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connection.go
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connection.go
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package torrent
import (
"bufio"
"bytes"
"fmt"
"io"
"math"
"math/rand"
"net"
"strconv"
"strings"
"sync"
"time"
"github.com/anacrolix/dht/v2"
"github.com/anacrolix/log"
"github.com/anacrolix/missinggo"
"github.com/anacrolix/missinggo/bitmap"
"github.com/anacrolix/missinggo/iter"
"github.com/anacrolix/missinggo/prioritybitmap"
"github.com/pkg/errors"
"github.com/scionproto/scion/go/lib/snet"
"github.com/anacrolix/torrent/bencode"
"github.com/anacrolix/torrent/mse"
pp "github.com/anacrolix/torrent/peer_protocol"
)
type peerSource string
const (
peerSourceTracker = "Tr"
peerSourceIncoming = "I"
peerSourceDHTGetPeers = "Hg" // Peers we found by searching a DHT.
peerSourceDHTAnnouncePeer = "Ha" // Peers that were announced to us by a DHT.
peerSourcePEX = "X"
)
// Maintains the state of a connection with a peer.
type connection struct {
// First to ensure 64-bit alignment for atomics. See #262.
stats ConnStats
BytesReadOverTime map[int64]int64
BytesWrittenOverTime map[int64]int64
TimeInterval int64
Ticker *time.Ticker
t *Torrent
// The actual Conn, used for closing, and setting socket options.
conn net.Conn
outgoing bool
network string
remoteAddr IpPort
scionAddr *snet.UDPAddr
scionPath *snet.Path
// The Reader and Writer for this Conn, with hooks installed for stats,
// limiting, deadlines etc.
w io.Writer
r io.Reader
// True if the connection is operating over MSE obfuscation.
headerEncrypted bool
cryptoMethod mse.CryptoMethod
Discovery peerSource
closed missinggo.Event
// Set true after we've added our ConnStats generated during handshake to
// other ConnStat instances as determined when the *Torrent became known.
reconciledHandshakeStats bool
lastMessageReceived time.Time
completedHandshake *time.Time
startHandshake time.Time
lastUsefulChunkReceived time.Time
lastChunkSent time.Time
// Stuff controlled by the local peer.
Interested bool
lastBecameInterested time.Time
priorInterest time.Duration
lastStartedExpectingToReceiveChunks time.Time
cumulativeExpectedToReceiveChunks time.Duration
chunksReceivedWhileExpecting int64
Choked bool
requests map[request]struct{}
requestsLowWater int
// Chunks that we might reasonably expect to receive from the peer. Due to
// latency, buffering, and implementation differences, we may receive
// chunks that are no longer in the set of requests actually want.
validReceiveChunks map[request]struct{}
// Indexed by metadata piece, set to true if posted and pending a
// response.
metadataRequests []bool
sentHaves bitmap.Bitmap
// Stuff controlled by the remote peer.
PeerID PeerID
PeerInterested bool
PeerChoked bool
PeerRequests map[request]struct{}
PeerExtensionBytes pp.PeerExtensionBits
// 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.
peerSentHaveAll 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 pieceIndex
// Pieces we've accepted chunks for from the peer.
peerTouchedPieces map[pieceIndex]struct{}
peerAllowedFast bitmap.Bitmap
PeerMaxRequests int // Maximum pending requests the peer allows.
PeerExtensionIDs map[pp.ExtensionName]pp.ExtensionNumber
PeerClientName string
pieceInclination []int
pieceRequestOrder prioritybitmap.PriorityBitmap
writeBuffer *bytes.Buffer
uploadTimer *time.Timer
writerCond sync.Cond
logger log.Logger
lastReadBytes int64
lastWrittenBytes int64
WasClosed bool
}
func (cn *connection) updateExpectingChunks() {
if cn.expectingChunks() {
if cn.lastStartedExpectingToReceiveChunks.IsZero() {
cn.lastStartedExpectingToReceiveChunks = time.Now()
}
} else {
if !cn.lastStartedExpectingToReceiveChunks.IsZero() {
cn.cumulativeExpectedToReceiveChunks += time.Since(cn.lastStartedExpectingToReceiveChunks)
cn.lastStartedExpectingToReceiveChunks = time.Time{}
}
}
}
func (cn *connection) expectingChunks() bool {
return cn.Interested && !cn.PeerChoked
}
// Returns true if the connection is over IPv6.
func (cn *connection) ipv6() bool {
ip := cn.remoteAddr.IP
if ip.To4() != nil {
return false
}
return len(ip) == net.IPv6len
}
// Returns true the dialer has the lower client peer ID. TODO: Find the
// specification for this.
func (cn *connection) isPreferredDirection() bool {
return bytes.Compare(cn.t.cl.peerID[:], cn.PeerID[:]) < 0 == cn.outgoing
}
// Returns whether the left connection should be preferred over the right one,
// considering only their networking properties. If ok is false, we can't
// decide.
func (l *connection) hasPreferredNetworkOver(r *connection) (left, ok bool) {
var ml multiLess
ml.NextBool(l.isPreferredDirection(), r.isPreferredDirection())
ml.NextBool(!l.utp(), !r.utp())
ml.NextBool(l.ipv6(), r.ipv6())
return ml.FinalOk()
}
func (cn *connection) cumInterest() time.Duration {
ret := cn.priorInterest
if cn.Interested {
ret += time.Since(cn.lastBecameInterested)
}
return ret
}
func (cn *connection) peerHasAllPieces() (all bool, known bool) {
if cn.peerSentHaveAll {
return true, true
}
if !cn.t.haveInfo() {
return false, false
}
return bitmap.Flip(cn.peerPieces, 0, bitmap.BitIndex(cn.t.numPieces())).IsEmpty(), true
}
func (cn *connection) mu() sync.Locker {
return cn.t.cl.locker()
}
func (cn *connection) localAddr() net.Addr {
return cn.conn.LocalAddr()
}
func (cn *connection) supportsExtension(ext pp.ExtensionName) bool {
_, ok := cn.PeerExtensionIDs[ext]
return ok
}
// The best guess at number of pieces in the torrent for this peer.
func (cn *connection) bestPeerNumPieces() pieceIndex {
if cn.t.haveInfo() {
return cn.t.numPieces()
}
return cn.peerMinPieces
}
func (cn *connection) completedString() string {
have := pieceIndex(cn.peerPieces.Len())
if cn.peerSentHaveAll {
have = cn.bestPeerNumPieces()
}
return fmt.Sprintf("%d/%d", have, 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 pieceIndex) error {
cn.peerPieces.RemoveRange(bitmap.BitIndex(num), bitmap.ToEnd)
cn.peerPiecesChanged()
return nil
}
func eventAgeString(t time.Time) string {
if t.IsZero() {
return "never"
}
return fmt.Sprintf("%.2fs ago", time.Since(t).Seconds())
}
func (cn *connection) connectionFlags() (ret string) {
c := func(b byte) {
ret += string([]byte{b})
}
if cn.cryptoMethod == mse.CryptoMethodRC4 {
c('E')
} else if cn.headerEncrypted {
c('e')
}
ret += string(cn.Discovery)
if cn.utp() {
c('U')
}
return
}
func (cn *connection) utp() bool {
return parseNetworkString(cn.network).Udp
}
// Inspired by https://github.com/transmission/transmission/wiki/Peer-Status-Text.
func (cn *connection) statusFlags() (ret string) {
c := func(b byte) {
ret += string([]byte{b})
}
if cn.Interested {
c('i')
}
if cn.Choked {
c('c')
}
c('-')
ret += cn.connectionFlags()
c('-')
if cn.PeerInterested {
c('i')
}
if cn.PeerChoked {
c('c')
}
return
}
// func (cn *connection) String() string {
// var buf bytes.Buffer
// cn.WriteStatus(&buf, nil)
// return buf.String()
// }
func (cn *connection) downloadRate() float64 {
return float64(cn.stats.BytesReadUsefulData.Int64()) / cn.cumInterest().Seconds()
}
func (cn *connection) WriteStatus(w io.Writer, t *Torrent) {
// \t isn't preserved in <pre> blocks?
fmt.Fprintf(w, "%+-55q %s %s-%s\n", cn.PeerID, cn.PeerExtensionBytes, cn.localAddr(), cn.remoteAddr)
fmt.Fprintf(w, " last msg: %s, connected: %s, last helpful: %s, itime: %s, etime: %s\n",
eventAgeString(cn.lastMessageReceived),
eventAgeString(*cn.completedHandshake),
eventAgeString(cn.lastHelpful()),
cn.cumInterest(),
cn.totalExpectingTime(),
)
fmt.Fprintf(w,
" %s completed, %d pieces touched, good chunks: %v/%v-%v reqq: (%d,%d,%d]-%d, flags: %s, dr: %.1f KiB/s\n",
cn.completedString(),
len(cn.peerTouchedPieces),
&cn.stats.ChunksReadUseful,
&cn.stats.ChunksRead,
&cn.stats.ChunksWritten,
cn.requestsLowWater,
cn.numLocalRequests(),
cn.nominalMaxRequests(),
len(cn.PeerRequests),
cn.statusFlags(),
cn.downloadRate()/(1<<10),
)
fmt.Fprintf(w, " next pieces: %v%s\n",
iter.ToSlice(iter.Head(10, cn.iterPendingPiecesUntyped)),
func() string {
if cn.shouldRequestWithoutBias() {
return " (fastest)"
} else {
return ""
}
}())
fmt.Println("Bytes read over Time")
fmt.Println(cn.BytesReadOverTime)
fmt.Println("Bytes written over Time")
fmt.Println(cn.BytesWrittenOverTime)
for key, value := range cn.BytesReadOverTime {
cn.BytesReadOverTime[key] = (value / 1024 / 1024) * 8
}
for key, value := range cn.BytesWrittenOverTime {
cn.BytesWrittenOverTime[key] = (value / 1024 / 1024) * 8
}
fmt.Println("Mbit read over Time")
fmt.Println(cn.BytesReadOverTime)
fmt.Println("Mbit written over Time")
fmt.Println(cn.BytesWrittenOverTime)
fmt.Println("-----------------------------------")
}
func (cn *connection) Close() {
if !cn.closed.Set() {
return
}
cn.tickleWriter()
cn.discardPieceInclination()
cn.pieceRequestOrder.Clear()
if cn.conn != nil {
go cn.conn.Close()
}
}
func (cn *connection) PeerHasPiece(piece pieceIndex) bool {
return cn.peerSentHaveAll || cn.peerPieces.Contains(bitmap.BitIndex(piece))
}
// Writes a message into the write buffer.
func (cn *connection) Post(msg pp.Message) {
torrent.Add(fmt.Sprintf("messages posted of type %s", msg.Type.String()), 1)
// We don't need to track bytes here because a connection.w Writer wrapper
// takes care of that (although there's some delay between us recording
// the message, and the connection writer flushing it out.).
cn.writeBuffer.Write(msg.MustMarshalBinary())
// Last I checked only Piece messages affect stats, and we don't post
// those.
cn.wroteMsg(&msg)
cn.tickleWriter()
}
func (cn *connection) requestMetadataPiece(index int) {
eID := cn.PeerExtensionIDs[pp.ExtensionNameMetadata]
if eID == 0 {
return
}
if index < len(cn.metadataRequests) && cn.metadataRequests[index] {
return
}
cn.logger.Printf("requesting metadata piece %d", index)
cn.Post(pp.Message{
Type: pp.Extended,
ExtendedID: eID,
ExtendedPayload: func() []byte {
b, err := bencode.Marshal(map[string]int{
"msg_type": pp.RequestMetadataExtensionMsgType,
"piece": index,
})
if err != nil {
panic(err)
}
return b
}(),
})
for index >= len(cn.metadataRequests) {
cn.metadataRequests = append(cn.metadataRequests, false)
}
cn.metadataRequests[index] = true
}
func (cn *connection) requestedMetadataPiece(index int) bool {
return index < len(cn.metadataRequests) && cn.metadataRequests[index]
}
// The actual value to use as the maximum outbound requests.
func (cn *connection) nominalMaxRequests() (ret int) {
if cn.t.requestStrategy == 3 {
expectingTime := int64(cn.totalExpectingTime())
if expectingTime == 0 {
expectingTime = math.MaxInt64
} else {
expectingTime *= 2
}
return int(clamp(
1,
int64(cn.PeerMaxRequests),
max(
// It makes sense to always pipeline at least one connection,
// since latency must be non-zero.
2,
// Request only as many as we expect to receive in the
// dupliateRequestTimeout window. We are trying to avoid having to
// duplicate requests.
cn.chunksReceivedWhileExpecting*int64(cn.t.duplicateRequestTimeout)/expectingTime,
),
))
}
return int(clamp(
1,
cn.stats.ChunksReadUseful.Int64()-(cn.stats.ChunksRead.Int64()-cn.stats.ChunksReadUseful.Int64()),
int64(cn.PeerMaxRequests)))
}
func (cn *connection) totalExpectingTime() (ret time.Duration) {
ret = cn.cumulativeExpectedToReceiveChunks
if !cn.lastStartedExpectingToReceiveChunks.IsZero() {
ret += time.Since(cn.lastStartedExpectingToReceiveChunks)
}
return
}
func (cn *connection) onPeerSentCancel(r request) {
if _, ok := cn.PeerRequests[r]; !ok {
torrent.Add("unexpected cancels received", 1)
return
}
if cn.fastEnabled() {
cn.reject(r)
} else {
delete(cn.PeerRequests, r)
}
}
func (cn *connection) Choke(msg messageWriter) (more bool) {
if cn.Choked {
return true
}
cn.Choked = true
more = msg(pp.Message{
Type: pp.Choke,
})
if cn.fastEnabled() {
for r := range cn.PeerRequests {
// TODO: Don't reject pieces in allowed fast set.
cn.reject(r)
}
} else {
cn.PeerRequests = nil
}
return
}
func (cn *connection) Unchoke(msg func(pp.Message) bool) bool {
if !cn.Choked {
return true
}
cn.Choked = false
return msg(pp.Message{
Type: pp.Unchoke,
})
}
func (cn *connection) SetInterested(interested bool, msg func(pp.Message) bool) bool {
if cn.Interested == interested {
return true
}
cn.Interested = interested
if interested {
cn.lastBecameInterested = time.Now()
} else if !cn.lastBecameInterested.IsZero() {
cn.priorInterest += time.Since(cn.lastBecameInterested)
}
cn.updateExpectingChunks()
// log.Printf("%p: setting interest: %v", cn, interested)
return msg(pp.Message{
Type: func() pp.MessageType {
if interested {
return pp.Interested
} else {
return pp.NotInterested
}
}(),
})
}
// The function takes a message to be sent, and returns true if more messages
// are okay.
type messageWriter func(pp.Message) bool
// Proxies the messageWriter's response.
func (cn *connection) request(r request, mw messageWriter) bool {
if _, ok := cn.requests[r]; ok {
panic("chunk already requested")
}
if !cn.PeerHasPiece(pieceIndex(r.Index)) {
panic("requesting piece peer doesn't have")
}
if _, ok := cn.t.conns[cn]; !ok {
panic("requesting but not in active conns")
}
if cn.closed.IsSet() {
panic("requesting when connection is closed")
}
if cn.PeerChoked {
if cn.peerAllowedFast.Get(int(r.Index)) {
torrent.Add("allowed fast requests sent", 1)
} else {
panic("requesting while choked and not allowed fast")
}
}
if cn.t.hashingPiece(pieceIndex(r.Index)) {
panic("piece is being hashed")
}
if cn.t.pieceQueuedForHash(pieceIndex(r.Index)) {
panic("piece is queued for hash")
}
if cn.requests == nil {
cn.requests = make(map[request]struct{})
}
cn.requests[r] = struct{}{}
if cn.validReceiveChunks == nil {
cn.validReceiveChunks = make(map[request]struct{})
}
cn.validReceiveChunks[r] = struct{}{}
cn.t.pendingRequests[r]++
cn.t.lastRequested[r] = time.AfterFunc(cn.t.duplicateRequestTimeout, func() {
torrent.Add("duplicate request timeouts", 1)
cn.mu().Lock()
defer cn.mu().Unlock()
delete(cn.t.lastRequested, r)
for cn := range cn.t.conns {
if cn.PeerHasPiece(pieceIndex(r.Index)) {
cn.updateRequests()
}
}
})
cn.updateExpectingChunks()
return mw(pp.Message{
Type: pp.Request,
Index: r.Index,
Begin: r.Begin,
Length: r.Length,
})
}
func (cn *connection) fillWriteBuffer(msg func(pp.Message) bool) {
if !cn.t.networkingEnabled {
if !cn.SetInterested(false, msg) {
return
}
if len(cn.requests) != 0 {
for r := range cn.requests {
cn.deleteRequest(r)
// log.Printf("%p: cancelling request: %v", cn, r)
if !msg(makeCancelMessage(r)) {
return
}
}
}
}
if len(cn.requests) <= cn.requestsLowWater {
filledBuffer := false
cn.iterPendingPieces(func(pieceIndex pieceIndex) bool {
cn.iterPendingRequests(pieceIndex, func(r request) bool {
if !cn.SetInterested(true, msg) {
filledBuffer = true
return false
}
if len(cn.requests) >= cn.nominalMaxRequests() {
return false
}
// Choking is looked at here because our interest is dependent
// on whether we'd make requests in its absence.
if cn.PeerChoked {
if !cn.peerAllowedFast.Get(bitmap.BitIndex(r.Index)) {
return false
}
}
if _, ok := cn.requests[r]; ok {
return true
}
filledBuffer = !cn.request(r, msg)
return !filledBuffer
})
return !filledBuffer
})
if filledBuffer {
// If we didn't completely top up the requests, we shouldn't mark
// the low water, since we'll want to top up the requests as soon
// as we have more write buffer space.
return
}
cn.requestsLowWater = len(cn.requests) / 2
}
cn.upload(msg)
}
// Routine that writes to the peer. Some of what to write is buffered by
// activity elsewhere in the Client, and some is determined locally when the
// connection is writable.
func (cn *connection) writer(keepAliveTimeout time.Duration) {
var (
lastWrite time.Time = time.Now()
keepAliveTimer *time.Timer
)
keepAliveTimer = time.AfterFunc(keepAliveTimeout, func() {
cn.mu().Lock()
defer cn.mu().Unlock()
if time.Since(lastWrite) >= keepAliveTimeout {
cn.tickleWriter()
}
keepAliveTimer.Reset(keepAliveTimeout)
})
cn.mu().Lock()
defer cn.mu().Unlock()
defer cn.Close()
defer keepAliveTimer.Stop()
frontBuf := new(bytes.Buffer)
for {
if cn.closed.IsSet() {
return
}
if cn.writeBuffer.Len() == 0 {
cn.fillWriteBuffer(func(msg pp.Message) bool {
cn.wroteMsg(&msg)
cn.writeBuffer.Write(msg.MustMarshalBinary())
torrent.Add(fmt.Sprintf("messages filled of type %s", msg.Type.String()), 1)
return cn.writeBuffer.Len() < 1<<16 // 64KiB
})
}
if cn.writeBuffer.Len() == 0 && time.Since(lastWrite) >= keepAliveTimeout {
cn.writeBuffer.Write(pp.Message{Keepalive: true}.MustMarshalBinary())
postedKeepalives.Add(1)
}
if cn.writeBuffer.Len() == 0 {
// TODO: Minimize wakeups....
cn.writerCond.Wait()
continue
}
// Flip the buffers.
frontBuf, cn.writeBuffer = cn.writeBuffer, frontBuf
cn.mu().Unlock()
n, err := cn.w.Write(frontBuf.Bytes())
cn.mu().Lock()
if n != 0 {
lastWrite = time.Now()
keepAliveTimer.Reset(keepAliveTimeout)
}
if err != nil {
return
}
if n != frontBuf.Len() {
panic("short write")
}
frontBuf.Reset()
}
}
func (cn *connection) Have(piece pieceIndex) {
if cn.sentHaves.Get(bitmap.BitIndex(piece)) {
return
}
cn.Post(pp.Message{
Type: pp.Have,
Index: pp.Integer(piece),
})
cn.sentHaves.Add(bitmap.BitIndex(piece))
}
func (cn *connection) PostBitfield() {
if cn.sentHaves.Len() != 0 {
panic("bitfield must be first have-related message sent")
}
if !cn.t.haveAnyPieces() {
return
}
cn.Post(pp.Message{
Type: pp.Bitfield,
Bitfield: cn.t.bitfield(),
})
cn.sentHaves = cn.t.completedPieces.Copy()
}
func (cn *connection) updateRequests() {
// log.Print("update requests")
cn.tickleWriter()
}
// Emits the indices in the Bitmaps bms in order, never repeating any index.
// skip is mutated during execution, and its initial values will never be
// emitted.
func iterBitmapsDistinct(skip *bitmap.Bitmap, bms ...bitmap.Bitmap) iter.Func {
return func(cb iter.Callback) {
for _, bm := range bms {
if !iter.All(func(i interface{}) bool {
skip.Add(i.(int))
return cb(i)
}, bitmap.Sub(bm, *skip).Iter) {
return
}
}
}
}
func (cn *connection) iterUnbiasedPieceRequestOrder(f func(piece pieceIndex) bool) bool {
now, readahead := cn.t.readerPiecePriorities()
var skip bitmap.Bitmap
if !cn.peerSentHaveAll {
// Pieces to skip include pieces the peer doesn't have.
skip = bitmap.Flip(cn.peerPieces, 0, bitmap.BitIndex(cn.t.numPieces()))
}
// And pieces that we already have.
skip.Union(cn.t.completedPieces)
skip.Union(cn.t.piecesQueuedForHash)
// Return an iterator over the different priority classes, minus the skip
// pieces.
return iter.All(
func(_piece interface{}) bool {
i := _piece.(bitmap.BitIndex)
if cn.t.hashingPiece(pieceIndex(i)) {
return true
}
return f(pieceIndex(i))
},
iterBitmapsDistinct(&skip, now, readahead),
func(cb iter.Callback) {
cn.t.pendingPieces.IterTyped(func(piece int) bool {
if skip.Contains(piece) {
return true
}
more := cb(piece)
skip.Add(piece)
return more
})
},
)
}
// The connection should download highest priority pieces first, without any
// inclination toward avoiding wastage. Generally we might do this if there's
// a single connection, or this is the fastest connection, and we have active
// readers that signal an ordering preference. It's conceivable that the best
// connection should do this, since it's least likely to waste our time if
// assigned to the highest priority pieces, and assigning more than one this
// role would cause significant wasted bandwidth.
func (cn *connection) shouldRequestWithoutBias() bool {
if cn.t.requestStrategy != 2 {
return false
}
if len(cn.t.readers) == 0 {
return false
}
if len(cn.t.conns) == 1 {
return true
}
if cn == cn.t.fastestConn {
return true
}
return false
}
func (cn *connection) iterPendingPieces(f func(pieceIndex) bool) bool {
if !cn.t.haveInfo() {
return false
}
if cn.t.requestStrategy == 3 {
return cn.iterUnbiasedPieceRequestOrder(f)
}
if cn.shouldRequestWithoutBias() {
return cn.iterUnbiasedPieceRequestOrder(f)
} else {
return cn.pieceRequestOrder.IterTyped(func(i int) bool {
return f(pieceIndex(i))
})
}
}
func (cn *connection) iterPendingPiecesUntyped(f iter.Callback) {
cn.iterPendingPieces(func(i pieceIndex) bool { return f(i) })
}
func (cn *connection) iterPendingRequests(piece pieceIndex, f func(request) bool) bool {
return iterUndirtiedChunks(piece, cn.t, func(cs chunkSpec) bool {
r := request{pp.Integer(piece), cs}
if cn.t.requestStrategy == 3 {
if _, ok := cn.t.lastRequested[r]; ok {
// This piece has been requested on another connection, and
// the duplicate request timer is still running.
return true
}
}
return f(r)
})
}
func iterUndirtiedChunks(piece pieceIndex, t *Torrent, f func(chunkSpec) bool) bool {
p := &t.pieces[piece]
if t.requestStrategy == 3 {
for i := pp.Integer(0); i < p.numChunks(); i++ {
if !p.dirtyChunks.Get(bitmap.BitIndex(i)) {
if !f(t.chunkIndexSpec(i, piece)) {
return false
}
}
}
return true
}
chunkIndices := t.pieces[piece].undirtiedChunkIndices()
return iter.ForPerm(chunkIndices.Len(), func(i int) bool {
ci, err := chunkIndices.RB.Select(uint32(i))
if err != nil {
panic(err)
}
return f(t.chunkIndexSpec(pp.Integer(ci), piece))
})
}
// check callers updaterequests
func (cn *connection) stopRequestingPiece(piece pieceIndex) bool {
return cn.pieceRequestOrder.Remove(bitmap.BitIndex(piece))
}
// This is distinct from Torrent piece priority, which is the user's
// preference. Connection piece priority is specific to a connection and is
// used to pseudorandomly avoid connections always requesting the same pieces
// and thus wasting effort.
func (cn *connection) updatePiecePriority(piece pieceIndex) bool {
tpp := cn.t.piecePriority(piece)
if !cn.PeerHasPiece(piece) {
tpp = PiecePriorityNone
}
if tpp == PiecePriorityNone {
return cn.stopRequestingPiece(piece)
}
prio := cn.getPieceInclination()[piece]
switch cn.t.requestStrategy {
case 1:
switch tpp {
case PiecePriorityNormal:
case PiecePriorityReadahead:
prio -= int(cn.t.numPieces())
case PiecePriorityNext, PiecePriorityNow:
prio -= 2 * int(cn.t.numPieces())
default:
panic(tpp)
}
prio += int(piece / 3)
default:
}
return cn.pieceRequestOrder.Set(bitmap.BitIndex(piece), prio) || cn.shouldRequestWithoutBias()
}
func (cn *connection) getPieceInclination() []int {
if cn.pieceInclination == nil {
cn.pieceInclination = cn.t.getConnPieceInclination()
}
return cn.pieceInclination
}
func (cn *connection) discardPieceInclination() {
if cn.pieceInclination == nil {
return
}
cn.t.putPieceInclination(cn.pieceInclination)
cn.pieceInclination = nil
}
func (cn *connection) peerPiecesChanged() {
if cn.t.haveInfo() {
prioritiesChanged := false
for i := pieceIndex(0); i < cn.t.numPieces(); i++ {
if cn.updatePiecePriority(i) {
prioritiesChanged = true
}
}
if prioritiesChanged {
cn.updateRequests()
}
}
}
func (cn *connection) raisePeerMinPieces(newMin pieceIndex) {
if newMin > cn.peerMinPieces {
cn.peerMinPieces = newMin
}
}
func (cn *connection) peerSentHave(piece pieceIndex) error {
if cn.t.haveInfo() && piece >= cn.t.numPieces() || piece < 0 {
return errors.New("invalid piece")
}
if cn.PeerHasPiece(piece) {
return nil
}
cn.raisePeerMinPieces(piece + 1)
cn.peerPieces.Set(bitmap.BitIndex(piece), true)
if cn.updatePiecePriority(piece) {
cn.updateRequests()
}
return nil
}
func (cn *connection) peerSentBitfield(bf []bool) error {
cn.peerSentHaveAll = 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(pieceIndex(len(bf) - 7))
if cn.t.haveInfo() && len(bf) > int(cn.t.numPieces()) {
// Ignore known excess pieces.
bf = bf[:cn.t.numPieces()]
}
for i, have := range bf {
if have {
cn.raisePeerMinPieces(pieceIndex(i) + 1)
}
cn.peerPieces.Set(i, have)
}
cn.peerPiecesChanged()
return nil
}
func (cn *connection) onPeerSentHaveAll() error {
cn.peerSentHaveAll = true
cn.peerPieces.Clear()
cn.peerPiecesChanged()
return nil
}
func (cn *connection) peerSentHaveNone() error {
cn.peerPieces.Clear()
cn.peerSentHaveAll = false
cn.peerPiecesChanged()
return nil
}
func (c *connection) requestPendingMetadata() {
if c.t.haveInfo() {
return
}
if c.PeerExtensionIDs[pp.ExtensionNameMetadata] == 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)
}
}
rand.Shuffle(len(pending), func(i, j int) { pending[i], pending[j] = pending[j], pending[i] })
for _, i := range pending {
c.requestMetadataPiece(i)
}
}
func (cn *connection) wroteMsg(msg *pp.Message) {
torrent.Add(fmt.Sprintf("messages written of type %s", msg.Type.String()), 1)
cn.allStats(func(cs *ConnStats) { cs.wroteMsg(msg) })
}
func (cn *connection) readMsg(msg *pp.Message) {
cn.allStats(func(cs *ConnStats) { cs.readMsg(msg) })
}
// After handshake, we know what Torrent and Client stats to include for a
// connection.
func (cn *connection) postHandshakeStats(f func(*ConnStats)) {
t := cn.t
f(&t.stats)
f(&t.cl.stats)
}