Introduction

Cisco's CGv6 (Carrier Grade IPv6) solution helps customer transitioning from IPv4 to IPv6 gradually, maintaining business continuity. VSM (Virtualized Services Module) on ASR9K is a Service Card which provides different CGv6 Applications. This is the next generation Service Card after ISM (Integrated Services Module). This document talks about how to deploy NAT44 (Network Address Translation - from IPv4 to IPv4), one of the applications fall under CGv6 suite of applications.

This document does NOT intend to cover details on VSM, how to install CGv6 software on VSM, how to trouble-shoot CGv6 issues, CGv6 Applications other than NAT44.

DISCLAIMER: This document contains some Public IP addresses to explain different deployment use-cases and features related to NAT44. The Public IP addresses are picked up randomly and matching of these addresses with any specific customer's or organization's public IP is purely coincidental. Please DO NOT use these public addresses in your NAT setup / deployment, unless the public IP addresses are not owned by you / your organization. Cisco is not responsible for any issues arising out of this.

Introduction to NAT44

This section introduces NAT44 and terminologies related to it.

1. Why NAT44 ?

IPv4 address is 32-bit long which means there can be 4,294,967,296 (i.e., 4 billions) unique addresses. However, population on earth has crossed 7 billions and is still growing. Also, nowadays, a single person can own multiple IP devices, each having its own IP address. Thus, we are running short of IPv4 addresses. In 2 of the 5 RIR (Regional Internet Registries), IPv4 address exhaustion is declared (in its last /8 stage).

Apat from moving to IPv6 (which uses 128-bit long IP address), an alternate mechanism is to use NAT44 where Private IP addresses can be re-used in different Private networks, but can be translated to a unique Public IP address when the packet enters Internet or Public network.

If you are a Service Provider and running short of Public IP addresses, NAT44 should be of great usefulness to you as an intermediate solution before you slowly convert your IPv4 network into IPv6.

2. NAT44 Overview

NAT44 literally means translating one IPv4 address to another IPv4 address. "Typically", first IPv4 address is "Private" IPv4 Address (defined by RFC 1918) and second IPv4 address is "Public" (non-Private) IPv4 address. As defined by RFC 1918, Private IPv4 addresses fall in the following blocks.

However, it is to be noted that not always "Private" IPv4 address is to be translated to "Public" IPv4 address. There are deployment cases where NAT44 is used to convert "Private" IPv4 address (say, 192.168.x.x range) to another "Private" IPv4 address (say, 10.x.x.x range) as well.

NOTE: In this document, however, we will refer "Private" side as the pre-NAT side of the NAT device and "Public" side as the post-NAT side of the NAT device, irrespective of the actual IP address being used.

One more important point, although NAT indicates Network Address Translation, it is actually NAPT (Network Address and Port Translation). What it means is - in addition to IPv4 address, Layer 4 (UDP/TCP) port is also translated by NAT44.

NOTE: Unless mentioned otherwise, in this document, NAT44 will indicate translation of both IPv4 address and Port.

Following Layer 4 Protocols are supported by NAT44 implementation on VSM.

• UDP (IP Protocol 17) - UDP Port number (2 bytes) is translated along with IPv4 address.
• TCP (IP Protocol 6) - TCP Port number (2 bytes) is translated along with IPv4 address.
• ICMP (IP Protocol 1) - ICMP Identifier field (2 bytes) in Echo Request and Echo Response messages is used as (dummy) Layer 4 port.
• GRE (used with PPTP ALG, IP Protocol 47) - Call ID field (2 bytes) is used as (dummy) Layer 4 port.

Another useful property of NAT44 is multiple Private IP addresses can be mapped to one Public IP address. This is possible as all of the 65,536 ports (0 to 65,535) on any Private IP address are typically not used by Applications.

Following diagram shows how NAT44 works.

As shown above, the Private IP addresses 192.168.1.1 and 192.168.1.5 are translated to same Public IP address 20.1.1.1 (along with specific Layer 4 ports) by the NAT44 device (VSM on ASR9K). The translation entries are maintained in NAT DB at the NAT44 device.

3. Basic Terminologies

In this section, let us get introduced with different terminologies related to NAT44 deployment on VSM.

4. Standard Compliance

Following are the important RFCs that the NAT44 solution on VSM complies (most of the cases, fully) to.

Basic Deployment Scenario: NAT444

This section talks about one of the basic deployment scenario for NAT44 which is called "Double NAT44" or "NAT444".

5. Network Diagram

Following diagram depicts NAT444.

In the above diagram, there are 2 NAT44 instances shown (hence, it is termed as "Dual NAT44" or "NAT444").

• CPE (Customer Premise Equipment) NAT44 - This typically happens within customer premise. Each customer / end user is given one (or, more) IPv4 address (10.8.1.11 in the above example) by the Service Provider. There could be multiple devices within customer premise which will have IPv4 addresses in 192.168.1.x network (as shown in the above diagram). As an example, CPE NAT44 device translates IPv4 address/Port of 192.168.1.1:4128 to 10.8.1.11:6593, while sending the packet out to provider network. A NAT table is maintained at CPE NAT level as well. But, the scale of this is less (as there won't be too many end devices). As you can see, both Private-side and Public-side IP addresses used here are from RFC 1918 (i.e., Private IPv4 addresses).

• CGN (Carrier Grade NAT) or LSN (Large Scale NAT) - This happens within the Service Provider network. CGN device (as per the diagram) translates Private IPv4 address/Port of 10.8.1.11:6593 to a public IPv4 address/Port of 170.0.0.1:9185 before sending the packet to Internet. A relatively huge NAT table is maintained at CGN level as it may need to deal with millions of CPEs.

VSM with ASR9K will be positioned as CGN in Service Provider network.

6. NAT44 on VSM Configuration

Before we start configuring NAT44 on VSM, let us understand the following concepts related to NAT44 implementation on VSM.

• CGN Instance - On each VSM card, we can configure one CGN instance (<cgn1> in the diagram below).
• NAT44 Instance - On each VSM card, we can configure one NAT44 instance (<nat1> in the diagram below).
• ServiceInfra interface - ServiceInfra interface is a virtual interface which is used by the internal (to ASR9K) management / control traffic. We need 1 ServiceInfra interface per VSM card. ServiceInfra interface cannot be in any VRF (needs to be in default VRF).
• ServiceApp interface - ServiceApp interface is a virtual interface which is used to bring CGv6 Application (NAT44) data traffic to VSM card. We need 1 pair of ServiceApp interface for each VRF instance - 1 Inside ServiceApp interface (ServiceApp <x> in the diagram below) to bring Inside traffic to VSM (I2O direction) and 1 Outside ServiceApp interface (ServiceApp <y> in the diagram below) to bring Outside traffic to VSM (O2I direction).

NOTE: ServiceInfra and ServiceApp interfaces are used within the ASR9K router only and do not need to be announced/redistributed into IGP.

• Inside VRF instance - Within one NAT44 instance, we can have multiple Inside VRF instances. For each Inside VRF instance, we can have different NAT44 parameters configured. Inside ServiceApp must be within one unique Inside VRF. Outside ServiceApp may or may not be within a (Outside) VRF.

NOTEs:
- We cannot have multiple Inside ServiceApps within same Inside VRF. 
- We can, however, have multiple Outside ServiceApps within same Outside VRF or default VRF.
- Inside and Outside VRF cannot be same.

• Logical Partitioning inside VSM - Internally, VSM is divided into 2 Logic Partitions. Hence, in order to achive full throughput and scale limit (per VSM), you should have minimal of 2 Inside VRFs, 4 ServiceApp interfaces (2 in each partition), 2 Public IP address pool, etc. Traffic / subscribers which needs to avail NAT44 service also needs to be divided into 2 groups (each one associated to each Inside VRF). Following table shows the partitioning of ServiceApp interfaces between these 2 groups (which needs to be kept in mind during configuration).

NOTE: ServiceApp interafce pair needs to be selected from same Logical Partition (as per the above table). Otherwise, packets will be dropped. Using consecutive numbers for ServiceApp interface pair will be recommended (as shown above).

Following diagram provides summary / overview of NAT44 configuration for VSM.

Below are sample configurations for each of the above steps.

! Install CGv6 VM's OVA package
! -----------------------------
RP/0/RSP0/CPU0:ios# virtual-service install name cgn123 package /disk0a:/usr/vsmcgv6.ova node 0/1/CPU0

! Configure and Activate CGv6 VM
! ------------------------------

RP/0/RSP0/CPU0:ios#conf t
Fri Aug 2 18:10:25.525 UTC
RP/0/RSP0/CPU0:ios(config)#virtual-service cgn123
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/0
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/1
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/2
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/3
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/4
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/5
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/6
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/7
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/8
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/9
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/10
RP/0/RSP0/CPU0:ios(config-virt-service)#vnic interface tenGigE 0/1/1/11
RP/0/RSP0/CPU0:ios(config-virt-service)#commit
Fri Aug 2 18:11:34.285 UTC
RP/0/RSP0/CPU0:ios(config-virt-service)#activate 
RP/0/RSP0/CPU0:ios(config-virt-service)#commit

! Bring up 10-GE interfaces on VSM
! Must before configuring any ServiceInfra/App interfaces
! -------------------------------------------------------
interface TenGigE 0/1/1/0
  no shut
interface TenGigE 0/1/1/1
  no shut
interface TenGigE 0/1/1/2
  no shut
interface TenGigE 0/1/1/3
  no shut
interface TenGigE 0/1/1/4
  no shut
interface TenGigE 0/1/1/5
  no shut
interface TenGigE 0/1/1/6
  no shut
interface TenGigE 0/1/1/7
  no shut
interface TenGigE 0/1/1/8
  no shut
interface TenGigE 0/1/1/9
  no shut
interface TenGigE 0/1/1/10
  no shut
interface TenGigE 0/1/1/11
  no shut
 
! Define Service Infra interface
! ------------------------------
interface ServiceInfra 1
 
  ! Assign IPv4 address and netmask
  ipv4 address 100.1.1.1 255.255.255.252
 
  ! Define service location
  service-location 0/1/CPU0

Please note that inside and outside VRFs are also need to be configured, as shown below.

vrf ivrf1
    address-family ipv4 unicast
vrf ivrf2
    address-family ipv4 unicast

vrf ovrf1
    address-family ipv4 unicast
vrf ovrf2
    address-family ipv4 unicast

Once the VRFs are configured, let us proceed with further configuration.

! Configure Ingress interfaces
! ----------------------------
interface TenGigE0/0/0/0
 ! Add it to Inside VRF
 vrf ivrf1
 ! Assign IP address to it
 ipv4 address 10.10.10.1 255.255.255.0
!
interface TenGigE0/0/0/1
 vrf ivrf2
 ipv4 address 10.10.11.1 255.255.255.0
 
! Configure Egress interfaces
! --------------------------
interface TenGigE0/2/0/0
 vrf ovrf1
 ipv4 address 20.20.20.1 255.255.255.0
interface TenGigE0/2/0/1
 vrf ovrf2
 ipv4 address 20.20.21.1 255.255.255.0

! Define CGN Instance
! -------------------
service cgn cgn1
 ! Define location
 service-location preferred-active 0/1/CPU0
 ! Define NAT44 Service Type and instance (one per VSM card)
 service-type nat44 nat1
  ! Define per-user Port limit for NAT44 instance
  portlimit 250
  ! Enable Active FTP ALG
  alg ActiveFTP
  ! Define UDP protocol session timeout values
  protocol udp
    session initial timeout 240
    session active timeout 600
  ! Define inside VRF
  inside-vrf ivrf1
    ! Define Public IP address Pool
    map outside-vrf ovrf1 address-pool 100.1.1.0/24
  ! Define inside VRF
  inside-vrf ivrf2
    ! Define Public IP address Pool
    map outside-vrf ovrf2 address-pool 100.1.2.0/24

! Define Inside Service App interfaces
! ------------------------------------
interface ServiceApp 1
 ! Define VRF where it should belong to (optional)
 vrf ivrf1
  ! Assign IPv4 address and netmask
  ipv4 address 1.1.1.1/30
  ! Define CGN instance and service type in which it belongs to
  service cgn cgn1 service-type nat44
interface ServiceApp 3
 vrf ivrf2
  ipv4 address 1.1.2.1/30
  service cgn cgn1 service-type nat44
! Define Outside Service App interfaces
! -------------------------------------
interface ServiceApp 2
 vrf ovrf1
  ipv4 address 2.1.1.1/30
  service cgn cgn1 service-type nat44 
interface ServiceApp 4
 vrf ovrf2
  ipv4 address 2.1.2.1/30
  service cgn cgn1 service-type nat44

! Define static route for Inside-to-outside traffic
! -------------------------------------------------
router static
 ! Specify the Inside VRF
 vrf ivrf1
  ! Define address family
  address-family ipv4 unicast
   ! Re-direct all traffic to Inside Service App
   0.0.0.0/0 ServiceApp 1
router static
 vrf ivrf2
  address-family ipv4 unicast
   0.0.0.0/0 ServiceApp 3
! Define static route for Outside-to-inside traffic
! -------------------------------------------------
router static
 vrf ovrf1
  address-family ipv4 unicast
   100.1.1.0/24 ServiceApp 2
router static
 vrf ovrf2
  address-family ipv4 unicast
   100.1.2.0/24 ServiceApp 4

7. I2O Packet Flow on VSM

Following diagram shows the packet flow within ASR9K (including VSM) for Inside to Outside NAT44 traffic at a high-level.

Step 1: Packet from Inside / Private side reaches ASR9K Ingress Line Card.

Step 2: Forwarding lookup (rule added by static route, ACL-based forwarding, etc.) should forward the packet to VSM card, via Inside ServiceApp 1 interface. Inside VRF (ivrf1) will be used during the forwarding lookup.

Step 3: NAT44 Application performs necessary action for the packet. As it is Inside-to-Outside packet, it first checks if there is a NAT entry exists for the source IP (10.10.10.2) and port (5000). If it does not exists, it allocates a Public IP (from the Public IP pool configured) and port and creates a NAT entry. From the NAT entry, it finds the corresponding Public IP (100.2.0.192) and port (23156) and replaces the existing Source IP and port with the same.

Step 4: After NAT translation is done, a forwarding lookup is done in Outside VRF (ovrf1) for the destination IP address (5.5.5.2) which forwards the packet to egress LC interface.

Step 5: Egress Line Card interface sends the packet out to Outside / Public side.

8. O2I Packet Flow on VSM

Following diagram shows the packet flow within ASR9K (including VSM) for Outside to Inside NAT44 traffic at a high-level.

Step 1: Packet from Outside / Public side reaches ASR9K Ingress Line Card.

Step 2: Forwarding lookup (rule added by static route, ACL-based forwarding, etc.) should forward the packet to VSM card, via Outside ServiceApp 2 interface. Outside VRF (ovrf1), if being configured, will be used during the forwarding lookup.

Step 3: NAT44 Application performs necessary action for the packet. As it is Outside-to-Inside packet, it first checks if there is a NAT entry exists for the Destination IP (100.2.0.192) and port (23156). If it does not exists, packet is dropped. Otherwise, from the NAT entry, it finds the corresponding Private IP (10.10.10.2) and port (5000) and replaces the existing Destination IP and port with the same.

Step 4: After (reverse) NAT translation is done, a forwarding lookup is done in Inside VRF (ivrf1) for the destination IP address (10.10.10.2) which forwards the packet to egress LC interface.

Step 5: Egress Line Card interface sends the packet out to Inside / Private side.

Parameters to be considered before Deployment

Before deploying NAT44 solution with VSM, you need to analyze the deployment scenario/requirement and come up with the appropriate values of different configurable parameters related to NAT44. Improper selection of the parameters may not address the deployment goals accurately.

9. Performance and Scale

These are possibly the most important parameters to be considered during deployment. These are not configurable parameters, but these will determine how many VSM cards will be needed for the NAT44 solution.

• Identify the performance and scale need for NAT44 solution
• Please check "CGv6 on VSM Feature Support" page, to find out the supported scale and performance values.

Based on the above two, find out how many VSM cards will be needed for the solution.

NOTE: For better NAT44 performance, Cisco recommends keeping the default physical interface MTU size on the customer-facing interfaces in NAT44 deployment.

10. Address Pool and Mapping

Identify the following for the deployment scenario.

• How many Public IPv4 addresses the customer has to form the Public IP pool ?
• How many (approximately) Private (Pre-NAT) IPv4 addresses the customer has ?
• Do you need to limit the ratio of Private to Public IP addresses ?

Based on the same, number of inside VRFs, address pools, many-to-one ratio can be configured as follows.

service cgn cgn1 
 service-type nat44 nat1 
  inside-vrf ivrf1
   ! Define Public IP address Pool
   map outside-vrf ovrf1 address-pool 100.1.1.0/20
   ! Define Many to one IP addresses maping
   map ip many-to-one 6

NOTE: Network address and Broadcast address in the subnet (as configuredby address-pool parameter) are also used as NAT'ed Public / Outside IP address.

11. VRF (Inside and Outside)

Identify the following VRF related information from deployment requirement.

• Whether Private side traffic comes / can / should come in VRF or not ?
• Whenther Public side traffic can / should go in a VRF or not ?
• Is there a overlap of Private IP addresses or not ?
• Are there different values of certain parameters (which are configured per-VRF) needed or not ?
• What is the Scale and Bandwidth requirement for each VRF

Above information will determine,

• How many Inside and Outside VRFs will be needed in the solution
• Which per-Inside VRF parameters need to be set
• How the Public IP pool needs to be divided

12. Port Limit (Per-User)

As NAT DB is shared among all users, there could be a situation where few users (Private IP owners) uses lots of NAT entries (in thousands) and because of the same, new users cannot create NAT entries. In order to keep control on creation of NAT entries by a single user, Port Limit parameter is introduced. Port limit indicates how many port numbers are allowed per Private / Inside IP address. If any flow arrives after Port Limit is reached, no NAT entry will be created for the same and the packets for the new flows will be dropped. The Port limit value will be same for all Private IP addresses.

NOTE: Port Limit is specified per Private / Inside IP address and NOT per Public / Outside IP address.

Find out the following:

• How many ports will be needed by a Private IP address holder ?
• How many Public IP addresses are available ?

Based on the above Port Limit can be configured as follows.

service cgn cgn1 
 ! Define NAT44 Service Type and instance (one per VSM card)
 service-type nat44 nat1
  ! Define per-user Port limit for NAT44 instance
  portlimit 250

13. External Logging (Netflow and Syslog)

As you have seen above, a NAT DB entry is created for each new flow (Private IP address and port) which keeps the mapping of Private / Inside IP address + Port and Public / Outside IP address + Port. The NAT DB entry is deleted when the flow terminates (because of timeout and any user intervention).

On VSM, we support millions of NAT translations with high (in thousands and millions) setup and deletion rate (Please refer to CGv6 on VSM Feature List for scale numbers). This produces huge amount of NAT translation entries / records which cannot be stored / saved on VSM or ASR9K because of limited disk space. Hence, there is a need of having external servers where these translations can be saved.

The creation and deletion of NAT transactions (also called "Logging Records") are very important to be saved to get association of different IP addresses. In almost all countries, it is mandated by the Lawful Agencies / Authorities that the Service Provide must provide these records accurately so that the agencies can find out the owner of these APIs for different reasons. Thus it becomes a very important feature for deployment of NAT44.

On VSM, we support the 2 formats of logging records - Netflow (version 9) and Syslog. Table below compares the two.

Logging records are sent to Logging Server (IP address and Port for which is configurable) either when the Logging packet is complete or timeout occurs. Logging packets are sent with ServiceInfra interface's remote IP (for e.g., 100.1.1.2 is the remote IP of 100.1.1.1) as Source address.

NOTE: External Logging Server IP address should be reachable via any ASR9K LC interface (NOT via Management Ethernet interface), in default VRF.

Destination-Based Logging (DBL)

In some countries, Lawful Agencies also require the Service Provider to provide the Destination IP address and Port (along with Source IP address and Port information) as part of Logging Record. This is termed as Destination-Based Logging (DBL).

NOTE: Including Destination (IP + Port) information in the Logging Record will increase the size of the Record. 

DBL can be supported with Netflow v9 as well as with Syslog.

Bulk Port Allocation (BPA)

In order to reduce the size of the logging record, a feature called Bulk Port Allocation (BPA) is introduced.

Without BPA, for every new flow, a Port is allocated for the Public IP and a new logging record is created with Private IP + Port and Public IP + Port. Similarly, another Logging record is created when a flow or NAT entry is deleted.

Following table captures the working of it (without BPA) with some sample IP addresses and port numbers.

With BPA, for the first new flow, a bulk (group) of Ports are allocated (but only one port from the group is assigned for the new flow) for the Public IP and a logging record is created with Private IP and Public IP + Start Port + End Port. Next time, a new flow comes, a new port from the already allocated pool is taken and no logging record is created. Only when all the ports in the group are used, a new bulk is allocated and logging record is created. Similarly, when all the ports from a group is released, a (deletion) logging record is generated.

Following table captures the working of it (with BPA enabled) with sample IP addresses and port numbers.

Following table illustrates the amount stoage space needed per second with varying translation creation + deletion rate for both Netflow and Syslog (with DBL disabled). It also shows the impact of BPA on the storage.

NOTE: Both DBL and BPA cannot be enabled at the same  time. This is because BPA requires logging record to be generated for a  set of NAT entries whereas DBL requires logging record to be generated  for each NAT entry. These are conflicting requirements.

Please collect the following information and accordingly determine External Logging related parameter configuration.

• What setup rate needs to be supported ?
• Do the Lawful Agencies mandate DBL ?
• What protocol (netflow or syslog) the external logging server support ?
• How many packets per second the logging server can support ?
• How many logging servers need to be configured ?
• How much space would be needed for storing logging record ? How much would the cost of disk space ?

Following table shows how to configure different external logging parameters.

service cgn cgn1
 service-type nat44 nat1
  inside-vrf ivrf1
   ! Define Netflow V9 logging configuration
   external-logging netflow version 9
    ! Define netflow server configuration
    server
     ! Define logging server address and port
     address 10.10.0.0 port 2055
     ! Define Path MTU size
     path-mtu 1200
     ! Define refresh rate
     refresh-rate 50
     ! Define timeout
     timeout 50 
    ! Define Syslog logging configuration
    external-logging syslog
     server
      address 10.10.0.1 port 514

14. NAT Session Timeouts (TCP, UDP, ICMP)

As the new flows creates NAT entries, we need a way to delete those NAT entries as well. Protocols like UDP is connection-less and hence, there is no way to identify when a session / connection has ended by inspecting the packets. Also, in some cases, if no packet flows between the applications for a long period of time, there is no point in holding on to the NAT entries, as that will disallow creation of new NAT sessions.

Due the above reasons, NAT entries are deleted when session timeout happens.

For every protocol (TCP, UDP, ICMP), we have different types and values of session timeouts, as depicted below.

• TCP - It has two timeouts.                                                                                       
  • Initial Timeout - It kicks in before the connection moves into Active state. Default: 120 sec.
  • Active Timeout - It kicks in when the connection is in Active state. Default: 30 Minutes.
• UDP - It has two timeouts as well.                                                                                       
  • Initial Timeout - It kicks in before the connection moves into Active state. Default: 30 sec.
  • Active Timeout - It kicks in when the connection is in Active state. Default: 120 sec.
• ICMP - It has one timeout. Default: 60 sec.

If the timeout is configured to be too less, NAT sessions will be deleted too soon, resulting in changing of Public IP addresses. This may cause issues with the Applications.

If the timeout is configured to be too high, NAT sessions will remain in the system for long time (even though there is no data is flowing using the session) and it will restrict new sessions to be created as well (resulting in dropping of those packets).

Hence, timeout value needs to be set appropriately.

NOTE: These timeouts are set for the NAT44 instance (per VSM card) and cannot be configured differently for each Inside VRF.

You need to have some knowledge about the following, to determine the timeout values.

• Application traffic that is going through the network                                                                                         
  • How sensitive it is with respect to change in IP address ?
  • How periodically, it would generate packets
• How many NAT sessions are expected ?

Following table shows how to configure timeout values for different protocols.

service cgn cgn1 
 service-type nat44 nat1
  ! Define UDP protocol session timeout values
  protocol udp
   session initial timeout 65535
   session active timeout 65535
  ! Define TCP protocol session timeout values
  protocol tcp
   session initial timeout 65535
   session active timeout 65535
  ! Define ICMP protocol session timeout value
  protocol icmp
   timeout 908

15. Endpoint Independent and Dependent Filtering (EIF / EDF)

Filtering behavior of NAT is explained in Section 5 of RFC 4787.

When an internal endpoint opens an outgoing session through a NAT,    the NAT assigns a filtering rule for the mapping between an internal    IP:port (X:x) and external IP:port (Y:y) tuple.     The key behavior to describe is what criteria are used by the NAT to    filter (Outside-to-Inside, O2I) packets originating from specific external endpoints. We have the following 3 options here:

• Endpoint-Independent Filtering (EIF) - NAT forwards any packet destined to X:x, regardless of the external IP address and port source.
• Endpoint-Dependent Filtering (EDF)
  • Address-Dependent Filtering - NAT forwards any packet destined to X:x, provided it is coming from the external IP to which I2O packets were sent earlier.
  • Address and Port-Dependent Filtering - NAT forwards any packet destined to X:x, provided it is coming from the external IP:port to which I2O packets were sent earlier.

All the behavior are explained in the following diagram with an example scenario.

As shown above, depending on the filtering policy and NAT session DB, O2I packets coming from specific IP and port will be either allowed to cross NAT device (VSM card) or dropped by CGv6 Application on VSM.

Table below shows how to configure CGv6 application on VSM to support different filtering policy.

! To configure Endpoint-Independent Filtering
! -------------------------------------------
service cgn cgn1
 service-type nat44 nat1
  inside-vrf ivrf1
   ! Do not specify 'filter-policy' CLI for Endpoint-Independent Filtering

! To configure Address Dependent Filtering
! ----------------------------------------
service cgn cgn1
 service-type nat44 nat1
  inside-vrf ivrf1
   ! Filtering policy for Address Dependent Filtering
   filter-policy ignore-port

! To configure Address and Port Dependent Filtering
! -------------------------------------------------
service cgn cgn1
 service-type nat44 nat1
  inside-vrf ivrf1
   ! Filtering policy for Address and Port Dependent Filtering
   filter-policy

16. Traffic Diversion (to VSM)

We can use different mechanisms to divert the traffic to VSM card (to specific ServiceApp interface).

Default Route

If the inside traffic is arriving on a (Inside) VRF and ALL traffic needs to undergo NAT44 operation, we can add a default route under the VRF to divert traffic to the Inside ServiceApp (as shown below).

! Define static route for Inside-to-outside traffic
! -------------------------------------------------
router static
 ! Specify the Inside VRF
 vrf insidevrf1
  ! Define address family
  address-family ipv4 unicast 
   ! Re-direct all traffic to Inside Service App
   0.0.0.0/0 serviceapp 1

Static Route

In some cases, Outside ServiceApp interfaces reside in same / default VRF. Hence, in order to divert O2I traffic to specific Outside ServiceApp interfaces, static route can be used in the following way.

router static
 address-family ipv4 unicast
  ! Diverting traffic for one Public IP pool to one Outside ServiceApp
  100.1.1.0/24 serviceapp 2
  ! Diverting traffic for another Public IP pool to another Outside ServiceApp
  200.1.1.0/24 serviceapp 4

ACL-based Forwarding (ABF)

In certain deployment cases, default route may not work.

• Deployment Use-case 1: Customer wants to divert traffic coming from specific subscriber network (containing Private IP address) to VSM (for NAT44) and the remaining traffic (which may already contain Public IP address) need not go to VSM.

• Deployment Use-case 2: Customer wants to distribute subscriber traffic into different Inside VRFs which may go to same VSM card or different VSM cards (but, will certainly using different Public IP pool).

• Deployment Use-case 3: Subscriber / Access / Inside traffic comes in default / global VRF and we need to distribute the traffic to different Inside ServiceApps which are in different Inside VRFs.

NOTE: Typically, ABF is to be used in Private side / Subscriber side and NOT towards Public / Core / Network side. 

In the above cases, ABF provides a very good solution. Below is sample configuration on how to use ABF for traffic diversion.

! Define IPv4 Access List
ipv4 access-list nat44_abf
 ! Divert to ServiceApp 1
 10 permit ipv4 10.0.100.0/24 any nexthop1 vrf ivrf1 ipv4 5.1.1.2
 ! Divert to ServiceApp 3
 20 permit ipv4 10.0.200.0/24 any nexthop1 vrf ivrf2 ipv4 6.1.1.2
 100 permit ipv4 any any
! Configure Ingress Interface
interface TenGigE0/5/0/2
 vrf subscriber
 ipv4 address 10.1.1.1 255.255.255.0
 ! Apply ABF on Ingress Interface
 ipv4 access-group nat44_abf ingress
! Define one Inside ServiceApp interface
interface ServiceApp1
 vrf ivrf1
 ipv4 address 5.1.1.1/30
 service cgn cgn1 service-type nat44
! Define another Inside ServiceApp interface
interface ServiceApp3
 vrf ivrf2
 ipv4 address 6.1.1.1/30
 service cgn cgn1 service-type nat44

17. Static Port Forwarding

There is a very important point about Dynamic NAT44. All the NAT translations / sessions are created by I2O traffic. If O2I traffic reaches VSM for which there is no NAT entry, the packets will be dropped. This works fine for most of the cases as the session / traffic is initiated by Applications which reside on Private side.

However, there are cases, where a server resides on the Private side of the network. In this case, there are 2 issues.

• Clients (on Public side) cannot initiate session to this Server, as those (O2I) packets will be dropped by VSM.
• Clients do not know the Public IP of the Server (and cannot use Private IP to communicate either)

To address these problems related to Server sitting on Private side of the network, a new feature called "Static Port Forwarding" is introduced. Following diagram explains "Static Port Forwarding" feature functionality.

Using Static Port Forwarding, user can provide the Private IP address and Port (via CLI) and NAT44 Application on VSM generates (dynamically) the corresponding Public IP and Port. Also, these mapping are made permanent - i.e., they do not get timed out and get deleted. The Public IP and port generated by the Application can be added to DNS database and thus made available to all.

With this design, any device on Public side of network can now send traffic to the known Public IP and port (to reach the Server sitting inside Private network). Also, as the NAT entry is permanent, O2I traffic always finds the entry and using the same can translate the packet (without dropping it).

Staic Port Forwarding entries can be created separately for each protocol - TCP, UDP and ICMP. To know the maximum number of such entries, please check CGv6 on VSM Feature page.

NOTES:

- User cannot provide the Outside / Public IP and port while configuring Static Port Forwarding.

- Outside / Public IP is generated by the NAT44 Application and hence, can be random.

- Outside port is usually assigned same as Inside Port, unless the Outside port is already being used

As these are used for Servers located in Private network, it is desirable that the Public IP address remain constant across RP failover.

As Outside / Public IP address for a Static Port Forwarding entry is allocated by NAT44 application based on the instant situation of Public IP availability stock as well as the allocation algorithm's state, it is highly probable that if the Static Port Forwarding entry is deleted and re-added or, if the VSM card is reloaded), it may allocate a different Public IP address.

In order to keep the same Outside IP address, it is recommended to add the Static Port Forwarding configuration as a first thing after VSM card comes up and when there is no NAT traffic on the router / VSM card (could be in a "maintenance window"). That way, every time, VSM is reloaded, the Public IP addresses assigned for Static Port Forwarding entries will remain the same.

Try to find out the following, before using Static Port Forwarding.

• Will there be any Servers sitting in the Private side of the deployment network ?
• How many of those Servers will be ?
• Can the Public IP address of the Servers be random and can be published via DNS or similar mechanism ?

A sample configuration for Static Port Forwarding is shown below.

service cgn cgn1
  service type nat44 nat1
   inside-vrf ivrf1
   map address-pool 180.0.0.0/24
   ! Define TCP related configuration
   protocol tcp
    ! Define Static Port Forwarding configuration
    static-forward inside address 10.0.0.50 port 6050
    static-forward inside address 10.0.0.50 port 80
   ! Define UDP related configuration
   protocol udp
    ! Define Static Port Forwarding configuration
    static-forward inside address 10.0.0.61 port 550
   ! Define ICMP related configuration
   protocol icmp
    ! Define Static Port Forwarding configuration
    ! For ICMP, 'identifier' field in ICMP header is used for 'port'
    static-forward inside address 10.0.0.189 port 750

Following table shows the NAT entries corresponding to the above Static Port Forwarding entries (for TCP protocol).

RP/0/RSP0/CPU0:VSM-Lab#show cgn nat44 nat44-1 inside-translation protocol tcp inside-vrf vrf1 inside-address 10.0.0.50 port start 25 end 8000


Fri Nov  1 13:44:44.874 UTC

Inside-translation details

---------------------------

NAT44 instance : nat44-1

Inside-VRF     : vrf1

--------------------------------------------------------------------------------------------
 
  Outside         Protocol  Inside       Outside       Translation   Inside      Outside
 
  Address                   Source       Source        Type          to          to

                             Port         Port                        Outside     Inside
                                                                      Packets     Packets

--------------------------------------------------------------------------------------------

  180.0.9.0          tcp       80           80            static       1218         45

  180.0.9.0          tcp     6050         6050            static        516       7162

NOTE:

- Outside IP (180.0.9.0) and Ports are assigned by the NAT44 Application when user supplies Inside IP (10.0.0.50) and Ports (80, 6025).

- "Translation Type" is shown as "static" (as opposed to "dynamic")

- Outside port is same as Inside port (usually, unless it is not available)

18. Application Layer Gateway (ALG)

Application Layer Gateway (ALG) is a device which has the capability of inspecting into a packet beyond layer 4 and can change Application layer content to meet certain need.

NAT44 changes IP address and Layer 4 (UDP/TCP/ICMP etc.) port. There are certain applications which embeds IP address and/or Port information in Application content. Now, the issue is while the packet traverses across a NAT44 device, layer 3 and 4 addresses get changed. However, in the Application layer, the content still contains old layer 3 and / or layer 4 addresses. This causes an issue in the Application as this is unexpected. Hence, the need of ALG functionality within a NAT device which while changing Layer 3 and 4 packet content, also changes Application content where Layer 3 and 4 addresses were embedded. With this change, end Application will be happy as it does not need to deal with 2 sets of addresses any more.

However, there are 2 ways this problem can be solved.

• Adding ALG functionality to NAT device - ALG functionality needs to be added to NAT device for each such Applicaton which embeds Layer 3 and/or 4 addresses in Application content.
• Changing the Application to deal with NAT device in the network - Application needs to assume that the Layer 3 and/or 4 address can get changed on the way (as there could be NAT device in the network) and hence, either avoid embedding Layer 3/4 addresses in Application content or find other mechanism to handle 2 sets of addresses.

The main challenges in adding ALG functionality to NAT device are:

• Every time a new Application is written which embeds Layer 3/4 address in Application content, all NAT devices need to be changed to address the new Application. This is not scalable as lot of new Applications are written everyday.
• In order to implement ALG for an Application, NAT device needs to understand the Application protocol as well as packet formt/content. Many Applications implement proprietary protocol and hence, do not want to make the same as public information. Hence, those Application packets will face issues with NAT device.
• There are applications (like, crypto) which do not want any intermediate device to understand / peek into the Application content and modify it. These packets should only be encoded/decoded by end Applications. These application packets would not be able to deal with intermediate NAT device.

On the contrary,

• Application can be written in such a way not to use Layer 3/4 addresses in Application content and to use Application-level ID, instead.
• There can be other mechanisms, e.g. - using STUN (Session Traversal Utilities for NAT) that applications can take to handle intermediate NAT device.

NOTE: Due to the above reasons, our solution does not encourage to support ALG within NAT44 functionality.

However, few basic ALG functionality is implemented with NAT44 Application. These are:

• Active FTP (File Transfer Protocol) - Passive FTP does not need ALG.
• RTSP (Real Time Streaming Protocol)
• PPTP (Point-to-Point Tunneling Protocol)

Following table show how to configure / enable different ALGs on VSM.

service cgn cgn1
  service-type nat44 nat1
   ! Enable Active FTP ALG
   alg ActiveFTP
    ! Enable RTSP ALG
    alg rtsp
   ! Enable PPTP ALG
   alg pptpAlg

19. Redundancy

Redundancy is an integral part of CGN (Carrier Grade NAT). Majority of the Service Providers want Redundancy in their network to make it more resilient. It helps in minimizing the traffic outage when one device fails.

On VSM, we support 2 types of redundancy.

• N:1 ABF-based redundancy (N can be 1 as well)
• 1:1 Warm Stand-by Redundancy (starting from XR release 5.2.2)

N:1 ABF-Based Redundancy

In this case, there needs to be N Primary VSM card and 1 Backup VSM card. Value of N can be 1 as well, but typically would be 2 or 3. Following are different characteristics of this solution.

• Each VSM card needs to be configured independently                                                                                                
  • Configuration (usually) should be similar (w.r.to parameters, number of ServiceApp interfaces, etc.)
• In ABF configuration, For each Primary VSM,                   
  • ServiceApp interface on Primary VSM becomes 1st Next-Hop and ServiceApp interface on Back-up VSM becomes 2nd Next-hop
• Each VSM will have different Public IP address pools (Address Pool is not same in Primary and Backup)
• When one Primary VSM card fails, Backup VSM card receives all the traffic of Primary VSM card.
• When Primary VSM card comes up, all traffic again switches back to it from Backup VSM card (it causes, another traffic outage)
• Each VSM card can support full scale and bandwidth

Following table shows how the ABF Next-Hop configuration would look like for N:1 (N = 3) ABF-based Redundancy.

Following diagram depicts N:1 (N = 2) configuration with 1 set of ServiceApps.

As shown in the diagram,

• before 1st failure, traffic coming from 10.2.0.0/24 subnet will go via Primary 1 VSM (Inside ServiceApp 1) which will use Public IP pool of 151.0.1.0/24.
• if and when Primary 1 VSM fails, traffic coming from 10.2.0.0/24 subnet will go via Backup VSM (Inside ServiceApp 5) which will use Public IP pool of 151.0.3.0/24.
• Instead of Primary 1 VSM, if Primary 2 VSM would have failed, traffic from 10.2.1.0/24 (not 10.2.0.0/24) should have switched to Backup VSM.

Following table captures the relevant ABF configuration for this sample setup.

1:1 Warm Stand-by Redundancy

In this mode, one VSM card acts as Primary and another as backup. Following are the properties of 1:1 Warm Stand-by redundancy.

• Easy to configure (Active and Stand-by locations are specified once)
• A single Public IP address pool is used
• Configuration is sent to both VSM cards
• NAT Application data traffic reaches to Active card only
• During switchover (usually takes few seconds), dynamic NAT entries get deleted (on failed VSM cards) and re-created on newly Active VSM card. Hence, there would be some traffic drop. Also, Private to Public IP/Port mapping gets changed during Switchover.
• When the previously Active VSM comes up, it stays as Stand-by and the traffic does not come back to it (until the Active VSM card fails)
• Each VSM can support full scale and throughput

Following diagram explains the working of 1:1 Redundancy for NAT44.

Please note that both Primary and Backup VSM cards share same ServiceApp interfaces and NAT44 configuration (including Public IP pool).

Following tables shows how to configure 1:1 VSM redundancy.

To check the health of the VSM card and trigger redundancy switchover, in case any failure occurs, following HA-specific test can be enabled:

• Data Path Test - It checks if the packet path from CGv6 Application to Fabric works fine or not.

If the test is enabled and any failure is detected by the test, the VSM card will be reloaded.

NOTE: By default, these tests run in the back-ground however, no acton is taken in case failure is detected. Using the following CLI, the test is enabled.

! To enable Data Path Test

20. NAT44 Licenses

In order to use NAT44 functionality on ASR9K, Licenses needs to be purchased. Depending on the number of Stateful Translations needed by the solution, required number of NAT44 specific licenses can be purchased. This fits nicely with "Pay as you grow" model as well.

Following licenses need to be purchased for NAT44 and other CGv6 applications.

Details of the Licensing (how to install, etc.) can be obtained from ASR9K S/w License Operations White Paper.

21. Summary of parameter values

In the following table, all the useful parameters are listed along with their default and valid range of values. You can consult this table to come up with the parameter value for your deployment case.

22. NAT44 Configuration / Feature Differences with ISM

Back to top

23. MTU and Fragmentation Considerations

Cisco recommends keeping the default physical interface MTU size on the customer-facing interfaces in NAT44 deployment.

Configure the MTU on physical VSM interfaces to 1518.

Specific Deployment Scenarios / Use-Cases

In this section, specific deployment scenarion / use-cases and presented which can be useful for some deployment.

24. Sample Applications over NAT44

Following table lists some of the important / well-known applications and their working status over NAT44 (on VSM).

NOTE:

- This list is not a complete/exhaustive list of applications that would work with NAT44.

- It also does not mean that any application not listed here will not work with NAT44.

25. Multiple Outside ServiceApps sharing same Outside VRF

It is very common to have default VRF as Outside VRF and when there are multiple Inside VRFs mapped to the same. In the following table, a sample ServiceApp and VRF configuration is shown. Please note that in this case, multiple Outside ServiceApps share share a comon Outside VRF.

To handle this scenario, we need to specify "outsideServiceApp" parameter configuration to indicate what is the Outside ServiceApp to be used with the mapping. Static route rule for specific Public IP address pool should guide the traffic to specific Outside ServiceApp. Only these configurations are shown below. Rest of the configuration remain the same.

service cgn cgn1
  service-type nat44 nat1

    ! 1st Inside VRF
    inside-vrf ivrf1

      ! MAP command using outsideServiceApp
      map [outside-vrf ovrf] outsideServiceApp ServiceApp2 address-pool 100.0.1.0/24

    ! 2nd Inside VRF
    inside-vrf ivrf2

      ! MAP command using outsideServiceApp
      map [outside-vrf ovrf] outsideServiceApp ServiceApp4 address-pool 100.0.2.0/24

    100.0.2.0/24 ServiceApp 4

26. NAT Bypass

There is an use-case where traffic selected traffic coming onto ASR9K via a Private side interface needs to go via NAT44 application, whereas remaining traffic can bypass NAT44 and should get forwarded via regular forwarding rule. This is called NAT bypass.

To implement NAT bypass, let's consider this situation:

• Private Traffic enters ASR9K via one VRF (say, RED)
• Selected traffic gets diverted to VSM card's Inside ServiceApp which is in different VRF (say, BLUE) and after translation comes out of Outside ServiceApp and eventually goes out of ASR9K via core-facing interface which is in RED VRF.
• Rest of the traffic (which bypasses NAT44) goes out of ASR9K via same core-facing i/f in RED VRF.

Please note that other than NAT bypass, there could be other deployment scenario where preserving VRF (across VSM) becomes a necessity. But, the solution would be same / very similar.

The above scenario can be achieved using VSM with some additional ABF and Static Route and appropriate VRF configuration.

Let us take a look at the following diagram as a sample scenario.

In the above diagram, traffic enters and exits out of ASR9K in RED VRF. Also, please note that Inside ServiceApp is in BLUE vrf whereas Outside ServiceApp is in RED VRF.

Following table shows the specific or additional configuration that is needed for appropriate traffic diversion.

27. MPLS (Layer 3) VPN and NAT Interworking

An Multiprotocol Label Switching (MPLS) Layer 3 Virtual Private Network (L3VPN) consists of a set of sites that are interconnected by means of an MPLS provider core network. At each customer site, one or more customer edge (CE) routers attach to one or more provider edge (PE) routers.

MPLS VPNs are easier to manage and expand than conventional VPNs. When a new site is added to an MPLS VPN, only the edge router of the service provider that provides services to the customer site needs to be updated. The components of the MPLS VPN are described as follows:

• Provider (P) router — Router in the core of the provider network. PE routers run MPLS switching and do not attach VPN labels to routed packets. VPN labels are used to direct data packets to the correct private network or customer edge router.
• Provider Edge (PE) router — Router that attaches the VPN label to incoming packets based on the interface or subinterface on which they are received, and also attaches the MPLS core labels. A PE router attaches directly to a CE router.
• Customer edge (CE) router — Edge router on the network of the ISP that connects to the PE router on the network. A CE router must interface with a PE router.

Details on L3VPN can be obtained from ASR9K MPLS Layer 3 VPN Configuration Guide.

Service providers and enterprises that have network application services they want to offer or share with customers and partners will want to      minimize any connectivity burden placed on the user of the service. It is desirable, even mandatory, to extend the offering to as many potential users as needed to achieve the desired goals or return.

By deploying NAT within the common MPLS VPN infrastructure, communications service providers can relieve some of the connectivity burden on      customers and accelerate their ability to link more shared application services to more consumers of those services

There are two options for NAT deployment within the MPLS provider edge:

• Distributed with ingress NAT PEs
• Centralized with egress NAT PEs

Following diagram shows Distrbuted NAT scenario with Ingress NAT PEs.

With this design, scalability is maintained to a large extent while performance is optimized by distributing the NAT function over many edge devices. Each NAT PE handles traffic for sites locally connected to that PE. NAT rules and access control lists or route maps control which packets require translation.

In the above case, at ingress PE router, customer private IP addresses are NAT'ed to public IP address by VSM card and then MPLS labels are added by it before the packet goes out of ASR9K. On the return path, MPLS label(s) are removed by MPLS-facing LC and IT packets are sent to VSM. VSM performs reverse NAT and sends the packet to LC which then sends it back to CE router.

Following diagram shows Distrbuted NAT scenario with Ingress NAT PEs.

With this design, scalability is reduced to some degree since the central PE must maintain routes for all customer networks that access the shared service. The application performance requirements must also be considered so that the traffic does not overburden the router that must translate the IP addresses of the packets. Because NAT occurs centrally for all customers using this path, IP address pools can be shared; thus, the total number of subnets required is reduced.

In the above case, in the egress PE router, first MPLS labels are removed by ingress LC and the IP packet is sent to VSM card. Customer private IP addresses are NAT'ed to public IP address by VSM card and the packets are forwarded to shared service network. In the reverse path, VSM translates Public destination IP to private IP addresses and then adds MPLS labels before sending it to egress LC. Egress LC swaps one label and sends the packet out of ASR9K towards MPLS network.

NOTE: MPLS labels should be removed by LC before sending the packet to VSM as IP packet. However, VSM can add the required MPLS labels before sending the packet to egress LC.

For sample MPLS VPN configuration, please refer to "Configuration Example: MPLS VPN on XR" document.

28. NAT Hairpining

Host behind a NAT device (on Private side) communicating with another host behind the same NAT device (on Private side) is called "NAT Hairpinning". Let us consider the following deployment use-case.

We have a server behind a NAT device which has a Public IP as well, created using Static Port Forwarding configuration. Now, this server can be accessed from hosts on public side of NAT device as well as Private side of the NAT device. When a host on Private side of the NAT device tries to communicate with the Server, it uses NAT Hairpinning. Following diagram depicts how NAT hairpinning works with NAT44 on VSM.

In this case, we first add a Static Port Forwarding entry for a service offered by the Server at 10.100.1.2:2055. Let's say, the Public IP pool configured is 200.2.0.0/24. NAT44 application allocates Public IP and port as 200.2.0.210:2055 (Please note that the port is preserved here). This Public IP and port is published / made available to the hosts. Let's the packet flow now when a host with Private IP 10.10.10.2 tries to access the service.

• Step 1: Host sends a packet (with Source IP 10.10.10.2 and port 3000) to Server's Public IP and port and the packet reaches ASR9K on TenGigE 0/0/0/0.1 which is in VRF ivrf.
• Step 2: Because of Static Route configuration in VRF ivrf, the packet is forwarded to VSM card via (Inside) ServiceApp 1 interface.
• Step 3: Application treats this as I2O packet. A new dynamic NAT entry is created by NAT44 application and it translates source IP/Port from (Private) 10.10.10.2:3000 to (Public) 200.2.0.192:23516. Please note that the Destination IP address and port are not touched here. The packet is sent out and because of Static route definition for Public IP pool, the packet comes back to VSM card via (Outside) ServiceApp 2.
• Step 4: Application treats this as O2I packet. As there is already a (Static) NAT entry exists for Destination IP and port, NAT44 application translates Destination IP address/Port from (Public) 200.2.0.210:2055 to (Private) 10.100.1.2:2055. Please note that the Source IP address and port are not touched here. The packet is sent out and via regular forwarding rule, it reaches egress i/f TenGigE 0/0/0/0.2.
• Step 5: The packet is forwarded to the Server with Source IP/Port as 200.2.0.192:23516 and Destination IP/Port as 10.100.1.2:2055 and the server consumes it.

Response from the Server will take the reverse path and it will use Dynamic NAT rule in first reverse NAT and then Static NAT rule in second NAT processing, to reach the host.

In this case, Static Port Forwarding configuration is used for Server as an use-case. But, it can be another host as well for which there is no Static Port Forwarding configuration. Only important thing is sender needs to know the Public IP and port of the receiver.

Please note that there is no specific NAT44 configuration is needed for this. Regular / basic NAT44 configuration will work here. Hence, no configuration is provided here.

29. Handling of Asymmetric I2O and O2I traffic with better performance

Unlike ISM card, we do NOT need to make any special configuration (like, dividing traffic into 2 sub-groups) for VSM. As long as I2O + O2I traffic do not exceed the capacity of the CGv6 Application instances, direction of traffic does not matter i.e., I2O and O2I traffic do not need to be equally balanced.

Validation of Configuration

Once NAT44 on VSM is configured, we need different ways (mainly, via "show" CLIs) to validate those. In this section, important NAT44 related CLIs are listed and also explained how those can be used for validation.

30. show run

As a first step, different "show run" output should be verified to ensure that configuration commands are rightly applied. Following commands can be used.

31. show virtual-service list

This CLI will list down the services that are installed and running on ASR9K chassis.

32. show virtual-service detail

This CLI shows detail information about the CGv6 service VM (mainly, what h/w resources are given to it, etc.), as shown below.

33. show cgn nat44 <> statistics

This is a very important CLI related to NAT44. A sample output of the CLI is shown below.

Following table explains the impotant fields from the above CLI and how it can be used for validation.

Please note that the values displayed by the CLI is valid at that instant for that particular VSM card. It may change at a later point of time.

Number of active translations

Number of sessions

Translations create rate

Translations delete rate

Inside to outside forward rate

Outside to inside forward rate

Inside to outside drops port limit exceeded

Inside to outside drops system limit reached

Inside to outside drops resource depletion

No translation entry drops

Number of subscribers

Drops due to session db limit exceeded

34. show cgn nat44 <> inside-translation

This command is helpful in seeing the list of all Outside / Public IP address + Port mapping for a specific Inside / Private IP address (and a Port range).

Following is a sample output of the command.

Above table shows all Outside IP (100.200.2.75) and Port combination for Inside IP (10.2.5.134) and Port Range (1 through 4580).

NOTE:

- As one Inside address can only map to one Outside address, there are not multiple Outside addresses in 1st column.

- The number of entries in this table should not exceed Port Limit value.

35. show cgn nat44 <> outside-translation

This command is helpful in seeing the list of all Inside / Private IP address + Port mapping for a specific Outside / Public IP address (and a Port range).

Following is a sample output of the command.

Above table shows all Inside IPs (10.2.5.134, 10.2.5.142) and Port combination for Inside IP (100.200.2.75) and Port Range (1 through 65535). In this case, there are multiple Inside IP addresses are mapped to one Public IP address.

Monitoring CGN Using SNMP

The attached CGN_MIB_Parameters.xlsx sheet lists the parameters supported in the CGN implementation on VSM/ISM.

• Go through this Deployment Guide to clearly understand                                     
  • how different feature works
  • what parameters are configurable and need to be considered for specific deployment
  • what are the different deployment use cases.
• Go through "CGv6 on VSM: Features Supported Across IOS-XR Release" page  to exactly know from which release specific features that you're  interested in are supported. This will help you in selecting the right  IOS-XR release.                    
• Select the configuration parameter values wisely, considering                                 
  • pros and cons,
  • best-case and worst-case scenarios
  • side effects
• Draw network diagram for deployment use-case including interface names (with VRF and IP address/subnet) and review for correctness.
• Try to find out what type of application traffic (VPN, Games, SIP, Video, etc.) may undergo NAT44 and whether there could be issues or not (not all applications are NAT friendly)                                    
  • If possible, try it in a lab setup, before actual deployment
• Estimate traffic throughput and nature of it (burstiness, average, etc.), scale of sessions/users and accordingly use correct number of VSM cards and related configuration.
• If possible, deploy in phases. First, send selected traffic (you can use ABF) through VSM and see if there are any issues. If not, you can send more and more traffic through VSM.

Related Information

1. CGv6 on VSM: Features Supported Across IOS-XR Releases
2. CGv6 on ISM: Features Supported Across IOS-XR Releases
3. CGv6 on ISM: CGN / NAT44 Deployment Guide
4. ASR9K Configuration Guides
5. ASR9K Command Reference Guides
6. ASR9K BNG Deployment Guide
7. IANA Service Name and Transport Protocol Port Port Number Registry
8. Configuration Example: MPLS VPN on IOS-XR
9. Cisco ASR9000 S/w License Operations White Paper

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