func createEvent(m plugin.MetricType, config map[string]ctypes.ConfigValue) *raidman.Event {
	return &raidman.Event{
		Host:    m.Tags()[core.STD_TAG_PLUGIN_RUNNING_ON],
		Service: m.Namespace().String(),
		Metric:  m.Data(),
	}
}
func checkValues(metric plugin.MetricType, mockData []uint64) bool {
	result := false

	// get last namespace's item
	last := len(metric.Namespace()) - 1
	// approximation error, acceptance boundary is (+/-) 0.5
	approxErr := 0.5
	switch metric.Namespace().Strings()[last] {
	case nLoggedUsers:
		// take the last set mock data
		if metric.Data() == mockData[len(mockData)-1] {
			result = true
		}
	case nLoggedUsersMin:
		if metric.Data() == min(mockData) {
			result = true
		}

	case nLoggedUsersMax:
		if metric.Data() == max(mockData) {
			result = true
		}
	case nLoggedUsersAvg:
		if math.Abs(metric.Data().(float64)-avg(mockData)) <= approxErr {
			result = true
		}
	}

	return result
}
Ejemplo n.º 3
0
func sendEvent(orgId int64, m *plugin.MetricType) {
	ns := m.Namespace().Strings()
	if len(ns) != 4 {
		log.Printf("Error: invalid event metric. Expected namesapce to be 4 fields.")
		return
	}
	if ns[0] != "worldping" || ns[1] != "event" {
		log.Printf("Error: invalid event metrics.  Metrics hould begin with 'worldping.event'")
		return
	}
	hostname, _ := os.Hostname()
	id := time.Now().UnixNano()
	event := &schema.ProbeEvent{
		OrgId:     orgId,
		EventType: ns[2],
		Severity:  ns[3],
		Source:    hostname,
		Timestamp: id / int64(time.Millisecond),
		Message:   m.Data().(string),
		Tags:      m.Tags(),
	}

	body, err := msg.CreateProbeEventMsg(event, id, msg.FormatProbeEventMsgp)
	if err != nil {
		log.Printf("Error: unable to convert event to ProbeEventMsgp. %s", err)
		return
	}
	sent := false
	for !sent {
		if err = PostData("events", Token, body); err != nil {
			log.Printf("Error: %s", err)
			time.Sleep(time.Second)
		} else {
			sent = true
		}
	}
}
func (p *movingAverageProcessor) calculateMovingAverage(m plugin.MetricType, logger *log.Logger) (float64, error) {

	namespace := concatNameSpace(m.Namespace().Strings())
	switch v := m.Data().(type) {
	default:
		logger.Warnln(fmt.Sprintf("Unknown data received: Type %T", v))
		return 0.0, nil
	case int:
		if _, ok := p.movingAverageMap[namespace]; ok {
			counter, err := p.getCounter(namespace)
			counterCurrent := counter % p.movingBufLength
			err = p.addBufferData(counterCurrent, m.Data(), namespace)
			if err != nil {
				return 0.0, err
			}

			sum := int(0)
			//Initial Counter is used to give correct average for initial iterations ie when the buffer is not full
			initialCounter := 0
			for i := 0; i < p.movingBufLength; i++ {
				if p.getBufferData(i, namespace) != nil {
					initialCounter++
					sum += p.getBufferData(i, namespace).(int)
				}
			}
			movingAvg := float64(sum) / float64(initialCounter)
			counterCurrent++
			p.setCounter(namespace, counterCurrent)
			return movingAvg, err

		} else {

			//Since map doesnot have an entry of this namespace, it's creating an entry for the namespace.
			//Also m.data value is inserted into 0th position of the buffer because we know that this buffer is being used for the first time
			p.movingAverageMap[namespace] = newmovingAverage(p.getBufferLength())
			err := p.addBufferData(0, m.Data(), namespace)
			if err != nil {
				return 0.0, err
			}

			sum := p.getBufferData(0, namespace).(int)
			p.setCounter(namespace, 1)
			return float64(sum), nil
		}

	case float64:

		if _, ok := p.movingAverageMap[namespace]; ok {
			counter, err := p.getCounter(namespace)
			counterCurrent := counter % p.movingBufLength
			err = p.addBufferData(counterCurrent, m.Data(), namespace)
			if err != nil {
				return 0.0, err
			}

			sum := float64(0)
			initialCounter := 0
			for i := 0; i < p.movingBufLength; i++ {
				if p.getBufferData(i, namespace) != nil {
					initialCounter++
					sum += p.getBufferData(i, namespace).(float64)
				}
			}
			movingAvg := float64(sum) / float64(initialCounter)
			counterCurrent++
			p.setCounter(namespace, counterCurrent)
			return movingAvg, err

		}
		p.movingAverageMap[namespace] = newmovingAverage(p.getBufferLength())
		err := p.addBufferData(0, m.Data(), namespace)
		if err != nil {
			return 0.0, err
		}

		sum := p.getBufferData(0, namespace).(float64)
		p.setCounter(namespace, 1)
		return float64(sum), nil

	case float32:
		if _, ok := p.movingAverageMap[namespace]; ok {
			counter, err := p.getCounter(namespace)
			counterCurrent := counter % p.movingBufLength
			err = p.addBufferData(counterCurrent, m.Data(), namespace)
			if err != nil {
				return 0.0, err
			}

			sum := float32(0)

			initialCounter := 0
			for i := 0; i < p.movingBufLength; i++ {
				if p.getBufferData(i, namespace) != nil {
					initialCounter++
					sum += p.getBufferData(i, namespace).(float32)
				}
			}
			movingAvg := float64(sum) / float64(initialCounter)
			p.setCounter(namespace, counterCurrent)
			return movingAvg, err

		}
		p.movingAverageMap[namespace] = newmovingAverage(p.getBufferLength())
		err := p.addBufferData(0, m.Data(), namespace)
		if err != nil {
			return 0.0, err
		}

		sum := p.getBufferData(0, namespace).(float32)
		p.setCounter(namespace, 1)
		return float64(sum), nil

	case uint32:
		if _, ok := p.movingAverageMap[namespace]; ok {
			counter, err := p.getCounter(namespace)
			counterCurrent := counter % p.movingBufLength
			err = p.addBufferData(counterCurrent, m.Data(), namespace)
			if err != nil {
				return 0.0, err
			}

			sum := uint32(0)
			initialCounter := 0
			for i := 0; i < p.movingBufLength; i++ {
				if p.getBufferData(i, namespace) != nil {
					initialCounter++
					sum += p.getBufferData(i, namespace).(uint32)
				}
			}
			movingAvg := float64(sum) / float64(initialCounter)
			counterCurrent++
			p.setCounter(namespace, counterCurrent)
			return movingAvg, err

		}
		p.movingAverageMap[namespace] = newmovingAverage(p.getBufferLength())
		err := p.addBufferData(0, m.Data(), namespace)
		if err != nil {
			return 0.0, err
		}
		sum := p.getBufferData(0, namespace).(uint32)
		p.setCounter(namespace, 1)
		return float64(sum), nil

	case uint64:
		if _, ok := p.movingAverageMap[namespace]; ok {
			counter, err := p.getCounter(namespace)
			counterCurrent := counter % p.movingBufLength
			err = p.addBufferData(counterCurrent, m.Data(), namespace)
			if err != nil {
				return 0.0, err
			}

			sum := uint64(0)
			initialCounter := 0
			for i := 0; i < p.movingBufLength; i++ {
				if p.getBufferData(i, namespace) != nil {
					initialCounter++
					sum += p.getBufferData(i, namespace).(uint64)
				}
			}
			movingAvg := float64(sum) / float64(initialCounter)
			counterCurrent++
			p.setCounter(namespace, counterCurrent)
			return movingAvg, err

		}
		p.movingAverageMap[namespace] = newmovingAverage(p.getBufferLength())
		err := p.addBufferData(0, m.Data(), namespace)
		if err != nil {
			return 0.0, err
		}
		sum := p.getBufferData(0, namespace).(uint64)
		p.setCounter(namespace, 1)
		return float64(sum), nil
	}
}
// function which fills all part of Heka message
func setHekaMessageFields(m plugin.MetricType, msg *message.Message) error {
	mName := make([]string, 0, len(m.Namespace()))
	var dimField *message.Field
	var err error
	// Loop on namespace elements
	for _, elt := range m.Namespace() {
		logger.WithField("_block", "setHekaMessageFields").Debug(
			fmt.Sprintf("Namespace %#+v",
				elt))
		// Dynamic element is not inserted in metric name
		// but rather added to dimension field
		if elt.IsDynamic() {
			dimField, err = addToDimensions(dimField, elt.Name)
			if err != nil {
				logger.WithField("_block", "setHekaMessageFields").Error(err)
				return err
			}
			addField(elt.Name, elt.Value, msg)
		} else {
			// Static element is concatenated to metric name
			mName = append(mName, elt.Value)
		}
	}
	// Processing of tags
	if len(m.Tags()) > 0 {
		for tag, value := range m.Tags() {
			logger.WithField("_block", "setHekaMessageFields").Debug(
				fmt.Sprintf("Adding tag=%s value=%s",
					tag, value))
			dimField, err = addToDimensions(dimField, tag)
			if err != nil {
				logger.WithField("_block", "setHekaMessageFields").Error(err)
				return err
			}
			addField(tag, value, msg)
		}
	}
	if dimField != nil {
		msg.AddField(dimField)
	}
	// Handle metric name
	metricName := strings.Join(mName, ".")
	// TODO protect access using mutex
	// for potential race conditions
	logger.WithField("_block", "setHekaMessageFields").Debug(
		fmt.Sprintf("Checking metric=%s",
			metricName))
	// Is mapping already stored
	if val, ok := MetricMappings[metricName]; ok {
		logger.WithField("_block", "setHekaMessageFields").Debug(
			fmt.Sprintf("Metric=%s in cache %s",
				metricName, val))
		metricName = val
	} else {
		oldMetricName := metricName
		logger.WithField("_block", "setHekaMessageFields").Debug(
			fmt.Sprintf("Metric=%s not in cache",
				metricName))
		// Namespace handling
		for kmapping, vmapping := range globalMappings.Namespace {
			logger.WithField("_block", "setHekaMessageFields").Debug(
				fmt.Sprintf("Checking metric=%s against namespace %s (%s)",
					metricName, kmapping, vmapping))
			// Try to see if substitution changes something
			newMetricName := strings.Replace(metricName, kmapping, vmapping, 1)
			if strings.Compare(newMetricName, metricName) != 0 {
				MetricMappings[oldMetricName] = newMetricName
				logger.WithField("_block", "setHekaMessageFields").Debug(
					fmt.Sprintf("Changing metric=%s into %s",
						metricName, newMetricName))
				metricName = newMetricName
			}
		}
		// Metrics handling
		for kmapping, vmapping := range globalMappings.Metrics {
			logger.WithField("_block", "setHekaMessageFields").Debug(
				fmt.Sprintf("Checking metric=%s against metric %s (%s)",
					metricName, kmapping, vmapping))
			// Try to see if substitution changes something
			newMetricName := strings.Replace(metricName, kmapping, vmapping, 1)
			if strings.Compare(newMetricName, metricName) != 0 {
				MetricMappings[oldMetricName] = newMetricName
				logger.WithField("_block", "setHekaMessageFields").Debug(
					fmt.Sprintf("Changing metric=%s into %s",
						metricName, newMetricName))
				metricName = newMetricName
			}
		}
	}
	addField("name", metricName, msg)
	addField("value", getData(m.Data()), msg)
	addField("timestamp", m.Timestamp().UnixNano(), msg)
	return nil
}