RFC1118

Network Working Group E. Krol Request for Comments: 1118 University of Illinois Urbana

                                                      September 1989

             The Hitchhikers Guide to the Internet

Status of this Memo

This RFC is being distributed to members of the Internet community in order to make available some "hints" which will allow new network participants to understand how the direction of the Internet is set, how to acquire online information and how to be a good Internet neighbor. While the information discussed may not be relevant to the research problems of the Internet, it may be interesting to a number of researchers and implementors. No standards are defined or specified in this memo. Distribution of this memo is unlimited.

NOTICE:

The hitchhikers guide to the Internet is a very unevenly edited memo and contains many passages which simply seemed to its editors like a good idea at the time. It is an indispensable companion to all those who are keen to make sense of life in an infinitely complex and confusing Internet, for although it cannot hope to be useful or informative on all matters, it does make the reassuring claim that where it is inaccurate, it is at least definitively inaccurate. In cases of major discrepancy it is always reality that's got it wrong. And remember, DON'T PANIC. (Apologies to Douglas Adams.)

Purpose and Audience

This document assumes that one is familiar with the workings of a non-connected simple IP network (e.g., a few 4.3 BSD systems on an Ethernet not connected to anywhere else). Appendix A contains remedial information to get one to this point. Its purpose is to get that person, familiar with a simple net, versed in the "oral tradition" of the Internet to the point that that net can be connected to the Internet with little danger to either. It is not a tutorial, it consists of pointers to other places, literature, and hints which are not normally documented. Since the Internet is a dynamic environment, changes to this document will be made regularly. The author welcomes comments and suggestions. This is especially true of terms for the glossary (definitions are not necessary).

What is the Internet?

In the beginning there was the ARPANET, a wide area experimental network connecting hosts and terminal servers together. Procedures were set up to regulate the allocation of addresses and to create voluntary standards for the network. As local area networks became more pervasive, many hosts became gateways to local networks. A network layer to allow the interoperation of these networks was developed and called Internet Protocol (IP). Over time other groups created long haul IP based networks (NASA, NSF, states...). These nets, too, interoperate because of IP. The collection of all of these interoperating networks is the Internet.

A few groups provide much of the information services on the Internet. Information Sciences Institute (ISI) does much of the standardization and allocation work of the Internet acting as the Internet Assigned Numbers Authority (IANA). SRI International provides the principal information services for the Internet by operating the Network Information Center (NIC). In fact, after you are connected to the Internet most of the information in this document can be retrieved from the SRI-NIC. Bolt Beranek and Newman (BBN) provides information services for CSNET (the CIC) and NSFNET (the NNSC), and Merit provides information services for NSFNET (the NIS).

Operating the Internet

Each network, be it the ARPANET, NSFNET or a regional network, has its own operations center. The ARPANET is run by BBN, Inc. under contract from DCA (on behalf of DARPA). Their facility is called the Network Operations Center or NOC. Merit, Inc. operates NSFNET from yet another and completely seperate NOC. It goes on to the regionals having similar facilities to monitor and keep watch over the goings on of their portion of the Internet. In addition, they all should have some knowledge of what is happening to the Internet in total. If a problem comes up, it is suggested that a campus network liaison should contact the network operator to which he is directly connected. That is, if you are connected to a regional network (which is gatewayed to the NSFNET, which is connected to the ARPANET...) and have a problem, you should contact your regional network operations center.

RFCs

The internal workings of the Internet are defined by a set of documents called RFCs (Request for Comments). The general process for creating an RFC is for someone wanting something formalized to write a document describing the issue and mailing it to Jon Postel

([email protected]). He acts as a referee for the proposal. It is then commented upon by all those wishing to take part in the discussion (electronically of course). It may go through multiple revisions. Should it be generally accepted as a good idea, it will be assigned a number and filed with the RFCs.

There are two independent categorizations of protocols. The first is the state of standardization which is one of "standard", "draft standard", "proposed", "experimental", or "historic". The second is the status of this protocol which is one of "required", "recommended", "elective", or "not recommended". One could expect a particular protocol to move along the scale of status from elective to required at the same time as it moves along the scale of standardization from proposed to standard.

A Required Standard protocol (e.g., RFC-791, The Internet Protocol) must be implemented on any host connected to the Internet. Recommended Standard protocols are generally implemented by network hosts. Lack of them does not preclude access to the Internet, but may impact its usability. RFC-793 (Transmission Control Protocol) is a Recommended Standard protocol. Elective Proposed protocols were discussed and agreed to, but their application has never come into wide use. This may be due to the lack of wide need for the specific application (RFC-937, The Post Office Protocol) or that, although technically superior, ran against other pervasive approaches. It is suggested that should the facility be required by a particular site, an implementation be done in accordance with the RFC. This insures that, should the idea be one whose time has come, the implementation will be in accordance with some standard and will be generally usable.

Informational RFCs contain factual information about the Internet and its operation (RFC-1010, Assigned Numbers). Finally, as the Internet and technology have grown, some RFCs have become unnecessary. These obsolete RFCs cannot be ignored, however. Frequently when a change is made to some RFC that causes a new one to be issued obsoleting others, the new RFC may only contains explanations and motivations for the change. Understanding the model on which the whole facility is based may involve reading the original and subsequent RFCs on the topic. (Appendix B contains a list of what are considered to be the major RFCs necessary for understanding the Internet).

Only a few RFCs actually specify standards, most RFCs are for information or discussion purposes. To find out what the current standards are see the RFC titled "IAB Official Protocol Standards" (most recently published as RFC-1100).

The Network Information Center (NIC)

The NIC is a facility available to all Internet users which provides information to the community. There are three means of NIC contact: network, telephone, and mail. The network accesses are the most prevalent. Interactive access is frequently used to do queries of NIC service overviews, look up user and host names, and scan lists of NIC documents. It is available by using

  %telnet nic.ddn.mil

on a BSD system, and following the directions provided by a user friendly prompter. From poking around in the databases provided, one might decide that a document named NETINFO:NUG.DOC (The Users Guide to the ARPANET) would be worth having. It could be retrieved via an anonymous FTP. An anonymous FTP would proceed something like the following. (The dialogue may vary slightly depending on the implementation of FTP you are using).

 %ftp nic.ddn.mil
 Connected to nic.ddn.mil
 220 NIC.DDN.MIL FTP Server 5Z(47)-6 at Wed 17-Jun-87 12:00 PDT
 Name (nic.ddn.mil:myname): anonymous
 331 ANONYMOUS user ok, send real ident as password.
 Password: myname
 230 User ANONYMOUS logged in at Wed 17-Jun-87 12:01 PDT, job 15.
 ftp> get netinfo:nug.doc
 200 Port 18.144 at host 128.174.5.50 accepted.
 150 ASCII retrieve of <NETINFO>NUG.DOC.11 started.
 226 Transfer Completed 157675 (8) bytes transferred
 local: netinfo:nug.doc  remote:netinfo:nug.doc
 157675 bytes in 4.5e+02 seconds (0.34 Kbytes/s)
 ftp> quit
 221 QUIT command received. Goodbye.

(Another good initial document to fetch is NETINFO:WHAT-THE-NIC- DOES.TXT).

Questions of the NIC or problems with services can be asked of or reported to using electronic mail. The following addresses can be used:

 [email protected]         General user assistance, document requests
 [email protected]   User registration and WHOIS updates
 [email protected]  Hostname and domain changes and updates
 [email protected]      SRI-NIC computer operations
 [email protected] Comments on NIC publications and services

For people without network access, or if the number of documents is large, many of the NIC documents are available in printed form for a small charge. One frequently ordered document for starting sites is a compendium of major RFCs. Telephone access is used primarily for questions or problems with network access. (See appendix B for mail/telephone contact numbers).

The NSFNET Network Service Center

The NSFNET Network Service Center (NNSC), located at BBN Systems and Technologies Corp., is a project of the University Corporation for Atmospheric Research under agreement with the National Science Foundation. The NNSC provides support to end-users of NSFNET should they have questions or encounter problems traversing the network.

The NNSC, which has information and documents online and in printed form, distributes news through network mailing lists, bulletins, and online reports. NNSC publications include a hardcopy newsletter, the NSF Network News, which contains articles of interest to network users and the Internet Resource Guide, which lists facilities (such as supercomputer centers and on-line library catalogues) accessible from the Internet. The Resource Guide can be obtained via anonymous ftp to nnsc.nsf.net in the directory resource-guide, or by joining the resource guide mailing list (send a subscription request to [email protected].)

Mail Reflectors

The way most people keep up to date on network news is through subscription to a number of mail reflectors (also known as mail exploders). Mail reflectors are special electronic mailboxes which, when they receive a message, resend it to a list of other mailboxes. This in effect creates a discussion group on a particular topic. Each subscriber sees all the mail forwarded by the reflector, and if one wants to put his "two cents" in sends a message with the comments to the reflector.

The general format to subscribe to a mail list is to find the address reflector and append the string -REQUEST to the mailbox name (not the host name). For example, if you wanted to take part in the mailing list for NSFNET reflected by [email protected], one sends a request to [email protected]. This may be a wonderful scheme, but the problem is that you must know the list exists in the first place. It is suggested that, if you are interested, you read the mail from one list (like NSFNET-INFO) and you will probably become familiar with the existence of others. A registration service for mail reflectors is provided by the NIC in the files NETINFO:INTEREST-GROUPS-1.TXT, NETINFO:INTEREST-GROUPS-2.TXT,

NETINFO:INTEREST-GROUPS-3.TXT, through NETINFO:INTEREST-GROUPS-9.TXT.

The NSFNET-INFO mail reflector is targeted at those people who have a day to day interest in the news of the NSFNET (the backbone, regional network, and Internet inter-connection site workers). The messages are reflected by a central location and are sent as separate messages to each subscriber. This creates hundreds of messages on the wide area networks where bandwidth is the scarcest.

There are two ways in which a campus could spread the news and not cause these messages to inundate the wide area networks. One is to re-reflect the message on the campus. That is, set up a reflector on a local machine which forwards the message to a campus distribution list. The other is to create an alias on a campus machine which places the messages into a notesfile on the topic. Campus users who want the information could access the notesfile and see the messages that have been sent since their last access. One might also elect to have the campus wide area network liaison screen the messages in either case and only forward those which are considered of merit. Either of these schemes allows one message to be sent to the campus, while allowing wide distribution within.

Address Allocation

Before a local network can be connected to the Internet it must be allocated a unique IP address. These addresses are allocated by SRI-NIC. The allocation process consists of getting an application form. Send a message to [email protected] and ask for the template for a connected address. This template is filled out and mailed back to the hostmaster. An address is allocated and e-mailed back to you. This can also be done by postal mail (Appendix B).

IP addresses are 32 bits long. It is usually written as four decimal numbers separated by periods (e.g., 192.17.5.100). Each number is the value of an octet of the 32 bits. Some networks might choose to organize themselves as very flat (one net with a lot of nodes) and some might organize hierarchically (many interconnected nets with fewer nodes each and a backbone). To provide for these cases, addresses were differentiated into class A, B, and C networks. This classification had to with the interpretation of the octets. Class A networks have the first octet as a network address and the remaining three as a host address on that network. Class C addresses have three octets of network address and one of host. Class B is split two and two. Therefore, there is an address space for a few large nets, a reasonable number of medium nets and a large number of small nets. The high order bits in the first octet are coded to tell the address format. There are very few unallocated class A nets, so a very good case must be made for them. So as a practical matter, one

has to choose between Class B and Class C when placing an order. (There are also class D (Multicast) and E (Experimental) formats. Multicast addresses will likely come into greater use in the near future, but are not frequently used yet).

In the past, sites requiring multiple network addresses requested multiple discrete addresses (usually Class C). This was done because much of the software available (notably 4.2BSD) could not deal with subnetted addresses. Information on how to reach a particular network (routing information) must be stored in Internet gateways and packet switches. Some of these nodes have a limited capability to store and exchange routing information (limited to about 700 networks). Therefore, it is suggested that any campus announce (make known to the Internet) no more than two discrete network numbers.

If a campus expects to be constrained by this, it should consider subnetting. Subnetting (RFC-950) allows one to announce one address to the Internet and use a set of addresses on the campus. Basically, one defines a mask which allows the network to differentiate between the network portion and host portion of the address. By using a different mask on the Internet and the campus, the address can be interpreted in multiple ways. For example, if a campus requires two networks internally and has the 32,000 addresses beginning 128.174.X.X (a Class B address) allocated to it, the campus could allocate 128.174.5.X to one part of campus and 128.174.10.X to another. By advertising 128.174 to the Internet with a subnet mask of FF.FF.00.00, the Internet would treat these two addresses as one. Within the campus a mask of FF.FF.FF.00 would be used, allowing the campus to treat the addresses as separate entities. (In reality, you don't pass the subnet mask of FF.FF.00.00 to the Internet, the octet meaning is implicit in its being a class B address).

A word of warning is necessary. Not all systems know how to do subnetting. Some 4.2BSD systems require additional software. 4.3BSD systems subnet as released. Other devices and operating systems vary in the problems they have dealing with subnets. Frequently, these machines can be used as a leaf on a network but not as a gateway within the subnetted portion of the network. As time passes and more systems become 4.3BSD based, these problems should disappear.

There has been some confusion in the past over the format of an IP broadcast address. Some machines used an address of all zeros to mean broadcast and some all ones. This was confusing when machines of both type were connected to the same network. The broadcast address of all ones has been adopted to end the grief. Some systems (e.g., 4.3 BSD) allow one to choose the format of the broadcast address. If a system does allow this choice, care should be taken that the all ones format is chosen. (This is explained in RFC-1009

and RFC-1010).

Internet Problems

There are a number of problems with the Internet. Solutions to the problems range from software changes to long term research projects. Some of the major ones are detailed below:

Number of Networks

  When the Internet was designed it was to have about 50 connected
  networks.  With the explosion of networking, the number is now
  approaching 1000.  The software in a group of critical gateways
  (called the core gateways) are not able to pass or store much more
  than that number.  In the short term, core reallocation and
  recoding has raised the number slightly.

Routing Issues

  Along with sheer mass of the data necessary to route packets to a
  large number of networks, there are many problems with the
  updating, stability, and optimality of the routing algorithms.
  Much research is being done in the area, but the optimal solution
  to these routing problems is still years away.  In most cases, the
  the routing we have today works, but sub-optimally and sometimes
  unpredictably.  The current best hope for a good routing protocol
  is something known as OSPFIGP which will be generally available
  from many router manufacturers within a year.

Trust Issues

  Gateways exchange network routing information.  Currently, most
  gateways accept on faith that the information provided about the
  state of the network is correct.  In the past this was not a big
  problem since most of the gateways belonged to a single
  administrative entity (DARPA).  Now, with multiple wide area
  networks under different administrations, a rogue gateway
  somewhere in the net could cripple the Internet.  There is design
  work going on to solve both the problem of a gateway doing
  unreasonable things and providing enough information to reasonably
  route data between multiply connected networks (multi-homed
  networks).

Capacity & Congestion

  Some portions of the Internet are very congested during the busy
  part of the day.  Growth is dramatic with some networks
  experiencing growth in traffic in excess of 20% per month.

  Additional bandwidth is planned, but delivery and budgets might
  not allow supply to keep up.

Setting Direction and Priority

The Internet Activities Board (IAB), currently chaired by Vint Cerf of NRI, is responsible for setting the technical direction, establishing standards, and resolving problems in the Internet.

The current IAB members are:

       Vinton Cerf          - Chairman
       David Clark          - IRTF Chairman
       Phillip Gross        - IETF Chairman
       Jon Postel           - RFC Editor
       Robert Braden        - Executive Director
       Hans-Werner Braun    - NSFNET Liaison
       Barry Leiner         - CCIRN Liaison
       Daniel Lynch         - Vendor Liaison
       Stephen Kent         - Internet Security

This board is supported by a Research Task Force (chaired by Dave Clark of MIT) and an Engineering Task Force (chaired by Phill Gross of NRI).

The Internet Research Task Force has the following Research Groups:

        Autonomous Networks            Deborah Estrin
        End-to-End Services            Bob Braden
        Privacy                        Steve Kent
        User Interfaces                Keith Lantz

The Internet Engineering Task Force has the following technical areas:

       Applications                    TBD
       Host Protocols                  Craig Partridge
       Internet Protocols              Noel Chiappa
       Routing                         Robert Hinden
       Network Management              David Crocker
       OSI Interoperability            Ross Callon, Robert Hagen
       Operations                      TBD
       Security                        TBD

The Internet Engineering Task Force has the following Working Groups:

        ALERTMAN                       Louis Steinberg
        Authentication                 Jeff Schiller

        CMIP over TCP                  Lee LaBarre
        Domain Names                   Paul Mockapetris
        Dynamic Host Config            Ralph Droms
        Host Requirements              Bob Braden
        Interconnectivity              Guy Almes
        Internet MIB                   Craig Partridge
        Joint Management               Susan Hares
        LAN Mgr MIB                    Amatzia Ben-Artzi
        NISI                           Karen Bowers
        NM Serial Interface            Jeff Case
        NOC Tools                      Bob Enger
        OSPF                           Mike Petry
        Open Systems Routing           Marianne Lepp
        OSI Interoperability           Ross Callon
        PDN Routing Group              CH Rokitansky
        Performance and CC             Allison Mankin
        Point - Point IP               Drew Perkins
        ST and CO-IP                   Claudio Topolcic
        Telnet                         Dave Borman
        User Documents                 Karen Roubicek
        User Services                  Karen Bowers

Routing

Routing is the algorithm by which a network directs a packet from its source to its destination. To appreciate the problem, watch a small child trying to find a table in a restaurant. From the adult point of view, the structure of the dining room is seen and an optimal route easily chosen. The child, however, is presented with a set of paths between tables where a good path, let alone the optimal one to the goal is not discernible.

A little more background might be appropriate. IP gateways (more correctly routers) are boxes which have connections to multiple networks and pass traffic between these nets. They decide how the packet is to be sent based on the information in the IP header of the packet and the state of the network. Each interface on a router has an unique address appropriate to the network to which it is connected. The information in the IP header which is used is primarily the destination address. Other information (e.g., type of service) is largely ignored at this time. The state of the network is determined by the routers passing information among themselves. The distribution of the database (what each node knows), the form of the updates, and metrics used to measure the value of a connection, are the parameters which determine the characteristics of a routing protocol.

Under some algorithms, each node in the network has complete

knowledge of the state of the network (the adult algorithm). This implies the nodes must have larger amounts of local storage and enough CPU to search the large tables in a short enough time (remember, this must be done for each packet). Also, routing updates usually contain only changes to the existing information (or you spend a large amount of the network capacity passing around megabyte routing updates). This type of algorithm has several problems. Since the only way the routing information can be passed around is across the network and the propagation time is non-trivial, the view of the network at each node is a correct historical view of the network at varying times in the past. (The adult algorithm, but rather than looking directly at the dining area, looking at a photograph of the dining room. One is likely to pick the optimal route and find a bus-cart has moved in to block the path after the photo was taken). These inconsistencies can cause circular routes (called routing loops) where once a packet enters it is routed in a closed path until its time to live (TTL) field expires and it is discarded.

Other algorithms may know about only a subset of the network. To prevent loops in these protocols, they are usually used in a hierarchical network. They know completely about their own area, but to leave that area they go to one particular place (the default gateway). Typically these are used in smaller networks (campus or regional).

Routing protocols in current use:

Static (no protocol-table/default routing)

  Don't laugh.  It is probably the most reliable, easiest to
  implement, and least likely to get one into trouble for a small
  network or a leaf on the Internet.  This is, also, the only method
  available on some CPU-operating system combinations.  If a host is
  connected to an Ethernet which has only one gateway off of it, one
  should make that the default gateway for the host and do no other
  routing.  (Of course, that gateway may pass the reachability
  information somehow on the other side of itself.)

  One word of warning, it is only with extreme caution that one
  should use static routes in the middle of a network which is also
  using dynamic routing.  The routers passing dynamic information
  are sometimes confused by conflicting dynamic and static routes.
  If your host is on an ethernet with multiple routers to other
  networks on it and the routers are doing dynamic routing among
  themselves, it is usually better to take part in the dynamic
  routing than to use static routes.

RIP

  RIP is a routing protocol based on XNS (Xerox Network System)
  adapted for IP networks.  It is used by many routers (Proteon,
  cisco, UB...) and many BSD Unix systems.  BSD systems typically
  run a program called "routed" to exchange information with other
  systems running RIP.  RIP works best for nets of small diameter
  (few hops) where the links are of equal speed.  The reason for
  this is that the metric used to determine which path is best is
  the hop-count.  A hop is a traversal across a gateway.  So, all
  machines on the same Ethernet are zero hops away.  If a router
  connects connects two networks directly, a machine on the other
  side of the router is one hop away.  As the routing information is
  passed through a gateway, the gateway adds one to the hop counts
  to keep them consistent across the network.  The diameter of a
  network is defined as the largest hop-count possible within a
  network.  Unfortunately, a hop count of 16 is defined as infinity
  in RIP meaning the link is down.  Therefore, RIP will not allow
  hosts separated by more than 15 gateways in the RIP space to
  communicate.

  The other problem with hop-count metrics is that if links have
  different speeds, that difference is not reflected in the hop-
  count.  So a one hop satellite link (with a .5 sec delay) at 56kb
  would be used instead of a two hop T1 connection.  Congestion can
  be viewed as a decrease in the efficacy of a link.  So, as a link
  gets more congested, RIP will still know it is the best hop-count
  route and congest it even more by throwing more packets on the
  queue for that link.

  RIP was originally not well documented in the community and people
  read BSD code to find out how RIP really worked.  Finally, it was
  documented in RFC-1058.

Routed

  The routed program, which does RIP for 4.2BSD systems, has many
  options.  One of the most frequently used is: "routed -q" (quiet
  mode) which means listen to RIP information, but never broadcast
  it.  This would be used by a machine on a network with multiple
  RIP speaking gateways.  It allows the host to determine which
  gateway is best (hopwise) to use to reach a distant network.  (Of
  course, you might want to have a default gateway to prevent having
  to pass all the addresses known to the Internet around with RIP.)

  There are two ways to insert static routes into routed; the
  /etc/gateways file, and the "route add" command.  Static routes
  are useful if you know how to reach a distant network, but you are

  not receiving that route using RIP.  For the most part the "route
  add" command is preferable to use.  The reason for this is that
  the command adds the route to that machine's routing table but
  does not export it through RIP.  The /etc/gateways file takes
  precedence over any routing information received through a RIP
  update.  It is also broadcast as fact in RIP updates produced by
  the host without question, so if a mistake is made in the
  /etc/gateways file, that mistake will soon permeate the RIP space
  and may bring the network to its knees.

  One of the problems with routed is that you have very little
  control over what gets broadcast and what doesn't.  Many times in
  larger networks where various parts of the network are under
  different administrative controls, you would like to pass on
  through RIP only nets which you receive from RIP and you know are
  reasonable.  This prevents people from adding IP addresses to the
  network which may be illegal and you being responsible for passing
  them on to the Internet.  This type of reasonability checks are
  not available with routed and leave it usable, but inadequate for
  large networks.

Hello (RFC-891)

  Hello is a routing protocol which was designed and implemented in
  a experimental software router called a "Fuzzball" which runs on a
  PDP-11.  It does not have wide usage, but is the routing protocol
  formerly used on the initial NSFNET backbone.  The data
  transferred between nodes is similar to RIP (a list of networks
  and their metrics).  The metric, however, is milliseconds of
  delay.  This allows Hello to be used over nets of various link
  speeds and performs better in congestive situations.

  One of the most interesting side effects of Hello based networks
  is their great timekeeping ability.  If you consider the problem
  of measuring delay on a link for the metric, you find that it is
  not an easy thing to do.  You cannot measure round trip time since
  the return link may be more congested, of a different speed, or
  even not there.  It is not really feasible for each node on the
  network to have a builtin WWV (nationwide radio time standard)
  receiver.  So, you must design an algorithm to pass around time
  between nodes over the network links where the delay in
  transmission can only be approximated.  Hello routers do this and
  in a nationwide network maintain synchronized time within
  milliseconds. (See also the Network Time Protocol, RFC-1059.)

Gateway Gateway Protocol (GGP RFC-823)

  The core gateways originally used GGP to exchange information
  among themselves.  This is a "distance-vector" algorithm.  The new
  core gateways use a "link-state" algorithm.

NSFNET SPF (RFC-1074)

  The current NSFNET Backbone routers use a version of the ANSI IS-
  IS and ISO ES-IS routing protocol.  This is a "shortest path
  first" (SPF) algorithm which is in the class of "link-state"
  algorithms.

Exterior Gateway Protocol (EGP RFC-904)

  EGP is not strictly a routing protocol, it is a reachability
  protocol.  It tells what nets can be reached through what gateway,
  but not how good the connection is.  It is the standard by which
  gateways exchange network reachability information with the core
  gateways.  It is generally used between autonomous systems.  There
  is a metric passed around by EGP, but its usage is not
  standardized formally.  The metric's value ranges from 0 to 255
  with smaller values considered "better".  Some implementations
  consider the value 255 to mean unreachable.  Many routers talk EGP
  so they can be used to interface to routers of different
  manufacture or operated by different administrations.  For
  example, when a router of the NSFNET Backbone exchanges routing or
  reachability information with a gateway of a regional network EGP
  is used.

Gated

  So we have regional and campus networks talking RIP among
  themselves and the DDN and NSFNET speaking EGP.  How do they
  interoperate?  In the beginning, there was static routing.  The
  problem with doing static routing in the middle of the network is
  that it is broadcast to the Internet whether it is usable or not.
  Therefore, if a net becomes unreachable and you try to get there,
  dynamic routing will immediately issue a net unreachable to you.
  Under static routing the routers would think the net could be
  reached and would continue trying until the application gave up
  (in 2 or more minutes).  Mark Fedor, then of Cornell, attempted to
  solve these problems with a replacement for routed called gated.

  Gated talks RIP to RIP speaking hosts, EGP to EGP speakers, and
  Hello to Hello'ers.  These speakers frequently all live on one
  Ethernet, but luckily (or unluckily) cannot understand each others
  ruminations.  In addition, under configuration file control it can

  filter the conversion.  For example, one can produce a
  configuration saying announce RIP nets via Hello only if they are
  specified in a list and are reachable by way of a RIP broadcast as
  well.  This means that if a rogue network appears in your local
  site's RIP space, it won't be passed through to the Hello side of
  the world.  There are also configuration options to do static
  routing and name trusted gateways.

  This may sound like the greatest thing since sliced bread, but
  there is a catch called metric conversion.  You have RIP measuring
  in hops, Hello measuring in milliseconds, and EGP using arbitrary
  small numbers.  The big questions is how many hops to a

  remember that infinity (unreachability) is 16 to RIP, 30000 or so
  to Hello, and 8 to the DDN with EGP.  Getting all these metrics to
  work well together is no small feat.  If done incorrectly and you
  translate an RIP of 16 into an EGP of 6, everyone in the ARPANET
  will still think your gateway can reach the unreachable and will
  send every packet in the world your way.  Gated is available via
  anonymous FTP from devvax.tn.cornell.edu in directory pub/gated.

Names

All routing across the network is done by means of the IP address associated with a packet. Since humans find it difficult to remember addresses like 128.174.5.50, a symbolic name register was set up at the NIC where people would say, "I would like my host to be named uiucuxc". Machines connected to the Internet across the nation would connect to the NIC in the middle of the night, check modification dates on the hosts file, and if modified, move it to their local machine. With the advent of workstations and micros, changes to the host file would have to be made nightly. It would also be very labor intensive and consume a lot of network bandwidth. RFC-1034 and a number of others describe Domain Name Service (DNS), a distributed data base system for mapping names into addresses.

We must look a little more closely into what's in a name. First, note that an address specifies a particular connection on a specific network. If the machine moves, the address changes. Second, a machine can have one or more names and one or more network addresses (connections) to different networks. Names point to a something which does useful work (i.e., the machine) and IP addresses point to an interface on that provider. A name is a purely symbolic representation of a list of addresses on the network. If a machine moves to a different network, the addresses will change but the name could remain the same.

Domain names are tree structured names with the root of the tree at

the right. For example:

                         uxc.cso.uiuc.edu

is a machine called "uxc" (purely arbitrary), within the subdomains of the U of I, and "uiuc" (the University of Illinois at Urbana), registered with "edu" (the set of educational institutions).

A simplified model of how a name is resolved is that on the user's machine there is a resolver. The resolver knows how to contact across the network a root name server. Root servers are the base of the tree structured data retrieval system. They know who is responsible for handling first level domains (e.g., 'edu'). What root servers to use is an installation parameter. From the root server the resolver finds out who provides 'edu' service. It contacts the 'edu' name server which supplies it with a list of addresses of servers for the subdomains (like 'uiuc'). This action is repeated with the sub-domain servers until the final subdomain returns a list of addresses of interfaces on the host in question. The user's machine then has its choice of which of these addresses to use for communication.

A group may apply for its own domain name (like 'uiuc' above). This is done in a manner similar to the IP address allocation. The only requirements are that the requestor have two machines reachable from the Internet, which will act as name servers for that domain. Those servers could also act as servers for subdomains or other servers could be designated as such. Note that the servers need not be located in any particular place, as long as they are reachable for name resolution. (U of I could ask Michigan State to act on its behalf and that would be fine.) The biggest problem is that someone must do maintenance on the database. If the machine is not convenient, that might not be done in a timely fashion. The other thing to note is that once the domain is allocated to an administrative entity, that entity can freely allocate subdomains using what ever manner it sees fit.

The Berkeley Internet Name Domain (BIND) Server implements the Internet name server for UNIX systems. The name server is a distributed data base system that allows clients to name resources and to share that information with other network hosts. BIND is integrated with 4.3BSD and is used to lookup and store host names, addresses, mail agents, host information, and more. It replaces the /etc/hosts file or host name lookup. BIND is still an evolving program. To keep up with reports on operational problems, future design decisions, etc., join the BIND mailing list by sending a request to [email protected]. BIND can also be obtained via anonymous FTP from ucbarpa.berkeley.edu.

There are several advantages in using BIND. One of the most important is that it frees a host from relying on /etc/hosts being up to date and complete. Within the .uiuc.edu domain, only a few hosts are included in the host table distributed by SRI. The remainder are listed locally within the BIND tables on uxc.cso.uiuc.edu (the server machine for most of the .uiuc.edu domain). All are equally reachable from any other Internet host running BIND, or any DNS resolver.

BIND can also provide mail forwarding information for interior hosts not directly reachable from the Internet. These hosts an either be on non-advertised networks, or not connected to an IP network at all, as in the case of UUCP-reachable hosts (see RFC-974). More information on BIND is available in the "Name Server Operations Guide for BIND" in UNIX System Manager's Manual, 4.3BSD release.

There are a few special domains on the network, like NIC.DDN.MIL. The hosts database at the NIC. There are others of the form NNSC.NSF.NET. These special domains are used sparingly, and require ample justification. They refer to servers under the administrative control of the network rather than any single organization. This allows for the actual server to be moved around the net while the user interface to that machine remains constant. That is, should BBN relinquish control of the NNSC, the new provider would be pointed to by that name.

In actuality, the domain system is a much more general and complex system than has been described. Resolvers and some servers cache information to allow steps in the resolution to be skipped. Information provided by the servers can be arbitrary, not merely IP addresses. This allows the system to be used both by non-IP networks and for mail, where it may be necessary to give information on intermediate mail bridges.

What's wrong with Berkeley Unix

University of California at Berkeley has been funded by DARPA to modify the Unix system in a number of ways. Included in these modifications is support for the Internet protocols. In earlier versions (e.g., BSD 4.2) there was good support for the basic Internet protocols (TCP, IP, SMTP, ARP) which allowed it to perform nicely on IP Ethernets and smaller Internets. There were deficiencies, however, when it was connected to complicated networks. Most of these problems have been resolved under the newest release (BSD 4.3). Since it is the springboard from which many vendors have launched Unix implementations (either by porting the existing code or by using it as a model), many implementations (e.g., Ultrix) are still based on BSD 4.2. Therefore, many implementations still exist with the BSD 4.2 problems. As time goes on, when BSD 4.3 trickles

through vendors as new release, many of the problems will be resolved. Following is a list of some problem scenarios and their handling under each of these releases.

ICMP redirects

  Under the Internet model, all a system needs to know to get
  anywhere in the Internet is its own address, the address of where
  it wants to go, and how to reach a gateway which knows about the
  Internet.  It doesn't have to be the best gateway.  If the system
  is on a network with multiple gateways, and a host sends a packet
  for delivery to a gateway which feels another directly connected
  gateway is more appropriate, the gateway sends the sender a
  message.  This message is an ICMP redirect, which politely says,
  "I'll deliver this message for you, but you really ought to use
  that gateway over there to reach this host".  BSD 4.2 ignores
  these messages.  This creates more stress on the gateways and the
  local network, since for every packet sent, the gateway sends a
  packet to the originator.  BSD 4.3 uses the redirect to update its
  routing tables, will use the route until it times out, then revert
  to the use of the route it thinks is should use.  The whole
  process then repeats, but it is far better than one per packet.

Trailers

  An application (like FTP) sends a string of octets to TCP which
  breaks it into chunks, and adds a TCP header.  TCP then sends
  blocks of data to IP which adds its own headers and ships the
  packets over the network.  All this prepending of the data with
  headers causes memory moves in both the sending and the receiving
  machines.  Someone got the bright idea that if packets were long
  and they stuck the headers on the end (they became trailers), the
  receiving machine could put the packet on the beginning of a page
  boundary and if the trailer was OK merely delete it and transfer
  control of the page with no memory moves involved.  The problem is
  that trailers were never standardized and most gateways don't know
  to look for the routing information at the end of the block.  When
  trailers are used, the machine typically works fine on the local
  network (no gateways involved) and for short blocks through
  gateways (on which trailers aren't used).  So TELNET and FTP's of
  very short files work just fine and FTP's of long files seem to
  hang.  On BSD 4.2 trailers are a boot option and one should make
  sure they are off when using the Internet.  BSD 4.3 negotiates
  trailers, so it uses them on its local net and doesn't use them
  when going across the network.

Retransmissions

  TCP fires off blocks to its partner at the far end of the
  connection.  If it doesn't receive an acknowledgement in a
  reasonable amount of time it retransmits the blocks.  The
  determination of what is reasonable is done by TCP's
  retransmission algorithm.

  There is no correct algorithm but some are better than others,
  where worse is measured by the number of retransmissions done
  unnecessarily.  BSD 4.2 had a retransmission algorithm which
  retransmitted quickly and often.  This is exactly what you would
  want if you had a bunch of machines on an Ethernet (a low delay
  network of large bandwidth).  If you have a network of relatively
  longer delay and scarce bandwidth (e.g., 56kb lines), it tends to
  retransmit too aggressively.  Therefore, it makes the networks and
  gateways pass more traffic than is really necessary for a given
  conversation.  Retransmission algorithms do adapt to the delay of
  the network after a few packets, but 4.2's adapts slowly in delay
  situations.  BSD 4.3 does a lot better and tries to do the best
  for both worlds.  It fires off a few retransmissions really
  quickly assuming it is on a low delay network, and then backs off
  very quickly.  It also allows the delay to be about 4 minutes
  before it gives up and declares the connection broken.

  Even better than the original 4.3 code is a version of TCP with a
  retransmission algorithm developed by Van Jacobson of LBL.  He did
  a lot of research into how the algorithm works on real networks
  and modified it to get both better throughput and be friendlier to
  the network.  This code has been integrated into the later
  releases of BSD 4.3 and can be fetched anonymously from
  ucbarpa.berkeley.edu in directory 4.3.

Time to Live

  The IP packet header contains a field called the time to live
  (TTL) field.  It is decremented each time the packet traverses a
  gateway.  TTL was designed to prevent packets caught in routing
  loops from being passed forever with no hope of delivery.  Since
  the definition bears some likeness to the RIP hop count, some
  misguided systems have set the TTL field to 15 because the
  unreachable flag in RIP is 16.  Obviously, no networks could have
  more than 15 hops.  The RIP space where hops are limited ends when
  RIP is not used as a routing protocol any more (e.g., when NSFnet
  starts transporting the packet).  Therefore, it is quite easy for
  a packet to require more than 15 hops.  These machines will
  exhibit the behavior of being able to reach some places but not
  others even though the routing information appears correct.

  Solving the problem typically requires kernel patches so it may be
  difficult if source is not available.

Appendix A - References to Remedial Information

---

 [1]  Quarterman and Hoskins, "Notable Computer Networks",
   Communications of the ACM, Vol. 29, No. 10, pp. 932-971, October
   1986.

 [2]  Tannenbaum, A., "Computer Networks", Prentice Hall, 1981.

 [3]  Hedrick, C., "Introduction to the Internet Protocols", Via
   Anonymous FTP from topaz.rutgers.edu, directory pub/tcp-ip-docs,
   file tcp-ip-intro.doc.

 [4]  Comer, D., "Internetworking with TCP/IP: Principles, Protocols,
   and Architecture", Copyright 1988,  by Prentice-Hall, Inc.,
   Englewood Cliffs, NJ,  07632 ISBN 0-13-470154-2.

Appendix B - List of Major RFCs

---

This list of key "Basic Beige" RFCs was compiled by J.K. Reynolds. This is the 30 August 1989 edition of the list.

RFC-768 User Datagram Protocol (UDP) RFC-791 Internet Protocol (IP) RFC-792 Internet Control Message Protocol (ICMP) RFC-793 Transmission Control Protocol (TCP) RFC-821 Simple Mail Transfer Protocol (SMTP) RFC-822 Standard for the Format of ARPA Internet Text Messages RFC-826 Ethernet Address Resolution Protocol RFC-854 Telnet Protocol RFC-862 Echo Protocol RFC-894 A Standard for the Transmission of IP

          Datagrams over Ethernet Networks

RFC-904 Exterior Gateway Protocol RFC-919 Broadcasting Internet Datagrams RFC-922 Broadcasting Internet Datagrams in the Presence of Subnets RFC-950 Internet Standard Subnetting Procedure RFC-951 Bootstrap Protocol (BOOTP) RFC-959 File Transfer Protocol (FTP) RFC-966 Host Groups: A Multicast Extension to the Internet Protocol RFC-974 Mail Routing and the Domain System RFC-1000 The Request for Comments Reference Guide RFC-1009 Requirements for Internet Gateways RFC-1010 Assigned Numbers

RFC-1011 Official Internet Protocols RFC-1012 Bibliography of Request for Comments 1 through 999 RFC-1034 Domain Names - Concepts and Facilities RFC-1035 Domain Names - Implementation RFC-1042 A Standard for the Transmission of IP

          Datagrams over IEEE 802 Networks

RFC-1048 BOOTP Vendor Information Extensions RFC-1058 Routing Information Protocol RFC-1059 Network Time Protocol (NTP) RFC-1065 Structure and Identification of

          Management Information for TCP/IP-based internets

RFC-1066 Management Information Base for Network

          Management of TCP/IP-based internets

RFC-1084 BOOTP Vendor Information Extensions RFC-1087 Ethics and the Internet RFC-1095 The Common Management Information

          Services and Protocol over TCP/IP (CMOT)

RFC-1098 A Simple Network Management Protocol (SNMP) RFC-1100 IAB Official Protocol Standards RFC-1101 DNS Encoding of Network Names and Other Types RFC-1112 Host Extensions for IP Multicasting RFC-1117 Internet Numbers

Note: This list is a portion of a list of RFC's by topic that may be retrieved from the NIC under NETINFO:RFC-SETS.TXT (anonymous FTP, of course).

The following list is not necessary for connection to the Internet, but is useful in understanding the domain system, mail system, and gateways:

RFC-974 Mail Routing and the Domain System RFC-1009 Requirements for Internet Gateways RFC-1034 Domain Names - Concepts and Facilities RFC-1035 Domain Names - Implementation and Specification RFC-1101 DNS Encoding of Network Names and Other Types

Appendix C - Contact Points for Network Information

---

Network Information Center (NIC)

  DDN Network Information Center
  SRI International, Room EJ291
  333 Ravenswood Avenue
  Menlo Park, CA 94025
  (800) 235-3155 or (415) 859-3695

  [email protected]

NSF Network Service Center (NNSC)

  NNSC
  BBN Systems and Technology Corporation
  10 Moulton St.
  Cambridge, MA 02238
  (617) 873-3400

  [email protected]

NSF Network Information Service (NIS)

  NIS
  Merit Inc.
  University of Michigan
  1075 Beal Avenue
  Ann Arbor, MI 48109
  (313) 763-4897

  [email protected]

CIC

  CSNET Coordination and Information Center
  Bolt Beranek and Newman Inc.
  10 Moulton Street
  Cambridge, MA 02238
  (617) 873-2777

  [email protected]

Glossary

---

autonomous system

  A set of gateways under a single administrative control and using
  compatible and consistent routing procedures.  Generally speaking,
  the gateways run by a particular organization.  Since a gateway is
  connected to two (or more) networks it is not usually correct to
  say that a gateway is in a network.  For example, the gateways
  that connect regional networks to the NSF Backbone network are run
  by Merit and form an autonomous system.  Another example, the
  gateways that connect campuses to NYSERNET are run by NYSER and
  form an autonomous system.

core gateway

  The innermost gateways of the Internet.  These gateways have a
  total picture of the reachability to all networks known to the
  Internet.  They then redistribute reachability information to
  their neighbor gateways speaking EGP.  It is from them your EGP
  agent (there is one acting for you somewhere if you can reach the
  core of the Internet) finds out it can reach all the nets on the
  Internet.  Which is then passed to you via Hello, gated, RIP.  The
  core gateways mostly connect campuses to the ARPANET, or
  interconnect the ARPANET and the MILNET, and are run by BBN.

count to infinity

  The symptom of a routing problem where routing information is
  passed in a circular manner through multiple gateways.  Each
  gateway increments the metric appropriately and passes it on.  As
  the metric is passed around the loop, it increments to ever
  increasing values until it reaches the maximum for the routing
  protocol being used, which typically denotes a link outage.

hold down

  When a router discovers a path in the network has gone down
  announcing that that path is down for a minimum amount of time
  (usually at least two minutes).  This allows for the propagation
  of the routing information across the network and prevents the
  formation of routing loops.

split horizon

  When a router (or group of routers working in consort) accept
  routing information from multiple external networks, but do not

  pass on information learned from one external network to any
  others.  This is an attempt to prevent bogus routes to a network
  from being propagated because of gossip or counting to infinity.

DDN

  Defense Data Network the collective name for the ARPANET and
  MILNET.  Used frequently because although they are seperate
  networks the operational and informational foci are the same.

Security Considerations

Security and privacy protection is a serious matter and too often nothing is done about it. There are some known security bugs (especially in access control) in BSD Unix and in some implementations of network services. The hitchhikers guide does not discuss these issues (too bad).

Author's Address

Ed Krol University of Illinois 195 DCL 1304 West Springfield Avenue Urbana, IL 61801-4399

Phone: (217) 333-7886

EMail: [email protected]