package influxql_test import ( "errors" "fmt" "strings" "testing" "time" "github.com/influxdata/influxdb/influxql" ) var errUnexpected = errors.New("unexpected error") type StatementExecutor struct { ExecuteStatementFn func(stmt influxql.Statement, ctx influxql.ExecutionContext) error } func (e *StatementExecutor) ExecuteStatement(stmt influxql.Statement, ctx influxql.ExecutionContext) error { return e.ExecuteStatementFn(stmt, ctx) } func NewQueryExecutor() *influxql.QueryExecutor { return influxql.NewQueryExecutor() } func TestQueryExecutor_AttachQuery(t *testing.T) { q, err := influxql.ParseQuery(`SELECT count(value) FROM cpu`) if err != nil { t.Fatal(err) } e := NewQueryExecutor() e.StatementExecutor = &StatementExecutor{ ExecuteStatementFn: func(stmt influxql.Statement, ctx influxql.ExecutionContext) error { if ctx.QueryID != 1 { t.Errorf("incorrect query id: exp=1 got=%d", ctx.QueryID) } return nil }, } discardOutput(e.ExecuteQuery(q, influxql.ExecutionOptions{}, nil)) } func TestQueryExecutor_KillQuery(t *testing.T) { q, err := influxql.ParseQuery(`SELECT count(value) FROM cpu`) if err != nil { t.Fatal(err) } qid := make(chan uint64) e := NewQueryExecutor() e.StatementExecutor = &StatementExecutor{ ExecuteStatementFn: func(stmt influxql.Statement, ctx influxql.ExecutionContext) error { switch stmt.(type) { case *influxql.KillQueryStatement: return e.TaskManager.ExecuteStatement(stmt, ctx) } qid <- ctx.QueryID select { case <-ctx.InterruptCh: return influxql.ErrQueryInterrupted case <-time.After(100 * time.Millisecond): t.Error("killing the query did not close the channel after 100 milliseconds") return errUnexpected } }, } results := e.ExecuteQuery(q, influxql.ExecutionOptions{}, nil) q, err = influxql.ParseQuery(fmt.Sprintf("KILL QUERY %d", <-qid)) if err != nil { t.Fatal(err) } discardOutput(e.ExecuteQuery(q, influxql.ExecutionOptions{}, nil)) result := <-results if result.Err != influxql.ErrQueryInterrupted { t.Errorf("unexpected error: %s", result.Err) } } func TestQueryExecutor_Interrupt(t *testing.T) { q, err := influxql.ParseQuery(`SELECT count(value) FROM cpu`) if err != nil { t.Fatal(err) } e := NewQueryExecutor() e.StatementExecutor = &StatementExecutor{ ExecuteStatementFn: func(stmt influxql.Statement, ctx influxql.ExecutionContext) error { select { case <-ctx.InterruptCh: return influxql.ErrQueryInterrupted case <-time.After(100 * time.Millisecond): t.Error("killing the query did not close the channel after 100 milliseconds") return errUnexpected } }, } closing := make(chan struct{}) results := e.ExecuteQuery(q, influxql.ExecutionOptions{}, closing) close(closing) result := <-results if result.Err != influxql.ErrQueryInterrupted { t.Errorf("unexpected error: %s", result.Err) } } func TestQueryExecutor_Abort(t *testing.T) { q, err := influxql.ParseQuery(`SELECT count(value) FROM cpu`) if err != nil { t.Fatal(err) } ch1 := make(chan struct{}) ch2 := make(chan struct{}) e := NewQueryExecutor() e.StatementExecutor = &StatementExecutor{ ExecuteStatementFn: func(stmt influxql.Statement, ctx influxql.ExecutionContext) error { <-ch1 if err := ctx.Send(&influxql.Result{Err: errUnexpected}); err != influxql.ErrQueryAborted { t.Errorf("unexpected error: %v", err) } close(ch2) return nil }, } done := make(chan struct{}) close(done) results := e.ExecuteQuery(q, influxql.ExecutionOptions{AbortCh: done}, nil) close(ch1) <-ch2 discardOutput(results) } func TestQueryExecutor_ShowQueries(t *testing.T) { e := NewQueryExecutor() e.StatementExecutor = &StatementExecutor{ ExecuteStatementFn: func(stmt influxql.Statement, ctx influxql.ExecutionContext) error { switch stmt.(type) { case *influxql.ShowQueriesStatement: return e.TaskManager.ExecuteStatement(stmt, ctx) } t.Errorf("unexpected statement: %s", stmt) return errUnexpected }, } q, err := influxql.ParseQuery(`SHOW QUERIES`) if err != nil { t.Fatal(err) } results := e.ExecuteQuery(q, influxql.ExecutionOptions{}, nil) result := <-results if len(result.Series) != 1 { t.Errorf("expected %d rows, got %d", 1, len(result.Series)) } if result.Err != nil { t.Errorf("unexpected error: %s", result.Err) } } func TestQueryExecutor_Limit_Timeout(t *testing.T) { q, err := influxql.ParseQuery(`SELECT count(value) FROM cpu`) if err != nil { t.Fatal(err) } e := NewQueryExecutor() e.StatementExecutor = &StatementExecutor{ ExecuteStatementFn: func(stmt influxql.Statement, ctx influxql.ExecutionContext) error { select { case <-ctx.InterruptCh: return influxql.ErrQueryInterrupted case <-time.After(time.Second): t.Errorf("timeout has not killed the query") return errUnexpected } }, } e.TaskManager.QueryTimeout = time.Nanosecond results := e.ExecuteQuery(q, influxql.ExecutionOptions{}, nil) result := <-results if result.Err == nil || !strings.Contains(result.Err.Error(), "query-timeout") { t.Errorf("unexpected error: %s", result.Err) } } func TestQueryExecutor_Limit_ConcurrentQueries(t *testing.T) { q, err := influxql.ParseQuery(`SELECT count(value) FROM cpu`) if err != nil { t.Fatal(err) } qid := make(chan uint64) e := NewQueryExecutor() e.StatementExecutor = &StatementExecutor{ ExecuteStatementFn: func(stmt influxql.Statement, ctx influxql.ExecutionContext) error { qid <- ctx.QueryID <-ctx.InterruptCh return influxql.ErrQueryInterrupted }, } e.TaskManager.MaxConcurrentQueries = 1 defer e.Close() // Start first query and wait for it to be executing. go discardOutput(e.ExecuteQuery(q, influxql.ExecutionOptions{}, nil)) <-qid // Start second query and expect for it to fail. results := e.ExecuteQuery(q, influxql.ExecutionOptions{}, nil) select { case result := <-results: if len(result.Series) != 0 { t.Errorf("expected %d rows, got %d", 0, len(result.Series)) } if result.Err == nil || !strings.Contains(result.Err.Error(), "max-concurrent-queries") { t.Errorf("unexpected error: %s", result.Err) } case <-qid: t.Errorf("unexpected statement execution for the second query") } } func TestQueryExecutor_Close(t *testing.T) { q, err := influxql.ParseQuery(`SELECT count(value) FROM cpu`) if err != nil { t.Fatal(err) } ch1 := make(chan struct{}) ch2 := make(chan struct{}) e := NewQueryExecutor() e.StatementExecutor = &StatementExecutor{ ExecuteStatementFn: func(stmt influxql.Statement, ctx influxql.ExecutionContext) error { close(ch1) <-ctx.InterruptCh return influxql.ErrQueryInterrupted }, } results := e.ExecuteQuery(q, influxql.ExecutionOptions{}, nil) go func(results <-chan *influxql.Result) { result := <-results if result.Err != influxql.ErrQueryEngineShutdown { t.Errorf("unexpected error: %s", result.Err) } close(ch2) }(results) // Wait for the statement to start executing. <-ch1 // Close the query executor. e.Close() // Check that the statement gets interrupted and finishes. select { case <-ch2: case <-time.After(100 * time.Millisecond): t.Fatal("closing the query manager did not kill the query after 100 milliseconds") } results = e.ExecuteQuery(q, influxql.ExecutionOptions{}, nil) result := <-results if len(result.Series) != 0 { t.Errorf("expected %d rows, got %d", 0, len(result.Series)) } if result.Err != influxql.ErrQueryEngineShutdown { t.Errorf("unexpected error: %s", result.Err) } } func TestQueryExecutor_Panic(t *testing.T) { q, err := influxql.ParseQuery(`SELECT count(value) FROM cpu`) if err != nil { t.Fatal(err) } e := NewQueryExecutor() e.StatementExecutor = &StatementExecutor{ ExecuteStatementFn: func(stmt influxql.Statement, ctx influxql.ExecutionContext) error { panic("test error") }, } results := e.ExecuteQuery(q, influxql.ExecutionOptions{}, nil) result := <-results if len(result.Series) != 0 { t.Errorf("expected %d rows, got %d", 0, len(result.Series)) } if result.Err == nil || result.Err.Error() != "SELECT count(value) FROM cpu [panic:test error]" { t.Errorf("unexpected error: %s", result.Err) } } func TestQueryExecutor_InvalidSource(t *testing.T) { e := NewQueryExecutor() e.StatementExecutor = &StatementExecutor{ ExecuteStatementFn: func(stmt influxql.Statement, ctx influxql.ExecutionContext) error { return errors.New("statement executed unexpectedly") }, } for i, tt := range []struct { q string err string }{ { q: `SELECT fieldKey, fieldType FROM _fieldKeys`, err: `unable to use system source '_fieldKeys': use SHOW FIELD KEYS instead`, }, { q: `SELECT "name" FROM _measurements`, err: `unable to use system source '_measurements': use SHOW MEASUREMENTS instead`, }, { q: `SELECT "key" FROM _series`, err: `unable to use system source '_series': use SHOW SERIES instead`, }, { q: `SELECT tagKey FROM _tagKeys`, err: `unable to use system source '_tagKeys': use SHOW TAG KEYS instead`, }, { q: `SELECT "key", value FROM _tags`, err: `unable to use system source '_tags': use SHOW TAG VALUES instead`, }, } { q, err := influxql.ParseQuery(tt.q) if err != nil { t.Errorf("%d. unable to parse: %s", i, tt.q) continue } results := e.ExecuteQuery(q, influxql.ExecutionOptions{}, nil) result := <-results if len(result.Series) != 0 { t.Errorf("%d. expected %d rows, got %d", 0, i, len(result.Series)) } if result.Err == nil || result.Err.Error() != tt.err { t.Errorf("%d. unexpected error: %s", i, result.Err) } } } func discardOutput(results <-chan *influxql.Result) { for range results { // Read all results and discard. } }