Ejemplo n.º 1
0
func (ac *AdvancingClock) UnixNano() int64 {
	ac.Lock()
	time := ac.time
	ac.time = time.Add(ac.getAdvancementInterval())
	ac.Unlock()
	return time.UnixNano()
}
Ejemplo n.º 2
0
func parseLogFilename(filename string) (FileDetails, error) {
	matches := logFileRE.FindStringSubmatch(filename)
	if matches == nil || len(matches) != 7 {
		return FileDetails{}, errMalformedName
	}

	// Replace the '_'s with ':'s to restore the correct time format.
	fixTime := strings.Replace(matches[4], "_", ":", -1)
	time, err := time.Parse(time.RFC3339, fixTime)
	if err != nil {
		return FileDetails{}, err
	}

	pid, err := strconv.ParseInt(matches[5], 10, 0)
	if err != nil {
		return FileDetails{}, err
	}

	sev, sevFound := SeverityByName(matches[6])
	if !sevFound {
		return FileDetails{}, errMalformedSev
	}

	return FileDetails{
		Program:  matches[1],
		Host:     matches[2],
		UserName: matches[3],
		Severity: sev,
		Time:     time.UnixNano(),
		PID:      pid,
	}, nil
}
Ejemplo n.º 3
0
func main() {
	time.AfterFunc(2000000000, func() {
		fmt.Printf("Timer expired\n")
	})
	timer := time.NewTimer(3000000000)
	time := <-timer.C
	fmt.Printf("Current time: %d nanoseconds\n", time.UnixNano())
}
Ejemplo n.º 4
0
func main() {
	var start = time.UnixNano()
	fmt.Printf("Starting Euler #28 \n")

	var sum int = 0
	var x = 1001

	for ; x > 1; x -= 2 {
		sum += SumSpiral(x)
	}

	sum += 1 // dont forget the center

	var end = time.UnixNano()
	var duration = (end - start) / 1000000
	fmt.Printf("Sum: %d \n", sum)
	fmt.Printf("Calculated in %vms \n", duration)

}
Ejemplo n.º 5
0
// Returns cpu and memory usage percentiles.
func GetPercentiles(stats []*info.ContainerStats) (Percentiles, Percentiles) {
	lastCpu := uint64(0)
	lastTime := time.Time{}
	memorySamples := make(uint64Slice, 0, len(stats))
	cpuSamples := make(uint64Slice, 0, len(stats)-1)
	numSamples := 0
	memoryMean := Mean{count: 0, Mean: 0}
	cpuMean := Mean{count: 0, Mean: 0}
	memoryPercentiles := Percentiles{}
	cpuPercentiles := Percentiles{}
	for _, stat := range stats {
		var elapsed int64
		time := stat.Timestamp
		if !lastTime.IsZero() {
			elapsed = time.UnixNano() - lastTime.UnixNano()
			if elapsed < 10*milliSecondsToNanoSeconds {
				glog.Infof("Elapsed time too small: %d ns: time now %s last %s", elapsed, time.String(), lastTime.String())
				continue
			}
		}
		numSamples++
		cpuNs := stat.Cpu.Usage.Total
		// Ignore actual usage and only focus on working set.
		memory := stat.Memory.WorkingSet
		if memory > memoryPercentiles.Max {
			memoryPercentiles.Max = memory
		}
		glog.V(2).Infof("Read sample: cpu %d, memory %d", cpuNs, memory)
		memoryMean.Add(memory)
		memorySamples = append(memorySamples, memory)
		if lastTime.IsZero() {
			lastCpu = cpuNs
			lastTime = time
			continue
		}
		cpuRate := (cpuNs - lastCpu) * secondsToMilliSeconds / uint64(elapsed)
		if cpuRate < 0 {
			glog.Infof("cpu rate too small: %f ns", cpuRate)
			continue
		}
		glog.V(2).Infof("Adding cpu rate sample : %d", cpuRate)
		lastCpu = cpuNs
		lastTime = time
		cpuSamples = append(cpuSamples, cpuRate)
		if cpuRate > cpuPercentiles.Max {
			cpuPercentiles.Max = cpuRate
		}
		cpuMean.Add(cpuRate)
	}
	cpuPercentiles.Mean = uint64(cpuMean.Mean)
	memoryPercentiles.Mean = uint64(memoryMean.Mean)
	cpuPercentiles.Ninety = cpuSamples.Get90Percentile()
	memoryPercentiles.Ninety = memorySamples.Get90Percentile()
	return cpuPercentiles, memoryPercentiles
}
Ejemplo n.º 6
0
func (b *broker) HandleActivation(activation *pb.DeviceActivationRequest) (res *pb.DeviceActivationResponse, err error) {
	ctx := b.Ctx.WithFields(log.Fields{
		"GatewayID": activation.GatewayMetadata.GatewayId,
		"AppEUI":    *activation.AppEui,
		"DevEUI":    *activation.DevEui,
	})
	start := time.Now()
	defer func() {
		if err != nil {
			ctx.WithError(err).Warn("Could not handle activation")
		} else {
			ctx.WithField("Duration", time.Now().Sub(start)).Info("Handled activation")
		}
	}()

	time := time.Now()

	b.status.activations.Mark(1)

	// De-duplicate uplink messages
	duplicates := b.deduplicateActivation(activation)
	if len(duplicates) == 0 {
		return nil, errDuplicateActivation
	}

	b.status.activationsUnique.Mark(1)

	base := duplicates[0]

	// Collect GatewayMetadata and DownlinkOptions
	var gatewayMetadata []*gateway.RxMetadata
	var downlinkOptions []*pb.DownlinkOption
	var deviceActivationResponse *pb.DeviceActivationResponse
	for _, duplicate := range duplicates {
		gatewayMetadata = append(gatewayMetadata, duplicate.GatewayMetadata)
		downlinkOptions = append(downlinkOptions, duplicate.DownlinkOptions...)
	}

	// Select best DownlinkOption
	if len(downlinkOptions) > 0 {
		deviceActivationResponse = &pb.DeviceActivationResponse{
			DownlinkOption: selectBestDownlink(downlinkOptions),
		}
	}

	// Build Uplink
	deduplicatedActivationRequest := &pb.DeduplicatedDeviceActivationRequest{
		Payload:            base.Payload,
		DevEui:             base.DevEui,
		AppEui:             base.AppEui,
		ProtocolMetadata:   base.ProtocolMetadata,
		GatewayMetadata:    gatewayMetadata,
		ActivationMetadata: base.ActivationMetadata,
		ServerTime:         time.UnixNano(),
		ResponseTemplate:   deviceActivationResponse,
	}

	// Send Activate to NS
	deduplicatedActivationRequest, err = b.ns.PrepareActivation(b.Component.GetContext(b.nsToken), deduplicatedActivationRequest)
	if err != nil {
		return nil, errors.Wrap(errors.FromGRPCError(err), "NetworkServer refused to prepare activation")
	}

	ctx = ctx.WithFields(log.Fields{
		"AppID": deduplicatedActivationRequest.AppId,
		"DevID": deduplicatedActivationRequest.DevId,
	})

	// Find Handler (based on AppEUI)
	var announcements []*pb_discovery.Announcement
	announcements, err = b.Discovery.GetAllHandlersForAppID(deduplicatedActivationRequest.AppId)
	if err != nil {
		return nil, err
	}
	if len(announcements) == 0 {
		return nil, errors.NewErrNotFound(fmt.Sprintf("Handler for AppID %s", deduplicatedActivationRequest.AppId))
	}

	ctx = ctx.WithField("NumHandlers", len(announcements))

	// LoRaWAN: Unmarshal and prepare version without MIC
	var phyPayload lorawan.PHYPayload
	err = phyPayload.UnmarshalBinary(deduplicatedActivationRequest.Payload)
	if err != nil {
		return nil, err
	}
	correctMIC := phyPayload.MIC
	phyPayload.MIC = [4]byte{0, 0, 0, 0}
	phyPayloadWithoutMIC, err := phyPayload.MarshalBinary()
	if err != nil {
		return nil, err
	}

	// Build Challenge
	challenge := &pb.ActivationChallengeRequest{
		Payload: phyPayloadWithoutMIC,
		AppId:   deduplicatedActivationRequest.AppId,
		DevId:   deduplicatedActivationRequest.DevId,
		AppEui:  deduplicatedActivationRequest.AppEui,
		DevEui:  deduplicatedActivationRequest.DevEui,
	}

	// Send Challenge to all handlers and collect responses
	var wg sync.WaitGroup
	responses := make(chan *challengeResponseWithHandler, len(announcements))
	for _, announcement := range announcements {
		conn, err := b.getHandlerConn(announcement.Id)
		if err != nil {
			ctx.WithError(err).Warn("Could not dial handler for Activation")
			continue
		}
		client := pb_handler.NewHandlerClient(conn)

		// Do async request
		wg.Add(1)
		go func(announcement *pb_discovery.Announcement) {
			res, err := client.ActivationChallenge(b.Component.GetContext(""), challenge)
			if err == nil && res != nil {
				responses <- &challengeResponseWithHandler{
					handler:  announcement,
					client:   client,
					response: res,
				}
			}
			wg.Done()
		}(announcement)
	}

	// Make sure to close channel when all requests are done
	go func() {
		wg.Wait()
		close(responses)
	}()

	var gotFirst bool
	var joinHandler *pb_discovery.Announcement
	var joinHandlerClient pb_handler.HandlerClient
	for res := range responses {
		var phyPayload lorawan.PHYPayload
		err = phyPayload.UnmarshalBinary(res.response.Payload)
		if err != nil {
			continue
		}
		if phyPayload.MIC != correctMIC {
			continue
		}

		if gotFirst {
			ctx.Warn("Duplicate Activation Response")
		} else {
			gotFirst = true
			joinHandler = res.handler
			joinHandlerClient = res.client
		}
	}

	// Activation not accepted by any broker
	if !gotFirst {
		ctx.Debug("Activation not accepted by any Handler")
		return nil, errors.New("Activation not accepted by any Handler")
	}

	ctx.WithField("HandlerID", joinHandler.Id).Debug("Forward Activation")

	handlerResponse, err := joinHandlerClient.Activate(b.Component.GetContext(""), deduplicatedActivationRequest)
	if err != nil {
		return nil, errors.Wrap(errors.FromGRPCError(err), "Handler refused activation")
	}
	handlerResponse, err = b.ns.Activate(b.Component.GetContext(b.nsToken), handlerResponse)
	if err != nil {
		return nil, errors.Wrap(errors.FromGRPCError(err), "NetworkServer refused activation")
	}

	res = &pb.DeviceActivationResponse{
		Payload:        handlerResponse.Payload,
		Message:        handlerResponse.Message,
		DownlinkOption: handlerResponse.DownlinkOption,
	}

	return res, nil
}
Ejemplo n.º 7
0
func (b *broker) HandleUplink(uplink *pb.UplinkMessage) (err error) {
	ctx := b.Ctx.WithField("GatewayID", uplink.GatewayMetadata.GatewayId)
	start := time.Now()
	defer func() {
		if err != nil {
			ctx.WithError(err).Warn("Could not handle uplink")
		} else {
			ctx.WithField("Duration", time.Now().Sub(start)).Info("Handled uplink")
		}
	}()

	time := time.Now()

	b.status.uplink.Mark(1)

	// De-duplicate uplink messages
	duplicates := b.deduplicateUplink(uplink)
	if len(duplicates) == 0 {
		return nil
	}

	b.status.uplinkUnique.Mark(1)

	ctx = ctx.WithField("Duplicates", len(duplicates))

	base := duplicates[0]

	if base.ProtocolMetadata.GetLorawan() == nil {
		return errors.NewErrInvalidArgument("Uplink", "does not contain LoRaWAN metadata")
	}

	// LoRaWAN: Unmarshal
	var phyPayload lorawan.PHYPayload
	err = phyPayload.UnmarshalBinary(base.Payload)
	if err != nil {
		return err
	}
	macPayload, ok := phyPayload.MACPayload.(*lorawan.MACPayload)
	if !ok {
		return errors.NewErrInvalidArgument("Uplink", "does not contain a MAC payload")
	}

	// Request devices from NS
	devAddr := types.DevAddr(macPayload.FHDR.DevAddr)
	ctx = ctx.WithFields(log.Fields{
		"DevAddr": devAddr,
		"FCnt":    macPayload.FHDR.FCnt,
	})
	var getDevicesResp *networkserver.DevicesResponse
	getDevicesResp, err = b.ns.GetDevices(b.Component.GetContext(b.nsToken), &networkserver.DevicesRequest{
		DevAddr: &devAddr,
		FCnt:    macPayload.FHDR.FCnt,
	})
	if err != nil {
		return errors.Wrap(errors.FromGRPCError(err), "NetworkServer did not return devices")
	}
	b.status.deduplication.Update(int64(len(getDevicesResp.Results)))
	if len(getDevicesResp.Results) == 0 {
		return errors.NewErrNotFound(fmt.Sprintf("Device with DevAddr %s and FCnt <= %d", devAddr, macPayload.FHDR.FCnt))
	}
	ctx = ctx.WithField("DevAddrResults", len(getDevicesResp.Results))

	// Sort by FCntUp to optimize the number of MIC checks
	sort.Sort(ByFCntUp(getDevicesResp.Results))

	// Find AppEUI/DevEUI through MIC check
	var device *pb_lorawan.Device
	var micChecks int
	var originalFCnt uint32
	for _, candidate := range getDevicesResp.Results {
		nwkSKey := lorawan.AES128Key(*candidate.NwkSKey)

		// First check with the 16 bit counter
		micChecks++
		ok, err = phyPayload.ValidateMIC(nwkSKey)
		if err != nil {
			return err
		}
		if ok {
			device = candidate
			break
		}

		originalFCnt = macPayload.FHDR.FCnt
		if candidate.Uses32BitFCnt {
			macPayload.FHDR.FCnt = fcnt.GetFull(candidate.FCntUp, uint16(originalFCnt))

			// If 32 bit counter has different value, perform another MIC check
			if macPayload.FHDR.FCnt != originalFCnt {
				micChecks++
				ok, err = phyPayload.ValidateMIC(nwkSKey)
				if err != nil {
					return err
				}
				if ok {
					device = candidate
					break
				}
			}
		}

		return errors.NewErrNotFound("device that validates MIC")
	}
	ctx = ctx.WithFields(log.Fields{
		"MICChecks": micChecks,
		"DevEUI":    device.DevEui,
		"AppEUI":    device.AppEui,
		"AppID":     device.AppId,
		"DevID":     device.DevId,
		"FCnt":      originalFCnt,
	})
	if macPayload.FHDR.FCnt != originalFCnt {
		ctx = ctx.WithField("RealFCnt", macPayload.FHDR.FCnt)
	}

	if device.DisableFCntCheck {
		// TODO: Add warning to message?
	} else if device.FCntUp == 0 {

	} else if macPayload.FHDR.FCnt <= device.FCntUp || macPayload.FHDR.FCnt-device.FCntUp > maxFCntGap {
		// Replay attack or FCnt gap too big
		return errors.NewErrNotFound("device with matching FCnt")
	}

	// Add FCnt to Metadata (because it's not marshaled in lorawan payload)
	base.ProtocolMetadata.GetLorawan().FCnt = macPayload.FHDR.FCnt

	// Collect GatewayMetadata and DownlinkOptions
	var gatewayMetadata []*gateway.RxMetadata
	var downlinkOptions []*pb.DownlinkOption
	var downlinkMessage *pb.DownlinkMessage
	for _, duplicate := range duplicates {
		gatewayMetadata = append(gatewayMetadata, duplicate.GatewayMetadata)
		downlinkOptions = append(downlinkOptions, duplicate.DownlinkOptions...)
	}

	// Select best DownlinkOption
	if len(downlinkOptions) > 0 {
		downlinkMessage = &pb.DownlinkMessage{
			DevEui:         device.DevEui,
			AppEui:         device.AppEui,
			AppId:          device.AppId,
			DevId:          device.DevId,
			DownlinkOption: selectBestDownlink(downlinkOptions),
		}
	}

	// Build Uplink
	deduplicatedUplink := &pb.DeduplicatedUplinkMessage{
		Payload:          base.Payload,
		DevEui:           device.DevEui,
		DevId:            device.DevId,
		AppEui:           device.AppEui,
		AppId:            device.AppId,
		ProtocolMetadata: base.ProtocolMetadata,
		GatewayMetadata:  gatewayMetadata,
		ServerTime:       time.UnixNano(),
		ResponseTemplate: downlinkMessage,
	}

	// Pass Uplink through NS
	deduplicatedUplink, err = b.ns.Uplink(b.Component.GetContext(b.nsToken), deduplicatedUplink)
	if err != nil {
		return errors.Wrap(errors.FromGRPCError(err), "NetworkServer did not handle uplink")
	}

	var announcements []*pb_discovery.Announcement
	announcements, err = b.Discovery.GetAllHandlersForAppID(device.AppId)
	if err != nil {
		return err
	}
	if len(announcements) == 0 {
		return errors.NewErrNotFound(fmt.Sprintf("Handler for AppID %s", device.AppId))
	}
	if len(announcements) > 1 {
		return errors.NewErrInternal(fmt.Sprintf("Multiple Handlers for AppID %s", device.AppId))
	}

	var handler chan<- *pb.DeduplicatedUplinkMessage
	handler, err = b.getHandlerUplink(announcements[0].Id)
	if err != nil {
		return err
	}

	handler <- deduplicatedUplink

	return nil
}