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workers.go
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workers.go
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package bitswap
import (
"context"
"math/rand"
"sync"
"time"
process "gx/ipfs/QmSF8fPo3jgVBAy8fpdjjYqgG87dkJgUprRBHRd2tmfgpP/goprocess"
procctx "gx/ipfs/QmSF8fPo3jgVBAy8fpdjjYqgG87dkJgUprRBHRd2tmfgpP/goprocess/context"
logging "gx/ipfs/QmSpJByNKFX1sCsHBEp3R73FL4NF6FnQTEGyNAXHm2GS52/go-log"
cid "gx/ipfs/QmcTcsTvfaeEBRFo1TkFgT8sRmgi1n1LTZpecfVP8fzpGD/go-cid"
peer "gx/ipfs/QmfMmLGoKzCHDN7cGgk64PJr4iipzidDRME8HABSJqvmhC/go-libp2p-peer"
)
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.providerQueryManager(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.Cid().String(),
})
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 *cid.Cid, 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.Warning(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 []*cid.Cid
var nextKey *cid.Cid
var keysOut chan *cid.Cid
for {
select {
case blkey, ok := <-bs.newBlocks:
if !ok {
log.Debug("newBlocks channel closed")
return
}
if keysOut == nil {
nextKey = blkey
keysOut = bs.provideKeys
} else {
toProvide = append(toProvide, blkey)
}
case keysOut <- nextKey:
if len(toProvide) > 0 {
nextKey = toProvide[0]
toProvide = toProvide[1:]
} else {
keysOut = nil
}
case <-ctx.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 {
continue
}
// TODO: come up with a better strategy for determining when to search
// for new providers for blocks.
i := rand.Intn(len(entries))
bs.findKeys <- &blockRequest{
Cid: entries[i].Cid,
Ctx: ctx,
}
case <-parent.Done():
return
}
}
}
func (bs *Bitswap) providerQueryManager(ctx context.Context) {
var activeLk sync.Mutex
kset := cid.NewSet()
for {
select {
case e := <-bs.findKeys:
select { // make sure its not already cancelled
case <-e.Ctx.Done():
continue
default:
}
activeLk.Lock()
if kset.Has(e.Cid) {
activeLk.Unlock()
continue
}
kset.Add(e.Cid)
activeLk.Unlock()
go func(e *blockRequest) {
child, cancel := context.WithTimeout(e.Ctx, providerRequestTimeout)
defer cancel()
providers := bs.network.FindProvidersAsync(child, e.Cid, maxProvidersPerRequest)
wg := &sync.WaitGroup{}
for p := range providers {
wg.Add(1)
go func(p peer.ID) {
defer wg.Done()
err := bs.network.ConnectTo(child, p)
if err != nil {
log.Debug("failed to connect to provider %s: %s", p, err)
}
}(p)
}
wg.Wait()
activeLk.Lock()
kset.Remove(e.Cid)
activeLk.Unlock()
}(e)
case <-ctx.Done():
return
}
}
}