/* SPDX-License-Identifier: GPL-2.0 */
#ifndef _LINUX_WAIT_BIT_H
#define _LINUX_WAIT_BIT_H
/*
* Linux wait-bit related types and methods:
*/
#include <linux/wait.h>
struct wait_bit_key {
unsigned long *flags;
int bit_nr;
unsigned long timeout;
};
struct wait_bit_queue_entry {
struct wait_bit_key key;
struct wait_queue_entry wq_entry;
};
#define __WAIT_BIT_KEY_INITIALIZER(word, bit) \
{ .flags = word, .bit_nr = bit, }
typedef int wait_bit_action_f(struct wait_bit_key *key, int mode);
void __wake_up_bit(struct wait_queue_head *wq_head, unsigned long *word, int bit);
int __wait_on_bit(struct wait_queue_head *wq_head, struct wait_bit_queue_entry *wbq_entry, wait_bit_action_f *action, unsigned int mode);
int __wait_on_bit_lock(struct wait_queue_head *wq_head, struct wait_bit_queue_entry *wbq_entry, wait_bit_action_f *action, unsigned int mode);
void wake_up_bit(unsigned long *word, int bit);
int out_of_line_wait_on_bit(unsigned long *word, int, wait_bit_action_f *action, unsigned int mode);
int out_of_line_wait_on_bit_timeout(unsigned long *word, int, wait_bit_action_f *action, unsigned int mode, unsigned long timeout);
int out_of_line_wait_on_bit_lock(unsigned long *word, int, wait_bit_action_f *action, unsigned int mode);
struct wait_queue_head *bit_waitqueue(unsigned long *word, int bit);
extern void __init wait_bit_init(void);
int wake_bit_function(struct wait_queue_entry *wq_entry, unsigned mode, int sync, void *key);
#define DEFINE_WAIT_BIT(name, word, bit) \
struct wait_bit_queue_entry name = { \
.key = __WAIT_BIT_KEY_INITIALIZER(word, bit), \
.wq_entry = { \
.private = current, \
.func = wake_bit_function, \
.entry = \
LIST_HEAD_INIT((name).wq_entry.entry), \
}, \
}
extern int bit_wait(struct wait_bit_key *key, int mode);
extern int bit_wait_io(struct wait_bit_key *key, int mode);
extern int bit_wait_timeout(struct wait_bit_key *key, int mode);
/**
* wait_on_bit - wait for a bit to be cleared
* @word: the address containing the bit being waited on
* @bit: the bit at that address being waited on
* @mode: the task state to sleep in
*
* Wait for the given bit in an unsigned long or bitmap (see DECLARE_BITMAP())
* to be cleared. The clearing of the bit must be signalled with
* wake_up_bit(), often as clear_and_wake_up_bit().
*
* The process will wait on a waitqueue selected by hash from a shared
* pool. It will only be woken on a wake_up for the target bit, even
* if other processes on the same queue are waiting for other bits.
*
* Returned value will be zero if the bit was cleared in which case the
* call has ACQUIRE semantics, or %-EINTR if the process received a
* signal and the mode permitted wake up on that signal.
*/
static inline int
wait_on_bit(unsigned long *word, int bit, unsigned mode)
{
might_sleep();
if (!test_bit_acquire(bit, word))
return 0;
return out_of_line_wait_on_bit(word, bit,
bit_wait,
mode);
}
/**
* wait_on_bit_io - wait for a bit to be cleared
* @word: the address containing the bit being waited on
* @bit: the bit at that address being waited on
* @mode: the task state to sleep in
*
* Wait for the given bit in an unsigned long or bitmap (see DECLARE_BITMAP())
* to be cleared. The clearing of the bit must be signalled with
* wake_up_bit(), often as clear_and_wake_up_bit().
*
* This is similar to wait_on_bit(), but calls io_schedule() instead of
* schedule() for the actual waiting.
*
* Returned value will be zero if the bit was cleared in which case the
* call has ACQUIRE semantics, or %-EINTR if the process received a
* signal and the mode permitted wake up on that signal.
*/
static inline int
wait_on_bit_io(unsigned long *word, int bit, unsigned mode)
{
might_sleep();
if (!test_bit_acquire(bit, word))
return 0;
return out_of_line_wait_on_bit(word, bit,
bit_wait_io,
mode);
}
/**
* wait_on_bit_timeout - wait for a bit to be cleared or a timeout to elapse
* @word: the address containing the bit being waited on
* @bit: the bit at that address being waited on
* @mode: the task state to sleep in
* @timeout: timeout, in jiffies
*
* Wait for the given bit in an unsigned long or bitmap (see
* DECLARE_BITMAP()) to be cleared, or for a timeout to expire. The
* clearing of the bit must be signalled with wake_up_bit(), often as
* clear_and_wake_up_bit().
*
* This is similar to wait_on_bit(), except it also takes a timeout
* parameter.
*
* Returned value will be zero if the bit was cleared in which case the
* call has ACQUIRE semantics, or %-EINTR if the process received a
* signal and the mode permitted wake up on that signal, or %-EAGAIN if the
* timeout elapsed.
*/
static inline int
wait_on_bit_timeout(unsigned long *word, int bit, unsigned mode,
unsigned long timeout)
{
might_sleep();
if (!test_bit_acquire(bit, word))
return 0;
return out_of_line_wait_on_bit_timeout(word, bit,
bit_wait_timeout,
mode, timeout);
}
/**
* wait_on_bit_action - wait for a bit to be cleared
* @word: the address containing the bit waited on
* @bit: the bit at that address being waited on
* @action: the function used to sleep, which may take special actions
* @mode: the task state to sleep in
*
* Wait for the given bit in an unsigned long or bitmap (see DECLARE_BITMAP())
* to be cleared. The clearing of the bit must be signalled with
* wake_up_bit(), often as clear_and_wake_up_bit().
*
* This is similar to wait_on_bit(), but calls @action() instead of
* schedule() for the actual waiting.
*
* Returned value will be zero if the bit was cleared in which case the
* call has ACQUIRE semantics, or the error code returned by @action if
* that call returned non-zero.
*/
static inline int
wait_on_bit_action(unsigned long *word, int bit, wait_bit_action_f *action,
unsigned mode)
{
might_sleep();
if (!test_bit_acquire(bit, word))
return 0;
return out_of_line_wait_on_bit(word, bit, action, mode);
}
/**
* wait_on_bit_lock - wait for a bit to be cleared, then set it
* @word: the address containing the bit being waited on
* @bit: the bit of the word being waited on and set
* @mode: the task state to sleep in
*
* Wait for the given bit in an unsigned long or bitmap (see
* DECLARE_BITMAP()) to be cleared. The clearing of the bit must be
* signalled with wake_up_bit(), often as clear_and_wake_up_bit(). As
* soon as it is clear, atomically set it and return.
*
* This is similar to wait_on_bit(), but sets the bit before returning.
*
* Returned value will be zero if the bit was successfully set in which
* case the call has the same memory sequencing semantics as
* test_and_clear_bit(), or %-EINTR if the process received a signal and
* the mode permitted wake up on that signal.
*/
static inline int
wait_on_bit_lock(unsigned long *word, int bit, unsigned mode)
{
might_sleep();
if (!test_and_set_bit(bit, word))
return 0;
return out_of_line_wait_on_bit_lock(word, bit, bit_wait, mode);
}
/**
* wait_on_bit_lock_io - wait for a bit to be cleared, then set it
* @word: the address containing the bit being waited on
* @bit: the bit of the word being waited on and set
* @mode: the task state to sleep in
*
* Wait for the given bit in an unsigned long or bitmap (see
* DECLARE_BITMAP()) to be cleared. The clearing of the bit must be
* signalled with wake_up_bit(), often as clear_and_wake_up_bit(). As
* soon as it is clear, atomically set it and return.
*
* This is similar to wait_on_bit_lock(), but calls io_schedule() instead
* of schedule().
*
* Returns zero if the bit was (eventually) found to be clear and was
* set. Returns non-zero if a signal was delivered to the process and
* the @mode allows that signal to wake the process.
*/
static inline int
wait_on_bit_lock_io(unsigned long *word, int bit, unsigned mode)
{
might_sleep();
if (!test_and_set_bit(bit, word))
return 0;
return out_of_line_wait_on_bit_lock(word, bit, bit_wait_io, mode);
}
/**
* wait_on_bit_lock_action - wait for a bit to be cleared, then set it
* @word: the address containing the bit being waited on
* @bit: the bit of the word being waited on and set
* @action: the function used to sleep, which may take special actions
* @mode: the task state to sleep in
*
* This is similar to wait_on_bit_lock(), but calls @action() instead of
* schedule() for the actual waiting.
*
* Returned value will be zero if the bit was successfully set in which
* case the call has the same memory sequencing semantics as
* test_and_clear_bit(), or the error code returned by @action if that
* call returned non-zero.
*/
static inline int
wait_on_bit_lock_action(unsigned long *word, int bit, wait_bit_action_f *action,
unsigned mode)
{
might_sleep();
if (!test_and_set_bit(bit, word))
return 0;
return out_of_line_wait_on_bit_lock(word, bit, action, mode);
}
extern void init_wait_var_entry(struct wait_bit_queue_entry *wbq_entry, void *var, int flags);
extern void wake_up_var(void *var);
extern wait_queue_head_t *__var_waitqueue(void *p);
#define ___wait_var_event(var, condition, state, exclusive, ret, cmd) \
({ \
__label__ __out; \
struct wait_queue_head *__wq_head = __var_waitqueue(var); \
struct wait_bit_queue_entry __wbq_entry; \
long __ret = ret; /* explicit shadow */ \
\
init_wait_var_entry(&__wbq_entry, var, \
exclusive ? WQ_FLAG_EXCLUSIVE : 0); \
for (;;) { \
long __int = prepare_to_wait_event(__wq_head, \
&__wbq_entry.wq_entry, \
state); \
if (condition) \
break; \
\
if (___wait_is_interruptible(state) && __int) { \
__ret = __int; \
goto __out; \
} \
\
cmd; \
} \
finish_wait(__wq_head, &__wbq_entry.wq_entry); \
__out: __ret; \
})
#define __wait_var_event(var, condition) \
___wait_var_event(var, condition, TASK_UNINTERRUPTIBLE, 0, 0, \
schedule())
#define __wait_var_event_io(var, condition) \
___wait_var_event(var, condition, TASK_UNINTERRUPTIBLE, 0, 0, \
io_schedule())
/**
* wait_var_event - wait for a variable to be updated and notified
* @var: the address of variable being waited on
* @condition: the condition to wait for
*
* Wait for a @condition to be true, only re-checking when a wake up is
* received for the given @var (an arbitrary kernel address which need
* not be directly related to the given condition, but usually is).
*
* The process will wait on a waitqueue selected by hash from a shared
* pool. It will only be woken on a wake_up for the given address.
*
* The condition should normally use smp_load_acquire() or a similarly
* ordered access to ensure that any changes to memory made before the
* condition became true will be visible after the wait completes.
*/
#define wait_var_event(var, condition) \
do { \
might_sleep(); \
if (condition) \
break; \
__wait_var_event(var, condition); \
} while (0)
/**
* wait_var_event_io - wait for a variable to be updated and notified
* @var: the address of variable being waited on
* @condition: the condition to wait for
*
* Wait for an IO related @condition to be true, only re-checking when a
* wake up is received for the given @var (an arbitrary kernel address
* which need not be directly related to the given condition, but
* usually is).
*
* The process will wait on a waitqueue selected by hash from a shared
* pool. It will only be woken on a wake_up for the given address.
*
* This is similar to wait_var_event(), but calls io_schedule() instead
* of schedule().
*
* The condition should normally use smp_load_acquire() or a similarly
* ordered access to ensure that any changes to memory made before the
* condition became true will be visible after the wait completes.
*/
#define wait_var_event_io(var, condition) \
do { \
might_sleep(); \
if (condition) \
break; \
__wait_var_event_io(var, condition); \
} while (0)
#define __wait_var_event_killable(var, condition) \
___wait_var_event(var, condition, TASK_KILLABLE, 0, 0, \
schedule())
/**
* wait_var_event_killable - wait for a variable to be updated and notified
* @var: the address of variable being waited on
* @condition: the condition to wait for
*
* Wait for a @condition to be true or a fatal signal to be received,
* only re-checking the condition when a wake up is received for the given
* @var (an arbitrary kernel address which need not be directly related
* to the given condition, but usually is).
*
* This is similar to wait_var_event() but returns a value which is
* 0 if the condition became true, or %-ERESTARTSYS if a fatal signal
* was received.
*
* The condition should normally use smp_load_acquire() or a similarly
* ordered access to ensure that any changes to memory made before the
* condition became true will be visible after the wait completes.
*/
#define wait_var_event_killable(var, condition) \
({ \
int __ret = 0; \
might_sleep(); \
if (!(condition)) \
__ret = __wait_var_event_killable(var, condition); \
__ret; \
})
#define __wait_var_event_timeout(var, condition, timeout) \
___wait_var_event(var, ___wait_cond_timeout(condition), \
TASK_UNINTERRUPTIBLE, 0, timeout, \
__ret = schedule_timeout(__ret))
/**
* wait_var_event_timeout - wait for a variable to be updated or a timeout to expire
* @var: the address of variable being waited on
* @condition: the condition to wait for
* @timeout: maximum time to wait in jiffies
*
* Wait for a @condition to be true or a timeout to expire, only
* re-checking the condition when a wake up is received for the given
* @var (an arbitrary kernel address which need not be directly related
* to the given condition, but usually is).
*
* This is similar to wait_var_event() but returns a value which is 0 if
* the timeout expired and the condition was still false, or the
* remaining time left in the timeout (but at least 1) if the condition
* was found to be true.
*
* The condition should normally use smp_load_acquire() or a similarly
* ordered access to ensure that any changes to memory made before the
* condition became true will be visible after the wait completes.
*/
#define wait_var_event_timeout(var, condition, timeout) \
({ \
long __ret = timeout; \
might_sleep(); \
if (!___wait_cond_timeout(condition)) \
__ret = __wait_var_event_timeout(var, condition, timeout); \
__ret; \
})
#define __wait_var_event_interruptible(var, condition) \
___wait_var_event(var, condition, TASK_INTERRUPTIBLE, 0, 0, \
schedule())
/**
* wait_var_event_killable - wait for a variable to be updated and notified
* @var: the address of variable being waited on
* @condition: the condition to wait for
*
* Wait for a @condition to be true or a signal to be received, only
* re-checking the condition when a wake up is received for the given
* @var (an arbitrary kernel address which need not be directly related
* to the given condition, but usually is).
*
* This is similar to wait_var_event() but returns a value which is 0 if
* the condition became true, or %-ERESTARTSYS if a signal was received.
*
* The condition should normally use smp_load_acquire() or a similarly
* ordered access to ensure that any changes to memory made before the
* condition became true will be visible after the wait completes.
*/
#define wait_var_event_interruptible(var, condition) \
({ \
int __ret = 0; \
might_sleep(); \
if (!(condition)) \
__ret = __wait_var_event_interruptible(var, condition); \
__ret; \
})
/**
* wait_var_event_any_lock - wait for a variable to be updated under a lock
* @var: the address of the variable being waited on
* @condition: condition to wait for
* @lock: the object that is locked to protect updates to the variable
* @type: prefix on lock and unlock operations
* @state: waiting state, %TASK_UNINTERRUPTIBLE etc.
*
* Wait for a condition which can only be reliably tested while holding
* a lock. The variables assessed in the condition will normal be updated
* under the same lock, and the wake up should be signalled with
* wake_up_var_locked() under the same lock.
*
* This is similar to wait_var_event(), but assumes a lock is held
* while calling this function and while updating the variable.
*
* This must be called while the given lock is held and the lock will be
* dropped when schedule() is called to wait for a wake up, and will be
* reclaimed before testing the condition again. The functions used to
* unlock and lock the object are constructed by appending _unlock and _lock
* to @type.
*
* Return %-ERESTARTSYS if a signal arrives which is allowed to interrupt
* the wait according to @state.
*/
#define wait_var_event_any_lock(var, condition, lock, type, state) \
({ \
int __ret = 0; \
if (!(condition)) \
__ret = ___wait_var_event(var, condition, state, 0, 0, \
type ## _unlock(lock); \
schedule(); \
type ## _lock(lock)); \
__ret; \
})
/**
* wait_var_event_spinlock - wait for a variable to be updated under a spinlock
* @var: the address of the variable being waited on
* @condition: condition to wait for
* @lock: the spinlock which protects updates to the variable
*
* Wait for a condition which can only be reliably tested while holding
* a spinlock. The variables assessed in the condition will normal be updated
* under the same spinlock, and the wake up should be signalled with
* wake_up_var_locked() under the same spinlock.
*
* This is similar to wait_var_event(), but assumes a spinlock is held
* while calling this function and while updating the variable.
*
* This must be called while the given lock is held and the lock will be
* dropped when schedule() is called to wait for a wake up, and will be
* reclaimed before testing the condition again.
*/
#define wait_var_event_spinlock(var, condition, lock) \
wait_var_event_any_lock(var, condition, lock, spin, TASK_UNINTERRUPTIBLE)
/**
* wait_var_event_mutex - wait for a variable to be updated under a mutex
* @var: the address of the variable being waited on
* @condition: condition to wait for
* @mutex: the mutex which protects updates to the variable
*
* Wait for a condition which can only be reliably tested while holding
* a mutex. The variables assessed in the condition will normal be
* updated under the same mutex, and the wake up should be signalled
* with wake_up_var_locked() under the same mutex.
*
* This is similar to wait_var_event(), but assumes a mutex is held
* while calling this function and while updating the variable.
*
* This must be called while the given mutex is held and the mutex will be
* dropped when schedule() is called to wait for a wake up, and will be
* reclaimed before testing the condition again.
*/
#define wait_var_event_mutex(var, condition, lock) \
wait_var_event_any_lock(var, condition, lock, mutex, TASK_UNINTERRUPTIBLE)
/**
* wake_up_var_protected - wake up waiters for a variable asserting that it is safe
* @var: the address of the variable being waited on
* @cond: the condition which afirms this is safe
*
* When waking waiters which use wait_var_event_any_lock() the waker must be
* holding the reelvant lock to avoid races. This version of wake_up_var()
* asserts that the relevant lock is held and so no barrier is needed.
* The @cond is only tested when CONFIG_LOCKDEP is enabled.
*/
#define wake_up_var_protected(var, cond) \
do { \
lockdep_assert(cond); \
wake_up_var(var); \
} while (0)
/**
* wake_up_var_locked - wake up waiters for a variable while holding a spinlock or mutex
* @var: the address of the variable being waited on
* @lock: The spinlock or mutex what protects the variable
*
* Send a wake up for the given variable which should be waited for with
* wait_var_event_spinlock() or wait_var_event_mutex(). Unlike wake_up_var(),
* no extra barriers are needed as the locking provides sufficient sequencing.
*/
#define wake_up_var_locked(var, lock) \
wake_up_var_protected(var, lockdep_is_held(lock))
/**
* clear_and_wake_up_bit - clear a bit and wake up anyone waiting on that bit
* @bit: the bit of the word being waited on
* @word: the address containing the bit being waited on
*
* The designated bit is cleared and any tasks waiting in wait_on_bit()
* or similar will be woken. This call has RELEASE semantics so that
* any changes to memory made before this call are guaranteed to be visible
* after the corresponding wait_on_bit() completes.
*/
static inline void clear_and_wake_up_bit(int bit, unsigned long *word)
{
clear_bit_unlock(bit, word);
/* See wake_up_bit() for which memory barrier you need to use. */
smp_mb__after_atomic();
wake_up_bit(word, bit);
}
/**
* test_and_clear_wake_up_bit - clear a bit if it was set: wake up anyone waiting on that bit
* @bit: the bit of the word being waited on
* @word: the address of memory containing that bit
*
* If the bit is set and can be atomically cleared, any tasks waiting in
* wait_on_bit() or similar will be woken. This call has the same
* complete ordering semantics as test_and_clear_bit(). Any changes to
* memory made before this call are guaranteed to be visible after the
* corresponding wait_on_bit() completes.
*
* Returns %true if the bit was successfully set and the wake up was sent.
*/
static inline bool test_and_clear_wake_up_bit(int bit, unsigned long *word)
{
if (!test_and_clear_bit(bit, word))
return false;
/* no extra barrier required */
wake_up_bit(word, bit);
return true;
}
/**
* atomic_dec_and_wake_up - decrement an atomic_t and if zero, wake up waiters
* @var: the variable to dec and test
*
* Decrements the atomic variable and if it reaches zero, send a wake_up to any
* processes waiting on the variable.
*
* This function has the same complete ordering semantics as atomic_dec_and_test.
*
* Returns %true is the variable reaches zero and the wake up was sent.
*/
static inline bool atomic_dec_and_wake_up(atomic_t *var)
{
if (!atomic_dec_and_test(var))
return false;
/* No extra barrier required */
wake_up_var(var);
return true;
}
/**
* store_release_wake_up - update a variable and send a wake_up
* @var: the address of the variable to be updated and woken
* @val: the value to store in the variable.
*
* Store the given value in the variable send a wake up to any tasks
* waiting on the variable. All necessary barriers are included to ensure
* the task calling wait_var_event() sees the new value and all values
* written to memory before this call.
*/
#define store_release_wake_up(var, val) \
do { \
smp_store_release(var, val); \
smp_mb(); \
wake_up_var(var); \
} while (0)
#endif /* _LINUX_WAIT_BIT_H */