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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 hostinet
import (
"fmt"
"syscall"
"golang.org/x/sys/unix"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/binary"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/fdnotifier"
"gvisor.dev/gvisor/pkg/log"
"gvisor.dev/gvisor/pkg/marshal"
"gvisor.dev/gvisor/pkg/marshal/primitive"
"gvisor.dev/gvisor/pkg/safemem"
"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/syserr"
"gvisor.dev/gvisor/pkg/syserror"
"gvisor.dev/gvisor/pkg/usermem"
"gvisor.dev/gvisor/pkg/waiter"
)
const (
sizeofInt32 = 4
// sizeofSockaddr is the size in bytes of the largest sockaddr type
// supported by this package.
sizeofSockaddr = syscall.SizeofSockaddrInet6 // sizeof(sockaddr_in6) > sizeof(sockaddr_in)
// maxControlLen is the maximum size of a control message buffer used in a
// recvmsg or sendmsg syscall.
maxControlLen = 1024
)
// LINT.IfChange
// socketOperations implements fs.FileOperations and socket.Socket for a socket
// implemented using a host socket.
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"`
socketOpsCommon
}
// socketOpsCommon contains the socket operations common to VFS1 and VFS2.
//
// +stateify savable
type socketOpsCommon struct {
socket.SendReceiveTimeout
family int // Read-only.
stype linux.SockType // Read-only.
protocol int // Read-only.
queue waiter.Queue
// fd is the host socket fd. It must have O_NONBLOCK, so that operations
// will return EWOULDBLOCK instead of blocking on the host. This allows us to
// handle blocking behavior independently in the sentry.
fd int
}
var _ = socket.Socket(&socketOperations{})
func newSocketFile(ctx context.Context, family int, stype linux.SockType, protocol int, fd int, nonblock bool) (*fs.File, *syserr.Error) {
s := &socketOperations{
socketOpsCommon: socketOpsCommon{
family: family,
stype: stype,
protocol: protocol,
fd: fd,
},
}
if err := fdnotifier.AddFD(int32(fd), &s.queue); err != nil {
return nil, syserr.FromError(err)
}
dirent := socket.NewDirent(ctx, socketDevice)
defer dirent.DecRef(ctx)
return fs.NewFile(ctx, dirent, fs.FileFlags{NonBlocking: nonblock, Read: true, Write: true, NonSeekable: true}, s), nil
}
// Release implements fs.FileOperations.Release.
func (s *socketOpsCommon) Release(context.Context) {
fdnotifier.RemoveFD(int32(s.fd))
syscall.Close(s.fd)
}
// Readiness implements waiter.Waitable.Readiness.
func (s *socketOpsCommon) Readiness(mask waiter.EventMask) waiter.EventMask {
return fdnotifier.NonBlockingPoll(int32(s.fd), mask)
}
// EventRegister implements waiter.Waitable.EventRegister.
func (s *socketOpsCommon) EventRegister(e *waiter.Entry, mask waiter.EventMask) {
s.queue.EventRegister(e, mask)
fdnotifier.UpdateFD(int32(s.fd))
}
// EventUnregister implements waiter.Waitable.EventUnregister.
func (s *socketOpsCommon) EventUnregister(e *waiter.Entry) {
s.queue.EventUnregister(e)
fdnotifier.UpdateFD(int32(s.fd))
}
// Ioctl implements fs.FileOperations.Ioctl.
func (s *socketOperations) Ioctl(ctx context.Context, _ *fs.File, io usermem.IO, args arch.SyscallArguments) (uintptr, error) {
return ioctl(ctx, s.fd, io, args)
}
// Read implements fs.FileOperations.Read.
func (s *socketOperations) Read(ctx context.Context, _ *fs.File, dst usermem.IOSequence, _ int64) (int64, error) {
n, err := dst.CopyOutFrom(ctx, safemem.ReaderFunc(func(dsts safemem.BlockSeq) (uint64, error) {
// Refuse to do anything if any part of dst.Addrs was unusable.
if uint64(dst.NumBytes()) != dsts.NumBytes() {
return 0, nil
}
if dsts.IsEmpty() {
return 0, nil
}
if dsts.NumBlocks() == 1 {
// Skip allocating []syscall.Iovec.
n, err := syscall.Read(s.fd, dsts.Head().ToSlice())
if err != nil {
return 0, translateIOSyscallError(err)
}
return uint64(n), nil
}
return readv(s.fd, safemem.IovecsFromBlockSeq(dsts))
}))
return int64(n), err
}
// Write implements fs.FileOperations.Write.
func (s *socketOperations) Write(ctx context.Context, _ *fs.File, src usermem.IOSequence, _ int64) (int64, error) {
n, err := src.CopyInTo(ctx, safemem.WriterFunc(func(srcs safemem.BlockSeq) (uint64, error) {
// Refuse to do anything if any part of src.Addrs was unusable.
if uint64(src.NumBytes()) != srcs.NumBytes() {
return 0, nil
}
if srcs.IsEmpty() {
return 0, nil
}
if srcs.NumBlocks() == 1 {
// Skip allocating []syscall.Iovec.
n, err := syscall.Write(s.fd, srcs.Head().ToSlice())
if err != nil {
return 0, translateIOSyscallError(err)
}
return uint64(n), nil
}
return writev(s.fd, safemem.IovecsFromBlockSeq(srcs))
}))
return int64(n), err
}
// Connect implements socket.Socket.Connect.
func (s *socketOpsCommon) Connect(t *kernel.Task, sockaddr []byte, blocking bool) *syserr.Error {
if len(sockaddr) > sizeofSockaddr {
sockaddr = sockaddr[:sizeofSockaddr]
}
_, _, errno := syscall.Syscall(syscall.SYS_CONNECT, uintptr(s.fd), uintptr(firstBytePtr(sockaddr)), uintptr(len(sockaddr)))
if errno == 0 {
return nil
}
if errno != syscall.EINPROGRESS || !blocking {
return syserr.FromError(translateIOSyscallError(errno))
}
// "EINPROGRESS: The socket is nonblocking and the connection cannot be
// completed immediately. It is possible to select(2) or poll(2) for
// completion by selecting the socket for writing. After select(2)
// indicates writability, use getsockopt(2) to read the SO_ERROR option at
// level SOL-SOCKET to determine whether connect() completed successfully
// (SO_ERROR is zero) or unsuccessfully (SO_ERROR is one of the usual error
// codes listed here, explaining the reason for the failure)." - connect(2)
e, ch := waiter.NewChannelEntry(nil)
s.EventRegister(&e, waiter.EventOut)
defer s.EventUnregister(&e)
if s.Readiness(waiter.EventOut)&waiter.EventOut == 0 {
if err := t.Block(ch); err != nil {
return syserr.FromError(err)
}
}
val, err := syscall.GetsockoptInt(s.fd, syscall.SOL_SOCKET, syscall.SO_ERROR)
if err != nil {
return syserr.FromError(err)
}
if val != 0 {
return syserr.FromError(syscall.Errno(uintptr(val)))
}
return nil
}
// Accept implements socket.Socket.Accept.
func (s *socketOpsCommon) Accept(t *kernel.Task, peerRequested bool, flags int, blocking bool) (int32, linux.SockAddr, uint32, *syserr.Error) {
var peerAddr linux.SockAddr
var peerAddrBuf []byte
var peerAddrlen uint32
var peerAddrPtr *byte
var peerAddrlenPtr *uint32
if peerRequested {
peerAddrBuf = make([]byte, sizeofSockaddr)
peerAddrlen = uint32(len(peerAddrBuf))
peerAddrPtr = &peerAddrBuf[0]
peerAddrlenPtr = &peerAddrlen
}
// Conservatively ignore all flags specified by the application and add
// SOCK_NONBLOCK since socketOpsCommon requires it.
fd, syscallErr := accept4(s.fd, peerAddrPtr, peerAddrlenPtr, syscall.SOCK_NONBLOCK|syscall.SOCK_CLOEXEC)
if blocking {
var ch chan struct{}
for syscallErr == syserror.ErrWouldBlock {
if ch != nil {
if syscallErr = t.Block(ch); syscallErr != nil {
break
}
} else {
var e waiter.Entry
e, ch = waiter.NewChannelEntry(nil)
s.EventRegister(&e, waiter.EventIn)
defer s.EventUnregister(&e)
}
fd, syscallErr = accept4(s.fd, peerAddrPtr, peerAddrlenPtr, syscall.SOCK_NONBLOCK|syscall.SOCK_CLOEXEC)
}
}
if peerRequested {
peerAddr = socket.UnmarshalSockAddr(s.family, peerAddrBuf[:peerAddrlen])
}
if syscallErr != nil {
return 0, peerAddr, peerAddrlen, syserr.FromError(syscallErr)
}
var (
kfd int32
kerr error
)
if kernel.VFS2Enabled {
f, err := newVFS2Socket(t, s.family, s.stype, s.protocol, fd, uint32(flags&syscall.SOCK_NONBLOCK))
if err != nil {
syscall.Close(fd)
return 0, nil, 0, err
}
defer f.DecRef(t)
kfd, kerr = t.NewFDFromVFS2(0, f, kernel.FDFlags{
CloseOnExec: flags&syscall.SOCK_CLOEXEC != 0,
})
t.Kernel().RecordSocketVFS2(f)
} else {
f, err := newSocketFile(t, s.family, s.stype, s.protocol, fd, flags&syscall.SOCK_NONBLOCK != 0)
if err != nil {
syscall.Close(fd)
return 0, nil, 0, err
}
defer f.DecRef(t)
kfd, kerr = t.NewFDFrom(0, f, kernel.FDFlags{
CloseOnExec: flags&syscall.SOCK_CLOEXEC != 0,
})
t.Kernel().RecordSocket(f)
}
return kfd, peerAddr, peerAddrlen, syserr.FromError(kerr)
}
// Bind implements socket.Socket.Bind.
func (s *socketOpsCommon) Bind(t *kernel.Task, sockaddr []byte) *syserr.Error {
if len(sockaddr) > sizeofSockaddr {
sockaddr = sockaddr[:sizeofSockaddr]
}
_, _, errno := syscall.Syscall(syscall.SYS_BIND, uintptr(s.fd), uintptr(firstBytePtr(sockaddr)), uintptr(len(sockaddr)))
if errno != 0 {
return syserr.FromError(errno)
}
return nil
}
// Listen implements socket.Socket.Listen.
func (s *socketOpsCommon) Listen(t *kernel.Task, backlog int) *syserr.Error {
return syserr.FromError(syscall.Listen(s.fd, backlog))
}
// Shutdown implements socket.Socket.Shutdown.
func (s *socketOpsCommon) Shutdown(t *kernel.Task, how int) *syserr.Error {
switch how {
case syscall.SHUT_RD, syscall.SHUT_WR, syscall.SHUT_RDWR:
return syserr.FromError(syscall.Shutdown(s.fd, how))
default:
return syserr.ErrInvalidArgument
}
}
// GetSockOpt implements socket.Socket.GetSockOpt.
func (s *socketOpsCommon) GetSockOpt(t *kernel.Task, level int, name int, outPtr usermem.Addr, outLen int) (marshal.Marshallable, *syserr.Error) {
if outLen < 0 {
return nil, syserr.ErrInvalidArgument
}
// Only allow known and safe options.
optlen := getSockOptLen(t, level, name)
switch level {
case linux.SOL_IP:
switch name {
case linux.IP_TOS, linux.IP_RECVTOS, linux.IP_PKTINFO, linux.IP_RECVORIGDSTADDR:
optlen = sizeofInt32
}
case linux.SOL_IPV6:
switch name {
case linux.IPV6_TCLASS, linux.IPV6_RECVTCLASS, linux.IPV6_V6ONLY, linux.IPV6_RECVORIGDSTADDR:
optlen = sizeofInt32
}
case linux.SOL_SOCKET:
switch name {
case linux.SO_ERROR, linux.SO_KEEPALIVE, linux.SO_SNDBUF, linux.SO_RCVBUF, linux.SO_REUSEADDR, linux.SO_TIMESTAMP:
optlen = sizeofInt32
case linux.SO_LINGER:
optlen = syscall.SizeofLinger
}
case linux.SOL_TCP:
switch name {
case linux.TCP_NODELAY:
optlen = sizeofInt32
case linux.TCP_INFO:
optlen = int(linux.SizeOfTCPInfo)
}
}
if optlen == 0 {
return nil, syserr.ErrProtocolNotAvailable // ENOPROTOOPT
}
if outLen < optlen {
return nil, syserr.ErrInvalidArgument
}
opt, err := getsockopt(s.fd, level, name, optlen)
if err != nil {
return nil, syserr.FromError(err)
}
optP := primitive.ByteSlice(opt)
return &optP, nil
}
// SetSockOpt implements socket.Socket.SetSockOpt.
func (s *socketOpsCommon) SetSockOpt(t *kernel.Task, level int, name int, opt []byte) *syserr.Error {
// Only allow known and safe options.
optlen := setSockOptLen(t, level, name)
switch level {
case linux.SOL_IP:
switch name {
case linux.IP_TOS, linux.IP_RECVTOS, linux.IP_RECVORIGDSTADDR:
optlen = sizeofInt32
case linux.IP_PKTINFO:
optlen = linux.SizeOfControlMessageIPPacketInfo
}
case linux.SOL_IPV6:
switch name {
case linux.IPV6_TCLASS, linux.IPV6_RECVTCLASS, linux.IPV6_V6ONLY, linux.IPV6_RECVORIGDSTADDR:
optlen = sizeofInt32
}
case linux.SOL_SOCKET:
switch name {
case linux.SO_SNDBUF, linux.SO_RCVBUF, linux.SO_REUSEADDR, linux.SO_TIMESTAMP:
optlen = sizeofInt32
}
case linux.SOL_TCP:
switch name {
case linux.TCP_NODELAY, linux.TCP_INQ:
optlen = sizeofInt32
}
}
if optlen == 0 {
// Pretend to accept socket options we don't understand. This seems
// dangerous, but it's what netstack does...
return nil
}
if len(opt) < optlen {
return syserr.ErrInvalidArgument
}
opt = opt[:optlen]
_, _, errno := syscall.Syscall6(syscall.SYS_SETSOCKOPT, uintptr(s.fd), uintptr(level), uintptr(name), uintptr(firstBytePtr(opt)), uintptr(len(opt)), 0)
if errno != 0 {
return syserr.FromError(errno)
}
return nil
}
// RecvMsg implements socket.Socket.RecvMsg.
func (s *socketOpsCommon) RecvMsg(t *kernel.Task, dst usermem.IOSequence, flags int, haveDeadline bool, deadline ktime.Time, senderRequested bool, controlLen uint64) (int, int, linux.SockAddr, uint32, socket.ControlMessages, *syserr.Error) {
// Only allow known and safe flags.
//
// FIXME(jamieliu): We can't support MSG_ERRQUEUE because it uses ancillary
// messages that gvisor/pkg/tcpip/transport/unix doesn't understand. Kill the
// Socket interface's dependence on netstack.
if flags&^(syscall.MSG_DONTWAIT|syscall.MSG_PEEK|syscall.MSG_TRUNC) != 0 {
return 0, 0, nil, 0, socket.ControlMessages{}, syserr.ErrInvalidArgument
}
var senderAddr linux.SockAddr
var senderAddrBuf []byte
if senderRequested {
senderAddrBuf = make([]byte, sizeofSockaddr)
}
var controlBuf []byte
var msgFlags int
recvmsgToBlocks := safemem.ReaderFunc(func(dsts safemem.BlockSeq) (uint64, error) {
// Refuse to do anything if any part of dst.Addrs was unusable.
if uint64(dst.NumBytes()) != dsts.NumBytes() {
return 0, nil
}
if dsts.IsEmpty() {
return 0, nil
}
// We always do a non-blocking recv*().
sysflags := flags | syscall.MSG_DONTWAIT
iovs := safemem.IovecsFromBlockSeq(dsts)
msg := syscall.Msghdr{
Iov: &iovs[0],
Iovlen: uint64(len(iovs)),
}
if len(senderAddrBuf) != 0 {
msg.Name = &senderAddrBuf[0]
msg.Namelen = uint32(len(senderAddrBuf))
}
if controlLen > 0 {
if controlLen > maxControlLen {
controlLen = maxControlLen
}
controlBuf = make([]byte, controlLen)
msg.Control = &controlBuf[0]
msg.Controllen = controlLen
}
n, err := recvmsg(s.fd, &msg, sysflags)
if err != nil {
return 0, err
}
senderAddrBuf = senderAddrBuf[:msg.Namelen]
msgFlags = int(msg.Flags)
controlLen = uint64(msg.Controllen)
return n, nil
})
var ch chan struct{}
n, err := dst.CopyOutFrom(t, recvmsgToBlocks)
if flags&syscall.MSG_DONTWAIT == 0 {
for err == syserror.ErrWouldBlock {
// We only expect blocking to come from the actual syscall, in which
// case it can't have returned any data.
if n != 0 {
panic(fmt.Sprintf("CopyOutFrom: got (%d, %v), wanted (0, %v)", n, err, err))
}
if ch != nil {
if err = t.BlockWithDeadline(ch, haveDeadline, deadline); err != nil {
break
}
} else {
var e waiter.Entry
e, ch = waiter.NewChannelEntry(nil)
s.EventRegister(&e, waiter.EventIn)
defer s.EventUnregister(&e)
}
n, err = dst.CopyOutFrom(t, recvmsgToBlocks)
}
}
if err != nil {
return 0, 0, nil, 0, socket.ControlMessages{}, syserr.FromError(err)
}
if senderRequested {
senderAddr = socket.UnmarshalSockAddr(s.family, senderAddrBuf)
}
unixControlMessages, err := unix.ParseSocketControlMessage(controlBuf[:controlLen])
if err != nil {
return 0, 0, nil, 0, socket.ControlMessages{}, syserr.FromError(err)
}
controlMessages := socket.ControlMessages{}
for _, unixCmsg := range unixControlMessages {
switch unixCmsg.Header.Level {
case linux.SOL_SOCKET:
switch unixCmsg.Header.Type {
case linux.SO_TIMESTAMP:
controlMessages.IP.HasTimestamp = true
binary.Unmarshal(unixCmsg.Data[:linux.SizeOfTimeval], usermem.ByteOrder, &controlMessages.IP.Timestamp)
}
case linux.SOL_IP:
switch unixCmsg.Header.Type {
case linux.IP_TOS:
controlMessages.IP.HasTOS = true
binary.Unmarshal(unixCmsg.Data[:linux.SizeOfControlMessageTOS], usermem.ByteOrder, &controlMessages.IP.TOS)
case linux.IP_PKTINFO:
controlMessages.IP.HasIPPacketInfo = true
var packetInfo linux.ControlMessageIPPacketInfo
binary.Unmarshal(unixCmsg.Data[:linux.SizeOfControlMessageIPPacketInfo], usermem.ByteOrder, &packetInfo)
controlMessages.IP.PacketInfo = packetInfo
case linux.IP_RECVORIGDSTADDR:
var addr linux.SockAddrInet
binary.Unmarshal(unixCmsg.Data[:addr.SizeBytes()], usermem.ByteOrder, &addr)
controlMessages.IP.OriginalDstAddress = &addr
}
case linux.SOL_IPV6:
switch unixCmsg.Header.Type {
case linux.IPV6_TCLASS:
controlMessages.IP.HasTClass = true
binary.Unmarshal(unixCmsg.Data[:linux.SizeOfControlMessageTClass], usermem.ByteOrder, &controlMessages.IP.TClass)
case linux.IPV6_RECVORIGDSTADDR:
var addr linux.SockAddrInet6
binary.Unmarshal(unixCmsg.Data[:addr.SizeBytes()], usermem.ByteOrder, &addr)
controlMessages.IP.OriginalDstAddress = &addr
}
case linux.SOL_TCP:
switch unixCmsg.Header.Type {
case linux.TCP_INQ:
controlMessages.IP.HasInq = true
binary.Unmarshal(unixCmsg.Data[:linux.SizeOfControlMessageInq], usermem.ByteOrder, &controlMessages.IP.Inq)
}
}
}
return int(n), msgFlags, senderAddr, uint32(len(senderAddrBuf)), controlMessages, nil
}
// SendMsg implements socket.Socket.SendMsg.
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) {
// Only allow known and safe flags.
if flags&^(syscall.MSG_DONTWAIT|syscall.MSG_EOR|syscall.MSG_FASTOPEN|syscall.MSG_MORE|syscall.MSG_NOSIGNAL) != 0 {
return 0, syserr.ErrInvalidArgument
}
space := uint64(control.CmsgsSpace(t, controlMessages))
if space > maxControlLen {
space = maxControlLen
}
controlBuf := make([]byte, 0, space)
// PackControlMessages will append up to space bytes to controlBuf.
controlBuf = control.PackControlMessages(t, controlMessages, controlBuf)
sendmsgFromBlocks := safemem.WriterFunc(func(srcs safemem.BlockSeq) (uint64, error) {
// Refuse to do anything if any part of src.Addrs was unusable.
if uint64(src.NumBytes()) != srcs.NumBytes() {
return 0, nil
}
if srcs.IsEmpty() && len(controlBuf) == 0 {
return 0, nil
}
// We always do a non-blocking send*().
sysflags := flags | syscall.MSG_DONTWAIT
if srcs.NumBlocks() == 1 && len(controlBuf) == 0 {
// Skip allocating []syscall.Iovec.
src := srcs.Head()
n, _, errno := syscall.Syscall6(syscall.SYS_SENDTO, uintptr(s.fd), src.Addr(), uintptr(src.Len()), uintptr(sysflags), uintptr(firstBytePtr(to)), uintptr(len(to)))
if errno != 0 {
return 0, translateIOSyscallError(errno)
}
return uint64(n), nil
}
iovs := safemem.IovecsFromBlockSeq(srcs)
msg := syscall.Msghdr{
Iov: &iovs[0],
Iovlen: uint64(len(iovs)),
}
if len(to) != 0 {
msg.Name = &to[0]
msg.Namelen = uint32(len(to))
}
if len(controlBuf) != 0 {
msg.Control = &controlBuf[0]
msg.Controllen = uint64(len(controlBuf))
}
return sendmsg(s.fd, &msg, sysflags)
})
var ch chan struct{}
n, err := src.CopyInTo(t, sendmsgFromBlocks)
if flags&syscall.MSG_DONTWAIT == 0 {
for err == syserror.ErrWouldBlock {
// We only expect blocking to come from the actual syscall, in which
// case it can't have returned any data.
if n != 0 {
panic(fmt.Sprintf("CopyInTo: got (%d, %v), wanted (0, %v)", n, err, err))
}
if ch != nil {
if err = t.BlockWithDeadline(ch, haveDeadline, deadline); err != nil {
if err == syserror.ETIMEDOUT {
err = syserror.ErrWouldBlock
}
break
}
} else {
var e waiter.Entry
e, ch = waiter.NewChannelEntry(nil)
s.EventRegister(&e, waiter.EventOut)
defer s.EventUnregister(&e)
}
n, err = src.CopyInTo(t, sendmsgFromBlocks)
}
}
return int(n), syserr.FromError(err)
}
func translateIOSyscallError(err error) error {
if err == syscall.EAGAIN || err == syscall.EWOULDBLOCK {
return syserror.ErrWouldBlock
}
return err
}
// State implements socket.Socket.State.
func (s *socketOpsCommon) State() uint32 {
info := linux.TCPInfo{}
buf, err := getsockopt(s.fd, syscall.SOL_TCP, syscall.TCP_INFO, linux.SizeOfTCPInfo)
if err != nil {
if err != syscall.ENOPROTOOPT {
log.Warningf("Failed to get TCP socket info from %+v: %v", s, err)
}
// For non-TCP sockets, silently ignore the failure.
return 0
}
if len(buf) != linux.SizeOfTCPInfo {
// Unmarshal below will panic if getsockopt returns a buffer of
// unexpected size.
log.Warningf("Failed to get TCP socket info from %+v: getsockopt(2) returned %d bytes, expecting %d bytes.", s, len(buf), linux.SizeOfTCPInfo)
return 0
}
binary.Unmarshal(buf, usermem.ByteOrder, &info)
return uint32(info.State)
}
// Type implements socket.Socket.Type.
func (s *socketOpsCommon) Type() (family int, skType linux.SockType, protocol int) {
return s.family, s.stype, s.protocol
}
type socketProvider struct {
family int
}
// Socket implements socket.Provider.Socket.
func (p *socketProvider) Socket(t *kernel.Task, stypeflags linux.SockType, protocol int) (*fs.File, *syserr.Error) {
// Check that we are using the host network stack.
stack := t.NetworkContext()
if stack == nil {
return nil, nil
}
if _, ok := stack.(*Stack); !ok {
return nil, nil
}
// Only accept TCP and UDP.
stype := stypeflags & linux.SOCK_TYPE_MASK
switch stype {
case syscall.SOCK_STREAM:
switch protocol {
case 0, syscall.IPPROTO_TCP:
// ok
default:
return nil, nil
}
case syscall.SOCK_DGRAM:
switch protocol {
case 0, syscall.IPPROTO_UDP:
// ok
default:
return nil, nil
}
default:
return nil, nil
}
// Conservatively ignore all flags specified by the application and add
// SOCK_NONBLOCK since socketOperations requires it. Pass a protocol of 0
// to simplify the syscall filters, since 0 and IPPROTO_* are equivalent.
fd, err := syscall.Socket(p.family, int(stype)|syscall.SOCK_NONBLOCK|syscall.SOCK_CLOEXEC, 0)
if err != nil {
return nil, syserr.FromError(err)
}
return newSocketFile(t, p.family, stype, protocol, fd, stypeflags&syscall.SOCK_NONBLOCK != 0)
}
// Pair implements socket.Provider.Pair.
func (p *socketProvider) Pair(t *kernel.Task, stype linux.SockType, protocol int) (*fs.File, *fs.File, *syserr.Error) {
// Not supported by AF_INET/AF_INET6.
return nil, nil, nil
}
// LINT.ThenChange(./socket_vfs2.go)
func init() {
for _, family := range []int{syscall.AF_INET, syscall.AF_INET6} {
socket.RegisterProvider(family, &socketProvider{family})
socket.RegisterProviderVFS2(family, &socketProviderVFS2{family})
}
}
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