// persist writes the current services to disc.
func (srvs *services) persist() {
for name, srv := range srvs.m {
if !srv.info.Monitored {
continue
}
content, err := json.Marshal(srv.targetGroups())
if err != nil {
log.Errorln(err)
continue
}
f, err := create("tgroups/" + name + ".json")
if err != nil {
log.Errorln(err)
continue
}
if _, err := f.Write(content); err != nil {
log.Errorln(err)
}
f.Close()
}
// Remove files for disappeared services.
for _, name := range srvs.del {
if err := os.Remove("tgroups/" + name + ".json"); err != nil {
log.Errorln(err)
}
}
srvs.del = nil
}
// persist writes the current services to disc.
func (srvs services) persist() {
var tgroups []*TargetGroup
// Write files for current services.
for job, instances := range srvs {
var targets []string
for _, addr := range instances {
targets = append(targets, addr)
}
tgroups = append(tgroups, &TargetGroup{
Targets: targets,
Labels: map[string]string{"job": job},
})
}
content, err := json.Marshal(tgroups)
if err != nil {
log.Errorln(err)
return
}
f, err := create(*targetFile)
if err != nil {
log.Errorln(err)
return
}
defer f.Close()
if _, err := f.Write(content); err != nil {
log.Errorln(err)
}
}
func (h *Handler) getTemplate(name string) (*template_std.Template, error) {
t := template_std.New("_base")
var err error
t.Funcs(template_std.FuncMap{
"since": time.Since,
"getConsoles": h.getConsoles,
"pathPrefix": func() string { return h.options.PathPrefix },
"stripLabels": func(lset clientmodel.LabelSet, labels ...clientmodel.LabelName) clientmodel.LabelSet {
for _, ln := range labels {
delete(lset, ln)
}
return lset
},
"globalURL": func(url string) string {
for _, localhostRepresentation := range localhostRepresentations {
url = strings.Replace(url, "//"+localhostRepresentation, "//"+h.options.Hostname, 1)
}
return url
},
"healthToClass": func(th retrieval.TargetHealth) string {
switch th {
case retrieval.HealthUnknown:
return "warning"
case retrieval.HealthGood:
return "success"
default:
return "danger"
}
},
})
file, err := h.getTemplateFile("_base")
if err != nil {
log.Errorln("Could not read base template:", err)
return nil, err
}
t, err = t.Parse(file)
if err != nil {
log.Errorln("Could not parse base template:", err)
}
file, err = h.getTemplateFile(name)
if err != nil {
log.Error("Could not read template %s: %s", name, err)
return nil, err
}
t, err = t.Parse(file)
if err != nil {
log.Errorf("Could not parse template %s: %s", name, err)
}
return t, err
}
// update the services based on the given node.
func (srvs *services) update(node *etcd.Node) {
if node.Dir {
for _, n := range node.Nodes {
srvs.update(n)
}
return
}
if pathPatInfo.MatchString(node.Key) {
var info *ServiceInfo
err := json.Unmarshal([]byte(node.Value), &info)
if err != nil {
log.Errorln(err)
return
}
name := pathPatInfo.FindStringSubmatch(node.Key)[1]
srv, ok := srvs.m[name]
if !ok {
srv = &service{instances: map[string]*Instance{}}
srvs.m[name] = srv
}
if !info.Monitored {
srvs.del = append(srvs.del, name)
}
srv.info = info
} else if pathPatInstance.MatchString(node.Key) {
match := pathPatInstance.FindStringSubmatch(node.Key)
name := match[1]
srv, ok := srvs.m[name]
if !ok {
log.Errorf("instance update for unknown service %q", name)
return
}
var inst *Instance
err := json.Unmarshal([]byte(node.Value), &inst)
if err != nil {
log.Errorln(err)
return
}
srv.instances[match[2]] = inst
} else {
log.Errorf("cannot resolve key %q", node.Key)
}
}
func (n *notifier) handleNotification(a *Alert, op notificationOp, config *pb.NotificationConfig) {
for _, pdConfig := range config.PagerdutyConfig {
if err := n.sendPagerDutyNotification(pdConfig.GetServiceKey(), op, a); err != nil {
log.Errorln("Error sending PagerDuty notification:", err)
}
}
for _, emailConfig := range config.EmailConfig {
if op == notificationOpResolve && !emailConfig.GetSendResolved() {
continue
}
if *smtpSmartHost == "" {
log.Warn("No SMTP smarthost configured, not sending email notification.")
continue
}
if err := n.sendEmailNotification(emailConfig.GetEmail(), op, a); err != nil {
log.Errorln("Error sending email notification:", err)
}
}
for _, poConfig := range config.PushoverConfig {
if op == notificationOpResolve && !poConfig.GetSendResolved() {
continue
}
if err := n.sendPushoverNotification(poConfig.GetToken(), op, poConfig.GetUserKey(), a); err != nil {
log.Errorln("Error sending Pushover notification:", err)
}
}
for _, hcConfig := range config.HipchatConfig {
if op == notificationOpResolve && !hcConfig.GetSendResolved() {
continue
}
if err := n.sendHipChatNotification(op, hcConfig, a); err != nil {
log.Errorln("Error sending HipChat notification:", err)
}
}
for _, scConfig := range config.SlackConfig {
if op == notificationOpResolve && !scConfig.GetSendResolved() {
continue
}
if err := n.sendSlackNotification(op, scConfig, a); err != nil {
log.Errorln("Error sending Slack notification:", err)
}
}
for _, fdConfig := range config.FlowdockConfig {
if op == notificationOpResolve && !fdConfig.GetSendResolved() {
continue
}
if err := n.sendFlowdockNotification(op, fdConfig, a); err != nil {
log.Errorln("Error sending Flowdock notification:", err)
}
}
for _, whConfig := range config.WebhookConfig {
if op == notificationOpResolve && !whConfig.GetSendResolved() {
continue
}
if err := n.sendWebhookNotification(op, whConfig, a); err != nil {
log.Errorln("Error sending Webhook notification:", err)
}
}
}
func (s *memorySeriesStorage) loop() {
checkpointTimer := time.NewTimer(s.checkpointInterval)
dirtySeriesCount := 0
defer func() {
checkpointTimer.Stop()
log.Info("Maintenance loop stopped.")
close(s.loopStopped)
}()
memoryFingerprints := s.cycleThroughMemoryFingerprints()
archivedFingerprints := s.cycleThroughArchivedFingerprints()
loop:
for {
select {
case <-s.loopStopping:
break loop
case <-checkpointTimer.C:
err := s.persistence.checkpointSeriesMapAndHeads(s.fpToSeries, s.fpLocker)
if err != nil {
log.Errorln("Error while checkpointing:", err)
} else {
dirtySeriesCount = 0
}
checkpointTimer.Reset(s.checkpointInterval)
case fp := <-memoryFingerprints:
if s.maintainMemorySeries(fp, model.Now().Add(-s.dropAfter)) {
dirtySeriesCount++
// Check if we have enough "dirty" series so that we need an early checkpoint.
// However, if we are already behind persisting chunks, creating a checkpoint
// would be counterproductive, as it would slow down chunk persisting even more,
// while in a situation like that, where we are clearly lacking speed of disk
// maintenance, the best we can do for crash recovery is to persist chunks as
// quickly as possible. So only checkpoint if the storage is not in "graceful
// degradation mode".
if dirtySeriesCount >= s.checkpointDirtySeriesLimit && !s.isDegraded() {
checkpointTimer.Reset(0)
}
}
case fp := <-archivedFingerprints:
s.maintainArchivedSeries(fp, model.Now().Add(-s.dropAfter))
}
}
// Wait until both channels are closed.
for range memoryFingerprints {
}
for range archivedFingerprints {
}
}
// Start implements Storage.
func (s *memorySeriesStorage) Start() (err error) {
var syncStrategy syncStrategy
switch s.options.SyncStrategy {
case Never:
syncStrategy = func() bool { return false }
case Always:
syncStrategy = func() bool { return true }
case Adaptive:
syncStrategy = func() bool { return !s.isDegraded() }
default:
panic("unknown sync strategy")
}
var p *persistence
p, err = newPersistence(s.options.PersistenceStoragePath, s.options.Dirty, s.options.PedanticChecks, syncStrategy)
if err != nil {
return err
}
s.persistence = p
// Persistence must start running before loadSeriesMapAndHeads() is called.
go s.persistence.run()
defer func() {
if err != nil {
if e := p.close(); e != nil {
log.Errorln("Error closing persistence:", e)
}
}
}()
log.Info("Loading series map and head chunks...")
s.fpToSeries, s.numChunksToPersist, err = p.loadSeriesMapAndHeads()
if err != nil {
return err
}
log.Infof("%d series loaded.", s.fpToSeries.length())
s.numSeries.Set(float64(s.fpToSeries.length()))
s.mapper, err = newFPMapper(s.fpToSeries, p)
if err != nil {
return err
}
go s.handleEvictList()
go s.loop()
return nil
}
func main() {
flag.Parse()
client := etcd.NewClient([]string{etcdServer})
srvs := &services{
m: map[string]*service{},
}
updates := make(chan *etcd.Response)
// Perform an initial read of all services.
res, err := client.Get(servicesPrefix, false, true)
if err != nil {
log.Fatalf("Error on initial retrieval: %s", err)
}
srvs.update(res.Node)
srvs.persist()
// Start watching for updates.
go func() {
res, err := client.Watch(servicesPrefix, 0, true, updates, nil)
if err != nil {
log.Errorln(err)
}
log.Infoln(res)
}()
// Apply updates sent on the channel.
for res := range updates {
if res.Action == "delete" {
log.Debugf("delete: %s", res.Node.Key)
srvs.delete(res.Node)
} else {
log.Debugf("%s: %s = %s", res.Action, res.Node.Key, res.Node.Value)
srvs.update(res.Node)
}
srvs.persist()
}
}
func main() {
flag.Parse()
var (
client = etcd.NewClient([]string{*etcdServer})
srvs = services{}
updates = make(chan *etcd.Response)
)
// Perform an initial read of all services.
res, err := client.Get(servicesPrefix, false, true)
if err != nil {
log.Fatalf("Error on initial retrieval: %s", err)
}
srvs.handle(res.Node, srvs.update)
srvs.persist()
// Start watching for updates.
go func() {
_, err := client.Watch(servicesPrefix, 0, true, updates, nil)
if err != nil {
log.Errorln(err)
}
}()
// Apply updates sent on the channel.
for res := range updates {
log.Infoln(res.Action, res.Node.Key, res.Node.Value)
h := srvs.update
if res.Action == "delete" {
h = srvs.delete
}
srvs.handle(res.Node, h)
srvs.persist()
}
}
func Main() int {
if err := parse(os.Args[1:]); err != nil {
return 2
}
versionInfoTmpl.Execute(os.Stdout, BuildInfo)
if cfg.printVersion {
return 0
}
memStorage := local.NewMemorySeriesStorage(&cfg.storage)
var (
sampleAppender storage.SampleAppender
remoteStorageQueues []*remote.StorageQueueManager
)
if cfg.opentsdbURL == "" && cfg.influxdbURL == "" {
log.Warnf("No remote storage URLs provided; not sending any samples to long-term storage")
sampleAppender = memStorage
} else {
fanout := storage.Fanout{memStorage}
addRemoteStorage := func(c remote.StorageClient) {
qm := remote.NewStorageQueueManager(c, 100*1024)
fanout = append(fanout, qm)
remoteStorageQueues = append(remoteStorageQueues, qm)
}
if cfg.opentsdbURL != "" {
addRemoteStorage(opentsdb.NewClient(cfg.opentsdbURL, cfg.remoteStorageTimeout))
}
if cfg.influxdbURL != "" {
addRemoteStorage(influxdb.NewClient(cfg.influxdbURL, cfg.remoteStorageTimeout, cfg.influxdbDatabase, cfg.influxdbRetentionPolicy))
}
sampleAppender = fanout
}
var (
notificationHandler = notification.NewNotificationHandler(&cfg.notification)
targetManager = retrieval.NewTargetManager(sampleAppender)
queryEngine = promql.NewEngine(memStorage, &cfg.queryEngine)
)
ruleManager := rules.NewManager(&rules.ManagerOptions{
SampleAppender: sampleAppender,
NotificationHandler: notificationHandler,
QueryEngine: queryEngine,
PrometheusURL: cfg.prometheusURL,
PathPrefix: cfg.web.PathPrefix,
})
flags := map[string]string{}
cfg.fs.VisitAll(func(f *flag.Flag) {
flags[f.Name] = f.Value.String()
})
status := &web.PrometheusStatus{
BuildInfo: BuildInfo,
TargetPools: targetManager.Pools,
Rules: ruleManager.Rules,
Flags: flags,
Birth: time.Now(),
}
webHandler := web.New(memStorage, queryEngine, ruleManager, status, &cfg.web)
if !reloadConfig(cfg.configFile, status, targetManager, ruleManager) {
os.Exit(1)
}
// Wait for reload or termination signals. Start the handler for SIGHUP as
// early as possible, but ignore it until we are ready to handle reloading
// our config.
hup := make(chan os.Signal)
hupReady := make(chan bool)
signal.Notify(hup, syscall.SIGHUP)
go func() {
<-hupReady
for range hup {
reloadConfig(cfg.configFile, status, targetManager, ruleManager)
}
}()
// Start all components.
if err := memStorage.Start(); err != nil {
log.Errorln("Error opening memory series storage:", err)
return 1
}
defer func() {
if err := memStorage.Stop(); err != nil {
log.Errorln("Error stopping storage:", err)
}
}()
// The storage has to be fully initialized before registering.
registry.MustRegister(memStorage)
registry.MustRegister(notificationHandler)
for _, q := range remoteStorageQueues {
registry.MustRegister(q)
go q.Run()
defer q.Stop()
}
go ruleManager.Run()
defer ruleManager.Stop()
go notificationHandler.Run()
defer notificationHandler.Stop()
go targetManager.Run()
defer targetManager.Stop()
defer queryEngine.Stop()
go webHandler.Run()
// Wait for reload or termination signals.
close(hupReady) // Unblock SIGHUP handler.
term := make(chan os.Signal)
signal.Notify(term, os.Interrupt, syscall.SIGTERM)
select {
case <-term:
log.Warn("Received SIGTERM, exiting gracefully...")
case <-webHandler.Quit():
log.Warn("Received termination request via web service, exiting gracefully...")
}
close(hup)
log.Info("See you next time!")
return 0
}
// Main manages the startup and shutdown lifecycle of the entire Prometheus server.
func Main() int {
if err := parse(os.Args[1:]); err != nil {
return 2
}
printVersion()
if cfg.printVersion {
return 0
}
var reloadables []Reloadable
var (
memStorage = local.NewMemorySeriesStorage(&cfg.storage)
remoteStorage = remote.New(&cfg.remote)
sampleAppender = storage.Fanout{memStorage}
)
if remoteStorage != nil {
sampleAppender = append(sampleAppender, remoteStorage)
reloadables = append(reloadables, remoteStorage)
}
var (
notificationHandler = notification.NewNotificationHandler(&cfg.notification)
targetManager = retrieval.NewTargetManager(sampleAppender)
queryEngine = promql.NewEngine(memStorage, &cfg.queryEngine)
)
ruleManager := rules.NewManager(&rules.ManagerOptions{
SampleAppender: sampleAppender,
NotificationHandler: notificationHandler,
QueryEngine: queryEngine,
ExternalURL: cfg.web.ExternalURL,
})
flags := map[string]string{}
cfg.fs.VisitAll(func(f *flag.Flag) {
flags[f.Name] = f.Value.String()
})
status := &web.PrometheusStatus{
TargetPools: targetManager.Pools,
Rules: ruleManager.Rules,
Flags: flags,
Birth: time.Now(),
}
webHandler := web.New(memStorage, queryEngine, ruleManager, status, &cfg.web)
reloadables = append(reloadables, status, targetManager, ruleManager, webHandler, notificationHandler)
if !reloadConfig(cfg.configFile, reloadables...) {
return 1
}
// Wait for reload or termination signals. Start the handler for SIGHUP as
// early as possible, but ignore it until we are ready to handle reloading
// our config.
hup := make(chan os.Signal)
hupReady := make(chan bool)
signal.Notify(hup, syscall.SIGHUP)
go func() {
<-hupReady
for {
select {
case <-hup:
case <-webHandler.Reload():
}
reloadConfig(cfg.configFile, reloadables...)
}
}()
// Start all components.
if err := memStorage.Start(); err != nil {
log.Errorln("Error opening memory series storage:", err)
return 1
}
defer func() {
if err := memStorage.Stop(); err != nil {
log.Errorln("Error stopping storage:", err)
}
}()
if remoteStorage != nil {
prometheus.MustRegister(remoteStorage)
go remoteStorage.Run()
defer remoteStorage.Stop()
}
// The storage has to be fully initialized before registering.
prometheus.MustRegister(memStorage)
prometheus.MustRegister(notificationHandler)
prometheus.MustRegister(configSuccess)
prometheus.MustRegister(configSuccessTime)
go ruleManager.Run()
defer ruleManager.Stop()
go notificationHandler.Run()
defer notificationHandler.Stop()
go targetManager.Run()
defer targetManager.Stop()
defer queryEngine.Stop()
go webHandler.Run()
// Wait for reload or termination signals.
close(hupReady) // Unblock SIGHUP handler.
term := make(chan os.Signal)
signal.Notify(term, os.Interrupt, syscall.SIGTERM)
select {
case <-term:
log.Warn("Received SIGTERM, exiting gracefully...")
case <-webHandler.Quit():
log.Warn("Received termination request via web service, exiting gracefully...")
case err := <-webHandler.ListenError():
log.Errorln("Error starting web server, exiting gracefully:", err)
}
log.Info("See you next time!")
return 0
}
func (e *Exporter) scrape(ch chan<- prometheus.Metric) {
defer func(begun time.Time) {
e.duration.Set(time.Since(begun).Seconds())
}(time.Now())
e.error.Set(0)
e.totalScrapes.Inc()
db, err := sql.Open("postgres", e.dsn)
if err != nil {
log.Println("Error opening connection to database:", err)
e.error.Set(1)
return
}
defer db.Close()
for namespaceAndQuery, mapping := range e.metricMap {
namespace := namespaceAndQuery.namespace
log.Debugln("Querying namespace: ", namespace, " query: ", namespaceAndQuery.query)
func() { // Don't fail on a bad scrape of one metric
rows, err := db.Query(namespaceAndQuery.query)
if err != nil {
log.Println("Error running query on database: ", namespace, err)
e.error.Set(1)
return
}
defer rows.Close()
var columnNames []string
columnNames, err = rows.Columns()
if err != nil {
log.Println("Error retrieving column list for: ", namespace, err)
e.error.Set(1)
return
}
// Make a lookup map for the column indices
var columnIdx = make(map[string]int, len(columnNames))
for i, n := range columnNames {
columnIdx[n] = i
}
var columnData = make([]interface{}, len(columnNames))
var scanArgs = make([]interface{}, len(columnNames))
for i := range columnData {
scanArgs[i] = &columnData[i]
}
for rows.Next() {
err = rows.Scan(scanArgs...)
if err != nil {
log.Println("Error retrieving rows:", namespace, err)
e.error.Set(1)
return
}
// Get the label values for this row
var labels = make([]string, len(mapping.labels))
for idx, columnName := range mapping.labels {
labels[idx], _ = dbToString(columnData[columnIdx[columnName]])
}
// Loop over column names, and match to scan data. Unknown columns
// will be filled with an untyped metric number *if* they can be
// converted to float64s. NULLs are allowed and treated as NaN.
for idx, columnName := range columnNames {
if metricMapping, ok := mapping.columnMappings[columnName]; ok {
// Is this a metricy metric?
if metricMapping.discard {
continue
}
value, ok := dbToFloat64(columnData[idx])
if !ok {
e.error.Set(1)
log.Errorln("Unexpected error parsing column: ", namespace, columnName, columnData[idx])
continue
}
// Generate the metric
ch <- prometheus.MustNewConstMetric(metricMapping.desc, metricMapping.vtype, value, labels...)
} else {
// Unknown metric. Report as untyped if scan to float64 works, else note an error too.
desc := prometheus.NewDesc(fmt.Sprintf("%s_%s", namespace, columnName), fmt.Sprintf("Unknown metric from %s", namespace), nil, nil)
// Its not an error to fail here, since the values are
// unexpected anyway.
value, ok := dbToFloat64(columnData[idx])
if !ok {
log.Warnln("Unparseable column type - discarding: ", namespace, columnName, err)
continue
}
ch <- prometheus.MustNewConstMetric(desc, prometheus.UntypedValue, value, labels...)
}
}
}
}()
}
}
// Turn the MetricMap column mapping into a prometheus descriptor mapping.
func makeDescMap(metricMaps map[string]map[string]ColumnMapping) map[string]MetricMapNamespace {
var metricMap = make(map[string]MetricMapNamespace)
for namespace, mappings := range metricMaps {
thisMap := make(map[string]MetricMap)
// Get the constant labels
var constLabels []string
for columnName, columnMapping := range mappings {
if columnMapping.usage == LABEL {
constLabels = append(constLabels, columnName)
}
}
for columnName, columnMapping := range mappings {
switch columnMapping.usage {
case DISCARD, LABEL:
thisMap[columnName] = MetricMap{
discard: true,
conversion: func(in interface{}) (float64, bool) {
return math.NaN(), true
},
}
case COUNTER:
thisMap[columnName] = MetricMap{
vtype: prometheus.CounterValue,
desc: prometheus.NewDesc(fmt.Sprintf("%s_%s", namespace, columnName), columnMapping.description, constLabels, nil),
conversion: func(in interface{}) (float64, bool) {
return dbToFloat64(in)
},
}
case GAUGE:
thisMap[columnName] = MetricMap{
vtype: prometheus.GaugeValue,
desc: prometheus.NewDesc(fmt.Sprintf("%s_%s", namespace, columnName), columnMapping.description, constLabels, nil),
conversion: func(in interface{}) (float64, bool) {
return dbToFloat64(in)
},
}
case MAPPEDMETRIC:
thisMap[columnName] = MetricMap{
vtype: prometheus.GaugeValue,
desc: prometheus.NewDesc(fmt.Sprintf("%s_%s", namespace, columnName), columnMapping.description, constLabels, nil),
conversion: func(in interface{}) (float64, bool) {
text, ok := in.(string)
if !ok {
return math.NaN(), false
}
val, ok := columnMapping.mapping[text]
if !ok {
return math.NaN(), false
}
return val, true
},
}
case DURATION:
thisMap[columnName] = MetricMap{
vtype: prometheus.GaugeValue,
desc: prometheus.NewDesc(fmt.Sprintf("%s_%s_milliseconds", namespace, columnName), columnMapping.description, constLabels, nil),
conversion: func(in interface{}) (float64, bool) {
var durationString string
switch t := in.(type) {
case []byte:
durationString = string(t)
case string:
durationString = t
default:
log.Errorln("DURATION conversion metric was not a string")
return math.NaN(), false
}
d, err := time.ParseDuration(durationString)
if err != nil {
log.Errorln("Failed converting result to metric:", columnName, in, err)
return math.NaN(), false
}
return float64(d / time.Millisecond), true
},
}
}
}
metricMap[namespace] = MetricMapNamespace{constLabels, thisMap}
}
return metricMap
}
