Internet security protocols |
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Key management |
Application layer |
Domain Name System |
Internet Layer |
The Domain Name System Security Extensions (DNSSEC) is a suite of extension specifications by the Internet Engineering Task Force (IETF) for securing data exchanged in the Domain Name System (DNS) in Internet Protocol (IP) networks. The protocol provides cryptographic authentication of data, authenticated denial of existence, and data integrity, but not availability or confidentiality.
The original design of the Domain Name System did not include any security features. It was conceived only as a scalable distributed system. The Domain Name System Security Extensions (DNSSEC) attempt to add security, while maintaining backward compatibility. RFC 3833 of 2004 documents some of the known threats to the DNS, and their solutions in DNSSEC.
DNSSEC was designed to protect applications using DNS from accepting forged or manipulated DNS data, such as that created by DNS cache poisoning. All answers from DNSSEC protected zones are digitally signed. [1] By checking the digital signature, a DNS resolver is able to check if the information is identical (i.e. unmodified and complete) to the information published by the zone owner and served on an authoritative DNS server. While protecting IP addresses is the immediate concern for many users, DNSSEC can protect any data published in the DNS, including text records (TXT) and mail exchange records (MX), and can be used to bootstrap other security systems that publish references to cryptographic certificates stored in the DNS such as Certificate Records (CERT records, RFC 4398), SSH fingerprints (SSHFP, RFC 4255), IPSec public keys (IPSECKEY, RFC 4025), TLS Trust Anchors (TLSA, RFC 6698), or Encrypted Client Hello (SVCB/HTTPS records for ECH [2] [3] ).
DNSSEC does not provide confidentiality of data; in particular, all DNSSEC responses are authenticated but not encrypted. DNSSEC does not protect against DoS attacks directly, though it indirectly provides some benefit (because signature checking allows the use of potentially untrustworthy parties).[ citation needed ]
Other standards (not DNSSEC) are used to secure bulk data (such as a DNS zone transfer) sent between DNS servers. As documented in RFC 4367, some users and developers make false assumptions about DNS names, such as assuming that a company's common name plus ".com" is always its domain name. DNSSEC cannot protect against false assumptions; it can only authenticate that the data is truly from or not available from the domain owner.[ citation needed ]
The DNSSEC specifications (called DNSSEC-bis) describe the current DNSSEC protocol in great detail. See RFC 4033, RFC 4034, and RFC 4035. With the publication of these new RFCs (March 2005), an earlier RFC, RFC 2535 has become obsolete. The full set of RFCs that specify DNSSEC are collected in RFC 9364, which is also BCP 237.
It is widely believed [4] that securing the DNS is critically important for securing the Internet as a whole, but deployment of DNSSEC specifically has been hampered (As of 22 January 2010 [update] ) by several difficulties:
DNSSEC works by digitally signing records for DNS lookup using public-key cryptography. The correct DNSKEY record is authenticated via a chain of trust, starting with a set of verified public keys for the DNS root zone which is the trusted third party. Domain owners generate their own keys, and upload them using their DNS control panel at their domain-name registrar, which in turn pushes the keys via secDNS to the zone operator (e.g., Verisign for .com) who signs and publishes them in DNS.
DNS is implemented by the use of several resource records. To implement DNSSEC, several new DNS record types were created or adapted to use with DNSSEC:
When DNSSEC is used, each answer to a DNS lookup contains an RRSIG DNS record, in addition to the record type that was requested. The RRSIG record is a digital signature of the answer DNS resource record set. The digital signature is verified by locating the correct public key found in a DNSKEY record. The NSEC and NSEC3 records are used to provide cryptographic evidence of the non-existence of any Resource Record (RR). The DS record is used in the authentication of DNSKEYs in the lookup procedure using the chain of trust. NSEC and NSEC3 records are used for robust resistance against spoofing.
DNSSEC was designed to be extensible so that as attacks are discovered against existing algorithms, new ones can be introduced in a backward-compatible fashion as described in RFC 8624. The following table defines, as of June 2019, the security algorithms that are or were most often used: [5]
Algorithm field | Algorithm | Source | DNSSEC Signing | DNSSEC Validation |
---|---|---|---|---|
1 | RSA/MD5 | Must Not Implement | Must Not Implement | |
3 | DSA/SHA-1 | Must Not Implement | Must Not Implement | |
5 | RSA/SHA-1 | RFC 3110 | Not Recommended | Required |
6 | DSA-NSEC3-SHA1 | Must Not Implement | Must Not Implement | |
7 | RSASHA1-NSEC3-SHA1 | RFC 5155 | Not Recommended | Required |
8 | RSA/SHA-256 | RFC 5702 | Required | Required |
10 | RSA/SHA-512 | Not Recommended | Required | |
12 | GOST R 34.10-2001 | RFC 5933 | Must Not Implement | Optional |
13 | ECDSA P-256/SHA-256 | RFC 6605 | Required | Required |
14 | ECDSA P-384/SHA-384 | Optional | Recommended | |
15 | Ed25519 | RFC 8080 | Recommended | Recommended |
16 | Ed448 | Optional | Recommended |
Digest field | Digest | Source | DNSSEC Delegation | DNSSEC Validation |
---|---|---|---|---|
1 | SHA-1 | RFC 3658 | Must Not Implement | Required |
2 | SHA-256 | RFC 4509 | Required | Required |
3 | GOST R 34.10-2001 | RFC 5933 | Must Not Implement | Optional |
4 | SHA-384 | RFC 6605 | Optional | Recommended |
From the results of a DNS lookup, a security-aware DNS resolver can determine whether the authoritative name server for the domain being queried supports DNSSEC, whether the answer it receives is secure, and whether there is some sort of error. The lookup procedure is different for recursive name servers such as those of many ISPs, and for stub resolvers such as those included by default in mainstream operating systems. Microsoft Windows uses a stub resolver, and Windows Server 2008 R2 and Windows 7 in particular use a non-validating but DNSSEC-aware stub resolver. [6] [7]
Using the chain of trust model, a Delegation Signer (DS) record in a parent domain (DNS zone) can be used to verify a DNSKEY record in a subdomain, which can then contain other DS records to verify further subdomains. Say that a recursive resolver such as an ISP name server wants to get the IP addresses (A record and/or AAAA records) of the domain "www.example.com".
There are several exceptions to the above example.
First, if "example.com" does not support DNSSEC, there will be no RRSIG record in the answer and there will not be a DS record for "example.com" in the "com" zone. If there is a DS record for "example.com", but no RRSIG record in the reply, something is wrong and maybe a man in the middle attack is going on, stripping the DNSSEC information and modifying the A records. Or, it could be a broken security-oblivious name server along the way that stripped the DO flag bit from the query or the RRSIG record from the answer. Or, it could be a configuration error.
Next, it may be that there is not a domain name named "www.example.com", in which case instead of returning a RRSIG record in the answer, there will be either an NSEC record or an NSEC3 record. These are "next secure" records that allow the resolver to prove that a domain name does not exist. The NSEC/NSEC3 records have RRSIG records, which can be verified as above.
Finally, it may be that the "example.com" zone implements DNSSEC, but either the "com" zone or the root zone do not, creating an "island of security" which needs to be validated in some other way. As of 15 July 2010 [update] , deployment of DNSSEC to root is completed. [8] The .com domain was signed with valid security keys and the secure delegation was added to the root zone on 1 April 2011. [9]
Stub resolvers are "minimal DNS resolvers that use recursive query mode to offload most of the work of DNS resolution to a recursive name server." [10] A stub resolver will simply forward a request to a recursive name server, and use the Authenticated Data (AD) bit in the response as a "hint to find out whether the recursive name server was able to validate signatures for all of the data in the Answer and Authority sections of the response." [11] Microsoft Windows uses a stub resolver, and Windows Server 2008 R2 and Windows 7 in particular use a non-validating but AD-bit-aware stub resolver. [6] [7]
A validating stub resolver can also potentially perform its own signature validation by setting the Checking Disabled (CD) bit in its query messages. [11] A validating stub resolver uses the CD bit to perform its own recursive authentication. Using such a validating stub resolver gives the client end-to-end DNS security for domains implementing DNSSEC, even if the Internet service provider or the connection to them is not trusted.
Non-validating stub resolvers must rely on external DNSSEC validation services, such as those controlled by the user's Internet service provider or a public recursive name server, and the communication channels between itself and those name servers, using methods such as DNS over TLS. [11] [12]
To be able to prove that a DNS answer is correct, one needs to know at least one key or DS record that is correct from sources other than the DNS. These starting points are known as trust anchors and are typically obtained with the operating system or via some other trusted source. When DNSSEC was originally designed, it was thought that the only trust anchor that would be needed was for the DNS root. The root anchors were first published on 15 July 2010. [13]
An authentication chain is a series of linked DS and DNSKEY records, starting with a trust anchor to the authoritative name server for the domain in question. Without a complete authentication chain, an answer to a DNS lookup cannot be securely authenticated.
To limit replay attacks, there are not only the normal DNS TTL values for caching purposes, but additional timestamps in RRSIG records to limit the validity of a signature. Unlike TTL values which are relative to when the records were sent, the timestamps are absolute. This means that all security-aware DNS resolvers must have clocks that are fairly closely in sync, say to within a few minutes.
These timestamps imply that a zone must regularly be re-signed and re-distributed to secondary servers, or the signatures will be rejected by validating resolvers.
DNSSEC involves many different keys, stored both in DNSKEY records, and from other sources to form trust anchors.
In order to allow for replacement keys, a key rollover scheme is required. Typically, this involves first rolling out new keys in new DNSKEY records, in addition to the existing old keys. Then, when it is safe to assume that the time to live values have caused the caching of old keys to have passed, these new keys can be used. Finally, when it is safe to assume that the caching of records using the old keys have expired, the old DNSKEY records can be deleted. This process is more complicated for things such as the keys to trust anchors, such as at the root, which may require an update of the operating system.
Keys in DNSKEY records can be used for two different things and typically different DNSKEY records are used for each. First, there are key signing keys (KSK) which are used to sign other DNSKEY records containing zone signing keys (ZSK), which are used to sign other records. Since the ZSKs are under complete control and use by one particular DNS zone, they can be switched more easily and more often. As a result, ZSKs can be much shorter than KSKs and still offer the same level of protection while reducing the size of the RRSIG/DNSKEY records.
When a new KSK is created, the DS record must be transferred to the parent zone and published there. The DS records use a message digest of the KSK instead of the complete key in order to keep the size of the records small. This is helpful for zones such as the .com domain, which are very large. The procedure to update DS keys in the parent zone is also simpler than earlier DNSSEC versions that required DNSKEY records to be in the parent zone.
A closely related principle is that of Algorithm rollover, this involves migrating a zone from one signing Algorithm to another. A good example of this would be migrating from Algorithm 8 (RSA/SHA-256) to Algorithm 13 (ECDSA/SHA-256). Several ccTLD's have already migrated including .at, .br, .cz, .ch, .fr, .ie, .nl [14] and .ph. Verisign migrated .com, .net and .edu to Algorithm 13 in late 2023. [15] [16] The migration of the root domain from Algorithm 8 to Algorithm 13 is currently in planning as of early 2024. [17]
DNS-based Authentication of Named Entities (DANE) is an IETF working group [18] with the goal of developing protocols and techniques that allow Internet applications to establish cryptographically secured communications with TLS, DTLS, SMTP, and S/MIME based on DNSSEC.
The new protocols will enable additional assurances and constraints for the traditional model based on public key infrastructure. They will also enable domain holders to assert certificates for themselves, without reference to third-party certificate authorities.
Support for DNSSEC stapled certificates was enabled in Google Chrome 14, [19] but was later removed. [20] For Mozilla Firefox, support was provided by an add-on [21] while native support is currently awaiting someone to start working on it. [22]
DNS is a critical and fundamental Internet service, yet in 1990 Steve Bellovin discovered serious security flaws in it. Research into securing it began, and progressed dramatically when his paper was made public in 1995. [23] The initial RFC 2065 was published by the IETF in 1997, and initial attempts to implement that specification led to a revised (and believed fully workable) specification in 1999 as IETF RFC 2535. Plans were made to deploy DNSSEC based on RFC 2535.
Unfortunately, the IETF RFC 2535 specification had very significant problems scaling up to the full Internet; by 2001 it became clear that this specification was unusable for large networks. In normal operation DNS servers often get out of sync with their parents. This isn't usually a problem, but when DNSSEC is enabled, this out-of-sync data could have the effect of a serious self-created denial of service. The original DNSSEC required a complex six-message protocol and a lot of data transfers to perform key changes for a child (DNS child zones had to send all of their data up to the parent, have the parent sign each record, and then send those signatures back to the child for the child to store in a SIG record). Also, public key changes could have absurd effects; for example, if the ".com" zone changed its public key, it would have to send 22 million records (because it would need to update all of the signatures in all of its children). Thus, DNSSEC as defined in RFC 2535 could not scale up to the Internet.
The IETF fundamentally modified DNSSEC, which is called DNSSEC-bis when necessary to distinguish it from the original DNSSEC approach of RFC 2535. This new version uses "delegation signer (DS) resource records" to provide an additional level of indirection at delegation points between a parent and child zone. In the new approach, when a child's master public key changes, instead of having six messages for every record in the child, there is one simple message: the child sends the new public key to its parent (signed, of course). Parents simply store one master public key for each child; this is much more practical. This means that a little data is pushed to the parent, instead of massive amounts of data being exchanged between the parent and children. This does mean that clients have to do a little more work when verifying keys. More specifically, verifying a DNS zone's KEY RRset requires two signature verification operations instead of the one required by RFC 2535 (there is no impact on the number of signatures verified for other types of RRsets). Most view this as a small price to pay, since it makes DNSSEC deployment more practical. The new version is published in RFC4033-4035.
In January 2024, a "KeyTrap" denial-of-service attack was announced for all specification-respecting DNSSEC resolvers. The DNSSEC specification (RFC4033-4035) specifies that a resolver, when receiving a signed packet from the upstream, should try all keys with the correct "tag" on all signatures until one of the combinations successfully verifies. By putting many keys with the same "tag" and many signatures corresponding to that "tag" in a packet, the researchers can slow down a resolver by a factor of 2 million. In response, resolvers began to place limits on the amount of verification errors, key tag collisions, and hash calculations. [24]
Cryptographically proving the absence of a domain requires signing the response to every query for a non-existent domain. This is not a problem for online signing servers, which keep their keys available online. However, DNSSEC was designed around using offline computers to sign records so that zone-signing-keys could be kept in cold storage. This represents a problem when trying to authenticate responses to queries for non-existent domains since it is impossible to pre-generate a response to every possible hostname query.
The initial solution was to create NSEC records for every pair of domains in a zone. Thus if a client queried for a record at the non-existent k.example.com
, the server would respond with an NSEC record stating that nothing exists between a.example.com
and z.example.com
. However, this leaks more information about the zone than traditional unauthenticated NXDOMAIN errors because it exposes the existence of real domains.
The NSEC3 records (RFC 5155) were created as an alternative which hashes the name instead of listing them directly. Over time, advancements in hashing using GPUs and dedicated hardware meant that NSEC3 responses could be cheaply brute forced using offline dictionary attacks. NSEC5 has been proposed to allow authoritative servers to sign NSEC responses without having to keep a private key that can be used to modify the zone. Thus stealing an NSEC5KEY would only result in the ability to more easily enumerate a zone. [25]
Due to the messy evolution of the protocol and a desire to preserve backwards compatibility, online DNSSEC signing servers return a "white lie" instead of authenticating a denial of existence directly. The technique outlined in RFC 4470 returns a NSEC record in which the pairs of domains lexically surrounding the requested domain. For example, request for k.example.com
would thus result in an NSEC record proving that nothing exists between the (fictitious) domains j.example.com
and l.example.com
. This is also possible with NSEC3 records. [26]
CloudFlare pioneered a pair of alternative approaches, which manage to achieve the same result in one third of the response size. [27] The first is a variation on the "white lies" approach, called "black lies", which exploits common DNS client behavior to state the nonexistence more compactly. [28] The second approach instead chooses to prove that "the record exists but the requested record type does not", which they call "DNS shotgun". [29] [27]
The Internet is critical infrastructure, yet its operation depends on the fundamentally insecure DNS. Thus, there is strong incentive to secure DNS, and deploying DNSSEC is generally considered to be a critical part of that effort. For example, the U.S. National Strategy to Secure Cyberspace specifically identified the need to secure DNS. [30] Wide-scale deployment of DNSSEC could resolve many other security problems as well, such as secure key distribution for e-mail addresses.
DNSSEC deployment in large-scale networks is also challenging. Ozment and Schechter observe that DNSSEC (and other technologies) has a "bootstrap problem": users typically only deploy a technology if they receive an immediate benefit, but if a minimal level of deployment is required before any users receive a benefit greater than their costs (as is true for DNSSEC), it is difficult to deploy. DNSSEC can be deployed at any level of a DNS hierarchy, but it must be widely available in a zone before many others will want to adopt it. DNS servers must be updated with software that supports DNSSEC, and DNSSEC data must be created and added to the DNS zone data. A TCP/IP-using client must have their DNS resolver (client) updated before it can use DNSSEC's capabilities. What is more, any resolver must have, or have a way to acquire, at least one public key that it can trust before it can start using DNSSEC.
DNSSEC implementation can add significant load to some DNS servers. Common DNSSEC-signed responses are far larger than the default UDP size of 512 bytes. In theory, this can be handled through multiple IP fragments, but many "middleboxes" in the field do not handle these correctly. This leads to the use of TCP instead. Yet many current TCP implementations store a great deal of data for each TCP connection; heavily loaded servers can run out of resources simply trying to respond to a larger number of (possibly bogus) DNSSEC requests. Some protocol extensions, such as TCP Cookie Transactions, have been developed to reduce this loading. [31] To address these challenges, significant effort is ongoing to deploy DNSSEC, because the Internet is so vital to so many organizations.
Early adopters include Brazil (.br), Bulgaria (.bg), Czech Republic (.cz), Namibia (.na) [32] Puerto Rico (.pr) and Sweden (.se), who use DNSSEC for their country code top-level domains; [33] RIPE NCC, who have signed all the reverse lookup records (in-addr.arpa) that are delegated to it from the Internet Assigned Numbers Authority (IANA). [34] ARIN is also signing their reverse zones. [35] In February 2007, TDC became the first Swedish ISP to start offering this feature to its customers. [36]
IANA publicly tested a sample signed root since June 2007. During this period prior to the production signing of the root, there were also several alternative trust anchors. The IKS Jena introduced one on January 19, 2006, [37] the Internet Systems Consortium introduced another on March 27 of the same year, [38] while ICANN themselves announced a third on February 17, 2009. [39]
On June 2, 2009, Afilias, the registry service provider for Public Interest Registry's .org zone signed the .org TLD. [40] Afilias and PIR also detailed on September 26, 2008, that the first phase, involving large registrars it has a strong working relationship with ("friends and family") would be the first to be able to sign their domains, beginning "early 2009". [41] On June 23, 2010, 13 registrars were listed as offering DNSSEC records for .ORG domains. [42]
VeriSign ran a pilot project to allow .com and .net domains to register themselves for the purpose of NSEC3 experimentation. On February 24, 2009, they announced that they would deploy DNSSEC across all their top-level domains (.com, .net, etc.) within 24 months, [43] and on November 16 of the same year, they said the .com and .net domains would be signed by the first quarter of 2011, after delays caused by technical aspects of the implementation. [44] This goal was achieved on-schedule [45] and Verisign's DNSSEC VP, Matt Larson, won InfoWorld's Technology Leadership Award for 2011 for his role in advancing DNSSEC. [46] [47]
DNSSEC was first deployed at the root level on July 15, 2010. [48] This is expected to greatly simplify the deployment of DNSSEC resolvers, since the root trust anchor can be used to validate any DNSSEC zone that has a complete chain of trust from the root. Since the chain of trust must be traced back to a trusted root without interruption in order to validate, trust anchors must still be configured for secure zones if any of the zones above them are not secure. For example, if the zone "signed.example.org" was secured but the "example.org" zone was not, then, even though the ".org" zone and the root are signed, a trust anchor has to be deployed in order to validate the zone.
Political issues surrounding signing the root have been a continuous concern, primarily about some central issues:
In September 2008, ICANN and VeriSign each published implementation proposals [49] and in October, the National Telecommunications and Information Administration (NTIA) asked the public for comments. [50] It is unclear if the comments received affected the design of the final deployment plan.
On June 3, 2009, the National Institute of Standards and Technology (NIST) announced plans to sign the root by the end of 2009, in conjunction with ICANN, VeriSign and the NTIA. [51]
On October 6, 2009, at the 59th RIPE Conference meeting, ICANN and VeriSign announced the planned deployment timeline for deploying DNSSEC within the root zone. [52] At the meeting it was announced that it would be incrementally deployed to one root name server a month, starting on December 1, 2009, with the final root name server serving a DNSSEC signed zone on July 1, 2010, and the root zone will be signed with a RSA/SHA256 DNSKEY. [52] During the incremental roll-out period the root zone will serve a Deliberately Unvalidatable Root Zone (DURZ) that uses dummy keys, with the final DNSKEY record not being distributed until July 1, 2010. [53] This means the keys that were used to sign the zone use are deliberately unverifiable; the reason for this deployment was to monitor changes in traffic patterns caused by the larger responses to queries requesting DNSSEC resource records.
The .org top-level domain was signed with DNSSEC in June 2010, followed by .com, .net, and .edu later in 2010 and 2011. [54] [55] Country code top-level domains were able to deposit keys starting in May 2010. [56] As of November 2011 [update] more than 25% of top-level domains are signed with DNSSEC. [57]
On January 25, 2010, the L (ell) root server began serving a Deliberately Unvalidatable Root Zone (DURZ). The zone uses signatures of a SHA-2 (SHA-256) hash created using the RSA algorithm, as defined in RFC 5702. As of May 2010, all thirteen root servers began serving the DURZ. [53] On July 15, 2010, the first root full production DNSSEC root zone was signed, with the SOA serial 2010071501. Root trust anchors are available from IANA. [48]
Underneath the root there is a large set of top-level domains that must be signed in order to achieve full DNSSEC deployment. The List of Internet top-level domains provides details about which of the existing top-level domains have been signed and linked to the root.
In March 2006, the Internet Systems Consortium introduced the DNSSEC Lookaside Validation registry. [58] DLV was intended to make DNSSEC easier to deploy in the absence of a root trust anchor. At the time it was imagined that a validator might have to maintain large numbers of trust anchors corresponding to signed subtrees of the DNS. [59] The purpose of DLV was to allow validators to offload the effort of managing a trust anchor repository to a trusted third party. The DLV registry maintained a central list of trust anchors, instead of each validator repeating the work of maintaining its own list.
To use DLV, a validator that supports it was needed, such as BIND or Unbound, configured with a trust anchor for a DLV zone. This zone contained DLV records; [60] these had exactly the same format as DS records, but instead of referring to a delegated sub-zone, they referred to a zone elsewhere in the DNS tree. When the validator could not find a chain of trust from the root to the RRset it is trying to check, it searched for a DLV record that could provide an alternative chain of trust. [61]
Gaps in the chain of trust, such as unsigned top-level domains or registrars that did not support DNSSEC delegations, meant administrators of lower-level domains could use DLV to allow their DNS data to be validated by resolvers which had been configured to use DLV. This may have hindered DNSSEC deployment by taking pressure off registrars and TLD registries to properly support DNSSEC. DLV also added complexity by adding more actors and code paths for DNSSEC validation.
ISC decommissioned its DLV registry in 2017. [62] DLV support was deprecated in BIND 9.12 and completely removed from BIND 9.16. [63] Unbound version 1.5.4 (July 2015) marked DLV as decommissioned in the example configuration and manual page. [64] Knot Resolver and PowerDNS Recursor never implemented DLV.
In March 2020, the IETF published RFC 8749, retiring DLV as a standard and moving RFC 4432 and RFC 5074 to "Historic" status. [65]
The Science and Technology Directorate of the U.S. Department of Homeland Security (DHS) sponsors the "DNSSEC Deployment Initiative". This initiative encourages "all sectors to voluntarily adopt security measures that will improve security of the Internet's naming infrastructure, as part of a global, cooperative effort that involves many nations and organizations in the public and private sectors." DHS also funds efforts to mature DNSSEC and get it deployed inside the U.S. federal government.
It was reported [66] that on March 30, 2007, the U.S. Department of Homeland Security proposed "to have the key to sign the DNS root zone solidly in the hands of the US government." However no U.S. Government officials were present in the meeting room and the comment that sparked the article was made by another party. DHS later commented [67] [68] on why they believe others jumped to the false conclusion that the U.S. Government had made such a proposal: "The U.S. Department of Homeland Security is funding the development of a technical plan for implementing DNSSec, and last October distributed an initial draft of it to a long list of international experts for comments. The draft lays out a series of options for who could be the holder, or "operator," of the Root Zone Key, essentially boiling down to a governmental agency or a contractor. "Nowhere in the document do we make any proposal about the identity of the Root Key Operator," said Maughan, the cyber-security research and development manager for Homeland Security."
This section needs to be updated.(November 2015) |
The National Institute of Standards and Technology (NIST) published NIST Special Publication 800-81 Secure Domain Name System (DNS) Deployment Guide on May 16, 2006, with guidance on how to deploy DNSSEC. NIST intended to release new DNSSEC Federal Information Security Management Act (FISMA) requirements in NIST SP800-53-R1, referencing this deployment guide. U.S. agencies would then have had one year after final publication of NIST SP800-53-R1 to meet these new FISMA requirements. [69] However, at the time NSEC3 had not been completed. NIST had suggested using split domains, a technique that is known to be possible but is difficult to deploy correctly, and has the security weaknesses noted above.
On 22 August 2008, the Office of Management and Budget (OMB) released a memorandum requiring U.S. Federal Agencies to deploy DNSSEC across .gov sites; the .gov root must be signed by January 2009, and all subdomains under .gov must be signed by December 2009. [70] While the memo focuses on .gov sites, the U.S. Defense Information Systems Agency says it intends to meet OMB DNSSEC requirements in the .mil (U.S. military) domain as well. NetworkWorld's Carolyn Duffy Marsan stated that DNSSEC "hasn't been widely deployed because it suffers from a classic chicken-and-egg dilemma... with the OMB mandate, it appears the egg is cracking." [71]
Several ISPs have started to deploy DNSSEC-validating DNS recursive resolvers. Comcast became the first major ISP to do so in the United States, announcing their intentions on October 18, 2010 [72] [73] and completing deployment on January 11, 2012. [74]
According to a study at APNIC, the proportion of clients who exclusively use DNS resolvers that perform DNSSEC validation rose to 8.3% in May 2013. [75] About half of these clients were using Google's public DNS resolver.
In September 2015, Verisign announced their free public DNS resolver service, [76] and although unmentioned in their press releases, it also performs DNSSEC validation.
By the beginning of 2016, APNIC's monitoring showed the proportion of clients who exclusively use DNS resolvers that perform DNSSEC validation had increased to about 15%. [77]
Google's public recursive DNS server enabled DNSSEC validation on May 6, 2013. [78]
BIND, the most popular DNS management software, enables DNSSEC support by default since version 9.5.
The Quad9 public recursive DNS has performed DNSSEC validation on its main 9.9.9.9 address since it was established on May 11, 2016. Quad9 also provides an alternate service which does not perform DNSSEC validation, principally for debugging. [79]
In September 2023, Microsoft announced it would utilize DNSSEC (via DANE) to verify the authenticity of certificates during SMTP communications. [80]
Geoff Hutson has argued that DNSSEC deployment should be given up. [81]
DNSSEC deployment requires software on the server and client side. Some of the tools that support DNSSEC include:
The Domain Name System (DNS) is a hierarchical and distributed name service that provides a naming system for computers, services, and other resources on the Internet or other Internet Protocol (IP) networks. It associates various information with domain names assigned to each of the associated entities. Most prominently, it translates readily memorized domain names to the numerical IP addresses needed for locating and identifying computer services and devices with the underlying network protocols. The Domain Name System has been an essential component of the functionality of the Internet since 1985.
In cryptography, a public key certificate, also known as a digital certificate or identity certificate, is an electronic document used to prove the validity of a public key. The certificate includes the public key and information about it, information about the identity of its owner, and the digital signature of an entity that has verified the certificate's contents. If the device examining the certificate trusts the issuer and finds the signature to be a valid signature of that issuer, then it can use the included public key to communicate securely with the certificate's subject. In email encryption, code signing, and e-signature systems, a certificate's subject is typically a person or organization. However, in Transport Layer Security (TLS) a certificate's subject is typically a computer or other device, though TLS certificates may identify organizations or individuals in addition to their core role in identifying devices. TLS, sometimes called by its older name Secure Sockets Layer (SSL), is notable for being a part of HTTPS, a protocol for securely browsing the web.
The DNS root zone is the top-level DNS zone in the hierarchical namespace of the Domain Name System (DNS) of the Internet.
In cryptography, X.509 is an International Telecommunication Union (ITU) standard defining the format of public key certificates. X.509 certificates are used in many Internet protocols, including TLS/SSL, which is the basis for HTTPS, the secure protocol for browsing the web. They are also used in offline applications, like electronic signatures.
In cryptography, a certificate authority or certification authority (CA) is an entity that stores, signs, and issues digital certificates. A digital certificate certifies the ownership of a public key by the named subject of the certificate. This allows others to rely upon signatures or on assertions made about the private key that corresponds to the certified public key. A CA acts as a trusted third party—trusted both by the subject (owner) of the certificate and by the party relying upon the certificate. The format of these certificates is specified by the X.509 or EMV standard.
Verisign, Inc. is an American company based in Reston, Virginia, that operates a diverse array of network infrastructure, including two of the Internet's thirteen root nameservers, the authoritative registry for the .com, .net, and .name generic top-level domains and the .cc country-code top-level domains, and the back-end systems for the .jobs and .edu sponsored top-level domains.
A Canonical Name (CNAME) record is a type of resource record in the Domain Name System (DNS) that maps one domain name to another.
DNS spoofing, also referred to as DNS cache poisoning, is a form of computer security hacking in which corrupt Domain Name System data is introduced into the DNS resolver's cache, causing the name server to return an incorrect result record, e.g. an IP address. This results in traffic being diverted to any computer that the attacker chooses.
A hardware security module (HSM) is a physical computing device that safeguards and manages secrets, performs encryption and decryption functions for digital signatures, strong authentication and other cryptographic functions. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server. A hardware security module contains one or more secure cryptoprocessor chips.
This article presents a comparison of the features, platform support, and packaging of many independent implementations of Domain Name System (DNS) name server software.
TSIG is a computer-networking protocol defined in RFC 2845. Primarily it enables the Domain Name System (DNS) to authenticate updates to a DNS database. It is most commonly used to update Dynamic DNS or a secondary/slave DNS server. TSIG uses shared secret keys and one-way hashing to provide a cryptographically secure means of authenticating each endpoint of a connection as being allowed to make or respond to a DNS update.
Unbound is a validating, recursive, and caching DNS resolver product from NLnet Labs. It is distributed free of charge in open-source form under the BSD license.
DNSCurve is a proposed secure protocol for the Domain Name System (DNS), designed by Daniel J. Bernstein. It encrypts and authenticates DNS packets between resolvers and authoritative servers.
Google Public DNS is a Domain Name System (DNS) service offered to Internet users worldwide by Google. It functions as a recursive name server. Google Public DNS was announced on December 3, 2009, in an effort described as "making the web faster and more secure." As of 2018, it is the largest public DNS service in the world, handling over a trillion queries per day. Google Public DNS is not related to Google Cloud DNS, which is a DNS hosting service.
OpenDNSSEC is a computer program that manages the security of domain names on the Internet. The project intends to drive adoption of Domain Name System Security Extensions (DNSSEC) to further enhance Internet security.
Knot DNS is an open-source authoritative-only server for the Domain Name System. It was created from scratch and is actively developed by CZ.NIC, the .CZ domain registry. The purpose of this project is to supply an alternative open-source implementation of an authoritative DNS server suitable for TLD operators to increase overall security, stability and resiliency of the Domain Name System. It is implemented as a multi-threaded daemon, using a number of programming techniques and data structures to make the server very fast, notably Read-copy-update or a special kind of a radix tree.
DNS-based Authentication of Named Entities (DANE) is an Internet security protocol to allow X.509 digital certificates, commonly used for Transport Layer Security (TLS), to be bound to domain names using Domain Name System Security Extensions (DNSSEC).
A public recursive name server is a name server service that networked computers may use to query the Domain Name System (DNS), the decentralized Internet naming system, in place of name servers operated by the local Internet service provider (ISP) to which the devices are connected. Reasons for using these services include:
The Windows DNS client is a stub resolver...
The DNS client in Windows Server 2008 R2 and Windows® 7 is a non-validating security-aware stub resolver.
Stub resolvers, by definition, are minimal DNS resolvers that use recursive query mode to offload most of the work of DNS resolution to a recursive name server.An earlier definition was given in an earlier RFC: Robert Braden (October 1989). Braden, R. (ed.). RFC 1123 - Requirements for Internet Hosts -- Application and Support. IETF (Internet Engineering Task Force). p. 74. doi:10.17487/RFC1123.
A "stub resolver" relies on the services of a recursive name server [...]