In 90s we observed an exponential growth of users connecting to a global network called the Internet. As of today, there are billions of people in this global village. The problem is that the designers of TCP/IP protocol suite did not realize this would happen. With the 32 bit IP address that was used originally we could allocate more than 4 billions unique identifiers. Apparently, this is not enough today having billions of devices using public network.
In February 1996 RFC 1918 document has been published. In it, some IP address reservations have been made known as PRIVATE ADDRESS SPACE. The ranges have been reserved as follows:
- 10.0.0.0 - 10.255.255.255 (10/8 prefix)
- 172.16.0.0 - 172.31.255.255 (172.16/12 prefix)
- 192.168.0.0 - 192.168.255.255 (192.168/16 prefix)
What is NAT?
Network Address Translation is a technique in which the EDGE router (the one that is connected to ISP (Internet Service Provider) and your LAN, removes the original SOURCE address in the IP header (private range - RFC 1918) and replaces with legitimate, unique, public one leased to us by ISP while sending packets towards the Internet. However it is smart enough to keep this information in the special database called: NAT table. When the reply comes back, the SOURCE and DESTINATION addresses are reversed in the IP header. Once the packet reaches our EDGE router, it uses the right entry in the NAT table to swap the destination IP PUBLIC address (that represented our computer) back to its PRIVATE address.
If it sounds a little vague right now, do not worry since in my next post I will show you this operation step by step using some graphics.
If you want to fully understand this technique, you must understand the terminology that is used by it first. The official terms can be found on Cisco web site:
Look at the below picture I'm going to use in the NAT section of this tutorial.
Pic. 1 - NAT TopologyIcons designed by: Andrzej Szoblik - http://www.newo.pl
What you are looking at is two companies (ABC and XYZ) connected to the Internet represented by R3 here. In real life this cloud consists of many routers belonging to different ISPs.
Computers are connected to the LAN and in both cases (I did this on purpose), use the same range of Private Address (192.168.1.0/24). Of course they can use any of addresses listed in RFC 1918.
R1's Serial0/1 interface uses 126.96.36.199, and R2 uses 188.8.131.52 address. Both are NOT described as the PRIVATE so they are PUBLIC or legitimate ones (my apologies if I used somebody's real, public addresses here. They are only used for educational purposes).
Using NAT technique you must be able to properly name them as per Cisco article above. Let's assume that we work for ABC company and we look at all addresses from this standpoint (this is critical). Here's what they are as per Pic. 1:
- INSIDE LOCAL - address (inside your LAN, before translation). In our example this would be our 192.168.1.0 (ABC) address.
- INSIDE GLOBAL - address used on the router's interface facing the Internet. GLOBAL means that is is legitimate, globally unique address. These are provided by ISP or Network Information Center (RIPE in Europe, ARIN in the US, etc.). For instance, in the example this would be 184.108.40.206 address.
- OUTSIDE GLOBAL - address which is also globally unique (like inside global), but is leased to another company, not us (remember? We're ABC here). In this example this would be 220.127.116.11 for instance.
- OUTSIDE LOCAL - address of the outside host as it appears to our local hosts. Typically in the NAT table we see them as OUTSIDE GLOBAL addresses. Our R1 router will never see XYZ company's 192.168.1.0 scope since it will be translated into a public IP before they send packets towards the Internet.
If you want to read more in-depth description of the terminology please, read the Cisco article I included in this post.
This concludes the introduction to NAT. In my next post, we will inspect step-by-step the process of NAT on the router.