func main() {
tm.Clear()
tm.MoveCursor(0, 0)
chart := tm.NewLineChart(100, 20)
data := new(tm.DataTable)
data.AddColumn("Time")
data.AddColumn("Sin(x)")
data.AddColumn("Cos(x+1)")
for i := 0.1; i < 10; i += 0.1 {
data.AddRow(i, math.Sin(i), math.Cos(i+1))
}
tm.Println(chart.Draw(data))
tm.Flush()
}
func main() {
var (
errCh = make(chan error, 16)
receivedCh = make(chan int, 1024)
sentCh = make(chan int, 1024)
sent = 0
lastSent = 0
received = 0
lastReceived = 0
)
// read params (server address:port, qos settings, number of publishers, number of subscribers)
flag.Parse()
// generate topics in advance, so we can run the subscribers before starting to publish
for i := 0; i < *numTop; i++ {
newTopic()
}
//
// subscribe to topics
//
// TODO: multiple subscribers.
// initialise a timeout (if no messages are received in the given time since the last publish.)
timeout := time.NewTimer(10 * time.Second)
resetSubTimeout := func() {
timeout.Reset(time.Duration(*subTimeout) * time.Second)
}
// discarding received messages
messageHandler := func(client *mqtt.Client, m mqtt.Message) {
if string(m.Payload()) == "hello world" {
receivedCh <- 1
resetSubTimeout() // reset timeout
}
}
// prepare filter from topics and qos
filters := map[string]byte{}
for _, topic := range getTopics() {
fmt.Printf("Created topic %s with qos %v\n", topic, *qos)
filters[topic] = byte(*qos)
}
// multisubscribers
fmt.Println("Connecting subscribers...")
for i := 0; i < *numSub; i++ {
subscriber := newClient()
if token := subscriber.client.Connect(); token.Wait() && token.Error() != nil {
errCh <- token.Error()
}
defer subscriber.client.Disconnect(250)
token := subscriber.client.SubscribeMultiple(filters, messageHandler)
if token.Wait() && token.Error() != nil {
errCh <- token.Error()
}
}
//
// Publish to topics
//
// set value for timeout
timeout = time.NewTimer(time.Duration(*subTimeout) * time.Second)
go func() {
for {
select {
case <-timeout.C:
errCh <- fmt.Errorf("Subscriber timeout.. no more messages?")
}
}
}()
// publishers
for i := 0; i < *numPub; i++ {
go func() {
c := newClient()
if token := c.client.Connect(); token.Wait() && token.Error() != nil {
errCh <- token.Error()
}
defer c.client.Disconnect(100)
// publish (sequential per client)
topics := getTopics()
for k := 0; k < *numMessages; k++ {
topic := topics[k%len(topics)]
token := c.client.Publish(topic, byte(*qos), *retained, "hello world")
if token.Wait() && token.Error() != nil {
errCh <- token.Error()
}
sentCh <- 1
time.Sleep(time.Duration(*pubDelay) * time.Millisecond)
}
}()
}
// creating fancy output
// start := time.Now()
redraw := time.NewTicker(100 * time.Millisecond)
if *nograph {
redraw = time.NewTicker(1 * time.Second)
}
row := 0.0
// table
data := new(tm.DataTable)
data.AddColumn("Time (sec)")
data.AddColumn("Sent")
data.AddColumn("Received")
for {
select {
case <-redraw.C:
if !*nograph {
tm.Clear()
tm.Printf("[Published : Received]: [%v : %v]\n\n", sent, received)
row += 1.0
data.AddRow(row/10.0, float64(sent), float64(received))
tm.Print(tm.NewLineChart(tm.Width()-4, tm.Height()-6).Draw(data))
tm.Flush()
} else {
if sent != lastSent || received != lastReceived {
fmt.Printf("[Published : Received]: [%v : %v]\n", sent, received)
lastSent, lastReceived = sent, received
}
}
case e := <-errCh:
fmt.Println(e.Error())
return
case s := <-sentCh:
sent += s
case r := <-receivedCh:
received += r
}
}
}
func StatQueue(writeQ bool) error {
var myresults results
var wg sync.WaitGroup
for id, sl := range record.RecordByThread {
wg.Add(1)
go func(tid string, rs []*record.Record) {
defer wg.Done()
for _, r := range rs {
if !window.InCurrentWindow(r.Time) {
continue
}
if len(r.Raw) < 151 {
continue
}
txt := strings.Split(r.Raw[60:150], ">")
if len(txt) < 2 {
continue
}
tokens := strings.Split(txt[1], " ") // 60:140 to limit the scope of search, with reasonable margins
if len(tokens) < 3 {
continue
}
if writeQ {
if ((tokens[1] == "Queue") && (tokens[2] == "command")) ||
((tokens[1] == "Dequeue") && (tokens[2] == "and") && (tokens[3] == "execute")) {
//2015/08/04 15:19:59.904847 magap302 masterag-11298 MDW INFO <SEI_MAAdminSequence.cpp#223 TID#13> Queue command 0x2aacbf979400 [Command#14015: kSEIBELibLoaded : BE->MAG:Notify the Master Agent that a lib has been loaded (version 1)^@] (from BENT0UCL4VXODY to masterag); Command sequence queue size: 0
backToken := strings.Split(r.Raw[len(r.Raw)-40:len(r.Raw)], " ")
last := len(backToken) - 1
txt1 := strings.Join(backToken[last-2:last], " ")
if txt1 == "queue size:" {
if s, err := strconv.Atoi(backToken[last]); err == nil {
myresults.Lock()
myresults.HasRecords = append(myresults.HasRecords, &result{qSize: s, tid: tid, r: r})
myresults.Unlock()
}
}
}
} else {
if (tokens[1] == "Scheduling") && (tokens[3] == "command") && (tokens[6] == "Read-only") {
//2015/12/03 05:07:12.577382 magap302 masterag-32357 MDW INFO <SEI_MAAdminSequence.cpp#196 TID#13> Scheduling the command in the Read-only command sequencer pool. Pool queue size: 393
backToken := strings.Split(r.Raw[len(r.Raw)-40:len(r.Raw)], " ")
last := len(backToken) - 1
txt1 := strings.Join(backToken[last-2:last], " ")
if txt1 == "queue size:" {
if s, err := strconv.Atoi(backToken[last]); err == nil {
myresults.Lock()
myresults.HasRecords = append(myresults.HasRecords, &result{qSize: s, tid: tid, r: r})
myresults.Unlock()
}
}
}
}
}
}(id, sl)
}
wg.Wait()
sort.Sort(record.ByHasRecordTime{myresults.HasRecords})
// Build chart
chart := tm.NewLineChart(tm.Width()-10, tm.Height()-10)
data := new(tm.DataTable)
data.AddColumn("Seconds")
data.AddColumn("QMax")
data.AddColumn("QMin")
type prec struct {
max int
min int
}
t0 := myresults.HasRecords[0].(*result).r.Time
tmax := myresults.HasRecords[len(myresults.HasRecords)-1].(*result).r.Time
indexMax := int(tmax.Sub(t0).Seconds())
qmaxTime := time.Unix(0, 0)
qmax := 0
m := make(map[int]prec)
for _, v := range myresults.HasRecords {
r := v.(*result)
d := int(r.r.Time.Sub(t0).Seconds())
p, ok := m[d]
if !ok {
p = prec{r.qSize, r.qSize}
} else {
if p.max < r.qSize {
p.max = r.qSize
}
if p.min > r.qSize {
p.min = r.qSize
}
}
m[d] = p
if p.max > qmax {
qmax = p.max
qmaxTime = r.GetRecord().Time
}
}
for t := 0; t <= int(indexMax); t++ {
data.AddRow(float64(t), float64(m[t].max), float64(m[t].min))
}
tm.Println(chart.Draw(data))
tm.Flush()
fmt.Printf("Qmax=%d at %s\n", qmax, qmaxTime.Format(utils.DateFormat))
return nil
}
//Display the distribution for a given command
func StatCmdDistribution(cmdName string) {
for _, ss := range buildStats() {
if ss.cmd == cmdName {
// Build chart
chart := tm.NewLineChart(tm.Width()-10, tm.Height()-33)
data := new(tm.DataTable)
data.AddColumn("CmdCount")
data.AddColumn("Duration")
for i, rec := range ss.records {
if d, err := rec.GetCmdDuration(); err != nil {
data.AddRow(float64(i), -1.)
} else {
data.AddRow(float64(i), float64(d.Nanoseconds()/1000000))
}
}
tm.Println(chart.Draw(data))
tm.Flush()
// Statistics for that particular command
{
w := new(tabwriter.Writer)
w.Init(os.Stdout, 20, 0, 2, ' ', tabwriter.AlignRight)
fmt.Fprintln(w, "Command\tcount\tmiss\tmin (ms)\tmax (ms)\tavg (ms)\t95% (ms)\t")
c := int64(len(ss.records) - ss.incomplete)
i95 := c * 95 / 100
if c == 0 {
c = 1
}
percentile95 := int64(-1)
if d95, err := ss.records[i95].GetCmdDuration(); err == nil {
percentile95 = d95.Nanoseconds()
}
fmt.Fprintf(w, "%s\t%d\t%d\t%d\t%d\t%d\t%d\t\n", ss.cmd, len(ss.records), ss.incomplete, ss.min.Nanoseconds()/1000000, ss.max.Nanoseconds()/1000000, ss.sum.Nanoseconds()/1000000/c, percentile95/1000000)
fmt.Fprintln(w)
w.Flush()
}
// The 10 slowest occurence
{
w := new(tabwriter.Writer)
w.Init(os.Stdout, 5, 0, 2, ' ', tabwriter.TabIndent)
fmt.Fprintln(w, "Duration(ms)\tcmd\t")
min := 10
if len(ss.records) < 10 {
min = len(ss.records)
}
for i := 1; i <= min; i++ {
rec := ss.records[len(ss.records)-i]
if d, err := rec.GetCmdDuration(); err != nil {
fmt.Fprintf(w, "-\t%s\t\n", rec.Raw)
} else {
fmt.Fprintf(w, "%d\t%s\t\n", d.Nanoseconds()/1000000, rec.Raw)
}
}
fmt.Fprintln(w)
w.Flush()
}
return
}
}
}