// 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 tcpip provides the interfaces and related types that users of the // tcpip stack will use in order to create endpoints used to send and receive // data over the network stack. // // The starting point is the creation and configuration of a stack. A stack can // be created by calling the New() function of the tcpip/stack/stack package; // configuring a stack involves creating NICs (via calls to Stack.CreateNIC()), // adding network addresses (via calls to Stack.AddAddress()), and // setting a route table (via a call to Stack.SetRouteTable()). // // Once a stack is configured, endpoints can be created by calling // Stack.NewEndpoint(). Such endpoints can be used to send/receive data, connect // to peers, listen for connections, accept connections, etc., depending on the // transport protocol selected. package tcpip import ( "errors" "fmt" "math/bits" "reflect" "strconv" "strings" "sync" "sync/atomic" "time" "gvisor.dev/gvisor/pkg/tcpip/buffer" "gvisor.dev/gvisor/pkg/tcpip/iptables" "gvisor.dev/gvisor/pkg/waiter" ) // Error represents an error in the netstack error space. Using a special type // ensures that errors outside of this space are not accidentally introduced. // // Note: to support save / restore, it is important that all tcpip errors have // distinct error messages. type Error struct { msg string ignoreStats bool } // String implements fmt.Stringer.String. func (e *Error) String() string { if e == nil { return "" } return e.msg } // IgnoreStats indicates whether this error type should be included in failure // counts in tcpip.Stats structs. func (e *Error) IgnoreStats() bool { return e.ignoreStats } // Errors that can be returned by the network stack. var ( ErrUnknownProtocol = &Error{msg: "unknown protocol"} ErrUnknownNICID = &Error{msg: "unknown nic id"} ErrUnknownDevice = &Error{msg: "unknown device"} ErrUnknownProtocolOption = &Error{msg: "unknown option for protocol"} ErrDuplicateNICID = &Error{msg: "duplicate nic id"} ErrDuplicateAddress = &Error{msg: "duplicate address"} ErrNoRoute = &Error{msg: "no route"} ErrBadLinkEndpoint = &Error{msg: "bad link layer endpoint"} ErrAlreadyBound = &Error{msg: "endpoint already bound", ignoreStats: true} ErrInvalidEndpointState = &Error{msg: "endpoint is in invalid state"} ErrAlreadyConnecting = &Error{msg: "endpoint is already connecting", ignoreStats: true} ErrAlreadyConnected = &Error{msg: "endpoint is already connected", ignoreStats: true} ErrNoPortAvailable = &Error{msg: "no ports are available"} ErrPortInUse = &Error{msg: "port is in use"} ErrBadLocalAddress = &Error{msg: "bad local address"} ErrClosedForSend = &Error{msg: "endpoint is closed for send"} ErrClosedForReceive = &Error{msg: "endpoint is closed for receive"} ErrWouldBlock = &Error{msg: "operation would block", ignoreStats: true} ErrConnectionRefused = &Error{msg: "connection was refused"} ErrTimeout = &Error{msg: "operation timed out"} ErrAborted = &Error{msg: "operation aborted"} ErrConnectStarted = &Error{msg: "connection attempt started", ignoreStats: true} ErrDestinationRequired = &Error{msg: "destination address is required"} ErrNotSupported = &Error{msg: "operation not supported"} ErrQueueSizeNotSupported = &Error{msg: "queue size querying not supported"} ErrNotConnected = &Error{msg: "endpoint not connected"} ErrConnectionReset = &Error{msg: "connection reset by peer"} ErrConnectionAborted = &Error{msg: "connection aborted"} ErrNoSuchFile = &Error{msg: "no such file"} ErrInvalidOptionValue = &Error{msg: "invalid option value specified"} ErrNoLinkAddress = &Error{msg: "no remote link address"} ErrBadAddress = &Error{msg: "bad address"} ErrNetworkUnreachable = &Error{msg: "network is unreachable"} ErrMessageTooLong = &Error{msg: "message too long"} ErrNoBufferSpace = &Error{msg: "no buffer space available"} ErrBroadcastDisabled = &Error{msg: "broadcast socket option disabled"} ErrNotPermitted = &Error{msg: "operation not permitted"} ErrAddressFamilyNotSupported = &Error{msg: "address family not supported by protocol"} ) // Errors related to Subnet var ( errSubnetLengthMismatch = errors.New("subnet length of address and mask differ") errSubnetAddressMasked = errors.New("subnet address has bits set outside the mask") ) // ErrSaveRejection indicates a failed save due to unsupported networking state. // This type of errors is only used for save logic. type ErrSaveRejection struct { Err error } // Error returns a sensible description of the save rejection error. func (e ErrSaveRejection) Error() string { return "save rejected due to unsupported networking state: " + e.Err.Error() } // A Clock provides the current time. // // Times returned by a Clock should always be used for application-visible // time. Only monotonic times should be used for netstack internal timekeeping. type Clock interface { // NowNanoseconds returns the current real time as a number of // nanoseconds since the Unix epoch. NowNanoseconds() int64 // NowMonotonic returns a monotonic time value. NowMonotonic() int64 } // Address is a byte slice cast as a string that represents the address of a // network node. Or, in the case of unix endpoints, it may represent a path. type Address string // AddressMask is a bitmask for an address. type AddressMask string // String implements Stringer. func (m AddressMask) String() string { return Address(m).String() } // Prefix returns the number of bits before the first host bit. func (m AddressMask) Prefix() int { p := 0 for _, b := range []byte(m) { p += bits.LeadingZeros8(^b) } return p } // Subnet is a subnet defined by its address and mask. type Subnet struct { address Address mask AddressMask } // NewSubnet creates a new Subnet, checking that the address and mask are the same length. func NewSubnet(a Address, m AddressMask) (Subnet, error) { if len(a) != len(m) { return Subnet{}, errSubnetLengthMismatch } for i := 0; i < len(a); i++ { if a[i]&^m[i] != 0 { return Subnet{}, errSubnetAddressMasked } } return Subnet{a, m}, nil } // String implements Stringer. func (s Subnet) String() string { return fmt.Sprintf("%s/%d", s.ID(), s.Prefix()) } // Contains returns true iff the address is of the same length and matches the // subnet address and mask. func (s *Subnet) Contains(a Address) bool { if len(a) != len(s.address) { return false } for i := 0; i < len(a); i++ { if a[i]&s.mask[i] != s.address[i] { return false } } return true } // ID returns the subnet ID. func (s *Subnet) ID() Address { return s.address } // Bits returns the number of ones (network bits) and zeros (host bits) in the // subnet mask. func (s *Subnet) Bits() (ones int, zeros int) { ones = s.mask.Prefix() return ones, len(s.mask)*8 - ones } // Prefix returns the number of bits before the first host bit. func (s *Subnet) Prefix() int { return s.mask.Prefix() } // Mask returns the subnet mask. func (s *Subnet) Mask() AddressMask { return s.mask } // Broadcast returns the subnet's broadcast address. func (s *Subnet) Broadcast() Address { addr := []byte(s.address) for i := range addr { addr[i] |= ^s.mask[i] } return Address(addr) } // Equal returns true if s equals o. // // Needed to use cmp.Equal on Subnet as its fields are unexported. func (s Subnet) Equal(o Subnet) bool { return s == o } // NICID is a number that uniquely identifies a NIC. type NICID int32 // ShutdownFlags represents flags that can be passed to the Shutdown() method // of the Endpoint interface. type ShutdownFlags int // Values of the flags that can be passed to the Shutdown() method. They can // be OR'ed together. const ( ShutdownRead ShutdownFlags = 1 << iota ShutdownWrite ) // FullAddress represents a full transport node address, as required by the // Connect() and Bind() methods. // // +stateify savable type FullAddress struct { // NIC is the ID of the NIC this address refers to. // // This may not be used by all endpoint types. NIC NICID // Addr is the network or link layer address. Addr Address // Port is the transport port. // // This may not be used by all endpoint types. Port uint16 } // Payloader is an interface that provides data. // // This interface allows the endpoint to request the amount of data it needs // based on internal buffers without exposing them. type Payloader interface { // FullPayload returns all available bytes. FullPayload() ([]byte, *Error) // Payload returns a slice containing at most size bytes. Payload(size int) ([]byte, *Error) } // SlicePayload implements Payloader for slices. // // This is typically used for tests. type SlicePayload []byte // FullPayload implements Payloader.FullPayload. func (s SlicePayload) FullPayload() ([]byte, *Error) { return s, nil } // Payload implements Payloader.Payload. func (s SlicePayload) Payload(size int) ([]byte, *Error) { if size > len(s) { size = len(s) } return s[:size], nil } // A ControlMessages contains socket control messages for IP sockets. // // +stateify savable type ControlMessages struct { // HasTimestamp indicates whether Timestamp is valid/set. HasTimestamp bool // Timestamp is the time (in ns) that the last packet used to create // the read data was received. Timestamp int64 // HasInq indicates whether Inq is valid/set. HasInq bool // Inq is the number of bytes ready to be received. Inq int32 // HasTOS indicates whether Tos is valid/set. HasTOS bool // TOS is the IPv4 type of service of the associated packet. TOS uint8 // HasTClass indicates whether Tclass is valid/set. HasTClass bool // Tclass is the IPv6 traffic class of the associated packet. TClass int32 } // Endpoint is the interface implemented by transport protocols (e.g., tcp, udp) // that exposes functionality like read, write, connect, etc. to users of the // networking stack. type Endpoint interface { // Close puts the endpoint in a closed state and frees all resources // associated with it. Close() // Read reads data from the endpoint and optionally returns the sender. // // This method does not block if there is no data pending. It will also // either return an error or data, never both. Read(*FullAddress) (buffer.View, ControlMessages, *Error) // Write writes data to the endpoint's peer. This method does not block if // the data cannot be written. // // Unlike io.Writer.Write, Endpoint.Write transfers ownership of any bytes // successfully written to the Endpoint. That is, if a call to // Write(SlicePayload{data}) returns (n, err), it may retain data[:n], and // the caller should not use data[:n] after Write returns. // // Note that unlike io.Writer.Write, it is not an error for Write to // perform a partial write (if n > 0, no error may be returned). Only // stream (TCP) Endpoints may return partial writes, and even then only // in the case where writing additional data would block. Other Endpoints // will either write the entire message or return an error. // // For UDP and Ping sockets if address resolution is required, // ErrNoLinkAddress and a notification channel is returned for the caller to // block. Channel is closed once address resolution is complete (success or // not). The channel is only non-nil in this case. Write(Payloader, WriteOptions) (int64, <-chan struct{}, *Error) // Peek reads data without consuming it from the endpoint. // // This method does not block if there is no data pending. Peek([][]byte) (int64, ControlMessages, *Error) // Connect connects the endpoint to its peer. Specifying a NIC is // optional. // // There are three classes of return values: // nil -- the attempt to connect succeeded. // ErrConnectStarted/ErrAlreadyConnecting -- the connect attempt started // but hasn't completed yet. In this case, the caller must call Connect // or GetSockOpt(ErrorOption) when the endpoint becomes writable to // get the actual result. The first call to Connect after the socket has // connected returns nil. Calling connect again results in ErrAlreadyConnected. // Anything else -- the attempt to connect failed. // // If address.Addr is empty, this means that Enpoint has to be // disconnected if this is supported, otherwise // ErrAddressFamilyNotSupported must be returned. Connect(address FullAddress) *Error // Disconnect disconnects the endpoint from its peer. Disconnect() *Error // Shutdown closes the read and/or write end of the endpoint connection // to its peer. Shutdown(flags ShutdownFlags) *Error // Listen puts the endpoint in "listen" mode, which allows it to accept // new connections. Listen(backlog int) *Error // Accept returns a new endpoint if a peer has established a connection // to an endpoint previously set to listen mode. This method does not // block if no new connections are available. // // The returned Queue is the wait queue for the newly created endpoint. Accept() (Endpoint, *waiter.Queue, *Error) // Bind binds the endpoint to a specific local address and port. // Specifying a NIC is optional. Bind(address FullAddress) *Error // GetLocalAddress returns the address to which the endpoint is bound. GetLocalAddress() (FullAddress, *Error) // GetRemoteAddress returns the address to which the endpoint is // connected. GetRemoteAddress() (FullAddress, *Error) // Readiness returns the current readiness of the endpoint. For example, // if waiter.EventIn is set, the endpoint is immediately readable. Readiness(mask waiter.EventMask) waiter.EventMask // SetSockOpt sets a socket option. opt should be one of the *Option types. SetSockOpt(opt interface{}) *Error // SetSockOptInt sets a socket option, for simple cases where a value // has the int type. SetSockOptInt(opt SockOpt, v int) *Error // GetSockOpt gets a socket option. opt should be a pointer to one of the // *Option types. GetSockOpt(opt interface{}) *Error // GetSockOptInt gets a socket option for simple cases where a return // value has the int type. GetSockOptInt(SockOpt) (int, *Error) // State returns a socket's lifecycle state. The returned value is // protocol-specific and is primarily used for diagnostics. State() uint32 // ModerateRecvBuf should be called everytime data is copied to the user // space. This allows for dynamic tuning of recv buffer space for a // given socket. // // NOTE: This method is a no-op for sockets other than TCP. ModerateRecvBuf(copied int) // IPTables returns the iptables for this endpoint's stack. IPTables() (iptables.IPTables, error) // Info returns a copy to the transport endpoint info. Info() EndpointInfo // Stats returns a reference to the endpoint stats. Stats() EndpointStats } // EndpointInfo is the interface implemented by each endpoint info struct. type EndpointInfo interface { // IsEndpointInfo is an empty method to implement the tcpip.EndpointInfo // marker interface. IsEndpointInfo() } // EndpointStats is the interface implemented by each endpoint stats struct. type EndpointStats interface { // IsEndpointStats is an empty method to implement the tcpip.EndpointStats // marker interface. IsEndpointStats() } // WriteOptions contains options for Endpoint.Write. type WriteOptions struct { // If To is not nil, write to the given address instead of the endpoint's // peer. To *FullAddress // More has the same semantics as Linux's MSG_MORE. More bool // EndOfRecord has the same semantics as Linux's MSG_EOR. EndOfRecord bool // Atomic means that all data fetched from Payloader must be written to the // endpoint. If Atomic is false, then data fetched from the Payloader may be // discarded if available endpoint buffer space is unsufficient. Atomic bool } // SockOpt represents socket options which values have the int type. type SockOpt int const ( // ReceiveQueueSizeOption is used in GetSockOptInt to specify that the // number of unread bytes in the input buffer should be returned. ReceiveQueueSizeOption SockOpt = iota // SendBufferSizeOption is used by SetSockOptInt/GetSockOptInt to // specify the send buffer size option. SendBufferSizeOption // ReceiveBufferSizeOption is used by SetSockOptInt/GetSockOptInt to // specify the receive buffer size option. ReceiveBufferSizeOption // SendQueueSizeOption is used in GetSockOptInt to specify that the // number of unread bytes in the output buffer should be returned. SendQueueSizeOption // DelayOption is used by SetSockOpt/GetSockOpt to specify if data // should be sent out immediately by the transport protocol. For TCP, // it determines if the Nagle algorithm is on or off. DelayOption // TODO(b/137664753): convert all int socket options to be handled via // GetSockOptInt. ) // ErrorOption is used in GetSockOpt to specify that the last error reported by // the endpoint should be cleared and returned. type ErrorOption struct{} // V6OnlyOption is used by SetSockOpt/GetSockOpt to specify whether an IPv6 // socket is to be restricted to sending and receiving IPv6 packets only. type V6OnlyOption int // CorkOption is used by SetSockOpt/GetSockOpt to specify if data should be // held until segments are full by the TCP transport protocol. type CorkOption int // ReuseAddressOption is used by SetSockOpt/GetSockOpt to specify whether Bind() // should allow reuse of local address. type ReuseAddressOption int // ReusePortOption is used by SetSockOpt/GetSockOpt to permit multiple sockets // to be bound to an identical socket address. type ReusePortOption int // BindToDeviceOption is used by SetSockOpt/GetSockOpt to specify that sockets // should bind only on a specific NIC. type BindToDeviceOption string // QuickAckOption is stubbed out in SetSockOpt/GetSockOpt. type QuickAckOption int // PasscredOption is used by SetSockOpt/GetSockOpt to specify whether // SCM_CREDENTIALS socket control messages are enabled. // // Only supported on Unix sockets. type PasscredOption int // TCPInfoOption is used by GetSockOpt to expose TCP statistics. // // TODO(b/64800844): Add and populate stat fields. type TCPInfoOption struct { RTT time.Duration RTTVar time.Duration } // KeepaliveEnabledOption is used by SetSockOpt/GetSockOpt to specify whether // TCP keepalive is enabled for this socket. type KeepaliveEnabledOption int // KeepaliveIdleOption is used by SetSockOpt/GetSockOpt to specify the time a // connection must remain idle before the first TCP keepalive packet is sent. // Once this time is reached, KeepaliveIntervalOption is used instead. type KeepaliveIdleOption time.Duration // KeepaliveIntervalOption is used by SetSockOpt/GetSockOpt to specify the // interval between sending TCP keepalive packets. type KeepaliveIntervalOption time.Duration // KeepaliveCountOption is used by SetSockOpt/GetSockOpt to specify the number // of un-ACKed TCP keepalives that will be sent before the connection is // closed. type KeepaliveCountOption int // TCPUserTimeoutOption is used by SetSockOpt/GetSockOpt to specify a user // specified timeout for a given TCP connection. // See: RFC5482 for details. type TCPUserTimeoutOption time.Duration // CongestionControlOption is used by SetSockOpt/GetSockOpt to set/get // the current congestion control algorithm. type CongestionControlOption string // AvailableCongestionControlOption is used to query the supported congestion // control algorithms. type AvailableCongestionControlOption string // ModerateReceiveBufferOption allows the caller to enable/disable TCP receive // buffer moderation. type ModerateReceiveBufferOption bool // MaxSegOption is used by SetSockOpt/GetSockOpt to set/get the current // Maximum Segment Size(MSS) value as specified using the TCP_MAXSEG option. type MaxSegOption int // TTLOption is used by SetSockOpt/GetSockOpt to control the default TTL/hop // limit value for unicast messages. The default is protocol specific. // // A zero value indicates the default. type TTLOption uint8 // TCPLingerTimeoutOption is used by SetSockOpt/GetSockOpt to set/get the // maximum duration for which a socket lingers in the TCP_FIN_WAIT_2 state // before being marked closed. type TCPLingerTimeoutOption time.Duration // TCPTimeWaitTimeoutOption is used by SetSockOpt/GetSockOpt to set/get the // maximum duration for which a socket lingers in the TIME_WAIT state // before being marked closed. type TCPTimeWaitTimeoutOption time.Duration // MulticastTTLOption is used by SetSockOpt/GetSockOpt to control the default // TTL value for multicast messages. The default is 1. type MulticastTTLOption uint8 // MulticastInterfaceOption is used by SetSockOpt/GetSockOpt to specify a // default interface for multicast. type MulticastInterfaceOption struct { NIC NICID InterfaceAddr Address } // MulticastLoopOption is used by SetSockOpt/GetSockOpt to specify whether // multicast packets sent over a non-loopback interface will be looped back. type MulticastLoopOption bool // MembershipOption is used by SetSockOpt/GetSockOpt as an argument to // AddMembershipOption and RemoveMembershipOption. type MembershipOption struct { NIC NICID InterfaceAddr Address MulticastAddr Address } // AddMembershipOption is used by SetSockOpt/GetSockOpt to join a multicast // group identified by the given multicast address, on the interface matching // the given interface address. type AddMembershipOption MembershipOption // RemoveMembershipOption is used by SetSockOpt/GetSockOpt to leave a multicast // group identified by the given multicast address, on the interface matching // the given interface address. type RemoveMembershipOption MembershipOption // OutOfBandInlineOption is used by SetSockOpt/GetSockOpt to specify whether // TCP out-of-band data is delivered along with the normal in-band data. type OutOfBandInlineOption int // BroadcastOption is used by SetSockOpt/GetSockOpt to specify whether // datagram sockets are allowed to send packets to a broadcast address. type BroadcastOption int // DefaultTTLOption is used by stack.(*Stack).NetworkProtocolOption to specify // a default TTL. type DefaultTTLOption uint8 // IPv4TOSOption is used by SetSockOpt/GetSockOpt to specify TOS // for all subsequent outgoing IPv4 packets from the endpoint. type IPv4TOSOption uint8 // IPv6TrafficClassOption is used by SetSockOpt/GetSockOpt to specify TOS // for all subsequent outgoing IPv6 packets from the endpoint. type IPv6TrafficClassOption uint8 // ReceiveTOSOption is used by SetSockOpt/GetSockOpt to specify if the TOS // ancillary message is passed with incoming packets. type ReceiveTOSOption bool // Route is a row in the routing table. It specifies through which NIC (and // gateway) sets of packets should be routed. A row is considered viable if the // masked target address matches the destination address in the row. type Route struct { // Destination must contain the target address for this row to be viable. Destination Subnet // Gateway is the gateway to be used if this row is viable. Gateway Address // NIC is the id of the nic to be used if this row is viable. NIC NICID } // String implements the fmt.Stringer interface. func (r Route) String() string { var out strings.Builder fmt.Fprintf(&out, "%s", r.Destination) if len(r.Gateway) > 0 { fmt.Fprintf(&out, " via %s", r.Gateway) } fmt.Fprintf(&out, " nic %d", r.NIC) return out.String() } // TransportProtocolNumber is the number of a transport protocol. type TransportProtocolNumber uint32 // NetworkProtocolNumber is the number of a network protocol. type NetworkProtocolNumber uint32 // A StatCounter keeps track of a statistic. type StatCounter struct { count uint64 } // Increment adds one to the counter. func (s *StatCounter) Increment() { s.IncrementBy(1) } // Decrement minuses one to the counter. func (s *StatCounter) Decrement() { s.IncrementBy(^uint64(0)) } // Value returns the current value of the counter. func (s *StatCounter) Value() uint64 { return atomic.LoadUint64(&s.count) } // IncrementBy increments the counter by v. func (s *StatCounter) IncrementBy(v uint64) { atomic.AddUint64(&s.count, v) } func (s *StatCounter) String() string { return strconv.FormatUint(s.Value(), 10) } // ICMPv4PacketStats enumerates counts for all ICMPv4 packet types. type ICMPv4PacketStats struct { // Echo is the total number of ICMPv4 echo packets counted. Echo *StatCounter // EchoReply is the total number of ICMPv4 echo reply packets counted. EchoReply *StatCounter // DstUnreachable is the total number of ICMPv4 destination unreachable // packets counted. DstUnreachable *StatCounter // SrcQuench is the total number of ICMPv4 source quench packets // counted. SrcQuench *StatCounter // Redirect is the total number of ICMPv4 redirect packets counted. Redirect *StatCounter // TimeExceeded is the total number of ICMPv4 time exceeded packets // counted. TimeExceeded *StatCounter // ParamProblem is the total number of ICMPv4 parameter problem packets // counted. ParamProblem *StatCounter // Timestamp is the total number of ICMPv4 timestamp packets counted. Timestamp *StatCounter // TimestampReply is the total number of ICMPv4 timestamp reply packets // counted. TimestampReply *StatCounter // InfoRequest is the total number of ICMPv4 information request // packets counted. InfoRequest *StatCounter // InfoReply is the total number of ICMPv4 information reply packets // counted. InfoReply *StatCounter } // ICMPv6PacketStats enumerates counts for all ICMPv6 packet types. type ICMPv6PacketStats struct { // EchoRequest is the total number of ICMPv6 echo request packets // counted. EchoRequest *StatCounter // EchoReply is the total number of ICMPv6 echo reply packets counted. EchoReply *StatCounter // DstUnreachable is the total number of ICMPv6 destination unreachable // packets counted. DstUnreachable *StatCounter // PacketTooBig is the total number of ICMPv6 packet too big packets // counted. PacketTooBig *StatCounter // TimeExceeded is the total number of ICMPv6 time exceeded packets // counted. TimeExceeded *StatCounter // ParamProblem is the total number of ICMPv6 parameter problem packets // counted. ParamProblem *StatCounter // RouterSolicit is the total number of ICMPv6 router solicit packets // counted. RouterSolicit *StatCounter // RouterAdvert is the total number of ICMPv6 router advert packets // counted. RouterAdvert *StatCounter // NeighborSolicit is the total number of ICMPv6 neighbor solicit // packets counted. NeighborSolicit *StatCounter // NeighborAdvert is the total number of ICMPv6 neighbor advert packets // counted. NeighborAdvert *StatCounter // RedirectMsg is the total number of ICMPv6 redirect message packets // counted. RedirectMsg *StatCounter } // ICMPv4SentPacketStats collects outbound ICMPv4-specific stats. type ICMPv4SentPacketStats struct { ICMPv4PacketStats // Dropped is the total number of ICMPv4 packets dropped due to link // layer errors. Dropped *StatCounter // RateLimited is the total number of ICMPv6 packets dropped due to // rate limit being exceeded. RateLimited *StatCounter } // ICMPv4ReceivedPacketStats collects inbound ICMPv4-specific stats. type ICMPv4ReceivedPacketStats struct { ICMPv4PacketStats // Invalid is the total number of ICMPv4 packets received that the // transport layer could not parse. Invalid *StatCounter } // ICMPv6SentPacketStats collects outbound ICMPv6-specific stats. type ICMPv6SentPacketStats struct { ICMPv6PacketStats // Dropped is the total number of ICMPv6 packets dropped due to link // layer errors. Dropped *StatCounter // RateLimited is the total number of ICMPv6 packets dropped due to // rate limit being exceeded. RateLimited *StatCounter } // ICMPv6ReceivedPacketStats collects inbound ICMPv6-specific stats. type ICMPv6ReceivedPacketStats struct { ICMPv6PacketStats // Invalid is the total number of ICMPv6 packets received that the // transport layer could not parse. Invalid *StatCounter } // ICMPStats collects ICMP-specific stats (both v4 and v6). type ICMPStats struct { // ICMPv4SentPacketStats contains counts of sent packets by ICMPv4 packet type // and a single count of packets which failed to write to the link // layer. V4PacketsSent ICMPv4SentPacketStats // ICMPv4ReceivedPacketStats contains counts of received packets by ICMPv4 // packet type and a single count of invalid packets received. V4PacketsReceived ICMPv4ReceivedPacketStats // ICMPv6SentPacketStats contains counts of sent packets by ICMPv6 packet type // and a single count of packets which failed to write to the link // layer. V6PacketsSent ICMPv6SentPacketStats // ICMPv6ReceivedPacketStats contains counts of received packets by ICMPv6 // packet type and a single count of invalid packets received. V6PacketsReceived ICMPv6ReceivedPacketStats } // IPStats collects IP-specific stats (both v4 and v6). type IPStats struct { // PacketsReceived is the total number of IP packets received from the // link layer in nic.DeliverNetworkPacket. PacketsReceived *StatCounter // InvalidAddressesReceived is the total number of IP packets received // with an unknown or invalid destination address. InvalidAddressesReceived *StatCounter // PacketsDelivered is the total number of incoming IP packets that // are successfully delivered to the transport layer via HandlePacket. PacketsDelivered *StatCounter // PacketsSent is the total number of IP packets sent via WritePacket. PacketsSent *StatCounter // OutgoingPacketErrors is the total number of IP packets which failed // to write to a link-layer endpoint. OutgoingPacketErrors *StatCounter // MalformedPacketsReceived is the total number of IP Packets that were // dropped due to the IP packet header failing validation checks. MalformedPacketsReceived *StatCounter // MalformedFragmentsReceived is the total number of IP Fragments that were // dropped due to the fragment failing validation checks. MalformedFragmentsReceived *StatCounter } // TCPStats collects TCP-specific stats. type TCPStats struct { // ActiveConnectionOpenings is the number of connections opened // successfully via Connect. ActiveConnectionOpenings *StatCounter // PassiveConnectionOpenings is the number of connections opened // successfully via Listen. PassiveConnectionOpenings *StatCounter // CurrentEstablished is the number of TCP connections for which the // current state is either ESTABLISHED or CLOSE-WAIT. CurrentEstablished *StatCounter // EstablishedResets is the number of times TCP connections have made // a direct transition to the CLOSED state from either the // ESTABLISHED state or the CLOSE-WAIT state. EstablishedResets *StatCounter // EstablishedClosed is the number of times established TCP connections // made a transition to CLOSED state. EstablishedClosed *StatCounter // EstablishedTimedout is the number of times an established connection // was reset because of keep-alive time out. EstablishedTimedout *StatCounter // ListenOverflowSynDrop is the number of times the listen queue overflowed // and a SYN was dropped. ListenOverflowSynDrop *StatCounter // ListenOverflowAckDrop is the number of times the final ACK // in the handshake was dropped due to overflow. ListenOverflowAckDrop *StatCounter // ListenOverflowCookieSent is the number of times a SYN cookie was sent. ListenOverflowSynCookieSent *StatCounter // ListenOverflowSynCookieRcvd is the number of times a valid SYN // cookie was received. ListenOverflowSynCookieRcvd *StatCounter // ListenOverflowInvalidSynCookieRcvd is the number of times an invalid SYN cookie // was received. ListenOverflowInvalidSynCookieRcvd *StatCounter // FailedConnectionAttempts is the number of calls to Connect or Listen // (active and passive openings, respectively) that end in an error. FailedConnectionAttempts *StatCounter // ValidSegmentsReceived is the number of TCP segments received that // the transport layer successfully parsed. ValidSegmentsReceived *StatCounter // InvalidSegmentsReceived is the number of TCP segments received that // the transport layer could not parse. InvalidSegmentsReceived *StatCounter // SegmentsSent is the number of TCP segments sent. SegmentsSent *StatCounter // SegmentSendErrors is the number of TCP segments failed to be sent. SegmentSendErrors *StatCounter // ResetsSent is the number of TCP resets sent. ResetsSent *StatCounter // ResetsReceived is the number of TCP resets received. ResetsReceived *StatCounter // Retransmits is the number of TCP segments retransmitted. Retransmits *StatCounter // FastRecovery is the number of times Fast Recovery was used to // recover from packet loss. FastRecovery *StatCounter // SACKRecovery is the number of times SACK Recovery was used to // recover from packet loss. SACKRecovery *StatCounter // SlowStartRetransmits is the number of segments retransmitted in slow // start. SlowStartRetransmits *StatCounter // FastRetransmit is the number of segments retransmitted in fast // recovery. FastRetransmit *StatCounter // Timeouts is the number of times the RTO expired. Timeouts *StatCounter // ChecksumErrors is the number of segments dropped due to bad checksums. ChecksumErrors *StatCounter } // UDPStats collects UDP-specific stats. type UDPStats struct { // PacketsReceived is the number of UDP datagrams received via // HandlePacket. PacketsReceived *StatCounter // UnknownPortErrors is the number of incoming UDP datagrams dropped // because they did not have a known destination port. UnknownPortErrors *StatCounter // ReceiveBufferErrors is the number of incoming UDP datagrams dropped // due to the receiving buffer being in an invalid state. ReceiveBufferErrors *StatCounter // MalformedPacketsReceived is the number of incoming UDP datagrams // dropped due to the UDP header being in a malformed state. MalformedPacketsReceived *StatCounter // PacketsSent is the number of UDP datagrams sent via sendUDP. PacketsSent *StatCounter // PacketSendErrors is the number of datagrams failed to be sent. PacketSendErrors *StatCounter } // Stats holds statistics about the networking stack. // // All fields are optional. type Stats struct { // UnknownProtocolRcvdPackets is the number of packets received by the // stack that were for an unknown or unsupported protocol. UnknownProtocolRcvdPackets *StatCounter // MalformedRcvdPackets is the number of packets received by the stack // that were deemed malformed. MalformedRcvdPackets *StatCounter // DroppedPackets is the number of packets dropped due to full queues. DroppedPackets *StatCounter // ICMP breaks out ICMP-specific stats (both v4 and v6). ICMP ICMPStats // IP breaks out IP-specific stats (both v4 and v6). IP IPStats // TCP breaks out TCP-specific stats. TCP TCPStats // UDP breaks out UDP-specific stats. UDP UDPStats } // ReceiveErrors collects packet receive errors within transport endpoint. type ReceiveErrors struct { // ReceiveBufferOverflow is the number of received packets dropped // due to the receive buffer being full. ReceiveBufferOverflow StatCounter // MalformedPacketsReceived is the number of incoming packets // dropped due to the packet header being in a malformed state. MalformedPacketsReceived StatCounter // ClosedReceiver is the number of received packets dropped because // of receiving endpoint state being closed. ClosedReceiver StatCounter } // SendErrors collects packet send errors within the transport layer for // an endpoint. type SendErrors struct { // SendToNetworkFailed is the number of packets failed to be written to // the network endpoint. SendToNetworkFailed StatCounter // NoRoute is the number of times we failed to resolve IP route. NoRoute StatCounter // NoLinkAddr is the number of times we failed to resolve ARP. NoLinkAddr StatCounter } // ReadErrors collects segment read errors from an endpoint read call. type ReadErrors struct { // ReadClosed is the number of received packet drops because the endpoint // was shutdown for read. ReadClosed StatCounter // InvalidEndpointState is the number of times we found the endpoint state // to be unexpected. InvalidEndpointState StatCounter } // WriteErrors collects packet write errors from an endpoint write call. type WriteErrors struct { // WriteClosed is the number of packet drops because the endpoint // was shutdown for write. WriteClosed StatCounter // InvalidEndpointState is the number of times we found the endpoint state // to be unexpected. InvalidEndpointState StatCounter // InvalidArgs is the number of times invalid input arguments were // provided for endpoint Write call. InvalidArgs StatCounter } // TransportEndpointStats collects statistics about the endpoint. type TransportEndpointStats struct { // PacketsReceived is the number of successful packet receives. PacketsReceived StatCounter // PacketsSent is the number of successful packet sends. PacketsSent StatCounter // ReceiveErrors collects packet receive errors within transport layer. ReceiveErrors ReceiveErrors // ReadErrors collects packet read errors from an endpoint read call. ReadErrors ReadErrors // SendErrors collects packet send errors within the transport layer. SendErrors SendErrors // WriteErrors collects packet write errors from an endpoint write call. WriteErrors WriteErrors } // IsEndpointStats is an empty method to implement the tcpip.EndpointStats // marker interface. func (*TransportEndpointStats) IsEndpointStats() {} func fillIn(v reflect.Value) { for i := 0; i < v.NumField(); i++ { v := v.Field(i) if s, ok := v.Addr().Interface().(**StatCounter); ok { if *s == nil { *s = new(StatCounter) } } else { fillIn(v) } } } // FillIn returns a copy of s with nil fields initialized to new StatCounters. func (s Stats) FillIn() Stats { fillIn(reflect.ValueOf(&s).Elem()) return s } // Clone returns a copy of the TransportEndpointStats by atomically reading // each field. func (src *TransportEndpointStats) Clone() TransportEndpointStats { var dst TransportEndpointStats clone(reflect.ValueOf(&dst).Elem(), reflect.ValueOf(src).Elem()) return dst } func clone(dst reflect.Value, src reflect.Value) { for i := 0; i < dst.NumField(); i++ { d := dst.Field(i) s := src.Field(i) if c, ok := s.Addr().Interface().(*StatCounter); ok { d.Addr().Interface().(*StatCounter).IncrementBy(c.Value()) } else { clone(d, s) } } } // String implements the fmt.Stringer interface. func (a Address) String() string { switch len(a) { case 4: return fmt.Sprintf("%d.%d.%d.%d", int(a[0]), int(a[1]), int(a[2]), int(a[3])) case 16: // Find the longest subsequence of hexadecimal zeros. start, end := -1, -1 for i := 0; i < len(a); i += 2 { j := i for j < len(a) && a[j] == 0 && a[j+1] == 0 { j += 2 } if j > i+2 && j-i > end-start { start, end = i, j } } var b strings.Builder for i := 0; i < len(a); i += 2 { if i == start { b.WriteString("::") i = end if end >= len(a) { break } } else if i > 0 { b.WriteByte(':') } v := uint16(a[i+0])<<8 | uint16(a[i+1]) if v == 0 { b.WriteByte('0') } else { const digits = "0123456789abcdef" for i := uint(3); i < 4; i-- { if v := v >> (i * 4); v != 0 { b.WriteByte(digits[v&0xf]) } } } } return b.String() default: return fmt.Sprintf("%x", []byte(a)) } } // To4 converts the IPv4 address to a 4-byte representation. // If the address is not an IPv4 address, To4 returns "". func (a Address) To4() Address { const ( ipv4len = 4 ipv6len = 16 ) if len(a) == ipv4len { return a } if len(a) == ipv6len && isZeros(a[0:10]) && a[10] == 0xff && a[11] == 0xff { return a[12:16] } return "" } // isZeros reports whether a is all zeros. func isZeros(a Address) bool { for i := 0; i < len(a); i++ { if a[i] != 0 { return false } } return true } // LinkAddress is a byte slice cast as a string that represents a link address. // It is typically a 6-byte MAC address. type LinkAddress string // String implements the fmt.Stringer interface. func (a LinkAddress) String() string { switch len(a) { case 6: return fmt.Sprintf("%02x:%02x:%02x:%02x:%02x:%02x", a[0], a[1], a[2], a[3], a[4], a[5]) default: return fmt.Sprintf("%x", []byte(a)) } } // ParseMACAddress parses an IEEE 802 address. // // It must be in the format aa:bb:cc:dd:ee:ff or aa-bb-cc-dd-ee-ff. func ParseMACAddress(s string) (LinkAddress, error) { parts := strings.FieldsFunc(s, func(c rune) bool { return c == ':' || c == '-' }) if len(parts) != 6 { return "", fmt.Errorf("inconsistent parts: %s", s) } addr := make([]byte, 0, len(parts)) for _, part := range parts { u, err := strconv.ParseUint(part, 16, 8) if err != nil { return "", fmt.Errorf("invalid hex digits: %s", s) } addr = append(addr, byte(u)) } return LinkAddress(addr), nil } // AddressWithPrefix is an address with its subnet prefix length. type AddressWithPrefix struct { // Address is a network address. Address Address // PrefixLen is the subnet prefix length. PrefixLen int } // String implements the fmt.Stringer interface. func (a AddressWithPrefix) String() string { return fmt.Sprintf("%s/%d", a.Address, a.PrefixLen) } // Subnet converts the address and prefix into a Subnet value and returns it. func (a AddressWithPrefix) Subnet() Subnet { addrLen := len(a.Address) if a.PrefixLen <= 0 { return Subnet{ address: Address(strings.Repeat("\x00", addrLen)), mask: AddressMask(strings.Repeat("\x00", addrLen)), } } if a.PrefixLen >= addrLen*8 { return Subnet{ address: a.Address, mask: AddressMask(strings.Repeat("\xff", addrLen)), } } sa := make([]byte, addrLen) sm := make([]byte, addrLen) n := uint(a.PrefixLen) for i := 0; i < addrLen; i++ { if n >= 8 { sa[i] = a.Address[i] sm[i] = 0xff n -= 8 continue } sm[i] = ^byte(0xff >> n) sa[i] = a.Address[i] & sm[i] n = 0 } // For extra caution, call NewSubnet rather than directly creating the Subnet // value. If that fails it indicates a serious bug in this code, so panic is // in order. s, err := NewSubnet(Address(sa), AddressMask(sm)) if err != nil { panic("invalid subnet: " + err.Error()) } return s } // ProtocolAddress is an address and the network protocol it is associated // with. type ProtocolAddress struct { // Protocol is the protocol of the address. Protocol NetworkProtocolNumber // AddressWithPrefix is a network address with its subnet prefix length. AddressWithPrefix AddressWithPrefix } var ( // danglingEndpointsMu protects access to danglingEndpoints. danglingEndpointsMu sync.Mutex // danglingEndpoints tracks all dangling endpoints no longer owned by the app. danglingEndpoints = make(map[Endpoint]struct{}) ) // GetDanglingEndpoints returns all dangling endpoints. func GetDanglingEndpoints() []Endpoint { danglingEndpointsMu.Lock() es := make([]Endpoint, 0, len(danglingEndpoints)) for e := range danglingEndpoints { es = append(es, e) } danglingEndpointsMu.Unlock() return es } // AddDanglingEndpoint adds a dangling endpoint. func AddDanglingEndpoint(e Endpoint) { danglingEndpointsMu.Lock() danglingEndpoints[e] = struct{}{} danglingEndpointsMu.Unlock() } // DeleteDanglingEndpoint removes a dangling endpoint. func DeleteDanglingEndpoint(e Endpoint) { danglingEndpointsMu.Lock() delete(danglingEndpoints, e) danglingEndpointsMu.Unlock() } // AsyncLoading is the global barrier for asynchronous endpoint loading // activities. var AsyncLoading sync.WaitGroup