Documentation/rt-mutex.txt - kernel/msm-4.9 - Gitiles

 RT-mutex subsystem with PI support
 ----------------------------------

 RT-mutexes with priority inheritance are used to support PI-futexes,
 which enable pthread_mutex_t priority inheritance attributes
 (PTHREAD_PRIO_INHERIT). [See Documentation/pi-futex.txt for more details
 about PI-futexes.]

 This technology was developed in the -rt tree and streamlined for
 pthread_mutex support.

 Basic principles:
 -----------------

 RT-mutexes extend the semantics of simple mutexes by the priority
 inheritance protocol.

 A low priority owner of a rt-mutex inherits the priority of a higher
 priority waiter until the rt-mutex is released. If the temporarily
 boosted owner blocks on a rt-mutex itself it propagates the priority
 boosting to the owner of the other rt_mutex it gets blocked on. The
 priority boosting is immediately removed once the rt_mutex has been
 unlocked.

 This approach allows us to shorten the block of high-prio tasks on
 mutexes which protect shared resources. Priority inheritance is not a
 magic bullet for poorly designed applications, but it allows
 well-designed applications to use userspace locks in critical parts of
 an high priority thread, without losing determinism.

 The enqueueing of the waiters into the rtmutex waiter list is done in
 priority order. For same priorities FIFO order is chosen. For each
 rtmutex, only the top priority waiter is enqueued into the owner's
 priority waiters list. This list too queues in priority order. Whenever
 the top priority waiter of a task changes (for example it timed out or
 got a signal), the priority of the owner task is readjusted. [The
 priority enqueueing is handled by "plists", see include/linux/plist.h
 for more details.]

 RT-mutexes are optimized for fastpath operations and have no internal
 locking overhead when locking an uncontended mutex or unlocking a mutex
 without waiters. The optimized fastpath operations require cmpxchg
 support. [If that is not available then the rt-mutex internal spinlock
 is used]

 The state of the rt-mutex is tracked via the owner field of the rt-mutex
 structure:

 rt_mutex->owner holds the task_struct pointer of the owner. Bit 0 and 1
 are used to keep track of the "owner is pending" and "rtmutex has
 waiters" state.

  owner		bit1	bit0
  NULL		0	0	mutex is free (fast acquire possible)
  NULL		0	1	invalid state
  NULL		1	0	Transitional state*
  NULL		1	1	invalid state
  taskpointer	0	0	mutex is held (fast release possible)
  taskpointer	0	1	task is pending owner
  taskpointer	1	0	mutex is held and has waiters
  taskpointer	1	1	task is pending owner and mutex has waiters

 Pending-ownership handling is a performance optimization:
 pending-ownership is assigned to the first (highest priority) waiter of
 the mutex, when the mutex is released. The thread is woken up and once
 it starts executing it can acquire the mutex. Until the mutex is taken
 by it (bit 0 is cleared) a competing higher priority thread can "steal"
 the mutex which puts the woken up thread back on the waiters list.

 The pending-ownership optimization is especially important for the
 uninterrupted workflow of high-prio tasks which repeatedly
 takes/releases locks that have lower-prio waiters. Without this
 optimization the higher-prio thread would ping-pong to the lower-prio
 task [because at unlock time we always assign a new owner].

 (*) The "mutex has waiters" bit gets set to take the lock. If the lock
 doesn't already have an owner, this bit is quickly cleared if there are
 no waiters.  So this is a transitional state to synchronize with looking
 at the owner field of the mutex and the mutex owner releasing the lock.
	RT-mutex subsystem with PI support
	----------------------------------

	RT-mutexes with priority inheritance are used to support PI-futexes,
	which enable pthread_mutex_t priority inheritance attributes
	(PTHREAD_PRIO_INHERIT). [See Documentation/pi-futex.txt for more details
	about PI-futexes.]

	This technology was developed in the -rt tree and streamlined for
	pthread_mutex support.

	Basic principles:
	-----------------

	RT-mutexes extend the semantics of simple mutexes by the priority
	inheritance protocol.

	A low priority owner of a rt-mutex inherits the priority of a higher
	priority waiter until the rt-mutex is released. If the temporarily
	boosted owner blocks on a rt-mutex itself it propagates the priority
	boosting to the owner of the other rt_mutex it gets blocked on. The
	priority boosting is immediately removed once the rt_mutex has been
	unlocked.

	This approach allows us to shorten the block of high-prio tasks on
	mutexes which protect shared resources. Priority inheritance is not a
	magic bullet for poorly designed applications, but it allows
	well-designed applications to use userspace locks in critical parts of
	an high priority thread, without losing determinism.

	The enqueueing of the waiters into the rtmutex waiter list is done in
	priority order. For same priorities FIFO order is chosen. For each
	rtmutex, only the top priority waiter is enqueued into the owner's
	priority waiters list. This list too queues in priority order. Whenever
	the top priority waiter of a task changes (for example it timed out or
	got a signal), the priority of the owner task is readjusted. [The
	priority enqueueing is handled by "plists", see include/linux/plist.h
	for more details.]

	RT-mutexes are optimized for fastpath operations and have no internal
	locking overhead when locking an uncontended mutex or unlocking a mutex
	without waiters. The optimized fastpath operations require cmpxchg
	support. [If that is not available then the rt-mutex internal spinlock
	is used]

	The state of the rt-mutex is tracked via the owner field of the rt-mutex
	structure:

	rt_mutex->owner holds the task_struct pointer of the owner. Bit 0 and 1
	are used to keep track of the "owner is pending" and "rtmutex has
	waiters" state.

	owner bit1 bit0
	NULL 0 0 mutex is free (fast acquire possible)
	NULL 0 1 invalid state
	NULL 1 0 Transitional state*
	NULL 1 1 invalid state
	taskpointer 0 0 mutex is held (fast release possible)
	taskpointer 0 1 task is pending owner
	taskpointer 1 0 mutex is held and has waiters
	taskpointer 1 1 task is pending owner and mutex has waiters

	Pending-ownership handling is a performance optimization:
	pending-ownership is assigned to the first (highest priority) waiter of
	the mutex, when the mutex is released. The thread is woken up and once
	it starts executing it can acquire the mutex. Until the mutex is taken
	by it (bit 0 is cleared) a competing higher priority thread can "steal"
	the mutex which puts the woken up thread back on the waiters list.

	The pending-ownership optimization is especially important for the
	uninterrupted workflow of high-prio tasks which repeatedly
	takes/releases locks that have lower-prio waiters. Without this
	optimization the higher-prio thread would ping-pong to the lower-prio
	task [because at unlock time we always assign a new owner].

	(*) The "mutex has waiters" bit gets set to take the lock. If the lock
	doesn't already have an owner, this bit is quickly cleared if there are
	no waiters. So this is a transitional state to synchronize with looking
	at the owner field of the mutex and the mutex owner releasing the lock.