TIMEOUT(9) | Kernel Developer's Manual | TIMEOUT(9) |
callout_active
,
callout_deactivate
,
callout_async_drain
,
callout_drain
,
callout_handle_init
,
callout_init
,
callout_init_mtx
,
callout_init_rm
,
callout_init_rw
,
callout_pending
,
callout_reset
,
callout_reset_curcpu
,
callout_reset_on
,
callout_reset_sbt
,
callout_reset_sbt_curcpu
,
callout_reset_sbt_on
,
callout_schedule
,
callout_schedule_curcpu
,
callout_schedule_on
,
callout_schedule_sbt
,
callout_schedule_sbt_curcpu
,
callout_schedule_sbt_on
,
callout_stop
, callout_when
,
timeout
, untimeout
—
execute a function after a specified length of
time
#include
<sys/types.h>
#include <sys/systm.h>
typedef void timeout_t (void *);
callout_active
(struct
callout *c);
void
callout_deactivate
(struct
callout *c);
int
callout_async_drain
(struct
callout *c, timeout_t
*drain);
int
callout_drain
(struct
callout *c);
void
callout_handle_init
(struct
callout_handle *handle);
struct callout_handle handle = CALLOUT_HANDLE_INITIALIZER(&handle);
callout_init
(struct
callout *c, int
mpsafe);
void
callout_init_mtx
(struct
callout *c, struct mtx
*mtx, int
flags);
void
callout_init_rm
(struct
callout *c, struct rmlock
*rm, int
flags);
void
callout_init_rw
(struct
callout *c, struct rwlock
*rw, int
flags);
int
callout_pending
(struct
callout *c);
int
callout_reset
(struct
callout *c, int
ticks, timeout_t
*func, void
*arg);
int
callout_reset_curcpu
(struct callout
*c, int ticks, timeout_t
*func, void *arg);
int
callout_reset_on
(struct callout
*c, int ticks, timeout_t
*func, void *arg, int
cpu);
int
callout_reset_sbt
(struct callout
*c, sbintime_t sbt, sbintime_t
pr, timeout_t *func, void
*arg, int flags);
int
callout_reset_sbt_curcpu
(struct
callout *c, sbintime_t sbt,
sbintime_t pr, timeout_t *func,
void *arg, int flags);
int
callout_reset_sbt_on
(struct callout
*c, sbintime_t sbt, sbintime_t
pr, timeout_t *func, void
*arg, int cpu, int
flags);
int
callout_schedule
(struct
callout *c, int
ticks);
int
callout_schedule_curcpu
(struct
callout *c, int
ticks);
int
callout_schedule_on
(struct
callout *c, int
ticks, int
cpu);
int
callout_schedule_sbt
(struct callout
*c, sbintime_t sbt, sbintime_t
pr, int flags);
int
callout_schedule_sbt_curcpu
(struct
callout *c, sbintime_t sbt,
sbintime_t pr, int flags);
int
callout_schedule_sbt_on
(struct callout
*c, sbintime_t sbt, sbintime_t
pr, int cpu, int
flags);
int
callout_stop
(struct
callout *c);
sbintime_t
callout_when
(sbintime_t sbt,
sbintime_t precision, int flags,
sbintime_t *sbt_res, sbintime_t
*precision_res);
struct callout_handle
timeout
(timeout_t
*func, void *arg,
int ticks);
void
untimeout
(timeout_t
*func, void *arg,
struct callout_handle
handle);
The callout
API is used to schedule a call
to an arbitrary function at a specific time in the future. Consumers of this
API are required to allocate a callout structure (struct callout) for each
pending function invocation. This structure stores state about the pending
function invocation including the function to be called and the time at
which the function should be invoked. Pending function calls can be
cancelled or rescheduled to a different time. In addition, a callout
structure may be reused to schedule a new function call after a scheduled
call is completed.
Callouts only provide a single-shot mode. If a consumer requires a periodic timer, it must explicitly reschedule each function call. This is normally done by rescheduling the subsequent call within the called function.
Callout functions must not sleep. They may not acquire sleepable locks, wait on condition variables, perform blocking allocation requests, or invoke any other action that might sleep.
Each callout structure must be initialized by
callout_init
(),
callout_init_mtx
(),
callout_init_rm
(), or
callout_init_rw
() before it is passed to any of the
other callout functions. The callout_init
() function
initializes a callout structure in c that is not
associated with a specific lock. If the mpsafe
argument is zero, the callout structure is not considered to be
“multi-processor safe”; and the Giant lock will be acquired
before calling the callout function and released when the callout function
returns.
The
callout_init_mtx
(),
callout_init_rm
(),
and
callout_init_rw
()
functions initialize a callout structure in c that is
associated with a specific lock. The lock is specified by the
mtx, rm, or
rw parameter. The associated lock must be held while
stopping or rescheduling the callout. The callout subsystem acquires the
associated lock before calling the callout function and releases it after
the function returns. If the callout was cancelled while the callout
subsystem waited for the associated lock, the callout function is not
called, and the associated lock is released. This ensures that stopping or
rescheduling the callout will abort any previously scheduled invocation.
Only regular mutexes may be used with
callout_init_mtx
();
spin mutexes are not supported. A sleepable read-mostly lock (one
initialized with the RM_SLEEPABLE
flag) may not be
used with
callout_init_rm
().
Similarly, other sleepable lock types such as sx(9) and
lockmgr(9) cannot be used with callouts because sleeping
is not permitted in the callout subsystem.
These flags may be
specified for
callout_init_mtx
(),
callout_init_rm
(),
or
callout_init_rw
():
CALLOUT_RETURNUNLOCKED
CALLOUT_SHAREDLOCK
callout_init_mtx
().The function
callout_stop
()
cancels a callout c if it is currently pending. If the
callout is pending and successfully stopped, then
callout_stop
() returns a value of one. If the
callout is not set, or has already been serviced, then negative one is
returned. If the callout is currently being serviced and cannot be stopped,
then zero will be returned. If the callout is currently being serviced and
cannot be stopped, and at the same time a next invocation of the same
callout is also scheduled, then callout_stop
()
unschedules the next run and returns zero. If the callout has an associated
lock, then that lock must be held when this function is called.
The function
callout_async_drain
()
is identical to callout_stop
() with one difference.
When callout_async_drain
() returns zero it will
arrange for the function drain to be called using the
same argument given to the callout_reset
() function.
callout_async_drain
() If the callout has an
associated lock, then that lock must be held when this function is called.
Note that when stopping multiple callouts that use the same lock it is
possible to get multiple return's of zero and multiple calls to the
drain function, depending upon which CPU's the
callouts are running. The drain function itself is
called from the context of the completing callout i.e. softclock or
hardclock, just like a callout itself.
The function
callout_drain
()
is identical to callout_stop
() except that it will
wait for the callout c to complete if it is already in
progress. This function MUST NOT be called while holding any locks on which
the callout might block, or deadlock will result. Note that if the callout
subsystem has already begun processing this callout, then the callout
function may be invoked before callout_drain
()
returns. However, the callout subsystem does guarantee that the callout will
be fully stopped before callout_drain
() returns.
The
callout_reset
()
and
callout_schedule
()
function families schedule a future function invocation for callout
c. If c already has a pending
callout, it is cancelled before the new invocation is scheduled. These
functions return a value of one if a pending callout was cancelled and zero
if there was no pending callout. If the callout has an associated lock, then
that lock must be held when any of these functions are called.
The time at which the callout function will be invoked is determined by either the ticks argument or the sbt, pr, and flags arguments. When ticks is used, the callout is scheduled to execute after ticks/hz seconds. Non-positive values of ticks are silently converted to the value ‘1’.
The sbt, pr, and flags arguments provide more control over the scheduled time including support for higher resolution times, specifying the precision of the scheduled time, and setting an absolute deadline instead of a relative timeout. The callout is scheduled to execute in a time window which begins at the time specified in sbt and extends for the amount of time specified in pr. If sbt specifies a time in the past, the window is adjusted to start at the current time. A non-zero value for pr allows the callout subsystem to coalesce callouts scheduled close to each other into fewer timer interrupts, reducing processing overhead and power consumption. These flags may be specified to adjust the interpretation of sbt and pr:
C_ABSOLUTE
C_DIRECT_EXEC
C_PREL
()C_PRECALC
callout_when
() which uses the user-supplied
sbt, pr, and
flags values.C_HARDCLOCK
hardclock
()
calls if possible.The
callout_reset
()
functions accept a func argument which identifies the
function to be called when the time expires. It must be a pointer to a
function that takes a single void * argument. Upon
invocation, func will receive
arg as its only argument. The
callout_schedule
()
functions reuse the func and arg
arguments from the previous callout. Note that one of the
callout_reset
() functions must always be called to
initialize func and arg before
one of the callout_schedule
() functions can be
used.
The callout subsystem provides a softclock
thread for each CPU in the system. Callouts are assigned to a single CPU and
are executed by the softclock thread for that CPU. Initially, callouts are
assigned to CPU 0. The
callout_reset_on
(),
callout_reset_sbt_on
(),
callout_schedule_on
()
and
callout_schedule_sbt_on
()
functions assign the callout to CPU cpu. The
callout_reset_curcpu
(),
callout_reset_sbt_curpu
(),
callout_schedule_curcpu
()
and
callout_schedule_sbt_curcpu
()
functions assign the callout to the current CPU. The
callout_reset
(),
callout_reset_sbt
(),
callout_schedule
() and
callout_schedule_sbt
()
functions schedule the callout to execute in the softclock thread of the CPU
to which it is currently assigned.
Softclock threads are not pinned to their respective CPUs by default. The softclock thread for CPU 0 can be pinned to CPU 0 by setting the kern.pin_default_swi loader tunable to a non-zero value. Softclock threads for CPUs other than zero can be pinned to their respective CPUs by setting the kern.pin_pcpu_swi loader tunable to a non-zero value.
The macros
callout_pending
(),
callout_active
() and
callout_deactivate
() provide access to the current
state of the callout. The callout_pending
() macro
checks whether a callout is pending; a callout is
considered pending when a timeout has been set but the
time has not yet arrived. Note that once the timeout time arrives and the
callout subsystem starts to process this callout,
callout_pending
() will return
FALSE
even though the callout function may not have
finished (or even begun) executing. The
callout_active
() macro checks whether a callout is
marked as active, and the
callout_deactivate
() macro clears the callout's
active flag. The callout subsystem marks a callout as
active when a timeout is set and it clears the
active flag in callout_stop
() and
callout_drain
(), but it
does not
clear it when a callout expires normally via the execution of the callout
function.
The
callout_when
()
function may be used to pre-calculate the absolute time at which the timeout
should be run and the precision of the scheduled run time according to the
required time sbt, precision
precision, and additional adjustments requested by the
flags argument. Flags accepted by the
callout_when
() function are the same as flags for
the callout_reset
() function. The resulting time is
assigned to the variable pointed to by the sbt_res
argument, and the resulting precision is assigned to
*precision_res. When passing the results to
callout_reset, add the C_PRECALC
flag to flags, to avoid incorrect re-adjustment. The
function is intended for situations where precise time of the callout run
should be known in advance, since trying to read this time from the callout
structure itself after a callout_reset
() call is
racy.
The callout subsystem invokes callout functions from its own thread context. Without some kind of synchronization, it is possible that a callout function will be invoked concurrently with an attempt to stop or reset the callout by another thread. In particular, since callout functions typically acquire a lock as their first action, the callout function may have already been invoked, but is blocked waiting for that lock at the time that another thread tries to reset or stop the callout.
There are three main techniques for addressing these synchronization concerns. The first approach is preferred as it is the simplest:
callout_init_mtx
(),
callout_init_rm
(),
or
callout_init_rw
().
When a callout is associated with a lock, the callout subsystem acquires
the lock before the callout function is invoked. This allows the callout
subsystem to transparently handle races between callout cancellation,
scheduling, and execution. Note that the associated lock must be acquired
before calling callout_stop
() or one of the
callout_reset
() or
callout_schedule
() functions to provide this
safety.
A callout initialized via
callout_init
()
with mpsafe set to zero is implicitly associated
with the Giant mutex. If
Giant is held when cancelling or rescheduling the
callout, then its use will prevent races with the callout function.
callout_stop
() (or the
callout_reset
() and
callout_schedule
() function families) indicates
whether or not the callout was removed. If it is known that the callout
was set and the callout function has not yet executed, then a return value
of FALSE
indicates that the callout function is
about to be called. For example:
if (sc->sc_flags & SCFLG_CALLOUT_RUNNING) { if (callout_stop(&sc->sc_callout)) { sc->sc_flags &= ~SCFLG_CALLOUT_RUNNING; /* successfully stopped */ } else { /* * callout has expired and callout * function is about to be executed */ } }
callout_pending
(),
callout_active
() and
callout_deactivate
() macros can be used together
to work around the race conditions. When a callout's timeout is set, the
callout subsystem marks the callout as both active and
pending. When the timeout time arrives, the callout
subsystem begins processing the callout by first clearing the
pending flag. It then invokes the callout function
without changing the active flag, and does not clear the
active flag even after the callout function returns. The
mechanism described here requires the callout function itself to clear the
active flag using the
callout_deactivate
() macro. The
callout_stop
() and
callout_drain
() functions always clear both the
active and pending flags before
returning.
The callout function should first check
the pending flag and return without action if
callout_pending
()
returns TRUE
. This indicates that the callout
was rescheduled using callout_reset
() just
before the callout function was invoked. If
callout_active
() returns
FALSE
then the callout function should also
return without action. This indicates that the callout has been stopped.
Finally, the callout function should call
callout_deactivate
() to clear the
active flag. For example:
mtx_lock(&sc->sc_mtx); if (callout_pending(&sc->sc_callout)) { /* callout was reset */ mtx_unlock(&sc->sc_mtx); return; } if (!callout_active(&sc->sc_callout)) { /* callout was stopped */ mtx_unlock(&sc->sc_mtx); return; } callout_deactivate(&sc->sc_callout); /* rest of callout function */
Together with appropriate synchronization,
such as the mutex used above, this approach permits the
callout_stop
()
and callout_reset
() functions to be used at any
time without races. For example:
mtx_lock(&sc->sc_mtx); callout_stop(&sc->sc_callout); /* The callout is effectively stopped now. */
If the callout is still pending then
these functions operate normally, but if processing of the callout has
already begun then the tests in the callout function cause it to return
without further action. Synchronization between the callout function and
other code ensures that stopping or resetting the callout will never be
attempted while the callout function is past the
callout_deactivate
()
call.
The above technique additionally ensures
that the active flag always reflects whether the
callout is effectively enabled or disabled. If
callout_active
()
returns false, then the callout is effectively disabled, since even if
the callout subsystem is actually just about to invoke the callout
function, the callout function will return without action.
There is one final race condition that must
be considered when a callout is being stopped for the last time. In this
case it may not be safe to let the callout function itself detect that the
callout was stopped, since it may need to access data objects that have
already been destroyed or recycled. To ensure that the callout is completely
finished, a call to
callout_drain
()
should be used. In particular, a callout should always be drained prior to
destroying its associated lock or releasing the storage for the callout
structure.
The function
timeout
()
schedules a call to the function given by the argument
func to take place after
ticks/hz seconds. Non-positive
values of ticks are silently converted to the value
‘1’. func should be a pointer to a
function that takes a void * argument. Upon
invocation, func will receive
arg as its only argument. The return value from
timeout
() is a struct
callout_handle which can be used in conjunction with the
untimeout
() function to request that a scheduled
timeout be canceled.
The function
callout_handle_init
()
can be used to initialize a handle to a state which will cause any calls to
untimeout
() with that handle to return with no side
effects.
Assigning a callout handle the
value of
CALLOUT_HANDLE_INITIALIZER
()
performs the same function as callout_handle_init
()
and is provided for use on statically declared or global callout
handles.
The function
untimeout
()
cancels the timeout associated with handle using the
func and arg arguments to
validate the handle. If the handle does not correspond to a timeout with the
function func taking the argument
arg no action is taken. handle
must be initialized by a previous call to timeout
(),
callout_handle_init
(), or assigned the value of
CALLOUT_HANDLE_INITIALIZER
(&handle)
before being passed to untimeout
(). The behavior of
calling untimeout
() with an uninitialized handle is
undefined.
As handles are recycled by the system, it is
possible (although unlikely) that a handle from one invocation of
timeout
()
may match the handle of another invocation of
timeout
() if both calls used the same function
pointer and argument, and the first timeout is expired or canceled before
the second call. The timeout facility offers O(1) running time for
timeout
() and untimeout
().
Timeouts are executed from
softclock
()
with the Giant lock held. Thus they are protected from
re-entrancy.
The callout_active
() macro returns the
state of a callout's active flag.
The callout_pending
() macro returns the
state of a callout's pending flag.
The callout_reset
() and
callout_schedule
() function families return a value
of one if the callout was pending before the new function invocation was
scheduled.
The callout_stop
() and
callout_drain
() functions return a value of one if
the callout was still pending when it was called, a zero if the callout
could not be stopped and a negative one is it was either not running or has
already completed. The timeout
() function returns a
struct callout_handle that can be passed to
untimeout
().
The current timeout and untimeout routines are based on the work of Adam M. Costello and George Varghese, published in a technical report entitled Redesigning the BSD Callout and Timer Facilities and modified slightly for inclusion in FreeBSD by Justin T. Gibbs. The original work on the data structures used in this implementation was published by G. Varghese and A. Lauck in the paper Hashed and Hierarchical Timing Wheels: Data Structures for the Efficient Implementation of a Timer Facility in the Proceedings of the 11th ACM Annual Symposium on Operating Systems Principles. The current implementation replaces the long standing BSD linked list callout mechanism which offered O(n) insertion and removal running time but did not generate or require handles for untimeout operations.
July 27, 2016 | Debian |