#include #include #include #include #include #include "unity.h" #include "esp_log.h" #include #include "esp_efuse.h" #include "esp_efuse_table.h" #include "esp_efuse_utility.h" #include "esp_efuse_test_table.h" #include "bootloader_random.h" #include "freertos/FreeRTOS.h" #include "freertos/task.h" #include "freertos/semphr.h" #include "test_utils.h" #include "sdkconfig.h" #include "esp_rom_efuse.h" #include "bootloader_common.h" static const char* TAG = "efuse_test"; static void test_read_blob(void) { esp_efuse_utility_update_virt_blocks(); esp_efuse_utility_debug_dump_blocks(); uint8_t mac[6]; ESP_LOGI(TAG, "1. Read MAC address"); memset(mac, 0, sizeof(mac)); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_MAC_FACTORY, &mac, sizeof(mac) * 8)); TEST_ASSERT_EQUAL_INT(sizeof(mac) * 8, esp_efuse_get_field_size(ESP_EFUSE_MAC_FACTORY)); ESP_LOGI(TAG, "MAC: %02x:%02x:%02x:%02x:%02x:%02x", mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]); #ifdef CONFIG_IDF_TARGET_ESP32 ESP_LOGI(TAG, "2. Check CRC by MAC"); uint8_t crc; TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_MAC_FACTORY_CRC, &crc, 8)); TEST_ASSERT_EQUAL_HEX8(crc, esp_rom_efuse_mac_address_crc8(mac, sizeof(mac))); #endif // CONFIG_IDF_TARGET_ESP32 ESP_LOGI(TAG, "3. Test check args"); uint32_t test_var; TEST_ESP_ERR(ESP_ERR_INVALID_ARG, esp_efuse_read_field_blob(ESP_EFUSE_MAC_FACTORY, NULL, 1)); TEST_ESP_ERR(ESP_ERR_INVALID_ARG, esp_efuse_read_field_blob(ESP_EFUSE_MAC_FACTORY, &test_var, 0)); uint8_t half_byte; TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_MAC_FACTORY, &half_byte, 4)); TEST_ASSERT_EQUAL_HEX8(mac[0]&0x0F, half_byte); uint8_t buff[7] = {0x59}; TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_MAC_FACTORY, &buff, sizeof(buff) * 8)); TEST_ASSERT_TRUE_MESSAGE(memcmp(mac, buff, sizeof(mac)) == 0, "Operation read blob is not success"); TEST_ASSERT_EQUAL_HEX8(0, buff[6]); } TEST_CASE("efuse test read_field_blob", "[efuse]") { test_read_blob(); } static void test_read_cnt(void) { esp_efuse_utility_update_virt_blocks(); esp_efuse_utility_debug_dump_blocks(); ESP_LOGI(TAG, "1. Test check args"); size_t cnt; TEST_ESP_ERR(ESP_ERR_INVALID_ARG, esp_efuse_read_field_cnt(ESP_EFUSE_MAC_FACTORY, NULL)); ESP_LOGI(TAG, "2. Read MAC address"); uint8_t mac[6]; memset(mac, 0, sizeof(mac)); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_MAC_FACTORY, &mac, 48)); TEST_ESP_OK(esp_efuse_read_field_cnt(ESP_EFUSE_MAC_FACTORY, &cnt)); size_t cnt_summ = 0; for (int i = 0; i < sizeof(mac); ++i) { cnt_summ += __builtin_popcount(mac[i]); } TEST_ASSERT_EQUAL_INT(cnt_summ, cnt); } TEST_CASE("efuse test read_field_cnt", "[efuse]") { test_read_cnt(); } // If using efuse is real, then turn off writing tests. #ifdef CONFIG_EFUSE_VIRTUAL static void test_write_blob(void) { esp_efuse_coding_scheme_t scheme = esp_efuse_get_coding_scheme(EFUSE_BLK1); esp_efuse_utility_erase_virt_blocks(); esp_efuse_utility_debug_dump_blocks(); ESP_LOGI(TAG, "1. Test check args"); uint16_t test1_len_8 = 0x5FAA; TEST_ESP_ERR(ESP_ERR_INVALID_ARG, esp_efuse_write_field_blob(ESP_EFUSE_MAC_FACTORY, &test1_len_8, 0)); TEST_ESP_ERR(ESP_ERR_INVALID_ARG, esp_efuse_write_field_blob(ESP_EFUSE_TEST1_LEN_8, NULL, 8)); TEST_ASSERT_EQUAL_HEX16(0x5FAA, test1_len_8); ESP_LOGI(TAG, "2. Test write operation"); TEST_ESP_OK(esp_efuse_write_field_blob(ESP_EFUSE_TEST1_LEN_8, &test1_len_8, 7)); TEST_ESP_ERR(ESP_ERR_EFUSE_REPEATED_PROG, esp_efuse_write_field_blob(ESP_EFUSE_TEST1_LEN_8, &test1_len_8, 9)); uint16_t val_read1 = 0; TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_TEST1_LEN_8, &val_read1, 8)); TEST_ASSERT_EQUAL_HEX16(test1_len_8&((1 << 7) - 1), val_read1); uint16_t test1_len_8_hi = test1_len_8 & ~((1 << 7) - 1); if (scheme == EFUSE_CODING_SCHEME_NONE) { TEST_ESP_OK(esp_efuse_write_field_blob(ESP_EFUSE_TEST1_LEN_8, &test1_len_8_hi, 8)); } else { TEST_ESP_ERR(ESP_ERR_CODING, esp_efuse_write_field_blob(ESP_EFUSE_TEST1_LEN_8, &test1_len_8_hi, 8)); } TEST_ESP_ERR(ESP_ERR_EFUSE_REPEATED_PROG, esp_efuse_write_field_blob(ESP_EFUSE_TEST1_LEN_8, &test1_len_8, 8)); val_read1 = 0; TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_TEST1_LEN_8, &val_read1, 16)); if (scheme == EFUSE_CODING_SCHEME_NONE) { TEST_ASSERT_EQUAL_HEX16(test1_len_8&0x00FF, val_read1); } else { TEST_ASSERT_EQUAL_HEX16(test1_len_8&0x007F, val_read1); } if (scheme != EFUSE_CODING_SCHEME_NONE) { esp_efuse_utility_erase_virt_blocks(); ESP_LOGI(TAG, "erase virt blocks"); } uint16_t test2_len_16 = 0xAA55; uint32_t val_32 = test2_len_16; TEST_ESP_OK(esp_efuse_write_field_blob(ESP_EFUSE_TEST2_LEN_16, &val_32, 17)); TEST_ESP_ERR(ESP_ERR_EFUSE_REPEATED_PROG, esp_efuse_write_field_blob(ESP_EFUSE_TEST2_LEN_16, &test2_len_16, 16)); uint16_t test_16 = 0; TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_TEST2_LEN_16, &test_16, 16)); TEST_ASSERT_EQUAL_HEX16(test2_len_16, test_16); ESP_LOGI(TAG, "3. Test field with one bit"); uint8_t test5_len_1; TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_TEST5_LEN_1, &test5_len_1, 1)); TEST_ASSERT_EQUAL_HEX8(0, test5_len_1); test5_len_1 = 0; TEST_ESP_OK(esp_efuse_write_field_blob(ESP_EFUSE_TEST5_LEN_1, &test5_len_1, 1)); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_TEST5_LEN_1, &test5_len_1, 1)); TEST_ASSERT_EQUAL_HEX8(0, test5_len_1); test5_len_1 = 1; TEST_ESP_OK(esp_efuse_write_field_blob(ESP_EFUSE_TEST5_LEN_1, &test5_len_1, 1)); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_TEST5_LEN_1, &test5_len_1, 1)); TEST_ASSERT_EQUAL_HEX8(1, test5_len_1); test5_len_1 = 1; TEST_ESP_ERR(ESP_ERR_EFUSE_REPEATED_PROG, esp_efuse_write_field_blob(ESP_EFUSE_TEST5_LEN_1, &test5_len_1, 1)); esp_efuse_utility_debug_dump_blocks(); } TEST_CASE("efuse test write_field_blob", "[efuse]") { test_write_blob(); } static void test_write_cnt(void) { esp_efuse_coding_scheme_t scheme = esp_efuse_get_coding_scheme(EFUSE_BLK1); esp_efuse_utility_erase_virt_blocks(); esp_efuse_utility_debug_dump_blocks(); ESP_LOGI(TAG, "1. Test check args"); size_t test3_len_6 = 5; TEST_ESP_ERR(ESP_ERR_INVALID_ARG, esp_efuse_write_field_cnt(ESP_EFUSE_MAC_FACTORY, 0)); TEST_ESP_ERR(ESP_ERR_INVALID_ARG, esp_efuse_write_field_cnt(NULL, 5)); TEST_ESP_ERR(ESP_ERR_INVALID_ARG, esp_efuse_write_field_cnt(ESP_EFUSE_TEST3_LEN_6, 0)); ESP_LOGI(TAG, "2. Test write operation"); TEST_ESP_OK(esp_efuse_read_field_cnt(ESP_EFUSE_TEST3_LEN_6, &test3_len_6)); TEST_ASSERT_EQUAL_INT(0, test3_len_6); TEST_ESP_OK(esp_efuse_write_field_cnt(ESP_EFUSE_TEST3_LEN_6, 1)); TEST_ESP_OK(esp_efuse_read_field_cnt(ESP_EFUSE_TEST3_LEN_6, &test3_len_6)); TEST_ASSERT_EQUAL_INT(1, test3_len_6); if (scheme == EFUSE_CODING_SCHEME_NONE) { TEST_ESP_OK(esp_efuse_write_field_cnt(ESP_EFUSE_TEST3_LEN_6, 1)); } else { esp_efuse_utility_erase_virt_blocks(); ESP_LOGI(TAG, "erase virt blocks"); TEST_ESP_OK(esp_efuse_write_field_cnt(ESP_EFUSE_TEST3_LEN_6, 2)); } TEST_ESP_OK(esp_efuse_read_field_cnt(ESP_EFUSE_TEST3_LEN_6, &test3_len_6)); TEST_ASSERT_EQUAL_INT(2, test3_len_6); if (scheme == EFUSE_CODING_SCHEME_NONE) { TEST_ESP_OK(esp_efuse_write_field_cnt(ESP_EFUSE_TEST3_LEN_6, 3)); } else { esp_efuse_utility_erase_virt_blocks(); ESP_LOGI(TAG, "erase virt blocks"); TEST_ESP_OK(esp_efuse_write_field_cnt(ESP_EFUSE_TEST3_LEN_6, 5)); } TEST_ESP_OK(esp_efuse_read_field_cnt(ESP_EFUSE_TEST3_LEN_6, &test3_len_6)); TEST_ASSERT_EQUAL_INT(5, test3_len_6); esp_efuse_utility_debug_dump_blocks(); ESP_LOGI(TAG, "3. Test field is full set"); int max_bits = esp_efuse_get_field_size(ESP_EFUSE_TEST4_LEN_182); size_t test4_len_182; esp_efuse_utility_debug_dump_blocks(); for (int i = 0; i < max_bits / 26; ++i) { ESP_LOGD(TAG, "# %d", i); if (scheme == EFUSE_CODING_SCHEME_NONE) { TEST_ESP_OK(esp_efuse_write_field_cnt(ESP_EFUSE_TEST4_LEN_182, 26)); } else { esp_efuse_utility_erase_virt_blocks(); TEST_ESP_OK(esp_efuse_write_field_cnt(ESP_EFUSE_TEST4_LEN_182, (i + 1) * 26)); } TEST_ESP_OK(esp_efuse_read_field_cnt(ESP_EFUSE_TEST4_LEN_182, &test4_len_182)); esp_efuse_utility_debug_dump_blocks(); TEST_ASSERT_EQUAL_INT((i + 1) * 26, test4_len_182); } esp_efuse_utility_debug_dump_blocks(); ESP_LOGI(TAG, "4. Test field ESP_EFUSE_TEST4_LEN_182 is full"); TEST_ESP_ERR(ESP_ERR_EFUSE_CNT_IS_FULL, esp_efuse_write_field_cnt(ESP_EFUSE_TEST4_LEN_182, 1)); ESP_LOGI(TAG, "3. Test field with one bit"); size_t test5_len_1; TEST_ESP_OK(esp_efuse_read_field_cnt(ESP_EFUSE_TEST5_LEN_1, &test5_len_1)); TEST_ASSERT_EQUAL_HEX8(0, test5_len_1); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_TEST5_LEN_1, &test5_len_1, 1)); TEST_ASSERT_EQUAL_HEX8(0, test5_len_1); if (scheme != EFUSE_CODING_SCHEME_NONE) { esp_efuse_utility_erase_virt_blocks(); ESP_LOGI(TAG, "erase virt blocks"); } test5_len_1 = 1; TEST_ESP_OK(esp_efuse_write_field_cnt(ESP_EFUSE_TEST5_LEN_1, test5_len_1)); TEST_ESP_OK(esp_efuse_read_field_cnt(ESP_EFUSE_TEST5_LEN_1, &test5_len_1)); TEST_ASSERT_EQUAL_HEX8(1, test5_len_1); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_TEST5_LEN_1, &test5_len_1, 1)); TEST_ASSERT_EQUAL_HEX8(1, test5_len_1); test5_len_1 = 1; TEST_ESP_ERR(ESP_ERR_EFUSE_CNT_IS_FULL, esp_efuse_write_field_cnt(ESP_EFUSE_TEST5_LEN_1, test5_len_1)); esp_efuse_utility_debug_dump_blocks(); ESP_LOGI(TAG, "4. Test field test2_len_16"); size_t test2_len_16 = 11; TEST_ESP_OK(esp_efuse_write_field_cnt(ESP_EFUSE_TEST2_LEN_16, test2_len_16)); TEST_ESP_OK(esp_efuse_read_field_cnt(ESP_EFUSE_TEST2_LEN_16, &test2_len_16)); TEST_ASSERT_EQUAL_HEX16(11, test2_len_16); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_TEST2_LEN_16, &test2_len_16, 16)); TEST_ASSERT_EQUAL_HEX16(0x07FF, test2_len_16); esp_efuse_utility_debug_dump_blocks(); } TEST_CASE("efuse test write_field_cnt", "[efuse]") { test_write_cnt(); } TEST_CASE("efuse test single bit functions", "[efuse]") { esp_efuse_utility_erase_virt_blocks(); esp_efuse_utility_debug_dump_blocks(); uint8_t test_bit; TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_TEST5_LEN_1, &test_bit, 1)); TEST_ASSERT_EQUAL_HEX8(0, test_bit); test_bit = esp_efuse_read_field_bit(ESP_EFUSE_TEST5_LEN_1); TEST_ASSERT_EQUAL_HEX8(0, test_bit); TEST_ESP_OK(esp_efuse_write_field_bit(ESP_EFUSE_TEST5_LEN_1)); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_TEST5_LEN_1, &test_bit, 1)); TEST_ASSERT_EQUAL_HEX8(1, test_bit); test_bit = esp_efuse_read_field_bit(ESP_EFUSE_TEST5_LEN_1); TEST_ASSERT_EQUAL_HEX8(1, test_bit); // Can write the bit again and it's a no-op TEST_ESP_OK(esp_efuse_write_field_bit(ESP_EFUSE_TEST5_LEN_1)); TEST_ASSERT_EQUAL_HEX8(1, esp_efuse_read_field_bit(ESP_EFUSE_TEST5_LEN_1)); esp_efuse_utility_debug_dump_blocks(); } void cut_tail_arr(uint8_t *arr, int num_used_bits, size_t count_bits) { if ((num_used_bits + count_bits) % 8) { int start_used_item = (num_used_bits - 1) / 8; int last_used_item = ((num_used_bits + count_bits) - 1) / 8; int shift = 0; int mask = num_used_bits + count_bits; if (last_used_item == start_used_item) { shift = (num_used_bits) % 8; mask = count_bits; } arr[last_used_item] &= ((1 << (mask % 8)) - 1) << shift; } } void cut_start_arr(uint8_t *arr, size_t num_used_bits) { if (num_used_bits % 8) { int start_used_item = (num_used_bits - 1) / 8; arr[start_used_item] &= ~((1 << (num_used_bits % 8)) - 1); } } void get_part_arr(uint8_t *arr_in, uint8_t *arr_out, int num_used_bits, int count_bits) { int num_items = esp_efuse_utility_get_number_of_items(num_used_bits + count_bits, 8); memcpy(arr_out, arr_in, num_items); memset(arr_out, 0, num_used_bits / 8); cut_start_arr(arr_out, num_used_bits); cut_tail_arr(arr_out, num_used_bits, count_bits); } void fill_part_arr(uint8_t *arr_in, uint8_t *arr_out, int count_bits) { int num_items = esp_efuse_utility_get_number_of_items(count_bits, 8); memcpy(arr_out, arr_in, num_items); cut_tail_arr(arr_out, 0, count_bits); } // Writes a random array to efuse, then reads and compares it. void test_blob(const esp_efuse_desc_t* field[], uint8_t *arr_w, uint8_t *arr_r, uint8_t *arr_temp, int arr_size, size_t field_size) { ESP_LOG_BUFFER_HEX_LEVEL(TAG, arr_w, arr_size, ESP_LOG_INFO); TEST_ESP_OK(esp_efuse_write_field_blob(field, arr_w, field_size)); memset(arr_r, 0, arr_size); TEST_ESP_OK(esp_efuse_read_field_blob(field, arr_r, field_size)); ESP_LOG_BUFFER_HEX_LEVEL(TAG, arr_r, arr_size, ESP_LOG_INFO); esp_efuse_utility_debug_dump_blocks(); TEST_ASSERT_TRUE_MESSAGE(memcmp(arr_w, arr_r, arr_size) == 0, "Operation write/read blob is not success"); int count_once = 0; for (int i = 0; i < arr_size; ++i) { count_once += __builtin_popcount(arr_w[i]); } size_t num_bits_r = 0; TEST_ESP_OK(esp_efuse_read_field_cnt(field, &num_bits_r)); TEST_ASSERT_EQUAL_INT(count_once, num_bits_r); size_t num_bits_w = field_size - count_once; if (num_bits_w == 0) { esp_efuse_utility_erase_virt_blocks(); num_bits_w = field_size; } TEST_ESP_OK(esp_efuse_write_field_cnt(field, num_bits_w)); TEST_ESP_OK(esp_efuse_read_field_cnt(field, &num_bits_r)); esp_efuse_utility_debug_dump_blocks(); TEST_ASSERT_EQUAL_INT(field_size, num_bits_r); memset(arr_r, 0, arr_size); TEST_ESP_OK(esp_efuse_read_field_blob(field, arr_r, field_size)); memset(arr_temp, 0xFF, arr_size); cut_tail_arr(arr_temp, 0, field_size); esp_efuse_utility_debug_dump_blocks(); TEST_ASSERT_TRUE_MESSAGE(memcmp(arr_temp, arr_r, arr_size) == 0, "Operation write/read blob is not success"); } // Records a random number of bits (as "1") in the efuse field, then reads and compares. void test_cnt_part(const esp_efuse_desc_t* field[], uint8_t *arr_r, int arr_size, size_t field_size) { size_t num_bits_r = 0; TEST_ESP_OK(esp_efuse_read_field_cnt(field, &num_bits_r)); TEST_ASSERT_EQUAL_INT(0, num_bits_r); TEST_ESP_OK(esp_efuse_write_field_cnt(field, field_size)); TEST_ESP_OK(esp_efuse_read_field_cnt(field, &num_bits_r)); TEST_ASSERT_EQUAL_INT(field_size, num_bits_r); esp_efuse_utility_erase_virt_blocks(); int num_bits_summ_r = 0; int num_bits_w = 0; while(field_size > num_bits_summ_r) { num_bits_w = 0; while(num_bits_w == 0 || (num_bits_summ_r + num_bits_w) > field_size) { bootloader_random_enable(); bootloader_fill_random(&num_bits_w, 1); bootloader_random_disable(); num_bits_w = num_bits_w * field_size / 255; if (num_bits_w != 0 && (num_bits_summ_r + num_bits_w) <= field_size) { break; } } TEST_ESP_OK(esp_efuse_write_field_cnt(field, num_bits_w)); TEST_ESP_OK(esp_efuse_read_field_cnt(field, &num_bits_r)); num_bits_summ_r += num_bits_w; TEST_ASSERT_EQUAL_INT(num_bits_summ_r, num_bits_r); memset(arr_r, 0, arr_size); TEST_ESP_OK(esp_efuse_read_field_blob(field, arr_r, field_size)); int count_once = 0; for (int i = 0; i < arr_size; ++i) { count_once += __builtin_popcount(arr_r[i]); } TEST_ASSERT_EQUAL_INT(num_bits_summ_r, count_once); ESP_LOGI(TAG, "Once bits=%d, step=%d", num_bits_summ_r, num_bits_w); } esp_efuse_utility_debug_dump_blocks(); } // From a random array takes a random number of bits and write to efuse, it repeats until the entire length of the field is written down. void test_blob_part(const esp_efuse_desc_t* field[], uint8_t *arr_w, uint8_t *arr_r, uint8_t *arr_temp, int arr_size, size_t field_size) { esp_efuse_utility_debug_dump_blocks(); int num_bits_summ_r = 0; int num_bits_w = 0; memset(arr_w, 0, arr_size); bootloader_random_enable(); bootloader_fill_random(arr_w, arr_size); bootloader_random_disable(); ESP_LOG_BUFFER_HEX_LEVEL(TAG, arr_w, arr_size, ESP_LOG_INFO); while(field_size > num_bits_summ_r) { num_bits_w = 0; while(num_bits_w == 0 || (num_bits_summ_r + num_bits_w) > field_size) { bootloader_random_enable(); bootloader_fill_random(&num_bits_w, 1); bootloader_random_disable(); num_bits_w = num_bits_w * field_size / 255; if (num_bits_w != 0 && (num_bits_summ_r + num_bits_w) <= field_size) { break; } } ESP_LOGI(TAG, "Summ bits=%d, step=%d", num_bits_summ_r, num_bits_w); memset(arr_temp, 0, arr_size); get_part_arr(arr_w, arr_temp, num_bits_summ_r, num_bits_w); ESP_LOG_BUFFER_HEX_LEVEL(TAG, arr_temp, arr_size, ESP_LOG_INFO); TEST_ESP_OK(esp_efuse_write_field_blob(field, arr_temp, field_size)); memset(arr_r, 0, arr_size); TEST_ESP_OK(esp_efuse_read_field_blob(field, arr_r, field_size)); ESP_LOG_BUFFER_HEX_LEVEL(TAG, arr_r, arr_size, ESP_LOG_INFO); esp_efuse_utility_debug_dump_blocks(); num_bits_summ_r += num_bits_w; memset(arr_temp, 0, arr_size); fill_part_arr(arr_w, arr_temp, num_bits_summ_r); ESP_LOG_BUFFER_HEX_LEVEL(TAG, arr_temp, arr_size, ESP_LOG_INFO); TEST_ASSERT_TRUE_MESSAGE(memcmp(arr_temp, arr_r, arr_size) == 0, "Operation write/read blob is not success"); } } void check_efuse_table_test(int cycle) { int num_test = 0; while(1) { const esp_efuse_desc_t** field; switch (num_test++) { case 0: field = ESP_EFUSE_TEST1_LEN_8; break; case 1: field = ESP_EFUSE_TEST2_LEN_16; break; case 2: field = ESP_EFUSE_TEST3_LEN_6; break; case 3: field = ESP_EFUSE_TEST4_LEN_182; break; case 4: field = ESP_EFUSE_TEST5_LEN_1; break; case 5: field = ESP_EFUSE_TEST6_LEN_17; break; default: return; break; } size_t field_size = esp_efuse_get_field_size(field); int arr_size = esp_efuse_utility_get_number_of_items(field_size, 8); uint8_t *arr_w = (uint8_t *) malloc(arr_size); uint8_t *arr_r = (uint8_t *) malloc(arr_size); uint8_t *arr_temp = (uint8_t *) malloc(arr_size); ESP_LOGI(TAG, "Test#%d", num_test); for (int c = 1; c <= cycle; ++c) { ESP_LOGI(TAG, "Cycle#%d/%d", c, cycle); memset(arr_w, 0, arr_size); bootloader_random_enable(); bootloader_fill_random(arr_w, arr_size); bootloader_random_disable(); cut_tail_arr(arr_w, 0, field_size); esp_efuse_utility_erase_virt_blocks(); ESP_LOGI(TAG, "1) blob write/read"); test_blob(field, arr_w, arr_r, arr_temp, arr_size, field_size); esp_efuse_utility_erase_virt_blocks(); ESP_LOGI(TAG, "2) cnt part write/read"); test_cnt_part(field, arr_r, arr_size, field_size); esp_efuse_utility_erase_virt_blocks(); ESP_LOGI(TAG, "3) blob part write/read"); test_blob_part(field, arr_w, arr_r, arr_temp, arr_size, field_size); } free(arr_temp); free(arr_r); free(arr_w); } } TEST_CASE("efuse esp_efuse_table_test", "[efuse]") { esp_efuse_coding_scheme_t coding_scheme = esp_efuse_get_coding_scheme(EFUSE_BLK2); if (coding_scheme == EFUSE_CODING_SCHEME_NONE) { check_efuse_table_test(2); } else { ESP_LOGI(TAG, "This test is applicable only to the EFUSE_CODING_SCHEME_NONE. Skip this test."); } } TEST_CASE("Test esp_efuse_read_block esp_efuse_write_block functions", "[efuse]") { int count_useful_reg = 0; esp_efuse_coding_scheme_t coding_scheme = esp_efuse_get_coding_scheme(EFUSE_BLK2); if (coding_scheme == EFUSE_CODING_SCHEME_NONE) { printf("EFUSE_CODING_SCHEME_NONE\n"); count_useful_reg = 8; } #if CONFIG_IDF_TARGET_ESP32 if (coding_scheme == EFUSE_CODING_SCHEME_3_4) { printf("EFUSE_CODING_SCHEME_3_4\n"); count_useful_reg = 6; } else if (coding_scheme == EFUSE_CODING_SCHEME_REPEAT) { printf("EFUSE_CODING_SCHEME_REPEAT\n"); count_useful_reg = 4; } #else if (coding_scheme == EFUSE_CODING_SCHEME_RS) { printf("EFUSE_CODING_SCHEME_RS\n"); count_useful_reg = 8; } #endif esp_efuse_utility_reset(); esp_efuse_utility_erase_virt_blocks(); uint8_t src_key[32] = { 0 }; uint8_t dst_key[32] = { 0 }; int offset_in_bits = 0; for (int i = 0; i < count_useful_reg * 4; ++i) { src_key[i] = 0xAB + i; } TEST_ESP_OK(esp_efuse_write_block(EFUSE_BLK2, src_key, offset_in_bits, count_useful_reg * 32)); TEST_ESP_OK(esp_efuse_read_block(EFUSE_BLK2, dst_key, offset_in_bits, count_useful_reg * 32)); esp_efuse_utility_debug_dump_blocks(); TEST_ASSERT_EQUAL_HEX8_ARRAY(src_key, dst_key, sizeof(src_key)); esp_efuse_utility_erase_virt_blocks(); memset(src_key, 0, sizeof(src_key)); memset(dst_key, 0, sizeof(dst_key)); offset_in_bits = count_useful_reg * 32 / 2; for (int i = 0; i < count_useful_reg * 4 / 2; ++i) { src_key[i] = 0xCD + i; } TEST_ESP_OK(esp_efuse_write_block(EFUSE_BLK2, src_key, offset_in_bits, count_useful_reg * 32 / 2)); TEST_ESP_OK(esp_efuse_read_block(EFUSE_BLK2, dst_key, offset_in_bits, count_useful_reg * 32 / 2)); esp_efuse_utility_debug_dump_blocks(); TEST_ASSERT_EQUAL_HEX8_ARRAY(src_key, dst_key, count_useful_reg * 4 / 2); esp_efuse_utility_erase_virt_blocks(); } TEST_CASE("Test Bits are not empty. Write operation is forbidden", "[efuse]") { esp_efuse_utility_update_virt_blocks(); esp_efuse_utility_debug_dump_blocks(); int count_useful_reg = 0; uint8_t r_buff[32]; int st_offset = -1; int num_block; for (num_block = EFUSE_BLK1; num_block < 4; ++num_block) { memset(r_buff, 0, sizeof(r_buff)); esp_efuse_coding_scheme_t coding_scheme = esp_efuse_get_coding_scheme(num_block); if (coding_scheme == EFUSE_CODING_SCHEME_NONE) { printf("EFUSE_CODING_SCHEME_NONE. The test is not applicable.\n"); count_useful_reg = 8; return; } #if CONFIG_IDF_TARGET_ESP32 if (coding_scheme == EFUSE_CODING_SCHEME_3_4) { printf("EFUSE_CODING_SCHEME_3_4\n"); count_useful_reg = 6; } else if (coding_scheme == EFUSE_CODING_SCHEME_REPEAT) { printf("EFUSE_CODING_SCHEME_REPEAT\n"); count_useful_reg = 4; } #else if (coding_scheme == EFUSE_CODING_SCHEME_RS) { printf("EFUSE_CODING_SCHEME_RS\n"); if (num_block == EFUSE_BLK1) { count_useful_reg = 6; } else { count_useful_reg = 8; } } #endif TEST_ESP_OK(esp_efuse_read_block(num_block, r_buff, 0, count_useful_reg * 32)); for (int i = 0; i < count_useful_reg * 4; ++i) { if (r_buff[i] != 0) { // found used byte for (int j = 0; j < 8; ++j) { if ((r_buff[i] & (1 << j)) == 0) { // found empty bit into this byte st_offset = i * 8 + j; printf("Byte = 0x%02x. offset is = %d\n", r_buff[i], st_offset); break; } } if (st_offset != -1) { break; } } } if (st_offset != -1) { break; } } if (st_offset != -1) { // write 1 bit to empty place. uint8_t val = 1; TEST_ESP_ERR(ESP_ERR_CODING, esp_efuse_write_block(num_block, &val, st_offset, 1)); } else { printf("Test skipped. It is not applicable, the device has no written bits."); } } #ifndef CONFIG_FREERTOS_UNICORE static const int delay_ms = 2000; static xSemaphoreHandle sema; static void task1(void* arg) { TEST_ESP_OK(esp_efuse_batch_write_begin()); ESP_LOGI(TAG, "Start work in batch mode"); xSemaphoreGive(sema); vTaskDelay((delay_ms + 100) / portTICK_PERIOD_MS); ESP_LOGI(TAG, "Finish work in batch mode"); TEST_ESP_OK(esp_efuse_batch_write_cancel()); vTaskDelete(NULL); } static void task2(void* arg) { xSemaphoreTake(sema, portMAX_DELAY); uint8_t mac[6]; int64_t t1 = esp_timer_get_time(); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_MAC_FACTORY, &mac, sizeof(mac) * 8)); int64_t t2 = esp_timer_get_time(); int diff_ms = (t2 - t1) / 1000; TEST_ASSERT_GREATER_THAN(delay_ms, diff_ms); ESP_LOGI(TAG, "read MAC address: %02x:%02x:%02x:%02x:%02x:%02x", mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]); xSemaphoreGive(sema); vTaskDelete(NULL); } static void task3(void* arg) { xSemaphoreTake(sema, portMAX_DELAY); size_t test3_len_6 = 2; int64_t t1 = esp_timer_get_time(); TEST_ESP_OK(esp_efuse_write_field_cnt(ESP_EFUSE_TEST3_LEN_6, test3_len_6)); TEST_ESP_OK(esp_efuse_read_field_cnt(ESP_EFUSE_TEST3_LEN_6, &test3_len_6)); int64_t t2 = esp_timer_get_time(); ESP_LOGI(TAG, "write&read test3_len_6: %d", test3_len_6); int diff_ms = (t2 - t1) / 1000; TEST_ASSERT_GREATER_THAN(delay_ms, diff_ms); TEST_ASSERT_EQUAL_INT(2, test3_len_6); xSemaphoreGive(sema); vTaskDelete(NULL); } TEST_CASE("Batch mode is thread-safe", "[efuse]") { // Batch mode blocks work with efuse on other tasks. esp_efuse_utility_update_virt_blocks(); esp_efuse_utility_debug_dump_blocks(); sema = xSemaphoreCreateBinary(); printf("\n"); xTaskCreatePinnedToCore(task1, "task1", 3072, NULL, UNITY_FREERTOS_PRIORITY - 1, NULL, 0); xTaskCreatePinnedToCore(task2, "task2", 3072, NULL, UNITY_FREERTOS_PRIORITY - 1, NULL, 1); vTaskDelay(3000 / portTICK_PERIOD_MS); xSemaphoreTake(sema, portMAX_DELAY); esp_efuse_utility_reset(); esp_efuse_utility_erase_virt_blocks(); printf("\n"); xTaskCreatePinnedToCore(task1, "task1", 3072, NULL, UNITY_FREERTOS_PRIORITY - 1, NULL, 0); xTaskCreatePinnedToCore(task3, "task3", 3072, NULL, UNITY_FREERTOS_PRIORITY - 1, NULL, 1); vTaskDelay(3000 / portTICK_PERIOD_MS); xSemaphoreTake(sema, portMAX_DELAY); printf("\n"); vSemaphoreDelete(sema); esp_efuse_utility_reset(); esp_efuse_utility_erase_virt_blocks(); } #endif // #ifndef CONFIG_FREERTOS_UNICORE static void test_wp(esp_efuse_block_t blk, const esp_efuse_desc_t* field[]) { size_t out_cnt; TEST_ESP_OK(esp_efuse_set_write_protect(blk)); esp_efuse_read_field_cnt(field, &out_cnt); TEST_ASSERT_EQUAL_INT(1, out_cnt); } static void test_rp(esp_efuse_block_t blk, const esp_efuse_desc_t* field[], bool read_first) { size_t out_cnt; if (read_first) { esp_efuse_read_field_cnt(field, &out_cnt); TEST_ASSERT_EQUAL_INT(0, out_cnt); } TEST_ESP_OK(esp_efuse_set_read_protect(blk)); esp_efuse_read_field_cnt(field, &out_cnt); TEST_ASSERT_EQUAL_INT(1, out_cnt); if (read_first) { TEST_ESP_ERR(ESP_ERR_EFUSE_CNT_IS_FULL, esp_efuse_set_read_protect(blk)); } } TEST_CASE("Test a write/read protection", "[efuse]") { esp_efuse_utility_reset(); esp_efuse_utility_erase_virt_blocks(); esp_efuse_utility_debug_dump_blocks(); TEST_ESP_ERR(ESP_ERR_NOT_SUPPORTED, esp_efuse_set_write_protect(EFUSE_BLK0)); TEST_ESP_ERR(ESP_ERR_NOT_SUPPORTED, esp_efuse_set_read_protect(EFUSE_BLK0)); size_t out_cnt; esp_efuse_read_field_cnt(ESP_EFUSE_WR_DIS_BLK1, &out_cnt); TEST_ASSERT_EQUAL_INT(0, out_cnt); TEST_ESP_OK(esp_efuse_set_write_protect(EFUSE_BLK1)); esp_efuse_read_field_cnt(ESP_EFUSE_WR_DIS_BLK1, &out_cnt); TEST_ASSERT_EQUAL_INT(1, out_cnt); TEST_ESP_ERR(ESP_ERR_EFUSE_CNT_IS_FULL, esp_efuse_set_write_protect(EFUSE_BLK1)); #ifdef CONFIG_IDF_TARGET_ESP32 test_wp(EFUSE_BLK2, ESP_EFUSE_WR_DIS_BLK2); test_wp(EFUSE_BLK3, ESP_EFUSE_WR_DIS_BLK3); esp_efuse_utility_debug_dump_blocks(); test_rp(EFUSE_BLK1, ESP_EFUSE_RD_DIS_BLK1, true); test_rp(EFUSE_BLK2, ESP_EFUSE_RD_DIS_BLK2, false); test_rp(EFUSE_BLK3, ESP_EFUSE_RD_DIS_BLK3, false); #else test_wp(EFUSE_BLK2, ESP_EFUSE_WR_DIS_SYS_DATA_PART1); test_wp(EFUSE_BLK3, ESP_EFUSE_WR_DIS_USER_DATA); esp_efuse_utility_debug_dump_blocks(); test_rp(EFUSE_BLK4, ESP_EFUSE_RD_DIS_KEY0, true); test_rp(EFUSE_BLK5, ESP_EFUSE_RD_DIS_KEY1, false); test_rp(EFUSE_BLK6, ESP_EFUSE_RD_DIS_KEY2, false); #endif esp_efuse_utility_debug_dump_blocks(); esp_efuse_utility_reset(); esp_efuse_utility_erase_virt_blocks(); } #endif // #ifdef CONFIG_EFUSE_VIRTUAL #ifdef CONFIG_IDF_ENV_FPGA TEST_CASE("Test a real write (FPGA)", "[efuse]") { ESP_LOGI(TAG, "1. Write MAC address"); esp_efuse_utility_debug_dump_blocks(); uint8_t mac[6]; TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_MAC_FACTORY, &mac, sizeof(mac) * 8)); ESP_LOGI(TAG, "MAC: %02x:%02x:%02x:%02x:%02x:%02x", mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]); uint8_t new_mac[6]; if (mac[0] == 0) { new_mac[0] = 0x71; new_mac[1] = 0x62; new_mac[2] = 0x53; new_mac[3] = 0x44; new_mac[4] = 0x35; new_mac[5] = 0x26; TEST_ESP_OK(esp_efuse_write_field_blob(ESP_EFUSE_MAC_FACTORY, &new_mac, sizeof(new_mac) * 8)); ESP_LOGI(TAG, "new MAC: %02x:%02x:%02x:%02x:%02x:%02x", new_mac[0], new_mac[1], new_mac[2], new_mac[3], new_mac[4], new_mac[5]); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_MAC_FACTORY, &mac, sizeof(mac) * 8)); TEST_ASSERT_EQUAL_HEX8_ARRAY(new_mac, mac, sizeof(new_mac)); esp_efuse_utility_debug_dump_blocks(); } #ifndef CONFIG_IDF_TARGET_ESP32 ESP_LOGI(TAG, "2. Write KEY3"); uint8_t key[32] = {0}; TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_KEY3, &key, 256)); for (int i = 0; i < sizeof(key); ++i) { TEST_ASSERT_EQUAL_INT(0, key[i]); } uint8_t new_key[32] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 12, 14, 15, 16, 17, 18, 19, 20, 21, 22, 22, 24, 25, 26, 27, 28, 29, 30, 31}; TEST_ESP_OK(esp_efuse_write_field_blob(ESP_EFUSE_KEY3, &new_key, 256)); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_KEY3, &key, 256)); TEST_ASSERT_EQUAL_HEX8_ARRAY(new_key, key, sizeof(new_mac)); esp_efuse_utility_debug_dump_blocks(); ESP_LOGI(TAG, "3. Set a read protection for KEY3"); TEST_ESP_OK(esp_efuse_set_read_protect(EFUSE_BLK7)); TEST_ESP_OK(esp_efuse_read_field_blob(ESP_EFUSE_KEY3, &key, 256)); for (int i = 0; i < sizeof(key); ++i) { TEST_ASSERT_EQUAL_INT(0, key[i]); } esp_efuse_utility_debug_dump_blocks(); #endif // not CONFIG_IDF_TARGET_ESP32 ESP_LOGI(TAG, "4. Write SECURE_VERSION"); int max_bits = esp_efuse_get_field_size(ESP_EFUSE_SECURE_VERSION); size_t read_sec_version; esp_efuse_utility_debug_dump_blocks(); for (int i = 0; i < max_bits; ++i) { ESP_LOGI(TAG, "# %d", i); TEST_ESP_OK(esp_efuse_write_field_cnt(ESP_EFUSE_SECURE_VERSION, 1)); TEST_ESP_OK(esp_efuse_read_field_cnt(ESP_EFUSE_SECURE_VERSION, &read_sec_version)); esp_efuse_utility_debug_dump_blocks(); TEST_ASSERT_EQUAL_INT(i + 1, read_sec_version); } } #endif // CONFIG_IDF_ENV_FPGA TEST_CASE("Test chip_ver_pkg APIs return the same value", "[efuse]") { esp_efuse_utility_update_virt_blocks(); TEST_ASSERT_EQUAL_INT(esp_efuse_get_pkg_ver(), bootloader_common_get_chip_ver_pkg()); } TEST_CASE("Test chip_revision APIs return the same value", "[efuse]") { esp_efuse_utility_update_virt_blocks(); TEST_ASSERT_EQUAL_INT(esp_efuse_get_chip_ver(), bootloader_common_get_chip_revision()); }