# no unicode_literals, revisit after twisted patch from __future__ import print_function, absolute_import import os, re, sys, time, socket from collections import namedtuple, deque from binascii import hexlify, unhexlify import six from zope.interface import implementer from twisted.python import log from twisted.python.runtime import platformType from twisted.internet import (reactor, interfaces, defer, protocol, endpoints, task, address, error) from twisted.internet.defer import inlineCallbacks, returnValue from twisted.protocols import policies from nacl.secret import SecretBox from hkdf import Hkdf from .errors import InternalError from .timing import DebugTiming from .util import bytes_to_hexstr from . import ipaddrs def HKDF(skm, outlen, salt=None, CTXinfo=b""): return Hkdf(salt, skm).expand(CTXinfo, outlen) class TransitError(Exception): pass class BadHandshake(Exception): pass class TransitClosed(TransitError): pass class BadNonce(TransitError): pass # The beginning of each TCP connection consists of the following handshake # messages. The sender transmits the same text regardless of whether it is on # the initiating/connecting end of the TCP connection, or on the # listening/accepting side. Same for the receiver. # # sender -> receiver: transit sender TXID_HEX ready\n\n # receiver -> sender: transit receiver RXID_HEX ready\n\n # # Any deviations from this result in the socket being closed. The handshake # messages are designed to provoke an invalid response from other sorts of # servers (HTTP, SMTP, echo). # # If the sender is satisfied with the handshake, and this is the first socket # to complete negotiation, the sender does: # # sender -> receiver: go\n # # and the next byte on the wire will be from the application. # # If this is not the first socket, the sender does: # # sender -> receiver: nevermind\n # # and closes the socket. # So the receiver looks for "transit sender TXID_HEX ready\n\ngo\n" and hangs # up upon the first wrong byte. The sender lookgs for "transit receiver # RXID_HEX ready\n\n" and then makes a first/not-first decision about sending # "go\n" or "nevermind\n"+close(). def build_receiver_handshake(key): hexid = HKDF(key, 32, CTXinfo=b"transit_receiver") return b"transit receiver "+hexlify(hexid)+b" ready\n\n" def build_sender_handshake(key): hexid = HKDF(key, 32, CTXinfo=b"transit_sender") return b"transit sender "+hexlify(hexid)+b" ready\n\n" def build_sided_relay_handshake(key, side): assert isinstance(side, type(u"")) assert len(side) == 8*2 token = HKDF(key, 32, CTXinfo=b"transit_relay_token") return b"please relay "+hexlify(token)+b" for side "+side.encode("ascii")+b"\n" # These namedtuples are "hint objects". The JSON-serializable dictionaries # are "hint dicts". # DirectTCPV1Hint and TorTCPV1Hint mean the following protocol: # * make a TCP connection (possibly via Tor) # * send the sender/receiver handshake bytes first # * expect to see the receiver/sender handshake bytes from the other side # * the sender writes "go\n", the receiver waits for "go\n" # * the rest of the connection contains transit data DirectTCPV1Hint = namedtuple("DirectTCPV1Hint", ["hostname", "port", "priority"]) TorTCPV1Hint = namedtuple("TorTCPV1Hint", ["hostname", "port", "priority"]) # RelayV1Hint contains a tuple of DirectTCPV1Hint and TorTCPV1Hint hints (we # use a tuple rather than a list so they'll be hashable into a set). For each # one, make the TCP connection, send the relay handshake, then complete the # rest of the V1 protocol. Only one hint per relay is useful. RelayV1Hint = namedtuple("RelayV1Hint", ["hints"]) def describe_hint_obj(hint): if isinstance(hint, DirectTCPV1Hint): return u"tcp:%s:%d" % (hint.hostname, hint.port) elif isinstance(hint, TorTCPV1Hint): return u"tor:%s:%d" % (hint.hostname, hint.port) else: return str(hint) def parse_hint_argv(hint, stderr=sys.stderr): assert isinstance(hint, type(u"")) # return tuple or None for an unparseable hint priority = 0.0 mo = re.search(r'^([a-zA-Z0-9]+):(.*)$', hint) if not mo: print("unparseable hint '%s'" % (hint,), file=stderr) return None hint_type = mo.group(1) if hint_type != "tcp": print("unknown hint type '%s' in '%s'" % (hint_type, hint), file=stderr) return None hint_value = mo.group(2) pieces = hint_value.split(":") if len(pieces) < 2: print("unparseable TCP hint (need more colons) '%s'" % (hint,), file=stderr) return None mo = re.search(r'^(\d+)$', pieces[1]) if not mo: print("non-numeric port in TCP hint '%s'" % (hint,), file=stderr) return None hint_host = pieces[0] hint_port = int(pieces[1]) for more in pieces[2:]: if more.startswith("priority="): more_pieces = more.split("=") try: priority = float(more_pieces[1]) except ValueError: print("non-float priority= in TCP hint '%s'" % (hint,), file=stderr) return None return DirectTCPV1Hint(hint_host, hint_port, priority) TIMEOUT = 60 # seconds @implementer(interfaces.IProducer, interfaces.IConsumer) class Connection(protocol.Protocol, policies.TimeoutMixin): def __init__(self, owner, relay_handshake, start, description): self.state = "too-early" self.buf = b"" self.owner = owner self.relay_handshake = relay_handshake self.start = start self._description = description self._negotiation_d = defer.Deferred(self._cancel) self._error = None self._consumer = None self._consumer_bytes_written = 0 self._consumer_bytes_expected = None self._consumer_deferred = None self._inbound_records = deque() self._waiting_reads = deque() def connectionMade(self): self.setTimeout(TIMEOUT) # does timeoutConnection() when it expires self.factory.connectionWasMade(self) def startNegotiation(self): if self.relay_handshake is not None: self.transport.write(self.relay_handshake) self.state = "relay" else: self.state = "start" self.dataReceived(b"") # cycle the state machine return self._negotiation_d def _cancel(self, d): self.state = "hung up" # stop reacting to anything further self._error = defer.CancelledError() self.transport.loseConnection() # if connectionLost isn't called synchronously, then our # self._negotiation_d will have been errbacked by Deferred.cancel # (which is our caller). So if it's still around, clobber it if self._negotiation_d: self._negotiation_d = None def dataReceived(self, data): try: self._dataReceived(data) except Exception as e: self.setTimeout(None) self._error = e self.transport.loseConnection() self.state = "hung up" if not isinstance(e, BadHandshake): raise def _check_and_remove(self, expected): # any divergence is a handshake error if not self.buf.startswith(expected[:len(self.buf)]): raise BadHandshake("got %r want %r" % (self.buf, expected)) if len(self.buf) < len(expected): return False # keep waiting self.buf = self.buf[len(expected):] return True def _dataReceived(self, data): # protocol is: # (maybe: send relay handshake, wait for ok) # send (send|receive)_handshake # wait for (receive|send)_handshake # sender: decide, send "go" or hang up # receiver: wait for "go" self.buf += data assert self.state != "too-early" if self.state == "relay": if not self._check_and_remove(b"ok\n"): return self.state = "start" if self.state == "start": self.transport.write(self.owner._send_this()) self.state = "handshake" if self.state == "handshake": if not self._check_and_remove(self.owner._expect_this()): return self.state = self.owner.connection_ready(self) # If we're the receiver, we'll be moved to state # "wait-for-decision", which means we're waiting for the other # side (the sender) to make a decision. If we're the sender, # we'll either be moved to state "go" (send GO and move directly # to state "records") or state "nevermind" (send NEVERMIND and # hang up). if self.state == "wait-for-decision": if not self._check_and_remove(b"go\n"): return self._negotiationSuccessful() if self.state == "go": GO = b"go\n" self.transport.write(GO) self._negotiationSuccessful() if self.state == "nevermind": self.transport.write(b"nevermind\n") raise BadHandshake("abandoned") if self.state == "records": return self.dataReceivedRECORDS() if self.state == "hung up": return if isinstance(self.state, Exception): # for tests raise self.state raise ValueError("internal error: unknown state %s" % (self.state,)) def _negotiationSuccessful(self): self.state = "records" self.setTimeout(None) send_key = self.owner._sender_record_key() self.send_box = SecretBox(send_key) self.send_nonce = 0 receive_key = self.owner._receiver_record_key() self.receive_box = SecretBox(receive_key) self.next_receive_nonce = 0 d, self._negotiation_d = self._negotiation_d, None d.callback(self) def dataReceivedRECORDS(self): while True: if len(self.buf) < 4: return length = int(hexlify(self.buf[:4]), 16) if len(self.buf) < 4+length: return encrypted, self.buf = self.buf[4:4+length], self.buf[4+length:] record = self._decrypt_record(encrypted) self.recordReceived(record) def _decrypt_record(self, encrypted): nonce_buf = encrypted[:SecretBox.NONCE_SIZE] # assume it's prepended nonce = int(hexlify(nonce_buf), 16) if nonce != self.next_receive_nonce: raise BadNonce("received out-of-order record: got %d, expected %d" % (nonce, self.next_receive_nonce)) self.next_receive_nonce += 1 record = self.receive_box.decrypt(encrypted) return record def describe(self): return self._description def send_record(self, record): if not isinstance(record, type(b"")): raise InternalError assert SecretBox.NONCE_SIZE == 24 assert self.send_nonce < 2**(8*24) assert len(record) < 2**(8*4) nonce = unhexlify("%048x" % self.send_nonce) # big-endian self.send_nonce += 1 encrypted = self.send_box.encrypt(record, nonce) length = unhexlify("%08x" % len(encrypted)) # always 4 bytes long self.transport.write(length) self.transport.write(encrypted) def recordReceived(self, record): if self._consumer: self._writeToConsumer(record) return self._inbound_records.append(record) self._deliverRecords() def receive_record(self): d = defer.Deferred() self._waiting_reads.append(d) self._deliverRecords() return d def _deliverRecords(self): while self._inbound_records and self._waiting_reads: r = self._inbound_records.popleft() d = self._waiting_reads.popleft() d.callback(r) def close(self): self.transport.loseConnection() while self._waiting_reads: d = self._waiting_reads.popleft() d.errback(error.ConnectionClosed()) def timeoutConnection(self): self._error = BadHandshake("timeout") self.transport.loseConnection() def connectionLost(self, reason=None): self.setTimeout(None) d, self._negotiation_d = self._negotiation_d, None # the Deferred is only relevant until negotiation finishes, so skip # this if it's alredy been fired if d: # Each call to loseConnection() sets self._error first, so we can # deliver useful information to the Factory that's waiting on # this (although they'll generally ignore the specific error, # except for logging unexpected ones). The possible cases are: # # cancel: defer.CancelledError # far-end disconnect: BadHandshake("connection lost") # handshake error (something we didn't like): BadHandshake(what) # other error: some other Exception # timeout: BadHandshake("timeout") d.errback(self._error or BadHandshake("connection lost")) if self._consumer_deferred: self._consumer_deferred.errback(error.ConnectionClosed()) # IConsumer methods, for outbound flow-control. We pass these through to # the transport. The 'producer' is something like a t.p.basic.FileSender def registerProducer(self, producer, streaming): assert interfaces.IConsumer.providedBy(self.transport) self.transport.registerProducer(producer, streaming) def unregisterProducer(self): self.transport.unregisterProducer() def write(self, data): self.send_record(data) # IProducer methods, for inbound flow-control. We pass these through to # the transport. def stopProducing(self): self.transport.stopProducing() def pauseProducing(self): self.transport.pauseProducing() def resumeProducing(self): self.transport.resumeProducing() # Helper methods def connectConsumer(self, consumer, expected=None): """Helper method to glue an instance of e.g. t.p.ftp.FileConsumer to us. Inbound records will be written as bytes to the consumer. Set 'expected' to an integer to automatically disconnect when at least that number of bytes have been written. This function will then return a Deferred (that fires with the number of bytes actually received). If the connection is lost while this Deferred is outstanding, it will errback. If 'expected' is 0, the Deferred will fire right away. If 'expected' is None, then this function returns None instead of a Deferred, and you must call disconnectConsumer() when you are done.""" if self._consumer: raise RuntimeError("A consumer is already attached: %r" % self._consumer) # be aware of an ordering hazard: when we call the consumer's # .registerProducer method, they are likely to immediately call # self.resumeProducing, which we'll deliver to self.transport, which # might call our .dataReceived, which may cause more records to be # available. By waiting to set self._consumer until *after* we drain # any pending records, we avoid delivering records out of order, # which would be bad. consumer.registerProducer(self, True) # There might be enough data queued to exceed 'expected' before we # leave this function. We must be sure to register the producer # before it gets unregistered. self._consumer = consumer self._consumer_bytes_written = 0 self._consumer_bytes_expected = expected d = None if expected is not None: d = defer.Deferred() self._consumer_deferred = d if expected == 0: # write empty record to kick consumer into shutdown self._writeToConsumer(b"") # drain any pending records while self._consumer and self._inbound_records: r = self._inbound_records.popleft() self._writeToConsumer(r) return d def _writeToConsumer(self, record): self._consumer.write(record) self._consumer_bytes_written += len(record) if self._consumer_bytes_expected is not None: if self._consumer_bytes_written >= self._consumer_bytes_expected: d = self._consumer_deferred self.disconnectConsumer() d.callback(self._consumer_bytes_written) def disconnectConsumer(self): self._consumer.unregisterProducer() self._consumer = None self._consumer_bytes_expected = None self._consumer_deferred = None # Helper method to write a known number of bytes to a file. This has no # flow control: the filehandle cannot push back. 'progress' is an # optional callable which will be called on each write (with the number # of bytes written). Returns a Deferred that fires (with the number of # bytes written) when the count is reached or the RecordPipe is closed. def writeToFile(self, f, expected, progress=None, hasher=None): fc = FileConsumer(f, progress, hasher) return self.connectConsumer(fc, expected) class OutboundConnectionFactory(protocol.ClientFactory): protocol = Connection def __init__(self, owner, relay_handshake, description): self.owner = owner self.relay_handshake = relay_handshake self._description = description self.start = time.time() def buildProtocol(self, addr): p = self.protocol(self.owner, self.relay_handshake, self.start, self._description) p.factory = self return p def connectionWasMade(self, p): # outbound connections are handled via the endpoint pass class InboundConnectionFactory(protocol.ClientFactory): protocol = Connection def __init__(self, owner): self.owner = owner self.start = time.time() self._inbound_d = defer.Deferred(self._cancel) self._pending_connections = set() def whenDone(self): return self._inbound_d def _cancel(self, inbound_d): self._shutdown() # our _inbound_d will be errbacked by Deferred.cancel() def _shutdown(self): for d in list(self._pending_connections): d.cancel() # that fires _remove and _proto_failed def _describePeer(self, addr): if isinstance(addr, address.HostnameAddress): return "<-%s:%d" % (addr.hostname, addr.port) elif isinstance(addr, (address.IPv4Address, address.IPv6Address)): return "<-%s:%d" % (addr.host, addr.port) return "<-%r" % addr def buildProtocol(self, addr): p = self.protocol(self.owner, None, self.start, self._describePeer(addr)) p.factory = self return p def connectionWasMade(self, p): d = p.startNegotiation() self._pending_connections.add(d) d.addBoth(self._remove, d) d.addCallbacks(self._proto_succeeded, self._proto_failed) def _remove(self, res, d): self._pending_connections.remove(d) return res def _proto_succeeded(self, p): self._shutdown() self._inbound_d.callback(p) def _proto_failed(self, f): # ignore these two, let Twisted log everything else f.trap(BadHandshake, defer.CancelledError) pass def allocate_tcp_port(): """Return an (integer) available TCP port on localhost. This briefly listens on the port in question, then closes it right away.""" # We want to bind() the socket but not listen(). Twisted (in # tcp.Port.createInternetSocket) would do several other things: # non-blocking, close-on-exec, and SO_REUSEADDR. We don't need # non-blocking because we never listen on it, and we don't need # close-on-exec because we close it right away. So just add SO_REUSEADDR. s = socket.socket(socket.AF_INET, socket.SOCK_STREAM) if platformType == "posix" and sys.platform != "cygwin": s.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) s.bind(("127.0.0.1", 0)) port = s.getsockname()[1] s.close() return port class _ThereCanBeOnlyOne: """Accept a list of contender Deferreds, and return a summary Deferred. When the first contender fires successfully, cancel the rest and fire the summary with the winning contender's result. If all error, errback the summary. status_cb=? """ def __init__(self, contenders): self._remaining = set(contenders) self._winner_d = defer.Deferred(self._cancel) self._first_success = None self._first_failure = None self._have_winner = False self._fired = False def _cancel(self, _): for d in list(self._remaining): d.cancel() # since that will errback everything in _remaining, we'll have hit # _maybe_done() and fired self._winner_d by this point def run(self): for d in list(self._remaining): d.addBoth(self._remove, d) d.addCallbacks(self._succeeded, self._failed) d.addCallback(self._maybe_done) return self._winner_d def _remove(self, res, d): self._remaining.remove(d) return res def _succeeded(self, res): self._have_winner = True self._first_success = res for d in list(self._remaining): d.cancel() def _failed(self, f): if self._first_failure is None: self._first_failure = f def _maybe_done(self, _): if self._remaining: return if self._fired: return self._fired = True if self._have_winner: self._winner_d.callback(self._first_success) else: self._winner_d.errback(self._first_failure) def there_can_be_only_one(contenders): return _ThereCanBeOnlyOne(contenders).run() class Common: RELAY_DELAY = 2.0 TRANSIT_KEY_LENGTH = SecretBox.KEY_SIZE def __init__(self, transit_relay, no_listen=False, tor=None, reactor=reactor, timing=None): self._side = bytes_to_hexstr(os.urandom(8)) # unicode if transit_relay: if not isinstance(transit_relay, type(u"")): raise InternalError # TODO: allow multiple hints for a single relay relay_hint = parse_hint_argv(transit_relay) relay = RelayV1Hint(hints=(relay_hint,)) self._transit_relays = [relay] else: self._transit_relays = [] self._their_direct_hints = [] # hintobjs self._our_relay_hints = set(self._transit_relays) self._tor = tor self._transit_key = None self._no_listen = no_listen self._waiting_for_transit_key = [] self._listener = None self._winner = None self._reactor = reactor self._timing = timing or DebugTiming() self._timing.add("transit") def _build_listener(self): if self._no_listen or self._tor: return ([], None) portnum = allocate_tcp_port() addresses = ipaddrs.find_addresses() non_loopback_addresses = [a for a in addresses if a != "127.0.0.1"] if non_loopback_addresses: # some test hosts, including the appveyor VMs, *only* have # 127.0.0.1, and the tests will hang badly if we remove it. addresses = non_loopback_addresses direct_hints = [DirectTCPV1Hint(six.u(addr), portnum, 0.0) for addr in addresses] ep = endpoints.serverFromString(reactor, "tcp:%d" % portnum) return direct_hints, ep def get_connection_abilities(self): return [{u"type": u"direct-tcp-v1"}, {u"type": u"relay-v1"}, ] @inlineCallbacks def get_connection_hints(self): hints = [] direct_hints = yield self._get_direct_hints() for dh in direct_hints: hints.append({u"type": u"direct-tcp-v1", u"priority": dh.priority, u"hostname": dh.hostname, u"port": dh.port, # integer }) for relay in self._transit_relays: rhint = {u"type": u"relay-v1", u"hints": []} for rh in relay.hints: rhint[u"hints"].append({u"type": u"direct-tcp-v1", u"priority": rh.priority, u"hostname": rh.hostname, u"port": rh.port}) hints.append(rhint) returnValue(hints) def _get_direct_hints(self): if self._listener: return defer.succeed(self._my_direct_hints) # there is a slight race here: if someone calls get_direct_hints() a # second time, before the listener has actually started listening, # then they'll get a Deferred that fires (with the hints) before the # listener starts listening. But most applications won't call this # multiple times, and the race is between 1: the parent Wormhole # protocol getting the connection hints to the other end, and 2: the # listener being ready for connections, and I'm confident that the # listener will win. self._my_direct_hints, self._listener = self._build_listener() if self._listener is None: # don't listen self._listener_d = None return defer.succeed(self._my_direct_hints) # empty # Start the server, so it will be running by the time anyone tries to # connect to the direct hints we return. f = InboundConnectionFactory(self) self._listener_f = f # for tests # XX move to __init__ ? self._listener_d = f.whenDone() d = self._listener.listen(f) def _listening(lp): # lp is an IListeningPort #self._listener_port = lp # for tests def _stop_listening(res): lp.stopListening() return res self._listener_d.addBoth(_stop_listening) return self._my_direct_hints d.addCallback(_listening) return d def _stop_listening(self): # this is for unit tests. The usual control flow (via connect()) # wires the listener's Deferred into a there_can_be_only_one(), which # eats the errback. If we don't ever call connect(), we must catch it # ourselves. self._listener_d.addErrback(lambda f: None) self._listener_d.cancel() def _parse_tcp_v1_hint(self, hint): # hint_struct -> hint_obj hint_type = hint.get(u"type", u"") if hint_type not in [u"direct-tcp-v1", u"tor-tcp-v1"]: log.msg("unknown hint type: %r" % (hint,)) return None if not(u"hostname" in hint and isinstance(hint[u"hostname"], type(u""))): log.msg("invalid hostname in hint: %r" % (hint,)) return None if not(u"port" in hint and isinstance(hint[u"port"], six.integer_types)): log.msg("invalid port in hint: %r" % (hint,)) return None priority = hint.get(u"priority", 0.0) if hint_type == u"direct-tcp-v1": return DirectTCPV1Hint(hint[u"hostname"], hint[u"port"], priority) else: return TorTCPV1Hint(hint[u"hostname"], hint[u"port"], priority) def add_connection_hints(self, hints): for h in hints: # hint structs hint_type = h.get(u"type", u"") if hint_type in [u"direct-tcp-v1", u"tor-tcp-v1"]: dh = self._parse_tcp_v1_hint(h) if dh: self._their_direct_hints.append(dh) # hint_obj elif hint_type == u"relay-v1": # TODO: each relay-v1 clause describes a different relay, # with a set of equally-valid ways to connect to it. Treat # them as separate relays, instead of merging them all # together like this. relay_hints = [] for rhs in h.get(u"hints", []): h = self._parse_tcp_v1_hint(rhs) if h: relay_hints.append(h) if relay_hints: rh = RelayV1Hint(hints=tuple(sorted(relay_hints))) self._our_relay_hints.add(rh) else: log.msg("unknown hint type: %r" % (h,)) def _send_this(self): assert self._transit_key if self.is_sender: return build_sender_handshake(self._transit_key) else: return build_receiver_handshake(self._transit_key) def _expect_this(self): assert self._transit_key if self.is_sender: return build_receiver_handshake(self._transit_key) else: return build_sender_handshake(self._transit_key)# + b"go\n" def _sender_record_key(self): assert self._transit_key if self.is_sender: return HKDF(self._transit_key, SecretBox.KEY_SIZE, CTXinfo=b"transit_record_sender_key") else: return HKDF(self._transit_key, SecretBox.KEY_SIZE, CTXinfo=b"transit_record_receiver_key") def _receiver_record_key(self): assert self._transit_key if self.is_sender: return HKDF(self._transit_key, SecretBox.KEY_SIZE, CTXinfo=b"transit_record_receiver_key") else: return HKDF(self._transit_key, SecretBox.KEY_SIZE, CTXinfo=b"transit_record_sender_key") def set_transit_key(self, key): assert isinstance(key, type(b"")), type(key) # We use pubsub to protect against the race where the sender knows # the hints and the key, and connects to the receiver's transit # socket before the receiver gets the relay message (and thus the # key). self._transit_key = key waiters = self._waiting_for_transit_key del self._waiting_for_transit_key for d in waiters: # We don't need eventual-send here. It's safer in general, but # set_transit_key() is only called once, and _get_transit_key() # won't touch the subscribers list once the key is set. d.callback(key) def _get_transit_key(self): if self._transit_key: return defer.succeed(self._transit_key) d = defer.Deferred() self._waiting_for_transit_key.append(d) return d @inlineCallbacks def connect(self): with self._timing.add("transit connect"): yield self._get_transit_key() # we want to have the transit key before starting any outbound # connections, so those connections will know what to say when # they connect winner = yield self._connect() returnValue(winner) def _connect(self): # It might be nice to wire this so that a failure in the direct hints # causes the relay hints to be used right away (fast failover). But # none of our current use cases would take advantage of that: if we # have any viable direct hints, then they're either going to succeed # quickly or hang for a long time. contenders = [] if self._listener_d: contenders.append(self._listener_d) relay_delay = 0 for hint_obj in self._their_direct_hints: # Check the hint type to see if we can support it (e.g. skip # onion hints on a non-Tor client). Do not increase relay_delay # unless we have at least one viable hint. ep = self._endpoint_from_hint_obj(hint_obj) if not ep: continue description = "->%s" % describe_hint_obj(hint_obj) if self._tor: description = "tor" + description d = self._start_connector(ep, description) contenders.append(d) relay_delay = self.RELAY_DELAY # Start trying the relays a few seconds after we start to try the # direct hints. The idea is to prefer direct connections, but not be # afraid of using a relay when we have direct hints that don't # resolve quickly. Many direct hints will be to unused local-network # IP addresses, which won't answer, and would take the full TCP # timeout (30s or more) to fail. prioritized_relays = {} for rh in self._our_relay_hints: for hint_obj in rh.hints: priority = hint_obj.priority if priority not in prioritized_relays: prioritized_relays[priority] = set() prioritized_relays[priority].add(hint_obj) for priority in sorted(prioritized_relays, reverse=True): for hint_obj in prioritized_relays[priority]: ep = self._endpoint_from_hint_obj(hint_obj) if not ep: continue description = "->relay:%s" % describe_hint_obj(hint_obj) if self._tor: description = "tor" + description d = task.deferLater(self._reactor, relay_delay, self._start_connector, ep, description, is_relay=True) contenders.append(d) relay_delay += self.RELAY_DELAY if not contenders: raise TransitError("No contenders for connection") winner = there_can_be_only_one(contenders) return self._not_forever(2*TIMEOUT, winner) def _not_forever(self, timeout, d): """If the timer fires first, cancel the deferred. If the deferred fires first, cancel the timer.""" t = self._reactor.callLater(timeout, d.cancel) def _done(res): if t.active(): t.cancel() return res d.addBoth(_done) return d def _build_relay_handshake(self): return build_sided_relay_handshake(self._transit_key, self._side) def _start_connector(self, ep, description, is_relay=False): relay_handshake = None if is_relay: assert self._transit_key relay_handshake = self._build_relay_handshake() f = OutboundConnectionFactory(self, relay_handshake, description) d = ep.connect(f) # fires with protocol, or ConnectError d.addCallback(lambda p: p.startNegotiation()) return d def _endpoint_from_hint_obj(self, hint): if self._tor: if isinstance(hint, (DirectTCPV1Hint, TorTCPV1Hint)): # this Tor object will throw ValueError for non-public IPv4 # addresses and any IPv6 address try: return self._tor.stream_via(hint.hostname, hint.port) except ValueError: return None return None if isinstance(hint, DirectTCPV1Hint): return endpoints.HostnameEndpoint(self._reactor, hint.hostname, hint.port) return None def connection_ready(self, p): # inbound/outbound Connection protocols call this when they finish # negotiation. The first one wins and gets a "go". Any subsequent # ones lose and get a "nevermind" before being closed. if not self.is_sender: return "wait-for-decision" if self._winner: # we already have a winner, so this one loses return "nevermind" # this one wins! self._winner = p return "go" class TransitSender(Common): is_sender = True class TransitReceiver(Common): is_sender = False # based on twisted.protocols.ftp.FileConsumer, but don't close the filehandle # when done, and add a progress function that gets called with the length of # each write, and a hasher function that gets called with the data. @implementer(interfaces.IConsumer) class FileConsumer: def __init__(self, f, progress=None, hasher=None): self._f = f self._progress = progress self._hasher = hasher self._producer = None def registerProducer(self, producer, streaming): assert not self._producer self._producer = producer assert streaming def write(self, bytes): self._f.write(bytes) if self._progress: self._progress(len(bytes)) if self._hasher: self._hasher(bytes) def unregisterProducer(self): assert self._producer self._producer = None # the TransitSender/Receiver.connect() yields a Connection, on which you can # do send_record(), but what should the receive API be? set a callback for # inbound records? get a Deferred for the next record? The producer/consumer # API is enough for file transfer, but what would other applications want? # how should the Listener be managed? we want to shut it down when the # connect() Deferred is cancelled, as well as terminating any negotiations in # progress. # # the factory should return/manage a deferred, which fires iff an inbound # connection completes negotiation successfully, can be cancelled (which # stops the listener and drops all pending connections), but will never # timeout, and only errbacks if cancelled. # write unit test for _ThereCanBeOnlyOne # check start/finish time-gathering instrumentation # relay URLs are probably mishandled: both sides probably send their URL, # then connect to the *other* side's URL, when they really should connect to # both their own and the other side's. The current implementation probably # only works if the two URLs are the same.