Example #1
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    def test_pretty_hex_str_items_value_hi(self):
        """Check that the utils.pretty_hex_str() function fails when the
        "byte_seq" items's value is wrong (too high)."""

        byte_seq = (0xffff, 0, 10)  # the first item is too high
        with self.assertRaises(ValueError):
            utils.pretty_hex_str(byte_seq)
Example #2
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    def test_pretty_hex_str_items_value_hi(self):
        """Check that the utils.pretty_hex_str() function fails when the
        "byte_seq" items's value is wrong (too high)."""

        byte_seq = (0xffff, 0, 10)    # the first item is too high
        with self.assertRaises(ValueError):
            utils.pretty_hex_str(byte_seq)
Example #3
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    def test_pretty_hex_str_wrong_arg_type(self):
        """Check that the utils.pretty_hex_str() function fails when the
        "byte_seq" argument's type is wrong (int)."""

        with self.assertRaises(TypeError):
            utils.pretty_hex_str(1.0)

        with self.assertRaises(TypeError):
            utils.pretty_hex_str("hello")
Example #4
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    def test_pretty_hex_str_wrong_arg_type(self):
        """Check that the utils.pretty_hex_str() function fails when the
        "byte_seq" argument's type is wrong (int)."""

        with self.assertRaises(TypeError):
            utils.pretty_hex_str(1.0)

        with self.assertRaises(TypeError):
            utils.pretty_hex_str("hello")
Example #5
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    def test_pretty_hex_str_2(self):
        """Check the returned value of utils.pretty_hex_str()."""

        byte_seq = (0xff,) * 10
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff," * 9 + "ff"

        self.assertEqual(hex_str, expected_str)
Example #6
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    def test_pretty_hex_str_2(self):
        """Check the returned value of utils.pretty_hex_str()."""

        byte_seq = (0xff, ) * 10
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff," * 9 + "ff"

        self.assertEqual(hex_str, expected_str)
Example #7
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    def test_pretty_hex_str_good_arg_type(self):
        """Check the returned value of utils.pretty_hex_str() when various
        correct arguments are given."""

        # Test with a tuple of bytes
        byte_seq = (0xff, 0x00, 0x0a)
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff,00,0a"

        self.assertEqual(hex_str, expected_str)

        # Test with a list of bytes
        byte_seq = [0xff, 0x00, 0x0a]
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff,00,0a"

        self.assertEqual(hex_str, expected_str)

        # Test with a bytes string
        byte_seq = bytes((0xff, 0x00, 0x0a))
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff,00,0a"

        self.assertEqual(hex_str, expected_str)

        # Test with a bytearray
        byte_seq = bytearray((0xff, 0x00, 0x0a))
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff,00,0a"

        self.assertEqual(hex_str, expected_str)

        # Test with an integer
        byte_seq = 0xff
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff"

        self.assertEqual(hex_str, expected_str)
Example #8
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    def test_pretty_hex_str_good_arg_type(self):
        """Check the returned value of utils.pretty_hex_str() when various
        correct arguments are given."""

        # Test with a tuple of bytes
        byte_seq = (0xff, 0x00, 0x0a)
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff,00,0a"

        self.assertEqual(hex_str, expected_str)

        # Test with a list of bytes
        byte_seq = [0xff, 0x00, 0x0a]
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff,00,0a"

        self.assertEqual(hex_str, expected_str)

        # Test with a bytes string
        byte_seq = bytes((0xff, 0x00, 0x0a))
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff,00,0a"

        self.assertEqual(hex_str, expected_str)

        # Test with a bytearray
        byte_seq = bytearray((0xff, 0x00, 0x0a))
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff,00,0a"

        self.assertEqual(hex_str, expected_str)

        # Test with an integer
        byte_seq = 0xff
        hex_str = utils.pretty_hex_str(byte_seq)
        expected_str = "ff"

        self.assertEqual(hex_str, expected_str)
Example #9
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    def test_pretty_hex_str_items_type(self):
        """Check that the utils.pretty_hex_str() function fails when the
        "byte_seq" items have wrong type."""

        byte_seq = (1.0, 0, 10)       # wrong type (float)
        with self.assertRaises(TypeError):
            utils.pretty_hex_str(byte_seq)

        byte_seq = ("hello", 0, 10)   # wrong type (str)
        with self.assertRaises(TypeError):
            utils.pretty_hex_str(byte_seq)

        byte_seq = ((1, ), 0, 10)     # wrong type (tuple)
        with self.assertRaises(TypeError):
            utils.pretty_hex_str(byte_seq)
Example #10
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    def test_pretty_hex_str_items_type(self):
        """Check that the utils.pretty_hex_str() function fails when the
        "byte_seq" items have wrong type."""

        byte_seq = (1.0, 0, 10)  # wrong type (float)
        with self.assertRaises(TypeError):
            utils.pretty_hex_str(byte_seq)

        byte_seq = ("hello", 0, 10)  # wrong type (str)
        with self.assertRaises(TypeError):
            utils.pretty_hex_str(byte_seq)

        byte_seq = ((1, ), 0, 10)  # wrong type (tuple)
        with self.assertRaises(TypeError):
            utils.pretty_hex_str(byte_seq)
    def __init__(self, dynamixel_id, instruction, parameters=None):

        # Check the parameters byte.
        # "TypeError" and "ValueError" are raised by the "bytes" constructor if
        # necessary.
        # The statement "tuple(parameters)" implicitely rejects integers (and
        # all non-iterable objects) to compensate the fact that the bytes
        # constructor doesn't reject them: bytes(3) is valid and returns
        # b'\x00\x00\x00'.
        if parameters is None:
            parameters = bytes()
        else:
            parameters = bytes(tuple(parameters))

        # Add the header bytes.
        self._bytes = bytearray((0xff, 0xff))

        # Check and add the Dynamixel ID byte.
        # "TypeError" and "ValueError" are raised by the "bytearray.append()"
        # if necessary.
        if 0x00 <= dynamixel_id <= 0xfe:
            self._bytes.append(dynamixel_id)
        else:
            if isinstance(dynamixel_id, int):
                msg = ("Wrong dynamixel_id value, "
                       "an integer in range(0x00, 0xfe) is required.")
                raise ValueError(msg)
            else:
                raise TypeError("Wrong dynamixel_id type (integer required).")

        # Add the length byte.
        self._bytes.append(len(parameters) + 2)

        # Check and add the instruction byte.
        # "TypeError" and "ValueError" are raised by the "bytearray.append()"
        # if necessary.
        if instruction in INSTRUCTIONS:
            self._bytes.append(instruction)
        else:
            if isinstance(instruction, int):
                msg = "Wrong instruction, should be in ({})."
                instructions_str = utils.pretty_hex_str(INSTRUCTIONS)
                raise ValueError(msg.format(instructions_str))
            else:
                raise TypeError("Wrong instruction type (integer required).")

        # Check and add the parameter bytes.
        nb_param_min = NUMBER_OF_PARAMETERS[self.instruction]['min']
        nb_param_max = NUMBER_OF_PARAMETERS[self.instruction]['max']

        if nb_param_min <= len(parameters) <= nb_param_max:
            self._bytes.extend(parameters)
        else:
            msg = ("Wrong number of parameters: {} parameters "
                   "(min expected={}; max expected={}).")
            nb_param = len(parameters)
            raise ValueError(msg.format(nb_param, nb_param_min, nb_param_max))

        # Add the checksum byte.
        computed_checksum = pk.compute_checksum(self._bytes[2:])
        self._bytes.append(computed_checksum)
Example #12
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    def __init__(self, dynamixel_id, instruction, parameters=None):

        # Check the parameters byte.
        # "TypeError" and "ValueError" are raised by the "bytes" constructor if
        # necessary.
        # The statement "tuple(parameters)" implicitely rejects integers (and
        # all non-iterable objects) to compensate the fact that the bytes
        # constructor doesn't reject them: bytes(3) is valid and returns
        # b'\x00\x00\x00'.
        if parameters is None:
            parameters = bytes()
        else:
            parameters = bytes(tuple(parameters))

        # Add the header bytes.
        self._bytes = bytearray((0xff, 0xff))

        # Check and add the Dynamixel ID byte.
        # "TypeError" and "ValueError" are raised by the "bytearray.append()"
        # if necessary.
        if 0x00 <= dynamixel_id <= 0xfe:
            self._bytes.append(dynamixel_id)
        else:
            if isinstance(dynamixel_id, int):
                msg = ("Wrong dynamixel_id value, "
                       "an integer in range(0x00, 0xfe) is required.")
                raise ValueError(msg)
            else:
                raise TypeError("Wrong dynamixel_id type (integer required).")

        # Add the length byte.
        self._bytes.append(len(parameters) + 2)

        # Check and add the instruction byte.
        # "TypeError" and "ValueError" are raised by the "bytearray.append()"
        # if necessary.
        if instruction in INSTRUCTIONS:
            self._bytes.append(instruction)
        else:
            if isinstance(instruction, int):
                msg = "Wrong instruction, should be in ({})."
                instructions_str = utils.pretty_hex_str(INSTRUCTIONS)
                raise ValueError(msg.format(instructions_str))
            else:
                raise TypeError("Wrong instruction type (integer required).")

        # Check and add the parameter bytes.
        nb_param_min = NUMBER_OF_PARAMETERS[self.instruction]['min']
        nb_param_max = NUMBER_OF_PARAMETERS[self.instruction]['max']

        if nb_param_min <= len(parameters) <= nb_param_max:
            self._bytes.extend(parameters)
        else:
            msg = ("Wrong number of parameters: {} parameters "
                   "(min expected={}; max expected={}).")
            nb_param = len(parameters)
            raise ValueError(msg.format(nb_param, nb_param_min, nb_param_max))

        # Add the checksum byte.
        computed_checksum = pk.compute_checksum(self._bytes[2:])
        self._bytes.append(computed_checksum)