EVENTTIMERS(9) | Kernel Developer's Manual | EVENTTIMERS(9) |
eventtimers
—
kernel event timers subsystem
#include
<sys/timeet.h>
struct eventtimer; typedef int et_start_t(struct eventtimer *et, sbintime_t first, sbintime_t period); typedef int et_stop_t(struct eventtimer *et); typedef void et_event_cb_t(struct eventtimer *et, void *arg); typedef int et_deregister_cb_t(struct eventtimer *et, void *arg); struct eventtimer { SLIST_ENTRY(eventtimer) et_all; char *et_name; int et_flags; #define ET_FLAGS_PERIODIC 1 #define ET_FLAGS_ONESHOT 2 #define ET_FLAGS_PERCPU 4 #define ET_FLAGS_C3STOP 8 #define ET_FLAGS_POW2DIV 16 int et_quality; int et_active; uint64_t et_frequency; sbintime_t et_min_period; sbintime_t et_max_period; et_start_t *et_start; et_stop_t *et_stop; et_event_cb_t *et_event_cb; et_deregister_cb_t *et_deregister_cb; void *et_arg; void *et_priv; struct sysctl_oid *et_sysctl; };
et_register
(struct
eventtimer *et);
int
et_deregister
(struct
eventtimer *et);
void
et_change_frequency
(struct
eventtimer *et, uint64_t
newfreq);
ET_LOCK
();
ET_UNLOCK
();
struct eventtimer *
et_find
(const
char *name, int
check, int
want);
int
et_init
(struct
eventtimer *et,
et_event_cb_t *event,
et_deregister_cb_t
*deregister, void
*arg);
int
et_start
(struct
eventtimer *et,
sbintime_t first,
sbintime_t period);
int
et_stop
(struct
eventtimer *et);
int
et_ban
(struct
eventtimer *et);
int
et_free
(struct
eventtimer *et);
Event timers are responsible for generating interrupts at specified time or periodically, to run different time-based events. Subsystem consists of three main parts:
Driver API is built around eventtimer structure. To register its
functionality driver allocates that structure and calls
et_register
().
Driver should fill following fields there:
After the event timer functionality is registered, it is controlled via et_start and et_stop methods. et_start method is called to start the specified event timer. The last two arguments are used to specify time when events should be generated. first argument specifies time period before the first event generated. In periodic mode NULL value specifies that first period is equal to the period argument value. period argument specifies the time period between following events for the periodic mode. The NULL value there specifies the one-shot mode. At least one of these two arguments should be not NULL. When event time arrive, driver should call et_event_cb callback function, passing et_arg as the second argument. et_stop method is called to stop the specified event timer. For the per-CPU event timers et_start and et_stop methods control timers associated with the current CPU.
Driver may deregister its functionality by
calling
et_deregister
().
If the frequency of the clock hardware
can change while it is running (for example, during power-saving modes), the
driver must call
et_change_frequency
()
on each change. If the given event timer is the active timer,
et_change_frequency
() stops the timer on all CPUs,
updates et->frequency, then restarts the timer on
all CPUs so that all current events are rescheduled using the new frequency.
If the given timer is not currently active,
et_change_frequency
() simply updates
et->frequency.
et_find
() allows consumer to find
available event timer, optionally matching specific name and/or capability
flags. Consumer may read returned eventtimer structure, but should not
modify it. When wanted event timer is found,
et_init
() should be called for it, submitting
event and optionally deregister
callbacks functions, and the opaque argument arg. That
argument will be passed as argument to the callbacks. Event callback
function will be called on scheduled time events. It is called from the
hardware interrupt context, so no sleep is permitted there. Deregister
callback function may be called to report consumer that the event timer
functionality is no longer available. On this call, consumer should stop
using event timer before the return.
After the timer is found and initialized, it can
be controlled via
et_start
()
and et_stop
(). The arguments are the same as
described in driver API. Per-CPU event timers can be controlled only from
specific CPUs.
et_ban
()
allows consumer to mark event timer as broken via clearing both one-shot and
periodic capability flags, if it was somehow detected.
et_free
()
is the opposite to
et_init
().
It releases the event timer for other consumers use.
ET_LOCK
()
and
ET_UNLOCK
()
macros should be used to manage mutex(9) lock around
et_find
(),
et_init
() and et_free
()
calls to serialize access to the list of the registered event timers and the
pointers returned by et_find
().
et_start
() and et_stop
()
calls should be serialized in consumer's internal way to avoid concurrent
timer hardware access.
Alexander Motin <mav@FreeBSD.org>
April 2, 2014 | Debian |