// Copyright 2016 The Prometheus Authors // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package scrape import ( "bufio" "bytes" "context" "errors" "fmt" "io" "math" "net/http" "reflect" "slices" "strconv" "strings" "sync" "time" "github.com/go-kit/log" "github.com/go-kit/log/level" "github.com/klauspost/compress/gzip" config_util "github.com/prometheus/common/config" "github.com/prometheus/common/model" "github.com/prometheus/common/version" "github.com/prometheus/prometheus/config" "github.com/prometheus/prometheus/discovery/targetgroup" "github.com/prometheus/prometheus/model/exemplar" "github.com/prometheus/prometheus/model/histogram" "github.com/prometheus/prometheus/model/labels" "github.com/prometheus/prometheus/model/metadata" "github.com/prometheus/prometheus/model/relabel" "github.com/prometheus/prometheus/model/textparse" "github.com/prometheus/prometheus/model/timestamp" "github.com/prometheus/prometheus/model/value" "github.com/prometheus/prometheus/storage" "github.com/prometheus/prometheus/util/pool" ) // ScrapeTimestampTolerance is the tolerance for scrape appends timestamps // alignment, to enable better compression at the TSDB level. // See https://github.com/prometheus/prometheus/issues/7846 var ScrapeTimestampTolerance = 2 * time.Millisecond // AlignScrapeTimestamps enables the tolerance for scrape appends timestamps described above. var AlignScrapeTimestamps = true var errNameLabelMandatory = fmt.Errorf("missing metric name (%s label)", labels.MetricName) // scrapePool manages scrapes for sets of targets. type scrapePool struct { appendable storage.Appendable logger log.Logger cancel context.CancelFunc httpOpts []config_util.HTTPClientOption // mtx must not be taken after targetMtx. mtx sync.Mutex config *config.ScrapeConfig client *http.Client loops map[uint64]loop symbolTable *labels.SymbolTable lastSymbolTableCheck time.Time initialSymbolTableLen int targetMtx sync.Mutex // activeTargets and loops must always be synchronized to have the same // set of hashes. activeTargets map[uint64]*Target droppedTargets []*Target // Subject to KeepDroppedTargets limit. droppedTargetsCount int // Count of all dropped targets. // Constructor for new scrape loops. This is settable for testing convenience. newLoop func(scrapeLoopOptions) loop noDefaultPort bool metrics *scrapeMetrics } type labelLimits struct { labelLimit int labelNameLengthLimit int labelValueLengthLimit int } type scrapeLoopOptions struct { target *Target scraper scraper sampleLimit int bucketLimit int maxSchema int32 labelLimits *labelLimits honorLabels bool honorTimestamps bool trackTimestampsStaleness bool interval time.Duration timeout time.Duration scrapeClassicHistograms bool mrc []*relabel.Config cache *scrapeCache enableCompression bool } const maxAheadTime = 10 * time.Minute // returning an empty label set is interpreted as "drop". type labelsMutator func(labels.Labels) labels.Labels func newScrapePool(cfg *config.ScrapeConfig, app storage.Appendable, offsetSeed uint64, logger log.Logger, buffers *pool.Pool, options *Options, metrics *scrapeMetrics) (*scrapePool, error) { if logger == nil { logger = log.NewNopLogger() } client, err := config_util.NewClientFromConfig(cfg.HTTPClientConfig, cfg.JobName, options.HTTPClientOptions...) if err != nil { return nil, fmt.Errorf("error creating HTTP client: %w", err) } ctx, cancel := context.WithCancel(context.Background()) sp := &scrapePool{ cancel: cancel, appendable: app, config: cfg, client: client, activeTargets: map[uint64]*Target{}, loops: map[uint64]loop{}, symbolTable: labels.NewSymbolTable(), lastSymbolTableCheck: time.Now(), logger: logger, metrics: metrics, httpOpts: options.HTTPClientOptions, noDefaultPort: options.NoDefaultPort, } sp.newLoop = func(opts scrapeLoopOptions) loop { // Update the targets retrieval function for metadata to a new scrape cache. cache := opts.cache if cache == nil { cache = newScrapeCache(metrics) } opts.target.SetMetadataStore(cache) return newScrapeLoop( ctx, opts.scraper, log.With(logger, "target", opts.target), buffers, func(l labels.Labels) labels.Labels { return mutateSampleLabels(l, opts.target, opts.honorLabels, opts.mrc) }, func(l labels.Labels) labels.Labels { return mutateReportSampleLabels(l, opts.target) }, func(ctx context.Context) storage.Appender { return app.Appender(ctx) }, cache, sp.symbolTable, offsetSeed, opts.honorTimestamps, opts.trackTimestampsStaleness, opts.enableCompression, opts.sampleLimit, opts.bucketLimit, opts.maxSchema, opts.labelLimits, opts.interval, opts.timeout, opts.scrapeClassicHistograms, options.EnableNativeHistogramsIngestion, options.EnableCreatedTimestampZeroIngestion, options.ExtraMetrics, options.EnableMetadataStorage, opts.target, options.PassMetadataInContext, metrics, options.skipOffsetting, ) } sp.metrics.targetScrapePoolTargetLimit.WithLabelValues(sp.config.JobName).Set(float64(sp.config.TargetLimit)) return sp, nil } func (sp *scrapePool) ActiveTargets() []*Target { sp.targetMtx.Lock() defer sp.targetMtx.Unlock() var tActive []*Target for _, t := range sp.activeTargets { tActive = append(tActive, t) } return tActive } // Return dropped targets, subject to KeepDroppedTargets limit. func (sp *scrapePool) DroppedTargets() []*Target { sp.targetMtx.Lock() defer sp.targetMtx.Unlock() return sp.droppedTargets } func (sp *scrapePool) DroppedTargetsCount() int { sp.targetMtx.Lock() defer sp.targetMtx.Unlock() return sp.droppedTargetsCount } // stop terminates all scrape loops and returns after they all terminated. func (sp *scrapePool) stop() { sp.mtx.Lock() defer sp.mtx.Unlock() sp.cancel() var wg sync.WaitGroup sp.targetMtx.Lock() for fp, l := range sp.loops { wg.Add(1) go func(l loop) { l.stop() wg.Done() }(l) delete(sp.loops, fp) delete(sp.activeTargets, fp) } sp.targetMtx.Unlock() wg.Wait() sp.client.CloseIdleConnections() if sp.config != nil { sp.metrics.targetScrapePoolSyncsCounter.DeleteLabelValues(sp.config.JobName) sp.metrics.targetScrapePoolTargetLimit.DeleteLabelValues(sp.config.JobName) sp.metrics.targetScrapePoolTargetsAdded.DeleteLabelValues(sp.config.JobName) sp.metrics.targetSyncIntervalLength.DeleteLabelValues(sp.config.JobName) sp.metrics.targetSyncFailed.DeleteLabelValues(sp.config.JobName) } } // reload the scrape pool with the given scrape configuration. The target state is preserved // but all scrape loops are restarted with the new scrape configuration. // This method returns after all scrape loops that were stopped have stopped scraping. func (sp *scrapePool) reload(cfg *config.ScrapeConfig) error { sp.mtx.Lock() defer sp.mtx.Unlock() sp.metrics.targetScrapePoolReloads.Inc() start := time.Now() client, err := config_util.NewClientFromConfig(cfg.HTTPClientConfig, cfg.JobName, sp.httpOpts...) if err != nil { sp.metrics.targetScrapePoolReloadsFailed.Inc() return fmt.Errorf("error creating HTTP client: %w", err) } reuseCache := reusableCache(sp.config, cfg) sp.config = cfg oldClient := sp.client sp.client = client sp.metrics.targetScrapePoolTargetLimit.WithLabelValues(sp.config.JobName).Set(float64(sp.config.TargetLimit)) var ( wg sync.WaitGroup interval = time.Duration(sp.config.ScrapeInterval) timeout = time.Duration(sp.config.ScrapeTimeout) bodySizeLimit = int64(sp.config.BodySizeLimit) sampleLimit = int(sp.config.SampleLimit) bucketLimit = int(sp.config.NativeHistogramBucketLimit) maxSchema = pickSchema(sp.config.NativeHistogramMinBucketFactor) labelLimits = &labelLimits{ labelLimit: int(sp.config.LabelLimit), labelNameLengthLimit: int(sp.config.LabelNameLengthLimit), labelValueLengthLimit: int(sp.config.LabelValueLengthLimit), } honorLabels = sp.config.HonorLabels honorTimestamps = sp.config.HonorTimestamps enableCompression = sp.config.EnableCompression trackTimestampsStaleness = sp.config.TrackTimestampsStaleness mrc = sp.config.MetricRelabelConfigs ) sp.targetMtx.Lock() forcedErr := sp.refreshTargetLimitErr() for fp, oldLoop := range sp.loops { var cache *scrapeCache if oc := oldLoop.getCache(); reuseCache && oc != nil { oldLoop.disableEndOfRunStalenessMarkers() cache = oc } else { cache = newScrapeCache(sp.metrics) } t := sp.activeTargets[fp] interval, timeout, err := t.intervalAndTimeout(interval, timeout) var ( s = &targetScraper{ Target: t, client: sp.client, timeout: timeout, bodySizeLimit: bodySizeLimit, acceptHeader: acceptHeader(cfg.ScrapeProtocols), acceptEncodingHeader: acceptEncodingHeader(enableCompression), } newLoop = sp.newLoop(scrapeLoopOptions{ target: t, scraper: s, sampleLimit: sampleLimit, bucketLimit: bucketLimit, maxSchema: maxSchema, labelLimits: labelLimits, honorLabels: honorLabels, honorTimestamps: honorTimestamps, enableCompression: enableCompression, trackTimestampsStaleness: trackTimestampsStaleness, mrc: mrc, cache: cache, interval: interval, timeout: timeout, }) ) if err != nil { newLoop.setForcedError(err) } wg.Add(1) go func(oldLoop, newLoop loop) { oldLoop.stop() wg.Done() newLoop.setForcedError(forcedErr) newLoop.run(nil) }(oldLoop, newLoop) sp.loops[fp] = newLoop } sp.targetMtx.Unlock() wg.Wait() oldClient.CloseIdleConnections() sp.metrics.targetReloadIntervalLength.WithLabelValues(interval.String()).Observe( time.Since(start).Seconds(), ) // Here we take steps to clear out the symbol table if it has grown a lot. // After waiting some time for things to settle, we take the size of the symbol-table. // If, after some more time, the table has grown to twice that size, we start a new one. const minTimeToCleanSymbolTable = 5 * time.Minute if time.Since(sp.lastSymbolTableCheck) > minTimeToCleanSymbolTable { if sp.initialSymbolTableLen == 0 { sp.initialSymbolTableLen = sp.symbolTable.Len() } else if sp.symbolTable.Len() > 2*sp.initialSymbolTableLen { sp.symbolTable = labels.NewSymbolTable() sp.initialSymbolTableLen = 0 } sp.lastSymbolTableCheck = time.Now() } return nil } // Sync converts target groups into actual scrape targets and synchronizes // the currently running scraper with the resulting set and returns all scraped and dropped targets. func (sp *scrapePool) Sync(tgs []*targetgroup.Group) { sp.mtx.Lock() defer sp.mtx.Unlock() start := time.Now() sp.targetMtx.Lock() var all []*Target var targets []*Target lb := labels.NewBuilderWithSymbolTable(sp.symbolTable) sp.droppedTargets = []*Target{} sp.droppedTargetsCount = 0 for _, tg := range tgs { targets, failures := TargetsFromGroup(tg, sp.config, sp.noDefaultPort, targets, lb) for _, err := range failures { level.Error(sp.logger).Log("msg", "Creating target failed", "err", err) } sp.metrics.targetSyncFailed.WithLabelValues(sp.config.JobName).Add(float64(len(failures))) for _, t := range targets { // Replicate .Labels().IsEmpty() with a loop here to avoid generating garbage. nonEmpty := false t.LabelsRange(func(l labels.Label) { nonEmpty = true }) switch { case nonEmpty: all = append(all, t) case !t.discoveredLabels.IsEmpty(): if sp.config.KeepDroppedTargets == 0 || uint(len(sp.droppedTargets)) < sp.config.KeepDroppedTargets { sp.droppedTargets = append(sp.droppedTargets, t) } sp.droppedTargetsCount++ } } } sp.targetMtx.Unlock() sp.sync(all) sp.metrics.targetSyncIntervalLength.WithLabelValues(sp.config.JobName).Observe( time.Since(start).Seconds(), ) sp.metrics.targetScrapePoolSyncsCounter.WithLabelValues(sp.config.JobName).Inc() } // sync takes a list of potentially duplicated targets, deduplicates them, starts // scrape loops for new targets, and stops scrape loops for disappeared targets. // It returns after all stopped scrape loops terminated. func (sp *scrapePool) sync(targets []*Target) { var ( uniqueLoops = make(map[uint64]loop) interval = time.Duration(sp.config.ScrapeInterval) timeout = time.Duration(sp.config.ScrapeTimeout) bodySizeLimit = int64(sp.config.BodySizeLimit) sampleLimit = int(sp.config.SampleLimit) bucketLimit = int(sp.config.NativeHistogramBucketLimit) maxSchema = pickSchema(sp.config.NativeHistogramMinBucketFactor) labelLimits = &labelLimits{ labelLimit: int(sp.config.LabelLimit), labelNameLengthLimit: int(sp.config.LabelNameLengthLimit), labelValueLengthLimit: int(sp.config.LabelValueLengthLimit), } honorLabels = sp.config.HonorLabels honorTimestamps = sp.config.HonorTimestamps enableCompression = sp.config.EnableCompression trackTimestampsStaleness = sp.config.TrackTimestampsStaleness mrc = sp.config.MetricRelabelConfigs scrapeClassicHistograms = sp.config.ScrapeClassicHistograms ) sp.targetMtx.Lock() for _, t := range targets { hash := t.hash() if _, ok := sp.activeTargets[hash]; !ok { // The scrape interval and timeout labels are set to the config's values initially, // so whether changed via relabeling or not, they'll exist and hold the correct values // for every target. var err error interval, timeout, err = t.intervalAndTimeout(interval, timeout) s := &targetScraper{ Target: t, client: sp.client, timeout: timeout, bodySizeLimit: bodySizeLimit, acceptHeader: acceptHeader(sp.config.ScrapeProtocols), acceptEncodingHeader: acceptEncodingHeader(enableCompression), metrics: sp.metrics, } l := sp.newLoop(scrapeLoopOptions{ target: t, scraper: s, sampleLimit: sampleLimit, bucketLimit: bucketLimit, maxSchema: maxSchema, labelLimits: labelLimits, honorLabels: honorLabels, honorTimestamps: honorTimestamps, enableCompression: enableCompression, trackTimestampsStaleness: trackTimestampsStaleness, mrc: mrc, interval: interval, timeout: timeout, scrapeClassicHistograms: scrapeClassicHistograms, }) if err != nil { l.setForcedError(err) } sp.activeTargets[hash] = t sp.loops[hash] = l uniqueLoops[hash] = l } else { // This might be a duplicated target. if _, ok := uniqueLoops[hash]; !ok { uniqueLoops[hash] = nil } // Need to keep the most updated labels information // for displaying it in the Service Discovery web page. sp.activeTargets[hash].SetDiscoveredLabels(t.DiscoveredLabels()) } } var wg sync.WaitGroup // Stop and remove old targets and scraper loops. for hash := range sp.activeTargets { if _, ok := uniqueLoops[hash]; !ok { wg.Add(1) go func(l loop) { l.stop() wg.Done() }(sp.loops[hash]) delete(sp.loops, hash) delete(sp.activeTargets, hash) } } sp.targetMtx.Unlock() sp.metrics.targetScrapePoolTargetsAdded.WithLabelValues(sp.config.JobName).Set(float64(len(uniqueLoops))) forcedErr := sp.refreshTargetLimitErr() for _, l := range sp.loops { l.setForcedError(forcedErr) } for _, l := range uniqueLoops { if l != nil { go l.run(nil) } } // Wait for all potentially stopped scrapers to terminate. // This covers the case of flapping targets. If the server is under high load, a new scraper // may be active and tries to insert. The old scraper that didn't terminate yet could still // be inserting a previous sample set. wg.Wait() } // refreshTargetLimitErr returns an error that can be passed to the scrape loops // if the number of targets exceeds the configured limit. func (sp *scrapePool) refreshTargetLimitErr() error { if sp.config == nil || sp.config.TargetLimit == 0 { return nil } if l := len(sp.activeTargets); l > int(sp.config.TargetLimit) { sp.metrics.targetScrapePoolExceededTargetLimit.Inc() return fmt.Errorf("target_limit exceeded (number of targets: %d, limit: %d)", l, sp.config.TargetLimit) } return nil } func verifyLabelLimits(lset labels.Labels, limits *labelLimits) error { if limits == nil { return nil } met := lset.Get(labels.MetricName) if limits.labelLimit > 0 { nbLabels := lset.Len() if nbLabels > limits.labelLimit { return fmt.Errorf("label_limit exceeded (metric: %.50s, number of labels: %d, limit: %d)", met, nbLabels, limits.labelLimit) } } if limits.labelNameLengthLimit == 0 && limits.labelValueLengthLimit == 0 { return nil } return lset.Validate(func(l labels.Label) error { if limits.labelNameLengthLimit > 0 { nameLength := len(l.Name) if nameLength > limits.labelNameLengthLimit { return fmt.Errorf("label_name_length_limit exceeded (metric: %.50s, label name: %.50s, length: %d, limit: %d)", met, l.Name, nameLength, limits.labelNameLengthLimit) } } if limits.labelValueLengthLimit > 0 { valueLength := len(l.Value) if valueLength > limits.labelValueLengthLimit { return fmt.Errorf("label_value_length_limit exceeded (metric: %.50s, label name: %.50s, value: %.50q, length: %d, limit: %d)", met, l.Name, l.Value, valueLength, limits.labelValueLengthLimit) } } return nil }) } func mutateSampleLabels(lset labels.Labels, target *Target, honor bool, rc []*relabel.Config) labels.Labels { lb := labels.NewBuilder(lset) if honor { target.LabelsRange(func(l labels.Label) { if !lset.Has(l.Name) { lb.Set(l.Name, l.Value) } }) } else { var conflictingExposedLabels []labels.Label target.LabelsRange(func(l labels.Label) { existingValue := lset.Get(l.Name) if existingValue != "" { conflictingExposedLabels = append(conflictingExposedLabels, labels.Label{Name: l.Name, Value: existingValue}) } // It is now safe to set the target label. lb.Set(l.Name, l.Value) }) if len(conflictingExposedLabels) > 0 { resolveConflictingExposedLabels(lb, conflictingExposedLabels) } } res := lb.Labels() if len(rc) > 0 { res, _ = relabel.Process(res, rc...) } return res } func resolveConflictingExposedLabels(lb *labels.Builder, conflictingExposedLabels []labels.Label) { slices.SortStableFunc(conflictingExposedLabels, func(a, b labels.Label) int { return len(a.Name) - len(b.Name) }) for _, l := range conflictingExposedLabels { newName := l.Name for { newName = model.ExportedLabelPrefix + newName if lb.Get(newName) == "" { lb.Set(newName, l.Value) break } } } } func mutateReportSampleLabels(lset labels.Labels, target *Target) labels.Labels { lb := labels.NewBuilder(lset) target.LabelsRange(func(l labels.Label) { lb.Set(model.ExportedLabelPrefix+l.Name, lset.Get(l.Name)) lb.Set(l.Name, l.Value) }) return lb.Labels() } // appender returns an appender for ingested samples from the target. func appender(app storage.Appender, sampleLimit, bucketLimit int, maxSchema int32) storage.Appender { app = &timeLimitAppender{ Appender: app, maxTime: timestamp.FromTime(time.Now().Add(maxAheadTime)), } // The sampleLimit is applied after metrics are potentially dropped via relabeling. if sampleLimit > 0 { app = &limitAppender{ Appender: app, limit: sampleLimit, } } if bucketLimit > 0 { app = &bucketLimitAppender{ Appender: app, limit: bucketLimit, } } if maxSchema < nativeHistogramMaxSchema { app = &maxSchemaAppender{ Appender: app, maxSchema: maxSchema, } } return app } // A scraper retrieves samples and accepts a status report at the end. type scraper interface { scrape(ctx context.Context) (*http.Response, error) readResponse(ctx context.Context, resp *http.Response, w io.Writer) (string, error) Report(start time.Time, dur time.Duration, err error) offset(interval time.Duration, offsetSeed uint64) time.Duration } // targetScraper implements the scraper interface for a target. type targetScraper struct { *Target client *http.Client req *http.Request timeout time.Duration gzipr *gzip.Reader buf *bufio.Reader bodySizeLimit int64 acceptHeader string acceptEncodingHeader string metrics *scrapeMetrics } var errBodySizeLimit = errors.New("body size limit exceeded") // acceptHeader transforms preference from the options into specific header values as // https://www.rfc-editor.org/rfc/rfc9110.html#name-accept defines. // No validation is here, we expect scrape protocols to be validated already. func acceptHeader(sps []config.ScrapeProtocol) string { var vals []string weight := len(config.ScrapeProtocolsHeaders) + 1 for _, sp := range sps { vals = append(vals, fmt.Sprintf("%s;q=0.%d", config.ScrapeProtocolsHeaders[sp], weight)) weight-- } // Default match anything. vals = append(vals, fmt.Sprintf("*/*;q=0.%d", weight)) return strings.Join(vals, ",") } func acceptEncodingHeader(enableCompression bool) string { if enableCompression { return "gzip" } return "identity" } var UserAgent = fmt.Sprintf("Prometheus/%s", version.Version) func (s *targetScraper) scrape(ctx context.Context) (*http.Response, error) { if s.req == nil { req, err := http.NewRequest(http.MethodGet, s.URL().String(), nil) if err != nil { return nil, err } req.Header.Add("Accept", s.acceptHeader) req.Header.Add("Accept-Encoding", s.acceptEncodingHeader) req.Header.Set("User-Agent", UserAgent) req.Header.Set("X-Prometheus-Scrape-Timeout-Seconds", strconv.FormatFloat(s.timeout.Seconds(), 'f', -1, 64)) s.req = req } return s.client.Do(s.req.WithContext(ctx)) } func (s *targetScraper) readResponse(ctx context.Context, resp *http.Response, w io.Writer) (string, error) { defer func() { io.Copy(io.Discard, resp.Body) resp.Body.Close() }() if resp.StatusCode != http.StatusOK { return "", fmt.Errorf("server returned HTTP status %s", resp.Status) } if s.bodySizeLimit <= 0 { s.bodySizeLimit = math.MaxInt64 } if resp.Header.Get("Content-Encoding") != "gzip" { n, err := io.Copy(w, io.LimitReader(resp.Body, s.bodySizeLimit)) if err != nil { return "", err } if n >= s.bodySizeLimit { s.metrics.targetScrapeExceededBodySizeLimit.Inc() return "", errBodySizeLimit } return resp.Header.Get("Content-Type"), nil } if s.gzipr == nil { s.buf = bufio.NewReader(resp.Body) var err error s.gzipr, err = gzip.NewReader(s.buf) if err != nil { return "", err } } else { s.buf.Reset(resp.Body) if err := s.gzipr.Reset(s.buf); err != nil { return "", err } } n, err := io.Copy(w, io.LimitReader(s.gzipr, s.bodySizeLimit)) s.gzipr.Close() if err != nil { return "", err } if n >= s.bodySizeLimit { s.metrics.targetScrapeExceededBodySizeLimit.Inc() return "", errBodySizeLimit } return resp.Header.Get("Content-Type"), nil } // A loop can run and be stopped again. It must not be reused after it was stopped. type loop interface { run(errc chan<- error) setForcedError(err error) stop() getCache() *scrapeCache disableEndOfRunStalenessMarkers() } type cacheEntry struct { ref storage.SeriesRef lastIter uint64 hash uint64 lset labels.Labels } type scrapeLoop struct { scraper scraper l log.Logger cache *scrapeCache lastScrapeSize int buffers *pool.Pool offsetSeed uint64 honorTimestamps bool trackTimestampsStaleness bool enableCompression bool forcedErr error forcedErrMtx sync.Mutex sampleLimit int bucketLimit int maxSchema int32 labelLimits *labelLimits interval time.Duration timeout time.Duration scrapeClassicHistograms bool // Feature flagged options. enableNativeHistogramIngestion bool enableCTZeroIngestion bool appender func(ctx context.Context) storage.Appender symbolTable *labels.SymbolTable sampleMutator labelsMutator reportSampleMutator labelsMutator parentCtx context.Context appenderCtx context.Context ctx context.Context cancel func() stopped chan struct{} disabledEndOfRunStalenessMarkers bool reportExtraMetrics bool appendMetadataToWAL bool metrics *scrapeMetrics skipOffsetting bool // For testability. } // scrapeCache tracks mappings of exposed metric strings to label sets and // storage references. Additionally, it tracks staleness of series between // scrapes. type scrapeCache struct { iter uint64 // Current scrape iteration. // How many series and metadata entries there were at the last success. successfulCount int // Parsed string to an entry with information about the actual label set // and its storage reference. series map[string]*cacheEntry // Cache of dropped metric strings and their iteration. The iteration must // be a pointer so we can update it. droppedSeries map[string]*uint64 // seriesCur and seriesPrev store the labels of series that were seen // in the current and previous scrape. // We hold two maps and swap them out to save allocations. seriesCur map[uint64]labels.Labels seriesPrev map[uint64]labels.Labels metaMtx sync.Mutex metadata map[string]*metaEntry metrics *scrapeMetrics } // metaEntry holds meta information about a metric. type metaEntry struct { metadata.Metadata lastIter uint64 // Last scrape iteration the entry was observed at. lastIterChange uint64 // Last scrape iteration the entry was changed at. } func (m *metaEntry) size() int { // The attribute lastIter although part of the struct it is not metadata. return len(m.Help) + len(m.Unit) + len(m.Type) } func newScrapeCache(metrics *scrapeMetrics) *scrapeCache { return &scrapeCache{ series: map[string]*cacheEntry{}, droppedSeries: map[string]*uint64{}, seriesCur: map[uint64]labels.Labels{}, seriesPrev: map[uint64]labels.Labels{}, metadata: map[string]*metaEntry{}, metrics: metrics, } } func (c *scrapeCache) iterDone(flushCache bool) { c.metaMtx.Lock() count := len(c.series) + len(c.droppedSeries) + len(c.metadata) c.metaMtx.Unlock() switch { case flushCache: c.successfulCount = count case count > c.successfulCount*2+1000: // If a target had varying labels in scrapes that ultimately failed, // the caches would grow indefinitely. Force a flush when this happens. // We use the heuristic that this is a doubling of the cache size // since the last scrape, and allow an additional 1000 in case // initial scrapes all fail. flushCache = true c.metrics.targetScrapeCacheFlushForced.Inc() } if flushCache { // All caches may grow over time through series churn // or multiple string representations of the same metric. Clean up entries // that haven't appeared in the last scrape. for s, e := range c.series { if c.iter != e.lastIter { delete(c.series, s) } } for s, iter := range c.droppedSeries { if c.iter != *iter { delete(c.droppedSeries, s) } } c.metaMtx.Lock() for m, e := range c.metadata { // Keep metadata around for 10 scrapes after its metric disappeared. if c.iter-e.lastIter > 10 { delete(c.metadata, m) } } c.metaMtx.Unlock() c.iter++ } // Swap current and previous series. c.seriesPrev, c.seriesCur = c.seriesCur, c.seriesPrev // We have to delete every single key in the map. for k := range c.seriesCur { delete(c.seriesCur, k) } } func (c *scrapeCache) get(met []byte) (*cacheEntry, bool, bool) { e, ok := c.series[string(met)] if !ok { return nil, false, false } alreadyScraped := e.lastIter == c.iter e.lastIter = c.iter return e, true, alreadyScraped } func (c *scrapeCache) addRef(met []byte, ref storage.SeriesRef, lset labels.Labels, hash uint64) { if ref == 0 { return } c.series[string(met)] = &cacheEntry{ref: ref, lastIter: c.iter, lset: lset, hash: hash} } func (c *scrapeCache) addDropped(met []byte) { iter := c.iter c.droppedSeries[string(met)] = &iter } func (c *scrapeCache) getDropped(met []byte) bool { iterp, ok := c.droppedSeries[string(met)] if ok { *iterp = c.iter } return ok } func (c *scrapeCache) trackStaleness(hash uint64, lset labels.Labels) { c.seriesCur[hash] = lset } func (c *scrapeCache) forEachStale(f func(labels.Labels) bool) { for h, lset := range c.seriesPrev { if _, ok := c.seriesCur[h]; !ok { if !f(lset) { break } } } } func (c *scrapeCache) setType(metric []byte, t model.MetricType) { c.metaMtx.Lock() e, ok := c.metadata[string(metric)] if !ok { e = &metaEntry{Metadata: metadata.Metadata{Type: model.MetricTypeUnknown}} c.metadata[string(metric)] = e } if e.Type != t { e.Type = t e.lastIterChange = c.iter } e.lastIter = c.iter c.metaMtx.Unlock() } func (c *scrapeCache) setHelp(metric, help []byte) { c.metaMtx.Lock() e, ok := c.metadata[string(metric)] if !ok { e = &metaEntry{Metadata: metadata.Metadata{Type: model.MetricTypeUnknown}} c.metadata[string(metric)] = e } if e.Help != string(help) { e.Help = string(help) e.lastIterChange = c.iter } e.lastIter = c.iter c.metaMtx.Unlock() } func (c *scrapeCache) setUnit(metric, unit []byte) { c.metaMtx.Lock() e, ok := c.metadata[string(metric)] if !ok { e = &metaEntry{Metadata: metadata.Metadata{Type: model.MetricTypeUnknown}} c.metadata[string(metric)] = e } if e.Unit != string(unit) { e.Unit = string(unit) e.lastIterChange = c.iter } e.lastIter = c.iter c.metaMtx.Unlock() } func (c *scrapeCache) GetMetadata(metric string) (MetricMetadata, bool) { c.metaMtx.Lock() defer c.metaMtx.Unlock() m, ok := c.metadata[metric] if !ok { return MetricMetadata{}, false } return MetricMetadata{ Metric: metric, Type: m.Type, Help: m.Help, Unit: m.Unit, }, true } func (c *scrapeCache) ListMetadata() []MetricMetadata { c.metaMtx.Lock() defer c.metaMtx.Unlock() res := make([]MetricMetadata, 0, len(c.metadata)) for m, e := range c.metadata { res = append(res, MetricMetadata{ Metric: m, Type: e.Type, Help: e.Help, Unit: e.Unit, }) } return res } // MetadataSize returns the size of the metadata cache. func (c *scrapeCache) SizeMetadata() (s int) { c.metaMtx.Lock() defer c.metaMtx.Unlock() for _, e := range c.metadata { s += e.size() } return s } // MetadataLen returns the number of metadata entries in the cache. func (c *scrapeCache) LengthMetadata() int { c.metaMtx.Lock() defer c.metaMtx.Unlock() return len(c.metadata) } func newScrapeLoop(ctx context.Context, sc scraper, l log.Logger, buffers *pool.Pool, sampleMutator labelsMutator, reportSampleMutator labelsMutator, appender func(ctx context.Context) storage.Appender, cache *scrapeCache, symbolTable *labels.SymbolTable, offsetSeed uint64, honorTimestamps bool, trackTimestampsStaleness bool, enableCompression bool, sampleLimit int, bucketLimit int, maxSchema int32, labelLimits *labelLimits, interval time.Duration, timeout time.Duration, scrapeClassicHistograms bool, enableNativeHistogramIngestion bool, enableCTZeroIngestion bool, reportExtraMetrics bool, appendMetadataToWAL bool, target *Target, passMetadataInContext bool, metrics *scrapeMetrics, skipOffsetting bool, ) *scrapeLoop { if l == nil { l = log.NewNopLogger() } if buffers == nil { buffers = pool.New(1e3, 1e6, 3, func(sz int) interface{} { return make([]byte, 0, sz) }) } if cache == nil { cache = newScrapeCache(metrics) } appenderCtx := ctx if passMetadataInContext { // Store the cache and target in the context. This is then used by downstream OTel Collector // to lookup the metadata required to process the samples. Not used by Prometheus itself. // TODO(gouthamve) We're using a dedicated context because using the parentCtx caused a memory // leak. We should ideally fix the main leak. See: https://github.com/prometheus/prometheus/pull/10590 appenderCtx = ContextWithMetricMetadataStore(appenderCtx, cache) appenderCtx = ContextWithTarget(appenderCtx, target) } sl := &scrapeLoop{ scraper: sc, buffers: buffers, cache: cache, appender: appender, symbolTable: symbolTable, sampleMutator: sampleMutator, reportSampleMutator: reportSampleMutator, stopped: make(chan struct{}), offsetSeed: offsetSeed, l: l, parentCtx: ctx, appenderCtx: appenderCtx, honorTimestamps: honorTimestamps, trackTimestampsStaleness: trackTimestampsStaleness, enableCompression: enableCompression, sampleLimit: sampleLimit, bucketLimit: bucketLimit, maxSchema: maxSchema, labelLimits: labelLimits, interval: interval, timeout: timeout, scrapeClassicHistograms: scrapeClassicHistograms, enableNativeHistogramIngestion: enableNativeHistogramIngestion, enableCTZeroIngestion: enableCTZeroIngestion, reportExtraMetrics: reportExtraMetrics, appendMetadataToWAL: appendMetadataToWAL, metrics: metrics, skipOffsetting: skipOffsetting, } sl.ctx, sl.cancel = context.WithCancel(ctx) return sl } func (sl *scrapeLoop) run(errc chan<- error) { if !sl.skipOffsetting { select { case <-time.After(sl.scraper.offset(sl.interval, sl.offsetSeed)): // Continue after a scraping offset. case <-sl.ctx.Done(): close(sl.stopped) return } } var last time.Time alignedScrapeTime := time.Now().Round(0) ticker := time.NewTicker(sl.interval) defer ticker.Stop() mainLoop: for { select { case <-sl.parentCtx.Done(): close(sl.stopped) return case <-sl.ctx.Done(): break mainLoop default: } // Temporary workaround for a jitter in go timers that causes disk space // increase in TSDB. // See https://github.com/prometheus/prometheus/issues/7846 // Calling Round ensures the time used is the wall clock, as otherwise .Sub // and .Add on time.Time behave differently (see time package docs). scrapeTime := time.Now().Round(0) if AlignScrapeTimestamps { // Tolerance is clamped to maximum 1% of the scrape interval. tolerance := min(sl.interval/100, ScrapeTimestampTolerance) // For some reason, a tick might have been skipped, in which case we // would call alignedScrapeTime.Add(interval) multiple times. for scrapeTime.Sub(alignedScrapeTime) >= sl.interval { alignedScrapeTime = alignedScrapeTime.Add(sl.interval) } // Align the scrape time if we are in the tolerance boundaries. if scrapeTime.Sub(alignedScrapeTime) <= tolerance { scrapeTime = alignedScrapeTime } } last = sl.scrapeAndReport(last, scrapeTime, errc) select { case <-sl.parentCtx.Done(): close(sl.stopped) return case <-sl.ctx.Done(): break mainLoop case <-ticker.C: } } close(sl.stopped) if !sl.disabledEndOfRunStalenessMarkers { sl.endOfRunStaleness(last, ticker, sl.interval) } } // scrapeAndReport performs a scrape and then appends the result to the storage // together with reporting metrics, by using as few appenders as possible. // In the happy scenario, a single appender is used. // This function uses sl.appenderCtx instead of sl.ctx on purpose. A scrape should // only be cancelled on shutdown, not on reloads. func (sl *scrapeLoop) scrapeAndReport(last, appendTime time.Time, errc chan<- error) time.Time { start := time.Now() // Only record after the first scrape. if !last.IsZero() { sl.metrics.targetIntervalLength.WithLabelValues(sl.interval.String()).Observe( time.Since(last).Seconds(), ) } var total, added, seriesAdded, bytesRead int var err, appErr, scrapeErr error app := sl.appender(sl.appenderCtx) defer func() { if err != nil { app.Rollback() return } err = app.Commit() if err != nil { level.Error(sl.l).Log("msg", "Scrape commit failed", "err", err) } }() defer func() { if err = sl.report(app, appendTime, time.Since(start), total, added, seriesAdded, bytesRead, scrapeErr); err != nil { level.Warn(sl.l).Log("msg", "Appending scrape report failed", "err", err) } }() if forcedErr := sl.getForcedError(); forcedErr != nil { scrapeErr = forcedErr // Add stale markers. if _, _, _, err := sl.append(app, []byte{}, "", appendTime); err != nil { app.Rollback() app = sl.appender(sl.appenderCtx) level.Warn(sl.l).Log("msg", "Append failed", "err", err) } if errc != nil { errc <- forcedErr } return start } var contentType string var resp *http.Response var b []byte var buf *bytes.Buffer scrapeCtx, cancel := context.WithTimeout(sl.parentCtx, sl.timeout) resp, scrapeErr = sl.scraper.scrape(scrapeCtx) if scrapeErr == nil { b = sl.buffers.Get(sl.lastScrapeSize).([]byte) defer sl.buffers.Put(b) buf = bytes.NewBuffer(b) contentType, scrapeErr = sl.scraper.readResponse(scrapeCtx, resp, buf) } cancel() if scrapeErr == nil { b = buf.Bytes() // NOTE: There were issues with misbehaving clients in the past // that occasionally returned empty results. We don't want those // to falsely reset our buffer size. if len(b) > 0 { sl.lastScrapeSize = len(b) } bytesRead = len(b) } else { level.Debug(sl.l).Log("msg", "Scrape failed", "err", scrapeErr) if errc != nil { errc <- scrapeErr } if errors.Is(scrapeErr, errBodySizeLimit) { bytesRead = -1 } } // A failed scrape is the same as an empty scrape, // we still call sl.append to trigger stale markers. total, added, seriesAdded, appErr = sl.append(app, b, contentType, appendTime) if appErr != nil { app.Rollback() app = sl.appender(sl.appenderCtx) level.Debug(sl.l).Log("msg", "Append failed", "err", appErr) // The append failed, probably due to a parse error or sample limit. // Call sl.append again with an empty scrape to trigger stale markers. if _, _, _, err := sl.append(app, []byte{}, "", appendTime); err != nil { app.Rollback() app = sl.appender(sl.appenderCtx) level.Warn(sl.l).Log("msg", "Append failed", "err", err) } } if scrapeErr == nil { scrapeErr = appErr } return start } func (sl *scrapeLoop) setForcedError(err error) { sl.forcedErrMtx.Lock() defer sl.forcedErrMtx.Unlock() sl.forcedErr = err } func (sl *scrapeLoop) getForcedError() error { sl.forcedErrMtx.Lock() defer sl.forcedErrMtx.Unlock() return sl.forcedErr } func (sl *scrapeLoop) endOfRunStaleness(last time.Time, ticker *time.Ticker, interval time.Duration) { // Scraping has stopped. We want to write stale markers but // the target may be recreated, so we wait just over 2 scrape intervals // before creating them. // If the context is canceled, we presume the server is shutting down // and will restart where is was. We do not attempt to write stale markers // in this case. if last.IsZero() { // There never was a scrape, so there will be no stale markers. return } // Wait for when the next scrape would have been, record its timestamp. var staleTime time.Time select { case <-sl.parentCtx.Done(): return case <-ticker.C: staleTime = time.Now() } // Wait for when the next scrape would have been, if the target was recreated // samples should have been ingested by now. select { case <-sl.parentCtx.Done(): return case <-ticker.C: } // Wait for an extra 10% of the interval, just to be safe. select { case <-sl.parentCtx.Done(): return case <-time.After(interval / 10): } // Call sl.append again with an empty scrape to trigger stale markers. // If the target has since been recreated and scraped, the // stale markers will be out of order and ignored. // sl.context would have been cancelled, hence using sl.appenderCtx. app := sl.appender(sl.appenderCtx) var err error defer func() { if err != nil { app.Rollback() return } err = app.Commit() if err != nil { level.Warn(sl.l).Log("msg", "Stale commit failed", "err", err) } }() if _, _, _, err = sl.append(app, []byte{}, "", staleTime); err != nil { app.Rollback() app = sl.appender(sl.appenderCtx) level.Warn(sl.l).Log("msg", "Stale append failed", "err", err) } if err = sl.reportStale(app, staleTime); err != nil { level.Warn(sl.l).Log("msg", "Stale report failed", "err", err) } } // Stop the scraping. May still write data and stale markers after it has // returned. Cancel the context to stop all writes. func (sl *scrapeLoop) stop() { sl.cancel() <-sl.stopped } func (sl *scrapeLoop) disableEndOfRunStalenessMarkers() { sl.disabledEndOfRunStalenessMarkers = true } func (sl *scrapeLoop) getCache() *scrapeCache { return sl.cache } type appendErrors struct { numOutOfOrder int numDuplicates int numOutOfBounds int numExemplarOutOfOrder int } func (sl *scrapeLoop) append(app storage.Appender, b []byte, contentType string, ts time.Time) (total, added, seriesAdded int, err error) { p, err := textparse.New(b, contentType, sl.scrapeClassicHistograms, sl.symbolTable) if err != nil { level.Debug(sl.l).Log( "msg", "Invalid content type on scrape, using prometheus parser as fallback.", "content_type", contentType, "err", err, ) } var ( defTime = timestamp.FromTime(ts) appErrs = appendErrors{} sampleLimitErr error bucketLimitErr error lset labels.Labels // escapes to heap so hoisted out of loop e exemplar.Exemplar // escapes to heap so hoisted out of loop meta metadata.Metadata metadataChanged bool ) exemplars := make([]exemplar.Exemplar, 1) // updateMetadata updates the current iteration's metadata object and the // metadataChanged value if we have metadata in the scrape cache AND the // labelset is for a new series or the metadata for this series has just // changed. It returns a boolean based on whether the metadata was updated. updateMetadata := func(lset labels.Labels, isNewSeries bool) bool { if !sl.appendMetadataToWAL { return false } sl.cache.metaMtx.Lock() defer sl.cache.metaMtx.Unlock() metaEntry, metaOk := sl.cache.metadata[lset.Get(labels.MetricName)] if metaOk && (isNewSeries || metaEntry.lastIterChange == sl.cache.iter) { metadataChanged = true meta.Type = metaEntry.Type meta.Unit = metaEntry.Unit meta.Help = metaEntry.Help return true } return false } // Take an appender with limits. app = appender(app, sl.sampleLimit, sl.bucketLimit, sl.maxSchema) defer func() { if err != nil { return } // Only perform cache cleaning if the scrape was not empty. // An empty scrape (usually) is used to indicate a failed scrape. sl.cache.iterDone(len(b) > 0) }() loop: for { var ( et textparse.Entry sampleAdded, isHistogram bool met []byte parsedTimestamp *int64 val float64 h *histogram.Histogram fh *histogram.FloatHistogram ) if et, err = p.Next(); err != nil { if errors.Is(err, io.EOF) { err = nil } break } switch et { case textparse.EntryType: sl.cache.setType(p.Type()) continue case textparse.EntryHelp: sl.cache.setHelp(p.Help()) continue case textparse.EntryUnit: sl.cache.setUnit(p.Unit()) continue case textparse.EntryComment: continue case textparse.EntryHistogram: isHistogram = true default: } total++ t := defTime if isHistogram { met, parsedTimestamp, h, fh = p.Histogram() } else { met, parsedTimestamp, val = p.Series() } if !sl.honorTimestamps { parsedTimestamp = nil } if parsedTimestamp != nil { t = *parsedTimestamp } // Zero metadata out for current iteration until it's resolved. meta = metadata.Metadata{} metadataChanged = false if sl.cache.getDropped(met) { continue } ce, ok, seriesAlreadyScraped := sl.cache.get(met) var ( ref storage.SeriesRef hash uint64 ) if ok { ref = ce.ref lset = ce.lset hash = ce.hash // Update metadata only if it changed in the current iteration. updateMetadata(lset, false) } else { p.Metric(&lset) hash = lset.Hash() // Hash label set as it is seen local to the target. Then add target labels // and relabeling and store the final label set. lset = sl.sampleMutator(lset) // The label set may be set to empty to indicate dropping. if lset.IsEmpty() { sl.cache.addDropped(met) continue } if !lset.Has(labels.MetricName) { err = errNameLabelMandatory break loop } if !lset.IsValid() { err = fmt.Errorf("invalid metric name or label names: %s", lset.String()) break loop } // If any label limits is exceeded the scrape should fail. if err = verifyLabelLimits(lset, sl.labelLimits); err != nil { sl.metrics.targetScrapePoolExceededLabelLimits.Inc() break loop } // Append metadata for new series if they were present. updateMetadata(lset, true) } if seriesAlreadyScraped && parsedTimestamp == nil { err = storage.ErrDuplicateSampleForTimestamp } else { if ctMs := p.CreatedTimestamp(); sl.enableCTZeroIngestion && ctMs != nil { ref, err = app.AppendCTZeroSample(ref, lset, t, *ctMs) if err != nil && !errors.Is(err, storage.ErrOutOfOrderCT) { // OOO is a common case, ignoring completely for now. // CT is an experimental feature. For now, we don't need to fail the // scrape on errors updating the created timestamp, log debug. level.Debug(sl.l).Log("msg", "Error when appending CT in scrape loop", "series", string(met), "ct", *ctMs, "t", t, "err", err) } } if isHistogram && sl.enableNativeHistogramIngestion { if h != nil { ref, err = app.AppendHistogram(ref, lset, t, h, nil) } else { ref, err = app.AppendHistogram(ref, lset, t, nil, fh) } } else { ref, err = app.Append(ref, lset, t, val) } } if err == nil { if (parsedTimestamp == nil || sl.trackTimestampsStaleness) && ce != nil { sl.cache.trackStaleness(ce.hash, ce.lset) } } sampleAdded, err = sl.checkAddError(met, err, &sampleLimitErr, &bucketLimitErr, &appErrs) if err != nil { if !errors.Is(err, storage.ErrNotFound) { level.Debug(sl.l).Log("msg", "Unexpected error", "series", string(met), "err", err) } break loop } if !ok { if parsedTimestamp == nil || sl.trackTimestampsStaleness { // Bypass staleness logic if there is an explicit timestamp. sl.cache.trackStaleness(hash, lset) } sl.cache.addRef(met, ref, lset, hash) if sampleAdded && sampleLimitErr == nil && bucketLimitErr == nil { seriesAdded++ } } // Increment added even if there's an error so we correctly report the // number of samples remaining after relabeling. // We still report duplicated samples here since this number should be the exact number // of time series exposed on a scrape after relabelling. added++ exemplars = exemplars[:0] // Reset and reuse the exemplar slice. for hasExemplar := p.Exemplar(&e); hasExemplar; hasExemplar = p.Exemplar(&e) { if !e.HasTs { if isHistogram { // We drop exemplars for native histograms if they don't have a timestamp. // Missing timestamps are deliberately not supported as we want to start // enforcing timestamps for exemplars as otherwise proper deduplication // is inefficient and purely based on heuristics: we cannot distinguish // between repeated exemplars and new instances with the same values. // This is done silently without logs as it is not an error but out of spec. // This does not affect classic histograms so that behaviour is unchanged. e = exemplar.Exemplar{} // Reset for next time round loop. continue } e.Ts = t } exemplars = append(exemplars, e) e = exemplar.Exemplar{} // Reset for next time round loop. } // Sort so that checking for duplicates / out of order is more efficient during validation. slices.SortFunc(exemplars, exemplar.Compare) outOfOrderExemplars := 0 for _, e := range exemplars { _, exemplarErr := app.AppendExemplar(ref, lset, e) switch { case exemplarErr == nil: // Do nothing. case errors.Is(exemplarErr, storage.ErrOutOfOrderExemplar): outOfOrderExemplars++ default: // Since exemplar storage is still experimental, we don't fail the scrape on ingestion errors. level.Debug(sl.l).Log("msg", "Error while adding exemplar in AddExemplar", "exemplar", fmt.Sprintf("%+v", e), "err", exemplarErr) } } if outOfOrderExemplars > 0 && outOfOrderExemplars == len(exemplars) { // Only report out of order exemplars if all are out of order, otherwise this was a partial update // to some existing set of exemplars. appErrs.numExemplarOutOfOrder += outOfOrderExemplars level.Debug(sl.l).Log("msg", "Out of order exemplars", "count", outOfOrderExemplars, "latest", fmt.Sprintf("%+v", exemplars[len(exemplars)-1])) sl.metrics.targetScrapeExemplarOutOfOrder.Add(float64(outOfOrderExemplars)) } if sl.appendMetadataToWAL && metadataChanged { if _, merr := app.UpdateMetadata(ref, lset, meta); merr != nil { // No need to fail the scrape on errors appending metadata. level.Debug(sl.l).Log("msg", "Error when appending metadata in scrape loop", "ref", fmt.Sprintf("%d", ref), "metadata", fmt.Sprintf("%+v", meta), "err", merr) } } } if sampleLimitErr != nil { if err == nil { err = sampleLimitErr } // We only want to increment this once per scrape, so this is Inc'd outside the loop. sl.metrics.targetScrapeSampleLimit.Inc() } if bucketLimitErr != nil { if err == nil { err = bucketLimitErr // If sample limit is hit, that error takes precedence. } // We only want to increment this once per scrape, so this is Inc'd outside the loop. sl.metrics.targetScrapeNativeHistogramBucketLimit.Inc() } if appErrs.numOutOfOrder > 0 { level.Warn(sl.l).Log("msg", "Error on ingesting out-of-order samples", "num_dropped", appErrs.numOutOfOrder) } if appErrs.numDuplicates > 0 { level.Warn(sl.l).Log("msg", "Error on ingesting samples with different value but same timestamp", "num_dropped", appErrs.numDuplicates) } if appErrs.numOutOfBounds > 0 { level.Warn(sl.l).Log("msg", "Error on ingesting samples that are too old or are too far into the future", "num_dropped", appErrs.numOutOfBounds) } if appErrs.numExemplarOutOfOrder > 0 { level.Warn(sl.l).Log("msg", "Error on ingesting out-of-order exemplars", "num_dropped", appErrs.numExemplarOutOfOrder) } if err == nil { sl.cache.forEachStale(func(lset labels.Labels) bool { // Series no longer exposed, mark it stale. _, err = app.Append(0, lset, defTime, math.Float64frombits(value.StaleNaN)) switch { case errors.Is(err, storage.ErrOutOfOrderSample), errors.Is(err, storage.ErrDuplicateSampleForTimestamp): // Do not count these in logging, as this is expected if a target // goes away and comes back again with a new scrape loop. err = nil } return err == nil }) } return } // Adds samples to the appender, checking the error, and then returns the # of samples added, // whether the caller should continue to process more samples, and any sample or bucket limit errors. func (sl *scrapeLoop) checkAddError(met []byte, err error, sampleLimitErr, bucketLimitErr *error, appErrs *appendErrors) (bool, error) { switch { case err == nil: return true, nil case errors.Is(err, storage.ErrNotFound): return false, storage.ErrNotFound case errors.Is(err, storage.ErrOutOfOrderSample): appErrs.numOutOfOrder++ level.Debug(sl.l).Log("msg", "Out of order sample", "series", string(met)) sl.metrics.targetScrapeSampleOutOfOrder.Inc() return false, nil case errors.Is(err, storage.ErrDuplicateSampleForTimestamp): appErrs.numDuplicates++ level.Debug(sl.l).Log("msg", "Duplicate sample for timestamp", "series", string(met)) sl.metrics.targetScrapeSampleDuplicate.Inc() return false, nil case errors.Is(err, storage.ErrOutOfBounds): appErrs.numOutOfBounds++ level.Debug(sl.l).Log("msg", "Out of bounds metric", "series", string(met)) sl.metrics.targetScrapeSampleOutOfBounds.Inc() return false, nil case errors.Is(err, errSampleLimit): // Keep on parsing output if we hit the limit, so we report the correct // total number of samples scraped. *sampleLimitErr = err return false, nil case errors.Is(err, errBucketLimit): // Keep on parsing output if we hit the limit, so we report the correct // total number of samples scraped. *bucketLimitErr = err return false, nil default: return false, err } } // The constants are suffixed with the invalid \xff unicode rune to avoid collisions // with scraped metrics in the cache. var ( scrapeHealthMetricName = []byte("up" + "\xff") scrapeDurationMetricName = []byte("scrape_duration_seconds" + "\xff") scrapeSamplesMetricName = []byte("scrape_samples_scraped" + "\xff") samplesPostRelabelMetricName = []byte("scrape_samples_post_metric_relabeling" + "\xff") scrapeSeriesAddedMetricName = []byte("scrape_series_added" + "\xff") scrapeTimeoutMetricName = []byte("scrape_timeout_seconds" + "\xff") scrapeSampleLimitMetricName = []byte("scrape_sample_limit" + "\xff") scrapeBodySizeBytesMetricName = []byte("scrape_body_size_bytes" + "\xff") ) func (sl *scrapeLoop) report(app storage.Appender, start time.Time, duration time.Duration, scraped, added, seriesAdded, bytes int, scrapeErr error) (err error) { sl.scraper.Report(start, duration, scrapeErr) ts := timestamp.FromTime(start) var health float64 if scrapeErr == nil { health = 1 } b := labels.NewBuilderWithSymbolTable(sl.symbolTable) if err = sl.addReportSample(app, scrapeHealthMetricName, ts, health, b); err != nil { return } if err = sl.addReportSample(app, scrapeDurationMetricName, ts, duration.Seconds(), b); err != nil { return } if err = sl.addReportSample(app, scrapeSamplesMetricName, ts, float64(scraped), b); err != nil { return } if err = sl.addReportSample(app, samplesPostRelabelMetricName, ts, float64(added), b); err != nil { return } if err = sl.addReportSample(app, scrapeSeriesAddedMetricName, ts, float64(seriesAdded), b); err != nil { return } if sl.reportExtraMetrics { if err = sl.addReportSample(app, scrapeTimeoutMetricName, ts, sl.timeout.Seconds(), b); err != nil { return } if err = sl.addReportSample(app, scrapeSampleLimitMetricName, ts, float64(sl.sampleLimit), b); err != nil { return } if err = sl.addReportSample(app, scrapeBodySizeBytesMetricName, ts, float64(bytes), b); err != nil { return } } return } func (sl *scrapeLoop) reportStale(app storage.Appender, start time.Time) (err error) { ts := timestamp.FromTime(start) stale := math.Float64frombits(value.StaleNaN) b := labels.NewBuilder(labels.EmptyLabels()) if err = sl.addReportSample(app, scrapeHealthMetricName, ts, stale, b); err != nil { return } if err = sl.addReportSample(app, scrapeDurationMetricName, ts, stale, b); err != nil { return } if err = sl.addReportSample(app, scrapeSamplesMetricName, ts, stale, b); err != nil { return } if err = sl.addReportSample(app, samplesPostRelabelMetricName, ts, stale, b); err != nil { return } if err = sl.addReportSample(app, scrapeSeriesAddedMetricName, ts, stale, b); err != nil { return } if sl.reportExtraMetrics { if err = sl.addReportSample(app, scrapeTimeoutMetricName, ts, stale, b); err != nil { return } if err = sl.addReportSample(app, scrapeSampleLimitMetricName, ts, stale, b); err != nil { return } if err = sl.addReportSample(app, scrapeBodySizeBytesMetricName, ts, stale, b); err != nil { return } } return } func (sl *scrapeLoop) addReportSample(app storage.Appender, s []byte, t int64, v float64, b *labels.Builder) error { ce, ok, _ := sl.cache.get(s) var ref storage.SeriesRef var lset labels.Labels if ok { ref = ce.ref lset = ce.lset } else { // The constants are suffixed with the invalid \xff unicode rune to avoid collisions // with scraped metrics in the cache. // We have to drop it when building the actual metric. b.Reset(labels.EmptyLabels()) b.Set(labels.MetricName, string(s[:len(s)-1])) lset = sl.reportSampleMutator(b.Labels()) } ref, err := app.Append(ref, lset, t, v) switch { case err == nil: if !ok { sl.cache.addRef(s, ref, lset, lset.Hash()) } return nil case errors.Is(err, storage.ErrOutOfOrderSample), errors.Is(err, storage.ErrDuplicateSampleForTimestamp): // Do not log here, as this is expected if a target goes away and comes back // again with a new scrape loop. return nil default: return err } } // zeroConfig returns a new scrape config that only contains configuration items // that alter metrics. func zeroConfig(c *config.ScrapeConfig) *config.ScrapeConfig { z := *c // We zero out the fields that for sure don't affect scrape. z.ScrapeInterval = 0 z.ScrapeTimeout = 0 z.SampleLimit = 0 z.HTTPClientConfig = config_util.HTTPClientConfig{} return &z } // reusableCache compares two scrape config and tells whether the cache is still // valid. func reusableCache(r, l *config.ScrapeConfig) bool { if r == nil || l == nil { return false } return reflect.DeepEqual(zeroConfig(r), zeroConfig(l)) } // CtxKey is a dedicated type for keys of context-embedded values propagated // with the scrape context. type ctxKey int // Valid CtxKey values. const ( ctxKeyMetadata ctxKey = iota + 1 ctxKeyTarget ) func ContextWithMetricMetadataStore(ctx context.Context, s MetricMetadataStore) context.Context { return context.WithValue(ctx, ctxKeyMetadata, s) } func MetricMetadataStoreFromContext(ctx context.Context) (MetricMetadataStore, bool) { s, ok := ctx.Value(ctxKeyMetadata).(MetricMetadataStore) return s, ok } func ContextWithTarget(ctx context.Context, t *Target) context.Context { return context.WithValue(ctx, ctxKeyTarget, t) } func TargetFromContext(ctx context.Context) (*Target, bool) { t, ok := ctx.Value(ctxKeyTarget).(*Target) return t, ok } func pickSchema(bucketFactor float64) int32 { if bucketFactor <= 1 { bucketFactor = 1.00271 } floor := math.Floor(-math.Log2(math.Log2(bucketFactor))) switch { case floor >= float64(nativeHistogramMaxSchema): return nativeHistogramMaxSchema case floor <= float64(nativeHistogramMinSchema): return nativeHistogramMinSchema default: return int32(floor) } }