLOCK() or
__SPIN_LOCK_UNLOCKED() / __RW_LOCK_UNLOCKED() as appropriate.
Commit	Line	Data
fb0bbb92	1	Lesson 1: Spin locks
1da177e4	2
fb0bbb92	3	The most basic primitive for locking is spinlock.
1da177e4	4
fb0bbb92	5	static DEFINE_SPINLOCK(xxx_lock);
1da177e4 LT	6
	7	unsigned long flags;
	8
	9	spin_lock_irqsave(&xxx_lock, flags);
	10	... critical section here ..
	11	spin_unlock_irqrestore(&xxx_lock, flags);
	12
fb0bbb92	13	The above is always safe. It will disable interrupts _locally_, but the
1da177e4 LT	14	spinlock itself will guarantee the global lock, so it will guarantee that
1da177e4 LT	15	there is only one thread-of-control within the region(s) protected by that
05801817 MK	16	lock. This works well even under UP also, so the code does _not_ need to
05801817 MK	17	worry about UP vs SMP issues: the spinlocks work correctly under both.
fb0bbb92 WAS	18
fb0bbb92 WAS	19	NOTE! Implications of spin_locks for memory are further described in:
1da177e4	20
fb0bbb92 WAS	21	Documentation/memory-barriers.txt
	22	(5) LOCK operations.
	23	(6) UNLOCK operations.
1da177e4 LT	24
	25	The above is usually pretty simple (you usually need and want only one
	26	spinlock for most things - using more than one spinlock can make things a
	27	lot more complex and even slower and is usually worth it only for
	28	sequences that you _know_ need to be split up: avoid it at all cost if you
05801817	29	aren't sure).
1da177e4 LT	30
	31	This is really the only really hard part about spinlocks: once you start
	32	using spinlocks they tend to expand to areas you might not have noticed
	33	before, because you have to make sure the spinlocks correctly protect the
	34	shared data structures _everywhere_ they are used. The spinlocks are most
fb0bbb92 WAS	35	easily added to places that are completely independent of other code (for
	36	example, internal driver data structures that nobody else ever touches).
	37
	38	NOTE! The spin-lock is safe only when you _also_ use the lock itself
	39	to do locking across CPU's, which implies that EVERYTHING that
	40	touches a shared variable has to agree about the spinlock they want
	41	to use.
1da177e4 LT	42
	43	----
	44
	45	Lesson 2: reader-writer spinlocks.
	46
	47	If your data accesses have a very natural pattern where you usually tend
	48	to mostly read from the shared variables, the reader-writer locks
fb0bbb92	49	(rw_lock) versions of the spinlocks are sometimes useful. They allow multiple
1da177e4	50	readers to be in the same critical region at once, but if somebody wants
fb0bbb92	51	to change the variables it has to get an exclusive write lock.
1da177e4	52
fb0bbb92 WAS	53	NOTE! reader-writer locks require more atomic memory operations than
	54	simple spinlocks. Unless the reader critical section is long, you
	55	are better off just using spinlocks.
1da177e4	56
fb0bbb92 WAS	57	The routines look the same as above:
fb0bbb92 WAS	58
d04fa5a3	59	rwlock_t xxx_lock = __RW_LOCK_UNLOCKED(xxx_lock);
1da177e4 LT	60
	61	unsigned long flags;
	62
	63	read_lock_irqsave(&xxx_lock, flags);
	64	.. critical section that only reads the info ...
	65	read_unlock_irqrestore(&xxx_lock, flags);
	66
	67	write_lock_irqsave(&xxx_lock, flags);
	68	.. read and write exclusive access to the info ...
	69	write_unlock_irqrestore(&xxx_lock, flags);
	70
fb0bbb92 WAS	71	The above kind of lock may be useful for complex data structures like
	72	linked lists, especially searching for entries without changing the list
	73	itself. The read lock allows many concurrent readers. Anything that
	74	_changes_ the list will have to get the write lock.
	75
	76	NOTE! RCU is better for list traversal, but requires careful
	77	attention to design detail (see Documentation/RCU/listRCU.txt).
1da177e4	78
fb0bbb92	79	Also, you cannot "upgrade" a read-lock to a write-lock, so if you at _any_
1da177e4	80	time need to do any changes (even if you don't do it every time), you have
fb0bbb92 WAS	81	to get the write-lock at the very beginning.
	82
	83	NOTE! We are working hard to remove reader-writer spinlocks in most
	84	cases, so please don't add a new one without consensus. (Instead, see
	85	Documentation/RCU/rcu.txt for complete information.)
1da177e4 LT	86
	87	----
	88
	89	Lesson 3: spinlocks revisited.
	90
	91	The single spin-lock primitives above are by no means the only ones. They
	92	are the most safe ones, and the ones that work under all circumstances,
05801817 MK	93	but partly _because_ they are safe they are also fairly slow. They are slower
	94	than they'd need to be, because they do have to disable interrupts
	95	(which is just a single instruction on a x86, but it's an expensive one -
	96	and on other architectures it can be worse).
1da177e4 LT	97
	98	If you have a case where you have to protect a data structure across
	99	several CPU's and you want to use spinlocks you can potentially use
	100	cheaper versions of the spinlocks. IFF you know that the spinlocks are
	101	never used in interrupt handlers, you can use the non-irq versions:
	102
	103	spin_lock(&lock);
	104	...
	105	spin_unlock(&lock);
	106
	107	(and the equivalent read-write versions too, of course). The spinlock will
	108	guarantee the same kind of exclusive access, and it will be much faster.
	109	This is useful if you know that the data in question is only ever
	110	manipulated from a "process context", ie no interrupts involved.
	111
	112	The reasons you mustn't use these versions if you have interrupts that
	113	play with the spinlock is that you can get deadlocks:
	114
	115	spin_lock(&lock);
	116	...
	117	<- interrupt comes in:
	118	spin_lock(&lock);
	119
	120	where an interrupt tries to lock an already locked variable. This is ok if
	121	the other interrupt happens on another CPU, but it is _not_ ok if the
	122	interrupt happens on the same CPU that already holds the lock, because the
	123	lock will obviously never be released (because the interrupt is waiting
	124	for the lock, and the lock-holder is interrupted by the interrupt and will
	125	not continue until the interrupt has been processed).
	126
	127	(This is also the reason why the irq-versions of the spinlocks only need
	128	to disable the _local_ interrupts - it's ok to use spinlocks in interrupts
	129	on other CPU's, because an interrupt on another CPU doesn't interrupt the
	130	CPU that holds the lock, so the lock-holder can continue and eventually
	131	releases the lock).
	132
	133	Note that you can be clever with read-write locks and interrupts. For
	134	example, if you know that the interrupt only ever gets a read-lock, then
	135	you can use a non-irq version of read locks everywhere - because they
	136	don't block on each other (and thus there is no dead-lock wrt interrupts.
	137	But when you do the write-lock, you have to use the irq-safe version.
	138
	139	For an example of being clever with rw-locks, see the "waitqueue_lock"
	140	handling in kernel/sched.c - nothing ever _changes_ a wait-queue from
	141	within an interrupt, they only read the queue in order to know whom to
	142	wake up. So read-locks are safe (which is good: they are very common
	143	indeed), while write-locks need to protect themselves against interrupts.
	144
	145	Linus
	146
fb0bbb92 WAS	147	----
	148
	149	Reference information:
	150
	151	For dynamic initialization, use spin_lock_init() or rwlock_init() as
	152	appropriate:
	153
	154	spinlock_t xxx_lock;
	155	rwlock_t xxx_rw_lock;
	156
	157	static int __init xxx_init(void)
	158	{
	159	spin_lock_init(&xxx_lock);
	160	rwlock_init(&xxx_rw_lock);
	161	...
	162	}
	163
	164	module_init(xxx_init);
	165
	166	For static initialization, use DEFINE_SPINLOCK() / DEFINE_RWLOCK() or
	167	__SPIN_LOCK_UNLOCKED() / __RW_LOCK_UNLOCKED() as appropriate.