package service import ( "context" "fmt" "os" "strconv" "strings" "time" "github.com/jmoiron/sqlx" "github.com/pkg/errors" log "github.com/sirupsen/logrus" "github.com/c9s/bbgo/pkg/exchange/batch" "github.com/c9s/bbgo/pkg/types" ) type BacktestService struct { DB *sqlx.DB } func (s *BacktestService) SyncKLineByInterval(ctx context.Context, exchange types.Exchange, symbol string, interval types.Interval, startTime, endTime time.Time) error { log.Infof("synchronizing lastKLine for interval %s from exchange %s", interval, exchange.Name()) q := &batch.KLineBatchQuery{Exchange: exchange} klineC, errC := q.Query(ctx, symbol, interval, startTime, endTime) for kline := range klineC { if err := s.Insert(kline); err != nil { return err } } return <-errC } func (s *BacktestService) Verify(symbols []string, startTime time.Time, endTime time.Time, sourceExchange types.Exchange, verboseCnt int) error { var corruptCnt = 0 for _, symbol := range symbols { log.Infof("verifying backtesting data...") for interval := range types.SupportedIntervals { log.Infof("verifying %s %s kline data...", symbol, interval) klineC, errC := s.QueryKLinesCh(startTime, endTime, sourceExchange, []string{symbol}, []types.Interval{interval}) var emptyKLine types.KLine var prevKLine types.KLine for k := range klineC { if verboseCnt > 1 { fmt.Fprint(os.Stderr, ".") } if prevKLine != emptyKLine { if prevKLine.StartTime.Unix() == k.StartTime.Unix() { s._deleteDuplicatedKLine(k) log.Errorf("found kline data duplicated at time: %s kline: %+v , deleted it", k.StartTime, k) } else if prevKLine.StartTime.Time().Add(interval.Duration()).Unix() != k.StartTime.Time().Unix() { corruptCnt++ log.Errorf("found kline data corrupted at time: %s kline: %+v", k.StartTime, k) log.Errorf("between %d and %d", prevKLine.StartTime.Unix(), k.StartTime.Unix()) } } prevKLine = k } if verboseCnt > 1 { fmt.Fprintln(os.Stderr) } if err := <-errC; err != nil { return err } } } log.Infof("backtest verification completed") if corruptCnt > 0 { log.Errorf("found %d corruptions", corruptCnt) } else { log.Infof("found %d corruptions", corruptCnt) } return nil } func (s *BacktestService) Sync(ctx context.Context, exchange types.Exchange, symbol string, startTime time.Time, endTime time.Time, interval types.Interval) error { return s.SyncKLineByInterval(ctx, exchange, symbol, interval, startTime, endTime) } func (s *BacktestService) QueryFirstKLine(ex types.ExchangeName, symbol string, interval types.Interval) (*types.KLine, error) { return s.QueryKLine(ex, symbol, interval, "ASC", 1) } // QueryLastKLine queries the last kline from the database func (s *BacktestService) QueryLastKLine(ex types.ExchangeName, symbol string, interval types.Interval) (*types.KLine, error) { return s.QueryKLine(ex, symbol, interval, "DESC", 1) } // QueryKLine queries the klines from the database func (s *BacktestService) QueryKLine(ex types.ExchangeName, symbol string, interval types.Interval, orderBy string, limit int) (*types.KLine, error) { log.Infof("querying last kline exchange = %s AND symbol = %s AND interval = %s", ex, symbol, interval) tableName := s._targetKlineTable(ex) // make the SQL syntax IDE friendly, so that it can analyze it. sql := fmt.Sprintf("SELECT * FROM `%s` WHERE `symbol` = :symbol AND `interval` = :interval and exchange = :exchange ORDER BY end_time "+orderBy+" LIMIT "+strconv.Itoa(limit), tableName) rows, err := s.DB.NamedQuery(sql, map[string]interface{}{ "exchange": ex.String(), "interval": interval, "symbol": symbol, }) if err != nil { return nil, errors.Wrap(err, "query kline error") } if rows.Err() != nil { return nil, rows.Err() } defer rows.Close() if rows.Next() { var kline types.KLine err = rows.StructScan(&kline) return &kline, err } return nil, rows.Err() } func (s *BacktestService) QueryKLinesForward(exchange types.ExchangeName, symbol string, interval types.Interval, startTime time.Time, limit int) ([]types.KLine, error) { tableName := s._targetKlineTable(exchange) sql := "SELECT * FROM `binance_klines` WHERE `end_time` >= :start_time AND `symbol` = :symbol AND `interval` = :interval and exchange = :exchange ORDER BY end_time ASC LIMIT :limit" sql = strings.ReplaceAll(sql, "binance_klines", tableName) rows, err := s.DB.NamedQuery(sql, map[string]interface{}{ "start_time": startTime, "limit": limit, "symbol": symbol, "interval": interval, "exchange": exchange.String(), }) if err != nil { return nil, err } return s.scanRows(rows) } func (s *BacktestService) QueryKLinesBackward(exchange types.ExchangeName, symbol string, interval types.Interval, endTime time.Time, limit int) ([]types.KLine, error) { tableName := s._targetKlineTable(exchange) sql := "SELECT * FROM `binance_klines` WHERE `end_time` <= :end_time and exchange = :exchange AND `symbol` = :symbol AND `interval` = :interval ORDER BY end_time DESC LIMIT :limit" sql = strings.ReplaceAll(sql, "binance_klines", tableName) sql = "SELECT t.* FROM (" + sql + ") AS t ORDER BY t.end_time ASC" rows, err := s.DB.NamedQuery(sql, map[string]interface{}{ "limit": limit, "end_time": endTime, "symbol": symbol, "interval": interval, "exchange": exchange.String(), }) if err != nil { return nil, err } return s.scanRows(rows) } func (s *BacktestService) QueryKLinesCh(since, until time.Time, exchange types.Exchange, symbols []string, intervals []types.Interval) (chan types.KLine, chan error) { if len(symbols) == 0 { return returnError(errors.Errorf("symbols is empty when querying kline, plesae check your strategy setting. ")) } tableName := s._targetKlineTable(exchange.Name()) sql := "SELECT * FROM `binance_klines` WHERE `end_time` BETWEEN :since AND :until AND `symbol` IN (:symbols) AND `interval` IN (:intervals) and exchange = :exchange ORDER BY end_time ASC" sql = strings.ReplaceAll(sql, "binance_klines", tableName) sql, args, err := sqlx.Named(sql, map[string]interface{}{ "since": since, "until": until, "symbols": symbols, "intervals": types.IntervalSlice(intervals), "exchange": exchange.Name().String(), }) sql, args, err = sqlx.In(sql, args...) if err != nil { return returnError(err) } sql = s.DB.Rebind(sql) rows, err := s.DB.Queryx(sql, args...) if err != nil { return returnError(err) } return s.scanRowsCh(rows) } func returnError(err error) (chan types.KLine, chan error) { ch := make(chan types.KLine, 0) close(ch) log.WithError(err).Error("backtest query error") errC := make(chan error, 1) // avoid blocking go func() { errC <- err close(errC) }() return ch, errC } // scanRowsCh scan rows into channel func (s *BacktestService) scanRowsCh(rows *sqlx.Rows) (chan types.KLine, chan error) { ch := make(chan types.KLine, 500) errC := make(chan error, 1) go func() { defer close(errC) defer close(ch) defer rows.Close() for rows.Next() { var kline types.KLine if err := rows.StructScan(&kline); err != nil { errC <- err return } ch <- kline } if err := rows.Err(); err != nil { errC <- err return } }() return ch, errC } func (s *BacktestService) scanRows(rows *sqlx.Rows) (klines []types.KLine, err error) { for rows.Next() { var kline types.KLine if err := rows.StructScan(&kline); err != nil { return nil, err } klines = append(klines, kline) } return klines, rows.Err() } func (s *BacktestService) _targetKlineTable(exchangeName types.ExchangeName) string { switch exchangeName { case types.ExchangeBinance: return "binance_klines" case types.ExchangeFTX: return "ftx_klines" case types.ExchangeMax: return "max_klines" case types.ExchangeOKEx: return "okex_klines" case types.ExchangeKucoin: return "kucoin_klines" default: return "klines" } } func (s *BacktestService) Insert(kline types.KLine) error { if len(kline.Exchange) == 0 { return errors.New("kline.Exchange field should not be empty") } tableName := s._targetKlineTable(kline.Exchange) sql := fmt.Sprintf("INSERT INTO `%s` (`exchange`, `start_time`, `end_time`, `symbol`, `interval`, `open`, `high`, `low`, `close`, `closed`, `volume`, `quote_volume`, `taker_buy_base_volume`, `taker_buy_quote_volume`)"+ "VALUES (:exchange, :start_time, :end_time, :symbol, :interval, :open, :high, :low, :close, :closed, :volume, :quote_volume, :taker_buy_base_volume, :taker_buy_quote_volume)", tableName) _, err := s.DB.NamedExec(sql, kline) return err } func (s *BacktestService) _deleteDuplicatedKLine(k types.KLine) error { if len(k.Exchange) == 0 { return errors.New("kline.Exchange field should not be empty") } tableName := s._targetKlineTable(k.Exchange) sql := fmt.Sprintf("DELETE FROM `%s` WHERE gid = :gid ", tableName) _, err := s.DB.NamedExec(sql, k) return err } func (s *BacktestService) SyncExist(ctx context.Context, exchange types.Exchange, symbol string, fromTime time.Time, endTime time.Time, interval types.Interval) error { klineC, errC := s.QueryKLinesCh(fromTime, endTime, exchange, []string{symbol}, []types.Interval{interval}) nowStartTime := fromTime for k := range klineC { if nowStartTime.Unix() < k.StartTime.Unix() { log.Infof("syncing %s interval %s syncing %s ~ %s ", symbol, interval, nowStartTime, k.EndTime) if err := s.Sync(ctx, exchange, symbol, nowStartTime, k.EndTime.Time().Add(-1*interval.Duration()), interval); err != nil { log.WithError(err).Errorf("sync error") } } nowStartTime = k.StartTime.Time().Add(interval.Duration()) } if nowStartTime.Unix() < endTime.Unix() && nowStartTime.Unix() < time.Now().Unix() { if err := s.Sync(ctx, exchange, symbol, nowStartTime, endTime, interval); err != nil { log.WithError(err).Errorf("sync error") } } if err := <-errC; err != nil { return err } return nil }