package torrent import ( "container/heap" "fmt" "io" "log" "net" "sort" "sync" "time" "github.com/anacrolix/missinggo" "github.com/bradfitz/iter" "github.com/anacrolix/torrent/bencode" "github.com/anacrolix/torrent/data" "github.com/anacrolix/torrent/metainfo" pp "github.com/anacrolix/torrent/peer_protocol" "github.com/anacrolix/torrent/tracker" "github.com/anacrolix/torrent/util" ) func (t *torrent) pieceNumPendingBytes(index int) (count pp.Integer) { if t.pieceComplete(index) { return 0 } piece := t.Pieces[index] pieceLength := t.pieceLength(index) if !piece.EverHashed { return pieceLength } for i, pending := range piece.PendingChunkSpecs { if pending { count += chunkIndexSpec(i, pieceLength, t.chunkSize).Length } } return } type peersKey struct { IPBytes string Port int } // Data maintains per-piece persistent state. type StatefulData interface { data.Data // We believe the piece data will pass a hash check. PieceCompleted(index int) error // Returns true if the piece is complete. PieceComplete(index int) bool } // Is not aware of Client. Maintains state of torrent for with-in a Client. type torrent struct { stateMu sync.Mutex closing chan struct{} // Closed when no more network activity is desired. This includes // announcing, and communicating with peers. ceasingNetworking chan struct{} InfoHash InfoHash Pieces []*piece chunkSize pp.Integer // Chunks that are wanted before all others. This is for // responsive/streaming readers that want to unblock ASAP. urgent map[request]struct{} // Total length of the torrent in bytes. Stored because it's not O(1) to // get this from the info dict. length int64 data StatefulData // The info dict. Nil if we don't have it (yet). Info *metainfo.Info // Active peer connections, running message stream loops. Conns []*connection // Set of addrs to which we're attempting to connect. Connections are // half-open until all handshakes are completed. HalfOpen map[string]struct{} // Reserve of peers to connect to. A peer can be both here and in the // active connections if were told about the peer after connecting with // them. That encourages us to reconnect to peers that are well known. Peers map[peersKey]Peer wantPeers sync.Cond // BEP 12 Multitracker Metadata Extension. The tracker.Client instances // mirror their respective URLs from the announce-list metainfo key. Trackers [][]tracker.Client // Name used if the info name isn't available. DisplayName string // The bencoded bytes of the info dict. MetaData []byte // Each element corresponds to the 16KiB metadata pieces. If true, we have // received that piece. metadataHave []bool // Closed when .Info is set. gotMetainfo chan struct{} } func (t *torrent) pieceComplete(piece int) bool { // TODO: This is called when setting metadata, and before storage is // assigned, which doesn't seem right. return t.data != nil && t.data.PieceComplete(piece) } func (t *torrent) numConnsUnchoked() (num int) { for _, c := range t.Conns { if !c.PeerChoked { num++ } } return } // There's a connection to that address already. func (t *torrent) addrActive(addr string) bool { if _, ok := t.HalfOpen[addr]; ok { return true } for _, c := range t.Conns { if c.remoteAddr().String() == addr { return true } } return false } func (t *torrent) worstConns(cl *Client) (wcs *worstConns) { wcs = &worstConns{ c: make([]*connection, 0, len(t.Conns)), t: t, cl: cl, } for _, c := range t.Conns { select { case <-c.closing: default: wcs.c = append(wcs.c, c) } } return } func (t *torrent) ceaseNetworking() { t.stateMu.Lock() defer t.stateMu.Unlock() select { case <-t.ceasingNetworking: return default: } close(t.ceasingNetworking) for _, c := range t.Conns { c.Close() } } func (t *torrent) addPeer(p Peer) { t.Peers[peersKey{string(p.IP), p.Port}] = p } func (t *torrent) invalidateMetadata() { t.MetaData = nil t.metadataHave = nil t.Info = nil } func (t *torrent) saveMetadataPiece(index int, data []byte) { if t.haveInfo() { return } if index >= len(t.metadataHave) { log.Printf("%s: ignoring metadata piece %d", t, index) return } copy(t.MetaData[(1<<14)*index:], data) t.metadataHave[index] = true } func (t *torrent) metadataPieceCount() int { return (len(t.MetaData) + (1 << 14) - 1) / (1 << 14) } func (t *torrent) haveMetadataPiece(piece int) bool { if t.haveInfo() { return (1<<14)*piece < len(t.MetaData) } else { return piece < len(t.metadataHave) && t.metadataHave[piece] } } func (t *torrent) metadataSizeKnown() bool { return t.MetaData != nil } func (t *torrent) metadataSize() int { return len(t.MetaData) } func infoPieceHashes(info *metainfo.Info) (ret []string) { for i := 0; i < len(info.Pieces); i += 20 { ret = append(ret, string(info.Pieces[i:i+20])) } return } // Called when metadata for a torrent becomes available. func (t *torrent) setMetadata(md *metainfo.Info, infoBytes []byte, eventLocker sync.Locker) (err error) { err = validateInfo(md) if err != nil { err = fmt.Errorf("bad info: %s", err) return } t.Info = md t.length = 0 for _, f := range t.Info.UpvertedFiles() { t.length += f.Length } t.MetaData = infoBytes t.metadataHave = nil for _, hash := range infoPieceHashes(md) { piece := &piece{} piece.Event.L = eventLocker util.CopyExact(piece.Hash[:], hash) t.Pieces = append(t.Pieces, piece) } for _, conn := range t.Conns { t.initRequestOrdering(conn) if err := conn.setNumPieces(t.numPieces()); err != nil { log.Printf("closing connection: %s", err) conn.Close() } } return } func (t *torrent) setStorage(td data.Data) (err error) { if c, ok := t.data.(io.Closer); ok { c.Close() } if sd, ok := td.(StatefulData); ok { t.data = sd } else { t.data = &statelessDataWrapper{td, make([]bool, t.Info.NumPieces())} } return } func (t *torrent) haveAllMetadataPieces() bool { if t.haveInfo() { return true } if t.metadataHave == nil { return false } for _, have := range t.metadataHave { if !have { return false } } return true } func (t *torrent) setMetadataSize(bytes int64, cl *Client) { if t.haveInfo() { // We already know the correct metadata size. return } if bytes <= 0 || bytes > 10000000 { // 10MB, pulled from my ass. log.Printf("received bad metadata size: %d", bytes) return } if t.MetaData != nil && len(t.MetaData) == int(bytes) { return } t.MetaData = make([]byte, bytes) t.metadataHave = make([]bool, (bytes+(1<<14)-1)/(1<<14)) for _, c := range t.Conns { cl.requestPendingMetadata(t, c) } } // The current working name for the torrent. Either the name in the info dict, // or a display name given such as by the dn value in a magnet link, or "". func (t *torrent) Name() string { if t.haveInfo() { return t.Info.Name } if t.DisplayName != "" { return t.DisplayName } return "" } func (t *torrent) pieceState(index int) (ret PieceState) { p := t.Pieces[index] ret.Priority = p.Priority if t.pieceComplete(index) { ret.Complete = true } if p.QueuedForHash || p.Hashing { ret.Checking = true } if !ret.Complete && t.piecePartiallyDownloaded(index) { ret.Partial = true } return } func (t *torrent) metadataPieceSize(piece int) int { return metadataPieceSize(len(t.MetaData), piece) } func (t *torrent) newMetadataExtensionMessage(c *connection, msgType int, piece int, data []byte) pp.Message { d := map[string]int{ "msg_type": msgType, "piece": piece, } if data != nil { d["total_size"] = len(t.MetaData) } p, err := bencode.Marshal(d) if err != nil { panic(err) } return pp.Message{ Type: pp.Extended, ExtendedID: byte(c.PeerExtensionIDs["ut_metadata"]), ExtendedPayload: append(p, data...), } } func (t *torrent) pieceStateRuns() (ret []PieceStateRun) { rle := missinggo.NewRunLengthEncoder(func(el interface{}, count uint64) { ret = append(ret, PieceStateRun{ PieceState: el.(PieceState), Length: int(count), }) }) for index := range t.Pieces { rle.Append(t.pieceState(index), 1) } rle.Flush() return } // Produces a small string representing a PieceStateRun. func pieceStateRunStatusChars(psr PieceStateRun) (ret string) { ret = fmt.Sprintf("%d", psr.Length) ret += func() string { switch psr.Priority { case PiecePriorityNext: return "N" case PiecePriorityNormal: return "." case PiecePriorityReadahead: return "R" case PiecePriorityNow: return "!" default: return "" } }() if psr.Checking { ret += "H" } if psr.Partial { ret += "P" } if psr.Complete { ret += "C" } return } func (t *torrent) writeStatus(w io.Writer, cl *Client) { fmt.Fprintf(w, "Infohash: %x\n", t.InfoHash) fmt.Fprintf(w, "Metadata length: %d\n", t.metadataSize()) if !t.haveInfo() { fmt.Fprintf(w, "Metadata have: ") for _, h := range t.metadataHave { fmt.Fprintf(w, "%c", func() rune { if h { return 'H' } else { return '.' } }()) } fmt.Fprintln(w) } fmt.Fprintf(w, "Piece length: %s\n", func() string { if t.haveInfo() { return fmt.Sprint(t.usualPieceSize()) } else { return "?" } }()) if t.haveInfo() { fmt.Fprint(w, "Pieces:") for _, psr := range t.pieceStateRuns() { w.Write([]byte(" ")) w.Write([]byte(pieceStateRunStatusChars(psr))) } fmt.Fprintln(w) } fmt.Fprintf(w, "Urgent:") for req := range t.urgent { fmt.Fprintf(w, " %v", req) } fmt.Fprintln(w) fmt.Fprintf(w, "Trackers: ") for _, tier := range t.Trackers { for _, tr := range tier { fmt.Fprintf(w, "%q ", tr.String()) } } fmt.Fprintf(w, "\n") fmt.Fprintf(w, "Pending peers: %d\n", len(t.Peers)) fmt.Fprintf(w, "Half open: %d\n", len(t.HalfOpen)) fmt.Fprintf(w, "Active peers: %d\n", len(t.Conns)) sort.Sort(&worstConns{ c: t.Conns, t: t, cl: cl, }) for i, c := range t.Conns { fmt.Fprintf(w, "%2d. ", i+1) c.WriteStatus(w, t) } } func (t *torrent) String() string { s := t.Name() if s == "" { s = fmt.Sprintf("%x", t.InfoHash) } return s } func (t *torrent) haveInfo() bool { return t != nil && t.Info != nil } // TODO: Include URIs that weren't converted to tracker clients. func (t *torrent) announceList() (al [][]string) { for _, tier := range t.Trackers { var l []string for _, tr := range tier { l = append(l, tr.URL()) } al = append(al, l) } return } // Returns a run-time generated MetaInfo that includes the info bytes and // announce-list as currently known to the client. func (t *torrent) MetaInfo() *metainfo.MetaInfo { if t.MetaData == nil { panic("info bytes not set") } return &metainfo.MetaInfo{ Info: metainfo.InfoEx{ Info: *t.Info, Bytes: t.MetaData, }, CreationDate: time.Now().Unix(), Comment: "dynamic metainfo from client", CreatedBy: "go.torrent", AnnounceList: t.announceList(), } } func (t *torrent) bytesLeft() (left int64) { if !t.haveInfo() { return -1 } for i := 0; i < t.numPieces(); i++ { left += int64(t.pieceNumPendingBytes(i)) } return } func (t *torrent) piecePartiallyDownloaded(index int) bool { pendingBytes := t.pieceNumPendingBytes(index) return pendingBytes != 0 && pendingBytes != t.pieceLength(index) } func numChunksForPiece(chunkSize int, pieceSize int) int { return (pieceSize + chunkSize - 1) / chunkSize } func (t *torrent) usualPieceSize() int { return int(t.Info.PieceLength) } func (t *torrent) lastPieceSize() int { return int(t.pieceLength(t.numPieces() - 1)) } func (t *torrent) numPieces() int { return t.Info.NumPieces() } func (t *torrent) numPiecesCompleted() (num int) { for i := range iter.N(t.Info.NumPieces()) { if t.pieceComplete(i) { num++ } } return } func (t *torrent) Length() int64 { return t.length } func (t *torrent) isClosed() bool { select { case <-t.closing: return true default: return false } } func (t *torrent) close() (err error) { if t.isClosed() { return } t.ceaseNetworking() close(t.closing) if c, ok := t.data.(io.Closer); ok { c.Close() } for _, conn := range t.Conns { conn.Close() } return } func (t *torrent) requestOffset(r request) int64 { return torrentRequestOffset(t.Length(), int64(t.usualPieceSize()), r) } // Return the request that would include the given offset into the torrent // data. Returns !ok if there is no such request. func (t *torrent) offsetRequest(off int64) (req request, ok bool) { return torrentOffsetRequest(t.Length(), t.Info.PieceLength, int64(t.chunkSize), off) } func (t *torrent) writeChunk(piece int, begin int64, data []byte) (err error) { n, err := t.data.WriteAt(data, int64(piece)*t.Info.PieceLength+begin) if err == nil && n != len(data) { err = io.ErrShortWrite } return } func (t *torrent) bitfield() (bf []bool) { for _, p := range t.Pieces { // TODO: Check this logic. bf = append(bf, p.EverHashed && p.numPendingChunks() == 0) } return } func (t *torrent) validOutgoingRequest(r request) bool { if r.Index >= pp.Integer(t.Info.NumPieces()) { return false } if r.Begin%t.chunkSize != 0 { return false } if r.Length > t.chunkSize { return false } pieceLength := t.pieceLength(int(r.Index)) if r.Begin+r.Length > pieceLength { return false } return r.Length == t.chunkSize || r.Begin+r.Length == pieceLength } func (t *torrent) pieceChunks(piece int) (css []chunkSpec) { css = make([]chunkSpec, 0, (t.pieceLength(piece)+t.chunkSize-1)/t.chunkSize) var cs chunkSpec for left := t.pieceLength(piece); left != 0; left -= cs.Length { cs.Length = left if cs.Length > t.chunkSize { cs.Length = t.chunkSize } css = append(css, cs) cs.Begin += cs.Length } return } func (t *torrent) pendAllChunkSpecs(pieceIndex int) { piece := t.Pieces[pieceIndex] if piece.PendingChunkSpecs == nil { // Allocate to exact size. piece.PendingChunkSpecs = make([]bool, (t.pieceLength(pieceIndex)+t.chunkSize-1)/t.chunkSize) } // Pend all the chunks. pcss := piece.PendingChunkSpecs for i := range pcss { pcss[i] = true } return } type Peer struct { Id [20]byte IP net.IP Port int Source peerSource // Peer is known to support encryption. SupportsEncryption bool } func (t *torrent) pieceLength(piece int) (len_ pp.Integer) { if int(piece) == t.numPieces()-1 { len_ = pp.Integer(t.Length() % t.Info.PieceLength) } if len_ == 0 { len_ = pp.Integer(t.Info.PieceLength) } return } func (t *torrent) hashPiece(piece pp.Integer) (ps pieceSum) { hash := pieceHash.New() p := t.Pieces[piece] p.pendingWrites.Wait() t.data.WriteSectionTo(hash, int64(piece)*t.Info.PieceLength, t.Info.PieceLength) util.CopyExact(ps[:], hash.Sum(nil)) return } func (t *torrent) haveAllPieces() bool { if !t.haveInfo() { return false } for i := range t.Pieces { if !t.pieceComplete(i) { return false } } return true } func (me *torrent) haveAnyPieces() bool { for i := range me.Pieces { if me.pieceComplete(i) { return true } } return false } func (t *torrent) havePiece(index int) bool { return t.haveInfo() && t.pieceComplete(index) } func (t *torrent) haveChunk(r request) bool { if !t.haveInfo() { return false } if t.pieceComplete(int(r.Index)) { return true } p := t.Pieces[r.Index] if p.PendingChunkSpecs == nil { return false } return !p.pendingChunk(r.chunkSpec, t.chunkSize) } func chunkIndex(cs chunkSpec, chunkSize pp.Integer) int { return int(cs.Begin / chunkSize) } // TODO: This should probably be called wantPiece. func (t *torrent) wantChunk(r request) bool { if !t.wantPiece(int(r.Index)) { return false } if t.Pieces[r.Index].pendingChunk(r.chunkSpec, t.chunkSize) { return true } _, ok := t.urgent[r] return ok } func (t *torrent) urgentChunkInPiece(piece int) bool { p := pp.Integer(piece) for req := range t.urgent { if req.Index == p { return true } } return false } // TODO: This should be called wantPieceIndex. func (t *torrent) wantPiece(index int) bool { if !t.haveInfo() { return false } p := t.Pieces[index] if p.QueuedForHash { return false } if p.Hashing { return false } if p.Priority == PiecePriorityNone { if !t.urgentChunkInPiece(index) { return false } } // Put piece complete check last, since it's the slowest as it can involve // calling out into external data stores. return !t.pieceComplete(index) } func (t *torrent) connHasWantedPieces(c *connection) bool { return c.pieceRequestOrder != nil && c.pieceRequestOrder.First() != nil } func (t *torrent) extentPieces(off, _len int64) (pieces []int) { for i := off / int64(t.usualPieceSize()); i*int64(t.usualPieceSize()) < off+_len; i++ { pieces = append(pieces, int(i)) } return } func (t *torrent) worstBadConn(cl *Client) *connection { wcs := t.worstConns(cl) heap.Init(wcs) // A connection can only be bad if it's in the worst half, rounded down. for wcs.Len() > (socketsPerTorrent+1)/2 { c := heap.Pop(wcs).(*connection) // Give connections 1 minute to prove themselves. if time.Since(c.completedHandshake) < time.Minute { continue } return c } return nil }