package torrent import ( "container/list" "encoding" "errors" "expvar" "fmt" "io" "net" "sync" "time" pp "bitbucket.org/anacrolix/go.torrent/peer_protocol" ) var optimizedCancels = expvar.NewInt("optimizedCancels") type peerSource byte const ( peerSourceIncoming = 'I' peerSourceDHT = 'H' peerSourcePEX = 'X' ) // Maintains the state of a connection with a peer. type connection struct { Socket net.Conn Discovery peerSource uTP bool closing chan struct{} mu sync.Mutex // Only for closing. post chan pp.Message writeCh chan []byte UnwantedChunksReceived int UsefulChunksReceived int lastMessageReceived time.Time completedHandshake time.Time lastUsefulChunkReceived time.Time // Stuff controlled by the local peer. Interested bool Choked bool Requests map[request]struct{} // Stuff controlled by the remote peer. PeerID [20]byte PeerInterested bool PeerChoked bool PeerRequests map[request]struct{} PeerExtensionBytes peerExtensionBytes // Whether the peer has the given piece. nil if they've not sent any // related messages yet. PeerPieces []bool PeerMaxRequests int // Maximum pending requests the peer allows. PeerExtensionIDs map[string]int64 PeerClientName string } func newConnection(sock net.Conn, peb peerExtensionBytes, peerID [20]byte, uTP bool) (c *connection) { c = &connection{ Socket: sock, uTP: uTP, Choked: true, PeerChoked: true, PeerMaxRequests: 250, PeerExtensionBytes: peb, PeerID: peerID, closing: make(chan struct{}), writeCh: make(chan []byte), post: make(chan pp.Message), completedHandshake: time.Now(), } go c.writer() go c.writeOptimizer(time.Minute) return } func (cn *connection) completedString() string { if cn.PeerPieces == nil { return "?" } // f := float32(cn.piecesPeerHasCount()) / float32(cn.totalPiecesCount()) // return fmt.Sprintf("%d%%", int(f*100)) return fmt.Sprintf("%d/%d", cn.piecesPeerHasCount(), cn.totalPiecesCount()) } func (cn *connection) totalPiecesCount() int { return len(cn.PeerPieces) } func (cn *connection) piecesPeerHasCount() (count int) { for _, has := range cn.PeerPieces { if has { count++ } } return } // 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 { if cn.PeerPieces == nil { return nil } if len(cn.PeerPieces) == num { } else if len(cn.PeerPieces) < num { cn.PeerPieces = append(cn.PeerPieces, make([]bool, num-len(cn.PeerPieces))...) } else if len(cn.PeerPieces) <= (num+7)/8*8 { for _, have := range cn.PeerPieces[num:] { if have { return errors.New("peer has invalid piece") } } cn.PeerPieces = cn.PeerPieces[:num] } else { return fmt.Errorf("peer bitfield is excessively long: expected %d, have %d", num, len(cn.PeerPieces)) } if len(cn.PeerPieces) != num { panic("wat") } 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) WriteStatus(w io.Writer) { fmt.Fprintf(w, "%-90s: %s completed, good chunks: %d/%d reqs: %d-%d, last msg: %s, connected: %s, last useful chunk: %s, flags: ", fmt.Sprintf("%q: %s-%s", cn.PeerID, cn.Socket.LocalAddr(), cn.Socket.RemoteAddr()), cn.completedString(), cn.UsefulChunksReceived, cn.UnwantedChunksReceived+cn.UsefulChunksReceived, len(cn.Requests), len(cn.PeerRequests), eventAgeString(cn.lastMessageReceived), eventAgeString(cn.completedHandshake), eventAgeString(cn.lastUsefulChunkReceived)) c := func(b byte) { fmt.Fprintf(w, "%c", b) } // Inspired by https://trac.transmissionbt.com/wiki/PeerStatusText if len(cn.Requests) != 0 { c('D') } if cn.PeerChoked && cn.Interested { c('d') } if !cn.Choked { if cn.PeerInterested { c('U') } else { c('u') } } if cn.Discovery != 0 { c(byte(cn.Discovery)) } if cn.uTP { c('T') } fmt.Fprintln(w) } func (c *connection) Close() { c.mu.Lock() defer c.mu.Unlock() select { case <-c.closing: return default: } close(c.closing) c.Socket.Close() } func (c *connection) PeerHasPiece(index pp.Integer) bool { if c.PeerPieces == nil { return false } if int(index) >= len(c.PeerPieces) { return false } return c.PeerPieces[index] } func (c *connection) Post(msg pp.Message) { select { case c.post <- msg: case <-c.closing: } } func (c *connection) RequestPending(r request) bool { _, ok := c.Requests[r] return ok } // Returns true if more requests can be sent. func (c *connection) Request(chunk request) bool { if len(c.Requests) >= c.PeerMaxRequests { return false } if !c.PeerHasPiece(chunk.Index) { return true } if c.RequestPending(chunk) { return true } c.SetInterested(true) if c.PeerChoked { return false } if c.Requests == nil { c.Requests = make(map[request]struct{}, c.PeerMaxRequests) } c.Requests[chunk] = struct{}{} c.Post(pp.Message{ Type: pp.Request, Index: chunk.Index, Begin: chunk.Begin, Length: chunk.Length, }) return true } // Returns true if an unsatisfied request was canceled. func (c *connection) Cancel(r request) bool { if c.Requests == nil { return false } if _, ok := c.Requests[r]; !ok { return false } delete(c.Requests, r) c.Post(pp.Message{ Type: pp.Cancel, Index: r.Index, Begin: r.Begin, Length: r.Length, }) return true } // Returns true if an unsatisfied request was canceled. func (c *connection) PeerCancel(r request) bool { if c.PeerRequests == nil { return false } if _, ok := c.PeerRequests[r]; !ok { return false } delete(c.PeerRequests, r) return true } func (c *connection) Choke() { if c.Choked { return } c.Post(pp.Message{ Type: pp.Choke, }) c.Choked = true } func (c *connection) Unchoke() { if !c.Choked { return } c.Post(pp.Message{ Type: pp.Unchoke, }) c.Choked = false } func (c *connection) SetInterested(interested bool) { if c.Interested == interested { return } c.Post(pp.Message{ Type: func() pp.MessageType { if interested { return pp.Interested } else { return pp.NotInterested } }(), }) c.Interested = interested } var ( // Four consecutive zero bytes that comprise a keep alive on the wire. keepAliveBytes [4]byte ) // Writes buffers to the socket from the write channel. func (conn *connection) writer() { for { select { case b, ok := <-conn.writeCh: if !ok { return } _, err := conn.Socket.Write(b) if err != nil { conn.Close() return } case <-conn.closing: return } } } func (conn *connection) writeOptimizer(keepAliveDelay time.Duration) { defer close(conn.writeCh) // Responsible for notifying downstream routines. pending := list.New() // Message queue. var nextWrite []byte // Set to nil if we need to need to marshal the next message. timer := time.NewTimer(keepAliveDelay) defer timer.Stop() lastWrite := time.Now() for { write := conn.writeCh // Set to nil if there's nothing to write. if pending.Len() == 0 { write = nil } else if nextWrite == nil { var err error nextWrite, err = pending.Front().Value.(encoding.BinaryMarshaler).MarshalBinary() if err != nil { panic(err) } } event: select { case <-timer.C: if pending.Len() != 0 { break } keepAliveTime := lastWrite.Add(keepAliveDelay) if time.Now().Before(keepAliveTime) { timer.Reset(keepAliveTime.Sub(time.Now())) break } pending.PushBack(pp.Message{Keepalive: true}) case msg, ok := <-conn.post: if !ok { return } if msg.Type == pp.Cancel { for e := pending.Back(); e != nil; e = e.Prev() { elemMsg := e.Value.(pp.Message) if elemMsg.Type == pp.Request && msg.Index == elemMsg.Index && msg.Begin == elemMsg.Begin && msg.Length == elemMsg.Length { pending.Remove(e) optimizedCancels.Add(1) break event } } } pending.PushBack(msg) case write <- nextWrite: pending.Remove(pending.Front()) nextWrite = nil lastWrite = time.Now() if pending.Len() == 0 { timer.Reset(keepAliveDelay) } case <-conn.closing: return } } }