deb-ryu/ryu/app/simple_isolation.py
YAMAMOTO Takashi b2636e0cc1 use ofproto.OFP_NO_BUFFER in some places
Signed-off-by: YAMAMOTO Takashi <yamamoto@valinux.co.jp>
Signed-off-by: FUJITA Tomonori <fujita.tomonori@lab.ntt.co.jp>
2013-07-09 12:33:17 +09:00

348 lines
14 KiB
Python

# Copyright (C) 2011 Nippon Telegraph and Telephone Corporation.
# Copyright (C) 2011, 2012 Isaku Yamahata <yamahata at valinux co jp>
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
# implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import logging
import struct
from ryu.app.rest_nw_id import NW_ID_UNKNOWN, NW_ID_EXTERNAL
from ryu.base import app_manager
from ryu.exception import MacAddressDuplicated
from ryu.exception import PortUnknown
from ryu.controller import dpset
from ryu.controller import mac_to_network
from ryu.controller import mac_to_port
from ryu.controller import network
from ryu.controller import ofp_event
from ryu.controller.handler import MAIN_DISPATCHER
from ryu.controller.handler import CONFIG_DISPATCHER
from ryu.controller.handler import set_ev_cls
from ryu.ofproto import nx_match
from ryu.lib.mac import haddr_to_str
from ryu.lib import mac
class SimpleIsolation(app_manager.RyuApp):
_CONTEXTS = {
'network': network.Network,
'dpset': dpset.DPSet,
}
def __init__(self, *args, **kwargs):
super(SimpleIsolation, self).__init__(*args, **kwargs)
self.nw = kwargs['network']
self.dpset = kwargs['dpset']
self.mac2port = mac_to_port.MacToPortTable()
self.mac2net = mac_to_network.MacToNetwork(self.nw)
@set_ev_cls(ofp_event.EventOFPSwitchFeatures, CONFIG_DISPATCHER)
def switch_features_handler(self, ev):
msg = ev.msg
datapath = msg.datapath
datapath.send_delete_all_flows()
datapath.send_barrier()
self.mac2port.dpid_add(ev.msg.datapath_id)
self.nw.add_datapath(ev.msg)
@staticmethod
def _modflow_and_send_packet(msg, src, dst, actions):
datapath = msg.datapath
ofproto = datapath.ofproto
#
# install flow and then send packet
#
rule = nx_match.ClsRule()
rule.set_in_port(msg.in_port)
rule.set_dl_dst(dst)
rule.set_dl_src(src)
datapath.send_flow_mod(
rule=rule, cookie=0, command=datapath.ofproto.OFPFC_ADD,
idle_timeout=0, hard_timeout=0,
priority=ofproto.OFP_DEFAULT_PRIORITY,
buffer_id=ofproto.OFP_NO_BUFFER, out_port=ofproto.OFPP_NONE,
flags=ofproto.OFPFF_SEND_FLOW_REM, actions=actions)
datapath.send_packet_out(msg.buffer_id, msg.in_port, actions)
def _forward_to_nw_id(self, msg, src, dst, nw_id, out_port):
assert out_port is not None
datapath = msg.datapath
if not self.nw.same_network(datapath.id, nw_id, out_port,
NW_ID_EXTERNAL):
self.logger.debug('packet is blocked src %s dst %s '
'from %d to %d on datapath %d',
haddr_to_str(src), haddr_to_str(dst),
msg.in_port, out_port, datapath.id)
return
self.logger.debug("learned dpid %s in_port %d out_port "
"%d src %s dst %s",
datapath.id, msg.in_port, out_port,
haddr_to_str(src), haddr_to_str(dst))
actions = [datapath.ofproto_parser.OFPActionOutput(out_port)]
self._modflow_and_send_packet(msg, src, dst, actions)
def _flood_to_nw_id(self, msg, src, dst, nw_id):
datapath = msg.datapath
actions = []
self.logger.debug("dpid %s in_port %d src %s dst %s ports %s",
datapath.id, msg.in_port,
haddr_to_str(src), haddr_to_str(dst),
self.nw.dpids.get(datapath.id, {}).items())
for port_no in self.nw.filter_ports(datapath.id, msg.in_port,
nw_id, NW_ID_EXTERNAL):
self.logger.debug("port_no %s", port_no)
actions.append(datapath.ofproto_parser.OFPActionOutput(port_no))
self._modflow_and_send_packet(msg, src, dst, actions)
def _learned_mac_or_flood_to_nw_id(self, msg, src, dst,
dst_nw_id, out_port):
if out_port is not None:
self._forward_to_nw_id(msg, src, dst, dst_nw_id, out_port)
else:
self._flood_to_nw_id(msg, src, dst, dst_nw_id)
def _modflow_and_drop_packet(self, msg, src, dst):
self._modflow_and_send_packet(msg, src, dst, [])
def _drop_packet(self, msg):
datapath = msg.datapath
datapath.send_packet_out(msg.buffer_id, msg.in_port, [])
@set_ev_cls(ofp_event.EventOFPPacketIn, MAIN_DISPATCHER)
def packet_in_handler(self, ev):
# self.logger.debug('packet in ev %s msg %s', ev, ev.msg)
msg = ev.msg
datapath = msg.datapath
ofproto = datapath.ofproto
dst, src, _eth_type = struct.unpack_from('!6s6sH', buffer(msg.data), 0)
try:
port_nw_id = self.nw.get_network(datapath.id, msg.in_port)
except PortUnknown:
port_nw_id = NW_ID_UNKNOWN
if port_nw_id != NW_ID_UNKNOWN:
# Here it is assumed that the
# (port <-> network id)/(mac <-> network id) relationship
# is stable once the port is created. The port will be destroyed
# before assigning new network id to the given port.
# This is correct nova-network/nova-compute.
try:
# allow external -> known nw id change
self.mac2net.add_mac(src, port_nw_id, NW_ID_EXTERNAL)
except MacAddressDuplicated:
self.logger.warn('mac address %s is already in use.'
' So (dpid %s, port %s) can not use it',
haddr_to_str(src), datapath.id, msg.in_port)
#
# should we install drop action pro-actively for future?
#
self._drop_packet(msg)
return
old_port = self.mac2port.port_add(datapath.id, msg.in_port, src)
if old_port is not None and old_port != msg.in_port:
# We really overwrite already learned mac address.
# So discard already installed stale flow entry which conflicts
# new port.
rule = nx_match.ClsRule()
rule.set_dl_dst(src)
datapath.send_flow_mod(rule=rule,
cookie=0,
command=ofproto.OFPFC_DELETE,
idle_timeout=0,
hard_timeout=0,
priority=ofproto.OFP_DEFAULT_PRIORITY,
out_port=old_port)
# to make sure the old flow entries are purged.
datapath.send_barrier()
src_nw_id = self.mac2net.get_network(src, NW_ID_UNKNOWN)
dst_nw_id = self.mac2net.get_network(dst, NW_ID_UNKNOWN)
# we handle multicast packet as same as broadcast
broadcast = (dst == mac.BROADCAST) or mac.is_multicast(dst)
out_port = self.mac2port.port_get(datapath.id, dst)
#
# there are several combinations:
# in_port: known nw_id, external, unknown nw,
# src mac: known nw_id, external, unknown nw,
# dst mac: known nw_id, external, unknown nw, and broadcast/multicast
# where known nw_id: is quantum network id
# external: means that these ports are connected to outside
# unknown nw: means that we don't know this port is bounded to
# specific nw_id or external
# broadcast: the destination mac address is broadcast address
# (or multicast address)
#
# Can the following logic be refined/shortened?
#
# When NW_ID_UNKNOWN is found, registering ports might be delayed.
# So just drop only this packet and not install flow entry.
# It is expected that when next packet arrives, the port is registers
# with some network id
if port_nw_id != NW_ID_EXTERNAL and port_nw_id != NW_ID_UNKNOWN:
if broadcast:
# flood to all ports of external or src_nw_id
self._flood_to_nw_id(msg, src, dst, src_nw_id)
elif src_nw_id == NW_ID_EXTERNAL:
self._modflow_and_drop_packet(msg, src, dst)
return
elif src_nw_id == NW_ID_UNKNOWN:
self._drop_packet(msg)
return
else:
# src_nw_id != NW_ID_EXTERNAL and src_nw_id != NW_ID_UNKNOWN:
#
# try learned mac check if the port is net_id
# or
# flood to all ports of external or src_nw_id
self._learned_mac_or_flood_to_nw_id(msg, src, dst,
src_nw_id, out_port)
elif port_nw_id == NW_ID_EXTERNAL:
if src_nw_id != NW_ID_EXTERNAL and src_nw_id != NW_ID_UNKNOWN:
if broadcast:
# flood to all ports of external or src_nw_id
self._flood_to_nw_id(msg, src, dst, src_nw_id)
elif (dst_nw_id != NW_ID_EXTERNAL and
dst_nw_id != NW_ID_UNKNOWN):
if src_nw_id == dst_nw_id:
# try learned mac
# check if the port is external or same net_id
# or
# flood to all ports of external or src_nw_id
self._learned_mac_or_flood_to_nw_id(msg, src, dst,
src_nw_id,
out_port)
else:
# should not occur?
self.logger.debug("should this case happen?")
self._drop_packet(msg)
elif dst_nw_id == NW_ID_EXTERNAL:
# try learned mac
# or
# flood to all ports of external or src_nw_id
self._learned_mac_or_flood_to_nw_id(msg, src, dst,
src_nw_id, out_port)
else:
assert dst_nw_id == NW_ID_UNKNOWN
self.logger.debug("Unknown dst_nw_id")
self._drop_packet(msg)
elif src_nw_id == NW_ID_EXTERNAL:
self._modflow_and_drop_packet(msg, src, dst)
else:
# should not occur?
assert src_nw_id == NW_ID_UNKNOWN
self._drop_packet(msg)
else:
# drop packets
assert port_nw_id == NW_ID_UNKNOWN
self._drop_packet(msg)
# self.logger.debug("Unknown port_nw_id")
def _port_add(self, ev):
#
# delete flows entries that matches with
# dl_dst == broadcast/multicast
# and dl_src = network id if network id of this port is known
# to send broadcast packet to this newly added port.
#
# Openflow v1.0 doesn't support masked match of dl_dst,
# so delete all flow entries. It's inefficient, though.
#
msg = ev.msg
datapath = msg.datapath
datapath.send_delete_all_flows()
datapath.send_barrier()
self.nw.port_added(datapath, msg.desc.port_no)
def _port_del(self, ev):
# free mac addresses associated to this VM port,
# and delete related flow entries for later reuse of mac address
dps_needs_barrier = set()
msg = ev.msg
datapath = msg.datapath
datapath_id = datapath.id
port_no = msg.desc.port_no
rule = nx_match.ClsRule()
rule.set_in_port(port_no)
datapath.send_flow_del(rule=rule, cookie=0)
rule = nx_match.ClsRule()
datapath.send_flow_del(rule=rule, cookie=0, out_port=port_no)
dps_needs_barrier.add(datapath)
try:
port_nw_id = self.nw.get_network(datapath_id, port_no)
except PortUnknown:
# race condition between rest api delete port
# and openflow port deletion ofp_event
pass
else:
if port_nw_id in (NW_ID_UNKNOWN, NW_ID_EXTERNAL):
datapath.send_barrier()
return
for mac_ in self.mac2port.mac_list(datapath_id, port_no):
for (_dpid, dp) in self.dpset.get_all():
if self.mac2port.port_get(dp.id, mac_) is None:
continue
rule = nx_match.ClsRule()
rule.set_dl_src(mac_)
dp.send_flow_del(rule=rule, cookie=0)
rule = nx_match.ClsRule()
rule.set_dl_dst(mac_)
dp.send_flow_del(rule=rule, cookie=0)
dps_needs_barrier.add(dp)
self.mac2port.mac_del(dp.id, mac_)
self.mac2net.del_mac(mac_)
self.nw.port_deleted(datapath.id, port_no)
for dp in dps_needs_barrier:
dp.send_barrier()
@set_ev_cls(ofp_event.EventOFPPortStatus, MAIN_DISPATCHER)
def port_status_handler(self, ev):
msg = ev.msg
reason = msg.reason
ofproto = msg.datapath.ofproto
if reason == ofproto.OFPPR_ADD:
self._port_add(ev)
elif reason == ofproto.OFPPR_DELETE:
self._port_del(ev)
else:
assert reason == ofproto.OFPPR_MODIFY