CoRE C. Amsüss
Internet-Draft
Intended status: Standards Track M. S. Lenders
Expires: 25 April 2025 TU Dresden
22 October 2024
CoAP Transport Indication
draft-ietf-core-transport-indication-07
Abstract
The Constrained Application Protocol (CoAP, [RFC7252]) is available
over different transports (UDP, DTLS, TCP, TLS, WebSockets), but
lacks a way to unify these addresses. This document provides
terminology and provisions based on Web Linking [RFC8288] and Service
Bindings (SVCB, [RFC9460]) to express alternative transports
available to a device, and to optimize exchanges using these.
About This Document
This note is to be removed before publishing as an RFC.
The latest revision of this draft can be found at https://core-
wg.github.io/transport-indication/. Status information for this
document may be found at https://datatracker.ietf.org/doc/draft-ietf-
core-transport-indication/.
Discussion of this document takes place on the core Working Group
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Source for this draft and an issue tracker can be found at
https://github.com/core-wg/transport-indication.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1. Terminology . . . . . . . . . . . . . . . . . . . . . . . 4
1.2. Goals . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.3. Core principle: Transport endpoints are proxies . . . . . 5
1.4. Concepts . . . . . . . . . . . . . . . . . . . . . . . . 5
1.4.1. Using URIs to identify transport endpoints . . . . . 6
2. Finding suitable endpoints for a URI . . . . . . . . . . . . 6
2.1. Processing scheme and authority . . . . . . . . . . . . . 7
2.1.1. Transport-unaware resolution . . . . . . . . . . . . 7
2.1.2. Transport-aware resolution mechanisms . . . . . . . . 8
2.2. Explicit proxy indication . . . . . . . . . . . . . . . . 8
2.2.1. Example . . . . . . . . . . . . . . . . . . . . . . . 8
3. Operational concerns of discovered transport endpoints . . . 9
3.1. Security context propagation . . . . . . . . . . . . . . 9
3.2. Choice of endpoints . . . . . . . . . . . . . . . . . . . 10
3.3. Selection of a canonical origin . . . . . . . . . . . . . 10
3.3.1. Unreachable canonical origin addresses . . . . . . . 11
3.4. Advertisement through a Resource Directory . . . . . . . 11
4. Elision of Proxy-Scheme and Uri-Host . . . . . . . . . . . . 12
4.1. Impact on caches . . . . . . . . . . . . . . . . . . . . 14
4.2. Using unique proxies securely . . . . . . . . . . . . . . 14
4.3. Self-description as a unique proxy . . . . . . . . . . . 14
5. Third party proxy services . . . . . . . . . . . . . . . . . 15
5.1. Generic proxy advertisements . . . . . . . . . . . . . . 16
6. Client picked proxies . . . . . . . . . . . . . . . . . . . . 17
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7. Service Binding Parameters for CoAP transports . . . . . . . 18
7.1. Discovering transport indication details from name
resolution . . . . . . . . . . . . . . . . . . . . . . . 18
7.2. Service Parameters . . . . . . . . . . . . . . . . . . . 20
7.2.1. Examples of using name resolution discovery and
parameters . . . . . . . . . . . . . . . . . . . . . 22
7.3. Producing request for a discovered service . . . . . . . 23
7.4. Expressing Service Parameters as literals . . . . . . . . 25
8. Guidance to upcoming transports . . . . . . . . . . . . . . . 25
9. Security considerations . . . . . . . . . . . . . . . . . . . 26
9.1. Security context propagation . . . . . . . . . . . . . . 26
9.2. Traffic misdirection . . . . . . . . . . . . . . . . . . 26
9.3. Protecting the proxy . . . . . . . . . . . . . . . . . . 27
10. IANA considerations . . . . . . . . . . . . . . . . . . . . . 28
10.1. Link Relation Types . . . . . . . . . . . . . . . . . . 28
10.2. Resource Types . . . . . . . . . . . . . . . . . . . . . 28
10.3. Service Parameter Key (SvcParamKey) . . . . . . . . . . 28
10.4. Underscored and Globally Scoped DNS Node Names . . . . . 29
11. References . . . . . . . . . . . . . . . . . . . . . . . . . 29
11.1. Normative References . . . . . . . . . . . . . . . . . . 29
11.2. Informative References . . . . . . . . . . . . . . . . . 30
Appendix A. Change log . . . . . . . . . . . . . . . . . . . . . 35
Appendix B. Related work and applicability to related fields . . 40
B.1. On HTTP . . . . . . . . . . . . . . . . . . . . . . . . . 40
B.2. Using DNS . . . . . . . . . . . . . . . . . . . . . . . . 40
B.3. Using names outside regular DNS . . . . . . . . . . . . . 40
B.4. Multipath TCP . . . . . . . . . . . . . . . . . . . . . . 41
Appendix C. Open Questions / further ideas . . . . . . . . . . . 42
Appendix D. EDHOC EAD for verifying legitimate proxies . . . . . 43
Appendix E. Literals beyond IP addresses . . . . . . . . . . . . 43
E.1. Motivation for new literal-ish names . . . . . . . . . . 44
E.2. Structure of service.arpa . . . . . . . . . . . . . . . . 44
E.3. Syntax of service.arpa . . . . . . . . . . . . . . . . . 46
E.4. Processing service.arpa . . . . . . . . . . . . . . . . . 46
E.5. Examples . . . . . . . . . . . . . . . . . . . . . . . . 46
Appendix F. Acknowledgements . . . . . . . . . . . . . . . . . . 47
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 47
1. Introduction
The Constrained Application Protocol (CoAP) provides multiple
transports mechanisms: UDP and DTLS since [RFC7252], and TCP, TLS and
WebSockets since [RFC8323]. Some additional transports being used in
LwM2M [lwm2m], and even more being explored
([I-D.bormann-t2trg-slipmux], [I-D.amsuess-core-coap-over-gatt].
These are mutually incompatible on the wire, but CoAP implementations
commonly support several of them, and proxies can translate between
them.
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CoAP currently lacks a way to indicate which transports are available
for a given resource, and which endpoints are available for them.
This document introduces ways to discover and how to use them.
CoAP also lacks a unified scheme to label a resource in a transport-
independent way. This document does _not_ attempt to introduce any
new scheme here, or raise a scheme to be the canonical one. Instead,
each host or application can pick a canonical address for its
resources, and advertise other transports in addition.
1.1. Terminology
Readers are expected to be familiar with the terms and concepts
described in CoAP [RFC7252] and link format [RFC6690] (or,
equivalently, web links as described in [RFC8288]).
The phrase "the transport indicated by (a URI)" is used as described
in Section 1.4.1.
A protocol that implements CoAP request-response semantics for a
lower layer is called a "(CoAP) transport".
When the term "endpoint" is used in this document, it is generalized
from the [RFC7252] definition to mean the transport and any
multiplexing information particular to that transport.
1.2. Goals
This document introduces provisions for the seamless use of different
transport mechanisms for CoAP. Combined, these provide:
1. Enablement: Inform clients of the availability of other
transports of servers.
2. No Aliasing: Any URI aliasing must be opt-in by the server. Any
defined mechanisms must allow applications to keep working on the
canonical URIs given by the server.
3. Optimization: Do not incur per-request overhead from switching
transports. This may depend on the server's willingness to
create aliased URIs.
4. Proxy usability: All information provided must be usable by aware
proxies to reduce the need for duplicate cache entries.
5. Proxy announcement: Allow third parties to announce that they
provide alternative transports to a host.
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For all these functions, security policies must be described that
allow the client to use them as securely as the original transport.
This document will not concern itself with changes in transport
availability over time, neither in causing them ("Please take up your
TCP interface, I'm going to send a firmware update") nor in
advertising their availability in advance. Hosts whose transport's
availability changes over time can utilize any suitable mechanism to
keep client updated, such as placing a suitable Max-Age value on
their resources or having them observable.
1.3. Core principle: Transport endpoints are proxies
CoAP does not need any special provisions to send the same request
for a single resource through different transports: A request to any
globally addressable resource can be sent to any endpoint by phrasing
it as a proxy request.
Whether that endpoint is trusted to, capable to and willing to relay
that request, and how to find suitable endpoints to serve as a proxy
for a request is discussed in this document.
When resource identifiers have different meanings depending on the
host. the applicability of this document is limited.
// Possibly not limited a lot, but we have not looked into those
// cases in detail yet. --CA Examples of such resources are those
whose URIs including loopback addresses or partially-qualified domain
names.
1.4. Concepts
Same-host proxy: A CoAP server that accepts forward proxy requests
(i.e., requests carrying the Proxy-Scheme option) exclusively for
URIs that it is also the authoritative server for is defined as a
"same-host proxy".
The distinction between a same-host and any other proxy is only
relevant on a practical, server-implementation and illustrative
level; this specification does not use the distinction in
normative requirements, and clients need not make the distinction
at all.
When talking of proxy requests, this document only talks of the
Proxy-Scheme option. Given that all URIs this is usable with can be
expressed in decomposed CoAP URIs, the need for using the Proxy-URI
option should never arise. The Proxy-URI option is still equivalent
to the decomposed options, and can be used if the server supports it.
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1.4.1. Using URIs to identify transport endpoints
The URI coap://[2001:db8::1] identifies a particular resource,
possibly a "welcome" text. It is, colloquially, also used to
identify the combination of a CoAP transport and the transport
specific details.
For precision, this document uses the term "the transport address
indicated by (a URI)" to refer to the transport and its details (in
the example, CoAP over UDP with an IPv6 address and the default
port), but otherwise no big deal is made of it.
The transport indicated by a URI is not only influenced by the URI
scheme, but also by the authority component. The transports and
resolution mechanisms currently specified make little use of this
possibility, mainly because the most prominent resolution mechanism
(SVCB records) has not been available when [RFC8323] was published
and because it can not be expressed in IP literals. The provisions
of this document enable this opportunistically for registered names
(Section 7.1) and for literals using the mechanism in Appendix E.
When the resolution mechanism used for a registered name authority
component yields multiple addresses, all of those are possible ways
to interact with the resource. The resolution mechanism or other
underlying transport can give guidance on how to find the best usable
one. With the currently specified transports and resolution
mechanisms, the most prominent example of making use of that
information is applying the Happy Eyeballs mechanism [RFC8305] to
establish a TCP connection when a name resolves to both IPv4 and IPv6
addresses,
[ TBD: Do we want to extend this to HTTP proxies? Probably just not,
and if so, only to those that can just take coap://... for a URI. ]
2. Finding suitable endpoints for a URI
When a CoAP request is created, a typical starting point is the URI
of the request's target resource. To send the request, a suitable
endpoint needs to be discovered. This section lists the ways one or
more such endpoints can be found.
In some situations, a client decides to use a forward proxy to access
the resource. In that case, it relays all the URI components to the
proxy, which then decides on an endpoint to which to forward the
request using the tools described in this section. Section 6
describes this in more detail.
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The endpoint (and thus transport) used to access a resource does not
alter the resource's URI. If the URI scheme associated with the
selected transport differs from the request URI's scheme, a different
host name is encountered as part of the resolution process (e.g. due
to a DNS CNAME or an explicit SVCB target name) or a different port
is used (as possible through SVCB), the Proxy-Scheme, Uri-Host and
Uri-Port options are set as needed to ensure that the request keeps
targetting the requested resource. For servers that follow the
common pattern of exposing the same resources on all transports (and
thus having multiple aliased URIs for the same resource) and that do
not act as proxies for other systems, the presence of the Proxy-
Scheme option has little practical consequence: such servers become
same-host proxies, and can ignore the Proxy-Scheme option as long as
they recognize the Uri-Host value (which they already have been
required to process).
While a server is at liberty to create aliases, clients can not infer
from the presence of a transport for a host that URIs created from
addressing that transport are present. For example, if
coap://h.example.net/sensors/temp is a known resource, and CoAP-over-
TCP on [2001:db8::1] is indicated as a transport endpoint, there is
no reason for the client to assume that
coap+tcp://[2001:db8::1]/sensors/temp exists, let alone is the same
resource: Clients that access the known resource by establishing a
TCP connection need to send the options Proxy-Scheme value "coap",
the Uri-Host value "h.example.net" and the Uri-Path values "sensors"
and "temp".
2.1. Processing scheme and authority
To discover endpoints for a given URI, the scheme and the authority
component of the URI are typical starting points.
2.1.1. Transport-unaware resolution
The IP based transports specified so far (CoAP over UDP, DTLS, TCP,
TLS and WebSockets) all indicate the transport in their scheme, and
have a default port. The only remaining details of multiplexing
information required are the IP version(s) and IP address(es) of the
server.
If the host component of the URI is a literal, that information is
already available.
If the host component of the URI is a registered name, a name
resolution service is used for a simple name lookup: When DNS is used
as a resolution service, AAAA (or A) records of the name are looked
up.
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Beyond the IP address, the resolution service may provide some
additional information, such as the zone identifier (implied in DNS
by using the zone the DNS response was obtained through) or TLSA
records (which can guide the (D)TLS certificate validation process
but are out of scope for this document).
Simple resolution services do not indicate which transports are
available on the address. Servers reached that way can resort to
Section 2.2 to indicate alternative transports while exchanging
initial data through the original transport, or to store information
in link format / web-link based information systems (such as a
Resource Directory [RFC9176]).
2.1.2. Transport-aware resolution mechanisms
Advanced resolution services provide information about which
transports are available.
For the DNS resolution mechanism, SVCB lookups described in
Section 7.1 provide that information.
It is recommended that future transports are designed to utilize
transport-aware resolution mechanisms; see Section 8 for details.
2.2. Explicit proxy indication
A server can advertise a recommended proxy by publishing a Web Link
with the "has-proxy" relation, defined in this document, to a URI
indicating its transport address. In particular (and that is a
typical case), it can indicate its own network address on an
alternative transport when implementing same-host proxy
functionality.
The semantics of a link from S to P with relations has-proxy ("S has-
proxy P",
;rel=has-proxy;anchor="S") are that for any resource
that has the same origin as S, the transport address indicated by P
can be used to obtain that resource.
2.2.1. Example
A constrained device at the address 2001:db8::1 that supports CoAP
over TCP in addition to CoAP can self-describe like this:
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Req: to [ff02::fd]:5683 on UDP
Code: GET
Uri-Path: /.well-known/core
Uri-Query: if=tag:example.com,sensor
Res: from [2001:db8::1]:5683
Content-Format: application/link-format
Payload:
;if="tag:example.com,sensor",
;rel=has-proxy;anchor="/"
Req: to [2001:db8::1]:5683 on TCP
Code: GET
Proxy-Scheme: coap
Uri-Path: /sensors/temp
Observe: 0
Res: 2.05 Content
Observe: 0
Payload:
39.1°C
Figure 1: Discovery and follow-up request through a has-proxy
relation
The discovery process yields two links: The first describes the
resource, the second describes that an additional (TCP) endpoint is
available for all resources on this host.
Note that generating this discovery file needs to be dynamic based on
its available addresses; only if queried using a link-local source
address, the server may also respond with a link-local address in the
authority component of the proxy URI.
3. Operational concerns of discovered transport endpoints
3.1. Security context propagation
Any security requirements posed by a server or client application on
a CoAP request MUST be applied independently of the transport that is
used to perform the request. If a transport can not be used to
satisfy the requirements, it is ineligible for use with the request
(from a client's point of view), and unauthorized (from a server's
point of view).
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If the requirements contain transport layer security, the proxy needs
to present the credentials required of the server to the client, and
those of the client to the server; this is only practical when the
proxy is a same-host proxy.
Some applications have requirements exceeding the requirements of a
secure connection, e.g., (explicitly or implicitly) requiring that
name resolution happen through a secure process and packets are only
routed into networks where it trusts that they will not be
intercepted on the path to the server. Such applications need to
extend their requirements to the the sources used to obtain the
endpoints (i.e., the source of any has-proxy statement or the SVCB
data); a sufficient (but maybe needlessly strict) requirement for
has-proxy statements is to only follow those that are part of the
same resource that advertises the link currently being followed.
Section Section 9.2 adds further considerations.
3.2. Choice of endpoints
It is up to the client whether to use an advertised endpoint, or (if
multiple are provided) which to pick.
Information about endpoints may be annotated with additional metadata
that may help guide such a choice; defining such metadata is out of
scope for this document.
Clients MAY switch between endpoints as long as the source describing
them is fresh; they may even do so per request. (For example, they
may perform individual requests using CoAP-over-UDP, but choose CoAP-
over-TCP for requests with large expected responses). When the
information about endpoints is obtained through CoAP (eg. as a has-
proxy link), the client can use the describing representation's ETag
to efficiently renew its justification for using the alternative
transport.
3.3. Selection of a canonical origin
While a server is at liberty to provide the same resource
independently on different transports (i.e. to create aliases), it
may make sense for it to pick a single scheme and authority under
which it announces its resources. Using only one address helps
proxies keep their caches efficient, and makes it easier for clients
to avoid exploring the same server twice from different angles.
When there is a predominant scheme and authority through which an
existing service is discovered, it makes sense to use these for the
canonical addresses.
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Otherwise, it is suggested to use the coap or coaps scheme (given
that these are the most basic and widespread ones), and the most
stable usable name the host has.
3.3.1. Unreachable canonical origin addresses
For devices that are not generally reachable at a stable address, it
may make sense to use a scheme and authority as the canonical address
that can not actually be dereferenced.
The registered names available for that purpose depend on the
resolution mechanisms in use. When the Domain Name System (DNS) is
used, such names would not be associated with any A or AAAA records
(but may still use, for example, TLSA records).
Such URIs are _only_ usable to clients that discover a suitable proxy
along with the URI, and which can place sufficient trust in that
proxy.
3.4. Advertisement through a Resource Directory
In the Resource Directory specification [rfc9176], protocol
negotiation was anticipated to use multiple base values. This
approach was abandoned since then, as it would incur heavy URI
aliasing.
Instead, devices can submit their has-proxy links to the Resource
Directory like all their other metadata.
A client performing resource lookup can ask the RD to provide
available (same-host-)proxies in a follow-up request by asking for
?anchor=&rel=has-proxy. The RD may also
volunteer that information during resource lookups even though the
has-proxy link itself does not match the search criteria.
[
It may be useful to define RD parameters for use with lookup here,
which'd guide which available proxies to include. For example,
asking ?if=tag:example.com,sensor&proxy-links=tcp could give as a
result:
;rt=tag:example.com,sensor,;rel=has-proxy;anchor="coap://[2001:db8::1]/"
This is similar to the extension suggested in Section 5 of
[I-D.amsuess-core-resource-directory-extensions].
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]
4. Elision of Proxy-Scheme and Uri-Host
A CoAP server may publish and accept multiple URIs for the same
resource, for example when it accepts requests on different IP
addresses that do not carry a Uri-Host option, or when it accepts
requests both with and without the Uri-Host option carrying a
registered name. Likewise, the server may serve the same resources
on different transports. This makes for efficient requests (with no
Proxy-Scheme or Uri-Host option), but in general is discouraged
[aliases].
To make efficient requests possible without creating URI aliases that
propagate, the "has-unique-proxy" specialization of the has-proxy
relation and the "is-unique-proxy" SVCB parameter are defined.
If a proxy is unique, it means that requests arriving at the proxy
are treated the same no matter whether the scheme, authority and port
of the link context are set in the Proxy-Scheme, Uri-Host and Uri-
Port options, respectively, or whether all of them are absent.
[ The following two paragraphs are both true but follow different
approaches to explaining the observable and implementable behavior;
it may later be decided to focus on one or the other in this
document. ]
While this creates URI aliasing in the requests as they are sent over
the network, applications that discover a proxy this way should not
"think" in terms of these URIs, but retain the originally discovered
URIs (which, because Cool URIs Don't Change[cooluris], should be
long-term usable). They use the proxy for as long as they have fresh
knowledge of the has-(unique-)proxy statement.
In a way, advertising has-unique-proxy can be viewed as a description
of the link target in terms of SCHC
[I-D.ietf-lpwan-coap-static-context-hc]: In requests to that target,
the link source's scheme and host are implicitly present.
While applications retain knowledge of the originally requested URI
(even if it is not expressed in full on the wire), the original URI
is not accessible to caches both within the host and on the network
(for the latter, see Section 6). Thus, cached responses to the
canonical and any aliased URI are mutually interchangeable as long as
both the response and the proxy statement are fresh.
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A client MAY use a unique-proxy like a proxy and still send the
Proxy-Scheme and Uri-Host option; such a client needs to recognize
both relation types, as relations of the has-unique-proxy type are a
specialization of has-proxy and typically don't carry the latter
(redundant) annotation. [ To be evaluated -- on one hand, supporting
it this way means that the server needs to identify all of its
addresses and reject others. Then again, is a server that (like many
now do) fully ignore any set Uri-Host correct at all? ]
Example:
Req: to [ff02::fd]:5683 on UDP
Code: GET
Uri-Path: /.well-known/core
Uri-Query: if=tag:example.com,sensor
Res: from [2001:db8::1]:5683
Content-Format: application/link-format
Payload:
;if="tag:example.com,collection",
;rel=has-unique-proxy;anchor="/"
Req: to [2001:db8::1] via WebSockets over HTTPS
Code: GET
Uri-Path: /sensors/
Res: 2.05 Content
Content-Format: application/link-format
Payload:
;if="tag:example.com,sensor"
Figure 2: Follow-up request through a has-unique-proxy relation.
Compared to the last example, 5 bytes of scheme indication are
saved during the follow-up request.
It is noteworthy that when the URI reference /sensors/temperature is
resolved, the base URI is coap://device0815.example.com and not its
coaps+ws counterpart -- as the request is still for that URI, which
both the client and the server are aware of. However, this detail is
of little practical importance: A simplistic client that uses
coaps+ws://device0815.proxy.rd.example.com as a base URI will still
arrive at an identical follow-up request with no ill effect, as long
as it only uses the wrongly assembled URI for dereferencing
resources, the security context is the same, the state is kept no
longer than the has-unique-proxy statement is fresh, and it does not
(for example) pass the URI on to other devices.
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4.1. Impact on caches
[ This section is written with the "there is implied URI aliasing"
mindset; it should be possible to write it with the "compression"
mindset as well (but there is no point in having both around in the
document at this time).
It is also slightly duplicating, but also more detailed than, the
brief note on the topic in Section 6 ]
When a node that performs caching learns of a has-unique-proxy
statement, it can utilize the information about the implied URI
aliasing: As long as the has-unique-proxy statement is fresh and
trusted, requests for either of the origins can be served from the
cache of the other origin.
4.2. Using unique proxies securely
The elision of the host name afforded by the unique-proxy relation is
only possible if the required security mechanisms verify the scheme
and host of the server.
This is given for OSCORE based mechanisms, where "unprotected message
fields (including Uri-Host [...]) MUST not lead to an OSCORE message
becoming verified".
With TLS based security mechanisms, name and scheme can not be
completely elided in general. While the use of the SNI HostName
field sets the default Uri-Host already, the scheme still needs to be
sent in a Proxy-Scheme option to satisfy the requirement of
Section 3.1.
[ It may be possible to relax this requirement if the host publishes
a _trustworthy_ statement about serving the same content on all
schemes; however, no urgent need for this optimization is currently
known that warrants the extra scrutiny. ]
4.3. Self-description as a unique proxy
The level of assurance a client needs from a server to elide the Uri-
Host option in a request that was created from a URI with no IP
address literal has been a controversial topic. [ Should we dig up
old conversations, link to https://github.com/core-wg/wiki/wiki/CoAP-
FAQ#q4, or just let the weight of a WG consensus-document-to-be do
its work? ]
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The has-unique-proxy relation provides an easy way for a server to
indicate that this is in fact allowed: A server can publish a
statement such as >;rel=has-unique-proxy in its /.well-known/core
file. A client that receives and understands it can thus elide the
Uri-Host option in requests to the server as per the definition of
the relation.
5. Third party proxy services
A server that is aware of a suitable cross proxy may use the has-
proxy relation to advertise that proxy. If the transport used
towards the proxy provides name indication (as CoAP over TLS or
WebSockets does), or by using a large number of addresses or ports,
it can even advertise a (more efficient) has-unique-proxy relation.
This is particularly interesting when the advertisements are made
available across transports, for example in a Resource Directory.
How the server can discover and trust such a proxy is out of scope
for this document, but generally involves the same kind of links. In
particular, a server may obtain a link to a third party proxy from an
administrator as part of its configuration.
The proxy may advertise itself without the origin server's
involvement; in that case, the client needs to take additional care
(see Section 9.2).
Req: GET http://rd.example.com/rd-lookup?if=tag:example.com,sensor
Res:
Content-Format: application/link-format
Payload:
;if="tag:example.com,collection",
;rel=has-unique-proxy;anchor="coap://device0815.example.com/"
Req: to device0815.proxy.rd.example.com on WebSocket
Host (indicated during upgrade): device0815.proxy.rd.example.com
Code: GET
Uri-Path: /sensors/
Res: 2.05 Content
Content-Format: application/link-format
Payload:
;if="tag:example.com,sensor"
Figure 3: HTTP based discovery and CoAP-over-WS request to a CoAP
resource through a has-unique-proxy relation
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5.1. Generic proxy advertisements
A third party proxy may advertise its availability to act as a proxy
for arbitrary CoAP requests. This use is not directly related to the
transport indication in other parts of this document, but
sufficiently similar to warrant being described in the same document.
The resource type "CPA-core.proxy" can be used to describe such a
proxy.
Req: GET coap://[fe80::1]/.well-known/core?rt=CPA-core.proxy
Res:
Content-Format: application/link-format
Payload:
<>;rt=CPA-core.proxy
Req: to [fe80::1] via CoAP
Code: GET
Proxy-Scheme: http
Uri-Host: example.com
Uri-Path: /motd
Accept: text/plain
Res: 2.05 Content
Content-Format: text/plain
Payload:
On Monday, October 25th 2021, there is no special message of the day.
Figure 4: A CoAP client discovers that its border router can also
serve as a proxy, and uses that to access a resource on an HTTP
server.
The considerations of Section 9.2 apply here.
A generic advertised proxy is always a forward proxy, and can not be
advertised as a "unique" proxy as it would lack information about
where to forward.
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A proxy may be limited in the URIs it can service, for technical
reasons (e.g. when none of the URI's transports are supported by the
server) or for policy reasons (only accessing servers inside an
organizational structure). Future documents (or versions of this
document) may add target attributes that allow specifying the
capabilities of a proxy. [ An earlier version of this document
contained a proxy-schemes attribute. This was discontinued because
it could already not express whether a proxy could access IPv4 or
IPv6 peers, and because the use of schemes is becoming less useful
given the new recommendation of incorporating details from registered
name resolution into the transport selection. ]
The use of a generic proxy can be limited to a set of devices that
have permission to use it. Clients can be allowed by their network
address if they can be verified, or by using explicit client
authentication using the methods of
[I-D.tiloca-core-oscore-capable-proxies].
6. Client picked proxies
This section is purely informative, and serves to illustrate that the
mechanisms introduced in this document do not hinder the continued
use of existing proxies.
When a resource is accessed through an "actual" proxy (i.e., a host
between the client and the server, which itself may have a same-host
proxy in addition to that), the proxy's choice of the upstream server
is originally (i.e., without the mechanisms of this document) either
configured (as in a "chain" of proxies) or determined by the request
URI (where a proxy picks CoAP over TCP and resolves the given name
for a request aimed at a coap+tcp URI).
A proxy that has learned, by active solicitation of the information
or by consulting links in its cache, that the requested URI is
available through a (possibly same-host) proxy, may use that
information in choosing the upstream transport, to correct the URI
associated with a cached response, and to use responses obtained
through one transport to satisfy requests on another.
For example, if a host at coap://h1.example.com has advertised
,;rel=has-proxy;anchor="/", then a
proxy that has an active CoAP-over-TCP connection to h1.example.com
can forward an incoming request for coap://h1.example.com/res through
that CoAP-over-TCP connection with a suitable Proxy-Scheme and Uri-
Host on that connection.
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If the host had marked the proxy point as
;rel=has-unique-proxy instead, then the
proxy could elide the Proxy-Scheme and Uri-Host options, and would
(from the original CoAP caching rules) also be allowed to use any
fresh cache representation of coap+tcp://h1.example.com/res to
satisfy requests for coap://h1.example.com/res.
A client that uses a forward proxy and learns of a different proxy
advertised to access a particular resource will not change its
behavior if its original proxy is part of its configuration. If the
forward proxy was only used out of necessity (e.g., to access a
resource whose indicated transport not supported by the client) it
can be practical for the client to use the advertised proxy instead.
7. Service Binding Parameters for CoAP transports
Discovery mechanisms that exist in DNS [RFC9460], DHCP, Router
Advertisements [RFC9463] or other mechanisms can provide details
already that would otherwise only be discovered later through proxy
links. For when those details are provided in the shape of Service
Binding Parameters, this section describes their interpretation in
the context of CoAP transport indication.
[ The following paragraph is outdated, but its replacement will
depend on the outcome of IETF121 discussions. ]
The subsections in this section are arranged to describe a consistent
sequential full picture. The capabilities of this big picture are
not exercised by any application known at the time of draft
publication. It is instead backed by many small-scope use cases
(such as bootstrapping issues of proxy-link based CoAP scheme
unification, [I-D.lenders-core-dnr], [I-D.amsuess-t2trg-onion-coap]
and also applications outside CoAP such as [SUIB]) and presents a
unified solution framework.
7.1. Discovering transport indication details from name resolution
This document registers the _coap attrleaf label in Section 10.4
using the pattern described as described in Section 10.4.5 of
[RFC9460], and thus enables the use of SVCB records. This path is
chosen over the creation of a new SVCB RR "COAP" because it is
considered unlikely that DNS implementations would update their code
bases to apply SVCB behavior; this assumption will be revisited
before registration.
These can be used during the resolution of URIs that use any CoAP
scheme. The presence of an SVCB record for a registered name implies
that any transport advertised in the record is suitable for proxying
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to resources of any CoAP scheme and that registered name, provided
that a resource is available at that URI in the first place. This
does not create URI aliasing: Any resource is still accessed at its
original URI through the advertised proxy endpoints.
It is possible through this to advertise transports without transport
layer security for URIs with the schemes "coaps", "coaps+tcp" and
"coaps+ws". Unless the applications explicitly regards an object
layer security mechanism as a sufficient replacement for transport
layer security, those transports can not be selected for operations
on such URIs as per Section 3.1.
Some SVCB parameters have defaults; for "_coap", these are:
* port: 5683
* ALPN: empty
As SVCB records were not specified for the existing CoAP transports
originally, generic CoAP clients are not required to use the SVCB
lookup mechanism, but MAY attempt it opportunistically in order to
obtain a usable transport (or to obtain it faster). Applications
built on CoAP MAY require clients to perform this kind of discovery.
Adding such a requirement is particularly useful if the application
frequently advertises URIs with a scheme that defaults to a transport
which its clients may not support, or when the application makes use
of functionality afforded by [RFC9460] such as apex domain
redirection. (Had the SVCB specification predated the first new CoAP
transports, that mechanism might have been used in the first place
instead of additional schemes).
[ The following paragraph may need to be revisited depending on the
outcome of IETF121 discussions. ]
The effects on a client of seeing SVCB parameters are similar to
those of seeing a "has-proxy" link from the origin to the URI built
using {#svcblit}. They differ in that SVCB parameters describe the
server itself: Credentials expressed apply end to end (as opposed to
credentials that describe the proxy in a "has-proxy" link), and the
client could conclude that the implied proxy is a same-host proxy (if
that had any impact on the client, which it does not).
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7.2. Service Parameters
Several parameters are relevant in the context of CoAP, independently
of whether they are used with SVCB records or Service Binding
Parameters transported outside of SVCB records, and independently of
whether they apply to the _coap service or another service that can
be used on top of CoAP (such as _dns):
* port: The CoAP service using the transport described in this
parameter is reachable on this port (described in [RFC9460]).
* alpn: The ALPN "coap" has been defined for CoAP-over-TLS
[RFC8323], and "co" for CoAP-over-DTLS in
[I-D.ietf-core-coap-dtls-alpn].
If an ALPN service parameter is found, this indicates that the
ALPN(s) and thus the CoAP transport that can be used on this
address / port. For example, "co" indicates that DTLS (and thus
UDP) is used.
* coaptransport: This is a new parameter defined in this document,
and similar to the ALPN parameter.
If a coaptransport parameter is present, the indicated
transport(s) can be used on this address / port.
The names registered for existing transports are identical to the
URI schemes that indicate their use in the absence of Service
Binding Parameters.
[ It is left for review by SVCB experts whether these are a
separate parameter space or we should just take ALPNs for them,
like eg. h2c does. ]
* is-unique-proxy: This is a new parameter defined in this document,
and equivalent to the has-unique-proxy in its semantics.
Its value is empty.
* edhoc-cred: This is a new parameter defined in this document, and
describes that EDHOC can be used with the server, and which
credentials can authenticate the server.
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The edhoc-cred parameter's value is a CBOR sequence of COSE Header
maps as defined in [RFC9052]. If the parameter is present, it
indicates that EDHOC [RFC9528] can be used on the transport, and
that the server can be authenticated by any credential expressed
in the sequence. This is similar to the TLSA records specified in
[RFC6698].
A COSE Header map can express many properties, not all of which
are sufficient to authenticate a peer on any given security
mechanism. Without excluding applications that may process other
entries, a practical criterion for whether a header map is
suitable for EDHOC is that the header map could also be used in
EDHOC as ID_CRED_R if the credential is sent by value.
For example, a header map with a kccs entry can be used to
indicate a public key including a Key ID (kid), and that public
key does not need to be sent during the EDHOC exchange.
Alternatively, a header map with an x5t identifies the end entity
certificate the server presents by a thumbprint (hash).
It is up to the application to define requirements for the
provenance of the edhoc-cred parameter, whether it needs to be
provided through secure mechanism, or whether the server is
strictly required to present that credential.
This is unlike TLSA, which needs to be transported through DNSSEC,
because a edhoc-cred parameter may be sent using other means than
DNS (for example in DHCPv6 responses or Router Advertisements).
* edhoc-info: This is a new parameter defined in this document,
describing how EDHOC can be used on the server.
The value of the parameter is a CBOR map following the
EDHOC_Information structure defined in
[I-D.ietf-ace-edhoc-oscore-profile] and extended in
[I-D.tiloca-lake-app-profiles].
It is optional to provide and optional to process, but can help
speed up the establishment of a security context.
* oauth-hints: This is a new parameter defined in this document,
describing how ACE-OAuth [RFC9200] can be used with this service.
Its value is a CBOR map containing AS Request Creation Hints as
described in Section 5.3 of [RFC9200]. While an empty map can be
useful (hinting that the client should use its configured ACE-
OAuth setup), typical useful keys are 1 (AS, indicating the URI of
the Authorization Server), 5 (audience, indicating the name under
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which the service is known to the Authorization Server), and 9
(scope, when discovering a particular service rather than just
getting transport information for a host). That data is using the
same shape the server might use when responding to an attempt at
an unencrypted connection, and can not only speed up the discovery
of the right AS, but can also protect that information (eg. when
DNSSEC is used), and avoids the need for an unprotected first
request.
It is up to the application to define requirements for the use of
such data. For example, it may require that the audience matches
the requested host name, or may require that the scope matches the
kind of service being discovered.
When expressed in text format, e.g. in DNS zone files, the CBOR
diagnostic notation [I-D.ietf-cbor-edn-literals] can be used.
7.2.1. Examples of using name resolution discovery and parameters
7.2.1.1. Generic client discovering transport options
A generic client is directed to obtain coap://dev1.example.com/log
requests the name to be resolved using the system's resolution
mechanisms, resulting in a DNS query for these records:
_coap.dev1.example.com IN SVCB
dev1.example.com IN AAAA
The following records are returned:
_coap.dev1.example.com IN SVCB 1 . coaptransport=tcp,udp
_coap.dev1.example.com IN SVCB 1 . alpn=co,coap port=5684
_coap.dev1.example.com IN SVCB 1 . coaptransport=udp port=61616
dev1.example.com IN AAAA 2001:db8:1::1
Exceeding the single option it had with just the IP address, it may
now also choose to establish a TCP connection on the default port, to
use port 61616 for UDP (which results in more compact frames on a
6LoWPAN link), or to use either of the TLS based options.
7.2.1.2. Application mandating SVCB
An application's policy is to mandate client support for SVCB
records, and to require that a security mechanism must be used where
credentials are backed either by DNSSEC or by the Web PKI.
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A server operator is running in a legacy network that only provides
an IPv4 address behind NAT with a dynamic public address, but has PCP
[RFC7291] available. After running PCP to open a UDP port, it learns
that 1.2.3.4:5678 will be available for some time.
It therefore updates its DNS record like this:
_coap.host.example.net 600 IN SVCB 1 publicudp.host.example.net \
port=5678 \
edhoc-cred={14:{... /KCCS with its public key/}}
When a client starts using coap://host.example.net/interactive, it
looks up that record and verifies it using DNSSEC. It then proceeds
to send EDHOC requests over CoAP to 1.2.3.4 port 5678, setting the
Uri-Host option to "host.example.net".
The client could also have initiated an EDHOC session if no edhoc-
cred parameter had been present, but then, it would have required
that the server present some credential that could be verified
through the Web PKI, for example an x5chain containing a Let's
Encrypt certificate.
7.3. Producing request for a discovered service
If a service's discovery process does not produce a URI but an
address, host name and/or Service Binding Parameters, those can be
converted to a CoAP URI, for which transport hints are already
encoded in the parameters the URI is constructed from. An example of
this is DNS server discovery [I-D.ietf-core-coap-dtls-alpn].
While it is up to the service to define the service's semantics, this
section applies to any service whose use with CoAP is defined by a
normative referencing this section:
* The client tries the available services with their ALPNs and CoAP
transports according to its capabilities and the priorities and
mandatory parameters as defined for Service Bindings.
* The service either defines a well-known path, or it defines a
Service Binding Parameter that describes the service's path on the
described endpoint, or it defines both (and the well-known path is
the default in absence of the defined parameter).
The value is a CBOR sequence [RFC8742] of text strings, which
represent Uri-Path options in a CoAP request, or (equivalently)
the path of a CRI reference [I-D.ietf-core-href].
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A parameter value that is not a well-formed CBOR sequence, or any
item is not a text string, is considerd malformed.
When expressed in text format, e.g. in DNS zone files, the CBOR
diagnostic notation [I-D.ietf-cbor-edn-literals] can be used.
To access the service, a client sets the text string values of the
used Service Binding parameter as Uri-Path options in the request.
If the resource is unavailable, the client may continue with
options that have a larger SvcPriority value associated (if such a
property exists in the discovery method).
An example of such an option is docpath as defined in
[I-D.ietf-core-dns-over-coap]. (As that document precedes this
one, it repeats the same rules explicitly rather than reusing
these rules).
* A Service Binding is accompanied by a hostname: For example, this
is the hostname of the Encrypted DNS Resolver or the Special-Use
Domain Name in the case of [RFC9462] lookups, or the
authentication-domain-name in case of [RFC9463] DHCP options or
Router Advertisements.
Unless its value is identical to the default value for Uri-Host
(which is the case on transports with Server Name Indication
(SNI)), the that name is added in the Uri-Host option.
* If the port Service Binding Parameter is set, the Uri-Port option
is set to the port that set in the port prefix of the query (or
the used CoAP transport's default port), unless that is its
default value anyway.
* No Proxy-Scheme option is set.
By following the rules of Section 6.5 of [RFC7252] or the equivalent
rules for the respective CoAP transport, the service can be
translated into a URI. This implies URI aliasing between the
composed URIs of all transports if any of the transports use
different schemes.
The rules for setting Uri-Host and Uri-Port result in the authority
component of the URI being equal to the Binding Authority defined in
[RFC9461].
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Note that since different security policies may apply to service
discovery and other application components that dereference URIs, any
connections established while using the service and cache entries
created by it need to be treated carefully, for example by using
separate connection and cache pools.
7.4. Expressing Service Parameters as literals
A method for expressing Service Parameters in URIs that do not use
registered names is described in Appendix E.
Among other things, that mechanism allows encoding the full
information obtained during service discovery in a URI instead of
just the one choice taken. It is also required if different CoAP
transports are using the same scheme (as is recommended in Section 8)
with IP address literals in URIs, for which unlike for resolved names
no service parameters are available.
8. Guidance to upcoming transports
When new transports are defined for CoAP, it is recommended to use
the "coap" scheme (or "coaps" for TLS based transports).
If the transport's identifiers are IP based and have identifiers
typically resolved through DNS, authors of new transports are
encouraged to specify Service Binding records ([RFC9460]) for CoAP,
e.g., using an alpn or coaptransport parameter. and if IP literals
are relevant to the transport, to follow up on Appendix E.
If the transport's native identifiers are compatible with the
structure of the authority component of a URI, those identifiers can
be used as an authority as-is. To help the host decide the
resolution mechanism, it may be helpful to register a subdomain of
.arpa as described in [rfc3172]. The guidence for users is to never
attempt to resolve such a name, and for the zone's implementation is
to return NXDOMAIN unconditionally.
For the purpose of specifying a transport protocol via Service
Binding records, and to encourage future authors more, this document
specifies the coaptransport Service Parameter Key (SvcParamKey) with
the initial legal values "udp" and "tcp" which indicate either CoAP
over UDP and CoAP over TCP as the transport. The present of
transport security is indicated by the alpn SvcParamKey. If it the
alpn SvcParamKey is not provided, but coaptransport is, the transport
is unencrypted.
// Wondering if "udp" or "tcp" should be strings or numeric
// representations as value. The later would need an extra table or
// is there something we could reuse, e.g. from [I-D.ietf-core-href]?
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If the transport's native identifiers are incompatible with that
structure (e.g. because they contain colons), the document may define
some transformation.
If a transport's native identifiers are only local, the zone .alt
[rfc9476] may be used instead.
For example, CoAP over GATT [I-D.amsuess-core-coap-over-gatt] removes
the colons from Bluetooth Low Energy MAC addresses like
00:11:22:33:44:55 and combines them into authority compoennts such as
001122334455.ble.arpa. Slipmux [I-D.bormann-t2trg-slipmux] might use
the locally significant device name /dev/ttyUSB0 as
coap://ttyUSB0.dev.alt/.
URIs created from such names may not indicate the protocol uniquely:
Additional transports specified later may also provide CoAP services
for the same name. In the sense of Section 1.4.1, both transport
would be identified by that URI. That is not an issue as long as the
protocols underneath the CoAP transport provide a means of
advertising the precise protocol used. For example, a hypothetical
CoAP transport for BLE that is not GATT based can be selected for the
same scheme and authority based on data in the BLE advertisement.
9. Security considerations
9.1. Security context propagation
Clients need to strictly enforce the rules of Section 3.1. Failure
to do so, in particular using a thusly announced proxy based on a
certificate that attests the proxy's name, would allow attackers to
circumvent the client's security expectation.
When security is terminated at proxies (as is in DTLS and TLS), a
third party proxy can usually not satisfy this requirement; these
transports are limited to same-host proxies.
9.2. Traffic misdirection
Accepting arbitrary proxies, even with security context propagation
performed properly, would allow attackers to redirect traffic through
systems under their control. Not only does that impact availability,
it also allows an attacker to observe traffic patterns.
This affects both OSCORE and (D)TLS, as neither protect the
participants' network addresses.
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Other than the security context propagation rules, there are no hard
and general rules about when an advertised proxy is a suitable
candidate. Aspects for consideration are:
* When no direct connection is possible (e.g. because the resource
to be accessed is served as coap+tcp and TCP is not implemented in
the client, or because the resource's host is available on IPv6
while the client has no default IPv6 route), using a proxy is
necessary if complete service disruption is to be avoided.
While an adversary can cause such a situation (e.g. by
manipulating routing or DNS entries), such an adversary is usually
already in a position to observe traffic patterns.
* A proxy advertised by the device hosting the resource to be
accessed is less risky to use than one advertised by a third
party.
The /.well-known/core resource is regarded as a source of
authoritative information on the endpoint's CoAP related metadata,
and can be queried early in the discovery process, or queried for
verification (with filtering applied) after discovery through an
RD. Other resources may be less trustworthy as they may be
controlled by entities not trusted with the endpoint's traffic.
Appendix D describes an extension to [I-D.ietf-lake-edhoc] by which
the client can verify that the proxy used by the client is recognized
by the server. This is similar to querying /.well-known/core for any
proxies advertised there, but happens earlier in the connection
establishment, and leaves the decision whether the proxy is
legitimate to the server.
It only conveys information about the URI of the proxy. The mapping
of any host name inside it to an IP address, or of an IP address to a
routing decision, is left to the security mechanisms of the
respective layers.
9.3. Protecting the proxy
A widely published statement about a host's availability as a proxy
can cause many clients to attempt to use it.
This is mitigated in well-behaved clients by observing the rate
limits of [RFC7252], and by ceasing attempts to reach a proxy for the
Max-Age of received errors.
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Operators can further limit ill-effects by ensuring that their client
systems do not needlessly use proxies advertised in an unsecured way,
and by providing own proxies when their clients need them.
10. IANA considerations
10.1. Link Relation Types
IANA is asked to add two entries into the Link Relation Type Registry
last updated in [RFC8288]:
+==================+=================================+===========+
| Relation Name | Description | Reference |
+==================+=================================+===========+
| has-proxy | The link target can be used as | RFCthis |
| | a proxy to reach URIs inside | |
| | the origin of the link context. | |
+------------------+---------------------------------+-----------+
| has-unique-proxy | Like has-proxy, and using this | RFCthis |
| | proxy implies scheme and host | |
| | of the target. | |
+------------------+---------------------------------+-----------+
Table 1: New Link Relation types
10.2. Resource Types
IANA is asked to add an entry into the "Resource Type (rt=) Link
Target Attribute Values" registry under the Constrained RESTful
Environments (CoRE) Parameters:
[ The RFC Editor is asked to replace any occurrence of CPA-core.proxy
with the actually registered attribute value. ]
Attribute Value: core.proxy
Description: Forward proxying services
Reference: [ this document ]
10.3. Service Parameter Key (SvcParamKey)
IANA is NOT YET requested to add the following entries to the SVCB
Service Parameters registry ([RFC9460]). The definition of this
parameter can be found in Section 8.
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+================+===============+=================================+
| Number | Name | Meaning |
+================+===============+=================================+
| 10 (suggested) | coaptransport | CoAP transport protocol |
+----------------+---------------+---------------------------------+
| to be assigned | edhoc-cred | EDHOC credentials identifying |
| | | the server |
+----------------+---------------+---------------------------------+
| to be assigned | edhoc-info | EDHOC profile information |
+----------------+---------------+---------------------------------+
| to be assigned | oauth-hints | Describes how to obtain a token |
| | | at an ACE Authorization Server |
+----------------+---------------+---------------------------------+
Table 2
All entries have in common that their Reference is this this
document, Section 7.2}, and that their change controller is IETF.
10.4. Underscored and Globally Scoped DNS Node Names
IANA is NOT YET requested to add the following entry to the
Underscored and Globally Scoped DNS Node Names registry (in the DNS
Parameters group) established in [RFC8552] and thus enables its use
with SVCB records:
* SVCB, _coap, Section 7.1 of this document
The request for registration is deliberately not expressed at this
point because it is yet to be revisited whether the creation of a
"COAP" RR similar to the "HTTPS" RR would be preferable.
11. References
11.1. Normative References
[I-D.ietf-core-href]
Bormann, C. and H. Birkholz, "Constrained Resource
Identifiers", Work in Progress, Internet-Draft, draft-
ietf-core-href-16, 24 July 2024,
.
[RFC6690] Shelby, Z., "Constrained RESTful Environments (CoRE) Link
Format", RFC 6690, DOI 10.17487/RFC6690, August 2012,
.
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[RFC7252] Shelby, Z., Hartke, K., and C. Bormann, "The Constrained
Application Protocol (CoAP)", RFC 7252,
DOI 10.17487/RFC7252, June 2014,
.
[RFC8288] Nottingham, M., "Web Linking", RFC 8288,
DOI 10.17487/RFC8288, October 2017,
.
[RFC8742] Bormann, C., "Concise Binary Object Representation (CBOR)
Sequences", RFC 8742, DOI 10.17487/RFC8742, February 2020,
.
[RFC9052] Schaad, J., "CBOR Object Signing and Encryption (COSE):
Structures and Process", STD 96, RFC 9052,
DOI 10.17487/RFC9052, August 2022,
.
[RFC9460] Schwartz, B., Bishop, M., and E. Nygren, "Service Binding
and Parameter Specification via the DNS (SVCB and HTTPS
Resource Records)", RFC 9460, DOI 10.17487/RFC9460,
November 2023, .
[RFC9528] Selander, G., Preuß Mattsson, J., and F. Palombini,
"Ephemeral Diffie-Hellman Over COSE (EDHOC)", RFC 9528,
DOI 10.17487/RFC9528, March 2024,
.
11.2. Informative References
[aliases] W3C, "Architecture of the World Wide Web, Section 2.3.1
URI aliases", n.d.,
.
[cooluris] BL, T., "Cool URIs don't change", n.d.,
.
[evossl] Baier, E., "The Evolution of SSL and TLS", 2 February
2015, .
[I-D.amsuess-core-coap-over-gatt]
Amsüss, C., "CoAP over GATT (Bluetooth Low Energy Generic
Attributes)", Work in Progress, Internet-Draft, draft-
amsuess-core-coap-over-gatt-07, 25 September 2024,
.
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[I-D.amsuess-core-resource-directory-extensions]
Amsüss, C., "CoRE Resource Directory Extensions", Work in
Progress, Internet-Draft, draft-amsuess-core-resource-
directory-extensions-10, 4 March 2024,
.
[I-D.amsuess-t2trg-onion-coap]
Amsüss, C., Tiloca, M., and R. Höglund, "Using onion
routing with CoAP", Work in Progress, Internet-Draft,
draft-amsuess-t2trg-onion-coap-02, 17 May 2024,
.
[I-D.amsuess-t2trg-rdlink]
Amsüss, C., "rdlink: Robust distributed links to
constrained devices", Work in Progress, Internet-Draft,
draft-amsuess-t2trg-rdlink-01, 23 September 2019,
.
[I-D.bormann-t2trg-slipmux]
Bormann, C. and T. Kaupat, "Slipmux: Using an UART
interface for diagnostics, configuration, and packet
transfer", Work in Progress, Internet-Draft, draft-
bormann-t2trg-slipmux-03, 4 November 2019,
.
[I-D.ietf-ace-edhoc-oscore-profile]
Selander, G., Mattsson, J. P., Tiloca, M., and R. Höglund,
"Ephemeral Diffie-Hellman Over COSE (EDHOC) and Object
Security for Constrained Environments (OSCORE) Profile for
Authentication and Authorization for Constrained
Environments (ACE)", Work in Progress, Internet-Draft,
draft-ietf-ace-edhoc-oscore-profile-06, 21 October 2024,
.
[I-D.ietf-cbor-edn-literals]
Bormann, C., "CBOR Extended Diagnostic Notation (EDN)",
Work in Progress, Internet-Draft, draft-ietf-cbor-edn-
literals-12, 1 September 2024,
.
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[I-D.ietf-core-coap-dtls-alpn]
Lenders, M. S., Amsüss, C., Schmidt, T. C., and M.
Wählisch, "ALPN ID Specification for CoAP over DTLS", Work
in Progress, Internet-Draft, draft-ietf-core-coap-dtls-
alpn-00, 5 September 2024,
.
[I-D.ietf-core-dns-over-coap]
Lenders, M. S., Amsüss, C., Gündoğan, C., Schmidt, T. C.,
and M. Wählisch, "DNS over CoAP (DoC)", Work in Progress,
Internet-Draft, draft-ietf-core-dns-over-coap-09, 21
October 2024, .
[I-D.ietf-lake-edhoc]
Selander, G., Mattsson, J. P., and F. Palombini,
"Ephemeral Diffie-Hellman Over COSE (EDHOC)", Work in
Progress, Internet-Draft, draft-ietf-lake-edhoc-23, 22
January 2024, .
[I-D.ietf-lpwan-coap-static-context-hc]
Minaburo, A., Toutain, L., and R. Andreasen, "Static
Context Header Compression (SCHC) for the Constrained
Application Protocol (CoAP)", Work in Progress, Internet-
Draft, draft-ietf-lpwan-coap-static-context-hc-19, 8 March
2021, .
[I-D.lenders-core-dnr]
Lenders, M. S., Amsüss, C., Schmidt, T. C., and M.
Wählisch, "Discovery of Network-designated OSCORE-based
Resolvers: Problem Statement", Work in Progress, Internet-
Draft, draft-lenders-core-dnr-03, 8 July 2024,
.
[I-D.silverajan-core-coap-protocol-negotiation]
Silverajan, B. and M. Ocak, "CoAP Protocol Negotiation",
Work in Progress, Internet-Draft, draft-silverajan-core-
coap-protocol-negotiation-09, 2 July 2018,
.
[I-D.tiloca-core-oscore-capable-proxies]
Tiloca, M. and R. Höglund, "OSCORE-capable Proxies", Work
in Progress, Internet-Draft, draft-tiloca-core-oscore-
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capable-proxies-07, 10 July 2023,
.
[I-D.tiloca-lake-app-profiles]
Tiloca, M. and R. Höglund, "Coordinating the Use of
Application Profiles for Ephemeral Diffie-Hellman Over
COSE (EDHOC)", Work in Progress, Internet-Draft, draft-
tiloca-lake-app-profiles-03, 21 October 2024,
.
[lwm2m] OMA SpecWorks, "White Paper – Lightweight M2M 1.1", n.d.,
.
[noproxy] Hu, S., "We need to talk: Can we standardize NO_PROXY?",
27 January 2021,
.
[RFC1123] Braden, R., Ed., "Requirements for Internet Hosts -
Application and Support", STD 3, RFC 1123,
DOI 10.17487/RFC1123, October 1989,
.
[RFC2616] Fielding, R., Gettys, J., Mogul, J., Frystyk, H.,
Masinter, L., Leach, P., and T. Berners-Lee, "Hypertext
Transfer Protocol -- HTTP/1.1", RFC 2616,
DOI 10.17487/RFC2616, June 1999,
.
[rfc3172] Huston, G., Ed., "Management Guidelines & Operational
Requirements for the Address and Routing Parameter Area
Domain ("arpa")", BCP 52, RFC 3172, DOI 10.17487/RFC3172,
September 2001, .
[RFC3986] Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform
Resource Identifier (URI): Generic Syntax", STD 66,
RFC 3986, DOI 10.17487/RFC3986, January 2005,
.
[RFC4648] Josefsson, S., "The Base16, Base32, and Base64 Data
Encodings", RFC 4648, DOI 10.17487/RFC4648, October 2006,
.
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[RFC5952] Kawamura, S. and M. Kawashima, "A Recommendation for IPv6
Address Text Representation", RFC 5952,
DOI 10.17487/RFC5952, August 2010,
.
[RFC6698] Hoffman, P. and J. Schlyter, "The DNS-Based Authentication
of Named Entities (DANE) Transport Layer Security (TLS)
Protocol: TLSA", RFC 6698, DOI 10.17487/RFC6698, August
2012, .
[RFC7291] Boucadair, M., Penno, R., and D. Wing, "DHCP Options for
the Port Control Protocol (PCP)", RFC 7291,
DOI 10.17487/RFC7291, July 2014,
.
[RFC7838] Nottingham, M., McManus, P., and J. Reschke, "HTTP
Alternative Services", RFC 7838, DOI 10.17487/RFC7838,
April 2016, .
[RFC8305] Schinazi, D. and T. Pauly, "Happy Eyeballs Version 2:
Better Connectivity Using Concurrency", RFC 8305,
DOI 10.17487/RFC8305, December 2017,
.
[RFC8323] Bormann, C., Lemay, S., Tschofenig, H., Hartke, K.,
Silverajan, B., and B. Raymor, Ed., "CoAP (Constrained
Application Protocol) over TCP, TLS, and WebSockets",
RFC 8323, DOI 10.17487/RFC8323, February 2018,
.
[RFC8552] Crocker, D., "Scoped Interpretation of DNS Resource
Records through "Underscored" Naming of Attribute Leaves",
BCP 222, RFC 8552, DOI 10.17487/RFC8552, March 2019,
.
[RFC9176] Amsüss, C., Ed., Shelby, Z., Koster, M., Bormann, C., and
P. van der Stok, "Constrained RESTful Environments (CoRE)
Resource Directory", RFC 9176, DOI 10.17487/RFC9176, April
2022, .
[rfc9176] Amsüss, C., Ed., Shelby, Z., Koster, M., Bormann, C., and
P. van der Stok, "Constrained RESTful Environments (CoRE)
Resource Directory", RFC 9176, DOI 10.17487/RFC9176, April
2022, .
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[RFC9200] Seitz, L., Selander, G., Wahlstroem, E., Erdtman, S., and
H. Tschofenig, "Authentication and Authorization for
Constrained Environments Using the OAuth 2.0 Framework
(ACE-OAuth)", RFC 9200, DOI 10.17487/RFC9200, August 2022,
.
[RFC9461] Schwartz, B., "Service Binding Mapping for DNS Servers",
RFC 9461, DOI 10.17487/RFC9461, November 2023,
.
[RFC9462] Pauly, T., Kinnear, E., Wood, C. A., McManus, P., and T.
Jensen, "Discovery of Designated Resolvers", RFC 9462,
DOI 10.17487/RFC9462, November 2023,
.
[RFC9463] Boucadair, M., Ed., Reddy.K, T., Ed., Wing, D., Cook, N.,
and T. Jensen, "DHCP and Router Advertisement Options for
the Discovery of Network-designated Resolvers (DNR)",
RFC 9463, DOI 10.17487/RFC9463, November 2023,
.
[rfc9476] Kumari, W. and P. Hoffman, "The .alt Special-Use Top-Level
Domain", RFC 9476, DOI 10.17487/RFC9476, September 2023,
.
[SUIB] "Router and IoT Vulnerabilities: Insecure by Design",
2021, .
[w3address]
BL, T., "W3 address syntax: BNF", 29 June 1992,
.
Appendix A. Change log
Since draft-ietf-core-transport-indication-06:
* Split introduction into terminology (with new definitions), goals
and concepts.
* Add principle of operation into abstract, elevating SVCB and has-
proxy to equally ranked sources of endpoint information.
* Restructure document to split overview and operations from the
concrete methods of obtaining endpoints.
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* Add is-unique-proxy SVCB parameter equivalent to has-unique-proxy
relation.
* Remove _coaps service, describing _coap as applying to all CoAP
transports.
* Add SVCB to abstract.
* Remove distracting text on URIs identifying transports/endpoints.
* Editorial changes.
* IANA considerations: Set change controller to IETF.
Since draft-ietf-core-transport-indication-05:
* Semantics for where a has-proxy applies were changed from
"wherever there is a hosts relation" to "across the same origin".
The hosts relation has received complaints about its complexity,
and there were no strong voices in either direction during or
after IETF119 when the question has been asked; going for the
easier version.
* Use of SVCB is added as a section. Underscore prefixes are
registered for CoAP, enabling the use of SVCB DNS records for
applications that opt in to it (rather than processing it as an
alternative history).
While the alternative history section was appreciated during
IETF119, the authors found it highly impractical to provide SVCB
ground work without having the actual registrations (it would have
worked only because DNS discovery acts on a separate _dns prefix
anyway), and chose the consistent approach of allowing SVCB
lookups.
* Material from the DNS and DNR for CoAP documents was moved in (and
overhauled in the process):
- Constructing CoAP requests from Service Parameters that did not
result from a host name lookup is described.
- The coaptransport SVCB parameter is defined.
- SVCB hints for ACE/OAuth are defined.
* Section on how a host can tell that Uri-Host is optional was moved
from Open Questions into a section.
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This had been around for ages, and gathering some more experience
with the matter, looks like the obvious approach.
* Editorial:
- Style for unallocated registrations changed from TBD to CPA
- References updated
- Tooling updates
- Minor fixes
Since draft-ietf-core-transport-indication-04:
* Not just the scheme, but also the authority value influences the
transport selection.
- Add guidance section for new transports.
- Point out that registerd names already can fan out to different
addresses.
* Rephrase and simplify security considerations, especially by
limiting unique proxying for TLS.
* Add recommendation to new scheme authors to use "coap"/"coaps" and
let the resolution process guide the selection.
- Remove proxy-schemes attribute from core.proxy because of its
greatly reduced value.
* Update "Related work" appendix to cover SVCB instead of SRV
records
* Rename to "Transport Indication", using "protocol" only for other
protocols, in established phrases, or when referring to CoAP as a
general protocol.
* Add note linking CoAP-over-WS's .well-known/coap to dohpath
* Remove OSCORE vs. unique-proxy open point
* EDHOC EAD: Describe response option content
* Editorial updates
Since draft-ietf-core-transport-indication-03:
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* Added appendices on alternative history and Literals beyond IP
addresses. The remaining document was not brought in sync with
those new parts.
Since draft-ietf-core-transport-indication-02:
* Added EAD appendix, adjusted security considerations to match.
Since draft-ietf-core-transport-indication-01:
* Simplify same-host proxy behavior by referring to existing RFC7252
mandate.
* proxy-links= lookup: Refer to prior art.
Since draft-ietf-core-transport-indication-00:
* Add section on canonical URIs that are not necessarily reachable.
* Clarify that the the "hosts" relation is followed transitively.
* Cross reference with compatible multicast-notifications concept.
Since draft-amsuess-core-transport-indication-03:
* No changes (merely changing the name after WG adoption)
Since -02 (mainly processing reviews from Marco and Klaus):
* Acknowledge that 'coap://hostname/' is not the proxy but a URI
that (in a particular phrasing) is used to stand in for the
proxy's address (while it regularly identifies a resurce on the
server)
* Security: Referencing traffic misdirection already in the first
security block.
* Security: Add (incomplete) considerations for unique-proxy case.
* Narrow down "unique" proxy semantics to those properties used by
the client, allowing unique proxies to be co-hosted with forward
proxies.
* "Client picked proxies" clarified to merely illustrate how this is
compatible with them.
* Use of "hosts" relation sharpened.
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* Precision on how this does and does not consider changing
transports.
* "Related work" section demoted to appendix.
* Add note on DTLS session resumption.
* Variable renaming.
* Various editorial fixes.
Since -01:
* Removed suggestion for generally trusted proxies; now stating that
with (D)TLS, "a third party proxy can usually not satisfy [the
security context propagation requirement]".
* State more clearly that valid cache entries for resources aliased
through has-unique-proxy can be used.
* Added considerations for Multipath TCP.
* Added concrete suggestion and example for advertisement of general
proxies.
* Added concrete suggestion for RD lookup extension that provides
proxies.
* Minor editorial and example changes.
Since -00:
* Added introduction
* Added examples
* Added SCHC analogy
* Expanded security considerations
* Added guidance on choice of transport, and canonical addresses
* Added subsection on interaction with a Resource Directory
* Added comparisons with related work, including rdlink and DNS-SD
sketches
* Added IANA considerations
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* Added section on open questions
Appendix B. Related work and applicability to related fields
B.1. On HTTP
The mechanisms introduced here are similar to the Alt-Svc header of
[RFC7838] in that they do not create different application-visible
addresses, but provide dispatch through lower transport
implementations.
In HTTP, different versions of the protocol (i.e., different
transports) are distinguished using a protocol identifier equivalent
to an ALPN. This works well because all relevant transports use
transport layer security and thus can use ALPNs. In contrast, the
currently specified CoAP transports predate ALPNs, and specified per-
transport schemes, which enable the use of URIs that indicate
transports.
To accommodate the message size constraints typical of CoRE
environments, and accounting for the differences between HTTP headers
and CoAP options, information is delivered once at discovery time.
Using the has-proxy and has-unique-proxy with HTTP URIs as the
context is NOT RECOMMENDED; the HTTP provisions of the Alt-Svc header
and ALPN are preferred.
B.2. Using DNS
DNS Service Binding resource records (SVCB RRs) described in
[RFC9460] can carry many of the details otherwise negotiated using
the proxy relations. In HTTP, they can be used in a way similar to
Alt-Svc headers.
SVCB records were not specified when CoAP was specified for TCP.
If at any point SVCB records for CoAP are defined, name resolution
produces a set of transport details that can be used immediately
without the need for a has-proxy link. Explicit has-proxy links
would still be relevant for third party advertised proxies.
B.3. Using names outside regular DNS
Names that are resolved through different mechanisms than DNS, or
names which are defined within the scope of DNS but have no
universally valid answers to A/AAAA requests, can be advertised using
the relation types defined here and CoAP discovery.
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In Figure 5, a server using a cryptographic name as described in
[I-D.amsuess-t2trg-rdlink] is discovered and used.
Req: to [ff02::fd]:5683 on UDP
Code: GET
Uri-Path: /.well-known/core
Uri-Query: rel=has-proxy
Uri-Query: anchor=coap://nbswy3dpo5xxe3denbswy3dpo5xxe3de.ab.rdlink.arpa
Res: from [2001:db8::1]:5683
Content-Format: application/link-format
Payload:
;rel=has-unique-proxy;
anchor="coap://nbswy3dpo5xxe3denbswy3dpo5xxe3de.ab.rdlink.arpa"
Req: to [2001:db8::1]:5683 on TCP
Code: GET
OSCORE: ...
Uri-Path: /sensors/temp
Observe: 0
Res: 2.05 Content
OSCORE: ...
Observe: 0
Payload:
39.1°C
Figure 5: Obtaining a sensor value from a local device with a
global name
B.4. Multipath TCP
When CoAP-over-TCP is used over Multipath TCP and no Uri-Host option
is sent, the implicit assumption is that there is aliasing between
URIs containing any of the endpoints' addresses.
As these are negotiated within MPTCP, this works independently of
this document's mechanisms. As long as all the server's addresses
are equally reachable, there is no need to advertise multiple
addresses that can later be discovered through MPTCP anyway. When
advertisements are long-lived and there is no single more stable
address, several available addresses can be advertised (independently
of whether MPTCP is involved or not). If a client uses an address
that is merely a proxy address (and not a unique proxy address), but
during MPTCP finds out that the network location being accessed is
actually an MPTCP alternative address of the used one, the client MAY
forego sending of the Proxy-Scheme and Uri-Path option.
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[ This follows from multiple addresses being valid for that TCP
connection; at some point we may want to say something about what
that means for the default value of the Uri-Host option -- maybe
something like "has the default value of any of the associated
addresses, but the server may only enable MPTCP if there is implicit
aliasing between all of them" (similar to OSCORE's statement)? ]
[ TBD: Do we need a section analog to this that deals with (D)TLS
session resumption in absence of SNI? ]
Appendix C. Open Questions / further ideas
* Advertising under a stable name:
If a host wants to advertise its host name rather than its IP
address during multicast, how does it best do that?
Options, when answering from 2001:db8::1 to a request to ff02::fd
are:
,...,
;rel=has-unique-proxy;anchor="coap://myhostname"
which is verbose but formally clear, and
,...,
;rel=has-unique-proxy;anchor="coap://myhostname"
which is compatible with unaware clients, but its correctness with
respect to canonical URIs needs to be argued by the client, in
this sequence
- understanding the has-unique-proxy line,
- understanding that the request that went to 2001:db8::1 was
really a Proxy-Scheme/Uri-Host-elided version of a request to
coap://myhostname, and then
- processing any relative reference with this new base in mind.
(Not that it'd need to happen in software in that sequence, but
that's the sequence needed to understand how the /foo here is
really coap://myhostname/foo).
If CoRAL is used during discovery, a base directive or reverse
relation to has-unique-proxy would make this easier.
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Appendix D. EDHOC EAD for verifying legitimate proxies
This document sketches an extension to [I-D.ietf-lake-edhoc] that
informs the server of the public address the client is using,
allowing it to detect undesired reverse proxies.
[ This section is immature, and written up as a discussion starting
point. Further research into prior art is still necessary. ]
The External Authorization Data (EAD) item with name "Proxy CRI",
label 24-CPA, is defined for use with messages 1, 2 and 3.
A client can set this label in uncritical form, followed by a CRI
([I-D.ietf-core-href]) that is CBOR-encoded in a byte string as a
CBOR sequence. The transport indicated by the URI is the proxy the
client chose from information advertised about the server.
If a server can not determine its set of legitimate proxies, it
ignores the option (as does any EDHOC implementation that is unaware
of it).
If it recognizes the CRI as belonging to a legitimate proxy, it
places the empty label in its non-critical form in the next message
to confirm the proxy choice. Otherwise, it places the label in its
critical form, either empty or containing a recommended CRI. The
client may then decide to discontinue using the proxy, or to use more
extensive padding options to sidestep the attack. Both the client
and the server may alert their administrators of a possible traffic
misdirection.
[ While using an EDHOC EAD is suitable for connection setup, such a
mechanism may also be useful at a later time, eg. to re-check a
server's address after a name change; establishing an equivalent CoAP
option is being considered, also oin light of the discussion around
https://github.com/core-wg/corrclar/pull/40 and https://github.com/
core-wg/groupcomm-proxy/issues/3. ]
Appendix E. Literals beyond IP addresses
[ This section is placed here preliminarily: After initial review in
CoRE, this may be better moved into a separate document aiming for a
wider IETF audience. ]
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E.1. Motivation for new literal-ish names
IP literals were part of URIs from the start [w3address]. Initially,
they were equivalent to host names in their expressiveness, save for
their inherent difference that the former can be used without a
shared resolver, and the latter can be switched to a different
network address.
This equivalence got lost gradually: Certificates for TLS (its
precursor SSL has been available since 1995 [evossl]) have only
practically been available to host names. The Host header introduced
in HTTP 1.1 Section 14.23 of [RFC2616] introduced name based virtual
hosting in 1999. DANE [RFC6698], which provides TLS public keys
augmenting the or outside of the public key infrastructure, is only
available for host names resolved through DNSSEC. SVCB records
[RFC9460] introduced in 2023 allow starting newer HTTP transports
without going through HTTP/1.1 first, enables load balancing, fail-
over, and enable Encrypted Client Hello -- again, only for host names
resolved through DNS.
This document proposes an expression for the host component of a URI
that fills that gap. Note that no attempt is yet made to register
service.arpa in the .ARPA Zone Management; that name is used only for
the purpose of discussion.
// The structure and even more the syntax used here is highly
// preliminary. They serves to illustrate that the desired
// properties can be obtained, and do not claim to be optimal. As
// one of many aspects, they are missing considerations for
// normalization and for internationalization.
E.2. Structure of service.arpa
Names under service.arpa are structured into an optional custom
prefix, an ordered list of key-value component pairs, and the common
suffix service.arpa.
The custom prefix can contain user defined components. The intended
use is labelling, and to differentiate services provided by a single
host. Any data is allowed within the structure of a URI (ABNF reg-
name) and DNS name rules (63 bytes per segment). (While not ever
carried by DNS, this upholds the constraints of DNS for names. That
decision may be revised later, but is upheld while demonstrating that
the desired properties can be obtained).
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Component pairs consist of a registered component type (no precise
registry is proposed at this early point) followed by encoded data.
The component type "--" is special in that it concatenates the values
to its left and to its right, creating component values that may
exceed 63 bytes in length.
Initial component types are:
* "6": The value encodes an IPv6 address in [RFC5952] format, with
the colon character (":") replaced with a dash ("-").
It indicates an address of a host providing the service.
If any address information is present, a client SHOULD use that
information to access the service.
* "4": The value encodes an IPv4 address in dotted decimal format
[RFC1123], with the dot character (".") replaced with a dash
("-").
It indicates an address of a host providing the service.
* "tlsa": The data of a DNS TLSA record [RFC6698] encoded in base32
[RFC4648].
Depending on the usage, this describes TLS credentials through
which the service can be authenticated.
If present, a client MUST establish a secure connection, and MUST
fail the connection if the TLSA record's requirements are not met.
* "edhoc-cred", "edhoc-info", "oauth-info": SvcbParams in base32
encoding of their wire format.
* "coaptransport": SvcbParam in its text encoding.
* "s": Other Service Parameters that do not have an explicit
component type. SvcbParams in base32 encoding of their wire
format.
TBD: There is likely a transformation of the parameters'
presentation format that is compatible with the requirements of
the authority component, but this will require some more work on
the syntax.
If present, a client SHOULD use these hints to establish a
connection.
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TBD: Encoding only the SvcParams and not priorities and targets
appears to be the right thing to do for the immediate record, but
does not enable load balancing and failover. Further work is
required to explore how those can be expressed, and how data
pertaining to the target can be expressed, possibly in a nested
structure.
E.3. Syntax of service.arpa
name = [ custom ".-." ] *(component) "service.arpa"
custom = reg-name
component = 1*63nodot "." comptype "."
comptype = nodotnodash / 2*63nodot
; unreserved/subdelims without dot
nodot = nodotnodash / "-"
; unreserved/subdelims without dot or dash
nodotnodash = ALPHA / DIGIT / "_" / "~" / sub-delims
; reg-name and sub-delims as in RFC3986
Due to [RFC3986]'s rules, all components are case insensitive and
canonically lowercase.
Note that while using the IPvFuture mechanism of [RFC3986] would
avoid compatibility issues around the 63 character limit and some of
the character restrictions, it would not resolve the larger
limitation of case insensitivity.
E.4. Processing service.arpa
A client accessing a resource under a service.arpa name does not
consult DNS, but obtains information equivalent to the results of a
DNS query from parsing the name.
DNS resolvers should refuse to resolve service.arpa names. (They
would have all the information needed to produce sensible results,
but operational aspects would need a lot of consideration; future
versions of this document may revise this).
E.5. Examples
TBD: For SvcParams, the examples are inconsistent with the base32
recommendation; they serve to explore the possible alternatives.
* http://s.alpn_h2c.6.2001-db8--1.service.arpa/ -- The server is
reachable on 2001:db8::1 using HTTP/2
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* https://mail.-.tlsa.amaqckrkfivcukrkfivcukrkfivcukrkfivcukrkfivcuk
rkfivcukrk.service.arpa/ -- No address information is provided,
the client needs to resort to other discovery mechanisms. Any
server is eligible to serve the resource if it can present a
(possibly self-signed) certificate whose public key SHA256 matches
the encoded value. The "mail.-." part is provided to the server
as part of the Host header, and can be used for name based virtual
hosting.
* coap://coaptransport.tcp.edhoc-cred.ueekcandaeasabbblaqlxq2jmbjg5j
gtf2kazljkenaurxocc6i2ckx3zowjgyr.--.ai3ouj4a.6.2001-db8--
1.service.arpa/ -- The server is reachable using CoAP over TCP
with EDHOC security at 2001:db8::1, and the service is
identifiable by the use of a KCCS credential describing an X25519
public key.
* coap://edhoc-cred.ueekcandaeasabbblaqlxq2jmbjg5jgtf2kazljkenaurxoc
c6i2ckx3zowjgyr.--.ai3ouj4a.service.arpa/ -- The same server
without any discoverability hints; it is up to the client to
discover a (possibly short-lived) connection opportunities to the
server identified by that key.
Appendix F. Acknowledgements
This document heavily builds on concepts explored by Bill Silverajan
and Mert Ocak in [I-D.silverajan-core-coap-protocol-negotiation], and
together with Ines Robles and Klaus Hartke inside T2TRG.
[ TBD: reviewers Marco Klaus ]
Authors' Addresses
Christian Amsüss
Austria
Email: christian@amsuess.com
Martine Sophie Lenders
TUD Dresden University of Technology
Helmholtzstr. 10
D-01069 Dresden
Germany
Email: martine.lenders@tu-dresden.de
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