| Internet-Draft | SVCB-DANE | October 2023 |
| Schwartz & Evans | Expires 25 April 2024 | [Page] |
Service Binding (SVCB) records introduce a new form of name indirection in DNS. They also convey information about the endpoint's supported protocols, such as whether QUIC transport is available. This document specifies how DNS-Based Authentication of Named Entities (DANE) interacts with Service Bindings to secure connections, including use of port numbers and transport protocols discovered via SVCB queries. The "_quic" transport name label is introduced to distinguish TLSA records for DTLS and QUIC.¶
This note is to be removed before publishing as an RFC.¶
Source for this draft and an issue tracker can be found at https://github.com/bemasc/svcb-dane.¶
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The DNS-Based Authentication of Named Entities specification [RFC7671] explains how clients locate the TLSA record for a service of interest, starting with knowledge of the service's hostname, transport, and port number. These are concatenated, forming a name like _8080._tcp.example.com. It also specifies how clients should locate the TLSA records when one or more CNAME records are present, aliasing either the hostname or the initial TLSA query name, and the resulting server names used in TLS or DTLS.¶
There are various DNS records other than CNAME that add indirection to the host resolution process, requiring similar specifications. Thus, [RFC7672] describes how DANE interacts with MX records, and [RFC7673] describes its interaction with SRV records.¶
This document describes the interaction of DANE with indirection via Service Bindings [SVCB], i.e. SVCB-compatible records such as SVCB and HTTPS. It also explains how to use DANE with new TLS-based transports such as QUIC.¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
The contents of this document apply equally to all SVCB-compatible record types, such as SVCB and HTTPS records. For brevity, the abbrevation "SVCB" is used to refer to these record types generally.¶
With protocols that support explicit transport redirection via DNS MX records, SRV records, or other similar records, the TLSA base domain is based on the redirected transport endpoint rather than the origin domain.¶
This document applies the same logic to SVCB-compatible records. Specifically, if SVCB resolution was entirely secure (including any AliasMode records and/or CNAMEs), then for each connection attempt derived from a SVCB-compatible record,¶
The initial TLSA base domain MUST be the final SVCB TargetName used for this connection attempt. (Names appearing earlier in a resolution chain are not used.)¶
The transport prefix MUST be the transport of this connection attempt (possibly influenced by the "alpn" SvcParam).¶
The port prefix MUST be the port number of this connection attempt (possibly influenced by the "port" SvcParam).¶
Resolution security is assessed according to the criteria in Section 4.1 of [RFC6698].¶
If the initial TLSA base domain is the start of a secure CNAME chain, clients MUST first try to use the end of the chain as the TLSA base domain, with fallback to the initial base domain, as described in Section 7 of [RFC7671]. However, domain owners SHOULD NOT place a CNAME record on a SVCB TargetName, as this arrangement is unusual, inefficient, and at risk for deprecation in a future revision.¶
If any TLSA QNAME is aliased by a CNAME, clients MUST follow the TLSA CNAME to complete the resolution of the TLSA record. (This does not alter the TLSA base domain.)¶
If a TLSA RRSet is securely resolved, the client MUST set the SNI to the TLSA base domain of the RRSet. In usage modes other than DANE-EE(3), the client MUST validate that the certificate covers this base domain, and MUST NOT require it to cover any other domain.¶
If the client has SVCB-optional behavior (as defined in Section 3 of [SVCB]), it MUST use the standard DANE logic described in Section 4.1 of [RFC6698] when falling back to non-SVCB connection.¶
Section 3 of [RFC6698] defined the protocol prefix used for constructing TLSA QNAMEs, and said:¶
The transport names defined for this protocol are "tcp", "udp", and "sctp".¶
At that time, there was exactly one TLS-based protocol defined for each of these transports. However, with the introduction of QUIC [RFC9000], there are now multiple TLS-derived protocols that can operate over UDP, even on the same port. To distinguish the availability and configuration of DTLS and QUIC, this document updates the above sentence as follows:¶
Service consumers are expected to use a CNAME or SVCB AliasMode record to point at provider-controlled records when possible, e.g.:¶
alias.example. HTTPS 0 xyz.provider.example. www.alias.example. CNAME xyz.provider.example. xyz.provider.example. HTTPS 1 . alpn=h2 ... xyz.provider.example. A 192.0.2.1 _443._tcp.xyz.provider.example. TLSA ...¶
If the service needs its own SvcParamKeys, it cannot use CNAME or AliasMode, so it publishes its own SVCB ServiceMode record with SvcParams that are compatible with the provider, e.g.:¶
_dns.dns.example. HTTPS 1 xyz.provider.example. ( alpn=h2 ...
dohpath=/doh{?dns} )
¶
For ease of management, providers may want to alias various TLSA QNAMEs to a single RRSet:¶
_443._tcp.xyz.provider.example. CNAME dane-central.provider.example. dane-central.provider.example. TLSA ...¶
Any DANE certificate usage mode is compatible with SVCB, but the usage guidelines from Section 4 of [RFC7671] continue to apply.¶
As noted in Section 6 of [RFC7671], DANE encounters operational difficulties when the TLSA record is published by an entity other than the service provider. For example, a customer might copy the TLSA record into their own zone, rather than publishing an alias to the TLSA record hosted in the service provider's zone. When the service subsequently rotates its TLS keys, DANE authentication will fail, resulting in an outage for this customer. Accordingly, zone owners MUST NOT publish TLSA records for public keys that are not under their control unless they have an explicit arrangement with the key holder.¶
To prevents the above misconfiguration and ensure that TLS keys can be rotated freely, service operators MAY reject TLS connections whose SNI does not correspond to an approved TLSA base domain.¶
Service Bindings also enable any third party consumer to publish fixed SvcParams for the service. This can cause an outage or service degradation if the service makes a backward-incompatible configuration change. Accordingly, zone owners should avoid publishing SvcParams for a TargetName that they do not control, and service operators should exercise caution when making incompatible configuration changes.¶
The use of TLSA records specified in this document is independent for each SVCB connection attempt. In environments where DANE is optional, this means that the client might use DANE for some connection attempts but not others when processing a single SVCB RRSet.¶
This document only specifies the use of TLSA records when all relevant DNS records (including SVCB, TLSA, and CNAME records) were resolved securely. If any of these resolutions were insecure (as defined in Section 4.3 of [RFC4035]), the client MUST NOT rely on the TLSA record for connection security. However, if the client would otherwise have used an insecure plaintext transport, it MAY use an insecure resolution result to achieve opportunistic security.¶
Certain protocols that can run over TLS, such as HTTP/1.0, do not confirm the name of the service after connecting. With DANE, these protocols are subject to an Unknown Key Share (UKS) attack, in which the client believes it is connecting to the attacker's domain, but is actually connecting to an unaffiliated victim domain [I-D.barnes-dane-uks-00]. When using a vulnerable protocol with DANE, clients MUST NOT perform any action that modifies persistent server state. (HTTP/1.1 and later and encrypted DNS are not vulnerable to UKS attacks; see Appendix A.)¶
The following examples demonstrate Service Binding interaction with TLSA base domain selection.¶
All of the RRSets below are assumed fully-secure with all related DNSSEC record types omitted for brevity.¶
Given service URI https://api.example.com and record:¶
api.example.com. HTTPS 1 .¶
The TLSA QNAME is _443._tcp.api.example.com.¶
Given service URI https://api.example.com and records:¶
api.example.com. HTTPS 0 svc4.example.net. svc4.example.net. HTTPS 0 xyz.cdn.example. xyz.cdn.example. A 192.0.2.1¶
The TLSA QNAME is _443._tcp.xyz.cdn.example.¶
Given service URI https://www.example.com and records:¶
www.example.com. CNAME api.example.com. api.example.com. HTTPS 1 svc4.example.net alpn=h2,h3 port=8443 svc4.example.net. CNAME xyz.cdn.example.¶
If the connection attempt is using HTTP/3, the transport label is set to _quic; otherwise _tcp is used.¶
The initial TLSA QNAME would be one of:¶
If no TLSA record is found, the fallback TLSA QNAME would be one of:¶
Given a DNS server dns.example.com and record:¶
_dns.dns.example.com. SVCB 1 dns.my-dns-host.example. alpn=dot¶
The TLSA QNAME is _853._tcp.dns.my-dns-host.example. The port and protocol are inferred from the "dot" ALPN value.¶
Given a DNS server dns.example.com and records:¶
_dns.dns.example.com. SVCB 0 dns.my-dns-host.example. dns.my-dns-host.example. SVCB 1 . alpn=doq¶
The TLSA QNAME is _853._quic.dns.my-dns-host.example. The port and protocol are inferred from the "doq" ALPN value.¶
Given service URI foo://api.example.com:8443 and record:¶
_8443._foo.api.example.com. SVCB 1 api.example.com.¶
The TLSA QNAME is _8443._$PROTO.api.example.com, where $PROTO is the appropriate value for the client-selected transport as discussed in Section 4 .¶
Given service URI foo://api.example.com:8443 and records:¶
_8443._foo.api.example.com. SVCB 0 svc4.example.net. svc4.example.net. SVCB 1 . svc4.example.net. A 192.0.2.1¶
The TLSA QNAME is _8443._$PROTO.svc4.example.net (with $PROTO as above). This is the same if the ServiceMode record is absent.¶
Given service URI foo://api.example.com:8443 and records:¶
_8443._foo.api.example.com. SVCB 0 svc4.example.net. svc4.example.net. SVCB 3 . alpn=foo,bar port=8004¶
The TLSA QNAME is _8004._$PROTO1.svc4.example.net or _8004._$PROTO2.svc4.example.net, where $PROTO1 and $PROTO2 are the transport prefixes appropriate for "foo" and "bar" respectively. (Note that SVCB requires each ALPN to unambiguously indicate a transport.)¶
IANA is requested to add the following entry to the "Underscored and Globally Scoped DNS Node Names" registry ([RFC8552], Section 4):¶
| RR Type | _NODE NAME | Reference |
|---|---|---|
| TLSA | _quic | (This document) |
When using DANE, a client is vulnerable to an Unknown Key-Share (UKS) attack if it sends a command that can result in a persistent change in server-side state, using a protocol that does not confirm the server's identity. This section analyzes the vulnerability of some popular protocols to this attack, and indicates any resulting restrictions on their use:¶
HTTP/0.9 and HTTP/1.0: Vulnerable¶
HTTP/1.1 and later: Not Vulnerable¶
The CONNECT method ([RFC9110], Section 3.6) does not create a persistent change in server state.¶
All other methods are defended from misdirection attacks by server verification of the Host or :authority header ([RFC9110], Section 7.4).¶
DNS over TLS, DTLS, or QUIC [RFC7858][RFC8094][RFC9250]: Not Vulnerable¶
TODO acknowledge.¶