doc/kernel/timing/clocks.rst - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 .. _kernel_timing:

 Kernel Timing
 #############

 Zephyr provides a robust and scalable timing framework to enable
 reporting and tracking of timed events from hardware timing sources of
 arbitrary precision.

 Time Units
 ==========

 Kernel time is tracked in several units which are used for different
 purposes.

 Real time values, typically specified in milliseconds or microseconds,
 are the default presentation of time to application code.  They have
 the advantages of being universally portable and pervasively
 understood, though they may not match the precision of the underlying
 hardware perfectly.

 The kernel presents a "cycle" count via the :c:func:`k_cycle_get_32`
 and :c:func:`k_cycle_get_64` APIs.  The intent is that this counter
 represents the fastest cycle counter that the operating system is able
 to present to the user (for example, a CPU cycle counter) and that the
 read operation is very fast.  The expectation is that very sensitive
 application code might use this in a polling manner to achieve maximal
 precision.  The frequency of this counter is required to be steady
 over time, and is available from
 :c:func:`sys_clock_hw_cycles_per_sec` (which on almost all
 platforms is a runtime constant that evaluates to
 CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC).

 For asynchronous timekeeping, the kernel defines a "ticks" concept.  A
 "tick" is the internal count in which the kernel does all its internal
 uptime and timeout bookkeeping.  Interrupts are expected to be
 delivered on tick boundaries to the extent practical, and no
 fractional ticks are tracked.  The choice of tick rate is configurable
 via :kconfig:option:`CONFIG_SYS_CLOCK_TICKS_PER_SEC`.  Defaults on most
 hardware platforms (ones that support setting arbitrary interrupt
 timeouts) are expected to be in the range of 10 kHz, with software
 emulation platforms and legacy drivers using a more traditional 100 Hz
 value.

 Conversion
 ----------

 Zephyr provides an extensively enumerated conversion library with
 rounding control for all time units.  Any unit of "ms" (milliseconds),
 "us" (microseconds), "tick", or "cyc" can be converted to any other.
 Control of rounding is provided, and each conversion is available in
 "floor" (round down to nearest output unit), "ceil" (round up) and
 "near" (round to nearest).  Finally the output precision can be
 specified as either 32 or 64 bits.

 For example: :c:func:`k_ms_to_ticks_ceil32` will convert a
 millisecond input value to the next higher number of ticks, returning
 a result truncated to 32 bits of precision; and
 :c:func:`k_cyc_to_us_floor64` will convert a measured cycle count
 to an elapsed number of microseconds in a full 64 bits of precision.
 See the reference documentation for the full enumeration of conversion
 routines.

 On most platforms, where the various counter rates are integral
 multiples of each other and where the output fits within a single
 word, these conversions expand to a 2-4 operation sequence, requiring
 full precision only where actually required and requested.

 .. _kernel_timing_uptime:

 Uptime
 ======

 The kernel tracks a system uptime count on behalf of the application.
 This is available at all times via :c:func:`k_uptime_get`, which
 provides an uptime value in milliseconds since system boot.  This is
 expected to be the utility used by most portable application code.

 The internal tracking, however, is as a 64 bit integer count of ticks.
 Apps with precise timing requirements (that are willing to do their
 own conversions to portable real time units) may access this with
 :c:func:`k_uptime_ticks`.

 Timeouts
 ========

 The Zephyr kernel provides many APIs with a "timeout" parameter.
 Conceptually, this indicates the time at which an event will occur.
 For example:

 * Kernel blocking operations like :c:func:`k_sem_take` or
   :c:func:`k_queue_get` may provide a timeout after which the
   routine will return with an error code if no data is available.

 * Kernel :c:struct:`k_timer` objects must specify delays for
   their duration and period.

 * The kernel :c:struct:`k_work_delayable` API provides a timeout parameter
   indicating when a work queue item will be added to the system queue.

 All these values are specified using a :c:struct:`k_timeout_t` value.  This is
 an opaque struct type that must be initialized using one of a family
 of kernel timeout macros.  The most common, :c:macro:`K_MSEC` , defines
 a time in milliseconds after the current time (strictly: the time at
 which the kernel receives the timeout value).

 Other options for timeout initialization follow the unit conventions
 described above: :c:macro:`K_NSEC()`, :c:macro:`K_USEC`, :c:macro:`K_TICKS` and
 :c:macro:`K_CYC()` specify timeout values that will expire after specified
 numbers of nanoseconds, microseconds, ticks and cycles, respectively.

 Precision of :c:struct:`k_timeout_t` values is configurable, with the default
 being 32 bits.  Large uptime counts in non-tick units will experience
 complicated rollover semantics, so it is expected that
 timing-sensitive applications with long uptimes will be configured to
 use a 64 bit timeout type.

 Finally, it is possible to specify timeouts as absolute times since
 system boot.  A timeout initialized with :c:macro:`K_TIMEOUT_ABS_MS`
 indicates a timeout that will expire after the system uptime reaches
 the specified value.  There are likewise nanosecond, microsecond,
 cycles and ticks variants of this API.

 Timing Internals
 ================

 Timeout Queue
 -------------

 All Zephyr :c:struct:`k_timeout_t` events specified using the API above are
 managed in a single, global queue of events.  Each event is stored in
 a double-linked list, with an attendant delta count in ticks from the
 previous event.  The action to take on an event is specified as a
 callback function pointer provided by the subsystem requesting the
 event, along with a :c:struct:`_timeout` tracking struct that is
 expected to be embedded within subsystem-defined data structures (for
 example: a :c:struct:`wait_q` struct, or a :c:struct:`k_tid_t` thread struct).

 Note that all variant units passed via a :c:struct:`k_timeout_t` are converted
 to ticks once on insertion into the list.  There no
 multiple-conversion steps internal to the kernel, so precision is
 guaranteed at the tick level no matter how many events exist or how
 long a timeout might be.

 Note that the list structure means that the CPU work involved in
 managing large numbers of timeouts is quadratic in the number of
 active timeouts.  The API design of the timeout queue was intended to
 permit a more scalable backend data structure, but no such
 implementation exists currently.

 Timer Drivers
 -------------

 Kernel timing at the tick level is driven by a timer driver with a
 comparatively simple API.

 * The driver is expected to be able to "announce" new ticks to the
   kernel via the :c:func:`sys_clock_announce` call, which passes an integer
   number of ticks that have elapsed since the last announce call (or
   system boot).  These calls can occur at any time, but the driver is
   expected to attempt to ensure (to the extent practical given
   interrupt latency interactions) that they occur near tick boundaries
   (i.e. not "halfway through" a tick), and most importantly that they
   be correct over time and subject to minimal skew vs. other counters
   and real world time.

 * The driver is expected to provide a :c:func:`sys_clock_set_timeout` call
   to the kernel which indicates how many ticks may elapse before the
   kernel must receive an announce call to trigger registered timeouts.
   It is legal to announce new ticks before that moment (though they
   must be correct) but delay after that will cause events to be
   missed.  Note that the timeout value passed here is in a delta from
   current time, but that does not absolve the driver of the
   requirement to provide ticks at a steady rate over time.  Naive
   implementations of this function are subject to bugs where the
   fractional tick gets "reset" incorrectly and causes clock skew.

 * The driver is expected to provide a :c:func:`sys_clock_elapsed` call which
   provides a current indication of how many ticks have elapsed (as
   compared to a real world clock) since the last call to
   :c:func:`sys_clock_announce`, which the kernel needs to test newly
   arriving timeouts for expiration.

 Note that a natural implementation of this API results in a "tickless"
 kernel, which receives and processes timer interrupts only for
 registered events, relying on programmable hardware counters to
 provide irregular interrupts.  But a traditional, "ticked" or "dumb"
 counter driver can be trivially implemented also:

 * The driver can receive interrupts at a regular rate corresponding to
   the OS tick rate, calling :c:func:`sys_clock_announce` with an argument of one
   each time.

 * The driver can ignore calls to :c:func:`sys_clock_set_timeout`, as every
   tick will be announced regardless of timeout status.

 * The driver can return zero for every call to :c:func:`sys_clock_elapsed`
   as no more than one tick can be detected as having elapsed (because
   otherwise an interrupt would have been received).


 SMP Details
 -----------

 In general, the timer API described above does not change when run in
 a multiprocessor context.  The kernel will internally synchronize all
 access appropriately, and ensure that all critical sections are small
 and minimal.  But some notes are important to detail:

 * Zephyr is agnostic about which CPU services timer interrupts.  It is
   not illegal (though probably undesirable in some circumstances) to
   have every timer interrupt handled on a single processor.  Existing
   SMP architectures implement symmetric timer drivers.

 * The :c:func:`sys_clock_announce` call is expected to be globally
   synchronized at the driver level.  The kernel does not do any
   per-CPU tracking, and expects that if two timer interrupts fire near
   simultaneously, that only one will provide the current tick count to
   the timing subsystem.  The other may legally provide a tick count of
   zero if no ticks have elapsed.  It should not "skip" the announce
   call because of timeslicing requirements (see below).

 * Some SMP hardware uses a single, global timer device, others use a
   per-CPU counter.  The complexity here (for example: ensuring counter
   synchronization between CPUs) is expected to be managed by the
   driver, not the kernel.

 * The next timeout value passed back to the driver via
   :c:func:`sys_clock_set_timeout` is done identically for every CPU.
   So by default, every CPU will see simultaneous timer interrupts for
   every event, even though by definition only one of them should see a
   non-zero ticks argument to :c:func:`sys_clock_announce`.  This is probably
   a correct default for timing sensitive applications (because it
   minimizes the chance that an errant ISR or interrupt lock will delay
   a timeout), but may be a performance problem in some cases.  The
   current design expects that any such optimization is the
   responsibility of the timer driver.

 Time Slicing
 ------------

 An auxiliary job of the timing subsystem is to provide tick counters
 to the scheduler that allow implementation of time slicing of threads.
 A thread time-slice cannot be a timeout value, as it does not reflect
 a global expiration but instead a per-CPU value that needs to be
 tracked independently on each CPU in an SMP context.

 Because there may be no other hardware available to drive timeslicing,
 Zephyr multiplexes the existing timer driver.  This means that the
 value passed to :c:func:`sys_clock_set_timeout` may be clamped to a
 smaller value than the current next timeout when a time sliced thread
 is currently scheduled.

 Subsystems that keep millisecond APIs
 -------------------------------------

 In general, code like this will port just like applications code will.
 Millisecond values from the user may be treated any way the subsystem
 likes, and then converted into kernel timeouts using
 :c:macro:`K_MSEC()` at the point where they are presented to the
 kernel.

 Obviously this comes at the cost of not being able to use new
 features, like the higher precision timeout constructors or absolute
 timeouts.  But for many subsystems with simple needs, this may be
 acceptable.

 One complexity is :c:macro:`K_FOREVER`.  Subsystems that might have
 been able to accept this value to their millisecond API in the past no
 longer can, because it is no longer an integral type.  Such code
 will need to use a different, integer-valued token to represent
 "forever".  :c:macro:`K_NO_WAIT` has the same typesafety concern too,
 of course, but as it is (and has always been) simply a numerical zero,
 it has a natural porting path.

 Subsystems using ``k_timeout_t``
 --------------------------------

 Ideally, code that takes a "timeout" parameter specifying a time to
 wait should be using the kernel native abstraction where possible.
 But :c:type:`k_timeout_t` is opaque, and needs to be converted before
 it can be inspected by an application.

 Some conversions are simple.  Code that needs to test for
 :c:macro:`K_FOREVER` can simply use the :c:macro:`K_TIMEOUT_EQ()`
 macro to test the opaque struct for equality and take special action.

 The more complicated case is when the subsystem needs to take a
 timeout and loop, waiting for it to finish while doing some processing
 that may require multiple blocking operations on underlying kernel
 code.  For example, consider this design:

 .. code-block:: c

     void my_wait_for_event(struct my_subsys *obj, int32_t timeout_in_ms)
     {
         while (true) {
             uint32_t start = k_uptime_get_32();

             if (is_event_complete(obj)) {
                 return;
             }

             /* Wait for notification of state change */
             k_sem_take(obj->sem, timeout_in_ms);

             /* Subtract elapsed time */
             timeout_in_ms -= (k_uptime_get_32() - start);
         }
     }

 This code requires that the timeout value be inspected, which is no
 longer possible.  For situations like this, the new API provides an
 internal :c:func:`sys_clock_timeout_end_calc` routine that converts an
 arbitrary timeout to the uptime value in ticks at which it will
 expire.  So such a loop might look like:


 .. code-block:: c

     void my_wait_for_event(struct my_subsys *obj, k_timeout_t timeout_in_ms)
     {
         /* Compute the end time from the timeout */
         uint64_t end = sys_clock_timeout_end_calc(timeout_in_ms);

         while (end > k_uptime_ticks()) {
             if (is_event_complete(obj)) {
                 return;
             }

             /* Wait for notification of state change */
             k_sem_take(obj->sem, timeout_in_ms);
         }
     }

 Note that :c:func:`sys_clock_timeout_end_calc` returns values in units of
 ticks, to prevent conversion aliasing, is always presented at 64 bit
 uptime precision to prevent rollover bugs, handles special
 :c:macro:`K_FOREVER` naturally (as ``UINT64_MAX``), and works
 identically for absolute timeouts as well as conventional ones.

 But some care is still required for subsystems that use it.  Note that
 delta timeouts need to be interpreted relative to a "current time",
 and obviously that time is the time of the call to
 :c:func:`sys_clock_timeout_end_calc`.  But the user expects that the time is
 the time they passed the timeout to you.  Care must be taken to call
 this function just once, as synchronously as possible to the timeout
 creation in user code.  It should not be used on a "stored" timeout
 value, and should never be called iteratively in a loop.


 API Reference
 *************

 .. doxygengroup:: clock_apis
	.. _kernel_timing:

	Kernel Timing
	#############

	Zephyr provides a robust and scalable timing framework to enable
	reporting and tracking of timed events from hardware timing sources of
	arbitrary precision.

	Time Units
	==========

	Kernel time is tracked in several units which are used for different
	purposes.

	Real time values, typically specified in milliseconds or microseconds,
	are the default presentation of time to application code. They have
	the advantages of being universally portable and pervasively
	understood, though they may not match the precision of the underlying
	hardware perfectly.

	The kernel presents a "cycle" count via the :c:func:`k_cycle_get_32`
	and :c:func:`k_cycle_get_64` APIs. The intent is that this counter
	represents the fastest cycle counter that the operating system is able
	to present to the user (for example, a CPU cycle counter) and that the
	read operation is very fast. The expectation is that very sensitive
	application code might use this in a polling manner to achieve maximal
	precision. The frequency of this counter is required to be steady
	over time, and is available from
	:c:func:`sys_clock_hw_cycles_per_sec` (which on almost all
	platforms is a runtime constant that evaluates to
	CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC).

	For asynchronous timekeeping, the kernel defines a "ticks" concept. A
	"tick" is the internal count in which the kernel does all its internal
	uptime and timeout bookkeeping. Interrupts are expected to be
	delivered on tick boundaries to the extent practical, and no
	fractional ticks are tracked. The choice of tick rate is configurable
	via :kconfig:option:`CONFIG_SYS_CLOCK_TICKS_PER_SEC`. Defaults on most
	hardware platforms (ones that support setting arbitrary interrupt
	timeouts) are expected to be in the range of 10 kHz, with software
	emulation platforms and legacy drivers using a more traditional 100 Hz
	value.

	Conversion
	----------

	Zephyr provides an extensively enumerated conversion library with
	rounding control for all time units. Any unit of "ms" (milliseconds),
	"us" (microseconds), "tick", or "cyc" can be converted to any other.
	Control of rounding is provided, and each conversion is available in
	"floor" (round down to nearest output unit), "ceil" (round up) and
	"near" (round to nearest). Finally the output precision can be
	specified as either 32 or 64 bits.

	For example: :c:func:`k_ms_to_ticks_ceil32` will convert a
	millisecond input value to the next higher number of ticks, returning
	a result truncated to 32 bits of precision; and
	:c:func:`k_cyc_to_us_floor64` will convert a measured cycle count
	to an elapsed number of microseconds in a full 64 bits of precision.
	See the reference documentation for the full enumeration of conversion
	routines.

	On most platforms, where the various counter rates are integral
	multiples of each other and where the output fits within a single
	word, these conversions expand to a 2-4 operation sequence, requiring
	full precision only where actually required and requested.

	.. _kernel_timing_uptime:

	Uptime
	======

	The kernel tracks a system uptime count on behalf of the application.
	This is available at all times via :c:func:`k_uptime_get`, which
	provides an uptime value in milliseconds since system boot. This is
	expected to be the utility used by most portable application code.

	The internal tracking, however, is as a 64 bit integer count of ticks.
	Apps with precise timing requirements (that are willing to do their
	own conversions to portable real time units) may access this with
	:c:func:`k_uptime_ticks`.

	Timeouts
	========

	The Zephyr kernel provides many APIs with a "timeout" parameter.
	Conceptually, this indicates the time at which an event will occur.
	For example:

	* Kernel blocking operations like :c:func:`k_sem_take` or
	:c:func:`k_queue_get` may provide a timeout after which the
	routine will return with an error code if no data is available.

	* Kernel :c:struct:`k_timer` objects must specify delays for
	their duration and period.

	* The kernel :c:struct:`k_work_delayable` API provides a timeout parameter
	indicating when a work queue item will be added to the system queue.

	All these values are specified using a :c:struct:`k_timeout_t` value. This is
	an opaque struct type that must be initialized using one of a family
	of kernel timeout macros. The most common, :c:macro:`K_MSEC` , defines
	a time in milliseconds after the current time (strictly: the time at
	which the kernel receives the timeout value).

	Other options for timeout initialization follow the unit conventions
	described above: :c:macro:`K_NSEC()`, :c:macro:`K_USEC`, :c:macro:`K_TICKS` and
	:c:macro:`K_CYC()` specify timeout values that will expire after specified
	numbers of nanoseconds, microseconds, ticks and cycles, respectively.

	Precision of :c:struct:`k_timeout_t` values is configurable, with the default
	being 32 bits. Large uptime counts in non-tick units will experience
	complicated rollover semantics, so it is expected that
	timing-sensitive applications with long uptimes will be configured to
	use a 64 bit timeout type.

	Finally, it is possible to specify timeouts as absolute times since
	system boot. A timeout initialized with :c:macro:`K_TIMEOUT_ABS_MS`
	indicates a timeout that will expire after the system uptime reaches
	the specified value. There are likewise nanosecond, microsecond,
	cycles and ticks variants of this API.

	Timing Internals
	================

	Timeout Queue
	-------------

	All Zephyr :c:struct:`k_timeout_t` events specified using the API above are
	managed in a single, global queue of events. Each event is stored in
	a double-linked list, with an attendant delta count in ticks from the
	previous event. The action to take on an event is specified as a
	callback function pointer provided by the subsystem requesting the
	event, along with a :c:struct:`_timeout` tracking struct that is
	expected to be embedded within subsystem-defined data structures (for
	example: a :c:struct:`wait_q` struct, or a :c:struct:`k_tid_t` thread struct).

	Note that all variant units passed via a :c:struct:`k_timeout_t` are converted
	to ticks once on insertion into the list. There no
	multiple-conversion steps internal to the kernel, so precision is
	guaranteed at the tick level no matter how many events exist or how
	long a timeout might be.

	Note that the list structure means that the CPU work involved in
	managing large numbers of timeouts is quadratic in the number of
	active timeouts. The API design of the timeout queue was intended to
	permit a more scalable backend data structure, but no such
	implementation exists currently.

	Timer Drivers
	-------------

	Kernel timing at the tick level is driven by a timer driver with a
	comparatively simple API.

	* The driver is expected to be able to "announce" new ticks to the
	kernel via the :c:func:`sys_clock_announce` call, which passes an integer
	number of ticks that have elapsed since the last announce call (or
	system boot). These calls can occur at any time, but the driver is
	expected to attempt to ensure (to the extent practical given
	interrupt latency interactions) that they occur near tick boundaries
	(i.e. not "halfway through" a tick), and most importantly that they
	be correct over time and subject to minimal skew vs. other counters
	and real world time.

	* The driver is expected to provide a :c:func:`sys_clock_set_timeout` call
	to the kernel which indicates how many ticks may elapse before the
	kernel must receive an announce call to trigger registered timeouts.
	It is legal to announce new ticks before that moment (though they
	must be correct) but delay after that will cause events to be
	missed. Note that the timeout value passed here is in a delta from
	current time, but that does not absolve the driver of the
	requirement to provide ticks at a steady rate over time. Naive
	implementations of this function are subject to bugs where the
	fractional tick gets "reset" incorrectly and causes clock skew.

	* The driver is expected to provide a :c:func:`sys_clock_elapsed` call which
	provides a current indication of how many ticks have elapsed (as
	compared to a real world clock) since the last call to
	:c:func:`sys_clock_announce`, which the kernel needs to test newly
	arriving timeouts for expiration.

	Note that a natural implementation of this API results in a "tickless"
	kernel, which receives and processes timer interrupts only for
	registered events, relying on programmable hardware counters to
	provide irregular interrupts. But a traditional, "ticked" or "dumb"
	counter driver can be trivially implemented also:

	* The driver can receive interrupts at a regular rate corresponding to
	the OS tick rate, calling :c:func:`sys_clock_announce` with an argument of one
	each time.

	* The driver can ignore calls to :c:func:`sys_clock_set_timeout`, as every
	tick will be announced regardless of timeout status.

	* The driver can return zero for every call to :c:func:`sys_clock_elapsed`
	as no more than one tick can be detected as having elapsed (because
	otherwise an interrupt would have been received).


	SMP Details
	-----------

	In general, the timer API described above does not change when run in
	a multiprocessor context. The kernel will internally synchronize all
	access appropriately, and ensure that all critical sections are small
	and minimal. But some notes are important to detail:

	* Zephyr is agnostic about which CPU services timer interrupts. It is
	not illegal (though probably undesirable in some circumstances) to
	have every timer interrupt handled on a single processor. Existing
	SMP architectures implement symmetric timer drivers.

	* The :c:func:`sys_clock_announce` call is expected to be globally
	synchronized at the driver level. The kernel does not do any
	per-CPU tracking, and expects that if two timer interrupts fire near
	simultaneously, that only one will provide the current tick count to
	the timing subsystem. The other may legally provide a tick count of
	zero if no ticks have elapsed. It should not "skip" the announce
	call because of timeslicing requirements (see below).

	* Some SMP hardware uses a single, global timer device, others use a
	per-CPU counter. The complexity here (for example: ensuring counter
	synchronization between CPUs) is expected to be managed by the
	driver, not the kernel.

	* The next timeout value passed back to the driver via
	:c:func:`sys_clock_set_timeout` is done identically for every CPU.
	So by default, every CPU will see simultaneous timer interrupts for
	every event, even though by definition only one of them should see a
	non-zero ticks argument to :c:func:`sys_clock_announce`. This is probably
	a correct default for timing sensitive applications (because it
	minimizes the chance that an errant ISR or interrupt lock will delay
	a timeout), but may be a performance problem in some cases. The
	current design expects that any such optimization is the
	responsibility of the timer driver.

	Time Slicing
	------------

	An auxiliary job of the timing subsystem is to provide tick counters
	to the scheduler that allow implementation of time slicing of threads.
	A thread time-slice cannot be a timeout value, as it does not reflect
	a global expiration but instead a per-CPU value that needs to be
	tracked independently on each CPU in an SMP context.

	Because there may be no other hardware available to drive timeslicing,
	Zephyr multiplexes the existing timer driver. This means that the
	value passed to :c:func:`sys_clock_set_timeout` may be clamped to a
	smaller value than the current next timeout when a time sliced thread
	is currently scheduled.

	Subsystems that keep millisecond APIs
	-------------------------------------

	In general, code like this will port just like applications code will.
	Millisecond values from the user may be treated any way the subsystem
	likes, and then converted into kernel timeouts using
	:c:macro:`K_MSEC()` at the point where they are presented to the
	kernel.

	Obviously this comes at the cost of not being able to use new
	features, like the higher precision timeout constructors or absolute
	timeouts. But for many subsystems with simple needs, this may be
	acceptable.

	One complexity is :c:macro:`K_FOREVER`. Subsystems that might have
	been able to accept this value to their millisecond API in the past no
	longer can, because it is no longer an integral type. Such code
	will need to use a different, integer-valued token to represent
	"forever". :c:macro:`K_NO_WAIT` has the same typesafety concern too,
	of course, but as it is (and has always been) simply a numerical zero,
	it has a natural porting path.

	Subsystems using ``k_timeout_t``
	--------------------------------

	Ideally, code that takes a "timeout" parameter specifying a time to
	wait should be using the kernel native abstraction where possible.
	But :c:type:`k_timeout_t` is opaque, and needs to be converted before
	it can be inspected by an application.

	Some conversions are simple. Code that needs to test for
	:c:macro:`K_FOREVER` can simply use the :c:macro:`K_TIMEOUT_EQ()`
	macro to test the opaque struct for equality and take special action.

	The more complicated case is when the subsystem needs to take a
	timeout and loop, waiting for it to finish while doing some processing
	that may require multiple blocking operations on underlying kernel
	code. For example, consider this design:

	.. code-block:: c

	void my_wait_for_event(struct my_subsys *obj, int32_t timeout_in_ms)
	{
	while (true) {
	uint32_t start = k_uptime_get_32();

	if (is_event_complete(obj)) {
	return;
	}

	/* Wait for notification of state change */
	k_sem_take(obj->sem, timeout_in_ms);

	/* Subtract elapsed time */
	timeout_in_ms -= (k_uptime_get_32() - start);
	}
	}

	This code requires that the timeout value be inspected, which is no
	longer possible. For situations like this, the new API provides an
	internal :c:func:`sys_clock_timeout_end_calc` routine that converts an
	arbitrary timeout to the uptime value in ticks at which it will
	expire. So such a loop might look like:


	.. code-block:: c

	void my_wait_for_event(struct my_subsys *obj, k_timeout_t timeout_in_ms)
	{
	/* Compute the end time from the timeout */
	uint64_t end = sys_clock_timeout_end_calc(timeout_in_ms);

	while (end > k_uptime_ticks()) {
	if (is_event_complete(obj)) {
	return;
	}

	/* Wait for notification of state change */
	k_sem_take(obj->sem, timeout_in_ms);
	}
	}

	Note that :c:func:`sys_clock_timeout_end_calc` returns values in units of
	ticks, to prevent conversion aliasing, is always presented at 64 bit
	uptime precision to prevent rollover bugs, handles special
	:c:macro:`K_FOREVER` naturally (as ``UINT64_MAX``), and works
	identically for absolute timeouts as well as conventional ones.

	But some care is still required for subsystems that use it. Note that
	delta timeouts need to be interpreted relative to a "current time",
	and obviously that time is the time of the call to
	:c:func:`sys_clock_timeout_end_calc`. But the user expects that the time is
	the time they passed the timeout to you. Care must be taken to call
	this function just once, as synchronously as possible to the timeout
	creation in user code. It should not be used on a "stored" timeout
	value, and should never be called iteratively in a loop.


	API Reference
	*************

	.. doxygengroup:: clock_apis