def __init__(self, logger_name, max_request=10000):
LoggerHelper.__init__(self, logger_name)
self.__max_request = 10000
self.__status = StatusEnum.stopped
self.__status_mutex = threading.RLock()
##block after create
self.__request_available = ResetEvent() #threading.Event()
self.__request_list = []
self.__request_lock = threading.Lock()
self.__main_thread = threading.Thread(target=self.__mainProcess)
def __init__(self, callback, batch_call = False):
self.max_message = 10000
self.status = MessageQueue.StatusEnum.stopped
self.status_lock = threading.RLock()
##block after create
self.message_available = ResetEvent() #threading.Event()
self.message_queue = []
self.message_lock = threading.RLock()
self.main_thread = threading.Thread(target=self.dispathProcess)
self.callback = callback
self.batch_call = batch_call
def __init__(self,
listen_ip,
start_port,
port_count,
callback=None,
bufsize=2 * 1024 * 1024,
send_thread=1,
receive_thread=1):
self.local_ip = listen_ip
self.local_ports = []
self.start_port = start_port
self.port_count = port_count
self.callback = callback
self.bufsize = bufsize
self.sender_count = send_thread
self.receiver_count = receive_thread
self.status = StatusEnum.stopped
self.status_mutex = threading.RLock()
self.sockets = []
# monitro receive socket and send socket, and then dispatch to corresponding thread
self.monitor_thread = threading.Thread(target=self.monitorProcess)
self.notify_thread = threading.Thread(target=self.notifyProcess)
self.notify_queue = [
] # content tuple of (data, remote_ip, remote_port)
self.notify_lock = threading.RLock()
self.notify_available = ResetEvent() # threading.Event()
self.send_packet_queue = [
] # list of (consolidated_packet, remote_ip, remote_port)
self.send_packet_lock = threading.RLock()
self.sendable_socket = []
self.sendable_socket_available = ResetEvent() # threading.Event()
self.sendable_lock = threading.RLock()
self.send_packet_available = ResetEvent(
) # threading.Event() # self.sendProcess
self.send_packet_thread = [] # self.sendProcess
self.receivable_socket = []
self.receivable_lock = threading.RLock()
self.receivable_socket_available = ResetEvent(
) # threading.Event() # self.receiveProcess
self.receive_packet_thread = [] # self.receiveProcess
def __init__(self,
logger_name,
min_id=1,
session_count=1000,
work_thread=1):
self.logger = logging.getLogger(logger_name)
self.lock = threading.RLock()
self.status_lock = threading.RLock()
self.status = StatusEnum.stopped
self.thread_index = 0
self.task_lock = []
self.task_queue = []
self.task_available = []
##key = task type, value = task
self.task_map = {}
##key = session id, value = session
self.session_map = {}
##key = session id, value = allocated
self.allocate_map = {}
self.min_session_id = min_id
self.max_session_id = min_id + session_count - 1
self.session_count = session_count
self.last_session = min_id - 1
for session_id in range(self.min_session_id, self.max_session_id + 1):
session = self.createSession(session_id)
self.session_map[session_id] = session
self.allocate_map[session_id] = False
self.logger.info(
"<TaskManager>transaction session created, id %d ~ %d" %
(self.min_session_id, self.max_session_id))
self.invoke_thread = []
self.thread_count = work_thread
for i in range(work_thread):
self.invoke_thread.append(
threading.Thread(target=self.invokeProcess))
self.task_lock.append(threading.RLock())
self.task_available.append(
ResetEvent()) #self.task_available.append(threading.Event())
self.task_queue.append([])
self.logger.info(
"<TaskManager>%d work thread(s), 1 check thread(s) ready" %
(work_thread))
def __init__(self,
name,
logger_name,
handler=None,
socket_count=1,
process_channel=1,
notify_channel=1,
max_datagram_size=548):
self.handler = handler
self.name = name
self.bound = False
self.ip = ""
self.port = 0
##server_key
int_value = random.random() * 10000000
sha = hashlib.sha1()
sha.update(str(int_value))
self.server_key = sha.hexdigest()
self.channel_lock = threading.RLock()
self.channel_index = 0
self.channels = []
self.socket_count = socket_count
self.process_channel = process_channel
self.notify_channel = notify_channel
self.logger = logging.getLogger(logger_name)
self.endpoint_manager = EndpointManager()
self.max_datagram_size = max_datagram_size
self.max_message_size = max_datagram_size - 20
self.status = StatusEnum.stopped
self.status_mutex = threading.RLock()
self.serial_request_available = ResetEvent(
) # threading.Event() # self.serialProcess()
self.serial_request = [
] # list of tuple (session_id, list of AppMessage)
self.serial_thread = []
self.serial_lock = threading.Lock()
self.package_request_available = ResetEvent(
) # threading.Event() # self.packageProcess()
self.package_request = [
] # list of tuple (remote_ip, remote_port, datagram_list), datagram means stringlized of ConnectRequest()
self.package_thread = []
self.package_lock = threading.Lock()
self.unpackage_request_available = ResetEvent(
) # threading.Event() # self.unpackageProcess()
self.unpackage_request = [
] # content tuple of (packet, remote_ip, remote_port)
self.unpackage_thread = []
self.unpackage_lock = threading.Lock()
self.process_request_available = ResetEvent(
) # threading.Event() # self.processProcess()
self.process_request = [
] # contain tuple of (address, instance of subclass of TransportCommand())
self.process_thread = []
self.process_lock = threading.Lock()
self.notify_request_available = ResetEvent(
) # threading.Event() # self.notifyProcess()
self.notify_request = []
self.notify_thread = []
self.notify_lock = threading.Lock()
for i in range(process_channel):
self.serial_thread.append(
threading.Thread(target=self.serialProcess))
self.package_thread.append(
threading.Thread(target=self.packageProcess))
self.unpackage_thread.append(
threading.Thread(target=self.unpackageProcess))
self.process_thread.append(
threading.Thread(target=self.processProcess))
for i in range(notify_channel):
self.notify_thread.append(
threading.Thread(target=self.notifyProcess))
self.packet_handler = None
self.task_manager = SendTaskManager(self.max_task, self.max_timeout,
self.max_retry)
##timeout check
self.timeout_check_event = threading.Event()
self.timeout_check_thread = threading.Thread(
target=self.timeoutCheckProcess)
class Transporter(object):
"""
usage:
function:
isRunning():is transpoter running
bind(address, start_port, port_range):bind to local socket
start():
stop():
connect(remote_ip, remote_port):
disconnect(session_id):
sendMessage(session_id, message_list):
"""
timeout_check_interval = 1
max_timeout = 5
max_retry = 2
max_task = 10000
max_queue = 50000
def __init__(self,
name,
logger_name,
handler=None,
socket_count=1,
process_channel=1,
notify_channel=1,
max_datagram_size=548):
self.handler = handler
self.name = name
self.bound = False
self.ip = ""
self.port = 0
##server_key
int_value = random.random() * 10000000
sha = hashlib.sha1()
sha.update(str(int_value))
self.server_key = sha.hexdigest()
self.channel_lock = threading.RLock()
self.channel_index = 0
self.channels = []
self.socket_count = socket_count
self.process_channel = process_channel
self.notify_channel = notify_channel
self.logger = logging.getLogger(logger_name)
self.endpoint_manager = EndpointManager()
self.max_datagram_size = max_datagram_size
self.max_message_size = max_datagram_size - 20
self.status = StatusEnum.stopped
self.status_mutex = threading.RLock()
self.serial_request_available = ResetEvent(
) # threading.Event() # self.serialProcess()
self.serial_request = [
] # list of tuple (session_id, list of AppMessage)
self.serial_thread = []
self.serial_lock = threading.Lock()
self.package_request_available = ResetEvent(
) # threading.Event() # self.packageProcess()
self.package_request = [
] # list of tuple (remote_ip, remote_port, datagram_list), datagram means stringlized of ConnectRequest()
self.package_thread = []
self.package_lock = threading.Lock()
self.unpackage_request_available = ResetEvent(
) # threading.Event() # self.unpackageProcess()
self.unpackage_request = [
] # content tuple of (packet, remote_ip, remote_port)
self.unpackage_thread = []
self.unpackage_lock = threading.Lock()
self.process_request_available = ResetEvent(
) # threading.Event() # self.processProcess()
self.process_request = [
] # contain tuple of (address, instance of subclass of TransportCommand())
self.process_thread = []
self.process_lock = threading.Lock()
self.notify_request_available = ResetEvent(
) # threading.Event() # self.notifyProcess()
self.notify_request = []
self.notify_thread = []
self.notify_lock = threading.Lock()
for i in range(process_channel):
self.serial_thread.append(
threading.Thread(target=self.serialProcess))
self.package_thread.append(
threading.Thread(target=self.packageProcess))
self.unpackage_thread.append(
threading.Thread(target=self.unpackageProcess))
self.process_thread.append(
threading.Thread(target=self.processProcess))
for i in range(notify_channel):
self.notify_thread.append(
threading.Thread(target=self.notifyProcess))
self.packet_handler = None
self.task_manager = SendTaskManager(self.max_task, self.max_timeout,
self.max_retry)
##timeout check
self.timeout_check_event = threading.Event()
self.timeout_check_thread = threading.Thread(
target=self.timeoutCheckProcess)
def isRunning(self):
return (StatusEnum.running == self.status)
def bind(self, address, start_port=5600, port_range=200):
buf_size = 2 * 1024 * 1024
self.packet_handler = PacketHandler(address, start_port,
self.socket_count,
self.onPacketReceived, buf_size)
if not self.packet_handler.initial():
return False
self.bound = True
self.ip = address
self.port = self.packet_handler.getDefaultPort()
ports = self.packet_handler.getLocalPorts()
self.logger.info("<Transporter>bind to '%s:%d' success, port list:%s" %
(self.ip, self.port, ports))
for index in range(len(ports)):
port = ports[index]
info = ChannelInfo(index)
info.ip = address
info.port = port
self.channels.append(info)
return True
def getListenPort(self):
if self.bound:
return self.port
else:
return -1
def start(self):
with self.status_mutex:
if StatusEnum.stopped != self.status:
self.logger.error(
"<Transporter>start transporter fail, not in stop status")
return False
self.status = StatusEnum.running
self.packet_handler.start()
for i in range(self.process_channel):
self.serial_thread[i].start()
self.package_thread[i].start()
self.unpackage_thread[i].start()
self.process_thread[i].start()
for i in range(self.notify_channel):
self.notify_thread[i].start()
self.timeout_check_event.clear()
self.timeout_check_thread.start()
self.logger.info("<Transporter>start transporter success")
return True
def stop(self):
with self.status_mutex:
if StatusEnum.stopped == self.status:
return
if StatusEnum.running == self.status:
self.status = StatusEnum.stopping
self.logger.info("<Transporter>stopping transporter...")
self.disconnectAll()
self.timeout_check_event.set()
self.serial_request_available.set()
self.package_request_available.set()
self.unpackage_request_available.set()
self.process_request_available.set()
self.notify_request_available.set()
self.packet_handler.stop()
self.timeout_check_thread.join()
for i in range(self.process_channel):
self.serial_thread[i].join()
self.package_thread[i].join()
self.unpackage_thread[i].join()
self.process_thread[i].join()
for i in range(self.notify_channel):
self.notify_thread[i].join()
with self.status_mutex:
self.status = StatusEnum.stopped
self.logger.info("<Transporter>transporter stopped")
def connect(self, remote_name, remote_ip, remote_port):
if self.endpoint_manager.isExists(remote_name):
self.logger.error(
"<Transporter>connect fail, remote endpoint '%s' already exists"
% (remote_name))
return False
session_id = self.endpoint_manager.allocate(remote_name)
if -1 == session_id:
self.logger.error(
"<Transporter>connect fail, can't allocate endpoint for endpoint '%s'"
% (remote_name))
return False
##new session
channel_id = session_id % (self.socket_count)
endpoint = self.endpoint_manager.getSession(session_id)
if not endpoint.initial(channel_id):
self.logger.error(
"<Transporter>connect fail, can't initial endpoint")
return False
info = self.channels[channel_id]
request = ConnectRequest()
request.sender = session_id
request.ip = info.ip
request.port = info.port
request.name = self.name
##client_key
int_value = random.random() * 10000000
sha = hashlib.sha1()
sha.update(str(int_value))
request.client_key = sha.hexdigest()
datagram = request.toString()
self.sendDatagram(remote_ip, remote_port, [datagram])
return True
def disconnect(self, session_id):
endpoint = self.endpoint_manager.getSession(session_id)
if not endpoint:
self.logger.error(
"<Transporter>disconnect fail, invalid session %d" %
(session_id))
return
request = DisconnectRequest()
request.name = self.name
request.session = endpoint.remote_session
## self.logger.info("[%08X]send disconnect request to node '%s'"%(session_id, endpoint.remote_name))
self.sendDatagramToSession(session_id, [request.toString()])
def disconnectAll(self):
session_list = self.endpoint_manager.getConnectedEndpoint()
if 0 == len(session_list):
return
for session_id in session_list:
self.disconnect(session_id)
## self.logger.info("<Transporter>disconnect %d connectd endpoint"%(len(session_list)))
def sendMessage(self, session_id, message_list):
with self.serial_lock:
if self.max_queue < len(self.serial_request):
self.logger.error(
"<Transporter>send message fail, send queue is full")
return False
self.serial_request.append((session_id, message_list))
self.serial_request_available.set()
return True
def serialProcess(self):
max_fetch = 100
while self.isRunning():
##wait for signal
self.serial_request_available.wait()
if not self.isRunning():
##double protect
##pass notify to other thread
self.serial_request_available.set()
break
with self.serial_lock:
##check queue
request_count = len(self.serial_request)
if 0 == request_count:
##empty
continue
##FIFO/pop front
fetch_count = min(request_count, max_fetch)
if fetch_count < request_count:
##more available,self invoke
self.serial_request_available.set()
request_list = self.serial_request[:fetch_count]
del self.serial_request[:fetch_count]
##begin process
try:
##list of (ip, port, datagram_list)
package_request = []
##list of (session_id, message_list)
for request in request_list:
session_id = request[0]
message_list = request[1]
endpoint = self.endpoint_manager.getSession(session_id)
if not endpoint:
self.logger.error(
"<Transporter>send message fail, invalid session %d"
% session_id)
continue
if not endpoint.isConnected():
self.logger.error(
"[%08X]send message fail, session disconnected" %
session_id)
continue
begin_serial, end_serial = endpoint.allocateSerial(
len(message_list))
if 0 == begin_serial:
self.logger.error(
"[%08X]send message fail, allocate serial fail" %
session_id)
continue
message_serial = begin_serial
datagram_list = []
for message in message_list:
content = message.toString()
if len(content) > self.max_message_size:
##split
length = len(content)
total = (length - length % self.max_message_size
) / self.max_message_size + 1
begin = 0
end = begin + self.max_message_size
index = 1
while begin != len(content):
message_data = MessageData()
message_data.serial = message_serial
message_data.index = index
message_data.total = total
message_data.data = content[begin:end]
message_data.session = endpoint.remote_session
datagram_list.append(message_data.toString())
##next split
index += 1
begin = end
end = begin + self.max_message_size
if end > len(content):
end = len(content)
else:
##single datagram
message_data = MessageData()
message_data.serial = message_serial
message_data.index = 1
message_data.total = 1
message_data.data = content
message_data.session = endpoint.remote_session
datagram_list.append(message_data.toString())
if message_serial > EndpointSession.max_serial:
message_serial = 1
else:
message_serial += 1
package_request.append(
(endpoint.nat_ip, endpoint.nat_port, datagram_list))
##end of for request in request_list:
self.putToPackage(package_request)
except Exception as e:
self.logger.exception(
"<Transporter>exception when serial message, message:%s" %
(e.args))
def putToPackage(self, request_list):
"""
@request_list: list of tuple (remote_ip, remote_port, datagram_list)
@datagram_list: list of datagram, datagram means stringlized of ConnectRequest(), MessageData(),
"""
with self.package_lock:
if self.max_queue < len(self.package_request):
self.logger.error(
"<Transporter>put package fail, package queue is full")
return False
self.package_request.extend(request_list)
self.package_request_available.set()
return True
def packageProcess(self):
max_fetch = 100
while self.isRunning():
##wait for signal
self.package_request_available.wait()
if not self.isRunning():
##double protect
##pass notify to other thread
self.package_request_available.set()
break
with self.package_lock:
##check queue
request_count = len(self.package_request)
if 0 == request_count:
##empty
continue
##FIFO/pop front
fetch_count = min(request_count, max_fetch)
if fetch_count < request_count:
##more available,self invoke
self.package_request_available.set()
request_list = self.package_request[:fetch_count]
del self.package_request[:fetch_count]
##package
send_list = [] ##list of (packet, ip, port)
##key = (ip, port), value = datagram_list
rawdata = {}
##list of (ip, port, datagram_list)
##resort by address
for request in request_list:
address = (request[0], request[1])
datagram_list = request[2]
if not rawdata.has_key(address):
rawdata[address] = datagram_list
else:
rawdata[address].extend(datagram_list)
##package to packet
packets = {}
for address in rawdata.keys():
packets[address] = []
cache = ""
length = 0
for data in rawdata[address]:
##4 bytes length + raw data
data_length = len(data)
if (data_length + length) > self.max_datagram_size:
##new packet, flush cache
if 0 != length:
packets[address].append(cache)
cache = data
length = data_length
else:
cache += data
length += data_length
if 0 != len(cache):
##flush last packet
packets[address].append(cache)
##end of for address in rawdata.keys():
##resort to send_list
for address in packets.keys():
ip = address[0]
port = address[1]
for packet in packets[address]:
send_list.append((packet, ip, port))
packet_count = len(send_list)
id_list = self.task_manager.allocate(packet_count)
if 0 == len(id_list):
self.logger.error(
"<Transporter>package fail, allocate %d task fail" %
(packet_count))
continue
updated = self.task_manager.update(id_list, send_list)
if updated != packet_count:
self.logger.error(
"<Transporter>package fail, not all task updated (%d / %d)"
% (updated, packet_count))
self.task_manager.deallocate(id_list)
continue
##refetch packeted data gram
send_list = self.task_manager.fetch(id_list)
if not self.packet_handler.sendPacketList(send_list):
self.logger.error(
"<Transporter>package fail, send packet to handler fail")
self.task_manager.deallocate(id_list)
def sendDatagramToSession(self, session_id, datagram_list):
endpoint = self.endpoint_manager.getSession(session_id)
if not endpoint:
self.logger.error(
"<Transporter>send fail, invalid endpoint id %d" %
(session_id))
return False
return self.sendDatagram(endpoint.nat_ip, endpoint.nat_port,
datagram_list)
def sendDatagram(self, remote_ip, remote_port, datagram_list):
return self.putToPackage([(remote_ip, remote_port, datagram_list)])
def onPacketReceived(self, message_list):
"""
@message_list:list of (packet, remote_ip, remote_port)
"""
with self.unpackage_lock:
if self.max_queue < len(self.unpackage_request):
self.logger.error(
"<Transporter>put unpackage fail, unpackage queue is full")
return False
self.unpackage_request.extend(message_list)
self.unpackage_request_available.set()
return True
def unpackageProcess(self):
max_fetch = 100
while self.isRunning():
##wait for signal
self.unpackage_request_available.wait()
if not self.isRunning():
##double protect
##pass notify to other thread
self.unpackage_request_available.set()
break
with self.unpackage_lock:
##check queue
request_count = len(self.unpackage_request)
if 0 == request_count:
##empty
continue
##FIFO/pop front
fetch_count = min(request_count, max_fetch)
if fetch_count < request_count:
##more available,self invoke
self.unpackage_request_available.set()
request_list = self.unpackage_request[:fetch_count]
del self.unpackage_request[:fetch_count]
##list of (address, datagram)
received_datagram = [
] # contain tuple of (address, instance of subclass of TransportCommand())
finished = []
ack_packets = {}
##list of (packet, remote_ip, remote_port)
for request in request_list:
remote_ip = request[1]
remote_port = request[2]
packet = request[0]
address = (remote_ip, remote_port)
length = len(packet)
begin = 0
while (length - begin) >= 3:
header, seq = struct.unpack(">BH",
packet[begin:(begin + 3)])
if Datagram.header_mask != ((header & 0xF0) >> 4):
break
version = (header & 0x0C) >> 2
data_type = header & 0x03
if 1 == data_type:
##ack
finished.append(seq)
begin += 3
else:
##data
if (length - begin) < 9:
##incomplete
break
data_length, crc = struct.unpack(
">HI", packet[(begin + 3):(begin + 9)])
content_offset = begin + 9
data_content = packet[content_offset:(content_offset +
data_length)]
##crc check
computed_crc = zlib.crc32(data_content) & 0xFFFFFFFF
if computed_crc != crc:
##data damaged
break
##unserialize
command_list = unpackageFromRawdata(data_content)
for command in command_list:
received_datagram.append((address, command))
ack = DatagramACK(seq)
if not ack_packets.has_key(address):
ack_packets[address] = [ack.toString()]
else:
ack_packets[address].append(ack.toString())
begin = content_offset + data_length
##end while (length - begin) >= 3:
##end for request in request_list:
if 0 != len(ack_packets):
send_list = [] ##list of (packet, ip, port)
##send ack
for address in ack_packets.keys():
ack_list = ack_packets[address]
for packet in ack_list:
send_list.append((packet, address[0], address[1]))
if not self.packet_handler.sendPacketList(send_list):
self.logger.warn("<Transporter>try send %d ack fail!" %
(len(send_list)))
self.task_manager.deallocate(finished)
self.putToProcess(received_datagram)
def putToProcess(self, request_list):
"""
@request_list: # contain tuple of (address, instance of subclass of TransportCommand())
"""
##list of (address, datagram)
with self.process_lock:
if self.max_queue < len(self.process_request):
self.logger.error(
"<Transporter>put to process fail, process queue is full")
return False
self.process_request.extend(request_list)
self.process_request_available.set()
return True
def processProcess(self):
max_fetch = 100
while self.isRunning():
##wait for signal
self.process_request_available.wait()
if not self.isRunning():
##double protect
##pass notify to other thread
self.process_request_available.set()
break
with self.process_lock:
##check queue
request_count = len(self.process_request)
if 0 == request_count:
##empty
continue
##FIFO/pop front
fetch_count = min(request_count, max_fetch)
if fetch_count < request_count:
##more available,self invoke
self.process_request_available.set()
request_list = self.process_request[:fetch_count]
del self.process_request[:fetch_count]
##list of (address, datagram)
for request in request_list: # contain tuple of (address, instance of subclass of TransportCommand())
address = request[0]
command = request[1]
try:
if command.type == TransportCommand.type_keep_alive:
self.handleKeepAlive(command, command.session)
elif command.type == TransportCommand.type_connect_request:
self.handleConnectRequest(command, address,
command.session)
elif command.type == TransportCommand.type_connect_response:
self.handleConnectResponse(command, address,
command.session)
elif command.type == TransportCommand.type_connect_acknowledge:
self.handleConnectACK(command, command.session)
elif command.type == TransportCommand.type_disconnect_request:
self.handleDisconnectRequest(command, command.session)
elif command.type == TransportCommand.type_disconnect_response:
self.handleDisconnectResponse(command, command.session)
elif command.type == TransportCommand.type_message_data:
self.handleMessageData(command, command.session)
except Exception, ex:
self.logger.error(
"<Transporter>handle received datagram exception:%s" %
(ex))
continue
class PacketHandler(object):
"""
def initial()
def start()
def stop()
def getLocalIP()
def getDefaultPort()
def getLocalPorts()
def sendPacket(packet, remote_ip, remote_port)
def sendPacketList(request_list)
def onPacketReceived(message_list)
"""
max_queue = 50000
threhold = 5
max_batch = 20
slow_interval = 1
##20 ms
normal_interval = 0.02
##5ms
fast_interval = 0.005
def __init__(self,
listen_ip,
start_port,
port_count,
callback=None,
bufsize=2 * 1024 * 1024,
send_thread=1,
receive_thread=1):
self.local_ip = listen_ip
self.local_ports = []
self.start_port = start_port
self.port_count = port_count
self.callback = callback
self.bufsize = bufsize
self.sender_count = send_thread
self.receiver_count = receive_thread
self.status = StatusEnum.stopped
self.status_mutex = threading.RLock()
self.sockets = []
# monitro receive socket and send socket, and then dispatch to corresponding thread
self.monitor_thread = threading.Thread(target=self.monitorProcess)
self.notify_thread = threading.Thread(target=self.notifyProcess)
self.notify_queue = [
] # content tuple of (data, remote_ip, remote_port)
self.notify_lock = threading.RLock()
self.notify_available = ResetEvent() # threading.Event()
self.send_packet_queue = [
] # list of (consolidated_packet, remote_ip, remote_port)
self.send_packet_lock = threading.RLock()
self.sendable_socket = []
self.sendable_socket_available = ResetEvent() # threading.Event()
self.sendable_lock = threading.RLock()
self.send_packet_available = ResetEvent(
) # threading.Event() # self.sendProcess
self.send_packet_thread = [] # self.sendProcess
self.receivable_socket = []
self.receivable_lock = threading.RLock()
self.receivable_socket_available = ResetEvent(
) # threading.Event() # self.receiveProcess
self.receive_packet_thread = [] # self.receiveProcess
def getLocalIP(self):
return self.local_ip
def getDefaultPort(self):
if 0 == len(self.local_ports):
return -1
else:
return self.local_ports[0]
def getLocalPorts(self):
return self.local_ports
def sendPacket(self, packet, remote_ip, remote_port):
with self.send_packet_lock:
current_length = len(self.send_packet_queue)
if current_length < self.max_queue:
self.send_packet_queue.append((packet, remote_ip, remote_port))
self.send_packet_available.set()
return True
else:
logging.warn("<PacketHandler>send queue is full, %d / %d" %
(current_length, self.max_queue))
return False
def sendPacketList(self, request_list):
"""
@request_list:list of (packet, remote_ip, remote_port)
"""
with self.send_packet_lock:
current_length = len(self.send_packet_queue)
if current_length < self.max_queue:
self.send_packet_queue.extend(request_list)
self.send_packet_available.set()
return True
else:
logging.warn("<PacketHandler>send queue is full, %d / %d" %
(current_length, self.max_queue))
return False
def onPacketReceived(self, message_list):
"""
@message_list:list of (packet, remote_ip, remote_port)
"""
if self.callback is not None:
self.callback(message_list)
def initial(self):
max_try = 1000
count = 0
ip = self.local_ip
for port in range(self.start_port, self.start_port + max_try):
try:
new_socket = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
new_socket.setsockopt(socket.SOL_SOCKET, socket.SO_RCVBUF,
self.bufsize)
new_socket.setsockopt(socket.SOL_SOCKET, socket.SO_SNDBUF,
self.bufsize)
new_socket.setblocking(0)
new_socket.bind((ip, port))
except socket.error as e:
continue
##bind success
self.local_ports.append(port)
self.sockets.append(new_socket)
count += 1
if count >= self.port_count:
logging.info("<PacketHandler> %d socket(s) established" %
(self.port_count))
##initial threads
for i in range(self.sender_count):
self.send_packet_thread.append(
threading.Thread(target=self.sendProcess))
for i in range(self.receiver_count):
self.receive_packet_thread.append(
threading.Thread(target=self.receiveProcess))
logging.info(
"<PacketHandler> %d send thread, %d receive thread ready" %
(self.sender_count, self.receiver_count))
return True
else:
##no port availabe
logging.error(
"<PacketHandler> not enough available port(%d required) in %s:%d~%d"
% (self.port_count, self.local_ip, self.start_port,
self.start_port + max_try))
return False
def start(self):
with self.status_mutex:
if StatusEnum.stopped != self.status:
return False
self.status = StatusEnum.running
self.monitor_thread.start()
for i in range(self.sender_count):
self.send_packet_thread[i].start()
for i in range(self.receiver_count):
self.receive_packet_thread[i].start()
self.notify_thread.start()
return True
def stop(self):
with self.status_mutex:
if StatusEnum.stopped == self.status:
return
if StatusEnum.running == self.status:
self.status = StatusEnum.stopping
self.send_packet_available.set()
self.receivable_socket_available.set()
self.notify_available.set()
for socket in self.sockets:
socket.close()
self.notify_thread.join()
for i in range(self.sender_count):
self.send_packet_thread[i].join()
for i in range(self.receiver_count):
self.receive_packet_thread[i].join()
self.monitor_thread.join()
with self.status_mutex:
self.status = StatusEnum.stopped
def monitorProcess(self):
monitor = select.epoll()
for _socket in self.sockets:
monitor.register(
_socket.fileno(), select.EPOLLIN | select.EPOLLOUT
| select.EPOLLET | select.EPOLLERR | select.EPOLLHUP)
while StatusEnum.running == self.status:
try:
epoll_list = monitor.poll(self.slow_interval)
if StatusEnum.running != self.status:
##double protect
break
receivable = []
sendable = []
result_count = len(epoll_list)
if 0 == result_count:
continue
for result in epoll_list:
socket_fd = result[0]
event = result[1]
if (event & select.EPOLLIN):
##available for read
for target_socket in self.sockets:
if socket_fd == target_socket.fileno():
receivable.append(target_socket)
break
if (event & select.EPOLLOUT):
##available for write
for target_socket in self.sockets:
if socket_fd == target_socket.fileno():
sendable.append(target_socket)
break
if 0 != len(receivable):
with self.receivable_lock:
for recv_socket in receivable:
socket_fd = recv_socket.fileno()
for exist in self.receivable_socket:
##avoid duplicate
if socket_fd == exist.fileno():
##duplicate
break
else:
##new
self.receivable_socket.append(recv_socket)
self.receivable_socket_available.set()
if 0 != len(sendable):
with self.sendable_lock:
for target in sendable:
socket_fd = target.fileno()
for exist in self.sendable_socket:
##avoid duplicate
if socket_fd == exist.fileno():
##duplicate
break
else:
##new
self.sendable_socket.append(target)
self.sendable_socket_available.set()
except socket.error, e:
logging.exception(
"<PacketHandler>exception when monitor network, message:%s"
% (e.strerror))
class BaseService(LoggerHelper):
def __init__(self, logger_name, max_request=10000):
LoggerHelper.__init__(self, logger_name)
self.__max_request = 10000
self.__status = StatusEnum.stopped
self.__status_mutex = threading.RLock()
##block after create
self.__request_available = ResetEvent() #threading.Event()
self.__request_list = []
self.__request_lock = threading.Lock()
self.__main_thread = threading.Thread(target=self.__mainProcess)
def start(self):
"""
start service
"""
with self.__status_mutex:
if StatusEnum.stopped != self.__status:
return False
if not self.onStart():
return False
self.__status = StatusEnum.running
self.__main_thread.start()
return True
def stop(self):
"""
stop service
"""
with self.__status_mutex:
if StatusEnum.stopped == self.__status:
return
if StatusEnum.running == self.__status:
self.__status = StatusEnum.stopping
##notify wait thread
self.__request_available.set()
self.__main_thread.join()
with self.__status_mutex:
self.__status = StatusEnum.stopped
self.onStop()
def __mainProcess(self):
max_batch = 100
while StatusEnum.running == self.__status:
##wait for signal
self.__request_available.wait()
if StatusEnum.running != self.__status:
##double protect
self.__request_available.set()
break
with self.__request_lock:
request_count = len(self.__request_list)
if (0 == request_count):
##empty
continue
##FIFO/pop front
fetch_count = min(request_count, max_batch)
if fetch_count < request_count:
##more available,self invoke
self.__request_available.set()
request_list = self.__request_list[:fetch_count]
del self.__request_list[:fetch_count]
try:
## self.info("<BaseService>debug:%d request fetched"%(fetch_count))
for request in request_list:
## begin = datetime.datetime.now()
self.OnRequestReceived(request)
## diff = datetime.datetime.now() - begin
## elapse_seconds = diff.seconds + float(diff.microseconds)/1000000
## if (request.type == 0) or(request.type == 1):
## ##message
## msg = request.message
## self.info("<BaseService>debug:handle message in %.1f second(s), msg type %d, id %d, session[%08X]"%(
## elapse_seconds, msg.type, msg.id, msg.session))
## else:
## ##
## self.info("<BaseService>debug:handle request in %.1f second(s), request type %d, session[%08X]"%(
## elapse_seconds, request.type, request.session_id))
except Exception as e:
self.console("<BaseService>OnRequestReceived exception:%s" %
e.args[0])
self.exception("<BaseService>OnRequestReceived exception:%s" %
e.args[0])
traceback.print_exc()
def putRequest(self, request):
"""
put request into queue tail
"""
## begin = datetime.datetime.now()
## if (request.type == 0) or(request.type == 1):
## ##message
## msg = request.message
## self.info("<BaseService>debug:try put message msg type %d, id %d, session[%08X]..."%(
## msg.type, msg.id, msg.session))
with self.__request_lock:
length = len(self.__request_list)
if length >= self.__max_request:
self.console(
"<BaseService> put request fail, request queue is full")
self.error(
"<BaseService> put request fail, request queue is full")
return False
self.__request_list.append(request)
self.__request_available.set()
## diff = datetime.datetime.now() - begin
## elapse_seconds = diff.seconds + float(diff.microseconds)/1000000
## if (request.type == 0) or(request.type == 1):
## ##message
## msg = request.message
## self.info("<BaseService>debug:put message in %.1f second(s), msg type %d, id %d, session[%08X]"%(
## elapse_seconds, msg.type, msg.id, msg.session))
## else:
## ##
## self.info("<BaseService>debug:put request in %.1f second(s), request type %d, session[%08X]"%(
## elapse_seconds, request.type, request.session_id))
return True
def putRequestList(self, request_list):
with self.__request_lock:
length = len(self.__request_list)
if length >= self.__max_request:
self.console(
"<BaseService> put request list fail, request queue is full"
)
self.error(
"<BaseService> put request list fail, request queue is full"
)
return False
self.__request_list.extend(request_list)
self.__request_available.set()
return True
def insertRequest(self, request):
"""
put request into queue head
"""
## begin = datetime.datetime.now()
with self.__request_lock:
length = len(self.__request_list)
if length >= self.__max_request:
self.console(
"<BaseService> insert request fail, request queue is full")
self.error(
"<BaseService> insert request fail, request queue is full")
return False
self.__request_list.insert(0, request)
self.__request_available.set()
## diff = datetime.datetime.now() - begin
## elapse_seconds = diff.seconds + float(diff.microseconds)/1000000
## if (request.type == 0) or(request.type == 1):
## ##message
## msg = request.message
## self.info("<BaseService>debug:insert message in %.1f second(s), msg type %d, id %d, session[%08X]"%(
## elapse_seconds, msg.type, msg.id, msg.session))
## else:
## ##
## self.info("<BaseService>debug:insert request in %.1f second(s), request type %d, session[%08X]"%(
## elapse_seconds, request.type, request.session_id))
return True
"""
method need override by subclass
"""
"""
onStart
@return:
False = initial fail, stop service
True = initial success, start main service
"""
def onStart(self):
pass
def onStop(self):
pass
def OnRequestReceived(self, request):
pass
class MessageQueue(object):
"""
usage:
MessageQueue(callback_function):
start():
stop():
putMessage(msg):
insertMessage(msg):
"""
class StatusEnum:
stopped = 0
running = 1
stopping = 2
min_threhold = 5
max_threhold = 200
max_batch = 200
check_interval = 0.02##20ms
max_message = 10000
def __init__(self, callback, batch_call = False):
self.max_message = 10000
self.status = MessageQueue.StatusEnum.stopped
self.status_lock = threading.RLock()
##block after create
self.message_available = ResetEvent() #threading.Event()
self.message_queue = []
self.message_lock = threading.RLock()
self.main_thread = threading.Thread(target=self.dispathProcess)
self.callback = callback
self.batch_call = batch_call
def start(self):
"""
start service
"""
with self.status_lock:
if MessageQueue.StatusEnum.stopped != self.status:
return False
self.status = MessageQueue.StatusEnum.running
self.main_thread.start()
return True
def stop(self):
"""
stop service
"""
with self.status_lock:
if MessageQueue.StatusEnum.stopped == self.status:
return
if MessageQueue.StatusEnum.running == self.status:
self.status = MessageQueue.StatusEnum.stopping
##notify wait thread
self.message_available.set()
self.main_thread.join()
with self.status_lock:
self.status = MessageQueue.StatusEnum.stopped
def dispathProcess(self):
while MessageQueue.StatusEnum.running == self.status:
##wait for signal
self.message_available.wait(self.check_interval)
if MessageQueue.StatusEnum.running != self.status:
##double protect
break
## if self.message_available.isSet():
## self.message_available.clear()
if(0 == len(self.message_queue)):
##empty
continue
with self.message_lock:
request_count = len(self.message_queue)
if(0 == request_count):
##empty
continue
##FIFO/pop front
fetch_count = min(request_count, self.max_batch)
if fetch_count < request_count:
##more available,self invoke
self.message_available.set()
request_list = self.message_queue[:fetch_count]
del self.message_queue[:fetch_count]
if self.callback:
if self.batch_call:
self.callback(request_list)
else:
##single call
for request in request_list:
self.callback(request)
def putMessage(self, message):
"""
put message into queue tail
"""
with self.message_lock:
length = len(self.message_queue)
if length >= self.max_message:
return False
self.message_queue.append(message)
## length += 1
## if (length < self.min_threhold) or (length > self.max_threhold):
self.message_available.set()
return True
def insertMessage(self, message):
"""
put message into queue head
"""
with self.message_lock:
length = len(self.message_queue)
if length >= self.max_message:
return False
self.message_queue.insert(0, message)
## length += 1
## if (length < self.min_threhold) or (length > self.max_threhold):
self.message_available.set()
return True
def batchPut(self,message_list):
"""
put message into queue tail
"""
with self.message_lock:
length = len(self.message_queue)
if length >= self.max_message:
return False
self.message_queue.extend(message_list)
self.message_available.set()
return True