OVMS3-idf/components/esp32/include/esp_system.h

// Copyright 2015-2016 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.

#ifndef __ESP_SYSTEM_H__
#define __ESP_SYSTEM_H__

#include <stdint.h>

#ifdef __cplusplus
extern "C" {
#endif

/** \defgroup System_APIs System APIs
  * @brief System APIs
  */

/** @addtogroup System_APIs
  * @{
  */

/**
  * @brief  Get information of the SDK version.
  *
  * @param  null
  *
  * @return Information of the SDK version.
  */
const char *system_get_sdk_version(void);

/**
  * @brief  Reset to default settings.
  *
  *         Reset to default settings of the following APIs : wifi_station_set_auto_connect,
  *         wifi_set_phy_mode, wifi_softap_set_config related, wifi_station_set_config
  *         related, and wifi_set_opmode.
  *
  * @param  null
  *
  * @return null
  */
void system_restore(void);

/**
  * @brief  Restart system.
  *
  * @param  null
  *
  * @return null
  */
void system_restart(void);

/**
  * @brief     Set the chip to deep-sleep mode.
  *
  *            The device will automatically wake up after the deep-sleep time set
  *            by the users. Upon waking up, the device boots up from user_init.
  *
  * @attention  The parameter time_in_us to be "uint64" is for further development. 
  *                  Only the low 32 bits of parameter time_in_us are avalable now.
  *
  * @param     uint64 time_in_us : deep-sleep time, only the low 32bits are avalable now. unit: microsecond
  *
  * @return    null
  */
void system_deep_sleep(uint64_t time_in_us);

/**
  * @brief  Get system time, unit: microsecond.
  *
  * @param  null
  *
  * @return System time, unit: microsecond.
  */
uint32_t system_get_time(void);

/**
  * @brief  Print the system memory distribution, including data/rodata/bss/heap.
  *
  * @param  null
  *
  * @return null
  */
void system_print_meminfo(void);

/**
  * @brief  Get the size of available heap.
  *
  * @param  null
  *
  * @return Available heap size.
  */
uint32_t system_get_free_heap_size(void);

/**
  * @brief  Get the chip ID.
  *
  * Example:          
  * <pre> 
  *         uint8 chip_id[6];
  *         system_get_chip_id(chip_id);
  * </pre>
  *
  * @param  uint8 *chip_id : the chip ID
  *
  * @return    true  : succeed
  * @return    false : fail
  */
bool system_get_chip_id(uint8_t *chip_id);

/**
  * @brief     Get RTC time, unit: RTC clock cycle.
  *
  * @param     null
  *
  * @return    RTC time.
  */
uint64_t system_get_rtc_time(void);

/**
  * @brief     Read user data from the RTC memory.
  *
  *            The user data segment (1024 bytes, as shown below) is used to store user data.
  *
  *             |<---- system data(512 bytes) ---->|<----------- user data(1024 bytes) --------->|
  *
  * @attention Read and write unit for data stored in the RTC memory is 4 bytes.
  * @attention src_addr is the block number (4 bytes per block). So when reading data
  *            at the beginning of the user data segment, src_addr will be 512/4 = 128,
  *            n will be data length.
  *
  * @param     uint16 src : source address of rtc memory, src_addr >= 128
  * @param     void *dst : data pointer
  * @param     uint16 n : data length, unit: byte
  *
  * @return    true  : succeed
  * @return    false : fail
  */
bool system_rtc_mem_read(uint16_t src, void *dst, uint16_t n);

/**
  * @brief     Write user data to  the RTC memory.
  *
  *            During deep-sleep, only RTC is working. So users can store their data
  *            in RTC memory if it is needed. The user data segment below (1024 bytes)
  *            is used to store the user data.
  *
  *            |<---- system data(512 bytes) ---->|<----------- user data(1024 bytes) --------->|
  *
  * @attention Read and write unit for data stored in the RTC memory is 4 bytes.
  * @attention src_addr is the block number (4 bytes per block). So when storing data
  *            at the beginning of the user data segment, src_addr will be 512/4 = 128,
  *            n will be data length.
  *
  * @param     uint16 src : source address of rtc memory, src_addr >= 128
  * @param     void *dst : data pointer
  * @param     uint16 n : data length, unit: byte
  *
  * @return    true  : succeed
  * @return    false : fail
  */
bool system_rtc_mem_write(uint16_t dst, const void *src, uint16_t n);

typedef enum {
    ADC1_PAD_GPIO36 = 0,
    ADC1_PAD_GPIO37,
    ADC1_PAD_GPIO38,
    ADC1_PAD_GPIO39,
    ADC1_PAD_GPIO32,
    ADC1_PAD_GPIO33,
    ADC1_PAD_GPIO34,
    ADC1_PAD_GPIO35
} adc1_read_pad_t;

typedef enum {
    ADC1_ATTEN_0DB = 0,
    ADC1_ATTEN_3DB,
    ADC1_ATTEN_6DB,
    ADC1_ATTEN_12DB
} adc1_read_atten_t;

/**
  * @brief    Read ADC1.
  *
  * @param     adc1_read_pad pad : the corresponding GPIO
  * @param     adc1_read_atten atten :  value of attenuation 
  *
  * @return    range of the return value is [0, 4096].
  *    - If atten == 0, the range of voltage can be measured is  [0, 1] V.
  *    - If atten == 1, the range of voltage can be measured is  [0, 1.4] V.
  *    - If atten == 2, the range of voltage can be measured is  [0, 2] V.
  *    - If atten == 3, the range of voltage can be measured is  [0, 4] V.
  */
uint16_t system_adc1_read(adc1_read_pad_t pad, adc1_read_atten_t atten);

/**
  * @brief     Measure the power voltage of VDD3P3 pin 3 and 4, unit : 1/1024 V.
  *
  * @attention system_get_vdd33 depends on RF, please do not use it if RF is disabled.
  *
  * @param     null
  *
  * @return    Power voltage of VDD33, unit : 1/1024 V
  */
uint16_t system_get_vdd33(void);

/**
  * @brief  Write data into flash with protection.
  *
  *         Flash read/write has to be 4-bytes aligned.
  *
  *         Protection of flash read/write :
  *             use 3 sectors (4KBytes per sector) to save  4KB data with protect,
  *             sector 0 and sector 1 are data sectors, back up each other,
  *             save data alternately, sector 2 is flag sector, point out which sector
  *             is keeping the latest data, sector 0 or sector 1.
  *
  * @param  uint16 start_sec : start sector (sector 0) of the 3 sectors which are
  *                            used for flash read/write protection.
  *    - For example, in IOT_Demo we can use the 3 sectors (3 * 4KB) starting from flash
  *      0x3D000 for flash read/write protection, so the parameter start_sec should be 0x3D
  * @param  void *param : pointer of the data to be written
  * @param  uint16 len : data length, should be less than a sector, which is 4 * 1024
  *
  * @return true  : succeed
  * @return false : fail
  */
bool system_param_save_with_protect(uint16_t start_sec, void *param, uint16_t len);

/**
  * @brief  Read the data saved into flash with the read/write protection.
  *
  *         Flash read/write has to be 4-bytes aligned.
  *
  *         Read/write protection of flash:
  *             use 3 sectors (4KB per sector) to save  4KB data with protect, sector
  *             0 and sector 1 are data sectors, back up each other, save data alternately,
  *             sector 2 is flag sector, point out which sector is keeping the latest data,
  *             sector 0 or sector 1.
  *
  * @param  uint16 start_sec : start sector (sector 0) of the 3 sectors used for
  *                            flash read/write protection. It cannot be sector 1 or sector 2.
  *    - For example, in IOT_Demo, the 3 sectors (3 * 4KB) starting from flash 0x3D000
  *      can be used for flash read/write protection.
  *      The parameter start_sec is 0x3D, and it cannot be 0x3E or 0x3F.
  * @param  uint16 offset : offset of data saved in sector
  * @param  void *param : data pointer
  * @param  uint16 len : data length, offset + len =< 4 * 1024
  *
  * @return true  : succeed
  * @return false : fail
  */
bool system_param_load(uint16_t start_sec, uint16_t offset, void *param, uint16_t len);


/** \defgroup System_boot_APIs Boot APIs
  * @brief boot APIs
  */

/** @addtogroup System_boot_APIs
  * @{
  */

/**
  * @}
  */
  
/** \defgroup Hardware_MAC_APIs Hardware MAC APIs
  * @brief Hardware MAC address APIs
  *
  * In WiFi MAC, only ESP32 station MAC is the hardware MAC, ESP32 softAP MAC is a software MAC 
  * calculated from ESP32 station MAC. 
  * So users need to call wifi_get_macaddr to query the ESP32 softAP MAC if ESP32 station MAC changed.
  *
  */

/** @addtogroup Hardware_MAC_APIs
  * @{
  */

typedef enum {
    DEFAULT_MAC = 0,    /**< Default hardware MAC provided by Espressif Systems */
    USER_MAC,           /**< User-define hardware MAC  */
} mac_group_t;

typedef enum {
    WIFI_MAC = 0,       /**< Hardware MAC address of ESP32 WiFi  */
    BT_MAC,             /**< Hardware MAC address of ESP32 bluetooth  */
} mac_type_t;

/**
  * @brief  Set user-define hardware MAC address.
  *
  * @attention  Hardware MAC address can only be set ONCE for each ESP32 chip.
  *
  * @param  mac_type type : type of hardware MAC address.
  * @param  uint8 *mac : user-define hardware MAC address, length: 6 bytes.
  *
  * @return  0 : succeed to set.
  * @return  1 : the hardware MAC has been set once, users can not set it any more.
  * @return  2 : fail to set.
  * @return  3 : invalid parameter.
  */
int system_efuse_program_user_mac(mac_type_t type, uint8_t *mac);

/**
  * @brief  Read hardware MAC address.
  *
  * @param  mac_group group : default MAC or user-defined MAC.
  * @param  mac_type type : type of hardware MAC address.
  * @param  uint8 *mac : the hardware MAC address, length: 6 bytes.
  *
  * @return  true  : succeed
  * @return  false : fail
  */
bool system_efuse_read_mac(mac_group_t group, mac_type_t type, uint8_t *mac);

/**
  * @brief  Set hardware MAC group, default MAC or user-defined MAC.
  *
  * @attention  This API needs system_restart to take effect.
  *
  * @param  mac_group group : default MAC or user-defined MAC.
  *
  * @return  true  : succeed
  * @return  false : fail
  */
bool system_efuse_set_mac_group(mac_group_t group);

/**
  * @brief  Get hardware MAC group, default MAC or user-defined MAC.
  *
  * @param  null
  *
  * @return  mac_group, the hardware MAC group.
  */
mac_group_t system_efuse_get_mac_group(void);

void system_init(void);

/**
  * @}
  */


/**
  * @}
  */

#ifdef __cplusplus
}
#endif

#endif /* __ESP_SYSTEM_H__ */