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MZnet: Mail Service for Personal
Micro-Computer Systems
Einar Stefferud
President,
Network Management Associates
and
Visiting Lecturer,
in Information and Computer Science
University of California at Irvine
Jerry Sweet
Department of Information and Computer Science
University of California at Irvine
Terrance Domae
School of Engineering
University of California at Los Angeles
0
\f
Abstract
Traditional computer mail systems involve a co-resident User Agent
(UA) and Mail Transfer System (MTS) on a time-shared host com-
puter which may be connected to other hosts in a network, with new
mail posted or delivered directly through co-resident mail-slot pro-
grams. To introduce personal micro-computers (PCs) into this envi-
ronment requires modification of the traditional mail system architec-
ture. To this end, the MZnet project uses a split-slot model, placing
UA programs on the PCs while leaving MTA programs on a mail relay
host which can provide authentication and buffering. The split-slot
arrangement might be viewed as a new protocol level which operates
somewhere between the currently defined MTS-MTS and UA-UA lev-
els.
\f
Introduction
Mail systems were born and have grown up on large central time sharing
systems, often imbedded in large networks of inter-operating computers with
a set of distributed processes automatically transferring mail between users.
This is certainly the case with the U.S. Department of Defense (DoD) Ad-
vanced Research Projects Agency Network (ARPANET) [1 ] where much of
the original computer network mail systems research and development has
taken place. Other mail networks such as the Computer Science Network
[2 ] sponsored by the U.S. National Science Foundation, have also used rela-
tively large shared computers lodged in an institutional setting, though they
are often connected together with ordinary dial-up telephone links to form a
large geographic network. Another U.S. example is USENET [3 ] which con-
nects thousands of Unix1 systems together with informally-supported dial
telephone links. Although there have been several attempts, there appear to
be no successful mail networks based on small personal computers, such as
those that use the CP/M2 or MS-DOS3 operating systems.
The accepted architectural model (see Figure 1) for computer network
mail (first articulated by the IFIP 6.5 Systems Environment Working Group)
involves a User Agent (UA) which posts new mail items through a mail slot
[4 , 5, 6, 7] to a Mail Transfer Agent (MTA) which delivers posted items to
designated UA recipients through corresponding delivery slots. When mail
is to be delivered to a UA on another host, it is transferred first to another
MTA on the recipient user's host, which in turn puts the mail item through
its local delivery slot. In this model, a Mail Transfer System (MTS) may
be viewed as a collection of MTAs with network connections among them to
provide Mail Transfer Services for a large number of users on different host
computers.
Replicating this UA/MTA/MTS model on a personal micro-computer
(PC) is not an easy task. Aspects of PCs that make support of this model
difficult include limited storage capacities, limited processing capabilities,
and the fact that PCs are geared to support a single user rather than several
users at once. A PC with limited secondary diskette storage and limited
________________________________________________
1 UNIX is a Trademark of Bell Laboratories, Inc.
2 CP/M is a Trademark of Digital Research, Inc.
3 MS-DOS is a Trademark of Microsoft Corporation.
1
\f
processing capacity (often single-thread) is not well suited to support the full
range of automatic interactions between a UA and an MTA, or the necessary
interactions between MTAs in an MTS. For example, we do not see any way
to certify PC systems for authentication of posted mail. A PC can change
its entire character and behavior with insertion of a new program diskette,
suggesting that it is the operating system diskettes and their users that must
be certified, rather than the computers. Review of certification issues shows
that it is not the computer, but its operators and managers that must be
certified, and this involves the notions of central management and control.
All this is lost in the maze of PCs that we see proliferating on and off our
campuses, in and out of our offices and homes.
Thus, we see a need for a new arrangement with the UA separated from
its MTA, and using communication protocols to interact with it in ways
that resemble MTA-to-MTA interactions. The UA is placed on the PC end,
while the more complex tasks performed by the MTA are relegated to the
remote host end. The remote MTA must authenticate mail items offered by
the PC-based UA, just as it would for a co-located UA, but the task is more
difficult because the PC UA is potentially anyone among the public telephone
connectable population. This can be handled with password systems, but
recognition and identification are not the only services to be provided at the
posting slot. Posting also requires some validation of recipient addresses,
and validation of the syntax and semantics of certain header fields. Example
standards are provided by the U.S. National Bureau of Standards (NBS) and
the U.S. DoD ARPANET for the format of mail to be transferred [8 , 9 , 10 ].
The new arrangement described in this paper might be called a split mail
slot in that the UA side of the slot is split away from the MTA side. Although
the UA and MTA may be on opposite ends of a telephone connection, they
must still act together as a single processing unit to move mail from one
to the other, with all that this may entail. This gives rise to a number of
new MTA/UA requirements such as error control for service requests, user
intervention to select items for delivery, and user postponement or rejection
of delivery without triggering failure notices to senders. These are not serious
problems when both MTA and UA are programs running on a single host.
For example, with both UA and MTA on the same host, unwanted junk mail
is simply deleted at low cost, compared to the cost of deletion after a long
delivery transmission time. Better that our PC users be able to discard items
without delivery transmission.
2
\f
Overview of the MZnet Environment
The MZnet project is an undergraduate student effort sponsored within the
Information and Computer Science (ICS) Department of the University of
California at Irvine (UCI) in Southern California. For the past 2 years, the
UCI mail network, known as ZOTnet, has been connected into the Computer
Science Network (CSnet) and in 1984, has joined the DoD ARPA Internet
with a Split-Gateway connection [11 ] to the University of Southern California
Information Sciences Institute (USC-ISI). The MZnet split-slot arrangement
may have some similarities to the Split-Slot Internet Gateway at least in
name, but the problems and the implementations are quite different.
The UCI ZOTnet environment [13 ] gives the MZnet project a full-fledged
Internet-class mail system as its foundation. The MZnet project objective is
to extend this class of mail service to personal computers located in student
and faculty residences, offices and laboratories, without waiting for full-blown
local area networking to first provide connections. This follows a pattern of
making the most of existing facilities to provide a reasonable level of service.
The UCI ZOTnet uses the CSnet-provided MMDF (Multi-channel Memo
Distribution Facility) software [12 ] from the University of Delaware to inter-
connect two VAX 750 Unix systems with two DEC TOPS-20 systems through
a port selector, with dial telephone connection to a CSnet relay [14 ]. The
ZOTnet has since evolved into an ethernet-connected local area network with
the aforementioned gateway connection into the DoD Internet. The ZOTnet
also connects to USENET with the UUCP protocols, and provides format
transformations for mail flowing between protocol domains [15 , 16 ]. Adding
to the reach of the ZOTnet with MZnet is a natural part of its evolution4 .
To this point we have set the context of the MZnet project. The remainder
of this paper is devoted to relatively technical discussions of implementation
of the PC user agent programs and the split-slot UA/MTA interface.
________________________________________________
4 For those who are properly curious about such things, the name "ZOTnet" derives
from the cry of the UCI mascot which is the Anteater from the B.C. comic strip, and
MZnet is simply a contraction for Micro-ZOTnet.
3
\f
The MZnet User Agent: CP/MH
CP/MH is a collection of programs designed to work in conjunction with
the Micro ZOTnet (MZnet) as an extension of the UCI ZOTnet. CP/MH
programs permit a user of a CP/M 2.2-based microcomputer to send and re-
ceive ZOTnet mail messages, as well as to manipulate them locally on floppy
disks. The CP/MH programs are written in the C programming language
and should be portable to similar operating environments, such as MS-DOS,
etc.
CP/MH is based on the UCI version of the Rand MH message handling
system [17 ] for the Unix operating system. The major philosophical dif-
ferences between CP/MH and typical user agents such as MSG [4 ] and its
descendants are those of modularity and of user interface. In CP/MH (as
in MH) the user does not invoke a single monolithic program to deal with
mail, but rather invokes individual, non-interactive programs with common
knowledge of the way messages are stored. Each program has default behav-
ior which can be modified by using Unix-style command line options at time
of invocation or through a user profile. Help messages can also be evoked
from CP/MH programs.
Messages and Folders
The format of a CP/MH message adheres more or less to the syntax described
in RFC 822 in which a message consists of headers containing information
pertaining to the message source and destination, and the message body,
separated from the headers by a blank line. An example of such a message
might be:
Date: 02 Nov 83 23:04:53 PST (Wed)
To: Toto <dog@Univ-Kansas>
From: The Great And Powerful Oz <Oz@Emerald-City>
Subject: What Be Your Excuse?
What's the matter? I ask you for a simple thing like
"distribute this to Witch@Oz-West," and you can't do it.
You undergrads will do anything to get out of work!
4
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--ozzie
Following the MH convention, each message is kept in a separate file.
Since a message is simply ASCII text, it can be operated upon by non-
CP/MH programs (such as text editors, in particular).
Collections of messages are called folders. Under CP/MH, folders are
represented by several files: an info file, containing maintenance information
about the folder, and a set of message files with the same name as the info
file, but with unique numeric suffixes (extensions in CP/M parlance). An
example of this naming scheme might be:
DRAFT the info file for the DRAFT folder
DRAFT.001 message 1 in the folder
DRAFT.002 message 2 in the folder
DRAFT.003 message 3 in the folder
The number of messages that may be stored in a folder is limited primarily
by the storage capacity of a floppy disk, but also by the three-digit limit of
a CP/M extension.
The info file contains a field named CURRENT: specifying the current mes-
sage number. The current message number signifies the default message
operated upon by CP/MH commands using a particular folder. The current
message number may be modified by some commands. An example of the
contents of the info file DRAFT might be
CURRENT: 3
This indicates that the file DRAFT.003 would be operated upon when
default conditions apply (i.e. when no message number is explicitly given to
a CP/MH command).
Possible future uses for the info file include named message sequences (a
set of messages to which commands may be applied as a whole) and user
profile information for application to particular folders (there is presently a
single user profile, described shortly).
A floppy diskette may contain more than one folder, but folders do not
extend over more than one floppy diskette; therefore two different diskettes
may contain folders with the same name.
5
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CP/MH Commands
Commands operating on messages can be divided into several general cate-
gories:
Transporting: sending, receiving
Viewing: selecting for display, showing header summaries
Creating: composing, replying, forwarding
Archiving: categorizing, refiling, deleting, sorting
The architecture of CP/MH permits the simulation of some of these cat-
egories using standard CP/M commands when CP/MH, in its present prim-
itive state, does not cover them.
A minimal functionality is presently provided by the following four com-
mands:
COMP composes mail items: creates a file containing header information
taken from a standard or user-specified template. This newly-created
file may be edited to fill in the header fields and body.
REPL replies to mail items: creates a file containing header information
appropriate for answering a given mail item. This newly-created file
may be edited to change header fields and fill in the body.
SEND sends mail items: posts selected items through the split-slot from a
draft folder.
INC receives mail items: takes delivery of selected items across the split-
slot, incorporating them into a mailbox folder.
These commands, with a few enhancements and modifications appropriate
to the CP/M environment, are functionally almost identical to their Unix
MH counterparts.
CP/MH commands are invoked like any other CP/M commands such as
ED, PIP, or DIR. Command line options are generally preceded by a dash
(e.g. -editor A:ED), and may be abbreviated. Folder names are preceded
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by a plus (e.g. +B:DRAFT). Messages are identified by numbers or by the
special names first, last, current, next, and previous.
An example of use of a CP/MH command is:
comp -edit a:ed -use last +b:draft -log
This particular example will edit the last-composed message (the -use
last option) in the folder DRAFT on disk drive B: (the +b:draft option),
using the standard CP/M editor ED on disk drive A: (the -edit a:ed op-
tion), and prompting the user when it is appropriate to change disks (the
-log option).
All CP/MH commands have a -help option which displays all available
options for the particular command invoked. Another common option is
-log which permits the user to change (relog) diskettes after invoking a
command, for purposes of selecting diskettes with message folders or with
editor programs. This is particularly useful on single-drive systems or on
systems with diskettes of low storage capacity.
The Profile
If there are options commonly used with a particular CP/MH command,
they may be entered in the user profile contained in the file called (naturally
enough) PROFILE, which must exist on the same diskette on which CP/MH
commands reside and from which the commands are invoked. A profile entry
consists of a program name followed by a colon and the options to be used
with that program, for example:
comp: -editor A:VEDIT +B:outbox -log
repl: -editor A:VEDIT -log
send: +B:outbox
inc: +B:inbox -log
Individual profile components are overridden by options given at the time
of invocation (e.g. -noedit given on the command line will override the
-editor profile component for a particular command).
7
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The MZnet Split-Slot Mail Transfer System
The MZnet split-slot software implements a peer-to-peer communication pro-
tocol between a time-sharing host's MTA and a personal micro-computer
(PC) UA. This MZnet protocol extends the UA/MTA/UA model of computer-
based message systems (CBMS) to provide a split gateway function between
individual PCs and the ZOTnet similar to the UCI ICS split Internet gateway
described previously (see Figure 2).
The Structure of the Split-Slot
The MZnet Split Gateway consists of three distributed processing compo-
nents:
- A PC running a UA (in MZnet, CP/MH) acting as the mail server.
- A mini/mainframe host running a full MTA (MMDF in MZnet) pro-
viding mail relay services.
- A communication protocol (a modified version of MMDF PhoneNet)
to connect the two ends of the split-slot.
Although this combination may not be unique, the method by which the
MZnet split-slot bonds these parts together uniquely deals with the prob-
lems of remote user agents. In addition to overcoming limited storage and
processing capacities, remote user agents must deal with noisy modem lines,
mail software certification, and mail system security problems. The MZnet
architecture appears to solve these problems with a clean mail interface for
PCs.
The MZnet Mail Server
The split-slot mail server consists of a set of command packet programs run
from the PC. These programs simply present commands through the Phone-
Net communication protocol to the mail relay slave program on the host.
Some basic commands are:
PostMail posts mail drafts to MTA
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GetMail accepts mail from MTA
RemoteScan displays information about waiting mail
Quit drops connection between PC and Host
Each command has the form:
Command Request
Data Transmission
Command Termination
For example, the PostMail command is a small program that:
- initiates a command with the Mail Slave by sending the command name
(PostMail) encoded within a PhoneNet packet;
- sends a series of PhoneNet packets that contain pieces of the mail item
to be posted;
- finally sends a command termination signal to end the transaction with-
out terminating the connection between host and PC.
The MZnet Channel To MMDF
The MZnet Channel runs on the MTA host under the University of Delaware's
MMDF (Version 1) and is responsible for both delivery of received mail to
MZnet users, and posting of MZnet user-originated mail. The MMDF MZnet
channel maintains a unique message queue for each registered MZnet user.
As new mail items arrive, they are posted to the appropriate queues, where
MZnet holds the mail items for pickup by their registered recipients.
To send or receive mail, the MZnet user must attach to the host, log into
the public MZnet account, and identify (authenticate) himself. During the
MZnet session with the host, the user has access only to that restricted set
of functions provided by the MZnet split gateway protocol: he may request
delivery of queued mail with GetMail, or post new mail with PostMail. Prior
to taking delivery of queued mail, a survey of waiting mail also may be
9
\f
requested with RemoteScan to obtain message size information (among other
data) to allow intelligent disposition of mail in the queue.
Hidden within these activities are issues of security and certification. To
certify and establish the identity of the user, a second password is requested
after logging into the public MZnet account. This certification procedure
allows MZnet to certify the source of originated mail. A relatively secure
environment is provided by MZnet, as it is the only interface to the host
permitted to MZnet users (once beyond the public login procedure), and it
offers only the severely restricted set of PhoneNet-encoded commands. Aside
from security issues, using a single account to handle all MZnet users reduces
demands on system resources.
The MZnet-PhoneNet Protocol
A unique facet of the MZnet system derives from the PhoneNet File Transfer
Protocol (FTP). PhoneNet FTP is a simple error-checked packet protocol
which transfers ASCII plaintext. PhoneNet encodes any non-plaintext char-
acter (or any other character "forbidden" by the idiosyncrasies of the com-
municating systems) by mapping it onto an "accepted" character set. The
accepted character set mapping is determined by a "negotiating" session be-
tween the two systems at the start of the PhoneNet session.
MZnet transfers all information (both commands and data) in PhoneNet
packets to obtain error control. The MZnet-PhoneNet command FTP toler-
ates noise with a high degree of success, and in effect, connects both ends of
the Split Slot together with a reliable set of virtual wires.
MZnet Session Example
Here, a typical MZnet session is presented, with the UA commands issued
from the PC side of the connection printed in a typewriter typeface, and
the responses from the host side printed in an italic typeface. PhoneNet
interactions are indented. The initial connection to the host is accomplished
with the term program, which provides a simple terminal emulation function.
The prompt of the PC for a UA command is "Ai". Note that passwords are
never echoed by the host system.
Ai term
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login: mznet
password:
MZ-Password:
PhoneNet packet negotiation
Connected.
exit terminal mode
Ai send cur
PostMail command
message text packet transmission
command terminator
Ai quit
Quit command
Disconnecting.
Conclusions
The main conclusions of this paper are that small personal computer systems
with dial-up phone connections constrain User Agent systems design in ways
that require use of a split-slot interface between the UA and its supporting
Mail Transfer Agent (MTA), and that this interface will best provide the re-
quired services if it has error controlled command and data transfer facilities,
with interactive behavior.
It is also believed that a good design for the small PC UA is based on
a very modular architecture, such as the Rand MH system, which has been
used as a pattern for the MZnet UA.
By bringing these concepts together, we expect MZnet to provide reliable
UA/MTA service to a distributed set of small personal computers, to match
the quality of service that is normally only available from larger mainframe
host systems with co-resident UA/MTA pairs.
References
[1] SRI-NIC, ARPANET Directory, Network Information Center, SRI In-
ternational, Menlo Park, California (November 1980).
11
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[2] Comer, D., A Computer Science Research Network CSNET: A History
and Status Report, Communications of the ACM, volume 26, number 10
(October 1983) 747-753.
[3] Emerson, S. L., USENET: A Bulletin Board for Unix Users. BYTE,
volume 8, number 10 (October 1983) 219-236.
[4] Vittal, J., MSG: A Simple Message System, in: Uhlig (editor), Proceed-
ings of the IFIP TC-6 International Symposium on Computer Message
Systems (North-Holland, April 1981).
[5] Deutsch, D., Design of a Message Format Standard, in: Uhlig (editor),
Proceedings of the IFIP TC-6 International Symposium on Computer
Message Systems (North-Holland, April 1981).
[6] v.Bochmann, G. and Pickens, J. R., A Methodology for the Specifica-
tion of a Message Transport System, in: Uhlig (editor), Proceedings of
the IFIP TC-6 International Symposium on Computer Message Systems
(North-Holland, April 1981).
[7] Kerr, I. H., Interconnection of Electronic Mail Systems, in: Uhlig (edi-
tor), Proceedings of the IFIP TC-6 International Symposium on Com-
puter Message Systems (North-Holland, April 1981).
[8] Crocker, D., Standard for the Format of ARPA Internet Text Messages
(RFC 822) Network Information Center, SRI International, Menlo Park,
California (August 1982).
[9] NBS, Message Format for Computer-Based Message Systems, U.S. Na-
tional Bureau of Standards FIPS Publication 98 (March 1983).
[10] CCITT Study Group VII/5, Draft Recommendation X.MHS1: Mes-
sage Handling Systems: System Model_Service Elements (version 2),
Technical Report, International Telegraph and Telephone Consultative
Committee (CCITT) (December 1982).
[11] Rose, M., Low Tech Connections into the ARPA Internet: The Raw-
Packet Split-Gateway, University of California Irvine Techical Report
number 216 (February 1984).
12
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[12] Crocker, D., Szurkowski, E., Farber, D. J., An Internet Memo Distribu-
tion Facility_MMDF, Proceedings of the Sixth IEEE Data Communi-
cations Symposium (November 1979).
[13] Rose, M., The ZOTnet_A Local Area Mailing Network, University of
California Irvine Technical Report number 200 (January 1983).
[14] CSNET-CIC, Focus on the University of California, Irvine, CSNET
News 2, Bolt, Beranek, and Newman, Cambridge, Massachusetts (Octo-
ber 1983).
[15] Rose, M., Achieving Interoperability Between Two Domains_
Connecting the ZOTnet and UUCP Computer Mail Networks, University
of California Irvine Technical Report number 201 (January 1983).
[16] Rose, M., Proposed Standard for Message Munging (RFC 886), Network
Information Center, SRI International, Menlo Park, California (Decem-
ber 1983).
[17] Borden, B. S., Gaines, R. S., and Shapiro, N.Z., The Rand MH Message
Handling System: User's Manual (Rand Corporation, March 1983).
13
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________________________________________________________________________________________________________________________
Any Host Relay Host Any Other Host
user user
UA UA
slot slot
MTA MTA MTA MTA
PhoneNet PhoneNet PhoneNet PhoneNet
modem modem modem modem
_______________________________________Figure_1:__The_MHS_Model_________________________________________________________
14
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________________________________________________________________________________________________________________________
Any Host MZnet Host PC
user user
UA UA
slot split slot
MZnet MZnet
MTA MTA
PhoneNet PhoneNet PhoneNet PhoneNet
modem modem modem modem
____________________________________Figure_2:__The_Split-Slot_Model_____________________________________________________
15