FedP2P/connection.go

1167 lines
28 KiB
Go

package torrent
import (
"bufio"
"bytes"
"errors"
"fmt"
"io"
"log"
"math/rand"
"net"
"strconv"
"strings"
"sync"
"time"
"github.com/anacrolix/torrent/mse"
"github.com/anacrolix/missinggo"
"github.com/anacrolix/missinggo/bitmap"
"github.com/anacrolix/missinggo/iter"
"github.com/anacrolix/missinggo/prioritybitmap"
"github.com/anacrolix/torrent/bencode"
pp "github.com/anacrolix/torrent/peer_protocol"
)
type peerSource string
const (
peerSourceTracker = "T" // It's the default.
peerSourceIncoming = "I"
peerSourceDHTGetPeers = "Hg"
peerSourceDHTAnnouncePeer = "Ha"
peerSourcePEX = "X"
)
// Maintains the state of a connection with a peer.
type connection struct {
t *Torrent
// The actual Conn, used for closing, and setting socket options.
conn net.Conn
// The Reader and Writer for this Conn, with hooks installed for stats,
// limiting, deadlines etc.
w io.Writer
r io.Reader
// True if the connection is operating over MSE obfuscation.
headerEncrypted bool
cryptoMethod uint32
Discovery peerSource
uTP bool
closed missinggo.Event
stats ConnStats
UnwantedChunksReceived int
UsefulChunksReceived int
chunksSent int
goodPiecesDirtied int
badPiecesDirtied int
lastMessageReceived time.Time
completedHandshake time.Time
lastUsefulChunkReceived time.Time
lastChunkSent time.Time
// Stuff controlled by the local peer.
Interested bool
Choked bool
requests map[request]struct{}
requestsLowWater int
// Indexed by metadata piece, set to true if posted and pending a
// response.
metadataRequests []bool
sentHaves []bool
// Stuff controlled by the remote peer.
PeerID [20]byte
PeerInterested bool
PeerChoked bool
PeerRequests map[request]struct{}
PeerExtensionBytes peerExtensionBytes
// The pieces the peer has claimed to have.
peerPieces bitmap.Bitmap
// The peer has everything. This can occur due to a special message, when
// we may not even know the number of pieces in the torrent yet.
peerHasAll bool
// The highest possible number of pieces the torrent could have based on
// communication with the peer. Generally only useful until we have the
// torrent info.
peerMinPieces int
// Pieces we've accepted chunks for from the peer.
peerTouchedPieces map[int]struct{}
PeerMaxRequests int // Maximum pending requests the peer allows.
PeerExtensionIDs map[string]byte
PeerClientName string
pieceInclination []int
pieceRequestOrder prioritybitmap.PriorityBitmap
postedBuffer bytes.Buffer
uploadTimer *time.Timer
writerCond sync.Cond
}
func (cn *connection) mu() sync.Locker {
return &cn.t.cl.mu
}
func (cn *connection) remoteAddr() net.Addr {
return cn.conn.RemoteAddr()
}
func (cn *connection) localAddr() net.Addr {
return cn.conn.LocalAddr()
}
func (cn *connection) supportsExtension(ext string) bool {
_, ok := cn.PeerExtensionIDs[ext]
return ok
}
// The best guess at number of pieces in the torrent for this peer.
func (cn *connection) bestPeerNumPieces() int {
if cn.t.haveInfo() {
return cn.t.numPieces()
}
return cn.peerMinPieces
}
func (cn *connection) completedString() string {
return fmt.Sprintf("%d/%d", cn.peerPieces.Len(), cn.bestPeerNumPieces())
}
// Correct the PeerPieces slice length. Return false if the existing slice is
// invalid, such as by receiving badly sized BITFIELD, or invalid HAVE
// messages.
func (cn *connection) setNumPieces(num int) error {
cn.peerPieces.RemoveRange(num, -1)
cn.peerPiecesChanged()
return nil
}
func eventAgeString(t time.Time) string {
if t.IsZero() {
return "never"
}
return fmt.Sprintf("%.2fs ago", time.Now().Sub(t).Seconds())
}
func (cn *connection) connectionFlags() (ret string) {
c := func(b byte) {
ret += string([]byte{b})
}
if cn.cryptoMethod == mse.CryptoMethodRC4 {
c('E')
} else if cn.headerEncrypted {
c('e')
}
ret += string(cn.Discovery)
if cn.uTP {
c('T')
}
return
}
// Inspired by https://trac.transmissionbt.com/wiki/PeerStatusText
func (cn *connection) statusFlags() (ret string) {
c := func(b byte) {
ret += string([]byte{b})
}
if cn.Interested {
c('i')
}
if cn.Choked {
c('c')
}
c('-')
ret += cn.connectionFlags()
c('-')
if cn.PeerInterested {
c('i')
}
if cn.PeerChoked {
c('c')
}
return
}
func (cn *connection) String() string {
var buf bytes.Buffer
cn.WriteStatus(&buf, nil)
return buf.String()
}
func (cn *connection) WriteStatus(w io.Writer, t *Torrent) {
// \t isn't preserved in <pre> blocks?
fmt.Fprintf(w, "%+q: %s-%s\n", cn.PeerID, cn.localAddr(), cn.remoteAddr())
fmt.Fprintf(w, " last msg: %s, connected: %s, last useful chunk: %s\n",
eventAgeString(cn.lastMessageReceived),
eventAgeString(cn.completedHandshake),
eventAgeString(cn.lastUsefulChunkReceived))
fmt.Fprintf(w,
" %s completed, %d pieces touched, good chunks: %d/%d-%d reqq: %d-%d, flags: %s\n",
cn.completedString(),
len(cn.peerTouchedPieces),
cn.UsefulChunksReceived,
cn.UnwantedChunksReceived+cn.UsefulChunksReceived,
cn.chunksSent,
cn.numLocalRequests(),
len(cn.PeerRequests),
cn.statusFlags(),
)
roi := cn.pieceRequestOrderIter()
fmt.Fprintf(w, " next pieces: %v%s\n",
iter.ToSlice(iter.Head(10, roi)),
func() string {
if cn.shouldRequestWithoutBias() {
return " (fastest)"
} else {
return ""
}
}())
}
func (cn *connection) Close() {
if !cn.closed.Set() {
return
}
cn.discardPieceInclination()
cn.pieceRequestOrder.Clear()
if cn.conn != nil {
go cn.conn.Close()
}
}
func (cn *connection) PeerHasPiece(piece int) bool {
return cn.peerHasAll || cn.peerPieces.Contains(piece)
}
func (cn *connection) Post(msg pp.Message) {
messageTypesPosted.Add(strconv.FormatInt(int64(msg.Type), 10), 1)
cn.postedBuffer.Write(msg.MustMarshalBinary())
cn.tickleWriter()
}
func (cn *connection) requestMetadataPiece(index int) {
eID := cn.PeerExtensionIDs["ut_metadata"]
if eID == 0 {
return
}
if index < len(cn.metadataRequests) && cn.metadataRequests[index] {
return
}
cn.Post(pp.Message{
Type: pp.Extended,
ExtendedID: eID,
ExtendedPayload: func() []byte {
b, err := bencode.Marshal(map[string]int{
"msg_type": pp.RequestMetadataExtensionMsgType,
"piece": index,
})
if err != nil {
panic(err)
}
return b
}(),
})
for index >= len(cn.metadataRequests) {
cn.metadataRequests = append(cn.metadataRequests, false)
}
cn.metadataRequests[index] = true
}
func (cn *connection) requestedMetadataPiece(index int) bool {
return index < len(cn.metadataRequests) && cn.metadataRequests[index]
}
// The actual value to use as the maximum outbound requests.
func (cn *connection) nominalMaxRequests() (ret int) {
ret = cn.PeerMaxRequests
if ret > 64 {
ret = 64
}
return
}
// Returns true if an unsatisfied request was canceled.
func (cn *connection) PeerCancel(r request) bool {
if cn.PeerRequests == nil {
return false
}
if _, ok := cn.PeerRequests[r]; !ok {
return false
}
delete(cn.PeerRequests, r)
return true
}
func (cn *connection) Choke(msg func(pp.Message) bool) bool {
if cn.Choked {
return true
}
cn.PeerRequests = nil
cn.Choked = true
return msg(pp.Message{
Type: pp.Choke,
})
}
func (cn *connection) Unchoke(msg func(pp.Message) bool) bool {
if !cn.Choked {
return true
}
cn.Choked = false
return msg(pp.Message{
Type: pp.Unchoke,
})
}
func (cn *connection) SetInterested(interested bool, msg func(pp.Message) bool) bool {
if cn.Interested == interested {
return true
}
cn.Interested = interested
// log.Printf("%p: setting interest: %v", cn, interested)
return msg(pp.Message{
Type: func() pp.MessageType {
if interested {
return pp.Interested
} else {
return pp.NotInterested
}
}(),
})
}
func (cn *connection) fillWriteBuffer(msg func(pp.Message) bool) {
numFillBuffers.Add(1)
cancel, new, i := cn.desiredRequestState()
if !cn.SetInterested(i, msg) {
return
}
if cancel && len(cn.requests) != 0 {
fillBufferSentCancels.Add(1)
for r := range cn.requests {
cn.deleteRequest(r)
// log.Printf("%p: cancelling request: %v", cn, r)
if !msg(makeCancelMessage(r)) {
return
}
}
}
if len(new) != 0 {
fillBufferSentRequests.Add(1)
for _, r := range new {
if cn.requests == nil {
cn.requests = make(map[request]struct{}, cn.nominalMaxRequests())
}
cn.requests[r] = struct{}{}
// log.Printf("%p: requesting %v", cn, r)
if !msg(pp.Message{
Type: pp.Request,
Index: r.Index,
Begin: r.Begin,
Length: r.Length,
}) {
return
}
}
// If we didn't completely top up the requests, we shouldn't mark the
// low water, since we'll want to top up the requests as soon as we
// have more write buffer space.
cn.requestsLowWater = len(cn.requests) / 2
}
cn.upload(msg)
}
// Writes buffers to the socket from the write channel.
func (cn *connection) writer(keepAliveTimeout time.Duration) {
var (
buf bytes.Buffer
lastWrite time.Time = time.Now()
)
var keepAliveTimer *time.Timer
keepAliveTimer = time.AfterFunc(keepAliveTimeout, func() {
cn.mu().Lock()
defer cn.mu().Unlock()
if time.Since(lastWrite) >= keepAliveTimeout {
cn.tickleWriter()
}
keepAliveTimer.Reset(keepAliveTimeout)
})
cn.mu().Lock()
defer cn.mu().Unlock()
defer cn.Close()
defer keepAliveTimer.Stop()
for {
buf.Write(cn.postedBuffer.Bytes())
cn.postedBuffer.Reset()
if buf.Len() == 0 {
cn.fillWriteBuffer(func(msg pp.Message) bool {
cn.wroteMsg(&msg)
buf.Write(msg.MustMarshalBinary())
return buf.Len() < 1<<16
})
}
if buf.Len() == 0 && time.Since(lastWrite) >= keepAliveTimeout {
buf.Write(pp.Message{Keepalive: true}.MustMarshalBinary())
postedKeepalives.Add(1)
}
if buf.Len() == 0 {
cn.writerCond.Wait()
continue
}
cn.mu().Unlock()
// log.Printf("writing %d bytes", buf.Len())
n, err := cn.w.Write(buf.Bytes())
cn.mu().Lock()
if n != 0 {
lastWrite = time.Now()
keepAliveTimer.Reset(keepAliveTimeout)
}
if err != nil {
return
}
if n != buf.Len() {
panic("short write")
}
buf.Reset()
}
}
func (cn *connection) Have(piece int) {
for piece >= len(cn.sentHaves) {
cn.sentHaves = append(cn.sentHaves, false)
}
if cn.sentHaves[piece] {
return
}
cn.Post(pp.Message{
Type: pp.Have,
Index: pp.Integer(piece),
})
cn.sentHaves[piece] = true
}
func (cn *connection) Bitfield(haves []bool) {
if cn.sentHaves != nil {
panic("bitfield must be first have-related message sent")
}
cn.Post(pp.Message{
Type: pp.Bitfield,
Bitfield: haves,
})
// Make a copy of haves, as that's read when the message is marshalled
// without the lock. Also it obviously shouldn't change in the Msg due to
// changes in .sentHaves.
cn.sentHaves = append([]bool(nil), haves...)
}
func nextRequestState(
networkingEnabled bool,
currentRequests map[request]struct{},
peerChoking bool,
requestPieces iter.Func,
pendingChunks func(piece int, f func(chunkSpec) bool) bool,
requestsLowWater int,
requestsHighWater int,
) (
cancelExisting bool, // Cancel all our pending requests
newRequests []request, // Chunks to request that we currently aren't
interested bool, // Whether we should indicate interest, even if we don't request anything
) {
if !networkingEnabled {
return true, nil, false
}
if len(currentRequests) > requestsLowWater {
return false, nil, true
}
requestPieces(func(_piece interface{}) bool {
interested = true
if peerChoking {
return false
}
piece := _piece.(int)
return pendingChunks(piece, func(cs chunkSpec) bool {
r := request{pp.Integer(piece), cs}
if _, ok := currentRequests[r]; !ok {
if newRequests == nil {
newRequests = make([]request, 0, requestsHighWater-len(currentRequests))
}
newRequests = append(newRequests, r)
}
return len(currentRequests)+len(newRequests) < requestsHighWater
})
})
return
}
func (cn *connection) updateRequests() {
cn.tickleWriter()
}
func iterBitmapsDistinct(skip bitmap.Bitmap, bms ...bitmap.Bitmap) iter.Func {
return func(cb iter.Callback) {
for _, bm := range bms {
if !iter.All(func(i interface{}) bool {
skip.Add(i.(int))
return cb(i)
}, bitmap.Sub(bm, skip).Iter) {
return
}
}
}
}
func (cn *connection) unbiasedPieceRequestOrder() iter.Func {
now, readahead := cn.t.readerPiecePriorities()
return iterBitmapsDistinct(cn.t.completedPieces.Copy(), now, readahead, cn.t.pendingPieces)
}
// The connection should download highest priority pieces first, without any
// inclination toward avoiding wastage. Generally we might do this if there's
// a single connection, or this is the fastest connection, and we have active
// readers that signal an ordering preference. It's conceivable that the best
// connection should do this, since it's least likely to waste our time if
// assigned to the highest priority pieces, and assigning more than one this
// role would cause significant wasted bandwidth.
func (cn *connection) shouldRequestWithoutBias() bool {
if cn.t.requestStrategy != 2 {
return false
}
if len(cn.t.readers) == 0 {
return false
}
if len(cn.t.conns) == 1 {
return true
}
if cn == cn.t.fastestConn {
return true
}
return false
}
func (cn *connection) pieceRequestOrderIter() iter.Func {
if cn.shouldRequestWithoutBias() {
return cn.unbiasedPieceRequestOrder()
} else {
return cn.pieceRequestOrder.Iter
}
}
func (cn *connection) desiredRequestState() (bool, []request, bool) {
return nextRequestState(
cn.t.networkingEnabled,
cn.requests,
cn.PeerChoked,
cn.pieceRequestOrderIter(),
func(piece int, f func(chunkSpec) bool) bool {
return undirtiedChunks(piece, cn.t, f)
},
cn.requestsLowWater,
cn.nominalMaxRequests(),
)
}
func undirtiedChunks(piece int, t *Torrent, f func(chunkSpec) bool) bool {
chunkIndices := t.pieces[piece].undirtiedChunkIndices().ToSortedSlice()
return iter.ForPerm(len(chunkIndices), func(i int) bool {
return f(t.chunkIndexSpec(chunkIndices[i], piece))
})
}
// check callers updaterequests
func (cn *connection) stopRequestingPiece(piece int) bool {
return cn.pieceRequestOrder.Remove(piece)
}
// This is distinct from Torrent piece priority, which is the user's
// preference. Connection piece priority is specific to a connection,
// pseudorandomly avoids connections always requesting the same pieces and
// thus wasting effort.
func (cn *connection) updatePiecePriority(piece int) bool {
tpp := cn.t.piecePriority(piece)
if !cn.PeerHasPiece(piece) {
tpp = PiecePriorityNone
}
if tpp == PiecePriorityNone {
return cn.stopRequestingPiece(piece)
}
prio := cn.getPieceInclination()[piece]
switch cn.t.requestStrategy {
case 1:
switch tpp {
case PiecePriorityNormal:
case PiecePriorityReadahead:
prio -= cn.t.numPieces()
case PiecePriorityNext, PiecePriorityNow:
prio -= 2 * cn.t.numPieces()
default:
panic(tpp)
}
prio += piece / 3
default:
}
return cn.pieceRequestOrder.Set(piece, prio)
}
func (cn *connection) getPieceInclination() []int {
if cn.pieceInclination == nil {
cn.pieceInclination = cn.t.getConnPieceInclination()
}
return cn.pieceInclination
}
func (cn *connection) discardPieceInclination() {
if cn.pieceInclination == nil {
return
}
cn.t.putPieceInclination(cn.pieceInclination)
cn.pieceInclination = nil
}
func (cn *connection) peerPiecesChanged() {
if cn.t.haveInfo() {
prioritiesChanged := false
for i := range iter.N(cn.t.numPieces()) {
if cn.updatePiecePriority(i) {
prioritiesChanged = true
}
}
if prioritiesChanged {
cn.updateRequests()
}
}
}
func (cn *connection) raisePeerMinPieces(newMin int) {
if newMin > cn.peerMinPieces {
cn.peerMinPieces = newMin
}
}
func (cn *connection) peerSentHave(piece int) error {
if cn.t.haveInfo() && piece >= cn.t.numPieces() {
return errors.New("invalid piece")
}
if cn.PeerHasPiece(piece) {
return nil
}
cn.raisePeerMinPieces(piece + 1)
cn.peerPieces.Set(piece, true)
if cn.updatePiecePriority(piece) {
cn.updateRequests()
}
return nil
}
func (cn *connection) peerSentBitfield(bf []bool) error {
cn.peerHasAll = false
if len(bf)%8 != 0 {
panic("expected bitfield length divisible by 8")
}
// We know that the last byte means that at most the last 7 bits are
// wasted.
cn.raisePeerMinPieces(len(bf) - 7)
if cn.t.haveInfo() && len(bf) > cn.t.numPieces() {
// Ignore known excess pieces.
bf = bf[:cn.t.numPieces()]
}
for i, have := range bf {
if have {
cn.raisePeerMinPieces(i + 1)
}
cn.peerPieces.Set(i, have)
}
cn.peerPiecesChanged()
return nil
}
func (cn *connection) peerSentHaveAll() error {
cn.peerHasAll = true
cn.peerPieces.Clear()
cn.peerPiecesChanged()
return nil
}
func (cn *connection) peerSentHaveNone() error {
cn.peerPieces.Clear()
cn.peerHasAll = false
cn.peerPiecesChanged()
return nil
}
func (c *connection) requestPendingMetadata() {
if c.t.haveInfo() {
return
}
if c.PeerExtensionIDs["ut_metadata"] == 0 {
// Peer doesn't support this.
return
}
// Request metadata pieces that we don't have in a random order.
var pending []int
for index := 0; index < c.t.metadataPieceCount(); index++ {
if !c.t.haveMetadataPiece(index) && !c.requestedMetadataPiece(index) {
pending = append(pending, index)
}
}
for _, i := range rand.Perm(len(pending)) {
c.requestMetadataPiece(pending[i])
}
}
func (cn *connection) wroteMsg(msg *pp.Message) {
messageTypesSent.Add(strconv.FormatInt(int64(msg.Type), 10), 1)
cn.stats.wroteMsg(msg)
cn.t.stats.wroteMsg(msg)
}
func (cn *connection) readMsg(msg *pp.Message) {
cn.stats.readMsg(msg)
cn.t.stats.readMsg(msg)
}
func (cn *connection) wroteBytes(n int64) {
cn.stats.wroteBytes(n)
if cn.t != nil {
cn.t.stats.wroteBytes(n)
}
}
func (cn *connection) readBytes(n int64) {
cn.stats.readBytes(n)
if cn.t != nil {
cn.t.stats.readBytes(n)
}
}
// Returns whether the connection is currently useful to us. We're seeding and
// they want data, we don't have metainfo and they can provide it, etc.
func (c *connection) useful() bool {
t := c.t
if c.closed.IsSet() {
return false
}
if !t.haveInfo() {
return c.supportsExtension("ut_metadata")
}
if t.seeding() {
return c.PeerInterested
}
return c.peerHasWantedPieces()
}
func (c *connection) lastHelpful() (ret time.Time) {
ret = c.lastUsefulChunkReceived
if c.t.seeding() && c.lastChunkSent.After(ret) {
ret = c.lastChunkSent
}
return
}
// Processes incoming bittorrent messages. The client lock is held upon entry
// and exit. Returning will end the connection.
func (c *connection) mainReadLoop() error {
t := c.t
cl := t.cl
decoder := pp.Decoder{
R: bufio.NewReaderSize(c.r, 1<<17),
MaxLength: 256 * 1024,
Pool: t.chunkPool,
}
for {
var (
msg pp.Message
err error
)
func() {
cl.mu.Unlock()
defer cl.mu.Lock()
err = decoder.Decode(&msg)
}()
if cl.closed.IsSet() || c.closed.IsSet() || err == io.EOF {
return nil
}
if err != nil {
return err
}
c.readMsg(&msg)
c.lastMessageReceived = time.Now()
if msg.Keepalive {
receivedKeepalives.Add(1)
continue
}
messageTypesReceived.Add(strconv.FormatInt(int64(msg.Type), 10), 1)
switch msg.Type {
case pp.Choke:
c.PeerChoked = true
c.requests = nil
// We can then reset our interest.
c.updateRequests()
case pp.Reject:
if c.deleteRequest(newRequest(msg.Index, msg.Begin, msg.Length)) {
c.updateRequests()
}
case pp.Unchoke:
c.PeerChoked = false
c.tickleWriter()
case pp.Interested:
c.PeerInterested = true
c.tickleWriter()
case pp.NotInterested:
c.PeerInterested = false
c.PeerRequests = nil
case pp.Have:
err = c.peerSentHave(int(msg.Index))
case pp.Request:
if c.Choked {
break
}
if len(c.PeerRequests) >= maxRequests {
break
}
if c.PeerRequests == nil {
c.PeerRequests = make(map[request]struct{}, maxRequests)
}
c.PeerRequests[newRequest(msg.Index, msg.Begin, msg.Length)] = struct{}{}
c.tickleWriter()
case pp.Cancel:
req := newRequest(msg.Index, msg.Begin, msg.Length)
if !c.PeerCancel(req) {
unexpectedCancels.Add(1)
}
case pp.Bitfield:
err = c.peerSentBitfield(msg.Bitfield)
case pp.HaveAll:
err = c.peerSentHaveAll()
case pp.HaveNone:
err = c.peerSentHaveNone()
case pp.Piece:
c.receiveChunk(&msg)
if len(msg.Piece) == int(t.chunkSize) {
t.chunkPool.Put(msg.Piece)
}
case pp.Extended:
switch msg.ExtendedID {
case pp.HandshakeExtendedID:
// TODO: Create a bencode struct for this.
var d map[string]interface{}
err = bencode.Unmarshal(msg.ExtendedPayload, &d)
if err != nil {
err = fmt.Errorf("error decoding extended message payload: %s", err)
break
}
// log.Printf("got handshake from %q: %#v", c.Socket.RemoteAddr().String(), d)
if reqq, ok := d["reqq"]; ok {
if i, ok := reqq.(int64); ok {
c.PeerMaxRequests = int(i)
}
}
if v, ok := d["v"]; ok {
c.PeerClientName = v.(string)
}
m, ok := d["m"]
if !ok {
err = errors.New("handshake missing m item")
break
}
mTyped, ok := m.(map[string]interface{})
if !ok {
err = errors.New("handshake m value is not dict")
break
}
if c.PeerExtensionIDs == nil {
c.PeerExtensionIDs = make(map[string]byte, len(mTyped))
}
for name, v := range mTyped {
id, ok := v.(int64)
if !ok {
log.Printf("bad handshake m item extension ID type: %T", v)
continue
}
if id == 0 {
delete(c.PeerExtensionIDs, name)
} else {
if c.PeerExtensionIDs[name] == 0 {
supportedExtensionMessages.Add(name, 1)
}
c.PeerExtensionIDs[name] = byte(id)
}
}
metadata_sizeUntyped, ok := d["metadata_size"]
if ok {
metadata_size, ok := metadata_sizeUntyped.(int64)
if !ok {
log.Printf("bad metadata_size type: %T", metadata_sizeUntyped)
} else {
err = t.setMetadataSize(metadata_size)
if err != nil {
err = fmt.Errorf("error setting metadata size to %d", metadata_size)
break
}
}
}
if _, ok := c.PeerExtensionIDs["ut_metadata"]; ok {
c.requestPendingMetadata()
}
case metadataExtendedId:
err = cl.gotMetadataExtensionMsg(msg.ExtendedPayload, t, c)
if err != nil {
err = fmt.Errorf("error handling metadata extension message: %s", err)
}
case pexExtendedId:
if cl.config.DisablePEX {
break
}
var pexMsg peerExchangeMessage
err = bencode.Unmarshal(msg.ExtendedPayload, &pexMsg)
if err != nil {
err = fmt.Errorf("error unmarshalling PEX message: %s", err)
break
}
go func() {
cl.mu.Lock()
t.addPeers(func() (ret []Peer) {
for i, cp := range pexMsg.Added {
p := Peer{
IP: make([]byte, 4),
Port: cp.Port,
Source: peerSourcePEX,
}
if i < len(pexMsg.AddedFlags) && pexMsg.AddedFlags[i]&0x01 != 0 {
p.SupportsEncryption = true
}
missinggo.CopyExact(p.IP, cp.IP[:])
ret = append(ret, p)
}
return
}())
cl.mu.Unlock()
}()
default:
err = fmt.Errorf("unexpected extended message ID: %v", msg.ExtendedID)
}
if err != nil {
// That client uses its own extension IDs for outgoing message
// types, which is incorrect.
if bytes.HasPrefix(c.PeerID[:], []byte("-SD0100-")) ||
strings.HasPrefix(string(c.PeerID[:]), "-XL0012-") {
return nil
}
}
case pp.Port:
if cl.dHT == nil {
break
}
pingAddr, err := net.ResolveUDPAddr("", c.remoteAddr().String())
if err != nil {
panic(err)
}
if msg.Port != 0 {
pingAddr.Port = int(msg.Port)
}
go cl.dHT.Ping(pingAddr, nil)
default:
err = fmt.Errorf("received unknown message type: %#v", msg.Type)
}
if err != nil {
return err
}
}
}
// Set both the Reader and Writer for the connection from a single ReadWriter.
func (cn *connection) setRW(rw io.ReadWriter) {
cn.r = rw
cn.w = rw
}
// Returns the Reader and Writer as a combined ReadWriter.
func (cn *connection) rw() io.ReadWriter {
return struct {
io.Reader
io.Writer
}{cn.r, cn.w}
}
// Handle a received chunk from a peer.
func (c *connection) receiveChunk(msg *pp.Message) {
t := c.t
cl := t.cl
chunksReceived.Add(1)
req := newRequest(msg.Index, msg.Begin, pp.Integer(len(msg.Piece)))
// Request has been satisfied.
if c.deleteRequest(req) {
c.updateRequests()
} else {
unexpectedChunksReceived.Add(1)
}
// Do we actually want this chunk?
if !t.wantPiece(req) {
unwantedChunksReceived.Add(1)
c.UnwantedChunksReceived++
return
}
index := int(req.Index)
piece := &t.pieces[index]
c.UsefulChunksReceived++
c.lastUsefulChunkReceived = time.Now()
if t.fastestConn != c {
// log.Printf("setting fastest connection %p", c)
}
t.fastestConn = c
// Need to record that it hasn't been written yet, before we attempt to do
// anything with it.
piece.incrementPendingWrites()
// Record that we have the chunk.
piece.unpendChunkIndex(chunkIndex(req.chunkSpec, t.chunkSize))
// Cancel pending requests for this chunk.
for c := range t.conns {
c.postCancel(req)
}
cl.mu.Unlock()
// Write the chunk out. Note that the upper bound on chunk writing
// concurrency will be the number of connections.
err := t.writeChunk(int(msg.Index), int64(msg.Begin), msg.Piece)
cl.mu.Lock()
piece.decrementPendingWrites()
if err != nil {
log.Printf("%s (%x): error writing chunk %v: %s", t, t.infoHash, req, err)
t.pendRequest(req)
t.updatePieceCompletion(int(msg.Index))
return
}
// It's important that the piece is potentially queued before we check if
// the piece is still wanted, because if it is queued, it won't be wanted.
if t.pieceAllDirty(index) {
t.queuePieceCheck(int(req.Index))
}
if c.peerTouchedPieces == nil {
c.peerTouchedPieces = make(map[int]struct{})
}
c.peerTouchedPieces[index] = struct{}{}
cl.event.Broadcast()
t.publishPieceChange(int(req.Index))
return
}
// Also handles choking and unchoking of the remote peer.
func (c *connection) upload(msg func(pp.Message) bool) bool {
t := c.t
cl := t.cl
if cl.config.NoUpload {
return true
}
if !c.PeerInterested {
return true
}
seeding := t.seeding()
if !seeding && !c.peerHasWantedPieces() {
// There's no reason to upload to this peer.
return true
}
// Breaking or completing this loop means we don't want to upload to the
// peer anymore, and we choke them.
another:
for seeding || c.chunksSent < c.UsefulChunksReceived+6 {
// We want to upload to the peer.
if !c.Unchoke(msg) {
return false
}
for r := range c.PeerRequests {
res := cl.uploadLimit.ReserveN(time.Now(), int(r.Length))
if !res.OK() {
panic(res)
}
delay := res.Delay()
if delay > 0 {
res.Cancel()
if c.uploadTimer == nil {
c.uploadTimer = time.AfterFunc(delay, c.writerCond.Broadcast)
} else {
c.uploadTimer.Reset(delay)
}
// Hard to say what to return here.
return true
}
more, err := cl.sendChunk(t, c, r, msg)
if err != nil {
i := int(r.Index)
if t.pieceComplete(i) {
t.updatePieceCompletion(i)
if !t.pieceComplete(i) {
// We had the piece, but not anymore.
break another
}
}
log.Printf("error sending chunk %+v to peer: %s", r, err)
// If we failed to send a chunk, choke the peer to ensure they
// flush all their requests. We've probably dropped a piece,
// but there's no way to communicate this to the peer. If they
// ask for it again, we'll kick them to allow us to send them
// an updated bitfield.
break another
}
delete(c.PeerRequests, r)
if !more {
return false
}
goto another
}
return true
}
return c.Choke(msg)
}
func (cn *connection) Drop() {
cn.t.dropConnection(cn)
}
func (cn *connection) netGoodPiecesDirtied() int {
return cn.goodPiecesDirtied - cn.badPiecesDirtied
}
func (c *connection) peerHasWantedPieces() bool {
return !c.pieceRequestOrder.IsEmpty()
}
func (c *connection) numLocalRequests() int {
return len(c.requests)
}
func (c *connection) deleteRequest(r request) bool {
if _, ok := c.requests[r]; !ok {
return false
}
delete(c.requests, r)
return true
}
func (c *connection) tickleWriter() {
c.writerCond.Broadcast()
}
func (c *connection) postCancel(r request) bool {
if !c.deleteRequest(r) {
return false
}
c.Post(makeCancelMessage(r))
return true
}