FedP2P/connection.go

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package torrent
import (
"bufio"
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"bytes"
"container/list"
"errors"
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"expvar"
"fmt"
"io"
"log"
"math/rand"
"net"
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"strconv"
"strings"
"sync"
"time"
"github.com/anacrolix/missinggo"
"github.com/anacrolix/missinggo/bitmap"
"github.com/anacrolix/missinggo/itertools"
"github.com/anacrolix/missinggo/prioritybitmap"
"github.com/bradfitz/iter"
"github.com/anacrolix/torrent/bencode"
pp "github.com/anacrolix/torrent/peer_protocol"
)
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var optimizedCancels = expvar.NewInt("optimizedCancels")
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.
encrypted bool
Discovery peerSource
uTP bool
closed missinggo.Event
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stats ConnStats
UnwantedChunksReceived int
UsefulChunksReceived int
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chunksSent int
goodPiecesDirtied int
badPiecesDirtied int
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lastMessageReceived time.Time
completedHandshake time.Time
lastUsefulChunkReceived time.Time
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lastChunkSent time.Time
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// 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.
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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{}
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PeerMaxRequests int // Maximum pending requests the peer allows.
PeerExtensionIDs map[string]byte
PeerClientName string
pieceInclination []int
pieceRequestOrder prioritybitmap.PriorityBitmap
outgoingUnbufferedMessages *list.List
outgoingUnbufferedMessagesNotEmpty missinggo.Event
}
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})
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}
if cn.encrypted {
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
}
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func (cn *connection) String() string {
var buf bytes.Buffer
cn.WriteStatus(&buf, nil)
return buf.String()
}
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func (cn *connection) WriteStatus(w io.Writer, t *Torrent) {
// \t isn't preserved in <pre> blocks?
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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))
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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,
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cn.chunksSent,
len(cn.Requests),
len(cn.PeerRequests),
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cn.statusFlags(),
)
}
func (cn *connection) Close() {
cn.closed.Set()
cn.discardPieceInclination()
cn.pieceRequestOrder.Clear()
if cn.conn != nil {
// TODO: This call blocks sometimes, why?
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) {
switch msg.Type {
case pp.Cancel:
for e := cn.outgoingUnbufferedMessages.Back(); e != nil; e = e.Prev() {
elemMsg := e.Value.(pp.Message)
if elemMsg.Type == pp.Request && elemMsg.Index == msg.Index && elemMsg.Begin == msg.Begin && elemMsg.Length == msg.Length {
cn.outgoingUnbufferedMessages.Remove(e)
optimizedCancels.Add(1)
return
}
}
}
if cn.outgoingUnbufferedMessages == nil {
cn.outgoingUnbufferedMessages = list.New()
}
cn.outgoingUnbufferedMessages.PushBack(msg)
cn.outgoingUnbufferedMessagesNotEmpty.Set()
postedMessageTypes.Add(strconv.FormatInt(int64(msg.Type), 10), 1)
}
func (cn *connection) RequestPending(r request) bool {
_, ok := cn.Requests[r]
return ok
}
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]
}
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// The actual value to use as the maximum outbound requests.
func (cn *connection) nominalMaxRequests() (ret int) {
ret = cn.PeerMaxRequests
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if ret > 64 {
ret = 64
}
return
}
// Returns true if more requests can be sent.
func (cn *connection) Request(chunk request) bool {
if len(cn.Requests) >= cn.nominalMaxRequests() {
return false
}
if !cn.PeerHasPiece(int(chunk.Index)) {
return true
}
if cn.RequestPending(chunk) {
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return true
}
cn.SetInterested(true)
if cn.PeerChoked {
return false
}
if cn.Requests == nil {
cn.Requests = make(map[request]struct{}, cn.PeerMaxRequests)
}
cn.Requests[chunk] = struct{}{}
cn.requestsLowWater = len(cn.Requests) / 2
cn.Post(pp.Message{
Type: pp.Request,
Index: chunk.Index,
Begin: chunk.Begin,
Length: chunk.Length,
})
return true
}
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// Returns true if an unsatisfied request was canceled.
func (cn *connection) Cancel(r request) bool {
if !cn.RequestPending(r) {
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return false
}
delete(cn.Requests, r)
cn.Post(pp.Message{
Type: pp.Cancel,
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Index: r.Index,
Begin: r.Begin,
Length: r.Length,
})
return true
}
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// Returns true if an unsatisfied request was canceled.
func (cn *connection) PeerCancel(r request) bool {
if cn.PeerRequests == nil {
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return false
}
if _, ok := cn.PeerRequests[r]; !ok {
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return false
}
delete(cn.PeerRequests, r)
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return true
}
func (cn *connection) Choke() {
if cn.Choked {
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return
}
cn.Post(pp.Message{
Type: pp.Choke,
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})
cn.PeerRequests = nil
cn.Choked = true
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}
func (cn *connection) Unchoke() {
if !cn.Choked {
return
}
cn.Post(pp.Message{
Type: pp.Unchoke,
})
cn.Choked = false
}
func (cn *connection) SetInterested(interested bool) {
if cn.Interested == interested {
return
}
cn.Post(pp.Message{
Type: func() pp.MessageType {
if interested {
return pp.Interested
} else {
return pp.NotInterested
}
}(),
})
cn.Interested = interested
}
var (
// Track connection writer buffer writes and flushes, to determine its
// efficiency.
connectionWriterFlush = expvar.NewInt("connectionWriterFlush")
connectionWriterWrite = expvar.NewInt("connectionWriterWrite")
)
// Writes buffers to the socket from the write channel.
func (cn *connection) writer(keepAliveTimeout time.Duration) {
defer func() {
cn.mu().Lock()
defer cn.mu().Unlock()
cn.Close()
}()
// Reduce write syscalls.
buf := bufio.NewWriter(cn.w)
keepAliveTimer := time.NewTimer(keepAliveTimeout)
for {
cn.mu().Lock()
for cn.outgoingUnbufferedMessages != nil && cn.outgoingUnbufferedMessages.Len() != 0 {
msg := cn.outgoingUnbufferedMessages.Remove(cn.outgoingUnbufferedMessages.Front()).(pp.Message)
cn.mu().Unlock()
b, err := msg.MarshalBinary()
if err != nil {
panic(err)
}
connectionWriterWrite.Add(1)
n, err := buf.Write(b)
if err != nil {
return
}
keepAliveTimer.Reset(keepAliveTimeout)
if n != len(b) {
panic("short write")
}
cn.mu().Lock()
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cn.wroteMsg(&msg)
}
cn.outgoingUnbufferedMessagesNotEmpty.Clear()
cn.mu().Unlock()
connectionWriterFlush.Add(1)
if buf.Buffered() != 0 {
if buf.Flush() != nil {
return
}
keepAliveTimer.Reset(keepAliveTimeout)
}
select {
case <-cn.closed.LockedChan(cn.mu()):
return
case <-cn.outgoingUnbufferedMessagesNotEmpty.LockedChan(cn.mu()):
case <-keepAliveTimer.C:
cn.mu().Lock()
cn.Post(pp.Message{Keepalive: true})
cn.mu().Unlock()
postedKeepalives.Add(1)
}
}
}
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) {
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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 (cn *connection) updateRequests() {
if !cn.t.haveInfo() {
return
}
if cn.Interested {
if cn.PeerChoked {
return
}
if len(cn.Requests) > cn.requestsLowWater {
return
}
}
cn.fillRequests()
if len(cn.Requests) == 0 && !cn.PeerChoked {
// So we're not choked, but we don't want anything right now. We may
// have completed readahead, and the readahead window has not rolled
// over to the next piece. Better to stay interested in case we're
// going to want data in the near future.
cn.SetInterested(!cn.t.haveAllPieces())
}
}
func (cn *connection) fillRequests() {
cn.pieceRequestOrder.IterTyped(func(piece int) (more bool) {
if cn.t.cl.config.Debug && cn.t.havePiece(piece) {
panic(piece)
}
return cn.requestPiecePendingChunks(piece)
})
}
func (c *connection) requestPiecePendingChunks(piece int) (again bool) {
if !c.PeerHasPiece(piece) {
return true
}
chunkIndices := c.t.pieces[piece].undirtiedChunkIndices().ToSortedSlice()
return itertools.ForPerm(len(chunkIndices), func(i int) bool {
req := request{pp.Integer(piece), c.t.chunkIndexSpec(chunkIndices[i], piece)}
return c.Request(req)
})
}
func (cn *connection) stopRequestingPiece(piece int) {
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) {
tpp := cn.t.piecePriority(piece)
if !cn.PeerHasPiece(piece) {
tpp = PiecePriorityNone
}
if tpp == PiecePriorityNone {
cn.stopRequestingPiece(piece)
return
}
prio := cn.getPieceInclination()[piece]
switch tpp {
case PiecePriorityNormal:
case PiecePriorityReadahead:
prio -= cn.t.numPieces()
case PiecePriorityNext, PiecePriorityNow:
prio -= 2 * cn.t.numPieces()
default:
panic(tpp)
}
prio += piece / 3
cn.pieceRequestOrder.Set(piece, prio)
cn.updateRequests()
}
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
}
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func (cn *connection) peerHasPieceChanged(piece int) {
cn.updatePiecePriority(piece)
}
func (cn *connection) peerPiecesChanged() {
if cn.t.haveInfo() {
for i := range iter.N(cn.t.numPieces()) {
cn.peerHasPieceChanged(i)
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}
}
}
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)
cn.peerHasPieceChanged(piece)
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)
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}
cn.peerPieces.Set(i, have)
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}
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()
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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])
}
}
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func (cn *connection) wroteMsg(msg *pp.Message) {
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cn.stats.wroteMsg(msg)
cn.t.stats.wroteMsg(msg)
}
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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)
}
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}
// 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 t.connHasWantedPieces(c)
}
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func (c *connection) lastHelpful() (ret time.Time) {
ret = c.lastUsefulChunkReceived
if c.t.seeding() && c.lastChunkSent.After(ret) {
ret = c.lastChunkSent
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}
return
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}
// 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
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decoder := pp.Decoder{
R: bufio.NewReader(c.r),
MaxLength: 256 * 1024,
Pool: t.chunkPool,
}
for {
cl.mu.Unlock()
var msg pp.Message
err := decoder.Decode(&msg)
cl.mu.Lock()
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
}
receivedMessageTypes.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:
cl.connDeleteRequest(t, c, newRequest(msg.Index, msg.Begin, msg.Length))
c.updateRequests()
case pp.Unchoke:
c.PeerChoked = false
cl.peerUnchoked(t, c)
case pp.Interested:
c.PeerInterested = true
c.upload()
case pp.NotInterested:
c.PeerInterested = false
c.Choke()
case pp.Have:
err = c.peerSentHave(int(msg.Index))
case pp.Request:
if c.Choked {
break
}
if !c.PeerInterested {
err = errors.New("peer sent request but isn't interested")
break
}
if !t.havePiece(msg.Index.Int()) {
// This isn't necessarily them screwing up. We can drop pieces
// from our storage, and can't communicate this to peers
// except by reconnecting.
requestsReceivedForMissingPieces.Add(1)
err = errors.New("peer requested piece we don't have")
break
}
if c.PeerRequests == nil {
c.PeerRequests = make(map[request]struct{}, maxRequests)
}
c.PeerRequests[newRequest(msg.Index, msg.Begin, msg.Length)] = struct{}{}
c.upload()
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)
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if len(msg.Piece) == int(t.chunkSize) {
t.chunkPool.Put(msg.Piece)
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}
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)
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 cl.connDeleteRequest(t, c, req) {
defer 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()
c.upload()
// 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 {
if cl.connCancel(t, c, req) {
c.updateRequests()
}
}
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: error writing chunk %v: %s", t, 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) {
2017-01-01 08:02:37 +08:00
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() {
t := c.t
cl := t.cl
if cl.config.NoUpload {
return
}
if !c.PeerInterested {
return
}
seeding := t.seeding()
if !seeding && !t.connHasWantedPieces(c) {
// There's no reason to upload to this peer.
return
}
// 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.
c.Unchoke()
for r := range c.PeerRequests {
res := cl.uploadLimit.ReserveN(time.Now(), int(r.Length))
delay := res.Delay()
if delay > 0 {
res.Cancel()
go func() {
time.Sleep(delay)
cl.mu.Lock()
defer cl.mu.Unlock()
c.upload()
}()
return
}
err := cl.sendChunk(t, c, r)
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)
goto another
}
return
}
c.Choke()
}
func (cn *connection) Drop() {
cn.t.dropConnection(cn)
}
func (cn *connection) netGoodPiecesDirtied() int {
return cn.goodPiecesDirtied - cn.badPiecesDirtied
}