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<!doctype html>
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<html>
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<head>
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<meta charset=utf-8>
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<meta name=generator content="Pelican 4.8.0">
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<meta name=author content="LEdoian">
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<meta name=description content="My personal webpage">
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<meta name=referrer content=no-referrer>
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<link rel=stylesheet href="../theme/css/theme.css">
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<title>Do not forget about IPv6 DNS – LEdoian's Blog</title>
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</head>
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<body>
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<header>
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<h1>LEdoian's Blog</h1>
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</header>
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<div id=main>
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<nav>
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<div>
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<!-- Main navigation -->
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<!-- TODO! -->
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</div>
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<div>
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<h2>Categories</h2>
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<ul>
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</ul>
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<h2>Tags</h2>
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<ul>
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</ul>
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</div>
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<div>
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<h2>Stalk me also at</h2>
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TODO!
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<h2>I stalk</h2>
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TODO!
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</nav>
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<main>
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<div>
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<h1>Do not forget about IPv6 DNS</h1>
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<p>Do you think IPv6-only internet works OK? I am going to tell you that it does
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not, but it is not immediately visible. TL;DR: The internet can be broken also
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by forgetting to add AAAA records of the <em>nameservers</em>. This creates IPv4
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requirement for the resolving even when the target is reachable using IPv6.</p>
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<div class="section" id="quick-recap">
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<h2>Quick recap</h2>
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<p>Connecting to a website is easy, right? You type in the name, you get the front page.</p>
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<div class="figure">
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<object data="../images/forgetting-dns6/image1.svg" style="width: 50%;" type="image/svg+xml"></object>
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<p class="caption">This is a very naïve idea of connecting to a server.</p>
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</div>
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<p>OK, it is a bit harder: the computer needs an IP address, so we need to use
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this magic box called DNS. The flow looks something like this:</p>
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<div class="figure">
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<object data="../images/forgetting-dns6/image2.svg" style="width: 50%;" type="image/svg+xml"></object>
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<p class="caption">Slightly better, now we at least know the machine-readable address.</p>
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</div>
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<p>And for IPv6-only, everything on the picture has to have IPv6 connectivity and AAAA DNS records.</p>
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<div class="section" id="reaching-ipv4-land-from-ipv6-only">
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<h3>Reaching IPv4 land from IPv6-only</h3>
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<p>There are :s:few many sites that still only support IPv4. To reach them, we
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need someone, who can reach both the IPv4- and IPv6-land, to go there on our
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behalf – a proxy. This proxy can be ad-hoc (I often use <tt class="docutils literal">ssh <span class="pre">-D</span></tt>), or there
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are well-known protocols like NAT64 with DNS64 to do that in a standard and
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lightweight manner. <a class="footnote-reference" href="#nat44" id="footnote-reference-1">[1]</a>
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In that case, the connection looks like this:</p>
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<div class="figure">
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<object data="../images/forgetting-dns6/image3.svg" style="width: 100%;" type="image/svg+xml"></object>
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<p class="caption">And now we can reach the whole internet.</p>
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</div>
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<p>You might already know that you need some workaround like this to reach GitHub.
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What I think you didn't know, you need similar workaround to reach the Wikipedia.</p>
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<p>Disclaimer: While I am sad that GitHub lives in the past and it is stupid that
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they do not have IPv6, I do not want to shame Wikipedia in particular.
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It is just an example I found out recently. I am aware of several other
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sites suffering from the same problem, including at least one IPv6 test. <a class="footnote-reference" href="#test-aaaa" id="footnote-reference-2">[2]</a> (It would
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be nice if they added the missing piece in the puzzle, though.)</p>
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</div>
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</div>
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<div class="section" id="enter-dns">
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<h2>Enter DNS</h2>
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<p>Our picture has one unexplored magic box: the DNS. As per the definition (which
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I just made up and was not bothered to even fully formulate):</p>
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<p>> yada yada distributed database of records attached to the strings – domain
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names. The records hold various information about the domain, depending on the type.</p>
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<p>There are three interesting types of records: A records give IPv4 addresses,
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AAAA give IPv6 addresses, and NS give names of servers who know about the
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particular subtree of the database. And to actually resolve the final AAAA
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record, the (recursive) resolver starts at the <em>root zone</em> and tries to find
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the answer. <a class="footnote-reference" href="#dns-simplification" id="footnote-reference-3">[3]</a> The resolution algorithm can be visualised like this:</p>
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<div class="figure">
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<object data="../images/forgetting-dns6/image4.svg" style="width: 100%;" type="image/svg+xml"></object>
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<p class="caption">Yeah, it's a mess.</p>
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</div>
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<p>There is one extra tricky bit: the NS records contain <em>names</em>, not addresses,
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so when resolving, we need <em>two</em> queries for each layer (very simplified):
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first we ask for the final domain (<tt class="docutils literal">blog.ledoian.cz</tt>) and get a NS record
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(when the server does not have the answer) and then we need to ask for the A or
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AAAA record of the name from that record, so that we can connect to the server
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mentioned in the NS record.</p>
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<p>You might start to see the issue. When the DNS was just a black box, we could
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paint the whole picture green and call it a day. And from the regular user's
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point of view, that is the case, just use some public DNS like 1.1.1.1, 8.8.8.8
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or 9.9.9.9. Oh, right, I meant these easy-to-remember addresses:
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2606:4700:4700::1111, 2001:4860:4860::8888 and 2620:fe::fe, respectively. The
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point is, they will give you the answer, because they are dual-stack, not IPv6-only.</p>
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<p>In a way, those servers (or other dual-stack resolvers) act like another proxy,
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similar to the SSH, NAT64 and NAT44 ones mentioned earlier. This may not be
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much of a problem for many people. But if you have any reason to use your own
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recursive DNS server (privacy reasons, DNSSEC validation, ISP provides bad
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service, you are the ISP, …) <em>inside</em> an IPv6-only network, you <em>will</em> have
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issues. <a class="footnote-reference" href="#dns-behind-nat64" id="footnote-reference-4">[4]</a></p>
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</div>
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<div class="section" id="example-wikipedia">
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<h2>Example: Wikipedia</h2>
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<p>Let's now see this in action. You know Wikipedia, right? And you can reach
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Wikipedia on IPv6, right? It has an AAAA record (don't mind the CNAME, that
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means that the server is really called some other way):</p>
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<pre class="literal-block">
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$ dig en.wikipedia.org AAAA
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[…]
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en.wikipedia.org. 18737 IN CNAME dyna.wikimedia.org.
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dyna.wikimedia.org. 323 IN AAAA 2a02:ec80:600:ed1a::1
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</pre>
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<p>And this record does work:</p>
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<pre class="literal-block">
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$ ncat --ssl 2a02:ec80:600:ed1a::1 443 <<GO
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GET /wiki/Main_Page HTTP/1.1
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Host: en.wikipedia.org
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GO
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HTTP/1.1 200 OK
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[…]
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content-language: en
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content-type: text/html; charset=UTF-8
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content-length: 98078
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<!DOCTYPE html>
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[…]
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</pre>
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<p>But we can dig deeper: let's see what servers we are really asking:</p>
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<pre class="literal-block">
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$ dig en.wikipedia.org AAAA +trace
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; <<>> DiG … <<>> en.wikipedia.org AAAA +trace
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;; global options: +cmd
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. 78918 IN NS e.root-servers.net.
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. 78918 IN NS f.root-servers.net.
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. 78918 IN NS g.root-servers.net.
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. 78918 IN NS h.root-servers.net.
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. 78918 IN NS i.root-servers.net.
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. 78918 IN NS j.root-servers.net.
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. 78918 IN NS k.root-servers.net.
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. 78918 IN NS l.root-servers.net.
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. 78918 IN NS m.root-servers.net.
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. 78918 IN NS a.root-servers.net.
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. 78918 IN NS b.root-servers.net.
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. 78918 IN NS c.root-servers.net.
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. 78918 IN NS d.root-servers.net.
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;; Received 525 bytes from … in 0 ms
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org. 172800 IN NS c0.org.afilias-nst.info.
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org. 172800 IN NS a2.org.afilias-nst.info.
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org. 172800 IN NS a0.org.afilias-nst.info.
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org. 172800 IN NS b0.org.afilias-nst.org.
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org. 172800 IN NS b2.org.afilias-nst.org.
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org. 172800 IN NS d0.org.afilias-nst.org.
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;; Received 788 bytes from 202.12.27.33#53(m.root-servers.net) in 24 ms
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wikipedia.org. 3600 IN NS ns0.wikimedia.org.
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wikipedia.org. 3600 IN NS ns1.wikimedia.org.
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wikipedia.org. 3600 IN NS ns2.wikimedia.org.
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;; Received 658 bytes from 2001:500:48::1#53(b2.org.afilias-nst.org) in 20 ms
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en.wikipedia.org. 86400 IN CNAME dyna.wikimedia.org.
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;; Received 94 bytes from 208.80.153.231#53(ns1.wikimedia.org) in 132 ms
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</pre>
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<p>Hey, there are IPv4 addresses in there! I know, this is cheating, the output is
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run from a dual-stack machine. But we can still simulate IPv6-only resolution
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by adding <tt class="docutils literal"><span class="pre">-6</span></tt> flag:</p>
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<pre class="literal-block">
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$ dig en.wikipedia.org AAAA +trace -6
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; <<>> DiG … <<>> en.wikipedia.org AAAA +trace -6
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;; global options: +cmd
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. 78915 IN NS d.root-servers.net.
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. 78915 IN NS e.root-servers.net.
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. 78915 IN NS f.root-servers.net.
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. 78915 IN NS g.root-servers.net.
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. 78915 IN NS h.root-servers.net.
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. 78915 IN NS i.root-servers.net.
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. 78915 IN NS j.root-servers.net.
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. 78915 IN NS k.root-servers.net.
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. 78915 IN NS l.root-servers.net.
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. 78915 IN NS m.root-servers.net.
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. 78915 IN NS a.root-servers.net.
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. 78915 IN NS b.root-servers.net.
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. 78915 IN NS c.root-servers.net.
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;; Received 525 bytes from … in 0 ms
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org. 172800 IN NS d0.org.afilias-nst.org.
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org. 172800 IN NS c0.org.afilias-nst.info.
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org. 172800 IN NS b2.org.afilias-nst.org.
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org. 172800 IN NS a0.org.afilias-nst.info.
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org. 172800 IN NS b0.org.afilias-nst.org.
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org. 172800 IN NS a2.org.afilias-nst.info.
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;; Received 816 bytes from 2001:500:2::c#53(c.root-servers.net) in 8 ms
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wikipedia.org. 3600 IN NS ns0.wikimedia.org.
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wikipedia.org. 3600 IN NS ns1.wikimedia.org.
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wikipedia.org. 3600 IN NS ns2.wikimedia.org.
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couldn't get address for 'ns0.wikimedia.org': not found
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couldn't get address for 'ns1.wikimedia.org': not found
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couldn't get address for 'ns2.wikimedia.org': not found
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dig: couldn't get address for 'ns0.wikimedia.org': no more
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</pre>
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<p>Some of those IPv4 addresses were benign – the respective servers are reachable
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both using IPv4 and IPv6 address, or there is an alternative server that is
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reachable using IPv6. That is the case for the root nameserver – in the second
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case, we used C, which has IPv6 address (2001:500:2::c). In fact, the M server
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also has IPv6 address, but dig chose the IPv4 one (it should not matter):</p>
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<pre class="literal-block">
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$ dig m.root-servers.net AAAA
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[…]
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m.root-servers.net. 77991 IN AAAA 2001:dc3::35
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</pre>
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<p>But the latter case is the bigger issue. For the domain <tt class="docutils literal">wikipedia.org</tt> there
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are three nameservers:</p>
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<pre class="literal-block">
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$ dig wikipedia.org NS -6
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[…]
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wikipedia.org. 86400 IN NS ns0.wikimedia.org.
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wikipedia.org. 86400 IN NS ns1.wikimedia.org.
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wikipedia.org. 86400 IN NS ns2.wikimedia.org.
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</pre>
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<p>This resolution is the last one that worked in IPv6-only mode, because none of
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these three servers has AAAA record (some of them may have IPv6, which we do not learn about):</p>
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<pre class="literal-block">
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$ dig ns0.wikimedia.org AAAA
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[…]
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;; Got answer:
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;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 59468
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;; flags: qr rd ra; QUERY: 1, ANSWER: 0, AUTHORITY: 1, ADDITIONAL: 1
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</pre>
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<p>The NOERROR status says the domain name exists, but we got zero answers for
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AAAA records. This is the case for all three nameservers. And here is the
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ultimate picture of what is happening and what goes wrong.</p>
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<div class="figure">
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<object data="../images/forgetting-dns6/image5.svg" style="width: 100%;" type="image/svg+xml"></object>
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<p class="caption">The breakage in action</p>
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</div>
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<p>Also note that the connection from the laptop to the DNS resolver may in fact
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consist of a chain of several (caching, non-recursive) DNS resolvers, so that
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the final DNS resolver can have dual-stack connectivity.</p>
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</div>
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<div class="section" id="the-problems-with-this-state">
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<h2>The problems with this state</h2>
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<p>So, what is the deal. We <em>just</em> need to have a dual-stack DNS resolver
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somewhere, and that's it, no? Well, yes but actually no.</p>
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<p>There are two problems with this: First, this means that any new ISP needs to
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have <em>at least some</em> IPv4 address, even if they intend to just use IPv6
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services. IPv4 addresses are scarce, <a class="reference external" href="https://blog.apnic.net/2021/12/16/opinion-ipv4-address-markets/">expensive</a> and small
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blocks <a class="reference external" href="https://labs.ripe.net/author/stephen_strowes/visibility-of-ipv4-and-ipv6-prefix-lengths-in-2019/">don't route well</a>,
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which is not great both from the
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new ISP's and from overal routing's point of view. It also hinders IPv6
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deployment and postpones IPv4 abandonment, needlessly.</p>
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<p>The second issue is that this is not very visible. We are building IPv6 world,
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but deep inside, it still relies on IPv4, which might lead to great surprise
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when we start cutting off IPv4 internet. And it might lead to false sense of
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having IPv6 deployed, which is not true to the whole extent.</p>
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<p>Insert "It was DNS" meme here.</p>
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</div>
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<div class="section" id="solution">
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<h2>Solution</h2>
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<p>The solution of this state is simple: get IPv6 connectivity to your
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authoritative DNS server (or use another) and do not forget to add an AAAA
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record for it in DNS. If the DNS server already has IPv6, it is probably just
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adding a single line to the zone file (and a second one for the DNSSEC
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signature), which should not be a big deal.</p>
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<p>Unfortunately, this needs to be done for the whole DNS chain.
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Especially domain names at universities are infamous for very nested domains.
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A domain name may looks like
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<tt class="docutils literal"><span class="pre">machine.department.location.faculty.university.some-common.suffix</span></tt>. That
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tree is deep, and so is the resolution of this problem.</p>
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</div>
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<div class="section" id="amusing-bug-of-almost-good-deployment">
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<h2>Amusing bug of almost good deployment</h2>
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<p>We have seen there may be multiple NS records for a domain, and thus
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multiple nameservers. This is good for redundancy. But this does not mean that
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the servers will have the same records – they are only supposed to give
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equivalent answers.</p>
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<p>I have come across a silly misconfiguration: a domain which has several
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nameservers, which serve a <em>slightly</em> different set of NS records for its
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subdomain. Specifically, the servers which were only reachable using IPv4 were
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<em>exactly</em> the servers that knew about one additional nameserver for the
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subdomain, which, incidentally, was the <em>only</em> one that was IPv6-capable.</p>
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<p>So, while all the correct records were present in DNS (somewhat/somewhere), this still
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meant that IPv6-only resolution was doomed to fail, because the IPv6 nameserver
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chain was broken.</p>
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<hr class="docutils" />
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<table class="docutils footnote" frame="void" id="nat44" rules="none">
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<colgroup><col class="label" /><col /></colgroup>
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<tbody valign="top">
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<tr><td class="label"><a class="fn-backref" href="#footnote-reference-1">[1]</a></td><td>This is very much the same as when you try to reach the
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IPv4-public-land from IPv4-private-land, that is, from a private range of IP
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addresses. This is called either just NAT, or NAT44, meaning IPv4-to-IPv4 NAT.</td></tr>
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</tbody>
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</table>
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<table class="docutils footnote" frame="void" id="test-aaaa" rules="none">
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<colgroup><col class="label" /><col /></colgroup>
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<tbody valign="top">
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<tr><td class="label"><a class="fn-backref" href="#footnote-reference-2">[2]</a></td><td>There are several more tests that do not even have the AAAA
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record, lol.</td></tr>
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</tbody>
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</table>
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<table class="docutils footnote" frame="void" id="dns-simplification" rules="none">
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<colgroup><col class="label" /><col /></colgroup>
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<tbody valign="top">
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<tr><td class="label"><a class="fn-backref" href="#footnote-reference-3">[3]</a></td><td>In my example, there is a recursive DNS resolver external to my machine,
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in order not to complicate it too much. Yes, the real deployment is often
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trickier.</td></tr>
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</tbody>
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</table>
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<table class="docutils footnote" frame="void" id="dns-behind-nat64" rules="none">
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<colgroup><col class="label" /><col /></colgroup>
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<tbody valign="top">
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<tr><td class="label"><a class="fn-backref" href="#footnote-reference-4">[4]</a></td><td>I have not yet tried to run a recursive DNS in a network
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with DNS64 and NAT64. Could be fun :-D My wild guess is that I would need
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CLAT (i.e. the full 464XLAT deployment) to make that work, since the
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resolver is connecting directly to IPv4 addresses and would need to learn to
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use NAT64 to resolve them. (The CLAT could be built right into the resolver,
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though).</td></tr>
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</tbody>
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</table>
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</div>
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</div>
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</main>
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</div> <!-- #main -->
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<footer>
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<hr>
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Written using Pelican 4.8.0 by LEdoian.
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