add python3 tnetstring implementation

This commit is contained in:
Maximilian Hils 2016-07-05 17:27:20 -07:00
parent 9c873d63f4
commit e6e839d56d
6 changed files with 746 additions and 372 deletions

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# imported from the tnetstring project: https://github.com/rfk/tnetstring
#
# Copyright (c) 2011 Ryan Kelly
#
# 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.
"""
tnetstring: data serialization using typed netstrings
======================================================
This is a data serialization library. It's a lot like JSON but it uses a
new syntax called "typed netstrings" that Zed has proposed for use in the
Mongrel2 webserver. It's designed to be simpler and easier to implement
than JSON, with a happy consequence of also being faster in many cases.
An ordinary netstring is a blob of data prefixed with its length and postfixed
with a sanity-checking comma. The string "hello world" encodes like this::
11:hello world,
Typed netstrings add other datatypes by replacing the comma with a type tag.
Here's the integer 12345 encoded as a tnetstring::
5:12345#
And here's the list [12345,True,0] which mixes integers and bools::
19:5:12345#4:true!1:0#]
Simple enough? This module gives you the following functions:
:dump: dump an object as a tnetstring to a file
:dumps: dump an object as a tnetstring to a string
:load: load a tnetstring-encoded object from a file
:loads: load a tnetstring-encoded object from a string
:pop: pop a tnetstring-encoded object from the front of a string
Note that since parsing a tnetstring requires reading all the data into memory
at once, there's no efficiency gain from using the file-based versions of these
functions. They're only here so you can use load() to read precisely one
item from a file or socket without consuming any extra data.
By default tnetstrings work only with byte strings, not unicode. If you want
unicode strings then pass an optional encoding to the various functions,
like so::
>>> print(repr(tnetstring.loads("2:\\xce\\xb1,")))
'\\xce\\xb1'
>>>
>>> print(repr(tnetstring.loads("2:\\xce\\xb1,","utf8")))
u'\u03b1'
"""
from collections import deque
import six
__ver_major__ = 0
__ver_minor__ = 2
__ver_patch__ = 0
__ver_sub__ = ""
__version__ = "%d.%d.%d%s" % (
__ver_major__, __ver_minor__, __ver_patch__, __ver_sub__)
def dumps(value):
"""
This function dumps a python object as a tnetstring.
"""
# This uses a deque to collect output fragments in reverse order,
# then joins them together at the end. It's measurably faster
# than creating all the intermediate strings.
# If you're reading this to get a handle on the tnetstring format,
# consider the _gdumps() function instead; it's a standard top-down
# generator that's simpler to understand but much less efficient.
q = deque()
_rdumpq(q, 0, value)
return b''.join(q)
def dump(value, file_handle):
"""
This function dumps a python object as a tnetstring and
writes it to the given file.
"""
file_handle.write(dumps(value))
def _rdumpq(q, size, value):
"""
Dump value as a tnetstring, to a deque instance, last chunks first.
This function generates the tnetstring representation of the given value,
pushing chunks of the output onto the given deque instance. It pushes
the last chunk first, then recursively generates more chunks.
When passed in the current size of the string in the queue, it will return
the new size of the string in the queue.
Operating last-chunk-first makes it easy to calculate the size written
for recursive structures without having to build their representation as
a string. This is measurably faster than generating the intermediate
strings, especially on deeply nested structures.
"""
write = q.appendleft
if value is None:
write(b'0:~')
return size + 3
elif value is True:
write(b'4:true!')
return size + 7
elif value is False:
write(b'5:false!')
return size + 8
elif isinstance(value, six.integer_types):
data = str(value).encode()
ldata = len(data)
span = str(ldata).encode()
write(b'#')
write(data)
write(b':')
write(span)
return size + 2 + len(span) + ldata
elif isinstance(value, float):
# Use repr() for float rather than str().
# It round-trips more accurately.
# Probably unnecessary in later python versions that
# use David Gay's ftoa routines.
data = repr(value).encode()
ldata = len(data)
span = str(ldata).encode()
write(b'^')
write(data)
write(b':')
write(span)
return size + 2 + len(span) + ldata
elif isinstance(value, bytes):
lvalue = len(value)
span = str(lvalue).encode()
write(b',')
write(value)
write(b':')
write(span)
return size + 2 + len(span) + lvalue
elif isinstance(value, (list, tuple)):
write(b']')
init_size = size = size + 1
for item in reversed(value):
size = _rdumpq(q, size, item)
span = str(size - init_size).encode()
write(b':')
write(span)
return size + 1 + len(span)
elif isinstance(value, dict):
write(b'}')
init_size = size = size + 1
for (k, v) in value.items():
size = _rdumpq(q, size, v)
size = _rdumpq(q, size, k)
span = str(size - init_size).encode()
write(b':')
write(span)
return size + 1 + len(span)
else:
raise ValueError("unserializable object: {} ({})".format(value, type(value)))
def _gdumps(value):
"""
Generate fragments of value dumped as a tnetstring.
This is the naive dumping algorithm, implemented as a generator so that
it's easy to pass to "".join() without building a new list.
This is mainly here for comparison purposes; the _rdumpq version is
measurably faster as it doesn't have to build intermediate strins.
"""
if value is None:
yield b'0:~'
elif value is True:
yield b'4:true!'
elif value is False:
yield b'5:false!'
elif isinstance(value, six.integer_types):
data = str(value).encode()
yield str(len(data)).encode()
yield b':'
yield data
yield b'#'
elif isinstance(value, float):
data = repr(value).encode()
yield str(len(data)).encode()
yield b':'
yield data
yield b'^'
elif isinstance(value, bytes):
yield str(len(value)).encode()
yield b':'
yield value
yield b','
elif isinstance(value, (list, tuple)):
sub = []
for item in value:
sub.extend(_gdumps(item))
sub = b''.join(sub)
yield str(len(sub)).encode()
yield b':'
yield sub
yield b']'
elif isinstance(value, (dict,)):
sub = []
for (k, v) in value.items():
sub.extend(_gdumps(k))
sub.extend(_gdumps(v))
sub = b''.join(sub)
yield str(len(sub)).encode()
yield b':'
yield sub
yield b'}'
else:
raise ValueError("unserializable object")
def loads(string):
"""
This function parses a tnetstring into a python object.
"""
# No point duplicating effort here. In the C-extension version,
# loads() is measurably faster then pop() since it can avoid
# the overhead of building a second string.
return pop(string)[0]
def load(file_handle):
"""load(file) -> object
This function reads a tnetstring from a file and parses it into a
python object. The file must support the read() method, and this
function promises not to read more data than necessary.
"""
# Read the length prefix one char at a time.
# Note that the netstring spec explicitly forbids padding zeros.
c = file_handle.read(1)
if not c.isdigit():
raise ValueError("not a tnetstring: missing or invalid length prefix")
datalen = ord(c) - ord('0')
c = file_handle.read(1)
if datalen != 0:
while c.isdigit():
datalen = (10 * datalen) + (ord(c) - ord('0'))
if datalen > 999999999:
errmsg = "not a tnetstring: absurdly large length prefix"
raise ValueError(errmsg)
c = file_handle.read(1)
if c != b':':
raise ValueError("not a tnetstring: missing or invalid length prefix")
# Now we can read and parse the payload.
# This repeats the dispatch logic of pop() so we can avoid
# re-constructing the outermost tnetstring.
data = file_handle.read(datalen)
if len(data) != datalen:
raise ValueError("not a tnetstring: length prefix too big")
tns_type = file_handle.read(1)
if tns_type == b',':
return data
if tns_type == b'#':
try:
return int(data)
except ValueError:
raise ValueError("not a tnetstring: invalid integer literal")
if tns_type == b'^':
try:
return float(data)
except ValueError:
raise ValueError("not a tnetstring: invalid float literal")
if tns_type == b'!':
if data == b'true':
return True
elif data == b'false':
return False
else:
raise ValueError("not a tnetstring: invalid boolean literal")
if tns_type == b'~':
if data:
raise ValueError("not a tnetstring: invalid null literal")
return None
if tns_type == b']':
l = []
while data:
item, data = pop(data)
l.append(item)
return l
if tns_type == b'}':
d = {}
while data:
key, data = pop(data)
val, data = pop(data)
d[key] = val
return d
raise ValueError("unknown type tag")
def pop(string):
"""pop(string,encoding='utf_8') -> (object, remain)
This function parses a tnetstring into a python object.
It returns a tuple giving the parsed object and a string
containing any unparsed data from the end of the string.
"""
# Parse out data length, type and remaining string.
try:
dlen, rest = string.split(b':', 1)
dlen = int(dlen)
except ValueError:
raise ValueError("not a tnetstring: missing or invalid length prefix: {}".format(string))
try:
data, tns_type, remain = rest[:dlen], rest[dlen:dlen + 1], rest[dlen + 1:]
except IndexError:
# This fires if len(rest) < dlen, meaning we don't need
# to further validate that data is the right length.
raise ValueError("not a tnetstring: invalid length prefix: {}".format(dlen))
# Parse the data based on the type tag.
if tns_type == b',':
return data, remain
if tns_type == b'#':
try:
return int(data), remain
except ValueError:
raise ValueError("not a tnetstring: invalid integer literal: {}".format(data))
if tns_type == b'^':
try:
return float(data), remain
except ValueError:
raise ValueError("not a tnetstring: invalid float literal: {}".format(data))
if tns_type == b'!':
if data == b'true':
return True, remain
elif data == b'false':
return False, remain
else:
raise ValueError("not a tnetstring: invalid boolean literal: {}".format(data))
if tns_type == b'~':
if data:
raise ValueError("not a tnetstring: invalid null literal")
return None, remain
if tns_type == b']':
l = []
while data:
item, data = pop(data)
l.append(item)
return (l, remain)
if tns_type == b'}':
d = {}
while data:
key, data = pop(data)
val, data = pop(data)
d[key] = val
return d, remain
raise ValueError("unknown type tag: {}".format(tns_type))

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"""
tnetstring: data serialization using typed netstrings
======================================================
This is a custom Python 3 implementation of tnetstrings.
Compared to other implementations, the main difference
is the conversion of dictionary keys to str.
An ordinary tnetstring is a blob of data prefixed with its length and postfixed
with its type. Here are some examples:
>>> tnetstring.dumps("hello world")
11:hello world,
>>> tnetstring.dumps(12345)
5:12345#
>>> tnetstring.dumps([12345, True, 0])
19:5:12345#4:true!1:0#]
This module gives you the following functions:
:dump: dump an object as a tnetstring to a file
:dumps: dump an object as a tnetstring to a string
:load: load a tnetstring-encoded object from a file
:loads: load a tnetstring-encoded object from a string
Note that since parsing a tnetstring requires reading all the data into memory
at once, there's no efficiency gain from using the file-based versions of these
functions. They're only here so you can use load() to read precisely one
item from a file or socket without consuming any extra data.
The tnetstrings specification explicitly states that strings are binary blobs
and forbids the use of unicode at the protocol level.
**This implementation decodes dictionary keys as surrogate-escaped ASCII**,
all other strings are returned as plain bytes.
:Copyright: (c) 2012-2013 by Ryan Kelly <ryan@rfk.id.au>.
:Copyright: (c) 2014 by Carlo Pires <carlopires@gmail.com>.
:Copyright: (c) 2016 by Maximilian Hils <tnetstring3@maximilianhils.com>.
:License: MIT
"""
import collections
from typing import io, Union, Tuple
TSerializable = Union[None, bool, int, float, bytes, list, tuple, dict]
def dumps(value: TSerializable) -> bytes:
"""
This function dumps a python object as a tnetstring.
"""
# This uses a deque to collect output fragments in reverse order,
# then joins them together at the end. It's measurably faster
# than creating all the intermediate strings.
q = collections.deque()
_rdumpq(q, 0, value)
return b''.join(q)
def dump(value: TSerializable, file_handle: io.BinaryIO) -> None:
"""
This function dumps a python object as a tnetstring and
writes it to the given file.
"""
file_handle.write(dumps(value))
def _rdumpq(q: collections.deque, size: int, value: TSerializable) -> int:
"""
Dump value as a tnetstring, to a deque instance, last chunks first.
This function generates the tnetstring representation of the given value,
pushing chunks of the output onto the given deque instance. It pushes
the last chunk first, then recursively generates more chunks.
When passed in the current size of the string in the queue, it will return
the new size of the string in the queue.
Operating last-chunk-first makes it easy to calculate the size written
for recursive structures without having to build their representation as
a string. This is measurably faster than generating the intermediate
strings, especially on deeply nested structures.
"""
write = q.appendleft
if value is None:
write(b'0:~')
return size + 3
elif value is True:
write(b'4:true!')
return size + 7
elif value is False:
write(b'5:false!')
return size + 8
elif isinstance(value, int):
data = str(value).encode()
ldata = len(data)
span = str(ldata).encode()
write(b'%s:%s#' % (span, data))
return size + 2 + len(span) + ldata
elif isinstance(value, float):
# Use repr() for float rather than str().
# It round-trips more accurately.
# Probably unnecessary in later python versions that
# use David Gay's ftoa routines.
data = repr(value).encode()
ldata = len(data)
span = str(ldata).encode()
write(b'%s:%s^' % (span, data))
return size + 2 + len(span) + ldata
elif isinstance(value, bytes):
lvalue = len(value)
span = str(lvalue).encode()
write(b'%s:%s,' % (span, value))
return size + 2 + len(span) + lvalue
elif isinstance(value, (list, tuple)):
write(b']')
init_size = size = size + 1
for item in reversed(value):
size = _rdumpq(q, size, item)
span = str(size - init_size).encode()
write(b':')
write(span)
return size + 1 + len(span)
elif isinstance(value, dict):
write(b'}')
init_size = size = size + 1
for (k, v) in value.items():
size = _rdumpq(q, size, v)
size = _rdumpq(q, size, k)
span = str(size - init_size).encode()
write(b':')
write(span)
return size + 1 + len(span)
else:
raise ValueError("unserializable object: {} ({})".format(value, type(value)))
def loads(string: bytes) -> TSerializable:
"""
This function parses a tnetstring into a python object.
"""
return pop(string)[0]
def load(file_handle: io.BinaryIO) -> TSerializable:
"""load(file) -> object
This function reads a tnetstring from a file and parses it into a
python object. The file must support the read() method, and this
function promises not to read more data than necessary.
"""
# Read the length prefix one char at a time.
# Note that the netstring spec explicitly forbids padding zeros.
c = file_handle.read(1)
data_length = b""
while ord(b'0') <= ord(c) <= ord(b'9'):
data_length += c
if len(data_length) > 9:
raise ValueError("not a tnetstring: absurdly large length prefix")
c = file_handle.read(1)
if c != b":":
raise ValueError("not a tnetstring: missing or invalid length prefix")
data = file_handle.read(int(data_length))
data_type = file_handle.read(1)[0]
return parse(data_type, data)
def parse(data_type: int, data: bytes) -> TSerializable:
if data_type == ord(b','):
return data
if data_type == ord(b'#'):
try:
return int(data)
except ValueError:
raise ValueError("not a tnetstring: invalid integer literal: {}".format(data))
if data_type == ord(b'^'):
try:
return float(data)
except ValueError:
raise ValueError("not a tnetstring: invalid float literal: {}".format(data))
if data_type == ord(b'!'):
if data == b'true':
return True
elif data == b'false':
return False
else:
raise ValueError("not a tnetstring: invalid boolean literal: {}".format(data))
if data_type == ord(b'~'):
if data:
raise ValueError("not a tnetstring: invalid null literal")
return None
if data_type == ord(b']'):
l = []
while data:
item, data = pop(data)
l.append(item)
return l
if data_type == ord(b'}'):
d = {}
while data:
key, data = pop(data)
val, data = pop(data)
d[key] = val
return d
raise ValueError("unknown type tag: {}".format(data_type))
def pop(data: bytes) -> Tuple[TSerializable, bytes]:
"""
This function parses a tnetstring into a python object.
It returns a tuple giving the parsed object and a string
containing any unparsed data from the end of the string.
"""
# Parse out data length, type and remaining string.
try:
length, data = data.split(b':', 1)
length = int(length)
except ValueError:
raise ValueError("not a tnetstring: missing or invalid length prefix: {}".format(data))
try:
data, data_type, remain = data[:length], data[length], data[length + 1:]
except IndexError:
# This fires if len(data) < dlen, meaning we don't need
# to further validate that data is the right length.
raise ValueError("not a tnetstring: invalid length prefix: {}".format(length))
# Parse the data based on the type tag.
return parse(data_type, data), remain
__all__ = ["dump", "dumps", "load", "loads"]

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import unittest
import random
import math
import io
from . import tnetstring
import struct
MAXINT = 2 ** (struct.Struct('i').size * 8 - 1) - 1
FORMAT_EXAMPLES = {
b'0:}': {},
b'0:]': [],
b'51:5:hello,39:11:12345678901#4:this,4:true!0:~4:\x00\x00\x00\x00,]}':
{b'hello': [12345678901, b'this', True, None, b'\x00\x00\x00\x00']},
b'5:12345#': 12345,
b'12:this is cool,': b'this is cool',
b'0:,': b'',
b'0:~': None,
b'4:true!': True,
b'5:false!': False,
b'10:\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00,': b'\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00',
b'24:5:12345#5:67890#5:xxxxx,]': [12345, 67890, b'xxxxx'],
b'18:3:0.1^3:0.2^3:0.3^]': [0.1, 0.2, 0.3],
b'243:238:233:228:223:218:213:208:203:198:193:188:183:178:173:168:163:158:153:148:143:138:133:128:123:118:113:108:103:99:95:91:87:83:79:75:71:67:63:59:55:51:47:43:39:35:31:27:23:19:15:11:hello-there,]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]': [[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[[b'hello-there']]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]
}
def get_random_object(random=random, depth=0):
"""Generate a random serializable object."""
# The probability of generating a scalar value increases as the depth increase.
# This ensures that we bottom out eventually.
if random.randint(depth,10) <= 4:
what = random.randint(0,1)
if what == 0:
n = random.randint(0,10)
l = []
for _ in range(n):
l.append(get_random_object(random,depth+1))
return l
if what == 1:
n = random.randint(0,10)
d = {}
for _ in range(n):
n = random.randint(0,100)
k = bytes([random.randint(32,126) for _ in range(n)])
d[k] = get_random_object(random,depth+1)
return d
else:
what = random.randint(0,4)
if what == 0:
return None
if what == 1:
return True
if what == 2:
return False
if what == 3:
if random.randint(0,1) == 0:
return random.randint(0,MAXINT)
else:
return -1 * random.randint(0,MAXINT)
n = random.randint(0,100)
return bytes([random.randint(32,126) for _ in range(n)])
class Test_Format(unittest.TestCase):
def test_roundtrip_format_examples(self):
for data, expect in FORMAT_EXAMPLES.items():
self.assertEqual(expect,tnetstring.loads(data))
self.assertEqual(expect,tnetstring.loads(tnetstring.dumps(expect)))
self.assertEqual((expect,b''),tnetstring.pop(data))
def test_roundtrip_format_random(self):
for _ in range(500):
v = get_random_object()
self.assertEqual(v,tnetstring.loads(tnetstring.dumps(v)))
self.assertEqual((v,b""),tnetstring.pop(tnetstring.dumps(v)))
def test_unicode_handling(self):
with self.assertRaises(ValueError):
tnetstring.dumps("hello")
self.assertEqual(tnetstring.dumps("hello".encode()),b"5:hello,")
self.assertEqual(type(tnetstring.loads(b"5:hello,")),bytes)
def test_roundtrip_format_unicode(self):
for _ in range(500):
v = get_random_object()
self.assertEqual(v,tnetstring.loads(tnetstring.dumps(v)))
self.assertEqual((v,b''),tnetstring.pop(tnetstring.dumps(v)))
def test_roundtrip_big_integer(self):
i1 = math.factorial(30000)
s = tnetstring.dumps(i1)
i2 = tnetstring.loads(s)
self.assertEqual(i1, i2)
class Test_FileLoading(unittest.TestCase):
def test_roundtrip_file_examples(self):
for data, expect in FORMAT_EXAMPLES.items():
s = io.BytesIO()
s.write(data)
s.write(b'OK')
s.seek(0)
self.assertEqual(expect,tnetstring.load(s))
self.assertEqual(b'OK',s.read())
s = io.BytesIO()
tnetstring.dump(expect,s)
s.write(b'OK')
s.seek(0)
self.assertEqual(expect,tnetstring.load(s))
self.assertEqual(b'OK',s.read())
def test_roundtrip_file_random(self):
for _ in range(500):
v = get_random_object()
s = io.BytesIO()
tnetstring.dump(v,s)
s.write(b'OK')
s.seek(0)
self.assertEqual(v,tnetstring.load(s))
self.assertEqual(b'OK',s.read())
def test_error_on_absurd_lengths(self):
s = io.BytesIO()
s.write(b'1000000000:pwned!,')
s.seek(0)
with self.assertRaises(ValueError):
tnetstring.load(s)
self.assertEqual(s.read(1),b':')
def suite():
loader = unittest.TestLoader()
suite = unittest.TestSuite()
suite.addTest(loader.loadTestsFromTestCase(Test_Format))
suite.addTest(loader.loadTestsFromTestCase(Test_FileLoading))
return suite

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# imported from the tnetstring project: https://github.com/rfk/tnetstring
#
# Copyright (c) 2011 Ryan Kelly
#
# 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.
"""
tnetstring: data serialization using typed netstrings
======================================================
This is a data serialization library. It's a lot like JSON but it uses a
new syntax called "typed netstrings" that Zed has proposed for use in the
Mongrel2 webserver. It's designed to be simpler and easier to implement
than JSON, with a happy consequence of also being faster in many cases.
An ordinary netstring is a blob of data prefixed with its length and postfixed
with a sanity-checking comma. The string "hello world" encodes like this::
11:hello world,
Typed netstrings add other datatypes by replacing the comma with a type tag.
Here's the integer 12345 encoded as a tnetstring::
5:12345#
And here's the list [12345,True,0] which mixes integers and bools::
19:5:12345#4:true!1:0#]
Simple enough? This module gives you the following functions:
:dump: dump an object as a tnetstring to a file
:dumps: dump an object as a tnetstring to a string
:load: load a tnetstring-encoded object from a file
:loads: load a tnetstring-encoded object from a string
:pop: pop a tnetstring-encoded object from the front of a string
Note that since parsing a tnetstring requires reading all the data into memory
at once, there's no efficiency gain from using the file-based versions of these
functions. They're only here so you can use load() to read precisely one
item from a file or socket without consuming any extra data.
By default tnetstrings work only with byte strings, not unicode. If you want
unicode strings then pass an optional encoding to the various functions,
like so::
>>> print(repr(tnetstring.loads("2:\\xce\\xb1,")))
'\\xce\\xb1'
>>>
>>> print(repr(tnetstring.loads("2:\\xce\\xb1,","utf8")))
u'\u03b1'
"""
from collections import deque
import six import six
__ver_major__ = 0 if six.PY2:
__ver_minor__ = 2 from .py2.tnetstring import load, loads, dump, dumps
__ver_patch__ = 0
__ver_sub__ = ""
__version__ = "%d.%d.%d%s" % (
__ver_major__, __ver_minor__, __ver_patch__, __ver_sub__)
def dumps(value):
"""
This function dumps a python object as a tnetstring.
"""
# This uses a deque to collect output fragments in reverse order,
# then joins them together at the end. It's measurably faster
# than creating all the intermediate strings.
# If you're reading this to get a handle on the tnetstring format,
# consider the _gdumps() function instead; it's a standard top-down
# generator that's simpler to understand but much less efficient.
q = deque()
_rdumpq(q, 0, value)
return b''.join(q)
def dump(value, file_handle):
"""
This function dumps a python object as a tnetstring and
writes it to the given file.
"""
file_handle.write(dumps(value))
def _rdumpq(q, size, value):
"""
Dump value as a tnetstring, to a deque instance, last chunks first.
This function generates the tnetstring representation of the given value,
pushing chunks of the output onto the given deque instance. It pushes
the last chunk first, then recursively generates more chunks.
When passed in the current size of the string in the queue, it will return
the new size of the string in the queue.
Operating last-chunk-first makes it easy to calculate the size written
for recursive structures without having to build their representation as
a string. This is measurably faster than generating the intermediate
strings, especially on deeply nested structures.
"""
write = q.appendleft
if value is None:
write(b'0:~')
return size + 3
elif value is True:
write(b'4:true!')
return size + 7
elif value is False:
write(b'5:false!')
return size + 8
elif isinstance(value, six.integer_types):
data = str(value).encode()
ldata = len(data)
span = str(ldata).encode()
write(b'#')
write(data)
write(b':')
write(span)
return size + 2 + len(span) + ldata
elif isinstance(value, float):
# Use repr() for float rather than str().
# It round-trips more accurately.
# Probably unnecessary in later python versions that
# use David Gay's ftoa routines.
data = repr(value).encode()
ldata = len(data)
span = str(ldata).encode()
write(b'^')
write(data)
write(b':')
write(span)
return size + 2 + len(span) + ldata
elif isinstance(value, bytes):
lvalue = len(value)
span = str(lvalue).encode()
write(b',')
write(value)
write(b':')
write(span)
return size + 2 + len(span) + lvalue
elif isinstance(value, (list, tuple)):
write(b']')
init_size = size = size + 1
for item in reversed(value):
size = _rdumpq(q, size, item)
span = str(size - init_size).encode()
write(b':')
write(span)
return size + 1 + len(span)
elif isinstance(value, dict):
write(b'}')
init_size = size = size + 1
for (k, v) in value.items():
size = _rdumpq(q, size, v)
size = _rdumpq(q, size, k)
span = str(size - init_size).encode()
write(b':')
write(span)
return size + 1 + len(span)
else: else:
raise ValueError("unserializable object: {} ({})".format(value, type(value))) from .py3.tnetstring import load, loads, dump, dumps
__all__ = ["load", "loads", "dump", "dumps"]
def _gdumps(value):
"""
Generate fragments of value dumped as a tnetstring.
This is the naive dumping algorithm, implemented as a generator so that
it's easy to pass to "".join() without building a new list.
This is mainly here for comparison purposes; the _rdumpq version is
measurably faster as it doesn't have to build intermediate strins.
"""
if value is None:
yield b'0:~'
elif value is True:
yield b'4:true!'
elif value is False:
yield b'5:false!'
elif isinstance(value, six.integer_types):
data = str(value).encode()
yield str(len(data)).encode()
yield b':'
yield data
yield b'#'
elif isinstance(value, float):
data = repr(value).encode()
yield str(len(data)).encode()
yield b':'
yield data
yield b'^'
elif isinstance(value, bytes):
yield str(len(value)).encode()
yield b':'
yield value
yield b','
elif isinstance(value, (list, tuple)):
sub = []
for item in value:
sub.extend(_gdumps(item))
sub = b''.join(sub)
yield str(len(sub)).encode()
yield b':'
yield sub
yield b']'
elif isinstance(value, (dict,)):
sub = []
for (k, v) in value.items():
sub.extend(_gdumps(k))
sub.extend(_gdumps(v))
sub = b''.join(sub)
yield str(len(sub)).encode()
yield b':'
yield sub
yield b'}'
else:
raise ValueError("unserializable object")
def loads(string):
"""
This function parses a tnetstring into a python object.
"""
# No point duplicating effort here. In the C-extension version,
# loads() is measurably faster then pop() since it can avoid
# the overhead of building a second string.
return pop(string)[0]
def load(file_handle):
"""load(file) -> object
This function reads a tnetstring from a file and parses it into a
python object. The file must support the read() method, and this
function promises not to read more data than necessary.
"""
# Read the length prefix one char at a time.
# Note that the netstring spec explicitly forbids padding zeros.
c = file_handle.read(1)
if not c.isdigit():
raise ValueError("not a tnetstring: missing or invalid length prefix")
datalen = ord(c) - ord('0')
c = file_handle.read(1)
if datalen != 0:
while c.isdigit():
datalen = (10 * datalen) + (ord(c) - ord('0'))
if datalen > 999999999:
errmsg = "not a tnetstring: absurdly large length prefix"
raise ValueError(errmsg)
c = file_handle.read(1)
if c != b':':
raise ValueError("not a tnetstring: missing or invalid length prefix")
# Now we can read and parse the payload.
# This repeats the dispatch logic of pop() so we can avoid
# re-constructing the outermost tnetstring.
data = file_handle.read(datalen)
if len(data) != datalen:
raise ValueError("not a tnetstring: length prefix too big")
tns_type = file_handle.read(1)
if tns_type == b',':
return data
if tns_type == b'#':
try:
return int(data)
except ValueError:
raise ValueError("not a tnetstring: invalid integer literal")
if tns_type == b'^':
try:
return float(data)
except ValueError:
raise ValueError("not a tnetstring: invalid float literal")
if tns_type == b'!':
if data == b'true':
return True
elif data == b'false':
return False
else:
raise ValueError("not a tnetstring: invalid boolean literal")
if tns_type == b'~':
if data:
raise ValueError("not a tnetstring: invalid null literal")
return None
if tns_type == b']':
l = []
while data:
item, data = pop(data)
l.append(item)
return l
if tns_type == b'}':
d = {}
while data:
key, data = pop(data)
val, data = pop(data)
d[key] = val
return d
raise ValueError("unknown type tag")
def pop(string):
"""pop(string,encoding='utf_8') -> (object, remain)
This function parses a tnetstring into a python object.
It returns a tuple giving the parsed object and a string
containing any unparsed data from the end of the string.
"""
# Parse out data length, type and remaining string.
try:
dlen, rest = string.split(b':', 1)
dlen = int(dlen)
except ValueError:
raise ValueError("not a tnetstring: missing or invalid length prefix: {}".format(string))
try:
data, tns_type, remain = rest[:dlen], rest[dlen:dlen + 1], rest[dlen + 1:]
except IndexError:
# This fires if len(rest) < dlen, meaning we don't need
# to further validate that data is the right length.
raise ValueError("not a tnetstring: invalid length prefix: {}".format(dlen))
# Parse the data based on the type tag.
if tns_type == b',':
return data, remain
if tns_type == b'#':
try:
return int(data), remain
except ValueError:
raise ValueError("not a tnetstring: invalid integer literal: {}".format(data))
if tns_type == b'^':
try:
return float(data), remain
except ValueError:
raise ValueError("not a tnetstring: invalid float literal: {}".format(data))
if tns_type == b'!':
if data == b'true':
return True, remain
elif data == b'false':
return False, remain
else:
raise ValueError("not a tnetstring: invalid boolean literal: {}".format(data))
if tns_type == b'~':
if data:
raise ValueError("not a tnetstring: invalid null literal")
return None, remain
if tns_type == b']':
l = []
while data:
item, data = pop(data)
l.append(item)
return (l, remain)
if tns_type == b'}':
d = {}
while data:
key, data = pop(data)
val, data = pop(data)
d[key] = val
return d, remain
raise ValueError("unknown type tag: {}".format(tns_type))