Documentation/pi-futex.txt - linux - Git at Google

 ======================
 Lightweight PI-futexes
 ======================

 We are calling them lightweight for 3 reasons:

  - in the user-space fastpath a PI-enabled futex involves no kernel work
    (or any other PI complexity) at all. No registration, no extra kernel
    calls - just pure fast atomic ops in userspace.

  - even in the slowpath, the system call and scheduling pattern is very
    similar to normal futexes.

  - the in-kernel PI implementation is streamlined around the mutex
    abstraction, with strict rules that keep the implementation
    relatively simple: only a single owner may own a lock (i.e. no
    read-write lock support), only the owner may unlock a lock, no
    recursive locking, etc.

 Priority Inheritance - why?
 ---------------------------

 The short reply: user-space PI helps achieving/improving determinism for
 user-space applications. In the best-case, it can help achieve
 determinism and well-bound latencies. Even in the worst-case, PI will
 improve the statistical distribution of locking related application
 delays.

 The longer reply
 ----------------

 Firstly, sharing locks between multiple tasks is a common programming
 technique that often cannot be replaced with lockless algorithms. As we
 can see it in the kernel [which is a quite complex program in itself],
 lockless structures are rather the exception than the norm - the current
 ratio of lockless vs. locky code for shared data structures is somewhere
 between 1:10 and 1:100. Lockless is hard, and the complexity of lockless
 algorithms often endangers to ability to do robust reviews of said code.
 I.e. critical RT apps often choose lock structures to protect critical
 data structures, instead of lockless algorithms. Furthermore, there are
 cases (like shared hardware, or other resource limits) where lockless
 access is mathematically impossible.

 Media players (such as Jack) are an example of reasonable application
 design with multiple tasks (with multiple priority levels) sharing
 short-held locks: for example, a highprio audio playback thread is
 combined with medium-prio construct-audio-data threads and low-prio
 display-colory-stuff threads. Add video and decoding to the mix and
 we've got even more priority levels.

 So once we accept that synchronization objects (locks) are an
 unavoidable fact of life, and once we accept that multi-task userspace
 apps have a very fair expectation of being able to use locks, we've got
 to think about how to offer the option of a deterministic locking
 implementation to user-space.

 Most of the technical counter-arguments against doing priority
 inheritance only apply to kernel-space locks. But user-space locks are
 different, there we cannot disable interrupts or make the task
 non-preemptible in a critical section, so the 'use spinlocks' argument
 does not apply (user-space spinlocks have the same priority inversion
 problems as other user-space locking constructs). Fact is, pretty much
 the only technique that currently enables good determinism for userspace
 locks (such as futex-based pthread mutexes) is priority inheritance:

 Currently (without PI), if a high-prio and a low-prio task shares a lock
 [this is a quite common scenario for most non-trivial RT applications],
 even if all critical sections are coded carefully to be deterministic
 (i.e. all critical sections are short in duration and only execute a
 limited number of instructions), the kernel cannot guarantee any
 deterministic execution of the high-prio task: any medium-priority task
 could preempt the low-prio task while it holds the shared lock and
 executes the critical section, and could delay it indefinitely.

 Implementation
 --------------

 As mentioned before, the userspace fastpath of PI-enabled pthread
 mutexes involves no kernel work at all - they behave quite similarly to
 normal futex-based locks: a 0 value means unlocked, and a value==TID
 means locked. (This is the same method as used by list-based robust
 futexes.) Userspace uses atomic ops to lock/unlock these mutexes without
 entering the kernel.

 To handle the slowpath, we have added two new futex ops:

   - FUTEX_LOCK_PI
   - FUTEX_UNLOCK_PI

 If the lock-acquire fastpath fails, [i.e. an atomic transition from 0 to
 TID fails], then FUTEX_LOCK_PI is called. The kernel does all the
 remaining work: if there is no futex-queue attached to the futex address
 yet then the code looks up the task that owns the futex [it has put its
 own TID into the futex value], and attaches a 'PI state' structure to
 the futex-queue. The pi_state includes an rt-mutex, which is a PI-aware,
 kernel-based synchronization object. The 'other' task is made the owner
 of the rt-mutex, and the FUTEX_WAITERS bit is atomically set in the
 futex value. Then this task tries to lock the rt-mutex, on which it
 blocks. Once it returns, it has the mutex acquired, and it sets the
 futex value to its own TID and returns. Userspace has no other work to
 perform - it now owns the lock, and futex value contains
 FUTEX_WAITERS|TID.

 If the unlock side fastpath succeeds, [i.e. userspace manages to do a
 TID -> 0 atomic transition of the futex value], then no kernel work is
 triggered.

 If the unlock fastpath fails (because the FUTEX_WAITERS bit is set),
 then FUTEX_UNLOCK_PI is called, and the kernel unlocks the futex on the
 behalf of userspace - and it also unlocks the attached
 pi_state->rt_mutex and thus wakes up any potential waiters.

 Note that under this approach, contrary to previous PI-futex approaches,
 there is no prior 'registration' of a PI-futex. [which is not quite
 possible anyway, due to existing ABI properties of pthread mutexes.]

 Also, under this scheme, 'robustness' and 'PI' are two orthogonal
 properties of futexes, and all four combinations are possible: futex,
 robust-futex, PI-futex, robust+PI-futex.

 More details about priority inheritance can be found in
 Documentation/locking/rt-mutex.txt.
	======================
	Lightweight PI-futexes
	======================

	We are calling them lightweight for 3 reasons:

	- in the user-space fastpath a PI-enabled futex involves no kernel work
	(or any other PI complexity) at all. No registration, no extra kernel
	calls - just pure fast atomic ops in userspace.

	- even in the slowpath, the system call and scheduling pattern is very
	similar to normal futexes.

	- the in-kernel PI implementation is streamlined around the mutex
	abstraction, with strict rules that keep the implementation
	relatively simple: only a single owner may own a lock (i.e. no
	read-write lock support), only the owner may unlock a lock, no
	recursive locking, etc.

	Priority Inheritance - why?
	---------------------------

	The short reply: user-space PI helps achieving/improving determinism for
	user-space applications. In the best-case, it can help achieve
	determinism and well-bound latencies. Even in the worst-case, PI will
	improve the statistical distribution of locking related application
	delays.

	The longer reply
	----------------

	Firstly, sharing locks between multiple tasks is a common programming
	technique that often cannot be replaced with lockless algorithms. As we
	can see it in the kernel [which is a quite complex program in itself],
	lockless structures are rather the exception than the norm - the current
	ratio of lockless vs. locky code for shared data structures is somewhere
	between 1:10 and 1:100. Lockless is hard, and the complexity of lockless
	algorithms often endangers to ability to do robust reviews of said code.
	I.e. critical RT apps often choose lock structures to protect critical
	data structures, instead of lockless algorithms. Furthermore, there are
	cases (like shared hardware, or other resource limits) where lockless
	access is mathematically impossible.

	Media players (such as Jack) are an example of reasonable application
	design with multiple tasks (with multiple priority levels) sharing
	short-held locks: for example, a highprio audio playback thread is
	combined with medium-prio construct-audio-data threads and low-prio
	display-colory-stuff threads. Add video and decoding to the mix and
	we've got even more priority levels.

	So once we accept that synchronization objects (locks) are an
	unavoidable fact of life, and once we accept that multi-task userspace
	apps have a very fair expectation of being able to use locks, we've got
	to think about how to offer the option of a deterministic locking
	implementation to user-space.

	Most of the technical counter-arguments against doing priority
	inheritance only apply to kernel-space locks. But user-space locks are
	different, there we cannot disable interrupts or make the task
	non-preemptible in a critical section, so the 'use spinlocks' argument
	does not apply (user-space spinlocks have the same priority inversion
	problems as other user-space locking constructs). Fact is, pretty much
	the only technique that currently enables good determinism for userspace
	locks (such as futex-based pthread mutexes) is priority inheritance:

	Currently (without PI), if a high-prio and a low-prio task shares a lock
	[this is a quite common scenario for most non-trivial RT applications],
	even if all critical sections are coded carefully to be deterministic
	(i.e. all critical sections are short in duration and only execute a
	limited number of instructions), the kernel cannot guarantee any
	deterministic execution of the high-prio task: any medium-priority task
	could preempt the low-prio task while it holds the shared lock and
	executes the critical section, and could delay it indefinitely.

	Implementation
	--------------

	As mentioned before, the userspace fastpath of PI-enabled pthread
	mutexes involves no kernel work at all - they behave quite similarly to
	normal futex-based locks: a 0 value means unlocked, and a value==TID
	means locked. (This is the same method as used by list-based robust
	futexes.) Userspace uses atomic ops to lock/unlock these mutexes without
	entering the kernel.

	To handle the slowpath, we have added two new futex ops:

	- FUTEX_LOCK_PI
	- FUTEX_UNLOCK_PI

	If the lock-acquire fastpath fails, [i.e. an atomic transition from 0 to
	TID fails], then FUTEX_LOCK_PI is called. The kernel does all the
	remaining work: if there is no futex-queue attached to the futex address
	yet then the code looks up the task that owns the futex [it has put its
	own TID into the futex value], and attaches a 'PI state' structure to
	the futex-queue. The pi_state includes an rt-mutex, which is a PI-aware,
	kernel-based synchronization object. The 'other' task is made the owner
	of the rt-mutex, and the FUTEX_WAITERS bit is atomically set in the
	futex value. Then this task tries to lock the rt-mutex, on which it
	blocks. Once it returns, it has the mutex acquired, and it sets the
	futex value to its own TID and returns. Userspace has no other work to
	perform - it now owns the lock, and futex value contains
	FUTEX_WAITERS\|TID.

	If the unlock side fastpath succeeds, [i.e. userspace manages to do a
	TID -> 0 atomic transition of the futex value], then no kernel work is
	triggered.

	If the unlock fastpath fails (because the FUTEX_WAITERS bit is set),
	then FUTEX_UNLOCK_PI is called, and the kernel unlocks the futex on the
	behalf of userspace - and it also unlocks the attached
	pi_state->rt_mutex and thus wakes up any potential waiters.

	Note that under this approach, contrary to previous PI-futex approaches,
	there is no prior 'registration' of a PI-futex. [which is not quite
	possible anyway, due to existing ABI properties of pthread mutexes.]

	Also, under this scheme, 'robustness' and 'PI' are two orthogonal
	properties of futexes, and all four combinations are possible: futex,
	robust-futex, PI-futex, robust+PI-futex.

	More details about priority inheritance can be found in
	Documentation/locking/rt-mutex.txt.