mirror of
https://github.com/EmilHernvall/dnsguide.git
synced 2024-12-22 15:54:17 +07:00
Eliminate all useless allocation
This commit is contained in:
parent
45cbfa59f7
commit
4202cae860
@ -97,7 +97,7 @@ impl DnsHeader {
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)?;
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buffer.write_u8(
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(self.rescode.clone() as u8)
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(self.rescode as u8)
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| ((self.checking_disabled as u8) << 4)
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| ((self.authed_data as u8) << 5)
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| ((self.z as u8) << 6)
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21
chapter4.md
21
chapter4.md
@ -190,7 +190,7 @@ fn handle_query(socket: &UdpSocket) -> Result<()> {
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// Next, `DnsPacket::from_buffer` is used to parse the raw bytes into
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// a `DnsPacket`.
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let request = DnsPacket::from_buffer(&mut req_buffer)?;
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let mut request = DnsPacket::from_buffer(&mut req_buffer)?;
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// Create and initialize the response packet
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let mut packet = DnsPacket::new();
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@ -199,15 +199,8 @@ fn handle_query(socket: &UdpSocket) -> Result<()> {
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packet.header.recursion_available = true;
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packet.header.response = true;
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// Being mindful of how unreliable input data from arbitrary senders can be, we
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// need make sure that a question is actually present. If not, we return `FORMERR`
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// to indicate that the sender made something wrong.
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if request.questions.is_empty() {
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packet.header.rescode = ResultCode::FORMERR;
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}
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// Usually a question will be present, though.
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else {
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let question = &request.questions[0];
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// In the normal case, exactly one question is present
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if let Some(question) = request.questions.pop() {
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println!("Received query: {:?}", question);
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// Since all is set up and as expected, the query can be forwarded to the
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@ -216,7 +209,7 @@ fn handle_query(socket: &UdpSocket) -> Result<()> {
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// as much to the client. If rather everything goes as planned, the
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// question and response records as copied into our response packet.
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if let Ok(result) = lookup(&question.name, question.qtype) {
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packet.questions.push(question.clone());
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packet.questions.push(question);
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packet.header.rescode = result.header.rescode;
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for rec in result.answers {
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@ -235,6 +228,12 @@ fn handle_query(socket: &UdpSocket) -> Result<()> {
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packet.header.rescode = ResultCode::SERVFAIL;
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}
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}
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// Being mindful of how unreliable input data from arbitrary senders can be, we
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// need make sure that a question is actually present. If not, we return `FORMERR`
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// to indicate that the sender made something wrong.
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else {
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packet.header.rescode = ResultCode::FORMERR;
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}
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// The only thing remaining is to encode our response and send it off!
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let mut res_buffer = BytePacketBuffer::new();
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59
chapter5.md
59
chapter5.md
@ -171,11 +171,11 @@ impl DnsPacket {
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/// It's useful to be able to pick a random A record from a packet. When we
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/// get multiple IP's for a single name, it doesn't matter which one we
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/// choose, so in those cases we can now pick one at random.
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pub fn get_random_a(&self) -> Option<String> {
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pub fn get_random_a(&self) -> Option<Ipv4Addr> {
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self.answers
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.iter()
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.filter_map(|record| match record {
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DnsRecord::A { ref addr, .. } => Some(addr.to_string()),
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DnsRecord::A { addr, .. } => Some(*addr),
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_ => None,
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})
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.next()
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@ -183,8 +183,9 @@ impl DnsPacket {
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/// A helper function which returns an iterator over all name servers in
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/// the authorities section, represented as (domain, host) tuples
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fn get_ns<'a>(&'a self, qname: &'a str) -> impl Iterator<Item=(&'a str, &'a str)> {
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self.authorities.iter()
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fn get_ns<'a>(&'a self, qname: &'a str) -> impl Iterator<Item = (&'a str, &'a str)> {
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self.authorities
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.iter()
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// In practice, these are always NS records in well formed packages.
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// Convert the NS records to a tuple which has only the data we need
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// to make it easy to work with.
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@ -196,17 +197,18 @@ impl DnsPacket {
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.filter(move |(domain, _)| qname.ends_with(*domain))
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}
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/// When there is a NS record in the authorities section, there may also
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/// be a matching A record in the additional section. This saves us
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/// from doing a separate query to resolve the IP of the name server.
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pub fn get_resolved_ns(&self, qname: &str) -> Option<String> {
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/// We'll use the fact that name servers often bundle the corresponding
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/// A records when replying to an NS query to implement a function that
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/// returns the actual IP for an NS record if possible.
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pub fn get_resolved_ns(&self, qname: &str) -> Option<Ipv4Addr> {
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// Get an iterator over the nameservers in the authorities section
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self.get_ns(qname)
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// Now we need to look for a matching A record in the additional
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// section. Since we just want the first valid record, we can just
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// build a stream of matching records.
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.flat_map(|(_, host)| {
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self.resources.iter()
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self.resources
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.iter()
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// Filter for A records where the domain match the host
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// of the NS record that we are currently processing
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.filter_map(move |record| match record {
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@ -214,19 +216,19 @@ impl DnsPacket {
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_ => None,
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})
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})
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.map(|addr| addr.to_string())
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.map(|addr| *addr)
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// Finally, pick the first valid entry
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.next()
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}
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/// However, not all name servers are as that nice. In certain cases there won't
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/// be any A records in the additional section, and we'll have to perform *another*
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/// lookup in the midst of our first. For this, we introduce a method for
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/// returning the hostname of an appropriate name server.
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pub fn get_unresolved_ns(&self, qname: &str) -> Option<String> {
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/// lookup in the midst. For this, we introduce a method for returning the host
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/// name of an appropriate name server.
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pub fn get_unresolved_ns<'a>(&'a self, qname: &'a str) -> Option<&'a str> {
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// Get an iterator over the nameservers in the authorities section
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self.get_ns(qname)
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.map(|(_, host)| host.to_string())
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.map(|(_, host)| host)
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// Finally, pick the first valid entry
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.next()
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}
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@ -240,36 +242,35 @@ We move swiftly on to our new `recursive_lookup` function:
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```rust
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fn recursive_lookup(qname: &str, qtype: QueryType) -> Result<DnsPacket> {
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// For now we're always starting with *a.root-servers.net*.
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let mut ns = "198.41.0.4".to_string();
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let mut ns = "198.41.0.4".parse::<Ipv4Addr>().unwrap();
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// Since it might take an arbitrary number of steps, we enter an unbounded loop.
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loop {
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println!("attempting lookup of {:?} {} with ns {}", qtype, qname, ns);
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// The next step is to send the query to the active server.
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let ns_copy = ns.clone();
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let ns_copy = ns;
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let server = (ns_copy.as_str(), 53);
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let response = lookup(qname, qtype.clone(), server)?;
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let server = (ns_copy, 53);
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let response = lookup(qname, qtype, server)?;
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// If there are entries in the answer section, and no errors, we are done!
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if !response.answers.is_empty() && response.header.rescode == ResultCode::NOERROR {
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return Ok(response.clone());
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return Ok(response);
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}
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// We might also get a `NXDOMAIN` reply, which is the authoritative name servers
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// way of telling us that the name doesn't exist.
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if response.header.rescode == ResultCode::NXDOMAIN {
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return Ok(response.clone());
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return Ok(response);
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}
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// Otherwise, we'll try to find a new nameserver based on NS and a corresponding A
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// record in the additional section. If this succeeds, we can switch name server
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// and retry the loop.
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if let Some(new_ns) = response.get_resolved_ns(qname) {
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ns = new_ns.clone();
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ns = new_ns;
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continue;
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}
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@ -278,7 +279,7 @@ fn recursive_lookup(qname: &str, qtype: QueryType) -> Result<DnsPacket> {
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// we'll go with what the last server told us.
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let new_ns_name = match response.get_unresolved_ns(qname) {
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Some(x) => x,
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None => return Ok(response.clone()),
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None => return Ok(response),
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};
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// Here we go down the rabbit hole by starting _another_ lookup sequence in the
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@ -289,14 +290,22 @@ fn recursive_lookup(qname: &str, qtype: QueryType) -> Result<DnsPacket> {
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// Finally, we pick a random ip from the result, and restart the loop. If no such
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// record is available, we again return the last result we got.
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if let Some(new_ns) = recursive_response.get_random_a() {
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ns = new_ns.clone();
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ns = new_ns;
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} else {
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return Ok(response.clone());
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return Ok(response);
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}
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}
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}
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```
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This also requires a small change to the `lookup` function, as we need to
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pass which server to use. We add a server parameter to the function signature,
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and remove the hardcoded `server` variable we used in chapter 4:
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```rust
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fn lookup(qname: &str, qtype: QueryType, server: (Ipv4Addr, u16)) -> Result<DnsPacket> {
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```
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### Trying out recursive lookup
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The only thing remaining is to change our `handle_query` function to use
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@ -290,7 +290,7 @@ impl DnsHeader {
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)?;
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buffer.write_u8(
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(self.rescode.clone() as u8)
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(self.rescode as u8)
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| ((self.checking_disabled as u8) << 4)
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| ((self.authed_data as u8) << 5)
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| ((self.z as u8) << 6)
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@ -303,7 +303,7 @@ impl DnsHeader {
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)?;
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buffer.write_u8(
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(self.rescode.clone() as u8)
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(self.rescode as u8)
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| ((self.checking_disabled as u8) << 4)
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| ((self.authed_data as u8) << 5)
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| ((self.z as u8) << 6)
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@ -303,7 +303,7 @@ impl DnsHeader {
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)?;
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buffer.write_u8(
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(self.rescode.clone() as u8)
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(self.rescode as u8)
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| ((self.checking_disabled as u8) << 4)
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| ((self.authed_data as u8) << 5)
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| ((self.z as u8) << 6)
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@ -643,7 +643,7 @@ impl DnsPacket {
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result.header.read(buffer)?;
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for _ in 0..result.header.questions {
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let mut question = DnsQuestion::new("".to_string(), QueryType::UNKNOWN(0));
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let mut question = DnsQuestion::new(String::new(), QueryType::UNKNOWN(0));
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question.read(buffer)?;
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result.questions.push(question);
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}
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@ -728,7 +728,7 @@ fn handle_query(socket: &UdpSocket) -> Result<()> {
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// Next, `DnsPacket::from_buffer` is used to parse the raw bytes into
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// a `DnsPacket`.
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let request = DnsPacket::from_buffer(&mut req_buffer)?;
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let mut request = DnsPacket::from_buffer(&mut req_buffer)?;
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// Create and initialize the response packet
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let mut packet = DnsPacket::new();
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@ -737,15 +737,8 @@ fn handle_query(socket: &UdpSocket) -> Result<()> {
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packet.header.recursion_available = true;
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packet.header.response = true;
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// Being mindful of how unreliable input data from arbitrary senders can be, we
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// need make sure that a question is actually present. If not, we return `FORMERR`
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// to indicate that the sender made something wrong.
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if request.questions.is_empty() {
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packet.header.rescode = ResultCode::FORMERR;
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}
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// Usually a question will be present, though.
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else {
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let question = &request.questions[0];
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// In the normal case, exactly one question is present
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if let Some(question) = request.questions.pop() {
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println!("Received query: {:?}", question);
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// Since all is set up and as expected, the query can be forwarded to the
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@ -754,7 +747,7 @@ fn handle_query(socket: &UdpSocket) -> Result<()> {
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// as much to the client. If rather everything goes as planned, the
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// question and response records as copied into our response packet.
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if let Ok(result) = lookup(&question.name, question.qtype) {
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packet.questions.push(question.clone());
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packet.questions.push(question);
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packet.header.rescode = result.header.rescode;
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for rec in result.answers {
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@ -773,6 +766,12 @@ fn handle_query(socket: &UdpSocket) -> Result<()> {
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packet.header.rescode = ResultCode::SERVFAIL;
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}
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}
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// Being mindful of how unreliable input data from arbitrary senders can be, we
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// need make sure that a question is actually present. If not, we return `FORMERR`
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// to indicate that the sender made something wrong.
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else {
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packet.header.rescode = ResultCode::FORMERR;
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}
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// The only thing remaining is to encode our response and send it off!
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let mut res_buffer = BytePacketBuffer::new();
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@ -303,7 +303,7 @@ impl DnsHeader {
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)?;
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buffer.write_u8(
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(self.rescode.clone() as u8)
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(self.rescode as u8)
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| ((self.checking_disabled as u8) << 4)
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| ((self.authed_data as u8) << 5)
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| ((self.z as u8) << 6)
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@ -691,11 +691,11 @@ impl DnsPacket {
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/// It's useful to be able to pick a random A record from a packet. When we
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/// get multiple IP's for a single name, it doesn't matter which one we
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/// choose, so in those cases we can now pick one at random.
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pub fn get_random_a(&self) -> Option<String> {
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pub fn get_random_a(&self) -> Option<Ipv4Addr> {
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self.answers
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.iter()
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.filter_map(|record| match record {
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DnsRecord::A { ref addr, .. } => Some(addr.to_string()),
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DnsRecord::A { addr, .. } => Some(*addr),
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_ => None,
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})
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.next()
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@ -720,7 +720,7 @@ impl DnsPacket {
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/// We'll use the fact that name servers often bundle the corresponding
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/// A records when replying to an NS query to implement a function that
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/// returns the actual IP for an NS record if possible.
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pub fn get_resolved_ns(&self, qname: &str) -> Option<String> {
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pub fn get_resolved_ns(&self, qname: &str) -> Option<Ipv4Addr> {
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// Get an iterator over the nameservers in the authorities section
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self.get_ns(qname)
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// Now we need to look for a matching A record in the additional
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@ -736,7 +736,7 @@ impl DnsPacket {
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_ => None,
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})
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})
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.map(|addr| addr.to_string())
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.map(|addr| *addr)
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// Finally, pick the first valid entry
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.next()
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}
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@ -745,16 +745,16 @@ impl DnsPacket {
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/// be any A records in the additional section, and we'll have to perform *another*
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/// lookup in the midst. For this, we introduce a method for returning the host
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/// name of an appropriate name server.
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pub fn get_unresolved_ns(&self, qname: &str) -> Option<String> {
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pub fn get_unresolved_ns<'a>(&'a self, qname: &'a str) -> Option<&'a str> {
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// Get an iterator over the nameservers in the authorities section
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self.get_ns(qname)
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.map(|(_, host)| host.to_string())
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.map(|(_, host)| host)
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// Finally, pick the first valid entry
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.next()
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}
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}
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fn lookup(qname: &str, qtype: QueryType, server: (&str, u16)) -> Result<DnsPacket> {
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fn lookup(qname: &str, qtype: QueryType, server: (Ipv4Addr, u16)) -> Result<DnsPacket> {
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let socket = UdpSocket::bind(("0.0.0.0", 43210))?;
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let mut packet = DnsPacket::new();
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@ -778,34 +778,34 @@ fn lookup(qname: &str, qtype: QueryType, server: (&str, u16)) -> Result<DnsPacke
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fn recursive_lookup(qname: &str, qtype: QueryType) -> Result<DnsPacket> {
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// For now we're always starting with *a.root-servers.net*.
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let mut ns = "198.41.0.4".to_string();
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let mut ns = "198.41.0.4".parse::<Ipv4Addr>().unwrap();
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// Since it might take an arbitrary number of steps, we enter an unbounded loop.
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loop {
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println!("attempting lookup of {:?} {} with ns {}", qtype, qname, ns);
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// The next step is to send the query to the active server.
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let ns_copy = ns.clone();
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let ns_copy = ns;
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let server = (ns_copy.as_str(), 53);
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let response = lookup(qname, qtype.clone(), server)?;
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let server = (ns_copy, 53);
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let response = lookup(qname, qtype, server)?;
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// If there are entries in the answer section, and no errors, we are done!
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if !response.answers.is_empty() && response.header.rescode == ResultCode::NOERROR {
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return Ok(response.clone());
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return Ok(response);
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}
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// We might also get a `NXDOMAIN` reply, which is the authoritative name servers
|
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// way of telling us that the name doesn't exist.
|
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if response.header.rescode == ResultCode::NXDOMAIN {
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return Ok(response.clone());
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return Ok(response);
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}
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// Otherwise, we'll try to find a new nameserver based on NS and a corresponding A
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// record in the additional section. If this succeeds, we can switch name server
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// and retry the loop.
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if let Some(new_ns) = response.get_resolved_ns(qname) {
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ns = new_ns.clone();
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ns = new_ns;
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continue;
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}
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@ -814,7 +814,7 @@ fn recursive_lookup(qname: &str, qtype: QueryType) -> Result<DnsPacket> {
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// we'll go with what the last server told us.
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let new_ns_name = match response.get_unresolved_ns(qname) {
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Some(x) => x,
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None => return Ok(response.clone()),
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None => return Ok(response),
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};
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|
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// Here we go down the rabbit hole by starting _another_ lookup sequence in the
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||||
@ -825,9 +825,9 @@ fn recursive_lookup(qname: &str, qtype: QueryType) -> Result<DnsPacket> {
|
||||
// Finally, we pick a random ip from the result, and restart the loop. If no such
|
||||
// record is available, we again return the last result we got.
|
||||
if let Some(new_ns) = recursive_response.get_random_a() {
|
||||
ns = new_ns.clone();
|
||||
ns = new_ns;
|
||||
} else {
|
||||
return Ok(response.clone());
|
||||
return Ok(response);
|
||||
}
|
||||
}
|
||||
}
|
||||
@ -836,7 +836,7 @@ fn handle_query(socket: &UdpSocket) -> Result<()> {
|
||||
let mut req_buffer = BytePacketBuffer::new();
|
||||
let (_, src) = socket.recv_from(&mut req_buffer.buf)?;
|
||||
|
||||
let request = DnsPacket::from_buffer(&mut req_buffer)?;
|
||||
let mut request = DnsPacket::from_buffer(&mut req_buffer)?;
|
||||
|
||||
let mut packet = DnsPacket::new();
|
||||
packet.header.id = request.header.id;
|
||||
@ -844,10 +844,7 @@ fn handle_query(socket: &UdpSocket) -> Result<()> {
|
||||
packet.header.recursion_available = true;
|
||||
packet.header.response = true;
|
||||
|
||||
if request.questions.is_empty() {
|
||||
packet.header.rescode = ResultCode::FORMERR;
|
||||
} else {
|
||||
let question = &request.questions[0];
|
||||
if let Some(question) = request.questions.pop() {
|
||||
println!("Received query: {:?}", question);
|
||||
|
||||
if let Ok(result) = recursive_lookup(&question.name, question.qtype) {
|
||||
@ -869,6 +866,8 @@ fn handle_query(socket: &UdpSocket) -> Result<()> {
|
||||
} else {
|
||||
packet.header.rescode = ResultCode::SERVFAIL;
|
||||
}
|
||||
} else {
|
||||
packet.header.rescode = ResultCode::FORMERR;
|
||||
}
|
||||
|
||||
let mut res_buffer = BytePacketBuffer::new();
|
||||
|
Loading…
Reference in New Issue
Block a user