func main() {
flag.Parse()
if flag.NArg() < 1 {
fmt.Println("Usage: game6 num_runs hideTrace")
return
} else if flag.NArg() > 1 {
showPingPong = false
}
numRuns, _ := strconv.Atoi(flag.Arg(0))
c0, c1 := net.Pipe()
done := make(chan bool)
//create router and connect it to io conn
rot1 := router.New(router.StrID(), 32, router.BroadcastPolicy)
go rot1.ConnectRemote(c0, router.GobMarshaling, router.XOnOffFlowController)
//hook up Pinger and Ponger
newPinger(rot1, done, numRuns)
//create router and connect it to io conn
rot2 := router.New(router.StrID(), 32, router.BroadcastPolicy)
rot2.ConnectRemote(c1, router.GobMarshaling, router.XOnOffFlowController)
//hook up Ponger
newPonger(rot2, done)
//wait for ping-pong to finish
<-done
<-done
}
func test_async_router() {
//create a async router by setting buffer size to UnlimitedBuffer(-1) in router.New()
rout1 := router.New(router.IntID(), router.UnlimitedBuffer, router.BroadcastPolicy /* , "router1", router.ScopeLocal*/)
rout2 := router.New(router.IntID(), router.UnlimitedBuffer, router.BroadcastPolicy /* , "router2", router.ScopeLocal*/)
rout1.Connect(rout2)
chi1 := make(chan string)
chi2 := make(chan string)
chi3 := make(chan string)
cho := make(chan string)
bound := make(chan *router.BindEvent, 1)
//when attaching sending chan, add a (chan BindEvent) for notifying recver connecting
rout1.AttachSendChan(router.IntID(10), cho, bound)
rout1.AttachRecvChan(router.IntID(10), chi1)
rout2.AttachRecvChan(router.IntID(10), chi2)
rout2.AttachRecvChan(router.IntID(10), chi3)
//wait for some recvers connecting
for {
if (<-bound).Count == 2 {
break
}
}
//because we use async router, sending on those router attached channels
//will never block. we do not need spawn goroutines in the following
//go func() {
cho <- "hello1"
cho <- "hello2"
cho <- "hello3"
cho <- "from router1/src"
close(cho)
//}()
//go func() {
for v := range chi1 {
fmt.Println("router1/sink1 got: ", v)
}
//}()
//go func() {
for v := range chi2 {
fmt.Println("router2/sink2 got: ", v)
}
//}()
//go func() {
i := 0
for v := range chi3 {
fmt.Println("router2/sink3 got: ", v)
i++
if i == 2 {
rout2.DetachChan(router.IntID(10), chi3)
}
}
//}()
rout1.Close()
rout2.Close()
}
func main() {
flag.Parse()
if flag.NArg() < 1 {
fmt.Println("Usage: game4 num_runs hideTrace")
return
} else if flag.NArg() > 1 {
showPingPong = false
}
//clean up test sock
addr := "/tmp/pingpong.test"
os.Remove(addr)
//
numRuns, _ := strconv.Atoi(flag.Arg(0))
done := make(chan bool)
connNow := make(chan bool)
//start two goroutines to setup a unix sock connection
//connect two routers thru unix sock
//and then hook up Pinger and Ponger to the routers
go func() { //setup Pinger sock conn
//wait for ponger up
<-connNow
//set up an io conn to ponger thru unix sock
addr := "/tmp/pingpong.test"
conn, _ := net.Dial("unix", addr)
fmt.Println("ping conn up")
//create router and connect it to io conn
rot := router.New(router.StrID(), 32, router.BroadcastPolicy /*, "pinger", router.ScopeLocal*/)
rot.ConnectRemote(conn, router.JsonMarshaling)
//hook up Pinger and Ponger
newPinger(rot, done, numRuns)
}()
go func() { //setup Ponger sock conn
//wait to set up an io conn thru unix sock
l, _ := net.Listen("unix", addr)
connNow <- true //notify pinger that ponger's ready to accept
conn, _ := l.Accept()
fmt.Println("pong conn up")
//create router and connect it to io conn
rot := router.New(router.StrID(), 32, router.BroadcastPolicy /*, "ponger", router.ScopeLocal*/)
rot.ConnectRemote(conn, router.JsonMarshaling)
//hook up Ponger
newPonger(rot, done)
}()
//wait for ping-pong to finish
<-done
<-done
}
func test_StrId() {
rout := router.New(router.StrID(), 32, router.BroadcastPolicy)
chi1 := make(chan string)
chi2 := make(chan string)
cho := make(chan string)
done := make(chan bool)
rout.AttachSendChan(router.StrID("test"), cho)
rout.AttachRecvChan(router.StrID("test"), chi1)
rout.AttachRecvChan(router.StrID("test"), chi2)
go func() {
cho <- "hello"
cho <- "from StrID"
close(cho)
}()
go func() {
for v := range chi1 {
fmt.Println("StrId/sink1 got: ", v)
}
done <- true
}()
go func() {
for v := range chi2 {
fmt.Println("StrId/sink2 got: ", v)
}
done <- true
}()
<-done
<-done
}
func main() {
flag.Parse()
if flag.NArg() < 1 {
fmt.Println("Usage: game5 num_runs hideTrace")
return
} else if flag.NArg() > 1 {
showPingPong = false
}
numRuns, _ := strconv.Atoi(flag.Arg(0))
done := make(chan bool)
connNow := make(chan bool)
//start two goroutines to setup a unix sock connection
//connect two routers thru unix sock
//and then hook up Pinger and Ponger to the routers
go func() { //setup Pinger sock conn
//wait for ponger up
<-connNow
//set up an io conn to ponger thru tcp sock
conn, _ := net.Dial("tcp", "[::]:9099")
fmt.Println("ping conn up")
//create router and connect it to io conn
rot := router.New(router.StrID(), 32, router.BroadcastPolicy)
rot.ConnectRemote(conn, router.GobMarshaling, router.XOnOffFlowController)
//hook up Pinger and Ponger
newPinger(rot, done, numRuns)
}()
go func() { //setup Ponger sock conn
//wait to set up an io conn thru tcp sock
l, _ := net.Listen("tcp", ":9099")
connNow <- true //notify pinger that ponger's ready to accept
conn, _ := l.Accept()
fmt.Println("pong conn up")
//create router and connect it to io conn
rot := router.New(router.StrID(), 32, router.BroadcastPolicy)
rot.ConnectRemote(conn, router.GobMarshaling, router.XOnOffFlowController)
//hook up Ponger
newPonger(rot, done)
}()
//wait for ping-pong to finish
<-done
<-done
}
func test_notification() {
rout := router.New(router.StrID(), 32, router.BroadcastPolicy)
chi1 := make(chan string)
chi2 := make(chan string)
chiN := make(chan *router.ChanInfoMsg)
cho := make(chan string)
bound := make(chan *router.BindEvent, 1)
done := make(chan bool)
//subscribe to recver attach events
rout.AttachRecvChan(rout.SysID(router.SubId), chiN)
//
rout.AttachSendChan(router.StrID("test"), cho, bound)
rout.AttachRecvChan(router.StrID("test"), chi1)
rout.AttachRecvChan(router.StrID("test"), chi2)
//wait for two recvers to connect
for {
if (<-bound).Count == 2 {
break
}
}
go func() {
cho <- "hello1"
cho <- "hello2"
cho <- "hello3"
cho <- "from notif"
close(cho)
}()
go func() {
for v := range chi1 {
fmt.Println("notif/sink1 got: ", v)
}
done <- true
}()
go func() {
for v := range chi2 {
fmt.Println("notif/sink2 got: ", v)
rout.DetachChan(router.StrID("test"), chi2)
}
done <- true
}()
go func() {
count := 0
for m := range chiN {
for _, v := range m.Info {
fmt.Println("got sub notif: ", v.Id)
}
count++
if count >= 2 {
break
}
}
done <- true
}()
<-done
<-done
<-done
rout.Close()
}
func main() {
flag.Parse()
if flag.NArg() < 2 {
fmt.Println("Usage: client ServiceName numRuns")
return
}
svcName := flag.Arg(0)
numRuns, _ := strconv.Atoi(flag.Arg(1))
conn1, _ := net.Dial("unix", ServantAddr1)
fmt.Println("conn to servant1 up")
conn2, _ := net.Dial("unix", ServantAddr2)
fmt.Println("conn to servant2 up")
//create router and connect it to both active and standby servants
rot := router.New(router.StrID(), 32, router.BroadcastPolicy /* , "cli", router.ScopeLocal*/)
proxy1 := router.NewProxy(rot, "proxy1", nil, nil)
proxy2 := router.NewProxy(rot, "proxy2", nil, nil)
proxy1.ConnectRemote(conn1, router.GobMarshaling, router.XOnOffFlowController)
proxy2.ConnectRemote(conn2, router.GobMarshaling, router.XOnOffFlowController)
reqChan := make(chan string)
rspChan := make(chan string)
bindChan := make(chan *router.BindEvent, 1)
rot.AttachSendChan(router.StrID("/App/"+svcName+"/Request"), reqChan, bindChan)
rot.AttachRecvChan(router.StrID("/App/"+svcName+"/Response"), rspChan)
//make sure client connect to 2 servants before sending requests
for {
if (<-bindChan).Count > 1 {
break
}
}
cont := true
for i := 0; i < numRuns && cont; i++ {
req := fmt.Sprintf("request %d", i)
fmt.Printf("client sent request [%s] to serivce [%s]\n", req, svcName)
reqChan <- req
timer := time.NewTimer(6e8) //the wait for response will time out in less than 1 sec
select {
case rsp, chOpen := <-rspChan:
if !chOpen {
fmt.Println("client response closed, exit")
cont = false
} else {
fmt.Printf("client recv response ( %s )\n", rsp)
}
case <-timer.C:
fmt.Printf("time out for reqest [%s]\n", req)
i-- //resend it
}
timer.Stop()
}
fmt.Printf("client exit\n")
conn1.Close()
conn2.Close()
rot.Close()
}
func main() {
flag.Parse()
if flag.NArg() < 1 {
fmt.Println("Usage: game3 num_runs hideTrace")
return
} else if flag.NArg() > 1 {
showPingPong = false
}
numRuns, _ := strconv.Atoi(flag.Arg(0))
//alloc two routers to connect them
rot1 := router.New(router.StrID(), 32, router.BroadcastPolicy)
rot2 := router.New(router.StrID(), 32, router.BroadcastPolicy)
rot1.Connect(rot2)
done := make(chan bool)
//hook up Pinger and Ponger
newPinger(rot1, done, numRuns)
newPonger(rot2, done)
//wait for ping-pong to finish
<-done
<-done
}
func test_PathId() {
rout := router.New(router.PathID(), 32, router.BroadcastPolicy)
chi1 := make(chan string)
chi2 := make(chan string)
chi3 := make(chan string)
cho1 := make(chan string)
cho2 := make(chan string)
cho3 := make(chan string)
done := make(chan bool)
rout.AttachSendChan(router.PathID("/sport/basketball"), cho1)
rout.AttachSendChan(router.PathID("/sport/baseball"), cho2)
rout.AttachSendChan(router.PathID("/sport/basketball/Jordan"), cho3)
rout.AttachRecvChan(router.PathID("/sport/*"), chi1) //subscribe to all sports news
rout.AttachRecvChan(router.PathID("/sport/baseball"), chi2)
rout.AttachRecvChan(router.PathID("/sport/basketball*"), chi3) //subscribe to all basketball news
go func() {
cho1 <- "want to play"
cho1 <- "basketball?"
close(cho1)
}()
go func() {
cho2 <- "want to watch"
cho2 <- "baseball?"
close(cho2)
}()
go func() {
cho3 <- "hello there, anybody know"
cho3 <- "will Michael Jordan play again?"
close(cho3)
}()
go func() {
for v := range chi1 {
fmt.Println("sport fan read: ", v)
}
done <- true
}()
go func() {
for v := range chi2 {
fmt.Println("baseball fan read: ", v)
}
done <- true
}()
go func() {
for v := range chi3 {
fmt.Println("basketball fan read: ", v)
}
done <- true
}()
<-done
<-done
<-done
}
func NewServant(n string, role ServantRole, done chan bool) *Servant {
s := new(Servant)
s.Rot = router.New(router.StrID(), 32, router.BroadcastPolicy /* , n, router.ScopeLocal*/)
s.role = role
s.name = n
//start system tasks, ServiceTask will be created when clients connect
NewSysMgrTask(s.Rot, n, role)
NewDbTask(s.Rot, n, role)
NewFaultMgrTask(s.Rot, n, role)
//run Servant mainloop to wait for client connection
go s.Run(done)
return s
}
func test_IntId() {
rout := router.New(router.IntID(), 32, router.BroadcastPolicy)
chi1 := make(chan string)
chi2 := make(chan string)
cho1 := make(chan string)
cho2 := make(chan string)
done := make(chan bool)
rout.AttachSendChan(router.IntID(10), cho1)
rout.AttachSendChan(router.IntID(10), cho2)
rout.AttachRecvChan(router.IntID(10), chi1)
rout.AttachRecvChan(router.IntID(10), chi2)
go func() {
cho1 <- "hello"
cho1 <- "from IntID/src1"
close(cho1)
}()
go func() {
for v := range chi1 {
fmt.Println("IntId/sink1 got: ", v)
}
done <- true
}()
go func() {
for v := range chi2 {
fmt.Println("IntId/sink2 got: ", v)
}
done <- true
}()
go func() {
cho2 <- "hello"
cho2 <- "from IntID/src2"
close(cho2)
}()
<-done
<-done
}
func test_flow_control() {
listening := make(chan string)
srvdone := make(chan int)
clidone := make(chan int)
//run server
go func() {
l, err := net.Listen("tcp", ":0")
listening <- l.Addr().String()
conn, err := l.Accept()
if err != nil {
fmt.Println(err)
return
}
fmt.Println("server start")
rout1 := router.New(router.IntID(), 5, router.BroadcastPolicy /* , "router1", router.ScopeLocal*/)
//set FlowControl to turn on flow control on connection stream
_, err = rout1.ConnectRemote(conn, router.GobMarshaling, router.WindowFlowController)
if err != nil {
fmt.Println(err)
} else {
cho := make(chan int)
bound := make(chan *router.BindEvent, 1)
done := make(chan bool)
rout1.AttachSendChan(router.IntID(10), cho, bound)
//wait for recvers connecting
<-bound
//start sending msgs
go func() {
for i := 0; i < 30; i++ {
cho <- i
fmt.Println("client sent: ", i)
time.Sleep(1e8)
}
close(cho)
done <- true
}()
<-done
}
<-clidone
conn.Close()
l.Close()
srvdone <- 1
rout1.Close()
}()
//run client
go func() {
addr := <-listening // wait for server to start
dialaddr := "127.0.0.1" + addr[strings.LastIndex(addr, ":"):]
conn, err := net.Dial("tcp", dialaddr)
if err != nil {
fmt.Println(err)
}
fmt.Println("client connect")
rout2 := router.New(router.IntID(), 5, router.BroadcastPolicy /* , "router2", router.ScopeLocal*/)
//turn on flow control
_, err = rout2.ConnectRemote(conn, router.GobMarshaling, router.WindowFlowController)
if err != nil {
fmt.Println(err)
} else {
chi2 := make(chan int)
chi3 := make(chan int)
done := make(chan bool)
rout2.AttachRecvChan(router.IntID(10), chi2, 3)
rout2.AttachRecvChan(router.IntID(10), chi3)
go func() {
for v := range chi2 {
fmt.Println("router2/sink2 got: ", v)
if v < 10 {
time.Sleep(1e9)
}
}
done <- true
}()
go func() {
i := 0
for v := range chi3 {
fmt.Println("router2/sink3 got: ", v)
i++
if i == 2 {
rout2.DetachChan(router.IntID(10), chi3)
}
}
done <- true
}()
<-done
<-done
}
clidone <- 1
conn.Close()
rout2.Close()
}()
<-srvdone
}
func test_remote_conn() {
listening := make(chan string)
srvdone := make(chan int)
clidone := make(chan int)
//run server
go func() {
l, err := net.Listen("tcp", ":0")
listening <- l.Addr().String()
conn, err := l.Accept()
if err != nil {
fmt.Println(err)
return
}
fmt.Println("server start")
//
rout1 := router.New(router.IntID(), 32, router.BroadcastPolicy /* , "router1", router.ScopeLocal*/)
_, err = rout1.ConnectRemote(conn, router.JsonMarshaling)
if err != nil {
fmt.Println(err)
} else {
cho := make(chan string)
chi1 := make(chan string)
bound := make(chan *router.BindEvent, 1)
done := make(chan bool)
rout1.AttachSendChan(router.IntID(10), cho, bound)
rout1.AttachRecvChan(router.IntID(10), chi1)
//wait for recvers connecting
for {
if (<-bound).Count == 2 {
break
}
}
go func() {
cho <- "hello1"
cho <- "hello2"
cho <- "hello3"
cho <- "hello4"
cho <- "from router1/src"
close(cho)
}()
go func() {
for v := range chi1 {
fmt.Println("router1/sink1 got: ", v)
}
done <- true
}()
<-done
}
<-clidone
conn.Close()
l.Close()
srvdone <- 1
rout1.Close()
}()
//run client
go func() {
addr := <-listening // wait for server to start
dialaddr := "127.0.0.1" + addr[strings.LastIndex(addr, ":"):]
conn, err := net.Dial("tcp", dialaddr)
if err != nil {
fmt.Println(err)
}
fmt.Println("client connect")
//
rout2 := router.New(router.IntID(), 32, router.BroadcastPolicy /* , "router2", router.ScopeLocal*/)
_, err = rout2.ConnectRemote(conn, router.JsonMarshaling)
if err != nil {
fmt.Println(err)
} else {
chi2 := make(chan string)
chi3 := make(chan string)
done := make(chan bool)
rout2.AttachRecvChan(router.IntID(10), chi2)
rout2.AttachRecvChan(router.IntID(10), chi3)
go func() {
for v := range chi2 {
fmt.Println("router2/sink2 got: ", v)
}
done <- true
}()
go func() {
i := 0
for v := range chi3 {
fmt.Println("router2/sink3 got: ", v)
i++
if i == 2 {
rout2.DetachChan(router.IntID(10), chi3)
}
}
done <- true
}()
<-done
<-done
}
clidone <- 1
conn.Close()
rout2.Close()
}()
<-srvdone
}
func test_logger() {
rout1 := router.New(router.IntID(), 32, router.BroadcastPolicy, "router1", router.ScopeLocal)
rout2 := router.New(router.IntID(), 32, router.BroadcastPolicy, "router2", router.ScopeLocal)
rout1.Connect(rout2)
chi1 := make(chan string)
chi2 := make(chan string)
chi3 := make(chan string)
chiN := make(chan *router.ChanInfoMsg)
cho := make(chan string)
done := make(chan bool)
bound := make(chan *router.BindEvent, 1)
//subscribe to recver attach events
rout1.AttachRecvChan(rout1.SysID(router.SubId), chiN)
//when attaching sending chan, add a (chan BindEvent) for notifying recver connecting
rout1.AttachSendChan(router.IntID(10), cho, bound)
rout1.AttachRecvChan(router.IntID(10), chi1)
rout2.AttachRecvChan(router.IntID(10), chi2)
rout2.AttachRecvChan(router.IntID(10), chi3)
//wait for some recvers connecting
for {
if (<-bound).Count == 2 {
break
}
}
go func() {
cho <- "hello1"
cho <- "hello2"
cho <- "from router1/src"
close(cho)
}()
go func() {
for v := range chi1 {
fmt.Println("router1/sink1 got: ", v)
}
done <- true
}()
go func() {
for v := range chi2 {
fmt.Println("router2/sink2 got: ", v)
}
done <- true
}()
go func() {
i := 0
for v := range chi3 {
fmt.Println("router2/sink3 got: ", v)
i++
if i == 2 {
rout2.DetachChan(router.IntID(10), chi3)
}
}
done <- true
}()
go func() {
count := 0
for m := range chiN {
for _, v := range m.Info {
fmt.Println("got sub notif: ", v.Id)
}
count++
if count >= 2 {
break
}
}
done <- true
}()
//waiting goroutines can exit
<-done
<-done
<-done
<-done
rout1.Close()
rout2.Close()
}
func main() {
l, err := net.Listen("tcp", ":0")
if err != nil {
fmt.Println(err)
return
}
fmt.Println(l.Addr().String())
subjMap := make(map[string]*Subject)
rot := router.New(router.StrID(), 32, router.BroadcastPolicy /*, "chatsrv", router.ScopeLocal*/)
//start server mainloop in a separate goroutine, and recv client conn in main goroutine
go func() {
//subscribe to remote publications, so learn what subjects are created
pubChan := make(chan *router.ChanInfoMsg)
//attach a recv chan with a "chan BindEvent"
//this recv chan will not be closed when all senders detach
bindChan := make(chan *router.BindEvent, 1)
rot.AttachRecvChan(rot.NewSysID(router.PubId, router.ScopeRemote), pubChan, bindChan)
//stopChan to notify when all people leave a subject
stopChan := make(chan string, 36)
for {
select {
case idstr := <-stopChan:
delete(subjMap, idstr)
case pub := <-pubChan:
//process recved client publication of subjects
for _, v := range pub.Info {
id := v.Id.(*router.StrId) //get the real id type
subj, ok := subjMap[id.Val]
if ok {
continue
}
fmt.Printf("add subject: %v\n", id.Val)
//add a new subject with ScopeRemote, so that msgs are forwarded
//to peers in connected routers
id.ScopeVal = router.ScopeRemote
id.MemberVal = router.MemberLocal
subj = newSubject()
subjMap[id.Val] = subj
//subscribe to new subjects, forward recved msgs to other
rot.AttachSendChan(id, subj.sendChan)
rot.AttachRecvChan(id, subj.recvChan)
//start forwarding
go func(subjname string) {
for val := range subj.recvChan {
fmt.Printf("chatsrv forward: subject[%v], msg[%s]\n", subjname, val)
subj.sendChan <- val
}
stopChan <- subjname
fmt.Printf("chatsrv stop forwarding for : %v\n", subjname)
}(id.Val)
}
}
}
}()
//keep accepting client conn and connect local router to it
for {
conn, err := l.Accept()
if err != nil {
fmt.Println(err)
return
}
fmt.Println("one client connect")
_, err = rot.ConnectRemote(conn, router.JsonMarshaling)
if err != nil {
fmt.Println(err)
return
}
}
//in fact never reach here
rot.Close()
l.Close()
}