package bitswap import ( "time" process "github.com/ipfs/go-ipfs/Godeps/_workspace/src/github.com/jbenet/goprocess" procctx "github.com/ipfs/go-ipfs/Godeps/_workspace/src/github.com/jbenet/goprocess/context" context "github.com/ipfs/go-ipfs/Godeps/_workspace/src/golang.org/x/net/context" key "github.com/ipfs/go-ipfs/blocks/key" logging "github.com/ipfs/go-ipfs/vendor/QmQg1J6vikuXF9oDvm4wpdeAUvvkVEKW1EYDw9HhTMnP2b/go-log" ) var TaskWorkerCount = 8 func (bs *Bitswap) startWorkers(px process.Process, ctx context.Context) { // Start up a worker to handle block requests this node is making px.Go(func(px process.Process) { bs.providerConnector(ctx) }) // Start up workers to handle requests from other nodes for the data on this node for i := 0; i < TaskWorkerCount; i++ { i := i px.Go(func(px process.Process) { bs.taskWorker(ctx, i) }) } // Start up a worker to manage periodically resending our wantlist out to peers px.Go(func(px process.Process) { bs.rebroadcastWorker(ctx) }) // Start up a worker to manage sending out provides messages px.Go(func(px process.Process) { bs.provideCollector(ctx) }) // Spawn up multiple workers to handle incoming blocks // consider increasing number if providing blocks bottlenecks // file transfers px.Go(bs.provideWorker) } func (bs *Bitswap) taskWorker(ctx context.Context, id int) { idmap := logging.LoggableMap{"ID": id} defer log.Info("bitswap task worker shutting down...") for { log.Event(ctx, "Bitswap.TaskWorker.Loop", idmap) select { case nextEnvelope := <-bs.engine.Outbox(): select { case envelope, ok := <-nextEnvelope: if !ok { continue } log.Event(ctx, "Bitswap.TaskWorker.Work", logging.LoggableMap{ "ID": id, "Target": envelope.Peer.Pretty(), "Block": envelope.Block.Multihash.B58String(), }) bs.wm.SendBlock(ctx, envelope) case <-ctx.Done(): return } case <-ctx.Done(): return } } } func (bs *Bitswap) provideWorker(px process.Process) { limit := make(chan struct{}, provideWorkerMax) limitedGoProvide := func(k key.Key, wid int) { defer func() { // replace token when done <-limit }() ev := logging.LoggableMap{"ID": wid} ctx := procctx.OnClosingContext(px) // derive ctx from px defer log.EventBegin(ctx, "Bitswap.ProvideWorker.Work", ev, &k).Done() ctx, cancel := context.WithTimeout(ctx, provideTimeout) // timeout ctx defer cancel() if err := bs.network.Provide(ctx, k); err != nil { //log.Error(err) } } // worker spawner, reads from bs.provideKeys until it closes, spawning a // _ratelimited_ number of workers to handle each key. for wid := 2; ; wid++ { ev := logging.LoggableMap{"ID": 1} log.Event(procctx.OnClosingContext(px), "Bitswap.ProvideWorker.Loop", ev) select { case <-px.Closing(): return case k, ok := <-bs.provideKeys: if !ok { log.Debug("provideKeys channel closed") return } select { case <-px.Closing(): return case limit <- struct{}{}: go limitedGoProvide(k, wid) } } } } func (bs *Bitswap) provideCollector(ctx context.Context) { defer close(bs.provideKeys) var toProvide []key.Key var nextKey key.Key var keysOut chan key.Key for { select { case blk, ok := <-bs.newBlocks: if !ok { log.Debug("newBlocks channel closed") return } if keysOut == nil { nextKey = blk.Key() keysOut = bs.provideKeys } else { toProvide = append(toProvide, blk.Key()) } case keysOut <- nextKey: if len(toProvide) > 0 { nextKey = toProvide[0] toProvide = toProvide[1:] } else { keysOut = nil } case <-ctx.Done(): return } } } // connects to providers for the given keys func (bs *Bitswap) providerConnector(parent context.Context) { defer log.Info("bitswap client worker shutting down...") for { log.Event(parent, "Bitswap.ProviderConnector.Loop") select { case req := <-bs.findKeys: keys := req.keys if len(keys) == 0 { log.Warning("Received batch request for zero blocks") continue } log.Event(parent, "Bitswap.ProviderConnector.Work", logging.LoggableMap{"Keys": keys}) // NB: Optimization. Assumes that providers of key[0] are likely to // be able to provide for all keys. This currently holds true in most // every situation. Later, this assumption may not hold as true. child, cancel := context.WithTimeout(req.ctx, providerRequestTimeout) providers := bs.network.FindProvidersAsync(child, keys[0], maxProvidersPerRequest) for p := range providers { go bs.network.ConnectTo(req.ctx, p) } cancel() case <-parent.Done(): return } } } func (bs *Bitswap) rebroadcastWorker(parent context.Context) { ctx, cancel := context.WithCancel(parent) defer cancel() broadcastSignal := time.NewTicker(rebroadcastDelay.Get()) defer broadcastSignal.Stop() tick := time.NewTicker(10 * time.Second) defer tick.Stop() for { log.Event(ctx, "Bitswap.Rebroadcast.idle") select { case <-tick.C: n := bs.wm.wl.Len() if n > 0 { log.Debug(n, "keys in bitswap wantlist") } case <-broadcastSignal.C: // resend unfulfilled wantlist keys log.Event(ctx, "Bitswap.Rebroadcast.active") entries := bs.wm.wl.Entries() if len(entries) > 0 { bs.connectToProviders(ctx, entries) } case <-parent.Done(): return } } }