esp-idf/components/efuse/esp32s2/esp_efuse_rtc_table.c

160 wiersze
7.7 KiB
C

/*
* SPDX-FileCopyrightText: 2017-2021 Espressif Systems (Shanghai) CO LTD
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <stdbool.h>
#include "esp_efuse_rtc_table.h"
#include "esp_efuse.h"
#include "esp_efuse_table.h"
#include "esp_log.h"
#include "soc/soc_caps.h"
#define RTC_TBL_LOG_TAG "efuse_rtc_table"
/* Note on definition of tags
*
* For adc calibration, value = raw * multiplier + offset, but these values are kind of arbitrary so
* we use a lookup table to do the bookkeeping.
*
* The offset of an item can be calculated as follows:
* PARAM_OFFSET + ADC_NUM(which is the UNIT_COUNT minus 1) * ATTEN_NUM + ATTEN_NUM
* where PARAM_OFFSET is the index of the first item.
*
* ADC, ATTEN form a 2-dim array. For each (version number, extra parameters) tuple we keep a such array,
* and use if-else statements to choose which array we use.
* */
#define RTCCALIB_V1_ADCREADINGLOW_OFFSET RTCCALIB_V1IDX_A10L
#define RTCCALIB_V1_ADCREADINGHIGH_OFFSET RTCCALIB_V1IDX_A10H
#define RTCCALIB_V2_ADCREADINGHIGH_OFFSET RTCCALIB_V2IDX_A10H
#define RTCCALIB_V2_ADCREADINGINIT_OFFSET RTCCALIB_V2IDX_A10I
typedef struct {
const int tag; // should be the same as the index in adc_efuse_raw_map
const int block;
const int begin_bit;
const int length;
const int multiplier;
const int base;
const int depends;
} efuse_map_info_t;
static const efuse_map_info_t adc_efuse_raw_map[] = {
{0},
// INDEXING TAG, BLOCK, BEGIN_BIT, LENGTH, MULTIPLIER, OFFSET BASE, OFFSET DEP
{RTCCALIB_V1IDX_A10L, 2, 208, 6, 4, 2231, 0},
{RTCCALIB_V1IDX_A11L, 2, 214, 6, 4, 1643, 0},
{RTCCALIB_V1IDX_A12L, 2, 220, 6, 4, 1290, 0},
{RTCCALIB_V1IDX_A13L, 2, 226, 6, 4, 701, 0},
{RTCCALIB_V1IDX_A20L, 2, 232, 6, 4, 2305, 0},
{RTCCALIB_V1IDX_A21L, 2, 238, 6, 4, 1693, 0},
{RTCCALIB_V1IDX_A22L, 2, 244, 6, 4, 1343, 0},
{RTCCALIB_V1IDX_A23L, 2, 250, 6, 4, 723, 0},
{RTCCALIB_V1IDX_A10H, 2, 144, 8, 4, 5775, 0},
{RTCCALIB_V1IDX_A11H, 2, 152, 8, 4, 5693, 0},
{RTCCALIB_V1IDX_A12H, 2, 160, 8, 4, 5723, 0},
{RTCCALIB_V1IDX_A13H, 2, 168, 8, 4, 6209, 0},
{RTCCALIB_V1IDX_A20H, 2, 176, 8, 4, 5817, 0},
{RTCCALIB_V1IDX_A21H, 2, 184, 8, 4, 5703, 0},
{RTCCALIB_V1IDX_A22H, 2, 192, 8, 4, 5731, 0},
{RTCCALIB_V1IDX_A23H, 2, 200, 8, 4, 6157, 0},
{RTCCALIB_V2IDX_A10H, 2, 197, 6, 2, 169, RTCCALIB_V2IDX_A12H},
{RTCCALIB_V2IDX_A11H, 2, 203, 6, 2, -26, RTCCALIB_V2IDX_A12H},
{RTCCALIB_V2IDX_A12H, 2, 209, 9, 2, 126, RTCCALIB_V2IDX_A21H},
{RTCCALIB_V2IDX_A13H, 2, 218, 7, 2, 387, RTCCALIB_V2IDX_A12H},
{RTCCALIB_V2IDX_A20H, 2, 225, 7, 2, 177, RTCCALIB_V2IDX_A21H},
{RTCCALIB_V2IDX_A21H, 2, 232, 10, 2, 5815, 0},
{RTCCALIB_V2IDX_A22H, 2, 242, 7, 2, 27, RTCCALIB_V2IDX_A21H},
{RTCCALIB_V2IDX_A23H, 2, 249, 7, 2, 410, RTCCALIB_V2IDX_A21H},
{RTCCALIB_V2IDX_A10I, 2, 147, 8, 2, 1519, 0},
{RTCCALIB_V2IDX_A11I, 2, 155, 6, 2, 88, RTCCALIB_V2IDX_A10I},
{RTCCALIB_V2IDX_A12I, 2, 161, 5, 2, 8, RTCCALIB_V2IDX_A11I},
{RTCCALIB_V2IDX_A13I, 2, 166, 6, 2, 70, RTCCALIB_V2IDX_A12I},
{RTCCALIB_V2IDX_A20I, 2, 172, 8, 2, 1677, 0},
{RTCCALIB_V2IDX_A21I, 2, 180, 6, 2, 23, RTCCALIB_V2IDX_A20I},
{RTCCALIB_V2IDX_A22I, 2, 186, 5, 2, 6, RTCCALIB_V2IDX_A21I},
{RTCCALIB_V2IDX_A23I, 2, 191, 6, 2, 13, RTCCALIB_V2IDX_A22I},
{RTCCALIB_IDX_TMPSENSOR, 2, 135, 9, 1, 0, 0},
};
int esp_efuse_rtc_table_read_calib_version(void)
{
uint32_t result = 0;
esp_efuse_read_field_blob(ESP_EFUSE_BLK_VERSION_MINOR, &result, 3);
return result;
}
int esp_efuse_rtc_table_get_tag(int version, int adc_num, int atten, int extra_params)
{
int param_offset; // used to index which (adc_num, atten) array to use.
if (version == 1 && extra_params == RTCCALIB_V1_PARAM_VLOW) { // Volage LOW, Version 1
param_offset = RTCCALIB_V1_ADCREADINGLOW_OFFSET;
} else if (version == 1 && extra_params == RTCCALIB_V1_PARAM_VHIGH) {
param_offset = RTCCALIB_V1_ADCREADINGHIGH_OFFSET;
} else if (version == 2 && extra_params == RTCCALIB_V2_PARAM_VHIGH) {
param_offset = RTCCALIB_V2_ADCREADINGHIGH_OFFSET;
} else if (version == 2 && extra_params == RTCCALIB_V2_PARAM_VINIT) {
param_offset = RTCCALIB_V2_ADCREADINGINIT_OFFSET;
} else {
return -1;
}
int result = param_offset + (adc_num - 1) * RTCCALIB_ESP32S2_ATTENCOUNT + atten;
ESP_EARLY_LOGV(RTC_TBL_LOG_TAG, "V%d ADC%d ATTEN%d PARAM%d -> %d", version, adc_num, atten, extra_params, result);
return result;
}
/*
* Converts a signed-bit int to a normal (2-complement) int.
* */
static int signed_bit_to_int(uint32_t number, int len)
{
if (number >> (len - 1)) {
// first bit is set, unset that bit and negate the number.
number = -(number ^ (1 << (len - 1)));
}
return number;
}
int esp_efuse_rtc_table_get_raw_efuse_value(int tag)
{
assert(tag > 0);
if (tag == 0) {
return 0;
}
uint32_t val = 0;
esp_efuse_read_block(adc_efuse_raw_map[tag].block, &val, adc_efuse_raw_map[tag].begin_bit, adc_efuse_raw_map[tag].length);
int result = signed_bit_to_int(val, adc_efuse_raw_map[tag].length);
ESP_EARLY_LOGV(RTC_TBL_LOG_TAG, "Fetching raw for tag %d @blk%d bit%d len%d: %d", tag, adc_efuse_raw_map[tag].block, adc_efuse_raw_map[tag].begin_bit, adc_efuse_raw_map[tag].length,
result);
return result;
}
int esp_efuse_rtc_table_get_parsed_efuse_value(int tag, bool skip_efuse_reading)
{
assert(tag >= 0);
if (tag == 0) {
return 0; // tag 0 is the dummy tag and has no value. (used by depends)
}
int efuse_val = 0;
if (!skip_efuse_reading) {
efuse_val = esp_efuse_rtc_table_get_raw_efuse_value(tag) * adc_efuse_raw_map[tag].multiplier;
}
int result = efuse_val + adc_efuse_raw_map[tag].base +
esp_efuse_rtc_table_get_parsed_efuse_value(adc_efuse_raw_map[tag].depends, skip_efuse_reading);
ESP_EARLY_LOGV(RTC_TBL_LOG_TAG, "Parsed efuse val for tag %d: %d", tag, result);
return result;
}