package strategy
import (
"sync"
"github.com/jbenet/go-ipfs/Godeps/_workspace/src/code.google.com/p/go.net/context"
bstore "github.com/jbenet/go-ipfs/blocks/blockstore"
bsmsg "github.com/jbenet/go-ipfs/exchange/bitswap/message"
wl "github.com/jbenet/go-ipfs/exchange/bitswap/wantlist"
peer "github.com/jbenet/go-ipfs/peer"
u "github.com/jbenet/go-ipfs/util"
)
var log = u.Logger("strategy")
// LedgerMap lists Ledgers by their Partner key.
type ledgerMap map[u.Key]*ledger
type Envelope struct {
Peer peer.Peer
Message bsmsg.BitSwapMessage
}
type LedgerManager struct {
lock sync.RWMutex
ledgerMap ledgerMap
bs bstore.Blockstore
tasklist *taskList
outbox chan Envelope
workSignal chan struct{}
}
func NewLedgerManager(ctx context.Context, bs bstore.Blockstore) *LedgerManager {
lm := &LedgerManager{
ledgerMap: make(ledgerMap),
bs: bs,
tasklist: newTaskList(),
outbox: make(chan Envelope, 4), // TODO extract constant
workSignal: make(chan struct{}),
}
go lm.taskWorker(ctx)
return lm
}
func (lm *LedgerManager) taskWorker(ctx context.Context) {
for {
nextTask := lm.tasklist.Pop()
if nextTask == nil {
// No tasks in the list?
// Wait until there are!
select {
case <-ctx.Done():
return
case <-lm.workSignal:
}
continue
}
block, err := lm.bs.Get(nextTask.Key)
if err != nil {
continue // TODO maybe return an error
}
// construct message here so we can make decisions about any additional
// information we may want to include at this time.
m := bsmsg.New()
m.AddBlock(block)
// TODO: maybe add keys from our wantlist?
select {
case <-ctx.Done():
return
case lm.outbox <- Envelope{Peer: nextTask.Target, Message: m}:
}
}
}
func (lm *LedgerManager) Outbox() <-chan Envelope {
return lm.outbox
}
// Returns a slice of Peers with whom the local node has active sessions
func (lm *LedgerManager) Peers() []peer.Peer {
lm.lock.RLock()
defer lm.lock.RUnlock()
response := make([]peer.Peer, 0)
for _, ledger := range lm.ledgerMap {
response = append(response, ledger.Partner)
}
return response
}
// BlockIsWantedByPeer returns true if peer wants the block given by this
// key
func (lm *LedgerManager) BlockIsWantedByPeer(k u.Key, p peer.Peer) bool {
lm.lock.RLock()
defer lm.lock.RUnlock()
ledger := lm.findOrCreate(p)
return ledger.WantListContains(k)
}
// MessageReceived performs book-keeping. Returns error if passed invalid
// arguments.
func (lm *LedgerManager) MessageReceived(p peer.Peer, m bsmsg.BitSwapMessage) error {
lm.lock.Lock()
defer lm.lock.Unlock()
l := lm.findOrCreate(p)
if m.Full() {
l.wantList = wl.New()
}
for _, e := range m.Wantlist() {
if e.Cancel {
l.CancelWant(e.Key)
lm.tasklist.Cancel(e.Key, p)
} else {
l.Wants(e.Key, e.Priority)
lm.tasklist.Push(e.Key, e.Priority, p)
// Signal task generation to restart (if stopped!)
select {
case lm.workSignal <- struct{}{}:
default:
}
}
}
for _, block := range m.Blocks() {
// FIXME extract blocks.NumBytes(block) or block.NumBytes() method
l.ReceivedBytes(len(block.Data))
for _, l := range lm.ledgerMap {
if l.WantListContains(block.Key()) {
lm.tasklist.Push(block.Key(), 1, l.Partner)
// Signal task generation to restart (if stopped!)
select {
case lm.workSignal <- struct{}{}:
default:
}
}
}
}
return nil
}
// TODO add contents of m.WantList() to my local wantlist? NB: could introduce
// race conditions where I send a message, but MessageSent gets handled after
// MessageReceived. The information in the local wantlist could become
// inconsistent. Would need to ensure that Sends and acknowledgement of the
// send happen atomically
func (lm *LedgerManager) MessageSent(p peer.Peer, m bsmsg.BitSwapMessage) error {
lm.lock.Lock()
defer lm.lock.Unlock()
l := lm.findOrCreate(p)
for _, block := range m.Blocks() {
l.SentBytes(len(block.Data))
l.wantList.Remove(block.Key())
lm.tasklist.Cancel(block.Key(), p)
}
return nil
}
func (lm *LedgerManager) NumBytesSentTo(p peer.Peer) uint64 {
lm.lock.RLock()
defer lm.lock.RUnlock()
return lm.findOrCreate(p).Accounting.BytesSent
}
func (lm *LedgerManager) NumBytesReceivedFrom(p peer.Peer) uint64 {
lm.lock.RLock()
defer lm.lock.RUnlock()
return lm.findOrCreate(p).Accounting.BytesRecv
}
// ledger lazily instantiates a ledger
func (lm *LedgerManager) findOrCreate(p peer.Peer) *ledger {
l, ok := lm.ledgerMap[p.Key()]
if !ok {
l = newLedger(p)
lm.ledgerMap[p.Key()] = l
}
return l
}