Exemplo n.º 1
0
 def make_encrypted(self, compress=False):
     data = np.arange(2**16, dtype=np.uint16).tobytes()
     fh = io.BytesIO(F1)
     fw = datafile.DataFileWriter(fh)
     signing_key_prv = bytes(range(32))
     encryption_key = bytes(range(1, 33))
     nonce = bytes(range(16, 16 + 24 * 2, 2))
     associated_data = bytes(range(2, 50, 2))
     fw.append_encrypted(b'RAW',
                         data,
                         signing_key_prv,
                         encryption_key,
                         nonce,
                         associated_data,
                         compress=compress)
     fw.finalize()
     fh.seek(0)
     fr = datafile.DataFileReader(fh)
     return fr, {
         'data':
         data,
         'signing_key_prv':
         signing_key_prv,
         'signing_key_pub':
         monocypher.compute_signing_public_key(signing_key_prv),
         'encryption_key':
         encryption_key,
         'nonce':
         nonce,
         'associated_data':
         associated_data,
         'fh':
         fh,
     }
Exemplo n.º 2
0
 def signature_start(self, private_key, flags=None):
     self._signature = {
         'flags': 0 if flags is None else int(flags),
         'key': private_key,
         'data': b'',
     }
     payload = bytearray(8)
     payload[0] = 1  # Ed25519 using Blake2b
     payload[1] = self._signature['flags']
     payload += monocypher.compute_signing_public_key(private_key)
     self.append(TAG_SIGNATURE_START, payload)
     if 0 == (self._signature['flags'] & SIGNATURE_FLAG_KEY_INCLUDE):
         self._signature['data'] = b''
Exemplo n.º 3
0
 def test_sign(self):
     random = np.random.RandomState(seed=1)
     for i in range(10):
         length = random.randint(1, 4096)
         secret_key = bytes(random.randint(0, 256, 32, dtype=np.uint8))
         msg = bytes(random.randint(0, 256, length, dtype=np.uint8))
         public_key = monocypher.compute_signing_public_key(secret_key)
         sig = monocypher.signature_sign(secret_key, msg)
         self.assertTrue(monocypher.signature_check(sig, public_key, msg))
         self.assertFalse(
             monocypher.signature_check(sig, public_key, msg + b'0'))
         sig2 = sig[:10] + bytes([sig[10] + 1]) + sig[11:]
         self.assertFalse(monocypher.signature_check(sig2, public_key, msg))
Exemplo n.º 4
0
CAL1_VG = [0.0009468113102263853, 0.00029342128123136175]
CAL1_IK = [
    -2806.717811538373, -2822.6645675137756, -2820.88100055503,
    -2822.6200621623125, -2820.462616626318, -2820.5826040862453,
    -2818.676888822763, 0.0,
    float('nan')
]
CAL1_1G = [
    0.0006828914450133605, 0.00016375303534373303, 1.4626174421742075e-05,
    1.4937616926812478e-06, 1.4970493483159016e-07, 1.498388811827842e-08,
    1.4984542304875239e-09, 0.0,
    float('nan')
]

PRIVATE_KEY = bytes(range(32))
PUBLIC_KEY = monocypher.compute_signing_public_key(PRIVATE_KEY)


class TestCalibrate(unittest.TestCase):
    def test_save_load_unsigned(self):
        c1 = Calibration()
        c1.current_offset = CAL1_IK[:7]
        c1.current_gain = CAL1_1G[:7]
        c1.voltage_offset = CAL1_VK
        c1.voltage_gain = CAL1_VG
        data = c1.save()
        c2 = Calibration().load(data, keys=[])
        self.assertFalse(c2.signed)
        np.testing.assert_allclose(CAL1_VK, c2.voltage_offset)
        np.testing.assert_allclose(CAL1_VG, c2.voltage_gain)
        np.testing.assert_allclose(CAL1_IK, c2.current_offset)