338 lines
11 KiB
ReStructuredText
338 lines
11 KiB
ReStructuredText
.. _device_drivers:
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Device Driver Model
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###############################
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Introduction
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************
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The Zephyr kernel supports a variety of device drivers. Whether a
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driver is available depends on the board and the driver.
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The Zephyr device model provides a consistent device model for configuring the
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drivers that are part of a system. The device model is responsible
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for initializing all the drivers configured into the system.
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Each type of driver (UART, SPI, I2C) is supported by a generic type API.
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In this model the driver fills in the pointer to the structure containing the
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function pointers to its API functions during driver initialization. These
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structures are placed into the RAM section in initialization level order.
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Standard Drivers
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****************
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Device drivers which are present on all supported board configurations
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are listed below.
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* **Interrupt controller**: This device driver is used by the kernel's
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interrupt management subsystem.
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* **Timer**: This device driver is used by the kernel's system clock and
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hardware clock subsystem.
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* **Serial communication**: This device driver is used by the kernel's
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system console subsystem.
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* **Random number generator**: This device driver provides a source of random
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numbers.
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.. important::
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Certain implementations of this device driver do not generate sequences of
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values that are truly random.
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Synchronous Calls
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*****************
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Zephyr provides a set of device drivers for multiple boards. Each driver
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should support an interrupt-based implementation, rather than polling, unless
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the specific hardware does not provide any interrupt.
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High-level calls accessed through device-specific APIs, such as i2c.h
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or spi.h, are usually intended as synchronous. Thus, these calls should be
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blocking.
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Driver APIs
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***********
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The following APIs for device drivers are provided by :file:`device.h`. The APIs
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are intended for use in device drivers only and should not be used in
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applications.
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:c:func:`DEVICE_INIT()`
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create device object and set it up for boot time initialization.
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:c:func:`DEVICE_AND_API_INIT()`
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Create device object and set it up for boot time initialization.
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This also takes a pointer to driver API struct for link time
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pointer assignment.
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:c:func:`DEVICE_NAME_GET()`
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Expands to the full name of a global device object.
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:c:func:`DEVICE_GET()`
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Obtain a pointer to a device object by name.
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:c:func:`DEVICE_DECLARE()`
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Declare a device object.
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Driver Data Structures
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**********************
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The device initialization macros populate some data structures at build time
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which are
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split into read-only and runtime-mutable parts. At a high level we have:
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.. code-block:: C
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struct device {
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struct device_config *config;
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void *driver_api;
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void *driver_data;
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};
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struct device_config {
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char *name;
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int (*init)(struct device *device);
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const void *config_info;
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[...]
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};
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The ``config`` member is for read-only configuration data set at build time. For
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example, base memory mapped IO addresses, IRQ line numbers, or other fixed
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physical characteristics of the device. This is the ``config_info`` structure
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passed to the ``DEVICE_*INIT()`` macros.
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The ``driver_data`` struct is kept in RAM, and is used by the driver for
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per-instance runtime housekeeping. For example, it may contain reference counts,
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semaphores, scratch buffers, etc.
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The ``driver_api`` struct maps generic subsystem APIs to the device-specific
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implementations in the driver. It is typically read-only and populated at
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build time. The next section describes this in more detail.
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Subsystems and API Structures
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*****************************
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Most drivers will be implementing a device-independent subsystem API.
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Applications can simply program to that generic API, and application
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code is not specific to any particular driver implementation.
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A subsystem API definition typically looks like this:
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.. code-block:: C
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typedef int (*subsystem_do_this_t)(struct device *device, int foo, int bar);
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typedef void (*subsystem_do_that_t)(struct device *device, void *baz);
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struct subsystem_api {
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subsystem_do_this_t do_this;
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subsystem_do_that_t do_that;
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};
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static inline int subsystem_do_this(struct device *device, int foo, int bar)
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{
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struct subsystem_api *api;
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api = (struct subsystem_api *)device->driver_api;
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return api->do_this(device, foo, bar);
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}
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static inline void subsystem_do_that(struct device *device, void *baz)
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{
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struct subsystem_api *api;
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api = (struct subsystem_api *)device->driver_api;
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api->do_that(device, foo, bar);
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}
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A driver implementing a particular subsystem will define the real implementation
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of these APIs, and populate an instance of subsystem_api structure:
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.. code-block:: C
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static int my_driver_do_this(struct device *device, int foo, int bar)
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{
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...
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}
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static void my_driver_do_that(struct device *device, void *baz)
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{
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...
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}
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static struct subsystem_api my_driver_api_funcs = {
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.do_this = my_driver_do_this,
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.do_that = my_driver_do_that
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};
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The driver would then pass ``my_driver_api_funcs`` as the ``api`` argument to
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``DEVICE_AND_API_INIT()``, or manually assign it to ``device->driver_api``
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in the driver init function.
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.. note::
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Since pointers to the API functions are referenced in the ``driver_api``
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struct, they will always be included in the binary even if unused;
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``gc-sections`` linker option will always see at least one reference to
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them. Providing for link-time size optimizations with driver APIs in
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most cases requires that the optional feature be controlled by a
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Kconfig option.
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Single Driver, Multiple Instances
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*********************************
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Some drivers may be instantiated multiple times in a given system. For example
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there can be multiple GPIO banks, or multiple UARTS. Each instance of the driver
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will have a different ``config_info`` struct and ``driver_data`` struct.
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Configuring interrupts for multiple drivers instances is a special case. If each
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instance needs to configure a different interrupt line, this can be accomplished
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through the use of per-instance configuration functions, since the parameters
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to ``IRQ_CONNECT()`` need to be resolvable at build time.
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For example, let's say we need to configure two instances of ``my_driver``, each
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with a different interrupt line. In ``drivers/subsystem/subsystem_my_driver.h``:
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.. code-block:: C
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typedef void (*my_driver_config_irq_t)(struct device *device);
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struct my_driver_config {
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u32_t base_addr;
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my_driver_config_irq_t config_func;
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};
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In the implementation of the common init function:
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.. code-block:: C
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void my_driver_isr(struct device *device)
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{
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/* Handle interrupt */
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...
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}
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int my_driver_init(struct device *device)
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{
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const struct my_driver_config *config = device->config->config_info;
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/* Do other initialization stuff */
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...
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config->config_func(device);
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return 0;
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}
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Then when the particular instance is declared:
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.. code-block:: C
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#if CONFIG_MY_DRIVER_0
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DEVICE_DECLARE(my_driver_0);
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static void my_driver_config_irq_0(void)
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{
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IRQ_CONNECT(MY_DRIVER_0_IRQ, MY_DRIVER_0_PRI, my_driver_isr,
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DEVICE_GET(my_driver_0), MY_DRIVER_0_FLAGS);
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}
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const static struct my_driver_config my_driver_config_0 = {
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.base_addr = MY_DRIVER_0_BASE_ADDR,
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.config_func = my_driver_config_irq_0
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}
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static struct my_driver_data_0;
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DEVICE_AND_API_INIT(my_driver_0, MY_DRIVER_0_NAME, my_driver_init,
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&my_driver_data_0, &my_driver_config_0, POST_KERNEL,
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MY_DRIVER_0_PRIORITY, &my_driver_api_funcs);
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#endif /* CONFIG_MY_DRIVER_0 */
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Note the use of ``DEVICE_DECLARE()`` to avoid a circular dependency on providing
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the IRQ handler argument and the definition of the device itself.
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Initialization Levels
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*********************
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Drivers may depend on other drivers being initialized first, or
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require the use of kernel services. The DEVICE_INIT() APIs allow the user to
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specify at what time during the boot sequence the init function will be
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executed. Any driver will specify one of five initialization levels:
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``PRE_KERNEL_1``
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Used for devices that have no dependencies, such as those that rely
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solely on hardware present in the processor/SOC. These devices cannot
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use any kernel services during configuration, since the kernel services are
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not yet available. The interrupt subsystem will be configured however
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so it's OK to set up interrupts. Init functions at this level run on the
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interrupt stack.
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``PRE_KERNEL_2``
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Used for devices that rely on the initialization of devices initialized
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as part of the ``PRE_KERNEL_1`` level. These devices cannot use any kernel
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services during configuration, since the kernel services are not yet
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available. Init functions at this level run on the interrupt stack.
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``POST_KERNEL``
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Used for devices that require kernel services during configuration.
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Init functions at this level run in context of the kernel main task.
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``APPLICATION``
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Used for application components (i.e. non-kernel components) that need
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automatic configuration. These devices can use all services provided by
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the kernel during configuration. Init functions at this level run on
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the kernel main task.
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Within each initialization level you may specify a priority level, relative to
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other devices in the same initialization level. The priority level is specified
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as an integer value in the range 0 to 99; lower values indicate earlier
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initialization. The priority level must be a decimal integer literal without
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leading zeroes or sign (e.g. 32), or an equivalent symbolic name (e.g.
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``\#define MY_INIT_PRIO 32``); symbolic expressions are *not* permitted (e.g.
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``CONFIG_KERNEL_INIT_PRIORITY_DEFAULT + 5``).
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System Drivers
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**************
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In some cases you may just need to run a function at boot. Special ``SYS_*``
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macros exist that map to ``DEVICE_*INIT()`` calls.
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For ``SYS_INIT()`` there are no config or runtime data structures and there
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isn't a way
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to later get a device pointer by name. The same policies for initialization
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level and priority apply.
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For ``SYS_DEVICE_DEFINE()`` you can obtain pointers by name, see
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:ref:`power management <power_management>` section.
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:c:func:`SYS_INIT()`
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:c:func:`SYS_DEVICE_DEFINE()`
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Error handling
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**************
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In general, it's best to use ``__ASSERT()`` macros instead of
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propagating return values unless the failure is expected to occur
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during the normal course of operation (such as a storage device
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full). Bad parameters, programming errors, consistency checks,
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pathological/unrecoverable failures, etc., should be handled by
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assertions.
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When it is appropriate to return error conditions for the caller to
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check, 0 should be returned on success and a POSIX errno.h code
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returned on failure. See
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https://github.com/zephyrproject-rtos/zephyr/wiki/Naming-Conventions#return-codes
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for details about this.
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API Reference
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**************
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.. doxygengroup:: device_model
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:project: Zephyr
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