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# -*- coding: utf-8 -*- """ hpack/hpack ~~~~~~~~~~~ Implements the HPACK header compression algorithm as detailed by the IETF. """ import logging from .table import HeaderTable, table_entry_size from .exceptions import ( HPACKDecodingError, OversizedHeaderListError, InvalidTableSizeError ) from .huffman import HuffmanEncoder from .huffman_constants import ( REQUEST_CODES, REQUEST_CODES_LENGTH ) from .huffman_table import decode_huffman from .struct import HeaderTuple, NeverIndexedHeaderTuple log = logging.getLogger(__name__) INDEX_NONE = b'\x00' INDEX_NEVER = b'\x10' INDEX_INCREMENTAL = b'\x40' # Precompute 2^i for 1-8 for use in prefix calcs. # Zero index is not used but there to save a subtraction # as prefix numbers are not zero indexed. _PREFIX_BIT_MAX_NUMBERS = [(2 ** i) - 1 for i in range(9)] try: # pragma: no cover basestring = basestring except NameError: # pragma: no cover basestring = (str, bytes) # We default the maximum header list we're willing to accept to 64kB. That's a # lot of headers, but if applications want to raise it they can do. DEFAULT_MAX_HEADER_LIST_SIZE = 2 ** 16 def _unicode_if_needed(header, raw): """ Provides a header as a unicode string if raw is False, otherwise returns it as a bytestring. """ name = bytes(header[0]) value = bytes(header[1]) if not raw: name = name.decode('utf-8') value = value.decode('utf-8') return header.__class__(name, value) def encode_integer(integer, prefix_bits): """ This encodes an integer according to the wacky integer encoding rules defined in the HPACK spec. """ log.debug("Encoding %d with %d bits", integer, prefix_bits) if integer < 0: raise ValueError( "Can only encode positive integers, got %s" % integer ) if prefix_bits < 1 or prefix_bits > 8: raise ValueError( "Prefix bits must be between 1 and 8, got %s" % prefix_bits ) max_number = _PREFIX_BIT_MAX_NUMBERS[prefix_bits] if integer < max_number: return bytearray([integer]) # Seriously? else: elements = [max_number] integer -= max_number while integer >= 128: elements.append((integer & 127) + 128) integer >>= 7 elements.append(integer) return bytearray(elements) def decode_integer(data, prefix_bits): """ This decodes an integer according to the wacky integer encoding rules defined in the HPACK spec. Returns a tuple of the decoded integer and the number of bytes that were consumed from ``data`` in order to get that integer. """ if prefix_bits < 1 or prefix_bits > 8: raise ValueError( "Prefix bits must be between 1 and 8, got %s" % prefix_bits ) max_number = _PREFIX_BIT_MAX_NUMBERS[prefix_bits] index = 1 shift = 0 mask = (0xFF >> (8 - prefix_bits)) try: number = data[0] & mask if number == max_number: while True: next_byte = data[index] index += 1 if next_byte >= 128: number += (next_byte - 128) << shift else: number += next_byte << shift break shift += 7 except IndexError: raise HPACKDecodingError( "Unable to decode HPACK integer representation from %r" % data ) log.debug("Decoded %d, consumed %d bytes", number, index) return number, index def _dict_to_iterable(header_dict): """ This converts a dictionary to an iterable of two-tuples. This is a HPACK-specific function because it pulls "special-headers" out first and then emits them. """ assert isinstance(header_dict, dict) keys = sorted( header_dict.keys(), key=lambda k: not _to_bytes(k).startswith(b':') ) for key in keys: yield key, header_dict[key] def _to_bytes(string): """ Convert string to bytes. """ if not isinstance(string, basestring): # pragma: no cover string = str(string) return string if isinstance(string, bytes) else string.encode('utf-8') class Encoder: """ An HPACK encoder object. This object takes HTTP headers and emits encoded HTTP/2 header blocks. """ def __init__(self): self.header_table = HeaderTable() self.huffman_coder = HuffmanEncoder( REQUEST_CODES, REQUEST_CODES_LENGTH ) self.table_size_changes = [] @property def header_table_size(self): """ Controls the size of the HPACK header table. """ return self.header_table.maxsize @header_table_size.setter def header_table_size(self, value): self.header_table.maxsize = value if self.header_table.resized: self.table_size_changes.append(value) def encode(self, headers, huffman=True): """ Takes a set of headers and encodes them into a HPACK-encoded header block. :param headers: The headers to encode. Must be either an iterable of tuples, an iterable of :class:`HeaderTuple <hpack.HeaderTuple>`, or a ``dict``. If an iterable of tuples, the tuples may be either two-tuples or three-tuples. If they are two-tuples, the tuples must be of the format ``(name, value)``. If they are three-tuples, they must be of the format ``(name, value, sensitive)``, where ``sensitive`` is a boolean value indicating whether the header should be added to header tables anywhere. If not present, ``sensitive`` defaults to ``False``. If an iterable of :class:`HeaderTuple <hpack.HeaderTuple>`, the tuples must always be two-tuples. Instead of using ``sensitive`` as a third tuple entry, use :class:`NeverIndexedHeaderTuple <hpack.NeverIndexedHeaderTuple>` to request that the field never be indexed. .. warning:: HTTP/2 requires that all special headers (headers whose names begin with ``:`` characters) appear at the *start* of the header block. While this method will ensure that happens for ``dict`` subclasses, callers using any other iterable of tuples **must** ensure they place their special headers at the start of the iterable. For efficiency reasons users should prefer to use iterables of two-tuples: fixing the ordering of dictionary headers is an expensive operation that should be avoided if possible. :param huffman: (optional) Whether to Huffman-encode any header sent as a literal value. Except for use when debugging, it is recommended that this be left enabled. :returns: A bytestring containing the HPACK-encoded header block. """ # Transforming the headers into a header block is a procedure that can # be modeled as a chain or pipe. First, the headers are encoded. This # encoding can be done a number of ways. If the header name-value pair # are already in the header table we can represent them using the # indexed representation: the same is true if they are in the static # table. Otherwise, a literal representation will be used. header_block = [] # Turn the headers into a list of tuples if possible. This is the # natural way to interact with them in HPACK. Because dictionaries are # un-ordered, we need to make sure we grab the "special" headers first. if isinstance(headers, dict): headers = _dict_to_iterable(headers) # Before we begin, if the header table size has been changed we need # to signal all changes since last emission appropriately. if self.header_table.resized: header_block.append(self._encode_table_size_change()) self.header_table.resized = False # Add each header to the header block for header in headers: sensitive = False if isinstance(header, HeaderTuple): sensitive = not header.indexable elif len(header) > 2: sensitive = header[2] header = (_to_bytes(header[0]), _to_bytes(header[1])) header_block.append(self.add(header, sensitive, huffman)) header_block = b''.join(header_block) log.debug("Encoded header block to %s", header_block) return header_block def add(self, to_add, sensitive, huffman=False): """ This function takes a header key-value tuple and serializes it. """ log.debug( "Adding %s to the header table, sensitive:%s, huffman:%s", to_add, sensitive, huffman ) name, value = to_add # Set our indexing mode indexbit = INDEX_INCREMENTAL if not sensitive else INDEX_NEVER # Search for a matching header in the header table. match = self.header_table.search(name, value) if match is None: # Not in the header table. Encode using the literal syntax, # and add it to the header table. encoded = self._encode_literal(name, value, indexbit, huffman) if not sensitive: self.header_table.add(name, value) return encoded # The header is in the table, break out the values. If we matched # perfectly, we can use the indexed representation: otherwise we # can use the indexed literal. index, name, perfect = match if perfect: # Indexed representation. encoded = self._encode_indexed(index) else: # Indexed literal. We are going to add header to the # header table unconditionally. It is a future todo to # filter out headers which are known to be ineffective for # indexing since they just take space in the table and # pushed out other valuable headers. encoded = self._encode_indexed_literal( index, value, indexbit, huffman ) if not sensitive: self.header_table.add(name, value) return encoded def _encode_indexed(self, index): """ Encodes a header using the indexed representation. """ field = encode_integer(index, 7) field[0] |= 0x80 # we set the top bit return bytes(field) def _encode_literal(self, name, value, indexbit, huffman=False): """ Encodes a header with a literal name and literal value. If ``indexing`` is True, the header will be added to the header table: otherwise it will not. """ if huffman: name = self.huffman_coder.encode(name) value = self.huffman_coder.encode(value) name_len = encode_integer(len(name), 7) value_len = encode_integer(len(value), 7) if huffman: name_len[0] |= 0x80 value_len[0] |= 0x80 return b''.join( [indexbit, bytes(name_len), name, bytes(value_len), value] ) def _encode_indexed_literal(self, index, value, indexbit, huffman=False): """ Encodes a header with an indexed name and a literal value and performs incremental indexing. """ if indexbit != INDEX_INCREMENTAL: prefix = encode_integer(index, 4) else: prefix = encode_integer(index, 6) prefix[0] |= ord(indexbit) if huffman: value = self.huffman_coder.encode(value) value_len = encode_integer(len(value), 7) if huffman: value_len[0] |= 0x80 return b''.join([bytes(prefix), bytes(value_len), value]) def _encode_table_size_change(self): """ Produces the encoded form of all header table size change context updates. """ block = b'' for size_bytes in self.table_size_changes: size_bytes = encode_integer(size_bytes, 5) size_bytes[0] |= 0x20 block += bytes(size_bytes) self.table_size_changes = [] return block class Decoder: """ An HPACK decoder object. .. versionchanged:: 2.3.0 Added ``max_header_list_size`` argument. :param max_header_list_size: The maximum decompressed size we will allow for any single header block. This is a protection against DoS attacks that attempt to force the application to expand a relatively small amount of data into a really large header list, allowing enormous amounts of memory to be allocated. If this amount of data is exceeded, a `OversizedHeaderListError <hpack.OversizedHeaderListError>` exception will be raised. At this point the connection should be shut down, as the HPACK state will no longer be usable. Defaults to 64kB. :type max_header_list_size: ``int`` """ def __init__(self, max_header_list_size=DEFAULT_MAX_HEADER_LIST_SIZE): self.header_table = HeaderTable() #: The maximum decompressed size we will allow for any single header #: block. This is a protection against DoS attacks that attempt to #: force the application to expand a relatively small amount of data #: into a really large header list, allowing enormous amounts of memory #: to be allocated. #: #: If this amount of data is exceeded, a `OversizedHeaderListError #: <hpack.OversizedHeaderListError>` exception will be raised. At this #: point the connection should be shut down, as the HPACK state will no #: longer be usable. #: #: Defaults to 64kB. #: #: .. versionadded:: 2.3.0 self.max_header_list_size = max_header_list_size #: Maximum allowed header table size. #: #: A HTTP/2 implementation should set this to the most recent value of #: SETTINGS_HEADER_TABLE_SIZE that it sent *and has received an ACK #: for*. Once this setting is set, the actual header table size will be #: checked at the end of each decoding run and whenever it is changed, #: to confirm that it fits in this size. self.max_allowed_table_size = self.header_table.maxsize @property def header_table_size(self): """ Controls the size of the HPACK header table. """ return self.header_table.maxsize @header_table_size.setter def header_table_size(self, value): self.header_table.maxsize = value def decode(self, data, raw=False): """ Takes an HPACK-encoded header block and decodes it into a header set. :param data: A bytestring representing a complete HPACK-encoded header block. :param raw: (optional) Whether to return the headers as tuples of raw byte strings or to decode them as UTF-8 before returning them. The default value is False, which returns tuples of Unicode strings :returns: A list of two-tuples of ``(name, value)`` representing the HPACK-encoded headers, in the order they were decoded. :raises HPACKDecodingError: If an error is encountered while decoding the header block. """ log.debug("Decoding %s", data) data_mem = memoryview(data) headers = [] data_len = len(data) inflated_size = 0 current_index = 0 while current_index < data_len: # Work out what kind of header we're decoding. # If the high bit is 1, it's an indexed field. current = data[current_index] indexed = True if current & 0x80 else False # Otherwise, if the second-highest bit is 1 it's a field that does # alter the header table. literal_index = True if current & 0x40 else False # Otherwise, if the third-highest bit is 1 it's an encoding context # update. encoding_update = True if current & 0x20 else False if indexed: header, consumed = self._decode_indexed( data_mem[current_index:] ) elif literal_index: # It's a literal header that does affect the header table. header, consumed = self._decode_literal_index( data_mem[current_index:] ) elif encoding_update: # It's an update to the encoding context. These are forbidden # in a header block after any actual header. if headers: raise HPACKDecodingError( "Table size update not at the start of the block" ) consumed = self._update_encoding_context( data_mem[current_index:] ) header = None else: # It's a literal header that does not affect the header table. header, consumed = self._decode_literal_no_index( data_mem[current_index:] ) if header: headers.append(header) inflated_size += table_entry_size(*header) if inflated_size > self.max_header_list_size: raise OversizedHeaderListError( "A header list larger than %d has been received" % self.max_header_list_size ) current_index += consumed # Confirm that the table size is lower than the maximum. We do this # here to ensure that we catch when the max has been *shrunk* and the # remote peer hasn't actually done that. self._assert_valid_table_size() try: return [_unicode_if_needed(h, raw) for h in headers] except UnicodeDecodeError: raise HPACKDecodingError("Unable to decode headers as UTF-8.") def _assert_valid_table_size(self): """ Check that the table size set by the encoder is lower than the maximum we expect to have. """ if self.header_table_size > self.max_allowed_table_size: raise InvalidTableSizeError( "Encoder did not shrink table size to within the max" ) def _update_encoding_context(self, data): """ Handles a byte that updates the encoding context. """ # We've been asked to resize the header table. new_size, consumed = decode_integer(data, 5) if new_size > self.max_allowed_table_size: raise InvalidTableSizeError( "Encoder exceeded max allowable table size" ) self.header_table_size = new_size return consumed def _decode_indexed(self, data): """ Decodes a header represented using the indexed representation. """ index, consumed = decode_integer(data, 7) header = HeaderTuple(*self.header_table.get_by_index(index)) log.debug("Decoded %s, consumed %d", header, consumed) return header, consumed def _decode_literal_no_index(self, data): return self._decode_literal(data, False) def _decode_literal_index(self, data): return self._decode_literal(data, True) def _decode_literal(self, data, should_index): """ Decodes a header represented with a literal. """ total_consumed = 0 # When should_index is true, if the low six bits of the first byte are # nonzero, the header name is indexed. # When should_index is false, if the low four bits of the first byte # are nonzero the header name is indexed. if should_index: indexed_name = data[0] & 0x3F name_len = 6 not_indexable = False else: high_byte = data[0] indexed_name = high_byte & 0x0F name_len = 4 not_indexable = high_byte & 0x10 if indexed_name: # Indexed header name. index, consumed = decode_integer(data, name_len) name = self.header_table.get_by_index(index)[0] total_consumed = consumed length = 0 else: # Literal header name. The first byte was consumed, so we need to # move forward. data = data[1:] length, consumed = decode_integer(data, 7) name = data[consumed:consumed + length] if len(name) != length: raise HPACKDecodingError("Truncated header block") if data[0] & 0x80: name = decode_huffman(name) total_consumed = consumed + length + 1 # Since we moved forward 1. data = data[consumed + length:] # The header value is definitely length-based. length, consumed = decode_integer(data, 7) value = data[consumed:consumed + length] if len(value) != length: raise HPACKDecodingError("Truncated header block") if data[0] & 0x80: value = decode_huffman(value) # Updated the total consumed length. total_consumed += length + consumed # If we have been told never to index the header field, encode that in # the tuple we use. if not_indexable: header = NeverIndexedHeaderTuple(name, value) else: header = HeaderTuple(name, value) # If we've been asked to index this, add it to the header table. if should_index: self.header_table.add(name, value) log.debug( "Decoded %s, total consumed %d bytes, indexed %s", header, total_consumed, should_index ) return header, total_consumed