class HomeBase(Thread):
def __init__(self):
super(HomeBase, self).__init__(name="HomeBase")
self.context = Context()
self.pull = self.context.socket(PULL)
self.pull.bind("tcp://*:7001")
self._shutdown = False
self.poller = Poller()
self.poller.register(self.pull, POLLIN)
def cleanup(self):
self.pull.close()
self.context.term()
def run(self):
while True:
socks = dict(self.poller.poll(timeout=1))
if socks.get(self.pull) == POLLIN:
msg = self.pull.recv()
msg += ", WORK RECEIVED "
print msg
if self._shutdown:
break
self.cleanup()
class Listener(Thread):
def __init__(self):
super(Listener, self).__init__(name="Listener")
self._shutdown = False
self.context = Context()
self.sub = self.context.socket(SUB)
self.sub.bind('tcp://*:7000')
self.sub.setsockopt(SUBSCRIBE, "")
self.poller = Poller()
self.poller.register(self.sub, POLLIN)
def cleanup(self):
self.sub.close()
self.context.term()
def run(self):
while True:
socks = dict(self.poller.poll(timeout=1))
if socks.get(self.sub) == POLLIN:
msg = self.sub.recv(flags=NOBLOCK)
print msg
if self._shutdown:
break
self.cleanup()
class Listener(Thread):
def __init__(self):
super(Listener, self).__init__(name="Listener")
self._shutdown = False
self.context = Context()
self.sub = self.context.socket(SUB)
self.sub.bind('tcp://*:7000')
self.sub.setsockopt(SUBSCRIBE, "")
self.poller = Poller()
self.poller.register(self.sub, POLLIN)
def cleanup(self):
self.sub.close()
self.context.term()
def run(self):
while True:
socks = dict(self.poller.poll(timeout=1))
if socks.get(self.sub) == POLLIN:
msg = self.sub.recv(flags=NOBLOCK)
print msg
if self._shutdown:
break
self.cleanup()
class Leatherneck(Thread):
def __init__(self):
super(Leatherneck, self).__init__(name="Leatherneck")
self.context = Context()
self.pull = self.context.socket(PULL)
self.pull.connect("tcp://localhost:7000")
self.push = self.context.socket(PUSH)
self.push.connect("tcp://localhost:7001")
self.poller = Poller()
self.poller.register(self.pull, POLLIN)
self._shutdown = False
def cleanup(self):
self.push.close()
self.pull.close()
self.context.term()
def run(self):
while True:
socks = dict(self.poller.poll(timeout=1))
if socks.get(self.pull) == POLLIN:
msg = self.pull.recv()
msg += " WORK COMPLETE, " + str(time())
self.push.send(msg)
if self._shutdown:
break
self.cleanup()
class Stethoscope(Thread):
def __init__(self, context, *args, **kw):
self.context = context
self.recv = self.context.socket(PAIR)
self.recv.connect("inproc://#1")
self.pub = self.context.socket(PUB)
self.pub.connect('tcp://localhost:7003')
self.pub.setsockopt(HWM, 1000)
self.poller = Poller()
self.poller.register(self.recv, POLLIN)
super(Stethoscope, self).__init__(*args, **kw)
def cleanup(self):
self.recv.close()
self.pub.close()
def run(self):
try:
while not shutdown.is_set():
socks = dict(self.poller.poll())
if socks.get(self.recv) == POLLIN:
msg = self.recv.recv()
self.pub.send(msg, flags=NOBLOCK)
if msg == "DIE":
raise KillThread
except KillThread:
print "%s exiting..." % self.name
finally:
self.cleanup()
def run(self, *args):
"""Run the listener and answer to requests.
"""
del args
arec = AddressReceiver(max_age=self._max_age)
arec.start()
port = PORT
try:
self.listener = context.socket(REP)
self.listener.bind("tcp://*:" + str(port))
poller = Poller()
poller.register(self.listener, POLLIN)
while self.loop:
socks = dict(poller.poll(1000))
if socks:
if socks.get(self.listener) == POLLIN:
msg = self.listener.recv()
else:
continue
logger.debug("Replying to request: " + str(msg))
msg = Message.decode(msg)
self.listener.send_unicode(str(get_active_address(
msg.data["service"], arec)))
except KeyboardInterrupt:
# Needed to stop the nameserver.
pass
finally:
arec.stop()
self.listener.close()
def get_pub_address(name, timeout=10, nameserver="localhost"):
"""Get the address of the publisher for a given publisher *name* from the
nameserver on *nameserver* (localhost by default).
"""
# Socket to talk to server
socket = context.socket(REQ)
try:
socket.setsockopt(LINGER, timeout * 1000)
socket.connect("tcp://" + nameserver + ":" + str(PORT))
poller = Poller()
poller.register(socket, POLLIN)
message = Message("/oper/ns", "request", {"service": name})
socket.send(str(message))
# Get the reply.
sock = poller.poll(timeout=timeout * 1000)
if sock:
if sock[0][0] == socket:
message = Message.decode(socket.recv(NOBLOCK))
return message.data
else:
raise TimeoutError("Didn't get an address after %d seconds."
% timeout)
finally:
socket.close()
class ControllerServer:
def __init__(self):
self.pairSockets = []
self.poller = Poller()
def connect(self, address):
socket = zmq.Context().socket(zmq.PAIR)
socket.connect(address)
self.poller.register(socket, zmq.POLLIN)
self.pairSockets.append(socket)
return socket
def send(self, message, socket=None):
message = IO.wrap(message)
if socket:
socket.send(message)
else:
for socket in self.pairSockets:
socket.send(message)
def sendAction(self, action, socket=None):
message = {'action': action}
self.send(message, socket)
def receive(self, receiveCb, timeout=-1):
socks = dict(self.poller.poll(timeout))
if socks:
for si, socket in enumerate(self.pairSockets):
if self.pairSockets[si] in socks and socks[
self.pairSockets[si]] == zmq.POLLIN:
msg = socket.recv()
msg, _ = IO.unwrap(msg)
receiveCb(si, msg)
def get_pub_address(name, timeout=10, nameserver="localhost"):
"""Get the address of the publisher for a given publisher *name* from the
nameserver on *nameserver* (localhost by default).
"""
# Socket to talk to server
socket = get_context().socket(REQ)
try:
socket.setsockopt(LINGER, timeout * 1000)
socket.connect("tcp://" + nameserver + ":" + str(PORT))
logger.debug('Connecting to %s',
"tcp://" + nameserver + ":" + str(PORT))
poller = Poller()
poller.register(socket, POLLIN)
message = Message("/oper/ns", "request", {"service": name})
socket.send_string(six.text_type(message))
# Get the reply.
sock = poller.poll(timeout=timeout * 1000)
if sock:
if sock[0][0] == socket:
message = Message.decode(socket.recv_string(NOBLOCK))
return message.data
else:
raise TimeoutError("Didn't get an address after %d seconds." %
timeout)
finally:
socket.close()
class Leatherneck(Thread):
def __init__(self):
super(Leatherneck, self).__init__(name="Leatherneck")
self.context = Context()
self.pull = self.context.socket(PULL)
self.pull.connect("tcp://localhost:7000")
self.push = self.context.socket(PUSH)
self.push.connect("tcp://localhost:7001")
self.poller = Poller()
self.poller.register(self.pull, POLLIN)
self._shutdown = False
for th in t_enum():
if th.name == "MainThread":
self.mainthread = th
def cleanup(self):
print "Workers exiting..."
self.push.close()
self.pull.close()
self.context.term()
def run(self):
while True:
if not self.mainthread.is_alive():
self._shutdown = True
break
socks = dict(self.poller.poll(timeout=1))
if socks.get(self.pull) == POLLIN:
msg = self.pull.recv(flags=NOBLOCK)
msg += " WORK COMPLETE, " + str(time())
self.push.send(msg, flags=NOBLOCK)
if self._shutdown:
break
self.cleanup()
class HomeBase(Thread):
def __init__(self):
super(HomeBase, self).__init__(name="HomeBase")
self.context = Context()
self.pull = self.context.socket(PULL)
self.pull.bind("tcp://*:7001")
self._shutdown = False
self.poller = Poller()
self.poller.register(self.pull, POLLIN)
for th in t_enum():
if th.name == "MainThread":
self.mainthread = th
def cleanup(self):
print "Home exiting..."
self.pull.close()
self.context.term()
def run(self):
while True:
if not self.mainthread.is_alive():
self._shutdown = True
break
socks = dict(self.poller.poll(timeout=1))
if socks.get(self.pull) == POLLIN:
msg = self.pull.recv(flags=NOBLOCK)
msg += ", WORK RECEIVED "
print msg
if self._shutdown:
break
self.cleanup()
class HomeBase(Thread):
def __init__(self):
super(HomeBase, self).__init__(name="HomeBase")
self.context = Context()
self.pull = self.context.socket(PULL)
self.pull.bind("tcp://*:7001")
self._shutdown = False
self.poller = Poller()
self.poller.register(self.pull, POLLIN)
for th in t_enum():
if th.name == "MainThread":
self.mainthread = th
def cleanup(self):
print "Home exiting..."
self.pull.close()
self.context.term()
def run(self):
while True:
if not self.mainthread.is_alive():
self._shutdown = True
break
socks = dict(self.poller.poll(timeout=1))
if socks.get(self.pull) == POLLIN:
msg = self.pull.recv(flags=NOBLOCK)
msg += ", WORK RECEIVED "
print msg
if self._shutdown:
break
self.cleanup()
class Leatherneck(Thread):
def __init__(self):
super(Leatherneck, self).__init__(name="Leatherneck")
self.context = Context()
self.pull = self.context.socket(PULL)
self.pull.connect("tcp://localhost:7000")
self.push = self.context.socket(PUSH)
self.push.connect("tcp://localhost:7001")
self.poller = Poller()
self.poller.register(self.pull, POLLIN)
self._shutdown = False
for th in t_enum():
if th.name == "MainThread":
self.mainthread = th
def cleanup(self):
print "Workers exiting..."
self.push.close()
self.pull.close()
self.context.term()
def run(self):
while True:
if not self.mainthread.is_alive():
self._shutdown = True
break
socks = dict(self.poller.poll(timeout=1))
if socks.get(self.pull) == POLLIN:
msg = self.pull.recv(flags=NOBLOCK)
msg += " WORK COMPLETE, " + str(time())
self.push.send(msg, flags=NOBLOCK)
if self._shutdown:
break
self.cleanup()
class Leatherneck(Thread):
def __init__(self):
super(Leatherneck, self).__init__(name="Leatherneck")
self.context = Context()
self.pull = self.context.socket(PULL)
self.pull.connect("tcp://localhost:7000")
self.push = self.context.socket(PUSH)
self.push.connect("tcp://localhost:7001")
self.poller = Poller()
self.poller.register(self.pull, POLLIN)
self._shutdown = False
def cleanup(self):
self.push.close()
self.pull.close()
self.context.term()
def run(self):
while True:
socks = dict(self.poller.poll(timeout=1))
if socks.get(self.pull) == POLLIN:
msg = self.pull.recv()
msg += " WORK COMPLETE, " + str(time())
self.push.send(msg)
if self._shutdown:
break
self.cleanup()
class Stethoscope(Thread):
def __init__(self, context, *args, **kw):
self.context = context
self.recv = self.context.socket(PAIR)
self.recv.connect("inproc://#1")
self.pub = self.context.socket(PUB)
self.pub.connect('tcp://localhost:7003')
self.pub.setsockopt(HWM, 1000)
self.poller = Poller()
self.poller.register(self.recv, POLLIN)
super(Stethoscope, self).__init__(*args, **kw)
def cleanup(self):
self.recv.close()
self.pub.close()
def run(self):
try:
while not shutdown.is_set():
socks = dict(self.poller.poll())
if socks.get(self.recv) == POLLIN:
msg = self.recv.recv()
self.pub.send(msg, flags=NOBLOCK)
if msg == "DIE":
raise KillThread
except KillThread:
print "%s exiting..." % self.name
finally:
self.cleanup()
def _send_request(req_id, action, key, value=None):
""" Generate a request ID, push the request to the node and wait for the
result, filtering by the ID on the subscription.
This should be a request/response call to the node, but since many must be
possible at the same time, a PUSH/PULL AND PUB/SUB with an unique ID for
each request is used instead.
:return: the node response
:rtype: []
"""
# Create and connect the sockets.
context = current_app.config["context"]
subscriber = context.socket(SUB)
subscriber.setsockopt_string(SUBSCRIBE, req_id)
subscriber.connect(SUB_ENDPOINT)
request = context.socket(PUSH)
request.setsockopt(SNDTIMEO, _TIMEOUT)
request.connect(PUSH_ENDPOINT)
# Push the request.
request.send_json([req_id, action, key, value])
# Wait for the response from the publisher.
poller = Poller()
poller.register(subscriber, POLLIN)
sockets = dict(poller.poll(_TIMEOUT))
if subscriber not in sockets: # no response, time out
raise InternalServerError()
# Return the response, without the unique request ID
return subscriber.recv_multipart()[1:]
class MirrorWatcher(Thread):
"""Watches a other server.
"""
def __init__(self, holder, host, pubport, reqport, sched):
Thread.__init__(self)
self._holder = holder
self._pubaddress = "tcp://" + host + ":" + str(pubport)
self._reqaddress = "tcp://" + host + ":" + str(reqport)
self._req = SimpleRequester(host, reqport)
self._subsocket = context.socket(SUB)
self._subsocket.connect(self._pubaddress)
self._subsocket.setsockopt(SUBSCRIBE, "pytroll")
self._poller = Poller()
self._poller.register(self._subsocket, POLLIN)
self._lock = Lock()
self._loop = True
self._sched = sched
def run(self):
last_hb = datetime.now()
minutes = 2
while self._loop:
if datetime.now() - last_hb > timedelta(minutes=minutes):
logger.error("No heartbeat from " + str(self._pubaddress))
last_hb = datetime.now()
minutes = 1440
socks = dict(self._poller.poll(2000))
if (socks and
self._subsocket in socks and
socks[self._subsocket] == POLLIN):
message = Message.decode(self._subsocket.recv())
else:
continue
if message.type == "have":
sat = message.data["satellite"]
key = strp_isoformat(message.data["timecode"])
elevation = message.data["elevation"]
quality = message.data.get("quality", 100)
data = _MirrorGetter(self._req, sat, key)
self._holder.add(sat, key, elevation, quality, data)
if message.type == "heartbeat":
logger.debug("Got heartbeat from " + str(self._pubaddress)
+ ": " + str(message))
self._sched.mirror_next_pass = message.data["next_pass"]
last_hb = datetime.now()
minutes = 2
def stop(self):
"""Stop the watcher
"""
self._loop = False
self._req.stop()
self._subsocket.setsockopt(LINGER, 0)
self._subsocket.close()
def start_poll(pull, push, sub, hash_checker):
global INPUT_DATA
seq_no = 0
poller = Poller()
poller.register(pull, zmq.POLLIN)
poller.register(sub, zmq.POLLIN)
while True:
try:
socks = dict(poller.poll())
except KeyboardInterrupt:
return
if sub in socks:
log.debug('recv -> {}'.format(sub.recv_multipart()))
try:
log.info('Concatting...')
concat_string = process()
concat_string_hash = HASHER(concat_string).digest()
# Send final hash
push.send_multipart([
MessageType.INPUT.value,
seq_no.to_bytes(2, byteorder='big'),
concat_string_hash,
])
log.debug('send -> {} | {} | {}', MessageType.INPUT.name,
seq_no, concat_string_hash.hex())
# Send original concatted string
push.send_multipart([
MessageType.COMMIT.value,
seq_no.to_bytes(2, byteorder='big'),
concat_string,
])
log.debug('send -> {} | {} | {}...', MessageType.COMMIT.name,
seq_no, concat_string[:20])
INPUT_DATA.clear()
log.info("Reset concat")
if seq_no == 0xFFFF:
seq_no = 0
else:
seq_no += 1
except Exception as e:
log.error("Could not concat inputs -> {}".format(e))
if pull in socks:
inp = pull.recv()
log.debug('recv -> {}'.format(inp.hex()))
try:
hash_checker.check(inp)
except:
log.warn('Bad hash received! -> {}', inp)
continue
INPUT_DATA.append(inp)
log.info('Input added | Elements: {}'.format(len(INPUT_DATA)))
class Requester:
def __init__(self, timeout=-1, poolSize=4):
self.timeout = timeout
self.socket = None
self.numConnections = 0
self.poller = Poller()
def addServer(self, address, bind=False, linger=-1):
if self.socket is None:
self.socket = zmq.Context().socket(zmq.REQ)
# self.socket.setsockopt(zmq.LINGER, linger)
self.poller.register(self.socket, zmq.POLLIN)
if bind:
self.socket.bind(address)
else:
self.socket.connect(address)
self.numConnections += 1
def numConnections(self):
return self.numConnections
def request(self, message):
if message is None or self.socket is None: return None
message = IO.wrap(message)
self.socket.send(message)
socks = dict(self.poller.poll(self.timeout))
if socks:
replyMessage = self.socket.recv()
reply, _ = IO.unwrap(replyMessage)
return reply
return None
def requestAllServers(self, message):
replies = []
for n in range(self.numConnections):
reply = self.request(message)
replies.append(reply)
return replies
def requestAllServersCb(self, message, replyCb):
for n in range(self.numConnections):
reply = self.request(message)
replyCb(reply)
def requestAllServersPool(self, message, poolSize=0):
if poolSize < 1: poolSize = self.numConnections
pool = Pool(processes=poolSize)
replies = pool.map(self.request,
[message for n in range(self.numConnections)])
return replies
class MirrorWatcher(Thread):
"""Watches a other server.
"""
def __init__(self, holder, host, pubport, reqport, sched):
Thread.__init__(self)
self._holder = holder
self._pubaddress = "tcp://" + host + ":" + str(pubport)
self._reqaddress = "tcp://" + host + ":" + str(reqport)
self._req = SimpleRequester(host, reqport)
self._subsocket = get_context().socket(SUB)
self._subsocket.connect(self._pubaddress)
self._subsocket.setsockopt_string(SUBSCRIBE, "pytroll")
self._poller = Poller()
self._poller.register(self._subsocket, POLLIN)
self._lock = Lock()
self._loop = True
self._sched = sched
def run(self):
last_hb = datetime.now()
minutes = 2
while self._loop:
if datetime.now() - last_hb > timedelta(minutes=minutes):
logger.error("No heartbeat from " + str(self._pubaddress))
last_hb = datetime.now()
minutes = 1440
socks = dict(self._poller.poll(2000))
if (socks and self._subsocket in socks
and socks[self._subsocket] == POLLIN):
message = Message.decode(self._subsocket.recv())
else:
continue
if message.type == "have":
sat = message.data["satellite"]
key = strp_isoformat(message.data["timecode"])
elevation = message.data["elevation"]
quality = message.data.get("quality", 100)
data = _MirrorGetter(self._req, sat, key)
self._holder.add(sat, key, elevation, quality, data)
if message.type == "heartbeat":
logger.debug("Got heartbeat from " + str(self._pubaddress) +
": " + str(message))
self._sched.mirror_next_pass = message.data["next_pass"]
last_hb = datetime.now()
minutes = 2
def stop(self):
"""Stop the watcher
"""
self._loop = False
self._req.stop()
self._subsocket.setsockopt(LINGER, 0)
self._subsocket.close()
def refresh_serum_index(self):
try:
rawData = []
for i in range(3):
socket = self.context.socket(REQ)
socket.connect("tcp://serum-server:6900")
socket.setsockopt(LINGER, 0)
poller = Poller()
poller.register(socket, POLLIN)
socket.send(dumps({"endpoint": "list"}))
responses = poller.poll(10000)
if len(responses) != 0:
response = socket.recv()
socket.close()
rawData = loads(response)
break
else:
socket.close()
for market in rawData["markets"]:
base, quote = market["name"].split("/", 1)
if base not in self.serumIndex:
self.serumIndex[base] = []
self.serumIndex[base].append({"id": market["address"], "name": base, "base": base, "quote": quote, "image": None, "program": market["programId"]})
for token in rawData["tokenList"]:
symbol = token["symbol"].upper()
if symbol not in self.serumIndex:
self.serumIndex[symbol] = []
processed = []
for market in self.serumIndex[symbol]:
processed.append(market["quote"])
market["name"] = token["name"]
market["image"] = token.get("logoURI")
for extension, address in token.get("extensions", {}).items():
if extension.startswith("serumV3"):
quote = extension.removeprefix("serumV3").upper()
if quote not in processed:
processed.append(quote)
self.serumIndex[symbol].append({"id": address, "name": token["name"], "base": symbol, "quote": quote, "image": token.get("logoURI"), "program": "9xQeWvG816bUx9EPjHmaT23yvVM2ZWbrrpZb9PusVFin"})
if len(self.serumIndex[symbol]) == 0:
self.serumIndex.pop(symbol)
elif self.serumIndex[symbol][0]["quote"] != "USDC":
usdcMarket = None
for index, market in enumerate(self.serumIndex[symbol]):
if market["quote"] == "USDC":
usdcMarket = self.serumIndex[symbol].pop(index)
break
if usdcMarket is not None:
self.serumIndex[symbol].insert(0, usdcMarket)
except Exception:
print(format_exc())
def __stop(self):
""" try to stop all of this Role's services """
# send commands
poller = Poller()
for (pipe, svc) in self.__services.items():
pipe.send_string('STOP')
self.logger.debug('sent STOP command to %s service' % svc)
poller.register(pipe, POLLIN)
# give services a few seconds to cleanup and exit before checking responses
sleep(1)
max_attempts = len(self.__services)
attempts = 0
while self.__some_alive() and attempts < max_attempts:
attempts += 1
# poll for any replies
items = dict(poller.poll(60000)) # wait for messages
# mark responding services as stopped
alive = dict(self.__services) # make copy
for (pipe, svc) in alive.items():
if pipe in items:
reply = pipe.recv_string()
if 'STOPPED' == reply:
self.logger.debug('received STOPPED control reply from %s service' % svc)
svc.join(timeout=5) # STOPPED response should be sent right before svc exit
if svc.is_alive():
self.logger.error('%s service is still alive; not waiting' % svc)
else:
self.logger.debug('%s service thread stopped' % svc)
poller.unregister(pipe)
pipe.close()
del (self.__services[pipe])
else:
self.logger.debug('unknown control reply: %s' % reply)
# log some useful info
if len(self.__services) > 0:
msg = '%s services still alive after %d cycles; ' % (
[str(s) for s in self.__services.values()], attempts)
if attempts < max_attempts:
msg += 'waiting'
else:
msg += 'giving up'
self.logger.debug(msg)
def listen(self, topics: Iterable[str] = ("log|", )):
"""
Listens to incoming log messages on the ZeroMQ socket(s).
Blocks until `Ctrl + C` is pressed,
or ``SIGINT`` or ``SIGTERM`` is received by the process.
Returns immediately if either a bind address nor at least
one connect address is set.
:param topics:
The topic to subscribe with.
Can be used for selecting log messages from specific source.
Defaults to ``["log|"]``.
:type topics: Iterable[str]
"""
if not self._bind_address and not self._connect_addresses:
return
poller = Poller()
if self._bind_address:
self._pull_socket = self._ctx.socket(PULL)
self._pull_socket.bind('tcp://' + self._bind_address)
poller.register(self._pull_socket, POLLIN)
if self._connect_addresses:
self._sub_socket = self._ctx.socket(SUB)
for topic in topics:
self._sub_socket.setsockopt(
SUBSCRIBE, topic.encode(encoding=_TOPIC_ENCODING))
for address in self._connect_addresses:
self._sub_socket.connect('tcp://' + address)
poller.register(self._sub_socket, POLLIN)
try:
while not is_stopped():
events = dict(poller.poll(self._interval * 1000))
if self._pull_socket in events \
and events[self._pull_socket] == POLLIN:
data = self._pull_socket.recv_multipart(flags=NOBLOCK)
self._handle_message(data)
if self._sub_socket in events \
and events[self._sub_socket] == POLLIN:
data = self._sub_socket.recv_multipart(flags=NOBLOCK)
self._handle_message(data)
finally:
if self._pull_socket:
self._pull_socket.close()
self._pull_socket = None
if self._sub_socket:
self._sub_socket.close()
self._sub_socket = None
def _request_quote(cls, request, ticker, context=None):
try:
socket = context.socket(REQ)
socket.connect("tcp://serum-server:6900")
socket.setsockopt(LINGER, 0)
poller = Poller()
poller.register(socket, POLLIN)
socket.send(bytes(dumps({"endpoint": "quote", "marketAddress": ticker.get("id"), "program": ticker.get("symbol")}), encoding='utf8'))
responses = poller.poll(5000)
if len(responses) != 0:
response = socket.recv()
socket.close()
rawData = loads(response)
else:
socket.close()
return [{}, ""]
except:
return [{}, ""]
coinThumbnail = static_storage.icon if ticker.get("image") is None else ticker.get("image")
price = [float(rawData["price"])]
priceChange = 0
volume = 0
tokenImage = static_storage.icon
base = "USD" if ticker.get("base") in AbstractProvider.stableCoinTickers else ticker.get("base")
quote = "USD" if ticker.get("quote") in AbstractProvider.stableCoinTickers else ticker.get("quote")
payload = {
"quotePrice": "{:,.10f}".format(price[0]).rstrip('0').rstrip('.') + " " + quote,
"quoteVolume": "{:,.4f}".format(volume).rstrip('0').rstrip('.') + " " + base,
"title": ticker.get("name"),
"thumbnailUrl": coinThumbnail,
"messageColor": "amber" if priceChange == 0 else ("green" if priceChange > 0 else "red"),
"sourceText": "Data from Serum DEX",
"platform": "Serum",
"raw": {
"quotePrice": [price[0]],
"quoteVolume": [volume],
"timestamp": time()
}
}
return [payload, ""]
def _request_translation(self, language, country, key, plural):
""" Start up a worker, sync it and then send it a translation request.
Returns the result, shuts down the worker at the end as well.
Fails the current test, if something goes wrong.
"""
request = [
language, country if country is not None else "", key,
str(plural) if plural is not None else ""]
request = [x.encode(_ENCODING) for x in request]
context = Context()
# Create synchronization and backend sockets.
try:
sync_socket = context.socket(ROUTER)
try:
sync_socket.bind(_SYNC_ENDPOINT)
backend = context.socket(DEALER)
try:
backend.bind(_REQUEST_ENDPOINT)
worker_threads, worker_identities = _start_workers(
context, sync_socket, 1, _TIMEOUT)
poller = Poller()
poller.register(backend, POLLIN)
poller.register(sync_socket, POLLIN)
# Send request.
backend.send_multipart(
[worker_identities[0], b""] + request)
sockets = dict(poller.poll(_TIMEOUT))
# Shutdown worker.
_shut_down_workers(
sync_socket, worker_threads, worker_identities,
_TIMEOUT / 1000.0)
if backend in sockets:
# Return translation.
return backend.recv_multipart()[2].decode("utf-8")
self.fail("Worker did not response the request in time.")
finally:
backend.set(LINGER, 0)
backend.close()
finally:
sync_socket.set(LINGER, 0)
sync_socket.close()
finally:
context.destroy(linger=0)
class Server(object):
def __init__(self, port):
self._ctx = Context()
self._socket = self._ctx.socket(DEALER)
self._socket.bind('tcp://*:%s' % port)
self._poller = Poller()
self._poller.register(self._socket, POLLIN)
self._clients = {}
self._actions = {'register': self._register_client}
def _register_client(self, message):
if message['pseudonym'] not in self._clients:
self._clients[message['pseudonym']] = message['cert']
message = {'type': 'Accepted'}
self._send_msg(message)
else:
message = {'type': 'Failed'}
self._send_msg(message)
def _send_msg(self, message):
pickled_message = dumps(message)
self._socket.send(pickled_message)
print('Sent --> ', message)
def _recv_msg(self):
pickled_message = self._socket.recv()
received_message = loads(pickled_message)
print("Received --> ", received_message)
return received_message
def execute(self):
while True:
sockets = dict(self._poller.poll())
if sockets.get(self._socket) == POLLIN:
received_message = self._recv_msg()
self._actions[received_message['type']](received_message)
def execute_parser_request(endpoint, parameters, timeout=5):
socket = TickerParser.zmqContext.socket(REQ)
payload, responseText = None, None
socket.connect("tcp://parser:6900")
socket.setsockopt(LINGER, 0)
poller = Poller()
poller.register(socket, POLLIN)
socket.send_multipart([endpoint] + parameters)
responses = poller.poll(timeout * 1000)
if len(responses) != 0:
response = socket.recv_multipart()
socket.close()
return response
else:
socket.close()
raise Exception("time out")
return None
def _server(self, response):
""" Wait for a client request, record it and send the response. """
context = Context()
try:
socket = context.socket(REP)
try:
socket.set(LINGER, 0)
socket.bind("tcp://*:{}".format(_PORT))
poller = Poller()
poller.register(socket, POLLIN)
sockets = dict(poller.poll(_TIMEOUT))
if socket in sockets:
self._client_request = socket.recv_multipart()
if response:
socket.send_multipart(response)
finally:
socket.close()
finally:
context.destroy(linger=0)
def _server(self, response):
""" Wait for a client request, record it and send the response. """
context = Context()
try:
socket = context.socket(REP)
try:
socket.set(LINGER, 0)
socket.bind("tcp://*:{}".format(_PORT))
poller = Poller()
poller.register(socket, POLLIN)
sockets = dict(poller.poll(_TIMEOUT))
if socket in sockets:
self._client_request = socket.recv_multipart()
if response:
socket.send_multipart(response)
finally:
socket.close()
finally:
context.destroy(linger=0)
class ZMQPoller(object):
"""A poller that can be used in the tornado IOLoop.
This simply wraps a regular zmq.Poller, scaling the timeout
by 1000, so that it is in seconds rather than milliseconds.
"""
def __init__(self):
self._poller = Poller()
@staticmethod
def _map_events(events):
"""translate IOLoop.READ/WRITE/ERROR event masks into zmq.POLLIN/OUT/ERR"""
z_events = 0
if events & IOLoop.READ:
z_events |= POLLIN
if events & IOLoop.WRITE:
z_events |= POLLOUT
if events & IOLoop.ERROR:
z_events |= POLLERR
return z_events
@staticmethod
def _remap_events(z_events):
"""translate zmq.POLLIN/OUT/ERR event masks into IOLoop.READ/WRITE/ERROR"""
events = 0
if z_events & POLLIN:
events |= IOLoop.READ
if z_events & POLLOUT:
events |= IOLoop.WRITE
if z_events & POLLERR:
events |= IOLoop.ERROR
return events
def register(self, fd, events):
return self._poller.register(fd, self._map_events(events))
def modify(self, fd, events):
return self._poller.modify(fd, self._map_events(events))
def unregister(self, fd):
return self._poller.unregister(fd)
def poll(self, timeout):
"""poll in seconds rather than milliseconds.
Event masks will be IOLoop.READ/WRITE/ERROR
"""
z_events = self._poller.poll(1000*timeout)
return [ (fd,self._remap_events(evt)) for (fd,evt) in z_events ]
def close(self):
pass
class ZMQPoller(object):
"""A poller that can be used in the tornado IOLoop.
This simply wraps a regular zmq.Poller, scaling the timeout
by 1000, so that it is in seconds rather than milliseconds.
"""
def __init__(self):
self._poller = Poller()
@staticmethod
def _map_events(events):
"""translate IOLoop.READ/WRITE/ERROR event masks into zmq.POLLIN/OUT/ERR"""
z_events = 0
if events & IOLoop.READ:
z_events |= POLLIN
if events & IOLoop.WRITE:
z_events |= POLLOUT
if events & IOLoop.ERROR:
z_events |= POLLERR
return z_events
@staticmethod
def _remap_events(z_events):
"""translate zmq.POLLIN/OUT/ERR event masks into IOLoop.READ/WRITE/ERROR"""
events = 0
if z_events & POLLIN:
events |= IOLoop.READ
if z_events & POLLOUT:
events |= IOLoop.WRITE
if z_events & POLLERR:
events |= IOLoop.ERROR
return events
def register(self, fd, events):
return self._poller.register(fd, self._map_events(events))
def modify(self, fd, events):
return self._poller.modify(fd, self._map_events(events))
def unregister(self, fd):
return self._poller.unregister(fd)
def poll(self, timeout):
"""poll in seconds rather than milliseconds.
Event masks will be IOLoop.READ/WRITE/ERROR
"""
z_events = self._poller.poll(1000*timeout)
return [ (fd,self._remap_events(evt)) for (fd,evt) in z_events ]
def close(self):
pass
def execute_database_request(endpoint, parameters, timeout=1):
socket = DatabaseConnector.zmqContext.socket(REQ)
payload, responseText = None, None
socket.connect("tcp://database:6900")
socket.setsockopt(LINGER, 0)
poller = Poller()
poller.register(socket, POLLIN)
socket.send_multipart([
endpoint,
bytes(str(int((time() + timeout) * 1000)), encoding='utf8'),
parameters
])
responses = poller.poll(timeout * 1000)
if len(responses) != 0:
[response] = socket.recv_multipart()
socket.close()
return loads(response)
else:
socket.close()
return None
def directory_server(store: DirectoryServerStore, zmq_context: Context):
# pylint: disable=no-member # These zmq.ROUTER and zmq.PUB must be actually exists
print("Starting on libzmq {} with PyZMQ {}".format(zmq.zmq_version(),
zmq.pyzmq_version()))
entrypoint: Socket = zmq_context.socket(zmq.ROUTER)
entrypoint.bind("tcp://127.0.0.1:5350") # This is just a PROTOTYPE!
pub_file_changes: Socket = zmq_context.socket(zmq.PUB)
pub_file_changes.bind("tcp://127.0.0.1:5351")
poller = Poller()
poller.register(entrypoint, flags=zmq.POLLIN)
print(
"Directory server is started on 127.0.0.1:5350 (commands) and 127.0.0.1:5351 (file_changes_push)"
)
while True:
events: List[Tuple[Socket, int]] = poller.poll()
for socket, _ in events:
frames: List[Frame] = socket.recv_multipart(copy=False)
id_frame: Frame = frames.pop(0)
empty_frame: Frame = frames.pop(0)
assert (len(empty_frame.bytes) == 0)
command_frame: Frame = frames.pop(0)
command = str(command_frame.bytes, encoding='utf8')
if command == 'ping':
ping_handler(store, socket, frames, id_frame)
elif command == 'device.cast_address':
casting_address_handler(store, socket, frames, id_frame)
elif command == 'device.get_addresses':
get_addresses_handler(store, socket, frames, id_frame)
elif command == 'fs.list':
file_list_handler(store, socket, id_frame)
elif command == 'fs.declare':
file_declare_handler(store, socket, frames, id_frame,
pub_file_changes)
elif command == 'fs.disown':
file_disown_handler(store, socket, frames, id_frame,
pub_file_changes)
elif command == 'fs.get':
file_get_handler(store, socket, frames, id_frame)
def run(self, *args):
"""Run the listener and answer to requests.
"""
del args
arec = AddressReceiver(
max_age=self._max_age,
multicast_enabled=self._multicast_enabled,
restrict_to_localhost=self._restrict_to_localhost)
arec.start()
port = PORT
try:
with nslock:
self.listener = get_context().socket(REP)
self.listener.bind("tcp://*:" + str(port))
logger.debug('Listening on port %s', str(port))
poller = Poller()
poller.register(self.listener, POLLIN)
while self.loop:
with nslock:
socks = dict(poller.poll(1000))
if socks:
if socks.get(self.listener) == POLLIN:
msg = self.listener.recv_string()
else:
continue
logger.debug("Replying to request: " + str(msg))
msg = Message.decode(msg)
active_address = get_active_address(
msg.data["service"], arec)
self.listener.send_unicode(six.text_type(active_address))
except KeyboardInterrupt:
# Needed to stop the nameserver.
pass
finally:
arec.stop()
self.stop()
def start_poll(self, start_seq_no=None):
seq_no = start_seq_no if start_seq_no is not None else 0
last_process = time.time()
poller = Poller()
poller.register(self.pull, zmq.POLLIN)
poller.register(self.router, zmq.POLLIN)
while True:
try:
socks = dict(poller.poll(timeout=self.gather_time * 100))
except KeyboardInterrupt:
return
if self.pull in socks:
self.recv_input()
if self.router in socks:
self.recv_from_comp()
if self.worker_deque and self.ready_to_process() and time.time() - last_process >= self.gather_time:
compute_id = self.worker_deque.popleft()
last_process = time.time()
try:
self.process()
self.send_to_comp(compute_id, seq_no)
self.reset_inputs()
if seq_no == 0xFFFF:
seq_no = 0
else:
seq_no += 1
except Exception as e:
log.error("Could not process send and reset inputs -> {}".format(e))
else:
log.debug('time since last {}, deque size {}',
time.time() - last_process, len(self.worker_deque))
class HomeBase(Thread):
def __init__(self):
super(HomeBase, self).__init__(name="HomeBase")
self.context = Context()
self.pull = self.context.socket(PULL)
self.pull.bind("tcp://*:7001")
self._shutdown = False
self.poller = Poller()
self.poller.register(self.pull, POLLIN)
def cleanup(self):
self.pull.close()
self.context.term()
def run(self):
while True:
socks = dict(self.poller.poll(timeout=1))
if socks.get(self.pull) == POLLIN:
msg = self.pull.recv()
msg += ", WORK RECEIVED "
print msg
if self._shutdown:
break
self.cleanup()
def _start_workers(context, sync_socket, count, timeout=None):
"""
:type context: zmq.Context
:type sync_socker: zmq.Socket
:type count: int
:param timeout: Timeout for waiting for worker messages, in milliseconds.
:type timeout: float
"""
_LOG.debug("Starting workers...")
worker_threads = [
Thread(
target=_handle_requests, name="worker {}".format(i),
args=(context, ))
for i in range(count)]
for thread in worker_threads:
thread.start()
_LOG.debug("Synchronizing workers...")
poller = Poller()
poller.register(sync_socket, POLLIN)
worker_identities = []
for _ in worker_threads:
sockets = dict(poller.poll(timeout=timeout))
if sync_socket in sockets:
worker_identities.append(sync_socket.recv_multipart()[0])
else:
raise RuntimeError("Worker did not respond in time.")
for worker_identity in worker_identities:
sync_socket.send_multipart([worker_identity, b"", b""])
for _ in worker_identities:
sockets = dict(poller.poll(timeout=timeout))
if sync_socket in sockets:
sync_socket.recv_multipart()
else:
raise RuntimeError("Worker did not respond in time.")
_LOG.debug("Workers synchronized.")
return worker_threads, worker_identities
def _handle_requests(context):
""" This is supposed to run as a background thread.
It listens for translation requests and answers them until a message is
arrived on the sync socket, whereupon the function (thread) ends.
:type context: zmq.Context
"""
sync_socket = context.socket(REQ)
sync_socket.connect(_SYNC_ENDPOINT)
requests_socket = context.socket(REP)
requests_socket.connect(_REQUEST_ENDPOINT)
_LOG.debug("Synchronizing worker")
sync_socket.send(b"")
sync_socket.recv()
sync_socket.send(b"")
keep_running = True
poller = Poller()
poller.register(requests_socket, POLLIN)
poller.register(sync_socket, POLLIN)
_LOG.debug("Running worker")
while keep_running:
sockets = dict(poller.poll())
if requests_socket in sockets:
try:
response = _handle_request(requests_socket.recv_multipart())
except Exception: # pylint: disable=broad-except
_LOG.critical("Handler crashed!", exc_info=True)
response = [b""]
requests_socket.send_multipart(response)
if sync_socket in sockets:
sync_socket.recv()
keep_running = False
_LOG.debug("Terminating worker")
class Listener:
def __init__(self, timeout=-1):
self.controllerSocket = None
self.timecodeSocket = None
self.requestSocket = None
self.subscribers = {}
self.subscriberCallbacks = {}
self.subscriberTopicFilters = {}
self.periodicPublisher = None
self.commandCb = None
self.requestCb = None
self.timeout = timeout
self.poller = Poller()
self.running = False
self.pollCounter = 0
def connectController(self, address, commandCb=None):
self.controllerSocket = zmq.Context().socket(zmq.PAIR)
self.controllerSocket.bind(address)
self.notifyConnected(address)
self.poller.register(self.controllerSocket, zmq.POLLIN)
self.commandCb = commandCb
def sendController(self, message):
wrappedMsg = IO.wrap(message)
self.controllerSocket.send(wrappedMsg)
def notifyConnected(self, address):
msg = {'status': 'connected', 'address': address}
self.sendController(msg)
def notifyReady(self, address):
msg = {'status': 'ready', 'address': address}
self.sendController(msg)
def listenToRequests(self, address, requestCb):
self.requestCb = requestCb
self.requestSocket = zmq.Context().socket(zmq.REP)
self.requestSocket.bind(address)
self.poller.register(self.requestSocket, zmq.POLLIN)
def subscribeTimecode(self, address, timecodeCb):
self.addSubscription(address,
timecodeCb,
label='_TC_',
filters=['TIMECODE'])
def addSubscription(self,
address,
subCb,
label='default',
filters=['default']):
if label not in self.subscribers:
self.subscribers[label] = zmq.Context().socket(zmq.SUB)
self.subscribers[label].set_hwm(1)
#self.subscribers[label].setsockopt(zmq.RCVHWM, 1)
self.subscriberCallbacks[label] = subCb
self.subscriberTopicFilters[label] = filters
self.poller.register(self.subscribers[label], zmq.POLLIN)
print "Subscribing", label, "to:", address
self.subscribers[label].connect(address)
if filters:
for filter in filters:
self.subscribers[label].setsockopt(zmq.SUBSCRIBE, filter)
else:
self.subscribers[label].setsockopt(zmq.SUBSCRIBE, '')
def setPeriodicPublisher(self, publisher, overrideTimeout=True):
self.periodicPublisher = publisher
if overrideTimeout: self.timeout = publisher.getTimeout()
def start(self):
self.running = True
self._main()
def stop(self):
self.running = False
def pollRegistered(self, expected=-1, timeout=-1):
if expected == -1: expected = len(self.poller.sockets)
self.pollCounter = expected
while self.pollCounter > 0:
self.poll(timeout)
def poll(self, timeout=-1):
if timeout == -1: timeout = self.timeout
socks = dict(self.poller.poll(timeout))
if self.controllerSocket in socks and socks[
self.controllerSocket] == zmq.POLLIN:
command = self.controllerSocket.recv()
command, _ = IO.unwrap(command)
self.pollCounter -= 1
# Allow the user of this module to react to this command and to modify its contents
if self.commandCb:
modifiedCommand = self.commandCb(command)
if modifiedCommand is not None: command = modifiedCommand
if 'action' not in command: return
action = command['action']
if action == 'exit':
self.running = False
if self.requestSocket in socks and socks[
self.requestSocket] == zmq.POLLIN:
self.pollCounter -= 1
message = self.requestSocket.recv()
message, _ = IO.unwrap(message)
replyMessage = self.requestCb(message)
if replyMessage is None: return
wrappedReply = IO.wrap(replyMessage)
self.requestSocket.send(wrappedReply)
if socks:
for label in self.subscribers.keys():
if self.subscribers[label] in socks and socks[
self.subscribers[label]] == zmq.POLLIN:
self.pollCounter -= 1
data = self.subscribers[label].recv()
# In case there is not space in the data, use find. Find returns -1 when the string isn't found
sepIndex = data.find(' ')
if sepIndex > -1 and not data[:4] == 'TIMS' and data[
0:sepIndex] in self.subscriberTopicFilters[label]:
topic, content = data[0:sepIndex], data[sepIndex + 1:]
else:
topic, content = '', data
content, _ = IO.unwrap(content)
if content is not None:
self.subscriberCallbacks[label](content)
if self.periodicPublisher:
self.periodicPublisher.publish()
def _main(self):
while self.running:
self.poll()
#
# Weather Server
#
if __name__ == '__main__':
context = Context()
socket = context.socket(PUB)
socket.bind('tcp://*:6667')
# socket to receive control messages on
controller = context.socket(SUB)
controller.connect('tcp://localhost:6670')
controller.setsockopt(SUBSCRIBE, "")
# poller for handling receiver and controller messages
poller = Poller()
poller.register(socket, POLLIN)
poller.register(controller, POLLIN)
print 'Weather Update Server started ...'
while True:
socks = dict(poller.poll(timeout=1))
# exit the program if the kill command is executed
if socks.get(controller) == POLLIN:
controller.recv()
print 'Got kill command'
break
# if not killed, then tranmit the next weather update
zipcode = random.choice(zip_list)
temperature = random.randrange(1, 215) - 80
class Server():
"""A node server.
Each node has a request URL where request are accepted and a service URL
where the node periodically publishes its list of known nodes and the time
of the last contact (last publication from that node on the service URL).
The request commands are:
-new: register a new node
-get: get a key
-set: set a key
Each node owns a Nodes object which tells to which node a key belongs and a
Cache object to store key/value pairs.
When keys need to be moved (node list did change) then the old and new
owners are compared for each key and the key gets sent or deleted
accordingly.
"""
PUB_INTERVALL = timedelta(seconds=5)
IO_TIMEOUT = 5 * 1000 # milliseconds
CMD_NEW = "new"
CMD_GET = "get"
CMD_SET = "set"
def __init__(self, context, req_address, pub_address):
self._context = context
self._poller = Poller()
self._nodes_sockets = {} # requests and service sockets
# FIFO request queue for nodes: [in_progress, data, callback(response)]
self._nodes_requests = defaultdict(list) # requests queues for nodes
self._cache = Cache() # the cache
node_id = uuid1().hex # unique node id, based on current time
_LOG.info("node id: %s", node_id)
self._nodes = Nodes(node_id, req_address, pub_address) # other nodes
def _open_req_socket(self, addr):
req_socket = self._context.socket(REQ)
req_socket.setsockopt(RCVTIMEO, self.IO_TIMEOUT)
req_socket.connect(addr)
self._poller.register(req_socket, POLLIN)
return req_socket
def _open_sub_socket(self, addr):
sub_socket = self._context.socket(SUB)
sub_socket.setsockopt_string(SUBSCRIBE, "")
sub_socket.connect(addr)
self._poller.register(sub_socket, POLLIN)
return sub_socket
def _add_request(self, node_id, data, callback):
"""Adds a new request for a particular node.
Each request in the queue consists of:
- in progress flag
- data to be send
- function (with one argument, the response) to be called when the
response is ready
"""
self._nodes_requests[node_id].append([False, data, callback])
def _hanlde_subscriptions(self, poll_sockets):
"""Read the nodes list from each other node and merge the information
into the local node list.
:return: true if nodes where added
"""
added = []
for node_id, (_, pub_socket) in self._nodes_sockets.items():
if pub_socket in poll_sockets:
node_id, nodes = pub_socket.recv_json()
# Convert string to datetime.
nodes = {
i: (req_addr, pub_addr, _str_to_dt(last))
for i, (req_addr, pub_addr, last) in nodes.items()}
# Merge nodes list.
new_nodes = self._nodes.update_nodes(nodes)
# Create sockets for new nodes.
for node_id, req_addr, pub_addr in new_nodes:
_LOG.debug("adding node: %s", node_id)
req_socket = self._open_req_socket(req_addr)
sub_socket = self._open_sub_socket(pub_addr)
added.append((node_id, (req_socket, sub_socket)))
self._nodes_sockets.update(dict(added)) # save sockets
return len(added) > 0 # nodes list got changed?
def _add_node(self, node_id, req_addr, pub_addr, req_socket=None):
"""Add one node to the list and create the sockets for the request
and service URLs (subscribe to the node).
"""
_LOG.debug("adding node: %s", node_id)
# Add node to the nodes list.
self._nodes.add_node(node_id, req_addr, pub_addr)
if req_socket is None: # does that not yet exist?
req_socket = self._open_req_socket(req_addr)
sub_socket = self._open_sub_socket(pub_addr)
# Remember sockets.
self._nodes_sockets[node_id] = (req_socket, sub_socket)
def _remove_nodes(self, removed_nodes):
"""Unregister and remove a node, remove all pending request, too.
"""
for node_id in removed_nodes:
_LOG.debug("removing node: %s", node_id)
# Unregister sockets from poller.
req_socket, pub_socket = self._nodes_sockets.get(
node_id, (None, None))
if req_socket is not None:
self._poller.unregister(req_socket)
if pub_socket is not None:
self._poller.unregister(pub_socket)
# Forget the sockets and erase request queue.
self._nodes_sockets.pop(node_id, None)
self._nodes_requests.pop(node_id, None)
return len(removed_nodes) > 0 # nodes list got changed?
def _handle_responses(self, poll_sockets):
"""When a request from the queue gets an answer call the function for
that request, if possible.
"""
for node_id, (req_socket, _) in self._nodes_sockets.items():
# Some node did replay?
if req_socket in poll_sockets:
# Get the answer and call the callback function with it, if
# there was one.
response = req_socket.recv_json()
requests = self._nodes_requests[node_id]
if requests:
in_progress, _, callback = requests[0]
if in_progress:
callback(response)
# Request done, remove it from the queue.
self._nodes_requests[node_id] = requests[1:]
def _handle_request(self, node_changes, action, data):
# Handle the requested action.
_LOG.debug("Request %s: %s", action, str(data))
if action == self.CMD_NEW: # new node, register it
node_id, req_addr, pub_addr = data
self._add_node(node_id, req_addr, pub_addr)
node_changes[0] = True # a node was added!
return (self._nodes.id, self._nodes.pub_address)
if action == self.CMD_SET: # set a key and value
key, timestamp, value = data
timestamp = _str_to_dt(timestamp)
return self._cache.set(
key, value, timestamp,
self._nodes.get_nodes_for_index(key_index(key)))
if action == self.CMD_GET: # return value for a key
in_cache, timestamp, value = self._cache.get(data)
return (in_cache, _dt_to_str(timestamp), value)
def _rebalance(self):
""" Check if key should be on some other nodes now, move/delete as
necessary.
"""
send_entries = defaultdict(list)
remove_entries = []
# Loop through all keys and compare on which nodes they should be.
for key, ts, nodes, value, index in self._cache.key_indices:
new_nodes = self._nodes.get_nodes_for_index(index)
if new_nodes != nodes: # node list for that key changed?
if self._nodes.id not in new_nodes:
remove_entries.append(key) # no longer local
for new_node in new_nodes - nodes: # where should they be?
send_entries[new_node].append((key, ts, value))
self._cache.set(key, value, ts, new_nodes) # save new nodelist
# Queue requests to set the keys on the new nodes.
moves = 0
for new_node, entries in send_entries.items():
if new_node != self._nodes.id:
for key, ts, value in entries:
self._add_request(
new_node, (self.CMD_SET, (key, _dt_to_str(ts), value)),
lambda response: None)
moves += 1
# Remove dead nodes from cache.
for key in remove_entries:
self._cache.delete_key(key)
_LOG.debug(
"adjusted distribution, %d moves, %d deletes", moves,
len(remove_entries))
def _handle_api_get(self, api_pub_socket, req_id, key):
"""Handle a API get request from the local API.
If the key is not local, send a request to one of the responsible
nodes. Upon arrival of the response publish the response for the API,
using the request id, which only the right listens for.
"""
req_id = req_id.encode("utf-8")
# Publish the result.
def send_response(resp, req_id=req_id, api_pub_socket=api_pub_socket):
found, _, value = resp
found = b"1" if found else b"0"
value = value.encode("utf-8") if value else b""
api_pub_socket.send_multipart([req_id, found, value])
# Where is the key stored?
nodes = self._nodes.get_nodes_for_index(key_index(key))
if nodes:
if self._nodes.id in nodes: # local answer directly
in_cache, _, value = self._cache.get(key)
send_response((in_cache, None, value))
else: # remote, make request
node_id = choice(list(nodes))
self._add_request(node_id, (self.CMD_GET, key), send_response)
else: # can not be stored in cache, for whatever strange reason
send_response((False, None, None))
def _handle_api_set(self, api_pub_socket, req_id, key, value):
"""Handle a API set request from the local API.
Check where the key should be stored and make the appropriate requests.
The publish all results to the API, alltough the API only cares about
the fastest response.
"""
req_id = req_id.encode("utf-8")
def send_response(resp, req_id=req_id, api_pub_socket=api_pub_socket):
resp = str(resp).encode("utf-8") # "0", "-1", ...
api_pub_socket.send_multipart([req_id, resp])
# Where should the key go?
nodes = self._nodes.get_nodes_for_index(key_index(key))
if nodes:
timestamp = datetime.now()
if self._nodes.id in nodes: # save locally and publish response
resp = self._cache.set(key, value, timestamp, nodes)
send_response(resp)
nodes.remove(self._nodes.id) # done with local node!
for node_id in nodes: # make requests to all remote nodes
self._add_request(
node_id,
(self.CMD_SET, (key, _dt_to_str(timestamp), value)),
send_response)
else:
send_response(-2) # no nodes
def loop(self, api_port, req_addr):
"""Event loop, listen to all sockets and handle all messages.
If a req_address of an existing node is given the this node will
register itself there, before entering the loop.
The request on the api_port are handled by a Python WSGI instance
running the Flask API app.
"""
# Register to existing node?
if req_addr is not None:
_LOG.debug("Contacting %s", req_addr)
req_socket = self._open_req_socket(req_addr)
req_socket.send_json(
(self.CMD_NEW,
(self._nodes.id, self._nodes.req_address,
self._nodes.pub_address)))
node_id, pub_addr = req_socket.recv_json()
_LOG.debug("Received: %s %s", str(node_id), pub_addr)
self._add_node(node_id, req_addr, pub_addr, req_socket)
self._rebalance()
# Create request and service sockets.
nodes_publisher = self._context.socket(PUB)
nodes_publisher.setsockopt(RCVTIMEO, self.IO_TIMEOUT)
nodes_publisher.setsockopt(SNDTIMEO, self.IO_TIMEOUT)
_LOG.debug("Publishing on %s", self._nodes.pub_address)
nodes_publisher.bind(self._nodes.pub_address)
req_socket = self._context.socket(REP)
req_socket.setsockopt(RCVTIMEO, self.IO_TIMEOUT)
req_socket.setsockopt(SNDTIMEO, self.IO_TIMEOUT)
_LOG.debug("waiting for requests on %s", self._nodes.req_address)
req_socket.bind(self._nodes.req_address)
self._poller.register(req_socket, POLLIN)
# Create in-process sockets to the API app.
api_pull_socket = self._context.socket(PULL)
api_pull_socket.bind(PUSH_ENDPOINT)
self._poller.register(api_pull_socket, POLLIN)
api_pub_socket = self._context.socket(PUB)
api_pub_socket.bind(SUB_ENDPOINT)
_LOG.info("Entering server loop")
# Start web server.
set_config(self._context)
httpd = simple_server.make_server(
'0.0.0.0', int(api_port), app)
Thread(target=httpd.serve_forever).start()
# Enter ZMQ loop.
stop = False
last_published = None
try:
while not stop:
try:
# Wait for messages, but not too long!
sockets = dict(
self._poller.poll(self.PUB_INTERVALL.seconds * 1000))
except KeyboardInterrupt:
stop = True
else:
changes = [False]
# Handle incoming node updates (subscriptions).
if self._hanlde_subscriptions(sockets):
changes[0] = True
# Handle incoming responses.
self._handle_responses(sockets)
# Incoming requests?
if req_socket in sockets:
req_socket.send_json(
self._handle_request(
changes, *req_socket.recv_json()))
# Remove dead nodes?
if self._remove_nodes(self._nodes.remove_dead_nodes()):
changes[0] = True
# Did nodes change?
if changes[0]:
self._rebalance()
# Request something?
for node_id, requests in self._nodes_requests.items():
if requests and not requests[0][0]:
request = requests[0]
request[0] = True # in progress
self._nodes_sockets[node_id][0].send_json(
request[1])
# Publish something?
now = datetime.now()
if (last_published is None or
now - last_published > self.PUB_INTERVALL):
# Get nodes, convert last datetime to string
nodes = {
i: (req_addr, pub_addr, _dt_to_str(last))
for i, (req_addr, pub_addr, last)
in self._nodes.nodes.items()}
_LOG.debug(
"publishing:\n%s", "\n".join(
"{}: {}".format(i, str(n))
for i, n in nodes.items()))
nodes_publisher.send_json((self._nodes.id, nodes))
last_published = now
# Handle API get requests
if api_pull_socket in sockets:
req_id, action, key, value = (
api_pull_socket.recv_json())
if action == "get":
self._handle_api_get(api_pub_socket, req_id, key)
if action == "set":
self._handle_api_set(
api_pub_socket, req_id, key, value)
finally:
httpd.shutdown()
class Distributor(Thread):
def __init__(self, query):
Thread.__init__(self)
self._pool = ThreadPool(processes=4)
self._workers = HashRing(WORKER_SERVERS)
self._identity = bytes(uuid.uuid4())
self._query = query
self._init_sock()
def _log(self, text):
if LOG_DISTRIBUTOR:
log_debug(self, text)
def _init_sock(self):
self._context = Context(1)
self._poller = Poller()
self._set_sock()
def _set_sock(self):
self._socket = self._context.socket(DEALER)
self._socket.setsockopt(IDENTITY, self._identity)
self._poller.register(self._socket, POLLIN)
self._socket.connect(zmqaddr(self._get_broker(), BROKER_PORT))
self._socket.send(PPP_READY)
def _reset_sock(self):
self._poller.unregister(self._socket)
self._socket.setsockopt(LINGER, 0)
self._socket.close()
self._set_sock()
def _get_broker(self):
length = len(BROKER_SERVERS)
return BROKER_SERVERS[randint(0, length - 1)]
def _get_worker(self, uid):
return self._workers.get_node(uid)
def _get_user(self, buf):
if len(buf) < USERNAME_SIZE:
log_err(self, 'failed to get user, invalid length')
raise Exception(log_get(self, 'failed to get user'))
name = filter(lambda x:x != '*', buf[:USERNAME_SIZE])
if not name:
log_err(self, 'failed to get user')
raise Exception(log_get(self, 'failed to get user'))
return name
def _get_token(self, buf):
if len(buf) < UID_SIZE:
log_err(self, 'failed to get token, invalid length')
raise Exception(log_get(self, 'failed to get token'))
uid = None
token = None
if buf[UID_SIZE - 1] == '*':
user = self._get_user(buf)
uid, token = self._query.user.get(user, 'uid', 'password')
else:
uid = buf[0:UID_SIZE]
token = self._query.token.get(uid)
if uid and token:
return (uid, token)
else:
log_err(self, 'failed to get token')
raise Exception(log_get(self, 'failed to get token'))
def _reply(self, identity, seq, buf):
msg = [identity, '', seq, buf]
self._socket.send_multipart(msg)
def _request(self, addr, **args):
sock = io.connect(addr, WORKER_PORT)
try:
buf = bson.dumps(args)
io.send_pkt(sock, buf)
res = io.recv_pkt(sock)
return unicode2str(bson.loads(res)['result'])
finally:
io.close(sock)
def _proc(self, identity, seq, buf):
uid, token = self._get_token(buf)
if not uid or not token:
log_err(self, 'failed to process, cannot get token')
return
addr = self._get_worker(uid)
ret = self._request(addr, uid=uid, token=token, buf=buf)
self._reply(identity, seq, ret)
def _proc_safe(self, identity, seq, buf):
try:
self._proc(identity, seq, buf)
except:
log_err(self, 'failed to process')
def _handler(self, identity, seq, buf):
if DEBUG and not SAFE:
self._proc(identity, seq, buf)
else:
self._proc_safe(identity, seq, buf)
def run(self):
self._log('start ...')
liveness = PPP_HEARTBEAT_LIVENESS
timeout = time.time() + PPP_HEARTBEAT_INTERVAL
while True:
sockets = dict(self._poller.poll(PPP_HEARTBEAT_INTERVAL * 1000))
if sockets.get(self._socket) == POLLIN:
frames = self._socket.recv_multipart()
if not frames:
log_err(self, 'invalid request')
break
if len(frames) == PPP_NR_FRAMES:
self._pool.apply_async(self._proc, args=(frames[PPP_FRAME_ID], frames[PPP_FRAME_SEQ], frames[PPP_FRAME_BUF]))
elif len(frames) == 1 and frames[0] == PPP_HEARTBEAT:
liveness = PPP_HEARTBEAT_LIVENESS
else:
log_err(self, "invalid request")
else:
liveness -= 1
if liveness == 0:
time.sleep(random.randint(SLEEP_TIME / 2, SLEEP_TIME))
self._reset_sock()
liveness = PPP_HEARTBEAT_LIVENESS
if time.time() > timeout:
timeout = time.time() + PPP_HEARTBEAT_INTERVAL
self._socket.send(PPP_HEARTBEAT)
class StagerZmq(Component, Process, Connexions):
"""`StagerZmq` class represents a Stager pipeline Step.
It is derived from Process class.
It receives new input from its prev stage, thanks to its ZMQ REQ socket,
and executes its coroutine objet's run method by passing
input as parameter. Finaly it sends coroutine returned value to its next
stage, thanks to its ZMQ REQ socket,
The processus is launched by calling run method.
init() method is call by run method.
The processus is stopped by setting share data stop to True
"""
def __init__(
self, coroutine, sock_job_for_me_port,
name=None, connexions=dict(),main_connexion_name=None):
"""
Parameters
----------
coroutine : Class instance that contains init, run and finish methods
sock_job_for_me_port: str
Port number for input socket url
name: str
Stage name
main_connexion_name : str
Default next step name. Used to send data when destination is not provided
connexions: dict {'STEP_NANE' : (zmq STEP_NANE port in)}
Port number for socket for each next steps
"""
Process.__init__(self)
Component.__init__(self,parent=None)
self.name = name
Connexions.__init__(self,main_connexion_name,connexions)
self.coroutine = coroutine
self.sock_job_for_me_url = 'tcp://localhost:' + sock_job_for_me_port
self.done = False
self.waiting_since = Value('i',0)
self._nb_job_done = Value('i',0)
self._stop = Value('i',0)
self._running = Value('i',0)
def init(self):
"""
Initialise coroutine sockets and poller
Returns
-------
True if coroutine init and init_connexions methods returns True,
otherwise False
"""
if self.name is None:
self.name = "STAGER"
if self.coroutine is None:
return False
if self.coroutine.init() == False:
return False
return self.init_connexions()
def run(self):
"""
Method representing the processus's activity.
It polls its socket and when received new input from it,
it executes coroutine run method by passing new input.
Then it sends coroutine return value to its next stage,
thanks to its ZMQ REQ socket.
The poll method's timeout is 100 ms in case of self.stop flag
has been set to False.
Atfer the main while loop, coroutine.finish method is called
"""
if self.init() :
while not self.stop:
sockets = dict(self.poll.poll(100)) # Poll or time out (100ms)
if (self.sock_for_me in sockets and
sockets[self.sock_for_me] == POLLIN):
# Get the input from prev_stage
self.waiting_since.value = 0
self.running = 1
request = self.sock_for_me.recv_multipart()
receiv_input = loads(request[0])
# do the job
results = self.coroutine.run(receiv_input)
if isinstance(results, GeneratorType):
for val in results:
msg,destination = self.get_destination_msg_from_result(val)
self.send_msg(msg,destination)
else:
msg,destination = self.get_destination_msg_from_result(results)
self.send_msg(msg,destination)
# send acknoledgement to prev router/queue to inform it that I
# am available
self.sock_for_me.send_multipart(request)
self._nb_job_done.value = self._nb_job_done.value + 1
self.running = 0
else:
self.waiting_since.value = self.waiting_since.value+100 # 100 ms
self.sock_for_me.close()
self.finish()
self.done = True
def finish(self):
self.coroutine.finish()
def init_connexions(self):
"""
Initialise zmq sockets.
Because this class is s Process, This method must be call in the run
method to be hold by the correct processus.
"""
Connexions.init_connexions(self)
context = Context()
self.sock_for_me = context.socket(REQ)
self.sock_for_me.connect(self.sock_job_for_me_url)
# Use a ZMQ Pool to get multichannel message
self.poll = Poller()
# Register sockets
self.poll.register(self.sock_for_me, POLLIN)
# Send READY to next_router to inform about my capacity to compute new
# job
self.sock_for_me.send_pyobj("READY")
return True
@property
def wait_since(self):
return self.waiting_since.value
@property
def stop(self):
return self._stop.value
@stop.setter
def stop(self, value):
self._stop.value = value
@property
def nb_job_done(self):
return self._nb_job_done.value
@nb_job_done.setter
def nb_job_done(self, value):
self._nb_job_done.value = value
@property
def running(self):
return self._running.value
@running.setter
def running(self, value):
self._running.value = value
# socket to receive messages on
receiver = context.socket(PULL)
receiver.connect("tcp://localhost:7779")
# socket to send messages to
sender = context.socket(PUSH)
sender.connect("tcp://localhost:7780")
# socket to receive control messages on
controller = context.socket(SUB)
controller.connect("tcp://localhost:6670")
controller.setsockopt(SUBSCRIBE, "")
# poler for handling receiver and controller messages
poller = Poller()
poller.register(receiver, POLLIN)
poller.register(controller, POLLIN)
print "Waiting for job ..."
# poller handling
while True:
socks = dict(poller.poll())
if socks.get(receiver) == POLLIN:
msg = receiver.recv()
# process task
workload_msec = int(msg)
time.sleep(workload_msec * 0.001)
def run(self):
poller = Poller()
poller.register(self._socket, POLLIN)
while self._loop:
socks = dict(poller.poll(timeout=2000))
if self._socket in socks and socks[self._socket] == POLLIN:
message = Message(rawstr=self._socket.recv(NOBLOCK))
logger.debug("Request: " + str(message))
# send list of scanlines
if(message.type == "request" and
message.data["type"] == "scanlines"):
sat = message.data["satellite"]
epoch = "1950-01-01T00:00:00"
start_time = strp_isoformat(message.data.get("start_time",
epoch))
end_time = strp_isoformat(message.data.get("end_time",
epoch))
resp = Message('/oper/polar/direct_readout/' + self._station,
"scanlines",
[(utctime.isoformat(),
self._holder[sat][utctime][2])
for utctime in self._holder.get(sat, [])
if utctime >= start_time
and utctime <= end_time])
self._socket.send(str(resp))
# send one scanline
elif(message.type == "request" and
message.data["type"] == "scanline"):
sat = message.data["satellite"]
utctime = strp_isoformat(message.data["utctime"])
try:
url = urlparse(self._holder[sat][utctime][1])
except KeyError:
resp = Message('/oper/polar/direct_readout/'
+ self._station,
"missing")
else:
if url.scheme in ["", "file"]: # data is locally stored.
resp = Message('/oper/polar/direct_readout/'
+ self._station,
"scanline",
self._holder.get_scanline(sat, utctime),
binary=True)
else: # it's the address of a remote server.
resp = self.forward_request(urlunparse(url),
message)
self._socket.send(str(resp))
# take in a new scanline
elif(message.type == "notice" and
message.data["type"] == "scanline"):
sat = message.data["satellite"]
utctime = message.data["utctime"]
elevation = message.data["elevation"]
filename = message.data["filename"]
line_start = message.data["file_position"]
utctime = strp_isoformat(utctime)
self._holder.add_scanline(sat, utctime, elevation,
line_start, filename)
resp = Message('/oper/polar/direct_readout/'
+ self._station,
"notice",
"ack")
self._socket.send(str(resp))
elif(message.type == "ping"):
resp = Message('/oper/polar/direct_readout/'
+ self._station,
"pong",
{"station": self._station})
self._socket.send(str(resp))
if resp.binary:
logger.debug("Response: " + " ".join(str(resp).split()[:6]))
else:
logger.debug("Response: " + str(resp))
class Subscriber(object):
"""Subscriber
Subscribes to *addresses* for *topics*, and perform address translation of
*translate* is true. The function *message_filter* can be used to
discriminate some messages on the subscriber side. *topics* on the other
hand performs filtering on the publishing side (from zeromq 3).
Example::
from posttroll.subscriber import Subscriber, get_pub_address
addr = get_pub_address(service, timeout=2)
sub = Subscriber([addr], 'my_topic')
try:
for msg in sub(timeout=2):
print("Consumer got", msg)
except KeyboardInterrupt:
print("terminating consumer...")
sub.close()
"""
def __init__(self, addresses, topics='', message_filter=None,
translate=False):
self._topics = self._magickfy_topics(topics)
self._filter = message_filter
self._translate = translate
self.sub_addr = {}
self.addr_sub = {}
self.poller = None
self._hooks = []
self._hooks_cb = {}
self.poller = Poller()
self._lock = Lock()
self.update(addresses)
self._loop = True
def add(self, address, topics=None):
"""Add *address* to the subscribing list for *topics*.
It topics is None we will subscibe to already specified topics.
"""
with self._lock:
if address in self.addresses:
return False
topics = self._magickfy_topics(topics) or self._topics
LOGGER.info("Subscriber adding address %s with topics %s",
str(address), str(topics))
subscriber = get_context().socket(SUB)
for t__ in topics:
subscriber.setsockopt_string(SUBSCRIBE, six.text_type(t__))
subscriber.connect(address)
self.sub_addr[subscriber] = address
self.addr_sub[address] = subscriber
if self.poller:
self.poller.register(subscriber, POLLIN)
return True
def remove(self, address):
"""Remove *address* from the subscribing list for *topics*.
"""
with self._lock:
try:
subscriber = self.addr_sub[address]
except KeyError:
return False
LOGGER.info("Subscriber removing address %s", str(address))
if self.poller:
self.poller.unregister(subscriber)
del self.addr_sub[address]
del self.sub_addr[subscriber]
subscriber.close()
return True
def update(self, addresses):
"""Updating with a set of addresses.
"""
if isinstance(addresses, six.string_types):
addresses = [addresses, ]
s0_, s1_ = set(self.addresses), set(addresses)
sr_, sa_ = s0_.difference(s1_), s1_.difference(s0_)
for a__ in sr_:
self.remove(a__)
for a__ in sa_:
self.add(a__)
return bool(sr_ or sa_)
def add_hook_sub(self, address, topics, callback):
"""Specify a *callback* in the same stream (thread) as the main receive
loop. The callback will be called with the received messages from the
specified subscription.
Good for operations, which is required to be done in the same thread as
the main recieve loop (e.q operations on the underlying sockets).
"""
LOGGER.info("Subscriber adding SUB hook %s for topics %s",
str(address), str(topics))
socket = get_context().socket(SUB)
for t__ in self._magickfy_topics(topics):
socket.setsockopt_string(SUBSCRIBE, six.text_type(t__))
socket.connect(address)
self._add_hook(socket, callback)
def add_hook_pull(self, address, callback):
"""Same as above, but with a PULL socket.
(e.g good for pushed 'inproc' messages from another thread).
"""
LOGGER.info("Subscriber adding PULL hook %s", str(address))
socket = get_context().socket(PULL)
socket.connect(address)
self._add_hook(socket, callback)
def _add_hook(self, socket, callback):
"""Generic hook. The passed socket has to be "receive only".
"""
self._hooks.append(socket)
self._hooks_cb[socket] = callback
if self.poller:
self.poller.register(socket, POLLIN)
@property
def addresses(self):
"""Get the addresses
"""
return self.sub_addr.values()
@property
def subscribers(self):
"""Get the subscribers
"""
return self.sub_addr.keys()
def recv(self, timeout=None):
"""Receive, optionally with *timeout* in seconds.
"""
if timeout:
timeout *= 1000.
for sub in list(self.subscribers) + self._hooks:
self.poller.register(sub, POLLIN)
self._loop = True
try:
while self._loop:
sleep(0)
try:
socks = dict(self.poller.poll(timeout=timeout))
if socks:
for sub in self.subscribers:
if sub in socks and socks[sub] == POLLIN:
m__ = Message.decode(sub.recv_string(NOBLOCK))
if not self._filter or self._filter(m__):
if self._translate:
url = urlsplit(self.sub_addr[sub])
host = url[1].split(":")[0]
m__.sender = (m__.sender.split("@")[0]
+ "@" + host)
yield m__
for sub in self._hooks:
if sub in socks and socks[sub] == POLLIN:
m__ = Message.decode(sub.recv_string(NOBLOCK))
self._hooks_cb[sub](m__)
else:
# timeout
yield None
except ZMQError as err:
LOGGER.exception("Receive failed: %s", str(err))
finally:
for sub in list(self.subscribers) + self._hooks:
self.poller.unregister(sub)
def __call__(self, **kwargs):
return self.recv(**kwargs)
def stop(self):
"""Stop the subscriber.
"""
self._loop = False
def close(self):
"""Close the subscriber: stop it and close the local subscribers.
"""
self.stop()
for sub in list(self.subscribers) + self._hooks:
try:
sub.setsockopt(LINGER, 1)
sub.close()
except ZMQError:
pass
@staticmethod
def _magickfy_topics(topics):
"""Add the magick to the topics if missing.
"""
# If topic does not start with messages._MAGICK (pytroll:/), it will be
# prepended.
if topics is None:
return None
if isinstance(topics, six.string_types):
topics = [topics, ]
ts_ = []
for t__ in topics:
if not t__.startswith(_MAGICK):
if t__ and t__[0] == '/':
t__ = _MAGICK + t__
else:
t__ = _MAGICK + '/' + t__
ts_.append(t__)
return ts_
def __del__(self):
for sub in list(self.subscribers) + self._hooks:
try:
sub.close()
except:
pass
class PushRequester(object):
"""Base requester class.
"""
request_retries = 3
def __init__(self, host, port):
self._socket = None
self._reqaddress = "tcp://" + host + ":" + str(port)
self._poller = Poller()
self._lock = Lock()
self.failures = 0
self.jammed = False
self.connect()
def connect(self):
"""Connect to the server
"""
self._socket = context.socket(REQ)
self._socket.connect(self._reqaddress)
self._poller.register(self._socket, POLLIN)
def stop(self):
"""Close the connection to the server
"""
self._socket.setsockopt(LINGER, 0)
self._socket.close()
self._poller.unregister(self._socket)
def reset_connection(self):
"""Reset the socket
"""
self.stop()
self.connect()
def __del__(self, *args, **kwargs):
self.stop()
def send_and_recv(self, msg, timeout=REQ_TIMEOUT):
with self._lock:
retries_left = self.request_retries
request = str(msg)
self._socket.send(request)
rep = None
while retries_left:
socks = dict(self._poller.poll(timeout))
if socks.get(self._socket) == POLLIN:
reply = self._socket.recv()
if not reply:
LOGGER.error("Empty reply!")
break
rep = Message(rawstr=reply)
self.failures = 0
self.jammed = False
break
else:
LOGGER.warning("Timeout from " + str(self._reqaddress)
+ ", retrying...")
# Socket is confused. Close and remove it.
self.stop()
retries_left -= 1
if retries_left <= 0:
LOGGER.error("Server doesn't answer, abandoning... " +
str(self._reqaddress))
self.connect()
self.failures += 1
if self.failures == 5:
LOGGER.critical("Server jammed ? %s",
self._reqaddress)
self.jammed = True
break
LOGGER.info("Reconnecting and resending " + str(msg))
# Create new connection
self.connect()
self._socket.send(request)
return rep
class Requester(object):
"""Make a request connection, waiting to get scanlines .
"""
def __init__(self, host, port):
self._host = host
self._port = port
self._context = Context()
self._socket = self._context.socket(REQ)
self._socket.setsockopt(LINGER, 1)
self._socket.connect("tcp://"+host+":"+str(port))
self._poller = Poller()
self._poller.register(self._socket, POLLIN)
def stop(self):
"""Close the socket.
"""
self._socket.close()
def __del__(self, *args, **kwargs):
self.stop()
def send(self, msg):
"""Send a message.
"""
return self._socket.send(str(msg))
def recv(self, timeout=None):
"""Receive a message. *timeout* in ms.
"""
if self._poller.poll(timeout):
return Message(rawstr=self._socket.recv())
else:
raise IOError("Timeout from " + str(self._host) +
":" + str(self._port))
def get_line(self, satellite, utctime):
"""Get the scanline of *satellite* at *utctime*.
"""
msg = Message('/oper/polar/direct_readout/norrköping',
'request',
{"type": "scanline",
"satellite": satellite,
"utctime": utctime.isoformat()})
self.send(msg)
return self.recv(1000).data
def get_slice(self, satellite, start_time, end_time):
"""Get a slice of scanlines.
"""
msg = Message('/oper/polar/direct_readout/norrköping',
'request',
{"type": 'scanlines',
"satellite": satellite,
"start_time": start_time.isoformat(),
"end_time": end_time.isoformat()})
self.send(msg)
return self.recv(1000).data
def send_lineinfo(self, sat, utctime, elevation, filename, pos):
"""Send information to our own server.
"""
msg = Message('/oper/polar/direct_readout/norrköping',
'notice',
{"type": 'scanline',
"satellite": sat,
"utctime": utctime.isoformat(),
"elevation": elevation,
"filename": filename,
"file_position": pos})
self.send(msg)
self._socket.recv()
def client_handler(ctx, pipe, bot, rule_object, writer_addr, broker_addr):
'''Connect to and marshall messages between broker and writer sockets.
Parameters
----------
bot : zio.Message
The BOT message
rule_object: dicionary
A ruleset rule object.
writer_addr :: string
The address of the writer's PULL socket to connect.
broker_addr : string
The address of the broker's SERVER socket to connect.
'''
# An HDF path to be added to every message we send to writer.
mattr = message_to_dict(bot)
rattr = dict(rule_object.get("attr",{}), **mattr)
log.info(f'writer: attrs: {rattr}')
try:
base_path = rule_object.get("grouppat","/").format(**rattr)
except KeyError as e:
log.error(f'writer: missing attribute: {e}')
raise
log.debug(f'client_handler(msg, "{base_path}", "{broker_addr}", "{writer_addr}")')
log.debug(bot)
pipe.signal()
push = ctx.socket(PUSH)
push.connect(writer_addr)
sock = ctx.socket(CLIENT)
port = Port("write-handler", sock)
port.connect(broker_addr)
port.online(None)
direction = mattr["direction"]
if direction != "inject":
raise RuntimeError(f'zio.flow.hdf.writer bad direction: "{direction}"')
credit = mattr["credit"]
flow = Flow(port, direction, credit)
log.debug (f'writer({base_path}) send BOT to {broker_addr}')
bot = flow.bot(bot) # this introduces us to the server
log.debug (f'writer({base_path}) got response:\n{bot}')
flow.begin()
def push_message(m):
log.debug (f'write_handler({base_path}) push {m}')
attr = message_to_dict(m)
attr['hdfgroup'] = base_path
m.label = json.dumps(attr)
push.send(m.encode())
#push_message(bot)
poller = Poller()
poller.register(pipe, POLLIN)
poller.register(sock, POLLIN)
while True:
for which,_ in poller.poll():
if not which:
return
if which == pipe: # signal exit
log.debug ('write_handler pipe hit')
return
# o.w. we have flow
try:
msg = flow.get()
except TransmissionEnd as te:
flow.eotsend()
break
push_message(msg)
continue
log.debug ('write_handler exiting')
pipe.signal()
server_sock = context.socket(SUB)
server_sock.connect('tcp://localhost:6667')
server_sock.setsockopt(SUBSCRIBE, "")
# this is public endpoint for subscribers
client_sock = context.socket(PUB)
client_sock.bind("tcp://*:6668")
# socket to receive control messages on
controller = context.socket(SUB)
controller.connect('tcp://localhost:6670')
controller.setsockopt(SUBSCRIBE, "")
# poller for handling receiver and controller messages
poller = Poller()
poller.register(server_sock, POLLIN)
poller.register(controller, POLLIN)
print 'Weather proxy started ...'
# shunt messages out to our own subscriber or handle incomming commandds
while True:
socks = dict(poller.poll())
if socks.get(server_sock) == POLLIN:
# process weather updates to clients
msg = server_sock.recv()
more = server_sock.getsockopt(RCVMORE)
if more:
client_sock.send(msg, SNDMORE)
else:
class ServiceMixin(Thread):
def __init__(self, pipe, local_ep, local_uuid, config_svc):
Thread.__init__(self, name='dcamp.service.{}'.format(self))
self.ctx = Context.instance()
self.__control_pipe = pipe
assert isinstance(local_ep, EndpntSpec)
self.__endpoint = local_ep
assert isinstance(local_uuid, UUID)
self.__uuid = local_uuid
self.__cfgsvc = config_svc
self.logger = getLogger('dcamp.service.%s' % self)
self.poller = Poller()
self.poller_timer = None
self.poller.register(self.__control_pipe, POLLIN)
def __str__(self):
return self.__class__.__name__
@property
def cfgsvc(self):
return self.__cfgsvc
@property
def endpoint(self):
return self.__endpoint
@property
def uuid(self):
return self.__uuid
def __send_control(self, message):
self.__control_pipe.send_string(message)
def __recv_control(self):
return self.__control_pipe.recv_string()
def _cleanup(self):
# tell role we're done (if we can)
if not self.in_errored_state:
# @todo: this might raise an exception / issue #38
self.__send_control('STOPPED')
self.logger.debug('sent STOPPED control reply')
# shared context; will be term()'ed by caller
self.__control_pipe.close()
del self.__control_pipe
self.logger.debug('service cleanup finished; exiting')
def _pre_poll(self):
pass
def _post_poll(self, items):
raise NotImplementedError('subclass must implement _post_poll()')
def _do_control(self):
"""
Process control command on the pipe.
"""
msg = self.__recv_control()
if 'STOP' == msg:
self.logger.debug('received STOP control command')
self.stop_state()
else:
self.__send_control('WTF')
self.logger.error('unknown control command: %s' % msg)
def run(self):
self.run_state()
# wait for configuration service to init
if self.__cfgsvc is not None:
self.__cfgsvc.wait_for_gogo()
while self.in_running_state:
try:
self._pre_poll()
items = dict(self.poller.poll(self.poller_timer))
self._post_poll(items)
if self.__control_pipe in items:
self._do_control()
except ZMQError as e:
if e.errno == ETERM:
self.logger.debug('received ETERM: %s' % self.__class__)
self.error_state()
else:
raise
# thread is stopping; cleanup and exit
return self._cleanup()
class Cornerstone(Scaffold):
""" Cornerstone can be used to create a 0mq poll loop.
Upon creation of a Cornerstone instance, the initial state of the instance
internal xmq poll loop is passive. To start the loop call Cornerstone
run(). To stop the Cornerstone instance call Cornerstone.kill().
Cornerstone only allows for one zmq input port and one zmq output port.
Cornerstone support respectively; Cornerstone.register_input_sock() and
Cornerstone.register_output_sock() methods.
Cornerstone implements an internal signal handler for detection of
interrupt signals to handle shutdown of connection resources.
Example Usage:
>>> import threading
>>> import time
>>> from zmq import Context, SUB, SUBSCRIBE
>>> # create, configure, and run a Cornerstone instance
>>> foo = Cornerstone()
>>> property_bag = foo.__create_property_bag__()
>>> property_bag.heartbeat = 1
>>> foo.configure(args=property_bag)
>>> t = threading.Thread(target=foo.run)
>>> t.start()
>>> time.sleep(1)
>>> assert t.is_alive()
>>> foo.kill()
>>> t.join(1)
>>> assert not t.is_alive()
>>> # register an input socket
>>> ctx = foo.zmq_ctx
>>> sock = ctx.socket(SUB)
>>> sock.connect('tcp://localhost:6670')
>>> sock.setsockopt(SUBSCRIBE, "")
>>> foo.register_input_sock(sock)
>>> t = threading.Thread(target=foo.run)
>>> t.start()
>>> time.sleep(1)
>>> foo.kill()
>>> t.join(1)
>>> assert not t.is_alive()
"""
def __init__(self, **kwargs):
self._input_sock = None
self._output_sock = None
self._control_sock = None
# determine if outgoing messages should enable NOBLOCK on send
# default behaviour is to block on a send call till receiver is present
self.no_block_send = False
# configure the interrupt handling
self._stop = True
signal.signal(signal.SIGINT, self._signal_interrupt_handler)
# a regular hearbeat interval must be set to the default.
self.heartbeat = 3 # seconds
# create the zmq context
self.zmq_ctx = Context()
# set the default input receive handler, if none has been assigned
if not hasattr(self, 'input_recv_handler'):
self.input_recv_handler = self._default_recv_handler
# set the default handler, if none has been assigned.
if not hasattr(self, '_command_handler'):
self._command_handler = self._default_command_handler
# construct the poller
self._poll = Poller()
# monitoring of message stream is off by default
self.monitor_stream = False
Scaffold.__init__(self, **kwargs)
def configuration_options(self, arg_parser=None):
"""
The configuration_options method utilizes the arg_parser parameter to
add arguments that should be handled during configuration.
Keyword Arguments:
arg_parser - argparse.ArgumentParser object.
Sample invocation:
>>> import argparse
>>> parser = argparse.ArgumentParser(prog='app.py')
>>> foo = Cornerstone()
>>> foo.configuration_options(arg_parser=parser)
>>> args = parser.print_usage() # doctest: +NORMALIZE_WHITESPACE
usage: app.py [-h] [--heartbeat HEARTBEAT] [--monitor_stream]
[--no_block_send]
"""
assert arg_parser
arg_parser.add_argument('--heartbeat',
type=int,
default=3,
help="Set the heartbeat rate in seconds of "
"the core 0mq poller timeout.")
arg_parser.add_argument('--monitor_stream',
action='store_true',
help='Enable the sampling of message flow.')
arg_parser.add_argument('--no_block_send',
action='store_true',
help='Enable NOBLOCK on the sending of messages.'
' This will cause an message to be dropped '
'if no receiver is present.')
def configure(self, args=None):
"""
The configure method configures a Cornerstone instance by
prior to the invocation of start.
Keyword Arguments:
args - an object with attributes set to the argument values.e
"""
assert args
def register_input_sock(self, sock):
"""
Register a given input socket as the ingest point for a Cornerstone
instance.
Keyward Arguments:
sock - the input socket that is to be registered.
Return: None
Cornerstone does not support multiple input sockets, so any currently
registered input socket will be discarded. This is a per instance
limitation, in which case the primary concern is ipaddress collision.
Example Usage:
>>> from zmq import SUB, SUBSCRIBE
>>> foo = Cornerstone()
>>> ctx = foo.zmq_ctx
>>> sock1 = ctx.socket(SUB)
>>> sock1.connect('tcp://localhost:2880')
>>> sock1.setsockopt(SUBSCRIBE, "")
>>> assert foo._poll.sockets == {}
>>> foo.register_input_sock(sock1)
>>> assert foo._poll.sockets.has_key(sock1)
>>> sock2 = ctx.socket(SUB)
>>> sock2.connect('tcp://localhost:2881')
>>> sock2.setsockopt(SUBSCRIBE, "")
>>> foo.register_input_sock(sock2)
>>> assert not foo._poll.sockets.has_key(sock1)
>>> assert foo._poll.sockets.has_key(sock2)
"""
# if there is an existing input socket, then it will be removed.
if self._input_sock is not None:
self._poll.unregister(self._input_sock)
self._input_sock.close()
self._input_sock = None
self._input_sock = sock
if self._input_sock is not None:
self._poll.register(self._input_sock, POLLIN)
def register_output_sock(self, sock):
"""
Register a given output socket as the egress point for a Cornerstone
instance.
Keyward Arguments:
sock - the output socket that is to be registered.
Return: none
Cornerstone does not support multiple output sockets,
so any currently registered output socket will be discarded. This is
a per instance limitation. In which case the primary concern is
ipaddress collision.
Example Usage:
>>> from zmq import PUB
>>> foo = Cornerstone()
>>> ctx = foo.zmq_ctx
>>> sock1 = ctx.socket(PUB)
>>> sock1.bind('tcp://*:2880')
>>> assert foo._output_sock == None
>>> foo.register_output_sock(sock1)
>>> assert foo._output_sock == sock1
>>> sock2 = ctx.socket(PUB)
>>> sock2.bind('tcp://*:28881')
>>> foo.register_output_sock(sock2)
>>> assert foo._output_sock == sock2
"""
# if there is an existing output socket, then it will be removed.
if self._output_sock is not None:
self._output_sock.close()
self._output_sock = None
self._output_sock = sock
def send(self, msg):
assert msg
if self.monitor_stream:
self.log.info('o: %s', msg)
if not self.no_block_send:
self._output_sock.send(msg)
else:
try:
self._output_sock.send(msg, NOBLOCK)
except:
self.log.error("Unexpected error:", sys.exc_info()[0])
def setRun(self):
self._stop = False
def isStopped(self):
return self._stop
def run(self):
"""
Comment: -- AAA --
What needs to occur here si to see if there is a 0mq connection
configured. If so, then we will simply push to that connector. This
will be the default behavior, at least for now. There should be a
mechanism for transmitting the data out to a registered handler.
"""
self._stop = False
self.log.info('Beginning run() with configuration: %s', self._args)
#todo: raul - move this section to command configuraiton layer
# +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
# of course this is when a command configuration layer get's added
controller = self.zmq_ctx.socket(SUB)
controller.connect('tcp://localhost:7885')
controller.setsockopt(SUBSCRIBE, "")
self._control_sock = controller
self._poll.register(self._control_sock)
# +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
loop_count = 0
input_count = 0
while True:
try:
socks = dict(self._poll.poll(timeout=self.heartbeat))
loop_count += 1
if self.monitor_stream and (loop_count % 1000) == 0:
sys.stdout.write('loop(%s)' % loop_count)
sys.stdout.flush()
if self._input_sock and socks.get(self._input_sock) == POLLIN:
#todo: raul - this whole section needs to be redone,
# see additional comment AAA above.
msg = self.input_recv_handler(self._input_sock)
input_count += 1
if self.monitor_stream: # and (input_count % 10) == 0:
self.log.info('i:%s- %s', input_count, msg)
if (self._control_sock and
socks.get(self._control_sock) == POLLIN):
msg = self._control_sock.recv()
if self._command_handler is not None:
self._command_handler(msg)
if self._stop:
self.log.info('Stop flag triggered ... shutting down.')
break
except ZMQError, ze:
if ze.errno == 4: # Known exception due to keyboard ctrl+c
self.log.info('System interrupt call detected.')
else: # exit hard on unhandled exceptions
self.log.error('Unhandled exception in run execution:%d - %s'
% (ze.errno, ze.strerror))
exit(-1)
# close the sockets held by the poller
self._control_sock.close()
self.register_input_sock(sock=None)
self.register_output_sock(sock=None)
self.log.info('Run terminated for %s', self.name)
class Broker(Thread):
def __init__(self, faddr, baddr):
Thread.__init__(self)
self._faddr = faddr
self._baddr = baddr
self._init()
def _log(self, text):
if LOG_BROKER:
log_debug(self, text)
def _init(self):
self._context = Context(1)
self._queue = BrokerQueue()
self._init_frontend()
self._init_backend()
self._init_pollers()
self._active = True
def _init_frontend(self):
self._frontend = self._context.socket(ROUTER)
self._frontend.bind(zmqaddr(self._faddr, GATEWAY_PORT))
def _init_backend(self):
self._backend = self._context.socket(ROUTER)
self._backend.bind(zmqaddr(self._baddr, BROKER_PORT))
def _init_pollers(self):
self._poller1 = Poller()
self._poller2 = Poller()
self._poller1.register(self._backend, POLLIN)
self._poller2.register(self._backend, POLLIN)
self._poller2.register(self._frontend, POLLIN)
def run(self):
self._log('start ...')
timeout = time.time() + PPP_HEARTBEAT_INTERVAL
while self._active:
if len(self._queue.queue) > 0:
poller = self._poller2
else:
poller = self._poller1
socks = dict(poller.poll(PPP_HEARTBEAT_INTERVAL * 1000))
if socks.get(self._backend) == POLLIN:
frames = self._backend.recv_multipart()
if not frames:
break
identity = frames[0]
self._queue.add(BrokerItem(identity))
msg = frames[1:]
if len(msg) == 1:
if msg[0] not in (PPP_READY, PPP_HEARTBEAT):
log_err(self, "invalid message")
else:
self._frontend.send_multipart(msg)
if time.time() >= timeout:
for identity in self._queue.queue:
msg = [identity, PPP_HEARTBEAT]
self._backend.send_multipart(msg)
timeout = time.time() + PPP_HEARTBEAT_INTERVAL
if socks.get(self._frontend) == POLLIN:
frames = self._frontend.recv_multipart()
if not frames:
break
frames.insert(0, self._queue.pop())
self._backend.send_multipart(frames)
self._queue.purge()
def stop(self):
self._active = False
class RouterQueue(Process, Component):
"""`RouterQueue` class represents a router between pipeline steps, and it
manages queue for prev step.
It is derived from Process class.
RouterQueue class is connected to one or more input steps and to one
or more output steps thanks to zmq.ROUTER sockets.
If inputs arrive quickers than output are sent (because next stage have not
enough time to compute) these inputs are queued in RouterQueue.
RouterQueue send output the next steps in LRU(last recently used) pattern.
If a queue limit is reach for a step, RouterQueue replies "FULL"
without taking new job in account, so the prev step have to send it again
later.
"""
def __init__(self, connexions=dict(), gui_address=None):
"""
Parameters
----------
connexions: dict {'STEP_NANE' : (STEP port in, STEP port out,
STEP queue lengh max )}
Port in, port out for socket for each next steps.
Max queue lengh (-1 menans no maximum)
gui_address : str
GUI port for ZMQ 'hostname': + 'port'
"""
Process.__init__(self)
Component.__init__(self, parent=None)
self.gui_address = gui_address
# list of available stages which receive next job
# This list allow to use next_stage in a LRU (Last recently used)
# pattern
self.next_available_stages = dict()
# queue jobs to be send to next_stage
self.queue_jobs = dict()
self.router_sockets = dict()
self.dealer_sockets = dict()
self.queue_limit = dict()
self.connexions = connexions
self.done = False
self._stop = Value('i', 0)
self._total_queue_size = Value('i', 0)
def run(self):
"""
Method representing the processus’s activity.
It sends a job present in its queue (FIFO) to an available stager
(if exist). Then it polls its sockets (in and out).
When received new input from input socket, it appends contains to
its queue.
When received a signal from its output socket, it append sender
(a pipeline step) to availble stagers list
"""
if self.init_connexions():
nb_job_remains = 0
while not self.stop or nb_job_remains > 0:
for name in self.connexions:
queue = self.queue_jobs[name]
next_available = self.next_available_stages[name]
if queue and next_available:
# get that oldest job and remove it form list
job = self.queue_jobs[name].pop(0)
if self.gui_address: self.update_gui(name)
# Get the next_stage for new job, and remove it from
# available list
next_stage = self.next_available_stages[name].pop(0)
# send new job
self.dealer_sockets[name].send_multipart(
[next_stage, b"", dumps(job)])
# check if new socket message arrive. Or skip after timeout
# (100 s)
sockets = dict(self.poller.poll(100))
# Test if message arrived from next_stages
for n, socket_dealer in self.dealer_sockets.items():
if (socket_dealer in sockets
and sockets[socket_dealer] == POLLIN):
request = socket_dealer.recv_multipart()
# Get next_stage identity(to responde) and message
next_stage, _, _ = request[:3]
# add stager to next_available_stages
self.next_available_stages[n].append(next_stage)
# Test if message arrived from prev_stage (stage or producer)
for n, socket_router in self.router_sockets.items():
if (socket_router in sockets
and sockets[socket_router] == POLLIN):
# Get next prev_stage request
address, empty, request = socket_router.recv_multipart(
)
# store it to job queue
queue = self.queue_jobs[n]
if (len(queue) > self.queue_limit[n]
and self.queue_limit[n] != -1):
socket_router.send_multipart(
[address, b"", b"FULL"])
else:
queue.append(loads(request))
if self.gui_address: self.update_gui(n)
socket_router.send_multipart([address, b"", b"OK"])
nb_job_remains = 0
for n, queue in self.queue_jobs.items():
nb_job_remains += len(queue)
self._total_queue_size.value = nb_job_remains
for socket in self.router_sockets.values():
socket.close()
for socket in self.dealer_sockets.values():
socket.close()
self.done = True
def isQueueEmpty(self, stage_name=None):
"""
Get status of steps' queue
Parameters
----------
stage_name: str
router_name corresponding to stager name or consumer name
If stage_name=None, it take in account all queues
Returns
-------
True is corresponding queue is empty, otherwise False
If stage_name = None it returns True if sum of all queues is 0
"""
if stage_name:
val = stage_name.find("$$processus_number$$")
if val != -1:
name_to_search = stage_name[0:val]
else:
name_to_search = stage_name
for name, queue in self.queue_jobs.items():
if name.find("_router"):
pos = name.find("_router")
name = name[:pos]
if name == name_to_search:
if not queue:
return True
return False
else:
for queue in self.queue_jobs.values():
if queue:
return False
return True
def init_connexions(self):
"""
Initialise zmq sockets, poller and queues.
Because this class is s Process, This method must be call in the run
method to be hold by the correct processus.
"""
# Prepare our context and sockets
context = Context()
# Socket to talk to prev_stages
for name, connexions in self.connexions.items():
self.queue_limit[name] = connexions[2]
sock_router = context.socket(ROUTER)
try:
sock_router.bind('tcp://*:' + connexions[0])
except ZMQError as e:
self.log.error('{} : tcp://localhost:{}'.format(
e, connexions[0]))
return False
self.router_sockets[name] = sock_router
# Socket to talk to next_stages
sock_dealer = context.socket(ROUTER)
try:
sock_dealer.bind("tcp://*:" + connexions[1])
except ZMQError as e:
self.log.error('{} : tcp://localhost:{}'.format(
e, connexions[1]))
return False
self.dealer_sockets[name] = sock_dealer
self.next_available_stages[name] = list()
self.queue_jobs[name] = list()
# Use a ZMQ Pool to get multichannel message
self.poller = Poller()
# Register dealer socket to next_stage
for n, dealer in self.dealer_sockets.items():
self.poller.register(dealer, POLLIN)
for n, router in self.router_sockets.items():
self.poller.register(router, POLLIN)
# Register router socket to prev_stages or producer
self.socket_pub = context.socket(PUB)
if self.gui_address is not None:
try:
self.socket_pub.connect("tcp://" + self.gui_address)
except ZMQError as e:
self.log.error("".format(e, self.gui_address))
return False
# This flag stop this current processus
return True
def update_gui(self, name):
"""
send status to GUI
name: str
step name
"""
msg = [name, str(len(self.queue_jobs[name]))]
self.socket_pub.send_multipart([b'GUI_ROUTER_CHANGE', dumps(msg)])
@property
def stop(self):
return self._stop.value
@stop.setter
def stop(self, value):
self._stop.value = value
@property
def total_queue_size(self):
return self._total_queue_size.value
class RequestManager(Thread):
"""Manage requests.
"""
def __init__(self, port, attrs=None):
Thread.__init__(self)
self._loop = True
self.out_socket = get_context().socket(ROUTER)
self.out_socket.bind("tcp://*:" + str(port))
self.port = port
self.in_socket = get_context().socket(PULL)
self.in_socket.bind("inproc://replies" + str(port))
self._poller = Poller()
self._poller.register(self.out_socket, POLLIN)
self._poller.register(self.in_socket, POLLIN)
self._attrs = attrs
try:
# Checking the validity of the file pattern
_pattern = globify(attrs["origin"])
except ValueError as err:
raise ConfigError('Invalid file pattern: ' + str(err))
except KeyError:
if 'listen' not in attrs:
raise
self._deleter = Deleter()
try:
self._station = self._attrs["station"]
except (KeyError, TypeError):
LOGGER.warning("Station is not defined in config file")
self._station = "unknown"
LOGGER.debug("Station is '%s'" % self._station)
def start(self):
self._deleter.start()
Thread.start(self)
def pong(self, message):
"""Reply to ping
"""
return Message(message.subject, "pong", {"station": self._station})
def push(self, message):
"""Reply to push request
"""
for the_dict in gen_dict_contains(message.data, 'uri'):
uri = urlparse(the_dict['uri'])
rel_path = the_dict.get('path', '')
pathname = uri.path
# FIXME: check against file_cache
if 'origin' in self._attrs and not fnmatch.fnmatch(
os.path.basename(pathname),
os.path.basename(globify(self._attrs["origin"]))):
LOGGER.warning('Client trying to get invalid file: %s',
pathname)
return Message(message.subject,
"err",
data="{0:s} not reachable".format(pathname))
try:
move_it(pathname,
message.data['destination'],
self._attrs,
rel_path=rel_path)
except Exception as err:
return Message(message.subject, "err", data=str(err))
else:
if (self._attrs.get('compression')
or self._attrs.get('delete', 'False').lower()
in ["1", "yes", "true", "on"]):
self._deleter.add(pathname)
if 'dataset' in message.data:
mtype = 'dataset'
elif 'collection' in message.data:
mtype = 'collection'
elif 'uid' in message.data:
mtype = 'file'
else:
raise KeyError('No known metadata in message.')
new_msg = Message(message.subject, mtype, data=message.data.copy())
new_msg.data['destination'] = clean_url(new_msg.data['destination'])
return new_msg
def ack(self, message):
"""Reply with ack to a publication
"""
for url in gen_dict_extract(message.data, 'uri'):
uri = urlparse(url)
pathname = uri.path
if 'origin' in self._attrs and not fnmatch.fnmatch(
os.path.basename(pathname),
os.path.basename(globify(self._attrs["origin"]))):
LOGGER.warning('Client trying to get invalid file: %s',
pathname)
return Message(message.subject,
"err",
data="{0:s} not reacheable".format(pathname))
if (self._attrs.get('compression') or self._attrs.get(
'delete', 'False').lower() in ["1", "yes", "true", "on"]):
self._deleter.add(pathname)
new_msg = Message(message.subject, "ack", data=message.data.copy())
try:
new_msg.data['destination'] = clean_url(
new_msg.data['destination'])
except KeyError:
pass
return new_msg
def info(self, message):
topic = message.subject
max_count = 2256 # Let's set a (close to arbitrary) limit on messages size.
try:
max_count = min(message.data.get("max_count", max_count),
max_count)
except AttributeError:
pass
uptime = datetime.datetime.utcnow() - START_TIME
files = []
with file_cache_lock:
for i in file_cache:
if i.startswith(topic):
files.append(i)
if len(files) == max_count:
break
return Message(message.subject,
"info",
data={
"files": files,
"max_count": max_count,
"uptime": str(uptime)
})
def unknown(self, message):
"""Reply to any unknown request.
"""
return Message(message.subject, "unknown")
def reply_and_send(self, fun, address, message):
in_socket = get_context().socket(PUSH)
in_socket.connect("inproc://replies" + str(self.port))
reply = Message(message.subject, "error")
try:
reply = fun(message)
except Exception:
LOGGER.exception(
"Something went wrong"
" when processing the request: %s", str(message))
finally:
LOGGER.debug("Response: " + str(reply))
try:
in_socket.send_multipart([address, b'', str(reply)])
except TypeError:
in_socket.send_multipart(
[address, b'', bytes(str(reply), 'utf-8')])
def run(self):
while self._loop:
try:
socks = dict(self._poller.poll(timeout=2000))
except ZMQError:
LOGGER.info("Poller interrupted.")
continue
if socks.get(self.out_socket) == POLLIN:
LOGGER.debug("Received a request")
address, empty, payload = self.out_socket.recv_multipart(
NOBLOCK)
message = Message(rawstr=payload)
fake_msg = Message(rawstr=str(message))
try:
urlparse(message.data['destination'])
except (KeyError, TypeError):
pass
else:
fake_msg.data['destination'] = clean_url(
message.data['destination'])
LOGGER.debug("processing request: " + str(fake_msg))
if message.type == "ping":
Thread(target=self.reply_and_send,
args=(self.pong, address, message)).start()
elif message.type == "push":
Thread(target=self.reply_and_send,
args=(self.push, address, message)).start()
elif message.type == "ack":
Thread(target=self.reply_and_send,
args=(self.ack, address, message)).start()
elif message.type == "info":
Thread(target=self.reply_and_send,
args=(self.info, address, message)).start()
else: # unknown request
Thread(target=self.reply_and_send,
args=(self.unknown, address, message)).start()
elif socks.get(self.in_socket) == POLLIN:
self.out_socket.send_multipart(
self.in_socket.recv_multipart(NOBLOCK))
else: # timeout
pass
def stop(self):
"""Stop the request manager."""
self._loop = False
self._deleter.stop()
self.out_socket.close(1)
self.in_socket.close(1)
class ZmqSelector(BaseSelector):
"""A selector that can be used with asyncio's selector base event loops."""
def __init__(self):
# this maps file descriptors to keys
self._fd_to_key = {}
# read-only mapping returned by get_map()
self._map = _SelectorMapping(self)
self._poller = ZMQPoller()
def _fileobj_lookup(self, fileobj):
"""Return a file descriptor from a file object.
This wraps _fileobj_to_fd() to do an exhaustive search in case
the object is invalid but we still have it in our map. This
is used by unregister() so we can unregister an object that
was previously registered even if it is closed. It is also
used by _SelectorMapping.
"""
try:
return _fileobj_to_fd(fileobj)
except ValueError:
# Do an exhaustive search.
for key in self._fd_to_key.values():
if key.fileobj is fileobj:
return key.fd
# Raise ValueError after all.
raise
def register(self, fileobj, events, data=None):
if (not events) or (events & ~(EVENT_READ | EVENT_WRITE)):
raise ValueError("Invalid events: {!r}".format(events))
key = SelectorKey(fileobj, self._fileobj_lookup(fileobj), events, data)
if key.fd in self._fd_to_key:
raise KeyError("{!r} (FD {}) is already registered"
.format(fileobj, key.fd))
z_events = 0
if events & EVENT_READ:
z_events |= POLLIN
if events & EVENT_WRITE:
z_events |= POLLOUT
try:
self._poller.register(key.fd, z_events)
except ZMQError as exc:
raise OSError(exc.errno, exc.strerror) from exc
self._fd_to_key[key.fd] = key
return key
def unregister(self, fileobj):
try:
key = self._fd_to_key.pop(self._fileobj_lookup(fileobj))
except KeyError:
raise KeyError("{!r} is not registered".format(fileobj)) from None
try:
self._poller.unregister(key.fd)
except ZMQError as exc:
self._fd_to_key[key.fd] = key
raise OSError(exc.errno, exc.strerror) from exc
return key
def modify(self, fileobj, events, data=None):
try:
fd = self._fileobj_lookup(fileobj)
key = self._fd_to_key[fd]
except KeyError:
raise KeyError("{!r} is not registered".format(fileobj)) from None
if data == key.data and events == key.events:
return key
if events != key.events:
z_events = 0
if events & EVENT_READ:
z_events |= POLLIN
if events & EVENT_WRITE:
z_events |= POLLOUT
try:
self._poller.modify(fd, z_events)
except ZMQError as exc:
raise OSError(exc.errno, exc.strerror) from exc
key = key._replace(data=data, events=events)
self._fd_to_key[key.fd] = key
return key
def close(self):
self._fd_to_key.clear()
self._poller = None
def get_map(self):
return self._map
def _key_from_fd(self, fd):
"""Return the key associated to a given file descriptor.
Parameters:
fd -- file descriptor
Returns:
corresponding key, or None if not found
"""
try:
return self._fd_to_key[fd]
except KeyError:
return None
def select(self, timeout=None):
if timeout is None:
timeout = None
elif timeout <= 0:
timeout = 0
else:
# poll() has a resolution of 1 millisecond, round away from
# zero to wait *at least* timeout seconds.
timeout = math.ceil(timeout * 1e3)
ready = []
try:
z_events = self._poller.poll(timeout)
except ZMQError as exc:
if exc.errno == EINTR:
return ready
else:
raise OSError(exc.errno, exc.strerror) from exc
for fd, evt in z_events:
events = 0
if evt & POLLIN:
events |= EVENT_READ
if evt & POLLOUT:
events |= EVENT_WRITE
if evt & POLLERR:
events = EVENT_READ | EVENT_WRITE
key = self._key_from_fd(fd)
if key:
ready.append((key, events & key.events))
return ready
class PushRequester(object):
"""Base requester class.
"""
request_retries = 3
def __init__(self, host, port):
self._socket = None
self._reqaddress = "tcp://" + host + ":" + str(port)
self._poller = Poller()
self._lock = Lock()
self.failures = 0
self.jammed = False
self.running = True
self.connect()
def connect(self):
"""Connect to the server
"""
self._socket = context.socket(REQ)
self._socket.connect(self._reqaddress)
self._poller.register(self._socket, POLLIN)
def stop(self):
"""Close the connection to the server
"""
self.running = False
self._socket.setsockopt(LINGER, 0)
self._socket.close()
self._poller.unregister(self._socket)
def reset_connection(self):
"""Reset the socket
"""
self.stop()
self.connect()
def __del__(self, *args, **kwargs):
self.stop()
def send_and_recv(self, msg, timeout=DEFAULT_REQ_TIMEOUT):
with self._lock:
retries_left = self.request_retries
request = str(msg)
self._socket.send(request)
rep = None
small_timeout = 0.1
while retries_left and self.running:
now = time.time()
while time.time() < now + timeout:
if not self.running:
return rep
socks = dict(self._poller.poll(small_timeout))
if socks.get(self._socket) == POLLIN:
reply = self._socket.recv()
if not reply:
LOGGER.error("Empty reply!")
break
try:
rep = Message(rawstr=reply)
except MessageError as err:
LOGGER.error('Message error: %s', str(err))
break
LOGGER.debug("Receiving (REQ) %s", str(rep))
self.failures = 0
self.jammed = False
return rep
# During big file transfers, give some time to a friend.
time.sleep(0.1)
LOGGER.warning("Timeout from " + str(self._reqaddress) +
", retrying...")
# Socket is confused. Close and remove it.
self.stop()
retries_left -= 1
if retries_left <= 0:
LOGGER.error("Server doesn't answer, abandoning... " +
str(self._reqaddress))
self.connect()
self.failures += 1
if self.failures == 5:
LOGGER.critical("Server jammed ? %s", self._reqaddress)
self.jammed = True
break
LOGGER.info("Reconnecting and resending " + str(msg))
# Create new connection
self.connect()
self._socket.send(request)
return rep
