include/device.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google


 /*
  * Copyright (c) 2015 Intel Corporation.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #ifndef ZEPHYR_INCLUDE_DEVICE_H_
 #define ZEPHYR_INCLUDE_DEVICE_H_

 #include <kernel.h>

 /**
  * @brief Device Driver APIs
  * @defgroup io_interfaces Device Driver APIs
  * @{
  * @}
  */
 /**
  * @brief Device Model APIs
  * @defgroup device_model Device Model APIs
  * @{
  */

 #include <zephyr/types.h>

 #ifdef __cplusplus
 extern "C" {
 #endif

 #define Z_DEVICE_MAX_NAME_LEN	48

 /**
  * @def DEVICE_INIT
  *
  * @brief Create device object and set it up for boot time initialization.
  *
  * @details This macro defines a device object that is automatically
  * configured by the kernel during system initialization. Note that
  * devices set up with this macro will not be accessible from user mode
  * since the API is not specified; whenever possible, use DEVICE_AND_API_INIT
  * instead.
  *
  * @param dev_name Device name. This must be less than Z_DEVICE_MAX_NAME_LEN
  * characters in order to be looked up from user mode with device_get_binding().
  *
  * @param drv_name The name this instance of the driver exposes to
  * the system.
  *
  * @param init_fn Address to the init function of the driver.
  *
  * @param data Pointer to the device's configuration data.
  *
  * @param cfg_info The address to the structure containing the
  * configuration information for this instance of the driver.
  *
  * @param level The initialization level at which configuration occurs.
  * Must be one of the following symbols, which are listed in the order
  * they are performed by the kernel:
  * \n
  * \li PRE_KERNEL_1: Used for devices that have no dependencies, such as those
  * that rely solely on hardware present in the processor/SOC. These devices
  * cannot use any kernel services during configuration, since they are not
  * yet available.
  * \n
  * \li PRE_KERNEL_2: Used for devices that rely on the initialization of devices
  * initialized as part of the PRE_KERNEL_1 level. These devices cannot use any
  * kernel services during configuration, since they are not yet available.
  * \n
  * \li POST_KERNEL: Used for devices that require kernel services during
  * configuration.
  * \n
  * \li APPLICATION: Used for application components (i.e. non-kernel components)
  * that need automatic configuration. These devices can use all services
  * provided by the kernel during configuration.
  *
  * @param prio The initialization priority of the device, relative to
  * other devices of the same initialization level. Specified as an integer
  * value in the range 0 to 99; lower values indicate earlier initialization.
  * Must be a decimal integer literal without leading zeroes or sign (e.g. 32),
  * or an equivalent symbolic name (e.g. \#define MY_INIT_PRIO 32); symbolic
  * expressions are *not* permitted
  * (e.g. CONFIG_KERNEL_INIT_PRIORITY_DEFAULT + 5).
  */
 #define DEVICE_INIT(dev_name, drv_name, init_fn, data, cfg_info, level, prio) \
 	DEVICE_AND_API_INIT(dev_name, drv_name, init_fn,\
 	data, cfg_info, level, prio, NULL)


 /**
  * @def DEVICE_AND_API_INIT
  *
  * @brief Create device object and set it up for boot time initialization,
  * with the option to set driver_api.
  *
  * @copydetails DEVICE_INIT
  * @param api Provides an initial pointer to the API function struct
  * used by the driver. Can be NULL.
  * @details The driver api is also set here, eliminating the need to do that
  * during initialization.
  */
 #ifndef CONFIG_DEVICE_POWER_MANAGEMENT
 #define DEVICE_AND_API_INIT(dev_name, drv_name, init_fn, data, cfg_info,  \
 			    level, prio, api)				  \
 	static struct device_config _CONCAT(__config_, dev_name) __used	  \
 	__attribute__((__section__(".devconfig.init"))) = {		  \
 		.name = drv_name, .init = (init_fn),			  \
 		.config_info = (cfg_info)				  \
 	};								  \
 	static struct device _CONCAT(__device_, dev_name) __used	  \
 	__attribute__((__section__(".init_" #level STRINGIFY(prio)))) = { \
 		.config = &_CONCAT(__config_, dev_name),		  \
 		.driver_api = api,					  \
 		.driver_data = data					  \
 	}
 #else
 /*
  * Use the default device_pm_control for devices that do not call the
  * DEVICE_DEFINE macro so that caller of hook functions
  * need not check device_pm_control != NULL.
  */
 #define DEVICE_AND_API_INIT(dev_name, drv_name, init_fn, data, cfg_info, \
 			    level, prio, api)				 \
 	DEVICE_DEFINE(dev_name, drv_name, init_fn,			 \
 		      device_pm_control_nop, data, cfg_info, level,	 \
 		      prio, api)
 #endif

 /**
  * @def DEVICE_DEFINE
  *
  * @brief Create device object and set it up for boot time initialization,
  * with the option to device_pm_control. In case of Device Idle Power
  * Management is enabled, make sure the device is in suspended state after
  * initialization.
  *
  * @copydetails DEVICE_AND_API_INIT
  * @param pm_control_fn Pointer to device_pm_control function.
  * Can be empty function (device_pm_control_nop) if not implemented.
  */
 #ifndef CONFIG_DEVICE_POWER_MANAGEMENT
 #define DEVICE_DEFINE(dev_name, drv_name, init_fn, pm_control_fn,	 \
 		      data, cfg_info, level, prio, api)			 \
 	DEVICE_AND_API_INIT(dev_name, drv_name, init_fn, data, cfg_info, \
 			    level, prio, api)
 #else
 #define DEVICE_DEFINE(dev_name, drv_name, init_fn, pm_control_fn,	  \
 		      data, cfg_info, level, prio, api)			  \
 	static struct device_pm _CONCAT(__pm_, dev_name) __used           \
 							= {               \
 		.usage = ATOMIC_INIT(0),                                  \
 		.lock = Z_SEM_INITIALIZER(                               \
 				_CONCAT(__pm_, dev_name).lock, 1, 1),     \
 		.signal = K_POLL_SIGNAL_INITIALIZER(                      \
 				_CONCAT(__pm_, dev_name).signal),         \
 		.event = K_POLL_EVENT_INITIALIZER(K_POLL_TYPE_SIGNAL,     \
 				K_POLL_MODE_NOTIFY_ONLY,                  \
 				&_CONCAT(__pm_, dev_name).signal),        \
 	};								  \
 	static struct device_config _CONCAT(__config_, dev_name) __used	  \
 	__attribute__((__section__(".devconfig.init"))) = {		  \
 		.name = drv_name, .init = (init_fn),			  \
 		.device_pm_control = (pm_control_fn),			  \
 		.pm  = &_CONCAT(__pm_, dev_name),                         \
 		.config_info = (cfg_info)				  \
 	};								  \
 	static struct device _CONCAT(__device_, dev_name) __used	  \
 	__attribute__((__section__(".init_" #level STRINGIFY(prio)))) = { \
 		.config = &_CONCAT(__config_, dev_name),		  \
 		.driver_api = api,					  \
 		.driver_data = data,					  \
 	}
 #endif

 /**
  * @def DEVICE_NAME_GET
  *
  * @brief Expands to the full name of a global device object
  *
  * @details Return the full name of a device object symbol created by
  * DEVICE_INIT(), using the dev_name provided to DEVICE_INIT().
  *
  * It is meant to be used for declaring extern symbols pointing on device
  * objects before using the DEVICE_GET macro to get the device object.
  *
  * @param name The same as dev_name provided to DEVICE_INIT()
  *
  * @return The expanded name of the device object created by DEVICE_INIT()
  */
 #define DEVICE_NAME_GET(name) (_CONCAT(__device_, name))

 /**
  * @def DEVICE_GET
  *
  * @brief Obtain a pointer to a device object by name
  *
  * @details Return the address of a device object created by
  * DEVICE_INIT(), using the dev_name provided to DEVICE_INIT().
  *
  * @param name The same as dev_name provided to DEVICE_INIT()
  *
  * @return A pointer to the device object created by DEVICE_INIT()
  */
 #define DEVICE_GET(name) (&DEVICE_NAME_GET(name))

 /** @def DEVICE_DECLARE
  *
  * @brief Declare a static device object
  *
  * This macro can be used at the top-level to declare a device, such
  * that DEVICE_GET() may be used before the full declaration in
  * DEVICE_INIT().
  *
  * This is often useful when configuring interrupts statically in a
  * device's init or per-instance config function, as the init function
  * itself is required by DEVICE_INIT() and use of DEVICE_GET()
  * inside it creates a circular dependency.
  *
  * @param name Device name
  */
 #define DEVICE_DECLARE(name) static struct device DEVICE_NAME_GET(name)

 struct device;

 typedef void (*device_pm_cb)(struct device *dev,
 			     int status, void *context, void *arg);

 /**
  * @brief Device PM info
  *
  * @param dev pointer to device structure
  * @param lock lock to synchronize the get/put operations
  * @param enable device pm enable flag
  * @param usage device usage count
  * @param fsm_state device idle internal power state
  * @param event event object to listen to the sync request events
  * @param signal signal to notify the Async API callers
  */
 struct device_pm {
 	struct device *dev;
 	struct k_sem lock;
 	bool enable;
 	atomic_t usage;
 	atomic_t fsm_state;
 	struct k_work work;
 	struct k_poll_event event;
 	struct k_poll_signal signal;
 };

 /**
  * @brief Static device information (In ROM) Per driver instance
  *
  * @param name name of the device
  * @param init init function for the driver
  * @param config_info address of driver instance config information
  */
 struct device_config {
 	const char *name;
 	int (*init)(struct device *device);
 #ifdef CONFIG_DEVICE_POWER_MANAGEMENT
 	int (*device_pm_control)(struct device *device, u32_t command,
 				 void *context, device_pm_cb cb, void *arg);
 	struct device_pm *pm;
 #endif
 	const void *config_info;
 };

 /**
  * @brief Runtime device structure (In memory) Per driver instance
  * @param device_config Build time config information
  * @param driver_api pointer to structure containing the API functions for
  * the device type. This pointer is filled in by the driver at init time.
  * @param driver_data driver instance data. For driver use only
  */
 struct device {
 	struct device_config *config;
 	const void *driver_api;
 	void *driver_data;
 #if defined(__x86_64) && __SIZEOF_POINTER__ == 4
 	/* The x32 ABI hits an edge case.  This is a 12 byte struct,
 	 * but the x86_64 linker will pack them only in units of 8
 	 * bytes, leading to alignment problems when iterating over
 	 * the link-time array.
 	 */
 	void *padding;
 #endif
 };

 void z_sys_device_do_config_level(s32_t level);

 /**
  * @brief Retrieve the device structure for a driver by name
  *
  * @details Device objects are created via the DEVICE_INIT() macro and
  * placed in memory by the linker. If a driver needs to bind to another driver
  * it can use this function to retrieve the device structure of the lower level
  * driver by the name the driver exposes to the system.
  *
  * @param name device name to search for.
  *
  * @return pointer to device structure; NULL if not found or cannot be used.
  */
 __syscall struct device *device_get_binding(const char *name);

 /**
  * @}
  */

 /**
  * @brief Device Power Management APIs
  * @defgroup device_power_management_api Device Power Management APIs
  * @ingroup power_management_api
  * @{
  */

 #ifdef CONFIG_DEVICE_POWER_MANAGEMENT

 /** @def DEVICE_PM_ACTIVE_STATE
  *
  * @brief device is in ACTIVE power state
  *
  * @details Normal operation of the device. All device context is retained.
  */
 #define DEVICE_PM_ACTIVE_STATE          1

 /** @def DEVICE_PM_LOW_POWER_STATE
  *
  * @brief device is in LOW power state
  *
  * @details Device context is preserved by the HW and need not be
  * restored by the driver.
  */
 #define DEVICE_PM_LOW_POWER_STATE       2

 /** @def DEVICE_PM_SUSPEND_STATE
  *
  * @brief device is in SUSPEND power state
  *
  * @details Most device context is lost by the hardware.
  * Device drivers must save and restore or reinitialize any context
  * lost by the hardware
  */
 #define DEVICE_PM_SUSPEND_STATE         3

 /** @def DEVICE_PM_FORCE_SUSPEND_STATE
  *
  * @brief device is in force SUSPEND power state
  *
  * @details Driver puts the device in suspended state after
  * completing the ongoing transactions and will not process any
  * queued work or will not take any new requests for processing.
  * Most device context is lost by the hardware. Device drivers must
  * save and restore or reinitialize any context lost by the hardware.
  */
 #define DEVICE_PM_FORCE_SUSPEND_STATE	4

 /** @def DEVICE_PM_OFF_STATE
  *
  * @brief device is in OFF power state
  *
  * @details - Power has been fully removed from the device.
  * The device context is lost when this state is entered, so the OS
  * software will reinitialize the device when powering it back on
  */
 #define DEVICE_PM_OFF_STATE             5

 /* Constants defining support device power commands */
 #define DEVICE_PM_SET_POWER_STATE       1
 #define DEVICE_PM_GET_POWER_STATE       2

 #endif /* CONFIG_DEVICE_POWER_MANAGEMENT */

 /**
  * @brief Indicate that the device is in the middle of a transaction
  *
  * Called by a device driver to indicate that it is in the middle of a
  * transaction.
  *
  * @param busy_dev Pointer to device structure of the driver instance.
  */
 void device_busy_set(struct device *busy_dev);

 /**
  * @brief Indicate that the device has completed its transaction
  *
  * Called by a device driver to indicate the end of a transaction.
  *
  * @param busy_dev Pointer to device structure of the driver instance.
  */
 void device_busy_clear(struct device *busy_dev);

 #ifdef CONFIG_DEVICE_POWER_MANAGEMENT
 /*
  * Device PM functions
  */

 /**
  * @brief No-op function to initialize unimplemented hook
  *
  * This function should be used to initialize device hook
  * for which a device has no PM operations.
  *
  * @param unused_device Unused
  * @param unused_ctrl_command Unused
  * @param unused_context Unused
  * @param cb Unused
  * @param unused_arg Unused
  *
  * @retval 0 Always returns 0
  */
 int device_pm_control_nop(struct device *unused_device,
 			  u32_t unused_ctrl_command,
 			  void *unused_context,
 			  device_pm_cb cb,
 			  void *unused_arg);
 /**
  * @brief Call the set power state function of a device
  *
  * Called by the application or power management service to let the device do
  * required operations when moving to the required power state
  * Note that devices may support just some of the device power states
  * @param device Pointer to device structure of the driver instance.
  * @param device_power_state Device power state to be set
  * @param cb Callback function to notify device power status
  * @param arg Caller passed argument to callback function
  *
  * @retval 0 If successful in queuing the request or changing the state.
  * @retval Errno Negative errno code if failure. Callback will not be called.
  */
 static inline int device_set_power_state(struct device *device,
 					 u32_t device_power_state,
 					 device_pm_cb cb, void *arg)
 {
 	return device->config->device_pm_control(device,
 						 DEVICE_PM_SET_POWER_STATE,
 						 &device_power_state, cb, arg);
 }

 /**
  * @brief Call the get power state function of a device
  *
  * This function lets the caller know the current device
  * power state at any time. This state will be one of the defined
  * power states allowed for the devices in that system
  *
  * @param device pointer to device structure of the driver instance.
  * @param device_power_state Device power state to be filled by the device
  *
  * @retval 0 If successful.
  * @retval Errno Negative errno code if failure.
  */
 static inline int device_get_power_state(struct device *device,
 					 u32_t *device_power_state)
 {
 	return device->config->device_pm_control(device,
 						 DEVICE_PM_GET_POWER_STATE,
 						 device_power_state,
 						 NULL, NULL);
 }

 /**
  * @brief Gets the device structure list array and device count
  *
  * Called by the Power Manager application to get the list of
  * device structures associated with the devices in the system.
  * The PM app would use this list to create its own sorted list
  * based on the order it wishes to suspend or resume the devices.
  *
  * @param device_list Pointer to receive the device list array
  * @param device_count Pointer to receive the device count
  */
 void device_list_get(struct device **device_list, int *device_count);

 /**
  * @brief Check if any device is in the middle of a transaction
  *
  * Called by an application to see if any device is in the middle
  * of a critical transaction that cannot be interrupted.
  *
  * @retval 0 if no device is busy
  * @retval -EBUSY if any device is busy
  */
 int device_any_busy_check(void);

 /**
  * @brief Check if a specific device is in the middle of a transaction
  *
  * Called by an application to see if a particular device is in the
  * middle of a critical transaction that cannot be interrupted.
  *
  * @param chk_dev Pointer to device structure of the specific device driver
  * the caller is interested in.
  * @retval 0 if the device is not busy
  * @retval -EBUSY if the device is busy
  */
 int device_busy_check(struct device *chk_dev);

 #ifdef CONFIG_DEVICE_IDLE_PM

 /* Device PM FSM states */
 enum device_pm_fsm_state {
 	DEVICE_PM_FSM_STATE_ACTIVE = 1,
 	DEVICE_PM_FSM_STATE_SUSPENDED,
 	DEVICE_PM_FSM_STATE_SUSPENDING,
 	DEVICE_PM_FSM_STATE_RESUMING,
 };

 /**
  * @brief Enable device idle PM
  *
  * Called by a device driver to enable device idle power management.
  * The device might be asynchronously suspended if Idle PM is enabled
  * when the device is not use.
  *
  * @param dev Pointer to device structure of the specific device driver
  * the caller is interested in.
  */
 void device_pm_enable(struct device *dev);

 /**
  * @brief Disable device idle PM
  *
  * Called by a device driver to disable device idle power management.
  * The device might be asynchronously resumed if Idle PM is disabled
  *
  * @param dev Pointer to device structure of the specific device driver
  * the caller is interested in.
  */
 void device_pm_disable(struct device *dev);

 /**
  * @brief Call device resume asynchronously based on usage count
  *
  * Called by a device driver to mark the device as being used.
  * This API will asynchronously bring the device to resume state
  * if it not already in active state.
  *
  * @param dev Pointer to device structure of the specific device driver
  * the caller is interested in.
  * @retval 0 If successfully queued the Async request. If queued,
  * the caller need to wait on the poll event linked to device
  * pm signal mechanism to know the completion of resume operation.
  * @retval Errno Negative errno code if failure.
  */
 int device_pm_get(struct device *dev);

 /**
  * @brief Call device resume synchronously based on usage count
  *
  * Called by a device driver to mark the device as being used. It
  * will bring up or resume the device if it is in suspended state
  * based on the device usage count. This call is blocked until the
  * device PM state is changed to resume.
  *
  * @param dev Pointer to device structure of the specific device driver
  * the caller is interested in.
  * @retval 0 If successful.
  * @retval Errno Negative errno code if failure.
  */
 int device_pm_get_sync(struct device *dev);

 /**
  * @brief Call device suspend asynchronously based on usage count
  *
  * Called by a device driver to mark the device as being released.
  * This API asynchronously put the device to suspend state if
  * it not already in suspended state.
  *
  * @param dev Pointer to device structure of the specific device driver
  * the caller is interested in.
  * @retval 0 If successfully queued the Async request. If queued,
  * the caller need to wait on the poll event linked to device pm
  * signal mechanism to know the completion of suspend operation.
  * @retval Errno Negative errno code if failure.
  */
 int device_pm_put(struct device *dev);

 /**
  * @brief Call device suspend synchronously based on usage count
  *
  * Called by a device driver to mark the device as being released. It
  * will put the device to suspended state if is is in active state
  * based on the device usage count. This call is blocked until the
  * device PM state is changed to resume.
  *
  * @param dev Pointer to device structure of the specific device driver
  * the caller is interested in.
  * @retval 0 If successful.
  * @retval Errno Negative errno code if failure.
  */
 int device_pm_put_sync(struct device *dev);
 #else
 static inline void device_pm_enable(struct device *dev) { }
 static inline void device_pm_disable(struct device *dev) { }
 static inline int device_pm_get(struct device *dev) { return -ENOTSUP; }
 static inline int device_pm_get_sync(struct device *dev) { return -ENOTSUP; }
 static inline int device_pm_put(struct device *dev) { return -ENOTSUP; }
 static inline int device_pm_put_sync(struct device *dev) { return -ENOTSUP; }
 #endif

 #endif

 /**
  * @}
  */

 #include <syscalls/device.h>

 #ifdef __cplusplus
 }
 #endif
 #endif /* ZEPHYR_INCLUDE_DEVICE_H_ */

	/*
	* Copyright (c) 2015 Intel Corporation.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#ifndef ZEPHYR_INCLUDE_DEVICE_H_
	#define ZEPHYR_INCLUDE_DEVICE_H_

	#include <kernel.h>

	/**
	* @brief Device Driver APIs
	* @defgroup io_interfaces Device Driver APIs
	* @{
	* @}
	*/
	/**
	* @brief Device Model APIs
	* @defgroup device_model Device Model APIs
	* @{
	*/

	#include <zephyr/types.h>

	#ifdef __cplusplus
	extern "C" {
	#endif

	#define Z_DEVICE_MAX_NAME_LEN 48

	/**
	* @def DEVICE_INIT
	*
	* @brief Create device object and set it up for boot time initialization.
	*
	* @details This macro defines a device object that is automatically
	* configured by the kernel during system initialization. Note that
	* devices set up with this macro will not be accessible from user mode
	* since the API is not specified; whenever possible, use DEVICE_AND_API_INIT
	* instead.
	*
	* @param dev_name Device name. This must be less than Z_DEVICE_MAX_NAME_LEN
	* characters in order to be looked up from user mode with device_get_binding().
	*
	* @param drv_name The name this instance of the driver exposes to
	* the system.
	*
	* @param init_fn Address to the init function of the driver.
	*
	* @param data Pointer to the device's configuration data.
	*
	* @param cfg_info The address to the structure containing the
	* configuration information for this instance of the driver.
	*
	* @param level The initialization level at which configuration occurs.
	* Must be one of the following symbols, which are listed in the order
	* they are performed by the kernel:
	* \n
	* \li PRE_KERNEL_1: Used for devices that have no dependencies, such as those
	* that rely solely on hardware present in the processor/SOC. These devices
	* cannot use any kernel services during configuration, since they are not
	* yet available.
	* \n
	* \li PRE_KERNEL_2: Used for devices that rely on the initialization of devices
	* initialized as part of the PRE_KERNEL_1 level. These devices cannot use any
	* kernel services during configuration, since they are not yet available.
	* \n
	* \li POST_KERNEL: Used for devices that require kernel services during
	* configuration.
	* \n
	* \li APPLICATION: Used for application components (i.e. non-kernel components)
	* that need automatic configuration. These devices can use all services
	* provided by the kernel during configuration.
	*
	* @param prio The initialization priority of the device, relative to
	* other devices of the same initialization level. Specified as an integer
	* value in the range 0 to 99; lower values indicate earlier initialization.
	* Must be a decimal integer literal without leading zeroes or sign (e.g. 32),
	* or an equivalent symbolic name (e.g. \#define MY_INIT_PRIO 32); symbolic
	* expressions are not permitted
	* (e.g. CONFIG_KERNEL_INIT_PRIORITY_DEFAULT + 5).
	*/
	#define DEVICE_INIT(dev_name, drv_name, init_fn, data, cfg_info, level, prio) \
	DEVICE_AND_API_INIT(dev_name, drv_name, init_fn,\
	data, cfg_info, level, prio, NULL)


	/**
	* @def DEVICE_AND_API_INIT
	*
	* @brief Create device object and set it up for boot time initialization,
	* with the option to set driver_api.
	*
	* @copydetails DEVICE_INIT
	* @param api Provides an initial pointer to the API function struct
	* used by the driver. Can be NULL.
	* @details The driver api is also set here, eliminating the need to do that
	* during initialization.
	*/
	#ifndef CONFIG_DEVICE_POWER_MANAGEMENT
	#define DEVICE_AND_API_INIT(dev_name, drv_name, init_fn, data, cfg_info, \
	level, prio, api) \
	static struct device_config _CONCAT(__config_, dev_name) __used \
	__attribute__((__section__(".devconfig.init"))) = { \
	.name = drv_name, .init = (init_fn), \
	.config_info = (cfg_info) \
	}; \
	static struct device _CONCAT(__device_, dev_name) __used \
	__attribute__((__section__(".init_" #level STRINGIFY(prio)))) = { \
	.config = &_CONCAT(__config_, dev_name), \
	.driver_api = api, \
	.driver_data = data \
	}
	#else
	/*
	* Use the default device_pm_control for devices that do not call the
	* DEVICE_DEFINE macro so that caller of hook functions
	* need not check device_pm_control != NULL.
	*/
	#define DEVICE_AND_API_INIT(dev_name, drv_name, init_fn, data, cfg_info, \
	level, prio, api) \
	DEVICE_DEFINE(dev_name, drv_name, init_fn, \
	device_pm_control_nop, data, cfg_info, level, \
	prio, api)
	#endif

	/**
	* @def DEVICE_DEFINE
	*
	* @brief Create device object and set it up for boot time initialization,
	* with the option to device_pm_control. In case of Device Idle Power
	* Management is enabled, make sure the device is in suspended state after
	* initialization.
	*
	* @copydetails DEVICE_AND_API_INIT
	* @param pm_control_fn Pointer to device_pm_control function.
	* Can be empty function (device_pm_control_nop) if not implemented.
	*/
	#ifndef CONFIG_DEVICE_POWER_MANAGEMENT
	#define DEVICE_DEFINE(dev_name, drv_name, init_fn, pm_control_fn, \
	data, cfg_info, level, prio, api) \
	DEVICE_AND_API_INIT(dev_name, drv_name, init_fn, data, cfg_info, \
	level, prio, api)
	#else
	#define DEVICE_DEFINE(dev_name, drv_name, init_fn, pm_control_fn, \
	data, cfg_info, level, prio, api) \
	static struct device_pm _CONCAT(__pm_, dev_name) __used \
	= { \
	.usage = ATOMIC_INIT(0), \
	.lock = Z_SEM_INITIALIZER( \
	_CONCAT(__pm_, dev_name).lock, 1, 1), \
	.signal = K_POLL_SIGNAL_INITIALIZER( \
	_CONCAT(__pm_, dev_name).signal), \
	.event = K_POLL_EVENT_INITIALIZER(K_POLL_TYPE_SIGNAL, \
	K_POLL_MODE_NOTIFY_ONLY, \
	&_CONCAT(__pm_, dev_name).signal), \
	}; \
	static struct device_config _CONCAT(__config_, dev_name) __used \
	__attribute__((__section__(".devconfig.init"))) = { \
	.name = drv_name, .init = (init_fn), \
	.device_pm_control = (pm_control_fn), \
	.pm = &_CONCAT(__pm_, dev_name), \
	.config_info = (cfg_info) \
	}; \
	static struct device _CONCAT(__device_, dev_name) __used \
	__attribute__((__section__(".init_" #level STRINGIFY(prio)))) = { \
	.config = &_CONCAT(__config_, dev_name), \
	.driver_api = api, \
	.driver_data = data, \
	}
	#endif

	/**
	* @def DEVICE_NAME_GET
	*
	* @brief Expands to the full name of a global device object
	*
	* @details Return the full name of a device object symbol created by
	* DEVICE_INIT(), using the dev_name provided to DEVICE_INIT().
	*
	* It is meant to be used for declaring extern symbols pointing on device
	* objects before using the DEVICE_GET macro to get the device object.
	*
	* @param name The same as dev_name provided to DEVICE_INIT()
	*
	* @return The expanded name of the device object created by DEVICE_INIT()
	*/
	#define DEVICE_NAME_GET(name) (_CONCAT(__device_, name))

	/**
	* @def DEVICE_GET
	*
	* @brief Obtain a pointer to a device object by name
	*
	* @details Return the address of a device object created by
	* DEVICE_INIT(), using the dev_name provided to DEVICE_INIT().
	*
	* @param name The same as dev_name provided to DEVICE_INIT()
	*
	* @return A pointer to the device object created by DEVICE_INIT()
	*/
	#define DEVICE_GET(name) (&DEVICE_NAME_GET(name))

	/** @def DEVICE_DECLARE
	*
	* @brief Declare a static device object
	*
	* This macro can be used at the top-level to declare a device, such
	* that DEVICE_GET() may be used before the full declaration in
	* DEVICE_INIT().
	*
	* This is often useful when configuring interrupts statically in a
	* device's init or per-instance config function, as the init function
	* itself is required by DEVICE_INIT() and use of DEVICE_GET()
	* inside it creates a circular dependency.
	*
	* @param name Device name
	*/
	#define DEVICE_DECLARE(name) static struct device DEVICE_NAME_GET(name)

	struct device;

	typedef void (device_pm_cb)(struct device dev,
	int status, void context, void arg);

	/**
	* @brief Device PM info
	*
	* @param dev pointer to device structure
	* @param lock lock to synchronize the get/put operations
	* @param enable device pm enable flag
	* @param usage device usage count
	* @param fsm_state device idle internal power state
	* @param event event object to listen to the sync request events
	* @param signal signal to notify the Async API callers
	*/
	struct device_pm {
	struct device *dev;
	struct k_sem lock;
	bool enable;
	atomic_t usage;
	atomic_t fsm_state;
	struct k_work work;
	struct k_poll_event event;
	struct k_poll_signal signal;
	};

	/**
	* @brief Static device information (In ROM) Per driver instance
	*
	* @param name name of the device
	* @param init init function for the driver
	* @param config_info address of driver instance config information
	*/
	struct device_config {
	const char *name;
	int (init)(struct device device);
	#ifdef CONFIG_DEVICE_POWER_MANAGEMENT
	int (device_pm_control)(struct device device, u32_t command,
	void context, device_pm_cb cb, void arg);
	struct device_pm *pm;
	#endif
	const void *config_info;
	};

	/**
	* @brief Runtime device structure (In memory) Per driver instance
	* @param device_config Build time config information
	* @param driver_api pointer to structure containing the API functions for
	* the device type. This pointer is filled in by the driver at init time.
	* @param driver_data driver instance data. For driver use only
	*/
	struct device {
	struct device_config *config;
	const void *driver_api;
	void *driver_data;
	#if defined(__x86_64) && __SIZEOF_POINTER__ == 4
	/* The x32 ABI hits an edge case. This is a 12 byte struct,
	* but the x86_64 linker will pack them only in units of 8
	* bytes, leading to alignment problems when iterating over
	* the link-time array.
	*/
	void *padding;
	#endif
	};

	void z_sys_device_do_config_level(s32_t level);

	/**
	* @brief Retrieve the device structure for a driver by name
	*
	* @details Device objects are created via the DEVICE_INIT() macro and
	* placed in memory by the linker. If a driver needs to bind to another driver
	* it can use this function to retrieve the device structure of the lower level
	* driver by the name the driver exposes to the system.
	*
	* @param name device name to search for.
	*
	* @return pointer to device structure; NULL if not found or cannot be used.
	*/
	__syscall struct device device_get_binding(const char name);

	/**
	* @}
	*/

	/**
	* @brief Device Power Management APIs
	* @defgroup device_power_management_api Device Power Management APIs
	* @ingroup power_management_api
	* @{
	*/

	#ifdef CONFIG_DEVICE_POWER_MANAGEMENT

	/** @def DEVICE_PM_ACTIVE_STATE
	*
	* @brief device is in ACTIVE power state
	*
	* @details Normal operation of the device. All device context is retained.
	*/
	#define DEVICE_PM_ACTIVE_STATE 1

	/** @def DEVICE_PM_LOW_POWER_STATE
	*
	* @brief device is in LOW power state
	*
	* @details Device context is preserved by the HW and need not be
	* restored by the driver.
	*/
	#define DEVICE_PM_LOW_POWER_STATE 2

	/** @def DEVICE_PM_SUSPEND_STATE
	*
	* @brief device is in SUSPEND power state
	*
	* @details Most device context is lost by the hardware.
	* Device drivers must save and restore or reinitialize any context
	* lost by the hardware
	*/
	#define DEVICE_PM_SUSPEND_STATE 3

	/** @def DEVICE_PM_FORCE_SUSPEND_STATE
	*
	* @brief device is in force SUSPEND power state
	*
	* @details Driver puts the device in suspended state after
	* completing the ongoing transactions and will not process any
	* queued work or will not take any new requests for processing.
	* Most device context is lost by the hardware. Device drivers must
	* save and restore or reinitialize any context lost by the hardware.
	*/
	#define DEVICE_PM_FORCE_SUSPEND_STATE 4

	/** @def DEVICE_PM_OFF_STATE
	*
	* @brief device is in OFF power state
	*
	* @details - Power has been fully removed from the device.
	* The device context is lost when this state is entered, so the OS
	* software will reinitialize the device when powering it back on
	*/
	#define DEVICE_PM_OFF_STATE 5

	/* Constants defining support device power commands */
	#define DEVICE_PM_SET_POWER_STATE 1
	#define DEVICE_PM_GET_POWER_STATE 2

	#endif /* CONFIG_DEVICE_POWER_MANAGEMENT */

	/**
	* @brief Indicate that the device is in the middle of a transaction
	*
	* Called by a device driver to indicate that it is in the middle of a
	* transaction.
	*
	* @param busy_dev Pointer to device structure of the driver instance.
	*/
	void device_busy_set(struct device *busy_dev);

	/**
	* @brief Indicate that the device has completed its transaction
	*
	* Called by a device driver to indicate the end of a transaction.
	*
	* @param busy_dev Pointer to device structure of the driver instance.
	*/
	void device_busy_clear(struct device *busy_dev);

	#ifdef CONFIG_DEVICE_POWER_MANAGEMENT
	/*
	* Device PM functions
	*/

	/**
	* @brief No-op function to initialize unimplemented hook
	*
	* This function should be used to initialize device hook
	* for which a device has no PM operations.
	*
	* @param unused_device Unused
	* @param unused_ctrl_command Unused
	* @param unused_context Unused
	* @param cb Unused
	* @param unused_arg Unused
	*
	* @retval 0 Always returns 0
	*/
	int device_pm_control_nop(struct device *unused_device,
	u32_t unused_ctrl_command,
	void *unused_context,
	device_pm_cb cb,
	void *unused_arg);
	/**
	* @brief Call the set power state function of a device
	*
	* Called by the application or power management service to let the device do
	* required operations when moving to the required power state
	* Note that devices may support just some of the device power states
	* @param device Pointer to device structure of the driver instance.
	* @param device_power_state Device power state to be set
	* @param cb Callback function to notify device power status
	* @param arg Caller passed argument to callback function
	*
	* @retval 0 If successful in queuing the request or changing the state.
	* @retval Errno Negative errno code if failure. Callback will not be called.
	*/
	static inline int device_set_power_state(struct device *device,
	u32_t device_power_state,
	device_pm_cb cb, void *arg)
	{
	return device->config->device_pm_control(device,
	DEVICE_PM_SET_POWER_STATE,
	&device_power_state, cb, arg);
	}

	/**
	* @brief Call the get power state function of a device
	*
	* This function lets the caller know the current device
	* power state at any time. This state will be one of the defined
	* power states allowed for the devices in that system
	*
	* @param device pointer to device structure of the driver instance.
	* @param device_power_state Device power state to be filled by the device
	*
	* @retval 0 If successful.
	* @retval Errno Negative errno code if failure.
	*/
	static inline int device_get_power_state(struct device *device,
	u32_t *device_power_state)
	{
	return device->config->device_pm_control(device,
	DEVICE_PM_GET_POWER_STATE,
	device_power_state,
	NULL, NULL);
	}

	/**
	* @brief Gets the device structure list array and device count
	*
	* Called by the Power Manager application to get the list of
	* device structures associated with the devices in the system.
	* The PM app would use this list to create its own sorted list
	* based on the order it wishes to suspend or resume the devices.
	*
	* @param device_list Pointer to receive the device list array
	* @param device_count Pointer to receive the device count
	*/
	void device_list_get(struct device *device_list, int device_count);

	/**
	* @brief Check if any device is in the middle of a transaction
	*
	* Called by an application to see if any device is in the middle
	* of a critical transaction that cannot be interrupted.
	*
	* @retval 0 if no device is busy
	* @retval -EBUSY if any device is busy
	*/
	int device_any_busy_check(void);

	/**
	* @brief Check if a specific device is in the middle of a transaction
	*
	* Called by an application to see if a particular device is in the
	* middle of a critical transaction that cannot be interrupted.
	*
	* @param chk_dev Pointer to device structure of the specific device driver
	* the caller is interested in.
	* @retval 0 if the device is not busy
	* @retval -EBUSY if the device is busy
	*/
	int device_busy_check(struct device *chk_dev);

	#ifdef CONFIG_DEVICE_IDLE_PM

	/* Device PM FSM states */
	enum device_pm_fsm_state {
	DEVICE_PM_FSM_STATE_ACTIVE = 1,
	DEVICE_PM_FSM_STATE_SUSPENDED,
	DEVICE_PM_FSM_STATE_SUSPENDING,
	DEVICE_PM_FSM_STATE_RESUMING,
	};

	/**
	* @brief Enable device idle PM
	*
	* Called by a device driver to enable device idle power management.
	* The device might be asynchronously suspended if Idle PM is enabled
	* when the device is not use.
	*
	* @param dev Pointer to device structure of the specific device driver
	* the caller is interested in.
	*/
	void device_pm_enable(struct device *dev);

	/**
	* @brief Disable device idle PM
	*
	* Called by a device driver to disable device idle power management.
	* The device might be asynchronously resumed if Idle PM is disabled
	*
	* @param dev Pointer to device structure of the specific device driver
	* the caller is interested in.
	*/
	void device_pm_disable(struct device *dev);

	/**
	* @brief Call device resume asynchronously based on usage count
	*
	* Called by a device driver to mark the device as being used.
	* This API will asynchronously bring the device to resume state
	* if it not already in active state.
	*
	* @param dev Pointer to device structure of the specific device driver
	* the caller is interested in.
	* @retval 0 If successfully queued the Async request. If queued,
	* the caller need to wait on the poll event linked to device
	* pm signal mechanism to know the completion of resume operation.
	* @retval Errno Negative errno code if failure.
	*/
	int device_pm_get(struct device *dev);

	/**
	* @brief Call device resume synchronously based on usage count
	*
	* Called by a device driver to mark the device as being used. It
	* will bring up or resume the device if it is in suspended state
	* based on the device usage count. This call is blocked until the
	* device PM state is changed to resume.
	*
	* @param dev Pointer to device structure of the specific device driver
	* the caller is interested in.
	* @retval 0 If successful.
	* @retval Errno Negative errno code if failure.
	*/
	int device_pm_get_sync(struct device *dev);

	/**
	* @brief Call device suspend asynchronously based on usage count
	*
	* Called by a device driver to mark the device as being released.
	* This API asynchronously put the device to suspend state if
	* it not already in suspended state.
	*
	* @param dev Pointer to device structure of the specific device driver
	* the caller is interested in.
	* @retval 0 If successfully queued the Async request. If queued,
	* the caller need to wait on the poll event linked to device pm
	* signal mechanism to know the completion of suspend operation.
	* @retval Errno Negative errno code if failure.
	*/
	int device_pm_put(struct device *dev);

	/**
	* @brief Call device suspend synchronously based on usage count
	*
	* Called by a device driver to mark the device as being released. It
	* will put the device to suspended state if is is in active state
	* based on the device usage count. This call is blocked until the
	* device PM state is changed to resume.
	*
	* @param dev Pointer to device structure of the specific device driver
	* the caller is interested in.
	* @retval 0 If successful.
	* @retval Errno Negative errno code if failure.
	*/
	int device_pm_put_sync(struct device *dev);
	#else
	static inline void device_pm_enable(struct device *dev) { }
	static inline void device_pm_disable(struct device *dev) { }
	static inline int device_pm_get(struct device *dev) { return -ENOTSUP; }
	static inline int device_pm_get_sync(struct device *dev) { return -ENOTSUP; }
	static inline int device_pm_put(struct device *dev) { return -ENOTSUP; }
	static inline int device_pm_put_sync(struct device *dev) { return -ENOTSUP; }
	#endif

	#endif

	/**
	* @}
	*/

	#include <syscalls/device.h>

	#ifdef __cplusplus
	}
	#endif
	#endif /* ZEPHYR_INCLUDE_DEVICE_H_ */