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Tcp-Ip Essay, Research Paper

November 13, 2000

TCP-IP

TCP and IP were developed by a Department of Defense (DOD) research project to

connect a number different networks designed by different vendors into a network of networks

(the “Internet”). It was initially successful because it delivered a few basic services that everyone

needs (file transfer, electronic mail, remote logon) across a very large number of client and server

systems. Several computers in a small department can use TCP/IP (along with other protocols) on

a single LAN. The IP component provides routing from the department to the enterprise network,

then to regional networks, and finally to the global Internet. On the battlefield a communications

network will sustain damage, so the DOD designed TCP/IP to be robust and automatically

recover from any node or phone line failure. This design allows the construction of very large

networks with less central management. However, because of the automatic recovery, network

problems can go undiagnosed and uncorrected for long periods of time.

As with all other communications protocol, TCP/IP is composed of layers:

IP – is responsible for moving packet of data from node to node. IP forwards each packet

based on a four byte destination address (the IP number). The Internet authorities assign

ranges of numbers to different organizations. The organizations assign groups of their

numbers to departments. IP operates on gateway machines that move data from

department to organization to region and then around the world.

TCP – is responsible for verifying the correct delivery of data from client to server. Data

can be lost in the intermediate network. TCP adds support to detect errors or lost data and

to trigger retransmission until the data is correctly and completely received.

Sockets – is a name given to the package of subroutines that provide access to TCP/IP on

most systems.

Network of Lowest Bidders

The Army puts out a bid on a computer and DEC wins the bid. The Air Force puts out a bid and

IBM wins. The Navy bid is won by Unisys. Then the President decides to invade Grenada and

the armed forces discover that their computers cannot talk to each other. The DOD must build a

“network” out of systems each of which, by law, was delivered by the lowest bidder on a single

contract.

The Internet Protocol was developed to create a Network of Networks (the “Internet”).

Individual machines are first connected to a LAN (Ethernet or Token Ring). TCP/IP shares the

LAN with other uses (a Novell file server, Windows for Workgroups peer systems). One device

provides the TCP/IP connection between the LAN and the rest of the world.

To insure that all types of systems from all vendors can communicate, TCP/IP is absolutely

standardized on the LAN. However, larger networks based on long distances and phone lines are

more volatile. In the US, many large corporations would wish to reuse large internal networks

based on IBM’s SNA. In Europe, the national phone companies traditionally standardize on

X.25. However, the sudden explosion of high speed microprocessors, fiber optics, and digital

phone systems has created a burst of new options: ISDN, frame relay, FDDI, Asynchronous

Transfer Mode (ATM). New technologies arise and become obsolete within a few years. With

cable TV and phone companies competing to build the National Information Superhighway, no

single standard can govern citywide, nationwide, or worldwide communications.

The original design of TCP/IP as a Network of Networks fits nicely within the current

technological uncertainty. TCP/IP data can be sent across a LAN, or it can be carried within an

internal corporate SNA network, or it can piggyback on the cable TV service. Furthermore,

machines connected to any of these networks can communicate to any other network through

gateways supplied by the network vendor.

Addresses

Each technology has its own convention for transmitting messages between two machines within

the same network. On a LAN, messages are sent between machines by supplying the six byte

unique identifier (the “MAC” address). In an SNA network, every machine has Logical Units with

their own network address. DECNET, Appletalk, and Novell IPX all have a scheme for assigning

numbers to each local network and to each workstation attached to the network.

On top of these local or vendor specific network addresses, TCP/IP assigns a unique number to

every workstation in the world. This “IP number” is a four byte value that, by convention, is

expressed by converting each byte into a decimal number (0 to 255) and separating the bytes with

a period. For example, the PC Lube and Tune server is 130.132.59.234.

An organization begins by sending electronic mail to [email protected] requesting

assignment of a network number. It is still possible for almost anyone to get assignment of a

number for a small “Class C” network in which the first three bytes identify the network and the

last byte identifies the individual computer. The author followed this procedure and was assigned

the numbers 192.35.91.* for a network of computers at his house. Larger organizations can get a

“Class B” network where the first two bytes identify the network and the last two bytes identify

each of up to 64 thousand individual workstations. Yale’s Class B network is 130.132, so all

computers with IP address 130.132.*.* are connected through Yale.

The organization then connects to the Internet through one of a dozen regional or specialized

network suppliers. The network vendor is given the subscriber network number and adds it to the

routing configuration in its own machines and those of the other major network suppliers.

There is no mathematical formula that translates the numbers 192.35.91 or 130.132 into “Yale

University” or “New Haven, CT.” The machines that manage large regional networks or the

central Internet routers managed by the National Science Foundation can only locate these

networks by looking each network number up in a table. There are potentially thousands of Class

B networks, and millions of Class C networks, but computer memory costs are low, so the tables

are reasonable. Customers that connect to the Internet, even customers as large as IBM, do not

need to maintain any information on other networks. They send all external data to the regional

carrier to which they subscribe, and the regional carrier maintains the tables and does the

appropriate routing.

New Haven is in a border state, split 50-50 between the Yankees and the Red Sox. In this spirit,

Yale recently switched its connection from the Middle Atlantic regional network to the New

England carrier. When the switch occurred, tables in the other regional areas and in the national

spine had to be updated, so that traffic for 130.132 was routed through Boston instead of New

Jersey. The large network carriers handle the paperwork and can perform such a switch given

sufficient notice. During a conversion period, the university was connected to both networks so

that messages could arrive through either path.

Subnets

Although the individual subscribers do not need to tabulate network numbers or provide explicit

routing, it is convenient for most Class B networks to be internally managed as a much smaller and

simpler version of the larger network organizations. It is common to subdivide the two bytes

available for internal assignment into a one byte department number and a one byte workstation

ID.

The enterprise network is built using commercially available TCP/IP router boxes. Each router has

small tables with 255 entries to translate the one byte department number into selection of a

destination Ethernet connected to one of the routers. Messages to the PC Lube and Tune server

(130.132.59.234) are sent through the national and New England regional networks based on the

130.132 part of the number. Arriving at Yale, the 59 department ID selects an Ethernet connector

in the C& IS building. The 234 selects a particular workstation on that LAN. The Yale network

must be updated as new Ethernets and departments are added, but it is not effected by changes

outside the university or the movement of machines within the department.

A Uncertain Path

Every time a message arrives at an IP router, it makes an individual decision about where to send

it next. There is concept of a session with a preselected path for all traffic. Consider a company

with facilities in New York, Los Angeles, Chicago and Atlanta. It could build a network from four

phone lines forming a loop (NY to Chicago to LA to Atlanta to NY). A message arriving at the

NY router could go to LA via either Chicago or Atlanta. The reply could come back the other

way.

How does the router make a decision between routes? There is no correct answer. Traffic could

be routed by the “clockwise” algorithm (go NY to Atlanta, LA to Chicago). The routers could

alternate, sending one message to Atlanta and the next to Chicago. More sophisticated routing

measures traffic patterns and sends data through the least busy link.

If one phone line in this network breaks down, traffic can still reach its destination through a

roundabout path. After losing the NY to Chicago line, data can be sent NY to Atlanta to LA to

Chicago. This provides continued service though with degraded performance. This kind of

recovery is the primary design feature of IP. The loss of the line is immediately detected by the

routers in NY and Chicago, but somehow this information must be sent to the other nodes.

Otherwise, LA could continue to send NY messages through Chicago, where they arrive at a

“dead end.” Each network adopts some Router Protocol which periodically updates the routing

tables throughout the network with information about changes in route status.

If the size of the network grows, then the complexity of the routing updates will increase as will the

cost of transmitting them. Building a single network that covers the entire US would be

unreasonably complicated. Fortunately, the Internet is designed as a Network of Networks. This

means that loops and redundancy are built into each regional carrier. The regional network

handles its own problems and reroutes messages internally. Its Router Protocol updates the tables

in its own routers, but no routing updates need to propagate from a regional carrier to the NSF

spine or to the other regions (unless, of course, a subscriber switches permanently from one

region to another).

Undiagnosed Problems

IBM designs its SNA networks to be centrally managed. If any error occurs, it is reported to the

network authorities. By design, any error is a problem that should be corrected or repaired. IP

networks, however, were designed to be robust. In battlefield conditions, the loss of a node or

line is a normal circumstance. Casualties can be sorted out later on, but the network must stay up.

So IP networks are robust. They automatically (and silently) reconfigure themselves when

something goes wrong. If there is enough redundancy built into the system, then communication is

maintained.

In 1975 when SNA was designed, such redundancy would be prohibitively expensive, or it might

have been argued that only the Defense Department could afford it. Today, however, simple

routers cost no more than a PC. However, the TCP/IP design that, “Errors are normal and can be

largely ignored,” produces problems of its own.

Data traffic is frequently organized around “hubs,” much like airline traffic. One could imagine an

IP router in Atlanta routing messages for smaller cities throughout the Southeast. The problem is

that data arrives without a reservation. Airline companies experience the problem around major

events, like the Super Bowl. Just before the game, everyone wants to fly into the city. After the

game, everyone wants to fly out. Imbalance occurs on the network when something new gets

advertised. Adam Curry announced the server at “mtv.com” and his regional carrier was

swamped with traffic the next day. The problem is that messages come in from the entire world

over high speed lines, but they go out to mvt.com over what was then a slow speed phone line.

Occasionally a snow storm cancels flights and airports fill up with stranded passengers. Many go

off to hotels in town. When data arrives at a congested router, there is no place to send the

overflow. Excess packets are simply discarded. It becomes the responsibility of the sender to

retry the data a few seconds later and to persist until it finally gets through. This recovery is

provided by the TCP component of the Internet protocol.

TCP was designed to recover from node or line failures where the network propagates routing

table changes to all router nodes. Since the update takes some time, TCP is slow to initiate

recovery. The TCP algorithms are not tuned to optimally handle packet loss due to traffic

congestion. Instead, the traditional Internet response to traffic problems has been to increase the

speed of lines and equipment in order to say ahead of growth in demand.

TCP treats the data as a stream of bytes. It logically assigns a sequence number to each byte. The

TCP packet has a header that says, in effect, “This packet starts with byte 379642 and contains

200 bytes of data.” The receiver can detect missing or incorrectly sequenced packets. TCP

acknowledges data that has been received and retransmits data that has been lost. The TCP

design means that error recovery is done end-to-end between the Client and Server machine.

There is no formal standard for tracking problems in the middle of the network, though each

network has adopted some ad hoc tools.


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