/* * SPDX-FileCopyrightText: 2020-2021 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Apache-2.0 */ // The LL layer for Timer Group register operations. // Note that most of the register operations in this layer are non-atomic operations. #pragma once #ifdef __cplusplus extern "C" { #endif #include #include #include "hal/wdt_types.h" #include "soc/rtc_cntl_periph.h" #include "soc/efuse_reg.h" #include "esp_attr.h" //Type check wdt_stage_action_t _Static_assert(WDT_STAGE_ACTION_OFF == RTC_WDT_STG_SEL_OFF, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_stage_action_t"); _Static_assert(WDT_STAGE_ACTION_INT == RTC_WDT_STG_SEL_INT, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_stage_action_t"); _Static_assert(WDT_STAGE_ACTION_RESET_CPU == RTC_WDT_STG_SEL_RESET_CPU, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_stage_action_t"); _Static_assert(WDT_STAGE_ACTION_RESET_SYSTEM == RTC_WDT_STG_SEL_RESET_SYSTEM, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_stage_action_t"); _Static_assert(WDT_STAGE_ACTION_RESET_RTC == RTC_WDT_STG_SEL_RESET_RTC, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_stage_action_t"); //Type check wdt_reset_sig_length_t _Static_assert(WDT_RESET_SIG_LENGTH_100ns == RTC_WDT_RESET_LENGTH_100_NS, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_reset_sig_length_t"); _Static_assert(WDT_RESET_SIG_LENGTH_200ns == RTC_WDT_RESET_LENGTH_200_NS, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_reset_sig_length_t"); _Static_assert(WDT_RESET_SIG_LENGTH_300ns == RTC_WDT_RESET_LENGTH_300_NS, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_reset_sig_length_t"); _Static_assert(WDT_RESET_SIG_LENGTH_400ns == RTC_WDT_RESET_LENGTH_400_NS, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_reset_sig_length_t"); _Static_assert(WDT_RESET_SIG_LENGTH_500ns == RTC_WDT_RESET_LENGTH_500_NS, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_reset_sig_length_t"); _Static_assert(WDT_RESET_SIG_LENGTH_800ns == RTC_WDT_RESET_LENGTH_800_NS, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_reset_sig_length_t"); _Static_assert(WDT_RESET_SIG_LENGTH_1_6us == RTC_WDT_RESET_LENGTH_1600_NS, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_reset_sig_length_t"); _Static_assert(WDT_RESET_SIG_LENGTH_3_2us == RTC_WDT_RESET_LENGTH_3200_NS, "Add mapping to LL watchdog timeout behavior, since it's no longer naturally compatible with wdt_reset_sig_length_t"); /** * @brief Enable the RWDT * * @param hw Start address of the peripheral registers. */ FORCE_INLINE_ATTR void rwdt_ll_enable(rtc_cntl_dev_t *hw) { hw->wdt_config0.en = 1; } /** * @brief Disable the RWDT * * @param hw Start address of the peripheral registers. * @note This function does not disable the flashboot mode. Therefore, given that * the MWDT is disabled using this function, a timeout can still occur * if the flashboot mode is simultaneously enabled. */ FORCE_INLINE_ATTR void rwdt_ll_disable(rtc_cntl_dev_t *hw) { hw->wdt_config0.en = 0; } /** * @brief Check if the RWDT is enabled * * @param hw Start address of the peripheral registers. * @return True if RTC WDT is enabled */ FORCE_INLINE_ATTR bool rwdt_ll_check_if_enabled(rtc_cntl_dev_t *hw) { return (hw->wdt_config0.en) ? true : false; } /** * @brief Configure a particular stage of the RWDT * * @param hw Start address of the peripheral registers. * @param stage Which stage to configure * @param timeout Number of timer ticks for the stage to timeout (see note). * @param behavior What action to take when the stage times out * * @note The value of of RWDT stage 0 timeout register is special, in * that an implicit multiplier is applied to that value to produce * and effective timeout tick value. The multiplier is dependent * on an EFuse value. Therefore, when configuring stage 0, the valid * values for the timeout argument are: * - If Efuse value is 0, any even number between [2,2*UINT32_MAX] * - If Efuse value is 1, any multiple of 4 between [4,4*UINT32_MAX] * - If Efuse value is 2, any multiple of 8 between [8,8*UINT32_MAX] * - If Efuse value is 3, any multiple of 16 between [16,16*UINT32_MAX] */ FORCE_INLINE_ATTR void rwdt_ll_config_stage(rtc_cntl_dev_t *hw, wdt_stage_t stage, uint32_t timeout_ticks, wdt_stage_action_t behavior) { switch (stage) { case WDT_STAGE0: hw->wdt_config0.stg0 = behavior; //Account of implicty multiplier applied to stage 0 timeout tick config value hw->wdt_config1 = timeout_ticks >> (1 + REG_GET_FIELD(EFUSE_RD_REPEAT_DATA0_REG, EFUSE_WDT_DELAY_SEL)); break; case WDT_STAGE1: hw->wdt_config0.stg1 = behavior; hw->wdt_config2 = timeout_ticks; break; case WDT_STAGE2: hw->wdt_config0.stg2 = behavior; hw->wdt_config3 = timeout_ticks; break; case WDT_STAGE3: hw->wdt_config0.stg3 = behavior; hw->wdt_config4 = timeout_ticks; break; default: abort(); } } /** * @brief Disable a particular stage of the RWDT * * @param hw Start address of the peripheral registers. * @param stage Which stage to disable */ FORCE_INLINE_ATTR void rwdt_ll_disable_stage(rtc_cntl_dev_t *hw, wdt_stage_t stage) { switch (stage) { case WDT_STAGE0: hw->wdt_config0.stg0 = WDT_STAGE_ACTION_OFF; break; case WDT_STAGE1: hw->wdt_config0.stg1 = WDT_STAGE_ACTION_OFF; break; case WDT_STAGE2: hw->wdt_config0.stg2 = WDT_STAGE_ACTION_OFF; break; case WDT_STAGE3: hw->wdt_config0.stg3 = WDT_STAGE_ACTION_OFF; break; default: abort(); } } /** * @brief Set the length of the CPU reset action * * @param hw Start address of the peripheral registers. * @param length Length of CPU reset signal */ FORCE_INLINE_ATTR void rwdt_ll_set_cpu_reset_length(rtc_cntl_dev_t *hw, wdt_reset_sig_length_t length) { hw->wdt_config0.cpu_reset_length = length; } /** * @brief Set the length of the system reset action * * @param hw Start address of the peripheral registers. * @param length Length of system reset signal */ FORCE_INLINE_ATTR void rwdt_ll_set_sys_reset_length(rtc_cntl_dev_t *hw, wdt_reset_sig_length_t length) { hw->wdt_config0.sys_reset_length = length; } /** * @brief Enable/Disable the RWDT flashboot mode. * * @param hw Start address of the peripheral registers. * @param enable True to enable RWDT flashboot mode, false to disable RWDT flashboot mode. * * @note Flashboot mode is independent and can trigger a WDT timeout event if the * WDT's enable bit is set to 0. Flashboot mode for RWDT is automatically enabled * on flashboot, and should be disabled by software when flashbooting completes. */ FORCE_INLINE_ATTR void rwdt_ll_set_flashboot_en(rtc_cntl_dev_t *hw, bool enable) { hw->wdt_config0.flashboot_mod_en = (enable) ? 1 : 0; } /** * @brief Enable/Disable the CPU0 to be reset on WDT_STAGE_ACTION_RESET_CPU * * @param hw Start address of the peripheral registers. * @param enable True to enable CPU0 to be reset, false to disable. */ FORCE_INLINE_ATTR void rwdt_ll_set_procpu_reset_en(rtc_cntl_dev_t *hw, bool enable) { hw->wdt_config0.procpu_reset_en = (enable) ? 1 : 0; } /** * @brief Enable/Disable the RWDT pause during sleep functionality * * @param hw Start address of the peripheral registers. * @param enable True to enable, false to disable. */ FORCE_INLINE_ATTR void rwdt_ll_set_pause_in_sleep_en(rtc_cntl_dev_t *hw, bool enable) { hw->wdt_config0.pause_in_slp = (enable) ? 1 : 0; } /** * @brief Enable/Disable chip reset on RWDT timeout. * * A chip reset also resets the analog portion of the chip. It will appear as a * POWERON reset rather than an RTC reset. * * @param hw Start address of the peripheral registers. * @param enable True to enable, false to disable. */ FORCE_INLINE_ATTR void rwdt_ll_set_chip_reset_en(rtc_cntl_dev_t *hw, bool enable) { hw->wdt_config0.chip_reset_en = (enable) ? 1 : 0; } /** * @brief Set width of chip reset signal * * @param hw Start address of the peripheral registers. * @param width Width of chip reset signal in terms of number of RTC_SLOW_CLK cycles */ FORCE_INLINE_ATTR void rwdt_ll_set_chip_reset_width(rtc_cntl_dev_t *hw, uint32_t width) { hw->wdt_config0.chip_reset_width = width; } /** * @brief Feed the RWDT * * Resets the current timer count and current stage. * * @param hw Start address of the peripheral registers. */ FORCE_INLINE_ATTR void rwdt_ll_feed(rtc_cntl_dev_t *hw) { hw->wdt_feed.feed = 1; } /** * @brief Enable write protection of the RWDT registers * * @param hw Start address of the peripheral registers. */ FORCE_INLINE_ATTR void rwdt_ll_write_protect_enable(rtc_cntl_dev_t *hw) { hw->wdt_wprotect = 0; } /** * @brief Disable write protection of the RWDT registers * * @param hw Start address of the peripheral registers. */ FORCE_INLINE_ATTR void rwdt_ll_write_protect_disable(rtc_cntl_dev_t *hw) { hw->wdt_wprotect = RTC_CNTL_WDT_WKEY_VALUE; } /** * @brief Enable the RWDT interrupt. * * @param hw Start address of the peripheral registers. * @param enable True to enable RWDT interrupt, false to disable. */ FORCE_INLINE_ATTR void rwdt_ll_set_intr_enable(rtc_cntl_dev_t *hw, bool enable) { hw->int_ena.rtc_wdt = (enable) ? 1 : 0; } /** * @brief Check if the RWDT interrupt has been triggered * * @param hw Start address of the peripheral registers. * @return True if the RWDT interrupt was triggered */ FORCE_INLINE_ATTR bool rwdt_ll_check_intr_status(rtc_cntl_dev_t *hw) { return (hw->int_st.rtc_wdt) ? true : false; } /** * @brief Clear the RWDT interrupt status. * * @param hw Start address of the peripheral registers. */ FORCE_INLINE_ATTR void rwdt_ll_clear_intr_status(rtc_cntl_dev_t *hw) { hw->int_clr.rtc_wdt = 1; } #ifdef __cplusplus } #endif