Example #1
0
    def load_edges(self, fname):
        with open(fname) as f:
            for line in f.readlines():
                tokens = line.strip().split()
                src = tokens[0]
                dst = tokens[1]
                if src not in self.switches:
                    self.hosts[src] = Host(ip=src, name=src)
                if dst not in self.switches:
                    self.hosts[dst] = Host(ip=dst, name=dst)

                if src in self.switches:
                    if dst not in self.edges[src]:
                        self.edges[src].append(dst)
Example #2
0
    def _make_topo(self):
        self.graph = self._generate_graph()
        switches = [node for node in self.graph.nodes() if node[0] == 's']
        hosts = [node for node in self.graph.nodes() if node[0] == 'h']

        startip = ip2int("10.1.0.0")
        for name in switches:
            ip = startip + len(self.switches) + 1
            self.switches[name] = Switch(name=name, ip=int2ip(ip))

        count = 0
        for name in hosts:
            podnum, idx = self.pods_rev[name]
            ip = "10.0.{0}.{1}".format(podnum, idx)
            mac = int2mac(count)
            count += 1
            self.hosts[name] = Host(name=name, ip=ip, mac=mac)

        for e0, e1 in self.graph.edges():
            if e0 not in self.edges:
                self.edges[e0] = []
            if e1 not in self.edges:
                self.edges[e1] = []

            self.edges[e0].append(e1)
            self.edges[e1].append(e0)
Example #3
0
    def read_links(self, path):
        topofile = os.path.join(path, "as1755.topo")
        egressfile = os.path.join(path, "as1755.egress")

        #self.graph = networkx.DiGraph()
        self.graph = networkx.Graph()

        with open(topofile) as f:
            for line in f.readlines():
                tokens = line.split()
                if len(tokens) != 2:
                    raise Exception("Invalid line in topo: {0}".format(line))

                # skip duplicates and self loops
                if not self.graph.has_edge(tokens[0], tokens[1]) and \
                   tokens[0] != tokens[1]:
                    self.graph.add_edge(tokens[0], tokens[1])

        for node in self.graph.nodes():
            if node.startswith("10."):
                if node not in self.switches:
                    self.switches[node] = Switch(name=node, ip=node)
            else:
                if node not in self.hosts:
                    self.hosts[node] = Host(name=node, ip=node)

        for e0, e1 in self.graph.edges():
            if e0 not in self.edges:
                self.edges[e0] = []
            if e1 not in self.edges:
                self.edges[e1] = []

            self.edges[e0].append(e1)
            self.edges[e1].append(e0)

        with open(egressfile) as f:
            self._egresses = [e.strip() for e in f.readlines()]
Example #4
0
from link import Link, LinkLayer
import threading
from time import sleep
import sys
from copy import deepcopy

##configuration parameters
router_queue_size = 0  #0 means unlimited
simulation_time = 10  #give the network sufficient time to execute transfers

if __name__ == '__main__':
    object_L = [
    ]  #keeps track of objects, so we can kill their threads at the end

    #create network hosts
    host_1 = Host('H1')
    object_L.append(host_1)
    host_2 = Host('H2')
    object_L.append(host_2)

    #create routers and routing tables for connected clients (subnets)
    encap_tbl_D = {
    }  # table used to encapsulate network packets into MPLS frames
    frwd_tbl_D = {}  # table used to forward MPLS frames
    decap_tbl_D = {
    }  # table used to decapsulate network packets from MPLS frames
    router_a = Router(name='RA',
                      intf_capacity_L=[500, 500],
                      encap_tbl_D=encap_tbl_D,
                      frwd_tbl_D=frwd_tbl_D,
                      decap_tbl_D=decap_tbl_D,
Example #5
0
    def __init__(self, definition, ntf, ttf, port_ids, router, no_ft=False):
        super(TfTopology, self).__init__()
        self.definition = definition
        if no_ft:
            for rtr1, intf1, rtr2, intf2 in self.definition:
                if rtr1 not in self.edges:
                    self.edges[rtr1] = []
                if rtr2 not in self.edges:
                    self.edges[rtr2] = []

                self.edges[rtr1].append(rtr2)
                self.edges[rtr2].append(rtr1)
                self.switches[rtr1] = Switch(name=rtr1)
                self.switches[rtr2] = Switch(name=rtr2)

            return

        self.ntf = ntf()
        self.ttf = ttf()
        self.port_map, self.port_reverse_map = port_ids()
        self.router = router(1)
        self.edge_ports = set()
        self.intfs = {}
        edge_port_ips = {}
        start_ip = ip2int("10.0.0.1")

        # keys (ports) should be ints
        self.port_reverse_map = dict(
            (int(k), v) for (k, v) in self.port_reverse_map.iteritems())

        for rtr1, intf1, rtr2, intf2 in self.definition:
            if rtr1 not in self.intfs:
                self.intfs[rtr1] = {}
            if rtr2 not in self.intfs:
                self.intfs[rtr2] = {}

            if rtr1 not in self.edges:
                self.edges[rtr1] = []
            if rtr2 not in self.edges:
                self.edges[rtr2] = []

            self.intfs[rtr1][intf1] = rtr2
            self.intfs[rtr2][intf2] = rtr1
            self.edges[rtr1].append(rtr2)
            self.edges[rtr2].append(rtr1)
            self.switches[rtr1] = Switch(name=rtr1)
            self.switches[rtr2] = Switch(name=rtr2)

        host_limit = {}
        for rtr in self.port_map.keys():
            for port in self.port_map[rtr].values():
                host_limit[rtr] = int(port) + \
                                  self.router.PORT_TYPE_MULTIPLIER * \
                                  self.router.OUTPUT_PORT_TYPE_CONST
                break
                # self.edge_ports.add(int(port) +
                #                     self.router.PORT_TYPE_MULTIPLIER *
                #                     self.router.OUTPUT_PORT_TYPE_CONST)

        #for port in sorted(self.edge_ports):
        for port in sorted(host_limit.values()):
            self.edge_ports.add(port)

            ip = int2ip(start_ip + len(edge_port_ips))
            edge_port_ips[port] = ip
            self.hosts[ip] = Host(ip=ip, name=ip)

        for tf in self.ntf.tf_list:
            ofg = OpenFlow_Rule_Generator(tf, self.router.HS_FORMAT())
            rules = ofg.generate_of_rules()
            swname = tf.prefix_id

            for rule in rules:
                #dest = int2ip(rule['ip_dst_match'])
                #wc = wc2ip(rule['ip_dst_wc'])
                outports = rule['out_ports']
                location = tf.prefix_id
                nexthops = []

                for port in outports:
                    if port in self.edge_ports:
                        nexthops.append(edge_port_ips[port])
                        pass
                    else:
                        p = port - self.router.PORT_TYPE_MULTIPLIER
                        if p in self.port_reverse_map.keys():
                            portname = self.port_reverse_map[p].split("-")[1]
                            if portname in self.intfs[location].keys():
                                nexthop = self.intfs[location][portname]
                                nexthops.append(nexthop)
                            else:
                                # TODO
                                pass

                r = trie.Rule()
                r.ruleType = trie.Rule.FORWARDING
                r.location = location
                r.priority = 1

                # TODO: handle multipath
                if len(nexthops) > 0:
                    r.nextHop = nexthops[0]

                nw_dst_match = rule['ip_dst_match']
                nw_dst_wc = ip2int(wc2ip(rule['ip_dst_wc']))
                nw_src_match = rule['ip_src_match']
                nw_src_wc = ip2int(wc2ip(rule['ip_src_wc']))

                r.fieldValue[HeaderField.Index["NW_DST"]] = nw_dst_match
                r.fieldMask[HeaderField.Index["NW_DST"]] = nw_dst_wc
                r.fieldValue[HeaderField.Index["NW_SRC"]] = nw_src_match
                r.fieldMask[HeaderField.Index["NW_SRC"]] = nw_src_wc

                # filter inports - only add edge inports
                inports = [
                    (p + router.PORT_TYPE_MULTIPLIER) for p in rule['in_ports']
                    if (p + router.PORT_TYPE_MULTIPLIER) in self.edge_ports
                ]

                if len(inports) > 0:
                    r.fieldValue[HeaderField.Index["IN_PORT"]] = sorted(
                        inports)[0]
                    r.fieldMask[HeaderField.Index["IN_PORT"]] = 0xFFFF

                # TODO: handle vlan rewrite?
                # r.fieldValue[HeaderField.Index["DL_VLAN"]] = rule['vlan_match']
                # flow = FlowEntry(dest=dest,
                #                  wildcard=wc,
                #                  location=location,
                #                  nexthops=nexthops)

                # add host to edges
                for n in nexthops:
                    if n in self.hosts and n not in self.edges[location]:
                        self.edges[location].append(n)

                if len(nexthops) > 1:
                    print "Can't handle multiple next hops", nexthops

                if len(nexthops) > 0:
                    # self.switches[swname].ft.append(flow)
                    self.switches[swname].ft.append(r)