Verifying NAT Operation and Basic NAT Troubleshooting
Verifying NAT Operation and Basic NAT Troubleshooting
Verifying NAT Operation and Basic NAT Troubleshooting
Troubleshooting
Document ID: 8605
Contents
Introduction
Prerequisites
Requirements
Components Used
Conventions
How to Rule Out NAT
Sample Problem: Can Ping One Router But Not Another
Problem Summary
Sample Problem: Outside Network Devices Cannot Communicate with Inside Routers
Problem Summary
Troubleshooting Checklists
Translation Not Installed in the Translation Table
Correct Translation Entry Isn't Being Used
NAT Operating Correctly, But There Are still Connectivity Problems
NAT Translation for Port 80 Does not Work
%NAT: System busy. Try later
Large Translation Table Increases the CPU
Prerequisites
Requirements
There are no specific requirements for this document.
Components Used
This document is not restricted to specific software and hardware versions.
The information in this document was created from the devices in a specific lab environment. All of the
devices used in this document started with a cleared (default) configuration. If your network is live, make sure
that you understand the potential impact of any command.
Conventions
For more information on document conventions, refer to the Cisco Technical Tips Conventions.
1. Based on the configuration, clearly define what NAT is supposed to achieve. At this point you may
determine that there is a problem with the configuration. For help with configuring NAT refer to
Configuring Network Address Translation: Getting Started.
2. Verify that correct translations exist in the translation table.
3. Use the show and debug commands to verify that the translation is occurring.
4. Review in detail what is happening to the packet and verify that routers have the correct routing
information to move the packet along.
Below are some sample problems in which we use the above steps to help determine the cause of the problem.
There are no routing protocols running in any of the routers, and Router 4 has Router 6 as its default gateway.
Router 6 is configured with NAT in this manner:
Router 6
interface Ethernet0
ip address 172.16.6.6 255.255.255.0
ip directed−broadcast
ip nat outside
media−type 10BaseT
!
interface Ethernet1
ip address 10.10.10.6 255.255.255.0
ip nat inside
media−type 10BaseT
!
interface Serial2.7 point−to−point
ip address 172.16.11.6 255.255.255.0
ip nat outside
frame−relay interface−dlci 101
!
ip nat pool test 172.16.11.70 172.16.11.71 prefix−length 24
ip nat inside source list 7 pool test
ip nat inside source static 10.10.10.4 172.16.6.14
!
access−list 7 permit 10.10.50.4
access−list 7 permit 10.10.60.4
access−list 7 permit 10.10.70.4
First, determine that NAT is working correctly. You know from the configuration that the Router 4 IP address
(10.10.10.4) is supposed to be statically translated to 172.16.6.14. You can use the show ip nat translation
command on Router 6 to verify that the translation does exist in the translation table:
Now, ensure this translation is taking place when Router 4 sources IP traffic. You can do this in two ways
from Router 6: by running NAT debug or by monitoring NAT statistics with the show ip nat statistics
command. Because debug commands should always be used as a last resort, start with the show command.
The intention here is to monitor the hits counter to see if it is increasing as we send traffic from Router 4. The
hits counter increments every time a translation in the translation table is used to translate an address. First,
clear the statistics, then display the statistics, try to ping Router 7 from Router 4, and then display the statistics
again.
After you use the ping 172.16.11.7 command on Router 4, the NAT statistics on Router 6 show as:
You can see from the show commands that the number of hits incremented by five. In a successful ping from
a Cisco router, the number of hits should increase by ten. The five Internet Control Message Protocol (ICMP)
echoes sent by the source router (Router 4) should be translated, and the five echo reply packets from the
destination router (Router 7) should also be translated, for a total of ten hits. The five missing hits are most
likely due to the echo replies not getting translated or not being sent from Router 7.
See if you can find any reason Router 7 would not send echo reply packets to Router 4. First review what
NAT is doing to the packet. Router 4 is sending ICMP echo packets with a source address of 10.10.10.4 and a
destination address of 172.16.11.7. After NAT takes place the packet received by Router 7 has a source
address of 172.16.6.14 and a destination address of 172.16.11.7. Router 7 needs to reply to 172.16.6.14, and
since 172.16.6.14 is not directly connected to Router 7, it needs a route for this network in order to respond.
Check Router 7's routing table to verify the route exists.
You can see that the Router 7 routing table does not have a route for 172.16.6.14. Once you add this route,
ping works fine.
Problem Summary
You first defined what NAT was supposed to accomplish. Next, you verified that the static NAT entry existed
in the translation table and that it was accurate. You verified that translation truly was taking place by
monitoring the NAT statistics. There you found a problem which led you to check the routing information on
Router 7, where you found that Router 7 needed a route to the inside global address of Router 4.
Note that in this simple lab environment, it is useful to monitor NAT statistics with the show ip nat statistics
command. However, in a more complex NAT environment with several translations taking place, this show
command is no longer useful. In this case it may be necessary to run debugs on the router. The next problem
scenario demonstrates the use of debug commands.
Sample Problem: Outside Network Devices Cannot
Communicate with Inside Routers
In this scenario, Router 4 can ping both Router 5 and Router 7, but devices on the 10.10.50.0 network cannot
communicate with Router 5 or Router 7 (in the test lab we emulate this by sourcing pings from the loopback
interface with the IP address 10.10.50.4). Look at the network diagram:
Router 6
interface Ethernet0
ip address 172.16.6.6 255.255.255.0
ip directed−broadcast
ip nat outside
media−type 10BaseT
!
interface Ethernet1
ip address 10.10.10.6 255.255.255.0
ip nat inside
media−type 10BaseT
!
interface Serial2.7 point−to−point
ip address 172.16.11.6 255.255.255.0
ip nat outside
frame−relay interface−dlci 101
!
ip nat pool test 172.16.11.70 172.16.11.71 prefix−length 24
ip nat inside source list 7 pool test
ip nat inside source static 10.10.10.4 172.16.6.14
!
access−list 7 permit 10.10.50.4
access−list 7 permit 10.10.60.4
access−list 7 permit 10.10.70.4
First, clearly state the expected behavior of NAT. From the configuration of Router 6, you know that NAT is
supposed to dynamically translate 10.10.50.4 to the first available address in the NAT pool "test". The pool
consists of addresses 172.16.11.70 and 172.16.11.71. From what you learned in the problem above, you can
deduce that the packets that Routers 5 and 7 receive either have a source address of 172.16.11.70 or
172.16.11.71. These addresses are on the same subnet as Router 7, so Router 7 should have a directly
connected route, however Router 5 needs a route to the subnet if it does not have one already.
You can use the show ip route command to see that the Router 5 routing table does list 172.16.11.0:
router−5# show ip route
Codes: C − connected, S − static, I − IGRP, R − RIP, M − mobile, B − BGP
D − EIGRP, EX − EIGRP external, O − OSPF, IA − OSPF inter area
N1 − OSPF NSSA external type 1, N2 − OSPF NSSA external type 2
E1 − OSPF external type 1, E2 − OSPF external type 2, E − EGP
i − IS−IS, L1 − IS−IS level−1, L2 − IS−IS level−2, ia − IS−IS inter area
* − candidate default, U − per−user static route, o − ODR
P − periodic downloaded static route
You can use the show ip route command to see that the Router 7 routing table lists 172.16.11.0 as a directly
connected subnet:
Now that you have clearly stated what NAT is supposed to do, you need to verify that it is operating correctly.
Start by checking the NAT translation table and verifying that the expected translation exists. Since the
translation you are interested in is created dynamically, you must first send IP traffic sourced from the
appropriate address. After a sent ping, sourced from 10.10.50.4 and destined to 172.16.11.7, the translation
table in Router 6 shows this:
Since the expected translation is in the translation table, you know that the ICMP echo packets are getting
translated appropriately, but what about the echo reply packets? As mentioned above, you could monitor the
NAT statistics, but this is not very useful in a complex environment. Another option is to run NAT debugging
on the NAT router (Router 6). In this case, you should turn on debug ip nat on Router 6 while you send a
ping sourced from 10.10.50.4 destined to 172.16.11.7. The debug results are below.
Note: When you use any debug command on a router, you could overload the router which causes it to
become inoperable. Always use extreme caution, and if possible never run a debug on a critical production
router without the supervision of a Cisco Technical Support engineer.
As you can see from the above debug output, the first line shows the source address of 10.10.50.4 being
translated to 172.16.11.70. The second line shows the destination address of 172.16.11.70 being translated
back to 10.10.50.4. This pattern repeats throughout the rest of the debug. This tells you that Router 6 is
translating the packets in both directions.
Now review in more detail exactly what should be happening. Router 4 sends a packet sourced from
10.10.50.4 destined for 172.16.11.7. Router 6 performs NAT on the packet and forwards a packet with a
source of 172.16.11.70 and a destination of 172.16.11.7. Router 7 sends a response with a source of
172.16.11.7 and a destination of 172.16.11.70. Router 6 performs NAT on the packet, which results in a
packet with source address 172.16.11.7 and destination address 10.10.50.4. At this point Router 6 should
route the packet to 10.10.50.4 based on information it has in its routing table. You need to use the show ip
route command to confirm that Router 6 has the necessary route in its routing table.
Problem Summary
First you clearly defined what NAT was supposed to accomplish. Second, you verified that the necessary
translations existed in the translation table. Third, you used the debug or show commands to verified that the
translation was actually taking place. Finally, you reviewed in more detail what was happening to the packet
and what the routers need in order to forward or respond to the packet.
Troubleshooting Checklists
Now that you have a basic procedure for finding the cause of connectivity problems, here are some checklists
for troubleshooting common issues.
• The configuration is correct. Getting NAT to accomplish what you want can sometimes be tricky. For
some configuration help, refer to Configuring Network Address Translation: Getting Started.
• There are not any inbound access lists that deny the packets from entering the NAT router.
• The NAT router has the appropriate route in the routing table if the packet is going from inside to
outside. Refer to NAT Order of Operation for more information.
• The access list referenced by the NAT command permits all necessary networks.
• There are enough addresses in the NAT pool. This should only be a problem if NAT is not configured
for overloading.
• That the router interfaces are appropriately defined as NAT inside or NAT outside.
• In the case of translating the payload of Domain Name System (DNS) packets, make sure that
translation takes place on the address in the IP header of the packet. If this does not happen, then NAT
does not look into the payload of the packet.
• Verify there are not any inbound access lists that deny the packets from entering the NAT router.
• For packets going from inside to outside, verify there is a route to the destination as this is checked
before translation. Refer to NAT Order of Operation for more information.
1. Run the debug ip nat translations and debug ip packet commands in order to see if the translations
are correct and the correct translation entry is installed in the translation table.
2. Verify that the server responds.
3. Disable the HTTP server.
4. Clear the NAT and ARP tables.
%NAT: System busy. Try later
The %NAT: System busy. Try later error message appears when a show command related to NAT
or a show running−config or write memory command is executed. This issue is due to the increase in the
size of the NAT table. When the size of the NAT table increases, the router runs out of memory.
Reload the router in order to solve this issue. If the error message appears when HSRP SNAT is configured,
configure these commands in order to resolve the issue:
In order to NAT the public IP address to two internal IP addresses, use two public IP addresses in the DNS.
Conclusion
The problems above demonstrated that NAT is not always the cause of IP connectivity issues. In many cases,
the cause is something other than NAT and requires further investigation. This document explains basic steps
to take when troubleshooting and verifying NAT operation. These steps include:
The error means that NAT attempts to do a layer 4 fix on the address in an FTP open, and can not find the IP
addresses it needs to translate in the packet.
The reason why the message includes tokens is that IP addresses in the packet are found by looking for a
token, or a set of symbols, in the IP packet, in order to find the details needed to translate.
When an FTP session is initiated, it negotiates two channels, a command channel and a data channel. These
are both IP addresses with different port numbers. The FTP client and server negotiate a second data channel
to transfer files. The packet exchanged through control channel has the format "PORT,i,i,i,i,p,p", where i,i,i,i
are the four bytes of an IP address and p,p specify the port. NAT tries to match this pattern and translate
address/port if necessary. NAT must translate both channels' addressing schemes. NAT scans for numbers in
the command stream until it thinks it has found a port command that requires translation. It tries to parse out
the translation, which it calculates with the pattern as described earlier.
If the packet is corrupt or the FTP server or client has malforming commands, NAT cannot properly calculate
the translation and it generates that error.A suggestion is to set the FTP client to "passive" so that it initiates
both channels. This sometimes helps with FTP through NAT.
Related Information
• NAT Support Page
• Technical Support − Cisco Systems