doc/develop/api/terminology.rst - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 .. _api_terms:

 API Terminology
 ###############

 The following terms may be used as shorthand API tags to indicate the
 allowed calling context (thread, ISR, pre-kernel), the effect of a call
 on the current thread state, and other behavioral characteristics.

 :ref:`api_term_reschedule`
    if executing the function reaches a reschedule point
 :ref:`api_term_sleep`
    if executing the function can cause the invoking thread to sleep
 :ref:`api_term_no-wait`
    if a parameter to the function can prevent the invoking thread from
    trying to sleep
 :ref:`api_term_isr-ok`
    if the function can be safely called and will have its specified
    effect whether invoked from interrupt or thread context
 :ref:`api_term_pre-kernel-ok`
    if the function can be safely called before the kernel has been fully
    initialized and will have its specified effect when invoked from that
    context.
 :ref:`api_term_async`
    if the function may return before the operation it initializes is
    complete (i.e. function return and operation completion are
    asynchronous)
 :ref:`api_term_supervisor`
    if the calling thread must have supervisor privileges to execute the
    function

 Details on the behavioral impact of each attribute are in the following
 sections.

 .. _api_term_reschedule:

 reschedule
 ==========

 The reschedule attribute is used on a function that can reach a
 :ref:`reschedule point <scheduling_v2>` within its execution.

 Details
 -------

 The significance of this attribute is that when a rescheduling function
 is invoked by a thread it is possible for that thread to be suspended as
 a consequence of a higher-priority thread being made ready.  Whether the
 suspension actually occurs depends on the operation associated with the
 reschedule point and the relative priorities of the invoking thread and
 the head of the ready queue.

 Note that in the case of timeslicing, or reschedule points executed from
 interrupts, any thread may be suspended in any function.

 Functions that are not **reschedule** may be invoked from either thread
 or interrupt context.

 Functions that are **reschedule** may be invoked from thread context.

 Functions that are **reschedule** but not **sleep** may be invoked from
 interrupt context.

 .. _api_term_sleep:

 sleep
 =====

 The sleep attribute is used on a function that can cause the invoking
 thread to :ref:`sleep <scheduling_v2>`.

 Explanation
 -----------

 This attribute is of relevance specifically when considering
 applications that use only non-preemptible threads, because the kernel
 will not replace a running cooperative-only thread at a reschedule point
 unless that thread has explicitly invoked an operation that caused it to
 sleep.

 This attribute does not imply the function will sleep unconditionally,
 but that the operation may require an invoking thread that would have to
 suspend, wait, or invoke :c:func:`k_yield` before it can complete
 its operation.  This behavior may be mediated by **no-wait**.

 Functions that are **sleep** are implicitly **reschedule**.

 Functions that are **sleep** may be invoked from thread context.

 Functions that are **sleep** may be invoked from interrupt and
 pre-kernel contexts if and only if invoked in **no-wait** mode.

 .. _api_term_no-wait:

 no-wait
 =======

 The no-wait attribute is used on a function that is also **sleep** to
 indicate that a parameter to the function can force an execution path
 that will not cause the invoking thread to sleep.

 Explanation
 -----------

 The paradigmatic case of a no-wait function is a function that takes a
 timeout, to which :c:macro:`K_NO_WAIT` can be passed.  The semantics of
 this special timeout value are to execute the function's operation as
 long as it can be completed immediately, and to return an error code
 rather than sleep if it cannot.

 It is use of the no-wait feature that allows functions like
 :c:func:`k_sem_take` to be invoked from ISRs, since it is not
 permitted to sleep in interrupt context.

 A function with a no-wait path does not imply that taking that path
 guarantees the function is synchronous.

 Functions with this attribute may be invoked from interrupt and
 pre-kernel contexts only when the parameter selects the no-wait path.

 .. _api_term_isr-ok:

 isr-ok
 ======

 The isr-ok attribute is used on a function to indicate that it works
 whether it is being invoked from interrupt or thread context.

 Explanation
 -----------

 Any function that is not **sleep** is inherently **isr-ok**.  Functions
 that are **sleep** are **isr-ok** if the implementation ensures that the
 documented behavior is implemented even if called from an interrupt
 context.  This may be achieved by having the implementation detect the
 calling context and transfer the operation that would sleep to a thread,
 or by documenting that when invoked from a non-thread context the
 function will return a specific error (generally ``-EWOULDBLOCK``).

 Note that a function that is **no-wait** is safe to call from interrupt
 context only when the no-wait path is selected.  **isr-ok** functions
 need not provide a no-wait path.

 .. _api_term_pre-kernel-ok:

 pre-kernel-ok
 =============

 The pre-kernel-ok attribute is used on a function to indicate that it
 works as documented even when invoked before the kernel main thread has
 been started.

 Explanation
 -----------

 This attribute is similar to **isr-ok** in function, but is intended for
 use by any API that is expected to be called in :c:macro:`DEVICE_DEFINE()`
 or :c:macro:`SYS_INIT()` calls that may be invoked with ``PRE_KERNEL_1``
 or ``PRE_KERNEL_2`` initialization levels.

 Generally a function that is **pre-kernel-ok** checks
 :c:func:`k_is_pre_kernel` when determining whether it can fulfill its
 required behavior.  In many cases it would also check
 :c:func:`k_is_in_isr` so it can be **isr-ok** as well.

 .. _api_term_async:

 async
 =====

 A function is **async** (i.e. asynchronous) if it may return before the
 operation it initiates has completed.  An asynchronous function will
 generally provide a mechanism by which operation completion is reported,
 e.g. a callback or event.

 A function that is not asynchronous is synchronous, i.e. the operation
 will always be complete when the function returns.  As most functions
 are synchronous this behavior does not have a distinct attribute to
 identify it.

 Explanation
 -----------

 Be aware that **async** is orthogonal to context-switching.  Some APIs
 may provide completion information through a callback, but may suspend
 while waiting for the resource necessary to initiate the operation; an
 example is :c:func:`spi_transceive_async`.

 If a function is both **no-wait** and **async** then selecting the
 no-wait path only guarantees that the function will not sleep.  It does
 not affect whether the operation will be completed before the function
 returns.

 .. _api_term_supervisor:

 supervisor
 ==========

 The supervisor attribute is relevant only in user-mode applications, and
 indicates that the function cannot be invoked from user mode.
	.. _api_terms:

	API Terminology
	###############

	The following terms may be used as shorthand API tags to indicate the
	allowed calling context (thread, ISR, pre-kernel), the effect of a call
	on the current thread state, and other behavioral characteristics.

	:ref:`api_term_reschedule`
	if executing the function reaches a reschedule point
	:ref:`api_term_sleep`
	if executing the function can cause the invoking thread to sleep
	:ref:`api_term_no-wait`
	if a parameter to the function can prevent the invoking thread from
	trying to sleep
	:ref:`api_term_isr-ok`
	if the function can be safely called and will have its specified
	effect whether invoked from interrupt or thread context
	:ref:`api_term_pre-kernel-ok`
	if the function can be safely called before the kernel has been fully
	initialized and will have its specified effect when invoked from that
	context.
	:ref:`api_term_async`
	if the function may return before the operation it initializes is
	complete (i.e. function return and operation completion are
	asynchronous)
	:ref:`api_term_supervisor`
	if the calling thread must have supervisor privileges to execute the
	function

	Details on the behavioral impact of each attribute are in the following
	sections.

	.. _api_term_reschedule:

	reschedule
	==========

	The reschedule attribute is used on a function that can reach a
	:ref:`reschedule point <scheduling_v2>` within its execution.

	Details
	-------

	The significance of this attribute is that when a rescheduling function
	is invoked by a thread it is possible for that thread to be suspended as
	a consequence of a higher-priority thread being made ready. Whether the
	suspension actually occurs depends on the operation associated with the
	reschedule point and the relative priorities of the invoking thread and
	the head of the ready queue.

	Note that in the case of timeslicing, or reschedule points executed from
	interrupts, any thread may be suspended in any function.

	Functions that are not reschedule may be invoked from either thread
	or interrupt context.

	Functions that are reschedule may be invoked from thread context.

	Functions that are reschedule but not sleep may be invoked from
	interrupt context.

	.. _api_term_sleep:

	sleep
	=====

	The sleep attribute is used on a function that can cause the invoking
	thread to :ref:`sleep <scheduling_v2>`.

	Explanation
	-----------

	This attribute is of relevance specifically when considering
	applications that use only non-preemptible threads, because the kernel
	will not replace a running cooperative-only thread at a reschedule point
	unless that thread has explicitly invoked an operation that caused it to
	sleep.

	This attribute does not imply the function will sleep unconditionally,
	but that the operation may require an invoking thread that would have to
	suspend, wait, or invoke :c:func:`k_yield` before it can complete
	its operation. This behavior may be mediated by no-wait.

	Functions that are sleep are implicitly reschedule.

	Functions that are sleep may be invoked from thread context.

	Functions that are sleep may be invoked from interrupt and
	pre-kernel contexts if and only if invoked in no-wait mode.

	.. _api_term_no-wait:

	no-wait
	=======

	The no-wait attribute is used on a function that is also sleep to
	indicate that a parameter to the function can force an execution path
	that will not cause the invoking thread to sleep.

	Explanation
	-----------

	The paradigmatic case of a no-wait function is a function that takes a
	timeout, to which :c:macro:`K_NO_WAIT` can be passed. The semantics of
	this special timeout value are to execute the function's operation as
	long as it can be completed immediately, and to return an error code
	rather than sleep if it cannot.

	It is use of the no-wait feature that allows functions like
	:c:func:`k_sem_take` to be invoked from ISRs, since it is not
	permitted to sleep in interrupt context.

	A function with a no-wait path does not imply that taking that path
	guarantees the function is synchronous.

	Functions with this attribute may be invoked from interrupt and
	pre-kernel contexts only when the parameter selects the no-wait path.

	.. _api_term_isr-ok:

	isr-ok
	======

	The isr-ok attribute is used on a function to indicate that it works
	whether it is being invoked from interrupt or thread context.

	Explanation
	-----------

	Any function that is not sleep is inherently isr-ok. Functions
	that are sleep are isr-ok if the implementation ensures that the
	documented behavior is implemented even if called from an interrupt
	context. This may be achieved by having the implementation detect the
	calling context and transfer the operation that would sleep to a thread,
	or by documenting that when invoked from a non-thread context the
	function will return a specific error (generally ``-EWOULDBLOCK``).

	Note that a function that is no-wait is safe to call from interrupt
	context only when the no-wait path is selected. isr-ok functions
	need not provide a no-wait path.

	.. _api_term_pre-kernel-ok:

	pre-kernel-ok
	=============

	The pre-kernel-ok attribute is used on a function to indicate that it
	works as documented even when invoked before the kernel main thread has
	been started.

	Explanation
	-----------

	This attribute is similar to isr-ok in function, but is intended for
	use by any API that is expected to be called in :c:macro:`DEVICE_DEFINE()`
	or :c:macro:`SYS_INIT()` calls that may be invoked with ``PRE_KERNEL_1``
	or ``PRE_KERNEL_2`` initialization levels.

	Generally a function that is pre-kernel-ok checks
	:c:func:`k_is_pre_kernel` when determining whether it can fulfill its
	required behavior. In many cases it would also check
	:c:func:`k_is_in_isr` so it can be isr-ok as well.

	.. _api_term_async:

	async
	=====

	A function is async (i.e. asynchronous) if it may return before the
	operation it initiates has completed. An asynchronous function will
	generally provide a mechanism by which operation completion is reported,
	e.g. a callback or event.

	A function that is not asynchronous is synchronous, i.e. the operation
	will always be complete when the function returns. As most functions
	are synchronous this behavior does not have a distinct attribute to
	identify it.

	Explanation
	-----------

	Be aware that async is orthogonal to context-switching. Some APIs
	may provide completion information through a callback, but may suspend
	while waiting for the resource necessary to initiate the operation; an
	example is :c:func:`spi_transceive_async`.

	If a function is both no-wait and async then selecting the
	no-wait path only guarantees that the function will not sleep. It does
	not affect whether the operation will be completed before the function
	returns.

	.. _api_term_supervisor:

	supervisor
	==========

	The supervisor attribute is relevant only in user-mode applications, and
	indicates that the function cannot be invoked from user mode.