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|
// Copyright 2018 The gVisor Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Package unix provides an implementation of the socket.Socket interface for
// the AF_UNIX protocol family.
package unix
import (
"fmt"
"strings"
"syscall"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/fspath"
"gvisor.dev/gvisor/pkg/marshal"
"gvisor.dev/gvisor/pkg/sentry/arch"
"gvisor.dev/gvisor/pkg/sentry/fs"
"gvisor.dev/gvisor/pkg/sentry/fs/fsutil"
"gvisor.dev/gvisor/pkg/sentry/kernel"
ktime "gvisor.dev/gvisor/pkg/sentry/kernel/time"
"gvisor.dev/gvisor/pkg/sentry/socket"
"gvisor.dev/gvisor/pkg/sentry/socket/control"
"gvisor.dev/gvisor/pkg/sentry/socket/netstack"
"gvisor.dev/gvisor/pkg/sentry/socket/unix/transport"
"gvisor.dev/gvisor/pkg/sentry/vfs"
"gvisor.dev/gvisor/pkg/syserr"
"gvisor.dev/gvisor/pkg/syserror"
"gvisor.dev/gvisor/pkg/tcpip"
"gvisor.dev/gvisor/pkg/usermem"
"gvisor.dev/gvisor/pkg/waiter"
)
// SocketOperations is a Unix socket. It is similar to a netstack socket,
// except it is backed by a transport.Endpoint instead of a tcpip.Endpoint.
//
// +stateify savable
type SocketOperations struct {
fsutil.FilePipeSeek `state:"nosave"`
fsutil.FileNotDirReaddir `state:"nosave"`
fsutil.FileNoFsync `state:"nosave"`
fsutil.FileNoMMap `state:"nosave"`
fsutil.FileNoSplice `state:"nosave"`
fsutil.FileNoopFlush `state:"nosave"`
fsutil.FileUseInodeUnstableAttr `state:"nosave"`
socketOperationsRefs
socketOpsCommon
}
// New creates a new unix socket.
func New(ctx context.Context, endpoint transport.Endpoint, stype linux.SockType) *fs.File {
dirent := socket.NewDirent(ctx, unixSocketDevice)
defer dirent.DecRef(ctx)
return NewWithDirent(ctx, dirent, endpoint, stype, fs.FileFlags{Read: true, Write: true, NonSeekable: true})
}
// NewWithDirent creates a new unix socket using an existing dirent.
func NewWithDirent(ctx context.Context, d *fs.Dirent, ep transport.Endpoint, stype linux.SockType, flags fs.FileFlags) *fs.File {
// You can create AF_UNIX, SOCK_RAW sockets. They're the same as
// SOCK_DGRAM and don't require CAP_NET_RAW.
if stype == linux.SOCK_RAW {
stype = linux.SOCK_DGRAM
}
s := SocketOperations{
socketOpsCommon: socketOpsCommon{
ep: ep,
stype: stype,
},
}
s.EnableLeakCheck()
return fs.NewFile(ctx, d, flags, &s)
}
// DecRef implements RefCounter.DecRef.
func (s *SocketOperations) DecRef(ctx context.Context) {
s.socketOperationsRefs.DecRef(func() {
s.ep.Close(ctx)
if s.abstractNamespace != nil {
s.abstractNamespace.Remove(s.abstractName, s)
}
})
}
// Release implemements fs.FileOperations.Release.
func (s *SocketOperations) Release(ctx context.Context) {
// Release only decrements a reference on s because s may be referenced in
// the abstract socket namespace.
s.DecRef(ctx)
}
// socketOpsCommon contains the socket operations common to VFS1 and VFS2.
//
// +stateify savable
type socketOpsCommon struct {
socket.SendReceiveTimeout
ep transport.Endpoint
stype linux.SockType
// abstractName and abstractNamespace indicate the name and namespace of the
// socket if it is bound to an abstract socket namespace. Once the socket is
// bound, they cannot be modified.
abstractName string
abstractNamespace *kernel.AbstractSocketNamespace
}
func (s *socketOpsCommon) isPacket() bool {
switch s.stype {
case linux.SOCK_DGRAM, linux.SOCK_SEQPACKET:
return true
case linux.SOCK_STREAM:
return false
default:
// We shouldn't have allowed any other socket types during creation.
panic(fmt.Sprintf("Invalid socket type %d", s.stype))
}
}
// Endpoint extracts the transport.Endpoint.
func (s *socketOpsCommon) Endpoint() transport.Endpoint {
return s.ep
}
// extractPath extracts and validates the address.
func extractPath(sockaddr []byte) (string, *syserr.Error) {
addr, family, err := netstack.AddressAndFamily(sockaddr)
if err != nil {
if err == syserr.ErrAddressFamilyNotSupported {
err = syserr.ErrInvalidArgument
}
return "", err
}
if family != linux.AF_UNIX {
return "", syserr.ErrInvalidArgument
}
// The address is trimmed by GetAddress.
p := string(addr.Addr)
if p == "" {
// Not allowed.
return "", syserr.ErrInvalidArgument
}
if p[len(p)-1] == '/' {
// Weird, they tried to bind '/a/b/c/'?
return "", syserr.ErrIsDir
}
return p, nil
}
// GetPeerName implements the linux syscall getpeername(2) for sockets backed by
// a transport.Endpoint.
func (s *socketOpsCommon) GetPeerName(t *kernel.Task) (linux.SockAddr, uint32, *syserr.Error) {
addr, err := s.ep.GetRemoteAddress()
if err != nil {
return nil, 0, syserr.TranslateNetstackError(err)
}
a, l := netstack.ConvertAddress(linux.AF_UNIX, addr)
return a, l, nil
}
// GetSockName implements the linux syscall getsockname(2) for sockets backed by
// a transport.Endpoint.
func (s *socketOpsCommon) GetSockName(t *kernel.Task) (linux.SockAddr, uint32, *syserr.Error) {
addr, err := s.ep.GetLocalAddress()
if err != nil {
return nil, 0, syserr.TranslateNetstackError(err)
}
a, l := netstack.ConvertAddress(linux.AF_UNIX, addr)
return a, l, nil
}
// Ioctl implements fs.FileOperations.Ioctl.
func (s *SocketOperations) Ioctl(ctx context.Context, _ *fs.File, io usermem.IO, args arch.SyscallArguments) (uintptr, error) {
return netstack.Ioctl(ctx, s.ep, io, args)
}
// GetSockOpt implements the linux syscall getsockopt(2) for sockets backed by
// a transport.Endpoint.
func (s *SocketOperations) GetSockOpt(t *kernel.Task, level, name int, outPtr usermem.Addr, outLen int) (marshal.Marshallable, *syserr.Error) {
return netstack.GetSockOpt(t, s, s.ep, linux.AF_UNIX, s.ep.Type(), level, name, outPtr, outLen)
}
// Listen implements the linux syscall listen(2) for sockets backed by
// a transport.Endpoint.
func (s *socketOpsCommon) Listen(t *kernel.Task, backlog int) *syserr.Error {
return s.ep.Listen(backlog)
}
// blockingAccept implements a blocking version of accept(2), that is, if no
// connections are ready to be accept, it will block until one becomes ready.
func (s *SocketOperations) blockingAccept(t *kernel.Task, peerAddr *tcpip.FullAddress) (transport.Endpoint, *syserr.Error) {
// Register for notifications.
e, ch := waiter.NewChannelEntry(nil)
s.EventRegister(&e, waiter.EventIn)
defer s.EventUnregister(&e)
// Try to accept the connection; if it fails, then wait until we get a
// notification.
for {
if ep, err := s.ep.Accept(peerAddr); err != syserr.ErrWouldBlock {
return ep, err
}
if err := t.Block(ch); err != nil {
return nil, syserr.FromError(err)
}
}
}
// Accept implements the linux syscall accept(2) for sockets backed by
// a transport.Endpoint.
func (s *SocketOperations) Accept(t *kernel.Task, peerRequested bool, flags int, blocking bool) (int32, linux.SockAddr, uint32, *syserr.Error) {
var peerAddr *tcpip.FullAddress
if peerRequested {
peerAddr = &tcpip.FullAddress{}
}
ep, err := s.ep.Accept(peerAddr)
if err != nil {
if err != syserr.ErrWouldBlock || !blocking {
return 0, nil, 0, err
}
var err *syserr.Error
ep, err = s.blockingAccept(t, peerAddr)
if err != nil {
return 0, nil, 0, err
}
}
ns := New(t, ep, s.stype)
defer ns.DecRef(t)
if flags&linux.SOCK_NONBLOCK != 0 {
flags := ns.Flags()
flags.NonBlocking = true
ns.SetFlags(flags.Settable())
}
var addr linux.SockAddr
var addrLen uint32
if peerAddr != nil {
addr, addrLen = netstack.ConvertAddress(linux.AF_UNIX, *peerAddr)
}
fd, e := t.NewFDFrom(0, ns, kernel.FDFlags{
CloseOnExec: flags&linux.SOCK_CLOEXEC != 0,
})
if e != nil {
return 0, nil, 0, syserr.FromError(e)
}
t.Kernel().RecordSocket(ns)
return fd, addr, addrLen, nil
}
// Bind implements the linux syscall bind(2) for unix sockets.
func (s *SocketOperations) Bind(t *kernel.Task, sockaddr []byte) *syserr.Error {
p, e := extractPath(sockaddr)
if e != nil {
return e
}
bep, ok := s.ep.(transport.BoundEndpoint)
if !ok {
// This socket can't be bound.
return syserr.ErrInvalidArgument
}
return s.ep.Bind(tcpip.FullAddress{Addr: tcpip.Address(p)}, func() *syserr.Error {
// Is it abstract?
if p[0] == 0 {
if t.IsNetworkNamespaced() {
return syserr.ErrInvalidEndpointState
}
asn := t.AbstractSockets()
name := p[1:]
if err := asn.Bind(t, name, bep, s); err != nil {
// syserr.ErrPortInUse corresponds to EADDRINUSE.
return syserr.ErrPortInUse
}
s.abstractName = name
s.abstractNamespace = asn
} else {
// The parent and name.
var d *fs.Dirent
var name string
cwd := t.FSContext().WorkingDirectory()
defer cwd.DecRef(t)
// Is there no slash at all?
if !strings.Contains(p, "/") {
d = cwd
name = p
} else {
root := t.FSContext().RootDirectory()
defer root.DecRef(t)
// Find the last path component, we know that something follows
// that final slash, otherwise extractPath() would have failed.
lastSlash := strings.LastIndex(p, "/")
subPath := p[:lastSlash]
if subPath == "" {
// Fix up subpath in case file is in root.
subPath = "/"
}
var err error
remainingTraversals := uint(fs.DefaultTraversalLimit)
d, err = t.MountNamespace().FindInode(t, root, cwd, subPath, &remainingTraversals)
if err != nil {
// No path available.
return syserr.ErrNoSuchFile
}
defer d.DecRef(t)
name = p[lastSlash+1:]
}
// Create the socket.
//
// Note that the file permissions here are not set correctly (see
// gvisor.dev/issue/2324). There is no convenient way to get permissions
// on the socket referred to by s, so we will leave this discrepancy
// unresolved until VFS2 replaces this code.
childDir, err := d.Bind(t, t.FSContext().RootDirectory(), name, bep, fs.FilePermissions{User: fs.PermMask{Read: true}})
if err != nil {
return syserr.ErrPortInUse
}
childDir.DecRef(t)
}
return nil
})
}
// extractEndpoint retrieves the transport.BoundEndpoint associated with a Unix
// socket path. The Release must be called on the transport.BoundEndpoint when
// the caller is done with it.
func extractEndpoint(t *kernel.Task, sockaddr []byte) (transport.BoundEndpoint, *syserr.Error) {
path, err := extractPath(sockaddr)
if err != nil {
return nil, err
}
// Is it abstract?
if path[0] == 0 {
if t.IsNetworkNamespaced() {
return nil, syserr.ErrInvalidArgument
}
ep := t.AbstractSockets().BoundEndpoint(path[1:])
if ep == nil {
// No socket found.
return nil, syserr.ErrConnectionRefused
}
return ep, nil
}
if kernel.VFS2Enabled {
p := fspath.Parse(path)
root := t.FSContext().RootDirectoryVFS2()
start := root
relPath := !p.Absolute
if relPath {
start = t.FSContext().WorkingDirectoryVFS2()
}
pop := vfs.PathOperation{
Root: root,
Start: start,
Path: p,
FollowFinalSymlink: true,
}
ep, e := t.Kernel().VFS().BoundEndpointAt(t, t.Credentials(), &pop, &vfs.BoundEndpointOptions{path})
root.DecRef(t)
if relPath {
start.DecRef(t)
}
if e != nil {
return nil, syserr.FromError(e)
}
return ep, nil
}
// Find the node in the filesystem.
root := t.FSContext().RootDirectory()
cwd := t.FSContext().WorkingDirectory()
remainingTraversals := uint(fs.DefaultTraversalLimit)
d, e := t.MountNamespace().FindInode(t, root, cwd, path, &remainingTraversals)
cwd.DecRef(t)
root.DecRef(t)
if e != nil {
return nil, syserr.FromError(e)
}
// Extract the endpoint if one is there.
ep := d.Inode.BoundEndpoint(path)
d.DecRef(t)
if ep == nil {
// No socket!
return nil, syserr.ErrConnectionRefused
}
return ep, nil
}
// Connect implements the linux syscall connect(2) for unix sockets.
func (s *socketOpsCommon) Connect(t *kernel.Task, sockaddr []byte, blocking bool) *syserr.Error {
ep, err := extractEndpoint(t, sockaddr)
if err != nil {
return err
}
defer ep.Release(t)
// Connect the server endpoint.
err = s.ep.Connect(t, ep)
if err == syserr.ErrWrongProtocolForSocket {
// Linux for abstract sockets returns ErrConnectionRefused
// instead of ErrWrongProtocolForSocket.
path, _ := extractPath(sockaddr)
if len(path) > 0 && path[0] == 0 {
err = syserr.ErrConnectionRefused
}
}
return err
}
// Write implements fs.FileOperations.Write.
func (s *SocketOperations) Write(ctx context.Context, _ *fs.File, src usermem.IOSequence, _ int64) (int64, error) {
t := kernel.TaskFromContext(ctx)
ctrl := control.New(t, s.ep, nil)
if src.NumBytes() == 0 {
nInt, err := s.ep.SendMsg(ctx, [][]byte{}, ctrl, nil)
return int64(nInt), err.ToError()
}
return src.CopyInTo(ctx, &EndpointWriter{
Ctx: ctx,
Endpoint: s.ep,
Control: ctrl,
To: nil,
})
}
// SendMsg implements the linux syscall sendmsg(2) for unix sockets backed by
// a transport.Endpoint.
func (s *socketOpsCommon) SendMsg(t *kernel.Task, src usermem.IOSequence, to []byte, flags int, haveDeadline bool, deadline ktime.Time, controlMessages socket.ControlMessages) (int, *syserr.Error) {
w := EndpointWriter{
Ctx: t,
Endpoint: s.ep,
Control: controlMessages.Unix,
To: nil,
}
if len(to) > 0 {
switch s.stype {
case linux.SOCK_SEQPACKET:
to = nil
case linux.SOCK_STREAM:
if s.State() == linux.SS_CONNECTED {
return 0, syserr.ErrAlreadyConnected
}
return 0, syserr.ErrNotSupported
default:
ep, err := extractEndpoint(t, to)
if err != nil {
return 0, err
}
defer ep.Release(t)
w.To = ep
if ep.Passcred() && w.Control.Credentials == nil {
w.Control.Credentials = control.MakeCreds(t)
}
}
}
n, err := src.CopyInTo(t, &w)
if err != syserror.ErrWouldBlock || flags&linux.MSG_DONTWAIT != 0 {
return int(n), syserr.FromError(err)
}
// We'll have to block. Register for notification and keep trying to
// send all the data.
e, ch := waiter.NewChannelEntry(nil)
s.EventRegister(&e, waiter.EventOut)
defer s.EventUnregister(&e)
total := n
for {
// Shorten src to reflect bytes previously written.
src = src.DropFirst64(n)
n, err = src.CopyInTo(t, &w)
total += n
if err != syserror.ErrWouldBlock {
break
}
if err = t.BlockWithDeadline(ch, haveDeadline, deadline); err != nil {
if err == syserror.ETIMEDOUT {
err = syserror.ErrWouldBlock
}
break
}
}
return int(total), syserr.FromError(err)
}
// Passcred implements transport.Credentialer.Passcred.
func (s *socketOpsCommon) Passcred() bool {
return s.ep.Passcred()
}
// ConnectedPasscred implements transport.Credentialer.ConnectedPasscred.
func (s *socketOpsCommon) ConnectedPasscred() bool {
return s.ep.ConnectedPasscred()
}
// Readiness implements waiter.Waitable.Readiness.
func (s *socketOpsCommon) Readiness(mask waiter.EventMask) waiter.EventMask {
return s.ep.Readiness(mask)
}
// EventRegister implements waiter.Waitable.EventRegister.
func (s *socketOpsCommon) EventRegister(e *waiter.Entry, mask waiter.EventMask) {
s.ep.EventRegister(e, mask)
}
// EventUnregister implements waiter.Waitable.EventUnregister.
func (s *socketOpsCommon) EventUnregister(e *waiter.Entry) {
s.ep.EventUnregister(e)
}
// SetSockOpt implements the linux syscall setsockopt(2) for sockets backed by
// a transport.Endpoint.
func (s *SocketOperations) SetSockOpt(t *kernel.Task, level int, name int, optVal []byte) *syserr.Error {
return netstack.SetSockOpt(t, s, s.ep, level, name, optVal)
}
// Shutdown implements the linux syscall shutdown(2) for sockets backed by
// a transport.Endpoint.
func (s *socketOpsCommon) Shutdown(t *kernel.Task, how int) *syserr.Error {
f, err := netstack.ConvertShutdown(how)
if err != nil {
return err
}
// Issue shutdown request.
return s.ep.Shutdown(f)
}
// Read implements fs.FileOperations.Read.
func (s *SocketOperations) Read(ctx context.Context, _ *fs.File, dst usermem.IOSequence, _ int64) (int64, error) {
if dst.NumBytes() == 0 {
return 0, nil
}
r := &EndpointReader{
Ctx: ctx,
Endpoint: s.ep,
NumRights: 0,
Peek: false,
From: nil,
}
n, err := dst.CopyOutFrom(ctx, r)
// Drop control messages.
r.Control.Release(ctx)
return n, err
}
// RecvMsg implements the linux syscall recvmsg(2) for sockets backed by
// a transport.Endpoint.
func (s *socketOpsCommon) RecvMsg(t *kernel.Task, dst usermem.IOSequence, flags int, haveDeadline bool, deadline ktime.Time, senderRequested bool, controlDataLen uint64) (n int, msgFlags int, senderAddr linux.SockAddr, senderAddrLen uint32, controlMessages socket.ControlMessages, err *syserr.Error) {
trunc := flags&linux.MSG_TRUNC != 0
peek := flags&linux.MSG_PEEK != 0
dontWait := flags&linux.MSG_DONTWAIT != 0
waitAll := flags&linux.MSG_WAITALL != 0
isPacket := s.isPacket()
// Calculate the number of FDs for which we have space and if we are
// requesting credentials.
var wantCreds bool
rightsLen := int(controlDataLen) - syscall.SizeofCmsghdr
if s.Passcred() {
// Credentials take priority if they are enabled and there is space.
wantCreds = rightsLen > 0
if !wantCreds {
msgFlags |= linux.MSG_CTRUNC
}
credLen := syscall.CmsgSpace(syscall.SizeofUcred)
rightsLen -= credLen
}
// FDs are 32 bit (4 byte) ints.
numRights := rightsLen / 4
if numRights < 0 {
numRights = 0
}
r := EndpointReader{
Ctx: t,
Endpoint: s.ep,
Creds: wantCreds,
NumRights: numRights,
Peek: peek,
}
if senderRequested {
r.From = &tcpip.FullAddress{}
}
doRead := func() (int64, error) {
return dst.CopyOutFrom(t, &r)
}
// If MSG_TRUNC is set with a zero byte destination then we still need
// to read the message and discard it, or in the case where MSG_PEEK is
// set, leave it be. In both cases the full message length must be
// returned.
if trunc && dst.Addrs.NumBytes() == 0 {
doRead = func() (int64, error) {
err := r.Truncate()
// Always return zero for bytes read since the destination size is
// zero.
return 0, err
}
}
var total int64
if n, err := doRead(); err != syserror.ErrWouldBlock || dontWait {
var from linux.SockAddr
var fromLen uint32
if r.From != nil && len([]byte(r.From.Addr)) != 0 {
from, fromLen = netstack.ConvertAddress(linux.AF_UNIX, *r.From)
}
if r.ControlTrunc {
msgFlags |= linux.MSG_CTRUNC
}
if err != nil || dontWait || !waitAll || isPacket || n >= dst.NumBytes() {
if isPacket && n < int64(r.MsgSize) {
msgFlags |= linux.MSG_TRUNC
}
if trunc {
n = int64(r.MsgSize)
}
return int(n), msgFlags, from, fromLen, socket.ControlMessages{Unix: r.Control}, syserr.FromError(err)
}
// Don't overwrite any data we received.
dst = dst.DropFirst64(n)
total += n
}
// We'll have to block. Register for notification and keep trying to
// send all the data.
e, ch := waiter.NewChannelEntry(nil)
s.EventRegister(&e, waiter.EventIn)
defer s.EventUnregister(&e)
for {
if n, err := doRead(); err != syserror.ErrWouldBlock {
var from linux.SockAddr
var fromLen uint32
if r.From != nil {
from, fromLen = netstack.ConvertAddress(linux.AF_UNIX, *r.From)
}
if r.ControlTrunc {
msgFlags |= linux.MSG_CTRUNC
}
if trunc {
// n and r.MsgSize are the same for streams.
total += int64(r.MsgSize)
} else {
total += n
}
streamPeerClosed := s.stype == linux.SOCK_STREAM && n == 0 && err == nil
if err != nil || !waitAll || isPacket || n >= dst.NumBytes() || streamPeerClosed {
if total > 0 {
err = nil
}
if isPacket && n < int64(r.MsgSize) {
msgFlags |= linux.MSG_TRUNC
}
return int(total), msgFlags, from, fromLen, socket.ControlMessages{Unix: r.Control}, syserr.FromError(err)
}
// Don't overwrite any data we received.
dst = dst.DropFirst64(n)
}
if err := t.BlockWithDeadline(ch, haveDeadline, deadline); err != nil {
if total > 0 {
err = nil
}
if err == syserror.ETIMEDOUT {
return int(total), msgFlags, nil, 0, socket.ControlMessages{}, syserr.ErrTryAgain
}
return int(total), msgFlags, nil, 0, socket.ControlMessages{}, syserr.FromError(err)
}
}
}
// State implements socket.Socket.State.
func (s *socketOpsCommon) State() uint32 {
return s.ep.State()
}
// Type implements socket.Socket.Type.
func (s *socketOpsCommon) Type() (family int, skType linux.SockType, protocol int) {
// Unix domain sockets always have a protocol of 0.
return linux.AF_UNIX, s.stype, 0
}
// provider is a unix domain socket provider.
type provider struct{}
// Socket returns a new unix domain socket.
func (*provider) Socket(t *kernel.Task, stype linux.SockType, protocol int) (*fs.File, *syserr.Error) {
// Check arguments.
if protocol != 0 && protocol != linux.AF_UNIX /* PF_UNIX */ {
return nil, syserr.ErrProtocolNotSupported
}
// Create the endpoint and socket.
var ep transport.Endpoint
switch stype {
case linux.SOCK_DGRAM, linux.SOCK_RAW:
ep = transport.NewConnectionless(t)
case linux.SOCK_SEQPACKET, linux.SOCK_STREAM:
ep = transport.NewConnectioned(t, stype, t.Kernel())
default:
return nil, syserr.ErrInvalidArgument
}
return New(t, ep, stype), nil
}
// Pair creates a new pair of AF_UNIX connected sockets.
func (*provider) Pair(t *kernel.Task, stype linux.SockType, protocol int) (*fs.File, *fs.File, *syserr.Error) {
// Check arguments.
if protocol != 0 && protocol != linux.AF_UNIX /* PF_UNIX */ {
return nil, nil, syserr.ErrProtocolNotSupported
}
switch stype {
case linux.SOCK_STREAM, linux.SOCK_DGRAM, linux.SOCK_SEQPACKET, linux.SOCK_RAW:
// Ok
default:
return nil, nil, syserr.ErrInvalidArgument
}
// Create the endpoints and sockets.
ep1, ep2 := transport.NewPair(t, stype, t.Kernel())
s1 := New(t, ep1, stype)
s2 := New(t, ep2, stype)
return s1, s2, nil
}
func init() {
socket.RegisterProvider(linux.AF_UNIX, &provider{})
socket.RegisterProviderVFS2(linux.AF_UNIX, &providerVFS2{})
}
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