/python3/lib/python3.9/email/_encoded_words.py
Python | 233 lines | 155 code | 18 blank | 60 comment | 9 complexity | 5460a0bc3e6c47831aacd0c87a21ba47 MD5 | raw file
- """ Routines for manipulating RFC2047 encoded words.
- This is currently a package-private API, but will be considered for promotion
- to a public API if there is demand.
- """
- # An ecoded word looks like this:
- #
- # =?charset[*lang]?cte?encoded_string?=
- #
- # for more information about charset see the charset module. Here it is one
- # of the preferred MIME charset names (hopefully; you never know when parsing).
- # cte (Content Transfer Encoding) is either 'q' or 'b' (ignoring case). In
- # theory other letters could be used for other encodings, but in practice this
- # (almost?) never happens. There could be a public API for adding entries
- # to the CTE tables, but YAGNI for now. 'q' is Quoted Printable, 'b' is
- # Base64. The meaning of encoded_string should be obvious. 'lang' is optional
- # as indicated by the brackets (they are not part of the syntax) but is almost
- # never encountered in practice.
- #
- # The general interface for a CTE decoder is that it takes the encoded_string
- # as its argument, and returns a tuple (cte_decoded_string, defects). The
- # cte_decoded_string is the original binary that was encoded using the
- # specified cte. 'defects' is a list of MessageDefect instances indicating any
- # problems encountered during conversion. 'charset' and 'lang' are the
- # corresponding strings extracted from the EW, case preserved.
- #
- # The general interface for a CTE encoder is that it takes a binary sequence
- # as input and returns the cte_encoded_string, which is an ascii-only string.
- #
- # Each decoder must also supply a length function that takes the binary
- # sequence as its argument and returns the length of the resulting encoded
- # string.
- #
- # The main API functions for the module are decode, which calls the decoder
- # referenced by the cte specifier, and encode, which adds the appropriate
- # RFC 2047 "chrome" to the encoded string, and can optionally automatically
- # select the shortest possible encoding. See their docstrings below for
- # details.
- import re
- import base64
- import binascii
- import functools
- from string import ascii_letters, digits
- from email import errors
- __all__ = ['decode_q',
- 'encode_q',
- 'decode_b',
- 'encode_b',
- 'len_q',
- 'len_b',
- 'decode',
- 'encode',
- ]
- #
- # Quoted Printable
- #
- # regex based decoder.
- _q_byte_subber = functools.partial(re.compile(br'=([a-fA-F0-9]{2})').sub,
- lambda m: bytes.fromhex(m.group(1).decode()))
- def decode_q(encoded):
- encoded = encoded.replace(b'_', b' ')
- return _q_byte_subber(encoded), []
- # dict mapping bytes to their encoded form
- class _QByteMap(dict):
- safe = b'-!*+/' + ascii_letters.encode('ascii') + digits.encode('ascii')
- def __missing__(self, key):
- if key in self.safe:
- self[key] = chr(key)
- else:
- self[key] = "={:02X}".format(key)
- return self[key]
- _q_byte_map = _QByteMap()
- # In headers spaces are mapped to '_'.
- _q_byte_map[ord(' ')] = '_'
- def encode_q(bstring):
- return ''.join(_q_byte_map[x] for x in bstring)
- def len_q(bstring):
- return sum(len(_q_byte_map[x]) for x in bstring)
- #
- # Base64
- #
- def decode_b(encoded):
- # First try encoding with validate=True, fixing the padding if needed.
- # This will succeed only if encoded includes no invalid characters.
- pad_err = len(encoded) % 4
- missing_padding = b'==='[:4-pad_err] if pad_err else b''
- try:
- return (
- base64.b64decode(encoded + missing_padding, validate=True),
- [errors.InvalidBase64PaddingDefect()] if pad_err else [],
- )
- except binascii.Error:
- # Since we had correct padding, this is likely an invalid char error.
- #
- # The non-alphabet characters are ignored as far as padding
- # goes, but we don't know how many there are. So try without adding
- # padding to see if it works.
- try:
- return (
- base64.b64decode(encoded, validate=False),
- [errors.InvalidBase64CharactersDefect()],
- )
- except binascii.Error:
- # Add as much padding as could possibly be necessary (extra padding
- # is ignored).
- try:
- return (
- base64.b64decode(encoded + b'==', validate=False),
- [errors.InvalidBase64CharactersDefect(),
- errors.InvalidBase64PaddingDefect()],
- )
- except binascii.Error:
- # This only happens when the encoded string's length is 1 more
- # than a multiple of 4, which is invalid.
- #
- # bpo-27397: Just return the encoded string since there's no
- # way to decode.
- return encoded, [errors.InvalidBase64LengthDefect()]
- def encode_b(bstring):
- return base64.b64encode(bstring).decode('ascii')
- def len_b(bstring):
- groups_of_3, leftover = divmod(len(bstring), 3)
- # 4 bytes out for each 3 bytes (or nonzero fraction thereof) in.
- return groups_of_3 * 4 + (4 if leftover else 0)
- _cte_decoders = {
- 'q': decode_q,
- 'b': decode_b,
- }
- def decode(ew):
- """Decode encoded word and return (string, charset, lang, defects) tuple.
- An RFC 2047/2243 encoded word has the form:
- =?charset*lang?cte?encoded_string?=
- where '*lang' may be omitted but the other parts may not be.
- This function expects exactly such a string (that is, it does not check the
- syntax and may raise errors if the string is not well formed), and returns
- the encoded_string decoded first from its Content Transfer Encoding and
- then from the resulting bytes into unicode using the specified charset. If
- the cte-decoded string does not successfully decode using the specified
- character set, a defect is added to the defects list and the unknown octets
- are replaced by the unicode 'unknown' character \\uFDFF.
- The specified charset and language are returned. The default for language,
- which is rarely if ever encountered, is the empty string.
- """
- _, charset, cte, cte_string, _ = ew.split('?')
- charset, _, lang = charset.partition('*')
- cte = cte.lower()
- # Recover the original bytes and do CTE decoding.
- bstring = cte_string.encode('ascii', 'surrogateescape')
- bstring, defects = _cte_decoders[cte](bstring)
- # Turn the CTE decoded bytes into unicode.
- try:
- string = bstring.decode(charset)
- except UnicodeError:
- defects.append(errors.UndecodableBytesDefect("Encoded word "
- "contains bytes not decodable using {} charset".format(charset)))
- string = bstring.decode(charset, 'surrogateescape')
- except LookupError:
- string = bstring.decode('ascii', 'surrogateescape')
- if charset.lower() != 'unknown-8bit':
- defects.append(errors.CharsetError("Unknown charset {} "
- "in encoded word; decoded as unknown bytes".format(charset)))
- return string, charset, lang, defects
- _cte_encoders = {
- 'q': encode_q,
- 'b': encode_b,
- }
- _cte_encode_length = {
- 'q': len_q,
- 'b': len_b,
- }
- def encode(string, charset='utf-8', encoding=None, lang=''):
- """Encode string using the CTE encoding that produces the shorter result.
- Produces an RFC 2047/2243 encoded word of the form:
- =?charset*lang?cte?encoded_string?=
- where '*lang' is omitted unless the 'lang' parameter is given a value.
- Optional argument charset (defaults to utf-8) specifies the charset to use
- to encode the string to binary before CTE encoding it. Optional argument
- 'encoding' is the cte specifier for the encoding that should be used ('q'
- or 'b'); if it is None (the default) the encoding which produces the
- shortest encoded sequence is used, except that 'q' is preferred if it is up
- to five characters longer. Optional argument 'lang' (default '') gives the
- RFC 2243 language string to specify in the encoded word.
- """
- if charset == 'unknown-8bit':
- bstring = string.encode('ascii', 'surrogateescape')
- else:
- bstring = string.encode(charset)
- if encoding is None:
- qlen = _cte_encode_length['q'](bstring)
- blen = _cte_encode_length['b'](bstring)
- # Bias toward q. 5 is arbitrary.
- encoding = 'q' if qlen - blen < 5 else 'b'
- encoded = _cte_encoders[encoding](bstring)
- if lang:
- lang = '*' + lang
- return "=?{}{}?{}?{}?=".format(charset, lang, encoding, encoded)