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numa/src/record.rs
Razvan Dimescu b6703b4315 feat: recursive DNS + DNSSEC + TCP fallback (#17) 
* feat: recursive resolution + full DNSSEC validation

Numa becomes a true DNS resolver — resolves from root nameservers
with complete DNSSEC chain-of-trust verification.

Recursive resolution:
- Iterative RFC 1034 from configurable root hints (13 default)
- CNAME chasing (depth 8), referral following (depth 10)
- A+AAAA glue extraction, IPv6 nameserver support
- TLD priming: NS + DS + DNSKEY for 34 gTLDs + EU ccTLDs
- Config: mode = "recursive" in [upstream], root_hints, prime_tlds

DNSSEC (all 4 phases):
- EDNS0 OPT pseudo-record (DO bit, 1232 payload per DNS Flag Day 2020)
- DNSKEY, DS, RRSIG, NSEC, NSEC3 record types with wire read/write
- Signature verification via ring: RSA/SHA-256, ECDSA P-256, Ed25519
- Chain-of-trust: zone DNSKEY → parent DS → root KSK (key tag 20326)
- DNSKEY RRset self-signature verification (RRSIG(DNSKEY) by KSK)
- RRSIG expiration/inception time validation
- NSEC: NXDOMAIN gap proofs, NODATA type absence, wildcard denial
- NSEC3: SHA-1 iterated hashing, closest encloser proof, hash range
- Authority RRSIG verification for denial proofs
- Config: [dnssec] enabled/strict (default false, opt-in)
- AD bit on Secure, SERVFAIL on Bogus+strict
- DnssecStatus cached per entry, ValidationStats logging

Performance:
- TLD chain pre-warmed on startup (root DNSKEY + TLD DS/DNSKEY)
- Referral DS piggybacking from authority sections
- DNSKEY prefetch before validation loop
- Cold-cache validation: ~1 DNSKEY fetch (down from 5)
- Benchmarks: RSA 10.9µs, ECDSA 174ns, DS verify 257ns

Also:
- write_qname fix for root domain "." (was producing malformed queries)
- write_record_header() dedup, write_bytes() bulk writes
- DnsRecord::domain() + query_type() accessors
- UpstreamMode enum, DEFAULT_EDNS_PAYLOAD const
- Real glue TTL (was hardcoded 3600)
- DNSSEC restricted to recursive mode only

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>

* feat: TCP fallback, query minimization, UDP auto-disable

Transport resilience for restrictive networks (ISPs blocking UDP:53):
- DNS-over-TCP fallback: UDP fail/truncation → automatic TCP retry
- UDP auto-disable: after 3 consecutive failures, switch to TCP-first
- IPv6 → TCP directly (UDP socket binds 0.0.0.0, can't reach IPv6)
- Network change resets UDP detection for re-probing
- Root hint rotation in TLD priming

Privacy:
- RFC 7816 query minimization: root servers see TLD only, not full name

Code quality:
- Merged find_starting_ns + find_starting_zone → find_closest_ns
- Extracted resolve_ns_addrs_from_glue shared helper
- Removed overall timeout wrapper (per-hop timeouts sufficient)
- forward_tcp for DNS-over-TCP (RFC 1035 §4.2.2)

Testing:
- Mock TCP-only DNS server for fallback tests (no network needed)
- tcp_fallback_resolves_when_udp_blocked
- tcp_only_iterative_resolution
- tcp_fallback_handles_nxdomain
- udp_auto_disable_resets
- Integration test suite (4 suites, 51 tests)
- Network probe script (tests/network-probe.sh)

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>

* feat: DNSSEC verified badge in dashboard query log

- Add dnssec field to QueryLogEntry, track validation status per query
- DnssecStatus::as_str() for API serialization
- Dashboard shows green checkmark next to DNSSEC-verified responses
- Blog post: add "How keys get there" section, transport resilience section,
  trim code blocks, update What's Next

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>

* fix: use SVG shield for DNSSEC badge, update blog HTML

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>

* fix: NS cache lookup from authorities, UDP re-probe, shield alignment

- find_closest_ns checks authorities (not just answers) for NS records,
  fixing TLD priming cache misses that caused redundant root queries
- Periodic UDP re-probe every 5min when disabled — re-enables UDP
  after switching from a restrictive network to an open one
- Dashboard DNSSEC shield uses fixed-width container for alignment
- Blog post: tuck key-tag into trust anchor paragraph

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>

* fix: TCP single-write, mock server consistency, integration tests

- TCP single-write fix: combine length prefix + message to avoid split
  segments that Microsoft/Azure DNS servers reject
- Mock server (spawn_tcp_dns_server) updated to use single-write too
- Tests: forward_tcp_wire_format, forward_tcp_single_segment_write
- Integration: real-server checks for Microsoft/Office/Azure domains

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>

* feat: recursive bar in dashboard, special-use domain interception

Dashboard:
- Add Recursive bar to resolution paths chart (cyan, distinct from Override)
- Add RECURSIVE path tag style in query log

Special-use domains (RFC 6761/6303/8880/9462):
- .localhost → 127.0.0.1 (RFC 6761)
- Private reverse PTR (10.x, 192.168.x, 172.16-31.x) → NXDOMAIN
- _dns.resolver.arpa (DDR) → NXDOMAIN
- ipv4only.arpa (NAT64) → 192.0.0.170/171
- mDNS service discovery for private ranges → NXDOMAIN

Eliminates ~900ms SERVFAILs for macOS system queries that were
hitting root servers unnecessarily.

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>

* chore: move generated blog HTML to site/blog/posts/, gitignore

- Generated HTML now in site/blog/posts/ (gitignored)
- CI workflow runs pandoc + make blog before deploy
- Updated all internal blog links to /blog/posts/ path
- blog/*.md remains the source of truth

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>

* fix: review feedback — memory ordering, RRSIG time, NS resolution

- Ordering::Relaxed → Acquire/Release for UDP_DISABLED/UDP_FAILURES
  (ARM correctness for cross-thread coordination)
- RRSIG time validation: serial number arithmetic (RFC 4034 §3.1.5)
  + 300s clock skew fudge factor (matches BIND)
- resolve_ns_addrs_from_glue collects addresses from ALL NS names,
  not just the first with glue (improves failover)
- is_special_use_domain: eliminate 16 format! allocations per
  .in-addr.arpa query (parse octet instead)

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>

* feat: API endpoint tests, coverage target

- 8 new axum handler tests: health, stats, query-log, overrides CRUD,
  cache, blocking stats, services CRUD, dashboard HTML
- Tests use tower::oneshot — no network, no server startup
- test_ctx() builds minimal ServerCtx for isolated testing
- `make coverage` target (cargo-tarpaulin), separate from `make all`
- 82 total tests (was 74)

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>

---------

Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
2026-03-28 04:03:47 +02:00

654 lines
21 KiB
Rust
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use std::net::Ipv4Addr;
use std::net::Ipv6Addr;
use crate::buffer::BytePacketBuffer;
use crate::question::QueryType;
use crate::Result;
#[derive(Debug, Clone, PartialEq, Eq, Hash, PartialOrd, Ord)]
#[allow(dead_code)]
pub enum DnsRecord {
UNKNOWN {
domain: String,
qtype: u16,
data: Vec<u8>,
ttl: u32,
},
A {
domain: String,
addr: Ipv4Addr,
ttl: u32,
},
NS {
domain: String,
host: String,
ttl: u32,
},
CNAME {
domain: String,
host: String,
ttl: u32,
},
MX {
domain: String,
priority: u16,
host: String,
ttl: u32,
},
AAAA {
domain: String,
addr: Ipv6Addr,
ttl: u32,
},
DNSKEY {
domain: String,
flags: u16,
protocol: u8,
algorithm: u8,
public_key: Vec<u8>,
ttl: u32,
},
DS {
domain: String,
key_tag: u16,
algorithm: u8,
digest_type: u8,
digest: Vec<u8>,
ttl: u32,
},
RRSIG {
domain: String,
type_covered: u16,
algorithm: u8,
labels: u8,
original_ttl: u32,
expiration: u32,
inception: u32,
key_tag: u16,
signer_name: String,
signature: Vec<u8>,
ttl: u32,
},
NSEC {
domain: String,
next_domain: String,
type_bitmap: Vec<u8>,
ttl: u32,
},
NSEC3 {
domain: String,
hash_algorithm: u8,
flags: u8,
iterations: u16,
salt: Vec<u8>,
next_hashed_owner: Vec<u8>,
type_bitmap: Vec<u8>,
ttl: u32,
},
}
impl DnsRecord {
pub fn domain(&self) -> &str {
match self {
DnsRecord::A { domain, .. }
| DnsRecord::NS { domain, .. }
| DnsRecord::CNAME { domain, .. }
| DnsRecord::MX { domain, .. }
| DnsRecord::AAAA { domain, .. }
| DnsRecord::DNSKEY { domain, .. }
| DnsRecord::DS { domain, .. }
| DnsRecord::RRSIG { domain, .. }
| DnsRecord::NSEC { domain, .. }
| DnsRecord::NSEC3 { domain, .. }
| DnsRecord::UNKNOWN { domain, .. } => domain,
}
}
pub fn query_type(&self) -> QueryType {
match self {
DnsRecord::A { .. } => QueryType::A,
DnsRecord::AAAA { .. } => QueryType::AAAA,
DnsRecord::NS { .. } => QueryType::NS,
DnsRecord::CNAME { .. } => QueryType::CNAME,
DnsRecord::MX { .. } => QueryType::MX,
DnsRecord::DNSKEY { .. } => QueryType::DNSKEY,
DnsRecord::DS { .. } => QueryType::DS,
DnsRecord::RRSIG { .. } => QueryType::RRSIG,
DnsRecord::NSEC { .. } => QueryType::NSEC,
DnsRecord::NSEC3 { .. } => QueryType::NSEC3,
DnsRecord::UNKNOWN { qtype, .. } => QueryType::UNKNOWN(*qtype),
}
}
pub fn ttl(&self) -> u32 {
match self {
DnsRecord::A { ttl, .. }
| DnsRecord::NS { ttl, .. }
| DnsRecord::CNAME { ttl, .. }
| DnsRecord::MX { ttl, .. }
| DnsRecord::AAAA { ttl, .. }
| DnsRecord::DNSKEY { ttl, .. }
| DnsRecord::DS { ttl, .. }
| DnsRecord::RRSIG { ttl, .. }
| DnsRecord::NSEC { ttl, .. }
| DnsRecord::NSEC3 { ttl, .. }
| DnsRecord::UNKNOWN { ttl, .. } => *ttl,
}
}
pub fn set_ttl(&mut self, new_ttl: u32) {
match self {
DnsRecord::A { ttl, .. }
| DnsRecord::NS { ttl, .. }
| DnsRecord::CNAME { ttl, .. }
| DnsRecord::MX { ttl, .. }
| DnsRecord::AAAA { ttl, .. }
| DnsRecord::DNSKEY { ttl, .. }
| DnsRecord::DS { ttl, .. }
| DnsRecord::RRSIG { ttl, .. }
| DnsRecord::NSEC { ttl, .. }
| DnsRecord::NSEC3 { ttl, .. }
| DnsRecord::UNKNOWN { ttl, .. } => *ttl = new_ttl,
}
}
pub fn read(buffer: &mut BytePacketBuffer) -> Result<DnsRecord> {
let mut domain = String::with_capacity(64);
buffer.read_qname(&mut domain)?;
let qtype_num = buffer.read_u16()?;
let qtype = QueryType::from_num(qtype_num);
let _ = buffer.read_u16()?; // class
let ttl = buffer.read_u32()?;
let data_len = buffer.read_u16()?;
let rdata_start = buffer.pos();
match qtype {
QueryType::A => {
let raw_addr = buffer.read_u32()?;
let addr = Ipv4Addr::new(
((raw_addr >> 24) & 0xFF) as u8,
((raw_addr >> 16) & 0xFF) as u8,
((raw_addr >> 8) & 0xFF) as u8,
(raw_addr & 0xFF) as u8,
);
Ok(DnsRecord::A { domain, addr, ttl })
}
QueryType::AAAA => {
let raw_addr1 = buffer.read_u32()?;
let raw_addr2 = buffer.read_u32()?;
let raw_addr3 = buffer.read_u32()?;
let raw_addr4 = buffer.read_u32()?;
let addr = Ipv6Addr::new(
((raw_addr1 >> 16) & 0xFFFF) as u16,
(raw_addr1 & 0xFFFF) as u16,
((raw_addr2 >> 16) & 0xFFFF) as u16,
(raw_addr2 & 0xFFFF) as u16,
((raw_addr3 >> 16) & 0xFFFF) as u16,
(raw_addr3 & 0xFFFF) as u16,
((raw_addr4 >> 16) & 0xFFFF) as u16,
(raw_addr4 & 0xFFFF) as u16,
);
Ok(DnsRecord::AAAA { domain, addr, ttl })
}
QueryType::NS => {
let mut ns = String::with_capacity(64);
buffer.read_qname(&mut ns)?;
Ok(DnsRecord::NS {
domain,
host: ns,
ttl,
})
}
QueryType::CNAME => {
let mut cname = String::with_capacity(64);
buffer.read_qname(&mut cname)?;
Ok(DnsRecord::CNAME {
domain,
host: cname,
ttl,
})
}
QueryType::MX => {
let priority = buffer.read_u16()?;
let mut mx = String::with_capacity(64);
buffer.read_qname(&mut mx)?;
Ok(DnsRecord::MX {
domain,
priority,
host: mx,
ttl,
})
}
QueryType::DNSKEY => {
let flags = buffer.read_u16()?;
let protocol = buffer.read()?;
let algorithm = buffer.read()?;
let key_len = data_len as usize - 4; // flags(2) + protocol(1) + algorithm(1)
let public_key = buffer.get_range(buffer.pos(), key_len)?.to_vec();
buffer.step(key_len)?;
Ok(DnsRecord::DNSKEY {
domain,
flags,
protocol,
algorithm,
public_key,
ttl,
})
}
QueryType::DS => {
let key_tag = buffer.read_u16()?;
let algorithm = buffer.read()?;
let digest_type = buffer.read()?;
let digest_len = data_len as usize - 4; // key_tag(2) + algorithm(1) + digest_type(1)
let digest = buffer.get_range(buffer.pos(), digest_len)?.to_vec();
buffer.step(digest_len)?;
Ok(DnsRecord::DS {
domain,
key_tag,
algorithm,
digest_type,
digest,
ttl,
})
}
QueryType::RRSIG => {
let type_covered = buffer.read_u16()?;
let algorithm = buffer.read()?;
let labels = buffer.read()?;
let original_ttl = buffer.read_u32()?;
let expiration = buffer.read_u32()?;
let inception = buffer.read_u32()?;
let key_tag = buffer.read_u16()?;
let mut signer_name = String::with_capacity(64);
buffer.read_qname(&mut signer_name)?;
let rdata_end = rdata_start + data_len as usize;
let sig_len = rdata_end
.checked_sub(buffer.pos())
.ok_or("RRSIG data_len too short for fixed fields + signer_name")?;
let signature = buffer.get_range(buffer.pos(), sig_len)?.to_vec();
buffer.step(sig_len)?;
Ok(DnsRecord::RRSIG {
domain,
type_covered,
algorithm,
labels,
original_ttl,
expiration,
inception,
key_tag,
signer_name,
signature,
ttl,
})
}
QueryType::NSEC => {
let rdata_end = rdata_start + data_len as usize;
let mut next_domain = String::with_capacity(64);
buffer.read_qname(&mut next_domain)?;
let bitmap_len = rdata_end
.checked_sub(buffer.pos())
.ok_or("NSEC data_len too short for type bitmap")?;
let type_bitmap = buffer.get_range(buffer.pos(), bitmap_len)?.to_vec();
buffer.step(bitmap_len)?;
Ok(DnsRecord::NSEC {
domain,
next_domain,
type_bitmap,
ttl,
})
}
QueryType::NSEC3 => {
let rdata_end = rdata_start + data_len as usize;
let hash_algorithm = buffer.read()?;
let flags = buffer.read()?;
let iterations = buffer.read_u16()?;
let salt_length = buffer.read()? as usize;
let salt = buffer.get_range(buffer.pos(), salt_length)?.to_vec();
buffer.step(salt_length)?;
let hash_length = buffer.read()? as usize;
let next_hashed_owner = buffer.get_range(buffer.pos(), hash_length)?.to_vec();
buffer.step(hash_length)?;
let bitmap_len = rdata_end
.checked_sub(buffer.pos())
.ok_or("NSEC3 data_len too short for type bitmap")?;
let type_bitmap = buffer.get_range(buffer.pos(), bitmap_len)?.to_vec();
buffer.step(bitmap_len)?;
Ok(DnsRecord::NSEC3 {
domain,
hash_algorithm,
flags,
iterations,
salt,
next_hashed_owner,
type_bitmap,
ttl,
})
}
_ => {
// SOA, TXT, SRV, etc. — stored as opaque bytes until parsed natively
let data = buffer.get_range(buffer.pos(), data_len as usize)?.to_vec();
buffer.step(data_len as usize)?;
Ok(DnsRecord::UNKNOWN {
domain,
qtype: qtype_num,
data,
ttl,
})
}
}
}
pub fn write(&self, buffer: &mut BytePacketBuffer) -> Result<usize> {
let start_pos = buffer.pos();
match *self {
DnsRecord::A {
ref domain,
ref addr,
ttl,
} => {
write_header(buffer, domain, QueryType::A.to_num(), ttl)?;
buffer.write_u16(4)?;
buffer.write_bytes(&addr.octets())?;
}
DnsRecord::NS {
ref domain,
ref host,
ttl,
} => {
write_header(buffer, domain, QueryType::NS.to_num(), ttl)?;
let pos = buffer.pos();
buffer.write_u16(0)?;
buffer.write_qname(host)?;
let size = buffer.pos() - (pos + 2);
buffer.set_u16(pos, size as u16)?;
}
DnsRecord::CNAME {
ref domain,
ref host,
ttl,
} => {
write_header(buffer, domain, QueryType::CNAME.to_num(), ttl)?;
let pos = buffer.pos();
buffer.write_u16(0)?;
buffer.write_qname(host)?;
let size = buffer.pos() - (pos + 2);
buffer.set_u16(pos, size as u16)?;
}
DnsRecord::MX {
ref domain,
priority,
ref host,
ttl,
} => {
write_header(buffer, domain, QueryType::MX.to_num(), ttl)?;
let pos = buffer.pos();
buffer.write_u16(0)?;
buffer.write_u16(priority)?;
buffer.write_qname(host)?;
let size = buffer.pos() - (pos + 2);
buffer.set_u16(pos, size as u16)?;
}
DnsRecord::AAAA {
ref domain,
ref addr,
ttl,
} => {
write_header(buffer, domain, QueryType::AAAA.to_num(), ttl)?;
buffer.write_u16(16)?;
for octet in &addr.segments() {
buffer.write_u16(*octet)?;
}
}
DnsRecord::DNSKEY {
ref domain,
flags,
protocol,
algorithm,
ref public_key,
ttl,
} => {
write_header(buffer, domain, QueryType::DNSKEY.to_num(), ttl)?;
buffer.write_u16((4 + public_key.len()) as u16)?;
buffer.write_u16(flags)?;
buffer.write_u8(protocol)?;
buffer.write_u8(algorithm)?;
buffer.write_bytes(public_key)?;
}
DnsRecord::DS {
ref domain,
key_tag,
algorithm,
digest_type,
ref digest,
ttl,
} => {
write_header(buffer, domain, QueryType::DS.to_num(), ttl)?;
buffer.write_u16((4 + digest.len()) as u16)?;
buffer.write_u16(key_tag)?;
buffer.write_u8(algorithm)?;
buffer.write_u8(digest_type)?;
buffer.write_bytes(digest)?;
}
DnsRecord::RRSIG {
ref domain,
type_covered,
algorithm,
labels,
original_ttl,
expiration,
inception,
key_tag,
ref signer_name,
ref signature,
ttl,
} => {
write_header(buffer, domain, QueryType::RRSIG.to_num(), ttl)?;
let rdlen_pos = buffer.pos();
buffer.write_u16(0)?; // RDLENGTH placeholder
buffer.write_u16(type_covered)?;
buffer.write_u8(algorithm)?;
buffer.write_u8(labels)?;
buffer.write_u32(original_ttl)?;
buffer.write_u32(expiration)?;
buffer.write_u32(inception)?;
buffer.write_u16(key_tag)?;
buffer.write_qname(signer_name)?;
buffer.write_bytes(signature)?;
let rdlen = buffer.pos() - (rdlen_pos + 2);
buffer.set_u16(rdlen_pos, rdlen as u16)?;
}
DnsRecord::NSEC {
ref domain,
ref next_domain,
ref type_bitmap,
ttl,
} => {
write_header(buffer, domain, QueryType::NSEC.to_num(), ttl)?;
let rdlen_pos = buffer.pos();
buffer.write_u16(0)?;
buffer.write_qname(next_domain)?;
buffer.write_bytes(type_bitmap)?;
let rdlen = buffer.pos() - (rdlen_pos + 2);
buffer.set_u16(rdlen_pos, rdlen as u16)?;
}
DnsRecord::NSEC3 {
ref domain,
hash_algorithm,
flags,
iterations,
ref salt,
ref next_hashed_owner,
ref type_bitmap,
ttl,
} => {
write_header(buffer, domain, QueryType::NSEC3.to_num(), ttl)?;
let rdlen =
1 + 1 + 2 + 1 + salt.len() + 1 + next_hashed_owner.len() + type_bitmap.len();
buffer.write_u16(rdlen as u16)?;
buffer.write_u8(hash_algorithm)?;
buffer.write_u8(flags)?;
buffer.write_u16(iterations)?;
buffer.write_u8(salt.len() as u8)?;
buffer.write_bytes(salt)?;
buffer.write_u8(next_hashed_owner.len() as u8)?;
buffer.write_bytes(next_hashed_owner)?;
buffer.write_bytes(type_bitmap)?;
}
DnsRecord::UNKNOWN {
ref domain,
qtype,
ref data,
ttl,
} => {
write_header(buffer, domain, qtype, ttl)?;
buffer.write_u16(data.len() as u16)?;
buffer.write_bytes(data)?;
}
}
Ok(buffer.pos() - start_pos)
}
}
fn write_header(buffer: &mut BytePacketBuffer, domain: &str, qtype: u16, ttl: u32) -> Result<()> {
buffer.write_qname(domain)?;
buffer.write_u16(qtype)?;
buffer.write_u16(1)?; // class IN
buffer.write_u32(ttl)?;
Ok(())
}
#[cfg(test)]
mod tests {
use super::*;
fn round_trip(record: &DnsRecord) -> DnsRecord {
let mut buf = BytePacketBuffer::new();
record.write(&mut buf).unwrap();
buf.seek(0).unwrap();
DnsRecord::read(&mut buf).unwrap()
}
#[test]
fn unknown_preserves_raw_bytes() {
let rec = DnsRecord::UNKNOWN {
domain: "example.com".into(),
qtype: 99,
data: vec![0xDE, 0xAD, 0xBE, 0xEF],
ttl: 300,
};
let parsed = round_trip(&rec);
if let DnsRecord::UNKNOWN { data, .. } = &parsed {
assert_eq!(data.len(), 4);
assert_eq!(data, &[0xDE, 0xAD, 0xBE, 0xEF]);
} else {
panic!("expected UNKNOWN");
}
}
#[test]
fn dnskey_round_trip() {
let rec = DnsRecord::DNSKEY {
domain: "example.com".into(),
flags: 257, // KSK
protocol: 3,
algorithm: 13, // ECDSAP256SHA256
public_key: vec![1, 2, 3, 4, 5, 6, 7, 8],
ttl: 3600,
};
let parsed = round_trip(&rec);
assert_eq!(rec, parsed);
}
#[test]
fn ds_round_trip() {
let rec = DnsRecord::DS {
domain: "example.com".into(),
key_tag: 12345,
algorithm: 8,
digest_type: 2,
digest: vec![0xAA, 0xBB, 0xCC, 0xDD],
ttl: 86400,
};
let parsed = round_trip(&rec);
assert_eq!(rec, parsed);
}
#[test]
fn rrsig_round_trip() {
let rec = DnsRecord::RRSIG {
domain: "example.com".into(),
type_covered: 1, // A
algorithm: 13,
labels: 2,
original_ttl: 300,
expiration: 1700000000,
inception: 1690000000,
key_tag: 54321,
signer_name: "example.com".into(),
signature: vec![0x01, 0x02, 0x03, 0x04, 0x05],
ttl: 300,
};
let parsed = round_trip(&rec);
assert_eq!(rec, parsed);
}
#[test]
fn query_type_method() {
assert_eq!(
DnsRecord::DNSKEY {
domain: String::new(),
flags: 0,
protocol: 3,
algorithm: 8,
public_key: vec![],
ttl: 0,
}
.query_type(),
QueryType::DNSKEY
);
assert_eq!(
DnsRecord::DS {
domain: String::new(),
key_tag: 0,
algorithm: 0,
digest_type: 0,
digest: vec![],
ttl: 0,
}
.query_type(),
QueryType::DS
);
}
#[test]
fn nsec_round_trip() {
let rec = DnsRecord::NSEC {
domain: "alpha.example.com".into(),
next_domain: "gamma.example.com".into(),
type_bitmap: vec![0, 2, 0x40, 0x01], // A(1), MX(15)
ttl: 3600,
};
let parsed = round_trip(&rec);
assert_eq!(rec, parsed);
}
#[test]
fn nsec3_round_trip() {
let rec = DnsRecord::NSEC3 {
domain: "abc123.example.com".into(),
hash_algorithm: 1,
flags: 0,
iterations: 10,
salt: vec![0xAB, 0xCD],
next_hashed_owner: vec![0x01, 0x02, 0x03, 0x04, 0x05],
type_bitmap: vec![0, 1, 0x40], // A(1)
ttl: 3600,
};
let parsed = round_trip(&rec);
assert_eq!(rec, parsed);
}
}
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