forked from Shiloh/githaven
293 lines
10 KiB
Go
Vendored
293 lines
10 KiB
Go
Vendored
/*
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Package dns implements a full featured interface to the Domain Name System.
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Both server- and client-side programming is supported. The package allows
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complete control over what is sent out to the DNS. The API follows the
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less-is-more principle, by presenting a small, clean interface.
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It supports (asynchronous) querying/replying, incoming/outgoing zone transfers,
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TSIG, EDNS0, dynamic updates, notifies and DNSSEC validation/signing.
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Note that domain names MUST be fully qualified before sending them, unqualified
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names in a message will result in a packing failure.
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Resource records are native types. They are not stored in wire format. Basic
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usage pattern for creating a new resource record:
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r := new(dns.MX)
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r.Hdr = dns.RR_Header{Name: "miek.nl.", Rrtype: dns.TypeMX, Class: dns.ClassINET, Ttl: 3600}
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r.Preference = 10
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r.Mx = "mx.miek.nl."
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Or directly from a string:
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mx, err := dns.NewRR("miek.nl. 3600 IN MX 10 mx.miek.nl.")
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Or when the default origin (.) and TTL (3600) and class (IN) suit you:
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mx, err := dns.NewRR("miek.nl MX 10 mx.miek.nl")
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Or even:
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mx, err := dns.NewRR("$ORIGIN nl.\nmiek 1H IN MX 10 mx.miek")
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In the DNS messages are exchanged, these messages contain resource records
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(sets). Use pattern for creating a message:
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m := new(dns.Msg)
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m.SetQuestion("miek.nl.", dns.TypeMX)
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Or when not certain if the domain name is fully qualified:
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m.SetQuestion(dns.Fqdn("miek.nl"), dns.TypeMX)
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The message m is now a message with the question section set to ask the MX
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records for the miek.nl. zone.
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The following is slightly more verbose, but more flexible:
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m1 := new(dns.Msg)
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m1.Id = dns.Id()
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m1.RecursionDesired = true
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m1.Question = make([]dns.Question, 1)
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m1.Question[0] = dns.Question{"miek.nl.", dns.TypeMX, dns.ClassINET}
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After creating a message it can be sent. Basic use pattern for synchronous
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querying the DNS at a server configured on 127.0.0.1 and port 53:
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c := new(dns.Client)
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in, rtt, err := c.Exchange(m1, "127.0.0.1:53")
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Suppressing multiple outstanding queries (with the same question, type and
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class) is as easy as setting:
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c.SingleInflight = true
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More advanced options are available using a net.Dialer and the corresponding API.
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For example it is possible to set a timeout, or to specify a source IP address
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and port to use for the connection:
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c := new(dns.Client)
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laddr := net.UDPAddr{
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IP: net.ParseIP("[::1]"),
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Port: 12345,
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Zone: "",
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}
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c.Dialer := &net.Dialer{
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Timeout: 200 * time.Millisecond,
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LocalAddr: &laddr,
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}
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in, rtt, err := c.Exchange(m1, "8.8.8.8:53")
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If these "advanced" features are not needed, a simple UDP query can be sent,
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with:
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in, err := dns.Exchange(m1, "127.0.0.1:53")
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When this functions returns you will get DNS message. A DNS message consists
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out of four sections.
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The question section: in.Question, the answer section: in.Answer,
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the authority section: in.Ns and the additional section: in.Extra.
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Each of these sections (except the Question section) contain a []RR. Basic
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use pattern for accessing the rdata of a TXT RR as the first RR in
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the Answer section:
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if t, ok := in.Answer[0].(*dns.TXT); ok {
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// do something with t.Txt
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}
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Domain Name and TXT Character String Representations
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Both domain names and TXT character strings are converted to presentation form
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both when unpacked and when converted to strings.
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For TXT character strings, tabs, carriage returns and line feeds will be
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converted to \t, \r and \n respectively. Back slashes and quotations marks will
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be escaped. Bytes below 32 and above 127 will be converted to \DDD form.
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For domain names, in addition to the above rules brackets, periods, spaces,
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semicolons and the at symbol are escaped.
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DNSSEC
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DNSSEC (DNS Security Extension) adds a layer of security to the DNS. It uses
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public key cryptography to sign resource records. The public keys are stored in
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DNSKEY records and the signatures in RRSIG records.
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Requesting DNSSEC information for a zone is done by adding the DO (DNSSEC OK)
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bit to a request.
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m := new(dns.Msg)
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m.SetEdns0(4096, true)
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Signature generation, signature verification and key generation are all supported.
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DYNAMIC UPDATES
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Dynamic updates reuses the DNS message format, but renames three of the
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sections. Question is Zone, Answer is Prerequisite, Authority is Update, only
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the Additional is not renamed. See RFC 2136 for the gory details.
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You can set a rather complex set of rules for the existence of absence of
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certain resource records or names in a zone to specify if resource records
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should be added or removed. The table from RFC 2136 supplemented with the Go
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DNS function shows which functions exist to specify the prerequisites.
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3.2.4 - Table Of Metavalues Used In Prerequisite Section
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CLASS TYPE RDATA Meaning Function
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--------------------------------------------------------------
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ANY ANY empty Name is in use dns.NameUsed
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ANY rrset empty RRset exists (value indep) dns.RRsetUsed
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NONE ANY empty Name is not in use dns.NameNotUsed
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NONE rrset empty RRset does not exist dns.RRsetNotUsed
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zone rrset rr RRset exists (value dep) dns.Used
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The prerequisite section can also be left empty. If you have decided on the
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prerequisites you can tell what RRs should be added or deleted. The next table
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shows the options you have and what functions to call.
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3.4.2.6 - Table Of Metavalues Used In Update Section
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CLASS TYPE RDATA Meaning Function
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---------------------------------------------------------------
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ANY ANY empty Delete all RRsets from name dns.RemoveName
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ANY rrset empty Delete an RRset dns.RemoveRRset
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NONE rrset rr Delete an RR from RRset dns.Remove
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zone rrset rr Add to an RRset dns.Insert
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TRANSACTION SIGNATURE
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An TSIG or transaction signature adds a HMAC TSIG record to each message sent.
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The supported algorithms include: HmacMD5, HmacSHA1, HmacSHA256 and HmacSHA512.
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Basic use pattern when querying with a TSIG name "axfr." (note that these key names
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must be fully qualified - as they are domain names) and the base64 secret
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"so6ZGir4GPAqINNh9U5c3A==":
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If an incoming message contains a TSIG record it MUST be the last record in
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the additional section (RFC2845 3.2). This means that you should make the
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call to SetTsig last, right before executing the query. If you make any
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changes to the RRset after calling SetTsig() the signature will be incorrect.
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c := new(dns.Client)
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c.TsigSecret = map[string]string{"axfr.": "so6ZGir4GPAqINNh9U5c3A=="}
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m := new(dns.Msg)
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m.SetQuestion("miek.nl.", dns.TypeMX)
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m.SetTsig("axfr.", dns.HmacMD5, 300, time.Now().Unix())
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...
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// When sending the TSIG RR is calculated and filled in before sending
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When requesting an zone transfer (almost all TSIG usage is when requesting zone
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transfers), with TSIG, this is the basic use pattern. In this example we
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request an AXFR for miek.nl. with TSIG key named "axfr." and secret
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"so6ZGir4GPAqINNh9U5c3A==" and using the server 176.58.119.54:
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t := new(dns.Transfer)
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m := new(dns.Msg)
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t.TsigSecret = map[string]string{"axfr.": "so6ZGir4GPAqINNh9U5c3A=="}
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m.SetAxfr("miek.nl.")
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m.SetTsig("axfr.", dns.HmacMD5, 300, time.Now().Unix())
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c, err := t.In(m, "176.58.119.54:53")
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for r := range c { ... }
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You can now read the records from the transfer as they come in. Each envelope
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is checked with TSIG. If something is not correct an error is returned.
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A custom TSIG implementation can be used. This requires additional code to
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perform any session establishment and signature generation/verification. The
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client must be configured with an implementation of the TsigProvider interface:
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type Provider struct{}
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func (*Provider) Generate(msg []byte, tsig *dns.TSIG) ([]byte, error) {
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// Use tsig.Hdr.Name and tsig.Algorithm in your code to
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// generate the MAC using msg as the payload.
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}
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func (*Provider) Verify(msg []byte, tsig *dns.TSIG) error {
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// Use tsig.Hdr.Name and tsig.Algorithm in your code to verify
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// that msg matches the value in tsig.MAC.
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}
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c := new(dns.Client)
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c.TsigProvider = new(Provider)
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m := new(dns.Msg)
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m.SetQuestion("miek.nl.", dns.TypeMX)
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m.SetTsig(keyname, dns.HmacSHA1, 300, time.Now().Unix())
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...
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// TSIG RR is calculated by calling your Generate method
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Basic use pattern validating and replying to a message that has TSIG set.
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server := &dns.Server{Addr: ":53", Net: "udp"}
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server.TsigSecret = map[string]string{"axfr.": "so6ZGir4GPAqINNh9U5c3A=="}
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go server.ListenAndServe()
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dns.HandleFunc(".", handleRequest)
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func handleRequest(w dns.ResponseWriter, r *dns.Msg) {
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m := new(dns.Msg)
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m.SetReply(r)
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if r.IsTsig() != nil {
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if w.TsigStatus() == nil {
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// *Msg r has an TSIG record and it was validated
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m.SetTsig("axfr.", dns.HmacMD5, 300, time.Now().Unix())
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} else {
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// *Msg r has an TSIG records and it was not validated
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}
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}
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w.WriteMsg(m)
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}
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PRIVATE RRS
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RFC 6895 sets aside a range of type codes for private use. This range is 65,280
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- 65,534 (0xFF00 - 0xFFFE). When experimenting with new Resource Records these
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can be used, before requesting an official type code from IANA.
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See https://miek.nl/2014/september/21/idn-and-private-rr-in-go-dns/ for more
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information.
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EDNS0
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EDNS0 is an extension mechanism for the DNS defined in RFC 2671 and updated by
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RFC 6891. It defines an new RR type, the OPT RR, which is then completely
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abused.
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Basic use pattern for creating an (empty) OPT RR:
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o := new(dns.OPT)
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o.Hdr.Name = "." // MUST be the root zone, per definition.
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o.Hdr.Rrtype = dns.TypeOPT
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The rdata of an OPT RR consists out of a slice of EDNS0 (RFC 6891) interfaces.
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Currently only a few have been standardized: EDNS0_NSID (RFC 5001) and
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EDNS0_SUBNET (RFC 7871). Note that these options may be combined in an OPT RR.
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Basic use pattern for a server to check if (and which) options are set:
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// o is a dns.OPT
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for _, s := range o.Option {
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switch e := s.(type) {
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case *dns.EDNS0_NSID:
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// do stuff with e.Nsid
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case *dns.EDNS0_SUBNET:
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// access e.Family, e.Address, etc.
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}
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}
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SIG(0)
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From RFC 2931:
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SIG(0) provides protection for DNS transactions and requests ....
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... protection for glue records, DNS requests, protection for message headers
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on requests and responses, and protection of the overall integrity of a response.
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It works like TSIG, except that SIG(0) uses public key cryptography, instead of
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the shared secret approach in TSIG. Supported algorithms: ECDSAP256SHA256,
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ECDSAP384SHA384, RSASHA1, RSASHA256 and RSASHA512.
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Signing subsequent messages in multi-message sessions is not implemented.
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*/
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package dns
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