// Copyright 2016 The Netstack Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package tcp import ( "crypto/rand" "crypto/sha1" "encoding/binary" "hash" "io" "sync" "time" "gvisor.googlesource.com/gvisor/pkg/sleep" "gvisor.googlesource.com/gvisor/pkg/tcpip" "gvisor.googlesource.com/gvisor/pkg/tcpip/header" "gvisor.googlesource.com/gvisor/pkg/tcpip/seqnum" "gvisor.googlesource.com/gvisor/pkg/tcpip/stack" "gvisor.googlesource.com/gvisor/pkg/waiter" ) const ( // tsLen is the length, in bits, of the timestamp in the SYN cookie. tsLen = 8 // tsMask is a mask for timestamp values (i.e., tsLen bits). tsMask = (1 << tsLen) - 1 // tsOffset is the offset, in bits, of the timestamp in the SYN cookie. tsOffset = 24 // hashMask is the mask for hash values (i.e., tsOffset bits). hashMask = (1 << tsOffset) - 1 // maxTSDiff is the maximum allowed difference between a received cookie // timestamp and the current timestamp. If the difference is greater // than maxTSDiff, the cookie is expired. maxTSDiff = 2 ) var ( // SynRcvdCountThreshold is the global maximum number of connections // that are allowed to be in SYN-RCVD state before TCP starts using SYN // cookies to accept connections. // // It is an exported variable only for testing, and should not otherwise // be used by importers of this package. SynRcvdCountThreshold uint64 = 1000 // mssTable is a slice containing the possible MSS values that we // encode in the SYN cookie with two bits. mssTable = []uint16{536, 1300, 1440, 1460} ) func encodeMSS(mss uint16) uint32 { for i := len(mssTable) - 1; i > 0; i-- { if mss >= mssTable[i] { return uint32(i) } } return 0 } // syncRcvdCount is the number of endpoints in the SYN-RCVD state. The value is // protected by a mutex so that we can increment only when it's guaranteed not // to go above a threshold. var synRcvdCount struct { sync.Mutex value uint64 } // listenContext is used by a listening endpoint to store state used while // listening for connections. This struct is allocated by the listen goroutine // and must not be accessed or have its methods called concurrently as they // may mutate the stored objects. type listenContext struct { stack *stack.Stack rcvWnd seqnum.Size nonce [2][sha1.BlockSize]byte hasherMu sync.Mutex hasher hash.Hash v6only bool netProto tcpip.NetworkProtocolNumber } // timeStamp returns an 8-bit timestamp with a granularity of 64 seconds. func timeStamp() uint32 { return uint32(time.Now().Unix()>>6) & tsMask } // incSynRcvdCount tries to increment the global number of endpoints in SYN-RCVD // state. It succeeds if the increment doesn't make the count go beyond the // threshold, and fails otherwise. func incSynRcvdCount() bool { synRcvdCount.Lock() defer synRcvdCount.Unlock() if synRcvdCount.value >= SynRcvdCountThreshold { return false } synRcvdCount.value++ return true } // decSynRcvdCount atomically decrements the global number of endpoints in // SYN-RCVD state. It must only be called if a previous call to incSynRcvdCount // succeeded. func decSynRcvdCount() { synRcvdCount.Lock() defer synRcvdCount.Unlock() synRcvdCount.value-- } // newListenContext creates a new listen context. func newListenContext(stack *stack.Stack, rcvWnd seqnum.Size, v6only bool, netProto tcpip.NetworkProtocolNumber) *listenContext { l := &listenContext{ stack: stack, rcvWnd: rcvWnd, hasher: sha1.New(), v6only: v6only, netProto: netProto, } rand.Read(l.nonce[0][:]) rand.Read(l.nonce[1][:]) return l } // cookieHash calculates the cookieHash for the given id, timestamp and nonce // index. The hash is used to create and validate cookies. func (l *listenContext) cookieHash(id stack.TransportEndpointID, ts uint32, nonceIndex int) uint32 { // Initialize block with fixed-size data: local ports and v. var payload [8]byte binary.BigEndian.PutUint16(payload[0:], id.LocalPort) binary.BigEndian.PutUint16(payload[2:], id.RemotePort) binary.BigEndian.PutUint32(payload[4:], ts) // Feed everything to the hasher. l.hasherMu.Lock() l.hasher.Reset() l.hasher.Write(payload[:]) l.hasher.Write(l.nonce[nonceIndex][:]) io.WriteString(l.hasher, string(id.LocalAddress)) io.WriteString(l.hasher, string(id.RemoteAddress)) // Finalize the calculation of the hash and return the first 4 bytes. h := make([]byte, 0, sha1.Size) h = l.hasher.Sum(h) l.hasherMu.Unlock() return binary.BigEndian.Uint32(h[:]) } // createCookie creates a SYN cookie for the given id and incoming sequence // number. func (l *listenContext) createCookie(id stack.TransportEndpointID, seq seqnum.Value, data uint32) seqnum.Value { ts := timeStamp() v := l.cookieHash(id, 0, 0) + uint32(seq) + (ts << tsOffset) v += (l.cookieHash(id, ts, 1) + data) & hashMask return seqnum.Value(v) } // isCookieValid checks if the supplied cookie is valid for the given id and // sequence number. If it is, it also returns the data originally encoded in the // cookie when createCookie was called. func (l *listenContext) isCookieValid(id stack.TransportEndpointID, cookie seqnum.Value, seq seqnum.Value) (uint32, bool) { ts := timeStamp() v := uint32(cookie) - l.cookieHash(id, 0, 0) - uint32(seq) cookieTS := v >> tsOffset if ((ts - cookieTS) & tsMask) > maxTSDiff { return 0, false } return (v - l.cookieHash(id, cookieTS, 1)) & hashMask, true } // createConnectedEndpoint creates a new connected endpoint, with the connection // parameters given by the arguments. func (l *listenContext) createConnectedEndpoint(s *segment, iss seqnum.Value, irs seqnum.Value, rcvdSynOpts *header.TCPSynOptions) (*endpoint, *tcpip.Error) { // Create a new endpoint. netProto := l.netProto if netProto == 0 { netProto = s.route.NetProto } n := newEndpoint(l.stack, netProto, nil) n.v6only = l.v6only n.id = s.id n.boundNICID = s.route.NICID() n.route = s.route.Clone() n.effectiveNetProtos = []tcpip.NetworkProtocolNumber{s.route.NetProto} n.rcvBufSize = int(l.rcvWnd) n.maybeEnableTimestamp(rcvdSynOpts) n.maybeEnableSACKPermitted(rcvdSynOpts) // Register new endpoint so that packets are routed to it. if err := n.stack.RegisterTransportEndpoint(n.boundNICID, n.effectiveNetProtos, ProtocolNumber, n.id, n); err != nil { n.Close() return nil, err } n.isRegistered = true n.state = stateConnected // Create sender and receiver. // // The receiver at least temporarily has a zero receive window scale, // but the caller may change it (before starting the protocol loop). n.snd = newSender(n, iss, irs, s.window, rcvdSynOpts.MSS, rcvdSynOpts.WS) n.rcv = newReceiver(n, irs, l.rcvWnd, 0) return n, nil } // createEndpoint creates a new endpoint in connected state and then performs // the TCP 3-way handshake. func (l *listenContext) createEndpointAndPerformHandshake(s *segment, opts *header.TCPSynOptions) (*endpoint, *tcpip.Error) { // Create new endpoint. irs := s.sequenceNumber cookie := l.createCookie(s.id, irs, encodeMSS(opts.MSS)) ep, err := l.createConnectedEndpoint(s, cookie, irs, opts) if err != nil { return nil, err } // Perform the 3-way handshake. h, err := newHandshake(ep, l.rcvWnd) if err != nil { ep.Close() return nil, err } h.resetToSynRcvd(cookie, irs, opts) if err := h.execute(); err != nil { ep.Close() return nil, err } // Update the receive window scaling. We can't do it before the // handshake because it's possible that the peer doesn't support window // scaling. ep.rcv.rcvWndScale = h.effectiveRcvWndScale() return ep, nil } // deliverAccepted delivers the newly-accepted endpoint to the listener. If the // endpoint has transitioned out of the listen state, the new endpoint is closed // instead. func (e *endpoint) deliverAccepted(n *endpoint) { e.mu.RLock() if e.state == stateListen { e.acceptedChan <- n e.waiterQueue.Notify(waiter.EventIn) } else { n.Close() } e.mu.RUnlock() } // handleSynSegment is called in its own goroutine once the listening endpoint // receives a SYN segment. It is responsible for completing the handshake and // queueing the new endpoint for acceptance. // // A limited number of these goroutines are allowed before TCP starts using SYN // cookies to accept connections. func (e *endpoint) handleSynSegment(ctx *listenContext, s *segment, opts *header.TCPSynOptions) { defer decSynRcvdCount() defer s.decRef() n, err := ctx.createEndpointAndPerformHandshake(s, opts) if err != nil { return } e.deliverAccepted(n) } // handleListenSegment is called when a listening endpoint receives a segment // and needs to handle it. func (e *endpoint) handleListenSegment(ctx *listenContext, s *segment) { switch s.flags { case flagSyn: opts := parseSynSegmentOptions(s) if incSynRcvdCount() { s.incRef() go e.handleSynSegment(ctx, s, &opts) // S/R-FIXME } else { cookie := ctx.createCookie(s.id, s.sequenceNumber, encodeMSS(opts.MSS)) // Send SYN with window scaling because we currently // dont't encode this information in the cookie. // // Enable Timestamp option if the original syn did have // the timestamp option specified. synOpts := header.TCPSynOptions{ WS: -1, TS: opts.TS, TSVal: tcpTimeStamp(timeStampOffset()), TSEcr: opts.TSVal, } sendSynTCP(&s.route, s.id, flagSyn|flagAck, cookie, s.sequenceNumber+1, ctx.rcvWnd, synOpts) } case flagAck: if data, ok := ctx.isCookieValid(s.id, s.ackNumber-1, s.sequenceNumber-1); ok && int(data) < len(mssTable) { // Create newly accepted endpoint and deliver it. rcvdSynOptions := &header.TCPSynOptions{ MSS: mssTable[data], // Disable Window scaling as original SYN is // lost. WS: -1, } // When syn cookies are in use we enable timestamp only // if the ack specifies the timestamp option assuming // that the other end did in fact negotiate the // timestamp option in the original SYN. if s.parsedOptions.TS { rcvdSynOptions.TS = true rcvdSynOptions.TSVal = s.parsedOptions.TSVal rcvdSynOptions.TSEcr = s.parsedOptions.TSEcr } n, err := ctx.createConnectedEndpoint(s, s.ackNumber-1, s.sequenceNumber-1, rcvdSynOptions) if err == nil { // clear the tsOffset for the newly created // endpoint as the Timestamp was already // randomly offset when the original SYN-ACK was // sent above. n.tsOffset = 0 e.deliverAccepted(n) } } } } // protocolListenLoop is the main loop of a listening TCP endpoint. It runs in // its own goroutine and is responsible for handling connection requests. func (e *endpoint) protocolListenLoop(rcvWnd seqnum.Size) *tcpip.Error { defer func() { // Mark endpoint as closed. This will prevent goroutines running // handleSynSegment() from attempting to queue new connections // to the endpoint. e.mu.Lock() e.state = stateClosed // Notify waiters that the endpoint is shutdown. e.waiterQueue.Notify(waiter.EventIn | waiter.EventOut) // Do cleanup if needed. e.completeWorkerLocked() if e.drainDone != nil { close(e.drainDone) } e.mu.Unlock() }() e.mu.Lock() v6only := e.v6only e.mu.Unlock() ctx := newListenContext(e.stack, rcvWnd, v6only, e.netProto) s := sleep.Sleeper{} s.AddWaker(&e.notificationWaker, wakerForNotification) s.AddWaker(&e.newSegmentWaker, wakerForNewSegment) for { switch index, _ := s.Fetch(true); index { case wakerForNotification: n := e.fetchNotifications() if n¬ifyClose != 0 { return nil } if n¬ifyDrain != 0 { for s := e.segmentQueue.dequeue(); s != nil; s = e.segmentQueue.dequeue() { e.handleListenSegment(ctx, s) s.decRef() } close(e.drainDone) <-e.undrain } case wakerForNewSegment: // Process at most maxSegmentsPerWake segments. mayRequeue := true for i := 0; i < maxSegmentsPerWake; i++ { s := e.segmentQueue.dequeue() if s == nil { mayRequeue = false break } e.handleListenSegment(ctx, s) s.decRef() } // If the queue is not empty, make sure we'll wake up // in the next iteration. if mayRequeue && !e.segmentQueue.empty() { e.newSegmentWaker.Assert() } } } }