| DPRIVE WG | T. Reddy |
| Internet-Draft | McAfee |
| Intended status: Standards Track | D. Wing |
| Expires: September 10, 2019 | |
| M. Richardson | |
| Sandelman Software Works | |
| M. Boucadair | |
| Orange | |
| March 9, 2019 |
A Bootstrapping Procedure to Discover and Authenticate DNS-over-(D)TLS and DNS-over-HTTPS Servers
draft-reddy-dprive-bootstrap-dns-server-01
This document specifies mechanisms to automatically bootstrap endpoints (e.g., hosts, Customer Equipment) to discover and authenticate DNS-over-(D)TLS and DNS-over-HTTPS servers provided by a local network.
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Traditionally a caching DNS server has been provided by the local network. This provides benefits like low latency to that DNS server (due to its network proximity to the endpoint). However, if an endpoint is configured to use Internet-hosted or public DNS-over-(D)TLS [RFC7858] [RFC8094] or DNS-over-HTTPS [RFC8484] servers, the local DNS server cannot serve the DNS requests from the endpoints. If public DNS servers are used instead of using local DNS servers, the operational problems are listed below:
If public DNS servers are used instead of using local DNS servers, the following paragraph discusses the impact on Network-based security:
Various network security services are provided by Enterprise, secure home and wall-gardened networks to protect endpoints (e.g,. Hosts, IoT devices). [I-D.camwinget-tls-use-cases] discusses some of the Network-based security use cases. These network security services act on DNS requests from endpoints. However, if an endpoint is configured to use public DNS-over-(D)TLS or DNS-over-HTTPS servers, network security services cannot act efficiently on DNS requests from the endpoints. In order to act on DNS requests from endpoints, network security services can block DNS-over-(D)TLS traffic by dropping outgoing packets to destination port 853. Identifying DNS-over-HTTPS traffic is far more challenging than DNS-over-(D)TLS traffic. Network security services can try to identify the domains offering DNS-over-HTTPS servers, and DNS-over-HTTPS traffic can be blocked by dropping outgoing packets to these domains. If the endpoint has enabled strict privacy profile (Section 5 of [RFC8310]), and the network security service blocks the traffic to the public DNS server, DNS service is not available to the endpoint and ultimately the endpoint cannot access Internet. If the endpoint has enabled opportunistic privacy profile (Section 5 of [RFC8310]), and the network security service blocks traffic to the public DNS server, the endpoint will either fallback to an encrypted connection without authenticating the DNS server provided by the local network or fallback to clear text DNS, and cannot exchange encrypted DNS messages. This can compromise the endpoint security and privacy; some of the potential privacy and security threats are listed below:
The DPRIVE and DoH working groups have not yet defined an automated mechanism to securely bootstrap the endpoints to discover and authenticate DNS-over-(D)TLS and DNS-over-HTTPS servers in the local network. The document proposes a mechanism to automatically bootstrap the endpoints to discover and authenticate the DNS-over-(D)TLS and DNS-over-HTTPS servers provided by the local network. The overall procedure can be structured into the following steps:
Note: The strict and opportunistic privacy profiles as defined in [RFC8310] only applies to DNS-over-(D)TLS protocols, there has been no such distinction made for DNS-over-HTTPS protocol.
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.
(D)TLS is used for statements that apply to both Transport Layer Security [RFC8446] and Datagram Transport Layer Security [RFC6347]. Specific terms are used for any statement that applies to either protocol alone.
This document uses the terms defined in [RFC8499].
The following steps explain the mechanism to automatically bootstrap an endpoint with the local network's CA certificates and DNS server certificate:
The following steps explain the mechanism to automatically bootstrap IoT devices with local network's CA certificates and DNS server certificate. The below steps can also be used by CPE acting as DNS forwarders to discover and authenticate DNS-over-(D)TLS and DNS-over-HTTPS servers provided by the access networks.
A DNS client discovers the DNS server in the local network supporting DNS-over-TLS, DNS-over-DTLS and DNS-over-HTTPS protocols by using the following discovery mechanism:
example.net. IN NAPTR 100 10 "" DPRIVE:dns.tls "" dns1.example.net. IN NAPTR 200 10 "" DPRIVE:dns.dtls "" dns2.example.net. dns1.example.net. IN NAPTR 100 10 S DPRIVE:dns.tls "" _domain-s._tcp.example.net. dns2.example.net. IN NAPTR 100 10 S DPRIVE:dns.dtls "" _domain-s._udp.example.net. _domain-s._tcp.example.net. IN SRV 0 0 853 a.example.net. _domain-s._udp.example.net. IN SRV 0 0 853 a.example.net. a.example.net. IN A 192.0.2.1 IN AAAA 2001:db8:8:4::2
Figure 1
$ORIGIN example.net. _domain-s._tcp IN URI 10 1 "https://example.net/dns-query"
Figure 2
Once the DNS client has retrieved the authentication domain name for the DNS server, an S-NAPTR lookup with 'DPRIVE' application service and the desired protocol tag is made to obtain information necessary to securely connect to the DNS server. The S-NAPTR lookup is performed using an recursive DNS resolver discovered from an untrusted source (such as DHCP).
This specification defines "DPRIVE" as an application service tag (Section 9.1.1) and "dns.tls" (Section 9.1.2), "dns.dtls" (Section 9.1.3), and "dns.https" (Section 9.1.4) as application protocol tags.
If no DNS-specific S-NAPTR records can be retrieved, the discovery procedure fails for this authentication domain name. However, before retrying a lookup that has failed, a DNS client MUST wait a time period that is appropriate for the encountered error (e.g., NXDOMAIN, timeout, etc.).
The DNS client initiates (D)TLS handshake with the DNS server, the server presents its certificate in ServerHello message, and the DNS client matches the DNS server certificate downloaded in step 4 in Section 3 and Section 4 with the certificate provided by the DNS server in (D)TLS handshake. If the match is successful, the DNS client validates the server certificate using the Explicit Trust Anchor database entries downloaded in step 3 in Section 3 and Section 4.
If the match is successful and server certificate is successfully validated, the client continues with the connection as normal. Otherwise, the client MUST treat the server certificate validation failure as a non-recoverable error. If the DNS client cannot reach or establish an authenticated and encrypted connection with the privacy-enabling DNS server provided by the local network, the DNS client can fallback to the privacy-enabling public DNS server.
The bootstrapping procedure to discover and authenticate DNS-over-(D)TLS and DNS-over-HTTPS Servers MUST be enabled by the endpoint in a trusted network (e.g. Enterprise, Secure home networks) and disabled in a untrusted network (e.g. Public WiFi network), similar to the way VPN connection from the endpoint to a VPN gateway is disconnected in a trusted network and VPN connection is established in a untrusted network.
If the endpoint has enabled strict privacy profile, and the network security service blocks the traffic to the privacy-enabling public DNS server, a hard failure occurs and the user is notified. The user has a choice to switch to another network or if the user trusts the network, the user can enable strict privacy profile with the DNS-over-(D)TLS or DNS-over-HTTPS server discovered in the network instead of downgrading to opportunistic privacy profile.
The primary attacks against the methods described in Section 5 are the ones that would lead to impersonation of a DNS server and spoofing the DNS response to indicate that the DNS server does not support any privacy-enabling protocols. To protect against DNS-vectored attacks, secured DNS (DNSSEC) can be used to ensure the validity of the DNS records received. The explicit trust anchor database entries downloaded in step 3 in Section 3 and Section 4 can be used by the endpoint to validate the DNSSEC signature. Impersonation of the DNS server is prevented by validating the certificate presented by the DNS server. If the BRSKI-EST server conveys the DNS server certificate, but the S-NAPTR lookup indicates that the DNS server does not support any privacy-enabling protocols, the client can detect the DNS response is spoofed.
Security considerations in [I-D.ietf-anima-bootstrapping-keyinfra] and [RFC7804] need to be taken into consideration.
[RFC7626] discusses DNS privacy considerations in both "on the wire" (Section 2.4 of [RFC7626]) and "in the server" (Section 2.5 of [RFC7626] contexts. The endpoint may not know if the DNS-over-(D)TLS or DNS-over-HTTPS server in the local network has a privacy preserving data policy. A new privacy certificate extension can be defined that identifies the privacy preserving data policy of the DNS server. The extension will contain a URL that points to the privacy preserving data policy.
IANA is requested to allocate the SRV service name of "domain-s" for DNS-over-(D)TLS and DNS-over-HTTPS.
This document requests IANA to make the following allocations from the registry available at: https://www.iana.org/assignments/s-naptr-parameters/s-naptr-parameters.xhtml.
Thanks to Joe Hildebrand, Harsha Joshi, Shashank Jain, Patrick McManus and Sara Dickinson for the discussion and comments.
| [CDN] | "End-User Mapping: Next Generation Request Routing for Content Delivery", 2015. |
| [I-D.camwinget-tls-use-cases] | Andreasen, F., Cam-Winget, N. and E. Wang, "TLS 1.3 Impact on Network-Based Security", Internet-Draft draft-camwinget-tls-use-cases-03, December 2018. |
| [I-D.ietf-opsawg-mud] | Lear, E., Droms, R. and D. Romascanu, "Manufacturer Usage Description Specification", Internet-Draft draft-ietf-opsawg-mud-25, June 2018. |
| [RFC2775] | Carpenter, B., "Internet Transparency", RFC 2775, DOI 10.17487/RFC2775, February 2000. |
| [RFC7626] | Bortzmeyer, S., "DNS Privacy Considerations", RFC 7626, DOI 10.17487/RFC7626, August 2015. |
| [RFC7871] | Contavalli, C., van der Gaast, W., Lawrence, D. and W. Kumari, "Client Subnet in DNS Queries", RFC 7871, DOI 10.17487/RFC7871, May 2016. |
| [RFC8310] | Dickinson, S., Gillmor, D. and T. Reddy, "Usage Profiles for DNS over TLS and DNS over DTLS", RFC 8310, DOI 10.17487/RFC8310, March 2018. |