Network Working Group
Request for Comments: 3965
Obsoletes: 2305
Category: Standards Track
K. Toyoda
H. Ohno
J. Murai
WIDE Project
D. Wing
December 2004

A Simple Mode of Facsimile Using Internet Mail

Status of this Memo

This document specifies an Internet standards track protocol for the Internet community, and requests discussion and suggestions for improvements. Please refer to the current edition of the "Internet Official Protocol Standards" (STD 1) for the standardization state and status of this protocol. Distribution of this memo is unlimited.

Copyright Notice

Copyright © The Internet Society (2004).


This specification provides for "simple mode" carriage of facsimile data using Internet mail. Extensions to this document will follow. The current specification employs standard protocols and file formats such as TCP/IP, Internet mail protocols, Multipurpose Internet Mail Extensions (MIME), and Tagged Image File Format (TIFF) for Facsimile. It can send images not only to other Internet-aware facsimile devices but also to Internet-native systems, such as PCs with common email readers which can handle MIME mail and TIFF for Facsimile data. The specification facilitates communication among existing facsimile devices, Internet mail agents, and the gateways which connect them.

This document is a revision of RFC 2305. There have been no technical changes.

1. Introduction

This specification defines message-based facsimile communication over the Internet. It describes a minimum set of capabilities, taking into account those of typical facsimile devices and PCs that can generate facsimile data.

A G3Fax device has substantial restrictions due to specifications in the standards, such as for timers. This specification defines a profile for Internet mail, rather than creating a distinct "facsimile over the Internet" service. The semantics resulting from the profile are designed to be compatible with facsimile operation over the general switched telephone network, so that gateways between facsimile and Internet mail can operate with very high fidelity.

The reason for developing this capability as an email profile is to permit interworking amongst facsimile and email users. For example, it is intended that existing email users be able to send normal messages to lists of users, including facsimile-based recipients, and that other email recipients shall be able to reply to the original and continue to include facsimile recipients. Similarly, it is intended that existing email software work without modification and not be required to process new, or different data structures, beyond what is normal for Internet mail users. Existing email service standards are used, rather than replicating mechanisms which are more tailored to existing facsimile standards, to ensure this compatibility with existing email service.

1.1. Services

   A facsimile-capable device that uses T.4 [15] and the general
   switched telephone network (GSTN) is called a "G3Fax device" in this
   specification.  An "IFax device" is an Internet-accessible device
   capable of sending, receiving or forwarding Internet faxes.  A
   message can be sent to an IFax device using  an Internet mail
   address.  A message can be sent to a G3Fax device  using an Internet
   mail address; the message MAY be forwarded via an IFax offramp

1.2. Cases

This specification provides for communication between each of the following combinations:

   Internet mail             =>  Network printer
   Internet mail             =>  Offramp gateway (forward to
   Network scanner           =>  Network printer
   Network scanner           =>  Offramp gateway (forward to
   Network scanner           =>  Internet mail

1.3. Key Words

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   document are to be interpreted as described in [13].

2. Communication Protocols

The set of conventions necessary to achieve facsimile-compatible service covers basic data transport, document data formats, message (document) addressing, delivery confirmation, and message security. In this section, the first 4 are covered. The remainder are covered in following sections, along with additional details for addressing and formats.

2.1. Transport

This section describes mechanisms involved in the transport between IFAX devices.

2.1.1. Relay

Data transfer MAY be achieved using standard Internet mail transfer mechanisms [1, 3]. The format of addresses MUST conform to the RFC 821 <addr-spec> and RFC 822 <mailbox> Internet mail standards [1, 2, 3].

2.1.2. Gateway

A gateway translates between dissimilar environments. For IFax, a gateway connects between Internet mail and the T.4/GSTN facsimile. Gateways can service multiple T.4/GSTN facsimile users or can service only one. In the former case, they serve as a classic "mail transfer agent" (MTA) and in the latter as a classic "mail user agent" (UA). An onramp is a gateway which connects from T.4/GSTN facsimile to Internet mail. An offramp is a gateway which connects from Internet mail to T.4/GSTN facsimile. Behavior of onramps is out of scope for this specification.

This specification describes the Internet mail service portion of offramp addressing, confirmation and failure notification. Details are provided in later sections.

2.1.3. Mailbox protocols

An offramp gateway that operate as an MTA serving multiple users SHOULD use SMTP; a gateway that operates as a UA serving a single mail recipient MAY use a mailbox access protocol such as POP [6] or similar mailbox access protocols.

NOTE: An offramp gateway that relays mail based on addressing information needs to ensure that it uses addresses supplied in the MTA envelope, rather than from elsewhere, such as addresses listed in the message content headers.

2.2. Formats

2.2.1. Headers

IFax devices MUST be compliant with RFC 2822 and RFC 1123, which define the format of mail headers. The header of an IFax message SHOULD include Message-ID and MUST include all fields required by [2, 3], such as DATE and FROM.

2.2.2. MIME

IFax devices MUST be compliant with MIME [4], except as noted in Appendix A.

2.2.3. Content

   The data format of the facsimile image is based on the minimum set of
   TIFF for Facsimile [5], also known as the S profile.   Such facsimile
   data are included in a MIME object by use of the image/TIFF sub-type
   [12].  Additional rules for the use of TIFF for Facsimile, for the
   message-based Internet facsimile application, are defined later.

2.2.4. Multipart

A single multi-page document SHOULD be sent as a single multi- page TIFF file, even though recipients MUST process multipart/mixed containing multiple TIFF files. If multipart content is present and processing of any part fails, then processing for the entire message is treated as failing, per [Processing failure] below.

2.3. Error Handling

2.3.1. Delivery failure

This section describes existing requirements for Internet mail, rather than indicating special requirements for IFax devices.

In the event of relay failure, the sending relay MUST generate a failure message, which SHOULD be in the format of a DSN [9].

   NOTE:  Internet mail transported via SMTP MUST contain a MAIL FROM
          address appropriate for delivery of return notices.  (See
          section 5.2.6.)

2.3.2. Processing Failure

IFax devices with limited capabilities might be unable to process the content of a message. If this occurs it is important to ensure that the message is not lost without any notice. Notice MAY be provided in any appropriate fashion, and the exact handling is a local matter. (See Appendix A, second bullet.)

3. Addressing

3.1. Classic Email Destinations

Messages being sent to normal Internet mail recipients will use standard Internet mail addresses, without additional constraints.

3.2. G3Fax Devices

G3Fax devices are accessed via an IFAX offramp gateway, which performs any authorized telephone dial-up.

3.3. Address Formats Used by Offramps

When a G3Fax device is identified by a telephone number, the entire address used for the G3fax device, including the number and offramp host reference MUST be contained within standard Internet mail transport fields, such as RCPT TO and MAIL FROM [1, 3]. The address MAY be contained within message content fields, such as <authentic> and <destination> [2, 3], as appropriate.

As for all Internet mail addresses, the left-hand-side (local-part) of an address is not to be interpreted except by the MTA that is named on the right-hand-side (domain).

The telephone number format SHOULD conform to [7, 8]. Other formats MUST be syntactically distinct from [7, 8].

4. Image File Format

Sending IFax devices MUST be able to write minimum set TIFF files, per the rules for creating minimum set TIFF files defined in TIFF for Facsimile (the S profile) [5], which is also compatible with the specification for the minimum subset of TIFF-F in [14]. Receiving IFax devices MUST be able to read minimum set TIFF files.

A sender SHOULD NOT use TIFF fields and values beyond the minimum subset of TIFF for Facsimile unless the sender has prior knowledge of other TIFF fields or values supported by the recipient. The mechanism for determining capabilities of recipients is beyond the scope of this document.

5. Security Considerations

5.1. General Directive

This specification is based on use of existing Internet mail. To maintain interoperability with Internet mail, any security to be provided should be part of the of the Internet security infrastructure, rather than a new mechanism or some other mechanism outside of the Internet infrastructure.

5.2. Threats and Problems

Both Internet mail and G3Fax standards and operational services have their own set of threats and countermeasures. This section attends only to the set of additional threats which ensue from integrating the two services. This section reviews relevant concerns about Internet mail for IFax environments, as well as considering the potential problems which can result of integrating the existing G3Fax service with Internet mail.

5.2.1. Spoofed Sender

The actual sender of the message might not be the same as that specified in the Sender or From fields of the message content headers or the MAIL FROM address from the SMTP envelope.

In a tightly constrained environment, sufficient physical and software controls may be able to ensure prevention of this problem. The usual solution is through encryption-based authentication, either for the channel or associated with the object, as discussed below.

It should be recognized that SMTP implementations do not provide inherent authentication of the senders of messages, nor are sites under obligation to provide such authentication. End-to-end approaches such as S/MIME and PGP/MIME are currently being developed within the IETF. These technologies can provide such authentication.

5.2.2. Resources Consumed by Dialout

In addition to the resources normally consumed for email (CPU cycles and disk), offramp facsimile causes an outdial which often imposes significant resource consumption, such as financial cost. Techniques for establishing authorization of the sender are essential to those offramp facsimile services that need to manage such consumption.

Due to the consumption of these resources by dialout, unsolicited bulk email which causes an outdial is undesirable.

Offramp gateways SHOULD provide the ability to authorize senders in some manner to prevent unauthorized use of the offramp. There are no standard techniques for authorization using Internet protocols.

Typical solutions use simple authentication of the originator to establish and verify their identity and then check the identity against a private authorization table.

Originator authentication entails the use of weak or strong mechanisms, such as cleartext keywords or encryption-based data-signing, respectively, to determine and validate the identify of the sender and assess permissions accordingly.

Other control mechanisms which are common include source filtering and originator authentication. Source filtering entails offramp gateway verification of the host or network originating the message and permitting or prohibiting relaying accordingly.

5.2.3. GSTN Authorization Information

Confidential information about the sender necessary to dial a G3Fax recipient, such as sender's calling card authorization number, might be disclosed to the G3Fax recipient (on the cover page), such as through parameters encoded in the G3Fax recipients address in the To: or CC: fields.

Senders SHOULD be provided with a method of preventing such disclosure. As with mechanisms for handling unsolicited faxes, there are not yet standard mechanisms for protecting such information.

Out-of-band communication of authorization information or use of encrypted data in special fields are the available non-standard techniques.

Typically authorization needs to be associated to specific senders and specific messages, in order to prevent a "replay" attack which causes and earlier authorization to enable a later dial-out by a different (and unauthorized) sender. A non-malicious example of such a replay would be to have an email recipient reply to all original recipients -- including an offramp IFax recipient -- and have the original sender's authorization cause the reply to be sent.

5.2.4. Sender Accountability

   In many countries, there is a legal requirement that the "sender" be
   disclosed on a facsimile message.  Email From addresses are trivial
   to fake, so that using only the MAIL FROM [1, 3]  or From [2, 3]
   header is not sufficient.

Offramps SHOULD ensure that the recipient is provided contact information about the offramp, in the event of problems.

The G3Fax recipient SHOULD be provided with sufficient information which permits tracing the originator of the IFax message. Such information might include the contents of the MAIL FROM, From, Sender and Reply-To headers, as well as Message-Id and Received headers.

5.2.5. Message Disclosure

Users of G3Fax devices have an expectation of a level of message privacy which is higher than the level provided by Internet mail without security enhancements.

This expectation of privacy by G3Fax users SHOULD be preserved as much as possible.

Sufficient physical and software control may be acceptable in constrained environments. The usual mechanism for ensuring data confidentially entail encryption, as discussed below.

5.2.6. Non Private Mailboxes

With email, bounces (delivery failures) are typically returned to the sender and not to a publicly-accessible email account or printer. With facsimile, bounces do not typically occur. However, with IFax, a bounce could be sent elsewhere (see section [Delivery Failure]), such as a local system administrator's account, publicly-accessible account, or an IFax printer (see also [Traffic Analysis]).

5.2.7. Traffic Analysis

Eavesdropping of senders and recipients is easier on the Internet than GSTN. Note that message object encryption does not prevent traffic analysis, but channel security can help to frustrate attempts at traffic analysis.

5.3. Security Techniques

There are two basic approaches to encryption-based security which support authentication and privacy:

5.3.1. Channel Security

As with all email, an IFax message can be viewed as it traverses internal networks or the Internet itself.

Virtual Private Networks (VPN), encrypted tunnels, or transport layer security can be used to prevent eavesdropping of a message as it traverses such networks. It also provides some protection against traffic analysis, as described above.

At the current time various protocols exist for performing the above functions, and are only mentioned here for information. Such protocols are IPSec [17] and TLS [18].

5.3.2. Object Security

As with all email, an IFax message can be viewed while it resides on, or while it is relayed through, an intermediate Mail Transfer Agent.

Message encryption can be used to provide end-to-end encryption.

At the current time two protocols are commonly used for message encryption and are only mentioned here for information. The two protocols are PGP-MIME [16] and S/MIME [19].

6. References

6.1. Normative References

   [1]  Klensin, J., Editor, "Simple Mail Transfer Protocol", RFC 2821,
        April 2001.
   [2]  Resnick, P., Editor, "Internet Message Format", RFC 2822, April
   [3]  Braden, R., "Requirements for Internet hosts - application and
        support", STD 3, RFC 1123, October 1989.
   [4]  Borenstein, N. and N. Freed, "Multipurpose Internet Mail
        Extensions (MIME) Part Five: Conformance Criteria and Examples",
        RFC 2049, November 1996.
   [5]  Buckley, R., Venable, D., McIntyre, L., Parsons, G., and J.
        Rafferty, "File Format for Internet Fax", RFC 3949, November
   [6]  Myers, J. and M. Rose, "Post Office Protocol - Version 3", STD
        53, RFC 1939, May 1996.
   [7]  Allocchio, C., "Minimal GSTN address format for Internet mail",
        RFC 3191, October 2001.
   [8]  Allocchio, C., "Minimal fax address format for Internet mail",
        RFC 3192, October 2001.
   [9]  Moore, K., and G. Vaudreuil, "An Extensible Message Format for
        Delivery Status Notifications", RFC 3464, January 2003.
   [10] Freed, N. and N. Borenstein, "Multipurpose Internet Mail
        Extensions (MIME) Part Two: Media Types", RFC 2046, November
   [11] Moore, K. "MIME (Multipurpose Internet Mail Extensions) Part
        Three: Message Header Extensions for Non-ASCII Text", RFC 2047,
        November 1996.
   [12] Parsons, G. and J. Rafferty, "Tag Image File Format (TIFF) -
        image/tiff MIME Sub-type Registration", RFC 3302, September
   [13] Bradner, S., "Key words for use in RFCs to Indicate Requirement
        Levels", BCP 14, RFC 2119, March 1997.

6.2. Informative References

   [14] Parsons, G. and J. Rafferty, "Tag Image File Format (TIFF) -- F
        Profile for Facsimile", RFC 2306, March 1998.
   [15] ITU-T (CCITT), "Standardization of Group 3 facsimile apparatus
        for document transmission", ITU-T (CCITT), Recommendation T.4.
   [16] Callas, J., Donnerhacke, L., Finney, H., and R. Thayer, "OpenPGP
        Message Format", RFC 2440, November 1998.
   [17] Kent, S. and R. Atkinson, "Security Architecture for the
        Internet Protocol", RFC 2401, November 1998.
   [18] Hoffman, P., "SMTP Service Extension for Secure SMTP over
        Transport Layer Security", RFC 3207, February 2002.
   [19] Ramsdell, B., "S/MIME Version 3 Message Specification", RFC
        2633, June 1999.

7. Acknowledgements

This specification was produced by the Internet Engineering Task Force Fax Working Group, over the course of more than one year's online and face-to-face discussions. As with all IETF efforts, many people contributed to the final product.

Active for this document were: Steve Huston, Jeffrey Perry, Greg Vaudreuil, Richard Shockey, Charles Wu, Graham Klyne, Robert A. Rosenberg, Larry Masinter, Dave Crocker, Herman Silbiger, James Rafferty.

Appendix A: Exceptions to MIME

  • IFax senders are not required to be able to send text/plain messages (RFC 2049 requirement 4), although IFax recipients are required to accept such messages, and to process them.
  • IFax recipients are not required to offer to put results in a file. (Also see 2.3.2.)
   * IFax recipients MAY directly print/fax  the received message rather
     than "display" it, as indicated in RFC 2049.

Appendix B: List of edits to RFC 2305

   | No.| Section  |             Edit  July 27, 2001                 |
   | 1. |Copyright | Updated copyright from "1998" to "1999,2000"    |
   |    |Notice    |                                                 |
   | 2. |SUMMARY   | Changed the phrase "over the Internet" to       |
   |    |          |               "using Internet mail"             |
   | 3. |5         | Changed the paragraphs regarding to the         |
   |    |          | following references to make them very          |
   |    |          | non-normative.                                  |
   |    |          |  "OpenPGP Message Format", RFC 2440             |
   |    |          |  "Security Architecture for the IP", RFC 2401   |
   |    |          |  "SMTP Service Extensions for Secure SMTP over  |
   |    |          |   TLS", RFC 2487                                |
   |    |          |  "S/MIME Version 2 Message Specification",      |
   |    |          |   RFC 2311                                      |
   | 4. |REFERENCES| Removed the following references because they   |
   |    |          | are non-normative                               |
   |    |          |  "SMTP Service Extensions for Delivery Status   |
   |    |          |   Notifications", RFC 1891                      |
   |    |          |  "Internet Message Access Protocol", RFC 2060   |
   | 5. |REFERENCES| Separated REFERENCES to the normative and       |
   |    |          | non-normative                                   |
   | 6. |Appendix  | Changed the phrase from "NOT REQUIRED" to       |
   |    | A        | "not required"                                  |
   | 7. |Appendix  | Added "Appendix B  List of edits to RFC 2305"   |

Authors' Addresses

   Kiyoshi Toyoda
   Panasonic Communications Co., Ltd.
   4-1-62 Minoshima Hakata-ku
   Fukuoka 812-8531 Japan
   Fax:   +81 92 477 1389
   Hiroyuki Ohno
   National Institute of Information and Communications Technology
   4-2-1, Nukui-Kitamachi, Koganei, Tokyo,
   184-8795, Japan
   Fax:   +81 42 327 7941

Jun Murai
Keio University
5322 Endo, Fujisawa
Kanagawa 252 Japan

   Fax:   +81 466 49 1101

Dan Wing
170 W. Tasman Drive
San Jose, CA 95134 USA

   Phone: +1 408 525 5314

Full Copyright Statement

Copyright © The Internet Society (2004).

This document is subject to the rights, licenses and restrictions contained in BCP 78, and except as set forth therein, the authors retain all their rights.


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