610 lines
25 KiB
Python
610 lines
25 KiB
Python
"""
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Comprehensive Indicator Comparison Test Suite
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This module provides testing framework to compare original indicators from cycles module
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with new implementations in IncrementalTrader module to ensure mathematical equivalence.
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"""
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import pandas as pd
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import numpy as np
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import matplotlib.pyplot as plt
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import matplotlib.dates as mdates
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from datetime import datetime
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import sys
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import os
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from pathlib import Path
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# Add project root to path
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project_root = Path(__file__).parent.parent
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sys.path.insert(0, str(project_root))
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# Import original indicators
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from cycles.IncStrategies.indicators import (
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MovingAverageState as OriginalMA,
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ExponentialMovingAverageState as OriginalEMA,
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ATRState as OriginalATR,
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SimpleATRState as OriginalSimpleATR,
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SupertrendState as OriginalSupertrend,
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RSIState as OriginalRSI,
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SimpleRSIState as OriginalSimpleRSI,
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BollingerBandsState as OriginalBB,
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BollingerBandsOHLCState as OriginalBBOHLC
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)
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# Import new indicators
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from IncrementalTrader.strategies.indicators import (
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MovingAverageState as NewMA,
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ExponentialMovingAverageState as NewEMA,
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ATRState as NewATR,
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SimpleATRState as NewSimpleATR,
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SupertrendState as NewSupertrend,
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RSIState as NewRSI,
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SimpleRSIState as NewSimpleRSI,
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BollingerBandsState as NewBB,
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BollingerBandsOHLCState as NewBBOHLC
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)
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class IndicatorComparisonTester:
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"""Test framework for comparing original and new indicator implementations."""
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def __init__(self, data_file: str = "data/btcusd_1-min_data.csv", sample_size: int = 10000):
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"""
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Initialize the tester with data.
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Args:
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data_file: Path to the CSV data file
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sample_size: Number of data points to use for testing (None for all data)
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"""
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self.data_file = data_file
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self.sample_size = sample_size
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self.data = None
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self.results = {}
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# Create results directory
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self.results_dir = Path("test/results")
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self.results_dir.mkdir(exist_ok=True)
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def load_data(self):
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"""Load and prepare the data for testing."""
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print(f"Loading data from {self.data_file}...")
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# Load data
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df = pd.read_csv(self.data_file)
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# Convert timestamp to datetime
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df['datetime'] = pd.to_datetime(df['Timestamp'], unit='s')
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# Take sample if specified
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if self.sample_size and len(df) > self.sample_size:
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# Take the most recent data
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df = df.tail(self.sample_size).reset_index(drop=True)
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self.data = df
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print(f"Loaded {len(df)} data points from {df['datetime'].iloc[0]} to {df['datetime'].iloc[-1]}")
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def compare_moving_averages(self, periods=[20, 50]):
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"""Compare Moving Average implementations."""
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print("\n=== Testing Moving Averages ===")
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for period in periods:
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print(f"Testing MA({period})...")
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# Initialize indicators
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original_ma = OriginalMA(period)
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new_ma = NewMA(period)
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original_values = []
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new_values = []
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# Process data
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for _, row in self.data.iterrows():
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price = row['Close']
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original_ma.update(price)
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new_ma.update(price)
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original_values.append(original_ma.get_current_value() if original_ma.is_warmed_up() else np.nan)
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new_values.append(new_ma.get_current_value() if new_ma.is_warmed_up() else np.nan)
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# Store results
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self.results[f'MA_{period}'] = {
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'original': original_values,
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'new': new_values,
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'dates': self.data['datetime'].tolist()
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}
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# Calculate differences
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diff = np.array(new_values) - np.array(original_values)
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valid_diff = diff[~np.isnan(diff)]
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print(f" Max difference: {np.max(np.abs(valid_diff)):.10f}")
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print(f" Mean difference: {np.mean(np.abs(valid_diff)):.10f}")
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print(f" Std difference: {np.std(valid_diff):.10f}")
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def compare_exponential_moving_averages(self, periods=[20, 50]):
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"""Compare Exponential Moving Average implementations."""
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print("\n=== Testing Exponential Moving Averages ===")
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for period in periods:
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print(f"Testing EMA({period})...")
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# Initialize indicators
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original_ema = OriginalEMA(period)
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new_ema = NewEMA(period)
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original_values = []
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new_values = []
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# Process data
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for _, row in self.data.iterrows():
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price = row['Close']
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original_ema.update(price)
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new_ema.update(price)
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original_values.append(original_ema.value if original_ema.is_ready else np.nan)
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new_values.append(new_ema.value if new_ema.is_ready else np.nan)
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# Store results
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self.results[f'EMA_{period}'] = {
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'original': original_values,
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'new': new_values,
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'dates': self.data['datetime'].tolist()
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}
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# Calculate differences
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diff = np.array(new_values) - np.array(original_values)
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valid_diff = diff[~np.isnan(diff)]
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print(f" Max difference: {np.max(np.abs(valid_diff)):.10f}")
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print(f" Mean difference: {np.mean(np.abs(valid_diff)):.10f}")
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print(f" Std difference: {np.std(valid_diff):.10f}")
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def compare_atr(self, periods=[14]):
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"""Compare ATR implementations."""
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print("\n=== Testing ATR ===")
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for period in periods:
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print(f"Testing ATR({period})...")
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# Initialize indicators
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original_atr = OriginalATR(period)
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new_atr = NewATR(period)
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original_values = []
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new_values = []
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# Process data
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for _, row in self.data.iterrows():
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high, low, close = row['High'], row['Low'], row['Close']
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original_atr.update(high, low, close)
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new_atr.update(high, low, close)
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original_values.append(original_atr.value if original_atr.is_ready else np.nan)
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new_values.append(new_atr.value if new_atr.is_ready else np.nan)
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# Store results
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self.results[f'ATR_{period}'] = {
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'original': original_values,
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'new': new_values,
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'dates': self.data['datetime'].tolist()
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}
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# Calculate differences
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diff = np.array(new_values) - np.array(original_values)
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valid_diff = diff[~np.isnan(diff)]
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print(f" Max difference: {np.max(np.abs(valid_diff)):.10f}")
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print(f" Mean difference: {np.mean(np.abs(valid_diff)):.10f}")
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print(f" Std difference: {np.std(valid_diff):.10f}")
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def compare_simple_atr(self, periods=[14]):
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"""Compare Simple ATR implementations."""
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print("\n=== Testing Simple ATR ===")
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for period in periods:
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print(f"Testing SimpleATR({period})...")
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# Initialize indicators
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original_atr = OriginalSimpleATR(period)
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new_atr = NewSimpleATR(period)
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original_values = []
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new_values = []
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# Process data
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for _, row in self.data.iterrows():
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high, low, close = row['High'], row['Low'], row['Close']
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original_atr.update(high, low, close)
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new_atr.update(high, low, close)
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original_values.append(original_atr.value if original_atr.is_ready else np.nan)
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new_values.append(new_atr.value if new_atr.is_ready else np.nan)
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# Store results
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self.results[f'SimpleATR_{period}'] = {
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'original': original_values,
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'new': new_values,
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'dates': self.data['datetime'].tolist()
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}
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# Calculate differences
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diff = np.array(new_values) - np.array(original_values)
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valid_diff = diff[~np.isnan(diff)]
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print(f" Max difference: {np.max(np.abs(valid_diff)):.10f}")
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print(f" Mean difference: {np.mean(np.abs(valid_diff)):.10f}")
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print(f" Std difference: {np.std(valid_diff):.10f}")
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def compare_supertrend(self, periods=[10], multipliers=[3.0]):
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"""Compare Supertrend implementations."""
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print("\n=== Testing Supertrend ===")
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for period in periods:
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for multiplier in multipliers:
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print(f"Testing Supertrend({period}, {multiplier})...")
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# Initialize indicators
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original_st = OriginalSupertrend(period, multiplier)
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new_st = NewSupertrend(period, multiplier)
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original_values = []
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new_values = []
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original_trends = []
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new_trends = []
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# Process data
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for _, row in self.data.iterrows():
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high, low, close = row['High'], row['Low'], row['Close']
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original_st.update(high, low, close)
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new_st.update(high, low, close)
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original_values.append(original_st.value if original_st.is_ready else np.nan)
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new_values.append(new_st.value if new_st.is_ready else np.nan)
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original_trends.append(original_st.trend if original_st.is_ready else 0)
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new_trends.append(new_st.trend if new_st.is_ready else 0)
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# Store results
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key = f'Supertrend_{period}_{multiplier}'
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self.results[key] = {
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'original': original_values,
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'new': new_values,
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'original_trend': original_trends,
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'new_trend': new_trends,
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'dates': self.data['datetime'].tolist()
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}
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# Calculate differences
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diff = np.array(new_values) - np.array(original_values)
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valid_diff = diff[~np.isnan(diff)]
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trend_diff = np.array(new_trends) - np.array(original_trends)
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trend_matches = np.sum(trend_diff == 0) / len(trend_diff) * 100
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print(f" Max difference: {np.max(np.abs(valid_diff)):.10f}")
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print(f" Mean difference: {np.mean(np.abs(valid_diff)):.10f}")
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print(f" Trend match: {trend_matches:.2f}%")
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def compare_rsi(self, periods=[14]):
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"""Compare RSI implementations."""
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print("\n=== Testing RSI ===")
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for period in periods:
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print(f"Testing RSI({period})...")
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# Initialize indicators
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original_rsi = OriginalRSI(period)
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new_rsi = NewRSI(period)
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original_values = []
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new_values = []
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# Process data
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for _, row in self.data.iterrows():
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price = row['Close']
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original_rsi.update(price)
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new_rsi.update(price)
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original_values.append(original_rsi.value if original_rsi.is_ready else np.nan)
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new_values.append(new_rsi.value if new_rsi.is_ready else np.nan)
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# Store results
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self.results[f'RSI_{period}'] = {
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'original': original_values,
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'new': new_values,
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'dates': self.data['datetime'].tolist()
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}
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# Calculate differences
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diff = np.array(new_values) - np.array(original_values)
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valid_diff = diff[~np.isnan(diff)]
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print(f" Max difference: {np.max(np.abs(valid_diff)):.10f}")
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print(f" Mean difference: {np.mean(np.abs(valid_diff)):.10f}")
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print(f" Std difference: {np.std(valid_diff):.10f}")
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def compare_simple_rsi(self, periods=[14]):
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"""Compare Simple RSI implementations."""
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print("\n=== Testing Simple RSI ===")
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for period in periods:
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print(f"Testing SimpleRSI({period})...")
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# Initialize indicators
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original_rsi = OriginalSimpleRSI(period)
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new_rsi = NewSimpleRSI(period)
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original_values = []
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new_values = []
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# Process data
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for _, row in self.data.iterrows():
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price = row['Close']
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original_rsi.update(price)
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new_rsi.update(price)
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original_values.append(original_rsi.value if original_rsi.is_ready else np.nan)
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new_values.append(new_rsi.value if new_rsi.is_ready else np.nan)
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# Store results
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self.results[f'SimpleRSI_{period}'] = {
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'original': original_values,
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'new': new_values,
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'dates': self.data['datetime'].tolist()
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}
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# Calculate differences
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diff = np.array(new_values) - np.array(original_values)
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valid_diff = diff[~np.isnan(diff)]
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print(f" Max difference: {np.max(np.abs(valid_diff)):.10f}")
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print(f" Mean difference: {np.mean(np.abs(valid_diff)):.10f}")
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print(f" Std difference: {np.std(valid_diff):.10f}")
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def compare_bollinger_bands(self, periods=[20], std_devs=[2.0]):
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"""Compare Bollinger Bands implementations."""
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print("\n=== Testing Bollinger Bands ===")
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for period in periods:
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for std_dev in std_devs:
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print(f"Testing BollingerBands({period}, {std_dev})...")
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# Initialize indicators
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original_bb = OriginalBB(period, std_dev)
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new_bb = NewBB(period, std_dev)
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original_upper = []
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original_middle = []
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original_lower = []
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new_upper = []
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new_middle = []
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new_lower = []
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# Process data
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for _, row in self.data.iterrows():
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price = row['Close']
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original_bb.update(price)
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new_bb.update(price)
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if original_bb.is_ready:
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original_upper.append(original_bb.upper)
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original_middle.append(original_bb.middle)
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original_lower.append(original_bb.lower)
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else:
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original_upper.append(np.nan)
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original_middle.append(np.nan)
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original_lower.append(np.nan)
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if new_bb.is_ready:
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new_upper.append(new_bb.upper)
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new_middle.append(new_bb.middle)
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new_lower.append(new_bb.lower)
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else:
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new_upper.append(np.nan)
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new_middle.append(np.nan)
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new_lower.append(np.nan)
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# Store results
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key = f'BB_{period}_{std_dev}'
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self.results[key] = {
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'original_upper': original_upper,
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'original_middle': original_middle,
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'original_lower': original_lower,
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'new_upper': new_upper,
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'new_middle': new_middle,
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'new_lower': new_lower,
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'dates': self.data['datetime'].tolist()
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}
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# Calculate differences
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for band in ['upper', 'middle', 'lower']:
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orig = np.array(locals()[f'original_{band}'])
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new = np.array(locals()[f'new_{band}'])
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diff = new - orig
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valid_diff = diff[~np.isnan(diff)]
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print(f" {band.capitalize()} band - Max diff: {np.max(np.abs(valid_diff)):.10f}, "
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f"Mean diff: {np.mean(np.abs(valid_diff)):.10f}")
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def plot_comparison(self, indicator_name: str, save_plot: bool = True):
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"""Plot comparison between original and new indicator implementations."""
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if indicator_name not in self.results:
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print(f"No results found for {indicator_name}")
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return
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result = self.results[indicator_name]
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dates = pd.to_datetime(result['dates'])
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# Create figure
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fig, axes = plt.subplots(2, 1, figsize=(15, 10))
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fig.suptitle(f'{indicator_name} - Original vs New Implementation Comparison', fontsize=16)
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# Plot 1: Overlay comparison
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ax1 = axes[0]
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if 'original' in result and 'new' in result:
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# Standard indicator comparison
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ax1.plot(dates, result['original'], label='Original', alpha=0.7, linewidth=1)
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ax1.plot(dates, result['new'], label='New', alpha=0.7, linewidth=1, linestyle='--')
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ax1.set_title(f'{indicator_name} Values Comparison')
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ax1.legend()
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ax1.grid(True, alpha=0.3)
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# Plot 2: Difference
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ax2 = axes[1]
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diff = np.array(result['new']) - np.array(result['original'])
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ax2.plot(dates, diff, color='red', alpha=0.7)
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ax2.set_title(f'{indicator_name} Difference (New - Original)')
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ax2.axhline(y=0, color='black', linestyle='-', alpha=0.5)
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ax2.grid(True, alpha=0.3)
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elif 'original_upper' in result:
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# Bollinger Bands comparison
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ax1.plot(dates, result['original_upper'], label='Original Upper', alpha=0.7)
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ax1.plot(dates, result['original_middle'], label='Original Middle', alpha=0.7)
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ax1.plot(dates, result['original_lower'], label='Original Lower', alpha=0.7)
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ax1.plot(dates, result['new_upper'], label='New Upper', alpha=0.7, linestyle='--')
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ax1.plot(dates, result['new_middle'], label='New Middle', alpha=0.7, linestyle='--')
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ax1.plot(dates, result['new_lower'], label='New Lower', alpha=0.7, linestyle='--')
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ax1.set_title(f'{indicator_name} Bollinger Bands Comparison')
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ax1.legend()
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ax1.grid(True, alpha=0.3)
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# Plot 2: Differences for all bands
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ax2 = axes[1]
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for band in ['upper', 'middle', 'lower']:
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orig = np.array(result[f'original_{band}'])
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new = np.array(result[f'new_{band}'])
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diff = new - orig
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ax2.plot(dates, diff, label=f'{band.capitalize()} diff', alpha=0.7)
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ax2.set_title(f'{indicator_name} Differences (New - Original)')
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ax2.axhline(y=0, color='black', linestyle='-', alpha=0.5)
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ax2.legend()
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ax2.grid(True, alpha=0.3)
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# Format x-axis
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for ax in axes:
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ax.xaxis.set_major_formatter(mdates.DateFormatter('%Y-%m-%d'))
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ax.xaxis.set_major_locator(mdates.DayLocator(interval=max(1, len(dates)//10)))
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plt.setp(ax.xaxis.get_majorticklabels(), rotation=45)
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|
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plt.tight_layout()
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|
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if save_plot:
|
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plot_path = self.results_dir / f"{indicator_name}_comparison.png"
|
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plt.savefig(plot_path, dpi=300, bbox_inches='tight')
|
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print(f"Plot saved to {plot_path}")
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|
|
|
plt.show()
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|
|
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def plot_all_comparisons(self):
|
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"""Plot comparisons for all tested indicators."""
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print("\n=== Generating Comparison Plots ===")
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|
|
|
for indicator_name in self.results.keys():
|
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print(f"Plotting {indicator_name}...")
|
|
self.plot_comparison(indicator_name, save_plot=True)
|
|
plt.close('all') # Close plots to save memory
|
|
|
|
def generate_summary_report(self):
|
|
"""Generate a summary report of all comparisons."""
|
|
print("\n=== Summary Report ===")
|
|
|
|
report_lines = []
|
|
report_lines.append("# Indicator Comparison Summary Report")
|
|
report_lines.append(f"Generated: {datetime.now().strftime('%Y-%m-%d %H:%M:%S')}")
|
|
report_lines.append(f"Data file: {self.data_file}")
|
|
report_lines.append(f"Sample size: {len(self.data)} data points")
|
|
report_lines.append("")
|
|
|
|
for indicator_name, result in self.results.items():
|
|
report_lines.append(f"## {indicator_name}")
|
|
|
|
if 'original' in result and 'new' in result:
|
|
# Standard indicator
|
|
diff = np.array(result['new']) - np.array(result['original'])
|
|
valid_diff = diff[~np.isnan(diff)]
|
|
|
|
if len(valid_diff) > 0:
|
|
report_lines.append(f"- Max absolute difference: {np.max(np.abs(valid_diff)):.10f}")
|
|
report_lines.append(f"- Mean absolute difference: {np.mean(np.abs(valid_diff)):.10f}")
|
|
report_lines.append(f"- Standard deviation: {np.std(valid_diff):.10f}")
|
|
report_lines.append(f"- Valid data points: {len(valid_diff)}")
|
|
|
|
# Check if differences are negligible
|
|
if np.max(np.abs(valid_diff)) < 1e-10:
|
|
report_lines.append("- ✅ **PASSED**: Implementations are mathematically equivalent")
|
|
elif np.max(np.abs(valid_diff)) < 1e-6:
|
|
report_lines.append("- ⚠️ **WARNING**: Small differences detected (likely floating point precision)")
|
|
else:
|
|
report_lines.append("- ❌ **FAILED**: Significant differences detected")
|
|
else:
|
|
report_lines.append("- ❌ **ERROR**: No valid data points for comparison")
|
|
|
|
elif 'original_upper' in result:
|
|
# Bollinger Bands
|
|
all_passed = True
|
|
for band in ['upper', 'middle', 'lower']:
|
|
orig = np.array(result[f'original_{band}'])
|
|
new = np.array(result[f'new_{band}'])
|
|
diff = new - orig
|
|
valid_diff = diff[~np.isnan(diff)]
|
|
|
|
if len(valid_diff) > 0:
|
|
max_diff = np.max(np.abs(valid_diff))
|
|
report_lines.append(f"- {band.capitalize()} band max diff: {max_diff:.10f}")
|
|
if max_diff >= 1e-6:
|
|
all_passed = False
|
|
|
|
if all_passed:
|
|
report_lines.append("- ✅ **PASSED**: All bands are mathematically equivalent")
|
|
else:
|
|
report_lines.append("- ❌ **FAILED**: Significant differences in one or more bands")
|
|
|
|
report_lines.append("")
|
|
|
|
# Save report
|
|
report_path = self.results_dir / "comparison_summary.md"
|
|
with open(report_path, 'w') as f:
|
|
f.write('\n'.join(report_lines))
|
|
|
|
print(f"Summary report saved to {report_path}")
|
|
|
|
# Print summary to console
|
|
print('\n'.join(report_lines))
|
|
|
|
def run_all_tests(self):
|
|
"""Run all indicator comparison tests."""
|
|
print("Starting comprehensive indicator comparison tests...")
|
|
|
|
# Load data
|
|
self.load_data()
|
|
|
|
# Run all comparisons
|
|
self.compare_moving_averages()
|
|
self.compare_exponential_moving_averages()
|
|
self.compare_atr()
|
|
self.compare_simple_atr()
|
|
self.compare_supertrend()
|
|
self.compare_rsi()
|
|
self.compare_simple_rsi()
|
|
self.compare_bollinger_bands()
|
|
|
|
# Generate plots and reports
|
|
self.plot_all_comparisons()
|
|
self.generate_summary_report()
|
|
|
|
print("\n✅ All tests completed! Check the test/results/ directory for detailed outputs.")
|
|
|
|
|
|
if __name__ == "__main__":
|
|
# Run the comprehensive test suite
|
|
tester = IndicatorComparisonTester(sample_size=5000) # Use 5000 data points for faster testing
|
|
tester.run_all_tests() |