esp-idf/components/esp_adc_cal/esp_adc_cal_esp32s2.c

// Copyright 2019-2020 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.

#include <stdint.h>
#include "esp_types.h"
#include "driver/adc.h"
#include "soc/efuse_periph.h"
#include "esp_err.h"
#include "assert.h"
#include "esp_adc_cal.h"
#include "esp_efuse.h"

#define ADC_CAL_CHECK(cond, ret) ({                                         \
            if(!(cond)){                                                    \
                return ret;                                                 \
            }                                                               \
})
/* ------------------------ Characterization Constants ---------------------- */
#define ADC_CHAR_VERSION1_EFUSEVAL 1

static const uint32_t adc1_D_mean_low[] = {2231, 1643, 1290, 701};
static const uint32_t adc2_D_mean_low[] = {2305, 1693, 1343, 723};
static const uint32_t adc1_D_mean_high[] = {5775, 5692, 5725, 6209};
static const uint32_t adc2_D_mean_high[] = {5817, 5703, 5731, 6157};

static const int Dlow_data_length = 6;
static const int Dhigh_data_length = 8;

static const int adc_efuse_block = 2;
static const int adc_calib_ver_block = 2;
static const int adc_calib_ver_word_loc = 4;
static const int adc_calib_ver_offset = 4;
static const int adc_calib_ver_len = 3;

static const int adc1_atten0_Dlow_word_loc = 6;
static const int adc2_atten0_Dlow_word_loc = 7;
static const int adc1_atten0_Dhigh_word_loc = 4;
static const int adc2_atten0_Dhigh_word_loc = 5;

static const int adc1_atten0_Dlow_offset = 16;
static const int adc2_atten0_Dlow_offset = 8;
static const int adc1_atten0_Dhigh_offset = 16;
static const int adc2_atten0_Dhigh_offset = 16;
/* ----------------------- EFuse Access Functions --------------------------- */
/**
 *  Convenience function that reads a few bits from efuse and assembles them.
 *  For example, if the contents of the EFuse are:
 *   Word2: 0x1234 Word3:0x5678
 *   Then, setting base=2, offset=24, len=24 will yield 0x456.
 *  @note does not check for boundaries, make sure parameters are correct
 *  @param blk EFuse Block
 *  @param base the starting word
 *  @param offset the bit offset in the starting word
 *  @param bit how many consecutive bits to fetch
 *  @return the assembled number
 */
static uint32_t get_consecutive_bits_from_blk(int blk, uint32_t base, int offset, int len)
{

    base += offset / 32;
    offset %= 32;
    if (offset + len <= 32 || base == 7) {
        uint32_t result = esp_efuse_read_reg(blk, base);
        result <<= (32 - offset - len);
        result >>= (32 - len);
        return result;
    } else {
        // need to fetch both bytes.
        uint64_t result = ((uint64_t)esp_efuse_read_reg(blk, base + 1) << 32) + esp_efuse_read_reg(blk, base);
        result &= ((uint64_t)1 << (offset + len)) - 1;
        result >>= offset;
        return result;
    }
}

/**
 *  To save space in EFuse, the calibration values for adc are compressed.
 *  The compression scheme is: for X bits of ADC Efuse data,
 *  The actual ADC reading is: BASE_VALUE + 4*ADC_OFFSET
 *  where ADC_OFFSET = bits X-1:0 in Efuse, the highest bit is the sign bit (0:+, 1:-).
 *
 *  The following functions do this conversion.
 *  @param efuse_val raw values read from efuse.
 *  @param adc_num Specifies the channel number. The 2 adc channels each have different calibration values.
 *  @param attem Specifies the attenuation. Different attenuation level have different calibration values.
 */
static uint32_t efuse_low_val_to_d(uint16_t efuse_val, adc_unit_t adc_num, adc_atten_t atten)
{
    // efuse_val is 5 bits + 6th sign bit.
    int32_t rawoffsetval = efuse_val & ((1 << (Dlow_data_length - 1)) - 1);
    // if the sign bit is 1, it means it is a negative sign.
    int32_t offset = (efuse_val & (1 << (Dlow_data_length - 1))) ? (-rawoffsetval * 4) : (rawoffsetval * 4);
    if (adc_num == ADC_UNIT_1) {
        return offset + adc1_D_mean_low[atten - ADC_ATTEN_DB_0];
    } else {
        return offset + adc2_D_mean_low[atten - ADC_ATTEN_DB_0];
    }
}

static uint32_t efuse_high_val_to_d (uint16_t efuse_val, adc_unit_t adc_num, adc_atten_t atten)
{
    // efuse_val is 7 bits + 8th sign bit.
    int32_t rawoffsetval = efuse_val & ((1 << (Dhigh_data_length - 1)) - 1);
    int32_t offset = (efuse_val & (1 << (Dhigh_data_length - 1))) ? (-rawoffsetval * 4) : (rawoffsetval * 4);
    if (adc_num == ADC_UNIT_1) {
        return offset + adc1_D_mean_high[atten - ADC_ATTEN_DB_0];
    } else {
        return offset + adc2_D_mean_high[atten - ADC_ATTEN_DB_0];
    }

}

/**
 *  To save space in EFuse, the calibration values for adc are compressed.
 *  The compression scheme is: for X bits of ADC Efuse data,
 *  The actual ADC reading is: BASE_VALUE + 4*ADC_OFFSET
 *  where ADC_OFFSET = bits X-1:0 in Efuse, the highest bit is the sign bit (0:+, 1:-).
 *
 *  The following functions do the reading.
 *  @param efuse_val raw values read from efuse.
 *  @param adc_num Specifies the channel number. The 2 adc channels each have different calibration values.
 *  @param attem Specifies the attenuation. Different attenuation level have different calibration values.
 */
static uint32_t read_efuse_tp_low(adc_unit_t adc_num, adc_atten_t atten)
{
    // this fcn retrieves and decodes the calibration value stored in efuse.
    uint32_t base;
    int offset;
    // may need to move magic numbers out
    if (adc_num == ADC_UNIT_1) {
        // the first value is at the 16th bit of the 6th word of the efuse block 2, each value is 6 bits long.
        base = adc1_atten0_Dlow_word_loc;
        offset = adc1_atten0_Dlow_offset + Dlow_data_length * (atten - ADC_ATTEN_DB_0);

    } else {
        // the first value is at the 8th bit of the 7th word of the efuse block 2, each value is 6 bits long.
        base = adc2_atten0_Dlow_word_loc;
        offset = adc2_atten0_Dlow_offset + Dlow_data_length * (atten - ADC_ATTEN_DB_0);
    }
    uint32_t read_result = get_consecutive_bits_from_blk(adc_efuse_block, base, offset, Dlow_data_length);
    return read_result;
}

static uint32_t read_efuse_tp_high(adc_unit_t adc_num, adc_atten_t atten)
{
    // this fcn retrieves and decodes the calibration value stored in efuse.
    uint32_t base;
    int offset;

    if (adc_num == ADC_UNIT_1) {
        // the first value is at the 16th bit of the 4th word of the efuse block 2, each value is 8 bits long.
        base = adc1_atten0_Dhigh_word_loc;
        offset = adc1_atten0_Dhigh_offset + Dhigh_data_length * (atten - ADC_ATTEN_DB_0);

    } else {
        // the first value is at the 16th bit of the 5th word of the efuse block 2, each value is 8 bits long.
        base = adc2_atten0_Dhigh_word_loc;
        offset = adc2_atten0_Dhigh_offset + Dhigh_data_length * (atten - ADC_ATTEN_DB_0);
    }
    uint32_t read_result = get_consecutive_bits_from_blk(adc_efuse_block, base, offset, Dhigh_data_length);
    return read_result;
}

/* ----------------------- Characterization Functions ----------------------- */

// coeff_a and coeff_b are actually floats
// they are scaled to put them into uint32_t so that the headers do not have to be changed
static const int coeff_a_scaling = 65536;
static const int coeff_b_scaling = 1024;

/**
 *  The Two Point calibration measures the reading at two specific input voltages, and calculates the (assumed linear) relation
 *  between input voltage and ADC response. (Response = A * Vinput + B)
 *  A and B are scaled ints.
 *  @param high The ADC response at the higher voltage of the corresponding attenuation (600mV, 800mV, 1000mV, 2000mV).
 *  @param low The ADC response at the lower voltage of the corresponding attenuation (all 250mV).
 *
 */
static void characterize_using_two_point(adc_unit_t adc_num,
        adc_atten_t atten,
        uint32_t high,
        uint32_t low,
        uint32_t *coeff_a,
        uint32_t *coeff_b)
{
    // once we have recovered the reference high(Dhigh) and low(Dlow) readings, we can calculate a and b from
    // the measured high and low readings
    static const uint32_t v_high[] = {600, 800, 1000, 2000};
    static const uint32_t v_low = 250;
    *coeff_a = coeff_a_scaling * (v_high[atten] - v_low) / (high - low);
    *coeff_b = coeff_b_scaling * (v_low * high - v_high[atten] * low) / (high - low);
}


/* ------------------------- Public API ------------------------------------- */
esp_err_t esp_adc_cal_check_efuse(esp_adc_cal_value_t source)
{
    if (source != ESP_ADC_CAL_VAL_EFUSE_TP) {
        return ESP_ERR_NOT_SUPPORTED;
    }
    uint8_t adc1_atten0_dh = get_consecutive_bits_from_blk(adc_efuse_block, adc1_atten0_Dhigh_word_loc, adc1_atten0_Dhigh_offset, Dhigh_data_length);
    uint8_t adc2_atten0_dh = get_consecutive_bits_from_blk(adc_efuse_block, adc2_atten0_Dhigh_word_loc, adc2_atten0_Dhigh_offset, Dhigh_data_length);
    if (!adc1_atten0_dh || !adc2_atten0_dh) {
        return ESP_ERR_NOT_SUPPORTED;
    }
    uint8_t adc_encoding_version = get_consecutive_bits_from_blk(adc_calib_ver_block, adc_calib_ver_word_loc, adc_calib_ver_offset, adc_calib_ver_len);
    if (adc_encoding_version != 1) {
        // current version only accepts encoding ver 1.
        return ESP_ERR_INVALID_VERSION;
    }
    return ESP_OK;
}

esp_adc_cal_value_t esp_adc_cal_characterize(adc_unit_t adc_num,
        adc_atten_t atten,
        adc_bits_width_t bit_width,
        uint32_t default_vref,
        esp_adc_cal_characteristics_t *chars)
{
    // Check parameters
    assert((adc_num == ADC_UNIT_1) || (adc_num == ADC_UNIT_2));
    assert(chars != NULL);
    assert(bit_width == ADC_WIDTH_BIT_13);

    // Characterize based on efuse Two Point values. If these values are not present in efuse,
    // or efuse values are of a version that we do not recognize, automatically assume default values.
    uint32_t adc_calib_high, adc_calib_low;
    if (esp_adc_cal_check_efuse(ESP_ADC_CAL_VAL_EFUSE_TP) == ESP_OK) {
        adc_calib_high = read_efuse_tp_high(adc_num, atten);
        adc_calib_low = read_efuse_tp_low(adc_num, atten);
    } else {
        adc_calib_high = 0;
        adc_calib_low = 0;
    }
    uint32_t high = efuse_high_val_to_d(adc_calib_high, adc_num, atten);
    uint32_t low = efuse_low_val_to_d(adc_calib_low, adc_num, atten);
    characterize_using_two_point(adc_num, atten, high, low, &(chars->coeff_a), &(chars->coeff_b));
    // Initialize remaining fields
    chars->adc_num = adc_num;
    chars->atten = atten;
    chars->bit_width = bit_width;

    // these values are not used as the corresponding calibration themes are deprecated.
    chars->vref = 0;
    chars->low_curve = NULL;
    chars->high_curve = NULL;

    // in esp32s2 we only use the two point method to calibrate the adc.
    return ESP_ADC_CAL_VAL_EFUSE_TP;
}

uint32_t esp_adc_cal_raw_to_voltage(uint32_t adc_reading, const esp_adc_cal_characteristics_t *chars)
{
    ADC_CAL_CHECK(chars != NULL, ESP_ERR_INVALID_ARG);

    return adc_reading * chars->coeff_a / coeff_a_scaling + chars->coeff_b / coeff_b_scaling;
}

esp_err_t esp_adc_cal_get_voltage(adc_channel_t channel,
                                  const esp_adc_cal_characteristics_t *chars,
                                  uint32_t *voltage)
{
    // Check parameters
    ADC_CAL_CHECK(chars != NULL, ESP_ERR_INVALID_ARG);
    ADC_CAL_CHECK(voltage != NULL, ESP_ERR_INVALID_ARG);

    int adc_reading;
    if (chars->adc_num == ADC_UNIT_1) {
        //Check if channel is valid on ADC1
        ADC_CAL_CHECK((adc1_channel_t)channel < ADC1_CHANNEL_MAX, ESP_ERR_INVALID_ARG);
        adc_reading = adc1_get_raw(channel);
    } else {
        //Check if channel is valid on ADC2
        ADC_CAL_CHECK((adc2_channel_t)channel < ADC2_CHANNEL_MAX, ESP_ERR_INVALID_ARG);
        if (adc2_get_raw(channel, chars->bit_width, &adc_reading) != ESP_OK) {
            return ESP_ERR_TIMEOUT;     //Timed out waiting for ADC2
        }
    }
    *voltage = esp_adc_cal_raw_to_voltage((uint32_t)adc_reading, chars);
    return ESP_OK;
}
driver/adc: support for esp32s2 adc calibration scheme ESP32 lets the user choose from using Vref, Lookup Table, and Two-Point Calibration. In ESP32S2 only two-point calibration is supported. This commit support these changes in idf. Closes https://github.com/espressif/esp-idf/issues/5455 2020-07-09 08:55:52 -04:00			`// Copyright 2019-2020 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.`

			`#include <stdint.h>`
			`#include "esp_types.h"`
			`#include "driver/adc.h"`
			`#include "soc/efuse_periph.h"`
			`#include "esp_err.h"`
			`#include "assert.h"`
			`#include "esp_adc_cal.h"`
			`#include "esp_efuse.h"`

			`#define ADC_CAL_CHECK(cond, ret) ({ \`
			`if(!(cond)){ \`
			`return ret; \`
			`} \`
			`})`
			`/* ------------------------ Characterization Constants ---------------------- */`
			`#define ADC_CHAR_VERSION1_EFUSEVAL 1`

			`static const uint32_t adc1_D_mean_low[] = {2231, 1643, 1290, 701};`
			`static const uint32_t adc2_D_mean_low[] = {2305, 1693, 1343, 723};`
			`static const uint32_t adc1_D_mean_high[] = {5775, 5692, 5725, 6209};`
			`static const uint32_t adc2_D_mean_high[] = {5817, 5703, 5731, 6157};`

			`static const int Dlow_data_length = 6;`
			`static const int Dhigh_data_length = 8;`

			`static const int adc_efuse_block = 2;`
			`static const int adc_calib_ver_block = 2;`
			`static const int adc_calib_ver_word_loc = 4;`
			`static const int adc_calib_ver_offset = 4;`
			`static const int adc_calib_ver_len = 3;`

			`static const int adc1_atten0_Dlow_word_loc = 6;`
			`static const int adc2_atten0_Dlow_word_loc = 7;`
			`static const int adc1_atten0_Dhigh_word_loc = 4;`
			`static const int adc2_atten0_Dhigh_word_loc = 5;`

			`static const int adc1_atten0_Dlow_offset = 16;`
			`static const int adc2_atten0_Dlow_offset = 8;`
			`static const int adc1_atten0_Dhigh_offset = 16;`
			`static const int adc2_atten0_Dhigh_offset = 16;`
			`/* ----------------------- EFuse Access Functions --------------------------- */`
			`/**`
			`* Convenience function that reads a few bits from efuse and assembles them.`
			`* For example, if the contents of the EFuse are:`
			`* Word2: 0x1234 Word3:0x5678`
			`* Then, setting base=2, offset=24, len=24 will yield 0x456.`
			`* @note does not check for boundaries, make sure parameters are correct`
			`* @param blk EFuse Block`
			`* @param base the starting word`
			`* @param offset the bit offset in the starting word`
			`* @param bit how many consecutive bits to fetch`
			`* @return the assembled number`
			`*/`
			`static uint32_t get_consecutive_bits_from_blk(int blk, uint32_t base, int offset, int len)`
			`{`

			`base += offset / 32;`
			`offset %= 32;`
			`if (offset + len <= 32 \|\| base == 7) {`
			`uint32_t result = esp_efuse_read_reg(blk, base);`
			`result <<= (32 - offset - len);`
			`result >>= (32 - len);`
			`return result;`
			`} else {`
			`// need to fetch both bytes.`
			`uint64_t result = ((uint64_t)esp_efuse_read_reg(blk, base + 1) << 32) + esp_efuse_read_reg(blk, base);`
			`result &= ((uint64_t)1 << (offset + len)) - 1;`
			`result >>= offset;`
			`return result;`
			`}`
			`}`

			`/**`
			`* To save space in EFuse, the calibration values for adc are compressed.`
			`* The compression scheme is: for X bits of ADC Efuse data,`
			`* The actual ADC reading is: BASE_VALUE + 4*ADC_OFFSET`
			`* where ADC_OFFSET = bits X-1:0 in Efuse, the highest bit is the sign bit (0:+, 1:-).`
			`*`
			`* The following functions do this conversion.`
			`* @param efuse_val raw values read from efuse.`
			`* @param adc_num Specifies the channel number. The 2 adc channels each have different calibration values.`
			`* @param attem Specifies the attenuation. Different attenuation level have different calibration values.`
			`*/`
			`static uint32_t efuse_low_val_to_d(uint16_t efuse_val, adc_unit_t adc_num, adc_atten_t atten)`
			`{`
			`// efuse_val is 5 bits + 6th sign bit.`
			`int32_t rawoffsetval = efuse_val & ((1 << (Dlow_data_length - 1)) - 1);`
			`// if the sign bit is 1, it means it is a negative sign.`
			`int32_t offset = (efuse_val & (1 << (Dlow_data_length - 1))) ? (-rawoffsetval * 4) : (rawoffsetval * 4);`
			`if (adc_num == ADC_UNIT_1) {`
			`return offset + adc1_D_mean_low[atten - ADC_ATTEN_DB_0];`
			`} else {`
			`return offset + adc2_D_mean_low[atten - ADC_ATTEN_DB_0];`
			`}`
			`}`

			`static uint32_t efuse_high_val_to_d (uint16_t efuse_val, adc_unit_t adc_num, adc_atten_t atten)`
			`{`
			`// efuse_val is 7 bits + 8th sign bit.`
			`int32_t rawoffsetval = efuse_val & ((1 << (Dhigh_data_length - 1)) - 1);`
			`int32_t offset = (efuse_val & (1 << (Dhigh_data_length - 1))) ? (-rawoffsetval * 4) : (rawoffsetval * 4);`
			`if (adc_num == ADC_UNIT_1) {`
			`return offset + adc1_D_mean_high[atten - ADC_ATTEN_DB_0];`
			`} else {`
			`return offset + adc2_D_mean_high[atten - ADC_ATTEN_DB_0];`
			`}`

			`}`

			`/**`
			`* To save space in EFuse, the calibration values for adc are compressed.`
			`* The compression scheme is: for X bits of ADC Efuse data,`
			`* The actual ADC reading is: BASE_VALUE + 4*ADC_OFFSET`
			`* where ADC_OFFSET = bits X-1:0 in Efuse, the highest bit is the sign bit (0:+, 1:-).`
			`*`
			`* The following functions do the reading.`
			`* @param efuse_val raw values read from efuse.`
			`* @param adc_num Specifies the channel number. The 2 adc channels each have different calibration values.`
			`* @param attem Specifies the attenuation. Different attenuation level have different calibration values.`
			`*/`
			`static uint32_t read_efuse_tp_low(adc_unit_t adc_num, adc_atten_t atten)`
			`{`
			`// this fcn retrieves and decodes the calibration value stored in efuse.`
			`uint32_t base;`
			`int offset;`
			`// may need to move magic numbers out`
			`if (adc_num == ADC_UNIT_1) {`
			`// the first value is at the 16th bit of the 6th word of the efuse block 2, each value is 6 bits long.`
			`base = adc1_atten0_Dlow_word_loc;`
			`offset = adc1_atten0_Dlow_offset + Dlow_data_length * (atten - ADC_ATTEN_DB_0);`

			`} else {`
			`// the first value is at the 8th bit of the 7th word of the efuse block 2, each value is 6 bits long.`
			`base = adc2_atten0_Dlow_word_loc;`
			`offset = adc2_atten0_Dlow_offset + Dlow_data_length * (atten - ADC_ATTEN_DB_0);`
			`}`
			`uint32_t read_result = get_consecutive_bits_from_blk(adc_efuse_block, base, offset, Dlow_data_length);`
			`return read_result;`
			`}`

			`static uint32_t read_efuse_tp_high(adc_unit_t adc_num, adc_atten_t atten)`
			`{`
			`// this fcn retrieves and decodes the calibration value stored in efuse.`
			`uint32_t base;`
			`int offset;`

			`if (adc_num == ADC_UNIT_1) {`
			`// the first value is at the 16th bit of the 4th word of the efuse block 2, each value is 8 bits long.`
			`base = adc1_atten0_Dhigh_word_loc;`
			`offset = adc1_atten0_Dhigh_offset + Dhigh_data_length * (atten - ADC_ATTEN_DB_0);`

			`} else {`
			`// the first value is at the 16th bit of the 5th word of the efuse block 2, each value is 8 bits long.`
			`base = adc2_atten0_Dhigh_word_loc;`
			`offset = adc2_atten0_Dhigh_offset + Dhigh_data_length * (atten - ADC_ATTEN_DB_0);`
			`}`
			`uint32_t read_result = get_consecutive_bits_from_blk(adc_efuse_block, base, offset, Dhigh_data_length);`
			`return read_result;`
			`}`

			`/* ----------------------- Characterization Functions ----------------------- */`

			`// coeff_a and coeff_b are actually floats`
			`// they are scaled to put them into uint32_t so that the headers do not have to be changed`
			`static const int coeff_a_scaling = 65536;`
			`static const int coeff_b_scaling = 1024;`

			`/**`
			`* The Two Point calibration measures the reading at two specific input voltages, and calculates the (assumed linear) relation`
			`* between input voltage and ADC response. (Response = A * Vinput + B)`
			`* A and B are scaled ints.`
			`* @param high The ADC response at the higher voltage of the corresponding attenuation (600mV, 800mV, 1000mV, 2000mV).`
			`* @param low The ADC response at the lower voltage of the corresponding attenuation (all 250mV).`
			`*`
			`*/`
			`static void characterize_using_two_point(adc_unit_t adc_num,`
			`adc_atten_t atten,`
			`uint32_t high,`
			`uint32_t low,`
			`uint32_t *coeff_a,`
			`uint32_t *coeff_b)`
			`{`
			`// once we have recovered the reference high(Dhigh) and low(Dlow) readings, we can calculate a and b from`
			`// the measured high and low readings`
			`static const uint32_t v_high[] = {600, 800, 1000, 2000};`
			`static const uint32_t v_low = 250;`
			`coeff_a = coeff_a_scaling (v_high[atten] - v_low) / (high - low);`
			`coeff_b = coeff_b_scaling (v_low * high - v_high[atten] * low) / (high - low);`
			`}`


			`/* ------------------------- Public API ------------------------------------- */`
			`esp_err_t esp_adc_cal_check_efuse(esp_adc_cal_value_t source)`
			`{`
			`if (source != ESP_ADC_CAL_VAL_EFUSE_TP) {`
			`return ESP_ERR_NOT_SUPPORTED;`
			`}`
			`uint8_t adc1_atten0_dh = get_consecutive_bits_from_blk(adc_efuse_block, adc1_atten0_Dhigh_word_loc, adc1_atten0_Dhigh_offset, Dhigh_data_length);`
			`uint8_t adc2_atten0_dh = get_consecutive_bits_from_blk(adc_efuse_block, adc2_atten0_Dhigh_word_loc, adc2_atten0_Dhigh_offset, Dhigh_data_length);`
			`if (!adc1_atten0_dh \|\| !adc2_atten0_dh) {`
			`return ESP_ERR_NOT_SUPPORTED;`
			`}`
			`uint8_t adc_encoding_version = get_consecutive_bits_from_blk(adc_calib_ver_block, adc_calib_ver_word_loc, adc_calib_ver_offset, adc_calib_ver_len);`
			`if (adc_encoding_version != 1) {`
			`// current version only accepts encoding ver 1.`
			`return ESP_ERR_INVALID_VERSION;`
			`}`
			`return ESP_OK;`
			`}`

			`esp_adc_cal_value_t esp_adc_cal_characterize(adc_unit_t adc_num,`
			`adc_atten_t atten,`
			`adc_bits_width_t bit_width,`
			`uint32_t default_vref,`
			`esp_adc_cal_characteristics_t *chars)`
			`{`
			`// Check parameters`
			`assert((adc_num == ADC_UNIT_1) \|\| (adc_num == ADC_UNIT_2));`
			`assert(chars != NULL);`
			`assert(bit_width == ADC_WIDTH_BIT_13);`

			`// Characterize based on efuse Two Point values. If these values are not present in efuse,`
			`// or efuse values are of a version that we do not recognize, automatically assume default values.`
			`uint32_t adc_calib_high, adc_calib_low;`
			`if (esp_adc_cal_check_efuse(ESP_ADC_CAL_VAL_EFUSE_TP) == ESP_OK) {`
			`adc_calib_high = read_efuse_tp_high(adc_num, atten);`
			`adc_calib_low = read_efuse_tp_low(adc_num, atten);`
			`} else {`
			`adc_calib_high = 0;`
			`adc_calib_low = 0;`
			`}`
			`uint32_t high = efuse_high_val_to_d(adc_calib_high, adc_num, atten);`
			`uint32_t low = efuse_low_val_to_d(adc_calib_low, adc_num, atten);`
			`characterize_using_two_point(adc_num, atten, high, low, &(chars->coeff_a), &(chars->coeff_b));`
			`// Initialize remaining fields`
			`chars->adc_num = adc_num;`
			`chars->atten = atten;`
			`chars->bit_width = bit_width;`

			`// these values are not used as the corresponding calibration themes are deprecated.`
			`chars->vref = 0;`
			`chars->low_curve = NULL;`
			`chars->high_curve = NULL;`

			`// in esp32s2 we only use the two point method to calibrate the adc.`
			`return ESP_ADC_CAL_VAL_EFUSE_TP;`
			`}`

			`uint32_t esp_adc_cal_raw_to_voltage(uint32_t adc_reading, const esp_adc_cal_characteristics_t *chars)`
			`{`
			`ADC_CAL_CHECK(chars != NULL, ESP_ERR_INVALID_ARG);`

			`return adc_reading * chars->coeff_a / coeff_a_scaling + chars->coeff_b / coeff_b_scaling;`
			`}`

			`esp_err_t esp_adc_cal_get_voltage(adc_channel_t channel,`
			`const esp_adc_cal_characteristics_t *chars,`
			`uint32_t *voltage)`
			`{`
			`// Check parameters`
			`ADC_CAL_CHECK(chars != NULL, ESP_ERR_INVALID_ARG);`
			`ADC_CAL_CHECK(voltage != NULL, ESP_ERR_INVALID_ARG);`

			`int adc_reading;`
			`if (chars->adc_num == ADC_UNIT_1) {`
			`//Check if channel is valid on ADC1`
			`ADC_CAL_CHECK((adc1_channel_t)channel < ADC1_CHANNEL_MAX, ESP_ERR_INVALID_ARG);`
			`adc_reading = adc1_get_raw(channel);`
			`} else {`
			`//Check if channel is valid on ADC2`
			`ADC_CAL_CHECK((adc2_channel_t)channel < ADC2_CHANNEL_MAX, ESP_ERR_INVALID_ARG);`
			`if (adc2_get_raw(channel, chars->bit_width, &adc_reading) != ESP_OK) {`
			`return ESP_ERR_TIMEOUT; //Timed out waiting for ADC2`
			`}`
			`}`
			`*voltage = esp_adc_cal_raw_to_voltage((uint32_t)adc_reading, chars);`
			`return ESP_OK;`
			`}`