void test_mifare_application (void) { /* Card publisher part */ MadAid aid = { 0x22, 0x42 }; Mad mad = mad_new (2); int i; cut_assert_not_null (mad, cut_message ("mad_new() failed")); MifareClassicSectorNumber *s_alloc = mifare_application_alloc (mad, aid, 3*3*16); cut_assert_not_null (s_alloc, cut_message ("mifare_application_alloc() failed")); MifareClassicSectorNumber *s_found = mifare_application_find (mad, aid); cut_assert_not_null (s_found, cut_message ("mifare_application_alloc() failed")); for (i = 0; s_alloc[i]; i++) { cut_assert_equal_int (s_alloc[i], s_found[i], cut_message ("Allocated and found blocks don't match at position %d", i)); } cut_assert_equal_int (0, s_alloc[i], cut_message ("Invalid size")); cut_assert_equal_int (0, s_found[i], cut_message ("Invalid size")); mifare_application_free (mad, aid); free (s_alloc); free (s_found); s_found = mifare_application_find (mad, aid); cut_assert_null (s_found, cut_message ("mifare_application_free() failed")); s_alloc = mifare_application_alloc (mad, aid, 15*16 + 1*16 + 1); cut_assert_not_null (s_alloc, cut_message ("mifare_application_alloc() failed")); s_found = mifare_application_find (mad, aid); cut_assert_not_null (s_found, cut_message ("mifare_application_alloc() failed")); for (i = 0; s_alloc[i]; i++) { cut_assert_equal_int (s_alloc[i], s_found[i], cut_message ("Allocated and found blocks don't match at position %d", i)); } cut_assert_equal_int (0, s_alloc[i], cut_message ("Invalid size")); cut_assert_equal_int (0, s_found[i], cut_message ("Invalid size")); mifare_application_free (mad, aid); free (s_alloc); free (s_found); s_found = mifare_application_find (mad, aid); cut_assert_null (s_found, cut_message ("mifare_application_free() failed")); mad_free (mad); }
void test_mad_sector_0x00_crc8 (void) { int res; Mad mad = mad_new (1); cut_assert_not_null (mad, cut_message ("mad_new() failed")); res = mad_set_card_publisher_sector (mad, 0x01); /* Block 1 */ MadAid aid1 = { 0x01, 0x08 }; mad_set_aid (mad, 1, aid1); mad_set_aid (mad, 2, aid1); mad_set_aid (mad, 3, aid1); /* Block 2 */ MadAid empty_aid = { 0x00, 0x00 }; mad_set_aid (mad, 4, empty_aid); mad_set_aid (mad, 5, empty_aid); mad_set_aid (mad, 6, empty_aid); MadAid aid2 = { 0x04, 0x00 }; mad_set_aid (mad, 7, aid2); /* Block 3 */ MadAid aid3 = { 0x03, 0x10 }; mad_set_aid (mad, 8, aid3); mad_set_aid (mad, 9, aid3); MadAid aid4 = { 0x02, 0x10 }; mad_set_aid (mad, 10, aid4); mad_set_aid (mad, 11, aid4); mad_set_aid (mad, 12, empty_aid); mad_set_aid (mad, 13, empty_aid); mad_set_aid (mad, 14, empty_aid); MadAid aid5 = { 0x11, 0x30 }; mad_set_aid (mad, 15, aid5); res = sector_0x00_crc8 (mad); cut_assert_equal_int(0x89, res, cut_message ("Sample CRC should match")); mad_free (mad); }
void test_mifare_classic_mad (void) { MifareClassicKey key_a_transport = { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff }; MifareClassicKey key_b_sector_00 = { 0xaa, 0xbb, 0xcc, 0xdd, 0xee, 0xff }; MifareClassicKey key_b_sector_10 = { 0x1a, 0x98, 0x2c, 0x7e, 0x45 ,0x9a }; MifareClassicBlock tb; Mad mad; int res; /* __ __ _ ___ _ * | \/ | /_\ | \__ _/ | * | |\/| |/ _ \| |) \ V / | * |_| |_/_/ \_\___/ \_/|_| */ mad = mad_new (1); cut_assert_not_null (mad, cut_message ("mad_new() failed")); // Prepare sector 0x00 for writing a MAD. res = mifare_classic_authenticate (tag, 0x00, key_a_transport, MFC_KEY_A); cut_assert_equal_int (0, res, cut_message ("mifare_classic_authenticate() failed")); mifare_classic_trailer_block (&tb, key_a_transport, 00, 00, 00, 06, 0x00, key_b_sector_00); res = mifare_classic_write (tag, 0x03, tb); cut_assert_equal_int (0, res, cut_message ("mifare_classic_write() failed")); // Write the empty MAD res = mad_write (tag, mad, key_b_sector_00, NULL); cut_assert_equal_int (0, res, cut_message ("mad_write() failed")); // Check the empty MAD MifareClassicBlock ref_01 = { 0xce, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; MifareClassicBlock ref_02 = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; MifareClassicBlock data; res = mifare_classic_authenticate (tag, 0x01, mad_public_key_a, MFC_KEY_A); cut_assert_equal_int (0, res, cut_message ("mifare_classic_authenticate() failed")); res = mifare_classic_read (tag, 0x01, &data); cut_assert_equal_int (0, res, cut_message ("mad_read() failed")); cut_assert_equal_memory (ref_01, sizeof (ref_01), data, sizeof (data), cut_message ("Wrong data")); res = mifare_classic_read (tag, 0x02, &data); cut_assert_equal_int (0, res, cut_message ("mad_read() failed")); cut_assert_equal_memory (ref_02, sizeof (ref_02), data, sizeof (data), cut_message ("Wrong data")); Mad mad2 = mad_read (tag); cut_assert_not_null (mad2, cut_message ("mad_read() failed")); cut_assert_equal_memory (mad, sizeof (mad), mad2, sizeof (mad2), cut_message ("Wrong MAD")); const char application_data[] = "APPLICATION DATA >> APPLICATION DATA >> APPLICATION DATA >> " \ "APPLICATION DATA >> APPLICATION DATA >> APPLICATION DATA >> " \ "APPLICATION DATA >> APPLICATION DATA >> APPLICATION DATA >> " \ "APPLICATION DATA >> APPLICATION DATA >> APPLICATION DATA >> " \ "APPLICATION DATA >> APPLICATION DATA >> APPLICATION DATA >> " \ "APPLICATION DATA >> APPLICATION DATA >> APPLICATION DATA >> "; MadAid aid = { .function_cluster_code = 0x01, .application_code = 0x12 }; // Write some data in the application MifareClassicSectorNumber *sectors = mifare_application_alloc (mad, aid, sizeof (application_data)); cut_assert_not_null (sectors, cut_message ("mifare_application_alloc() failed")); free (sectors); res = mad_write (tag, mad, key_b_sector_00, NULL); cut_assert_equal_int (0, res, cut_message ("mad_write() failed")); ssize_t s = mifare_application_write (tag, mad, aid, &application_data, sizeof (application_data), key_a_transport, MFC_KEY_A); cut_assert_equal_int (sizeof (application_data), s, cut_message ("mifare_application_write() failed")); char read_buf[500]; // Read it again s = mifare_application_read (tag, mad, aid, read_buf, sizeof (application_data), key_a_transport, MFC_KEY_A); cut_assert_equal_int (sizeof (application_data), s, cut_message ("mifare_application_read() failed")); cut_assert_equal_memory (application_data, sizeof (application_data), read_buf, s, cut_message ("Wrong application data")); mad_free (mad); mad_free (mad2); // Revert to the transport configuration res = mifare_classic_authenticate (tag, 0x00, key_b_sector_00, MFC_KEY_B); cut_assert_equal_int (0, res, cut_message ("mifare_classic_authenticate() failed")); res = mifare_classic_format_sector (tag, 0x00); cut_assert_equal_int (0, res, cut_message ("mifare_classic_format_sector() failed")); /* __ __ _ ___ ___ * | \/ | /_\ | \__ _|_ ) * | |\/| |/ _ \| |) \ V // / * |_| |_/_/ \_\___/ \_//___| */ if (freefare_get_tag_type (tag) != CLASSIC_4K) { cut_omit ("MADv2 requires a MIFARE Classic 4K to be tested"); } mad = mad_new (2); cut_assert_not_null (mad, cut_message ("mad_new() failed")); // Prepare sector 0x00 for writing a MAD. res = mifare_classic_authenticate (tag, 0x00, key_a_transport, MFC_KEY_A); cut_assert_equal_int (0, res, cut_message ("mifare_classic_authenticate() failed")); mifare_classic_trailer_block (&tb, key_a_transport, 00, 00, 00, 06, 0x00, key_b_sector_00); res = mifare_classic_write (tag, 0x03, tb); cut_assert_equal_int (0, res, cut_message ("mifare_classic_write() failed")); // Prepare sector 0x10 for writing a MAD. res = mifare_classic_authenticate (tag, 0x40, key_a_transport, MFC_KEY_A); cut_assert_equal_int (0, res, cut_message ("mifare_classic_authenticate() failed")); mifare_classic_trailer_block (&tb, key_a_transport, 00, 00, 00, 06, 0x00, key_b_sector_10); res = mifare_classic_write (tag, 0x43, tb); cut_assert_equal_int (0, res, cut_message ("mifare_classic_write() failed")); // Write the empty MAD res = mad_write (tag, mad, key_b_sector_00, key_b_sector_10); cut_assert_equal_int (0, res, cut_message ("mad_write() failed")); // Check the empty MAD res = mifare_classic_authenticate (tag, 0x01, mad_public_key_a, MFC_KEY_A); cut_assert_equal_int (0, res, cut_message ("mifare_classic_authenticate() failed")); res = mifare_classic_read (tag, 0x01, &data); cut_assert_equal_int (0, res, cut_message ("mad_read() failed")); cut_assert_equal_memory (ref_01, sizeof (ref_01), data, sizeof (data), cut_message ("Wrong data")); res = mifare_classic_read (tag, 0x02, &data); cut_assert_equal_int (0, res, cut_message ("mad_read() failed")); cut_assert_equal_memory (ref_02, sizeof (ref_02), data, sizeof (data), cut_message ("Wrong data")); MifareClassicBlock ref_40 = { 0x16, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; MifareClassicBlock ref_41 = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; MifareClassicBlock ref_42 = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; res = mifare_classic_authenticate (tag, 0x40, mad_public_key_a, MFC_KEY_A); cut_assert_equal_int (0, res, cut_message ("mifare_classic_authenticate() failed")); res = mifare_classic_read (tag, 0x40, &data); cut_assert_equal_int (0, res, cut_message ("mad_read() failed")); cut_assert_equal_memory (ref_40, sizeof (ref_01), data, sizeof (data), cut_message ("Wrong data")); res = mifare_classic_read (tag, 0x41, &data); cut_assert_equal_int (0, res, cut_message ("mad_read() failed")); cut_assert_equal_memory (ref_41, sizeof (ref_02), data, sizeof (data), cut_message ("Wrong data")); res = mifare_classic_read (tag, 0x42, &data); cut_assert_equal_int (0, res, cut_message ("mad_read() failed")); cut_assert_equal_memory (ref_42, sizeof (ref_02), data, sizeof (data), cut_message ("Wrong data")); mad2 = mad_read (tag); cut_assert_not_null (mad2, cut_message ("mad_read() failed")); cut_assert_equal_memory (mad, sizeof (mad), mad2, sizeof (mad2), cut_message ("Wrong MAD")); // Write some data in the application sectors = mifare_application_alloc (mad, aid, sizeof (application_data)); cut_assert_not_null (sectors, cut_message ("mifare_application_alloc() failed")); free (sectors); res = mad_write (tag, mad, key_b_sector_00, key_b_sector_10); cut_assert_equal_int (0, res, cut_message ("mad_write() failed")); s = mifare_application_write (tag, mad, aid, &application_data, sizeof (application_data), key_a_transport, MFC_KEY_A); cut_assert_equal_int (sizeof (application_data), s, cut_message ("mifare_application_write() failed")); // Read it again s = mifare_application_read (tag, mad, aid, read_buf, sizeof (application_data), key_a_transport, MFC_KEY_A); cut_assert_equal_int (sizeof (application_data), s, cut_message ("mifare_application_read() failed")); cut_assert_equal_memory (application_data, sizeof (application_data), read_buf, s, cut_message ("Wrong application data")); mad_free (mad); mad_free (mad2); // Revert to the transport configuration res = mifare_classic_authenticate (tag, 0x00, key_b_sector_00, MFC_KEY_B); cut_assert_equal_int (0, res, cut_message ("mifare_classic_authenticate() failed")); res = mifare_classic_format_sector (tag, 0x00); cut_assert_equal_int (0, res, cut_message ("mifare_classic_format_sector() failed")); res = mifare_classic_authenticate (tag, 0x40, key_b_sector_10, MFC_KEY_B); cut_assert_equal_int (0, res, cut_message ("mifare_classic_authenticate() failed")); res = mifare_classic_format_sector (tag, 0x10); cut_assert_equal_int (0, res, cut_message ("mifare_classic_format_sector() failed")); }
int main(int argc, char *argv[]) { MYSQL *conn; MYSQL_RES *result; MYSQL_ROW row; int retval; conn = mysql_init(NULL); retval = mysql_real_connect(conn, def_host_name, def_user_name, def_password, def_db_name, def_port_num, def_socket_name, def_client_flag); if(!retval) { printf("Error connecting to database: %s\n", mysql_error(conn)); return -1; } printf("Connection successful\n"); int error = 0; nfc_device_t *device = NULL; MifareTag *tags = NULL; Mad mad; MifareClassicKey transport_key = { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff }; char ndef_input[15] = {'\0'}; char ID[9] = {'\0'}; double balance = 0; printf("\nID: "); scanf("%s", ID); while (getchar() != '\n') continue; printf("\nBalance: "); scanf("%lf", &balance); while (getchar() != '\n') continue; ID[0] = toupper(ID[0]); ID[1] = toupper(ID[1]); char balance_char[6] = {'\0'}; snprintf(balance_char, 6, "%.2f", balance); //ensure balance always with 4 digit, 4.00 => 04.00 char final_balance[6] = {'\0'}; if(strlen(balance_char) != 5) { strcat(final_balance, "0"); strcat(final_balance, balance_char); } else { strcpy(final_balance, balance_char); } strcat(ndef_input, ID); strcat(ndef_input, final_balance); int i = 0; if (ndef_input == NULL) { printf("Write default message.\n"); for(i=0; i < sizeof(ndef_default_msg); i++) { ndef_msg[i] = (uint8_t)ndef_default_msg[i]; } ndef_msg_len = sizeof(ndef_default_msg); } else { for(i=0; i < strlen(ndef_input); i++) { ndef_msg[i] = (uint8_t)ndef_input[i]; } ndef_msg_len = strlen(ndef_input); } printf ("NDEF message is %zu bytes long.\n", ndef_msg_len); struct mifare_classic_key_and_type *card_write_keys; if (!(card_write_keys = malloc (40 * sizeof (*card_write_keys)))) { err (EXIT_FAILURE, "malloc"); } nfc_device_desc_t devices[8]; size_t device_count; nfc_list_devices (devices, 8, &device_count); if (!device_count) errx (EXIT_FAILURE, "No NFC device found."); for (size_t d = 0; d < device_count; d++) { device = nfc_connect (&(devices[d])); if (!device) { warnx ("nfc_connect() failed."); error = EXIT_FAILURE; continue; } tags = freefare_get_tags (device); if (!tags) { nfc_disconnect (device); errx (EXIT_FAILURE, "Error listing MIFARE classic tag."); } for (int i = 0; (!error) && tags[i]; i++) { switch (freefare_get_tag_type (tags[i])) { case CLASSIC_1K: case CLASSIC_4K: break; default: continue; } char *tag_uid = freefare_get_tag_uid (tags[i]); char buffer[BUFSIZ]; printf ("Found %s with UID %s.\n", freefare_get_tag_friendly_name (tags[i]), tag_uid); bool write_ndef = true; for (int n = 0; n < 40; n++) { memcpy(card_write_keys[n].key, transport_key, sizeof (transport_key)); card_write_keys[n].type = MFC_KEY_A; } if (write_ndef) { switch (freefare_get_tag_type (tags[i])) { case CLASSIC_4K: if (!search_sector_key (tags[i], 0x10, &(card_write_keys[0x10].key), &(card_write_keys[0x10].type))) { error = 1; goto error; } /* fallthrough */ case CLASSIC_1K: if (!search_sector_key (tags[i], 0x00, &(card_write_keys[0x00].key), &(card_write_keys[0x00].type))) { error = 1; goto error; } break; default: /* Keep compiler quiet */ break; } if (!error) { /* Ensure the auth key is always a B one. If not, change it! */ switch (freefare_get_tag_type (tags[i])) { case CLASSIC_4K: if (card_write_keys[0x10].type != MFC_KEY_B) { if( 0 != fix_mad_trailer_block (device, tags[i], 0x10, card_write_keys[0x10].key, card_write_keys[0x10].type)) { error = 1; goto error; } memcpy (&(card_write_keys[0x10].key), &default_keyb, sizeof (MifareClassicKey)); card_write_keys[0x10].type = MFC_KEY_B; } /* fallthrough */ case CLASSIC_1K: if (card_write_keys[0x00].type != MFC_KEY_B) { if( 0 != fix_mad_trailer_block (device, tags[i], 0x00, card_write_keys[0x00].key, card_write_keys[0x00].type)) { error = 1; goto error; } memcpy (&(card_write_keys[0x00].key), &default_keyb, sizeof (MifareClassicKey)); card_write_keys[0x00].type = MFC_KEY_B; } break; default: /* Keep compiler quiet */ break; } } size_t encoded_size; uint8_t *tlv_data = tlv_encode (3, ndef_msg, ndef_msg_len, &encoded_size); /* * At his point, we should have collected all information needed to * succeed. */ // If the card already has a MAD, load it. if ((mad = mad_read (tags[i]))) { // If our application already exists, erase it. MifareClassicSectorNumber *sectors, *p; sectors = p = mifare_application_find (mad, mad_nfcforum_aid); if (sectors) { while (*p) { if (mifare_classic_authenticate (tags[i], mifare_classic_sector_last_block(*p), default_keyb, MFC_KEY_B) < 0) { nfc_perror (device, "mifare_classic_authenticate"); error = 1; goto error; } if (mifare_classic_format_sector (tags[i], *p) < 0) { nfc_perror (device, "mifare_classic_format_sector"); error = 1; goto error; } p++; } } free (sectors); mifare_application_free (mad, mad_nfcforum_aid); } else { // Create a MAD and mark unaccessible sectors in the card if (!(mad = mad_new ((freefare_get_tag_type (tags[i]) == CLASSIC_4K) ? 2 : 1))) { perror ("mad_new"); error = 1; goto error; } MifareClassicSectorNumber max_s; switch (freefare_get_tag_type (tags[i])) { case CLASSIC_1K: max_s = 15; break; case CLASSIC_4K: max_s = 39; break; default: /* Keep compiler quiet */ break; } // Mark unusable sectors as so for (size_t s = max_s; s; s--) { if (s == 0x10) continue; if (!search_sector_key (tags[i], s, &(card_write_keys[s].key), &(card_write_keys[s].type))) { mad_set_aid (mad, s, mad_defect_aid); } else if ((memcmp (card_write_keys[s].key, transport_key, sizeof (transport_key)) != 0) && (card_write_keys[s].type != MFC_KEY_A)) { // Revert to transport configuration if (mifare_classic_format_sector (tags[i], s) < 0) { nfc_perror (device, "mifare_classic_format_sector"); error = 1; goto error; } } } } MifareClassicSectorNumber *sectors = mifare_application_alloc (mad, mad_nfcforum_aid, encoded_size); if (!sectors) { nfc_perror (device, "mifare_application_alloc"); error = EXIT_FAILURE; goto error; } if (mad_write (tags[i], mad, card_write_keys[0x00].key, card_write_keys[0x10].key) < 0) { nfc_perror (device, "mad_write"); error = EXIT_FAILURE; goto error; } int s = 0; while (sectors[s]) { MifareClassicBlockNumber block = mifare_classic_sector_last_block (sectors[s]); MifareClassicBlock block_data; mifare_classic_trailer_block (&block_data, mifare_classic_nfcforum_public_key_a, 0x0, 0x0, 0x0, 0x6, 0x40, default_keyb); if (mifare_classic_authenticate (tags[i], block, card_write_keys[sectors[s]].key, card_write_keys[sectors[s]].type) < 0) { nfc_perror (device, "mifare_classic_authenticate"); error = EXIT_FAILURE; goto error; } if (mifare_classic_write (tags[i], block, block_data) < 0) { nfc_perror (device, "mifare_classic_write"); error = EXIT_FAILURE; goto error; } s++; } if ((ssize_t) encoded_size != mifare_application_write (tags[i], mad, mad_nfcforum_aid, tlv_data, encoded_size, default_keyb, MCAB_WRITE_KEYB)) { nfc_perror (device, "mifare_application_write"); error = EXIT_FAILURE; goto error; } //create new student record in database char sql_stmnt[57] = {'\0'}; int n = 0; //filter tag_uid ulong uid_length = strlen(tag_uid); char uid_esc[(2 * uid_length)+1]; mysql_real_escape_string(conn, uid_esc, tag_uid, uid_length); //filter ID ulong id_length = strlen(ID); char id_esc[(2 * id_length)+1]; mysql_real_escape_string(conn, id_esc, ID, id_length); n = snprintf(sql_stmnt, 57, "INSERT INTO student VALUES('%s', '%s', %.1f)", uid_esc, id_esc, balance); retval = mysql_real_query(conn, sql_stmnt, n); if(retval) { printf("Inserting data from DB Failed\n"); return -1; } printf("Insert to DB successful\n"); free (sectors); free (tlv_data); free (mad); } error: free (tag_uid); } //should at the line 412, but the compiler keep on complaining //jump into scope of identifier with variably modified type //no idea why that happens, goto is always call inside any {} to outside error: //even at 412, still not outside enough freefare_free_tags (tags); nfc_disconnect (device); } free (card_write_keys); mysql_free_result(result); mysql_close(conn); exit (error); }
void test_mad (void) { int res; Mad mad = mad_new (1); cut_assert_not_null (mad, cut_message ("Can create a new MAD")); cut_assert_equal_int (1, mad_get_version (mad), cut_message ("Wrong default MAD version")); mad_set_version (mad, 2); cut_assert_equal_int (2, mad_get_version (mad), cut_message ("Can't change MAD version")); cut_assert_equal_int (0, mad_get_card_publisher_sector (mad), cut_message ("Wrong default MAD publisher")); res = mad_set_card_publisher_sector (mad, 13); cut_assert_equal_int (0, res, cut_message ("mad_set_card_publisher_sector() returned an error.")); cut_assert_equal_int (13, mad_get_card_publisher_sector (mad), cut_message ("Wrong publisher sector")); res = mad_set_card_publisher_sector (mad, 0xff); cut_assert_equal_int (-1, res, cut_message ("Invalid sector")); cut_assert_equal_int (13, mad_get_card_publisher_sector (mad), cut_message ("Previous publisher sector value")); MadAid aid = { .function_cluster_code = 0, .application_code = 0 }; res = mad_get_aid (mad, 3, &aid); cut_assert_equal_int (0, res, cut_message ("mad_get_aid() failed")); cut_assert_equal_int (0, aid.function_cluster_code, cut_message ("Invalid default value")); cut_assert_equal_int (0, aid.application_code, cut_message ("Invalid default value")); aid.function_cluster_code = 0xc0; aid.application_code = 0x42; res = mad_set_aid (mad, 3, aid); cut_assert_equal_int (0, res, cut_message ("mad_set_aid() failed")); res = mad_get_aid (mad, 3, &aid); cut_assert_equal_int (0, res, cut_message ("mad_get_aid() failed")); cut_assert_equal_int (0xC0, aid.function_cluster_code, cut_message ("Invalid value")); cut_assert_equal_int (0x42, aid.application_code, cut_message ("Invalid value")); mad_free (mad); } #define CRC_PRESET 0xc7 void test_mad_crc8_basic (void) { uint8_t crc; const uint8_t crc_value = 0x42; /* Check integrity */ crc = CRC_PRESET; nxp_crc(&crc, crc_value); uint8_t save = crc; crc = CRC_PRESET; nxp_crc(&crc, crc_value); nxp_crc(&crc, save); cut_assert_equal_int (0x00, crc, cut_message ("CRC should verify crc(message + crc(message)) = 0")); }