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torrent/client.go

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/*
Package torrent implements a torrent client.
Simple example:
c, _ := torrent.NewClient(&torrent.Config{})
defer c.Close()
t, _ := c.AddMagnet("magnet:?xt=urn:btih:ZOCMZQIPFFW7OLLMIC5HUB6BPCSDEOQU")
t.DownloadAll()
c.WaitAll()
log.Print("ermahgerd, torrent downloaded")
*/
package torrent
import (
"bufio"
"bytes"
"container/heap"
"crypto/rand"
"crypto/sha1"
"encoding/hex"
"errors"
"expvar"
"fmt"
"io"
"log"
"math/big"
mathRand "math/rand"
"net"
"net/url"
"os"
"path/filepath"
"sort"
"strconv"
"strings"
"syscall"
"time"
"github.com/anacrolix/libtorgo/bencode"
"github.com/anacrolix/libtorgo/metainfo"
"github.com/anacrolix/sync"
"github.com/anacrolix/utp"
"github.com/bradfitz/iter"
"github.com/anacrolix/torrent/data"
filePkg "github.com/anacrolix/torrent/data/file"
"github.com/anacrolix/torrent/dht"
"github.com/anacrolix/torrent/internal/pieceordering"
"github.com/anacrolix/torrent/iplist"
"github.com/anacrolix/torrent/logonce"
"github.com/anacrolix/torrent/mse"
pp "github.com/anacrolix/torrent/peer_protocol"
"github.com/anacrolix/torrent/tracker"
. "github.com/anacrolix/torrent/util"
)
var (
unusedDownloadedChunksCount = expvar.NewInt("unusedDownloadedChunksCount")
chunksDownloadedCount = expvar.NewInt("chunksDownloadedCount")
peersFoundByDHT = expvar.NewInt("peersFoundByDHT")
peersFoundByPEX = expvar.NewInt("peersFoundByPEX")
peersFoundByTracker = expvar.NewInt("peersFoundByTracker")
uploadChunksPosted = expvar.NewInt("uploadChunksPosted")
unexpectedCancels = expvar.NewInt("unexpectedCancels")
postedCancels = expvar.NewInt("postedCancels")
duplicateConnsAvoided = expvar.NewInt("duplicateConnsAvoided")
failedPieceHashes = expvar.NewInt("failedPieceHashes")
unsuccessfulDials = expvar.NewInt("unsuccessfulDials")
successfulDials = expvar.NewInt("successfulDials")
acceptedConns = expvar.NewInt("acceptedConns")
inboundConnsBlocked = expvar.NewInt("inboundConnsBlocked")
peerExtensions = expvar.NewMap("peerExtensions")
// Count of connections to peer with same client ID.
connsToSelf = expvar.NewInt("connsToSelf")
// Number of completed connections to a client we're already connected with.
duplicateClientConns = expvar.NewInt("duplicateClientConns")
receivedMessageTypes = expvar.NewMap("receivedMessageTypes")
supportedExtensionMessages = expvar.NewMap("supportedExtensionMessages")
)
const (
// Justification for set bits follows.
//
// Extension protocol: http://www.bittorrent.org/beps/bep_0010.html ([5]|=0x10)
// DHT: http://www.bittorrent.org/beps/bep_0005.html ([7]|=1)
// Fast Extension:
// http://bittorrent.org/beps/bep_0006.html ([7]|=4)
// Disabled until AllowedFast is implemented
defaultExtensionBytes = "\x00\x00\x00\x00\x00\x10\x00\x01"
socketsPerTorrent = 40
torrentPeersHighWater = 200
torrentPeersLowWater = 50
// Limit how long handshake can take. This is to reduce the lingering
// impact of a few bad apples. 4s loses 1% of successful handshakes that
// are obtained with 60s timeout, and 5% of unsuccessful handshakes.
btHandshakeTimeout = 4 * time.Second
handshakesTimeout = 20 * time.Second
pruneInterval = 10 * time.Second
metadataExtendedId = iota + 1 // 0 is reserved for deleting keys
pexExtendedId
extendedHandshakeClientVersion = "go.torrent dev 20140825"
)
// Currently doesn't really queue, but should in the future.
func (cl *Client) queuePieceCheck(t *torrent, pieceIndex pp.Integer) {
piece := t.Pieces[pieceIndex]
if piece.QueuedForHash {
return
}
piece.QueuedForHash = true
go cl.verifyPiece(t, pieceIndex)
}
// Queue a piece check if one isn't already queued, and the piece has never
// been checked before.
func (cl *Client) queueFirstHash(t *torrent, piece int) {
p := t.Pieces[piece]
if p.EverHashed || p.Hashing || p.QueuedForHash || t.pieceComplete(piece) {
return
}
cl.queuePieceCheck(t, pp.Integer(piece))
}
type Client struct {
noUpload bool
dataDir string
halfOpenLimit int
peerID [20]byte
listeners []net.Listener
utpSock *utp.Socket
disableTrackers bool
dHT *dht.Server
disableUTP bool
disableTCP bool
ipBlockList *iplist.IPList
bannedTorrents map[InfoHash]struct{}
_configDir string
config Config
pruneTimer *time.Timer
extensionBytes peerExtensionBytes
// Set of addresses that have our client ID. This intentionally will
// include ourselves if we end up trying to connect to our own address
// through legitimate channels.
dopplegangerAddrs map[string]struct{}
torrentDataOpener TorrentDataOpener
mu sync.RWMutex
event sync.Cond
quit chan struct{}
torrents map[InfoHash]*torrent
}
func (me *Client) IPBlockList() *iplist.IPList {
me.mu.Lock()
defer me.mu.Unlock()
return me.ipBlockList
}
func (me *Client) SetIPBlockList(list *iplist.IPList) {
me.mu.Lock()
defer me.mu.Unlock()
me.ipBlockList = list
if me.dHT != nil {
me.dHT.SetIPBlockList(list)
}
}
func (me *Client) PeerID() string {
return string(me.peerID[:])
}
func (me *Client) ListenAddr() (addr net.Addr) {
for _, l := range me.listeners {
if addr != nil && l.Addr().String() != addr.String() {
panic("listeners exist on different addresses")
}
addr = l.Addr()
}
return
}
type hashSorter struct {
Hashes []InfoHash
}
func (me hashSorter) Len() int {
return len(me.Hashes)
}
func (me hashSorter) Less(a, b int) bool {
return (&big.Int{}).SetBytes(me.Hashes[a][:]).Cmp((&big.Int{}).SetBytes(me.Hashes[b][:])) < 0
}
func (me hashSorter) Swap(a, b int) {
me.Hashes[a], me.Hashes[b] = me.Hashes[b], me.Hashes[a]
}
func (cl *Client) sortedTorrents() (ret []*torrent) {
var hs hashSorter
for ih := range cl.torrents {
hs.Hashes = append(hs.Hashes, ih)
}
sort.Sort(hs)
for _, ih := range hs.Hashes {
ret = append(ret, cl.torrent(ih))
}
return
}
// Writes out a human readable status of the client, such as for writing to a
// HTTP status page.
func (cl *Client) WriteStatus(_w io.Writer) {
cl.mu.RLock()
defer cl.mu.RUnlock()
w := bufio.NewWriter(_w)
defer w.Flush()
if addr := cl.ListenAddr(); addr != nil {
fmt.Fprintf(w, "Listening on %s\n", cl.ListenAddr())
} else {
fmt.Fprintln(w, "Not listening!")
}
fmt.Fprintf(w, "Peer ID: %q\n", cl.peerID)
if cl.dHT != nil {
dhtStats := cl.dHT.Stats()
fmt.Fprintf(w, "DHT nodes: %d (%d good)\n", dhtStats.NumNodes, dhtStats.NumGoodNodes)
fmt.Fprintf(w, "DHT Server ID: %x\n", cl.dHT.IDString())
fmt.Fprintf(w, "DHT port: %d\n", addrPort(cl.dHT.LocalAddr()))
fmt.Fprintf(w, "DHT announces: %d\n", cl.dHT.NumConfirmedAnnounces)
fmt.Fprintf(w, "Outstanding transactions: %d\n", dhtStats.NumOutstandingTransactions)
}
fmt.Fprintln(w)
for _, t := range cl.sortedTorrents() {
if t.Name() == "" {
fmt.Fprint(w, "<unknown name>")
} else {
fmt.Fprint(w, t.Name())
}
fmt.Fprint(w, "\n")
if t.haveInfo() {
fmt.Fprintf(w, "%f%% of %d bytes", 100*(1-float32(t.bytesLeft())/float32(t.Length())), t.Length())
} else {
w.WriteString("<missing metainfo>")
}
fmt.Fprint(w, "\n")
t.writeStatus(w)
fmt.Fprintln(w)
}
}
// Read torrent data at the given offset. Will block until it is available.
func (cl *Client) torrentReadAt(t *torrent, off int64, p []byte) (n int, err error) {
cl.mu.Lock()
defer cl.mu.Unlock()
index := int(off / int64(t.usualPieceSize()))
// Reading outside the bounds of a file is an error.
if index < 0 {
err = os.ErrInvalid
return
}
if int(index) >= len(t.Pieces) {
err = io.EOF
return
}
pieceOff := pp.Integer(off % int64(t.usualPieceSize()))
pieceLeft := int(t.pieceLength(index) - pieceOff)
if pieceLeft <= 0 {
err = io.EOF
return
}
if len(p) > pieceLeft {
p = p[:pieceLeft]
}
if len(p) == 0 {
panic(len(p))
}
// TODO: ReadAt should always try to fill the buffer.
for {
avail := cl.prepareRead(t, off)
if avail < int64(len(p)) {
p = p[:avail]
}
n, err = dataReadAt(t.data, p, off)
if n != 0 || err != io.ErrUnexpectedEOF {
break
}
// If we reach here, the data we thought was ready, isn't. So we
// prepare it again, and retry.
}
return
}
// Sets priorities to download from the given offset. Returns when the piece
// at the given offset can be read. Returns the number of bytes that are
// immediately available from the offset.
func (cl *Client) prepareRead(t *torrent, off int64) (n int64) {
index := int(off / int64(t.usualPieceSize()))
// Reading outside the bounds of a file is an error.
if index < 0 || index >= t.numPieces() {
return
}
piece := t.Pieces[index]
cl.readRaisePiecePriorities(t, off)
for !t.pieceComplete(index) && !t.isClosed() {
// This is to prevent being starved if a piece is dropped before we
// can read it.
cl.readRaisePiecePriorities(t, off)
piece.Event.Wait()
}
return t.Info.Piece(index).Length() - off%t.Info.PieceLength
}
func (T Torrent) prepareRead(off int64) (avail int64) {
T.cl.mu.Lock()
defer T.cl.mu.Unlock()
return T.cl.prepareRead(T.torrent, off)
}
// Data implements a streaming interface that's more efficient than ReadAt.
type SectionOpener interface {
OpenSection(off, n int64) (io.ReadCloser, error)
}
func dataReadAt(d data.Data, b []byte, off int64) (n int, err error) {
again:
if ra, ok := d.(io.ReaderAt); ok {
return ra.ReadAt(b, off)
}
if so, ok := d.(SectionOpener); ok {
var rc io.ReadCloser
rc, err = so.OpenSection(off, int64(len(b)))
if err != nil {
return
}
defer rc.Close()
return io.ReadFull(rc, b)
}
if dp, ok := super(d); ok {
d = dp.(data.Data)
goto again
}
panic(fmt.Sprintf("can't read from %T", d))
}
// Calculates the number of pieces to set to Readahead priority, after the
// Now, and Next pieces.
func readaheadPieces(readahead, pieceLength int64) int {
return int((readahead+pieceLength-1)/pieceLength - 1)
}
func (cl *Client) readRaisePiecePriorities(t *torrent, off int64) {
index := int(off / int64(t.usualPieceSize()))
cl.raisePiecePriority(t, index, piecePriorityNow)
index++
if index >= t.numPieces() {
return
}
cl.raisePiecePriority(t, index, piecePriorityNext)
for range iter.N(readaheadPieces(5*1024*1024, t.Info.PieceLength)) {
index++
if index >= t.numPieces() {
break
}
cl.raisePiecePriority(t, index, piecePriorityReadahead)
}
}
func (cl *Client) configDir() string {
if cl._configDir == "" {
return filepath.Join(os.Getenv("HOME"), ".config/torrent")
}
return cl._configDir
}
func (cl *Client) ConfigDir() string {
return cl.configDir()
}
func (t *torrent) connPendPiece(c *connection, piece int) {
c.pendPiece(piece, t.Pieces[piece].Priority)
}
func (cl *Client) raisePiecePriority(t *torrent, piece int, priority piecePriority) {
if t.Pieces[piece].Priority < priority {
cl.event.Broadcast()
cl.prioritizePiece(t, piece, priority)
}
}
func (cl *Client) prioritizePiece(t *torrent, piece int, priority piecePriority) {
if t.havePiece(piece) {
return
}
cl.queueFirstHash(t, piece)
t.Pieces[piece].Priority = priority
cl.pieceChanged(t, piece)
}
func (cl *Client) setEnvBlocklist() (err error) {
filename := os.Getenv("TORRENT_BLOCKLIST_FILE")
defaultBlocklist := filename == ""
if defaultBlocklist {
filename = filepath.Join(cl.configDir(), "blocklist")
}
f, err := os.Open(filename)
if err != nil {
if defaultBlocklist {
err = nil
}
return
}
defer f.Close()
var ranges []iplist.Range
uniqStrs := make(map[string]string)
scanner := bufio.NewScanner(f)
lineNum := 1
for scanner.Scan() {
r, ok, lineErr := iplist.ParseBlocklistP2PLine(scanner.Bytes())
if lineErr != nil {
err = fmt.Errorf("error reading torrent blocklist line %d: %s", lineNum, lineErr)
return
}
lineNum++
if !ok {
continue
}
if s, ok := uniqStrs[r.Description]; ok {
r.Description = s
} else {
uniqStrs[r.Description] = r.Description
}
ranges = append(ranges, r)
}
err = scanner.Err()
if err != nil {
err = fmt.Errorf("error reading torrent blocklist: %s", err)
return
}
cl.ipBlockList = iplist.New(ranges)
return
}
func (cl *Client) initBannedTorrents() error {
f, err := os.Open(filepath.Join(cl.configDir(), "banned_infohashes"))
if err != nil {
if os.IsNotExist(err) {
return nil
}
return fmt.Errorf("error opening banned infohashes file: %s", err)
}
defer f.Close()
scanner := bufio.NewScanner(f)
cl.bannedTorrents = make(map[InfoHash]struct{})
for scanner.Scan() {
if strings.HasPrefix(strings.TrimSpace(scanner.Text()), "#") {
continue
}
var ihs string
n, err := fmt.Sscanf(scanner.Text(), "%x", &ihs)
if err != nil {
return fmt.Errorf("error reading infohash: %s", err)
}
if n != 1 {
continue
}
if len(ihs) != 20 {
return errors.New("bad infohash")
}
var ih InfoHash
CopyExact(&ih, ihs)
cl.bannedTorrents[ih] = struct{}{}
}
if err := scanner.Err(); err != nil {
return fmt.Errorf("error scanning file: %s", err)
}
return nil
}
// Creates a new client. Clients contain zero or more Torrents.
func NewClient(cfg *Config) (cl *Client, err error) {
if cfg == nil {
cfg = &Config{}
}
cl = &Client{
noUpload: cfg.NoUpload,
disableTrackers: cfg.DisableTrackers,
halfOpenLimit: socketsPerTorrent,
dataDir: cfg.DataDir,
disableUTP: cfg.DisableUTP,
disableTCP: cfg.DisableTCP,
_configDir: cfg.ConfigDir,
config: *cfg,
torrentDataOpener: func(md *metainfo.Info) data.Data {
return filePkg.TorrentData(md, cfg.DataDir)
},
dopplegangerAddrs: make(map[string]struct{}),
quit: make(chan struct{}),
torrents: make(map[InfoHash]*torrent),
}
CopyExact(&cl.extensionBytes, defaultExtensionBytes)
cl.event.L = &cl.mu
if cfg.TorrentDataOpener != nil {
cl.torrentDataOpener = cfg.TorrentDataOpener
}
if !cfg.NoDefaultBlocklist {
err = cl.setEnvBlocklist()
if err != nil {
return
}
}
if err = cl.initBannedTorrents(); err != nil {
err = fmt.Errorf("error initing banned torrents: %s", err)
return
}
if cfg.PeerID != "" {
CopyExact(&cl.peerID, cfg.PeerID)
} else {
o := copy(cl.peerID[:], bep20)
_, err = rand.Read(cl.peerID[o:])
if err != nil {
panic("error generating peer id")
}
}
// Returns the laddr string to listen on for the next Listen call.
listenAddr := func() string {
if addr := cl.ListenAddr(); addr != nil {
return addr.String()
}
if cfg.ListenAddr == "" {
// IPv6 isn't well supported with blocklists, or with trackers and
// DHT.
return "0.0.0.0:50007"
}
return cfg.ListenAddr
}
if !cl.disableTCP {
var l net.Listener
l, err = net.Listen("tcp", listenAddr())
if err != nil {
return
}
cl.listeners = append(cl.listeners, l)
go cl.acceptConnections(l, false)
}
if !cl.disableUTP {
cl.utpSock, err = utp.NewSocket(listenAddr())
if err != nil {
return
}
cl.listeners = append(cl.listeners, cl.utpSock)
go cl.acceptConnections(cl.utpSock, true)
}
if !cfg.NoDHT {
dhtCfg := cfg.DHTConfig
if dhtCfg == nil {
dhtCfg = &dht.ServerConfig{}
}
if dhtCfg.Addr == "" {
dhtCfg.Addr = listenAddr()
}
if dhtCfg.Conn == nil && cl.utpSock != nil {
dhtCfg.Conn = cl.utpSock.PacketConn()
}
cl.dHT, err = dht.NewServer(dhtCfg)
if cl.ipBlockList != nil {
cl.dHT.SetIPBlockList(cl.ipBlockList)
}
if err != nil {
return
}
}
return
}
func (cl *Client) stopped() bool {
select {
case <-cl.quit:
return true
default:
return false
}
}
// Stops the client. All connections to peers are closed and all activity will
// come to a halt.
func (me *Client) Close() {
me.mu.Lock()
defer me.mu.Unlock()
close(me.quit)
for _, l := range me.listeners {
l.Close()
}
me.event.Broadcast()
for _, t := range me.torrents {
t.close()
}
}
var ipv6BlockRange = iplist.Range{Description: "non-IPv4 address"}
func (cl *Client) ipBlockRange(ip net.IP) (r *iplist.Range) {
if cl.ipBlockList == nil {
return
}
ip = ip.To4()
if ip == nil {
log.Printf("saw non-IPv4 address")
r = &ipv6BlockRange
return
}
r = cl.ipBlockList.Lookup(ip)
return
}
func (cl *Client) waitAccept() {
cl.mu.Lock()
defer cl.mu.Unlock()
for {
for _, t := range cl.torrents {
if cl.wantConns(t) {
return
}
}
cl.event.Wait()
}
}
func (cl *Client) acceptConnections(l net.Listener, utp bool) {
for {
cl.waitAccept()
// We accept all connections immediately, because we don't know what
// torrent they're for.
conn, err := l.Accept()
select {
case <-cl.quit:
if conn != nil {
conn.Close()
}
return
default:
}
if err != nil {
log.Print(err)
return
}
acceptedConns.Add(1)
cl.mu.RLock()
doppleganger := cl.dopplegangerAddr(conn.RemoteAddr().String())
blockRange := cl.ipBlockRange(AddrIP(conn.RemoteAddr()))
cl.mu.RUnlock()
if blockRange != nil || doppleganger {
inboundConnsBlocked.Add(1)
// log.Printf("inbound connection from %s blocked by %s", conn.RemoteAddr(), blockRange)
conn.Close()
continue
}
go cl.incomingConnection(conn, utp)
}
}
func (cl *Client) incomingConnection(nc net.Conn, utp bool) {
defer nc.Close()
if tc, ok := nc.(*net.TCPConn); ok {
tc.SetLinger(0)
}
c := newConnection()
c.conn = nc
c.rw = nc
c.Discovery = peerSourceIncoming
c.uTP = utp
err := cl.runReceivedConn(c)
if err != nil {
// log.Print(err)
}
}
// Returns a handle to the given torrent, if it's present in the client.
func (cl *Client) Torrent(ih InfoHash) (T Torrent, ok bool) {
cl.mu.Lock()
defer cl.mu.Unlock()
t, ok := cl.torrents[ih]
if !ok {
return
}
T = Torrent{cl, t}
return
}
func (me *Client) torrent(ih InfoHash) *torrent {
return me.torrents[ih]
}
type dialResult struct {
Conn net.Conn
UTP bool
}
func doDial(dial func(addr string, t *torrent) (net.Conn, error), ch chan dialResult, utp bool, addr string, t *torrent) {
conn, err := dial(addr, t)
if err != nil {
if conn != nil {
conn.Close()
}
conn = nil // Pedantic
}
ch <- dialResult{conn, utp}
if err == nil {
successfulDials.Add(1)
return
}
unsuccessfulDials.Add(1)
if netErr, ok := err.(net.Error); ok && netErr.Timeout() {
return
}
if netOpErr, ok := err.(*net.OpError); ok {
switch netOpErr.Err {
case syscall.ECONNREFUSED, syscall.EHOSTUNREACH:
return
}
}
if err != nil {
log.Printf("error dialing %s: %s", addr, err)
return
}
}
func reducedDialTimeout(max time.Duration, halfOpenLimit int, pendingPeers int) (ret time.Duration) {
ret = max / time.Duration((pendingPeers+halfOpenLimit)/halfOpenLimit)
if ret < minDialTimeout {
ret = minDialTimeout
}
return
}
func (me *Client) dopplegangerAddr(addr string) bool {
_, ok := me.dopplegangerAddrs[addr]
return ok
}
// Start the process of connecting to the given peer for the given torrent if
// appropriate.
func (me *Client) initiateConn(peer Peer, t *torrent) {
if peer.Id == me.peerID {
return
}
addr := net.JoinHostPort(peer.IP.String(), fmt.Sprintf("%d", peer.Port))
if me.dopplegangerAddr(addr) || t.addrActive(addr) {
duplicateConnsAvoided.Add(1)
return
}
if r := me.ipBlockRange(peer.IP); r != nil {
log.Printf("outbound connect to %s blocked by IP blocklist rule %s", peer.IP, r)
return
}
t.HalfOpen[addr] = struct{}{}
go me.outgoingConnection(t, addr, peer.Source)
}
func (me *Client) dialTimeout(t *torrent) time.Duration {
return reducedDialTimeout(nominalDialTimeout, me.halfOpenLimit, len(t.Peers))
}
func (me *Client) dialTCP(addr string, t *torrent) (c net.Conn, err error) {
c, err = net.DialTimeout("tcp", addr, me.dialTimeout(t))
if err == nil {
c.(*net.TCPConn).SetLinger(0)
}
return
}
func (me *Client) dialUTP(addr string, t *torrent) (c net.Conn, err error) {
return me.utpSock.DialTimeout(addr, me.dialTimeout(t))
}
// Returns a connection over UTP or TCP.
func (me *Client) dial(addr string, t *torrent) (conn net.Conn, utp bool) {
// Initiate connections via TCP and UTP simultaneously. Use the first one
// that succeeds.
left := 0
if !me.disableUTP {
left++
}
if !me.disableTCP {
left++
}
resCh := make(chan dialResult, left)
if !me.disableUTP {
go doDial(me.dialUTP, resCh, true, addr, t)
}
if !me.disableTCP {
go doDial(me.dialTCP, resCh, false, addr, t)
}
var res dialResult
// Wait for a successful connection.
for ; left > 0 && res.Conn == nil; left-- {
res = <-resCh
}
if left > 0 {
// There are still incompleted dials.
go func() {
for ; left > 0; left-- {
conn := (<-resCh).Conn
if conn != nil {
conn.Close()
}
}
}()
}
conn = res.Conn
utp = res.UTP
return
}
func (me *Client) noLongerHalfOpen(t *torrent, addr string) {
if _, ok := t.HalfOpen[addr]; !ok {
panic("invariant broken")
}
delete(t.HalfOpen, addr)
me.openNewConns(t)
}
// Returns nil connection and nil error if no connection could be established
// for valid reasons.
func (me *Client) establishOutgoingConn(t *torrent, addr string) (c *connection, err error) {
handshakesConnection := func(nc net.Conn, encrypted, utp bool) (c *connection, err error) {
c = newConnection()
c.conn = nc
c.rw = nc
c.encrypted = encrypted
c.uTP = utp
err = nc.SetDeadline(time.Now().Add(handshakesTimeout))
if err != nil {
return
}
ok, err := me.initiateHandshakes(c, t)
if !ok {
c = nil
}
return
}
nc, utp := me.dial(addr, t)
if nc == nil {
return
}
c, err = handshakesConnection(nc, true, utp)
if err != nil {
nc.Close()
return
} else if c != nil {
return
}
nc.Close()
if utp {
nc, err = me.dialUTP(addr, t)
} else {
nc, err = me.dialTCP(addr, t)
}
if err != nil {
err = fmt.Errorf("error dialing for unencrypted connection: %s", err)
return
}
c, err = handshakesConnection(nc, false, utp)
if err != nil {
nc.Close()
}
return
}
// Called to dial out and run a connection. The addr we're given is already
// considered half-open.
func (me *Client) outgoingConnection(t *torrent, addr string, ps peerSource) {
c, err := me.establishOutgoingConn(t, addr)
me.mu.Lock()
defer me.mu.Unlock()
// Don't release lock between here and addConnection, unless it's for
// failure.
me.noLongerHalfOpen(t, addr)
if err != nil {
return
}
if c == nil {
return
}
defer c.Close()
c.Discovery = ps
err = me.runInitiatedHandshookConn(c, t)
if err != nil {
// log.Print(err)
}
}
// The port number for incoming peer connections. 0 if the client isn't
// listening.
func (cl *Client) incomingPeerPort() int {
listenAddr := cl.ListenAddr()
if listenAddr == nil {
return 0
}
return addrPort(listenAddr)
}
// Convert a net.Addr to its compact IP representation. Either 4 or 16 bytes
// per "yourip" field of http://www.bittorrent.org/beps/bep_0010.html.
func addrCompactIP(addr net.Addr) (string, error) {
host, _, err := net.SplitHostPort(addr.String())
if err != nil {
return "", err
}
ip := net.ParseIP(host)
if v4 := ip.To4(); v4 != nil {
if len(v4) != 4 {
panic(v4)
}
return string(v4), nil
}
return string(ip.To16()), nil
}
func handshakeWriter(w io.Writer, bb <-chan []byte, done chan<- error) {
var err error
for b := range bb {
_, err = w.Write(b)
if err != nil {
break
}
}
done <- err
}
type (
peerExtensionBytes [8]byte
peerID [20]byte
)
func (me *peerExtensionBytes) SupportsExtended() bool {
return me[5]&0x10 != 0
}
func (me *peerExtensionBytes) SupportsDHT() bool {
return me[7]&0x01 != 0
}
func (me *peerExtensionBytes) SupportsFast() bool {
return me[7]&0x04 != 0
}
type handshakeResult struct {
peerExtensionBytes
peerID
InfoHash
}
// ih is nil if we expect the peer to declare the InfoHash, such as when the
// peer initiated the connection. Returns ok if the handshake was successful,
// and err if there was an unexpected condition other than the peer simply
// abandoning the handshake.
func handshake(sock io.ReadWriter, ih *InfoHash, peerID [20]byte, extensions peerExtensionBytes) (res handshakeResult, ok bool, err error) {
// Bytes to be sent to the peer. Should never block the sender.
postCh := make(chan []byte, 4)
// A single error value sent when the writer completes.
writeDone := make(chan error, 1)
// Performs writes to the socket and ensures posts don't block.
go handshakeWriter(sock, postCh, writeDone)
defer func() {
close(postCh) // Done writing.
if !ok {
return
}
if err != nil {
panic(err)
}
// Wait until writes complete before returning from handshake.
err = <-writeDone
if err != nil {
err = fmt.Errorf("error writing: %s", err)
}
}()
post := func(bb []byte) {
select {
case postCh <- bb:
default:
panic("mustn't block while posting")
}
}
post([]byte(pp.Protocol))
post(extensions[:])
if ih != nil { // We already know what we want.
post(ih[:])
post(peerID[:])
}
var b [68]byte
_, err = io.ReadFull(sock, b[:68])
if err != nil {
err = nil
return
}
if string(b[:20]) != pp.Protocol {
return
}
CopyExact(&res.peerExtensionBytes, b[20:28])
CopyExact(&res.InfoHash, b[28:48])
CopyExact(&res.peerID, b[48:68])
peerExtensions.Add(hex.EncodeToString(res.peerExtensionBytes[:]), 1)
// TODO: Maybe we can just drop peers here if we're not interested. This
// could prevent them trying to reconnect, falsely believing there was
// just a problem.
if ih == nil { // We were waiting for the peer to tell us what they wanted.
post(res.InfoHash[:])
post(peerID[:])
}
ok = true
return
}
// Wraps a raw connection and provides the interface we want for using the
// connection in the message loop.
type deadlineReader struct {
nc net.Conn
r io.Reader
}
func (me deadlineReader) Read(b []byte) (n int, err error) {
// Keep-alives should be received every 2 mins. Give a bit of gracetime.
err = me.nc.SetReadDeadline(time.Now().Add(150 * time.Second))
if err != nil {
err = fmt.Errorf("error setting read deadline: %s", err)
}
n, err = me.r.Read(b)
// Convert common errors into io.EOF.
// if err != nil {
// if opError, ok := err.(*net.OpError); ok && opError.Op == "read" && opError.Err == syscall.ECONNRESET {
// err = io.EOF
// } else if netErr, ok := err.(net.Error); ok && netErr.Timeout() {
// if n != 0 {
// panic(n)
// }
// err = io.EOF
// }
// }
return
}
type readWriter struct {
io.Reader
io.Writer
}
func maybeReceiveEncryptedHandshake(rw io.ReadWriter, skeys [][]byte) (ret io.ReadWriter, encrypted bool, err error) {
var protocol [len(pp.Protocol)]byte
_, err = io.ReadFull(rw, protocol[:])
if err != nil {
return
}
ret = readWriter{
io.MultiReader(bytes.NewReader(protocol[:]), rw),
rw,
}
if string(protocol[:]) == pp.Protocol {
return
}
encrypted = true
ret, err = mse.ReceiveHandshake(ret, skeys)
return
}
func (cl *Client) receiveSkeys() (ret [][]byte) {
for ih := range cl.torrents {
ret = append(ret, ih[:])
}
return
}
func (me *Client) initiateHandshakes(c *connection, t *torrent) (ok bool, err error) {
if c.encrypted {
c.rw, err = mse.InitiateHandshake(c.rw, t.InfoHash[:], nil)
if err != nil {
return
}
}
ih, ok, err := me.connBTHandshake(c, &t.InfoHash)
if ih != t.InfoHash {
ok = false
}
return
}
// Do encryption and bittorrent handshakes as receiver.
func (cl *Client) receiveHandshakes(c *connection) (t *torrent, err error) {
cl.mu.Lock()
skeys := cl.receiveSkeys()
cl.mu.Unlock()
c.rw, c.encrypted, err = maybeReceiveEncryptedHandshake(c.rw, skeys)
if err != nil {
if err == mse.ErrNoSecretKeyMatch {
err = nil
}
return
}
ih, ok, err := cl.connBTHandshake(c, nil)
if err != nil {
fmt.Errorf("error during bt handshake: %s", err)
return
}
if !ok {
return
}
cl.mu.Lock()
t = cl.torrents[ih]
cl.mu.Unlock()
return
}
// Returns !ok if handshake failed for valid reasons.
func (cl *Client) connBTHandshake(c *connection, ih *InfoHash) (ret InfoHash, ok bool, err error) {
res, ok, err := handshake(c.rw, ih, cl.peerID, cl.extensionBytes)
if err != nil || !ok {
return
}
ret = res.InfoHash
c.PeerExtensionBytes = res.peerExtensionBytes
c.PeerID = res.peerID
c.completedHandshake = time.Now()
return
}
func (cl *Client) runInitiatedHandshookConn(c *connection, t *torrent) (err error) {
if c.PeerID == cl.peerID {
// Only if we initiated the connection is the remote address a
// listen addr for a doppleganger.
connsToSelf.Add(1)
addr := c.conn.RemoteAddr().String()
cl.dopplegangerAddrs[addr] = struct{}{}
return
}
return cl.runHandshookConn(c, t)
}
func (cl *Client) runReceivedConn(c *connection) (err error) {
err = c.conn.SetDeadline(time.Now().Add(handshakesTimeout))
if err != nil {
return
}
t, err := cl.receiveHandshakes(c)
if err != nil {
err = fmt.Errorf("error receiving handshakes: %s", err)
return
}
if t == nil {
return
}
cl.mu.Lock()
defer cl.mu.Unlock()
if c.PeerID == cl.peerID {
return
}
return cl.runHandshookConn(c, t)
}
func (cl *Client) runHandshookConn(c *connection, t *torrent) (err error) {
c.conn.SetWriteDeadline(time.Time{})
c.rw = readWriter{
deadlineReader{c.conn, c.rw},
c.rw,
}
if !cl.addConnection(t, c) {
return
}
defer cl.dropConnection(t, c)
go c.writer()
go c.writeOptimizer(time.Minute)
cl.sendInitialMessages(c, t)
if t.haveInfo() {
t.initRequestOrdering(c)
}
err = cl.connectionLoop(t, c)
if err != nil {
err = fmt.Errorf("error during connection loop: %s", err)
}
return
}
func (me *Client) sendInitialMessages(conn *connection, torrent *torrent) {
if conn.PeerExtensionBytes.SupportsExtended() && me.extensionBytes.SupportsExtended() {
conn.Post(pp.Message{
Type: pp.Extended,
ExtendedID: pp.HandshakeExtendedID,
ExtendedPayload: func() []byte {
d := map[string]interface{}{
"m": func() (ret map[string]int) {
ret = make(map[string]int, 2)
ret["ut_metadata"] = metadataExtendedId
if !me.config.DisablePEX {
ret["ut_pex"] = pexExtendedId
}
return
}(),
"v": extendedHandshakeClientVersion,
// No upload queue is implemented yet.
"reqq": func() int {
if me.noUpload {
// No need to look strange if it costs us nothing.
return 250
} else {
return 1
}
}(),
"e": 1, // Awwww yeah
}
if torrent.metadataSizeKnown() {
d["metadata_size"] = torrent.metadataSize()
}
if p := me.incomingPeerPort(); p != 0 {
d["p"] = p
}
yourip, err := addrCompactIP(conn.remoteAddr())
if err != nil {
log.Printf("error calculating yourip field value in extension handshake: %s", err)
} else {
d["yourip"] = yourip
}
// log.Printf("sending %v", d)
b, err := bencode.Marshal(d)
if err != nil {
panic(err)
}
return b
}(),
})
}
if torrent.haveAnyPieces() {
conn.Post(pp.Message{
Type: pp.Bitfield,
Bitfield: torrent.bitfield(),
})
} else if me.extensionBytes.SupportsFast() && conn.PeerExtensionBytes.SupportsFast() {
conn.Post(pp.Message{
Type: pp.HaveNone,
})
}
if conn.PeerExtensionBytes.SupportsDHT() && me.extensionBytes.SupportsDHT() && me.dHT != nil {
conn.Post(pp.Message{
Type: pp.Port,
Port: uint16(AddrPort(me.dHT.LocalAddr())),
})
}
}
// Randomizes the piece order for this connection. Every connection will be
// given a different ordering. Having it stored per connection saves having to
// randomize during request filling, and constantly recalculate the ordering
// based on piece priorities.
func (t *torrent) initRequestOrdering(c *connection) {
if c.pieceRequestOrder != nil || c.piecePriorities != nil {
panic("double init of request ordering")
}
c.piecePriorities = mathRand.Perm(t.numPieces())
c.pieceRequestOrder = pieceordering.New()
for i := range iter.N(t.Info.NumPieces()) {
if !c.PeerHasPiece(i) {
continue
}
if !t.wantPiece(i) {
continue
}
t.connPendPiece(c, i)
}
}
func (me *Client) peerGotPiece(t *torrent, c *connection, piece int) {
if !c.peerHasAll {
if t.haveInfo() {
if c.PeerPieces == nil {
c.PeerPieces = make([]bool, t.numPieces())
}
} else {
for piece >= len(c.PeerPieces) {
c.PeerPieces = append(c.PeerPieces, false)
}
}
c.PeerPieces[piece] = true
}
if t.wantPiece(piece) {
t.connPendPiece(c, piece)
me.replenishConnRequests(t, c)
}
}
func (me *Client) peerUnchoked(torrent *torrent, conn *connection) {
me.replenishConnRequests(torrent, conn)
}
func (cl *Client) connCancel(t *torrent, cn *connection, r request) (ok bool) {
ok = cn.Cancel(r)
if ok {
postedCancels.Add(1)
}
return
}
func (cl *Client) connDeleteRequest(t *torrent, cn *connection, r request) {
if !cn.RequestPending(r) {
return
}
delete(cn.Requests, r)
}
func (cl *Client) requestPendingMetadata(t *torrent, c *connection) {
if 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 < t.metadataPieceCount(); index++ {
if !t.haveMetadataPiece(index) && !c.requestedMetadataPiece(index) {
pending = append(pending, index)
}
}
for _, i := range mathRand.Perm(len(pending)) {
c.requestMetadataPiece(pending[i])
}
}
func (cl *Client) completedMetadata(t *torrent) {
h := sha1.New()
h.Write(t.MetaData)
var ih InfoHash
CopyExact(&ih, h.Sum(nil))
if ih != t.InfoHash {
log.Print("bad metadata")
t.invalidateMetadata()
return
}
var info metainfo.Info
err := bencode.Unmarshal(t.MetaData, &info)
if err != nil {
log.Printf("error unmarshalling metadata: %s", err)
t.invalidateMetadata()
return
}
// TODO(anacrolix): If this fails, I think something harsher should be
// done.
err = cl.setMetaData(t, &info, t.MetaData)
if err != nil {
log.Printf("error setting metadata: %s", err)
t.invalidateMetadata()
return
}
log.Printf("%s: got metadata from peers", t)
}
// Process incoming ut_metadata message.
func (cl *Client) gotMetadataExtensionMsg(payload []byte, t *torrent, c *connection) (err error) {
var d map[string]int
err = bencode.Unmarshal(payload, &d)
if err != nil {
err = fmt.Errorf("error unmarshalling payload: %s: %q", err, payload)
return
}
msgType, ok := d["msg_type"]
if !ok {
err = errors.New("missing msg_type field")
return
}
piece := d["piece"]
switch msgType {
case pp.DataMetadataExtensionMsgType:
if t.haveInfo() {
break
}
begin := len(payload) - metadataPieceSize(d["total_size"], piece)
if begin < 0 || begin >= len(payload) {
log.Printf("got bad metadata piece")
break
}
if !c.requestedMetadataPiece(piece) {
log.Printf("got unexpected metadata piece %d", piece)
break
}
c.metadataRequests[piece] = false
t.saveMetadataPiece(piece, payload[begin:])
c.UsefulChunksReceived++
c.lastUsefulChunkReceived = time.Now()
if !t.haveAllMetadataPieces() {
break
}
cl.completedMetadata(t)
case pp.RequestMetadataExtensionMsgType:
if !t.haveMetadataPiece(piece) {
c.Post(t.newMetadataExtensionMessage(c, pp.RejectMetadataExtensionMsgType, d["piece"], nil))
break
}
start := (1 << 14) * piece
c.Post(t.newMetadataExtensionMessage(c, pp.DataMetadataExtensionMsgType, piece, t.MetaData[start:start+t.metadataPieceSize(piece)]))
case pp.RejectMetadataExtensionMsgType:
default:
err = errors.New("unknown msg_type value")
}
return
}
type peerExchangeMessage struct {
Added CompactPeers `bencode:"added"`
AddedFlags []byte `bencode:"added.f"`
Dropped CompactPeers `bencode:"dropped"`
}
// Extracts the port as an integer from an address string.
func addrPort(addr net.Addr) int {
return AddrPort(addr)
}
func (cl *Client) peerHasAll(t *torrent, cn *connection) {
cn.peerHasAll = true
cn.PeerPieces = nil
if t.haveInfo() {
for i := 0; i < t.numPieces(); i++ {
cl.peerGotPiece(t, cn, i)
}
}
}
// Processes incoming bittorrent messages. The client lock is held upon entry
// and exit.
func (me *Client) connectionLoop(t *torrent, c *connection) error {
decoder := pp.Decoder{
R: bufio.NewReader(c.rw),
MaxLength: 256 * 1024,
}
for {
me.mu.Unlock()
var msg pp.Message
err := decoder.Decode(&msg)
receivedMessageTypes.Add(strconv.FormatInt(int64(msg.Type), 10), 1)
me.mu.Lock()
c.lastMessageReceived = time.Now()
select {
case <-c.closing:
return nil
default:
}
if err != nil {
if me.stopped() || err == io.EOF {
return nil
}
return err
}
if msg.Keepalive {
continue
}
switch msg.Type {
case pp.Choke:
c.PeerChoked = true
for r := range c.Requests {
me.connDeleteRequest(t, c, r)
}
// We can then reset our interest.
me.replenishConnRequests(t, c)
case pp.Reject:
me.connDeleteRequest(t, c, newRequest(msg.Index, msg.Begin, msg.Length))
me.replenishConnRequests(t, c)
case pp.Unchoke:
c.PeerChoked = false
me.peerUnchoked(t, c)
case pp.Interested:
c.PeerInterested = true
// TODO: This should be done from a dedicated unchoking routine.
if me.noUpload {
break
}
c.Unchoke()
case pp.NotInterested:
c.PeerInterested = false
c.Choke()
case pp.Have:
me.peerGotPiece(t, c, int(msg.Index))
case pp.Request:
if me.noUpload {
break
}
if c.PeerRequests == nil {
c.PeerRequests = make(map[request]struct{}, maxRequests)
}
request := newRequest(msg.Index, msg.Begin, msg.Length)
// TODO: Requests should be satisfied from a dedicated upload
// routine.
// c.PeerRequests[request] = struct{}{}
p := make([]byte, msg.Length)
n, err := dataReadAt(t.data, p, int64(t.pieceLength(0))*int64(msg.Index)+int64(msg.Begin))
if err != nil {
return fmt.Errorf("reading t data to serve request %q: %s", request, err)
}
if n != int(msg.Length) {
return fmt.Errorf("bad request: %v", msg)
}
c.Post(pp.Message{
Type: pp.Piece,
Index: msg.Index,
Begin: msg.Begin,
Piece: p,
})
uploadChunksPosted.Add(1)
case pp.Cancel:
req := newRequest(msg.Index, msg.Begin, msg.Length)
if !c.PeerCancel(req) {
unexpectedCancels.Add(1)
}
case pp.Bitfield:
if c.PeerPieces != nil || c.peerHasAll {
err = errors.New("received unexpected bitfield")
break
}
if t.haveInfo() {
if len(msg.Bitfield) < t.numPieces() {
err = errors.New("received invalid bitfield")
break
}
msg.Bitfield = msg.Bitfield[:t.numPieces()]
}
c.PeerPieces = msg.Bitfield
for index, has := range c.PeerPieces {
if has {
me.peerGotPiece(t, c, index)
}
}
case pp.HaveAll:
if c.PeerPieces != nil || c.peerHasAll {
err = errors.New("unexpected have-all")
break
}
me.peerHasAll(t, c)
case pp.HaveNone:
if c.peerHasAll || c.PeerPieces != nil {
err = errors.New("unexpected have-none")
break
}
c.PeerPieces = make([]bool, func() int {
if t.haveInfo() {
return t.numPieces()
} else {
return 0
}
}())
case pp.Piece:
err = me.downloadedChunk(t, c, &msg)
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 {
t.setMetadataSize(metadata_size, me)
}
}
if _, ok := c.PeerExtensionIDs["ut_metadata"]; ok {
me.requestPendingMetadata(t, c)
}
case metadataExtendedId:
err = me.gotMetadataExtensionMsg(msg.ExtendedPayload, t, c)
if err != nil {
err = fmt.Errorf("error handling metadata extension message: %s", err)
}
case pexExtendedId:
if me.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() {
me.mu.Lock()
me.addPeers(t, func() (ret []Peer) {
for i, cp := range pexMsg.Added {
p := Peer{
IP: make([]byte, 4),
Port: int(cp.Port),
Source: peerSourcePEX,
}
if i < len(pexMsg.AddedFlags) && pexMsg.AddedFlags[i]&0x01 != 0 {
p.SupportsEncryption = true
}
CopyExact(p.IP, cp.IP[:])
ret = append(ret, p)
}
return
}())
me.mu.Unlock()
peersFoundByPEX.Add(int64(len(pexMsg.Added)))
}()
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 me.dHT == nil {
break
}
pingAddr, err := net.ResolveUDPAddr("", c.remoteAddr().String())
if err != nil {
panic(err)
}
if msg.Port != 0 {
pingAddr.Port = int(msg.Port)
}
_, err = me.dHT.Ping(pingAddr)
default:
err = fmt.Errorf("received unknown message type: %#v", msg.Type)
}
if err != nil {
return err
}
}
}
func (me *Client) dropConnection(torrent *torrent, conn *connection) {
me.event.Broadcast()
for r := range conn.Requests {
me.connDeleteRequest(torrent, conn, r)
}
conn.Close()
for i0, c := range torrent.Conns {
if c != conn {
continue
}
i1 := len(torrent.Conns) - 1
if i0 != i1 {
torrent.Conns[i0] = torrent.Conns[i1]
}
torrent.Conns = torrent.Conns[:i1]
me.openNewConns(torrent)
return
}
panic("connection not found")
}
func (me *Client) addConnection(t *torrent, c *connection) bool {
if me.stopped() {
return false
}
select {
case <-t.ceasingNetworking:
return false
default:
}
if !me.wantConns(t) {
return false
}
for _, c0 := range t.Conns {
if c.PeerID == c0.PeerID {
// Already connected to a client with that ID.
duplicateClientConns.Add(1)
return false
}
}
t.Conns = append(t.Conns, c)
// TODO: This should probably be done by a routine that kills off bad
// connections, and extra connections killed here instead.
if len(t.Conns) > socketsPerTorrent {
wcs := t.worstConnsHeap()
heap.Pop(wcs).(*connection).Close()
}
return true
}
func (t *torrent) needData() bool {
if !t.haveInfo() {
return true
}
for i := range t.Pieces {
if t.wantPiece(i) {
return true
}
}
return false
}
// TODO: I'm sure there's something here to do with seeding.
func (t *torrent) badConn(c *connection) bool {
// A 30 second grace for initial messages to go through.
if time.Since(c.completedHandshake) < 30*time.Second {
return false
}
if !t.haveInfo() {
if !c.supportsExtension("ut_metadata") {
return true
}
if time.Since(c.completedHandshake) > 2*time.Minute {
return true
}
}
return !t.connHasWantedPieces(c)
}
func (t *torrent) numGoodConns() (num int) {
for _, c := range t.Conns {
if !t.badConn(c) {
num++
}
}
return
}
func (me *Client) wantConns(t *torrent) bool {
if me.noUpload && !t.needData() {
return false
}
if t.numGoodConns() >= socketsPerTorrent {
return false
}
return true
}
func (me *Client) openNewConns(t *torrent) {
select {
case <-t.ceasingNetworking:
return
default:
}
for len(t.Peers) != 0 {
if !me.wantConns(t) {
return
}
if len(t.HalfOpen) >= me.halfOpenLimit {
return
}
var (
k peersKey
p Peer
)
for k, p = range t.Peers {
break
}
delete(t.Peers, k)
me.initiateConn(p, t)
}
t.wantPeers.Broadcast()
}
func (me *Client) addPeers(t *torrent, peers []Peer) {
for _, p := range peers {
if me.dopplegangerAddr(net.JoinHostPort(p.IP.String(), strconv.FormatInt(int64(p.Port), 10))) {
continue
}
if me.ipBlockRange(p.IP) != nil {
continue
}
t.addPeer(p)
}
me.openNewConns(t)
}
func (cl *Client) cachedMetaInfoFilename(ih InfoHash) string {
return filepath.Join(cl.configDir(), "torrents", ih.HexString()+".torrent")
}
func (cl *Client) saveTorrentFile(t *torrent) error {
path := cl.cachedMetaInfoFilename(t.InfoHash)
os.MkdirAll(filepath.Dir(path), 0777)
f, err := os.OpenFile(path, os.O_WRONLY|os.O_CREATE|os.O_TRUNC, 0666)
if err != nil {
return fmt.Errorf("error opening file: %s", err)
}
defer f.Close()
e := bencode.NewEncoder(f)
err = e.Encode(t.MetaInfo())
if err != nil {
return fmt.Errorf("error marshalling metainfo: %s", err)
}
mi, err := cl.torrentCacheMetaInfo(t.InfoHash)
if err != nil {
// For example, a script kiddy makes us load too many files, and we're
// able to save the torrent, but not load it again to check it.
return nil
}
if !bytes.Equal(mi.Info.Hash, t.InfoHash[:]) {
log.Fatalf("%x != %x", mi.Info.Hash, t.InfoHash[:])
}
return nil
}
func (cl *Client) startTorrent(t *torrent) {
if t.Info == nil || t.data == nil {
panic("nope")
}
// If the client intends to upload, it needs to know what state pieces are
// in.
if !cl.noUpload {
// Queue all pieces for hashing. This is done sequentially to avoid
// spamming goroutines.
for _, p := range t.Pieces {
p.QueuedForHash = true
}
go func() {
for i := range t.Pieces {
cl.verifyPiece(t, pp.Integer(i))
}
}()
}
}
// Storage cannot be changed once it's set.
func (cl *Client) setStorage(t *torrent, td data.Data) (err error) {
err = t.setStorage(td)
cl.event.Broadcast()
if err != nil {
return
}
cl.startTorrent(t)
return
}
type TorrentDataOpener func(*metainfo.Info) data.Data
func (cl *Client) setMetaData(t *torrent, md *metainfo.Info, bytes []byte) (err error) {
err = t.setMetadata(md, bytes, &cl.mu)
if err != nil {
return
}
if !cl.config.DisableMetainfoCache {
if err := cl.saveTorrentFile(t); err != nil {
log.Printf("error saving torrent file for %s: %s", t, err)
}
}
cl.event.Broadcast()
if strings.Contains(strings.ToLower(md.Name), "porn") {
cl.dropTorrent(t.InfoHash)
err = errors.New("no porn plx")
return
}
close(t.gotMetainfo)
td := cl.torrentDataOpener(md)
err = cl.setStorage(t, td)
return
}
// Prepare a Torrent without any attachment to a Client. That means we can
// initialize fields all fields that don't require the Client without locking
// it.
func newTorrent(ih InfoHash) (t *torrent, err error) {
t = &torrent{
InfoHash: ih,
Peers: make(map[peersKey]Peer),
closing: make(chan struct{}),
ceasingNetworking: make(chan struct{}),
gotMetainfo: make(chan struct{}),
HalfOpen: make(map[string]struct{}),
}
t.wantPeers.L = &t.stateMu
t.GotMetainfo = t.gotMetainfo
return
}
func init() {
// For shuffling the tracker tiers.
mathRand.Seed(time.Now().Unix())
}
// The trackers within each tier must be shuffled before use.
// http://stackoverflow.com/a/12267471/149482
// http://www.bittorrent.org/beps/bep_0012.html#order-of-processing
func shuffleTier(tier []tracker.Client) {
for i := range tier {
j := mathRand.Intn(i + 1)
tier[i], tier[j] = tier[j], tier[i]
}
}
func copyTrackers(base [][]tracker.Client) (copy [][]tracker.Client) {
for _, tier := range base {
copy = append(copy, append([]tracker.Client{}, tier...))
}
return
}
func mergeTier(tier []tracker.Client, newURLs []string) []tracker.Client {
nextURL:
for _, url := range newURLs {
for _, tr := range tier {
if tr.URL() == url {
continue nextURL
}
}
tr, err := tracker.New(url)
if err != nil {
log.Printf("error creating tracker client for %q: %s", url, err)
continue
}
tier = append(tier, tr)
}
return tier
}
func (t *torrent) addTrackers(announceList [][]string) {
newTrackers := copyTrackers(t.Trackers)
for tierIndex, tier := range announceList {
if tierIndex < len(newTrackers) {
newTrackers[tierIndex] = mergeTier(newTrackers[tierIndex], tier)
} else {
newTrackers = append(newTrackers, mergeTier(nil, tier))
}
shuffleTier(newTrackers[tierIndex])
}
t.Trackers = newTrackers
}
// A handle to a live torrent within a Client.
type Torrent struct {
cl *Client
*torrent
}
// Don't call this before the info is available.
func (t *torrent) BytesCompleted() int64 {
if !t.haveInfo() {
return 0
}
return t.Info.TotalLength() - t.bytesLeft()
}
func (t Torrent) NumPieces() int {
return t.numPieces()
}
func (t Torrent) Drop() {
t.cl.mu.Lock()
t.cl.dropTorrent(t.InfoHash)
t.cl.mu.Unlock()
}
// Provides access to regions of torrent data that correspond to its files.
type File struct {
t Torrent
path string
offset int64
length int64
fi metainfo.FileInfo
}
func (f File) FileInfo() metainfo.FileInfo {
return f.fi
}
func (f File) Path() string {
return f.path
}
// A file-like handle to some torrent data resource.
type Handle interface {
io.Reader
io.Seeker
io.Closer
io.ReaderAt
}
// Implements a Handle within a subsection of another Handle.
type sectionHandle struct {
h Handle
off, n, cur int64
}
func (me *sectionHandle) Seek(offset int64, whence int) (ret int64, err error) {
if whence == 0 {
offset += me.off
} else if whence == 2 {
whence = 0
offset += me.off + me.n
}
ret, err = me.h.Seek(offset, whence)
me.cur = ret
ret -= me.off
return
}
func (me *sectionHandle) Close() error {
return me.h.Close()
}
func (me *sectionHandle) Read(b []byte) (n int, err error) {
max := me.off + me.n - me.cur
if int64(len(b)) > max {
b = b[:max]
}
n, err = me.h.Read(b)
me.cur += int64(n)
if err != nil {
return
}
if me.cur == me.off+me.n {
err = io.EOF
}
return
}
func (me *sectionHandle) ReadAt(b []byte, off int64) (n int, err error) {
if off >= me.n {
err = io.EOF
return
}
if int64(len(b)) >= me.n-off {
b = b[:me.n-off]
}
return me.h.ReadAt(b, me.off+off)
}
func (f File) Open() (h Handle, err error) {
h = f.t.NewReadHandle()
_, err = h.Seek(f.offset, os.SEEK_SET)
if err != nil {
h.Close()
return
}
h = &sectionHandle{h, f.offset, f.Length(), f.offset}
return
}
func (f File) ReadAt(p []byte, off int64) (n int, err error) {
maxLen := f.length - off
if int64(len(p)) > maxLen {
p = p[:maxLen]
}
return f.t.ReadAt(p, off+f.offset)
}
func (f *File) Length() int64 {
return f.length
}
type FilePieceState struct {
Length int64
State byte
}
func (f *File) Progress() (ret []FilePieceState) {
pieceSize := int64(f.t.usualPieceSize())
off := f.offset % pieceSize
remaining := f.length
for i := int(f.offset / pieceSize); ; i++ {
if remaining == 0 {
break
}
len1 := pieceSize - off
if len1 > remaining {
len1 = remaining
}
ret = append(ret, FilePieceState{len1, f.t.pieceStatusChar(i)})
off = 0
remaining -= len1
}
return
}
func (f *File) PrioritizeRegion(off, len int64) {
if off < 0 || off >= f.length {
return
}
if off+len > f.length {
len = f.length - off
}
off += f.offset
f.t.SetRegionPriority(off, len)
}
// Returns handles to the files in the torrent. This requires the metainfo is
// available first.
func (t Torrent) Files() (ret []File) {
t.cl.mu.Lock()
info := t.Info
t.cl.mu.Unlock()
if info == nil {
return
}
var offset int64
for _, fi := range info.UpvertedFiles() {
ret = append(ret, File{
t,
strings.Join(append([]string{info.Name}, fi.Path...), "/"),
offset,
fi.Length,
fi,
})
offset += fi.Length
}
return
}
func (t Torrent) SetRegionPriority(off, len int64) {
t.cl.mu.Lock()
defer t.cl.mu.Unlock()
pieceSize := int64(t.usualPieceSize())
for i := off / pieceSize; i*pieceSize < off+len; i++ {
t.cl.prioritizePiece(t.torrent, int(i), piecePriorityNormal)
}
}
func (t Torrent) AddPeers(pp []Peer) error {
cl := t.cl
cl.mu.Lock()
defer cl.mu.Unlock()
cl.addPeers(t.torrent, pp)
return nil
}
// Marks the entire torrent for download.
func (t Torrent) DownloadAll() {
t.cl.mu.Lock()
defer t.cl.mu.Unlock()
for i := range iter.N(t.numPieces()) {
t.cl.raisePiecePriority(t.torrent, i, piecePriorityNormal)
}
// Nice to have the first and last pieces sooner for various interactive
// purposes.
t.cl.raisePiecePriority(t.torrent, 0, piecePriorityReadahead)
t.cl.raisePiecePriority(t.torrent, t.numPieces()-1, piecePriorityReadahead)
}
func (me Torrent) ReadAt(p []byte, off int64) (n int, err error) {
return me.cl.torrentReadAt(me.torrent, off, p)
}
// Returns nil metainfo if it isn't in the cache. Checks that the retrieved
// metainfo has the correct infohash.
func (cl *Client) torrentCacheMetaInfo(ih InfoHash) (mi *metainfo.MetaInfo, err error) {
if cl.config.DisableMetainfoCache {
return
}
f, err := os.Open(cl.cachedMetaInfoFilename(ih))
if err != nil {
if os.IsNotExist(err) {
err = nil
}
return
}
defer f.Close()
dec := bencode.NewDecoder(f)
err = dec.Decode(&mi)
if err != nil {
return
}
if !bytes.Equal(mi.Info.Hash, ih[:]) {
err = fmt.Errorf("cached torrent has wrong infohash: %x != %x", mi.Info.Hash, ih[:])
return
}
return
}
// Specifies a new torrent for adding to a client. There are helpers for
// magnet URIs and torrent metainfo files.
type TorrentSpec struct {
Trackers [][]string
InfoHash InfoHash
Info *metainfo.InfoEx
DisplayName string
}
func TorrentSpecFromMagnetURI(uri string) (spec *TorrentSpec, err error) {
m, err := ParseMagnetURI(uri)
if err != nil {
return
}
spec = &TorrentSpec{
Trackers: [][]string{m.Trackers},
DisplayName: m.DisplayName,
}
CopyExact(&spec.InfoHash, &m.InfoHash)
return
}
func TorrentSpecFromMetaInfo(mi *metainfo.MetaInfo) (spec *TorrentSpec) {
spec = &TorrentSpec{
Trackers: mi.AnnounceList,
Info: &mi.Info,
DisplayName: mi.Info.Name,
}
CopyExact(&spec.InfoHash, &mi.Info.Hash)
return
}
func (cl *Client) AddTorrentSpec(spec *TorrentSpec) (T Torrent, new bool, err error) {
T.cl = cl
cl.mu.Lock()
defer cl.mu.Unlock()
t, ok := cl.torrents[spec.InfoHash]
if ok {
T.torrent = t
return
}
new = true
if _, ok := cl.bannedTorrents[spec.InfoHash]; ok {
err = errors.New("banned torrent")
return
}
t, err = newTorrent(spec.InfoHash)
if err != nil {
return
}
if spec.DisplayName != "" {
t.DisplayName = spec.DisplayName
}
if spec.Info != nil {
err = cl.setMetaData(t, &spec.Info.Info, spec.Info.Bytes)
} else {
var mi *metainfo.MetaInfo
mi, err = cl.torrentCacheMetaInfo(spec.InfoHash)
if err != nil {
log.Printf("error getting cached metainfo: %s", err)
} else if mi != nil {
t.addTrackers(mi.AnnounceList)
err = cl.setMetaData(t, &mi.Info.Info, mi.Info.Bytes)
}
}
if err != nil {
return
}
cl.torrents[spec.InfoHash] = t
T.torrent = t
T.torrent.pruneTimer = time.AfterFunc(0, func() {
cl.pruneConnectionsUnlocked(T.torrent)
})
t.addTrackers(spec.Trackers)
if !cl.disableTrackers {
go cl.announceTorrentTrackers(T.torrent)
}
if cl.dHT != nil {
go cl.announceTorrentDHT(T.torrent, true)
}
return
}
// Prunes unused connections. This is required to make space to dial for
// replacements.
func (cl *Client) pruneConnectionsUnlocked(t *torrent) {
select {
case <-t.ceasingNetworking:
return
case <-t.closing:
return
default:
}
cl.mu.Lock()
license := len(t.Conns) - (socketsPerTorrent+1)/2
for _, c := range t.Conns {
if license <= 0 {
break
}
if time.Now().Sub(c.lastUsefulChunkReceived) < time.Minute {
continue
}
if time.Now().Sub(c.completedHandshake) < time.Minute {
continue
}
c.Close()
license--
}
cl.mu.Unlock()
t.pruneTimer.Reset(pruneInterval)
}
func (me *Client) dropTorrent(infoHash InfoHash) (err error) {
t, ok := me.torrents[infoHash]
if !ok {
err = fmt.Errorf("no such torrent")
return
}
err = t.close()
if err != nil {
panic(err)
}
delete(me.torrents, infoHash)
return
}
// Returns true when peers are required, or false if the torrent is closing.
func (cl *Client) waitWantPeers(t *torrent) bool {
cl.mu.Lock()
defer cl.mu.Unlock()
t.stateMu.Lock()
defer t.stateMu.Unlock()
for {
select {
case <-t.ceasingNetworking:
return false
default:
}
if len(t.Peers) < torrentPeersLowWater && t.needData() {
return true
}
cl.mu.Unlock()
t.wantPeers.Wait()
t.stateMu.Unlock()
cl.mu.Lock()
t.stateMu.Lock()
}
}
func (cl *Client) announceTorrentDHT(t *torrent, impliedPort bool) {
for cl.waitWantPeers(t) {
log.Printf("getting peers for %q from DHT", t)
ps, err := cl.dHT.Announce(string(t.InfoHash[:]), cl.incomingPeerPort(), impliedPort)
if err != nil {
log.Printf("error getting peers from dht: %s", err)
return
}
allAddrs := make(map[string]struct{})
getPeers:
for {
select {
case v, ok := <-ps.Values:
if !ok {
break getPeers
}
peersFoundByDHT.Add(int64(len(v.Peers)))
for _, p := range v.Peers {
allAddrs[(&net.UDPAddr{
IP: p.IP[:],
Port: int(p.Port),
}).String()] = struct{}{}
}
// log.Printf("%s: %d new peers from DHT", t, len(v.Peers))
cl.mu.Lock()
cl.addPeers(t, func() (ret []Peer) {
for _, cp := range v.Peers {
ret = append(ret, Peer{
IP: cp.IP[:],
Port: int(cp.Port),
Source: peerSourceDHT,
})
}
return
}())
numPeers := len(t.Peers)
cl.mu.Unlock()
if numPeers >= torrentPeersHighWater {
break getPeers
}
case <-t.ceasingNetworking:
ps.Close()
return
}
}
ps.Close()
log.Printf("finished DHT peer scrape for %s: %d peers", t, len(allAddrs))
}
}
func (cl *Client) trackerBlockedUnlocked(tr tracker.Client) (blocked bool, err error) {
url_, err := url.Parse(tr.URL())
if err != nil {
return
}
host, _, err := net.SplitHostPort(url_.Host)
if err != nil {
host = url_.Host
}
addr, err := net.ResolveIPAddr("ip", host)
if err != nil {
return
}
cl.mu.Lock()
if cl.ipBlockList != nil {
if cl.ipBlockRange(addr.IP) != nil {
blocked = true
}
}
cl.mu.Unlock()
return
}
func (cl *Client) announceTorrentSingleTracker(tr tracker.Client, req *tracker.AnnounceRequest, t *torrent) error {
blocked, err := cl.trackerBlockedUnlocked(tr)
if err != nil {
return fmt.Errorf("error determining if tracker blocked: %s", err)
}
if blocked {
return fmt.Errorf("tracker blocked: %s", tr)
}
if err := tr.Connect(); err != nil {
return fmt.Errorf("error connecting: %s", err)
}
resp, err := tr.Announce(req)
if err != nil {
return fmt.Errorf("error announcing: %s", err)
}
var peers []Peer
for _, peer := range resp.Peers {
peers = append(peers, Peer{
IP: peer.IP,
Port: peer.Port,
})
}
cl.mu.Lock()
cl.addPeers(t, peers)
cl.mu.Unlock()
log.Printf("%s: %d new peers from %s", t, len(peers), tr)
peersFoundByTracker.Add(int64(len(peers)))
time.Sleep(time.Second * time.Duration(resp.Interval))
return nil
}
func (cl *Client) announceTorrentTrackersFastStart(req *tracker.AnnounceRequest, trackers [][]tracker.Client, t *torrent) (atLeastOne bool) {
oks := make(chan bool)
outstanding := 0
for _, tier := range trackers {
for _, tr := range tier {
outstanding++
go func(tr tracker.Client) {
err := cl.announceTorrentSingleTracker(tr, req, t)
oks <- err == nil
}(tr)
}
}
for outstanding > 0 {
ok := <-oks
outstanding--
if ok {
atLeastOne = true
}
}
return
}
// Announce torrent to its trackers.
func (cl *Client) announceTorrentTrackers(t *torrent) {
req := tracker.AnnounceRequest{
Event: tracker.Started,
NumWant: -1,
Port: uint16(cl.incomingPeerPort()),
PeerId: cl.peerID,
InfoHash: t.InfoHash,
}
if !cl.waitWantPeers(t) {
return
}
cl.mu.RLock()
req.Left = uint64(t.bytesLeft())
trackers := t.Trackers
cl.mu.RUnlock()
if cl.announceTorrentTrackersFastStart(&req, trackers, t) {
req.Event = tracker.None
}
newAnnounce:
for cl.waitWantPeers(t) {
cl.mu.RLock()
req.Left = uint64(t.bytesLeft())
trackers = t.Trackers
cl.mu.RUnlock()
numTrackersTried := 0
for _, tier := range trackers {
for trIndex, tr := range tier {
numTrackersTried++
err := cl.announceTorrentSingleTracker(tr, &req, t)
if err != nil {
logonce.Stderr.Printf("%s: error announcing to %s: %s", t, tr, err)
continue
}
// Float the successful announce to the top of the tier. If
// the trackers list has been changed, we'll be modifying an
// old copy so it won't matter.
cl.mu.Lock()
tier[0], tier[trIndex] = tier[trIndex], tier[0]
cl.mu.Unlock()
req.Event = tracker.None
continue newAnnounce
}
}
if numTrackersTried != 0 {
log.Printf("%s: all trackers failed", t)
}
// TODO: Wait until trackers are added if there are none.
time.Sleep(10 * time.Second)
}
}
func (cl *Client) allTorrentsCompleted() bool {
for _, t := range cl.torrents {
if !t.haveInfo() {
return false
}
if t.numPiecesCompleted() != t.numPieces() {
return false
}
}
return true
}
// Returns true when all torrents are completely downloaded and false if the
// client is stopped before that.
func (me *Client) WaitAll() bool {
me.mu.Lock()
defer me.mu.Unlock()
for !me.allTorrentsCompleted() {
if me.stopped() {
return false
}
me.event.Wait()
}
return true
}
func (me *Client) fillRequests(t *torrent, c *connection) {
if c.Interested {
if c.PeerChoked {
return
}
if len(c.Requests) > c.requestsLowWater {
return
}
}
addRequest := func(req request) (again bool) {
if len(c.Requests) >= 64 {
return false
}
return c.Request(req)
}
for e := c.pieceRequestOrder.First(); e != nil; e = e.Next() {
pieceIndex := e.Piece()
if !c.PeerHasPiece(pieceIndex) {
panic("piece in request order but peer doesn't have it")
}
if !t.wantPiece(pieceIndex) {
panic("unwanted piece in connection request order")
}
piece := t.Pieces[pieceIndex]
for _, cs := range piece.shuffledPendingChunkSpecs() {
r := request{pp.Integer(pieceIndex), cs}
if !addRequest(r) {
return
}
}
}
return
}
func (me *Client) replenishConnRequests(t *torrent, c *connection) {
if !t.haveInfo() {
return
}
me.fillRequests(t, c)
if len(c.Requests) == 0 && !c.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.
c.SetInterested(!t.haveAllPieces())
}
}
// Handle a received chunk from a peer.
func (me *Client) downloadedChunk(t *torrent, c *connection, msg *pp.Message) error {
chunksDownloadedCount.Add(1)
req := newRequest(msg.Index, msg.Begin, pp.Integer(len(msg.Piece)))
// Request has been satisfied.
me.connDeleteRequest(t, c, req)
defer me.replenishConnRequests(t, c)
piece := t.Pieces[req.Index]
// Do we actually want this chunk?
if _, ok := piece.PendingChunkSpecs[req.chunkSpec]; !ok || piece.Priority == piecePriorityNone {
unusedDownloadedChunksCount.Add(1)
c.UnwantedChunksReceived++
return nil
}
c.UsefulChunksReceived++
c.lastUsefulChunkReceived = time.Now()
// Write the chunk out.
err := t.writeChunk(int(msg.Index), int64(msg.Begin), msg.Piece)
if err != nil {
return fmt.Errorf("error writing chunk: %s", err)
}
// Record that we have the chunk.
delete(piece.PendingChunkSpecs, req.chunkSpec)
if len(piece.PendingChunkSpecs) == 0 {
for _, c := range t.Conns {
c.pieceRequestOrder.DeletePiece(int(req.Index))
}
me.queuePieceCheck(t, req.Index)
}
// Cancel pending requests for this chunk.
for _, c := range t.Conns {
if me.connCancel(t, c, req) {
me.replenishConnRequests(t, c)
}
}
return nil
}
func (me *Client) pieceHashed(t *torrent, piece pp.Integer, correct bool) {
p := t.Pieces[piece]
if p.EverHashed && !correct {
log.Printf("%s: piece %d failed hash", t, piece)
failedPieceHashes.Add(1)
}
p.EverHashed = true
if correct {
if sd, ok := t.data.(StatefulData); ok {
err := sd.PieceCompleted(int(piece))
if err != nil {
log.Printf("error completing piece: %s", err)
correct = false
}
}
}
me.pieceChanged(t, int(piece))
}
func (me *Client) pieceChanged(t *torrent, piece int) {
correct := t.pieceComplete(piece)
p := t.Pieces[piece]
if correct {
p.Priority = piecePriorityNone
p.PendingChunkSpecs = nil
p.Event.Broadcast()
} else {
if len(p.PendingChunkSpecs) == 0 {
t.pendAllChunkSpecs(int(piece))
}
if p.Priority != piecePriorityNone {
me.openNewConns(t)
}
}
for _, conn := range t.Conns {
if correct {
conn.Post(pp.Message{
Type: pp.Have,
Index: pp.Integer(piece),
})
// TODO: Cancel requests for this piece.
for r := range conn.Requests {
if int(r.Index) == piece {
panic("wat")
}
}
conn.pieceRequestOrder.DeletePiece(int(piece))
}
if t.wantPiece(piece) && conn.PeerHasPiece(piece) {
t.connPendPiece(conn, int(piece))
me.replenishConnRequests(t, conn)
}
}
if t.haveAllPieces() && me.noUpload {
t.ceaseNetworking()
}
me.event.Broadcast()
}
func (cl *Client) verifyPiece(t *torrent, index pp.Integer) {
cl.mu.Lock()
defer cl.mu.Unlock()
p := t.Pieces[index]
for p.Hashing || t.data == nil {
cl.event.Wait()
}
p.QueuedForHash = false
if t.isClosed() || t.pieceComplete(int(index)) {
return
}
p.Hashing = true
cl.mu.Unlock()
sum := t.hashPiece(index)
cl.mu.Lock()
select {
case <-t.closing:
return
default:
}
p.Hashing = false
cl.pieceHashed(t, index, sum == p.Hash)
}
// Returns handles to all the torrents loaded in the Client.
func (me *Client) Torrents() (ret []Torrent) {
me.mu.Lock()
for _, t := range me.torrents {
ret = append(ret, Torrent{me, t})
}
me.mu.Unlock()
return
}
func (me *Client) AddMagnet(uri string) (T Torrent, err error) {
spec, err := TorrentSpecFromMagnetURI(uri)
if err != nil {
return
}
T, _, err = me.AddTorrentSpec(spec)
return
}
func (me *Client) AddTorrent(mi *metainfo.MetaInfo) (T Torrent, err error) {
T, _, err = me.AddTorrentSpec(TorrentSpecFromMetaInfo(mi))
return
}
func (me *Client) AddTorrentFromFile(filename string) (T Torrent, err error) {
mi, err := metainfo.LoadFromFile(filename)
if err != nil {
return
}
T, _, err = me.AddTorrentSpec(TorrentSpecFromMetaInfo(mi))
return
}
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