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This commit updates the documentation and API descriptions of the esp_ipc and esp_ipc_isr features.
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116 lines
7.8 KiB
ReStructuredText
Inter-Processor Call
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====================
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.. note::
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The IPC is an **Inter-Processor Call** and **NOT Inter-Process Communication** as found on other operating systems.
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Overview
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--------
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Due to the dual core nature of the {IDF_TARGET_NAME}, there are instances where a certain callback must be run in the context of a particular CPU such as:
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- When allocating an ISR to an interrupt source of a particular CPU (applies to freeing a particular CPU's interrupt source as well).
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- On particular chips (such as the ESP32), accessing memory that is exclusive to a particular CPU (such as RTC Fast Memory).
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- Reading the registers/state of another CPU.
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The IPC (Inter-Processor Call) feature allows a particular CPU (the calling CPU) to trigger the execution of a callback function on another CPU (the target CPU). The IPC feature allows execution of a callback function on the target CPU in either a task context, or a High Priority Interrupt context (see :doc:`/api-guides/hlinterrupts` for more details). Depending on the context that the callback function is executed in, different restrictions apply to the implementation of the callback function.
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IPC in Task Context
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-------------------
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The IPC feature implements callback execution in a task context by creating an IPC task for each CPU during application startup. When the calling CPU needs to execute a callback on the target CPU, the callback will execute in the context of the target CPU's IPC task.
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When using IPCs in a task context, users need to consider the following:
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- IPC callbacks should ideally be simple and short. **An IPC callback should avoid attempting to block or yield**.
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- The IPC tasks are created at the highest possible priority (i.e., ``configMAX_PRIORITIES - 1``) thus the callback should also run at that priority as a result. However, :ref:`CONFIG_ESP_IPC_USES_CALLERS_PRIORITY` is enabled by default which will temporarily lower the priority of the target CPU's IPC task to the calling CPU before executing the callback.
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- Depending on the complexity of the callback, users may need to configure the stack size of the IPC task via :ref:`CONFIG_ESP_IPC_TASK_STACK_SIZE`.
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- The IPC feature is internally protected by a mutex. Therefore, simultaneous IPC calls from two or more calling CPUs will be handled on a first come first serve basis.
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API Usage
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^^^^^^^^^
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Task Context IPC callbacks have the following restrictions:
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- The callback must be of type ``void func(void *arg)``
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- The callback should avoid attempting to block or yield as this will result in the target CPU's IPC task blocking or yielding.
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- The callback must avoid changing any aspect of the IPC task (e.g., by calling ``vTaskPrioritySet(NULL, x)``).
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The IPC feature offers the API listed below to execute a callback in a task context on a target CPU. The API allows the calling CPU to block until the callback's execution has completed, or return immediately once the callback's execution has started.
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- :cpp:func:`esp_ipc_call` will trigger an IPC call on the target CPU. This function will block until the target CPU's IPC task **begins** execution of the callback.
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- :cpp:func:`esp_ipc_call_blocking` will trigger an IPC on the target CPU. This function will block until the target CPU's IPC task **completes** execution of the callback.
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IPC in ISR Context
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------------------
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In some cases, we need to quickly obtain the state of another CPU such as in a core dump, GDB stub, various unit tests, and DPORT workaround. For such scenarios, the IPC feature supports execution of callbacks in a :doc:`High Priority Interrupt </api-guides/hlinterrupts>` context. The IPC feature implements the High Priority Interrupt context by reserving a High Priority Interrupt on each CPU for IPC usage. When a calling CPU needs to execute a callback on the target CPU, the callback will execute in the context of the High Priority Interrupt of the target CPU.
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When using IPCs in High Priority Interrupt context, users need to consider the following:
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- Since the callback is executed in a High Priority Interrupt context, the callback must be written entirely in assembly. See the API Usage below for more details regarding writing assembly callbacks.
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- The priority of the reserved High Priority Interrupt is dependent on the :ref:`CONFIG_ESP_SYSTEM_CHECK_INT_LEVEL` option
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- When the callback executes:
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- The calling CPU will disable interrupts of level 3 and lower
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- Although the priority of the reserved interrupt depends on :ref:`CONFIG_ESP_SYSTEM_CHECK_INT_LEVEL`, during the execution IPC ISR callback, the target CPU will disable interrupts of level 5 and lower regardless of what :ref:`CONFIG_ESP_SYSTEM_CHECK_INT_LEVEL` is set to.
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API Usage
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^^^^^^^^^
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High Priority Interrupt IPC callbacks have the following restrictions:
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- The callback must be of type ``void func(void *arg)`` but implemented entirely in assembly
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- The callback is invoked via the ``CALLX0`` instruction with register windowing disabled, thus the callback:
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- Must not call any register window related instructions (e.g., ``entry`` and ``retw``).
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- Must not call other C functions as register windowing is disabled
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- The callback should be placed in IRAM at a 4-byte aligned address
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- (On invocation of/after returning from) the callback, the registers ``a2, a3, a4`` are (saved/restored) automatically thus can be used in the callback. The callback should **ONLY** use those registers.
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- ``a2`` will contain the ``void *arg`` of the callback
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- ``a3/a4`` are free to use as scratch registers
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The IPC feature offers the API listed below to execute a callback in a High Priority Interrupt context.
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- :cpp:func:`esp_ipc_isr_asm_call` will trigger an IPC call on the target CPU. This function will busy-wait until the target CPU begins execution of the callback.
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- :cpp:func:`esp_ipc_isr_asm_call_blocking` will trigger an IPC call on the target CPU. This function will busy-wait until the target CPU completes execution of the callback.
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The following code-blocks demonstrates a High Priority Interrupt IPC callback written in assembly that simply reads the target CPU's cycle count.
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.. code-block:: asm
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/* esp_test_ipc_isr_get_cycle_count_other_cpu(void *arg) */
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// this function reads CCOUNT of the target CPU and stores it in arg.
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// use only a2, a3 and a4 regs here.
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.section .iram1, "ax"
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.align 4
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.global esp_test_ipc_isr_get_cycle_count_other_cpu
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.type esp_test_ipc_isr_get_cycle_count_other_cpu, @function
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// Args:
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// a2 - void* arg
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esp_test_ipc_isr_get_cycle_count_other_cpu:
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rsr.ccount a3
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s32i a3, a2, 0
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ret
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.. code-block:: c
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unit32_t cycle_count;
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esp_ipc_isr_asm_call_blocking(esp_test_ipc_isr_get_cycle_count_other_cpu, (void *)cycle_count);
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.. note::
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The number of scratch registers available for use is sufficient for most simple use cases. But if your callback requires more scratch registers, ``void *arg`` can point to a buffer that is used as a register save area. The callback can then save and restore more registers. See the :example:`system/ipc/ipc_isr`.
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.. note::
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For more examples of High Priority Interrupt IPC callbacks, see :idf_file:`components/esp_system/port/arch/xtensa/esp_ipc_isr_routines.S` and :`components/esp_system/test/test_ipc_isr.S`
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The High Priority Interrupt IPC API also provides the following convenience functions that can stall/resume the target CPU. These API utilize the High Priority Interrupt IPC, but supply their own internal callbacks:
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- :cpp:func:`esp_ipc_isr_stall_other_cpu` stalls the target CPU. The calling CPU disables interrupts of level 3 and lower while the target CPU will busy-wait with interrupts of level 5 and lower disabled. The target CPU will busy-wait until :cpp:func:`esp_ipc_isr_release_other_cpu` is called.
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- :cpp:func:`esp_ipc_isr_release_other_cpu` resumes the target CPU.
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API Reference
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-------------
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.. include-build-file:: inc/esp_ipc.inc
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.. include-build-file:: inc/esp_ipc_isr.inc
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