Internet Engineering Task Force C. Grothoff
Internet-Draft INRIA
Intended status: Informational M. Wachs
Expires: July 28, 2015 Technische Universität München
H. Wolf, Ed.
GNU consensus
J. Appelbaum
L. Ryge
Tor Project Inc.
January 24, 2015

Special-Use Domain Names of Peer-to-Peer Systems
draft-grothoff-iesg-special-use-p2p-names-04

Abstract

This document registers a set of Special-Use Domain Names for use with Peer-to-Peer (P2P) systems, as per RFC6761.

Status of This Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at http://datatracker.ietf.org/drafts/current/.

Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress."

This Internet-Draft will expire on July 28, 2015.

Copyright Notice

Copyright (c) 2015 IETF Trust and the persons identified as the document authors. All rights reserved.

This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (http://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License.


Table of Contents

1. Introduction

The Domain Name System (DNS) is primarily used to map human-memorable names to IP addresses, which are used for routing but generally not meaningful for humans.

Peer-to-Peer (P2P) systems use specific decentralized mechanisms to allocate, register, manage, and resolve names. However, the hierarchical nature of DNS makes it unsuitable for various P2P Name Systems. Such P2P Name Systems operate entirely outside of DNS, independently from the DNS root and delegation tree.

As compatibility with applications using domain names is desired, these P2P overlay networks often define exclusive alternative Top-Level Domains to avoid conflict between the P2P namespace and the DNS hierarchy.

In order to avoid interoperability issues with DNS as well as to address security and privacy concerns, this document registers a set of Special-Use Domain Names for use with P2P systems (pTLDs), as per [RFC6761],: "GNU", "ZKEY", "ONION", "EXIT", "I2P", and "BIT".

The GNU Name System (GNS) ("GNU", "ZKEY"), the Tor network ("ONION", "EXIT"), the Invisible Internet Project ("I2P"), and the Dot-Bit Project ("BIT") use these pTLDs to realize fully-decentralized and censorship-resistant naming. The "EXIT" pTLD is used to control overlay routing and to securely specify path selection choices [TOR-PATH].

2. Applicability

[RFC6761] Section 3 states:

The set of Special-Use Domain Names for Peer-to-Peer Systems (pTLDs) reserved by this document meet this requirement, as they share the following specificities:

3. Terminology and Conventions Used in This Document

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC2119].

The word "peer" is used in the meaning of a individual system on the network.

The abbreviation "pTLD" is used in this document to mean a pseudo Top-Level Domain, i.e., a Special-Use Domain Name per [RFC6761] reserved to P2P Systems in this document. A pTLD is mentioned in capitals, and within double quotes to mark the difference with a regular DNS gTLD.

In this document, ".tld" (lowercase, with quotes) means: any domain or hostname within the scope of a given pTLD, while .tld (lowercase, without quotes) refers to an adjective form. For example, a collection of ".gnu" peers in "GNU", but an .onion URL. [TO REMOVE: in the IANA Considerations section, we use the simple .tld format to request TLD reservation for consistency with previous RFCs].

The word "NXDOMAIN" refers to an alternate expression for the "Name Error" RCODE as described in section 4.1.1 of [RFC1035]. When referring to "NXDOMAIN" and negative caching [RFC2308] response, this document means an authoritative (AA=1) name error (RCODE=3) response exclusively.

The Tor-related names such as 'circuit', 'exit', 'node', 'relay', 'stream', and related Tor terms are described in [Dingledine2004] and the Tor protocol specification [TOR-PROTOCOL].

The I2P-related names such as 'Destination' are described in [zzz2009].

4. Description of Special-Use Domains in P2P Networks

4.1. The "GNU" Relative pTLD

"GNU" is used to specify that a domain name should be resolved using GNS. The GNS resolution process is documented in [Wachs2014].

The "GNU" domain is special in the following ways:

  1. Users can use these names as they would other domain names, entering them anywhere that they would otherwise enter a conventional DNS domain name.

    Since there is no central authority responsible for assigning .gnu names, and that specific domain is local to the local peer, users need to be aware of that specificity.

    Legacy applications MAY expect the DNS-to-GNS proxy to return DNS compatible results for the resolution of .gnu domains.

  2. Legacy application software does not need to recognize .gnu domains as special, and may continue to use these names as they would other domain names.

    GNS-aware applications MAY also use GNS resolvers directly to resolve .gnu domains (in particular, if they want access to GNS-specific record types).

  3. Name resolution APIs and libraries SHOULD either respond to requests for .gnu names by resolving them via the GNS protocol, or respond with NXDOMAIN.

  4. Caching DNS servers SHOULD recognize .gnu names as special and SHOULD NOT attempt to look up NS records for them, or otherwise query authoritative DNS servers in an attempt to resolve .gnu names. Instead, caching DNS servers SHOULD generate immediate negative responses for all such queries.

  5. Authoritative DNS servers are not expected to treat .gnu domain requests specially. In practice, they MUST answer with NXDOMAIN, as "GNU" is not available via global DNS resolution, and not doing so can put users' privacy at risk (see item 6).

  6. DNS server operators SHOULD be aware that .gnu names are reserved for use with GNS, and MUST NOT override their resolution (e.g., to redirect users to another service or error information).

  7. DNS registries/registrars MUST NOT grant any request to register .gnu names. This helps avoid conflicts [SAC45]. These names are defined by the GNS protocol specification, and they fall outside the set of names available for allocation by registries/registrars.

4.2. The "ZKEY" Compressed Public Key pTLD

The "ZKEY" pTLD is used to signify that resolution of the given name MUST be performed using a record signed by an authority that is in possession of a particular public key. Names in "ZKEY" MUST end with a domain which is the compressed point representation from [EdDSA] on [Curve25519] of the public key of the authority, encoded using Crockford's variant of base32hex [RFC4648] (with additionally 'U' being considered equal to 'V') for easier optical character recognition. A GNS resolver uses the key to locate a record signed by the respective authority.

"ZKEY" provides a (reverse) mapping from globally unique hashes to public key, therefore .zkey names are non-memorable, and are expected to be hidden from the user [Wachs2014].

The "ZKEY" domain is special in the following ways:

  1. Users can use these names as they would other domain names, entering them anywhere that they would otherwise enter a conventional DNS domain name.

    Since there is no central authority necessary or possible for assigning .zkey names, and those names match cryptographic keys, users need to be aware that they do not belong to regular DNS, but are still global in their scope.

    Legacy applications MAY expect the DNS-to-GNS proxy to return DNS-compatible results for the resolution of .zkey domains.

  2. Application software does not need to recognize .zkey domains as special, and may continue to use these names as they would other domain names.

    GNS-aware applications MAY also use GNS resolvers directly to resolve .zkey domains

  3. Name resolution APIs and libraries SHOULD either respond to requests for .zkey names by resolving them via the GNS protocol, or respond with NXDOMAIN.

  4. Caching DNS servers SHOULD recognize .zkey names as special and SHOULD NOT attempt to look up NS records for them, or otherwise query authoritative DNS servers in an attempt to resolve .zkey names. Instead, caching DNS servers SHOULD generate immediate negative responses for all such queries.

  5. Authoritative DNS Servers are not expected to treat .zkey domain requests specially. In practice, they MUST answer with NXDOMAIN, as "ZKEY" is not available via global DNS resolution, and not doing so MAY put users' privacy at risk (see item 6).

  6. DNS server operators SHOULD be aware that .zkey names are reserved for use with GNS, and MUST NOT override their resolution (e.g., to redirect users to another service or error information).

  7. DNS registries/registrars MUST NOT grant any request to register .zkey names. This helps avoid conflicts [SAC45]. These names are defined as described above, and they fall outside the set of names available for allocation by registries/registrars.

4.3. Geographically Anonymous pTLDs

Both the Tor "Onionspace" and the I2P network are designed to provide geographic anonymity to services and all clients visiting them. They provide additional properties such as NAT traversal, strong authentication, anonymity, and censorship resistance.

The Tor anonymization network makes use of several special pTLD labels, three of which have seen widespread usage to date. This document introduces two of them, "ONION" and "EXIT". The interested reader is invited to refer to [TOR-ADDRESS] for further information on the "NOCONNECT" pTLD, whose limited testing scope does not warrant the attention of the larger Internet community.

The I2P network uses a single pTLD, "I2P", but the specific subdomain "B32.I2P" offers properties similar to Tor's "ONION" and GNS's "ZKEY"

The public literature often uses the term "Hidden Service" to refer to both Tor's Hidden Service protocol and services, and I2P's Destinations. This term suggests that such services are hidden from view, whereas only their geographic location is unknown: given their name and the appropriate name resolver, such services are as much accessible as any other regular Web site or Internet service.

4.3.1. The "ONION" Hidden Service pTLD

The widely deployed "ONION" designates the "Onionspace", an anonymous Tor Hidden Service reachable via the Tor network [Dingledine2004]. These .onion hostnames are self-authenticating addresses for use with any TCP service.

Addresses in "ONION" are opaque, non-mnemonic, alpha-semi-numeric digest hashes corresponding to the unique identity key of a given Tor hidden service. Therefore such .onion addresses are self-authenticating. The algorithm to obtain the .onion hash from the Tor hidden service's public key is out of scope of this document, and described in the Tor Address specification [TOR-ADDRESS]. Tor generates this "Onion key" automatically when the hidden service is configured. Tor clients use it following the Tor Rendezvous specifications [TOR-RENDEZVOUS].

The "ONION" domain is special in the following ways:

  1. Users can use these names as they would other domain names, entering them anywhere that they would otherwise enter a conventional DNS domain name.

    Since there is no central authority necessary or possible for assigning .onion names, and those names correspond to cryptographic keys, users need to be aware that they do not belong to regular DNS, but are still global in their scope.

  2. Application software MAY recognize .onion domains as special, and SHOULD use these names as they would other domain names.

    Application software MAY implement mechanisms helping the user to ensure their privacy expectations are met, such as warning the user if they do not detect an active local Tor resolver, displaying a warning on first-use of an .onion domain to explain the necessity of a Tor resolver to reach such domains, etc.

    If an application knows how to differenciate between DNS and P2P name resolution, it:



    Tor-aware applications MAY also use Tor resolvers directly.

  3. Name resolution APIs and libraries SHOULD either respond to requests for .onion names by resolving them via the Tor protocol, or respond with NXDOMAIN.

  4. Caching DNS servers SHOULD recognize .onion names as special and SHOULD NOT attempt to look up NS records for them, or otherwise query authoritative DNS servers in an attempt to resolve .onion names. Instead, caching DNS servers SHOULD generate immediate negative responses for all such queries.

  5. Authoritative DNS servers are not expected to treat .onion domain requests specially. In practice, they MUST answer with NXDOMAIN, as "ONION" is not available via global DNS resolution, and not doing so MAY put users' privacy at risk (see item 6).

  6. DNS server operators SHOULD be aware that .onion names are reserved for use with Tor, and MUST NOT override their resolution (e.g., to redirect users to another service or error information).

  7. DNS registries/registrars MUST NOT grant any request to register .onion names. This helps avoid conflicts [SAC45]. These names are defined the Tor protocol specification [TOR-PROTOCOL], and they fall outside the set of names available for allocation by registries/registrars.

4.3.2. The "EXIT" Client Source Routing pTLD

The .exit suffix is used as an in-band source routing control channel, usually for selection of a specific Tor relay during path creation as the last node in the Tor circuit.

It may be used to access a DNS host via specific Torservers, in the form "hostname.nickname-or-fingerprint.exit", where the "hostname" is a valid hostname, and the "nickname-or-fingerprint" is either the nickname of a Tor relay in the Tor network consensus, or the hex-encoded SHA1 digest of the given node's public key (fingerprint).

For example, "gnu.org.noisetor.exit" will route the client to "gnu.org" via the Tor node nicknamed "noisetor". Using the fingerprint instead of the nickname ensures that the path selection uses a specific Tor exit node, and is harder to remember: e.g., "gnu.org.f97f3b153fed6604230cd497a3d1e9815b007637.exit".

When Tor sees an address in this format, it uses the specified "nickname-or-fingerprint" as the exit node. If no "hostname" component is given, Tor defaults to the published IPv4 address of the Tor exit node [TOR-EXTSOCKS].

Because "hostname" is allegedly valid, the total length of a .exit construct may exceed the maximum length allowed for domain names. Moreover, the resolution of "hostname" happens at the exit node. Trying to resolve such invalid domain names, including chaining .exit names will likely return a DNS lookup failure at the first exit node.

The "EXIT" domain is special in the following ways:

  1. Users can use these names as they would other domain names, entering them anywhere that they would otherwise enter a conventional DNS domain name.

    Since .exit names correspond to a Tor-specific routing construct to reach target hosts via chosen Tor exit nodes, users need to be aware that they do not belong to regular DNS and that the actual target precedes the second-level domain name.

  2. Application software MAY recognize that .exit domains are special and when they do SHOULD NOT pass requests for these domains to DNS resolvers and libraries.

    As mentioned in items 4 and 5 below, regular DNS resolution is expected to respond with NXDOMAIN. Therefore, if it can differentiate between DNS and P2P name resolution, application software:



    Tor-aware applications MAY also use Tor resolvers directly.
  3. Name resolution APIs and libraries SHOULD either respond to requests for .exit names by resolving them via the Tor protocol, or respond with NXDOMAIN.

  4. Caching DNS servers SHOULD recognize .exit names as special and SHOULD NOT, by default, attempt to look up NS records for them, or otherwise query authoritative DNS servers in an attempt to resolve .exit names. Instead, caching DNS servers SHOULD, by default, generate immediate negative responses for all such queries.

  5. Authoritative DNS servers are not expected to treat .exit domain requests specially. In practice, they MUST answer with NXDOMAIN, as "EXIT" is not available via global DNS resolution, and not doing so MAY put users' privacy at risk (see item 6).

  6. DNS server operators SHOULD be aware that .exit names are reserved for use with Tor, and MUST NOT override their resolution (e.g., to redirect users to another service or error information).

  7. DNS registries/registrars MUST NOT grant any request to register .exit names. This helps avoid conflicts [SAC45]. These names are defined by the Tor address specification, and they fall outside the set of names available for allocation by registries/registrars.

4.3.3. The "I2P" Addressbook pTLD

"I2P" provides accessibility to hidden services within the I2P network [zzz2009]. I2P is a scalable, self-organizing, resilient packet switched anonymous network layer, upon which any number of different anonymity or security-conscious applications can operate, using any protocol.

I2P hidden services and clients are identified by Destinations, anonymous analogues of IP addresses. The "I2P" pTLD, chosen in 2003 [I2P-CHOICE], houses two methods for looking up Destinations:

The "I2P" domain is special in the following ways:

  1. Users can use these names as they would other domain names, entering them anywhere that they would otherwise enter a conventional DNS domain name.

    Since there is no central authority responsible for assigning .i2p names, and that the ultimate mapping is decided by the local peer, users need to be aware of that specificity.

  2. Application software SHOULD recognize .i2p domains as special and SHOULD NOT use them as they would other domains.

    Applications SHOULD NOT pass requests for .i2p domains to DNS resolvers and libraries.

    As mentioned in points 4 and 5 below, regular DNS resolution is expected to respond with NXDOMAIN. Therefore, if it can differentiate between DNS and P2P name resolution, application software can expect such a response, and can choose to treat other responses from resolvers and libraries as errors.

  3. Name resolution APIs and libraries SHOULD either respond to requests for .i2p names by resolving them via the I2P protocol, or respond with NXDOMAIN.

  4. Caching DNS servers SHOULD recognize .i2p names as special and SHOULD NOT attempt to look up NS records for them, or otherwise query authoritative DNS servers in an attempt to resolve .i2p names. Instead, caching DNS servers SHOULD generate immediate negative responses for all such queries.

  5. Authoritative DNS servers are not expected to treat .i2p domain requests specially. In practice, they MUST answer with NXDOMAIN, as "I2P" is not available via global DNS resolution, and not doing so MAY put users' privacy at risk (see item 6).

  6. DNS server operators SHOULD be aware that .i2p names are reserved for use with I2P, and MUST NOT override their resolution (e.g., to redirect users to another service or error information).

  7. DNS registries/registrars MUST NOT grant any request to register .i2p names. This helps avoid conflicts [SAC45]. These names are defined by the I2P protocol specification, and they fall outside the set of names available for allocation by registries/registrars.

4.4. The "BIT" Timeline System pTLD

Namecoin is a timeline-based system in the style of Bitcoin to create a global, secure, and memorable name system. It creates a single, globally accessible, append-only timeline of name registrations. Timeline-based systems rely on a peer-to-peer network to manage updates and store the timeline. In the Namecoin system, modifications to key-value mapping are attached to transactions which are committed to the timeline by "mining". Mining is the use of brute-force methods to find (partial) hash collisions with a state summary (fingerprint) representing the complete global state — including the full history — of the timeline .

"BIT" provides a name space where names are registered via transactions in the Namecoin currency [Namecoin]. Like Bitcoins, Namecoins are created using a proof-of-work calculation, which is also used to establish a decentralized, multi-party consensus on the valid transaction history, and thus the set of registered names and their values [SquareZooko].

The Namecoin used in a transaction to register a name in "BIT" is lost. This is not a fundamental problem as more coins can be generated via mining (proof-of-work calculations). The registration cost is set to decrease over time, to prevent early adopters from registering too many names.

The owner of a name can update the associated value by issuing an update, which is a transaction that uses a special coin. This coin is generated as change during the registration operation. If a name is not updated for a long time, the registration expires.

Performing a lookup for a name with Namecoin consists in checking the timeline for correctness to ensure the validity of the blockchain, and traversing it to see if it contains an entry for the desired name. Namecoin supports resolution for other peer-to-peer systems such as ".onion" and ".i2p" via specific resource records.

Like DNS registry, the Dot-Bit registry is public. But unlike DNS, the public registry is maintained by network consensus on the blockchain. It departs from DNS in three ways:

The "BIT" domain is special in the following ways:

  1. Users can use these names as they would other domain names, entering them anywhere that they would otherwise enter a conventional DNS domain name.

    From the user's perspective, the resolution of .bit names is similar to the normal DNS resolution, and thus should not affect normal usage of most Internet applications.

  2. Application software SHOULD NOT recognize .bit domains as special and SHOULD treat them as they would other domains.

    Applications MAY pass requests to the "BIT" pTLD to DNS resolvers and libraries if A/AAAA records are desired. If available, the local resolver can intercept such requests within the respective operating system hooks and return DNS-compatible results.

    Namecoin-aware applications MAY choose to talk directly to the respective P2P resolver, and use this to access additional record types that are not defined in DNS.

  3. Name resolution APIs and libraries SHOULD either respond to requests for .bit names by resolving them via the Namecoin protocol, or respond with NXDOMAIN.

  4. Caching DNS servers SHOULD recognize .bit names as special and SHOULD NOT attempt to resolve them. Instead, caching DNS servers SHOULD generate immediate negative responses for all such queries.

    Given that .bit users typically have no special privacy expectations, and those names are globally unique, local caching DNS servers MAY choose to treat them as regular domain names, and cache the responses obtained from the Namecoin blockchain. In that case however, NXDOMAIN results SHOULD NOT be cached, as new .bit domains may become active at any time.

  5. Authoritative DNS servers are not expected to treat .bit domain requests specially. In practice, they MUST answer with NXDOMAIN, as "BIT" is not available via global DNS resolution.

  6. DNS server operators SHOULD be aware that .bit names are reserved for use with Namecoin, and MUST NOT override their resolution (e.g., to redirect users to another service or error information).

  7. DNS registries/registrars MUST NOT grant any request to register .bit names. This helps avoid conflicts [SAC45]. These names are defined by the Namecoin protocol specification, and they fall outside the set of names available for allocation by registries/registrars.

5. Security Considerations

Specific software performs the resolution of the six Special-Use Domain Names presented in this document; this resolution process happens outside of the scope of DNS. Leakage of requests to such domains to the global operational DNS can cause interception of traffic that might be misused to monitor, censor, or abuse the user's trust, and lead to privacy issues with potentially tragic consequences for the user.

This document reserves these Top-Level Domain names to minimize the possibility of confusion, conflict, and especially privacy risks for users.

In the introduction of this document, there's a requirement that DNS operators do not override resolution of the P2P Names. This is a regulatory measure and cannot prevent such malicious abuse in practice. Its purpose is to limit any information leak that would result from incorrectly configured systems, and to avoid that resolvers make unnecessary contact to the DNS Root Zone for such domains. Verisign, Inc., as well as several Internet service providers (ISPs) have notoriously abused their position to override NXDOMAIN responses to their customers in the past. For example, if a DNS operator would decide to override NXDOMAIN and send advertising to leaked .onion sites, the information leak to the DNS would extend to the advertising server, with unpredictable consequences. Thus, implementors should be aware that any positive response coming from DNS must be considered with extra care, as it suggests a leak to DNS has been made, contrary to user's privacy expectations.

The reality of X.509 Certificate Authorities (CAs) creating misleading certificates for these pTLDs due to ignorance stresses the need to document their special use. X.509 Certificate Authorities MAY create certificates for "ONION", "BIT", and "ZKEY" given CSRs signed with the respective private keys corresponding to the respective names. For "BIT", the Certificate Authority SHOULD limit the expiration time of the certificate to match the registration. Certificate Authorities MUST NOT create certificates for the "EXIT", "GNU", and "I2P" Top-Level domains. Nevertheless, clients SHOULD accept certificates for these Top-Level domains as they may be created legitimately by local proxies on the fly.

[SAC57] reports, page 11, that the CA/Browser forum stated: "Also as of the Effective Date [1 July 2012], the CA SHALL NOT issue a certificate with an Expiry Date later than 1 November 2015 with a subjectAlternativeName extension or Subject commonName field containing a Reserved IP Address or Internal Server Name."

It is not clear whether e.g., .onion sites are considered "Internal Server Names", however, we can expect that services doubling their public Web site with an onion site would use a single SSL certificate for both, as did Facebook with "facebookcorewwwi.onion". Given this forum also declared the CAs would revoke such SSL certificates in October 2016, that opens a three (now two) years period of vulnerability for new gTLDs to suffer MiTM attacks over HTTPS. Such practice by CAs to validate certificates to invalid TLDs without verification may lead, e.g., to mailicious third parties without any relation to an existing .onion site to register a fake certificate for that site in order to facilitate attacks, especially when combined with name collision risk as explained in [SAC62].

Because the Namecoin system uses a timeline-based blockchain for name assignment and resolution, it grants query privacy to the users who maintain their own copy of the blockchain (Section 4.4), but the entire zone of a .bit domains is publicly available in the Namecoin blockchain, making enumeration of names within a .bit zone ("zone walking") a trivial attack to conduct. This might be a concern to some domain operators as it exposes their infrastructure to potential adversaries. That concern may be addressed in future versions of Namecoin, but the records already in the blockchain will remain there unprotected.

Finally, legacy applications that do not explicitly support the pTLDs significantly increase the risk of pTLD queries escaping to DNS, as they are entirely dependent on the correct configuration on the operating system.

6. IANA Considerations

The Internet Assigned Numbers Authority (IANA) reserved the following entries in the Special-Use Domain Names registry [RFC6761]:

[TO REMOVE: the assignement URL is https://www.iana.org/assignments/special-use-domain-names/ ]

7. Acknowledgements

The authors thank the I2P and Namecoin developers for their constructive feedback, as well as Mark Nottingham for his proof-reading and valuable feedback. The authors also thank the members of DNSOP WG for their critiques and suggestions.

8. References

8.1. Normative References

[RFC1034] Mockapetris, P., "Domain names - concepts and facilities", STD 13, RFC 1034, November 1987.
[RFC1035] Mockapetris, P., "Domain names - implementation and specification", STD 13, RFC 1035, November 1987.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC2308] Andrews, M., "Negative Caching of DNS Queries (DNS NCACHE)", RFC 2308, March 1998.
[RFC5226] Narten, T. and H. Alvestrand, "Guidelines for Writing an IANA Considerations Section in RFCs", BCP 26, RFC 5226, May 2008.
[RFC6761] Cheshire, S. and M. Krochmal, "Special-Use Domain Names", RFC 6761, February 2013.

8.2. Informative References

[Curve25519] Bernstein, D., "Curve25519: new Diffie-Hellman speed record", February 2006.
[Dingledine2004] Dingledine, R., Mathewson, N. and P. Syverson, "Tor: the second-generation onion router", 2004.
[EdDSA] Bernstein, D., Duif, N., Lange, T., Schwabe, P. and Y. Yang, "High-speed, high-security signatures", September 2011.
[I2P-CHOICE] Hacker, J. and The I2P Community, "I2P Dev Meeting 059", September 2003.
[I2P-NAMING] Hacker, J. and The I2P Community, "Naming in I2P and Addressbook", April 2014.
[Namecoin] The .bit Project, "Namecoin", 2013.
[Namecoin-DNS] The .bit Project, "Namecoin Domain Name Specification", 2015.
[RFC4648] Josefsson, S., "The Base16, Base32, and Base64 Data Encodings", RFC 4648, October 2006.
[SAC45] ICANN Security and Stability Advisory Committee, "Invalid Top Level Domain Queries at the Root Level of the Domain Name System", November 2010.
[SAC57] ICANN Security and Stability Advisory Committee, "SSAC Advisory on Internal Name Certificates", March 2013.
[SAC62] ICANN Security and Stability Advisory Committee, "SSAC Advisory Concerning the Mitigation of Name Collision Risk", November 2013.
[SquareZooko] Swartz, A., "Squaring the Triangle: Secure, Decentralized, Human-Readable Names", 2011.
[TOR-ADDRESS] Mathewson, N. and R. Dingledine, "Special Hostnames in Tor", September 2011.
[TOR-EXTSOCKS] Mathewson, N. and R. Dingledine, "Tor's extensions to the SOCKS protocol", February 2014.
[TOR-PATH] Mathewson, N. and R. Dingledine, "Tor Path Specification", November 2014.
[TOR-PROTOCOL] Dingledine, R. and N. Mathewson, "Tor Protocol Specification", August 2014.
[TOR-RENDEZVOUS] Mathewson, N. and R. Dingledine, "Tor Rendezvous Specification", April 2014.
[Wachs2014] Wachs, M., Schanzenbach, M. and C. Grothoff, "A Censorship-Resistant, Privacy-Enhancing and Fully Decentralized Name System", October 2014.
[zzz2009] The I2P Project and L. Schimmer, "Peer Profiling and Selection in the I2P Anonymous Network", January 2009.

Authors' Addresses

Christian Grothoff INRIA Équipe Décentralisée INRIA Rennes Bretagne Atlantique 263 avenue du Général Leclerc Campus Universitaire de Beaulieu Rennes, Bretagne F-35042 FR EMail: christian@grothoff.org
Matthias Wachs Technische Universität München Free Secure Network Systems Group Lehrstuhl fuer Netzarchitekturen und Netzdienste Boltzmannstrasse 3 Technische Universitaet Muenchen Garching bei Muenchen, Bayern D-85748 DE EMail: wachs@net.in.tum.de
Hellekin O. Wolf (editor) GNU consensus EMail: hellekin@gnu.org
Jacob Appelbaum Tor Project Inc. EMail: jacob@appelbaum.net
Leif Ryge Tor Project Inc. EMail: leif@synthesize.us