#include #include #include #include #include #include #include #include #include #include #include #include "../minunit.h" #define TAG "NfcTest" #define NFC_TEST_RESOURCES_DIR EXT_PATH("unit_tests/nfc/") #define NFC_TEST_SIGNAL_SHORT_FILE "nfc_nfca_signal_short.nfc" #define NFC_TEST_SIGNAL_LONG_FILE "nfc_nfca_signal_long.nfc" #define NFC_TEST_DICT_PATH EXT_PATH("unit_tests/mf_classic_dict.nfc") #define NFC_TEST_NFC_DEV_PATH EXT_PATH("unit_tests/nfc/nfc_dev_test.nfc") static const char* nfc_test_file_type = "Flipper NFC test"; static const uint32_t nfc_test_file_version = 1; #define NFC_TEST_DATA_MAX_LEN 18 #define NFC_TETS_TIMINGS_MAX_LEN 1350 typedef struct { Storage* storage; NfcaSignal* signal; uint32_t test_data_len; uint8_t test_data[NFC_TEST_DATA_MAX_LEN]; uint32_t test_timings_len; uint32_t test_timings[NFC_TETS_TIMINGS_MAX_LEN]; } NfcTest; static NfcTest* nfc_test = NULL; static void nfc_test_alloc() { nfc_test = malloc(sizeof(NfcTest)); nfc_test->signal = nfca_signal_alloc(); nfc_test->storage = furi_record_open(RECORD_STORAGE); } static void nfc_test_free() { furi_assert(nfc_test); furi_record_close(RECORD_STORAGE); nfca_signal_free(nfc_test->signal); free(nfc_test); nfc_test = NULL; } static bool nfc_test_read_signal_from_file(const char* file_name) { bool success = false; FlipperFormat* file = flipper_format_file_alloc(nfc_test->storage); FuriString* file_type; file_type = furi_string_alloc(); uint32_t file_version = 0; do { if(!flipper_format_file_open_existing(file, file_name)) break; if(!flipper_format_read_header(file, file_type, &file_version)) break; if(furi_string_cmp_str(file_type, nfc_test_file_type) || file_version != nfc_test_file_version) break; if(!flipper_format_read_uint32(file, "Data length", &nfc_test->test_data_len, 1)) break; if(nfc_test->test_data_len > NFC_TEST_DATA_MAX_LEN) break; if(!flipper_format_read_hex( file, "Plain data", nfc_test->test_data, nfc_test->test_data_len)) break; if(!flipper_format_read_uint32(file, "Timings length", &nfc_test->test_timings_len, 1)) break; if(nfc_test->test_timings_len > NFC_TETS_TIMINGS_MAX_LEN) break; if(!flipper_format_read_uint32( file, "Timings", nfc_test->test_timings, nfc_test->test_timings_len)) break; success = true; } while(false); furi_string_free(file_type); flipper_format_free(file); return success; } static bool nfc_test_digital_signal_test_encode( const char* file_name, uint32_t encode_max_time, uint32_t timing_tolerance, uint32_t timings_sum_tolerance) { furi_assert(nfc_test); bool success = false; uint32_t time = 0; uint32_t dut_timings_sum = 0; uint32_t ref_timings_sum = 0; uint8_t parity[10] = {}; do { // Read test data if(!nfc_test_read_signal_from_file(file_name)) { FURI_LOG_E(TAG, "Failed to read signal from file"); break; } // Encode signal FURI_CRITICAL_ENTER(); time = DWT->CYCCNT; nfca_signal_encode( nfc_test->signal, nfc_test->test_data, nfc_test->test_data_len * 8, parity); digital_signal_prepare_arr(nfc_test->signal->tx_signal); time = (DWT->CYCCNT - time) / furi_hal_cortex_instructions_per_microsecond(); FURI_CRITICAL_EXIT(); // Check timings if(time > encode_max_time) { FURI_LOG_E( TAG, "Encoding time: %ld us while accepted value: %ld us", time, encode_max_time); break; } // Check data if(nfc_test->signal->tx_signal->edge_cnt != nfc_test->test_timings_len) { FURI_LOG_E(TAG, "Not equal timings buffers length"); break; } uint32_t timings_diff = 0; uint32_t* ref = nfc_test->test_timings; uint32_t* dut = nfc_test->signal->tx_signal->reload_reg_buff; bool timing_check_success = true; for(size_t i = 0; i < nfc_test->test_timings_len; i++) { timings_diff = dut[i] > ref[i] ? dut[i] - ref[i] : ref[i] - dut[i]; dut_timings_sum += dut[i]; ref_timings_sum += ref[i]; if(timings_diff > timing_tolerance) { FURI_LOG_E( TAG, "Too big difference in %d timings. Ref: %ld, DUT: %ld", i, ref[i], dut[i]); timing_check_success = false; break; } } if(!timing_check_success) break; uint32_t sum_diff = dut_timings_sum > ref_timings_sum ? dut_timings_sum - ref_timings_sum : ref_timings_sum - dut_timings_sum; if(sum_diff > timings_sum_tolerance) { FURI_LOG_E( TAG, "Too big difference in timings sum. Ref: %ld, DUT: %ld", ref_timings_sum, dut_timings_sum); break; } FURI_LOG_I(TAG, "Encoding time: %ld us. Acceptable time: %ld us", time, encode_max_time); FURI_LOG_I( TAG, "Timings sum difference: %ld [1/64MHZ]. Acceptable difference: %ld [1/64MHz]", sum_diff, timings_sum_tolerance); success = true; } while(false); return success; } MU_TEST(nfc_digital_signal_test) { mu_assert( nfc_test_digital_signal_test_encode( NFC_TEST_RESOURCES_DIR NFC_TEST_SIGNAL_SHORT_FILE, 500, 1, 37), "NFC short digital signal test failed\r\n"); mu_assert( nfc_test_digital_signal_test_encode( NFC_TEST_RESOURCES_DIR NFC_TEST_SIGNAL_LONG_FILE, 2000, 1, 37), "NFC long digital signal test failed\r\n"); } MU_TEST(mf_classic_dict_test) { MfClassicDict* instance = NULL; uint64_t key = 0; FuriString* temp_str; temp_str = furi_string_alloc(); instance = mf_classic_dict_alloc(MfClassicDictTypeUnitTest); mu_assert(instance != NULL, "mf_classic_dict_alloc\r\n"); mu_assert( mf_classic_dict_get_total_keys(instance) == 0, "mf_classic_dict_get_total_keys == 0 assert failed\r\n"); furi_string_set(temp_str, "2196FAD8115B"); mu_assert( mf_classic_dict_add_key_str(instance, temp_str), "mf_classic_dict_add_key == true assert failed\r\n"); mu_assert( mf_classic_dict_get_total_keys(instance) == 1, "mf_classic_dict_get_total_keys == 1 assert failed\r\n"); mu_assert(mf_classic_dict_rewind(instance), "mf_classic_dict_rewind == 1 assert failed\r\n"); mu_assert( mf_classic_dict_get_key_at_index_str(instance, temp_str, 0), "mf_classic_dict_get_key_at_index_str == true assert failed\r\n"); mu_assert( furi_string_cmp(temp_str, "2196FAD8115B") == 0, "string_cmp(temp_str, \"2196FAD8115B\") == 0 assert failed\r\n"); mu_assert(mf_classic_dict_rewind(instance), "mf_classic_dict_rewind == 1 assert failed\r\n"); mu_assert( mf_classic_dict_get_key_at_index(instance, &key, 0), "mf_classic_dict_get_key_at_index == true assert failed\r\n"); mu_assert(key == 0x2196FAD8115B, "key == 0x2196FAD8115B assert failed\r\n"); mu_assert(mf_classic_dict_rewind(instance), "mf_classic_dict_rewind == 1 assert failed\r\n"); mu_assert( mf_classic_dict_delete_index(instance, 0), "mf_classic_dict_delete_index == true assert failed\r\n"); mf_classic_dict_free(instance); furi_string_free(temp_str); } MU_TEST(mf_classic_dict_load_test) { Storage* storage = furi_record_open(RECORD_STORAGE); mu_assert(storage != NULL, "storage != NULL assert failed\r\n"); // Delete unit test dict file if exists if(storage_file_exists(storage, NFC_TEST_DICT_PATH)) { mu_assert( storage_simply_remove(storage, NFC_TEST_DICT_PATH), "remove == true assert failed\r\n"); } // Create unit test dict file Stream* file_stream = file_stream_alloc(storage); mu_assert(file_stream != NULL, "file_stream != NULL assert failed\r\n"); mu_assert( file_stream_open(file_stream, NFC_TEST_DICT_PATH, FSAM_WRITE, FSOM_OPEN_ALWAYS), "file_stream_open == true assert failed\r\n"); // Write unit test dict file char key_str[] = "a0a1a2a3a4a5"; mu_assert( stream_write_cstring(file_stream, key_str) == strlen(key_str), "write == true assert failed\r\n"); // Close unit test dict file mu_assert(file_stream_close(file_stream), "file_stream_close == true assert failed\r\n"); // Load unit test dict file MfClassicDict* instance = NULL; instance = mf_classic_dict_alloc(MfClassicDictTypeUnitTest); mu_assert(instance != NULL, "mf_classic_dict_alloc\r\n"); uint32_t total_keys = mf_classic_dict_get_total_keys(instance); mu_assert(total_keys == 1, "total_keys == 1 assert failed\r\n"); // Read key uint64_t key_ref = 0xa0a1a2a3a4a5; uint64_t key_dut = 0; FuriString* temp_str = furi_string_alloc(); mu_assert( mf_classic_dict_get_next_key_str(instance, temp_str), "get_next_key_str == true assert failed\r\n"); mu_assert(furi_string_cmp_str(temp_str, key_str) == 0, "invalid key loaded\r\n"); mu_assert(mf_classic_dict_rewind(instance), "mf_classic_dict_rewind == 1 assert failed\r\n"); mu_assert( mf_classic_dict_get_next_key(instance, &key_dut), "get_next_key == true assert failed\r\n"); mu_assert(key_dut == key_ref, "invalid key loaded\r\n"); furi_string_free(temp_str); mf_classic_dict_free(instance); // Check that MfClassicDict added new line to the end of the file mu_assert( file_stream_open(file_stream, NFC_TEST_DICT_PATH, FSAM_READ, FSOM_OPEN_EXISTING), "file_stream_open == true assert failed\r\n"); mu_assert(stream_seek(file_stream, -1, StreamOffsetFromEnd), "seek == true assert failed\r\n"); uint8_t last_char = 0; mu_assert(stream_read(file_stream, &last_char, 1) == 1, "read == true assert failed\r\n"); mu_assert(last_char == '\n', "last_char == '\\n' assert failed\r\n"); mu_assert(file_stream_close(file_stream), "file_stream_close == true assert failed\r\n"); // Delete unit test dict file mu_assert( storage_simply_remove(storage, NFC_TEST_DICT_PATH), "remove == true assert failed\r\n"); stream_free(file_stream); furi_record_close(RECORD_STORAGE); } MU_TEST(nfca_file_test) { NfcDevice* nfc = nfc_device_alloc(); mu_assert(nfc != NULL, "nfc_device_data != NULL assert failed\r\n"); nfc->format = NfcDeviceSaveFormatUid; // Fill the UID, sak, ATQA and type uint8_t uid[7] = {0x04, 0x01, 0x23, 0x45, 0x67, 0x89, 0x00}; memcpy(nfc->dev_data.nfc_data.uid, uid, 7); nfc->dev_data.nfc_data.uid_len = 7; nfc->dev_data.nfc_data.sak = 0x08; nfc->dev_data.nfc_data.atqa[0] = 0x00; nfc->dev_data.nfc_data.atqa[1] = 0x04; nfc->dev_data.nfc_data.type = FuriHalNfcTypeA; // Save the NFC device data to the file mu_assert( nfc_device_save(nfc, NFC_TEST_NFC_DEV_PATH), "nfc_device_save == true assert failed\r\n"); nfc_device_free(nfc); // Load the NFC device data from the file NfcDevice* nfc_validate = nfc_device_alloc(); mu_assert( nfc_device_load(nfc_validate, NFC_TEST_NFC_DEV_PATH, true), "nfc_device_load == true assert failed\r\n"); // Check the UID, sak, ATQA and type mu_assert(memcmp(nfc_validate->dev_data.nfc_data.uid, uid, 7) == 0, "uid assert failed\r\n"); mu_assert(nfc_validate->dev_data.nfc_data.sak == 0x08, "sak == 0x08 assert failed\r\n"); mu_assert( nfc_validate->dev_data.nfc_data.atqa[0] == 0x00, "atqa[0] == 0x00 assert failed\r\n"); mu_assert( nfc_validate->dev_data.nfc_data.atqa[1] == 0x04, "atqa[1] == 0x04 assert failed\r\n"); mu_assert( nfc_validate->dev_data.nfc_data.type == FuriHalNfcTypeA, "type == FuriHalNfcTypeA assert failed\r\n"); nfc_device_free(nfc_validate); } static void mf_classic_generator_test(uint8_t uid_len, MfClassicType type) { NfcDevice* nfc_dev = nfc_device_alloc(); mu_assert(nfc_dev != NULL, "nfc_device_data != NULL assert failed\r\n"); nfc_dev->format = NfcDeviceSaveFormatMifareClassic; // Create a test file nfc_generate_mf_classic(&nfc_dev->dev_data, uid_len, type); // Get the uid from generated MFC uint8_t uid[7] = {0}; memcpy(uid, nfc_dev->dev_data.nfc_data.uid, uid_len); uint8_t sak = nfc_dev->dev_data.nfc_data.sak; uint8_t atqa[2] = {}; memcpy(atqa, nfc_dev->dev_data.nfc_data.atqa, 2); MfClassicData* mf_data = &nfc_dev->dev_data.mf_classic_data; // Check the manufacturer block (should be uid[uid_len] + 0xFF[rest]) uint8_t manufacturer_block[16] = {0}; memcpy(manufacturer_block, nfc_dev->dev_data.mf_classic_data.block[0].value, 16); mu_assert( memcmp(manufacturer_block, uid, uid_len) == 0, "manufacturer_block uid doesn't match the file\r\n"); for(uint8_t i = uid_len; i < 16; i++) { mu_assert( manufacturer_block[i] == 0xFF, "manufacturer_block[i] == 0xFF assert failed\r\n"); } // Reference sector trailers (should be 0xFF[6] + 0xFF + 0x07 + 0x80 + 0x69 + 0xFF[6]) uint8_t sector_trailer[16] = { 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0x07, 0x80, 0x69, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF}; // Reference block data uint8_t block_data[16] = {}; memset(block_data, 0xff, sizeof(block_data)); uint16_t total_blocks = mf_classic_get_total_block_num(type); for(size_t i = 1; i < total_blocks; i++) { if(mf_classic_is_sector_trailer(i)) { mu_assert( memcmp(mf_data->block[i].value, sector_trailer, 16) == 0, "Failed sector trailer compare"); } else { mu_assert(memcmp(mf_data->block[i].value, block_data, 16) == 0, "Failed data compare"); } } // Save the NFC device data to the file mu_assert( nfc_device_save(nfc_dev, NFC_TEST_NFC_DEV_PATH), "nfc_device_save == true assert failed\r\n"); // Verify that key cache is saved FuriString* key_cache_name = furi_string_alloc(); furi_string_set_str(key_cache_name, "/ext/nfc/.cache/"); for(size_t i = 0; i < uid_len; i++) { furi_string_cat_printf(key_cache_name, "%02X", uid[i]); } furi_string_cat_printf(key_cache_name, ".keys"); mu_assert( storage_common_stat(nfc_dev->storage, furi_string_get_cstr(key_cache_name), NULL) == FSE_OK, "Key cache file save failed"); nfc_device_free(nfc_dev); // Load the NFC device data from the file NfcDevice* nfc_validate = nfc_device_alloc(); mu_assert(nfc_validate, "Nfc device alloc assert"); mu_assert( nfc_device_load(nfc_validate, NFC_TEST_NFC_DEV_PATH, false), "nfc_device_load == true assert failed\r\n"); // Check the UID, sak, ATQA and type mu_assert( memcmp(nfc_validate->dev_data.nfc_data.uid, uid, uid_len) == 0, "uid compare assert failed\r\n"); mu_assert(nfc_validate->dev_data.nfc_data.sak == sak, "sak compare assert failed\r\n"); mu_assert( memcmp(nfc_validate->dev_data.nfc_data.atqa, atqa, 2) == 0, "atqa compare assert failed\r\n"); mu_assert( nfc_validate->dev_data.nfc_data.type == FuriHalNfcTypeA, "type == FuriHalNfcTypeA assert failed\r\n"); // Check the manufacturer block mu_assert( memcmp(nfc_validate->dev_data.mf_classic_data.block[0].value, manufacturer_block, 16) == 0, "manufacturer_block assert failed\r\n"); // Check other blocks for(size_t i = 1; i < total_blocks; i++) { if(mf_classic_is_sector_trailer(i)) { mu_assert( memcmp(mf_data->block[i].value, sector_trailer, 16) == 0, "Failed sector trailer compare"); } else { mu_assert(memcmp(mf_data->block[i].value, block_data, 16) == 0, "Failed data compare"); } } nfc_device_free(nfc_validate); // Check saved key cache NfcDevice* nfc_keys = nfc_device_alloc(); mu_assert(nfc_validate, "Nfc device alloc assert"); nfc_keys->dev_data.nfc_data.uid_len = uid_len; memcpy(nfc_keys->dev_data.nfc_data.uid, uid, uid_len); mu_assert(nfc_device_load_key_cache(nfc_keys), "Failed to load key cache"); uint8_t total_sec = mf_classic_get_total_sectors_num(type); uint8_t default_key[6] = {}; memset(default_key, 0xff, 6); for(size_t i = 0; i < total_sec; i++) { MfClassicSectorTrailer* sec_tr = mf_classic_get_sector_trailer_by_sector(&nfc_keys->dev_data.mf_classic_data, i); mu_assert(memcmp(sec_tr->key_a, default_key, 6) == 0, "Failed key compare"); mu_assert(memcmp(sec_tr->key_b, default_key, 6) == 0, "Failed key compare"); } // Delete key cache file mu_assert( storage_common_remove(nfc_keys->storage, furi_string_get_cstr(key_cache_name)) == FSE_OK, "Failed to remove key cache file"); furi_string_free(key_cache_name); nfc_device_free(nfc_keys); } MU_TEST(mf_mini_file_test) { mf_classic_generator_test(4, MfClassicTypeMini); } MU_TEST(mf_classic_1k_4b_file_test) { mf_classic_generator_test(4, MfClassicType1k); } MU_TEST(mf_classic_4k_4b_file_test) { mf_classic_generator_test(4, MfClassicType4k); } MU_TEST(mf_classic_1k_7b_file_test) { mf_classic_generator_test(7, MfClassicType1k); } MU_TEST(mf_classic_4k_7b_file_test) { mf_classic_generator_test(7, MfClassicType4k); } MU_TEST_SUITE(nfc) { nfc_test_alloc(); MU_RUN_TEST(nfca_file_test); MU_RUN_TEST(mf_mini_file_test); MU_RUN_TEST(mf_classic_1k_4b_file_test); MU_RUN_TEST(mf_classic_4k_4b_file_test); MU_RUN_TEST(mf_classic_1k_7b_file_test); MU_RUN_TEST(mf_classic_4k_7b_file_test); MU_RUN_TEST(nfc_digital_signal_test); MU_RUN_TEST(mf_classic_dict_test); MU_RUN_TEST(mf_classic_dict_load_test); nfc_test_free(); } int run_minunit_test_nfc() { MU_RUN_SUITE(nfc); return MU_EXIT_CODE; }