Topology
Addressing Table
Device
|
Interface
|
IP Address
|
Subnet Mask
|
Default Gateway
|
Gateway
|
G0/1
|
192.168.1.1
|
255.255.255.0
|
N/A
|
|
S0/0/1
|
209.165.201.18
|
255.255.255.252
|
N/A
|
ISP
|
S0/0/0 (DCE)
|
209.165.201.17
|
255.255.255.252
|
N/A
|
|
Lo0
|
192.31.7.1
|
255.255.255.255
|
N/A
|
PC-A (Simulated Server)
|
NIC
|
192.168.1.20
|
255.255.255.0
|
192.168.1.1
|
PC-B
|
NIC
|
192.168.1.21
|
255.255.255.0
|
192.168.1.1
|
Objectives
Part 1: Build the Network and Verify
Connectivity
Part 2: Configure and Verify Static
NAT
Part 3: Configure and Verify Dynamic
NAT
Background / Scenario
Network Address Translation (NAT) is the
process where a network device, such as a Cisco router, assigns a public
address to host devices inside a private network. The main reason to use NAT is
to reduce the number of public IP addresses that an organization uses because
the number of available IPv4 public addresses is limited.
In this lab, an ISP has allocated the
public IP address space of 209.165.200.224/27 to a company. This provides the
company with 30 public IP addresses. The addresses, 209.165.200.225 to
209.165.200.241, are for static allocation and 209.165.200.242 to
209.165.200.254 are for dynamic allocation. A static route is used from the ISP
to the gateway router, and a default route is used from the gateway to the ISP
router. The ISP connection to the Internet is simulated by a loopback address
on the ISP router.
Note: The routers used with CCNA hands-on labs
are Cisco 1941 Integrated Services Routers (ISRs) with Cisco IOS Release 15.2(4)M3
(universalk9 image). The switches used are Cisco Catalyst 2960s with Cisco IOS Release
15.0(2) (lanbasek9 image). Other routers, switches and Cisco IOS versions can
be used. Depending on the model and Cisco IOS version, the commands available
and output produced might vary from what is shown in the labs. Refer to the
Router Interface Summary Table at the end of this lab for the correct interface
identifiers.
Note: Make sure that the routers and switch have been erased and have no
startup configurations. If you are unsure, contact your instructor.
Required Resources
·
2 Routers (Cisco 1941 with
Cisco IOS Release 15.2(4)M3 universal image or comparable)
·
1 Switch (Cisco 2960 with Cisco
IOS Release 15.0(2) lanbasek9 image or comparable)
·
2 PCs (Windows 7, Vista, or XP
with terminal emulation program, such as Tera Term)
·
Console cables to configure the
Cisco IOS devices via the console ports
·
Ethernet and serial cables as
shown in the topology
Part 1:
Build the Network and Verify
Connectivity
In Part 1, you will set up the network
topology and configure basic settings, such as the interface IP addresses,
static routing, device access, and passwords.
Step 1:
Cable the network as shown in
the topology.
Attach the devices as shown in the
topology diagram, and cable as necessary.
Step 2:
Configure PC hosts.
Step 3:
Initialize and reload the
routers and switches as necessary.
Step 4:
Configure basic settings for
each router.
a.
Disable DNS lookup.
b.
Configure IP addresses for the
routers as listed in the Addressing Table.
c.
Set the clock rate to 128000 for the DCE serial interfaces.
d.
Configure device name as shown
in the topology.
e.
Assign cisco as the console and vty passwords.
f.
Assign class as the encrypted privileged EXEC mode password.
g.
Configure logging synchronous to prevent console messages from interrupting the
command entry.
Step 5:
Create a simulated web server
on ISP.
a.
Create a local user named webuser with an encrypted password of webpass.
ISP(config)# username
webuser privilege 15 secret webpass
b.
Enable the HTTP server service
on ISP.
ISP(config)# ip
http server
c.
Configure the HTTP service to
use the local user database.
ISP(config)# ip
http authentication local
Step 6:
Configure static routing.
a.
Create a static route from the
ISP router to the Gateway router using the assigned public network address
range 209.165.200.224/27.
ISP(config)# ip
route 209.165.200.224 255.255.255.224 209.165.201.18
b.
Create a default route from the
Gateway router to the ISP router.
Gateway(config)# ip route 0.0.0.0 0.0.0.0 209.165.201.17
Step 7:
Save the running configuration
to the startup configuration.
Step 8:
Verify network connectivity.
a.
From the PC hosts, ping the G0/1
interface on the Gateway router. Troubleshoot if the pings are unsuccessful.
b.
Display the routing tables on
both routers to verify that the static routes are in the routing table and configured
correctly on both routers.
Part 2:
Configure and Verify Static NAT
Static
NAT uses a one-to-one mapping of local and global addresses, and these mappings
remain constant. Static NAT is particularly useful for web servers or devices
that must have static addresses that are accessible from the Internet.
Step 1:
Configure a static mapping.
A static map is configured to tell the
router to translate between the private inside server address 192.168.1.20 and the
public address 209.165.200.225. This allows a user from the Internet to access
PC-A. PC-A is simulating a server or device with a constant address that can be
accessed from the Internet.
Gateway(config)# ip nat inside source static 192.168.1.20 209.165.200.225
Step 2:
Specify the interfaces.
Issue the ip nat inside and ip nat
outside commands to the interfaces.
Gateway(config)# interface g0/1
Gateway(config-if)# ip nat inside
Gateway(config-if)# interface s0/0/1
Gateway(config-if)# ip nat outside
Step 3:
Test the configuration.
a.
Display the static NAT table by
issuing the show ip nat translations
command.
Gateway# show
ip nat translations
Pro Inside global Inside local Outside local Outside global
--- 209.165.200.225
192.168.1.20 --- ---
What is the translation of the Inside
local host address?
192.168.1.20 =
_________________________________________________________
The Inside global address is assigned by?
____________________________________________________________________________________
The Inside local address is assigned by?
____________________________________________________________________________________
b.
From PC-A, ping the Lo0
interface (192.31.7.1) on ISP. If the ping was unsuccessful, troubleshoot and
correct the issues. On the Gateway router, display the NAT table.
Gateway# show
ip nat translations
Pro Inside global Inside local Outside local Outside global
icmp 209.165.200.225:1 192.168.1.20:1 192.31.7.1:1 192.31.7.1:1
--- 209.165.200.225 192.168.1.20 --- ---
A NAT entry was added to the table with ICMP
listed as the protocol when PC-A sent an ICMP request (ping) to 192.31.7.1 on
ISP.
What port number was used in this ICMP
exchange? ________________
Note: It may be necessary to disable the PC-A firewall for the ping to
be successful.
c.
From PC-A, telnet to the ISP Lo0
interface and display the NAT table.
Pro Inside global Inside
local Outside local Outside global
icmp 209.165.200.225:1 192.168.1.20:1 192.31.7.1:1 192.31.7.1:1
tcp 209.165.200.225:1034 192.168.1.20:1034 192.31.7.1:23 192.31.7.1:23
--- 209.165.200.225 192.168.1.20 --- ---
Note: The NAT for the ICMP request may have timed out and been removed
from the NAT table.
What was the protocol used in this
translation? ____________
What are the port numbers used?
Inside global / local: ________________
Outside global / local: ________________
d.
Because static NAT was
configured for PC-A, verify that pinging from ISP to PC-A at the static NAT
public address (209.165.200.225) is successful.
e.
On the Gateway router, display
the NAT table to verify the translation.
Gateway# show
ip nat translations
Pro Inside global Inside
local Outside local Outside global
icmp 209.165.200.225:12 192.168.1.20:12 209.165.201.17:12 209.165.201.17:12
--- 209.165.200.225 192.168.1.20 --- ---
Notice that the Outside local and Outside
global addresses are the same. This address is the ISP remote network source
address. For the ping from the ISP to succeed, the Inside global static NAT
address 209.165.200.225 was translated to the Inside local address of PC-A
(192.168.1.20).
f.
Verify NAT statistics by using
the show ip nat statistics command on
the Gateway router.
Gateway# show
ip nat statistics
Total active translations: 2 (1 static, 1 dynamic; 1 extended)
Peak translations: 2, occurred 00:02:12 ago
Outside interfaces:
Serial0/0/1
Inside interfaces:
GigabitEthernet0/1
Hits: 39
Misses: 0
CEF Translated packets: 39, CEF Punted
packets: 0
Expired translations: 3
Dynamic mappings:
Total doors: 0
Appl doors: 0
Normal doors: 0
Queued Packets: 0
Note: This is only a sample output. Your output may not match exactly.
Part 3:
Configure and Verify Dynamic
NAT
Dynamic
NAT uses a pool of public addresses and assigns them on a first-come,
first-served basis. When an inside device requests access to an outside network,
dynamic NAT assigns an available public IPv4 address from the pool. Dynamic NAT
results in a many-to-many address mapping between local and global addresses.
Step 1:
Clear NATs.
Before proceeding to add dynamic NATs,
clear the NATs and statistics from Part 2.
Gateway# clear
ip nat translation *
Gateway# clear
ip nat statistics
Step 2:
Define an access control list (ACL)
that matches the LAN private IP address range.
ACL 1 is used to allow 192.168.1.0/24
network to be translated.
Gateway(config)# access-list 1 permit 192.168.1.0 0.0.0.255
Step 3:
Verify that the NAT interface
configurations are still valid.
Issue the show ip nat statistics command on the Gateway router to verify the
NAT configurations.
Step 4:
Define the pool of usable
public IP addresses.
Gateway(config)# ip nat pool
public_access 209.165.200.242 209.165.200.254 netmask 255.255.255.224
Step 5:
Define the NAT from the inside source
list to the outside pool.
Note: Remember that NAT pool names are case-sensitive and the pool name
entered here must match that used in the previous step.
Gateway(config)# ip nat inside source list 1 pool public_access
Step 6:
Test the configuration.
a.
From PC-B, ping the Lo0
interface (192.31.7.1) on ISP. If the ping was unsuccessful, troubleshoot and
correct the issues. On the Gateway router, display the NAT table.
Gateway# show
ip nat translations
Pro Inside global Inside local Outside local Outside global
--- 209.165.200.225 192.168.1.20 --- ---
icmp 209.165.200.242:1 192.168.1.21:1 192.31.7.1:1 192.31.7.1:1
--- 209.165.200.242 192.168.1.21 --- ---
What is the translation of the Inside
local host address for PC-B?
192.168.1.21 =
_________________________________________________________
A dynamic NAT entry was added to the
table with ICMP as the protocol when PC-B sent an ICMP message to 192.31.7.1 on
ISP.
What port number was used in this ICMP
exchange? ______________
b.
From PC-B, open a browser and
enter the IP address of the ISP-simulated web server (Lo0 interface). When
prompted, log in as webuser with a
password of webpass.
c.
Display the NAT table.
Pro Inside global Inside
local Outside local Outside global
--- 209.165.200.225 192.168.1.20 --- ---
tcp 209.165.200.242:1038 192.168.1.21:1038 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1039 192.168.1.21:1039 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1040 192.168.1.21:1040 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1041 192.168.1.21:1041 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1042 192.168.1.21:1042 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1043 192.168.1.21:1043 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1044 192.168.1.21:1044 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1045 192.168.1.21:1045 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1046 192.168.1.21:1046 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1047 192.168.1.21:1047 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1048 192.168.1.21:1048 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1049 192.168.1.21:1049 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1050 192.168.1.21:1050 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1051 192.168.1.21:1051 192.31.7.1:80 192.31.7.1:80
tcp 209.165.200.242:1052 192.168.1.21:1052 192.31.7.1:80 192.31.7.1:80
--- 209.165.200.242 192.168.1.22 --- ---
What protocol was used in this
translation? ____________
What port numbers were used?
Inside: ________________
outside: ________________
What well-known port number and service was
used? ________________
d.
Verify NAT statistics by using
the show ip nat statistics command on
the Gateway router.
Gateway# show
ip nat statistics
Total active translations: 3 (1 static,
2 dynamic; 1 extended)
Peak
translations: 17, occurred 00:06:40 ago
Outside
interfaces:
Serial0/0/1
Inside
interfaces:
GigabitEthernet0/1
Hits:
345 Misses: 0
CEF
Translated packets: 345, CEF Punted packets: 0
Expired
translations: 20
Dynamic
mappings:
--
Inside Source
[Id: 1] access-list 1 pool
public_access refcount 2
pool public_access: netmask 255.255.255.224
start 209.165.200.242 end 209.165.200.254
type generic, total addresses 13, allocated 1 (7%), misses 0
Total
doors: 0
Appl
doors: 0
Normal
doors: 0
Queued Packets: 0
Note: This is only a sample output. Your output may not match exactly.
Step 7:
Remove the static NAT entry.
In Step 7, the static NAT entry is
removed and you can observe the NAT entry.
a.
Remove the static NAT from Part
2. Enter yes when prompted to delete
child entries.
Gateway(config)# no ip nat inside source static 192.168.1.20 209.165.200.225
Static entry in use, do you want to delete child
entries? [no]: yes
b.
Clear the NATs and statistics.
c.
Ping the ISP (192.31.7.1) from
both hosts.
d.
Display the NAT table and
statistics.
Gateway# show
ip nat statistics
Total active translations: 4 (0 static, 4
dynamic; 2 extended)
Peak translations: 15, occurred 00:00:43
ago
Outside interfaces:
Serial0/0/1
Inside interfaces:
GigabitEthernet0/1
Hits: 16
Misses: 0
CEF Translated packets: 285, CEF Punted
packets: 0
Expired translations: 11
Dynamic mappings:
-- Inside Source
[Id: 1] access-list 1 pool public_access
refcount 4
pool
public_access: netmask 255.255.255.224
start 209.165.200.242 end 209.165.200.254
type generic, total addresses 13, allocated 2 (15%), misses 0
Total doors: 0
Appl doors: 0
Normal doors: 0
Queued Packets: 0
Gateway# show
ip nat translation
Pro
Inside global Inside local Outside local Outside global
icmp
209.165.200.243:512 192.168.1.20:512 192.31.7.1:512 192.31.7.1:512
---
209.165.200.243 192.168.1.20 --- ---
icmp
209.165.200.242:512 192.168.1.21:512 192.31.7.1:512 192.31.7.1:512
--- 209.165.200.242 192.168.1.21 --- ---
Note: This is only a sample output. Your output may not match exactly.
Reflection
1.
Why would NAT be used in a
network?
_______________________________________________________________________________________
_______________________________________________________________________________________
_______________________________________________________________________________________
2.
What are the limitations of NAT?
_______________________________________________________________________________________
_______________________________________________________________________________________
_______________________________________________________________________________________
Router Interface Summary Table
Router Interface Summary
|
||||
Router Model
|
Ethernet Interface #1
|
Ethernet Interface #2
|
Serial Interface #1
|
Serial Interface #2
|
1800
|
Fast Ethernet 0/0 (F0/0)
|
Fast Ethernet 0/1 (F0/1)
|
Serial 0/0/0 (S0/0/0)
|
Serial 0/0/1 (S0/0/1)
|
1900
|
Gigabit Ethernet 0/0 (G0/0)
|
Gigabit Ethernet 0/1 (G0/1)
|
Serial 0/0/0 (S0/0/0)
|
Serial 0/0/1 (S0/0/1)
|
2801
|
Fast Ethernet 0/0 (F0/0)
|
Fast Ethernet 0/1 (F0/1)
|
Serial 0/1/0 (S0/1/0)
|
Serial 0/1/1 (S0/1/1)
|
2811
|
Fast Ethernet 0/0 (F0/0)
|
Fast Ethernet 0/1 (F0/1)
|
Serial 0/0/0 (S0/0/0)
|
Serial 0/0/1 (S0/0/1)
|
2900
|
Gigabit Ethernet 0/0 (G0/0)
|
Gigabit Ethernet 0/1 (G0/1)
|
Serial 0/0/0 (S0/0/0)
|
Serial 0/0/1 (S0/0/1)
|
Note: To find out how the router is configured, look at the interfaces
to identify the type of router and how many interfaces the router has. There
is no way to effectively list all the combinations of configurations for each
router class. This table includes identifiers for the possible combinations
of Ethernet and Serial interfaces in the device. The table does not include
any other type of interface, even though a specific router may contain one.
An example of this might be an ISDN BRI interface. The string in parenthesis
is the legal abbreviation that can be used in Cisco IOS commands to represent
the interface.
|
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