func statsdLoop(addr string, prefix string, interval time.Duration) {
lastStats := make([]TopicStats, 0)
ticker := time.NewTicker(interval)
for {
select {
case <-ticker.C:
statsd := util.NewStatsdClient(addr, prefix)
err := statsd.CreateSocket()
if err != nil {
log.Printf("ERROR: failed to create UDP socket to statsd(%s)", statsd)
continue
}
log.Printf("STATSD: pushing stats to %s", statsd)
stats := nsqd.getStats()
for _, topic := range stats {
// try to find the topic in the last collection
lastTopic := TopicStats{}
for _, checkTopic := range lastStats {
if topic.TopicName == checkTopic.TopicName {
lastTopic = checkTopic
break
}
}
diff := topic.MessageCount - lastTopic.MessageCount
stat := fmt.Sprintf("topic.%s.message_count", topic.TopicName)
statsd.Incr(stat, int(diff))
stat = fmt.Sprintf("topic.%s.depth", topic.TopicName)
statsd.Gauge(stat, int(topic.Depth))
stat = fmt.Sprintf("topic.%s.backend_depth", topic.TopicName)
statsd.Gauge(stat, int(topic.BackendDepth))
for _, channel := range topic.Channels {
// try to find the channel in the last collection
lastChannel := ChannelStats{}
for _, checkChannel := range lastTopic.Channels {
if channel.ChannelName == checkChannel.ChannelName {
lastChannel = checkChannel
break
}
}
diff := channel.MessageCount - lastChannel.MessageCount
stat := fmt.Sprintf("topic.%s.channel.%s.message_count", topic.TopicName, channel.ChannelName)
statsd.Incr(stat, int(diff))
stat = fmt.Sprintf("topic.%s.channel.%s.depth", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, int(channel.Depth))
stat = fmt.Sprintf("topic.%s.channel.%s.backend_depth", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, int(channel.BackendDepth))
stat = fmt.Sprintf("topic.%s.channel.%s.in_flight_count", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, int(channel.InFlightCount))
stat = fmt.Sprintf("topic.%s.channel.%s.deferred_count", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, int(channel.DeferredCount))
diff = channel.RequeueCount - lastChannel.RequeueCount
stat = fmt.Sprintf("topic.%s.channel.%s.requeue_count", topic.TopicName, channel.ChannelName)
statsd.Incr(stat, int(diff))
diff = channel.TimeoutCount - lastChannel.TimeoutCount
stat = fmt.Sprintf("topic.%s.channel.%s.timeout_count", topic.TopicName, channel.ChannelName)
statsd.Incr(stat, int(diff))
stat = fmt.Sprintf("topic.%s.channel.%s.clients", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, len(channel.Clients))
}
}
lastStats = stats
statsd.Close()
}
}
ticker.Stop()
}
func (n *NSQd) statsdLoop() {
var lastMemStats runtime.MemStats
lastStats := make([]TopicStats, 0)
ticker := time.NewTicker(n.options.statsdInterval)
for {
select {
case <-n.exitChan:
goto exit
case <-ticker.C:
statsd := util.NewStatsdClient(n.options.statsdAddress, n.options.statsdPrefix)
err := statsd.CreateSocket()
if err != nil {
log.Printf("ERROR: failed to create UDP socket to statsd(%s)", statsd)
continue
}
log.Printf("STATSD: pushing stats to %s", statsd)
stats := n.getStats()
for _, topic := range stats {
// try to find the topic in the last collection
lastTopic := TopicStats{}
for _, checkTopic := range lastStats {
if topic.TopicName == checkTopic.TopicName {
lastTopic = checkTopic
break
}
}
diff := topic.MessageCount - lastTopic.MessageCount
stat := fmt.Sprintf("topic.%s.message_count", topic.TopicName)
statsd.Incr(stat, int64(diff))
stat = fmt.Sprintf("topic.%s.depth", topic.TopicName)
statsd.Gauge(stat, topic.Depth)
stat = fmt.Sprintf("topic.%s.backend_depth", topic.TopicName)
statsd.Gauge(stat, topic.BackendDepth)
for _, channel := range topic.Channels {
// try to find the channel in the last collection
lastChannel := ChannelStats{}
for _, checkChannel := range lastTopic.Channels {
if channel.ChannelName == checkChannel.ChannelName {
lastChannel = checkChannel
break
}
}
diff := channel.MessageCount - lastChannel.MessageCount
stat := fmt.Sprintf("topic.%s.channel.%s.message_count", topic.TopicName, channel.ChannelName)
statsd.Incr(stat, int64(diff))
stat = fmt.Sprintf("topic.%s.channel.%s.depth", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, channel.Depth)
stat = fmt.Sprintf("topic.%s.channel.%s.backend_depth", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, channel.BackendDepth)
stat = fmt.Sprintf("topic.%s.channel.%s.in_flight_count", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, int64(channel.InFlightCount))
stat = fmt.Sprintf("topic.%s.channel.%s.deferred_count", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, int64(channel.DeferredCount))
diff = channel.RequeueCount - lastChannel.RequeueCount
stat = fmt.Sprintf("topic.%s.channel.%s.requeue_count", topic.TopicName, channel.ChannelName)
statsd.Incr(stat, int64(diff))
diff = channel.TimeoutCount - lastChannel.TimeoutCount
stat = fmt.Sprintf("topic.%s.channel.%s.timeout_count", topic.TopicName, channel.ChannelName)
statsd.Incr(stat, int64(diff))
stat = fmt.Sprintf("topic.%s.channel.%s.clients", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, int64(len(channel.Clients)))
}
}
lastStats = stats
if *statsdMemStats {
var memStats runtime.MemStats
runtime.ReadMemStats(&memStats)
// sort the GC pause array
length := 256
if len(memStats.PauseNs) <= 256 {
length = int(memStats.NumGC)
}
gcPauses := make(Uint64Slice, length)
copy(gcPauses, memStats.PauseNs[:])
sort.Sort(gcPauses)
statsd.Gauge("mem.heap_objects", int64(memStats.HeapObjects))
statsd.Gauge("mem.heap_idle_bytes", int64(memStats.HeapIdle))
statsd.Gauge("mem.heap_in_use_bytes", int64(memStats.HeapInuse))
statsd.Gauge("mem.heap_released_bytes", int64(memStats.HeapReleased))
statsd.Gauge("mem.gc_pause_usec_100", int64(percentile(100.0, gcPauses, len(gcPauses))/1000))
statsd.Gauge("mem.gc_pause_usec_99", int64(percentile(99.0, gcPauses, len(gcPauses))/1000))
statsd.Gauge("mem.gc_pause_usec_95", int64(percentile(95.0, gcPauses, len(gcPauses))/1000))
statsd.Gauge("mem.next_gc_bytes", int64(memStats.NextGC))
statsd.Incr("mem.gc_runs", int64(memStats.NumGC-lastMemStats.NumGC))
lastMemStats = memStats
}
statsd.Close()
}
}
exit:
ticker.Stop()
}
func (n *NSQD) statsdLoop() {
var lastMemStats runtime.MemStats
lastStats := make([]TopicStats, 0)
ticker := time.NewTicker(n.opts.StatsdInterval)
for {
select {
case <-n.exitChan:
goto exit
case <-ticker.C:
statsd := util.NewStatsdClient(n.opts.StatsdAddress, n.opts.StatsdPrefix)
err := statsd.CreateSocket()
if err != nil {
n.logf("ERROR: failed to create UDP socket to statsd(%s)", statsd)
continue
}
n.logf("STATSD: pushing stats to %s", statsd)
stats := n.GetStats()
for _, topic := range stats {
// try to find the topic in the last collection
lastTopic := TopicStats{}
for _, checkTopic := range lastStats {
if topic.TopicName == checkTopic.TopicName {
lastTopic = checkTopic
break
}
}
diff := topic.MessageCount - lastTopic.MessageCount
stat := fmt.Sprintf("topic.%s.message_count", topic.TopicName)
statsd.Incr(stat, int64(diff))
stat = fmt.Sprintf("topic.%s.depth", topic.TopicName)
statsd.Gauge(stat, topic.Depth)
stat = fmt.Sprintf("topic.%s.backend_depth", topic.TopicName)
statsd.Gauge(stat, topic.BackendDepth)
for _, item := range topic.E2eProcessingLatency.Percentiles {
stat = fmt.Sprintf("topic.%s.e2e_processing_latency_%.0f", topic.TopicName, item["quantile"]*100.0)
// We can cast the value to int64 since a value of 1 is the
// minimum resolution we will have, so there is no loss of
// accuracy
statsd.Gauge(stat, int64(item["value"]))
}
for _, channel := range topic.Channels {
// try to find the channel in the last collection
lastChannel := ChannelStats{}
for _, checkChannel := range lastTopic.Channels {
if channel.ChannelName == checkChannel.ChannelName {
lastChannel = checkChannel
break
}
}
diff := channel.MessageCount - lastChannel.MessageCount
stat := fmt.Sprintf("topic.%s.channel.%s.message_count", topic.TopicName, channel.ChannelName)
statsd.Incr(stat, int64(diff))
stat = fmt.Sprintf("topic.%s.channel.%s.depth", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, channel.Depth)
stat = fmt.Sprintf("topic.%s.channel.%s.backend_depth", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, channel.BackendDepth)
stat = fmt.Sprintf("topic.%s.channel.%s.in_flight_count", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, int64(channel.InFlightCount))
stat = fmt.Sprintf("topic.%s.channel.%s.deferred_count", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, int64(channel.DeferredCount))
diff = channel.RequeueCount - lastChannel.RequeueCount
stat = fmt.Sprintf("topic.%s.channel.%s.requeue_count", topic.TopicName, channel.ChannelName)
statsd.Incr(stat, int64(diff))
diff = channel.TimeoutCount - lastChannel.TimeoutCount
stat = fmt.Sprintf("topic.%s.channel.%s.timeout_count", topic.TopicName, channel.ChannelName)
statsd.Incr(stat, int64(diff))
stat = fmt.Sprintf("topic.%s.channel.%s.clients", topic.TopicName, channel.ChannelName)
statsd.Gauge(stat, int64(len(channel.Clients)))
for _, item := range channel.E2eProcessingLatency.Percentiles {
stat = fmt.Sprintf("topic.%s.channel.%s.e2e_processing_latency_%.0f", topic.TopicName, channel.ChannelName, item["quantile"]*100.0)
statsd.Gauge(stat, int64(item["value"]))
}
}
}
lastStats = stats
if n.opts.StatsdMemStats {
var memStats runtime.MemStats
runtime.ReadMemStats(&memStats)
gcPauses := recentGCPauses(memStats, int(memStats.NumGC-lastMemStats.NumGC))
sort.Sort(gcPauses)
statsd.Gauge("mem.heap_objects", int64(memStats.HeapObjects))
statsd.Gauge("mem.heap_idle_bytes", int64(memStats.HeapIdle))
statsd.Gauge("mem.heap_in_use_bytes", int64(memStats.HeapInuse))
statsd.Gauge("mem.heap_released_bytes", int64(memStats.HeapReleased))
statsd.Gauge("mem.gc_pause_usec_100", int64(percentile(100.0, gcPauses, len(gcPauses))/1000))
statsd.Gauge("mem.gc_pause_usec_99", int64(percentile(99.0, gcPauses, len(gcPauses))/1000))
statsd.Gauge("mem.gc_pause_usec_95", int64(percentile(95.0, gcPauses, len(gcPauses))/1000))
statsd.Gauge("mem.next_gc_bytes", int64(memStats.NextGC))
statsd.Incr("mem.gc_runs", int64(memStats.NumGC-lastMemStats.NumGC))
lastMemStats = memStats
}
statsd.Close()
}
}
exit:
ticker.Stop()
}
