/* * Copyright (c) 2015 Intel Corporation. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef _DEVICE_H_ #define _DEVICE_H_ #include /** * @brief Device Driver APIs * @defgroup io_interfaces Device Driver APIs * @{ * @} */ /** * @brief Device Model APIs * @defgroup device_model Device Model APIs * @{ */ #ifdef __cplusplus extern "C" { #endif /** * @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. * * @param dev_name Device name. * * @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: * * PRIMARY: 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. * * SECONDARY: Used for devices that rely on the initialization of devices * initialized as part of the PRIMARY level. These devices cannot use any * kernel services during configuration, since they are not yet available. * * NANOKERNEL: Used for devices that require nanokernel services during * configuration. * * MICROKERNEL: Used for devices that require microkernel services during * configuration. * * 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). */ #ifndef CONFIG_DEVICE_POWER_MANAGEMENT #define DEVICE_INIT(dev_name, drv_name, init_fn, data, cfg_info, level, prio) \ \ static struct device_config __config_##dev_name __used \ __attribute__((__section__(".devconfig.init"))) = { \ .name = drv_name, .init = (init_fn), \ .config_info = (cfg_info) \ }; \ \ static struct device (__device_##dev_name) __used \ __attribute__((__section__(".init_" #level STRINGIFY(prio)))) = { \ .config = &(__config_##dev_name), \ .driver_data = data \ } #else /** * @def DEVICE_INIT_PM * * @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. * * @param dev_name Device name. * * @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 device_pm_ops Address to the device_pm_ops structure 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: * * PRIMARY: 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. * * SECONDARY: Used for devices that rely on the initialization of devices * initialized as part of the PRIMARY level. These devices cannot use any * kernel services during configuration, since they are not yet available. * * NANOKERNEL: Used for devices that require nanokernel services during * configuration. * * MICROKERNEL: Used for devices that require microkernel services during * configuration. * * 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_PM(dev_name, drv_name, init_fn, device_pm_ops, \ data, cfg_info, level, prio) \ \ static struct device_config __config_##dev_name __used \ __attribute__((__section__(".devconfig.init"))) = { \ .name = drv_name, .init = (init_fn), \ .dev_pm_ops = (device_pm_ops), \ .config_info = (cfg_info) \ }; \ \ static struct device (__device_##dev_name) __used \ __attribute__((__section__(".init_" #level STRINGIFY(prio)))) = { \ .config = &(__config_##dev_name), \ .driver_data = data \ } /* * Create a default device_pm_ops for devices that do not call the * DEVICE_INIT_PM macro so that caller of hook functions * need not check dev_pm_ops != NULL. */ extern struct device_pm_ops device_pm_ops_nop; #define DEVICE_INIT(dev_name, drv_name, init_fn, data, cfg_info, level, prio) \ DEVICE_INIT_PM(dev_name, drv_name, init_fn, \ &device_pm_ops_nop, data, cfg_info, \ level, prio) #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 exanded 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 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(), or reference the device in another C file. * * 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 dependeny. * * @param name Device name */ #define DEVICE_DECLARE(name) extern struct device DEVICE_NAME_GET(name) /* * DEPRECATED. * * DEV_* error codes are deprecated. Use error codes from errno.h instead. */ #define DEV_OK 0 /* No error */ #define DEV_FAIL (-EIO) /* General operation failure */ #define DEV_INVALID_OP (-ENOTSUP) /* Invalid operation */ #define DEV_INVALID_CONF (-EINVAL) /* Invalid configuration */ #define DEV_USED (-EBUSY) /* Device controller in use */ #define DEV_NO_ACCESS (-EACCES) /* Controller not accessible */ #define DEV_NO_SUPPORT (-ENODEV) /* Device type not supported */ #define DEV_NOT_CONFIG (-EPERM) /* Device not configured */ struct device; #ifdef CONFIG_DEVICE_POWER_MANAGEMENT struct device_pm_ops { int (*suspend)(struct device *device, int pm_policy); int (*resume)(struct device *device, int pm_policy); }; #endif /** * @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 { char *name; int (*init)(struct device *device); #ifdef CONFIG_DEVICE_POWER_MANAGEMENT struct device_pm_ops *dev_pm_ops; #endif 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 river instance data. For driver use only */ struct device { struct device_config *config; void *driver_api; void *driver_data; }; void _sys_device_do_config_level(int level); struct device* device_get_binding(char *name); #ifdef CONFIG_DEVICE_POWER_MANAGEMENT /** * Device PM functions */ /** * @brief No-op function to initialize unimplemented pm hooks * * This function should be used to initialize device pm hooks * for which a device has no operation. * * @param unused_device * @param unused_policy * * @retval Always returns 0 */ int device_pm_nop(struct device *unused_device, int unused_policy); /** * @brief Call the suspend function of a device * * Called by the Power Manager application to let the device do * any policy based PM suspend operations. * * @param device Pointer to device structure of the driver instance. * @param pm_policy PM policy for which this call is made. * * @retval 0 If successful. * @retval -EBUSY If device is busy * @retval Other negative errno code if failure. */ static inline int device_suspend(struct device *device, int pm_policy) { return device->config->dev_pm_ops->suspend(device, pm_policy); } /** * @brief Call the resume function of a device * * Called by the Power Manager application to let the device do * any policy based PM resume operations. * * @param device Pointer to device structure of the driver instance. * @param pm_policy PM policy for which this call is made. * * @retval 0 If successful. * @retval Negative errno code if failure. */ static inline int device_resume(struct device *device, int pm_policy) { return device->config->dev_pm_ops->resume(device, pm_policy); } /** * @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); #endif /** * Synchronous calls API */ #include #include #ifdef CONFIG_MICROKERNEL #include #endif #ifdef CONFIG_MICROKERNEL enum device_sync_waiter { DEVICE_SYNC_WAITER_NONE, DEVICE_SYNC_WAITER_FIBER, DEVICE_SYNC_WAITER_TASK, }; #endif /** * Specific type for synchronizing calls among the 2 possible contexts */ typedef struct { /** Nanokernel semaphore used for fiber context */ struct nano_sem f_sem; #ifdef CONFIG_MICROKERNEL /** Microkernel semaphore used for task context */ struct _k_sem_struct _t_sem; ksem_t t_sem; enum device_sync_waiter waiter; bool device_ready; #endif } device_sync_call_t; /** * @brief Initialize the context-dependent synchronization data * * @param sync A pointer to a valid device_sync_call_t */ static inline void device_sync_call_init(device_sync_call_t *sync) { nano_sem_init(&sync->f_sem); #ifdef CONFIG_MICROKERNEL sync->_t_sem.waiters = NULL; sync->_t_sem.level = sync->_t_sem.count = 0; sync->t_sem = (ksem_t)&sync->_t_sem; sync->waiter = DEVICE_SYNC_WAITER_NONE; sync->device_ready = false; #endif } #ifdef CONFIG_MICROKERNEL /* * The idle task cannot block and is used during boot, and thus polls a * nanokernel semaphore instead of waiting on a microkernel semaphore. */ static inline bool _is_blocking_task(void) { bool is_task = sys_execution_context_type_get() == NANO_CTX_TASK; bool is_idle_task = task_priority_get() == (CONFIG_NUM_TASK_PRIORITIES - 1); return is_task && !is_idle_task; } /** * @brief Wait for the isr to complete the synchronous call * Note: In a microkernel built this function will take care of the caller * context and thus use the right attribute to handle the synchronization. * * @param sync A pointer to a valid device_sync_call_t */ static inline void device_sync_call_wait(device_sync_call_t *sync) { /* protect the state of device_ready and waiter fields */ int key = irq_lock(); if (sync->device_ready) { sync->device_ready = false; /* * If device_ready was set, the waiter field had to be NONE, so we * don't have to reset it. */ irq_unlock(key); return; } if (_is_blocking_task()) { sync->waiter = DEVICE_SYNC_WAITER_TASK; irq_unlock(key); task_sem_take(sync->t_sem, TICKS_UNLIMITED); } else { sync->waiter = DEVICE_SYNC_WAITER_FIBER; irq_unlock(key); nano_sem_take(&sync->f_sem, TICKS_UNLIMITED); } sync->waiter = DEVICE_SYNC_WAITER_NONE; /* if we get here, device_ready was not set: we don't have to reset it */ } /** * @brief Signal the waiter about synchronization completion * Note: In a microkernel built this function will take care of the waiter * context and thus use the right attribute to signale the completion. * * @param sync A pointer to a valid device_sync_call_t */ static inline void device_sync_call_complete(device_sync_call_t *sync) { static void (*func[3])(ksem_t sema) = { isr_sem_give, fiber_sem_give, task_sem_give }; /* protect the state of device_ready and waiter fields */ int key = irq_lock(); if (sync->waiter == DEVICE_SYNC_WAITER_NONE) { sync->device_ready = true; irq_unlock(key); return; } /* * It's safe to unlock interrupts here since we know there was a waiter, * and only one thread is allowed to wait on the object, so the state of * waiter will not change and the device_ready flag will not get set. */ irq_unlock(key); if (sync->waiter == DEVICE_SYNC_WAITER_TASK) { func[sys_execution_context_type_get()](sync->t_sem); } else /* fiber */ { nano_sem_give(&sync->f_sem); } } #else /** * @brief Wait for the isr to complete the synchronous call * Note: It will simply wait on the internal semaphore. * * @param sync A pointer to a valid device_sync_call_t */ static inline void device_sync_call_wait(device_sync_call_t *sync) { nano_sem_take(&sync->f_sem, TICKS_UNLIMITED); } /** * @brief Signal the waiter about synchronization completion * Note: It will simply release the internal semaphore * * @param sync A pointer to a valid device_sync_call_t */ static inline void device_sync_call_complete(device_sync_call_t *sync) { nano_sem_give(&sync->f_sem); } #endif /* CONFIG_MICROKERNEL || CONFIG_NANOKERNEL */ #ifdef __cplusplus } #endif /** * @} */ #endif /* _DEVICE_H_ */