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- /**
- * 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 <nordic_common.h>
- #include "nrf_drv_clock.h"
- #if NRF_MODULE_ENABLED(NRF_CLOCK)
- #ifdef SOFTDEVICE_PRESENT
- #include "nrf_sdh.h"
- #include "nrf_sdh_soc.h"
- #endif
- #define NRF_LOG_MODULE_NAME clock
- #if CLOCK_CONFIG_LOG_ENABLED
- #define NRF_LOG_LEVEL CLOCK_CONFIG_LOG_LEVEL
- #define NRF_LOG_INFO_COLOR CLOCK_CONFIG_INFO_COLOR
- #define NRF_LOG_DEBUG_COLOR CLOCK_CONFIG_DEBUG_COLOR
- #else //CLOCK_CONFIG_LOG_ENABLED
- #define NRF_LOG_LEVEL 0
- #endif //CLOCK_CONFIG_LOG_ENABLED
- #include "nrf_log.h"
- NRF_LOG_MODULE_REGISTER();
- #define EVT_TO_STR(event) \
- (event == NRF_CLOCK_EVENT_HFCLKSTARTED ? "NRF_CLOCK_EVENT_HFCLKSTARTED" : \
- (event == NRF_CLOCK_EVENT_LFCLKSTARTED ? "NRF_CLOCK_EVENT_LFCLKSTARTED" : \
- (event == NRF_CLOCK_EVENT_DONE ? "NRF_CLOCK_EVENT_DONE" : \
- (event == NRF_CLOCK_EVENT_CTTO ? "NRF_CLOCK_EVENT_CTTO" : \
- "UNKNOWN EVENT"))))
- /*lint -save -e652 */
- #define NRF_CLOCK_LFCLK_RC CLOCK_LFCLKSRC_SRC_RC
- #define NRF_CLOCK_LFCLK_Xtal CLOCK_LFCLKSRC_SRC_Xtal
- #define NRF_CLOCK_LFCLK_Synth CLOCK_LFCLKSRC_SRC_Synth
- /*lint -restore */
- #if (CLOCK_CONFIG_LF_SRC == NRF_CLOCK_LFCLK_RC) && !defined(SOFTDEVICE_PRESENT)
- #define CALIBRATION_SUPPORT 1
- #else
- #define CALIBRATION_SUPPORT 0
- #endif
- typedef enum
- {
- CAL_STATE_IDLE,
- CAL_STATE_CT,
- CAL_STATE_HFCLK_REQ,
- CAL_STATE_CAL,
- CAL_STATE_ABORT,
- } nrf_drv_clock_cal_state_t;
- /**@brief CLOCK control block. */
- typedef struct
- {
- bool module_initialized; /*< Indicate the state of module */
- volatile bool hfclk_on; /*< High-frequency clock state. */
- volatile bool lfclk_on; /*< Low-frequency clock state. */
- volatile uint32_t hfclk_requests; /*< High-frequency clock request counter. */
- volatile nrf_drv_clock_handler_item_t * p_hf_head;
- volatile uint32_t lfclk_requests; /*< Low-frequency clock request counter. */
- volatile nrf_drv_clock_handler_item_t * p_lf_head;
- #if CALIBRATION_SUPPORT
- nrf_drv_clock_handler_item_t cal_hfclk_started_handler_item;
- nrf_drv_clock_event_handler_t cal_done_handler;
- volatile nrf_drv_clock_cal_state_t cal_state;
- #endif // CALIBRATION_SUPPORT
- } nrf_drv_clock_cb_t;
- static nrf_drv_clock_cb_t m_clock_cb;
- static void clock_irq_handler(nrfx_clock_evt_type_t evt);
- static void lfclk_stop(void)
- {
- #if CALIBRATION_SUPPORT
- nrfx_clock_calibration_timer_stop();
- #endif
- #ifdef SOFTDEVICE_PRESENT
- // If LFCLK is requested to stop while SD is still enabled,
- // it indicates an error in the application.
- // Enabling SD should increment the LFCLK request.
- ASSERT(!nrf_sdh_is_enabled());
- #endif // SOFTDEVICE_PRESENT
- nrfx_clock_lfclk_stop();
- m_clock_cb.lfclk_on = false;
- }
- static void hfclk_start(void)
- {
- #ifdef SOFTDEVICE_PRESENT
- if (nrf_sdh_is_enabled())
- {
- (void)sd_clock_hfclk_request();
- return;
- }
- #endif // SOFTDEVICE_PRESENT
- nrfx_clock_hfclk_start();
- }
- static void hfclk_stop(void)
- {
- #ifdef SOFTDEVICE_PRESENT
- if (nrf_sdh_is_enabled())
- {
- (void)sd_clock_hfclk_release();
- m_clock_cb.hfclk_on = false;
- return;
- }
- #endif // SOFTDEVICE_PRESENT
- nrfx_clock_hfclk_stop();
- m_clock_cb.hfclk_on = false;
- }
- bool nrf_drv_clock_init_check(void)
- {
- return m_clock_cb.module_initialized;
- }
- ret_code_t nrf_drv_clock_init(void)
- {
- ret_code_t err_code = NRF_SUCCESS;
- if (m_clock_cb.module_initialized)
- {
- err_code = NRF_ERROR_MODULE_ALREADY_INITIALIZED;
- }
- else
- {
- m_clock_cb.p_hf_head = NULL;
- m_clock_cb.hfclk_requests = 0;
- m_clock_cb.p_lf_head = NULL;
- m_clock_cb.lfclk_requests = 0;
- err_code = nrfx_clock_init(clock_irq_handler);
- #ifdef SOFTDEVICE_PRESENT
- if (!nrf_sdh_is_enabled())
- #endif
- {
- nrfx_clock_enable();
- }
- #if CALIBRATION_SUPPORT
- m_clock_cb.cal_state = CAL_STATE_IDLE;
- #endif
- m_clock_cb.module_initialized = true;
- }
- NRF_LOG_INFO("Function: %s, error code: %s.",
- (uint32_t)__func__,
- (uint32_t)NRF_LOG_ERROR_STRING_GET(err_code));
- return err_code;
- }
- void nrf_drv_clock_uninit(void)
- {
- ASSERT(m_clock_cb.module_initialized);
- nrfx_clock_disable();
- nrfx_clock_uninit();
- m_clock_cb.module_initialized = false;
- }
- static void item_enqueue(nrf_drv_clock_handler_item_t ** p_head,
- nrf_drv_clock_handler_item_t * p_item)
- {
- nrf_drv_clock_handler_item_t * p_next = *p_head;
- while (p_next)
- {
- if (p_next == p_item)
- {
- return;
- }
- p_next = p_next->p_next;
- }
- p_item->p_next = (*p_head ? *p_head : NULL);
- *p_head = p_item;
- }
- static nrf_drv_clock_handler_item_t * item_dequeue(nrf_drv_clock_handler_item_t ** p_head)
- {
- nrf_drv_clock_handler_item_t * p_item = *p_head;
- if (p_item)
- {
- *p_head = p_item->p_next;
- }
- return p_item;
- }
- void nrf_drv_clock_lfclk_request(nrf_drv_clock_handler_item_t * p_handler_item)
- {
- ASSERT(m_clock_cb.module_initialized);
- if (m_clock_cb.lfclk_on)
- {
- if (p_handler_item)
- {
- p_handler_item->event_handler(NRF_DRV_CLOCK_EVT_LFCLK_STARTED);
- }
- CRITICAL_REGION_ENTER();
- ++(m_clock_cb.lfclk_requests);
- CRITICAL_REGION_EXIT();
- }
- else
- {
- CRITICAL_REGION_ENTER();
- if (p_handler_item)
- {
- item_enqueue((nrf_drv_clock_handler_item_t **)&m_clock_cb.p_lf_head,
- p_handler_item);
- }
- if (m_clock_cb.lfclk_requests == 0)
- {
- nrfx_clock_lfclk_start();
- }
- ++(m_clock_cb.lfclk_requests);
- CRITICAL_REGION_EXIT();
- }
- ASSERT(m_clock_cb.lfclk_requests > 0);
- }
- void nrf_drv_clock_lfclk_release(void)
- {
- ASSERT(m_clock_cb.module_initialized);
- ASSERT(m_clock_cb.lfclk_requests > 0);
- CRITICAL_REGION_ENTER();
- --(m_clock_cb.lfclk_requests);
- if (m_clock_cb.lfclk_requests == 0)
- {
- lfclk_stop();
- }
- CRITICAL_REGION_EXIT();
- }
- bool nrf_drv_clock_lfclk_is_running(void)
- {
- ASSERT(m_clock_cb.module_initialized);
- #ifdef SOFTDEVICE_PRESENT
- if (nrf_sdh_is_enabled())
- {
- return true;
- }
- #endif // SOFTDEVICE_PRESENT
- return nrfx_clock_lfclk_is_running();
- }
- void nrf_drv_clock_hfclk_request(nrf_drv_clock_handler_item_t * p_handler_item)
- {
- ASSERT(m_clock_cb.module_initialized);
- if (m_clock_cb.hfclk_on)
- {
- if (p_handler_item)
- {
- p_handler_item->event_handler(NRF_DRV_CLOCK_EVT_HFCLK_STARTED);
- }
- CRITICAL_REGION_ENTER();
- ++(m_clock_cb.hfclk_requests);
- CRITICAL_REGION_EXIT();
- }
- else
- {
- CRITICAL_REGION_ENTER();
- if (p_handler_item)
- {
- item_enqueue((nrf_drv_clock_handler_item_t **)&m_clock_cb.p_hf_head,
- p_handler_item);
- }
- if (m_clock_cb.hfclk_requests == 0)
- {
- hfclk_start();
- }
- ++(m_clock_cb.hfclk_requests);
- CRITICAL_REGION_EXIT();
- }
- ASSERT(m_clock_cb.hfclk_requests > 0);
- }
- void nrf_drv_clock_hfclk_release(void)
- {
- ASSERT(m_clock_cb.module_initialized);
- ASSERT(m_clock_cb.hfclk_requests > 0);
- CRITICAL_REGION_ENTER();
- --(m_clock_cb.hfclk_requests);
- if (m_clock_cb.hfclk_requests == 0)
- {
- hfclk_stop();
- }
- CRITICAL_REGION_EXIT();
- }
- bool nrf_drv_clock_hfclk_is_running(void)
- {
- ASSERT(m_clock_cb.module_initialized);
- #ifdef SOFTDEVICE_PRESENT
- if (nrf_sdh_is_enabled())
- {
- uint32_t is_running;
- UNUSED_VARIABLE(sd_clock_hfclk_is_running(&is_running));
- return (is_running ? true : false);
- }
- #endif // SOFTDEVICE_PRESENT
- return nrfx_clock_hfclk_is_running();
- }
- #if CALIBRATION_SUPPORT
- static void clock_calibration_hf_started(nrf_drv_clock_evt_type_t event)
- {
- if (m_clock_cb.cal_state == CAL_STATE_ABORT)
- {
- nrf_drv_clock_hfclk_release();
- m_clock_cb.cal_state = CAL_STATE_IDLE;
- if (m_clock_cb.cal_done_handler)
- {
- m_clock_cb.cal_done_handler(NRF_DRV_CLOCK_EVT_CAL_ABORTED);
- }
- }
- else
- {
- ASSERT(event == NRF_DRV_CLOCK_EVT_HFCLK_STARTED);
- if (nrfx_clock_calibration_start() != NRFX_SUCCESS)
- {
- ASSERT(false);
- }
- }
- }
- #endif // CALIBRATION_SUPPORT
- ret_code_t nrf_drv_clock_calibration_start(uint8_t interval, nrf_drv_clock_event_handler_t handler)
- {
- ret_code_t err_code = NRF_SUCCESS;
- #if CALIBRATION_SUPPORT
- ASSERT(m_clock_cb.cal_state == CAL_STATE_IDLE);
- if (m_clock_cb.lfclk_on == false)
- {
- err_code = NRF_ERROR_INVALID_STATE;
- }
- else if (m_clock_cb.cal_state == CAL_STATE_IDLE)
- {
- m_clock_cb.cal_done_handler = handler;
- m_clock_cb.cal_hfclk_started_handler_item.event_handler = clock_calibration_hf_started;
- if (interval == 0)
- {
- m_clock_cb.cal_state = CAL_STATE_HFCLK_REQ;
- nrf_drv_clock_hfclk_request(&m_clock_cb.cal_hfclk_started_handler_item);
- }
- else
- {
- m_clock_cb.cal_state = CAL_STATE_CT;
- nrfx_clock_calibration_timer_start(interval);
- }
- }
- else
- {
- err_code = NRF_ERROR_BUSY;
- }
- NRF_LOG_WARNING("Function: %s, error code: %s.",
- (uint32_t)__func__,
- (uint32_t)NRF_LOG_ERROR_STRING_GET(err_code));
- return err_code;
- #else
- UNUSED_PARAMETER(interval);
- UNUSED_PARAMETER(handler);
- err_code = NRF_ERROR_FORBIDDEN;
- NRF_LOG_WARNING("Function: %s, error code: %s.",
- (uint32_t)__func__,
- (uint32_t)NRF_LOG_ERROR_STRING_GET(err_code));
- return err_code;
- #endif // CALIBRATION_SUPPORT
- }
- ret_code_t nrf_drv_clock_calibration_abort(void)
- {
- ret_code_t err_code = NRF_SUCCESS;
- #if CALIBRATION_SUPPORT
- CRITICAL_REGION_ENTER();
- switch (m_clock_cb.cal_state)
- {
- case CAL_STATE_CT:
- nrfx_clock_calibration_timer_stop();
- m_clock_cb.cal_state = CAL_STATE_IDLE;
- if (m_clock_cb.cal_done_handler)
- {
- m_clock_cb.cal_done_handler(NRF_DRV_CLOCK_EVT_CAL_ABORTED);
- }
- break;
- case CAL_STATE_HFCLK_REQ:
- /* fall through. */
- case CAL_STATE_CAL:
- m_clock_cb.cal_state = CAL_STATE_ABORT;
- break;
- default:
- break;
- }
- CRITICAL_REGION_EXIT();
- NRF_LOG_INFO("Function: %s, error code: %s.",
- (uint32_t)__func__,
- (uint32_t)NRF_LOG_ERROR_STRING_GET(err_code));
- return err_code;
- #else
- err_code = NRF_ERROR_FORBIDDEN;
- NRF_LOG_WARNING("Function: %s, error code: %s.",
- (uint32_t)__func__,
- (uint32_t)NRF_LOG_ERROR_STRING_GET(err_code));
- return err_code;
- #endif // CALIBRATION_SUPPORT
- }
- ret_code_t nrf_drv_clock_is_calibrating(bool * p_is_calibrating)
- {
- ret_code_t err_code = NRF_SUCCESS;
- #if CALIBRATION_SUPPORT
- ASSERT(m_clock_cb.module_initialized);
- *p_is_calibrating = (m_clock_cb.cal_state != CAL_STATE_IDLE);
- NRF_LOG_INFO("Function: %s, error code: %s.",
- (uint32_t)__func__,
- (uint32_t)NRF_LOG_ERROR_STRING_GET(err_code));
- return err_code;
- #else
- UNUSED_PARAMETER(p_is_calibrating);
- err_code = NRF_ERROR_FORBIDDEN;
- NRF_LOG_WARNING("Function: %s, error code: %s.",
- (uint32_t)__func__,
- (uint32_t)NRF_LOG_ERROR_STRING_GET(err_code));
- return err_code;
- #endif // CALIBRATION_SUPPORT
- }
- __STATIC_INLINE void clock_clk_started_notify(nrf_drv_clock_evt_type_t evt_type)
- {
- nrf_drv_clock_handler_item_t **p_head;
- if (evt_type == NRF_DRV_CLOCK_EVT_HFCLK_STARTED)
- {
- p_head = (nrf_drv_clock_handler_item_t **)&m_clock_cb.p_hf_head;
- }
- else
- {
- p_head = (nrf_drv_clock_handler_item_t **)&m_clock_cb.p_lf_head;
- }
- while (1)
- {
- nrf_drv_clock_handler_item_t * p_item = item_dequeue(p_head);
- if (!p_item)
- {
- break;
- }
- p_item->event_handler(evt_type);
- }
- }
- static void clock_irq_handler(nrfx_clock_evt_type_t evt)
- {
- if (evt == NRFX_CLOCK_EVT_HFCLK_STARTED)
- {
- m_clock_cb.hfclk_on = true;
- clock_clk_started_notify(NRF_DRV_CLOCK_EVT_HFCLK_STARTED);
- }
- if (evt == NRFX_CLOCK_EVT_LFCLK_STARTED)
- {
- m_clock_cb.lfclk_on = true;
- clock_clk_started_notify(NRF_DRV_CLOCK_EVT_LFCLK_STARTED);
- }
- #if CALIBRATION_SUPPORT
- if (evt == NRFX_CLOCK_EVT_CTTO)
- {
- nrf_drv_clock_hfclk_request(&m_clock_cb.cal_hfclk_started_handler_item);
- }
- if (evt == NRFX_CLOCK_EVT_CAL_DONE)
- {
- nrf_drv_clock_hfclk_release();
- bool aborted = (m_clock_cb.cal_state == CAL_STATE_ABORT);
- m_clock_cb.cal_state = CAL_STATE_IDLE;
- if (m_clock_cb.cal_done_handler)
- {
- m_clock_cb.cal_done_handler(aborted ?
- NRF_DRV_CLOCK_EVT_CAL_ABORTED : NRF_DRV_CLOCK_EVT_CAL_DONE);
- }
- }
- #endif // CALIBRATION_SUPPORT
- }
- #ifdef SOFTDEVICE_PRESENT
- /**
- * @brief SoftDevice SoC event handler.
- *
- * @param[in] evt_id SoC event.
- * @param[in] p_context Context.
- */
- static void soc_evt_handler(uint32_t evt_id, void * p_context)
- {
- if (evt_id == NRF_EVT_HFCLKSTARTED)
- {
- m_clock_cb.hfclk_on = true;
- clock_clk_started_notify(NRF_DRV_CLOCK_EVT_HFCLK_STARTED);
- }
- }
- NRF_SDH_SOC_OBSERVER(m_soc_evt_observer, CLOCK_CONFIG_SOC_OBSERVER_PRIO, soc_evt_handler, NULL);
- /**
- * @brief SoftDevice enable/disable state handler.
- *
- * @param[in] state State.
- * @param[in] p_context Context.
- */
- static void sd_state_evt_handler(nrf_sdh_state_evt_t state, void * p_context)
- {
- switch (state)
- {
- case NRF_SDH_EVT_STATE_ENABLE_PREPARE:
- NVIC_DisableIRQ(POWER_CLOCK_IRQn);
- break;
- case NRF_SDH_EVT_STATE_ENABLED:
- CRITICAL_REGION_ENTER();
- /* Make sure that nrf_drv_clock module is initialized */
- if (!m_clock_cb.module_initialized)
- {
- (void)nrf_drv_clock_init();
- }
- /* SD is one of the LFCLK requesters, but it will enable it by itself. */
- ++(m_clock_cb.lfclk_requests);
- m_clock_cb.lfclk_on = true;
- CRITICAL_REGION_EXIT();
- break;
- case NRF_SDH_EVT_STATE_DISABLED:
- /* Reinit interrupts */
- ASSERT(m_clock_cb.module_initialized);
- nrfx_clock_enable();
- /* SD leaves LFCLK enabled - disable it if it is no longer required. */
- nrf_drv_clock_lfclk_release();
- break;
- default:
- break;
- }
- }
- NRF_SDH_STATE_OBSERVER(m_sd_state_observer, CLOCK_CONFIG_STATE_OBSERVER_PRIO) =
- {
- .handler = sd_state_evt_handler,
- .p_context = NULL,
- };
- #endif // SOFTDEVICE_PRESENT
- #undef NRF_CLOCK_LFCLK_RC
- #undef NRF_CLOCK_LFCLK_Xtal
- #undef NRF_CLOCK_LFCLK_Synth
- #endif // NRF_MODULE_ENABLED(NRF_CLOCK)
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