RFC1498 - On the Naming and Binding of Network Destinations
Network Working Group J. Saltzer
Request for Comments: 1498 M.I.T. Laboratory for Computer Science
August 1993
On the Naming and Binding of Network Destinations
Status of this Memo
This memo provides information for the Internet community. It does
not specify an Internet standard. Distribution of this memo is
unlimited.
Abstract
This brief paper offers a perspective on the subject of names of
destinations in data communication networks. It suggests two ideas:
First, it is helpful to distinguish among four different kinds of
objects that may be named as the destination of a packet in a
network. Second, the operating system concept of binding is a useful
way to describe the relations among the four kinds of objects. To
illustrate the usefulness of this approach, the paper interprets some
more suBTle and confusing properties of two real-world network
systems for naming destinations.
Note
This document was originally published in: "Local Computer Networks",
edited by P. Ravasio et al., North-Holland Publishing Company,
Amsterdam, 1982, pp. 311-317. Copyright IFIP, 1982. Permission is
granted by IFIP for reprodUCtion for non-commercial purposes.
Permission to copy without fee this document is granted provided that
the copies are not made or distributed for commercial advantage, the
IFIP copyright notice and the title of the publication and its date
appear, and notice is given that copying is by permission of IFIP. To
copy otherwise, or to republish, requires a specific permission.
This research was supported in part by the Defense Advanced Research
Projects Agency of the United States Government and monitored by the
Office of Naval Research under contract number N00014-75-C-0661.
What is the Problem?
Despite a very helpful effort of John Shoch [1] to impose some
organization on the discussion of names, addresses, and routes to
destinations in computer networks, these discussions continue to be
more confusing than one would eXPect. This confusion stems sometimes
from making too tight an association between various types of network
objects and the most common form for their names. It also stems from
trying to discuss the issues with too few well-defined concepts at
hand. This paper tries a different approach to develop insight, by
applying a perspective that has proven helpful in the corresponding
area of computer operating systems.
Operating systems have a similar potential for confusion concerning
names and addresses, since there are file names, unique identifiers,
virtual and real memory addresses, page numbers, block numbers, I/O
channel addresses, disk track addresses, a seemingly endless list.
But most of that potential has long been rendered harmless by
recognizing that the concept of binding provides a systematic way to
think about naming [2]. (Shoch pointed out this opportunity to
exploit the operating system concept; in this paper we make it the
central theme.) In operating systems, it was apparent very early that
there were too many different kinds of identifiers and therefore one
does not get much insight by trying to make a distinction just
between names and addresses. It is more profitable instead to look
upon all identifiers as examples of a single phenomenon, and ask
instead "where is the context in which a binding for this name (or
address, or indentifier, or whatever) will be found?", and "to what
object, identified by what kind of name, is it therein bound?" This
same approach is equally workable in data communications networks.
To start with, let us review Shoch's suggested terminology in its
broadest form:
- a name identifies what you want,
- an address identifies where it is, and
- an route identifies a way to get there.
There will be no need to tamper with these definitions, but it will
be seen that they will leave a lot of room for interpretation.
Shoch's suggestion implies that there are three abstract concepts
that together provide an intellectual cover for discussion. In this
paper, we propose that a more mechanical view may lead to an easier-
to-think-with set of concepts. This more mechanical view starts by
listing the kinds of things one finds in a communication network.
Types of Network Destinations, and Bindings Among Them
In a data communication network, when thinking about how to describe
the destination of a packet, there are several types of things for
which there are more than one instance, so one attaches names to them
to distinguish one instance from another. Of these several types,
four turn up quite often:
1. Service and Users. These are the functions that one uses, and
the clients that use them. Examples of services are one that
tells the time of day, one that performs accounting, or one
that forwards packets. An example of a client is a particular
desktop computer.
2. Nodes. These are computers that can run services or user
programs. Some nodes are clients of the network, while others
help implement the network by running forwarding services.
(We will not need to distinguish between these two kinds of
nodes.)
3. Network attachment points. These are the ports of a network, the
places where a node is attached. In many discussions about data
communication networks, the term "address" is an identifier of a
network attachment point.
4. Paths. These run between network attachment points, traversing
forwarding nodes and communication links.
We might note that our first step, the listing and characterization
of the objects of discussion, is borrowed from the world of abstract
data types. Our second step is to make two observations about the
naming of network objects, the first about form and the second about
bindings.
First, one is free to choose any form of name that seems helpful --
binary identifiers, printable character strings, or whatever, and
they may be chosen from either a flat or hierarchical name space.
There may be more than one form of name for a single type of object.
A node might, for example, have both a hierarchical character string
name and a unique binary identifier. There are two semantic traps
that one can fall into related to name form. First, the Word "name"
is, in the network world, usually associated with a printable
character string, while the word "address" is usually associated with
machine-interpretable binary strings. In the world of systems and
languages, the term "print name" is commonly used for the first and
"machine name" or "address" for the second, while "name" broadly
encompasses both forms. (In this paper we are using the broad meaning
of "name".) The second semantic trap is to associate some
conventional form of name for a particular type of object as a
property of that type. For example, services might be named by
character strings, nodes by unique ID's, and network attachment
points named by hierarchical addresses. When one participant in a
discussion assumes a particular name form is invariably associated
with a particular type of object and another doesn't, the resulting
conversation can be very puzzling to all participants.
The second observation about the four types of network objects listed
above is that most of the naming requirements in a network can simply
and concisely be described in terms of bindings and changes of
bindings among the four types of objects. To wit:
1. A given service may run at one or more nodes, and may need to move
from one node to another without losing its identity as a service.
2. A given node may be connected to one or more network attachment
points, and may need to move from one attachment point to another
without losing its identity as a node.
3. A given pair of attachment points may be connected by one or more
paths, and those paths may need to change with time without
affecting the identity of the attachment points.
(This summary of network naming requirements is intentionally brief.
An Excellent in-depth review of these requirements can be found in a
recent paper by Sunshine [3].)
Each of these three requirements includes the idea of preserving
identity, whether of service, node or attachment point. To preserve
an identity, one must arrange that the name used for identification
not change during moves of the kind required. If the associations
among services, nodes, attachment points and routes are maintained as
lists of bindings this goal can easily be met. Whether or not all the
flexibility implied by these possibilities should be provided in a
particular network design is a matter of engineering judgment. A
judgment that a particular binding can be made at network design time
and will never need to be changed (e.g., a particular service might
always run at a particular node) should not be allowed to confuse the
question of what names and bindings are in principle present. In
principle, to send a data packet to a service one must discover three
bindings:
1. find a node on which the required service operates,
2. find a network attachment point to which that node is connected,
3. find a path from this attachment point to that attachment point.
There are, in turn, three conceptually distinct binding services that
the network needs to provide:
1. Service name resolution, to identify the nodes that run the
service.
2. Node name location, to identify attachment points that reach the
nodes found in 1.
3. Route service, to identify the paths that lead from the
requestor's attachment point to the ones found in 2.
At each level of binding, there can be several alternatives, so a
choice of which node, which attachment point, and which path must be
made. These choices are distinct, but can interact. For example, one
might chose the node only after first looking over the various paths
leading to the possible choices. In this case, the network tables may
only produce a partial binding, which means that an enquiry produces
a list of answers rather than a single one. The final binding choice
may be delayed until the last moment and recorded outside the three
binding services provided within the network.
There is a very important subtlety about bindings that often leads
designers astray. Suppose we have recorded in a network table the
fact that the "Lockheed DIALOG Service" is running on node "5". There
are actually three different bindings involved here but only one of
these three is recorded in this table and changeable by simply
adjusting the table.
1. The name "Lockheed DIALOG Service" is properly associate with a
specific service, management, and collection of stored files. One
does not usually reassign such a name to a different service. The
association of the name with the service is quite permanent, and
because of that permanence is not usually expressed in a single,
easily changed table.
2. Similarly, the name "5" is assigned to a particular node on a
fairly long-term basis, without the expectation that it will
change. So that assignment is also not typically expressed in a
single, easily changed table.
3. The fact that "DIALOG" is now operating on node "5"is the one
binding that our table does express, because we anticipate that
this association might reasonably change. The function of our
table is to allow us to express changes such as "DIALOG" is now
operating at node "6" or the "Pipe-fitting Service" is now
operating at node "5".
The design mistake is to believe that this table allows one to give
the Lockheed DIALOG service a new name, merely by changing this table
entry. That is not the function of this table of bindings, and such a
name change is actually quite difficult to accomplish, since the
association in question is not usually expressed as a binding in a
single table. One would have to change not only this table, but also
user programs, documentation, scribbled notes and advertising copy to
accomplish such a name change.
Some Real-World Examples
Although the ideas outlined so far seem fairly straightforward, it is
surprisingly easy to find real-world examples that pose a challenge
in interpretation. In the Xerox/DEC/Intel Ethernet [5, 6], for
example, the concept of a network attachment point is elusive,
because it collapses into the node name. A node can physical attach
to an Ethernet anywhere along it; the node brings with it a 48-bit
unique identifier that its interfaces watches for in packets passing
by. This identifier should probably be thought of as the name of a
network attachment point, even though the physical point of
attachment can be anywhere. At the same time, one can adopt a policy
that the node will supply from its own memory the 48-bit identifier
that is to be used by the Ethernet interface, so a second, equally
reasonable, view (likely to be taken elsewhere in the network in
interpreting the meaning of these identifiers) is that this 48-bit
identifier is the name of the node itself. From a binding
perspective this way of using the Ethernet binds the node name and
the network attachment point name to be the same 48-bit unique
identifier.
This permanent binding of node name to attachment point name has
several network management advantages:
- a node can be moved from one physical location to another
without changing any network records.
- one level of binding tables is omitted. This advantage is
particularly noticeable in implementing internetwork routing.
- a node that is attached to two Ethernets can present the same
attachment point name to both networks, which simplifies
communication among internet routers and alternate path
finding.
But permanent binding also produces a curiosity if is happens that
one wants one node to connect to two attachment points on the same
Ethernet. The curiosity arises because the only way to make the
second attachment point independently addressable by others is to
allow the node to use two different 48-bit identifiers, which means
that some other network records (the ones that interpret the ID to be
a node name) will likely be fooled into believing that there are not
one, but two nodes. To avoid this confusion, the same 48-bit
identifier could be used in both attachment points, but then there
will be no way intentionally to direct a message to one rather than
the other. One way or another, the permanent binding of attachment
point name to node name has made some function harder to accomplish,
though the overall effect of the advantages probably outweighs the
lost function in this case.
For another example, the ARPANET NCP protocol provides character
string names that appear, from their mnemonics, to be node names or
service names, but in fact they are the names of network attachment
points [6]. Thus the character string name RADC-Multics is the name
of the network attachment point at ARPANET IMP 18, port 0, so
reattaching the node (a Honeywell 68/80 computer) to another network
attachment point requires either that the users learn a new name for
the service or else a change of tables in all other nodes. Changing
tables superficially appears to be what rebinding is all about, but
the need to change more than one table is the tip-off that something
deeper is going on. What is actually happening is the change of the
permanent name of the network attachment point. We can see this more
clearly by noting that a parallel attachment of that Honeywell 68/80
to a second ARPANET port would be achievable only by assigning a
second character string identity; this requirement emphasizes that
the name is really of the attachment point, not the node.
Unfortunately, because of their mnemonic value, the ARPANET NCP name
mnemonics are often thought of as service names. Thus one expects
that that the Rome Air Development Center Multics service is operated
on the node reached by the name RADC-Multics. This particular
assumption doesn't produce any surprises. But any one of the four
Digital PDP-10 computers at Bolt, Beranek and Newman can accept mail
for any of the others, as can the groups of PDP-10's at the USC
Information Sciences Institute, and at the Massachusetts Institute of
Technology. If the node to which ones tries to send mail is down, the
customer must realize that the same service is available by aSKINg
for a different node, using what appears to be a different service
name. The need for a customer to realize that he must give a
different name to get the same service comes about because in the
ARPANET the name is not of a service that is bound to a node that is
bound to an attachment point, but rather it is directly the name of
an attachment point.
Finally, confusion can arise because the three conceptually distinct
binding services (service name resolution, node name location, and
route dispensing) may not be mechanically distinct. There is usually
suggested only one identifiable service, a "name server". The name
server starts with a service name and returns a list of network
attachment points that can provide that service. It thereby performs
both the first and second conceptual binding services, though it may
leave to the customer the final choice of which attachment point to
use. Path choice may be accomplished by a distributed routing
algorithm that provides the final binding service without anyone
noticing it.
Correspondence with Names, Addresses, and Routes
With this model of binding among services, nodes, network attachment
points, and paths in mind, one possible interpretation of Shoch's
names, addresses and routes is as follows:
1. Any of the four kinds of objects (service, node, network
attachment point, and path) may have a name, though Shoch would
restrict that term to human-readable character strings.
2. The address of an object is a name (in the broad sense, not
Shoch's restricted sense) of the object it is bound to. Thus, an
address of a service is the name of some node that runs it. An
address of a node is the name of some network attachment point to
which it connects. An address of a network attachment point (a
concept not usually discussed) can be taken to be the name of a
path that leads to it. This interpretation captures Shoch's
meaning "An address indicates where it is," but does not very
well match Shoch's other notion that an address is a
machine-processable, rather than a human-processable form of
identification. This is probably the primary point where our
perspectives differ on which definitions provide the most clarity.
3. A route is a more sophisticated concept. A route to either a
network attachment point or a node is just a path, as we have
been using the term. Because a single node can run several
services at once, a route to a service consists of a path to the
network attachment point of a node that runs the service, plus
some identification of which activity within that node runs the
service (e.g., a "socket identifier" in the PUP internet [4] or
the ARPA Internet [7] protocols). But note that a route may
actually consist of a series of names, typically a list of
forwarding name nodes or attachment points and the names used by
the forwarding nodes for the paths between them.
Whether or not one likes this particular interpretation of Shoch's
terms, it seems clear that there are more than three concepts
involved, so more than three labels are needed to discuss them.
Summary
This paper has argued that some insight into the naming of
destinations in a network can be obtained by recognizing four kinds
of named objects at or leading to every destination (services, nodes,
attachment points, and routes) and then identifying three successive,
changeable, bindings (service to node, node to attachment point, and
attachment point to route). This perspective, modeled on analogous
successive bindings of storage management systems (file--storage
region--physical location) and virtual memories (object--segment--
page--memory block) provides a systematic explanation for some design
problems that are encountered in network naming systems.
Acknowledgements
Discussions with David D. Clark, J. Noel Chiappa, David P. Reed, and
Danny Cohen helped clarify the reasoning used here. John F. Shoch
provided both inspiration and detailed comments, but should not be
held responsible for the result.
References
1. Shoch, John F., "Inter-Network Naming, Addressing, and Routing,"
IEEE Proc. COMPCON Fall 1978, pp. 72-79. Also in Thurber, K.
(ed.), Tutorial: Distributed Processor Communication
Architecture, IEEE Publ. #EHO 152-9, 1979, pp. 280-287.
2. Saltzer, J. H., "Naming and Binding of Objects", in: Operating
Systems, Lecture notes in Computer Science, Vol. 60, Edited by R.
Bayer, New York; Springer-Verlag, 1978.
3. Sunshine, Carl A., "Addressing Problems in Multi-Network
Systems", to appear in Proc. IEEE INFOCOM 82, Las Vegas, Nevada,
March 30 - April 1, 1982.
4. Boggs, D. R., Shoch, J. F., Taft, E. A., and Metcalfe, R. M.,
"PUP: An Internetwork Architecture", IEEE Trans. on Comm. 28, 4
(April, 1980) pp. 612-623.
5. (Anonymous), "The Ethernet, A Local Area Network: Data Link Layer
and Physical Layer Specifications, Version 1.0", published by
Xerox Corp., Palo Alto, Calif., Intel Corp., Sunnyvale, Calif.,
and Digital Equipment Corp., Tewksbury, Mass., September 30,
1980.
6. Dalal, Y. K., and Printis, R. S., "48-bit Absolute Internet and
Ethernet Host Numbers", Proc. Seventh Data Communications
Symposium, Mexico City, Mexico, October 1981, pp. 240-245.
7. Feinler, E., and J. Postel, Editors, "ARPANET Protocol Handbook",
SRI International, Menlo Park, Calif., January, 1978.
Security Considerations
Security issues are not discussed in this memo.
Author's Address
Jerome H. Saltzer
M.I.T. Laboratory for Computer Science
545 Technology Square
Cambridge, MA 02139
U.S.A.
Phone: (617) 253-6016
EMail: Saltzer@MIT.EDU