Network Working Group S. Hardcastle-Kille Request for Comments: 1328 University College London May 1992 X.400 1988 to 1984 downgrading Status of this Memo This RFC specifies an IAB standards track protocol for the Internet community, and requests discussion and suggestions for improvements. Please refer to the current edition of the "IAB Official Protocol Standards" for the standardization state and status of this protocol. Distribution of this memo is unlimited. Abstract This document considers issues of downgrading from X.400(1988) to X.400(1984) [MHS88a, MHS84]. Annexe B of X.419 specifies some downgrading rules [MHS88b], but these are not sufficient for provision of service in an environment containing both 1984 and 1988 components. This document defines a number of extensions to this annexe. This specification is not tutorial. COSINE Study 8.2 by J.A.I. Craigie gives a useful overview [Cra88]. 1. The need to Downgrade It is expected that X.400(1988) systems will be extensively deployed, whilst there is still substantial use of X.400(1984). If 1988 features are to be used, it it important for there to be a clear approach to downgrading. This document specifies an approach to downgrading for the Internet and COSINE communities. As 1988 is a strict superset of 1984, the mapping is a one-way problem. 2. Avoiding Downgrading Perhaps the most important consideration is to configure systems so as to minimise the need for downgrading. Use of 1984 systems to interconnect 1988 systems should be strenuously avoided. In practice, many of the downgrading issues will be avoided. When a 1988 originator sends to a 1984 recipient, 1988 specific features will not be used as they will not work! For distribution lists with 1984 and 1988 recipients, messages will tend to be "lowest common denominator".
3. Addressing In general there is a problem with O/R addresses which use 88 specific features. The X.419 downgrade approach will mean that addresses using these features cannot be specified from 84 systems. Worse, a message originating from such an address cannot be transferred into X.400(1984). This is unacceptable. Two approaches are defined. The first is a general purpose mechanism, which can be implemented by the gateway only. The second is a special purpose mechanism to optimise for a form of X.400(88) address which is expected to be used frequently (Common Name). The second approach requires cooperation from all X.400(88) UAs and MTAs which are involved in these interactions. 3.1 General Approach The first approach is to use a DDA "X400-88". The DDA value is an std-or encoding of the address as defined in RFC 1327 [Kil92]. This will allow source routing through an appropriate gateway. This solution is general, and does not require co-operation. For example: 88: PD-ADDRESS=Empire State Building; PRMD=XX; ADMD=ZZ; C=US; 84: O=MHS-Relay; PRMD=UK.AC; C=GB; DD.X400-88=/PD-ADDRESS=Empire State Building/PRMD=XX/ADMD=ZZ/C=US/; The std-or syntax can use IA5 characters not in the printable string set (typically to handle teletext versions). To enable this to be handled, the std-or encoded in encapsulated into printable string using the mappings of Section 3.4 of RFC 1327. Where the generated address is longer than 128 characters, up to three overflow domain defined attributes are used: X400-C1; X400-C2; X400-C3. 3.2 Common Name Where a common name attribute is used, this is downgraded to the Domain Defined Attribute "Common". For example: 88: CN=Postmaster; O=A; ADMD=B; C=GB; 84: DD.Common=Postmaster; O=A; ADMD=B; C=GB; The downgrade will always happen correctly. However, it will not always be possible for the gateway to do the reverse mapping.
Therefore, this approach requires that all 1988 MTAs and UAs which wish to interact with 1984 systems through gateways following this specification will need to understand the equivalence of these two forms of address. 4. MTS Annexe B of X.419 is sufficient, apart from the addressing. The discard of envelope fields is unfortunate. However, the criticality mechanism ensures that no information the originator specifies to be critical is discarded. There is no sensible alternative. If mapping to a system which support the MOTIS-86 trace extensions, it is recommended that the internal trace of X.400(88) is mapped on to this, noting the slight differences in syntax. 5. IPM Downgrading The IPM service in X.400(1984) is usually provided by content type 2. In many cases, it will be useful for a gateway to downgrade P2 from content type 22 to 2. This will clearly need to be made dependent on the destination, as it is quite possible to carry content type 22 over P1(1984). The decision to make this downgrade will be on the basis of gateway configuration. When a gateway downgrades from 22 to 2, the following should be done: 1. Strip any 1988 specific headings (language indication, and partial message indication). 2. Downgrade all O/R addresses, as described in Section 3. 3. If a directory name is present, there is no method to preserve the semantics within a 1984 O/R Address. However, it is possible to pass the information across, so that the information in the Distinguished Name can be informally displayed to the end user. This is done by appendend a text representation of the Distinguished Name to the Free Form Name enclosed in round brackets. It is recommended that the "User Friendly Name" syntax is used to represent the Distinguished Name [Kil90]. For example: (Steve Hardcastle-Kille, Computer Science, University College London, GB) 4. The issue of body part downgrade is discussed in Section 6.
5.1 RFC 822 Considerations A message represented as content type 22 may have originated from RFC 822 [Cro82]. The downgrade for this type of message can be improved. This is discussed in RFC 1327 [Kil92]. 6. Body Part downgrading The issue of body part downgrade is very much linked up with the whole issue of body part format conversion. If no explicit conversion is requested, conversion depends on the MTA knowing the remote UA's capabilities. The following options are available for body part conversion in all cases, including this one. It is assumed that body part conversion is avoided where possible. 1. Downgrade to a standard 1984 body part, without loss of information 2. Downgrade to a standard 1984 body part, with loss of information 3. Discard the body part, and replace with a (typically IA5 text) message. For example: ********************************************** * * There was a hologram here which could * not be converted * ********************************************** 4. Bounce the message If conversion is prohibited, 4) must be done. If conversion-with- loss is prohibited, 1) should be done if possible, otherwise 4). In other cases 2) should be done if possible. If it is not possible, the choice between 3) and 4) should be a configuration choice. X.419 only recognises 4). 3) Seems to be a useful choice in practice, particularly where the message contains other body parts. Another option is available when downgrading: 1. Encapsulate the body part as a Nationally Defined 1984 body part (body part 7). This should be used when configured for the recipient UA.
References [Cra88] Craigie, J., "Migration strategy for x.400(84) to x.400(88)/MOTIS", COSINE Specification Phase 8.2, RARE, 1988. [Cro82] Crocker, D., "Standard of the Format of ARPA Internet Text Messages", RFC 822, UDEL, August 1982. [Kil90] Kille, S., "Using the OSI directory to achieve user friendly naming", Research Note RN/90/29, Department of Computer Science, University College London, February 1990. [Kil92] Kille, S., "Mapping between X.400(1988) / ISO 10021 and RFC 822", RFC 1327, University College London, May 1992. [MHS84] Recommendations X.400, October 1984. CCITT SG 5/VII, Message Handling Systems: System Model - Service Elements. [MHS88a] CCITT recommendations X.400 / ISO 10021, April 1988. CCITT SG 5/VII / ISO/IEC JTC1, Message Handling: System and Service Overview. [MHS88b] CCITT recommendations X.419/ ISO 10021, April 1988. CCITT SG 5/VII / ISO/IEC JTC1, Message Handling: Protocol Specifications. 7. Security Considerations Security issues are not discussed in this memo. 8. Author's Address Steve Hardcastle-Kille Department of Computer Science University College London Gower Street WC1E 6BT England Phone: +44-71-380-7294 EMail: S.Kille@CS.UCL.AC.UK