Ejemplo n.º 1
0
// addToIndexFromKey will pull the measurement name, series key, and field name from a composite key and add it to the
// database index and measurement fields
func (e *Engine) addToIndexFromKey(shardID uint64, key []byte, fieldType influxql.DataType, index *tsdb.DatabaseIndex) error {
	seriesKey, field := SeriesAndFieldFromCompositeKey(key)
	measurement := tsdb.MeasurementFromSeriesKey(string(seriesKey))

	m := index.CreateMeasurementIndexIfNotExists(measurement)
	m.SetFieldName(field)

	mf := e.measurementFields[measurement]
	if mf == nil {
		mf = tsdb.NewMeasurementFields()
		e.measurementFields[measurement] = mf
	}

	if err := mf.CreateFieldIfNotExists(field, fieldType, false); err != nil {
		return err
	}

	// Have we already indexed this series?
	ss := index.SeriesBytes(seriesKey)
	if ss != nil {
		// Add this shard to the existing series
		ss.AssignShard(shardID)
		return nil
	}

	// ignore error because ParseKey returns "missing fields" and we don't have
	// fields (in line protocol format) in the series key
	_, tags, _ := models.ParseKey(seriesKey)

	s := tsdb.NewSeries(string(seriesKey), tags)
	index.CreateSeriesIndexIfNotExists(measurement, s)
	s.AssignShard(shardID)

	return nil
}
Ejemplo n.º 2
0
func BenchmarkMeasurement_SeriesIDForExp_NERegex(b *testing.B) {
	m := tsdb.NewMeasurement("cpu")
	for i := 0; i < 100000; i++ {
		s := tsdb.NewSeries("cpu", models.Tags{models.Tag{
			Key:   []byte("host"),
			Value: []byte(fmt.Sprintf("host%d", i))}})
		s.ID = uint64(i)
		m.AddSeries(s)
	}

	if exp, got := 100000, len(m.SeriesKeys()); exp != got {
		b.Fatalf("series count mismatch: exp %v got %v", exp, got)
	}

	stmt, err := influxql.NewParser(strings.NewReader(`SELECT * FROM cpu WHERE host !~ /foo\d+/`)).ParseStatement()
	if err != nil {
		b.Fatalf("invalid statement: %s", err)
	}

	selectStmt := stmt.(*influxql.SelectStatement)

	b.ResetTimer()
	for i := 0; i < b.N; i++ {
		ids := m.IDsForExpr(selectStmt.Condition.(*influxql.BinaryExpr))
		if exp, got := 100000, len(ids); exp != got {
			b.Fatalf("series count mismatch: exp %v got %v", exp, got)
		}

	}

}
Ejemplo n.º 3
0
// addToIndexFromKey will pull the measurement name, series key, and field name from a composite key and add it to the
// database index and measurement fields
func (e *Engine) addToIndexFromKey(key string, fieldType influxql.DataType, index *tsdb.DatabaseIndex, measurementFields map[string]*tsdb.MeasurementFields) error {
	seriesKey, field := seriesAndFieldFromCompositeKey(key)
	measurement := tsdb.MeasurementFromSeriesKey(seriesKey)

	m := index.CreateMeasurementIndexIfNotExists(measurement)
	m.SetFieldName(field)

	mf := measurementFields[measurement]
	if mf == nil {
		mf = &tsdb.MeasurementFields{
			Fields: map[string]*tsdb.Field{},
		}
		measurementFields[measurement] = mf
	}

	if err := mf.CreateFieldIfNotExists(field, fieldType, false); err != nil {
		return err
	}

	_, tags, err := models.ParseKey(seriesKey)
	if err == nil {
		return err
	}

	s := tsdb.NewSeries(seriesKey, tags)
	s.InitializeShards()
	index.CreateSeriesIndexIfNotExists(measurement, s)

	return nil
}
Ejemplo n.º 4
0
// Ensure engine can create an iterator with a condition.
func TestEngine_CreateIterator_Condition(t *testing.T) {
	t.Parallel()

	e := MustOpenEngine()
	defer e.Close()

	e.Index().CreateMeasurementIndexIfNotExists("cpu")
	e.Index().Measurement("cpu").SetFieldName("X")
	e.Index().Measurement("cpu").SetFieldName("Y")
	e.MeasurementFields("cpu").CreateFieldIfNotExists("value", influxql.Float, false)
	e.MeasurementFields("cpu").CreateFieldIfNotExists("X", influxql.Float, false)
	e.MeasurementFields("cpu").CreateFieldIfNotExists("Y", influxql.Float, false)
	si := e.Index().CreateSeriesIndexIfNotExists("cpu", tsdb.NewSeries("cpu,host=A", models.NewTags(map[string]string{"host": "A"})))
	si.AssignShard(1)

	if err := e.WritePointsString(
		`cpu,host=A value=1.1 1000000000`,
		`cpu,host=A X=10 1000000000`,
		`cpu,host=A Y=100 1000000000`,

		`cpu,host=A value=1.2 2000000000`,

		`cpu,host=A value=1.3 3000000000`,
		`cpu,host=A X=20 3000000000`,
		`cpu,host=A Y=200 3000000000`,
	); err != nil {
		t.Fatalf("failed to write points: %s", err.Error())
	}

	itr, err := e.CreateIterator(influxql.IteratorOptions{
		Expr:       influxql.MustParseExpr(`value`),
		Dimensions: []string{"host"},
		Condition:  influxql.MustParseExpr(`X = 10 OR Y > 150`),
		Sources:    []influxql.Source{&influxql.Measurement{Name: "cpu"}},
		StartTime:  influxql.MinTime,
		EndTime:    influxql.MaxTime,
		Ascending:  true,
	})
	if err != nil {
		t.Fatal(err)
	}
	fitr := itr.(influxql.FloatIterator)

	if p, err := fitr.Next(); err != nil {
		t.Fatalf("unexpected error(0): %v", err)
	} else if !reflect.DeepEqual(p, &influxql.FloatPoint{Name: "cpu", Tags: ParseTags("host=A"), Time: 1000000000, Value: 1.1}) {
		t.Fatalf("unexpected point(0): %v", p)
	}
	if p, err := fitr.Next(); err != nil {
		t.Fatalf("unexpected point(1): %v", err)
	} else if !reflect.DeepEqual(p, &influxql.FloatPoint{Name: "cpu", Tags: ParseTags("host=A"), Time: 3000000000, Value: 1.3}) {
		t.Fatalf("unexpected point(1): %v", p)
	}
	if p, err := fitr.Next(); err != nil {
		t.Fatalf("expected eof, got error: %v", err)
	} else if p != nil {
		t.Fatalf("expected eof: %v", p)
	}
}
Ejemplo n.º 5
0
// MustInitBenchmarkEngine creates a new engine and fills it with points.
// Reuses previous engine if the same parameters were used.
func MustInitBenchmarkEngine(pointN int) *Engine {
	// Reuse engine, if available.
	if benchmark.Engine != nil {
		if benchmark.PointN == pointN {
			return benchmark.Engine
		}

		// Otherwise close and remove it.
		benchmark.Engine.Close()
		benchmark.Engine = nil
	}

	const batchSize = 1000
	if pointN%batchSize != 0 {
		panic(fmt.Sprintf("point count (%d) must be a multiple of batch size (%d)", pointN, batchSize))
	}

	e := MustOpenEngine()

	// Initialize metadata.
	e.Index().CreateMeasurementIndexIfNotExists("cpu")
	e.MeasurementFields("cpu").CreateFieldIfNotExists("value", influxql.Float, false)
	si := e.Index().CreateSeriesIndexIfNotExists("cpu", tsdb.NewSeries("cpu,host=A", models.NewTags(map[string]string{"host": "A"})))
	si.AssignShard(1)

	// Generate time ascending points with jitterred time & value.
	rand := rand.New(rand.NewSource(0))
	for i := 0; i < pointN; i += batchSize {
		var buf bytes.Buffer
		for j := 0; j < batchSize; j++ {
			fmt.Fprintf(&buf, "cpu,host=%s value=%d %d",
				hostNames[j%len(hostNames)],
				100+rand.Intn(50)-25,
				(time.Duration(i+j)*time.Second)+(time.Duration(rand.Intn(500)-250)*time.Millisecond),
			)
			if j != pointN-1 {
				fmt.Fprint(&buf, "\n")
			}
		}

		if err := e.WritePointsString(buf.String()); err != nil {
			panic(err)
		}
	}

	if err := e.WriteSnapshot(); err != nil {
		panic(err)
	}

	// Force garbage collection.
	runtime.GC()

	// Save engine reference for reuse.
	benchmark.Engine = e
	benchmark.PointN = pointN

	return e
}
Ejemplo n.º 6
0
// Ensure engine can create an iterator with auxilary fields.
func TestEngine_CreateIterator_Aux(t *testing.T) {
	t.Parallel()

	e := MustOpenEngine()
	defer e.Close()

	e.Index().CreateMeasurementIndexIfNotExists("cpu")
	e.MeasurementFields("cpu").CreateFieldIfNotExists("value", influxql.Float, false)
	e.MeasurementFields("cpu").CreateFieldIfNotExists("F", influxql.Float, false)
	si := e.Index().CreateSeriesIndexIfNotExists("cpu", tsdb.NewSeries("cpu,host=A", models.NewTags(map[string]string{"host": "A"})))
	si.AssignShard(1)

	if err := e.WritePointsString(
		`cpu,host=A value=1.1 1000000000`,
		`cpu,host=A F=100 1000000000`,
		`cpu,host=A value=1.2 2000000000`,
		`cpu,host=A value=1.3 3000000000`,
		`cpu,host=A F=200 3000000000`,
	); err != nil {
		t.Fatalf("failed to write points: %s", err.Error())
	}

	itr, err := e.CreateIterator(influxql.IteratorOptions{
		Expr:       influxql.MustParseExpr(`value`),
		Aux:        []influxql.VarRef{{Val: "F"}},
		Dimensions: []string{"host"},
		Sources:    []influxql.Source{&influxql.Measurement{Name: "cpu"}},
		StartTime:  influxql.MinTime,
		EndTime:    influxql.MaxTime,
		Ascending:  true,
	})
	if err != nil {
		t.Fatal(err)
	}
	fitr := itr.(influxql.FloatIterator)

	if p, err := fitr.Next(); err != nil {
		t.Fatalf("unexpected error(0): %v", err)
	} else if !deep.Equal(p, &influxql.FloatPoint{Name: "cpu", Tags: ParseTags("host=A"), Time: 1000000000, Value: 1.1, Aux: []interface{}{float64(100)}}) {
		t.Fatalf("unexpected point(0): %v", p)
	}
	if p, err := fitr.Next(); err != nil {
		t.Fatalf("unexpected error(1): %v", err)
	} else if !deep.Equal(p, &influxql.FloatPoint{Name: "cpu", Tags: ParseTags("host=A"), Time: 2000000000, Value: 1.2, Aux: []interface{}{(*float64)(nil)}}) {
		t.Fatalf("unexpected point(1): %v", p)
	}
	if p, err := fitr.Next(); err != nil {
		t.Fatalf("unexpected error(2): %v", err)
	} else if !deep.Equal(p, &influxql.FloatPoint{Name: "cpu", Tags: ParseTags("host=A"), Time: 3000000000, Value: 1.3, Aux: []interface{}{float64(200)}}) {
		t.Fatalf("unexpected point(2): %v", p)
	}
	if p, err := fitr.Next(); err != nil {
		t.Fatalf("expected eof, got error: %v", err)
	} else if p != nil {
		t.Fatalf("expected eof: %v", p)
	}
}
Ejemplo n.º 7
0
func genTestSeries(mCnt, tCnt, vCnt int) []*TestSeries {
	measurements := genStrList("measurement", mCnt)
	tagSets := NewTagSetGenerator(tCnt, vCnt).AllSets()
	series := []*TestSeries{}
	for _, m := range measurements {
		for _, ts := range tagSets {
			series = append(series, &TestSeries{
				Measurement: m,
				Series:      tsdb.NewSeries(fmt.Sprintf("%s:%s", m, string(tsdb.MarshalTags(ts))), models.NewTags(ts)),
			})
		}
	}
	return series
}
Ejemplo n.º 8
0
func TestMeasurement_AppendSeriesKeysByID_Exists(t *testing.T) {
	m := tsdb.NewMeasurement("cpu")
	s := tsdb.NewSeries("cpu,host=foo", models.Tags{models.Tag{Key: []byte("host"), Value: []byte("foo")}})
	s.ID = 1
	m.AddSeries(s)

	var dst []string
	dst = m.AppendSeriesKeysByID(dst, []uint64{1})
	if exp, got := 1, len(dst); exp != got {
		t.Fatalf("series len mismatch: exp %v, got %v", exp, got)
	}

	if exp, got := "cpu,host=foo", dst[0]; exp != got {
		t.Fatalf("series mismatch: exp %v, got %v", exp, got)
	}
}
Ejemplo n.º 9
0
// Ensure engine can create an descending iterator for cached values.
func TestEngine_CreateIterator_TSM_Descending(t *testing.T) {
	t.Parallel()

	e := MustOpenEngine()
	defer e.Close()

	e.Index().CreateMeasurementIndexIfNotExists("cpu")
	e.MeasurementFields("cpu").CreateFieldIfNotExists("value", influxql.Float, false)
	e.Index().CreateSeriesIndexIfNotExists("cpu", tsdb.NewSeries("cpu,host=A", map[string]string{"host": "A"}))
	if err := e.WritePointsString(
		`cpu,host=A value=1.1 1000000000`,
		`cpu,host=A value=1.2 2000000000`,
		`cpu,host=A value=1.3 3000000000`,
	); err != nil {
		t.Fatalf("failed to write points: %s", err.Error())
	}
	e.MustWriteSnapshot()

	itr, err := e.CreateIterator(influxql.IteratorOptions{
		Expr:       influxql.MustParseExpr(`value`),
		Dimensions: []string{"host"},
		Sources:    []influxql.Source{&influxql.Measurement{Name: "cpu"}},
		StartTime:  influxql.MinTime,
		EndTime:    influxql.MaxTime,
		Ascending:  false,
	})
	if err != nil {
		t.Fatal(err)
	}
	fitr := itr.(influxql.FloatIterator)

	if p := fitr.Next(); !reflect.DeepEqual(p, &influxql.FloatPoint{Name: "cpu", Tags: ParseTags("host=A"), Time: 3000000000, Value: 1.3}) {
		t.Fatalf("unexpected point(0): %v", p)
	}
	if p := fitr.Next(); !reflect.DeepEqual(p, &influxql.FloatPoint{Name: "cpu", Tags: ParseTags("host=A"), Time: 2000000000, Value: 1.2}) {
		t.Fatalf("unexpected point(1): %v", p)
	}
	if p := fitr.Next(); !reflect.DeepEqual(p, &influxql.FloatPoint{Name: "cpu", Tags: ParseTags("host=A"), Time: 1000000000, Value: 1.1}) {
		t.Fatalf("unexpected point(2): %v", p)
	}
	if p := fitr.Next(); p != nil {
		t.Fatalf("expected eof: %v", p)
	}
}