class MACDSignal(CtaSignal): """""" def __init__(self, fast_window: int, slow_window: int, signal_period: int, period: int = 30): """""" super().__init__() self.fast_window = fast_window self.slow_window = slow_window self.signal_period = signal_period self.period = period self.bg = BarGenerator(self.on_bar, period, self.on_n_min_bar) self.am = ArrayManager( size=max(self.fast_window, self.slow_window, self.signal_period) + 50) logger.info( f"fast_window, slow_window, signal_period, period=" f"{self.fast_window, self.slow_window, self.signal_period, self.period}" ) def on_tick(self, tick: TickData): """ Callback of new tick data update. """ self.bg.update_tick(tick) def on_bar(self, bar: BarData): """ Callback of new bar data update. """ self.bg.update_bar(bar) def on_n_min_bar(self, bar: BarData): """""" self.am.update_bar(bar) if not self.am.inited: self.set_signal_pos(0) _, _, macd = self.am.macd(self.fast_window, self.slow_window, self.signal_period) if macd < -5: self.set_signal_pos(1) elif macd > 5: self.set_signal_pos(-1) else: # self.set_signal_pos(0) pass
def generate_3mindata(self, am:ArrayManager, bar:BarData): offset = -self.offset offset_m = int(offset / 2) calc_nums = np.array(self.ma_tag[-offset:-1]) # var_val = np.var(calc_nums) std_val = np.std(calc_nums) std_val2 = np.std(np.array(self.ma_tag[-10:-1])) std_val3 = np.std(np.array(am.range[-30:-10])) ma = self.ma_tag[-1] mean_val = np.mean(calc_nums) mean_val2 = np.mean(np.array(self.ma_tag[-5:-1])) mean_val3 = np.mean(np.array(self.ma_tag[-20:-1])) mean_val4 = np.mean(np.array(self.ma_tag[-30:-5])) kdj_val = am.kdj() deg1 = calc_regress_deg(am.close[offset : offset_m], False) deg2 = calc_regress_deg(am.close[offset_m :], False) deg3 = calc_regress_deg(am.close[-10 :], False) deg_full = calc_regress_deg(am.close[offset :], False) wave = self.wave(am.close[-30:]) wave_r_sum = np.sum(wave["range"]) macd=am.macd(20,40, 16) calc_data = (dict( kdj=[round(kdj_val["k"][-1],2),round(kdj_val["d"][-1],2),round(kdj_val["j"][-1],2)], cci_20=am.cci(20),rsi=am.rsi(20),adx=am.adx(20),boll=am.boll(20, 3.4), macd=[round(macd[0],2),round(macd[1],2),round(macd[2],2)], deg40_20=round(deg1,2), deg20_0=round(deg2,2), deg20_10=round(calc_regress_deg(am.close[-20:-10], False),2), deg10_0=round(deg3,2), deg30_15=round(calc_regress_deg(am.close[-30:-15], False),2), deg15_0=round(calc_regress_deg(am.close[-15:], False),2),deg_f=round(deg_full,2), atr=round(am.atr(10, length=15), 3), tr=round(am.atr(1, length=2), 3),atr_40=round(am.atr(40, length=42), 3), time=bar.datetime, price=bar.close_price, ma=round(ma, 2), std_40=round(std_val, 2),mean40=round(mean_val,2), mean_std=np.mean(self.std_range.data[-5:]), std_10=round(std_val2,2), mean30_10=round(mean_val4,2), mean10=round(mean_val2,2), vol=am.volume[-1], std_range=self.std_range.data[-1:-5:-1], range=am.range[-1:-5:-1].tolist(), range_sum=np.sum(am.range[-5:]), pattern=list(map(lambda x: KLINE_PATTERN_CHINESE[x], self.pattern_record.keys())), ma120t=self.ma120_track, ma120t_list=self.ma120_track_list[-1:-10:-1], ma120t_sort=sorted(self.ma120_track_list[-20:-1], key=abs), ma120t_sum=np.sum(self.ma120_track_list[-20:-1] + [self.ma120_track]), ma120t_mean=np.mean(self.ma120_track_list[-20:-1] + [self.ma120_track]), ma120t_std=np.std(self.ma120_track_list[-20:-1] + [self.ma120_track]), ma_info=list(map(lambda x:x["std"], self.ma_info[-1:])), wave_cnt=len(wave), wave_r_sum=wave_r_sum, atr_mean=np.mean(am.atr(20, array=True,length=240)[-200:]) )) return calc_data
def generate_data(self, am: ArrayManager, bar: BarData): offset = -self.offset offset_m = int(offset / 2) std_val3 = np.std(np.array(am.range[-30:-10])) kdj_val = am.kdj() has_kdj_recore = False k = kdj_val["k"] d = kdj_val["d"] j = kdj_val["j"] if (k[-1] > 75 and d[-1] > 75 and j[-1] > 75) or \ (k[-1] < 25 and d[-1] < 25 and j[-1] < 75): if (j[-2] < k[-2] or j[-2] < d[-2]) and (j[-1] > k[-1] and j[-1] > d[-1]) \ or \ (j[-2] > k[-2] or j[-2] > d[-2]) and (j[-1] < k[-1] and j[-1] < d[-1]): has_kdj_recore = True t = bar.datetime self.kdj_record.append( (t.strftime("%H:%M:%S"), round(k[-1], 3), round(d[-1], 3), round(j[-1], 3))) deg1 = calc_regress_deg(am.close[offset:offset_m], False) deg2 = calc_regress_deg(am.close[offset_m:], False) deg3 = calc_regress_deg(am.close[-10:], False) deg_full = calc_regress_deg(am.close[offset:], False) macd = am.macd(20, 40, 16) calc_data = (dict( kdj=[ round(kdj_val["k"][-1], 2), round(kdj_val["d"][-1], 2), round(kdj_val["j"][-1], 2) ], cci_20=am.cci(20), rsi=am.rsi(20), adx=am.adx(20), boll=am.boll(20, 3.4), macd=[round(macd[0], 2), round(macd[1], 2), round(macd[2], 2)], deg40_20=round(deg1, 2), deg20_0=round(deg2, 2), deg20_10=round(calc_regress_deg(am.close[-20:-10], False), 2), deg30_15=round(calc_regress_deg(am.close[-30:-15], False), 2), deg15_0=round(calc_regress_deg(am.close[-15:], False), 2), deg_f=round(deg_full, 2), deg30_10=round(calc_regress_deg(am.close[-30:-10], False), 2), deg10_0=round(deg3, 2), atr=round(am.atr(10, length=15), 3), tr=round(am.atr(1, length=2), 3), atr_40=round(am.atr(40, length=42), 3), time=bar.datetime, price=bar.close_price, mean_std=np.mean(self.std_range.data[-5:]), vol=am.volume[-1], std_range=self.std_range.data[-1:-5:-1], range=am.range[-1:-5:-1].tolist(), range_sum=np.sum(am.range[-5:]), pattern=list( map(lambda x: KLINE_PATTERN_CHINESE[x], self.pattern_record.keys())), atr_mean=np.mean(am.atr(20, array=True, length=240)[-200:]), )) if self.ma_info.info.index.size >= 31: ma5 = self.ma_info.info[5][-31:] x = AnalyseWave(ma5) calc_data["ma5_info"] = x.optimize ma10 = self.ma_info.info[10][-31:] x = AnalyseWave(ma10) calc_data["ma10_info"] = x.optimize return calc_data
class MaLevelTrackStrategy(CtaTemplate): author = "用Python的交易员" ma_level = [5, 10, 20, 30, 120] ma_tag = [] bd = [] fast_ma0 = 0.0 fast_ma1 = 0.0 slow_ma0 = 0.0 slow_ma1 = 0.0 request_order = [] bar_identify = [] parameters = ["ma_level"] variables = ["fast_ma0", "fast_ma1", "slow_ma0", "slow_ma1"] def __init__(self, cta_engine, strategy_name, vt_symbol, setting): """""" super(MaLevelTrackStrategy, self).__init__(cta_engine, strategy_name, vt_symbol, setting) self.bg = BarGenerator(self.on_bar, 15, self.on_1min_bar) self.am = ArrayManager(400) self.am3 = ArrayManager(150) self.bg3 = BarGenerator(self.on_bar, 3, self.on_3min_bar) self.am5 = ArrayManager(120) self.bg5 = BarGenerator(self.on_bar, 5, self.on_5min_bar) self.order_data = None self.positions = Position(self) self.std_range = IntervalGen(np.std, 5) self.std_range3 = IntervalGen(np.std, 5) self.std_range5 = IntervalGen(np.std, 5) self.pattern_record = PatternRecord() # self.pattern_record.set_expiry([KlinePattern.CDLEVENINGSTAR], 3) self.pattern_record.set_expiry(list(KlinePattern), 1) five_min_open_5 = partial(self.reverse_shape_strategy, setting={ "atr": 10, "atr_valve": 0.8, "deg1": (10, 5), "deg2": 5 }) self.open_strategy = { "1": [self.reverse_shape_strategy], "5": [five_min_open_5], } self.offset = 40 self.ma120_track = None self.ma120_track_list = [] def on_init(self): """ Callback when strategy is inited. """ self.write_log("策略初始化") self.load_bar(10) def on_start(self): """ Callback when strategy is started. """ self.write_log("策略启动") self.put_event() def on_stop(self): """ Callback when strategy is stopped. """ self.write_log("策略停止") self.put_event() def on_tick(self, tick: TickData): """ Callback of new tick data update. """ self.bg.update_tick(tick) self.bg3.update_tick(tick) self.bg5.update_tick(tick) def on_3min_bar(self, bar: BarData): self.am3.update_bar(bar) self.std_range3.update(self.am3.range[-1]) if not self.am.inited or not self.trading: return pattern = self.am3.pattern( [KlinePattern.CDLEVENINGSTAR, KlinePattern.CDL2CROWS]) if len(pattern) > 0: print(pattern) self.pattern_record.add_pattern(pattern) # deg = calc_regress_deg(self.am3.close[-20:]) def wave(self, data, window=0.0002): if len(data) <= 0: return # r = array[::-1] result = {"value": [], "range": [], "pos": [], "length": []} r = data l = len(data) - 1 now = r[0] # v_list.append(now) # p_list.append(0) pos = 1 vol = 0 u_tag = None d_tag = None end_tag = None start_pos = 0 while pos < l: if math.isnan(now): now = r[pos] pos += 1 continue else: start_pos = pos - 1 break while pos < l: if now < r[pos]: u_tag = pos if d_tag: diff = r[start_pos] - r[d_tag] if abs(diff / r[start_pos]) > window and d_tag - start_pos > 1: end_tag = d_tag elif now > r[pos]: d_tag = pos if u_tag: diff = r[start_pos] - r[u_tag] if abs(diff / r[start_pos]) > window and d_tag - start_pos > 1: end_tag = u_tag if end_tag is not None: result["range"].append(r[end_tag] / r[start_pos] - 1) result["length"].append(end_tag - start_pos) start_pos = end_tag result["value"].append(r[end_tag]) result["pos"].append(end_tag) end_tag = None vol += r[pos] - now now = r[pos] pos += 1 return pd.DataFrame(result) def mode_identify(self, bar: BarData): self.bar_identify = [] hl_scale = round(bar.high_price / bar.low_price - 1, 4) if hl_scale > 0.001: diff = bar.high_price - bar.low_price diff_up = bar.low_price + diff / 2 * 1.20 diff_down = bar.low_price + diff / 2 * 0.80 close = bar.close_price if bar.open_price < diff_up and bar.open_price > diff_down and \ bar.close_price < diff_up and bar.close_price > diff_down: if bar.close_price > bar.open_price: print("绿十字星", bar.datetime, bar.high_price, bar.low_price, diff, diff_up, diff_down, bar.open_price, bar.close_price) else: print("红十字星", bar.datetime, bar.high_price, bar.low_price, diff, diff_up, diff_down, bar.open_price, bar.close_price) def on_5min_bar(self, bar: BarData): self.std_range5.update(self.am5.range[-1]) self.am5.update_bar(bar) if not self.am.inited or not self.trading: return self.on_strategy(self.am5, bar, self.open_strategy["5"]) # pattern_list = [KlinePattern.CDLEVENINGSTAR, KlinePattern.CDL2CROWS, KlinePattern.CDLCONCEALBABYSWALL, KlinePattern.CDLEVENINGDOJISTAR] # pattern = self.am5.pattern(list(KlinePattern)) # if len(pattern) > 0: # print(list(map(lambda x: (KLINE_PATTERN_CHINESE[x[0]],x[1]), pattern))) # self.pattern_record.add_pattern(pattern) # deg_full = calc_regress_deg(self.am.close[-40 :], False) # print("deg:",deg_full) # self.pattern_record.update() def open_v3(self, am: ArrayManager, bar: BarData): std_val2 = np.std(np.array(self.ma_tag[-10:-1])) mean_val2 = np.mean(np.array(self.ma_tag[-10:-1])) mean = np.mean(np.array(self.ma_tag[-30:-10])) if std_val2 < 0.2: if mean_val2 > 3: if mean_val2 >= (mean + 1): return self.buy(bar.close_price, 1, type=OrderType.MARKET) elif mean_val2 < 2: if mean_val2 <= (mean - 1): return self.short(bar.close_price, 1, type=OrderType.MARKET) def open_v1(self, am: ArrayManager, bar: BarData): offset = -40 offset_m = int(offset / 2) calc_nums = np.array(self.ma_tag[-offset:-1]) mean_val = np.mean(calc_nums) # var_val = np.var(calc_nums) std_val = np.std(calc_nums) if std_val < 1 and mean_val < 2 and self.ma_tag[-1] >= (mean_val + 2): return self.buy(bar.close_price, 1, type=OrderType.MARKET) elif std_val < 1 and mean_val > 3 and self.ma_tag[-1] <= (mean_val - 2): return self.short(bar.close_price, 1, type=OrderType.MARKET) def open_v2(self, am: ArrayManager, bar: BarData): std_val2 = np.std(np.array(self.ma_tag[-10:-1])) mean_val2 = np.mean(np.array(self.ma_tag[-10:-1])) mean = np.mean(np.array(self.ma_tag[-30:-10])) if std_val2 < 0.2: if mean_val2 > 2.5: if mean_val2 >= (mean + 1): return self.buy(bar.close_price, 1, type=OrderType.MARKET) elif mean_val2 < 2.5: if mean_val2 <= (mean - 1): return self.short(bar.close_price, 1, type=OrderType.MARKET) def open2(self, am: ArrayManager, bar: BarData, calc_data): deg = calc_data["deg20"] ma = self.ma_tag[-1] if deg > 0.5 and ma > 3 and self.am5.range[-1] > -0.002: return self.buy(bar.close_price, 1, type=OrderType.MARKET) elif deg < -0.5 and ma < 2 and self.am5.range[-1] < 0.002: return self.short(bar.close_price, 1, type=OrderType.MARKET) def open1(self, am: ArrayManager, bar: BarData, calc_data): mean = calc_data["mean30_10"] mean_val2 = calc_data["mean10"] # if std_val2 < 0.2: if mean_val2 > 3.5 and mean_val2 >= (mean + 2): return self.buy(bar.close_price, 1, type=OrderType.MARKET) elif mean_val2 < 1.5 and mean_val2 <= (mean - 2): return self.short(bar.close_price, 1, type=OrderType.MARKET) # v形反转捕获 def reverse_shape_strategy(self, am: ArrayManager, bar: BarData, calc_data, setting={ "atr": 40, "atr_valve": 0.8, "deg1": (40, 20), "deg2": (20, 0), }): deg1 = calc_data["deg40_20"] deg2 = calc_data["deg20_0"] kdj = calc_data["kdj"] atr = self.am.atr(40) if atr < 0.08: return if deg1 > 0 and deg2 > 0 or \ deg1 < 0 and deg2 < 0: return if not (abs(deg1) > 0.15 and abs(deg2) > 0.1 and (abs(deg1) + abs(deg2)) > 0.3): return close = am.close[-40:] min_val = np.min(close) max_val = np.max(close) mid_val = max_val if deg1 > 0 else min_val mid_pos = np.where(close == mid_val)[0][0] if mid_pos < 10 or mid_pos > 30: return start_val = np.min(close[:mid_pos]) if deg1 > 0 else np.max( close[:mid_pos]) start_pos = np.where(close == start_val)[0][0] l = mid_pos - start_pos # pos2 = np.where(close == min_val)[0][0] x_fit = reg_util.regress_y_polynomial(close[:mid_pos], zoom=True) deg1_remake = calc_regress_deg(x_fit[:abs(mid_pos)], False) y_fit = reg_util.regress_y_polynomial(close[mid_pos:], zoom=True) deg2_remake = calc_regress_deg(y_fit[:abs(mid_pos)], False) print(start_pos, mid_pos, deg1, deg2, deg1_remake, deg2_remake, l, start_val, mid_val) if deg2 < 0: if kdj[0] < 20 and kdj[1] < 10 and kdj[2] < 10: # if kdj[2] < 10: return self.short(bar.close_price, 1, type=OrderType.MARKET) else: if kdj[0] > 80 and kdj[1] > 90 and kdj[2] > 90: # if kdj[2] > 90: return self.buy(bar.close_price, 1, type=OrderType.MARKET) # print("找到大v形:", deg1, deg2 ) def open5(self, am: ArrayManager, bar: BarData, calc_data): ma = self.ma_tag[-1] mean = calc_data["mean30_10"] atr = self.am.atr(10, array=True, length=20) tr = self.am.atr(1, array=True, length=11) # self.ma120_track ma120 = self.am.sma(120) # if std_val2 < 0.2: mean_std = calc_data["mean_std"] if mean_std < 0.8 and tr[-1] > 0.1 and tr[-1] / tr[-10] > 3 and tr[ -1] / atr[-1] >= 1.7 and tr[-10] / atr[-10] < 1: if np.sum(self.am.range[-10:]) > 0 and self.ma120_track > 0: return self.buy(bar.close_price, 1, type=OrderType.MARKET) elif self.ma120_track < 0: return self.short(bar.close_price, 1, type=OrderType.MARKET) def open_kline1(self, am: ArrayManager, bar: BarData, calc_data): if KlinePattern.CDLEVENINGSTAR not in self.pattern_record: return # if std_val2 < 0.2: deg = calc_regress_deg(self.am.close[-5:], False) print("kline_strategy", deg) if deg < -0.1: return self.short(bar.close_price, 1, type=OrderType.MARKET) def generate_data(self, bar: BarData): offset = -self.offset offset_m = int(offset / 2) calc_nums = np.array(self.ma_tag[-offset:-1]) # var_val = np.var(calc_nums) std_val = np.std(calc_nums) std_val2 = np.std(np.array(self.ma_tag[-10:-1])) std_val3 = np.std(np.array(self.am.range[-30:-10])) ma = self.ma_tag[-1] mean_val = np.mean(calc_nums) mean_val2 = np.mean(np.array(self.ma_tag[-5:-1])) mean_val3 = np.mean(np.array(self.ma_tag[-20:-1])) mean_val4 = np.mean(np.array(self.ma_tag[-30:-5])) kdj_val = self.am.kdj() deg1 = calc_regress_deg(self.am.close[offset:offset_m], False) deg2 = calc_regress_deg(self.am.close[offset_m:], False) deg3 = calc_regress_deg(self.am.close[-10:], False) deg_full = calc_regress_deg(self.am.close[offset:], False) wave = self.wave(self.am.close[-30:]) wave_r_sum = np.sum(wave["range"]) macd = self.am.macd(20, 40, 16) calc_data = (dict( kdj=[ round(kdj_val["k"][-1], 2), round(kdj_val["d"][-1], 2), round(kdj_val["j"][-1], 2) ], cci_20=self.am.cci(20), rsi=self.am.rsi(20), adx=self.am.adx(20), boll=self.am.boll(20, 3.4), macd=[round(macd[0], 2), round(macd[1], 2), round(macd[2], 2)], deg40_20=round(deg1, 2), deg20_0=round(deg2, 2), deg20_10=round(calc_regress_deg(self.am.close[-20:-10], False), 2), deg10_0=round(deg3, 2), deg30_15=round(calc_regress_deg(self.am.close[-30:-15], False), 2), deg15_0=round(calc_regress_deg(self.am.close[-15:], False), 2), deg_f=round(deg_full, 2), atr=round(self.am.atr(10, length=15), 3), tr=round(self.am.atr(1, length=2), 3), atr_40=round(self.am.atr(40, length=42), 3), time=bar.datetime, price=bar.close_price, ma=round(ma, 2), std_40=round(std_val, 2), mean40=round(mean_val, 2), mean_std=np.mean(self.std_range.data[-5:]), std_10=round(std_val2, 2), mean30_10=round(mean_val4, 2), mean10=round(mean_val2, 2), vol=self.am.volume[-1], std_range=self.std_range.data[-1:-5:-1], range=self.am.range[-1:-5:-1].tolist(), range_sum=np.sum(self.am.range[-5:]), pattern=list( map(lambda x: KLINE_PATTERN_CHINESE[x], self.pattern_record.keys())), ma120t=self.ma120_track, ma120t_list=self.ma120_track_list[-1:-10:-1], ma120t_sort=sorted(self.ma120_track_list[-20:-1], key=abs), ma120t_sum=np.sum(self.ma120_track_list[-20:-1] + [self.ma120_track]), ma120t_mean=np.mean(self.ma120_track_list[-20:-1] + [self.ma120_track]), ma120t_std=np.std(self.ma120_track_list[-20:-1] + [self.ma120_track]), wave_cnt=len(wave), wave_r_sum=wave_r_sum, atr_mean=np.mean(self.am.atr(20, array=True, length=240)[-200:]))) return calc_data def on_strategy(self, am: ArrayManager, bar: BarData, strategy_list): calc_data = self.generate_data(bar) order_id = None if self.pos == 0: for open_strategy in strategy_list: if order_id is not None: break order_id = open_strategy(am, bar, calc_data) else: order_id = self.positions.on_strategy(bar, calc_data) if order_id is not None: offset = -self.offset offset_m = int(offset / 2) self.tracker["trade_info"].append( (self.am.time_array[offset], self.am.time_array[offset_m], bar.datetime, calc_data["deg40_20"], calc_data["deg20_0"])) self.request_order.extend(order_id) if self.tracker is not None: self.tracker["ma_tag_ls"].append(calc_data) def on_1min_bar(self, bar: BarData): self.am.update_bar(bar) am = self.am max_len = self.ma_level[-1] + 20 data = self.am.close[-max_len:-1] ma_lvl = [] for i in self.ma_level: ma = self.am.sma(i, True)[-1] ma_lvl.append(ma) l = len(ma_lvl) ma_lvl_tag = [] now = bar.close_price direction = 1 if now > ma_lvl[0] else 0 ma_lvl_tag.append(direction) for i in range(l - 1): val = 1 if ma_lvl[i] > ma_lvl[i + 1] else 0 ma_lvl_tag.append(val) bincount_val = np.bincount(np.array(ma_lvl_tag)) tag_val = 0 if len(bincount_val) == 2: tag_val = bincount_val[1] if len(self.ma_tag) < 200: self.ma_tag.append(tag_val) else: self.ma_tag[:-1] = self.ma_tag[1:] self.ma_tag[-1] = tag_val if self.tracker is not None: self.tracker["bar_data"].append(bar) self.std_range.update(self.am.range[-1]) ma120 = self.am.sma(120) if bar.close_price >= ma120: if self.ma120_track is None: self.ma120_track = 1 elif self.ma120_track > 0: self.ma120_track += 1 else: self.ma120_track_list.append(self.ma120_track) self.ma120_track = 1 elif bar.close_price < ma120: if self.ma120_track is None: self.ma120_track = -1 elif self.ma120_track < 0: self.ma120_track -= 1 else: self.ma120_track_list.append(self.ma120_track) self.ma120_track = -1 if not am.inited or not self.trading: return self.on_strategy(am, bar, self.open_strategy["1"]) # median_val = np.median(calc_nums) self.put_event() def on_bar(self, bar: BarData): """ Callback of new bar data update. """ self.bg3.update_bar(bar) self.bg5.update_bar(bar) self.bg.update_bar(bar) # def init_order_data(self): # self.order_data = np.array([]) def on_order(self, order: OrderData): """ Callback of new order data update. """ print("{}产生了{},价格为{},笔数为{},交易{},pos={}".format( order.datetime.strftime("%m/%d %H:%M:%S"), order.offset.value + order.direction.value, order.price, order.volume, order.status.value, self.pos)) if order.vt_orderid in self.request_order: self.positions.on_order(order) if order.status == Status.ALLTRADED or order.status == Status.CANCELLED or order.status == Status.REJECTED: self.request_order.remove(order.vt_orderid) # if order.status == Status.ALLTRADED or order.status == Status.PARTTRADED: # if order.direction == Direction.LONG: # if self.positions.volumn == 0: # self.positions.close_price = round(order.price * 0.995) # self.positions.volumn += order.volume # elif order.direction == Direction.SHORT: # self.positions.volumn -= order.volume # elif order.direction == Direction.NET: # self.positions.volumn = order.volume def on_trade(self, trade: TradeData): """ Callback of new trade data update. """ self.put_event() def on_stop_order(self, stop_order: StopOrder): """ Callback of stop order update. """ pass
def generate_data(self, am:ArrayManager, bar:BarData): offset = -self.offset offset_m = int(offset / 2) calc_nums = np.array(self.ma_tag[-offset:-1]) # var_val = np.var(calc_nums) std_val = np.std(calc_nums) std_val2 = np.std(np.array(self.ma_tag[-10:-1])) std_val3 = np.std(np.array(am.range[-30:-10])) ma = self.ma_tag[-1] mean_val = np.mean(calc_nums) mean_val2 = np.mean(np.array(self.ma_tag[-5:-1])) mean_val3 = np.mean(np.array(self.ma_tag[-20:-1])) mean_val4 = np.mean(np.array(self.ma_tag[-30:-5])) kdj_val = am.kdj() has_kdj_recore = False k = kdj_val["k"] d = kdj_val["d"] j = kdj_val["j"] if (k[-1] > 75 and d[-1] > 75 and j[-1] > 75) or \ (k[-1] < 25 and d[-1] < 25 and j[-1] < 75): if (j[-2] < k[-2] or j[-2] < d[-2]) and (j[-1] > k[-1] and j[-1] > d[-1]) \ or \ (j[-2] > k[-2] or j[-2] > d[-2]) and (j[-1] < k[-1] and j[-1] < d[-1]): has_kdj_recore = True t = local_to_eastern(bar.datetime.timestamp()) self.kdj_record.append((t.strftime("%H:%M:%S"), round(k[-1], 3), round(d[-1], 3), round(j[-1], 3))) deg1 = calc_regress_deg(am.close[offset : offset_m], False) deg2 = calc_regress_deg(am.close[offset_m :], False) deg3 = calc_regress_deg(am.close[-10 :], False) deg_full = calc_regress_deg(am.close[offset :], False) wave = self.wave(am.close[-30:]) wave_r_sum = np.sum(wave["range"]) macd=am.macd(20,40, 16) calc_data = (dict( ma_info=self.ma_info[-1:], kdj=[round(kdj_val["k"][-1],2),round(kdj_val["d"][-1],2),round(kdj_val["j"][-1],2)], cci_20=am.cci(20),rsi=am.rsi(20),adx=am.adx(20),boll=am.boll(20, 3.4), macd=[round(macd[0],2),round(macd[1],2),round(macd[2],2)], deg40_20=round(deg1,2), deg20_0=round(deg2,2), deg20_10=round(calc_regress_deg(am.close[-20:-10], False),2), deg30_10=round(calc_regress_deg(am.close[-30:-10], False),2),deg10_0=round(deg3,2), deg30_15=round(calc_regress_deg(am.close[-30:-15], False),2), deg15_0=round(calc_regress_deg(am.close[-15:], False),2),deg_f=round(deg_full,2), atr=round(am.atr(10, length=15), 3), tr=round(am.atr(1, length=2), 3),atr_40=round(am.atr(40, length=42), 3), time=bar.datetime, price=bar.close_price, ma=round(ma, 2), std_40=round(std_val, 2),mean40=round(mean_val,2), mean_std=np.mean(self.std_range.data[-5:]), std_10=round(std_val2,2), mean30_10=round(mean_val4,2), mean10=round(mean_val2,2), vol=am.volume[-1], std_range=self.std_range.data[-1:-5:-1], range=am.range[-1:-5:-1].tolist(), range_sum=np.sum(am.range[-5:]), pattern=list(map(lambda x: KLINE_PATTERN_CHINESE[x], self.pattern_record.keys())), ma120t=self.ma120_track, ma120t_list=self.ma120_track_list[-1:-10:-1], ma120t_sort=sorted(self.ma120_track_list[-20:-1], key=abs), ma120t_sum=np.sum(self.ma120_track_list[-20:-1] + [self.ma120_track]), ma120t_mean=np.mean(self.ma120_track_list[-20:-1] + [self.ma120_track]), ma120t_std=np.std(self.ma120_track_list[-20:-1] + [self.ma120_track]), wave_cnt=len(wave), wave_r_sum=wave_r_sum, atr_mean=np.mean(am.atr(20, array=True,length=240)[-200:]), kdj_record=self.kdj_record[-10:], )) if self.ma_info[-1]["ma5"] <= 0.16: calc_data["kdj_key"] = True return calc_data
class MacdRsibollDcMinuteStrategy(CtaTemplate): """ 策略逻辑: 一、、过虑信号 (小时周期) 1、使用macd 快慢线交叉来判断多空大方向。 2、使用rsiboll来判断信号强弱 二、开单信号 (分钟周期) 1、使用布林上下轨作为开单条件 三、止损 1、使用固定止损 2、dc 移动止损 3、布林宽度比例 三个止损相结合的方式 """ author = "yunya" max_window = 45 min_window = 15 open_window = 5 fast_macd = 12 slow_macd = 26 signal_macd = 9 macd_trend_level = 1.0 rsi_length = 15 boll_length = 20 boll_dev = 2.0 dc_length = 20 atr_window = 30 trailing_tax = 2.0 risk_level = 1 exit_down = 0 exit_up = 0 macd = 0 macd_entry = 0 rsi_entry = 0 intra_trade_high = 0 intra_trade_low = 0 long_stop = 0 short_stop = 0 atr_value = 0 parameters = [ "max_window", "min_window", "open_window", "fast_macd", "slow_macd", "signal_macd", "macd_trend_level", "boll_length", "boll_dev", "rsi_length", "dc_length", "atr_window", "trailing_tax", "risk_level", ] variables = [ "exit_down", "exit_up", "macd", "macd_entry", "rsi_entry", "intra_trade_high", "intra_trade_low", "long_stop", "short_stop", "atr_value", ] def __init__( self, cta_engine: Any, strategy_name: str, vt_symbol: str, setting: dict, ): """""" super().__init__(cta_engine, strategy_name, vt_symbol, setting) self.atr_stop_array = np.zeros(10) self.bg_xhour = NewBarGenerator( on_bar=self.on_bar, window=self.max_window, on_window_bar=self.on_xhour_bar, interval=Interval.MINUTE # 由小时修改到分钟级 ) self.am_hour = ArrayManager(self.boll_length + 100) self.bg_xminute = NewBarGenerator( on_bar=self.on_bar, window=self.min_window, on_window_bar=self.on_xminute_bar ) self.am_xminute = ArrayManager(self.boll_length + 100) self.bg_open = NewBarGenerator( on_bar=self.on_bar, window=self.open_window, on_window_bar=self.on_5min_bar ) self.am_open = ArrayManager(self.dc_length * int(self.min_window / self.open_window) + 30) def on_init(self): """ Callback when strategy is inited. """ self.write_log("策略初始化。。") self.load_bar(10) self.put_event() def on_start(self): """ Callback when strategy is started. """ self.write_log("策略启动。。") self.put_event() def on_stop(self): """ Callback when strategy is stopped. """ self.write_log("策略停止。。") self.put_event() def on_tick(self, tick: TickData): """ Callback of new tick data update. """ self.bg_open.update_tick(tick) self.ask = tick.ask_price_1 # 卖一价 self.bid = tick.bid_price_1 # 买一价 self.put_event() def on_bar(self, bar: BarData): """ Callback of new bar data update. """ self.bg_xhour.update_bar(bar) self.bg_xminute.update_bar(bar) self.bg_open.update_bar(bar) def on_5min_bar(self, bar: BarData): self.cancel_all() self.am_open.update_bar(bar) if not self.am_open.inited or not self.am_xminute.inited or not self.am_hour.inited: return # self.exit_up, self.exit_down = self.am_open.donchian( self.dc_length * int(self.min_window / self.open_window)) if not self.pos: self.intra_trade_high = bar.high_price self.intra_trade_low = bar.low_price if self.macd_entry > 0 and self.rsi_entry > 0: self.buy(self.boll_up, self.trading_size, True) # print(bar.datetime, self.boll_up, self.trading_size) # print(bar.datetime, self.entry_up, self.trading_size, bar) if self.macd_entry < 0 and self.rsi_entry < 0: self.short(self.boll_down, self.trading_size, True) elif self.pos > 0: self.intra_trade_high = max(self.intra_trade_high, bar.high_price) long_high = self.intra_trade_high * \ (1 - self.trailing_tax / 100) self.long_stop = max(self.exit_down, long_high) self.sell(self.long_stop, abs(self.pos), True) elif self.pos < 0: self.intra_trade_low = min(self.intra_trade_low, bar.low_price) short_low = self.intra_trade_low * \ (1 + self.trailing_tax / 100) self.short_stop = min(self.exit_up, short_low) self.cover(short_low, abs(self.pos), True) self.put_event() def on_xminute_bar(self, bar: BarData): """ :param bar: :return: """ self.am_xminute.update_bar(bar) if not self.am_hour.inited or not self.am_xminute.inited: return rsi_array = talib.RSI(self.am_xminute.close[:-1], self.rsi_length) ema_array = talib.EMA(self.am_xminute.close, self.rsi_length) dev_array = abs(self.am_xminute.close[:-1] - ema_array[:-1]) / rsi_array rsi_up_array = rsi_array + rsi_array * dev_array rsi_dow_array = rsi_array - rsi_array * dev_array self.rsi_value = self.am_xminute.rsi(self.rsi_length, True) self.rsi_up = rsi_up_array[-1] self.rsi_dow = rsi_dow_array[-1] current_rsi_up = rsi_up_array[-1] current_rsi_down = rsi_dow_array[-1] current_rsi_value = self.rsi_value[-1] if current_rsi_value > current_rsi_up: self.rsi_entry = 1 elif current_rsi_value < current_rsi_down: self.rsi_entry = -1 else: self.rsi_entry = 0 self.boll_up, self.boll_down = self.am_xminute.boll(self.boll_length, self.boll_dev) def on_xhour_bar(self, bar: BarData): """""" am_hour = self.am_hour am_hour.update_bar(bar) if not am_hour.inited: return macd_signal, signal, hist = self.am_hour.macd( self.fast_macd, self.slow_macd, self.signal_macd ) self.macd = signal - hist if self.macd > self.macd_trend_level: self.macd_entry = 1 elif self.macd < (-self.macd_trend_level): self.macd_entry = -1 else: self.macd_entry = 0 # 动态调整仓位 if not self.pos: self.atr_value = self.am_hour.atr(self.atr_window) if self.atr_value == 0: # 保证仓位值是有效的 return # 正向合约 atr_risk = self.am_hour.atr(self.atr_window) self.trading_size = max(int(self.risk_level / atr_risk), 1) self.put_event() def on_trade(self, trade: TradeData): """ 有成交时 Callback of new trade data update. """ self.put_event() def on_order(self, order: OrderData): """ 订单更新回调 Callback of new order data update. """ self.put_event() def on_stop_order(self, stop_order: StopOrder): """ Callback of stop order update. """ self.put_event()
class LifeHunterStrategy(CtaTemplate): """""" author = "super dino" entry_window = 28 exit_window = 7 fast_period = 12 slow_period = 26 signal_period = 9 trend_level = 10 atr_window = 4 risk_level = 0.2 trailing_tax = 0.3 trading_size = 0 entry_up = 0 entry_down = 0 exit_up = 0 exit_down = 0 atr_value = 0 MACD_sign = 0 signal = 0 hist = 0 MACD_trend = 0 long_entry = 0 short_entry = 0 long_stop = 0 short_stop = 0 intra_trade_high = 0 intra_trade_low = 0 long_out = 0 short_out = 0 parameters = [ "entry_window", "exit_window", "fast_period", "slow_period", "signal_period", "trend_level", "atr_window", "risk_level", "trailing_tax" ] variables = [ "trading_size", "entry_up", "entry_down", "exit_up", "exit_down", "atr_value", "MACD_sign", "signal", "hist", "MACD_trend", "long_entry", "short_entry", "long_stop", "short_stop", "intra_trade_high", "intra_trade_low", "long_out", "short_out" ] def __init__(self, cta_engine, strategy_name, vt_symbol, setting): """""" super().__init__(cta_engine, strategy_name, vt_symbol, setting) self.bg = BarGenerator(self.on_bar, 30, self.on_30min_bar) self.am = ArrayManager() self.am30 = ArrayManager() def on_init(self): """ Callback when strategy is inited. """ self.write_log("策略初始化") self.load_bar(20) def on_start(self): """ Callback when strategy is started. """ self.write_log("策略启动") def on_stop(self): """ Callback when strategy is stopped. """ self.write_log("策略停止") def on_tick(self, tick: TickData): """ Callback of new tick data update. """ self.bg.update_tick(tick) def on_bar(self, bar: BarData): """ Callback of new bar data update. """ self.bg.update_bar(bar) self.cancel_all() self.am.update_bar(bar) if not self.am.inited or not self.am30.inited: return # No Position if not self.pos: self.atr_value = self.am.atr(self.atr_window) if self.atr_value == 0: return atr_risk = talib.ATR(1 / self.am.high, 1 / self.am.low, 1 / self.am.close, self.atr_window)[-1] self.trading_size = max(int(self.risk_level / atr_risk), 1) self.long_entry = 0 self.short_entry = 0 self.intra_trade_high = bar.high_price self.intra_trade_low = bar.low_price self.long_stop = 0 self.short_stop = 0 if self.MACD_trend > 0: self.buy(self.entry_up, self.trading_size, True) if self.MACD_trend < 0: self.short(self.entry_down, self.trading_size, True) elif self.pos > 0: self.intra_trade_high = max(self.intra_trade_high, bar.high_price) self.long_out = self.intra_trade_high * \ (1 - self.trailing_tax / 100) sell_price = max(self.long_stop, self.exit_down, self.long_out) self.sell(sell_price, abs(self.pos), True) elif self.pos < 0: self.intra_trade_low = min(self.intra_trade_low, bar.low_price) self.short_out = self.intra_trade_low * \ (1 + self.trailing_tax / 100) cover_price = min(self.short_stop, self.exit_up, self.short_out) self.cover(cover_price, abs(self.pos), True) if bar.datetime.day == 21: print(bar.datetime, self.entry_up, bar.open_price, bar.high_price, bar.low_price, bar.close_price) self.put_event() def on_30min_bar(self, bar: BarData): """""" self.am30.update_bar(bar) if not self.am30.inited: return self.entry_up, self.entry_down = self.am30.donchian(self.entry_window) self.exit_up, self.exit_down = self.am30.donchian(self.exit_window) if bar.datetime.day == 21: print("on 30 min", bar.datetime, self.entry_up) self.MACD_sign, self.signal, self.hist = self.am30.macd( self.fast_period, self.slow_period, self.signal_period) self.MACD_sign = self.signal - self.hist if self.MACD_sign > self.trend_level: self.MACD_trend = 1 elif self.MACD_sign < (-self.trend_level): self.MACD_trend = -1 else: self.MACD_trend = 0 self.put_event() def on_trade(self, trade: TradeData): """ Callback of new trade data update. """ if trade.direction == Direction.LONG: self.long_entry = trade.price self.long_stop = self.long_entry - 2 * self.atr_value else: self.short_entry = trade.price self.short_stop = self.short_entry + 2 * self.atr_value msg = f"新的成交,策略是{self.strategy_name},方向{trade.direction},开平{trade.offset},当前仓位{self.pos}" self.send_email(msg) def on_order(self, order: OrderData): """ Callback of new order data update. """ pass def on_stop_order(self, stop_order: StopOrder): """ Callback of stop order update. """ pass
class PeriodResonanceStrategy(TargetPosTemplate): """""" author = "MG" fast_window_1 = 6 slow_window_1 = 26 signal_period_1 = 9 period_n = 30 fast_window_n = 5 slow_window_n = 14 signal_period_n = 7 signal_pos = {} parameters = [ "fast_window_1", "slow_window_1", "signal_period_1", "fast_window_n", "slow_window_n", "signal_period_n", "period_n" ] variables = ["signal_pos", "target_pos"] def __init__(self, cta_engine, strategy_name, vt_symbol, setting): """""" super().__init__(cta_engine, strategy_name, vt_symbol, setting) self.write_log(f"setting={setting}") self.am = ArrayManager(size=max(self.fast_window_1, self.slow_window_1, self.signal_period_1) + 50) self.macd_signal = MACDSignal(self.fast_window_n, self.slow_window_n, self.signal_period_n, self.period_n) self.signal_pos = { "macd_1": 0, "macd_n": 0, } def on_init(self): """ Callback when strategy is inited. """ self.write_log("策略初始化") self.load_bar(10) def on_start(self): """ Callback when strategy is started. """ self.write_log("策略启动") def on_stop(self): """ Callback when strategy is stopped. """ self.write_log("策略停止") def on_tick(self, tick: TickData): """ Callback of new tick data update. """ super().on_tick(tick) self.macd_signal.on_tick(tick) self.calculate_target_pos() def on_bar(self, bar: BarData): """ Callback of new bar data update. """ super().on_bar(bar) # 更新1分钟级别MACD信号 self.am.update_bar(bar) if not self.am.inited: self.signal_pos['macd_1'] = 0 dif, dea, macd = self.am.macd(self.fast_window_1, self.slow_window_1, self.signal_period_1) if macd < -5: self.signal_pos['macd_1'] = 1 # self.write_log(f"{datetime_2_str(bar.datetime)} macd_1=1") elif macd > 5: self.signal_pos['macd_1'] = -1 # self.write_log(f"{datetime_2_str(bar.datetime)} macd_1=-1") else: # self.set_signal_pos(0) pass self.macd_signal.on_bar(bar) self.calculate_target_pos() def calculate_target_pos(self): """""" self.signal_pos["macd_n"] = self.macd_signal.get_signal_pos() target_pos = 0 for v in self.signal_pos.values(): target_pos += v self.set_target_pos(target_pos) # if target_pos != 0: # self.write_log(f"target_pos={target_pos}") def on_order(self, order: OrderData): """ Callback of new order data update. """ super().on_order(order) def on_trade(self, trade: TradeData): """ Callback of new trade data update. """ self.put_event() def on_stop_order(self, stop_order: StopOrder): """ Callback of stop order update. """ pass def on_stop_order(self, stop_order: StopOrder): """ Callback of stop order update. """ pass def write_log(self, msg: str): super().write_log(msg) logger.info(msg)