# this is a standalone single-file merge of aplib compression and decompression # taken from my own library Kabopan http://code.google.com/p/kabopan/ # (no other clean-up or improvement) # Ange Albertini, BSD Licence, 2007-2011 # from kbp\comp\_lz77.py ################################################## def find_longest_match(s, sub): """returns the number of byte to look backward and the length of byte to copy)""" if sub == "": return 0, 0 limit = len(s) dic = s[:] l = 0 offset = 0 length = 0 first = 0 word = "" word += sub[l] pos = dic.rfind(word, 0, limit + 1) if pos == -1: return offset, length offset = limit - pos length = len(word) dic += sub[l] while l < len(sub) - 1: l += 1 word += sub[l] pos = dic.rfind(word, 0, limit + 1) if pos == -1: return offset, length offset = limit - pos length = len(word) dic += sub[l] return offset, length # from _misc.py ############################### def int2lebin(value, size): """ouputs value in binary, as little-endian""" result = "" for i in xrange(size): result = result + chr((value >> (8 * i)) & 0xFF ) return result def modifystring(s, sub, offset): """overwrites 'sub' at 'offset' of 's'""" return s[:offset] + sub + s[offset + len(sub):] def getbinlen(value): """return the bit length of an integer""" result = 0 if value == 0: return 1 while value != 0: value >>= 1 result += 1 return result # from kbp\_bits.py ################################# class _bits_compress(): """bit machine for variable-sized auto-reloading tag compression""" def __init__(self, tagsize): """tagsize is the number of bytes that takes the tag""" self.out = "" self.__tagsize = tagsize self.__tag = 0 self.__tagoffset = -1 self.__maxbit = (self.__tagsize * 8) - 1 self.__curbit = 0 self.__isfirsttag = True def getdata(self): """builds an output string of what's currently compressed: currently output bit + current tag content""" tagstr = int2lebin(self.__tag, self.__tagsize) return modifystring(self.out, tagstr, self.__tagoffset) def write_bit(self, value): """writes a bit, make space for the tag if necessary""" if self.__curbit != 0: self.__curbit -= 1 else: if self.__isfirsttag: self.__isfirsttag = False else: self.out = self.getdata() self.__tagoffset = len(self.out) self.out += "".join(["\x00"] * self.__tagsize) self.__curbit = self.__maxbit self.__tag = 0 if value: self.__tag |= (1 << self.__curbit) return def write_bitstring(self, s): """write a string of bits""" for c in s: self.write_bit(0 if c == "0" else 1) return def write_byte(self, b): """writes a char or a number""" assert len(b) == 1 if isinstance(b, str) else 0 <= b <= 255 self.out += b[0:1] if isinstance(b, str) else chr(b) return def write_fixednumber(self, value, nbbit): """write a value on a fixed range of bits""" for i in xrange(nbbit - 1, -1, -1): self.write_bit( (value >> i) & 1) return def write_variablenumber(self, value): assert value >= 2 length = getbinlen(value) - 2 # the highest bit is 1 self.write_bit(value & (1 << length)) for i in xrange(length - 1, -1, -1): self.write_bit(1) self.write_bit(value & (1 << i)) self.write_bit(0) return class _bits_decompress(): """bit machine for variable-sized auto-reloading tag decompression""" def __init__(self, data, tagsize): self.__curbit = 0 self.__offset = 0 self.__tag = None self.__tagsize = tagsize self.__in = data self.out = "" def getoffset(self): """return the current byte offset""" return self.__offset # def getdata(self): # return self.__lzdata def read_bit(self): """read next bit from the stream, reloads the tag if necessary""" if self.__curbit != 0: self.__curbit -= 1 else: self.__curbit = (self.__tagsize * 8) - 1 self.__tag = ord(self.read_byte()) for i in xrange(self.__tagsize - 1): self.__tag += ord(self.read_byte()) << (8 * (i + 1)) bit = (self.__tag >> ((self.__tagsize * 8) - 1)) & 0x01 self.__tag <<= 1 return bit def is_end(self): return self.__offset == len(self.__in) and self.__curbit == 1 def read_byte(self): """read next byte from the stream""" if type(self.__in) == str: result = self.__in[self.__offset] elif type(self.__in) == file: result = self.__in.read(1) self.__offset += 1 return result def read_fixednumber(self, nbbit, init=0): """reads a fixed bit-length number""" result = init for i in xrange(nbbit): result = (result << 1) + self.read_bit() return result def read_variablenumber(self): """return a variable bit-length number x, x >= 2 reads a bit until the next bit in the pair is not set""" result = 1 result = (result << 1) + self.read_bit() while self.read_bit(): result = (result << 1) + self.read_bit() return result def read_setbits(self, max_, set_=1): """read bits as long as their set or a maximum is reached""" result = 0 while result < max_ and self.read_bit() == set_: result += 1 return result def back_copy(self, offset, length=1): for i in xrange(length): self.out += self.out[-offset] return def read_literal(self, value=None): if value is None: self.out += self.read_byte() else: self.out += value return False # from kbp\comp\aplib.py ################################################### """ aPLib, LZSS based lossless compression algorithm Jorgen Ibsen U{http://www.ibsensoftware.com} """ def lengthdelta(offset): if offset < 0x80 or 0x7D00 <= offset: return 2 elif 0x500 <= offset: return 1 return 0 class compress(_bits_compress): """ aplib compression is based on lz77 """ def __init__(self, data, length=None): _bits_compress.__init__(self, 1) self.__in = data self.__length = length if length is not None else len(data) self.__offset = 0 self.__lastoffset = 0 self.__pair = True return def __literal(self, marker=True): if marker: self.write_bit(0) self.write_byte(self.__in[self.__offset]) self.__offset += 1 self.__pair = True return def __block(self, offset, length): assert offset >= 2 self.write_bitstring("10") # if the last operations were literal or single byte # and the offset is unchanged since the last block copy # we can just store a 'null' offset and the length if self.__pair and self.__lastoffset == offset: self.write_variablenumber(2) # 2- self.write_variablenumber(length) else: high = (offset >> 8) + 2 if self.__pair: high += 1 self.write_variablenumber(high) low = offset & 0xFF self.write_byte(low) self.write_variablenumber(length - lengthdelta(offset)) self.__offset += length self.__lastoffset = offset self.__pair = False return def __shortblock(self, offset, length): assert 2 <= length <= 3 assert 0 < offset <= 127 self.write_bitstring("110") b = (offset << 1 ) + (length - 2) self.write_byte(b) self.__offset += length self.__lastoffset = offset self.__pair = False return def __singlebyte(self, offset): assert 0 <= offset < 16 self.write_bitstring("111") self.write_fixednumber(offset, 4) self.__offset += 1 self.__pair = True return def __end(self): self.write_bitstring("110") self.write_byte(chr(0)) return def do(self): self.__literal(False) while self.__offset < self.__length: offset, length = find_longest_match(self.__in[:self.__offset], self.__in[self.__offset:]) if length == 0: c = self.__in[self.__offset] if c == "\x00": self.__singlebyte(0) else: self.__literal() elif length == 1 and 0 <= offset < 16: self.__singlebyte(offset) elif 2 <= length <= 3 and 0 < offset <= 127: self.__shortblock(offset, length) elif 3 <= length and 2 <= offset: self.__block(offset, length) else: self.__literal() #raise ValueError("no parsing found", offset, length) self.__end() return self.getdata() class decompress(_bits_decompress): def __init__(self, data): _bits_decompress.__init__(self, data, tagsize=1) self.__pair = True # paired sequence self.__lastoffset = 0 self.__functions = [ self.__literal, self.__block, self.__shortblock, self.__singlebyte] return def __literal(self): self.read_literal() self.__pair = True return False def __block(self): b = self.read_variablenumber() # 2- if b == 2 and self.__pair : # reuse the same offset offset = self.__lastoffset length = self.read_variablenumber() # 2- else: high = b - 2 # 0- if self.__pair: high -= 1 offset = (high << 8) + ord(self.read_byte()) length = self.read_variablenumber() # 2- length += lengthdelta(offset) self.__lastoffset = offset self.back_copy(offset, length) self.__pair = False return False def __shortblock(self): b = ord(self.read_byte()) if b <= 1: # likely 0 return True length = 2 + (b & 0x01) # 2-3 offset = b >> 1 # 1-127 self.back_copy(offset, length) self.__lastoffset = offset self.__pair = False return False def __singlebyte(self): offset = self.read_fixednumber(4) # 0-15 if offset: self.back_copy(offset) else: self.read_literal('\x00') self.__pair = True return False def do(self): """returns decompressed buffer and consumed bytes counter""" self.read_literal() while True: if self.__functions[self.read_setbits(3)](): break return self.out, self.getoffset() if __name__ == "__main__": # from kbp\test\aplib_test.py ###################################################################### assert decompress(compress("a").do()).do() == ("a", 3) assert decompress(compress("ababababababab").do()).do() == ('ababababababab', 9) assert decompress(compress("aaaaaaaaaaaaaacaaaaaa").do()).do() == ('aaaaaaaaaaaaaacaaaaaa', 11)