--- 1/draft-ietf-urn-req-frame-00.txt 2008-04-11 11:00:18.000000000 +0200 +++ 2/draft-ietf-urn-req-frame-01.txt 2008-04-11 11:00:18.000000000 +0200 @@ -1,14 +1,14 @@ Internet Draft Karen R. Sollins -draft-ietf-urn-req-frame-00.txt MIT/LCS -Expires May 26, 1997 November 26, 1996 +draft-ietf-urn-req-frame-01.txt MIT/LCS +Expires September 28, 1997 March 28, 1997 Requirements and a Framework for URN Resolution Systems Status of this draft This document is an Internet-Draft. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF), its areas, and its working groups. Note that other groups may also distribute working documents as Internet-Drafts. Internet-Drafts are draft documents valid for a maximum of six @@ -19,904 +19,995 @@ To learn the current status of any Internet-Draft, please check the ``1id-abstracts.txt'' listing contained in the Internet- Drafts Shadow Directories on ftp.is.co.za (Africa), nic.nordu.net (Europe), munnari.oz.au (Pacific Rim), ds.internic.net (US East Coast), or ftp.isi.edu (US West Coast). Abstract: This document addresses the issues of the discovery of local URN -resolution services that in turn will directly translate URNs into +resolver services that in turn will directly translate URNs into URLs and URCs. The document falls into three major parts, the assumptions underlying the work, the requirements in order to be a -viable URN-resolution-service discovery service or UDS, and a -framework for designing UDSs. The requirements fall into three major -areas: evolvability, usability, and security and privacy. A UDS that -is compliant with the framework will not necessarily be compliant with -the requirements. Compliance with the requirements will need to be -validated separately. +viable Resolver Discovery Service or RDS to help in finding URN +resolvers, and a framework for designing RDSs. The requirements fall +into three major areas: evolvability, usability, and security and +privacy. An RDS that is compliant with the framework will not +necessarily be compliant with the requirements. Compliance with the +requirements will need to be validated separately. 1. Introduction -The purpose of this document is to lay out the engineering criteria for -what we will call here a URN-resolution-service discovery service (UDS). -__________ - -Acknowledgments - -Foremost acknowledgment for this document goes to Lewis Girod, as my -co-author on a previous URN requirements document and for his insightful -comments on this version of the document. In addition, I recognize the -contributors to a previous URN framework document, the "Knoxville" -group. There are too many of you to acknowledge here individually, but -thank you. Finally, I must thank the contributors to the URN working -group mailing list (urn-ietf@bunyip.com), for their animated discussions -on these and related topics. - -URN Resolution Requirements Page 1 - -This is a component of the realization of an information infrastructure. -In the case of this work, that infrastructure is to be available, "in -the Internet" or globally, and hence the solutions to the problems we -are addressing must globally scalable. In this work, we are focussing -specifically on naming of resources and resolution of those names to the -exclusion of other problems such as typing, resource access and +The purpose of this document is to lay out the engineering criteria +for what we will call here a Resolver Discovery Service (RDS), a +service to help in the learning about URN resolvers. This is a +component of the realization of an information infrastructure. In the +case of this work, that infrastructure is to be available, "in the +Internet" or globally, and hence the solutions to the problems we are +addressing must globally scalable. In this work, we are focussing +specifically on naming of resources and resolution of those names to +the exclusion of other problems such as typing, resource access and availability, security of the resources, etc. Those are all important problems, but not part of this effort. The Uniform Resource Identifier Working Group defined a naming architecture, as demonstrated in a series of three RFCs 1736[RFC1736], + + - 1 - + 1737{RFC1737}, and 1738[RFC1738]. Although several further documents are needed to complete the description of that architecture, it incorporates three core functions often associated with "naming": -identification, location, and mnemonics or semantics. Names may provide -the ability to distinguish one resource from another, by distinguishing -their "names". Names may help to provide access to a resource by -including "location" information. Lastly, names may have other semantic -or mnemonic information that either helps human users remember or figure -out the names, or include other semantic information about the resource -being named. The URI working group concluded that there was need for -persistent, globally unique identifiers, distinct from location or other -semantic information; these "names" provide identity, in that if two of -them are "the same" (under some simple rule of canonicalization), they -identify the same resource. Furthermore, the group decided that these -"names" were generally to be for machine, rather than human consumption. -One can imagine a variety human-friendly naming (HFN) schemes supporting -different suites of applications and user communities. These will need -to provide mappings to URNs in tighter or looser couplings, depending on -the namespace. It is these that will be mnemonic, content-full, and -perhaps mutable, to track changes in use and semantics. They may -provide nicknaming and other aliasing, relative or short names, context -sensitive names, descriptive names, etc. The URI naming architecture as -described in the introductions to RFCs 1736 and 1737 lays out three -sorts of components to the naming architecture: identifiers called -Uniform Resource Names (URNs), locators called Uniform Resource Locators -(URLs) and semantic meta-information called Uniform Resource -Characteristics (URCs). This document focusses on part of the problem -of the translation from URN to URL and/or URC. +identification, location, and mnemonics or semantics. By location, we +mean full-qualified Domain Names or IP addresses. Names may provide +the ability to distinguish one resource from another, by +distinguishing their "names". Names may help to provide access to a +resource by including "location" information. Lastly, names may have +other semantic or mnemonic information that either helps human users +remember or figure out the names, or include other semantic +information about the resource being named. The URI working group +concluded that there was need for persistent, globally unique +identifiers, distinct from location or other semantic information; +these "names" provide identity, in that if two of them are "the same" +(under some simple rule of canonicalization), they identify the same +resource. Furthermore, the group decided that these "names" were +generally to be for machine, rather than human consumption. One can +imagine a variety human-friendly naming (HFN) schemes supporting +different suites of applications and user communities. These will +need to provide mappings to URNs in tighter or looser couplings, +depending on the namespace. It is these that will be mnemonic, +content-full, and perhaps mutable, to track changes in use and +semantics. They may provide nicknaming and other aliasing, relative +or short names, context sensitive names, descriptive names, etc. The +URI naming architecture as described in the introductions to RFCs 1736 +and 1737 lays out three sorts of components to the naming +architecture: identifiers called Uniform Resource Names (URNs), +locators called Uniform Resource Locators (URLs) and semantic +meta-information called Uniform Resource Characteristics (URCs). This +document focusses on part of the problem of the translation from URN +to URL and/or URC. Within the URI community there has been a concept used frequently that for lack of a better term we will call a _hint_. A hint is something -that helps in the resolution of a URN. Examples of hints are: 1) the -name of a resolution service that may further resolve the URN, 2) the -address of such a service, 3) a location at which the resource was -previously found. The defining feature of hints is that they are only -hints; they may be out of date, temporarily invalid, or only applicable -within a specific locality. They do not provide a guarantee of access, -but they probably will help in the resolution process. Wemust assume -that most resolutions of URNs will be provided by the use of locally -stored hints, because maintaining a database of globally available, -completely up-to-date location information is infeasible for performance -reasons. There are a number of circumstances in which one can imagine -that hints become invalid, either because a resource has moved or -because a different URN resolution service has taken over the +that helps in the resolution of a URN; we map URNs to hints as an +interim stage in accessing a resource. A hint may also have +meta-information associated with it, such as an expiration_time or +certification of authenticity. We expect that these will stay with a +hint rather than being managed elsewhere. We will assume in all +further discussion of hints that they include any necessary +meta-information as well as the hint information itself. Examples of +hints are: 1) the name of a resolver service that may further resolve +the URN, 2) the address of such a service, 3) a location at which the +resource was previously found. The defining feature of hints is that +they are only hints; they may be out of date, temporarily invalid, or +only applicable within a specific locality. They do not provide a +guarantee of access, but they probably will help in the resolution +process. We must assume that most resolutions of URNs will be +provided by the use of locally stored hints, because maintaining a +database of globally available, completely up-to-date location +information is infeasible for performance reasons. There are a number +of circumstances in which one can imagine that hints become invalid, +either because a resource has moved or because a different URN +resolver service has taken over the responsibility for resolution of +the URN. Hints may be found in a variety of places. It is generally +assumed that a well engineered system will maintain a set of hints for -URN Resolution Requirements Page 2 + - 2 - -responsibility for resolution of the URN. Hints may be found in a -variety of places. It is generally assumed that a well engineered -system will maintain a set of hints for each URN at each location where -that URN is found. In addition, for those situations in which those -hints found locally fail, a well-engineered system will provide a -fall-back mechanism for discovering further hints. It is this fall-back -mechanism, a UDS, that is being addressed in this document. As with all -hints, there can never be a guarantee that access to a resource will be -available to all clients, even if the resource is accessible to some. -However, a UDS is expected to work with reasonably high reliability, -and, hence, may result in increased response time. The remainder of -this document falls into three sections. The first identifies several -sets of assumptions underlying this work. The next lays out the -requirements for a URN-resolution-service discovery service. This +each URN at each location where that URN is found. In addition, for +those situations in which those hints found locally fail, a +well-engineered system will provide a fall-back mechanism for +discovering further hints. It is this fall-back mechanism, an RDS, +that is being addressed in this document. As with all hints, there +can never be a guarantee that access to a resource will be available +to all clients, even if the resource is accessible to some. However, +an RDS is expected to work with reasonably high reliability, and, +hence, may result in increased response time. + +The remainder of this document falls into three sections. The first +identifies several sets of assumptions underlying this work. The next +lays out the requirements for a Resolver Discovery Service. This section is probably the most critical of the document, because it is -this that provides the metric for whether or not a proposed scheme for a -UDS is adequate or not. For the reader short on time, each of the three -major subsections of the requirements section concludes with a summary -list of the requirements identified in that section. The final section -of the document lays out a framework for such UDSs. The purpose of this -last section is to bound the search space for UDS schemes. One must be -careful not to assume that because a UDS scheme fits within the -framework that it necessarily meets the requirements. As will be -discussed further in this last section, designing within the framework -does not guarantee compliance, so compliance evaluation must also be -part of the process of evaluation of a scheme. +this that provides the metric for whether or not a proposed scheme for +a RDS is adequate or not. For the reader short on time, each of the +three major subsections of the requirements section begins with a +summary list of the requirements identified in that section. The +final section of the document lays out a framework for such RDSs. The +purpose of this last section is to bound the search space for RDS +schemes. One must be careful not to assume that because an RDS scheme +fits within the framework that it necessarily meets the requirements. +As will be discussed further in this last section, designing within +the framework does not guarantee compliance, so compliance evaluation +must also be part of the process of evaluation of a scheme. 2. Assumptions Based on previous internet drafts and discussion in both the URN BOFs and on the URN WG mailing list, three major areas of assumptions are apparent: longevity, delegation, and independence. Each will be discussed separately. The URN requirements state that a URN is to be a "persistent identifier". It is probably the case that nothing will last forever, but in the time frame of resources, users of those resources, and the systems to support the resources, the identifier should be considered to be persistent or have a longer lifetime than those other entities. There are two assumptions that are implied by longevity of URNs: -mobility and evolution. "Mobility" assumes that. everything will move +mobility and evolution. "Mobility" assumes that everything will move over the life of a URN. For example, resources will move from one machine to another, because individual machines have a much shorter lifetime than resources, generally measured in a number of years less than a decade. Owners of resources may move and wish their resources to -follow them. The services themselves will move. "Evolutions" assumes +follow them. The services themselves will move. "Evolution" assumes that the supporting infrastructure will evolve. This may take the form of entirely new transport protocols or new versions of existing protocols. Furthermore, services such as storage services may evolve; it is even possible that within a human lifetime the Unix file system model may no longer be in use! Clearly there will be evolution of and improvement in supporting authentication and security mechanisms. These are only examples. In general, we must assume that almost any piece of the supporting infrastructure of URN resolution will evolve. In order to deal with both the mobility and evolution assumptions that derive +from the assumption of longevity, we must assume that users and their -URN Resolution Requirements Page 3 + - 3 - -from the assumption of longevity, we must assume that users and their applications can remain independent of these mutating details of the supporting infrastructure. -The second and third assumptions are two forms of modularity, delegation +The second and third assumptions are two forms of modularity: delegation and isolation. The delegation assumption is that an entity may partition and pass off some of its authority or responsibility. One of those responsibilities is for assigning URNs; practically speaking, there cannot be only a single authority for assigning URNs. We expect that there will be a multi-tiered naming authority delegation. Furthermore, it is difficult to imagine a non-partitioned and delegated -global UDS, meaning that hint discovery and resolution will be -partitioned and delegated. In some UDS schemes, the delegation of +global RDS, meaning that hint discovery and resolution will be +partitioned and delegated. In some RDS schemes, the delegation of naming authority will form a basis for delegating the management and dispensing of location information. The third assumption is independence or isolation of one authority from another and, at least to some extent from its parent. Underlying much of the thinking and discussion in the URI and URN working groups has been the assumption that when a component delegates authority to another component, the delegatee can operate in that domain independently of its peers and within bounds specified by the delegation, independently of the delegator. This isolation is critically important in order to allow for independence of policy and mechanism. There are a number of more specific assumptions that fall under this rubric of isolation. First, we assume that the publisher of a resource -can choose resolution services, independently of choices made by others. +can choose resolver services, independently of choices made by others. At any given time, the owner of a namespace may choose a particular URN -resolution service for that delegated namespace. Such a URN resolution -service may be outside the UDS service model, and just identified or -located by the UDS service. Second, it must be possible to make a -choice among UDS services, perhaps based on different underlying +resolver service for that delegated namespace. Such a URN resolver +service may be outside the RDS service model, and just identified or +located by the RDS service. Second, it must be possible to make a +choice among RDS services, perhaps based on different underlying internal architectures. The reason that this is an assumption is that -there must be an evolutionary path through a sequence of core UDS +there must be an evolutionary path through a sequence of core RDS services. Although at any given time there is likely to be only one or a small set of such services, the number is likely to increase during a transition period from one architecture to another. Thus, it must be assumed that clients can make a choice among a probably very small set -of UDSs. Third, there must be independence in the choice about levels +of RDSs. Third, there must be independence in the choice about levels and models of security and authenticity required. This choice may be made by the owner of a naming subspace, in controlling who can modify hints in that subspace. A naming authority may delegate this choice to the owners of the resources named by the names it has assigned. There may be limitations on this freedom of choice in order to allow other participants to have the level of security and authenticity they -require, for example, in order to maintain the integrity of the UDS +require, for example, in order to maintain the integrity of the RDS infrastructure as a whole. Fourth, there is an assumption of independence of choice of the rule of canonicalization of URNs within a namespace, limited by any restrictions or constraints that may have been set by its parent namespace. This is a choice held by naming authorities over their own subnamespaces. Rules for canonicalization will be discussed further in the framework section below. Thus, there are assumptions of independence and isolation to allow for delegated, independent authority in a variety of domains. -URN Resolution Requirements Page 4 + - 4 - The modularity assumptions of delegation and isolation imply independence of decision and implementation, leading to a decentralization that provides a certain degree of safety from denial of service. Based on these these assumptions in conjunction with that of longevity and those for URLs and URNs as detailed in RFCs 1736 and 1737, -we can now turn to the requirements for a URN services delegation -service. +we can now turn to the requirements for a Resolver Discovery Service. 3. Requirements -The requirements applying to a URN-resolution-service discovery service -or UDS center around three important design goals: evolvability, -usability, and security and privacy. At its core the function of a UDS -is to provide hints for accessing a resource given a URN for it. These +The requirements applying to a Resolver Discovery Service or RDS +center around three important design goals: evolvability, usability, +and security and privacy. At its core the function of an RDS is to +provide hints for accessing a resource given a URN for it. These hints may range in applicability from local to global, and from short-lived to long-lived. They also may vary in their degree of -verifiable authenticity. While it may be neither feasible nor necessary -that initial implementations support every requirement, every -implementation must support evolution to systems that do support every -requirement. +verifiable authenticity. While it may be neither feasible nor +necessary that initial implementations support every requirement, +every implementation must support evolution to systems that do support +every requirement. -It is also important to note that there are other requirements, not -applicable specifically to a UDS that must also be met. A whole URN +It is important to note that there are other requirements, not +applicable specifically to an RDS that must also be met. A whole URN system will consist of namespaces, the resolution information for them, and the mapping from names in the namespaces to resolution information (or hints). URN schemes must meet the requirements of RFC 1737. Resolution information, to the extent it is expressed as URLs must meet the requirements of RFC 1736. But this does not tell the whole story. Although the URN working group will identify several acceptable namespaces and the rules binding them, such as how delegation occurs, how it is expressed in the names, how and to what extent binding to hint information will be constrained by the namespace, in the long run a document will be needed to guide the evaluation criteria for acceptance of new namespaces. These are not included in the list of requirements -below because they are not requirements for a UDS, but rather for naming +below because they are not requirements for an RDS, but rather for naming schemes themselves. +Each section below begins with a summary of the points made and discussed +in the following discussion. It is worth noting here that there is +some degree of overlap in the areas of requirements, such as in +allowing for the evolution of security mechanisms, etc. Issues may +appear in more than one requirement. It is also important to +recognize that conformance with the requirements may often be +subjective. Most of these requirements are not quantifiable and hence +conformance is a judgment call and a matter of degree. Lastly, the +reader may find that some of the requirements are those of general +applicability to distributed systems and some are specific to URN +resolution. Those of general applicability are included for +completeness and are not distinguished as such. + 3.1 Evolution +The requirements in the area of evolvability are: + + [R1] To support evolution of mechanisms, specifically for + {R1.1] a growing set of URN schemes; + + - 5 - + [R1.2] new kinds local URN resolver services; + [R1.3] new authentication schemes; + [R1.4] alternative RDS schemes active simultaneously; + [R2] To support the separation of global identification from + location information. + [R3] To allow for the support the development and deployment of + administrative control mechanisms to manage human behavior + with respect to limited resources. + One of the lessons of the Internet that we must incorporate into the development of mechanisms for resolving URNs is that we must be prepared for change. Such changes may happen slowly enough to be considered evolutionary modifications of existing services or dramatically enough to be considered revolutionary. They may permeate the Internet universe bit by bit, living side by side with earlier services or they may take the Internet by storm, causing an apparent complete transformation over a short period of time. There are several directions in which we can predict the need for evolution, even at this time, prior to the deployment of any such service. At the very least, the community and the mechanisms proposed should be prepared for these. First, we expect there to be additions and changes to the mechanisms. The community already understands that there must be a capacity for new URN schemes. A URN scheme will define a set of URNs that meet the URN requirements[RFC1737], but may have further constraints on the internal - -URN Resolution Requirements Page 5 - structure of the URN. The requirements document would allow for an overall plan in which URN schemes are free to specify parts of the URN that are left opaque in the larger picture. In fact, a URN scheme may choose to make public the algorithms for any such "opaque" part of the URN. For example, although it may be unnecessary to know the structure of an ISBN, the algorithm for understanding the structure of an ISBN has been made public. Other schemes may either choose not to make their algorithms public, or choose a scheme in which knowledge of the scheme does not provide any significant semantics to the user. In any case, we must be prepared for a growing number of URN schemes. Often in conjunction with a new URN scheme, but possibly independently -of any particular URN scheme, new resolution services may evolve. For -example, one can imagine a specialized resolution service based on the -particular structure of ISBNs that improves the efficiency of finding -documents given their ISBNs. Alternatively, one can also imagine a -general purpose resolution service that trades performance for -generality; although it exhibits only average performance resolving -ISBNs, it makes up for this weakness by understanding all existing URN -schemes, so that its clients can use the same service to resolve URNs -regardless of naming scheme. In this context, there will always be room -for improvement of services, through improved performance, better -adaptability to new URN schemes, or lower cost. In any case, new models -for URN resolution will evolve and we must be prepared to allow for -their participation in the overall resolution of URNs. +of any particular URN scheme, new kinds of resolver services may +evolve. For example, one can imagine a specialized resolver service +based on the particular structure of ISBNs that improves the +efficiency of finding documents given their ISBNs. Alternatively, one +can also imagine a general purpose resolver service that trades +performance for generality; although it exhibits only average +performance resolving ISBNs, it makes up for this weakness by +understanding all existing URN schemes, so that its clients can use +the same service to resolve URNs regardless of naming scheme. In this +context, there will always be room for improvement of services, +through improved performance, better adaptability to new URN schemes, +or lower cost. In any case, new models for URN resolution will evolve +and we must be prepared to allow for their participation in the +overall resolution of URNs. If we begin with one overall plan for URN resolution, into which the enhancements described above may fit, we must also be prepared for an + + - 6 - + evolution in the authentication schemes that will be considered either useful or necessary in the future. There is no single globally accepted authentication scheme, and there may never be one. Even if one does exist at some point in time, there will always be threats to it, and so we must always be prepared to move on to newer and better schemes, as the old ones become too easily spoofed or guessed. Lastly, in terms of mechanism, although we may develop and deploy a -single UDS scheme initially, we must be prepared for that top level -model to evolve. Thus, if the UDS model supports an apparently +single RDS scheme initially, we must be prepared for that top level +model to evolve. Thus, if the RDS model supports an apparently centralized (from a policy standpoint) scheme for inserting and modifying authoritative information, over time we must be prepared to evolve to a different model, perhaps one that has a more distributed model of authority and authenticity. If the model has no core but rather a cascaded partial discovery of information, we may find that this becomes unmanageable with an increase in scaling. Whatever the core of the model, we must be prepared for it to evolve with changes in scaling, performance, and policy constraints such as security and cost. -Second, in addition to the evolution of resolution mechanisms, we expect -that the community will follow an evolutionary path towards the -separation of semantics from identification. The URN requirements -document suggested this path as well, and there has been general -agreement in much of the community that such a separation is desirable. -This is a problem that the public at large has generally not understood. -Today we see the problem most clearly with the use of URLs for -identification. When a web page moves, its URL becomes invalid. - -URN Resolution Requirements Page 6 - -Suppose such a URL is embedded in some page, stored in long term -storage. There are three possible outcomes to this scenario. One -possibility is that the client is left high and dry with some message -saying that the page cannot be found. Alternatively, a "forwarding -pointer" may be left behind, in the form of an explicit page requesting -the client to click on a new URL. Although this will allow the client -to find the intended page, the broken link cannot be fixed because the -URL is embedded in a file outside of the client's control. A third -alternative is that the target server supplies an HTTP redirect so that -the new page is provided for the client automatically. In this case, -the client may not even realize that the URL is no longer correct. The -real problem with both of these latter two situations is that they only -work as long as the forwarding pointer can be found at the old URL. -Semantics, in this case location information, was embedded in the -identifier, and the resolution system was designed to depend on the -semantics being correct. There are few cases in which we can expect -semantics of any sort to remain valid for a long time, but in many cases -references need to have long lifespans. Most documents are only useful -while their references still function. - -We expect the evolution to separation of semantics from identification -to move along at least three paths. The first will be to develop -temporary aliases to capture the semantics currently embedded in -identifiers. This will require additional translation, but it will -allow for the development of semantics-free URNs. Second, we expect -locally shared or private aliases to arise, again supported by a -translation mechanism and allowing for the long-term storage of global, -semantics-free URNs. Such an aliasing scheme may be used to permit -local aliases for named resources as well as to present these aliases to -users in lieu of the URNs themselves. Lastly, we expect there may be a -development of global aliases. These will be more user friendly "names" -that would be shared on a much larger scale, and might be defined in -some global registry. This may include trademarked names as well as -names in extremely common use. As with the other alias systems, a -facility for translation is needed. However, in this case, since the -system of aliases is of global scope, the translation facility will be -very slow if each time an alias is translated it needs to query a -centralized or even reasonably distributed global registry. In order to -achieve acceptable speeds, the translation facility will need to -maintain a local cache, possibly in cooperation with other nearby alias -caches. Clearly this is all postulation at present, but it is provided -here to demonstrate some of the scope of evolution for which we must be -prepared. +Second, in addition to the evolution of resolution mechanisms, we +expect that the community will follow an evolutionary path towards the +separation of location information from identification. The URN +requirements document suggested this path as well, and there has been +general agreement in much of the community that such a separation is +desirable. This is a problem that the public at large has generally +not understood. Today we see the problem most clearly with the use of +URLs for identification. When a web page moves, its URL becomes +invalid. Suppose such a URL is embedded in some page, stored in long +term storage. There are three possible outcomes to this scenario. +One possibility is that the client is left high and dry with some +message saying that the page cannot be found. Alternatively, a +"forwarding pointer" may be left behind, in the form of an explicit +page requesting the client to click on a new URL. Although this will +allow the client to find the intended page, the broken link cannot be +fixed because the URL is embedded in a file outside of the client's +control. A third alternative is that the target server supplies an +HTTP redirect so that the new page is provided for the client +automatically. In this case, the client may not even realize that the +URL is no longer correct. The real problem with both of these latter +two situations is that they only work as long as the forwarding +pointer can be found at the old URL. Location information, was +embedded in the identifier, and the resolution system was designed to +depend on that location information being correct. There are few +cases in which we can expect such information to remain valid for a +long time, but in many cases references need to have long lifespans. +Most documents are only useful while their references still function. +To the extent that an RDS scheme supports the separation of global +identification from location information it will be encouraging the +longer utility of the identities. A third evolutionary requirement is even more mechanical than the -others. At any point in time, the community is likely to be supporting -a compromise position with respect to resolution. We will probably be -operating in a situation balanced between feasibility and the ideal, -perhaps with policy controls used to help stabilize the service. -Ideally, the service would be providing exactly what the customers -wanted and they in turn would not request more support than they need. -Since we will always be in a situation in which some service provision -resources will be in short supply, some form of policy controls will -always be necessary. For example, suppose hint entries are being -submitted in such volume that the hint servers are using up their excess +others. At any point in time, the community is likely to be +supporting a compromise position with respect to resolution. We will +probably be operating in a situation balanced between feasibility and +the ideal, perhaps with policy controls used to help stabilize the -URN Resolution Requirements Page 7 + - 7 - -capacity and need more disk space. An effective solution to this -problem would be a mechanism such as a pricing policy. This pricing -policy has the dual effect of both encouraging conservative use of -resources and collecting revenue for the improvement and maintenance of -the system. As technology changes and the balance of which resources -are in short supply changes, the mechanisms and policies for controlling -their use must evolve as well. +service. Ideally, the service would be providing exactly what the +customers wanted and they in turn would not request more support than +they need. Since we will always be in a situation in which some +service provision resources will be in short supply, some form of +policy controls will always be necessary. Some policy controls may be +realized as mechanisms within the servers or in the details of +protocols, while others may only be realized externally to the system. +For example, suppose hint entries are being submitted in such volume +that the hint servers are using up their excess capacity and need more +disk space. An effective solution to this problem would be a +mechanism such as a pricing policy. This pricing policy has the dual +effect of both encouraging conservative use of resources and +collecting revenue for the improvement and maintenance of the system. +We can also imagine administrative policy controls with the force of +laws or other social pressures behind them, but with no technical +mechanism enforcing or enabling them. As technology changes and the +balance of which resources are in short supply changes, the mechanisms +and policies for controlling their use must evolve as well. -In summary, the requirements in the area of evolvability are: +3.2 Usability and Feature Set Requirements - * To support evolution of mechanisms, specifically for - a) a growing set of URN schemes; - b) new local URN resolution schemes; - c) new authentication schemes; - d) alternative UDS schemes active simultaneously; - * To support and encourage the evolution toward the separation of - global identification from short-lived, locally useful, or human - friendly semantics; - * To support the development and deployment of pricing models to - manage human behavior with respect to limited resources. +To summarize, the usability requirements fall into three areas based on +participation in hint management and discovery: -3.2 Usability and Feature Set Requirements + * The publisher + [R4] URN to hint resolution must be correct and efficient with + very high probability; + [R5] Publishers must be able to select and move among URN + resolver services to locate their resources; + [R6] Publishers should be able to arrange for multiple access + points for their location information; + [R7] Publishers must be able to provide for both long-lived and + short-lived hints; + [R8] It must be relatively easy for publishers to specify to the + management and observer their hint information as well as + any security constraints they need for their hints. + * The client + [R9] The interface to the RDS must be simple, effective, and + efficient; + [R10] The client and client applications must be able to understand + the information stored in and provided by the RDS easily, + in order to be able to make informed choices. + * The management + [R11] The management of hints must be as unobtrusive as possible, + avoiding using too many network resources; + [R12] The management of hints should allow for administrative + controls that encourage certain sorts of behavior deemed + necessary to meet other requirements; + [R13] The configuration and verification of configuration of + individual RDS servers must be simple enough not to + discourage configuration and verification. Usability can be evaluated from three distinct perspectives: those of a publisher wishing to make a piece of information public, those of a + + - 8 - + client requesting URN resolution, and those of the provider or manager of resolution information. We will separately address the usability requirements from each of these three perspectives. It is worth noting that there are two additional sorts of participants in the whole naming process, as discussed in the URN WG. They are the naming authorities which choose and assign names, and the authors who include URNs in their resources. These two are not relevant to the -design of a UDS and hence are not discussed further here. +design of an RDS and hence are not discussed further here. 3.2.1 The Publisher The publisher must be able to make URNs known to potential customers. From the perspective of a publisher, it is of primary importance that -URNs be correctly and efficiently resolvable by potential clients. -Publishers also stand to gain from long-lived URNs, since they increase -the chance that references continue to point to their published -resources. The publisher must also be able to choose easily among a -variety of potential services that might translate URNs to location -information. In order to allow for this mobility among resolution -services, the architecture for resolution services specified within the -IETF should not result in a scenario in which changing from one -resolution service to another is an expensive operation. +URNs be correctly and efficiently resolvable by potential clients with +very high probability. Publishers also stand to gain from long-lived +URNs, since they increase the chance that references continue to point +to their published resources. + +The publisher must also be able to choose easily among a variety of +potential services that might translate URNs to location information. +In order to allow for this mobility among resolver services, the +architecture for resolver services specified within the IETF should +not result in a scenario in which changing from one resolver service +to another is an expensive operation. The publisher should be able to arrange for multiple access points to a -published resource. For this to be useful, resolution services should +published resource. For this to be useful, resolver services should be prepared to provide different resolution or hint information to different clients, based on a variety of information including location and the various access privileges the client might have. For example, companies might arrange for locally replicated copies of popular - -URN Resolution Requirements Page 8 - resources, and would like to provide access to the local copies only for their own employees. This is distinct from access control on the resource as a whole, and may be applied differently to different copies. The publisher should be able to provide both long and short term -information about accessing the resource. Long term information is -likely to be such information as the long term location of the resource -or the location or identity of a resolution service with which the -publisher has a long term relationship. One can imagine that the -arrangement with such a long term "authoritative" resolution service -might be a guarantee of reliability, resiliency to failure, and atomic -updates. Shorter term information is useful for short term changes in -services or to avoid short lived congestion or failure problems. For -example, if the actual repository of the resource is temporarily -inaccessible, the resource might be made available from another -repository. This short term information can be viewed as temporary -refinements of the longer term information, and as such should be more -easily and quickly made available, but may be less reliable. +location information about accessing the resource. Long term +information is likely to be such information as the long term or the +location or identity of a resolver service with which the publisher +has a long term relationship. One can imagine that the arrangement +with such a long term "authoritative" resolver service might be a +guarantee of reliability, resiliency to failure, and atomic updates. +Shorter term information is useful for short term changes in services +or to avoid short lived congestion or failure problems. For example, +if the actual repository of the resource is temporarily inaccessible, +the resource might be made available from another repository. This +short term information can be viewed as temporary refinements of the +longer term information, and as such should be more easily and quickly +made available, but may be less reliable. Lastly, the publishers will be the source of much hint information that will be stored and served by the manager of the infrastructure. Despite -the fact that many publishers will not understand the details of the UDS +the fact that many publishers will not understand the details of the RDS mechanism, it must be easy and straightforward to install hint + + - 9 - + information. The publisher must be able not only to express hints, but also to verify that what is being served by the manager is correct. Furthermore, to the extent that there are security constraints on hint information, the publisher must be able to both express them and verify -compliance to them easily. +compliance with them easily. 3.2.2 The Client From the perspective of the client, simplicity and usability are paramount. Of critical importance to serving clients effectively is that there be an efficient protocol through which the client can acquire hint information. Since resolving the name is only the first step on the way to getting access to a resource, the amount of time spent on it must be minimized. Furthermore, it will be important to be able to build simple, standard -interfaces to the UDS so that both the client and applications on the +interfaces to the RDS so that both the client and applications on the client's behalf can interpret hints and subsequently make informed choices. The client, perhaps with the assistance of the application, must be able to specify preferences and priorities and then apply them. If the ordering of hints is only partial, the client may become directly involved in the choice and interpretation of them and hence they must be understandable to that client. On the other hand, in general it should be possible to configure default preferences, with individual preferences viewed as overriding any defaults. From the client's perspective, although URNs will provide important functionality, the client is most likely to interact directly only with human friendly names (HFNs). As in direct human interaction (not computer mediated), the sharing of names will be on a small,private, or domain specific scale. HFNs will be the sorts of references and names that are easy to remember, type, choose among, assign, etc. There will - -URN Resolution Requirements Page 9 - also need to be a number of mechanisms for mapping HFNs to URNs. Such services as "yellow pages" or "search tools" fall into this category. Although we are mentioning HFNs here, it is important to recognize that HFNs and the mappings from HFNs to URNs is and must remain a separate -functionality from a UDS. Hence, although HFNs will be critical to +functionality from an RDS. Hence, although HFNs will be critical to clients, they do not fall into the domain of this document. 3.2.3 The Management Finally, we must address the usability concerns with respect to the management of the hint infrastructure itself. What we are terming "management" is a service that is distinct from publishing; it is the -core of a UDS. It involves the storage and provision of hints to the +core of an RDS. It involves the storage and provision of hints to the clients, so that they can find published resources. It also provides security to the extent that there is a commitment for provision of such security; this is addressed below. The management of hints must be as unobtrusive as possible. First, its infrastructure (hint storage servers and distribution protocols) should have as little impact as possible on other network activities. It must be remembered that this is an auxiliary activity and must remain in the background. -Second, in order to make hint management feasible, there will need to be -a system for economic incentives and disincentives. Recovering the cost -of running the system is only one reason for levying charges. The -introduction of payments often has a beneficial impact on social -behavior. It may be necessary to discourage certain forms of behavior -that when out of control have serious negative impact on the whole -community. At the same time, payment policies should encourage behavior -that benefits the community as a whole. Thus, for example, a small + - 10 - + +Second, in order to make hint management feasible, there may need to +be a system for administrative incentives and disincentives such as +pricing or legal restrictions. Recovering the cost of running the +system is only one reason for levying charges. The introduction of +payments often has a beneficial impact on social behavior. It may be +necessary to discourage certain forms of behavior that when out of +control have serious negative impact on the whole community. At the +same time, any administrative policies should encourage behavior that +benefits the community as a whole. Thus, for example, a small one-time charge for authoritatively storing a hint will encourage -conservative use of hints. If we assume that there is a fixed cost for -managing a hint, then the broader its applicability across the URN -space, the more cost effective it is. That is, when one hint can serve -for a whole collection of URNs, there will be an incentive to submit one -general hint over a large number of more specific hints. Similar -policies can be instituted to discourage the frequent changing of hints. -In these ways and others, cost effective behavior can be encouraged. +conservative use of hints. If we assume that there is a fixed cost +for managing a hint, then the broader its applicability across the URN +space, the more cost effective it is. That is, when one hint can +serve for a whole collection of URNs, there will be an incentive to +submit one general hint over a large number of more specific hints. +Similar policies can be instituted to discourage the frequent changing +of hints. In these ways and others, behavior benefitting the +community as a whole can be encouraged. -Lastly, symmetric to issues of usability for publishers, it must also be -simple for the management to configure the mapping of URNs to hints. It -must be easy both to understand the configuration and to verify that -configuration is correct. With respect to management, this requirement -may have an impact not only on the information itself but also on how it -is partitioned among network servers that collaboratively provide the -management service or UDS. For example, it should be straightforward to -bring up a server and verify that the data it is managing is correct. -Since we are discussing a global and probably growing service, -encouraging volunteer participants requires that, as with the DNS, such -volunteers can feel confident about the service they are providing and -its benefit to both themselves and the rest of the community. +Lastly, symmetric to issues of usability for publishers, it must also +be simple for the management to configure the mapping of URNs to +hints. It must be easy both to understand the configuration and to +verify that configuration is correct. With respect to management, +this requirement may have an impact not only on the information itself +but also on how it is partitioned among network servers that +collaboratively provide the management service or RDS. For example, +it should be straightforward to bring up a server and verify that the +data it is managing is correct. Although this is not a requirement, +it is worth nothing that since we are discussing a global and probably +growing service, encouraging volunteer participants suggests that, as +with the DNS, such volunteers can feel confident about the service +they are providing and its benefit to both themselves and the rest of +the community. -To summarize, the usability requirements fall into three areas based on -participation in hint management and discovery: +3.3 Security and Privacy Requirements - * The publisher - a) URN to hint resolution must be correct and efficient; - b) Publishers must be able to select among URN resolution - services to locate their resources; - c) Publishers must be able to arrange for multiple access points - for their location information; - d) Publishers must be able to provide for both long-lived and - short-lived hints; - e) It must be relatively easy for publishers to install and - observer their hint information and any security constraints - they need for their hints. - * The client - a) The interface to the UDS must be simple, effective, and - efficient; - b) The client and client applications must be able to understand - the information stored in and provided by the UDS, in order - to be able to make informed choices. - * The management - a) The management of hints must be as unobtrusive as possible, - avoiding using too many network resources; - b) A pricing scheme may be necessary to provide not only cost - recovery, but also social incentives and disincentives to - encourage certain sorts of behavior deemed necessary to meet - other requirements; - c) The configuration and verification of configuration of - individual UDS servers must be simple enough not to - discourage configuration and verification. +SUMMARY: Security and privacy requirements can be identified as some +degree of protection from threats. These requirements are all stated +in terms of possibilities or options for users of the service to +require and utilize. Hence they are requirements for the availability +of functionality, but not for the use of it. We recognize that all +security is a matter of degree and compromise. These may not satisfy +all potential customers, and there is no intention here to prevent +them from building more secure servers with more secure protocols to +suit their needs. These are intended to satisfy the needs of the +general public. -3.3 Security and Privacy Requirements + [R14] It must be possible to create authoritative versions of a hint + with access-to-modification privileges controlled; + [R15] It must be possible to determine the identity of servers or avoid + contact with unauthenticated servers; + [R16] It must be possible to reduce the threat of denial of service + by broad distribution of information across servers. -Although much of the information we are discussing in this document -might be considered "meta-information", there are some important -security and privacy concerns that must be addressed by a service -supporting that information. By first considering the sorts of attacks -that are of concern, we can then focus on the security and privacy -issues that are important. The reader will notice that integrity plays -less of a role here than might be expected. To the extent that servers -provide access control, the information they manage will have certain -integrity guarantees. Beyond that we must recognize that we are dealing -merely with hint information about the location of possibly interesting -resources. Therefore we believe that the benefit of providing integrity -guarantees beyond those provided by the servers themselves does not -outweigh the cost. + - 11 - + [R17] It must be possible within the bounds of organization policy + criteria to provide at least some degree of privacy for + traffic. + [R18] It must be possible for publishers to keep private certain + information such as an overall picture of the resources they are + publishing and the identity of their clients; + [R19] It must be possible for publishers to be able to restrict + access to the resolution of the URNs for the resources they + publish, if they wish. -Because the majority of the activity will be the distribution of hint -information, the threats of concern are those affecting the maintenance -of correct information to distribute and the availability of the sources -of information. The first approach to URN resolution is to discover -local hints. By being local, they will be as widely distributed as -possible. The drawback of such wide distribution is the inability to -update them; therefore, they will become out of date with time. An -alternative or backup mechanism would concentrate hint information in +When one discusses security, one of the primary issues is an +enumeration of the threats being considered for mitigation. The +tradeoffs often include cost in money and computational and +communications resources, ease of use, likelihood of use, and +effectiveness of the mechanisms proposed. With this in mind, let us +consider a set of threats. + +A good place to begin is with the early work of Voydock and Kent +[VK83]. They identify unauthorized release of information as a +passive attack, and all three of unauthorized modification of +information, denial of service, and spurious association initiation as +active attacks. An intruder at any protocol layer can attack at any +of the links or computational elements (hosts, routers, etc.) at that +layer. Attacks at one layer can be achieved by subverting or +attacking the lower layers. An unauthorized release of information is +a violation of privacy or confidentiality. This may be achieved by a +release of the information itself. Additional passive threats are +from secondary information through traffic analysis or other +violations of transmission security, such as noticing lengths and/or +sources and destinations of traffic. Moving to the active threats, +unauthorized modification of information can be partitioned into +problems with authenticity, integrity and ordering. Denial of service +may take the form of discarding information before it reaches its +destination or some degree of delay in delivering information. +Finally, spurious association may occur when a previous legitimate +association initiation is played back or an initiation is made under +false identity. Security measures may take the form of either +detection or prevention of each of these threats. Within the scope of +this work, we must identify those threats that are both of concern and +that we expect to be able to mediate. Of these threats the prevention +of passive attacks is known to be a particularly difficult problem to +address in the general case. + +Of these threats, the passive threats to privacy or confidentiality +and the active threats of authenticity and integrity are probably the +most important to consider here. To the extent that spurious +association causes threats to the privacy, authenticity, or integrity +with respect to information within servers managing data, it is also +important. Because updates to hint information are idempotent, at +least with short periods of time, we will set aside the problems of +ordering for this analysis. Denial of service is probably the most +difficult of these areas of threats both to detect and to prevent, and +we will therefore set it aside for the present as well, although it +will be seen that solutions to other problems will also mitigate some +of the problems of denial of service. Furthermore, because this is + + - 12 - + +intended to be provide a global service to meet the needs of a variety +of communities, the engineering tradeoffs will be different for +different clients. Hence the requirements are stated in terms of, +"It must be possible..." It is important to note that the +information of concern here is hint information, which by nature is +not guaranteed to be correct or up-to-date; therefore, it is unlikely +to be worth putting too much expense into the correctness of hints, +because there is no guarantee that they are still correct anyway. But +the exact choice of degree of privacy, authenticity, and integrity +must be determined by the needs of the client and the availability of +services from the server. + +There is one further issue to address at this point, the distinction +between mechanism and policy. In general, a policy is realized by +means of a set of mechanisms. In the case of an RDS there may be +policies internal to the RDS that it needs to have supported in order +to do its business as it sees fit. Since, in general it is in the +business of storing and distributing information, most of its security +policies may have to do with maintaining its own integrity, and are +rather limited. Beyond that, to the degree possible, it should impose +no policy on its customers, the publishers and users. It is they that +may have policies that they would like supported by the RDS. To that +end, an RDS should provide a spectrum of "tools" or mechanisms that +the customers can cause to be deployed on their behalf to realize +policies. An RDS may not provide all that is needed by a customer. A +customer may have different requirements within his or her +administrative bounds than outside. Thus, "it must be possible..." +captures the idea that the RDS must generally provide the tools to +implement policies as needed by the customers. +The first approach to URN resolution is to discover local hints. In +order for hints to be discovered locally, they will be as widely +distributed to what is considered to be local for every locale. The +drawback of such wide distribution is the wide distribution of +updates, causing network traffic problems or delays in delivering +updates. An alternative model would concentrate hint information in servers, thus requiring that update information only be distributed to -these servers. Hence the vulnerable points are the sources of the -information and the distribution network among them. If one assumes -that there will be principals of some sort that are responsible for the -information about each URN entry in the URN resolution service, then one -major threat is an attacker that masquerades as a valid principal and -inserts incorrect information into the service. A second threat vector -results from the fact that the service itself will be implemented by a -set of servers that collaborate and share the hint information critical -to their activities. By masquerading as a valid server in this pool, an -attacker can both provide incorrect information to clients and provide -incorrect information to other servers, which those servers will then -distribute. A third threat is that if the resolution service is too -centralized, service can be denied by a variety of network attacks -ranging from flooding the service with queries to causing various -network problems that will reduce access to the service. The more -centralized a service is the more vulnerable is the community that -trusts it not to be compromised. We can turn each of these into a -security goal. +these servers. In such a model the vulnerable points are the sources +of the information and the distribution network among them. Attackers +on the integrity of the information stored in a server may come in the +form of other a fake owner of the information or a fake server to the +extent that servers exchange updates with each other. Wide +replication of information among servers increases the difficult of +masquerading at all the locations of the information as well as +reducing the threat of denial service. These lead us to three +identifiable goals for our security model: -* ACCESS CONTROL ON HINTS: There needs to be an authoritative version of - each hint, and it must support change control limited only to those - principals with the right to modify it. The choice of who those - principals are or whether they are unlimited must be made by the - publisher of a hint. +* ACCESS CONTROL ON HINTS: It must be possible to create an + authoritative version of each hint with change control limited only + to those principals with the right to modify it. The choice of who + those principals are or whether they are unlimited must be made by + the publisher of a hint. + + - 13 - * SERVER AUTHENTICITY: Servers and clients must be able to learn the identity of the servers with which they communicate. This will be a matter of degree and it is possible that there will be more trustworthy, but less accessible servers, supported by a larger cluster of less authenticatable servers that are more widely available. In the worst case, if the client receives what appears to - be invalid information, the client should assume that the hint may be - inaccurate and confirmation of the data should be sought from more - reliable but less accessible data. + be unvalidated information, the client should assume that the hint + may be inaccurate and confirmation of the data might be sought from + more reliable but less accessible data. * SERVER DISTRIBUTION: Broad availability will provide resistance to denial of service. It is only to the extent that the services are available that they provide any degree of trustworthiness. In - addition, the distribution of services will reduce to vulnerability + addition, the distribution of services will reduce vulnerability of the whole community, by reducing the trust put in any single server. This must be mitigated by the fact that to the extent trust is based on a linked set of servers, if any one fails, the whole chain of trust fails; the more elements there are in such a chain, the more vulnerable it may become. -_Ensuring_ privacy for clients and publishers is in some respects -essentially impossible. Fortunately, assuring a reasonable degree of -privacy for those who want it is possible. The privacy of clients is -primarily threatened by packet sniffers and servers that log requests. -A server or a packet sniffer can without much difficulty record the -contents of queries as they pass by and compile the information into a -relation between URNs and clients. This can be combatted by anonymizing -queries through a trusted, fairly local gateway, although it involves an - -extra step and another potential bottleneck. The additional step can be -mitigated by caching responses in the gateway, thus often avoiding the -need to forward requests beyond it. A second alternative is to send -only partial queries. As will be discussed further in the framework -section, there may be two reasons for transformation of a URN, first to -canonicalize it and second to extract the identity of another server to -which to send a further request. This second alternative of sending -partial queries would be achieved by also extracting some partial URN to -further resolve at each stage. This would not anonymize the queries, -but might make them more difficult to chain together into a complete -story for logging. - -On the other hand, to the degree that the search process is distributed, -packet sniffing at a single point is less likely to reveal data about a -specific person, and is hence less threatening to privacy. Furthermore, -if clients have flexibility in terms of the specific services they -choose to use, they can regularly switch services in the hopes of -foiling a packet sniffer watching their usual access point. +Privacy is a more difficult problem to address. It may be a +double-edged sword; for example, an organization may consider it +critically important that its competitors not be able to read its +traffic, while it may also consider it important to be able to monitor +exactly what its employees are transmitting to and from whom, for a +variety of reasons such as reducing the probability that its employees +are giving or selling the company's secrets to verifying that +employees are not using company resources for private endeavor. Thus, +although there are likely to be needs for privacy and confidentiality, +what they are, who controls them and how, and by what mechanisms vary +widely enough that it is difficult to say anything concrete about them +here. The privacy of publishers is much easier to safeguard. Since they are -trying to publish something, in some situations privacy is probably not +trying to publish something, in general privacy is probably not desired. However, publishers do have information that they might like to keep private: information about who their clients are, and -information about what names exist in their namespace. The information -about who their clients are may be difficult to collect depending on the -implementation of the resolution system. For example, if the resolution -information relating to a given publisher is widely replicated, the hits -to _each_ replicated copy will need to be recorded. Of course, -determining if a specific client is requesting a given name can be -approached from the other direction, by watching the client as we saw -above. +information about what names exist in their namespace. The +information about who their clients are may be difficult to collect +depending on the implementation of the resolution system. For +example, if the resolution information relating to a given publisher +is widely replicated, the hits to _each_ replicated copy will need to +be recorded. Of course, determining if a specific client is +requesting a given name can be approached from the other direction, by +watching the client as we saw above. The other privacy issue for publishers has to do with access control over URN resolution. This issue is dependent on the implementation of -the publisher's authoritative URN resolution server. URN resolution +the publisher's authoritative URN resolver server. URN resolver servers can be designed to require proof of identity in order to be -issued resolution information; if the client does not have permission to -access the URN requested, the service denies that such a URN exists. An -encrypted protocol can also be used so that both the request and the -response are obscured. Encryption is possible in this case because the -identity of the final recipient is known (i.e. the URN server). +issued resolution information; if the client does not have permission +to access the URN requested, the service denies that such a URN +exists. An encrypted protocol can also be used so that both the +request and the response are obscured. Encryption is possible in this -In summary, security and privacy requirements can be identified as some -degree of protection from threats: + - 14 - - * It must be possible to create authoritative versions of a hint - with access to modification privileges controlled; - * It must be possible to determine the identity of servers or avoid - contact with unauthenticated servers; - * Broad availability of servers will reduce the thread to denial - of service; - * Client privacy is threatened by packet sniffing and server - logging. It is desirable to reduce these threats as much as - possible; - * It should be feasible for publishers to keep private certain - information such as an overall picture of the resources they are - publishing and the identity of their clients; - * Publishers should be able to restrict access to the resolution of - the URNs for the resources they publish, if they wish. +case because the identity of the final recipient is known (i.e. the +URN server). 4. The Framework With these assumptions and requirements in mind, one can conclude with a -general framework within which UDS designs will fall. As stated +general framework within which RDS designs will fall. As stated earlier, although this framework is put forth as a suggested guide for -UDS designers, compliance with it will in no way guarantee compliance +RDS designers, compliance with it will in no way guarantee compliance with the requirements. Such an evaluation must be performed separately. -It is also understood that there may be UDS services that do not meet +It is also understood that there may be RDS services that do not meet the requirements in clearly identified ways. This may be true especially with early plans and experiments. For example, although a careful threat analysis may have been done to understand security requirements, not all those security requirements may be addressed, in order to use existing facilities to allow for early deployment for experimentation purposes. All such lack of compliance should be clearly documented. The design of the framework is based on a simple assumption about the -syntax of a URN. This assumed syntax is: +syntax of a URN a documented in RFC-XXX[RFCXXX}. This assumed syntax +is: URN:: -where URN: is a prefix on all URNs, NID is the namespace identifier, and -NSS is the namespace specific string. The prefix identifies each URN as -such. The NID determines the general syntax for all URNs within its -namespace. The NSS is probably partitioned into a set of delegated and -subdelegated namespaces, and this is probably reflected in further -syntax specifications. In the more complex environments, each delegated -namespace will be permitted to choose the syntax of the variable part of -the namespace that has been delegated to it. In simpler namespaces, the -syntax will be restricted completely by the parent namespace. For -example, although the DNS does not meet all the requirements for URNs, -it has a completely restricted syntax, such that any further structuring -must be done only by adding further refinements to the left, maintaining -the high order to low order, right to left structure. A delegated -syntax might be one in which a host is named by the DNS, but to the -right of that and separated by an "@" is a string whose internal -ordering is defined by the file system on the host, which may be defined -high order to low order, left to right. Of course, much more complex -and nested syntaxes should be possible, especially given the need to -grandfather namespaces. In order to resolve URNs, rules will be needed -for two reasons. One is simply to canonicalize those namespaces that do -not fall into a straightforward (probably right to left or left to -right) ordering of the components of a URN, as determined by the -delegated naming authorities involved. It is also possible that rules -will be needed in order to derive from URNs the names of UDS servers to -be used in stages. +where URN: is a prefix on all URNs, NID is the namespace identifier, +and NSS is the namespace specific string. The prefix identifies each +URN as such. The NID determines the general syntax for all URNs +within its namespace. The NSS is probably partitioned into a set of +delegated and subdelegated namespaces, and this is probably reflected +in further syntax specifications. In more complex environments, each +delegated namespace will be permitted to choose the syntax of the +variable part of the namespace that has been delegated to it. In +simpler namespaces, the syntax will be restricted completely by the +parent namespace. For example, although the DNS does not meet all the +requirements for URNs, it has a completely restricted syntax, such +that any further structuring must be done only by adding further +refinements to the left, maintaining the high order to low order, +right to left structure. A delegated syntax might be one in which a +host is named by the DNS, but to the right of that and separated by an +"@" is a string whose internal ordering is defined by the file system +on the host, which may be defined high order to low order, left to +right. Of course, much more complex and nested syntaxes should be +possible, especially given the need to grandfather namespaces. In +order to resolve URNs, rules will be needed for two reasons. One is +simply to canonicalize those namespaces that do not fall into a +straightforward (probably right to left or left to right) ordering of +the components of a URN, as determined by the delegated naming +authorities involved. It is also possible that rules will be needed +in order to derive from URNs the names of RDS servers to be used in +stages. -The NID defines a top level syntax. This syntax will determine whether -the NID alone or in conjunction with some extraction from the NSS (for -the top level naming authority name) to identify the first level server +The NID defines a top level syntax. This syntax will determine +whether the NID alone or in conjunction with some extraction from the +NSS (for the top level naming authority name) is to be used to -to be contacted. Each stage of the lookup either a new rule for -generating the strings used in yet another lookup (the strings being the -identify of another UDS server and possibly a string to be resolved if -it is different than the original URN) or a reference outside the UDS to -a private URN resolution service, sidestepping any furthere use of the -UDS scheme. Figure 1 depicts this process. + - 15 - + +identify the first level server to be contacted. At each stage of the +lookup either a new rule for generating the strings used in yet +another lookup (the strings being the identity of another RDS server +and possibly a string to be resolved if it is different than the +original URN) or a reference outside the RDS to a private URN +resolver service, sidestepping any further use of the RDS scheme. +Figure 1 depicts this process. URN: | | | | v +-------------------+ |Global NID registry| +-------------------+ | | | - (return rule or URN resolution service reference) + (return rule or URN resolver service reference) | +----------------------------------+ | | - +->(apply rule to determine UDS server) | + +->(apply rule to determine RDS server) | | | | | | | | | | | +----------+ | - | |UDS server| +-----------------+ + | |RDS server| +-----------------+ | +----------+ | | | | v | | | (set of choices) | | +----+----------(...)--------+ | (rule) | | | | | | | | | | +------+ | | v v +----------+ +----------+ |private | |private | |URN | |URN | - |resolution| |resolution| + |resolver | |resolver | |service | |service | +----------+ +----------+ - Figure 1: A UDS framework + Figure 1: An RDS framework -There are several points worth noting about the UDS framework. First, -it leaves open the determination of the protocols and data organization, -distribution and replication needed to support a particular UDS scheme. -Second, it leaves open the location of the computations engendered by +There are several points worth noting about the RDS framework. First, +it leaves open the determination of the protocols, data organization, +distribution and replication needed to support a particular RDS -the rules. Third, it leaves open the possibility that partitioning -(distribution) of the UDS database need not be on the same boundaries as -the name delegation. This may seem radical to some, but if the -information is stored in balanced B-trees for example, the partitioning -may not be along those naming authority delegation boundaries. Lastly, -it leaves open access to the Global NID Registry. Is this distributed -to every client, or managed in widely distributed servers? One concept -that has not been addressed in Figure 1 is that there may be more than -one UDS available at any given time, in order to allow for evolution to -new schemes. Thus, the picture should probably look more like Figure 2. + - 16 - + +scheme. Second, it leaves open the location of the computations +engendered by the rules. Third, it leaves open the possibility that +partitioning (distribution) of the RDS database need not be on the +same boundaries as the name delegation. This may seem radical to +some, but if the information is stored in balanced B-trees for +example, the partitioning may not be along those naming authority +delegation boundaries. Lastly, it leaves open access to the Global +NID Registry. Is this distributed to every client, or managed in +widely distributed servers? + +One concept that has not been addressed in Figure 1 is that there may +be more than one RDS available at any given time, in order to allow +for evolution to new schemes. Thus, the picture should probably look +more like Figure 2. URN:: | | +-----------+-------(...)-------+ | | | | | | v v +---------------------+ +---------------------+ |Global NID registry 1| |Global NID registry N| +---------------------+ +---------------------+ . . . . . . - Figure 2: More than one co-existing UDS scheme + Figure 2: More than one co-existing RDS scheme -If we are to support more than one co-existing UDS scheme, there will +If we are to support more than one co-existing RDS scheme, there will need to be coordination between them with respect to storage and propagation of information and modifications. The issue is that generally it should be assumed that all information should be available -through any operational UDS scheme. One cannot expect potential -publishers to submit updates to N UDS schemes. Hence there will need to +through any operational RDS scheme. One cannot expect potential +publishers to submit updates to N RDS schemes. Hence there will need to be a straightforward mapping of information from one to the other of these schemes. It is possible that that transformation will only go in -one direction, because a newer UDS service is replacing an older one, +one direction, because a newer RDS service is replacing an older one, which is not kept up to date, in order to encourage transfer to the newer one. Thus, at some point, updates may be made only to the newer one and not be made available to the older one. Such a situation should probably be avoided, if possible. -This framework is presented in order to suggest to UDS scheme designers -a direction in which to start designing. It is obvious to the reader -that adherence to this framework will in no way guarantee compliance -with the requirements or even assumption described in Sections 2 and 3. -These must be reviewed independently as part of the design process. -There is no single correct design that will meet these requirements. -Furthermore, it is assumed that preliminary proposals may not meet all -the requirements, but should be expected to itemized and justify any -lack of compliance. +This framework is presented in order to suggest to RDS scheme +designers a direction in which to start designing. It should be +obvious to the reader that adherence to this framework will in no way +guarantee compliance with the requirements or even assumption +described in Sections 2 and 3. These must be reviewed independently +as part of the design process. There is no single correct design that -5. References + - 17 - + +will meet these requirements. Furthermore, it is assumed that +preliminary proposals may not meet all the requirements, but should be +expected to itemized and justify any lack of compliance. + +5. Acknowledgments + +Foremost acknowledgment for this document goes to Lewis Girod, as my +co-author on a previous URN requirements document and for his insightful +comments on this version of the document. In addition, I recognize the +contributors to a previous URN framework document, the "Knoxville" +group. There are too many of you to acknowledge here individually, but +thank you. Finally, I must thank the contributors to the URN working +group mailing list (urn-ietf@bunyip.com), for their animated discussions +on these and related topics. + +6. References [RFC1736] Kunze, J., "Functional Recommendations for Internet Resource Locators", RFC 1736, February, 1995. [RFC1737] Sollins, K. and Masinter, L., "Functional Requirements for Uniform Resource Names", RFC 1738, December, 1994. [RFC1738] Berners-Lee, T., Masinter, L., McCahill, M., "Uniform Resource Locators (URL)", RFC 1738, December, 1994. -6. Contact information: +[RFCXXX] Moats, Ryan, "URN Syntax", currently available as +draft-ietf-urn-syntax-04.txt, March, 1997. + +[VK83] Voydock, V. L., and Kent, S. T., "Security Mechanisms in +High-Level Protocols", ACM Computing Surveys, v. 15, No. 2, June, +1983, pp. 135-171. + +7. Contact information: Karen Sollins MIT Laboratory for Computer Science 545 Technology Sq. Cambridge, MA 02139 Tel: +1 617 253 6006 Email: sollins@lcs.mit.edu -This InternetDraft expires on May 26, 1997. +This Internet Draft expires on September 28, 1997. + + - 18 -