VCS to EVPN Hitless Migration enables support for migrating from only using VCS as the control plane to only using EVPN as a control plane in a hitless manner with respect to L2 reachability information.
Configuration
On the multi-homing PEs, you must configure the Ethernet Segment (ES) to the CE. In
addition, the configuration needed for asymmetric IRB or symmetric IRB must be
configured on the local and the remote PEs.Figure 1. Asymmetric IRB with IPv4
In the example, CE1 is a multi-homed CE in
VLAN20. CE2 is a remote CE
in VLAN30. Asymmetric IRB is configured for inter-VLAN
traffic.
The Ethernet segment to the multi-homed CE is configured on the port channel interface
Port-Channel 100. SVI 20 and
SVI 30 along with VARP IP are configured for
inter-subnet routing. A VARP MAC is configured globally on
PE1. The configuration on PE2 is
similar to the configuration shown above. On PE3,
SVI 20 and SVI 30 are
configured along with VARP IP and VARP MAC.
The Ethernet segment to the multi-homed CE1 is configured on
the port channel interface Port-Channel 100. SVI
20 along with VARP IP and VARP MAC is configured. Also, IP VRF is
configured which is needed for symmetric IRB. The configuration on
PE2 is similar. On PE3, IP
VRF and SVI 30 are configured for symmetric IRB.
VXLAN example
A netwok with 2 VRFs, red and blue
has VLANs 10 and 20 in
red and VLANs 30 and
40 in blue. The spines in
these act as a route reflectors. Multicast groups are used to encapsulate traffic
arriving in a VRF such that it is delivered to VTEPs that have that VRF provisioned.
interface Loopback0
ip address 10.0.0.20/32
!
vlan 10
vlan 20
vlan 30
vlan 40
!
interface Ethernet1
switchport access vlan 10
!
interface Ethernet2
switchport access vlan 20
!
interface Ethernet3
switchport access vlan 30
!
interface Ethernet4
switchport access vlan 40
!
interface Vlan10
vrf red
ip address virtual 192.168.1.0/24
ip igmp
pim ipv4 local-interface loopback0
!
interface Vlan20
vrf red
ip address 192.168.2.0/24
ip igmp
!
interface Vlan30
vrf blue
ip address 192.168.1.0/24
ip igmp
!
interface Vlan40
vrf blue
ip address 192.168.2.0/24
ip igmp
!
interface Vxlan1
vxlan source-interface Loopback0
vxlan vlan 10 vni 10
vxlan vlan 20 vni 20
vxlan vlan 30 vni 30
vxlan vlan 40 vni 40
vxlan vrf red vni 100
vxlan vrf blue vni 200
vxlan vlan 10 flood group 225.1.1.2
vxlan vlan 20 flood group 225.1.1.3
vxlan vlan 30 flood group 226.1.1.2
vxlan vlan 40 flood group 226.1.1.3
vxlan vrf red multicast group 225.1.1.1
vxlan vrf blue multicast group 226.1.1.1
!
Show Commands
The following examples are based on the sample topology and configuration in the previous
sections.
On the remote VTEP, to display the EVPN routes to the multi-homed CE
(20.0.20.2):
switch# show bgp evpn route-type mac-ip 20.0.20.2
BGP routing table information for VRF default
Router identifier 0.0.3.1, local AS number 302
Route status codes: s - suppressed, * - valid, > - active, # - not installed, E - ECMP head,
e - ECMP S - Stale, c - Contributing to ECMP, b - backup
% - Pending BGP convergence
Origin codes: i - IGP, e - EGP, ? - incomplete
AS Path Attributes: Or-ID - Originator ID, C-LST - Cluster List, LL Nexthop - Link Local Nexthop
Network Next Hop Metric LocPref Weight Path
* > RD: 10.255.0.0:20 mac-ip 0000.0101.0000 20.0.20.2
10.255.0.0 - 100 0 303 300 i
* > RD: 10.255.0.1:20 mac-ip 0000.0101.0000 20.0.20.2
10.255.0.1 - 100 0 303 301 i
As shown above, there are two EVPN MAC-IP routes for the multi-homed CE.
On the remote PE, to display the installed routes to the multi-homed
CE:
switch# show ip route vrf red 20.0.20.2/32
VRF: red
Codes: C - connected, S - static, K - kernel,
O - OSPF, IA - OSPF inter area, E1 - OSPF external type 1,
E2 - OSPF external type 2, N1 - OSPF NSSA external type 1,
N2 - OSPF NSSA external type2, B - BGP, B I - iBGP, B E - eBGP,
R - RIP, I L1 - IS-IS level 1, I L2 - IS-IS level 2,
O3 - OSPFv3, A B - BGP Aggregate, A O - OSPF Summary,
NG - Nexthop Group Static Route, V - VXLAN Control Service,
DH - DHCP client installed default route, M - Martian,
DP - Dynamic Policy Route, L - VRF Leaked
B E 20.0.20.2/32 [200/0] via VTEP 10.255.0.0 VNI 20000 router-mac 00:00:78:01:00:00
via VTEP 10.255.0.1 VNI 20000 router-mac 00:00:78:04:00:00
Two routes to the multi-homed CE are installed from the two EVPN MAC-IP routes and they
form L3 ECMP.
On the remote PE, to check the details of the two routes in BGP
RIB:
switch# show ip bgp 20.0.20.2/32 vrf red
BGP routing table information for VRF red
Router identifier 10.255.0.2, local AS number 302
BGP routing table entry for 20.0.20.2/32
Paths: 2 available
303 300
10.255.0.0 from 10.0.2.1 (0.0.1.1), imported EVPN route, RD 10.255.0.0:20
Origin IGP, metric 0, localpref 100, IGP metric 0, weight 0, received 00:14:43 ago,
valid, external, ECMP head, ECMP, best, ECMP contributor
Extended Community: Route-Target-AS:64500:10020 Route-Target-AS:64500:20000
TunnelEncap:tunnelTypeVxlan EvpnMacMobility:1 EvpnRouterMac:00:00:78:01:00:00
Remote VNI: 20000
Rx SAFI: Unicast
303 301
10.255.0.1 from 10.0.2.1 (0.0.1.1), imported EVPN route, RD 10.255.0.1:20
Origin IGP, metric 0, localpref 100, IGP metric 0, weight 0, received 00:14:43 ago,
valid, external, ECMP, ECMP contributor
Extended Community: Route-Target-AS:64500:10020 Route-Target-AS:64500:20000
TunnelEncap:tunnelTypeVxlan EvpnMacMobility:1 EvpnRouterMac:00:00:78:04:00:00
EvpnNdFlags:pflag
Remote VNI: 20000
Rx SAFI: Unicast
The second route has EvpnNdFlags:pflag to indicate
that this is a proxy MAC-IP route.
This command shows information about the SBD instance that is created when
evpn multicast is configured under an IP
VRF:
switch# show bgp evpn instance sbd red
EVPN instance: SBD red
Route distinguisher: 100:1
Service interface: VLAN-based
Local IP address: 10.0.0.20
Encapsulation type: VXLAN
vtep2#show bgp evpn instance sbd blue
EVPN instance: SBD red
Route distinguisher: 200:1
Service interface: VLAN-based
Local IP address: 10.0.0.20
Encapsulation type: VXLAN
The OISM supported capability is set in IMET routes for the SBD when evpn
multicast is configured for a VRF. The IGMP proxy flag is not set in IMET
routes for VLANs in the VRF unlessredistribute igmp is configured in
a
VLAN:
switch# show bgp evpn route-type imet next-hop 10.0.0.10 detail
BGP routing table information for VRF default
Router identifier 0.0.0.1, local AS number 300
BGP routing table entry for imet 10.0.0.10, Route Distinguisher: 10:1
Paths: 1 available
Local
10.0.0.10 from 10.0.0.1 (0.0.1.1)
Origin IGP, metric -, localpref 100, weight 0, valid, internal, best
Extended Community: Route-Target-AS:10:1 TunnelEncap:tunnelTypeVxlan
VNI: 10
PMSI Tunnel: PIM-SSM Tree, MPLS Label: 10, Leaf Information Required: false,
Tunnel ID: 10.0.0.10, 225.1.1.2
BGP routing table information for VRF default
Router identifier 0.0.0.1, local AS number 300
BGP routing table entry for imet 10.0.0.10, Route Distinguisher: 100:1
Paths: 1 available
Local
10.0.0.10 from 10.0.0.1 (0.0.1.1)
Origin IGP, metric -, localpref 100, weight 0, valid, internal, best
Extended Community: Route-Target-AS:100:1 TunnelEncap:tunnelTypeVxlan Multicast
Flags: IGMP proxy, OISM-supported, SBD
VNI: 100
PMSI Tunnel: Ingress Replication, MPLS Label: 100, Leaf Information Required: false,
Tunnel ID: 10.0.0.10
This command shows information about the single SMET route for the group with the RD of
VRF
red:
switch# show bgp evpn route-type smet multicast 228.1.1.1
BGP routing table information for VRF default
Router identifier 0.0.1.1, local AS number 300
Route status codes: s - suppressed, * - valid, > - active, E - ECMP head, e - ECMP
S - Stale, c - Contributing to ECMP, b - backup
% - Pending BGP convergence
Origin codes: i - IGP, e - EGP, ? - incomplete
AS Path Attributes: Or-ID - Originator ID, C-LST - Cluster List, LL Nexthop - Link Local Nexthop
Network Next Hop Metric LocPref Weight Path
* > RD: 100:1 smet (S, G): (*, 228.1.1.1) originating IP: 10.0.0.10
10.0.0.10 - 100 0 i
* > RD: 100:1 smet (S, G): (*, 228.1.1.1) originating IP: 10.0.0.20
- - - 0 i
* > RD: 100:1 smet (S, G): (*, 228.1.1.1) originating IP: 10.0.0.30
10.0.0.30 - 100 0 i
* > RD: 200:1 smet (S, G): (*, 228.1.1.1) originating IP: 10.0.0.20
- - - 0 i
* > RD: 200:1 smet (S, G): (*, 228.1.1.1) originating IP: 10.0.0.40
10.0.0.40 - 100 0 i
This command shows information about the SPMSI route for the
group:
switch# show bgp evpn route-type spmsi
BGP routing table information for VRF defaultRouter identifier 0.0.0.1, local AS number 300
Route status codes: s - suppressed, * - valid, > - active, E - ECMP head, e - ECMP
S - Stale, c - Contributing to ECMP, b - backup
% - Pending BGP convergence
Origin codes: i - IGP, e - EGP, ? - incomplete
AS Path Attributes: Or-ID - Originator ID, C-LST - Cluster List, LL Nexthop - Link Local Nexthop
Network Next Hop Metric LocPref Weight Path
* > RD: 10:1 spmsi (S, G): (*, *) originating IP: 10.0.0.10
10.0.0.10 - 100 0 i
* > RD: 10:1 spmsi (S, G): (*, *) originating IP: 10.0.0.20
- - - 0 i
* > RD: 20:1 spmsi (S, G): (*, *) originating IP: 10.0.0.20
- - - 0 i
* > RD: 30:1 spmsi (S, G): (*, *) originating IP: 10.0.0.20
- - - 0 i
* > RD: 40:1 spmsi (S, G): (*, *) originating IP: 10.0.0.20
- - - 0 i
* > RD: 10:1 spmsi (S, G): (*, *) originating IP: 10.0.0.30
10.0.0.30 - 100 0 i
* > RD: 20:1 spmsi (S, G): (*, *) originating IP: 10.0.0.30
10.0.0.30 - 100 0 i
* > RD: 30:1 spmsi (S, G): (*, *) originating IP: 10.0.0.30
10.0.0.30 - 100 0 i
* > RD: 40:1 spmsi (S, G): (*, *) originating IP: 10.0.0.30
10.0.0.30 - 100 0 i
* > RD: 30:1 spmsi (S, G): (*, *) originating IP: 10.0.0.40
10.0.0.40 - 100 0 i
* > RD: 100:1 spmsi (S, G): (*, *) originating IP: 10.0.0.10
10.0.0.10 - 100 0 i
* > RD: 100:1 spmsi (S, G): (*, *) originating IP: 10.0.0.20
- - - 0 i
* > RD: 200:1 spmsi (S, G): (*, *) originating IP: 10.0.0.20
- - - 0 i
* > RD: 100:1 spmsi (S, G): (*, *) originating IP: 10.0.0.30
10.0.0.30 - 100 0 i
* > RD: 200:1 spmsi (S, G): (*, *) originating IP: 10.0.0.30
10.0.0.30 - 100 0 i
* > RD: 200:1 spmsi (S, G): (*, *) originating IP: 10.0.0.40
10.0.0.40 - 100 0 i
Limitations
The following limitations are included in the EVPN VXLAN all-active multi-homing
integrated routing and bridging feature:
L2 loop-free protocols, such as Spanning Tree Protocol (STP) are not supported
between PE-CE with EVPN VXLAN All-Active Multi-homing. Users must ensure their
topology is loop-free. STP must be disabled for the Multihomed VLANs on PEs and
CEs.
A limit of two multi-homing destinations are installed at one time for any
particular MAC address. Any other valid destinations are ignored in the context
of switching unicast traffic until one of the active destinations is removed.
The multi-homing PEs themselves operate normally regardless of the number of PEs
on the ethernet segment; this limitation only affects the selection of a
destination for unicast traffic.
VXLAN GPE is not currently supported, so packets cannot be flagged as having
been broadcast. As a result, unicast packets that are known at the sender and
unknown at the receiver are dropped if the receiving PE is not a designated
forwarder. Similarly, unicast packets that are unknown at the sender and known
at the receiver are duplicated at the receiving CE. This state automatically
resolves itself as the BGP network distributes the appropriate type 1
auto-discovery and type 2 MAC/IP advertisement EVPN routes.
Fast mass withdrawal is not supported, so there may be a delay if an interface
harboring a large number of MAC addresses goes down.
