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VRF-Aware NAT for
WAN-WAN Topology with Symmetric Routing Box-to-Box Redundancy
In Cisco IOS XE
Release 3.14S, Network Address Translation (NAT) supports the VRF-Aware NAT for
WAN-WAN Topology with Symmetric Routing Box-to-Box Redundancy feature.
VRF-Aware NAT for WAN-to-LAN topology is already supported in NAT.
This module
describes this feature.
Finding Feature Information
Your software release may not support all the features documented in this module. For
the latest caveats and feature information, see Bug Search
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information about the features documented in this module, and to see a list of the
releases in which each feature is supported, see the feature information table.
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Restrictions for
VRF-Aware NAT for WAN-WAN Topology with Symmetric Routing Box-to-Box
Redundancy
The following
features are not supported:
Asymmetric routing
Cisco TrustSec
Edge switching services
Header Compression
IPsec
Lawful intercept
(Intercept twice, once at active and once at standby)
Information About
VRF-Aware NAT for WAN-WAN Topology with Symmetric Routing Box-to-Box
Redundancy
VRF-Aware
Box-to-Box High Availability Support
In Cisco IOS XE
Release 3.14S, Network Address Translation (NAT) supports VRF-aware box-to-box
high availability in a WAN-to-WAN topology.
To support
VRF-aware box-to-box high availability, NAT ties the NAT mapping with a
mandatorily configured mapping ID when a redundancy group (RG) is configured.
The standby device retrieves the correct locally significant VRF ID from the
mapping ID after synchronization. The VRF ID is set before NAT processes or
translates a packet on the active device.
The VRF-aware
box-to-box high availability configuration must be the same on both active and
standby devices. The VRF configuration must use the same VRF name at active and
standby devices. NAT provides a hashed VRF name value in the high availability
message, and sends it to active and standby devices, so that the corresponding
local VRF ID is converted at the peer device by using the VRF name hash
value-to-VRF ID mapping.
Note
In some cases you might experience FTP disconnection after failover
in a NAT B2B scenario. To resolve this issue, quit the existing FTP connection
and start a new FTP connection.
Stateful Interchassis Redundancy Overview
You can configure the Stateful Interchassis Redundancy feature to determine the active device from a group of devices, based
on a number of failover conditions. When a failover occurs, the standby device seamlessly takes over, starts performing traffic
forwarding services, and maintains a dynamic routing table.
Note
Manually shutting down the control or data interface link on an active NAT router results in traffic outage as the NAT router
never transitions to active state.
Stateful Interchassis
Redundancy Operation in NAT
You can configure
pairs of devices to act as hot standbys for each other. Redundancy is
configured on an interface basis. Pairs of redundant interfaces are known as
redundancy groups (RGs). Redundancy occurs at an application level and does not
require a complete physical failure of the interface or device for a switchover
of the application to occur. When a switchover occurs, the application activity
continues to run seamlessly on the redundant interface.
The figure below
depicts an active/standby load-sharing scenario. The figure shows how an RG is
configured for a pair of devices that has one outgoing interface. Group A on
Router 1 is the active RG and Group A on Router 2 is the standby RG.
Redundant devices
are joined by a configurable control link and a data synchronization link. The
control link is used to communicate the status of devices. The data
synchronization link is used to transfer stateful information from Network
Address Translation (NAT) and the firewall and synchronize the stateful
database. The pairs of redundant interfaces are configured with the same unique
ID number known as the redundant interface identifier (RII).
The status of
redundancy group members is determined through the use of hello messages sent
over the control link. The software considers either device not responding to a
hello message within a configurable amount of time to be a failure and
initiates a switchover. For the software to detect a failure in milliseconds,
control links run the failover protocol that is integrated with the
Bidirectional Forwarding Detection (BFD) protocol. You can configure the
following parameters for hello messages:
Hello time—Interval at
which hello messages are sent.
Hold time—Amount of time
before which the active or standby device is declared to be down.
The hello time
defaults to 3 seconds to align with the Hot Standby Router Protocol (HSRP), and
the hold time defaults to 10 seconds. You can also configure these timers in
milliseconds by using the
timers hellotime
msec command.
To determine the
pairs of interfaces that are affected by the switchover, you must configure a
unique ID for each pair of redundant interfaces. This ID is known as the RII
that is associated with the interface.
A switchover to the
standby device can occur when the priority setting that is configured on each
device changes. The device with the highest priority value acts as the active
device. If a fault occurs on either the active or standby device, the priority
of the device is decremented by a configurable amount known as the weight. If
the priority of the active device falls below the priority of the standby
device, a switchover occurs and the standby device becomes the active device.
This default behavior can be overridden by disabling the preemption attribute
for the RG. You can also configure each interface to decrease the priority when
the Layer 1 state of the interface goes down. The priority that is configured
overrides the default priority of an RG.
Each failure event
that causes a modification of an RG priority generates a syslog entry that
contains a time stamp, the RG that was affected, the previous priority, the new
priority, and a description of the failure event cause.
A switchover also
can occur when the priority of a device or interface falls below a configurable
threshold level.
A switchover to the
standby device occurs under the following circumstances:
Power loss or a reload
occurs on the active device (including reloads).
The run-time priority of
the active device goes below that of the standby device (with preempt
configured).
The run-time priority of
the active device goes below that of the configured threshold.
The redundancy group on
the active device is reloaded manually. Use the
redundancyapplicationreloadgrouprg-number
command for a manual reload.
How to Configure
VRF-Aware NAT for WAN-WAN Topology with Symmetric Routing Box-to-Box
Redundancy
The configuration
for VRF-aware box-to-box redundancy is same as the configuration for stateful
interchassis redundancy. For more information, see the "Configuring Stateful
Interchassis Redundancy" module in the
IP Addressing: NAT
Configuration Guide.
Configuration
Examples for VRF-Aware NAT for WAN-WAN Topology with Symmetric Routing
Box-to-Box Redundancy
Example:
Configuring VRF-Aware NAT for WAN-WAN Topology with Symmetric Routing
Box-to-Box Redundancy
The following is
a sample WAN-to-WAN symmetric routing configuration:
vrf definition Mgmt-intf
address-family ipv4
exit-address-family
!
address-family ipv6
exit-address-family
!
!
vrf definition VRFA
rd 100:1
route-target export 100:1
route-target import 100:1
address-family ipv4
exit-address-family
!
!
no logging console
no aaa new-model
!
multilink bundle-name authenticated
!
redundancy
mode sso
application redundancy
group 1
preempt
priority 120
control GigabitEthernet 0/0/1 protocol 1
data GigabitEthernet 0/0/2
!
!
!
!
ip tftp source-interface GigabitEthernet0
ip tftp blocksize 8192
!
track 1 interface GigabitEthernet 0/0/4 line-protocol
!
interface Loopback 0
ip address 209.165.201.1 255.255.255.224
!
interface GigabitEthernet 0/0/0
vrf forwarding VRFA
ip address 192.168.0.1 255.255.255.248
ip nat inside
negotiation auto
bfd interval 50 min_rx 50 multiplier 3
redundancy rii 2
!
interface GigabitEthernet 0/0/1
ip address 209.165.202.129 255.255.255.224
negotiation auto
!
interface GigabitEthernet 0/0/2
ip address 192.0.2.1 255.255.255.224
negotiation auto
!
interface GigabitEthernet 0/0/3
ip address 198.51.100.1 255.255.255.240
negotiation auto
!
interface GigabitEthernet 0/0/4
ip address 203.0.113.1 255.255.255.240
negotiation auto
!
interface GigabitEthernet 0
vrf forwarding Mgmt-intf
ip address 172.16.0.1 255.255.0.0
negotiation auto
!
interface vasileft 1
vrf forwarding VRFA
ip address 10.4.4.1 255.255.0.0
ip nat outside
no keepalive
!
interface vasiright 1
ip address 10.4.4.2 255.255.0.0
no keepalive
!
router mobile
!
router bgp 577
bgp router-id 1.1.1.1
bgp log-neighbor-changes
neighbor 203.0.113.1 remote-as 223
neighbor 203.0.113.1 description PEERING to PTNR neighbor 10.4.4.1 remote-as 577
neighbor 10.4.4.1 description PEEERING to VASI VRFA interface
!
address-family ipv4
network 203.0.113.1 mask 255.255.255.240
network 10.4.0.0 mask 255.255.0.0
network 209.165.200.224 mask 255.255.255.224
neighbor 203.0.113.1 activate
neighbor 10.4.4.1 activate
neighbor 10.4.4.1 next-hop-self
exit-address-family
!
address-family ipv4 vrf VRFA
bgp router-id 4.4.4.4
network 192.168.0.0 mask 255.255.255.248
network 10.4.0.0 mask 255.255.0.0
redistribute connected
redistribute static
neighbor 192.168.0.2 remote-as 65004
neighbor 192.168.0.2 fall-over bfd
neighbor 192.168.0.2 activate
neighbor 10.4.4.2 remote-as 577
neighbor 10.4.4.2 description PEERING to VASI Global intf
neighbor 10.4.4.2 activate
exit-address-family
!
ip nat switchover replication http
ip nat pool att_pool 209.165.200.225 209.165.200.225 prefix-length 16
ip nat inside source list 4 pool att_pool redundancy 1 mapping-id 100 vrf VRFA overload
ip forward-protocol nd
!
no ip http server
no ip http secure-server
ip route 203.0.113.1 255.255.255.224 10.4.4.1
ip route 192.168.0.0 255.255.0.0 10.4.4.1
ip route 209.165.200.224 255.255.255.224 10.4.4.1
ip route vrf Mgmt-intf 209.165.200.1 255.255.255.224 172.16.0.0
!
ip prefix-list VRF_Pool seq 5 permit 209.165.200.0/27
ip prefix-list p1-adv-1 seq 5 permit 209.165.200.0/27
ip prefix-list p1-exist-1 seq 5 permit 203.0.113.193/27
logging esm config
access-list 4 permit 203.0.113.193 255.255.255.224
!
control-plane
line console 0
stopbits 1
!
line vty 0 3
login
!
line vty 4
password lab
login
!
end
Additional
References for VRF-Aware NAT for WAN-WAN Topology with Symmetric Routing
Box-to-Box Redundancy
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Feature
Information for VRF-Aware NAT for WAN-WAN Topology with Symmetric Routing
Box-to-Box Redundancy
Table 1. Feature Information for
VRF-Aware NAT for WAN-WAN Topology with Symmetric Routing Box-to-Box
Redundancy
Feature
Name
Releases
Feature
Information
VRF-Aware
NAT for WAN-WAN Topology with Symmetric Routing Box-to-Box Redundancy
Cisco IOS
XE Release 3.14S
In Cisco
IOS XE Release 3.14S, Network Address Translation (NAT) supports the VRF-Aware
NAT for WAN-WAN Topology with Symmetric Routing Box-to-Box Redundancy feature.
This feature contains the following two features: VRF-aware stateful
interchassis redundancy and VRF-aware interchassis symmetric routing.
No
commands were introduced or modified by this feature.