Esempio n. 1
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def write_nse(fname, time_stamps, remarks=''):
    """Write out the given time stamps into a nse file."""
    with open(fname, 'wb') as fout:
        fmt = '=QII8I32h'
        dwScNumber = 1
        dwCellNumber = 1
        #dnParams = [0]*8
        #snData = [0]*32
        garbage = [0] * 40

        header = remarks.ljust(16 * 1024, '\x00')
        fout.write(header)
        for ts in time_stamps:
            fout.write(pk(fmt, ts, dwScNumber, dwCellNumber, *garbage))
Esempio n. 2
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 def decrypt_block_ecb(self, block):
     assert (len(block) == self.block_size)
     words = list(up('>IIII', block))
     for rnd in range(self.num_rounds, 0, -1):
         for i in range(len(words)):
             words[i] ^= self.keys[rnd][i]
         if rnd != self.num_rounds:
             words = self.unmix_columns(words)
         words = self.unshift_columns(words)
         for i in range(len(words)):
             words[i] = self.send_through_sbox(words[i], self.sbox_dec)
     for i in range(len(words)):
         words[i] ^= self.keys[0][i]
     return pk('>IIII', words[0], words[1], words[2], words[3])
Esempio n. 3
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def write_nse(fname, time_stamps, remarks=''):
  """Write out the given time stamps into a nse file."""
  with open(fname,'wb') as fout:
    fmt = '=QII8I32h'
    dwScNumber = 1
    dwCellNumber = 1
    #dnParams = [0]*8
    #snData = [0]*32
    garbage = [0]*40

    header = remarks.ljust(16*1024,'\x00')
    fout.write(header)
    for ts in time_stamps:
      fout.write(pk(fmt, ts, dwScNumber, dwCellNumber, *garbage))
Esempio n. 4
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def Q(delay, w, h, x, y, tidx):

    assert 0 <= tidx <= 255
    assert 0 <= delay < 2**16

    # this is used for the compression
    # multiplies tidx by (w*h) times
    # so eventually the size of list is w*h and each cell is tidx
    indices = [tidx] * (w * h)
    buf = BIO('')

    # 0x21 0xf9  = intro & label
    # 0x04 = block size
    # 0x05 = 0000 0101
    # bit 0 is reserved (???)
    # bit 2 is is also reserved (?????)
    buf.write('\x21\xF9\x04\x05')

    # write delay as unsigned short 2 bytes
    buf.write(pk('H', delay))
    # write index as unsigned char 1 byte
    buf.write(pk('B', tidx))
    # terminate block
    buf.write('\x00')

    # new image block
    buf.write('\x2c')
    # left pos
    buf.write(pk('H', x))
    # top pos
    buf.write(pk('H', y))
    # width & height
    buf.write(pk('H', w))
    buf.write(pk('H', h))
    # flag  section & local color table = 0
    buf.write('\x00')

    # min code size equals 8
    LZWMinimumCodeSize = 8

    # compression
    cmprs, _ = lzwlib.Lzwg.compress(indices, LZWMinimumCodeSize)

    # write min code size and the compressed blocks
    obuf = pk('B', LZWMinimumCodeSize) + WB(cmprs)

    # write obuf to buf
    buf.write(obuf)
    buf.seek(0)

    # read entire buffer
    return buf.read()
def make_standard(exp):
    std = exp[:]
    _, metadata_offset, is_exp = up('<III', exp[:12])
    assert is_exp == 1

    # Patch the experimental flag to zero.
    std = std[:8] + pk('<I', 0) + std[12:]

    # Locate the mesosphere content header, patch to be experimental.
    magic, size, code_ofs, content_ofs, num_contents, ver, sup_ver, rev = up(
        '<IIIIIIII', exp[metadata_offset:metadata_offset + 0x20])
    for i in range(num_contents):
        start, size, cnt_type, flag0, flag1, flag2, pad = up(
            '<IIBBBBI',
            exp[content_ofs + 0x20 * i:content_ofs + 0x20 * i + 0x10])
        if cnt_type == 10:  # CONTENT_TYPE_KRN
            assert exp[content_ofs + 0x20 * i + 0x10:content_ofs + 0x20 * i +
                       0x10 + len(b'mesosphere') + 1] == (b'mesosphere\x00')
            assert flag0 == 0 and flag1 == 0 and flag2 == 0
            std = std[:content_ofs + 0x20 * i] + pk(
                '<IIBBBBI', start, size, cnt_type, flag0 | 0x1, flag1, flag2,
                pad) + std[content_ofs + 0x20 * i + 0x10:]

    return std
Esempio n. 6
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def convert_image(image_fn):
    splash = Image.open(image_fn, 'r')
    w, h = splash.size
    if w == 1280 and h == 720:
        splash = splash.transpose(Image.ROTATE_90)
        w, h = splash.size
    assert w == 720
    assert h == 1280
    splash = splash.convert('RGBA')
    splash_bin = b''
    for row in range(SPLASH_SCREEN_WIDTH):
        for col in range(SPLASH_SCREEN_HEIGHT):
            r, g, b, a = splash.getpixel((col, row))
            splash_bin += pk('<BBBB', b, g, r, a)
        splash_bin += b'\x00' * ((SPLASH_SCREEN_STRIDE - SPLASH_SCREEN_HEIGHT) * 4)
    return splash_bin
Esempio n. 7
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def main(argc, argv):
    if argc != 4:
        print('Usage: %s kernel_ldr.bin kernel.bin output.bin' % argv[0])
        return 1
    with open(argv[1], 'rb') as f:
        kernel_ldr = f.read()
    with open(argv[2], 'rb') as f:
        kernel = f.read()
    kernel_metadata_offset = 4
    assert (kernel_metadata_offset <= len(kernel) - 0x40)
    assert (kernel[kernel_metadata_offset:kernel_metadata_offset + 4] == b'MSS0')

    bss_start, bss_end, kernel_end = up('<III', kernel[kernel_metadata_offset + 0x30:kernel_metadata_offset + 0x3C])
    assert (bss_end >= bss_start)
    assert (bss_end == kernel_end)

    assert (len(kernel) <= kernel_end)
    if len(kernel) < kernel_end:
        kernel += b'\x00' * (kernel_end - len(kernel))
    assert (kernel_end == len(kernel))

    embedded_ini = b''
    try:
        with open('ini.bin', 'rb') as f:
            embedded_ini = f.read()
    except:
        pass
    embedded_ini_offset = align_up(kernel_end, 0x1000)
    embedded_ini_end = embedded_ini_offset + len(embedded_ini) # TODO: Create and embed an INI, eventually.

    kernel_ldr_offset = align_up(embedded_ini_end, 0x1000) + (0x1000 if len(embedded_ini) == 0 else 0)
    kernel_ldr_end    = kernel_ldr_offset + len(kernel_ldr)
    mesosphere_end    = align_up(kernel_ldr_end, 0x1000)

    with open(argv[3], 'wb') as f:
        f.write(kernel[:kernel_metadata_offset + 4])
        f.write(pk('<QQI', embedded_ini_offset, kernel_ldr_offset, atmosphere_target_firmware(13, 0, 0)))
        f.write(kernel[kernel_metadata_offset + 0x18:])
        f.seek(embedded_ini_offset)
        f.write(embedded_ini)
        f.seek(embedded_ini_end)
        f.seek(kernel_ldr_offset)
        f.write(kernel_ldr)
        f.seek(mesosphere_end)
        f.write(b'\x00'*0x1000)
    return 0
Esempio n. 8
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def main(argc, argv):
    if argc != 1:
        print('Usage: %s' % argv[0])
        return 1
    with open('kernel_ldr/kernel_ldr.bin', 'rb') as f:
        kernel_ldr = f.read()
    with open('kernel/kernel.bin', 'rb') as f:
        kernel = f.read()
    kernel_metadata_offset = 4
    assert (kernel_metadata_offset <= len(kernel) - 0x40)
    assert (kernel[kernel_metadata_offset:kernel_metadata_offset +
                   4] == b'MSS0')
    kernel_end = up(
        '<I',
        kernel[kernel_metadata_offset + 0x38:kernel_metadata_offset + 0x3C])[0]
    assert (kernel_end >= len(kernel))

    embedded_ini = b''
    try:
        with open('ini.bin', 'rb') as f:
            embedded_ini = f.read()
    except:
        pass
    embedded_ini_offset = align_up(kernel_end, 0x1000) + 0x1000
    embedded_ini_end = embedded_ini_offset + len(
        embedded_ini)  # TODO: Create and embed an INI, eventually.

    kernel_ldr_offset = align_up(embedded_ini_end, 0x1000) + 0x1000
    kernel_ldr_end = kernel_ldr_offset + len(kernel_ldr)
    mesosphere_end = align_up(kernel_ldr_end, 0x1000)

    with open('mesosphere.bin', 'wb') as f:
        f.write(kernel[:kernel_metadata_offset + 4])
        f.write(
            pk('<QQI', embedded_ini_offset, kernel_ldr_offset,
               atmosphere_target_firmware(10, 1, 0)))
        f.write(kernel[kernel_metadata_offset + 0x18:])
        f.seek(embedded_ini_offset)
        f.write(embedded_ini)
        f.seek(embedded_ini_end)
        f.seek(kernel_ldr_offset)
        f.write(kernel_ldr)
        f.seek(mesosphere_end)
        f.write(b'\x00' * 0x1000)
    return 0
Esempio n. 9
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def WB(buf):
    # amount of blocks. each block size should be FF = 255
    blockcount = len(buf) / 0xFF
    # if amount of blocks is not divisble by 255, add 1, else nothing
    blockcount += 1 if len(buf) % 0xFF else 0

    # pack/parse length of each subblock as unsigned integer
    # each sub block is the size FF
    # so each "mapped" cell in blocks array should be of the format
    # ${parsedLength}${subBlock}
    blocks = [
        pk('B', len(subblock)) + subblock for subblock in
        [buf[i:0xFF + i] for i in xrange(0, blockcount * 0xFF, 0xFF)]
    ]

    # join all blocks to a string and append 00 at the end
    # 0x00 represents end of block
    return ''.join(blocks) + '\x00'
Esempio n. 10
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def testGetValveCfg(s):
    # frame head
    data = pk('B', 0x02)
    data += pk('B', 0X06)
    # payload length
    data += pk('<H', 0x0006)
    # payload
    data += pk('<I', 0x0901000a)
    data += pk('<H', 0x0008)
    # frame tail
    data += pk('<H', 0xd1b8)
    data += pk('B', 0x03)

    print "testGetValveCfg frame on network is:"
    print repr(data)
    print "send testGetValveCfg data to server"
    s.sendall(data)
    data = s.recv(4096)
    print('received', repr(data))
Esempio n. 11
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 def hook_code(uc, address, size, self):
     assert size == 4
     insn = up('<I', uc.mem_read(address, 4))[0]
     self.restore_instructions(uc)
     if insn in self.invalid_instructions:
         self.patch_instruction(uc, address,
                                pk('<I', self.invalid_instructions[insn]))
     if self.calling_function:
         self.add_function_call(uc, address)
         self.calling_function = False
     if (insn & 0xFC000000) in [0x94000000]:
         self.calling_function = True
     if (insn & 0xFFFFFFE0) == 0xD51E1000 and len(self.virt_to_phys) == 0:
         mmu_funcs = [
             func for func in self.function_calls if self.is_mmu_func(func)
         ]
         assert len(mmu_funcs) == 1
         mmu_func = mmu_funcs[0]
         for call in self.function_calls[mmu_func]:
             l3_tab, vaddr, paddr, size, attr = tuple(call[:5])
             self.l3_table = l3_tab
             if vaddr != paddr:
                 assert vaddr >= 0x80000000
                 uc.mem_map(vaddr, size)
                 mem = uc.mem_read(paddr, size)
                 uc.mem_write(vaddr, str(mem))
                 self.virt_to_phys[vaddr] = (paddr, size, attr)
                 self.phys_to_virt[paddr] = (vaddr, size, attr)
                 self.mappings.append((vaddr, paddr, size, attr))
     if (insn & 0xFFFFFFE0) == 0xD51EC000:
         # VBAR set
         which = insn & 0x1F
         self.vbar = uc.reg_read(Emulator.REGISTER_IDS[which])
     if (insn & 0xFFFFFFE0) == 0xD51E2000:
         # TTBR set
         which = insn & 0x1F
         self.ttbr = uc.reg_read(Emulator.REGISTER_IDS[which])
         assert (self.ttbr & 0x7FF) == 0x7C0
Esempio n. 12
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def locate_fields(full):
    start = ['TestU64', 'TestU32', 'TestI64', 'TestI32']
    inds = [LOAD_BASE + full.index('%s\x00' % s) for s in start]
    target = pk('<QQQQ', inds[0], inds[1], inds[2], inds[3])
    return full.index(target)
Esempio n. 13
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 def put_qword(z, target, val):
     return z[:target] + pk('<Q', val) + z[target + 8:]
Esempio n. 14
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 def put_dword(z, target, val):
     return z[:target] + pk('<I', val) + z[target + 4:]
Esempio n. 15
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def E(f, s, o):
    # Headers of file
    global_colors, bgcoloridx, size_count, hh, ww = F(f)

    # (mutated) Flag (??)
    mp, ks = M(s)

    # By here, current file cursor should be at the end of the header
    hdr_end = f.tell()

    # Go back to file beginning
    f.seek(0)
    # Write header string to output
    o.write(f.read(hdr_end))

    fc = 0

    # write these 2 bytes.
    # 0x21 is extension into
    # 0xfe is COMMENT LABEL
    o.write('\x21\xFE')

    # writes the mapped flags with RDBNB prepended after mutating iwth WB
    o.write(WB('RDBNB' + mp))
    o.flush()

    # iterate on the generator C returns
    for t, buf in C(f):
        print('.', end='')
        # if comment
        # IGNORES COMMENT SECTION TO OUTPUT.
        if t == T.EC:
            continue

        # if graphic control label
        if t == T.EG:
            # if havent finished encoding the flag into file, mutate in the following way:
            if ks:
                # reads 2 bytes from buffer ([4,5]) and parses as H - unsigned short
                delay = up('<H', buf[4:6])
                # all delays of gif were over 6
                assert delay >= 6
                # changes the delay. decrease by 3
                buf = buf[:4] + pk('<H', delay - 3) + buf[6:]
            obuf = buf

        # else if image sep
        elif t == T.I:
            fc += 1
            total_raw_blocks_data = ''
            bf = BIO(buf)
            pref = bf.read(10)

            # reads the code size but parses it as char
            LZWMinimumCodeSize = ord(bf.read(1))
            # read block data
            total_raw_blocks_data = k(bf)

            indices, dcmprsdcodes = lzwlib.Lzwg.decompress(
                total_raw_blocks_data, LZWMinimumCodeSize)

            # < = little endian
            # B = unsigned char
            # H = unsigned short
            xxx = unpack('<B H H H H B', pref)

            cmprs, codes = lzwlib.Lzwg.compress(indices, LZWMinimumCodeSize)

            obuf = pref + pk('B', LZWMinimumCodeSize) + WB(cmprs)

            # pop ks here - only on image section
            if ks:
                mpindx, isup = ks.pop(0)
                obuf += h(mpindx, isup, ww, hh, len(global_colors) - 1)
        else:
            obuf = buf

        # write to output
        o.write(obuf)
    o.flush()

    # eventually, ks should be false
    assert not ks, ''

    return 0
Esempio n. 16
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 def __init__(self, data):
     self.ftype = data[TYPE]
     tmpbuf = pk('<I', data[DEVID])
     tmpbuf += pk('B', data[STATUS])
     self.payload = tmpbuf
Esempio n. 17
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    def groupNetData(self):
        data = ''
        data += pk('B', self.head)
        data += pk('B', self.type)
        data += pk('<H', self.len)
        data += pk('<I', self.devid)
        data += pk('<I', self.model)
        data += pk('<I', self.hwVer)
        data += pk('<I', self.fwVer)
        data += pk('B', self.lang)
        data += pk('<H', self.year)
        data += pk('B', self.month)
        data += pk('B', self.day)
        data += pk('B',self.hour)
        data += pk('B', self.minute)
        data += pk('B', self.second)
        data += pk('<H', self.crc)
        data += pk('B',self.etx)

        return data
Esempio n. 18
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    def __init__(self):
        data = pk('B' ,0x02)
        data += pk('B', 0X05)
        data += pk('<H', 0x0036)# length
        data += pk('<I', 0x0901000a)
        data += pk('<H', 0x0008)

        for i in range(8):
            data += pk('B', i)
            data += pk('<H', 0x000a+i)
            data += pk('B', i)
            data += pk('<H', 0x000a+i)

        data += pk('<H', 0xd1b8)
        data += pk('B', 0x03)
         
        self.data = data   
Esempio n. 19
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def repack_nso(path_original, path_patch, path_out):
    nso = b''

    patched_text_hash = b''

    # Read the original NSO
    with open(path_original, 'rb') as f:
        nso = bytearray(f.read())

    # Read the patched text
    with open(path_patch, 'rb') as f:
        data = f.read()
        patched_text_hash = sha256(data)
        compressed_patched_text = lz4.block.compress(data, store_size=False)

    text_off = up('<I', nso[0x10:0x14])[0]
    text_compressed_size = len(compressed_patched_text)

    # Retrieve original rodata segment
    rodata_off = up('<I', nso[0x20:0x24])[0]
    rodata_compressed_size = up('<I', nso[0x64:0x68])[0]
    compressed_rodata = nso[rodata_off:rodata_off + rodata_compressed_size]

    # Retrieve original data segment
    data_off = up('<I', nso[0x30:0x34])[0]
    data_compressed_size = up('<I', nso[0x68:0x6C])[0]
    compressed_data = nso[data_off:data_off + data_compressed_size]

    # Set to the offsets of the output nso
    rodata_off = text_off + text_compressed_size
    data_off = rodata_off + rodata_compressed_size

    # Create the output nso
    out_nso = bytearray(data_off + data_compressed_size)

    # Copy over the original header
    out_nso[0x0:0x100] = nso[0x0:text_off]

    # Write the new text hash
    out_nso[0xA0:0xC0] = patched_text_hash

    # Write the new compressed text size
    out_nso[0x60:0x64] = pk('<I', text_compressed_size)

    # Correct the header offsets
    out_nso[0x20:0x24] = pk('<I', rodata_off)  # rodata offset
    out_nso[0x30:0x34] = pk('<I', data_off)  # data offset

    # Write new data
    out_nso[text_off:text_off + text_compressed_size] = compressed_patched_text
    out_nso[rodata_off:rodata_off + rodata_compressed_size] = compressed_rodata
    out_nso[data_off:data_off + data_compressed_size] = compressed_data

    print('text:')

    print('\nrodata:')
    print('Offset                    {}'.format(rodata_off))
    print('len(compressed_rodata)    {}'.format(len(compressed_rodata)))
    print('Original header size      {}'.format(rodata_compressed_size))

    print('\ndata:')
    print('Offset                    {}'.format(data_off))
    print('len(compressed_rodata)    {}'.format(len(compressed_data)))
    print('Original header size      {}'.format(data_compressed_size))

    with open(path_out, 'wb') as f:
        f.write(out_nso)
def sxor(s1, s2):
    assert (len(s1) == len(s2))
    return b''.join([pk('B', x ^ y) for x, y in zip(s1, s2)])
Esempio n. 21
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def find_types(full, num_fields):
    KNOWN = range(10) + [4, 4, 2, 4]
    ind = full.index(''.join(pk('<I', i) for i in KNOWN))
    return list(up('<' + 'I' * num_fields, full[ind:ind + 4 * num_fields]))
Esempio n. 22
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def decrypt(encryptedFile, decodedFile):
    # Headers of file
    global_colors, bgcoloridx, size_count, hh, ww = readHeader(encryptedFile)

    # By here, current file cursor should be at the end of the header
    hdr_end = encryptedFile.tell()

    # Go back to file beginning
    encryptedFile.seek(0)
    # Write header string to output
    decodedFile.write(encryptedFile.read(hdr_end))

    # Reaching here means the header section of decoded file is done
    # Moving on ...

    # The first block should be a comment section which includes the secret flag (mutated)
    # should look like:
    # 0x21 extension introducer
    # 0xfe comment label
    # [{
    #   blockSize, RDBNB+flag
    # }]
    # 0x00

    readFirstComment(encryptedFile)

    encryptedFlag = 'OE7AUKL}_GY#0FR{!HMTWS'
    originalFlag = ''

    print('Finished reading first block (comment)')
    print 'The flag is: {0}'.format(encryptedFlag)
    print 'Flag size: {0}'.format(len(encryptedFlag))
    print 'Now pointing to the next section...'

    firstPotential = 0
    secondPotential = 0
    encodedFlag = []

    # After this, there should be no comment sections at all, becuase the encoder doesnt write any comments.

    gen = readBlocks(f)
    # Iterate on sections using the generator
    for t, buf in gen:
        if t == BlockType.GRAPHIC_CONTROL:
            # Get delay
            delay = up('<H', buf[4:6])
            # Flags
            flags = up('<B', buf[3:4])
            # Trans Color Idx
            transColIdx = up('<B', buf[6:7])

            if flags == 5 and delay == 3 and (transColIdx >= 0
                                              and transColIdx <= 63):
                secondPotential += 1
                encodedFlag.append(
                    (BlockType.GRAPHIC_CONTROL, secondPotential, {
                        'delay': delay,
                        'flags': flags,
                        'transColIdx': transColIdx
                    }))

            obuf = buf

        elif t == BlockType.IMAGE:
            total_raw_blocks_data = ''
            # re-read buffer
            bf = BIO(buf)

            # skip first 10 bytes to get to lzw size
            pref = bf.read(10)

            # reads the code size but parses it as char
            LZWMinimumCodeSize = ord(bf.read(1))

            # Read all blocks of image data
            total_raw_blocks_data = readImageBlock(bf)

            # Decompress the data (compressed by lzw)
            indices, dcmprsdcodes = lzwlib.Lzwg.decompress(
                total_raw_blocks_data, LZWMinimumCodeSize)

            # < = little endian
            # B = unsigned char = 1 byte
            # H = unsigned short = 2 bytes
            sep, leftp, topp, width, height, flags = unpack(
                '<B H H H H B', pref)

            if (LZWMinimumCodeSize == 8 and flags == 0):
                firstPotential += 1
                encodedFlag.append((BlockType.IMAGE, firstPotential, {
                    'leftp': leftp,
                    'topp': topp,
                    'width': width,
                    'height': height,
                    'flags': flags,
                    'minCodeSize': LZWMinimumCodeSize,
                    'indices': indices,
                    'dcmprsdcodes': dcmprsdcodes
                }))

            cmprs, codes = lzwlib.Lzwg.compress(indices, LZWMinimumCodeSize)

            obuf = pref + pk('B', LZWMinimumCodeSize) + writeBlock(cmprs)

            # until flag has been encoded, 2 more blocks are added:
            # 1. Graphic Control Extension Block withe the following:
            # 1.1. block size = 4 (constant ?)
            # 1.2. flags = 0000 0101 = 5 = bit 0 & bit 2
            # 1.3. delay = 3
            # 1.4. transp color idx = if even then lowercase, else uppercase
            # 2. Image Block
            # 2.1. left pos, top pos, width, height = nothing useful now
            # 2.2. flags = 0
            # 2.3. Local color table = 0
            # 2.4. lzw min code size = 8
            # 2.5. blocks = array of length (width*height) containing only [tidx (from 1.4)]

        # if not graphic control or image, just write without mutating
        else:
            obuf = buf

        o.write(obuf)
    o.flush()

    i = 0

    while i < len(encodedFlag):
        grphic = encodedFlag[i]
        img = encodedFlag[i + 1]
        i += 2

        leftp = img[2]['leftp']
        topp = img[2]['topp']
        width = img[2]['width']
        height = img[2]['height']

        letterIdxInEnc = firstDecFunc(leftp, topp, width, height)

        isLower = grphic[2]['transColIdx'] % 2 == 0
        originalFlag += encryptedFlag[
            letterIdxInEnc] if not isLower else encryptedFlag[
                letterIdxInEnc].lower()

    print originalFlag
    return 0
Esempio n. 23
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def write_header(f, all_kips, wb_size, tk_size, xf_size, ex_size, ms_size,
                 fs_size, rb_size, git_revision, major, minor, micro, relstep,
                 s_major, s_minor, s_micro, s_relstep):
    # Unpack kips
    emummc, kips = all_kips
    # Write magic as PK31 magic.
    f.write(b'PK31')
    # Write metadata offset = 0x10
    f.write(pk('<I', 0x20))
    # Write flags
    f.write(pk('<I', 0x00000000))
    # Write meso_size
    f.write(pk('<I', ms_size))
    # Write num_kips
    f.write(pk('<I', len(KIP_NAMES)))
    # Write reserved1
    f.write(b'\xCC' * 0xC)
    # Write legacy magic
    f.write(b'FSS0')
    # Write total size
    f.write(pk('<I', 0x800000))
    # Write reserved2
    f.write(pk('<I', 0xCCCCCCCC))
    # Write content_header_offset
    f.write(pk('<I', 0x40))
    # Write num_content_headers;
    f.write(pk('<I', 8 + len(KIP_NAMES)))
    # Write supported_hos_version;
    f.write(pk('<BBBB', s_relstep, s_micro, s_minor, s_major))
    # Write release_version;
    f.write(pk('<BBBB', relstep, micro, minor, major))
    # Write git_revision;
    f.write(pk('<I', git_revision))
    # Write content metas
    f.write(
        pk('<IIBBBBI16s', 0x000800, wb_size, 2, 0, 0, 0, 0xCCCCCCCC,
           b'warmboot'))
    f.write(
        pk('<IIBBBBI16s', 0x002000, tk_size, 12, 0, 0, 0, 0xCCCCCCCC,
           b'tsec_keygen'))
    f.write(
        pk('<IIBBBBI16s', 0x004000, xf_size, 11, 0, 0, 0, 0xCCCCCCCC,
           b'exosphere_fatal'))
    f.write(
        pk('<IIBBBBI16s', 0x048000, ex_size, 1, 0, 0, 0, 0xCCCCCCCC,
           b'exosphere'))
    f.write(
        pk('<IIBBBBI16s', 0x056000, ms_size, 10, 0, 0, 0, 0xCCCCCCCC,
           b'mesosphere'))
    f.write(
        pk('<IIBBBBI16s', 0x7C0000, fs_size, 0, 0, 0, 0, 0xCCCCCCCC, b'fusee'))
    f.write(
        pk('<IIBBBBI16s', 0x7E0000, rb_size, 3, 0, 0, 0, 0xCCCCCCCC,
           b'rebootstub'))
    f.write(
        pk('<IIBBBBI16s', 0x100000, len(emummc), 8, 0, 0, 0, 0xCCCCCCCC,
           b'emummc'))
    ofs = (0x100000 + len(emummc) + 0xF) & ~0xF
    for kip_name in KIP_NAMES:
        kip_data = kips[kip_name]
        f.write(
            pk('<IIBBBBI16s', ofs, len(kip_data), 6, 0, 0, 0, 0xCCCCCCCC,
               kip_name))
        ofs += len(kip_data)
        ofs += 0xF
        ofs &= ~0xF
    # Pad to kip metas.
    f.write(b'\xCC' * (0x400 - 0x40 - (0x20 * (8 + len(KIP_NAMES)))))
    # Write emummc_meta. */
    write_kip_meta(f, emummc, 0x100000)
    # Write kip metas
    ofs = (0x100000 + len(emummc) + 0xF) & ~0xF
    for kip_name in KIP_NAMES:
        kip_data = kips[kip_name]
        write_kip_meta(f, kip_data, ofs)
        ofs += len(kip_data)
        ofs += 0xF
        ofs &= ~0xF
    # Pad to end of header
    f.write(b'\xCC' * (0x800 - (0x400 + (1 + len(KIP_NAMES)) * 0x30)))
Esempio n. 24
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 def groupFrame(self):
     head = pk('B', FRAME_HEAD)
     frameType = pk('B', self.ftype)
     tmpbuf = encodePayload(frameType, self.payload)
     return (head + tmpbuf)
Esempio n. 25
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def find_categories(full, num_fields):
    KNOWN = [0] * 10 + [1] * 2 + [0x3B] * 2
    ind = full.index(''.join(pk('<I', i) for i in KNOWN))
    return list(up('<' + 'I' * num_fields, full[ind:ind + 4 * num_fields]))
Esempio n. 26
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    def gen_rhfs0_head(self, upd_list, norm_list, sec_list, sec_fileSizes,
                       sec_shalist):

        hreg = 0x200
        hashregion = hreg.to_bytes(0x04, byteorder='little')
        #UPD HEADER
        filesNb = len(upd_list)
        stringTable = '\x00'.join(str(nca) for nca in upd_list)
        headerSize = 0x10 + (filesNb) * 0x40 + len(stringTable)
        upd_multiplier = math.ceil(headerSize / 0x200)
        remainder = 0x200 * upd_multiplier - headerSize
        headerSize += remainder
        fileSizes = list()
        fileOffsets = list()
        shalist = list()

        fileNamesLengths = [
            len(os.path.basename(file)) + 1 for file in upd_list
        ]  # +1 for the \x00
        stringTableOffsets = [
            sum(fileNamesLengths[:n]) for n in range(filesNb)
        ]

        upd_header = b''
        upd_header += b'HFS0'
        upd_header += pk('<I', filesNb)
        upd_header += pk('<I', len(stringTable) + remainder)
        upd_header += b'\x00\x00\x00\x00'
        for n in range(filesNb):
            upd_header += pk('<Q', fileOffsets[n])
            upd_header += pk('<Q', fileSizes[n])
            upd_header += pk('<I', stringTableOffsets[n])
            upd_header += hashregion
            upd_header += b'\x00\x00\x00\x00\x00\x00\x00\x00'
            upd_header += bytes.fromhex(shalist[n])
        upd_header += stringTable.encode()
        upd_header += remainder * b'\x00'

        updSize = len(upd_header) + sum(fileSizes)

        #print (hx(upd_header))
        #NORMAL HEADER
        filesNb = len(norm_list)
        stringTable = '\x00'.join(str(nca) for nca in norm_list)
        headerSize = 0x10 + (filesNb) * 0x40 + len(stringTable)
        norm_multiplier = math.ceil(headerSize / 0x200)
        remainder = 0x200 * norm_multiplier - headerSize
        headerSize += remainder
        fileSizes = list()
        fileOffsets = list()
        shalist = list()

        fileNamesLengths = [
            len(os.path.basename(file)) + 1 for file in norm_list
        ]  # +1 for the \x00
        stringTableOffsets = [
            sum(fileNamesLengths[:n]) for n in range(filesNb)
        ]

        norm_header = b''
        norm_header += b'HFS0'
        norm_header += pk('<I', filesNb)
        norm_header += pk('<I', len(stringTable) + remainder)
        norm_header += b'\x00\x00\x00\x00'
        for n in range(filesNb):
            norm_header += pk('<Q', fileOffsets[n])
            norm_header += pk('<Q', fileSizes[n])
            norm_header += pk('<I', stringTableOffsets[n])
            norm_header += hashregion
            norm_header += b'\x00\x00\x00\x00\x00\x00\x00\x00'
            norm_header += bytes.fromhex(shalist[n])
        norm_header += stringTable.encode()
        norm_header += remainder * b'\x00'

        normSize = len(norm_header) + sum(fileSizes)
        #print (hx(norm_header))

        #SECURE HEADER
        filesNb = len(sec_list)
        stringTable = '\x00'.join(str(nca) for nca in sec_list)
        headerSize = 0x10 + (filesNb) * 0x40 + len(stringTable)
        sec_multiplier = math.ceil(headerSize / 0x200)
        remainder = 0x200 * sec_multiplier - headerSize
        headerSize += remainder

        fileSizes = sec_fileSizes
        fileOffsets = [sum(fileSizes[:n]) for n in range(filesNb)]

        shalist = sec_shalist

        fileNamesLengths = [
            len(os.path.basename(file)) + 1 for file in sec_list
        ]  # +1 for the \x00
        stringTableOffsets = [
            sum(fileNamesLengths[:n]) for n in range(filesNb)
        ]

        sec_header = b''
        sec_header += b'HFS0'
        sec_header += pk('<I', filesNb)
        sec_header += pk('<I', len(stringTable) + remainder)
        sec_header += b'\x00\x00\x00\x00'
        for n in range(filesNb):
            sec_header += pk('<Q', fileOffsets[n])
            sec_header += pk('<Q', fileSizes[n])
            sec_header += pk('<I', stringTableOffsets[n])
            sec_header += hashregion
            sec_header += b'\x00\x00\x00\x00\x00\x00\x00\x00'
            sec_header += bytes.fromhex(shalist[n])
        sec_header += stringTable.encode()
        sec_header += remainder * b'\x00'
        secSize = len(sec_header) + sum(fileSizes)

        #print (hx(sec_header))

        #ROOT HEADER
        root_hreg = list()
        hr = 0x200 * upd_multiplier
        root_hreg.append(hr.to_bytes(4, byteorder='little'))
        hr = 0x200 * norm_multiplier
        root_hreg.append(hr.to_bytes(4, byteorder='little'))
        hr = 0x200 * sec_multiplier
        root_hreg.append(hr.to_bytes(4, byteorder='little'))
        root_list = list()
        root_list.append("update")
        root_list.append("normal")
        root_list.append("secure")
        fileSizes = list()
        fileSizes.append(updSize)
        fileSizes.append(normSize)
        fileSizes.append(secSize)
        #print(fileSizes)
        filesNb = len(root_list)
        #print(filesNb)
        stringTable = '\x00'.join(os.path.basename(file) for file in root_list)
        #print(stringTable)
        headerSize = 0x10 + (filesNb) * 0x40 + len(stringTable)
        root_multiplier = math.ceil(headerSize / 0x200)
        remainder = 0x200 * root_multiplier - headerSize
        headerSize += remainder
        #print(headerSize)
        fileOffsets = [sum(fileSizes[:n]) for n in range(filesNb)]
        shalist = list()
        sha = sha256(upd_header).hexdigest()
        shalist.append(sha)
        sha = sha256(norm_header).hexdigest()
        shalist.append(sha)
        sha = sha256(sec_header).hexdigest()
        shalist.append(sha)

        fileNamesLengths = [
            len(os.path.basename(file)) + 1 for file in root_list
        ]  # +1 for the \x00
        stringTableOffsets = [
            sum(fileNamesLengths[:n]) for n in range(filesNb)
        ]

        root_header = b''
        root_header += b'HFS0'
        root_header += pk('<I', filesNb)
        root_header += pk('<I', len(stringTable) + remainder)
        root_header += b'\x00\x00\x00\x00'
        for n in range(filesNb):
            root_header += pk('<Q', fileOffsets[n])
            root_header += pk('<Q', fileSizes[n])
            root_header += pk('<I', stringTableOffsets[n])
            root_header += root_hreg[n]
            root_header += b'\x00\x00\x00\x00\x00\x00\x00\x00'
            root_header += bytes.fromhex(shalist[n])
        root_header += stringTable.encode()
        root_header += remainder * b'\x00'
        #print (hx(root_header))
        rootSize = len(root_header) + sum(fileSizes)
        return root_header, upd_header, norm_header, sec_header, rootSize, upd_multiplier, norm_multiplier, sec_multiplier
Esempio n. 27
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def repack_nso(path_original, path_patch, path_out):
    nso = b''

    patched_text_hash = b''

    # Read the original NSO
    with open(path_original, 'rb') as f:
        nso = bytearray(f.read())

    # Read the patched text
    with open(path_patch, 'rb') as f:
        data = f.read()
        patched_text_hash = sha256(data)
        compressed_patched_text = lz4.block.compress(data, store_size=False)


    text_off = up('<I', nso[0x10:0x14])[0]
    text_compressed_size = len(compressed_patched_text)

    # Retrieve original rodata segment
    rodata_off = up('<I', nso[0x20:0x24])[0]
    rodata_compressed_size = up('<I', nso[0x64:0x68])[0]
    compressed_rodata = nso[rodata_off:rodata_off+rodata_compressed_size]

    # Retrieve original data segment
    data_off = up('<I', nso[0x30:0x34])[0]
    data_compressed_size = up('<I', nso[0x68:0x6C])[0]
    compressed_data = nso[data_off:data_off+data_compressed_size]

    # Set to the offsets of the output nso
    rodata_off = text_off + text_compressed_size
    data_off = rodata_off + rodata_compressed_size

    # Create the output nso
    out_nso = bytearray(data_off + data_compressed_size)

    # Copy over the original header
    out_nso[0x0:0x100] = nso[0x0:text_off]

    # Write the new text hash
    out_nso[0xA0:0xC0] = patched_text_hash

    # Write the new compressed text size
    out_nso[0x60:0x64] = pk('<I', text_compressed_size)

    # Correct the header offsets
    out_nso[0x20:0x24] = pk('<I', rodata_off) # rodata offset
    out_nso[0x30:0x34] = pk('<I', data_off) # data offset

    # Write new data
    out_nso[text_off:text_off+text_compressed_size] = compressed_patched_text
    out_nso[rodata_off:rodata_off+rodata_compressed_size] = compressed_rodata
    out_nso[data_off:data_off+data_compressed_size] = compressed_data

    print('text:')

    print('\nrodata:')
    print('Offset                    {}'.format(rodata_off))
    print('len(compressed_rodata)    {}'.format(len(compressed_rodata)))
    print('Original header size      {}'.format(rodata_compressed_size))

    print('\ndata:')
    print('Offset                    {}'.format(data_off))
    print('len(compressed_rodata)    {}'.format(len(compressed_data)))
    print('Original header size      {}'.format(data_compressed_size))

    with open(path_out, 'wb') as f:
        f.write(out_nso)
Esempio n. 28
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def main(argc, argv):
    if argc < 4:
        print(
            'Usage: %s kernel_ldr.bin kernel.bin output.bin [initial_process.kip ...]'
            % argv[0])
        return 1
    with open(argv[1], 'rb') as f:
        kernel_ldr = f.read()
    with open(argv[2], 'rb') as f:
        kernel = f.read()
    kernel_metadata_offset = 4
    assert (kernel_metadata_offset <= len(kernel) - 0x40)
    assert (kernel[kernel_metadata_offset:kernel_metadata_offset +
                   4] == b'MSS0')

    bss_start, bss_end, kernel_end = up(
        '<III',
        kernel[kernel_metadata_offset + 0x30:kernel_metadata_offset + 0x3C])
    assert (bss_end >= bss_start)
    assert (bss_end == kernel_end)

    assert (len(kernel) <= kernel_end)
    if len(kernel) < kernel_end:
        kernel += b'\x00' * (kernel_end - len(kernel))
    assert (kernel_end == len(kernel))

    embedded_kips = b''
    num_kips = 0
    for kip_file in argv[4:]:
        try:
            with open(kip_file, 'rb') as f:
                data = f.read()
                if data.startswith(b'KIP1'):
                    embedded_kips += data
                    num_kips += 1
        except:
            pass
    if num_kips > 0:
        embedded_ini_header = pk('<4sIII', b'INI1',
                                 len(embedded_kips) + 0x10, num_kips, 0)
    else:
        embedded_ini_header = b''
    embedded_ini_offset = align_up(kernel_end, 0x1000)
    embedded_ini_end = embedded_ini_offset + len(embedded_ini_header) + len(
        embedded_kips)

    kernel_ldr_offset = align_up(embedded_ini_end, 0x1000) + (
        0x1000 if len(embedded_ini_header) == 0 else 0)
    kernel_ldr_end = kernel_ldr_offset + len(kernel_ldr)
    mesosphere_end = align_up(kernel_ldr_end, 0x1000)

    with open(argv[3], 'wb') as f:
        f.write(kernel[:kernel_metadata_offset + 4])
        f.write(
            pk('<QQI', embedded_ini_offset, kernel_ldr_offset,
               atmosphere_target_firmware(13, 0, 0)))
        f.write(kernel[kernel_metadata_offset + 0x18:])
        f.seek(embedded_ini_offset)
        f.write(embedded_ini_header)
        f.write(embedded_kips)
        f.seek(embedded_ini_end)
        f.seek(kernel_ldr_offset)
        f.write(kernel_ldr)
        f.seek(mesosphere_end)
        f.write(b'\x00' * 0x1000)
    return 0
Esempio n. 29
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    def __init__(self):
        data = pk('B' ,0x02)
        data += pk('B', 0X07)
        data += pk('<H', 0x0cec)# length
        data += pk('<I', 0x0901000a)
        data += pk('<H', 0x0002)
        data += pk('<H', 20)

        for i in range(20):
            # formula type
            data += pk('B', i)
            for j in range(4):
                #step
                data += pk('B', 1) # prio
                for h in range(8):
                    # pump
                    data += pk('B', h) # pump type
                    data += pk('<H', h) # open
                    data += pk('<H', h) # volume

        data += pk('<H', 0xd1b8)
        data += pk('B', 0x03)
         
        self.data = data   
        print "data len is"
        print len(data)
Esempio n. 30
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def pk_u64(nb, endianness='<'):
    return pk(endianness + 'Q', nb)
Esempio n. 31
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    def __init__(self, month=4, day=1, devId=0x09010009, washId=1):
        data = pk('B' ,0x02)
        data += pk('B', 0X02)
        data += pk('<H', 0x0036)
        data += pk('<I', devId)
        data += pk('<H', washId)
        data += pk('<I', 0x00000203)
        data += pk('<H', 0x0006)
        data += pk('B', 0x02)
        data += pk('B', 0x02)
        data += pk('<H', 0x07e1)
        data += pk('B', month)
        data += pk('B', day)
        data += pk('B', 0x10)
        data += pk('B', 0x39)
        data += pk('B', 0x32)
        data += pk('<H', 0x07e1)
        data += pk('B', month)
        data += pk('B', day)
        data += pk('B', 0x10)
        data += pk('B', 0x3a)
        data += pk('B', 0x0f)
        data += pk('<H', 0x0008)

        for i in range(8):
            data += pk('B', i)
            data += pk('<H', 0x0005*(i+1))

        data += pk('<H', 0xab14)
        data += pk('B', 0x03)
         
        self.data = data   
Esempio n. 32
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 def __init__(self, data):
     self.ftype = data[TYPE]
     self.tmpbuf = pk('<I', data[DEVID])