// Copyright (c) Tailscale Inc & AUTHORS // SPDX-License-Identifier: BSD-3-Clause // Package prober implements a simple blackbox prober. Each probe runs // in its own goroutine, and run results are recorded as Prometheus // metrics. package prober import ( "container/ring" "context" "fmt" "hash/fnv" "log" "maps" "math/rand" "net/http" "sync" "time" "github.com/prometheus/client_golang/prometheus" "tailscale.com/tsweb" ) // recentHistSize is the number of recent probe results and latencies to keep // in memory. const recentHistSize = 10 // ProbeClass defines a probe of a specific type: a probing function that will // be regularly ran, and metric labels that will be added automatically to all // probes using this class. type ProbeClass struct { // Probe is a function that probes something and reports whether the Probe // succeeded. The provided context's deadline must be obeyed for correct // Probe scheduling. Probe func(context.Context) error // Class defines a user-facing name of the probe class that will be used // in the `class` metric label. Class string // Labels defines a set of metric labels that will be added to all metrics // exposed by this probe class. Labels Labels // Metrics allows a probe class to export custom Metrics. Can be nil. Metrics func(prometheus.Labels) []prometheus.Metric } // FuncProbe wraps a simple probe function in a ProbeClass. func FuncProbe(fn func(context.Context) error) ProbeClass { return ProbeClass{ Probe: fn, } } // a Prober manages a set of probes and keeps track of their results. type Prober struct { // Whether to spread probe execution over time by introducing a // random delay before the first probe run. spread bool // Whether to run all probes once instead of running them in a loop. once bool // Time-related functions that get faked out during tests. now func() time.Time newTicker func(time.Duration) ticker mu sync.Mutex // protects all following fields probes map[string]*Probe namespace string metrics *prometheus.Registry } // New returns a new Prober. func New() *Prober { return newForTest(time.Now, newRealTicker) } func newForTest(now func() time.Time, newTicker func(time.Duration) ticker) *Prober { p := &Prober{ now: now, newTicker: newTicker, probes: map[string]*Probe{}, metrics: prometheus.NewRegistry(), namespace: "prober", } prometheus.DefaultRegisterer.MustRegister(p.metrics) return p } // Run executes probe class function every interval, and exports probe results under probeName. // // Registering a probe under an already-registered name panics. func (p *Prober) Run(name string, interval time.Duration, labels Labels, pc ProbeClass) *Probe { p.mu.Lock() defer p.mu.Unlock() if _, ok := p.probes[name]; ok { panic(fmt.Sprintf("probe named %q already registered", name)) } l := prometheus.Labels{ "name": name, "class": pc.Class, } for k, v := range pc.Labels { l[k] = v } for k, v := range labels { l[k] = v } probe := newProbe(p, name, interval, l, pc) p.probes[name] = probe go probe.loop() return probe } // newProbe creates a new Probe with the given parameters, but does not start it. func newProbe(p *Prober, name string, interval time.Duration, l prometheus.Labels, pc ProbeClass) *Probe { ctx, cancel := context.WithCancel(context.Background()) probe := &Probe{ prober: p, ctx: ctx, cancel: cancel, stopped: make(chan struct{}), name: name, probeClass: pc, interval: interval, initialDelay: initialDelay(name, interval), successHist: ring.New(recentHistSize), latencyHist: ring.New(recentHistSize), metrics: prometheus.NewRegistry(), metricLabels: l, mInterval: prometheus.NewDesc("interval_secs", "Probe interval in seconds", nil, l), mStartTime: prometheus.NewDesc("start_secs", "Latest probe start time (seconds since epoch)", nil, l), mEndTime: prometheus.NewDesc("end_secs", "Latest probe end time (seconds since epoch)", nil, l), mLatency: prometheus.NewDesc("latency_millis", "Latest probe latency (ms)", nil, l), mResult: prometheus.NewDesc("result", "Latest probe result (1 = success, 0 = failure)", nil, l), mAttempts: prometheus.NewCounterVec(prometheus.CounterOpts{ Name: "attempts_total", Help: "Total number of probing attempts", ConstLabels: l, }, []string{"status"}), mSeconds: prometheus.NewCounterVec(prometheus.CounterOpts{ Name: "seconds_total", Help: "Total amount of time spent executing the probe", ConstLabels: l, }, []string{"status"}), } if p.metrics != nil { prometheus.WrapRegistererWithPrefix(p.namespace+"_", p.metrics).MustRegister(probe.metrics) } probe.metrics.MustRegister(probe) return probe } // unregister removes a probe from the prober's internal state. func (p *Prober) unregister(probe *Probe) { p.mu.Lock() defer p.mu.Unlock() probe.metrics.Unregister(probe) p.metrics.Unregister(probe.metrics) name := probe.name delete(p.probes, name) } // WithSpread is used to enable random delay before the first run of // each added probe. func (p *Prober) WithSpread(s bool) *Prober { p.spread = s return p } // WithOnce mode can be used if you want to run all configured probes once // rather than on a schedule. func (p *Prober) WithOnce(s bool) *Prober { p.once = s return p } // WithMetricNamespace allows changing metric name prefix from the default `prober`. func (p *Prober) WithMetricNamespace(n string) *Prober { p.namespace = n return p } // Wait blocks until all probes have finished execution. It should typically // be used with the `once` mode to wait for probes to finish before collecting // their results. func (p *Prober) Wait() { for { chans := make([]chan struct{}, 0) p.mu.Lock() for _, p := range p.probes { chans = append(chans, p.stopped) } p.mu.Unlock() for _, c := range chans { <-c } // Since probes can add other probes, retry if the number of probes has changed. if p.activeProbes() != len(chans) { continue } return } } // Reports the number of registered probes. func (p *Prober) activeProbes() int { p.mu.Lock() defer p.mu.Unlock() return len(p.probes) } // Probe is a probe that healthchecks something and updates Prometheus // metrics with the results. type Probe struct { prober *Prober ctx context.Context cancel context.CancelFunc // run to initiate shutdown stopped chan struct{} // closed when shutdown is complete runMu sync.Mutex // ensures only one probe runs at a time name string probeClass ProbeClass interval time.Duration initialDelay time.Duration tick ticker // metrics is a Prometheus metrics registry for metrics exported by this probe. // Using a separate registry allows cleanly removing metrics exported by this // probe when it gets unregistered. metrics *prometheus.Registry metricLabels prometheus.Labels mInterval *prometheus.Desc mStartTime *prometheus.Desc mEndTime *prometheus.Desc mLatency *prometheus.Desc mResult *prometheus.Desc mAttempts *prometheus.CounterVec mSeconds *prometheus.CounterVec mu sync.Mutex start time.Time // last time doProbe started end time.Time // last time doProbe returned latency time.Duration // last successful probe latency succeeded bool // whether the last doProbe call succeeded lastErr error // History of recent probe results and latencies. successHist *ring.Ring latencyHist *ring.Ring } // Close shuts down the Probe and unregisters it from its Prober. // It is safe to Run a new probe of the same name after Close returns. func (p *Probe) Close() error { p.cancel() <-p.stopped p.prober.unregister(p) return nil } // probeLoop invokes runProbe on fun every interval. The first probe // is run after a random delay (if spreading is enabled) or immediately. func (p *Probe) loop() { defer close(p.stopped) if p.prober.spread && p.initialDelay > 0 { t := p.prober.newTicker(p.initialDelay) select { case <-t.Chan(): p.run() case <-p.ctx.Done(): t.Stop() return } t.Stop() } else { p.run() } if p.prober.once { return } p.tick = p.prober.newTicker(p.interval) defer p.tick.Stop() for { select { case <-p.tick.Chan(): p.run() case <-p.ctx.Done(): return } } } // run invokes the probe function and records the result. It returns the probe // result and an error if the probe failed. // // The probe function is invoked with a timeout slightly less than interval, so // that the probe either succeeds or fails before the next cycle is scheduled to // start. func (p *Probe) run() (pi ProbeInfo, err error) { p.runMu.Lock() defer p.runMu.Unlock() p.recordStart() defer func() { // Prevent a panic within one probe function from killing the // entire prober, so that a single buggy probe doesn't destroy // our entire ability to monitor anything. A panic is recorded // as a probe failure, so panicking probes will trigger an // alert for debugging. if r := recover(); r != nil { log.Printf("probe %s panicked: %v", p.name, r) err = fmt.Errorf("panic: %v", r) p.recordEnd(err) } }() timeout := time.Duration(float64(p.interval) * 0.8) ctx, cancel := context.WithTimeout(p.ctx, timeout) defer cancel() err = p.probeClass.Probe(ctx) p.recordEnd(err) if err != nil { log.Printf("probe %s: %v", p.name, err) } pi = p.probeInfoLocked() return } func (p *Probe) recordStart() { p.mu.Lock() p.start = p.prober.now() p.mu.Unlock() } func (p *Probe) recordEnd(err error) { end := p.prober.now() p.mu.Lock() defer p.mu.Unlock() p.end = end p.succeeded = err == nil p.lastErr = err latency := end.Sub(p.start) if p.succeeded { p.latency = latency p.mAttempts.WithLabelValues("ok").Inc() p.mSeconds.WithLabelValues("ok").Add(latency.Seconds()) p.latencyHist.Value = latency p.latencyHist = p.latencyHist.Next() } else { p.latency = 0 p.mAttempts.WithLabelValues("fail").Inc() p.mSeconds.WithLabelValues("fail").Add(latency.Seconds()) } p.successHist.Value = p.succeeded p.successHist = p.successHist.Next() } // ProbeInfo is a snapshot of the configuration and state of a Probe. type ProbeInfo struct { Name string Class string Interval time.Duration Labels map[string]string Start time.Time End time.Time Latency time.Duration Result bool Error string RecentResults []bool RecentLatencies []time.Duration } // RecentSuccessRatio returns the success ratio of the probe in the recent history. func (pb ProbeInfo) RecentSuccessRatio() float64 { if len(pb.RecentResults) == 0 { return 0 } var sum int for _, r := range pb.RecentResults { if r { sum++ } } return float64(sum) / float64(len(pb.RecentResults)) } // RecentMedianLatency returns the median latency of the probe in the recent history. func (pb ProbeInfo) RecentMedianLatency() time.Duration { if len(pb.RecentLatencies) == 0 { return 0 } return pb.RecentLatencies[len(pb.RecentLatencies)/2] } // ProbeInfo returns the state of all probes. func (p *Prober) ProbeInfo() map[string]ProbeInfo { out := map[string]ProbeInfo{} p.mu.Lock() probes := make([]*Probe, 0, len(p.probes)) for _, probe := range p.probes { probes = append(probes, probe) } p.mu.Unlock() for _, probe := range probes { probe.mu.Lock() out[probe.name] = probe.probeInfoLocked() probe.mu.Unlock() } return out } // probeInfoLocked returns the state of the probe. func (probe *Probe) probeInfoLocked() ProbeInfo { inf := ProbeInfo{ Name: probe.name, Class: probe.probeClass.Class, Interval: probe.interval, Labels: probe.metricLabels, Start: probe.start, End: probe.end, Result: probe.succeeded, } if probe.lastErr != nil { inf.Error = probe.lastErr.Error() } if probe.latency > 0 { inf.Latency = probe.latency } probe.latencyHist.Do(func(v any) { if l, ok := v.(time.Duration); ok { inf.RecentLatencies = append(inf.RecentLatencies, l) } }) probe.successHist.Do(func(v any) { if r, ok := v.(bool); ok { inf.RecentResults = append(inf.RecentResults, r) } }) return inf } // RunHandler runs a probe by name and returns the result as an HTTP response. func (p *Prober) RunHandler(w http.ResponseWriter, r *http.Request) error { // Look up prober by name. name := r.FormValue("name") if name == "" { return tsweb.Error(http.StatusBadRequest, "missing name parameter", nil) } p.mu.Lock() probe, ok := p.probes[name] prevInfo := probe.probeInfoLocked() p.mu.Unlock() if !ok { return tsweb.Error(http.StatusNotFound, fmt.Sprintf("unknown probe %q", name), nil) } info, err := probe.run() stats := fmt.Sprintf("Previous runs: success rate %d%%, median latency %v", int(prevInfo.RecentSuccessRatio()*100), prevInfo.RecentMedianLatency()) if err != nil { return tsweb.Error(http.StatusFailedDependency, fmt.Sprintf("Probe failed: %s\n%s", err.Error(), stats), err) } w.WriteHeader(respStatus) w.Write([]byte(fmt.Sprintf("Probe succeeded in %v\n%s", info.Latency, stats))) return nil } // Describe implements prometheus.Collector. func (p *Probe) Describe(ch chan<- *prometheus.Desc) { ch <- p.mInterval ch <- p.mStartTime ch <- p.mEndTime ch <- p.mResult ch <- p.mLatency p.mAttempts.Describe(ch) p.mSeconds.Describe(ch) if p.probeClass.Metrics != nil { for _, m := range p.probeClass.Metrics(p.metricLabels) { ch <- m.Desc() } } } // Collect implements prometheus.Collector. func (p *Probe) Collect(ch chan<- prometheus.Metric) { p.mu.Lock() defer p.mu.Unlock() ch <- prometheus.MustNewConstMetric(p.mInterval, prometheus.GaugeValue, p.interval.Seconds()) if !p.start.IsZero() { ch <- prometheus.MustNewConstMetric(p.mStartTime, prometheus.GaugeValue, float64(p.start.Unix())) } if p.end.IsZero() { return } ch <- prometheus.MustNewConstMetric(p.mEndTime, prometheus.GaugeValue, float64(p.end.Unix())) if p.succeeded { ch <- prometheus.MustNewConstMetric(p.mResult, prometheus.GaugeValue, 1) } else { ch <- prometheus.MustNewConstMetric(p.mResult, prometheus.GaugeValue, 0) } if p.latency > 0 { ch <- prometheus.MustNewConstMetric(p.mLatency, prometheus.GaugeValue, float64(p.latency.Milliseconds())) } p.mAttempts.Collect(ch) p.mSeconds.Collect(ch) if p.probeClass.Metrics != nil { for _, m := range p.probeClass.Metrics(p.metricLabels) { ch <- m } } } // ticker wraps a time.Ticker in a way that can be faked for tests. type ticker interface { Chan() <-chan time.Time Stop() } type realTicker struct { *time.Ticker } func (t *realTicker) Chan() <-chan time.Time { return t.Ticker.C } func newRealTicker(d time.Duration) ticker { return &realTicker{time.NewTicker(d)} } // initialDelay returns a pseudorandom duration in [0, interval) that // is based on the provided seed string. func initialDelay(seed string, interval time.Duration) time.Duration { h := fnv.New64() fmt.Fprint(h, seed) r := rand.New(rand.NewSource(int64(h.Sum64()))).Float64() return time.Duration(float64(interval) * r) } // Labels is a set of metric labels used by a prober. type Labels map[string]string func (l Labels) With(k, v string) Labels { new := maps.Clone(l) new[k] = v return new }