Mapping between X.400 and RFC 822 (original) (raw)

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Obsoleted by: 2156, 1327 UNKNOWN
Updated by: 1026, 1138, 1148

UCL Technical Report 120 Mailgroup Note 19

Network Working Group S.E. Kille Request for Comments: 987 University College London June 1986

               Mapping between X.400 and [RFC 822](./rfc822)

Status of This Memo

This RFC suggests a proposed protocol for the ARPA-Internet community, and requests discussion and suggestions for improvements. Distribution of this memo is unlimited.

This document describes a set of mappings which will enable interworking between systems operating the CCITT X.400 (1984) series of protocols [CCITT84a], and systems using the RFC 822 mail protocol [Crocker82a], or protocols derived from RFC 822. The approach aims to maximise the services offered across the boundary, whilst not requiring unduly complex mappings. The mappings should not require any changes to end systems.

This specification should be used when this mapping is performed on the ARPA-Internet or in the UK Academic Community. This specification may be modified in the light of implementation experience, but no substantial changes are expected.

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Chapter 1 -- Overview

1.1. X.400

  The X.400 series protocols have been defined by CCITT to provide
  an Interpersonal Messaging Service (IPMS), making use of a store
  and forward Message Transfer Service.  It is expected that this
  standard will be implemented very widely.  As well as the base
  standard (X.400), work is underway on various functional standards
  of profiles which specify how X.400 will be used in various
  communities.  Many of the major functional standards (e.g. from
  CEPT, CEN/CENELEC, and NBS) are likely to be similar.  Some of the
  decisions in this document are in the light of this work.  No
  reference is given, as these documents are not currently stable.

1.2. RFC 822

  [RFC 822](./rfc822) evolved as a messaging standard on the DARPA (the US
  Defense Advanced Research Projects Agency) Internet.  It is
  currently used on the ARPA-Internet in conjunction with two other
  standards: [RFC 821](./rfc821), also known as Simple Mail Transfer Protocol
  (SMTP) [Postel82a], and [RFC 920](./rfc920) which is a specification for a
  domain name system and a distributed name service [Postel84a].
  [RFC 822](./rfc822), or protocols derived from [RFC 822](./rfc822) are used in a number of
  other networks.  In particular:

     UUCP Networks

        UUCP is the UNIX to UNIX CoPy protocol <0>, which is usually
        used over dialup telephone networks to provide a simple
        message transfer mechanism.  There are some extensions to
        [RFC 822](./rfc822), particularly in the addressing.  They are likely to
        use domains which conform to [RFC 920](./rfc920), but not the
        corresponding domain nameservers [Horton86a].

     CSNET

        Some portions of CSNET will follow the ARPA-Internet
        protocols. The dialup portion of CSNET uses the Phonenet
        protocols as a replacement for [RFC 821](./rfc821).  This portion is
        likely to use domains which conform to [RFC 920](./rfc920), but not the
        corresponding domain nameservers.

     BITNET

        Some parts of BITNET use [RFC 822](./rfc822) related protocols, with
        EBCDIC encoding.

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     JNT Mail Networks

        A number of X.25 networks, particularly those associated
        with the UK Academic Community, use the JNT (Joint Network
        Team) Mail Protocol, also known as Greybook [Kille84a].
        This is used with domains and name service specified by the
        JNT NRS (Name Registration Scheme) [Larmouth83a].

  The mappings specified here are appropriate for all of these
  networks.

1.3. The Need for Conversion

  There is a large community using [RFC 822](./rfc822) based protocols for mail
  services, who will wish to communicate with X.400 systems.  This
  will be a requirement, even in cases where communities intend to
  make a transition to use of X.400, where conversion will be needed
  to ensure a smooth service transition.  It is expected that there
  will be more than one gateway <1>, and this specification will
  enable them to behave in a consistent manner.  These gateways are
  sometimes called mail relays.  Consistency between gateways is
  desirable to provide:

     1.   Consistent service to users.

     2.   The best service in cases where a message passes through
          multiple gateways.

1.4. General Approach

  There are a number of basic principles underlying the details of
  the specification.

     1.   The specification should be pragmatic.  There should not
          be a requirement for complex mappings for 'Academic'
          reasons.  Complex mappings should not be required to
          support trivial additional functionality.

     2.   Subject to 1), functionality across a gateway should be as
          high as possible.

     3.   It is always a bad idea to lose information as a result of
          any transformation.  Hence, it is a bad idea for a gateway
          to discard information in the objects it processes.  This
          includes requested services which cannot be fully mapped.

     4.   All mail gateways actually operate at exactly one level

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          above the layer on which they conceptually operate.  This
          implies that the gateway must not only be cognisant of the
          semantics of objects at the gateway level, but also be
          cognisant of higher level semantics.  If meaningful
          transformation of the objects that the gateway operates on
          is to occur, then the gateway needs to understand more
          than the objects themselves.

1.5. Gatewaying Model

  1.5.1.  X.400

     The CCITT X.400 series recommendations specify a number of
     services and protocols.  The services are specified in X.400.
     Two of these services are fundamental to this document:

        1.   The Message Transfer Service, which can be provided by
             either the P1 or P3 protocols, which are  specified in
             X.411 [CCITT84b]. This document talks in terms of P1,
             but the mappings are equally applicable to P3.

        2.   The Interpersonal Messaging Service (IPMS), which is
             provided by the P2 protocol specified in X.420
             [CCITT84c].

     This document considers only IPMS, and not of any other usage
     of the Message Transfer Service.  This is reasonable, as
     [RFC 822](./rfc822), broadly speaking, provides a service corresponding to
     IPMS, and no services other than IPMS have been defined over
     the Message Transfer Service. As none of the RTS (Reliable
     Transfer Service) service elements is available to the IPMS
     user, this level and lower levels are of no concern in this
     gatewaying specification.  Note that in this memo "IP" means
     "InterPersonal" (not Internet Protocol).

     The Message Transfer Service defines an end-to-end service over
     a series of Message Transfer Agents (MTA).  It also defines a
     protocol, P1, which is used between a pair of MTAs.  This
     protocol is simply a file format (Message Protocol Data Unit,
     or MPDU), transferred between two MTAs using the RTS.  There
     are three types of MPDU:

        User MPDU

           This contains envelope information, and uninterpreted
           contents. The envelope includes an ID, an originator, a

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           list of recipients, and trace information.  It is used to
           carry data for higher level services.

        Probe

           This contains only envelope information.  It is used to
           determine whether a User UMPDU could be delivered to a
           given O/R (originator/recipient) name.

        Delivery Report

           This contains envelope information, and specified
           contents.  It is used to indicate delivery success or
           failure of a User or Probe MPDU over the Message Transfer
           Service.

     IPMS (P2) specifies two content types for the P1 User MPDU
     (User Agent Protocol Data Units or UAPDU):

        Interpersonal Message (IM-UAPDU)

           This has two components: a heading, and a body.  The body
           is structured as a sequence of body parts, which may be
           basic components (e.g.IA5 text, or G3 fax), or IP
           Messages.  The header contains end to end user
           information, such as subject, primary recipients (To:),
           and priority.  The validity of these fields is not
           guaranteed by the Message Transfer Service.  This
           provides the basic IPMS.

        Status Report (SR-UAPDU)

           This UAPDU has defined contents.  It is used to indicate
           that a message has been received by a User Agent.  It
           does not have to be implemented.

  1.5.2.  [RFC 822](./rfc822)

     [RFC 822](./rfc822) is based on the assumption that there is an underlying
     service, which is here called the 822-P1 service.  The 822-P1
     service provides three basic functions:

        1.   Identification of a list of recipients.

        2.   Identification of an error return address.

        3.   Transfer of an [RFC 822](./rfc822) message.

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     It is possible to achieve 2) within the [RFC 822](./rfc822) header.  Some
     822-P1 protocols, in particular SMTP, can provide additional
     functionality, but as these are neither mandatory in SMTP, nor
     available in other 822-P1 protocols, they are not considered
     here.  Details of aspects specific to a number of 822-P1
     protocols are given in appendices B to E.  An [RFC 822](./rfc822) message
     consists of a header, and content which is uninterpreted ASCII
     text.  The header is divided into fields, which are the
     protocol elements.  Most of these fields are analogous to P2
     header elements, although some are analogous to P1 envelope
     elements.

  1.5.3.  The Gateway

     Given this functional description of the two protocols, the
     functional nature of a gateway can now be considered.  It would
     be elegant to consider the 822-P1 service mapping onto P1 and
     [RFC 822](./rfc822) mapping onto P2, but reality just does not fit.
     Therefore one must consider that P1 or P1 + P2 on one side are
     mapped into [RFC 822](./rfc822) + 822-P1 on the other in a slightly tangled
     manner.  The details of the tangle will be made clear in
     chapter 5.  The following basic mappings are thus proposed.
     When going from [RFC 822](./rfc822) to X.400, an [RFC 822](./rfc822) message and the
     associated 822-P1 information is always mapped into an IM-UAPDU
     and the associated P1 envelope.  Going from X.400 to [RFC 822](./rfc822),
     an [RFC 822](./rfc822) message and the associated 822-P1 information may be
     derived from:

        1.   A Delivery Report MPDU

        2.   An SR-UAPDU and the associated P1 envelope.

        3.   An IM-UAPDU and the associated P1 envelope.

     Probe MPDUs must be processed by the gateway - this is
     discussed in chapter 5.  Any other User MPDUs are not mapped by
     the gateway, and should be rejected at the gateway.

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1.6. Document Structure

  This document has five chapters:

     1.   Overview - this document.

     2.   Service Elements - This describes the (end user) services
          mapped by a gateway.

     3.   Basic mappings - This describes some basic notation used
          in chapters 3-5, the mappings between character sets, and
          some fundamental protocol elements.

     4.   Addressing - This considers the mapping between X.400 O/R
          names and [RFC 822](./rfc822) addresses, which is a fundamental
          gateway component.

     5.   Protocol Elements - This describes the details of all
          other mappings.

  There are also six appendices:

     A.   Quoted String Encodings.

     B.   Mappings Specific to JNT Mail.

     C.   Mappings Specific to Internet Mail.

     D.   Mappings Specific to Phonenet Mail.

     E.   Mappings Specific to UUCP Mail.

     F.   Format of Address Tables.

1.7. Acknowledgements

  This document is eclectic, and credit should be given:

     -    Study of the EAN X.400 system code which performs this
          function [Neufeld85a].  Some detailed clarification was
          made by the DFN report on EAN [Bonacker85a].

     -    An unpublished ICL report, which considered a subset of
          the problem [ICL84a].

     -    A document by Marshall Rose [Rose85a].

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     -    A document by Mark Horton [Horton85a].  The string
          encodings of chapter 3 were derived directly from this
          work, as is much of chapter 4.

     -    Discussion on a number of electronic mailing lists.

     -    Meetings in the UK and the US.

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Chapter 2 -- Service Elements

RFC 822 and X.400 provide a number of services to the end user. This document describes the extent to which each service can be supported across an X.400 <-> RFC 822 gateway. The cases considered are single transfers across such a gateway, although the problems of multiple crossings are noted where appropriate.

When a service element is described as supported, this means that when this service element is specified by a message originator for a recipient behind a gateway, that it is mapped by the gateway to provide the service implied by the element. For example, if an RFC 822 originator specifies a Subject: field, this is considered to be supported, as an X.400 recipient will get a subject indication. Support implies:

  -    Semantic correspondence.

  -    No loss of information.

  -    Any actions required by the service element.

For some services, the corresponding protocol elements map well, and so the service can be fully provided. In other cases, the service cannot be provided, as there is a complete mismatch. In the remaining cases, the service can be partially fulfilled. The level of partial support is summarised.

  NOTE:  It should be clear that support of service elements on
  reception is not a gatewaying issue.  It is assumed that all
  outbound messages are fully conforming to the appropriate
  standards.

2.1. RFC 822

  [RFC 822](./rfc822) does not explicitly define service elements, as distinct
  from protocol elements.  However, all of the [RFC 822](./rfc822) header
  fields, with the exception of trace, can be regarded as
  corresponding to implicit [RFC 822](./rfc822) service elements.  A mechanism
  of mapping used in several cases, is to place the text of the
  header into the body of the IP Message.  This can usually be
  regarded as partial support, as it allows the information to be
  conveyed to the end user even though there is no corresponding
  X.400 protocol element.  Support for the various service elements
  (headers) is now listed.

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     Date:

        Supported.

     From:

        Supported.  For messages where there is also a sender field,
        the mapping is to "Authorising Addresses", which has subtly
        different semantics to the general [RFC 822](./rfc822) usage of From:.

     Sender:

        Supported.

     Reply-To:

        Supported.

     To:

        Supported.

     Cc:

        Supported.

     Bcc:

        Supported.

     Message-Id:

        Supported.

     In-Reply-To:

        Supported, for a single reference in msg-id form.  Other
        cases are passed in the message text.

     References:

        Supported.

     Keywords:

        Passed in the message text.

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     Subject:

        Supported.

     Comments:

        Passed in the message text.

     Encrypted:

        Passed in the message text.  This may not be very useful.

     Resent-*

        Passed in the message text.  In principle, these could be
        supported in a fuller manner, but this is not suggested.

     Other Fields

        In particular X-* fields, and "illegal" fields in common
        usage (e.g. "Fruit-of-the-day:") are passed in the message
        text.

2.2. X.400

  When mapping from X.400 to [RFC 822](./rfc822), it is not proposed to map any
  elements into the body of an [RFC 822](./rfc822) message.  Rather, new [RFC 822](./rfc822)
  headers are defined.  It is intended that these fields will be
  registered, and that co-operating [RFC 822](./rfc822) systems may use them.
  Where these new fields are used, and no system action is implied,
  the service can be regarded as being almost supported.  Chapter 5
  describes how to map these new headers in both directions.  Other
  elements are provided, in part, by the gateway as they cannot be
  provided by [RFC 822](./rfc822).  Some service elements are are marked N/A
  (not applicable).  These elements are only applicable to User
  Agent / Message Transfer Agent interaction and have no end-to-end
  implication. These elements do not need to be mapped by the
  gateway.

  2.2.1.  Message Transfer Service Elements

     Access Management

        N/A.

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     Content Type Indication

        Not mapped.  As it can only have one value (P2), there is
        little use in creating a new [RFC 822](./rfc822) header field, unless it
        was to distinguish delivery reports.

     Converted Indication

        Supported by a new [RFC 822](./rfc822) header.

     Delivery Time Stamp Indication

        N/A.

     Message Identification

        Supported, by use of a new [RFC 822](./rfc822) header.  This new header
        is required, as X.400 has two message-ids whereas [RFC 822](./rfc822)
        has only one.

     Non-delivery Notification

        Not supported, although in general an [RFC 822](./rfc822) system will
        return errors as IP messages.  In other elements, this
        pragmatic result is treated as effective support of this
        service element.

     Original Encoded Information Types Indication

        Supported as a new [RFC 822](./rfc822) header.

     Registered Encoded Information Types

        N/A.

     Submission Time Stamp Indication

        Supported.

     Alternate Recipient Allowed

        Not supported.  Any value is ignored by the gateway.

     Deferred Delivery

        Support is optional.  The framework is provided so that
        messages may be held at the gateway.  However, a gateway

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        following this specification does not have to do this.  This
        is in line with the emerging functional standards.

     Deferred Delivery Cancellation

        Supported.

     Delivery Notification

        Supported at gateway.  Thus, a notification is sent by the
        gateway to the originator  <2>.

     Disclosure of Other Recipients

        Supported by use of a new [RFC 822](./rfc822) header.

     Grade of Delivery Selection

        Supported as a new [RFC 822](./rfc822) header.  In general, this will
        only be for user information in the [RFC 822](./rfc822) world.

     Multi-Destination Delivery

        Supported.

     Prevention of Non-delivery Notification

        Not Supported, as there is no control in the [RFC 822](./rfc822) world
        (but see Non-delivery Notification).

     Return of Contents

        This is normally the case, although the user has no control
        (but see Non-delivery Notification).

     Conversion Prohibition

        Supported.  Note that in practice this support is restricted
        by the nature of the gateway.

     Explicit Conversion

        Supported, for appropriate values (See the IPMS Typed Body
        service element).

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     Implicit Conversion

        Supported, in the sense that there will be implicit
        conversion to IA5 in cases where this is practical.

     Probe

        Supported at the gateway (i.e. the gateway services the
        probe).

     Alternate Recipient Assignment

        N/A.

     Hold for Delivery

        N/A.

  2.2.2.  Interpersonal Message Service Elements

     IP-message Identification

        Supported.

     Typed Body

        Supported.  IA5 is fully supported.  ForwardedIPMessage is
        supported, with some loss of information.  A subset of TTX
        is supported (see [section 5](#section-5) for the specification of this
        subset), with some loss of information.  SFD may be
        supported, with some loss of information.  TTX and SFD are
        only supported when conversion is allowed.  Other types are
        not supported.

     Blind Copy Recipient Indication

        Supported.

     Non-receipt Notification

        Not supported.

     Receipt Notification

        Not supported.

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     Auto-forwarded Indication

        Supported as new [RFC 822](./rfc822) header.

     Originator Indication

        Supported.

     Authorising User's Indication

        Supported, although the mapping (From:) is not quite the
        same.

     Primary and Copy Recipients Indication

        Supported.

     Expiry Date Indication

        Supported as new [RFC 822](./rfc822) header.  In general, only human
        action can be expected.

     Cross Referencing Indication

        Supported.

     Importance Indication

        Supported as new [RFC 822](./rfc822) header.

     Obsoleting Indication

        Supported as new [RFC 822](./rfc822) header.

     Sensitivity Indication

        Supported as new [RFC 822](./rfc822) header.

     Subject Indication

        Supported.

     Reply Request Indication

        Supported as comment next to address.

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     Forwarded IP-message Indication

        Supported, with some loss of information.

     Body Part Encryption Indication

        Not supported.

     Multi-part Body

        Supported, with some loss of information, in that the
        structuring cannot be formalised in [RFC 822](./rfc822).

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Chapter 3 -- Basic Mappings

3.1. Notation

  The P1 and P2 protocols are encoded in a structured manner
  according to the X.409 specifications, whereas [RFC 822](./rfc822) is text
  encoded.  To define a detailed mapping, it is necessary to refer
  to detailed protocol elements in each format.  This is described.

  3.1.4.  [RFC 822](./rfc822)

     Structured text is defined according to the Extended Backus
     Naur Form (EBNF) defined in [section 2 of RFC 822](./rfc822#section-2) [Crocker82a].
     In the EBNF definitions used in this specification, the syntax
     rules given in [Appendix D of RFC 822](./rfc822#appendix-D) are assumed.  When these
     EBNF tokens are referred to outside an EBNF definition, they
     are identified by the string "882." appended to the beginning
     of the string (e.g. 822.addr-spec).  Additional syntax rules,
     to be used throughout this specification are defined in this
     chapter.

     The EBNF is used in two ways.

        1.   To describe components of [RFC 822](./rfc822) messages (or of
             822-P1 components).  In this case, the lexical analysis
             defined in [section 3 of RFC 822](./rfc822#section-3) should be used.  When
             these new EBNF tokens are referred to outside an EBNF
             definition, they are identified by the string "EBNF."
             appended to the beginning of the string (e.g.
             EBNF.bilateral-info).

        2.   To describe the structure of IA5 or ASCII information
             not in an [RFC 822](./rfc822) message.  In these cases, tokens will
             either be self delimiting, or be delimited by self
             delimiting tokens.  Comments and LWSP are not used as
             delimiters.

  3.1.5.  X.409

     An element is referred to with the following syntax, defined in
     EBNF:

        element        = protocol "." definition *( "." definition )
        protocol       = "P1" / "P2"
        definition     = identifier / context
        identifier     = ALPHA *< ALPHA or DIGIT or "-" >
        context        = "[" 1*DIGIT "]"

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     For example, P2.Heading.subject defines the subject element of
     the P2 heading.  The same syntax is also used to refer to
     element values. For example,
     P1.EncodedInformationTypes.[0].g3Fax refers to a value of
     P1.EncodedInformationTypes.[0] .

3.2. ASCII and IA5

  A gateway will interpret all IA5 as ASCII.  Thus, they are treated
  identically for the rest of this document.

3.3. Universal Primitives

  There is a need to convert between ASCII text, and some of the
  Universal Primitive types defined in X.409 [CCITT84d].  For each
  case, an EBNF syntax definition is given, for use in all of this
  specification.  All EBNF syntax definitions of Universal
  Primitives are in lower case, whereas X.409 primitives are
  referred to with the first letter in upper case.  Except as noted,
  all mappings are symmetrical.

  3.3.1.  Boolean

     Boolean is encoded as:

        boolean = "TRUE" / "FALSE"

  3.3.2.  NumericString

     NumericString is encoded as:

        numericstring = *DIGIT

  3.3.3.  PrintableString

     PrintableString is a restricted IA5String defined as:

        printablestring  = *( ps-char / ps-delim )

        ps-char          = 1DIGIT /  1ALPHA / " " / "'" / "+" / ")"
                           / "," / "-" / "." / "/" / ":" / "=" / "?"

        ps-delim         = "("

     A structured subset of EBNF.printablestring is now defined.
     This can be used to encode ASCII in the PrintableString
     character set.

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        ps-encoded       = *( ps-char / ps-encoded-char )

        ps-encoded-char  =   "(a)"               ; (@)
                           / "(p)"               ; (%)
                           / "(b)"               ; (!)
                           / "(q)"               ; (")
                           / "(u)"               ; (_)
                           / "(" 3DIGIT ")"

     The 822.3DIGIT in EBNF.ps-encoded-char must have range 0-127
     (Decimal), and is interpreted in decimal as the corresponding
     ASCII character. Special encodings are given for: at sign (@),
     percent (%), exclamation mark/bang (!), double quote ("), and
     underscore (_).  These characters are not included in
     PrintableString, but are common in [RFC 822](./rfc822) addresses.  The
     abbreviations will ease specification of [RFC 822](./rfc822) addresses from
     an X.400 system.

     An asymmetric mapping between PrintableString and ASCII can now
     be defined <3>.  To encode ASCII as PrintableString, the
     EBNF.ps-encoded syntax is used, with all EBNF.ps-char AND
     EBNF.ps-delim mapped directly <4>.  All other 822.CHAR are
     encoded as EBNF.ps-encoded-char. There are two cases of
     encoding PrintableString as ASCII.  If the PrintableString can
     be parsed as EBNF.ps-encoded, then the previous mapping should
     be reversed.  If not, it should be interpreted as
     EBNF.printablestring.

     Some examples are now given.  Note the arrows which indicate
     asymmetrical mappings:

        PrintableString           ASCII

        'a demo.'         <->   'a demo.'
        foo(a)bar         <->   foo@bar

        (q)(u)(p)(q)      <->   "_%"
        (a)               <->   @
        (a)               <-    (a)
        (040)a(041)       ->    (a)
        (040)(a)          ->    (@
        ((a)              <-    (@

     The algorithm is designed so that it is simple to use in all
     common cases, so that it is general, and so that it is
     straightforward to code.  It is not attempting to minimise the
     number of pathological cases.

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  3.3.4.  T.61String

     T.61 strings are, in general, only used for conveying human
     interpreted information.  Thus, the aim of a mapping should be
     to render the characters appropriately in the remote character
     set, rather than to maximise reversibility.  The mappings
     defined in the CEN/CENELEC X.400 functional standard should be
     used [CEN/CENELEC/85a].  These are based on the mappings of
     X.408 (sections [4.2.2](#section-4.2.2) and [5.2.2](#section-5.2.2)).

  3.3.5.  UTCTime

     Both UTCTime and the [RFC 822](./rfc822) 822.date-time syntax contain: Year
     (lowest two digits), Month, Day of Month, hour, minute, second
     (optional), and Timezone.  822.date-time also contains an
     optional day of the week, but this is redundant.  Therefore a
     symmetrical mapping can be made between these constructs <5>.
     The UTCTime format which specifies the timezone offset should
     be used, in line with CEN/CENELEC recommendations.

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Chapter 4 -- Addressing

Addressing is probably the trickiest problem of an X.400 <-> RFC 822 gateway. Therefore it is given a separate chapter. This chapter, as a side effect, also defines a standard textual representation of X.400 addresses.

Initially we consider an address in the (human) mail user sense of "what is typed at the mailsystem to reference a human". A basic RFC 822 address is defined by the EBNF EBNF.822-address:

  822-address     = [ route ] addr-spec

In an 822-P1 protocol, the originator and each recipient should be considered to be defined by such a construct. In an RFC 822 header, the EBNF.822-address is encapsulated in the 822.address syntax rule, and there may also be associated comments. None of this extra information has any semantics, other than to the end user.

The basic X.400 address is defined by P1.ORName. In P1 all recipient P1.ORnames are encapsulated within P1.RecipientInfo, and in P2 all P2.ORNames <6> are encapsulated within P2.ORDescriptor.

It can be seen that RFC 822 822.address must be mapped with P2.ORDescriptor, and that RFC 822 EBNF.822-address must be mapped with P1.ORName (originator) and P1.RecipientInfo (recipients).

This chapter is structured as follows:

  4.1  Introduction.

  4.2  A textual representation of P1.ORName.  This is needed for
       the later mappings, and as a side effect provides a standard
       representation for O/R names.

  4.3  Mapping between EBNF.822-address and P1.ORName

  4.4  The Full P1 / 822-P1 Mapping

  4.5  The Full P2 / [RFC 822](./rfc822) Mapping

  4.6  Mapping Message-IDs.

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4.1. A textual representation of P1.ORName.

  P1.ORName is structured as a set of attribute value pairs.  It is
  clearly necessary to be able to encode this in ASCII for
  gatewaying purposes.  A general encoding is given here, which may
  be used as a basis for a user interface, as well as for the
  defined gateway mapping.

  4.1.1.  Basic Representation

     A series of BNF definitions of each possible attribute value
     pair is given, which is given a 1:1 mapping with the X.400
     encoding.  The rest of the mapping then talks in terms of these
     BNF components, with the mapping to X.400 encoding being
     trivial.

     attributevalue = c / admd / prmd / x121 / t-id / o / ou
                     / ua-id / pn.g / pn.i / pn.s / pn.gq / dd.value

     c        = printablestring       ; P1.CountryName
     admd     = printablestring       ; P1.AdministrationDomainName
     prmd     = printablestring       ; P1.PrivateDomainName
     x121     = numericstring         ; P1.X121Address
     t-id     = numericstring         ; P1.TerminalID
     o        = printablestring       ; P1.OrganisationName
     ou       = printablestring       ; P1.OrganisationalUnit
     ua-id    = numericstring         ; P1.UniqueUAIdentifier
     pn.s     = printablestring       ; P1.PersonalName.surName
     pn.g     = printablestring       ; P1.PersonalName.givenName
     pn.i     = printablestring       ; P1.PersonalName.initials
     pn.gq    = printablestring       ; P1.PersonalName.generation
                                        Qualifier
     dd.value = printablestring       ; P1.DomainDefined
                                        Attribute.value

     In cases where an attribute can be encoded as either a
     PrintableString or NumericString (Country, ADMD, PRMD) it is
     assumed that the NumericString encoding will be adopted if
     possible.  This prevents the encoding of PrintableString where
     the characters are all numbers. This restriction seems
     preferable to the added complexity of a general solution.
     Similarly, we can define a set of attribute types.

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     dd.type = printablestring      ; P1.DomainDefinedAttribute.type

     standard-type =
               "C"           ; P1.CountryName
             / "ADMD"        ; P1.AdministrationDomainName
             / "PRMD"        ; P1.PrivateDomainName
             / "X121"        ; P1.X121Address
             / "T-ID"        ; P1.TerminalID
             / "O"           ; P1.OrganisationName
             / "OU"          ; P1.OrganisationalUnit
             / "UA-ID"       ; P1.UniqueUAIdentifier
             / "S"           ; P1.PersonalName.surName
             / "G"           ; P1.PersonalName.givenName
             / "I"           ; P1.PersonalName.initials
             / "GQ"          ; P1.PersonalName.generationQualifier

     standard-dd-type =
               "[RFC-822](./rfc822)"     ; dd.type = "[RFC-822](./rfc822)"
             / "JNT-Mail"    ; dd.type = "JNT-Mail"
             / "UUCP"        ; dd.type = "UUCP"

  4.1.2.  Encoding of Personal Name

     Handling of Personal Name based purely on the
     EBNF.standard-type syntax defined above is likely to be clumsy.
     It seems desirable to utilise the "human" conventions for
     encoding these components.  A syntax is proposed here.  It is
     designed to cope with the common cases of O/R Name
     specification where:

        1.   There is no generational qualifier

        2.   Initials contain only letters <7>.

        3.   Given Name does not contain full stop ("."), and is at
             least two characters long.

        4.   If Surname contains full stop, then it may not be in
             the first two characters, and either initials or given
             name is present.

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     The following EBNF is defined:

        encoded-pn      = [ given "." ] *( initial "." ) surname

        given           = 2*<ps-char not including ".">

        initial         = ALPHA

        surname         = printablestring

     Subject to the above restriction, this is a reversible mapping.

     For example:

        GivenName       = "Marshall"
        Surname         = "Rose"

        Maps with  "Marshall.Rose"

        Initials        = "MT"
        Surname         = "Rose"

        Maps with  "M.T.Rose"

        GivenName       = "Marshall"
        Initials        = "MT"
        Surname         = "Rose"

        Maps with  "Marshall.M.T.Rose"

     Note that CCITT guidelines suggest that Initials is used to
     encode ALL initials.  Therefore, the proposed encoding is
     "natural" when either GivenName or Initials, but not both, are
     present.  The case where both are present can be encoded, but
     this appears to be contrived!

  4.1.3.  Two encodings of P1.ORName

     Given this structure, we can specify a BNF representation of an
     O/R Name.

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        std-orname      = 1*( "/" attribute "=" value ) "/"
        attribute       = standard-type
                        / "PN"
                        / standard-dd-type
                        / registered-dd-type
                        / "DD." std-printablestring
        value           = std-printablestring
        registered-dd-type
                        = std-printablestring
        std-printablestring =
                        = *( std-char / std-pair )
        std-char        = <ps-delim, and any ps-char except "/"
                          and "=">
        std-pair        = "$" ( ps-delim / ps-char )

     If the type is PN, the value is interpreted according to
     EBNF.encoded-pn, and the components of P1.PersonalName derived
     accordingly.  If the value is registered-dd-type, if the value
     is registered at the SRI NIC as an accepted Domain Defined
     Attribute type, then the value should be interpreted
     accordingly.  This restriction maximises the syntax checking
     which can be done at a gateway.

     Another syntax is now defined.  This is intended to be
     compatible with the syntax used for 822.domains.  This syntax
     is not intended to be handled by users.

        dmn-orname      = dmn-part *( "." dmn-part )
        dmn-part        = attribute "$" value
        attribute       = standard-type
                        / "~" dmn-printablestring
        value           = dmn-printablestring
        dmn-printablestring =
                        = *( dmn-char / dmn-pair )
        dmn-char        = <ps-delim, and any ps-char except ".">
        dmn-pair        = "\."

     For example: C$US.ADMD$ATT.~ROLE$Big\.Chief

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RFC 987 June 1986 Mapping between X.400 and RFC 822

4.2. Mapping between EBNF.822-address and P1.ORName

  Ideally, the mapping specified would be entirely symmetrical and
  global, to enable addresses to be referred to transparently in the
  remote system, with the choice of gateway being left to the
  Message Transfer Service.  There are two fundamental reasons why
  this is not possible:

     1.   The syntaxes are sufficiently different to make this
          awkward.

     2.   In the general case, there would not be the necessary
          administrative co-operation between the X.400 and [RFC 822](./rfc822)
          worlds, which would be needed for this to work.

  Therefore, an asymmetrical mapping is defined.

  4.2.1.  X.400 encoded in [RFC 822](./rfc822)

     The std-orname syntax is  used to encode O/R Name information
     in the 822.local-part of EBNF.822-address.  Further  O/R Name
     information may be associated with the 822.domain component.
     This cannot be used in the general case, basically due to
     character set problems, and lack of order in X.400 O/R Names.
     The only way to encode the full PrintableString character set
     in a domain is by use of the 822.domain-ref syntax.  This is
     likely to cause problems on many systems.  The effective
     character set of domains is in practice reduced from the
     [RFC 822](./rfc822) set, by restrictions imposed by domain conventions and
     policy.

     A generic 822.address consists of a 822.local-part and a
     sequence of 822.domains (e.g.
     <@domain1,@domain2:user@domain3>).  All except the 822.domain
     associated with the 822.local-part (domain3 in this case)
     should be considered to specify routing within the [RFC 822](./rfc822)
     world, and will not be interpreted by the gateway (although
     they may have identified the gateway from within the [RFC 822](./rfc822)
     world).  The 822.domain associated with the 822.local-part may
     also identify the gateway from within the [RFC 822](./rfc822) world.  This
     final 822.domain may be used to determine some number of O/R
     Name attributes.  The following O/R Name attributes are
     considered as a hierarchy, and may be specified by the domain.
     They are (in order of hierarchy):

        Country, ADMD, PRMD, Organisation, Organisational Unit

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RFC 987 June 1986 Mapping between X.400 and RFC 822

     There may be multiple Organisational Units.

     Associations may be defined between domain specifications, and
     some set of attributes.  This association proceeds
     hierarchically: i.e. if a domain implies ADMD, it also implies
     country.  If one of the hierarchical components is omitted from
     an X.400 structure, this information can be associated with the
     corresponding domain (e.g. a domain can be mapped onto a
     Country/ADMD/Organisation tuple). Subdomains under this are
     associated according to the O/R Name hierarchy.  For example:

        => "AC.UK" might be associated with
                                      C="234", ADMD="BT", PRMD="DES"

        then domain "R-D.Salford.AC.UK" maps with
               C="234", ADMD="BT", PRMD="DES", O="Salford", OU="R-D"

     There are two basic reasons why a domain/attribute mapping
     might be maintained, as opposed to using simply subdomains:

        1.   As a shorthand to avoid redundant X.400 information.
             In particular, there will often be only one ADMD per
             country, and so it does not need to be given
             explicitly.

        2.   To deal with cases where attribute values do not fit
             the syntax:

           domain-syntax   = ALPHA [ *alphanumhyphen alphanum ]
           alphanum        = <ALPHA or DIGIT>
           alphanumhyphen  = <ALPHA or DIGIT or HYPHEN>

     Although [RFC 822](./rfc822) allows for a more general syntax, this
     restriced syntax is chosen as it is the one chosen by the
     various domain service administrations.

     This provides a general aliasing mechanism.

     This set of mappings need only be known by the gateways
     relaying between the [RFC 822](./rfc822) world, and the O/R Name namespace
     associated with the mapping in question.  However, it is
     desirable (for the optimal mapping of third party addresses)
     for all gateways to know these mappings.  A format for the
     exchange of this information is defined in [Appendix F](#appendix-F).

     From the standpoint of the [RFC 822](./rfc822) Message Transfer System, the
     domain specification is simply used to route the message in the

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     standard manner.  The standard domain mechanisms are used to
     identify gateways, and are used to select appropriate gateways
     for the corresponding O/R Name namespace.  In most cases, this
     will be done by registering the higher levels, and assuming
     that the gateway can handle the lower levels.

     As a further mechanism to simplify the encoding of common
     cases, where the only attributes to be encoded on the LHS are
     Personal Name attributes which comply with the restrictions of
     4.2.2, the 822.local-part may be encoded as EBNF.encoded-pn.

     An example encoding is:

        /PN=J.Linnimouth/GQ=5/@Marketing.Xerox.COM

        encodes the P1.ORName consisting of

           P1.CountryName                  = "US"
           P1.AdministrationDomainName     = "ATT"
           P1.OrganisationName             = "Xerox"
           P1.OrganisationalUnit           = "Marketing"
           P1.PersonalName.surName         = "Linnimouth"
           P1.PersonalName.initials        = "J"
           P1.PersonalName.GenerationQualifier = "5"

        If the GenerationQualifier was not present, the encoding
        J.Linnimouth@Marketing.Xerox.COM could be used.

     Note that in this example, the first three attributes are
     determined by the domain Xerox.COM.  The OrganisationalUnit is
     determined systematically.

     There has been an implicit assumption that an [RFC 822](./rfc822) domain is
     either X.400 or [RFC 822](./rfc822).  This is pragmatic, but undesirable,
     as the namespace should be structured on a logical basis which
     does not necessarily correspond to the choice of Message
     Transfer protocols. The restriction can be lifted, provided
     that the nameservice deals with multiple message transfer
     protocols.  This can happen in a straightforward manner for the
     UK NRS, as explained in [Kille86a].  It could also be achieved
     with the DARPA Domain Nameserver scheme by use of the WKS
     mechanism.

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  4.2.2.  [RFC 822](./rfc822) Encoded in X.400

     In some cases, the encoding defined above may be reversed, to
     give a "natural" encoding of genuine [RFC 822](./rfc822) addresses.  This
     depends largely on the allocation of appropriate management
     domains.

     The general case is mapped by use of domain defined attributes.
     Three are defined, according to the full environment used to
     interpret the [RFC 822](./rfc822) information.

        1.   Domain defined type "[RFC-822](./rfc822)".  This string is to be
             interpreted in the context of [RFC 822](./rfc822), and [RFC 920](./rfc920)
             [Crocker82a,Postel84a].

        2.   Domain defined type "JNT-Mail".  This string is to be
             interpreted in the context of the JNT Mail protocol,
             and the NRS [Kille84a,Larmouth83a].

        3.   Domain defined type "UUCP".  This is interpreted
             according to the constraints of the UUCP world
             [Horton86a].

     These three are values currently known to be of use.  Further
     recognised values may be defined.  These will be maintained in
     a list at the SRI Network Information Center.

     Other O/R Name attributes will be used to identify a context in
     which the O/R Name will be interpreted.  This might be a
     Management Domain, or some part of a Management Domain which
     identifies a gateway MTA.  For example:

        1)

        C               = "GB"
        ADMD            = "BT"
        PRMD            = "AC"
        "JNT-Mail"      = "Jimmy(a)UK.CO.BT-RESEARCH-LABS"

        2)

        C               = "US"
        ADMD            = "Telemail"
        PRMD            = "San Fransisco"
        O               = "U Cal"
        OU              = "Berkeley"
        "[RFC-822](./rfc822)"       = "postel(a)usc-isib.arpa"

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RFC 987 June 1986 Mapping between X.400 and RFC 822

     Note in each case the PrintableString encoding of "@" as "(a)".
     In the first example, the "JNT-Mail" domain defined attribute
     is interpreted everywhere within the (Administrative or
     Private) Management Domain.  In the second example, further
     attributes are needed within the Management Domain to identify
     a gateway.  Thus, this scheme can be used with varying levels
     of Management Domain co-operation.

  4.2.3.  [RFC 822](./rfc822) -> X.400

     There are two basic cases:

        1.   X.400 addresses encoded in [RFC 822](./rfc822).  This will also
             include [RFC 822](./rfc822) addresses which are given reversible
             encodings.

        2.   "Genuine" [RFC 822](./rfc822) addresses.

     The mapping should proceed as follows, by first assuming case
     1).

     STAGE 1.

        1.   If the 822-address is not of the form:

           local-part "@" domain

           go to stage 2.

        2.   Attempt to parse domain as:

           *( domain-syntax "." ) known-domain

           Where known-domain is the longest possible match in a
           list of gatewayed domains.  If this fails, and the domain
           does not explicitly identify the local gateway, go to
           stage 2.  If it succeeds, allocate the attributes
           associated with EBNF.known-domain, and systematically
           allocate the attributes implied by each
           EBNF.domain-syntax component.

        3.   Map 822.local-part to ASCII, according to the
             definition of [Appendix A](#appendix-A).  This step should be applied:

           A.  If the source network cannot support
               822.quoted-string (as discussed in [Appendix A](#appendix-A)).

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RFC 987 June 1986 Mapping between X.400 and RFC 822

           B.  If the address is an 822-P1 recipient.

              This mapping is always applied in case B, as it
              increases the functionality of the gateway, and does
              not imply any loss of generality.  Mapping case B
              allows sites which cannot generate 822.quoted-string
              to address recipients the gateway, without the gateway
              having to know this explicitly.  There is no loss of
              functionality, as the quoting character of [Appendix A](#appendix-A)
              (#) is not in PrintableString.  This seems desirable.
              It should not be applied in to other addresses, as a
              third party RFC#822 address containing the sequence
              EBNF.atom-encoded (as defined in [Appendix A](#appendix-A)) would be
              transformed asymmetrically.

        4.   Map the result of 3) to EBNF.ps-encoded according to
             [section 3](#section-3).

        5.   Parse the result of 4) according to the EBNF
             EBNF.std-orname.  If this parse fails, parse the result
             of 4) according to the EBNF EBNF.encoded-pn.  If this
             also fails, go to stage 2.  Otherwise, the result is a
             set of type/value pairs.

        6.   Associate the EBNF.attribute-value syntax (determined
             from the identified type) with each value, and check
             that it conforms.  If not, go to stage 2.

        7.   Ensure that the set of attributes conforms both to the
             X.411 P1.ORName specification and to the restrictions
             on this set given in X.400.  If not go to stage 2.

        8.   Build the O/R Name from this information.

     STAGE 2.

     This will only be reached if the [RFC 822](./rfc822) EBNF.822-address is
     not a valid X.400 encoding.  If the address is an 822-P1
     recipient address, it must be rejected, as there is a need to
     interpret such an address in X.400.  For the 822-P1 return
     address, and any addresses in the [RFC 822](./rfc822) header, they should
     now be encoded as [RFC 822](./rfc822) addresses in an X.400 O/R Name:

        1.   Convert the EBNF.822-address to PrintableString, as
             specified in chapter 3.

        2.   The domain defined attribute ("[RFC-822](./rfc822)", "JNT-Mail" or

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RFC 987 June 1986 Mapping between X.400 and RFC 822

             "UUCP") appropriate to the gateway should be selected,
             and its value set.

        3.   Build the rest of the O/R Name in the local Management
             Domain agreed manner, so that the O/R Name will receive
             a correct global interpretation.

  4.2.4.  X.400 -> [RFC 822](./rfc822)

     There are two basic cases:

        1.   [RFC 822](./rfc822) addresses encoded in X.400.

        2.   "Genuine" X.400 addresses.  This may include
             symmetrically encoded [RFC 822](./rfc822) addresses.

     When a P1 Recipient O/R Name is interpreted, gatewaying will be
     selected if there a single special domain defined attribute
     present ("[RFC-822](./rfc822)", "JNT-Mail" or "UUCP").  In this case, use
     mapping A.  For other O/R Names which

        1.   Contain the special attribute.

           AND

        2.   Identify the local gateway with the other attributes.

     Use mapping A.  In other cases, use mapping B.

     Mapping A

        1.   Map the domain defined attribute value to ASCII, as
             defined in chapter 3.

        2.   Where appropriate (P1 recipients), interpret the string
             according to the semantics implied by the domain
             defined attribute.

     Mapping B.

     This will be used for X.400 addresses which do not use the
     explicit [RFC 822](./rfc822) encoding.

        1.   Noting the hierarchy specified in 4.3.1, determine the
             maximum set of attributes which have an associated
             domain specification. If no match is found, allocate

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RFC 987 June 1986 Mapping between X.400 and RFC 822

             the domain as the domain specification of the local
             gateway, and go to step 4.

        2.   Following the 4.3.1 hierarchy, if each successive
             component exists, and conforms to the syntax
             EBNF.domain-syntax (as defined in 4.3.1), allocate the
             next subdomain.

        3.   If the remaining components are personal-name
             components, conforming to the restrictions of 4.2.2,
             then EBNF.encoded-pn should be derived to form
             822.local-part.  In other cases the remaining
             components should simply be encoded as a 822.local-part
             using the EBNF.std-orname syntax.  Where registered
             domain defined types exist, the DD. syntax should not
             be used.

        4.   If this step is reached for an 822-P1 recipient, then
             the address is invalid.  For other addresses, if the
             derived 822.local-part can only be encoded by use of
             822.quoted-string, the gateway may optionally use the
             ASCII to 822.local-part mapping defined in [Appendix A](#appendix-A),
             dependent on the mail protocols of the networks being
             relayed to.  Use of this encoding is discouraged.

4.3. Repeated Mappings

  The mappings defined are symmetrical across a single gateway,
  except in certain pathological cases (see chapter 3).  However, it
  is always possible to specify any valid address across a gateway.
  This symmetry is particularly useful in cases of (mail exploder
  type) distribution list expansion.  For example, an X.400 user
  sends to a list on an [RFC 822](./rfc822) system which he belongs to.  The
  received message will have the originator and any 3rd party X.400
  O/R names in correct format (rather than doubly encoded).  In
  cases (X.400 or [RFC 822](./rfc822)) where there is common agreement on
  gateway identification, then this will apply to multiple gateways.

  However, the syntax may be used to source route.

  For example:  X.400 -> [RFC 822](./rfc822)  -> X.400

     C               = "UK"
     ADMD            = "BT"
     PRMD            = "AC"
     "JNT-Mail"      = "/PN=Duval/DD.Title=Manager/(a)FR.PTT.Inria"

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     This will be sent to an arbitrary UK Academic Community gateway
     by X.400.  Then by JNT Mail to another gateway determined by
     the domain FR.PTT.Inria.  This will then derive the X.400 O/R
     Name:

        C               = "FR"
        ADMD            = "PTT"
        PRMD            = "Inria"
        PN.S            = "Duval"
        "Title"         = "Manager"

  Similarly:  [RFC 822](./rfc822) -> X.400 -> [RFC 822](./rfc822)

     "/C=UK/ADMD=BT/PRMD=AC/RFC-822=jj(a)seismo.css.gov/"
                                                 @monet.berkeley.edu

     /C=UK/ADMD=BT/PRMD=AC/RFC-822=jj#l#a#r#seismo.css.gov/
                                                 @monet.berkeley.edu

     The second case uses the [Appendix A](#appendix-A) encoding to avoid
     822.quoted-text. This will be sent to monet.berkeley.edu by
     [RFC 822](./rfc822), then to the AC PRMD by X.400, and then to
     jj@seismo.css.gov by [RFC 822](./rfc822).

4.4. The full P1 / 822-P1 mapping

  There are two basic mappings at the P1 level:

     1.   822-P1 return address <-> P1.UMPDUEnvelope.originator

     2.   822-P1 recipient <-> P1.RecipientInfo

  822-P1 recipients and return addresses are encoded as
  EBNF.822-address.  As P1.UMPDUEnvelope.originator is encoded as
  P1.ORName, mapping 1) has already been specified.
  P1.RecipientInfo contains a P1.ORName and additional information.
  The handling of this additional information is now specified.

  4.4.1.  [RFC 822](./rfc822) -> X.400

     The following default settings should be made for each
     component of P1.RecipientInfo.

        P1.ExtensionIdentifier

           This can be set systematically by the X.400 system.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

        P1.RecipientInfo.perRecipientFlag

           Responsibility Flag should be set.  Report Request should
           be set according to content return policy, as discussed
           in [section 5.3](#section-5.3). User Report Request should be set to
           Basic.

        P1.ExplicitConversion

           This optional component should be omitted.

  4.4.2.  X.400 -> [RFC 822](./rfc822)

     The mapping only takes place in cases where
     P1.RecipientInfo.perRecipientFlag Responsibility Flag is set.
     The following treatment should be given to the other
     P1.RecipientInfo components.

        P1.ExtensionIdentifier

           Not used.

        P1.RecipientInfo.perRecipientFlag

           If ReportRequest is Confirmed or Audit-and-Confirmed then
           a delivery report indicating success should be sent by
           the gateway. This report should use each
           P1.ReportedRecipientInfo.SupplementaryInformation to
           indicate the identity of the gateway, and the nature of
           the report (i.e. only as far as the gateway).  Failures
           will be handled by returning [RFC 822](./rfc822) messages, and so
           User Report Request set to No report is ignored.

        P1.ExplicitConversion

           If present, the O/R name should be rejected, unless the
           requested conversion can be achieved.  None of the
           currently recognised values of this parameter are
           appropriate to a gateway using this specification.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

4.5. The full P2 / RFC 822 mapping

  All [RFC 822](./rfc822) addresses are assumed to use the 822.mailbox syntax.
  This should include all 822.comments associated with the lexical
  tokens of the 822.mailbox.  All P2.ORNames are encoded within the
  syntax P2.ORDescriptor, or P2.Recipient (or within Message IDs).
  An asymmetrical mapping is defined between these components.

  4.5.1.  [RFC 822](./rfc822) -> X.400

     The following sequence is followed.

        1.   Take the address, and extract an EBNF.822-address.
             This can be derived trivially from either the
             822.addr-spec or 822.route-addr syntax.  This is mapped
             to P2.ORName as described above.

        2.   A string should be built consisting of (if present):

           -    The 822.phrase component if it is a 822.phrase
                822.route-addr construct.

           -    Any 822.comments, in order, retaining the
                parentheses.

              This string should then be encoded into T.61 (as
              described in chapter 3).  If the string is not null,
              it should be assigned to P2.ORDescriptor.freeformName.

        3.   P2.ORDescriptor.telephoneNumber should be omitted.

        4.   In cases of converting to P2.Recipient,
             P2.Recipient.replyRequest and
             P2.Recipient.reportRequest should be omitted.

     If the 822.group construct is present, each included
     822.mailbox should be encoded as above.  The 822.group should
     be mapped to T.61, and a P2.ORDesciptor with only a
     freeformName component built from it.

  4.5.2.  X.400 -> [RFC 822](./rfc822)

     In the basic case, where P2.ORName is present, proceed as
     follows.

        1.   Encode P2.ORName as EBNF.822-address.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

        2a.  If P2.ORDescriptor.freeformName is present, convert it
             to ASCII (chapter 3), and use use this as the
             822.phrase component of 822.mailbox using the
             822.phrase 822.route-addr construct.

        2b.  If P2.ORDescriptor.freeformName is absent, if
             EBNF.822-address is parsed as 822.addr-spec use this as
             the encoding of 822.mailbox. If EBNF.822-address is
             parsed as 822.route 822.addr-spec, then a 822.phrase
             taken from 822.local-part should be added.

        3.   If P2.ORDescriptor.telephoneNumber is present, this
             should be placed in a trailing 822.comment.

        4.   If P2.Recipient.reportRequest has the
             receiptNotification bit set, then an 822.comment
             "(Receipt Notification Requested)" should be appended
             to the address.  The effort of correlating P1 and P2
             information is too great to justify the gateway sending
             Receipt Notifications.

        5.   If P2.Recipient.replyRequest is present, an 822.comment
             "(Reply requested)" or "(Reply not requested)" should
             be appended to the address, dependent on its value.

     If P2.ORName is absent, P2.ORDescriptor.freeformName should be
     converted to ASCII, and used with the [RFC 822](./rfc822) 822.group syntax:

        freeformname ":" ";"

     Steps 3-5 should then be followed.

4.6. Message IDs

  There is a need to map both ways between 822.msg-id and
  P2.IPMessageID.  A mapping is defined which is symmetrical for
  non-pathological cases.  The mapping allows for the fact that
  P2.IPMessageID.PrintableString is mandatory for the Cen/Cenelec
  profile.  This allows for good things to happen when messages pass
  multiple times across the X.400/RFC 822 boundary.  A mapping
  between 822.msg-id and P1.MPDUIdentifier is defined.  This allows
  for X.400 error messages to reference an [RFC 822](./rfc822) ID, which is
  preferable to a gateway generated ID.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

  4.6.1.  P2.IPMessageID -> 822.msg-id

     P2.IPMessageID.ORName is used to generate an 822.addr-spec, as
     defined above.  P2.IPMessageID.PrintableString is mapped to
     ASCII, as defined in chapter 3.  This string (if it is present
     and if the value is not "[RFC-822](./rfc822)") is appended to the front of
     the 822.local-part of the 822.msg-id, with "*" as a separator.
     If no ORName is present, an 822.msg-id of the form
     "PrintableString*@gateway-domain" is generated.

  4.6.2.  822.msg-id -> P2.IPMessageID

     822.local-part is parsed as:

        [ printablestring "*" ] real-local-part

     If EBNF.printablestring is found, it is mapped to
     PrintableString, and used as P2.IPMessageID.PrintableString.
     Otherwise
     P2.IPMessageID.PrintableString is set to "[RFC-822](./rfc822)".  This
     arbitrary value allows for conformance to Cen/Cenelec.  If
     EBNF.real-local-part is not present, no P2.IPMessageID.ORName
     is generated.  Otherwise,  822.local-part is replaced with
     EBNF.real-local-part, and 822.addr-spec is mapped to
     P2.IPMessageID.ORName as defined above.

  4.6.3.  822.msg-id -> P1.MPDUIdentifier

     P1.CountryName is assigned to "", P1.AdministrationDomainName
     to 822.domain (from 822.msg-id) and P1.MPDUIdentifier.IA5String
     to 822.local-part (from 822.msg-id).

  4.6.4.  P1.MPDUIdentifier -> 822.msg-id

     822.local-part is set to P1.MPDUIdentifier.IA5String, with any
     CRLF mapped to SPACE.  If P1.CountryName is "", 822.domain is
     set to P1.AdministrationDomainName; Otherwise to
     P1.AdministrationDomainName ".." P1.CountryName.  If there are
     any specials,  the domain literal encoding should be used.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

Chapter 5 -- Protocol Elements

This chapter gives detailed mappings for the functions outlined in chapters 1 and 2. It makes extensive use of the notations and mappings defined in chapters 3 and 4. This chapter is structured as follows:

  5.1. Basic [RFC 822](./rfc822) -> X.400 mappings

  5.2. A definition of some new [RFC 822](./rfc822) elements, and their mapping
       to X.400.

  5.3  Some special handling associated with Return of Contents.

  5.4. X.400 -> [RFC 822](./rfc822)

5.1. RFC 822 -> X.400

  First, the basic functions of an 822-P1 protocol should be mapped
  as follows:

     822-P1 Originator

        Mapped to P1.UMPDUEnvelope.originator (see chapter 4).

     822-P1 Recipient

        Mapped to P1.RecipientInfo (see chapter 4).

  The [RFC 822](./rfc822) headers are used to generate both a P1.UMPDUEnvelope
  and a P2.Heading.  The IP Message will have either one or two
  P2.BodyParts which will be type P2.IA5Text with no
  P2.IA5Text.repertoire component. The last P2.BodyPart will contain
  the [RFC 822](./rfc822) message body.  If there are any [RFC 822](./rfc822) headers which
  indicate mapping into the P2.BodyPart, then two P2.BodyParts are
  generated.  If a revised version of P2 allowed for extensible
  header specification, this would be seen as a preferable mapping.
  The first body part will start with the line:

     [RFC-822](./rfc822)-Headers:

  The rest of this body part will contain all of the headers not
  otherwise mapped (both 822.field-name and 822.field-body).  The
  order of any such headers should be preserved.  Similarly,
  ordering within P2.Heading and P1.UMPDUEnvelope should reflect
  ordering within the [RFC 822](./rfc822) header.  No P1 or P2 optional fields
  are generated unless specified.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

  A pro-forma X.400 message is now specified.  Some of these
  defaults may be changed by the values in the [RFC 822](./rfc822) message being
  mapped.  The mandatory P1 and P2 components have the following
  defaults.

     P1.MPDUIdentifier

        The default should be unique value generated by the gateway.

     P1.OriginatorORName

        Always generated from 822-P1.

     P1.ContentType

        P1.ContentType.p2

     P1.RecipientInfo

        These will always be supplied from 822-P1.

     P1.Trace

        The last P1.TraceInformation component is generated such
        that: P1.TraceInformation.GlobalDomainIdentifier is set to
        the local vaglue.  P1.DomainSuppliedInfo.action is set to
        relayed. P1.DomainSuppliedInfo.arrival is set to the current
        time. P1.DomainSuppliedInfo.previous may be set if there is
        anything sensible to set it to.

     P2.IPMessageID

        The default should be a unique value generated by the
        gateway.

  The following optional parameters should be set:

     P1.PerMessageFlag

        The P1.PerMessageFlag.contentReturnRequest bit should be set
        according to the discussion in [section 5.3](#section-5.3).  The
        P1.PerMessageFlag.alternateRecipientAllowed bit should be
        set, as it seems desirable to maximise opportunity for
        (reliable) delivery.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

  The [RFC 822](./rfc822) headings should be mapped as follows:

     Received:

        Fudged onto P1.TraceInformation (try not to grimace too
        much). P1.DomainSuppliedInfo.action is set to relayed.
        P1.DomainSuppliedInfo.arrival is set to the date-time
        component P1.TraceInformation.GlobalDomainIdentifier has
        P1.CountryName as a null string, and
        P1..AdministrationDomainName as the domain of the receiving
        host (if present - null string if not).
        P1.DomainSuppliedInfo.previous has P1.CountryName as a null
        string, and P1.AdministrationDomainName has the domain of
        the sending host with all other information enclosed in
        round parentheses.  The encoding of ASCII to PrintableString
        (chapter 3) should be used if needed.  For example:

           Received: from 44e.cs.ucl.ac.uk by vax2.Cs.Ucl.AC.UK
                          with SMTP  id a002110; 18 Dec 85 10:40 GMT

              maps to -

              P1.GlobalDomainIdentifier
                 CountryName                  = ""
                 AdministrationDomainName     = "vax2.Cs.Ucl.AC.UK"
              P1.DomainSuppliedInfo
                 arrival                      = 18 Dec 85 10:40 GMT
                 action                       = relayed
                 previous
                    CountryName               = ""
                    AdministrationDomainName  =
                           "44e.cs.ucl.ac.uk (with SMTP id a002110)"

     Date:

        This is used to set the first component of
        P1.TraceInformation. The mandatory components are set as
        follows:

           P1.GlobalDomainIdentifier
              CountryName                  = ""
              AdministrationDomainName     = ""
           P1.DomainSuppliedInfo
              arrival                      = time derived from Date:
              action                       = relayed

        No optional fields are used in the trace.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

     Message-Id:

        Mapped to P2.IPMessageID.  If the [RFC 822](./rfc822) message does not
        contain a P1-Message-ID: field, the Message-Id: field is
        also mapped to P1.MPDUIdentifier.  For these, and all other
        fields containing msg-id the mappings of chapter 4 are used
        for each msg-id.

     From:

        If Sender: is present, this is mapped to
        P2.AuthorisingUsers.  If not, it is mapped to P2.Originator.
        For this, and other components containing addresses, the
        mappings of chapter 4 are used for each address.

     Sender:

        Mapped to P2.Originator.

     Reply-To:

        Mapped to P2.Heading.replyToUsers.

     To:

        Mapped to P2.Heading.primaryRecipients

     Cc:

        Mapped to P2.Heading.copyRecipients.

     Bcc:

        Mapped to P2.Heading.blindCopyRecipients.

     In-Reply-To:

        Mapped to P2.Heading.inReplyTo for the first (if any)
        822.msg-id component.  If the field contains an 822.phrase
        component, or there are multiple 822.msg-id components, the
        ENTIRE field is passed in the P2.BodyPart.

     References:

        Mapped to P2.Heading.crossReferences.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

     Keywords:

        Passed in the P2.BodyPart.

     Subject:

        Mapped to P2.Heading.subject.  The field-body uses the
        mapping referenced in chapter 3 from ASCII to T.61.

     Comments:

        Passed in the P2.BodyPart.

     Encrypted:

        Passed in the P2.BodyPart.

     Resent-*

        Passed in the P2..BodyPart <8>.

     Other Fields

        In particular X-* fields, and "illegal" fields in common
        usage (e.g. "Fruit-of-the-day:") are passed in the
        P2.BodyPart.  The same treatment should be applied to
        [RFC 822](./rfc822) fields where the content of the field does not
        conform to [RFC 822](./rfc822) (e.g. a Date: field with unparsable
        syntax).

5.2. Extended RFC 822 Elements -> X.400

  First an EBNF definition of a number of extended fields is given,
  and then a mapping to X.400 is defined.  In most cases, the
  [RFC 822](./rfc822) syntax is defined to make this mapping very
  straightforward, and so no detailed explanation of the mapping is
  needed.

     extended-field  = "P1-Message-ID" ":" p1-msg-id
                     / "X400-Trace" ":" x400-trace
                     / "Original-Encoded-Information-Types"
                        ":"encoded-info
                     / "P1-Content-Type" ":" p1-content-type
                     / "UA-Content-ID" ":" printablestring
                     / "Priority" ":" priority
                     / "P1-Recipient" : 1 mailbox
                     / "Deferred-Delivery" ":" date-time

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RFC 987 June 1986 Mapping between X.400 and RFC 822

                     / "Bilateral-Info" ":" bilateral-info
                     / "Obsoletes" ":" 1 msg-id
                     / "Expiry-Date" ":" date-time
                     / "Reply-By" ":" date-time
                     / "Importance" ":" importance
                     / "Sensitivity" ":" sensitivity
                     / "Autoforwarded" ":" boolean

     p1-msg-id       = global-id ";" *text

     p1-content-type = "P2" / atom

     x400-trace      = global-id ";"
                     "arrival" date-time
                     [ "deferred" date-time ]
                     [ "action" action ]
                     [ "converted" "(" encoded-info ")" ]
                     [ "previous" global-id ]

     action          = "Relayed" / "Rerouted" / escape

     global-id       = c "*" admd [ "*" prmd ]

     encoded-info    = 1 encoded-type

     encoded-type    = "Undefined"           ; undefined (0)
                     / "Telex"               ; tLX (1)
                     / "IA5-Text"            ; iA5Text (2)
                     / "G3-Fax"              ; g3Fax (3)
                     / "TIF0"                ; tIF0 (4)
                     / "Teletex"             ; tTX (5)
                     / "Videotex"            ; videotex (6)
                     / "Voice"               ; voice (7)
                     / "SFD"                 ; sFD (8)
                     / "TIF1"                ; tIF1 (9)
                     / escape

     priority        = "normal" / "non-urgent" / "urgent" / escape

     bilateral-info  = c "*" admd "*" *text

     importance      = "low" / "normal" / "high" / escape

     sensitivity     = "Personal" / "Private"
                     / "Company-Confidential" / escape

     escape          = 1*DIGIT

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RFC 987 June 1986 Mapping between X.400 and RFC 822

  With the exception of "Bilateral-Info:" and "X400-Trace:", there
  must be no more than one of each of these fields in an [RFC 822](./rfc822)
  header.  Any field beginning with the String "Autoforwarded-" is
  valid if the field would be syntactically valid with this string
  removed.

  The mappings to X.400 are as follows:

     P1-Message-ID:

        Mapped to P1.UMPDUEnvelope.MPDUIdentifier.  This take
        precedence over any value derived from Message-ID:.

     X400-Trace:

        Mapped to the next component of
        P1.UMPDUEnvelope.Traceinformation.  Care should be taken to
        preserve order.  If one or more of these mappings is made,
        then a trace component should NOT be generated from the
        Date: field which should be redundant.  This is because the
        message has previously come from X.400, and the Date:
        information will be redundant.  Note that all trace
        information (Received: and "X400-Trace:") in the [RFC 822](./rfc822)
        message will be in strict order, with the most recent at the
        top.  This order should be preserved in the mapping.

     Original-Encoded-Information-Types:

        This is used to set P1.UMPDUEnvelope.original.
        P1.EncodedInformationTypes.[0] has bits set according to
        each of the encoded-info components in this field.  Any
        escape values should not be encoded.

     P1-Content-Type:

        If the value is anything other than "P2", the mapping should
        not be performed (unless the new value has some semantics to
        the gateway).

     UA-Content-ID:

        Mapped to P1.UMPDUEnvelope.UAContentID.

     Priority:

        Mapped to P1.UMPDUEnvelope.Priority.  An escape value should
        be encoded as P1.Priority.normal.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

     P1-Recipient:

        If this field is set, the
        P1.PerMessageFlag.discloseRecipients bit should be set.  Any
        of the addresses here which do not correspond to 822-P1
        recipients should be added to the P1 recipient list, with
        the responsibility bit turned off.

     Deferred-Delivery:

        Mapped to P1.UMPDUEnvelope.deferredDelivery.  Note that the
        value of this field should always be in the past, as this
        field should only be present in messages which have come
        originally from X.400.  Thus there should be no implied
        action.  See also the comments on the reverse mapping.

     Bilateral-Info:

        No attempt is made to reconvert this information back to
        X.400.

     Obsoletes:

        Mapped to P2.Heading.obsoletes.

     Expiry-Date:

        Mapped to P2.Heading.expiryDate.

     Reply-By:

        Mapped to P2.Heading.replyBy.

     Importance:

        Mapped to P2.Heading.importance.  An escape value should be
        encoded as P2.Heading.importance.normal.

     Sensitivity:

        Mapped to P2.Heading.sensitivity.  An escape value should be
        encoded as P2.Heading.sensitivity.normal.

     Autoforwarded:

        If this field is present and the value is "TRUE", there will
        be zero or more field names beginning "Autoforwarded-".

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RFC 987 June 1986 Mapping between X.400 and RFC 822

        These should be taken, and the string "Autoforwarded-"
        stripped.  These fields, in conjunction with the 822-P1
        information should be used to build an IP Message.  Any
        implied actions should be taken. P2.Heading.autoforwarded is
        set in this message.  The other [RFC 822](./rfc822) fields are used to
        build another IP Message, which is used as the single body
        part of the first message.  This mechanism does not nest.

5.3. Return of Contents

  It is not clear how widely supported X.400 return of contents
  service will be.  However, profiling work suggests that most
  systems will not support this service.  As this service is
  expected in the [RFC 822](./rfc822) world, two approaches are specified (it is
  not so necessary in the X.400 world, as delivery reports are
  distinguished from messages).  The choice will depend on the
  service level of the X.400 community being serviced by the
  gateway.

  In environments where return of contents is widely supported, the
  P1.PerMessageFlag content return request bit will be set, and the
  Report Request bit in P1.PerRecipientFlag will be set to
  Confirmed, for every message passing from [RFC 822](./rfc822) -> X.400.  The
  content return service can then be passed back to the end
  ([RFC 822](./rfc822)) user in a straightforward manner.

  In environments where return of contents is not widely supported,
  a gateway must make special provisions to handle return of
  contents.  For every message passing from [RFC 822](./rfc822) -> X.400, the
  P1.PerMessageFlag content return request bit will be set, and the
  Report Request bit in P1.PerRecipientFlag will be set to
  Confirmed.  When the delivery report comes back, the gateway can
  note that the message has been delivered to the recipient(s) in
  question.  If a non-delivery report is received, a meaningful
  report (containing some or all of the original message) can be
  sent to the 822-P1 originator.  If no report is received for a
  recipient, a (timeout) failure notice should be sent to the 822-P1
  originator.  The gateway may retransmit the X.400 message if it
  wishes.  Delivery confirmations should only be sent back to the
  822-P1 originator if the P1.PerRecipientFlag User Report Request
  bit is set to Confirmed.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

5.4. X.400 -> RFC 822

  5.4.1.  General

     This section describes how to build a pro-forma message, and
     then explains how these defaults may be overridden.  It should
     be noted that [RFC 822](./rfc822) folding of headers should be used in an
     appropriate manner.

  5.4.2.  Service MPDU

     5.4.2.1.  Probe

        Any P1.ProbeMPDU should be serviced by the gateway, as there
        is no equivalent [RFC 822](./rfc822) functionality.  The value of the
        reply is dependent on whether the gateway could service a
        User MPDU with the values specified in the probe.  The reply
        should make use of P1.SupplementaryInformation to indicate
        that the probe was serviced by the gateway.

     5.4.2.2.  Delivery Report

        The 822-P1 components are constructed as follows:

           822-P1 Originator

              This is set to an 822.addr-spec pointing to an
              administrator at the gateway.

           822-P1 Recipient

              The single recipient is constructed from
              P1.DeliveryReportEnvelope.originator, using the
              mappings of chapter 4.

        The mandatory [RFC 822](./rfc822) headers for an [RFC 822](./rfc822) pro-forma are
        constructed as follows:

           Date:

              From the P1.DomainSuppliedInfo.arrival component of
              the first P1.TraceInformation component.

           From:

              This is set to the same as the 822-P1 originator.  An

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RFC 987 June 1986 Mapping between X.400 and RFC 822

              appropriate phrase component may be added (e.g. giving
              the name of the gateway).

           To:

              The same as the 822-P1 recipient.

        A Subject: field should be added, which contains some
        appropriate words (e.g. "Delivery Report").

        The other two P1.DeliveryReportEnvelope parameters should be
        mapped as follows:

           P1.DeliveryReportEnvelope.report

              This should be mapped to a P1-Message-Id: field.

           P1.DeliveryReportEnvelope.TraceInformation

              Each component should be mapped to an "X400-Trace:"
              field.  [RFC 822](./rfc822) and X.400 ordering should be
              maintained (see 5.3).

        The P1.DeliveryReportContent parameters should be mapped to
        a series of new [RFC 822](./rfc822) headers.  These new headers are
        intended for processing in the [RFC 822](./rfc822) world.  No attempt
        will be made to reverse the mappings.

           drc-field    = "Delivery-Report-Content-Original"
                       ":" msg-id
             / "Delivery-Report-Content-Intermediate-Trace"
                       ":" x400-trace
             / "Delivery-Report-Content-UA-Content-ID"
                       ":" printablestring
             / "Delivery-Report-Content-Billing-Information"
                       ":" *text
             / "Delivery-Report-Content-Reported-Recipient-Info"
                       ":" drc-info

           drc-info     = mailbox ";"
                        last-trace ";"
                        "ext" 1*DIGIT
                        "flags" 2DIGIT
                        [ "intended" mailbox ] ";"
                        [ "info" printablestring ]

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RFC 987 June 1986 Mapping between X.400 and RFC 822

           last-trace   = drc-report ";"
                        date-time ";"
                        [ "converted" "(" encoded-info ")"

           drc-report   = "SUCCESS" drc-success
                        / "FAILURE" drc-failure

           drc-success  = date-time ";" 1*DIGIT

           drc-failure  = *text [ ";" *text ] ";"

        There may be multiple
        "Delivery-Report-Content-Intermediate-Trace:" and
        "Delivery-Report-Content-Reported-Recipient-Info:" fields.
        The msg-id for "Delivery-Report-Content-Original" is derived
        according to the mapping of chapter 4.  EBNF.drc-failure may
        use numeric values or textual explanation.  The latter is
        preferred.  All P1.DeliveryReportContent parameters are
        mapped to the corresponding component.  The order of
        "Delivery-Report-Content-Intermediate-Trace:" should have
        the most recently stamped one first.

        The body of the [RFC 822](./rfc822) message should be a human readable
        description of the critical parts of the
        P1.DeliveryReportContent.  In particular, the failed
        recipients, and failure reason should be given.  Some or all
        of the original message should be included in the delivery
        report. The original message will be available at the
        gateway, as discussed in [section 5.3](#section-5.3).

  5.4.3.  User MPDU

     These elements are the basis for both Status Report and IP
     Message.

     The 822-P1 components are constructed as follows:

        822-P1 Originator

           This is derived from P1.UMPDUEnvelope.originator.

        822-P1 Recipient

           Each recipient is constructed from the P1.RecipientInfo,
           as described in chapter 4.  This describes actions as
           well as format mappings.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

     The mandatory [RFC 822](./rfc822) field pro-forma is derived as follows.
     In most cases where the P1.UMPDUContent is an IP Message, these
     defaults will be overridden:

        Date:

           From the P1.DomainSuppliedInfo.arrival component of the
           first P1.TraceInformation component.

        From:

           From the P1.UMPDUEnvelope.originator, as defined in
           chapter 4.

        To:

           This default is only required if the generated [RFC 822](./rfc822)
           message has no destination specification.  If
           P1.PerMessageFlag.discloseRecipients is set then it
           should contain the ORName in each P1.RecipientInfo
           component.  If it is not set, the it should be set to
           "To: No Recipients Specified : ;".

     The mappings, and any actions for each P1.UserMPDU element is
     now considered.

        P1.MPDUIdentifier

           Mapped to the extended [RFC 822](./rfc822) field "P1-Message-ID:".
           Note that the sequence CRLF is mapped to SPACE, which
           makes the mapping irreversible for such cases.

        P1.UMPDUEnvelope.original

           Mapped to the extended [RFC 822](./rfc822) field
           "Original-Encoded-Information-Types:".  If it contains
           only P2.IA5Text, the [RFC 822](./rfc822) field may be omitted.

        P1.ContentType

           As this can currently only have one value, it is not
           mapped, on the basis that it is redundant.  If the field
           contains any value other than P2, then the UMPDU should
           be rejected.

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        P1.UAContentID

           Mapped to the extended [RFC 822](./rfc822) field "UA-Content-Id:".

        P1.Priority

           Mapped to the extended [RFC 822](./rfc822) field "Priority:".

        P1.PerMesageFlag

           This has a number of components:

              - discloseRecipients

                 If this bit is set, a "P1-Recipient:" field should
                 be generated, and contain each of the P1
                 recipients.

              - conversionProhibited

                 If this bit is set, the message should be rejected
                 if it contains P2.BodyPart which is not P2.IA5Text
                 or P2.ForwardedIPMessage.

              - alternateRecipientAllowed

                 The value of this bit is ignored.

              - contentReturnRequest

                 The value of this bit is ignored.

        P1.UMPDUEnvelope.deferredDelivery

           This should be mapped to the extended [RFC 822](./rfc822) field
           "Deferred-Delivery:".  X.400 profiles, and in particular
           the CEN/CENELEC profile [CEN/CENELEC/85a], specify that
           this element must be supported at the first MTA.  Thus,
           it is expected that the value of this element will always
           be in the past.  If it is not, the function may
           optionally be implemented by the gateway: that is, the
           gateway should hold the message until the time specified
           in the protocol element.  Thus the extended [RFC 822](./rfc822) field
           is just for information.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

        P1.PerDomainBilateralInformation

           Each component should be encoded in the extended [RFC 822](./rfc822)
           field "Bilateral-Info:".  P1.BilateralInfo should be
           mapped into ASCII in a manner appropriate to its
           contents.  This submapping is not reversible.

        P1.TraceInformation

           This should be mapped to "X400-Trace:", as for the
           delivery report.

  5.4.4.  Status Report

     The entire status report is mapped into the body of the [RFC 822](./rfc822)
     message, in the same manner as for a Delivery Report.  An
     appropriate "Subject:" field should be generated.  As status
     reports cannot be requested from the [RFC 822](./rfc822) world, the mapping
     is not likely to be used a great deal.

  5.4.5.  IP Message

     The P1.UMPDUEnvelope pro-forma specification ensures all the
     822-P1 information, and a minimal (legal) [RFC 822](./rfc822) message.  The
     mappings and actions for the P2.Heading components are now
     described.  Basically, these are interpreted as actions and/or
     mappings into [RFC 822](./rfc822) fields. The following mappings are
     specified:

        P2.IPMessageID

           This is mapped to the field "Message-ID:", according to
           [section 4](#section-4).

        P2.Heading.originator

           If P2.Heading.authorisingUsers is present this is mapped
           to Sender:, if not to From:.

        P2.Heading.authorisingUsers

           Mapped to From:.

        P2.Heading.primaryRecipients

           Mapped to To:.

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        P2.Heading.copyRecipients

           Mapped to Cc:.

        P2.Heading.blindCopyRecipients

           Mapped to Bcc:.

        P2.Heading.inReplyTo

           Mapped to In-Reply-To:.

        P2.Heading.obsoletes

           Mapped to the extended [RFC 822](./rfc822) field "Obsoletes:"

        P2.Heading.crossReferences

           Mapped to References:.

        P2.Heading.subject

           Mapped to subject.  The contents are converted to ASCII
           (as defined in chapter 3).  Any CRLF are not mapped, but
           are used as points at which the subject field must be
           folded.  line.

        P2.Heading.expiryDate

           Mapped to the extended [RFC 822](./rfc822) field "Expiry-Date:".

        P2.Heading.replyBy

           Mapped to the extended [RFC 822](./rfc822) field "Reply-By:".

        P2.Heading.replyToUsers

           Mapped to Reply-To:.

        P2.Heading.importance

           Mapped to the extended [RFC 822](./rfc822) field "Importance:".

        P2.Heading.sensitivity

           Mapped to the extended [RFC 822](./rfc822) field "Sensitivity:".

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RFC 987 June 1986 Mapping between X.400 and RFC 822

        P2.Heading.autoforwarded

           If it is set to FALSE, it is simply mapped to the
           extended [RFC 822](./rfc822) field "Autoforwarded:".  If this is set
           to TRUE, the P2.Body does not consist of a single
           P2.ForwardedIPMessage, then there is an X.400 error, and
           the message should be bounced.  Otherwise the following
           steps are taken.

              1.  The mappings for all of the message, except the
                  body part are completed.

              2.  Prepend each [RFC 822](./rfc822) fieldname with the string
                  "Autoforwarded-". Mapped to the extended [RFC 822](./rfc822)
                  field "Autoforwarded:".

              3.  Add the field "Autoforwarded:" with value TRUE.

              4.  Convert the syntax of the P2.ForwardedIPMessage to
                  generate the remaining [RFC 822](./rfc822) fields.

     The P2.Body is mapped into the [RFC 822](./rfc822) message body.  Each
     P2.BodyPart is converted to ASCII.  If the P2.Body contains a
     P2.BodyPart not listed here, the entire message should be
     rejected.  If there are exactly two P2.IA5Text body parts, and
     the first line of the first is "[RFC-822](./rfc822)-Headers:", then the
     rest of this first body part should be treated as additional
     header information for the [RFC 822](./rfc822) message.  If there is an
     "In-Reply-To:" field, this should be used to replace any
     generated In-Reply-To: field.

     In other cases of multiple P2.BodyPart, the mapping defined by
     Rose and Stefferud in [Rose85b], should be used to separate the
     P2.BodyParts in the single [RFC 822](./rfc822) message body.

     Individual body parts are mapped as follows:

        P2.IA5Text

           The mapping is trivial.

        P2.TTX

           If any P1.Teletex.NonBasicParams are set, the message
           should be rejected.  Otherwise, it should be converted to
           ASCII according to chapter 3.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

        P2.SFD

           An SFD should be converted to ASCII as if it was being
           rendered on an 79 column ASCII only VDU.  It seems likely
           that many gateways will not support this conversion.  In
           these cases, the message should be rejected.

        P2.ForwardedIPMessage

           The P2.ForwardedIPMessage.delivery and
           P2.ForwardedIPMessage.DeliveryInformation are
           discarded <9>.  The IM-UAPDU should have its syntax
           mapped (recursively) according to this gatewaying
           specification.  Clearly, it makes no sense to apply any
           of the actions defined here.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

Appendix A -- Quoted String Encodings

This Appendix describes a quoting mechanism which may be used to allow general interworking between RFC 822, and variants of RFC 822 which do not support 822.quoted-string. This is important, as the basic X.400 <-> RFC 822 mapping makes use of 822.quoted-string.

  1. ASCII <-> 822.atom
  The following EBNF is specified.

     atom-encoded    = *( a-char / a-encoded-char )
     a-char          = <any CHAR except specials, SPACE,
                             CTL, "_", and "#">
     a-encoded-char  = "_"                   ; (space)
                     / "#u#"                 ; (_)
                     / "#l#"                 ; <(>
                     / "#r#"                 ; <)>
                     / "#m#"                 ; (,)
                     / "#c#"                 ; (:)
                     / "#b#"                 ; (\)
                     / "#h#"                 ; (#)
                     / "#e#"                 ; ($=)
                     / "#s#"                 ; ($/)
                     / "#" 3DIGIT "#"

  NOTE: There are two encodings of double characters.  This is so
  that systems using this encoding, do not also need to know about
  the "$" quoting mechanism defined in chapter 4.

  The 822.3DIGIT in EBNF.a-encoded-char must have range 0-127
  (Decimal), and is interpreted in decimal as the corresponding
  ASCII character.  The choice of special abbreviations (as opposed
  to octal encoding) provided is based on the manner in which this
  mapping is most frequently used: encoding PrintableString
  components of O/R names as atom.  Therefore, there are special
  encodings for each of the PrintableString characters not in
  EBNF.a-char, except ".".  Space is given a single character
  encoding, due to its (expected) frequency of use, and backslash as
  the [RFC 822](./rfc822) single quote character.

  To encode (ASCII -> atom): all EBNF.a-char are used directly and
  all other CHAR are encoded as EBNF.a-encoded-char.  To decode
  (822.atom -> ASCII): if 822.atom can be parsed as
  EBNF.encoded-atom reverse the previous mapping.  If it cannot be
  so parsed, map the characters directly.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

  1. 822.local-part <-> ASCII
  A related transformation is for 822.local-part (or other element
  defined as '822.word ("." 822.word)') where not 822.quoted-text is
  used.  To encode (ASCII -> 822.local-part), all EBNF.a-char and
  "." are used directly and all other 822.CHAR are encoded as
  EBNF.a-encoded-char.  To decode (822.local-part -> ASCII), first
  attempt to parse 822.local-part as '822.atom *("." 822.atom)'.  If
  this fails, or if each 822.atom cannot be parsed as
  EBNF.atom-encoded then map each character directly.  Otherwise map
  each "." directly, and each atom as in the previous section.

  There are places where it is needed to convert between
  PrintableString or IA5Text (X.400), and 822.word ([RFC 822](./rfc822)).  word
  may be encoded as 822.atom (which has a restricted character set)
  or as 822.quoted-string, which can handle all ASCII characters.
  If 822.quoted-string is used, clearly the mappings for
  PrintableString defined in Chapter 3 provide a straightforward
  mapping.  However, some [RFC 822](./rfc822) based networks cannot handle the
  822.quoted-string format in all cases.  This Appendix is for use
  in these cases.  The major requirement for this mapping is the
  UNIX world, but it may well be needed in other places.

  These mappings are somewhat artificial, and their usage is
  discouraged, except in cases where there is no alternative.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

Appendix B -- Mappings Specific to JNT Mail

This Appendix is specific to the JNT Mail Protocol. It describes specific changes in the context of this protocol. Addressing is not discussed here, as it is covered in Appendix A.

  1. Introduction
  There are four aspects of a gateway which are JNT Mail Specific,
  in addition to those relating to addressing.  These are each given
  a section of this appendix.
  1. Acknowledge-To:
  This field has no direct functional equivalent in X.400.  However,
  it can be supported to an extent, and can be used to improve X.400
  support.

  When going from JNT Mail to X.400, the User Report Request bits of
  each P1.RecipientInfo.perRecipientFlag should be set to confirmed.
  If there is more that one address in the Acknowledge-To: field, or
  if the one address is not equivalent to the 822-P1 return address,
  then:

     a.   Acknowledgement(s) should be generated by the gateway.
          The text of these acknowledgements should indicate that
          they are generated by the gateway.

     b.   The Acknowledge-To: field should also be passed in the
          first P2.BodyPart.

  When going from X.400 to JNT Mail, in cases where
  P1.RecipientInfo.perRecipientFlag has the user bits set to
  confirmed the copy of the message to that recipient should have an
  Acknowledge-To: field containing the P.UMPDUEnvelope.originator.
  No attempt should be made to map Receipt notification requests
  onto Acknowledge-To:.  This is because no association can be
  guaranteed between P2 and P1 level addressing information.
  1. Trace
  JNT Mail trace uses the Via: syntax.  When going from JNT Mail to
  X.400, the following mapping onto P1.TraceInformation is used.

     P1.DomainSuppliedInfo.action is set to relayed.

     P1.DomainSuppliedInfo.arrival is set to the date-time component

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RFC 987 June 1986 Mapping between X.400 and RFC 822

     of the Via: field.  P1.DomainSuppliedInfo.previous has
     P1.CountryName as a null string, and
     P1.AdministrationDomainName as the domain specified in the Via:
     field.
     P1.TraceInformation.GlobalDomainIdentifier has P1.CountryName
     as a null string, and P1.AdministrationDomainName as any
     commented information in the Via: field.  For example:

        Via: UK.AC.Edinburgh ; 17 Jun 85 9:15:29 BST (EMAS V7)

        maps to -

        P1.GlobalDomainIdentifier
           CountryName                  = ""
           AdministrationDomainName     = "(EMAS V7)"
        P1.DomainSuppliedInfo
           arrival                      = 17 Jun 85 9:15:29 BST
           action                       = relayed
           previous
              CountryName               = ""
              AdministrationDomainName  = "UK.AC.Edinburgh"
  1. Timezone specification
  The extended syntax of zone defined in the JNT Mail Protocol
  should be used in the mapping of UTCTime defined in chapter 3.
  1. Lack of separate 822-P1 originator specification
  In JNT Mail the default mapping of the P1.MPDUEnvelope.originator
  is to the Sender: field.  This can cause a problem if the mapping
  of P2.Heading has already generated a Sender: field.  To overcome
  this, new extended JNT Mail field is defined.  This is chosen to
  align with the JNT recommendation for interworking with full
  [RFC 822](./rfc822) systems [Kille84b].

     original-sender     = "Original-Sender" ":" mailbox

  If an IPM has no P2.heading.authorisingUsers component and
  P2.Heading.originator.ORName is different from
  P1.UMPDUEnvelope.originator, map P1.MPDUEnvelope.originator onto
  the Sender: field.

  If an IPM has a P2.heading.authorisingUsers component, and
  P2.Heading.originator.ORName is different from
  P1.UMPDUEnvelope.originator, P1.MPDUEnvelpoe.originator should be

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RFC 987 June 1986 Mapping between X.400 and RFC 822

  mapped onto the Sender: field, and P2.Heading.originator mapped
  onto the Original-Sender: field.

  In other cases the P1.MPDUEnvelope.Originator is already correctly
  represented.

  Note that in some pathological cases, this mapping is
  asymmetrical.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

Appendix C -- Mappings Specific to Internet Mail

The Simple Mail Transfer Protocol [Postel82a] is used in the ARPA-Internet, and in any network following the US DoD standards for internetwork protocols. This appendix is specific to those hosts which use SMTP to exchange mail.

  1. Mapping between O/R names and SMTP addresses
  The mappings of Chapter 4 are to be used.
  1. Use of the ARPA Domain System
  Whenever possible, domain-qualified addresses should be be used to
  specify encoded O/R names.  These domain encodings naturally
  should be independent of any routing information.
  1. Identification of gateways
  The ARPA-Internet Network Information Center (NIC) will maintain a
  list of registered X.400 gateways in the ARPA Internet.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

Appendix D -- Mappings Specific to Phonenet Mail

There are currently no mappings specific to Phonenet Mail.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

Appendix E -- Mappings Specific to UUCP Mail

Gatewaying of UUCP and X.400 is handled by first gatewaying the UUCP address into RFC 822 syntax (using RFC 976) [Horton86a] and then gatewaying the resulting RFC 822 address into X.400. For example, an X.400 address

  Country         US
  Organization    Xerox
  Personal Name   John Smith

might be expressed from UUCP as

  inthop!gate!gatehost.COM!/C=US/O=Xerox/PN=John.Smith/

(assuming gate is a UUCP-ARPA gateway and gatehost.COM is an ARPA-X.400 gateway) or

  inthop!gate!Xerox.COM!John.Smith

(assuming that Xerox.COM and /C=US/O=Xerox/ are equivalent.)

In the other direction, a UUCP address Smith@ATT.COM, integrated into 822, would be handled as any other 822 address. A non-integrated address such as inthop!dest!user might be handled thought a pair of gateways:

  Country         US
  ADMD            ATT
  PRMD            ARPA
  Organization    GateOrg
  [RFC-822](./rfc822)         inthop!dest!user@gatehost.COM

or through a single X.400 to UUCP gateway:

  Country         US
  ADMD            ATT
  PRMD            UUCP
  Organization    GateOrg
  UUCP            inthop!dest!user

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RFC 987 June 1986 Mapping between X.400 and RFC 822

Appendix F -- Format of Address Mapping Tables

There is a need to specify the association between the domain and X.400 namespaces described in 4.2.1. This is defined as a table syntax, but the syntax is defined in a manner which makes it suitable for use with domain nameservers (such as the DARPA Domain nameservers or the UK NRS). The symmetry of the mapping is not clear, so a separate table is specified for each direction. For domain -> X.400:

  domain-syntax "#" dmn-orname "#"

  For example:

  AC.UK#PRMD$DES.ADMD$BT.C$UK#
  XEROX.COM#O$Xerox.ADMD$ATT.C$US#

For X.400 -> domain:

  dmn-orname "#" domain-syntax "#"

EBNF.domain-syntax will be interpreted according to RFC 920. EBNF.dmn-orname will have components ordered as defined in section 4.2.1, and with the most significant component on the RHS.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

References

Bonacker85a.

  K.H. Bonacker, U. Pankoke-Babatz, and H. Santo, "EAN - Conformity
  to X.400 and DFN-Pflichtenheft," GMD (Gesellschaft fur Mathematik
  und Datenverarbeitung) report, June 1985.

CCITT84a.

  CCITT SG 5/VII, "Recommendations X.400," Message Handling Systems:
  System Model - Service Elements, October 1984.

CCITT84b.

  CCITT SG 5/VII, "Recommendations X.411," Message Handling Systems:
  Message Transfer Layer, October 1984.

CCITT84c.

  CCITT SG 5/VII, "Recommendations X.420," Message Handling Systems:
  Interpersonal Messaging User Agent Layer, October 1984.

CCITT84d.

  CCITT SG 5/VII, "Recommendations X.409," Message Handling Systems:
  Presentation Transfer Syntax and Notation, October 1984.

CEN/CENELEC/85a.

  CEN/CENELEC/Information Technology/Working Group on Private
  Message Handling Systems, "FUNCTIONAL STANDARD A/3222,"
  CEN/CLC/IT/WG/PMHS N 17, October 1985.

Crocker82a.

  D.H. Crocker, "Standard of the Format of ARPA Internet Text
  Messages," [RFC 822](./rfc822), August 1982.

Horton85a.

  M.R. Horton, "Draft Standard for ARPA/MHS Addressing Gateways,"
  AT&T Bell Laboratories, October 1985.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

Horton86a.

  M.R. Horton, "UUCP Mail Interchange Format Standard", [RFC 976](./rfc976),
  February 1986.

ICL84a.

  ICL, "Comparison of service elements of Grey Book Mail and X.400,"
  Mailgroup Note 18: Extract from unpublished report for ITSU
  (Information Technology Standards Unit), July 1984.

Kille84a.

  S.E. Kille, (editor), JNT Mail Protocol (revision 1.0), Joint
  Network Team, Rutherford Appleton Laboratory, March 1984.

Kille84b.

  S.E. Kille, "Gatewaying between [RFC 822](./rfc822) and JNT Mail," JNT
  Mailgroup Note 15, May 1984.

Kille86a.

  S.E. Kille, "O/R Names in the UK Academic Community," UK Working
  Document, March 1986.

Larmouth83a.

  J. Larmouth, "JNT Name Registration Technical Guide," Salford
  University Computer Centre, April 1983.

Neufeld85a.

  G. Neufeld, J. Demco, B. Hilpert, and R. Sample, "EAN: an X.400
  message system," in Second International Symposium on Computer
  Message Systems, Washington, pp. 1-13, North Holland,
  September 1985.

Postel82a.

  J. Postel, "Simple Mail Transfer Protocol," [RFC 821](./rfc821), August 1982.

Postel84a.

  J. Postel and J. Reynolds, "Domain Requirements," [RFC 920](./rfc920),
  October 1984.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

Rose85a.

  M.T. Rose, "Mapping Service Elements between ARPA and MHS," Draft
  proposal, October 1985.

Rose85b.

  M.T. Rose and E.A. Stefferud, "Proposed Standard for Message
  Encapsulation," [RFC 934](./rfc934), January 1985.

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RFC 987 June 1986 Mapping between X.400 and RFC 822

Notes:

<0> UNIX is a trademark of Bell Laboratories.

<1> The term gateway is used to describe a component performing the protocol mappings between RFC 822 and X.400. This is standard usage amongst mail implementors, but should be noted carefully by transport and network service implementors. (Sometime called a "mail relay".)

<2> If the remote protocol is JNT Mail, a notification may also be sent by the recipient UA.

<3> The asymmetry occurs where an ASCII string contains the sequence EBNF.ps-encoded-char. This would be mapped directly to PrintableString, but the reverse mapping would be to the value implied by the sequence.

<4> It might be suggested that for reasons of elegance, EBNF.ps-delim (left parenthesis) is encoded as EBNF.ps-encoded-char. This is not done, as it it would never be possible to represent a PrintableString containing the character "(" in ASCII. This is because an "(" in ASCII would be mapped to the encoding in PrintableString.

<5> In practice, a gateway will need to parse various illegal variants on 822.date-time. In cases where 822.date-time cannot be parsed, it is recommended that the derived UTCTime is set to the value at the time of translation.

<6> P2.ORname is defined as P1.ORName.

<7> This recommendation may change in the light of CCITT or CEN/CENELEC guidelines on the use of initials.

<8> It would be possible to use a ForwardedIPMessage for these fields, but the semantics are (arguably) slightly different, and it is probably not worth the effort.

<9> Although this violates chapter 1, part 4, principles 2 and 3, it is suggested that this is justified by principle 1.

Kille [Page 69]