Network Working Group G. Vaudreuil
Request for Comments: 1911 Octel Network Services
Category: Experimental February 1996
Voice Profile for Internet Mail
Status of this Memo
This memo defines an Experimental Protocol for the Internet
community. This memo does not specify an Internet standard of any
kind. Discussion and suggestions for improvement are requested.
Distribution of this memo is unlimited.
1. Abstract
A class of special-purpose computers has evolved to provide voice
messaging services. These machines generally interface to a
telephone switch and provide call answering and voice messaging
services. Traditionally, messages sent to a non-local machine are
transported using analog networking protocols based on DTMF signaling
and analog voice playback. As the demand for networking increases,
there is a need for a standard high-quality digital protocol to
connect these machines. The following document is a profile of the
Internet standard MIME and ESMTP protocols for use as a digital voice
networking protocol.
This profile is based on an earlier effort in the Audio Message
Interchange Specification (AMIS) group to define a voice messaging
protocol based on X.400 technology. This protocol is intended to
satisfy the user requirements statement from that earlier work with
the industry standard ESMTP/MIME mail protocol infrastructures
already used within corporate internets. This profile will be called
the voice profile in this document.
2. Scope and Design Goals
MIME is the Internet multipurpose, multimedia messaging standard.
This document explicitly recognizes its capabilities and provides a
mechanism for the exchange of various messaging technologies
including voice and facsimile.
This document specifies a profile of the TCP/IP multimedia messaging
protocols for use by special-purpose voice processing platforms.
These platforms have historically been special-purpose computers and
often do not have facilities normally associated with a traditional
Internet Email-capable computer. This profile is intended to specify
the minimum common set of features and functionally for conformant
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systems.
The voice profile does not place limits on the use of additional
media types or protocol options. However, systems which are
conformant to this profile should not send messages with features
beyond this profile unless explicit per-destination configuration of
these enhanced features is provided. Such configuration information
could be stored in a directory, though the implementation of this is
a local matter.
The following are typical limitations of voice messaging platform
which were considered in creating this baseline profile.
1) Text messages are not normally received and often cannot be
displayed or viewed. They can often be processed only via
advanced text-to-speech or text-to-fax features not currently
present in these machines.
2) Voice mail machines usually act as an integrated Message
Transfer Agent and a User Agent. The voice mail machine is
responsible for final delivery, and there is no relaying of
messages. RFC 822 header fields may have limited use in the
context of the simple messaging features currently deployed.
3) VM message stores are generally not capable of preserving the
full semantics of an Internet message. As such, use of a voice
mail machine for general message forwarding and gatewaying is not
supported. Storage of "Received" lines and "Message-ID" may be
limited.
4) Nothing in this document precludes use of a general purpose
email gateway from providing these services. However, significant
performance degradation may result if the email gateway does not
support the ESMTP options recommended by this document.
5) Internet-style mailing lists are not generally supported.
Distribution lists are implemented as local alias lists.
6) There is generally no human operator. Error reports must be
machine-parsable so that helpful responses can be given to users
whose only access mechanism is a telephone.
7) The system user names are often limited to 16 or fewer numeric
characters. Alpha characters are not generally used for mailbox
identification as they cannot be easily entered from a telephone
terminal.
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It is a goal of this effort to make as few restrictions and additions
to the existing Internet mail protocols as possible while satisfying
the user requirements for interoperability with current voice
messaging systems. This goal is motivated by the desire to increase
the accessibility to digital messaging by enabling the use of proven
existing networking software for rapid development.
This specification is intended for use on a TCP/IP network, however,
it is possible to use the SMTP protocol suite over other transport
protocols. The necessary protocol parameters for such use is outside
the scope of this document.
This profile is intended to be robust enough to be used in an
environment such as the global Internet with installed base gateways
which do not understand MIME. It is expected that a messaging system
will be managed by a system administrator who can perform TCP/IP
network configuration. When using facsimile or multiple voice
encodings, it is expected that the system administrator will maintain
a list of the capabilities of the networked mail machines to reduce
the sending of undeliverable messages due to lack of feature support.
Configuration, implementation and management of this directory
listing capabilities is a local matter.
This specification is a profile of the relevant TCP/IP Internet
protocols. These technologies, as well as the specifications for the
Internet mail protocols, are defined in the Request for Comment (RFC)
document series. That series documents the standards as well as the
lore of the TCP/IP protocol suite. This document should be read with
the following RFC documents: RFC 821, Simple Mail Transfer Protocol;
RFC 822, Standard for the format of ARPA Internet Messages; RFC 1521
and RFC 1522, Multipurpose Internet Mail Extensions; RFC 1651, RFC
1652, and RFC 1653, SMTP Service Extensions (ESMTP); and RFC 1034 and
RFC 1035, Domain Name System. Where additional functionality is
needed, it will be defined in this document or in an appendix.
3. Protocol Restrictions
This protocol does not limit the number of recipients per message.
Where possible, implementations should not restrict the number of
recipients in a single message. It is recognized that no
implementation supports unlimited recipients, and that the number of
supported recipients may be quite low. However, ESMTP currently does
not provide a mechanism for indicating the number of supported
recipients.
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This protocol does not limit the maximum message length.
Implementors should understand that some machines will be unable to
accept excessively long messages. A mechanism is defined in the RFC
1425 ESMTP extensions to declare the maximum message size supported.
The message size indicated in the ESMTP SIZE command is in bytes, not
minutes. The number of bytes varies by voice encoding format and
must include the MIME wrapper overhead. If the length must be known
before sending, an approximate translation into minutes can be
performed if the voice encoding is known.
4. Voice Message Interexchange Format
The voice message interchange format is a profile of the Internet
Email Protocol Suite. It requires components from the message format
standard for Internet messages [RFC822], the Multipurpose Internet
Message Extensions [MIME], the X.400 gateway specification [X.400],
and the delivery report specifications [DRPT][STATUS].
4.1 Message Addressing Formats
The RFC 822 uses the domain name system. This naming system has two
components: the local part, used for username or mailbox
identification; and the host part, used for global machine
identification.
The local part of the address shall be an ASCII string uniquely
identifying a mailbox on a destination system. For voice messaging,
the local part is a printable string containing the mailbox ID of the
originator or recipient. Administration of this space is expected to
conform to national or corporate private telephone numbering plans.
While alpha characters and long mailbox identifiers are permitted,
most voice mail networks rely on numeric mailbox identifiers to
retain compatibility with the limited 10 digit telephone keypad.
For example, a compliant message may contain the address
[email protected]. It should be noted that while the example
mailbox address is based on the North American Numbering Plan, any
other corporate numbering plan can be used. The use of the domain
naming system should be transparent to the user. It is the
responsibility of the voice mail machine to lookup the fully-
qualified domain name (FQDN) based on the address entered by the
user. The mapping of dialed address to final destination system is
generally accomplished through implementation-specific means.
Special addresses are provided for compatibility with the conventions
of the Internet mail system and to facilitate testing. These
addresses do not use numeric local addresses, both to conform to
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current Internet practice and to avoid conflict with existing numeric
addressing plans. Some special addresses are as follows:
Postmaster@domain
By convention, a special mailbox named "postmaster" MUST exist on all
systems. This address is used for diagnostics and should be checked
regularly by the system manager. This mailbox is particularly likely
to receive text messages, which is not normal on a voice processing
platform; the specific handling of these messages is a individual
implementation choice.
Loopback@domain
A special mailbox name named "loopback" SHOULD be designated for
loopback testing. If supported, all messages sent to this mailbox
MUST be returned back to the address listed in the From: address as a
new message. The originating address of the returned address MUST be
"postmaster" to prevent mail loops.
These two addresses are RESERVED so they do not conflict with any
internal addressing plan.
4.2 Message Header Fields
Internet messages contain a header information block. This header
block contains information required to identify the sender, the list
of recipients, the message send time, and other information intended
for user presentation. Except for specialized gateway and mailing
list cases, headers do not indicate delivery options for the
transport of messages.
The following header lines are permitted for use with voice messages.
From
The originator's fully-qualified domain address (a mailbox address
followed by the fully-qualified domain name). The user listed in
this field should be presented in the voice message envelope as the
originator of the message.
Systems conformant to this profile SHOULD provide the text personal
name of the sender in a quoted phrase if available. To facilitate
storage of the text name in a local dial-by-name cache directory, the
first and last name MUST be separable. Text names in voice messages
MUST be represented in the form "last, first, mi." [822].
The TO header contains the recipient's fully-qualified domain
address. There may be one or more To: fields in any message.
Systems conformant to this profile SHOULD provide the text personal
name of the recipient, if known, in a quoted phrase. The name MUST
be in the form "last, first, mi." [822].
The CC header contains additional recipients' fully-qualified domain
addresses. Many voice mail systems are not capable of storing or
reporting the full list of recipients to the receiver.
Systems conformant to this profile SHOULD provide the text personal
name of the recipient, if known, in a quoted phrase. The name MUST
be in the form "last, first, mi." [822].
Systems conformant to this profile may discard the CC list of
incoming messages as necessary. Systems conformant to this profile
should provide a complete list of recipients when possible.
Date
The Date header contains the date, time, and time zone in which the
message was sent by the originator. Conforming implementations
SHOULD be able to convert RFC 822 date and time stamps into local
time.
Example:
Date: Wed, 28 Jul 93 10:08:49 PST
The sending system MUST report the time the message was sent [822].
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Sender
The Sender header contains the actual address of the originator if
the message is sent by an agent on behalf of the author indicated in
the From: field. Support for this field cannot be assumed when
talking to a voice system and SHOULD NOT be generated by a conforming
implementation.
While it may not be possible to save this information in some voice
mail machines, discarding this information or the ESMTP MAIL FROM
address will make it difficult to send an error message to the proper
destination [822].
Message-id
The Message-id header contains a unique per-message identifier. A
unique message-id MUST be generated for each message sent from a
conforming implementation.
The message-id is not required to be stored on the receiving system.
This identifier MAY be used for tracking, auditing, and returning
read-receipt reports [822].
The Received header contains trace information added to the beginning
of a RFC 822 message by message transport agents (MTA). This is the
only header permitted to be added by an MTA. Information in this
header is useful for debugging when using an ASCII message reader or
a header parsing tool.
A conforming system MUST add Received headers when acting as a
gateway and must not remove them. These headers MAY be ignored or
deleted when the message is received at the final destination [822].
MIME Version
The MIME-Version header indicates that the message is conformant to
the MIME message format specification. Systems conformant to the
voice messaging profile MUST include a comment with the words "(Voice
1.0)" [MIME].
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Example:
MIME-Version: 1.0 (Voice 1.0)
Content-Type
The content-type header declares the type of content enclosed in the
message. One of the allowable contents is multipart, a mechanism for
bundling several message components into a single message. The
allowable contents are specified in the next section of this document
[MIME].
Content-Transfer-Encoding
Because Internet mail was initially specified to carry only 7-bit
US-ASCII text, it may be necessary to encode voice and fax data into
a representation suitable for that environment. The content-
transfer-encoding header describes this transformation if it is
needed. Conformant implementations MUST recognize and decode the
standard encodings, "Binary", "7bit, "8bit", "Base-64" and "Quoted-
Printable". The allowable content-transfer-encodings are specified
in the next section of this document [MIME].
Sensitivity
The sensitivity header, if present, indicates the requested privacy
level. The case-insensitive values "Personal" and "Private" are
specified. If no privacy is requested, this field is omitted.
If a sensitivity header is present in the message, a conformant
system MUST prohibit the recipient from forwarding this message to
any other user. If the receiving system does not support privacy and
the sensitivity is one of "Personal" or "Private", the message MUST
be returned to the sender with an appropriate error code indicating
that privacy could not be assured and that the message was not
delivered [X400].
Importance
Indicates the requested priority to be given by the receiving system.
The case-insensitive values "low", "normal" and "high" are specified.
If no special importance is requested, this header may be omitted and
the value assumed to be "normal".
Conformant implementations MAY use this header to indicate the
importance of a message and may order messages in a recipient's
mailbox [X400].
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Subject
The subject field is often provided by email systems but is not
widely supported on Voice Mail platforms. This field MAY be generated
by a conforming implementation and may be discarded if present by a
receiving system [822].
4.3 Message Content Types
MIME is a general-purpose message body format that is extensible to
carry a wide range of body parts. The basic protocol is described in
[MIME]. MIME also provides for encoding binary data so that it can
be transported over the 7-bit text-oriented SMTP protocol. This
transport encoding is independent of the audio encoding designed to
generate a binary object.
MIME defines two transport encoding mechanisms to transform binary
data into a 7 bit representation, one designed for text-like data
("Quoted-Printable"), and one for arbitrary binary data ("Base-64").
While Base-64 is dramatically more efficient for audio data, both
will work. Where binary transport is available, no transport
encoding is needed, and the data can be labeled as "Binary".
An implementation in conformance with this profile SHOULD send audio
data in binary form when binary message transport is available. When
binary transport is not available, implementations MUST encode the
message as Base-64. The detection and decoding of "Quoted-
Printable", "7bit", and "8bit" MUST be supported in order to meet
MIME requirements and to preserve interoperability with the fullest
range of possible devices.
The following content types are identified for use with this profile.
Note that each of these contents can be sent individually in a
message or wrapped in a multipart message to send multi-segment
messages.
Message/RFC822
MIME requires support of the Message/RFC822 message encapsulation
body part. This body part is used in the Internet to forward
complete messages within a multipart/mixed message. Processing of
this body part entails trivial processing to decapsulate/encapsulate
the message. Systems conformant to this profile SHOULD NOT send this
body part but MUST accept if in conformance with basic MIME.
Specific handling depends on the platform, and interpretation of this
content-type is left as an implementation decision [MIME].
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Text/Plain
MIME requires support of the basic Text/Plain content type. This
content type has no applicability within the voice messaging
environment. Conformant implementations MUST NOT send the Text/Plain
content-type. Conformant implementations MUST accept Text/Plain
messages, however, specific handling is left as an implementation
decision. One option is to return the message to the sender with a
media-unsupported error code [MIME].
Multipart/Mixed
MIME provides the facilities for enclosing several body parts in a
single message. Multipart/Mixed MAY be used for sending multi-segment
voice messages, that is, to preserve across the network the
distinction between an annotation and a forwarded message.
Conformant systems MUST accept multipart/mixed body parts. Systems
MAY to collapse such a multi-segment message into a single segment if
multi-segment messages are not supported on the receiving machine
[MIME].
Message/Notification
This MIME body part is used for sending machine-parsable delivery
status notifications. Conformant implementations must use the
Message/Notification construct when returning messages or sending
warnings. Conformant implementations must recognize and decode the
Message/Notification content type and present the reason for failure
to the user [NOTIFY].
Multipart/Report
The Multipart/Report is used for enclosing a Message/Notification
body part and any returned message content. This body type is a
companion to Message/Notification. Conformant implementations must
use the Multipart/Report construct when returning messages or sending
warnings. Conformant implementations must recognize and decode the
Multipart/Report content type [REPORT].
Audio/32KADPCM
CCITT Recommendation G.721 [G721] describes the algorithm recommended
for conversion of a 64 KB/s A-law or u-law PCM channel to and from a
32 KB/s channel. The conversion is applied to the PCM stream using
an Adaptive Differential Pulse Code Modulation (ADPCM) transcoding
technique. This algorithm will be registered with the IANA for MIME
use under the name Audio/32KADPCM.
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An implementation conformant to this profile MUST use Audio/32KADPCM
by default.
Proprietary Voice Formats
Proprietary voice encoding formats or other standard formats may be
supported under this profile provided a unique identifier is
registered with the IANA prior to use. These encodings should be
registered as sub-types of Audio.
Use of any other encoding except Audio/32KADPCM reduces
interoperability in the absence of explicit manual system
configuration. A conformant implementation MAY use any other
encoding with explicit per-destination configuration.
Multipart/Voice-Message
This new MIME multipart structure provides a mechanism for packaging
the senders spoken name, a spoken subject and, the message. The
multipart provides for the packaging of three segments, the first is
the spoken name, the second is a spoken subject, and the third is the
message itself. Forwarded messages can be created by simply nesting
multipart content-types (this is also possible with Multipart/Mixed
if spoken name or spoken subject is not present). This type is
defined in an appendix to this document.
Conforming implementations MUST send the Multipart/Voice-Message if a
spoken name or spoken subject is available. Conforming
implementations SHOULD recognize the Multipart/Voice-Message and
separate the spoken name or spoken subject.
5. Message Transport Protocol
Messages are transported between voice mail machines using the
Internet Extended Simple Mail Transfer Protocol (ESMTP). All
information required for proper delivery of the message is included
in the ESMTP dialog. This information, including the sender and
recipient addresses, is commonly referred to as the message
"envelope". This information is equivalent to the message control
block in many analog voice networking protocols.
ESMTP is a general-purpose messaging protocol, designed both to send
mail and to allow terminal console messaging. Simple Mail Transport
Protocol (SMTP) was originally created for the exchange of US-ASCII
7-bit text messages. Binary and 8-bit text messages have
traditionally been transported by encoding the messages into a 7-bit
text-like form. [ESMTP] was recently published and formalized an
extension mechanism for SMTP, and subsequent RFCs have defined 8-bit
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text networking, binary networking, and extensions to permit the
declaration of message size for the efficient transmission of large
messages such as multi-minute voice mail.
A command streaming extension for high performance message
transmission has been defined [PIPE]. This extension reduces the
number of round-trip packet exchanges and makes it possible to
validate all recipient addresses in one operation. This extension is
optional but recommended.
The following sections list ESMTP commands, keywords, and parameters
that are required and those that are optional.
5.1 ESMTP Commands
HELO
Base SMTP greeting and identification of sender. This command is not
to be sent by conforming systems unless the more-capable EHLO command
is not accepted. It is included for compatibility with general SMTP
implementations. Conforming implementations MUST implement the HELO
command for backward compatibility but SHOULD NOT send it unless EHLO
is not supported [SMTP].
MAIL FROM (REQUIRED)
Originating mailbox. This address contains the mailbox to which
errors should be sent. This address may not be the same as the
message sender listed in the message header fields if the message was
received from a gateway or sent to an Internet-style mailing list.
Conforming implementations MUST implement the extended MAIL FROM
command [SMTP, ESMTP].
RCPT TO
Recipient's mailbox. This field contains only the addresses to which
the message should be delivered for this transaction. In the event
that multiple transport connections to multiple destination machines
are required for the same message, this list may not match the list
of recipients in the message header. Conforming implementations MUST
implement the extended RCPT TO command [SMTP, ESMTP].
DATA
Initiates the transfer of message data. Support for this command is
required in the event the binary mode command BDAT is not supported
by the remote system. Conforming implementations MUST implement the
SMTP DATA command for backwards compatibility [SMTP].
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TURN
Requests a change-of-roles, that is, the client that opened the
connection offers to assume the role of server for any mail the
remote machine may wish to send. Because SMTP is not an
authenticated protocol, the TURN command presents an opportunity to
improperly fetch mail queued for another destination. Conforming
implementations SHOULD NOT implement the TURN command [SMTP].
QUIT
Requests that the connection be closed. If accepted, the remote
machine will reset and close the connection. Conforming
implementations MUST implement the QUIT command [SMTP].
RSET
Resets the connection to its initial state. Conforming
implementations MUST implement the RSET command [SMTP].
VRFY
Requests verification that this node can reach the listed recipient.
While this functionality is also included in the RCPT TO command,
VRFY allows the query without beginning a mail transfer transaction.
This command is useful for debugging and tracing problems.
Conforming implementations MAY implement the VRFY command [SMTP].
(Note that the implementation of VRFY may simplify the guessing of a
recipient's mailbox or automated sweeps for valid mailbox addresses,
resulting in a possible reduction in privacy. Various implementation
techniques may be used to reduce the threat, such as limiting the
number of queries per session [SMTP].)
EHLO
The enhanced mail greeting that enables a server to announce support
for extended messaging options. The extended messaging modes are
discussed in a later section of this document. Conformant
implementations MUST implement the ESMTP command and return the
capabilities indicated later in this memo [ESMTP].
BDAT
The BDAT command provides a higher efficiency alternative to the
earlier DATA command, especially for voice. The BDAT command provides
for native binary transport. Because voice messages are large binary
objects otherwise subject to BASE-64 encoding, BDAT will result in a
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substantial improvement in transmission efficiency over DATA.
Conformant implementations SHOULD support binary transport using the
BDAT command [BINARY].
5.2 ESMTP Capabilities
The following ESMTP keywords indicate extended features useful for
voice messaging.
PIPELINING
The "PIPELINING" keyword indicates ability of the receiving SMTP to
accept pipelined commands. Pipelining commands dramatically improves
the protocol performance over wide area networks. Conformant
implementations SHOULD support the command pipelining indicated by
this parameter [PIPE].
SIZE
The "SIZE" keyword provides a mechanism by which the receiving SMTP
can indicate the maximum size message supported. Conformant
implementations MUST provide the size capability and SHOULD honor any
size limitations when sending [SIZE].
CHUNKING
The "CHUNKING" keyword indicates that the receiver will support the
high-performance binary transport mode. Note that CHUNKING can be
used with any message format and does not imply support for binary
encoded messages. Conformant implementations SHOULD support binary
transport indicated by this capability [BINARY].
BINARYMIME
The "BINARYMIME" keyword indicates that the receiver SMTP can accept
binary encoded MIME messages. Conformant implementations should
support binary transport indicated by this capability [BINARY].
NOTIFY
The "NOTIFY" keyword indicates that the receiver SMTP will accept
explicit delivery status notification requests. Conformant
implementations MUST support the delivery notification extensions in
[DSN].
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5.3 ESMTP Parameters - MAIL FROM
BINARYMIME
The current message is a binary encoded MIME messages. Conformant
implementations SHOULD support binary transport indicated by this
parameter [BINARY].
5.4 ESMTP Parameters - RCPT TO
NOTIFY
The NOTIFY parameter indicates the conditions under which a delivery
report SHOULD be sent. Conformant implementations must honor this
request [DSN].
RET
The RET parameter indicates whether the content of the message should
be returned. Conformant systems SHOULD honor a request for returned
content [DSN].
6. Management Protocols
The Internet protocols provide a mechanism for the management of
messaging systems, from the management of the physical network
through the management of the message queues. SNMP should be
supported on a compliant message machine.
6.1 Network Management
The digital interface to the VM and the TCP/IP protocols SHOULD be
managed. MIB II SHOULD be implemented to provide basic statistics
and reporting of TCP and IP protocol performance [MIB II].
6.2 Directory and Message Management
Conformant systems SHOULD provide for the management of message
traffic and queue monitoring based on the Message and Directory MIB
[MADMAN].
7. References
[MIME] Borenstein, N., and N. Freed, "Multipurpose Internet Mail
Extensions", RFC 1521, Bellcore, Innosoft, September 1993.
[MSG822] Crocker, D., "Standard for the Format of ARPA Internet Text
Messages", STD 11, RFC 822, UDEL, August 1982.
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[X400] Hardcastle-Kille, S., "Mapping between X.400(1988) / ISO
10021 and RFC 822", RFC 1327, UCL, May 1992.
[PIPE] Freed, N., and A. Cargille, "SMTP Service Extension for
Command Pipelining", RFC 1854, October 1995.
[ESMTP] Klensin, J., Freed, N., Rose, M., Stefferud, E., and D.
Crocker, "SMTP Service Extensions", RFC 1869, United Nations
University, Innosoft International, Inc., Dover Beach
Consulting, Inc., Network Management Associates, Inc., The
Branch Office, November 1995.
[SIZE] Klensin, J, Freed, N., Moore, K, "SMTP Service Extensions for
Message Size Declaration", RFC 1870, United Nations
University, Innosoft International, Inc., November 1995.
[8BIT] Klensin, J., Freed, N., Rose, M., Stefferud, E., D. Crocker,
"SMTP Service Extension for 8bit-MIMEtransport", RFC 1426,
United Nations University, Innosoft International, Inc.,
Dover Beach Consulting, Inc., Network Management Associates,
Inc., The Branch Office, February 1993.
[DNS1] Mockapetris, P., "Domain Names - Implementation and
Specification", STD 13, RFC 1035, USC/Information Sciences
Institute, November 1987.
[DNS2] Mockapetris, P., "Domain Names - Concepts and Facilities",
STD 13, RFC 1034, USC/Information Sciences Institute,
November 1987.
[SMTP] Postel, J., "Simple Mail Transfer Protocol", STD 10, RFC 821,
USC/Information Sciences Institute, August 1982.
[BINARY] Vaudreuil, G., "SMTP Service Extensions for Transmission of
Large and Binary MIME Messages", RFC 1830, Octel Network
Services, October 1995.
[NOTIFY] Moore, K., and G. Vaudreuil, "An Extensible Message
Format for Delivery Status Notifications", RFC 1894,
University of Tennessee, Octel Network Services, January
1996.
[REPORT] Vaudreuil, G., "The Multipart/Report Content Type for the
Reporting of Mail System Administrative Messages", RFC
1892, Octel Network Services, January 1996.
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[DSN] Moore, K., "SMTP Service Extensions for Delivery Status
Notifications", RFC 1891, University of Tennessee, January
1996.
[G721] CCITT Recommendation G.700-G.795 (1988), General Aspects of
Digital Transmission Systems, Terminal Equipment. Blue Book.
[MADMAN] Freed, N., and S. Kille, "Mail Monitoring MIB", RFC 1566,
January 1994.
[MIB II] Rose, M., "Management Information Base for Network
Management of TCP/IP-based internets: MIB-II", RFC 1158,
May 1990.
8. Security Consideration
This document is a profile of existing Internet mail protocols. As
such, it does not create any security issues not already existing in
the profiled Internet mail protocols themselves.
9. Acknowledgments
The author would like to offer special thanks to Glenn Parsons/BNR
for his extensive review, helpful suggestions, and extensive editing
including the requirements matrix.
1. If a sensitive message is received by a system that does not
support sensitivity, then it must be returned to the originator
with an appropriate error notification.
2. When binary transport is not available
3. When binary transport is available
12. Appendix - Example Voice Message
The following message is a full-featured, all-options-enabled message
addressed to two recipients. The message includes the sender's spoken
name and a short speech segment. The message is marked as important
and private.
To: [email protected]
To: "Parsons, Glenn, W." [email protected]
From: "Vaudreuil, Greg" [email protected]
Date: Mon, 26 Aug 93 10:20:20 CST
MIME-Version: 1.0 (Voice 1.0)
Content-type: Multipart/Voice-Message; Boundary = "MessageBoundary"
Content-Transfer-Encoding: 7bit
Message-ID: VM2.mycompany.com-123456789
Sensitivity: Private
Importance: High
glslfdslsertiflkTfpgkTportrpkTpfgTpoiTpdadasssdasddasdasd
(This is a sample of the base-64 Spoken Name data) fgdhgd
jrgoij3o45itj09fiuvdkjgWlakgQ93ijkpokfpgokQ90gQ5tkjpokfgW
dlkgpokpeowrit09==
glslfdslsertiflkTfpgkTportrpkTpfgTpoiTpdadasssdasddasdasd
(This is a sample of the base-64 Spoken Subject data) fgdhgd
jrgoij3o45itj09fiuvdkjgWlakgQ93ijkpokfpgokQ90gQ5tkjpokfgW
dlkgpokpeowrit09==
glslfdslsertiflkTfpgkTportrpkTpfgTpoiTpdadasssdasddasdasd
(This is a sample of the base-64 message data) fgdhgdfwgd
jrgoij3o45itj09fiuvdkjgWlakgQ93ijkpokfpgokQ90gQ5tkjpokfgW
dlkgpokpeowrit09==
--MessageBoundary--
13. Appendix - Audio/32KADPCM Content Type
Mime type name: Audio
Mime Sub-Type name: 32KADPCM
Required Parameters: None
Optional Parameters: None
Encoding Considerations: Any encoding necessary for transport may be
used.
CCITT Recommendation G.721 [G721] describes the algorithm recommended
for conversion of a 64 KB/s A-law or u-law PCM channel to and from a
32 KB/s channel. The conversion is applied to the PCM stream using
an Adaptive Differential Pulse Code Modulation (ADPCM) transcoding
technique.
No header information shall be included before the audio data. When
this subtype is present, a sample rate of 8000 Hz and a single
channel is assumed.
Vaudreuil Experimental [Page 21]
RFC 1911 MIME Voice Profile February 1996
14. Appendix - Multipart/Voice-Message
Mime type name: Multipart
Mime Sub-Type name: Voice-Message
Required Parameters: Boundary
Optional Parameters: None
Encoding Considerations: Binary of 7 bit are sufficient. Base-64
and Quoted-Printable are prohibited on multipart content-types.
The syntax of a Multipart/Voice-Message is identical to the
Multipart/Mixed content type. The Voice-Message content-type
contains three body parts. The first is an audio segment containing
the spoken name of the originator, the second is an audio segment
containing a spoken subject, and the third is the voice message
itself. Forwarded voice messages can be created by simply nesting
multipart content types.
The spoken name segment shall contain the name of the message sender
in the voice of the sender. The length of the spoken name segment
must not exceed 12 seconds. If no spoken name is available, the
segment must still be present but may be empty.
The spoken subject segment shall contain the subject of the message
sender in the voice of the sender. The length of the spoken subject
segment must not exceed 20 seconds. If no spoken subject segment is
available, the segment must still be present but may be empty.
The voice message body part may contain any arbitrary content
including a multipart/mixed collections of body parts, though will
typically be an audio segment.
The default handling of the Multipart/Voice-Message shall be to voice
the spoken-name segment and then the spoken-subject prior to
displaying or voicing the remainder of the message.
