/** * Copyright (c) 2016 - 2019, Nordic Semiconductor ASA * * All rights reserved. * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * 2. Redistributions in binary form, except as embedded into a Nordic * Semiconductor ASA integrated circuit in a product or a software update for * such product, must reproduce the above copyright notice, this list of * conditions and the following disclaimer in the documentation and/or other * materials provided with the distribution. * * 3. Neither the name of Nordic Semiconductor ASA nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. * * 4. This software, with or without modification, must only be used with a * Nordic Semiconductor ASA integrated circuit. * * 5. Any software provided in binary form under this license must not be reverse * engineered, decompiled, modified and/or disassembled. * * THIS SOFTWARE IS PROVIDED BY NORDIC SEMICONDUCTOR ASA "AS IS" AND ANY EXPRESS * OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY, NONINFRINGEMENT, AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL NORDIC SEMICONDUCTOR ASA OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE * GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * */ #include "sdk_common.h" #if NRF_MODULE_ENABLED(APP_USBD) #include "app_usbd.h" #include "app_usbd_core.h" #include "app_usbd_request.h" #include "nrf_power.h" #include "nrf_drv_clock.h" #include "nrf_drv_power.h" #if APP_USBD_CONFIG_EVENT_QUEUE_ENABLE #include "nrf_atfifo.h" #include "nrf_atomic.h" #endif #define NRF_LOG_MODULE_NAME app_usbd #if APP_USBD_CONFIG_LOG_ENABLED #define NRF_LOG_LEVEL APP_USBD_CONFIG_LOG_LEVEL #define NRF_LOG_INFO_COLOR APP_USBD_CONFIG_INFO_COLOR #define NRF_LOG_DEBUG_COLOR APP_USBD_CONFIG_DEBUG_COLOR #else //APP_USBD_CONFIG_LOG_ENABLED #define NRF_LOG_LEVEL 0 #endif //APP_USBD_CONFIG_LOG_ENABLED #include "nrf_log.h" NRF_LOG_MODULE_REGISTER(); /* Base variables tests */ /* Check event of app_usbd_event_type_t enumerator */ STATIC_ASSERT((int32_t)APP_USBD_EVT_FIRST_POWER == (int32_t)NRF_DRV_USBD_EVT_CNT); STATIC_ASSERT(sizeof(app_usbd_event_type_t) == sizeof(nrf_drv_usbd_event_type_t)); STATIC_ASSERT(sizeof(app_usbd_descriptor_header_t) == 2); STATIC_ASSERT(sizeof(app_usbd_descriptor_device_t) == 18); STATIC_ASSERT(sizeof(app_usbd_descriptor_configuration_t) == 9); STATIC_ASSERT(sizeof(app_usbd_descriptor_iface_t) == 9); STATIC_ASSERT(sizeof(app_usbd_descriptor_ep_t) == 7); STATIC_ASSERT(sizeof(app_usbd_descriptor_iad_t) == 8); STATIC_ASSERT(sizeof(app_usbd_setup_t) == sizeof(nrf_drv_usbd_setup_t)); /** * @internal * @defgroup app_usbd_internals USBD library internals * @ingroup app_usbd * * Internal variables, auxiliary macros and functions of USBD library. * @{ */ #if (APP_USBD_PROVIDE_SOF_TIMESTAMP) || defined(__SDK_DOXYGEN__) /** * @brief The last received frame number. */ static uint16_t m_last_frame; #endif /** * @brief Variable type for endpoint configuration. * * Each endpoint would have assigned this type of configuration structure. */ typedef struct { /** * @brief The class instance. * * The pointer to the class instance that is connected to the endpoint. */ app_usbd_class_inst_t const * p_cinst; /** * @brief Endpoint event handler. * * Event handler for the endpoint. * It is set to event handler for the class instance during connection by default, * but it can be then updated for as a reaction for @ref APP_USBD_EVT_ATTACHED event. * This way we can speed up the interpretation of endpoint related events. */ app_usbd_ep_event_handler_t event_handler; }app_usbd_ep_conf_t; /** * @brief Internal event with SOF counter. */ typedef struct { app_usbd_internal_evt_t evt; //!< Internal event type #if (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) \ || defined(__SDK_DOXYGEN__) uint16_t sof_cnt; //!< Number of the SOF events that appears before current event uint16_t start_frame; //!< Number of the SOF frame that starts this event #endif // (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) } app_usbd_internal_queue_evt_t; #if (APP_USBD_CONFIG_EVENT_QUEUE_ENABLE) || defined(__SDK_DOXYGEN__) /** * @brief Event queue. * * The queue with events to be processed. */ NRF_ATFIFO_DEF(m_event_queue, app_usbd_internal_queue_evt_t, APP_USBD_CONFIG_EVENT_QUEUE_SIZE); #if (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) \ || defined(__SDK_DOXYGEN__) /** @brief SOF events counter */ static nrf_atomic_u32_t m_sof_events_cnt; /** @brief SOF Frame counter */ static uint16_t m_event_frame; /* Limit of SOF events stacked until warning message. */ #define APP_USBD_SOF_WARNING_LIMIT 500 #endif // (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) // || defined(__SDK_DOXYGEN__) #endif /** * @brief Instances connected with IN endpoints. * * Array of instance pointers connected with every IN endpoint. * @sa m_epout_instances */ static app_usbd_ep_conf_t m_epin_conf[NRF_USBD_EPIN_CNT]; /** * @brief Instances connected with OUT endpoints. * * Array of instance pointers connected with every OUT endpoint. * @sa m_epin_instances */ static app_usbd_ep_conf_t m_epout_conf[NRF_USBD_EPIN_CNT]; /** * @brief Beginning of classes list. * * All enabled in current configuration instances are connected into * a single linked list chain. * This variable points to first element. * Core class instance (connected to endpoint 0) is not listed here. */ static app_usbd_class_inst_t const * m_p_first_cinst; /** * @brief Classes list that requires SOF events. * * Pointer to first class that requires SOF events. */ static app_usbd_class_inst_t const * m_p_first_sof_cinst; /** * @brief Classes list that require SOF events in interrupt. * * Pointer to first class that requires SOF events in interrupt. */ static app_usbd_class_inst_t const * m_p_first_sof_interrupt_cinst; /** * @brief Default configuration (when NULL is passed to @ref app_usbd_init). */ static const app_usbd_config_t m_default_conf = { #if (!(APP_USBD_CONFIG_EVENT_QUEUE_ENABLE)) || defined(__SDK_DOXYGEN__) .ev_handler = app_usbd_event_execute, #endif #if (APP_USBD_CONFIG_EVENT_QUEUE_ENABLE) || defined(__SDK_DOXYGEN__) .ev_isr_handler = NULL, #endif .ev_state_proc = NULL, .enable_sof = false }; /** * @brief SUSPEND state machine states. * * The enumeration of internal SUSPEND state machine states. */ typedef enum { SUSTATE_STOPPED, /**< The USB driver was not started */ SUSTATE_STARTED, /**< The USB driver was started - waiting for USB RESET */ SUSTATE_ACTIVE, /**< Active state */ SUSTATE_SUSPENDING, /**< Suspending - waiting for the user to acknowledge */ SUSTATE_SUSPEND, /**< Suspended */ SUSTATE_RESUMING, /**< Resuming - waiting for clock */ SUSTATE_WAKINGUP_WAITING_HFCLK_WREQ, /**< Waking up - waiting for clock and WUREQ from driver */ SUSTATE_WAKINGUP_WAITING_HFCLK, /**< Waking up - waiting for HFCLK (WUREQ detected) */ SUSTATE_WAKINGUP_WAITING_WREQ, /**< Waking up - waiting for WREQ (HFCLK active) */ }app_usbd_sustate_t; /** * @brief Current suspend state. * * The state of the suspend state machine. */ static app_usbd_sustate_t m_sustate; /** * @brief Remote wake-up register/unregister. * * Counter incremented when appended instance required remote wake-up functionality. * It should be decremented when the class is removed. * When this counter is not zero, remote wake-up functionality is activated inside core. */ static uint8_t m_rwu_registered_counter; /** * @brief Current configuration. */ static app_usbd_config_t m_current_conf; /** * @brief Class interface call: event handler * * @ref app_usbd_class_interface_t::event_handler * * @param[in] p_cinst Class instance. * @param[in] p_event Event passed to class instance. * * @return Standard error code @ref ret_code_t * @retval NRF_SUCCESS event handled successfully. * @retval NRF_ERROR_NOT_SUPPORTED unsupported event. * */ static inline ret_code_t class_event_handler(app_usbd_class_inst_t const * const p_cinst, app_usbd_complex_evt_t const * const p_event) { ASSERT(p_cinst != NULL); ASSERT(p_cinst->p_class_methods != NULL); ASSERT(p_cinst->p_class_methods->event_handler != NULL); return p_cinst->p_class_methods->event_handler(p_cinst, p_event); } #if (APP_USBD_CONFIG_EVENT_QUEUE_ENABLE) || defined(__SDK_DOXYGEN__) static inline void class_sof_interrupt_handler(app_usbd_class_inst_t const * const p_cinst, app_usbd_complex_evt_t const * const p_event) { ASSERT(p_cinst != NULL); ASSERT(p_cinst->p_data != NULL); ASSERT(p_cinst->p_data->sof_handler != NULL); p_cinst->p_data->sof_handler(p_event->drv_evt.data.sof.framecnt); } /** * @brief User event handler call (passed via configuration). * * @param p_event Handler of an event that is going to be added into queue. * @param queued The event is visible in the queue. */ static inline void user_event_handler(app_usbd_internal_evt_t const * const p_event, bool queued) { if ((m_current_conf.ev_isr_handler) != NULL) { m_current_conf.ev_isr_handler(p_event, queued); } } #endif /** * @brief User event processor call (passed via configuration). * * @param event Event type. */ static inline void user_event_state_proc(app_usbd_event_type_t event) { if ((m_current_conf.ev_state_proc) != NULL) { m_current_conf.ev_state_proc(event); } } /** * @brief Find a specified descriptor. * * @param[in] p_cinst Class instance. * @param[in] desc_type Descriptor type @ref app_usbd_descriptor_t * @param[in] desc_index Descriptor index. * @param[out] p_desc Pointer to escriptor. * @param[out] p_desc_len Length of descriptor. * * @return Standard error code @ref ret_code_t * @retval NRF_SUCCESS Descriptor successfully found. * @retval NRF_ERROR_NOT_FOUND Descriptor not found. * */ ret_code_t app_usbd_class_descriptor_find(app_usbd_class_inst_t const * const p_cinst, uint8_t desc_type, uint8_t desc_index, uint8_t * p_desc, size_t * p_desc_len) { app_usbd_class_descriptor_ctx_t siz; APP_USBD_CLASS_DESCRIPTOR_INIT(&siz); uint32_t total_size = 0; while(p_cinst->p_class_methods->feed_descriptors(&siz, p_cinst, NULL, sizeof(uint8_t))) { total_size++; } uint8_t cur_len = 0; uint32_t cur_size = 0; uint8_t index = 0; app_usbd_class_descriptor_ctx_t descr; APP_USBD_CLASS_DESCRIPTOR_INIT(&descr); while(cur_size < total_size) { /* First byte of a descriptor is its size */ UNUSED_RETURN_VALUE(p_cinst->p_class_methods->feed_descriptors(&descr, p_cinst, &cur_len, sizeof(uint8_t))); /* Second byte is type of the descriptor */ uint8_t type; UNUSED_RETURN_VALUE(p_cinst->p_class_methods->feed_descriptors(&descr, p_cinst, &type, sizeof(uint8_t))); if(type == desc_type) { if(index == desc_index) { /* Copy the length of descriptor to *p_desc_len */ *p_desc_len = cur_len; /* Two first bytes of descriptor have already been fed - copy them to *p_desc */ *p_desc++ = cur_len; *p_desc++ = desc_type; /* Copy the rest of descriptor to *p_desc */ UNUSED_RETURN_VALUE(p_cinst->p_class_methods->feed_descriptors(&descr, p_cinst, p_desc, cur_len-2)); return NRF_SUCCESS; } else { index++; } } /* Fast-forward through unmatched descriptor */ UNUSED_RETURN_VALUE(p_cinst->p_class_methods->feed_descriptors(&descr, p_cinst, NULL, cur_len-2)); cur_size += cur_len; } return NRF_ERROR_NOT_FOUND; } /** * @brief Access into selected endpoint configuration structure. * * @param ep Endpoint address. * @return A pointer to the endpoint configuration structure. * * @note This function would assert when endpoint number is not correct and debugging is enabled. */ static app_usbd_ep_conf_t * app_usbd_ep_conf_access(nrf_drv_usbd_ep_t ep) { if (NRF_USBD_EPIN_CHECK(ep)) { uint8_t nr = NRF_USBD_EP_NR_GET(ep); ASSERT(nr < NRF_USBD_EPIN_CNT); return &m_epin_conf[nr]; } else { uint8_t nr = NRF_USBD_EP_NR_GET(ep); ASSERT(nr < NRF_USBD_EPOUT_CNT); return &m_epout_conf[nr]; } } /** * @brief Accessing instance connected with selected endpoint. * * @param ep Endpoint number. * * @return The pointer to the instance connected with endpoint. */ static inline app_usbd_class_inst_t const * app_usbd_ep_instance_get(nrf_drv_usbd_ep_t ep) { return app_usbd_ep_conf_access(ep)->p_cinst; } /** * @brief Connect instance with selected endpoint. * * This function configures instance connected to endpoint but also sets * default event handler function pointer. * * @param ep Endpoint number. * @param p_cinst The instance to connect into the selected endpoint. * NULL if endpoint is going to be disconnected. * * @note Disconnecting EP0 is not allowed and protected by assertion. */ static void app_usbd_ep_instance_set(nrf_drv_usbd_ep_t ep, app_usbd_class_inst_t const * p_cinst) { app_usbd_ep_conf_t * p_ep_conf = app_usbd_ep_conf_access(ep); /* Set instance and default event handler */ p_ep_conf->p_cinst = p_cinst; if (p_cinst == NULL) { ASSERT((ep != NRF_DRV_USBD_EPOUT0) && (ep != NRF_DRV_USBD_EPIN0)); /* EP0 should never be disconnected */ p_ep_conf->event_handler = NULL; } else { p_ep_conf->event_handler = p_cinst->p_class_methods->event_handler; } } /** * @brief Call the core handler. * * Core instance is special kind of instance that is connected only to endpoint 0. * It is not present in instance list. * This auxiliary function makes future changes easier. * Just call the event instance for core module here. */ static inline ret_code_t app_usbd_core_handler_call(app_usbd_internal_evt_t const * const p_event) { return m_epout_conf[0].event_handler( m_epout_conf[0].p_cinst, (app_usbd_complex_evt_t const *)p_event); } /** * @brief Add event for execution. * * Dependent on configuration event would be executed in place or would be added into queue * to be executed later. * * @param p_event_input Event to be executed. */ static inline void app_usbd_event_add(app_usbd_internal_evt_t const * const p_event_input) { app_usbd_internal_evt_t const * p_event = p_event_input; if (p_event->type == APP_USBD_EVT_DRV_SETUP) { uint8_t bRequest = nrf_usbd_setup_brequest_get(); uint8_t bmRequestType = nrf_usbd_setup_bmrequesttype_get(); if ((bmRequestType == app_usbd_setup_req_val( APP_USBD_SETUP_REQREC_DEVICE, APP_USBD_SETUP_REQTYPE_STD, APP_USBD_SETUP_REQDIR_OUT)) && (bRequest == APP_USBD_SETUP_STDREQ_SET_ADDRESS)) { static const app_usbd_internal_evt_t event_setaddress = { .type = APP_USBD_EVT_SETUP_SETADDRESS, }; p_event = &event_setaddress; } } #if (APP_USBD_CONFIG_EVENT_QUEUE_ENABLE) if (p_event->app_evt.type == APP_USBD_EVT_DRV_SOF) { /* Propagate SOF event to classes that need it in interrupt */ app_usbd_class_inst_t const * p_inst = app_usbd_class_sof_interrupt_first_get(); while (NULL != p_inst) { class_sof_interrupt_handler(p_inst, (app_usbd_complex_evt_t const *)p_event); p_inst = app_usbd_class_sof_interrupt_next_get(p_inst); } #if (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) CRITICAL_REGION_ENTER(); if (m_sof_events_cnt == 0) { m_event_frame = p_event->drv_evt.data.sof.framecnt; } UNUSED_RETURN_VALUE(nrf_atomic_u32_add(&m_sof_events_cnt, 1)); CRITICAL_REGION_EXIT(); user_event_handler(p_event, true); if (m_sof_events_cnt == APP_USBD_SOF_WARNING_LIMIT) { NRF_LOG_WARNING("Stacked over %d SOF events.", APP_USBD_SOF_WARNING_LIMIT); } return; #endif // (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) #if (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_INTERRUPT) user_event_handler(p_event, false); app_usbd_event_execute(p_event); return; #endif // (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_INTERRUPT) } nrf_atfifo_item_put_t cx; app_usbd_internal_queue_evt_t * p_event_item = nrf_atfifo_item_alloc(m_event_queue, &cx); if (NULL != p_event_item) { bool visible; p_event_item->evt = *p_event; #if (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) CRITICAL_REGION_ENTER(); p_event_item->start_frame = m_event_frame - m_sof_events_cnt + 1; p_event_item->sof_cnt = nrf_atomic_u32_fetch_store(&m_sof_events_cnt, 0); CRITICAL_REGION_EXIT(); #endif // (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) visible = nrf_atfifo_item_put(m_event_queue, &cx); user_event_handler(p_event, visible); } else { NRF_LOG_ERROR("Event queue full."); } #else m_current_conf.ev_handler(p_event); #endif } /** * @brief Power event handler. * * The function that pushes power events into the queue. * @param p_event Event from power driver to map into APP_USBD_EVT_POWER_ event. */ #if APP_USBD_CONFIG_POWER_EVENTS_PROCESS static void app_usbd_power_event_handler(nrf_drv_power_usb_evt_t event) { switch(event) { case NRF_DRV_POWER_USB_EVT_DETECTED: { static const app_usbd_internal_evt_t ev = { .type = APP_USBD_EVT_POWER_DETECTED }; app_usbd_event_add(&ev); break; } case NRF_DRV_POWER_USB_EVT_REMOVED: { static const app_usbd_internal_evt_t ev = { .type = APP_USBD_EVT_POWER_REMOVED }; app_usbd_event_add(&ev); break; } case NRF_DRV_POWER_USB_EVT_READY: { static const app_usbd_internal_evt_t ev = { .type = APP_USBD_EVT_POWER_READY }; app_usbd_event_add(&ev); break; } default: ASSERT(false); } } #endif /** * @brief Event handler. * * The function that pushes the event into the queue. * @param p_event Event to push. */ static void app_usbd_event_handler(nrf_drv_usbd_evt_t const * const p_event) { app_usbd_event_add((app_usbd_internal_evt_t const *)p_event); } /** * @brief HF clock ready event handler. * * Function that is called when high frequency clock is started. * * @param event Event type that comes from clock driver. */ static void app_usbd_hfclk_ready(nrf_drv_clock_evt_type_t event) { ASSERT(NRF_DRV_CLOCK_EVT_HFCLK_STARTED == event); static const app_usbd_evt_t evt_data = { .type = APP_USBD_EVT_HFCLK_READY }; app_usbd_event_add((app_usbd_internal_evt_t const * )&evt_data); } /** * @brief Check if the HFCLK was requested in selected suspend state machine state. * * * @param sustate State to be checked. * * @retval true High frequency clock was requested in selected state. * @retval false High frequency clock was released in selected state. */ static inline bool app_usbd_sustate_with_requested_hfclk(app_usbd_sustate_t sustate) { switch(sustate) { case SUSTATE_STOPPED: return false; case SUSTATE_STARTED: return false; case SUSTATE_ACTIVE: return true; case SUSTATE_SUSPENDING: return false; case SUSTATE_SUSPEND: return false; case SUSTATE_RESUMING: return true; case SUSTATE_WAKINGUP_WAITING_HFCLK_WREQ: return true; case SUSTATE_WAKINGUP_WAITING_HFCLK: return true; case SUSTATE_WAKINGUP_WAITING_WREQ: return true; default: return false; } } /** * @brief Check it the HFCLK is running in selected suspend state machine state. * * @param sustate State to be checked. * * @retval true High frequency clock is running in selected state. * @retval false High frequency clock is released in selected state. */ static inline bool app_usbd_sustate_with_running_hfclk(app_usbd_sustate_t sustate) { switch(sustate) { case SUSTATE_STOPPED: return false; case SUSTATE_STARTED: return false; case SUSTATE_ACTIVE: return true; case SUSTATE_SUSPENDING: return false; case SUSTATE_SUSPEND: return false; case SUSTATE_RESUMING: return false; case SUSTATE_WAKINGUP_WAITING_HFCLK_WREQ: return false; case SUSTATE_WAKINGUP_WAITING_HFCLK: return false; case SUSTATE_WAKINGUP_WAITING_WREQ: return true; default: return false; } } /** * @brief Get current suspend state machine state. * * @return The state of the suspend state machine. */ static inline app_usbd_sustate_t sustate_get(void) { return m_sustate; } /** * @brief Set current suspend state machine state. * * @param sustate The requested state of the state machine. */ static inline void sustate_set(app_usbd_sustate_t sustate) { if (app_usbd_sustate_with_requested_hfclk(sustate) != app_usbd_sustate_with_requested_hfclk(m_sustate)) { if (app_usbd_sustate_with_requested_hfclk(sustate)) { static nrf_drv_clock_handler_item_t clock_handler_item = { .event_handler = app_usbd_hfclk_ready }; nrf_drv_clock_hfclk_request(&clock_handler_item); } else { nrf_drv_clock_hfclk_release(); } } if (app_usbd_sustate_with_running_hfclk(sustate) != app_usbd_sustate_with_running_hfclk(m_sustate)) { if (app_usbd_sustate_with_running_hfclk(sustate)) { nrf_drv_usbd_active_irq_config(); } else { nrf_drv_usbd_suspend_irq_config(); } } m_sustate = sustate; } /** * @brief Default selection function for interface. * * This function just enables and clears interface endpoints. * * @param[in] p_inst Class instance. * @param[in] iface_idx Interface index. * @param[in] alternate Interface alternate setting. * * @note Currently only alternate setting 0 is supported. * * @return Standard error code @ref ret_code_t * @retval NRF_SUCCESS Endpoints enabled and cleared. * @retval NRF_ERROR_INVALID_PARAM Unsupported alternate selected. */ static inline ret_code_t default_iface_select( app_usbd_class_inst_t const * const p_inst, uint8_t iface_idx, uint8_t alternate) { ASSERT(iface_idx <= app_usbd_class_iface_count_get(p_inst)); if (alternate != 0) { return NRF_ERROR_INVALID_PARAM; } app_usbd_class_iface_conf_t const * p_iface = app_usbd_class_iface_get(p_inst, iface_idx); uint8_t ep_count = app_usbd_class_iface_ep_count_get(p_iface); for (uint8_t i = 0; i < ep_count; ++i) { /* Enable every endpoint */ app_usbd_class_ep_conf_t const * p_ep = app_usbd_class_iface_ep_get(p_iface, i); app_usbd_ep_enable(p_ep->address); } return NRF_SUCCESS; } /** * @brief Default deselection function for interface. * * This function just disables all interface endpoints. * * @param[in] p_inst Class instance. * @param[in] iface_idx Interface index. */ static inline void default_iface_deselect( app_usbd_class_inst_t const * const p_inst, uint8_t iface_idx) { ASSERT(iface_idx <= app_usbd_class_iface_count_get(p_inst)); app_usbd_class_iface_conf_t const * p_iface = app_usbd_class_iface_get(p_inst, iface_idx); uint8_t ep_count = app_usbd_class_iface_ep_count_get(p_iface); for (uint8_t i = 0; i < ep_count; ++i) { /* Disable every endpoint */ app_usbd_class_ep_conf_t const * p_ep = app_usbd_class_iface_ep_get(p_iface, i); app_usbd_ep_disable(p_ep->address); } } /** @} */ #if (APP_USBD_PROVIDE_SOF_TIMESTAMP) || defined(__SDK_DOXYGEN__) uint32_t app_usbd_sof_timestamp_get(void) { return m_last_frame; } #endif ret_code_t app_usbd_init(app_usbd_config_t const * p_config) { ASSERT(nrf_drv_clock_init_check()); ret_code_t ret; #if (APP_USBD_CONFIG_EVENT_QUEUE_ENABLE) || defined(__SDK_DOXYGEN__) ret = NRF_ATFIFO_INIT(m_event_queue); if (NRF_SUCCESS != ret) { return NRF_ERROR_INTERNAL; } #endif /* This is called at the beginning to secure multiple calls to init function */ ret = nrf_drv_usbd_init(app_usbd_event_handler); if (NRF_SUCCESS != ret) { return ret; } /* Clear the variables */ m_sustate = SUSTATE_STOPPED; m_p_first_cinst = NULL; m_p_first_sof_cinst = NULL; memset(m_epin_conf , 0, sizeof(m_epin_conf )); memset(m_epout_conf, 0, sizeof(m_epout_conf)); /* Save the new configuration */ if (p_config == NULL) { m_current_conf = m_default_conf; } else { m_current_conf = *p_config; } #if (!(APP_USBD_CONFIG_EVENT_QUEUE_ENABLE)) if(m_current_conf.ev_handler == NULL) { m_current_conf.ev_handler = m_default_conf.ev_handler; } #endif #if APP_USBD_CONFIG_POWER_EVENTS_PROCESS ret = nrf_drv_power_init(NULL); if ((ret != NRF_SUCCESS) && (ret != NRF_ERROR_MODULE_ALREADY_INITIALIZED)) { /* This should never happen */ APP_ERROR_HANDLER(ret); } #endif /*Pin core class to required endpoints*/ uint8_t iface_idx; app_usbd_class_iface_conf_t const * p_iface; app_usbd_class_inst_t const * const p_inst = app_usbd_core_instance_access(); iface_idx = 0; while ((p_iface = app_usbd_class_iface_get(p_inst, iface_idx++)) != NULL) { uint8_t ep_idx = 0; app_usbd_class_ep_conf_t const * p_ep; while ((p_ep = app_usbd_class_iface_ep_get(p_iface, ep_idx++)) != NULL) { app_usbd_ep_instance_set(app_usbd_class_ep_address_get(p_ep), p_inst); } } /* Successfully attached */ const app_usbd_evt_t evt_data = { .type = APP_USBD_EVT_INST_APPEND }; ret = class_event_handler(p_inst, (app_usbd_complex_evt_t const *)(&evt_data)); if (NRF_SUCCESS != ret) { UNUSED_RETURN_VALUE(nrf_drv_usbd_uninit()); return ret; } return NRF_SUCCESS; } ret_code_t app_usbd_uninit(void) { #if APP_USBD_CONFIG_POWER_EVENTS_PROCESS nrf_drv_power_usbevt_uninit(); #endif /* We get this error at very beginning but it would be used at the end of the function */ const ret_code_t ret = nrf_drv_usbd_uninit(); /* Unchain instance list */ app_usbd_class_inst_t const * * pp_inst; pp_inst = &m_p_first_cinst; while (NULL != (*pp_inst)) { app_usbd_class_inst_t const * * pp_next = &app_usbd_class_data_access(*pp_inst)->p_next; (*pp_inst) = NULL; pp_inst = pp_next; } /* Unchain SOF list */ pp_inst = &m_p_first_sof_cinst; while (NULL != (*pp_inst)) { app_usbd_class_inst_t const * * pp_next = &app_usbd_class_data_access(*pp_inst)->p_sof_next; (*pp_inst) = NULL; pp_inst = pp_next; } /* Unchain SOF interrupt list */ pp_inst = &m_p_first_sof_interrupt_cinst; while (NULL != (*pp_inst)) { app_usbd_class_inst_t const * * pp_next = &app_usbd_class_data_access(*pp_inst)->p_sof_next; (*pp_inst) = NULL; pp_inst = pp_next; } /* Clear all endpoints configurations */ memset(m_epin_conf , 0, sizeof(m_epin_conf )); memset(m_epout_conf, 0, sizeof(m_epout_conf)); /* Clear current configuration */ memset(&m_current_conf, 0, sizeof(m_current_conf)); return ret; } #if APP_USBD_CONFIG_POWER_EVENTS_PROCESS ret_code_t app_usbd_power_events_enable(void) { if (!nrf_drv_usbd_is_initialized() || nrf_drv_usbd_is_enabled()) { return NRF_ERROR_INVALID_STATE; } ASSERT((!APP_USBD_CONFIG_EVENT_QUEUE_ENABLE) || (USBD_CONFIG_IRQ_PRIORITY == POWER_CONFIG_IRQ_PRIORITY)); ret_code_t ret; static const nrf_drv_power_usbevt_config_t config = { .handler = app_usbd_power_event_handler }; ret = nrf_drv_power_usbevt_init(&config); APP_ERROR_CHECK(ret); return NRF_SUCCESS; } #endif /* APP_USBD_CONFIG_POWER_EVENTS_PROCESS */ void app_usbd_enable(void) { nrf_drv_usbd_enable(); } void app_usbd_disable(void) { ASSERT(!nrf_drv_usbd_is_started()); nrf_drv_usbd_disable(); } void app_usbd_start(void) { ASSERT(nrf_drv_usbd_is_enabled()); /* Check if interface numbers are in correct order */ if (APP_USBD_CONFIG_LOG_ENABLED) { uint8_t next_iface = 0; for (app_usbd_class_inst_t const * * pp_inst = &m_p_first_cinst; (*pp_inst) != NULL; pp_inst = &(app_usbd_class_data_access(*pp_inst)->p_next)) { uint8_t iface_idx = 0; app_usbd_class_iface_conf_t const * p_iface; while (NULL != (p_iface = app_usbd_class_iface_get(*pp_inst, iface_idx++))) { if (p_iface->number != next_iface) { NRF_LOG_WARNING("Unexpected interface number, expected %d, got %d", next_iface, p_iface->number); } ++next_iface; } } } /* Power should be already enabled - wait just in case if user calls * app_usbd_start just after app_usbd_enable without waiting for the event. */ while (!nrf_power_usbregstatus_outrdy_get()) { /* Wait for the power but terminate the function if USBD power disappears */ if (!nrf_power_usbregstatus_vbusdet_get()) return; } static const app_usbd_evt_t evt_data = { .type = APP_USBD_EVT_START_REQ }; app_usbd_event_add((app_usbd_internal_evt_t const * )&evt_data); } void app_usbd_stop(void) { const app_usbd_evt_t evt_data = { .type = APP_USBD_EVT_STOP_REQ }; app_usbd_event_add((app_usbd_internal_evt_t const * )&evt_data); } void app_usbd_suspend_req(void) { const app_usbd_evt_t evt_data = { .type = APP_USBD_EVT_SUSPEND_REQ }; app_usbd_event_add((app_usbd_internal_evt_t const * )&evt_data); } bool app_usbd_wakeup_req(void) { ASSERT(app_usbd_class_rwu_enabled_check()); if (!app_usbd_core_feature_state_get(APP_USBD_SETUP_STDFEATURE_DEVICE_REMOTE_WAKEUP)) return false; const app_usbd_evt_t evt_data = { .type = APP_USBD_EVT_WAKEUP_REQ }; app_usbd_event_add((app_usbd_internal_evt_t const * )&evt_data); return true; } bool app_usbd_active_check(void) { return (sustate_get() == SUSTATE_ACTIVE); } void app_usbd_event_execute(app_usbd_internal_evt_t const * const p_event) { ASSERT(NULL != m_p_first_cinst); /* If no event queue is implemented, it has to be ensured that this function is never called * from the context higher than USB interrupt level * If queue is implemented it would be called always from Thread level * if the library is used correctly. * NOTE: Higher interrupt level -> lower priority value. */ ASSERT(USBD_CONFIG_IRQ_PRIORITY <= current_int_priority_get()); /* Note - there should never be situation that event is generated on disconnected endpoint */ switch (p_event->type) { case APP_USBD_EVT_START_REQ: { static const app_usbd_evt_t evt_data = { .type = APP_USBD_EVT_STARTED }; /* Send event to all classes */ UNUSED_RETURN_VALUE(app_usbd_core_handler_call((app_usbd_internal_evt_t const * )&evt_data)); app_usbd_all_call((app_usbd_complex_evt_t const *)&evt_data); user_event_state_proc(APP_USBD_EVT_STARTED); app_usbd_all_iface_deselect(); app_usbd_core_ep0_disable(); nrf_drv_usbd_start((NULL != m_p_first_sof_cinst) || (m_current_conf.enable_sof) || (APP_USBD_PROVIDE_SOF_TIMESTAMP)); sustate_set(SUSTATE_STARTED); break; } case APP_USBD_EVT_STOP_REQ: { static const app_usbd_evt_t evt_data = { .type = APP_USBD_EVT_STOPPED }; app_usbd_all_iface_deselect(); nrf_drv_usbd_stop(); sustate_set(SUSTATE_STOPPED); /* Send event to all classes */ app_usbd_all_call((app_usbd_complex_evt_t const * )&evt_data); UNUSED_RETURN_VALUE(app_usbd_core_handler_call((app_usbd_internal_evt_t const *)&evt_data)); user_event_state_proc(APP_USBD_EVT_STOPPED); if (app_usbd_sustate_with_requested_hfclk(sustate_get())) { nrf_drv_clock_hfclk_release(); } break; } case APP_USBD_EVT_HFCLK_READY: { switch(sustate_get()) { case SUSTATE_RESUMING: { sustate_set(SUSTATE_ACTIVE); break; } case SUSTATE_WAKINGUP_WAITING_HFCLK_WREQ: { sustate_set(SUSTATE_WAKINGUP_WAITING_WREQ); break; } case SUSTATE_WAKINGUP_WAITING_HFCLK: { sustate_set(SUSTATE_ACTIVE); break; } default: break; // Just ignore - it can happen in specific situation } break; } case APP_USBD_EVT_SUSPEND_REQ: { /* Suspend request can be only processed when we are in suspending state */ if (SUSTATE_SUSPENDING == sustate_get()) { if (nrf_drv_usbd_suspend()) { sustate_set(SUSTATE_SUSPEND); } } break; } case APP_USBD_EVT_WAKEUP_REQ: { /* Suspend temporary if no suspend function was called from the application. * This makes it possible to generate APP_USBD_EVT_DRV_WUREQ event from the driver */ if (sustate_get() == SUSTATE_SUSPENDING) { if (nrf_drv_usbd_suspend()) { sustate_set(SUSTATE_SUSPEND); } } if (nrf_drv_usbd_wakeup_req()) { sustate_set(SUSTATE_WAKINGUP_WAITING_HFCLK_WREQ); } break; } case APP_USBD_EVT_DRV_SOF: { #if (APP_USBD_PROVIDE_SOF_TIMESTAMP) || defined(__SDK_DOXYGEN__) m_last_frame = p_event->drv_evt.data.sof.framecnt; #endif /* Wake up if suspended */ if ((sustate_get() == SUSTATE_SUSPENDING) || (sustate_get() == SUSTATE_WAKINGUP_WAITING_WREQ)) { static const app_usbd_evt_t evt_data = { .type = APP_USBD_EVT_DRV_RESUME }; app_usbd_event_execute((app_usbd_internal_evt_t *)&evt_data); } user_event_state_proc(APP_USBD_EVT_DRV_SOF); app_usbd_class_inst_t const * p_inst = app_usbd_class_sof_first_get(); while (NULL != p_inst) { ret_code_t r = class_event_handler(p_inst, (app_usbd_complex_evt_t const *)p_event); UNUSED_VARIABLE(r); p_inst = app_usbd_class_sof_next_get(p_inst); } break; } case APP_USBD_EVT_DRV_RESET: { app_usbd_all_iface_deselect(); app_usbd_core_ep0_enable(); sustate_set(SUSTATE_ACTIVE); user_event_state_proc(APP_USBD_EVT_DRV_RESET); /* Processing core interface (connected only to EP0) and then all instances from the list */ UNUSED_RETURN_VALUE(app_usbd_core_handler_call(p_event)); app_usbd_all_call((app_usbd_complex_evt_t const *)p_event); break; } case APP_USBD_EVT_DRV_RESUME: { if (sustate_get() == SUSTATE_WAKINGUP_WAITING_WREQ) { sustate_set(SUSTATE_ACTIVE); nrf_drv_usbd_force_bus_wakeup(); } else { sustate_set(SUSTATE_RESUMING); } user_event_state_proc(APP_USBD_EVT_DRV_RESUME); /* Processing core interface (connected only to EP0) and then all instances from the list */ UNUSED_RETURN_VALUE(app_usbd_core_handler_call(p_event)); app_usbd_all_call((app_usbd_complex_evt_t const *)p_event); break; } case APP_USBD_EVT_DRV_WUREQ: { static const app_usbd_evt_t evt_data = { .type = APP_USBD_EVT_DRV_RESUME }; user_event_state_proc(APP_USBD_EVT_DRV_RESUME); /* Processing core interface (connected only to EP0) and then all instances from the list */ UNUSED_RETURN_VALUE(app_usbd_core_handler_call((app_usbd_internal_evt_t const *)&evt_data)); app_usbd_all_call((app_usbd_complex_evt_t const *)&evt_data); switch(sustate_get()) { case SUSTATE_WAKINGUP_WAITING_HFCLK_WREQ: sustate_set(SUSTATE_WAKINGUP_WAITING_HFCLK); break; case SUSTATE_WAKINGUP_WAITING_WREQ: sustate_set(SUSTATE_ACTIVE); break; default: { /* This should not happen - but try to recover by setting directly active state */ NRF_LOG_WARNING("Unexpected state on WUREQ event (%u)", sustate_get()); sustate_set(SUSTATE_ACTIVE); } } break; } case APP_USBD_EVT_DRV_SUSPEND: { sustate_set(SUSTATE_SUSPENDING); user_event_state_proc(APP_USBD_EVT_DRV_SUSPEND); /* Processing all instances from the list and then core interface (connected only to EP0) */ app_usbd_all_call((app_usbd_complex_evt_t const *)p_event); UNUSED_RETURN_VALUE(app_usbd_core_handler_call(p_event)); break; } case APP_USBD_EVT_STATE_CHANGED: { user_event_state_proc(APP_USBD_EVT_STATE_CHANGED); /* Processing all instances from the list and then core interface (connected only to EP0) */ app_usbd_all_call((app_usbd_complex_evt_t const *)p_event); break; } case APP_USBD_EVT_DRV_SETUP: { UNUSED_RETURN_VALUE(app_usbd_core_handler_call(p_event)); break; } case APP_USBD_EVT_SETUP_SETADDRESS: { UNUSED_RETURN_VALUE(app_usbd_core_handler_call(p_event)); break; } case APP_USBD_EVT_DRV_EPTRANSFER: { app_usbd_ep_conf_t const * p_ep_conf = app_usbd_ep_conf_access(p_event->drv_evt.data.eptransfer.ep); ASSERT(NULL != p_ep_conf->p_cinst); ASSERT(NULL != p_ep_conf->event_handler); if (NRF_SUCCESS != p_ep_conf->event_handler(p_ep_conf->p_cinst, (app_usbd_complex_evt_t const *)p_event)) { /* If error returned, every bulk/interrupt endpoint would be stalled */ if (!(0 == NRF_USBD_EP_NR_GET(p_event->drv_evt.data.eptransfer.ep) || NRF_USBD_EPISO_CHECK(p_event->drv_evt.data.eptransfer.ep))) { nrf_drv_usbd_ep_stall(p_event->drv_evt.data.eptransfer.ep); } } break; } #if APP_USBD_CONFIG_POWER_EVENTS_PROCESS case APP_USBD_EVT_POWER_DETECTED: { user_event_state_proc(APP_USBD_EVT_POWER_DETECTED); app_usbd_all_call((app_usbd_complex_evt_t const *)p_event); break; } case APP_USBD_EVT_POWER_REMOVED: { user_event_state_proc(APP_USBD_EVT_POWER_REMOVED); app_usbd_all_call((app_usbd_complex_evt_t const *)p_event); break; } case APP_USBD_EVT_POWER_READY: { user_event_state_proc(APP_USBD_EVT_POWER_READY); app_usbd_all_call((app_usbd_complex_evt_t const *)p_event); break; } #endif default: ASSERT(0); break; } } #if (APP_USBD_CONFIG_EVENT_QUEUE_ENABLE) || defined(__SDK_DOXYGEN__) bool app_usbd_event_queue_process(void) { #if (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) app_usbd_internal_evt_t sof_event = { .app_evt.type = APP_USBD_EVT_DRV_SOF }; #endif // (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) static nrf_atfifo_item_get_t cx; static app_usbd_internal_queue_evt_t * p_event_item = NULL; if (NULL == p_event_item) { p_event_item = nrf_atfifo_item_get(m_event_queue, &cx); } if (NULL != p_event_item) { #if (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) if (p_event_item->sof_cnt > 0) { if (p_event_item->start_frame > USBD_FRAMECNTR_FRAMECNTR_Msk) { p_event_item->start_frame = 0; } sof_event.drv_evt.data.sof.framecnt = (p_event_item->start_frame)++; --(p_event_item->sof_cnt); app_usbd_event_execute(&sof_event); return true; } #endif // (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) app_usbd_event_execute(&(p_event_item->evt)); UNUSED_RETURN_VALUE(nrf_atfifo_item_free(m_event_queue, &cx)); p_event_item = NULL; return true; } #if (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) else if (m_sof_events_cnt > 0) { CRITICAL_REGION_ENTER(); if (m_event_frame > USBD_FRAMECNTR_FRAMECNTR_Msk) { m_event_frame = 0; } sof_event.drv_evt.data.sof.framecnt = m_event_frame++; UNUSED_RETURN_VALUE(nrf_atomic_u32_sub_hs(&m_sof_events_cnt, 1)); CRITICAL_REGION_EXIT(); app_usbd_event_execute(&sof_event); return true; } #endif // (APP_USBD_CONFIG_SOF_HANDLING_MODE == APP_USBD_SOF_HANDLING_COMPRESS_QUEUE) else { return false; } } #endif ret_code_t app_usbd_class_append(app_usbd_class_inst_t const * p_cinst) { ASSERT(NULL != p_cinst); ASSERT(NULL != p_cinst->p_class_methods); ASSERT(NULL != p_cinst->p_class_methods->event_handler); ASSERT(NULL == app_usbd_class_data_access(p_cinst)->p_next); /* This should be only called if USBD is disabled * We simply assume that USBD is enabled if its interrupts are */ ASSERT(!nrf_drv_usbd_is_enabled() && nrf_drv_usbd_is_initialized()); /* Check if all required endpoints are available * Checking is splitted from setting to avoid situation that anything * is modified and then operation finishes with error */ uint8_t iface_idx; app_usbd_class_iface_conf_t const * p_iface; iface_idx = 0; while (NULL != (p_iface = app_usbd_class_iface_get(p_cinst, iface_idx++))) { uint8_t ep_idx = 0; app_usbd_class_ep_conf_t const * p_ep; while (NULL != (p_ep = app_usbd_class_iface_ep_get(p_iface, ep_idx++))) { if (NULL != app_usbd_ep_instance_get(app_usbd_class_ep_address_get(p_ep))) { return NRF_ERROR_BUSY; } } } /* Connecting all required endpoints */ iface_idx = 0; while (NULL != (p_iface = app_usbd_class_iface_get(p_cinst, iface_idx++))) { uint8_t ep_idx = 0; app_usbd_class_ep_conf_t const * p_ep; while (NULL != (p_ep = app_usbd_class_iface_ep_get(p_iface, ep_idx++))) { app_usbd_ep_instance_set(app_usbd_class_ep_address_get(p_ep), p_cinst); } } /* Adding pointer to this instance to the end of the chain */ app_usbd_class_inst_t const * * pp_last = &m_p_first_cinst; while (NULL != (*pp_last)) { ASSERT((*pp_last) != p_cinst); pp_last = &(app_usbd_class_data_access(*pp_last)->p_next); } (*pp_last) = p_cinst; /* Successfully attached */ const app_usbd_evt_t evt_data = {.type = APP_USBD_EVT_INST_APPEND }; return class_event_handler(p_cinst, (app_usbd_complex_evt_t const *)(&evt_data)); } ret_code_t app_usbd_class_remove(app_usbd_class_inst_t const * p_cinst) { ASSERT(NULL != p_cinst); ASSERT(NULL != p_cinst->p_class_methods); ASSERT(NULL != p_cinst->p_class_methods->event_handler); /* This function should be only called if USBD is disabled */ ASSERT(!nrf_drv_usbd_is_enabled() && nrf_drv_usbd_is_initialized()); ret_code_t ret; /* Remove this class from the chain */ app_usbd_class_inst_t const * * pp_last = &m_p_first_cinst; while (NULL != (*pp_last)) { if ((*pp_last) == p_cinst) { /* Inform class instance that removing process is going to be started */ const app_usbd_evt_t evt_data = { .type = APP_USBD_EVT_INST_REMOVE }; ret = class_event_handler(p_cinst, (app_usbd_complex_evt_t const *)(&evt_data)); if (ret != NRF_SUCCESS) { return ret; } /* Breaking chain */ (*pp_last) = (app_usbd_class_data_access(p_cinst)->p_next); app_usbd_class_data_access(p_cinst)->p_next = NULL; /* Disconnecting endpoints */ uint8_t ep_idx; for (ep_idx = 0; ep_idx < NRF_USBD_EPIN_CNT; ++ep_idx) { nrf_drv_usbd_ep_t ep = NRF_DRV_USBD_EPIN(ep_idx); if (app_usbd_ep_instance_get(ep) == p_cinst) { app_usbd_ep_instance_set(ep, NULL); } } for (ep_idx = 0; ep_idx < NRF_USBD_EPOUT_CNT; ++ep_idx) { nrf_drv_usbd_ep_t ep = NRF_DRV_USBD_EPOUT(ep_idx); if (app_usbd_ep_instance_get(ep) == p_cinst) { app_usbd_ep_instance_set(ep, NULL); } } return NRF_SUCCESS; } pp_last = &(app_usbd_class_data_access(*pp_last)->p_next); } return NRF_ERROR_NOT_FOUND; } ret_code_t app_usbd_class_remove_all(void) { ret_code_t ret = NRF_SUCCESS; while (NULL != m_p_first_cinst) { ret = app_usbd_class_remove(m_p_first_cinst); if (ret != NRF_SUCCESS) { break; } } return ret; } ret_code_t app_usbd_ep_handler_set(app_usbd_class_inst_t const * const p_cinst, nrf_drv_usbd_ep_t ep, app_usbd_ep_event_handler_t handler) { ASSERT(NULL != p_cinst); ASSERT(NULL != handler); /* This function should be only called if USBD is disabled */ ASSERT(!nrf_drv_usbd_is_enabled() && nrf_drv_usbd_is_initialized()); if (p_cinst != app_usbd_ep_instance_get(ep)) { return NRF_ERROR_INVALID_PARAM; } (app_usbd_ep_conf_access(ep))->event_handler = handler; return NRF_SUCCESS; } ret_code_t app_usbd_class_sof_register(app_usbd_class_inst_t const * p_cinst) { ASSERT(NULL != p_cinst); ASSERT(NULL != p_cinst->p_class_methods); ASSERT(NULL != p_cinst->p_class_methods->event_handler); /* This function should be only called if USBD is disabled */ ASSERT(!nrf_drv_usbd_is_enabled() && nrf_drv_usbd_is_initialized()); /* Make sure it's not in interrupt SOF list */ app_usbd_class_inst_t const * * pp_last = &m_p_first_sof_interrupt_cinst; while (NULL != (*pp_last)) { ASSERT((*pp_last) != p_cinst); pp_last = &(app_usbd_class_data_access(*pp_last)->p_sof_next); } /* Next SOF event requiring instance has to be NULL now */ ASSERT(NULL == (app_usbd_class_data_access(p_cinst)->p_sof_next)); /* Adding pointer to this instance to the end of the chain */ pp_last = &m_p_first_sof_cinst; while (NULL != (*pp_last)) { ASSERT((*pp_last) != p_cinst); pp_last = &(app_usbd_class_data_access(*pp_last)->p_sof_next); } (*pp_last) = p_cinst; return NRF_SUCCESS; } ret_code_t app_usbd_class_sof_unregister(app_usbd_class_inst_t const * p_cinst) { ASSERT(NULL != p_cinst); /** This function should be only called if USBD is disabled */ ASSERT(!nrf_drv_usbd_is_enabled() && nrf_drv_usbd_is_initialized()); app_usbd_class_inst_t const * * pp_last = &m_p_first_sof_cinst; while (NULL != (*pp_last)) { if ((*pp_last) == p_cinst) { /* Breaking chain */ (*pp_last) = (app_usbd_class_data_access(p_cinst)->p_sof_next); app_usbd_class_data_access(p_cinst)->p_sof_next = NULL; return NRF_SUCCESS; } pp_last = &(app_usbd_class_data_access(*pp_last)->p_sof_next); } return NRF_ERROR_NOT_FOUND; } ret_code_t app_usbd_class_sof_interrupt_register(app_usbd_class_inst_t const * p_cinst, app_usbd_sof_interrupt_handler_t handler) { ASSERT(NULL != p_cinst); ASSERT(NULL != p_cinst->p_class_methods); ASSERT(NULL != handler); /* This function should be only called if USBD is disabled */ ASSERT(!nrf_drv_usbd_is_enabled() && nrf_drv_usbd_is_initialized()); /* Next SOF event requiring instance has to be NULL now */ ASSERT(NULL == (app_usbd_class_data_access(p_cinst)->p_sof_next)); app_usbd_class_data_access(p_cinst)->sof_handler = handler; /* Make sure it's not in normal SOF list */ app_usbd_class_inst_t const * * pp_last = &m_p_first_sof_cinst; while (NULL != (*pp_last)) { ASSERT((*pp_last) != p_cinst); pp_last = &(app_usbd_class_data_access(*pp_last)->p_sof_next); } /* Adding pointer to this instance to the end of the interrupt chain */ pp_last = &m_p_first_sof_interrupt_cinst; while (NULL != (*pp_last)) { ASSERT((*pp_last) != p_cinst); pp_last = &(app_usbd_class_data_access(*pp_last)->p_sof_next); } (*pp_last) = p_cinst; return NRF_SUCCESS; } ret_code_t app_usbd_class_sof_interrupt_unregister(app_usbd_class_inst_t const * p_cinst) { ASSERT(NULL != p_cinst); /** This function should be only called if USBD is disabled */ ASSERT(!nrf_drv_usbd_is_enabled() && nrf_drv_usbd_is_initialized()); app_usbd_class_inst_t const * * pp_last = &m_p_first_sof_interrupt_cinst; while (NULL != (*pp_last)) { if ((*pp_last) == p_cinst) { /* Breaking chain */ (*pp_last) = (app_usbd_class_data_access(p_cinst)->p_sof_next); app_usbd_class_data_access(p_cinst)->p_sof_next = NULL; return NRF_SUCCESS; } pp_last = &(app_usbd_class_data_access(*pp_last)->p_sof_next); } return NRF_ERROR_NOT_FOUND; } ret_code_t app_usbd_class_rwu_register(app_usbd_class_inst_t const * const p_inst) { ASSERT(p_inst != NULL); ++m_rwu_registered_counter; /*Overflow check*/ ASSERT(m_rwu_registered_counter != 0); return NRF_SUCCESS; } ret_code_t app_usbd_class_rwu_unregister(app_usbd_class_inst_t const * const p_inst) { ASSERT(p_inst != NULL); /* Usage validation. If counter is 0 unregister is not possible.*/ ASSERT(m_rwu_registered_counter != 0); --m_rwu_registered_counter; return NRF_SUCCESS; } bool app_usbd_class_rwu_enabled_check(void) { return (m_rwu_registered_counter != 0); } ret_code_t app_usbd_interface_ep_reset(app_usbd_class_inst_t const * const p_cinst, uint8_t iface) { uint8_t iface_count = app_usbd_class_iface_count_get(p_cinst); app_usbd_class_iface_conf_t const * p_iface = NULL; for (uint8_t j = 0; j < iface_count; ++j) { p_iface = app_usbd_class_iface_get(p_cinst, j); if (app_usbd_class_iface_number_get(p_iface) == iface) { break; } } if (p_iface == NULL) { return NRF_ERROR_NOT_SUPPORTED; } uint8_t ep_count = app_usbd_class_iface_ep_count_get(p_iface); for (uint8_t j = 0; j < ep_count; ++j) { /*Clear stall for every endpoint*/ app_usbd_class_ep_conf_t const * p_ep = app_usbd_class_iface_ep_get(p_iface, j); if (!NRF_USBD_EPISO_CHECK(p_ep->address)) { nrf_drv_usbd_ep_dtoggle_clear(p_ep->address); nrf_drv_usbd_ep_stall_clear(p_ep->address); } } return NRF_SUCCESS; } void app_usbd_ep_enable(nrf_drv_usbd_ep_t ep) { if (!NRF_USBD_EPISO_CHECK(ep)) { nrf_drv_usbd_ep_dtoggle_clear(ep); nrf_drv_usbd_ep_stall_clear(ep); } nrf_drv_usbd_ep_enable(ep); } void app_usbd_ep_disable(nrf_drv_usbd_ep_t ep) { nrf_drv_usbd_ep_disable(ep); } app_usbd_class_inst_t const * app_usbd_class_first_get(void) { return m_p_first_cinst; } app_usbd_class_inst_t const * app_usbd_class_sof_first_get(void) { return m_p_first_sof_cinst; } app_usbd_class_inst_t const * app_usbd_class_sof_interrupt_first_get(void) { return m_p_first_sof_interrupt_cinst; } app_usbd_class_inst_t const * app_usbd_iface_find(uint8_t iface, uint8_t * p_iface_idx) { app_usbd_class_inst_t const * p_inst = app_usbd_class_first_get(); while (p_inst != NULL) { uint8_t iface_count = app_usbd_class_iface_count_get(p_inst); /* Iterate over interfaces */ for (uint8_t i = 0; i < iface_count; ++i) { app_usbd_class_iface_conf_t const * p_iface; p_iface = app_usbd_class_iface_get(p_inst, i); if (app_usbd_class_iface_number_get(p_iface) == iface) { if (p_iface_idx != NULL) { (*p_iface_idx) = i; } return p_inst; } } p_inst = app_usbd_class_next_get(p_inst); } return NULL; } ret_code_t app_usbd_iface_call( app_usbd_class_inst_t const * const p_class_inst, uint8_t iface_idx, app_usbd_complex_evt_t const * const p_event) { UNUSED_PARAMETER(iface_idx); return class_event_handler(p_class_inst, p_event); } ret_code_t app_usbd_ep_call(nrf_drv_usbd_ep_t ep, app_usbd_complex_evt_t const * const p_event) { if (NRF_USBD_EP_VALIDATE(ep)) { app_usbd_class_inst_t const * p_inst = app_usbd_ep_conf_access(ep)->p_cinst; if (p_inst != NULL) { return class_event_handler(p_inst, p_event); } } return NRF_ERROR_INVALID_ADDR; } void app_usbd_all_call(app_usbd_complex_evt_t const * const p_event) { app_usbd_class_inst_t const * p_inst; for (p_inst = app_usbd_class_first_get(); NULL != p_inst; p_inst = app_usbd_class_next_get(p_inst)) { UNUSED_RETURN_VALUE(class_event_handler(p_inst, p_event)); } } ret_code_t app_usbd_all_until_served_call(app_usbd_complex_evt_t const * const p_event) { app_usbd_class_inst_t const * p_inst; ret_code_t ret = NRF_ERROR_NOT_SUPPORTED; /* Try to process via every instance */ for (p_inst = app_usbd_class_first_get(); NULL != p_inst; p_inst = app_usbd_class_next_get(p_inst)) { ret = class_event_handler(p_inst, p_event); if (NRF_ERROR_NOT_SUPPORTED != ret) { /* Processing finished */ break; } } return ret; } ret_code_t app_usbd_ep_transfer( nrf_drv_usbd_ep_t ep, nrf_drv_usbd_transfer_t const * const p_transfer) { if (!nrf_drv_usbd_ep_enable_check(ep)) { return NRF_ERROR_INVALID_STATE; } if (m_sustate != SUSTATE_ACTIVE) { return NRF_ERROR_INVALID_STATE; } return nrf_drv_usbd_ep_transfer(ep, p_transfer); } ret_code_t app_usbd_ep_handled_transfer( nrf_drv_usbd_ep_t ep, nrf_drv_usbd_handler_desc_t const * const p_handler) { if (!nrf_drv_usbd_ep_enable_check(ep)) { return NRF_ERROR_INVALID_STATE; } if (m_sustate != SUSTATE_ACTIVE) { return NRF_ERROR_INVALID_STATE; } return nrf_drv_usbd_ep_handled_transfer(ep, p_handler); } ret_code_t app_usbd_iface_select( app_usbd_class_inst_t const * const p_inst, uint8_t iface_idx, uint8_t alternate) { ret_code_t ret = NRF_ERROR_NOT_SUPPORTED; if (p_inst->p_class_methods->iface_select != NULL) { ret = p_inst->p_class_methods->iface_select(p_inst, iface_idx, alternate); } if(ret == NRF_ERROR_NOT_SUPPORTED) { ret = default_iface_select(p_inst, iface_idx, alternate); } return ret; } void app_usbd_iface_deselect( app_usbd_class_inst_t const * const p_inst, uint8_t iface_idx) { if (p_inst->p_class_methods->iface_deselect != NULL) { p_inst->p_class_methods->iface_deselect(p_inst, iface_idx); } default_iface_deselect(p_inst, iface_idx); } uint8_t app_usbd_iface_selection_get( app_usbd_class_inst_t const * const p_inst, uint8_t iface_idx) { uint8_t alt = 0; if (p_inst->p_class_methods->iface_selection_get != NULL) { alt = p_inst->p_class_methods->iface_selection_get(p_inst, iface_idx); } return alt; } void app_usbd_all_iface_select_0(void) { app_usbd_class_inst_t const * p_inst = app_usbd_class_first_get(); while (p_inst != NULL) { uint8_t iface_count = app_usbd_class_iface_count_get(p_inst); for (uint8_t i = 0; i < iface_count; ++i) { ret_code_t ret; ret = app_usbd_iface_select(p_inst, i, 0); ASSERT(ret == NRF_SUCCESS); UNUSED_VARIABLE(ret); } p_inst = app_usbd_class_next_get(p_inst); } } void app_usbd_all_iface_deselect(void) { app_usbd_class_inst_t const * p_inst = app_usbd_class_first_get(); while (p_inst != NULL) { uint8_t iface_count = app_usbd_class_iface_count_get(p_inst); for (uint8_t i = 0; i < iface_count; ++i) { app_usbd_iface_deselect(p_inst, i); } p_inst = app_usbd_class_next_get(p_inst); } } #endif //NRF_MODULE_ENABLED(APP_USBD)