INTERNET-DRAFT John Klensin, Editor
Expires in six months MCI
November 26, 1996
Simple Mail Transfer Protocol
draft-ietf-drums-smtpupd-03.txt
Status of this Memo
This document is an Internet-Draft. Internet-Drafts are working
documents of the Internet Engineering Task Force (IETF), its areas, and
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If consensus is reached on this document, it will be forwarded to the
IESG with the recommendation that it be processed as a Proposed
Standard for mail transport.
[[Sections marked with doubled brackets (e.g., "<<") are explicit
placeholders or known major loose ends. The marking ## is a note in
the draft to recheck a section number and should be ignored.]]
TABLE OF CONTENTS
0. ABSTRACT
1. INTRODUCTION
2. THE SMTP MODEL
2.1 Basic structure
2.2 The extension model
2.3 Other terminology
2.4 Syntax Principles
3. THE SMTP PROCEDURES: AN OVERVIEW
3.1 Session initiation
3.2 Client initiation
3.3 Mail transactions
3.4 Forwarding for Address Correction or Updating
3.5 Commands for Debugging
3.6 Domains
3.7 Relaying
3.8 Terminating sessions and connections
4. THE SMTP SPECIFICATIONS
4.1. SMTP Commands
4.1.1. Command Semantics and Syntax
4.1.2. Lower-level Syntax
4.1.3 Order of commands
4.1.4 Private-use commands
4.2. SMTP Replies
4.2.1. Reply Codes by Function Group
4.2.2. Reply Codes in Numeric Order
4.2.3. Reply code 502
4.2.4 Reply codes after DATA and the subsequent CRLF.CRLF.
4.3. Sequencing of Commands and Replies
4.4 Trace information
4.5. Details
4.5.1. Minimum Implementation
4.5.2. Transparency
4.5.3. Sizes and Timeouts
4.5.4 Queuing Strategies
5. Address resolution and mail handling
6. Problem detection and handling
6.1 Reliable delivery and replies by email
6.2 Loop detection
6.3 Compensating for irregularities
7. Security Considerations
8. References
9. Editor's addresses
10. Acknowledgements
APPENDIX A: TCP
APPENDIX B: Generating SMTP commands from RFC 822 headers
APPENDIX E: Theory of Reply Codes
APPENDIX F: Scenarios
APPENDIX G: Other gateway issues.
APPENDIX H: Glossary
APPENDIX I: Deprecated features of RFC 821
APPENDIX X: Change summary and Loose ends (temporary)
0. Abstract
This document is a self-contained specification of the basic protocol
for the Internet electronic mail transport, consolodating and
updating
* the original SMTP specification of RFC 821 [RFC-821],
* Domain name system requirements and implications for mail
transport from RFC 1035 [RFC-DNS] and RFC 974 [RFC974],
* the clarifications and applicability statements in
RFC 1123 [RFC-1123], and
* material drawn from the SMTP Extension mechanisms [SMTPEXT].
It is intended to replace RFC 821, RFC 974, and the mail transport
materials of RFC 1123. However, RFC 821 specifies some features that
are not in significant use in the Internet of the mid-1990s and, in
appendices, some additional transport models. Those sections are
omitted in this document in the interest of clarity and brevity;
readers needing them should refer to RFC 821.
It also includes some additional material from RFC 1123 that appeared
to need amplification. These have been identified in multiple ways,
mostly by tracking flaming on the header-people list [HEADER-PEOPLE]
and problems of unusual readings or interpretations that have turned
up as the SMTP extensions have been deployed. It is important to
note that everything here is in response to some identified confusion
or bad behavior, not just paranoia.
Where this specification moves beyond consolodation and actually
differs from earlier documents, it supersedes them technically as
well as textually.
Although SMTP was designed as a mail transport and delivery protocol,
this specification also contains information that is important to its
use as a "mail posting" protocol, as recommended for POP [RFC-POP2,
RFC-POP3] and IMAP [RFC-IMAP4].
Except when the historical terminology is necessary for clarity, this
document uses the current "client" and "server" terminology to
identify the sending and receiving SMTP processes, respectively.
A companion document discusses mail bodies and formats RFC 822,
MIME, and their relationship - [MSGFMT].
1. INTRODUCTION
The objective of the Simple Mail Transfer Protocol (SMTP) is to
transfer mail reliably and efficiently.
SMTP is independent of the particular transmission subsystem and
requires only a reliable ordered data stream channel. While this
document specifically discusses transport over TCP, other
transports are possible. Appendices to RFC 821 describe some of
them. A Glossary provides the definitions of terms as used in this
document.
An important feature of SMTP is its capability to transport mail
across transport service environments, usually referred to as "mail
gatewaying". A transport service environment might consist of the
mutually-TCP-accessible hosts on the public internet, a
firewall-isolated private TCP/IP LAN, or a LAN or WAN environment
utilizing an entirely different transport-level protocol. It is
important to realize that transport systems are not one-to-one with
usual definitions of "networks". A process can communicate directly
with another process, and mail communicated, through any mutually
known transport layer. Conversely, mail can be relayed (actually
gatewayed) between hosts on different transport systems by a host on
both transport systems. The Mail eXchanger mechanisms of the domain
name system [RFC-DNS, RFC974] usually permit relaying and gatewaying
to occur invisibly to the user.
2. THE SMTP MODEL
2.1 Basic structure
The SMTP design is based on the following model of communication: as
the result of a user mail request (or transfer from a mail user agent
(see section ##2.3)), the SMTP client establishes a two-way
transmission channel to an SMTP server. Fully-capable client SMTPs
determine the host address supporting the server SMTP function by
resolving the domain name in the user request to it into either an
intermediate mail exchanger host or a final target host. In other
cases, common with clients associated with implementations of the POP
[RFC-POP2, RFC-POP3] or IMAP [RFC-IMAP4] protocols, or when the
client is inside an isolated transport service enviroment, the SMTP
client may send all of its traffic to a single SMTP server which, in
turn, relays the mail to final (or other intermediate) destinations.
Those destinations in turn support all of the queuing, retrying, and
alternate address functions discussed in this specification. The SMTP
server may be either the ultimate destination or an intermediate
(i.e., may assume the role of an SMTP client after receiving the
message). SMTP commands are generated by the SMTP client and sent to
the SMTP server. SMTP replies are sent from the SMTP server to the
SMTP client in response to the commands.
Once the transmission channel is established and initial handshaking
completed, the SMTP-client normally initiates a mail transaction.
Such a transaction consists of a series of commands to specify the
originator and destination of the mail and transmission of the
message body (including any headers or other structure) itself. When
the same message is sent to multiple recipients the SMTP encourages
the transmission of only one copy of the data for all the recipients
at the same destination (or intermediate relay) host.
The server responds to each command with a reply; replies may
indicate that the command was accepted, that additional commands are
expected, or that a temporary or permanent error condition exists.
Commands that specify the sender or recipients may include
server-permitted SMTP service extension requests as discussed in
section ##2.2. The dialog is purposely lock-step, one-at-a-time
although this can be modified by mutually-agreed extension requests.
Once a given mail message has been transmitted, the client may either
request that the connection be shut down or may initiate other mail
transactions.
-------------------------------------------------------------
+----------+ +----------+
+------+ | | | |
| User |<-->| | SMTP | |
+------+ | Sender- |Commands/Replies| Receiver-|
+------+ | SMTP |<-------------->| SMTP | +------+
| File |<-->| | and Mail | |<-->| File |
|System| | | | | |System|
+------+ +----------+ +----------+ +------+
SMTP client SMTP server
Model for SMTP Use
Figure 1
-------------------------------------------------------------
Less commonly, the SMTP protocol and connection may be used by the
client to request ancillary services of the server such as
verification of addresses or exhibiting the contents of mailing
lists.
As suggested above, the SMTP provides mechanisms for the transmission
of mail. This transmission occurs directly from the sending user's
host to the receiving user's host when the two hosts are connected to
the same transport service. When they are not connected to the same
transport service, transmission occurs via one or more relay
SMTP-servers. An intermediate host that will act as either an SMTP
relay or as a gateway into some other transmission environment may
also be selected through the use of the domain name service (DNS)
Mail eXchanger mechanism.
To be able to provide the relay capability the server SMTP is
supplied with the name of the ultimate destination host as well as
the destination mailbox name. Usually, intermediate hosts are
determined via the DNS MX record, not by explicit "source" routing
(see Appendix I).
2.2 The Extension Model
2.2.1 Background
In an effort that started in 1990, approximately a decade after RFC
821 was completed, the protocol was modified with a "service
extensions" model that permits the client and server to agree to
utilize shared functionality that goes beyond the original basic SMTP
requirements. Contemporary SMTP implementations MUST support the
basic extension mechanisms (see below for details), i.e., servers
MUST support the EHLO command even if they do not implement any
specific extensions and clients MUST preferentially utilize EHLO
rather than HELO. However, for compatibility with older
implementations (which are expected to persist for some years), SMTP
clients and servers MUST support the original HELO mechanisms as a
fallback.
Although SMTP is widely and robustly deployed, some parts of the
Internet community might wish to extend the SMTP service. The SMTP
extension mechanism defines a means whereby an extended SMTP client
and server may recognize each other as such and the server can inform
the client as to the service extensions that it supports.
It must be emphasized that any extension to the SMTP service should
not be considered lightly. SMTP's strength comes primarily from its
simplicity. Experience with many protocols has shown that:
protocols with few options tend towards ubiquity, whilst
protocols with many options tend towards obscurity.
This means that each and every extension, regardless of its benefits,
must be carefully scrutinized with respect to its implementation,
deployment, and interoperability costs. In many cases, the cost of
extending the SMTP service will likely outweigh the benefit.
Given this environment, the extension framework consists of:
(1) The SMTP command EHLO, superseding the earlier HELO,
(2) a registry of SMTP service extensions, and
(3) additional parameters to the SMTP MAIL FROM and RCPT TO
commands.
2.2.2 Definition and Registration of Extensions
The IANA maintains a registry of SMTP service extensions.
Associated with each such extension is a corresponding EHLO
keyword value. Each service extension registered with the IANA
must be defined in an RFC. Such RFCs must either be on the
standards-track or must define an IESG-approved experimental
protocol. The definition must include:
(1) the textual name of the SMTP service extension;
(2) the EHLO keyword value associated with the extension;
(3) the syntax and possible values of parameters associated
with the EHLO keyword value;
(4) any additional SMTP verbs associated with the extension
(additional verbs will usually be, but are not required
to be, the same as the EHLO keyword value);
(5) any new parameters the extension associates with the
MAIL FROM or RCPT TO verbs;
(6) how support for the extension affects the behavior of a
server and client SMTP; and,
(7) the increment by which the extension is increasing the
maximum length of the commands MAIL FROM, RCPT TO, or
both, over that specified in RFC 821.
In addition, any EHLO keyword value that starts with an upper
or lower case "X" refers to a local SMTP service extension,
which is used through bilateral, rather than standardized,
agreement. Keywords beginning with "X" may not be used in a
registered service extension.
Any keyword values presented in the EHLO response that do not begin
with "X" must correspond to a standard, standards-track, or
IESG-approved experimental SMTP service extension registered with
IANA. A conforming server must not offer non-"X"-prefixed keyword
values that are not described in a registered extension.
Additional verbs are bound by the same rules as EHLO keywords;
specifically, verbs begining with "X" are local extensions
that may not be registered or standardized and verbs not
beginning with "X" must always be registered.
2.3 Terminology
A glossary of terms appears at the end of this document. However,
the following terms and concepts are used in special ways here, or
represent differences in terminology between RFC 821 and this
document, and should be understood before reading further.
2.3.1 Mail objects
SMTP relays a mail object containing an envelope and a content.
(1) The SMTP envelope is straightforward, and is sent as a
series of SMTP protocol units (described in section ##3): it
consists of an originator address (to which error reports
should be directed); a delivery mode (e.g., deliver to
recipient mailboxes); and, one or more recipient addresses.
(2) The SMTP content is sent in the SMTP DATA protocol unit
and has two parts: the headers and the body. The
headers form a collection of field/value pairs
structured according to RFC 822 [RFC822], whilst the body,
if structured, is defined according to MIME [3]. The
content is textual in nature, expressed using the US
ASCII repertoire (ANSI X3.4-1986). Although extensions
(such as MIME) may relax this restriction for the
content body, the content headers are always encoded
using the US ASCII repertoire. The algorithm defined in
[4] is used to represent header values outside the US
ASCII repertoire, whilst still encoding them using the
US ASCII repertoire.
2.3.2. Sender and receivers
In RFC 821, the two hosts participating in an SMTP transaction were
described as the "SMTP-sender" and "SMTP-receiver". This document
has been changed to reflect current industry terminology and hence
refers to them as the "SMTP client" (or sometimes just "the client")
and "SMTP server" (or just "the server") respectively. Since a given
host may act both as server and client in a relay situation,
"receiver" and "sender" terminology is still used where needed for
clarity.
2.3.3. Mail agents
Other mail system terminology became common after RFC 821 was
published and, where convenient, is used in this specification. In
particular, SMTP servers and clients provide a mail transport service
and therefore act as Mail Transfer Agents (MTAs). Mail User Agents
(MUAs or UAs) are normally thought of as the sources and targets of
mail. At the source, an MUA might collect mail to be transmitted
from a user and hand it off to an MTA; the final ("delivery") MTA
would be thought of as handing the mail off to an MUA (or at least
transferring responsibility to it). However, while these terms are
used with at least the appearance of great precision in other
environments, the implied boundaries between MUAs and MTAs often do
not accurately match common, and conforming, practices with Internet
mail. Hence, the reader should be cautious about inferring the strong
relationships and responsibilities that might be implied if these
terms were used elsewhere.
2.3.4 host
For the purposes of this specification, a computer system attached to
the Internet (or, in some cases, to a private TCP/IP network) and
supporting the SMTP protocol. Hosts are known by names (see
"domain"); identifying them by address is discouraged.
2.3.5 domain
The name of a host (often referred to as a "fully-qualified domain
name" or "FQDN") or some entry in the domain name hierarchy, usually
referred to as a "subdomain", that may contain many hosts. A domain,
or domain name, may also refer to an alias ("CNAME") or may provide a
reference to Mail eXchanger records to be used to deliver mail. See
[RFC-DNS] and section ##5.
Some published material about the Internet (and about Internet mail
in particular) refers to a "host in a domain" as if the host name
were an unqualified name with a domain name appended to it. This
convention has caused considerable confusion and some protocol
violations: the domain name, as described in this document and in
[RFC-DNS], is the entire, fully-qualified name, and an apparent host
name that is not in FQDN form is no more than a local alias.
2.3.6 buffer and state table
The SMTP protocol is described in terms of an abstract machine that
accumulates some information as the various commands are issued as
well as remembering, to the extent necessary, the sequence of
commands and the commands anticipated next. Using the terminology of
one possible implementation model, the storage for information
accumulation is referred to in this document as the "buffer" and the
history of commands and anticipated actions is referred to as the
"state table". The operations of "clearing the buffer" or "resetting
the state table" involve restoring that accumulated information to
their status and content before the relevant commands were issued.
2.4 Syntax Principles
2.4.1 General syntax and transaction model
The mail commands and replies have a rigid syntax. Replies also have
a numeric code. In the following, examples appear which use actual
commands and replies. The complete lists of commands and replies
appears in Section ##4 on specifications.
Commands and replies are not case sensitive. That is, a command or
reply word MAY be upper case, lower case, or any mixture of upper and
lower case. Note that this is not true of mailbox user names. For
some hosts the user name is case sensitive (this practice impedes
interoperability and is discouraged), and SMTP implementations
MUST take care to preserve the case of user names as they appear in
mailbox arguments. Domain names are not case sensitive.
Commands and replies are composed of characters from the ASCII
character set [1]. When the transport service provides an 8-bit byte
(octet) transmission channel, each 7-bit character is transmitted
right justified in an octet with the high order bit cleared to zero.
More specifically, the unextended SMTP service provides seven bit
transport only. SMTP clients MUST NOT transmit messages with
information in the high-order bit of octets. If such messages are
transmitted in violation of this rule, receiving SMTP servers MAY
clear the high-order bit or reject the message as invalid. Eight-bit
transmission MAY be requested of the server by the client using
extended SMTP facilities, notably the "8BITMIME" extension. 8BITMIME
SHOULD be supported by SMTP servers. However, it MUST not be
construed as authorization to transmit unrestricted 8 bit material;
for material with the high bit on that is not in MIME format with an
appropriate content-transfer encoding, "8BITMIME" MUST NOT be
requested by senders snd server MAY respond as discussed above.
The metalinguistic notation used in this document corresponds to the
"Augmented BNF" used in other Internet mail system documents. The
reader who is not familiar with that syntax should consult [ABNF].
2.4.2 Command and reply syntax
The commands consist of a command code followed by an argument field.
Command codes are four alphabetic characters. Upper and lower case
alphabetic characters are to be treated identically. Thus, any of
the following may represent the mail command:
MAIL Mail mail MaIl mAIl
This also applies to any symbols representing parameter values, such
as "TO" or "to" for the forward-path. Command codes and the argument
fields are separated by one or more spaces. However, within the
reverse-path and forward-path arguments case is important. In
particular, in some hosts the user "smith" is different from the user
"Smith".
The argument field consists of a variable length character string
ending with the character sequence <CRLF>. The receiver is to take
no action until this sequence is received.
The syntax for each command is shown with the discussion of that
command. Common elements and parameters are shown in section
##4.1.2.
3. THE SMTP PROCEDURES: AN OVERVIEW
This section presents the procedures used in SMTP in several parts.
After a review of session initiation by the server and client, there
is the basic mail procedure defined as a mail transaction. Following
this are descriptions of forwarding mail, verifying mailbox names and
expanding mailing lists, and the opening and closing exchanges. At
the end of this section are comments on relaying, a note on mail
domains, and a discussion of changing roles. Throughout this section
are examples of partial command and reply sequences, several complete
scenarios are presented in Appendix F.
3.1 Session initiation
An SMTP session is initiated by the client opening a connection to
the server and the server responding with an opening message.
SMTP server implementations SHOULD include identification of their
software and version information in the connection greeting reply
after the 220 code. This practice permits much more efficient
isolation and repair of any problems. While some systems also
identify their contact point for mail problems, this is not a
substitute for maintaining the required Postmaster address (see
[RFC822]). Implementations MAY make provision for SMTP servers to be
configured to disable the software and version announcement where it
causes security concerns.
3.2 Client initiation: EHLO
The client then sends the EHLO command to the server, indicating its
identity. In addition to opening the session, use of EHLO indicates
that the client is able to process service extensions and requests
that the server provide a list of the extensions it supports. Older
SMTP systems, unable to support service extensions, MAY use HELO
instead of EHLO but EHLO SHOULD be used by all current clients and
accepted by all current systems.
In the EHLO, or the older HELO, command the host sending the command
identifies itself; the command may be interpreted as saying "Hello, I
am <domain>" (and, in the case of EHLO, "and I support service
extension requests").
-------------------------------------------------------------
|
| Example of Connection Opening
|
| R: 220 BBN-UNIX.ARPA Simple Mail Transfer Service Ready
| S: HELO USC-ISIF.ARPA
| R: 250 BBN-UNIX.ARPA
|
| Example 5
|
-------------------------------------------------------------
-------------------------------------------------------------
|
| Example of Connection Closing
|
| S: QUIT
| R: 221 BBN-UNIX.ARPA Service closing transmission channel
|
| Example 6
|
-------------------------------------------------------------
3.3. Mail Transactions
There are three steps to SMTP mail transactions. The transaction
is started with a MAIL command which gives the sender
identification. A series of one or more RCPT commands follows
giving the receiver information. Then a DATA command gives the
mail data. And finally, the end of mail data indicator confirms
the transaction.
The first step in the procedure is the MAIL command. The
<reverse-path> contains the source mailbox.
MAIL <SP> FROM:<reverse-path> [<SP> <mail-parameters>] <CRLF>
This command tells the SMTP-receiver that a new mail
transaction is starting and to reset all its state tables and
buffers, including any recipients or mail data. It gives the
reverse-path which can be used to report errors (see section
##4.2 for a discussion of error reporting). If accepted, the
SMTP server returns a 250 OK reply.
The <reverse-path> can contain more than just a mailbox. The
<reverse-path> is a reverse source routing list of hosts and
source mailbox. The first host in the <reverse-path> should be
the host sending this command.
The optional <mail-parameters> are associated with negotiated SMTP
service extensions (see section ##2.2).
The second step in the procedure is the RCPT command.
RCPT <SP> TO:<forward-path> [<SP> <rcpt-parameters>] <CRLF>
This command gives a forward-path (normally a mailbox and domain)
identifying one recipient. If accepted, the SMTP server returns a
250 OK reply, and stores the forward-path. If the recipient is
unknown the SMTP server returns a 550 Failure reply (other
circumstances and reply codes are possible). This second step of
the procedure can be repeated any number of times. The
<forward-path> can contain more than just a mailbox. The
<forward-path> may be a source routing list of hosts and the
destination mailbox. However, in general, the <forward-path>
should contain only a mailbox and domain name, relying on the
domain name system to supply routing information if required.
Servers MUST be prepared to encounter a list of source routes in
the forward path, but MAY ignore the routes or decline to support
the relaying they imply. Similarly, servers MAY decline to accept
mail that is destined for other hosts or systems. Of course, such
a restrictions would make a server useless as a relay for clients
that do not support full SMTP functionality, but such clients MUST
NOT assume that any SMTP server on the Internet can be used as
their mail processing site.
Clients SHOULD NOT utilize explicit source routing except as
discussed in Appendix I.
The optional <mail-parameters> are associated with negotiated SMTP
service extensions (see section ##2.2).
The third step in the procedure is the DATA command.
DATA <CRLF>
If accepted, the SMTP server returns a 354 Intermediate reply
and considers all succeeding lines to be the message text.
When the end of text is received and stored the SMTP-receiver
sends a 250 OK reply.
Since the mail data is sent on the transmission channel, the end
of the mail data must be indicated so that the command and
reply dialog can be resumed. SMTP indicates the end of the
mail data by sending a line containing only "." (period or
full stop). A transparency procedure is used to prevent
this from interfering with the user's text (see Section ##4.5.2).
The end of mail data indicator also confirms the mail transaction
and tells the SMTP server to now process the stored recipients and
mail data. If accepted, the SMTP server returns a 250 OK reply.
The DATA command should fail only if the mail transaction was
incomplete (for example, no recipients), or if resources are not
available. However, some servers in practice do not perform
recipient verification until after the message text is received.
These servers SHOULD treat a failure for one or more recipients as
a "subsequent failure" and return a mail message as discussed in
section ##6. Using a "recipient not found" or equivalent
reply code after the data are accepted makes it difficult or
impossible for the client to determine which recipients failed.
Please note that, when RFC 822 format is being used, the mail data
includes the memo header items such as Date, Subject, To, Cc, From
[RFC822]. Server SMTP systems SHOULD NOT reject messages based on
perceived defects in the RFC 822 or MIME [MIME] message header or
message body. In particular, they MUST NOT reject messages on the
basis of trying to match numbers of Resent- fields. In
particular, messages MUST NOT be rejected because Resent-to
appears without Resent-from, Resent-date, or both.
The above procedure is an example of a mail transaction. These
commands must be used only in the order discussed above.
Example 1 (below) illustrates the use of these commands in a mail
transaction.
-------------------------------------------------------------
|
| Example of the SMTP Procedure
|
| This SMTP example shows mail sent by Smith at host Alpha.ARPA,
| to Jones, Green, and Brown at host Beta.ARPA. Here we assume
| that host Alpha contacts host Beta directly.
|
| S: MAIL FROM:<Smith@Alpha.ARPA>
| R: 250 OK
|
| S: RCPT TO:<Jones@Beta.ARPA>
| R: 250 OK
|
| S: RCPT TO:<Green@Beta.ARPA>
| R: 550 No such user here
|
| S: RCPT TO:<Brown@Beta.ARPA>
| R: 250 OK
|
| S: DATA
| R: 354 Start mail input; end with <CRLF>.<CRLF>
| S: Blah blah blah...
| S: ...etc. etc. etc.
| S: <CRLF>.<CRLF>
| R: 250 OK
|
| The mail has now been accepted for Jones and Brown. Green did
| not have a mailbox at domain Beta.ARPA.
|
| Example 1
|
-------------------------------------------------------------
3.4. Forwarding for Address Correction or Updating
The "forwarding" mechanisms described in section 3.2 of RFC 821, and
especially the 251 reply code from RCPT that indicates a corrected
destination, are no longer in active use. Forwarding support is most
often required to consolodate and simplify addresses within, or
relative to, some enterprise. In most of those cases, information
hiding (and sometimes security) considerations argue against exposure
of the "final" address through the SMTP protocol as a consequence of
the forwarding activity and, in some cases, that final address may
not even be reachable by the sender.
Silent forwarding of messages (without server notification to the
sender) is common in the contemporary Internet.
If the forwarding and address correction mechanisms described in
RFC 821 are used, the addresses given should be stable enough that
it would be reasonable for the client to update local records with
them.
3.5. Commands for Debugging
3.5.1 Overview
SMTP provides, as additional features, commands to verify a user
name or expand a mailing list. This is done with the VRFY and
EXPN commands, which have character string arguments. For the
VRFY command, the string is a user name (see below) and the
response may include the full name of the user and must include
the mailbox of the user, e.g., it MUST BE in either
User Name <mailbox@domain>
or
mailbox@domain
form.
Paths (explicit source routes) MUST NOT be returned by VRFY or
EXPN.
When a name that is the argument to VRFY could identify more
than one mailbox, the server MAY either note the ambiguity or
identify the alternatives. In other words, either of the
following are legitimate response to VRFY:
553 User ambiguous
or
553- Ambiguous; Possibilities are
553-Joe Smith <jsmith@somedomain>
553-Harry Smith <hsmith@somedomain>
553 Melvin Smith <dweep@somedomain>
Under normal circumstances a client receiving a 553 reply would be
expected to expose the result to the user. Use of exactly the forms
given, and the "user ambiguous" or "ambiguous" keywords, will
facilitate automated translation into other languages as needed.
For the EXPN command, the string identifies a mailing list, and the
multiline response may include the full name of the users and must
give the mailboxes on the mailing list.
"User name" is a fuzzy term and used purposely. An implementation of
the VRFY or EXPN commands MUST include at least recognition of local
mailboxes as "user names". If a host chooses to recognize other
strings as "user names" that is allowed.
In some hosts the distinction between a mailing list and an alias
for a single mailbox is a bit fuzzy, since a common data structure
may hold both types of entries, and it is possible to have mailing
lists of one mailbox. If a request is made to verify a mailing
list a positive response can be given if on receipt of a message
so addressed it will be delivered to everyone on the list,
otherwise an error should be reported (e.g., "550 That is a
mailing list, not a user"). If a request is made to expand a user
name a positive response can be formed by returning a list
containing one name, or an error can be reported (e.g., "550 That
is a user name, not a mailing list").
In the case of a multiline reply (normal for EXPN) exactly one
mailbox is to be specified on each line of the reply. The case
of an ambiguous request is discussed above.
The case of verifying a user name is straightforward as shown in
example 3.
-----------------------------------------------------------------
|
| Example of Verifying a User Name
|
| Either
|
| S: VRFY Smith
| R: 250 Fred Smith <Smith@USC-ISIF.ARPA>
|
| Or
|
| S: VRFY Smith
| R: 251 User not local; will forward to <Smith@USC-ISIQ.ARPA>
|
| Or
|
| S: VRFY Jones
| R: 550 String does not match anything.
|
| Or
|
| S: VRFY Jones
| R: 551 User not local; please try <Jones@USC-ISIQ.ARPA>
|
| Or
|
| S: VRFY Gourzenkyinplatz
| R: 553 User ambiguous.
|
| Example 3
|
-----------------------------------------------------------------
The case of expanding a mailbox list requires a multiline reply as
shown in example 4.
-------------------------------------------------------------
|
| Example of Expanding a Mailing List
|
| Either
|
| S: EXPN Example-People
| R: 250-Jon Postel <Postel@USC-ISIF.ARPA>
| R: 250-Fred Fonebone <Fonebone@USC-ISIQ.ARPA>
| R: 250-Sam Q. Smith <SQSmith@USC-ISIQ.ARPA>
| R: 250-Quincy Smith <@USC-ISIF.ARPA:Q-Smith@ISI-VAXA.ARPA>
| R: 250-<joe@foo-unix.ARPA>
| R: 250 <xyz@bar-unix.ARPA>
|
| Or
|
| S: EXPN Executive-Washroom-List
| R: 550 Access Denied to You.
|
| Example 4
|
-------------------------------------------------------------
The character string arguments of the VRFY and EXPN commands
cannot be further restricted due to the variety of implementations
of the user name and mailbox list concepts. On some systems it
may be appropriate for the argument of the EXPN command to be a
file name for a file containing a mailing list, but again there is
a variety of file naming conventions in the Internet.
3.5.2 VRFY normal response.
When normal (2yz or 551) responses are returned from a VRFY or EXPN
request, the reply should normally include the mailbox name, e.g.,
"<foo@bar>" (where "bar" is a fully qualified domain name) must
appear in the syntax. In exceptional circumstances, free-form text
MAY be returned. In order to facilitate parsing by both computers
and people, addresses SHOULD appear in pointed brackets. EXPN and
VRFY MUST return only valid domain addresses that are usable in SMTP
RCPT commands. Consequently, if an address implies delivery to a
program or other system, the mailbox name used to reach that target
should be given.
Server implementations MUST support VRFY and SHOULD support EXPN. For
security reasons, implementations MAY provide local installations a
way to disable either or both of these commands through configuration
options or the equivalent. When these commands are supported, they
are not required to work across relays when relaying is supported.
Since they were both optional in RFC 821, they MUST, if supported, be
listed in the response to EHLO if service extensions are supported.
3.5.3 Meaning of VRFY or EXPN success response.
A server MUST NOT return a 220 code in response to a VRFY or EXPN
command unless it has actually verified the address. In particular,
a server MUST NOT return 220 if all it has done is to verify that the
syntax given is valid. In that case 502 (Command not implemented) or
500 (Syntax error, command unrecognized) SHOULD be returned (note
that implementation of VRFY is required by RFC 1123 and EXPN is
strongly recommended; this specification does not change that
requirement and, hence, except as provided in section ##3.5.5,
implementations that return 500 or 502 for VRFY are not in compliance
with these specifications).
Especially when a server is acting as a mail exchanger for another,
there may be circumstances where an address appears to be correct but
cannot reasonably be verified in real time. In that situation, reply
code 252 SHOULD BE returned. These cases parallel the discussion of
RCPT verification discussed in section ##2.1 although implementations
generally SHOULD be more aggressive about address verification in the
case of VRFY than in the case of RCPT even if a little more time is
required to do so.
3.5.4. Semantics and applications of EXPN.
While EXPN is often very useful in debugging and understanding
problems with mailing lists and multiple-target-address aliases,
some systems have attempted to use source expansion of mailing
lists as a means of eliminating duplicates. The propagation of
aliasing systems with mail on the Internet--both for hosts
(typically with MX and CNAME DNS records) and for mailboxes
(various types of local host aliases) has made it nearly
impossible for these strategies to work, and mail systems SHOULD
NOT attempt them.
3.5.5 VRFY, EXPN, and security.
As discussed above, individual sites may want to disable one or both
of VRFY or EXPN for security reasons. As a corollary to the above,
implementations that permit this MUST NOT appear to have verified
addresses that are not, in fact, verified. If a site disables these
commands for security reasons, the SMTP server SHOULD return a 252
response, rather than a code that could be confused with successful
or unsuccessful verification.
Returning a 250 reply code with the address listed in the VRFY
command after having checked it for syntax only violates this
rule. Of course, an implementation that "supports" VRFY by
always returning 550 whether or not the address is valid is
equally not in conformance.
Within the last four years, the contents of mailing lists have become
popular as an address information source for so-called "spammers" and
their popularity has increased as the administrators of the lists
have devised and installed protections against inappropriate uses of
the lists themselves. Implementations SHOULD still provide support
for EXPN, but sites should carefully evaluate the tradeoffs between
the advantages of having EXPN available for debugging purposes and
the disadvantages of exposing information that may be used in ways
that list members may consider inappropriate.
3.6. Domains
Domains have become a key concept in the Internet mail system. The
use of domains changes the address space from a flat global space of
simple character string host names to a hierarchically structured
rooted tree of global addresses. The host name is replaced by a
domain designator which is a sequence of domain element strings
separated by periods with the understanding that the domain elements
are ordered from the most specific to the most general.
For example, "ISIF.ISI.EDU", "Fred.Cambridge.UK", and
"PC7.LCS.MIT.EDU" might be domain identifiers.
Whenever domain names are used in SMTP, only resolvable,
fully-qualified, domain names (FQDNs) are permitted. In other words,
names that can be resolved to MX RRs or A RRs (as discussed in
section ##5.??.??) are permitted, as are CNAME RRs whose targets can
be resolved, in turn, to MX or A RRs. Local nicknames or unqualified
names MUST NOT be used. There is one exception to this rule: the
domain name given in the EHLO (or HELO) command MUST BE either a
primary host name (a domain name that resolves to an A RR) or, if the
host has no name, a domain literal in dotted-decimal notation.
3.7. RELAYING
The forward-path may be a source route of the form
"@ONE,@TWO:JOE@THREE", where ONE, TWO, and THREE MUST BE
fully-qualified domain names. This form is used to emphasize the
distinction between an address and a route. The mailbox is an
absolute address, and the route is information about how to get
there. The two concepts should not be confused.
In general, the availability of Mail eXchanger records in the domain
name system [RFC-DNS] makes the use of explicit source routes in the
Internet mail system unnecessary. Many historical problems with
their interpretation have made their use undesirable. SMTP clients
SHOULD NOT generate explicit source routes except under unusual
circumstances. SMTP servers MAY decline to act as mail relays or to
accept addresses that specify source routes. They are also permitted
to ignore the route information and simply send to the final
destination as specified in the route and the DNS. However, there
has been a practice, albeit invalid, of using names that do not
appear in the DNS as destination names, with the senders counting on
the intermediate hosts specified in source routing to resolve any
problems. If source routes are stripped, this practice will cause
failures -- one of several reasons why SMTP clients MUST NOT generate
invalid source routes or depend on serial resolution of names.
If source routes are not used, the process described in RFC 821 for
constructing a reverse-path from the forward-path is not applicable
and the reverse-path at the time of delivery will simply be the
address that appeared in the MAIL command. If source routes are
used, RFC 821 should be consulted for the mechanisms for constructing
and updating the forward- and reverse-paths.
Using source routing the SMTP server receives mail to be relayed to
another SMTP server. The SMTP server may accept or reject the task
of relaying the mail in the same way it accepts or rejects mail for a
local user. The SMTP server transforms the command arguments by
moving its own identifier (its domain name or that of any domain for
which it is acting as a mail exchanger), if it appears, from the
forward-path to the beginning of the reverse-path. The SMTP server
then becomes an SMTP client, establishes a transmission channel to
the next SMTP server in the forward-path, and sends it the mail.
Notice that the forward-path and reverse-path appear in the SMTP
commands and replies, but not necessarily in the message. That is,
there is no need for these paths and especially this syntax to appear
in the "To:" , "From:", "CC:", etc. fields of the message header.
Conversely, SMTP servers MUST NOT derive final message delivery
information from message header fields.
If an SMTP server has accepted the task of relaying the mail and
later finds that the forward-path is incorrect or that the mail
cannot be delivered for some other reason, then it MUST construct an
"undeliverable mail" notification message and send it to the
originator of the undeliverable mail (as indicated by the
reverse-path). Formats specified for non-delivery reports by other
standards SHOULD be used if possible.
This notification message must be from the SMTP server at the relay
host or the host that first determines that delivery cannot be
accomplished. Of course, SMTP servers should not send notification
messages about problems with notification messages. One way to
prevent loops in error reporting is to specify a null reverse-path in
the MAIL command of a notification message. When such a message is
transmitted the reverse-path SHOULD BE set to null. A MAIL command
with a null reverse-path appears as follows:
MAIL FROM:<>
An undeliverable mail notification message is shown in example 7.
This notification is in response to a message originated by JOE at
HOSTW and sent via HOSTX to HOSTY with instructions to relay it on
to HOSTZ. What we see in the example is the transaction between
HOSTY and HOSTX, which is the first step in the return of the
notification message.
-------------------------------------------------------------
|
| Example Undeliverable Mail Notification Message
|
| S: MAIL FROM:<>
| R: 250 ok
| S: RCPT TO:<@HOSTX.ARPA:JOE@HOSTW.ARPA>
| R: 250 ok
| S: DATA
| R: 354 send the mail data, end with .
| S: Date: 23 Oct 81 11:22:33
| S: From: SMTP@HOSTY.ARPA
| S: To: JOE@HOSTW.ARPA
| S: Subject: Mail System Problem
| S:
<<>>replace with NOTARY format <<>>
| S: .
| R: 250 ok
|
| Example 7
|
-------------------------------------------------------------
3.8. Terminating Sessions and Connections
An SMTP connection is terminated by the client's sending a QUIT
command. The server then responds with a positive reply code, after
which it closes the connection.
An SMTP server MUST NOT intentionally close the connection
except:
o After receiving a QUIT connand and responding with a 221 reply.
o After detecting the need to shutdown the SMTP service and
returning a 451 reply to any command.
In particular, a server that closes connections in response
to commands that are not understood is in violation of this
specification. Instead, servers are expected to be tolerant of
unknown commands, issuing a 500 reply and awaiting further
instructions from the client.
An SMTP server which is forcibly shut down via external
means SHOULD attempt to send a line containing 451 response
code to the SMTP client before exiting. The SMTP client will
normally read the 451 response code after sending its next
command.
4. THE SMTP SPECIFICATIONS
4.1. SMTP COMMANDS
4.1.1. COMMAND SEMANTICS AND SYNTAX
The SMTP commands define the mail transfer or the mail system
function requested by the user. SMTP commands are character strings
terminated by <CRLF>. The command codes themselves are alphabetic
characters terminated by <SP> if parameters follow and <CRLF>
otherwise. The syntax of mailboxes must conform to receiver site
conventions. The SMTP commands are discussed below. The SMTP
replies are discussed in Section ##4.2.
A mail transaction involves several data objects which are
communicated as arguments to different commands. The reverse-path is
the argument of the MAIL command, the forward-path is the argument of
the RCPT command, and the mail data is the argument of the DATA
command. These arguments or data objects must be transmitted and
held pending the confirmation communicated by the end of mail data
indication which finalizes the transaction. The model for this is
that distinct buffers are provided to hold the types of data objects,
that is, there is a reverse-path buffer, a forward-path buffer, and a
mail data buffer. Specific commands cause information to be appended
to a specific buffer, or cause one or more buffers to be cleared.
4.1.1.1 Extended HELLO (EHLO) or HELLO (HELO)
These commands are used to identify the SMTP client to the SMTP
server. The argument field contains the host name of the SMTP
client.
The SMTP server identifies itself to the SMTP client in the
connection greeting reply, and in the response to this command.
A client SMTP SHOULD start an SMTP session by issuing the EHLO
command. If the SMTP server supports the SMTP service extensions it
will give a successful response, a failure response, or an error
response. If the SMTP server does not support any SMTP service
extensions it will generate an error response. Older client SMTP
systems MAY, as discussed above, use HELO (as specified in RFC 821)
instead of EHLO.
These commands and an OK reply to one of them confirm that both the
SMTP client and the SMTP server are in the initial state, that is,
there is no transaction in progress and all state tables and buffers
are cleared.
If the server SMTP implements and is able to perform the EHLO
command, it will return code 250. This indicates that both the
server and client SMTP are in the initial state, that is, there is no
transaction in progress and all state tables and buffers are cleared.
Normally, this response will be a multiline reply. Each line of the
response contains a keyword and, optionally, one or more parameters.
The syntax for a positive response, using the ABNF notation of
[RFC822], is:
ehlo-ok-rsp ::= "250" domain [ SP greeting ] CR LF
/ ( "250-" domain [ SP greeting ] CR LF
*( "250-" ehlo-line CR LF )
"250" SP ehlo-line CR LF )
; the usual HELO chit-chat
greeting ::= 1*<any character other than CR or LF>
ehlo-line ::= ehlo-keyword *( SP ehlo-param )
ehlo-keyword ::= (ALPHA / DIGIT) *(ALPHA / DIGIT / "-")
; syntax and values depend on ehlo-keyword
ehlo-param ::= 1*<any CHAR excluding SP and all
control characters (US ASCII 0-31
inclusive)>
ALPHA ::= <any one of the 52 alphabetic characters
(A through Z in upper case, and,
a through z in lower case)>
DIGIT ::= <any one of the 10 numeric characters
(0 through 9)>
CR ::= <the carriage-return character
(ASCII decimal code 13)>
LF ::= <the line-feed character
(ASCII decimal code 10)>
SP ::= <the space character
(ASCII decimal code 32)>
Although EHLO keywords may be specified in upper, lower, or mixed
case, they must always be recognized and processed in a
case-insensitive manner. This is simply an extension of practices
specified in RFC 821.
4.1.1.2 MAIL (MAIL)
This command is used to initiate a mail transaction in which the mail
data is delivered to one or more mailboxes. The argument field
contains a reverse-path.
The reverse-path consists of an optional list of hosts and the sender
mailbox. When the list of hosts is present, it is a "reverse" source
route and indicates that the mail was relayed through each host on
the list (the first host in the list was the most recent relay).
This list is used as a source route to return non-delivery notices to
the sender. As each relay host adds itself to the beginning of the
list, it must use its name as known in the transport environment to
which it is relaying the mail rather than that of the transport
environment from which the mail came (if they are different). In
some types of error reporting messages (for example, undeliverable
mail notifications) the reverse-path may be null (see Example 7).
This command clears the reverse-path buffer, the forward-path buffer,
and the mail data buffer; and inserts the reverse-path information
from this command into the reverse-path buffer.
If service extensions were negotiated, the MAIL command may also
carry parameters associated with a particular service extension.
Syntax: "MAIL FROM:" Reverse-path [ Mail-parameters ]
or
"MAIL FROM:<>"
4.1.1.3 RECIPIENT (RCPT)
This command is used to identify an individual recipient of
the mail data; multiple recipients are specified by multiple
use of this command.
The forward-path normally consists a required destination mailbox.
Sending systems SHOULD not generate the optimal list of hosts known
as a source route. Recieving systems MUST recognize source route
syntax but SHOULD strip off the source route specification and
utilize the domain name associated with the mailbox as if the source
route had not appeared.
Similarly, relay host SHOULD strip or ignore source routes and names
MUST NOT be copied into the reverse-path. When mail reaches its
ultimate destination (the forward-path contains only a destination
mailbox), the SMTP server inserts it into the destination mailbox in
accordance with its host mail conventions.
For example, mail received at relay host A with arguments
FROM:<USERX@HOSTY.ARPA>
TO:<@HOSTA.ARPA,@HOSTB.ARPA:USERC@HOSTD.ARPA>
will be relayed on to host B with arguments
FROM:<USERX@HOSTY.ARPA>
TO:<USERC@HOSTD.ARPA>.
If service extensions were negotiated, the MAIL command may also
carry parameters associated with a particular service extension.
Syntax: "RCPT TO:" Forward-path [ Rcpt-parameters ]
4.1.1.4 DATA (DATA)
The receiver treats the lines (strings ending in CRLF sequences)
following the command as mail data from the sender. This command
causes the mail data from this command to be appended to the mail
data buffer. The mail data may contain any of the 128 ASCII
character codes, although experience has indicated that use of
control characters other then SP, HT, CR, and LF may cause problems
and should be avoided when possible.
SMTP is defined in terms of sending messages consisting of lines of
text. Lines are strictly defined as ending in ASCII CR LF sequences.
Systems that use other line delimiting mechanisms internally MUST
convert to CR LF sequences before transmitting mail with unextended
SMTP or with any SMTP service extension on the standards track as of
the time of this writing.
The mail data is terminated by a line containing only a period, that
is the character sequence "<CRLF>.<CRLF>" (see Section ##4.6.2 on
Transparency). This is the end of mail data indication.
The custom of accepting lines ending only in LF, as a concession to
non-conforming behavior on the part of some UNIX systems, has proven
to cause more interoperability problems than it solves and SMTP
server systems MUST NOT do this, even in the name of improved
robustness. In particular, the sequence "LF.LF" (bare line feeds,
without carriage returns) MUST NOT be treated as equivalent to
CRLF.CRLF as the end of mail data indication.
Receipt of the end of mail data indication requires that the server
process the stored mail transaction information. This processing
consumes the information in the reverse-path buffer, the forward-path
buffer, and the mail data buffer, and on the completion of this
command these buffers are cleared. If the processing is successful
the receiver must send an OK reply. If the processing fails
completely the receiver must send a failure reply.
When the SMTP server accepts a message either for relaying or for
final delivery it inserts a trace record (also referred to
interchangabily as a "time stamp line" or "Received" line) at the top
of the mail data. This trace record indicates the identity of the
host that sent the message, and the identity of the host that
received the message (and that is inserting this time stamp), and the
date and time the message was received. Relayed messages will have
multiple time stamp lines. Details for formation of these lines,
including their syntax, is specified in section ##4.4.
4.1.1.5 RESET (RSET)
This command specifies that the current mail transaction is to be
aborted. Any stored sender, recipients, and mail data must be
discarded, and all buffers and state tables cleared. The receiver
must send an OK reply. A reset command may be issued by the client
at any time. It is effectively equivalent to a NOOP if issued
immediately after EHLO or HELO, or before either of those commands
have been issued. In other situations, it restores the state to
that immediately after the most recent EHLO or HELO. An SMTP server
MUST NOT close the connection as the result of receiving a RSET; that
action is reserved for QUIT (see section ##4.1.1.10, below).
4.1.1.6 VERIFY (VRFY)
This command asks the receiver to confirm that the argument
identifies a user. If it is a user name, the full name of
the user (if known) and the fully specified mailbox are
returned.
This command has no effect on any of the reverse-path
buffer, the forward-path buffer, or the mail data buffer.
Syntax: "VRFY" SP String
4.1.1.7 EXPAND (EXPN)
This command asks the receiver to confirm that the argument
identifies a mailing list, and if so, to return the
membership of that list. The full name of the users (if
known) and the fully specified mailboxes are returned in a
multiline reply.
This command has no effect on any of the reverse-path
buffer, the forward-path buffer, or the mail data buffer.
Syntax: "EXPN" SP String
4.1.1.8 HELP (HELP)
This command causes the receiver to send helpful information
to the sender of the HELP command. The command MAY take an
argument (e.g., any command name) and return more specific
information as a response.
This command has no effect on any of the reverse-path
buffer, the forward-path buffer, or the mail data buffer.
SMTP servers SHOULD support HELP even if the form with an argument
is not supported.
Syntax: "HELP" [ SP String ]
4.1.1.9 NOOP (NOOP)
This command does not affect any parameters or previously
entered commands. It specifies no action other than that
the receiver send an OK reply.
This command has no effect on any of the reverse-path
buffer, the forward-path buffer, or the mail data buffer.
Syntax: "NOOP" [SP String]
4.1.1.10 QUIT (QUIT)
This command specifies that the receiver must send an OK
reply, and then close the transmission channel.
The receiver MUST NOT intentionally close the transmission channel
until it receives and replies to a QUIT command (even if there was
an error). The sender MUST NOT intentionally close the
transmission channel until it send a QUIT command and receives the
reply (even if there was an error response to a previous command).
If the connection is closed prematurely due to violations of the
above or system or network failure the server MUST act as if a
RSET command had been received (cancelling any pending
transaction, but not undoing any previously completed transaction)
and the client MUST act as if the command or transaction in
progress had received a temporary error (4xx).
Syntax: "QUIT"
4.1.2. LOWER-LEVEL SYNTAX
The syntax of the argument fields of the above commands (using the
syntax specified in [ABNF] where applicable) is given below.
Reverse-path ::= Path
Forward-path ::= Path
Path ::= "<" [ A-d-l ":" ] <mailbox> ">"
A-d-l ::= At-domain *( "," A-d-l )
At-domain ::= "@" Domain
Mail-parameters ::= *( SP Keyword "=" Argument )
Rcpt-parameters ::= *( SP Keyword "=" Argument )
Keyword ::= String <<>>???
Argument ::= String <<>>???
Domain ::= sub-domain 1*("." sub-domain) | domain-literal
sub-domain ::= let-dig *(ldh-str)
domain-literal = "[" IP-address-literal "]"
IP-address-literal = snum 3*("." snum)
snum = one, two, or three digits representing a decimal
integer value in the range 0 through 255
let-dig = Alpha / Digit
ldh-str = *( Alpha / Digit / "-" ) 1*(let-dig)
Alpha = ASCII character in the range A-Z or a-z. As specified in
the domain name system definition [RFC-DNS], case is not
significant in domain strings.
Digit = 0 - 9
Mailbox ::= Local-part "@" Domain
Local-part ::= Dot-string | Quoted-string
While the definition for Local-part above is relatively
permissive, for maximum interoperability, a host that expects to
receive mail SHOULD avoid defining mailboxes where the Local-part
requires (or uses) the Quoted-string form or where the Local-part
is case-sensitive.
Systems MUST NOT define mailboxes in such a way as to require the use
of non-ASCII characters (octets with the high order bit set to one)
or ASCII "control characters" (decimal value 0-31 and 127). These
characters MUST NOT be used in MAIL FROM or RCPT TO commands or other
commands that require mailbox names.
<<?>> <string> ::= <char> | <char> <string>
<<?>> <quoted-string> ::= """ <qtext> """
<<?>> <qtext> ::= "\" <x> | "\" <x> <qtext> | <q> | <q> <qtext>
<char> ::= <c> | "\" <x>
<number> ::= <d> | <d> <number>
<CRLF> ::= <CR> <LF>
<CR> ::= the carriage return character (ASCII code 13)
<LF> ::= the line feed character (ASCII code 10)
<SP> ::= the space character (ASCII code 32)
<snum> ::= one, two, or three digits representing a decimal
integer value in the range 0 through 255
<a> ::= any one of the 52 alphabetic characters A through Z
in upper case and a through z in lower case
<c> ::= any one of the 128 ASCII characters, but not any
<special> or <SP>
<d> ::= any one of the ten digits 0 through 9
<q> ::= any one of the 128 ASCII characters except <CR>,
<LF>, quote ("), or backslash (\)
<x> ::= any one of the 128 ASCII characters (no exceptions)
<special> ::= "<" | ">" | "(" | ")" | "[" | "]" | "\" | "."
| "," | ";" | ":" | "@" """ | the control
characters (ASCII codes 0 through 31 inclusive and
127)
Note that the backslash, "\", is a quote character, which is
used to indicate that the next character is to be used
literally (instead of its normal interpretation). For example,
"Joe\,Smith" could be used to indicate a single nine character
user field with comma being the fourth character of the field.
Characters outside the set of specials, alphas, digits, and hyphen
are prohibited by the domain name system definition and MUST NOT
appear in domain names. In particular, the underscore character is
not permitted.
Sometimes a host is not known to the translation function and
communication is blocked. To bypass this barrier a numeric form is
also allowed for host "names". This form uses four or more small
decimal integers separated by dots and enclosed by brackets, e.g.,
"[123.255.37.2]", which indicates an Internet Address in
sequence-of-octets form.
The time stamp line and the return path line are formally defined as
follows:
<return-path-line> ::= "Return-Path:" <SP><reverse-path><CRLF>
<time-stamp-line> ::= "Received:" <SP> <stamp> <CRLF>
<stamp> ::= <from-domain> <by-domain> <opt-info> ";"
<daytime>
<from-domain> ::= "FROM" <SP> <domain> <SP>
<by-domain> ::= "BY" <SP> <domain> <SP>
<opt-info> ::= [<via>] [<with>] [<id>] [<for>]
<via> ::= "VIA" <SP> <link> <SP>
<with> ::= "WITH" <SP> <protocol> <SP>
<id> ::= "ID" <SP> <string> <SP>
<for> ::= "FOR" <SP> <path> <SP>
<<>>FOR and <link> need to be nailed down.
<link> ::= The standard names for links are registered with
the Internet Assigned Numbers Authority (IANA).
<protocol> ::= The standard names for protocols are
registered with the Internet Assigned Numbers Authority
(IANA).
<daytime> ::= <SP> <date> <SP> <time>
<date> ::= <dd> <SP> <mon> <SP> <yyyy>
Note that the earlier form, which permits
two-digit years, is deprecated. SMTP systems
SHOULD use four-digit years.
<time> ::= <hh> ":" <mm> ":" <ss> <SP> <zone>
<dd> ::= the one or two decimal integer day of the month in
the range 1 to 31.
<mon> ::= "JAN" | "FEB" | "MAR" | "APR" | "MAY" | "JUN" |
"JUL" | "AUG" | "SEP" | "OCT" | "NOV" | "DEC"
<yyyy> ::= the four decimal integer year in the range 0000 to
9999.
<hh> ::= the two decimal integer hour of the day in the
range 00 to 24.
<mm> ::= the two decimal integer minute of the hour in the
range 00 to 59.
<ss> ::= the two decimal integer second of the minute in the
range 00 to 59.
<zone> ::= A four-digit time zone offset, such as -0600 for US
Eastern Standard Time. This may be supplemented by a
time zone name in parentheses, e.g., "-0800 (PDT)". See
??? for additional discussion.
Note that there is no default; time zone information
is required and MUST be supplied.
-------------------------------------------------------------
|
| Return Path Example
|
| Return-Path: <@CHARLIE.ARPA,@BAKER.ARPA:JOE@ABLE.ARPA>
|
| Example 9
|
-------------------------------------------------------------
-------------------------------------------------------------
|
| Time Stamp Line Example
|
| Received: FROM ABC.ARPA BY XYZ.ARPA ; 22 OCT 81
| 09:23:59 PDT
|
| Received: from ABC.ARPA by XYZ.ARPA via TELENET with X25
| id M12345 for Smith@PDQ.ARPA ; 22 OCT 81 09:23:59 PDT
|
| Example 10
|
--------------------------------------------------------------
4.1.3. Order of commands
There are restrictions on the order in which these commands may
be used.
A session that is to contain mail transactions MUST first be
initialized by the use of the HELO or EHLO command. An SMTP server
SHOULD accept commands for non-mail transactions (e.g., VRFY or EXPN)
without this initialization.
HELO or EHLO commands MAY be issued by a client later in the session.
If either is issued after the session begins, the SMTP server MUST
clear all buffers and state as if an RSET command had been issued.
In other words, the sequence of RSET followed immediately by HELO is
redundant, but not harmful other than in the performance cost of
executing unnecessary commands.
If the HELO or EHLO commands are not acceptable to the SMTP server,
501, 500, or 502 failure replies MUST be returned as appropriate.
The SMTP server must stay in the same state after transmitting these
replies as it was in before the HELO or EHLO were received.
RFC 1123 contains a discussion of arguments to HELO and conditions
under which the HELO command can be rejected. In particular, HELO
(or EHLO) MUST NOT be rejected because the client's putative name
does not match some criteria established by the server (e.g.,
verification of reverse DNS mapping).
The NOOP, HELP, EXPN, VRFY, and RSET commands can be used at any time
during a session, or without previously initializing a session. SMTP
servers SHOULD process these normally (i.e., not return a 503 code)
even if no HELO or EHLO command has yet been received; clients SHOULD
open a session with HELO or EHLO before sending these commands.
If the above rules are followed, the example in RFC 821 that shows
"550 access denied to you" in response to an EXPN command is
essentially meaningless unless a HELO or EHLO command preceeds the
EXPN or the denial of access is based on the client's IP address.
The MAIL, SEND, SOML, or SAML commands begin a mail transaction.
Once started a mail transaction consists of one of the transaction
beginning commands, one or more RCPT commands, and a DATA command, in
that order. A mail transaction may be aborted by the RSET command.
There may be zero or more transactions in a session.
If the transaction beginning command argument is not acceptable a 501
failure reply MUST be returned and the SMTP server must stay in the
same state. If the commands in a transaction are out of order to the
degree that they cannot be processed by the server a 503 failure
reply MUST be returned and the SMTP server must stay in the same
state.
The last command in a session must be the QUIT command. The QUIT
command can not be used at any other time in a session, but may be
used by the client SMTP to request connection-closing even if no
session-opening command has been sent and accepted.
4.1.4 Private-use commands
Commands starting in "X" may be used by bilateral agreement
between the client (sending) and server (receiving) SMTPs.
An SMTP server that does not recognize such a command is
expected to reply with "500 Command not recognized". An
extended SMTP server MAY list the feature names associated
with these private commands in the response to the EHLO
command.
Commands sent or accepted by SMTP systems that do not start
with "X" MUST be documented in published RFCs and be at
least candidates for standardization.
4.2. SMTP REPLIES
Replies to SMTP commands are devised to ensure the synchronization of
requests and actions in the process of mail transfer, and to
guarantee that the SMTP client always knows the state of the SMTP
server. Every command must generate exactly one reply.
The details of the command-reply sequence are made explicit in
Section ##4.3 on Sequencing.
An SMTP reply consists of a three digit number (transmitted as three
alphanumeric characters) followed by some text. The number is
intended for use by automata to determine what state to enter next;
the text is meant for the human user. It is intended that the three
digits contain enough encoded information that the SMTP client need
not examine the text and may either discard it or pass it on to the
user, as appropriate. In particular, the text may be
receiver-dependent and context dependent, so there are likely to be
varying texts for each reply code. A discussion of the theory of
reply codes is given in Appendix E. Formally, a reply is defined to
be the sequence: a three-digit code, SP, one line of text, and
CRLF, or a multiline reply (as defined in Appendix E). Only the
EXPN and HELP commands are expected to result in multiline replies in
normal circumstances, however multiline replies are allowed for any
command.
An SMTP server SHOULD send only the reply codes listed in this
document. An SMTP server SHOULD use the text shown in the examples
whenever appropriate.
A client SMTP MUST determine its actions only by the reply
code, not by the text (except for 251 and 551 replies); any
text, including no text at all, must be acceptable. The space
(blank) following the reply code is considered part of the
text. Whenever possible, a sender-SMTP SHOULD test only the
first digit of the reply code.
4.2.1. REPLY CODES BY FUNCTION GROUPS
500 Syntax error, command unrecognized
[This may include errors such as command line too long]
501 Syntax error in parameters or arguments
502 Command not implemented (see section ##4.2.3)
503 Bad sequence of commands
504 Command parameter not implemented
211 System status, or system help reply
214 Help message
[Information on how to use the receiver or the meaning of a
particular non-standard command; this reply is useful only
to the human user]
220 <domain> Service ready
221 <domain> Service closing transmission channel
421 <domain> Service not available,
closing transmission channel
[This may be a reply to any command if the service knows it
must shut down]
250 Requested mail action okay, completed
251 User not local; will forward to <forward-path>
252 Cannot VRFY user, but will accept message and attempt
delivery
450 Requested mail action not taken: mailbox unavailable
[E.g., mailbox busy]
550 Requested action not taken: mailbox unavailable
[E.g., mailbox not found, no access]
451 Requested action aborted: error in processing
551 User not local; please try <forward-path>
452 Requested action not taken: insufficient system storage
552 Requested mail action aborted: exceeded storage allocation
553 Requested action not taken: mailbox name not allowed
[E.g., mailbox syntax incorrect]
354 Start mail input; end with <CRLF>.<CRLF>
554 Transaction failed
4.2.2. NUMERIC ORDER LIST OF REPLY CODES
211 System status, or system help reply
214 Help message
[Information on how to use the receiver or the meaning of a
particular non-standard command; this reply is useful only
to the human user]
220 <domain> Service ready
221 <domain> Service closing transmission channel
250 Requested mail action okay, completed
251 User not local; will forward to <forward-path>
252 Cannot VRFY user, but will accept message and attempt
delivery
354 Start mail input; end with <CRLF>.<CRLF>
421 <domain> Service not available,
closing transmission channel
[This may be a reply to any command if the service knows it
must shut down]
450 Requested mail action not taken: mailbox unavailable
[E.g., mailbox busy]
451 Requested action aborted: local error in processing
452 Requested action not taken: insufficient system storage
500 Syntax error, command unrecognized
[This may include errors such as command line too long]
501 Syntax error in parameters or arguments
502 Command not implemented
503 Bad sequence of commands
504 Command parameter not implemented
550 Requested action not taken: mailbox unavailable
[E.g., mailbox not found, no access]
551 User not local; please try <forward-path>
552 Requested mail action aborted: exceeded storage allocation
553 Requested action not taken: mailbox name not allowed
[E.g., mailbox syntax incorrect]
554 Transaction failed
4.2.3. Reply code 502
Questions have been raised as to when reply code 502 (Command
not implemented) should be returned in preference to other
codes. 502 SHOULD be used when the command is actually
recognized by the SMTP server, but not implemented. If the
command is not recognized, code 500 SHOULD be returned.
Extended SMTP systems MUST NOT list capabilities in response to
EHLO for which they will return 502 (or 500) replies.
4.2.4 Reply codes after DATA and the subsequent CRLF.CRLF.
When an SMTP server returns a positive completion status (2yz
code) after the DATA command is completed with CRLF.CRLF, it
accepts responsibity for:
+ delivering the message (if the recipient mailbox exists), or
+ if attempts to deliver the message fail due to transient
conditions, retrying delivery some reasonable number of times
at intervals as specified in RFC 1123, or
+ if attempts to deliver the message fail due to permanent
conditions, or if repeated attempts to deliver the message
fail due to transient conditions, returning appropriate
notification to the sender of the original message (using the
address in the SMTP MAIL FROM command).
When an SMTP server returns a transient error completion status
(4yz) code after the DATA command is completed with CRLF.CRLF,
it MUST NOT make any further attempt to deliver that message.
The SMTP client retains responsibility for delivery of that
message. The sending user should be able to interpret the
return of a transient or permanent failure status as a
non-delivery indication.
4.3. SEQUENCING OF COMMANDS AND REPLIES
4.3.1 Sequencing overview
The communication between the sender and receiver is intended to be
an alternating dialogue, controlled by the sender. As such, the
sender issues a command and the receiver responds with a reply.
Unless other arrangements are negotiated through service extensions,
the sender must wait for this response before sending further
commands.
One important reply is the connection greeting. Normally, a receiver
will send a 220 "Service ready" reply when the connection is
completed. The sender should wait for this greeting message before
sending any commands.
Note: all the greeting type replies have the official name (i.e., the
fully-qualified primary domain name) of the server host as the first
word following the reply code. When the host has no name, the IP
address should be used, in bracketed dotted-octet format, e.g.,
[10.0.0.6].
For example,
220 <SP> USC-ISIF.ARPA <SP> Service ready <CRLF>
The table below lists alternative success and failure replies for
each command. These must be strictly adhered to; a receiver may
substitute text in the replies, but the meaning and action implied
by the code numbers and by the specific command reply sequence
cannot be altered.
COMMAND-REPLY SEQUENCES
Each command is listed with its usual possible replies. The prefixes
used before the possible replies are "P" for preliminary (not used in
SMTP), "I" for intermediate, "S" for success, "F" for failure, and
"E" for error. The 421 reply (service not available, closing
transmission channel) may be given to any command if the
SMTP-receiver knows it must shut down. Since some servers may
generate other replies under special circumstances, and to allow for
future extension, SMTP clients SHOULD, when possible, interpret only
the first digit of the reply and MUST be prepared to deal with
unrecognized reply codes by interpreting the first digit only. SMTP
servers MUST NOT transmit reply codes to an SMTP client that are
other than three digits or that do not start in a digit between 2 and
5 inclusive.
CONNECTION ESTABLISHMENT
S: 220
F: 421
HELO
S: 250
E: 500, 501, 504, 421
MAIL
S: 250
F: 552, 451, 452
E: 500, 501, 421
RCPT
S: 250, 251 (but see section ##<<<>>> for discussion of 251)
F: 550, 551, 552, 553, 450, 451, 452
E: 500, 501, 503, 421
DATA
I: 354 -> data -> S: 250
F: 552, 554, 451, 452
F: 451, 554
E: 500, 501, 503, 421
RSET
S: 250
E: 500, 501, 504, 421
SEND
S: 250
F: 552, 451, 452
E: 500, 501, 502, 421
SOML
S: 250
F: 552, 451, 452
E: 500, 501, 502, 421
SAML
S: 250
F: 552, 451, 452
E: 500, 501, 502, 421
VRFY
S: 250, 251, 252
F: 550, 551, 553
E: 500, 501, 502, 504, 421
EXPN
S: 250, 252
F: 550
E: 500, 501, 502, 504, 421
HELP
S: 211, 214
E: 500, 501, 502, 504, 421
NOOP
S: 250
E: 500, 421
QUIT
S: 221
E: 500
TURN
S: 250
F: 502
E: 500, 503
4.4 Trace information
When an SMTP server receives a message for delivery or further
processing, it MUST insert trace ("time stamp" or "Received")
information at the beginning of the message body, as discussed under
the DATA command in section ##4.1.1.4.
This line must be structured as follows:
* The FROM field SHOULD contain both (1) the name of the
source host as presented in the EHLO or HELO command and (2)
a domain literal containing the IP address of the source,
determined from the TCP connection.
* The ID field MAY contain an "@" as suggested in RFC-822,
but this is not required.
* The FOR field MAY contain a list of <path> entries when
multiple RCPT commands have been given.
An Internet mail program MUST NOT change a Received: line that was
previously added to the message header.
As the Internet grows, comparability of Received fields is important
for detecting problems, especially slow relays. SMTP servers that
create Received fields SHOULD use explicit offsets in the dates
(e.g., -0800), rather than time zone names of any type. Local time
(with an offset) is preferred to UTF when feasible. If it is desired
to also use a time zone name, it should be included in a commment.
When the SMTP server makes the "final delivery" of a message it
inserts a return-path line at the beginning of the mail data. This
use of return-path is required; mail systems MUST support it. The
return path line preserves the information in the <reverse-path> from
the MAIL command. Here, final delivery means the message leaves the
SMTP world. Normally, this would mean it has been delivered to the
destination user, but in some cases it may be further processed and
transmitted by another mail system.
It is possible for the mailbox in the return path be different from
the actual sender's mailbox, for example, if error responses are to
be delivered a special error handling mailbox rather than to that of
the message sender. When mailing lists are involved, this
arrangement is common and useful as a means of directing errors to
the list maintainer rather than the message originator.
The preceding two paragraphs imply that the final mail data will
begin with a return path line, followed by one or more time stamp
lines. These lines will be followed by the mail data header and body
[RFC822]. See Example 8.
It is sometimes difficult for an SMTP server to determine whether or
not it is making final delivery since forwarding or other operations
may occur after the message is accepted for delivery. However any
further (forwarding, gateway, or relay) systems MAY remove the return
path and rebuild the MAIL FROM command as needed to ensure that
exactly one such line appears in a delivered message.
A message-originating SMTP system SHOULD NOT send a message that
already contains a Return-path header. If a message that contains
more than one Return-path header is received, only the first
Return-path header line in the message header is valid. A message
header processor SHOULD discard or, if necessary just ignore, any
Return-path headers following the first one.
The primary intent of the Return-path is that it designates the
address to which messages indicating non-delivery or other mail
system failures at to be sent. For this to be unambigious, exactly
one return path should be present when the message is delivered.
Systems using RFC 822 syntax with non-SMTP transports SHOULD preserve
the intent of having an unambiguous address, associated with the
transport envelope, to which to send error reports (e.g.,
non-delivery messages).
Historical note: Text in RFC 822 that appears to contradict the
use of Return-path (or the envelope MAIL FROM address) as the
destination of error messages is not applicable on the Internet.
The MAIL FROM address (as copied into the Return-path) MUST be
used as the target of any mail containing delivery error messages.
In particular,
(i) a gateway from SMTP->elsewhere SHOULD insert a return-path
header, unless it is known that the "elsewhere" transport
also uses Internet domain addresses and maintains the
envelope sender address separately.
(ii) a gateway from elsewhere->SMTP SHOULD delete any
return-path header present in the message, and either copy
that information to the SMTP envelope or combine it with
information present in the envelope of the other transport
system to construct the MAIL FROM part of the SMTP envelope.
Special mention is needed of the response and further action required
when the processing following the end of mail data indication is
partially successful. This could arise if after accepting several
recipients and the mail data, the SMTP server finds that the mail
data can be successfully delivered to some of the recipients, but it
cannot be to others (for example, due to mailbox space allocation
problems). In such a situation, the response to the DATA command
must be an OK reply. But, the SMTP server must compose and send an
"undeliverable mail" notification message to the originator of the
message. Either a single notification which lists all of the
recipients that failed to get the message, or separate notification
messages must be sent for each failed recipient (see Example 7). All
undeliverable mail notification messages are sent using the MAIL
command (even if they result from processing the obsolete SEND, SOML,
or SAML commands).
-------------------------------------------------------------
|
| Example of Return Path and Received Time Stamps
|
| Return-Path: <@GHI.ARPA,@DEF.ARPA,@ABC.ARPA:JOE@ABC.ARPA>
| Received: from GHI.ARPA by JKL.ARPA ; 27 Oct 81 15:27:39 -0800
| Received: from DEF.ARPA by GHI.ARPA ; 27 Oct 81 15:15:13 -0800
| Received: from ABC.ARPA by DEF.ARPA ; 27 Oct 81 15:01:59 -0800
| Date: 27 Oct 81 15:01:01 -0800 (PST)
| From: JOE@ABC.ARPA
| Subject: Improved Mailing System Installed
| To: SAM@JKL.ARPA
|
| This is to inform you that ...
|
| Example 8
|
-------------------------------------------------------------
4.5. DETAILS
4.5.1. MINIMUM IMPLEMENTATION
In order to make SMTP workable, the following minimum
implementation is required for all receivers:
COMMANDS -- HELO
VRFY
MAIL
RCPT
DATA
RSET
NOOP
QUIT
Any system that includes an SMTP server that supports RCPT MUST
support the reserved mailbox "Postmaster" as a case-insensitive
mailbox name. EHLO SHOULD be supported if possible.
4.5.2. TRANSPARENCY
Without some provision for data transparency the character
sequence "<CRLF>.<CRLF>" ends the mail text and cannot be sent
by the user. In general, users are not aware of such
"forbidden" sequences. To allow all user composed text to be
transmitted transparently the following procedures are used.
1. Before sending a line of mail text the SMTP client checks
the first character of the line. If it is a period, one
additional period is inserted at the beginning of the line.
2. When a line of mail text is received by the SMTP server
it checks the line. If the line is composed of a single
period it is the end of mail. If the first character is a
period and there are other characters on the line, the first
character is deleted.
The mail data may contain any of the 128 ASCII characters. All
characters are to be delivered to the recipient's mailbox
including format effectors and other control characters. If
the transmission channel provides an 8-bit byte (octets) data
stream, the 7-bit ASCII codes are transmitted right justified
in the octets with the high order bits cleared to zero.
In some systems it may be necessary to transform the data as
it is received and stored. This may be necessary for hosts
that use a different character set than ASCII as their local
character set, or that store data in records rather than
strings. If such transforms are necessary, they must be
reversible -- especially if such transforms are applied to
mail being relayed.
4.5.3. SIZES AND TIMEOUTS
There are several objects that have required minimum maximum
sizes. That is, every implementation must be able to receive
objects of at least these sizes, but must not send objects
larger than these sizes.
****************************************************
* *
* TO THE MAXIMUM EXTENT POSSIBLE, IMPLEMENTATION *
* TECHNIQUES WHICH IMPOSE NO LIMITS ON THE LENGTH *
* OF THESE OBJECTS SHOULD BE USED. *
* *
****************************************************
user
The maximum total length of a user name is 64 characters.
domain
The maximum total length of a domain name or number is 64
characters.
path
The maximum total length of a reverse-path or
forward-path is 256 characters (including the punctuation
and element separators).
command line
The maximum total length of a command line including the
command word and the <CRLF> is 512 characters.
reply line
The maximum total length of a reply line including the
reply code and the <CRLF> is 512 characters.
text line
The maximum total length of a text line including the
<CRLF> is 1000 characters (but not counting the leading
dot duplicated for transparency). This number may be increased by
the use of SMTP Service Extensions.
message body
The maximum total length of a message body (including any message
headers) MUST BE at least 64K octets. Especially since the
introduction of multimedia mail [RFC-MIME], message lengths on the
Internet have grown dramatically, and message size restrictions
should be avoided if at all possible. SMTP server systems that must
impose restrictions SHOULD implement the "SIZE" service extension
([RFC-SIZE]) and SMTP client systems that will send large messages
SHOULD utilize it when possible.
recipients buffer
The maximum total number of recipients that must be
buffered is 100 recipients.
****************************************************
* *
* TO THE MAXIMUM EXTENT POSSIBLE, IMPLEMENTATION *
* TECHNIQUES WHICH IMPOSE NO LIMITS ON THE LENGTH *
* OF THESE OBJECTS SHOULD BE USED. *
* *
****************************************************
Errors due to exceeding these limits may be reported by using
the reply codes, for example:
500 Line too long.
501 Path too long
552 Too many recipients.
552 Too much mail data.
An SMTP client should provide timeouts for all commands. Minimum
values SHOULD be as follows:
o Initial 220 Message: 5 minutes
An SMTP client process needs to distinguish between a
failed TCP connection and a delay in receiving the initial
220 greeting message. Many SMTP servers will accept a
TCP connection but delay delivery of the 220 message until
their system load will permit more mail to be processed.
o MAIL Command: 5 minutes
o RCPT Command: 5 minutes
A longer timeout would be required if processing of
mailing lists and aliases were not deferred until after
the message was accepted.
o DATA Initiation: 2 minutes
This is while awaiting the "354 Start Input" reply to a
DATA command.
o Data Block: 3 minutes
This is while awaiting the completion of each TCP SEND
call transmitting a chunk of data.
o DATA Termination: 10 minutes.
This is while awaiting the "250 OK" reply. When the
receiver gets the final period terminating the message
data, it typically performs processing to deliver the
message to a user mailbox. A spurious timeout at this
point would be very wasteful, since the message has been
successfully sent.
An SMTP server SHOULD have a timeout of at least 5 minutes
while it is awaiting the next command from the sender.
4.5.4 Queuing Strategies
The common structure of a host SMTP implementation includes
user mailboxes, one or more areas for queueing messages in
transit, and one or more daemon processes for sending and
receiving mail. The exact structure will vary depending on the
needs of the users on the host and the number and size of
mailing lists supported by the host. We describe several
optimizations that have proved helpful, particularly for
mailers supporting high traffic levels.
Any queueing strategy MUST include:
o Timeouts on all activities on a per-command basis
o Never sending error messages in response to error messages.
4.5.4.1 Sending Strategy
The general model of an SMTP client is one or more processes
that periodically attempt to transmit outgoing mail. In a
typical system, the program that composes a message has some
method for requesting immediate attention for a new piece of
outgoing mail, while mail that cannot be transmitted
immediately MUST be queued and periodically retried by the
sender. A mail queue entry will include not only the
message itself but also the envelope information.
The sender MUST delay retrying a particular destination
after one attempt has failed. In general, the retry
interval SHOULD be at least 30 minutes; however, more
sophisticated and variable strategies will be beneficial
when the SMTP client can determine the reason for non-
delivery.
Retries continue until the message is transmitted or the
sender gives up; the give-up time generally needs to be at
least 4-5 days. The parameters to the retry algorithm MUST
be configurable.
A sender SHOULD keep a list of hosts it cannot reach and
corresponding connection timeouts, rather than just retrying queued
mail items.
DISCUSSION:
Experience suggests that failures are typically
transient (the target system has crashed), favoring a
policy of two connection attempts in the first hour the
message is in the queue, and then backing off to once
every two or three hours.
The SMTP client can shorten the queueing delay by
cooperation with the SMTP server. In particular, if
mail is received from a particular address, it is good
evidence that any mail queued for that host can now be
sent.
The strategy may be further modified as a result of
multiple addresses per host (see Section ##5.??.??), to
optimize delivery time vs. resource usage.
an SMTP client may have a large queue of messages for
each unavailable destination host, and if it retried
all these messages in every retry cycle, there would be
excessive Internet overhead and the daemon would be
blocked for a long period. Note that an SMTP can
generally determine that a delivery attempt has failed
only after a timeout of a minute or more; a one minute
timeout per connection will result in a very large
delay if it is repeated for dozens or even hundreds of
queued messages.
When the same message is to be delivered to several users on
the same host, only one copy of the message SHOULD be
transmitted. That is, the SMTP client should use the
command sequence: RCPT, RCPT,... RCPT, DATA instead of the
sequence: RCPT, DATA, RCPT, DATA,... RCPT, DATA.
Implementation of this efficiency feature is strongly urged.
Similarly, the SMTP client MAY support multiple concurrent
outgoing mail transactions to achieve timely delivery.
However, some limit SHOULD be imposed to protect the host
from devoting all its resources to mail.
4.5.4.2 Receiving strategy
The SMTP server SHOULD attempt to keep a pending listen on
the SMTP port at all times. This will require the support
of multiple incoming TCP connections for SMTP. Some limit
MAY be imposed.
IMPLEMENTATION:
When the SMTP server receives mail from a particular
host address, it could notify the SMTP client to retry
any mail pending for that host address.
5. Address resolution and mail handling
Once an SMTP client lexically identifies a domain to which mail is to
be delivered for processing (as described in sections ##3.6 and
##3.7), a DNS lookup is performed to resolve that domain name (see
[RFC-DNS]). The lookup first attempts to locate an MX record
associated with that name. If a CNAME record is found instead, the
resulting name is processed as if it were the initial name.
When the lookup succeeds, the mapping can result in a list of
alternative delivery addresses rather than a single address, because
of (a) multiple MX records, (b) multihoming, or both. To provide
reliable mail transmission, the SMTP client MUST be able to try (and
retry) each of the addresses in this list in order, until a delivery
attempt succeeds. However, there MAY also be a configurable limit on
the number of alternate addresses that can be tried. In any case, a
host SHOULD try at least two addresses.
The following information is to be used to rank the host
addresses:
(1) Multiple MX Records -- these contain a preference
indication that should be used in sorting. If there are
multiple destinations with the same preference and there
is no clear reason to favor one (e.g., by address
preference), then the sender-SMTP SHOULD pick one at
random to spread the load across multiple mail exchanges
for a specific organization; note that this is a
refinement of the procedure in [DNS:3].
(2) Multihomed host -- The destination host (perhaps taken
from the preferred MX record) may be multihomed, in which
case the domain name resolver will return a list of
alternative IP addresses. It is the responsibility of the
domain name resolver interface to have ordered this list by
decreasing preference, and SMTP MUST try them in the order
presented.
DISCUSSION:
Although the capability to try multiple alternative
addresses is required, there may be circumstances where
specific installations want to limit or disable the use of
alternative addresses. The question of whether a sender
should attempt retries using the different addresses of a
multihomed host has been controversial. The main argument
for using the multiple addresses is that it maximizes the
probability of timely delivery, and indeed sometimes the
probability of any delivery; the counter argument is that
it may result in unnecessary resource use.
Note that resource use is also strongly determined by the
sending strategy discussed in Section #??.??.??
6. Problem detection and handling
6.1 Reliable delivery and replies by email
When the receiver-SMTP accepts a piece of mail (by sending a "250 OK"
message in response to DATA), it is accepting responsibility for
delivering or relaying the message. It must take this responsibility
seriously, i.e., it MUST NOT lose the message for frivolous reasons,
e.g., because the host later crashes or because of a predictable
resource shortage.
If there is a delivery failure after acceptance of a message, the
receiver-SMTP MUST formulate and mail a notification message. This
notification MUST be sent using a null ("<>") reverse path in the
envelope. The recipient of this notification SHOULD be the address
from the envelope return path (or the Return-Path: line). However,
if this address is null ("<>"), the receiver-SMTP MUST NOT send a
notification. If the address is an explicit source route, it MUST be
stripped down to its final hop.
DISCUSSION:
For example, suppose that an error notification must be
sent for a message that arrived with:
"MAIL FROM:<@a,@b:user@d>". The notification message
should be sent to: "RCPT TO:<user@d>".
Some delivery failures after the message is accepted by SMTP will be
unavoidable. For example, it may be impossible for the receiving
SMTP server to validate all the delivery addresses in RCPT command(s)
due to a "soft" domain system error, because the target is a mailing
list (see earlier discussion of RCPT), or because the server is
acting as a relay and has no immediate access to the delivering
system.
To avoid receiving duplicate messages as the result of timeouts, a
receiver-SMTP MUST seek to minimize the time required to respond to
the final "CRLF.CRLF" that ends a message transfer. See RFC-1047
[RFC1047] for a discussion of this problem.
6.2 Loop detection
Simple counting of the number of Received lines in a message has not
proven to be a desirable method of detecting loops in mail systems,
and SMTP servers SHOULD NOT use that technique. Loop detection by
examination of Received fields for the domain name or other signature
of the SMTP server making the check is effective and MAY be used by
SMTP servers.
6.3 Compensating for irregularities
Unfortunately, variations, creative interpretations, and outright
violations of Internet mail protocols do occur; some would suggest
that they occur quite frequently. The debate as to whether a
well-behaved SMTP receiver or relay should reject a malformed
message, attempt to pass it on unchanged, or attempt to repair it to
increase the odds of successful delivery (or subsequent reply) began
almost with the dawn of structured network mail and shows no signs of
abating. Advocates of rejection claim that attempted repairs are
rarely completely adequate and that rejection of bad messages is the
only way to get the offending software repaired. Advocates of
"repair" or "deliver no matter what" argue that users prefer that
mail go through it if at all possible and that there are significant
market pressures in that direction. In practice, these market
pressures may be more important to particular vendors then strict
conformance to the standards, regardless of the preference of the
actual developers.
The problems associated with ill-formed messages were exacerbated by
the introduction of the split-UA mail reading protocols [RFC-POP2,
RFC-POP3, RFC-IMAP2, RFC-PCMAIL]. These protocols, which facilitate
the use of a client machine to actually process incoming mail that is
separate from the one containing the receiving SMTP, have encouraged
the use of SMTP as a posting protocol and SMTP servers as relay
systems for these client hosts, which are often only intermittently
connected to the Internet. Historically, many of those client
machines lacked some of the mechanisms and information assumed by
SMTP (and indeed, by the mail format protocol [RFC-822]). Some could
not keep adequate track of time; others had no concept of timezones;
still others could not identify their own names or addresses; and, of
course, none could satisfy the assumptions that underlay RFC-822's
conception of authenticated addresses.
In response to these weak SMTP clients, many SMTP systems have taken
on the responsibility to complete messages that are delivered to them
in incomplete or incorrect form. This strategy is generally
considered to be appropriate when the server can identify or
authenticate the client and there are prior agreements between them.
By contrast, there is at best great concern about fixes applied by a
relay or delivery SMTP server that has little or no knowledge of the
user or client machine.
The following changes to a message being processed MAY be applied by
an SMTP server when necessary. The less information the server has
about the client, the less likely these changes are to be correct and
the more caution and conservatism should be applied in considering
whether or not to perform fixes and how.
In all cases, properly-operating clients that supply correct
information are preferred to corrections by the SMTP server. And,
equally in all cases, documentation of actions performed by the
servers (in trace fields and/or header comments) is strongly
encouraged.
- Addition of a message-id field when none appears
- Addition of a date, time or timezone when none appears
- Correction of addresses to proper FQDN format
7. Security Considerations
7.1 Mail security and spoofing
SMTP mail is inherently insecure in that it is feasible for even
fairly casual users to negotiate directly with receiving and
relaying SMTP servers and create messages that will trick a
naive recipient into believing that they came from somewhere
else. Constructing such a message so that the "spoofed"
behavior cannot be detected by an expert is somewhat more
difficult, but not sufficiently so as to be a deterrent to
someone who is determined and knowledgeable.
Consequently, as knowledge of Internet mail increases, so does the
knowledge that SMTP mail inherently cannot be authenticated, or
integrity checks provided, at the transport level. Real security
lies only in end-to-end methods involving the message bodies, e.g.,
those that can be provided in the MOSS framework [RFC-MOSS].
A corollary to this is that efforts to make it more difficult
for users to set envelope MAIL FROM and header "From" fields
to point to valid addresses other than their own are largely
misguided: they do not prevent any would-be mail spoofer from
doing so, and do frustrate legitimate applications in which
mail is sent by one user on behalf of another or in which
error (or normal) replies should be directed to a special
address. On the other hand, systems that provide convenient
ways for users to alter these fields on a per-message basis
should attempt to establish a primary and permanent mailbox
address for the user so that Sender fields can be generated
correctly.
This specification does not further address the security issues
associated with SMTP other than to advocate that useful
functionality not be disabled in the hope of providing some
small margin of protection against an ignorant user who is
trying to fake mail.
7.2 "Blind" copies.
Addresses may appear in the RCPT TO commands to an SMTP server
that do not appear in the message headers for a number of
reasons. The two most common of these involve the use of a
mailing address as a "list exploder" -- a single address that
resolves into multiple addresses -- and the appearance of "blind
copies". In order to avoid defeating some of the purpose of
these mechanisms, SMTP clients and servers SHOULD NOT copy the
RCPT TO command arguments into the headers, even as
informational or private-extension headers. Since this rule is
often violated in practice, and cannot be enforced, sending SMTP
systems that are aware of "bcc" use MAY find it helpful to send
each blind copy as a separate message transaction containing
only a single RCPT TO command.
More generally, while there are often similarities, there is no
inherent relationship between either "reverse" (MAIL FROM, SAML FROM,
etc.) or "forward" (RCPT TO) addresses in the SMTP transaction
("envelope") and the addresses in the headers. Receiving systems
SHOULD NOT attempt to deduce such relationships and use them to alter
the headers of the message for delivery. The popular "Apparently-to"
header is a violation of this principle and SHOULD NOT be used.
See also section ##3.5.5.
8. REFERENCES
[1] ASCII
ASCII, "USA Code for Information Interchange", United States of
America Standards Institute, X3.4, 1968.
[RFC822]
Crocker, D., "Standard for the Format of ARPA Internet Text
Messages", RFC 822, Department of Electrical Engineering,
University of Delaware, August 1982.
[3] TCP
Postel, J., ed., "Transmission Control Protocol - DARPA Internet
Program Protocol Specification", RFC 793, USC/Information Sciences
Institute, NTIS AD Number A111091, September 1981. Also in:
Feinler, E. and J. Postel, eds., "Internet Protocol Transition
Workbook", SRI International, Menlo Park, California, March 1982.
[HEADER-PEOPLE]
[RFC-DNS] P. Mockapetris, "Domain names - implementation and
specification", RFC 1035 and P. Mockapetris, "Domain names -
concepts and facilities", RFC 1034. (STD 13)
[RFC 974] C. Partridge, "Mail routing and the domain system",
01/01/1986
[RFC1047] C. Partridge, "Duplicate messages and SMTP", RFC 1047,
02/01/1988.
[RFC-SIZE] J. Klensin, N. Freed, K. Moore, "SMTP Service Extension
for Message Size Declaration", RFC 1870, 11/06/1995. (STD 10)
[8BITMIME] J. Klensin, N. Freed, M. Rose, E. Stefferud, D. Crocker,
"SMTP Service Extension for 8bit-MIMEtransport", RFC 1652,
07/18/1994.
[MSGFMT] P. Resnick, Work in progress,
draft-ietf-drums-msg-fmt-00.txt, November 1996.
[SMTPEX] J. Klensin, N. Freed, M. Rose, E. Stefferud, D.
Crocker, "SMTP Service Extensions", RFC-1869, 11/06/1995.
[RFC-1123] R. Braden, "Requirements for Internet hosts -
application and support", 10/01/1989
[RFC-MOSS] S. Crocker, N. Freed, J. Galvin, S. Murphy, "MIME Object
Security Services", RFC 1848, 10/03/1995.
[RFC-POP2] M. Butler, D. Chase, J. Goldberger, J. Postel, J.
Reynolds, "Post Office Protocol - version 2", RFC 937,
02/01/1985
[RFC-IMAP2] M. Crispin, "Interactive Mail Access Protocol - Version
2", RFC 1176, 08/20/1990.
[RFC-PCMAIL] M. Lambert, "PCMAIL: A distributed mail system for
personal computers", RFC 1056, 06/01/1988.
[RFC-POP3] J. Myers, M. Rose, "Post Office Protocol - Version 3",
RFC 1930, 5/14/96 (Std 53).
[RFC-IMAP4] M. Crispin, "Internet Message Access Protocol
- Version 4", RFC 1730, 12/20/1994.
[ABNF] Crocker, D., "Augmented BNF for Syntax Specifications: ABNF",
(in progress -- draft-ietf-drums-abnf-01.txt)
9. Editor's Addresses
John C. Klensin
MCI Communications
800 Boylston St, 7th floor
Boston, MA 02199
USA
Email: Klensin@mci.net
Phone: +1 617 960 1011
Fax: +1 617 960 1009
10. Acknowledgements
<<to be supplied>>
APPENDIX A
TCP Transport service
The Transmission Control Protocol [3] is used in the Internet, and in
any network following the Internet standards for internetwork protocols.
Connection Establishment
The SMTP transmission channel is a TCP connection established
between the sender process port U and the receiver process port
L. This single full duplex connection is used as the
transmission channel. This protocol is assigned the service
port 25 (31 octal), that is L=25.
Data Transfer
The TCP connection supports the transmission of 8-bit bytes.
The SMTP data is 7-bit ASCII characters. Each character is
transmitted as an 8-bit byte with the high-order bit cleared to
zero.
APPENDIX B
Generating SMTP commands from RFC 822 headers
Some systems use RFC 822 headers (only) in a mail submission
protocol, or otherwise generate SMTP commands from RFC 822 headers
when such a message is handed to an MTA from a UA. While the MTA-UA
protocol is a private matter, not covered by any Internet Standard,
there are problems with this approach. For example, there have been
repeated problems with proper handling of "bcc" copies and
redistribution lists when information that conceptually belongs to a
mail envelopes is not separated early in processing from header
information (and kept separate).
It is recommended that the UA provide its initial MTA with an
envelope separate from the message itself. However, if the envelope
is not supplied, SMTP commands should be generated as follows:
(i) each recipient addresses from a TO, CC, or BCC header field
should be copied to a RCPT command (generating multiple message
copies if that is required for queuing or delivery). This includes
any addresses listed in a RFC 822 "group". Any BCC fields should
then be removed from the headers. Once this process is completed,
the remaining headers should be checked to verify that at least one
To:, Cc:, or Bcc: header remains. If none do, then a bcc: header
with no additional information SHOULD be inserted (see section ##2.15
above).
(ii) the return address in the MAIL command should be derived from
the system's identity for the submitting (local) user. That return
address should also be copied to the Sender header field if it is
different from the address in the From header field. (Any Sender
field that was already there should be removed.) Systems may provide
a way for submitters to override the envelope return address, but may
want to restrict its use to privileged users. (This will not prevent
mail forgery, but may lessen its incidence.)
A submission protocol based on Standard RFC 822 information alone
MUST NOT be used to gateway a message from a foreign (non-SMTP) mail
system into an SMTP environment. Additional information to construct
an envelope must come from some source in the other environment,
whether supplemental headers or the foreign system's envelope.
Attempts to gateway messages using only their header "to" and "cc"
fields, have repeatedly caused mail loops and other behavior adverse
to the proper functioning of the Internet mail environment. These
problems have been especially common when the message originates from
an Internet mailing list and is distributed into the foreign
environment using envelope information. When these messages are then
processed by a header-only remailer, loops back to the Internet
environment (and the mailing list) are almost inevitable.
APPENDIX E
Theory of Reply Codes
The three digits of the reply each have a special significance.
The first digit denotes whether the response is good, bad or
incomplete. An unsophisticated SMTP client will be able to
determine its next action (proceed as planned, redo, retrench,
etc.) by simply examining this first digit. An SMTP client that
wants to know approximately what kind of error occurred (e.g.,
mail system error, command syntax error) may examine the second
digit, reserving the third digit for the finest gradation of
information.
There are five values for the first digit of the reply code:
1yz Positive Preliminary reply
The command has been accepted, but the requested action
is being held in abeyance, pending confirmation of the
information in this reply. The SMTP client should send
another command specifying whether to continue or abort
the action.
[Note: SMTP does not have any commands that allow this
type of reply, and so does not have the continue or
abort commands.]
2yz Positive Completion reply
The requested action has been successfully completed. A
new request may be initiated.
3yz Positive Intermediate reply
The command has been accepted, but the requested action
is being held in abeyance, pending receipt of further
information. The SMTP client should send another command
specifying this information. This reply is used in
command sequence groups.
4yz Transient Negative Completion reply
The command was not accepted and the requested action did
not occur. However, the error condition is temporary and
the action may be requested again. The sender should
return to the beginning of the command sequence (if any).
It is difficult to assign a meaning to "transient" when
two different sites (receiver- and sender- SMTPs) must
agree on the interpretation. Each reply in this category
might have a different time value, but the SMTP client is
encouraged to try again. A rule of thumb to determine if
a reply fits into the 4yz or the 5yz category (see below)
is that replies are 4yz if they can be repeated without
any change in command form or in properties of the sender
or receiver. (E.g., the command is repeated identically
and the receiver does not put up a new implementation.)
5yz Permanent Negative Completion reply
The command was not accepted and the requested action did
not occur. The SMTP client is discouraged from repeating
the exact request (in the same sequence). Even some
"permanent" error conditions can be corrected, so the
human user may want to direct the SMTP client to
reinitiate the command sequence by direct action at some
point in the future (e.g., after the spelling has been
changed, or the user has altered the account status).
The second digit encodes responses in specific categories:
x0z Syntax -- These replies refer to syntax errors,
syntactically correct commands that don't fit any
functional category, and unimplemented or superfluous
commands.
x1z Information -- These are replies to requests for
information, such as status or help.
x2z Connections -- These are replies referring to the
transmission channel.
x3z Unspecified as yet.
x4z Unspecified as yet.
x5z Mail system -- These replies indicate the status of
the receiver mail system vis-a-vis the requested
transfer or other mail system action.
The third digit gives a finer gradation of meaning in each
category specified by the second digit. The list of replies
illustrates this. Each reply text is recommended rather than
mandatory, and may even change according to the command with
which it is associated. On the other hand, the reply codes
must strictly follow the specifications in this section.
Receiver implementations should not invent new codes for
slightly different situations from the ones described here, but
rather adapt codes already defined.
For example, a command such as NOOP whose successful execution
does not offer the SMTP client any new information will return
a 250 reply. The response is 502 when the command requests an
unimplemented non-site-specific action. A refinement of that
is the 504 reply for a command that is implemented, but that
requests an unimplemented parameter.
The reply text may be longer than a single line; in these cases
the complete text must be marked so the SMTP client knows when it
can stop reading the reply. This requires a special format to
indicate a multiple line reply.
The format for multiline replies requires that every line,
except the last, begin with the reply code, followed
immediately by a hyphen, "-" (also known as minus), followed by
text. The last line will begin with the reply code, followed
immediately by <SP>, optionally some text, and <CRLF>.
For example:
123-First line
123-Second line
123-234 text beginning with numbers
123 The last line
In many cases the SMTP client then simply needs to search for
the reply code followed by <SP> at the beginning of a line, and
ignore all preceding lines. In a few cases, there is important
data for the sender in the reply "text". The sender will know
these cases from the current context.
APPENDIX F
Scenarios
This section presents complete scenarios of several types of SMTP
sessions.
A Typical SMTP Transaction Scenario
This SMTP example shows mail sent by Smith at host USC-ISIF, to
Jones, Green, and Brown at host BBN-UNIX. Here we assume that
host USC-ISIF contacts host BBN-UNIX directly. The mail is
accepted for Jones and Brown. Green does not have a mailbox at
host BBN-UNIX.
-------------------------------------------------------------
R: 220 BBN-UNIX.ARPA Simple Mail Transfer Service Ready
S: HELO USC-ISIF.ARPA
R: 250 BBN-UNIX.ARPA
S: MAIL FROM:<Smith@USC-ISIF.ARPA>
R: 250 OK
S: RCPT TO:<Jones@BBN-UNIX.ARPA>
R: 250 OK
S: RCPT TO:<Green@BBN-UNIX.ARPA>
R: 550 No such user here
S: RCPT TO:<Brown@BBN-UNIX.ARPA>
R: 250 OK
S: DATA
R: 354 Start mail input; end with <CRLF>.<CRLF>
S: Blah blah blah...
S: ...etc. etc. etc.
S: .
R: 250 OK
S: QUIT
R: 221 BBN-UNIX.ARPA Service closing transmission channel
Scenario 1
-------------------------------------------------------------
Aborted SMTP Transaction Scenario
-------------------------------------------------------------
R: 220 MIT-Multics.ARPA Simple Mail Transfer Service Ready
S: HELO ISI-VAXA.ARPA
R: 250 MIT-Multics.ARPA
S: MAIL FROM:<Smith@ISI-VAXA.ARPA>
R: 250 OK
S: RCPT TO:<Jones@MIT-Multics.ARPA>
R: 250 OK
S: RCPT TO:<Green@MIT-Multics.ARPA>
R: 550 No such user here
S: RSET
R: 250 OK
S: QUIT
R: 221 MIT-Multics.ARPA Service closing transmission channel
Scenario 2
-------------------------------------------------------------
Relayed Mail Scenario
-------------------------------------------------------------
Step 1 -- Source Host to Relay Host
R: 220 USC-ISIE.ARPA Simple Mail Transfer Service Ready
S: HELO MIT-AI.ARPA
R: 250 USC-ISIE.ARPA
S: MAIL FROM:<JQP@MIT-AI.ARPA>
R: 250 OK
S: RCPT TO:<@USC-ISIE.ARPA:Jones@BBN-VAX.ARPA>
R: 250 OK
S: DATA
R: 354 Start mail input; end with <CRLF>.<CRLF>
S: Date: 2 Nov 81 22:33:44
S: From: John Q. Public <JQP@MIT-AI.ARPA>
S: Subject: The Next Meeting of the Board
S: To: Jones@BBN-Vax.ARPA
S:
S: Bill:
S: The next meeting of the board of directors will be
S: on Tuesday.
S: John.
S: .
R: 250 OK
S: QUIT
R: 221 USC-ISIE.ARPA Service closing transmission channel
Step 2 -- Relay Host to Destination Host
R: 220 BBN-VAX.ARPA Simple Mail Transfer Service Ready
S: HELO USC-ISIE.ARPA
R: 250 BBN-VAX.ARPA
S: MAIL FROM:<@USC-ISIE.ARPA:JQP@MIT-AI.ARPA>
R: 250 OK
S: RCPT TO:<Jones@BBN-VAX.ARPA>
R: 250 OK
S: DATA
R: 354 Start mail input; end with <CRLF>.<CRLF>
S: Received: from MIT-AI.ARPA by USC-ISIE.ARPA ;
2 Nov 81 22:40:10 UT
S: Date: 2 Nov 81 22:33:44
S: From: John Q. Public <JQP@MIT-AI.ARPA>
S: Subject: The Next Meeting of the Board
S: To: Jones@BBN-Vax.ARPA
S:
S: Bill:
S: The next meeting of the board of directors will be
S: on Tuesday.
S: John.
S: .
R: 250 OK
S: QUIT
R: 221 USC-ISIE.ARPA Service closing transmission channel
Scenario 3
-------------------------------------------------------------
Verifying and Sending Scenario
-------------------------------------------------------------
R: 220 SU-SCORE.ARPA Simple Mail Transfer Service Ready
S: HELO MIT-MC.ARPA
R: 250 SU-SCORE.ARPA
S: VRFY Crispin
R: 250 Mark Crispin <Admin.MRC@SU-SCORE.ARPA>
S: SEND FROM:<EAK@MIT-MC.ARPA>
R: 250 OK
S: RCPT TO:<Admin.MRC@SU-SCORE.ARPA>
R: 250 OK
S: DATA
R: 354 Start mail input; end with <CRLF>.<CRLF>
S: Blah blah blah...
S: ...etc. etc. etc.
S: .
R: 250 OK
S: QUIT
R: 221 SU-SCORE.ARPA Service closing transmission channel
Scenario 4
-------------------------------------------------------------
Mailing List Scenario
First each of two mailing lists are expanded in separate sessions
with different hosts. Then the message is sent to everyone that
appeared on either list (but no duplicates) via a relay host.
-------------------------------------------------------------
Step 1 -- Expanding the First List
R: 220 MIT-AI.ARPA Simple Mail Transfer Service Ready
S: HELO SU-SCORE.ARPA
R: 250 MIT-AI.ARPA
S: EXPN Example-People
R: 250-<ABC@MIT-MC.ARPA>
R: 250-Fred Fonebone <Fonebone@USC-ISIQ.ARPA>
R: 250-Xenon Y. Zither <XYZ@MIT-AI.ARPA>
R: 250-Quincy Smith <@USC-ISIF.ARPA:Q-Smith@ISI-VAXA.ARPA>
R: 250-<joe@foo-unix.ARPA>
R: 250 <xyz@bar-unix.ARPA>
S: QUIT
R: 221 MIT-AI.ARPA Service closing transmission channel
Step 2 -- Expanding the Second List
R: 220 MIT-MC.ARPA Simple Mail Transfer Service Ready
S: HELO SU-SCORE.ARPA
R: 250 MIT-MC.ARPA
S: EXPN Interested-Parties
R: 250-Al Calico <ABC@MIT-MC.ARPA>
R: 250-<XYZ@MIT-AI.ARPA>
R: 250-Quincy Smith <@USC-ISIF.ARPA:Q-Smith@ISI-VAXA.ARPA>
R: 250-<fred@BBN-UNIX.ARPA>
R: 250 <xyz@bar-unix.ARPA>
S: QUIT
R: 221 MIT-MC.ARPA Service closing transmission channel
Step 3 -- Mailing to All via a Relay Host
R: 220 USC-ISIE.ARPA Simple Mail Transfer Service Ready
S: HELO SU-SCORE.ARPA
R: 250 USC-ISIE.ARPA
S: MAIL FROM:<Account.Person@SU-SCORE.ARPA>
R: 250 OK
S: RCPT TO:<@USC-ISIE.ARPA:ABC@MIT-MC.ARPA>
R: 250 OK
S: RCPT TO:<@USC-ISIE.ARPA:Fonebone@USC-ISIQA.ARPA>
R: 250 OK
S: RCPT TO:<@USC-ISIE.ARPA:XYZ@MIT-AI.ARPA>
R: 250 OK
S: RCPT
TO:<@USC-ISIE.ARPA,@USC-ISIF.ARPA:Q-Smith@ISI-VAXA.ARPA>
R: 250 OK
S: RCPT TO:<@USC-ISIE.ARPA:joe@FOO-UNIX.ARPA>
R: 250 OK
S: RCPT TO:<@USC-ISIE.ARPA:xyz@BAR-UNIX.ARPA>
R: 250 OK
S: RCPT TO:<@USC-ISIE.ARPA:fred@BBN-UNIX.ARPA>
R: 250 OK
S: DATA
R: 354 Start mail input; end with <CRLF>.<CRLF>
S: Blah blah blah...
S: ...etc. etc. etc.
S: .
R: 250 OK
S: QUIT
R: 221 USC-ISIE.ARPA Service closing transmission channel
Scenario 7
-------------------------------------------------------------
Too Many Recipients Scenario
-------------------------------------------------------------
R: 220 BERKELEY.ARPA Simple Mail Transfer Service Ready
S: HELO USC-ISIF.ARPA
R: 250 BERKELEY.ARPA
S: MAIL FROM:<Postel@USC-ISIF.ARPA>
R: 250 OK
S: RCPT TO:<fabry@BERKELEY.ARPA>
R: 250 OK
S: RCPT TO:<eric@BERKELEY.ARPA>
R: 552 Recipient storage full, try again in another transaction
S: DATA
R: 354 Start mail input; end with <CRLF>.<CRLF>
S: Blah blah blah...
S: ...etc. etc. etc.
S: .
R: 250 OK
S: MAIL FROM:<Postel@USC-ISIF.ARPA>
R: 250 OK
S: RCPT TO:<eric@BERKELEY.ARPA>
R: 250 OK
S: DATA
R: 354 Start mail input; end with <CRLF>.<CRLF>
S: Blah blah blah...
S: ...etc. etc. etc.
S: .
R: 250 OK
S: QUIT
R: 221 BERKELEY.ARPA Service closing transmission channel
Scenario 10
-------------------------------------------------------------
Note that a real implementation must handle many recipients as
specified in Section ##4.5.3.
APPENDIX G Other gateway issues.
In general, gateways between the Internet and other mail systems
SHOULD attempt to preserve any layering semantics across the
boundaries between the two mail systems involved. Gateway-
translation approaches that attempt to take shortcuts by
mapping, e.g., envelope information from one system to the
message headers or body of another have generally proven to be
inadequate in important ways. Systems translating between
environments that do not support both envelopes and headers and
Internet mail must be written with the understanding that some
information loss is almost inevitable.
APPENDIX H GLOSSARY
ASCII
American Standard Code for Information Interchange [1].
command
A request for a mail service action sent by the SMTP client to the
SMTP server.
domain
The hierarchially structured global character string address of a
host computer in the mail system. See section ##2.3.
end of mail data indication
A special sequence of characters that indicates the end of the
mail data. In particular, the five characters carriage return,
line feed, period, carriage return, line feed, in that order.
host
A computer in the internetwork environment on which mailboxes or
SMTP processes reside. See section ##2.3.
line
A a sequence of ASCII characters ending with a <CRLF>.
mail data
A sequence of ASCII characters of arbitrary length, which conforms
to the standard set in the Standard for the Format of ARPA
Internet Text Messages (RFC 822 [RFC822]##[MSGFMT]).
mailbox
A character string (address) which identifies a user to whom mail
is to be sent. Mailbox normally consists of the host and user
specifications. The standard mailbox naming convention is defined
to be "user@domain". Additionally, the "container" in which mail
is stored. <<Is this terminology now consistent with the Message
Format document??>>
SMTP server process
A process which transfers mail in cooperation with an SMTP client
process. It waits for a connection to be established via the
transport service. It receives SMTP commands from the
SMTP client, sends replies, and performs the specified operations.
reply
A reply is an acknowledgment (positive or negative) sent from
receiver to sender via the transmission channel in response to a
command. The general form of a reply is a completion code
(including error codes) followed by a text string. The codes are
for use by programs and the text is usually intended for human
users.
SMTP client process
A process which transfers mail in cooperation with an SMTP server
process. A local language may be used in the user interface
command/reply dialogue. The SMTP client initiates the transport
service connection. It initiates SMTP commands, receives replies,
and governs the transfer of mail.
session
The set of exchanges that occur while the transmission channel is
open.
transaction
The set of exchanges required for one message to be transmitted
for one or more recipients.
transmission channel
A full-duplex communication path between an SMTP client and a
SMTP server for the exchange of commands, replies, and mail
text.
transport service
Any reliable stream-oriented data communication services. For
example, TCP.
user
A human being (or a process on behalf of a human being) wishing to
obtain mail transfer service. In addition, a recipient of
computer mail.
word
A sequence of printing characters.
<CRLF>
The characters carriage return and line feed (in that order).
<SP>
The space character.
APPENDIX I: Deprecated features of RFC 821
A few features of RFC 821 have proven to be problematic and should
not be used in Internet mail. These are:
(1) TURN
This command, described in RFC 821, raises important security
issues (described in RFC 1123). Its use is deprecated; SMTP
systems SHOULD NOT use it unless the server can authenticate the
client.
(2) Source routing
RFC 821 utilized the concept of explicit source routing to get mail
from one host to another via a series of relays. The requirement to
utilize source routes in regular mail traffic was eliminated by the
introduction of the domain name system "MX" record and the last
significant justification for them was eliminated by the
introduction, in RFC 1123, of a clear requirement that addresses
following an "@" must all be fully-qualified domain names.
Consequently, the only remaining justifications for the use of source
routes are support for very old SMTP clients or MUAs and in mail system
debugging. They can, however, still be useful in the latter
circumstance and for routing mail around serious, but temporary,
problems such as problems with the relevant DNS records.
SMTP servers MUST continue to accept source route syntax as specified
in the main body of this document and in RFC 1123. They MAY, if
necessary, ignore the routes and utilize only the target domain in
the address. If they do utilize the source route, the message MUST
be sent to the first domain shown in the address. In particular, a
server MUST NOT guess at shortcuts within the source route.
Clients SHOULD NOT utilize explicit source routing except under
unusual circumstances, such as debugging or potentially relaying
around firewall or mail system configuration errors.
(3) HELO
As discussed in sections ##3.1 and ##4.1.1, EHLO is strongly
preferred to HELO when the server will accept the former. Servers
must continue to accept HELO in order to support older clients.
(4) #-literals
RFC 821 provided for specifying an Internet address as a decimal
integer host number prefixed by a pound sign, "#". In practice, that
form has been obsolete since the introduction of TCP/IP. It is
deprecated and MUST NOT be used.
(5) Dates and years
When dates are inserted into messages by SMTP clients or servers
(e.g., in trace fields), four-digit years MUST BE used. Two-digit
years are deprecated; three-digit years were never permitted in the
Internet mail system.
(6) Sending versus mailing
In addition to specifying a mechanism for delivering messages to
user's mailboxes, RFC 821 provided additional, optional, commands to
deliver messages directly to the user's terminal screen.
These commands (SEND, SAML, SOML) were rarely implemented, and
changes in workstation technology and the introduction of other
protocols may have rendered them obsolete even where they are
implemented.
Clients SHOULD NOT provide SEND, SAML, or SOML as services. Servers
MAY implement them. If they are implemented by servers, the
implementation model specified in RFC 821 MUST be used and the
command names MUST be published in the response to the EHLO command.
APPENDIX X: Change summary and Loose ends (temporary)
X.1 Change summary
X.1.1 Substantive changes between draft-ietf-drums-smtpupd-00.txt and
draft-ietf-drums-smtpupd-01.txt
(i) Slightly clarified the discussions of rejection and failure of
VRFY requests and the associated response codes.
(ii) Slightly clarified the discussion of deferred address
validation.
(iii) Removed the IPCE terminology and modified the text in section
##4.1.1.2 to explicitly introduce the "mail gateway" terminology and
to begin to distinguish a mail gateway from a conventional relay.
**Please Review This Text**.
(iv) Explicitly noted that SMTP clients for things like POP and IMAP
may send everything to a single relay for further processing, rather
than resolving final domain names.
(v) Tightened the RSET discussion.
(vi) Deprecation of 251 only for RCPT (still ok for VRFY)
X.1.2. Substantive changes between draft-ietf-drums-smtpupd-01.txt
and draft-ietf-drums-smtpupd-02.txt.
Incorporated additional RFC 1123 material; reorganized several
sections for clarity. Added definitions and other previous "loose
end" material.
X.1.3. Substantive changes between draft-ietf-drums-smtpupd-02.txt
and draft-ietf-drums-smtpupd-03.txt.
(i) Eliminated a number of placeholders and tightened some of the
definitions in section 2. Added a few new placeholders for
consistency checking against other documents.
(ii) Removed the state diagrams, per direction at IETF Montreal.
(iii) Added new section 6.3, an attempt to summarize WG discussions
on the "posting" versus "delivery" versus "relay" functions of SMTP
and on whether "fixups" are appropriate in different cases.
(iv) Inserted section 6.1, a minor rewrite of section 5.3.3 of
RFC1123.
(v) Added new text to 3.5.5 to discuss the spammer - EXPN
relationship.
(vi) The "ASCII requirement" in 4.1.1.4 has been tightened somewhat.
(v) The remaining miscellaneous changes agreed to in Montreal have
been incorporated except as noted below.
X.2 Loose ends
(i) Material in RFC1123, section 5.2.6, not yet fully incorporated.
(ii) Is 5.3.4 of RFC1123 adequately incorporated?
(iii) What needs to be done about RFC1123 5.3.6 and 5.3.7 and where
should it/they go?
(iv) The 822 BNF -> ABNF transition is not yet complete, and most of
what has been done needs checking.
(v) Example not yet revised, overview and grammer still to be merged.
See also Chris Newman's "Drums open issues" list.
Datatracker
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draft-ietf-drums-smtpupd-03
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