def __init__(self, key, port, ksize=20, alpha=3, storage=None,
max_messages=1024, default_hop_limit=64,
refresh_neighbours_interval=WALK_TIMEOUT):
"""
Create a server instance. This will start listening on the given port.
Args:
key (str): Bitcoin wif/hwif for auth, encryption and node id.
ksize (int): The k parameter from the kademlia paper.
alpha (int): The alpha parameter from the kademlia paper
storage: implements :interface:`~kademlia.storage.IStorage`
refresh_neighbours_interval (float): Auto refresh neighbours.
"""
self.port = port
self._default_hop_limit = default_hop_limit
self._refresh_neighbours_interval = refresh_neighbours_interval
self._cached_address = None
self.port_handler = None
self.btctxstore = btctxstore.BtcTxStore(testnet=False)
# allow hwifs
is_hwif = self.btctxstore.validate_wallet(key)
self.key = self.btctxstore.get_key(key) if is_hwif else key
# XXX kademlia.network.Server.__init__ cant use super because Protocol
# passing the protocol class should be added upstream
self.ksize = ksize
self.alpha = alpha
self.log = storjnode.log.getLogger("kademlia.network")
self.log.setLevel(60)
self.storage = storage or ForgetfulStorage()
self.node = KademliaNode(self.get_id())
self.protocol = Protocol(
self.node, self.storage, ksize, max_messages=max_messages,
max_hop_limit=self._default_hop_limit
)
self.refreshLoop = LoopingCall(self.refreshTable).start(3600)
self._start_threads()
class Server(KademliaServer):
def __init__(self, key, port, ksize=20, alpha=3, storage=None,
max_messages=1024, default_hop_limit=64,
refresh_neighbours_interval=0.0):
"""
Create a server instance. This will start listening on the given port.
Args:
key (str): Bitcoin wif/hwif for auth, encryption and node id.
ksize (int): The k parameter from the kademlia paper.
alpha (int): The alpha parameter from the kademlia paper
storage: implements :interface:`~kademlia.storage.IStorage`
refresh_neighbours_interval (float): Auto refresh neighbours.
"""
self.port = port
self.thread_sleep_time = 0.02
self._default_hop_limit = default_hop_limit
self._refresh_neighbours_interval = refresh_neighbours_interval
self._cached_address = None
self.btctxstore = btctxstore.BtcTxStore(testnet=False)
# allow hwifs
is_hwif = self.btctxstore.validate_wallet(key)
self.key = self.btctxstore.get_key(key) if is_hwif else key
# XXX kademlia.network.Server.__init__ cant use super because Protocol
# passing the protocol class should be added upstream
self.ksize = ksize
self.alpha = alpha
self.log = storjnode.log.getLogger("kademlia.network")
self.log.setLevel(60)
self.storage = storage or ForgetfulStorage()
self.node = KademliaNode(self.get_id())
self.protocol = Protocol(
self.node, self.storage, ksize, max_messages=max_messages,
max_hop_limit=self._default_hop_limit
)
self.refreshLoop = LoopingCall(self.refreshTable).start(3600)
self._start_threads()
def _start_threads(self):
# setup relay message thread
self._relay_thread_stop = False
self._relay_thread = threading.Thread(target=self._relay_loop)
self._relay_thread.start()
# setup refresh neighbours thread
if self._refresh_neighbours_interval > 0.0:
self._refresh_thread_stop = False
self._refresh_thread = threading.Thread(target=self._refresh_loop)
self._refresh_thread.start()
def stop(self):
if self._refresh_neighbours_interval > 0.0:
self._refresh_thread_stop = True
self._refresh_thread.join()
self._relay_thread_stop = True
self._relay_thread.join()
# FIXME actually disconnect from port and stop properly
def refresh_neighbours(self):
_log.debug("Refreshing neighbours ...")
self.bootstrap(self.bootstrappableNeighbors())
def get_id(self):
return storjnode.util.address_to_node_id(self.get_address())
def get_address(self):
if self._cached_address is not None:
return self._cached_address
self._cached_address = self.btctxstore.get_address(self.key)
return self._cached_address
def get_known_peers(self):
"""Returns list of known node."""
return TableTraverser(self.protocol.router, self.node)
def get_neighbours(self):
return self.protocol.router.findNeighbors(self.node, exclude=self.node)
def has_messages(self):
return self.protocol.has_messages()
def get_messages(self):
return self.protocol.get_messages()
def relay_message(self, nodeid, message):
"""Send relay message to a node.
Queues a message to be relayed accross the network. Relay messages are
sent to the node nearest the receiver in the routing table that accepts
the relay message. This continues until it reaches the destination or
the nearest node to the receiver is reached.
Because messages are always relayed only to reachable nodes in the
current routing table, there is a fare chance nodes behind a NAT can
be reached if it is connected to the network.
Args:
nodeid: 160bit nodeid of the reciever as bytes
message: iu-msgpack-python serializable message data
Returns:
True if message was added to relay queue, otherwise False.
"""
# check max message size
packed_message = umsgpack.packb(message)
assert(len(packed_message) <= MAX_MESSAGE_DATA)
message = umsgpack.unpackb(packed_message) # sanatize abstract types
if nodeid == self.node.id:
_log.info("Adding message to self to received queue!.")
return self.protocol.queue_received_message({
"source": None, "message": message
})
else:
txt = "Queuing relay messaging for %s: %s"
address = storjnode.util.node_id_to_address(nodeid)
_log.debug(txt % (address, message))
return self.protocol.queue_relay_message({
"dest": nodeid, "message": message,
"hop_limit": self._default_hop_limit
})
def _relay_message(self, entry):
"""Returns entry if failed to relay to a closer node or None"""
dest = KademliaNode(entry["dest"])
nearest = self.protocol.router.findNeighbors(dest, exclude=self.node)
_log.debug("Relaying to nearest: %s" % repr(nearest))
for relay_node in nearest:
# do not relay away from node
if dest.distanceTo(self.node) <= dest.distanceTo(relay_node):
msg = "Skipping %s, farther then self."
_log.debug(msg % repr(relay_node))
continue
# relay message
address = storjnode.util.node_id_to_address(relay_node.id)
_log.debug("Attempting to relay message for %s" % address)
defered = self.protocol.callRelayMessage(
relay_node, entry["dest"], entry["hop_limit"], entry["message"]
)
defered = storjnode.util.default_defered(defered, None)
# wait for relay result
try:
result = storjnode.util.wait_for_defered(defered,
timeout=QUERY_TIMEOUT)
except TimeoutError: # pragma: no cover
msg = "Timeout while relayed message to %s" # pragma: no cover
_log.debug(msg % address) # pragma: no cover
result = None # pragma: no cover
# successfull relay
if result is not None:
_log.debug("Successfully relayed message to %s" % address)
return # relay to nearest peer, avoid amplification attacks
# failed to relay message
dest_address = storjnode.util.node_id_to_address(entry["dest"])
_log.debug("Failed to relay message for %s" % dest_address)
def _refresh_loop(self):
last_refresh = datetime.datetime.now()
delta = datetime.timedelta(seconds=self._refresh_neighbours_interval)
while not self._refresh_thread_stop:
if (datetime.datetime.now() - last_refresh) > delta:
self.refresh_neighbours()
last_refresh = datetime.datetime.now()
time.sleep(self.thread_sleep_time)
def _relay_loop(self):
while not self._relay_thread_stop:
# FIXME use worker pool to process queue
q = self.protocol.messages_relay
for entry in storjnode.util.empty_queue(q):
self._relay_message(entry)
time.sleep(self.thread_sleep_time)
def direct_message(self, nodeid, message):
"""Send direct message to a node.
Spidercrawls the network to find the node and sends the message
directly. This will fail if the node is behind a NAT and doesn't
have a public ip.
Args:
nodeid: 160bit nodeid of the reciever as bytes
message: iu-msgpack-python serializable message data
Returns:
Defered own transport address (ip, port) if successfull else None
"""
def found_callback(nodes):
nodes = filter(lambda n: n.id == nodeid, nodes)
if len(nodes) == 0:
return defer.succeed(None)
else:
async = self.protocol.callDirectMessage(nodes[0], message)
return async.addCallback(lambda r: r[0] and r[1] or None)
node = KademliaNode(nodeid)
nearest = self.protocol.router.findNeighbors(node)
if len(nearest) == 0:
return defer.succeed(None)
spider = NodeSpiderCrawl(
self.protocol, node, nearest, self.ksize, self.alpha
)
return spider.find().addCallback(found_callback)
def get_transport_info(self):
def handle(results):
results = filter(lambda r: r[0], results) # filter successful
if not results:
_log.warning("No successful stun!")
return None
# FIXME check all entries as some nodes may be on the local net
result = results[0][1]
if not result:
_log.warning("No stun result!")
return None
wan = (result[0], result[1])
lan = (storjnode.util.get_inet_facing_ip(), self.port)
return {"wan": wan, "lan": lan}
ds = []
for neighbor in self.bootstrappableNeighbors():
ds.append(self.protocol.stun(neighbor))
return defer.gatherResults(ds).addCallback(handle)
class Server(KademliaServer):
def __init__(self, key, port, ksize=20, alpha=3, storage=None,
max_messages=1024, default_hop_limit=64,
refresh_neighbours_interval=WALK_TIMEOUT):
"""
Create a server instance. This will start listening on the given port.
Args:
key (str): Bitcoin wif/hwif for auth, encryption and node id.
ksize (int): The k parameter from the kademlia paper.
alpha (int): The alpha parameter from the kademlia paper
storage: implements :interface:`~kademlia.storage.IStorage`
refresh_neighbours_interval (float): Auto refresh neighbours.
"""
self.port = port
self._default_hop_limit = default_hop_limit
self._refresh_neighbours_interval = refresh_neighbours_interval
self._cached_address = None
self.port_handler = None
self.btctxstore = btctxstore.BtcTxStore(testnet=False)
# allow hwifs
is_hwif = self.btctxstore.validate_wallet(key)
self.key = self.btctxstore.get_key(key) if is_hwif else key
# XXX kademlia.network.Server.__init__ cant use super because Protocol
# passing the protocol class should be added upstream
self.ksize = ksize
self.alpha = alpha
self.log = storjnode.log.getLogger("kademlia.network")
self.log.setLevel(60)
self.storage = storage or ForgetfulStorage()
self.node = KademliaNode(self.get_id())
self.protocol = Protocol(
self.node, self.storage, ksize, max_messages=max_messages,
max_hop_limit=self._default_hop_limit
)
self.refreshLoop = LoopingCall(self.refreshTable).start(3600)
self._start_threads()
def _start_threads(self):
# setup relay message thread
self._relay_thread_stop = False
self._relay_thread = threading.Thread(target=self._relay_loop)
self._relay_thread.start()
# setup refresh neighbours thread
if self._refresh_neighbours_interval > 0.0:
self._refresh_thread_stop = False
self._refresh_thread = threading.Thread(target=self._refresh_loop)
self._refresh_thread.start()
def set_port_handler(self, port_handler):
self.port_handler = port_handler
def stop(self):
if self._refresh_neighbours_interval > 0.0:
self._refresh_thread_stop = True
self._refresh_thread.join()
self._relay_thread_stop = True
self._relay_thread.join()
# disconnect from port and stop properly
if self.port_handler is not None:
self.port_handler.stopListening()
@run_in_reactor
def refresh_neighbours(self):
_log.debug("Refreshing neighbours ...")
self.bootstrap(self.bootstrappableNeighbors())
def get_id(self):
return storjnode.util.address_to_node_id(self.get_address())
def get_address(self):
if self._cached_address is not None:
return self._cached_address
self._cached_address = self.btctxstore.get_address(self.key)
return self._cached_address
def get_known_peers(self):
"""Returns list of known node."""
return TableTraverser(self.protocol.router, self.node)
def get_neighbours(self):
return self.protocol.router.findNeighbors(self.node, exclude=self.node)
def has_messages(self):
return self.protocol.has_messages()
def get_messages(self):
return self.protocol.get_messages()
def relay_message(self, nodeid, message):
"""Send relay message to a node.
Queues a message to be relayed accross the network. Relay messages are
sent to the node nearest the receiver in the routing table that accepts
the relay message. This continues until it reaches the destination or
the nearest node to the receiver is reached.
Because messages are always relayed only to reachable nodes in the
current routing table, there is a fare chance nodes behind a NAT can
be reached if it is connected to the network.
Args:
nodeid: 160bit nodeid of the reciever as bytes
message: iu-msgpack-python serializable message data
Returns:
True if message was added to relay queue, otherwise False.
"""
# check max message size
packed_message = umsgpack.packb(message)
if len(packed_message) > MAX_MESSAGE_DATA:
raise Exception("Message to large {0} > {1}: {2}".format(
len(packed_message), MAX_MESSAGE_DATA, repr(message)
))
message = umsgpack.unpackb(packed_message) # sanatize abstract types
if nodeid == self.node.id:
_log.debug("Adding message to self to received queue!.")
return self.protocol.queue_received_message(message)
else:
txt = "Queuing relay messaging for %s: %s"
address = storjnode.util.node_id_to_address(nodeid)
if type(message) in (type(b""), type(u"")):
safe_msg = safe_log_var(message)
else:
safe_msg = message
_log.debug(txt % (address, safe_msg))
return self.protocol.queue_relay_message({
"dest": nodeid, "message": message,
"hop_limit": self._default_hop_limit
})
def _refresh_loop(self):
last_refresh = datetime.datetime.now()
delta = datetime.timedelta(seconds=self._refresh_neighbours_interval)
while not self._refresh_thread_stop:
if (datetime.datetime.now() - last_refresh) > delta:
self.refresh_neighbours()
last_refresh = datetime.datetime.now()
time.sleep(THREAD_SLEEP)
def _relay_loop(self):
while not self._relay_thread_stop:
q = self.protocol.messages_relay
for entry in storjnode.util.empty_queue(q):
message_relayer = MessageRelayer(self, **entry)
message_relayer.start()
time.sleep(THREAD_SLEEP)
def get_transport_info(self, unl=None):
def handle(results):
results = filter(lambda r: r[0], results) # filter successful
if not results:
_log.warning("No successful stun!")
return None
# FIXME check all entries as some nodes may be on the local net
result = results[0][1]
if not result:
_log.warning("No stun result!")
return None
wan = (result[0], result[1])
lan = (storjnode.util.get_inet_facing_ip(), self.port)
transport_info = {
"wan": wan, "lan": lan, "unl": unl, "is_public": wan == lan
}
return transport_info
ds = []
for neighbor in self.bootstrappableNeighbors():
ds.append(self.protocol.stun(neighbor))
return defer.gatherResults(ds).addCallback(handle)
