cv_init(9F)

NAME

     condvar,   cv_init,    cv_destroy,    cv_wait,    cv_signal,
     cv_broadcast,  cv_wait_sig, cv_timedwait, cv_timedwait_sig -
     condition variable routines

SYNOPSIS

     #include <sys/ksynch.h>

     void cv_init(kcondvar_t *cvp, char *name,  kcv_type_t  type,
     void *arg);

     void cv_destroy(kcondvar_t *cvp);

     void cv_wait(kcondvar_t *cvp, kmutex_t *mp);

     void cv_signal(kcondvar_t *cvp);

     void cv_broadcast(kcondvar_t *cvp);

     int cv_wait_sig(kcondvar_t *cvp, kmutex_t *mp);

     clock_t cv_timedwait(kcondvar_t *cvp, kmutex_t *mp,  clock_t
     timeout);

     clock_t  cv_timedwait_sig(kcondvar_t  *cvp,  kmutex_t   *mp,
     clock_t timeout);

INTERFACE LEVEL

     Solaris DDI specific (Solaris DDI).

PARAMETERS

     cvp   A pointer to an abstract data type kcondvar_t.

     mp    A pointer to a mutual exclusion lock (kmutex_t),  ini-
           tialized by mutex_init(9F) and held by the caller.

     name  Descriptive string. This is  obsolete  and  should  be
           NULL. (Non-NULL strings are legal, but they're a waste
           of kernel memory.)

     type  The constant CV_DRIVER.

     arg   A type-specific argument, drivers should pass  arg  as
           NULL.

     timeout
           A  time,  in   absolute   ticks   since   boot,   when
           cv_timedwait() or cv_timedwait_sig() should return.

DESCRIPTION

     Condition variables are a standard form of thread synchroni-
     zation.  They  are designed to be used with mutual exclusion
     locks (mutexes). The associated mutex is used to ensure that
     a  condition  can  be checked atomically and that the thread
     can block on the associated condition variable without miss-
     ing  either  a  change to the condition or a signal that the
     condition has changed. Condition variables must be  initial-
     ized  by  calling cv_init(), and must be deallocated by cal-
     ling cv_destroy().

     The usual use of condition variables is to check a condition
     (for  example, device state, data structure reference count,
     etc.) while holding a mutex which keeps other  threads  from
     changing  the  condition.  If the condition is such that the
     thread should block, cv_wait() is called with a related con-
     dition  variable and the mutex. At some later point in time,
     another thread would acquire the mutex,  set  the  condition
     such  that the previous thread can be unblocked, unblock the
     previous thread with cv_signal() or cv_broadcast(), and then
     release the mutex.

     cv_wait() suspends the calling thread and  exits  the  mutex
     atomically so that another thread which holds the mutex can-
     not signal on the  condition  variable  until  the  blocking
     thread  is  blocked.  Before  returning,  the mutex is reac-
     quired.

     cv_signal() signals the  condition  and  wakes  one  blocked
     thread.  All  blocked  threads  can  be unblocked by calling
     cv_broadcast(). You  must  acquire  the  mutex  passed  into
     cv_wait() before calling cv_signal() or cv_broadcast().

     The function  cv_wait_sig()  is  similar  to  cv_wait()  but
     returns  0  if a signal (for example, by kill(2)) is sent to
     the thread. In any case,  the  mutex  is  reacquired  before
     returning.

     The function cv_timedwait() is similar to cv_wait(),  except
     that  it  returns  -1  without  the condition being signaled
     after the timeout time has been reached.

     The function cv_timedwait_sig() is similar to cv_timedwait()
     and  cv_wait_sig(),  except  that  it returns -1 without the
     condition being signaled after the  timeout  time  has  been
     reached,  or 0 if a signal (for example, by kill(2)) is sent
     to the thread.

     For both cv_timedwait() and cv_timedwait_sig(), time  is  in
     absolute  clock  ticks  since  the  last  system reboot. The
     current time may be found by calling ddi_get_lbolt(9F).

RETURN VALUES

     0     For  cv_wait_sig()  and  cv_timedwait_sig()  indicates
           that  the  condition  was not necessarily signaled and
           the function returned because a signal (as in kill(2))
           was pending.

     -1    For cv_timedwait()  and  cv_timedwait_sig()  indicates
           that  the  condition  was not necessarily signaled and
           the function returned because  the  timeout  time  was
           reached.

      >0   For       cv_wait_sig(),       cv_timedwait()       or
           cv_timedwait_sig()  indicates  that  the condition was
           met and  the  function  returned  due  to  a  call  to
           cv_signal()  or  cv_broadcast(), or due to a premature
           wakeup (see NOTES).

CONTEXT

     These functions can be called from user, kernel or interrupt
     context.  In most cases, however, cv_wait(), cv_timedwait(),
     cv_wait_sig(), and cv_timedwait_sig() should not  be  called
     from  interrupt  context,  and cannot be called from a high-
     level interrupt context.

     If    cv_wait(),    cv_timedwait(),    cv_wait_sig(),     or
     cv_timedwait_sig()  are  used from interrupt context, lower-
     priority interrupts will not be serviced  during  the  wait.
     This  means  that if the thread that will eventually perform
     the wakeup becomes blocked on  anything  that  requires  the
     lower-priority interrupt, the system will hang.

     For example, the thread that will  perform  the  wakeup  may
     need  to  first  allocate memory. This memory allocation may
     require waiting  for  paging  I/O  to  complete,  which  may
     require  a  lower-priority  disk  or network interrupt to be
     serviced. In general,  situations  like  this  are  hard  to
     predict,  so  it  is advisable to avoid waiting on condition
     variables or semaphores in an interrupt context.

EXAMPLES

     Example 1: Waiting for a Flag Value in a Driver's Unit

     Here the condition being waited for is a  flag  value  in  a
     driver's  unit  structure. The condition variable is also in
     the unit structure, and the flag  word  is  protected  by  a
     mutex in the unit structure.

          mutex_enter(&un->un_lock);
          while (un->un_flag & UNIT_BUSY)
            cv_wait(&un->un_cv, &un->un_lock);
          un->un_flag |= UNIT_BUSY;
          mutex_exit(&un->un_lock);

     Example 2: Unblocking Threads Blocked by the Code in Example
     1
     At some later point in time, another  thread  would  execute
     the  following  to  unblock any threads blocked by the above
     code.

     mutex_enter(&un->un_lock);
     un->un_flag &= ~UNIT_BUSY;
     cv_broadcast(&un->un_cv);
     mutex_exit(&un->un_lock);

NOTES

     It is possible for cv_wait(), cv_wait_sig(), cv_timedwait(),
     and  cv_timedwait_sig()  to return prematurely, that is, not
     due to a call to cv_signal() or cv_broadcast(). This  occurs
     most   commonly   in   the   case   of   cv_wait_sig()   and
     cv_timedwait_sig() when the thread is stopped and  restarted
     by  job  control signals or by a debugger, but can happen in
     other cases as well, even for  cv_wait().  Code  that  calls
     these  functions must always recheck the reason for blocking
     and call again if the reason for blocking is still true.

     If your driver needs to wait on  behalf  of  processes  that
     have  real-time  constraints, use cv_timedwait() rather than
     delay(9F). The delay() function calls timeout(9F), which can
     be subject to priority inversions.

SEE ALSO

     kill(2), ddi_get_lbolt(9F), mutex(9F), mutex_init(9F)

     Writing Device Drivers