socket.AF_UNSPEC: "unspecified",

socket.AF_INET: "IPv4",

socket.AF_INET6: "IPv6",

DISCONNECTING = '<disconnecting>'

DISCONNECTED = '<disconnected>'

CONNECTING = '<connecting>'

HANDSHAKE = '<handshake>'

CONNECTED = '<connected>'

"""Initialize a Kafka broker connection

DEFAULT_CONFIG = {

'client_id': 'kafka-python-' + __version__,

'node_id': 0,

'request_timeout_ms': 30000,

'reconnect_backoff_ms': 50,

'reconnect_backoff_max_ms': 1000,

'max_in_flight_requests_per_connection': 5,

'receive_buffer_bytes': None,

'send_buffer_bytes': None,

'socket_options': [(socket.IPPROTO_TCP, socket.TCP_NODELAY, 1)],

'sock_chunk_bytes': 4096, # undocumented experimental option

'sock_chunk_buffer_count': 1000, # undocumented experimental option

'security_protocol': 'PLAINTEXT',

'ssl_context': None,

'ssl_check_hostname': True,

'ssl_cafile': None,

'ssl_certfile': None,

'ssl_keyfile': None,

'ssl_crlfile': None,

'ssl_password': None,

'ssl_ciphers': None,

'api_version': (0, 8, 2), # default to most restrictive

'selector': selectors.DefaultSelector,

'state_change_callback': lambda node_id, sock, conn: True,

'metrics': None,

'metric_group_prefix': '',

'sasl_mechanism': None,

'sasl_plain_username': None,

'sasl_plain_password': None,

'sasl_kerberos_service_name': 'kafka',

'sasl_kerberos_domain_name': None,

'sasl_oauth_token_provider': None,

'socks5_proxy': None,

}

SECURITY_PROTOCOLS = ('PLAINTEXT', 'SSL', 'SASL_PLAINTEXT', 'SASL_SSL')

SASL_MECHANISMS = ('PLAIN', 'GSSAPI', 'OAUTHBEARER', "SCRAM-SHA-256", "SCRAM-SHA-512")

def __init__(self, host, port, afi, **configs):

self.host = host

self.port = port

self.afi = afi

self._sock_afi = afi

self._sock_addr = None

self._api_versions = None

self._socks5_proxy = None

self.config = copy.copy(self.DEFAULT_CONFIG)

for key in self.config:

if key in configs:

self.config[key] = configs[key]

self.node_id = self.config.pop('node_id')

if self.config['receive_buffer_bytes'] is not None:

self.config['socket_options'].append(

(socket.SOL_SOCKET, socket.SO_RCVBUF,

self.config['receive_buffer_bytes']))

if self.config['send_buffer_bytes'] is not None:

self.config['socket_options'].append(

(socket.SOL_SOCKET, socket.SO_SNDBUF,

self.config['send_buffer_bytes']))

assert self.config['security_protocol'] in self.SECURITY_PROTOCOLS, (

'security_protocol must be in ' + ', '.join(self.SECURITY_PROTOCOLS))

if self.config['security_protocol'] in ('SSL', 'SASL_SSL'):

assert ssl_available, "Python wasn't built with SSL support"

if self.config['security_protocol'] in ('SASL_PLAINTEXT', 'SASL_SSL'):

assert self.config['sasl_mechanism'] in self.SASL_MECHANISMS, (

'sasl_mechanism must be in ' + ', '.join(self.SASL_MECHANISMS))

if self.config['sasl_mechanism'] in ('PLAIN', 'SCRAM-SHA-256', 'SCRAM-SHA-512'):

assert self.config['sasl_plain_username'] is not None, (

'sasl_plain_username required for PLAIN or SCRAM sasl'

)

assert self.config['sasl_plain_password'] is not None, (

'sasl_plain_password required for PLAIN or SCRAM sasl'

)

if self.config['sasl_mechanism'] == 'GSSAPI':

assert gssapi is not None, 'GSSAPI lib not available'

assert self.config['sasl_kerberos_service_name'] is not None, 'sasl_kerberos_service_name required for GSSAPI sasl'

if self.config['sasl_mechanism'] == 'OAUTHBEARER':

token_provider = self.config['sasl_oauth_token_provider']

assert token_provider is not None, 'sasl_oauth_token_provider required for OAUTHBEARER sasl'

assert callable(getattr(token_provider, "token", None)), 'sasl_oauth_token_provider must implement method #token()'

# This is not a general lock / this class is not generally thread-safe yet

# However, to avoid pushing responsibility for maintaining

# per-connection locks to the upstream client, we will use this lock to

# make sure that access to the protocol buffer is synchronized

# when sends happen on multiple threads

self._lock = threading.Lock()

# the protocol parser instance manages actual tracking of the

# sequence of in-flight requests to responses, which should

# function like a FIFO queue. For additional request data,

# including tracking request futures and timestamps, we

# can use a simple dictionary of correlation_id => request data

self.in_flight_requests = dict()

self._protocol = KafkaProtocol(

client_id=self.config['client_id'],

api_version=self.config['api_version'])

self.state = ConnectionStates.DISCONNECTED

self._reset_reconnect_backoff()

self._sock = None

self._send_buffer = b''

self._ssl_context = None

if self.config['ssl_context'] is not None:

self._ssl_context = self.config['ssl_context']

self._sasl_auth_future = None

self.last_attempt = 0

self._gai = []

self._sensors = None

if self.config['metrics']:

self._sensors = BrokerConnectionMetrics(self.config['metrics'],

self.config['metric_group_prefix'],

self.node_id)

def _dns_lookup(self):

self._gai = dns_lookup(self.host, self.port, self.afi)

if not self._gai:

log.error('DNS lookup failed for %s:%i (%s)',

self.host, self.port, self.afi)

return False

return True

def _next_afi_sockaddr(self):

if not self._gai:

if not self._dns_lookup():

return

afi, _, __, ___, sockaddr = self._gai.pop(0)

return (afi, sockaddr)

def connect_blocking(self, timeout=float('inf')):

if self.connected():

return True

timeout += time.time()

# First attempt to perform dns lookup

# note that the underlying interface, socket.getaddrinfo,

# has no explicit timeout so we may exceed the user-specified timeout

self._dns_lookup()

# Loop once over all returned dns entries

selector = None

while self._gai:

while time.time() < timeout:

self.connect()

if self.connected():

if selector is not None:

selector.close()

return True

elif self.connecting():

if selector is None:

selector = self.config['selector']()

selector.register(self._sock, selectors.EVENT_WRITE)

selector.select(1)

elif self.disconnected():

if selector is not None:

selector.close()

selector = None

break

else:

break

return False

def connect(self):

"""Attempt to connect and return ConnectionState"""

if self.state is ConnectionStates.DISCONNECTED and not self.blacked_out():

self.last_attempt = time.time()

next_lookup = self._next_afi_sockaddr()

if not next_lookup:

self.close(Errors.KafkaConnectionError('DNS failure'))

return self.state

else:

log.debug('%s: creating new socket', self)

assert self._sock is None

self._sock_afi, self._sock_addr = next_lookup

if self.config["socks5_proxy"] is not None:

self._socks5_proxy = Socks5Wrapper(self.config["socks5_proxy"], self.afi)

self._sock = self._socks5_proxy.socket(self._sock_afi, socket.SOCK_STREAM)

else:

self._sock = socket.socket(self._sock_afi, socket.SOCK_STREAM)

for option in self.config['socket_options']:

log.debug('%s: setting socket option %s', self, option)

self._sock.setsockopt(*option)

self._sock.setblocking(False)

self.state = ConnectionStates.CONNECTING

self.config['state_change_callback'](self.node_id, self._sock, self)

log.info('%s: connecting to %s:%d [%s %s]', self, self.host,

self.port, self._sock_addr, AFI_NAMES[self._sock_afi])

if self.state is ConnectionStates.CONNECTING:

# in non-blocking mode, use repeated calls to socket.connect_ex

# to check connection status

ret = None

try:

if self._socks5_proxy:

ret = self._socks5_proxy.connect_ex(self._sock_addr)

else:

ret = self._sock.connect_ex(self._sock_addr)

except socket.error as err:

ret = err.errno

# Connection succeeded

if not ret or ret == errno.EISCONN:

log.debug('%s: established TCP connection', self)

if self.config['security_protocol'] in ('SSL', 'SASL_SSL'):

log.debug('%s: initiating SSL handshake', self)

self.state = ConnectionStates.HANDSHAKE

self.config['state_change_callback'](self.node_id, self._sock, self)

# _wrap_ssl can alter the connection state -- disconnects on failure

self._wrap_ssl()

elif self.config['security_protocol'] == 'SASL_PLAINTEXT':

log.debug('%s: initiating SASL authentication', self)

self.state = ConnectionStates.AUTHENTICATING

self.config['state_change_callback'](self.node_id, self._sock, self)

else:

# security_protocol PLAINTEXT

log.info('%s: Connection complete.', self)

self.state = ConnectionStates.CONNECTED

self._reset_reconnect_backoff()

self.config['state_change_callback'](self.node_id, self._sock, self)

# Connection failed

# WSAEINVAL == 10022, but errno.WSAEINVAL is not available on non-win systems

elif ret not in (errno.EINPROGRESS, errno.EALREADY, errno.EWOULDBLOCK, 10022):

log.error('Connect attempt to %s returned error %s.'

' Disconnecting.', self, ret)

errstr = errno.errorcode.get(ret, 'UNKNOWN')

self.close(Errors.KafkaConnectionError('{} {}'.format(ret, errstr)))

return self.state

# Needs retry

else:

pass

if self.state is ConnectionStates.HANDSHAKE:

if self._try_handshake():

log.debug('%s: completed SSL handshake.', self)

if self.config['security_protocol'] == 'SASL_SSL':

log.debug('%s: initiating SASL authentication', self)

self.state = ConnectionStates.AUTHENTICATING

else:

log.info('%s: Connection complete.', self)

self.state = ConnectionStates.CONNECTED

self._reset_reconnect_backoff()

self.config['state_change_callback'](self.node_id, self._sock, self)

if self.state is ConnectionStates.AUTHENTICATING:

assert self.config['security_protocol'] in ('SASL_PLAINTEXT', 'SASL_SSL')

if self._try_authenticate():

# _try_authenticate has side-effects: possibly disconnected on socket errors

if self.state is ConnectionStates.AUTHENTICATING:

log.info('%s: Connection complete.', self)

self.state = ConnectionStates.CONNECTED

self._reset_reconnect_backoff()

self.config['state_change_callback'](self.node_id, self._sock, self)

if self.state not in (ConnectionStates.CONNECTED,

ConnectionStates.DISCONNECTED):

# Connection timed out

request_timeout = self.config['request_timeout_ms'] / 1000.0

if time.time() > request_timeout + self.last_attempt:

log.error('Connection attempt to %s timed out', self)

self.close(Errors.KafkaConnectionError('timeout'))

return self.state

return self.state

def _wrap_ssl(self):

assert self.config['security_protocol'] in ('SSL', 'SASL_SSL')

if self._ssl_context is None:

log.debug('%s: configuring default SSL Context', self)

self._ssl_context = ssl.SSLContext(ssl.PROTOCOL_SSLv23) # pylint: disable=no-member

self._ssl_context.options |= ssl.OP_NO_SSLv2 # pylint: disable=no-member

self._ssl_context.options |= ssl.OP_NO_SSLv3 # pylint: disable=no-member

self._ssl_context.verify_mode = ssl.CERT_OPTIONAL

if self.config['ssl_check_hostname']:

self._ssl_context.check_hostname = True

if self.config['ssl_cafile']:

log.info('%s: Loading SSL CA from %s', self, self.config['ssl_cafile'])

self._ssl_context.load_verify_locations(self.config['ssl_cafile'])

self._ssl_context.verify_mode = ssl.CERT_REQUIRED

else:

log.info('%s: Loading system default SSL CAs from %s', self, ssl.get_default_verify_paths())

self._ssl_context.load_default_certs()

if self.config['ssl_certfile'] and self.config['ssl_keyfile']:

log.info('%s: Loading SSL Cert from %s', self, self.config['ssl_certfile'])

log.info('%s: Loading SSL Key from %s', self, self.config['ssl_keyfile'])

self._ssl_context.load_cert_chain(

certfile=self.config['ssl_certfile'],

keyfile=self.config['ssl_keyfile'],

password=self.config['ssl_password'])

if self.config['ssl_crlfile']:

if not hasattr(ssl, 'VERIFY_CRL_CHECK_LEAF'):

raise RuntimeError('This version of Python does not support ssl_crlfile!')

log.info('%s: Loading SSL CRL from %s', self, self.config['ssl_crlfile'])

self._ssl_context.load_verify_locations(self.config['ssl_crlfile'])

# pylint: disable=no-member

self._ssl_context.verify_flags |= ssl.VERIFY_CRL_CHECK_LEAF

if self.config['ssl_ciphers']:

log.info('%s: Setting SSL Ciphers: %s', self, self.config['ssl_ciphers'])

self._ssl_context.set_ciphers(self.config['ssl_ciphers'])

log.debug('%s: wrapping socket in ssl context', self)

try:

self._sock = self._ssl_context.wrap_socket(

self._sock,

server_hostname=self.host,

do_handshake_on_connect=False)

except ssl.SSLError as e:

log.exception('%s: Failed to wrap socket in SSLContext!', self)

self.close(e)

def _try_handshake(self):

assert self.config['security_protocol'] in ('SSL', 'SASL_SSL')

try:

self._sock.do_handshake()

return True

# old ssl in python2.6 will swallow all SSLErrors here...

except (SSLWantReadError, SSLWantWriteError):

pass

except (SSLZeroReturnError, ConnectionError, TimeoutError, SSLEOFError):

log.warning('SSL connection closed by server during handshake.')

self.close(Errors.KafkaConnectionError('SSL connection closed by server during handshake'))

# Other SSLErrors will be raised to user

return False

def _try_authenticate(self):

assert self.config['api_version'] is None or self.config['api_version'] >= (0, 10)

if self._sasl_auth_future is None:

# Build a SaslHandShakeRequest message

request = SaslHandShakeRequest[0](self.config['sasl_mechanism'])

future = Future()

sasl_response = self._send(request)

sasl_response.add_callback(self._handle_sasl_handshake_response, future)

sasl_response.add_errback(lambda f, e: f.failure(e), future)

self._sasl_auth_future = future

for r, f in self.recv():

f.success(r)

# A connection error could trigger close() which will reset the future

if self._sasl_auth_future is None:

return False

elif self._sasl_auth_future.failed():

ex = self._sasl_auth_future.exception

if not isinstance(ex, Errors.KafkaConnectionError):

raise ex # pylint: disable-msg=raising-bad-type

return self._sasl_auth_future.succeeded()

def _handle_sasl_handshake_response(self, future, response):

error_type = Errors.for_code(response.error_code)

if error_type is not Errors.NoError:

error = error_type(self)

self.close(error=error)

return future.failure(error_type(self))

if self.config['sasl_mechanism'] not in response.enabled_mechanisms:

return future.failure(

Errors.UnsupportedSaslMechanismError(

'Kafka broker does not support %s sasl mechanism. Enabled mechanisms are: %s'

% (self.config['sasl_mechanism'], response.enabled_mechanisms)))

elif self.config['sasl_mechanism'] == 'PLAIN':

return self._try_authenticate_plain(future)

elif self.config['sasl_mechanism'] == 'GSSAPI':

return self._try_authenticate_gssapi(future)

elif self.config['sasl_mechanism'] == 'OAUTHBEARER':

return self._try_authenticate_oauth(future)

elif self.config['sasl_mechanism'].startswith("SCRAM-SHA-"):

return self._try_authenticate_scram(future)

else:

return future.failure(

Errors.UnsupportedSaslMechanismError(

'kafka-python does not support SASL mechanism %s' %

self.config['sasl_mechanism']))

def _send_bytes(self, data):

"""Send some data via non-blocking IO

total_sent = 0

while total_sent < len(data):

try:

sent_bytes = self._sock.send(data[total_sent:])

total_sent += sent_bytes

except (SSLWantReadError, SSLWantWriteError):

break

except (ConnectionError, TimeoutError) as e:

if six.PY2 and e.errno == errno.EWOULDBLOCK:

break

raise

except BlockingIOError:

if six.PY3:

break

raise

return total_sent

def _send_bytes_blocking(self, data):

self._sock.settimeout(self.config['request_timeout_ms'] / 1000)

total_sent = 0

try:

while total_sent < len(data):

sent_bytes = self._sock.send(data[total_sent:])

total_sent += sent_bytes

if total_sent != len(data):

raise ConnectionError('Buffer overrun during socket send')

return total_sent

finally:

self._sock.settimeout(0.0)

def _recv_bytes_blocking(self, n):

self._sock.settimeout(self.config['request_timeout_ms'] / 1000)

try:

data = b''

while len(data) < n:

fragment = self._sock.recv(n - len(data))

if not fragment:

raise ConnectionError('Connection reset during recv')

data += fragment

return data

finally:

self._sock.settimeout(0.0)

def _try_authenticate_plain(self, future):

if self.config['security_protocol'] == 'SASL_PLAINTEXT':

log.warning('%s: Sending username and password in the clear', self)

data = b''

# Send PLAIN credentials per RFC-4616

msg = bytes('\0'.join([self.config['sasl_plain_username'],

self.config['sasl_plain_username'],

self.config['sasl_plain_password']]).encode('utf-8'))

size = Int32.encode(len(msg))

err = None

close = False

with self._lock:

if not self._can_send_recv():

err = Errors.NodeNotReadyError(str(self))

close = False

else:

try:

self._send_bytes_blocking(size + msg)

# The server will send a zero sized message (that is Int32(0)) on success.

# The connection is closed on failure

data = self._recv_bytes_blocking(4)

except (ConnectionError, TimeoutError) as e:

log.exception("%s: Error receiving reply from server", self)

err = Errors.KafkaConnectionError("%s: %s" % (self, e))

close = True

if err is not None:

if close:

self.close(error=err)

return future.failure(err)

if data != b'\x00\x00\x00\x00':

error = Errors.AuthenticationFailedError('Unrecognized response during authentication')

return future.failure(error)

log.info('%s: Authenticated as %s via PLAIN', self, self.config['sasl_plain_username'])

return future.success(True)

def _try_authenticate_scram(self, future):

if self.config['security_protocol'] == 'SASL_PLAINTEXT':

log.warning('%s: Exchanging credentials in the clear', self)

scram_client = ScramClient(

self.config['sasl_plain_username'], self.config['sasl_plain_password'], self.config['sasl_mechanism']

)

err = None

close = False

with self._lock:

if not self._can_send_recv():

err = Errors.NodeNotReadyError(str(self))

close = False

else:

try:

client_first = scram_client.first_message().encode('utf-8')

size = Int32.encode(len(client_first))

self._send_bytes_blocking(size + client_first)

(data_len,) = struct.unpack('>i', self._recv_bytes_blocking(4))

server_first = self._recv_bytes_blocking(data_len).decode('utf-8')

scram_client.process_server_first_message(server_first)

client_final = scram_client.final_message().encode('utf-8')

size = Int32.encode(len(client_final))

self._send_bytes_blocking(size + client_final)

(data_len,) = struct.unpack('>i', self._recv_bytes_blocking(4))

server_final = self._recv_bytes_blocking(data_len).decode('utf-8')

scram_client.process_server_final_message(server_final)

except (ConnectionError, TimeoutError) as e:

log.exception("%s: Error receiving reply from server", self)

err = Errors.KafkaConnectionError("%s: %s" % (self, e))

close = True

if err is not None:

if close:

self.close(error=err)

return future.failure(err)

log.info(

'%s: Authenticated as %s via %s', self, self.config['sasl_plain_username'], self.config['sasl_mechanism']

)

return future.success(True)

def _try_authenticate_gssapi(self, future):

kerberos_damin_name = self.config['sasl_kerberos_domain_name'] or self.host

auth_id = self.config['sasl_kerberos_service_name'] + '@' + kerberos_damin_name

gssapi_name = gssapi.Name(

auth_id,

name_type=gssapi.NameType.hostbased_service

).canonicalize(gssapi.MechType.kerberos)

log.debug('%s: GSSAPI name: %s', self, gssapi_name)

err = None

close = False

with self._lock:

if not self._can_send_recv():

err = Errors.NodeNotReadyError(str(self))

close = False

else:

# Establish security context and negotiate protection level

# For reference RFC 2222, section 7.2.1

try:

# Exchange tokens until authentication either succeeds or fails

client_ctx = gssapi.SecurityContext(name=gssapi_name, usage='initiate')

received_token = None

while not client_ctx.complete:

# calculate an output token from kafka token (or None if first iteration)

output_token = client_ctx.step(received_token)

# pass output token to kafka, or send empty response if the security

# context is complete (output token is None in that case)

if output_token is None:

self._send_bytes_blocking(Int32.encode(0))

else:

msg = output_token

size = Int32.encode(len(msg))

self._send_bytes_blocking(size + msg)

# The server will send a token back. Processing of this token either

# establishes a security context, or it needs further token exchange.

# The gssapi will be able to identify the needed next step.

# The connection is closed on failure.

header = self._recv_bytes_blocking(4)

(token_size,) = struct.unpack('>i', header)

received_token = self._recv_bytes_blocking(token_size)

# Process the security layer negotiation token, sent by the server

# once the security context is established.

# unwraps message containing supported protection levels and msg size

msg = client_ctx.unwrap(received_token).message

# Kafka currently doesn't support integrity or confidentiality security layers, so we

# simply set QoP to 'auth' only (first octet). We reuse the max message size proposed

# by the server

msg = Int8.encode(SASL_QOP_AUTH & Int8.decode(io.BytesIO(msg[0:1]))) + msg[1:]

# add authorization identity to the response, GSS-wrap and send it

msg = client_ctx.wrap(msg + auth_id.encode(), False).message

size = Int32.encode(len(msg))

self._send_bytes_blocking(size + msg)

except (ConnectionError, TimeoutError) as e:

log.exception("%s: Error receiving reply from server", self)

err = Errors.KafkaConnectionError("%s: %s" % (self, e))

close = True

except Exception as e:

err = e

close = True

if err is not None:

if close:

self.close(error=err)

return future.failure(err)

log.info('%s: Authenticated as %s via GSSAPI', self, gssapi_name)

return future.success(True)

def _try_authenticate_oauth(self, future):

data = b''

msg = bytes(self._build_oauth_client_request().encode("utf-8"))

size = Int32.encode(len(msg))

err = None

close = False

with self._lock:

if not self._can_send_recv():

err = Errors.NodeNotReadyError(str(self))

close = False

else:

try:

# Send SASL OAuthBearer request with OAuth token

self._send_bytes_blocking(size + msg)

# The server will send a zero sized message (that is Int32(0)) on success.

# The connection is closed on failure

data = self._recv_bytes_blocking(4)

except (ConnectionError, TimeoutError) as e:

log.exception("%s: Error receiving reply from server", self)

err = Errors.KafkaConnectionError("%s: %s" % (self, e))

close = True

if err is not None:

if close:

self.close(error=err)

return future.failure(err)

if data != b'\x00\x00\x00\x00':

error = Errors.AuthenticationFailedError('Unrecognized response during authentication')

return future.failure(error)

log.info('%s: Authenticated via OAuth', self)

return future.success(True)

def _build_oauth_client_request(self):

token_provider = self.config['sasl_oauth_token_provider']

return "n,,\x01auth=Bearer {}{}\x01\x01".format(token_provider.token(), self._token_extensions())

def _token_extensions(self):

"""

token_provider = self.config['sasl_oauth_token_provider']

# Only run if the #extensions() method is implemented by the clients Token Provider class

# Builds up a string separated by \x01 via a dict of key value pairs

if callable(getattr(token_provider, "extensions", None)) and len(token_provider.extensions()) > 0:

msg = "\x01".join(["{}={}".format(k, v) for k, v in token_provider.extensions().items()])

return "\x01" + msg

else:

return ""

def blacked_out(self):

"""

if self.state is ConnectionStates.DISCONNECTED:

if time.time() < self.last_attempt + self._reconnect_backoff:

return True

return False

def connection_delay(self):

"""

time_waited = time.time() - (self.last_attempt or 0)

if self.state is ConnectionStates.DISCONNECTED:

return max(self._reconnect_backoff - time_waited, 0) * 1000

else:

# When connecting or connected, we should be able to delay

# indefinitely since other events (connection or data acked) will

# cause a wakeup once data can be sent.

return float('inf')

def connected(self):

"""Return True iff socket is connected."""

return self.state is ConnectionStates.CONNECTED

def connecting(self):

"""Returns True if still connecting (this may encompass several

return self.state in (ConnectionStates.CONNECTING,

ConnectionStates.HANDSHAKE,

ConnectionStates.AUTHENTICATING)

def disconnected(self):

"""Return True iff socket is closed"""

return self.state is ConnectionStates.DISCONNECTED

def _reset_reconnect_backoff(self):

self._failures = 0

self._reconnect_backoff = self.config['reconnect_backoff_ms'] / 1000.0

def _update_reconnect_backoff(self):

# Do not mark as failure if there are more dns entries available to try

if len(self._gai) > 0:

return

if self.config['reconnect_backoff_max_ms'] > self.config['reconnect_backoff_ms']:

self._failures += 1

self._reconnect_backoff = self.config['reconnect_backoff_ms'] * 2 ** (self._failures - 1)

self._reconnect_backoff = min(self._reconnect_backoff, self.config['reconnect_backoff_max_ms'])

self._reconnect_backoff *= uniform(0.8, 1.2)

self._reconnect_backoff /= 1000.0

log.debug('%s: reconnect backoff %s after %s failures', self, self._reconnect_backoff, self._failures)

def _close_socket(self):

if hasattr(self, '_sock') and self._sock is not None:

self._sock.close()

self._sock = None

def __del__(self):

self._close_socket()

def close(self, error=None):

"""Close socket and fail all in-flight-requests.

if self.state is ConnectionStates.DISCONNECTED:

return

with self._lock:

if self.state is ConnectionStates.DISCONNECTED:

return

log.info('%s: Closing connection. %s', self, error or '')

self._update_reconnect_backoff()

self._sasl_auth_future = None

self._protocol = KafkaProtocol(

client_id=self.config['client_id'],

api_version=self.config['api_version'])

self._send_buffer = b''

if error is None:

error = Errors.Cancelled(str(self))

ifrs = list(self.in_flight_requests.items())

self.in_flight_requests.clear()

self.state = ConnectionStates.DISCONNECTED

# To avoid race conditions and/or deadlocks

# keep a reference to the socket but leave it

# open until after the state_change_callback

# This should give clients a change to deregister

# the socket fd from selectors cleanly.

sock = self._sock

self._sock = None

# drop lock before state change callback and processing futures

self.config['state_change_callback'](self.node_id, sock, self)

sock.close()

for (_correlation_id, (future, _timestamp)) in ifrs:

future.failure(error)

def _can_send_recv(self):

"""Return True iff socket is ready for requests / responses"""

return self.state in (ConnectionStates.AUTHENTICATING,

ConnectionStates.CONNECTED)

def send(self, request, blocking=True):

"""Queue request for async network send, return Future()"""

future = Future()

if self.connecting():

return future.failure(Errors.NodeNotReadyError(str(self)))

elif not self.connected():

return future.failure(Errors.KafkaConnectionError(str(self)))

elif not self.can_send_more():

return future.failure(Errors.TooManyInFlightRequests(str(self)))

return self._send(request, blocking=blocking)

def _send(self, request, blocking=True):

future = Future()

with self._lock:

if not self._can_send_recv():

# In this case, since we created the future above,

# we know there are no callbacks/errbacks that could fire w/

# lock. So failing + returning inline should be safe

return future.failure(Errors.NodeNotReadyError(str(self)))

correlation_id = self._protocol.send_request(request)

log.debug('%s Request %d: %s', self, correlation_id, request)

if request.expect_response():

sent_time = time.time()

assert correlation_id not in self.in_flight_requests, 'Correlation ID already in-flight!'

self.in_flight_requests[correlation_id] = (future, sent_time)

else:

future.success(None)

# Attempt to replicate behavior from prior to introduction of

# send_pending_requests() / async sends

if blocking:

self.send_pending_requests()

return future

def send_pending_requests(self):

"""Attempts to send pending requests messages via blocking IO