e6e979f5d0
Cross-reference timeout(9). Sponsored by: The FreeBSD Foundation MFC after: 1 week
415 lines
13 KiB
Groff
415 lines
13 KiB
Groff
.\" Copyright (c) 2007 Julian Elischer (julian - freebsd org )
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.\" All rights reserved.
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.\"
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.\" Redistribution and use in source and binary forms, with or without
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.\" modification, are permitted provided that the following conditions
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.\" are met:
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.\" 1. Redistributions of source code must retain the above copyright
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.\" notice, this list of conditions and the following disclaimer.
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.\" 2. Redistributions in binary form must reproduce the above copyright
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.\" notice, this list of conditions and the following disclaimer in the
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.\" documentation and/or other materials provided with the distribution.
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.\"
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.\" THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
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.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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.\" ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
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.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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.\" SUCH DAMAGE.
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.\"
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.\" $FreeBSD$
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.\"
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.Dd July 5, 2015
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.Dt LOCKING 9
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.Os
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.Sh NAME
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.Nm locking
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.Nd kernel synchronization primitives
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.Sh DESCRIPTION
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The
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.Em FreeBSD
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kernel is written to run across multiple CPUs and as such provides
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several different synchronization primitives to allow developers
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to safely access and manipulate many data types.
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.Ss Mutexes
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Mutexes (also called "blocking mutexes") are the most commonly used
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synchronization primitive in the kernel.
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A thread acquires (locks) a mutex before accessing data shared with other
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threads (including interrupt threads), and releases (unlocks) it afterwards.
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If the mutex cannot be acquired, the thread requesting it will wait.
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Mutexes are adaptive by default, meaning that
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if the owner of a contended mutex is currently running on another CPU,
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then a thread attempting to acquire the mutex will spin rather than yielding
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the processor.
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Mutexes fully support priority propagation.
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.Pp
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See
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.Xr mutex 9
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for details.
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.Ss Spin Mutexes
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Spin mutexes are a variation of basic mutexes; the main difference between
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the two is that spin mutexes never block.
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Instead, they spin while waiting for the lock to be released.
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To avoid deadlock, a thread that holds a spin mutex must never yield its CPU.
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Unlike ordinary mutexes, spin mutexes disable interrupts when acquired.
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Since disabling interrupts can be expensive, they are generally slower to
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acquire and release.
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Spin mutexes should be used only when absolutely necessary,
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e.g. to protect data shared
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with interrupt filter code (see
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.Xr bus_setup_intr 9
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for details),
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or for scheduler internals.
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.Ss Mutex Pools
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With most synchronization primitives, such as mutexes, the programmer must
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provide memory to hold the primitive.
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For example, a mutex may be embedded inside the structure it protects.
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Mutex pools provide a preallocated set of mutexes to avoid this
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requirement.
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Note that mutexes from a pool may only be used as leaf locks.
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.Pp
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See
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.Xr mtx_pool 9
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for details.
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.Ss Reader/Writer Locks
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Reader/writer locks allow shared access to protected data by multiple threads
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or exclusive access by a single thread.
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The threads with shared access are known as
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.Em readers
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since they should only read the protected data.
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A thread with exclusive access is known as a
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.Em writer
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since it may modify protected data.
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.Pp
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Reader/writer locks can be treated as mutexes (see above and
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.Xr mutex 9 )
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with shared/exclusive semantics.
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Reader/writer locks support priority propagation like mutexes,
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but priority is propagated only to an exclusive holder.
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This limitation comes from the fact that shared owners
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are anonymous.
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.Pp
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See
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.Xr rwlock 9
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for details.
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.Ss Read-Mostly Locks
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Read-mostly locks are similar to
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.Em reader/writer
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locks but optimized for very infrequent write locking.
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.Em Read-mostly
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locks implement full priority propagation by tracking shared owners
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using a caller-supplied
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.Em tracker
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data structure.
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.Pp
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See
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.Xr rmlock 9
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for details.
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.Ss Sleepable Read-Mostly Locks
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Sleepable read-mostly locks are a variation on read-mostly locks.
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Threads holding an exclusive lock may sleep,
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but threads holding a shared lock may not.
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Priority is propagated to shared owners but not to exclusive owners.
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.Ss Shared/exclusive locks
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Shared/exclusive locks are similar to reader/writer locks; the main difference
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between them is that shared/exclusive locks may be held during unbounded sleep.
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Acquiring a contested shared/exclusive lock can perform an unbounded sleep.
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These locks do not support priority propagation.
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.Pp
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See
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.Xr sx 9
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for details.
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.Ss Lockmanager locks
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Lockmanager locks are sleepable shared/exclusive locks used mostly in
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.Xr VFS 9
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.Po
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as a
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.Xr vnode 9
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lock
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.Pc
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and in the buffer cache
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.Po
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.Xr BUF_LOCK 9
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.Pc .
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They have features other lock types do not have such as sleep
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timeouts, blocking upgrades,
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writer starvation avoidance, draining, and an interlock mutex,
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but this makes them complicated both to use and to implement;
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for this reason, they should be avoided.
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.Pp
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See
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.Xr lock 9
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for details.
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.Ss Counting semaphores
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Counting semaphores provide a mechanism for synchronizing access
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to a pool of resources.
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Unlike mutexes, semaphores do not have the concept of an owner,
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so they can be useful in situations where one thread needs
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to acquire a resource, and another thread needs to release it.
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They are largely deprecated.
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.Pp
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See
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.Xr sema 9
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for details.
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.Ss Condition variables
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Condition variables are used in conjunction with locks to wait for
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a condition to become true.
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A thread must hold the associated lock before calling one of the
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.Fn cv_wait ,
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functions.
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When a thread waits on a condition, the lock
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is atomically released before the thread yields the processor
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and reacquired before the function call returns.
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Condition variables may be used with blocking mutexes,
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reader/writer locks, read-mostly locks, and shared/exclusive locks.
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.Pp
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See
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.Xr condvar 9
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for details.
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.Ss Sleep/Wakeup
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The functions
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.Fn tsleep ,
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.Fn msleep ,
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.Fn msleep_spin ,
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.Fn pause ,
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.Fn wakeup ,
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and
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.Fn wakeup_one
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also handle event-based thread blocking.
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Unlike condition variables,
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arbitrary addresses may be used as wait channels and a dedicated
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structure does not need to be allocated.
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However, care must be taken to ensure that wait channel addresses are
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unique to an event.
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If a thread must wait for an external event, it is put to sleep by
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.Fn tsleep ,
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.Fn msleep ,
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.Fn msleep_spin ,
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or
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.Fn pause .
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Threads may also wait using one of the locking primitive sleep routines
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.Xr mtx_sleep 9 ,
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.Xr rw_sleep 9 ,
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or
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.Xr sx_sleep 9 .
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.Pp
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The parameter
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.Fa chan
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is an arbitrary address that uniquely identifies the event on which
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the thread is being put to sleep.
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All threads sleeping on a single
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.Fa chan
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are woken up later by
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.Fn wakeup
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.Pq often called from inside an interrupt routine
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to indicate that the
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event the thread was blocking on has occurred.
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.Pp
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Several of the sleep functions including
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.Fn msleep ,
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.Fn msleep_spin ,
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and the locking primitive sleep routines specify an additional lock
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parameter.
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The lock will be released before sleeping and reacquired
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before the sleep routine returns.
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If
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.Fa priority
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includes the
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.Dv PDROP
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flag, then the lock will not be reacquired before returning.
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The lock is used to ensure that a condition can be checked atomically,
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and that the current thread can be suspended without missing a
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change to the condition or an associated wakeup.
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In addition, all of the sleep routines will fully drop the
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.Va Giant
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mutex
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.Pq even if recursed
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while the thread is suspended and will reacquire the
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.Va Giant
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mutex
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.Pq restoring any recursion
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before the function returns.
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.Pp
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The
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.Fn pause
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function is a special sleep function that waits for a specified
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amount of time to pass before the thread resumes execution.
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This sleep cannot be terminated early by either an explicit
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.Fn wakeup
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or a signal.
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.Pp
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See
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.Xr sleep 9
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for details.
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.Ss Giant
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Giant is a special mutex used to protect data structures that do not
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yet have their own locks.
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Since it provides semantics akin to the old
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.Xr spl 9
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interface,
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Giant has special characteristics:
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.Bl -enum
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.It
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It is recursive.
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.It
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Drivers can request that Giant be locked around them
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by not marking themselves MPSAFE.
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Note that infrastructure to do this is slowly going away as non-MPSAFE
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drivers either became properly locked or disappear.
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.It
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Giant must be locked before other non-sleepable locks.
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.It
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Giant is dropped during unbounded sleeps and reacquired after wakeup.
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.It
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There are places in the kernel that drop Giant and pick it back up
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again.
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Sleep locks will do this before sleeping.
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Parts of the network or VM code may do this as well.
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This means that you cannot count on Giant keeping other code from
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running if your code sleeps, even if you want it to.
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.El
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.Sh INTERACTIONS
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The primitives can interact and have a number of rules regarding how
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they can and can not be combined.
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Many of these rules are checked by
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.Xr witness 4 .
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.Ss Bounded vs. Unbounded Sleep
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In a bounded sleep
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.Po also referred to as
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.Dq blocking
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.Pc
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the only resource needed to resume execution of a thread
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is CPU time for the owner of a lock that the thread is waiting to acquire.
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In an unbounded sleep
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.Po
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often referred to as simply
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.Dq sleeping
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.Pc
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a thread waits for an external event or for a condition
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to become true.
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In particular,
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a dependency chain of threads in bounded sleeps should always make forward
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progress,
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since there is always CPU time available.
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This requires that no thread in a bounded sleep is waiting for a lock held
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by a thread in an unbounded sleep.
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To avoid priority inversions,
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a thread in a bounded sleep lends its priority to the owner of the lock
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that it is waiting for.
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.Pp
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The following primitives perform bounded sleeps:
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mutexes, reader/writer locks and read-mostly locks.
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.Pp
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The following primitives perform unbounded sleeps:
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sleepable read-mostly locks, shared/exclusive locks, lockmanager locks,
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counting semaphores, condition variables, and sleep/wakeup.
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.Ss General Principles
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.Bl -bullet
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.It
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It is an error to do any operation that could result in yielding the processor
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while holding a spin mutex.
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.It
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It is an error to do any operation that could result in unbounded sleep
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while holding any primitive from the 'bounded sleep' group.
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For example, it is an error to try to acquire a shared/exclusive lock while
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holding a mutex, or to try to allocate memory with M_WAITOK while holding a
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reader/writer lock.
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.Pp
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Note that the lock passed to one of the
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.Fn sleep
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or
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.Fn cv_wait
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functions is dropped before the thread enters the unbounded sleep and does
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not violate this rule.
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.It
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It is an error to do any operation that could result in yielding of
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the processor when running inside an interrupt filter.
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.It
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It is an error to do any operation that could result in unbounded sleep when
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running inside an interrupt thread.
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.El
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.Ss Interaction table
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The following table shows what you can and can not do while holding
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one of the locking primitives discussed. Note that
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.Dq sleep
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includes
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.Fn sema_wait ,
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.Fn sema_timedwait ,
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any of the
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.Fn cv_wait
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functions,
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and any of the
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.Fn sleep
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functions.
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.Bl -column ".Ic xxxxxxxxxxxxxxxx" ".Xr XXXXXXXXX" ".Xr XXXXXXXXX" ".Xr XXXXXXX" ".Xr XXXXXXXXX" ".Xr XXXXXX" -offset 3n
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.It Em " You want:" Ta spin mtx Ta mutex/rw Ta rmlock Ta sleep rm Ta sx/lk Ta sleep
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.It Em "You have: " Ta -------- Ta -------- Ta ------ Ta -------- Ta ------ Ta ------
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.It spin mtx Ta \&ok Ta \&no Ta \&no Ta \&no Ta \&no Ta \&no-1
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.It mutex/rw Ta \&ok Ta \&ok Ta \&ok Ta \&no Ta \&no Ta \&no-1
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.It rmlock Ta \&ok Ta \&ok Ta \&ok Ta \&no Ta \&no Ta \&no-1
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.It sleep rm Ta \&ok Ta \&ok Ta \&ok Ta \&ok-2 Ta \&ok-2 Ta \&ok-2/3
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.It sx Ta \&ok Ta \&ok Ta \&ok Ta \&ok Ta \&ok Ta \&ok-3
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.It lockmgr Ta \&ok Ta \&ok Ta \&ok Ta \&ok Ta \&ok Ta \&ok
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.El
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.Pp
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.Em *1
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There are calls that atomically release this primitive when going to sleep
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and reacquire it on wakeup
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.Po
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.Fn mtx_sleep ,
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.Fn rw_sleep ,
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.Fn msleep_spin ,
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etc.
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.Pc .
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.Pp
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.Em *2
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These cases are only allowed while holding a write lock on a sleepable
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read-mostly lock.
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.Pp
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.Em *3
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Though one can sleep while holding this lock,
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one can also use a
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.Fn sleep
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function to atomically release this primitive when going to sleep and
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reacquire it on wakeup.
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.Pp
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Note that non-blocking try operations on locks are always permitted.
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.Ss Context mode table
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The next table shows what can be used in different contexts.
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At this time this is a rather easy to remember table.
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.Bl -column ".Ic Xxxxxxxxxxxxxxxxxxx" ".Xr XXXXXXXXX" ".Xr XXXXXXXXX" ".Xr XXXXXXX" ".Xr XXXXXXXXX" ".Xr XXXXXX" -offset 3n
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.It Em "Context:" Ta spin mtx Ta mutex/rw Ta rmlock Ta sleep rm Ta sx/lk Ta sleep
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.It interrupt filter: Ta \&ok Ta \&no Ta \&no Ta \&no Ta \&no Ta \&no
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.It interrupt thread: Ta \&ok Ta \&ok Ta \&ok Ta \&no Ta \&no Ta \&no
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.It callout: Ta \&ok Ta \&ok Ta \&ok Ta \&no Ta \&no Ta \&no
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.It direct callout: Ta \&ok Ta \&no Ta \&no Ta \&no Ta \&no Ta \&no
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.It system call: Ta \&ok Ta \&ok Ta \&ok Ta \&ok Ta \&ok Ta \&ok
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.El
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.Sh SEE ALSO
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.Xr witness 4 ,
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.Xr BUS_SETUP_INTR 9 ,
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.Xr condvar 9 ,
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.Xr lock 9 ,
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.Xr LOCK_PROFILING 9 ,
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.Xr mtx_pool 9 ,
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.Xr mutex 9 ,
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.Xr rmlock 9 ,
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.Xr rwlock 9 ,
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.Xr sema 9 ,
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.Xr sleep 9 ,
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.Xr sx 9 ,
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.Xr timeout 9
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.Sh HISTORY
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These
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functions appeared in
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.Bsx 4.1
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through
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.Fx 7.0 .
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.Sh BUGS
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There are too many locking primitives to choose from.
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