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mylar/lib/deluge_client/rencode.py

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"""
rencode -- Web safe object pickling/unpickling.
Public domain, Connelly Barnes 2006-2007.
The rencode module is a modified version of bencode from the
BitTorrent project. For complex, heterogeneous data structures with
many small elements, r-encodings take up significantly less space than
b-encodings:
>>> len(rencode.dumps({'a':0, 'b':[1,2], 'c':99}))
13
>>> len(bencode.bencode({'a':0, 'b':[1,2], 'c':99}))
26
The rencode format is not standardized, and may change with different
rencode module versions, so you should check that you are using the
same rencode version throughout your project.
"""
__version__ = '1.0.2'
__all__ = ['dumps', 'loads']
# Original bencode module by Petru Paler, et al.
#
# Modifications by Connelly Barnes:
#
# - Added support for floats (sent as 32-bit or 64-bit in network
# order), bools, None.
# - Allowed dict keys to be of any serializable type.
# - Lists/tuples are always decoded as tuples (thus, tuples can be
# used as dict keys).
# - Embedded extra information in the 'typecodes' to save some space.
# - Added a restriction on integer length, so that malicious hosts
# cannot pass us large integers which take a long time to decode.
#
# Licensed by Bram Cohen under the "MIT license":
#
# "Copyright (C) 2001-2002 Bram Cohen
#
# Permission is hereby granted, free of charge, to any person
# obtaining a copy of this software and associated documentation files
# (the "Software"), to deal in the Software without restriction,
# including without limitation the rights to use, copy, modify, merge,
# publish, distribute, sublicense, and/or sell copies of the Software,
# and to permit persons to whom the Software is furnished to do so,
# subject to the following conditions:
#
# The above copyright notice and this permission notice shall be
# included in all copies or substantial portions of the Software.
#
# The Software is provided "AS IS", without warranty of any kind,
# express or implied, including but not limited to the warranties of
# merchantability, fitness for a particular purpose and
# noninfringement. In no event shall the authors or copyright holders
# be liable for any claim, damages or other liability, whether in an
# action of contract, tort or otherwise, arising from, out of or in
# connection with the Software or the use or other dealings in the
# Software."
#
# (The rencode module is licensed under the above license as well).
#
import sys
py3 = False
if sys.version_info >= (3, 0):
py3 = True
long = int
unicode = str
def int2byte(c):
if py3:
return bytes([c])
else:
return chr(c)
import struct
from threading import Lock
# Default number of bits for serialized floats, either 32 or 64 (also a parameter for dumps()).
DEFAULT_FLOAT_BITS = 32
# Maximum length of integer when written as base 10 string.
MAX_INT_LENGTH = 64
# The bencode 'typecodes' such as i, d, etc have been extended and
# relocated on the base-256 character set.
CHR_LIST = int2byte(59)
CHR_DICT = int2byte(60)
CHR_INT = int2byte(61)
CHR_INT1 = int2byte(62)
CHR_INT2 = int2byte(63)
CHR_INT4 = int2byte(64)
CHR_INT8 = int2byte(65)
CHR_FLOAT32 = int2byte(66)
CHR_FLOAT64 = int2byte(44)
CHR_TRUE = int2byte(67)
CHR_FALSE = int2byte(68)
CHR_NONE = int2byte(69)
CHR_TERM = int2byte(127)
# Positive integers with value embedded in typecode.
INT_POS_FIXED_START = 0
INT_POS_FIXED_COUNT = 44
# Dictionaries with length embedded in typecode.
DICT_FIXED_START = 102
DICT_FIXED_COUNT = 25
# Negative integers with value embedded in typecode.
INT_NEG_FIXED_START = 70
INT_NEG_FIXED_COUNT = 32
# Strings with length embedded in typecode.
STR_FIXED_START = 128
STR_FIXED_COUNT = 64
# Lists with length embedded in typecode.
LIST_FIXED_START = STR_FIXED_START+STR_FIXED_COUNT
LIST_FIXED_COUNT = 64
# Whether strings should be decoded when loading
_decode_utf8 = False
def decode_int(x, f):
f += 1
newf = x.index(CHR_TERM, f)
if newf - f >= MAX_INT_LENGTH:
raise ValueError('overflow')
try:
n = int(x[f:newf])
except (OverflowError, ValueError):
n = long(x[f:newf])
if x[f:f+1] == '-':
if x[f + 1:f + 2] == '0':
raise ValueError
elif x[f:f+1] == '0' and newf != f+1:
raise ValueError
return (n, newf+1)
def decode_intb(x, f):
f += 1
return (struct.unpack('!b', x[f:f+1])[0], f+1)
def decode_inth(x, f):
f += 1
return (struct.unpack('!h', x[f:f+2])[0], f+2)
def decode_intl(x, f):
f += 1
return (struct.unpack('!l', x[f:f+4])[0], f+4)
def decode_intq(x, f):
f += 1
return (struct.unpack('!q', x[f:f+8])[0], f+8)
def decode_float32(x, f):
f += 1
n = struct.unpack('!f', x[f:f+4])[0]
return (n, f+4)
def decode_float64(x, f):
f += 1
n = struct.unpack('!d', x[f:f+8])[0]
return (n, f+8)
def decode_string(x, f):
colon = x.index(b':', f)
try:
n = int(x[f:colon])
except (OverflowError, ValueError):
n = long(x[f:colon])
if x[f] == '0' and colon != f+1:
raise ValueError
colon += 1
s = x[colon:colon+n]
if _decode_utf8:
s = s.decode('utf8')
return (s, colon+n)
def decode_list(x, f):
r, f = [], f+1
while x[f:f+1] != CHR_TERM:
v, f = decode_func[x[f:f+1]](x, f)
r.append(v)
return (tuple(r), f + 1)
def decode_dict(x, f):
r, f = {}, f+1
while x[f:f+1] != CHR_TERM:
k, f = decode_func[x[f:f+1]](x, f)
r[k], f = decode_func[x[f:f+1]](x, f)
return (r, f + 1)
def decode_true(x, f):
return (True, f+1)
def decode_false(x, f):
return (False, f+1)
def decode_none(x, f):
return (None, f+1)
decode_func = {}
decode_func[b'0'] = decode_string
decode_func[b'1'] = decode_string
decode_func[b'2'] = decode_string
decode_func[b'3'] = decode_string
decode_func[b'4'] = decode_string
decode_func[b'5'] = decode_string
decode_func[b'6'] = decode_string
decode_func[b'7'] = decode_string
decode_func[b'8'] = decode_string
decode_func[b'9'] = decode_string
decode_func[CHR_LIST ] = decode_list
decode_func[CHR_DICT ] = decode_dict
decode_func[CHR_INT ] = decode_int
decode_func[CHR_INT1 ] = decode_intb
decode_func[CHR_INT2 ] = decode_inth
decode_func[CHR_INT4 ] = decode_intl
decode_func[CHR_INT8 ] = decode_intq
decode_func[CHR_FLOAT32] = decode_float32
decode_func[CHR_FLOAT64] = decode_float64
decode_func[CHR_TRUE ] = decode_true
decode_func[CHR_FALSE ] = decode_false
decode_func[CHR_NONE ] = decode_none
def make_fixed_length_string_decoders():
def make_decoder(slen):
def f(x, f):
s = x[f+1:f+1+slen]
if _decode_utf8:
s = s.decode("utf8")
return (s, f+1+slen)
return f
for i in range(STR_FIXED_COUNT):
decode_func[int2byte(STR_FIXED_START+i)] = make_decoder(i)
make_fixed_length_string_decoders()
def make_fixed_length_list_decoders():
def make_decoder(slen):
def f(x, f):
r, f = [], f+1
for i in range(slen):
v, f = decode_func[x[f:f+1]](x, f)
r.append(v)
return (tuple(r), f)
return f
for i in range(LIST_FIXED_COUNT):
decode_func[int2byte(LIST_FIXED_START+i)] = make_decoder(i)
make_fixed_length_list_decoders()
def make_fixed_length_int_decoders():
def make_decoder(j):
def f(x, f):
return (j, f+1)
return f
for i in range(INT_POS_FIXED_COUNT):
decode_func[int2byte(INT_POS_FIXED_START+i)] = make_decoder(i)
for i in range(INT_NEG_FIXED_COUNT):
decode_func[int2byte(INT_NEG_FIXED_START+i)] = make_decoder(-1-i)
make_fixed_length_int_decoders()
def make_fixed_length_dict_decoders():
def make_decoder(slen):
def f(x, f):
r, f = {}, f+1
for j in range(slen):
k, f = decode_func[x[f:f+1]](x, f)
r[k], f = decode_func[x[f:f+1]](x, f)
return (r, f)
return f
for i in range(DICT_FIXED_COUNT):
decode_func[int2byte(DICT_FIXED_START+i)] = make_decoder(i)
make_fixed_length_dict_decoders()
def loads(x, decode_utf8=False):
global _decode_utf8
_decode_utf8 = decode_utf8
try:
r, l = decode_func[x[0:1]](x, 0)
except (IndexError, KeyError):
raise ValueError
if l != len(x):
raise ValueError
return r
def encode_int(x, r):
if 0 <= x < INT_POS_FIXED_COUNT:
r.append(int2byte(INT_POS_FIXED_START+x))
elif -INT_NEG_FIXED_COUNT <= x < 0:
r.append(int2byte(INT_NEG_FIXED_START-1-x))
elif -128 <= x < 128:
r.extend((CHR_INT1, struct.pack('!b', x)))
elif -32768 <= x < 32768:
r.extend((CHR_INT2, struct.pack('!h', x)))
elif -2147483648 <= x < 2147483648:
r.extend((CHR_INT4, struct.pack('!l', x)))
elif -9223372036854775808 <= x < 9223372036854775808:
r.extend((CHR_INT8, struct.pack('!q', x)))
else:
s = str(x)
if py3:
s = bytes(s, "ascii")
if len(s) >= MAX_INT_LENGTH:
raise ValueError('overflow')
r.extend((CHR_INT, s, CHR_TERM))
def encode_float32(x, r):
r.extend((CHR_FLOAT32, struct.pack('!f', x)))
def encode_float64(x, r):
r.extend((CHR_FLOAT64, struct.pack('!d', x)))
def encode_bool(x, r):
r.append({False: CHR_FALSE, True: CHR_TRUE}[bool(x)])
def encode_none(x, r):
r.append(CHR_NONE)
def encode_string(x, r):
if len(x) < STR_FIXED_COUNT:
r.extend((int2byte(STR_FIXED_START + len(x)), x))
else:
s = str(len(x))
if py3:
s = bytes(s, "ascii")
r.extend((s, b':', x))
def encode_unicode(x, r):
encode_string(x.encode("utf8"), r)
def encode_list(x, r):
if len(x) < LIST_FIXED_COUNT:
r.append(int2byte(LIST_FIXED_START + len(x)))
for i in x:
encode_func[type(i)](i, r)
else:
r.append(CHR_LIST)
for i in x:
encode_func[type(i)](i, r)
r.append(CHR_TERM)
def encode_dict(x,r):
if len(x) < DICT_FIXED_COUNT:
r.append(int2byte(DICT_FIXED_START + len(x)))
for k, v in x.items():
encode_func[type(k)](k, r)
encode_func[type(v)](v, r)
else:
r.append(CHR_DICT)
for k, v in x.items():
encode_func[type(k)](k, r)
encode_func[type(v)](v, r)
r.append(CHR_TERM)
encode_func = {}
encode_func[int] = encode_int
encode_func[long] = encode_int
encode_func[bytes] = encode_string
encode_func[list] = encode_list
encode_func[tuple] = encode_list
encode_func[dict] = encode_dict
encode_func[type(None)] = encode_none
encode_func[unicode] = encode_unicode
encode_func[bool] = encode_bool
lock = Lock()
def dumps(x, float_bits=DEFAULT_FLOAT_BITS):
"""
Dump data structure to str.
Here float_bits is either 32 or 64.
"""
lock.acquire()
try:
if float_bits == 32:
encode_func[float] = encode_float32
elif float_bits == 64:
encode_func[float] = encode_float64
else:
raise ValueError('Float bits (%d) is not 32 or 64' % float_bits)
r = []
encode_func[type(x)](x, r)
finally:
lock.release()
return b''.join(r)
def test():
f1 = struct.unpack('!f', struct.pack('!f', 25.5))[0]
f2 = struct.unpack('!f', struct.pack('!f', 29.3))[0]
f3 = struct.unpack('!f', struct.pack('!f', -0.6))[0]
L = (({b'a':15, b'bb':f1, b'ccc':f2, b'':(f3,(),False,True,b'')},(b'a',10**20),tuple(range(-100000,100000)),b'b'*31,b'b'*62,b'b'*64,2**30,2**33,2**62,2**64,2**30,2**33,2**62,2**64,False,False, True, -1, 2, 0),)
assert loads(dumps(L)) == L
d = dict(zip(range(-100000,100000),range(-100000,100000)))
d.update({b'a':20, 20:40, 40:41, f1:f2, f2:f3, f3:False, False:True, True:False})
L = (d, {}, {5:6}, {7:7,True:8}, {9:10, 22:39, 49:50, 44: b''})
assert loads(dumps(L)) == L
L = (b'', b'a'*10, b'a'*100, b'a'*1000, b'a'*10000, b'a'*100000, b'a'*1000000, b'a'*10000000)
assert loads(dumps(L)) == L
L = tuple([dict(zip(range(n),range(n))) for n in range(100)]) + (b'b',)
assert loads(dumps(L)) == L
L = tuple([dict(zip(range(n),range(-n,0))) for n in range(100)]) + (b'b',)
assert loads(dumps(L)) == L
L = tuple([tuple(range(n)) for n in range(100)]) + (b'b',)
assert loads(dumps(L)) == L
L = tuple([b'a'*n for n in range(1000)]) + (b'b',)
assert loads(dumps(L)) == L
L = tuple([b'a'*n for n in range(1000)]) + (None,True,None)
assert loads(dumps(L)) == L
assert loads(dumps(None)) == None
assert loads(dumps({None:None})) == {None:None}
assert 1e-10<abs(loads(dumps(1.1))-1.1)<1e-6
assert 1e-10<abs(loads(dumps(1.1,32))-1.1)<1e-6
assert abs(loads(dumps(1.1,64))-1.1)<1e-12
assert loads(dumps("Hello World!!"), decode_utf8=True)
try:
import psyco
psyco.bind(dumps)
psyco.bind(loads)
except ImportError:
pass
if __name__ == '__main__':
test()
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