// Copyright The OpenTelemetry 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 metric // import "go.opentelemetry.io/otel/sdk/metric" import ( "container/list" "context" "errors" "fmt" "strings" "sync" "sync/atomic" "go.opentelemetry.io/otel/internal/global" "go.opentelemetry.io/otel/metric" "go.opentelemetry.io/otel/metric/embedded" "go.opentelemetry.io/otel/sdk/instrumentation" "go.opentelemetry.io/otel/sdk/metric/internal" "go.opentelemetry.io/otel/sdk/metric/internal/aggregate" "go.opentelemetry.io/otel/sdk/metric/metricdata" "go.opentelemetry.io/otel/sdk/resource" ) var ( errCreatingAggregators = errors.New("could not create all aggregators") errIncompatibleAggregation = errors.New("incompatible aggregation") errUnknownAggregation = errors.New("unrecognized aggregation") ) // instrumentSync is a synchronization point between a pipeline and an // instrument's aggregate function. type instrumentSync struct { name string description string unit string compAgg aggregate.ComputeAggregation } func newPipeline(res *resource.Resource, reader Reader, views []View) *pipeline { if res == nil { res = resource.Empty() } return &pipeline{ resource: res, reader: reader, views: views, // aggregations is lazy allocated when needed. } } // pipeline connects all of the instruments created by a meter provider to a Reader. // This is the object that will be `Reader.register()` when a meter provider is created. // // As instruments are created the instrument should be checked if it exists in // the views of a the Reader, and if so each aggregate function should be added // to the pipeline. type pipeline struct { resource *resource.Resource reader Reader views []View sync.Mutex aggregations map[instrumentation.Scope][]instrumentSync callbacks []func(context.Context) error multiCallbacks list.List } // addSync adds the instrumentSync to pipeline p with scope. This method is not // idempotent. Duplicate calls will result in duplicate additions, it is the // callers responsibility to ensure this is called with unique values. func (p *pipeline) addSync(scope instrumentation.Scope, iSync instrumentSync) { p.Lock() defer p.Unlock() if p.aggregations == nil { p.aggregations = map[instrumentation.Scope][]instrumentSync{ scope: {iSync}, } return } p.aggregations[scope] = append(p.aggregations[scope], iSync) } // addCallback registers a single instrument callback to be run when // `produce()` is called. func (p *pipeline) addCallback(cback func(context.Context) error) { p.Lock() defer p.Unlock() p.callbacks = append(p.callbacks, cback) } type multiCallback func(context.Context) error // addMultiCallback registers a multi-instrument callback to be run when // `produce()` is called. func (p *pipeline) addMultiCallback(c multiCallback) (unregister func()) { p.Lock() defer p.Unlock() e := p.multiCallbacks.PushBack(c) return func() { p.Lock() p.multiCallbacks.Remove(e) p.Unlock() } } // produce returns aggregated metrics from a single collection. // // This method is safe to call concurrently. func (p *pipeline) produce(ctx context.Context, rm *metricdata.ResourceMetrics) error { p.Lock() defer p.Unlock() var errs multierror for _, c := range p.callbacks { // TODO make the callbacks parallel. ( #3034 ) if err := c(ctx); err != nil { errs.append(err) } if err := ctx.Err(); err != nil { rm.Resource = nil rm.ScopeMetrics = rm.ScopeMetrics[:0] return err } } for e := p.multiCallbacks.Front(); e != nil; e = e.Next() { // TODO make the callbacks parallel. ( #3034 ) f := e.Value.(multiCallback) if err := f(ctx); err != nil { errs.append(err) } if err := ctx.Err(); err != nil { // This means the context expired before we finished running callbacks. rm.Resource = nil rm.ScopeMetrics = rm.ScopeMetrics[:0] return err } } rm.Resource = p.resource rm.ScopeMetrics = internal.ReuseSlice(rm.ScopeMetrics, len(p.aggregations)) i := 0 for scope, instruments := range p.aggregations { rm.ScopeMetrics[i].Metrics = internal.ReuseSlice(rm.ScopeMetrics[i].Metrics, len(instruments)) j := 0 for _, inst := range instruments { data := rm.ScopeMetrics[i].Metrics[j].Data if n := inst.compAgg(&data); n > 0 { rm.ScopeMetrics[i].Metrics[j].Name = inst.name rm.ScopeMetrics[i].Metrics[j].Description = inst.description rm.ScopeMetrics[i].Metrics[j].Unit = inst.unit rm.ScopeMetrics[i].Metrics[j].Data = data j++ } } rm.ScopeMetrics[i].Metrics = rm.ScopeMetrics[i].Metrics[:j] if len(rm.ScopeMetrics[i].Metrics) > 0 { rm.ScopeMetrics[i].Scope = scope i++ } } rm.ScopeMetrics = rm.ScopeMetrics[:i] return errs.errorOrNil() } // inserter facilitates inserting of new instruments from a single scope into a // pipeline. type inserter[N int64 | float64] struct { // aggregators is a cache that holds aggregate function inputs whose // outputs have been inserted into the underlying reader pipeline. This // cache ensures no duplicate aggregate functions are inserted into the // reader pipeline and if a new request during an instrument creation asks // for the same aggregate function input the same instance is returned. aggregators *cache[instID, aggVal[N]] // views is a cache that holds instrument identifiers for all the // instruments a Meter has created, it is provided from the Meter that owns // this inserter. This cache ensures during the creation of instruments // with the same name but different options (e.g. description, unit) a // warning message is logged. views *cache[string, instID] pipeline *pipeline } func newInserter[N int64 | float64](p *pipeline, vc *cache[string, instID]) *inserter[N] { if vc == nil { vc = &cache[string, instID]{} } return &inserter[N]{ aggregators: &cache[instID, aggVal[N]]{}, views: vc, pipeline: p, } } // Instrument inserts the instrument inst with instUnit into a pipeline. All // views the pipeline contains are matched against, and any matching view that // creates a unique aggregate function will have its output inserted into the // pipeline and its input included in the returned slice. // // The returned aggregate function inputs are ensured to be deduplicated and // unique. If another view in another pipeline that is cached by this // inserter's cache has already inserted the same aggregate function for the // same instrument, that functions input instance is returned. // // If another instrument has already been inserted by this inserter, or any // other using the same cache, and it conflicts with the instrument being // inserted in this call, an aggregate function input matching the arguments // will still be returned but an Info level log message will also be logged to // the OTel global logger. // // If the passed instrument would result in an incompatible aggregate function, // an error is returned and that aggregate function output is not inserted nor // is its input returned. // // If an instrument is determined to use a Drop aggregation, that instrument is // not inserted nor returned. func (i *inserter[N]) Instrument(inst Instrument, readerAggregation Aggregation) ([]aggregate.Measure[N], error) { var ( matched bool measures []aggregate.Measure[N] ) errs := &multierror{wrapped: errCreatingAggregators} seen := make(map[uint64]struct{}) for _, v := range i.pipeline.views { stream, match := v(inst) if !match { continue } matched = true in, id, err := i.cachedAggregator(inst.Scope, inst.Kind, stream, readerAggregation) if err != nil { errs.append(err) } if in == nil { // Drop aggregation. continue } if _, ok := seen[id]; ok { // This aggregate function has already been added. continue } seen[id] = struct{}{} measures = append(measures, in) } if matched { return measures, errs.errorOrNil() } // Apply implicit default view if no explicit matched. stream := Stream{ Name: inst.Name, Description: inst.Description, Unit: inst.Unit, } in, _, err := i.cachedAggregator(inst.Scope, inst.Kind, stream, readerAggregation) if err != nil { errs.append(err) } if in != nil { // Ensured to have not seen given matched was false. measures = append(measures, in) } return measures, errs.errorOrNil() } var aggIDCount uint64 // aggVal is the cached value in an aggregators cache. type aggVal[N int64 | float64] struct { ID uint64 Measure aggregate.Measure[N] Err error } // readerDefaultAggregation returns the default aggregation for the instrument // kind based on the reader's aggregation preferences. This is used unless the // aggregation is overridden with a view. func (i *inserter[N]) readerDefaultAggregation(kind InstrumentKind) Aggregation { aggregation := i.pipeline.reader.aggregation(kind) switch aggregation.(type) { case nil, AggregationDefault: // If the reader returns default or nil use the default selector. aggregation = DefaultAggregationSelector(kind) default: // Deep copy and validate before using. aggregation = aggregation.copy() if err := aggregation.err(); err != nil { orig := aggregation aggregation = DefaultAggregationSelector(kind) global.Error( err, "using default aggregation instead", "aggregation", orig, "replacement", aggregation, ) } } return aggregation } // cachedAggregator returns the appropriate aggregate input and output // functions for an instrument configuration. If the exact instrument has been // created within the inst.Scope, those aggregate function instances will be // returned. Otherwise, new computed aggregate functions will be cached and // returned. // // If the instrument configuration conflicts with an instrument that has // already been created (e.g. description, unit, data type) a warning will be // logged at the "Info" level with the global OTel logger. Valid new aggregate // functions for the instrument configuration will still be returned without an // error. // // If the instrument defines an unknown or incompatible aggregation, an error // is returned. func (i *inserter[N]) cachedAggregator(scope instrumentation.Scope, kind InstrumentKind, stream Stream, readerAggregation Aggregation) (meas aggregate.Measure[N], aggID uint64, err error) { switch stream.Aggregation.(type) { case nil: // The aggregation was not overridden with a view. Use the aggregation // provided by the reader. stream.Aggregation = readerAggregation case AggregationDefault: // The view explicitly requested the default aggregation. stream.Aggregation = DefaultAggregationSelector(kind) } if err := isAggregatorCompatible(kind, stream.Aggregation); err != nil { return nil, 0, fmt.Errorf( "creating aggregator with instrumentKind: %d, aggregation %v: %w", kind, stream.Aggregation, err, ) } id := i.instID(kind, stream) // If there is a conflict, the specification says the view should // still be applied and a warning should be logged. i.logConflict(id) // If there are requests for the same instrument with different name // casing, the first-seen needs to be returned. Use a normalize ID for the // cache lookup to ensure the correct comparison. normID := id.normalize() cv := i.aggregators.Lookup(normID, func() aggVal[N] { b := aggregate.Builder[N]{ Temporality: i.pipeline.reader.temporality(kind), } b.Filter = stream.AttributeFilter in, out, err := i.aggregateFunc(b, stream.Aggregation, kind) if err != nil { return aggVal[N]{0, nil, err} } if in == nil { // Drop aggregator. return aggVal[N]{0, nil, nil} } i.pipeline.addSync(scope, instrumentSync{ // Use the first-seen name casing for this and all subsequent // requests of this instrument. name: stream.Name, description: stream.Description, unit: stream.Unit, compAgg: out, }) id := atomic.AddUint64(&aggIDCount, 1) return aggVal[N]{id, in, err} }) return cv.Measure, cv.ID, cv.Err } // logConflict validates if an instrument with the same case-insensitive name // as id has already been created. If that instrument conflicts with id, a // warning is logged. func (i *inserter[N]) logConflict(id instID) { // The API specification defines names as case-insensitive. If there is a // different casing of a name it needs to be a conflict. name := id.normalize().Name existing := i.views.Lookup(name, func() instID { return id }) if id == existing { return } const msg = "duplicate metric stream definitions" args := []interface{}{ "names", fmt.Sprintf("%q, %q", existing.Name, id.Name), "descriptions", fmt.Sprintf("%q, %q", existing.Description, id.Description), "kinds", fmt.Sprintf("%s, %s", existing.Kind, id.Kind), "units", fmt.Sprintf("%s, %s", existing.Unit, id.Unit), "numbers", fmt.Sprintf("%s, %s", existing.Number, id.Number), } // The specification recommends logging a suggested view to resolve // conflicts if possible. // // https://github.com/open-telemetry/opentelemetry-specification/blob/v1.21.0/specification/metrics/sdk.md#duplicate-instrument-registration if id.Unit != existing.Unit || id.Number != existing.Number { // There is no view resolution for these, don't make a suggestion. global.Warn(msg, args...) return } var stream string if id.Name != existing.Name || id.Kind != existing.Kind { stream = `Stream{Name: "{{NEW_NAME}}"}` } else if id.Description != existing.Description { stream = fmt.Sprintf("Stream{Description: %q}", existing.Description) } inst := fmt.Sprintf( "Instrument{Name: %q, Description: %q, Kind: %q, Unit: %q}", id.Name, id.Description, "InstrumentKind"+id.Kind.String(), id.Unit, ) args = append(args, "suggested.view", fmt.Sprintf("NewView(%s, %s)", inst, stream)) global.Warn(msg, args...) } func (i *inserter[N]) instID(kind InstrumentKind, stream Stream) instID { var zero N return instID{ Name: stream.Name, Description: stream.Description, Unit: stream.Unit, Kind: kind, Number: fmt.Sprintf("%T", zero), } } // aggregateFunc returns new aggregate functions matching agg, kind, and // monotonic. If the agg is unknown or temporality is invalid, an error is // returned. func (i *inserter[N]) aggregateFunc(b aggregate.Builder[N], agg Aggregation, kind InstrumentKind) (meas aggregate.Measure[N], comp aggregate.ComputeAggregation, err error) { switch a := agg.(type) { case AggregationDefault: return i.aggregateFunc(b, DefaultAggregationSelector(kind), kind) case AggregationDrop: // Return nil in and out to signify the drop aggregator. case AggregationLastValue: meas, comp = b.LastValue() case AggregationSum: switch kind { case InstrumentKindObservableCounter: meas, comp = b.PrecomputedSum(true) case InstrumentKindObservableUpDownCounter: meas, comp = b.PrecomputedSum(false) case InstrumentKindCounter, InstrumentKindHistogram: meas, comp = b.Sum(true) default: // InstrumentKindUpDownCounter, InstrumentKindObservableGauge, and // instrumentKindUndefined or other invalid instrument kinds. meas, comp = b.Sum(false) } case AggregationExplicitBucketHistogram: var noSum bool switch kind { case InstrumentKindUpDownCounter, InstrumentKindObservableUpDownCounter, InstrumentKindObservableGauge: // The sum should not be collected for any instrument that can make // negative measurements: // https://github.com/open-telemetry/opentelemetry-specification/blob/v1.21.0/specification/metrics/sdk.md#histogram-aggregations noSum = true } meas, comp = b.ExplicitBucketHistogram(a.Boundaries, a.NoMinMax, noSum) case AggregationBase2ExponentialHistogram: var noSum bool switch kind { case InstrumentKindUpDownCounter, InstrumentKindObservableUpDownCounter, InstrumentKindObservableGauge: // The sum should not be collected for any instrument that can make // negative measurements: // https://github.com/open-telemetry/opentelemetry-specification/blob/v1.21.0/specification/metrics/sdk.md#histogram-aggregations noSum = true } meas, comp = b.ExponentialBucketHistogram(a.MaxSize, a.MaxScale, a.NoMinMax, noSum) default: err = errUnknownAggregation } return meas, comp, err } // isAggregatorCompatible checks if the aggregation can be used by the instrument. // Current compatibility: // // | Instrument Kind | Drop | LastValue | Sum | Histogram | Exponential Histogram | // |--------------------------|------|-----------|-----|-----------|-----------------------| // | Counter | ✓ | | ✓ | ✓ | ✓ | // | UpDownCounter | ✓ | | ✓ | ✓ | ✓ | // | Histogram | ✓ | | ✓ | ✓ | ✓ | // | Observable Counter | ✓ | | ✓ | ✓ | ✓ | // | Observable UpDownCounter | ✓ | | ✓ | ✓ | ✓ | // | Observable Gauge | ✓ | ✓ | | ✓ | ✓ |. func isAggregatorCompatible(kind InstrumentKind, agg Aggregation) error { switch agg.(type) { case AggregationDefault: return nil case AggregationExplicitBucketHistogram, AggregationBase2ExponentialHistogram: switch kind { case InstrumentKindCounter, InstrumentKindUpDownCounter, InstrumentKindHistogram, InstrumentKindObservableCounter, InstrumentKindObservableUpDownCounter, InstrumentKindObservableGauge: return nil default: return errIncompatibleAggregation } case AggregationSum: switch kind { case InstrumentKindObservableCounter, InstrumentKindObservableUpDownCounter, InstrumentKindCounter, InstrumentKindHistogram, InstrumentKindUpDownCounter: return nil default: // TODO: review need for aggregation check after // https://github.com/open-telemetry/opentelemetry-specification/issues/2710 return errIncompatibleAggregation } case AggregationLastValue: if kind == InstrumentKindObservableGauge { return nil } // TODO: review need for aggregation check after // https://github.com/open-telemetry/opentelemetry-specification/issues/2710 return errIncompatibleAggregation case AggregationDrop: return nil default: // This is used passed checking for default, it should be an error at this point. return fmt.Errorf("%w: %v", errUnknownAggregation, agg) } } // pipelines is the group of pipelines connecting Readers with instrument // measurement. type pipelines []*pipeline func newPipelines(res *resource.Resource, readers []Reader, views []View) pipelines { pipes := make([]*pipeline, 0, len(readers)) for _, r := range readers { p := newPipeline(res, r, views) r.register(p) pipes = append(pipes, p) } return pipes } func (p pipelines) registerCallback(cback func(context.Context) error) { for _, pipe := range p { pipe.addCallback(cback) } } func (p pipelines) registerMultiCallback(c multiCallback) metric.Registration { unregs := make([]func(), len(p)) for i, pipe := range p { unregs[i] = pipe.addMultiCallback(c) } return unregisterFuncs{f: unregs} } type unregisterFuncs struct { embedded.Registration f []func() } func (u unregisterFuncs) Unregister() error { for _, f := range u.f { f() } return nil } // resolver facilitates resolving aggregate functions an instrument calls to // aggregate measurements with while updating all pipelines that need to pull // from those aggregations. type resolver[N int64 | float64] struct { inserters []*inserter[N] } func newResolver[N int64 | float64](p pipelines, vc *cache[string, instID]) resolver[N] { in := make([]*inserter[N], len(p)) for i := range in { in[i] = newInserter[N](p[i], vc) } return resolver[N]{in} } // Aggregators returns the Aggregators that must be updated by the instrument // defined by key. func (r resolver[N]) Aggregators(id Instrument) ([]aggregate.Measure[N], error) { var measures []aggregate.Measure[N] errs := &multierror{} for _, i := range r.inserters { in, err := i.Instrument(id, i.readerDefaultAggregation(id.Kind)) if err != nil { errs.append(err) } measures = append(measures, in...) } return measures, errs.errorOrNil() } // HistogramAggregators returns the histogram Aggregators that must be updated by the instrument // defined by key. If boundaries were provided on instrument instantiation, those take precedence // over boundaries provided by the reader. func (r resolver[N]) HistogramAggregators(id Instrument, boundaries []float64) ([]aggregate.Measure[N], error) { var measures []aggregate.Measure[N] errs := &multierror{} for _, i := range r.inserters { agg := i.readerDefaultAggregation(id.Kind) if histAgg, ok := agg.(AggregationExplicitBucketHistogram); ok && len(boundaries) > 0 { histAgg.Boundaries = boundaries agg = histAgg } in, err := i.Instrument(id, agg) if err != nil { errs.append(err) } measures = append(measures, in...) } return measures, errs.errorOrNil() } type multierror struct { wrapped error errors []string } func (m *multierror) errorOrNil() error { if len(m.errors) == 0 { return nil } if m.wrapped == nil { return errors.New(strings.Join(m.errors, "; ")) } return fmt.Errorf("%w: %s", m.wrapped, strings.Join(m.errors, "; ")) } func (m *multierror) append(err error) { m.errors = append(m.errors, err.Error()) }