blob: ac1f9b431accff7b0b4d4e84353f25aa2be264b4 [file] [log] [blame]
// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package net
import (
"context"
"os"
"runtime"
"syscall"
"unsafe"
)
const _WSAHOST_NOT_FOUND = syscall.Errno(11001)
func winError(call string, err error) error {
switch err {
case _WSAHOST_NOT_FOUND:
return errNoSuchHost
}
return os.NewSyscallError(call, err)
}
func getprotobyname(name string) (proto int, err error) {
p, err := syscall.GetProtoByName(name)
if err != nil {
return 0, winError("getprotobyname", err)
}
return int(p.Proto), nil
}
// lookupProtocol looks up IP protocol name and returns correspondent protocol number.
func lookupProtocol(ctx context.Context, name string) (int, error) {
// GetProtoByName return value is stored in thread local storage.
// Start new os thread before the call to prevent races.
type result struct {
proto int
err error
}
ch := make(chan result) // unbuffered
go func() {
acquireThread()
defer releaseThread()
runtime.LockOSThread()
defer runtime.UnlockOSThread()
proto, err := getprotobyname(name)
select {
case ch <- result{proto: proto, err: err}:
case <-ctx.Done():
}
}()
select {
case r := <-ch:
if r.err != nil {
if proto, err := lookupProtocolMap(name); err == nil {
return proto, nil
}
r.err = &DNSError{Err: r.err.Error(), Name: name}
}
return r.proto, r.err
case <-ctx.Done():
return 0, mapErr(ctx.Err())
}
}
func (r *Resolver) lookupHost(ctx context.Context, name string) ([]string, error) {
ips, err := r.lookupIP(ctx, name)
if err != nil {
return nil, err
}
addrs := make([]string, 0, len(ips))
for _, ip := range ips {
addrs = append(addrs, ip.String())
}
return addrs, nil
}
func (r *Resolver) lookupIP(ctx context.Context, name string) ([]IPAddr, error) {
// TODO(bradfitz,brainman): use ctx more. See TODO below.
type ret struct {
addrs []IPAddr
err error
}
ch := make(chan ret, 1)
go func() {
acquireThread()
defer releaseThread()
hints := syscall.AddrinfoW{
Family: syscall.AF_UNSPEC,
Socktype: syscall.SOCK_STREAM,
Protocol: syscall.IPPROTO_IP,
}
var result *syscall.AddrinfoW
e := syscall.GetAddrInfoW(syscall.StringToUTF16Ptr(name), nil, &hints, &result)
if e != nil {
ch <- ret{err: &DNSError{Err: winError("getaddrinfow", e).Error(), Name: name}}
}
defer syscall.FreeAddrInfoW(result)
addrs := make([]IPAddr, 0, 5)
for ; result != nil; result = result.Next {
addr := unsafe.Pointer(result.Addr)
switch result.Family {
case syscall.AF_INET:
a := (*syscall.RawSockaddrInet4)(addr).Addr
addrs = append(addrs, IPAddr{IP: IPv4(a[0], a[1], a[2], a[3])})
case syscall.AF_INET6:
a := (*syscall.RawSockaddrInet6)(addr).Addr
zone := zoneCache.name(int((*syscall.RawSockaddrInet6)(addr).Scope_id))
addrs = append(addrs, IPAddr{IP: IP{a[0], a[1], a[2], a[3], a[4], a[5], a[6], a[7], a[8], a[9], a[10], a[11], a[12], a[13], a[14], a[15]}, Zone: zone})
default:
ch <- ret{err: &DNSError{Err: syscall.EWINDOWS.Error(), Name: name}}
}
}
ch <- ret{addrs: addrs}
}()
select {
case r := <-ch:
return r.addrs, r.err
case <-ctx.Done():
// TODO(bradfitz,brainman): cancel the ongoing
// GetAddrInfoW? It would require conditionally using
// GetAddrInfoEx with lpOverlapped, which requires
// Windows 8 or newer. I guess we'll need oldLookupIP,
// newLookupIP, and newerLookUP.
//
// For now we just let it finish and write to the
// buffered channel.
return nil, &DNSError{
Name: name,
Err: ctx.Err().Error(),
IsTimeout: ctx.Err() == context.DeadlineExceeded,
}
}
}
func (r *Resolver) lookupPort(ctx context.Context, network, service string) (int, error) {
if r.PreferGo {
return lookupPortMap(network, service)
}
// TODO(bradfitz): finish ctx plumbing. Nothing currently depends on this.
acquireThread()
defer releaseThread()
var stype int32
switch network {
case "tcp4", "tcp6":
stype = syscall.SOCK_STREAM
case "udp4", "udp6":
stype = syscall.SOCK_DGRAM
}
hints := syscall.AddrinfoW{
Family: syscall.AF_UNSPEC,
Socktype: stype,
Protocol: syscall.IPPROTO_IP,
}
var result *syscall.AddrinfoW
e := syscall.GetAddrInfoW(nil, syscall.StringToUTF16Ptr(service), &hints, &result)
if e != nil {
if port, err := lookupPortMap(network, service); err == nil {
return port, nil
}
return 0, &DNSError{Err: winError("getaddrinfow", e).Error(), Name: network + "/" + service}
}
defer syscall.FreeAddrInfoW(result)
if result == nil {
return 0, &DNSError{Err: syscall.EINVAL.Error(), Name: network + "/" + service}
}
addr := unsafe.Pointer(result.Addr)
switch result.Family {
case syscall.AF_INET:
a := (*syscall.RawSockaddrInet4)(addr)
return int(syscall.Ntohs(a.Port)), nil
case syscall.AF_INET6:
a := (*syscall.RawSockaddrInet6)(addr)
return int(syscall.Ntohs(a.Port)), nil
}
return 0, &DNSError{Err: syscall.EINVAL.Error(), Name: network + "/" + service}
}
func (*Resolver) lookupCNAME(ctx context.Context, name string) (string, error) {
// TODO(bradfitz): finish ctx plumbing. Nothing currently depends on this.
acquireThread()
defer releaseThread()
var r *syscall.DNSRecord
e := syscall.DnsQuery(name, syscall.DNS_TYPE_CNAME, 0, nil, &r, nil)
// windows returns DNS_INFO_NO_RECORDS if there are no CNAME-s
if errno, ok := e.(syscall.Errno); ok && errno == syscall.DNS_INFO_NO_RECORDS {
// if there are no aliases, the canonical name is the input name
return absDomainName([]byte(name)), nil
}
if e != nil {
return "", &DNSError{Err: winError("dnsquery", e).Error(), Name: name}
}
defer syscall.DnsRecordListFree(r, 1)
resolved := resolveCNAME(syscall.StringToUTF16Ptr(name), r)
cname := syscall.UTF16ToString((*[256]uint16)(unsafe.Pointer(resolved))[:])
return absDomainName([]byte(cname)), nil
}
func (*Resolver) lookupSRV(ctx context.Context, service, proto, name string) (string, []*SRV, error) {
// TODO(bradfitz): finish ctx plumbing. Nothing currently depends on this.
acquireThread()
defer releaseThread()
var target string
if service == "" && proto == "" {
target = name
} else {
target = "_" + service + "._" + proto + "." + name
}
var r *syscall.DNSRecord
e := syscall.DnsQuery(target, syscall.DNS_TYPE_SRV, 0, nil, &r, nil)
if e != nil {
return "", nil, &DNSError{Err: winError("dnsquery", e).Error(), Name: target}
}
defer syscall.DnsRecordListFree(r, 1)
srvs := make([]*SRV, 0, 10)
for _, p := range validRecs(r, syscall.DNS_TYPE_SRV, target) {
v := (*syscall.DNSSRVData)(unsafe.Pointer(&p.Data[0]))
srvs = append(srvs, &SRV{absDomainName([]byte(syscall.UTF16ToString((*[256]uint16)(unsafe.Pointer(v.Target))[:]))), v.Port, v.Priority, v.Weight})
}
byPriorityWeight(srvs).sort()
return absDomainName([]byte(target)), srvs, nil
}
func (*Resolver) lookupMX(ctx context.Context, name string) ([]*MX, error) {
// TODO(bradfitz): finish ctx plumbing. Nothing currently depends on this.
acquireThread()
defer releaseThread()
var r *syscall.DNSRecord
e := syscall.DnsQuery(name, syscall.DNS_TYPE_MX, 0, nil, &r, nil)
if e != nil {
return nil, &DNSError{Err: winError("dnsquery", e).Error(), Name: name}
}
defer syscall.DnsRecordListFree(r, 1)
mxs := make([]*MX, 0, 10)
for _, p := range validRecs(r, syscall.DNS_TYPE_MX, name) {
v := (*syscall.DNSMXData)(unsafe.Pointer(&p.Data[0]))
mxs = append(mxs, &MX{absDomainName([]byte(syscall.UTF16ToString((*[256]uint16)(unsafe.Pointer(v.NameExchange))[:]))), v.Preference})
}
byPref(mxs).sort()
return mxs, nil
}
func (*Resolver) lookupNS(ctx context.Context, name string) ([]*NS, error) {
// TODO(bradfitz): finish ctx plumbing. Nothing currently depends on this.
acquireThread()
defer releaseThread()
var r *syscall.DNSRecord
e := syscall.DnsQuery(name, syscall.DNS_TYPE_NS, 0, nil, &r, nil)
if e != nil {
return nil, &DNSError{Err: winError("dnsquery", e).Error(), Name: name}
}
defer syscall.DnsRecordListFree(r, 1)
nss := make([]*NS, 0, 10)
for _, p := range validRecs(r, syscall.DNS_TYPE_NS, name) {
v := (*syscall.DNSPTRData)(unsafe.Pointer(&p.Data[0]))
nss = append(nss, &NS{absDomainName([]byte(syscall.UTF16ToString((*[256]uint16)(unsafe.Pointer(v.Host))[:])))})
}
return nss, nil
}
func (*Resolver) lookupTXT(ctx context.Context, name string) ([]string, error) {
// TODO(bradfitz): finish ctx plumbing. Nothing currently depends on this.
acquireThread()
defer releaseThread()
var r *syscall.DNSRecord
e := syscall.DnsQuery(name, syscall.DNS_TYPE_TEXT, 0, nil, &r, nil)
if e != nil {
return nil, &DNSError{Err: winError("dnsquery", e).Error(), Name: name}
}
defer syscall.DnsRecordListFree(r, 1)
txts := make([]string, 0, 10)
for _, p := range validRecs(r, syscall.DNS_TYPE_TEXT, name) {
d := (*syscall.DNSTXTData)(unsafe.Pointer(&p.Data[0]))
s := ""
for _, v := range (*[1 << 10]*uint16)(unsafe.Pointer(&(d.StringArray[0])))[:d.StringCount] {
s += syscall.UTF16ToString((*[1 << 20]uint16)(unsafe.Pointer(v))[:])
}
txts = append(txts, s)
}
return txts, nil
}
func (*Resolver) lookupAddr(ctx context.Context, addr string) ([]string, error) {
// TODO(bradfitz): finish ctx plumbing. Nothing currently depends on this.
acquireThread()
defer releaseThread()
arpa, err := reverseaddr(addr)
if err != nil {
return nil, err
}
var r *syscall.DNSRecord
e := syscall.DnsQuery(arpa, syscall.DNS_TYPE_PTR, 0, nil, &r, nil)
if e != nil {
return nil, &DNSError{Err: winError("dnsquery", e).Error(), Name: addr}
}
defer syscall.DnsRecordListFree(r, 1)
ptrs := make([]string, 0, 10)
for _, p := range validRecs(r, syscall.DNS_TYPE_PTR, arpa) {
v := (*syscall.DNSPTRData)(unsafe.Pointer(&p.Data[0]))
ptrs = append(ptrs, absDomainName([]byte(syscall.UTF16ToString((*[256]uint16)(unsafe.Pointer(v.Host))[:]))))
}
return ptrs, nil
}
const dnsSectionMask = 0x0003
// returns only results applicable to name and resolves CNAME entries
func validRecs(r *syscall.DNSRecord, dnstype uint16, name string) []*syscall.DNSRecord {
cname := syscall.StringToUTF16Ptr(name)
if dnstype != syscall.DNS_TYPE_CNAME {
cname = resolveCNAME(cname, r)
}
rec := make([]*syscall.DNSRecord, 0, 10)
for p := r; p != nil; p = p.Next {
if p.Dw&dnsSectionMask != syscall.DnsSectionAnswer {
continue
}
if p.Type != dnstype {
continue
}
if !syscall.DnsNameCompare(cname, p.Name) {
continue
}
rec = append(rec, p)
}
return rec
}
// returns the last CNAME in chain
func resolveCNAME(name *uint16, r *syscall.DNSRecord) *uint16 {
// limit cname resolving to 10 in case of a infinite CNAME loop
Cname:
for cnameloop := 0; cnameloop < 10; cnameloop++ {
for p := r; p != nil; p = p.Next {
if p.Dw&dnsSectionMask != syscall.DnsSectionAnswer {
continue
}
if p.Type != syscall.DNS_TYPE_CNAME {
continue
}
if !syscall.DnsNameCompare(name, p.Name) {
continue
}
name = (*syscall.DNSPTRData)(unsafe.Pointer(&r.Data[0])).Host
continue Cname
}
break
}
return name
}