package file
import (
"github.com/coredns/coredns/plugin/file/tree"
"github.com/coredns/coredns/request"
"github.com/miekg/dns"
)
// Result is the result of a Lookup
type Result int
const (
// Success is a successful lookup.
Success Result = iota
// NameError indicates a nameerror
NameError
// Delegation indicates the lookup resulted in a delegation.
Delegation
// NoData indicates the lookup resulted in a NODATA.
NoData
// ServerFailure indicates a server failure during the lookup.
ServerFailure
)
// Lookup looks up qname and qtype in the zone. When do is true DNSSEC records are included.
// Three sets of records are returned, one for the answer, one for authority and one for the additional section.
func (z *Zone) Lookup(state request.Request, qname string) ([]dns.RR, []dns.RR, []dns.RR, Result) {
qtype := state.QType()
do := state.Do()
if 0 < z.ReloadInterval {
z.reloadMu.RLock()
}
defer func() {
if 0 < z.ReloadInterval {
z.reloadMu.RUnlock()
}
}()
// If z is a secondary zone we might not have transferred it, meaning we have
// all zone context setup, except the actual record. This means (for one thing) the apex
// is empty and we don't have a SOA record.
soa := z.Apex.SOA
if soa == nil {
return nil, nil, nil, ServerFailure
}
if qtype == dns.TypeSOA {
return z.soa(do), z.ns(do), nil, Success
}
if qtype == dns.TypeNS && qname == z.origin {
nsrrs := z.ns(do)
glue := z.Glue(nsrrs, do)
return nsrrs, nil, glue, Success
}
var (
found, shot bool
parts string
i int
elem, wildElem *tree.Elem
)
// Lookup:
// * Per label from the right, look if it exists. We do this to find potential
// delegation records.
// * If the per-label search finds nothing, we will look for the wildcard at the
// level. If found we keep it around. If we don't find the complete name we will
// use the wildcard.
//
// Main for-loop handles delegation and finding or not finding the qname.
// If found we check if it is a CNAME/DNAME and do CNAME processing
// We also check if we have type and do a nodata resposne.
//
// If not found, we check the potential wildcard, and use that for further processing.
// If not found and no wildcard we will process this as an NXDOMAIN response.
for {
parts, shot = z.nameFromRight(qname, i)
// We overshot the name, break and check if we previously found something.
if shot {
break
}
elem, found = z.Tree.Search(parts)
if !found {
// Apex will always be found, when we are here we can search for a wildcard
// and save the result of that search. So when nothing match, but we have a
// wildcard we should expand the wildcard.
wildcard := replaceWithAsteriskLabel(parts)
if wild, found := z.Tree.Search(wildcard); found {
wildElem = wild
}
// Keep on searching, because maybe we hit an empty-non-terminal (which aren't
// stored in the tree. Only when we have match the full qname (and possible wildcard
// we can be confident that we didn't find anything.
i++
continue
}
// If we see DNAME records, we should return those.
if dnamerrs := elem.Types(dns.TypeDNAME); dnamerrs != nil {
// Only one DNAME is allowed per name. We just pick the first one to synthesize from.
dname := dnamerrs[0]
if cname := synthesizeCNAME(state.Name(), dname.(*dns.DNAME)); cname != nil {
answer, ns, extra, rcode := z.additionalProcessing(state, elem, []dns.RR{cname})
if do {
sigs := elem.Types(dns.TypeRRSIG)
sigs = signatureForSubType(sigs, dns.TypeDNAME)
dnamerrs = append(dnamerrs, sigs...)
}
// The relevant DNAME RR should be included in the answer section,
// if the DNAME is being employed as a substitution instruction.
answer = append(dnamerrs, answer...)
return answer, ns, extra, rcode
}
// The domain name that owns a DNAME record is allowed to have other RR types
// at that domain name, except those have restrictions on what they can coexist
// with (e.g. another DNAME). So there is nothing special left here.
}
// If we see NS records, it means the name as been delegated, and we should return the delegation.
if nsrrs := elem.Types(dns.TypeNS); nsrrs != nil {
// If the query is specifically for DS and the qname matches the delegated name, we should
// return the DS in the answer section and leave the rest empty, i.e. just continue the loop
// and continue searching.
if qtype == dns.TypeDS && elem.Name() == qname {
i++
continue
}
glue := z.Glue(nsrrs, do)
if do {
dss := z.typeFromElem(elem, dns.TypeDS, do)
nsrrs = append(nsrrs, dss...)
}
return nil, nsrrs, glue, Delegation
}
i++
}
// What does found and !shot mean - do we ever hit it?
if found && !shot {
return nil, nil, nil, ServerFailure
}
// Found entire name.
if found && shot {
if rrs := elem.Types(dns.TypeCNAME); len(rrs) > 0 && qtype != dns.TypeCNAME {
return z.additionalProcessing(state, elem, rrs)
}
rrs := elem.Types(qtype, qname)
// NODATA
if len(rrs) == 0 {
ret := z.soa(do)
if do {
nsec := z.typeFromElem(elem, dns.TypeNSEC, do)
ret = append(ret, nsec...)
}
return nil, ret, nil, NoData
}
// Additional section processing for MX, SRV. Check response and see if any of the names are in baliwick -
// if so add IP addresses to the additional section.
additional := additionalProcessing(z, rrs, do)
if do {
sigs := elem.Types(dns.TypeRRSIG)
sigs = signatureForSubType(sigs, qtype)
rrs = append(rrs, sigs...)
}
return rrs, z.ns(do), additional, Success
}
// Haven't found the original name.
// Found wildcard.
if wildElem != nil {
auth := z.ns(do)
if rrs := wildElem.Types(dns.TypeCNAME, qname); len(rrs) > 0 {
return z.additionalProcessing(state, wildElem, rrs)
}
rrs := wildElem.Types(qtype, qname)
// NODATA response.
if len(rrs) == 0 {
ret := z.soa(do)
if do {
nsec := z.typeFromElem(wildElem, dns.TypeNSEC, do)
ret = append(ret, nsec...)
}
return nil, ret, nil, Success
}
if do {
// An NSEC is needed to say no longer name exists under this wildcard.
if deny, found := z.Tree.Prev(qname); found {
nsec := z.typeFromElem(deny, dns.TypeNSEC, do)
auth = append(auth, nsec...)
}
sigs := wildElem.Types(dns.TypeRRSIG, qname)
sigs = signatureForSubType(sigs, qtype)
rrs = append(rrs, sigs...)
}
return rrs, auth, nil, Success
}
rcode := NameError
// Hacky way to get around empty-non-terminals. If a longer name does exist, but this qname, does not, it
// must be an empty-non-terminal. If so, we do the proper NXDOMAIN handling, but set the rcode to be success.
if x, found := z.Tree.Next(qname); found {
if dns.IsSubDomain(qname, x.Name()) {
rcode = Success
}
}
ret := z.soa(do)
if do {
deny, found := z.Tree.Prev(qname)
if !found {
goto Out
}
nsec := z.typeFromElem(deny, dns.TypeNSEC, do)
ret = append(ret, nsec...)
if rcode != NameError {
goto Out
}
ce, found := z.ClosestEncloser(qname)
// wildcard denial only for NXDOMAIN
if found {
// wildcard denial
wildcard := "*." + ce.Name()
if ss, found := z.Tree.Prev(wildcard); found {
// Only add this nsec if it is different than the one already added
if ss.Name() != deny.Name() {
nsec := z.typeFromElem(ss, dns.TypeNSEC, do)
ret = append(ret, nsec...)
}
}
}
}
Out:
return nil, ret, nil, rcode
}
// Return type tp from e and add signatures (if they exists) and do is true.
func (z *Zone) typeFromElem(elem *tree.Elem, tp uint16, do bool) []dns.RR {
rrs := elem.Types(tp)
if do {
sigs := elem.Types(dns.TypeRRSIG)
sigs = signatureForSubType(sigs, tp)
if len(sigs) > 0 {
rrs = append(rrs, sigs...)
}
}
return rrs
}
func (z *Zone) soa(do bool) []dns.RR {
if do {
ret := append([]dns.RR{z.Apex.SOA}, z.Apex.SIGSOA...)
return ret
}
return []dns.RR{z.Apex.SOA}
}
func (z *Zone) ns(do bool) []dns.RR {
if do {
ret := append(z.Apex.NS, z.Apex.SIGNS...)
return ret
}
return z.Apex.NS
}
// aditionalProcessing adds signatures and tries to resolve CNAMEs that point to external names.
func (z *Zone) additionalProcessing(state request.Request, elem *tree.Elem, rrs []dns.RR) ([]dns.RR, []dns.RR, []dns.RR, Result) {
qtype := state.QType()
do := state.Do()
if do {
sigs := elem.Types(dns.TypeRRSIG)
sigs = signatureForSubType(sigs, dns.TypeCNAME)
if len(sigs) > 0 {
rrs = append(rrs, sigs...)
}
}
targetName := rrs[0].(*dns.CNAME).Target
elem, _ = z.Tree.Search(targetName)
if elem == nil {
rrs = append(rrs, z.externalLookup(state, targetName, qtype)...)
return rrs, z.ns(do), nil, Success
}
i := 0
Redo:
cname := elem.Types(dns.TypeCNAME)
if len(cname) > 0 {
rrs = append(rrs, cname...)
if do {
sigs := elem.Types(dns.TypeRRSIG)
sigs = signatureForSubType(sigs, dns.TypeCNAME)
if len(sigs) > 0 {
rrs = append(rrs, sigs...)
}
}
targetName := cname[0].(*dns.CNAME).Target
elem, _ = z.Tree.Search(targetName)
if elem == nil {
rrs = append(rrs, z.externalLookup(state, targetName, qtype)...)
return rrs, z.ns(do), nil, Success
}
i++
if i > maxChain {
return rrs, z.ns(do), nil, Success
}
goto Redo
}
targets := cnameForType(elem.All(), qtype)
if len(targets) > 0 {
rrs = append(rrs, targets...)
if do {
sigs := elem.Types(dns.TypeRRSIG)
sigs = signatureForSubType(sigs, qtype)
if len(sigs) > 0 {
rrs = append(rrs, sigs...)
}
}
}
return rrs, z.ns(do), nil, Success
}
func cnameForType(targets []dns.RR, origQtype uint16) []dns.RR {
ret := []dns.RR{}
for _, target := range targets {
if target.Header().Rrtype == origQtype {
ret = append(ret, target)
}
}
return ret
}
func (z *Zone) externalLookup(state request.Request, target string, qtype uint16) []dns.RR {
m, e := z.Upstream.Lookup(state, target, qtype)
if e != nil {
// TODO(miek): Log, or return error here?
return nil
}
if m == nil {
return nil
}
return m.Answer
}
// signatureForSubType range through the signature and return the correct ones for the subtype.
func signatureForSubType(rrs []dns.RR, subtype uint16) []dns.RR {
sigs := []dns.RR{}
for _, sig := range rrs {
if s, ok := sig.(*dns.RRSIG); ok {
if s.TypeCovered == subtype {
sigs = append(sigs, s)
}
}
}
return sigs
}
// Glue returns any potential glue records for nsrrs.
func (z *Zone) Glue(nsrrs []dns.RR, do bool) []dns.RR {
glue := []dns.RR{}
for _, rr := range nsrrs {
if ns, ok := rr.(*dns.NS); ok && dns.IsSubDomain(ns.Header().Name, ns.Ns) {
glue = append(glue, z.searchGlue(ns.Ns, do)...)
}
}
return glue
}
// searchGlue looks up A and AAAA for name.
func (z *Zone) searchGlue(name string, do bool) []dns.RR {
glue := []dns.RR{}
// A
if elem, found := z.Tree.Search(name); found {
glue = append(glue, elem.Types(dns.TypeA)...)
if do {
sigs := elem.Types(dns.TypeRRSIG)
sigs = signatureForSubType(sigs, dns.TypeA)
glue = append(glue, sigs...)
}
}
// AAAA
if elem, found := z.Tree.Search(name); found {
glue = append(glue, elem.Types(dns.TypeAAAA)...)
if do {
sigs := elem.Types(dns.TypeRRSIG)
sigs = signatureForSubType(sigs, dns.TypeAAAA)
glue = append(glue, sigs...)
}
}
return glue
}
// additionalProcessing checks the current answer section and retrieves A or AAAA records
// (and possible SIGs) to need to be put in the additional section.
func additionalProcessing(z *Zone, answer []dns.RR, do bool) (extra []dns.RR) {
for _, rr := range answer {
name := ""
switch x := rr.(type) {
case *dns.SRV:
name = x.Target
case *dns.MX:
name = x.Mx
}
if !dns.IsSubDomain(z.origin, name) {
continue
}
elem, _ := z.Tree.Search(name)
if elem == nil {
continue
}
sigs := elem.Types(dns.TypeRRSIG)
for _, addr := range []uint16{dns.TypeA, dns.TypeAAAA} {
if a := elem.Types(addr); a != nil {
extra = append(extra, a...)
if do {
sig := signatureForSubType(sigs, addr)
extra = append(extra, sig...)
}
}
}
}
return extra
}
const maxChain = 8