// Copyright 2018 Google Inc. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // Package unix contains the implementation of Unix endpoints. package unix import ( "sync" "sync/atomic" "gvisor.googlesource.com/gvisor/pkg/ilist" "gvisor.googlesource.com/gvisor/pkg/tcpip" "gvisor.googlesource.com/gvisor/pkg/tcpip/buffer" "gvisor.googlesource.com/gvisor/pkg/tcpip/transport/queue" "gvisor.googlesource.com/gvisor/pkg/waiter" ) // initialLimit is the starting limit for the socket buffers. const initialLimit = 16 * 1024 // A SockType is a type (as opposed to family) of sockets. These are enumerated // in the syscall package as syscall.SOCK_* constants. type SockType int const ( // SockStream corresponds to syscall.SOCK_STREAM. SockStream SockType = 1 // SockDgram corresponds to syscall.SOCK_DGRAM. SockDgram SockType = 2 // SockRaw corresponds to syscall.SOCK_RAW. SockRaw SockType = 3 // SockSeqpacket corresponds to syscall.SOCK_SEQPACKET. SockSeqpacket SockType = 5 ) // A RightsControlMessage is a control message containing FDs. type RightsControlMessage interface { // Clone returns a copy of the RightsControlMessage. Clone() RightsControlMessage // Release releases any resources owned by the RightsControlMessage. Release() } // A CredentialsControlMessage is a control message containing Unix credentials. type CredentialsControlMessage interface { // Equals returns true iff the two messages are equal. Equals(CredentialsControlMessage) bool } // A ControlMessages represents a collection of socket control messages. type ControlMessages struct { // Rights is a control message containing FDs. Rights RightsControlMessage // Credentials is a control message containing Unix credentials. Credentials CredentialsControlMessage } // Empty returns true iff the ControlMessages does not contain either // credentials or rights. func (c *ControlMessages) Empty() bool { return c.Rights == nil && c.Credentials == nil } // Clone clones both the credentials and the rights. func (c *ControlMessages) Clone() ControlMessages { cm := ControlMessages{} if c.Rights != nil { cm.Rights = c.Rights.Clone() } cm.Credentials = c.Credentials return cm } // Release releases both the credentials and the rights. func (c *ControlMessages) Release() { if c.Rights != nil { c.Rights.Release() } *c = ControlMessages{} } // Endpoint is the interface implemented by Unix transport protocol // implementations that expose functionality like sendmsg, recvmsg, connect, // etc. to Unix socket implementations. type Endpoint interface { Credentialer waiter.Waitable // Close puts the endpoint in a closed state and frees all resources // associated with it. Close() // RecvMsg reads data and a control message from the endpoint. This method // does not block if there is no data pending. // // creds indicates if credential control messages are requested by the // caller. This is useful for determining if control messages can be // coalesced. creds is a hint and can be safely ignored by the // implementation if no coalescing is possible. It is fine to return // credential control messages when none were requested or to not return // credential control messages when they were requested. // // numRights is the number of SCM_RIGHTS FDs requested by the caller. This // is useful if one must allocate a buffer to receive a SCM_RIGHTS message // or determine if control messages can be coalesced. numRights is a hint // and can be safely ignored by the implementation if the number of // available SCM_RIGHTS FDs is known and no coalescing is possible. It is // fine for the returned number of SCM_RIGHTS FDs to be either higher or // lower than the requested number. // // If peek is true, no data should be consumed from the Endpoint. Any and // all data returned from a peek should be available in the next call to // RecvMsg. // // recvLen is the number of bytes copied into data. // // msgLen is the length of the read message consumed for datagram Endpoints. // msgLen is always the same as recvLen for stream Endpoints. RecvMsg(data [][]byte, creds bool, numRights uintptr, peek bool, addr *tcpip.FullAddress) (recvLen, msgLen uintptr, cm ControlMessages, err *tcpip.Error) // SendMsg writes data and a control message to the endpoint's peer. // This method does not block if the data cannot be written. // // SendMsg does not take ownership of any of its arguments on error. SendMsg([][]byte, ControlMessages, BoundEndpoint) (uintptr, *tcpip.Error) // Connect connects this endpoint directly to another. // // This should be called on the client endpoint, and the (bound) // endpoint passed in as a parameter. // // The error codes are the same as Connect. Connect(server BoundEndpoint) *tcpip.Error // Shutdown closes the read and/or write end of the endpoint connection // to its peer. Shutdown(flags tcpip.ShutdownFlags) *tcpip.Error // Listen puts the endpoint in "listen" mode, which allows it to accept // new connections. Listen(backlog int) *tcpip.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, *tcpip.Error) // Bind binds the endpoint to a specific local address and port. // Specifying a NIC is optional. // // An optional commit function will be executed atomically with respect // to binding the endpoint. If this returns an error, the bind will not // occur and the error will be propagated back to the caller. Bind(address tcpip.FullAddress, commit func() *tcpip.Error) *tcpip.Error // Type return the socket type, typically either SockStream, SockDgram // or SockSeqpacket. Type() SockType // GetLocalAddress returns the address to which the endpoint is bound. GetLocalAddress() (tcpip.FullAddress, *tcpip.Error) // GetRemoteAddress returns the address to which the endpoint is // connected. GetRemoteAddress() (tcpip.FullAddress, *tcpip.Error) // SetSockOpt sets a socket option. opt should be one of the tcpip.*Option // types. SetSockOpt(opt interface{}) *tcpip.Error // GetSockOpt gets a socket option. opt should be a pointer to one of the // tcpip.*Option types. GetSockOpt(opt interface{}) *tcpip.Error } // A Credentialer is a socket or endpoint that supports the SO_PASSCRED socket // option. type Credentialer interface { // Passcred returns whether or not the SO_PASSCRED socket option is // enabled on this end. Passcred() bool // ConnectedPasscred returns whether or not the SO_PASSCRED socket option // is enabled on the connected end. ConnectedPasscred() bool } // A BoundEndpoint is a unix endpoint that can be connected to. type BoundEndpoint interface { // BidirectionalConnect establishes a bi-directional connection between two // unix endpoints in an all-or-nothing manner. If an error occurs during // connecting, the state of neither endpoint should be modified. // // In order for an endpoint to establish such a bidirectional connection // with a BoundEndpoint, the endpoint calls the BidirectionalConnect method // on the BoundEndpoint and sends a representation of itself (the // ConnectingEndpoint) and a callback (returnConnect) to receive the // connection information (Receiver and ConnectedEndpoint) upon a // successful connect. The callback should only be called on a successful // connect. // // For a connection attempt to be successful, the ConnectingEndpoint must // be unconnected and not listening and the BoundEndpoint whose // BidirectionalConnect method is being called must be listening. // // This method will return tcpip.ErrConnectionRefused on endpoints with a // type that isn't SockStream or SockSeqpacket. BidirectionalConnect(ep ConnectingEndpoint, returnConnect func(Receiver, ConnectedEndpoint)) *tcpip.Error // UnidirectionalConnect establishes a write-only connection to a unix endpoint. // // This method will return tcpip.ErrConnectionRefused on a non-SockDgram // endpoint. UnidirectionalConnect() (ConnectedEndpoint, *tcpip.Error) // Release releases any resources held by the BoundEndpoint. It must be // called before dropping all references to a BoundEndpoint returned by a // function. Release() } // message represents a message passed over a Unix domain socket. type message struct { ilist.Entry // Data is the Message payload. Data buffer.View // Control is auxiliary control message data that goes along with the // data. Control ControlMessages // Address is the bound address of the endpoint that sent the message. // // If the endpoint that sent the message is not bound, the Address is // the empty string. Address tcpip.FullAddress } // Length returns number of bytes stored in the Message. func (m *message) Length() int64 { return int64(len(m.Data)) } // Release releases any resources held by the Message. func (m *message) Release() { m.Control.Release() } func (m *message) Peek() queue.Entry { return &message{Data: m.Data, Control: m.Control.Clone(), Address: m.Address} } // A Receiver can be used to receive Messages. type Receiver interface { // Recv receives a single message. This method does not block. // // See Endpoint.RecvMsg for documentation on shared arguments. // // notify indicates if RecvNotify should be called. Recv(data [][]byte, creds bool, numRights uintptr, peek bool) (recvLen, msgLen uintptr, cm ControlMessages, source tcpip.FullAddress, notify bool, err *tcpip.Error) // RecvNotify notifies the Receiver of a successful Recv. This must not be // called while holding any endpoint locks. RecvNotify() // CloseRecv prevents the receiving of additional Messages. // // After CloseRecv is called, CloseNotify must also be called. CloseRecv() // CloseNotify notifies the Receiver of recv being closed. This must not be // called while holding any endpoint locks. CloseNotify() // Readable returns if messages should be attempted to be received. This // includes when read has been shutdown. Readable() bool // RecvQueuedSize returns the total amount of data currently receivable. // RecvQueuedSize should return -1 if the operation isn't supported. RecvQueuedSize() int64 // RecvMaxQueueSize returns maximum value for RecvQueuedSize. // RecvMaxQueueSize should return -1 if the operation isn't supported. RecvMaxQueueSize() int64 // Release releases any resources owned by the Receiver. It should be // called before droping all references to a Receiver. Release() } // queueReceiver implements Receiver for datagram sockets. type queueReceiver struct { readQueue *queue.Queue } // Recv implements Receiver.Recv. func (q *queueReceiver) Recv(data [][]byte, creds bool, numRights uintptr, peek bool) (uintptr, uintptr, ControlMessages, tcpip.FullAddress, bool, *tcpip.Error) { var m queue.Entry var notify bool var err *tcpip.Error if peek { m, err = q.readQueue.Peek() } else { m, notify, err = q.readQueue.Dequeue() } if err != nil { return 0, 0, ControlMessages{}, tcpip.FullAddress{}, false, err } msg := m.(*message) src := []byte(msg.Data) var copied uintptr for i := 0; i < len(data) && len(src) > 0; i++ { n := copy(data[i], src) copied += uintptr(n) src = src[n:] } return copied, uintptr(len(msg.Data)), msg.Control, msg.Address, notify, nil } // RecvNotify implements Receiver.RecvNotify. func (q *queueReceiver) RecvNotify() { q.readQueue.WriterQueue.Notify(waiter.EventOut) } // CloseNotify implements Receiver.CloseNotify. func (q *queueReceiver) CloseNotify() { q.readQueue.ReaderQueue.Notify(waiter.EventIn) q.readQueue.WriterQueue.Notify(waiter.EventOut) } // CloseRecv implements Receiver.CloseRecv. func (q *queueReceiver) CloseRecv() { q.readQueue.Close() } // Readable implements Receiver.Readable. func (q *queueReceiver) Readable() bool { return q.readQueue.IsReadable() } // RecvQueuedSize implements Receiver.RecvQueuedSize. func (q *queueReceiver) RecvQueuedSize() int64 { return q.readQueue.QueuedSize() } // RecvMaxQueueSize implements Receiver.RecvMaxQueueSize. func (q *queueReceiver) RecvMaxQueueSize() int64 { return q.readQueue.MaxQueueSize() } // Release implements Receiver.Release. func (*queueReceiver) Release() {} // streamQueueReceiver implements Receiver for stream sockets. type streamQueueReceiver struct { queueReceiver mu sync.Mutex `state:"nosave"` buffer []byte control ControlMessages addr tcpip.FullAddress } func vecCopy(data [][]byte, buf []byte) (uintptr, [][]byte, []byte) { var copied uintptr for len(data) > 0 && len(buf) > 0 { n := copy(data[0], buf) copied += uintptr(n) buf = buf[n:] data[0] = data[0][n:] if len(data[0]) == 0 { data = data[1:] } } return copied, data, buf } // Readable implements Receiver.Readable. func (q *streamQueueReceiver) Readable() bool { q.mu.Lock() bl := len(q.buffer) r := q.readQueue.IsReadable() q.mu.Unlock() // We're readable if we have data in our buffer or if the queue receiver is // readable. return bl > 0 || r } // RecvQueuedSize implements Receiver.RecvQueuedSize. func (q *streamQueueReceiver) RecvQueuedSize() int64 { q.mu.Lock() bl := len(q.buffer) qs := q.readQueue.QueuedSize() q.mu.Unlock() return int64(bl) + qs } // RecvMaxQueueSize implements Receiver.RecvMaxQueueSize. func (q *streamQueueReceiver) RecvMaxQueueSize() int64 { // The RecvMaxQueueSize() is the readQueue's MaxQueueSize() plus the largest // message we can buffer which is also the largest message we can receive. return 2 * q.readQueue.MaxQueueSize() } // Recv implements Receiver.Recv. func (q *streamQueueReceiver) Recv(data [][]byte, wantCreds bool, numRights uintptr, peek bool) (uintptr, uintptr, ControlMessages, tcpip.FullAddress, bool, *tcpip.Error) { q.mu.Lock() defer q.mu.Unlock() var notify bool // If we have no data in the endpoint, we need to get some. if len(q.buffer) == 0 { // Load the next message into a buffer, even if we are peeking. Peeking // won't consume the message, so it will be still available to be read // the next time Recv() is called. m, n, err := q.readQueue.Dequeue() if err != nil { return 0, 0, ControlMessages{}, tcpip.FullAddress{}, false, err } notify = n msg := m.(*message) q.buffer = []byte(msg.Data) q.control = msg.Control q.addr = msg.Address } var copied uintptr if peek { // Don't consume control message if we are peeking. c := q.control.Clone() // Don't consume data since we are peeking. copied, data, _ = vecCopy(data, q.buffer) return copied, copied, c, q.addr, notify, nil } // Consume data and control message since we are not peeking. copied, data, q.buffer = vecCopy(data, q.buffer) // Save the original state of q.control. c := q.control // Remove rights from q.control and leave behind just the creds. q.control.Rights = nil if !wantCreds { c.Credentials = nil } if c.Rights != nil && numRights == 0 { c.Rights.Release() c.Rights = nil } haveRights := c.Rights != nil // If we have more capacity for data and haven't received any usable // rights. // // Linux never coalesces rights control messages. for !haveRights && len(data) > 0 { // Get a message from the readQueue. m, n, err := q.readQueue.Dequeue() if err != nil { // We already got some data, so ignore this error. This will // manifest as a short read to the user, which is what Linux // does. break } notify = notify || n msg := m.(*message) q.buffer = []byte(msg.Data) q.control = msg.Control q.addr = msg.Address if wantCreds { if (q.control.Credentials == nil) != (c.Credentials == nil) { // One message has credentials, the other does not. break } if q.control.Credentials != nil && c.Credentials != nil && !q.control.Credentials.Equals(c.Credentials) { // Both messages have credentials, but they don't match. break } } if numRights != 0 && c.Rights != nil && q.control.Rights != nil { // Both messages have rights. break } var cpd uintptr cpd, data, q.buffer = vecCopy(data, q.buffer) copied += cpd if cpd == 0 { // data was actually full. break } if q.control.Rights != nil { // Consume rights. if numRights == 0 { q.control.Rights.Release() } else { c.Rights = q.control.Rights haveRights = true } q.control.Rights = nil } } return copied, copied, c, q.addr, notify, nil } // A ConnectedEndpoint is an Endpoint that can be used to send Messages. type ConnectedEndpoint interface { // Passcred implements Endpoint.Passcred. Passcred() bool // GetLocalAddress implements Endpoint.GetLocalAddress. GetLocalAddress() (tcpip.FullAddress, *tcpip.Error) // Send sends a single message. This method does not block. // // notify indicates if SendNotify should be called. Send(data [][]byte, controlMessages ControlMessages, from tcpip.FullAddress) (n uintptr, notify bool, err *tcpip.Error) // SendNotify notifies the ConnectedEndpoint of a successful Send. This // must not be called while holding any endpoint locks. SendNotify() // CloseSend prevents the sending of additional Messages. // // After CloseSend is call, CloseNotify must also be called. CloseSend() // CloseNotify notifies the ConnectedEndpoint of send being closed. This // must not be called while holding any endpoint locks. CloseNotify() // Writable returns if messages should be attempted to be sent. This // includes when write has been shutdown. Writable() bool // EventUpdate lets the ConnectedEndpoint know that event registrations // have changed. EventUpdate() // SendQueuedSize returns the total amount of data currently queued for // sending. SendQueuedSize should return -1 if the operation isn't // supported. SendQueuedSize() int64 // SendMaxQueueSize returns maximum value for SendQueuedSize. // SendMaxQueueSize should return -1 if the operation isn't supported. SendMaxQueueSize() int64 // Release releases any resources owned by the ConnectedEndpoint. It should // be called before droping all references to a ConnectedEndpoint. Release() } type connectedEndpoint struct { // endpoint represents the subset of the Endpoint functionality needed by // the connectedEndpoint. It is implemented by both connectionedEndpoint // and connectionlessEndpoint and allows the use of types which don't // fully implement Endpoint. endpoint interface { // Passcred implements Endpoint.Passcred. Passcred() bool // GetLocalAddress implements Endpoint.GetLocalAddress. GetLocalAddress() (tcpip.FullAddress, *tcpip.Error) // Type implements Endpoint.Type. Type() SockType } writeQueue *queue.Queue } // Passcred implements ConnectedEndpoint.Passcred. func (e *connectedEndpoint) Passcred() bool { return e.endpoint.Passcred() } // GetLocalAddress implements ConnectedEndpoint.GetLocalAddress. func (e *connectedEndpoint) GetLocalAddress() (tcpip.FullAddress, *tcpip.Error) { return e.endpoint.GetLocalAddress() } // Send implements ConnectedEndpoint.Send. func (e *connectedEndpoint) Send(data [][]byte, controlMessages ControlMessages, from tcpip.FullAddress) (uintptr, bool, *tcpip.Error) { var l int for _, d := range data { l += len(d) } // Discard empty stream packets. Since stream sockets don't preserve // message boundaries, sending zero bytes is a no-op. In Linux, the // receiver actually uses a zero-length receive as an indication that the // stream was closed. if l == 0 && e.endpoint.Type() == SockStream { controlMessages.Release() return 0, false, nil } v := make([]byte, 0, l) for _, d := range data { v = append(v, d...) } notify, err := e.writeQueue.Enqueue(&message{Data: buffer.View(v), Control: controlMessages, Address: from}) return uintptr(l), notify, err } // SendNotify implements ConnectedEndpoint.SendNotify. func (e *connectedEndpoint) SendNotify() { e.writeQueue.ReaderQueue.Notify(waiter.EventIn) } // CloseNotify implements ConnectedEndpoint.CloseNotify. func (e *connectedEndpoint) CloseNotify() { e.writeQueue.ReaderQueue.Notify(waiter.EventIn) e.writeQueue.WriterQueue.Notify(waiter.EventOut) } // CloseSend implements ConnectedEndpoint.CloseSend. func (e *connectedEndpoint) CloseSend() { e.writeQueue.Close() } // Writable implements ConnectedEndpoint.Writable. func (e *connectedEndpoint) Writable() bool { return e.writeQueue.IsWritable() } // EventUpdate implements ConnectedEndpoint.EventUpdate. func (*connectedEndpoint) EventUpdate() {} // SendQueuedSize implements ConnectedEndpoint.SendQueuedSize. func (e *connectedEndpoint) SendQueuedSize() int64 { return e.writeQueue.QueuedSize() } // SendMaxQueueSize implements ConnectedEndpoint.SendMaxQueueSize. func (e *connectedEndpoint) SendMaxQueueSize() int64 { return e.writeQueue.MaxQueueSize() } // Release implements ConnectedEndpoint.Release. func (*connectedEndpoint) Release() {} // baseEndpoint is an embeddable unix endpoint base used in both the connected and connectionless // unix domain socket Endpoint implementations. // // Not to be used on its own. type baseEndpoint struct { *waiter.Queue // passcred specifies whether SCM_CREDENTIALS socket control messages are // enabled on this endpoint. Must be accessed atomically. passcred int32 // Mutex protects the below fields. sync.Mutex `state:"nosave"` // receiver allows Messages to be received. receiver Receiver // connected allows messages to be sent and state information about the // connected endpoint to be read. connected ConnectedEndpoint // path is not empty if the endpoint has been bound, // or may be used if the endpoint is connected. path string } // EventRegister implements waiter.Waitable.EventRegister. func (e *baseEndpoint) EventRegister(we *waiter.Entry, mask waiter.EventMask) { e.Queue.EventRegister(we, mask) e.Lock() if e.connected != nil { e.connected.EventUpdate() } e.Unlock() } // EventUnregister implements waiter.Waitable.EventUnregister. func (e *baseEndpoint) EventUnregister(we *waiter.Entry) { e.Queue.EventUnregister(we) e.Lock() if e.connected != nil { e.connected.EventUpdate() } e.Unlock() } // Passcred implements Credentialer.Passcred. func (e *baseEndpoint) Passcred() bool { return atomic.LoadInt32(&e.passcred) != 0 } // ConnectedPasscred implements Credentialer.ConnectedPasscred. func (e *baseEndpoint) ConnectedPasscred() bool { e.Lock() defer e.Unlock() return e.connected != nil && e.connected.Passcred() } func (e *baseEndpoint) setPasscred(pc bool) { if pc { atomic.StoreInt32(&e.passcred, 1) } else { atomic.StoreInt32(&e.passcred, 0) } } // Connected implements ConnectingEndpoint.Connected. func (e *baseEndpoint) Connected() bool { return e.receiver != nil && e.connected != nil } // RecvMsg reads data and a control message from the endpoint. func (e *baseEndpoint) RecvMsg(data [][]byte, creds bool, numRights uintptr, peek bool, addr *tcpip.FullAddress) (uintptr, uintptr, ControlMessages, *tcpip.Error) { e.Lock() if e.receiver == nil { e.Unlock() return 0, 0, ControlMessages{}, tcpip.ErrNotConnected } recvLen, msgLen, cms, a, notify, err := e.receiver.Recv(data, creds, numRights, peek) e.Unlock() if err != nil { return 0, 0, ControlMessages{}, err } if notify { e.receiver.RecvNotify() } if addr != nil { *addr = a } return recvLen, msgLen, cms, nil } // SendMsg writes data and a control message to the endpoint's peer. // This method does not block if the data cannot be written. func (e *baseEndpoint) SendMsg(data [][]byte, c ControlMessages, to BoundEndpoint) (uintptr, *tcpip.Error) { e.Lock() if !e.Connected() { e.Unlock() return 0, tcpip.ErrNotConnected } if to != nil { e.Unlock() return 0, tcpip.ErrAlreadyConnected } n, notify, err := e.connected.Send(data, c, tcpip.FullAddress{Addr: tcpip.Address(e.path)}) e.Unlock() if err != nil { return 0, err } if notify { e.connected.SendNotify() } return n, nil } // SetSockOpt sets a socket option. Currently not supported. func (e *baseEndpoint) SetSockOpt(opt interface{}) *tcpip.Error { switch v := opt.(type) { case tcpip.PasscredOption: e.setPasscred(v != 0) return nil } return nil } // GetSockOpt implements tcpip.Endpoint.GetSockOpt. func (e *baseEndpoint) GetSockOpt(opt interface{}) *tcpip.Error { switch o := opt.(type) { case tcpip.ErrorOption: return nil case *tcpip.SendQueueSizeOption: e.Lock() if !e.Connected() { e.Unlock() return tcpip.ErrNotConnected } qs := tcpip.SendQueueSizeOption(e.connected.SendQueuedSize()) e.Unlock() if qs < 0 { return tcpip.ErrQueueSizeNotSupported } *o = qs return nil case *tcpip.ReceiveQueueSizeOption: e.Lock() if !e.Connected() { e.Unlock() return tcpip.ErrNotConnected } qs := tcpip.ReceiveQueueSizeOption(e.receiver.RecvQueuedSize()) e.Unlock() if qs < 0 { return tcpip.ErrQueueSizeNotSupported } *o = qs return nil case *tcpip.PasscredOption: if e.Passcred() { *o = tcpip.PasscredOption(1) } else { *o = tcpip.PasscredOption(0) } return nil case *tcpip.SendBufferSizeOption: e.Lock() if !e.Connected() { e.Unlock() return tcpip.ErrNotConnected } qs := tcpip.SendBufferSizeOption(e.connected.SendMaxQueueSize()) e.Unlock() if qs < 0 { return tcpip.ErrQueueSizeNotSupported } *o = qs return nil case *tcpip.ReceiveBufferSizeOption: e.Lock() if e.receiver == nil { e.Unlock() return tcpip.ErrNotConnected } qs := tcpip.ReceiveBufferSizeOption(e.receiver.RecvMaxQueueSize()) e.Unlock() if qs < 0 { return tcpip.ErrQueueSizeNotSupported } *o = qs return nil } return tcpip.ErrUnknownProtocolOption } // Shutdown closes the read and/or write end of the endpoint connection to its // peer. func (e *baseEndpoint) Shutdown(flags tcpip.ShutdownFlags) *tcpip.Error { e.Lock() if !e.Connected() { e.Unlock() return tcpip.ErrNotConnected } if flags&tcpip.ShutdownRead != 0 { e.receiver.CloseRecv() } if flags&tcpip.ShutdownWrite != 0 { e.connected.CloseSend() } e.Unlock() if flags&tcpip.ShutdownRead != 0 { e.receiver.CloseNotify() } if flags&tcpip.ShutdownWrite != 0 { e.connected.CloseNotify() } return nil } // GetLocalAddress returns the bound path. func (e *baseEndpoint) GetLocalAddress() (tcpip.FullAddress, *tcpip.Error) { e.Lock() defer e.Unlock() return tcpip.FullAddress{Addr: tcpip.Address(e.path)}, nil } // GetRemoteAddress returns the local address of the connected endpoint (if // available). func (e *baseEndpoint) GetRemoteAddress() (tcpip.FullAddress, *tcpip.Error) { e.Lock() c := e.connected e.Unlock() if c != nil { return c.GetLocalAddress() } return tcpip.FullAddress{}, tcpip.ErrNotConnected } // Release implements BoundEndpoint.Release. func (*baseEndpoint) Release() {}