func readAerospikeStats( stats map[string]string, acc inputs.Accumulator, host string, namespace string, ) { fields := make(map[string]interface{}) tags := map[string]string{ "aerospike_host": host, "namespace": "_service", } if namespace != "" { tags["namespace"] = namespace } for key, value := range stats { // We are going to ignore all string based keys val, err := strconv.ParseInt(value, 10, 64) if err == nil { if strings.Contains(key, "-") { key = strings.Replace(key, "-", "_", -1) } fields[key] = val } } acc.AddFields("aerospike", fields, tags) }
func gatherOverview(r *RabbitMQ, acc inputs.Accumulator, errChan chan error) { overview := &OverviewResponse{} err := r.requestJSON("/api/overview", &overview) if err != nil { errChan <- err return } if overview.QueueTotals == nil || overview.ObjectTotals == nil || overview.MessageStats == nil { errChan <- fmt.Errorf("Wrong answer from rabbitmq. Probably auth issue") return } tags := map[string]string{"url": r.URL} if r.Name != "" { tags["name"] = r.Name } fields := map[string]interface{}{ "messages": overview.QueueTotals.Messages, "messages_ready": overview.QueueTotals.MessagesReady, "messages_unacked": overview.QueueTotals.MessagesUnacknowledged, "channels": overview.ObjectTotals.Channels, "connections": overview.ObjectTotals.Connections, "consumers": overview.ObjectTotals.Consumers, "exchanges": overview.ObjectTotals.Exchanges, "queues": overview.ObjectTotals.Queues, "messages_acked": overview.MessageStats.Ack, "messages_delivered": overview.MessageStats.Deliver, "messages_published": overview.MessageStats.Publish, } acc.AddFields("rabbitmq_overview", fields, tags) errChan <- nil }
func gatherPoolStats(pool poolInfo, acc inputs.Accumulator) error { lines, err := internal.ReadLines(pool.ioFilename) if err != nil { return err } if len(lines) != 3 { return err } keys := strings.Fields(lines[1]) values := strings.Fields(lines[2]) keyCount := len(keys) if keyCount != len(values) { return fmt.Errorf("Key and value count don't match Keys:%v Values:%v", keys, values) } tag := map[string]string{"pool": pool.name} fields := make(map[string]interface{}) for i := 0; i < keyCount; i++ { value, err := strconv.ParseInt(values[i], 10, 64) if err != nil { return err } fields[keys[i]] = value } acc.AddFields("zfs_pool", fields, tag) return nil }
// Process pool data in Twemproxy stats func (t *Twemproxy) processPool( acc inputs.Accumulator, tags map[string]string, data map[string]interface{}, ) { serverTags := make(map[string]map[string]string) fields := make(map[string]interface{}) for key, value := range data { switch key { case "client_connections", "forward_error", "client_err", "server_ejects", "fragments", "client_eof": if val, ok := value.(float64); ok { fields[key] = val } default: if data, ok := value.(map[string]interface{}); ok { if _, ok := serverTags[key]; !ok { serverTags[key] = copyTags(tags) serverTags[key]["server"] = key } t.processServer(acc, serverTags[key], data) } } } acc.AddFields("twemproxy_pool", fields, tags) }
// Process Twemproxy server stats func (t *Twemproxy) processStat( acc inputs.Accumulator, tags map[string]string, data map[string]interface{}, ) { if source, ok := data["source"]; ok { if val, ok := source.(string); ok { tags["source"] = val } } fields := make(map[string]interface{}) metrics := []string{"total_connections", "curr_connections", "timestamp"} for _, m := range metrics { if value, ok := data[m]; ok { if val, ok := value.(float64); ok { fields[m] = val } } } acc.AddFields("twemproxy", fields, tags) for _, pool := range t.Pools { if poolStat, ok := data[pool]; ok { if data, ok := poolStat.(map[string]interface{}); ok { poolTags := copyTags(tags) poolTags["pool"] = pool t.processPool(acc, poolTags, data) } } } }
func clientStats(c ClientStats, acc inputs.Accumulator, host, version, topic, channel string) { tags := map[string]string{ "server_host": host, "server_version": version, "topic": topic, "channel": channel, "client_name": c.Name, "client_id": c.ID, "client_hostname": c.Hostname, "client_version": c.Version, "client_address": c.RemoteAddress, "client_user_agent": c.UserAgent, "client_tls": strconv.FormatBool(c.TLS), "client_snappy": strconv.FormatBool(c.Snappy), "client_deflate": strconv.FormatBool(c.Deflate), } fields := map[string]interface{}{ "ready_count": c.ReadyCount, "inflight_count": c.InFlightCount, "message_count": c.MessageCount, "finish_count": c.FinishCount, "requeue_count": c.RequeueCount, } acc.AddFields("nsq_client", fields, tags) }
func (b *Bcache) gatherBcache(bdev string, acc inputs.Accumulator) error { tags := getTags(bdev) metrics, err := filepath.Glob(bdev + "/stats_total/*") if len(metrics) < 0 { return errors.New("Can't read any stats file") } file, err := ioutil.ReadFile(bdev + "/dirty_data") if err != nil { return err } rawValue := strings.TrimSpace(string(file)) value := prettyToBytes(rawValue) fields := make(map[string]interface{}) fields["dirty_data"] = value for _, path := range metrics { key := filepath.Base(path) file, err := ioutil.ReadFile(path) rawValue := strings.TrimSpace(string(file)) if err != nil { return err } if key == "bypassed" { value := prettyToBytes(rawValue) fields[key] = value } else { value, _ := strconv.ParseUint(rawValue, 10, 64) fields[key] = value } } acc.AddFields("bcache", fields, tags) return nil }
// Import HTTP stat data into Telegraf system func importMetric(r io.Reader, acc inputs.Accumulator, host string) (poolStat, error) { stats := make(poolStat) var currentPool string scanner := bufio.NewScanner(r) for scanner.Scan() { statLine := scanner.Text() keyvalue := strings.Split(statLine, ":") if len(keyvalue) < 2 { continue } fieldName := strings.Trim(keyvalue[0], " ") // We start to gather data for a new pool here if fieldName == PF_POOL { currentPool = strings.Trim(keyvalue[1], " ") stats[currentPool] = make(metric) continue } // Start to parse metric for current pool switch fieldName { case PF_ACCEPTED_CONN, PF_LISTEN_QUEUE, PF_MAX_LISTEN_QUEUE, PF_LISTEN_QUEUE_LEN, PF_IDLE_PROCESSES, PF_ACTIVE_PROCESSES, PF_TOTAL_PROCESSES, PF_MAX_ACTIVE_PROCESSES, PF_MAX_CHILDREN_REACHED, PF_SLOW_REQUESTS: fieldValue, err := strconv.ParseInt(strings.Trim(keyvalue[1], " "), 10, 64) if err == nil { stats[currentPool][fieldName] = fieldValue } } } // Finally, we push the pool metric for pool := range stats { tags := map[string]string{ "url": host, "pool": pool, } fields := make(map[string]interface{}) for k, v := range stats[pool] { fields[strings.Replace(k, " ", "_", -1)] = v } acc.AddFields("phpfpm", fields, tags) } return stats, nil }
func (e *Engine) AddEngineStats( keys []string, acc inputs.Accumulator, tags map[string]string, ) { engine := reflect.ValueOf(e).Elem() fields := make(map[string]interface{}) for _, key := range keys { fields[key] = engine.FieldByName(engineStats[key]).Interface() } acc.AddFields("rethinkdb_engine", fields, tags) }
func (p *Ping) Gather(acc inputs.Accumulator) error { var wg sync.WaitGroup errorChannel := make(chan error, len(p.Urls)*2) // Spin off a go routine for each url to ping for _, url := range p.Urls { wg.Add(1) go func(url string, acc inputs.Accumulator) { defer wg.Done() args := p.args(url) out, err := p.pingHost(args...) if err != nil { // Combine go err + stderr output errorChannel <- errors.New( strings.TrimSpace(out) + ", " + err.Error()) } tags := map[string]string{"url": url} trans, rec, avg, err := processPingOutput(out) if err != nil { // fatal error errorChannel <- err return } // Calculate packet loss percentage loss := float64(trans-rec) / float64(trans) * 100.0 fields := map[string]interface{}{ "packets_transmitted": trans, "packets_received": rec, "percent_packet_loss": loss, } if avg > 0 { fields["average_response_ms"] = avg } acc.AddFields("ping", fields, tags) }(url, acc) } wg.Wait() close(errorChannel) // Get all errors and return them as one giant error errorStrings := []string{} for err := range errorChannel { errorStrings = append(errorStrings, err.Error()) } if len(errorStrings) == 0 { return nil } return errors.New(strings.Join(errorStrings, "\n")) }
func (s *Storage) AddStats(acc inputs.Accumulator, tags map[string]string) { fields := map[string]interface{}{ "cache_bytes_in_use": s.Cache.BytesInUse, "disk_read_bytes_per_sec": s.Disk.ReadBytesPerSec, "disk_read_bytes_total": s.Disk.ReadBytesTotal, "disk_written_bytes_per_sec": s.Disk.WriteBytesPerSec, "disk_written_bytes_total": s.Disk.WriteBytesTotal, "disk_usage_data_bytes": s.Disk.SpaceUsage.Data, "disk_usage_garbage_bytes": s.Disk.SpaceUsage.Garbage, "disk_usage_metadata_bytes": s.Disk.SpaceUsage.Metadata, "disk_usage_preallocated_bytes": s.Disk.SpaceUsage.Prealloc, } acc.AddFields("rethinkdb", fields, tags) }
func gatherQueues(r *RabbitMQ, acc inputs.Accumulator, errChan chan error) { // Gather information about queues queues := make([]Queue, 0) err := r.requestJSON("/api/queues", &queues) if err != nil { errChan <- err return } for _, queue := range queues { if !r.shouldGatherQueue(queue) { continue } tags := map[string]string{ "url": r.URL, "queue": queue.Name, "vhost": queue.Vhost, "node": queue.Node, "durable": strconv.FormatBool(queue.Durable), "auto_delete": strconv.FormatBool(queue.AutoDelete), } acc.AddFields( "rabbitmq_queue", map[string]interface{}{ // common information "consumers": queue.Consumers, "consumer_utilisation": queue.ConsumerUtilisation, "memory": queue.Memory, // messages information "messages": queue.Messages, "messages_ready": queue.MessagesReady, "messages_unack": queue.MessagesUnacknowledged, "messages_ack": queue.MessageStats.Ack, "messages_ack_rate": queue.MessageStats.AckDetails.Rate, "messages_deliver": queue.MessageStats.Deliver, "messages_deliver_rate": queue.MessageStats.DeliverDetails.Rate, "messages_deliver_get": queue.MessageStats.DeliverGet, "messages_deliver_get_rate": queue.MessageStats.DeliverGetDetails.Rate, "messages_publish": queue.MessageStats.Publish, "messages_publish_rate": queue.MessageStats.PublishDetails.Rate, "messages_redeliver": queue.MessageStats.Redeliver, "messages_redeliver_rate": queue.MessageStats.RedeliverDetails.Rate, }, tags, ) } errChan <- nil }
// Gather reads stats from all lustre targets func (l *Lustre2) Gather(acc inputs.Accumulator) error { l.allFields = make(map[string]map[string]interface{}) if len(l.Ost_procfiles) == 0 { // read/write bytes are in obdfilter/<ost_name>/stats err := l.GetLustreProcStats("/proc/fs/lustre/obdfilter/*/stats", wanted_ost_fields, acc) if err != nil { return err } // cache counters are in osd-ldiskfs/<ost_name>/stats err = l.GetLustreProcStats("/proc/fs/lustre/osd-ldiskfs/*/stats", wanted_ost_fields, acc) if err != nil { return err } } if len(l.Mds_procfiles) == 0 { // Metadata server stats err := l.GetLustreProcStats("/proc/fs/lustre/mdt/*/md_stats", wanted_mds_fields, acc) if err != nil { return err } } for _, procfile := range l.Ost_procfiles { err := l.GetLustreProcStats(procfile, wanted_ost_fields, acc) if err != nil { return err } } for _, procfile := range l.Mds_procfiles { err := l.GetLustreProcStats(procfile, wanted_mds_fields, acc) if err != nil { return err } } for name, fields := range l.allFields { tags := map[string]string{ "name": name, } acc.AddFields("lustre2", fields, tags) } return nil }
func (s *Trig) Gather(acc inputs.Accumulator) error { sinner := math.Sin((s.x*math.Pi)/5.0) * s.Amplitude cosinner := math.Cos((s.x*math.Pi)/5.0) * s.Amplitude fields := make(map[string]interface{}) fields["sine"] = sinner fields["cosine"] = cosinner tags := make(map[string]string) s.x += 1.0 acc.AddFields("trig", fields, tags) return nil }
func (z *Zookeeper) gatherServer(address string, acc inputs.Accumulator) error { _, _, err := net.SplitHostPort(address) if err != nil { address = address + ":2181" } c, err := net.DialTimeout("tcp", address, defaultTimeout) if err != nil { fmt.Fprintln(os.Stderr, err) return err } defer c.Close() fmt.Fprintf(c, "%s\n", "mntr") rdr := bufio.NewReader(c) scanner := bufio.NewScanner(rdr) service := strings.Split(address, ":") if len(service) != 2 { return fmt.Errorf("Invalid service address: %s", address) } tags := map[string]string{"server": service[0], "port": service[1]} fields := make(map[string]interface{}) for scanner.Scan() { line := scanner.Text() re := regexp.MustCompile(`^zk_(\w+)\s+([\w\.\-]+)`) parts := re.FindStringSubmatch(string(line)) if len(parts) != 3 { return fmt.Errorf("unexpected line in mntr response: %q", line) } measurement := strings.TrimPrefix(parts[1], "zk_") sValue := string(parts[2]) iVal, err := strconv.ParseInt(sValue, 10, 64) if err == nil { fields[measurement] = iVal } else { fields[measurement] = sValue } } acc.AddFields("zookeeper", fields, tags) return nil }
// Process backend server(redis/memcached) stats func (t *Twemproxy) processServer( acc inputs.Accumulator, tags map[string]string, data map[string]interface{}, ) { fields := make(map[string]interface{}) for key, value := range data { switch key { default: if val, ok := value.(float64); ok { fields[key] = val } } } acc.AddFields("twemproxy_pool_server", fields, tags) }
func (j *Jolokia) Gather(acc inputs.Accumulator) error { context := j.Context //"/jolokia/read" servers := j.Servers metrics := j.Metrics tags := make(map[string]string) for _, server := range servers { tags["server"] = server.Name tags["port"] = server.Port tags["host"] = server.Host fields := make(map[string]interface{}) for _, metric := range metrics { measurement := metric.Name jmxPath := metric.Jmx // Prepare URL requestUrl, err := url.Parse("http://" + server.Host + ":" + server.Port + context + jmxPath) if err != nil { return err } if server.Username != "" || server.Password != "" { requestUrl.User = url.UserPassword(server.Username, server.Password) } out, _ := j.getAttr(requestUrl) if values, ok := out["value"]; ok { switch t := values.(type) { case map[string]interface{}: for k, v := range t { fields[measurement+"_"+k] = v } case interface{}: fields[measurement] = t } } else { fmt.Printf("Missing key 'value' in '%s' output response\n", requestUrl.String()) } } acc.AddFields("jolokia", fields, tags) } return nil }
func (s *Sensors) Gather(acc inputs.Accumulator) error { gosensors.Init() defer gosensors.Cleanup() for _, chip := range gosensors.GetDetectedChips() { for _, feature := range chip.GetFeatures() { chipName := chip.String() featureLabel := feature.GetLabel() if len(s.Sensors) != 0 { var found bool for _, sensor := range s.Sensors { parts := strings.SplitN(":", sensor, 2) if parts[0] == chipName { if parts[1] == "*" || parts[1] == featureLabel { found = true break } } } if !found { continue } } tags := map[string]string{ "chip": chipName, "adapter": chip.AdapterName(), "feature-name": feature.Name, "feature-label": featureLabel, } fieldName := chipName + ":" + featureLabel fields := map[string]interface{}{ fieldName: feature.GetValue(), } acc.AddFields("sensors", fields, tags) } } return nil }
func (z *Zfs) Gather(acc inputs.Accumulator) error { kstatMetrics := z.KstatMetrics if len(kstatMetrics) == 0 { kstatMetrics = []string{"arcstats", "zfetchstats", "vdev_cache_stats"} } kstatPath := z.KstatPath if len(kstatPath) == 0 { kstatPath = "/proc/spl/kstat/zfs" } pools := getPools(kstatPath) tags := getTags(pools) if z.PoolMetrics { for _, pool := range pools { err := gatherPoolStats(pool, acc) if err != nil { return err } } } fields := make(map[string]interface{}) for _, metric := range kstatMetrics { lines, err := internal.ReadLines(kstatPath + "/" + metric) if err != nil { return err } for i, line := range lines { if i == 0 || i == 1 { continue } if len(line) < 1 { continue } rawData := strings.Split(line, " ") key := metric + "_" + rawData[0] rawValue := rawData[len(rawData)-1] value, _ := strconv.ParseInt(rawValue, 10, 64) fields[key] = value } } acc.AddFields("zfs", fields, tags) return nil }
// Gathers data from a particular server // Parameters: // acc : The telegraf Accumulator to use // serverURL: endpoint to send request to // service : the service being queried // // Returns: // error: Any error that may have occurred func (h *HttpJson) gatherServer( acc inputs.Accumulator, serverURL string, ) error { resp, responseTime, err := h.sendRequest(serverURL) if err != nil { return err } var jsonOut map[string]interface{} if err = json.Unmarshal([]byte(resp), &jsonOut); err != nil { return errors.New("Error decoding JSON response") } tags := map[string]string{ "server": serverURL, } for _, tag := range h.TagKeys { switch v := jsonOut[tag].(type) { case string: tags[tag] = v } delete(jsonOut, tag) } if responseTime >= 0 { jsonOut["response_time"] = responseTime } f := internal.JSONFlattener{} err = f.FlattenJSON("", jsonOut) if err != nil { return err } var msrmnt_name string if h.Name == "" { msrmnt_name = "httpjson" } else { msrmnt_name = "httpjson_" + h.Name } acc.AddFields(msrmnt_name, f.Fields, tags) return nil }
func (s *SwapStats) Gather(acc inputs.Accumulator) error { swap, err := s.ps.SwapStat() if err != nil { return fmt.Errorf("error getting swap memory info: %s", err) } fields := map[string]interface{}{ "total": swap.Total, "used": swap.Used, "free": swap.Free, "used_percent": swap.UsedPercent, "in": swap.Sin, "out": swap.Sout, } acc.AddFields("swap", fields, nil) return nil }
func (e *Elasticsearch) gatherNodeStats(url string, acc inputs.Accumulator) error { nodeStats := &struct { ClusterName string `json:"cluster_name"` Nodes map[string]*node `json:"nodes"` }{} if err := e.gatherData(url, nodeStats); err != nil { return err } for id, n := range nodeStats.Nodes { tags := map[string]string{ "node_id": id, "node_host": n.Host, "node_name": n.Name, "cluster_name": nodeStats.ClusterName, } for k, v := range n.Attributes { tags["node_attribute_"+k] = v } stats := map[string]interface{}{ "indices": n.Indices, "os": n.OS, "process": n.Process, "jvm": n.JVM, "thread_pool": n.ThreadPool, "fs": n.FS, "transport": n.Transport, "http": n.HTTP, "breakers": n.Breakers, } now := time.Now() for p, s := range stats { f := internal.JSONFlattener{} err := f.FlattenJSON("", s) if err != nil { return err } acc.AddFields("elasticsearch_"+p, f.Fields, tags, now) } } return nil }
func (e *Elasticsearch) gatherClusterStats(url string, acc inputs.Accumulator) error { clusterStats := &clusterHealth{} if err := e.gatherData(url, clusterStats); err != nil { return err } measurementTime := time.Now() clusterFields := map[string]interface{}{ "status": clusterStats.Status, "timed_out": clusterStats.TimedOut, "number_of_nodes": clusterStats.NumberOfNodes, "number_of_data_nodes": clusterStats.NumberOfDataNodes, "active_primary_shards": clusterStats.ActivePrimaryShards, "active_shards": clusterStats.ActiveShards, "relocating_shards": clusterStats.RelocatingShards, "initializing_shards": clusterStats.InitializingShards, "unassigned_shards": clusterStats.UnassignedShards, } acc.AddFields( "elasticsearch_cluster_health", clusterFields, map[string]string{"name": clusterStats.ClusterName}, measurementTime, ) for name, health := range clusterStats.Indices { indexFields := map[string]interface{}{ "status": health.Status, "number_of_shards": health.NumberOfShards, "number_of_replicas": health.NumberOfReplicas, "active_primary_shards": health.ActivePrimaryShards, "active_shards": health.ActiveShards, "relocating_shards": health.RelocatingShards, "initializing_shards": health.InitializingShards, "unassigned_shards": health.UnassignedShards, } acc.AddFields( "elasticsearch_indices", indexFields, map[string]string{"index": name}, measurementTime, ) } return nil }
func (s *DiskIOStats) Gather(acc inputs.Accumulator) error { diskio, err := s.ps.DiskIO() if err != nil { return fmt.Errorf("error getting disk io info: %s", err) } var restrictDevices bool devices := make(map[string]bool) if len(s.Devices) != 0 { restrictDevices = true for _, dev := range s.Devices { devices[dev] = true } } for _, io := range diskio { _, member := devices[io.Name] if restrictDevices && !member { continue } tags := map[string]string{} tags["name"] = io.Name if !s.SkipSerialNumber { if len(io.SerialNumber) != 0 { tags["serial"] = io.SerialNumber } else { tags["serial"] = "unknown" } } fields := map[string]interface{}{ "reads": io.ReadCount, "writes": io.WriteCount, "read_bytes": io.ReadBytes, "write_bytes": io.WriteBytes, "read_time": io.ReadTime, "write_time": io.WriteTime, "io_time": io.IoTime, } acc.AddFields("diskio", fields, tags) } return nil }
func structPrinter(s *State, acc inputs.Accumulator, tags map[string]string) { e := reflect.ValueOf(s).Elem() fields := make(map[string]interface{}) for tLevelFNum := 0; tLevelFNum < e.NumField(); tLevelFNum++ { name := e.Type().Field(tLevelFNum).Name nameNumField := e.FieldByName(name).NumField() for sLevelFNum := 0; sLevelFNum < nameNumField; sLevelFNum++ { sName := e.FieldByName(name).Type().Field(sLevelFNum).Name sValue := e.FieldByName(name).Field(sLevelFNum).Interface() lname := strings.ToLower(name) lsName := strings.ToLower(sName) fields[fmt.Sprintf("%s_%s", lname, lsName)] = sValue } } acc.AddFields("puppetagent", fields, tags) }
func (p *Postgresql) accRow(row scanner, acc inputs.Accumulator) error { var columnVars []interface{} var dbname bytes.Buffer // this is where we'll store the column name with its *interface{} columnMap := make(map[string]*interface{}) for _, column := range p.OrderedColumns { columnMap[column] = new(interface{}) } // populate the array of interface{} with the pointers in the right order for i := 0; i < len(columnMap); i++ { columnVars = append(columnVars, columnMap[p.OrderedColumns[i]]) } // deconstruct array of variables and send to Scan err := row.Scan(columnVars...) if err != nil { return err } // extract the database name from the column map dbnameChars := (*columnMap["datname"]).([]uint8) for i := 0; i < len(dbnameChars); i++ { dbname.WriteString(string(dbnameChars[i])) } tags := map[string]string{"server": p.Address, "db": dbname.String()} fields := make(map[string]interface{}) for col, val := range columnMap { _, ignore := ignoredColumns[col] if !ignore { fields[col] = *val } } acc.AddFields("postgresql", fields, tags) return nil }
func topicStats(t TopicStats, acc inputs.Accumulator, host, version string) { // per topic overall (tag: name, paused, channel count) tags := map[string]string{ "server_host": host, "server_version": version, "topic": t.Name, } fields := map[string]interface{}{ "depth": t.Depth, "backend_depth": t.BackendDepth, "message_count": t.MessageCount, "channel_count": int64(len(t.Channels)), } acc.AddFields("nsq_topic", fields, tags) for _, c := range t.Channels { channelStats(c, acc, host, version, t.Name) } }
func (s *MemStats) Gather(acc inputs.Accumulator) error { vm, err := s.ps.VMStat() if err != nil { return fmt.Errorf("error getting virtual memory info: %s", err) } fields := map[string]interface{}{ "total": vm.Total, "available": vm.Available, "used": vm.Used, "free": vm.Free, "cached": vm.Cached, "buffered": vm.Buffers, "used_percent": 100 * float64(vm.Used) / float64(vm.Total), "available_percent": 100 * float64(vm.Available) / float64(vm.Total), } acc.AddFields("mem", fields, nil) return nil }
// Parse the special Keyspace line at end of redis stats // This is a special line that looks something like: // db0:keys=2,expires=0,avg_ttl=0 // And there is one for each db on the redis instance func gatherKeyspaceLine( name string, line string, acc inputs.Accumulator, tags map[string]string, ) { if strings.Contains(line, "keys=") { fields := make(map[string]interface{}) tags["database"] = name dbparts := strings.Split(line, ",") for _, dbp := range dbparts { kv := strings.Split(dbp, "=") ival, err := strconv.ParseUint(kv[1], 10, 64) if err == nil { fields[kv[0]] = ival } } acc.AddFields("redis_keyspace", fields, tags) } }
func (s *NetStats) Gather(acc inputs.Accumulator) error { netconns, err := s.ps.NetConnections() if err != nil { return fmt.Errorf("error getting net connections info: %s", err) } counts := make(map[string]int) counts["UDP"] = 0 // TODO: add family to tags or else tags := map[string]string{} for _, netcon := range netconns { if netcon.Type == syscall.SOCK_DGRAM { counts["UDP"] += 1 continue // UDP has no status } c, ok := counts[netcon.Status] if !ok { counts[netcon.Status] = 0 } counts[netcon.Status] = c + 1 } fields := map[string]interface{}{ "tcp_established": counts["ESTABLISHED"], "tcp_syn_sent": counts["SYN_SENT"], "tcp_syn_recv": counts["SYN_RECV"], "tcp_fin_wait1": counts["FIN_WAIT1"], "tcp_fin_wait2": counts["FIN_WAIT2"], "tcp_time_wait": counts["TIME_WAIT"], "tcp_close": counts["CLOSE"], "tcp_close_wait": counts["CLOSE_WAIT"], "tcp_last_ack": counts["LAST_ACK"], "tcp_listen": counts["LISTEN"], "tcp_closing": counts["CLOSING"], "tcp_none": counts["NONE"], "udp_socket": counts["UDP"], } acc.AddFields("netstat", fields, tags) return nil }