/libnitrokey

Communicate with Nitrokey devices in a clean and easy manner

Primary LanguageC++GNU Lesser General Public License v3.0LGPL-3.0

Build Status Waffle.io - Columns and their card count

libnitrokey

libnitrokey is a project to communicate with Nitrokey Pro and Storage devices in a clean and easy manner. Written in C++14, testable with py.test and Catch frameworks, with C API, Python access (through CFFI and C API, in future with Pybind11).

The development of this project is aimed to make it itself a living documentation of communication protocol between host and the Nitrokey stick devices. The command packets' format is described here: Pro v0.7, Pro v0.8, Storage. Handling and additional operations are described here: NitrokeyManager.cc.

A C++14 complying compiler is required due to heavy use of variable templates. For feature support tables please check table 1 or table 2.

libnitrokey is developed and tested with the latest compilers: g++ 6.2, clang 3.8. We use Travis CI to test builds also on g++ 5.4 and under OSX compilers starting up from xcode 8.2 environment.

Getting sources

This repository uses git submodules. To clone please use git's --recursive option like in:

git clone --recursive https://github.com/Nitrokey/libnitrokey.git

or for already cloned repository:

git clone https://github.com/Nitrokey/libnitrokey.git
cd libnitrokey
git submodule update --init --recursive

Dependencies

Following libraries are needed to use libnitrokey on Linux (names of the packages on Ubuntu):

Compilation

libnitrokey uses CMake as its main build system. As a secondary option it offers building through Qt's qMake.

Qt

A Qt's .pro project file is provided for direct compilation and for inclusion to other projects. Using it directly is not recommended due to lack of dependencies check and not implemented library versioning. Compilation is tested with Qt 5.6 and greater.

Quick start example:

mkdir -p build
cd build
qmake ..
make -j2

Windows and Visual Studio 2017

Lately Visual Studio has started handling CMake files directly. After opening the project's directory it should recognize it and initialize build system. Afterwards please run:

  1. CMake -> Cache -> View Cache CMakeLists.txt -> CMakeLists.txt to edit settings
  2. CMake -> Build All to build

It is possible too to use CMake GUI directly with its settings editor.

CMake

To compile please run following sequence of commands:

# assuming current dir is ./libnitrokey/
mkdir -p build
cd build
cmake .. <OPTIONS>
make -j2

By default (with empty <OPTIONS> string) this will create in build/ directory a shared library (.so, .dll or .dynlib). If you wish to build static version you can use as <OPTIONS> string -DBUILD_SHARED_LIBS=OFF.

All options could be listed with cmake .. -L or instead cmake a ccmake .. tool could be used for configuration (where .. is the path to directory with CMakeLists.txt file). ccmake shows also description of the build parameters.

If you have trouble compiling or running the library you can check .travis.yml file for configuration details. This file is used by Travis CI service to make test builds on OSX and Ubuntu 14.04.

Other build options (all take either ON or OFF):

  • ADD_ASAN - add tests for memory leaks and out-of-bounds access
  • ADD_TSAN - add tests for threads race, needs USE_CLANG
  • COMPILE_TESTS - compile C++ tests
  • COMPILE_OFFLINE_TESTS - compile C++ tests, that do not require any device to be connected
  • LOG_VOLATILE_DATA (default: OFF) - include secrets in log (PWS passwords, PINs etc)
  • NO_LOG (default: OFF) - do not compile LOG statements - will make library smaller, but without any diagnostic messages

Meson

It is possible to use Meson and Ninja to build the project as well (currently available only master branch). Please run:

meson builddir <OPTIONS>
meson configure builddir # to show available build flags
ninja -C builddir

Using libnitrokey with Python

To use libnitrokey with Python a CFFI library is required (either 2.7+ or 3.0+). It can be installed with:

pip install --user cffi # for python 2.x
pip3 install cffi # for python 3.x

Just import it, read the C API header and it is done! You have access to the library. Here is an example (in Python 2) printing HOTP code for Pro or Storage device, assuming it is run in root directory (full example):

#!/usr/bin/env python2
import cffi

ffi = cffi.FFI()
get_string = ffi.string

def get_library():
    fp = 'NK_C_API.h'  # path to C API header

    declarations = []
    with open(fp, 'r') as f:
        declarations = f.readlines()

    cnt = 0
    a = iter(declarations)
    for declaration in a:
        if declaration.strip().startswith('NK_C_API'):
            declaration = declaration.replace('NK_C_API', '').strip()
            while ';' not in declaration:
                declaration += (next(a)).strip()
            # print(declaration)
            ffi.cdef(declaration, override=True)
            cnt +=1
    print('Imported {} declarations'.format(cnt))


    C = None
    import os, sys
    path_build = os.path.join(".", "build")
    paths = [
            os.environ.get('LIBNK_PATH', None),
            os.path.join(path_build,"libnitrokey.so"),
            os.path.join(path_build,"libnitrokey.dylib"),
            os.path.join(path_build,"libnitrokey.dll"),
            os.path.join(path_build,"nitrokey.dll"),
    ]
    for p in paths:
        if not p: continue
        print("Trying " +p)
        p = os.path.abspath(p)
        if os.path.exists(p):
            print("Found: "+p)
            C = ffi.dlopen(p)
            break
        else:
            print("File does not exist: " + p)
    if not C:
        print("No library file found")
        sys.exit(1)

    return C


def get_hotp_code(lib, i):
    return lib.NK_get_hotp_code(i)


libnitrokey = get_library()
libnitrokey.NK_set_debug(False)  # do not show debug messages (log library only)

hotp_slot_code = get_hotp_code(libnitrokey, 1)
print('Getting HOTP code from Nitrokey device: ')
print(hotp_slot_code)
libnitrokey.NK_logout()  # disconnect device

In case no devices are connected, a friendly message will be printed. All available functions for C and Python are listed in NK_C_API.h. Please check Documentation section below.

Documentation

The documentation of C API is included in the sources (can be generated with make doc if Doxygen is installed). Please check NK_C_API.h (C API) for high level commands and libnitrokey/NitrokeyManager.h (C++ API). All devices' commands are listed along with packet format in libnitrokey/stick10_commands.h and libnitrokey/stick20_commands.h respectively for Nitrokey Pro and Nitrokey Storage products.

Tests

Warning! Most of the tests will overwrite user data. The only user-data safe tests are specified in unittest/test_safe.cpp (see C++ tests chapter).

Warning! Before you run unittests please change both your Admin and User PINs on your Nitrostick to defaults (12345678 and 123456 respectively), or change the values in tests source code. If you do not change them, the tests might lock your device temporarily. If it's too late already, you can reset your Nitrokey using instructions from homepage.

Python tests

libnitrokey has a great suite of tests written in Python 3 under the path: unittest/test_*.py:

  • test_pro.py - contains tests of OTP, Password Safe and PIN control functionality. Could be run on both Pro and Storage devices.
  • test_storage.py - contains tests of Encrypted Volumes functionality. Could be run only on Storage.

The tests themselves show how to handle common requests to device. Before running please install all required libraries with:

cd unittest
pip install --user -r requirements.txt

or use Python's environment managing tool like pipenv or virtualenv.

To run them please execute:

# substitute <dev> with either 'pro' or 'storage'
py.test -v test_<dev>.py
# more specific use - run tests containing in name <test_name> 5 times:
py.test -v test_<dev>.py -k <test_name> --count 5

For additional documentation please check the following for py.test installation. For better coverage randomly plugin is installed - it randomizes the test order allowing to detect unseen dependencies between the tests.

C++ tests

There are also some unit tests implemented in C++, placed in unittest directory. The only user-data safe online test set here is test_safe.cpp, which tries to connect to the device, and collect its status data. Example run for Storage:

# Storage device inserted, firmware version v0.53
$ ./test_safe
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    => GET_DEVICE_STATUS
..
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    <= GET_DEVICE_STATUS 0 1
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    => GET_PASSWORD_RETRY_COUNT
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    <= GET_PASSWORD_RETRY_COUNT 0 0
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    => GET_DEVICE_STATUS
..
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    <= GET_DEVICE_STATUS 0 1
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    => GET_USER_PASSWORD_RETRY_COUNT
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    <= GET_USER_PASSWORD_RETRY_COUNT 0 0
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    => GET_DEVICE_STATUS
...
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    <= GET_DEVICE_STATUS 0 1
 transmission_data.dissect():   _padding:
0000    00 00 00 00 00 00 00 00 00 00 00 00 00 05 2e 01   ................
0010    00 00 -- -- -- -- -- -- -- -- -- -- -- -- -- --   ..
 (int) SendCounter_u8:  0
 (int) SendDataType_u8: 3
 (int) FollowBytesFlag_u8:      0
 (int) SendSize_u8:     28

 MagicNumber_StickConfig_u16:   13080
 (int) ReadWriteFlagUncryptedVolume_u8: 1
 (int) ReadWriteFlagCryptedVolume_u8:   0
 (int) ReadWriteFlagHiddenVolume_u8:    0
 (int) versionInfo.major:       0
 (int) versionInfo.minor:       53
 (int) versionInfo.build_iteration:     0
 (int) FirmwareLocked_u8:       0
 (int) NewSDCardFound_u8:       1
 (int) NewSDCardFound_st.NewCard:       1
 (int) NewSDCardFound_st.Counter:       0
 (int) SDFillWithRandomChars_u8:        1
 ActiveSD_CardID_u32:   3670817656
 (int) VolumeActiceFlag_u8:     1
 (int) VolumeActiceFlag_st.unencrypted: 1
 (int) VolumeActiceFlag_st.encrypted:   0
 (int) VolumeActiceFlag_st.hidden:      0
 (int) NewSmartCardFound_u8:    0
 (int) UserPwRetryCount:        3
 (int) AdminPwRetryCount:       3
 ActiveSmartCardID_u32: 24122
 (int) StickKeysNotInitiated:   0

[Wed Jan  2 13:31:17 2019][DEBUG_L1]    => GET_DEVICE_STATUS
..
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    <= GET_DEVICE_STATUS 0 1
00005e3a
[Wed Jan  2 13:31:17 2019][DEBUG_L1]    => GET_DEVICE_STATUS
....
[Wed Jan  2 13:31:18 2019][DEBUG_L1]    <= GET_DEVICE_STATUS 0 1
[Wed Jan  2 13:31:18 2019][DEBUG_L1]    => GET_DEVICE_STATUS
...
[Wed Jan  2 13:31:18 2019][DEBUG_L1]    <= GET_DEVICE_STATUS 0 1
===============================================================================
All tests passed (18 assertions in 6 test cases)

Test's execution configuration and verbosity could be manipulated - please see ./test_safe --help for details.

The other tests sets are not written as extensively as Python tests and are rather more a C++ low level interface check used during the library development, using either low-level components, C API from NK_C_API.cc, or C++ API from NitrokeyManager.cc. Some of them are: test_HOTP.cc, test1.cc. See more in unittest directory.

Note: these are not device model agnostic, and will most probably destroy your data on the device.

Unit tests were checked on Ubuntu 16.04/16.10/17.04. To run them just execute binaries built in ./libnitrokey/build dir, after enabling them by passing -DCOMPILE_TESTS=ON option to cmake - e.g.: cmake .. -DCOMPILE_TESTS=ON && make.

The documentation of how it works could be found in nitrokey-app project's README on Github: Nitrokey-app - internals.

To peek/debug communication with device running nitrokey-app (0.x branch) in debug mode (-d switch) and checking the logs (right click on tray icon and then 'Debug') might be helpful. Latest Nitrokey App (1.x branch) uses libnitrokey to communicate with device. Once run with --dl 3 (3 or higher; range 0-5) it will print all communication to the console. Additionally crosschecking with firmware code should show how things works: report_protocol.c (for Nitrokey Pro, for Storage similarly).

Known issues / tasks

  • Currently only one device can be connected at a time (experimental work could be found in wip-multiple_devices branch),
  • C++ API needs some reorganization to C++ objects (instead of pointers to byte arrays). This will be also preparing for integration with Pybind11,
  • Fix compilation warnings.

Other tasks might be listed either in TODO file or on project's issues page.

License

This project is licensed under LGPL version 3. License text could be found under LICENSE file.

Roadmap

To check what issues will be fixed and when please check milestones page.