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osm.etsi.org / osm / vim-emu / efdda12a005a63a449ea7afb9baab1743b4d04ab / . / src / emuvim / dcemulator / net.py
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# Copyright (c) 2015 SONATA-NFV and Paderborn University
# ALL RIGHTS RESERVED.
#
# 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.
#
# Neither the name of the SONATA-NFV, Paderborn University
# nor the names of its contributors may be used to endorse or promote
# products derived from this software without specific prior written
# permission.
#
# This work has been performed in the framework of the SONATA project,
# funded by the European Commission under Grant number 671517 through
# the Horizon 2020 and 5G-PPP programmes. The authors would like to
# acknowledge the contributions of their colleagues of the SONATA
# partner consortium (www.sonata-nfv.eu).
import logging
import time
import re
import requests
import os
import json
import networkx as nx
from subprocess import Popen
# from gevent import monkey
from mininet.net import Containernet
from mininet.node import OVSSwitch, OVSKernelSwitch, Docker, RemoteController
from mininet.cli import CLI
from mininet.link import TCLink
from mininet.clean import cleanup
from emuvim.dcemulator.monitoring import DCNetworkMonitor
from emuvim.dcemulator.node import Datacenter, EmulatorCompute
from emuvim.dcemulator.resourcemodel import ResourceModelRegistrar
# ensure correct functionality of all gevent based REST servers
# monkey.patch_all()
# setup logging
LOG = logging.getLogger("dcemulator.net")
LOG.setLevel(logging.DEBUG)
# default CPU period used for cpu percentage-based cfs values (microseconds)
CPU_PERIOD = 1000000
# default priority setting for added flow-rules
DEFAULT_PRIORITY = 1000
# default cookie number for new flow-rules
DEFAULT_COOKIE = 10
class DCNetwork(Containernet):
"""
Wraps the original Mininet/Containernet class and provides
methods to add data centers, switches, etc.
This class is used by topology definition scripts.
"""
def __init__(self, controller=RemoteController, monitor=False,
enable_learning=False,
# learning switch behavior of the default ovs switches icw Ryu
# controller can be turned off/on, needed for E-LAN
# functionality
dc_emulation_max_cpu=1.0, # fraction of overall CPU time for emulation
dc_emulation_max_mem=512, # emulation max mem in MB
**kwargs):
"""
Create an extended version of a Containernet network
:param dc_emulation_max_cpu: max. CPU time used by containers in data centers
:param kwargs: path through for Mininet parameters
:return:
"""
# members
self.dcs = {}
self.ryu_process = None
# list of deployed nsds.E_Lines and E_LANs (uploaded from the dummy
# gatekeeper)
self.deployed_nsds = []
self.deployed_elines = []
self.deployed_elans = []
self.installed_chains = []
# always cleanup environment before we start the emulator
self.killRyu()
cleanup()
# call original Docker.__init__ and setup default controller
Containernet.__init__(
self, switch=OVSKernelSwitch, controller=controller, **kwargs)
# default switch configuration
enable_ryu_learning = False
if enable_learning:
self.failMode = 'standalone'
enable_ryu_learning = True
else:
self.failMode = 'secure'
# Ryu management
if controller == RemoteController:
# start Ryu controller
self.startRyu(learning_switch=enable_ryu_learning)
# add the specified controller
self.addController('c0', controller=controller)
# graph of the complete DC network
self.DCNetwork_graph = nx.MultiDiGraph()
# initialize pool of vlan tags to setup the SDN paths
self.vlans = list(range(1, 4095))[::-1]
# link to Ryu REST_API
ryu_ip = 'localhost'
ryu_port = '8080'
self.ryu_REST_api = 'http://{0}:{1}'.format(ryu_ip, ryu_port)
self.RyuSession = requests.Session()
# monitoring agent
if monitor:
self.monitor_agent = DCNetworkMonitor(self)
else:
self.monitor_agent = None
# initialize resource model registrar
self.rm_registrar = ResourceModelRegistrar(
dc_emulation_max_cpu, dc_emulation_max_mem)
self.cpu_period = CPU_PERIOD
def addDatacenter(self, label, metadata={}, resource_log_path=None):
"""
Create and add a logical cloud data center to the network.
"""
if label in self.dcs:
raise Exception("Data center label already exists: %s" % label)
dc = Datacenter(label, metadata=metadata,
resource_log_path=resource_log_path)
dc.net = self # set reference to network
self.dcs[label] = dc
dc.create() # finally create the data center in our Mininet instance
LOG.info("added data center: %s" % label)
return dc
def addLink(self, node1, node2, **params):
"""
Able to handle Datacenter objects as link
end points.
"""
assert node1 is not None
assert node2 is not None
# ensure type of node1
if isinstance(node1, str):
if node1 in self.dcs:
node1 = self.dcs[node1].switch
if isinstance(node1, Datacenter):
node1 = node1.switch
# ensure type of node2
if isinstance(node2, str):
if node2 in self.dcs:
node2 = self.dcs[node2].switch
if isinstance(node2, Datacenter):
node2 = node2.switch
# try to give containers a default IP
if isinstance(node1, Docker):
if "params1" not in params:
params["params1"] = {}
if "ip" not in params["params1"]:
params["params1"]["ip"] = self.getNextIp()
if isinstance(node2, Docker):
if "params2" not in params:
params["params2"] = {}
if "ip" not in params["params2"]:
params["params2"]["ip"] = self.getNextIp()
# ensure that we allow TCLinks between data centers
# TODO this is not optimal, we use cls=Link for containers and TCLink for data centers
# see Containernet issue:
# https://github.com/mpeuster/containernet/issues/3
if "cls" not in params:
params["cls"] = TCLink
link = Containernet.addLink(self, node1, node2, **params)
# try to give container interfaces a default id
node1_port_id = node1.ports[link.intf1]
if isinstance(node1, Docker):
if "id" in params["params1"]:
node1_port_id = params["params1"]["id"]
node1_port_name = link.intf1.name
node2_port_id = node2.ports[link.intf2]
if isinstance(node2, Docker):
if "id" in params["params2"]:
node2_port_id = params["params2"]["id"]
node2_port_name = link.intf2.name
# add edge and assigned port number to graph in both directions between node1 and node2
# port_id: id given in descriptor (if available, otherwise same as port)
# port: portnumber assigned by Containernet
attr_dict = {}
# possible weight metrics allowed by TClink class:
weight_metrics = ['bw', 'delay', 'jitter', 'loss']
edge_attributes = [p for p in params if p in weight_metrics]
for attr in edge_attributes:
# if delay: strip ms (need number as weight in graph)
match = re.search('([0-9]*\.?[0-9]+)', str(params[attr]))
if match:
attr_number = match.group(1)
else:
attr_number = None
attr_dict[attr] = attr_number
attr_dict2 = {'src_port_id': node1_port_id, 'src_port_nr': node1.ports[link.intf1],
'src_port_name': node1_port_name,
'dst_port_id': node2_port_id, 'dst_port_nr': node2.ports[link.intf2],
'dst_port_name': node2_port_name}
attr_dict2.update(attr_dict)
self.DCNetwork_graph.add_edge(
node1.name, node2.name, **attr_dict2)
attr_dict2 = {'src_port_id': node2_port_id, 'src_port_nr': node2.ports[link.intf2],
'src_port_name': node2_port_name,
'dst_port_id': node1_port_id, 'dst_port_nr': node1.ports[link.intf1],
'dst_port_name': node1_port_name}
attr_dict2.update(attr_dict)
self.DCNetwork_graph.add_edge(
node2.name, node1.name, **attr_dict2)
LOG.debug("addLink: n1={0} intf1={1} -- n2={2} intf2={3}".format(
str(node1), node1_port_name, str(node2), node2_port_name))
return link
def removeLink(self, link=None, node1=None, node2=None):
"""
Remove the link from the Containernet and the networkx graph
"""
if link is not None:
node1 = link.intf1.node
node2 = link.intf2.node
assert node1 is not None
assert node2 is not None
Containernet.removeLink(self, link=link, node1=node1, node2=node2)
# TODO we might decrease the loglevel to debug:
try:
self.DCNetwork_graph.remove_edge(node2.name, node1.name)
except BaseException:
LOG.warning("%s, %s not found in DCNetwork_graph." %
((node2.name, node1.name)))
try:
self.DCNetwork_graph.remove_edge(node1.name, node2.name)
except BaseException:
LOG.warning("%s, %s not found in DCNetwork_graph." %
((node1.name, node2.name)))
def addDocker(self, label, **params):
"""
Wrapper for addDocker method to use custom container class.
"""
self.DCNetwork_graph.add_node(label, type=params.get('type', 'docker'))
return Containernet.addDocker(
self, label, cls=EmulatorCompute, **params)
def removeDocker(self, label, **params):
"""
Wrapper for removeDocker method to update graph.
"""
self.DCNetwork_graph.remove_node(label)
return Containernet.removeDocker(self, label, **params)
def addExtSAP(self, sap_name, sap_ip, **params):
"""
Wrapper for addExtSAP method to store SAP also in graph.
"""
# make sure that 'type' is set
params['type'] = params.get('type', 'sap_ext')
self.DCNetwork_graph.add_node(sap_name, type=params['type'])
return Containernet.addExtSAP(self, sap_name, sap_ip, **params)
def removeExtSAP(self, sap_name, **params):
"""
Wrapper for removeExtSAP method to remove SAP also from graph.
"""
self.DCNetwork_graph.remove_node(sap_name)
return Containernet.removeExtSAP(self, sap_name)
def addSwitch(self, name, add_to_graph=True, **params):
"""
Wrapper for addSwitch method to store switch also in graph.
"""
# add this switch to the global topology overview
if add_to_graph:
self.DCNetwork_graph.add_node(
name, type=params.get('type', 'switch'))
# set the learning switch behavior
if 'failMode' in params:
failMode = params['failMode']
else:
failMode = self.failMode
s = Containernet.addSwitch(
self, name, protocols='OpenFlow10,OpenFlow12,OpenFlow13', failMode=failMode, **params)
return s
def getAllContainers(self):
"""
Returns a list with all containers within all data centers.
"""
all_containers = []
for dc in self.dcs.values():
all_containers += dc.listCompute()
return all_containers
def start(self):
# start
for dc in self.dcs.values():
dc.start()
Containernet.start(self)
def stop(self):
# stop the monitor agent
if self.monitor_agent is not None:
self.monitor_agent.stop()
# stop emulator net
Containernet.stop(self)
# stop Ryu controller
self.killRyu()
def CLI(self):
CLI(self)
def setLAN(self, vnf_list):
"""
setup an E-LAN network by assigning the same VLAN tag to each DC interface of the VNFs in the E-LAN
:param vnf_list: names of the VNFs in this E-LAN [{name:,interface:},...]
:return:
"""
src_sw = None
src_sw_inport_name = None
# get a vlan tag for this E-LAN
vlan = self.vlans.pop()
for vnf in vnf_list:
vnf_src_name = vnf['name']
vnf_src_interface = vnf['interface']
# check if port is specified (vnf:port)
if vnf_src_interface is None:
# take first interface by default
connected_sw = self.DCNetwork_graph.neighbors(vnf_src_name)[0]
link_dict = self.DCNetwork_graph[vnf_src_name][connected_sw]
vnf_src_interface = link_dict[0]['src_port_id']
for connected_sw in self.DCNetwork_graph.neighbors(vnf_src_name):
link_dict = self.DCNetwork_graph[vnf_src_name][connected_sw]
for link in link_dict:
if (link_dict[link]['src_port_id'] == vnf_src_interface or
link_dict[link]['src_port_name'] == vnf_src_interface): # Fix: we might also get interface names, e.g, from a son-emu-cli call
# found the right link and connected switch
src_sw = connected_sw
src_sw_inport_name = link_dict[link]['dst_port_name']
break
# set the tag on the dc switch interface
LOG.debug('set E-LAN: vnf name: {0} interface: {1} tag: {2}'.format(
vnf_src_name, vnf_src_interface, vlan))
switch_node = self.getNodeByName(src_sw)
self._set_vlan_tag(switch_node, src_sw_inport_name, vlan)
def getNodeByName(self, name):
"""
Wraps Containernet's getNodeByName method to avoid
key not found exceptions.
"""
try:
return super(DCNetwork, self).getNodeByName(name)
except BaseException as ex:
LOG.warning("Node not found: {}".format(name))
LOG.debug("Node not found: {}".format(ex))
return None
def _addMonitorFlow(self, vnf_src_name, vnf_dst_name, vnf_src_interface=None, vnf_dst_interface=None,
tag=None, **kwargs):
"""
Add a monitoring flow entry that adds a special flowentry/counter at the begin or end of a chain.
So this monitoring flowrule exists on top of a previously defined chain rule and uses the same vlan tag/routing.
:param vnf_src_name:
:param vnf_dst_name:
:param vnf_src_interface:
:param vnf_dst_interface:
:param tag: vlan tag to be used for this chain (same tag as existing chain)
:param monitor_placement: 'tx' or 'rx' indicating to place the extra flowentry resp. at the beginning or end of the chain
:return:
"""
src_sw = None
src_sw_inport_nr = 0
src_sw_inport_name = None
dst_sw = None
dst_sw_outport_nr = 0
dst_sw_outport_name = None
LOG.debug("call AddMonitorFlow vnf_src_name=%r, vnf_src_interface=%r, vnf_dst_name=%r, vnf_dst_interface=%r",
vnf_src_name, vnf_src_interface, vnf_dst_name, vnf_dst_interface)
# check if port is specified (vnf:port)
if vnf_src_interface is None:
# take first interface by default
connected_sw = self.DCNetwork_graph.neighbors(vnf_src_name)[0]
link_dict = self.DCNetwork_graph[vnf_src_name][connected_sw]
vnf_src_interface = link_dict[0]['src_port_id']
for connected_sw in self.DCNetwork_graph.neighbors(vnf_src_name):
link_dict = self.DCNetwork_graph[vnf_src_name][connected_sw]
for link in link_dict:
if (link_dict[link]['src_port_id'] == vnf_src_interface or
link_dict[link]['src_port_name'] == vnf_src_interface): # Fix: we might also get interface names, e.g, from a son-emu-cli call
# found the right link and connected switch
src_sw = connected_sw
src_sw_inport_nr = link_dict[link]['dst_port_nr']
src_sw_inport_name = link_dict[link]['dst_port_name']
break
if vnf_dst_interface is None:
# take first interface by default
connected_sw = self.DCNetwork_graph.neighbors(vnf_dst_name)[0]
link_dict = self.DCNetwork_graph[connected_sw][vnf_dst_name]
vnf_dst_interface = link_dict[0]['dst_port_id']
vnf_dst_name = vnf_dst_name.split(':')[0]
for connected_sw in self.DCNetwork_graph.neighbors(vnf_dst_name):
link_dict = self.DCNetwork_graph[connected_sw][vnf_dst_name]
for link in link_dict:
if link_dict[link]['dst_port_id'] == vnf_dst_interface or \
link_dict[link]['dst_port_name'] == vnf_dst_interface: # Fix: we might also get interface names, e.g, from a son-emu-cli call
# found the right link and connected switch
dst_sw = connected_sw
dst_sw_outport_nr = link_dict[link]['src_port_nr']
dst_sw_outport_name = link_dict[link]['src_port_name']
break
if not tag >= 0:
LOG.exception('tag not valid: {0}'.format(tag))
# get shortest path
try:
# returns the first found shortest path
# if all shortest paths are wanted, use: all_shortest_paths
path = nx.shortest_path(
self.DCNetwork_graph, src_sw, dst_sw, weight=kwargs.get('weight'))
except BaseException:
LOG.exception("No path could be found between {0} and {1} using src_sw={2} and dst_sw={3}".format(
vnf_src_name, vnf_dst_name, src_sw, dst_sw))
LOG.debug("Graph nodes: %r" % self.DCNetwork_graph.nodes())
LOG.debug("Graph edges: %r" % self.DCNetwork_graph.edges())
for e, v in self.DCNetwork_graph.edges():
LOG.debug("%r" % self.DCNetwork_graph[e][v])
return "No path could be found between {0} and {1}".format(
vnf_src_name, vnf_dst_name)
LOG.debug("Creating path between {0} and {1}: {2}".format(
vnf_src_name, vnf_dst_name, path))
current_hop = src_sw
switch_inport_nr = src_sw_inport_nr
cmd = kwargs.get('cmd')
# iterate through the path to install the flow-entries
for i in range(0, len(path)):
current_node = self.getNodeByName(current_hop)
if path.index(current_hop) < len(path) - 1:
next_hop = path[path.index(current_hop) + 1]
else:
# last switch reached
next_hop = vnf_dst_name
next_node = self.getNodeByName(next_hop)
if next_hop == vnf_dst_name:
switch_outport_nr = dst_sw_outport_nr
LOG.debug("end node reached: {0}".format(vnf_dst_name))
elif not isinstance(next_node, OVSSwitch):
LOG.info("Next node: {0} is not a switch".format(next_hop))
return "Next node: {0} is not a switch".format(next_hop)
else:
# take first link between switches by default
index_edge_out = 0
switch_outport_nr = self.DCNetwork_graph[current_hop][next_hop][index_edge_out]['src_port_nr']
# set of entry via ovs-ofctl
if isinstance(current_node, OVSSwitch):
kwargs['vlan'] = tag
kwargs['path'] = path
kwargs['current_hop'] = current_hop
kwargs['switch_inport_name'] = src_sw_inport_name
kwargs['switch_outport_name'] = dst_sw_outport_name
kwargs['skip_vlan_tag'] = True
kwargs['pathindex'] = i
monitor_placement = kwargs.get('monitor_placement').strip()
# put monitor flow at the dst switch
insert_flow = False
# first node:
if monitor_placement == 'tx' and path.index(current_hop) == 0:
insert_flow = True
# put monitoring flow at the src switch
# last node:
elif monitor_placement == 'rx' and path.index(current_hop) == len(path) - 1:
insert_flow = True
elif monitor_placement not in ['rx', 'tx']:
LOG.exception(
'invalid monitor command: {0}'.format(monitor_placement))
if self.controller == RemoteController and insert_flow:
# set flow entry via ryu rest api
self._set_flow_entry_ryu_rest(
current_node, switch_inport_nr, switch_outport_nr, **kwargs)
break
elif insert_flow:
# set flow entry via ovs-ofctl
self._set_flow_entry_dpctl(
current_node, switch_inport_nr, switch_outport_nr, **kwargs)
break
# take first link between switches by default
if isinstance(next_node, OVSSwitch):
switch_inport_nr = self.DCNetwork_graph[current_hop][next_hop][0]['dst_port_nr']
current_hop = next_hop
return "path {2} between {0} and {1}".format(
vnf_src_name, vnf_dst_name, cmd)
def setChain(self, vnf_src_name, vnf_dst_name,
vnf_src_interface=None, vnf_dst_interface=None, **kwargs):
"""
Chain 2 vnf interfaces together by installing the flowrules in the switches along their path.
Currently the path is found using the default networkx shortest path function.
Each chain gets a unique vlan id , so different chains wil not interfere.
:param vnf_src_name: vnf name (string)
:param vnf_dst_name: vnf name (string)
:param vnf_src_interface: source interface name (string)
:param vnf_dst_interface: destination interface name (string)
:param cmd: 'add-flow' (default) to add a chain, 'del-flows' to remove a chain
:param cookie: cookie for the installed flowrules (can be used later as identifier for a set of installed chains)
:param match: custom match entry to be added to the flowrules (default: only in_port and vlan tag)
:param priority: custom flowrule priority
:param monitor: boolean to indicate whether this chain is a monitoring chain
:param tag: vlan tag to be used for this chain (pre-defined or new one if none is specified)
:param skip_vlan_tag: boolean to indicate if a vlan tag should be appointed to this flow or not
:param path: custom path between the two VNFs (list of switches)
:return: output log string
"""
# special procedure for monitoring flows
if kwargs.get('monitor'):
# check if chain already exists
found_chains = [chain_dict for chain_dict in self.installed_chains if
(chain_dict['vnf_src_name'] == vnf_src_name and
chain_dict['vnf_src_interface'] == vnf_src_interface and
chain_dict['vnf_dst_name'] == vnf_dst_name and
chain_dict['vnf_dst_interface'] == vnf_dst_interface)]
if len(found_chains) > 0:
# this chain exists, so need an extra monitoring flow
# assume only 1 chain per vnf/interface pair
LOG.debug('*** installing monitoring chain on top of pre-defined chain from {0}:{1} -> {2}:{3}'.
format(vnf_src_name, vnf_src_interface, vnf_dst_name, vnf_dst_interface))
tag = found_chains[0]['tag']
ret = self._addMonitorFlow(vnf_src_name, vnf_dst_name, vnf_src_interface, vnf_dst_interface,
tag=tag, table_id=0, **kwargs)
return ret
else:
# no chain existing (or E-LAN) -> install normal chain
LOG.warning('*** installing monitoring chain without pre-defined NSD chain from {0}:{1} -> {2}:{3}'.
format(vnf_src_name, vnf_src_interface, vnf_dst_name, vnf_dst_interface))
pass
cmd = kwargs.get('cmd', 'add-flow')
if cmd == 'add-flow' or cmd == 'del-flows':
ret = self._chainAddFlow(
vnf_src_name, vnf_dst_name, vnf_src_interface, vnf_dst_interface, **kwargs)
if kwargs.get('bidirectional'):
if kwargs.get('path') is not None:
kwargs['path'] = list(reversed(kwargs.get('path')))
ret = ret + '\n' + \
self._chainAddFlow(
vnf_dst_name, vnf_src_name, vnf_dst_interface, vnf_src_interface, **kwargs)
else:
ret = "Command unknown"
return ret
def _chainAddFlow(self, vnf_src_name, vnf_dst_name,
vnf_src_interface=None, vnf_dst_interface=None, **kwargs):
src_sw = None
src_sw_inport_nr = 0
src_sw_inport_name = None
dst_sw = None
dst_sw_outport_nr = 0
dst_sw_outport_name = None
LOG.debug("call chainAddFlow vnf_src_name=%r, vnf_src_interface=%r, vnf_dst_name=%r, vnf_dst_interface=%r",
vnf_src_name, vnf_src_interface, vnf_dst_name, vnf_dst_interface)
# check if port is specified (vnf:port)
if vnf_src_interface is None:
# take first interface by default
connected_sw = list(self.DCNetwork_graph.neighbors(vnf_src_name))[0]
link_dict = self.DCNetwork_graph[vnf_src_name][connected_sw]
vnf_src_interface = link_dict[0]['src_port_id']
for connected_sw in self.DCNetwork_graph.neighbors(vnf_src_name):
link_dict = self.DCNetwork_graph[vnf_src_name][connected_sw]
for link in link_dict:
if (link_dict[link]['src_port_id'] == vnf_src_interface or
link_dict[link]['src_port_name'] == vnf_src_interface): # Fix: we might also get interface names, e.g, from a son-emu-cli call
# found the right link and connected switch
src_sw = connected_sw
src_sw_inport_nr = link_dict[link]['dst_port_nr']
src_sw_inport_name = link_dict[link]['dst_port_name']
break
if vnf_dst_interface is None:
# take first interface by default
connected_sw = list(self.DCNetwork_graph.neighbors(vnf_dst_name))[0]
link_dict = self.DCNetwork_graph[connected_sw][vnf_dst_name]
vnf_dst_interface = link_dict[0]['dst_port_id']
vnf_dst_name = vnf_dst_name.split(':')[0]
for connected_sw in self.DCNetwork_graph.neighbors(vnf_dst_name):
link_dict = self.DCNetwork_graph[connected_sw][vnf_dst_name]
for link in link_dict:
if link_dict[link]['dst_port_id'] == vnf_dst_interface or \
link_dict[link]['dst_port_name'] == vnf_dst_interface: # Fix: we might also get interface names, e.g, from a son-emu-cli call
# found the right link and connected switch
dst_sw = connected_sw
dst_sw_outport_nr = link_dict[link]['src_port_nr']
dst_sw_outport_name = link_dict[link]['src_port_name']
break
path = kwargs.get('path')
if path is None:
# get shortest path
try:
# returns the first found shortest path
# if all shortest paths are wanted, use: all_shortest_paths
path = nx.shortest_path(
self.DCNetwork_graph, src_sw, dst_sw, weight=kwargs.get('weight'))
except BaseException:
LOG.exception("No path could be found between {0} and {1} using src_sw={2} and dst_sw={3}".format(
vnf_src_name, vnf_dst_name, src_sw, dst_sw))
LOG.debug("Graph nodes: %r" % self.DCNetwork_graph.nodes())
LOG.debug("Graph edges: %r" % self.DCNetwork_graph.edges())
for e, v in self.DCNetwork_graph.edges():
LOG.debug("%r" % self.DCNetwork_graph[e][v])
return "No path could be found between {0} and {1}".format(
vnf_src_name, vnf_dst_name)
LOG.debug("Creating path between {0} and {1}: {2}".format(
vnf_src_name, vnf_dst_name, path))
current_hop = src_sw
switch_inport_nr = src_sw_inport_nr
# choose free vlan
cmd = kwargs.get('cmd')
vlan = None
if cmd == 'add-flow':
if kwargs.get('tag'):
# use pre-defined tag
vlan = kwargs.get('tag')
else:
vlan = self.vlans.pop()
# store the used vlan tag to identify this chain
if not kwargs.get('monitor'):
chain_dict = {}
chain_dict['vnf_src_name'] = vnf_src_name
chain_dict['vnf_dst_name'] = vnf_dst_name
chain_dict['vnf_src_interface'] = vnf_src_interface
chain_dict['vnf_dst_interface'] = vnf_dst_interface
chain_dict['tag'] = vlan
self.installed_chains.append(chain_dict)
# iterate through the path to install the flow-entries
for i in range(0, len(path)):
current_node = self.getNodeByName(current_hop)
if i < len(path) - 1:
next_hop = path[i + 1]
else:
# last switch reached
next_hop = vnf_dst_name
next_node = self.getNodeByName(next_hop)
if next_hop == vnf_dst_name:
switch_outport_nr = dst_sw_outport_nr
LOG.debug("end node reached: {0}".format(vnf_dst_name))
elif not isinstance(next_node, OVSSwitch):
LOG.info("Next node: {0} is not a switch".format(next_hop))
return "Next node: {0} is not a switch".format(next_hop)
else:
# take first link between switches by default
index_edge_out = 0
switch_outport_nr = self.DCNetwork_graph[current_hop][next_hop][index_edge_out]['src_port_nr']
# set OpenFlow entry
if isinstance(current_node, OVSSwitch):
kwargs['vlan'] = vlan
kwargs['path'] = path
kwargs['current_hop'] = current_hop
kwargs['switch_inport_name'] = src_sw_inport_name
kwargs['switch_outport_name'] = dst_sw_outport_name
kwargs['pathindex'] = i
if self.controller == RemoteController:
# set flow entry via ryu rest api
self._set_flow_entry_ryu_rest(
current_node, switch_inport_nr, switch_outport_nr, **kwargs)
else:
# set flow entry via ovs-ofctl
self._set_flow_entry_dpctl(
current_node, switch_inport_nr, switch_outport_nr, **kwargs)
# take first link between switches by default
if isinstance(next_node, OVSSwitch):
switch_inport_nr = self.DCNetwork_graph[current_hop][next_hop][0]['dst_port_nr']
current_hop = next_hop
flow_options = {
'priority': kwargs.get('priority', DEFAULT_PRIORITY),
'cookie': kwargs.get('cookie', DEFAULT_COOKIE),
'vlan': kwargs['vlan'],
'path': kwargs['path'],
'match_input': kwargs.get('match')
}
flow_options_str = json.dumps(flow_options, indent=1)
LOG.info("Installed flow rule: ({}:{}) -> ({}:{}) with options: {}"
.format(vnf_src_name, vnf_src_interface, vnf_dst_name, vnf_dst_interface, flow_options))
return "success: {2} between {0} and {1} with options: {3}".format(
vnf_src_name, vnf_dst_name, cmd, flow_options_str)
def _set_flow_entry_ryu_rest(
self, node, switch_inport_nr, switch_outport_nr, **kwargs):
match = 'in_port=%s' % switch_inport_nr
cookie = kwargs.get('cookie')
match_input = kwargs.get('match')
cmd = kwargs.get('cmd')
path = kwargs.get('path')
index = kwargs.get('pathindex')
mod_dl_dst = kwargs.get('mod_dl_dst')
vlan = kwargs.get('vlan')
priority = kwargs.get('priority', DEFAULT_PRIORITY)
# flag to not set the ovs port vlan tag
skip_vlan_tag = kwargs.get('skip_vlan_tag')
# table id to put this flowentry
table_id = kwargs.get('table_id')
if not table_id:
table_id = 0
s = ','
if match_input:
match = s.join([match, match_input])
flow = {}
flow['dpid'] = int(node.dpid, 16)
if cookie:
flow['cookie'] = int(cookie)
if priority:
flow['priority'] = int(priority)
flow['table_id'] = table_id
flow['actions'] = []
# possible Ryu actions, match fields:
# http://ryu.readthedocs.io/en/latest/app/ofctl_rest.html#add-a-flow-entry
if cmd == 'add-flow':
prefix = 'stats/flowentry/add'
if vlan is not None:
if index == 0: # first node
# set vlan tag in ovs instance (to isolate E-LANs)
if not skip_vlan_tag:
in_port_name = kwargs.get('switch_inport_name')
self._set_vlan_tag(node, in_port_name, vlan)
# set vlan push action if more than 1 switch in the path
if len(path) > 1:
action = {}
# Push a new VLAN tag if a input frame is
# non-VLAN-tagged
action['type'] = 'PUSH_VLAN'
# Ethertype 0x8100(=33024): IEEE 802.1Q VLAN-tagged
# frame
action['ethertype'] = 33024
flow['actions'].append(action)
action = {}
action['type'] = 'SET_FIELD'
action['field'] = 'vlan_vid'
# ryu expects the field to be masked
action['value'] = vlan | 0x1000
flow['actions'].append(action)
elif index == len(path) - 1: # last node
# set vlan tag in ovs instance (to isolate E-LANs)
if not skip_vlan_tag:
out_port_name = kwargs.get('switch_outport_name')
self._set_vlan_tag(node, out_port_name, vlan)
# set vlan pop action if more than 1 switch in the path
if len(path) > 1:
match += ',dl_vlan=%s' % vlan
action = {}
action['type'] = 'POP_VLAN'
flow['actions'].append(action)
else: # middle nodes
match += ',dl_vlan=%s' % vlan
if mod_dl_dst:
action = {}
action['type'] = 'SET_FIELD'
action['field'] = 'eth_dst'
action['value'] = mod_dl_dst
flow['actions'].append(action)
# output action must come last
action = {}
action['type'] = 'OUTPUT'
action['port'] = switch_outport_nr
flow['actions'].append(action)
elif cmd == 'del-flows':
prefix = 'stats/flowentry/delete'
if cookie:
# TODO: add cookie_mask as argument
# need full mask to match complete cookie
flow['cookie_mask'] = int('0xffffffffffffffff', 16)
action = {}
action['type'] = 'OUTPUT'
action['port'] = switch_outport_nr
flow['actions'].append(action)
flow['match'] = self._parse_match(match)
self.ryu_REST(prefix, data=flow)
def _set_vlan_tag(self, node, switch_port, tag):
node.vsctl('set', 'port {0} tag={1}'.format(switch_port, tag))
LOG.debug("set vlan in switch: {0} in_port: {1} vlan tag: {2}".format(
node.name, switch_port, tag))
def _set_flow_entry_dpctl(
self, node, switch_inport_nr, switch_outport_nr, **kwargs):
match = 'in_port=%s' % switch_inport_nr
cookie = kwargs.get('cookie')
match_input = kwargs.get('match')
cmd = kwargs.get('cmd')
path = kwargs.get('path')
index = kwargs.get('pathindex')
vlan = kwargs.get('vlan')
s = ','
if cookie:
cookie = 'cookie=%s' % cookie
match = s.join([cookie, match])
if match_input:
match = s.join([match, match_input])
if cmd == 'add-flow':
action = 'action=%s' % switch_outport_nr
if vlan is not None:
if index == 0: # first node
action = ('action=mod_vlan_vid:%s' % vlan) + \
(',output=%s' % switch_outport_nr)
match = '-O OpenFlow13 ' + match
elif index == len(path) - 1: # last node
match += ',dl_vlan=%s' % vlan
action = 'action=strip_vlan,output=%s' % switch_outport_nr
else: # middle nodes
match += ',dl_vlan=%s' % vlan
ofcmd = s.join([match, action])
elif cmd == 'del-flows':
ofcmd = match
else:
ofcmd = ''
node.dpctl(cmd, ofcmd)
LOG.info("{3} in switch: {0} in_port: {1} out_port: {2}".format(node.name, switch_inport_nr,
switch_outport_nr, cmd))
# start Ryu Openflow controller as Remote Controller for the DCNetwork
def startRyu(self, learning_switch=True):
# start Ryu controller with rest-API
# ryu default learning switch
# ryu_learning_app = python_install_path + '/ryu/app/simple_switch_13.py'
# custom learning switch that installs a default NORMAL action in the
# ovs switches
dir_path = os.path.dirname(os.path.realpath(__file__))
ryu_learning_app = dir_path + '/son_emu_simple_switch_13.py'
ryu_rest_app = 'ryu.app.ofctl_rest'
# change the default Openflow controller port to 6653 (official IANA-assigned port number), as used by Mininet
# Ryu still uses 6633 as default
ryu_option = '--ofp-tcp-listen-port'
ryu_of_port = '6653'
ryu_cmd = 'ryu-manager'
FNULL = open("/tmp/ryu.log", 'w')
if learning_switch:
# learning and rest api
args = [ryu_cmd, ryu_learning_app, ryu_rest_app, ryu_option, ryu_of_port]
else:
# no learning switch, but with rest api
args = [ryu_cmd, ryu_rest_app, ryu_option, ryu_of_port]
self.ryu_process = Popen(args, stdout=FNULL, stderr=FNULL)
LOG.debug('starting ryu-controller with %s' % args)
time.sleep(1)
def killRyu(self):
"""
Stop the Ryu controller that might be started by son-emu.
:return:
"""
# try it nicely
try:
if self.ryu_process is not None:
self.ryu_process.terminate()
self.ryu_process.kill()
except BaseException as ex:
LOG.warning("Error during Ryu stop: {}".format(ex))
# ensure its death ;-)
Popen(['pkill', '-f', 'ryu-manager'])
def ryu_REST(self, prefix, dpid=None, data=None):
if dpid:
url = self.ryu_REST_api + '/' + str(prefix) + '/' + str(dpid)
else:
url = self.ryu_REST_api + '/' + str(prefix)
LOG.debug('sending RYU command: %s, payload: %s', url, data)
if data:
req = self.RyuSession.post(url, json=data)
else:
req = self.RyuSession.get(url)
# do extra logging if status code is not 200 (OK)
if req.status_code is not requests.codes.ok:
LOG.info(
'type {0} encoding: {1} text: {2} headers: {3} history: {4}'.format(req.headers['content-type'],
req.encoding, req.text,
req.headers, req.history))
LOG.info('url: {0}'.format(str(url)))
if data:
LOG.info('POST: {0}'.format(str(data)))
LOG.info('status: {0} reason: {1}'.format(
req.status_code, req.reason))
if 'json' in req.headers['content-type']:
ret = req.json()
return ret
ret = req.text.rstrip()
return ret
# need to respect that some match fields must be integers
# http://ryu.readthedocs.io/en/latest/app/ofctl_rest.html#description-of-match-and-actions
def _parse_match(self, match):
matches = match.split(',')
dict = {}
for m in matches:
match = m.split('=')
if len(match) == 2:
try:
m2 = int(match[1], 0)
except BaseException:
m2 = match[1]
dict.update({match[0]: m2})
return dict
def find_connected_dc_interface(
self, vnf_src_name, vnf_src_interface=None):
if vnf_src_interface is None:
# take first interface by default
connected_sw = self.DCNetwork_graph.neighbors(vnf_src_name)[0]
link_dict = self.DCNetwork_graph[vnf_src_name][connected_sw]
vnf_src_interface = link_dict[0]['src_port_id']
for connected_sw in self.DCNetwork_graph.neighbors(vnf_src_name):
link_dict = self.DCNetwork_graph[vnf_src_name][connected_sw]
for link in link_dict:
if (link_dict[link]['src_port_id'] == vnf_src_interface or
link_dict[link]['src_port_name'] == vnf_src_interface):
# Fix: we might also get interface names, e.g, from a son-emu-cli call
# found the right link and connected switch
src_sw_inport_name = link_dict[link]['dst_port_name']
return src_sw_inport_name