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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 netstack provides an implementation of the socket.Socket interface
// that is backed by a tcpip.Endpoint.
//
// It does not depend on any particular endpoint implementation, and thus can
// be used to expose certain endpoints to the sentry while leaving others out,
// for example, TCP endpoints and Unix-domain endpoints.
//
// Lock ordering: netstack => mm: ioSequencePayload copies user memory inside
// tcpip.Endpoint.Write(). Netstack is allowed to (and does) hold locks during
// this operation.
package netstack
import (
"bytes"
"fmt"
"io"
"math"
"reflect"
"sync/atomic"
"syscall"
"time"
"golang.org/x/sys/unix"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/amutex"
"gvisor.dev/gvisor/pkg/binary"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/log"
"gvisor.dev/gvisor/pkg/marshal"
"gvisor.dev/gvisor/pkg/marshal/primitive"
"gvisor.dev/gvisor/pkg/metric"
"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/inet"
"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/netfilter"
"gvisor.dev/gvisor/pkg/sentry/unimpl"
"gvisor.dev/gvisor/pkg/sync"
"gvisor.dev/gvisor/pkg/syserr"
"gvisor.dev/gvisor/pkg/syserror"
"gvisor.dev/gvisor/pkg/tcpip"
"gvisor.dev/gvisor/pkg/tcpip/buffer"
"gvisor.dev/gvisor/pkg/tcpip/header"
"gvisor.dev/gvisor/pkg/tcpip/stack"
"gvisor.dev/gvisor/pkg/tcpip/transport/tcp"
"gvisor.dev/gvisor/pkg/tcpip/transport/udp"
"gvisor.dev/gvisor/pkg/usermem"
"gvisor.dev/gvisor/pkg/waiter"
)
func mustCreateMetric(name, description string) *tcpip.StatCounter {
var cm tcpip.StatCounter
metric.MustRegisterCustomUint64Metric(name, true /* cumulative */, false /* sync */, description, cm.Value)
return &cm
}
func mustCreateGauge(name, description string) *tcpip.StatCounter {
var cm tcpip.StatCounter
metric.MustRegisterCustomUint64Metric(name, false /* cumulative */, false /* sync */, description, cm.Value)
return &cm
}
// Metrics contains metrics exported by netstack.
var Metrics = tcpip.Stats{
UnknownProtocolRcvdPackets: mustCreateMetric("/netstack/unknown_protocol_received_packets", "Number of packets received by netstack that were for an unknown or unsupported protocol."),
MalformedRcvdPackets: mustCreateMetric("/netstack/malformed_received_packets", "Number of packets received by netstack that were deemed malformed."),
DroppedPackets: mustCreateMetric("/netstack/dropped_packets", "Number of packets dropped by netstack due to full queues."),
ICMP: tcpip.ICMPStats{
V4: tcpip.ICMPv4Stats{
PacketsSent: tcpip.ICMPv4SentPacketStats{
ICMPv4PacketStats: tcpip.ICMPv4PacketStats{
Echo: mustCreateMetric("/netstack/icmp/v4/packets_sent/echo", "Total number of ICMPv4 echo packets sent by netstack."),
EchoReply: mustCreateMetric("/netstack/icmp/v4/packets_sent/echo_reply", "Total number of ICMPv4 echo reply packets sent by netstack."),
DstUnreachable: mustCreateMetric("/netstack/icmp/v4/packets_sent/dst_unreachable", "Total number of ICMPv4 destination unreachable packets sent by netstack."),
SrcQuench: mustCreateMetric("/netstack/icmp/v4/packets_sent/src_quench", "Total number of ICMPv4 source quench packets sent by netstack."),
Redirect: mustCreateMetric("/netstack/icmp/v4/packets_sent/redirect", "Total number of ICMPv4 redirect packets sent by netstack."),
TimeExceeded: mustCreateMetric("/netstack/icmp/v4/packets_sent/time_exceeded", "Total number of ICMPv4 time exceeded packets sent by netstack."),
ParamProblem: mustCreateMetric("/netstack/icmp/v4/packets_sent/param_problem", "Total number of ICMPv4 parameter problem packets sent by netstack."),
Timestamp: mustCreateMetric("/netstack/icmp/v4/packets_sent/timestamp", "Total number of ICMPv4 timestamp packets sent by netstack."),
TimestampReply: mustCreateMetric("/netstack/icmp/v4/packets_sent/timestamp_reply", "Total number of ICMPv4 timestamp reply packets sent by netstack."),
InfoRequest: mustCreateMetric("/netstack/icmp/v4/packets_sent/info_request", "Total number of ICMPv4 information request packets sent by netstack."),
InfoReply: mustCreateMetric("/netstack/icmp/v4/packets_sent/info_reply", "Total number of ICMPv4 information reply packets sent by netstack."),
},
Dropped: mustCreateMetric("/netstack/icmp/v4/packets_sent/dropped", "Total number of ICMPv4 packets dropped by netstack due to link layer errors."),
},
PacketsReceived: tcpip.ICMPv4ReceivedPacketStats{
ICMPv4PacketStats: tcpip.ICMPv4PacketStats{
Echo: mustCreateMetric("/netstack/icmp/v4/packets_received/echo", "Total number of ICMPv4 echo packets received by netstack."),
EchoReply: mustCreateMetric("/netstack/icmp/v4/packets_received/echo_reply", "Total number of ICMPv4 echo reply packets received by netstack."),
DstUnreachable: mustCreateMetric("/netstack/icmp/v4/packets_received/dst_unreachable", "Total number of ICMPv4 destination unreachable packets received by netstack."),
SrcQuench: mustCreateMetric("/netstack/icmp/v4/packets_received/src_quench", "Total number of ICMPv4 source quench packets received by netstack."),
Redirect: mustCreateMetric("/netstack/icmp/v4/packets_received/redirect", "Total number of ICMPv4 redirect packets received by netstack."),
TimeExceeded: mustCreateMetric("/netstack/icmp/v4/packets_received/time_exceeded", "Total number of ICMPv4 time exceeded packets received by netstack."),
ParamProblem: mustCreateMetric("/netstack/icmp/v4/packets_received/param_problem", "Total number of ICMPv4 parameter problem packets received by netstack."),
Timestamp: mustCreateMetric("/netstack/icmp/v4/packets_received/timestamp", "Total number of ICMPv4 timestamp packets received by netstack."),
TimestampReply: mustCreateMetric("/netstack/icmp/v4/packets_received/timestamp_reply", "Total number of ICMPv4 timestamp reply packets received by netstack."),
InfoRequest: mustCreateMetric("/netstack/icmp/v4/packets_received/info_request", "Total number of ICMPv4 information request packets received by netstack."),
InfoReply: mustCreateMetric("/netstack/icmp/v4/packets_received/info_reply", "Total number of ICMPv4 information reply packets received by netstack."),
},
Invalid: mustCreateMetric("/netstack/icmp/v4/packets_received/invalid", "Total number of ICMPv4 packets received that the transport layer could not parse."),
},
},
V6: tcpip.ICMPv6Stats{
PacketsSent: tcpip.ICMPv6SentPacketStats{
ICMPv6PacketStats: tcpip.ICMPv6PacketStats{
EchoRequest: mustCreateMetric("/netstack/icmp/v6/packets_sent/echo_request", "Total number of ICMPv6 echo request packets sent by netstack."),
EchoReply: mustCreateMetric("/netstack/icmp/v6/packets_sent/echo_reply", "Total number of ICMPv6 echo reply packets sent by netstack."),
DstUnreachable: mustCreateMetric("/netstack/icmp/v6/packets_sent/dst_unreachable", "Total number of ICMPv6 destination unreachable packets sent by netstack."),
PacketTooBig: mustCreateMetric("/netstack/icmp/v6/packets_sent/packet_too_big", "Total number of ICMPv6 packet too big packets sent by netstack."),
TimeExceeded: mustCreateMetric("/netstack/icmp/v6/packets_sent/time_exceeded", "Total number of ICMPv6 time exceeded packets sent by netstack."),
ParamProblem: mustCreateMetric("/netstack/icmp/v6/packets_sent/param_problem", "Total number of ICMPv6 parameter problem packets sent by netstack."),
RouterSolicit: mustCreateMetric("/netstack/icmp/v6/packets_sent/router_solicit", "Total number of ICMPv6 router solicit packets sent by netstack."),
RouterAdvert: mustCreateMetric("/netstack/icmp/v6/packets_sent/router_advert", "Total number of ICMPv6 router advert packets sent by netstack."),
NeighborSolicit: mustCreateMetric("/netstack/icmp/v6/packets_sent/neighbor_solicit", "Total number of ICMPv6 neighbor solicit packets sent by netstack."),
NeighborAdvert: mustCreateMetric("/netstack/icmp/v6/packets_sent/neighbor_advert", "Total number of ICMPv6 neighbor advert packets sent by netstack."),
RedirectMsg: mustCreateMetric("/netstack/icmp/v6/packets_sent/redirect_msg", "Total number of ICMPv6 redirect message packets sent by netstack."),
},
Dropped: mustCreateMetric("/netstack/icmp/v6/packets_sent/dropped", "Total number of ICMPv6 packets dropped by netstack due to link layer errors."),
},
PacketsReceived: tcpip.ICMPv6ReceivedPacketStats{
ICMPv6PacketStats: tcpip.ICMPv6PacketStats{
EchoRequest: mustCreateMetric("/netstack/icmp/v6/packets_received/echo_request", "Total number of ICMPv6 echo request packets received by netstack."),
EchoReply: mustCreateMetric("/netstack/icmp/v6/packets_received/echo_reply", "Total number of ICMPv6 echo reply packets received by netstack."),
DstUnreachable: mustCreateMetric("/netstack/icmp/v6/packets_received/dst_unreachable", "Total number of ICMPv6 destination unreachable packets received by netstack."),
PacketTooBig: mustCreateMetric("/netstack/icmp/v6/packets_received/packet_too_big", "Total number of ICMPv6 packet too big packets received by netstack."),
TimeExceeded: mustCreateMetric("/netstack/icmp/v6/packets_received/time_exceeded", "Total number of ICMPv6 time exceeded packets received by netstack."),
ParamProblem: mustCreateMetric("/netstack/icmp/v6/packets_received/param_problem", "Total number of ICMPv6 parameter problem packets received by netstack."),
RouterSolicit: mustCreateMetric("/netstack/icmp/v6/packets_received/router_solicit", "Total number of ICMPv6 router solicit packets received by netstack."),
RouterAdvert: mustCreateMetric("/netstack/icmp/v6/packets_received/router_advert", "Total number of ICMPv6 router advert packets received by netstack."),
NeighborSolicit: mustCreateMetric("/netstack/icmp/v6/packets_received/neighbor_solicit", "Total number of ICMPv6 neighbor solicit packets received by netstack."),
NeighborAdvert: mustCreateMetric("/netstack/icmp/v6/packets_received/neighbor_advert", "Total number of ICMPv6 neighbor advert packets received by netstack."),
RedirectMsg: mustCreateMetric("/netstack/icmp/v6/packets_received/redirect_msg", "Total number of ICMPv6 redirect message packets received by netstack."),
},
Invalid: mustCreateMetric("/netstack/icmp/v6/packets_received/invalid", "Total number of ICMPv6 packets received that the transport layer could not parse."),
},
},
},
IGMP: tcpip.IGMPStats{
PacketsSent: tcpip.IGMPSentPacketStats{
IGMPPacketStats: tcpip.IGMPPacketStats{
MembershipQuery: mustCreateMetric("/netstack/igmp/packets_sent/membership_query", "Total number of IGMP Membership Query messages sent by netstack."),
V1MembershipReport: mustCreateMetric("/netstack/igmp/packets_sent/v1_membership_report", "Total number of IGMPv1 Membership Report messages sent by netstack."),
V2MembershipReport: mustCreateMetric("/netstack/igmp/packets_sent/v2_membership_report", "Total number of IGMPv2 Membership Report messages sent by netstack."),
LeaveGroup: mustCreateMetric("/netstack/igmp/packets_sent/leave_group", "Total number of IGMP Leave Group messages sent by netstack."),
},
Dropped: mustCreateMetric("/netstack/igmp/packets_sent/dropped", "Total number of IGMP packets dropped by netstack due to link layer errors."),
},
PacketsReceived: tcpip.IGMPReceivedPacketStats{
IGMPPacketStats: tcpip.IGMPPacketStats{
MembershipQuery: mustCreateMetric("/netstack/igmp/packets_received/membership_query", "Total number of IGMP Membership Query messages received by netstack."),
V1MembershipReport: mustCreateMetric("/netstack/igmp/packets_received/v1_membership_report", "Total number of IGMPv1 Membership Report messages received by netstack."),
V2MembershipReport: mustCreateMetric("/netstack/igmp/packets_received/v2_membership_report", "Total number of IGMPv2 Membership Report messages received by netstack."),
LeaveGroup: mustCreateMetric("/netstack/igmp/packets_received/leave_group", "Total number of IGMP Leave Group messages received by netstack."),
},
Invalid: mustCreateMetric("/netstack/igmp/packets_received/invalid", "Total number of IGMP packets received by netstack that could not be parsed."),
ChecksumErrors: mustCreateMetric("/netstack/igmp/packets_received/checksum_errors", "Total number of received IGMP packets with bad checksums."),
Unrecognized: mustCreateMetric("/netstack/igmp/packets_received/unrecognized", "Total number of unrecognized IGMP packets received by netstack."),
},
},
IP: tcpip.IPStats{
PacketsReceived: mustCreateMetric("/netstack/ip/packets_received", "Total number of IP packets received from the link layer in nic.DeliverNetworkPacket."),
InvalidDestinationAddressesReceived: mustCreateMetric("/netstack/ip/invalid_addresses_received", "Total number of IP packets received with an unknown or invalid destination address."),
InvalidSourceAddressesReceived: mustCreateMetric("/netstack/ip/invalid_source_addresses_received", "Total number of IP packets received with an unknown or invalid source address."),
PacketsDelivered: mustCreateMetric("/netstack/ip/packets_delivered", "Total number of incoming IP packets that are successfully delivered to the transport layer via HandlePacket."),
PacketsSent: mustCreateMetric("/netstack/ip/packets_sent", "Total number of IP packets sent via WritePacket."),
OutgoingPacketErrors: mustCreateMetric("/netstack/ip/outgoing_packet_errors", "Total number of IP packets which failed to write to a link-layer endpoint."),
MalformedPacketsReceived: mustCreateMetric("/netstack/ip/malformed_packets_received", "Total number of IP packets which failed IP header validation checks."),
MalformedFragmentsReceived: mustCreateMetric("/netstack/ip/malformed_fragments_received", "Total number of IP fragments which failed IP fragment validation checks."),
IPTablesPreroutingDropped: mustCreateMetric("/netstack/ip/iptables/prerouting_dropped", "Total number of IP packets dropped in the Prerouting chain."),
IPTablesInputDropped: mustCreateMetric("/netstack/ip/iptables/input_dropped", "Total number of IP packets dropped in the Input chain."),
IPTablesOutputDropped: mustCreateMetric("/netstack/ip/iptables/output_dropped", "Total number of IP packets dropped in the Output chain."),
},
TCP: tcpip.TCPStats{
ActiveConnectionOpenings: mustCreateMetric("/netstack/tcp/active_connection_openings", "Number of connections opened successfully via Connect."),
PassiveConnectionOpenings: mustCreateMetric("/netstack/tcp/passive_connection_openings", "Number of connections opened successfully via Listen."),
CurrentEstablished: mustCreateGauge("/netstack/tcp/current_established", "Number of connections in ESTABLISHED state now."),
CurrentConnected: mustCreateGauge("/netstack/tcp/current_open", "Number of connections that are in connected state."),
EstablishedResets: mustCreateMetric("/netstack/tcp/established_resets", "Number of times TCP connections have made a direct transition to the CLOSED state from either the ESTABLISHED state or the CLOSE-WAIT state"),
EstablishedClosed: mustCreateMetric("/netstack/tcp/established_closed", "Number of times established TCP connections made a transition to CLOSED state."),
EstablishedTimedout: mustCreateMetric("/netstack/tcp/established_timedout", "Number of times an established connection was reset because of keep-alive time out."),
ListenOverflowSynDrop: mustCreateMetric("/netstack/tcp/listen_overflow_syn_drop", "Number of times the listen queue overflowed and a SYN was dropped."),
ListenOverflowAckDrop: mustCreateMetric("/netstack/tcp/listen_overflow_ack_drop", "Number of times the listen queue overflowed and the final ACK in the handshake was dropped."),
ListenOverflowSynCookieSent: mustCreateMetric("/netstack/tcp/listen_overflow_syn_cookie_sent", "Number of times a SYN cookie was sent."),
ListenOverflowSynCookieRcvd: mustCreateMetric("/netstack/tcp/listen_overflow_syn_cookie_rcvd", "Number of times a SYN cookie was received."),
ListenOverflowInvalidSynCookieRcvd: mustCreateMetric("/netstack/tcp/listen_overflow_invalid_syn_cookie_rcvd", "Number of times an invalid SYN cookie was received."),
FailedConnectionAttempts: mustCreateMetric("/netstack/tcp/failed_connection_attempts", "Number of calls to Connect or Listen (active and passive openings, respectively) that end in an error."),
ValidSegmentsReceived: mustCreateMetric("/netstack/tcp/valid_segments_received", "Number of TCP segments received that the transport layer successfully parsed."),
InvalidSegmentsReceived: mustCreateMetric("/netstack/tcp/invalid_segments_received", "Number of TCP segments received that the transport layer could not parse."),
SegmentsSent: mustCreateMetric("/netstack/tcp/segments_sent", "Number of TCP segments sent."),
SegmentSendErrors: mustCreateMetric("/netstack/tcp/segment_send_errors", "Number of TCP segments failed to be sent."),
ResetsSent: mustCreateMetric("/netstack/tcp/resets_sent", "Number of TCP resets sent."),
ResetsReceived: mustCreateMetric("/netstack/tcp/resets_received", "Number of TCP resets received."),
Retransmits: mustCreateMetric("/netstack/tcp/retransmits", "Number of TCP segments retransmitted."),
FastRecovery: mustCreateMetric("/netstack/tcp/fast_recovery", "Number of times fast recovery was used to recover from packet loss."),
SACKRecovery: mustCreateMetric("/netstack/tcp/sack_recovery", "Number of times SACK recovery was used to recover from packet loss."),
SlowStartRetransmits: mustCreateMetric("/netstack/tcp/slow_start_retransmits", "Number of segments retransmitted in slow start mode."),
FastRetransmit: mustCreateMetric("/netstack/tcp/fast_retransmit", "Number of TCP segments which were fast retransmitted."),
Timeouts: mustCreateMetric("/netstack/tcp/timeouts", "Number of times RTO expired."),
ChecksumErrors: mustCreateMetric("/netstack/tcp/checksum_errors", "Number of segments dropped due to bad checksums."),
},
UDP: tcpip.UDPStats{
PacketsReceived: mustCreateMetric("/netstack/udp/packets_received", "Number of UDP datagrams received via HandlePacket."),
UnknownPortErrors: mustCreateMetric("/netstack/udp/unknown_port_errors", "Number of incoming UDP datagrams dropped because they did not have a known destination port."),
ReceiveBufferErrors: mustCreateMetric("/netstack/udp/receive_buffer_errors", "Number of incoming UDP datagrams dropped due to the receiving buffer being in an invalid state."),
MalformedPacketsReceived: mustCreateMetric("/netstack/udp/malformed_packets_received", "Number of incoming UDP datagrams dropped due to the UDP header being in a malformed state."),
PacketsSent: mustCreateMetric("/netstack/udp/packets_sent", "Number of UDP datagrams sent."),
PacketSendErrors: mustCreateMetric("/netstack/udp/packet_send_errors", "Number of UDP datagrams failed to be sent."),
ChecksumErrors: mustCreateMetric("/netstack/udp/checksum_errors", "Number of UDP datagrams dropped due to bad checksums."),
},
}
// DefaultTTL is linux's default TTL. All network protocols in all stacks used
// with this package must have this value set as their default TTL.
const DefaultTTL = 64
const sizeOfInt32 int = 4
var errStackType = syserr.New("expected but did not receive a netstack.Stack", linux.EINVAL)
// commonEndpoint represents the intersection of a tcpip.Endpoint and a
// transport.Endpoint.
type commonEndpoint interface {
// GetLocalAddress implements tcpip.Endpoint.GetLocalAddress and
// transport.Endpoint.GetLocalAddress.
GetLocalAddress() (tcpip.FullAddress, *tcpip.Error)
// GetRemoteAddress implements tcpip.Endpoint.GetRemoteAddress and
// transport.Endpoint.GetRemoteAddress.
GetRemoteAddress() (tcpip.FullAddress, *tcpip.Error)
// Readiness implements tcpip.Endpoint.Readiness and
// transport.Endpoint.Readiness.
Readiness(mask waiter.EventMask) waiter.EventMask
// SetSockOpt implements tcpip.Endpoint.SetSockOpt and
// transport.Endpoint.SetSockOpt.
SetSockOpt(tcpip.SettableSocketOption) *tcpip.Error
// SetSockOptInt implements tcpip.Endpoint.SetSockOptInt and
// transport.Endpoint.SetSockOptInt.
SetSockOptInt(opt tcpip.SockOptInt, v int) *tcpip.Error
// GetSockOpt implements tcpip.Endpoint.GetSockOpt and
// transport.Endpoint.GetSockOpt.
GetSockOpt(tcpip.GettableSocketOption) *tcpip.Error
// GetSockOptInt implements tcpip.Endpoint.GetSockOptInt and
// transport.Endpoint.GetSockOpt.
GetSockOptInt(opt tcpip.SockOptInt) (int, *tcpip.Error)
// State returns a socket's lifecycle state. The returned value is
// protocol-specific and is primarily used for diagnostics.
State() uint32
// LastError implements tcpip.Endpoint.LastError and
// transport.Endpoint.LastError.
LastError() *tcpip.Error
// SocketOptions implements tcpip.Endpoint.SocketOptions and
// transport.Endpoint.SocketOptions.
SocketOptions() *tcpip.SocketOptions
}
// LINT.IfChange
// SocketOperations encapsulates all the state needed to represent a network stack
// endpoint in the kernel context.
//
// +stateify savable
type SocketOperations struct {
fsutil.FilePipeSeek `state:"nosave"`
fsutil.FileNotDirReaddir `state:"nosave"`
fsutil.FileNoopFlush `state:"nosave"`
fsutil.FileNoFsync `state:"nosave"`
fsutil.FileNoMMap `state:"nosave"`
fsutil.FileUseInodeUnstableAttr `state:"nosave"`
socketOpsCommon
}
// socketOpsCommon contains the socket operations common to VFS1 and VFS2.
//
// +stateify savable
type socketOpsCommon struct {
socket.SendReceiveTimeout
*waiter.Queue
family int
Endpoint tcpip.Endpoint
skType linux.SockType
protocol int
// readViewHasData is 1 iff readView has data to be read, 0 otherwise.
// Must be accessed using atomic operations. It must only be written
// with readMu held but can be read without holding readMu. The latter
// is required to avoid deadlocks in epoll Readiness checks.
readViewHasData uint32
// readMu protects access to the below fields.
readMu sync.Mutex `state:"nosave"`
// readView contains the remaining payload from the last packet.
readView buffer.View
// readCM holds control message information for the last packet read
// from Endpoint.
readCM socket.IPControlMessages
sender tcpip.FullAddress
linkPacketInfo tcpip.LinkPacketInfo
// sockOptTimestamp corresponds to SO_TIMESTAMP. When true, timestamps
// of returned messages can be returned via control messages. When
// false, the same timestamp is instead stored and can be read via the
// SIOCGSTAMP ioctl. It is protected by readMu. See socket(7).
sockOptTimestamp bool
// timestampValid indicates whether timestamp for SIOCGSTAMP has been
// set. It is protected by readMu.
timestampValid bool
// timestampNS holds the timestamp to use with SIOCTSTAMP. It is only
// valid when timestampValid is true. It is protected by readMu.
timestampNS int64
// sockOptInq corresponds to TCP_INQ. It is implemented at this level
// because it takes into account data from readView.
sockOptInq bool
}
// New creates a new endpoint socket.
func New(t *kernel.Task, family int, skType linux.SockType, protocol int, queue *waiter.Queue, endpoint tcpip.Endpoint) (*fs.File, *syserr.Error) {
if skType == linux.SOCK_STREAM {
endpoint.SocketOptions().SetDelayOption(true)
}
dirent := socket.NewDirent(t, netstackDevice)
defer dirent.DecRef(t)
return fs.NewFile(t, dirent, fs.FileFlags{Read: true, Write: true, NonSeekable: true}, &SocketOperations{
socketOpsCommon: socketOpsCommon{
Queue: queue,
family: family,
Endpoint: endpoint,
skType: skType,
protocol: protocol,
},
}), nil
}
var sockAddrInetSize = int(binary.Size(linux.SockAddrInet{}))
var sockAddrInet6Size = int(binary.Size(linux.SockAddrInet6{}))
var sockAddrLinkSize = int(binary.Size(linux.SockAddrLink{}))
// 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)
}
func (s *socketOpsCommon) isPacketBased() bool {
return s.skType == linux.SOCK_DGRAM || s.skType == linux.SOCK_SEQPACKET || s.skType == linux.SOCK_RDM || s.skType == linux.SOCK_RAW
}
// fetchReadView updates the readView field of the socket if it's currently
// empty. It assumes that the socket is locked.
//
// Precondition: s.readMu must be held.
func (s *socketOpsCommon) fetchReadView() *syserr.Error {
if len(s.readView) > 0 {
return nil
}
s.readView = nil
s.sender = tcpip.FullAddress{}
s.linkPacketInfo = tcpip.LinkPacketInfo{}
var v buffer.View
var cms tcpip.ControlMessages
var err *tcpip.Error
switch e := s.Endpoint.(type) {
// The ordering of these interfaces matters. The most specific
// interfaces must be specified before the more generic Endpoint
// interface.
case tcpip.PacketEndpoint:
v, cms, err = e.ReadPacket(&s.sender, &s.linkPacketInfo)
case tcpip.Endpoint:
v, cms, err = e.Read(&s.sender)
}
if err != nil {
atomic.StoreUint32(&s.readViewHasData, 0)
return syserr.TranslateNetstackError(err)
}
s.readView = v
s.readCM = socket.NewIPControlMessages(s.family, cms)
atomic.StoreUint32(&s.readViewHasData, 1)
return nil
}
// Release implements fs.FileOperations.Release.
func (s *socketOpsCommon) Release(ctx context.Context) {
e, ch := waiter.NewChannelEntry(nil)
s.EventRegister(&e, waiter.EventHUp|waiter.EventErr)
defer s.EventUnregister(&e)
s.Endpoint.Close()
// SO_LINGER option is valid only for TCP. For other socket types
// return after endpoint close.
if family, skType, _ := s.Type(); skType != linux.SOCK_STREAM || (family != linux.AF_INET && family != linux.AF_INET6) {
return
}
var v tcpip.LingerOption
if err := s.Endpoint.GetSockOpt(&v); err != nil {
return
}
// The case for zero timeout is handled in tcp endpoint close function.
// Close is blocked until either:
// 1. The endpoint state is not in any of the states: FIN-WAIT1,
// CLOSING and LAST_ACK.
// 2. Timeout is reached.
if v.Enabled && v.Timeout != 0 {
t := kernel.TaskFromContext(ctx)
start := t.Kernel().MonotonicClock().Now()
deadline := start.Add(v.Timeout)
t.BlockWithDeadline(ch, true, deadline)
}
}
// 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
}
n, _, _, _, _, err := s.nonBlockingRead(ctx, dst, false, false, false)
if err == syserr.ErrWouldBlock {
return int64(n), syserror.ErrWouldBlock
}
if err != nil {
return 0, err.ToError()
}
return int64(n), nil
}
// WriteTo implements fs.FileOperations.WriteTo.
func (s *SocketOperations) WriteTo(ctx context.Context, _ *fs.File, dst io.Writer, count int64, dup bool) (int64, error) {
s.readMu.Lock()
// Copy as much data as possible.
done := int64(0)
for count > 0 {
// This may return a blocking error.
if err := s.fetchReadView(); err != nil {
s.readMu.Unlock()
return done, err.ToError()
}
// Write to the underlying file.
n, err := dst.Write(s.readView)
done += int64(n)
count -= int64(n)
if dup {
// That's all we support for dup. This is generally
// supported by any Linux system calls, but the
// expectation is that now a caller will call read to
// actually remove these bytes from the socket.
break
}
// Drop that part of the view.
s.readView.TrimFront(n)
if err != nil {
s.readMu.Unlock()
return done, err
}
}
s.readMu.Unlock()
return done, nil
}
// ioSequencePayload implements tcpip.Payload.
//
// t copies user memory bytes on demand based on the requested size.
type ioSequencePayload struct {
ctx context.Context
src usermem.IOSequence
}
// FullPayload implements tcpip.Payloader.FullPayload
func (i *ioSequencePayload) FullPayload() ([]byte, *tcpip.Error) {
return i.Payload(int(i.src.NumBytes()))
}
// Payload implements tcpip.Payloader.Payload.
func (i *ioSequencePayload) Payload(size int) ([]byte, *tcpip.Error) {
if max := int(i.src.NumBytes()); size > max {
size = max
}
v := buffer.NewView(size)
if _, err := i.src.CopyIn(i.ctx, v); err != nil {
// EOF can be returned only if src is a file and this means it
// is in a splice syscall and the error has to be ignored.
if err == io.EOF {
return v, nil
}
return nil, tcpip.ErrBadAddress
}
return v, nil
}
// DropFirst drops the first n bytes from underlying src.
func (i *ioSequencePayload) DropFirst(n int) {
i.src = i.src.DropFirst(int(n))
}
// Write implements fs.FileOperations.Write.
func (s *SocketOperations) Write(ctx context.Context, _ *fs.File, src usermem.IOSequence, _ int64) (int64, error) {
f := &ioSequencePayload{ctx: ctx, src: src}
n, resCh, err := s.Endpoint.Write(f, tcpip.WriteOptions{})
if err == tcpip.ErrWouldBlock {
return 0, syserror.ErrWouldBlock
}
if resCh != nil {
if err := amutex.Block(ctx, resCh); err != nil {
return 0, err
}
n, _, err = s.Endpoint.Write(f, tcpip.WriteOptions{})
}
if err != nil {
return 0, syserr.TranslateNetstackError(err).ToError()
}
if int64(n) < src.NumBytes() {
return int64(n), syserror.ErrWouldBlock
}
return int64(n), nil
}
// readerPayload implements tcpip.Payloader.
//
// It allocates a view and reads from a reader on-demand, based on available
// capacity in the endpoint.
type readerPayload struct {
ctx context.Context
r io.Reader
count int64
err error
}
// FullPayload implements tcpip.Payloader.FullPayload.
func (r *readerPayload) FullPayload() ([]byte, *tcpip.Error) {
return r.Payload(int(r.count))
}
// Payload implements tcpip.Payloader.Payload.
func (r *readerPayload) Payload(size int) ([]byte, *tcpip.Error) {
if size > int(r.count) {
size = int(r.count)
}
v := buffer.NewView(size)
n, err := r.r.Read(v)
if n > 0 {
// We ignore the error here. It may re-occur on subsequent
// reads, but for now we can enqueue some amount of data.
r.count -= int64(n)
return v[:n], nil
}
if err == syserror.ErrWouldBlock {
return nil, tcpip.ErrWouldBlock
} else if err != nil {
r.err = err // Save for propation.
return nil, tcpip.ErrBadAddress
}
// There is no data and no error. Return an error, which will propagate
// r.err, which will be nil. This is the desired result: (0, nil).
return nil, tcpip.ErrBadAddress
}
// ReadFrom implements fs.FileOperations.ReadFrom.
func (s *SocketOperations) ReadFrom(ctx context.Context, _ *fs.File, r io.Reader, count int64) (int64, error) {
f := &readerPayload{ctx: ctx, r: r, count: count}
n, resCh, err := s.Endpoint.Write(f, tcpip.WriteOptions{
// Reads may be destructive but should be very fast,
// so we can't release the lock while copying data.
Atomic: true,
})
if err == tcpip.ErrWouldBlock {
return 0, syserror.ErrWouldBlock
}
if resCh != nil {
if err := amutex.Block(ctx, resCh); err != nil {
return 0, err
}
n, _, err = s.Endpoint.Write(f, tcpip.WriteOptions{
Atomic: true, // See above.
})
}
if err == tcpip.ErrWouldBlock {
return n, syserror.ErrWouldBlock
} else if err != nil {
return int64(n), f.err // Propagate error.
}
return int64(n), nil
}
// Readiness returns a mask of ready events for socket s.
func (s *socketOpsCommon) Readiness(mask waiter.EventMask) waiter.EventMask {
r := s.Endpoint.Readiness(mask)
// Check our cached value iff the caller asked for readability and the
// endpoint itself is currently not readable.
if (mask & ^r & waiter.EventIn) != 0 {
if atomic.LoadUint32(&s.readViewHasData) == 1 {
r |= waiter.EventIn
}
}
return r
}
func (s *socketOpsCommon) checkFamily(family uint16, exact bool) *syserr.Error {
if family == uint16(s.family) {
return nil
}
if !exact && family == linux.AF_INET && s.family == linux.AF_INET6 {
if !s.Endpoint.SocketOptions().GetV6Only() {
return nil
}
}
return syserr.ErrInvalidArgument
}
// mapFamily maps the AF_INET ANY address to the IPv4-mapped IPv6 ANY if the
// receiver's family is AF_INET6.
//
// This is a hack to work around the fact that both IPv4 and IPv6 ANY are
// represented by the empty string.
//
// TODO(gvisor.dev/issue/1556): remove this function.
func (s *socketOpsCommon) mapFamily(addr tcpip.FullAddress, family uint16) tcpip.FullAddress {
if len(addr.Addr) == 0 && s.family == linux.AF_INET6 && family == linux.AF_INET {
addr.Addr = "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xff\xff\x00\x00\x00\x00"
}
return addr
}
// Connect implements the linux syscall connect(2) for sockets backed by
// tpcip.Endpoint.
func (s *socketOpsCommon) Connect(t *kernel.Task, sockaddr []byte, blocking bool) *syserr.Error {
addr, family, err := socket.AddressAndFamily(sockaddr)
if err != nil {
return err
}
if family == linux.AF_UNSPEC {
err := s.Endpoint.Disconnect()
if err == tcpip.ErrNotSupported {
return syserr.ErrAddressFamilyNotSupported
}
return syserr.TranslateNetstackError(err)
}
if err := s.checkFamily(family, false /* exact */); err != nil {
return err
}
addr = s.mapFamily(addr, family)
// Always return right away in the non-blocking case.
if !blocking {
return syserr.TranslateNetstackError(s.Endpoint.Connect(addr))
}
// Register for notification when the endpoint becomes writable, then
// initiate the connection.
e, ch := waiter.NewChannelEntry(nil)
s.EventRegister(&e, waiter.EventOut)
defer s.EventUnregister(&e)
if err := s.Endpoint.Connect(addr); err != tcpip.ErrConnectStarted && err != tcpip.ErrAlreadyConnecting {
if (s.family == unix.AF_INET || s.family == unix.AF_INET6) && s.skType == linux.SOCK_STREAM {
// TCP unlike UDP returns EADDRNOTAVAIL when it can't
// find an available local ephemeral port.
if err == tcpip.ErrNoPortAvailable {
return syserr.ErrAddressNotAvailable
}
}
return syserr.TranslateNetstackError(err)
}
// It's pending, so we have to wait for a notification, and fetch the
// result once the wait completes.
if err := t.Block(ch); err != nil {
return syserr.FromError(err)
}
// Call Connect() again after blocking to find connect's result.
return syserr.TranslateNetstackError(s.Endpoint.Connect(addr))
}
// Bind implements the linux syscall bind(2) for sockets backed by
// tcpip.Endpoint.
func (s *socketOpsCommon) Bind(t *kernel.Task, sockaddr []byte) *syserr.Error {
if len(sockaddr) < 2 {
return syserr.ErrInvalidArgument
}
family := usermem.ByteOrder.Uint16(sockaddr)
var addr tcpip.FullAddress
// Bind for AF_PACKET requires only family, protocol and ifindex.
// In function AddressAndFamily, we check the address length which is
// not needed for AF_PACKET bind.
if family == linux.AF_PACKET {
var a linux.SockAddrLink
if len(sockaddr) < sockAddrLinkSize {
return syserr.ErrInvalidArgument
}
binary.Unmarshal(sockaddr[:sockAddrLinkSize], usermem.ByteOrder, &a)
if a.Protocol != uint16(s.protocol) {
return syserr.ErrInvalidArgument
}
addr = tcpip.FullAddress{
NIC: tcpip.NICID(a.InterfaceIndex),
Addr: tcpip.Address(a.HardwareAddr[:header.EthernetAddressSize]),
}
} else {
var err *syserr.Error
addr, family, err = socket.AddressAndFamily(sockaddr)
if err != nil {
return err
}
if err = s.checkFamily(family, true /* exact */); err != nil {
return err
}
addr = s.mapFamily(addr, family)
}
// Issue the bind request to the endpoint.
err := s.Endpoint.Bind(addr)
if err == tcpip.ErrNoPortAvailable {
// Bind always returns EADDRINUSE irrespective of if the specified port was
// already bound or if an ephemeral port was requested but none were
// available.
//
// tcpip.ErrNoPortAvailable is mapped to EAGAIN in syserr package because
// UDP connect returns EAGAIN on ephemeral port exhaustion.
//
// TCP connect returns EADDRNOTAVAIL on ephemeral port exhaustion.
err = tcpip.ErrPortInUse
}
return syserr.TranslateNetstackError(err)
}
// Listen implements the linux syscall listen(2) for sockets backed by
// tcpip.Endpoint.
func (s *socketOpsCommon) Listen(t *kernel.Task, backlog int) *syserr.Error {
return syserr.TranslateNetstackError(s.Endpoint.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 *socketOpsCommon) blockingAccept(t *kernel.Task, peerAddr *tcpip.FullAddress) (tcpip.Endpoint, *waiter.Queue, *syserr.Error) {
// Register for notifications.
e, ch := waiter.NewChannelEntry(nil)
s.EventRegister(&e, waiter.EventIn)
defer s.EventUnregister(&e)
// Try to accept the connection again; if it fails, then wait until we
// get a notification.
for {
if ep, wq, err := s.Endpoint.Accept(peerAddr); err != tcpip.ErrWouldBlock {
return ep, wq, syserr.TranslateNetstackError(err)
}
if err := t.Block(ch); err != nil {
return nil, nil, syserr.FromError(err)
}
}
}
// Accept implements the linux syscall accept(2) for sockets backed by
// tcpip.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, wq, terr := s.Endpoint.Accept(peerAddr)
if terr != nil {
if terr != tcpip.ErrWouldBlock || !blocking {
return 0, nil, 0, syserr.TranslateNetstackError(terr)
}
var err *syserr.Error
ep, wq, err = s.blockingAccept(t, peerAddr)
if err != nil {
return 0, nil, 0, err
}
}
ns, err := New(t, s.family, s.skType, s.protocol, wq, ep)
if err != nil {
return 0, nil, 0, err
}
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 = socket.ConvertAddress(s.family, *peerAddr)
}
fd, e := t.NewFDFrom(0, ns, kernel.FDFlags{
CloseOnExec: flags&linux.SOCK_CLOEXEC != 0,
})
t.Kernel().RecordSocket(ns)
return fd, addr, addrLen, syserr.FromError(e)
}
// ConvertShutdown converts Linux shutdown flags into tcpip shutdown flags.
func ConvertShutdown(how int) (tcpip.ShutdownFlags, *syserr.Error) {
var f tcpip.ShutdownFlags
switch how {
case linux.SHUT_RD:
f = tcpip.ShutdownRead
case linux.SHUT_WR:
f = tcpip.ShutdownWrite
case linux.SHUT_RDWR:
f = tcpip.ShutdownRead | tcpip.ShutdownWrite
default:
return 0, syserr.ErrInvalidArgument
}
return f, nil
}
// Shutdown implements the linux syscall shutdown(2) for sockets backed by
// tcpip.Endpoint.
func (s *socketOpsCommon) Shutdown(t *kernel.Task, how int) *syserr.Error {
f, err := ConvertShutdown(how)
if err != nil {
return err
}
// Issue shutdown request.
return syserr.TranslateNetstackError(s.Endpoint.Shutdown(f))
}
// GetSockOpt implements the linux syscall getsockopt(2) for sockets backed by
// tcpip.Endpoint.
func (s *SocketOperations) GetSockOpt(t *kernel.Task, level, name int, outPtr usermem.Addr, outLen int) (marshal.Marshallable, *syserr.Error) {
// TODO(b/78348848): Unlike other socket options, SO_TIMESTAMP is
// implemented specifically for netstack.SocketOperations rather than
// commonEndpoint. commonEndpoint should be extended to support socket
// options where the implementation is not shared, as unix sockets need
// their own support for SO_TIMESTAMP.
if level == linux.SOL_SOCKET && name == linux.SO_TIMESTAMP {
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
val := primitive.Int32(0)
s.readMu.Lock()
defer s.readMu.Unlock()
if s.sockOptTimestamp {
val = 1
}
return &val, nil
}
if level == linux.SOL_TCP && name == linux.TCP_INQ {
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
val := primitive.Int32(0)
s.readMu.Lock()
defer s.readMu.Unlock()
if s.sockOptInq {
val = 1
}
return &val, nil
}
return GetSockOpt(t, s, s.Endpoint, s.family, s.skType, level, name, outPtr, outLen)
}
// GetSockOpt can be used to implement the linux syscall getsockopt(2) for
// sockets backed by a commonEndpoint.
func GetSockOpt(t *kernel.Task, s socket.SocketOps, ep commonEndpoint, family int, skType linux.SockType, level, name int, outPtr usermem.Addr, outLen int) (marshal.Marshallable, *syserr.Error) {
switch level {
case linux.SOL_SOCKET:
return getSockOptSocket(t, s, ep, family, skType, name, outLen)
case linux.SOL_TCP:
return getSockOptTCP(t, s, ep, name, outLen)
case linux.SOL_IPV6:
return getSockOptIPv6(t, s, ep, name, outPtr, outLen)
case linux.SOL_IP:
return getSockOptIP(t, s, ep, name, outPtr, outLen, family)
case linux.SOL_UDP,
linux.SOL_ICMPV6,
linux.SOL_RAW,
linux.SOL_PACKET:
t.Kernel().EmitUnimplementedEvent(t)
}
return nil, syserr.ErrProtocolNotAvailable
}
func boolToInt32(v bool) int32 {
if v {
return 1
}
return 0
}
// getSockOptSocket implements GetSockOpt when level is SOL_SOCKET.
func getSockOptSocket(t *kernel.Task, s socket.SocketOps, ep commonEndpoint, family int, skType linux.SockType, name, outLen int) (marshal.Marshallable, *syserr.Error) {
// TODO(b/124056281): Stop rejecting short optLen values in getsockopt.
switch name {
case linux.SO_ERROR:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
// Get the last error and convert it.
err := ep.SocketOptions().GetLastError()
if err == nil {
optP := primitive.Int32(0)
return &optP, nil
}
optP := primitive.Int32(syserr.TranslateNetstackError(err).ToLinux().Number())
return &optP, nil
case linux.SO_PEERCRED:
if family != linux.AF_UNIX || outLen < syscall.SizeofUcred {
return nil, syserr.ErrInvalidArgument
}
tcred := t.Credentials()
creds := linux.ControlMessageCredentials{
PID: int32(t.ThreadGroup().ID()),
UID: uint32(tcred.EffectiveKUID.In(tcred.UserNamespace).OrOverflow()),
GID: uint32(tcred.EffectiveKGID.In(tcred.UserNamespace).OrOverflow()),
}
return &creds, nil
case linux.SO_PASSCRED:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetPassCred()))
return &v, nil
case linux.SO_SNDBUF:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
size, err := ep.GetSockOptInt(tcpip.SendBufferSizeOption)
if err != nil {
return nil, syserr.TranslateNetstackError(err)
}
if size > math.MaxInt32 {
size = math.MaxInt32
}
sizeP := primitive.Int32(size)
return &sizeP, nil
case linux.SO_RCVBUF:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
size, err := ep.GetSockOptInt(tcpip.ReceiveBufferSizeOption)
if err != nil {
return nil, syserr.TranslateNetstackError(err)
}
if size > math.MaxInt32 {
size = math.MaxInt32
}
sizeP := primitive.Int32(size)
return &sizeP, nil
case linux.SO_REUSEADDR:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetReuseAddress()))
return &v, nil
case linux.SO_REUSEPORT:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetReusePort()))
return &v, nil
case linux.SO_BINDTODEVICE:
var v tcpip.BindToDeviceOption
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
if v == 0 {
var b primitive.ByteSlice
return &b, nil
}
if outLen < linux.IFNAMSIZ {
return nil, syserr.ErrInvalidArgument
}
s := t.NetworkContext()
if s == nil {
return nil, syserr.ErrNoDevice
}
nic, ok := s.Interfaces()[int32(v)]
if !ok {
// The NICID no longer indicates a valid interface, probably because that
// interface was removed.
return nil, syserr.ErrUnknownDevice
}
name := primitive.ByteSlice(append([]byte(nic.Name), 0))
return &name, nil
case linux.SO_BROADCAST:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetBroadcast()))
return &v, nil
case linux.SO_KEEPALIVE:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetKeepAlive()))
return &v, nil
case linux.SO_LINGER:
if outLen < linux.SizeOfLinger {
return nil, syserr.ErrInvalidArgument
}
var v tcpip.LingerOption
var linger linux.Linger
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
if v.Enabled {
linger.OnOff = 1
}
linger.Linger = int32(v.Timeout.Seconds())
return &linger, nil
case linux.SO_SNDTIMEO:
// TODO(igudger): Linux allows shorter lengths for partial results.
if outLen < linux.SizeOfTimeval {
return nil, syserr.ErrInvalidArgument
}
sendTimeout := linux.NsecToTimeval(s.SendTimeout())
return &sendTimeout, nil
case linux.SO_RCVTIMEO:
// TODO(igudger): Linux allows shorter lengths for partial results.
if outLen < linux.SizeOfTimeval {
return nil, syserr.ErrInvalidArgument
}
recvTimeout := linux.NsecToTimeval(s.RecvTimeout())
return &recvTimeout, nil
case linux.SO_OOBINLINE:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetOutOfBandInline()))
return &v, nil
case linux.SO_NO_CHECK:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetNoChecksum()))
return &v, nil
case linux.SO_ACCEPTCONN:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
// This option is only viable for TCP endpoints.
var v bool
if _, skType, skProto := s.Type(); isTCPSocket(skType, skProto) {
v = tcp.EndpointState(ep.State()) == tcp.StateListen
}
vP := primitive.Int32(boolToInt32(v))
return &vP, nil
default:
socket.GetSockOptEmitUnimplementedEvent(t, name)
}
return nil, syserr.ErrProtocolNotAvailable
}
// getSockOptTCP implements GetSockOpt when level is SOL_TCP.
func getSockOptTCP(t *kernel.Task, s socket.SocketOps, ep commonEndpoint, name, outLen int) (marshal.Marshallable, *syserr.Error) {
if _, skType, skProto := s.Type(); !isTCPSocket(skType, skProto) {
log.Warningf("SOL_TCP options are only supported on TCP sockets: skType, skProto = %v, %d", skType, skProto)
return nil, syserr.ErrUnknownProtocolOption
}
switch name {
case linux.TCP_NODELAY:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(!ep.SocketOptions().GetDelayOption()))
return &v, nil
case linux.TCP_CORK:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetCorkOption()))
return &v, nil
case linux.TCP_QUICKACK:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetQuickAck()))
return &v, nil
case linux.TCP_MAXSEG:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v, err := ep.GetSockOptInt(tcpip.MaxSegOption)
if err != nil {
return nil, syserr.TranslateNetstackError(err)
}
vP := primitive.Int32(v)
return &vP, nil
case linux.TCP_KEEPIDLE:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
var v tcpip.KeepaliveIdleOption
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
keepAliveIdle := primitive.Int32(time.Duration(v) / time.Second)
return &keepAliveIdle, nil
case linux.TCP_KEEPINTVL:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
var v tcpip.KeepaliveIntervalOption
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
keepAliveInterval := primitive.Int32(time.Duration(v) / time.Second)
return &keepAliveInterval, nil
case linux.TCP_KEEPCNT:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v, err := ep.GetSockOptInt(tcpip.KeepaliveCountOption)
if err != nil {
return nil, syserr.TranslateNetstackError(err)
}
vP := primitive.Int32(v)
return &vP, nil
case linux.TCP_USER_TIMEOUT:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
var v tcpip.TCPUserTimeoutOption
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
tcpUserTimeout := primitive.Int32(time.Duration(v) / time.Millisecond)
return &tcpUserTimeout, nil
case linux.TCP_INFO:
var v tcpip.TCPInfoOption
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
// TODO(b/64800844): Translate fields once they are added to
// tcpip.TCPInfoOption.
info := linux.TCPInfo{}
// Linux truncates the output binary to outLen.
buf := t.CopyScratchBuffer(info.SizeBytes())
info.MarshalUnsafe(buf)
if len(buf) > outLen {
buf = buf[:outLen]
}
bufP := primitive.ByteSlice(buf)
return &bufP, nil
case linux.TCP_CC_INFO,
linux.TCP_NOTSENT_LOWAT,
linux.TCP_ZEROCOPY_RECEIVE:
t.Kernel().EmitUnimplementedEvent(t)
case linux.TCP_CONGESTION:
if outLen <= 0 {
return nil, syserr.ErrInvalidArgument
}
var v tcpip.CongestionControlOption
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
// We match linux behaviour here where it returns the lower of
// TCP_CA_NAME_MAX bytes or the value of the option length.
//
// This is Linux's net/tcp.h TCP_CA_NAME_MAX.
const tcpCANameMax = 16
toCopy := tcpCANameMax
if outLen < tcpCANameMax {
toCopy = outLen
}
b := make([]byte, toCopy)
copy(b, v)
bP := primitive.ByteSlice(b)
return &bP, nil
case linux.TCP_LINGER2:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
var v tcpip.TCPLingerTimeoutOption
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
var lingerTimeout primitive.Int32
if v >= 0 {
lingerTimeout = primitive.Int32(time.Duration(v) / time.Second)
} else {
lingerTimeout = -1
}
return &lingerTimeout, nil
case linux.TCP_DEFER_ACCEPT:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
var v tcpip.TCPDeferAcceptOption
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
tcpDeferAccept := primitive.Int32(time.Duration(v) / time.Second)
return &tcpDeferAccept, nil
case linux.TCP_SYNCNT:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v, err := ep.GetSockOptInt(tcpip.TCPSynCountOption)
if err != nil {
return nil, syserr.TranslateNetstackError(err)
}
vP := primitive.Int32(v)
return &vP, nil
case linux.TCP_WINDOW_CLAMP:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v, err := ep.GetSockOptInt(tcpip.TCPWindowClampOption)
if err != nil {
return nil, syserr.TranslateNetstackError(err)
}
vP := primitive.Int32(v)
return &vP, nil
default:
emitUnimplementedEventTCP(t, name)
}
return nil, syserr.ErrProtocolNotAvailable
}
// getSockOptIPv6 implements GetSockOpt when level is SOL_IPV6.
func getSockOptIPv6(t *kernel.Task, s socket.SocketOps, ep commonEndpoint, name int, outPtr usermem.Addr, outLen int) (marshal.Marshallable, *syserr.Error) {
if _, ok := ep.(tcpip.Endpoint); !ok {
log.Warningf("SOL_IPV6 options not supported on endpoints other than tcpip.Endpoint: option = %d", name)
return nil, syserr.ErrUnknownProtocolOption
}
family, skType, _ := s.Type()
if family != linux.AF_INET6 {
return nil, syserr.ErrUnknownProtocolOption
}
switch name {
case linux.IPV6_V6ONLY:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetV6Only()))
return &v, nil
case linux.IPV6_PATHMTU:
t.Kernel().EmitUnimplementedEvent(t)
case linux.IPV6_TCLASS:
// Length handling for parity with Linux.
if outLen == 0 {
var b primitive.ByteSlice
return &b, nil
}
v, err := ep.GetSockOptInt(tcpip.IPv6TrafficClassOption)
if err != nil {
return nil, syserr.TranslateNetstackError(err)
}
uintv := primitive.Uint32(v)
// Linux truncates the output binary to outLen.
ib := t.CopyScratchBuffer(uintv.SizeBytes())
uintv.MarshalUnsafe(ib)
// Handle cases where outLen is lesser than sizeOfInt32.
if len(ib) > outLen {
ib = ib[:outLen]
}
ibP := primitive.ByteSlice(ib)
return &ibP, nil
case linux.IPV6_RECVTCLASS:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetReceiveTClass()))
return &v, nil
case linux.IPV6_RECVORIGDSTADDR:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetReceiveOriginalDstAddress()))
return &v, nil
case linux.IP6T_ORIGINAL_DST:
if outLen < int(binary.Size(linux.SockAddrInet6{})) {
return nil, syserr.ErrInvalidArgument
}
var v tcpip.OriginalDestinationOption
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
a, _ := socket.ConvertAddress(linux.AF_INET6, tcpip.FullAddress(v))
return a.(*linux.SockAddrInet6), nil
case linux.IP6T_SO_GET_INFO:
if outLen < linux.SizeOfIPTGetinfo {
return nil, syserr.ErrInvalidArgument
}
// Only valid for raw IPv6 sockets.
if skType != linux.SOCK_RAW {
return nil, syserr.ErrProtocolNotAvailable
}
stack := inet.StackFromContext(t)
if stack == nil {
return nil, syserr.ErrNoDevice
}
info, err := netfilter.GetInfo(t, stack.(*Stack).Stack, outPtr, true)
if err != nil {
return nil, err
}
return &info, nil
case linux.IP6T_SO_GET_ENTRIES:
// IPTGetEntries is reused for IPv6.
if outLen < linux.SizeOfIPTGetEntries {
return nil, syserr.ErrInvalidArgument
}
// Only valid for raw IPv6 sockets.
if skType != linux.SOCK_RAW {
return nil, syserr.ErrProtocolNotAvailable
}
stack := inet.StackFromContext(t)
if stack == nil {
return nil, syserr.ErrNoDevice
}
entries, err := netfilter.GetEntries6(t, stack.(*Stack).Stack, outPtr, outLen)
if err != nil {
return nil, err
}
return &entries, nil
case linux.IP6T_SO_GET_REVISION_TARGET:
if outLen < linux.SizeOfXTGetRevision {
return nil, syserr.ErrInvalidArgument
}
// Only valid for raw IPv6 sockets.
if skType != linux.SOCK_RAW {
return nil, syserr.ErrProtocolNotAvailable
}
stack := inet.StackFromContext(t)
if stack == nil {
return nil, syserr.ErrNoDevice
}
ret, err := netfilter.TargetRevision(t, outPtr, header.IPv6ProtocolNumber)
if err != nil {
return nil, err
}
return &ret, nil
default:
emitUnimplementedEventIPv6(t, name)
}
return nil, syserr.ErrProtocolNotAvailable
}
// getSockOptIP implements GetSockOpt when level is SOL_IP.
func getSockOptIP(t *kernel.Task, s socket.SocketOps, ep commonEndpoint, name int, outPtr usermem.Addr, outLen int, family int) (marshal.Marshallable, *syserr.Error) {
if _, ok := ep.(tcpip.Endpoint); !ok {
log.Warningf("SOL_IP options not supported on endpoints other than tcpip.Endpoint: option = %d", name)
return nil, syserr.ErrUnknownProtocolOption
}
switch name {
case linux.IP_TTL:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v, err := ep.GetSockOptInt(tcpip.TTLOption)
if err != nil {
return nil, syserr.TranslateNetstackError(err)
}
// Fill in the default value, if needed.
vP := primitive.Int32(v)
if vP == 0 {
vP = DefaultTTL
}
return &vP, nil
case linux.IP_MULTICAST_TTL:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v, err := ep.GetSockOptInt(tcpip.MulticastTTLOption)
if err != nil {
return nil, syserr.TranslateNetstackError(err)
}
vP := primitive.Int32(v)
return &vP, nil
case linux.IP_MULTICAST_IF:
if outLen < len(linux.InetAddr{}) {
return nil, syserr.ErrInvalidArgument
}
var v tcpip.MulticastInterfaceOption
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
a, _ := socket.ConvertAddress(linux.AF_INET, tcpip.FullAddress{Addr: v.InterfaceAddr})
return &a.(*linux.SockAddrInet).Addr, nil
case linux.IP_MULTICAST_LOOP:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetMulticastLoop()))
return &v, nil
case linux.IP_TOS:
// Length handling for parity with Linux.
if outLen == 0 {
var b primitive.ByteSlice
return &b, nil
}
v, err := ep.GetSockOptInt(tcpip.IPv4TOSOption)
if err != nil {
return nil, syserr.TranslateNetstackError(err)
}
if outLen < sizeOfInt32 {
vP := primitive.Uint8(v)
return &vP, nil
}
vP := primitive.Int32(v)
return &vP, nil
case linux.IP_RECVTOS:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetReceiveTOS()))
return &v, nil
case linux.IP_PKTINFO:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetReceivePacketInfo()))
return &v, nil
case linux.IP_HDRINCL:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetHeaderIncluded()))
return &v, nil
case linux.IP_RECVORIGDSTADDR:
if outLen < sizeOfInt32 {
return nil, syserr.ErrInvalidArgument
}
v := primitive.Int32(boolToInt32(ep.SocketOptions().GetReceiveOriginalDstAddress()))
return &v, nil
case linux.SO_ORIGINAL_DST:
if outLen < int(binary.Size(linux.SockAddrInet{})) {
return nil, syserr.ErrInvalidArgument
}
var v tcpip.OriginalDestinationOption
if err := ep.GetSockOpt(&v); err != nil {
return nil, syserr.TranslateNetstackError(err)
}
a, _ := socket.ConvertAddress(linux.AF_INET, tcpip.FullAddress(v))
return a.(*linux.SockAddrInet), nil
case linux.IPT_SO_GET_INFO:
if outLen < linux.SizeOfIPTGetinfo {
return nil, syserr.ErrInvalidArgument
}
// Only valid for raw IPv4 sockets.
if family, skType, _ := s.Type(); family != linux.AF_INET || skType != linux.SOCK_RAW {
return nil, syserr.ErrProtocolNotAvailable
}
stack := inet.StackFromContext(t)
if stack == nil {
return nil, syserr.ErrNoDevice
}
info, err := netfilter.GetInfo(t, stack.(*Stack).Stack, outPtr, false)
if err != nil {
return nil, err
}
return &info, nil
case linux.IPT_SO_GET_ENTRIES:
if outLen < linux.SizeOfIPTGetEntries {
return nil, syserr.ErrInvalidArgument
}
// Only valid for raw IPv4 sockets.
if family, skType, _ := s.Type(); family != linux.AF_INET || skType != linux.SOCK_RAW {
return nil, syserr.ErrProtocolNotAvailable
}
stack := inet.StackFromContext(t)
if stack == nil {
return nil, syserr.ErrNoDevice
}
entries, err := netfilter.GetEntries4(t, stack.(*Stack).Stack, outPtr, outLen)
if err != nil {
return nil, err
}
return &entries, nil
case linux.IPT_SO_GET_REVISION_TARGET:
if outLen < linux.SizeOfXTGetRevision {
return nil, syserr.ErrInvalidArgument
}
// Only valid for raw IPv4 sockets.
if family, skType, _ := s.Type(); family != linux.AF_INET || skType != linux.SOCK_RAW {
return nil, syserr.ErrProtocolNotAvailable
}
stack := inet.StackFromContext(t)
if stack == nil {
return nil, syserr.ErrNoDevice
}
ret, err := netfilter.TargetRevision(t, outPtr, header.IPv4ProtocolNumber)
if err != nil {
return nil, err
}
return &ret, nil
default:
emitUnimplementedEventIP(t, name)
}
return nil, syserr.ErrProtocolNotAvailable
}
// SetSockOpt implements the linux syscall setsockopt(2) for sockets backed by
// tcpip.Endpoint.
func (s *SocketOperations) SetSockOpt(t *kernel.Task, level int, name int, optVal []byte) *syserr.Error {
// TODO(b/78348848): Unlike other socket options, SO_TIMESTAMP is
// implemented specifically for netstack.SocketOperations rather than
// commonEndpoint. commonEndpoint should be extended to support socket
// options where the implementation is not shared, as unix sockets need
// their own support for SO_TIMESTAMP.
if level == linux.SOL_SOCKET && name == linux.SO_TIMESTAMP {
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
s.readMu.Lock()
defer s.readMu.Unlock()
s.sockOptTimestamp = usermem.ByteOrder.Uint32(optVal) != 0
return nil
}
if level == linux.SOL_TCP && name == linux.TCP_INQ {
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
s.readMu.Lock()
defer s.readMu.Unlock()
s.sockOptInq = usermem.ByteOrder.Uint32(optVal) != 0
return nil
}
return SetSockOpt(t, s, s.Endpoint, level, name, optVal)
}
// SetSockOpt can be used to implement the linux syscall setsockopt(2) for
// sockets backed by a commonEndpoint.
func SetSockOpt(t *kernel.Task, s socket.SocketOps, ep commonEndpoint, level int, name int, optVal []byte) *syserr.Error {
switch level {
case linux.SOL_SOCKET:
return setSockOptSocket(t, s, ep, name, optVal)
case linux.SOL_TCP:
return setSockOptTCP(t, s, ep, name, optVal)
case linux.SOL_IPV6:
return setSockOptIPv6(t, s, ep, name, optVal)
case linux.SOL_IP:
return setSockOptIP(t, s, ep, name, optVal)
case linux.SOL_PACKET:
// gVisor doesn't support any SOL_PACKET options just return not
// supported. Returning nil here will result in tcpdump thinking AF_PACKET
// features are supported and proceed to use them and break.
t.Kernel().EmitUnimplementedEvent(t)
return syserr.ErrProtocolNotAvailable
case linux.SOL_UDP,
linux.SOL_ICMPV6,
linux.SOL_RAW:
t.Kernel().EmitUnimplementedEvent(t)
}
return nil
}
// setSockOptSocket implements SetSockOpt when level is SOL_SOCKET.
func setSockOptSocket(t *kernel.Task, s socket.SocketOps, ep commonEndpoint, name int, optVal []byte) *syserr.Error {
switch name {
case linux.SO_SNDBUF:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
return syserr.TranslateNetstackError(ep.SetSockOptInt(tcpip.SendBufferSizeOption, int(v)))
case linux.SO_RCVBUF:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
return syserr.TranslateNetstackError(ep.SetSockOptInt(tcpip.ReceiveBufferSizeOption, int(v)))
case linux.SO_REUSEADDR:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
ep.SocketOptions().SetReuseAddress(v != 0)
return nil
case linux.SO_REUSEPORT:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
ep.SocketOptions().SetReusePort(v != 0)
return nil
case linux.SO_BINDTODEVICE:
n := bytes.IndexByte(optVal, 0)
if n == -1 {
n = len(optVal)
}
name := string(optVal[:n])
if name == "" {
v := tcpip.BindToDeviceOption(0)
return syserr.TranslateNetstackError(ep.SetSockOpt(&v))
}
s := t.NetworkContext()
if s == nil {
return syserr.ErrNoDevice
}
for nicID, nic := range s.Interfaces() {
if nic.Name == name {
v := tcpip.BindToDeviceOption(nicID)
return syserr.TranslateNetstackError(ep.SetSockOpt(&v))
}
}
return syserr.ErrUnknownDevice
case linux.SO_BROADCAST:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
ep.SocketOptions().SetBroadcast(v != 0)
return nil
case linux.SO_PASSCRED:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
ep.SocketOptions().SetPassCred(v != 0)
return nil
case linux.SO_KEEPALIVE:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
ep.SocketOptions().SetKeepAlive(v != 0)
return nil
case linux.SO_SNDTIMEO:
if len(optVal) < linux.SizeOfTimeval {
return syserr.ErrInvalidArgument
}
var v linux.Timeval
binary.Unmarshal(optVal[:linux.SizeOfTimeval], usermem.ByteOrder, &v)
if v.Usec < 0 || v.Usec >= int64(time.Second/time.Microsecond) {
return syserr.ErrDomain
}
s.SetSendTimeout(v.ToNsecCapped())
return nil
case linux.SO_RCVTIMEO:
if len(optVal) < linux.SizeOfTimeval {
return syserr.ErrInvalidArgument
}
var v linux.Timeval
binary.Unmarshal(optVal[:linux.SizeOfTimeval], usermem.ByteOrder, &v)
if v.Usec < 0 || v.Usec >= int64(time.Second/time.Microsecond) {
return syserr.ErrDomain
}
s.SetRecvTimeout(v.ToNsecCapped())
return nil
case linux.SO_OOBINLINE:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
if v == 0 {
socket.SetSockOptEmitUnimplementedEvent(t, name)
}
ep.SocketOptions().SetOutOfBandInline(v != 0)
return nil
case linux.SO_NO_CHECK:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
ep.SocketOptions().SetNoChecksum(v != 0)
return nil
case linux.SO_LINGER:
if len(optVal) < linux.SizeOfLinger {
return syserr.ErrInvalidArgument
}
var v linux.Linger
binary.Unmarshal(optVal[:linux.SizeOfLinger], usermem.ByteOrder, &v)
if v != (linux.Linger{}) {
socket.SetSockOptEmitUnimplementedEvent(t, name)
}
return syserr.TranslateNetstackError(
ep.SetSockOpt(&tcpip.LingerOption{
Enabled: v.OnOff != 0,
Timeout: time.Second * time.Duration(v.Linger)}))
case linux.SO_DETACH_FILTER:
// optval is ignored.
var v tcpip.SocketDetachFilterOption
return syserr.TranslateNetstackError(ep.SetSockOpt(&v))
default:
socket.SetSockOptEmitUnimplementedEvent(t, name)
}
return nil
}
// setSockOptTCP implements SetSockOpt when level is SOL_TCP.
func setSockOptTCP(t *kernel.Task, s socket.SocketOps, ep commonEndpoint, name int, optVal []byte) *syserr.Error {
if _, skType, skProto := s.Type(); !isTCPSocket(skType, skProto) {
log.Warningf("SOL_TCP options are only supported on TCP sockets: skType, skProto = %v, %d", skType, skProto)
return syserr.ErrUnknownProtocolOption
}
switch name {
case linux.TCP_NODELAY:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
ep.SocketOptions().SetDelayOption(v == 0)
return nil
case linux.TCP_CORK:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
ep.SocketOptions().SetCorkOption(v != 0)
return nil
case linux.TCP_QUICKACK:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
ep.SocketOptions().SetQuickAck(v != 0)
return nil
case linux.TCP_MAXSEG:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
return syserr.TranslateNetstackError(ep.SetSockOptInt(tcpip.MaxSegOption, int(v)))
case linux.TCP_KEEPIDLE:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
if v < 1 || v > linux.MAX_TCP_KEEPIDLE {
return syserr.ErrInvalidArgument
}
opt := tcpip.KeepaliveIdleOption(time.Second * time.Duration(v))
return syserr.TranslateNetstackError(ep.SetSockOpt(&opt))
case linux.TCP_KEEPINTVL:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
if v < 1 || v > linux.MAX_TCP_KEEPINTVL {
return syserr.ErrInvalidArgument
}
opt := tcpip.KeepaliveIntervalOption(time.Second * time.Duration(v))
return syserr.TranslateNetstackError(ep.SetSockOpt(&opt))
case linux.TCP_KEEPCNT:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
if v < 1 || v > linux.MAX_TCP_KEEPCNT {
return syserr.ErrInvalidArgument
}
return syserr.TranslateNetstackError(ep.SetSockOptInt(tcpip.KeepaliveCountOption, int(v)))
case linux.TCP_USER_TIMEOUT:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := int32(usermem.ByteOrder.Uint32(optVal))
if v < 0 {
return syserr.ErrInvalidArgument
}
opt := tcpip.TCPUserTimeoutOption(time.Millisecond * time.Duration(v))
return syserr.TranslateNetstackError(ep.SetSockOpt(&opt))
case linux.TCP_CONGESTION:
v := tcpip.CongestionControlOption(optVal)
if err := ep.SetSockOpt(&v); err != nil {
return syserr.TranslateNetstackError(err)
}
return nil
case linux.TCP_LINGER2:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := int32(usermem.ByteOrder.Uint32(optVal))
opt := tcpip.TCPLingerTimeoutOption(time.Second * time.Duration(v))
return syserr.TranslateNetstackError(ep.SetSockOpt(&opt))
case linux.TCP_DEFER_ACCEPT:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := int32(usermem.ByteOrder.Uint32(optVal))
if v < 0 {
v = 0
}
opt := tcpip.TCPDeferAcceptOption(time.Second * time.Duration(v))
return syserr.TranslateNetstackError(ep.SetSockOpt(&opt))
case linux.TCP_SYNCNT:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
return syserr.TranslateNetstackError(ep.SetSockOptInt(tcpip.TCPSynCountOption, int(v)))
case linux.TCP_WINDOW_CLAMP:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := usermem.ByteOrder.Uint32(optVal)
return syserr.TranslateNetstackError(ep.SetSockOptInt(tcpip.TCPWindowClampOption, int(v)))
case linux.TCP_REPAIR_OPTIONS:
t.Kernel().EmitUnimplementedEvent(t)
default:
emitUnimplementedEventTCP(t, name)
}
return nil
}
// setSockOptIPv6 implements SetSockOpt when level is SOL_IPV6.
func setSockOptIPv6(t *kernel.Task, s socket.SocketOps, ep commonEndpoint, name int, optVal []byte) *syserr.Error {
if _, ok := ep.(tcpip.Endpoint); !ok {
log.Warningf("SOL_IPV6 options not supported on endpoints other than tcpip.Endpoint: option = %d", name)
return syserr.ErrUnknownProtocolOption
}
family, skType, skProto := s.Type()
if family != linux.AF_INET6 {
return syserr.ErrUnknownProtocolOption
}
switch name {
case linux.IPV6_V6ONLY:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
if isTCPSocket(skType, skProto) && tcp.EndpointState(ep.State()) != tcp.StateInitial {
return syserr.ErrInvalidEndpointState
} else if isUDPSocket(skType, skProto) && udp.EndpointState(ep.State()) != udp.StateInitial {
return syserr.ErrInvalidEndpointState
}
v := usermem.ByteOrder.Uint32(optVal)
ep.SocketOptions().SetV6Only(v != 0)
return nil
case linux.IPV6_ADD_MEMBERSHIP,
linux.IPV6_DROP_MEMBERSHIP,
linux.IPV6_IPSEC_POLICY,
linux.IPV6_JOIN_ANYCAST,
linux.IPV6_LEAVE_ANYCAST,
// TODO(b/148887420): Add support for IPV6_PKTINFO.
linux.IPV6_PKTINFO,
linux.IPV6_ROUTER_ALERT,
linux.IPV6_XFRM_POLICY,
linux.MCAST_BLOCK_SOURCE,
linux.MCAST_JOIN_GROUP,
linux.MCAST_JOIN_SOURCE_GROUP,
linux.MCAST_LEAVE_GROUP,
linux.MCAST_LEAVE_SOURCE_GROUP,
linux.MCAST_UNBLOCK_SOURCE:
t.Kernel().EmitUnimplementedEvent(t)
case linux.IPV6_RECVORIGDSTADDR:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := int32(usermem.ByteOrder.Uint32(optVal))
ep.SocketOptions().SetReceiveOriginalDstAddress(v != 0)
return nil
case linux.IPV6_TCLASS:
if len(optVal) < sizeOfInt32 {
return syserr.ErrInvalidArgument
}
v := int32(usermem.ByteOrder.Uint32(optVal))
if v < -1 || v > 255 {
return syserr.ErrInvalidArgument
}
if v == -1 {
v = 0
}
return syserr.TranslateNetstackError(ep.SetSockOptInt(tcpip.IPv6TrafficClassOption, int(v)))
case linux.IPV6_RECVTCLASS:
v, err := parseIntOrChar(optVal)
if err != nil {
return err
}
ep.SocketOptions().SetReceiveTClass(v != 0)
return nil
case linux.IP6T_SO_SET_REPLACE:
if len(optVal) < linux.SizeOfIP6TReplace {
return syserr.ErrInvalidArgument
}
// Only valid for raw IPv6 sockets.
if skType != linux.SOCK_RAW {
return syserr.ErrProtocolNotAvailable
}
stack := inet.StackFromContext(t)
if stack == nil {
return syserr.ErrNoDevice
}
// Stack must be a netstack stack.
return netfilter.SetEntries(stack.(*Stack).Stack, optVal, true)
case linux.IP6T_SO_SET_ADD_COUNTERS:
// TODO(gvisor.dev/issue/170): Counter support.
return nil
default:
emitUnimplementedEventIPv6(t, name)
}
return nil
}
var (
inetMulticastRequestSize = int(binary.Size(linux.InetMulticastRequest{}))
inetMulticastRequestWithNICSize = int(binary.Size(linux.InetMulticastRequestWithNIC{}))
)
// copyInMulticastRequest copies in a variable-size multicast request. The
// kernel determines which structure was passed by its length. IP_MULTICAST_IF
// supports ip_mreqn, ip_mreq and in_addr, while IP_ADD_MEMBERSHIP and
// IP_DROP_MEMBERSHIP only support ip_mreqn and ip_mreq. To handle this,
// allowAddr controls whether in_addr is accepted or rejected.
func copyInMulticastRequest(optVal []byte, allowAddr bool) (linux.InetMulticastRequestWithNIC, *syserr.Error) {
if len(optVal) < len(linux.InetAddr{}) {
return linux.InetMulticastRequestWithNIC{}, syserr.ErrInvalidArgument
}
if len(optVal) < inetMulticastRequestSize {
if !allowAddr {
return linux.InetMulticastRequestWithNIC{}, syserr.ErrInvalidArgument
}
var req linux.InetMulticastRequestWithNIC
copy(req.InterfaceAddr[:], optVal)
return req, nil
}
if len(optVal) >= inetMulticastRequestWithNICSize {
var req linux.InetMulticastRequestWithNIC
binary.Unmarshal(optVal[:inetMulticastRequestWithNICSize], usermem.ByteOrder, &req)
return req, nil
}
var req linux.InetMulticastRequestWithNIC
binary.Unmarshal(optVal[:inetMulticastRequestSize], usermem.ByteOrder, &req.InetMulticastRequest)
return req, nil
}
// parseIntOrChar copies either a 32-bit int or an 8-bit uint out of buf.
//
// net/ipv4/ip_sockglue.c:do_ip_setsockopt does this for its socket options.
func parseIntOrChar(buf []byte) (int32, *syserr.Error) {
if len(buf) == 0 {
return 0, syserr.ErrInvalidArgument
}
if len(buf) >= sizeOfInt32 {
return int32(usermem.ByteOrder.Uint32(buf)), nil
}
return int32(buf[0]), nil
}
// setSockOptIP implements SetSockOpt when level is SOL_IP.
func setSockOptIP(t *kernel.Task, s socket.SocketOps, ep commonEndpoint, name int, optVal []byte) *syserr.Error {
if _, ok := ep.(tcpip.Endpoint); !ok {
log.Warningf("SOL_IP options not supported on endpoints other than tcpip.Endpoint: option = %d", name)
return syserr.ErrUnknownProtocolOption
}
switch name {
case linux.IP_MULTICAST_TTL:
v, err := parseIntOrChar(optVal)
if err != nil {
return err
}
if v == -1 {
// Linux translates -1 to 1.
v = 1
}
if v < 0 || v > 255 {
return syserr.ErrInvalidArgument
}
return syserr.TranslateNetstackError(ep.SetSockOptInt(tcpip.MulticastTTLOption, int(v)))
case linux.IP_ADD_MEMBERSHIP:
req, err := copyInMulticastRequest(optVal, false /* allowAddr */)
if err != nil {
return err
}
return syserr.TranslateNetstackError(ep.SetSockOpt(&tcpip.AddMembershipOption{
NIC: tcpip.NICID(req.InterfaceIndex),
// TODO(igudger): Change AddMembership to use the standard
// any address representation.
InterfaceAddr: tcpip.Address(req.InterfaceAddr[:]),
MulticastAddr: tcpip.Address(req.MulticastAddr[:]),
}))
case linux.IP_DROP_MEMBERSHIP:
req, err := copyInMulticastRequest(optVal, false /* allowAddr */)
if err != nil {
return err
}
return syserr.TranslateNetstackError(ep.SetSockOpt(&tcpip.RemoveMembershipOption{
NIC: tcpip.NICID(req.InterfaceIndex),
// TODO(igudger): Change DropMembership to use the standard
// any address representation.
InterfaceAddr: tcpip.Address(req.InterfaceAddr[:]),
MulticastAddr: tcpip.Address(req.MulticastAddr[:]),
}))
case linux.IP_MULTICAST_IF:
req, err := copyInMulticastRequest(optVal, true /* allowAddr */)
if err != nil {
return err
}
return syserr.TranslateNetstackError(ep.SetSockOpt(&tcpip.MulticastInterfaceOption{
NIC: tcpip.NICID(req.InterfaceIndex),
InterfaceAddr: socket.BytesToIPAddress(req.InterfaceAddr[:]),
}))
case linux.IP_MULTICAST_LOOP:
v, err := parseIntOrChar(optVal)
if err != nil {
return err
}
ep.SocketOptions().SetMulticastLoop(v != 0)
return nil
case linux.MCAST_JOIN_GROUP:
// FIXME(b/124219304): Implement MCAST_JOIN_GROUP.
t.Kernel().EmitUnimplementedEvent(t)
return syserr.ErrInvalidArgument
case linux.IP_TTL:
v, err := parseIntOrChar(optVal)
if err != nil {
return err
}
// -1 means default TTL.
if v == -1 {
v = 0
} else if v < 1 || v > 255 {
return syserr.ErrInvalidArgument
}
return syserr.TranslateNetstackError(ep.SetSockOptInt(tcpip.TTLOption, int(v)))
case linux.IP_TOS:
if len(optVal) == 0 {
return nil
}
v, err := parseIntOrChar(optVal)
if err != nil {
return err
}
return syserr.TranslateNetstackError(ep.SetSockOptInt(tcpip.IPv4TOSOption, int(v)))
case linux.IP_RECVTOS:
v, err := parseIntOrChar(optVal)
if err != nil {
return err
}
ep.SocketOptions().SetReceiveTOS(v != 0)
return nil
case linux.IP_PKTINFO:
if len(optVal) == 0 {
return nil
}
v, err := parseIntOrChar(optVal)
if err != nil {
return err
}
ep.SocketOptions().SetReceivePacketInfo(v != 0)
return nil
case linux.IP_HDRINCL:
if len(optVal) == 0 {
return nil
}
v, err := parseIntOrChar(optVal)
if err != nil {
return err
}
ep.SocketOptions().SetHeaderIncluded(v != 0)
return nil
case linux.IP_RECVORIGDSTADDR:
if len(optVal) == 0 {
return nil
}
v, err := parseIntOrChar(optVal)
if err != nil {
return err
}
ep.SocketOptions().SetReceiveOriginalDstAddress(v != 0)
return nil
case linux.IPT_SO_SET_REPLACE:
if len(optVal) < linux.SizeOfIPTReplace {
return syserr.ErrInvalidArgument
}
// Only valid for raw IPv4 sockets.
if family, skType, _ := s.Type(); family != linux.AF_INET || skType != linux.SOCK_RAW {
return syserr.ErrProtocolNotAvailable
}
stack := inet.StackFromContext(t)
if stack == nil {
return syserr.ErrNoDevice
}
// Stack must be a netstack stack.
return netfilter.SetEntries(stack.(*Stack).Stack, optVal, false)
case linux.IPT_SO_SET_ADD_COUNTERS:
// TODO(gvisor.dev/issue/170): Counter support.
return nil
case linux.IP_ADD_SOURCE_MEMBERSHIP,
linux.IP_BIND_ADDRESS_NO_PORT,
linux.IP_BLOCK_SOURCE,
linux.IP_CHECKSUM,
linux.IP_DROP_SOURCE_MEMBERSHIP,
linux.IP_FREEBIND,
linux.IP_IPSEC_POLICY,
linux.IP_MINTTL,
linux.IP_MSFILTER,
linux.IP_MTU_DISCOVER,
linux.IP_MULTICAST_ALL,
linux.IP_NODEFRAG,
linux.IP_OPTIONS,
linux.IP_PASSSEC,
linux.IP_RECVERR,
linux.IP_RECVFRAGSIZE,
linux.IP_RECVOPTS,
linux.IP_RECVTTL,
linux.IP_RETOPTS,
linux.IP_TRANSPARENT,
linux.IP_UNBLOCK_SOURCE,
linux.IP_UNICAST_IF,
linux.IP_XFRM_POLICY,
linux.MCAST_BLOCK_SOURCE,
linux.MCAST_JOIN_SOURCE_GROUP,
linux.MCAST_LEAVE_GROUP,
linux.MCAST_LEAVE_SOURCE_GROUP,
linux.MCAST_MSFILTER,
linux.MCAST_UNBLOCK_SOURCE:
t.Kernel().EmitUnimplementedEvent(t)
}
return nil
}
// emitUnimplementedEventTCP emits unimplemented event if name is valid. This
// function contains names that are common between Get and SetSockOpt when
// level is SOL_TCP.
func emitUnimplementedEventTCP(t *kernel.Task, name int) {
switch name {
case linux.TCP_CONGESTION,
linux.TCP_CORK,
linux.TCP_FASTOPEN,
linux.TCP_FASTOPEN_CONNECT,
linux.TCP_FASTOPEN_KEY,
linux.TCP_FASTOPEN_NO_COOKIE,
linux.TCP_QUEUE_SEQ,
linux.TCP_REPAIR,
linux.TCP_REPAIR_QUEUE,
linux.TCP_REPAIR_WINDOW,
linux.TCP_SAVED_SYN,
linux.TCP_SAVE_SYN,
linux.TCP_THIN_DUPACK,
linux.TCP_THIN_LINEAR_TIMEOUTS,
linux.TCP_TIMESTAMP,
linux.TCP_ULP:
t.Kernel().EmitUnimplementedEvent(t)
}
}
// emitUnimplementedEventIPv6 emits unimplemented event if name is valid. It
// contains names that are common between Get and SetSockOpt when level is
// SOL_IPV6.
func emitUnimplementedEventIPv6(t *kernel.Task, name int) {
switch name {
case linux.IPV6_2292DSTOPTS,
linux.IPV6_2292HOPLIMIT,
linux.IPV6_2292HOPOPTS,
linux.IPV6_2292PKTINFO,
linux.IPV6_2292PKTOPTIONS,
linux.IPV6_2292RTHDR,
linux.IPV6_ADDR_PREFERENCES,
linux.IPV6_AUTOFLOWLABEL,
linux.IPV6_DONTFRAG,
linux.IPV6_DSTOPTS,
linux.IPV6_FLOWINFO,
linux.IPV6_FLOWINFO_SEND,
linux.IPV6_FLOWLABEL_MGR,
linux.IPV6_FREEBIND,
linux.IPV6_HOPOPTS,
linux.IPV6_MINHOPCOUNT,
linux.IPV6_MTU,
linux.IPV6_MTU_DISCOVER,
linux.IPV6_MULTICAST_ALL,
linux.IPV6_MULTICAST_HOPS,
linux.IPV6_MULTICAST_IF,
linux.IPV6_MULTICAST_LOOP,
linux.IPV6_RECVDSTOPTS,
linux.IPV6_RECVERR,
linux.IPV6_RECVFRAGSIZE,
linux.IPV6_RECVHOPLIMIT,
linux.IPV6_RECVHOPOPTS,
linux.IPV6_RECVPATHMTU,
linux.IPV6_RECVPKTINFO,
linux.IPV6_RECVRTHDR,
linux.IPV6_RTHDR,
linux.IPV6_RTHDRDSTOPTS,
linux.IPV6_TCLASS,
linux.IPV6_TRANSPARENT,
linux.IPV6_UNICAST_HOPS,
linux.IPV6_UNICAST_IF,
linux.MCAST_MSFILTER,
linux.IPV6_ADDRFORM:
t.Kernel().EmitUnimplementedEvent(t)
}
}
// emitUnimplementedEventIP emits unimplemented event if name is valid. It
// contains names that are common between Get and SetSockOpt when level is
// SOL_IP.
func emitUnimplementedEventIP(t *kernel.Task, name int) {
switch name {
case linux.IP_TOS,
linux.IP_TTL,
linux.IP_OPTIONS,
linux.IP_ROUTER_ALERT,
linux.IP_RECVOPTS,
linux.IP_RETOPTS,
linux.IP_PKTINFO,
linux.IP_PKTOPTIONS,
linux.IP_MTU_DISCOVER,
linux.IP_RECVERR,
linux.IP_RECVTTL,
linux.IP_RECVTOS,
linux.IP_MTU,
linux.IP_FREEBIND,
linux.IP_IPSEC_POLICY,
linux.IP_XFRM_POLICY,
linux.IP_PASSSEC,
linux.IP_TRANSPARENT,
linux.IP_ORIGDSTADDR,
linux.IP_MINTTL,
linux.IP_NODEFRAG,
linux.IP_CHECKSUM,
linux.IP_BIND_ADDRESS_NO_PORT,
linux.IP_RECVFRAGSIZE,
linux.IP_MULTICAST_IF,
linux.IP_MULTICAST_TTL,
linux.IP_MULTICAST_LOOP,
linux.IP_ADD_MEMBERSHIP,
linux.IP_DROP_MEMBERSHIP,
linux.IP_UNBLOCK_SOURCE,
linux.IP_BLOCK_SOURCE,
linux.IP_ADD_SOURCE_MEMBERSHIP,
linux.IP_DROP_SOURCE_MEMBERSHIP,
linux.IP_MSFILTER,
linux.MCAST_JOIN_GROUP,
linux.MCAST_BLOCK_SOURCE,
linux.MCAST_UNBLOCK_SOURCE,
linux.MCAST_LEAVE_GROUP,
linux.MCAST_JOIN_SOURCE_GROUP,
linux.MCAST_LEAVE_SOURCE_GROUP,
linux.MCAST_MSFILTER,
linux.IP_MULTICAST_ALL,
linux.IP_UNICAST_IF:
t.Kernel().EmitUnimplementedEvent(t)
}
}
// GetSockName implements the linux syscall getsockname(2) for sockets backed by
// tcpip.Endpoint.
func (s *socketOpsCommon) GetSockName(t *kernel.Task) (linux.SockAddr, uint32, *syserr.Error) {
addr, err := s.Endpoint.GetLocalAddress()
if err != nil {
return nil, 0, syserr.TranslateNetstackError(err)
}
a, l := socket.ConvertAddress(s.family, addr)
return a, l, nil
}
// GetPeerName implements the linux syscall getpeername(2) for sockets backed by
// tcpip.Endpoint.
func (s *socketOpsCommon) GetPeerName(t *kernel.Task) (linux.SockAddr, uint32, *syserr.Error) {
addr, err := s.Endpoint.GetRemoteAddress()
if err != nil {
return nil, 0, syserr.TranslateNetstackError(err)
}
a, l := socket.ConvertAddress(s.family, addr)
return a, l, nil
}
// coalescingRead is the fast path for non-blocking, non-peek, stream-based
// case. It coalesces as many packets as possible before returning to the
// caller.
//
// Precondition: s.readMu must be locked.
func (s *socketOpsCommon) coalescingRead(ctx context.Context, dst usermem.IOSequence, discard bool) (int, *syserr.Error) {
var err *syserr.Error
var copied int
// Copy as many views as possible into the user-provided buffer.
for {
// Always do at least one fetchReadView, even if the number of bytes to
// read is 0.
err = s.fetchReadView()
if err != nil || len(s.readView) == 0 {
break
}
if dst.NumBytes() == 0 {
break
}
var n int
var e error
if discard {
n = len(s.readView)
if int64(n) > dst.NumBytes() {
n = int(dst.NumBytes())
}
} else {
n, e = dst.CopyOut(ctx, s.readView)
// Set the control message, even if 0 bytes were read.
if e == nil {
s.updateTimestamp()
}
}
copied += n
s.readView.TrimFront(n)
dst = dst.DropFirst(n)
if e != nil {
err = syserr.FromError(e)
break
}
// If we are done reading requested data then stop.
if dst.NumBytes() == 0 {
break
}
}
if len(s.readView) == 0 {
atomic.StoreUint32(&s.readViewHasData, 0)
}
// If we managed to copy something, we must deliver it.
if copied > 0 {
s.Endpoint.ModerateRecvBuf(copied)
return copied, nil
}
return 0, err
}
func (s *socketOpsCommon) fillCmsgInq(cmsg *socket.ControlMessages) {
if !s.sockOptInq {
return
}
rcvBufUsed, err := s.Endpoint.GetSockOptInt(tcpip.ReceiveQueueSizeOption)
if err != nil {
return
}
cmsg.IP.HasInq = true
cmsg.IP.Inq = int32(len(s.readView) + rcvBufUsed)
}
func toLinuxPacketType(pktType tcpip.PacketType) uint8 {
switch pktType {
case tcpip.PacketHost:
return linux.PACKET_HOST
case tcpip.PacketOtherHost:
return linux.PACKET_OTHERHOST
case tcpip.PacketOutgoing:
return linux.PACKET_OUTGOING
case tcpip.PacketBroadcast:
return linux.PACKET_BROADCAST
case tcpip.PacketMulticast:
return linux.PACKET_MULTICAST
default:
panic(fmt.Sprintf("unknown packet type: %d", pktType))
}
}
// nonBlockingRead issues a non-blocking read.
//
// TODO(b/78348848): Support timestamps for stream sockets.
func (s *socketOpsCommon) nonBlockingRead(ctx context.Context, dst usermem.IOSequence, peek, trunc, senderRequested bool) (int, int, linux.SockAddr, uint32, socket.ControlMessages, *syserr.Error) {
isPacket := s.isPacketBased()
// Fast path for regular reads from stream (e.g., TCP) endpoints. Note
// that senderRequested is ignored for stream sockets.
if !peek && !isPacket {
// TCP sockets discard the data if MSG_TRUNC is set.
//
// This behavior is documented in man 7 tcp:
// Since version 2.4, Linux supports the use of MSG_TRUNC in the flags
// argument of recv(2) (and recvmsg(2)). This flag causes the received
// bytes of data to be discarded, rather than passed back in a
// caller-supplied buffer.
s.readMu.Lock()
n, err := s.coalescingRead(ctx, dst, trunc)
cmsg := s.controlMessages()
s.fillCmsgInq(&cmsg)
s.readMu.Unlock()
return n, 0, nil, 0, cmsg, err
}
s.readMu.Lock()
defer s.readMu.Unlock()
if err := s.fetchReadView(); err != nil {
return 0, 0, nil, 0, socket.ControlMessages{}, err
}
if !isPacket && peek && trunc {
// MSG_TRUNC with MSG_PEEK on a TCP socket returns the
// amount that could be read.
rql, err := s.Endpoint.GetSockOptInt(tcpip.ReceiveQueueSizeOption)
if err != nil {
return 0, 0, nil, 0, socket.ControlMessages{}, syserr.TranslateNetstackError(err)
}
available := len(s.readView) + int(rql)
bufLen := int(dst.NumBytes())
if available < bufLen {
return available, 0, nil, 0, socket.ControlMessages{}, nil
}
return bufLen, 0, nil, 0, socket.ControlMessages{}, nil
}
n, err := dst.CopyOut(ctx, s.readView)
// Set the control message, even if 0 bytes were read.
if err == nil {
s.updateTimestamp()
}
var addr linux.SockAddr
var addrLen uint32
if isPacket && senderRequested {
addr, addrLen = socket.ConvertAddress(s.family, s.sender)
switch v := addr.(type) {
case *linux.SockAddrLink:
v.Protocol = socket.Htons(uint16(s.linkPacketInfo.Protocol))
v.PacketType = toLinuxPacketType(s.linkPacketInfo.PktType)
}
}
if peek {
if l := len(s.readView); trunc && l > n {
// isPacket must be true.
return l, linux.MSG_TRUNC, addr, addrLen, s.controlMessages(), syserr.FromError(err)
}
if isPacket || err != nil {
return n, 0, addr, addrLen, s.controlMessages(), syserr.FromError(err)
}
// We need to peek beyond the first message.
dst = dst.DropFirst(n)
num, err := dst.CopyOutFrom(ctx, safemem.FromVecReaderFunc{func(dsts [][]byte) (int64, error) {
n, err := s.Endpoint.Peek(dsts)
// TODO(b/78348848): Handle peek timestamp.
if err != nil {
return int64(n), syserr.TranslateNetstackError(err).ToError()
}
return int64(n), nil
}})
n += int(num)
if err == syserror.ErrWouldBlock && n > 0 {
// We got some data, so no need to return an error.
err = nil
}
return n, 0, nil, 0, s.controlMessages(), syserr.FromError(err)
}
var msgLen int
if isPacket {
msgLen = len(s.readView)
s.readView = nil
} else {
msgLen = int(n)
s.readView.TrimFront(int(n))
}
if len(s.readView) == 0 {
atomic.StoreUint32(&s.readViewHasData, 0)
}
var flags int
if msgLen > int(n) {
flags |= linux.MSG_TRUNC
}
if trunc {
n = msgLen
}
cmsg := s.controlMessages()
s.fillCmsgInq(&cmsg)
return n, flags, addr, addrLen, cmsg, syserr.FromError(err)
}
func (s *socketOpsCommon) controlMessages() socket.ControlMessages {
return socket.ControlMessages{
IP: socket.IPControlMessages{
HasTimestamp: s.readCM.HasTimestamp && s.sockOptTimestamp,
Timestamp: s.readCM.Timestamp,
HasTOS: s.readCM.HasTOS,
TOS: s.readCM.TOS,
HasTClass: s.readCM.HasTClass,
TClass: s.readCM.TClass,
HasIPPacketInfo: s.readCM.HasIPPacketInfo,
PacketInfo: s.readCM.PacketInfo,
OriginalDstAddress: s.readCM.OriginalDstAddress,
},
}
}
// updateTimestamp sets the timestamp for SIOCGSTAMP. It should be called after
// successfully writing packet data out to userspace.
//
// Precondition: s.readMu must be locked.
func (s *socketOpsCommon) updateTimestamp() {
// Save the SIOCGSTAMP timestamp only if SO_TIMESTAMP is disabled.
if !s.sockOptTimestamp {
s.timestampValid = true
s.timestampNS = s.readCM.Timestamp
}
}
// RecvMsg implements the linux syscall recvmsg(2) for sockets backed by
// tcpip.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
if senderRequested && !s.isPacketBased() {
// Stream sockets ignore the sender address.
senderRequested = false
}
n, msgFlags, senderAddr, senderAddrLen, controlMessages, err = s.nonBlockingRead(t, dst, peek, trunc, senderRequested)
if s.isPacketBased() && err == syserr.ErrClosedForReceive && flags&linux.MSG_DONTWAIT != 0 {
// In this situation we should return EAGAIN.
return 0, 0, nil, 0, socket.ControlMessages{}, syserr.ErrTryAgain
}
if err != nil && (err != syserr.ErrWouldBlock || dontWait) {
// Read failed and we should not retry.
return 0, 0, nil, 0, socket.ControlMessages{}, err
}
if err == nil && (dontWait || !waitAll || s.isPacketBased() || int64(n) >= dst.NumBytes()) {
// We got all the data we need.
return
}
// Don't overwrite any data we received.
dst = dst.DropFirst(n)
// We'll have to block. Register for notifications and keep trying to
// send all the data.
e, ch := waiter.NewChannelEntry(nil)
s.EventRegister(&e, waiter.EventIn)
defer s.EventUnregister(&e)
for {
var rn int
rn, msgFlags, senderAddr, senderAddrLen, controlMessages, err = s.nonBlockingRead(t, dst, peek, trunc, senderRequested)
n += rn
if err != nil && err != syserr.ErrWouldBlock {
// Always stop on errors other than would block as we generally
// won't be able to get any more data. Eat the error if we got
// any data.
if n > 0 {
err = nil
}
return
}
if err == nil && (s.isPacketBased() || !waitAll || int64(rn) >= dst.NumBytes()) {
// We got all the data we need.
return
}
dst = dst.DropFirst(rn)
if err := t.BlockWithDeadline(ch, haveDeadline, deadline); err != nil {
if n > 0 {
return n, msgFlags, senderAddr, senderAddrLen, controlMessages, nil
}
if err == syserror.ETIMEDOUT {
return 0, 0, nil, 0, socket.ControlMessages{}, syserr.ErrTryAgain
}
return 0, 0, nil, 0, socket.ControlMessages{}, syserr.FromError(err)
}
}
}
// SendMsg implements the linux syscall sendmsg(2) for sockets backed by
// tcpip.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) {
// Reject Unix control messages.
if !controlMessages.Unix.Empty() {
return 0, syserr.ErrInvalidArgument
}
var addr *tcpip.FullAddress
if len(to) > 0 {
addrBuf, family, err := socket.AddressAndFamily(to)
if err != nil {
return 0, err
}
if err := s.checkFamily(family, false /* exact */); err != nil {
return 0, err
}
addrBuf = s.mapFamily(addrBuf, family)
addr = &addrBuf
}
opts := tcpip.WriteOptions{
To: addr,
More: flags&linux.MSG_MORE != 0,
EndOfRecord: flags&linux.MSG_EOR != 0,
}
v := &ioSequencePayload{t, src}
n, resCh, err := s.Endpoint.Write(v, opts)
if resCh != nil {
if err := t.Block(resCh); err != nil {
return 0, syserr.FromError(err)
}
n, _, err = s.Endpoint.Write(v, opts)
}
dontWait := flags&linux.MSG_DONTWAIT != 0
if err == nil && (n >= v.src.NumBytes() || dontWait) {
// Complete write.
return int(n), nil
}
if err != nil && (err != tcpip.ErrWouldBlock || dontWait) {
return int(n), syserr.TranslateNetstackError(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)
v.DropFirst(int(n))
total := n
for {
n, _, err = s.Endpoint.Write(v, opts)
v.DropFirst(int(n))
total += n
if err != nil && err != tcpip.ErrWouldBlock && total == 0 {
return 0, syserr.TranslateNetstackError(err)
}
if err == nil && v.src.NumBytes() == 0 || err != nil && err != tcpip.ErrWouldBlock {
return int(total), nil
}
if err := t.BlockWithDeadline(ch, haveDeadline, deadline); err != nil {
if err == syserror.ETIMEDOUT {
return int(total), syserr.ErrTryAgain
}
// handleIOError will consume errors from t.Block if needed.
return int(total), syserr.FromError(err)
}
}
}
// Ioctl implements fs.FileOperations.Ioctl.
func (s *SocketOperations) Ioctl(ctx context.Context, _ *fs.File, io usermem.IO, args arch.SyscallArguments) (uintptr, error) {
return s.socketOpsCommon.ioctl(ctx, io, args)
}
func (s *socketOpsCommon) ioctl(ctx context.Context, io usermem.IO, args arch.SyscallArguments) (uintptr, error) {
t := kernel.TaskFromContext(ctx)
if t == nil {
panic("ioctl(2) may only be called from a task goroutine")
}
// SIOCGSTAMP is implemented by netstack rather than all commonEndpoint
// sockets.
// TODO(b/78348848): Add a commonEndpoint method to support SIOCGSTAMP.
switch args[1].Int() {
case linux.SIOCGSTAMP:
s.readMu.Lock()
defer s.readMu.Unlock()
if !s.timestampValid {
return 0, syserror.ENOENT
}
tv := linux.NsecToTimeval(s.timestampNS)
_, err := tv.CopyOut(t, args[2].Pointer())
return 0, err
case linux.TIOCINQ:
v, terr := s.Endpoint.GetSockOptInt(tcpip.ReceiveQueueSizeOption)
if terr != nil {
return 0, syserr.TranslateNetstackError(terr).ToError()
}
// Add bytes removed from the endpoint but not yet sent to the caller.
s.readMu.Lock()
v += len(s.readView)
s.readMu.Unlock()
if v > math.MaxInt32 {
v = math.MaxInt32
}
// Copy result to userspace.
vP := primitive.Int32(v)
_, err := vP.CopyOut(t, args[2].Pointer())
return 0, err
}
return Ioctl(ctx, s.Endpoint, io, args)
}
// Ioctl performs a socket ioctl.
func Ioctl(ctx context.Context, ep commonEndpoint, io usermem.IO, args arch.SyscallArguments) (uintptr, error) {
t := kernel.TaskFromContext(ctx)
if t == nil {
panic("ioctl(2) may only be called from a task goroutine")
}
switch arg := int(args[1].Int()); arg {
case linux.SIOCGIFFLAGS,
linux.SIOCGIFADDR,
linux.SIOCGIFBRDADDR,
linux.SIOCGIFDSTADDR,
linux.SIOCGIFHWADDR,
linux.SIOCGIFINDEX,
linux.SIOCGIFMAP,
linux.SIOCGIFMETRIC,
linux.SIOCGIFMTU,
linux.SIOCGIFNAME,
linux.SIOCGIFNETMASK,
linux.SIOCGIFTXQLEN,
linux.SIOCETHTOOL:
var ifr linux.IFReq
if _, err := ifr.CopyIn(t, args[2].Pointer()); err != nil {
return 0, err
}
if err := interfaceIoctl(ctx, io, arg, &ifr); err != nil {
return 0, err.ToError()
}
_, err := ifr.CopyOut(t, args[2].Pointer())
return 0, err
case linux.SIOCGIFCONF:
// Return a list of interface addresses or the buffer size
// necessary to hold the list.
var ifc linux.IFConf
if _, err := ifc.CopyIn(t, args[2].Pointer()); err != nil {
return 0, err
}
if err := ifconfIoctl(ctx, t, io, &ifc); err != nil {
return 0, err
}
_, err := ifc.CopyOut(t, args[2].Pointer())
return 0, err
case linux.TIOCINQ:
v, terr := ep.GetSockOptInt(tcpip.ReceiveQueueSizeOption)
if terr != nil {
return 0, syserr.TranslateNetstackError(terr).ToError()
}
if v > math.MaxInt32 {
v = math.MaxInt32
}
// Copy result to userspace.
vP := primitive.Int32(v)
_, err := vP.CopyOut(t, args[2].Pointer())
return 0, err
case linux.TIOCOUTQ:
v, terr := ep.GetSockOptInt(tcpip.SendQueueSizeOption)
if terr != nil {
return 0, syserr.TranslateNetstackError(terr).ToError()
}
if v > math.MaxInt32 {
v = math.MaxInt32
}
// Copy result to userspace.
vP := primitive.Int32(v)
_, err := vP.CopyOut(t, args[2].Pointer())
return 0, err
case linux.SIOCGIFMEM, linux.SIOCGIFPFLAGS, linux.SIOCGMIIPHY, linux.SIOCGMIIREG:
unimpl.EmitUnimplementedEvent(ctx)
}
return 0, syserror.ENOTTY
}
// interfaceIoctl implements interface requests.
func interfaceIoctl(ctx context.Context, io usermem.IO, arg int, ifr *linux.IFReq) *syserr.Error {
var (
iface inet.Interface
index int32
found bool
)
// Find the relevant device.
stack := inet.StackFromContext(ctx)
if stack == nil {
return syserr.ErrNoDevice
}
// SIOCGIFNAME uses ifr.ifr_ifindex rather than ifr.ifr_name to
// identify a device.
if arg == linux.SIOCGIFNAME {
// Gets the name of the interface given the interface index
// stored in ifr_ifindex.
index = int32(usermem.ByteOrder.Uint32(ifr.Data[:4]))
if iface, ok := stack.Interfaces()[index]; ok {
ifr.SetName(iface.Name)
return nil
}
return syserr.ErrNoDevice
}
// Find the relevant device.
for index, iface = range stack.Interfaces() {
if iface.Name == ifr.Name() {
found = true
break
}
}
if !found {
return syserr.ErrNoDevice
}
switch arg {
case linux.SIOCGIFINDEX:
// Copy out the index to the data.
usermem.ByteOrder.PutUint32(ifr.Data[:], uint32(index))
case linux.SIOCGIFHWADDR:
// Copy the hardware address out.
//
// Refer: https://linux.die.net/man/7/netdevice
// SIOCGIFHWADDR, SIOCSIFHWADDR
//
// Get or set the hardware address of a device using
// ifr_hwaddr. The hardware address is specified in a struct
// sockaddr. sa_family contains the ARPHRD_* device type,
// sa_data the L2 hardware address starting from byte 0. Setting
// the hardware address is a privileged operation.
usermem.ByteOrder.PutUint16(ifr.Data[:], iface.DeviceType)
n := copy(ifr.Data[2:], iface.Addr)
for i := 2 + n; i < len(ifr.Data); i++ {
ifr.Data[i] = 0 // Clear padding.
}
case linux.SIOCGIFFLAGS:
f, err := interfaceStatusFlags(stack, iface.Name)
if err != nil {
return err
}
// Drop the flags that don't fit in the size that we need to return. This
// matches Linux behavior.
usermem.ByteOrder.PutUint16(ifr.Data[:2], uint16(f))
case linux.SIOCGIFADDR:
// Copy the IPv4 address out.
for _, addr := range stack.InterfaceAddrs()[index] {
// This ioctl is only compatible with AF_INET addresses.
if addr.Family != linux.AF_INET {
continue
}
copy(ifr.Data[4:8], addr.Addr)
break
}
case linux.SIOCGIFMETRIC:
// Gets the metric of the device. As per netdevice(7), this
// always just sets ifr_metric to 0.
usermem.ByteOrder.PutUint32(ifr.Data[:4], 0)
case linux.SIOCGIFMTU:
// Gets the MTU of the device.
usermem.ByteOrder.PutUint32(ifr.Data[:4], iface.MTU)
case linux.SIOCGIFMAP:
// Gets the hardware parameters of the device.
// TODO(gvisor.dev/issue/505): Implement.
case linux.SIOCGIFTXQLEN:
// Gets the transmit queue length of the device.
// TODO(gvisor.dev/issue/505): Implement.
case linux.SIOCGIFDSTADDR:
// Gets the destination address of a point-to-point device.
// TODO(gvisor.dev/issue/505): Implement.
case linux.SIOCGIFBRDADDR:
// Gets the broadcast address of a device.
// TODO(gvisor.dev/issue/505): Implement.
case linux.SIOCGIFNETMASK:
// Gets the network mask of a device.
for _, addr := range stack.InterfaceAddrs()[index] {
// This ioctl is only compatible with AF_INET addresses.
if addr.Family != linux.AF_INET {
continue
}
// Populate ifr.ifr_netmask (type sockaddr).
usermem.ByteOrder.PutUint16(ifr.Data[0:2], uint16(linux.AF_INET))
usermem.ByteOrder.PutUint16(ifr.Data[2:4], 0)
var mask uint32 = 0xffffffff << (32 - addr.PrefixLen)
// Netmask is expected to be returned as a big endian
// value.
binary.BigEndian.PutUint32(ifr.Data[4:8], mask)
break
}
case linux.SIOCETHTOOL:
// Stubbed out for now, Ideally we should implement the required
// sub-commands for ETHTOOL
//
// See:
// https://github.com/torvalds/linux/blob/aa0c9086b40c17a7ad94425b3b70dd1fdd7497bf/net/core/dev_ioctl.c
return syserr.ErrEndpointOperation
default:
// Not a valid call.
return syserr.ErrInvalidArgument
}
return nil
}
// ifconfIoctl populates a struct ifconf for the SIOCGIFCONF ioctl.
func ifconfIoctl(ctx context.Context, t *kernel.Task, io usermem.IO, ifc *linux.IFConf) error {
// If Ptr is NULL, return the necessary buffer size via Len.
// Otherwise, write up to Len bytes starting at Ptr containing ifreq
// structs.
stack := inet.StackFromContext(ctx)
if stack == nil {
return syserr.ErrNoDevice.ToError()
}
if ifc.Ptr == 0 {
ifc.Len = int32(len(stack.Interfaces())) * int32(linux.SizeOfIFReq)
return nil
}
max := ifc.Len
ifc.Len = 0
for key, ifaceAddrs := range stack.InterfaceAddrs() {
iface := stack.Interfaces()[key]
for _, ifaceAddr := range ifaceAddrs {
// Don't write past the end of the buffer.
if ifc.Len+int32(linux.SizeOfIFReq) > max {
break
}
if ifaceAddr.Family != linux.AF_INET {
continue
}
// Populate ifr.ifr_addr.
ifr := linux.IFReq{}
ifr.SetName(iface.Name)
usermem.ByteOrder.PutUint16(ifr.Data[0:2], uint16(ifaceAddr.Family))
usermem.ByteOrder.PutUint16(ifr.Data[2:4], 0)
copy(ifr.Data[4:8], ifaceAddr.Addr[:4])
// Copy the ifr to userspace.
dst := uintptr(ifc.Ptr) + uintptr(ifc.Len)
ifc.Len += int32(linux.SizeOfIFReq)
if _, err := ifr.CopyOut(t, usermem.Addr(dst)); err != nil {
return err
}
}
}
return nil
}
// interfaceStatusFlags returns status flags for an interface in the stack.
// Flag values and meanings are described in greater detail in netdevice(7) in
// the SIOCGIFFLAGS section.
func interfaceStatusFlags(stack inet.Stack, name string) (uint32, *syserr.Error) {
// We should only ever be passed a netstack.Stack.
epstack, ok := stack.(*Stack)
if !ok {
return 0, errStackType
}
// Find the NIC corresponding to this interface.
for _, info := range epstack.Stack.NICInfo() {
if info.Name == name {
return nicStateFlagsToLinux(info.Flags), nil
}
}
return 0, syserr.ErrNoDevice
}
func nicStateFlagsToLinux(f stack.NICStateFlags) uint32 {
var rv uint32
if f.Up {
rv |= linux.IFF_UP | linux.IFF_LOWER_UP
}
if f.Running {
rv |= linux.IFF_RUNNING
}
if f.Promiscuous {
rv |= linux.IFF_PROMISC
}
if f.Loopback {
rv |= linux.IFF_LOOPBACK
}
return rv
}
func isTCPSocket(skType linux.SockType, skProto int) bool {
return skType == linux.SOCK_STREAM && (skProto == 0 || skProto == syscall.IPPROTO_TCP)
}
func isUDPSocket(skType linux.SockType, skProto int) bool {
return skType == linux.SOCK_DGRAM && (skProto == 0 || skProto == syscall.IPPROTO_UDP)
}
func isICMPSocket(skType linux.SockType, skProto int) bool {
return skType == linux.SOCK_DGRAM && (skProto == syscall.IPPROTO_ICMP || skProto == syscall.IPPROTO_ICMPV6)
}
// State implements socket.Socket.State. State translates the internal state
// returned by netstack to values defined by Linux.
func (s *socketOpsCommon) State() uint32 {
if s.family != linux.AF_INET && s.family != linux.AF_INET6 {
// States not implemented for this socket's family.
return 0
}
switch {
case isTCPSocket(s.skType, s.protocol):
// TCP socket.
switch tcp.EndpointState(s.Endpoint.State()) {
case tcp.StateEstablished:
return linux.TCP_ESTABLISHED
case tcp.StateSynSent:
return linux.TCP_SYN_SENT
case tcp.StateSynRecv:
return linux.TCP_SYN_RECV
case tcp.StateFinWait1:
return linux.TCP_FIN_WAIT1
case tcp.StateFinWait2:
return linux.TCP_FIN_WAIT2
case tcp.StateTimeWait:
return linux.TCP_TIME_WAIT
case tcp.StateClose, tcp.StateInitial, tcp.StateBound, tcp.StateConnecting, tcp.StateError:
return linux.TCP_CLOSE
case tcp.StateCloseWait:
return linux.TCP_CLOSE_WAIT
case tcp.StateLastAck:
return linux.TCP_LAST_ACK
case tcp.StateListen:
return linux.TCP_LISTEN
case tcp.StateClosing:
return linux.TCP_CLOSING
default:
// Internal or unknown state.
return 0
}
case isUDPSocket(s.skType, s.protocol):
// UDP socket.
switch udp.EndpointState(s.Endpoint.State()) {
case udp.StateInitial, udp.StateBound, udp.StateClosed:
return linux.TCP_CLOSE
case udp.StateConnected:
return linux.TCP_ESTABLISHED
default:
return 0
}
case isICMPSocket(s.skType, s.protocol):
// TODO(b/112063468): Export states for ICMP sockets.
case s.skType == linux.SOCK_RAW:
// TODO(b/112063468): Export states for raw sockets.
default:
// Unknown transport protocol, how did we make this socket?
log.Warningf("Unknown transport protocol for an existing socket: family=%v, type=%v, protocol=%v, internal type %v", s.family, s.skType, s.protocol, reflect.TypeOf(s.Endpoint).Elem())
return 0
}
return 0
}
// Type implements socket.Socket.Type.
func (s *socketOpsCommon) Type() (family int, skType linux.SockType, protocol int) {
return s.family, s.skType, s.protocol
}
// LINT.ThenChange(./netstack_vfs2.go)
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