use std::net::IpAddr;
use std::sync::Arc;
use byteorder::{BigEndian, ByteOrder, WriteBytesExt};
use crate::dnscrypt_certs::*;
use crate::errors::*;
pub const DNS_MAX_HOSTNAME_SIZE: usize = 256;
pub const DNS_HEADER_SIZE: usize = 12;
pub const DNS_OFFSET_FLAGS: usize = 2;
pub const DNS_MAX_PACKET_SIZE: usize = 0x1600;
const DNS_MAX_INDIRECTIONS: usize = 16;
const DNS_FLAGS_TC: u16 = 1u16 << 9;
const DNS_FLAGS_QR: u16 = 1u16 << 15;
const DNS_FLAGS_RA: u16 = 1u16 << 7;
const DNS_FLAGS_RD: u16 = 1u16 << 8;
const DNS_FLAGS_CD: u16 = 1u16 << 4;
const DNS_OFFSET_QUESTION: usize = DNS_HEADER_SIZE;
pub const DNS_TYPE_A: u16 = 1;
pub const DNS_TYPE_AAAA: u16 = 28;
pub const DNS_TYPE_OPT: u16 = 41;
pub const DNS_TYPE_TXT: u16 = 16;
pub const DNS_TYPE_HINFO: u16 = 13;
pub const DNS_CLASS_INET: u16 = 1;
pub const DNS_RCODE_SERVFAIL: u8 = 2;
pub const DNS_RCODE_NXDOMAIN: u8 = 3;
pub const DNS_RCODE_REFUSED: u8 = 5;
#[inline]
pub fn rcode(packet: &[u8]) -> u8 {
packet[3] & 0x0f
}
#[inline]
pub fn set_rcode(packet: &mut [u8], rcode: u8) {
packet[3] = (packet[3] & !0x0f) | rcode;
}
#[inline]
pub fn rcode_servfail(packet: &[u8]) -> bool {
rcode(packet) == DNS_RCODE_SERVFAIL
}
#[inline]
pub fn set_rcode_servfail(packet: &mut [u8]) {
set_rcode(packet, DNS_RCODE_SERVFAIL)
}
#[inline]
pub fn rcode_refused(packet: &[u8]) -> bool {
rcode(packet) == DNS_RCODE_REFUSED
}
#[inline]
pub fn set_rcode_refused(packet: &mut [u8]) {
set_rcode(packet, DNS_RCODE_REFUSED)
}
#[inline]
pub fn rcode_nxdomain(packet: &[u8]) -> bool {
rcode(packet) == DNS_RCODE_NXDOMAIN
}
#[inline]
pub fn set_rcode_nxdomain(packet: &mut [u8]) {
set_rcode(packet, DNS_RCODE_NXDOMAIN)
}
#[inline]
pub fn qdcount(packet: &[u8]) -> u16 {
BigEndian::read_u16(&packet[4..])
}
#[inline]
pub fn ancount(packet: &[u8]) -> u16 {
BigEndian::read_u16(&packet[6..])
}
fn ancount_inc(packet: &mut [u8]) -> Result<(), Error> {
let mut ancount = ancount(packet);
ensure!(ancount < 0xffff, "Too many answer records");
ancount += 1;
BigEndian::write_u16(&mut packet[6..], ancount);
Ok(())
}
#[inline]
fn nscount(packet: &[u8]) -> u16 {
BigEndian::read_u16(&packet[8..])
}
#[inline]
pub fn arcount(packet: &[u8]) -> u16 {
BigEndian::read_u16(&packet[10..])
}
fn arcount_inc(packet: &mut [u8]) -> Result<(), Error> {
let mut arcount = arcount(packet);
ensure!(arcount < 0xffff, "Too many additional records");
arcount += 1;
BigEndian::write_u16(&mut packet[10..], arcount);
Ok(())
}
#[inline]
fn arcount_clear(packet: &mut [u8]) -> Result<(), Error> {
BigEndian::write_u16(&mut packet[10..], 0);
Ok(())
}
#[inline]
pub fn an_ns_ar_count_clear(packet: &mut [u8]) {
packet[6..12].iter_mut().for_each(|x| *x = 0);
}
#[inline]
pub fn tid(packet: &[u8]) -> u16 {
BigEndian::read_u16(&packet[0..])
}
#[inline]
pub fn set_tid(packet: &mut [u8], tid: u16) {
BigEndian::write_u16(&mut packet[0..], tid);
}
#[inline]
pub fn set_flags(packet: &mut [u8], flags: u16) {
BigEndian::write_u16(&mut packet[DNS_OFFSET_FLAGS..], flags);
}
#[inline]
pub fn authoritative_response(packet: &mut [u8]) {
let current_rd_cd_flags =
BigEndian::read_u16(&packet[DNS_OFFSET_FLAGS..]) & (DNS_FLAGS_CD | DNS_FLAGS_RD);
set_flags(packet, current_rd_cd_flags | DNS_FLAGS_QR | DNS_FLAGS_RA);
}
#[inline]
pub fn truncate(packet: &mut [u8]) {
let current_flags = BigEndian::read_u16(&packet[DNS_OFFSET_FLAGS..]);
BigEndian::write_u16(
&mut packet[DNS_OFFSET_FLAGS..],
current_flags | DNS_FLAGS_TC | DNS_FLAGS_QR | DNS_FLAGS_RA,
);
}
#[inline]
pub fn is_response(packet: &[u8]) -> bool {
BigEndian::read_u16(&packet[DNS_OFFSET_FLAGS..]) & DNS_FLAGS_QR == DNS_FLAGS_QR
}
#[inline]
pub fn is_truncated(packet: &[u8]) -> bool {
BigEndian::read_u16(&packet[DNS_OFFSET_FLAGS..]) & DNS_FLAGS_TC == DNS_FLAGS_TC
}
pub fn qname(packet: &[u8]) -> Result<Vec<u8>, Error> {
debug_assert!(std::usize::MAX > 0xffff);
debug_assert!(DNS_MAX_HOSTNAME_SIZE > 0xff);
let packet_len = packet.len();
ensure!(packet_len > DNS_OFFSET_QUESTION, "Short packet");
ensure!(qdcount(packet) == 1, "Unexpected query count");
let mut offset = DNS_HEADER_SIZE;
let mut qname = Vec::with_capacity(DNS_MAX_HOSTNAME_SIZE);
loop {
ensure!(offset < packet_len, "Short packet");
match packet[offset] as usize {
label_len if label_len & 0xc0 == 0xc0 => bail!("Indirections"),
0 => {
if qname.is_empty() {
qname.push(b'.')
}
break;
}
label_len => {
ensure!(label_len < 0x40, "Long label");
ensure!(packet_len - offset > 1, "Short packet");
offset += 1;
ensure!(packet_len - offset > label_len, "Short packet");
if !qname.is_empty() {
qname.push(b'.')
}
ensure!(
qname.len() < DNS_MAX_HOSTNAME_SIZE - label_len,
"Name too long"
);
qname.extend_from_slice(&packet[offset..offset + label_len]);
offset += label_len;
}
}
}
Ok(qname)
}
pub fn normalize_qname(packet: &mut [u8]) -> Result<(), Error> {
debug_assert!(std::usize::MAX > 0xffff);
debug_assert!(DNS_MAX_HOSTNAME_SIZE > 0xff);
let packet_len = packet.len();
ensure!(packet_len > DNS_OFFSET_QUESTION, "Short packet");
ensure!(qdcount(packet) == 1, "Unexpected query count");
let mut offset = DNS_HEADER_SIZE;
loop {
ensure!(offset < packet_len, "Short packet");
match packet[offset] as usize {
label_len if label_len & 0xc0 == 0xc0 => bail!("Indirections"),
0 => {
break;
}
label_len => {
ensure!(label_len < 0x40, "Long label");
ensure!(packet_len - offset > 1, "Short packet");
offset += 1;
ensure!(packet_len - offset > label_len, "Short packet");
ensure!(
offset - DNS_HEADER_SIZE < DNS_MAX_HOSTNAME_SIZE - label_len,
"Name too long"
);
packet[offset..offset + label_len]
.iter_mut()
.for_each(|x| *x = x.to_ascii_lowercase());
offset += label_len;
}
}
}
Ok(())
}
pub fn qname_tld(qname: &[u8]) -> &[u8] {
qname.rsplit(|c| *c == b'.').next().unwrap_or_default()
}
pub fn recase_qname(packet: &mut [u8], qname: &[u8]) -> Result<(), Error> {
debug_assert!(std::usize::MAX > 0xffff);
let packet_len = packet.len();
ensure!(packet_len > DNS_OFFSET_QUESTION, "Short packet");
ensure!(qdcount(packet) == 1, "Unexpected query count");
let qname_len = qname.len();
let mut offset = DNS_HEADER_SIZE;
let mut qname_offset = 0;
loop {
ensure!(offset < packet_len, "Short packet");
match packet[offset] as usize {
label_len if label_len & 0xc0 == 0xc0 => bail!("Indirections"),
0 => {
ensure!(
(qname_len == 1 && qname[0] == b'.') || qname_offset == qname_len,
"Unterminated reference qname"
);
break;
}
label_len => {
ensure!(label_len < 0x40, "Long label");
ensure!(packet_len - offset > 1, "Short packet");
ensure!(qname_offset < qname_len, "Short reference qname");
offset += 1;
if qname_offset != 0 {
ensure!(qname[qname_offset] == b'.', "Non-matching reference qname");
qname_offset += 1;
}
ensure!(packet_len - offset > label_len, "Short packet");
ensure!(
qname_len - qname_offset >= label_len,
"Short reference qname"
);
packet[offset..offset + label_len]
.iter_mut()
.zip(&qname[qname_offset..qname_offset + label_len])
.for_each(|(a, b)| {
debug_assert!(a.eq_ignore_ascii_case(b));
*a = *b
});
offset += label_len;
qname_offset += label_len;
}
}
}
Ok(())
}
fn skip_name(packet: &[u8], offset: usize) -> Result<usize, Error> {
let packet_len = packet.len();
ensure!(offset < packet_len - 1, "Short packet");
let mut qname_len: usize = 0;
let mut offset = offset;
loop {
let label_len = match packet[offset] as usize {
label_len if label_len & 0xc0 == 0xc0 => {
ensure!(packet_len - offset >= 2, "Incomplete offset");
offset += 2;
break;
}
label_len => label_len,
};
ensure!(label_len < 0x40, "Long label");
ensure!(
packet_len - offset - 1 > label_len,
"Malformed packet with an out-of-bounds name"
);
qname_len += label_len + 1;
ensure!(qname_len <= DNS_MAX_HOSTNAME_SIZE, "Name too long");
offset += label_len + 1;
if label_len == 0 {
break;
}
}
Ok(offset)
}
fn traverse_rrs<F: FnMut(usize) -> Result<(), Error>>(
packet: &[u8],
mut offset: usize,
rrcount: usize,
mut cb: F,
) -> Result<usize, Error> {
let packet_len = packet.len();
for _ in 0..rrcount {
offset = skip_name(packet, offset)?;
ensure!(packet_len - offset >= 10, "Short packet");
let rdlen = BigEndian::read_u16(&packet[offset + 8..]) as usize;
ensure!(
packet_len - offset >= 10 + rdlen,
"Record length would exceed packet length"
);
cb(offset)?;
offset += 10;
offset += rdlen;
}
Ok(offset)
}
fn traverse_rrs_mut<F: FnMut(&mut [u8], usize) -> Result<(), Error>>(
packet: &mut [u8],
mut offset: usize,
rrcount: usize,
mut cb: F,
) -> Result<usize, Error> {
let packet_len = packet.len();
for _ in 0..rrcount {
offset = skip_name(packet, offset)?;
ensure!(packet_len - offset >= 10, "Short packet");
let rdlen = BigEndian::read_u16(&packet[offset + 8..]) as usize;
ensure!(
packet_len - offset >= 10 + rdlen,
"Record length would exceed packet length"
);
cb(packet, offset)?;
offset += 10;
offset += rdlen;
}
Ok(offset)
}
pub fn min_ttl(packet: &[u8], min_ttl: u32, max_ttl: u32, failure_ttl: u32) -> Result<u32, Error> {
let packet_len = packet.len();
ensure!(packet_len > DNS_OFFSET_QUESTION, "Short packet");
ensure!(packet_len <= DNS_MAX_PACKET_SIZE, "Large packet");
ensure!(qdcount(packet) == 1, "No question");
let mut offset = skip_name(packet, DNS_OFFSET_QUESTION)?;
assert!(offset > DNS_OFFSET_QUESTION);
ensure!(packet_len - offset > 4, "Short packet");
offset += 4;
let (ancount, nscount, arcount) = (ancount(packet), nscount(packet), arcount(packet));
let rrcount = ancount as usize + nscount as usize + arcount as usize;
let mut found_min_ttl = if rrcount > 0 { max_ttl } else { failure_ttl };
offset = traverse_rrs(packet, offset, rrcount, |offset| {
let qtype = BigEndian::read_u16(&packet[offset..]);
let ttl = BigEndian::read_u32(&packet[offset + 4..]);
if qtype != DNS_TYPE_OPT && ttl < found_min_ttl {
found_min_ttl = ttl;
}
Ok(())
})?;
if found_min_ttl < min_ttl {
found_min_ttl = min_ttl;
}
ensure!(packet_len == offset, "Garbage after packet");
Ok(found_min_ttl)
}
pub fn set_ttl(packet: &mut [u8], ttl: u32) -> Result<(), Error> {
let packet_len = packet.len();
ensure!(packet_len > DNS_OFFSET_QUESTION, "Short packet");
ensure!(packet_len <= DNS_MAX_PACKET_SIZE, "Large packet");
ensure!(qdcount(packet) == 1, "No question");
let mut offset = skip_name(packet, DNS_OFFSET_QUESTION)?;
assert!(offset > DNS_OFFSET_QUESTION);
ensure!(packet_len - offset > 4, "Short packet");
offset += 4;
let (ancount, nscount, arcount) = (ancount(packet), nscount(packet), arcount(packet));
let rrcount = ancount as usize + nscount as usize + arcount as usize;
offset = traverse_rrs_mut(packet, offset, rrcount, |packet, offset| {
let qtype = BigEndian::read_u16(&packet[offset..]);
if qtype != DNS_TYPE_OPT {
BigEndian::write_u32(&mut packet[offset + 4..], ttl)
}
Ok(())
})?;
ensure!(packet_len == offset, "Garbage after packet");
Ok(())
}
fn add_edns_section(packet: &mut Vec<u8>, max_payload_size: u16) -> Result<(), Error> {
let opt_rr: [u8; 11] = [
0,
(DNS_TYPE_OPT >> 8) as u8,
DNS_TYPE_OPT as u8,
(max_payload_size >> 8) as u8,
max_payload_size as u8,
0,
0,
0,
0,
0,
0,
];
ensure!(
DNS_MAX_PACKET_SIZE - packet.len() >= opt_rr.len(),
"Packet would be too large to add a new record"
);
arcount_inc(packet)?;
packet.extend(opt_rr);
Ok(())
}
pub fn set_edns_max_payload_size(packet: &mut Vec<u8>, max_payload_size: u16) -> Result<(), Error> {
let packet_len = packet.len();
ensure!(packet_len > DNS_OFFSET_QUESTION, "Short packet");
ensure!(packet_len <= DNS_MAX_PACKET_SIZE, "Large packet");
ensure!(qdcount(packet) == 1, "No question");
let mut offset = skip_name(packet, DNS_OFFSET_QUESTION)?;
assert!(offset > DNS_OFFSET_QUESTION);
ensure!(packet_len - offset >= 4, "Short packet");
offset += 4;
let (ancount, nscount, arcount) = (ancount(packet), nscount(packet), arcount(packet));
offset = traverse_rrs(
packet,
offset,
ancount as usize + nscount as usize,
|_offset| Ok(()),
)?;
let mut edns_payload_set = false;
traverse_rrs_mut(packet, offset, arcount as _, |packet, offset| {
let qtype = BigEndian::read_u16(&packet[offset..]);
if qtype == DNS_TYPE_OPT {
ensure!(!edns_payload_set, "Duplicate OPT RR found");
BigEndian::write_u16(&mut packet[offset + 2..], max_payload_size);
edns_payload_set = true;
}
Ok(())
})?;
if edns_payload_set {
return Ok(());
}
add_edns_section(packet, max_payload_size)?;
Ok(())
}
pub fn serve_certificates<'t>(
client_packet: &[u8],
expected_qname: &str,
dnscrypt_encryption_params_set: impl IntoIterator<Item = &'t Arc<DNSCryptEncryptionParams>>,
) -> Result<Option<Vec<u8>>, Error> {
ensure!(client_packet.len() >= DNS_HEADER_SIZE, "Short packet");
ensure!(qdcount(client_packet) == 1, "No question");
ensure!(
!is_response(client_packet),
"Question expected, but got a response instead"
);
let offset = skip_name(client_packet, DNS_HEADER_SIZE)?;
ensure!(client_packet.len() - offset >= 4, "Short packet");
let qtype = BigEndian::read_u16(&client_packet[offset..]);
let qclass = BigEndian::read_u16(&client_packet[offset + 2..]);
if qtype != DNS_TYPE_TXT || qclass != DNS_CLASS_INET {
return Ok(None);
}
let qname_v = qname(client_packet)?;
let qname = std::str::from_utf8(&qname_v)?;
if !qname.eq_ignore_ascii_case(expected_qname) {
return Ok(None);
}
let mut packet = client_packet[..offset + 4].to_vec();
an_ns_ar_count_clear(&mut packet);
authoritative_response(&mut packet);
let dnscrypt_encryption_params = dnscrypt_encryption_params_set
.into_iter()
.max_by_key(|x| x.dnscrypt_cert().ts_end())
.ok_or_else(|| anyhow!("No certificates"))?;
let cert_bin = dnscrypt_encryption_params.dnscrypt_cert().as_bytes();
ensure!(cert_bin.len() <= 0xff, "Certificate too long");
ancount_inc(&mut packet)?;
packet.write_u16::<BigEndian>(0xc000 + DNS_HEADER_SIZE as u16)?;
packet.write_u16::<BigEndian>(DNS_TYPE_TXT)?;
packet.write_u16::<BigEndian>(DNS_CLASS_INET)?;
packet.write_u32::<BigEndian>(DNSCRYPT_CERTS_RENEWAL)?;
packet.write_u16::<BigEndian>(1 + cert_bin.len() as u16)?;
packet.write_u8(cert_bin.len() as u8)?;
packet.extend_from_slice(cert_bin);
ensure!(packet.len() < DNS_MAX_PACKET_SIZE, "Packet too large");
Ok(Some(packet))
}
pub fn serve_truncated_response(client_packet: Vec<u8>) -> Result<Vec<u8>, Error> {
ensure!(client_packet.len() >= DNS_HEADER_SIZE, "Short packet");
ensure!(qdcount(&client_packet) == 1, "No question");
ensure!(
!is_response(&client_packet),
"Question expected, but got a response instead"
);
let offset = skip_name(&client_packet, DNS_HEADER_SIZE)?;
let mut packet = client_packet;
ensure!(packet.len() - offset >= 4, "Short packet");
packet.truncate(offset + 4);
an_ns_ar_count_clear(&mut packet);
authoritative_response(&mut packet);
truncate(&mut packet);
Ok(packet)
}
pub fn qtype_qclass(packet: &[u8]) -> Result<(u16, u16), Error> {
ensure!(packet.len() >= DNS_HEADER_SIZE, "Short packet");
ensure!(qdcount(packet) == 1, "No question");
let offset = skip_name(packet, DNS_HEADER_SIZE)?;
ensure!(packet.len() - offset >= 4, "Short packet");
let qtype = BigEndian::read_u16(&packet[offset..]);
let qclass = BigEndian::read_u16(&packet[offset + 2..]);
Ok((qtype, qclass))
}
fn parse_txt_rrdata<F: FnMut(&str) -> Result<(), Error>>(
rrdata: &[u8],
mut cb: F,
) -> Result<(), Error> {
let rrdata_len = rrdata.len();
let mut offset = 0;
while offset < rrdata_len {
let part_len = rrdata[offset] as usize;
if part_len == 0 {
break;
}
ensure!(rrdata_len - offset > part_len, "Short TXT RR data");
offset += 1;
let part_bin = &rrdata[offset..offset + part_len];
let part = std::str::from_utf8(part_bin)?;
cb(part)?;
offset += part_len;
}
Ok(())
}
pub fn query_meta(packet: &mut Vec<u8>) -> Result<Option<String>, Error> {
let packet_len = packet.len();
ensure!(packet_len > DNS_OFFSET_QUESTION, "Short packet");
ensure!(packet_len <= DNS_MAX_PACKET_SIZE, "Large packet");
ensure!(qdcount(packet) == 1, "No question");
let mut offset = skip_name(packet, DNS_OFFSET_QUESTION)?;
assert!(offset > DNS_OFFSET_QUESTION);
ensure!(packet_len - offset >= 4, "Short packet");
offset += 4;
let (ancount, nscount, arcount) = (ancount(packet), nscount(packet), arcount(packet));
offset = traverse_rrs(
packet,
offset,
ancount as usize + nscount as usize,
|_offset| Ok(()),
)?;
let mut token = None;
traverse_rrs(packet, offset, arcount as _, |mut offset| {
let qtype = BigEndian::read_u16(&packet[offset..]);
let qclass = BigEndian::read_u16(&packet[offset + 2..]);
if qtype != DNS_TYPE_TXT || qclass != DNS_CLASS_INET {
return Ok(());
}
let len = BigEndian::read_u16(&packet[offset + 8..]) as usize;
offset += 10;
ensure!(packet_len - offset >= len, "Short packet");
let rrdata = &packet[offset..offset + len];
parse_txt_rrdata(rrdata, |txt| {
if txt.len() < 7 || !txt.starts_with("token:") {
return Ok(());
}
ensure!(token.is_none(), "Duplicate token");
let found_token = &txt[6..];
let found_token = found_token.to_owned();
token = Some(found_token);
Ok(())
})?;
Ok(())
})?;
if token.is_some() {
arcount_clear(packet)?;
packet.truncate(offset);
}
Ok(token)
}
pub fn serve_nxdomain_response(client_packet: Vec<u8>) -> Result<Vec<u8>, Error> {
ensure!(client_packet.len() >= DNS_HEADER_SIZE, "Short packet");
ensure!(qdcount(&client_packet) == 1, "No question");
ensure!(
!is_response(&client_packet),
"Question expected, but got a response instead"
);
let offset = skip_name(&client_packet, DNS_HEADER_SIZE)?;
let mut packet = client_packet;
ensure!(packet.len() - offset >= 4, "Short packet");
packet.truncate(offset + 4);
an_ns_ar_count_clear(&mut packet);
authoritative_response(&mut packet);
set_rcode_nxdomain(&mut packet);
Ok(packet)
}
pub fn serve_blocked_response(client_packet: Vec<u8>) -> Result<Vec<u8>, Error> {
ensure!(client_packet.len() >= DNS_HEADER_SIZE, "Short packet");
ensure!(qdcount(&client_packet) == 1, "No question");
ensure!(
!is_response(&client_packet),
"Question expected, but got a response instead"
);
let offset = skip_name(&client_packet, DNS_HEADER_SIZE)?;
let mut packet = client_packet;
ensure!(packet.len() - offset >= 4, "Short packet");
packet.truncate(offset + 4);
an_ns_ar_count_clear(&mut packet);
authoritative_response(&mut packet);
let hinfo_cpu = b"Query blocked";
let hinfo_rdata = b"by the DNS server";
let rdata_len = 1 + hinfo_cpu.len() + 1 + hinfo_rdata.len();
ancount_inc(&mut packet)?;
packet.write_u16::<BigEndian>(0xc000 + DNS_HEADER_SIZE as u16)?;
packet.write_u16::<BigEndian>(DNS_TYPE_HINFO)?;
packet.write_u16::<BigEndian>(DNS_CLASS_INET)?;
packet.write_u32::<BigEndian>(60)?;
packet.write_u16::<BigEndian>(rdata_len as _)?;
packet.push(hinfo_cpu.len() as u8);
packet.extend_from_slice(hinfo_cpu);
packet.push(hinfo_rdata.len() as u8);
packet.extend_from_slice(hinfo_rdata);
Ok(packet)
}
pub fn serve_ip_response(client_packet: Vec<u8>, ip: IpAddr, ttl: u32) -> Result<Vec<u8>, Error> {
ensure!(client_packet.len() >= DNS_HEADER_SIZE, "Short packet");
ensure!(qdcount(&client_packet) == 1, "No question");
ensure!(
!is_response(&client_packet),
"Question expected, but got a response instead"
);
let offset = skip_name(&client_packet, DNS_HEADER_SIZE)?;
let mut packet = client_packet;
ensure!(packet.len() - offset >= 4, "Short packet");
packet.truncate(offset + 4);
an_ns_ar_count_clear(&mut packet);
authoritative_response(&mut packet);
ancount_inc(&mut packet)?;
packet.write_u16::<BigEndian>(0xc000 + DNS_HEADER_SIZE as u16)?;
match ip {
IpAddr::V4(ip) => {
packet.write_u16::<BigEndian>(DNS_TYPE_A)?;
packet.write_u16::<BigEndian>(DNS_CLASS_INET)?;
packet.write_u32::<BigEndian>(ttl)?;
packet.write_u16::<BigEndian>(4)?;
packet.extend_from_slice(&ip.octets());
}
IpAddr::V6(ip) => {
packet.write_u16::<BigEndian>(DNS_TYPE_AAAA)?;
packet.write_u16::<BigEndian>(DNS_CLASS_INET)?;
packet.write_u32::<BigEndian>(ttl)?;
packet.write_u16::<BigEndian>(16)?;
packet.extend_from_slice(&ip.octets());
}
};
Ok(packet)
}