def build_layer3(anm):
""" l3_connectivity graph: switch nodes aggregated and exploded"""
g_in = anm['input']
gl2_conn = anm['layer2_conn']
g_l3 = anm.add_overlay("layer3")
g_l3.add_nodes_from(gl2_conn, retain=['label', 'devsubtype'])
ank_utils.copy_attr_from(g_in, g_l3, "multicast")
g_l3.add_nodes_from(g_in.switches(), retain=['asn'])
g_l3.add_edges_from(gl2_conn.edges(), retain=['link_type'])
edges_to_remove = [
edge for edge in gl2_conn.edges() if edge.link_type == 'is_not_l3'
]
g_l3.remove_edges_from(edges_to_remove)
edges_to_remove = []
switches = g_l3.switches()
ank_utils.aggregate_nodes(g_l3, switches)
exploded_edges = ank_utils.explode_nodes(g_l3,
switches,
retain=['link_type'])
# also explode virtual switches
vswitches = [
n for n in g_l3.nodes() if n['layer2'].device_type == "switch"
and n['layer2'].device_subtype == "virtual"
]
# explode each seperately?
for edge in exploded_edges:
edge.multipoint = True
edge.src_int.multipoint = True
edge.dst_int.multipoint = True
def apply_design_rules(anm):
"""Applies appropriate design rules to ANM"""
g_in = anm['input']
build_phy(anm)
g_phy = anm['phy']
import autonetkit
autonetkit.update_http(anm)
build_l3_connectivity(anm)
check_server_asns(anm)
autonetkit.update_http(anm)
build_vrf(anm) # need to do before to add loopbacks before ip allocations
from autonetkit.design.ip import build_ip, build_ipv4,build_ipv6
build_ip(anm) # ip infrastructure topology
#TODO: set defaults at the start, rather than inline, ie set g_in.data.address_family then use later
address_family = g_in.data.address_family or "v4" # default is v4
#TODO: can remove the infrastructure now create g_ip seperately
if address_family == "None":
log.info("IP addressing disabled, disabling routing protocol configuration")
anm['phy'].data.enable_routing = False
if address_family == "None":
log.info("IP addressing disabled, skipping IPv4")
anm.add_overlay("ipv4") # create empty so rest of code follows through
g_phy.update(g_phy, use_ipv4 = False)
elif address_family in ("v4", "dual_stack"):
build_ipv4(anm, infrastructure = True)
g_phy.update(g_phy, use_ipv4 = True)
elif address_family == "v6":
# Allocate v4 loopbacks for router ids
build_ipv4(anm, infrastructure = False)
g_phy.update(g_phy, use_ipv4 = False)
#TODO: Create a collision domain overlay for ip addressing - l2 overlay?
if address_family == "None":
log.info("IP addressing disabled, not allocating IPv6")
anm.add_overlay("ipv6") # create empty so rest of code follows through
g_phy.update(g_phy, use_ipv6 = False)
elif address_family in ("v6", "dual_stack"):
build_ipv6(anm)
g_phy.update(g_phy, use_ipv6 = True)
else:
anm.add_overlay("ipv6") # placeholder for compiler logic
default_igp = g_in.data.igp or "ospf"
non_igp_nodes = [n for n in g_in if not n.igp]
#TODO: should this be modifying g_in?
g_in.update(non_igp_nodes, igp=default_igp) # store igp onto each node
ank_utils.copy_attr_from(g_in, g_phy, "include_csr")
try:
from autonetkit_cisco import build_network as cisco_build_network
except ImportError, e:
log.debug("Unable to load autonetkit_cisco %s" % e)
def apply_design_rules(anm):
"""Applies appropriate design rules to ANM"""
g_in = anm['input']
build_phy(anm)
g_phy = anm['phy']
from autonetkit.design.osi_layers import (build_layer2,
build_layer2_broadcast, build_layer3)
build_layer2(anm)
build_layer2_broadcast(anm)
build_layer3(anm)
build_l3_connectivity(anm)
check_server_asns(anm)
from autonetkit.design.mpls import build_vrf
build_vrf(anm) # do before to add loopbacks before ip allocations
from autonetkit.design.ip import build_ip, build_ipv4, build_ipv6
# TODO: replace this with layer2 overlay topology creation
build_ip(anm) # ip infrastructure topology
address_family = g_in.data.address_family or "v4" # default is v4
# TODO: can remove the infrastructure now create g_ip seperately
if address_family == "None":
log.info("IP addressing disabled, disabling routing protocol ",
"configuration")
anm['phy'].data.enable_routing = False
if address_family == "None":
log.info("IP addressing disabled, skipping IPv4")
anm.add_overlay("ipv4") # create empty so rest of code follows
g_phy.update(g_phy, use_ipv4=False)
elif address_family in ("v4", "dual_stack"):
build_ipv4(anm, infrastructure=True)
g_phy.update(g_phy, use_ipv4=True)
elif address_family == "v6":
# Allocate v4 loopbacks for router ids
build_ipv4(anm, infrastructure=False)
g_phy.update(g_phy, use_ipv4=False)
# TODO: Create collision domain overlay for ip addressing - l2 overlay?
if address_family == "None":
log.info("IP addressing disabled, not allocating IPv6")
anm.add_overlay("ipv6") # create empty so rest of code follows
g_phy.update(g_phy, use_ipv6=False)
elif address_family in ("v6", "dual_stack"):
build_ipv6(anm)
g_phy.update(g_phy, use_ipv6=True)
else:
anm.add_overlay("ipv6") # placeholder for compiler logic
default_igp = g_in.data.igp or "ospf"
ank_utils.set_node_default(g_in, igp=default_igp)
ank_utils.copy_attr_from(g_in, g_phy, "include_csr")
try:
from autonetkit_cisco import build_network as cisco_build_network
except ImportError, e:
log.debug("Unable to load autonetkit_cisco %s" % e)
def build_rip(anm):
"""Build rip overlay"""
g_in = anm['input']
g_l3 = anm['layer3']
g_rip = anm.add_overlay("rip")
g_phy = anm['phy']
if not anm['phy'].data.enable_routing:
g_rip.log.info("Routing disabled, not configuring rip")
return
if not any(n.igp == "rip" for n in g_phy):
log.debug("No rip nodes")
return
rip_nodes = [n for n in g_l3 if n['phy'].igp == "rip"]
g_rip.add_nodes_from(rip_nodes)
g_rip.add_edges_from(g_l3.edges(), warn=False)
ank_utils.copy_int_attr_from(g_l3, g_rip, "multipoint")
ank_utils.copy_attr_from(
g_in, g_rip, "custom_config_rip", dst_attr="custom_config")
g_rip.remove_edges_from(
[link for link in g_rip.edges() if link.src.asn != link.dst.asn])
for node in g_rip:
node.process_id = node.asn
for link in g_rip.edges():
link.metric = 1 # default
for edge in g_rip.edges():
for interface in edge.interfaces():
interface.metric = edge.metric
interface.multipoint = edge.multipoint
def apply_design_rules(anm):
"""Applies appropriate design rules to ANM"""
g_in = anm['input']
build_phy(anm)
g_phy = anm['phy']
build_l3_connectivity(anm)
check_server_asns(anm)
from autonetkit.design.mpls import build_vrf
build_vrf(anm) # need to do before to add loopbacks before ip allocations
from autonetkit.design.ip import build_ip, build_ipv4, build_ipv6
#TODO: replace this with layer2 overlay topology creation
build_ip(anm) # ip infrastructure topology
#TODO: set defaults at the start, rather than inline, ie set g_in.data.address_family then use later
address_family = g_in.data.address_family or "v4" # default is v4
#TODO: can remove the infrastructure now create g_ip seperately
if address_family == "None":
log.info(
"IP addressing disabled, disabling routing protocol configuration")
anm['phy'].data.enable_routing = False
if address_family == "None":
log.info("IP addressing disabled, skipping IPv4")
anm.add_overlay("ipv4") # create empty so rest of code follows through
g_phy.update(g_phy, use_ipv4=False)
elif address_family in ("v4", "dual_stack"):
build_ipv4(anm, infrastructure=True)
g_phy.update(g_phy, use_ipv4=True)
elif address_family == "v6":
# Allocate v4 loopbacks for router ids
build_ipv4(anm, infrastructure=False)
g_phy.update(g_phy, use_ipv4=False)
#TODO: Create a collision domain overlay for ip addressing - l2 overlay?
if address_family == "None":
log.info("IP addressing disabled, not allocating IPv6")
anm.add_overlay("ipv6") # create empty so rest of code follows through
g_phy.update(g_phy, use_ipv6=False)
elif address_family in ("v6", "dual_stack"):
build_ipv6(anm)
g_phy.update(g_phy, use_ipv6=True)
else:
anm.add_overlay("ipv6") # placeholder for compiler logic
default_igp = g_in.data.igp or "ospf"
ank_utils.set_node_default(g_in, igp=default_igp)
ank_utils.copy_attr_from(g_in, g_phy, "include_csr")
try:
from autonetkit_cisco import build_network as cisco_build_network
except ImportError, e:
log.debug("Unable to load autonetkit_cisco %s" % e)
def build_phy(anm):
G_in = anm['input']
G_phy = anm['phy']
G_phy.add_nodes_from(G_in, retain=['label', 'update', 'device_type', 'device_subtype', 'asn', 'platform', 'host', 'syntax'])
if G_in.data.Creator == "Topology Zoo Toolset":
ank.copy_attr_from(G_in, G_phy, "Network") #TODO: move this into graphml (and later gml) reader
G_phy.add_edges_from(G_in.edges(type="physical"))
G_phy.allocate_interfaces() #TODO: make this automatic if adding to the physical graph?
def build_bgp(anm):
"""Build iBGP end eBGP overlays"""
# eBGP
g_in = anm['input']
g_l3 = anm['layer3']
if not anm['phy'].data.enable_routing:
log.info("Routing disabled, not configuring BGP")
return
build_ebgp(anm)
build_ebgp_v4(anm)
build_ebgp_v6(anm)
"""TODO: remove from here once compiler updated"""
g_bgp = anm.add_overlay("bgp", directed=True)
g_bgp.add_nodes_from(g_l3.routers())
edges_to_add = [e for e in g_l3.edges()
if e.src in g_bgp and e.dst in g_bgp]
g_bgp.add_edges_from(edges_to_add, bidirectional=True)
ank_utils.copy_int_attr_from(g_l3, g_bgp, "multipoint")
# remove ibgp links
"""TODO: remove up to here once compiler updated"""
ank_utils.copy_attr_from(
g_in, g_bgp, "custom_config_bgp", dst_attr="custom_config")
# log.info("Building eBGP")
ebgp_nodes = [d for d in g_bgp if any(
edge.type == 'ebgp' for edge in d.edges())]
g_bgp.update(ebgp_nodes, ebgp=True)
for ebgp_edge in g_bgp.edges(type="ebgp"):
for interface in ebgp_edge.interfaces():
interface.ebgp = True
for edge in g_bgp.edges(type='ibgp'):
# TODO: need interface querying/selection. rather than hard-coded ids
# TODO: create a new port (once API allows) rarher than binding to
# loopback zero
edge.bind_interface(edge.src, 0)
# TODO: need to initialise interface zero to be a loopback rather than physical type
# TODO: wat is this for?
for node in g_bgp:
for interface in node.interfaces():
interface.multipoint = any(e.multipoint for e in interface.edges())
# log.info("Building iBGP")
build_ibgp(anm)
build_ibgp_v4(anm)
build_ibgp_v6(anm)
def build_phy(anm):
"""Build physical overlay"""
g_in = anm['input']
g_phy = anm['phy']
g_phy.add_nodes_from(g_in, retain=['label', 'update', 'device_type', 'asn',
'device_subtype', 'platform', 'host', 'syntax'])
if g_in.data.Creator == "Topology Zoo Toolset":
ank_utils.copy_attr_from(g_in, g_phy, "Network")
g_phy.add_edges_from(g_in.edges(type="physical"))
g_phy.allocate_interfaces(
) # TODO: make this automatic if adding to the physical graph?
def build_bgp(anm):
"""Build iBGP end eBGP overlays"""
# eBGP
g_in = anm['input']
g_l3 = anm['layer3']
if not anm['phy'].data.enable_routing:
log.info("Routing disabled, not configuring BGP")
return
build_ebgp(anm)
build_ebgp_v4(anm)
build_ebgp_v6(anm)
"""TODO: remove from here once compiler updated"""
g_bgp = anm.add_overlay("bgp", directed=True)
g_bgp.add_nodes_from(g_l3.routers())
edges_to_add = [e for e in g_l3.edges()
if e.src in g_bgp and e.dst in g_bgp]
g_bgp.add_edges_from(edges_to_add, bidirectional=True)
ank_utils.copy_int_attr_from(g_l3, g_bgp, "multipoint")
# remove ibgp links
"""TODO: remove up to here once compiler updated"""
ank_utils.copy_attr_from(
g_in, g_bgp, "custom_config_bgp", dst_attr="custom_config")
log.info("Building eBGP")
ebgp_nodes = [d for d in g_bgp if any(
edge.type == 'ebgp' for edge in d.edges())]
g_bgp.update(ebgp_nodes, ebgp=True)
for ebgp_edge in g_bgp.edges(type="ebgp"):
for interface in ebgp_edge.interfaces():
interface.ebgp = True
for edge in g_bgp.edges(type='ibgp'):
# TODO: need interface querying/selection. rather than hard-coded ids
# TODO: create a new port (once API allows) rarher than binding to
# loopback zero
edge.bind_interface(edge.src, 0)
# TODO: need to initialise interface zero to be a loopback rather than physical type
# TODO: wat is this for?
for node in g_bgp:
for interface in node.interfaces():
interface.multipoint = any(e.multipoint for e in interface.edges())
log.info("Building iBGP")
build_ibgp(anm)
build_ibgp_v4(anm)
build_ibgp_v6(anm)
def build_phy(anm):
"""Build physical overlay"""
g_in = anm['input']
g_phy = anm['phy']
g_phy.data.enable_routing = g_in.data.enable_routing
if g_in.data.mgmt_block:
g_phy.data['mgmt_block'] = g_in.data['mgmt_block']
if g_in.data.vpcid_block:
g_phy.data['vpcid_block'] = g_in.data['vpcid_block']
if g_phy.data.enable_routing is None:
g_in.data.enable_routing = True # default if not set
g_phy.add_nodes_from(g_in, retain=['label', 'update', 'device_type', 'devsubtype',
'asn', 'specified_int_names', 'x', 'y',
'device_subtype', 'platform', 'host', 'syntax',
'profile', 'syslog'])
if g_in.data.Creator == "Topology Zoo Toolset":
ank_utils.copy_attr_from(g_in, g_phy, "Network")
ank_utils.set_node_default(g_phy, Network=None)
g_phy.add_edges_from(g_in.edges(type="physical"))
# TODO: make this automatic if adding to the physical graph?
ank_utils.set_node_default(g_phy, use_ipv4=False, use_ipv6=False)
ank_utils.copy_attr_from(g_in, g_phy, "custom_config_global",
dst_attr="custom_config")
for node in g_phy:
if node['input'].custom_config_loopback_zero:
lo_zero_config = node['input'].custom_config_loopback_zero
node.loopback_zero.custom_config = lo_zero_config
custom_config_phy_ints = node['input'].custom_config_phy_ints
for interface in node:
if custom_config_phy_ints:
interface.custom_config = custom_config_phy_ints
specified_id = interface['input'].get("specified_id")
if specified_id:
interface.specified_id = specified_id # map across
#TODO: tidy this code up
for node in g_phy:
for interface in node:
remote_edges = interface.edges()
if len(remote_edges):
interface.description = 'to %s' \
% remote_edges[0].dst.label
def build_ipv4(anm, infrastructure=True):
"""Builds IPv4 graph"""
import autonetkit.plugins.ipv4 as ipv4
g_ipv4 = anm.add_overlay("ipv4")
g_ip = anm['ip']
g_in = anm['input']
g_ipv4.add_nodes_from(
g_ip, retain="collision_domain") # retain if collision domain or not
# Copy ASN attribute chosen for collision domains (used in alloc algorithm)
ank_utils.copy_attr_from(g_ip, g_ipv4, "asn",
nbunch = g_ipv4.nodes("collision_domain"))
g_ipv4.add_edges_from(g_ip.edges())
# check if ip ranges have been specified on g_in
infra_block, loopback_block, vrf_loopback_block = extract_ipv4_blocks(anm)
# See if IP addresses specified on each interface
l3_devices = [d for d in g_in if d.device_type in ("router", "server")]
manual_alloc_devices = set()
for device in l3_devices:
physical_interfaces = list(device.physical_interfaces)
if all(interface.ipv4_address for interface in physical_interfaces
if interface.is_bound ):
manual_alloc_devices.add(device) # add as a manual allocated device
if manual_alloc_devices == set(l3_devices):
manual_alloc_ipv4_infrastructure = True
else:
manual_alloc_ipv4_infrastructure = False
#TODO: need to set allocate_ipv4 by default in the readers
if manual_alloc_ipv4_infrastructure:
manual_ipv4_infrastructure_allocation(anm)
else:
ipv4.allocate_infra(g_ipv4, infra_block)
if g_in.data.alloc_ipv4_loopbacks is False:
manual_ipv4_loopback_allocation(anm)
else:
ipv4.allocate_loopbacks(g_ipv4, loopback_block)
#TODO: need to also support secondary_loopbacks for IPv6
#TODO: only call if secondaries are set
ipv4.allocate_vrf_loopbacks(g_ipv4, vrf_loopback_block)
#TODO: replace this with direct allocation to interfaces in ip alloc plugin
for node in g_ipv4.nodes("is_l3device"):
node.loopback_zero.ip_address = node.loopback
def build_phy(anm):
"""Build physical overlay"""
g_in = anm['input']
g_phy = anm['phy']
g_phy.data.enable_routing = g_in.data.enable_routing
if g_phy.data.enable_routing is None:
g_in.data.enable_routing = True # default if not set
g_phy.add_nodes_from(g_in,
retain=[
'label', 'update', 'device_type', 'asn',
'specified_int_names', 'x', 'y', 'device_subtype',
'platform', 'host', 'syntax'
])
if g_in.data.Creator == "Topology Zoo Toolset":
ank_utils.copy_attr_from(g_in, g_phy, "Network")
ank_utils.set_node_default(g_phy, Network=None)
g_phy.add_edges_from(g_in.edges(type="physical"))
# TODO: make this automatic if adding to the physical graph?
ank_utils.set_node_default(g_phy, use_ipv4=False, use_ipv6=False)
ank_utils.copy_attr_from(g_in,
g_phy,
"custom_config_global",
dst_attr="custom_config")
for node in g_phy:
if node['input'].custom_config_loopback_zero:
lo_zero_config = node['input'].custom_config_loopback_zero
node.loopback_zero.custom_config = lo_zero_config
custom_config_phy_ints = node['input'].custom_config_phy_ints
for interface in node:
if custom_config_phy_ints:
interface.custom_config = custom_config_phy_ints
specified_id = interface['input'].get("specified_id")
if specified_id:
interface.specified_id = specified_id # map across
#TODO: tidy this code up
for node in g_phy:
for interface in node:
remote_edges = interface.edges()
if len(remote_edges):
interface.description = 'to %s' \
% remote_edges[0].dst.label
def apply_design_rules(anm):
g_in = anm['input']
build_phy(anm)
g_phy = anm['phy']
autonetkit.update_http(anm)
build_l3_connectivity(anm)
build_vrf(anm) # need to do before to add loopbacks before ip allocations
build_ip(anm) # ip infrastructure topology
#TODO: set defaults at the start, rather than inline, ie set g_in.data.address_family then use later
address_family = g_in.data.address_family or "v4" # default is v4
#TODO: can remove the infrastructure now create g_ip seperately
if address_family in ("v4", "dual_stack"):
build_ipv4(anm, infrastructure = True)
g_phy.update(g_phy, use_ipv4 = True)
else:
build_ipv4(anm, infrastructure = False)
#TODO: Create a collision domain overlay for ip addressing - l2 overlay?
if address_family in ("v6", "dual_stack"):
build_ipv6(anm)
g_phy.update(g_phy, use_ipv6 = True)
else:
anm.add_overlay("ipv6") # placeholder for compiler logic
default_igp = g_in.data.igp or "ospf"
non_igp_nodes = [n for n in g_in if not n.igp]
#TODO: should this be modifying g_in?
g_in.update(non_igp_nodes, igp=default_igp) # store igp onto each node
ank_utils.copy_attr_from(g_in, g_phy, "include_csr")
build_ospf(anm)
build_isis(anm)
build_bgp(anm)
autonetkit.update_http(anm)
# post-processing
mark_ebgp_vrf(anm)
build_ibgp_vpn_v4(anm) # build after bgp as is based on
#autonetkit.update_http(anm)
return anm
def build_ipv4(anm, infrastructure=True):
"""Builds IPv4 graph"""
g_ipv4 = anm.add_overlay("ipv4")
g_ip = anm["ip"]
g_in = anm["input"]
g_ipv4.add_nodes_from(g_ip, retain="collision_domain") # retain if collision domain or not
# Copy ASN attribute chosen for collision domains (used in alloc algorithm)
ank_utils.copy_attr_from(g_ip, g_ipv4, "asn", nbunch=g_ipv4.nodes("collision_domain"))
g_ipv4.add_edges_from(g_ip.edges())
autonetkit.update_http(anm)
# TODO: need to set allocate_ipv4 by default in the readers
if g_in.data.alloc_ipv4_infrastructure is False:
manual_ipv4_infrastructure_allocation(anm)
else:
import autonetkit.plugins.ipv4 as ipv4
ipv4.allocate_ips(g_ipv4, infrastructure=True, loopbacks=False)
# ank_utils.save(g_ipv4)
if g_in.data.alloc_ipv4_loopbacks is False:
manual_ipv4_loopback_allocation(anm)
else:
import autonetkit.plugins.ipv4 as ipv4
ipv4.allocate_ips(g_ipv4, infrastructure=False, loopbacks=True)
# ank_utils.save(g_ipv4)
# TODO: need to also support secondary_loopbacks for IPv6
ipv4.allocate_ips(g_ipv4, infrastructure=False, loopbacks=False, secondary_loopbacks=True)
autonetkit.update_http(anm)
# TODO: replace this with direct allocation to interfaces in ip alloc plugin
for node in g_ipv4.nodes("is_l3device"):
node.loopback_zero.ip_address = node.loopback
for interface in node:
edges = list(interface.edges())
if len(edges):
edge = edges[0] # first (only) edge
interface.ip_address = edge.ip_address
interface.subnet = edge.dst.subnet # from collision domain
# TODO: also map loopbacks to loopback interface 0
autonetkit.update_http(anm)
def build_phy(anm):
"""Build physical overlay"""
g_in = anm['input']
g_phy = anm['phy']
g_phy.data.enable_routing = g_in.data.enable_routing
if g_phy.data.enable_routing is None:
g_in.data.enable_routing = True # default if not set
g_phy.add_nodes_from(g_in, retain=['label', 'update', 'device_type', 'asn',
'specified_int_names',
'device_subtype', 'platform', 'host', 'syntax'])
if g_in.data.Creator == "Topology Zoo Toolset":
ank_utils.copy_attr_from(g_in, g_phy, "Network")
g_phy.add_edges_from(g_in.edges(type="physical"))
# TODO: make this automatic if adding to the physical graph?
if g_in.data.Creator == "Maestro":
g_phy.data.mgmt_interfaces_enabled = g_in.data.mgmt_interfaces_enabled
#TODO: remove this code now allocated externally
g_phy.data.mgmt_address_start = g_in.data.mgmt_address_start
g_phy.data.mgmt_address_end = g_in.data.mgmt_address_end
g_phy.data.mgmt_prefixlen = g_in.data.mgmt_prefixlen
g_phy.data.mgmt_prefixlen = g_in.data.mgmt_prefixlen
ank_utils.copy_attr_from(g_in, g_phy, "use_cdp")
ank_utils.copy_attr_from(g_in, g_phy, "use_onepk")
ank_utils.copy_attr_from(g_in, g_phy, "label_full")
ank_utils.copy_attr_from(g_in, g_phy, "indices")
g_phy.allocate_interfaces()
for node in g_phy:
for interface in node:
specified_id = interface['input'].get("specified_id")
if specified_id:
interface.specified_id = specified_id # map across
for node in g_phy.nodes("specified_int_names"):
for interface in node:
edge = interface.edges()[0]
directed_edge = anm['input_directed'].edge(edge)
interface.name = directed_edge.name
def build_eigrp(anm):
"""Build eigrp overlay"""
g_in = anm['input']
# add regardless, so allows quick check of node in anm['isis'] in compilers
g_l3 = anm['layer3']
g_eigrp = anm.add_overlay("eigrp")
g_phy = anm['phy']
if not anm['phy'].data.enable_routing:
g_eigrp.log.info("Routing disabled, not configuring EIGRP")
return
if not any(n.igp == "eigrp" for n in g_phy):
log.debug("No EIGRP nodes")
return
eigrp_nodes = [n for n in g_l3 if n['phy'].igp == "eigrp"]
g_eigrp.add_nodes_from(eigrp_nodes)
g_eigrp.add_edges_from(g_l3.edges(), warn=False)
ank_utils.copy_int_attr_from(g_l3, g_eigrp, "multipoint")
ank_utils.copy_attr_from(g_in,
g_eigrp,
"custom_config_eigrp",
dst_attr="custom_config")
# Merge and explode switches
ank_utils.aggregate_nodes(g_eigrp, g_eigrp.switches())
exploded_edges = ank_utils.explode_nodes(g_eigrp, g_eigrp.switches())
for edge in exploded_edges:
edge.multipoint = True
g_eigrp.remove_edges_from(
[link for link in g_eigrp.edges() if link.src.asn != link.dst.asn])
for node in g_eigrp:
node.process_id = node.asn
for link in g_eigrp.edges():
link.metric = 1 # default
for edge in g_eigrp.edges():
for interface in edge.interfaces():
interface.metric = edge.metric
interface.multipoint = edge.multipoint
def build_eigrp(anm):
"""Build eigrp overlay"""
g_in = anm['input']
# add regardless, so allows quick check of node in anm['isis'] in compilers
g_l3 = anm['layer3']
g_eigrp = anm.add_overlay("eigrp")
g_phy = anm['phy']
if not anm['phy'].data.enable_routing:
g_eigrp.log.info("Routing disabled, not configuring EIGRP")
return
if not any(n.igp == "eigrp" for n in g_phy):
log.debug("No EIGRP nodes")
return
eigrp_nodes = [n for n in g_l3 if n['phy'].igp == "eigrp"]
g_eigrp.add_nodes_from(eigrp_nodes)
g_eigrp.add_edges_from(g_l3.edges(), warn=False)
ank_utils.copy_int_attr_from(g_l3, g_eigrp, "multipoint")
ank_utils.copy_attr_from(
g_in, g_eigrp, "custom_config_eigrp", dst_attr="custom_config")
# Merge and explode switches
ank_utils.aggregate_nodes(g_eigrp, g_eigrp.switches())
exploded_edges = ank_utils.explode_nodes(g_eigrp,
g_eigrp.switches())
for edge in exploded_edges:
edge.multipoint = True
g_eigrp.remove_edges_from(
[link for link in g_eigrp.edges() if link.src.asn != link.dst.asn])
for node in g_eigrp:
node.process_id = node.asn
for link in g_eigrp.edges():
link.metric = 1 # default
for edge in g_eigrp.edges():
for interface in edge.interfaces():
interface.metric = edge.metric
interface.multipoint = edge.multipoint
def apply_design_rules(anm):
g_in = anm['input']
build_phy(anm)
g_phy = anm['phy']
build_vrf(anm) # need to do before to add loopbacks before ip allocations
build_ip(anm) # ip infrastructure topology
#TODO: set defaults at the start, rather than inline, ie set g_in.data.address_family then use later
address_family = g_in.data.address_family or "v4" # default is v4
#TODO: can remove the infrastructure now create g_ip seperately
if address_family in ("v4", "dual_stack"):
build_ipv4(anm, infrastructure=True)
g_phy.update(g_phy, use_ipv4=True)
else:
build_ipv4(anm, infrastructure=False)
#TODO: Create a collision domain overlay for ip addressing - l2 overlay?
if address_family in ("v6", "dual_stack"):
build_ipv6(anm)
g_phy.update(g_phy, use_ipv6=True)
else:
anm.add_overlay("ipv6") # placeholder for compiler logic
default_igp = g_in.data.igp or "ospf"
non_igp_nodes = [n for n in g_in if not n.igp]
#TODO: should this be modifying g_in?
g_in.update(non_igp_nodes, igp=default_igp) # store igp onto each node
ank_utils.copy_attr_from(g_in, g_phy, "include_csr")
build_ospf(anm)
build_isis(anm)
build_bgp(anm)
autonetkit.update_http(anm)
# post-processing
mark_ebgp_vrf(anm)
build_ibgp_vpn_v4(anm) # build after bgp as is based on
#autonetkit.update_http(anm)
return anm
def build_phy(anm):
"""Build physical overlay"""
g_in = anm['input']
g_phy = anm['phy']
g_phy.add_nodes_from(g_in, retain=['label', 'update', 'device_type', 'asn',
'device_subtype', 'platform', 'host', 'syntax'])
if g_in.data.Creator == "Topology Zoo Toolset":
ank_utils.copy_attr_from(g_in, g_phy, "Network")
g_phy.add_edges_from(g_in.edges(type="physical"))
# TODO: make this automatic if adding to the physical graph?
g_phy.allocate_interfaces()
specified_int_names = g_in.data.specified_int_names
if specified_int_names:
for node in g_phy:
for interface in node:
edge = interface.edges()[0]
directed_edge = anm['input_directed'].edge(edge)
interface.name = directed_edge.name
def build_isis(anm):
"""Build isis overlay"""
g_in = anm['input']
# add regardless, so allows quick check of node in anm['isis'] in compilers
g_l3 = anm['layer3']
g_phy = anm['phy']
g_isis = anm.add_overlay("isis")
if not anm['phy'].data.enable_routing:
g_isis.log.info("Routing disabled, not configuring ISIS")
return
if not any(n.igp == "isis" for n in g_phy):
g_isis.log.debug("No ISIS nodes")
return
isis_nodes = [n for n in g_l3 if n['phy'].igp == "isis"]
g_isis.add_nodes_from(isis_nodes)
g_isis.add_edges_from(g_l3.edges(), warn=False)
ank_utils.copy_int_attr_from(g_l3, g_isis, "multipoint")
ank_utils.copy_attr_from(g_in,
g_isis,
"custom_config_isis",
dst_attr="custom_config")
g_isis.remove_edges_from(
[link for link in g_isis.edges() if link.src.asn != link.dst.asn])
build_network_entity_title(anm)
for node in g_isis.routers():
node.process_id = node.asn
for link in g_isis.edges():
link.metric = 1 # default
for edge in g_isis.edges():
for interface in edge.interfaces():
interface.metric = edge.metric
interface.multipoint = edge.multipoint
def build_ipv4(anm, infrastructure=True):
"""Builds IPv4 graph"""
import autonetkit.plugins.ipv4 as ipv4
g_ipv4 = anm.add_overlay("ipv4")
g_ip = anm['ip']
g_in = anm['input']
g_ipv4.add_nodes_from(
g_ip, retain="collision_domain") # retain if collision domain or not
# Copy ASN attribute chosen for collision domains (used in alloc algorithm)
ank_utils.copy_attr_from(g_ip,
g_ipv4,
"asn",
nbunch=g_ipv4.nodes("collision_domain"))
g_ipv4.add_edges_from(g_ip.edges())
# check if ip ranges have been specified on g_in
infra_block, loopback_block, vrf_loopback_block = extract_ipv4_blocks(anm)
#TODO: need to set allocate_ipv4 by default in the readers
if g_in.data.alloc_ipv4_infrastructure is False:
manual_ipv4_infrastructure_allocation(anm)
else:
ipv4.allocate_infra(g_ipv4, infra_block)
if g_in.data.alloc_ipv4_loopbacks is False:
manual_ipv4_loopback_allocation(anm)
else:
ipv4.allocate_loopbacks(g_ipv4, loopback_block)
#TODO: need to also support secondary_loopbacks for IPv6
ipv4.allocate_vrf_loopbacks(g_ipv4, vrf_loopback_block)
#TODO: replace this with direct allocation to interfaces in ip alloc plugin
for node in g_ipv4.nodes("is_l3device"):
node.loopback_zero.ip_address = node.loopback
for interface in node:
edges = list(interface.edges())
if len(edges):
edge = edges[0] # first (only) edge
interface.ip_address = edge.ip_address
interface.subnet = edge.dst.subnet # from collision domain
def build_phy(anm):
"""Build physical overlay"""
g_in = anm['input']
g_phy = anm['phy']
g_phy.add_nodes_from(g_in,
retain=[
'label', 'update', 'device_type', 'asn',
'specified_int_names', 'device_subtype',
'platform', 'host', 'syntax'
])
if g_in.data.Creator == "Topology Zoo Toolset":
ank_utils.copy_attr_from(g_in, g_phy, "Network")
if g_in.data.Creator == "Maestro":
g_phy.data.mgmt_interfaces_enabled = g_in.data.mgmt_interfaces_enabled
g_phy.data.mgmt_address_start = g_in.data.mgmt_address_start
g_phy.data.mgmt_address_end = g_in.data.mgmt_address_end
g_phy.data.mgmt_prefixlen = g_in.data.mgmt_prefixlen
ank_utils.copy_attr_from(g_in, g_phy, "use_cdp")
ank_utils.copy_attr_from(g_in, g_phy, "use_onepk")
g_phy.add_edges_from(g_in.edges(type="physical"))
# TODO: make this automatic if adding to the physical graph?
g_phy.allocate_interfaces()
for node in g_phy.nodes("specified_int_names"):
for interface in node:
edge = interface.edges()[0]
directed_edge = anm['input_directed'].edge(edge)
interface.name = directed_edge.name
def build_phy(anm):
"""Build physical overlay"""
g_in = anm['input']
g_phy = anm['phy']
g_phy.add_nodes_from(g_in, retain=['label', 'update', 'device_type', 'asn',
'specified_int_names',
'device_subtype', 'platform', 'host', 'syntax'])
if g_in.data.Creator == "Topology Zoo Toolset":
ank_utils.copy_attr_from(g_in, g_phy, "Network")
if g_in.data.Creator == "Maestro":
g_phy.data.mgmt_interfaces_enabled = g_in.data.mgmt_interfaces_enabled
g_phy.data.mgmt_address_start = g_in.data.mgmt_address_start
g_phy.data.mgmt_address_end = g_in.data.mgmt_address_end
g_phy.data.mgmt_prefixlen = g_in.data.mgmt_prefixlen
ank_utils.copy_attr_from(g_in, g_phy, "use_cdp")
ank_utils.copy_attr_from(g_in, g_phy, "use_onepk")
g_phy.add_edges_from(g_in.edges(type="physical"))
# TODO: make this automatic if adding to the physical graph?
g_phy.allocate_interfaces()
for node in g_phy.nodes("specified_int_names"):
for interface in node:
edge = interface.edges()[0]
directed_edge = anm['input_directed'].edge(edge)
interface.name = directed_edge.name
def build_mcast(anm):
g_in = anm['input']
g_phy = anm['phy']
g_l3 = anm['layer3']
g_mcast = anm.add_overlay("mcast")
g_mcast.add_nodes_from(g_l3, retain=['label', 'update', 'device_type', 'devsubtype',
'asn', 'specified_int_names',
'profile', 'vxlan_vni_configured'])
g_mcast.add_edges_from(g_l3.edges())
ank_utils.copy_attr_from(g_in, g_mcast, "multicast")
nodes_to_be_removed =[]
for node in g_mcast:
if node.multicast is None or node.multicast is False:
nodes_to_be_removed.append(node)
g_mcast.remove_nodes_from(nodes_to_be_removed)
for node in g_mcast:
for interface in node.interfaces():
if interface.is_bound:
interface.pim = 1
def build_isis(anm):
"""Build isis overlay"""
g_in = anm['input']
# add regardless, so allows quick check of node in anm['isis'] in compilers
g_l3 = anm['layer3']
g_phy = anm['phy']
g_isis = anm.add_overlay("isis")
if not anm['phy'].data.enable_routing:
g_isis.log.info("Routing disabled, not configuring ISIS")
return
if not any(n.igp == "isis" for n in g_phy):
g_isis.log.debug("No ISIS nodes")
return
isis_nodes = [n for n in g_l3 if n['phy'].igp == "isis"]
g_isis.add_nodes_from(isis_nodes)
g_isis.add_edges_from(g_l3.edges(), warn=False)
ank_utils.copy_int_attr_from(g_l3, g_isis, "multipoint")
ank_utils.copy_attr_from(
g_in, g_isis, "custom_config_isis", dst_attr="custom_config")
g_isis.remove_edges_from(
[link for link in g_isis.edges() if link.src.asn != link.dst.asn])
build_network_entity_title(anm)
for node in g_isis.routers():
node.process_id = node.asn
for link in g_isis.edges():
link.metric = 1 # default
for edge in g_isis.edges():
for interface in edge.interfaces():
interface.metric = edge.metric
interface.multipoint = edge.multipoint
def build_ipv4(anm, infrastructure=True):
"""Builds IPv4 graph"""
import autonetkit.plugins.ipv4 as ipv4
g_ipv4 = anm.add_overlay("ipv4")
g_ip = anm['ip']
g_in = anm['input']
g_ipv4.add_nodes_from(
g_ip, retain="collision_domain") # retain if collision domain or not
# Copy ASN attribute chosen for collision domains (used in alloc algorithm)
ank_utils.copy_attr_from(g_ip, g_ipv4, "asn", nbunch = g_ipv4.nodes("collision_domain"))
g_ipv4.add_edges_from(g_ip.edges())
# check if ip ranges have been specified on g_in
infra_block, loopback_block, vrf_loopback_block = extract_ipv4_blocks(anm)
#TODO: need to set allocate_ipv4 by default in the readers
if g_in.data.alloc_ipv4_infrastructure is False:
manual_ipv4_infrastructure_allocation(anm)
else:
ipv4.allocate_infra(g_ipv4, infra_block)
if g_in.data.alloc_ipv4_loopbacks is False:
manual_ipv4_loopback_allocation(anm)
else:
ipv4.allocate_loopbacks(g_ipv4, loopback_block)
#TODO: need to also support secondary_loopbacks for IPv6
ipv4.allocate_vrf_loopbacks(g_ipv4, vrf_loopback_block)
#TODO: replace this with direct allocation to interfaces in ip alloc plugin
for node in g_ipv4.nodes("is_l3device"):
node.loopback_zero.ip_address = node.loopback
for interface in node:
edges = list(interface.edges())
if len(edges):
edge = edges[0] # first (only) edge
interface.ip_address = edge.ip_address
interface.subnet = edge.dst.subnet # from collision domain
def build_isis(anm):
"""Build isis overlay"""
g_in = anm['input']
# add regardless, so allows quick check of node in anm['isis'] in compilers
g_l3 = anm['layer3']
g_isis = anm.add_overlay("isis")
if not anm['phy'].data.enable_routing:
g_isis.log.info("Routing disabled, not configuring ISIS")
return
if not any(n.igp == "isis" for n in g_in):
g_isis.log.debug("No ISIS nodes")
return
g_isis.add_nodes_from(g_l3)
g_isis.add_edges_from(g_l3.edges())
ank_utils.copy_int_attr_from(g_l3, g_isis, "multipoint")
g_ipv4 = anm['ipv4']
ank_utils.copy_attr_from(g_in, g_isis, "custom_config_isis", dst_attr="custom_config")
g_isis.remove_edges_from(
[link for link in g_isis.edges() if link.src.asn != link.dst.asn])
for node in g_isis.routers():
ip_node = g_ipv4.node(node)
node.net = ip_to_net_ent_title_ios(ip_node.loopback)
node.process_id = node.asn
for link in g_isis.edges():
link.metric = 1 # default
for edge in g_isis.edges():
for interface in edge.interfaces():
interface.metric = edge.metric
interface.multipoint = edge.multipoint
def build_phy(anm):
"""Build physical overlay"""
g_in = anm['input']
g_phy = anm['phy']
g_phy.data.enable_routing = g_in.data.enable_routing
if g_phy.data.enable_routing is None:
g_in.data.enable_routing = True # default if not set
g_phy.add_nodes_from(g_in, retain=['label', 'update', 'device_type',
'asn', 'specified_int_names', 'x', 'y',
'device_subtype', 'platform', 'host', 'syntax'])
if g_in.data.Creator == "Topology Zoo Toolset":
ank_utils.copy_attr_from(g_in, g_phy, "Network")
ank_utils.set_node_default(g_phy, Network=None)
g_phy.add_edges_from(g_in.edges(type="physical"))
# TODO: make this automatic if adding to the physical graph?
ank_utils.set_node_default(g_phy, use_ipv4=False, use_ipv6=False)
ank_utils.copy_attr_from(g_in, g_phy, "custom_config_global",
dst_attr="custom_config")
for node in g_phy:
if node['input'].custom_config_loopback_zero:
lo_zero_config = node['input'].custom_config_loopback_zero
node.loopback_zero.custom_config = lo_zero_config
custom_config_phy_ints = node['input'].custom_config_phy_ints
for interface in node:
if custom_config_phy_ints:
interface.custom_config = custom_config_phy_ints
specified_id = interface['input'].get("specified_id")
if specified_id:
interface.specified_id = specified_id # map across
remove_parallel_switch_links(anm)
def build(input_graph):
"""Main function to build network overlay topologies"""
anm = autonetkit.anm.AbstractNetworkModel()
input_undirected = nx.Graph(input_graph)
g_in = anm.add_overlay("input", graph=input_undirected)
anm.add_overlay("input_directed", graph=input_graph, directed=True)
# set defaults
if not g_in.data.specified_int_names:
# if not specified then automatically assign interface names
g_in.data.specified_int_names = False
import autonetkit.plugins.graph_product as graph_product
graph_product.expand(g_in) # apply graph products if relevant
expand_fqdn = False
# TODO: make this set from config and also in the input file
if expand_fqdn and len(ank_utils.unique_attr(g_in, "asn")) > 1:
# Multiple ASNs set, use label format device.asn
anm.set_node_label(".", ["label", "pop", "asn"])
g_in.update(g_in.nodes("is_router", platform="junosphere"), syntax="junos")
g_in.update(g_in.nodes("is_router", platform="dynagen"), syntax="ios")
g_in.update(g_in.nodes("is_router", platform="netkit"), syntax="quagga")
g_graphics = anm.add_overlay("graphics") # plotting data
g_graphics.add_nodes_from(g_in, retain=["x", "y", "device_type", "device_subtype", "pop", "asn"])
build_phy(anm)
autonetkit.update_http(anm)
g_phy = anm["phy"]
build_vrf(anm) # need to do before to add loopbacks before ip allocations
build_ip(anm) # ip infrastructure topology
autonetkit.update_http(anm)
address_family = g_in.data.address_family or "v4" # default is v4
# TODO: can remove the infrastructure now create g_ip seperately
if address_family in ("v4", "dual_stack"):
build_ipv4(anm, infrastructure=True)
g_phy.update(g_phy, use_ipv4=True)
else:
build_ipv4(anm, infrastructure=False)
# TODO: Create a collision domain overlay for ip addressing - l2 overlay?
if address_family in ("v6", "dual_stack"):
build_ipv6(anm)
g_phy.update(g_phy, use_ipv6=True)
default_igp = g_in.data.igp or "ospf"
non_igp_nodes = [n for n in g_in if not n.igp]
# TODO: should this be modifying g_in?
g_in.update(non_igp_nodes, igp=default_igp) # store igp onto each node
anm.add_overlay("ospf")
anm.add_overlay("isis")
ank_utils.copy_attr_from(g_in, g_phy, "include_csr")
build_ospf(anm)
build_isis(anm)
build_bgp(anm)
autonetkit.update_http(anm)
return anm
def build_ipv4(anm, infrastructure=True):
"""Builds IPv4 graph"""
import autonetkit.plugins.ipv4 as ipv4
import netaddr
g_ipv4 = anm.add_overlay('ipv4')
g_ip = anm['ip']
g_in = anm['input']
# retain if collision domain or not
g_ipv4.add_nodes_from(g_ip, retain=['label', 'allocate',
'broadcast_domain'])
# Copy ASN attribute chosen for collision domains (used in alloc algorithm)
ank_utils.copy_attr_from(
g_ip, g_ipv4, 'asn', nbunch=g_ipv4.nodes('broadcast_domain'))
# work around until fall-through implemented
vswitches = [n for n in g_ip.nodes()
if n['layer2'].device_type == "switch"
and n['layer2'].device_subtype == "virtual"]
ank_utils.copy_attr_from(g_ip, g_ipv4, 'asn', nbunch=vswitches)
g_ipv4.add_edges_from(g_ip.edges())
# check if ip ranges have been specified on g_in
(infra_block, loopback_block, vrf_loopback_block) = \
extract_ipv4_blocks(anm)
# TODO: don't present if using manual allocation
if any(i for n in g_ip.nodes() for i in
n.loopback_interfaces() if not i.is_loopback_zero):
block_message = "IPv4 Secondary Loopbacks: %s" % vrf_loopback_block
log.info(block_message)
# See if IP addresses specified on each interface
# do we need this still? in ANM? - differnt because input graph.... but
# can map back to self overlay first then phy???
l3_devices = [d for d in g_in if d.device_type in ('router', 'server')]
# TODO: need to account for devices whose interfaces are in only e.g. vpns
manual_alloc_devices = set()
for device in l3_devices:
physical_interfaces = list(device.physical_interfaces())
allocated = list(
interface.ipv4_address for interface in physical_interfaces
if interface.is_bound and interface['ipv4'].allocate is not False
and interface['ipv4'].is_bound)
if all(interface.ipv4_address for interface in
physical_interfaces if interface.is_bound
and interface['ip'].allocate is not False
and interface['ip'].is_bound):
# add as a manual allocated device
manual_alloc_devices.add(device)
if manual_alloc_devices == set(l3_devices):
manual_alloc_ipv4_infrastructure = True
else:
log.info("Allocating from IPv4 infrastructure block: %s" % infra_block)
manual_alloc_ipv4_infrastructure = False
# warn if any set
allocated = []
unallocated = []
for node in l3_devices:
# TODO: make these inverse sets
allocated += sorted([i for i in node.physical_interfaces()
if i.is_bound and i.ipv4_address])
unallocated += sorted([i for i in node.physical_interfaces()
if i.is_bound and not i.ipv4_address
and i['ipv4'].is_bound])
# TODO: what if IP is set but not a prefix?
if len(allocated):
# TODO: if set is > 50% of nodes then list those that are NOT set
log.warning(
"Using automatic IPv4 interface allocation. IPv4 interface addresses specified on interfaces %s will be ignored." % allocated)
# TODO: need to set allocate_ipv4 by default in the readers
if manual_alloc_ipv4_infrastructure:
manual_ipv4_infrastructure_allocation(anm)
else:
ipv4.allocate_infra(g_ipv4, infra_block)
if g_in.data.alloc_ipv4_loopbacks is False:
manual_ipv4_loopback_allocation(anm)
else:
log.info("Allocating from IPv4 loopback block: %s" % loopback_block)
# Check if some nodes are allocated
allocated = sorted([n for n in g_ip if n['input'].loopback_v4])
unallocated = sorted([n for n in g_ip if not n['input'].loopback_v4])
if len(allocated):
log.warning(
"Using automatic IPv4 loopback allocation. IPv4 loopback addresses specified on nodes %s will be ignored." % allocated)
# TODO: if set is > 50% of nodes then list those that are NOT set
ipv4.allocate_loopbacks(g_ipv4, loopback_block)
# TODO: need to also support secondary_loopbacks for IPv6
# TODO: only call if secondaries are set
ipv4.allocate_secondary_loopbacks(g_ipv4, vrf_loopback_block)
# TODO: replace this with direct allocation to interfaces in ip alloc plugin
# TODO: add option for nonzero interfaces on node - ie
# node.secondary_loopbacks
for node in g_ipv4:
node.static_routes = []
for node in g_ipv4.routers():
node.loopback_zero.ip_address = node.loopback
node.loopback_zero.subnet = netaddr.IPNetwork("%s/32" % node.loopback)
for interface in node.loopback_interfaces():
if not interface.is_loopback_zero:
# TODO: fix this inconsistency elsewhere
interface.ip_address = interface.loopback
def build_bgp(anm):
"""Build iBGP end eBGP overlays"""
# eBGP
g_in = anm['input']
g_phy = anm['phy']
if not anm['phy'].data.enable_routing:
log.info("Routing disabled, not configuring BGP")
return
build_ebgp(anm)
build_ebgp_v4(anm)
build_ebgp_v6(anm)
"""TODO: remove from here once compiler updated"""
g_bgp = anm.add_overlay("bgp", directed=True)
g_bgp.add_nodes_from(g_in.nodes("is_router"))
ebgp_edges = [edge for edge in g_in.edges() if not edge.attr_equal("asn")]
g_bgp.add_edges_from(ebgp_edges, bidirectional=True, type='ebgp')
#TODO: why don't we include edge_id here
ebgp_switches = [n for n in g_in.nodes("is_switch")
if not ank_utils.neigh_equal(g_phy, n, "asn")]
g_bgp.add_nodes_from(ebgp_switches, retain=['asn'])
log.debug("eBGP switches are %s" % ebgp_switches)
g_bgp.add_edges_from((e for e in g_in.edges()
if e.src in ebgp_switches or e.dst in ebgp_switches), bidirectional=True, type='ebgp')
ank_utils.aggregate_nodes(g_bgp, ebgp_switches, retain="edge_id")
ebgp_switches = list(g_bgp.nodes("is_switch")) # need to recalculate as may have aggregated
log.debug("aggregated eBGP switches are %s" % ebgp_switches)
exploded_edges = ank_utils.explode_nodes(g_bgp, ebgp_switches,
retain="edge_id")
same_asn_edges = []
for edge in exploded_edges:
if edge.src.asn == edge.dst.asn:
same_asn_edges.append(edge)
else:
edge.multipoint = True
"""TODO: remove up to here once compiler updated"""
g_bgp.remove_edges_from(same_asn_edges)
# now iBGP
ank_utils.copy_attr_from(g_in, g_bgp, "ibgp_level")
ank_utils.copy_attr_from(g_in, g_bgp, "ibgp_l2_cluster")
ank_utils.copy_attr_from(g_in, g_bgp, "ibgp_l3_cluster")
for node in g_bgp:
# set defaults
if node.ibgp_level is None:
node.ibgp_level = 1
if node.ibgp_level == "None": # if unicode string from yEd
node.ibgp_level = 1
#TODO CHECK FOR IBGP NONE
node.ibgp_level = int(node.ibgp_level) # ensure is numeric
if not node.ibgp_l2_cluster or node.ibgp_l2_cluster == "None":
# ibgp_l2_cluster defaults to region
node.ibgp_l2_cluster = node.region or "default_l2_cluster"
if not node.ibgp_l3_cluster or node.ibgp_l3_cluster == "None":
# ibgp_l3_cluster defaults to ASN
node.ibgp_l3_cluster = node.asn
for asn, devices in ank_utils.groupby("asn", g_bgp):
# group by nodes in phy graph
routers = list(g_bgp.node(n) for n in devices if n.is_router)
# list of nodes from bgp graph
ibgp_levels = {int(r.ibgp_level) for r in routers}
max_level = max(ibgp_levels)
# all possible edge src/dst pairs
ibgp_routers = [r for r in routers if r.ibgp_level > 0]
all_pairs = [(s, t) for s in ibgp_routers for t in ibgp_routers if s != t]
if max_level == 3:
up_links, down_links, over_links = three_tier_ibgp_edges(ibgp_routers)
elif max_level == 2:
#TODO: check when this is reached - as RR is not HRR.... due to naming/levels mapping
up_links, down_links, over_links = build_two_tier_ibgp(ibgp_routers)
elif max_level == 1:
up_links = []
down_links = []
over_links = [(s, t) for (s, t) in all_pairs
if s.ibgp_l3_cluster == t.ibgp_l3_cluster
and s.ibgp_l2_cluster == t.ibgp_l2_cluster
]
else:
# no iBGP
up_links = []
down_links = []
over_links = []
if max_level > 0:
g_bgp.add_edges_from(up_links, type='ibgp', direction='up')
g_bgp.add_edges_from(down_links, type='ibgp', direction='down')
g_bgp.add_edges_from(over_links, type='ibgp', direction='over')
else:
log.debug("No iBGP routers in %s" % asn)
# and set label back
ibgp_label_to_level = {
0: "None", # Explicitly set role to "None" -> Not in iBGP
3: "RR",
1: "RRC",
2: "HRR",
}
for node in g_bgp:
node.ibgp_role = ibgp_label_to_level[node.ibgp_level]
ebgp_nodes = [d for d in g_bgp if any(
edge.type == 'ebgp' for edge in d.edges())]
g_bgp.update(ebgp_nodes, ebgp=True)
for ebgp_edge in g_bgp.edges(type = "ebgp"):
for interface in ebgp_edge.interfaces():
interface.ebgp = True
for edge in g_bgp.edges(type='ibgp'):
# TODO: need interface querying/selection. rather than hard-coded ids
edge.bind_interface(edge.src, 0)
#TODO: need to initialise interface zero to be a loopback rather than physical type
for node in g_bgp:
for interface in node.interfaces():
interface.multipoint = any(e.multipoint for e in interface.edges())
build_ibgp_v4(anm)
build_ibgp_v6(anm)
g_phy.update(g_phy, use_ipv4=False)
# TODO: Create collision domain overlay for ip addressing - l2 overlay?
if address_family == "None":
log.info("IP addressing disabled, not allocating IPv6")
anm.add_overlay("ipv6") # create empty so rest of code follows
g_phy.update(g_phy, use_ipv6=False)
elif address_family in ("v6", "dual_stack"):
build_ipv6(anm)
g_phy.update(g_phy, use_ipv6=True)
else:
anm.add_overlay("ipv6") # placeholder for compiler logic
default_igp = g_in.data.igp or "ospf"
ank_utils.set_node_default(g_in, igp=default_igp)
ank_utils.copy_attr_from(g_in, g_phy, "igp")
ank_utils.copy_attr_from(g_in, g_phy, "include_csr")
try:
from autonetkit_cisco import build_network as cisco_build_network
except ImportError, error:
log.debug("Unable to load autonetkit_cisco %s" % error)
else:
cisco_build_network.pre_design(anm)
# log.info("Building IGP")
from autonetkit.design.igp import build_igp
build_igp(anm)
# log.info("Building BGP")
def build_ospf(anm):
"""
Build OSPF graph.
Allowable area combinations:
0 -> 0
0 -> x (x!= 0)
x -> 0 (x!= 0)
x -> x (x != 0)
Not-allowed:
x -> x (x != y != 0)
#TODO: build check that verifies these rules
"""
import netaddr
g_in = anm['input']
# add regardless, so allows quick check of node in anm['ospf'] in compilers
g_ospf = anm.add_overlay("ospf")
if not any(n.igp == "ospf" for n in g_in):
log.debug("No OSPF nodes")
return
g_ospf.add_nodes_from(g_in.nodes("is_router", igp="ospf"), retain=['asn'])
g_ospf.add_nodes_from(g_in.nodes("is_switch"), retain=['asn'])
g_ospf.add_edges_from(g_in.edges(), retain=['edge_id'])
ank_utils.copy_attr_from(g_in, g_ospf, "ospf_area", dst_attr="area")
ank_utils.copy_edge_attr_from(g_in,
g_ospf,
"ospf_cost",
dst_attr="cost",
type=float)
ank_utils.aggregate_nodes(g_ospf,
g_ospf.nodes("is_switch"),
retain="edge_id")
exploded_edges = ank_utils.explode_nodes(g_ospf,
g_ospf.nodes("is_switch"),
retain="edge_id")
for edge in exploded_edges:
edge.multipoint = True
g_ospf.remove_edges_from([
link for link in g_ospf.edges() if link.src.asn != link.dst.asn
]) # remove inter-AS links
area_zero_ip = netaddr.IPAddress("0.0.0.0")
area_zero_int = 0
area_zero_ids = {area_zero_ip, area_zero_int}
default_area = area_zero_int
if any(router.area == "0.0.0.0" for router in g_ospf):
# string comparison as hasn't yet been cast to IPAddress
default_area = area_zero_ip
for router in g_ospf:
if not router.area or router.area == "None":
router.area = default_area
# check if 0.0.0.0 used anywhere, if so then use 0.0.0.0 as format
else:
try:
router.area = int(router.area)
except ValueError:
try:
router.area = netaddr.IPAddress(router.area)
except netaddr.core.AddrFormatError:
log.warning("Invalid OSPF area %s for %s. Using default"
" of %s" % (router.area, router, default_area))
router.area = default_area
for router in g_ospf:
# and set area on interface
for edge in router.edges():
if edge.area:
continue # allocated (from other "direction", as undirected)
if router.area == edge.dst.area:
edge.area = router.area # intra-area
continue
if router.area in area_zero_ids or edge.dst.area in area_zero_ids:
# backbone to other area
if router.area in area_zero_ids:
# router in backbone, use other area
edge.area = edge.dst.area
else:
# router not in backbone, use its area
edge.area = router.area
for router in g_ospf:
areas = {edge.area for edge in router.edges()}
router.areas = list(areas) # edges router participates in
if len(areas) in area_zero_ids:
router.type = "backbone" # no ospf edges (eg single node in AS)
elif len(areas) == 1:
# single area: either backbone (all 0) or internal (all nonzero)
if len(areas & area_zero_ids):
# intersection has at least one element -> router has area zero
router.type = "backbone"
else:
router.type = "internal"
else:
# multiple areas
if len(areas & area_zero_ids):
# intersection has at least one element -> router has area zero
router.type = "backbone ABR"
else:
log.warning(
"%s spans multiple areas but is not a member of area 0" %
router)
router.type = "INVALID"
if (any(area_zero_int in router.areas for router in g_ospf)
and any(area_zero_ip in router.areas for router in g_ospf)):
log.warning("Using both area 0 and area 0.0.0.0")
for link in g_ospf.edges():
if not link.cost:
link.cost = 1
# map areas and costs onto interfaces
#TODO: later map them directly rather than with edges - this is part of the transition
for edge in g_ospf.edges():
for interface in edge.interfaces():
interface.cost = edge.cost
interface.area = edge.area
interface.multipoint = edge.multipoint
for router in g_ospf:
router.loopback_zero.area = router.area
router.loopback_zero.cost = 0
def build_ospf(anm):
"""
Build OSPF graph.
Allowable area combinations:
0 -> 0
0 -> x (x!= 0)
x -> 0 (x!= 0)
x -> x (x != 0)
Not-allowed:
x -> x (x != y != 0)
"""
import netaddr
g_in = anm['input']
g_l3 = anm['layer3']
g_phy = anm['phy']
# add regardless, so allows quick check of node in anm['ospf'] in compilers
g_ospf = anm.add_overlay("ospf")
if not anm['phy'].data.enable_routing:
g_ospf.log.info("Routing disabled, not configuring OSPF")
return
if not any(n.igp == "ospf" for n in g_phy):
g_ospf.log.debug("No OSPF nodes")
return
ospf_nodes = [n for n in g_l3 if n['phy'].igp == "ospf"]
g_ospf.add_nodes_from(ospf_nodes)
g_ospf.add_edges_from(g_l3.edges(), warn=False)
ank_utils.copy_int_attr_from(g_l3, g_ospf, "multipoint")
# TODO: work out why this doesnt work
#ank_utils.copy_int_attr_from(g_in, g_ospf, "ospf_cost", dst_attr="cost", type=int, default = 1)
for node in g_ospf:
for interface in node.physical_interfaces():
interface.cost = 1
ank_utils.copy_attr_from(g_in, g_ospf, "ospf_area", dst_attr="area")
#ank_utils.copy_edge_attr_from(g_in, g_ospf, "ospf_cost", dst_attr="cost", type=int, default = 1)
ank_utils.copy_attr_from(
g_in, g_ospf, "custom_config_ospf", dst_attr="custom_config")
g_ospf.remove_edges_from([link for link in g_ospf.edges(
) if link.src.asn != link.dst.asn]) # remove inter-AS links
area_zero_ip = netaddr.IPAddress("0.0.0.0")
area_zero_int = 0
area_zero_ids = {area_zero_ip, area_zero_int}
default_area = area_zero_int
if any(router.area == "0.0.0.0" for router in g_ospf):
# string comparison as hasn't yet been cast to IPAddress
default_area = area_zero_ip
for router in g_ospf:
if not router.area or router.area == "None":
router.area = default_area
# check if 0.0.0.0 used anywhere, if so then use 0.0.0.0 as format
else:
try:
router.area = int(router.area)
except ValueError:
try:
router.area = netaddr.IPAddress(router.area)
except netaddr.core.AddrFormatError:
router.log.warning("Invalid OSPF area %s. Using default"
" of %s" % (router.area, default_area))
router.area = default_area
# TODO: use interfaces throughout, rather than edges
for router in g_ospf:
# and set area on interface
for edge in router.edges():
if edge.area:
continue # allocated (from other "direction", as undirected)
if router.area == edge.dst.area:
edge.area = router.area # intra-area
continue
if router.area in area_zero_ids or edge.dst.area in area_zero_ids:
# backbone to other area
if router.area in area_zero_ids:
# router in backbone, use other area
edge.area = edge.dst.area
else:
# router not in backbone, use its area
edge.area = router.area
for router in g_ospf:
areas = {edge.area for edge in router.edges()}
router.areas = list(areas) # edges router participates in
if len(areas) in area_zero_ids:
router.type = "backbone" # no ospf edges (eg single node in AS)
elif len(areas) == 1:
# single area: either backbone (all 0) or internal (all nonzero)
if len(areas & area_zero_ids):
# intersection has at least one element -> router has area zero
router.type = "backbone"
else:
router.type = "internal"
else:
# multiple areas
if len(areas & area_zero_ids):
# intersection has at least one element -> router has area zero
router.type = "backbone ABR"
elif router.area in area_zero_ids:
router.log.debug(
"Router belongs to area %s but has no area zero interfaces",
router.area)
router.type = "backbone ABR"
else:
router.log.warning(
"spans multiple areas but is not a member of area 0")
router.type = "INVALID"
if (any(area_zero_int in router.areas for router in g_ospf) and
any(area_zero_ip in router.areas for router in g_ospf)):
router.log.warning("Using both area 0 and area 0.0.0.0")
for link in g_ospf.edges():
if not link.cost:
link.cost = 1
# map areas and costs onto interfaces
# TODO: later map them directly rather than with edges - part of
# the transition
for edge in g_ospf.edges():
for interface in edge.interfaces():
interface.cost = edge.cost
interface.area = edge.area
interface.multipoint = edge.multipoint
for router in g_ospf:
router.loopback_zero.area = router.area
router.loopback_zero.cost = 0
router.process_id = router.asn
def build_ipv4(anm, infrastructure=True):
"""Builds IPv4 graph"""
import autonetkit.plugins.ipv4 as ipv4
import netaddr
g_ipv4 = anm.add_overlay('ipv4')
g_ip = anm['ip']
g_in = anm['input']
g_ipv4.add_nodes_from(g_ip, retain=['label', 'broadcast_domain'
]) # retain if collision domain or not
# Copy ASN attribute chosen for collision domains (used in alloc algorithm)
ank_utils.copy_attr_from(g_ip,
g_ipv4,
'asn',
nbunch=g_ipv4.nodes('broadcast_domain'))
g_ipv4.add_edges_from(g_ip.edges())
# check if ip ranges have been specified on g_in
(infra_block, loopback_block, vrf_loopback_block) = \
extract_ipv4_blocks(anm)
block_message = "IPv4 allocations: Infrastructure: %s, Loopback: %s" % (
infra_block, loopback_block)
if any(i for n in g_ip.nodes() for i in n.loopback_interfaces
if not i.is_loopback_zero):
block_message += " Secondary Loopbacks: %s" % vrf_loopback_block
log.info(block_message)
# See if IP addresses specified on each interface
# do we need this still? in ANM?
l3_devices = [d for d in g_in if d.device_type in ('router', 'server')]
manual_alloc_devices = set()
for device in l3_devices:
physical_interfaces = list(device.physical_interfaces)
allocated = list(interface.ipv4_address
for interface in physical_interfaces
if interface.is_bound)
if all(interface.ipv4_address for interface in physical_interfaces
if interface.is_bound):
manual_alloc_devices.add(
device) # add as a manual allocated device
if manual_alloc_devices == set(l3_devices):
manual_alloc_ipv4_infrastructure = True
else:
manual_alloc_ipv4_infrastructure = False
# warn if any set
allocated = []
unallocated = []
for node in l3_devices:
allocated += sorted([
i for i in node.physical_interfaces
if i.is_bound and i.ipv4_address
])
unallocated += sorted([
i for i in node.physical_interfaces
if i.is_bound and not i.ipv4_address
])
#TODO: what if IP is set but not a prefix?
if len(allocated):
#TODO: if set is > 50% of nodes then list those that are NOT set
log.warning(
"Using automatic IPv4 interface allocation. IPv4 interface addresses specified on interfaces %s will be ignored."
% allocated)
# TODO: need to set allocate_ipv4 by default in the readers
if manual_alloc_ipv4_infrastructure:
manual_ipv4_infrastructure_allocation(anm)
else:
ipv4.allocate_infra(g_ipv4, infra_block)
if g_in.data.alloc_ipv4_loopbacks is False:
manual_ipv4_loopback_allocation(anm)
else:
# Check if some nodes are allocated
allocated = sorted([n for n in g_ip if n['input'].loopback_v4])
unallocated = sorted([n for n in g_ip if not n['input'].loopback_v4])
if len(allocated):
log.warning(
"Using automatic IPv4 loopback allocation. IPv4 loopback addresses specified on nodes %s will be ignored."
% allocated)
#TODO: if set is > 50% of nodes then list those that are NOT set
ipv4.allocate_loopbacks(g_ipv4, loopback_block)
# TODO: need to also support secondary_loopbacks for IPv6
# TODO: only call if secondaries are set
ipv4.allocate_vrf_loopbacks(g_ipv4, vrf_loopback_block)
# TODO: replace this with direct allocation to interfaces in ip alloc plugin
#TODO: add option for nonzero interfaces on node - ie node.secondary_loopbacks
for node in g_ipv4.routers():
node.loopback_zero.ip_address = node.loopback
node.loopback_zero.subnet = netaddr.IPNetwork("%s/32" % node.loopback)
for interface in node.loopback_interfaces:
if not interface.is_loopback_zero:
interface.ip_address = interface.loopback #TODO: fix this inconsistency elsewhere
def build_ipv4(anm, infrastructure=True):
"""Builds IPv4 graph"""
import autonetkit.plugins.ipv4 as ipv4
import netaddr
g_ipv4 = anm.add_overlay("ipv4")
g_ip = anm["ip"]
g_in = anm["input"]
g_ipv4.add_nodes_from(g_ip, retain=["label", "broadcast_domain"]) # retain if collision domain or not
# Copy ASN attribute chosen for collision domains (used in alloc algorithm)
ank_utils.copy_attr_from(g_ip, g_ipv4, "asn", nbunch=g_ipv4.nodes("broadcast_domain"))
g_ipv4.add_edges_from(g_ip.edges())
# check if ip ranges have been specified on g_in
(infra_block, loopback_block, vrf_loopback_block) = extract_ipv4_blocks(anm)
# TODO: don't present if using manual allocation
block_message = "IPv4 allocations: Infrastructure: %s, Loopback: %s" % (infra_block, loopback_block)
if any(i for n in g_ip.nodes() for i in n.loopback_interfaces if not i.is_loopback_zero):
block_message += " Secondary Loopbacks: %s" % vrf_loopback_block
log.info(block_message)
# See if IP addresses specified on each interface
# do we need this still? in ANM? - differnt because input graph.... but can map back to self overlay first then phy???
l3_devices = [d for d in g_in if d.device_type in ("router", "server")]
manual_alloc_devices = set()
for device in l3_devices:
physical_interfaces = list(device.physical_interfaces)
allocated = list(interface.ipv4_address for interface in physical_interfaces if interface.is_bound)
if all(interface.ipv4_address for interface in physical_interfaces if interface.is_bound):
manual_alloc_devices.add(device) # add as a manual allocated device
if manual_alloc_devices == set(l3_devices):
manual_alloc_ipv4_infrastructure = True
else:
manual_alloc_ipv4_infrastructure = False
# warn if any set
allocated = []
unallocated = []
for node in l3_devices:
allocated += sorted([i for i in node.physical_interfaces if i.is_bound and i.ipv4_address])
unallocated += sorted([i for i in node.physical_interfaces if i.is_bound and not i.ipv4_address])
# TODO: what if IP is set but not a prefix?
if len(allocated):
# TODO: if set is > 50% of nodes then list those that are NOT set
log.warning(
"Using automatic IPv4 interface allocation. IPv4 interface addresses specified on interfaces %s will be ignored."
% allocated
)
# TODO: need to set allocate_ipv4 by default in the readers
if manual_alloc_ipv4_infrastructure:
manual_ipv4_infrastructure_allocation(anm)
else:
ipv4.allocate_infra(g_ipv4, infra_block)
if g_in.data.alloc_ipv4_loopbacks is False:
manual_ipv4_loopback_allocation(anm)
else:
# Check if some nodes are allocated
allocated = sorted([n for n in g_ip if n["input"].loopback_v4])
unallocated = sorted([n for n in g_ip if not n["input"].loopback_v4])
if len(allocated):
log.warning(
"Using automatic IPv4 loopback allocation. IPv4 loopback addresses specified on nodes %s will be ignored."
% allocated
)
# TODO: if set is > 50% of nodes then list those that are NOT set
ipv4.allocate_loopbacks(g_ipv4, loopback_block)
# TODO: need to also support secondary_loopbacks for IPv6
# TODO: only call if secondaries are set
ipv4.allocate_vrf_loopbacks(g_ipv4, vrf_loopback_block)
# TODO: replace this with direct allocation to interfaces in ip alloc plugin
# TODO: add option for nonzero interfaces on node - ie node.secondary_loopbacks
for node in g_ipv4.routers():
node.loopback_zero.ip_address = node.loopback
node.loopback_zero.subnet = netaddr.IPNetwork("%s/32" % node.loopback)
for interface in node.loopback_interfaces:
if not interface.is_loopback_zero:
interface.ip_address = interface.loopback # TODO: fix this inconsistency elsewhere
def build_ipv4(anm, infrastructure=True):
"""Builds IPv4 graph"""
import autonetkit.plugins.ipv4 as ipv4
import netaddr
g_ipv4 = anm.add_overlay('ipv4')
g_ip = anm['ip']
g_in = anm['input']
# retain if collision domain or not
g_ipv4.add_nodes_from(g_ip, retain=['label', 'allocate',
'broadcast_domain'])
ank_utils.copy_attr_from(g_in, g_ipv4, 'name')
# Copy ASN attribute chosen for collision domains (used in alloc algorithm)
ank_utils.copy_attr_from(
g_ip, g_ipv4, 'asn', nbunch=g_ipv4.nodes('broadcast_domain'))
# work around until fall-through implemented
vswitches = [n for n in g_ip.nodes()
if n['layer2'].device_type == "switch"
and n['layer2'].device_subtype == "virtual"]
ank_utils.copy_attr_from(g_ip, g_ipv4, 'asn', nbunch=vswitches)
g_ipv4.add_edges_from(g_ip.edges())
# check if ip ranges have been specified on g_in
(infra_block, loopback_block, vrf_loopback_block) = \
extract_ipv4_blocks(anm)
# TODO: don't present if using manual allocation
if any(i for n in g_ip.nodes() for i in
n.loopback_interfaces() if not i.is_loopback_zero):
block_message = "IPv4 Secondary Loopbacks: %s" % vrf_loopback_block
log.info(block_message)
# See if IP addresses specified on each interface
# do we need this still? in ANM? - differnt because input graph.... but
# can map back to self overlay first then phy???
l3_devices = [d for d in g_in if d.device_type in ('router', 'server')]
# TODO: need to account for devices whose interfaces are in only e.g. vpns
manual_alloc_devices = set()
for device in l3_devices:
physical_interfaces = list(device.edge_interfaces())
allocated = list(
interface.ipv4_address for interface in physical_interfaces
if interface.is_bound and interface['ipv4'].allocate is not False
and interface['ipv4'].is_bound)
if all(interface.ipv4_address for interface in
physical_interfaces if interface.is_bound
and interface['ip'].allocate is not False
and interface['ip'].is_bound):
# add as a manual allocated device
manual_alloc_devices.add(device)
if manual_alloc_devices == set(l3_devices):
manual_alloc_ipv4_infrastructure = True
else:
log.info("Allocating from IPv4 infrastructure block: %s" % infra_block)
manual_alloc_ipv4_infrastructure = False
# warn if any set
allocated = []
unallocated = []
for node in l3_devices:
# TODO: make these inverse sets
allocated += sorted([i for i in node.edge_interfaces()
if i.is_bound and i.ipv4_address])
unallocated += sorted([i for i in node.edge_interfaces()
if i.is_bound and not i.ipv4_address
and i['ipv4'].is_bound])
# TODO: what if IP is set but not a prefix?
if len(allocated):
# TODO: if set is > 50% of nodes then list those that are NOT set
log.warning(
"Using automatic IPv4 interface allocation. IPv4 interface addresses specified on interfaces %s will be ignored." % allocated)
# TODO: need to set allocate_ipv4 by default in the readers
if manual_alloc_ipv4_infrastructure:
manual_ipv4_infrastructure_allocation(anm)
else:
ipv4.allocate_infra(g_ipv4, infra_block)
if g_in.data.alloc_ipv4_loopbacks is False:
manual_ipv4_loopback_allocation(anm)
else:
log.info("Allocating from IPv4 loopback block: %s" % loopback_block)
# Check if some nodes are allocated
allocated = sorted([n for n in g_ip if n['input'].loopback_v4])
unallocated = sorted([n for n in g_ip if not n['input'].loopback_v4])
if len(allocated):
log.warning(
"Using automatic IPv4 loopback allocation. IPv4 loopback addresses specified on nodes %s will be ignored." % allocated)
# TODO: if set is > 50% of nodes then list those that are NOT set
ipv4.allocate_loopbacks(g_ipv4, loopback_block)
# TODO: need to also support secondary_loopbacks for IPv6
# TODO: only call if secondaries are set
ipv4.allocate_secondary_loopbacks(g_ipv4, vrf_loopback_block)
# TODO: replace this with direct allocation to interfaces in ip alloc plugin
# TODO: add option for nonzero interfaces on node - ie
# node.secondary_loopbacks
for node in g_ipv4:
node.static_routes = []
for node in g_ipv4.routers():
node.loopback_zero.ip_address = node.loopback
node.loopback_zero.subnet = netaddr.IPNetwork("%s/32" % node.loopback)
for interface in node.loopback_interfaces():
if not interface.is_loopback_zero:
# TODO: fix this inconsistency elsewhere
interface.ip_address = interface.loopback
# TODO: Create collision domain overlay for ip addressing - l2 overlay?
if address_family == "None":
log.info("IP addressing disabled, not allocating IPv6")
anm.add_overlay("ipv6") # create empty so rest of code follows
g_phy.update(g_phy, use_ipv6=False)
elif address_family in ("v6", "dual_stack"):
build_ipv6(anm)
g_phy.update(g_phy, use_ipv6=True)
else:
anm.add_overlay("ipv6") # placeholder for compiler logic
assign_loopback_ip_pool(anm)
# default_igp = g_in.data.igp or "ospf"
default_igp = g_in.data.igp
ank_utils.set_node_default(g_in, igp=default_igp)
ank_utils.copy_attr_from(g_in, g_phy, "igp")
ank_utils.copy_attr_from(g_in, g_phy, "include_csr")
try:
from autonetkit_cisco import build_network as cisco_build_network
except ImportError, error:
log.debug("Unable to load autonetkit_cisco %s" % error)
else:
cisco_build_network.pre_design(anm)
# log.info("Building IGP")
from autonetkit.design.igp import build_igp
build_igp(anm)
def build_ospf(anm):
"""
Build OSPF graph.
Allowable area combinations:
0 -> 0
0 -> x (x!= 0)
x -> 0 (x!= 0)
x -> x (x != 0)
Not-allowed:
x -> x (x != y != 0)
#TODO: build check that verifies these rules
"""
import netaddr
g_in = anm['input']
# add regardless, so allows quick check of node in anm['ospf'] in compilers
g_ospf = anm.add_overlay("ospf")
if not any(n.igp == "ospf" for n in g_in):
log.debug("No OSPF nodes")
return
g_ospf.add_nodes_from(g_in.nodes("is_router", igp = "ospf"), retain=['asn'])
g_ospf.add_nodes_from(g_in.nodes("is_server", igp = "ospf"), retain=['asn'])
g_ospf.add_nodes_from(g_in.nodes("is_switch"), retain=['asn'])
g_ospf.add_edges_from(g_in.edges(), retain=['edge_id'])
ank_utils.copy_attr_from(g_in, g_ospf, "ospf_area", dst_attr="area")
ank_utils.copy_edge_attr_from(g_in, g_ospf, "ospf_cost", dst_attr="cost", type=float)
ank_utils.aggregate_nodes(g_ospf, g_ospf.nodes("is_switch"),
retain="edge_id")
exploded_edges = ank_utils.explode_nodes(g_ospf, g_ospf.nodes("is_switch"),
retain="edge_id")
for edge in exploded_edges:
edge.multipoint = True
g_ospf.remove_edges_from([link for link in g_ospf.edges(
) if link.src.asn != link.dst.asn]) # remove inter-AS links
area_zero_ip = netaddr.IPAddress("0.0.0.0")
area_zero_int = 0
area_zero_ids = {area_zero_ip, area_zero_int}
default_area = area_zero_int
if any(router.area == "0.0.0.0" for router in g_ospf):
# string comparison as hasn't yet been cast to IPAddress
default_area = area_zero_ip
#TODO: use interfaces throughout, rather than edges
for router in g_ospf:
if not router.area or router.area == "None":
router.area = default_area
# check if 0.0.0.0 used anywhere, if so then use 0.0.0.0 as format
else:
try:
router.area = int(router.area)
except ValueError:
try:
router.area = netaddr.IPAddress(router.area)
except netaddr.core.AddrFormatError:
log.warning("Invalid OSPF area %s for %s. Using default"
" of %s" % (router.area, router, default_area))
router.area = default_area
for router in g_ospf:
# and set area on interface
for edge in router.edges():
if edge.area:
continue # allocated (from other "direction", as undirected)
if router.area == edge.dst.area:
edge.area = router.area # intra-area
continue
if router.area in area_zero_ids or edge.dst.area in area_zero_ids:
# backbone to other area
if router.area in area_zero_ids:
# router in backbone, use other area
edge.area = edge.dst.area
else:
# router not in backbone, use its area
edge.area = router.area
for router in g_ospf:
areas = {edge.area for edge in router.edges()}
router.areas = list(areas) # edges router participates in
if len(areas) in area_zero_ids:
router.type = "backbone" # no ospf edges (eg single node in AS)
elif len(areas) == 1:
# single area: either backbone (all 0) or internal (all nonzero)
if len(areas & area_zero_ids):
# intersection has at least one element -> router has area zero
router.type = "backbone"
else:
router.type = "internal"
else:
# multiple areas
if len(areas & area_zero_ids):
# intersection has at least one element -> router has area zero
router.type = "backbone ABR"
else:
log.warning(
"%s spans multiple areas but is not a member of area 0"
% router)
router.type = "INVALID"
if (any(area_zero_int in router.areas for router in g_ospf) and
any(area_zero_ip in router.areas for router in g_ospf)):
log.warning("Using both area 0 and area 0.0.0.0")
for link in g_ospf.edges():
if not link.cost:
link.cost = 1
# map areas and costs onto interfaces
#TODO: later map them directly rather than with edges - this is part of the transition
for edge in g_ospf.edges():
for interface in edge.interfaces():
interface.cost = edge.cost
interface.area = edge.area
interface.multipoint = edge.multipoint
for router in g_ospf:
router.loopback_zero.area = router.area
router.loopback_zero.cost = 0
def build_phy(anm):
"""Build physical overlay"""
g_in = anm['input']
g_phy = anm['phy']
g_phy.data.enable_routing = g_in.data.enable_routing
if g_phy.data.enable_routing is None:
g_in.data.enable_routing = True # default if not set
g_phy.add_nodes_from(g_in,
retain=[
'label', 'update', 'device_type', 'asn',
'specified_int_names', 'device_subtype',
'platform', 'host', 'syntax'
])
if g_in.data.Creator == "Topology Zoo Toolset":
ank_utils.copy_attr_from(g_in, g_phy, "Network")
ank_utils.set_node_default(g_phy, Network=None)
g_phy.add_edges_from(g_in.edges(type="physical"))
# TODO: make this automatic if adding to the physical graph?
if g_in.data.Creator == "VIRL":
g_phy.data.mgmt_interfaces_enabled = g_in.data.mgmt_interfaces_enabled
#TODO: remove this code now allocated externally
g_phy.data.mgmt_address_start = g_in.data.mgmt_address_start
g_phy.data.mgmt_address_end = g_in.data.mgmt_address_end
g_phy.data.mgmt_prefixlen = g_in.data.mgmt_prefixlen
g_phy.data.mgmt_prefixlen = g_in.data.mgmt_prefixlen
ank_utils.copy_attr_from(g_in, g_phy, "use_cdp")
ank_utils.copy_attr_from(g_in, g_phy, "use_onepk")
ank_utils.copy_attr_from(g_in, g_phy, "label_full")
ank_utils.copy_attr_from(g_in, g_phy, "indices")
ank_utils.copy_attr_from(g_in, g_phy, "dont_configure_static_routing")
ank_utils.copy_attr_from(g_in, g_phy, "server_username")
ank_utils.copy_attr_from(g_in, g_phy, "server_ssh_key")
ank_utils.set_node_default(g_phy, use_ipv4=False, use_ipv6=False)
g_phy.allocate_interfaces()
for node in g_phy:
for interface in node:
specified_id = interface['input'].get("specified_id")
if specified_id:
interface.specified_id = specified_id # map across
remove_parallel_switch_links(anm)
def build_bgp(anm):
"""Build iBGP end eBGP overlays"""
# eBGP
g_in = anm['input']
g_phy = anm['phy']
if not anm['phy'].data.enable_routing:
log.info("Routing disabled, not configuring BGP")
return
build_ebgp(anm)
build_ebgp_v4(anm)
build_ebgp_v6(anm)
"""TODO: remove from here once compiler updated"""
g_bgp = anm.add_overlay("bgp", directed=True)
g_bgp.add_nodes_from(g_in.routers())
ebgp_edges = [edge for edge in g_in.edges()
if edge.src.asn != edge.dst.asn]
g_bgp.add_edges_from(ebgp_edges, bidirectional=True, type='ebgp')
ebgp_switches = [n for n in g_in.switches()
if not ank_utils.neigh_equal(g_phy, n, "asn")]
g_bgp.add_nodes_from(ebgp_switches, retain=['asn'])
log.debug("eBGP switches are %s" % ebgp_switches)
g_bgp.add_edges_from((e for e in g_in.edges()
if e.src in ebgp_switches or e.dst in ebgp_switches), bidirectional=True, type='ebgp')
ank_utils.aggregate_nodes(g_bgp, ebgp_switches)
ebgp_switches = list(g_bgp.switches()) # need to recalculate as may have aggregated
log.debug("aggregated eBGP switches are %s" % ebgp_switches)
exploded_edges = ank_utils.explode_nodes(g_bgp, ebgp_switches)
same_asn_edges = []
for edge in exploded_edges:
if edge.src.asn == edge.dst.asn:
same_asn_edges.append(edge)
else:
edge.multipoint = True
"""TODO: remove up to here once compiler updated"""
ank_utils.copy_attr_from(g_in, g_bgp, "custom_config_bgp", dst_attr="custom_config")
g_bgp.remove_edges_from(same_asn_edges)
build_ibgp(anm)
ebgp_nodes = [d for d in g_bgp if any(
edge.type == 'ebgp' for edge in d.edges())]
g_bgp.update(ebgp_nodes, ebgp=True)
for ebgp_edge in g_bgp.edges(type = "ebgp"):
for interface in ebgp_edge.interfaces():
interface.ebgp = True
for edge in g_bgp.edges(type='ibgp'):
# TODO: need interface querying/selection. rather than hard-coded ids
edge.bind_interface(edge.src, 0)
#TODO: need to initialise interface zero to be a loopback rather than physical type
for node in g_bgp:
for interface in node.interfaces():
interface.multipoint = any(e.multipoint for e in interface.edges())
build_ibgp_v4(anm)
build_ibgp_v6(anm)
def build_ibgp(anm):
g_in = anm['input']
g_bgp = anm['bgp']
# TODO: build direct to ibgp graph - can construct combined bgp for vis
#TODO: normalise input property
ank_utils.copy_attr_from(g_in, g_bgp, "ibgp_role")
ank_utils.copy_attr_from(g_in,
g_bgp,
"ibgp_l2_cluster",
"hrr_cluster",
default=None)
ank_utils.copy_attr_from(g_in,
g_bgp,
"ibgp_l3_cluster",
"rr_cluster",
default=None)
# TODO: add more detailed logging
for n in g_bgp:
# Tag with label to make logic clearer
if n.ibgp_role is None:
n.ibgp_role = "Peer"
# TODO: if top-level, then don't mark as RRC
ibgp_nodes = [n for n in g_bgp if not n.ibgp_role is "Disabled"]
# Notify user of non-ibgp nodes
non_ibgp_nodes = [n for n in g_bgp if n.ibgp_role is "Disabled"]
if 0 < len(non_ibgp_nodes) < 10:
log.info("Skipping iBGP for iBGP disabled nodes: %s", non_ibgp_nodes)
elif len(non_ibgp_nodes) >= 10:
log.info("Skipping iBGP for more than 10 iBGP disabled nodes:"
"refer to visualization for resulting topology.")
# warn for any nodes that have RR set but no rr_cluster, or HRR set and no
# hrr_cluster
rr_mismatch = [
n for n in ibgp_nodes if n.ibgp_role == "RR" and n.rr_cluster is None
]
if len(rr_mismatch):
log.warning(
"Some routers are set as RR but have no rr_cluster: %s. Please specify an rr_cluster for peering."
% ", ".join(str(n) for n in rr_mismatch))
hrr_mismatch = [
n for n in ibgp_nodes if n.ibgp_role == "HRR" and n.hrr_cluster is None
]
if len(hrr_mismatch):
log.warning(
"Some routers are set as HRR but have no hrr_cluster: %s. Please specify an hrr_cluster for peering."
% ", ".join(str(n) for n in hrr_mismatch))
for _, asn_devices in ank_utils.groupby("asn", ibgp_nodes):
asn_devices = list(asn_devices)
# iBGP peer peers with
peers = [n for n in asn_devices if n.ibgp_role == "Peer"]
rrs = [n for n in asn_devices if n.ibgp_role == "RR"]
hrrs = [n for n in asn_devices if n.ibgp_role == "HRR"]
rrcs = [n for n in asn_devices if n.ibgp_role == "RRC"]
over_links = []
up_links = []
down_links = []
# 0. RRCs can only belong to either an rr_cluster or a hrr_cluster
invalid_rrcs = [
r for r in rrcs
if r.rr_cluster is not None and r.hrr_cluster is not None
]
if len(invalid_rrcs):
message = ", ".join(str(r) for r in invalid_rrcs)
log.warning(
"RRCs can only have either a rr_cluster or hrr_cluster set. "
"The following have both set, and only the rr_cluster will be used: %s",
message)
# TODO: do we also want to warn for RRCs with no cluster set? Do we also exclude these?
# TODO: do we also want to warn for HRRs and RRs with no cluster set?
# Do we also exclude these?
# 1. Peers:
# 1a. Peers connect over to peers
over_links += [(s, t) for s in peers for t in peers]
# 1b. Peers connect over to RRs
over_links += [(s, t) for s in peers for t in rrs]
# 2. RRs:
# 2a. RRs connect over to Peers
over_links += [(s, t) for s in rrs for t in peers]
# 2b. RRs connect over to RRs
over_links += [(s, t) for s in rrs for t in rrs]
# 2c. RRs connect down to RRCs in same rr_cluster
down_links += [(s, t) for s in rrs for t in rrcs
if s.rr_cluster == t.rr_cluster != None]
# 2d. RRs connect down to HRRs in the same rr_cluster
down_links += [(s, t) for s in rrs for t in hrrs
if s.rr_cluster == t.rr_cluster != None]
# 3. HRRs
# 3a. HRRs connect up to RRs in the same rr_cluster
up_links += [(s, t) for s in hrrs for t in rrs
if s.rr_cluster == t.rr_cluster != None]
# 3b. HRRs connect down to RRCs in same hrr_cluster (providing RRC has
# no rr_cluster set)
down_links += [
(s, t) for s in hrrs for t in rrcs
if s.hrr_cluster == t.hrr_cluster != None and t.rr_cluster is None
]
# 4. RRCs
# 4a. RRCs connect up to RRs in the same rr_cluster (regardless if RRC
# has hrr_cluster set)
up_links += [(s, t) for s in rrcs for t in rrs
if s.rr_cluster == t.rr_cluster != None]
# 3b. RRCs connect up to HRRs in same hrr_cluster (providing RRC has no
# rr_cluster set)
up_links += [
(s, t) for s in rrcs for t in hrrs
if s.hrr_cluster == t.hrr_cluster != None and s.rr_cluster is None
]
# Remove self-links
over_links = [(s, t) for s, t in over_links if s != t]
up_links = [(s, t) for s, t in up_links if s != t]
down_links = [(s, t) for s, t in down_links if s != t]
g_bgp.add_edges_from(over_links, type='ibgp', direction='over')
g_bgp.add_edges_from(up_links, type='ibgp', direction='up')
g_bgp.add_edges_from(down_links, type='ibgp', direction='down')
def build_phy(anm):
"""Build physical overlay"""
g_in = anm["input"]
g_phy = anm["phy"]
if g_in.data.enable_routing is not None:
g_phy.data.enable_routing = g_in.data.enable_routing
if g_in.data.mgmt_block:
g_phy.data["mgmt_block"] = g_in.data["mgmt_block"]
if g_in.data.ignite:
g_phy.data["ignite"] = g_in.data["ignite"]
if g_in.data.pc_only is not None:
g_phy.data["pc_only"] = g_in.data["pc_only"]
if g_in.data.vpcid_block:
g_phy.data["vpcid_block"] = g_in.data["vpcid_block"]
if g_in.data.vxlan_global_config:
g_phy.data["vxlan_global_config"] = g_in.data["vxlan_global_config"]
if g_phy.data.enable_routing is None:
g_in.data.enable_routing = True # default if not set
g_phy.add_nodes_from(
g_in,
retain=[
"name",
"label",
"update",
"device_type",
"devsubtype",
"asn",
"specified_int_names",
"x",
"y",
"device_subtype",
"platform",
"host",
"syntax",
"profile",
"syslog",
"vpc-peer",
"vxlan_vni_configured",
],
)
if g_in.data.Creator == "Topology Zoo Toolset":
ank_utils.copy_attr_from(g_in, g_phy, "Network")
ank_utils.set_node_default(g_phy, Network=None)
g_phy.add_edges_from(g_in.edges(type="physical"), retain=["link_type"])
# TODO: make this automatic if adding to the physical graph?
ank_utils.set_node_default(g_phy, use_ipv4=False, use_ipv6=False)
ank_utils.copy_attr_from(g_in, g_phy, "custom_config_global", dst_attr="custom_config")
for node in g_phy:
if node["input"].custom_config_loopback_zero:
lo_zero_config = node["input"].custom_config_loopback_zero
node.loopback_zero.custom_config = lo_zero_config
custom_config_phy_ints = node["input"].custom_config_phy_ints
for interface in node:
if custom_config_phy_ints:
interface.custom_config = custom_config_phy_ints
specified_id = interface["input"].get("specified_id")
if specified_id:
interface.specified_id = specified_id # map across
# TODO: tidy this code up
for node in g_phy:
for interface in node:
remote_edges = interface.edges()
if len(remote_edges):
interface.description = "to %s" % remote_edges[0].dst.label
def build_bgp(anm):
"""Build iBGP end eBGP overlays"""
# eBGP
g_in = anm['input']
g_phy = anm['phy']
build_ebgp(anm)
build_ebgp_v4(anm)
build_ebgp_v6(anm)
"""TODO: remove from here once compiler updated"""
g_bgp = anm.add_overlay("bgp", directed=True)
g_bgp.add_nodes_from(g_in.nodes("is_router"))
ebgp_edges = [edge for edge in g_in.edges() if not edge.attr_equal("asn")]
g_bgp.add_edges_from(ebgp_edges, bidirectional=True, type='ebgp')
#TODO: why don't we include edge_id here
ebgp_switches = [
n for n in g_in.nodes("is_switch")
if not ank_utils.neigh_equal(g_phy, n, "asn")
]
g_bgp.add_nodes_from(ebgp_switches, retain=['asn'])
log.debug("eBGP switches are %s" % ebgp_switches)
g_bgp.add_edges_from((e for e in g_in.edges()
if e.src in ebgp_switches or e.dst in ebgp_switches),
bidirectional=True,
type='ebgp')
ank_utils.aggregate_nodes(g_bgp, ebgp_switches, retain="edge_id")
ebgp_switches = list(
g_bgp.nodes("is_switch")) # need to recalculate as may have aggregated
log.debug("aggregated eBGP switches are %s" % ebgp_switches)
exploded_edges = ank_utils.explode_nodes(g_bgp,
ebgp_switches,
retain="edge_id")
for edge in exploded_edges:
edge.multipoint = True
"""TODO: remove up to here once compiler updated"""
# now iBGP
ank_utils.copy_attr_from(g_in, g_bgp, "ibgp_level")
ank_utils.copy_attr_from(g_in, g_bgp, "ibgp_l2_cluster")
ank_utils.copy_attr_from(g_in, g_bgp, "ibgp_l3_cluster")
for node in g_bgp:
# set defaults
if node.ibgp_level is None:
node.ibgp_level = 1
if node.ibgp_level == "None": # if unicode string from yEd
node.ibgp_level = 1
#TODO CHECK FOR IBGP NONE
node.ibgp_level = int(node.ibgp_level) # ensure is numeric
if not node.ibgp_l2_cluster or node.ibgp_l2_cluster == "None":
# ibgp_l2_cluster defaults to region
node.ibgp_l2_cluster = node.region or "default_l2_cluster"
if not node.ibgp_l3_cluster or node.ibgp_l3_cluster == "None":
# ibgp_l3_cluster defaults to ASN
node.ibgp_l3_cluster = node.asn
for asn, devices in ank_utils.groupby("asn", g_bgp):
# group by nodes in phy graph
routers = list(g_bgp.node(n) for n in devices if n.is_router)
# list of nodes from bgp graph
ibgp_levels = {int(r.ibgp_level) for r in routers}
max_level = max(ibgp_levels)
# all possible edge src/dst pairs
ibgp_routers = [r for r in routers if r.ibgp_level > 0]
all_pairs = [(s, t) for s in ibgp_routers for t in ibgp_routers
if s != t]
if max_level == 3:
up_links, down_links, over_links = three_tier_ibgp_edges(
ibgp_routers)
elif max_level == 2:
up_links, down_links, over_links = build_two_tier_ibgp(
ibgp_routers)
elif max_level == 1:
up_links = []
down_links = []
over_links = [(s, t) for (s, t) in all_pairs
if s.ibgp_l3_cluster == t.ibgp_l3_cluster
and s.ibgp_l2_cluster == t.ibgp_l2_cluster]
else:
# no iBGP
up_links = []
down_links = []
over_links = []
if max_level > 0:
g_bgp.add_edges_from(up_links, type='ibgp', direction='up')
g_bgp.add_edges_from(down_links, type='ibgp', direction='down')
g_bgp.add_edges_from(over_links, type='ibgp', direction='over')
else:
log.debug("No iBGP routers in %s" % asn)
# and set label back
ibgp_label_to_level = {
0: "None", # Explicitly set role to "None" -> Not in iBGP
3: "RR",
1: "RRC",
2: "HRR",
}
for node in g_bgp:
node.ibgp_role = ibgp_label_to_level[node.ibgp_level]
ebgp_nodes = [
d for d in g_bgp if any(edge.type == 'ebgp' for edge in d.edges())
]
g_bgp.update(ebgp_nodes, ebgp=True)
for ebgp_edge in g_bgp.edges(type="ebgp"):
for interface in ebgp_edge.interfaces():
interface.ebgp = True
for edge in g_bgp.edges(type='ibgp'):
# TODO: need interface querying/selection. rather than hard-coded ids
edge.bind_interface(edge.src, 0)
#TODO: need to initialise interface zero to be a loopback rather than physical type
for node in g_bgp:
for interface in node.interfaces():
interface.multipoint = any(e.multipoint for e in interface.edges())
build_ibgp_v4(anm)
build_ibgp_v6(anm)
def build_ibgp(anm):
g_in = anm['input']
g_bgp = anm['bgp']
# TODO: build direct to ibgp graph - can construct combined bgp for vis
#TODO: normalise input property
ank_utils.copy_attr_from(g_in, g_bgp, "ibgp_role")
ank_utils.copy_attr_from(
g_in, g_bgp, "ibgp_l2_cluster", "hrr_cluster", default=None)
ank_utils.copy_attr_from(
g_in, g_bgp, "ibgp_l3_cluster", "rr_cluster", default=None)
# TODO: add more detailed logging
for n in g_bgp:
# Tag with label to make logic clearer
if n.ibgp_role is None:
n.ibgp_role = "Peer"
# TODO: if top-level, then don't mark as RRC
ibgp_nodes = [n for n in g_bgp if not n.ibgp_role is "Disabled"]
# Notify user of non-ibgp nodes
non_ibgp_nodes = [n for n in g_bgp if n.ibgp_role is "Disabled"]
if 0 < len(non_ibgp_nodes) < 10:
log.info("Skipping iBGP for iBGP disabled nodes: %s", non_ibgp_nodes)
elif len(non_ibgp_nodes) >= 10:
log.info("Skipping iBGP for more than 10 iBGP disabled nodes:",
"refer to visualization for resulting topology.")
# warn for any nodes that have RR set but no rr_cluster, or HRR set and no
# hrr_cluster
rr_mismatch = [
n for n in ibgp_nodes if n.ibgp_role == "RR" and n.rr_cluster is None]
if len(rr_mismatch):
log.warning("Some routers are set as RR but have no rr_cluster: %s. Please specify an rr_cluster for peering."
% ", ".join(str(n) for n in rr_mismatch))
hrr_mismatch = [
n for n in ibgp_nodes if n.ibgp_role == "HRR" and n.hrr_cluster is None]
if len(hrr_mismatch):
log.warning("Some routers are set as HRR but have no hrr_cluster: %s. Please specify an hrr_cluster for peering."
% ", ".join(str(n) for n in hrr_mismatch))
for _, asn_devices in ank_utils.groupby("asn", ibgp_nodes):
asn_devices = list(asn_devices)
# iBGP peer peers with
peers = [n for n in asn_devices if n.ibgp_role == "Peer"]
rrs = [n for n in asn_devices if n.ibgp_role == "RR"]
hrrs = [n for n in asn_devices if n.ibgp_role == "HRR"]
rrcs = [n for n in asn_devices if n.ibgp_role == "RRC"]
over_links = []
up_links = []
down_links = []
# 0. RRCs can only belong to either an rr_cluster or a hrr_cluster
invalid_rrcs = [r for r in rrcs if r.rr_cluster is not None
and r.hrr_cluster is not None]
if len(invalid_rrcs):
message = ", ".join(str(r) for r in invalid_rrcs)
log.warning("RRCs can only have either a rr_cluster or hrr_cluster set. "
"The following have both set, and only the rr_cluster will be used: %s", message)
# TODO: do we also want to warn for RRCs with no cluster set? Do we also exclude these?
# TODO: do we also want to warn for HRRs and RRs with no cluster set?
# Do we also exclude these?
# 1. Peers:
# 1a. Peers connect over to peers
over_links += [(s, t) for s in peers for t in peers]
# 1b. Peers connect over to RRs
over_links += [(s, t) for s in peers for t in rrs]
# 2. RRs:
# 2a. RRs connect over to Peers
over_links += [(s, t) for s in rrs for t in peers]
# 2b. RRs connect over to RRs
over_links += [(s, t) for s in rrs for t in rrs]
# 2c. RRs connect down to RRCs in same rr_cluster
down_links += [(s, t) for s in rrs for t in rrcs
if s.rr_cluster == t.rr_cluster != None]
# 2d. RRs connect down to HRRs in the same rr_cluster
down_links += [(s, t) for s in rrs for t in hrrs
if s.rr_cluster == t.rr_cluster != None]
# 3. HRRs
# 3a. HRRs connect up to RRs in the same rr_cluster
up_links += [(s, t) for s in hrrs for t in rrs
if s.rr_cluster == t.rr_cluster != None]
# 3b. HRRs connect down to RRCs in same hrr_cluster (providing RRC has
# no rr_cluster set)
down_links += [(s, t) for s in hrrs for t in rrcs
if s.hrr_cluster == t.hrr_cluster != None
and t.rr_cluster is None]
# 4. RRCs
# 4a. RRCs connect up to RRs in the same rr_cluster (regardless if RRC
# has hrr_cluster set)
up_links += [(s, t) for s in rrcs for t in rrs
if s.rr_cluster == t.rr_cluster != None]
# 3b. RRCs connect up to HRRs in same hrr_cluster (providing RRC has no
# rr_cluster set)
up_links += [(s, t) for s in rrcs for t in hrrs
if s.hrr_cluster == t.hrr_cluster != None
and s.rr_cluster is None]
# Remove self-links
over_links = [(s, t) for s, t in over_links if s != t]
up_links = [(s, t) for s, t in up_links if s != t]
down_links = [(s, t) for s, t in down_links if s != t]
g_bgp.add_edges_from(over_links, type='ibgp', direction='over')
g_bgp.add_edges_from(up_links, type='ibgp', direction='up')
g_bgp.add_edges_from(down_links, type='ibgp', direction='down')
def build_bgp(anm):
"""Build iBGP end eBGP overlays"""
# eBGP
g_in = anm["input"]
g_phy = anm["phy"]
g_bgp = anm.add_overlay("bgp", directed=True)
g_bgp.add_nodes_from(g_in.nodes("is_router"))
ebgp_edges = [edge for edge in g_in.edges() if not edge.attr_equal("asn")]
g_bgp.add_edges_from(ebgp_edges, bidirectional=True, type="ebgp")
# TODO: why don't we include edge_id here
ebgp_switches = [n for n in g_in.nodes("is_switch") if not ank_utils.neigh_equal(g_phy, n, "asn")]
g_bgp.add_nodes_from(ebgp_switches, retain=["asn"])
log.debug("eBGP switches are %s" % ebgp_switches)
g_bgp.add_edges_from(
(e for e in g_in.edges() if e.src in ebgp_switches or e.dst in ebgp_switches), bidirectional=True, type="ebgp"
)
ank_utils.aggregate_nodes(g_bgp, ebgp_switches, retain="edge_id")
ebgp_switches = list(g_bgp.nodes("is_switch")) # need to recalculate as may have aggregated
log.debug("aggregated eBGP switches are %s" % ebgp_switches)
exploded_edges = ank_utils.explode_nodes(g_bgp, ebgp_switches, retain="edge_id")
for edge in exploded_edges:
edge.multipoint = True
# now iBGP
ank_utils.copy_attr_from(g_in, g_bgp, "ibgp_level")
ank_utils.copy_attr_from(g_in, g_bgp, "ibgp_l2_cluster")
ank_utils.copy_attr_from(g_in, g_bgp, "ibgp_l3_cluster")
for node in g_bgp:
# set defaults
if node.ibgp_level is None:
node.ibgp_level = 1
if node.ibgp_level == "None": # if unicode string from yEd
node.ibgp_level = 1
# TODO CHECK FOR IBGP NONE
node.ibgp_level = int(node.ibgp_level) # ensure is numeric
if not node.ibgp_l2_cluster or node.ibgp_l2_cluster == "None":
# ibgp_l2_cluster defaults to region
node.ibgp_l2_cluster = node.region or "default_l2_cluster"
if not node.ibgp_l3_cluster or node.ibgp_l3_cluster == "None":
# ibgp_l3_cluster defaults to ASN
node.ibgp_l3_cluster = node.asn
for asn, devices in ank_utils.groupby("asn", g_bgp):
# group by nodes in phy graph
routers = list(g_bgp.node(n) for n in devices if n.is_router)
# list of nodes from bgp graph
ibgp_levels = {int(r.ibgp_level) for r in routers}
max_level = max(ibgp_levels)
# all possible edge src/dst pairs
ibgp_routers = [r for r in routers if r.ibgp_level > 0]
all_pairs = [(s, t) for s in ibgp_routers for t in ibgp_routers if s != t]
if max_level == 3:
up_links, down_links, over_links = three_tier_ibgp_edges(ibgp_routers)
elif max_level == 2:
up_links, down_links, over_links = build_two_tier_ibgp(ibgp_routers)
elif max_level == 1:
up_links = []
down_links = []
over_links = [
(s, t)
for (s, t) in all_pairs
if s.ibgp_l3_cluster == t.ibgp_l3_cluster and s.ibgp_l2_cluster == t.ibgp_l2_cluster
]
else:
# no iBGP
up_links = []
down_links = []
over_links = []
if max_level > 0:
g_bgp.add_edges_from(up_links, type="ibgp", direction="up")
g_bgp.add_edges_from(down_links, type="ibgp", direction="down")
g_bgp.add_edges_from(over_links, type="ibgp", direction="over")
else:
log.debug("No iBGP routers in %s" % asn)
# and set label back
ibgp_label_to_level = {0: "None", 3: "RR", 1: "RRC", 2: "HRR"} # Explicitly set role to "None" -> Not in iBGP
for node in g_bgp:
node.ibgp_role = ibgp_label_to_level[node.ibgp_level]
ebgp_nodes = [d for d in g_bgp if any(edge.type == "ebgp" for edge in d.edges())]
g_bgp.update(ebgp_nodes, ebgp=True)
for ebgp_edge in g_bgp.edges(type="ebgp"):
for interface in ebgp_edge.interfaces():
interface.ebgp = True
for edge in g_bgp.edges(type="ibgp"):
# TODO: need interface querying/selection. rather than hard-coded ids
edge.bind_interface(edge.src, 0)
# TODO: need to initialise interface zero to be a loopback rather than physical type
for node in g_bgp:
for interface in node.interfaces():
interface.multipoint = any(e.multipoint for e in interface.edges())