263 lines
13 KiB
Python
263 lines
13 KiB
Python
from math import nan
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import pandas as pd
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import plotly.graph_objects as go
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from plotly import subplots
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import os
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from hts.HTS import HTS
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from stock.util.Stock2Vector import Stock2Vector
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from stock.util.LabelChecker import LabelChecker
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from hts.BuySellChecker import BuySellChecker
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from stock.analysis.StockStatus import StockStatus
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class Simulation (HTS):
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stock2Vector = None
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buySellChecker = None
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def __init__(self, RESOURCE_PATH):
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super().__init__(RESOURCE_PATH)
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self.RESOURCE_PATH = RESOURCE_PATH
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self.buySellChecker = BuySellChecker()
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try:
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self.stock2Vector = Stock2Vector(RESOURCE_PATH)
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self.labelChecker = LabelChecker(RESOURCE_PATH)
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except:
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pass
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#self.connect()
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return
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def draw(self, stock_code, given_day, data, bsLine):
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if bsLine is None:
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return
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# 어제 데이터는 지운다.
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data = data.loc[pd.DatetimeIndex(data.index).day == int(given_day[6:])]
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buy_line = bsLine['buy'][len(bsLine['buy'])-len(data):]
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buy_weight_line = bsLine['buy_weight'][len(bsLine['buy'])-len(data):]
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sell_line = bsLine['sell'][len(bsLine['sell'])-len(data):]
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sell_weight_line = bsLine['sell_weight'][len(bsLine['sell']) - len(data):]
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# 그래프 설정을 위한 변수를 생성한다.
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data = data.astype({'open': 'int',
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'high': 'int',
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'low': 'int',
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'close': 'int',
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'volume': 'int',
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'avg5': 'float',
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'avg20': 'float',
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'avg60': 'float',
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'avg120': 'float',
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'avg200': 'float',
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'disparity_avg5': 'float',
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'disparity_avg20': 'float',
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'disparity_avg60': 'float',
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'disparity_avg120': 'float',
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'disparity_avg200': 'float',
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'fast_k': 'float',
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'slow_k': 'float',
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'slow_d': 'float',
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'rsi': 'float',
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'rsis': 'float'
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})
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buy_size = []
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buy_colors = []
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for i in range(len(buy_line)):
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if buy_line[i] < 0:
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buy_colors.append("#ffffff")
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buy_line[i] = nan
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buy_size.append(0)
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else:
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buy_colors.append("#0C752E")
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buy_size.append(10 + (5 * buy_weight_line[i]))
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sell_size = []
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sell_colors = []
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for i in range(len(sell_line)):
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if sell_line[i] < 0:
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sell_colors.append("#ffffff")
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sell_line[i] = nan
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sell_size.append(0)
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else:
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sell_colors.append("#00ced1")
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sell_size.append(10 + (5 * sell_weight_line[i]))
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volume_colors = []
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for i in range(len(buy_line)):
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if data['open'][i] > data['close'][i]:
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volume_colors.append("#0000FF")
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elif data['open'][i] < data['close'][i]:
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volume_colors.append("#FF0000")
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else:
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volume_colors.append("#000000")
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# 그래프를 설정한다.
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buy_check = go.Scatter(x=data['date'], y=buy_line, mode='markers', name="buy", marker=dict(size=buy_size, color=buy_colors, line_width=0))
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sell_check = go.Scatter(x=data['date'], y=sell_line, mode='markers', name="sell", marker=dict(size=14, color=sell_colors, line_width=0))
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upper = go.Scatter(x=data['date'], y=data["upper"], name="upper", line_color='#000000')
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lower = go.Scatter(x=data['date'], y=data["lower"], name="lower", line_color='#000000')
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avg5 = go.Scatter(x=data['date'], y=data["avg5"], name="avg5", line_color='#F81191')
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avg20 = go.Scatter(x=data['date'], y=data["avg20"], name="avg20", line_color='#097F19')
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avg30 = go.Scatter(x=data['date'], y=data["avg30"], name="avg30", line_color='#097F19')
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avg60 = go.Scatter(x=data['date'], y=data["avg60"], name="avg60", line_color='#671BEA')
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avg120 = go.Scatter(x=data['date'], y=data["avg120"], name="avg120", line_color='#DFB809')
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avg200 = go.Scatter(x=data['date'], y=data["avg200"], name="avg200", line_color='#000000')
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laggingSpan = go.Scatter(x=data['date'], y=data["laggingSpan"], name='laggingSpan', line_color='#B50ABB')
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changeLine = go.Scatter(x=data['date'], y=data["changeLine"], name='changeLine', line_color='#14A200')
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baseLine = go.Scatter(x=data['date'], y=data["baseLine"], name='baseLine', line_color='#CF6E0D')
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candle_stick = go.Candlestick(x=data['date'], open=data['open'], high=data['high'], low=data['low'], close=data['close'], increasing_line_color='red', decreasing_line_color='blue', showlegend=False)
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#volume_line = go.Scatter(x=data['date'], y=data["volume"], mode='lines', name='volume')
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volume_line = go.Bar(x=data['date'], y=data["volume"], marker_color=volume_colors, name='volume')
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disparity_avg5 = go.Scatter(x=data['date'], y=data["disparity_avg5"], name="disparity_avg5", line_color='#F81191')
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disparity_avg20 = go.Scatter(x=data['date'], y=data["disparity_avg20"], name="disparity_avg20", line_color='#097F19')
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disparity_avg30 = go.Scatter(x=data['date'], y=data["disparity_avg30"], name="disparity_avg30", line_color='#097F19')
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disparity_avg60 = go.Scatter(x=data['date'], y=data["disparity_avg60"], name="disparity_avg60", line_color='#671BEA')
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disparity_avg120 = go.Scatter(x=data['date'], y=data["disparity_avg120"], name="disparity_avg120", line_color='#DFB809')
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disparity_avg200 = go.Scatter(x=data['date'], y=data["disparity_avg200"], name="disparity_avg200", line_color='#000000')
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macd_line = go.Scatter(x=data['date'], y=data["macd"], line=dict(color='red', width=2), name='macd')
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macd_s_line = go.Scatter(x=data['date'], y=data["macds"], line=dict(dash='dashdot', color='black', width=2), name='macds')
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macd_o_line = go.Bar(x=data['date'], y=data["macdo"], marker_color='purple', name='macdo')
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# fast_k_line = go.Scatter(x=hts['date'], y=hts["fast_k"], mode='lines', name='fast_k')
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slow_k_line = go.Scatter(x=data['date'], y=data["slow_k"], line=dict(color='red', width=2), name='slow_k')
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slow_d_line = go.Scatter(x=data['date'], y=data["slow_d"], line=dict(dash='dashdot', color='black', width=2), name='slow_d')
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rsi_line = go.Scatter(x=data['date'], y=data["rsi"], line=dict(color='red', width=2), name='rsi')
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rsis_line = go.Scatter(x=data['date'], y=data["rsis"], line=dict(dash='dashdot', color='black', width=2), name='rsis')
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#candle_data = [candle_stick, upper, lower, avg5, avg20, avg30, avg60, avg120, avg200, buy_check, sell_check, laggingSpan, changeLine, baseLine]
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candle_data = [candle_stick, avg5, avg20, avg30, avg60, avg200, buy_check, sell_check]
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#candle_data = [candle_stick, avg200, buy_check, sell_check]
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volume_data = [volume_line]
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disparity_data = [disparity_avg5, disparity_avg20, disparity_avg30, disparity_avg60, disparity_avg120, disparity_avg200]
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macd_data = [macd_line, macd_s_line, macd_o_line]
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stochastic_data = [slow_k_line, slow_d_line]
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rsi_data = [rsi_line, rsis_line]
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# 그래프를 그린다.
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"""
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fig = go.Figure(data=candle_data)
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fig.update_layout(title=stock_code + "_" + given_day)
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fig.show()
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"""
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fig = subplots.make_subplots(
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rows=6, cols=1,
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subplot_titles=("이격도", "스토캐스틱", "RSI", "MACD", "거래량", '캔들'),
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#specs=[[{}], [{}], [{}], [{}], [{}], [{}]],
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shared_xaxes=True, horizontal_spacing=0.03, vertical_spacing=0.01,
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row_heights=[200, 200, 200, 200, 200, 700]
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)
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for trace in disparity_data:
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fig.append_trace(trace, 1, 1)
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for trace in stochastic_data:
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fig.append_trace(trace, 2, 1)
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for trace in rsi_data:
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fig.append_trace(trace, 3, 1)
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for trace in macd_data:
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fig.append_trace(trace, 4, 1)
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for trace in volume_data:
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fig.append_trace(trace, 5, 1)
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for trace in candle_data:
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fig.append_trace(trace, 6, 1)
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#fig.update_xaxes(nticks=5)
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#fig.update_layout(height=1800, title=stock_code + "_" + given_day, xaxis_rangeslider_visible=False)
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df = pd.DataFrame(bsLine)
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df = df.fillna(-1)
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buy_count = len(df.loc[df["buy"] > 0])
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sell_count = len(df.loc[df["sell"] > 0])
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fig.update_layout(height=1700, title=stock_code + "_" + given_day + "_" + str(buy_count)+","+str(sell_count))
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#fig.update_layout(title=stock_code + "_" + given_day + "_" + str(buy_count) + "," + str(sell_count))
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fig.show()
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return
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def makeTickData(self, data, mins=30):
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result = {"check": set(),
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"time": [],
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"open": [],
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"close": [],
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"high": [],
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"low": [],
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"vol": [],
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"label": []}
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for i in range(mins, len(data['time'])+1):
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result["check"].add(data['time'][i-1])
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result["time"].append(data['time'][i-1])
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result["open"].append(data['open'][i-mins])
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result["close"].append(data['close'][i-1])
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result["high"].append(max(data['high'][i - mins: i]))
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result["low"].append(min(data['low'][i - mins: i]))
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result["vol"].append(sum(data['vol'][i - mins: i]))
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return result
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def simulate(self, stock_codes:dict=None, analyzed_day=1000):
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for stock_code in stock_codes:
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for given_day in stock_codes[stock_code]:
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LAST_DATA = self.stock2Vector.getLastData(stock_code, given_day)
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# 1분봉
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result = self.stock2Vector.getRealTime(stock_code, given_day, LAST_DATA)
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# 5분봉
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#result = self.makeTickData(result, mins=5)
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# 30분봉
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#result = self.makeTickData(result, mins=30)
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data = self.buySellChecker.analyze(result)
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data.drop(data.index[:len(data) - analyzed_day], inplace=True)
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# 이동평균, RSI, MACD, 일목균형, 볼린저밴드 상/하단을 계산한다.
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#data_5 = self.buySellChecker.analyze(result_5)
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# 분석일 데이터만 활용한다 (이전 데이터는 제거)
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#data_5.drop(data_5.index[:len(data_5) - analyzed_day], inplace=True)
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#data_30 = self.buySellChecker.analyze(result_30)
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# 분석일 데이터만 활용한다 (이전 데이터는 제거)
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#data_30.drop(data_30.index[:len(data_30) - analyzed_day], inplace=True)
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# 사야 할 시점과 팔아야 할 시점을 체크한다.
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#bsLine = self.buySellChecker.checkTransaction(stock_code, data, data_5, data_30, isRealTime=False)
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# 어제 데이터는 지운다.
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#data = data.loc[pd.DatetimeIndex(data.index).day == int(given_day[6:])]
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bsLine = self.buySellChecker.checkTransaction(stock_code, data, None, None, isRealTime=False)
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# 그래프를 그린다.
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self.draw(stock_code, given_day, data, bsLine)
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return
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if __name__ == "__main__":
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PROJECT_HOME = os.getcwd()
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RESOURCE_PATH = os.path.join(PROJECT_HOME, "resources")
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simulation = Simulation(RESOURCE_PATH)
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# to check bying
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stock_codes = {
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#"252670": ['20210930'],
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#"252670": ['20210903','20210910','20210913'],
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#"252670": ['20210901', '20210902', '20210903', '20210906', '20210907', '20210908', '20210909', '20210910', '20210913', '20210914', '20210915', '20210916', '20210917', '20210923', '20210924', '20210927', '20210928', '20210929', '20210930', '20211001', '20211005','20231012','20231013'],
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#"122630": ['20230930'],
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#"122630": ['20210901','20210902','20210903','20210906','20231012','20231013']
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#"122630": ['20210901', '20210902', '20210903', '20210906', '20210907', '20210908', '20210909', '20210910', '20210913', '20210914', '20210915', '20210916', '20210917', '20210923', '20210924', '20210927', '20210928', '20210929', '20210930', '20211001', '20211005','20231012','20231013'],
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"251340": ['20231012', '20231013'],
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"233740": ['20231012', '20231013'],
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}
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#simulation.simulate(stock_codes)
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simulation.simulate(stock_codes)
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print ("done...")
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