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+.. Copyright (C) Internet Systems Consortium, Inc. ("ISC")
+..
+.. SPDX-License-Identifier: MPL-2.0
+..
+.. This Source Code Form is subject to the terms of the Mozilla Public
+.. License, v. 2.0. If a copy of the MPL was not distributed with this
+.. file, you can obtain one at https://mozilla.org/MPL/2.0/.
+..
+.. See the COPYRIGHT file distributed with this work for additional
+.. information regarding copyright ownership.
+
+.. _dnssec_advanced_discussions:
+
+Advanced Discussions
+--------------------
+
+.. _signature_validity_periods:
+
+Signature Validity Periods and Zone Re-Signing Intervals
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+In :ref:`how_are_answers_verified`, we saw that record signatures
+have a validity period outside of which they are not valid. This means
+that at some point, a signature will no longer be valid and a query for
+the associated record will fail DNSSEC validation. But how long should a
+signature be valid for?
+
+The maximum value for the validity period should be determined by the impact of a
+replay attack: if this is low, the period can be long; if high,
+the period should be shorter. There is no "right" value, but periods of
+between a few days to a month are common.
+
+Deciding a minimum value is probably an easier task. Should something
+fail (e.g., a hidden primary distributing to secondary servers that
+actually answer queries), how long will it take before the failure is
+noticed, and how long before it is fixed? If you are a large 24x7
+operation with operators always on-site, the answer might be less than
+an hour. In smaller companies, if the failure occurs
+just after everyone has gone home for a long weekend, the answer might
+be several days.
+
+Again, there are no "right" values - they depend on your circumstances. The
+signature validity period you decide to use should be a value between
+the two bounds. At the time of this writing (mid-2020), the default policy used by BIND
+sets a value of 14 days.
+
+To keep the zone valid, the signatures must be periodically refreshed
+since they expire - i.e., the zone must be periodically
+re-signed. The frequency of the re-signing depends on your network's
+individual needs. For example, signing puts a load on your server, so if
+the server is very highly loaded, a lower re-signing frequency is better. Another
+consideration is the signature lifetime: obviously the intervals between
+signings must not be longer than the signature validity period. But if
+you have set a signature lifetime close to the minimum (see above), the
+signing interval must be much shorter. What would happen if the system
+failed just before the zone was re-signed?
+
+Again, there is no single "right" answer; it depends on your circumstances. The
+BIND 9 default policy sets the signature refresh interval to 5 days.
+
+.. _advanced_discussions_proof_of_nonexistence:
+
+Proof of Non-Existence (NSEC and NSEC3)
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+How do you prove that something does not exist? This zen-like question
+is an interesting one, and in this section we provide an overview
+of how DNSSEC solves the problem.
+
+Why is it even important to have authenticated denial of existence in DNS?
+Couldn't we just send back "hey, what you asked for does not exist,"
+and somehow generate a digital signature to go with it, proving it
+really is from the correct authoritative source? Aside from the technical
+challenge of signing something that doesn't exist, this solution has flaws, one of
+which is it gives an attacker a way to create the appearance of denial
+of service by replaying this message on the network.
+
+Let's use a little story, told three different ways, to
+illustrate how proof of nonexistence works. In our story, we run a small
+company with three employees: Alice, Edward, and Susan. For reasons that
+are far too complicated to go into, they don't have email accounts;
+instead, email for them is sent to a single account and a nameless
+intern passes the message to them. The intern has access to our private
+DNSSEC key to create signatures for their responses.
+
+If we followed the approach of giving back the same answer no matter
+what was asked, when people emailed and asked for the message to be
+passed to "Bob," our intern would simply answer "Sorry, that person
+doesn’t work here" and sign this message. This answer could be validated
+because our intern signed the response with our private DNSSEC key.
+However, since the signature doesn’t change, an attacker could record
+this message. If the attacker were able to intercept our email, when the next
+person emailed asking for the message to be passed to Susan, the attacker
+could return the exact same message: "Sorry, that person doesn’t work
+here," with the same signature. Now the attacker has successfully fooled
+the sender into thinking that Susan doesn’t work at our company, and
+might even be able to convince all senders that no one works at this
+company.
+
+To solve this problem, two different solutions were created. We will
+look at the first one, NSEC, next.
+
+.. _advanced_discussions_nsec:
+.. _NSEC:
+
+NSEC
+^^^^
+
+The NSEC record is used to prove that something does not exist, by
+providing the name before it and the name after it. Using our tiny
+company example, this would be analogous to someone sending an email for
+Bob and our nameless intern responding with with: "I'm sorry, that
+person doesn't work here. The name before the location where 'Bob'
+would be is Alice, and the name after that is Edward." Let's say
+another email was received for a
+non-existent person, this time Oliver; our intern would respond "I'm
+sorry, that person doesn't work here. The name before the location
+where 'Oliver' would be is Edward,
+and the name after that is Susan." If another sender asked for Todd, the
+answer would be: "I'm sorry, that person doesn't work here. The name
+before the location where 'Todd' would be is Susan, and there are no
+other names after that."
+
+So we end up with four NSEC records:
+
+::
+
+ example.com. 300 IN NSEC alice.example.com. A RRSIG NSEC
+ alice.example.com. 300 IN NSEC edward.example.com. A RRSIG NSEC
+ edward.example.com. 300 IN NSEC susan.example.com. A RRSIG NSEC
+ susan.example.com. 300 IN NSEC example.com. A RRSIG NSEC
+
+What if the attacker tried to use the same replay method described
+earlier? If someone sent an email for Edward, none of the four answers
+would fit. If attacker replied with message #2, "I'm sorry, that person
+doesn't work here. The name before it is Alice, and the name after it is
+Edward," it is obviously false, since "Edward" is in the response; and the same
+goes for #3, Edward and Susan. As for #1 and #4, Edward does not fall in
+the alphabetical range before Alice or after Susan, so the sender can logically deduce
+that it was an incorrect answer.
+
+When BIND signs your zone, the zone data is automatically sorted on
+the fly before generating NSEC records, much like how a phone directory
+is sorted.
+
+The NSEC record allows for a proof of non-existence for record types. If
+you ask a signed zone for a name that exists but for a record type that
+doesn't (for that name), the signed NSEC record returned lists all of
+the record types that *do* exist for the requested domain name.
+
+NSEC records can also be used to show whether a record was generated as
+the result of a wildcard expansion. The details of this are not
+within the scope of this document, but are described well in
+:rfc:`7129`.
+
+Unfortunately, the NSEC solution has a few drawbacks, one of which is
+trivial "zone walking." In our story, a curious person can keep sending emails, and
+our nameless, gullible intern keeps divulging information about our
+employees. Imagine if the sender first asked: "Is Bob there?" and
+received back the names Alice and Edward. Our sender could then email
+again: "Is Edwarda there?", and will get back Edward and Susan. (No,
+"Edwarda" is not a real name. However, it is the first name
+alphabetically after "Edward" and that is enough to get the intern to reply
+with a message telling us the next valid name after Edward.) Repeat the
+process enough times and the person sending the emails eventually
+learns every name in our company phone directory. For many of you, this
+may not be a problem, since the very idea of DNS is similar to a public
+phone book: if you don't want a name to be known publicly, don't put it
+in DNS! Consider using DNS views (split DNS) and only display your
+sensitive names to a select audience.
+
+The second potential drawback of NSEC is a bigger zone file and memory consumption;
+there is no opt-out mechanism for insecure child zones, so each name
+in the zone will get an additional NSEC record and a RRSIG record to go with
+it. In practice this is a problem only for parent-zone operators dealing with
+mostly insecure child zones, such as ``com.``. To learn more about opt-out,
+please see :ref:`advanced_discussions_nsec3_optout`.
+
+.. _advanced_discussions_nsec3:
+.. _nsec3:
+
+NSEC3
+^^^^^
+
+NSEC3 adds two additional features that NSEC does not have:
+
+1. It offers no easy zone enumeration.
+
+2. It provides a mechanism for the parent zone to exclude insecure
+ delegations (i.e., delegations to zones that are not signed) from the
+ proof of non-existence.
+
+Recall that in :ref:`advanced_discussions_nsec` we provided a range of
+names to prove that something does not exist. But as it turns
+out, even disclosing these ranges of names becomes a problem: this made
+it very easy for the curious-minded to look at our entire zone. Not
+only that, unlike a zone transfer, this "zone walking" is more
+resource-intensive. So how do we disclose something without actually disclosing
+it?
+
+The answer is actually quite simple: hashing functions, or one-way
+hashes. Without going into many details, think of it like a magical meat
+grinder. A juicy piece of ribeye steak goes in one end, and out comes a
+predictable shape and size of ground meat (hash) with a somewhat unique
+pattern. No matter how hard you try, you cannot turn the ground meat
+back into the ribeye steak: that's what we call a one-way hash.
+
+NSEC3 basically runs the names through a one-way hash before giving them
+out, so the recipients can verify the non-existence without any
+knowledge of the other names in the zone.
+
+So let's tell our little story for the third time, this
+time with NSEC3. In this version, our intern is not given a list of actual
+names; he is given a list of "hashed" names. So instead of Alice,
+Edward, and Susan, the list he is given reads like this (hashes
+shortened for easier reading):
+
+::
+
+ FSK5.... (produced from Edward)
+ JKMA.... (produced from Susan)
+ NTQ0.... (produced from Alice)
+
+Then, an email is received for Bob again. Our intern takes the name Bob
+through a hash function, and the result is L8J2..., so he replies: "I'm
+sorry, that person doesn't work here. The name before that is JKMA...,
+and the name after that is NTQ0...". There, we proved Bob doesn't exist,
+without giving away any names! To put that into proper NSEC3 resource
+records, they would look like this (again, hashes shortened for
+ease of display):
+
+::
+
+ FSK5....example.com. 300 IN NSEC3 1 0 0 - JKMA... A RRSIG
+ JKMA....example.com. 300 IN NSEC3 1 0 0 - NTQ0... A RRSIG
+ NTQ0....example.com. 300 IN NSEC3 1 0 0 - FSK5... A RRSIG
+
+.. note::
+
+ Just because we employed one-way hash functions does not mean there is
+ no way for a determined individual to figure out our zone data.
+
+Most names published in the DNS are rarely secret or unpredictable. They are
+published to be memorable, used and consumed by humans. They are often recorded
+in many other network logs such as email logs, certificate transparency logs,
+web page links, intrusion detection systems, malware scanners, email archives,
+etc. Many times a simple dictionary of commonly used domain-name prefixes
+(www, mail, imap, login, database, etc.) can be used to quickly reveal a large
+number of labels within a zone. Additionally, if an adversary really wants to
+expend significant CPU resources to mount an offline dictionary attack on a
+zone's NSEC3 chain, they will likely be able to find most of the "guessable"
+names despite any level of hashing.
+
+Also, it is still possible to gather all of our NSEC3 records and hashed
+names and perform an offline brute-force attack by trying all
+possible combinations to figure out what the original name is. In our
+meat-grinder analogy, this would be like someone
+buying all available cuts of meat and grinding them up at home using
+the same model of meat grinder, and comparing the output with the meat
+you gave him. It is expensive and time-consuming (especially with
+real meat), but like everything else in cryptography, if someone has
+enough resources and time, nothing is truly private forever. If you
+are concerned about someone performing this type of attack on your
+zone data, use some of the special techniques described in :rfc:`4470`.
+
+.. _advanced_discussions_nsec3param:
+
+NSEC3PARAM
+++++++++++
+
+.. warning::
+ Before we dive into the details of NSEC3 parametrization, please note:
+ the defaults should not be changed without a strong justification and a full
+ understanding of the potential impact.
+
+The above NSEC3 examples used four parameters: 1, 0, 0, and
+zero-length salt. 1 represents the algorithm, 0 represents the opt-out
+flag, 0 represents the number of additional iterations, and - is the
+salt. Let's look at how each one can be configured:
+
+.. glossary::
+
+ Algorithm
+ NSEC3 Hashing Algorithm
+ The only currently defined value is 1 for SHA-1, so there
+ is no configuration field for it.
+
+ Opt-out
+ Setting this bit to 1 enables NSEC3 opt-out, which is
+ discussed in :ref:`advanced_discussions_nsec3_optout`.
+
+ Iterations
+ Iterations defines the number of _additional_ times to
+ apply the algorithm when generating an NSEC3 hash. More iterations
+ consume more resources for both authoritative servers and validating
+ resolvers. The considerations here are similar to those seen in
+ :ref:`key_sizes`, of security versus resources.
+
+ .. warning::
+ Do not use values higher than zero. A value of zero provides one round
+ of SHA-1 hashing and protects from non-determined attackers.
+
+ A greater number of additional iterations causes interoperability problems
+ and opens servers to CPU-exhausting DoS attacks, while providing
+ only doubtful security benefits.
+
+ Salt
+ A salt value, which can be combined with an FQDN to influence the
+ resulting hash. Salt is discussed in more detail in
+ :ref:`advanced_discussions_nsec3_salt`.
+
+.. _advanced_discussions_nsec3_optout:
+
+NSEC3 Opt-Out
++++++++++++++
+
+First things first: For most DNS administrators who do not manage a huge number
+of insecure delegations, the NSEC3 opt-out featuere is not relevant.
+
+Opt-out allows for blocks of unsigned delegations to be covered by a single NSEC3
+record. In other words, use of the opt-out allows large registries to only sign as
+many NSEC3 records as there are signed DS or other RRsets in the zone; with
+opt-out, unsigned delegations do not require additional NSEC3 records. This
+sacrifices the tamper-resistance proof of non-existence offered by NSEC3 in
+order to reduce memory and CPU overheads, and decreases the effectiveness of the cache
+(:rfc:`8198`).
+
+Why would that ever be desirable? If a significant number of delegations
+are not yet securely delegated, meaning they lack DS records and are still
+insecure or unsigned, generating DNSSEC records for all their NS records
+might consume lots of memory and is not strictly required by the child zones.
+
+This resource-saving typically makes a difference only for *huge* zones like ``com.``.
+Imagine that you are the operator of busy top-level domains such as ``com.``,
+with millions of insecure delegated domain names.
+As of mid-2022, around 3% of all ``com.`` zones are signed. Basically,
+without opt-out, with 1,000,000 delegations, only 30,000 of which are secure, you
+still have to generate NSEC RRsets for the other 970,000 delegations; with
+NSEC3 opt-out, you will have saved yourself 970,000 sets of records.
+
+In contrast, for a small zone the difference is operationally negligible
+and the drawbacks outweigh the benefits.
+
+If NSEC3 opt-out is truly essential for a zone, the following
+configuration can be added to ``dnssec-policy``; for example, to create an
+NSEC3 chain using the SHA-1 hash algorithm, with the opt-out flag,
+no additional iterations, and no extra salt, use:
+
+.. code-block:: none
+
+ dnssec-policy "nsec3" {
+ ...
+ nsec3param iterations 0 optout yes salt-length 0;
+ };
+
+
+
+To learn more about how to configure NSEC3 opt-out, please see
+:ref:`recipes_nsec3_optout`.
+
+.. _advanced_discussions_nsec3_salt:
+
+NSEC3 Salt
+++++++++++
+
+.. warning::
+ Contrary to popular belief, adding salt provides little value.
+ Each DNS zone is always uniquely salted using the zone name. **Operators should
+ use a zero-length salt value.**
+
+The properties of this extra salt are complicated and beyond scope of this
+document. For detailed description why the salt in the context of DNSSEC
+provides little value please see `IETF draft ietf-dnsop-nsec3-guidance version
+10 section 2.4
+<https://datatracker.ietf.org/doc/html/draft-ietf-dnsop-nsec3-guidance-10#section-2.4>`__.
+
+.. _advanced_discussions_nsec_or_nsec3:
+
+NSEC or NSEC3?
+^^^^^^^^^^^^^^
+
+So which is better: NSEC or NSEC3? There is no single right
+answer here that fits everyone; it comes down to a given network's needs or
+requirements.
+
+In most cases, NSEC is a good choice for zone administrators. It
+relieves the authoritative servers and resolver of the additional cryptographic
+operations that NSEC3 requires, and NSEC is comparatively easier to
+troubleshoot than NSEC3.
+
+NSEC3 comes with many drawbacks and should be implemented only if zone
+enumeration prevention is really needed, or when opt-out provides a
+significant reduction in memory and CPU overheads (in other words, with a
+huge zone with mostly insecure delegations).
+
+.. _advanced_discussions_key_generation:
+
+DNSSEC Keys
+~~~~~~~~~~~
+
+Types of Keys
+^^^^^^^^^^^^^
+
+Although DNSSEC
+documentation talks about three types of keys, they are all the same
+thing - but they have different roles. The roles are:
+
+Zone-Signing Key (ZSK)
+ This is the key used to sign the zone. It signs all records in the
+ zone apart from the DNSSEC key-related RRsets: DNSKEY, CDS, and
+ CDNSKEY.
+
+Key-Signing Key (KSK)
+ This is the key used to sign the DNSSEC key-related RRsets and is the
+ key used to link the parent and child zones. The parent zone stores a
+ digest of the KSK. When a resolver verifies the chain of trust it
+ checks to see that the DS record in the parent (which holds the
+ digest of a key) matches a key in the DNSKEY RRset, and that it is
+ able to use that key to verify the DNSKEY RRset. If it can do
+ that, the resolver knows that it can trust the DNSKEY resource
+ records, and so can use one of them to validate the other records in
+ the zone.
+
+Combined Signing Key (CSK)
+ A CSK combines the functionality of a ZSK and a KSK. Instead of
+ having one key for signing the zone and one for linking the parent
+ and child zones, a CSK is a single key that serves both roles.
+
+It is important to realize the terms ZSK, KSK, and CSK describe how the
+keys are used - all these keys are represented by DNSKEY records. The
+following examples are the DNSKEY records from a zone signed with a KSK
+and ZSK:
+
+::
+
+ $ dig @192.168.1.12 example.com DNSKEY
+
+ ; <<>> DiG 9.16.0 <<>> @192.168.1.12 example.com dnskey +multiline
+ ; (1 server found)
+ ;; global options: +cmd
+ ;; Got answer:
+ ;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 54989
+ ;; flags: qr aa rd; QUERY: 1, ANSWER: 2, AUTHORITY: 0, ADDITIONAL: 1
+ ;; WARNING: recursion requested but not available
+
+ ;; OPT PSEUDOSECTION:
+ ; EDNS: version: 0, flags:; udp: 4096
+ ; COOKIE: 5258d7ed09db0d76010000005ea1cc8c672d8db27a464e37 (good)
+ ;; QUESTION SECTION:
+ ;example.com. IN DNSKEY
+
+ ;; ANSWER SECTION:
+ example.com. 60 IN DNSKEY 256 3 13 (
+ tAeXLtIQ3aVDqqS/1UVRt9AE6/nzfoAuaT1Vy4dYl2CK
+ pLNcUJxME1Z//pnGXY+HqDU7Gr5HkJY8V0W3r5fzlw==
+ ) ; ZSK; alg = ECDSAP256SHA256 ; key id = 63722
+ example.com. 60 IN DNSKEY 257 3 13 (
+ cxkNegsgubBPXSra5ug2P8rWy63B8jTnS4n0IYSsD9eW
+ VhiyQDmdgevKUhfG3SE1wbLChjJc2FAbvSZ1qk03Nw==
+ ) ; KSK; alg = ECDSAP256SHA256 ; key id = 42933
+
+... and a zone signed with just a CSK:
+
+::
+
+ $ dig @192.168.1.13 example.com DNSKEY
+
+ ; <<>> DiG 9.16.0 <<>> @192.168.1.13 example.com dnskey +multiline
+ ; (1 server found)
+ ;; global options: +cmd
+ ;; Got answer:
+ ;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 22628
+ ;; flags: qr aa rd; QUERY: 1, ANSWER: 1, AUTHORITY: 0, ADDITIONAL: 1
+ ;; WARNING: recursion requested but not available
+
+ ;; OPT PSEUDOSECTION:
+ ; EDNS: version: 0, flags:; udp: 4096
+ ; COOKIE: bf19ee914b5df46e010000005ea1cd02b66c06885d274647 (good)
+ ;; QUESTION SECTION:
+ ;example.com. IN DNSKEY
+
+ ;; ANSWER SECTION:
+ example.com. 60 IN DNSKEY 257 3 13 (
+ p0XM6AJ68qid2vtOdyGaeH1jnrdk2GhZeVvGzXfP/PNa
+ 71wGtzR6jdUrTbXo5Z1W5QeeJF4dls4lh4z7DByF5Q==
+ ) ; KSK; alg = ECDSAP256SHA256 ; key id = 1231
+
+The only visible difference between the records (apart from the key data
+itself) is the value of the flags fields; this is 256
+for a ZSK and 257 for a KSK or CSK. Even then, the flags field is only a
+hint to the software using it as to the role of the key: zones can be
+signed by any key. The fact that a CSK and KSK both have the same flags
+emphasizes this. A KSK usually only signs the DNSSEC key-related RRsets
+in a zone, whereas a CSK is used to sign all records in the zone.
+
+The original idea of separating the function of the key into a KSK and
+ZSK was operational. With a single key, changing it for any reason is
+"expensive," as it requires interaction with the parent zone
+(e.g., uploading the key to the parent may require manual interaction
+with the organization running that zone). By splitting it, interaction
+with the parent is required only if the KSK is changed; the ZSK can be
+changed as often as required without involving the parent.
+
+The split also allows the keys to be of different lengths. So the ZSK,
+which is used to sign the record in the zone, can be of a (relatively)
+short length, lowering the load on the server. The KSK, which is used
+only infrequently, can be of a much longer length. The relatively
+infrequent use also allows the private part of the key to be stored in a
+way that is more secure but that may require more overhead to access, e.g., on
+an HSM (see :ref:`hardware_security_modules`).
+
+In the early days of DNSSEC, the idea of splitting the key went more or
+less unchallenged. However, with the advent of more powerful computers
+and the introduction of signaling methods between the parent and child
+zones (see :ref:`cds_cdnskey`), the advantages of a ZSK/KSK split are
+less clear and, for many zones, a single key is all that is required.
+
+As with many questions related to the choice of DNSSEC policy, the
+decision on which is "best" is not clear and depends on your circumstances.
+
+Which Algorithm?
+^^^^^^^^^^^^^^^^
+
+There are three algorithm choices for DNSSEC as of this writing
+(mid-2020):
+
+- RSA
+
+- Elliptic Curve DSA (ECDSA)
+
+- Edwards Curve Digital Security Algorithm (EdDSA)
+
+All are supported in BIND 9, but only RSA and ECDSA (specifically
+RSASHA256 and ECDSAP256SHA256) are mandatory to implement in DNSSEC.
+However, RSA is a little long in the tooth, and ECDSA/EdDSA are emerging
+as the next new cryptographic standards. In fact, the US federal
+government recommended discontinuing RSA use altogether by September 2015
+and migrating to using ECDSA or similar algorithms.
+
+For now, use ECDSAP256SHA256 but keep abreast of developments in this
+area. For details about rolling over DNSKEYs to a new algorithm, see
+:ref:`advanced_discussions_DNSKEY_algorithm_rollovers`.
+
+.. _key_sizes:
+
+Key Sizes
+^^^^^^^^^
+
+If using RSA keys, the choice of key sizes is a classic issue of finding
+the balance between performance and security. The larger the key size,
+the longer it takes for an attacker to crack the key; but larger keys
+also mean more resources are needed both when generating signatures
+(authoritative servers) and verifying signatures (recursive servers).
+
+Of the two sets of keys, ZSK is used much more frequently. ZSK is used whenever zone
+data changes or when signatures expire, so performance
+certainly is of a bigger concern. As for KSK, it is used less
+frequently, so performance is less of a factor, but its impact is bigger
+because of its role in signing other keys.
+
+In earlier versions of this guide, the following key lengths were
+chosen for each set, with the recommendation that they be rotated more
+frequently for better security:
+
+- *ZSK*: RSA 1024 bits, rollover every year
+
+- *KSK*: RSA 2048 bits, rollover every five years
+
+These should be considered minimum RSA key sizes. At the time
+of this writing (mid-2020), the root zone and many TLDs are already using 2048
+bit ZSKs. If you choose to implement larger key sizes, keep in mind that
+larger key sizes result in larger DNS responses, which this may mean more
+load on network resources. Depending on your network configuration, end users
+may even experience resolution failures due to the increased response
+sizes, as discussed in :ref:`whats_edns0_all_about`.
+
+ECDSA key sizes can be much smaller for the same level of security, e.g.,
+an ECDSA key length of 224 bits provides the same level of security as a
+2048-bit RSA key. Currently BIND 9 sets a key size of 256 for all ECDSA keys.
+
+.. _advanced_discussions_key_storage:
+
+Key Storage
+^^^^^^^^^^^
+
+Public Key Storage
+++++++++++++++++++
+
+The beauty of a public key cryptography system is that the public key
+portion can and should be distributed to as many people as possible. As
+the administrator, you may want to keep the public keys on an easily
+accessible file system for operational ease, but there is no need to
+securely store them, since both ZSK and KSK public keys are published in
+the zone data as DNSKEY resource records.
+
+Additionally, a hash of the KSK public key is also uploaded to the
+parent zone (see :ref:`working_with_parent_zone` for more details),
+and is published by the parent zone as DS records.
+
+Private Key Storage
++++++++++++++++++++
+
+Ideally, private keys should be stored offline, in secure devices such
+as a smart card. Operationally, however, this creates certain
+challenges, since the private key is needed to create RRSIG resource
+records, and it is a hassle to bring the private key out of
+storage every time the zone file changes or signatures expire.
+
+A common approach to strike the balance between security and
+practicality is to have two sets of keys: a ZSK set and a KSK set. A ZSK
+private key is used to sign zone data, and can be kept online for ease
+of use, while a KSK private key is used to sign just the DNSKEY (the ZSK); it is
+used less frequently, and can be stored in a much more secure and
+restricted fashion.
+
+For example, a KSK private key stored on a USB flash drive that is kept
+in a fireproof safe, only brought online once a year to sign a new pair
+of ZSKs, combined with a ZSK private key stored on the network
+file system and available for routine use, may be a good balance between
+operational flexibility and security.
+
+For more information on changing keys, please see
+:ref:`key_rollovers`.
+
+.. _hardware_security_modules:
+
+Hardware Security Modules (HSMs)
+++++++++++++++++++++++++++++++++
+
+A Hardware Security Module (HSM) may come in different shapes and sizes,
+but as the name indicates, it is a physical device or devices, usually
+with some or all of the following features:
+
+- Tamper-resistant key storage
+
+- Strong random-number generation
+
+- Hardware for faster cryptographic operations
+
+Most organizations do not incorporate HSMs into their security practices
+due to cost and the added operational complexity.
+
+BIND supports Public Key Cryptography Standard #11 (PKCS #11) for
+communication with HSMs and other cryptographic support devices. For
+more information on how to configure BIND to work with an HSM, please
+refer to the `BIND 9 Administrator Reference
+Manual <https://bind9.readthedocs.io/en/latest/index.html>`_.
+
+.. _advanced_discussions_key_management:
+
+Rollovers
+~~~~~~~~~
+
+.. _key_rollovers:
+
+Key Rollovers
+^^^^^^^^^^^^^
+
+A key rollover is where one key in a zone is replaced by a new one.
+There are arguments for and against regularly rolling keys. In essence
+these are:
+
+Pros:
+
+1. Regularly changing the key hinders attempts at determination of the
+ private part of the key by cryptanalysis of signatures.
+
+2. It gives administrators practice at changing a key; should a key ever need to be
+ changed in an emergency, they would not be doing it for the first time.
+
+Cons:
+
+1. A lot of effort is required to hack a key, and there are probably
+ easier ways of obtaining it, e.g., by breaking into the systems on
+ which it is stored.
+
+2. Rolling the key adds complexity to the system and introduces the
+ possibility of error. We are more likely to
+ have an interruption to our service than if we had not rolled it.
+
+Whether and when to roll the key is up to you. How serious would the
+damage be if a key were compromised without you knowing about it? How
+serious would a key roll failure be?
+
+Before going any further, it is worth noting that if you sign your zone
+with either of the fully automatic methods (described in ref:`signing_alternative_ways`),
+you don't really need to
+concern yourself with the details of a key rollover: BIND 9 takes care of
+it all for you. If you are doing a manual key roll or are setting up the
+keys for a semi-automatic key rollover, you do need to familiarize yourself
+with the various steps involved and the timing details.
+
+Rolling a key is not as simple as replacing the DNSKEY statement in the
+zone. That is an essential part of it, but timing is everything. For
+example, suppose that we run the ``example.com`` zone and that a friend
+queries for the AAAA record of ``www.example.com``. As part of the
+resolution process (described in
+:ref:`how_does_dnssec_change_dns_lookup`), their recursive server
+looks up the keys for the ``example.com`` zone and uses them to verify
+the signature associated with the AAAA record. We'll assume that the
+records validated successfully, so they can use the
+address to visit ``example.com``'s website.
+
+Let's also assume that immediately after the lookup, we want to roll the ZSK
+for ``example.com``. Our first attempt at this is to remove the old
+DNSKEY record and signatures, add a new DNSKEY record, and re-sign the
+zone with it. So one minute our server is serving the old DNSKEY and
+records signed with the old key, and the next minute it is serving the
+new key and records signed with it. We've achieved our goal - we are
+serving a zone signed with the new keys; to check this is really the
+case, we booted up our laptop and looked up the AAAA record
+``ftp.example.com``. The lookup succeeded so all must be well. Or is it?
+Just to be sure, we called our friend and asked them to check. They
+tried to lookup ``ftp.example.com`` but got a SERVFAIL response from
+their recursive server. What's going on?
+
+The answer, in a word, is "caching." When our friend looked up
+``www.example.com``, their recursive server retrieved and cached
+not only the AAAA record, but also a lot of other records. It cached
+the NS records for ``com`` and ``example.com``, as well as
+the AAAA (and A) records for those name servers (and this action may, in turn, have
+caused the lookup and caching of other NS and AAAA/A records). Most
+importantly for this example, it also looked up and cached the DNSKEY
+records for the root, ``com``, and ``example.com`` zones. When a query
+was made for ``ftp.example.com``, the recursive server believed it
+already had most of the information
+we needed. It knew what nameservers served ``example.com`` and their
+addresses, so it went directly to one of those to get the AAAA record for
+``ftp.example.com`` and its associated signature. But when it tried to
+validate the signature, it used the cached copy of the DNSKEY, and that
+is when our friend had the problem. Their recursive server had a copy of
+the old DNSKEY in its cache, but the AAAA record for ``ftp.example.com``
+was signed with the new key. So, not surprisingly, the signature could not
+validate.
+
+How should we roll the keys for ``example.com``? A clue to the
+answer is to note that the problem came about because the DNSKEY records
+were cached by the recursive server. What would have happened had our
+friend flushed the DNSKEY records from the recursive server's cache before
+making the query? That would have worked; those records would have been
+retrieved from ``example.com``'s nameservers at the same time that we
+retrieved the AAAA record for ``ftp.example.com``. Our friend's server would have
+obtained the new key along with the AAAA record and associated signature
+created with the new key, and all would have been well.
+
+As it is obviously impossible for us to notify all recursive server
+operators to flush our DNSKEY records every time we roll a key, we must
+use another solution. That solution is to wait
+for the recursive servers to remove old records from caches when they
+reach their TTL. How exactly we do this depends on whether we are trying
+to roll a ZSK, a KSK, or a CSK.
+
+.. _zsk_rollover_methods:
+
+ZSK Rollover Methods
+++++++++++++++++++++
+
+The ZSK can be rolled in one of the following two ways:
+
+1. *Pre-Publication*: Publish the new ZSK into zone data before it is
+ actually used. Wait at least one TTL interval, so the world's recursive servers
+ know about both keys, then stop using the old key and generate a new
+ RRSIG using the new key. Wait at least another TTL, so the cached old
+ key data is expunged from the world's recursive servers, and then remove
+ the old key.
+
+ The benefit of the pre-publication approach is it does not
+ dramatically increase the zone size; however, the duration of the rollover
+ is longer. If insufficient time has passed after the new ZSK is
+ published, some resolvers may only have the old ZSK cached when the
+ new RRSIG records are published, and validation may fail. This is the
+ method described in :ref:`recipes_zsk_rollover`.
+
+2. *Double-Signature*: Publish the new ZSK and new RRSIG, essentially
+ doubling the size of the zone. Wait at least one TTL interval, and then remove
+ the old ZSK and old RRSIG.
+
+ The benefit of the double-signature approach is that it is easier to
+ understand and execute, but it causes a significantly increased zone size
+ during a rollover event.
+
+.. _ksk_rollover_methods:
+
+KSK Rollover Methods
+++++++++++++++++++++
+
+Rolling the KSK requires interaction with the parent zone, so
+operationally this may be more complex than rolling ZSKs. There are
+three methods of rolling the KSK:
+
+1. *Double-KSK*: Add the new KSK to the DNSKEY RRset, which is then
+ signed with both the old and new keys. After waiting for the old RRset
+ to expire from caches, change the DS record in the parent zone.
+ After waiting a further TTL interval for this change to be reflected in
+ caches, remove the old key from the RRset.
+
+ Basically, the new KSK is added first at the child zone and
+ used to sign the DNSKEY; then the DS record is changed, followed by the
+ removal of the old KSK. Double-KSK keeps the interaction with the
+ parent zone to a minimum, but for the duration of the rollover, the
+ size of the DNSKEY RRset is increased.
+
+2. *Double-DS*: Publish the new DS record. After waiting for this
+ change to propagate into caches, change the KSK. After a further TTL
+ interval during which the old DNSKEY RRset expires from caches, remove the
+ old DS record.
+
+ Double-DS is the reverse of Double-KSK: the new DS is published at
+ the parent first, then the KSK at the child is updated, then
+ the old DS at the parent is removed. The benefit is that the size of the DNSKEY
+ RRset is kept to a minimum, but interactions with the parent zone are
+ increased to two events. This is the method described in
+ :ref:`recipes_ksk_rollover`.
+
+3. *Double-RRset*: Add the new KSK to the DNSKEY RRset, which is
+ then signed with both the old and new key, and add the new DS record
+ to the parent zone. After waiting a suitable interval for the
+ old DS and DNSKEY RRsets to expire from caches, remove the old DNSKEY and
+ old DS record.
+
+ Double-RRset is the fastest way to roll the KSK (i.e., it has the shortest rollover
+ time), but has the drawbacks of both of the other methods: a larger
+ DNSKEY RRset and two interactions with the parent.
+
+.. _csk_rollover_methods:
+
+CSK Rollover Methods
+++++++++++++++++++++
+
+Rolling the CSK is more complex than rolling either the ZSK or KSK, as
+the timing constraints relating to both the parent zone and the caching
+of records by downstream recursive servers must be taken into
+account. There are numerous possible methods that are a combination of ZSK
+rollover and KSK rollover methods. BIND 9 automatic signing uses a
+combination of ZSK Pre-Publication and Double-KSK rollover.
+
+.. _advanced_discussions_emergency_rollovers:
+
+Emergency Key Rollovers
+^^^^^^^^^^^^^^^^^^^^^^^
+
+Keys are generally rolled on a regular schedule - if you choose
+to roll them at all. But sometimes, you may have to rollover keys
+out-of-schedule due to a security incident. The aim of an emergency
+rollover is to re-sign the zone with a new key as soon as possible, because
+when a key is suspected of being compromised, a malicious attacker (or
+anyone who has access to the key) could impersonate your server and trick other
+validating resolvers into believing that they are receiving authentic,
+validated answers.
+
+During an emergency rollover, follow the same operational
+procedures described in :ref:`recipes_rollovers`, with the added
+task of reducing the TTL of the current active (potentially compromised) DNSKEY
+RRset, in an attempt to phase out the compromised key faster before the new
+key takes effect. The time frame should be significantly reduced from
+the 30-days-apart example, since you probably do not want to wait up to
+60 days for the compromised key to be removed from your zone.
+
+Another method is to carry a spare key with you at all times. If
+you have a second key pre-published and that one
+is not compromised at the same time as the first key,
+you could save yourself some time by immediately
+activating the spare key if the active
+key is compromised. With pre-publication, all validating resolvers should already
+have this spare key cached, thus saving you some time.
+
+With a KSK emergency rollover, you also need to consider factors
+related to your parent zone, such as how quickly they can remove the old
+DS records and publish the new ones.
+
+As with many other facets of DNSSEC, there are multiple aspects to take into
+account when it comes to emergency key rollovers. For more in-depth
+considerations, please check out :rfc:`7583`.
+
+.. _advanced_discussions_DNSKEY_algorithm_rollovers:
+
+Algorithm Rollovers
+^^^^^^^^^^^^^^^^^^^
+
+From time to time, new digital signature algorithms with improved
+security are introduced, and it may be desirable for administrators to
+roll over DNSKEYs to a new algorithm, e.g., from RSASHA1 (algorithm 5 or
+7) to RSASHA256 (algorithm 8). The algorithm rollover steps must be followed with
+care to avoid breaking DNSSEC validation.
+
+If you are managing DNSSEC by using the ``dnssec-policy`` configuration,
+``named`` handles the rollover for you. Simply change the algorithm
+for the relevant keys, and ``named`` uses the new algorithm when the
+key is next rolled. It performs a smooth transition to the new
+algorithm, ensuring that the zone remains valid throughout rollover.
+
+If you are using other methods to sign the zone, the administrator needs to do more work. As
+with other key rollovers, when the zone is a primary zone, an algorithm
+rollover can be accomplished using dynamic updates or automatic key
+rollovers. For secondary zones, only automatic key rollovers are
+possible, but the ``dnssec-settime`` utility can be used to control the
+timing.
+
+In any case, the first step is to put DNSKEYs in place using the new algorithm.
+You must generate the ``K*`` files for the new algorithm and put
+them in the zone's key directory, where ``named`` can access them. Take
+care to set appropriate ownership and permissions on the keys. If the
+``auto-dnssec`` zone option is set to ``maintain``, ``named``
+automatically signs the zone with the new keys, based on their timing
+metadata when the ``dnssec-loadkeys-interval`` elapses or when you issue the
+``rndc loadkeys`` command. Otherwise, for primary zones, you can use
+``nsupdate`` to add the new DNSKEYs to the zone; this causes ``named``
+to use them to sign the zone. For secondary zones, e.g., on a
+"bump in the wire" signing server, ``nsupdate`` cannot be used.
+
+Once the zone has been signed by the new DNSKEYs (and you have waited
+for at least one TTL period), you must inform the parent zone and any trust
+anchor repositories of the new KSKs, e.g., you might place DS records in
+the parent zone through your DNS registrar's website.
+
+Before starting to remove the old algorithm from a zone, you must allow
+the maximum TTL on its DS records in the parent zone to expire. This
+assures that any subsequent queries retrieve the new DS records
+for the new algorithm. After the TTL has expired, you can remove the DS
+records for the old algorithm from the parent zone and any trust anchor
+repositories. You must then allow another maximum TTL interval to elapse
+so that the old DS records disappear from all resolver caches.
+
+The next step is to remove the DNSKEYs using the old algorithm from your
+zone. Again this can be accomplished using ``nsupdate`` to delete the
+old DNSKEYs (for primary zones only) or by automatic key rollover when
+``auto-dnssec`` is set to ``maintain``. You can cause the automatic key
+rollover to take place immediately by using the ``dnssec-settime``
+utility to set the *Delete* date on all keys to any time in the past.
+(See the ``dnssec-settime -D <date/offset>`` option.)
+
+After adjusting the timing metadata, the ``rndc loadkeys`` command
+causes ``named`` to remove the DNSKEYs and
+RRSIGs for the old algorithm from the zone. Note also that with the
+``nsupdate`` method, removing the DNSKEYs also causes ``named`` to
+remove the associated RRSIGs automatically.
+
+Once you have verified that the old DNSKEYs and RRSIGs have been removed
+from the zone, the final (optional) step is to remove the key files for
+the old algorithm from the key directory.
+
+Other Topics
+~~~~~~~~~~~~
+
+DNSSEC and Dynamic Updates
+^^^^^^^^^^^^^^^^^^^^^^^^^^
+
+Dynamic DNS (DDNS) is actually independent of DNSSEC. DDNS provides a
+mechanism, separate from editing the zone file or zone database, to edit DNS
+data. Most DNS clients and servers are able to handle dynamic
+updates, and DDNS can also be integrated as part of your DHCP
+environment.
+
+When you have both DNSSEC and dynamic updates in your environment,
+updating zone data works the same way as with traditional (insecure)
+DNS: you can use ``rndc freeze`` before editing the zone file, and
+``rndc thaw`` when you have finished editing, or you can use the
+command ``nsupdate`` to add, edit, or remove records like this:
+
+::
+
+ $ nsupdate
+ > server 192.168.1.13
+ > update add xyz.example.com. 300 IN A 1.1.1.1
+ > send
+ > quit
+
+The examples provided in this guide make ``named`` automatically
+re-sign the zone whenever its content has changed. If you decide to sign
+your own zone file manually, you need to remember to execute the
+``dnssec-signzone`` command whenever your zone file has been updated.
+
+As far as system resources and performance are concerned, be mindful that
+with a DNSSEC zone that changes frequently, every time the zone
+changes your system is executing a series of cryptographic operations
+to (re)generate signatures and NSEC or NSEC3 records.
+
+.. _dnssec_on_private_networks:
+
+DNSSEC on Private Networks
+^^^^^^^^^^^^^^^^^^^^^^^^^^
+
+Let's clarify what we mean: in this section, "private networks" really refers to
+a private or internal DNS view. Most DNS products offer the ability to
+have different versions of DNS answers, depending on the origin of the
+query. This feature is often called "DNS views" or "split DNS," and is most
+commonly implemented as an "internal" versus an "external" setup.
+
+For instance, your organization may have a version of ``example.com``
+that is offered to the world, and its names most likely resolve to
+publicly reachable IP addresses. You may also have an internal version
+of ``example.com`` that is only accessible when you are on the company's
+private networks or via a VPN connection. These private networks typically
+fall under 10.0.0.0/8, 172.16.0.0/12, or 192.168.0.0/16 for IPv4.
+
+So what if you want to offer DNSSEC for your internal version of
+``example.com``? This can be done: the golden rule is to use the same
+key for both the internal and external versions of the zones. This
+avoids problems that can occur when machines (e.g., laptops) move
+between accessing the internal and external zones, when it is possible
+that they may have cached records from the wrong zone.
+
+.. _introduction_to_dane:
+
+Introduction to DANE
+^^^^^^^^^^^^^^^^^^^^
+
+With your DNS infrastructure secured with DNSSEC, information can
+now be stored in DNS and its integrity and authenticity can be proved.
+One of the new features that takes advantage of this is the DNS-Based
+Authentication of Named Entities, or DANE. This improves security in a
+number of ways, including:
+
+- The ability to store self-signed X.509 certificates and bypass having to pay a third
+ party (such as a Certificate Authority) to sign the certificates
+ (:rfc:`6698`).
+
+- Improved security for clients connecting to mail servers (:rfc:`7672`).
+
+- A secure way of getting public PGP keys (:rfc:`7929`).
+
+Disadvantages of DNSSEC
+~~~~~~~~~~~~~~~~~~~~~~~
+
+DNSSEC, like many things in this world, is not without its problems.
+Below are a few challenges and disadvantages that DNSSEC faces.
+
+1. *Increased, well, everything*: With DNSSEC, signed zones are larger,
+ thus taking up more disk space; for DNSSEC-aware servers, the
+ additional cryptographic computation usually results in increased
+ system load; and the network packets are bigger, possibly putting
+ more strains on the network infrastructure.
+
+2. *Different security considerations*: DNSSEC addresses many security
+ concerns, most notably cache poisoning. But at the same time, it may
+ introduce a set of different security considerations, such as
+ amplification attack and zone enumeration through NSEC. These
+ concerns are still being identified and addressed by the Internet
+ community.
+
+3. *More complexity*: If you have read this far, you have probably already
+ concluded this yourself. With additional resource records, keys,
+ signatures, and rotations, DNSSEC adds many more moving pieces on top of
+ the existing DNS machine. The job of the DNS administrator changes,
+ as DNS becomes the new secure repository of everything from spam
+ avoidance to encryption keys, and the amount of work involved to
+ troubleshoot a DNS-related issue becomes more challenging.
+
+4. *Increased fragility*: The increased complexity means more
+ opportunities for things to go wrong. Before DNSSEC, DNS
+ was essentially "add something to the zone and forget it." With DNSSEC,
+ each new component - re-signing, key rollover, interaction with
+ parent zone, key management - adds more opportunity for error. It is
+ entirely possible that a failure to validate a name may come down to
+ errors on the part of one or more zone operators rather than the
+ result of a deliberate attack on the DNS.
+
+5. *New maintenance tasks*: Even if your new secure DNS infrastructure
+ runs without any hiccups or security breaches, it still requires
+ regular attention, from re-signing to key rollovers. While most of
+ these can be automated, some of the tasks, such as KSK rollover,
+ remain manual for the time being.
+
+6. *Not enough people are using it today*: While it's estimated (as of
+ mid-2020) that roughly 30% of the global Internet DNS traffic is
+ validating [#]_ , that doesn't mean that many of the DNS zones are
+ actually signed. What this means is, even if your company's zone is
+ signed today, fewer than 30% of the Internet's servers are taking
+ advantage of this extra security. It gets worse: with less than 1.5%
+ of the ``com.`` domains signed, even if your DNSSEC validation is enabled today,
+ it's not likely to buy you or your users a whole lot more protection
+ until these popular domain names decide to sign their zones.
+
+The last point may have more impact than you realize. Consider this:
+HTTP and HTTPS make up the majority of traffic on the Internet. While you may have
+secured your DNS infrastructure through DNSSEC, if your web hosting is
+outsourced to a third party that does not yet support DNSSEC in its
+own domain, or if your web page loads contents and components from
+insecure domains, end users may experience validation problems when
+trying to access your web page. For example, although you may have signed
+the zone ``company.com``, the web address ``www.company.com`` may actually be a
+CNAME to ``foo.random-cloud-provider.com``. As long as
+``random-cloud-provider.com`` remains an insecure DNS zone, users cannot
+fully validate everything when they visit your web page and could be
+redirected elsewhere by a cache poisoning attack.
+
+.. [#]
+ Based on APNIC statistics at
+ `<https://stats.labs.apnic.net/dnssec/XA>`__