| Network Working Group | H. S. Thompson |
| Internet-Draft | University of Edinburgh |
| Obsoletes: 3023 (if approved) | C. Lilley |
| Updates: 6839 (if approved) | W3C |
| Intended status: Standards Track | November 19, 2013 |
| Expires: May 23, 2014 |
XML Media Types
draft-ietf-appsawg-xml-mediatypes-05
This specification standardizes three media types -- application/xml, application/xml-external-parsed-entity, and application/xml-dtd -- for use in exchanging network entities that are related to the Extensible Markup Language (XML) while defining text/xml and text/xml-external-parsed-entity as aliases for the respective application/ types. This specification also standardizes the '+xml' suffix for naming media types outside of these five types when those media types represent XML MIME entities.
This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at http://datatracker.ietf.org/drafts/current/.
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This Internet-Draft will expire on May 23, 2014.
Copyright (c) 2013 IETF Trust and the persons identified as the document authors. All rights reserved.
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The World Wide Web Consortium has issued the Extensible Markup Language (XML) 1.0 [XML] and Extensible Markup Language (XML) 1.1 [XML1.1] specifications. To enable the exchange of XML network entities, this specification standardizes three media types -- application/xml, application/xml-external-parsed-entity, and application/xml-dtd and two aliases -- text/xml and text/xml-external-parsed-entity, as well as a naming convention for identifying XML-based MIME media types (using '+xml').
XML has been used as a foundation for other media types, including types in every branch of the IETF media types tree. To facilitate the processing of such types, and in line with the recognition in [RFC6838] of structured syntax name suffixes, a suffix of '+xml' is described in Section 8. This will allow generic XML-based tools -- browsers, editors, search engines, and other processors -- to work with all XML-based media types.
This specification replaces [RFC3023]. Major differences are in the areas of alignment of charset handling for text/xml and text/xml-external-parsed-entity with application/xml, the addition of XPointer and XML Base as fragment identifiers and base URIs, respectively, integration of the XPointer Registry and updating of many references.
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this specification are to be interpreted as described in [RFC2119].
As defined in [RFC2781] (informative), the three character sets "utf-16", "utf-16le", and "utf-16be" are used to label UTF-16 text. In this specification, "the UTF-16 family" refers to those three character sets. By contrast, the phrases "utf-16" or UTF-16 in this specification refer specifically to the single charset "utf-16".
As sometimes happens between two communities, both MIME and XML have defined the term entity, with different meanings. Section 2.4 of [RFC2045] says:
Section 4 of [XML] says:
In this specification, "XML MIME entity" is defined as the latter (an XML entity) encapsulated in the former (a MIME entity).
Furthermore, XML provides for the naming and referencing of entities for purposes of inclusion and/or substitution. In this specification "XML-entity declaration/reference/..." is used to avoid confusion when referring to such cases.
Registration information for media types for use with XML MIME entities is described in the sections below. Within the XML specification, such entities can be classified into four types. In the XML terminology, they are called "document entities", "external DTD subsets", "external parsed entities", and "external parameter entities". Appropriate usage for the types registered below is as follows:
Neither external DTD subsets nor external parameter entities parse as XML documents, and while some XML document entities may be used as external parsed entities and vice versa, there are many cases where the two are not interchangeable. XML also has unparsed entities, internal parsed entities, and internal parameter entities, but they are not XML MIME entities.
Compared to [RFC2376] or [RFC3023], this specification alters the charset handling of text/xml and text/xml-external-parsed-entity, treating them no differently from the respective application/ types, however application/xml and application/xml-external-parsed-entity are still RECOMMENDED, to avoid possible confusion based on the earlier distinction. The former confusion around the question of default character sets for the text/xml... types has been resolved by [HTTPbis] changing [RFC2616] by removing the ISO-8859-1 default and not defining any default at all, as well as [RFC6657] updating [RFC2046] to remove the US-ASCII default. See Section 3.6 for the now-unified approach to the charset parameter which results.
XML provides a general framework for defining sequences of structured data. It is often appropriate to define new media types that use XML but define a specific application of XML, due to domain-specific display, editing, security considerations or runtime information. Furthermore, such media types may allow only UTF-8 and/or UTF-16 and prohibit other character sets. This specification does not prohibit such media types and in fact expects them to proliferate. However, developers of such media types are RECOMMENDED to use this specification as a basis for their registration. See Section 8 for more detailed recommendations on using the '+xml' suffix for registration of such media types.
An XML document labeled as application/xml or text/xml, or with a '+xml' media type, might contain namespace declarations, stylesheet-linking processing instructions (PIs), schema information, or other declarations that might be used to suggest how the document is to be processed. For example, a document might have the XHTML namespace and a reference to a CSS stylesheet. Such a document might be handled by applications that would use this information to dispatch the document for appropriate processing.
text/xml is an alias for application/xml, as defined in Section 3.1 above.
text/xml-external-parsed-entity is an alias for application/xml-external-parsed-entity, as defined in Section 3.3 above.
As many as three distinct sources of information about character encoding may be present for an XML MIME entity: a charset parameter, a Byte Order Mark (BOM -- see Section 4 below) and an XML encoding declaration (see Section 4.3.3 of [XML]). Ensuring consistency among these sources requires coordination between entity authors and MIME agents (that is, processes which package, transfer, deliver and/or receive MIME entities). Some MIME agents will be what we will call "XML-aware", that is, capable of processing XML MIME entities and detecting the XML encoding declaration (or its absence). Others will not be XML-aware, and thus cannot know anything about the XML encoding declaration. Some MIME agents, such as proxies and transcoders, both consume and produce MIME entities.
XML-aware MIME producers SHOULD supply a charset parameter and/or an appropriate BOM with non-UTF-8-encoded XML MIME entities which lack an encoding declaration, and SHOULD remove or correct an encoding declaration which is known to be incorrect (for example, as a result of transcoding).
XML-unaware MIME producers MUST NOT supply a charset parameter with an XML MIME entity unless the entity's character encoding is reliably known.
XML MIME producers are RECOMMENDED to provide means for XML MIME entity authors to control the supply of charset parameters for their entities, for example by enabling user-level configuration of filename-to-Content-Type-header mappings on a file-by-file or suffix basis.
For XML MIME consumers, the question of priority arises in cases when the available character encoding information is not consistent. Again, we must distinguish betweeen XML-aware and XML-unaware processors.
When a charset parameter is specified for an XML MIME entity, then regardless of whether or not the entity contains in-band encoding information, that is, either a BOM [bom] or an XML encoding declaration or both, or none, the normative component of the [XML] specification leaves the question open as to how to determine the encoding with which to attempt to process the entity. In particular, in the case where there is in-band information and it conflicts with the charset parameter, the [XML] specification does not specify which should be taken to be authoritative. In its (non-normative) Appendix F it defers to this specification:
Accordingly, to conform with deployed processors and content and to avoid conflicting with this or other normative specifications, this specification sets the priority as follows:
All consumers SHOULD treat a BOM [bom] as authoritative if it is present in an XML MIME entity. In the absence of a BOM [bom], all consumers SHOULD treat the charset parameter as authoritative if it is present. For XML-aware consumers, note that Section 4.3.3 of the [XML] specification does not make it an error for the charset parameter and the XML encoding declaration (or the UTF-8 default in the absence of encoding declaration and BOM) to be inconsistent, although such processors might choose to issue a warning in this case.
When MIME producers conform to the requirements on them stated above, such inconsistencies will not arise---this statement of priorities only has practical impact in the case of non-conforming XML MIME entities.
If an XML MIME entity is received where the charset parameter is omitted, no information is being provided about the charset by the MIME Content-Type header. XML-aware processors MUST follow the requirements in section 4.3.3 of [XML] that directly address this case. XML-unaware MIME processors SHOULD NOT assume a default charset in this case.
Section 4.3.3 of [XML] specifies that XML MIME entities in the charset "utf-16" MUST begin with a byte order mark (BOM), which is a hexadecimal octet sequence 0xFE 0xFF (or 0xFF 0xFE, depending on
Due to the presence of the BOM, applications that convert XML from "utf-16" to an encoding other than "utf-8" MUST strip the BOM before conversion. Similarly, when converting from another encoding into "utf-16", the BOM MUST be added after conversion is complete unless the original encoding was "utf-8" and a BOM was already present, in which case it will have been transcoded into a "utf-16" BOM already.
Section 4.3.3 of [XML] also allows for XML MIME entities in the charset "utf-8" to begin with a byte order mark (BOM), which is a hexadecimal octet sequence 0xEF 0xBB 0xBF, also defined to be an encoding signature, and not part of either the markup or the character data of the XML document.
Applications that convert XML from "utf-8" to an encoding other than "utf-16" MUST strip the BOM, if present, before conversion. Applications which convert XML into "utf-8" SHOULD add a BOM after conversion is complete.
In addition to the charset "utf-16", [RFC2781] introduces "utf-16le" (little endian) and "utf-16be" (big endian) as well. The BOM is prohibited for these character sets. When an XML MIME entity is encoded in "utf-16le" or "utf-16be", it MUST NOT begin with the BOM but SHOULD contain an in-band XML encoding declaration. Conversion from "utf-16"or "utf-8" to "utf-16be" or "utf-16le" and conversion in the other direction MUST strip or add the appropriate BOM, respectively.
Uniform Resource Identifiers (URIs) can contain fragment identifiers (see Section 3.5 of [RFC3986]). Specifying the syntax and semantics of fragment identifiers is devolved by [RFC3986] to the appropriate media type registration.
The syntax and semantics of fragment identifiers for the XML media types defined in this specification are based on the [XPointerFramework] W3C Recommendation. It allows simple names, and more complex constructions based on named schemes. When the syntax of a fragment identifier part of any URI or IRI with a retrieved media type governed by this specification conforms to the syntax specified in [XPointerFramework], conforming applications MUST interpret such fragment identifiers as designating whatever is specified by the [XPointerFramework] together with any other specifications governing the XPointer schemes used in those identifiers which the applications support. Conforming applications MUST support the 'element' scheme as defined in [XPointerElement], but need not support other schemes.
If an XPointer error is reported in the attempt to process the part, this specification does not define an interpretation for the part.
A registry of XPointer schemes [XPtrReg] is maintained at the W3C. Document authors SHOULD NOT use unregistered schemes. Scheme authors SHOULD register their schemes ([XPtrRegPolicy] describes requirements and procedures for doing so).
See Section 8.1 for additional requirements which apply when an XML-based media type follows the naming convention '+xml'.
If [XPointerFramework] and [XPointerElement] are inappropriate for some XML-based media type, it SHOULD NOT follow the naming convention '+xml'.
When a URI has a fragment identifier, it is encoded by a limited subset of the repertoire of US-ASCII [ASCII] characters, as defined in [RFC3986].
Section 5.1 of [RFC3986] specifies that the semantics of a relative URI reference embedded in a MIME entity is dependent on the base URI. The base URI is established by (1) the base URI embedded in content, (2) the base URI from the encapsulating entity, (3) the base URI from the Retrieval URI, or (4) the default base URI, in order of precedence. [RFC3986] further specifies that the mechanism for embedding the base URI is dependent on the media type.
This specification accordingly provides the following media type dependent mechanism for embedding the base URI in a MIME entity of type application/xml, text/xml, application/xml-external-parsed-entity or text/xml-external-parsed-entity: An XML MIME entity MAY use the xml:base attribute, as described in detail in [XMLBase], to establish a base URI for that entity.
Note that the base URI itself might be embedded in a different MIME entity, since the default value for the xml:base attribute can be specified in an external DTD subset or external parameter entity. Since conforming XML processors need not always read and process external entities, the effect of such an external default is uncertain and therefore its use is NOT RECOMMENDED.
application/xml, application/xml-external-parsed-entity, and application/xml-dtd, text/xml and text/xml-external-parsed-entity are to be used with [XML]. In all examples herein where version="1.0" is shown, it is understood that version="1.1" might also appear, providing the content does indeed conform to [XML1.1].
The normative requirement of this specification upon XML documents and processors is to follow the requirements of [XML], section 4.3.3. Except for minor clarifications, that section is substantially identical from the first edition to the current (5th) edition of XML 1.0, and for XML 1.1 1st or 2nd edition [XML1.1]. Therefore, references herein to [XML] may be interpreted as referencing any existing version or edition of XML, or any subsequent edition or version which makes no incompatible changes to that section.
Specifications and recommendations based on or referring to this RFC SHOULD indicate any limitations on the particular versions or editions of XML to be used.
This section supersedes the earlier registration of the '+xml' suffix [RFC6839].
This specification recommends the use of a naming convention (a suffix of '+xml') for identifying XML-based media types, in line with the recognition in [RFC6838] of structured syntax name suffixes. This allows the use of generic XML processors and technologies on a wide variety of different XML document types at a minimum cost, using existing frameworks for media type registration.
When a new media type is introduced for an XML-based format, the name of the media type SHOULD end with '+xml' unless generic XML processing is in some way inappropriate for documents of the new type. This convention will allow applications that can process XML generically to detect that the MIME entity is supposed to be an XML document, verify this assumption by invoking some XML processor, and then process the XML document accordingly. Applications may match for types that represent XML MIME entities by comparing the subtype to the pattern '*/*+xml'. (However note that 4 of the 5 media types defined in this specification -- text/xml, application/xml, text/xml-external-parsed-entity, and application/xml-external-parsed-entity -- also represent XML MIME entities while not conforming to the '*/*+xml' pattern.)
Media types following the naming convention '+xml' SHOULD introduce the charset parameter for consistency, since XML-generic processing applies the same program for any such media type. However, there are some cases that the charset parameter need not be introduced. For example:
XML generic processing is not always appropriate for XML-based media types. For example, authors of some such media types may wish that the types remain entirely opaque except to applications that are specifically designed to deal with that media type. By NOT following the naming convention '+xml', such media types can avoid XML-generic processing. Since generic processing will be useful in many cases, however -- including in some situations that are difficult to predict ahead of time -- the '+xml' convention is to be preferred unless there is some particularly compelling reason not to.
The registration process for specific '+xml' media types is described in [RFC6838]. The registrar for the IETF tree will encourage new XML-based media type registrations in the IETF tree to follow this guideline. Registrars for other trees SHOULD follow this convention in order to ensure maximum interoperability of their XML-based documents. Similarly, media subtypes that do not represent XML MIME entities MUST NOT be allowed to register with a '+xml' suffix.
Registrations for new XML-based media types under top-level types SHOULD, in specifying the charset parameter and encoding considerations, define them as: "Same as [charset parameter / encoding considerations] of application/xml as specified in RFC XXXX."
Enabling the charset parameter is RECOMMENDED, since this information can be used by XML processors to determine authoritatively the charset of the XML MIME entity in the absence of a BOM. If there are some reasons not to follow this advice, they SHOULD be included as part of the registration. As shown above, two such reasons are "UTF-8 only" or "UTF-8 or UTF-16 only".
These registrations SHOULD specify that the XML-based media type being registered has all of the security considerations described in RFC XXXX plus any additional considerations specific to that media type.
These registrations SHOULD also make reference to RFC XXXX in specifying magic numbers, base URIs, and use of the BOM.
These registrations MAY reference the application/xml registration in RFC XXXX in specifying interoperability considerations, if these considerations are not overridden by issues specific to that media type.
The examples below give the charset portion, if any, of the value of the MIME Content-type header and the XML declaration or Text declaration (which includes the encoding declaration) inside the XML MIME entity. For UTF-16 examples, the Byte Order Mark character appropriately UTF-16-encoded is denoted as "{BOM}", and the XML or Text declaration is assumed to come at the beginning of the XML MIME entity, immediately following the encoded BOM. Note that other MIME headers may be present, and the XML MIME entity may contain other data in addition to the XML declaration; the examples focus on the Content-type header and the encoding declaration for clarity.
All the examples below apply to all five media types declared above in Section 3, as well as to any media types declared using the '+xml' convention (with the exception of the examples involving the charset parameter for any such media types which do not enable its use). See the XML MIME entities table [xml_entities] for discussion of which types are appropriate for which varieties of XML MIME entities.
This section is non-normative. In particular, note that all [RFC2119] language herein reproduces or summarizes the consequences of normative statements already made above, and has no independent normative force, and accordingly does not appear in uppercase.
Content-type charset: charset="utf-8"
<?xml version="1.0" encoding="utf-8"?>
This is the recommended encoding for use with all the media types defined in this specification. Since the charset parameter is provided and there is no BOM, both MIME and XML processors must treat the enclosed entity as UTF-8 encoded.
If sent using a 7-bit transport (e.g. SMTP [RFC5321]), the XML MIME entity must use a content-transfer-encoding of either quoted-printable or base64. For an 8-bit clean transport (e.g.
Content-type charset: charset="utf-16"
{BOM}<?xml version="1.0" encoding="utf-16"?>
or
{BOM}<?xml version="1.0"?>
For application/... cases, if sent using a 7-bit transport (e.g. SMTP) or an 8-bit clean transport (e.g.
As described in [RFC2781], the UTF-16 family must not be used with media types under the top-level type "text" except over HTTP or HTTPS (see section
Content-type charset: [none]
<?xml version="1.0" encoding="iso-8859-1"?>
Since the charset parameter is not provided in the Content-Type header and there is no BOM, XML processors must treat the "iso-8859-1" encoding as authoritative. XML-unaware MIME processors should make no assumptions about the charset of the XML MIME entity.
Content-type charset: [none]
{BOM}<?xml version="1.0" encoding="utf-16"?>
or
{BOM}<?xml version="1.0"?>
This example shows a 16-bit MIME entity with no charset parameter. However since there is a BOM all processors must treat the entity as UTF-16-encoded.
Omitting the charset parameter is not recommended for application/... when used with transports other than HTTP or HTTPS. text/... should not be used for 16-bit MIME with transports other than HTTP or HTTPS (see discussion above [tx16]).
Content-type charset: [none]
<?xml version='1.0'?>
In this example, the charset parameter has been omitted, there is no internal encoding declaration, and there is no BOM. Since there is no BOM or charset parameter, the XML processor follows the requirements in section 4.3.3, and optionally applies the mechanism described in Appendix F (which is non-normative) of [XML] to determine the charset encoding of UTF-8. Although the XML MIME entity does not contain an encoding declaration, the encoding actually is UTF-8, so this is still a conforming XML MIME entity.
An XML-unaware MIME processor should make no assumptions about the charset of the XML MIME entity.
See Section 9.1 for transport-related issues for UTF-8 XML MIME entities.
Content-type charset: charset="utf-16be"
<?xml version='1.0' encoding='utf-16be'?>
Observe that the BOM does not exist. Since the charset parameter is provided and there is no BOM, MIME and XML processors must treat the enclosed entity as UTF-16BE encoded.
See also the additional considerations in the UTF-16 example [utf16] above.
Content-type charset: charset="iso-2022-kr"
<?xml version="1.0" encoding="iso-2022-kr"?>
This example shows the use of a non-UTF charset (in this case Hangul, but this example is intended to cover all non-UTF-family character sets). Since the charset parameter is provided and there is no BOM, all processors must treat the enclosed entity as encoded per RFC 1557.
Since ISO-2022-KR [RFC1557] has been defined to use only 7 bits of data, no content-transfer-encoding is necessary with any transport: for character sets needing 8 or more bits, considerations such as those discussed above (Section 9.1, Section 9.2) would apply.
Content-type charset: [none]
<?xml version='1.0' encoding="iso-10646-ucs-4"?>
In this example, the charset parameter has been omitted, and there is no BOM. However, the XML MIME entity does have an encoding declaration inside the XML MIME entity that specifies the entity's charset. Following the requirements in section 4.3.3, and optionally applying the mechanism described in Appendix F (non-normative) of [XML], the XML processor determines the charset encoding of the XML MIME entity (in this example, UCS-4).
An XML-unaware MIME processor should make no assumptions about the charset of the XML MIME entity.
For character sets needing 8 or more bits, considerations such as those discussed above (Section 9.1, Section 9.2) would apply
Content-type charset: charset="iso-8859-1"
<?xml version="1.0" encoding="utf-8"?>
Although the charset parameter is provided in the Content-Type header and there is no BOM and the charset parameter differs from the XML encoding declaration, MIME and XML processors will interoperate. Since the charset parameter is authoritative in the absence of a BOM, all processors will treat the enclosed entity as iso-8859-1 encoded. That is, the "UTF-8" encoding declaration will be ignored.
Processors generating XML MIME entities must not label conflicting charset information between the MIME Content-Type and the XML declaration unless they have definitive information about the actual encoding, for example as a result of systematic transcoding. In particular, the addition by servers of an explicit, site-wide charset default has frequently lead to interoperability problems for XML documents.
Content-type charset: charset="iso-8859-1"
{BOM}<?xml version="1.0"?>
Although the charset parameter is provided in the Content-Type header, there is a BOM, so MIME and XML processors may not interoperate. Since the BOM parameter is authoritative for XML processors, they will treat the enclosed entity as UTF-16-encoded. That is, the "iso-8859-1" charset parameter will be ignored. XML-unaware MIME processors on the other hand may be unaware of the BOM and so treat the entity as encoded in iso-8859-1.
Processors generating XML MIME entities must not label conflicting charset information between the MIME Content-Type and an entity-initial BOM.
As described in Section 8, this specification updates the [RFC6839] registration for XML-based MIME types (the "+xml" types).
XML MIME entities contain information which may be parsed and further processed by the recipient. These entities may contain, and recipients may permit, explicit system level commands to be executed while processing the data. To the extent that a recipient application executes arbitrary command strings from within XML MIME entities, they may be at risk.
In general, any information stored outside of the direct control of the user -- including CSS style sheets, XSL transformations, XML-entity declarations, and DTDs -- can be a source of insecurity, by either obvious or subtle means. For example, a tiny "whiteout attack" modification made to a "master" style sheet could make words in critical locations disappear in user documents, without directly modifying the user document or the stylesheet it references. Thus, the security of any XML document is vitally dependent on all of the documents recursively referenced by that document.
The XML-entity lists and DTDs for XHTML 1.0 [XHTML], for instance, are likely to be a commonly used set of information. Many developers will use and trust them, few of whom will know much about the level of security on the W3C's servers, or on any similarly trusted repository.
The simplest attack involves adding declarations that break validation. Adding extraneous declarations to a list of character XML-entities can effectively "break the contract" used by documents. A tiny change that produces a fatal error in a DTD could halt XML processing on a large scale. Extraneous declarations are fairly obvious, but more sophisticated tricks, like changing attributes from being optional to required, can be difficult to track down. Perhaps the most dangerous option available to attackers, when external DTD subsets or external parameter entities or other externally-specified defaulting is involved, is redefining default values for attributes: e.g. if developers have relied on defaulted attributes for security, a relatively small change might expose enormous quantities of information.
Apart from the structural possibilities, another option, "XML-entity spoofing," can be used to insert text into documents, vandalizing and perhaps conveying an unintended message. Because XML permits multiple XML-entity declarations, and the first declaration takes precedence, it is possible to insert malicious content where an XML-entity reference is used, such as by inserting the full text of Winnie the Pooh in place of every occurrence of —.
Security considerations will vary by domain of use. For example, XML medical records will have much more stringent privacy and security considerations than XML library metadata. Similarly, use of XML as a parameter marshalling syntax necessitates a case by case security review.
XML may also have some of the same security concerns as plain text. Like plain text, XML can contain escape sequences that, when displayed, have the potential to change the display processor environment in ways that adversely affect subsequent operations. Possible effects include, but are not limited to, locking the keyboard, changing display parameters so subsequent displayed text is unreadable, or even changing display parameters to deliberately obscure or distort subsequent displayed material so that its meaning is lost or altered. Display processors SHOULD either filter such material from displayed text or else make sure to reset all important settings after a given display operation is complete.
Some terminal devices have keys whose output, when pressed, can be changed by sending the display processor a character sequence. If this is possible the display of a text object containing such character sequences could reprogram keys to perform some illicit or dangerous action when the key is subsequently pressed by the user. In some cases not only can keys be programmed, they can be triggered remotely, making it possible for a text display operation to directly perform some unwanted action. As such, the ability to program keys SHOULD be blocked either by filtering or by disabling the ability to program keys entirely.
Note that it is also possible to construct XML documents that make use of what XML terms "[XML-]entity references" to construct repeated expansions of text. Recursive expansions are prohibited by [XML] and XML processors are required to detect them. However, even non-recursive expansions may cause problems with the finite computing resources of computers, if they are performed many times. For example, consider the case where XML-entity A consists of 100 copies of XML-entity B, which in turn consists of 100 copies of XML-entity C, and so on.
[RFC3023] contains a detailed discussion of the (at the time) novel use of a suffix, a practice which has since become widespread. Interested parties are referred to [RFC3023], Appendix A.
There are numerous and significant differences between this specification and [RFC3023], which it obsoletes. This appendix summarizes the major differences only.
First, XPointer ([XPointerFramework] and [XPointerElement]) has been added as fragment identifier syntax for "application/xml", and the XPointer Registry ([XPtrReg]) mentioned. Second, [XMLBase] has been added as a mechanism for specifying base URIs. Third, the language regarding character sets was updated to correspond to the W3C TAG finding Internet Media Type registration, consistency of use [TAGMIME]. Fourth, many references are updated, and the existence of
MURATA Makoto (FAMILY Given) and Alexey Melnikov made early and important contributions to the effort to revise [RFC3023].
This specification reflects the input of numerous participants to the ietf-xml-mime@imc.org, xml-mime@ietf.org and apps-discuss@ietf.org mailing lists, though any errors are the responsibility of the authors. Special thanks to:
Mark Baker, James Clark, Dan Connolly, Martin Duerst, Ned Freed, Yaron Goland, Bjoern Hoehrmann, Rick Jelliffe, Murray S. Kucherawy, Larry Masinter, David Megginson, S. Moonesamy, Keith Moore, Chris Newman, Gavin Nicol, Julian Reschke, Marshall Rose, Jim Whitehead, Erik Wilde and participants of the XML activity and the TAG at the W3C.
Jim Whitehead and Simon St.Laurent were editors of [RFC2376] and [RFC3023], respectively.