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| import pandas as pd | |
| import matplotlib.pyplot as plt | |
| import sys | |
| sys.path.append("../") | |
| from model import Kronos, KronosTokenizer, KronosPredictor | |
| def plot_prediction(kline_df, pred_df): | |
| pred_df.index = kline_df.index[-pred_df.shape[0]:] | |
| sr_close = kline_df['close'] | |
| sr_pred_close = pred_df['close'] | |
| sr_close.name = 'Ground Truth' | |
| sr_pred_close.name = "Prediction" | |
| sr_volume = kline_df['volume'] | |
| sr_pred_volume = pred_df['volume'] | |
| sr_volume.name = 'Ground Truth' | |
| sr_pred_volume.name = "Prediction" | |
| close_df = pd.concat([sr_close, sr_pred_close], axis=1) | |
| volume_df = pd.concat([sr_volume, sr_pred_volume], axis=1) | |
| fig, (ax1, ax2) = plt.subplots(2, 1, figsize=(8, 6), sharex=True) | |
| ax1.plot(close_df['Ground Truth'], label='Ground Truth', color='blue', linewidth=1.5) | |
| ax1.plot(close_df['Prediction'], label='Prediction', color='red', linewidth=1.5) | |
| ax1.set_ylabel('Close Price', fontsize=14) | |
| ax1.legend(loc='lower left', fontsize=12) | |
| ax1.grid(True) | |
| ax2.plot(volume_df['Ground Truth'], label='Ground Truth', color='blue', linewidth=1.5) | |
| ax2.plot(volume_df['Prediction'], label='Prediction', color='red', linewidth=1.5) | |
| ax2.set_ylabel('Volume', fontsize=14) | |
| ax2.legend(loc='upper left', fontsize=12) | |
| ax2.grid(True) | |
| plt.tight_layout() | |
| plt.show() | |
| # 1. Load Model and Tokenizer | |
| tokenizer = KronosTokenizer.from_pretrained("NeoQuasar/Kronos-Tokenizer-base") | |
| model = Kronos.from_pretrained("NeoQuasar/Kronos-small") | |
| # 2. Instantiate Predictor | |
| predictor = KronosPredictor(model, tokenizer, max_context=512) | |
| # 3. Prepare Data | |
| df = pd.read_csv("./data/XSHG_5min_600977.csv") | |
| df['timestamps'] = pd.to_datetime(df['timestamps']) | |
| lookback = 400 | |
| pred_len = 120 | |
| x_df = df.loc[:lookback-1, ['open', 'high', 'low', 'close', 'volume', 'amount']] | |
| x_timestamp = df.loc[:lookback-1, 'timestamps'] | |
| y_timestamp = df.loc[lookback:lookback+pred_len-1, 'timestamps'] | |
| # 4. Make Prediction | |
| pred_df = predictor.predict( | |
| df=x_df, | |
| x_timestamp=x_timestamp, | |
| y_timestamp=y_timestamp, | |
| pred_len=pred_len, | |
| T=1.0, | |
| top_p=0.9, | |
| sample_count=1, | |
| verbose=True | |
| ) | |
| # 5. Visualize Results | |
| print("Forecasted Data Head:") | |
| print(pred_df.head()) | |
| # Combine historical and forecasted data for plotting | |
| kline_df = df.loc[:lookback+pred_len-1] | |
| # visualize | |
| plot_prediction(kline_df, pred_df) | |