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RFC 3249

Implementers Guide for Facsimile Using Internet Mail

Pages: 21
Informational

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Network Working Group                                          V. Cancio
Request for Comments: 3249                             Xerox Corporation
Category: Informational                                      M. Moldovan
                                                G3 Nova Technology, Inc.
                                                               H. Tamura
                                                     Ricoh Company, LTD.
                                                                 D. Wing
                                                           Cisco Systems
                                                          September 2002


          Implementers Guide for Facsimile Using Internet Mail

Status of this Memo

   This memo provides information for the Internet community.  It does
   not specify an Internet standard of any kind.  Distribution of this
   memo is unlimited.

Copyright Notice

   Copyright (C) The Internet Society (2002).  All Rights Reserved.

Abstract

This document is intended for the implementers of software that use email to send to facsimiles using RFC 2305 and 2532. This is an informational document and its guidelines do not supersede the referenced documents.

Table of Contents

1. Introduction .................................................. 2 1.1 Organization of this document ................................ 2 1.2 Discussion of this document .................................. 2 2. Terminology ................................................... 3 3. Implementation Issues Specific to Simple Mode ................. 3 3.1 Simple Mode Fax Senders ...................................... 3 3.1.1 Multipart-alternative ...................................... 3 3.2 Simple Mode Fax Receivers .................................... 4 3.2.1 Multipart-alternative and Storage Capacity ................. 4 4. Implementation Issues Specific to Extended Mode ............... 4 4.1 Multipart-alternative ........................................ 4 4.2 Correlation of MDN with Original Message ..................... 4 4.3 Correlation of DSN with Original Message ..................... 5 4.4 Extended Mode Receivers ...................................... 5 4.4.1 Confirmation of receipt and processing from User Agents .... 5 4.4.1.1 Discrepancies in MDN [9] Interpretation .................. 5
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   4.4.1.2 Disposition-Type and body of message in MDN ..............  6
   4.4.2 "Subject" of MDN and DSN in Success and Failure Cases ......  6
   4.4.3 Extended Mode Receivers that are MTAs (or ESMTP servers) ...  7
   4.4.3.1 Success Case Example .....................................  7
   4.4.3.2 Failure Case Example 1 ...................................  9
   4.4.3.3 Failure Case Example 2 ................................... 10
   4.4.4 Extended Mode Receivers that are POP3/IMAP4 ................ 11
   4.4.4.1 Success Case Example ..................................... 11
   4.4.4.2 Failure Case Example ..................................... 12
   4.4.5 Receiving Multiple Attachments ............................. 13
   5. Implementation Issues Specific to the File Format ............. 13
   5.1 IFD Placement & Profile-S Constraints ........................ 13
   5.2 Precautions for implementers of RFC 2301 [4] ................. 14
   5.2.1 Errors encountered during interoperability testing ......... 14
   5.2.2 Color Gamut Considerations ................................. 14
   5.2.3 File format Considerations ................................. 15
   5.2.3.1 Considerations for greater reader flexibility ............ 15
   5.2.3.2 Error considerations ..................................... 16
   5.3 Content-Type for the file format ............................. 17
   6. Implementation Issues for Internet Fax Addressing ............. 17
   7. Security Considerations ....................................... 18
   8. Acknowledgements .............................................. 18
   9. References .................................................... 18
   10. Authors' Addresses ........................................... 20
   11. Full Copyright Statement ..................................... 21

1. Introduction

This document clarifies published RFCs which standardize facsimile communications using Internet Email. The intent is to prevent implementations that deviate in such a way as to cause interoperability problems.

1.1 Organization of this document

This document contains four sections that clarify, in order, the handling of simple mode fax messages, extended mode fax messages, the file format, and the internet addressing of fax recipients. See Section 2 for terminology.

1.2 Discussion of this document

Discussion of this document should take place on the Internet fax mailing list hosted by the Internet Mail Consortium (IMC). Please send comments regarding this document to: ietf-fax@imc.org
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   To subscribe to this list, send a message with the body 'subscribe'
   to "ietf-fax-request@imc.org".

   To see what has gone on before you subscribed, please see the mailing
   list archive at:

      http://www.imc.org/ietf-fax/

2. Terminology

The following terms are used throughout this document: DSN - RFC 1894, "An Extensible Message Format for Delivery Status Notifications" [7] Extended Mode - RFC 2532, "Extended Facsimile Using Internet Mail" [3] MDN - RFC 2298, "An Extensible Message Format for Message Disposition Notifications" [9] Simple Mode - RFC 2305, "A Simple Mode of Facsimile Using Internet Mail" [2] TIFF - profile S or F of "File Format for Internet Fax" [4] delivered as "image/tiff" TIFF-FX - other profiles sent as "image/tiff-fx" In examples, "C:" is used to indicate lines sent by the client, and "S:" to indicate those sent by the server.

3. Implementation Issues Specific to Simple Mode

Issues specific to Simple Mode [2] are described below:

3.1 Simple Mode Fax Senders

3.1.1 Multipart/alternative

Although a requirement of MIME compliance (16, Section 5.1.4), some email client implementations are not capable of correctly processing messages with a MIME Content-Type of "multipart/alternative". If a sender is unsure if the recipient is able to correctly process a message with a Content-Type of "multipart/alternative", the sender should assume the worst and not use this MIME Content-Type.
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3.2 Simple Mode Fax Receivers

3.2.1 Multipart/alternative and Storage Capacity

Devices with little storage capacity are unable to cache previous parts of a multipart/alternative message. In order for such devices to correctly process only one part of a multipart/alternative message, such devices may simply use the first part of a multipart/alternative message it is capable of processing. This behavior means that even if subsequent, higher-fidelity parts could have been processed, they will not be used. This behavior can cause user dissatisfaction because when two high- fidelity but low-memory devices are used with each other, the lowest-fidelity part of the multipart/alternative will be processed. The solution to this problem is for the sender to determine the capability of the recipient and send only high fidelity parts. However, a mechanism to determine the recipient capabilities prior to an initial message sent to the recipient doesn't yet exist on the Internet. After an initial message is sent, the Extended Mode mechanism, described in RFC 2532 [3], Section 3.3, enables a recipient to include its capabilities in a delivery and/or a disposition notification: in a DSN, if the recipient device is an RFC 2532/ESMTP [3] compliant server or in an MDN if the recipient is a User Agent.

4. Implementation Issues Specific to Extended Mode

Issues specific to Extended Mode [3] fax are described below. Note that any Extended Mode device also needs to consider issues specific to Simple Mode (Section 3 of this document).

4.1 Multipart/Alternative

Sections 3.1.1 and 3.2.1 are also applicable to this mode.

4.2. Correlation of MDN with Original Message

To re-iterate a paragraph from section 2.1, RFC 2298 [9]: A message that contains a Disposition-Notification-To header SHOULD also contain a Message-ID header, as specified in RFC 822 [10]. This will permit automatic correlation of MDNs with original messages by user agents.
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4.3 Correlation of DSN with Original Message

Similar to the requirement to correlate an MDN, above, DSNs also need to be correlated. This is best done using the ENVID parameter in the "MAIL" command. See Sections 3 and 5.4 of RFC 1891 [5] for details.

4.4 Extended Mode Receivers

Confirmation that the facsimile image (attachment) was delivered and successfully processed is an important aspect of the extended mode of the facsimile using Internet mail. This section describes implementation issues with several types of confirmations.

4.4.1 Confirmation of receipt and processing from User Agents

When a message is received with the "Disposition-Notification-To" header and the receiver has determined whether the message can be processed, it may generate a: a) Negative MDN in case of error, or b) Positive MDN in case of success The purpose of receiving a requested MDN acknowledgement from an Extended Mode recipient is the indication of success or failure to process the file attachment that was sent. The attachment, not the body, constitutes the facsimile message. Therefore an Extended Mode sender would expect, and it is recommended that the Extended Mode receiver send (with an MDN), an acknowledgement of the success or failure to decode and process the file attachment. Implementers of the Extended Mode [3] should be consistent in the feedback provided to senders in the form of error codes and/or failure/success messages.
4.4.1.1 Discrepancies in MDN [9] Interpretation
An Extended Mode sender must be aware that RFC 2298 [9] does not distinguish between the success or failure to decode the body-content part of the message and the success or failure to decode a file attachment. Consequently MDNs may be received which do not reflect the success or failure to decode the attached file, but rather to decode the body-content part of the message.
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4.4.1.2 Disposition-Type and body of message in MDN
If the receiver of an MDN request is an RFC 2532 compliant device that automatically prints the received Internet mail messages and attachments, or forwards the attachment via GSTN fax, it should, in the case of success: a) Use a "disposition-type" of "dispatched" (with no "disposition- modifier") in the MDN, and b) Use text similar to the following in the body of the message: "This is a Return Receipt for the mail that you sent to [above, or below, or this address, etc]. The message and attached files[s] may have been printed, faxed or saved. This is no guarantee that the message has been read or understood". and in the case of failure: a) Use a "disposition-type" of "processed" and disposition-modifier of "error", and b) Use text similar to the following in the body of the message: "This is a Return Receipt for the mail that you sent to [above, or below, or this address, etc]. An error occurred while attempting to decode the attached file[s]". This recommendation adheres to the definition in RFC 2298 [9] and helps to distinguish the returned MDNs for proper handling. Implementers may wish to consider sending messages in the language of the sender (by utilizing a header field from the original message) or including multiple languages, by using multipart/alternative for the text portion of the MDN.

4.4.2 "Subject" of MDN and DSN in Success and Failure Cases

Because legacy e-mail applications do not parse the machine-readable headers, e-mail users depend on the human-readable parts of the MDN to recognize the type of acknowledgement that is received. Examples: MDN: Subject: Your message was processed successfully. (MDN) Subject: Your message has been rejected. (MDN)
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      DSN:
         Subject: Your message was delivered successfully. (DSN)
         Subject: Your message could not be delivered. (DSN)
         Subject: Your message is delayed. (DSN)

4.4.3 Extended Mode Receivers that are MTAs (or ESMTP servers)

SMTP server-based implementations are strongly encouraged to implement the "SMTP Service Extension for Returning Enhanced Error Codes" [8]. This standard is easy to implement and it allows detailed standardized success and error indications to be returned to the sender by the submitting MTA. The following examples, are provided as illustration only. They should not be interpreted as limiting the protocol or the DSN form. If the examples conflict with the definitions in the standards (RFC 1891[5]/1893[6]/1894[7]/2034[8]), the standards take precedence.
4.4.3.1 Success Case Example
In the following example the sender <jean@example.com> sends a message to the receiver <ifax@example.net> which is an ESMTP server and the receiver successfully decodes the message. example.com +-------+ | Mail | | User | | Agent | +-------+ | V +----------+ +--------+ +---------+ | Mail + | Mail | | Mail | |Submission|----->|Transfer|---->|Transfer | | Agent | | Agent | | Agent | +----------+ +--------+ +---------+ example.org example.net
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   SMTP Sequence:

      S: 220 example.net SMTP service ready
      C: EHLO example.org
      S: 250-example.net
      S: 250-DSN
      S: 250 ENHANCEDSTATUSCODES
      C: MAIL FROM:<jean@example.com> RET=HDRS ENVID=MM123456
      S: 250 2.1.0 Originator <jean@example.com> ok
      C: RCPT TO:<ifax@example.net> NOTIFY=SUCCESS,FAILURE \
         ORCPT=rfc822;ifax@example.net
      S: 250 2.1.5 Recipient <ifax@example.net> ok
      C: DATA
      S: 354 Send message, ending in <CRLF>.<CRLF>
      C:
      C:  [Message goes here.]
      C:
      C: .
      S: 250 2.0.0 Message accepted
      C: QUIT
      S: 221 2.0.0 Goodbye

   DSN (to jean@example.com):

      Date: Mon, 12 Dec 1999 19:01:57 +0900
      From: postmaster@example.net
      Message-ID: <19991212190157.01234@example.net>
      To: jean@example.com
      Subject: Your message was delivered successfully. (DSN)
      MIME-Version: 1.0
      Content-Type: multipart/report; report-type=delivery-status;
        boundary=JUK199912121854870001

      --JUK199912121854870001
      Content-type: text/plain

      Your message (id MM123456) was successfully delivered
      to ifax@example.net.

      --JUK199912121854870001
      Content-type: message/delivery-status
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      Reporting-MTA: dns; example.net
      Original-Envelope-ID: MM123456
      Final-Recipient: rfc822;ifax@example.net
      Action: delivered
      Status: 2.1.5 (Destination address valid)
      Diagnostic-Code: smtp; 250 2.1.5
        Recipient <ifax@example.net> ok

      --JUK199912121854870001
      Content-type: message/rfc822

      [headers of returned message go here.]

      --JUK199912121854870001--

4.4.3.2 Failure Case Example 1
In this example, the receiver determines it is unable to decode the attached file AFTER it has received the SMTP message. The receiver then sends a 'failure' DSN. example.com +-------+ | Mail | | User | | Agent | +-------+ | V +----------+ +--------+ +---------+ | Mail + | Mail | | Mail | |Submission|----->|Transfer|---->|Transfer | | Agent | | Agent | | Agent | +----------+ +--------+ +---------+ example.org example.net SMTP Sequence: This is the same as the case a). After the sequence, a decode error occurs at the receiver, so instead of a 'success' DSN, a 'failure' DSN is sent.
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   DSN (to jean@example.com):

      Date: Mon, 12 Dec 1999 19:31:20 +0900
      From: postmaster@example.net
      Message-ID: <19991212193120.87652@example.net>
      To: jean@example.com
      Subject:  Your message could not be delivered. (DSN)
      MIME-Version: 1.0
      Content-Type: multipart/report; report-type=delivery-status;
        boundary=JUK199912121934240002

      --JUK199912121934240002
      Content-type: text/plain

      Your message (id MM123456) to ifax@example.net resulted in an
      error while attempting to decode the attached file.

      --JUK199912121934240002
      Content-type: message/delivery-status

      Reporting-MTA: dns; example.net
      Original-Envelope-ID: MM123456
      Final-Recipient: rfc822;ifax@example.net
      Action: Failed
      Status: 5.6.1 (Media not supported)
      Diagnostic-Code: smtp; 554 5.6.1 Decode error

      --JUK199912121934240002
      Content-type: message/rfc822

      [headers of returned message go here.]

      --JUK199912121934240002--

4.4.3.3 Failure Case Example 2
In this example, the receiver determines it is unable to decode the attached file BEFORE it accepts the SMTP transmission.
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   SMTP sequence:

      S: 220 example.net SMTP service ready
      C: EHLO example.org
      S: 250-example.net
      S: 250-DSN
      S: 250 ENHANCEDSTATUSCODES
      C: MAIL FROM:<jean@example.com> RET=HDRS ENVID=MM123456
      S: 250 2.1.0 Originator <jean@example.com> ok
      C: RCPT TO:<ifax@example.net> NOTIFY=SUCCESS,FAILURE \
         ORCPT=rfc822;ifax@example.net
      S: 250 2.1.5 Recipient <ifax@example.net> ok
      C: DATA
      S: 354 Send message, ending in <CRLF>.<CRLF>
      C:
      C:  [Message goes here.]
      C:
      C: .
      S: 554 5.6.1 Media not supported
      C: QUIT
      S: 221 2.0.0 Goodbye

   DSN:

      Note: In this case, the previous MTA generates the DSN that is
      forwarded to the original sender.  The receiving MTA has not
      accepted delivery and therefore can not generate a DSN.

4.4.4 Extended Mode Receivers that are POP3/IMAP4

NOTE: This document does not define new disposition-types or disposition-modifiers. Those used below are defined in RFC 2298[9]. This section provides examples on how POP3/IMAP4 devices may use the already defined values. These examples are provided as illustration only. They should not be interpreted as limiting the protocol or the MDN form. If the examples conflict with the MDN [9] standard, the standard takes precedence.
4.4.4.1 Success Case Example
If the original sender receives an MDN which has "displayed", "dispatched" or "processed" disposition-type without disposition- modifier, the receiver may have received or decoded the attached file that it sent. The MDN does not guarantee that the receiver displays, prints or saves the attached file. See Section 4.4.1.1, Discrepancies in MDN Interpretation.
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      NOTE: This example does not include the third component of the
      MDN.

      Date: 14 Dec 1999 17:48:44 +0900
      From: ken_recipient@example.com
      Message-ID: <19991214174844.98765@example.com>
      Subject:  Your message was processed successfully. (MDN)
      To: mary@example.net
      Mime-Version: 1.0
      Content-Type: multipart/report;
        report-type=disposition-notification; boundary="61FD1001_IFAX"

      --61FD1001_IFAX
      Content-Type: text/plain

      This is a Return Receipt for the mail that you sent to
      "ken_recipient@example.com".  The message and attached files may
      have been printed, faxed or saved.  This is no guarantee that the
      message has been read or understood.

      --61FD1001_IFAX
      Content-Type: message/disposition-notification

      Reporting-UA: ken-ifax.example.com; barmail 1999.10
      Original-Recipient: rfc822;ken_recipient@example.com
      Final-Recipient: rfc822;ken_recipient@example.com
      Original-Message-ID: <19991214174010O.mary@example.net>
      Disposition: automatic-action/MDN-sent-automatically; dispatched

      --61FD1001_IFAX--

4.4.4.2 Failure Case Example
If the original sender receives an MDN with an "error" or "warning" disposition-modifier, it is possible that the receiver could not receive or decode the attached file. Currently there is no mechanism to associate the disposition-type with the handling of the main content body of the message or the attached file. Date: 14 Dec 1999 19:48:44 +0900 From: ken_recipient@example.com Message-ID: <19991214194844.67325@example.com> Subject: Your message has been rejected. (MDN) To: mary@example.net Mime-Version: 1.0 Content-Type: multipart/report; report-type=disposition-notification; boundary="84FD1011_IFAX"
Top   ToC   RFC3249 - Page 13
      --84FD1011_IFAX
      Content-Type: text/plain

      This is a Return Receipt for the mail that you sent to
      "ken_recipient@example.com".  An error occurred while attempting
      to decode the attached file[s]".

      --84FD1011_IFAX
      Content-Type: message/disposition-notification

      Reporting-UA: ken-ifax.example.com; barmail 1999.10
      Original-Recipient: rfc822;ken_recipient@example.com
      Final-Recipient: rfc822;ken_recipient@example.com
      Original-Message-ID: <199912141823123.mary@example.net>
      Disposition: automatic-action/MDN-sent-automatically;
        processed/error

      --84FD1011_IFAX
      Content-Type: message/rfc822

      [original message goes here]

      --84FD1011_IFAX--

4.4.5 Receiving Multiple Attachments

A received email message could contain multiple attachments and each distinct attachment could use TIFF or TIFF-FX with different encodings or resolutions, and these could be mixed with other file types. There is currently no mechanism to identify, in a returned MDN, the attachments that were successfully decoded from those that could not be decoded. If the Extended Mode recipient is unable to decode any of the attached files, it is recommended that the Extended Mode recipient return a decoding error for the entire message.

5. Implementation Issues Specific to the File Format

5.1 IFD Placement & Profile-S Constraints

a) An IFD is required, by TIFF 6.0, to begin on a word boundary, however, there is ambiguity with regard to the defined size of a word. A word should be interpreted as a 2-byte quantity. This
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      recommendation is based on examination of Figure 1 and the
      definition of IFD Entry, Bytes 8-11, found in Section 2 of TIFF
      6.0.

   b) Low memory devices, which support resolutions greater than the
      required Profile-S, may be memory-constrained, such that those
      devices cannot properly handle arbitrary placement of TIFF IFDs
      within a TIFF file.

      To interoperate with a receiver that is constrained, it is
      strongly recommended that senders always place the IFD at the
      beginning of the image file when using any of the Profiles defined
      in [4].

5.2 Precautions for implementers of RFC 2301 [4]

5.2.1 Errors encountered during interoperability testing

The TIFF/RFC 2301 [4] errors listed below were encountered during interoperability testing and are provided so that implementers of TIFF readers and writers can take precautionary measures. a) Although Profile S of TIFF [4] specifies that files should be in little-endian order, during testing it was found that some common TIFF writers create big-endian files. If possible, the TIFF reader should be coded to handle big-endian files. TIFF writers should always create little-endian files to be compliant with the standard and to allow interoperation with memory-constrained devices. b) Bytes 0-1 of the Image File Header are supposed to be set to "II" (4949h) or "MM" (4d4dh) to indicate the byte order. During testing, other values were encountered. Readers should handle cases where the byte order field contains values other than "II" or "MM", and writers should ensure the correct value is used.

5.2.2 Color Gamut Considerations

The ITULAB encoding (PhotometricInterpretation = 10) allows choosing a gamut range for L*a*b* (see the TIFF field Decode), which in turn provides a way to place finer granularity on the integer values represented in this colorspace. But consequently, an inadequate gamut choice may cause a loss in the preservation of colors that don't fall within the space of colors bounded by the gamut. As such, it is worth commenting on this.
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   The ITULAB default gamut, L [0,100] a [-85,85] b [-75,125], was
   chosen to accommodate most scan devices, which are typically acquired
   from a hardcopy source.  It wasn't chosen to deal with the range of
   color from camera input or sRGB monitor data.  In fact, when dealing
   with images from the web and other display oriented sources, the
   color range for a scanned hardcopy may likely be inadequate.  It is
   important to use a gamut that matches the source of the image data.

   The following guidelines are recommended:

   1. When acquiring input from a printed hardcopy source, without
      modification, the ITU-T Recommendation T.42 default ITULAB gamut
      should be appropriate.

   2. For an sRGB source, the ITU-T Recommendation T.42 default ITULAB
      gamut is not appropriate.  A more appropriate gamut to consider
      is: L [0,100], a [-88,99] and b [-108.8,95.2].  These may be
      realized by using the following Decode values for 8-bit data:
      (0/1, 100/1, -22440/255, 25245/255, -27744/255, 24276/255).

   3. If the range of L*a*b* value can be precomputed efficiently before
      converting to ITULAB, then you may get the best result by picking
      a gamut that is custom to this range.

5.2.3 File format Considerations

Implementers should make sure of the contents in the following two sections.
5.2.3.1 Considerations for greater reader flexibility
a) Readers are able to handle cases where IFD offsets point beyond the end of the file, while writers ensure that the IFD offset does not point beyond the end of the file. b) Readers are able to handle the first IFD offset being on a non- word boundary, while writers ensure that the first IFD offset is on a word boundary. c) Readers are flexible and able to accommodate: IFDs that are not presented in ascending page order; IFDs that are not placed at a location that precedes the image which the IFD describes; next IFD offsets that precede the current IFD, the current IFDs' field data, or the current IFDs' image data. Writers on the other hand should generate files with IFDs presented in ascending page order; IFDs placed at a location that precedes the image which the IFD describes; the next IFD should always follow the current IFD and all of its data.
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   d) Writers generate tags with the appropriate type of data (for
      example RATIONAL instead of SRATIONAL).  Readers are flexible with
      those types of misrepresentations that may be readily accommodated
      (for example SHORT instead of LONG) and lead to enhanced
      robustness.

   e) The appropriate count is associated with the tags (it is not 0 and
      matches the tag requirement), while readers are flexible with
      these types of misrepresentations, which may be readily
      accommodated and lead to enhanced robustness.

   f) Tags appear in the correct order in the IFD and readers are
      flexible with these types of misrepresentations.

5.2.3.2 Error considerations
a) Readers only accept files with bytes 2-3 of the Image File Header equal to 42 (2Ah), the "magic number", as being valid TIFF or TIFF-FX files, while writers only generate files with the appropriate magic number. b) Files are not generated with missing field entries, and readers reject any such files. c) The PageNumber value is based on the order within the Primary IFD chain. The ImageLayer values are based on the layer order and the image order within the layer respectively. Readers may reject the pages where the PageNumber or ImageLayer values are not consistent with the number of Primary IFDs, number of layers or number of images within the layers. d) Tags are unique within an IFD and readers may reject pages where this is not the case. e) Strip data does not overlap other file data and the reader may error appropriately. f) The strip offset does not point outside the file, under these conditions readers may reject the page where this is the case. g) The strip offset + StripByteCounts does not point outside the file, under these conditions the reader may error appropriately. h) Only one endian order is used within the file otherwise the rendered file will be corrupted.
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   i) Tag values are consistent with the data contained within the image
      strip.  For example, a bi-level black mark on a white background
      image strip with a PhotometricInterpretation tag value of "1" (bit
      value of "0" means black) will result in the rendering of the
      image as white marks on a black background (reverse video).

   j) For the special color spaces (ITULAB, YCBCR, CMYK), the parameters
      used for transformations are correct and compliant with the
      specification.

   k) The XPosition and YPosition values are consistent with the
      horizontal and vertical offsets of the top-left of the IFD from
      the top-left of the Primary IFD, in units of the resolution.  To
      do otherwise results in misplacement of the rendered image.

   l) All combinations of tag values are correct, with special attention
      being given to the sets: XResolution, YResolution and ImageWidth;
      PhotometricInterpretation, SamplesPerPixel, and BitsPerSample.
      Any appropriate combinations will likely result in image
      distortion or an inability to render the image.

   m) The appropriate Compression types are used for the image layers
      within a Profile M file, such as a bi-level coder for the mask
      layers (i.e. odd numbered layers) and multi-level (color) coders
      for the background and foreground layers.  Readers should reject
      files where this is not true.

5.3 Content-Type for the file format

The content-type "image/tiff" should only be used for Profiles S and F. Some existing implementations based on [4] may use "image/tiff" for other Profiles. However, this usage is now deprecated. Instead, the content-type "image/tiff-fx", whose registration is being defined in [17] should be used. To maximize interworking with devices that are only capable of rendering Profile S or F, "image/tiff" SHOULD be used when transporting Profile S or F.

6. Implementation Issues for Internet Fax Addressing

The "+" and "=" characters are valid within message headers, but must be encoded within some ESMTP commands, most notably ORCPT [5]. Implementations must take special care that ORCPT (and other ESMTP values) are properly encoded.
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   For example, the following header is valid as-is:

      To: Home Fax <FAX=+390408565@example.com>

   but when used with ORCPT, the "=" and "+" must be encoded like this:

      RCPT TO:<FAX=+390408565@example.com> \
        ORCPT=FAX+3D+2B390408565@example.com

   Note the "=" and "+" are valid inside the forward-path, but must be
   encoded when used within the esmtp value.

   See [5] for details on this encoding.

7. Security Considerations

With regards to this document, Sections 5 in RFC 2305 [2] and Section 4 in RFC 2532 [3] apply.

8. Acknowledgements

The authors gratefully acknowledge the following persons who contributed or made comments on earlier versions of this memo: Claudio Allocchio, Richard Coles, Ryuji Iwazaki, Graham Klyne, James Rafferty, Kensuke Yamada, Jutta Degener and Lloyd McIntyre.

9. References

[1] Masinter, L., "Terminology and Goals for Internet Fax", RFC 2542, March 1999. [2] Toyoda, K., Ohno, H., Murai, J. and D. Wing, "A Simple Mode of Facsimile Using Internet Mail", RFC 3205, March 1998. [3] Masinter, L. and D. Wing, "Extended Facsimile Using Internet Mail", RFC 2532, March 1999. [4] McIntyre, L., Zilles, S., Buckley, R., Venable, D., Parsons, G. and J. Rafferty, "File Format for Internet Fax", RFC 2301, March 1998. [5] Moore, K., "SMTP Service Extension for Delivery Status Notification", RFC 1891, January 1996. [6] Vaudreuil, G., "Enhanced Mail System Status Codes", RFC 1893, January 1996.
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   [7]  Moore, K. and G. Vaudreuil, "An Extensible Message Format for
        Delivery Status Notifications", RFC 1894, January 1996.

   [8]  Freed, N., "SMTP Service Extension for Returning Enhanced Error
        Codes", RFC 2034, October 1996.

   [9]  Fajman, R., "An Extensible Message Format for Message
        Disposition Notifications", RFC 2298, March 1998.

   [10] Crocker, D., "Standard for the Format of ARPA Internet Text
        Messages", STD 11, RFC 822, August 1982.

   [11] Postel, J., "A Simple Mail Transfer Protocol", STD 10, RFC 821,
        August 1982.

   [12] Allocchio, C., "Minimal GSTN address format in Internet Mail",
        RFC 3191, October 2001.

   [13] Allocchio, C., "Minimal FAX address format in Internet Mail",
        RFC 3192, October 2001.

   [14] Allocchio, C., "GSTN Address Element Extensions in E-mail
        Services", RFC 2846, June 2000

   [15] Klensin, J., Freed, N., Rose, M., Stefferud, E. and D. Crocker,
        D., "SMTP Service Extensions", RFC 2846, November 1995

   [16] Freed, N. and N. Borenstein, "Multipurpose Internet Mail
        Extensions (MIME) Part Two: Media Types", RFC 2046, November
        1996

   [17] McIntyre, L., Parsons, G. and J. Rafferty, "Tag Image File
        Format Fax eXtended (TIFF-FX) - image/tiff-fx MIME Sub-type
        Registration", RFC 3250, September 2002.

   [18] Klensin, J., "Simple Mail Transfer Protocol", RFC 2821, April
        2001.

   [19] Resnick, P., "Internet Message Format", RFC 2822, April 2001.
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10. Authors' Addresses

Vivian Cancio 103 Cuesta Drive Los Altos, CA 94022 Phone: +1-650-948-3135 EMail: vcancio@pacbell.net Mike Moldovan G3 Nova Technology Inc. 5743 Corsa Avenue, Suite 122 Westlake Village, CA 91362 Phone: (818) 865-6600 Ext.113 EMail: mmoldovan@g3nova.com Hiroshi Tamura Ricoh Company, LTD. 1-3-6 Nakamagome, Ohta-ku Tokyo 143-8555 Japan Phone: +81-3-3777-8124 Fax: +81-3-5742-8859 EMail: tamura@toda.ricoh.co.jp Dan Wing Cisco Systems, Inc. 170 W. Tasman Drive San Jose, CA 95134-1706 USA Phone: +1-408-525-5314 Fax: +1-408-527-8083 EMail: dwing@cisco.com
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11. Full Copyright Statement

Copyright (C) The Internet Society (2002). All Rights Reserved. This document and translations of it may be copied and furnished to others, and derivative works that comment on or otherwise explain it or assist in its implementation may be prepared, copied, published and distributed, in whole or in part, without restriction of any kind, provided that the above copyright notice and this paragraph are included on all such copies and derivative works. However, this document itself may not be modified in any way, such as by removing the copyright notice or references to the Internet Society or other Internet organizations, except as needed for the purpose of developing Internet standards in which case the procedures for copyrights defined in the Internet Standards process must be followed, or as required to translate it into languages other than English. The limited permissions granted above are perpetual and will not be revoked by the Internet Society or its successors or assigns. This document and the information contained herein is provided on an "AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Acknowledgement Funding for the RFC Editor function is currently provided by the Internet Society.