/** * Copyright (c) 2016 - 2018, 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(NRF_PWR_MGMT) #include "nrf_pwr_mgmt.h" #include "nrf.h" #include "nrf_mtx.h" #include "nrf_power.h" #include "app_error.h" #include "nrf_assert.h" #include "nrf_log_ctrl.h" #include "app_util_platform.h" #define NRF_LOG_MODULE_NAME pwr_mgmt #if NRF_PWR_MGMT_CONFIG_LOG_ENABLED #define NRF_LOG_LEVEL NRF_PWR_MGMT_CONFIG_LOG_LEVEL #define NRF_LOG_INFO_COLOR NRF_PWR_MGMT_CONFIG_INFO_COLOR #define NRF_LOG_DEBUG_COLOR NRF_PWR_MGMT_CONFIG_DEBUG_COLOR #else #define NRF_LOG_LEVEL 0 #endif // NRF_PWR_MGMT_CONFIG_LOG_ENABLED #include "nrf_log.h" NRF_LOG_MODULE_REGISTER(); #ifdef SOFTDEVICE_PRESENT #include "nrf_soc.h" #include "nrf_sdh.h" #endif // SOFTDEVICE_PRESENT #if NRF_PWR_MGMT_CONFIG_USE_SCHEDULER #if (APP_SCHEDULER_ENABLED != 1) #error "APP_SCHEDULER is required." #endif #include "app_scheduler.h" #endif // NRF_PWR_MGMT_CONFIG_USE_SCHEDULER // Create section "pwr_mgmt_data". NRF_SECTION_SET_DEF(pwr_mgmt_data, nrf_pwr_mgmt_shutdown_handler_t, NRF_PWR_MGMT_CONFIG_HANDLER_PRIORITY_COUNT); static nrf_pwr_mgmt_evt_t m_pwr_mgmt_evt; /**< Event type which will be passed to the shutdown handlers.*/ static nrf_mtx_t m_sysoff_mtx; /**< Module API lock.*/ static bool m_shutdown_started; /**< True if application started the shutdown preparation. */ static nrf_section_iter_t m_handlers_iter; /**< Shutdown handlers iterator. */ #if (NRF_PWR_MGMT_CONFIG_FPU_SUPPORT_ENABLED && __FPU_PRESENT) #define PWR_MGMT_FPU_SLEEP_PREPARE() pwr_mgmt_fpu_sleep_prepare() __STATIC_INLINE void pwr_mgmt_fpu_sleep_prepare(void) { uint32_t fpscr; CRITICAL_REGION_ENTER(); fpscr = __get_FPSCR(); /* * Clear FPU exceptions. * Without this step, the FPU interrupt is marked as pending, * preventing system from sleeping. Exceptions cleared: * - IOC - Invalid Operation cumulative exception bit. * - DZC - Division by Zero cumulative exception bit. * - OFC - Overflow cumulative exception bit. * - UFC - Underflow cumulative exception bit. * - IXC - Inexact cumulative exception bit. * - IDC - Input Denormal cumulative exception bit. */ __set_FPSCR(fpscr & ~0x9Fu); __DMB(); NVIC_ClearPendingIRQ(FPU_IRQn); CRITICAL_REGION_EXIT(); /* * Assert no critical FPU exception is signaled: * - IOC - Invalid Operation cumulative exception bit. * - DZC - Division by Zero cumulative exception bit. * - OFC - Overflow cumulative exception bit. */ ASSERT((fpscr & 0x07) == 0); } #else #define PWR_MGMT_FPU_SLEEP_PREPARE() #endif // NRF_PWR_MGMT_CONFIG_FPU_SUPPORT_ENABLED #if NRF_PWR_MGMT_CONFIG_DEBUG_PIN_ENABLED #undef PWR_MGMT_SLEEP_IN_CRITICAL_SECTION_REQUIRED #define PWR_MGMT_SLEEP_IN_CRITICAL_SECTION_REQUIRED #include "nrf_gpio.h" #define PWR_MGMT_DEBUG_PINS_INIT() pwr_mgmt_debug_pins_init() #define PWR_MGMT_DEBUG_PIN_CLEAR() nrf_gpio_pin_clear(NRF_PWR_MGMT_SLEEP_DEBUG_PIN) #define PWR_MGMT_DEBUG_PIN_SET() nrf_gpio_pin_set(NRF_PWR_MGMT_SLEEP_DEBUG_PIN) __STATIC_INLINE void pwr_mgmt_debug_pins_init(void) { nrf_gpio_pin_clear(NRF_PWR_MGMT_SLEEP_DEBUG_PIN); nrf_gpio_cfg_output(NRF_PWR_MGMT_SLEEP_DEBUG_PIN); } #else #define PWR_MGMT_DEBUG_PIN_CLEAR() #define PWR_MGMT_DEBUG_PIN_SET() #define PWR_MGMT_DEBUG_PINS_INIT() #endif #if NRF_PWR_MGMT_CONFIG_CPU_USAGE_MONITOR_ENABLED #undef PWR_MGMT_SLEEP_IN_CRITICAL_SECTION_REQUIRED #define PWR_MGMT_SLEEP_IN_CRITICAL_SECTION_REQUIRED #undef PWR_MGMT_TIMER_REQUIRED #define PWR_MGMT_TIMER_REQUIRED #include "app_timer.h" #define PWR_MGMT_CPU_USAGE_MONITOR_INIT() pwr_mgmt_cpu_usage_monitor_init() #define PWR_MGMT_CPU_USAGE_MONITOR_UPDATE() pwr_mgmt_cpu_usage_monitor_update() #define PWR_MGMT_CPU_USAGE_MONITOR_SUMMARY() NRF_LOG_INFO("Maximum CPU usage: %u%%", \ m_max_cpu_usage) #define PWR_MGMT_CPU_USAGE_MONITOR_SECTION_ENTER() \ { \ uint32_t sleep_start = app_timer_cnt_get() #define PWR_MGMT_CPU_USAGE_MONITOR_SECTION_EXIT() \ uint32_t sleep_end = app_timer_cnt_get(); \ uint32_t sleep_duration; \ sleep_duration = app_timer_cnt_diff_compute(sleep_end, \ sleep_start); \ m_ticks_sleeping += sleep_duration; \ } static uint32_t m_ticks_sleeping; /**< Number of ticks spent in sleep mode (__WFE()). */ static uint32_t m_ticks_last; /**< Number of ticks from the last CPU usage computation. */ static uint8_t m_max_cpu_usage; /**< Maximum observed CPU usage (0 - 100%). */ __STATIC_INLINE void pwr_mgmt_cpu_usage_monitor_init(void) { m_ticks_sleeping = 0; m_ticks_last = 0; m_max_cpu_usage = 0; } __STATIC_INLINE void pwr_mgmt_cpu_usage_monitor_update(void) { uint32_t delta; uint32_t ticks; uint8_t cpu_usage; ticks = app_timer_cnt_get(); delta = app_timer_cnt_diff_compute(ticks, m_ticks_last); cpu_usage = 100 * (delta - m_ticks_sleeping) / delta; NRF_LOG_INFO("CPU Usage: %u%%", cpu_usage); if (m_max_cpu_usage < cpu_usage) { m_max_cpu_usage = cpu_usage; } m_ticks_last = ticks; m_ticks_sleeping = 0; } #else #define PWR_MGMT_CPU_USAGE_MONITOR_INIT() #define PWR_MGMT_CPU_USAGE_MONITOR_UPDATE() #define PWR_MGMT_CPU_USAGE_MONITOR_SUMMARY() #define PWR_MGMT_CPU_USAGE_MONITOR_SECTION_ENTER() #define PWR_MGMT_CPU_USAGE_MONITOR_SECTION_EXIT() #endif // NRF_PWR_MGMT_CONFIG_CPU_USAGE_MONITOR_ENABLED #if NRF_PWR_MGMT_CONFIG_STANDBY_TIMEOUT_ENABLED #undef PWR_MGMT_TIMER_REQUIRED #define PWR_MGMT_TIMER_REQUIRED #define PWR_MGMT_STANDBY_TIMEOUT_INIT() pwr_mgmt_standby_timeout_clear() #define PWR_MGMT_STANDBY_TIMEOUT_CLEAR() pwr_mgmt_standby_timeout_clear() #define PWR_MGMT_STANDBY_TIMEOUT_CHECK() pwr_mgmt_standby_timeout_check() static uint16_t m_standby_counter; /**< Number of seconds from the last activity (@ref pwr_mgmt_feed). */ __STATIC_INLINE void pwr_mgmt_standby_timeout_clear(void) { m_standby_counter = 0; } __STATIC_INLINE void pwr_mgmt_standby_timeout_check(void) { if (m_standby_counter < NRF_PWR_MGMT_CONFIG_STANDBY_TIMEOUT_S) { m_standby_counter++; } else if (m_shutdown_started == false) { nrf_pwr_mgmt_shutdown(NRF_PWR_MGMT_SHUTDOWN_GOTO_SYSOFF); } } #else #define PWR_MGMT_STANDBY_TIMEOUT_INIT() #define PWR_MGMT_STANDBY_TIMEOUT_CLEAR() #define PWR_MGMT_STANDBY_TIMEOUT_CHECK() #endif // NRF_PWR_MGMT_CONFIG_STANDBY_TIMEOUT_ENABLED #if NRF_PWR_MGMT_CONFIG_AUTO_SHUTDOWN_RETRY #undef PWR_MGMT_TIMER_REQUIRED #define PWR_MGMT_TIMER_REQUIRED #define PWR_MGMT_AUTO_SHUTDOWN_RETRY() pwr_mgmt_auto_shutdown_retry() __STATIC_INLINE void pwr_mgmt_auto_shutdown_retry(void) { if (m_shutdown_started) { // Try to continue the shutdown procedure. nrf_pwr_mgmt_shutdown(NRF_PWR_MGMT_SHUTDOWN_CONTINUE); } } #else #define PWR_MGMT_AUTO_SHUTDOWN_RETRY() #endif // NRF_PWR_MGMT_CONFIG_AUTO_SHUTDOWN_RETRY #ifdef PWR_MGMT_SLEEP_IN_CRITICAL_SECTION_REQUIRED #define PWR_MGMT_SLEEP_INIT() pwr_mgmt_sleep_init() #define PWR_MGMT_SLEEP_LOCK_ACQUIRE() CRITICAL_REGION_ENTER() #define PWR_MGMT_SLEEP_LOCK_RELEASE() CRITICAL_REGION_EXIT() __STATIC_INLINE void pwr_mgmt_sleep_init(void) { #ifdef SOFTDEVICE_PRESENT ASSERT(current_int_priority_get() >= APP_IRQ_PRIORITY_LOW); #endif SCB->SCR |= SCB_SCR_SEVONPEND_Msk; } #else #define PWR_MGMT_SLEEP_INIT() #define PWR_MGMT_SLEEP_LOCK_ACQUIRE() #define PWR_MGMT_SLEEP_LOCK_RELEASE() #endif // PWR_MGMT_SLEEP_IN_CRITICAL_SECTION_REQUIRED #ifdef PWR_MGMT_TIMER_REQUIRED #include "app_timer.h" #define PWR_MGMT_TIMER_CREATE() pwr_mgmt_timer_create() APP_TIMER_DEF(m_pwr_mgmt_timer); /**< Timer used by this module. */ /**@brief Handle events from m_pwr_mgmt_timer. */ static void nrf_pwr_mgmt_timeout_handler(void * p_context) { PWR_MGMT_CPU_USAGE_MONITOR_UPDATE(); PWR_MGMT_AUTO_SHUTDOWN_RETRY(); PWR_MGMT_STANDBY_TIMEOUT_CHECK(); } __STATIC_INLINE ret_code_t pwr_mgmt_timer_create(void) { ret_code_t ret_code = app_timer_create(&m_pwr_mgmt_timer, APP_TIMER_MODE_REPEATED, nrf_pwr_mgmt_timeout_handler); if (ret_code != NRF_SUCCESS) { return ret_code; } return app_timer_start(m_pwr_mgmt_timer, APP_TIMER_TICKS(1000), NULL); } #else #define PWR_MGMT_TIMER_CREATE() NRF_SUCCESS #endif // PWR_MGMT_TIMER_REQUIRED ret_code_t nrf_pwr_mgmt_init(void) { NRF_LOG_INFO("Init"); m_shutdown_started = false; nrf_mtx_init(&m_sysoff_mtx); nrf_section_iter_init(&m_handlers_iter, &pwr_mgmt_data); PWR_MGMT_SLEEP_INIT(); PWR_MGMT_DEBUG_PINS_INIT(); PWR_MGMT_STANDBY_TIMEOUT_INIT(); PWR_MGMT_CPU_USAGE_MONITOR_INIT(); return PWR_MGMT_TIMER_CREATE(); } void nrf_pwr_mgmt_run(void) { PWR_MGMT_FPU_SLEEP_PREPARE(); PWR_MGMT_SLEEP_LOCK_ACQUIRE(); PWR_MGMT_CPU_USAGE_MONITOR_SECTION_ENTER(); PWR_MGMT_DEBUG_PIN_SET(); // Wait for an event. #ifdef SOFTDEVICE_PRESENT if (nrf_sdh_is_enabled()) { ret_code_t ret_code = sd_app_evt_wait(); ASSERT((ret_code == NRF_SUCCESS) || (ret_code == NRF_ERROR_SOFTDEVICE_NOT_ENABLED)); UNUSED_VARIABLE(ret_code); } else #endif // SOFTDEVICE_PRESENT { // Wait for an event. __WFE(); // Clear the internal event register. __SEV(); __WFE(); } PWR_MGMT_DEBUG_PIN_CLEAR(); PWR_MGMT_CPU_USAGE_MONITOR_SECTION_EXIT(); PWR_MGMT_SLEEP_LOCK_RELEASE(); } void nrf_pwr_mgmt_feed(void) { NRF_LOG_DEBUG("Feed"); // It does not stop started shutdown process. PWR_MGMT_STANDBY_TIMEOUT_CLEAR(); } /**@brief Function runs the shutdown procedure. */ static void shutdown_process(void) { NRF_LOG_INFO("Shutdown started. Type %d", m_pwr_mgmt_evt); // Executing all callbacks. for (/* m_handlers_iter is initialized in nrf_pwr_mgmt_init(). Thanks to that each handler is called only once.*/; nrf_section_iter_get(&m_handlers_iter) != NULL; nrf_section_iter_next(&m_handlers_iter)) { nrf_pwr_mgmt_shutdown_handler_t * p_handler = (nrf_pwr_mgmt_shutdown_handler_t *) nrf_section_iter_get(&m_handlers_iter); if ((*p_handler)(m_pwr_mgmt_evt)) { NRF_LOG_INFO("SysOff handler 0x%08X => ready", (unsigned int)*p_handler); } else { // One of the modules is not ready. NRF_LOG_INFO("SysOff handler 0x%08X => blocking", (unsigned int)*p_handler); return; } } PWR_MGMT_CPU_USAGE_MONITOR_SUMMARY(); NRF_LOG_INFO("Shutdown complete."); NRF_LOG_FINAL_FLUSH(); if ((m_pwr_mgmt_evt == NRF_PWR_MGMT_EVT_PREPARE_RESET) || (m_pwr_mgmt_evt == NRF_PWR_MGMT_EVT_PREPARE_DFU)) { NVIC_SystemReset(); } else { // Enter System OFF. #ifdef SOFTDEVICE_PRESENT if (nrf_sdh_is_enabled()) { ret_code_t ret_code = sd_power_system_off(); ASSERT((ret_code == NRF_SUCCESS) || (ret_code == NRF_ERROR_SOFTDEVICE_NOT_ENABLED)); UNUSED_VARIABLE(ret_code); } #endif // SOFTDEVICE_PRESENT nrf_power_system_off(); } } #if NRF_PWR_MGMT_CONFIG_USE_SCHEDULER /**@brief Handle events from app_scheduler. */ static void scheduler_shutdown_handler(void * p_event_data, uint16_t event_size) { UNUSED_PARAMETER(p_event_data); UNUSED_PARAMETER(event_size); shutdown_process(); } #endif // NRF_PWR_MGMT_CONFIG_USE_SCHEDULER void nrf_pwr_mgmt_shutdown(nrf_pwr_mgmt_shutdown_t shutdown_type) { // Check if shutdown procedure is not started. if (!nrf_mtx_trylock(&m_sysoff_mtx)) { return; } if (shutdown_type != NRF_PWR_MGMT_SHUTDOWN_CONTINUE) { if (m_shutdown_started) { nrf_mtx_unlock(&m_sysoff_mtx); return; } else { m_pwr_mgmt_evt = (nrf_pwr_mgmt_evt_t)shutdown_type; m_shutdown_started = true; } } ASSERT(m_shutdown_started); NRF_LOG_INFO("Shutdown request %d", shutdown_type); #if NRF_PWR_MGMT_CONFIG_USE_SCHEDULER ret_code_t ret_code = app_sched_event_put(NULL, 0, scheduler_shutdown_handler); APP_ERROR_CHECK(ret_code); #else shutdown_process(); #endif // NRF_PWR_MGMT_CONFIG_USE_SCHEDULER nrf_mtx_unlock(&m_sysoff_mtx); } #endif // NRF_MODULE_ENABLED(NRF_PWR_MGMT)