""" Multi-part parsing for file uploads. Exposes one class, ``MultiPartParser``, which feeds chunks of uploaded data to file upload handlers for processing. """ from __future__ import unicode_literals import base64 import binascii import cgi import sys from django.conf import settings from django.core.exceptions import SuspiciousMultipartForm from django.utils.datastructures import MultiValueDict from django.utils.encoding import force_text from django.utils import six from django.utils.text import unescape_entities from django.core.files.uploadhandler import StopUpload, SkipFile, StopFutureHandlers __all__ = ('MultiPartParser', 'MultiPartParserError', 'InputStreamExhausted') class MultiPartParserError(Exception): pass class InputStreamExhausted(Exception): """ No more reads are allowed from this device. """ pass RAW = "raw" FILE = "file" FIELD = "field" _BASE64_DECODE_ERROR = TypeError if six.PY2 else binascii.Error class MultiPartParser(object): """ A rfc2388 multipart/form-data parser. ``MultiValueDict.parse()`` reads the input stream in ``chunk_size`` chunks and returns a tuple of ``(MultiValueDict(POST), MultiValueDict(FILES))``. """ def __init__(self, META, input_data, upload_handlers, encoding=None): """ Initialize the MultiPartParser object. :META: The standard ``META`` dictionary in Django request objects. :input_data: The raw post data, as a file-like object. :upload_handlers: A list of UploadHandler instances that perform operations on the uploaded data. :encoding: The encoding with which to treat the incoming data. """ # # Content-Type should containt multipart and the boundary information. # content_type = META.get('HTTP_CONTENT_TYPE', META.get('CONTENT_TYPE', '')) if not content_type.startswith('multipart/'): raise MultiPartParserError('Invalid Content-Type: %s' % content_type) # Parse the header to get the boundary to split the parts. ctypes, opts = parse_header(content_type.encode('ascii')) boundary = opts.get('boundary') if not boundary or not cgi.valid_boundary(boundary): raise MultiPartParserError('Invalid boundary in multipart: %s' % boundary) # Content-Length should contain the length of the body we are about # to receive. try: content_length = int(META.get('HTTP_CONTENT_LENGTH', META.get('CONTENT_LENGTH', 0))) except (ValueError, TypeError): content_length = 0 if content_length < 0: # This means we shouldn't continue...raise an error. raise MultiPartParserError("Invalid content length: %r" % content_length) if isinstance(boundary, six.text_type): boundary = boundary.encode('ascii') self._boundary = boundary self._input_data = input_data # For compatibility with low-level network APIs (with 32-bit integers), # the chunk size should be < 2^31, but still divisible by 4. possible_sizes = [x.chunk_size for x in upload_handlers if x.chunk_size] self._chunk_size = min([2 ** 31 - 4] + possible_sizes) self._meta = META self._encoding = encoding or settings.DEFAULT_CHARSET self._content_length = content_length self._upload_handlers = upload_handlers def parse(self): """ Parse the POST data and break it into a FILES MultiValueDict and a POST MultiValueDict. Returns a tuple containing the POST and FILES dictionary, respectively. """ # We have to import QueryDict down here to avoid a circular import. from django.http import QueryDict encoding = self._encoding handlers = self._upload_handlers # HTTP spec says that Content-Length >= 0 is valid # handling content-length == 0 before continuing if self._content_length == 0: return QueryDict('', encoding=self._encoding), MultiValueDict() # See if any of the handlers take care of the parsing. # This allows overriding everything if need be. for handler in handlers: result = handler.handle_raw_input(self._input_data, self._meta, self._content_length, self._boundary, encoding) # Check to see if it was handled if result is not None: return result[0], result[1] # Create the data structures to be used later. self._post = QueryDict('', mutable=True) self._files = MultiValueDict() # Instantiate the parser and stream: stream = LazyStream(ChunkIter(self._input_data, self._chunk_size)) # Whether or not to signal a file-completion at the beginning of the loop. old_field_name = None counters = [0] * len(handlers) try: for item_type, meta_data, field_stream in Parser(stream, self._boundary): if old_field_name: # We run this at the beginning of the next loop # since we cannot be sure a file is complete until # we hit the next boundary/part of the multipart content. self.handle_file_complete(old_field_name, counters) old_field_name = None try: disposition = meta_data['content-disposition'][1] field_name = disposition['name'].strip() except (KeyError, IndexError, AttributeError): continue transfer_encoding = meta_data.get('content-transfer-encoding') if transfer_encoding is not None: transfer_encoding = transfer_encoding[0].strip() field_name = force_text(field_name, encoding, errors='replace') if item_type == FIELD: # This is a post field, we can just set it in the post if transfer_encoding == 'base64': raw_data = field_stream.read() try: data = base64.b64decode(raw_data) except _BASE64_DECODE_ERROR: data = raw_data else: data = field_stream.read() self._post.appendlist(field_name, force_text(data, encoding, errors='replace')) elif item_type == FILE: # This is a file, use the handler... file_name = disposition.get('filename') if not file_name: continue file_name = force_text(file_name, encoding, errors='replace') file_name = self.IE_sanitize(unescape_entities(file_name)) content_type, content_type_extra = meta_data.get('content-type', ('', {})) content_type = content_type.strip() charset = content_type_extra.get('charset') try: content_length = int(meta_data.get('content-length')[0]) except (IndexError, TypeError, ValueError): content_length = None counters = [0] * len(handlers) try: for handler in handlers: try: handler.new_file(field_name, file_name, content_type, content_length, charset, content_type_extra) except StopFutureHandlers: break for chunk in field_stream: if transfer_encoding == 'base64': # We only special-case base64 transfer encoding # We should always read base64 streams by multiple of 4 over_bytes = len(chunk) % 4 if over_bytes: over_chunk = field_stream.read(4 - over_bytes) chunk += over_chunk try: chunk = base64.b64decode(chunk) except Exception as e: # Since this is only a chunk, any error is an unfixable error. msg = "Could not decode base64 data: %r" % e six.reraise(MultiPartParserError, MultiPartParserError(msg), sys.exc_info()[2]) for i, handler in enumerate(handlers): chunk_length = len(chunk) chunk = handler.receive_data_chunk(chunk, counters[i]) counters[i] += chunk_length if chunk is None: # If the chunk received by the handler is None, then don't continue. break except SkipFile: # Just use up the rest of this file... exhaust(field_stream) else: # Handle file upload completions on next iteration. old_field_name = field_name else: # If this is neither a FIELD or a FILE, just exhaust the stream. exhaust(stream) except StopUpload as e: if not e.connection_reset: exhaust(self._input_data) else: # Make sure that the request data is all fed exhaust(self._input_data) # Signal that the upload has completed. for handler in handlers: retval = handler.upload_complete() if retval: break return self._post, self._files def handle_file_complete(self, old_field_name, counters): """ Handle all the signalling that takes place when a file is complete. """ for i, handler in enumerate(self._upload_handlers): file_obj = handler.file_complete(counters[i]) if file_obj: # If it returns a file object, then set the files dict. self._files.appendlist( force_text(old_field_name, self._encoding, errors='replace'), file_obj) break def IE_sanitize(self, filename): """Cleanup filename from Internet Explorer full paths.""" return filename and filename[filename.rfind("\\") + 1:].strip() class LazyStream(six.Iterator): """ The LazyStream wrapper allows one to get and "unget" bytes from a stream. Given a producer object (an iterator that yields bytestrings), the LazyStream object will support iteration, reading, and keeping a "look-back" variable in case you need to "unget" some bytes. """ def __init__(self, producer, length=None): """ Every LazyStream must have a producer when instantiated. A producer is an iterable that returns a string each time it is called. """ self._producer = producer self._empty = False self._leftover = b'' self.length = length self.position = 0 self._remaining = length self._unget_history = [] def tell(self): return self.position def read(self, size=None): def parts(): remaining = self._remaining if size is None else size # do the whole thing in one shot if no limit was provided. if remaining is None: yield b''.join(self) return # otherwise do some bookkeeping to return exactly enough # of the stream and stashing any extra content we get from # the producer while remaining != 0: assert remaining > 0, 'remaining bytes to read should never go negative' chunk = next(self) emitting = chunk[:remaining] self.unget(chunk[remaining:]) remaining -= len(emitting) yield emitting out = b''.join(parts()) return out def __next__(self): """ Used when the exact number of bytes to read is unimportant. This procedure just returns whatever is chunk is conveniently returned from the iterator instead. Useful to avoid unnecessary bookkeeping if performance is an issue. """ if self._leftover: output = self._leftover self._leftover = b'' else: output = next(self._producer) self._unget_history = [] self.position += len(output) return output def close(self): """ Used to invalidate/disable this lazy stream. Replaces the producer with an empty list. Any leftover bytes that have already been read will still be reported upon read() and/or next(). """ self._producer = [] def __iter__(self): return self def unget(self, bytes): """ Places bytes back onto the front of the lazy stream. Future calls to read() will return those bytes first. The stream position and thus tell() will be rewound. """ if not bytes: return self._update_unget_history(len(bytes)) self.position -= len(bytes) self._leftover = b''.join([bytes, self._leftover]) def _update_unget_history(self, num_bytes): """ Updates the unget history as a sanity check to see if we've pushed back the same number of bytes in one chunk. If we keep ungetting the same number of bytes many times (here, 50), we're mostly likely in an infinite loop of some sort. This is usually caused by a maliciously-malformed MIME request. """ self._unget_history = [num_bytes] + self._unget_history[:49] number_equal = len([current_number for current_number in self._unget_history if current_number == num_bytes]) if number_equal > 40: raise SuspiciousMultipartForm( "The multipart parser got stuck, which shouldn't happen with" " normal uploaded files. Check for malicious upload activity;" " if there is none, report this to the Django developers." ) class ChunkIter(six.Iterator): """ An iterable that will yield chunks of data. Given a file-like object as the constructor, this object will yield chunks of read operations from that object. """ def __init__(self, flo, chunk_size=64 * 1024): self.flo = flo self.chunk_size = chunk_size def __next__(self): try: data = self.flo.read(self.chunk_size) except InputStreamExhausted: raise StopIteration() if data: return data else: raise StopIteration() def __iter__(self): return self class InterBoundaryIter(six.Iterator): """ A Producer that will iterate over boundaries. """ def __init__(self, stream, boundary): self._stream = stream self._boundary = boundary def __iter__(self): return self def __next__(self): try: return LazyStream(BoundaryIter(self._stream, self._boundary)) except InputStreamExhausted: raise StopIteration() class BoundaryIter(six.Iterator): """ A Producer that is sensitive to boundaries. Will happily yield bytes until a boundary is found. Will yield the bytes before the boundary, throw away the boundary bytes themselves, and push the post-boundary bytes back on the stream. The future calls to next() after locating the boundary will raise a StopIteration exception. """ def __init__(self, stream, boundary): self._stream = stream self._boundary = boundary self._done = False # rollback an additional six bytes because the format is like # this: CRLF[--CRLF] self._rollback = len(boundary) + 6 # Try to use mx fast string search if available. Otherwise # use Python find. Wrap the latter for consistency. unused_char = self._stream.read(1) if not unused_char: raise InputStreamExhausted() self._stream.unget(unused_char) def __iter__(self): return self def __next__(self): if self._done: raise StopIteration() stream = self._stream rollback = self._rollback bytes_read = 0 chunks = [] for bytes in stream: bytes_read += len(bytes) chunks.append(bytes) if bytes_read > rollback: break if not bytes: break else: self._done = True if not chunks: raise StopIteration() chunk = b''.join(chunks) boundary = self._find_boundary(chunk, len(chunk) < self._rollback) if boundary: end, next = boundary stream.unget(chunk[next:]) self._done = True return chunk[:end] else: # make sure we dont treat a partial boundary (and # its separators) as data if not chunk[:-rollback]: # and len(chunk) >= (len(self._boundary) + 6): # There's nothing left, we should just return and mark as done. self._done = True return chunk else: stream.unget(chunk[-rollback:]) return chunk[:-rollback] def _find_boundary(self, data, eof=False): """ Finds a multipart boundary in data. Should no boundry exist in the data None is returned instead. Otherwise a tuple containing the indices of the following are returned: * the end of current encapsulation * the start of the next encapsulation """ index = data.find(self._boundary) if index < 0: return None else: end = index next = index + len(self._boundary) # backup over CRLF last = max(0, end - 1) if data[last:last + 1] == b'\n': end -= 1 last = max(0, end - 1) if data[last:last + 1] == b'\r': end -= 1 return end, next def exhaust(stream_or_iterable): """ Completely exhausts an iterator or stream. Raise a MultiPartParserError if the argument is not a stream or an iterable. """ iterator = None try: iterator = iter(stream_or_iterable) except TypeError: iterator = ChunkIter(stream_or_iterable, 16384) if iterator is None: raise MultiPartParserError('multipartparser.exhaust() was passed a non-iterable or stream parameter') for __ in iterator: pass def parse_boundary_stream(stream, max_header_size): """ Parses one and exactly one stream that encapsulates a boundary. """ # Stream at beginning of header, look for end of header # and parse it if found. The header must fit within one # chunk. chunk = stream.read(max_header_size) # 'find' returns the top of these four bytes, so we'll # need to munch them later to prevent them from polluting # the payload. header_end = chunk.find(b'\r\n\r\n') def _parse_header(line): main_value_pair, params = parse_header(line) try: name, value = main_value_pair.split(':', 1) except ValueError: raise ValueError("Invalid header: %r" % line) return name, (value, params) if header_end == -1: # we find no header, so we just mark this fact and pass on # the stream verbatim stream.unget(chunk) return (RAW, {}, stream) header = chunk[:header_end] # here we place any excess chunk back onto the stream, as # well as throwing away the CRLFCRLF bytes from above. stream.unget(chunk[header_end + 4:]) TYPE = RAW outdict = {} # Eliminate blank lines for line in header.split(b'\r\n'): # This terminology ("main value" and "dictionary of # parameters") is from the Python docs. try: name, (value, params) = _parse_header(line) except ValueError: continue if name == 'content-disposition': TYPE = FIELD if params.get('filename'): TYPE = FILE outdict[name] = value, params if TYPE == RAW: stream.unget(chunk) return (TYPE, outdict, stream) class Parser(object): def __init__(self, stream, boundary): self._stream = stream self._separator = b'--' + boundary def __iter__(self): boundarystream = InterBoundaryIter(self._stream, self._separator) for sub_stream in boundarystream: # Iterate over each part yield parse_boundary_stream(sub_stream, 1024) def parse_header(line): """ Parse the header into a key-value. Input (line): bytes, output: unicode for key/name, bytes for value which will be decoded later """ plist = _parse_header_params(b';' + line) key = plist.pop(0).lower().decode('ascii') pdict = {} for p in plist: i = p.find(b'=') if i >= 0: name = p[:i].strip().lower().decode('ascii') value = p[i + 1:].strip() if len(value) >= 2 and value[:1] == value[-1:] == b'"': value = value[1:-1] value = value.replace(b'\\\\', b'\\').replace(b'\\"', b'"') pdict[name] = value return key, pdict def _parse_header_params(s): plist = [] while s[:1] == b';': s = s[1:] end = s.find(b';') while end > 0 and s.count(b'"', 0, end) % 2: end = s.find(b';', end + 1) if end < 0: end = len(s) f = s[:end] plist.append(f.strip()) s = s[end:] return plist