doc/kernel/nanokernel/nanokernel_timers.rst - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 .. _nanokernel_timers:

 Timer Services
 ##############

 Concepts
 ********

 The nanokernel's :dfn:`timer` object type uses the kernel's system clock to
 monitor the passage of time, as measured in ticks. It is mainly intended for use
 by fibers.

 A *nanokernel timer* allows a fiber or task to determine whether or not a
 specified time limit has been reached while the thread itself is busy performing
 other work. A thread can use more than one timer when it needs to monitor multiple
 time intervals simultaneously.

 A nanokernel timer points to a *user data structure* that is supplied by the
 thread that uses it; this pointer is returned when the timer expires. The user
 data structure must be at least 4 bytes long and aligned on a 4-byte boundary,
 as the kernel reserves the first 32 bits of this area for its own use. Any
 remaining bytes of this area can be used to hold data that is helpful to the
 thread that uses the timer.

 Any number of nanokernel timers can be defined. Each timer is a distinct
 variable of type :cpp:type:`struct nano_timer`, and is referenced using a pointer
 to that variable. A timer must be initialized with its user data structure
 before it can be used.

 A nanokernel timer is started by specifying a *duration*, which is the number
 of ticks the timer counts before it expires.

 .. note::
    Care must be taken when specifying the duration of a nanokernel timer,
    since the first tick measured by the timer after it is started will be
    less than a full tick interval. For example, when the system clock period
    is 10 milliseconds, starting a timer than expires after 1 tick will result
    in the timer expiring anywhere from a fraction of a millisecond
    later to just slightly less than 10 milliseconds later. To ensure that
    a timer doesn't expire for at least ``N`` ticks it is necessary to specify
    a duration of ``N+1`` ticks.

 Once started, a nanokernel timer can be tested in either a non-blocking or
 blocking manner to allow a thread to determine if the timer has expired.
 If the timer has expired, the kernel returns the pointer to the user data
 structure. If the timer has not expired, the kernel either returns
 :c:macro:`NULL` (for a non-blocking test), or it waits for the timer to expire
 (for a blocking test).

 .. note::
    The nanokernel does not allow more than one thread to wait on a nanokernel
    timer at any given time. If a second thread starts waiting, only the first
    waiting thread wakes up when the timer expires. The second thread continues
    waiting.

    A task that waits on a nanokernel timer does a ``busy wait``. This is
    not an issue for a nanokernel application's background task; however, in
    a microkernel application, a task that waits on a nanokernel timer remains
    the *current task* and prevents other tasks of equal or lower priority
    from doing useful work.

 A nanokernel timer can be cancelled after it has been started. Cancelling
 a timer while it is still running causes the timer to expire immediately,
 thereby unblocking any thread waiting on the timer. Cancelling a timer
 that has already expired has no effect on the timer.

 A nanokernel timer can be reused once it has expired, but must **not** be
 restarted while it is still running. If desired, a timer can be re-initialized
 with a different user data structure before it is started again.


 Purpose
 *******

 Use a nanokernel timer to determine whether or not a specified number
 of system clock ticks have elapsed while a fiber or task is busy performing
 other work.

 .. note::
    If a fiber or task has no other work to perform while waiting
    for time to pass, it can simply call :cpp:func:`fiber_sleep()`
    or :cpp:func:`task_sleep()`, respectively.

 .. note::
    The kernel provides additional APIs that allow a fiber or task to monitor
    the system clock, as well as the higher precision hardware clock,
    without using a nanokernel timer.


 Usage
 *****

 Example: Initializing a Nanokernel Timer
 ========================================

 This code initializes a nanokernel timer.

 .. code-block:: c

    struct nano_timer my_timer;
    uint32_t data_area[3] = { 0, 1111, 2222 };

    nano_timer_init(&my_timer, data_area);


 Example: Starting a Nanokernel Timer
 ====================================
 This code uses the above nanokernel timer to limit the amount of time a fiber
 spends gathering data before processing it.

 .. code-block:: c

    /* set timer to expire in 10 ticks */
    nano_fiber_timer_start(&my_timer, 10);

    /* gather data until timer expires */
    do {
        ...
    } while (nano_fiber_timer_test(&my_timer, TICKS_NONE) == NULL);

    /* process the data */
    ...


 Example: Cancelling a Nanokernel Timer
 ======================================
 This code illustrates how an active nanokernel timer can be stopped prematurely.

 .. code-block:: c

    struct nano_timer my_timer;
    uint32_t dummy;

    ...

    /* set timer to expire in 10 ticks */
    nano_timer_init(&my_timer, &dummy);
    nano_fiber_timer_start(&my_timer, 10);

    /* do work while waiting for an input signal to arrive */
    ...

    /* now have input signal, so stop the timer if it is still running */
    nano_fiber_timer_stop(&my_timer);

    /* check to see if the timer expired before it was stopped */
    if (nano_fiber_timer_test(&my_timer, TICKS_NONE) != NULL) {
        printf("Warning: Input signal took too long to arrive!");
    }


 APIs
 ****

 APIs for a nanokernel timer provided by :file:`nanokernel.h`
 ============================================================

 :cpp:func:`nano_timer_init()`
    Initialize a timer.

 :cpp:func:`nano_task_timer_start()`, :cpp:func:`nano_fiber_timer_start()`,
 :cpp:func:`nano_isr_timer_start()`, :cpp:func:`nano_timer_start()`
    Start a timer.

 :cpp:func:`nano_task_timer_test()`, :cpp:func:`nano_fiber_timer_test()`,
 :cpp:func:`nano_isr_timer_test()`, :cpp:func:`nano_timer_test()`
    Wait or test for timer expiration.

 :cpp:func:`nano_task_timer_stop()`, :cpp:func:`nano_fiber_timer_stop()`,
 :cpp:func:`nano_isr_timer_stop()`, :cpp:func:`nano_timer_stop()`
    Force timer expiration, if not already expired.

 :cpp:func:`nano_timer_ticks_remain()`
    Return timer ticks before timer expiration.
	.. _nanokernel_timers:

	Timer Services
	##############

	Concepts
	********

	The nanokernel's :dfn:`timer` object type uses the kernel's system clock to
	monitor the passage of time, as measured in ticks. It is mainly intended for use
	by fibers.

	A nanokernel timer allows a fiber or task to determine whether or not a
	specified time limit has been reached while the thread itself is busy performing
	other work. A thread can use more than one timer when it needs to monitor multiple
	time intervals simultaneously.

	A nanokernel timer points to a user data structure that is supplied by the
	thread that uses it; this pointer is returned when the timer expires. The user
	data structure must be at least 4 bytes long and aligned on a 4-byte boundary,
	as the kernel reserves the first 32 bits of this area for its own use. Any
	remaining bytes of this area can be used to hold data that is helpful to the
	thread that uses the timer.

	Any number of nanokernel timers can be defined. Each timer is a distinct
	variable of type :cpp:type:`struct nano_timer`, and is referenced using a pointer
	to that variable. A timer must be initialized with its user data structure
	before it can be used.

	A nanokernel timer is started by specifying a duration, which is the number
	of ticks the timer counts before it expires.

	.. note::
	Care must be taken when specifying the duration of a nanokernel timer,
	since the first tick measured by the timer after it is started will be
	less than a full tick interval. For example, when the system clock period
	is 10 milliseconds, starting a timer than expires after 1 tick will result
	in the timer expiring anywhere from a fraction of a millisecond
	later to just slightly less than 10 milliseconds later. To ensure that
	a timer doesn't expire for at least ``N`` ticks it is necessary to specify
	a duration of ``N+1`` ticks.

	Once started, a nanokernel timer can be tested in either a non-blocking or
	blocking manner to allow a thread to determine if the timer has expired.
	If the timer has expired, the kernel returns the pointer to the user data
	structure. If the timer has not expired, the kernel either returns
	:c:macro:`NULL` (for a non-blocking test), or it waits for the timer to expire
	(for a blocking test).

	.. note::
	The nanokernel does not allow more than one thread to wait on a nanokernel
	timer at any given time. If a second thread starts waiting, only the first
	waiting thread wakes up when the timer expires. The second thread continues
	waiting.

	A task that waits on a nanokernel timer does a ``busy wait``. This is
	not an issue for a nanokernel application's background task; however, in
	a microkernel application, a task that waits on a nanokernel timer remains
	the current task and prevents other tasks of equal or lower priority
	from doing useful work.

	A nanokernel timer can be cancelled after it has been started. Cancelling
	a timer while it is still running causes the timer to expire immediately,
	thereby unblocking any thread waiting on the timer. Cancelling a timer
	that has already expired has no effect on the timer.

	A nanokernel timer can be reused once it has expired, but must not be
	restarted while it is still running. If desired, a timer can be re-initialized
	with a different user data structure before it is started again.


	Purpose
	*******

	Use a nanokernel timer to determine whether or not a specified number
	of system clock ticks have elapsed while a fiber or task is busy performing
	other work.

	.. note::
	If a fiber or task has no other work to perform while waiting
	for time to pass, it can simply call :cpp:func:`fiber_sleep()`
	or :cpp:func:`task_sleep()`, respectively.

	.. note::
	The kernel provides additional APIs that allow a fiber or task to monitor
	the system clock, as well as the higher precision hardware clock,
	without using a nanokernel timer.


	Usage
	*****

	Example: Initializing a Nanokernel Timer
	========================================

	This code initializes a nanokernel timer.

	.. code-block:: c

	struct nano_timer my_timer;
	uint32_t data_area[3] = { 0, 1111, 2222 };

	nano_timer_init(&my_timer, data_area);


	Example: Starting a Nanokernel Timer
	====================================
	This code uses the above nanokernel timer to limit the amount of time a fiber
	spends gathering data before processing it.

	.. code-block:: c

	/* set timer to expire in 10 ticks */
	nano_fiber_timer_start(&my_timer, 10);

	/* gather data until timer expires */
	do {
	...
	} while (nano_fiber_timer_test(&my_timer, TICKS_NONE) == NULL);

	/* process the data */
	...


	Example: Cancelling a Nanokernel Timer
	======================================
	This code illustrates how an active nanokernel timer can be stopped prematurely.

	.. code-block:: c

	struct nano_timer my_timer;
	uint32_t dummy;

	...

	/* set timer to expire in 10 ticks */
	nano_timer_init(&my_timer, &dummy);
	nano_fiber_timer_start(&my_timer, 10);

	/* do work while waiting for an input signal to arrive */
	...

	/* now have input signal, so stop the timer if it is still running */
	nano_fiber_timer_stop(&my_timer);

	/* check to see if the timer expired before it was stopped */
	if (nano_fiber_timer_test(&my_timer, TICKS_NONE) != NULL) {
	printf("Warning: Input signal took too long to arrive!");
	}


	APIs
	****

	APIs for a nanokernel timer provided by :file:`nanokernel.h`
	============================================================

	:cpp:func:`nano_timer_init()`
	Initialize a timer.

	:cpp:func:`nano_task_timer_start()`, :cpp:func:`nano_fiber_timer_start()`,
	:cpp:func:`nano_isr_timer_start()`, :cpp:func:`nano_timer_start()`
	Start a timer.

	:cpp:func:`nano_task_timer_test()`, :cpp:func:`nano_fiber_timer_test()`,
	:cpp:func:`nano_isr_timer_test()`, :cpp:func:`nano_timer_test()`
	Wait or test for timer expiration.

	:cpp:func:`nano_task_timer_stop()`, :cpp:func:`nano_fiber_timer_stop()`,
	:cpp:func:`nano_isr_timer_stop()`, :cpp:func:`nano_timer_stop()`
	Force timer expiration, if not already expired.

	:cpp:func:`nano_timer_ticks_remain()`
	Return timer ticks before timer expiration.