esp-idf/components/soc/esp32s2/include/soc/rtc.h
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// Copyright 2015-2017 Espressif Systems (Shanghai) PTE LTD
//
// 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.
#pragma once
#include <stdbool.h>
#include <stddef.h>
#include <stdint.h>
#include "soc/soc.h"
#ifdef __cplusplus
extern "C" {
#endif
/**
* @file rtc.h
* @brief Low-level RTC power, clock, and sleep functions.
*
* Functions in this file facilitate configuration of ESP32's RTC_CNTL peripheral.
* RTC_CNTL peripheral handles many functions:
* - enables/disables clocks and power to various parts of the chip; this is
* done using direct register access (forcing power up or power down) or by
* allowing state machines to control power and clocks automatically
* - handles sleep and wakeup functions
* - maintains a 48-bit counter which can be used for timekeeping
*
* These functions are not thread safe, and should not be viewed as high level
* APIs. For example, while this file provides a function which can switch
* CPU frequency, this function is on its own is not sufficient to implement
* frequency switching in ESP-IDF context: some coordination with RTOS,
* peripheral drivers, and WiFi/BT stacks is also required.
*
* These functions will normally not be used in applications directly.
* ESP-IDF provides, or will provide, drivers and other facilities to use
* RTC subsystem functionality.
*
* The functions are loosely split into the following groups:
* - rtc_clk: clock switching, calibration
* - rtc_time: reading RTC counter, conversion between counter values and time
* - rtc_sleep: entry into sleep modes
* - rtc_init: initialization
*/
#define MHZ (1000000)
#define RTC_SLOW_CLK_X32K_CAL_TIMEOUT_THRES(cycles) (cycles << 12)
#define RTC_SLOW_CLK_8MD256_CAL_TIMEOUT_THRES(cycles) (cycles << 12)
#define RTC_SLOW_CLK_90K_CAL_TIMEOUT_THRES(cycles) (cycles << 10)
#define RTC_SLOW_CLK_FREQ_90K 90000
#define RTC_SLOW_CLK_FREQ_8MD256 (RTC_FAST_CLK_FREQ_APPROX / 256)
#define RTC_SLOW_CLK_FREQ_32K 32768
#define OTHER_BLOCKS_POWERUP 1
#define OTHER_BLOCKS_WAIT 1
/* Approximate mapping of voltages to RTC_CNTL_DBIAS_WAK, RTC_CNTL_DBIAS_SLP,
* RTC_CNTL_DIG_DBIAS_WAK, RTC_CNTL_DIG_DBIAS_SLP values.
* Valid if RTC_CNTL_DBG_ATTEN is 0.
*/
#define RTC_CNTL_DBIAS_0V90 0
#define RTC_CNTL_DBIAS_0V95 1
#define RTC_CNTL_DBIAS_1V00 2
#define RTC_CNTL_DBIAS_1V05 3
#define RTC_CNTL_DBIAS_1V10 4
#define RTC_CNTL_DBIAS_1V15 5
#define RTC_CNTL_DBIAS_1V20 6
#define RTC_CNTL_DBIAS_1V25 7
#define DELAY_FAST_CLK_SWITCH 3
#define DELAY_SLOW_CLK_SWITCH 300
#define DELAY_8M_ENABLE 50
/* Number of 8M/256 clock cycles to use for XTAL frequency estimation.
* 10 cycles will take approximately 300 microseconds.
*/
#define XTAL_FREQ_EST_CYCLES 10
/* Core voltage needs to be increased in two cases:
* 1. running at 240 MHz
* 2. running with 80MHz Flash frequency
*/
#ifdef CONFIG_ESPTOOLPY_FLASHFREQ_80M
#define DIG_DBIAS_80M_160M RTC_CNTL_DBIAS_1V25
#else
#define DIG_DBIAS_80M_160M RTC_CNTL_DBIAS_1V10
#endif
#define DIG_DBIAS_240M RTC_CNTL_DBIAS_1V25
#define DIG_DBIAS_XTAL RTC_CNTL_DBIAS_1V10
#define DIG_DBIAS_2M RTC_CNTL_DBIAS_1V00
#define RTC_CNTL_PLL_BUF_WAIT_DEFAULT 20
#define RTC_CNTL_XTL_BUF_WAIT_DEFAULT 100
#define RTC_CNTL_CK8M_WAIT_DEFAULT 20
#define RTC_CK8M_ENABLE_WAIT_DEFAULT 5
/* Various delays to be programmed into power control state machines */
#define RTC_CNTL_PLL_BUF_WAIT_SLP_CYCLES (1)
#define RTC_CNTL_XTL_BUF_WAIT_SLP_US (1000)
#define RTC_CNTL_CK8M_WAIT_SLP_CYCLES (4)
#define RTC_CNTL_WAKEUP_DELAY_CYCLES (4)
#define RTC_CNTL_CK8M_DFREQ_DEFAULT 172
#define RTC_CNTL_SCK_DCAP_DEFAULT 255
#define RTC_CNTL_ULPCP_TOUCH_START_WAIT_IN_SLEEP (0xFF)
#define RTC_CNTL_ULPCP_TOUCH_START_WAIT_DEFAULT (0x10)
/*
set sleep_init default param
*/
#define RTC_CNTL_DBG_ATTEN_LIGHTSLEEP_DEFAULT 6
#define RTC_CNTL_DBG_ATTEN_LIGHTSLEEP_NODROP 0
#define RTC_CNTL_DBG_ATTEN_DEEPSLEEP_DEFAULT 15
#define RTC_CNTL_DBG_ATTEN_MONITOR_DEFAULT 0
#define RTC_CNTL_BIASSLP_MONITOR_DEFAULT 0
#define RTC_CNTL_BIASSLP_SLEEP_ON 0
#define RTC_CNTL_BIASSLP_SLEEP_DEFAULT 1
#define RTC_CNTL_PD_CUR_MONITOR_DEFAULT 1
#define RTC_CNTL_PD_CUR_SLEEP_ON 0
#define RTC_CNTL_PD_CUR_SLEEP_DEFAULT 1
#define APLL_SDM_STOP_VAL_1 0x09
#define APLL_SDM_STOP_VAL_2_REV0 0x69
#define APLL_SDM_STOP_VAL_2_REV1 0x49
#define APLL_CAL_DELAY_1 0x0f
#define APLL_CAL_DELAY_2 0x3f
#define APLL_CAL_DELAY_3 0x1f
/**
* @brief Possible main XTAL frequency values.
*
* Enum values should be equal to frequency in MHz.
*/
typedef enum {
RTC_XTAL_FREQ_40M = 40, //!< 40 MHz XTAL
} rtc_xtal_freq_t;
/** @brief Fixed crystal frequency for this SoC
On an SoC where only one crystal frequency is supported,
using this macro is an alternative to calling rtc_clk_xtal_freq_get()
*/
#define RTC_XTAL_FREQ RTC_XTAL_FREQ_40M
/**
* @brief CPU frequency values
*/
typedef enum {
RTC_CPU_FREQ_XTAL = 0, //!< Main XTAL frequency
RTC_CPU_FREQ_80M = 1, //!< 80 MHz
RTC_CPU_FREQ_160M = 2, //!< 160 MHz
RTC_CPU_FREQ_240M = 3, //!< 240 MHz
RTC_CPU_FREQ_2M = 4, //!< 2 MHz
RTC_CPU_320M_80M = 5, //!< for test
RTC_CPU_320M_160M = 6, //!< for test
RTC_CPU_FREQ_XTAL_DIV2 = 7, //!< XTAL/2 after reset
} rtc_cpu_freq_t;
/**
* @brief CPU clock source
*/
typedef enum {
RTC_CPU_FREQ_SRC_XTAL, //!< XTAL
RTC_CPU_FREQ_SRC_PLL, //!< PLL (480M or 320M)
RTC_CPU_FREQ_SRC_8M, //!< Internal 8M RTC oscillator
RTC_CPU_FREQ_SRC_APLL //!< APLL
} rtc_cpu_freq_src_t;
/**
* @brief CPU clock configuration structure
*/
typedef struct rtc_cpu_freq_config_s {
rtc_cpu_freq_src_t source; //!< The clock from which CPU clock is derived
uint32_t source_freq_mhz; //!< Source clock frequency
uint32_t div; //!< Divider, freq_mhz = source_freq_mhz / div
uint32_t freq_mhz; //!< CPU clock frequency
} rtc_cpu_freq_config_t;
/**
* @brief RTC SLOW_CLK frequency values
*/
typedef enum {
RTC_SLOW_FREQ_RTC = 0, //!< Internal 90 kHz RC oscillator
RTC_SLOW_FREQ_32K_XTAL = 1, //!< External 32 kHz XTAL
RTC_SLOW_FREQ_8MD256 = 2, //!< Internal 8 MHz RC oscillator, divided by 256
} rtc_slow_freq_t;
/**
* @brief RTC FAST_CLK frequency values
*/
typedef enum {
RTC_FAST_FREQ_XTALD4 = 0, //!< Main XTAL, divided by 4
RTC_FAST_FREQ_8M = 1, //!< Internal 8 MHz RC oscillator
} rtc_fast_freq_t;
/* With the default value of CK8M_DFREQ, 8M clock frequency is 8.5 MHz +/- 7% */
#define RTC_FAST_CLK_FREQ_APPROX 8500000
#define RTC_CLK_CAL_FRACT 19 //!< Number of fractional bits in values returned by rtc_clk_cal
#define RTC_VDDSDIO_TIEH_1_8V 0 //!< TIEH field value for 1.8V VDDSDIO
#define RTC_VDDSDIO_TIEH_3_3V 1 //!< TIEH field value for 3.3V VDDSDIO
/**
* @brief Clock source to be calibrated using rtc_clk_cal function
*/
typedef enum {
RTC_CAL_RTC_MUX = 0, //!< Currently selected RTC SLOW_CLK
RTC_CAL_8MD256 = 1, //!< Internal 8 MHz RC oscillator, divided by 256
RTC_CAL_32K_XTAL = 2, //!< External 32 kHz XTAL
RTC_CAL_INTERNAL_OSC = 3 //!< Internal 150 kHz oscillator
} rtc_cal_sel_t;
/**
* Initialization parameters for rtc_clk_init
*/
typedef struct {
rtc_xtal_freq_t xtal_freq : 8; //!< Main XTAL frequency
uint32_t cpu_freq_mhz : 10; //!< CPU frequency to set, in MHz
rtc_fast_freq_t fast_freq : 1; //!< RTC_FAST_CLK frequency to set
rtc_slow_freq_t slow_freq : 2; //!< RTC_SLOW_CLK frequency to set
uint32_t clk_rtc_clk_div : 8;
uint32_t clk_8m_clk_div : 3; //!< RTC 8M clock divider (division is by clk_8m_div+1, i.e. 0 means 8MHz frequency)
uint32_t slow_clk_dcap : 8; //!< RTC 90k clock adjustment parameter (higher value leads to lower frequency)
uint32_t clk_8m_dfreq : 8; //!< RTC 8m clock adjustment parameter (higher value leads to higher frequency)
} rtc_clk_config_t;
/**
* Default initializer for rtc_clk_config_t
*/
#define RTC_CLK_CONFIG_DEFAULT() { \
.xtal_freq = RTC_XTAL_FREQ_40M, \
.cpu_freq_mhz = 80, \
.fast_freq = RTC_FAST_FREQ_8M, \
.slow_freq = RTC_SLOW_FREQ_RTC, \
.clk_rtc_clk_div = 0, \
.clk_8m_clk_div = 0, \
.slow_clk_dcap = RTC_CNTL_SCK_DCAP_DEFAULT, \
.clk_8m_dfreq = RTC_CNTL_CK8M_DFREQ_DEFAULT, \
}
typedef struct {
uint32_t dac : 6;
uint32_t dres : 3;
uint32_t dgm : 3;
uint32_t dbuf: 1;
} x32k_config_t;
#define X32K_CONFIG_DEFAULT() { \
.dac = 3, \
.dres = 3, \
.dgm = 3, \
.dbuf = 1, \
}
#if 0
#define X32K_CONFIG_BOOTSTRAP_DEFAULT() { \
.dac = 3, \
.dres = 3, \
.dgm = 0, \
}
typedef struct {
x32k_config_t x32k_cfg;
uint32_t bt_lpck_div_num : 12;
uint32_t bt_lpck_div_a : 12;
uint32_t bt_lpck_div_b : 12;
} x32k_bootstrap_config_t;
#define X32K_BOOTSTRAP_CONFIG_DEFAULT() { \
.x32k_cfg = X32K_CONFIG_BOOTSTRAP_DEFAULT(), \
.bt_lpck_div_num = 2441, \
.bt_lpck_div_a = 32, \
.bt_lpck_div_b = 13, \
}
#endif
typedef struct {
uint16_t wifi_powerup_cycles : 7;
uint16_t wifi_wait_cycles : 9;
uint16_t rtc_powerup_cycles : 7;
uint16_t rtc_wait_cycles : 9;
uint16_t dg_wrap_powerup_cycles : 7;
uint16_t dg_wrap_wait_cycles : 9;
uint16_t rtc_mem_powerup_cycles : 7;
uint16_t rtc_mem_wait_cycles : 9;
} rtc_init_config_t;
#define RTC_INIT_CONFIG_DEFAULT() { \
.wifi_powerup_cycles = OTHER_BLOCKS_POWERUP, \
.wifi_wait_cycles = OTHER_BLOCKS_WAIT, \
.rtc_powerup_cycles = OTHER_BLOCKS_POWERUP, \
.rtc_wait_cycles = OTHER_BLOCKS_WAIT, \
.dg_wrap_powerup_cycles = OTHER_BLOCKS_POWERUP, \
.dg_wrap_wait_cycles = OTHER_BLOCKS_WAIT, \
.rtc_mem_powerup_cycles = OTHER_BLOCKS_POWERUP, \
.rtc_mem_wait_cycles = OTHER_BLOCKS_WAIT, \
}
/* Two different calibration mode for slow clock */
#define RTC_TIME_CAL_ONEOFF_MODE 0
#define RTC_TIME_CAL_CYCLING_MODE 1
void rtc_clk_divider_set(uint32_t div);
void rtc_clk_8m_divider_set(uint32_t div);
/**
* Initialize clocks and set CPU frequency
*
* @param cfg clock configuration as rtc_clk_config_t
*/
void rtc_clk_init(rtc_clk_config_t cfg);
/**
* @brief Get main XTAL frequency
*
* Result is a constant as XTAL frequency is fixed.
*
* @note Function is included for ESP32 compatible code only. Code which only
* needs to support this SoC can use the macro RTC_XTAL_FREQ for this SoC's
* fixed crystal value.
*
* @return XTAL frequency in MHz, RTC_XTAL_FREQ_40M
*/
rtc_xtal_freq_t rtc_clk_xtal_freq_get(void);
/**
* @brief Enable or disable 32 kHz XTAL oscillator
* @param en true to enable, false to disable
*/
void rtc_clk_32k_enable(bool en);
/**
* @brief Configure 32 kHz XTAL oscillator to accept external clock signal
*/
void rtc_clk_32k_enable_external(void);
/**
* @brief Get the state of 32k XTAL oscillator
* @return true if 32k XTAL oscillator has been enabled
*/
bool rtc_clk_32k_enabled(void);
/**
* @brief Enable 32k oscillator, configuring it for fast startup time.
* Note: to achieve higher frequency stability, rtc_clk_32k_enable function
* must be called one the 32k XTAL oscillator has started up. This function
* will initially disable the 32k XTAL oscillator, so it should not be called
* when the system is using 32k XTAL as RTC_SLOW_CLK.
*
* @param cycle Number of 32kHz cycles to bootstrap external crystal.
* If 0, no square wave will be used to bootstrap crystal oscillation.
*/
void rtc_clk_32k_bootstrap(uint32_t cycle);
/**
* @brief Enable or disable 8 MHz internal oscillator
*
* Output from 8 MHz internal oscillator is passed into a configurable
* divider, which by default divides the input clock frequency by 256.
* Output of the divider may be used as RTC_SLOW_CLK source.
* Output of the divider is referred to in register descriptions and code as
* 8md256 or simply d256. Divider values other than 256 may be configured, but
* this facility is not currently needed, so is not exposed in the code.
*
* When 8MHz/256 divided output is not needed, the divider should be disabled
* to reduce power consumption.
*
* @param clk_8m_en true to enable 8MHz generator
* @param d256_en true to enable /256 divider
*/
void rtc_clk_8m_enable(bool clk_8m_en, bool d256_en);
/**
* @brief Get the state of 8 MHz internal oscillator
* @return true if the oscillator is enabled
*/
bool rtc_clk_8m_enabled(void);
/**
* @brief Get the state of /256 divider which is applied to 8MHz clock
* @return true if the divided output is enabled
*/
bool rtc_clk_8md256_enabled(void);
/**
* @brief Enable or disable APLL
*
* Output frequency is given by the formula:
* apll_freq = xtal_freq * (4 + sdm2 + sdm1/256 + sdm0/65536)/((o_div + 2) * 2)
*
* The dividend in this expression should be in the range of 240 - 600 MHz.
*
* In rev. 0 of ESP32, sdm0 and sdm1 are unused and always set to 0.
*
* @param enable true to enable, false to disable
* @param sdm0 frequency adjustment parameter, 0..255
* @param sdm1 frequency adjustment parameter, 0..255
* @param sdm2 frequency adjustment parameter, 0..63
* @param o_div frequency divider, 0..31
*/
void rtc_clk_apll_enable(bool enable, uint32_t sdm0, uint32_t sdm1, uint32_t sdm2, uint32_t o_div);
/**
* @brief Select source for RTC_SLOW_CLK
* @param slow_freq clock source (one of rtc_slow_freq_t values)
*/
void rtc_clk_slow_freq_set(rtc_slow_freq_t slow_freq);
/**
* @brief Get the RTC_SLOW_CLK source
* @return currently selected clock source (one of rtc_slow_freq_t values)
*/
rtc_slow_freq_t rtc_clk_slow_freq_get(void);
/**
* @brief Get the approximate frequency of RTC_SLOW_CLK, in Hz
*
* - if RTC_SLOW_FREQ_RTC is selected, returns ~90000
* - if RTC_SLOW_FREQ_32K_XTAL is selected, returns 32768
* - if RTC_SLOW_FREQ_8MD256 is selected, returns ~33000
*
* rtc_clk_cal function can be used to get more precise value by comparing
* RTC_SLOW_CLK frequency to the frequency of main XTAL.
*
* @return RTC_SLOW_CLK frequency, in Hz
*/
uint32_t rtc_clk_slow_freq_get_hz(void);
/**
* @brief Select source for RTC_FAST_CLK
* @param fast_freq clock source (one of rtc_fast_freq_t values)
*/
void rtc_clk_fast_freq_set(rtc_fast_freq_t fast_freq);
/**
* @brief Get the RTC_FAST_CLK source
* @return currently selected clock source (one of rtc_fast_freq_t values)
*/
rtc_fast_freq_t rtc_clk_fast_freq_get(void);
/**
* @brief Get CPU frequency config for a given frequency
* @param freq_mhz Frequency in MHz
* @param[out] out_config Output, CPU frequency configuration structure
* @return true if frequency can be obtained, false otherwise
*/
bool rtc_clk_cpu_freq_mhz_to_config(uint32_t freq_mhz, rtc_cpu_freq_config_t* out_config);
/**
* @brief Switch CPU frequency
*
* This function sets CPU frequency according to the given configuration
* structure. It enables PLLs, if necessary.
*
* @note This function in not intended to be called by applications in FreeRTOS
* environment. This is because it does not adjust various timers based on the
* new CPU frequency.
*
* @param config CPU frequency configuration structure
*/
void rtc_clk_cpu_freq_set_config(const rtc_cpu_freq_config_t* config);
/**
* @brief Switch CPU frequency (optimized for speed)
*
* This function is a faster equivalent of rtc_clk_cpu_freq_set_config.
* It works faster because it does not disable PLLs when switching from PLL to
* XTAL and does not enabled them when switching back. If PLL is not already
* enabled when this function is called to switch from XTAL to PLL frequency,
* or the PLL which is enabled is the wrong one, this function will fall back
* to calling rtc_clk_cpu_freq_set_config.
*
* Unlike rtc_clk_cpu_freq_set_config, this function relies on static data,
* so it is less safe to use it e.g. from a panic handler (when memory might
* be corrupted).
*
* @note This function in not intended to be called by applications in FreeRTOS
* environment. This is because it does not adjust various timers based on the
* new CPU frequency.
*
* @param config CPU frequency configuration structure
*/
void rtc_clk_cpu_freq_set_config_fast(const rtc_cpu_freq_config_t* config);
/**
* @brief Get the currently used CPU frequency configuration
* @param[out] out_config Output, CPU frequency configuration structure
*/
void rtc_clk_cpu_freq_get_config(rtc_cpu_freq_config_t* out_config);
/**
* @brief Switch CPU clock source to XTAL
*
* Short form for filling in rtc_cpu_freq_config_t structure and calling
* rtc_clk_cpu_freq_set_config when a switch to XTAL is needed.
* Assumes that XTAL frequency has been determined — don't call in startup code.
*/
void rtc_clk_cpu_freq_set_xtal(void);
/**
* @brief Store new APB frequency value into RTC_APB_FREQ_REG
*
* This function doesn't change any hardware clocks.
*
* Functions which perform frequency switching and change APB frequency call
* this function to update the value of APB frequency stored in RTC_APB_FREQ_REG
* (one of RTC general purpose retention registers). This should not normally
* be called from application code.
*
* @param apb_freq new APB frequency, in Hz
*/
void rtc_clk_apb_freq_update(uint32_t apb_freq);
/**
* @brief Get the current stored APB frequency.
* @return The APB frequency value as last set via rtc_clk_apb_freq_update(), in Hz.
*/
uint32_t rtc_clk_apb_freq_get(void);
uint32_t rtc_clk_cal_internal(rtc_cal_sel_t cal_clk, uint32_t slowclk_cycles, uint32_t cal_mode);
/**
* @brief Measure RTC slow clock's period, based on main XTAL frequency
*
* This function will time out and return 0 if the time for the given number
* of cycles to be counted exceeds the expected time twice. This may happen if
* 32k XTAL is being calibrated, but the oscillator has not started up (due to
* incorrect loading capacitance, board design issue, or lack of 32 XTAL on board).
*
* @param cal_clk clock to be measured
* @param slow_clk_cycles number of slow clock cycles to average
* @return average slow clock period in microseconds, Q13.19 fixed point format,
* or 0 if calibration has timed out
*/
uint32_t rtc_clk_cal(rtc_cal_sel_t cal_clk, uint32_t slow_clk_cycles);
/**
* @brief Measure ratio between XTAL frequency and RTC slow clock frequency
* @param cal_clk slow clock to be measured
* @param slow_clk_cycles number of slow clock cycles to average
* @return average ratio between XTAL frequency and slow clock frequency,
* Q13.19 fixed point format, or 0 if calibration has timed out.
*/
uint32_t rtc_clk_cal_ratio(rtc_cal_sel_t cal_clk, uint32_t slow_clk_cycles);
/**
* @brief Convert time interval from microseconds to RTC_SLOW_CLK cycles
* @param time_in_us Time interval in microseconds
* @param slow_clk_period Period of slow clock in microseconds, Q13.19
* fixed point format (as returned by rtc_slowck_cali).
* @return number of slow clock cycles
*/
uint64_t rtc_time_us_to_slowclk(uint64_t time_in_us, uint32_t period);
/**
* @brief Convert time interval from RTC_SLOW_CLK to microseconds
* @param time_in_us Time interval in RTC_SLOW_CLK cycles
* @param slow_clk_period Period of slow clock in microseconds, Q13.19
* fixed point format (as returned by rtc_slowck_cali).
* @return time interval in microseconds
*/
uint64_t rtc_time_slowclk_to_us(uint64_t rtc_cycles, uint32_t period);
/**
* @brief Get current value of RTC counter
*
* RTC has a 48-bit counter which is incremented by 2 every 2 RTC_SLOW_CLK
* cycles. Counter value is not writable by software. The value is not adjusted
* when switching to a different RTC_SLOW_CLK source.
*
* Note: this function may take up to 1 RTC_SLOW_CLK cycle to execute
*
* @return current value of RTC counter
*/
uint64_t rtc_time_get(void);
uint64_t rtc_light_slp_time_get(void);
uint64_t rtc_deep_slp_time_get(void);
/**
* @brief Busy loop until next RTC_SLOW_CLK cycle
*
* This function returns not earlier than the next RTC_SLOW_CLK clock cycle.
* In some cases (e.g. when RTC_SLOW_CLK cycle is very close), it may return
* one RTC_SLOW_CLK cycle later.
*/
void rtc_clk_wait_for_slow_cycle(void);
/**
* @brief Enable the rtc digital 8M clock
*
* This function is used to enable the digital rtc 8M clock to support peripherals.
* For enabling the analog 8M clock, using `rtc_clk_8M_enable` function above.
*/
void rtc_dig_clk8m_enable(void);
/**
* @brief Disable the rtc digital 8M clock
*
* This function is used to disable the digital rtc 8M clock, which is only used to support peripherals.
*/
void rtc_dig_clk8m_disable(void);
/**
* @brief Get whether the rtc digital 8M clock is enabled
*/
bool rtc_dig_8m_enabled(void);
/**
* @brief Calculate the real clock value after the clock calibration
*
* @param cal_val Average slow clock period in microseconds, fixed point value as returned from `rtc_clk_cal`
* @return Frequency of the clock in Hz
*/
uint32_t rtc_clk_freq_cal(uint32_t cal_val);
/**
* @brief Power down flags for rtc_sleep_pd function
*/
typedef struct {
uint32_t dig_fpu : 1; //!< Set to 1 to power down digital part in sleep
uint32_t rtc_fpu : 1; //!< Set to 1 to power down RTC memories in sleep
uint32_t cpu_fpu : 1; //!< Set to 1 to power down digital memories and CPU in sleep
uint32_t i2s_fpu : 1; //!< Set to 1 to power down I2S in sleep
uint32_t bb_fpu : 1; //!< Set to 1 to power down WiFi in sleep
uint32_t nrx_fpu : 1; //!< Set to 1 to power down WiFi in sleep
uint32_t fe_fpu : 1; //!< Set to 1 to power down WiFi in sleep
} rtc_sleep_pd_config_t;
/**
* Initializer for rtc_sleep_pd_config_t which sets all flags to the same value
*/
#define RTC_SLEEP_PD_CONFIG_ALL(val) {\
.dig_fpu = (val), \
.rtc_fpu = (val), \
.cpu_fpu = (val), \
.i2s_fpu = (val), \
.bb_fpu = (val), \
.nrx_fpu = (val), \
.fe_fpu = (val), \
}
void rtc_sleep_pd(rtc_sleep_pd_config_t cfg);
/**
* @brief sleep configuration for rtc_sleep_init function
*/
typedef struct {
uint32_t lslp_mem_inf_fpu : 1; //!< force normal voltage in sleep mode (digital domain memory)
uint32_t rtc_mem_inf_follow_cpu : 1;//!< keep low voltage in sleep mode (even if ULP/touch is used)
uint32_t rtc_fastmem_pd_en : 1; //!< power down RTC fast memory
uint32_t rtc_slowmem_pd_en : 1; //!< power down RTC slow memory
uint32_t rtc_peri_pd_en : 1; //!< power down RTC peripherals
uint32_t wifi_pd_en : 1; //!< power down WiFi
uint32_t int_8m_pd_en : 1; //!< Power down Internal 8M oscillator
uint32_t deep_slp : 1; //!< power down digital domain
uint32_t wdt_flashboot_mod_en : 1; //!< enable WDT flashboot mode
uint32_t dig_dbias_wak : 3; //!< set bias for digital domain, in active mode
uint32_t dig_dbias_slp : 3; //!< set bias for digital domain, in sleep mode
uint32_t rtc_dbias_wak : 3; //!< set bias for RTC domain, in active mode
uint32_t rtc_dbias_slp : 3; //!< set bias for RTC domain, in sleep mode
uint32_t dbg_atten_monitor : 4; //!< voltage parameter, in monitor mode
uint32_t bias_sleep_monitor : 1; //!< circuit control parameter, in monitor mode
uint32_t dbg_atten_slp : 4; //!< voltage parameter, in sleep mode
uint32_t bias_sleep_slp : 1; //!< circuit control parameter, in sleep mode
uint32_t pd_cur_monitor : 1; //!< circuit control parameter, in monitor mode
uint32_t pd_cur_slp : 1; //!< circuit control parameter, in sleep mode
uint32_t vddsdio_pd_en : 1; //!< power down VDDSDIO regulator
uint32_t xtal_fpu : 1; //!< keep main XTAL powered up in sleep
uint32_t deep_slp_reject : 1;
uint32_t light_slp_reject : 1;
} rtc_sleep_config_t;
#define RTC_SLEEP_PD_DIG BIT(0) //!< Deep sleep (power down digital domain)
#define RTC_SLEEP_PD_RTC_PERIPH BIT(1) //!< Power down RTC peripherals
#define RTC_SLEEP_PD_RTC_SLOW_MEM BIT(2) //!< Power down RTC SLOW memory
#define RTC_SLEEP_PD_RTC_FAST_MEM BIT(3) //!< Power down RTC FAST memory
#define RTC_SLEEP_PD_RTC_MEM_FOLLOW_CPU BIT(4) //!< RTC FAST and SLOW memories are automatically powered up and down along with the CPU
#define RTC_SLEEP_PD_VDDSDIO BIT(5) //!< Power down VDDSDIO regulator
#define RTC_SLEEP_PD_WIFI BIT(6)
#define RTC_SLEEP_PD_INT_8M BIT(7) //!< Power down Internal 8M oscillator
#define RTC_SLEEP_PD_XTAL BIT(8) //!< Power down main XTAL
//These flags are not power domains, but will affect some sleep parameters
#define RTC_SLEEP_DIG_USE_8M BIT(16)
#define RTC_SLEEP_USE_ADC_TESEN_MONITOR BIT(17)
#define RTC_SLEEP_NO_ULTRA_LOW BIT(18) //!< Avoid using ultra low power in deep sleep, in which RTCIO cannot be used as input, and RTCMEM can't work under high temperature
/**
* Default initializer for rtc_sleep_config_t
*
* This initializer sets all fields to "reasonable" values (e.g. suggested for
* production use) based on a combination of RTC_SLEEP_PD_x flags.
*
* @param RTC_SLEEP_PD_x flags combined using bitwise OR
*/
void rtc_sleep_get_default_config(uint32_t sleep_flags, rtc_sleep_config_t *out_config);
/**
* @brief Prepare the chip to enter sleep mode
*
* This function configures various power control state machines to handle
* entry into light sleep or deep sleep mode, switches APB and CPU clock source
* (usually to XTAL), and sets bias voltages for digital and RTC power domains.
*
* This function does not actually enter sleep mode; this is done using
* rtc_sleep_start function. Software may do some other actions between
* rtc_sleep_init and rtc_sleep_start, such as set wakeup timer and configure
* wakeup sources.
* @param cfg sleep mode configuration
*/
void rtc_sleep_init(rtc_sleep_config_t cfg);
/**
* @brief Low level initialize for rtc state machine waiting cycles after waking up
*
* This function configures the cycles chip need to wait for internal 8MHz
* oscillator and external 40MHz crystal. As we configure fixed time for waiting
* crystal, we need to pass period to calculate cycles. Now this function only
* used in lightsleep mode.
*
* @param slowclk_period re-calibrated slow clock period
*/
void rtc_sleep_low_init(uint32_t slowclk_period);
#define RTC_EXT0_TRIG_EN BIT(0) //!< EXT0 GPIO wakeup
#define RTC_EXT1_TRIG_EN BIT(1) //!< EXT1 GPIO wakeup
#define RTC_GPIO_TRIG_EN BIT(2) //!< GPIO wakeup (light sleep only)
#define RTC_TIMER_TRIG_EN BIT(3) //!< Timer wakeup
#define RTC_SDIO_TRIG_EN BIT(4) //!< SDIO wakeup (light sleep only)
#define RTC_WIFI_TRIG_EN BIT(5) //!< WIFI wakeup (light sleep only)
#define RTC_UART0_TRIG_EN BIT(6) //!< UART0 wakeup (light sleep only)
#define RTC_UART1_TRIG_EN BIT(7) //!< UART1 wakeup (light sleep only)
#define RTC_TOUCH_TRIG_EN BIT(8) //!< Touch wakeup
#define RTC_ULP_TRIG_EN BIT(9) //!< ULP wakeup
#define RTC_BT_TRIG_EN BIT(10) //!< BT wakeup (light sleep only)
#define RTC_COCPU_TRIG_EN BIT(11)
#define RTC_XTAL32K_DEAD_TRIG_EN BIT(12)
#define RTC_COCPU_TRAP_TRIG_EN BIT(13)
#define RTC_USB_TRIG_EN BIT(14)
/**
* @brief Enter deep or light sleep mode
*
* This function enters the sleep mode previously configured using rtc_sleep_init
* function. Before entering sleep, software should configure wake up sources
* appropriately (set up GPIO wakeup registers, timer wakeup registers,
* and so on).
*
* If deep sleep mode was configured using rtc_sleep_init, and sleep is not
* rejected by hardware (based on reject_opt flags), this function never returns.
* When the chip wakes up from deep sleep, CPU is reset and execution starts
* from ROM bootloader.
*
* If light sleep mode was configured using rtc_sleep_init, this function
* returns on wakeup, or if sleep is rejected by hardware.
*
* @param wakeup_opt bit mask wake up reasons to enable (RTC_xxx_TRIG_EN flags
* combined with OR)
* @param reject_opt bit mask of sleep reject reasons:
* - RTC_CNTL_GPIO_REJECT_EN
* - RTC_CNTL_SDIO_REJECT_EN
* These flags are used to prevent entering sleep when e.g.
* an external host is communicating via SDIO slave
* @param lslp_mem_inf_fpu If non-zero then the low power config is restored
* immediately on wake. Recommended for light sleep,
* has no effect if the system goes into deep sleep.
* @return non-zero if sleep was rejected by hardware
*/
uint32_t rtc_sleep_start(uint32_t wakeup_opt, uint32_t reject_opt, uint32_t lslp_mem_inf_fpu);
/**
* @brief Enter deep sleep mode
*
* Similar to rtc_sleep_start(), but additionally uses hardware to calculate the CRC value
* of RTC FAST memory. On wake, this CRC is used to determine if a deep sleep wake
* stub is valid to execute (if a wake address is set).
*
* No RAM is accessed while calculating the CRC and going into deep sleep, which makes
* this function safe to use even if the caller's stack is in RTC FAST memory.
*
* @note If no deep sleep wake stub address is set then calling rtc_sleep_start() will
* have the same effect and takes less time as CRC calculation is skipped.
*
* @note This function should only be called after rtc_sleep_init() has been called to
* configure the system for deep sleep.
*
* @param wakeup_opt - same as for rtc_sleep_start
* @param reject_opt - same as for rtc_sleep_start
*
* @return non-zero if sleep was rejected by hardware
*/
uint32_t rtc_deep_sleep_start(uint32_t wakeup_opt, uint32_t reject_opt);
/**
* RTC power and clock control initialization settings
*/
typedef struct {
uint32_t ck8m_wait : 8; //!< Number of rtc_fast_clk cycles to wait for 8M clock to be ready
uint32_t xtal_wait : 8; //!< Number of rtc_fast_clk cycles to wait for XTAL clock to be ready
uint32_t pll_wait : 8; //!< Number of rtc_fast_clk cycles to wait for PLL to be ready
uint32_t clkctl_init : 1; //!< Perform clock control related initialization
uint32_t pwrctl_init : 1; //!< Perform power control related initialization
uint32_t rtc_dboost_fpd : 1; //!< Force power down RTC_DBOOST
uint32_t xtal_fpu : 1;
uint32_t bbpll_fpu : 1;
uint32_t cpu_waiti_clk_gate : 1;
uint32_t cali_ocode : 1; //!< Calibrate Ocode to make bangap voltage more precise.
} rtc_config_t;
/**
* Default initializer of rtc_config_t.
*
* This initializer sets all fields to "reasonable" values (e.g. suggested for
* production use).
*/
#define RTC_CONFIG_DEFAULT() {\
.ck8m_wait = RTC_CNTL_CK8M_WAIT_DEFAULT, \
.xtal_wait = RTC_CNTL_XTL_BUF_WAIT_DEFAULT, \
.pll_wait = RTC_CNTL_PLL_BUF_WAIT_DEFAULT, \
.clkctl_init = 1, \
.pwrctl_init = 1, \
.rtc_dboost_fpd = 1, \
.xtal_fpu = 0, \
.bbpll_fpu = 0, \
.cpu_waiti_clk_gate = 1, \
.cali_ocode = 0\
}
/**
* Initialize RTC clock and power control related functions
* @param cfg configuration options as rtc_config_t
*/
void rtc_init(rtc_config_t cfg);
/**
* Structure describing vddsdio configuration
*/
typedef struct {
uint32_t force : 1; //!< If 1, use configuration from RTC registers; if 0, use EFUSE/bootstrapping pins.
uint32_t enable : 1; //!< Enable VDDSDIO regulator
uint32_t tieh : 1; //!< Select VDDSDIO voltage. One of RTC_VDDSDIO_TIEH_1_8V, RTC_VDDSDIO_TIEH_3_3V
uint32_t drefh : 2; //!< Tuning parameter for VDDSDIO regulator
uint32_t drefm : 2; //!< Tuning parameter for VDDSDIO regulator
uint32_t drefl : 2; //!< Tuning parameter for VDDSDIO regulator
} rtc_vddsdio_config_t;
/**
* Get current VDDSDIO configuration
* If VDDSDIO configuration is overridden by RTC, get values from RTC
* Otherwise, if VDDSDIO is configured by EFUSE, get values from EFUSE
* Otherwise, use default values and the level of MTDI bootstrapping pin.
* @return currently used VDDSDIO configuration
*/
rtc_vddsdio_config_t rtc_vddsdio_get_config(void);
/**
* Set new VDDSDIO configuration using RTC registers.
* If config.force == 1, this overrides configuration done using bootstrapping
* pins and EFUSE.
*
* @param config new VDDSDIO configuration
*/
void rtc_vddsdio_set_config(rtc_vddsdio_config_t config);
/**
* Using valid hardware calibration value to calibrate slowclk
* If there is no hardware calibration in process, start hardware calibration and wait for calibration finished
* @param cal_clk clock to be measured
* @param slowclk_cycles if no hardware calibration in process, use this amount of slow cycles to calibrate slowclk.
*/
uint32_t rtc_clk_cal_cycling(rtc_cal_sel_t cal_clk, uint32_t slowclk_cycles);
#ifdef __cplusplus
}
#endif