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

 .. _nanokernel_fibers:

 Fiber Services
 ##############

 Concepts
 ********

 A :dfn:`fiber` is a lightweight, non-preemptible thread of execution that
 implements a portion of an application's processing. Fibers are often
 used in device drivers and for performance-critical work.

 Fibers can be used by microkernel applications, as well as by nanokernel
 applications. However, fibers can interact with microkernel object types
 to only a limited degree; for more information see :ref:`microkernel_fibers`.

 An application can use any number of fibers. Each fiber is anonymous, and
 cannot be directly referenced by other fibers or tasks once it has started
 executing. The properties that must be specified when a fiber is spawned
 include:

 * A **memory region** to be used for stack and execution context information.
 * A **function** to be invoked when the fiber starts executing.
 * A **pair of arguments** to be passed to that entry point function.
 * A **priority** to be used by the nanokernel scheduler.
 * A **set of options** that will apply to the fiber.

 The kernel may automatically spawn zero or more system fibers during system
 initialization. The specific set of fibers spawned depends upon both:

 #. The kernel capabilities that have been configured by the application.
 #. The board configuration used to build the application image.


 Fiber Lifecycle
 ===============

 A fiber can be spawned by another fiber, by a task, or by the kernel itself
 during system initialization. A fiber typically becomes executable immediately;
 however, it is possible to delay the scheduling of a newly-spawned fiber for a
 specified time period. For example, scheduling can be delayed to allow device
 hardware which the fiber uses to become available. The kernel also supports a
 delayed start cancellation capability, which prevents a newly-spawned fiber from
 executing if the fiber becomes unnecessary before its full delay period is reached.

 Once a fiber is started it normally executes forever. A fiber may terminate
 itself gracefully by simply returning from its entry point function. When this
 happens, it is the fiber's responsibility to release any system resources it may
 own (such as a nanokernel semaphore being used in a mutex-like manner) prior
 to returning, since the kernel does *not* attempt to reclaim them so they can
 be reused.

 A fiber may also terminate non-gracefully by *aborting*. The kernel
 automatically aborts a fiber when it generates a fatal error condition,
 such as dereferencing a null pointer. A fiber can also explicitly abort itself
 using :cpp:func:`fiber_abort()`. As with graceful fiber termination, the kernel
 does not attempt to reclaim system resources owned by the fiber.

 .. note::
    The kernel does not currently make any claims regarding an application's
    ability to restart a terminated fiber.

 Fiber Scheduling
 ================

 The nanokernel's scheduler selects which of the system's threads is allowed
 to execute; this thread is known as the :dfn:`current context`. The nanokernel's
 scheduler permits threads to execute only when no ISR needs to execute; execution
 of ISRs take precedence.

 When executing threads, the nanokernel's scheduler gives fiber execution
 precedence over task execution. The scheduler preempts task execution
 whenever a fiber needs to execute, but never preempts the execution of a fiber
 to allow another fiber to execute -- even if it is a higher priority fiber.

 The kernel automatically saves an executing fiber's CPU register values when
 making a context switch to a different fiber, a task, or an ISR; these values
 get restored when the fiber later resumes execution.

 Fiber State
 -----------

 A fiber has an implicit *state* that determines whether or not it can be
 scheduled for execution. The state records all factors that can prevent
 the fiber from executing, such as:

 * The fiber has not been spawned.
 * The fiber is waiting for a kernel service, for example, a semaphore or a timer.
 * The fiber has terminated.

 A fiber whose state has no factors that prevent its execution is said to be
 *executable*.

 Fiber Priorities
 ----------------

 The kernel supports a virtually unlimited number of fiber priority levels,
 ranging from 0 (highest priority) to 2^31-1 (lowest priority). Negative
 priority levels must not be used.

 A fiber's original priority cannot be altered up or down after it has been
 spawned.

 Fiber Scheduling Algorithm
 --------------------------

 Whenever possible, the nanokernel's scheduler selects the highest priority
 executable fiber to be the current context. When multiple executable fibers
 of that priority are available, the scheduler chooses the one that has been
 waiting longest.

 When no executable fibers exist, the scheduler selects the current task
 to be the current context. The current task selected depends upon whether the
 application is a nanokernel application or a microkernel application. In nanokernel
 applications, the current task is always the background task. In microkernel
 applications, the current task is the current task selected by the microkernel's
 scheduler. The current task is always executable.

 Once a fiber becomes the current context, it remains scheduled for execution
 by the nanokernel until one of the following occurs:

 * The fiber is supplanted by another thread because it calls a kernel API
   that blocks its own execution. (For example, the fiber attempts to take
   a nanokernel semaphore that is unavailable.)

 * The fiber terminates itself by returning from its entry point function.

 * The fiber aborts itself by performing an operation that causes a fatal error,
   or by calling :cpp:func:`fiber_abort()`.

 Once the current task becomes the current context, it remains scheduled for
 execution by the nanokernel until is supplanted by a fiber.

 .. note::
    The current task is **never** directly supplanted by another task, since the
    microkernel scheduler uses the microkernel server fiber to initiate a
    change from one microkernel task to another.

 Cooperative Time Slicing
 ------------------------

 Due to the non-preemptive nature of the nanokernel's scheduler, a fiber that
 performs lengthy computations may cause an unacceptable delay in the scheduling
 of other fibers, including higher priority and equal priority ones. To overcome
 such problems, the fiber can choose to voluntarily relinquish the CPU from time
 to time to permit other fibers to execute.

 A fiber can relinquish the CPU in two ways:

 * Calling :cpp:func:`fiber_yield()` places the fiber back in the nanokernel
   scheduler's list of executable fibers and then invokes the scheduler.
   All executable fibers whose priority is higher or equal to that of the
   yielding fiber are then allowed to execute before the yielding fiber is
   rescheduled. If no such executable fibers exist, the scheduler immediately
   reschedules the yielding fiber without context switching.

 * Calling :cpp:func:`fiber_sleep()` blocks the execution of the fiber for
   a specified time period. Executable fibers of all priorities are then
   allowed to execute, although there is no guarantee that fibers whose
   priority is lower than that of the sleeping task will actually be scheduled
   before the time period expires and the sleeping task becomes executable
   once again.

 Fiber Options
 =============

 The kernel supports several :dfn:`fiber options` that may be used to inform
 the kernel of special treatment the fiber requires.

 The set of kernel options associated with a fiber are specified when the fiber
 is spawned. If the fiber uses multiple options, they are separated with
 :literal:`|`, the logical ``OR`` operator. A fiber that does not use any
 options is spawned using an options value of 0.

 The fiber options listed below are pre-defined by the kernel.

 :c:macro:`USE_FP`
       Instructs the kernel to save the fiber's x87 FPU and MMX floating point
       context information during context switches.

 :c:macro:`USE_SSE`
       Instructs the kernel to save the fiber's SSE floating point context
       information during context switches. A fiber with this option
       implicitly uses the :c:macro:`USE_FP` option, as well.

 Usage
 *****

 Defining a Fiber
 ================

 The following properties must be defined when spawning a fiber:

    *stack_name*
       This specifies the memory region used for the fiber's stack and for
       other execution context information. To ensure proper memory alignment,
       it should have the following form:

       .. code-block:: c

          char __stack <stack_name>[<stack_size>];

    *stack_size*
       This specifies the size of the *stack_name* memory region, in bytes.

    *entry_point*
       This specifies the name of the fiber's entry point function,
       which should have the following form:

       .. code-block:: c

          void <entry_point>(int arg1, int arg2)
          {
              /* fiber mainline processing */
              ...
              /* (optional) normal fiber termination */
              return;
          }

    *arguments*
       This specifies the two arguments passed to *entry_point* when the fiber
       begins executing. Non-integer arguments can be passed in by casting to
       an integer type.

    *priority*
       This specifies the scheduling priority of the fiber.

    *options*
       This specifies the fiber's options.

 Example: Spawning a Fiber from a Task
 =====================================

 This code shows how the currently executing task can spawn multiple fibers,
 each dedicated to processing data from a different communication channel.

 .. code-block:: c

    #define COMM_STACK_SIZE    512
    #define NUM_COMM_CHANNELS  8

    struct descriptor {
        ...;
    };

    char __stack comm_stack[NUM_COMM_CHANNELS][COMM_STACK_SIZE];
    struct descriptor comm_desc[NUM_COMM_CHANNELS] = { ... };

    ...

    void comm_fiber(int desc_arg, int unused);
    {
        ARG_UNUSED(unused);

        struct descriptor  *desc = (struct descriptor *) desc_arg;

        while (1) {
            /* process packet of data from comm channel */

            ...
        }
    }

    void comm_main(void)
    {
        ...

        for (int i = 0; i < NUM_COMM_CHANNELS; i++) {
            task_fiber_start(&comm_stack[i][0], COMM_STACK_SIZE,
                             comm_fiber, (int) &comm_desc[i], 0,
                             10, 0);
        }

        ...
    }

 APIs
 ****

 APIs affecting the currently-executing fiber are provided
 by :file:`microkernel.h` and by :file:`nanokernel.h`:

 :cpp:func:`fiber_yield()`
    Yield the CPU to higher priority and equal priority fibers.

 :cpp:func:`fiber_sleep()`
    Yield the CPU for a specified time period.

 :cpp:func:`fiber_abort()`
    Terminate fiber execution.

 APIs affecting a specified fiber are provided by
 :file:`microkernel.h` and by :file:`nanokernel.h`:

 :cpp:func:`task_fiber_start()`, :cpp:func:`fiber_fiber_start()`,
 :cpp:func:`fiber_start()`
    Spawn a new fiber.

 :cpp:func:`task_fiber_delayed_start()`,
 :cpp:func:`fiber_fiber_delayed_start()`,
 :cpp:func:`fiber_delayed_start()`
    Spawn a new fiber after a specified time period.

 :cpp:func:`task_fiber_delayed_start_cancel()`,
 :cpp:func:`fiber_fiber_delayed_start_cancel()`,
 :cpp:func:`fiber_delayed_start_cancel()`
    Cancel spawning of a new fiber, if not already started.
	.. _nanokernel_fibers:

	Fiber Services
	##############

	Concepts
	********

	A :dfn:`fiber` is a lightweight, non-preemptible thread of execution that
	implements a portion of an application's processing. Fibers are often
	used in device drivers and for performance-critical work.

	Fibers can be used by microkernel applications, as well as by nanokernel
	applications. However, fibers can interact with microkernel object types
	to only a limited degree; for more information see :ref:`microkernel_fibers`.

	An application can use any number of fibers. Each fiber is anonymous, and
	cannot be directly referenced by other fibers or tasks once it has started
	executing. The properties that must be specified when a fiber is spawned
	include:

	* A memory region to be used for stack and execution context information.
	* A function to be invoked when the fiber starts executing.
	* A pair of arguments to be passed to that entry point function.
	* A priority to be used by the nanokernel scheduler.
	* A set of options that will apply to the fiber.

	The kernel may automatically spawn zero or more system fibers during system
	initialization. The specific set of fibers spawned depends upon both:

	#. The kernel capabilities that have been configured by the application.
	#. The board configuration used to build the application image.


	Fiber Lifecycle
	===============

	A fiber can be spawned by another fiber, by a task, or by the kernel itself
	during system initialization. A fiber typically becomes executable immediately;
	however, it is possible to delay the scheduling of a newly-spawned fiber for a
	specified time period. For example, scheduling can be delayed to allow device
	hardware which the fiber uses to become available. The kernel also supports a
	delayed start cancellation capability, which prevents a newly-spawned fiber from
	executing if the fiber becomes unnecessary before its full delay period is reached.

	Once a fiber is started it normally executes forever. A fiber may terminate
	itself gracefully by simply returning from its entry point function. When this
	happens, it is the fiber's responsibility to release any system resources it may
	own (such as a nanokernel semaphore being used in a mutex-like manner) prior
	to returning, since the kernel does not attempt to reclaim them so they can
	be reused.

	A fiber may also terminate non-gracefully by aborting. The kernel
	automatically aborts a fiber when it generates a fatal error condition,
	such as dereferencing a null pointer. A fiber can also explicitly abort itself
	using :cpp:func:`fiber_abort()`. As with graceful fiber termination, the kernel
	does not attempt to reclaim system resources owned by the fiber.

	.. note::
	The kernel does not currently make any claims regarding an application's
	ability to restart a terminated fiber.

	Fiber Scheduling
	================

	The nanokernel's scheduler selects which of the system's threads is allowed
	to execute; this thread is known as the :dfn:`current context`. The nanokernel's
	scheduler permits threads to execute only when no ISR needs to execute; execution
	of ISRs take precedence.

	When executing threads, the nanokernel's scheduler gives fiber execution
	precedence over task execution. The scheduler preempts task execution
	whenever a fiber needs to execute, but never preempts the execution of a fiber
	to allow another fiber to execute -- even if it is a higher priority fiber.

	The kernel automatically saves an executing fiber's CPU register values when
	making a context switch to a different fiber, a task, or an ISR; these values
	get restored when the fiber later resumes execution.

	Fiber State
	-----------

	A fiber has an implicit state that determines whether or not it can be
	scheduled for execution. The state records all factors that can prevent
	the fiber from executing, such as:

	* The fiber has not been spawned.
	* The fiber is waiting for a kernel service, for example, a semaphore or a timer.
	* The fiber has terminated.

	A fiber whose state has no factors that prevent its execution is said to be
	executable.

	Fiber Priorities
	----------------

	The kernel supports a virtually unlimited number of fiber priority levels,
	ranging from 0 (highest priority) to 2^31-1 (lowest priority). Negative
	priority levels must not be used.

	A fiber's original priority cannot be altered up or down after it has been
	spawned.

	Fiber Scheduling Algorithm
	--------------------------

	Whenever possible, the nanokernel's scheduler selects the highest priority
	executable fiber to be the current context. When multiple executable fibers
	of that priority are available, the scheduler chooses the one that has been
	waiting longest.

	When no executable fibers exist, the scheduler selects the current task
	to be the current context. The current task selected depends upon whether the
	application is a nanokernel application or a microkernel application. In nanokernel
	applications, the current task is always the background task. In microkernel
	applications, the current task is the current task selected by the microkernel's
	scheduler. The current task is always executable.

	Once a fiber becomes the current context, it remains scheduled for execution
	by the nanokernel until one of the following occurs:

	* The fiber is supplanted by another thread because it calls a kernel API
	that blocks its own execution. (For example, the fiber attempts to take
	a nanokernel semaphore that is unavailable.)

	* The fiber terminates itself by returning from its entry point function.

	* The fiber aborts itself by performing an operation that causes a fatal error,
	or by calling :cpp:func:`fiber_abort()`.

	Once the current task becomes the current context, it remains scheduled for
	execution by the nanokernel until is supplanted by a fiber.

	.. note::
	The current task is never directly supplanted by another task, since the
	microkernel scheduler uses the microkernel server fiber to initiate a
	change from one microkernel task to another.

	Cooperative Time Slicing
	------------------------

	Due to the non-preemptive nature of the nanokernel's scheduler, a fiber that
	performs lengthy computations may cause an unacceptable delay in the scheduling
	of other fibers, including higher priority and equal priority ones. To overcome
	such problems, the fiber can choose to voluntarily relinquish the CPU from time
	to time to permit other fibers to execute.

	A fiber can relinquish the CPU in two ways:

	* Calling :cpp:func:`fiber_yield()` places the fiber back in the nanokernel
	scheduler's list of executable fibers and then invokes the scheduler.
	All executable fibers whose priority is higher or equal to that of the
	yielding fiber are then allowed to execute before the yielding fiber is
	rescheduled. If no such executable fibers exist, the scheduler immediately
	reschedules the yielding fiber without context switching.

	* Calling :cpp:func:`fiber_sleep()` blocks the execution of the fiber for
	a specified time period. Executable fibers of all priorities are then
	allowed to execute, although there is no guarantee that fibers whose
	priority is lower than that of the sleeping task will actually be scheduled
	before the time period expires and the sleeping task becomes executable
	once again.

	Fiber Options
	=============

	The kernel supports several :dfn:`fiber options` that may be used to inform
	the kernel of special treatment the fiber requires.

	The set of kernel options associated with a fiber are specified when the fiber
	is spawned. If the fiber uses multiple options, they are separated with
	:literal:`\|`, the logical ``OR`` operator. A fiber that does not use any
	options is spawned using an options value of 0.

	The fiber options listed below are pre-defined by the kernel.

	:c:macro:`USE_FP`
	Instructs the kernel to save the fiber's x87 FPU and MMX floating point
	context information during context switches.

	:c:macro:`USE_SSE`
	Instructs the kernel to save the fiber's SSE floating point context
	information during context switches. A fiber with this option
	implicitly uses the :c:macro:`USE_FP` option, as well.

	Usage
	*****

	Defining a Fiber
	================

	The following properties must be defined when spawning a fiber:

	stack_name
	This specifies the memory region used for the fiber's stack and for
	other execution context information. To ensure proper memory alignment,
	it should have the following form:

	.. code-block:: c

	char __stack <stack_name>[<stack_size>];

	stack_size
	This specifies the size of the stack_name memory region, in bytes.

	entry_point
	This specifies the name of the fiber's entry point function,
	which should have the following form:

	.. code-block:: c

	void <entry_point>(int arg1, int arg2)
	{
	/* fiber mainline processing */
	...
	/* (optional) normal fiber termination */
	return;
	}

	arguments
	This specifies the two arguments passed to entry_point when the fiber
	begins executing. Non-integer arguments can be passed in by casting to
	an integer type.

	priority
	This specifies the scheduling priority of the fiber.

	options
	This specifies the fiber's options.

	Example: Spawning a Fiber from a Task
	=====================================

	This code shows how the currently executing task can spawn multiple fibers,
	each dedicated to processing data from a different communication channel.

	.. code-block:: c

	#define COMM_STACK_SIZE 512
	#define NUM_COMM_CHANNELS 8

	struct descriptor {
	...;
	};

	char __stack comm_stack[NUM_COMM_CHANNELS][COMM_STACK_SIZE];
	struct descriptor comm_desc[NUM_COMM_CHANNELS] = { ... };

	...

	void comm_fiber(int desc_arg, int unused);
	{
	ARG_UNUSED(unused);

	struct descriptor desc = (struct descriptor ) desc_arg;

	while (1) {
	/* process packet of data from comm channel */

	...
	}
	}

	void comm_main(void)
	{
	...

	for (int i = 0; i < NUM_COMM_CHANNELS; i++) {
	task_fiber_start(&comm_stack[i][0], COMM_STACK_SIZE,
	comm_fiber, (int) &comm_desc[i], 0,
	10, 0);
	}

	...
	}

	APIs
	****

	APIs affecting the currently-executing fiber are provided
	by :file:`microkernel.h` and by :file:`nanokernel.h`:

	:cpp:func:`fiber_yield()`
	Yield the CPU to higher priority and equal priority fibers.

	:cpp:func:`fiber_sleep()`
	Yield the CPU for a specified time period.

	:cpp:func:`fiber_abort()`
	Terminate fiber execution.

	APIs affecting a specified fiber are provided by
	:file:`microkernel.h` and by :file:`nanokernel.h`:

	:cpp:func:`task_fiber_start()`, :cpp:func:`fiber_fiber_start()`,
	:cpp:func:`fiber_start()`
	Spawn a new fiber.

	:cpp:func:`task_fiber_delayed_start()`,
	:cpp:func:`fiber_fiber_delayed_start()`,
	:cpp:func:`fiber_delayed_start()`
	Spawn a new fiber after a specified time period.

	:cpp:func:`task_fiber_delayed_start_cancel()`,
	:cpp:func:`fiber_fiber_delayed_start_cancel()`,
	:cpp:func:`fiber_delayed_start_cancel()`
	Cancel spawning of a new fiber, if not already started.