498 lines
24 KiB
ReStructuredText
498 lines
24 KiB
ReStructuredText
ESP-IDF FreeRTOS SMP Changes
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============================
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Overview
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--------
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The vanilla FreeRTOS is designed to run on a single core. However the ESP32 is
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dual core containing a Protocol CPU (known as **CPU 0** or **PRO_CPU**) and an
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Application CPU (known as **CPU 1** or **APP_CPU**). The two cores are
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identical in practice and share the same memory. This allows the two cores to
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run tasks interchangeably between them.
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The ESP-IDF FreeRTOS is a modified version of vanilla FreeRTOS which supports
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symmetric multiprocessing (SMP). ESP-IDF FreeRTOS is based on the Xtensa port
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of FreeRTOS v8.2.0. This guide outlines the major differences between vanilla
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FreeRTOS and ESP-IDF FreeRTOS. The API reference for vanilla FreeRTOS can be
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found via http://www.freertos.org/a00106.html
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For information regarding features that are exclusive to ESP-IDF FreeRTOS,
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see :doc:`ESP-IDF FreeRTOS Additions<../api-reference/system/freertos_additions>`.
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:ref:`backported-features`: Although ESP-IDF FreeRTOS is based on the Xtensa
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port of FreeRTOS v8.2.0, a number of FreeRTOS v9.0.0 features have been backported
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to ESP-IDF.
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:ref:`tasks-and-task-creation`: Use :cpp:func:`xTaskCreatePinnedToCore` or
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:cpp:func:`xTaskCreateStaticPinnedToCore` to create tasks in ESP-IDF FreeRTOS. The
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last parameter of the two functions is ``xCoreID``. This parameter specifies
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which core the task is pinned to. Acceptable values are ``0`` for **PRO_CPU**,
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``1`` for **APP_CPU**, or ``tskNO_AFFINITY`` which allows the task to run on
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both.
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:ref:`round-robin-scheduling`: The ESP-IDF FreeRTOS scheduler will skip tasks when
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implementing Round-Robin scheduling between multiple tasks in the Ready state
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that are of the same priority. To avoid this behavior, ensure that those tasks either
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enter a blocked state, or are distributed across a wider range of priorities.
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:ref:`scheduler-suspension`: Suspending the scheduler in ESP-IDF FreeRTOS will only
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affect the scheduler on the the calling core. In other words, calling
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:cpp:func:`vTaskSuspendAll` on **PRO_CPU** will not prevent **APP_CPU** from scheduling, and
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vice versa. Use critical sections or semaphores instead for simultaneous
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access protection.
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:ref:`tick-interrupt-synchronicity`: Tick interrupts of **PRO_CPU** and **APP_CPU**
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are not synchronized. Do not expect to use :cpp:func:`vTaskDelay` or
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:cpp:func:`vTaskDelayUntil` as an accurate method of synchronizing task execution
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between the two cores. Use a counting semaphore instead as their context
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switches are not tied to tick interrupts due to preemption.
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:ref:`critical-sections`: In ESP-IDF FreeRTOS, critical sections are implemented using
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mutexes. Entering critical sections involve taking a mutex, then disabling the
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scheduler and interrupts of the calling core. However the other core is left
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unaffected. If the other core attemps to take same mutex, it will spin until
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the calling core has released the mutex by exiting the critical section.
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:ref:`floating-points`: The ESP32 supports hardware acceleration of single
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precision floating point arithmetic (``float``). However the use of hardware
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acceleration leads to some behavioral restrictions in ESP-IDF FreeRTOS.
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Therefore, tasks that utilize ``float`` will automatically be pinned to a core if
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not done so already. Furthermore, ``float`` cannot be used in interrupt service
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routines.
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:ref:`task-deletion`: Task deletion behavior has been backported from FreeRTOS
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v9.0.0 and modified to be SMP compatible. Task memory will be freed immediately
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when :cpp:func:`vTaskDelete` is called to delete a task that is not currently running
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and not pinned to the other core. Otherwise, freeing of task memory will still
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be delegated to the Idle Task.
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:ref:`deletion-callbacks`: ESP-IDF FreeRTOS has backported the Thread Local
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Storage Pointers (TLSP) feature. However the extra feature of Deletion Callbacks has been
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added. Deletion callbacks are called automatically during task deletion and are
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used to free memory pointed to by TLSP. Call
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:cpp:func:`vTaskSetThreadLocalStoragePointerAndDelCallback()` to set TLSP and Deletion
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Callbacks.
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:ref:`esp-idf-freertos-configuration`: Several aspects of ESP-IDF FreeRTOS can be
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configured using ``make meunconfig`` such as running ESP-IDF in Unicore Mode,
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or configuring the number of Thread Local Storage Pointers each task will have.
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.. _backported-features:
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Backported Features
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-------------------
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The following features have been backported from FreeRTOS v9.0.0 to ESP-IDF.
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Static Alocation
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^^^^^^^^^^^^^^^^^
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This feature has been backported from FreeRTOS v9.0.0 to ESP-IDF. The
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:envvar:`CONFIG_SUPPORT_STATIC_ALLOCATION` option must be enabled in `menuconfig`
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in order for static allocation functions to be available. Once enabled, the
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following functions can be called...
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- :cpp:func:`xTaskCreateStatic` (see :ref:`backporting-notes` below)
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- :c:macro:`xQueueCreateStatic`
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- :c:macro:`xSemaphoreCreateBinaryStatic`
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- :c:macro:`xSemaphoreCreateCountingStatic`
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- :c:macro:`xSemaphoreCreateMutexStatic`
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- :c:macro:`xSemaphoreCreateRecursiveMutexStatic`
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- :cpp:func:`xTimerCreateStatic` (see :ref:`backporting-notes` below)
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- :cpp:func:`xEventGroupCreateStatic`
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Other Features
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^^^^^^^^^^^^^^
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- :cpp:func:`vTaskSetThreadLocalStoragePointer` (see :ref:`backporting-notes` below)
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- :cpp:func:`pvTaskGetThreadLocalStoragePointer` (see :ref:`backporting-notes` below)
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- :cpp:func:`vTimerSetTimerID`
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- :cpp:func:`xTimerGetPeriod`
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- :cpp:func:`xTimerGetExpiryTime`
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- :cpp:func:`pcQueueGetName`
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- :c:macro:`uxSemaphoreGetCount`
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.. _backporting-notes:
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Backporting Notes
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^^^^^^^^^^^^^^^^^
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**1)** :cpp:func:`xTaskCreateStatic` has been made SMP compatible in a similar
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fashion to :cpp:func:`xTaskCreate` (see :ref:`tasks-and-task-creation`). Therefore
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:cpp:func:`xTaskCreateStaticPinnedToCore` can also be called.
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**2)** Although vanilla FreeRTOS allows the Timer feature's daemon task to
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be statically allocated, the daemon task is always dynamically allocated in
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ESP-IDF. Therefore ``vApplicationGetTimerTaskMemory`` **does not** need to be
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defined when using statically allocated timers in ESP-IDF FreeRTOS.
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**3)** The Thread Local Storage Pointer feature has been modified in ESP-IDF
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FreeRTOS to include Deletion Callbacks (see :ref:`deletion-callbacks`). Therefore
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the function :cpp:func:`vTaskSetThreadLocalStoragePointerAndDelCallback` can also be
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called.
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.. _tasks-and-task-creation:
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Tasks and Task Creation
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-----------------------
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Tasks in ESP-IDF FreeRTOS are designed to run on a particular core, therefore
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two new task creation functions have been added to ESP-IDF FreeRTOS by
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appending ``PinnedToCore`` to the names of the task creation functions in
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vanilla FreeRTOS. The vanilla FreeRTOS functions of :cpp:func:`xTaskCreate`
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and :cpp:func:`xTaskCreateStatic` have led to the addition of
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:cpp:func:`xTaskCreatePinnedToCore` and :cpp:func:`xTaskCreateStaticPinnedToCore` in
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ESP-IDF FreeRTOS (see :ref:`backported-features`).
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For more details see :component_file:`freertos/task.c`
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The ESP-IDF FreeRTOS task creation functions are nearly identical to their
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vanilla counterparts with the exception of the extra parameter known as
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``xCoreID``. This parameter specifies the core on which the task should run on
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and can be one of the following values.
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- ``0`` pins the task to **PRO_CPU**
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- ``1`` pins the task to **APP_CPU**
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- ``tskNO_AFFINITY`` allows the task to be run on both CPUs
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For example ``xTaskCreatePinnedToCore(tsk_callback, “APP_CPU Task”, 1000, NULL, 10, NULL, 1)``
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creates a task of priority 10 that is pinned to **APP_CPU** with a stack size
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of 1000 bytes. It should be noted that the ``uxStackDepth`` parameter in
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vanilla FreeRTOS specifies a task’s stack depth in terms of the number of
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words, whereas ESP-IDF FreeRTOS specifies the stack depth in terms of bytes.
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Note that the vanilla FreeRTOS functions :cpp:func:`xTaskCreate` and
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:cpp:func:`xTaskCreateStatic` have been defined in ESP-IDF FreeRTOS as inline functions which call
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:cpp:func:`xTaskCreatePinnedToCore` and :cpp:func:`xTaskCreateStaticPinnedToCore`
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respectively with ``tskNO_AFFINITY`` as the ``xCoreID`` value.
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Each Task Control Block (TCB) in ESP-IDF stores the ``xCoreID`` as a member.
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Hence when each core calls the scheduler to select a task to run, the
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``xCoreID`` member will allow the scheduler to determine if a given task is
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permitted to run on the core that called it.
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Scheduling
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----------
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The vanilla FreeRTOS implements scheduling in the ``vTaskSwitchContext()``
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function. This function is responsible for selecting the highest priority task
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to run from a list of tasks in the Ready state known as the Ready Tasks List
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(described in the next section). In ESP-IDF FreeRTOS, each core will call
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``vTaskSwitchContext()`` independently to select a task to run from the
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Ready Tasks List which is shared between both cores. There are several
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differences in scheduling behavior between vanilla and ESP-IDF FreeRTOS such as
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differences in Round Robin scheduling, scheduler suspension, and tick interrupt
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synchronicity.
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.. _round-robin-scheduling:
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Round Robin Scheduling
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^^^^^^^^^^^^^^^^^^^^^^
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Given multiple tasks in the Ready state and of the same priority, vanilla
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FreeRTOS implements Round Robin scheduling between each task. This will result
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in running those tasks in turn each time the scheduler is called
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(e.g. every tick interrupt). On the other hand, the ESP-IDF FreeRTOS scheduler
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may skip tasks when Round Robin scheduling multiple Ready state tasks of the
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same priority.
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The issue of skipping tasks during Round Robin scheduling arises from the way
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the Ready Tasks List is implemented in FreeRTOS. In vanilla FreeRTOS,
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``pxReadyTasksList`` is used to store a list of tasks that are in the Ready
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state. The list is implemented as an array of length ``configMAX_PRIORITIES``
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where each element of the array is a linked list. Each linked list is of type
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``List_t`` and contains TCBs of tasks of the same priority that are in the
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Ready state. The following diagram illustrates the ``pxReadyTasksList``
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structure.
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.. figure:: ../../_static/freertos-ready-task-list.png
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:align: center
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:alt: Vanilla FreeRTOS Ready Task List Structure
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Illustration of FreeRTOS Ready Task List Data Structure
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Each linked list also contains a ``pxIndex`` which points to the last TCB
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returned when the list was queried. This index allows the ``vTaskSwitchContext()``
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to start traversing the list at the TCB immediately after ``pxIndex`` hence
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implementing Round Robin Scheduling between tasks of the same priority.
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In ESP-IDF FreeRTOS, the Ready Tasks List is shared between cores hence
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``pxReadyTasksList`` will contain tasks pinned to different cores. When a core
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calls the scheduler, it is able to look at the ``xCoreID`` member of each TCB
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in the list to determine if a task is allowed to run on calling the core. The
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ESP-IDF FreeRTOS ``pxReadyTasksList`` is illustrated below.
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.. figure:: ../../_static/freertos-ready-task-list-smp.png
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:align: center
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:alt: ESP-IDF FreeRTOS Ready Task List Structure
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Illustration of FreeRTOS Ready Task List Data Structure in ESP-IDF
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Therefore when **PRO_CPU** calls the scheduler, it will only consider the tasks
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in blue or purple. Whereas when **APP_CPU** calls the scheduler, it will only
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consider the tasks in orange or purple.
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Although each TCB has an ``xCoreID`` in ESP-IDF FreeRTOS, the linked list of
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each priority only has a single ``pxIndex``. Therefore when the scheduler is
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called from a particular core and traverses the linked list, it will skip all
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TCBs pinned to the other core and point the pxIndex at the selected task. If
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the other core then calls the scheduler, it will traverse the linked list
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starting at the TCB immediately after ``pxIndex``. Therefore, TCBs skipped on
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the previous scheduler call from the other core would not be considered on the
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current scheduler call. This issue is demonstrated in the following
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illustration.
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.. figure:: ../../_static/freertos-ready-task-list-smp-pxIndex.png
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:align: center
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:alt: ESP-IDF pxIndex Behavior
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Illustration of pxIndex behavior in ESP-IDF FreeRTOS
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Referring to the illustration above, assume that priority 9 is the highest
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priority, and none of the tasks in priority 9 will block hence will always be
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either in the running or Ready state.
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1) **PRO_CPU** calls the scheduler and selects Task A to run, hence moves
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``pxIndex`` to point to Task A
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2) **APP_CPU** calls the scheduler and starts traversing from the task after
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``pxIndex`` which is Task B. However Task B is not selected to run as it is not
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pinned to **APP_CPU** hence it is skipped and Task C is selected instead.
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``pxIndex`` now points to Task C
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3) **PRO_CPU** calls the scheduler and starts traversing from Task D. It skips
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Task D and selects Task E to run and points ``pxIndex`` to Task E. Notice that
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Task B isn’t traversed because it was skipped the last time **APP_CPU** called
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the scheduler to traverse the list.
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4) The same situation with Task D will occur if **APP_CPU** calls the
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scheduler again as ``pxIndex`` now points to Task E
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One solution to the issue of task skipping is to ensure that every task will
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enter a blocked state so that they are removed from the Ready Task List.
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Another solution is to distribute tasks across multiple priorities such that
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a given priority will not be assigned multiple tasks that are pinned to
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different cores.
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.. _scheduler-suspension:
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Scheduler Suspension
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^^^^^^^^^^^^^^^^^^^^
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In vanilla FreeRTOS, suspending the scheduler via :cpp:func:`vTaskSuspendAll` will
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prevent calls of ``vTaskSwitchContext`` from context switching until the
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scheduler has been resumed with :cpp:func:`xTaskResumeAll`. However servicing ISRs
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are still permitted. Therefore any changes in task states as a result from the
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current running task or ISRSs will not be executed until the scheduler is
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resumed. Scheduler suspension in vanilla FreeRTOS is a common protection method
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against simultaneous access of data shared between tasks, whilst still allowing
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ISRs to be serviced.
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In ESP-IDF FreeRTOS, :cpp:func:`xTaskResumeAll` will only prevent calls of
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``vTaskSwitchContext()`` from switching contexts on the core that called for the
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suspension. Hence if **PRO_CPU** calls :cpp:func:`vTaskSuspendAll`, **APP_CPU** will
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still be able to switch contexts. If data is shared between tasks that are
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pinned to different cores, scheduler suspension is **NOT** a valid method of
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protection against simultaneous access. Consider using critical sections
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(disables interrupts) or semaphores (does not disable interrupts) instead when
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protecting shared resources in ESP-IDF FreeRTOS.
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In general, it's better to use other RTOS primitives like mutex semaphores to protect
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against data shared between tasks, rather than :cpp:func:`vTaskSuspendAll`.
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.. _tick-interrupt-synchronicity:
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Tick Interrupt Synchronicity
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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In ESP-IDF FreeRTOS, tasks on different cores that unblock on the same tick
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count might not run at exactly the same time due to the scheduler calls from
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each core being independent, and the tick interrupts to each core being
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unsynchronized.
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In vanilla FreeRTOS the tick interrupt triggers a call to
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:cpp:func:`xTaskIncrementTick` which is responsible for incrementing the tick
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counter, checking if tasks which have called :cpp:func:`vTaskDelay` have fulfilled
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their delay period, and moving those tasks from the Delayed Task List to the
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Ready Task List. The tick interrupt will then call the scheduler if a context
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switch is necessary.
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In ESP-IDF FreeRTOS, delayed tasks are unblocked with reference to the tick
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interrupt on PRO_CPU as PRO_CPU is responsible for incrementing the shared tick
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count. However tick interrupts to each core might not be synchronized (same
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frequency but out of phase) hence when PRO_CPU receives a tick interrupt,
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APP_CPU might not have received it yet. Therefore if multiple tasks of the same
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priority are unblocked on the same tick count, the task pinned to PRO_CPU will
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run immediately whereas the task pinned to APP_CPU must wait until APP_CPU
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receives its out of sync tick interrupt. Upon receiving the tick interrupt,
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APP_CPU will then call for a context switch and finally switches contexts to
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the newly unblocked task.
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Therefore, task delays should **NOT** be used as a method of synchronization
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between tasks in ESP-IDF FreeRTOS. Instead, consider using a counting semaphore
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to unblock multiple tasks at the same time.
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.. _critical-sections:
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Critical Sections & Disabling Interrupts
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----------------------------------------
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Vanilla FreeRTOS implements critical sections in ``vTaskEnterCritical`` which
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disables the scheduler and calls ``portDISABLE_INTERRUPTS``. This prevents
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context switches and servicing of ISRs during a critical section. Therefore,
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critical sections are used as a valid protection method against simultaneous
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access in vanilla FreeRTOS.
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On the other hand, the ESP32 has no hardware method for cores to disable each
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other’s interrupts. Calling ``portDISABLE_INTERRUPTS()`` will have no effect on
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the interrupts of the other core. Therefore, disabling interrupts is **NOT**
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a valid protection method against simultaneous access to shared data as it
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leaves the other core free to access the data even if the current core has
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disabled its own interrupts.
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For this reason, ESP-IDF FreeRTOS implements critical sections using mutexes,
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and calls to enter or exit a critical must provide a mutex that is associated
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with a shared resource requiring access protection. When entering a critical
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section in ESP-IDF FreeRTOS, the calling core will disable its scheduler and
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interrupts similar to the vanilla FreeRTOS implementation. However, the calling
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core will also take the mutex whilst the other core is left unaffected during
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the critical section. If the other core attempts to take the same mutex, it
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will spin until the mutex is released. Therefore, the ESP-IDF FreeRTOS
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implementation of critical sections allows a core to have protected access to a
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shared resource without disabling the other core. The other core will only be
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affected if it tries to concurrently access the same resource.
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The ESP-IDF FreeRTOS critical section functions have been modified as follows…
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- ``taskENTER_CRITICAL(mux)``, ``taskENTER_CRITICAL_ISR(mux)``,
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``portENTER_CRITICAL(mux)``, ``portENTER_CRITICAL_ISR(mux)`` are all macro
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defined to call :cpp:func:`vTaskEnterCritical`
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- ``taskEXIT_CRITICAL(mux)``, ``taskEXIT_CRITICAL_ISR(mux)``,
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``portEXIT_CRITICAL(mux)``, ``portEXIT_CRITICAL_ISR(mux)`` are all macro
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defined to call :cpp:func:`vTaskExitCritical`
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For more details see :component_file:`freertos/include/freertos/portmacro.h`
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and :component_file:`freertos/task.c`
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It should be noted that when modifying vanilla FreeRTOS code to be ESP-IDF
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FreeRTOS compatible, it is trivial to modify the type of critical section
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called as they are all defined to call the same function. As long as the same
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mutex is provided upon entering and exiting, the type of call should not
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matter.
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.. _floating-points:
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Floating Point Aritmetic
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------------------------
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The ESP32 supports hardware acceleration of single precision floating point
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arithmetic (``float``) via Floating Point Units (FPU, also known as coprocessors)
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attached to each core. The use of the FPUs imposes some behavioral restrictions
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on ESP-IDF FreeRTOS.
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ESP-IDF FreeRTOS implements Lazy Context Switching for FPUs. In other words,
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the state of a core's FPU registers are not immediately saved when a context
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switch occurs. Therefore, tasks that utilize ``float`` must be pinned to a
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particular core upon creation. If not, ESP-IDF FreeRTOS will automatically pin
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the task in question to whichever core the task was running on upon the task's
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first use of ``float``. Likewise due to Lazy Context Switching, interrupt service
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routines must also not use ``float``.
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ESP32 does not support hardware acceleration for double precision floating point
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arithmetic (``double``). Instead ``double`` is implemented via software hence the
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behavioral restrictions with regards to ``float`` do not apply to ``double``. Note
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that due to the lack of hardware acceleration, ``double`` operations may consume
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significantly larger amount of CPU time in comparison to ``float``.
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.. _task-deletion:
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Task Deletion
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-------------
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FreeRTOS task deletion prior to v9.0.0 delegated the freeing of task memory
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entirely to the Idle Task. Currently, the freeing of task memory will occur
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immediately (within :cpp:func:`vTaskDelete`) if the task being deleted is not currently
|
||
running or is not pinned to the other core (with respect to the core
|
||
:cpp:func:`vTaskDelete` is called on). TLSP deletion callbacks will also run immediately
|
||
if the same conditions are met.
|
||
|
||
However, calling :cpp:func:`vTaskDelete` to delete a task that is either currently
|
||
running or pinned to the other core will still result in the freeing of memory
|
||
being delegated to the Idle Task.
|
||
|
||
|
||
.. _deletion-callbacks:
|
||
|
||
Thread Local Storage Pointers & Deletion Callbacks
|
||
--------------------------------------------------
|
||
|
||
Thread Local Storage Pointers (TLSP) are pointers stored directly in the TCB.
|
||
TLSP allow each task to have its own unique set of pointers to data structures.
|
||
However task deletion behavior in vanilla FreeRTOS does not automatically
|
||
free the memory pointed to by TLSP. Therefore if the memory pointed to by
|
||
TLSP is not explicitly freed by the user before task deletion, memory leak will
|
||
occur.
|
||
|
||
ESP-IDF FreeRTOS provides the added feature of Deletion Callbacks. Deletion
|
||
Callbacks are called automatically during task deletion to free memory pointed
|
||
to by TLSP. Each TLSP can have its own Deletion Callback. Note that due to the
|
||
to :ref:`task-deletion` behavior, there can be instances where Deletion
|
||
Callbacks are called in the context of the Idle Tasks. Therefore Deletion
|
||
Callbacks **should never attempt to block** and critical sections should be kept
|
||
as short as possible to minimize priority inversion.
|
||
|
||
Deletion callbacks are of type
|
||
``void (*TlsDeleteCallbackFunction_t)( int, void * )`` where the first parameter
|
||
is the index number of the associated TLSP, and the second parameter is the
|
||
TLSP itself.
|
||
|
||
Deletion callbacks are set alongside TLSP by calling
|
||
:cpp:func:`vTaskSetThreadLocalStoragePointerAndDelCallback`. Calling the vanilla
|
||
FreeRTOS function :cpp:func:`vTaskSetThreadLocalStoragePointer` will simply set the
|
||
TLSP's associated Deletion Callback to `NULL` meaning that no callback will be
|
||
called for that TLSP during task deletion. If a deletion callback is `NULL`,
|
||
users should manually free the memory pointed to by the associated TLSP before
|
||
task deletion in order to avoid memory leak.
|
||
|
||
:envvar:`CONFIG_FREERTOS_THREAD_LOCAL_STORAGE_POINTERS` in menuconfig can be used
|
||
to configure the number TLSP and Deletion Callbacks a TCB will have.
|
||
|
||
For more details see :doc:`FreeRTOS API reference<../api-reference/system/freertos>`.
|
||
|
||
|
||
.. _esp-idf-freertos-configuration:
|
||
|
||
Configuring ESP-IDF FreeRTOS
|
||
----------------------------
|
||
|
||
The ESP-IDF FreeRTOS can be configured using ``make menuconfig`` under
|
||
``Component_Config/FreeRTOS``. The following section highlights some of the
|
||
ESP-IDF FreeRTOS configuration options. For a full list of ESP-IDF
|
||
FreeRTOS configurations, see :doc:`FreeRTOS <../api-reference/kconfig>`
|
||
|
||
:envvar:`CONFIG_FREERTOS_UNICORE` will run ESP-IDF FreeRTOS only
|
||
on **PRO_CPU**. Note that this is **not equivalent to running vanilla
|
||
FreeRTOS**. Behaviors of multiple components in ESP-IDF will be modified such
|
||
as :component_file:`esp32/cpu_start.c`. For more details regarding the
|
||
effects of running ESP-IDF FreeRTOS on a single core, search for
|
||
occurences of ``CONFIG_FREERTOS_UNICORE`` in the ESP-IDF components.
|
||
|
||
:envvar:`CONFIG_FREERTOS_THREAD_LOCAL_STORAGE_POINTERS` will define the
|
||
number of Thread Local Storage Pointers each task will have in ESP-IDF
|
||
FreeRTOS.
|
||
|
||
:envvar:`CONFIG_SUPPORT_STATIC_ALLOCATION` will enable the backported
|
||
functionality of :cpp:func:`xTaskCreateStaticPinnedToCore` in ESP-IDF FreeRTOS
|
||
|
||
:envvar:`CONFIG_FREERTOS_ASSERT_ON_UNTESTED_FUNCTION` will trigger a halt in
|
||
particular functions in ESP-IDF FreeRTOS which have not been fully tested
|
||
in an SMP context.
|
||
|