def __init__(self, *args, **kargs): super(VOPServerBridge, self).__init__(*args, **kargs) self.__HSHAKE_MAXLEN = 64 self.__have_client_hello = False self.__buf = VByteBuffer() self.__negotiated_factory = None
def __init__(self, reactor, buf_len=4096): self.__reactor = reactor self.__buf_len = buf_len self.__bc_consumed = 0 self.__bc_consume_lim = 0 self.__bc_producer = None self.__bc_eod = False self.__bc_eod_clean = None self.__bc_rbuf = VByteBuffer() self.__bc_rbuf_len = buf_len self.__bc_reader = None self.__bc_aborted = False self.__bc_cond = Condition() self.__bc_scheduled_lim_update = False self.__bp_produced = 0 self.__bp_produce_lim = 0 self.__bp_consumer = None self.__bp_eod = False self.__bp_eod_clean = None self.__bp_wbuf = VByteBuffer() self.__bp_wbuf_len = buf_len self.__bp_writer = None self.__bp_sent_eod = False self.__bp_aborted = False self.__bp_cond = Condition() self.__bp_scheduled_produce = False self.__bc_iface = self.__bp_iface = None # Set up a local logger for convenience self.__logger = VLogger(prefix='ByteChannel') self.__logger.add_watcher(self.reactor.log)
class VConstantGenerator(VByteGenerator): """Generates a constant repeating data output. :param pattern: a byte pattern :type pattern: bytes Generator output will be an infinitely recurring sequence of *pattern* \ . """ def __init__(self, pattern): if not isinstance(pattern, bytes) or not pattern: raise TypeError('Pattern must be non-empty bytes object') self.__pattern = pattern self.__cache = VByteBuffer() def data(self, num_bytes): result = [] bytes_left = num_bytes while bytes_left: if not self.__cache: self.__cache.append(self.__pattern) data = self.__cache.pop(bytes_left) result.append(data) bytes_left -= len(data) return b''.join(result)
def __init__(self, blocksize, start_value=None): if blocksize <= 0: raise TypeError('Blocksize must be >= 1') self._blocksize = blocksize if start_value is not None: if (not isinstance(start_value, bytes) or len(start_value) != blocksize): raise TypeError('Start value must be blocksize bytes') self._block = start_value else: self._block = b'\x00' * blocksize self.__cache = VByteBuffer() self.__cache.append(self._block)
def __init__(self, *args, **kargs): super(VOPClientBridge, self).__init__(*args, **kargs) self.__HSHAKE_MAXLEN = 64 self.__sent_client_hello = False self.__have_server_response = False self.__buf = VByteBuffer() # Set up client hello message based on enabled protocols self.__buf.append(b'VOP_DRAFT-0.8 TRANSPORTS') if self._vts_factory: self.__buf.append(b':VTS') if self._tls_factory: self.__buf.append(b':TLS') if self._allow_insecure: self.__buf.append(b':PLAIN') self.__buf.append(b'\n')
def __init__(self, reactor, sock=None, hc_pol=None, close_cback=None, connected=False, max_read=0x4000, max_write=0x4000, wbuf_len=None): self._max_read = max_read self._max_write = max_write self._wbuf = VByteBuffer() if wbuf_len is None: wbuf_len = max_write self._wbuf_len = wbuf_len self._ci = None self._ci_eod = False self._ci_eod_clean = None self._ci_producer = None self._ci_consumed = 0 self._ci_lim_sent = 0 self._ci_aborted = False self._pi = None self._pi_closed = False self._pi_consumer = None self._pi_produced = 0 self._pi_prod_lim = 0 self._pi_buffer = VByteBuffer() self._pi_aborted = False # Parent __init__ must be called after local attributes are # initialized due to overloaded methods called during construction super_init = super(VClientSocketAgent, self).__init__ super_init(reactor=reactor, sock=sock, hc_pol=hc_pol, close_cback=close_cback, connected=connected)
class VTransformer(VByteGenerator): """Performs block transformation applies on another generator's output. :param in_gen: generator for transform input data :type in_gen: :class:`VByteGenerator` :param transform: a transform function :type transform: callable :param blocksize: blocksize for transform input data :type blocksize: int The parameter *transform* should be a callable which takes a bytes object as input and returns an output block of the transform. If *blocksize* is None then it is assumed that the transform operates on arbitrary-length inputs. Otherwise input data from *in_gen* is fed to the transform in blocks of *blocksize* length. """ def __init__(self, in_gen, transform, blocksize=None): self.__input = in_gen self.__transform = transform self.__blocksize = blocksize self.__cache = VByteBuffer() def data(self, num_bytes): result = [] bytes_left = num_bytes while bytes_left: if not self.__cache: if self.__blocksize is None: data = self.__input(bytes_left) else: data = self.__input(self.__blocksize) block = self.__transform(data) self.__cache.append(block) data = self.__cache.pop(bytes_left) result.append(data) bytes_left -= len(data) return b''.join(result)
class VPseudoRandomHMAC(VByteGenerator): """Generates pseudo-random data based on :term:`HMAC`\ . :param hash_cls: hash class for :term:`HMAC` algorithm :type hash_cls: :class:`versile.crypto.VHash` :param secret: :term:`HMAC` secret :type secret: bytes :param seed: PRF seed :type seed: bytes Implements the :term:`HMAC` based pseudo-random function defined by :rfc:`5246`\ . """ def __init__(self, hash_cls, secret, seed): self._hash_cls = hash_cls self._secret = secret self._seed = seed self._pr_data_buff = VByteBuffer() self._a = seed # A_i from RFC 5246, initialized as A_0 @abstract def data(self, num_bytes): result = [] num_left = num_bytes while num_left > 0: if self._pr_data_buff: d = self._pr_data_buff.pop(num_left) result.append(d) num_left -= len(d) else: # Compute next A_i self._a = self._hash_cls.hmac(self._secret, self._a + self._seed) # Generate next block of output data hmac = self._hash_cls.hmac(self._secret, self._a + self._seed) self._pr_data_buff.append(hmac) return b''.join(result)
class VHashReducer(VByteGenerator): """Performs hash reduction on data from another generator. Operates on a hash method with a given blocksize. Each new block of output data is generated by taking a number of blocks of data from the input generator and computing a hash digest. By tuning the ratio between data which is fed into the hash function and the output that is provided, the entropy per output byte can be increased. This can be useful for converting a source of low but uniform entropy into higher-entropy data. :param in_gen: a generator of input data for the hasher :type in_gen: :class:`VByteGenerator` :param hasher: a hasher object :type hasher: :class:`versile.crypto.VHash` :param ratio: the ratio of input data read to output data produced :type ratio: int """ def __init__(self, in_gen, hasher, ratio): self.__input = in_gen self.__hasher = hasher self.__digest_size = hasher.digest_size() self.__ratio = ratio self.__cache = VByteBuffer() def data(self, num_bytes): result = [] bytes_left = num_bytes while bytes_left: if not self.__cache: data = self.__input(self.__ratio * self.__digest_size) self.__hasher.update(data) self.__cache.append(self.__hasher.digest()) data = self.__cache.pop(bytes_left) result.append(data) bytes_left -= len(data) return b''.join(result)
def __init__(self, reactor, read_fd, write_fd, max_read=0x4000, max_write=0x4000, wbuf_len=None): self.__reactor = reactor self._reader = _VAgentReader(self, reactor, read_fd) self._writer = _VAgentWriter(self, reactor, write_fd) self._reader.set_pipe_peer(self._writer) self._writer.set_pipe_peer(self._reader) self._max_read = max_read self._max_write = max_write self._wbuf = VByteBuffer() if wbuf_len is None: wbuf_len = max_write self._wbuf_len = wbuf_len self._ci = None self._ci_eod = False self._ci_eod_clean = None self._ci_producer = None self._ci_consumed = 0 self._ci_lim_sent = 0 self._ci_aborted = False self._pi = None self._pi_closed = False self._pi_consumer = None self._pi_produced = 0 self._pi_prod_lim = 0 self._pi_buffer = VByteBuffer() self._pi_aborted = False
def __init__(self, decrypter, hash_cls, mac_secret): self._decrypter = decrypter self._hash_cls = hash_cls self._mac_secret = mac_secret self._max_plaintext_len = 0x10000 # HARDCODED 2-byte message length self._cipher_blocksize = decrypter.blocksize self._hash_len = hash_cls.digest_size() self._read_buf = VByteBuffer() self._in_buf = VByteBuffer() self._msg_buf = VByteBuffer() self._have_len = False self._plaintext_blocksize = None self._plaintext_len = None self._invalid = False self._result = None self._msg_num = 0
class VClientSocketAgent(VClientSocket): """A :class:`VClientSocket` with a byte producer/consumer interface. :param max_read: max bytes fetched per socket read :type max_read: int :param max_write: max bytes written per socket send :type max_write: int :param wbuf_len: buffer size of data held for writing (or None) :type wbuf_len: int *max_read* is also the maximum size of the buffer for data read from the socket (so maximum bytes read in one read operation is *max_read* minus the amount of data currently held in the receive buffer). If *wbuf_len* is None then *max_write* is used as the buffer size. """ def __init__(self, reactor, sock=None, hc_pol=None, close_cback=None, connected=False, max_read=0x4000, max_write=0x4000, wbuf_len=None): self._max_read = max_read self._max_write = max_write self._wbuf = VByteBuffer() if wbuf_len is None: wbuf_len = max_write self._wbuf_len = wbuf_len self._ci = None self._ci_eod = False self._ci_eod_clean = None self._ci_producer = None self._ci_consumed = 0 self._ci_lim_sent = 0 self._ci_aborted = False self._pi = None self._pi_closed = False self._pi_consumer = None self._pi_produced = 0 self._pi_prod_lim = 0 self._pi_buffer = VByteBuffer() self._pi_aborted = False # Parent __init__ must be called after local attributes are # initialized due to overloaded methods called during construction super_init = super(VClientSocketAgent, self).__init__ super_init(reactor=reactor, sock=sock, hc_pol=hc_pol, close_cback=close_cback, connected=connected) @property def byte_consume(self): """Holds a :class:`IVByteConsumer` interface to the socket.""" if not self._ci: ci = _VSocketConsumer(self) self._ci = weakref.ref(ci) return ci else: ci = self._ci() if ci: return ci else: ci = _VSocketConsumer(self) self._ci = weakref.ref(ci) return ci @property def byte_produce(self): """Holds a :class:`IVByteProducer` interface to the socket.""" if not self._pi: pi = _VSocketProducer(self) self._pi = weakref.ref(pi) return pi else: pi = self._pi() if pi: return pi else: pi = _VSocketProducer(self) self._pi = weakref.ref(pi) return pi @property def byte_io(self): """Byte interface (\ :class:`versile.reactor.io.VByteIOPair`\ ).""" return VByteIOPair(self.byte_consume, self.byte_produce) def _can_connect(self, peer): """Called internally to validate whether a connection can be made. :param peer: peer to connect to :type peer: :class:`versile.common.peer.VPeer` :returns: True if connection is allowed :rtype: bool If the socket is connected to a byte consumer, sends a control request for 'can_connect(peer)'. If that control message returns a boolean, this is used as the _can_connect result. Otherwise, True is returned. """ if self._pi_consumer: try: return self._pi_consumer.control.can_connect(peer) except VIOMissingControl: return True else: return True def _sock_was_connected(self): super(VClientSocketAgent, self)._sock_was_connected() if self._p_consumer: # Notify producer-connected chain about 'connected' status control = self._p_consumer.control def notify(): try: control.connected(self._sock_peer) except VIOMissingControl: pass self.reactor.schedule(0.0, notify) @peer def _c_consume(self, buf, clim): if self._ci_eod: raise VIOClosed('Consumer already reached end-of-data') elif not self._ci_producer: raise VIOError('No connected producer') elif self._ci_consumed >= self._ci_lim_sent: raise VIOError('Consume limit exceeded') elif not buf: raise VIOError('No data to consume') max_cons = self._wbuf_len - len(self._wbuf) max_cons = min(max_cons, self._ci_lim_sent - self._ci_consumed) if clim is not None and clim > 0: max_cons = min(max_cons, clim) was_empty = not self._wbuf indata = buf.pop(max_cons) self._wbuf.append(indata) self._ci_consumed += len(indata) if was_empty: self.start_writing(internal=True) return self._ci_lim_sent def _c_end_consume(self, clean): if self._ci_eod: return self._ci_eod = True self._ci_eod_clean = clean if not self._wbuf: self.close_output(VFIOCompleted()) if self._ci_producer: self._ci_producer.abort() self._c_detach() def _c_abort(self, force=False): if not self._ci_aborted or force: self._ci_aborted = True self._ci_eod = True self._ci_consumed = self._ci_lim_sent = 0 self._wbuf.clear() if not self._sock_out_closed: self.close_output(VFIOCompleted()) if self._ci_producer: self._ci_producer.abort() self._c_detach() def _c_attach(self, producer, rthread=False): # Ensure 'attach' is performed in reactor thread if not rthread: self.reactor.execute(self._c_attach, producer, rthread=True) return if self._ci_producer is producer: return elif self._ci_producer: raise VIOError('Producer already attached') self._ci_producer = producer if self._sock_out_closed: self.reactor.schedule(0.0, self._c_abort, True) else: self._ci_consumed = self._ci_lim_sent = 0 producer.attach(self.byte_consume) self._ci_lim_sent = self._wbuf_len producer.can_produce(self._ci_lim_sent) # Notify attached chain try: producer.control.notify_consumer_attached(self.byte_consume) except VIOMissingControl: pass def _c_detach(self, rthread=False): # Ensure 'detach' is performed in reactor thread if not rthread: self.reactor.execute(self._c_detach, rthread=True) return if self._ci_producer: prod, self._ci_producer = self._ci_producer, None prod.detach() self._ci_consumed = self._ci_lim_sent = 0 def active_do_write(self): if self._wbuf: data = self._wbuf.peek(self._max_write) try: num_written = self.write_some(data) except VIOException: self._c_abort() else: if num_written > 0: self._wbuf.remove(num_written) if self._ci_producer: self._ci_lim_sent = (self._ci_consumed + self._wbuf_len - len(self._wbuf)) self._ci_producer.can_produce(self._ci_lim_sent) if not self._wbuf: self.stop_writing() if self._ci_eod: self._c_abort() else: self.stop_writing() def _output_was_closed(self, reason): # No more output will be written, abort consumer self._c_abort() @property def _c_control(self): return self._c_get_control() # Implements _c_control in order to be able to override _c_control # behavior by overloading as a regular method def _c_get_control(self): return VIOControl() @property def _c_producer(self): return self._ci_producer @property def _c_flows(self): return tuple() @property def _c_twoway(self): return True @property def _c_reverse(self): return self.byte_produce() @peer def _p_can_produce(self, limit): if not self._pi_consumer: raise VIOError('No connected consumer') if limit is None or limit < 0: if (not self._pi_prod_lim is None and not self._pi_prod_lim < 0): if self._pi_produced >= self._pi_prod_lim: self.start_reading(internal=True) self._pi_prod_lim = limit else: if (self._pi_prod_lim is not None and 0 <= self._pi_prod_lim < limit): if self._pi_produced >= self._pi_prod_lim: self.start_reading(internal=True) self._pi_prod_lim = limit def _p_abort(self, force=False): if not self._pi_aborted or force: self._pi_aborted = True self._pi_produced = self._pi_prod_lim = 0 if not self._sock_in_closed: self.close_input(VFIOCompleted()) if self._pi_consumer: self._pi_consumer.abort() self._p_detach() def _p_attach(self, consumer, rthread=False): # Ensure 'attach' is performed in reactor thread if not rthread: self.reactor.execute(self._p_attach, consumer, rthread=True) return if self._pi_consumer is consumer: return elif self._pi_consumer: raise VIOError('Consumer already attached') self._pi_produced = self._pi_prod_lim = 0 self._pi_consumer = consumer consumer.attach(self.byte_produce) # Notify attached chain try: consumer.control.notify_producer_attached(self.byte_produce) except VIOMissingControl: pass # If closed, pass notification if self._sock_in_closed: self.reactor.schedule(0.0, self._p_abort, True) def _p_detach(self, rthread=False): # Ensure 'detach' is performed in reactor thread if not rthread: self.reactor.execute(self._p_detach, rthread=True) return if self._pi_consumer: cons, self._pi_consumer = self._pi_consumer, None cons.detach() self._pi_produced = self._pi_prod_lim = 0 def active_do_read(self): if not self._pi_consumer: self.stop_reading() if self._pi_prod_lim is not None and self._pi_prod_lim >= 0: max_read = self._pi_prod_lim - self._pi_produced else: max_read = self._max_read max_read = min(max_read, self._max_read) if max_read <= 0: self.stop_reading() return try: data = self.read_some(max_read) except Exception as e: self._p_abort() else: self._pi_buffer.append(data) if self._pi_buffer: self.pi_prod_lim = self._pi_consumer.consume(self._pi_buffer) def _input_was_closed(self, reason): if self._pi_consumer: # Notify consumer about end-of-data clean = isinstance(reason, VFIOCompleted) self._pi_consumer.end_consume(clean) else: self._p_abort() @property def _p_control(self): return self._p_get_control() # Implements _p_control in order to be able to override _p_control # behavior by overloading as a regular method def _p_get_control(self): class _Control(VIOControl): def __init__(self, sock): self.__sock = sock def req_producer_state(self, consumer): # Send notification of socket connect status def notify(): if self.__sock._sock_peer: try: consumer.control.connected(self.__sock._sock_peer) except VIOMissingControl: pass self.__sock.reactor.schedule(0.0, notify) return _Control(self) @property def _p_consumer(self): return self._pi_consumer @property def _p_flows(self): return tuple() @property def _p_twoway(self): return True @property def _p_reverse(self): return self.byte_consume()
class VOPClientBridge(VOPBridge): """Client-side channel interface for the :term:`VOP` protocol. Implements the client side of a :term:`VOP` channel. See :class:`VOPBridge` for general information and constructor arguments. """ def __init__(self, *args, **kargs): super(VOPClientBridge, self).__init__(*args, **kargs) self.__HSHAKE_MAXLEN = 64 self.__sent_client_hello = False self.__have_server_response = False self.__buf = VByteBuffer() # Set up client hello message based on enabled protocols self.__buf.append(b'VOP_DRAFT-0.8 TRANSPORTS') if self._vts_factory: self.__buf.append(b':VTS') if self._tls_factory: self.__buf.append(b':TLS') if self._allow_insecure: self.__buf.append(b':PLAIN') self.__buf.append(b'\n') def _handshake_producer_attached(self): # Start listening only if client hello was sent if self.__sent_client_hello: self._ec_cons_lim = self.__HSHAKE_MAXLEN self._ec_producer.can_produce(self._ec_cons_lim) def _handshake_consume(self, data, clim): if (not self.__sent_client_hello or not self._handshaking or self._handshake_error): return num_read = 0 while (data and (clim is None or num_read < clim) and len(self.__buf) < self.__HSHAKE_MAXLEN): _data = data.pop(1) self.__buf.append(_data) self._handshake_consumed += 1 if (_pyver == 2 and _data[0] == b'\n' or _pyver == 3 and _data[0] == 0x0a): self.__have_server_response = True break else: if len(self.__buf) == self.__HSHAKE_MAXLEN: self._handshake_abort() if self.__have_server_response: # Parse the received hello message hello = self.__buf.pop() # Parse hello message and complete handshake hello = hello[:-1] if not hello[:28] == b'VOP_DRAFT-0.8 USE_TRANSPORT:': self._handshake_abort() return proto = hello[28:] if proto == b'VTS': if self._vts_factory: self._logger.debug('Negotiated VTS transport') self._handshake_complete(self._vts_factory) else: self._handshake_abort() elif proto == b'TLS': if self._tls_factory: self._logger.debug('Negotiated TLS transport') self._handshake_complete(self._tls_factory) else: self._handshake_abort() elif proto == b'PLAIN': if self._allow_insecure: self._logger.debug('Negotiated insecure (plaintext) ' + 'transport') self._handshake_complete(None) else: self._handshake_abort() else: self._handshake_abort() def _handshake_can_produce(self): if (not self._handshaking or self._handshake_error or self.__sent_client_hello): return # Send handshake message if (self._ep_consumer and (self._ep_prod_lim < 0 or self._ep_prod_lim > self._handshake_produced)): old_len = len(self.__buf) self._ep_prod_lim = self._ep_consumer.consume(self.__buf) self._handshake_produced += old_len - len(self.__buf) if not self.__buf: self.__sent_client_hello = True if self.__sent_client_hello and self._ec_producer: self._ec_cons_lim = self.__HSHAKE_MAXLEN self._ec_producer.can_produce(self._ec_cons_lim)
class VByteChannel(object): """Producer/consumer end-point for byte data. :param reactor: reactor driving the socket's event handling :param buf_len: buffer length for read operations :type buf_len: int This class is primarily intended for debugging byte producer/consumer I/O chains. """ def __init__(self, reactor, buf_len=4096): self.__reactor = reactor self.__buf_len = buf_len self.__bc_consumed = 0 self.__bc_consume_lim = 0 self.__bc_producer = None self.__bc_eod = False self.__bc_eod_clean = None self.__bc_rbuf = VByteBuffer() self.__bc_rbuf_len = buf_len self.__bc_reader = None self.__bc_aborted = False self.__bc_cond = Condition() self.__bc_scheduled_lim_update = False self.__bp_produced = 0 self.__bp_produce_lim = 0 self.__bp_consumer = None self.__bp_eod = False self.__bp_eod_clean = None self.__bp_wbuf = VByteBuffer() self.__bp_wbuf_len = buf_len self.__bp_writer = None self.__bp_sent_eod = False self.__bp_aborted = False self.__bp_cond = Condition() self.__bp_scheduled_produce = False self.__bc_iface = self.__bp_iface = None # Set up a local logger for convenience self.__logger = VLogger(prefix='ByteChannel') self.__logger.add_watcher(self.reactor.log) def __del__(self): self.__logger.debug('Dereferenced') def recv(self, max_read, timeout=None): """Receive input data from byte channel. :param max_read: max bytes to read (unlimited if None) :type max_read: int :param timeout: timeout in seconds (blocking if None) :type timeout: float :returns: data read (empty if input was closed) :rtype: bytes :raises: :exc:`versile.reactor.io.VIOTimeout`\ , :exc:`versile.reactor.io.VIOError` """ if timeout: start_time = time.time() with self.__bc_cond: while True: if self.__bc_rbuf: if max_read is None: result = self.__bc_rbuf.pop() elif max_read > 0: result = self.__bc_rbuf.pop(max_read) else: result = b'' # Trigger updating can_produce in reactor thread if not self.__bc_scheduled_lim_update: self.__bc_scheduled_lim_update = True self.reactor.schedule(0.0, self.__bc_lim_update) return result elif self.__bc_aborted: raise VIOError('Byte input was aborted') elif self.__bc_eod: if self.__bc_eod_clean: return b'' else: raise VIOError('Byte input was closed but not cleanly') if timeout == 0.0: raise VIOTimeout() elif timeout is not None and timeout > 0.0: current_time = time.time() if current_time > start_time + timeout: raise VIOTimeout() wait_time = start_time + timeout - current_time self.__bc_cond.wait(wait_time) else: self.__bc_cond.wait() def send(self, data, timeout=None): """Receive input data from byte channel. :param data: data to write :type data: bytes :type max_read: int :param timeout: timeout in seconds (blocking if None) :type timeout: float :returns: number bytes written :rtype: int :raises: :exc:`versile.reactor.io.VIOTimeout`\ , :exc:`versile.reactor.io.VIOError` """ if timeout: start_time = time.time() with self.__bp_cond: while True: if self.__bp_aborted: raise VIOError('Byte output was aborted') elif self.__bp_eod: raise VIOError('Byte output was closed') if not data: return 0 max_write = self.__bp_wbuf_len - len(self.__bp_wbuf) if max_write > 0: write_data = data[:max_write] self.__bp_wbuf.append(write_data) # Trigger reactor production if not self.__bp_scheduled_produce: self.__bp_scheduled_produce = True self.reactor.schedule(0.0, self.__bp_do_produce) return len(write_data) if timeout == 0.0: raise VIOTimeout() elif timeout is not None and timeout > 0.0: current_time = time.time() if current_time > start_time + timeout: raise VIOTimeout() wait_time = start_time + timeout - current_time self.__bc_cond.wait(wait_time) else: self.__bc_cond.wait() def close(self): """Closes the connection.""" def _close(): if not self.__bp_aborted and not self.__bp_eod: self.__bp_eod = True self.__bp_eod_clean = True self.__bp_do_produce() if not self.__bc_aborted and not self.__bc_eod: self.__bc_eod = True self.__bc_eod_clean = True self.reactor.schedule(0.0, _close) def abort(self): """Aborts the connection.""" def _abort(): self._bc_abort() self._bp_abort() self.reactor.schedule(0.0, _abort) @property def byte_consume(self): """Holds the Byte Consumer interface to the serializer.""" cons = None if self.__bc_iface: cons = self.__bc_iface() if not cons: cons = _VByteConsumer(self) self.__bc_iface = weakref.ref(cons) return cons @property def byte_produce(self): """Holds the Byte Producer interface to the serializer.""" prod = None if self.__bp_iface: prod = self.__bp_iface() if not prod: prod = _VByteProducer(self) self.__bp_iface = weakref.ref(prod) return prod @property def byte_io(self): """Byte interface (\ :class:`versile.reactor.io.VByteIOPair`\ ).""" return VByteIOPair(self.byte_consume, self.byte_produce) @property def reactor(self): """Holds the object's reactor.""" return self.__reactor @peer def _bc_consume(self, data, clim): if self.__bc_eod: raise VIOError('Consumer already received end-of-data') elif not self._bc_producer: raise VIOError('No connected producer') elif not data: raise VIOError('No data to consume') max_cons = self.__lim(self.__bc_consumed, self.__bc_consume_lim) if max_cons == 0: raise VIOError('Consume limit exceeded') if clim is not None and clim > 0: max_cons = min(max_cons, clim) with self.__bc_cond: buf_len = len(self.__bc_rbuf) self.__bc_rbuf.append_list(data.pop_list(max_cons)) self.__bc_consumed += len(self.__bc_rbuf) - buf_len # Update consume limit max_add = self.__lim(len(self.__bc_rbuf), self.__bc_rbuf_len) if max_add >= 0: self.__bc_consume_lim = self.__bc_consumed + max_add else: self.__bc_consume_lim = -1 # Notify data is available self.__bc_cond.notify_all() return self.__bc_consume_lim @peer def _bc_end_consume(self, clean): if self.__bc_eod: return self.__bc_eod = True self.__bc_eod_clean = clean with self.__bc_cond: self.__bc_cond.notify_all() def _bc_abort(self): if not self.__bc_aborted: with self.__bc_cond: self.__bc_aborted = True self.__bc_eod = True if self.__bc_producer: self.__bc_producer.abort() self._bc_detach() self.__bc_cond.notify_all() def _bc_attach(self, producer, rthread=False): # Ensure 'attach' is performed in reactor thread if not rthread: self.reactor.execute(self._bc_attach, producer, rthread=True) return if self.__bc_producer is producer: return if self.__bc_eod: raise VIOError('Consumer already received end-of-data') elif self.__bc_producer: raise VIOError('Producer already connected') self.__bc_producer = producer self.__bc_consumed = 0 self.__bc_consume_lim = self.__lim(len(self.__bc_rbuf), self.__bc_rbuf_len) producer.attach(self.byte_consume) producer.can_produce(self.__bc_consume_lim) # Notify attached chain try: producer.control.notify_consumer_attached(self.byte_consume) except VIOMissingControl: pass def _bc_detach(self, rthread=False): # Ensure 'detach' is performed in reactor thread if not rthread: self.reactor.execute(self._bc_detach, rthread=True) return if self.__bc_producer: prod, self.__bc_producer = self.__bc_producer, None self.__bc_consumed = self.__bc_consume_lim = 0 prod.detach() @peer def _bp_can_produce(self, limit): if not self.__bp_consumer: raise VIOError('No attached consumer') if limit is None or limit < 0: if (not self.__bp_produce_lim is None and not self.__bp_produce_lim < 0): self.__bp_produce_lim = limit if not self.__bp_scheduled_produce: self.__bp_scheduled_produce = True self.reactor.schedule(0.0, self.__bp_do_produce) else: if (self.__bp_produce_lim is not None and 0 <= self.__bp_produce_lim < limit): self.__bp_produce_lim = limit if not self.__bp_scheduled_produce: self.__bp_scheduled_produce = True self.reactor.schedule(0.0, self.__bp_do_produce) def _bp_abort(self): if not self.__bp_aborted: with self.__bp_cond: self.__bp_aborted = True self.__bp_wbuf.remove() if self.__bp_consumer: self.__bp_consumer.abort() self._bp_detach() self.__bp_cond.notify_all() def _bp_attach(self, consumer, rthread=False): # Ensure 'attach' is performed in reactor thread if not rthread: self.reactor.execute(self._bp_attach, consumer, rthread=True) return if self.__bp_consumer is consumer: return if self.__bp_consumer: raise VIOError('Consumer already attached') elif self.__bp_eod: raise VIOError('Producer already reached end-of-data') self.__bp_consumer = consumer self.__bp_produced = self.__bp_produce_lim = 0 consumer.attach(self.byte_produce) # Notify attached chain try: consumer.control.notify_producer_attached(self.byte_produce) except VIOMissingControl: pass def _bp_detach(self, rthread=False): # Ensure 'detach' is performed in reactor thread if not rthread: self.reactor.execute(self._bp_detach, rthread=True) return if self.__bp_consumer: cons, self.__bp_consumer = self.__bp_consumer, None cons.detach() self.__bp_produced = self.__bp_produce_lim = 0 @property def _bc_control(self): return VIOControl() @property def _bc_producer(self): return self.__bc_producer @property def _bc_flows(self): return (self.entity_produce, ) @property def _bc_twoway(self): return True @property def _bc_reverse(self): return self.byte_produce @property def _bp_control(self): return VIOControl() @property def _bp_consumer(self): return self.__bp_consumer @property def _bp_flows(self): return (self.entity_consume, ) @property def _bp_twoway(self): return True @property def _bp_reverse(self): return self.byte_consume def __bc_lim_update(self): self.__bc_scheduled_lim_update = False if not self.__bc_producer or self.__bc_aborted or self.__bc_eod: return old_lim = self.__bc_consume_lim self.__bc_consume_lim = self.__lim(len(self.__bc_rbuf), self.__bc_rbuf_len) if old_lim != self.__bc_consume_lim: self.__bc_producer.can_produce(self.__bc_consume_lim) def __bp_do_produce(self): self.__bp_scheduled_produce = False if not self.__bp_consumer: return with self.__bp_cond: if self.__bp_eod: # If end-of-data was reached notify consumer if self.__bp_consumer and not self.__bp_sent_eod: self.__bp_consumer.end_consume(self.__bp_eod_clean) self.__bp_sent_eod = True return if (self.__bp_produce_lim is not None and 0 <= self.__bp_produce_lim <= self.__bp_produced): return old_lim = self.__bp_produce_lim max_write = self.__lim(self.__bp_produced, self.__bp_produce_lim) if max_write != 0 and self.__bp_wbuf: old_len = len(self.__bp_wbuf) new_lim = self.__bp_consumer.consume(self.__bp_wbuf) self.__bp_produced += self.__bp_wbuf_len - len(self.__bp_wbuf) self.__bp_produce_lim = new_lim if old_len != len(self.__bp_wbuf): self.__bp_cond.notify_all() # Schedule another if produce limit was updated and buffer has data if self.__bp_wbuf and self.__bp_produce_lim != old_lim: if not self.__bp_scheduled_produce: self.__bp_scheduled_produce = True self.reactor.schedule(0.0, self.__bp_do_produce) @classmethod def __lim(self, base, *lims): """Return smallest (lim-base) limit, or -1 if all limits are <0""" result = -1 for lim in lims: if lim is not None and lim >= 0: lim = max(lim - base, 0) if result < 0: result = lim result = min(result, lim) return result
def __init__(self, hash_cls, secret, seed): self._hash_cls = hash_cls self._secret = secret self._seed = seed self._pr_data_buff = VByteBuffer() self._a = seed # A_i from RFC 5246, initialized as A_0
def __init__(self, in_gen, hasher, ratio): self.__input = in_gen self.__hasher = hasher self.__digest_size = hasher.digest_size() self.__ratio = ratio self.__cache = VByteBuffer()
class VMessageDecrypter(object): """Decrypter for encrypted messages with data integrity check. Decodes encrypted plaintext messages in the format encrypted by :class:`VMessageEncrypter`\ . :param decrypter: transform for decryption :type decrypter: :class:`versile.crypto.VBlockTransform` :param hash_cls: hash class for message integrity hash :type hash_cls: :class:`versile.crypto.VHash` :param mac_secret: secret data for package authentication :type mac_secret: bytes """ def __init__(self, decrypter, hash_cls, mac_secret): self._decrypter = decrypter self._hash_cls = hash_cls self._mac_secret = mac_secret self._max_plaintext_len = 0x10000 # HARDCODED 2-byte message length self._cipher_blocksize = decrypter.blocksize self._hash_len = hash_cls.digest_size() self._read_buf = VByteBuffer() self._in_buf = VByteBuffer() self._msg_buf = VByteBuffer() self._have_len = False self._plaintext_blocksize = None self._plaintext_len = None self._invalid = False self._result = None self._msg_num = 0 def reset(self): """Resets the decrypter to read a new message. :raises: :class:`VCryptoException` Raises an exception if ongoing decryption is not completed. """ if self._result is None: raise VCryptoException('Ongoing decryption not completed') self._read_buf.remove() self._in_buf.remove() self._msg_buf.remove() self._have_len = False self._plaintext_len = None self._invalid = False self._result = None def read(self, data): """Reads encrypted message data. :param data: input data to decrypt and decode :type data: bytes, :class:`versile.common.util.VByteBuffer` :returns: number of bytes read :rtype: int Reads only as much data as is required to complete processing a complete single message. If data is of type :class:`versile.common.util.VByteBuffer` then the data that was read will be popped off the buffer. .. note:: When decryption of one message has completed, :meth:`reset` must be called before a new message can be read. """ if isinstance(data, bytes): read_buf = self._read_buf read_buf.remove() read_buf.append(data) elif isinstance(data, VByteBuffer): read_buf = data else: raise TypeError('Input must be bytes or VByteBuffer') num_read = 0 _pbsize = self._plaintext_blocksize _cbsize = self._cipher_blocksize while read_buf and self._result is None and not self._invalid: # First decode single block to get blocksize if not self._have_len: max_read = _cbsize - len(self._in_buf) enc_data = read_buf.pop(max_read) self._in_buf.append(enc_data) num_read += len(enc_data) if len(self._in_buf) == _cbsize: enc_data = self._in_buf.pop() block = self._decrypter(enc_data) if _pbsize is None: _pbsize = len(block) self._plaintext_blocksize = _pbsize self._msg_buf.append(block) len_bytes = self._msg_buf.peek(2) if _pyver == 2: self._plaintext_len = 1 + ( (_b_ord(len_bytes[0]) << 8) + _b_ord(len_bytes[1])) else: self._plaintext_len = 1 + ( (len_bytes[0] << 8) + len_bytes[1]) self._have_len = True # If we have first block, decrypt more blocks as available/needed if self._have_len: msg_len = 2 + self._plaintext_len + self._hash_len pad_len = msg_len % _pbsize if pad_len: pad_len = _pbsize - pad_len msg_len += pad_len msg_left = msg_len - len(self._msg_buf) blocks_left = msg_left // _pbsize input_left = (blocks_left * _cbsize - len(self._in_buf)) in_data = read_buf.pop(input_left) num_read += len(in_data) self._in_buf.append(in_data) num_decode = len(self._in_buf) num_decode -= num_decode % _cbsize if num_decode > 0: enc_data = self._in_buf.pop(num_decode) self._msg_buf.append(self._decrypter(enc_data)) elif len(self._msg_buf) != msg_len: break if self._have_len and len(self._msg_buf) == msg_len: len_bytes = self._msg_buf.pop(2) plaintext = self._msg_buf.pop(self._plaintext_len) padding = self._msg_buf.pop(pad_len) msg_hash = self._msg_buf.pop(self._hash_len) _mac_msg = b''.join((posint_to_bytes(self._msg_num), len_bytes, plaintext, padding)) if msg_hash == self._hash_cls.hmac(self._mac_secret, _mac_msg): self._result = plaintext self._msg_num += 1 else: self._invalid = True return num_read def done(self): """Returns True if decryption and decoding of a message was done. :returns: True if reading is done :rtype: bool :raises: :exc:`versile.crypto.VCryptoException` Raises an exception if the message failed to verify against the message hash, meaning the message cannot be trusted and could have been tampered with. """ if self._invalid: raise VCryptoException('Message failed to verify') return (self._result is not None) def result(self): """Returns plaintext of a decrypted and decoded message. :returns: decoded plaintext :rtype: bytes :raises: :exc:`versile.crypto.VCryptoException` Should only be called if :meth:`done` indicates message parsing was completed, otherwise an exception may be raised due to incomplete message. Raises an exception if the message failed to verify against the message hash, meaning the message cannot be trusted and may have been tampered with. """ if self._invalid: raise VCryptoException('Message failed to verify') elif self._result is None: raise VCryptoException('Message not yet fully decoded') return self._result def has_data(self): """Returns True if object holds any data :returns: True if holds data :rtype: bool Returns False only if no data has been read since the object was instantiated or since the most recent :meth:`reset`\ . """ return bool(self._read_buf or self._in_buf or self._msg_buf or self._result) @property def max_plaintext_len(self): """Maximum plaintext length allowed in a message.""" return self._max_plaintext_len
class VOPServerBridge(VOPBridge): """Server-side channel interface for the :term:`VOP` protocol. Implements the server side of a :term:`VOP` channel. See :class:`VOPBridge` for general information and constructor arguments. """ def __init__(self, *args, **kargs): super(VOPServerBridge, self).__init__(*args, **kargs) self.__HSHAKE_MAXLEN = 64 self.__have_client_hello = False self.__buf = VByteBuffer() self.__negotiated_factory = None def _handshake_producer_attached(self): # Start listening for handshake message from client self._ec_cons_lim = self.__HSHAKE_MAXLEN self._ec_producer.can_produce(self._ec_cons_lim) def _handshake_consume(self, data, clim): if (self.__have_client_hello or not self._handshaking or self._handshake_error): return num_read = 0 while (data and (clim is None or num_read < clim) and len(self.__buf) < self.__HSHAKE_MAXLEN): _data = data.pop(1) self.__buf.append(_data) self._handshake_consumed += 1 if (_pyver == 2 and _data[0] == b'\n' or _pyver == 3 and _data[0] == 0x0a): self.__have_client_hello = True break else: if len(self.__buf) == self.__HSHAKE_MAXLEN: self._handshake_abort() if self.__have_client_hello: # Parse the received hello message hello = self.__buf.pop() hello = hello[:-1] if not hello[:25] == b'VOP_DRAFT-0.8 TRANSPORTS:': self._handshake_abort() return _protos = hello[25:].split(b':') protos = set() for p in _protos: if p == b'VTS' or p == b'TLS' or p == b'PLAIN': if p not in protos: protos.add(p) continue self._handshake_abort() return if b'VTS' in protos and self._vts_factory: proto = b'VTS' self.__negotiated_factory = self._vts_factory self._logger.debug('Negotiated VTS transport') elif b'TLS' in protos and self._tls_factory: proto = b'TLS' self.__negotiated_factory = self._tls_factory self._logger.debug('Negotiated TLS transport') elif b'PLAIN' in protos and self._allow_insecure: proto = b'PLAIN' self.__negotiated_factory = None self._logger.debug('Negotiated insecure (plaintext) transport') else: self._handshake_abort() return # Prepare protocol return message self.__buf.append(b'VOP_DRAFT-0.8 USE_TRANSPORT:') self.__buf.append(proto) self.__buf.append(b'\n') # Initiate production if self._ep_prod_lim != 0: self.reactor.schedule(0, self._handshake_can_produce) def _handshake_can_produce(self): if (not self._handshaking or self._handshake_error or not self.__have_client_hello): return # Send handshake message if (self._ep_consumer and (self._ep_prod_lim < 0 or self._ep_prod_lim > self._handshake_produced)): old_len = len(self.__buf) self._ep_prod_lim = self._ep_consumer.consume(self.__buf) self._handshake_produced += old_len - len(self.__buf) if not self.__buf: self._handshake_complete(self.__negotiated_factory)
class VIncrementer(VByteGenerator): """Generates blocks of incrementing block integer value. Generator output is a series of block data, where each block is an 'incrementation' of the previous block. :param blocksize: block size :type blocksize: int :param start_value: if not None, an initial block to generate :type start_value: bytes If *start_value* is None, the start block will be only zero-bytes. .. automethod:: _increment """ def __init__(self, blocksize, start_value=None): if blocksize <= 0: raise TypeError('Blocksize must be >= 1') self._blocksize = blocksize if start_value is not None: if (not isinstance(start_value, bytes) or len(start_value) != blocksize): raise TypeError('Start value must be blocksize bytes') self._block = start_value else: self._block = b'\x00' * blocksize self.__cache = VByteBuffer() self.__cache.append(self._block) def data(self, num_bytes): result = [] bytes_left = num_bytes while bytes_left: if not self.__cache: self._block = self._increment(self._block) self.__cache.append(self._block) data = self.__cache.pop(bytes_left) result.append(data) bytes_left -= len(data) return b''.join(result) def _increment(self, block): """Performs an increment of the previously generated block. :param block: input block :returns: output block Default is interpret the input block as an integer and to increment it by '1'. Derived classes can override to implement a different incrementation strategy. """ nums = [_b_ord(c) for c in block] for i in xrange((len(nums) - 1), -1, -1): if nums[i] == 255: nums[i] = 0 else: nums[i] += 1 break else: nums = [0] * len(nums) return b''.join([_s2b(_b_chr(n)) for n in nums])
def __init__(self, pattern): if not isinstance(pattern, bytes) or not pattern: raise TypeError('Pattern must be non-empty bytes object') self.__pattern = pattern self.__cache = VByteBuffer()
def __init__(self, in_gen, transform, blocksize=None): self.__input = in_gen self.__transform = transform self.__blocksize = blocksize self.__cache = VByteBuffer()
class VPipeAgent(object): """Byte producer/consumer interface to a pipe reader/writer pair. :param read_fd: read pipe file descriptor :type read_fd: int :param write_fd: write pipe file descriptor :type write_fd: int :param max_read: max bytes fetched per pipe read :type max_read: int :param max_write: max bytes written per pipe write :type max_write: int :param wbuf_len: buffer size of data held for writing (or None) :type wbuf_len: int The agent creates a :class:`VPipeReader` and :class:`VPipeWriter` for the provided pipe read/write descriptors which it uses for reactor driven pipe I/O communication. *max_read* is also the maximum size of the buffer for data read from the socket (so maximum bytes read in one read operation is *max_read* minus the amount of data currently held in the receive buffer). If *wbuf_len* is None then *max_write* is used as the buffer size. """ def __init__(self, reactor, read_fd, write_fd, max_read=0x4000, max_write=0x4000, wbuf_len=None): self.__reactor = reactor self._reader = _VAgentReader(self, reactor, read_fd) self._writer = _VAgentWriter(self, reactor, write_fd) self._reader.set_pipe_peer(self._writer) self._writer.set_pipe_peer(self._reader) self._max_read = max_read self._max_write = max_write self._wbuf = VByteBuffer() if wbuf_len is None: wbuf_len = max_write self._wbuf_len = wbuf_len self._ci = None self._ci_eod = False self._ci_eod_clean = None self._ci_producer = None self._ci_consumed = 0 self._ci_lim_sent = 0 self._ci_aborted = False self._pi = None self._pi_closed = False self._pi_consumer = None self._pi_produced = 0 self._pi_prod_lim = 0 self._pi_buffer = VByteBuffer() self._pi_aborted = False @property def byte_consume(self): """Holds a :class:`IVByteConsumer` interface to the pipe reader.""" if not self._ci: ci = _VPipeConsumer(self) self._ci = weakref.ref(ci) return ci else: ci = self._ci() if ci: return ci else: ci = _VPipeConsumer(self) self._ci = weakref.ref(ci) return ci @property def byte_produce(self): """Holds a :class:`IVByteProducer` interface to the pipe writer.""" if not self._pi: pi = _VPipeProducer(self) self._pi = weakref.ref(pi) return pi else: pi = self._pi() if pi: return pi else: pi = _VPipeProducer(self) self._pi = weakref.ref(pi) return pi @property def byte_io(self): """Byte interface (\ :class:`versile.reactor.io.VByteIOPair`\ ).""" return VByteIOPair(self.byte_consume, self.byte_produce) @property def reactor(self): """Holds the reactor of the associated reader.""" return self.__reactor @peer def _c_consume(self, buf, clim): if self._ci_eod: raise VIOClosed('Consumer already reached end-of-data') elif not self._ci_producer: raise VIOError('No connected producer') elif self._ci_consumed >= self._ci_lim_sent: raise VIOError('Consume limit exceeded') elif not buf: raise VIOError('No data to consume') max_cons = self._wbuf_len - len(self._wbuf) max_cons = min(max_cons, self._ci_lim_sent - self._ci_consumed) if clim is not None and clim > 0: max_cons = min(max_cons, clim) was_empty = not self._wbuf indata = buf.pop(max_cons) self._wbuf.append(indata) self._ci_consumed += len(indata) if was_empty: self._writer.start_writing(internal=True) return self._ci_lim_sent def _c_end_consume(self, clean): if self._ci_eod: return self._ci_eod = True self._ci_eod_clean = clean if not self._wbuf: self._writer.close_output(VFIOCompleted()) if self._ci_producer: self._ci_producer.abort() self._c_detach() def _c_abort(self): if not self._ci_aborted: self._ci_aborted = True self._ci_eod = True self._ci_consumed = self._ci_lim_sent = 0 self._wbuf.clear() self._writer.close_output(VFIOCompleted()) if self._ci_producer: self._ci_producer.abort() self._c_detach() def _c_attach(self, producer, rthread=False): # Ensure 'attach' is performed in reactor thread if not rthread: self.reactor.execute(self._c_attach, producer, rthread=True) return if self._ci_producer is producer: return elif self._ci_producer: raise VIOError('Producer already attached') self._ci_producer = producer self._ci_consumed = self._ci_lim_sent = 0 producer.attach(self.byte_consume) self._ci_lim_sent = self._wbuf_len producer.can_produce(self._ci_lim_sent) # Notify attached chain try: producer.control.notify_consumer_attached(self.byte_consume) except VIOMissingControl: pass def _c_detach(self, rthread=False): # Ensure 'detach' is performed in reactor thread if not rthread: self.reactor.execute(self._c_detach, rthread=True) return if self._ci_producer: prod, self._ci_producer = self._ci_producer, None prod.detach() self._ci_consumed = self._ci_lim_sent = 0 def _do_write(self): if self._wbuf: data = self._wbuf.peek(self._max_write) try: num_written = self._writer.write_some(data) except VIOException: self._c_abort() else: if num_written > 0: self._wbuf.remove(num_written) if self._ci_producer: self._ci_lim_sent = (self._ci_consumed + self._wbuf_len - len(self._wbuf)) self._ci_producer.can_produce(self._ci_lim_sent) if not self._wbuf: self._writer.stop_writing() if self._ci_eod: self._c_abort() else: self._writer.stop_writing() def _output_was_closed(self, reason): # No more output will be written, abort consumer self._c_abort() @property def _c_control(self): return VIOControl() @property def _c_producer(self): return self._ci_producer @property def _c_flows(self): return tuple() @property def _c_twoway(self): return True @property def _c_reverse(self): return self.byte_produce() @peer def _p_can_produce(self, limit): if not self._pi_consumer: raise VIOError('No connected consumer') if limit is None or limit < 0: if (not self._pi_prod_lim is None and not self._pi_prod_lim < 0): if self._pi_produced >= self._pi_prod_lim: self._reader.start_reading(internal=True) self._pi_prod_lim = limit else: if (self._pi_prod_lim is not None and 0 <= self._pi_prod_lim < limit): if self._pi_produced >= self._pi_prod_lim: self._reader.start_reading(internal=True) self._pi_prod_lim = limit def _p_abort(self): if not self._pi_aborted: self._pi_aborted = True self._pi_produced = self._pi_prod_lim = 0 self._reader.close_input(VFIOCompleted()) if self._pi_consumer: self._pi_consumer.abort() self._p_detach() def _p_attach(self, consumer, rthread=False): # Ensure 'attach' is performed in reactor thread if not rthread: self.reactor.execute(self._p_attach, consumer, rthread=True) return if self._pi_consumer is consumer: return elif self._pi_consumer: raise VIOError('Consumer already attached') self._pi_produced = self._pi_prod_lim = 0 self._pi_consumer = consumer consumer.attach(self.byte_produce) # Notify attached chain try: consumer.control.notify_producer_attached(self.byte_produce) except VIOMissingControl: pass def _p_detach(self, rthread=False): # Ensure 'detach' is performed in reactor thread if not rthread: self.reactor.execute(self._p_detach, rthread=True) return if self._pi_consumer: cons, self._pi_consumer = self._pi_consumer, None cons.detach() self._pi_produced = self._pi_prod_lim = 0 def _do_read(self): if not self._pi_consumer: self._reader.stop_reading() if self._pi_prod_lim is not None and self._pi_prod_lim >= 0: max_read = self._pi_prod_lim - self._pi_produced else: max_read = self._max_read max_read = min(max_read, self._max_read) if max_read <= 0: self._reader.stop_reading() return try: data = self._reader.read_some(max_read) except Exception as e: self._p_abort() else: self._pi_buffer.append(data) if self._pi_buffer: self.pi_prod_lim = self._pi_consumer.consume(self._pi_buffer) def _input_was_closed(self, reason): if self._pi_consumer: # Notify consumer about end-of-data clean = isinstance(reason, VFIOCompleted) self._pi_consumer.end_consume(clean) else: self._p_abort() @property def _p_control(self): class _Control(VIOControl): def __init__(self, obj): self._obj = obj def req_producer_state(self, consumer): # Send 'connected' notification if pipe is not closed def notify(): if (self._obj._reader._fd >= 0 and self._obj._writer._fd >= 0): try: consumer.control.connected(VPipePeer()) except VIOMissingControl: pass self._obj.reactor.schedule(0.0, notify) return _Control(self) @property def _p_consumer(self): return self._pi_consumer @property def _p_flows(self): return tuple() @property def _p_twoway(self): return True @property def _p_reverse(self): return self.byte_consume()