import pytest from conftest import skip_if_device_version_lower_than from constants import DefaultPasswords, DeviceErrorCode, RFC_SECRET from misc import ffi, gs, wait, cast_pointer_to_tuple from misc import is_pro_rtm_07, is_pro_rtm_08, is_storage @pytest.mark.lock_device @pytest.mark.PWS def test_enable_password_safe(C): """ All Password Safe tests depend on AES keys being initialized. They will fail otherwise. """ assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK assert C.NK_enable_password_safe('wrong_password') == DeviceErrorCode.WRONG_PASSWORD assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK @pytest.mark.lock_device @pytest.mark.PWS def test_write_password_safe_slot(C): assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK assert C.NK_write_password_safe_slot(0, 'slotname1', 'login1', 'pass1') == DeviceErrorCode.STATUS_NOT_AUTHORIZED assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK assert C.NK_write_password_safe_slot(0, 'slotname1', 'login1', 'pass1') == DeviceErrorCode.STATUS_OK @pytest.mark.lock_device @pytest.mark.PWS @pytest.mark.slowtest def test_write_all_password_safe_slots_and_read_10_times(C): def fill(s, wid): assert wid >= len(s) numbers = '1234567890'*4 s += numbers[:wid-len(s)] assert len(s) == wid return s def get_pass(suffix): return fill('pass' + suffix, 20) def get_loginname(suffix): return fill('login' + suffix, 32) def get_slotname(suffix): return fill('slotname' + suffix, 11) assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK PWS_slot_count = 16 for i in range(0, PWS_slot_count): iss = str(i) assert C.NK_write_password_safe_slot(i, get_slotname(iss), get_loginname(iss), get_pass(iss)) == DeviceErrorCode.STATUS_OK for j in range(0, 10): for i in range(0, PWS_slot_count): iss = str(i) assert gs(C.NK_get_password_safe_slot_name(i)) == get_slotname(iss) assert gs(C.NK_get_password_safe_slot_login(i)) == get_loginname(iss) assert gs(C.NK_get_password_safe_slot_password(i)) == get_pass(iss) @pytest.mark.lock_device @pytest.mark.PWS @pytest.mark.slowtest @pytest.mark.xfail(reason="This test should be run directly after test_write_all_password_safe_slots_and_read_10_times") def test_read_all_password_safe_slots_10_times(C): def fill(s, wid): assert wid >= len(s) numbers = '1234567890'*4 s += numbers[:wid-len(s)] assert len(s) == wid return s def get_pass(suffix): return fill('pass' + suffix, 20) def get_loginname(suffix): return fill('login' + suffix, 32) def get_slotname(suffix): return fill('slotname' + suffix, 11) assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK PWS_slot_count = 16 for j in range(0, 10): for i in range(0, PWS_slot_count): iss = str(i) assert gs(C.NK_get_password_safe_slot_name(i)) == get_slotname(iss) assert gs(C.NK_get_password_safe_slot_login(i)) == get_loginname(iss) assert gs(C.NK_get_password_safe_slot_password(i)) == get_pass(iss) @pytest.mark.lock_device @pytest.mark.PWS def test_get_password_safe_slot_name(C): assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK assert C.NK_write_password_safe_slot(0, 'slotname1', 'login1', 'pass1') == DeviceErrorCode.STATUS_OK assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK assert gs(C.NK_get_password_safe_slot_name(0)) == '' assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_NOT_AUTHORIZED assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK assert gs(C.NK_get_password_safe_slot_name(0)) == 'slotname1' assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK @pytest.mark.PWS def test_get_password_safe_slot_login_password(C): assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK assert C.NK_write_password_safe_slot(0, 'slotname1', 'login1', 'pass1') == DeviceErrorCode.STATUS_OK slot_login = C.NK_get_password_safe_slot_login(0) assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK assert gs(slot_login) == 'login1' slot_password = gs(C.NK_get_password_safe_slot_password(0)) assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK assert slot_password == 'pass1' @pytest.mark.PWS def test_erase_password_safe_slot(C): assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK assert C.NK_erase_password_safe_slot(0) == DeviceErrorCode.STATUS_OK assert gs(C.NK_get_password_safe_slot_name(0)) == '' assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK # TODO CHECK shouldn't this be DeviceErrorCode.NOT_PROGRAMMED ? @pytest.mark.PWS def test_password_safe_slot_status(C): C.NK_set_debug(True) assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK assert C.NK_erase_password_safe_slot(0) == DeviceErrorCode.STATUS_OK assert C.NK_write_password_safe_slot(1, 'slotname2', 'login2', 'pass2') == DeviceErrorCode.STATUS_OK safe_slot_status = C.NK_get_password_safe_slot_status() assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK is_slot_programmed = list(ffi.cast("uint8_t [16]", safe_slot_status)[0:16]) print((is_slot_programmed, len(is_slot_programmed))) assert is_slot_programmed[0] == 0 assert is_slot_programmed[1] == 1 @pytest.mark.aes def test_issue_device_locks_on_second_key_generation_in_sequence(C): if is_pro_rtm_07(C) or is_pro_rtm_08(C): pytest.skip("issue to register: device locks up " "after below commands sequence (reinsertion fixes), skipping for now") assert C.NK_build_aes_key(DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK assert C.NK_build_aes_key(DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK @pytest.mark.aes def test_regenerate_aes_key(C): C.NK_set_debug(True) assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_build_aes_key(DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK @pytest.mark.lock_device @pytest.mark.aes @pytest.mark.factory_reset def test_enable_password_safe_after_factory_reset(C): assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK if is_storage(C): # for some reason storage likes to be authenticated before reset (to investigate) assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_factory_reset(DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK wait(10) if is_storage(C): assert C.NK_clear_new_sd_card_warning(DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK enable_password_safe_result = C.NK_enable_password_safe(DefaultPasswords.USER) assert enable_password_safe_result == DeviceErrorCode.STATUS_AES_DEC_FAILED \ or is_storage(C) and enable_password_safe_result == DeviceErrorCode.WRONG_PASSWORD assert C.NK_build_aes_key(DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK @pytest.mark.lock_device @pytest.mark.aes @pytest.mark.xfail(reason="NK Pro firmware bug: regenerating AES key command not always results in cleared slot data") def test_destroy_password_safe(C): """ Sometimes fails on NK Pro - slot name is not cleared ergo key generation has not succeed despite the success result returned from the device """ C.NK_set_debug(True) assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK # write password safe slot assert C.NK_write_password_safe_slot(0, 'slotname1', 'login1', 'pass1') == DeviceErrorCode.STATUS_OK # read slot assert gs(C.NK_get_password_safe_slot_name(0)) == 'slotname1' assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK slot_login = C.NK_get_password_safe_slot_login(0) assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK assert gs(slot_login) == 'login1' # destroy password safe by regenerating aes key assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_build_aes_key(DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK assert gs(C.NK_get_password_safe_slot_name(0)) != 'slotname1' assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK # check was slot status cleared safe_slot_status = C.NK_get_password_safe_slot_status() assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK is_slot_programmed = list(ffi.cast("uint8_t [16]", safe_slot_status)[0:16]) assert is_slot_programmed[0] == 0 @pytest.mark.aes def test_is_AES_supported(C): if is_storage(C): pytest.skip("Storage does not implement this command") assert C.NK_is_AES_supported('wrong password') != 1 assert C.NK_get_last_command_status() == DeviceErrorCode.WRONG_PASSWORD assert C.NK_is_AES_supported(DefaultPasswords.USER) == 1 assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK @pytest.mark.pin def test_admin_PIN_change(C): new_password = '123123123' assert C.NK_change_admin_PIN('wrong_password', new_password) == DeviceErrorCode.WRONG_PASSWORD assert C.NK_change_admin_PIN(DefaultPasswords.ADMIN, new_password) == DeviceErrorCode.STATUS_OK assert C.NK_change_admin_PIN(new_password, DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK @pytest.mark.pin def test_user_PIN_change(C): new_password = '123123123' assert C.NK_change_user_PIN('wrong_password', new_password) == DeviceErrorCode.WRONG_PASSWORD assert C.NK_change_user_PIN(DefaultPasswords.USER, new_password) == DeviceErrorCode.STATUS_OK assert C.NK_change_user_PIN(new_password, DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK @pytest.mark.lock_device @pytest.mark.pin def test_admin_retry_counts(C): default_admin_retry_count = 3 assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK assert C.NK_get_admin_retry_count() == default_admin_retry_count assert C.NK_change_admin_PIN('wrong_password', DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.WRONG_PASSWORD assert C.NK_get_admin_retry_count() == default_admin_retry_count - 1 assert C.NK_change_admin_PIN(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK assert C.NK_get_admin_retry_count() == default_admin_retry_count @pytest.mark.lock_device @pytest.mark.pin def test_user_retry_counts_change_PIN(C): assert C.NK_change_user_PIN(DefaultPasswords.USER, DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK wrong_password = 'wrong_password' default_user_retry_count = 3 assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK assert C.NK_get_user_retry_count() == default_user_retry_count assert C.NK_change_user_PIN(wrong_password, wrong_password) == DeviceErrorCode.WRONG_PASSWORD assert C.NK_get_user_retry_count() == default_user_retry_count - 1 assert C.NK_change_user_PIN(DefaultPasswords.USER, DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK assert C.NK_get_user_retry_count() == default_user_retry_count @pytest.mark.lock_device @pytest.mark.pin def test_user_retry_counts_PWSafe(C): default_user_retry_count = 3 assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK assert C.NK_get_user_retry_count() == default_user_retry_count assert C.NK_enable_password_safe('wrong_password') == DeviceErrorCode.WRONG_PASSWORD assert C.NK_get_user_retry_count() == default_user_retry_count - 1 assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK assert C.NK_get_user_retry_count() == default_user_retry_count @pytest.mark.pin def test_unlock_user_password(C): C.NK_set_debug(True) default_user_retry_count = 3 default_admin_retry_count = 3 new_password = '123123123' assert C.NK_get_user_retry_count() == default_user_retry_count assert C.NK_change_user_PIN('wrong_password', new_password) == DeviceErrorCode.WRONG_PASSWORD assert C.NK_change_user_PIN('wrong_password', new_password) == DeviceErrorCode.WRONG_PASSWORD assert C.NK_change_user_PIN('wrong_password', new_password) == DeviceErrorCode.WRONG_PASSWORD assert C.NK_get_user_retry_count() == default_user_retry_count - 3 assert C.NK_get_admin_retry_count() == default_admin_retry_count assert C.NK_unlock_user_password('wrong password', DefaultPasswords.USER) == DeviceErrorCode.WRONG_PASSWORD assert C.NK_get_admin_retry_count() == default_admin_retry_count - 1 assert C.NK_unlock_user_password(DefaultPasswords.ADMIN, DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK assert C.NK_get_user_retry_count() == default_user_retry_count assert C.NK_get_admin_retry_count() == default_admin_retry_count @pytest.mark.pin def test_admin_auth(C): assert C.NK_first_authenticate('wrong_password', DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.WRONG_PASSWORD assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK @pytest.mark.pin def test_user_auth(C): assert C.NK_user_authenticate('wrong_password', DefaultPasswords.USER_TEMP) == DeviceErrorCode.WRONG_PASSWORD assert C.NK_user_authenticate(DefaultPasswords.USER, DefaultPasswords.USER_TEMP) == DeviceErrorCode.STATUS_OK @pytest.mark.otp def check_HOTP_RFC_codes(C, func, prep=None, use_8_digits=False): """ # https://tools.ietf.org/html/rfc4226#page-32 """ assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_hotp_slot(1, 'python_test', RFC_SECRET, 0, use_8_digits, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK test_data = [ 1284755224, 1094287082, 137359152, 1726969429, 1640338314, 868254676, 1918287922, 82162583, 673399871, 645520489, ] for code in test_data: if prep: prep() r = func(1) code = str(code)[-8:] if use_8_digits else str(code)[-6:] assert code == r @pytest.mark.otp @pytest.mark.parametrize("use_8_digits", [False, True, ]) @pytest.mark.parametrize("use_pin_protection", [False, True, ]) def test_HOTP_RFC_use8digits_usepin(C, use_8_digits, use_pin_protection): assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, use_pin_protection, not use_pin_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK if use_pin_protection: check_HOTP_RFC_codes(C, lambda x: gs(C.NK_get_hotp_code_PIN(x, DefaultPasswords.USER_TEMP)), lambda: C.NK_user_authenticate(DefaultPasswords.USER, DefaultPasswords.USER_TEMP), use_8_digits=use_8_digits) else: check_HOTP_RFC_codes(C, lambda x: gs(C.NK_get_hotp_code(x)), use_8_digits=use_8_digits) @pytest.mark.otp def test_HOTP_token(C): """ Check HOTP routine with written token ID to slot. """ use_pin_protection = False assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, use_pin_protection, not use_pin_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK token_ID = "AAV100000022" assert C.NK_write_hotp_slot(1, 'python_test', RFC_SECRET, 0, False, False, True, token_ID, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK for i in range(5): hotp_code = gs(C.NK_get_hotp_code(1)) assert hotp_code != "" assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK @pytest.mark.otp def test_HOTP_counters(C): """ # https://tools.ietf.org/html/rfc4226#page-32 """ use_pin_protection = False assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, use_pin_protection, not use_pin_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK use_8_digits = True HOTP_test_data = [ 1284755224, 1094287082, 137359152, 1726969429, 1640338314, 868254676, 1918287922, 82162583, 673399871, 645520489, ] slot_number = 1 for counter, code in enumerate(HOTP_test_data): assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_hotp_slot(slot_number, 'python_test', RFC_SECRET, counter, use_8_digits, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK r = gs(C.NK_get_hotp_code(slot_number)) code = str(code)[-8:] if use_8_digits else str(code)[-6:] assert code == r INT32_MAX = 2 ** 31 - 1 @pytest.mark.otp def test_HOTP_64bit_counter(C): if is_storage(C): pytest.xfail('bug in NK Storage HOTP firmware - counter is set with a 8 digits string, ' 'however int32max takes 10 digits to be written') oath = pytest.importorskip("oath") lib_at = lambda t: oath.hotp(RFC_SECRET, t, format='dec6') PIN_protection = False use_8_digits = False slot_number = 1 assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, PIN_protection, not PIN_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK dev_res = [] lib_res = [] for t in range(INT32_MAX - 5, INT32_MAX + 5, 1): assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_hotp_slot(slot_number, 'python_test', RFC_SECRET, t, use_8_digits, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK code_device = gs(C.NK_get_hotp_code(slot_number)) dev_res += (t, code_device) lib_res += (t, lib_at(t)) assert dev_res == lib_res @pytest.mark.otp def test_TOTP_64bit_time(C): if is_storage(C): pytest.xfail('bug in NK Storage TOTP firmware') oath = pytest.importorskip("oath") T = 1 lib_at = lambda t: oath.totp(RFC_SECRET, t=t) PIN_protection = False slot_number = 1 assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, PIN_protection, not PIN_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_totp_slot(slot_number, 'python_test', RFC_SECRET, 30, False, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK dev_res = [] lib_res = [] for t in range(INT32_MAX - 5, INT32_MAX + 5, 1): assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_totp_set_time(t) == DeviceErrorCode.STATUS_OK code_device = gs((C.NK_get_totp_code(slot_number, T, 0, 30))) dev_res += (t, code_device) lib_res += (t, lib_at(t)) assert dev_res == lib_res @pytest.mark.otp @pytest.mark.xfail(reason="NK Pro: Test fails in 50% of cases due to test vectors set 1 second before interval count change" "Here time is changed on seconds side only and miliseconds part is not being reset apparently" "This results in available time to test of half a second on average, thus 50% failed cases" "With disabled two first test vectors test passess 10/10 times" "Fail may also occurs on NK Storage with lower occurrency since it needs less time to execute " "commands") @pytest.mark.parametrize("PIN_protection", [False, True, ]) def test_TOTP_RFC_usepin(C, PIN_protection): slot_number = 1 assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, PIN_protection, not PIN_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK # test according to https://tools.ietf.org/html/rfc6238#appendix-B assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_totp_slot(slot_number, 'python_test', RFC_SECRET, 30, True, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK get_func = None if PIN_protection: get_func = lambda x, y, z, r: gs(C.NK_get_totp_code_PIN(x, y, z, r, DefaultPasswords.USER_TEMP)) else: get_func = lambda x: gs(C.NK_get_totp_code) # Mode: Sha1, time step X=30 test_data = [ #Time T (hex) TOTP (59, 0x1, 94287082), # Warning - test vector time 1 second before interval count changes (1111111109, 0x00000000023523EC, 7081804), # Warning - test vector time 1 second before interval count changes (1111111111, 0x00000000023523ED, 14050471), (1234567890, 0x000000000273EF07, 89005924), (2000000000, 0x0000000003F940AA, 69279037), # (20000000000, 0x0000000027BC86AA, 65353130), # 64bit is also checked in other test ] responses = [] data = [] correct = 0 for t, T, expected_code in test_data: if PIN_protection: C.NK_user_authenticate(DefaultPasswords.USER, DefaultPasswords.USER_TEMP) assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_totp_set_time(t) == DeviceErrorCode.STATUS_OK code_from_device = get_func(slot_number, T, 0, 30) # FIXME T is not changing the outcome data += [ (t, expected_code) ] responses += [ (t, code_from_device) ] correct += expected_code == code_from_device assert data == responses or correct == len(test_data) @pytest.mark.otp def test_get_slot_names(C): C.NK_set_debug(True) assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_erase_totp_slot(0, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK # erasing slot invalidates temporary password, so requesting authentication assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_erase_hotp_slot(0, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK for i in range(15): name = ffi.string(C.NK_get_totp_slot_name(i)) if name == '': assert C.NK_get_last_command_status() == DeviceErrorCode.NOT_PROGRAMMED for i in range(3): name = ffi.string(C.NK_get_hotp_slot_name(i)) if name == '': assert C.NK_get_last_command_status() == DeviceErrorCode.NOT_PROGRAMMED @pytest.mark.otp def test_get_OTP_codes(C): assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, False, True, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK for i in range(15): code = gs(C.NK_get_totp_code(i, 0, 0, 0)) if code == "": assert C.NK_get_last_command_status() == DeviceErrorCode.NOT_PROGRAMMED for i in range(3): code = gs(C.NK_get_hotp_code(i)) if code == "": assert C.NK_get_last_command_status() == DeviceErrorCode.NOT_PROGRAMMED @pytest.mark.otp def test_get_OTP_code_from_not_programmed_slot(C): assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, False, True, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_erase_hotp_slot(0, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_erase_totp_slot(0, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK code = gs(C.NK_get_hotp_code(0)) assert code == "" assert C.NK_get_last_command_status() == DeviceErrorCode.NOT_PROGRAMMED code = gs(C.NK_get_totp_code(0, 0, 0, 0)) assert code == "" assert C.NK_get_last_command_status() == DeviceErrorCode.NOT_PROGRAMMED @pytest.mark.otp def test_get_code_user_authorize(C): C.NK_set_debug(True) assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_totp_slot(0, 'python_otp_auth', RFC_SECRET, 30, True, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK # enable PIN protection of OTP codes with write_config # TODO create convinience function on C API side to enable/disable OTP USER_PIN protection assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, True, False, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK code = gs(C.NK_get_totp_code(0, 0, 0, 0)) assert code == "" assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_NOT_AUTHORIZED # disable PIN protection with write_config assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, False, True, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK code = gs(C.NK_get_totp_code(0, 0, 0, 0)) assert code != "" assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK def cast_pointer_to_tuple(obj, typen, len): # usage: # config = cast_pointer_to_tuple(config_raw_data, 'uint8_t', 5) return tuple(ffi.cast("%s [%d]" % (typen, len), obj)[0:len]) def test_read_write_config(C): C.NK_set_debug(True) # let's set sample config with pin protection and disabled scrolllock assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(0, 1, 2, True, False, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK config_raw_data = C.NK_read_config() assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK config = cast_pointer_to_tuple(config_raw_data, 'uint8_t', 5) assert config == (0, 1, 2, True, False) # restore defaults and check assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, False, True, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK config_raw_data = C.NK_read_config() assert C.NK_get_last_command_status() == DeviceErrorCode.STATUS_OK config = cast_pointer_to_tuple(config_raw_data, 'uint8_t', 5) assert config == (255, 255, 255, False, True) @pytest.mark.lock_device @pytest.mark.factory_reset def test_factory_reset(C): C.NK_set_debug(True) assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, False, True, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_hotp_slot(1, 'python_test', RFC_SECRET, 0, False, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert gs(C.NK_get_hotp_code(1)) == "755224" assert C.NK_factory_reset(DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK wait(10) assert gs(C.NK_get_hotp_code(1)) != "287082" assert C.NK_get_last_command_status() == DeviceErrorCode.NOT_PROGRAMMED # restore AES key assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_build_aes_key(DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK assert C.NK_enable_password_safe(DefaultPasswords.USER) == DeviceErrorCode.STATUS_OK assert C.NK_lock_device() == DeviceErrorCode.STATUS_OK if is_storage(C): assert C.NK_clear_new_sd_card_warning(DefaultPasswords.ADMIN) == DeviceErrorCode.STATUS_OK @pytest.mark.status def test_get_status(C): status = C.NK_status() s = gs(status) assert len(s) > 0 @pytest.mark.status def test_get_serial_number(C): sn = C.NK_device_serial_number() sn = gs(sn) assert len(sn) > 0 print(('Serial number of the device: ', sn)) @pytest.mark.otp @pytest.mark.parametrize("secret", ['000001', '00'*10+'ff', '00'*19+'ff', '000102', '00'*29+'ff', '00'*39+'ff', '002EF43F51AFA97BA2B46418768123C9E1809A5B' ]) def test_OTP_secret_started_from_null(C, secret): """ NK Pro 0.8+, NK Storage 0.43+ """ skip_if_device_version_lower_than({'S': 43, 'P': 8}) if len(secret) > 40: # feature: 320 bit long secret handling skip_if_device_version_lower_than({'P': 8}) oath = pytest.importorskip("oath") lib_at = lambda t: oath.hotp(secret, t, format='dec6') PIN_protection = False use_8_digits = False slot_number = 1 assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, PIN_protection, not PIN_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK dev_res = [] lib_res = [] for t in range(1,5): assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_hotp_slot(slot_number, 'null_secret', secret, t, use_8_digits, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK code_device = gs(C.NK_get_hotp_code(slot_number)) dev_res += (t, code_device) lib_res += (t, lib_at(t)) assert dev_res == lib_res @pytest.mark.otp @pytest.mark.parametrize("counter", [0, 3, 7, 0xffff, 0xffffffff, 0xffffffffffffffff] ) def test_HOTP_slots_read_write_counter(C, counter): """ Write different counters to all HOTP slots, read code and compare with 3rd party :param counter: """ if counter >= 1e7: # Storage does not handle counters longer than 7 digits skip_if_device_version_lower_than({'P': 7}) secret = RFC_SECRET oath = pytest.importorskip("oath") lib_at = lambda t: oath.hotp(secret, t, format='dec6') PIN_protection = False use_8_digits = False assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, PIN_protection, not PIN_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK dev_res = [] lib_res = [] for slot_number in range(3): assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_hotp_slot(slot_number, 'HOTP rw' + str(slot_number), secret, counter, use_8_digits, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK code_device = gs(C.NK_get_hotp_code(slot_number)) dev_res += (counter, code_device) lib_res += (counter, lib_at(counter)) assert dev_res == lib_res @pytest.mark.otp @pytest.mark.parametrize("period", [30,60] ) @pytest.mark.parametrize("time", range(21,70,20) ) def test_TOTP_slots_read_write_at_time_period(C, time, period): """ Write to all TOTP slots with specified period, read code at specified time and compare with 3rd party """ secret = RFC_SECRET oath = pytest.importorskip("oath") lib_at = lambda t: oath.totp(RFC_SECRET, t=t, period=period) PIN_protection = False use_8_digits = False T = 0 assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, PIN_protection, not PIN_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK dev_res = [] lib_res = [] for slot_number in range(15): assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_totp_slot(slot_number, 'TOTP rw' + str(slot_number), secret, period, use_8_digits, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_totp_set_time(time) == DeviceErrorCode.STATUS_OK code_device = gs(C.NK_get_totp_code(slot_number, T, 0, period)) dev_res += (time, code_device) lib_res += (time, lib_at(time)) assert dev_res == lib_res @pytest.mark.otp @pytest.mark.parametrize("secret", [RFC_SECRET, 2*RFC_SECRET, '12'*10, '12'*30] ) def test_TOTP_secrets(C, secret): ''' NK Pro 0.8+, NK Storage 0.44+ ''' skip_if_device_version_lower_than({'S': 44, 'P': 8}) if len(secret)>20*2: #*2 since secret is in hex # pytest.skip("Secret lengths over 20 bytes are not supported by NK Pro 0.7 and NK Storage") skip_if_device_version_lower_than({'P': 8}) slot_number = 0 time = 0 period = 30 oath = pytest.importorskip("oath") lib_at = lambda t: oath.totp(secret, t=t, period=period) PIN_protection = False use_8_digits = False T = 0 assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, PIN_protection, not PIN_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK dev_res = [] lib_res = [] assert C.NK_write_totp_slot(slot_number, 'secret' + str(len(secret)), secret, period, use_8_digits, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_totp_set_time(time) == DeviceErrorCode.STATUS_OK code_device = gs(C.NK_get_totp_code(slot_number, T, 0, period)) dev_res += (time, code_device) lib_res += (time, lib_at(time)) assert dev_res == lib_res @pytest.mark.otp @pytest.mark.parametrize("secret", [RFC_SECRET, 2*RFC_SECRET, '12'*10, '12'*30] ) def test_HOTP_secrets(C, secret): """ NK Pro 0.8+ feature needed: support for 320bit secrets """ if len(secret)>40: skip_if_device_version_lower_than({'P': 8}) slot_number = 0 counter = 0 oath = pytest.importorskip("oath") lib_at = lambda t: oath.hotp(secret, counter=t) PIN_protection = False use_8_digits = False T = 0 assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, PIN_protection, not PIN_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK dev_res = [] lib_res = [] # repeat authentication for Pro 0.7 assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_hotp_slot(slot_number, 'secret' + str(len(secret)), secret, counter, use_8_digits, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK code_device = gs(C.NK_get_hotp_code(slot_number)) dev_res += (counter, code_device) lib_res += (counter, lib_at(counter)) assert dev_res == lib_res def test_special_double_press(C): """ requires manual check after function run double press each of num-, scroll-, caps-lock and check inserted OTP codes (each 1st should be 755224) on nkpro 0.7 scrolllock should do nothing, on nkpro 0.8+ should return OTP code """ secret = RFC_SECRET counter = 0 PIN_protection = False use_8_digits = False assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(0, 1, 2, PIN_protection, not PIN_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK for slot_number in range(3): assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_hotp_slot(slot_number, 'double' + str(slot_number), secret, counter, use_8_digits, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK # requires manual check @pytest.mark.otp def test_edit_OTP_slot(C): """ should change slots counter and name without changing its secret (using null secret for second update) """ # counter is not getting updated under Storage v0.43 - #TOREPORT skip_if_device_version_lower_than({'S': 44, 'P': 7}) secret = RFC_SECRET counter = 0 PIN_protection = False use_8_digits = False assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, PIN_protection, not PIN_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK slot_number = 0 assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK first_name = 'edit slot' assert C.NK_write_hotp_slot(slot_number, first_name, secret, counter, use_8_digits, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert gs(C.NK_get_hotp_slot_name(slot_number)) == first_name first_code = gs(C.NK_get_hotp_code(slot_number)) changed_name = 'changedname' empty_secret = '' assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_hotp_slot(slot_number, changed_name, empty_secret, counter, use_8_digits, False, False, "", DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK second_code = gs(C.NK_get_hotp_code(slot_number)) assert first_code == second_code assert gs(C.NK_get_hotp_slot_name(slot_number)) == changed_name @pytest.mark.otp @pytest.mark.skip @pytest.mark.parametrize("secret", ['31323334353637383930'*2,'31323334353637383930'*4] ) def test_TOTP_codes_from_nitrokeyapp(secret, C): """ Helper test for manual TOTP check of written secret by Nitrokey App Destined to run by hand """ slot_number = 0 PIN_protection = False period = 30 assert C.NK_first_authenticate(DefaultPasswords.ADMIN, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK assert C.NK_write_config(255, 255, 255, PIN_protection, not PIN_protection, DefaultPasswords.ADMIN_TEMP) == DeviceErrorCode.STATUS_OK code_device = gs(C.NK_get_totp_code(slot_number, 0, 0, period)) oath = pytest.importorskip("oath") lib_at = lambda : oath.totp(secret, period=period) print (lib_at()) assert lib_at() == code_device