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package yggdrasil
import (
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"errors"
"fmt"
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"sync"
//"sync/atomic"
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"time"
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"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
//"github.com/yggdrasil-network/yggdrasil-go/src/util"
)
type link struct {
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core *Core
mutex sync.RWMutex // protects interfaces below
interfaces map[string]*linkInterface
}
type linkInterfaceMsgIO interface {
readMsg() ([]byte, error)
writeMsg([]byte) (int, error)
close() error
// These are temporary workarounds to stream semantics
_sendMetaBytes([]byte) error
_recvMetaBytes() ([]byte, error)
}
type linkInterface struct {
name string
link *link
peer *peer
msgIO linkInterfaceMsgIO
}
func (l *link) init(c *Core) error {
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l.core = c
l.mutex.Lock()
l.interfaces = make(map[string]*linkInterface)
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l.mutex.Unlock()
if err := l.core.awdl.init(c); err != nil {
l.core.log.Println("Failed to start AWDL interface")
return err
}
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return nil
}
func (l *link) create(msgIO linkInterfaceMsgIO, name string) (*linkInterface, error) {
l.mutex.Lock()
defer l.mutex.Unlock()
if _, ok := l.interfaces[name]; ok {
return nil, errors.New("Interface with this name already exists")
}
intf := linkInterface{
name: name,
link: l,
msgIO: msgIO,
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}
l.interfaces[intf.name] = &intf
//go intf.start()
return &intf, nil
}
func (intf *linkInterface) handler() error {
// TODO split some of this into shorter functions, so it's easier to read, and for the FIXME duplicate peer issue mentioned later
myLinkPub, myLinkPriv := crypto.NewBoxKeys()
meta := version_getBaseMetadata()
meta.box = intf.link.core.boxPub
meta.sig = intf.link.core.sigPub
meta.link = *myLinkPub
metaBytes := meta.encode()
// TODO timeouts on send/recv (goroutine for send/recv, channel select w/ timer)
err := intf.msgIO._sendMetaBytes(metaBytes)
if err != nil {
return err
}
metaBytes, err = intf.msgIO._recvMetaBytes()
if err != nil {
return err
}
meta = version_metadata{}
if !meta.decode(metaBytes) || !meta.check() {
return errors.New("failed to decode metadata")
}
base := version_getBaseMetadata()
if meta.ver > base.ver || meta.ver == base.ver && meta.minorVer > base.minorVer {
intf.link.core.log.Println("Failed to connect to node: " + intf.name + " version: " + fmt.Sprintf("%d.%d", meta.ver, meta.minorVer))
return errors.New("failed to connect: wrong version")
}
// FIXME we *must* stop here and check that we don't already have a connection to this peer. Need to figure out a sane way how to do that. Otherwise you'll have things like duplicate connections (one in each direction) for auto-discovered peers.
shared := crypto.GetSharedKey(myLinkPriv, &meta.link)
intf.peer = intf.link.core.peers.newPeer(&meta.box, &meta.sig, shared, intf.name)
if intf.peer == nil {
return errors.New("failed to create peer")
}
defer func() {
// More cleanup can go here
intf.link.core.peers.removePeer(intf.peer.port)
}()
// Finish setting up the peer struct
out := make(chan []byte, 1)
defer close(out)
intf.peer.out = func(msg []byte) {
defer func() { recover() }()
out <- msg
}
intf.peer.close = func() { intf.msgIO.close() }
go intf.peer.linkLoop()
// Start the writer
go func() {
interval := 4 * time.Second
timer := time.NewTimer(interval)
clearTimer := func() {
if !timer.Stop() {
<-timer.C
}
}
defer clearTimer()
for {
// First try to send any link protocol traffic
select {
case msg := <-intf.peer.linkOut:
intf.msgIO.writeMsg(msg)
continue
default:
}
// No protocol traffic to send, so reset the timer
clearTimer()
timer.Reset(interval)
// Now block until something is ready or the timer triggers keepalive traffic
select {
case <-timer.C:
intf.msgIO.writeMsg(nil)
case msg := <-intf.peer.linkOut:
intf.msgIO.writeMsg(msg)
case msg, ok := <-out:
if !ok {
return
}
intf.msgIO.writeMsg(msg)
if true {
// TODO *don't* do this if we're not reading any traffic
// In such a case, the reader is responsible for resetting it the next time we read something
intf.link.core.switchTable.idleIn <- intf.peer.port
}
}
}
}()
intf.link.core.switchTable.idleIn <- intf.peer.port // notify switch that we're idle
// Run reader loop
for {
msg, err := intf.msgIO.readMsg()
if len(msg) > 0 {
intf.peer.handlePacket(msg)
}
if err != nil {
return err
}
}
////////////////////////////////////////////////////////////////////////////////
return nil
}
/*
func (intf *linkInterface) start() {
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myLinkPub, myLinkPriv := crypto.NewBoxKeys()
meta := version_getBaseMetadata()
meta.box = intf.link.core.boxPub
meta.sig = intf.link.core.sigPub
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meta.link = *myLinkPub
metaBytes := meta.encode()
//intf.link.core.log.Println("start: intf.tolink <- metaBytes")
intf.tolink <- metaBytes
//intf.link.core.log.Println("finish: intf.tolink <- metaBytes")
//intf.link.core.log.Println("start: metaBytes = <-intf.fromlink")
metaBytes = <-intf.fromlink
//intf.link.core.log.Println("finish: metaBytes = <-intf.fromlink")
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meta = version_metadata{}
if !meta.decode(metaBytes) || !meta.check() {
intf.link.core.log.Println("Metadata decode failure")
return
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}
base := version_getBaseMetadata()
if meta.ver > base.ver || meta.ver == base.ver && meta.minorVer > base.minorVer {
intf.link.core.log.Println("Failed to connect to node: " + intf.name + " version: " + fmt.Sprintf("%d.%d", meta.ver, meta.minorVer))
return
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}
shared := crypto.GetSharedKey(myLinkPriv, &meta.link)
intf.peer = intf.link.core.peers.newPeer(&meta.box, &meta.sig, shared, intf.name)
if intf.peer == nil {
intf.link.mutex.Lock()
delete(intf.link.interfaces, intf.name)
intf.link.mutex.Unlock()
return
}
intf.peer.linkOut = make(chan []byte, 1) // protocol traffic
intf.peer.out = func(msg []byte) {
defer func() { recover() }()
intf.tolink <- msg
} // called by peer.sendPacket()
intf.link.core.switchTable.idleIn <- intf.peer.port // notify switch that we're idle
intf.peer.close = func() {
close(intf.fromlink)
close(intf.tolink)
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}
go intf.handler()
go intf.peer.linkLoop()
}
func (l *link) getInterface(identity string) *linkInterface {
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l.mutex.RLock()
defer l.mutex.RUnlock()
if intf, ok := l.interfaces[identity]; ok {
return intf
}
return nil
}
func (l *link) shutdown(identity string) error {
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if intf, ok := l.interfaces[identity]; ok {
intf.shutdown <- true
l.core.peers.removePeer(intf.peer.port)
l.mutex.Lock()
delete(l.interfaces, identity)
l.mutex.Unlock()
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return nil
} else {
return fmt.Errorf("interface '%s' doesn't exist or already shutdown", identity)
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}
}
func (ai *linkInterface) handler() {
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send := func(msg []byte) {
ai.tolink <- msg
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atomic.AddUint64(&ai.peer.bytesSent, uint64(len(msg)))
util.PutBytes(msg)
}
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for {
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timerInterval := tcp_ping_interval
timer := time.NewTimer(timerInterval)
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defer timer.Stop()
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select {
case p := <-ai.peer.linkOut:
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send(p)
continue
default:
}
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timer.Stop()
select {
case <-timer.C:
default:
}
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timer.Reset(timerInterval)
select {
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case _ = <-timer.C:
send([]byte{})
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case p := <-ai.peer.linkOut:
send(p)
continue
case r := <-ai.fromlink:
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ai.peer.handlePacket(r)
ai.link.core.switchTable.idleIn <- ai.peer.port
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case <-ai.shutdown:
return
}
}
}
*/