예제 #1
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def _header_chunk(header: None, data: bytes, data_out: Dict[str, Any]):
    """
    Represents .ani's header chunk, which has an identifier of "anih".
    """
    if (header is not None):
        raise SyntaxError("This ani has 2 headers!")

    if (len(data) == 36):
        data = data[4:]

    h_data = {
        "num_frames": to_int(data[0:4]),
        "num_steps": to_int(data[4:8]),
        "width": to_int(data[8:12]),
        "height": to_int(data[12:16]),
        "bit_count": to_int(data[16:20]),
        "num_planes": 1,
        "display_rate": to_int(data[24:28]),
        "contains_seq": bool((to_int(data[28:32]) >> 1) & 1),
        "is_in_ico": bool(to_int(data[28:32]) & 1)
    }

    data_out["header"] = h_data
    data_out["seq"] = [
        i % h_data["num_frames"] for i in range(h_data["num_steps"])
    ]
    data_out["rate"] = [h_data["display_rate"]] * h_data["num_steps"]
예제 #2
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def _rate_chunk(header: Dict[str, Any], data: bytes, data_out: Dict[str, Any]):
    """
    Represents .ani's rate chunk, which has an identifier of "rate".
    """
    if (header is None):
        raise SyntaxError("rate chunk became before header!")

    if ((len(data) // 4) != header["num_steps"]):
        raise SyntaxError(
            "Length of rate chunk does not match the number of steps!")

    data_out["rate"] = [to_int(data[i:i + 4]) for i in range(0, len(data), 4)]
예제 #3
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    def _read_chunk(cls, offset: int, buffer: BinaryIO,
                    nominal_size: int) -> Tuple[Image.Image, int, int, int]:
        buffer.seek(offset)
        # Begin to check if this is valid...
        chunk_size = to_int(buffer.read(4))
        cls._assert(chunk_size == cls.IMG_CHUNK_H_SIZE,
                    f"Image chunks must be {cls.IMG_CHUNK_H_SIZE} bytes!")
        cls._assert(
            to_int(buffer.read(4)) == cls.CURSOR_TYPE,
            f"Type does not match type in TOC!")
        cls._assert(
            to_int(buffer.read(4)) == nominal_size,
            f"Nominal sizes in TOC and image header don't match!")
        cls._assert(
            to_int(buffer.read(4)) == 1,
            f"Unsupported version of image header...")
        # Checks are done, load the rest of the header as we are good from here...
        rest_of_chunk = buffer.read(20)
        width, height, x_hot, y_hot, delay = [
            to_int(rest_of_chunk[i:i + 4])
            for i in range(0, len(rest_of_chunk), 4)
        ]

        cls._assert(width <= 0x7fff, "Invalid width!")
        cls._assert(height <= 0x7fff, "Invalid height!")

        x_hot, y_hot = x_hot if (0 <= x_hot < width) else 0, y_hot if (
            0 <= y_hot < height) else 0

        img_data = np.frombuffer(buffer.read(width * height * 4),
                                 dtype=np.uint8).reshape(width, height, 4)

        # ARGB packed in little endian format, therefore its actually BGRA when read sequentially....
        image = Image.fromarray(img_data[:, :, (2, 1, 0, 3)], "RGBA")

        return (image, x_hot, y_hot, delay)
예제 #4
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    def read(cls, cur_file: BinaryIO) -> AnimatedCursor:
        """
        Read an xcur or X-Org cursor file from the specified file buffer.

        :param cur_file: The file buffer with xcursor data.
        :return: An AnimatedCursor object, non-animated cursors will contain only 1 frame.
        """
        magic_data = cur_file.read(4)

        cls._assert(cls.check(magic_data), "Not a XCursor File!!!")

        header_size = to_int(cur_file.read(4))
        cls._assert(header_size == cls.HEADER_SIZE,
                    f"Header size is not {cls.HEADER_SIZE}!")
        version = to_int(cur_file.read(4))

        # Number of cursors...
        num_toc = to_int(cur_file.read(4))
        # Used to store cursor offsets per size...
        nominal_sizes = {}

        for i in range(num_toc):
            main_type = to_int(cur_file.read(4))

            if (main_type == cls.CURSOR_TYPE):
                nominal_size = to_int(cur_file.read(4))
                offset = to_int(cur_file.read(4))

                if (nominal_size not in nominal_sizes):
                    nominal_sizes[nominal_size] = [offset]
                else:
                    nominal_sizes[nominal_size].append(offset)

        max_len = max(len(nominal_sizes[size]) for size in nominal_sizes)
        cursors = []
        delays = []

        for i in range(max_len):
            cursor = Cursor()
            sub_delays = []

            for size, offsets in nominal_sizes.items():
                if (i < len(offsets)):
                    img, x_hot, y_hot, delay = cls._read_chunk(
                        offsets[i], cur_file, size)
                    cursor.add(CursorIcon(img, x_hot, y_hot))
                    sub_delays.append(delay)

            cursors.append(cursor)
            delays.append(max(sub_delays))

        return AnimatedCursor(cursors, delays)
예제 #5
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def read_chunks(buffer: BinaryIO,
                skip_chunks: Set[bytes] = None,
                list_chunks: Set[bytes] = None,
                byteorder="little") -> Iterator[Tuple[bytes, int, bytes]]:
    """
    Reads a valid RIFF file, reading all the chunks in the file...

    :param buffer: The file buffer with valid RIFF data.
    :param skip_chunks: A set of length 4 bytes specifying chunks which are not actual chunks but are identifiers
                        followed by valid chunks.
    :param list_chunks: A set of length 4 bytes specifying chunks which containing sub-chunks, meaning there data
                        should be sub-iterated.
    :param byteorder: The byteorder of the integers in the file, "big" or "little". Default is "little".
    :return: A generator which yields each chunks identifier, size, and data as bytes.
    """
    if (skip_chunks is None):
        skip_chunks = set()
    if (list_chunks is None):
        list_chunks = set()

    while (True):
        next_id = buffer.read(4)
        if (next_id == b''):
            return
        if (next_id in skip_chunks):
            continue

        size = to_int(buffer.read(4), byteorder=byteorder)

        if (next_id in list_chunks):
            # print(f"(entering {next_id} chunk) -> [")
            yield from read_chunks(BytesIO(buffer.read(size)), skip_chunks,
                                   list_chunks, byteorder)
            # print(f"](exiting {next_id} chunk)")
            continue

        # print(f"emit chunk {next_id} of size {size}")
        yield (next_id, size, buffer.read(size))