// 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_test import ( "context" "fmt" "math" "sync" "testing" "github.com/stretchr/testify/require" "go.opentelemetry.io/otel" "go.opentelemetry.io/otel/label" "go.opentelemetry.io/otel/metric" "go.opentelemetry.io/otel/metric/number" export "go.opentelemetry.io/otel/sdk/export/metric" "go.opentelemetry.io/otel/sdk/export/metric/aggregation" metricsdk "go.opentelemetry.io/otel/sdk/metric" "go.opentelemetry.io/otel/sdk/metric/processor/processortest" "go.opentelemetry.io/otel/sdk/resource" ) var Must = metric.Must var testResource = resource.NewWithAttributes(label.String("R", "V")) type handler struct { sync.Mutex err error } func (h *handler) Handle(err error) { h.Lock() h.err = err h.Unlock() } func (h *handler) Reset() { h.Lock() h.err = nil h.Unlock() } func (h *handler) Flush() error { h.Lock() err := h.err h.err = nil h.Unlock() return err } var testHandler *handler func init() { testHandler = new(handler) otel.SetErrorHandler(testHandler) } // correctnessProcessor could be replaced with processortest.Processor // with a non-default aggregator selector. TODO(#872) use the // processortest code here. type correctnessProcessor struct { t *testing.T *testSelector accumulations []export.Accumulation } type testSelector struct { selector export.AggregatorSelector newAggCount int } func (ts *testSelector) AggregatorFor(desc *metric.Descriptor, aggPtrs ...*export.Aggregator) { ts.newAggCount += len(aggPtrs) processortest.AggregatorSelector().AggregatorFor(desc, aggPtrs...) } func newSDK(t *testing.T) (metric.Meter, *metricsdk.Accumulator, *correctnessProcessor) { testHandler.Reset() processor := &correctnessProcessor{ t: t, testSelector: &testSelector{selector: processortest.AggregatorSelector()}, } accum := metricsdk.NewAccumulator( processor, testResource, ) meter := metric.WrapMeterImpl(accum, "test") return meter, accum, processor } func (ci *correctnessProcessor) Process(accumulation export.Accumulation) error { ci.accumulations = append(ci.accumulations, accumulation) return nil } func TestInputRangeCounter(t *testing.T) { ctx := context.Background() meter, sdk, processor := newSDK(t) counter := Must(meter).NewInt64Counter("name.sum") counter.Add(ctx, -1) require.Equal(t, aggregation.ErrNegativeInput, testHandler.Flush()) checkpointed := sdk.Collect(ctx) require.Equal(t, 0, checkpointed) processor.accumulations = nil counter.Add(ctx, 1) checkpointed = sdk.Collect(ctx) sum, err := processor.accumulations[0].Aggregator().(aggregation.Sum).Sum() require.Equal(t, int64(1), sum.AsInt64()) require.Equal(t, 1, checkpointed) require.Nil(t, err) require.Nil(t, testHandler.Flush()) } func TestInputRangeUpDownCounter(t *testing.T) { ctx := context.Background() meter, sdk, processor := newSDK(t) counter := Must(meter).NewInt64UpDownCounter("name.sum") counter.Add(ctx, -1) counter.Add(ctx, -1) counter.Add(ctx, 2) counter.Add(ctx, 1) checkpointed := sdk.Collect(ctx) sum, err := processor.accumulations[0].Aggregator().(aggregation.Sum).Sum() require.Equal(t, int64(1), sum.AsInt64()) require.Equal(t, 1, checkpointed) require.Nil(t, err) require.Nil(t, testHandler.Flush()) } func TestInputRangeValueRecorder(t *testing.T) { ctx := context.Background() meter, sdk, processor := newSDK(t) valuerecorder := Must(meter).NewFloat64ValueRecorder("name.exact") valuerecorder.Record(ctx, math.NaN()) require.Equal(t, aggregation.ErrNaNInput, testHandler.Flush()) checkpointed := sdk.Collect(ctx) require.Equal(t, 0, checkpointed) valuerecorder.Record(ctx, 1) valuerecorder.Record(ctx, 2) processor.accumulations = nil checkpointed = sdk.Collect(ctx) count, err := processor.accumulations[0].Aggregator().(aggregation.Distribution).Count() require.Equal(t, int64(2), count) require.Equal(t, 1, checkpointed) require.Nil(t, testHandler.Flush()) require.Nil(t, err) } func TestDisabledInstrument(t *testing.T) { ctx := context.Background() meter, sdk, processor := newSDK(t) valuerecorder := Must(meter).NewFloat64ValueRecorder("name.disabled") valuerecorder.Record(ctx, -1) checkpointed := sdk.Collect(ctx) require.Equal(t, 0, checkpointed) require.Equal(t, 0, len(processor.accumulations)) } func TestRecordNaN(t *testing.T) { ctx := context.Background() meter, _, _ := newSDK(t) c := Must(meter).NewFloat64Counter("name.sum") require.Nil(t, testHandler.Flush()) c.Add(ctx, math.NaN()) require.Error(t, testHandler.Flush()) } func TestSDKLabelsDeduplication(t *testing.T) { ctx := context.Background() meter, sdk, processor := newSDK(t) counter := Must(meter).NewInt64Counter("name.sum") const ( maxKeys = 21 keySets = 2 repeats = 3 ) var keysA []label.Key var keysB []label.Key for i := 0; i < maxKeys; i++ { keysA = append(keysA, label.Key(fmt.Sprintf("A%03d", i))) keysB = append(keysB, label.Key(fmt.Sprintf("B%03d", i))) } var allExpect [][]label.KeyValue for numKeys := 0; numKeys < maxKeys; numKeys++ { var kvsA []label.KeyValue var kvsB []label.KeyValue for r := 0; r < repeats; r++ { for i := 0; i < numKeys; i++ { kvsA = append(kvsA, keysA[i].Int(r)) kvsB = append(kvsB, keysB[i].Int(r)) } } var expectA []label.KeyValue var expectB []label.KeyValue for i := 0; i < numKeys; i++ { expectA = append(expectA, keysA[i].Int(repeats-1)) expectB = append(expectB, keysB[i].Int(repeats-1)) } counter.Add(ctx, 1, kvsA...) counter.Add(ctx, 1, kvsA...) allExpect = append(allExpect, expectA) if numKeys != 0 { // In this case A and B sets are the same. counter.Add(ctx, 1, kvsB...) counter.Add(ctx, 1, kvsB...) allExpect = append(allExpect, expectB) } } sdk.Collect(ctx) var actual [][]label.KeyValue for _, rec := range processor.accumulations { sum, _ := rec.Aggregator().(aggregation.Sum).Sum() require.Equal(t, sum, number.NewInt64Number(2)) kvs := rec.Labels().ToSlice() actual = append(actual, kvs) } require.ElementsMatch(t, allExpect, actual) } func newSetIter(kvs ...label.KeyValue) label.Iterator { labels := label.NewSet(kvs...) return labels.Iter() } func TestDefaultLabelEncoder(t *testing.T) { encoder := label.DefaultEncoder() encoded := encoder.Encode(newSetIter(label.String("A", "B"), label.String("C", "D"))) require.Equal(t, `A=B,C=D`, encoded) encoded = encoder.Encode(newSetIter(label.String("A", "B,c=d"), label.String(`C\`, "D"))) require.Equal(t, `A=B\,c\=d,C\\=D`, encoded) encoded = encoder.Encode(newSetIter(label.String(`\`, `=`), label.String(`,`, `\`))) require.Equal(t, `\,=\\,\\=\=`, encoded) // Note: the label encoder does not sort or de-dup values, // that is done in Labels(...). encoded = encoder.Encode(newSetIter( label.Int("I", 1), label.Uint("U", 1), label.Int32("I32", 1), label.Uint32("U32", 1), label.Int64("I64", 1), label.Uint64("U64", 1), label.Float64("F64", 1), label.Float64("F64", 1), label.String("S", "1"), label.Bool("B", true), )) require.Equal(t, "B=true,F64=1,I=1,I32=1,I64=1,S=1,U=1,U32=1,U64=1", encoded) } func TestObserverCollection(t *testing.T) { ctx := context.Background() meter, sdk, processor := newSDK(t) _ = Must(meter).NewFloat64ValueObserver("float.valueobserver.lastvalue", func(_ context.Context, result metric.Float64ObserverResult) { result.Observe(1, label.String("A", "B")) // last value wins result.Observe(-1, label.String("A", "B")) result.Observe(-1, label.String("C", "D")) }) _ = Must(meter).NewInt64ValueObserver("int.valueobserver.lastvalue", func(_ context.Context, result metric.Int64ObserverResult) { result.Observe(-1, label.String("A", "B")) result.Observe(1) // last value wins result.Observe(1, label.String("A", "B")) result.Observe(1) }) _ = Must(meter).NewFloat64SumObserver("float.sumobserver.sum", func(_ context.Context, result metric.Float64ObserverResult) { result.Observe(1, label.String("A", "B")) result.Observe(2, label.String("A", "B")) result.Observe(1, label.String("C", "D")) }) _ = Must(meter).NewInt64SumObserver("int.sumobserver.sum", func(_ context.Context, result metric.Int64ObserverResult) { result.Observe(2, label.String("A", "B")) result.Observe(1) // last value wins result.Observe(1, label.String("A", "B")) result.Observe(1) }) _ = Must(meter).NewFloat64UpDownSumObserver("float.updownsumobserver.sum", func(_ context.Context, result metric.Float64ObserverResult) { result.Observe(1, label.String("A", "B")) result.Observe(-2, label.String("A", "B")) result.Observe(1, label.String("C", "D")) }) _ = Must(meter).NewInt64UpDownSumObserver("int.updownsumobserver.sum", func(_ context.Context, result metric.Int64ObserverResult) { result.Observe(2, label.String("A", "B")) result.Observe(1) // last value wins result.Observe(1, label.String("A", "B")) result.Observe(-1) }) _ = Must(meter).NewInt64ValueObserver("empty.valueobserver.sum", func(_ context.Context, result metric.Int64ObserverResult) { }) collected := sdk.Collect(ctx) require.Equal(t, collected, len(processor.accumulations)) out := processortest.NewOutput(label.DefaultEncoder()) for _, rec := range processor.accumulations { require.NoError(t, out.AddAccumulation(rec)) } require.EqualValues(t, map[string]float64{ "float.valueobserver.lastvalue/A=B/R=V": -1, "float.valueobserver.lastvalue/C=D/R=V": -1, "int.valueobserver.lastvalue//R=V": 1, "int.valueobserver.lastvalue/A=B/R=V": 1, "float.sumobserver.sum/A=B/R=V": 2, "float.sumobserver.sum/C=D/R=V": 1, "int.sumobserver.sum//R=V": 1, "int.sumobserver.sum/A=B/R=V": 1, "float.updownsumobserver.sum/A=B/R=V": -2, "float.updownsumobserver.sum/C=D/R=V": 1, "int.updownsumobserver.sum//R=V": -1, "int.updownsumobserver.sum/A=B/R=V": 1, }, out.Map()) } func TestSumObserverInputRange(t *testing.T) { ctx := context.Background() meter, sdk, processor := newSDK(t) // TODO: these tests are testing for negative values, not for _descending values_. Fix. _ = Must(meter).NewFloat64SumObserver("float.sumobserver.sum", func(_ context.Context, result metric.Float64ObserverResult) { result.Observe(-2, label.String("A", "B")) require.Equal(t, aggregation.ErrNegativeInput, testHandler.Flush()) result.Observe(-1, label.String("C", "D")) require.Equal(t, aggregation.ErrNegativeInput, testHandler.Flush()) }) _ = Must(meter).NewInt64SumObserver("int.sumobserver.sum", func(_ context.Context, result metric.Int64ObserverResult) { result.Observe(-1, label.String("A", "B")) require.Equal(t, aggregation.ErrNegativeInput, testHandler.Flush()) result.Observe(-1) require.Equal(t, aggregation.ErrNegativeInput, testHandler.Flush()) }) collected := sdk.Collect(ctx) require.Equal(t, 0, collected) require.Equal(t, 0, len(processor.accumulations)) // check that the error condition was reset require.NoError(t, testHandler.Flush()) } func TestObserverBatch(t *testing.T) { ctx := context.Background() meter, sdk, processor := newSDK(t) var floatValueObs metric.Float64ValueObserver var intValueObs metric.Int64ValueObserver var floatSumObs metric.Float64SumObserver var intSumObs metric.Int64SumObserver var floatUpDownSumObs metric.Float64UpDownSumObserver var intUpDownSumObs metric.Int64UpDownSumObserver var batch = Must(meter).NewBatchObserver( func(_ context.Context, result metric.BatchObserverResult) { result.Observe( []label.KeyValue{ label.String("A", "B"), }, floatValueObs.Observation(1), floatValueObs.Observation(-1), intValueObs.Observation(-1), intValueObs.Observation(1), floatSumObs.Observation(1000), intSumObs.Observation(100), floatUpDownSumObs.Observation(-1000), intUpDownSumObs.Observation(-100), ) result.Observe( []label.KeyValue{ label.String("C", "D"), }, floatValueObs.Observation(-1), floatSumObs.Observation(-1), floatUpDownSumObs.Observation(-1), ) result.Observe( nil, intValueObs.Observation(1), intValueObs.Observation(1), intSumObs.Observation(10), floatSumObs.Observation(1.1), intUpDownSumObs.Observation(10), ) }) floatValueObs = batch.NewFloat64ValueObserver("float.valueobserver.lastvalue") intValueObs = batch.NewInt64ValueObserver("int.valueobserver.lastvalue") floatSumObs = batch.NewFloat64SumObserver("float.sumobserver.sum") intSumObs = batch.NewInt64SumObserver("int.sumobserver.sum") floatUpDownSumObs = batch.NewFloat64UpDownSumObserver("float.updownsumobserver.sum") intUpDownSumObs = batch.NewInt64UpDownSumObserver("int.updownsumobserver.sum") collected := sdk.Collect(ctx) require.Equal(t, collected, len(processor.accumulations)) out := processortest.NewOutput(label.DefaultEncoder()) for _, rec := range processor.accumulations { require.NoError(t, out.AddAccumulation(rec)) } require.EqualValues(t, map[string]float64{ "float.sumobserver.sum//R=V": 1.1, "float.sumobserver.sum/A=B/R=V": 1000, "int.sumobserver.sum//R=V": 10, "int.sumobserver.sum/A=B/R=V": 100, "int.updownsumobserver.sum/A=B/R=V": -100, "float.updownsumobserver.sum/A=B/R=V": -1000, "int.updownsumobserver.sum//R=V": 10, "float.updownsumobserver.sum/C=D/R=V": -1, "float.valueobserver.lastvalue/A=B/R=V": -1, "float.valueobserver.lastvalue/C=D/R=V": -1, "int.valueobserver.lastvalue//R=V": 1, "int.valueobserver.lastvalue/A=B/R=V": 1, }, out.Map()) } func TestRecordBatch(t *testing.T) { ctx := context.Background() meter, sdk, processor := newSDK(t) counter1 := Must(meter).NewInt64Counter("int64.sum") counter2 := Must(meter).NewFloat64Counter("float64.sum") valuerecorder1 := Must(meter).NewInt64ValueRecorder("int64.exact") valuerecorder2 := Must(meter).NewFloat64ValueRecorder("float64.exact") sdk.RecordBatch( ctx, []label.KeyValue{ label.String("A", "B"), label.String("C", "D"), }, counter1.Measurement(1), counter2.Measurement(2), valuerecorder1.Measurement(3), valuerecorder2.Measurement(4), ) sdk.Collect(ctx) out := processortest.NewOutput(label.DefaultEncoder()) for _, rec := range processor.accumulations { require.NoError(t, out.AddAccumulation(rec)) } require.EqualValues(t, map[string]float64{ "int64.sum/A=B,C=D/R=V": 1, "float64.sum/A=B,C=D/R=V": 2, "int64.exact/A=B,C=D/R=V": 3, "float64.exact/A=B,C=D/R=V": 4, }, out.Map()) } // TestRecordPersistence ensures that a direct-called instrument that // is repeatedly used each interval results in a persistent record, so // that its encoded labels will be cached across collection intervals. func TestRecordPersistence(t *testing.T) { ctx := context.Background() meter, sdk, processor := newSDK(t) c := Must(meter).NewFloat64Counter("name.sum") b := c.Bind(label.String("bound", "true")) uk := label.String("bound", "false") for i := 0; i < 100; i++ { c.Add(ctx, 1, uk) b.Add(ctx, 1) sdk.Collect(ctx) } require.Equal(t, 4, processor.newAggCount) } func TestIncorrectInstruments(t *testing.T) { // The Batch observe/record APIs are susceptible to // uninitialized instruments. var counter metric.Int64Counter var observer metric.Int64ValueObserver ctx := context.Background() meter, sdk, _ := newSDK(t) // Now try with uninitialized instruments. meter.RecordBatch(ctx, nil, counter.Measurement(1)) meter.NewBatchObserver(func(_ context.Context, result metric.BatchObserverResult) { result.Observe(nil, observer.Observation(1)) }) collected := sdk.Collect(ctx) require.Equal(t, metricsdk.ErrUninitializedInstrument, testHandler.Flush()) require.Equal(t, 0, collected) // Now try with instruments from another SDK. var noopMeter metric.Meter counter = metric.Must(noopMeter).NewInt64Counter("name.sum") observer = metric.Must(noopMeter).NewBatchObserver( func(context.Context, metric.BatchObserverResult) {}, ).NewInt64ValueObserver("observer") meter.RecordBatch(ctx, nil, counter.Measurement(1)) meter.NewBatchObserver(func(_ context.Context, result metric.BatchObserverResult) { result.Observe(nil, observer.Observation(1)) }) collected = sdk.Collect(ctx) require.Equal(t, 0, collected) require.Equal(t, metricsdk.ErrUninitializedInstrument, testHandler.Flush()) } func TestSyncInAsync(t *testing.T) { ctx := context.Background() meter, sdk, processor := newSDK(t) counter := Must(meter).NewFloat64Counter("counter.sum") _ = Must(meter).NewInt64ValueObserver("observer.lastvalue", func(ctx context.Context, result metric.Int64ObserverResult) { result.Observe(10) counter.Add(ctx, 100) }, ) sdk.Collect(ctx) out := processortest.NewOutput(label.DefaultEncoder()) for _, rec := range processor.accumulations { require.NoError(t, out.AddAccumulation(rec)) } require.EqualValues(t, map[string]float64{ "counter.sum//R=V": 100, "observer.lastvalue//R=V": 10, }, out.Map()) }