def handle_HELLO(con, msg): # S
# con.msg("HELLO wire protocol " + hex(msg.version))
# Send a features request
print("receive Hello message")
msg = of.ofp_features_request()
con.send(msg)
def handle_HELLO(con, msg): #S
#con.msg("HELLO wire protocol " + hex(msg.version))
# Send a features request
#log.info("recv a hello msg")
msg = of.ofp_features_request()
con.send(msg)
def _handle_PortStatus(self, event): """ The method sends features_request message every time it receives PortStatus message so that the object always contains upto date information of ports """ connection.send(ofp_features_request())
def __init__(self, sock, send_hello=True):
self._previous_stats = []
self.ofnexus = _dummyOFNexus
self.sock = sock
self.buf = ''
Connection.ID += 1
self.ID = Connection.ID
# TODO: dpid and features don't belong here; they should be eventually
# be in topology.switch
self.dpid = None
self.features = None
self.disconnected = False
self.disconnection_raised = False
self.connect_time = None
self.idle_time = time.time()
if send_hello:
log.debug('sending of.ofp_hello')
self.send(of.ofp_hello())
else:
log.debug('sending of.ofp_features_request')
msg = of.ofp_features_request()
log.debug(msg)
self.send(msg)
self.original_ports = PortCollection()
self.ports = PortCollection()
self.ports._chain = self.original_ports
def handle_HELLO (con, msg): #S
#con.msg("HELLO wire protocol " + hex(msg.version))
log.debug("-> Hello received")
# Send a features request
msg = of.ofp_features_request()
log.debug("<- Feature request sent")
con.send(msg)
def handle_HELLO(con, msg): #S
#con.msg("HELLO wire protocol " + hex(msg.version))
# Send a features request
"Enviar um pedido, recursos"
msg = of.ofp_features_request()
con.send(msg)
def handle_HELLO(con, msg): #S
#con.msg("HELLO wire protocol " + hex(msg.version))
# Send a features request
print("receive Hello message")
msg = of.ofp_features_request()
con.send(msg)
def handle_HELLO (con, msg): #S
#con.msg("HELLO wire protocol " + hex(msg.version))
# Send a features request
msg = of.ofp_features_request()
con.send(msg)
print ("DJ---/pox/openflow/of_01.py handle_HELLO con:",con)
def _on_timer():
for n in nodes:
#Sends out requests to the network nodes
core.openflow.getConnection(n.connection.dpid).send(of.ofp_features_request())
n.connection.send(of.ofp_stats_request(body=of.ofp_port_stats_request()))
n.connection.send(of.ofp_stats_request(body=of.ofp_aggregate_stats_request()))
n.connection.send(of.ofp_stats_request(body=of.ofp_flow_stats_request()))
def _check_ports (dpid):
"""
Sends a features request to the given dpid
"""
_dirty_switches.pop(dpid,None)
con = core.openflow.getConnection(dpid)
if con is None: return
con.send(of.ofp_barrier_request())
con.send(of.ofp_features_request())
log.debug("Requested switch features for %s", str(con))
def connect (self, connection):
if connection is None:
self.log.warn("Can't connect to nothing")
return
if self.dpid is None:
self.dpid = connection.dpid
assert self.dpid == connection.dpid
if self.ports is None:
self.ports = connection.features.ports
self.disconnect()
self.connection = connection
self._listeners = self.listenTo(connection)
self._connected_at = time.time()
label = dpid_to_str(connection.dpid)
self.log = log.getChild(label)
self.log.debug("Connect %s" % (connection,))
if self._id is None:
if self.dpid not in switches_by_id and self.dpid <= 254:
self._id = self.dpid
else:
self._id = TopoSwitch._next_id
TopoSwitch._next_id += 1
switches_by_id[self._id] = self
self.network = IPAddr("10.%s.0.0" % (self._id,))
self.mac = dpid_to_mac(self.dpid)
con = connection
log.debug("Disabling flooding for %i ports", len(con.ports))
for p in con.ports.itervalues():
if p.port_no >= of.OFPP_MAX: continue
pm = of.ofp_port_mod(port_no=p.port_no,
hw_addr=p.hw_addr,
config = of.OFPPC_NO_FLOOD,
mask = of.OFPPC_NO_FLOOD)
con.send(pm)
con.send(of.ofp_barrier_request())
con.send(of.ofp_features_request())
self.send_table()
def fix_addr (addr, backup):
if addr is None: return None
if addr is (): return IPAddr(backup)
return IPAddr(addr)
self.ip_addr = IPAddr("10.%s.0.1" % (self._id,))
self.router_addr = None
self.dns_addr = None
self.subnet = IPAddr("255.0.0.0")
self.pools = {}
for p in connection.ports:
if p < 0 or p >= of.OFPP_MAX: continue
self.pools[p] = [IPAddr("10.%s.%s.%s" % (self._id,p,n))
for n in range(1,255)]
self.lease_time = 60 * 60
self.offers = {}
self.leases = {}
def handle_HELLO (self, con, msg): #S
# Send features and switch desc requests
if not self._features_request_sent:
self._features_request_sent = True
fr = of.ofp_features_request()
if self.request_description:
ss = of.ofp_stats_request()
ss.body = of.ofp_desc_stats_request()
con.send(fr.pack() + ss.pack())
else:
con.send(fr)
def handle_HELLO(self, con, msg): #S
# Send features and switch desc requests
if not self._features_request_sent:
self._features_request_sent = True
fr = of.ofp_features_request()
if self.request_description:
ss = of.ofp_stats_request()
ss.body = of.ofp_desc_stats_request()
con.send(fr.pack() + ss.pack())
else:
con.send(fr)
def connect (self, connection):
if connection is None:
self.log.warn("Can't connect to nothing")
return
if self.dpid is None:
self.dpid = connection.dpid
#reises an exception if not true
assert self.dpid == connection.dpid
if self.ports is None:
self.ports = connection.features.ports
self.disconnect()
self.connection = connection
self._listeners = self.listenTo(connection)
self._connected_at = time.time()
label = dpid_to_str(connection.dpid)
self.log = log.getChild(label)
self.log.debug("Connect %s" % (connection,))
#assign an ID to the switch
if self._id is None:
if self.dpid not in switches_by_id and self.dpid <= 254:
self._id = self.dpid
else:
self._id = RoutingSwitch._next_id
RoutingSwitch._next_id += 1
switches_by_id[self._id] = self
#assign network address
self.network = IPAddr("10.%s.0.0" % (self._id,))
self.mac = dpid_to_mac(self.dpid)
# Disable flooding
con = connection
log.debug("Disabling flooding for %i ports", len(con.ports))
for p in con.ports.itervalues():
if p.port_no >= of.OFPP_MAX: continue
msg = of.ofp_port_mod(port_no=p.port_no, hw_addr=p.hw_addr, config = of.OFPPC_NO_FLOOD, mask = of.OFPPC_NO_FLOOD)
con.send(msg)
con.send(of.ofp_barrier_request())
con.send(of.ofp_features_request())
# Send thee initial forwarding table to the switch
self.send_table()
# Set IP address of the switch
self.ip_addr = IPAddr("10.%s.0.1" % (self._id,))
def _check_ports(dpid):
_dirty_switches.pop(dpid, None)
con = core.openflow.getConnection(dpid)
if con is None: return
"""
Barrier (Barreira) : Barreira de solicitação / resposta mensagens
são utilizados pelo controlador para garantir dependências de mensagens
foram cumpridos ou para receber notificações de operações concluídas .
"""
con.send(of.ofp_barrier_request())
"""
Features (Características): O controlador pode solicitar a identidade e as capacidades básicas de um switch através do envio
um pedido de recursos ; o interruptor deve responder com uma características responder que especifica a identidade e básico
capacidades da chave. Isto é comumente realizada mediante estabelecimento do canal OpenFlow .
"""
con.send(of.ofp_features_request())
log.debug("Requested switch features for %s", str(con))
def check_socket(self):
pkt_count = 0
while True:
pkt_count += 1
buff = self.s.recv(100)
pkt = of.ofp_header()
pkt.unpack(buff)
#print('[{}][check_socket]recved: ', len(buff))
print('\n[{0}] received [{1}]byte data.'.format(pkt_count, len(buff)))
print(pkt.show())
if pkt.header_type == gini_of.OFPT_HELLO: # OFPT_HELLO
print("OFPT_HELLO msg: ")
pkt = of.ofp_hello()
pkt.unpack(buff)
self.process_hello(pkt)
elif pkt.header_type == gini_of.OFPT_ECHO_REQUEST:
print("OFPT_ECHO_REPLY msg: ")
pkt = of.ofp_echo_request()
pkt.unpack(buff)
self.process_echo_request(pkt)
elif pkt.header_type == gini_of.OFPT_FEATURES_REQUEST:
print("OFPT_FEATURES_REQUEST msg: ")
pkt = of.ofp_features_request()
pkt.unpack(buff)
self.process_features_request(pkt)
elif pkt.header_type == gini_of.OFPT_SET_CONFIG:
print("OFPT_SET_CONFIG msg: ")
pkt = of.ofp_set_config()
pkt.unpack(buff)
self.process_set_config(pkt)
elif pkt.header_type == gini_of.OFPT_FLOW_MOD:
print("OFPT_FLOW_MOD msg: ")
pkt = giniclass_flow_mod()
pkt.unpack(buff)
self.process_flow_mod(pkt)
elif pkt.header_type == gini_of.OFPT_BARRIER_REQUEST:
print("OFPT_BARRIER_REQUEST msg: ")
pkt = of.ofp_barrier_request()
pkt.unpack(buff)
self.process_barrier_request(pkt)
else:
print("Unknown type!: ", pkt.header_type, "details: ")
print(pkt.show())
def _realize(self):
if self._port_out == self._port_out_cache: return
# We really shouldn't need to get the connection here...
con = core.openflow.connections.get(self.dpid)
if con is None: return
data = []
for port_no, cfg in self._port_out.items():
if port_no not in self.ports: continue
if port_no not in con.ports: continue
p = con.ports[port_no]
pm = of.ofp_port_mod(port_no=p.port_no,
hw_addr=p.hw_addr,
config=cfg,
mask=of.OFPPC_NO_FLOOD | of.OFPPC_NO_FWD)
data.append(pm.pack())
# We could probably handle the features stuff better
data.append(of.ofp_features_request().pack())
if self.send(b''.join(data)):
self._port_out_cache = self._port_out
self.log.info("Configured %s ports", len(data) - 1)
def handle_HELLO(con, msg): #S
#con.msg("HELLO wire protocol " + hex(msg.version))
# Send a features request
msg = of.ofp_features_request()
con.send(msg)
def handle_HELLO (con, msg): #S
#con.msg("HELLO wire protocol " + hex(msg.version))
# Send a features request
msg = of.ofp_features_request()
con.send(msg)
def timer_func():
for n in nodes:
core.openflow.getConnection(n.connection.dpid).send(of.ofp_features_request())
def connect (self, connection):
if connection is None:
self.log.warn("Can't connect to nothing")
return
if self.dpid is None:
self.dpid = connection.dpid
assert self.dpid == connection.dpid
if self.ports is None:
self.ports = connection.features.ports
self.disconnect()
self.connection = connection
self._listeners = self.listenTo(connection)
self._connected_at = time.time()
label = dpid_to_str(connection.dpid)
self.log = log.getChild(label)
self.log.debug("Connect %s" % (connection,))
if self._id is None:
if self.dpid not in switches_by_id and self.dpid <= 254:
self._id = self.dpid
else:
self._id = TopoSwitch._next_id
TopoSwitch._next_id += 1
switches_by_id[self._id] = self
self.network = IPAddr("10.%s.0.0" % (self._id,))
self.mac = dpid_to_mac(self.dpid)
# Disable flooding
con = connection
log.debug("Disabling flooding for %i ports", len(con.ports))
for p in con.ports.itervalues():
if p.port_no >= of.OFPP_MAX: continue
pm = of.ofp_port_mod(port_no=p.port_no,
hw_addr=p.hw_addr,
config = of.OFPPC_NO_FLOOD,
mask = of.OFPPC_NO_FLOOD)
con.send(pm)
con.send(of.ofp_barrier_request())
con.send(of.ofp_features_request())
# Some of this is copied from DHCPD's __init__().
self.send_table()
def fix_addr (addr, backup):
if addr is None: return None
if addr is (): return IPAddr(backup)
return IPAddr(addr)
self.ip_addr = IPAddr("10.%s.0.1" % (self._id,))
#self.router_addr = self.ip_addr
self.router_addr = None
self.dns_addr = None #fix_addr(dns_address, self.router_addr)
self.subnet = IPAddr("255.0.0.0")
self.pools = {}
for p in connection.ports:
if p < 0 or p >= of.OFPP_MAX: continue
self.pools[p] = [IPAddr("10.%s.%s.%s" % (self._id,p,n))
for n in range(1,255)]
self.lease_time = 60 * 60 # An hour
#TODO: Actually make them expire :)
self.offers = {} # Eth -> IP we offered
self.leases = {} # Eth -> IP we leased
def _refresh_features(self):
# Not sure if this is strictly necessary; pulled from openflow/spanning_tree.py
# We do this after we adjust link state via ofp_port_mod commands.
SpanningTreeSwitch.logger.info('switch-{}: Refreshing features.'.format(self.dpid))
self.connection.send(of.ofp_barrier_request())
self.connection.send(of.ofp_features_request())