# Copyright (C) 2001-2010 Python Software Foundation # Author: Barry Warsaw # Contact: email-sig@python.org """Classes to generate plain text from a message object tree.""" __all__ = ['Generator', 'DecodedGenerator'] import re import sys import time import random import warnings from io import StringIO, BytesIO from email.header import Header from email.message import _has_surrogates UNDERSCORE = '_' NL = '\n' # XXX: no longer used by the code below. fcre = re.compile(r'^From ', re.MULTILINE) class Generator: """Generates output from a Message object tree. This basic generator writes the message to the given file object as plain text. """ # # Public interface # def __init__(self, outfp, mangle_from_=True, maxheaderlen=78): """Create the generator for message flattening. outfp is the output file-like object for writing the message to. It must have a write() method. Optional mangle_from_ is a flag that, when True (the default), escapes From_ lines in the body of the message by putting a `>' in front of them. Optional maxheaderlen specifies the longest length for a non-continued header. When a header line is longer (in characters, with tabs expanded to 8 spaces) than maxheaderlen, the header will split as defined in the Header class. Set maxheaderlen to zero to disable header wrapping. The default is 78, as recommended (but not required) by RFC 2822. """ self._fp = outfp self._mangle_from_ = mangle_from_ self._maxheaderlen = maxheaderlen def write(self, s): # Just delegate to the file object self._fp.write(s) def flatten(self, msg, unixfrom=False, linesep='\n'): """Print the message object tree rooted at msg to the output file specified when the Generator instance was created. unixfrom is a flag that forces the printing of a Unix From_ delimiter before the first object in the message tree. If the original message has no From_ delimiter, a `standard' one is crafted. By default, this is False to inhibit the printing of any From_ delimiter. Note that for subobjects, no From_ line is printed. linesep specifies the characters used to indicate a new line in the output. """ # We use the _XXX constants for operating on data that comes directly # from the msg, and _encoded_XXX constants for operating on data that # has already been converted (to bytes in the BytesGenerator) and # inserted into a temporary buffer. self._NL = linesep self._encoded_NL = self._encode(linesep) self._EMPTY = '' self._encoded_EMTPY = self._encode('') if unixfrom: ufrom = msg.get_unixfrom() if not ufrom: ufrom = 'From nobody ' + time.ctime(time.time()) self.write(ufrom + self._NL) self._write(msg) def clone(self, fp): """Clone this generator with the exact same options.""" return self.__class__(fp, self._mangle_from_, self._maxheaderlen) # # Protected interface - undocumented ;/ # # Note that we use 'self.write' when what we are writing is coming from # the source, and self._fp.write when what we are writing is coming from a # buffer (because the Bytes subclass has already had a chance to transform # the data in its write method in that case). This is an entirely # pragmatic split determined by experiment; we could be more general by # always using write and having the Bytes subclass write method detect when # it has already transformed the input; but, since this whole thing is a # hack anyway this seems good enough. # Similarly, we have _XXX and _encoded_XXX attributes that are used on # source and buffer data, respectively. _encoded_EMPTY = '' def _new_buffer(self): # BytesGenerator overrides this to return BytesIO. return StringIO() def _encode(self, s): # BytesGenerator overrides this to encode strings to bytes. return s def _write(self, msg): # We can't write the headers yet because of the following scenario: # say a multipart message includes the boundary string somewhere in # its body. We'd have to calculate the new boundary /before/ we write # the headers so that we can write the correct Content-Type: # parameter. # # The way we do this, so as to make the _handle_*() methods simpler, # is to cache any subpart writes into a buffer. The we write the # headers and the buffer contents. That way, subpart handlers can # Do The Right Thing, and can still modify the Content-Type: header if # necessary. oldfp = self._fp try: self._fp = sfp = self._new_buffer() self._dispatch(msg) finally: self._fp = oldfp # Write the headers. First we see if the message object wants to # handle that itself. If not, we'll do it generically. meth = getattr(msg, '_write_headers', None) if meth is None: self._write_headers(msg) else: meth(self) self._fp.write(sfp.getvalue()) def _dispatch(self, msg): # Get the Content-Type: for the message, then try to dispatch to # self._handle__(). If there's no handler for the # full MIME type, then dispatch to self._handle_(). If # that's missing too, then dispatch to self._writeBody(). main = msg.get_content_maintype() sub = msg.get_content_subtype() specific = UNDERSCORE.join((main, sub)).replace('-', '_') meth = getattr(self, '_handle_' + specific, None) if meth is None: generic = main.replace('-', '_') meth = getattr(self, '_handle_' + generic, None) if meth is None: meth = self._writeBody meth(msg) # # Default handlers # def _write_headers(self, msg): for h, v in msg.items(): self.write('%s: ' % h) if isinstance(v, Header): self.write(v.encode( maxlinelen=self._maxheaderlen, linesep=self._NL)+self._NL) else: # Header's got lots of smarts, so use it. header = Header(v, maxlinelen=self._maxheaderlen, header_name=h) self.write(header.encode(linesep=self._NL)+self._NL) # A blank line always separates headers from body self.write(self._NL) # # Handlers for writing types and subtypes # def _handle_text(self, msg): payload = msg.get_payload() if payload is None: return if not isinstance(payload, str): raise TypeError('string payload expected: %s' % type(payload)) if _has_surrogates(msg._payload): charset = msg.get_param('charset') if charset is not None: del msg['content-transfer-encoding'] msg.set_payload(payload, charset) payload = msg.get_payload() if self._mangle_from_: payload = fcre.sub('>From ', payload) self.write(payload) # Default body handler _writeBody = _handle_text def _handle_multipart(self, msg): # The trick here is to write out each part separately, merge them all # together, and then make sure that the boundary we've chosen isn't # present in the payload. msgtexts = [] subparts = msg.get_payload() if subparts is None: subparts = [] elif isinstance(subparts, str): # e.g. a non-strict parse of a message with no starting boundary. self.write(subparts) return elif not isinstance(subparts, list): # Scalar payload subparts = [subparts] for part in subparts: s = self._new_buffer() g = self.clone(s) g.flatten(part, unixfrom=False, linesep=self._NL) msgtexts.append(s.getvalue()) # BAW: What about boundaries that are wrapped in double-quotes? boundary = msg.get_boundary() if not boundary: # Create a boundary that doesn't appear in any of the # message texts. alltext = self._encoded_NL.join(msgtexts) boundary = self._make_boundary(alltext) msg.set_boundary(boundary) # If there's a preamble, write it out, with a trailing CRLF if msg.preamble is not None: self.write(msg.preamble + self._NL) # dash-boundary transport-padding CRLF self.write('--' + boundary + self._NL) # body-part if msgtexts: self._fp.write(msgtexts.pop(0)) # *encapsulation # --> delimiter transport-padding # --> CRLF body-part for body_part in msgtexts: # delimiter transport-padding CRLF self.write(self._NL + '--' + boundary + self._NL) # body-part self._fp.write(body_part) # close-delimiter transport-padding self.write(self._NL + '--' + boundary + '--') if msg.epilogue is not None: self.write(self._NL) self.write(msg.epilogue) def _handle_multipart_signed(self, msg): # The contents of signed parts has to stay unmodified in order to keep # the signature intact per RFC1847 2.1, so we disable header wrapping. # RDM: This isn't enough to completely preserve the part, but it helps. old_maxheaderlen = self._maxheaderlen try: self._maxheaderlen = 0 self._handle_multipart(msg) finally: self._maxheaderlen = old_maxheaderlen def _handle_message_delivery_status(self, msg): # We can't just write the headers directly to self's file object # because this will leave an extra newline between the last header # block and the boundary. Sigh. blocks = [] for part in msg.get_payload(): s = self._new_buffer() g = self.clone(s) g.flatten(part, unixfrom=False, linesep=self._NL) text = s.getvalue() lines = text.split(self._encoded_NL) # Strip off the unnecessary trailing empty line if lines and lines[-1] == self._encoded_EMPTY: blocks.append(self._encoded_NL.join(lines[:-1])) else: blocks.append(text) # Now join all the blocks with an empty line. This has the lovely # effect of separating each block with an empty line, but not adding # an extra one after the last one. self._fp.write(self._encoded_NL.join(blocks)) def _handle_message(self, msg): s = self._new_buffer() g = self.clone(s) # The payload of a message/rfc822 part should be a multipart sequence # of length 1. The zeroth element of the list should be the Message # object for the subpart. Extract that object, stringify it, and # write it out. # Except, it turns out, when it's a string instead, which happens when # and only when HeaderParser is used on a message of mime type # message/rfc822. Such messages are generated by, for example, # Groupwise when forwarding unadorned messages. (Issue 7970.) So # in that case we just emit the string body. payload = msg.get_payload() if isinstance(payload, list): g.flatten(msg.get_payload(0), unixfrom=False, linesep=self._NL) payload = s.getvalue() self._fp.write(payload) # This used to be a module level function; we use a classmethod for this # and _compile_re so we can continue to provide the module level function # for backward compatibility by doing # _make_boudary = Generator._make_boundary # at the end of the module. It *is* internal, so we could drop that... @classmethod def _make_boundary(cls, text=None): # Craft a random boundary. If text is given, ensure that the chosen # boundary doesn't appear in the text. token = random.randrange(sys.maxsize) boundary = ('=' * 15) + (_fmt % token) + '==' if text is None: return boundary b = boundary counter = 0 while True: cre = cls._compile_re('^--' + re.escape(b) + '(--)?$', re.MULTILINE) if not cre.search(text): break b = boundary + '.' + str(counter) counter += 1 return b @classmethod def _compile_re(cls, s, flags): return re.compile(s, flags) class BytesGenerator(Generator): """Generates a bytes version of a Message object tree. Functionally identical to the base Generator except that the output is bytes and not string. When surrogates were used in the input to encode bytes, these are decoded back to bytes for output. The outfp object must accept bytes in its write method. """ # Bytes versions of this constant for use in manipulating data from # the BytesIO buffer. _encoded_EMPTY = b'' def write(self, s): self._fp.write(s.encode('ascii', 'surrogateescape')) def _new_buffer(self): return BytesIO() def _encode(self, s): return s.encode('ascii') def _write_headers(self, msg): # This is almost the same as the string version, except for handling # strings with 8bit bytes. for h, v in msg._headers: self.write('%s: ' % h) if isinstance(v, Header): self.write(v.encode(maxlinelen=self._maxheaderlen)+NL) elif _has_surrogates(v): # If we have raw 8bit data in a byte string, we have no idea # what the encoding is. There is no safe way to split this # string. If it's ascii-subset, then we could do a normal # ascii split, but if it's multibyte then we could break the # string. There's no way to know so the least harm seems to # be to not split the string and risk it being too long. self.write(v+NL) else: # Header's got lots of smarts and this string is safe... header = Header(v, maxlinelen=self._maxheaderlen, header_name=h) self.write(header.encode(linesep=self._NL)+self._NL) # A blank line always separates headers from body self.write(self._NL) def _handle_text(self, msg): # If the string has surrogates the original source was bytes, so # just write it back out. if msg._payload is None: return if _has_surrogates(msg._payload): self.write(msg._payload) else: super(BytesGenerator,self)._handle_text(msg) @classmethod def _compile_re(cls, s, flags): return re.compile(s.encode('ascii'), flags) _FMT = '[Non-text (%(type)s) part of message omitted, filename %(filename)s]' class DecodedGenerator(Generator): """Generates a text representation of a message. Like the Generator base class, except that non-text parts are substituted with a format string representing the part. """ def __init__(self, outfp, mangle_from_=True, maxheaderlen=78, fmt=None): """Like Generator.__init__() except that an additional optional argument is allowed. Walks through all subparts of a message. If the subpart is of main type `text', then it prints the decoded payload of the subpart. Otherwise, fmt is a format string that is used instead of the message payload. fmt is expanded with the following keywords (in %(keyword)s format): type : Full MIME type of the non-text part maintype : Main MIME type of the non-text part subtype : Sub-MIME type of the non-text part filename : Filename of the non-text part description: Description associated with the non-text part encoding : Content transfer encoding of the non-text part The default value for fmt is None, meaning [Non-text (%(type)s) part of message omitted, filename %(filename)s] """ Generator.__init__(self, outfp, mangle_from_, maxheaderlen) if fmt is None: self._fmt = _FMT else: self._fmt = fmt def _dispatch(self, msg): for part in msg.walk(): maintype = part.get_content_maintype() if maintype == 'text': print(part.get_payload(decode=False), file=self) elif maintype == 'multipart': # Just skip this pass else: print(self._fmt % { 'type' : part.get_content_type(), 'maintype' : part.get_content_maintype(), 'subtype' : part.get_content_subtype(), 'filename' : part.get_filename('[no filename]'), 'description': part.get('Content-Description', '[no description]'), 'encoding' : part.get('Content-Transfer-Encoding', '[no encoding]'), }, file=self) # Helper used by Generator._make_boundary _width = len(repr(sys.maxsize-1)) _fmt = '%%0%dd' % _width # Backward compatibility _make_boundary = Generator._make_boundary