From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc9138.txt | 956 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 956 insertions(+) create mode 100644 doc/rfc/rfc9138.txt (limited to 'doc/rfc/rfc9138.txt') diff --git a/doc/rfc/rfc9138.txt b/doc/rfc/rfc9138.txt new file mode 100644 index 0000000..45b44b7 --- /dev/null +++ b/doc/rfc/rfc9138.txt @@ -0,0 +1,956 @@ + + + + +Internet Research Task Force (IRTF) J. Hong +Request for Comments: 9138 T. You +Category: Informational ETRI +ISSN: 2070-1721 L. Dong + C. Westphal + Futurewei Technologies Inc. + B. Ohlman + Ericsson + November 2021 + + +Design Considerations for Name Resolution Service in Information-Centric + Networking (ICN) + +Abstract + + This document provides the functionalities and design considerations + for a Name Resolution Service (NRS) in Information-Centric Networking + (ICN). The purpose of an NRS in ICN is to translate an object name + into some other information such as a locator, another name, etc. in + order to forward the object request. This document is a product of + the Information-Centric Networking Research Group (ICNRG). + +Status of This Memo + + This document is not an Internet Standards Track specification; it is + published for informational purposes. + + This document is a product of the Internet Research Task Force + (IRTF). The IRTF publishes the results of Internet-related research + and development activities. These results might not be suitable for + deployment. This RFC represents the consensus of the Information- + Centric Networking Research Group of the Internet Research Task Force + (IRTF). Documents approved for publication by the IRSG are not + candidates for any level of Internet Standard; see Section 2 of RFC + 7841. + + Information about the current status of this document, any errata, + and how to provide feedback on it may be obtained at + https://www.rfc-editor.org/info/rfc9138. + +Copyright Notice + + Copyright (c) 2021 IETF Trust and the persons identified as the + document authors. All rights reserved. + + This document is subject to BCP 78 and the IETF Trust's Legal + Provisions Relating to IETF Documents + (https://trustee.ietf.org/license-info) in effect on the date of + publication of this document. Please review these documents + carefully, as they describe your rights and restrictions with respect + to this document. + +Table of Contents + + 1. Introduction + 2. Name Resolution Service in ICN + 2.1. Explicit Name Resolution Approach + 2.2. Name-Based Routing Approach + 2.3. Hybrid Approach + 2.4. Comparisons of Name Resolution Approaches + 3. Functionalities of NRS in ICN + 3.1. Support Heterogeneous Name Types + 3.2. Support Producer Mobility + 3.3. Support Scalable Routing System + 3.4. Support Off-Path Caching + 3.5. Support Nameless Object + 3.6. Support Manifest + 3.7. Support Metadata + 4. Design Considerations for NRS in ICN + 4.1. Resolution Response Time + 4.2. Response Accuracy + 4.3. Resolution Guarantee + 4.4. Resolution Fairness + 4.5. Scalability + 4.6. Manageability + 4.7. Deployed System + 4.8. Fault Tolerance + 4.9. Security and Privacy + 4.9.1. Confidentiality + 4.9.2. Authentication + 4.9.3. Integrity + 4.9.4. Resiliency and Availability + 5. Conclusion + 6. IANA Considerations + 7. Security Considerations + 8. References + 8.1. Normative References + 8.2. Informative References + Acknowledgements + Authors' Addresses + +1. Introduction + + The current Internet is based upon a host-centric networking + paradigm, where hosts are identified with IP addresses and + communication is possible between any pair of hosts. Thus, + information in the current Internet is identified by the name of the + host (or server) where the information is stored. In contrast to + host-centric networking, the primary communication objects in + Information-Centric Networking (ICN) are the named data objects + (NDOs), and they are uniquely identified by location-independent + names. Thus, ICN aims for the efficient dissemination and retrieval + of NDOs at a global scale and has been identified and acknowledged as + a promising technology for a future Internet architecture to overcome + the limitations of the current Internet, such as scalability and + mobility [Ahlgren] [Xylomenos]. ICN also has emerged as a candidate + architecture in the Internet of Things (IoT) environment since IoT + focuses on data and information [Baccelli] [Amadeo] [Quevedo] + [Amadeo2] [ID.Zhang2]. + + Since naming data independently from its current location (where it + is stored) is a primary concept of ICN, how to find any NDO using a + location-independent name is one of the most important design + challenges in ICN. Such ICN routing may comprise three steps + [RFC7927]: + + (1) Name resolution: matches/translates a content name to the + locator of the content producer or source that can provide the + content. + + (2) Content request routing: routes the content request towards the + content's location based either on its name or locator. + + (3) Content delivery: transfers the content to the requester. + + Among the three steps of ICN routing, this document investigates only + the name resolution step, which translates a content name to the + content locator. In addition, this document covers various possible + types of name resolution in ICN such as one name to another name, + name to locator, name to manifest, name to metadata, etc. + + The focus of this document is a Name Resolution Service (NRS) itself + as a service or a system in ICN, and it provides the functionalities + and the design considerations for an NRS in ICN as well as the + overview of the NRS approaches in ICN. On the other hand, its + companion document [NRSarch] describes considerations from the + perspective of the ICN architecture and routing system when using an + NRS in ICN. + + This document represents the consensus of the Information-Centric + Networking Research Group (ICNRG). It has been reviewed extensively + by the Research Group (RG) members who are actively involved in the + research and development of the technology covered by this document. + It is not an IETF product and is not a standard. + +2. Name Resolution Service in ICN + + A Name Resolution Service (NRS) in ICN is defined as the service that + provides the name resolution function for translating an object name + into some other information such as a locator, another name, + metadata, next-hop info, etc. that is used for forwarding the object + request. In other words, an NRS is a service that can be provided by + the ICN infrastructure to help a consumer reach a specific piece of + information (or named data object). The consumer provides an NRS + with a persistent name, and the NRS returns a name or locator (or + potentially multiple names and locators) that can reach a current + instance of the requested object. + + The name resolution is a necessary process in ICN routing, although + the name resolution either can be separated from the content request + routing as an explicit process or can be integrated with the content + request routing as an implicit process. The former is referred to as + an "explicit name resolution approach", and the latter is referred to + as a "name-based routing approach" in this document. + +2.1. Explicit Name Resolution Approach + + An NRS could take the explicit name resolution approach to return the + locators of the content to the client, which will be used by the + underlying network as the identifier to route the client's request to + one of the producers or to a copy of the content. There are several + ICN projects that use the explicit name resolution approach, such as + Data-Oriented Network Architecture (DONA) [Koponen], PURSUIT + [PURSUIT], Network of Information (NetInf) [SAIL], MobilityFirst + [MF], IDNet [Jung], etc. In addition, the explicit name resolution + approach has been allowed for 5G control planes [SA2-5GLAN]. + +2.2. Name-Based Routing Approach + + An NRS could take the name-based routing approach, which integrates + name resolution with content request message routing as in Named Data + Networking / Content-Centric Networking (NDN/CCNx) [NDN] [CCNx]. + + In cases where the content request also specifies the reverse path, + as in NDN/CCNx, the name resolution mechanism also derives the + routing path for the data. This adds a requirement to the name + resolution service to propagate the request in a way that is + consistent with the subsequent data forwarding. Namely, the request + must select a path for the data based upon finding a copy of the + content but also properly delivering the data. + +2.3. Hybrid Approach + + An NRS could also take hybrid approach. For instance, it can attempt + the name-based routing approach first. If this fails at a certain + router, the router can go back to the explicit name resolution + approach. The hybrid NRS approach also works the other way around: + first by performing explicit name resolution to find the locators of + routers, then by routing the client's request using the name-based + routing approach. + + A hybrid approach would combine name resolution over a subset of + routers on the path with some tunneling in between (say, across an + administrative domain) so that only a few of the nodes in the ICN + network perform name resolution in the name-based routing approach. + +2.4. Comparisons of Name Resolution Approaches + + The following compares the explicit name resolution and the name- + based routing approaches in several aspects: + + * Overhead due to the maintenance of the content location: The + content reachability is dynamic and includes new content being + cached or content being expired from a cache, content producer + mobility, etc. Maintaining a consistent view of the content + location across the network requires some overhead that differs + for the name resolution approaches. The name-based routing + approach may require flooding parts of the network for update + propagation. In the worst case, the name-based routing approach + may flood the whole network (but mitigating techniques may be used + to scope the flooding). However, the explicit name resolution + approach only requires updating propagation in part of the name + resolution system (which could be an overlay with a limited number + of nodes). + + * Resolution capability: The explicit name resolution approach, if + designed and deployed with sufficient robustness, can offer at + least weak guarantees that resolution will succeed for any content + name in the network if it is registered to the name resolution + overlay. In the name-based routing approach, content resolution + depends on the flooding scope of the content names (i.e., content + publishing message and the resulting name-based routing tables). + For example, when content is cached, the router may only notify + its direct neighbors of this information. Thus, only those + neighboring routers can build a name-based entry for this cached + content. But if the neighboring routers continue to propagate + this information, the other nodes are able to direct to this + cached copy as well. + + * Node failure impact: Nodes involved in the explicit name + resolution approach are the name resolution overlay servers (e.g., + resolution handlers in DONA), while the nodes involved in the + name-based routing approach are routers that route messages based + on the name-based routing tables (e.g., NDN routers). Node + failures in the explicit name resolution approach may cause some + content request routing to fail even though the content is + available. This problem does not exist in the name-based routing + approach because other alternative paths can be discovered to + bypass the failed ICN routers, given the assumption that the + network is still connected. + + * Maintained databases: The storage usage for the explicit name + resolution approach is different from that of the name-based + routing approach. The explicit name resolution approach typically + needs to maintain two databases: name-to-locator mapping in the + name resolution overlay and routing tables in the routers on the + data forwarding plane. The name-based routing approach needs to + maintain only the name-based routing tables. + + Additionally, some other intermediary step may be included in the + name resolution -- namely, the mapping of one name to other names -- + in order to facilitate the retrieval of named content by way of a + manifest [Westphal] [RFC8569]. The manifest is resolved using one of + the two above approaches, and it may include further mapping of names + to content and location. The steps for name resolution then become + the following: first, translate the manifest name into a location of + a copy of the manifest, which includes further names of the content + components and potentially locations for the content, then retrieve + the content by using these names and/or location, potentially + resulting in additional name resolutions. + + Thus, no matter which approach is taken by an NRS in ICN, the name + resolution is the essential function that shall be provided by the + ICN infrastructure. + +3. Functionalities of NRS in ICN + + This section presents the functionalities of an NRS in ICN. + +3.1. Support Heterogeneous Name Types + + In ICN, a name is used to identify the data object and is bound to it + [RFC7927]. ICN requires uniqueness and persistency of the name of + the data object to ensure the reachability of the object within a + certain scope. There are heterogeneous approaches to designing ICN + naming schemes [Bari]. Ideally, a name can include any form of + identifier, which can be flat or hierarchical, human readable or non- + readable. + + Although there are diverse types of naming schemes proposed in the + literature, they all need to provide basic functions for identifying + a data object, supporting named data lookup, and routing. An NRS may + combine the better aspects of different schemes. Basically, an NRS + should be able to support a generic naming schema so that it can + resolve any type of content name, irrespective of whether it is flat, + hierarchical, attribute based, or anything else. + + In PURSUIT [PURSUIT], names are flat, and the rendezvous functions + are defined for an NRS, which is implemented by a set of rendezvous + nodes (RNs), known as the rendezvous network (RENE). Thus, a name + consists of a sequence of scope IDs, and a single rendezvous ID is + routed by the RNs in RENE. Thus, PURSUIT decouples name resolution + and data routing, where the NRS is performed by the RENE. + + In MobilityFirst [MF], a name known as a "Global Unique Identifier + (GUID)", derived from a human-readable name via a global naming + service, is a flat typed 160-bit string with self-certifying + properties. Thus, MobilityFirst defines a Global Name Resolution + Service (GNRS), which resolves GUIDs to network addresses and + decouples name resolution and data routing similarly to PURSUIT. + + In NetInf [Dannewitz], information objects are named using Named + Information (NI) names [RFC6920], which consist of an authority part + and digest part (content hash). The NI names can be flat as the + authority part is optional. Thus, the NetInf architecture also + includes a Name Resolution System (NRS), which can be used to resolve + NI names to addresses in an underlying routable network layer. + + In NDN [NDN] and CCNx [CCNx], names are hierarchical and may be + similar to URLs. Each name component can be anything, including a + human-readable string or a hash value. NDN/CCNx adopts the name- + based routing approach. The NDN router forwards the request by doing + the longest-match lookup in the Forwarding Information Base (FIB) + based on the content name, and the request is stored in the Pending + Interest Table (PIT). + +3.2. Support Producer Mobility + + ICN inherently supports mobility by consumers. Namely, consumer or + client mobility is handled by re-requesting the content in case the + mobility event (say, handover) occurred before receiving the + corresponding content from the network. Since ICN can ensure that + content reception continues without any disruption in ICN + applications, seamless mobility from the consumer's point of view can + be easily supported. + + However, producer mobility does not emerge naturally from the ICN + forwarding model as does consumer mobility. If a producer moves into + a different network location or a different name domain, which is + assigned by another authoritative publisher, it would be difficult + for the mobility management to update Routing Information Base (RIB) + and FIB entries in ICN routers with the new forwarding path in a very + short time. Therefore, various ICN architectures in the literature + have proposed adopting an NRS to achieve the producer or publisher + mobility, where the NRS can be implemented in different ways such as + rendezvous points and/or overlay mapping systems. + + In NDN [Zhang2], for producer mobility support, rendezvous mechanisms + have been proposed to build interest rendezvous (RV) with data + generated by a mobile producer (MP). This can be classified into two + approaches: chase mobile producer and rendezvous data. Regarding MP + chasing, rendezvous acts as a mapping service that provides the + mapping from the name of the data produced by the MP to the name of + the MP's current point of attachment (PoA). Alternatively, the RV + serves as a home agent as in IP mobility support, so the RV enables + the consumer's Interest message to tunnel towards the MP at the PoA. + Regarding rendezvous data, the solution involves moving the data + produced by the MP to a data depot instead of forwarding Interest + messages. Thus, a consumer's Interest message can be forwarded to + stationary place called a "data rendezvous", so it would either + return the data or fetch it using another mapping solution. + Therefore, RV or other mapping functions are in the role of an NRS in + NDN. + + In [Ravindran], the forwarding label (FL) object is used to enable + identifier (ID) and locator (LID) namespaces to be split in ICN. + Generally, IDs are managed by applications, while locators are + managed by a network administrator so that IDs are mapped to + heterogeneous name schemes and LIDs are mapped to the network domains + or to specific network elements. Thus, the proposed FL object acts + as a locator (LID) and provides the flexibility to forward Interest + messages through a mapping service between IDs and LIDs. Therefore, + the mapping service in control plane infrastructure can be considered + as an NRS in this draft. + + In MobilityFirst [MF], both consumer and publisher mobility can be + primarily handled by the global name resolution service (GNRS), which + resolves GUIDs to network addresses. Thus, the GNRS must be updated + for mobility support when a network-attached object changes its point + of attachment, which differs from NDN/CCNx. + + In NetInf [Dannewitz], mobility is handled by an NRS in a very + similar way to MobilityFirst. + + Besides the consumer and producer mobility, ICN also faces challenges + to support the other dynamic features such as multi-homing, + migration, and replication of named resources such as content, + devices, and services. Therefore, an NRS can help to support these + dynamic features. + +3.3. Support Scalable Routing System + + In ICN, the name of data objects is used for routing by either a name + resolution step or a routing table lookup. Thus, routing information + for each data object should be maintained in the routing base, such + as RIB and FIB. Since the number of data objects would be very + large, the size of information bases would be significantly larger as + well [RFC7927]. + + The hierarchical namespace used in CCNx [CCNx] and NDN [NDN] + architectures reduces the size of these tables through name + aggregation and improves the scalability of the routing system. A + flat naming scheme, on the other hand, would aggravate the + scalability problem of the routing system. The non-aggregated name + prefixes injected into the Default Route Free Zone (DFZ) of ICN would + create a more serious scalability problem when compared to the + scalability issues of the IP routing system. Thus, an NRS may play + an important role in the reduction of the routing scalability problem + regardless of the types of namespaces. + + In [Afanasyev], in order to address the routing scalability problem + in NDN's DFZ, a well-known concept called "map-and-encap" is applied + to provide a simple and secure namespace mapping solution. In the + proposed map-and-encap design, data whose name prefixes do not exist + in the DFZ forwarding table can be retrieved by a distributed mapping + system called NDNS, which maintains and looks up the mapping + information from a name to its globally routed prefixes, where NDNS + is a kind of an NRS. + +3.4. Support Off-Path Caching + + Caching in-network is considered to be a basic architectural + component of an ICN architecture. It may be used to provide a level + of quality-of-service (QoS) experience to users to reduce the overall + network traffic, to prevent network congestion and denial-of-service + (DoS) attacks, and to increase availability. Caching approaches can + be categorized into off-path caching and on-path caching based on the + location of caches in relation to the forwarding path from the + original server to the consumer. Off-path caching, also referred to + as "content replication" or "content storing", aims to replicate + content within a network in order to increase availability, + regardless of the relationship of the location to the forwarding + path. Thus, finding off-path cached objects is not trivial in name- + based routing of ICN. In order to support off-path caches, replicas + are usually advertised into a name-based routing system or into an + NRS. + + In [Bayhan], an NRS is used to find off-path copies in the network, + which may not be accessible via name-based routing mechanisms. Such + a capability can be helpful for an Autonomous System (AS) to avoid + the costly inter-AS traffic for external content more, to yield + higher bandwidth efficiency for intra-AS traffic, and to decrease the + data access latency for a pleasant user experience. + +3.5. Support Nameless Object + + In CCNx 1.0 [Mosko2], the concept of a "Nameless Object", which is a + Content Object without a name, is introduced to provide a means to + move content between storage replicas without having to rename or re- + sign the Content Objects for the new name. Nameless Objects can be + addressed by the ContentObjectHash, which is to restrict Content + Object matching by using a SHA-256 hash. + + An Interest message would still carry a name and a ContentObjectHash, + where a name is used for routing, while a ContentObjectHash is used + for matching. However, on the reverse path, if the Content Object's + name is missing, it is a "Nameless Object" and only matches against + the ContentObjectHash. Therefore, a consumer needs to resolve the + proper name and hashes through an outside system, which can be + considered as an NRS. + +3.6. Support Manifest + + For collections of data objects that are organized as large and file- + like contents [FLIC], manifests are used as data structures to + transport this information. Thus, manifests may contain hash digests + of signed Content Objects or other manifests so that large Content + Objects that represent a large piece of application data can be + collected by using such a manifest. + + In order to request Content Objects, a consumer needs to know a + manifest root name to acquire the manifest. In the case of File-Like + ICN Collections (FLIC), a manifest name can be represented by a + nameless root manifest so that an outside system such as an NRS may + be involved to give this information to the consumer. + +3.7. Support Metadata + + When resolving the name of a Content Object, NRS could return a rich + set of metadata in addition to returning a locator. The metadata + could include alternative object locations, supported object transfer + protocol(s), caching policy, security parameters, data format, hash + of object data, etc. The consumer could use this metadata for the + selection of object transfer protocol, security mechanism, egress + interface, etc. An example of how metadata can be used in this way + is provided by the Networked Object (NEO) ICN architecture [NEO]. + +4. Design Considerations for NRS in ICN + + This section presents the design considerations for NRS in ICN. + +4.1. Resolution Response Time + + The name resolution process should provide a response within a + reasonable amount of time. The response should be either a proper + mapping of the name to a copy of the content or an error message + stating that no such object exists. If the name resolution does not + map to a location, the system may not issue any response, and the + client should set a timer when sending a request so as to consider + the resolution incomplete when the timer expires. + + The acceptable response delay could be of the order of a round-trip + time between the client issuing the request and the NRS servers that + provide the response. While this RTT may vary greatly depending on + the proximity between the two end points, some upper bound needs to + be used. Especially in some delay-sensitive scenarios such as + industrial Internet and telemedicine, the upper bound of the response + delay must be guaranteed. + + The response time includes all the steps of the resolution, including + potentially a hop-by-hop resolution or a hierarchical forwarding of + the resolution request. + +4.2. Response Accuracy + + An NRS must provide an accurate response -- namely, a proper binding + of the requested name (or prefix) with a location. The response can + be either a (prefix, location) pair or the actual forwarding of a + request to a node holding the content, which is then transmitted in + return. + + An NRS must provide an up-to-date response -- namely, an NRS should + be updated within a reasonable time when new copies of the content + are being stored in the network. While every transient cache + addition/eviction should not trigger an NRS update, some origin + servers may move and require the NRS to be updated. + + An NRS must provide mechanisms to update the mapping of the content + with its location. Namely, an NRS must provide a mechanism for a + content provider to add new content, revoke old/dated/obsolete + content, and modify existing content. Any content update should then + be propagated through the NRS system within reasonable delay. + + Content that is highly mobile may require specifying some type of + anchor that is kept at the NRS instead of the content location. + +4.3. Resolution Guarantee + + An NRS must ensure that the name resolution is successful with high + probability if the name-matching content exists in the network, + regardless of its popularity and the number of cached copies existing + in the network. Per Section 4.1, some resolutions may not occur in a + timely manner. However, the probability of such an event should be + minimized. The NRS system may provide a probability (five 9s or five + sigmas, for instance) that a resolution will be satisfied. + +4.4. Resolution Fairness + + An NRS could provide this service for all content in a fair manner, + independently of the specific content properties (content producer, + content popularity, availability of copies, content format, etc.). + Fairness may be defined as a per-request delay to complete the NRS + steps that is agnostic to the properties of the content itself. + Fairness may be defined as well as the number of requests answered + per unit of time. + + However, it is notable that content (or their associated producer) + may request a different level of QoS from the network (see [RFC9064], + for instance), and this may include the NRS as well, in which case + considerations of fairness may be restricted to content within the + same class of service. + +4.5. Scalability + + The NRS system must scale up to support a very large user population + (including human users as well as machine-to-machine communications). + As an idea of the scale, it is expected that 50 billion devices will + be connected in 2025 (per ITU projections). The system must be able + to respond to a very large number of requests per unit of time. + Message forwarding and processing, routing table buildup, and name + record propagation must be efficient and scalable. + + The NRS system must scale up with the number of pieces of content + (content names) and should be able to support a content catalog that + is extremely large. Internet traffic is of the order of zettabytes + per year (10^21 bytes). Since NRS is associated with actual traffic, + the number of pieces of content should scale with the amount of + traffic. Content size may vary from a few bytes to several GB, so + the NRS should be expected scale up to a catalog of the size of 10^21 + in the near future, and larger beyond. + + The NRS system must be able to scale up -- namely, to add NRS servers + to the NRS system in a way that is transparent to the users. The + addition of a new server should have a limited negative impact on the + other NRS servers (or should have a negative impact on only a small + subset of the NRS servers). The impact of adding new servers may + induce some overhead at the other servers to rebuild a hierarchy or + to exchange messages to include the new server within the service. + Further, data may be shared among the new servers for load balancing + or tolerance to failure. These steps should not disrupt the service + provided by the NRS and should improve the quality of the service in + the long run. + + The NRS system may support access from a heterogeneity of connection + methods and devices. In particular, the NRS system may support + access from constrained devices, and interactions with the NRS system + would not be too costly. An IoT node, for instance, should be able + to access the NRS system as well as a more powerful node. + + The NRS system should scale up in its responsiveness to the increased + request rate that is expected from applications such as IoT or + machine-to-machine (M2M), where data is being frequently generated + and/or requested. + +4.6. Manageability + + The NRS system must be manageable since some parts of the system may + grow or shrink dynamically and an NRS system node may be added or + deleted frequently. + + The NRS system may support an NRS management layer that allows for + adding or subtracting NRS nodes. In order to infer the circumstance, + the management layer can measure the network status. + +4.7. Deployed System + + The NRS system must be deployable since deployability is important + for a real-world system. The NRS system must be deployable in + network edges and cores so that the consumers as well as ICN routers + can perform name resolution in a very low latency. + +4.8. Fault Tolerance + + The NRS system must ensure resiliency in the event of NRS server + failures. The failure of a small subset of nodes should not impact + the NRS performance significantly. + + After an NRS server fails, the NRS system must be able to recover + and/or restore the name records stored in the NRS server. + +4.9. Security and Privacy + + On utilizing an NRS in ICN, there are some security considerations + for the NRS servers/nodes and name mapping records stored in the NRS + system. This subsection describes them. + +4.9.1. Confidentiality + + The name mapping records in the NRS system must be assigned with + proper access rights such that the information contained in the name + mapping records would not be revealed to unauthorized users. + + The NRS system may support access control for certain name mapping + records. Access control can be implemented with a reference monitor + that uses client authentication, so only users with appropriate + credentials can access these records, and they are not shared with + unauthorized users. Access control can also be implemented by + encryption-based techniques using control of keys to control the + propagations of the mappings. + + The NRS system may support obfuscation and/or encryption mechanisms + so that the content of a resolution request may not be accessible by + third parties outside of the NRS system. + + The NRS system must keep confidentiality to prevent sensitive name + mapping records from being reached by unauthorized data requesters. + This is more required in IoT environments where a lot of sensitive + data is produced. + + The NRS system must also keep confidentiality of metadata as well as + NRS usage to protect the privacy of the users. For instance, a + specific user's NRS requests should not be shared outside the NRS + system (with the exception of legal intercept). + +4.9.2. Authentication + + * NRS server authentication: Authentication of the new NRS servers/ + nodes that want to be registered with the NRS system must be + required so that only authenticated entities can store and update + name mapping records. The NRS system should detect an attacker + attempting to act as a fake NRS server to cause service disruption + or manipulate name mapping records. + + * Producer authentication: The NRS system must support + authentication of the content producers to ensure that + update/addition/removal of name mapping records requested by + content producers are actually valid and that content producers + are authorized to modify (or revoke) these records or add new + records. + + * Mapping record authentication: The NRS should verify new mapping + records that are being registered so that it cannot be polluted + with falsified information or invalid records. + +4.9.3. Integrity + + The NRS system must be protected from malicious users attempting to + hijack or corrupt the name mapping records. + +4.9.4. Resiliency and Availability + + The NRS system should be resilient against denial-of-service attacks + and other common attacks to isolate the impact of the attacks and + prevent collateral damage to the entire system. Therefore, if a part + of the NRS system fails, the failure should only affect a local + domain. And fast recovery mechanisms need to be in place to bring + the service back to normal. + +5. Conclusion + + ICN routing may comprise three steps: name resolution, content + request routing, and content delivery. This document investigates + the name resolution step, which is the first and most important to be + achieved for ICN routing to be successful. A Name Resolution Service + (NRS) in ICN is defined as the service that provides such a function + of name resolution for translating an object name into some other + information such as a locator, another name, metadata, next-hop info, + etc. that is used for forwarding the object request. + + This document classifies and analyzes the NRS approaches according to + whether the name resolution step is separated from the content + request routing as an explicit process or not. This document also + explains the NRS functions used to support heterogeneous name types, + producer mobility, scalable routing system, off-path caching, + nameless object, manifest, and metadata. Finally, this document + presents design considerations for NRS in ICN, which include + resolution response time and accuracy, resolution guarantee, + resolution fairness, scalability, manageability, deployed system, and + fault tolerance. + +6. IANA Considerations + + This document has no IANA actions. + +7. Security Considerations + + A discussion of security guidelines is provided in Section 4.9. + +8. References + +8.1. Normative References + + [RFC7927] Kutscher, D., Ed., Eum, S., Pentikousis, K., Psaras, I., + Corujo, D., Saucez, D., Schmidt, T., and M. Waehlisch, + "Information-Centric Networking (ICN) Research + Challenges", RFC 7927, DOI 10.17487/RFC7927, July 2016, + . + +8.2. Informative References + + [Afanasyev] + Afanasyev, A. et al., "SNAMP: Secure Namespace Mapping to + Scale NDN Forwarding", 2015 IEEE Conference on Computer + Communications Workshops, + DOI 10.1109/INFCOMW.2015.7179398, April 2015, + . + + [Ahlgren] Ahlgren, B., Dannewitz, C., Imbrenda, C., Kutscher, D., + and B. Ohlman, "A Survey of Information-Centric + Networking", IEEE Communications Magazine, Vol. 50, Issue + 7, DOI 10.1109/MCOM.2012.6231276, July 2012, + . + + [Amadeo] Amadeo, M., Campolo, C., Iera, A., and A. Molinaro, "Named + data networking for IoT: An architectural perspective", + European Conference on Networks and Communications + (EuCNC), DOI 10.1109/EuCNC.2014.6882665, June 2014, + . + + [Amadeo2] Amadeo, M. et al., "Information-centric networking for the + internet of things: challenges and opportunities", IEEE + Network, Vol. 30, No. 2, DOI 10.1109/MNET.2016.7437030, + March 2016, . + + [Baccelli] Baccelli, E., Mehlis, C., Hahm, O., Schmidt, T., and M. + Wählisch, "Information Centric Networking in the IoT: + Experiments with NDN in the Wild", ACM-ICN 2014, + DOI 10.1145/2660129.2660144, 2014, + . + + [Bari] Bari, M.F., Chowdhury, S.R., Ahmed, R., Boutaba, R., and + B. Mathieu, "A Survey of Naming and Routing in + Information-Centric Networks", IEEE Communications + Magazine, Vol. 50, No. 12, pp. 44-53, + DOI 10.1109/MCOM.2012.6384450, December 2012, + . + + [Bayhan] Bayhan, S. et al., "On Content Indexing for Off-Path + Caching in Information-Centric Networks", ACM-ICN 2016, + DOI 10.1145/2984356.2984372, September 2016, + . + + [CCNx] "CICN", . + + [Dannewitz] + Dannewitz, C. et al., "Network of Information (NetInf) - + An information-centric networking architecture", Computer + Communications, Vol. 36, Issue 7, + DOI 10.1016/j.comcom.2013.01.009, April 2013, + . + + [FLIC] Tschudin, C., Wood, C. A., Mosko, M., and D. Oran, "File- + Like ICN Collections (FLIC)", Work in Progress, Internet- + Draft, draft-irtf-icnrg-flic-03, 7 November 2021, + . + + [ID.Zhang2] + Ravindran, R., Zhang, Y., Grieco, L. A., Lindgren, A., + Burke, J., Ahlgren, B., and A. Azgin, "Design + Considerations for Applying ICN to IoT", Work in Progress, + Internet-Draft, draft-irtf-icnrg-icniot-03, 2 May 2019, + . + + [Jung] Jung, H. et al., "IDNet: Beyond All-IP Network", ETRI + Journal, Vol. 37, Issue 5, DOI 10.4218/etrij.15.2415.0045, + October 2015, + . + + [Koponen] Koponen, T., Chawla, M., Chun, B., Ermolinskiy, A., Kim, + K.H., Shenker, S., and I. Stoica, "A Data-Oriented (and + Beyond) Network Architecture", ACM SIGCOMM 2007, pp. + 181-192, DOI 10.1145/1282380.1282402, August 2007, + . + + [MF] "MobilityFirst Future Internet Architecture Project + Overview", . + + [Mosko2] Mosko, M., "Nameless Objects", IRTF ICNRG, January 2016, + . + + [NDN] "Named Data Networking", . + + [NEO] Eriksson, A. and A.M. Malik, "A DNS-based information- + centric network architecture open to multiple protocols + for transfer of data objects", 21st Conference on + Innovation in Clouds, Internet and Networks and Workshops + (ICIN), pp. 1-8, DOI 10.1109/ICIN.2018.8401595, February + 2018, . + + [NRSarch] Hong, J., You, T., and V. Kafle, "Architectural + Considerations of ICN using Name Resolution Service", Work + in Progress, Internet-Draft, draft-irtf-icnrg-nrsarch- + considerations-06, 12 February 2021, + . + + [PURSUIT] "FP7 PURSUIT", . + + [Quevedo] Quevedo, J., Corujo, D., and R. Aguiar, "A case for ICN + usage in IoT environments", IEEE GLOBECOM, + DOI GLOCOM.2014.7037227, December 2014, + . + + [Ravindran] + Ravindran, R., Chakraborti, A., and A. Azgin, "Forwarding + Label support in CCN Protocol", Work in Progress, + Internet-Draft, draft-ravi-icnrg-ccn-forwarding-label-02, + 5 March 2018, . + + [RFC6920] Farrell, S., Kutscher, D., Dannewitz, C., Ohlman, B., + Keranen, A., and P. Hallam-Baker, "Naming Things with + Hashes", RFC 6920, DOI 10.17487/RFC6920, April 2013, + . + + [RFC8569] Mosko, M., Solis, I., and C. Wood, "Content-Centric + Networking (CCNx) Semantics", RFC 8569, + DOI 10.17487/RFC8569, July 2019, + . + + [RFC9064] Oran, D., "Considerations in the Development of a QoS + Architecture for CCNx-Like Information-Centric Networking + Protocols", RFC 9064, DOI 10.17487/RFC9064, June 2021, + . + + [SA2-5GLAN] + 3GPP, "New WID: 5GS Enhanced support of Vertical and LAN + Services", TSG SA Meeting #SP-82, December 2018, + . + + [SAIL] "Scalable and Adaptive Internet Solutions (SAIL)", + . + + [Westphal] Westphal, C. and E. Demirors, "An IP-Based Manifest + Architecture for ICN", ACM-ICN 2015, + DOI 10.1145/2810156.2812614, September 2015, + . + + [Xylomenos] + Xylomenos, G., Ververidis, C., Siris, V., Fotiou, N., + Tsilopoulos, C., Vasilakos, X., Katsaros, K., and G. + Polyzos, "A Survey of Information-Centric Networking + Research", IEEE Communications Surveys and Tutorials, Vol. + 16, Issue 2, DOI 10.1109/SURV.2013.070813.00063, 2014, + . + + [Zhang2] Zhang, Y. et al., "A Survey of Mobility Support in Named + Data Networking", IEEE Conference on Computer + Communications Workshops, + DOI 10.1109/INFCOMW.2016.7562050, April 2016, + . + +Acknowledgements + + The authors would like to thank Dave Oran, Dirk Kutscher, Ved Kafle, + Vincent Roca, Marie-Jose Montpetit, Stephen Farrell, Mirja Kühlewind, + and Colin Perkins for very useful reviews, comments, and improvements + to the document. + +Authors' Addresses + + Jungha Hong + ETRI + Yuseung-Gu + 218 Gajeong-ro + Daejeon + 34129 + Republic of Korea + + Email: jhong@etri.re.kr + + + Tae-Wan You + ETRI + Yuseung-Gu + 218 Gajeong-ro + Daejeon + 34129 + Republic of Korea + + Email: twyou@etri.re.kr + + + Lijun Dong + Futurewei Technologies Inc. + 10180 Telesis Court + San Diego, CA 92121 + United States of America + + Email: lijun.dong@futurewei.com + + + Cedric Westphal + Futurewei Technologies Inc. + 2330 Central Expressway + Santa Clara, CA 95050 + United States of America + + Email: cedric.westphal@futurewei.com + + + Börje Ohlman + Ericsson Research + SE-16480 Stockholm + Sweden + + Email: Borje.Ohlman@ericsson.com -- cgit v1.2.3