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Mini Shell
Mini Shell
from collections import deque
from enum import Enum, IntEnum, IntFlag
import struct
from typing import Optional
class SizeLimitError(ValueError):
"""Raised when trying to (de-)serialise data exceeding D-Bus' size limit.
This is currently only implemented for arrays, where the maximum size is
64 MiB.
"""
pass
class Endianness(Enum):
little = 1
big = 2
def struct_code(self):
return '<' if (self is Endianness.little) else '>'
def dbus_code(self):
return b'l' if (self is Endianness.little) else b'B'
endian_map = {b'l': Endianness.little, b'B': Endianness.big}
class MessageType(Enum):
method_call = 1
method_return = 2
error = 3
signal = 4
class MessageFlag(IntFlag):
no_reply_expected = 1
no_auto_start = 2
allow_interactive_authorization = 4
class HeaderFields(IntEnum):
path = 1
interface = 2
member = 3
error_name = 4
reply_serial = 5
destination = 6
sender = 7
signature = 8
unix_fds = 9
def padding(pos, step):
pad = step - (pos % step)
if pad == step:
return 0
return pad
class FixedType:
def __init__(self, size, struct_code):
self.size = self.alignment = size
self.struct_code = struct_code
def parse_data(self, buf, pos, endianness, fds=()):
pos += padding(pos, self.alignment)
code = endianness.struct_code() + self.struct_code
val = struct.unpack(code, buf[pos:pos + self.size])[0]
return val, pos + self.size
def serialise(self, data, pos, endianness, fds=None):
pad = b'\0' * padding(pos, self.alignment)
code = endianness.struct_code() + self.struct_code
return pad + struct.pack(code, data)
def __repr__(self):
return 'FixedType({!r}, {!r})'.format(self.size, self.struct_code)
def __eq__(self, other):
return (type(other) is FixedType) and (self.size == other.size) \
and (self.struct_code == other.struct_code)
class Boolean(FixedType):
def __init__(self):
super().__init__(4, 'I') # D-Bus booleans take 4 bytes
def parse_data(self, buf, pos, endianness, fds=()):
val, new_pos = super().parse_data(buf, pos, endianness)
return bool(val), new_pos
def __repr__(self):
return 'Boolean()'
def __eq__(self, other):
return type(other) is Boolean
class FileDescriptor(FixedType):
def __init__(self):
super().__init__(4, 'I')
def parse_data(self, buf, pos, endianness, fds=()):
idx, new_pos = super().parse_data(buf, pos, endianness)
return fds[idx], new_pos
def serialise(self, data, pos, endianness, fds=None):
if fds is None:
raise RuntimeError("Sending FDs is not supported or not enabled")
if hasattr(data, 'fileno'):
data = data.fileno()
if isinstance(data, bool) or not isinstance(data, int):
raise TypeError("Cannot use {data!r} as file descriptor. Expected "
"an int or an object with fileno() method")
if data < 0:
raise ValueError(f"File descriptor can't be negative ({data})")
fds.append(data)
return super().serialise(len(fds) - 1, pos, endianness)
def __repr__(self):
return 'FileDescriptor()'
def __eq__(self, other):
return type(other) is FileDescriptor
simple_types = {
'y': FixedType(1, 'B'), # unsigned 8 bit
'n': FixedType(2, 'h'), # signed 16 bit
'q': FixedType(2, 'H'), # unsigned 16 bit
'b': Boolean(), # bool (32-bit)
'i': FixedType(4, 'i'), # signed 32-bit
'u': FixedType(4, 'I'), # unsigned 32-bit
'x': FixedType(8, 'q'), # signed 64-bit
't': FixedType(8, 'Q'), # unsigned 64-bit
'd': FixedType(8, 'd'), # double
'h': FileDescriptor(), # file descriptor (uint32 index in a separate list)
}
class StringType:
def __init__(self, length_type):
self.length_type = length_type
@property
def alignment(self):
return self.length_type.size
def parse_data(self, buf, pos, endianness, fds=()):
length, pos = self.length_type.parse_data(buf, pos, endianness)
end = pos + length
val = buf[pos:end].decode('utf-8')
assert buf[end:end + 1] == b'\0'
return val, end + 1
def serialise(self, data, pos, endianness, fds=None):
if not isinstance(data, str):
raise TypeError("Expected str, not {!r}".format(data))
encoded = data.encode('utf-8')
len_data = self.length_type.serialise(len(encoded), pos, endianness)
return len_data + encoded + b'\0'
def __repr__(self):
return 'StringType({!r})'.format(self.length_type)
def __eq__(self, other):
return (type(other) is StringType) \
and (self.length_type == other.length_type)
simple_types.update({
's': StringType(simple_types['u']), # String
'o': StringType(simple_types['u']), # Object path
'g': StringType(simple_types['y']), # Signature
})
class Struct:
alignment = 8
def __init__(self, fields):
if any(isinstance(f, DictEntry) for f in fields):
raise TypeError("Found dict entry outside array")
self.fields = fields
def parse_data(self, buf, pos, endianness, fds=()):
pos += padding(pos, 8)
res = []
for field in self.fields:
v, pos = field.parse_data(buf, pos, endianness, fds=fds)
res.append(v)
return tuple(res), pos
def serialise(self, data, pos, endianness, fds=None):
if not isinstance(data, tuple):
raise TypeError("Expected tuple, not {!r}".format(data))
if len(data) != len(self.fields):
raise ValueError("{} entries for {} fields".format(
len(data), len(self.fields)
))
pad = b'\0' * padding(pos, self.alignment)
pos += len(pad)
res_pieces = []
for item, field in zip(data, self.fields):
res_pieces.append(field.serialise(item, pos, endianness, fds=fds))
pos += len(res_pieces[-1])
return pad + b''.join(res_pieces)
def __repr__(self):
return "{}({!r})".format(type(self).__name__, self.fields)
def __eq__(self, other):
return (type(other) is type(self)) and (self.fields == other.fields)
class DictEntry(Struct):
def __init__(self, fields):
if len(fields) != 2:
raise TypeError(
"Dict entry must have 2 fields, not %d" % len(fields))
if not isinstance(fields[0], (FixedType, StringType)):
raise TypeError(
"First field in dict entry must be simple type, not {}"
.format(type(fields[0])))
super().__init__(fields)
class Array:
alignment = 4
length_type = FixedType(4, 'I')
def __init__(self, elt_type):
self.elt_type = elt_type
def parse_data(self, buf, pos, endianness, fds=()):
# print('Array start', pos)
length, pos = self.length_type.parse_data(buf, pos, endianness)
pos += padding(pos, self.elt_type.alignment)
end = pos + length
if self.elt_type == simple_types['y']: # Array of bytes
return buf[pos:end], end
res = []
while pos < end:
# print('Array elem', pos)
v, pos = self.elt_type.parse_data(buf, pos, endianness, fds=fds)
res.append(v)
if isinstance(self.elt_type, DictEntry):
# Convert list of 2-tuples to dict
res = dict(res)
return res, pos
def serialise(self, data, pos, endianness, fds=None):
data_is_bytes = False
if isinstance(self.elt_type, DictEntry) and isinstance(data, dict):
data = data.items()
elif (self.elt_type == simple_types['y']) and isinstance(data, bytes):
data_is_bytes = True
elif not isinstance(data, list):
raise TypeError("Not suitable for array: {!r}".format(data))
# Fail fast if we know in advance that the data is too big:
if isinstance(self.elt_type, FixedType):
if (self.elt_type.size * len(data)) > 2**26:
raise SizeLimitError("Array size exceeds 64 MiB limit")
pad1 = padding(pos, self.alignment)
pos_after_length = pos + pad1 + 4
pad2 = padding(pos_after_length, self.elt_type.alignment)
if data_is_bytes:
buf = data
else:
data_pos = pos_after_length + pad2
limit_pos = data_pos + 2 ** 26
chunks = []
for item in data:
chunks.append(self.elt_type.serialise(
item, data_pos, endianness, fds=fds
))
data_pos += len(chunks[-1])
if data_pos > limit_pos:
raise SizeLimitError("Array size exceeds 64 MiB limit")
buf = b''.join(chunks)
len_data = self.length_type.serialise(len(buf), pos+pad1, endianness)
# print('Array ser: pad1={!r}, len_data={!r}, pad2={!r}, buf={!r}'.format(
# pad1, len_data, pad2, buf))
return (b'\0' * pad1) + len_data + (b'\0' * pad2) + buf
def __repr__(self):
return 'Array({!r})'.format(self.elt_type)
def __eq__(self, other):
return (type(other) is Array) and (self.elt_type == other.elt_type)
class Variant:
alignment = 1
def parse_data(self, buf, pos, endianness, fds=()):
# print('variant', pos)
sig, pos = simple_types['g'].parse_data(buf, pos, endianness)
# print('variant sig:', repr(sig), pos)
valtype = parse_signature(list(sig))
val, pos = valtype.parse_data(buf, pos, endianness, fds=fds)
# print('variant done', (sig, val), pos)
return (sig, val), pos
def serialise(self, data, pos, endianness, fds=None):
sig, data = data
valtype = parse_signature(list(sig))
sig_buf = simple_types['g'].serialise(sig, pos, endianness)
return sig_buf + valtype.serialise(
data, pos + len(sig_buf), endianness, fds=fds
)
def __repr__(self):
return 'Variant()'
def __eq__(self, other):
return type(other) is Variant
def parse_signature(sig):
"""Parse a symbolic signature into objects.
"""
# Based on http://norvig.com/lispy.html
token = sig.pop(0)
if token == 'a':
return Array(parse_signature(sig))
if token == 'v':
return Variant()
elif token == '(':
fields = []
while sig[0] != ')':
fields.append(parse_signature(sig))
sig.pop(0) # )
return Struct(fields)
elif token == '{':
de = []
while sig[0] != '}':
de.append(parse_signature(sig))
sig.pop(0) # }
return DictEntry(de)
elif token in ')}':
raise ValueError('Unexpected end of struct')
else:
return simple_types[token]
def calc_msg_size(buf):
endian, = struct.unpack('c', buf[:1])
endian = endian_map[endian]
body_length, = struct.unpack(endian.struct_code() + 'I', buf[4:8])
fields_array_len, = struct.unpack(endian.struct_code() + 'I', buf[12:16])
header_len = 16 + fields_array_len
return header_len + padding(header_len, 8) + body_length
_header_fields_type = Array(Struct([simple_types['y'], Variant()]))
def parse_header_fields(buf, endianness):
l, pos = _header_fields_type.parse_data(buf, 12, endianness)
return {HeaderFields(k): v[1] for (k, v) in l}, pos
header_field_codes = {
1: 'o',
2: 's',
3: 's',
4: 's',
5: 'u',
6: 's',
7: 's',
8: 'g',
9: 'u',
}
def serialise_header_fields(d, endianness):
l = [(i.value, (header_field_codes[i], v)) for (i, v) in sorted(d.items())]
return _header_fields_type.serialise(l, 12, endianness)
class Header:
def __init__(self, endianness, message_type, flags, protocol_version,
body_length, serial, fields):
"""A D-Bus message header
It's not normally necessary to construct this directly: use higher level
functions and methods instead.
"""
self.endianness = endianness
self.message_type = MessageType(message_type)
self.flags = MessageFlag(flags)
self.protocol_version = protocol_version
self.body_length = body_length
self.serial = serial
self.fields = fields
def __repr__(self):
return 'Header({!r}, {!r}, {!r}, {!r}, {!r}, {!r}, fields={!r})'.format(
self.endianness, self.message_type, self.flags,
self.protocol_version, self.body_length, self.serial, self.fields)
def serialise(self, serial=None):
s = self.endianness.struct_code() + 'cBBBII'
if serial is None:
serial = self.serial
return struct.pack(s, self.endianness.dbus_code(),
self.message_type.value, self.flags,
self.protocol_version,
self.body_length, serial) \
+ serialise_header_fields(self.fields, self.endianness)
@classmethod
def from_buffer(cls, buf):
endian, msgtype, flags, pv = struct.unpack('cBBB', buf[:4])
endian = endian_map[endian]
bodylen, serial = struct.unpack(endian.struct_code() + 'II', buf[4:12])
fields, pos = parse_header_fields(buf, endian)
return cls(endian, msgtype, flags, pv, bodylen, serial, fields), pos
class Message:
"""Object representing a DBus message.
It's not normally necessary to construct this directly: use higher level
functions and methods instead.
"""
def __init__(self, header, body):
self.header = header
self.body = body
def __repr__(self):
return "{}({!r}, {!r})".format(type(self).__name__, self.header, self.body)
@classmethod
def from_buffer(cls, buf: bytes, fds=()) -> 'Message':
header, pos = Header.from_buffer(buf)
n_fds = header.fields.get(HeaderFields.unix_fds, 0)
if n_fds > len(fds):
raise ValueError(
f"Message expects {n_fds} FDs, but only {len(fds)} were received"
)
fds = fds[:n_fds]
body = ()
if HeaderFields.signature in header.fields:
sig = header.fields[HeaderFields.signature]
body_type = parse_signature(list('(%s)' % sig))
body = body_type.parse_data(buf, pos, header.endianness, fds=fds)[0]
return Message(header, body)
def serialise(self, serial=None, fds=None) -> bytes:
"""Convert this message to bytes.
Specifying *serial* overrides the ``msg.header.serial`` field, so a
connection can use its own serial number without modifying the message.
If file-descriptor support is in use, *fds* should be a
:class:`array.array` object with type ``'i'``. Any file descriptors in
the message will be added to the array. If the message contains FDs,
it can't be serialised without this array.
"""
endian = self.header.endianness
if HeaderFields.signature in self.header.fields:
sig = self.header.fields[HeaderFields.signature]
body_type = parse_signature(list('(%s)' % sig))
body_buf = body_type.serialise(self.body, 0, endian, fds=fds)
else:
body_buf = b''
self.header.body_length = len(body_buf)
if fds:
self.header.fields[HeaderFields.unix_fds] = len(fds)
header_buf = self.header.serialise(serial=serial)
pad = b'\0' * padding(len(header_buf), 8)
return header_buf + pad + body_buf
class Parser:
"""Parse DBus messages from a stream of incoming data.
"""
def __init__(self):
self.buf = BufferPipe()
self.fds = []
self.next_msg_size = None
def add_data(self, data: bytes, fds=()):
"""Provide newly received data to the parser"""
self.buf.write(data)
self.fds.extend(fds)
def feed(self, data):
"""Feed the parser newly read data.
Returns a list of messages completed by the new data.
"""
self.add_data(data)
return list(iter(self.get_next_message, None))
def bytes_desired(self):
"""How many bytes can be received without going beyond the next message?
This is only used with file-descriptor passing, so we don't get too many
FDs in a single recvmsg call.
"""
got = self.buf.bytes_buffered
if got < 16: # The first 16 bytes tell us the message size
return 16 - got
if self.next_msg_size is None:
self.next_msg_size = calc_msg_size(self.buf.peek(16))
return self.next_msg_size - got
def get_next_message(self) -> Optional[Message]:
"""Parse one message, if there is enough data.
Returns None if it doesn't have a complete message.
"""
if self.next_msg_size is None:
if self.buf.bytes_buffered >= 16:
self.next_msg_size = calc_msg_size(self.buf.peek(16))
nms = self.next_msg_size
if (nms is not None) and self.buf.bytes_buffered >= nms:
raw_msg = self.buf.read(nms)
msg = Message.from_buffer(raw_msg, fds=self.fds)
self.next_msg_size = None
fds_consumed = msg.header.fields.get(HeaderFields.unix_fds, 0)
self.fds = self.fds[fds_consumed:]
return msg
class BufferPipe:
"""A place to store received data until we can parse a complete message
The main difference from io.BytesIO is that read & write operate at
opposite ends, like a pipe.
"""
def __init__(self):
self.chunks = deque()
self.bytes_buffered = 0
def write(self, b: bytes):
self.chunks.append(b)
self.bytes_buffered += len(b)
def _peek_iter(self, nbytes: int):
assert nbytes <= self.bytes_buffered
for chunk in self.chunks:
chunk = chunk[:nbytes]
nbytes -= len(chunk)
yield chunk
if nbytes <= 0:
break
def peek(self, nbytes: int) -> bytes:
"""Get exactly nbytes bytes from the front without removing them"""
return b''.join(self._peek_iter(nbytes))
def _read_iter(self, nbytes: int):
assert nbytes <= self.bytes_buffered
while True:
chunk = self.chunks.popleft()
self.bytes_buffered -= len(chunk)
if nbytes <= len(chunk):
break
nbytes -= len(chunk)
yield chunk
# Final chunk
chunk, rem = chunk[:nbytes], chunk[nbytes:]
if rem:
self.chunks.appendleft(rem)
self.bytes_buffered += len(rem)
yield chunk
def read(self, nbytes: int) -> bytes:
"""Take & return exactly nbytes bytes from the front"""
return b''.join(self._read_iter(nbytes))
Zerion Mini Shell 1.0