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cpython/Lib/email/Parser.py

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# Copyright (C) 2001,2002 Python Software Foundation
# Author: barry@zope.com (Barry Warsaw)
"""A parser of RFC 2822 and MIME email messages.
"""
import re
from cStringIO import StringIO
from types import ListType
from email import Errors
from email import Message
EMPTYSTRING = ''
NL = '\n'
class Parser:
def __init__(self, _class=Message.Message, strict=0):
"""Parser of RFC 2822 and MIME email messages.
Creates an in-memory object tree representing the email message, which
can then be manipulated and turned over to a Generator to return the
textual representation of the message.
The string must be formatted as a block of RFC 2822 headers and header
continuation lines, optionally preceeded by a `Unix-from' header. The
header block is terminated either by the end of the string or by a
blank line.
_class is the class to instantiate for new message objects when they
must be created. This class must have a constructor that can take
zero arguments. Default is Message.Message.
Optional strict tells the parser to be strictly RFC compliant or to be
more forgiving in parsing of ill-formatted MIME documents. When
non-strict mode is used, the parser will try to make up for missing or
erroneous boundaries and other peculiarities seen in the wild.
Default is non-strict parsing.
"""
self._class = _class
self._strict = strict
def parse(self, fp, headersonly=0):
root = self._class()
self._parseheaders(root, fp)
if not headersonly:
self._parsebody(root, fp)
return root
def parsestr(self, text, headersonly=0):
return self.parse(StringIO(text), headersonly=headersonly)
def _parseheaders(self, container, fp):
# Parse the headers, returning a list of header/value pairs. None as
# the header means the Unix-From header.
lastheader = ''
lastvalue = []
lineno = 0
while 1:
# Don't strip the line before we test for the end condition,
# because whitespace-only header lines are RFC compliant
# continuation lines.
line = fp.readline()
if not line:
break
line = line.splitlines()[0]
if not line:
break
# Ignore the trailing newline
lineno += 1
# Check for initial Unix From_ line
if line.startswith('From '):
if lineno == 1:
container.set_unixfrom(line)
continue
elif self._strict:
raise Errors.HeaderParseError(
'Unix-from in headers after first rfc822 header')
else:
# ignore the wierdly placed From_ line
# XXX: maybe set unixfrom anyway? or only if not already?
continue
# Header continuation line
if line[0] in ' \t':
if not lastheader:
raise Errors.HeaderParseError(
'Continuation line seen before first header')
lastvalue.append(line)
continue
# Normal, non-continuation header. BAW: this should check to make
# sure it's a legal header, e.g. doesn't contain spaces. Also, we
# should expose the header matching algorithm in the API, and
# allow for a non-strict parsing mode (that ignores the line
# instead of raising the exception).
i = line.find(':')
if i < 0:
if self._strict:
raise Errors.HeaderParseError(
"Not a header, not a continuation: ``%s''"%line)
elif lineno == 1 and line.startswith('--'):
# allow through duplicate boundary tags.
continue
else:
raise Errors.HeaderParseError(
"Not a header, not a continuation: ``%s''"%line)
if lastheader:
container[lastheader] = NL.join(lastvalue)
lastheader = line[:i]
lastvalue = [line[i+1:].lstrip()]
# Make sure we retain the last header
if lastheader:
container[lastheader] = NL.join(lastvalue)
def _parsebody(self, container, fp):
# Parse the body, but first split the payload on the content-type
# boundary if present.
boundary = container.get_boundary()
isdigest = (container.get_type() == 'multipart/digest')
# If there's a boundary, split the payload text into its constituent
# parts and parse each separately. Otherwise, just parse the rest of
# the body as a single message. Note: any exceptions raised in the
# recursive parse need to have their line numbers coerced.
if boundary:
preamble = epilogue = None
# Split into subparts. The first boundary we're looking for won't
# always have a leading newline since we're at the start of the
# body text, and there's not always a preamble before the first
# boundary.
separator = '--' + boundary
payload = fp.read()
# We use an RE here because boundaries can have trailing
# whitespace.
mo = re.search(
r'(?P<sep>' + re.escape(separator) + r')(?P<ws>[ \t]*)',
payload)
if not mo:
if self._strict:
raise Errors.BoundaryError(
"Couldn't find starting boundary: %s" % boundary)
container.set_payload(payload)
return
start = mo.start()
if start > 0:
# there's some pre-MIME boundary preamble
preamble = payload[0:start]
# Find out what kind of line endings we're using
start += len(mo.group('sep')) + len(mo.group('ws'))
cre = re.compile('\r\n|\r|\n')
mo = cre.search(payload, start)
if mo:
start += len(mo.group(0))
# We create a compiled regexp first because we need to be able to
# specify the start position, and the module function doesn't
# support this signature. :(
cre = re.compile('(?P<sep>\r\n|\r|\n)' +
re.escape(separator) + '--')
mo = cre.search(payload, start)
if mo:
terminator = mo.start()
linesep = mo.group('sep')
if mo.end() < len(payload):
# There's some post-MIME boundary epilogue
epilogue = payload[mo.end():]
elif self._strict:
raise Errors.BoundaryError(
"Couldn't find terminating boundary: %s" % boundary)
else:
# Handle the case of no trailing boundary. Check that it ends
# in a blank line. Some cases (spamspamspam) don't even have
# that!
mo = re.search('(?P<sep>\r\n|\r|\n){2}$', payload)
if not mo:
mo = re.search('(?P<sep>\r\n|\r|\n)$', payload)
if not mo:
raise Errors.BoundaryError(
'No terminating boundary and no trailing empty line')
linesep = mo.group('sep')
terminator = len(payload)
# We split the textual payload on the boundary separator, which
# includes the trailing newline. If the container is a
# multipart/digest then the subparts are by default message/rfc822
# instead of text/plain. In that case, they'll have a optional
# block of MIME headers, then an empty line followed by the
# message headers.
parts = re.split(
linesep + re.escape(separator) + r'[ \t]*' + linesep,
payload[start:terminator])
for part in parts:
if isdigest:
if part[0] == linesep:
# There's no header block so create an empty message
# object as the container, and lop off the newline so
# we can parse the sub-subobject
msgobj = self._class()
part = part[1:]
else:
parthdrs, part = part.split(linesep+linesep, 1)
# msgobj in this case is the "message/rfc822" container
msgobj = self.parsestr(parthdrs, headersonly=1)
# while submsgobj is the message itself
submsgobj = self.parsestr(part)
msgobj.attach(submsgobj)
msgobj.set_default_type('message/rfc822')
else:
msgobj = self.parsestr(part)
container.preamble = preamble
container.epilogue = epilogue
container.attach(msgobj)
elif container.get_main_type() == 'multipart':
# Very bad. A message is a multipart with no boundary!
raise Errors.BoundaryError(
'multipart message with no defined boundary')
elif container.get_type() == 'message/delivery-status':
# This special kind of type contains blocks of headers separated
# by a blank line. We'll represent each header block as a
# separate Message object
blocks = []
while 1:
blockmsg = self._class()
self._parseheaders(blockmsg, fp)
if not len(blockmsg):
# No more header blocks left
break
blocks.append(blockmsg)
container.set_payload(blocks)
elif container.get_main_type() == 'message':
# Create a container for the payload, but watch out for there not
# being any headers left
try:
msg = self.parse(fp)
except Errors.HeaderParseError:
msg = self._class()
self._parsebody(msg, fp)
container.attach(msg)
else:
container.set_payload(fp.read())
class HeaderParser(Parser):
"""A subclass of Parser, this one only meaningfully parses message headers.
This class can be used if all you're interested in is the headers of a
message. While it consumes the message body, it does not parse it, but
simply makes it available as a string payload.
Parsing with this subclass can be considerably faster if all you're
interested in is the message headers.
"""
def _parsebody(self, container, fp):
# Consume but do not parse, the body
container.set_payload(fp.read())
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