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https://github.com/espressif/esp-idf.git
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270 lines
11 KiB
C
270 lines
11 KiB
C
/*
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* SPDX-FileCopyrightText: 2017-2024 Espressif Systems (Shanghai) CO LTD
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*
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* SPDX-License-Identifier: Apache-2.0
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*/
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#include "esp_efuse_utility.h"
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#include "soc/efuse_periph.h"
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#include "hal/efuse_hal.h"
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#include "esp_private/esp_clk.h"
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#include "esp_log.h"
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#include "assert.h"
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#include "sdkconfig.h"
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#include <sys/param.h>
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static const char *TAG = "efuse";
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#ifdef CONFIG_EFUSE_VIRTUAL
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extern uint32_t virt_blocks[EFUSE_BLK_MAX][COUNT_EFUSE_REG_PER_BLOCK];
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#endif // CONFIG_EFUSE_VIRTUAL
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/*Range addresses to read blocks*/
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const esp_efuse_range_addr_t range_read_addr_blocks[] = {
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{EFUSE_BLK0_RDATA0_REG, EFUSE_BLK0_RDATA6_REG}, // range address of EFUSE_BLK0
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{EFUSE_BLK1_RDATA0_REG, EFUSE_BLK1_RDATA7_REG}, // range address of EFUSE_BLK1
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{EFUSE_BLK2_RDATA0_REG, EFUSE_BLK2_RDATA7_REG}, // range address of EFUSE_BLK2
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{EFUSE_BLK3_RDATA0_REG, EFUSE_BLK3_RDATA7_REG} // range address of EFUSE_BLK3
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};
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static uint32_t write_mass_blocks[EFUSE_BLK_MAX][COUNT_EFUSE_REG_PER_BLOCK] = { 0 };
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/*Range addresses to write blocks (it is not real regs, it is a buffer) */
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const esp_efuse_range_addr_t range_write_addr_blocks[] = {
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{(uint32_t) &write_mass_blocks[EFUSE_BLK0][0], (uint32_t) &write_mass_blocks[EFUSE_BLK0][6]},
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{(uint32_t) &write_mass_blocks[EFUSE_BLK1][0], (uint32_t) &write_mass_blocks[EFUSE_BLK1][7]},
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{(uint32_t) &write_mass_blocks[EFUSE_BLK2][0], (uint32_t) &write_mass_blocks[EFUSE_BLK2][7]},
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{(uint32_t) &write_mass_blocks[EFUSE_BLK3][0], (uint32_t) &write_mass_blocks[EFUSE_BLK3][7]},
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};
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#ifndef CONFIG_EFUSE_VIRTUAL
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/* Addresses to write blocks*/
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const uint32_t start_write_addr[] = {
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EFUSE_BLK0_WDATA0_REG,
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EFUSE_BLK1_WDATA0_REG,
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EFUSE_BLK2_WDATA0_REG,
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EFUSE_BLK3_WDATA0_REG,
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};
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static void apply_repeat_encoding(const uint8_t *in_bytes, uint32_t *out_words, size_t in_bytes_len);
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// Update Efuse timing configuration
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static esp_err_t esp_efuse_set_timing(void)
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{
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uint32_t apb_freq_mhz = esp_clk_apb_freq() / 1000000;
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efuse_hal_set_timing(apb_freq_mhz);
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return ESP_OK;
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}
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#endif // ifndef CONFIG_EFUSE_VIRTUAL
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// Efuse read operation: copies data from physical efuses to efuse read registers.
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void esp_efuse_utility_clear_program_registers(void)
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{
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efuse_hal_clear_program_registers();
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}
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esp_err_t esp_efuse_utility_check_errors(void)
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{
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return ESP_OK;
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}
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// Burn values written to the efuse write registers
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esp_err_t esp_efuse_utility_burn_chip(void)
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{
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return esp_efuse_utility_burn_chip_opt(false, true);
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}
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esp_err_t esp_efuse_utility_burn_chip_opt(bool ignore_coding_errors, bool verify_written_data)
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{
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esp_err_t error = ESP_OK;
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#ifdef CONFIG_EFUSE_VIRTUAL
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(void) ignore_coding_errors;
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(void) verify_written_data;
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ESP_LOGW(TAG, "Virtual efuses enabled: Not really burning eFuses");
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for (int num_block = EFUSE_BLK_MAX - 1; num_block >= EFUSE_BLK0; num_block--) {
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int subblock = 0;
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for (uint32_t addr_wr_block = range_write_addr_blocks[num_block].start; addr_wr_block <= range_write_addr_blocks[num_block].end; addr_wr_block += 4) {
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virt_blocks[num_block][subblock++] |= REG_READ(addr_wr_block);
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}
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}
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#ifdef CONFIG_EFUSE_VIRTUAL_KEEP_IN_FLASH
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esp_efuse_utility_write_efuses_to_flash();
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#endif
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#else // CONFIG_EFUSE_VIRTUAL
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if (esp_efuse_set_timing() != ESP_OK) {
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ESP_LOGE(TAG, "Efuse fields are not burnt");
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} else {
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// Permanently update values written to the efuse write registers
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// It is necessary to process blocks in the order from MAX-> EFUSE_BLK0, because EFUSE_BLK0 has protection bits for other blocks.
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for (int num_block = EFUSE_BLK_MAX - 1; num_block >= EFUSE_BLK0; num_block--) {
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esp_efuse_coding_scheme_t scheme = esp_efuse_get_coding_scheme(num_block);
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bool need_burn_block = false;
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for (uint32_t addr_wr_block = range_write_addr_blocks[num_block].start; addr_wr_block <= range_write_addr_blocks[num_block].end; addr_wr_block += 4) {
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if (REG_READ(addr_wr_block) != 0) {
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need_burn_block = true;
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break;
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}
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}
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if (!need_burn_block) {
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continue;
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}
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if (error) {
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// It is done for a use case: BLOCK2 (Flash encryption key) could have an error (incorrect written data)
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// in this case we can not burn any data into BLOCK0 because it might set read/write protections of BLOCK2.
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ESP_LOGE(TAG, "BLOCK%d can not be burned because a previous block got an error, skipped.", num_block);
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continue;
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}
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efuse_hal_clear_program_registers();
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unsigned w_data_len;
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unsigned r_data_len;
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if (scheme == EFUSE_CODING_SCHEME_3_4) {
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esp_efuse_utility_apply_34_encoding((void *)range_write_addr_blocks[num_block].start, (uint32_t *)start_write_addr[num_block], ESP_EFUSE_LEN_OF_3_4_SCHEME_BLOCK_IN_BYTES);
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r_data_len = ESP_EFUSE_LEN_OF_3_4_SCHEME_BLOCK_IN_BYTES;
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w_data_len = 32;
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} else if (scheme == EFUSE_CODING_SCHEME_REPEAT) {
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apply_repeat_encoding((void *)range_write_addr_blocks[num_block].start, (uint32_t *)start_write_addr[num_block], 16);
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r_data_len = ESP_EFUSE_LEN_OF_REPEAT_BLOCK_IN_BYTES;
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w_data_len = 32;
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} else {
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r_data_len = (range_read_addr_blocks[num_block].end - range_read_addr_blocks[num_block].start) + sizeof(uint32_t);
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w_data_len = (range_write_addr_blocks[num_block].end - range_write_addr_blocks[num_block].start) + sizeof(uint32_t);
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memcpy((void *)start_write_addr[num_block], (void *)range_write_addr_blocks[num_block].start, w_data_len);
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}
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uint32_t backup_write_data[8];
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memcpy(backup_write_data, (void *)start_write_addr[num_block], w_data_len);
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int repeat_burn_op = 1;
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bool correct_written_data;
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bool coding_error_before = !ignore_coding_errors && efuse_hal_is_coding_error_in_block(num_block);
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if (coding_error_before) {
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ESP_LOGW(TAG, "BLOCK%d already has a coding error", num_block);
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}
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bool coding_error_occurred;
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do {
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ESP_LOGI(TAG, "BURN BLOCK%d", num_block);
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efuse_hal_program(0); // BURN a block
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bool coding_error_after = efuse_hal_is_coding_error_in_block(num_block);
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coding_error_occurred = !ignore_coding_errors && (coding_error_before != coding_error_after) && !coding_error_before;
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if (coding_error_occurred) {
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ESP_LOGW(TAG, "BLOCK%d got a coding error", num_block);
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}
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correct_written_data = (verify_written_data) ? esp_efuse_utility_is_correct_written_data(num_block, r_data_len) : true;
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if (!correct_written_data || coding_error_occurred) {
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ESP_LOGW(TAG, "BLOCK%d: next retry to fix an error [%d/3]...", num_block, repeat_burn_op);
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memcpy((void *)start_write_addr[num_block], (void *)backup_write_data, w_data_len);
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}
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} while ((!correct_written_data || coding_error_occurred) && repeat_burn_op++ < 3);
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if (coding_error_occurred) {
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ESP_LOGW(TAG, "Coding error was not fixed");
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}
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if (!correct_written_data) {
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ESP_LOGE(TAG, "Written data are incorrect");
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error = ESP_FAIL;
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}
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}
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}
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#endif // CONFIG_EFUSE_VIRTUAL
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esp_efuse_utility_reset();
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return error;
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}
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esp_err_t esp_efuse_utility_apply_34_encoding(const uint8_t *in_bytes, uint32_t *out_words, size_t in_bytes_len)
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{
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if (in_bytes == NULL || out_words == NULL || in_bytes_len % 6 != 0) {
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return ESP_ERR_INVALID_ARG;
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}
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while (in_bytes_len > 0) {
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uint8_t out[8];
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uint8_t xor = 0;
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uint8_t mul = 0;
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for (int i = 0; i < 6; i++) {
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xor ^= in_bytes[i];
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mul += (i + 1) * __builtin_popcount(in_bytes[i]);
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}
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memcpy(out, in_bytes, 6); // Data bytes
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out[6] = xor;
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out[7] = mul;
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memcpy(out_words, out, 8);
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in_bytes_len -= 6;
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in_bytes += 6;
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out_words += 2;
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}
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return ESP_OK;
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}
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#ifndef CONFIG_EFUSE_VIRTUAL
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static void apply_repeat_encoding(const uint8_t *in_bytes, uint32_t *out_words, size_t in_bytes_len)
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{
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for (unsigned i = 0; i < 2; i++) {
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memcpy(&out_words[i * 4], (uint32_t *)in_bytes, in_bytes_len);
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}
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}
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#endif // CONFIG_EFUSE_VIRTUAL
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static void read_r_data(esp_efuse_block_t num_block, uint32_t* buf_r_data)
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{
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int i = 0;
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for (uint32_t addr_rd_block = range_read_addr_blocks[num_block].start; addr_rd_block <= range_read_addr_blocks[num_block].end; addr_rd_block += 4, ++i) {
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buf_r_data[i] = esp_efuse_utility_read_reg(num_block, i);
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}
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}
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// This function just checkes that given data for blocks will not rise a coding issue during the burn operation.
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// Encoded data will be set during the burn operation.
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esp_err_t esp_efuse_utility_apply_new_coding_scheme()
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{
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uint8_t buf_r_data[COUNT_EFUSE_REG_PER_BLOCK * 4];
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// start with EFUSE_BLK1. EFUSE_BLK0 - always uses EFUSE_CODING_SCHEME_NONE.
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for (int num_block = EFUSE_BLK1; num_block < EFUSE_BLK_MAX; num_block++) {
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esp_efuse_coding_scheme_t scheme = esp_efuse_get_coding_scheme(num_block);
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if (scheme != EFUSE_CODING_SCHEME_NONE) {
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bool is_write_data = false;
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for (uint32_t addr_wr_block = range_write_addr_blocks[num_block].start; addr_wr_block <= range_write_addr_blocks[num_block].end; addr_wr_block += 4) {
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if (REG_READ(addr_wr_block)) {
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is_write_data = true;
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break;
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}
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}
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if (is_write_data) {
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read_r_data(num_block, (uint32_t*)buf_r_data);
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uint8_t* buf_w_data = (uint8_t*)range_write_addr_blocks[num_block].start;
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if (scheme == EFUSE_CODING_SCHEME_3_4) {
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if (*((uint32_t*)buf_w_data + 6) != 0 || *((uint32_t*)buf_w_data + 7) != 0) {
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return ESP_ERR_CODING;
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}
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for (int i = 0; i < ESP_EFUSE_LEN_OF_3_4_SCHEME_BLOCK_IN_BYTES; ++i) {
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if (buf_w_data[i] != 0) {
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int st_offset_buf = (i / 6) * 6;
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// check that place is free.
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for (int n = st_offset_buf; n < st_offset_buf + 6; ++n) {
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if (buf_r_data[n] != 0) {
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ESP_LOGE(TAG, "Bits are not empty. Write operation is forbidden.");
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return ESP_ERR_CODING;
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}
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}
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}
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}
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} else if (scheme == EFUSE_CODING_SCHEME_REPEAT) {
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for (int i = 4; i < 8; ++i) {
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if (*((uint32_t*)buf_w_data + i) != 0) {
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return ESP_ERR_CODING;
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}
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}
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}
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}
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}
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}
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return ESP_OK;
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}
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