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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 socket provides the interfaces that need to be provided by socket
// implementations and providers, as well as per family demultiplexing of socket
// creation.
package socket
import (
"bytes"
"fmt"
"sync/atomic"
"golang.org/x/sys/unix"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/hostarch"
"gvisor.dev/gvisor/pkg/marshal"
"gvisor.dev/gvisor/pkg/sentry/device"
"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/unix/transport"
"gvisor.dev/gvisor/pkg/sentry/vfs"
"gvisor.dev/gvisor/pkg/syserr"
"gvisor.dev/gvisor/pkg/tcpip"
"gvisor.dev/gvisor/pkg/tcpip/header"
"gvisor.dev/gvisor/pkg/usermem"
)
// ControlMessages represents the union of unix control messages and tcpip
// control messages.
type ControlMessages struct {
Unix transport.ControlMessages
IP IPControlMessages
}
// packetInfoToLinux converts IPPacketInfo from tcpip format to Linux format.
func packetInfoToLinux(packetInfo tcpip.IPPacketInfo) linux.ControlMessageIPPacketInfo {
var p linux.ControlMessageIPPacketInfo
p.NIC = int32(packetInfo.NIC)
copy(p.LocalAddr[:], []byte(packetInfo.LocalAddr))
copy(p.DestinationAddr[:], []byte(packetInfo.DestinationAddr))
return p
}
// errOriginToLinux maps tcpip socket origin to Linux socket origin constants.
func errOriginToLinux(origin tcpip.SockErrOrigin) uint8 {
switch origin {
case tcpip.SockExtErrorOriginNone:
return linux.SO_EE_ORIGIN_NONE
case tcpip.SockExtErrorOriginLocal:
return linux.SO_EE_ORIGIN_LOCAL
case tcpip.SockExtErrorOriginICMP:
return linux.SO_EE_ORIGIN_ICMP
case tcpip.SockExtErrorOriginICMP6:
return linux.SO_EE_ORIGIN_ICMP6
default:
panic(fmt.Sprintf("unknown socket origin: %d", origin))
}
}
// sockErrCmsgToLinux converts SockError control message from tcpip format to
// Linux format.
func sockErrCmsgToLinux(sockErr *tcpip.SockError) linux.SockErrCMsg {
if sockErr == nil {
return nil
}
ee := linux.SockExtendedErr{
Errno: uint32(syserr.TranslateNetstackError(sockErr.Err).ToLinux()),
Origin: errOriginToLinux(sockErr.Cause.Origin()),
Type: sockErr.Cause.Type(),
Code: sockErr.Cause.Code(),
Info: sockErr.Cause.Info(),
}
switch sockErr.NetProto {
case header.IPv4ProtocolNumber:
errMsg := &linux.SockErrCMsgIPv4{SockExtendedErr: ee}
if len(sockErr.Offender.Addr) > 0 {
addr, _ := ConvertAddress(linux.AF_INET, sockErr.Offender)
errMsg.Offender = *addr.(*linux.SockAddrInet)
}
return errMsg
case header.IPv6ProtocolNumber:
errMsg := &linux.SockErrCMsgIPv6{SockExtendedErr: ee}
if len(sockErr.Offender.Addr) > 0 {
addr, _ := ConvertAddress(linux.AF_INET6, sockErr.Offender)
errMsg.Offender = *addr.(*linux.SockAddrInet6)
}
return errMsg
default:
panic(fmt.Sprintf("invalid net proto for creating SockErrCMsg: %d", sockErr.NetProto))
}
}
// NewIPControlMessages converts the tcpip ControlMessgaes (which does not
// have Linux specific format) to Linux format.
func NewIPControlMessages(family int, cmgs tcpip.ControlMessages) IPControlMessages {
var orgDstAddr linux.SockAddr
if cmgs.HasOriginalDstAddress {
orgDstAddr, _ = ConvertAddress(family, cmgs.OriginalDstAddress)
}
return IPControlMessages{
HasTimestamp: cmgs.HasTimestamp,
Timestamp: cmgs.Timestamp,
HasInq: cmgs.HasInq,
Inq: cmgs.Inq,
HasTOS: cmgs.HasTOS,
TOS: cmgs.TOS,
HasTClass: cmgs.HasTClass,
TClass: cmgs.TClass,
HasIPPacketInfo: cmgs.HasIPPacketInfo,
PacketInfo: packetInfoToLinux(cmgs.PacketInfo),
OriginalDstAddress: orgDstAddr,
SockErr: sockErrCmsgToLinux(cmgs.SockErr),
}
}
// IPControlMessages contains socket control messages for IP sockets.
// This can contain Linux specific structures unlike tcpip.ControlMessages.
//
// +stateify savable
type IPControlMessages struct {
// HasTimestamp indicates whether Timestamp is valid/set.
HasTimestamp bool
// Timestamp is the time (in ns) that the last packet used to create
// the read data was received.
Timestamp int64
// HasInq indicates whether Inq is valid/set.
HasInq bool
// Inq is the number of bytes ready to be received.
Inq int32
// HasTOS indicates whether Tos is valid/set.
HasTOS bool
// TOS is the IPv4 type of service of the associated packet.
TOS uint8
// HasTClass indicates whether TClass is valid/set.
HasTClass bool
// TClass is the IPv6 traffic class of the associated packet.
TClass uint32
// HasIPPacketInfo indicates whether PacketInfo is set.
HasIPPacketInfo bool
// PacketInfo holds interface and address data on an incoming packet.
PacketInfo linux.ControlMessageIPPacketInfo
// OriginalDestinationAddress holds the original destination address
// and port of the incoming packet.
OriginalDstAddress linux.SockAddr
// SockErr is the dequeued socket error on recvmsg(MSG_ERRQUEUE).
SockErr linux.SockErrCMsg
}
// Release releases Unix domain socket credentials and rights.
func (c *ControlMessages) Release(ctx context.Context) {
c.Unix.Release(ctx)
}
// Socket is an interface combining fs.FileOperations and SocketOps,
// representing a VFS1 socket file.
type Socket interface {
fs.FileOperations
SocketOps
}
// SocketVFS2 is an interface combining vfs.FileDescription and SocketOps,
// representing a VFS2 socket file.
type SocketVFS2 interface {
vfs.FileDescriptionImpl
SocketOps
}
// SocketOps is the interface containing socket syscalls used by the syscall
// layer to redirect them to the appropriate implementation.
//
// It is implemented by both Socket and SocketVFS2.
type SocketOps interface {
// Connect implements the connect(2) linux unix.
Connect(t *kernel.Task, sockaddr []byte, blocking bool) *syserr.Error
// Accept implements the accept4(2) linux unix.
// Returns fd, real peer address length and error. Real peer address
// length is only set if len(peer) > 0.
Accept(t *kernel.Task, peerRequested bool, flags int, blocking bool) (int32, linux.SockAddr, uint32, *syserr.Error)
// Bind implements the bind(2) linux unix.
Bind(t *kernel.Task, sockaddr []byte) *syserr.Error
// Listen implements the listen(2) linux unix.
Listen(t *kernel.Task, backlog int) *syserr.Error
// Shutdown implements the shutdown(2) linux unix.
Shutdown(t *kernel.Task, how int) *syserr.Error
// GetSockOpt implements the getsockopt(2) linux unix.
GetSockOpt(t *kernel.Task, level int, name int, outPtr hostarch.Addr, outLen int) (marshal.Marshallable, *syserr.Error)
// SetSockOpt implements the setsockopt(2) linux unix.
SetSockOpt(t *kernel.Task, level int, name int, opt []byte) *syserr.Error
// GetSockName implements the getsockname(2) linux unix.
//
// addrLen is the address length to be returned to the application, not
// necessarily the actual length of the address.
GetSockName(t *kernel.Task) (addr linux.SockAddr, addrLen uint32, err *syserr.Error)
// GetPeerName implements the getpeername(2) linux unix.
//
// addrLen is the address length to be returned to the application, not
// necessarily the actual length of the address.
GetPeerName(t *kernel.Task) (addr linux.SockAddr, addrLen uint32, err *syserr.Error)
// RecvMsg implements the recvmsg(2) linux unix.
//
// senderAddrLen is the address length to be returned to the application,
// not necessarily the actual length of the address.
//
// flags control how RecvMsg should be completed. msgFlags indicate how
// the RecvMsg call was completed. Note that control message truncation
// may still be required even if the MSG_CTRUNC bit is not set in
// msgFlags. In that case, the caller should set MSG_CTRUNC appropriately.
//
// If err != nil, the recv was not successful.
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 ControlMessages, err *syserr.Error)
// SendMsg implements the sendmsg(2) linux unix. SendMsg does not take
// ownership of the ControlMessage on error.
//
// If n > 0, err will either be nil or an error from t.Block.
SendMsg(t *kernel.Task, src usermem.IOSequence, to []byte, flags int, haveDeadline bool, deadline ktime.Time, controlMessages ControlMessages) (n int, err *syserr.Error)
// SetRecvTimeout sets the timeout (in ns) for recv operations. Zero means
// no timeout, and negative means DONTWAIT.
SetRecvTimeout(nanoseconds int64)
// RecvTimeout gets the current timeout (in ns) for recv operations. Zero
// means no timeout, and negative means DONTWAIT.
RecvTimeout() int64
// SetSendTimeout sets the timeout (in ns) for send operations. Zero means
// no timeout, and negative means DONTWAIT.
SetSendTimeout(nanoseconds int64)
// SendTimeout gets the current timeout (in ns) for send operations. Zero
// means no timeout, and negative means DONTWAIT.
SendTimeout() int64
// State returns the current state of the socket, as represented by Linux in
// procfs. The returned state value is protocol-specific.
State() uint32
// Type returns the family, socket type and protocol of the socket.
Type() (family int, skType linux.SockType, protocol int)
}
// Provider is the interface implemented by providers of sockets for specific
// address families (e.g., AF_INET).
type Provider interface {
// Socket creates a new socket.
//
// If a nil Socket _and_ a nil error is returned, it means that the
// protocol is not supported. A non-nil error should only be returned
// if the protocol is supported, but an error occurs during creation.
Socket(t *kernel.Task, stype linux.SockType, protocol int) (*fs.File, *syserr.Error)
// Pair creates a pair of connected sockets.
//
// See Socket for error information.
Pair(t *kernel.Task, stype linux.SockType, protocol int) (*fs.File, *fs.File, *syserr.Error)
}
// families holds a map of all known address families and their providers.
var families = make(map[int][]Provider)
// RegisterProvider registers the provider of a given address family so that
// sockets of that type can be created via socket() and/or socketpair()
// syscalls.
//
// This should only be called during the initialization of the address family.
func RegisterProvider(family int, provider Provider) {
families[family] = append(families[family], provider)
}
// New creates a new socket with the given family, type and protocol.
func New(t *kernel.Task, family int, stype linux.SockType, protocol int) (*fs.File, *syserr.Error) {
for _, p := range families[family] {
s, err := p.Socket(t, stype, protocol)
if err != nil {
return nil, err
}
if s != nil {
t.Kernel().RecordSocket(s)
return s, nil
}
}
return nil, syserr.ErrAddressFamilyNotSupported
}
// Pair creates a new connected socket pair with the given family, type and
// protocol.
func Pair(t *kernel.Task, family int, stype linux.SockType, protocol int) (*fs.File, *fs.File, *syserr.Error) {
providers, ok := families[family]
if !ok {
return nil, nil, syserr.ErrAddressFamilyNotSupported
}
for _, p := range providers {
s1, s2, err := p.Pair(t, stype, protocol)
if err != nil {
return nil, nil, err
}
if s1 != nil && s2 != nil {
k := t.Kernel()
k.RecordSocket(s1)
k.RecordSocket(s2)
return s1, s2, nil
}
}
return nil, nil, syserr.ErrSocketNotSupported
}
// NewDirent returns a sockfs fs.Dirent that resides on device d.
func NewDirent(ctx context.Context, d *device.Device) *fs.Dirent {
ino := d.NextIno()
iops := &fsutil.SimpleFileInode{
InodeSimpleAttributes: fsutil.NewInodeSimpleAttributes(ctx, fs.FileOwnerFromContext(ctx), fs.FilePermissions{
User: fs.PermMask{Read: true, Write: true},
}, linux.SOCKFS_MAGIC),
}
inode := fs.NewInode(ctx, iops, fs.NewPseudoMountSource(ctx), fs.StableAttr{
Type: fs.Socket,
DeviceID: d.DeviceID(),
InodeID: ino,
BlockSize: hostarch.PageSize,
})
// Dirent name matches net/socket.c:sockfs_dname.
return fs.NewDirent(ctx, inode, fmt.Sprintf("socket:[%d]", ino))
}
// ProviderVFS2 is the vfs2 interface implemented by providers of sockets for
// specific address families (e.g., AF_INET).
type ProviderVFS2 interface {
// Socket creates a new socket.
//
// If a nil Socket _and_ a nil error is returned, it means that the
// protocol is not supported. A non-nil error should only be returned
// if the protocol is supported, but an error occurs during creation.
Socket(t *kernel.Task, stype linux.SockType, protocol int) (*vfs.FileDescription, *syserr.Error)
// Pair creates a pair of connected sockets.
//
// See Socket for error information.
Pair(t *kernel.Task, stype linux.SockType, protocol int) (*vfs.FileDescription, *vfs.FileDescription, *syserr.Error)
}
// familiesVFS2 holds a map of all known address families and their providers.
var familiesVFS2 = make(map[int][]ProviderVFS2)
// RegisterProviderVFS2 registers the provider of a given address family so that
// sockets of that type can be created via socket() and/or socketpair()
// syscalls.
//
// This should only be called during the initialization of the address family.
func RegisterProviderVFS2(family int, provider ProviderVFS2) {
familiesVFS2[family] = append(familiesVFS2[family], provider)
}
// NewVFS2 creates a new socket with the given family, type and protocol.
func NewVFS2(t *kernel.Task, family int, stype linux.SockType, protocol int) (*vfs.FileDescription, *syserr.Error) {
for _, p := range familiesVFS2[family] {
s, err := p.Socket(t, stype, protocol)
if err != nil {
return nil, err
}
if s != nil {
t.Kernel().RecordSocketVFS2(s)
return s, nil
}
}
return nil, syserr.ErrAddressFamilyNotSupported
}
// PairVFS2 creates a new connected socket pair with the given family, type and
// protocol.
func PairVFS2(t *kernel.Task, family int, stype linux.SockType, protocol int) (*vfs.FileDescription, *vfs.FileDescription, *syserr.Error) {
providers, ok := familiesVFS2[family]
if !ok {
return nil, nil, syserr.ErrAddressFamilyNotSupported
}
for _, p := range providers {
s1, s2, err := p.Pair(t, stype, protocol)
if err != nil {
return nil, nil, err
}
if s1 != nil && s2 != nil {
k := t.Kernel()
k.RecordSocketVFS2(s1)
k.RecordSocketVFS2(s2)
return s1, s2, nil
}
}
return nil, nil, syserr.ErrSocketNotSupported
}
// SendReceiveTimeout stores timeouts for send and receive calls.
//
// It is meant to be embedded into Socket implementations to help satisfy the
// interface.
//
// Care must be taken when copying SendReceiveTimeout as it contains atomic
// variables.
//
// +stateify savable
type SendReceiveTimeout struct {
// send is length of the send timeout in nanoseconds.
//
// send must be accessed atomically.
send int64
// recv is length of the receive timeout in nanoseconds.
//
// recv must be accessed atomically.
recv int64
}
// SetRecvTimeout implements Socket.SetRecvTimeout.
func (to *SendReceiveTimeout) SetRecvTimeout(nanoseconds int64) {
atomic.StoreInt64(&to.recv, nanoseconds)
}
// RecvTimeout implements Socket.RecvTimeout.
func (to *SendReceiveTimeout) RecvTimeout() int64 {
return atomic.LoadInt64(&to.recv)
}
// SetSendTimeout implements Socket.SetSendTimeout.
func (to *SendReceiveTimeout) SetSendTimeout(nanoseconds int64) {
atomic.StoreInt64(&to.send, nanoseconds)
}
// SendTimeout implements Socket.SendTimeout.
func (to *SendReceiveTimeout) SendTimeout() int64 {
return atomic.LoadInt64(&to.send)
}
// GetSockOptEmitUnimplementedEvent emits unimplemented event if name is valid.
// It contains names that are valid for GetSockOpt when level is SOL_SOCKET.
func GetSockOptEmitUnimplementedEvent(t *kernel.Task, name int) {
switch name {
case linux.SO_ACCEPTCONN,
linux.SO_BPF_EXTENSIONS,
linux.SO_COOKIE,
linux.SO_DOMAIN,
linux.SO_ERROR,
linux.SO_GET_FILTER,
linux.SO_INCOMING_NAPI_ID,
linux.SO_MEMINFO,
linux.SO_PEERCRED,
linux.SO_PEERGROUPS,
linux.SO_PEERNAME,
linux.SO_PEERSEC,
linux.SO_PROTOCOL,
linux.SO_SNDLOWAT,
linux.SO_TYPE:
t.Kernel().EmitUnimplementedEvent(t)
default:
emitUnimplementedEvent(t, name)
}
}
// SetSockOptEmitUnimplementedEvent emits unimplemented event if name is valid.
// It contains names that are valid for SetSockOpt when level is SOL_SOCKET.
func SetSockOptEmitUnimplementedEvent(t *kernel.Task, name int) {
switch name {
case linux.SO_ATTACH_BPF,
linux.SO_ATTACH_FILTER,
linux.SO_ATTACH_REUSEPORT_CBPF,
linux.SO_ATTACH_REUSEPORT_EBPF,
linux.SO_CNX_ADVICE,
linux.SO_DETACH_FILTER,
linux.SO_RCVBUFFORCE,
linux.SO_SNDBUFFORCE:
t.Kernel().EmitUnimplementedEvent(t)
default:
emitUnimplementedEvent(t, name)
}
}
// emitUnimplementedEvent emits unimplemented event if name is valid. It
// contains names that are common between Get and SetSocketOpt when level is
// SOL_SOCKET.
func emitUnimplementedEvent(t *kernel.Task, name int) {
switch name {
case linux.SO_BINDTODEVICE,
linux.SO_BROADCAST,
linux.SO_BSDCOMPAT,
linux.SO_BUSY_POLL,
linux.SO_DEBUG,
linux.SO_DONTROUTE,
linux.SO_INCOMING_CPU,
linux.SO_KEEPALIVE,
linux.SO_LINGER,
linux.SO_LOCK_FILTER,
linux.SO_MARK,
linux.SO_MAX_PACING_RATE,
linux.SO_NOFCS,
linux.SO_OOBINLINE,
linux.SO_PASSCRED,
linux.SO_PASSSEC,
linux.SO_PEEK_OFF,
linux.SO_PRIORITY,
linux.SO_RCVBUF,
linux.SO_RCVLOWAT,
linux.SO_RCVTIMEO,
linux.SO_REUSEADDR,
linux.SO_REUSEPORT,
linux.SO_RXQ_OVFL,
linux.SO_SELECT_ERR_QUEUE,
linux.SO_SNDBUF,
linux.SO_SNDTIMEO,
linux.SO_TIMESTAMP,
linux.SO_TIMESTAMPING,
linux.SO_TIMESTAMPNS,
linux.SO_TXTIME,
linux.SO_WIFI_STATUS,
linux.SO_ZEROCOPY:
t.Kernel().EmitUnimplementedEvent(t)
}
}
// UnmarshalSockAddr unmarshals memory representing a struct sockaddr to one of
// the ABI socket address types.
//
// Precondition: data must be long enough to represent a socket address of the
// given family.
func UnmarshalSockAddr(family int, data []byte) linux.SockAddr {
switch family {
case unix.AF_INET:
var addr linux.SockAddrInet
addr.UnmarshalUnsafe(data[:addr.SizeBytes()])
return &addr
case unix.AF_INET6:
var addr linux.SockAddrInet6
addr.UnmarshalUnsafe(data[:addr.SizeBytes()])
return &addr
case unix.AF_UNIX:
var addr linux.SockAddrUnix
addr.UnmarshalUnsafe(data[:addr.SizeBytes()])
return &addr
case unix.AF_NETLINK:
var addr linux.SockAddrNetlink
addr.UnmarshalUnsafe(data[:addr.SizeBytes()])
return &addr
default:
panic(fmt.Sprintf("Unsupported socket family %v", family))
}
}
var sockAddrLinkSize = (&linux.SockAddrLink{}).SizeBytes()
var sockAddrInetSize = (&linux.SockAddrInet{}).SizeBytes()
var sockAddrInet6Size = (&linux.SockAddrInet6{}).SizeBytes()
// Ntohs converts a 16-bit number from network byte order to host byte order. It
// assumes that the host is little endian.
func Ntohs(v uint16) uint16 {
return v<<8 | v>>8
}
// Htons converts a 16-bit number from host byte order to network byte order. It
// assumes that the host is little endian.
func Htons(v uint16) uint16 {
return Ntohs(v)
}
// isLinkLocal determines if the given IPv6 address is link-local. This is the
// case when it has the fe80::/10 prefix. This check is used to determine when
// the NICID is relevant for a given IPv6 address.
func isLinkLocal(addr tcpip.Address) bool {
return len(addr) >= 2 && addr[0] == 0xfe && addr[1]&0xc0 == 0x80
}
// ConvertAddress converts the given address to a native format.
func ConvertAddress(family int, addr tcpip.FullAddress) (linux.SockAddr, uint32) {
switch family {
case linux.AF_UNIX:
var out linux.SockAddrUnix
out.Family = linux.AF_UNIX
l := len([]byte(addr.Addr))
for i := 0; i < l; i++ {
out.Path[i] = int8(addr.Addr[i])
}
// Linux returns the used length of the address struct (including the
// null terminator) for filesystem paths. The Family field is 2 bytes.
// It is sometimes allowed to exclude the null terminator if the
// address length is the max. Abstract and empty paths always return
// the full exact length.
if l == 0 || out.Path[0] == 0 || l == len(out.Path) {
return &out, uint32(2 + l)
}
return &out, uint32(3 + l)
case linux.AF_INET:
var out linux.SockAddrInet
copy(out.Addr[:], addr.Addr)
out.Family = linux.AF_INET
out.Port = Htons(addr.Port)
return &out, uint32(sockAddrInetSize)
case linux.AF_INET6:
var out linux.SockAddrInet6
if len(addr.Addr) == header.IPv4AddressSize {
// Copy address in v4-mapped format.
copy(out.Addr[12:], addr.Addr)
out.Addr[10] = 0xff
out.Addr[11] = 0xff
} else {
copy(out.Addr[:], addr.Addr)
}
out.Family = linux.AF_INET6
out.Port = Htons(addr.Port)
if isLinkLocal(addr.Addr) {
out.Scope_id = uint32(addr.NIC)
}
return &out, uint32(sockAddrInet6Size)
case linux.AF_PACKET:
var out linux.SockAddrLink
out.Family = linux.AF_PACKET
out.InterfaceIndex = int32(addr.NIC)
out.HardwareAddrLen = header.EthernetAddressSize
copy(out.HardwareAddr[:], addr.Addr)
return &out, uint32(sockAddrLinkSize)
default:
return nil, 0
}
}
// BytesToIPAddress converts an IPv4 or IPv6 address from the user to the
// netstack representation taking any addresses into account.
func BytesToIPAddress(addr []byte) tcpip.Address {
if bytes.Equal(addr, make([]byte, 4)) || bytes.Equal(addr, make([]byte, 16)) {
return ""
}
return tcpip.Address(addr)
}
// AddressAndFamily reads an sockaddr struct from the given address and
// converts it to the FullAddress format. It supports AF_UNIX, AF_INET,
// AF_INET6, and AF_PACKET addresses.
//
// AddressAndFamily returns an address and its family.
func AddressAndFamily(addr []byte) (tcpip.FullAddress, uint16, *syserr.Error) {
// Make sure we have at least 2 bytes for the address family.
if len(addr) < 2 {
return tcpip.FullAddress{}, 0, syserr.ErrInvalidArgument
}
// Get the rest of the fields based on the address family.
switch family := hostarch.ByteOrder.Uint16(addr); family {
case linux.AF_UNIX:
path := addr[2:]
if len(path) > linux.UnixPathMax {
return tcpip.FullAddress{}, family, syserr.ErrInvalidArgument
}
// Drop the terminating NUL (if one exists) and everything after
// it for filesystem (non-abstract) addresses.
if len(path) > 0 && path[0] != 0 {
if n := bytes.IndexByte(path[1:], 0); n >= 0 {
path = path[:n+1]
}
}
return tcpip.FullAddress{
Addr: tcpip.Address(path),
}, family, nil
case linux.AF_INET:
var a linux.SockAddrInet
if len(addr) < sockAddrInetSize {
return tcpip.FullAddress{}, family, syserr.ErrInvalidArgument
}
a.UnmarshalUnsafe(addr[:sockAddrInetSize])
out := tcpip.FullAddress{
Addr: BytesToIPAddress(a.Addr[:]),
Port: Ntohs(a.Port),
}
return out, family, nil
case linux.AF_INET6:
var a linux.SockAddrInet6
if len(addr) < sockAddrInet6Size {
return tcpip.FullAddress{}, family, syserr.ErrInvalidArgument
}
a.UnmarshalUnsafe(addr[:sockAddrInet6Size])
out := tcpip.FullAddress{
Addr: BytesToIPAddress(a.Addr[:]),
Port: Ntohs(a.Port),
}
if isLinkLocal(out.Addr) {
out.NIC = tcpip.NICID(a.Scope_id)
}
return out, family, nil
case linux.AF_PACKET:
var a linux.SockAddrLink
if len(addr) < sockAddrLinkSize {
return tcpip.FullAddress{}, family, syserr.ErrInvalidArgument
}
a.UnmarshalUnsafe(addr[:sockAddrLinkSize])
if a.Family != linux.AF_PACKET || a.HardwareAddrLen != header.EthernetAddressSize {
return tcpip.FullAddress{}, family, syserr.ErrInvalidArgument
}
return tcpip.FullAddress{
NIC: tcpip.NICID(a.InterfaceIndex),
Addr: tcpip.Address(a.HardwareAddr[:header.EthernetAddressSize]),
}, family, nil
case linux.AF_UNSPEC:
return tcpip.FullAddress{}, family, nil
default:
return tcpip.FullAddress{}, 0, syserr.ErrAddressFamilyNotSupported
}
}
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