コード例 #1
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 def test_back_90(self):
     # Create the cube.
     cube = Cube(cube_input=self.cube_input, cube_side_length=2)
     cube.shift(Key(move=CubeMove.back.value, angle=90, index=1))
     assert cube.content == \
         "890767859012345678901234567890123456456312340129" \
         "123456784563234185670789290141236785789023415678"
コード例 #2
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 def test_down_90(self):
     # Create the cube.
     cube = Cube(cube_input=self.cube_input, cube_side_length=2)
     cube.shift(Key(move=CubeMove.down.value, angle=90, index=1))
     assert cube.content == \
         "123456789012345678901234123456783456789056789012" \
         "290141236345856778901234123456783456789056789012"
コード例 #3
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 def test_left_90(self):
     # Create the cube.
     cube = Cube(cube_input=self.cube_input, cube_side_length=2)
     cube.shift(Key(move=CubeMove.left.value, angle=90, index=1))
     assert cube.content == \
         "129056783412345612341234901290123456789012345678" \
         "789056785678345678901290567834124123634585670789"
コード例 #4
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 def test_front_90(self):
     # Create the cube.
     cube = Cube(cube_input=self.cube_input, cube_side_length=2)
     cube.shift(Key(move=CubeMove.front.value, angle=90, index=1))
     assert cube.content == \
         "123456788567078985670789290141232901789063455678" \
         "412363459012345678901234567890123456412312348567"
コード例 #5
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 def test_special(self):
     # Create the cube.
     cube = Cube(cube_input=self.cube_input, cube_side_length=2)
     try:
         cube.shift(Key(move="abracadabra", angle=90, index=0))
         raise AssertionError("Error message did not raise.")
     except ValueError as error:
         assert str(error) == WRONG_CUBE_MOVE
コード例 #6
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 def test_location_null(self):
     # Create the cube without location tracker.
     cube = Cube(cube_input=self.cube_input, cube_side_length=2)
     try:
         cube.get_tracked_location()
         raise AssertionError("Error message did not raise.")
     except ValueError as error:
         assert str(error) == "No Tracked Location"
コード例 #7
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    def _get_location_after_key(key: Key, cube: Cube) -> int:
        """Perform a move on the cube and find the tracked bit.

        :param key: Indicate the movement on the cube.
        :param cube: The cube object.
        :return: The new location of the tracked bit.
        """
        cube.shift(key=key)
        cube.shift_cubie_content()
        return cube.get_tracked_location()
コード例 #8
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    def _check_effective_key(self, key: Key) -> bool:
        """Check if the given key moves the tracked item.

        :param key: The possible key that moves the location.
        :return: If the key actually moves the item. (Not Equal = True)
        """
        # Make a new copy of the cube.
        temp_cube = Cube(cube_input="_" * self._cube_size,
                         cube_side_length=self._side_length,
                         track_location=self._track_item_location)
        # Perform the desired shift.
        temp_cube.shift(key=key)
        # Return True if the location is changed.
        return temp_cube.get_tracked_location() != self._track_item_location
コード例 #9
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 def test_down_shift(self):
     # This is the case where the down face rotate. (4 by 4 by 4 cube)
     cube = Cube(cube_input=self.cube_input, cube_side_length=4)
     cube._shift_d(index=2)
     assert cube.content == "10101010101010101010101010101010" \
                            "10101010101010101010101010101010" \
                            "20202020202020202020202020202020" \
                            "20202020202020206060606060606060" \
                            "30303030303030303030303030303030" \
                            "30303030303030302020202020202020" \
                            "04040404040404040404040404040404" \
                            "04040404040404040404040404040404" \
                            "50505050505050505050505050505050" \
                            "50505050505050503030303030303030" \
                            "60606060606060606060606060606060" \
                            "60606060606060605050505050505050"
コード例 #10
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 def test_left_shift(self):
     # This is the case where the left face rotate. (4 by 4 by 4 cube)
     cube = Cube(cube_input=self.cube_input, cube_side_length=4)
     cube._shift_l(index=2)
     assert cube.content == "50501010101010105050101010101010" \
                            "50501010101010105050101010101010" \
                            "10102020202020201010202020202020" \
                            "10102020202020201010202020202020" \
                            "30303030303030303030303030303030" \
                            "30303030303030303030303030303030" \
                            "20204040404040402020404040404040" \
                            "20204040404040402020404040404040" \
                            "50505050505040405050505050504040" \
                            "50505050505040405050505050504040" \
                            "06060606060606060606060606060606" \
                            "06060606060606060606060606060606"
コード例 #11
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 def test_middle_shift(self):
     # This is the case where the back face rotate. (4 by 4 by 4 cube)
     cube = Cube(cube_input=self.cube_input, cube_side_length=4)
     cube._shift_r(index=1)
     assert cube.content == "10101010202010101010101020201010" \
                            "10101010202010101010101020201010" \
                            "20202020404020202020202040402020" \
                            "20202020404020202020202040402020" \
                            "30303030303030303030303030303030" \
                            "30303030303030303030303030303030" \
                            "40404040505040404040404050504040" \
                            "40404040505040404040404050504040" \
                            "50501010505050505050101050505050" \
                            "50501010505050505050101050505050" \
                            "60606060606060606060606060606060" \
                            "60606060606060606060606060606060"
コード例 #12
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 def test_back_shift(self):
     # This is the case where the back face rotate. (4 by 4 by 4 cube)
     cube = Cube(cube_input=self.cube_input, cube_side_length=4)
     cube._shift_b(index=2)
     assert cube.content == "03030303030303031010101010101010" \
                            "10101010101010101010101010101010" \
                            "20202020202020202020202020202020" \
                            "20202020202020202020202020202020" \
                            "30303030303004043030303030300404" \
                            "30303030303004043030303030300404" \
                            "40404040404040404040404040404040" \
                            "40404040404040400606060606060606" \
                            "05050505050505050505050505050505" \
                            "05050505050505050505050505050505" \
                            "01016060606060600101606060606060" \
                            "01016060606060600101606060606060"
コード例 #13
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 def test_front_shift(self):
     # This is the case where the front face rotate. (4 by 4 by 4 cube)
     cube = Cube(cube_input=self.cube_input, cube_side_length=4)
     cube._shift_f(index=2)
     assert cube.content == "10101010101010101010101010101010" \
                            "10101010101010100606060606060606" \
                            "02020202020202020202020202020202" \
                            "02020202020202020202020202020202" \
                            "01013030303030300101303030303030" \
                            "01013030303030300101303030303030" \
                            "03030303030303034040404040404040" \
                            "40404040404040404040404040404040" \
                            "50505050505050505050505050505050" \
                            "50505050505050505050505050505050" \
                            "60606060606004046060606060600404" \
                            "60606060606004046060606060600404"
コード例 #14
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    def location_tracker(self, keys: List[Key]) -> List[int]:
        """Track position of a specific bit when moves are performed.

        :param keys: A list of cube movements.
        :return: A list of integers which each represent a location.
        """
        cube = Cube(cube_input="_" * self._cube_size,
                    cube_side_length=self._side_length,
                    track_location=self._track_item_location)

        return [self._track_item_location] + [
            self._get_location_after_key(key=key, cube=cube) for key in keys
        ]
コード例 #15
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    def _get_location(self, key: Key) -> int:
        """Get location of the tracked item after performing a effective key.

        :param key: One known effective effective key.
        :return: New location of the tracked item.
        """
        # Make a new copy of the cube.
        temp_cube = Cube(cube_input="_" * self._cube_size,
                         cube_side_length=self._side_length,
                         track_location=self._track_item_location)
        # Perform the desired shift and shift the content.
        temp_cube.shift(key=key)
        temp_cube.shift_cubie_content()

        # Return the new location of the tracked item.
        return temp_cube.get_tracked_location()
コード例 #16
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    def __init__(self, message: str, cube_side_length: int):
        """Put the message into a cube and create a queue to hold keys.

        :param message: The message to encrypt.
        :param cube_side_length: The desired length of cube side.
        """
        # Store the important information for other method to access.
        self._message = message
        self._max_index = math.floor(cube_side_length / 2)
        self._random_size = cube_side_length**2 * CUBIE_LENGTH
        self._message_size = cube_side_length**2 * 5 * CUBIE_LENGTH

        # Get the cubes.
        self._cubes = [
            Cube(cube_input=input_str, cube_side_length=cube_side_length)
            for input_str in self._get_binary_to_encrypt
        ]

        # Set up the holder for the key.
        self._key = deque()
コード例 #17
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def analyze_bit(key: List[Key], side_length: int, random_bits: str,
                message_bits: str):
    """Given input and key, count how the number of bits changes afterward.

    :param message_bits: Bits for the actual message.
    :param random_bits: Bits for the randomness.
    :param key: The desired key to use.
    :param side_length: Desired length of the Rubik's Cube.
    :return: Number of zeros and number of ones in the encrypted result.
    """
    # Concatenate the input to get cube input.
    cube_input = message_bits + random_bits
    # Initialize the cube.
    cube = Cube(cube_input=cube_input, cube_side_length=side_length)

    # Xor, Shift, and apply move onto the cube.
    for each_key in key:
        cube.xor()
        cube.shift_cubie_content()
        cube.shift(key=each_key)

    # Count number of zeros and number of ones.
    return {"0": cube.content.count("0"), "1": cube.content.count("1")}
コード例 #18
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 def test_xor(self):
     # Set the cube to be half 1 and half 0.
     cube = Cube(cube_input="0" * 180 + "1" * 36, cube_side_length=3)
     # Xor the cube and test result.
     cube.xor()
     assert cube.content == "1" * 216
コード例 #19
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class TestCubeOperations:
    # Setup testing inputs.
    cube_input = \
        "1010101010101010101010101010101010101010101010101010101010101010" \
        "2020202020202020202020202020202020202020202020202020202020202020" \
        "3030303030303030303030303030303030303030303030303030303030303030" \
        "4040404040404040404040404040404040404040404040404040404040404040" \
        "5050505050505050505050505050505050505050505050505050505050505050" \
        "6060606060606060606060606060606060606060606060606060606060606060"

    # Create the cube.
    cube = Cube(cube_input=copy.deepcopy(cube_input),
                cube_side_length=4,
                track_location=10)

    def test_cube_content(self):
        assert self.cube.content == self.cube_input

    def test_cube_location_tracker(self):
        assert self.cube.get_tracked_location() == 10

    def test_cube_shift_cubie_content(self):
        self.cube.shift_cubie_content()
        assert self.cube.content == f"{self.cube_input[-1]}" \
            f"{self.cube_input[: -1]}"

    def test_cube_shift_cubie_content_back(self):
        self.cube.shift_cubie_content_back()
        assert self.cube.content == self.cube_input

    def test_top_shift(self):
        # This is the case where the top face rotate. (4 by 4 by 4 cube)
        cube = Cube(cube_input=self.cube_input, cube_side_length=4)
        cube._shift_t(index=2)
        assert cube.content == "01010101010101010101010101010101" \
                               "01010101010101010101010101010101" \
                               "30303030303030302020202020202020" \
                               "20202020202020202020202020202020" \
                               "50505050505050503030303030303030" \
                               "30303030303030303030303030303030" \
                               "40404040404040404040404040404040" \
                               "40404040404040404040404040404040" \
                               "60606060606060605050505050505050" \
                               "50505050505050505050505050505050" \
                               "20202020202020206060606060606060" \
                               "60606060606060606060606060606060"

    def test_down_shift(self):
        # This is the case where the down face rotate. (4 by 4 by 4 cube)
        cube = Cube(cube_input=self.cube_input, cube_side_length=4)
        cube._shift_d(index=2)
        assert cube.content == "10101010101010101010101010101010" \
                               "10101010101010101010101010101010" \
                               "20202020202020202020202020202020" \
                               "20202020202020206060606060606060" \
                               "30303030303030303030303030303030" \
                               "30303030303030302020202020202020" \
                               "04040404040404040404040404040404" \
                               "04040404040404040404040404040404" \
                               "50505050505050505050505050505050" \
                               "50505050505050503030303030303030" \
                               "60606060606060606060606060606060" \
                               "60606060606060605050505050505050"

    def test_right_shift(self):
        # This is the case where the right face rotate. (4 by 4 by 4 cube)
        cube = Cube(cube_input=self.cube_input, cube_side_length=4)
        cube._shift_r(index=2)
        assert cube.content == "10101010101020201010101010102020" \
                               "10101010101020201010101010102020" \
                               "20202020202040402020202020204040" \
                               "20202020202040402020202020204040" \
                               "03030303030303030303030303030303" \
                               "03030303030303030303030303030303" \
                               "40404040404050504040404040405050" \
                               "40404040404050504040404040405050" \
                               "10105050505050501010505050505050" \
                               "10105050505050501010505050505050" \
                               "60606060606060606060606060606060" \
                               "60606060606060606060606060606060"

    def test_left_shift(self):
        # This is the case where the left face rotate. (4 by 4 by 4 cube)
        cube = Cube(cube_input=self.cube_input, cube_side_length=4)
        cube._shift_l(index=2)
        assert cube.content == "50501010101010105050101010101010" \
                               "50501010101010105050101010101010" \
                               "10102020202020201010202020202020" \
                               "10102020202020201010202020202020" \
                               "30303030303030303030303030303030" \
                               "30303030303030303030303030303030" \
                               "20204040404040402020404040404040" \
                               "20204040404040402020404040404040" \
                               "50505050505040405050505050504040" \
                               "50505050505040405050505050504040" \
                               "06060606060606060606060606060606" \
                               "06060606060606060606060606060606"

    def test_front_shift(self):
        # This is the case where the front face rotate. (4 by 4 by 4 cube)
        cube = Cube(cube_input=self.cube_input, cube_side_length=4)
        cube._shift_f(index=2)
        assert cube.content == "10101010101010101010101010101010" \
                               "10101010101010100606060606060606" \
                               "02020202020202020202020202020202" \
                               "02020202020202020202020202020202" \
                               "01013030303030300101303030303030" \
                               "01013030303030300101303030303030" \
                               "03030303030303034040404040404040" \
                               "40404040404040404040404040404040" \
                               "50505050505050505050505050505050" \
                               "50505050505050505050505050505050" \
                               "60606060606004046060606060600404" \
                               "60606060606004046060606060600404"

    def test_back_shift(self):
        # This is the case where the back face rotate. (4 by 4 by 4 cube)
        cube = Cube(cube_input=self.cube_input, cube_side_length=4)
        cube._shift_b(index=2)
        assert cube.content == "03030303030303031010101010101010" \
                               "10101010101010101010101010101010" \
                               "20202020202020202020202020202020" \
                               "20202020202020202020202020202020" \
                               "30303030303004043030303030300404" \
                               "30303030303004043030303030300404" \
                               "40404040404040404040404040404040" \
                               "40404040404040400606060606060606" \
                               "05050505050505050505050505050505" \
                               "05050505050505050505050505050505" \
                               "01016060606060600101606060606060" \
                               "01016060606060600101606060606060"

    def test_middle_shift(self):
        # This is the case where the back face rotate. (4 by 4 by 4 cube)
        cube = Cube(cube_input=self.cube_input, cube_side_length=4)
        cube._shift_r(index=1)
        assert cube.content == "10101010202010101010101020201010" \
                               "10101010202010101010101020201010" \
                               "20202020404020202020202040402020" \
                               "20202020404020202020202040402020" \
                               "30303030303030303030303030303030" \
                               "30303030303030303030303030303030" \
                               "40404040505040404040404050504040" \
                               "40404040505040404040404050504040" \
                               "50501010505050505050101050505050" \
                               "50501010505050505050101050505050" \
                               "60606060606060606060606060606060" \
                               "60606060606060606060606060606060"

    def test_xor(self):
        # Set the cube to be half 1 and half 0.
        cube = Cube(cube_input="0" * 180 + "1" * 36, cube_side_length=3)
        # Xor the cube and test result.
        cube.xor()
        assert cube.content == "1" * 216
コード例 #20
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 def test_content_message(self):
     cube = Cube(cube_input=self.cube_input, cube_side_length=2)
     assert cube.message_content == \
         self.cube_input[:int(len(self.cube_input) * 5 / 6)]
コード例 #21
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 def test_wrong_cube_side_length(self):
     try:
         Cube(cube_input="1" * 24, cube_side_length=1)
         raise AssertionError("Error message did not raise.")
     except AssertionError as error:
         assert str(error) == WRONG_CUBE_SIDE_LENGTH
コード例 #22
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 def test_wrong_input_length(self):
     try:
         Cube(cube_input="abracadabra", cube_side_length=100)
         raise AssertionError("Error message did not raise.")
     except AssertionError as error:
         assert str(error) == WRONG_CUBE_INPUT
コード例 #23
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 def test_random_message(self):
     cube = Cube(cube_input=self.cube_input, cube_side_length=2)
     assert cube.random_content == \
         self.cube_input[int(len(self.cube_input) * 5 / 6):]